Adding some new things

This commit is contained in:
Vedant Dave 2023-04-24 17:42:37 +02:00
parent 02a66cfb33
commit ab4e7b9a22
4 changed files with 437 additions and 100 deletions

View File

@ -23,23 +23,24 @@ class ObservationEncoder(nn.Module):
self.convs = nn.Sequential(*layers) self.convs = nn.Sequential(*layers)
self.fc = nn.Linear(256 * 3 * 3, 2 * state_size) self.fc = nn.Linear(256 * obs_shape[0], 2 * state_size) # 9 if 3 frames stacked
def forward(self, x): def forward(self, x):
x = self.convs(x) x_reshaped = x.reshape(-1, *x.shape[-3:])
x = x.view(x.size(0), -1) x_embed = self.convs(x_reshaped)
x = self.fc(x) x_embed = torch.reshape(x_embed, (*x.shape[:-3], -1))
x = self.fc(x_embed)
# Mean and standard deviation # Mean and standard deviation
mean, std = torch.chunk(x, 2, dim=-1) mean, std = torch.chunk(x, 2, dim=-1)
mean = nn.ELU()(mean)
std = F.softplus(std) std = F.softplus(std)
std = torch.clamp(std, min=0.0, max=1e5) std = torch.clamp(std, min=0.0, max=1e1)
# Normal Distribution # Normal Distribution
dist = self.get_dist(mean, std) dist = self.get_dist(mean, std)
# Sampling via reparameterization Trick # Sampling via reparameterization Trick
#x = dist.rsample()
x = self.reparameterize(mean, std) x = self.reparameterize(mean, std)
encoded_output = {"sample": x, "distribution": dist} encoded_output = {"sample": x, "distribution": dist}
@ -63,7 +64,7 @@ class ObservationDecoder(nn.Module):
self.output_shape = output_shape self.output_shape = output_shape
self.input_size = 256 * 3 * 3 self.input_size = 256 * 3 * 3
self.in_channels = [self.input_size, 256, 128, 64] self.in_channels = [self.input_size, 256, 128, 64]
self.out_channels = [256, 128, 64, 3] self.out_channels = [256, 128, 64, 9]
if output_shape[1] == 84: if output_shape[1] == 84:
self.kernels = [5, 7, 5, 6] self.kernels = [5, 7, 5, 6]
@ -94,43 +95,50 @@ class ObservationDecoder(nn.Module):
class Actor(nn.Module): class Actor(nn.Module):
def __init__(self, state_size, hidden_size, action_size, num_layers=5): def __init__(self, state_size, hidden_size, action_size, num_layers=4, min_std=1e-4, init_std=5, mean_scale=5):
super().__init__() super().__init__()
self.state_size = state_size self.state_size = state_size
self.hidden_size = hidden_size self.hidden_size = hidden_size
self.action_size = action_size self.action_size = action_size
self.num_layers = num_layers self.num_layers = num_layers
self._min_std=torch.Tensor([1e-4])[0] self._min_std = min_std
self._init_std=torch.Tensor([5])[0] self._init_std = init_std
self._mean_scale=torch.Tensor([5])[0] self._mean_scale = mean_scale
layers = [] layers = []
for i in range(self.num_layers): for i in range(self.num_layers):
input_channels = state_size if i == 0 else self.hidden_size input_channels = state_size if i == 0 else self.hidden_size
output_channels = self.hidden_size if i!= self.num_layers-1 else 2*action_size layers.append(nn.Linear(input_channels, self.hidden_size))
layers.append(nn.Linear(input_channels, output_channels)) layers.append(nn.ReLU())
layers.append(nn.LeakyReLU()) layers.append(nn.Linear(self.hidden_size, 2*self.action_size))
self.action_model = nn.Sequential(*layers) self.action_model = nn.Sequential(*layers)
def get_dist(self, mean, std): def get_dist(self, mean, std):
distribution = torch.distributions.Normal(mean, std) distribution = torch.distributions.Normal(mean, std)
distribution = torch.distributions.transformed_distribution.TransformedDistribution(distribution, TanhBijector()) distribution = torch.distributions.transformed_distribution.TransformedDistribution(distribution, TanhBijector())
distribution = torch.distributions.independent.Independent(distribution, 1) distribution = torch.distributions.independent.Independent(distribution, 1)
distribution = SampleDist(distribution)
return distribution return distribution
def add_exploration(self, action, action_noise=0.3):
return torch.clamp(torch.distributions.Normal(action, action_noise).rsample(), -1, 1)
def forward(self, features): def forward(self, features):
out = self.action_model(features) out = self.action_model(features)
mean, std = torch.chunk(out, 2, dim=-1) mean, std = torch.chunk(out, 2, dim=-1)
raw_init_std = torch.log(torch.exp(self._init_std) - 1) raw_init_std = np.log(np.exp(self._init_std) - 1)
action_mean = self._mean_scale * torch.tanh(mean / self._mean_scale) action_mean = self._mean_scale * torch.tanh(mean / self._mean_scale)
action_std = F.softplus(std + raw_init_std) + self._min_std action_std = F.softplus(std + raw_init_std) + self._min_std
dist = self.get_dist(action_mean, action_std) dist = self.get_dist(action_mean, action_std)
sample = dist.rsample() sample = dist.rsample() #self.reparameterize(action_mean, action_std)
return sample return sample
def reparameterize(self, mu, std):
eps = torch.randn_like(std)
return mu + eps * std
class ValueModel(nn.Module): class ValueModel(nn.Module):
def __init__(self, state_size, hidden_size, num_layers=4): def __init__(self, state_size, hidden_size, num_layers=4):
@ -140,11 +148,12 @@ class ValueModel(nn.Module):
self.num_layers = num_layers self.num_layers = num_layers
layers = [] layers = []
for i in range(self.num_layers): for i in range(self.num_layers-1):
input_channels = state_size if i == 0 else self.hidden_size input_channels = state_size if i == 0 else self.hidden_size
output_channels = self.hidden_size if i!= self.num_layers-1 else 1 output_channels = self.hidden_size
layers.append(nn.Linear(input_channels, output_channels)) layers.append(nn.Linear(input_channels, output_channels))
layers.append(nn.LeakyReLU()) layers.append(nn.LeakyReLU())
layers.append(nn.Linear(self.hidden_size, int(np.prod(1))))
self.value_model = nn.Sequential(*layers) self.value_model = nn.Sequential(*layers)
def forward(self, state): def forward(self, state):
@ -169,6 +178,7 @@ class RewardModel(nn.Module):
return torch.distributions.independent.Independent( return torch.distributions.independent.Independent(
torch.distributions.Normal(reward, 1), 1) torch.distributions.Normal(reward, 1), 1)
"""
class TransitionModel(nn.Module): class TransitionModel(nn.Module):
def __init__(self, state_size, hidden_size, action_size, history_size): def __init__(self, state_size, hidden_size, action_size, history_size):
super().__init__() super().__init__()
@ -180,6 +190,7 @@ class TransitionModel(nn.Module):
self.act_fn = nn.LeakyReLU() self.act_fn = nn.LeakyReLU()
self.fc_state_action = nn.Linear(state_size + action_size, hidden_size) self.fc_state_action = nn.Linear(state_size + action_size, hidden_size)
self.ln = nn.LayerNorm(hidden_size)
self.history_cell = nn.GRUCell(hidden_size + history_size, history_size) self.history_cell = nn.GRUCell(hidden_size + history_size, history_size)
self.fc_state_prior = nn.Linear(history_size + state_size + action_size, 2 * state_size) self.fc_state_prior = nn.Linear(history_size + state_size + action_size, 2 * state_size)
self.fc_state_posterior = nn.Linear(history_size + state_size + action_size, 2 * state_size) self.fc_state_posterior = nn.Linear(history_size + state_size + action_size, 2 * state_size)
@ -194,12 +205,25 @@ class TransitionModel(nn.Module):
distribution = torch.distributions.independent.Independent(distribution, 1) distribution = torch.distributions.independent.Independent(distribution, 1)
return distribution return distribution
def imagine_step(self, prev_state, prev_action, prev_history): def stack_states(self, states, dim=0):
state_action = self.act_fn(self.fc_state_action(torch.cat([prev_state, prev_action], dim=-1))) s = dict(
prev_hist = prev_history.detach() mean = torch.stack([state['mean'] for state in states], dim=dim),
history = self.history_cell(torch.cat([state_action, prev_hist], dim=-1), prev_hist) std = torch.stack([state['std'] for state in states], dim=dim),
sample = torch.stack([state['sample'] for state in states], dim=dim),
history = torch.stack([state['history'] for state in states], dim=dim),)
if 'distribution' in states:
dist = dict(distribution = [state['distribution'] for state in states])
s.update(dist)
return s
state_prior = self.fc_state_prior(torch.cat([history, prev_state, prev_action], dim=-1)) def seq_to_batch(self, state, name):
return dict(
sample = torch.reshape(state[name], (state[name].shape[0]* state[name].shape[1], *state[name].shape[2:])))
def imagine_step(self, state, action, history):
state_action = self.ln(self.act_fn(self.fc_state_action(torch.cat([state, action], dim=-1))))
imag_hist = self.history_cell(torch.cat([state_action, history], dim=-1), history)
state_prior = self.fc_state_prior(torch.cat([imag_hist, state, action], dim=-1))
state_prior_mean, state_prior_std = torch.chunk(state_prior, 2, dim=-1) state_prior_mean, state_prior_std = torch.chunk(state_prior, 2, dim=-1)
state_prior_std = F.softplus(state_prior_std) state_prior_std = F.softplus(state_prior_std)
@ -208,19 +232,9 @@ class TransitionModel(nn.Module):
# Sampling via reparameterization Trick # Sampling via reparameterization Trick
sample_state_prior = self.reparemeterize(state_prior_mean, state_prior_std) sample_state_prior = self.reparemeterize(state_prior_mean, state_prior_std)
prior = {"mean": state_prior_mean, "std": state_prior_std, "sample": sample_state_prior, "history": history, "distribution": state_prior_dist} prior = {"mean": state_prior_mean, "std": state_prior_std, "sample": sample_state_prior, "history": imag_hist, "distribution": state_prior_dist}
return prior return prior
def stack_states(self, states, dim=0):
s = dict(
mean = torch.stack([state['mean'] for state in states], dim=dim),
std = torch.stack([state['std'] for state in states], dim=dim),
sample = torch.stack([state['sample'] for state in states], dim=dim),
history = torch.stack([state['history'] for state in states], dim=dim),)
dist = dict(distribution = [state['distribution'] for state in states])
s.update(dist)
return s
def imagine_rollout(self, state, action, history, horizon): def imagine_rollout(self, state, action, history, horizon):
imagined_priors = [] imagined_priors = []
for i in range(horizon): for i in range(horizon):
@ -231,9 +245,125 @@ class TransitionModel(nn.Module):
imagined_priors = self.stack_states(imagined_priors, dim=0) imagined_priors = self.stack_states(imagined_priors, dim=0)
return imagined_priors return imagined_priors
def observe_step(self, prev_state, prev_action, prev_history, nonterms):
state_action = self.ln(self.act_fn(self.fc_state_action(torch.cat([prev_state, prev_action], dim=-1))))
current_history = self.history_cell(torch.cat([state_action, prev_history], dim=-1), prev_history)
state_prior = self.fc_state_prior(torch.cat([prev_history, prev_state, prev_action], dim=-1))
state_prior_mean, state_prior_std = torch.chunk(state_prior*nonterms, 2, dim=-1)
state_prior_std = F.softplus(state_prior_std) + 0.1
sample_state_prior = state_prior_mean + torch.randn_like(state_prior_mean) * state_prior_std
prior = {"mean": state_prior_mean, "std": state_prior_std, "sample": sample_state_prior, "history": current_history}
return prior
def observe_rollout(self, rollout_states, rollout_actions, init_history, nonterms):
observed_rollout = []
for i in range(rollout_states.shape[0]):
actions = rollout_actions[i] * nonterms[i]
prior = self.observe_step(rollout_states[i], actions, init_history, nonterms[i])
init_history = prior["history"]
observed_rollout.append(prior)
observed_rollout = self.stack_states(observed_rollout, dim=0)
return observed_rollout
def reparemeterize(self, mean, std): def reparemeterize(self, mean, std):
eps = torch.randn_like(std) eps = torch.randn_like(std)
return mean + eps * std return mean + eps * std
"""
class TransitionModel(nn.Module):
def __init__(self, state_size, hidden_size, action_size, history_size):
super().__init__()
self.state_size = state_size
self.hidden_size = hidden_size
self.action_size = action_size
self.history_size = history_size
self.act_fn = nn.ELU()
self.fc_state_action = nn.Linear(state_size + action_size, hidden_size)
self.history_cell = nn.GRUCell(hidden_size, history_size)
self.fc_state_mu = nn.Linear(history_size + hidden_size, state_size)
self.fc_state_sigma = nn.Linear(history_size + hidden_size, state_size)
self.batch_norm = nn.BatchNorm1d(hidden_size)
self.batch_norm2 = nn.BatchNorm1d(state_size)
self.min_sigma = 1e-4
self.max_sigma = 1e0
def init_states(self, batch_size, device):
self.prev_state = torch.zeros(batch_size, self.state_size).to(device)
self.prev_action = torch.zeros(batch_size, self.action_size).to(device)
self.prev_history = torch.zeros(batch_size, self.history_size).to(device)
def get_dist(self, mean, std):
distribution = torch.distributions.Normal(mean, std)
distribution = torch.distributions.independent.Independent(distribution, 1)
return distribution
def stack_states(self, states, dim=0):
s = dict(
mean = torch.stack([state['mean'] for state in states], dim=dim),
std = torch.stack([state['std'] for state in states], dim=dim),
sample = torch.stack([state['sample'] for state in states], dim=dim),
history = torch.stack([state['history'] for state in states], dim=dim),)
if 'distribution' in states:
dist = dict(distribution = [state['distribution'] for state in states])
s.update(dist)
return s
def seq_to_batch(self, state, name):
return dict(
sample = torch.reshape(state[name], (state[name].shape[0]* state[name].shape[1], *state[name].shape[2:])))
def imagine_step(self, state, action, history):
next_state_action_enc = self.act_fn(self.batch_norm(self.fc_state_action(torch.cat([state, action], dim=-1))))
imag_history = self.history_cell(next_state_action_enc, history)
next_state_mu = self.act_fn(self.batch_norm2(self.fc_state_mu(torch.cat([next_state_action_enc, imag_history], dim=-1))))
next_state_sigma = torch.sigmoid(self.fc_state_sigma(torch.cat([next_state_action_enc, imag_history], dim=-1)))
next_state_sigma = self.min_sigma + (self.max_sigma - self.min_sigma) * next_state_sigma
# Normal Distribution
next_state_dist = self.get_dist(next_state_mu, next_state_sigma)
next_state_sample = self.reparemeterize(next_state_mu, next_state_sigma)
prior = {"mean": next_state_mu, "std": next_state_sigma, "sample": next_state_sample, "history": imag_history, "distribution": next_state_dist}
return prior
def imagine_rollout(self, state, action, history, horizon):
imagined_priors = []
for i in range(horizon):
prior = self.imagine_step(state, action, history)
state = prior["sample"]
history = prior["history"]
imagined_priors.append(prior)
imagined_priors = self.stack_states(imagined_priors, dim=0)
return imagined_priors
def observe_step(self, prev_state, prev_action, prev_history):
state_action_enc = self.act_fn(self.batch_norm(self.fc_state_action(torch.cat([prev_state, prev_action], dim=-1))))
current_history = self.history_cell(state_action_enc, prev_history)
state_mu = self.act_fn(self.batch_norm2(self.fc_state_mu(torch.cat([state_action_enc, prev_history], dim=-1))))
state_sigma = F.softplus(self.fc_state_sigma(torch.cat([state_action_enc, prev_history], dim=-1)))
sample_state = state_mu + torch.randn_like(state_mu) * state_sigma
state_enc = {"mean": state_mu, "std": state_sigma, "sample": sample_state, "history": current_history}
return state_enc
def observe_rollout(self, rollout_states, rollout_actions, init_history, nonterms):
observed_rollout = []
for i in range(rollout_states.shape[0]):
rollout_states_ = rollout_states[i]
rollout_actions_ = rollout_actions[i]
init_history_ = nonterms[i] * init_history
state_enc = self.observe_step(rollout_states_, rollout_actions_, init_history_)
init_history = state_enc["history"]
observed_rollout.append(state_enc)
observed_rollout = self.stack_states(observed_rollout, dim=0)
return observed_rollout
def reparemeterize(self, mean, std):
eps = torch.randn_like(mean)
return mean + eps * std
class TanhBijector(torch.distributions.Transform): class TanhBijector(torch.distributions.Transform):
@ -300,6 +430,7 @@ class ContrastiveHead(nn.Module):
return logits return logits
"""
class CLUBSample(nn.Module): # Sampled version of the CLUB estimator class CLUBSample(nn.Module): # Sampled version of the CLUB estimator
def __init__(self, last_states, current_states, negative_current_states, predicted_current_states): def __init__(self, last_states, current_states, negative_current_states, predicted_current_states):
super(CLUBSample, self).__init__() super(CLUBSample, self).__init__()
@ -313,7 +444,7 @@ class CLUBSample(nn.Module): # Sampled version of the CLUB estimator
sample = state_dict["sample"] #dist.sample() # Use state_dict["sample"] if you want to use the same sample for all the losses sample = state_dict["sample"] #dist.sample() # Use state_dict["sample"] if you want to use the same sample for all the losses
mu = dist.mean mu = dist.mean
var = dist.variance var = dist.variance
return mu, var, sample return mu.detach(), var.detach(), sample.detach()
def loglikeli(self): def loglikeli(self):
_, _, pred_sample = self.get_mu_var_samples(self.predicted_current_states) _, _, pred_sample = self.get_mu_var_samples(self.predicted_current_states)
@ -330,15 +461,136 @@ class CLUBSample(nn.Module): # Sampled version of the CLUB estimator
random_index = torch.randperm(sample_size).long() random_index = torch.randperm(sample_size).long()
pos = (-(mu_curr - pred_sample)**2 /var_curr).sum(dim=1).mean(dim=0) pos = (-(mu_curr - pred_sample)**2 /var_curr).sum(dim=1).mean(dim=0)
neg = (-(mu_curr - pred_sample[random_index])**2 /var_curr).sum(dim=1).mean(dim=0) #neg = (-(mu_curr - pred_sample[random_index])**2 /var_curr).sum(dim=1).mean(dim=0)
#neg = (-(mu_neg - pred_sample)**2 /var_neg).sum(dim=1).mean(dim=0) neg = (-(mu_neg - pred_sample)**2 /var_neg).sum(dim=1).mean(dim=0)
upper_bound = pos - neg upper_bound = pos - neg
return upper_bound/2 return upper_bound/2
def learning_loss(self): def learning_loss(self):
return - self.loglikeli() return - self.loglikeli()
"""
class CLUBSample(nn.Module): # Sampled version of the CLUB estimator
def __init__(self, x_dim, y_dim, hidden_size):
super(CLUBSample, self).__init__()
self.p_mu = nn.Sequential(nn.Linear(x_dim, hidden_size//2),
nn.ReLU(),
nn.Linear(hidden_size//2, y_dim))
self.p_logvar = nn.Sequential(nn.Linear(x_dim, hidden_size//2),
nn.ReLU(),
nn.Linear(hidden_size//2, y_dim),
nn.Tanh())
def get_mu_logvar(self, x_samples):
mu = self.p_mu(x_samples)
logvar = self.p_logvar(x_samples)
return mu, logvar
def loglikeli(self, x_samples, y_samples):
mu, logvar = self.get_mu_logvar(x_samples)
return (-(mu - y_samples)**2 /logvar.exp()-logvar).sum(dim=1).mean(dim=0)
def forward(self, x_samples, y_samples, y_negatives):
mu, logvar = self.get_mu_logvar(x_samples)
sample_size = x_samples.shape[0]
#random_index = torch.randint(sample_size, (sample_size,)).long()
random_index = torch.randperm(sample_size).long()
positive = -(mu - y_samples)**2 / logvar.exp()
#negative = - (mu - y_samples[random_index])**2 / logvar.exp()
negative = -(mu - y_negatives)**2 / logvar.exp()
upper_bound = (positive.sum(dim = -1) - negative.sum(dim = -1)).mean()
return upper_bound/2.
def learning_loss(self, x_samples, y_samples):
return -self.loglikeli(x_samples, y_samples)
class QFunction(nn.Module):
"""MLP for q-function."""
def __init__(self, obs_dim, action_dim, hidden_dim):
super().__init__()
self.trunk = nn.Sequential(
nn.Linear(obs_dim + action_dim, hidden_dim), nn.ReLU(),
nn.Linear(hidden_dim, hidden_dim), nn.ReLU(),
nn.Linear(hidden_dim, 1)
)
def forward(self, obs, action):
assert obs.size(0) == action.size(0)
obs_action = torch.cat([obs, action], dim=1)
return self.trunk(obs_action)
class Critic(nn.Module):
"""Critic network, employes two q-functions."""
def __init__(
self, obs_shape, action_shape, hidden_dim, encoder_feature_dim):
super().__init__()
self.Q1 = QFunction(
self.encoder.feature_dim, action_shape[0], hidden_dim
)
self.Q2 = QFunction(
self.encoder.feature_dim, action_shape[0], hidden_dim
)
self.outputs = dict()
def forward(self, obs, action, detach_encoder=False):
# detach_encoder allows to stop gradient propogation to encoder
obs = self.encoder(obs, detach=detach_encoder)
q1 = self.Q1(obs, action)
q2 = self.Q2(obs, action)
self.outputs['q1'] = q1
self.outputs['q2'] = q2
return q1, q2
class SampleDist:
def __init__(self, dist, samples=100):
self._dist = dist
self._samples = samples
@property
def name(self):
return 'SampleDist'
def __getattr__(self, name):
return getattr(self._dist, name)
def mean(self):
sample = self._dist.rsample(self._samples)
return torch.mean(sample, 0)
def mode(self):
dist = self._dist.expand((self._samples, *self._dist.batch_shape))
sample = dist.rsample()
logprob = dist.log_prob(sample)
batch_size = sample.size(1)
feature_size = sample.size(2)
indices = torch.argmax(logprob, dim=0).reshape(1, batch_size, 1).expand(1, batch_size, feature_size)
return torch.gather(sample, 0, indices).squeeze(0)
def entropy(self):
dist = self._dist.expand((self._samples, *self._dist.batch_shape))
sample = dist.rsample()
logprob = dist.log_prob(sample)
return -torch.mean(logprob, 0)
def sample(self):
return self._dist.sample()
if "__name__ == __main__": if "__name__ == __main__":
pass tr = TransitionModel(50, 512, 1, 256)

51
DPI/replay_buffer.py Normal file
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@ -0,0 +1,51 @@
import torch
import numpy as np
class ReplayBuffer:
def __init__(self, size, obs_shape, action_size, seq_len, batch_size):
self.size = size
self.obs_shape = obs_shape
self.action_size = action_size
self.seq_len = seq_len
self.batch_size = batch_size
self.idx = 0
self.full = False
self.observations = np.empty((size, *obs_shape), dtype=np.uint8)
self.next_observations = np.empty((size, *obs_shape), dtype=np.uint8)
self.actions = np.empty((size, action_size), dtype=np.float32)
self.rewards = np.empty((size,), dtype=np.float32)
self.terminals = np.empty((size,), dtype=np.float32)
self.steps, self.episodes = 0, 0
def add(self, obs, ac, next_obs, rew, done):
self.observations[self.idx] = obs
self.next_observations[self.idx] = next_obs
self.actions[self.idx] = ac
self.rewards[self.idx] = rew
self.terminals[self.idx] = done
self.idx = (self.idx + 1) % self.size
self.full = self.full or self.idx == 0
self.steps += 1
self.episodes = self.episodes + (1 if done else 0)
def _sample_idx(self, L):
valid_idx = False
while not valid_idx:
idx = np.random.randint(0, self.size if self.full else self.idx - L)
idxs = np.arange(idx, idx + L) % self.size
valid_idx = not self.idx in idxs[1:]
return idxs
def _retrieve_batch(self, idxs, n, L):
vec_idxs = idxs.transpose().reshape(-1) # Unroll indices
observations = self.observations[vec_idxs]
next_observations = self.next_observations[vec_idxs]
return observations.reshape(L, n, *observations.shape[1:]),self.actions[vec_idxs].reshape(L, n, -1), next_observations.reshape(L, n, *next_observations.shape[1:]), self.rewards[vec_idxs].reshape(L, n), self.terminals[vec_idxs].reshape(L, n)
def sample(self):
n = self.batch_size
l = self.seq_len
obs,acs,nxt_obs,rews,terms= self._retrieve_batch(np.asarray([self._sample_idx(l) for _ in range(n)]), n, l)
return obs,acs,nxt_obs,rews,terms

View File

@ -48,10 +48,10 @@ def parse_args():
parser.add_argument('--episode_length', default=51, type=int) parser.add_argument('--episode_length', default=51, type=int)
# train # train
parser.add_argument('--agent', default='dpi', type=str, choices=['baseline', 'bisim', 'deepmdp', 'db', 'dpi', 'rpc']) parser.add_argument('--agent', default='dpi', type=str, choices=['baseline', 'bisim', 'deepmdp', 'db', 'dpi', 'rpc'])
parser.add_argument('--init_steps', default=10000, type=int) parser.add_argument('--init_steps', default=5000, type=int)
parser.add_argument('--num_train_steps', default=100000, type=int) parser.add_argument('--num_train_steps', default=100000, type=int)
parser.add_argument('--update_steps', default=100, type=int) parser.add_argument('--update_steps', default=100, type=int)
parser.add_argument('--batch_size', default=64, type=int) #512 parser.add_argument('--batch_size', default=64, type=int)
parser.add_argument('--state_size', default=50, type=int) parser.add_argument('--state_size', default=50, type=int)
parser.add_argument('--hidden_size', default=512, type=int) parser.add_argument('--hidden_size', default=512, type=int)
parser.add_argument('--history_size', default=256, type=int) parser.add_argument('--history_size', default=256, type=int)
@ -66,20 +66,20 @@ def parse_args():
parser.add_argument('--num_eval_episodes', default=20, type=int) parser.add_argument('--num_eval_episodes', default=20, type=int)
parser.add_argument('--evaluation_interval', default=10000, type=int) # TODO: master had 10000 parser.add_argument('--evaluation_interval', default=10000, type=int) # TODO: master had 10000
# value # value
parser.add_argument('--value_lr', default=1e-6, type=float) parser.add_argument('--value_lr', default=8e-5, type=float)
parser.add_argument('--value_target_update_freq', default=100, type=int) parser.add_argument('--value_target_update_freq', default=100, type=int)
parser.add_argument('--td_lambda', default=0.95, type=int) parser.add_argument('--td_lambda', default=0.95, type=int)
# actor # actor
parser.add_argument('--actor_lr', default=1e-6, type=float) parser.add_argument('--actor_lr', default=8e-5, type=float)
parser.add_argument('--actor_beta', default=0.9, type=float) parser.add_argument('--actor_beta', default=0.9, type=float)
parser.add_argument('--actor_log_std_min', default=-10, type=float) parser.add_argument('--actor_log_std_min', default=-10, type=float)
parser.add_argument('--actor_log_std_max', default=2, type=float) parser.add_argument('--actor_log_std_max', default=2, type=float)
parser.add_argument('--actor_update_freq', default=2, type=int) parser.add_argument('--actor_update_freq', default=2, type=int)
# world/encoder/decoder # world/encoder/decoder
parser.add_argument('--encoder_type', default='pixel', type=str, choices=['pixel', 'pixelCarla096', 'pixelCarla098', 'identity']) parser.add_argument('--encoder_type', default='pixel', type=str, choices=['pixel', 'pixelCarla096', 'pixelCarla098', 'identity'])
parser.add_argument('--world_model_lr', default=1e-5, type=float) parser.add_argument('--world_model_lr', default=6e-5, type=float)
parser.add_argument('--decoder_lr', default=1e-5, type=float) parser.add_argument('--decoder_lr', default=6e-4, type=float)
parser.add_argument('--reward_lr', default=1e-5, type=float) parser.add_argument('--reward_lr', default=6e-5, type=float)
parser.add_argument('--encoder_tau', default=0.001, type=float) parser.add_argument('--encoder_tau', default=0.001, type=float)
parser.add_argument('--decoder_type', default='pixel', type=str, choices=['pixel', 'identity', 'contrastive', 'reward', 'inverse', 'reconstruction']) parser.add_argument('--decoder_type', default='pixel', type=str, choices=['pixel', 'identity', 'contrastive', 'reward', 'inverse', 'reconstruction'])
parser.add_argument('--num_layers', default=4, type=int) parser.add_argument('--num_layers', default=4, type=int)
@ -157,16 +157,19 @@ class DPI:
obs_shape=(self.args.frame_stack*self.args.channels,self.args.image_size,self.args.image_size), # (9,84,84) obs_shape=(self.args.frame_stack*self.args.channels,self.args.image_size,self.args.image_size), # (9,84,84)
state_size=self.args.state_size # 128 state_size=self.args.state_size # 128
).to(device) ).to(device)
self.obs_encoder.apply(self.init_weights)
self.obs_encoder_momentum = ObservationEncoder( self.obs_encoder_momentum = ObservationEncoder(
obs_shape=(self.args.frame_stack*self.args.channels,self.args.image_size,self.args.image_size), # (9,84,84) obs_shape=(self.args.frame_stack*self.args.channels,self.args.image_size,self.args.image_size), # (9,84,84)
state_size=self.args.state_size # 128 state_size=self.args.state_size # 128
).to(device) ).to(device)
self.obs_encoder_momentum.apply(self.init_weights)
self.obs_decoder = ObservationDecoder( self.obs_decoder = ObservationDecoder(
state_size=self.args.state_size, # 128 state_size=self.args.state_size, # 128
output_shape=(self.args.channels*self.args.channels,self.args.image_size,self.args.image_size) # (3,84,84) output_shape=(self.args.channels*self.args.channels,self.args.image_size,self.args.image_size) # (3,84,84)
).to(device) ).to(device)
self.obs_decoder.apply(self.init_weights)
self.transition_model = TransitionModel( self.transition_model = TransitionModel(
state_size=self.args.state_size, # 128 state_size=self.args.state_size, # 128
@ -174,6 +177,7 @@ class DPI:
action_size=self.env.action_space.shape[0], # 6 action_size=self.env.action_space.shape[0], # 6
history_size=self.args.history_size, # 128 history_size=self.args.history_size, # 128
).to(device) ).to(device)
self.transition_model.apply(self.init_weights)
# Actor Model # Actor Model
self.actor_model = Actor( self.actor_model = Actor(
@ -181,7 +185,7 @@ class DPI:
hidden_size=self.args.hidden_size, # 256, hidden_size=self.args.hidden_size, # 256,
action_size=self.env.action_space.shape[0], # 6 action_size=self.env.action_space.shape[0], # 6
).to(device) ).to(device)
#self.actor_model.apply(self.init_weights) self.actor_model.apply(self.init_weights)
# Value Models # Value Models
@ -189,16 +193,19 @@ class DPI:
state_size=self.args.state_size, # 128 state_size=self.args.state_size, # 128
hidden_size=self.args.hidden_size, # 256 hidden_size=self.args.hidden_size, # 256
).to(device) ).to(device)
self.value_model.apply(self.init_weights)
self.target_value_model = ValueModel( self.target_value_model = ValueModel(
state_size=self.args.state_size, # 128 state_size=self.args.state_size, # 128
hidden_size=self.args.hidden_size, # 256 hidden_size=self.args.hidden_size, # 256
).to(device) ).to(device)
self.target_value_model.apply(self.init_weights)
self.reward_model = RewardModel( self.reward_model = RewardModel(
state_size=self.args.state_size, # 128 state_size=self.args.state_size, # 128
hidden_size=self.args.hidden_size, # 256 hidden_size=self.args.hidden_size, # 256
).to(device) ).to(device)
self.reward_model.apply(self.init_weights)
# Contrastive Models # Contrastive Models
self.prjoection_head = ProjectionHead( self.prjoection_head = ProjectionHead(
@ -228,22 +235,21 @@ class DPI:
self.world_model_parameters = list(self.obs_encoder.parameters()) + list(self.prjoection_head.parameters()) + \ self.world_model_parameters = list(self.obs_encoder.parameters()) + list(self.prjoection_head.parameters()) + \
list(self.transition_model.parameters()) + list(self.club_sample.parameters()) + \ list(self.transition_model.parameters()) + list(self.club_sample.parameters()) + \
list(self.contrastive_head.parameters()) list(self.contrastive_head.parameters())
self.past_transition_parameters = self.transition_model.parameters()
# optimizers # optimizers
self.world_model_opt = torch.optim.Adam(self.world_model_parameters, self.args.world_model_lr,eps=1e-6) self.world_model_opt = torch.optim.Adam(self.world_model_parameters, self.args.world_model_lr,eps=1e-6)
self.value_opt = torch.optim.Adam(self.value_model.parameters(), self.args.value_lr,eps=1e-6) self.value_opt = torch.optim.Adam(self.value_model.parameters(), self.args.value_lr,eps=1e-6, weight_decay=1e-5)
self.actor_opt = torch.optim.Adam(self.actor_model.parameters(), self.args.actor_lr,eps=1e-6) self.actor_opt = torch.optim.Adam(self.actor_model.parameters(), self.args.actor_lr,eps=1e-6)
self.decoder_opt = torch.optim.Adam(self.obs_decoder.parameters(), self.args.decoder_lr,eps=1e-6) self.decoder_opt = torch.optim.Adam(self.obs_decoder.parameters(), self.args.decoder_lr,eps=1e-6)
self.reward_opt = torch.optim.Adam(self.reward_model.parameters(), self.args.reward_lr,eps=1e-6) self.reward_opt = torch.optim.Adam(self.reward_model.parameters(), self.args.reward_lr,eps=1e-6, weight_decay=1e-5)
# Create Modules # Create Modules
self.world_model_modules = [self.obs_encoder, self.prjoection_head, self.transition_model, self.club_sample, self.contrastive_head] self.world_model_modules = [self.obs_encoder, self.prjoection_head, self.transition_model, self.club_sample, self.contrastive_head,
self.obs_encoder_momentum, self.prjoection_head_momentum]
self.value_modules = [self.value_model] self.value_modules = [self.value_model]
self.actor_modules = [self.actor_model] self.actor_modules = [self.actor_model]
self.decoder_modules = [self.obs_decoder] self.decoder_modules = [self.obs_decoder]
self.reward_modules = [self.reward_model] self.reward_modules = [self.reward_model]
#self.decoder_modules = [self.obs_decoder]
if use_saved: if use_saved:
self._use_saved_models(saved_model_dir) self._use_saved_models(saved_model_dir)
@ -282,7 +288,8 @@ class DPI:
with torch.no_grad(): with torch.no_grad():
obs_ = torch.tensor(obs.copy(), dtype=torch.float32) obs_ = torch.tensor(obs.copy(), dtype=torch.float32)
obs_ = preprocess_obs(obs_).to(device) obs_ = preprocess_obs(obs_).to(device)
state = self.get_features(obs_)["distribution"].rsample().unsqueeze(0) #state = self.get_features(obs_)["sample"].unsqueeze(0)
state = self.get_features(obs_)["distribution"].rsample()
action = actor_model(state) action = actor_model(state)
action = actor_model.add_exploration(action) action = actor_model.add_exploration(action)
action = action.cpu().numpy()[0] action = action.cpu().numpy()[0]
@ -307,7 +314,7 @@ class DPI:
initial_logs = OrderedDict() initial_logs = OrderedDict()
logger = Logger(logdir) logger = Logger(logdir)
episodic_rews = self.collect_random_sequences(5000//args.action_repeat) episodic_rews = self.collect_random_sequences(self.args.init_steps//args.action_repeat)
self.global_step = self.data_buffer.steps self.global_step = self.data_buffer.steps
initial_logs.update({ initial_logs.update({
@ -362,6 +369,7 @@ class DPI:
def collect_batch(self): def collect_batch(self):
obs_, acs_, nxt_obs_, rews_, terms_ = self.data_buffer.sample() obs_, acs_, nxt_obs_, rews_, terms_ = self.data_buffer.sample()
obs = torch.tensor(obs_, dtype=torch.float32)[1:] obs = torch.tensor(obs_, dtype=torch.float32)[1:]
last_obs = torch.tensor(obs_, dtype=torch.float32)[:-1] last_obs = torch.tensor(obs_, dtype=torch.float32)[:-1]
nxt_obs = torch.tensor(nxt_obs_, dtype=torch.float32)[1:] nxt_obs = torch.tensor(nxt_obs_, dtype=torch.float32)[1:]
@ -427,7 +435,7 @@ class DPI:
if step % self.args.logging_freq: if step % self.args.logging_freq:
writer.add_scalar('World Loss/World Loss', world_loss.detach().item(), step) writer.add_scalar('World Loss/World Loss', world_loss.detach().item(), step)
writer.add_scalar('Main Models Loss/Encoder Loss', enc_loss.detach().item(), step) writer.add_scalar('Main Models Loss/Encoder Loss', enc_loss.detach().item(), step)
writer.add_scalar('Main Models Loss/Decoder Loss', dec_loss, step) writer.add_scalar('Main Models Loss/Decoder Loss', dec_loss.detach().item(), step)
writer.add_scalar('Actor Critic Loss/Actor Loss', actor_loss.detach().item(), step) writer.add_scalar('Actor Critic Loss/Actor Loss', actor_loss.detach().item(), step)
writer.add_scalar('Actor Critic Loss/Value Loss', value_loss.detach().item(), step) writer.add_scalar('Actor Critic Loss/Value Loss', value_loss.detach().item(), step)
writer.add_scalar('Actor Critic Loss/Reward Loss', rew_loss.detach().item(), step) writer.add_scalar('Actor Critic Loss/Reward Loss', rew_loss.detach().item(), step)
@ -440,31 +448,28 @@ class DPI:
# get features # get features
self.last_state_feat = self.get_features(last_obs) self.last_state_feat = self.get_features(last_obs)
self.curr_state_feat = self.get_features(curr_obs) self.curr_state_feat = self.get_features(curr_obs)
self.nxt_state_feat = self.get_features(nxt_obs, momentum=True) self.nxt_state_feat = self.get_features(nxt_obs)
self.nxt_state_feat_lb = self.get_features(nxt_obs, momentum=True)
# states # states
self.last_state_enc = self.last_state_feat["sample"] self.last_state_enc = self.last_state_feat["distribution"].rsample() #self.last_state_feat["sample"]
self.curr_state_enc = self.curr_state_feat["sample"] self.curr_state_enc = self.curr_state_feat["distribution"].rsample() #self.curr_state_feat["sample"]
self.nxt_state_enc = self.nxt_state_feat["sample"] self.nxt_state_enc = self.nxt_state_feat["distribution"].rsample() #self.nxt_state_feat["sample"]
self.nxt_state_enc_lb = self.nxt_state_feat_lb["distribution"].rsample() #self.nxt_state_feat_lb["sample"]
# actions
actions = actions.clone()
nxt_actions = nxt_actions.clone()
# rewards
rewards = rewards.clone()
# predict next states # predict next states
self.transition_model.init_states(self.args.batch_size, device) # (N,128) self.transition_model.init_states(self.args.batch_size, device) # (N,128)
self.observed_rollout = self.transition_model.observe_rollout(self.last_state_enc, actions, self.transition_model.prev_history, nonterms) self.observed_rollout = self.transition_model.observe_rollout(self.last_state_enc, actions, self.transition_model.prev_history, nonterms)
self.pred_curr_state_dist = self.transition_model.get_dist(self.observed_rollout["mean"], self.observed_rollout["std"]) self.pred_curr_state_dist = self.transition_model.get_dist(self.observed_rollout["mean"], self.observed_rollout["std"])
self.pred_curr_state_enc = self.pred_curr_state_dist.mean #print(self.observed_rollout["mean"][0][0])
self.pred_curr_state_enc = self.pred_curr_state_dist.rsample() #self.observed_rollout["sample"]
# encoder loss # encoder loss
enc_loss = self._encoder_loss(self.curr_state_feat["distribution"], self.pred_curr_state_dist) enc_loss = self._encoder_loss(self.curr_state_feat["distribution"], self.pred_curr_state_dist)
# reward loss # reward loss
rew_dist = self.reward_model(self.curr_state_enc) rew_dist = self.reward_model(self.curr_state_enc)
#print(torch.cat([rew_dist.mean[0], rewards[0]],dim=-1))
rew_loss = -torch.mean(rew_dist.log_prob(rewards)) rew_loss = -torch.mean(rew_dist.log_prob(rewards))
# decoder loss # decoder loss
@ -472,13 +477,19 @@ class DPI:
dec_loss = -torch.mean(dec_dist.log_prob(nxt_obs)) dec_loss = -torch.mean(dec_dist.log_prob(nxt_obs))
# upper bound loss # upper bound loss
_, ub_loss = self._upper_bound_minimization(self.curr_state_enc, past_ub_loss = 0
self.pred_curr_state_enc) for i in range(self.curr_state_enc.shape[0]):
_, ub_loss = self._upper_bound_minimization(self.curr_state_enc[i],
self.pred_curr_state_enc[i])
ub_loss = ub_loss + past_ub_loss
past_ub_loss = ub_loss
ub_loss = ub_loss / self.curr_state_enc.shape[0]
ub_loss = 0.01 * ub_loss
# lower bound loss # lower bound loss
# contrastive projection # contrastive projection
vec_anchor = self.pred_curr_state_enc.detach() vec_anchor = self.pred_curr_state_enc.detach()
vec_positive = self.nxt_state_enc.detach() vec_positive = self.nxt_state_enc_lb.detach()
z_anchor = self.prjoection_head(vec_anchor, nxt_actions) z_anchor = self.prjoection_head(vec_anchor, nxt_actions)
z_positive = self.prjoection_head_momentum(vec_positive, nxt_actions) z_positive = self.prjoection_head_momentum(vec_positive, nxt_actions)
@ -489,7 +500,7 @@ class DPI:
labels = torch.arange(logits.shape[0]).long().to(device) labels = torch.arange(logits.shape[0]).long().to(device)
lb_loss = F.cross_entropy(logits, labels) + past_lb_loss lb_loss = F.cross_entropy(logits, labels) + past_lb_loss
past_lb_loss = lb_loss.detach().item() past_lb_loss = lb_loss.detach().item()
lb_loss = -0.1 * lb_loss/(z_anchor.shape[0]) lb_loss = -0.01 * lb_loss/(z_anchor.shape[0])
world_loss = enc_loss + ub_loss + lb_loss world_loss = enc_loss + ub_loss + lb_loss
@ -497,19 +508,26 @@ class DPI:
def actor_model_losses(self): def actor_model_losses(self):
with torch.no_grad(): with torch.no_grad():
curr_state_enc = self.transition_model.seq_to_batch(self.curr_state_feat, "sample")["sample"] #curr_state_enc = self.curr_state_enc.reshape(self.args.episode_length-1,-1) #self.transition_model.seq_to_batch(self.curr_state_feat, "sample")["sample"]
curr_state_hist = self.transition_model.seq_to_batch(self.observed_rollout, "history")["sample"] #curr_state_hist = self.observed_rollout["history"].reshape(self.args.episode_length-1,-1) #self.transition_model.seq_to_batch(self.observed_rollout, "history")["sample"]
curr_state_enc = self.curr_state_enc.reshape(-1, self.args.state_size)
curr_state_hist = self.observed_rollout["history"].reshape(-1, self.args.history_size)
with FreezeParameters(self.world_model_modules + self.decoder_modules + self.reward_modules): with FreezeParameters(self.world_model_modules + self.decoder_modules + self.reward_modules + self.value_modules):
imagine_horizon = self.args.imagine_horizon imagine_horizon = self.args.imagine_horizon
action = self.actor_model(curr_state_enc) action = self.actor_model(curr_state_enc.detach())
self.imagined_rollout = self.transition_model.imagine_rollout(curr_state_enc, self.imagined_rollout = self.transition_model.imagine_rollout(curr_state_enc,
action, curr_state_hist, action, curr_state_hist.detach(),
imagine_horizon) imagine_horizon)
self.pred_nxt_state_dist = self.transition_model.get_dist(self.imagined_rollout["mean"], self.imagined_rollout["std"])
#print(self.imagined_rollout["mean"][0][0])
self.pred_nxt_state_enc = self.pred_nxt_state_dist.rsample() #self.transition_model.reparemeterize(self.imagined_rollout["mean"], self.imagined_rollout["std"])
with FreezeParameters(self.world_model_modules + self.value_modules + self.decoder_modules + self.reward_modules): with FreezeParameters(self.world_model_modules + self.value_modules + self.decoder_modules + self.reward_modules):
imag_rewards = self.reward_model(self.imagined_rollout["sample"]).mean imag_rewards_dist = self.reward_model(self.pred_nxt_state_enc)
imag_values = self.value_model(self.imagined_rollout["sample"]).mean imag_values_dist = self.value_model(self.pred_nxt_state_enc)
imag_rewards = imag_rewards_dist.mean
imag_values = imag_values_dist.mean
discounts = self.args.discount * torch.ones_like(imag_rewards).detach() discounts = self.args.discount * torch.ones_like(imag_rewards).detach()
self.returns = self._compute_lambda_return(imag_rewards[:-1], self.returns = self._compute_lambda_return(imag_rewards[:-1],
@ -525,7 +543,7 @@ class DPI:
def value_model_losses(self): def value_model_losses(self):
# value loss # value loss
with torch.no_grad(): with torch.no_grad():
value_feat = self.imagined_rollout["sample"][:-1].detach() value_feat = self.pred_nxt_state_enc[:-1].detach()
value_targ = self.returns.detach() value_targ = self.returns.detach()
value_dist = self.value_model(value_feat) value_dist = self.value_model(value_feat)
value_loss = -torch.mean(self.discounts * value_dist.log_prob(value_targ).unsqueeze(-1)) value_loss = -torch.mean(self.discounts * value_dist.log_prob(value_targ).unsqueeze(-1))
@ -597,14 +615,13 @@ class DPI:
obs_processed = preprocess_obs(obs).to(device) obs_processed = preprocess_obs(obs).to(device)
state = self.get_features(obs_processed)["distribution"].rsample() state = self.get_features(obs_processed)["distribution"].rsample()
action = self.actor_model(state).cpu().detach().numpy().squeeze() action = self.actor_model(state).cpu().detach().numpy().squeeze()
next_obs, rew, done, _ = self.env.step(action) next_obs, rew, done, _ = self.env.step(action)
rewards += rew rewards += rew
obs = next_obs
if self.args.save_video: if self.args.save_video:
self.env.video.record(self.env) self.env.video.record(self.env)
self.env.video.save('/home/vedant/Curiosity/Curiosity/DPI/log/video/learned_model.mp4') self.env.video.save('/home/vedant/Curiosity/Curiosity/DPI/log/video/learned_model.mp4')
obs = next_obs
obs = self.env.reset() obs = self.env.reset()
episodic_rewards.append(rewards) episodic_rewards.append(rewards)
print("Episodic rewards: ", episodic_rewards) print("Episodic rewards: ", episodic_rewards)
@ -679,6 +696,19 @@ class DPI:
return x return x
def _compute_lambda_return(self, rewards, values, discounts, td_lam, last_value): def _compute_lambda_return(self, rewards, values, discounts, td_lam, last_value):
next_values = torch.cat([values[1:], last_value[None]], 0)
target = rewards + discounts * next_values * (1 - td_lam)
timesteps = list(range(rewards.shape[0] - 1, -1, -1))
outputs = []
accumulated_reward = last_value
for t in timesteps:
inp = target[t]
discount_factor = discounts[t]
accumulated_reward = inp + discount_factor * td_lam * accumulated_reward
outputs.append(accumulated_reward)
returns = torch.flip(torch.stack(outputs), [0])
return returns
"""
next_values = torch.cat([values[1:], last_value.unsqueeze(0)],0) next_values = torch.cat([values[1:], last_value.unsqueeze(0)],0)
targets = rewards + discounts * next_values * (1-td_lam) targets = rewards + discounts * next_values * (1-td_lam)
rets =[] rets =[]
@ -690,6 +720,7 @@ class DPI:
returns = torch.flip(torch.stack(rets), [0]) returns = torch.flip(torch.stack(rets), [0])
return returns return returns
"""
def lambda_return(self,imged_reward, value_pred, bootstrap, discount=0.99, lambda_=0.95): def lambda_return(self,imged_reward, value_pred, bootstrap, discount=0.99, lambda_=0.95):
# Setting lambda=1 gives a discounted Monte Carlo return. # Setting lambda=1 gives a discounted Monte Carlo return.
@ -740,7 +771,7 @@ if __name__ == '__main__':
device = torch.device('cuda:0' if torch.cuda.is_available() else 'cpu') device = torch.device('cuda:0' if torch.cuda.is_available() else 'cpu')
step = 0 step = 0
total_steps = 500000 total_steps = 1000000
dpi = DPI(args) dpi = DPI(args)
dpi.train(step,total_steps) dpi.train(step,total_steps)
dpi.evaluate() dpi.evaluate()

View File

@ -63,17 +63,6 @@ def make_dir(dir_path):
return dir_path return dir_path
def preprocess_obs(obs, bits=5):
"""Preprocessing image, see https://arxiv.org/abs/1807.03039."""
bins = 2**bits
assert obs.dtype == torch.float32
if bits < 8:
obs = torch.floor(obs / 2**(8 - bits))
obs = obs / bins
obs = obs + torch.rand_like(obs) / bins
obs = obs - 0.5
return obs
class FrameStack(gym.Wrapper): class FrameStack(gym.Wrapper):
def __init__(self, env, k): def __init__(self, env, k):
@ -338,8 +327,8 @@ def make_env(args):
return env return env
def shuffle_along_axis(a, axis): def shuffle_along_axis(a, axis):
idx = np.random.rand(*a.shape).argsort(axis=axis) idx = np.random.rand(*a.shape).argsort(axis=axis)
return np.take_along_axis(a,idx,axis=axis) return np.take_along_axis(a,idx,axis=axis)
def preprocess_obs(obs): def preprocess_obs(obs):
obs = (obs/255.0) - 0.5 obs = (obs/255.0) - 0.5
@ -374,6 +363,20 @@ def video_from_array(arr, high_noise, filename):
out.write(frame) out.write(frame)
out.release() out.release()
def save_video(images):
"""
Image shape is (T, C, H, W)
Example:(50, 3, 84, 84)
"""
output_file = "output.avi"
fourcc = cv2.VideoWriter_fourcc(*'XVID')
fps = 2
height, width, channels = 84,84,3
out = cv2.VideoWriter(output_file, fourcc, fps, (width, height))
for image in images:
image = np.uint8(image.transpose((1, 2, 0)))
out.write(image)
out.release()
class CorruptVideos: class CorruptVideos:
def __init__(self, dir_path): def __init__(self, dir_path):