Add encoder loss and include tqdm for visualization

This commit is contained in:
Vedant Dave 2023-03-27 19:23:42 +02:00
parent a1fe81f018
commit 11f00ad695

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@ -7,6 +7,7 @@ import time
import json
import dmc2gym
import tqdm
import wandb
import utils
from utils import ReplayBuffer, make_env, save_image
@ -33,10 +34,10 @@ def parse_args():
parser.add_argument('--resource_files', type=str)
parser.add_argument('--eval_resource_files', type=str)
parser.add_argument('--img_source', default=None, type=str, choices=['color', 'noise', 'images', 'video', 'none'])
parser.add_argument('--total_frames', default=10000, type=int)
parser.add_argument('--total_frames', default=1000, type=int) # 10000
parser.add_argument('--high_noise', action='store_true')
# replay buffer
parser.add_argument('--replay_buffer_capacity', default=50000, type=int) #100000
parser.add_argument('--replay_buffer_capacity', default=50000, type=int) #50000
parser.add_argument('--episode_length', default=50, type=int)
# train
parser.add_argument('--agent', default='dpi', type=str, choices=['baseline', 'bisim', 'deepmdp', 'db', 'dpi', 'rpc'])
@ -130,10 +131,6 @@ class DPI:
self.model_dir = utils.make_dir(os.path.join(self.args.work_dir, 'model'))
self.buffer_dir = utils.make_dir(os.path.join(self.args.work_dir, 'buffer'))
# create video recorder
#video = VideoRecorder(video_dir if args.save_video else None, resource_files=args.resource_files)
#video.init(enabled=True)
# create models
self.build_models(use_saved=False, saved_model_dir=self.model_dir)
@ -174,28 +171,24 @@ class DPI:
done = False
#video = VideoRecorder(self.video_dir if args.save_video else None, resource_files=args.resource_files)
for episode_count in range(episodes):
self.env.video.init(enabled=True)
for episode_count in tqdm.tqdm(range(episodes), desc='Collecting episodes'):
#self.env.video.init(enabled=True)
for i in range(self.args.episode_length):
action = self.env.action_space.sample()
next_obs, _, done, _ = self.env.step(action)
self.data_buffer.add(obs, action, next_obs, episode_count+1, done)
if args.save_video:
self.env.video.record(self.env)
#if args.save_video:
# self.env.video.record(self.env)
if done:
obs = self.env.reset()
done=False
else:
obs = next_obs
self.env.video.save('%d.mp4' % episode_count)
#self.env.video.save('%d.mp4' % episode_count)
print("Collected {} random episodes".format(episode_count+1))
#if args.save_video:
# video.record(self.env)
#video.save('%d.mp4' % step)
#video.close()
def train(self):
# collect experience
@ -204,26 +197,59 @@ class DPI:
# Group observations and next_observations by steps
observations = torch.Tensor(self.data_buffer.group_steps(self.data_buffer,"observations")).float()
next_observations = torch.Tensor(self.data_buffer.group_steps(self.data_buffer,"next_observations")).float()
actions = torch.Tensor(self.data_buffer.group_steps(self.data_buffer,"actions",obs=False)).float()
# Initialize transition model states
self.transition_model.init_states(self.args.batch_size, device="cpu") # (N,128)
self.history = self.transition_model.prev_history # (N,128)
# Train encoder
previous_information_loss = 0
previous_encoder_loss = 0
for i in range(self.args.episode_length):
# Encode observations and next_observations
self.features = self.obs_encoder(observations[i]) # (N,128)
self.next_features = self.obs_encoder(next_observations[i]) # (N,128)
self.states_dist = self.obs_encoder(observations[i])
self.next_states_dist = self.obs_encoder(next_observations[i])
# Sample states and next_states
self.states = self.states_dist["sample"] # (N,128)
self.next_states = self.next_states_dist["sample"] # (N,128)
self.actions = actions[i] # (N,6)
# Calculate upper bound loss
past_loss = previous_information_loss + self.upper_bound_minimization(self.features, self.next_features)
previous_information_loss = past_loss
print("past_loss: ", past_loss)
past_latent_loss = previous_information_loss + self._upper_bound_minimization(self.states, self.next_states)
def upper_bound_minimization(self, features, next_features):
# Calculate encoder loss
past_encoder_loss = previous_encoder_loss + self._past_encoder_loss(self.states, self.next_states,
self.states_dist, self.next_states_dist,
self.actions, self.history, i)
previous_information_loss = past_latent_loss
previous_encoder_loss = past_encoder_loss
def _upper_bound_minimization(self, states, next_states):
club_sample = CLUBSample(self.args.state_size,
self.args.state_size,
self.args.hidden_size)
club_loss = club_sample(features, next_features)
club_loss = club_sample(states, next_states)
return club_loss
def _past_encoder_loss(self, states, next_states, states_dist, next_states_dist, actions, history, step):
# Imagine next state
if step == 0:
actions = torch.zeros(self.args.batch_size, self.env.action_space.shape[0]).float() # Zero action for first step
imagined_next_states = self.transition_model.imagine_step(states, actions, history)
self.history = imagined_next_states["history"]
else:
imagined_next_states = self.transition_model.imagine_step(states, actions, self.history) # (N,128)
# State Distribution
imagined_next_states_dist = imagined_next_states["distribution"]
# KL divergence loss
loss = torch.distributions.kl.kl_divergence(imagined_next_states_dist, next_states_dist["distribution"]).mean()
return loss
if __name__ == '__main__':
args = parse_args()