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metalearner.py
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metalearner.py
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import os
import time
import gym
import numpy as np
import torch
from algorithms.a2c import A2C
from algorithms.online_storage import OnlineStorage
from algorithms.ppo import PPO
from environments.parallel_envs import make_vec_envs
from models.policy import Policy
from utils import evaluation as utl_eval
from utils import helpers as utl
from utils.tb_logger import TBLogger
from vae import VaribadVAE
device = torch.device("cuda:0" if torch.cuda.is_available() else "cpu")
class MetaLearner:
"""
Meta-Learner class with the main training loop for variBAD.
"""
def __init__(self, args):
self.args = args
utl.seed(self.args.seed, self.args.deterministic_execution)
# calculate number of updates and keep count of frames/iterations
self.num_updates = int(args.num_frames) // args.policy_num_steps // args.num_processes
self.frames = 0
self.iter_idx = -1
# initialise tensorboard logger
self.logger = TBLogger(self.args, self.args.exp_label)
# initialise environments
self.envs = make_vec_envs(env_name=args.env_name, seed=args.seed, num_processes=args.num_processes,
gamma=args.policy_gamma, device=device,
episodes_per_task=self.args.max_rollouts_per_task,
normalise_rew=args.norm_rew_for_policy, ret_rms=None,
tasks=None
)
if self.args.single_task_mode:
# get the current tasks (which will be num_process many different tasks)
self.train_tasks = self.envs.get_task()
# set the tasks to the first task (i.e. just a random task)
self.train_tasks[1:] = self.train_tasks[0]
# make it a list
self.train_tasks = [t for t in self.train_tasks]
# re-initialise environments with those tasks
self.envs = make_vec_envs(env_name=args.env_name, seed=args.seed, num_processes=args.num_processes,
gamma=args.policy_gamma, device=device,
episodes_per_task=self.args.max_rollouts_per_task,
normalise_rew=args.norm_rew_for_policy, ret_rms=None,
tasks=self.train_tasks
)
# save the training tasks so we can evaluate on the same envs later
utl.save_obj(self.train_tasks, self.logger.full_output_folder, "train_tasks")
else:
self.train_tasks = None
# calculate what the maximum length of the trajectories is
self.args.max_trajectory_len = self.envs._max_episode_steps
self.args.max_trajectory_len *= self.args.max_rollouts_per_task
# get policy input dimensions
self.args.state_dim = self.envs.observation_space.shape[0]
self.args.task_dim = self.envs.task_dim
self.args.belief_dim = self.envs.belief_dim
self.args.num_states = self.envs.num_states
# get policy output (action) dimensions
self.args.action_space = self.envs.action_space
if isinstance(self.envs.action_space, gym.spaces.discrete.Discrete):
self.args.action_dim = 1
else:
self.args.action_dim = self.envs.action_space.shape[0]
# initialise VAE and policy
self.vae = VaribadVAE(self.args, self.logger, lambda: self.iter_idx)
self.policy_storage = self.initialise_policy_storage()
self.policy = self.initialise_policy()
def initialise_policy_storage(self):
return OnlineStorage(args=self.args,
num_steps=self.args.policy_num_steps,
num_processes=self.args.num_processes,
state_dim=self.args.state_dim,
latent_dim=self.args.latent_dim,
belief_dim=self.args.belief_dim,
task_dim=self.args.task_dim,
action_space=self.args.action_space,
hidden_size=self.args.encoder_gru_hidden_size,
normalise_rewards=self.args.norm_rew_for_policy,
)
def initialise_policy(self):
# initialise policy network
policy_net = Policy(
args=self.args,
#
pass_state_to_policy=self.args.pass_state_to_policy,
pass_latent_to_policy=self.args.pass_latent_to_policy,
pass_belief_to_policy=self.args.pass_belief_to_policy,
pass_task_to_policy=self.args.pass_task_to_policy,
dim_state=self.args.state_dim,
dim_latent=self.args.latent_dim * 2,
dim_belief=self.args.belief_dim,
dim_task=self.args.task_dim,
#
hidden_layers=self.args.policy_layers,
activation_function=self.args.policy_activation_function,
policy_initialisation=self.args.policy_initialisation,
#
action_space=self.envs.action_space,
init_std=self.args.policy_init_std,
).to(device)
# initialise policy trainer
if self.args.policy == 'a2c':
policy = A2C(
self.args,
policy_net,
self.args.policy_value_loss_coef,
self.args.policy_entropy_coef,
policy_optimiser=self.args.policy_optimiser,
policy_anneal_lr=self.args.policy_anneal_lr,
train_steps=self.num_updates,
optimiser_vae=self.vae.optimiser_vae,
lr=self.args.lr_policy,
eps=self.args.policy_eps,
)
elif self.args.policy == 'ppo':
policy = PPO(
self.args,
policy_net,
self.args.policy_value_loss_coef,
self.args.policy_entropy_coef,
policy_optimiser=self.args.policy_optimiser,
policy_anneal_lr=self.args.policy_anneal_lr,
train_steps=self.num_updates,
lr=self.args.lr_policy,
eps=self.args.policy_eps,
ppo_epoch=self.args.ppo_num_epochs,
num_mini_batch=self.args.ppo_num_minibatch,
use_huber_loss=self.args.ppo_use_huberloss,
use_clipped_value_loss=self.args.ppo_use_clipped_value_loss,
clip_param=self.args.ppo_clip_param,
optimiser_vae=self.vae.optimiser_vae,
)
else:
raise NotImplementedError
return policy
def train(self):
""" Main Meta-Training loop """
start_time = time.time()
# reset environments
prev_state, belief, task = utl.reset_env(self.envs, self.args)
# insert initial observation / embeddings to rollout storage
self.policy_storage.prev_state[0].copy_(prev_state)
# log once before training
with torch.no_grad():
self.log(None, None, start_time)
for self.iter_idx in range(self.num_updates):
# First, re-compute the hidden states given the current rollouts (since the VAE might've changed)
with torch.no_grad():
latent_sample, latent_mean, latent_logvar, hidden_state = self.encode_running_trajectory()
# add this initial hidden state to the policy storage
assert len(self.policy_storage.latent_mean) == 0 # make sure we emptied buffers
self.policy_storage.hidden_states[0].copy_(hidden_state)
self.policy_storage.latent_samples.append(latent_sample.clone())
self.policy_storage.latent_mean.append(latent_mean.clone())
self.policy_storage.latent_logvar.append(latent_logvar.clone())
# rollout policies for a few steps
for step in range(self.args.policy_num_steps):
# sample actions from policy
with torch.no_grad():
value, action = utl.select_action(
args=self.args,
policy=self.policy,
state=prev_state,
belief=belief,
task=task,
deterministic=False,
latent_sample=latent_sample,
latent_mean=latent_mean,
latent_logvar=latent_logvar,
)
# take step in the environment
[next_state, belief, task], (rew_raw, rew_normalised), done, infos = utl.env_step(self.envs, action, self.args)
done = torch.from_numpy(np.array(done, dtype=int)).to(device).float().view((-1, 1))
# create mask for episode ends
masks_done = torch.FloatTensor([[0.0] if done_ else [1.0] for done_ in done]).to(device)
# bad_mask is true if episode ended because time limit was reached
bad_masks = torch.FloatTensor([[0.0] if 'bad_transition' in info.keys() else [1.0] for info in infos]).to(device)
with torch.no_grad():
# compute next embedding (for next loop and/or value prediction bootstrap)
latent_sample, latent_mean, latent_logvar, hidden_state = utl.update_encoding(
encoder=self.vae.encoder,
next_obs=next_state,
action=action,
reward=rew_raw,
done=done,
hidden_state=hidden_state)
# before resetting, update the embedding and add to vae buffer
# (last state might include useful task info)
if not (self.args.disable_decoder and self.args.disable_kl_term):
self.vae.rollout_storage.insert(prev_state.clone(),
action.detach().clone(),
next_state.clone(),
rew_raw.clone(),
done.clone(),
task.clone() if task is not None else None)
# add the obs before reset to the policy storage
self.policy_storage.next_state[step] = next_state.clone()
# reset environments that are done
done_indices = np.argwhere(done.cpu().flatten()).flatten()
if len(done_indices) > 0:
next_state, belief, task = utl.reset_env(self.envs, self.args,
indices=done_indices, state=next_state)
# TODO: deal with resampling for posterior sampling algorithm
# latent_sample = latent_sample
# latent_sample[i] = latent_sample[i]
# add experience to policy buffer
self.policy_storage.insert(
state=next_state,
belief=belief,
task=task,
actions=action,
rewards_raw=rew_raw,
rewards_normalised=rew_normalised,
value_preds=value,
masks=masks_done,
bad_masks=bad_masks,
done=done,
hidden_states=hidden_state.squeeze(0),
latent_sample=latent_sample,
latent_mean=latent_mean,
latent_logvar=latent_logvar,
)
prev_state = next_state
self.frames += self.args.num_processes
# --- UPDATE ---
if self.args.precollect_len <= self.frames:
# check if we are pre-training the VAE
if self.args.pretrain_len > self.iter_idx:
for p in range(self.args.num_vae_updates_per_pretrain):
self.vae.compute_vae_loss(update=True,
pretrain_index=self.iter_idx * self.args.num_vae_updates_per_pretrain + p)
# otherwise do the normal update (policy + vae)
else:
train_stats = self.update(state=prev_state,
belief=belief,
task=task,
latent_sample=latent_sample,
latent_mean=latent_mean,
latent_logvar=latent_logvar)
# log
run_stats = [action, self.policy_storage.action_log_probs, value]
with torch.no_grad():
self.log(run_stats, train_stats, start_time)
# clean up after update
self.policy_storage.after_update()
self.envs.close()
def encode_running_trajectory(self):
"""
(Re-)Encodes (for each process) the entire current trajectory.
Returns sample/mean/logvar and hidden state (if applicable) for the current timestep.
:return:
"""
# for each process, get the current batch (zero-padded obs/act/rew + length indicators)
prev_obs, next_obs, act, rew, lens = self.vae.rollout_storage.get_running_batch()
# get embedding - will return (1+sequence_len) * batch * input_size -- includes the prior!
all_latent_samples, all_latent_means, all_latent_logvars, all_hidden_states = self.vae.encoder(actions=act,
states=next_obs,
rewards=rew,
hidden_state=None,
return_prior=True)
# get the embedding / hidden state of the current time step (need to do this since we zero-padded)
latent_sample = (torch.stack([all_latent_samples[lens[i]][i] for i in range(len(lens))])).to(device)
latent_mean = (torch.stack([all_latent_means[lens[i]][i] for i in range(len(lens))])).to(device)
latent_logvar = (torch.stack([all_latent_logvars[lens[i]][i] for i in range(len(lens))])).to(device)
hidden_state = (torch.stack([all_hidden_states[lens[i]][i] for i in range(len(lens))])).to(device)
return latent_sample, latent_mean, latent_logvar, hidden_state
def get_value(self, state, belief, task, latent_sample, latent_mean, latent_logvar):
latent = utl.get_latent_for_policy(self.args, latent_sample=latent_sample, latent_mean=latent_mean, latent_logvar=latent_logvar)
return self.policy.actor_critic.get_value(state=state, belief=belief, task=task, latent=latent).detach()
def update(self, state, belief, task, latent_sample, latent_mean, latent_logvar):
"""
Meta-update.
Here the policy is updated for good average performance across tasks.
:return:
"""
# update policy (if we are not pre-training, have enough data in the vae buffer, and are not at iteration 0)
if self.iter_idx >= self.args.pretrain_len and self.iter_idx > 0:
# bootstrap next value prediction
with torch.no_grad():
next_value = self.get_value(state=state,
belief=belief,
task=task,
latent_sample=latent_sample,
latent_mean=latent_mean,
latent_logvar=latent_logvar)
# compute returns for current rollouts
self.policy_storage.compute_returns(next_value, self.args.policy_use_gae, self.args.policy_gamma,
self.args.policy_tau,
use_proper_time_limits=self.args.use_proper_time_limits)
# update agent (this will also call the VAE update!)
policy_train_stats = self.policy.update(
policy_storage=self.policy_storage,
encoder=self.vae.encoder,
rlloss_through_encoder=self.args.rlloss_through_encoder,
compute_vae_loss=self.vae.compute_vae_loss)
else:
policy_train_stats = 0, 0, 0, 0
# pre-train the VAE
if self.iter_idx < self.args.pretrain_len:
self.vae.compute_vae_loss(update=True)
return policy_train_stats
def log(self, run_stats, train_stats, start_time):
# --- visualise behaviour of policy ---
if (self.iter_idx + 1) % self.args.vis_interval == 0:
ret_rms = self.envs.venv.ret_rms if self.args.norm_rew_for_policy else None
utl_eval.visualise_behaviour(args=self.args,
policy=self.policy,
image_folder=self.logger.full_output_folder,
iter_idx=self.iter_idx,
ret_rms=ret_rms,
encoder=self.vae.encoder,
reward_decoder=self.vae.reward_decoder,
state_decoder=self.vae.state_decoder,
task_decoder=self.vae.task_decoder,
compute_rew_reconstruction_loss=self.vae.compute_rew_reconstruction_loss,
compute_state_reconstruction_loss=self.vae.compute_state_reconstruction_loss,
compute_task_reconstruction_loss=self.vae.compute_task_reconstruction_loss,
compute_kl_loss=self.vae.compute_kl_loss,
tasks=self.train_tasks,
)
# --- evaluate policy ----
if (self.iter_idx + 1) % self.args.eval_interval == 0:
ret_rms = self.envs.venv.ret_rms if self.args.norm_rew_for_policy else None
returns_per_episode = utl_eval.evaluate(args=self.args,
policy=self.policy,
ret_rms=ret_rms,
encoder=self.vae.encoder,
iter_idx=self.iter_idx,
tasks=self.train_tasks,
)
# log the return avg/std across tasks (=processes)
returns_avg = returns_per_episode.mean(dim=0)
returns_std = returns_per_episode.std(dim=0)
for k in range(len(returns_avg)):
self.logger.add('return_avg_per_iter/episode_{}'.format(k + 1), returns_avg[k], self.iter_idx)
self.logger.add('return_avg_per_frame/episode_{}'.format(k + 1), returns_avg[k], self.frames)
self.logger.add('return_std_per_iter/episode_{}'.format(k + 1), returns_std[k], self.iter_idx)
self.logger.add('return_std_per_frame/episode_{}'.format(k + 1), returns_std[k], self.frames)
print(f"Updates {self.iter_idx}, "
f"Frames {self.frames}, "
f"FPS {int(self.frames / (time.time() - start_time))}, "
f"\n Mean return (train): {returns_avg[-1].item()} \n"
)
# --- save models ---
if (self.iter_idx + 1) % self.args.save_interval == 0:
save_path = os.path.join(self.logger.full_output_folder, 'models')
if not os.path.exists(save_path):
os.mkdir(save_path)
idx_labels = ['']
if self.args.save_intermediate_models:
idx_labels.append(int(self.iter_idx))
for idx_label in idx_labels:
torch.save(self.policy.actor_critic, os.path.join(save_path, f"policy{idx_label}.pt"))
torch.save(self.vae.encoder, os.path.join(save_path, f"encoder{idx_label}.pt"))
if self.vae.state_decoder is not None:
torch.save(self.vae.state_decoder, os.path.join(save_path, f"state_decoder{idx_label}.pt"))
if self.vae.reward_decoder is not None:
torch.save(self.vae.reward_decoder, os.path.join(save_path, f"reward_decoder{idx_label}.pt"))
if self.vae.task_decoder is not None:
torch.save(self.vae.task_decoder, os.path.join(save_path, f"task_decoder{idx_label}.pt"))
# save normalisation params of envs
if self.args.norm_rew_for_policy:
rew_rms = self.envs.venv.ret_rms
utl.save_obj(rew_rms, save_path, f"env_rew_rms{idx_label}")
# TODO: grab from policy and save?
# if self.args.norm_obs_for_policy:
# obs_rms = self.envs.venv.obs_rms
# utl.save_obj(obs_rms, save_path, f"env_obs_rms{idx_label}")
# --- log some other things ---
if ((self.iter_idx + 1) % self.args.log_interval == 0) and (train_stats is not None):
self.logger.add('environment/state_max', self.policy_storage.prev_state.max(), self.iter_idx)
self.logger.add('environment/state_min', self.policy_storage.prev_state.min(), self.iter_idx)
self.logger.add('environment/rew_max', self.policy_storage.rewards_raw.max(), self.iter_idx)
self.logger.add('environment/rew_min', self.policy_storage.rewards_raw.min(), self.iter_idx)
self.logger.add('policy_losses/value_loss', train_stats[0], self.iter_idx)
self.logger.add('policy_losses/action_loss', train_stats[1], self.iter_idx)
self.logger.add('policy_losses/dist_entropy', train_stats[2], self.iter_idx)
self.logger.add('policy_losses/sum', train_stats[3], self.iter_idx)
self.logger.add('policy/action', run_stats[0][0].float().mean(), self.iter_idx)
if hasattr(self.policy.actor_critic, 'logstd'):
self.logger.add('policy/action_logstd', self.policy.actor_critic.dist.logstd.mean(), self.iter_idx)
self.logger.add('policy/action_logprob', run_stats[1].mean(), self.iter_idx)
self.logger.add('policy/value', run_stats[2].mean(), self.iter_idx)
self.logger.add('encoder/latent_mean', torch.cat(self.policy_storage.latent_mean).mean(), self.iter_idx)
self.logger.add('encoder/latent_logvar', torch.cat(self.policy_storage.latent_logvar).mean(), self.iter_idx)
# log the average weights and gradients of all models (where applicable)
for [model, name] in [
[self.policy.actor_critic, 'policy'],
[self.vae.encoder, 'encoder'],
[self.vae.reward_decoder, 'reward_decoder'],
[self.vae.state_decoder, 'state_transition_decoder'],
[self.vae.task_decoder, 'task_decoder']
]:
if model is not None:
param_list = list(model.parameters())
param_mean = np.mean([param_list[i].data.cpu().numpy().mean() for i in range(len(param_list))])
self.logger.add('weights/{}'.format(name), param_mean, self.iter_idx)
if name == 'policy':
self.logger.add('weights/policy_std', param_list[0].data.mean(), self.iter_idx)
if param_list[0].grad is not None:
param_grad_mean = np.mean([param_list[i].grad.cpu().numpy().mean() for i in range(len(param_list))])
self.logger.add('gradients/{}'.format(name), param_grad_mean, self.iter_idx)