500 lines
17 KiB
Python
500 lines
17 KiB
Python
import os
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import random
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import pickle
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import numpy as np
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from collections import deque
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import torch
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import torch.nn as nn
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from torch.utils.tensorboard import SummaryWriter
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import gym
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import dmc2gym
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import cv2
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from PIL import Image
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from typing import Iterable
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class eval_mode(object):
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def __init__(self, *models):
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self.models = models
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def __enter__(self):
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self.prev_states = []
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for model in self.models:
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self.prev_states.append(model.training)
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model.train(False)
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def __exit__(self, *args):
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for model, state in zip(self.models, self.prev_states):
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model.train(state)
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return False
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def soft_update_params(net, target_net, tau):
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for param, target_param in zip(net.parameters(), target_net.parameters()):
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target_param.data.copy_(
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tau * param.data + (1 - tau) * target_param.data
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)
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def set_seed_everywhere(seed):
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torch.manual_seed(seed)
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if torch.cuda.is_available():
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torch.cuda.manual_seed_all(seed)
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np.random.seed(seed)
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random.seed(seed)
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def module_hash(module):
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result = 0
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for tensor in module.state_dict().values():
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result += tensor.sum().item()
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return result
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def make_dir(dir_path):
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try:
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os.mkdir(dir_path)
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except OSError:
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pass
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return dir_path
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class FrameStack(gym.Wrapper):
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def __init__(self, env, k):
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gym.Wrapper.__init__(self, env)
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self._k = k
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self._frames = deque([], maxlen=k)
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shp = env.observation_space.shape
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self.observation_space = gym.spaces.Box(
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low=0,
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high=1,
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shape=((shp[0] * k,) + shp[1:]),
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dtype=env.observation_space.dtype
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)
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self._max_episode_steps = env._max_episode_steps
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def reset(self):
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obs = self.env.reset()
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for _ in range(self._k):
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self._frames.append(obs)
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return self._get_obs()
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def step(self, action):
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obs, reward, done, info = self.env.step(action)
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self._frames.append(obs)
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return self._get_obs(), reward, done, info
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def _get_obs(self):
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assert len(self._frames) == self._k
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return np.concatenate(list(self._frames), axis=0)
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class ActionRepeat:
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def __init__(self, env, amount):
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self._env = env
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self._amount = amount
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def __getattr__(self, name):
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return getattr(self._env, name)
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def step(self, action):
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done = False
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total_reward = 0
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current_step = 0
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while current_step < self._amount and not done:
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obs, reward, done, info = self._env.step(action)
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total_reward += reward
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current_step += 1
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return obs, total_reward, done, info
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class NormalizeActions:
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def __init__(self, env):
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self._env = env
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self._mask = np.logical_and(
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np.isfinite(env.action_space.low),
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np.isfinite(env.action_space.high))
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self._low = np.where(self._mask, env.action_space.low, -1)
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self._high = np.where(self._mask, env.action_space.high, 1)
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def __getattr__(self, name):
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return getattr(self._env, name)
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@property
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def action_space(self):
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low = np.where(self._mask, -np.ones_like(self._low), self._low)
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high = np.where(self._mask, np.ones_like(self._low), self._high)
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return gym.spaces.Box(low, high, dtype=np.float32)
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def step(self, action):
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original = (action + 1) / 2 * (self._high - self._low) + self._low
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original = np.where(self._mask, original, action)
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return self._env.step(original)
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class TimeLimit:
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def __init__(self, env, duration):
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self._env = env
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self._duration = duration
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self._step = None
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def __getattr__(self, name):
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return getattr(self._env, name)
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def step(self, action):
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assert self._step is not None, 'Must reset environment.'
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obs, reward, done, info = self._env.step(action)
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self._step += 1
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if self._step >= self._duration:
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done = True
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if 'discount' not in info:
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info['discount'] = np.array(1.0).astype(np.float32)
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self._step = None
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return obs, reward, done, info
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def reset(self):
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self._step = 0
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return self._env.reset()
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class ReplayBuffer:
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def __init__(self, size, obs_shape, action_size, seq_len, batch_size, args):
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self.size = size
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self.obs_shape = obs_shape
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self.action_size = action_size
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self.seq_len = seq_len
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self.batch_size = batch_size
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self.idx = 0
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self.full = False
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self.observations = np.empty((size, *obs_shape), dtype=np.uint8)
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self.next_observations = np.empty((size, *obs_shape), dtype=np.uint8)
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self.actions = np.empty((size, action_size), dtype=np.float32)
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self.rewards = np.empty((size,), dtype=np.float32)
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self.terminals = np.empty((size,), dtype=np.float32)
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self.steps, self.episodes = 0, 0
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self.episode_count = np.zeros((size,), dtype=np.int32)
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def add(self, obs, ac, next_obs, rew, done, episode_count):
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self.observations[self.idx] = obs
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self.next_observations[self.idx] = next_obs
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self.actions[self.idx] = ac
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self.rewards[self.idx] = rew
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self.terminals[self.idx] = done
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self.full = self.full or self.idx == 0
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self.steps += 1
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self.episodes = self.episodes + (1 if done else 0)
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self.episode_count[self.idx] = episode_count
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self.idx = (self.idx + 1) % self.size
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def _sample_idx(self, L):
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valid_idx = False
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while not valid_idx:
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idx = np.random.randint(0, self.size if self.full else self.idx - L)
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idxs = np.arange(idx, idx + L) % self.size
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valid_idx = not self.idx in idxs[1:]
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return idxs
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def _retrieve_batch(self, idxs, n, L):
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vec_idxs = idxs.transpose().reshape(-1) # Unroll indices
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observations = self.observations[vec_idxs]
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next_obs = self.next_observations[vec_idxs]
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obs = observations.reshape(L, n, *observations.shape[1:])
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next_obs = next_obs.reshape(L, n, *next_obs.shape[1:])
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acs = self.actions[vec_idxs].reshape(L, n, -1)
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rew = self.rewards[vec_idxs].reshape(L, n)
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term = self.terminals[vec_idxs].reshape(L, n)
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return obs, acs, next_obs, rew, term
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def sample(self):
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n = self.batch_size
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l = self.seq_len
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obs,acs,next_obs,rews,terms= self._retrieve_batch(np.asarray([self._sample_idx(l) for _ in range(n)]), n, l)
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return obs,acs,next_obs,rews,terms
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class ReplayBuffer1:
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def __init__(self, size, obs_shape, action_size, seq_len, batch_size, args):
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self.size = size
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self.obs_shape = obs_shape
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self.action_size = action_size
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self.seq_len = seq_len
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self.batch_size = batch_size
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self.idx = 0
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self.full = False
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self.args = args
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self.observations = np.empty((size, *obs_shape), dtype=np.uint8)
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self.actions = np.empty((size, action_size), dtype=np.float32)
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self.rewards = np.empty((size,1), dtype=np.float32)
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self.next_observations = np.empty((size, *obs_shape), dtype=np.uint8)
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self.episode_count = np.zeros((size,), dtype=np.uint8)
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self.terminals = np.empty((size,), dtype=np.float32)
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self.steps, self.episodes = 0, 0
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def add(self, obs, ac, next_obs, rew, episode_count, done):
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self.observations[self.idx] = obs
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self.actions[self.idx] = ac
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self.next_observations[self.idx] = next_obs
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self.rewards[self.idx] = rew
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self.episode_count[self.idx] = episode_count
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self.terminals[self.idx] = done
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self.idx = (self.idx + 1) % self.size
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self.full = self.full or self.idx == 0
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self.steps += 1
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self.episodes = self.episodes + (1 if done else 0)
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def _sample_idx(self, L):
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valid_idx = False
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while not valid_idx:
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idx = np.random.randint(0, self.size if self.full else self.idx - L)
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idxs = np.arange(idx, idx + L) % self.size
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valid_idx = not self.idx in idxs[1:]
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return idxs
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def _retrieve_batch(self, idxs, n, L):
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vec_idxs = idxs.transpose().reshape(-1) # Unroll indices
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observations = self.observations[vec_idxs]
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next_observations = self.next_observations[vec_idxs]
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return observations.reshape(L, n, *observations.shape[1:]), self.actions[vec_idxs].reshape(L, n, -1), observations.reshape(L, n, *next_observations.shape[1:]), \
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self.rewards[vec_idxs].reshape(L, n), self.terminals[vec_idxs].reshape(L, n)
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def sample(self):
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n = self.batch_size
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l = self.seq_len
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obs,acs,rews,terms= self._retrieve_batch(np.asarray([self._sample_idx(l) for _ in range(n)]), n, l)
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return obs,acs,rews,terms
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def group_steps(self, buffer, variable, obs=True):
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variable = getattr(buffer, variable)
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non_zero_indices = np.nonzero(buffer.episode_count)[0]
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print(buffer.episode_count)
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variable = variable[non_zero_indices]
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print(variable.shape)
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exit()
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if obs:
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variable = variable.reshape(-1, self.args.episode_length,
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self.args.frame_stack*self.args.channels,
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self.args.image_size,self.args.image_size).transpose(1, 0, 2, 3, 4)
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else:
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variable = variable.reshape(variable.shape[0]//self.args.episode_length, self.args.episode_length, -1).transpose(1, 0, 2)
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return variable
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def transform_grouped_steps(self, variable):
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variable = variable.transpose((1, 0, 2, 3, 4))
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variable = variable.reshape(self.args.batch_size*self.args.episode_length,self.args.frame_stack*self.args.channels,
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self.args.image_size,self.args.image_size)
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return variable
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def sample_random_idx(self, buffer_length, last=False):
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init = 0 if last else buffer_length - self.args.batch_size
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random_indices = random.sample(range(init, buffer_length), self.args.batch_size)
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return random_indices
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def group_and_sample_random_batch(self, buffer, variable_name, device, random_indices, is_obs=True, offset=0):
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if offset == 0:
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variable_tensor = torch.tensor(self.group_steps(buffer,variable_name, is_obs)).float()[:self.args.episode_length-1].to(device)
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else:
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variable_tensor = torch.tensor(self.group_steps(buffer,variable_name, is_obs)).float()[offset:].to(device)
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return variable_tensor[:,random_indices,:,:,:] if is_obs else variable_tensor[:,random_indices,:]
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def make_env(args):
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# For making ground plane transparent, change rgba to (0, 0, 0, 0) in local_dm_control_suite/{domain_name}.xml,
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# else change to (0.5, 0.5, 0.5, 1.0) for default ground plane color
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# https://mujoco.readthedocs.io/en/stable/XMLreference.html#body-geom
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env = dmc2gym.make(
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domain_name=args.domain_name,
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task_name=args.task_name,
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resource_files=args.resource_files,
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img_source=args.img_source,
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total_frames=args.total_frames,
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seed=args.seed,
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visualize_reward=False,
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from_pixels=(args.encoder_type == 'pixel'),
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height=args.image_size,
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width=args.image_size,
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frame_skip=args.action_repeat,
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video_recording=args.save_video,
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video_recording_dir=args.work_dir,
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version=args.version,
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)
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return env
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def shuffle_along_axis(a, axis):
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idx = np.random.rand(*a.shape).argsort(axis=axis)
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return np.take_along_axis(a,idx,axis=axis)
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def preprocess_obs(obs):
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obs = (obs/255.0) - 0.5
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return obs
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def soft_update_params(net, target_net, tau):
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for param, target_param in zip(net.parameters(), target_net.parameters()):
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target_param.data.copy_(
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tau * param.detach().data + (1 - tau) * target_param.data
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)
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def save_image(array, filename):
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array = array.transpose(1, 2, 0)
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array = ((array+0.5) * 255).astype(np.uint8)
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image = Image.fromarray(array)
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image.save(filename)
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def video_from_array(arr, high_noise, filename):
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"""
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Save a video from a numpy array of shape (T, H, W, C)
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Example:
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video_from_array(np.random.rand(100, 64, 64, 1), 'test.mp4')
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"""
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if arr.shape[-1] == 1:
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height, width, channels = arr.shape[1:]
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fourcc = cv2.VideoWriter_fourcc(*'mp4v')
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out = cv2.VideoWriter('output.mp4', fourcc, 30.0, (width, height))
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for i in range(arr.shape[0]):
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frame = arr[i]
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frame = np.uint8(frame)
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frame = cv2.cvtColor(frame, cv2.COLOR_GRAY2BGR)
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out.write(frame)
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out.release()
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def save_video(images):
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"""
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Image shape is (T, C, H, W)
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Example:(50, 3, 84, 84)
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"""
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output_file = "output.avi"
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fourcc = cv2.VideoWriter_fourcc(*'XVID')
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fps = 2
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height, width, channels = 84,84,3
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out = cv2.VideoWriter(output_file, fourcc, fps, (width, height))
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for image in images:
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image = np.uint8(image.transpose((1, 2, 0)))
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out.write(image)
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out.release()
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class CorruptVideos:
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def __init__(self, dir_path):
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self.dir_path = dir_path
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def _is_video_corrupt(self,filepath):
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"""
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Check if a video file is corrupt.
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Args:
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dir_path (str): Path to the video file.
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Returns:
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bool: True if the video is corrupt, False otherwise.
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"""
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# Open the video file
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cap = cv2.VideoCapture(filepath)
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if not cap.isOpened():
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return True
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ret, frame = cap.read()
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if not ret:
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return True
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cap.release()
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return False
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def _delete_corrupt_video(self, filepath):
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os.remove(filepath)
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def is_video_corrupt(self, delete=False):
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for filename in os.listdir(self.dir_path):
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filepath = os.path.join(self.dir_path, filename)
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if filepath.endswith(".mp4"):
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if self._is_video_corrupt(filepath):
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print(f"{filepath} is corrupt.")
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if delete:
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self._delete_corrupt_video(filepath)
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print(f"Deleted {filepath}")
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def get_parameters(modules: Iterable[nn.Module]):
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"""
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Given a list of torch modules, returns a list of their parameters.
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:param modules: iterable of modules
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:returns: a list of parameters
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"""
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model_parameters = []
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for module in modules:
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model_parameters += list(module.parameters())
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return model_parameters
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class FreezeParameters:
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def __init__(self, modules: Iterable[nn.Module]):
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"""
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Context manager to locally freeze gradients.
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In some cases with can speed up computation because gradients aren't calculated for these listed modules.
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example:
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```
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with FreezeParameters([module]):
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output_tensor = module(input_tensor)
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```
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:param modules: iterable of modules. used to call .parameters() to freeze gradients.
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"""
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self.modules = modules
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self.param_states = [p.requires_grad for p in get_parameters(self.modules)]
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def __enter__(self):
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for param in get_parameters(self.modules):
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param.requires_grad = False
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def __exit__(self, exc_type, exc_val, exc_tb):
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for i, param in enumerate(get_parameters(self.modules)):
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param.requires_grad = self.param_states[i]
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class Logger:
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def __init__(self, log_dir, n_logged_samples=10, summary_writer=None):
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self._log_dir = log_dir
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print('########################')
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print('logging outputs to ', log_dir)
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print('########################')
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self._n_logged_samples = n_logged_samples
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self._summ_writer = SummaryWriter(log_dir, flush_secs=1, max_queue=1)
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def log_scalar(self, scalar, name, step_):
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self._summ_writer.add_scalar('{}'.format(name), scalar, step_)
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def log_scalars(self, scalar_dict, step):
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for key, value in scalar_dict.items():
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print('{} : {}'.format(key, value))
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self.log_scalar(value, key, step)
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self.dump_scalars_to_pickle(scalar_dict, step)
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def log_videos(self, videos, step, max_videos_to_save=1, fps=20, video_title='video'):
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# max rollout length
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max_videos_to_save = np.min([max_videos_to_save, videos.shape[0]])
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max_length = videos[0].shape[0]
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for i in range(max_videos_to_save):
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if videos[i].shape[0]>max_length:
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max_length = videos[i].shape[0]
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|
|
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# pad rollouts to all be same length
|
|
for i in range(max_videos_to_save):
|
|
if videos[i].shape[0]<max_length:
|
|
padding = np.tile([videos[i][-1]], (max_length-videos[i].shape[0],1,1,1))
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videos[i] = np.concatenate([videos[i], padding], 0)
|
|
|
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clip = mpy.ImageSequenceClip(list(videos[i]), fps=fps)
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new_video_title = video_title+'{}_{}'.format(step, i) + '.gif'
|
|
filename = os.path.join(self._log_dir, new_video_title)
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|
video.write_gif(filename, fps =fps)
|
|
|
|
|
|
def dump_scalars_to_pickle(self, metrics, step, log_title=None):
|
|
log_path = os.path.join(self._log_dir, "scalar_data.pkl" if log_title is None else log_title)
|
|
with open(log_path, 'ab') as f:
|
|
pickle.dump({'step': step, **dict(metrics)}, f)
|
|
|
|
def flush(self):
|
|
self._summ_writer.flush() |