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objective.py
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# Copyright 2017 The TensorFlow Authors All Rights Reserved.
#
# Licensed under the Apache License, Version 2.0 (the "License");
# you may not use this file except in compliance with the License.
# You may obtain a copy of the License at
#
# http://www.apache.org/licenses/LICENSE-2.0
#
# Unless required by applicable law or agreed to in writing, software
# distributed under the License is distributed on an "AS IS" BASIS,
# WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
# See the License for the specific language governing permissions and
# limitations under the License.
# ==============================================================================
"""Objectives to compute loss and value targets.
Implements Actor Critic, PCL (vanilla PCL, Unified PCL, Trust PCL), and TRPO.
"""
import tensorflow as tf
import numpy as np
class Objective(object):
def __init__(self, learning_rate, clip_norm):
self.learning_rate = learning_rate
self.clip_norm = clip_norm
def get_optimizer(self, learning_rate):
"""Optimizer for gradient descent ops."""
return tf.train.AdamOptimizer(learning_rate=learning_rate,
epsilon=2e-4)
def training_ops(self, loss, learning_rate=None):
"""Gradient ops."""
opt = self.get_optimizer(learning_rate)
params = tf.trainable_variables()
grads = tf.gradients(loss, params)
if self.clip_norm:
grads, global_norm = tf.clip_by_global_norm(grads, self.clip_norm)
tf.summary.scalar('grad_global_norm', global_norm)
return opt.apply_gradients(zip(grads, params))
def get(self, rewards, pads, values, final_values,
log_probs, prev_log_probs, target_log_probs,
entropies, logits,
target_values, final_target_values):
"""Get objective calculations."""
raise NotImplementedError()
def discounted_future_sum(values, discount, rollout):
"""Discounted future sum of time-major values."""
discount_filter = tf.reshape(
discount ** tf.range(float(rollout)), [-1, 1, 1])
expanded_values = tf.concat(
[values, tf.zeros([rollout - 1, tf.shape(values)[1]])], 0)
conv_values = tf.transpose(tf.squeeze(tf.nn.conv1d(
tf.expand_dims(tf.transpose(expanded_values), -1), discount_filter,
stride=1, padding='VALID'), -1))
return conv_values
def discounted_two_sided_sum(values, discount, rollout):
"""Discounted two-sided sum of time-major values."""
roll = float(rollout)
discount_filter = tf.reshape(
discount ** tf.abs(tf.range(-roll + 1, roll)), [-1, 1, 1])
expanded_values = tf.concat(
[tf.zeros([rollout - 1, tf.shape(values)[1]]), values,
tf.zeros([rollout - 1, tf.shape(values)[1]])], 0)
conv_values = tf.transpose(tf.squeeze(tf.nn.conv1d(
tf.expand_dims(tf.transpose(expanded_values), -1), discount_filter,
stride=1, padding='VALID'), -1))
return conv_values
def shift_values(values, discount, rollout, final_values=0.0):
"""Shift values up by some amount of time.
Those values that shift from a value beyond the last value
are calculated using final_values.
"""
roll_range = tf.cumsum(tf.ones_like(values[:rollout, :]), 0,
exclusive=True, reverse=True)
final_pad = tf.expand_dims(final_values, 0) * discount ** roll_range
return tf.concat([discount ** rollout * values[rollout:, :],
final_pad], 0)
class ActorCritic(Objective):
"""Standard Actor-Critic."""
def __init__(self, learning_rate, clip_norm=5,
policy_weight=1.0, critic_weight=0.1,
tau=0.1, gamma=1.0, rollout=10,
eps_lambda=0.0, clip_adv=None,
use_target_values=False):
super(ActorCritic, self).__init__(learning_rate, clip_norm=clip_norm)
self.policy_weight = policy_weight
self.critic_weight = critic_weight
self.tau = tau
self.gamma = gamma
self.rollout = rollout
self.clip_adv = clip_adv
self.eps_lambda = tf.get_variable( # TODO: need a better way
'eps_lambda', [], initializer=tf.constant_initializer(eps_lambda),
trainable=False)
self.new_eps_lambda = tf.placeholder(tf.float32, [])
self.assign_eps_lambda = self.eps_lambda.assign(
0.99 * self.eps_lambda + 0.01 * self.new_eps_lambda)
self.use_target_values = use_target_values
def get(self, rewards, pads, values, final_values,
log_probs, prev_log_probs, target_log_probs,
entropies, logits,
target_values, final_target_values):
not_pad = 1 - pads
batch_size = tf.shape(rewards)[1]
entropy = not_pad * sum(entropies)
rewards = not_pad * rewards
value_estimates = not_pad * values
log_probs = not_pad * sum(log_probs)
target_values = not_pad * tf.stop_gradient(target_values)
final_target_values = tf.stop_gradient(final_target_values)
sum_rewards = discounted_future_sum(rewards, self.gamma, self.rollout)
if self.use_target_values:
last_values = shift_values(
target_values, self.gamma, self.rollout,
final_target_values)
else:
last_values = shift_values(value_estimates, self.gamma, self.rollout,
final_values)
future_values = sum_rewards + last_values
baseline_values = value_estimates
adv = tf.stop_gradient(-baseline_values + future_values)
if self.clip_adv:
adv = tf.minimum(self.clip_adv, tf.maximum(-self.clip_adv, adv))
policy_loss = -adv * log_probs
critic_loss = -adv * baseline_values
regularizer = -self.tau * entropy
policy_loss = tf.reduce_mean(
tf.reduce_sum(policy_loss * not_pad, 0))
critic_loss = tf.reduce_mean(
tf.reduce_sum(critic_loss * not_pad, 0))
regularizer = tf.reduce_mean(
tf.reduce_sum(regularizer * not_pad, 0))
# loss for gradient calculation
loss = (self.policy_weight * policy_loss +
self.critic_weight * critic_loss + regularizer)
raw_loss = tf.reduce_mean( # TODO
tf.reduce_sum(not_pad * policy_loss, 0))
gradient_ops = self.training_ops(
loss, learning_rate=self.learning_rate)
tf.summary.histogram('log_probs', tf.reduce_sum(log_probs, 0))
tf.summary.histogram('rewards', tf.reduce_sum(rewards, 0))
tf.summary.scalar('avg_rewards',
tf.reduce_mean(tf.reduce_sum(rewards, 0)))
tf.summary.scalar('policy_loss',
tf.reduce_mean(tf.reduce_sum(not_pad * policy_loss)))
tf.summary.scalar('critic_loss',
tf.reduce_mean(tf.reduce_sum(not_pad * policy_loss)))
tf.summary.scalar('loss', loss)
tf.summary.scalar('raw_loss', raw_loss)
return (loss, raw_loss, future_values,
gradient_ops, tf.summary.merge_all())
class PCL(ActorCritic):
"""PCL implementation.
Implements vanilla PCL, Unified PCL, and Trust PCL depending
on provided inputs.
"""
def get(self, rewards, pads, values, final_values,
log_probs, prev_log_probs, target_log_probs,
entropies, logits,
target_values, final_target_values):
not_pad = 1 - pads
batch_size = tf.shape(rewards)[1]
rewards = not_pad * rewards
value_estimates = not_pad * values
log_probs = not_pad * sum(log_probs)
target_log_probs = not_pad * tf.stop_gradient(sum(target_log_probs))
relative_log_probs = not_pad * (log_probs - target_log_probs)
target_values = not_pad * tf.stop_gradient(target_values)
final_target_values = tf.stop_gradient(final_target_values)
# Prepend.
not_pad = tf.concat([tf.ones([self.rollout - 1, batch_size]),
not_pad], 0)
rewards = tf.concat([tf.zeros([self.rollout - 1, batch_size]),
rewards], 0)
value_estimates = tf.concat(
[self.gamma ** tf.expand_dims(
tf.range(float(self.rollout - 1), 0, -1), 1) *
tf.ones([self.rollout - 1, batch_size]) *
value_estimates[0:1, :],
value_estimates], 0)
log_probs = tf.concat([tf.zeros([self.rollout - 1, batch_size]),
log_probs], 0)
prev_log_probs = tf.concat([tf.zeros([self.rollout - 1, batch_size]),
prev_log_probs], 0)
relative_log_probs = tf.concat([tf.zeros([self.rollout - 1, batch_size]),
relative_log_probs], 0)
target_values = tf.concat(
[self.gamma ** tf.expand_dims(
tf.range(float(self.rollout - 1), 0, -1), 1) *
tf.ones([self.rollout - 1, batch_size]) *
target_values[0:1, :],
target_values], 0)
sum_rewards = discounted_future_sum(rewards, self.gamma, self.rollout)
sum_log_probs = discounted_future_sum(log_probs, self.gamma, self.rollout)
sum_prev_log_probs = discounted_future_sum(prev_log_probs, self.gamma, self.rollout)
sum_relative_log_probs = discounted_future_sum(
relative_log_probs, self.gamma, self.rollout)
if self.use_target_values:
last_values = shift_values(
target_values, self.gamma, self.rollout,
final_target_values)
else:
last_values = shift_values(value_estimates, self.gamma, self.rollout,
final_values)
future_values = (
- self.tau * sum_log_probs
- self.eps_lambda * sum_relative_log_probs
+ sum_rewards + last_values)
baseline_values = value_estimates
adv = tf.stop_gradient(-baseline_values + future_values)
if self.clip_adv:
adv = tf.minimum(self.clip_adv, tf.maximum(-self.clip_adv, adv))
policy_loss = -adv * sum_log_probs
critic_loss = -adv * (baseline_values - last_values)
policy_loss = tf.reduce_mean(
tf.reduce_sum(policy_loss * not_pad, 0))
critic_loss = tf.reduce_mean(
tf.reduce_sum(critic_loss * not_pad, 0))
# loss for gradient calculation
loss = (self.policy_weight * policy_loss +
self.critic_weight * critic_loss)
# actual quantity we're trying to minimize
raw_loss = tf.reduce_mean(
tf.reduce_sum(not_pad * adv * (-baseline_values + future_values), 0))
gradient_ops = self.training_ops(
loss, learning_rate=self.learning_rate)
tf.summary.histogram('log_probs', tf.reduce_sum(log_probs, 0))
tf.summary.histogram('rewards', tf.reduce_sum(rewards, 0))
tf.summary.histogram('future_values', future_values)
tf.summary.histogram('baseline_values', baseline_values)
tf.summary.histogram('advantages', adv)
tf.summary.scalar('avg_rewards',
tf.reduce_mean(tf.reduce_sum(rewards, 0)))
tf.summary.scalar('policy_loss',
tf.reduce_mean(tf.reduce_sum(not_pad * policy_loss)))
tf.summary.scalar('critic_loss',
tf.reduce_mean(tf.reduce_sum(not_pad * policy_loss)))
tf.summary.scalar('loss', loss)
tf.summary.scalar('raw_loss', tf.reduce_mean(raw_loss))
tf.summary.scalar('eps_lambda', self.eps_lambda)
return (loss, raw_loss,
future_values[self.rollout - 1:, :],
gradient_ops, tf.summary.merge_all())
class TRPO(ActorCritic):
"""TRPO."""
def get(self, rewards, pads, values, final_values,
log_probs, prev_log_probs, target_log_probs,
entropies, logits,
target_values, final_target_values):
not_pad = 1 - pads
batch_size = tf.shape(rewards)[1]
rewards = not_pad * rewards
value_estimates = not_pad * values
log_probs = not_pad * sum(log_probs)
prev_log_probs = not_pad * prev_log_probs
target_values = not_pad * tf.stop_gradient(target_values)
final_target_values = tf.stop_gradient(final_target_values)
sum_rewards = discounted_future_sum(rewards, self.gamma, self.rollout)
if self.use_target_values:
last_values = shift_values(
target_values, self.gamma, self.rollout,
final_target_values)
else:
last_values = shift_values(value_estimates, self.gamma, self.rollout,
final_values)
future_values = sum_rewards + last_values
baseline_values = value_estimates
adv = tf.stop_gradient(-baseline_values + future_values)
if self.clip_adv:
adv = tf.minimum(self.clip_adv, tf.maximum(-self.clip_adv, adv))
policy_loss = -adv * tf.exp(log_probs - prev_log_probs)
critic_loss = -adv * baseline_values
policy_loss = tf.reduce_mean(
tf.reduce_sum(policy_loss * not_pad, 0))
critic_loss = tf.reduce_mean(
tf.reduce_sum(critic_loss * not_pad, 0))
raw_loss = policy_loss
# loss for gradient calculation
if self.policy_weight == 0:
policy_loss = 0.0
elif self.critic_weight == 0:
critic_loss = 0.0
loss = (self.policy_weight * policy_loss +
self.critic_weight * critic_loss)
gradient_ops = self.training_ops(
loss, learning_rate=self.learning_rate)
tf.summary.histogram('log_probs', tf.reduce_sum(log_probs, 0))
tf.summary.histogram('rewards', tf.reduce_sum(rewards, 0))
tf.summary.scalar('avg_rewards',
tf.reduce_mean(tf.reduce_sum(rewards, 0)))
tf.summary.scalar('policy_loss',
tf.reduce_mean(tf.reduce_sum(not_pad * policy_loss)))
tf.summary.scalar('critic_loss',
tf.reduce_mean(tf.reduce_sum(not_pad * policy_loss)))
tf.summary.scalar('loss', loss)
tf.summary.scalar('raw_loss', raw_loss)
return (loss, raw_loss, future_values,
gradient_ops, tf.summary.merge_all())