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rl.py
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rl.py
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"""Reinforcement Learning (Chapter 21)"""
from collections import defaultdict
from utils import argmax
from mdp import MDP, policy_evaluation
import random
class PassiveADPAgent:
"""Passive (non-learning) agent that uses adaptive dynamic programming
on a given MDP and policy. [Figure 21.2]"""
class ModelMDP(MDP):
""" Class for implementing modifed Version of input MDP with
an editable transition model P and a custom function T. """
def __init__(self, init, actlist, terminals, gamma, states):
super().__init__(init, actlist, terminals, gamma)
nested_dict = lambda: defaultdict(nested_dict)
# StackOverflow:whats-the-best-way-to-initialize-a-dict-of-dicts-in-python
self.P = nested_dict()
def T(self, s, a):
"""Returns a list of tuples with probabilities for states
based on the learnt model P."""
return [(prob, res) for (res, prob) in self.P[(s, a)].items()]
def __init__(self, pi, mdp):
self.pi = pi
self.mdp = PassiveADPAgent.ModelMDP(mdp.init, mdp.actlist,
mdp.terminals, mdp.gamma, mdp.states)
self.U = {}
self.Nsa = defaultdict(int)
self.Ns1_sa = defaultdict(int)
self.s = None
self.a = None
def __call__(self, percept):
s1, r1 = percept
self.mdp.states.add(s1) # Model keeps track of visited states.
R, P, mdp, pi = self.mdp.reward, self.mdp.P, self.mdp, self.pi
s, a, Nsa, Ns1_sa, U = self.s, self.a, self.Nsa, self.Ns1_sa, self.U
if s1 not in R: # Reward is only available for visted state.
U[s1] = R[s1] = r1
if s is not None:
Nsa[(s, a)] += 1
Ns1_sa[(s1, s, a)] += 1
# for each t such that Ns′|sa [t, s, a] is nonzero
for t in [res for (res, state, act), freq in Ns1_sa.items()
if (state, act) == (s, a) and freq != 0]:
P[(s, a)][t] = Ns1_sa[(t, s, a)] / Nsa[(s, a)]
U = policy_evaluation(pi, U, mdp)
if s1 in mdp.terminals:
self.s = self.a = None
else:
self.s, self.a = s1, self.pi[s1]
return self.a
def update_state(self, percept):
'''To be overridden in most cases. The default case
assumes the percept to be of type (state, reward)'''
return percept
class PassiveTDAgent:
"""The abstract class for a Passive (non-learning) agent that uses
temporal differences to learn utility estimates. Override update_state
method to convert percept to state and reward. The mdp being provided
should be an instance of a subclass of the MDP Class. [Figure 21.4]
"""
def __init__(self, pi, mdp, alpha=None):
self.pi = pi
self.U = {s: 0. for s in mdp.states}
self.Ns = {s: 0 for s in mdp.states}
self.s = None
self.a = None
self.r = None
self.gamma = mdp.gamma
self.terminals = mdp.terminals
if alpha:
self.alpha = alpha
else:
self.alpha = lambda n: 1./(1+n) # udacity video
def __call__(self, percept):
s1, r1 = self.update_state(percept)
pi, U, Ns, s, r = self.pi, self.U, self.Ns, self.s, self.r
alpha, gamma, terminals = self.alpha, self.gamma, self.terminals
if not Ns[s1]:
U[s1] = r1
if s is not None:
Ns[s] += 1
U[s] += alpha(Ns[s]) * (r + gamma * U[s1] - U[s])
if s1 in terminals:
self.s = self.a = self.r = None
else:
self.s, self.a, self.r = s1, pi[s1], r1
return self.a
def update_state(self, percept):
''' To be overridden in most cases. The default case
assumes the percept to be of type (state, reward)'''
return percept
class QLearningAgent:
""" An exploratory Q-learning agent. It avoids having to learn the transition
model because the Q-value of a state can be related directly to those of
its neighbors. [Figure 21.8]
"""
def __init__(self, mdp, Ne, Rplus, alpha=None):
self.gamma = mdp.gamma
self.terminals = mdp.terminals
self.all_act = mdp.actlist
self.Ne = Ne # iteration limit in exploration function
self.Rplus = Rplus # large value to assign before iteration limit
self.Q = defaultdict(float)
self.Nsa = defaultdict(float)
self.s = None
self.a = None
self.r = None
if alpha:
self.alpha = alpha
else:
self.alpha = lambda n: 1./(1+n) # udacity video
def f(self, u, n):
""" Exploration function. Returns fixed Rplus untill
agent has visited state, action a Ne number of times.
Same as ADP agent in book."""
if n < self.Ne:
return self.Rplus
else:
return u
def actions_in_state(self, state):
""" Returns actions possible in given state.
Useful for max and argmax. """
if state in self.terminals:
return [None]
else:
return self.all_act
def __call__(self, percept):
s1, r1 = self.update_state(percept)
Q, Nsa, s, a, r = self.Q, self.Nsa, self.s, self.a, self.r
alpha, gamma, terminals = self.alpha, self.gamma, self.terminals,
actions_in_state = self.actions_in_state
if s in terminals:
Q[s, None] = r1
if s is not None:
Nsa[s, a] += 1
Q[s, a] += alpha(Nsa[s, a]) * (r + gamma * max(Q[s1, a1]
for a1 in actions_in_state(s1)) - Q[s, a])
if s in terminals:
self.s = self.a = self.r = None
else:
self.s, self.r = s1, r1
self.a = argmax(actions_in_state(s1), key=lambda a1: self.f(Q[s1, a1], Nsa[s1, a1]))
return self.a
def update_state(self, percept):
''' To be overridden in most cases. The default case
assumes the percept to be of type (state, reward)'''
return percept
def run_single_trial(agent_program, mdp):
''' Execute trial for given agent_program
and mdp. mdp should be an instance of subclass
of mdp.MDP '''
def take_single_action(mdp, s, a):
'''
Selects outcome of taking action a
in state s. Weighted Sampling.
'''
x = random.uniform(0, 1)
cumulative_probability = 0.0
for probability_state in mdp.T(s, a):
probability, state = probability_state
cumulative_probability += probability
if x < cumulative_probability:
break
return state
current_state = mdp.init
while True:
current_reward = mdp.R(current_state)
percept = (current_state, current_reward)
next_action = agent_program(percept)
if next_action is None:
break
current_state = take_single_action(mdp, current_state, next_action)