mirror of
https://github.com/gsi-upm/sitc
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275 lines
10 KiB
Python
275 lines
10 KiB
Python
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# Class definition of QLearning
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from pathlib import Path
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from typing import NamedTuple
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import matplotlib.pyplot as plt
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import numpy as np
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import pandas as pd
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import seaborn as sns
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from tqdm import tqdm
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import gymnasium as gym
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from gymnasium.envs.toy_text.frozen_lake import generate_random_map
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# Params
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class Params(NamedTuple):
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total_episodes: int # Total episodes
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learning_rate: float # Learning rate
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gamma: float # Discounting rate
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epsilon: float # Exploration probability
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map_size: int # Number of tiles of one side of the squared environment
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seed: int # Define a seed so that we get reproducible results
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is_slippery: bool # If true the player will move in intended direction with probability of 1/3 else will move in either perpendicular direction with equal probability of 1/3 in both directions
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n_runs: int # Number of runs
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action_size: int # Number of possible actions
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state_size: int # Number of possible states
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proba_frozen: float # Probability that a tile is frozen
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savefig_folder: Path # Root folder where plots are saved
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class Qlearning:
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def __init__(self, learning_rate, gamma, state_size, action_size):
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self.state_size = state_size
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self.action_size = action_size
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self.learning_rate = learning_rate
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self.gamma = gamma
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self.reset_qtable()
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def update(self, state, action, reward, new_state):
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"""Update Q(s,a):= Q(s,a) + lr [R(s,a) + gamma * max Q(s',a') - Q(s,a)]"""
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delta = (
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reward
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+ self.gamma * np.max(self.qtable[new_state][:])
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- self.qtable[state][action]
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)
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q_update = self.qtable[state][action] + self.learning_rate * delta
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return q_update
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def reset_qtable(self):
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"""Reset the Q-table."""
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self.qtable = np.zeros((self.state_size, self.action_size))
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class EpsilonGreedy:
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def __init__(self, epsilon, rng):
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self.epsilon = epsilon
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self.rng = rng
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def choose_action(self, action_space, state, qtable):
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"""Choose an action `a` in the current world state (s)."""
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# First we randomize a number
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explor_exploit_tradeoff = self.rng.uniform(0, 1)
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# Exploration
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if explor_exploit_tradeoff < self.epsilon:
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action = action_space.sample()
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# Exploitation (taking the biggest Q-value for this state)
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else:
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# Break ties randomly
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# If all actions are the same for this state we choose a random one
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# (otherwise `np.argmax()` would always take the first one)
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if np.all(qtable[state][:]) == qtable[state][0]:
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action = action_space.sample()
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else:
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action = np.argmax(qtable[state][:])
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return action
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def run_frozen_maps(maps, params, rng):
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"""Run FrozenLake in maps and plot results"""
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map_sizes = maps
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res_all = pd.DataFrame()
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st_all = pd.DataFrame()
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for map_size in map_sizes:
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env = gym.make(
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"FrozenLake-v1",
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is_slippery=params.is_slippery,
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render_mode="rgb_array",
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desc=generate_random_map(
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size=map_size, p=params.proba_frozen, seed=params.seed
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),
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)
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params = params._replace(action_size=env.action_space.n)
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params = params._replace(state_size=env.observation_space.n)
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env.action_space.seed(
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params.seed
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) # Set the seed to get reproducible results when sampling the action space
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learner = Qlearning(
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learning_rate=params.learning_rate,
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gamma=params.gamma,
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state_size=params.state_size,
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action_size=params.action_size,
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)
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explorer = EpsilonGreedy(
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epsilon=params.epsilon,
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rng=rng
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)
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print(f"Map size: {map_size}x{map_size}")
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rewards, steps, episodes, qtables, all_states, all_actions = run_env(env, params, learner, explorer)
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# Save the results in dataframes
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res, st = postprocess(episodes, params, rewards, steps, map_size)
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res_all = pd.concat([res_all, res])
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st_all = pd.concat([st_all, st])
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qtable = qtables.mean(axis=0) # Average the Q-table between runs
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plot_states_actions_distribution(
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states=all_states, actions=all_actions, map_size=map_size, params=params
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) # Sanity check
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plot_q_values_map(qtable, env, map_size, params)
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env.close()
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return res_all, st_all
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def run_env(env, params, learner, explorer):
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rewards = np.zeros((params.total_episodes, params.n_runs))
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steps = np.zeros((params.total_episodes, params.n_runs))
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episodes = np.arange(params.total_episodes)
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qtables = np.zeros((params.n_runs, params.state_size, params.action_size))
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all_states = []
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all_actions = []
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for run in range(params.n_runs): # Run several times to account for stochasticity
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learner.reset_qtable() # Reset the Q-table between runs
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for episode in tqdm(
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episodes, desc=f"Run {run}/{params.n_runs} - Episodes", leave=False
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):
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state = env.reset(seed=params.seed)[0] # Reset the environment
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step = 0
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done = False
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total_rewards = 0
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while not done:
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action = explorer.choose_action(
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action_space=env.action_space, state=state, qtable=learner.qtable
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)
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# Log all states and actions
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all_states.append(state)
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all_actions.append(action)
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# Take the action (a) and observe the outcome state(s') and reward (r)
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new_state, reward, terminated, truncated, info = env.step(action)
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done = terminated or truncated
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learner.qtable[state, action] = learner.update(
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state, action, reward, new_state
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)
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total_rewards += reward
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step += 1
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# Our new state is state
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state = new_state
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# Log all rewards and steps
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rewards[episode, run] = total_rewards
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steps[episode, run] = step
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qtables[run, :, :] = learner.qtable
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return rewards, steps, episodes, qtables, all_states, all_actions
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def postprocess(episodes, params, rewards, steps, map_size):
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"""Convert the results of the simulation in dataframes."""
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res = pd.DataFrame(
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data={
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"Episodes": np.tile(episodes, reps=params.n_runs),
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"Rewards": rewards.flatten(),
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"Steps": steps.flatten(),
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}
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)
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res["cum_rewards"] = rewards.cumsum(axis=0).flatten(order="F")
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res["map_size"] = np.repeat(f"{map_size}x{map_size}", res.shape[0])
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st = pd.DataFrame(data={"Episodes": episodes, "Steps": steps.mean(axis=1)})
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st["map_size"] = np.repeat(f"{map_size}x{map_size}", st.shape[0])
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return res, st
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def qtable_directions_map(qtable, map_size):
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"""Get the best learned action & map it to arrows."""
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qtable_val_max = qtable.max(axis=1).reshape(map_size, map_size)
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qtable_best_action = np.argmax(qtable, axis=1).reshape(map_size, map_size)
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directions = {0: "←", 1: "↓", 2: "→", 3: "↑"}
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qtable_directions = np.empty(qtable_best_action.flatten().shape, dtype=str)
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eps = np.finfo(float).eps # Minimum float number on the machine
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for idx, val in enumerate(qtable_best_action.flatten()):
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if qtable_val_max.flatten()[idx] > eps:
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# Assign an arrow only if a minimal Q-value has been learned as best action
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# otherwise since 0 is a direction, it also gets mapped on the tiles where
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# it didn't actually learn anything
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qtable_directions[idx] = directions[val]
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qtable_directions = qtable_directions.reshape(map_size, map_size)
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return qtable_val_max, qtable_directions
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def plot_q_values_map(qtable, env, map_size, params):
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"""Plot the last frame of the simulation and the policy learned."""
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qtable_val_max, qtable_directions = qtable_directions_map(qtable, map_size)
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# Plot the last frame
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fig, ax = plt.subplots(nrows=1, ncols=2, figsize=(15, 5))
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ax[0].imshow(env.render())
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ax[0].axis("off")
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ax[0].set_title("Last frame")
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# Plot the policy
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sns.heatmap(
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qtable_val_max,
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annot=qtable_directions,
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fmt="",
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ax=ax[1],
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cmap=sns.color_palette("Blues", as_cmap=True),
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linewidths=0.7,
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linecolor="black",
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xticklabels=[],
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yticklabels=[],
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annot_kws={"fontsize": "xx-large"},
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).set(title="Learned Q-values\nArrows represent best action")
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for _, spine in ax[1].spines.items():
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spine.set_visible(True)
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spine.set_linewidth(0.7)
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spine.set_color("black")
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img_title = f"frozenlake_q_values_{map_size}x{map_size}.png"
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fig.savefig(params.savefig_folder / img_title, bbox_inches="tight")
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plt.show()
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def plot_states_actions_distribution(states, actions, map_size, params):
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"""Plot the distributions of states and actions."""
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labels = {"LEFT": 0, "DOWN": 1, "RIGHT": 2, "UP": 3}
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fig, ax = plt.subplots(nrows=1, ncols=2, figsize=(15, 5))
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sns.histplot(data=states, ax=ax[0], kde=True)
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ax[0].set_title("States")
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sns.histplot(data=actions, ax=ax[1])
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ax[1].set_xticks(list(labels.values()), labels=labels.keys())
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ax[1].set_title("Actions")
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fig.tight_layout()
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img_title = f"frozenlake_states_actions_distrib_{map_size}x{map_size}.png"
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fig.savefig(params.savefig_folder / img_title, bbox_inches="tight")
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plt.show()
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def plot_steps_and_rewards(rewards_df, steps_df,params):
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"""Plot the steps and rewards from dataframes."""
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fig, ax = plt.subplots(nrows=1, ncols=2, figsize=(15, 5))
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sns.lineplot(
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data=rewards_df, x="Episodes", y="cum_rewards", hue="map_size", ax=ax[0]
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)
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ax[0].set(ylabel="Cumulated rewards")
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sns.lineplot(data=steps_df, x="Episodes", y="Steps", hue="map_size", ax=ax[1])
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ax[1].set(ylabel="Averaged steps number")
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for axi in ax:
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axi.legend(title="map size")
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fig.tight_layout()
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img_title = "frozenlake_steps_and_rewards.png"
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fig.savefig(params.savefig_folder / img_title, bbox_inches="tight")
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plt.show()
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