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snakeClass.py
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snakeClass.py
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import os
import pygame
import argparse
import numpy as np
import seaborn as sns
import matplotlib.pyplot as plt
from DQN import DQNAgent
from random import randint
import random
import statistics
import torch.optim as optim
import torch
from GPyOpt.methods import BayesianOptimization
from bayesOpt import *
import datetime
import distutils.util
DEVICE = 'cpu' # 'cuda' if torch.cuda.is_available() else 'cpu'
#################################
# Define parameters manually #
#################################
def define_parameters():
params = dict()
# Neural Network
params['epsilon_decay_linear'] = 1/100
params['learning_rate'] = 0.00013629
params['first_layer_size'] = 200 # neurons in the first layer
params['second_layer_size'] = 20 # neurons in the second layer
params['third_layer_size'] = 50 # neurons in the third layer
params['episodes'] = 250
params['memory_size'] = 2500
params['batch_size'] = 1000
# Settings
params['weights_path'] = 'weights/weights.h5'
params['train'] = False
params["test"] = True
params['plot_score'] = True
params['log_path'] = 'logs/scores_' + str(datetime.datetime.now().strftime("%Y%m%d%H%M%S")) +'.txt'
return params
class Game:
""" Initialize PyGAME """
def __init__(self, game_width, game_height):
pygame.display.set_caption('SnakeGen')
self.game_width = game_width
self.game_height = game_height
self.gameDisplay = pygame.display.set_mode((game_width, game_height + 60))
self.bg = pygame.image.load("img/background.png")
self.crash = False
self.player = Player(self)
self.food = Food()
self.score = 0
class Player(object):
def __init__(self, game):
x = 0.45 * game.game_width
y = 0.5 * game.game_height
self.x = x - x % 20
self.y = y - y % 20
self.position = []
self.position.append([self.x, self.y])
self.food = 1
self.eaten = False
self.image = pygame.image.load('img/snakeBody.png')
self.x_change = 20
self.y_change = 0
def update_position(self, x, y):
if self.position[-1][0] != x or self.position[-1][1] != y:
if self.food > 1:
for i in range(0, self.food - 1):
self.position[i][0], self.position[i][1] = self.position[i + 1]
self.position[-1][0] = x
self.position[-1][1] = y
def do_move(self, move, x, y, game, food, agent):
move_array = [self.x_change, self.y_change]
if self.eaten:
self.position.append([self.x, self.y])
self.eaten = False
self.food = self.food + 1
if np.array_equal(move, [1, 0, 0]):
move_array = self.x_change, self.y_change
elif np.array_equal(move, [0, 1, 0]) and self.y_change == 0: # right - going horizontal
move_array = [0, self.x_change]
elif np.array_equal(move, [0, 1, 0]) and self.x_change == 0: # right - going vertical
move_array = [-self.y_change, 0]
elif np.array_equal(move, [0, 0, 1]) and self.y_change == 0: # left - going horizontal
move_array = [0, -self.x_change]
elif np.array_equal(move, [0, 0, 1]) and self.x_change == 0: # left - going vertical
move_array = [self.y_change, 0]
self.x_change, self.y_change = move_array
self.x = x + self.x_change
self.y = y + self.y_change
if self.x < 20 or self.x > game.game_width - 40 \
or self.y < 20 \
or self.y > game.game_height - 40 \
or [self.x, self.y] in self.position:
game.crash = True
eat(self, food, game)
self.update_position(self.x, self.y)
def display_player(self, x, y, food, game):
self.position[-1][0] = x
self.position[-1][1] = y
if game.crash == False:
for i in range(food):
x_temp, y_temp = self.position[len(self.position) - 1 - i]
game.gameDisplay.blit(self.image, (x_temp, y_temp))
update_screen()
else:
pygame.time.wait(300)
class Food(object):
def __init__(self):
self.x_food = 240
self.y_food = 200
self.image = pygame.image.load('img/food2.png')
def food_coord(self, game, player):
x_rand = randint(20, game.game_width - 40)
self.x_food = x_rand - x_rand % 20
y_rand = randint(20, game.game_height - 40)
self.y_food = y_rand - y_rand % 20
if [self.x_food, self.y_food] not in player.position:
return self.x_food, self.y_food
else:
self.food_coord(game, player)
def display_food(self, x, y, game):
game.gameDisplay.blit(self.image, (x, y))
update_screen()
def eat(player, food, game):
if player.x == food.x_food and player.y == food.y_food:
food.food_coord(game, player)
player.eaten = True
game.score = game.score + 1
def get_record(score, record):
if score >= record:
return score
else:
return record
def display_ui(game, score, record):
myfont = pygame.font.SysFont('Segoe UI', 20)
myfont_bold = pygame.font.SysFont('Segoe UI', 20, True)
text_score = myfont.render('SCORE: ', True, (0, 0, 0))
text_score_number = myfont.render(str(score), True, (0, 0, 0))
text_highest = myfont.render('HIGHEST SCORE: ', True, (0, 0, 0))
text_highest_number = myfont_bold.render(str(record), True, (0, 0, 0))
game.gameDisplay.blit(text_score, (45, 440))
game.gameDisplay.blit(text_score_number, (120, 440))
game.gameDisplay.blit(text_highest, (190, 440))
game.gameDisplay.blit(text_highest_number, (350, 440))
game.gameDisplay.blit(game.bg, (10, 10))
def display(player, food, game, record):
game.gameDisplay.fill((255, 255, 255))
display_ui(game, game.score, record)
player.display_player(player.position[-1][0], player.position[-1][1], player.food, game)
food.display_food(food.x_food, food.y_food, game)
def update_screen():
pygame.display.update()
def initialize_game(player, game, food, agent, batch_size):
state_init1 = agent.get_state(game, player, food) # [0 0 0 0 0 0 0 0 0 1 0 0 0 1 0 0]
action = [1, 0, 0]
player.do_move(action, player.x, player.y, game, food, agent)
state_init2 = agent.get_state(game, player, food)
reward1 = agent.set_reward(player, game.crash)
agent.remember(state_init1, action, reward1, state_init2, game.crash)
agent.replay_new(agent.memory, batch_size)
def plot_seaborn(array_counter, array_score, train):
sns.set(color_codes=True, font_scale=1.5)
sns.set_style("white")
plt.figure(figsize=(13,8))
fit_reg = False if train== False else True
ax = sns.regplot(
np.array([array_counter])[0],
np.array([array_score])[0],
#color="#36688D",
x_jitter=.1,
scatter_kws={"color": "#36688D"},
label='Data',
fit_reg = fit_reg,
line_kws={"color": "#F49F05"}
)
# Plot the average line
y_mean = [np.mean(array_score)]*len(array_counter)
ax.plot(array_counter,y_mean, label='Mean', linestyle='--')
ax.legend(loc='upper right')
ax.set(xlabel='# games', ylabel='score')
plt.show()
def get_mean_stdev(array):
return statistics.mean(array), statistics.stdev(array)
def test(params):
params['load_weights'] = True
params['train'] = False
params["test"] = False
score, mean, stdev = run(params)
return score, mean, stdev
def run(params):
"""
Run the DQN algorithm, based on the parameters previously set.
"""
pygame.init()
agent = DQNAgent(params)
agent = agent.to(DEVICE)
agent.optimizer = optim.Adam(agent.parameters(), weight_decay=0, lr=params['learning_rate'])
counter_games = 0
score_plot = []
counter_plot = []
record = 0
total_score = 0
while counter_games < params['episodes']:
for event in pygame.event.get():
if event.type == pygame.QUIT:
pygame.quit()
quit()
# Initialize classes
game = Game(440, 440)
player1 = game.player
food1 = game.food
# Perform first move
initialize_game(player1, game, food1, agent, params['batch_size'])
if params['display']:
display(player1, food1, game, record)
steps = 0 # steps since the last positive reward
while (not game.crash) and (steps < 100):
if not params['train']:
agent.epsilon = 0.01
else:
# agent.epsilon is set to give randomness to actions
agent.epsilon = 1 - (counter_games * params['epsilon_decay_linear'])
# get old state
state_old = agent.get_state(game, player1, food1)
# perform random actions based on agent.epsilon, or choose the action
if random.uniform(0, 1) < agent.epsilon:
final_move = np.eye(3)[randint(0,2)]
else:
# predict action based on the old state
with torch.no_grad():
state_old_tensor = torch.tensor(state_old.reshape((1, 11)), dtype=torch.float32).to(DEVICE)
prediction = agent(state_old_tensor)
final_move = np.eye(3)[np.argmax(prediction.detach().cpu().numpy()[0])]
# perform new move and get new state
player1.do_move(final_move, player1.x, player1.y, game, food1, agent)
state_new = agent.get_state(game, player1, food1)
# set reward for the new state
reward = agent.set_reward(player1, game.crash)
# if food is eaten, steps is set to 0
if reward > 0:
steps = 0
if params['train']:
# train short memory base on the new action and state
agent.train_short_memory(state_old, final_move, reward, state_new, game.crash)
# store the new data into a long term memory
agent.remember(state_old, final_move, reward, state_new, game.crash)
record = get_record(game.score, record)
if params['display']:
display(player1, food1, game, record)
pygame.time.wait(params['speed'])
steps+=1
if params['train']:
agent.replay_new(agent.memory, params['batch_size'])
counter_games += 1
total_score += game.score
print(f'Game {counter_games} Score: {game.score}')
score_plot.append(game.score)
counter_plot.append(counter_games)
mean, stdev = get_mean_stdev(score_plot)
if params['train']:
model_weights = agent.state_dict()
torch.save(model_weights, params["weights_path"])
if params['plot_score']:
plot_seaborn(counter_plot, score_plot, params['train'])
return total_score, mean, stdev
if __name__ == '__main__':
# Set options to activate or deactivate the game view, and its speed
pygame.font.init()
parser = argparse.ArgumentParser()
params = define_parameters()
parser.add_argument("--display", nargs='?', type=distutils.util.strtobool, default=True)
parser.add_argument("--speed", nargs='?', type=int, default=50)
parser.add_argument("--bayesianopt", nargs='?', type=distutils.util.strtobool, default=False)
args = parser.parse_args()
print("Args", args)
params['display'] = args.display
params['speed'] = args.speed
if args.bayesianopt:
bayesOpt = BayesianOptimizer(params)
bayesOpt.optimize_RL()
if params['train']:
print("Training...")
params['load_weights'] = False # when training, the network is not pre-trained
run(params)
if params['test']:
print("Testing...")
params['train'] = False
params['load_weights'] = True
run(params)