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final-evaluation.md
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final-evaluation.md
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Waiter project - Tao-Sen Chang, Weronika Skowronska, Martyna Druminska
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The main objective of our program is to help the customer with their
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order, serve meals and pick up dirty plates. Since the program emulates
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real life circumstances, where the waiter should work efficiently, we
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used reinforcement learning to train the agent to arrive at the tables
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as fast as possible by taking note of the table’s coordinates. If the
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plates happen to be empty, meaning that they probably have not ordered
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yet, the program renders a couple questions to determine if the customer
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would like a vegan menu or not. We used the decision tree learning
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algorithm, to make the best recommendation to the customer. Every 10
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plates visited, the program asks the user whether they would like to
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exit the program or not. At beginning of our project, we use
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reinforcement learning to get the shortest route for our agent to
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traversal specific tables. Reinforcement learning is how software agent
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ought to take actions in an environment in order to maximize the notion
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of cumulative reward. The agent makes a sequence of decisions, and
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learns to perform the best actions every step. After tons of training
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loops, the agent could get the optimal strategy which might collect
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maximal reward. In the case of our program, the “maximal reward”, would
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be to find the minimum distance to the customer, which in turn would
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save time and effort. Next, we used decision trees to make a prediction
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on whether the person would like a vegan menu or not, based on the
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“customers” appearance. The decision tree algorithm learns off of a
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dataset with a diverse set of variables to make the best prediction. The
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program generates a flow-like structure that represents the decisions,
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where each node is a “test” on an attribute. The decision tree finishes
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when there are only leaf nodes left. In conclusion, we managed to create
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a program that runs efficiently and cohesively to satisfy the needs of
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the customer.
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waiter1406.py
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waiter1406.py
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#### MD #######
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import pandas as pd
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import pygame
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from sklearn.model_selection import train_test_split
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from sklearn.preprocessing import LabelEncoder
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from sklearn.tree import DecisionTreeClassifier
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from sklearn.metrics import accuracy_score
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from sklearn.metrics import confusion_matrix
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from pygame.locals import *
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import numpy as np
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import matplotlib.pyplot as plt
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from sklearn import tree
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import random
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from textpygame import get_key, ask, display_box
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###### /MD ######
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import math
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import pickle
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########################
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### WS ###
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########################
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# For CNN:
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import keras
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from keras.preprocessing import image
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from keras.models import Sequential
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from keras.layers import Convolution2D
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from keras.layers import MaxPooling2D
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from keras.layers import Flatten
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from keras.layers import Dense
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#initializing:
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cnn_model = Sequential()
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#Convolution:
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cnn_model.add(Convolution2D(32, (3, 3), input_shape =(256, 256, 3), activation = "relu"))
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#Pooling:
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cnn_model.add(MaxPooling2D(pool_size = (2,2)))
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# Adding a second convolutional layer
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cnn_model.add(Convolution2D(32, 3, 3, activation = 'relu'))
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cnn_model.add(MaxPooling2D(pool_size = (2, 2)))
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#Flattening:
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cnn_model.add(Flatten())
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#Fully connected layers::
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cnn_model.add(Dense(units = 128, activation = "relu"))
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cnn_model.add(Dense(units = 3, activation = "softmax"))
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# loading weigjts:
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cnn_model.load_weights('s444523/best_model_weights2.h5')
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#Making CNN:
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cnn_model.compile(optimizer = "adam", loss = "categorical_crossentropy", metrics = ["accuracy"])
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########################
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### /WS ###
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########################
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#### MD#####
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#read csv file
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dataset= pd.read_csv("veganism.csv")
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#create a new dataset
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newdataset = pd.DataFrame(dataset, columns=['ethnicity', 'gender', 'appearence', 'vegan'])
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# creating instance of labelencoder
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labelencoder = LabelEncoder()
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# Assigning numerical values and storing in another column
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newdataset['ethnicity_no'] = labelencoder.fit_transform(newdataset['ethnicity'])
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newdataset['gender_no']= labelencoder.fit_transform(newdataset['gender'])
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newdataset['appearence_no']= labelencoder.fit_transform(newdataset['appearence'])
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# for x values drop unimportant columns, axis=1 specifies that we want the columns not rows
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Y=newdataset['vegan']
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X=newdataset.drop(newdataset.columns[0:4], axis=1)
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#test 14% of the data
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X_train, X_test, Y_train, Y_test = train_test_split(X, Y, test_size=0.15)
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classifier = DecisionTreeClassifier()
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classifier.fit(X_train, Y_train)
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y_pred = classifier.predict(X_test)
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fn=['ethnicity','gender','appearence']
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cn=['yes', 'no']
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# Setting dpi = 300 to make image clearer than default (for the decision tree visualisation)
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fig, axes = plt.subplots(nrows = 1,ncols = 1,figsize = (4,4), dpi=300)
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tree.plot_tree(classifier,
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feature_names = fn,
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class_names=cn,
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filled = True);
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fig.savefig('imagenamenew.png')
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class Customer:
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def __init__(self, coordinate_i, coordinate_j):
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self.coordinate_i = coordinate_i
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self.coordinate_j = coordinate_j
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change_value(coordinate_i, coordinate_j,1 , 4)
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class CustomerPlace:
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def __init__(self, coordinate_i, coordinate_j):
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self.coordinate_i = coordinate_i
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self.coordinate_j = coordinate_j
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change_value(coordinate_i, coordinate_j,1 , 5)
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###### /MD #######
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# Colors:
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# Define some colors
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BLACK = (0, 0, 0)
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WHITE = (255, 255, 255)
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GREEN = (0, 255, 0)
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RED = (255, 0, 0)
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BLUE = (0, 0, 240)
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YELLOW = (255, 255, 0)
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#Width and Height of each square:
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WIDTH = 20
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HEIGHT = 20
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#Margin:
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MARGIN = 5
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grid = [[0 for x in range(16)] for y in range(16)]
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def change_value(i, j, width, n):
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for r in range (i, i+width):
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for c in range (j, j+width):
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grid[r][c] = n
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class Table:
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def __init__(self, coordinate_i, coordinate_j):
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self.coordinate_i = coordinate_i
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self.coordinate_j = coordinate_j
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change_value(coordinate_i, coordinate_j, 2, 1)
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def get_destination_coor(self):
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return [self.coordinate_i+2, self.coordinate_j+2]
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########################
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### WS ###
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########################
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# The finction "state of meal" chooses a photo of a plate at the given table.
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def state_of_meal(self):
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## !!!!!!###
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num = np.random.randint(67, 100)
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## !!!!!!###
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if num<=67:
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img_name = 'plates/{}.png'.format(num)
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else:
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img_name = 'plates/{}.jpg'.format(num)
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return img_name
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# The function "change state" changes the value of the state variable.
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# It informs, whether the client are waiting for the waiter to make an order
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# (0 - empty plates) are eating (2 - full plates) or are waiting for the
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# waiter to get a recipt (1 - dirty plates)
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def change_state(self, st):
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self.state = st
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########################
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### /WS ###
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########################
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class Kitchen:
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def __init__(self, coordinate_i, coordinate_j):
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self.coordinate_i = coordinate_i
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self.coordinate_j = coordinate_j
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change_value(coordinate_i, coordinate_j, 3, 2)
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class Agent:
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def __init__(self,orig_coordinate_i, orig_coordinate_j):
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self.orig_coordinate_i = orig_coordinate_i
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self.orig_coordinate_j = orig_coordinate_j
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self.state = np.array([orig_coordinate_i,orig_coordinate_j])
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change_value(orig_coordinate_j, orig_coordinate_j, 1, 3)
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self.state_update(orig_coordinate_i, orig_coordinate_j)
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def state_update(self, c1, c2):
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self.state[0] = c1
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self.state[1] = c2
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def leave(self):
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change_value(self.state[0], self.state[1], 1, 0)
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def move_to(self, nextPos):
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self.leave()
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nextPos_x, nextPos_y = nextPos
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self.state_update(nextPos_x, nextPos_y)
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change_value(self.state[0], self.state[1], 1, 3)
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########################
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### WS ###
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########################
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#The function "define_table" serches for the apropriate table in the
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# table_dict (to enable the usage of class attributes and methods)
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def define_table(self, t_num):
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t_num = 'table{}'.format(t_num)
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t_num = table_dict[t_num]
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return t_num
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# The function "check_plates" uses the pretrained CNN model to classify
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# the plate on the table as empty(0), full(2) or dirty(1)
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def check_plates(self, table_number):
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table = self.define_table(table_number)
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plate = table.state_of_meal()
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plate= image.load_img(plate, target_size = (256, 256))
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plate = image.img_to_array(plate)
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#plate = plate.reshape((256, 256))
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plate = np.expand_dims(plate, axis = 0)
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result = cnn_model.predict(plate)[0]
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print(result)
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if result[1] == 1:
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result[1] = 0
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x = int(input("Excuse me, have You done eating? 1=Yes, 2 = No \n"))
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result[x] = 1
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for i, x in enumerate(result):
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if result[i] == 1:
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table.change_state(i)
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return i
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########################
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### /WS ###
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########################
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def check_done():
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for event in pygame.event.get(): # Checking for the event
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if event.type == pygame.QUIT: # If the program is closed:
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return True # To exit the loop
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def draw_grid():
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for row in range(16): # Drawing the grid
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for column in range(16):
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color = WHITE
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if grid[row][column] == 1:
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color = GREEN
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if grid[row][column] == 2:
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color = RED
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if grid[row][column] == 3:
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color = BLUE
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pygame.draw.rect(screen,
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color,
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[(MARGIN + WIDTH) * column + MARGIN,
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(MARGIN + HEIGHT) * row + MARGIN,
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WIDTH,
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HEIGHT])
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## default positions of the agent:
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x = 12
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y = 12
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agent = Agent(x, y)
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table1 = Table(2, 2)
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table2 = Table (2,7)
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table3 = Table(2, 12)
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table4 = Table(7, 2)
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table5 = Table(7, 7)
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table6 = Table(7, 12)
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table7 = Table(12, 2)
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table8 = Table(12, 7)
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################### WS #####################
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# I added the dict to loop through tables.
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table_dict = {"table1":table1, "table2":table2, "table3":table3,"table4":table4,
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"table5":table5,"table6":table6,"table7":table7,"table8":table8
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}
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################### WS #####################
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pygame.init()
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####MD ####
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'''
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# create a font object.
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# 1st parameter is the font file
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# which is present in pygame.
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# 2nd parameter is size of the font
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font = pygame.font.Font('freesansbold.ttf', 14)
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X = 400
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Y = 400
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# create a text suface object,
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# on which text is drawn on it.
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text = font.render('waiter: hello, let me help you with your order.', True, WHITE, BLACK)
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userText=font.render('user: ', True, BLUE, BLACK)
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# create a rectangular object for the
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# text surface object
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textRect = text.get_rect()
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inputRect = userText.get_rect()
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# set the center of the rectangular object.
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textRect.center= (200, 340)
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inputRect.center=(200,370)
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'''
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#### /MD ####
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#class Kitchen:
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kitchen = Kitchen(13, 13)
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WINDOW_SIZE = [405, 405]
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screen = pygame.display.set_mode(WINDOW_SIZE)
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pygame.display.set_caption("Waiter_Grid3")
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done = False
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clock = pygame.time.Clock()
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with open('res_targets_4-1.data', 'rb') as filehandle:
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# read the data as binary data stream
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trained_route = pickle.load(filehandle)
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destination = (4, 14)
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trained_route.append(destination)
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table_targets = [(9, 4),(4, 4),(4, 9),(4, 14)]
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destination_tables = []
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###### MD /########3
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x=[2,7,12]
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y=[2,7]
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random_customer_seat_x=random.choice(x)
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random_customer_seat_y=random.choice(y)
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print(random_customer_seat_x,random_customer_seat_y)
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seat=Customer(random_customer_seat_x,random_customer_seat_y)
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next_to=CustomerPlace(random_customer_seat_x,random_customer_seat_y-1)
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WINDOW_SIZE = [405, 405]
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screen = pygame.display.set_mode(WINDOW_SIZE)
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pygame.display.set_caption("Waiter_Grid3")
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done = False
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print(random_customer_seat_x,random_customer_seat_y-1)
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clock = pygame.time.Clock()
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#updating the drawing
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def updateDraw():
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x = agent.state[0]
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y = agent.state[1]
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screen.fill(BLACK) # Background color
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for row in range(16): # Drawing the grid
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for column in range(16):
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color = WHITE
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if grid[row][column] == 1:
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color = GREEN
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if grid[row][column] == 2:
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color = RED
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if grid[row][column] == 3:
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color = BLUE
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if grid[row][column] == 4:
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color = MAGENTA
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surface = pygame.draw.rect(screen,
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color,
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[(MARGIN + WIDTH) * column + MARGIN,
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(MARGIN + HEIGHT) * row + MARGIN,
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WIDTH,
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HEIGHT])
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def customer():
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screen.blit(text, textRect)
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ethnicity3 = input("Excuse me, What's you're ethnicity? <black>, <asian>, <white>\n")
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gender3= input("Excuse me, What's you're gender? <male>, <female>, <other> \n")
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appearence3=input("Excuse me, What's you're appearance? <hippie>, <other> \n")
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if (ethnicity3 =="black"):
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ethnicity3 = 1
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elif ethnicity3 == "asian":
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ethnicity3 = 0
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else:
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ethnicity3 = 2
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if gender3 == "male":
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gender3 = 0
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else:
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gender3 = 1
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if appearence3 == "hippie":
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appearence3= 0
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else:
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appearence3 = 1
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prediction = classifier.predict([[ethnicity3, gender3, appearence3]])
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#pygame.quit()
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if prediction == [0]:
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print("You're probably not vegan. Would you like a regular menu?")
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else:
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print("It seems like you're vegan. Would you like a vegan menu?")
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#exit()
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###### /MD ###
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# -------- Main Program Loop -----------
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exit_counter = 0
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while not done:
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screen.fill(BLACK) # Background color
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draw_grid()
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done = check_done()
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new_route = trained_route[:]
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for value in table_dict.values():
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destination_tables.append(value.get_destination_coor())
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num_of_table = 1
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while len(new_route) != 0:
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# move to next grid
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agent.move_to(new_route[0])
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# update the grid
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pygame.time.delay(150)
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screen.fill(BLACK)
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draw_grid()
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# Drawing the grid
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clock.tick(100) # Limit to 60 frames per second
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pygame.display.flip() # Updating the screen
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# get current grid coordinate
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x = agent.state[0]
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y = agent.state[1]
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# if reached the table, ask to collect the plates
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if [x, y] in destination_tables:
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########################
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### WS ###
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########################
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#pygame.time.delay(100)
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print("I'm at a table no. {}".format(num_of_table))
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## Checking at what state are the plates:
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state_of_table = agent.check_plates(num_of_table)
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num_of_table +=1
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if state_of_table == 0:
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customer()
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# Early stopping (after 10 rounds)
|
||||
exit_counter += 1
|
||||
print("exit_counter", exit_counter)
|
||||
if exit_counter == 10:
|
||||
play_again = 1
|
||||
play_again = int(input("Exit? 0=No, 1=Yes \n"))
|
||||
if play_again:
|
||||
pygame.quit()
|
||||
else:
|
||||
exit_counter = 0
|
||||
|
||||
########################
|
||||
### /WS ###
|
||||
########################
|
||||
destination_tables = destination_tables[1:]
|
||||
|
||||
new_route = new_route[1:]
|
||||
|
||||
# After each fool loop, we can quit the program:.
|
||||
|
||||
|
||||
|
||||
pygame.quit()
|
Loading…
Reference in New Issue
Block a user