Genetic algorithm

bin/Classess/Field.py

@@ -1,13 +1,15 @@
 from doctest import master
 from tkinter import *
 
-WINDOW_X = 533 + 1200
-WINDOW_Y = 950
-FRAME_WIDTH = 533
-FRAME_HEIGHT = 533
+# WINDOW_X = 533 + 1200
+# WINDOW_Y = 950
+# FRAME_WIDTH = 533
+# FRAME_HEIGHT = 533
+#
+# # Size of small image
+# IMAGE_SIZE = 50
 
-# Size of small image
-IMAGE_SIZE = 50
+from resources.Globals import *
 
 step = IMAGE_SIZE + 3
 
@@ -15,32 +17,38 @@ step = IMAGE_SIZE + 3
 class Field(object):
     def __init__(self):
         self.win = Tk()
-        self.width = 533
-        self.height = 533
+        self.width = 555
+        self.height = 555
         self.image_size = 50
         self.rows = 10
         self.columns = 10
-        self.x_start = 3
-        self.y_start = 3
+        self.x_start = 5
+        self.y_start = 5
         self.state_of_cell_array = [[0 for i in range(3)] for j in range(200)]
         self.field_state_array = [[False for i in range(self.rows)] for j in range(self.columns)]
         self.small_image_array = [[0 for i in range(self.rows)] for j in range(self.columns)]
         self.large_image_array = [[0 for i in range(self.rows)] for j in range(self.columns)]
+        self.cell_expense = [0 for i in range(self.rows * self.columns)]
+        self.visited_mines = []
 
         # Modified by Artem to search in the status area
         self.canvas_small_images = []
         self.rectangle = 0
 
+        self.mines_coord = []
+
         self.main_frame = Frame(master, width=FRAME_WIDTH, height=FRAME_HEIGHT, bd=0)
         self.main_frame.pack(anchor=NW)
         self.small_field_canvas = Canvas(self.main_frame, width=FRAME_WIDTH, height=FRAME_HEIGHT, highlightthickness=0,
-                                         bg='light gray')
+                                         bg='black')
 
         self.small_field_canvas.pack()
         self.large_image_canvas = Canvas(self.win, width=WINDOW_X - 533 - 20, height=900, highlightthickness=0,
                                          bg='gray')
         self.large_image_canvas.place(x=FRAME_WIDTH + 5, y=3)
 
+        self.flag_img = PhotoImage(master=self.small_field_canvas, file="../../files/flag/Flaga.png")
+
     # Clear Canvases
     def Moving(self):
         self.large_image_canvas.delete('all')
@@ -55,6 +63,7 @@ class Field(object):
         # Putting small images
         for i in range(self.columns):
             for j in range(self.rows):
+
                 small_image_name = self.small_image_array[column][row]
 
                 self.small_field_canvas.image = small_image_name
@@ -62,13 +71,19 @@ class Field(object):
                     self.small_field_canvas.create_image(x, y, anchor=NW, image=small_image_name))
                 # self.small_field_canvas.create_image(x, y, anchor=NW, image=small_image_name)
 
+                for k in range(0, len(self.mines_coord)):
+                    if self.mines_coord[k][0] == i and self.mines_coord[k][1] == j:
+                        new_mine_coord = self.small_field_canvas.coords(self.canvas_small_images[len(self.canvas_small_images) - 1])
+                        self.mines_coord[k] = new_mine_coord
+
                 x += self.image_size + self.x_start
                 row += 1
             y += self.image_size + self.y_start
             x = self.x_start
             column += 1
             row = 0
+        # print(self.mines_coord)
 
     def PuttingLargeImage(self, large_img_name):
         self.large_image_canvas.image = large_img_name
-        self.large_image_canvas.create_image(0, 0, anchor=NW, image=large_img_name)
+        self.large_image_canvas.create_image(0, 0, anchor=NW, image=large_img_name)

bin/Classess/Node.py

@@ -1,8 +1,15 @@
+from resources.Globals import *
+
+images_coord_list = []
+cell_expense_list = []
+
+
 class Node:
     def __init__(self):
         self.state = State()
-        self.parent = None
+        self.parent = []
         self.action = ""
+        self.priority = 0
 
 
 class State:
@@ -11,6 +18,14 @@ class State:
         self.direction = ""
 
 
+def init_data(coord_list, expense_list):
+    global images_coord_list
+    global cell_expense_list
+
+    images_coord_list = coord_list
+    cell_expense_list = expense_list
+
+
 def successor(state):
 
     node_state_left = Node()
@@ -22,153 +37,249 @@ def successor(state):
         node_state_left.state = State()
         node_state_left.state.coord = state.coord
         node_state_left.state.direction = "north"
-        #node_state_left.parent = state
         node_state_left.action = "Left"
 
         node_state_right.state = State()
         node_state_right.state.coord = state.coord
         node_state_right.state.direction = "south"
-        #node_state_right.parent = state
         node_state_right.action = "Right"
 
-        node_state_forward.state = State()
-        node_state_forward.state.coord = [state.coord[0] + 53, state.coord[1]]
-        node_state_forward.state.direction = state.direction
-        #node_state_forward.parent = state
-        node_state_forward.action = "Up"
-
-        #return [node_state_left, node_state_right, node_state_forward]
+        if state.coord[0] + STEP < FRAME_WIDTH:
+            node_state_forward.state = State()
+            node_state_forward.state.coord = [state.coord[0] + STEP, state.coord[1]]
+            node_state_forward.state.direction = state.direction
+            node_state_forward.action = "Up"
 
     elif state.direction == "west":
 
         node_state_left.state = State()
         node_state_left.state.coord = state.coord
         node_state_left.state.direction = "south"
-        #node_state_left.parent = state
         node_state_left.action = "Left"
 
         node_state_right.state = State()
         node_state_right.state.coord = state.coord
         node_state_right.state.direction = "north"
-        #node_state_right.parent = state
         node_state_right.action = "Right"
 
-        node_state_forward.state = State()
-        node_state_forward.state.coord = [state.coord[0] - 53, state.coord[1]]
-        node_state_forward.state.direction = state.direction
-        #node_state_forward.parent = state
-        node_state_forward.action = "Up"
-
-        #return [node_state_left, node_state_right, node_state_forward]
+        if state.coord[0] > x_start:
+            node_state_forward.state = State()
+            node_state_forward.state.coord = [state.coord[0] - STEP, state.coord[1]]
+            node_state_forward.state.direction = state.direction
+            node_state_forward.action = "Up"
 
     elif state.direction == "north":
 
         node_state_left.state = State()
         node_state_left.state.coord = state.coord
         node_state_left.state.direction = "west"
-        #node_state_left.parent = state
         node_state_left.action = "Left"
 
         node_state_right.state = State()
         node_state_right.state.coord = state.coord
         node_state_right.state.direction = "east"
-        #node_state_right.parent = state
         node_state_right.action = "Right"
 
-        node_state_forward.state = State()
-        node_state_forward.state.coord = [state.coord[0], state.coord[1] - 53]
-        node_state_forward.state.direction = state.direction
-        #node_state_forward.parent = state
-        node_state_forward.action = "Up"
-
-        #return [node_state_left, node_state_right, node_state_forward]
+        if state.coord[1] > x_start:
+            node_state_forward.state = State()
+            node_state_forward.state.coord = [state.coord[0], state.coord[1] - STEP]
+            node_state_forward.state.direction = state.direction
+            node_state_forward.action = "Up"
 
     elif state.direction == "south":
 
         node_state_left.state = State()
         node_state_left.state.coord = state.coord
         node_state_left.state.direction = "east"
-        #node_state_left.parent = state
         node_state_left.action = "Left"
 
         node_state_right.state = State()
         node_state_right.state.coord = state.coord
         node_state_right.state.direction = "west"
-        #node_state_right.parent = state
         node_state_right.action = "Right"
 
-        node_state_forward.state = State()
-        node_state_forward.state.coord = [state.coord[0], state.coord[1] + 53]
-        node_state_forward.state.direction = state.direction
-        #node_state_forward.parent = state
-        node_state_forward.action = "Up"
+        if state.coord[1] + STEP < FRAME_HEIGHT:
+            node_state_forward.state = State()
+            node_state_forward.state.coord = [state.coord[0], state.coord[1] + STEP]
+            node_state_forward.state.direction = state.direction
+            node_state_forward.action = "Up"
 
-        #return [node_state_left, node_state_right, node_state_forward]
-
-    return [node_state_left, node_state_right, node_state_forward]
+    if len(node_state_forward.state.coord) != 0:
+        return [node_state_left, node_state_right, node_state_forward]
+    else:
+        return [node_state_left, node_state_right]
 
 
-def graphsearch(fringe, explored, start_state, end_state_coord):
+def get_cell_expense(node):
+    global images_coord_list
+    global cell_expense_list
 
+    for i in range(0, len(images_coord_list)):
+        if (images_coord_list[i][0] <= node.state.coord[0] and node.state.coord[0] <= images_coord_list[i][0] + IMAGE_SIZE) and (images_coord_list[i][1] <= node.state.coord[1] and node.state.coord[1] <= images_coord_list[i][1] + IMAGE_SIZE):
+            return cell_expense_list[i]
+
+
+def heurystyka(node_now):
+
+    if node_now.action == "Left" or node_now.action == "Right":
+        return node_now.parent[2] + (get_cell_expense(node_now) / 2)
+    elif node_now.action == "Up":
+        return node_now.parent[2] + (get_cell_expense(node_now) * 2)
+    elif node_now.action == "":
+        return get_cell_expense(node_now)
+
+
+# def graph_search(fringe, explored, start_state, end_state_coord):
+#
+#     node = Node()
+#     node.state = start_state
+#     node.parent = node.state
+#     fringe.append(node)
+#     iterator = 0
+#
+#     end_loop = True
+#     while end_loop:
+#         if len(fringe) == 0:
+#             end_loop = False
+#             #return False
+#
+#         elem = fringe[iterator]
+#
+#         if elem.state.coord == end_state_coord:
+#             return fringe
+#
+#         explored.append(elem)
+#
+#         another_states = successor(elem.state)
+#         for i in range(0, len(another_states)):
+#             n = len(fringe)
+#             for j in range(0, n):
+#                 if another_states[i].state.coord[0] == fringe[j].state.coord[0] and another_states[i].state.coord[1] == fringe[j].state.coord[1]:
+#                     if another_states[i].state.direction == fringe[j].state.direction:
+#                         break
+#                     else:
+#                         states = []
+#                         for k in range(0, len(fringe)):
+#                             new_state = [fringe[k].state.coord, fringe[k].state.direction]
+#                             states.append(new_state)
+#                         now_state = [another_states[i].state.coord, another_states[i].state.direction]
+#                         if now_state in states:
+#                             break
+#
+#                         another_states[i].parent = elem.state
+#                         fringe.append(another_states[i])
+#                 else:
+#                     states = []
+#                     for k in range(0, len(fringe)):
+#                         new_state = [fringe[k].state.coord, fringe[k].state.direction]
+#                         states.append(new_state)
+#                     now_state = [another_states[i].state.coord, another_states[i].state.direction]
+#
+#                     if now_state in states:
+#                         break
+#
+#                     if another_states[i].state.direction == fringe[j].state.direction:
+#                         another_states[i].parent = elem.state
+#                         fringe.append(another_states[i])
+#         iterator += 1
+
+
+def graph_search_A(fringe, explored, start_state, end_state_coord):
     node = Node()
     node.state = start_state
-    node.parent = node.state
-    #node.action = "Right"
+    node.priority = heurystyka(node)
+    node.parent = [node.state.coord, node.state.direction, node.priority]
+
     fringe.append(node)
-    iter = 0
+    iterator = 0
 
-    bool = True
-    while bool:
+    end_loop = True
+    while end_loop:
         if len(fringe) == 0:
-            bool = False
-            #return False
+            end_loop = False
+            # return False
 
-        elem = fringe[iter]
+        elem = fringe[iterator]
 
         if elem.state.coord == end_state_coord:
-            print("Gotowe!")
-            bool = False
             return fringe
 
         explored.append(elem)
 
         another_states = successor(elem.state)
         for i in range(0, len(another_states)):
+            another_states[i].parent = [elem.state.coord, elem.state.direction, elem.priority]
+            p = heurystyka(another_states[i])
+
             n = len(fringe)
             for j in range(0, n):
                 if another_states[i].state.coord[0] == fringe[j].state.coord[0] and another_states[i].state.coord[1] == fringe[j].state.coord[1]:
-                    if another_states[i].state.direction == fringe[j].state.direction:
+                    if another_states[i].state.direction == fringe[j].state.direction and p < fringe[j].priority:
+                        another_states[i].priority = p
+                        fringe[j] = another_states[i]
                         break
                     else:
-                        # states = []
-                        # for k in range(0, len(fringe)):
-                        #     new_state = fringe[k].state
-                        #     states.append(new_state)
-                        # now_state = another_states[i].state
-                        # if now_state in states:
-                        #     break
-
                         states = []
                         for k in range(0, len(fringe)):
                             new_state = [fringe[k].state.coord, fringe[k].state.direction]
                             states.append(new_state)
                         now_state = [another_states[i].state.coord, another_states[i].state.direction]
                         if now_state in states:
+                            index = states.index(now_state)
+                            if p < fringe[index].priority:
+                                another_states[i].priority = p
+                                fringe[index] = another_states[i]
+                                break
+                            else:
+                                break
+
+                        another_states[i].priority = p
+                        fringe.append(another_states[i])
+
+                        n1 = len(fringe)
+
+                        while n1 > 1:
+                            change = False
+                            for l in range(0, n1 - 1):
+                                if fringe[l].priority > fringe[l + 1].priority:
+                                    fringe[l], fringe[l + 1] = fringe[l + 1], fringe[l]
+                                    change = True
+
+                            n1 -= 1
+
+                            if not change:
+                                break
+                else:
+                    states = []
+                    for k in range(0, len(fringe)):
+                        new_state = [fringe[k].state.coord, fringe[k].state.direction]
+                        states.append(new_state)
+                    now_state = [another_states[i].state.coord, another_states[i].state.direction]
+
+                    if now_state in states:
+                        index = states.index(now_state)
+                        if p < fringe[index].priority:
+                            another_states[i].priority = p
+                            fringe[index] = another_states[i]
+                            break
+                        else:
                             break
 
-                        # bool_break = False
-                        # for k in range(0, n):
-                        #     if another_states[i].state.coord[0] == fringe[k].state.coord[0] and another_states[i].state.coord[1] == fringe[k].state.coord[1]:
-                        #         if another_states[i].state.direction == fringe[k].state.direction:
-                        #             bool_break = True
-                        # if bool_break:
-                        #     break
-                        another_states[i].parent = elem.state
-                        fringe.append(another_states[i])
-                else:
-                    if another_states[i] in fringe:
-                        break
                     if another_states[i].state.direction == fringe[j].state.direction:
-                        another_states[i].parent = elem.state
+                        another_states[i].priority = p
                         fringe.append(another_states[i])
-        iter += 1
+
+                        n2 = len(fringe)
+
+                        while n2 > 1:
+                            change = False
+                            for h in range(0, n2 - 1):
+                                if fringe[h].priority > fringe[h + 1].priority:
+                                    fringe[h], fringe[h + 1] = fringe[h + 1], fringe[h]
+                                    change = True
+
+                            n2 -= 1
+
+                            if not change:
+                                break
+        iterator += 1

bin/Classess/Player.py

@@ -1,16 +1,18 @@
-WINDOW_X = 533 + 1200
-WINDOW_Y = 950
-FRAME_WIDTH = 533
-FRAME_HEIGHT = 533
+# WINDOW_X = 533 + 1200
+# WINDOW_Y = 950
+# FRAME_WIDTH = 533
+# FRAME_HEIGHT = 533
+#
+# # Size of small image
+# IMAGE_SIZE = 50
 
-# Size of small image
-IMAGE_SIZE = 50
+from resources.Globals import *
 
 
 class Player(object):
     def __init__(self):
-        self.x_start = 3
-        self.y_start = 3
+        self.x_start = 5
+        self.y_start = 5
         self.current_x = self.x_start
         self.current_y = self.y_start
         self.step = IMAGE_SIZE + self.x_start

bin/Classess/Track.py

@@ -0,0 +1,17 @@
+class Track:
+    def __init__(self, priority, road):
+        self.priority = priority
+        self.road = road
+
+    def __eq__(self, other):
+        try:
+            return self.priority == other.priority
+        except AttributeError:
+            return NotImplemented
+
+    def __lt__(self, other):
+        try:
+            return self.priority < other.priority
+        except AttributeError:
+            return NotImplemented
+

bin/Classess/Travel.py

@@ -0,0 +1,203 @@
+import queue
+from itertools import permutations, islice
+from math import sqrt
+import random
+
+from resources.Globals import NUMBER_OF_INDIVIDUALS_FOR_DUEL, NUMBER_OF_POINTS_PERMUTATION, PERCENT_OF_MUTATION, \
+    PERCENT_OF_OUTGOING_INDIVIDUALS
+
+
+class Travel:
+    def __init__(self):
+        self.points_coord = []
+        self.points_map = {}
+
+
+def genetic_algorithm(travel_map):
+    population = []
+    road_map = list(travel_map.keys())
+    points_permutation = list(map(list, islice(permutations(road_map), NUMBER_OF_POINTS_PERMUTATION)))
+    # Generate the first population
+    for i in range(0, len(points_permutation)):
+        road = points_permutation[i]
+        priority = adaptation_function(points_permutation[i], travel_map)
+
+        population.append((priority, road))
+
+    while len(population) < 10000:
+        parent1, parent2 = tournament_selection(population)
+
+        child = edge_recombination_crossover(parent1[1], parent2[1])
+        child_priority = adaptation_function(child, travel_map)
+
+        population.append((child_priority, child))
+
+        mutation_function(population, travel_map)
+        population.sort(key=lambda x: x[0], reverse=True)
+
+    return population[0]
+
+
+def adaptation_function(list_points, travel_map):
+    index_of_point = 0
+    distance = 0
+    while True:
+
+        if index_of_point < (-len(list_points)):
+            return round((1 / distance) * 1000000)
+
+        if index_of_point == (len(list_points) - 1):
+            x1 = travel_map.get(list_points[index_of_point])[0]
+            y1 = travel_map.get(list_points[index_of_point])[1]
+
+            x2 = travel_map.get(list_points[-len(list_points)])[0]
+            y2 = travel_map.get(list_points[-len(list_points)])[1]
+
+            index_of_point = -len(list_points) - 1
+        else:
+            x1 = travel_map.get(list_points[index_of_point])[0]
+            y1 = travel_map.get(list_points[index_of_point])[1]
+
+            x2 = travel_map.get(list_points[index_of_point + 1])[0]
+            y2 = travel_map.get(list_points[index_of_point + 1])[1]
+
+            index_of_point += 1
+
+        distance += sqrt((x2 - x1) ** 2 + (y2 - y1) ** 2)
+
+
+def tournament_selection(population):
+    individuals_for_duel1 = []
+    individuals_for_duel2 = []
+    population_length = len(population)
+
+    while True:
+
+        if len(individuals_for_duel1) == NUMBER_OF_INDIVIDUALS_FOR_DUEL and len(individuals_for_duel2) == NUMBER_OF_INDIVIDUALS_FOR_DUEL:
+            break
+
+        if len(individuals_for_duel1) != NUMBER_OF_INDIVIDUALS_FOR_DUEL:
+            index1 = random.randint(0, population_length - 1)
+            candidate_for_duel1 = population[index1]
+            if candidate_for_duel1 not in individuals_for_duel1:
+                individuals_for_duel1.append(candidate_for_duel1)
+
+        if len(individuals_for_duel2) != NUMBER_OF_INDIVIDUALS_FOR_DUEL:
+            index2 = random.randint(0, population_length - 1)
+            candidate_for_duel2 = population[index2]
+            if candidate_for_duel2 not in individuals_for_duel1 and candidate_for_duel2 not in individuals_for_duel2:
+                individuals_for_duel2.append(candidate_for_duel2)
+
+    winner_of_duel1 = max(individuals_for_duel1, key=lambda x: x[0])
+    winner_of_duel2 = max(individuals_for_duel2, key=lambda x: x[0])
+
+    return winner_of_duel1, winner_of_duel2
+
+def edge_recombination_crossover(parent1, parent2):
+    dict_of_neighbors = generate_dict_of_neighbors(parent1, parent2)
+
+    gen_index = random.randint(0, len(parent1) - 1)
+    gen = parent1[gen_index]
+    child = []
+    while True:
+
+        child.append(gen)
+
+        if len(child) == len(parent1):
+            return child
+
+        for key in dict_of_neighbors.keys():
+            if gen in dict_of_neighbors[key]:
+                dict_of_neighbors[key].remove(gen)
+
+        if not dict_of_neighbors[gen]:
+            while True:
+                # new_gen = random.randint(parent1[0], parent1[-1])
+                new_gen_index = random.randint(0, len(parent1) - 1)
+                new_gen = parent1[new_gen_index]
+                if new_gen not in child:
+                    break
+        else:
+            new_gen = dict_of_neighbors[gen][0]
+            best_neighbor = len(dict_of_neighbors[new_gen])
+            for neighbor in dict_of_neighbors[gen][1:]:
+                possible_best_neighbor = len(dict_of_neighbors[neighbor])
+                if possible_best_neighbor <= best_neighbor:
+                    best_neighbor = possible_best_neighbor
+                    new_gen = neighbor
+        gen = new_gen
+
+
+def generate_dict_of_neighbors(parent1, parent2):
+    dict_of_neighbors = {}
+    for i in range(0, len(parent1)):
+        list_of_neighbors = []
+        element = parent1[i]
+        if i == 0:
+            left_neighbor1 = parent1[-1]
+            right_neighbor1 = parent1[i + 1]
+        elif i == (len(parent1) - 1):
+            left_neighbor1 = parent1[i - 1]
+            right_neighbor1 = parent1[0]
+        else:
+            left_neighbor1 = parent1[i - 1]
+            right_neighbor1 = parent1[i + 1]
+
+        list_of_neighbors.extend([left_neighbor1, right_neighbor1])
+
+        index = parent2.index(element)
+        if index == 0:
+            left_neighbor2 = parent2[-1]
+            right_neighbor2 = parent2[index + 1]
+        elif index == (len(parent2) - 1):
+            left_neighbor2 = parent2[index - 1]
+            right_neighbor2 = parent2[0]
+        else:
+            left_neighbor2 = parent2[index - 1]
+            right_neighbor2 = parent2[index + 1]
+
+        if left_neighbor2 not in list_of_neighbors:
+            list_of_neighbors.append(left_neighbor2)
+        if right_neighbor2 not in list_of_neighbors:
+            list_of_neighbors.append(right_neighbor2)
+
+        dict_of_neighbors[element] = list_of_neighbors
+
+    return dict_of_neighbors
+
+
+def mutation_function(population, travel_map):
+    mutation_percentage = random.random()
+    if mutation_percentage <= PERCENT_OF_MUTATION:
+        count_individual_for_mutation = round(len(population) * mutation_percentage)
+        mutants = set()
+        for i in range(0, count_individual_for_mutation):
+            while True:
+                individual_for_mutation = random.randint(0, len(population) - 1)
+                if individual_for_mutation not in mutants:
+                    mutants.add(individual_for_mutation)
+                    candidate_mutant = population[individual_for_mutation]
+                    while True:
+                        chromosome1 = random.randint(0, len(candidate_mutant[1]) - 1)
+                        chromosome2 = random.randint(0, len(candidate_mutant[1]) - 1)
+                        if chromosome1 != chromosome2:
+                            candidate_mutant[1][chromosome1], candidate_mutant[1][chromosome2] = candidate_mutant[1][chromosome2], candidate_mutant[1][chromosome1]
+
+                        candidate_mutant_priority = adaptation_function(candidate_mutant[1], travel_map)
+                        mutant = (candidate_mutant_priority, candidate_mutant[1])
+
+                        if mutant not in population:
+                            population[individual_for_mutation] = mutant
+
+                        break
+                    break
+
+
+
+
+
+
+
+
+
+

bin/main/main.py

@@ -1,27 +1,37 @@
 import os
 import random
+import time
 from tkinter import *
 
 from bin.Classess.Field import Field
 from bin.Classess.Mine import Mine
+from bin.Classess.Travel import Travel
 from bin.Classess.Player import Player
 import bin.Classess.Node as nd
+import bin.Classess.Travel as tr
+from resources.Globals import *
 
-WINDOW_X = 533 + 1200
-WINDOW_Y = 950
-FRAME_WIDTH = 533
-FRAME_HEIGHT = 533
-
-# Size of small image
-IMAGE_SIZE = 50
-
-AMOUNT_OF_MINES = 10
+# WINDOW_X = 533 + 1200
+# WINDOW_Y = 950
+# FRAME_WIDTH = 533
+# FRAME_HEIGHT = 533
+#
+# # Size of small image
+# IMAGE_SIZE = 50
+#
+# AMOUNT_OF_MINES = 10
+#
+# DELAY_TIME = 0.5
 
 # Creating objects
 player = Player()
 field = Field()
+travel = Travel()
+
 fringe = []
 explored = []
+action_list = []
+images_coord = []
 
 
 def Arrow(direction):
@@ -40,9 +50,25 @@ def Arrow(direction):
 
 # Putting images
 def Fill(bool):
+    global images_coord
     if bool:
         field.PuttingSmallImages()
 
+        travel.points_coord.append(field.small_field_canvas.coords(field.canvas_small_images[0]))
+        travel.points_coord.extend(field.mines_coord)
+
+        for i in range(0, len(travel.points_coord)):
+            travel.points_map[i + 1] = travel.points_coord[i]
+
+        print(travel.points_map)
+
+
+        for i in range(0, len(field.canvas_small_images)):
+            images_coord.append(field.small_field_canvas.coords(field.canvas_small_images[i]))
+        # print("Coords List: ", images_coord)
+
+        nd.init_data(images_coord, field.cell_expense)
+
     # Drawing red/green rectangles
     for el in field.state_of_cell_array:
         if el[0] != 0:
@@ -58,7 +84,7 @@ def DrawingLargeImage():
     field.PuttingLargeImage(large_img_name)
 
 
-def Next_direction(side):
+def NextDirection(action):
     # Define next direction
     current_direction = player.direction
     t = -1
@@ -68,9 +94,9 @@ def Next_direction(side):
             break
 
     # Write next direction to Player
-    if side == "Right":
+    if action == "Right":
         player.direction = player.directions[(t + 1) % 4]
-    elif side == "Left":
+    elif action == "Left":
         player.direction = player.directions[(t - 1) % 4]
 
     return player.direction
@@ -87,31 +113,26 @@ def MovingForward():
         field.small_field_canvas.move(player.image_canvas_id, 0, player.step)
 
 
-def Moving(event):
+def Moving(action):
     # Moving
-    if event.keysym == "Right":
+    if action == "Right":
         # player.MovingRight()
         field.Moving()
         Fill(False)
-        next_direction = Next_direction(event.keysym)
+        next_direction = NextDirection(action)
         Arrow(next_direction)
-    elif event.keysym == "Left":
+    elif action == "Left":
         # player.MovingLeft()
         field.Moving()
         Fill(False)
-        next_direction = Next_direction(event.keysym)
+        next_direction = NextDirection(action)
         Arrow(next_direction)
-    elif event.keysym == "Up":
+    elif action == "Up":
         player.Moving()
         field.Moving()
         Fill(False)
         MovingForward()
         Arrow(player.direction)
-    # elif event.keysym == "space":
-    #     player.MovingDown()
-    #     field.Moving()
-    #     Fill()
-    #     Arrow(player.arrow_south_image)
 
 
 def ImagesInArray(directory, array):
@@ -135,11 +156,15 @@ def ImagesInArray(directory, array):
                 if column == 10:
                     column = 0
                     row += 1
+                if row == 10:
+                    break
 
         column += 1
         if column == 10:
             column = 0
             row += 1
+        if row == 10:
+            break
 
 
 def CellDesignation(array, color):
@@ -151,67 +176,151 @@ def CellDesignation(array, color):
             break
 
 
-def Action(event):
-    if event.keysym in ["Right", "Left", "Up", "space"]:
-        Moving(event)
-    elif event.keysym in ["1", "2"]:
-        if event.keysym == "1":
+def Action(action):
+    if action in ["Right", "Left", "Up", "space"]:
+        Moving(action)
+    elif action in ["1", "2"]:
+        if action == "1":
             CellDesignation(field.state_of_cell_array, "red")
         else:
             CellDesignation(field.state_of_cell_array, "green")
 
 
 # Modified by Artem to search in the status area
-def MouseClickEvent(event):
+def create_action_list(states, index):
     global fringe
-    #print(len(field.canvas_small_images), field.canvas_small_images)
-    for i in range(0, len(field.canvas_small_images)):
-        print(field.small_field_canvas.coords(field.canvas_small_images[i]))
-    #print("Lewy przycisk myszy zostal nacisniety!")
-    #node = nd.Node()
-    #print(node.state.coord, node.state.direction, node.action, node.parent)
-    #node.state = nd.State()
-    #node.state.coord = field.small_field_canvas.coords(player.image_canvas_id)
-    #node.state.direction = "east"
-    #node.state.coord = field.small_field_canvas.coords(field.canvas_small_images[5])
+    global action_list
 
-    start_position = field.small_field_canvas.coords(player.image_canvas_id)
-    end_state_coord = []
-    print("Pierwsza pozycja: {} {}".format(start_position[0], start_position[1]))
+    if index == 0:
+        action_list.reverse()
+        return True
+    action_list.append(fringe[index].action)
+    state_parent = [fringe[index].parent[0], fringe[index].parent[1]]
+    create_action_list(states, states.index(state_parent))
 
 
-    #print(node.state.coord, node.state.direction, node.parent, node.action)
-    #print("Pozycje myszy: {} {}".format(event.x, event.y))
+def MouseClickEvent(track):
+    global fringe
+    global explored
+    global action_list
 
-    for i in range(0, len(field.canvas_small_images)):
-        img_coords = field.small_field_canvas.coords(field.canvas_small_images[i])
-        if (img_coords[0] <= event.x and event.x <= img_coords[0] + IMAGE_SIZE) and (img_coords[1] <= event.y and event.y <= img_coords[1] + IMAGE_SIZE):
-            end_state_coord = img_coords
-    if len(end_state_coord) == 2:
-        print("Koncowa pozycja: {} {}".format(end_state_coord[0], end_state_coord[1]))
+    print("The best individual is: {} {}".format(track[1], track[0]))
+    for point in range(0, len(track[1]) + 1):
+        start_position = field.small_field_canvas.coords(player.image_canvas_id)
+        if point == len(track[1]):
+            end_position = travel.points_map[1]
+        else:
+            end_position = travel.points_map[track[1][point]]
 
-    node = nd.Node()
-    if len(fringe) == 0:
-        node.state.coord = field.small_field_canvas.coords(player.image_canvas_id)
-        node.state.direction = "east"
-        print("Pierwszy state - OK")
-    else:
-        node = fringe[len(fringe) - 1]
-        print("Pozostale states - OK")
-        
-    fringe.clear()
-    print("\nLIST IS EMPTY: {}\n".format(fringe))
-    explored.clear()
-    print("Czyszczenie list - OK")
+        node = nd.Node()
+        if len(fringe) == 0:
+            node.state.coord = start_position
+            node.state.direction = "east"
+        else:
+            states = []
+            for k in range(0, len(fringe)):
+                new_state = fringe[k].state.coord
+                states.append(new_state)
+            start_node = fringe[-1]
 
-    # Successor - only east
-    fringe = nd.graphsearch(fringe, explored, node.state, end_state_coord)
-    print("Fringe - OK")
-    #print(fringe)
+            node.state.coord = start_node.state.coord
+            node.state.direction = start_node.state.direction
 
-    print("{}".format(fringe))
-    for i in range(0, len(fringe)):
-        print('Node{} = State: {} {}, Parent: {} {}, Action: {}'.format(i + 1, fringe[i].state.coord, fringe[i].state.direction, fringe[i].parent.coord, fringe[i].parent.direction, fringe[i].action))
+        fringe.clear()
+        explored.clear()
+        action_list.clear()
+        fringe = nd.graph_search_A(fringe, explored, node.state, end_position)
+        # fringe = nd.graph_search(fringe, explored, node.state, end_position)
+
+        states = []
+        goal_all = []
+        for i in range(0, len(fringe)):
+            new_state = [fringe[i].state.coord, fringe[i].state.direction]
+            states.append(new_state)
+            if end_position[0] == fringe[i].state.coord[0] and end_position[1] == fringe[i].state.coord[1]:
+                goal_all.append(fringe[i])
+
+        elem_min = goal_all[0]
+        for i in range(1, len(goal_all)):
+            if elem_min.priority > goal_all[i].priority:
+                elem_min = goal_all[i]
+        index = fringe.index(elem_min)
+        fringe = fringe[:index + 1]
+
+        create_action_list(states, -1)
+
+        # for i in range(0, len(fringe)):
+        #     print('Node{} = State: {} {}, Parent: {} {} {}, Action: {}'.format(i + 1, fringe[i].state.coord, fringe[i].state.direction, fringe[i].parent[0], fringe[i].parent[1], fringe[i].parent[2], fringe[i].action))
+
+        # print(action_list)
+
+        # Start moving
+        AutoMove()
+        DrawFlag()
+
+        time.sleep(SLEEP_AFTER_CHECK_MINE)
+
+
+    # start_position = field.small_field_canvas.coords(player.image_canvas_id)
+    # end_position = []
+    #
+    # # print("Pierwsza pozycja: {} {}".format(start_position[0], start_position[1]))
+    #
+    # for i in range(0, len(field.canvas_small_images)):
+    #     img_coords = field.small_field_canvas.coords(field.canvas_small_images[i])
+    #     if (img_coords[0] <= event.x and event.x <= img_coords[0] + IMAGE_SIZE) and (img_coords[1] <= event.y and event.y <= img_coords[1] + IMAGE_SIZE):
+    #         end_position = img_coords
+    #         print("Color cost: ", field.cell_expense[i])
+    #
+    # # if len(end_position) == 2:
+    # #     print("Koncowa pozycja: {} {}".format(end_position[0], end_position[1]))
+    #
+    # node = nd.Node()
+    # if len(fringe) == 0:
+    #     node.state.coord = start_position
+    #     node.state.direction = "east"
+    # else:
+    #     states = []
+    #     for k in range(0, len(fringe)):
+    #         new_state = fringe[k].state.coord
+    #         states.append(new_state)
+    #     start_node = fringe[-1]
+    #
+    #     node.state.coord = start_node.state.coord
+    #     node.state.direction = start_node.state.direction
+    #
+    # fringe.clear()
+    # explored.clear()
+    # action_list.clear()
+    # fringe = nd.graph_search_A(fringe, explored, node.state, end_position)
+    # # fringe = nd.graph_search(fringe, explored, node.state, end_position)
+    #
+    # states = []
+    # goal_all = []
+    # for i in range(0, len(fringe)):
+    #     new_state = [fringe[i].state.coord, fringe[i].state.direction]
+    #     states.append(new_state)
+    #     if end_position[0] == fringe[i].state.coord[0] and end_position[1] == fringe[i].state.coord[1]:
+    #         goal_all.append(fringe[i])
+    #
+    # elem_min = goal_all[0]
+    # for i in range(1, len(goal_all)):
+    #     if elem_min.priority > goal_all[i].priority:
+    #         elem_min = goal_all[i]
+    # index = fringe.index(elem_min)
+    # fringe = fringe[:index + 1]
+    #
+    # create_action_list(states, -1)
+    #
+    # # for i in range(0, len(fringe)):
+    # #     print('Node{} = State: {} {}, Parent: {} {} {}, Action: {}'.format(i + 1, fringe[i].state.coord, fringe[i].state.direction, fringe[i].parent[0], fringe[i].parent[1], fringe[i].parent[2], fringe[i].action))
+    #
+    # print(action_list)
+    #
+    #
+    #
+    # # Start moving
+    # AutoMove()
 
 
 def PutMines(mines_array):
@@ -227,15 +336,18 @@ def PutMines(mines_array):
             if mine.array_x == x and mine.array_y == y:
                 is_equal = True
         if not is_equal:
-            mine = Mine(x, y)
-            mines_array.append(mine)
+            if x == 0 and y == 0:
+                continue
+            else:
+                mine = Mine(x, y)
+                mines_array.append(mine)
 
-            field.field_state_array[x][y] = True
+                field.field_state_array[x][y] = True
 
-            counter += 1
+                counter += 1
 
 
-def MinesInArrays(mines_array, directory, imgs_array):
+def MinesInArrays(mines_array, directory, imgs_array, bool_mines_coord):
     counter = 0
 
     temp_array = []
@@ -274,6 +386,99 @@ def MinesInArrays(mines_array, directory, imgs_array):
             # Add images in image array
             imgs_array[mines_array[i].array_x][mines_array[i].array_y] = temp_array[i]
 
+    if bool_mines_coord:
+        for i in range(len(mines_array)):
+            field.mines_coord.append([mines_array[i].array_x, mines_array[i].array_y])
+
+
+def DrawFlag():
+    field.small_field_canvas.create_image(player.current_x, player.current_y, anchor=NW, image=field.flag_img)
+
+
+# def IsItMine():
+#     visited = 0     # 0 - not mine; 1 - on this mine for the first time; 2 - already been on this mine
+#
+#     # Checks if the player is on the mine
+#     for i in field.mines_coord:
+#         if i[0] == player.current_x and i[1] == player.current_y:
+#             visited = 1
+#             # Checks if the player has already been on this mine
+#             for y in field.visited_mines:
+#                 if y[0] == player.current_x and y[1] == player.current_y:
+#                     visited = 2
+#         if visited == 1:
+#             DrawFlag()
+
+
+def AutoMove():
+    for action in action_list:
+        # Program wait for better illustration
+        time.sleep(DELAY_TIME)
+        # Move once
+        Action(action)
+        # Check if player on mine and if yes, draw flag
+        # IsItMine()
+        # Update main window
+        field.win.update()
+
+
+# Draws rectangles that indicate type of cells
+def DrawRectangle():
+    x = 4
+    y = 4
+
+    color = None
+    # Chose color for rectangle
+    for i in range(len(field.cell_expense)):
+        if field.cell_expense[i] == standard_cell_cost:
+            color = "None"
+        elif field.cell_expense[i] == sand_cell_cost:
+            color = "yellow"
+        elif field.cell_expense[i] == water_cell_cost:
+            color = "dodger blue"
+        elif field.cell_expense[i] == swamp_cell_cost:
+            color = "green4"
+        if color != "None":
+            field.small_field_canvas.create_rectangle(x, y, x + IMAGE_SIZE + 2, y + IMAGE_SIZE + 2, width=2, outline=color)
+        x += player.step
+        if x + IMAGE_SIZE + 2 > field.width:
+            x = 4
+            y += player.step
+
+
+
+
+def AddCostCellsToArray(amount, cost):
+    counter = 0
+    while counter < amount:
+        r = random.randint(0, 99)
+        if field.cell_expense[r] == 0:
+            field.cell_expense[r] = cost
+            counter += 1
+
+
+def CostingOfCells():
+    AddCostCellsToArray(amount_of_sand_cells, sand_cell_cost)
+    AddCostCellsToArray(amount_of_water_cells, water_cell_cost)
+    AddCostCellsToArray(amount_of_swamp_cells, swamp_cell_cost)
+    AddCostCellsToArray(field.rows * field.columns - (amount_of_sand_cells + amount_of_water_cells + amount_of_swamp_cells), standard_cell_cost)
+
+    # Draw rectangles
+    DrawRectangle()
+
+
+def click_button():
+    btn.destroy()
+    label = Label(field.win, text="Wait... AI conquers the world!", fg='black')
+    label.place(x=50, y=570)
+    field.win.update()
+    track = tr.genetic_algorithm(travel.points_map)
+
+    track[1].remove(1)
+    label.config(text=track[1])
+    field.win.update()
+    MouseClickEvent(track)
+
 
 def main():
     # Creating the main window of an application
@@ -281,14 +486,27 @@ def main():
     field.win.title("Sapper")
     field.win.configure(bg='gray')
     field.win.geometry(win_size)
+    print(f'Amount of mines: {AMOUNT_OF_MINES}')
+    global btn
+    btn = Button(field.win,
+                 text="Search for mines",  # текст кнопки
+                 background="#555",  # фоновый цвет кнопки
+                 foreground="#ccc",  # цвет текста
+                 padx="20",  # отступ от границ до содержимого по горизонтали
+                 pady="8",  # отступ от границ до содержимого по вертикали
+                 font="24",  # высота шрифта
+                 command=click_button
+                 )
+
+    btn.place(x=50, y=570)
 
     # Create array with mines objects
     mines_array = []
     # Put mines on coordinates
     PutMines(mines_array)
 
-    MinesInArrays(mines_array, "../../files/small_mines_images", field.small_image_array)
-    MinesInArrays(mines_array, "../../files/large_mines_images", field.large_image_array)
+    MinesInArrays(mines_array, "../../files/small_mines_images", field.small_image_array, True)
+    MinesInArrays(mines_array, "../../files/large_mines_images", field.large_image_array, False)
 
     # Filling image arrays
     small_directory = "../../files/small_images"
@@ -296,6 +514,8 @@ def main():
     large_directory = "../../files/large_images"
     ImagesInArray(large_directory, field.large_image_array)
 
+    CostingOfCells()
+
     # Add arrow image to Player class
     images = []
     for file in os.listdir("../../files/arrow"):
@@ -318,8 +538,8 @@ def main():
     # Rectangle(True, "None")
     # Rectangle()
     # Binding keyboard press to function
-    field.win.bind("<Key>", Action)
-    field.small_field_canvas.bind("<Button-1>", MouseClickEvent)
+    # field.win.bind("<Key>", Action)
+    # field.small_field_canvas.bind("<Button-1>", MouseClickEvent)
     # Starting mainloop for window
     field.win.mainloop()
 

resources/Globals.py

@@ -0,0 +1,38 @@
+import random
+
+FRAME_WIDTH = 555
+FRAME_HEIGHT = 555
+
+WINDOW_X = FRAME_WIDTH + 1200
+WINDOW_Y = 950
+
+# Size of small image
+IMAGE_SIZE = 50
+
+MIN_AMOUNT_OF_MINES = 6
+MAX_AMOUNT_OF_MINES = 11
+AMOUNT_OF_MINES = random.randint(MIN_AMOUNT_OF_MINES, MAX_AMOUNT_OF_MINES)
+
+DELAY_TIME = 0.2
+
+STEP = IMAGE_SIZE + 5
+
+standard_cell_cost = 10
+
+amount_of_sand_cells = 10
+sand_cell_cost = 20
+
+amount_of_water_cells = 10
+water_cell_cost = 40
+
+amount_of_swamp_cells = 10
+swamp_cell_cost = 80
+
+x_start = 5
+y_start = 5
+
+NUMBER_OF_INDIVIDUALS_FOR_DUEL = 4
+NUMBER_OF_POINTS_PERMUTATION = 10
+PERCENT_OF_MUTATION = 0.01
+PERCENT_OF_OUTGOING_INDIVIDUALS = 0.03
+SLEEP_AFTER_CHECK_MINE = 1