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merge into: s481825:refactor
Branches Tags
s481825:master
s481825:genetic_algorithms
s481825:final_show
s481825:genetic2
s481825:refactor
s481825:neural_network
s481825:neural_network_two_crops
s481825:tree
s481825:tree_tractor_move
s481825:astar_temp
s481825:algorytm_astar1
s481825:losowanie_celu
s481825:astar
s481825:introduction_astar
s481825:BFS
s481825:snake_move
s481825:algorytm_bfs2
s481825:ruch_traktora_po_bfs
s481825:algorytm_bfs
s481825:ruch_traktor_bfs
s481825:ram
s481825:srodek_akcja
s481825:traktor_osprzet
s481825:roslina&stan
s481825:cleaning
s481825:elastyczna_krata
s481825:ruch_traktora
s481825:zarzadzanie_slotami
s481825:srodowisko_wykonania
...
pull from: s481825:master
Branches Tags
s481825:master
s481825:genetic_algorithms
s481825:final_show
s481825:genetic2
s481825:refactor
s481825:neural_network
s481825:neural_network_two_crops
s481825:tree
s481825:tree_tractor_move
s481825:astar_temp
s481825:algorytm_astar1
s481825:losowanie_celu
s481825:astar
s481825:introduction_astar
s481825:BFS
s481825:snake_move
s481825:algorytm_bfs2
s481825:ruch_traktora_po_bfs
s481825:algorytm_bfs
s481825:ruch_traktor_bfs
s481825:ram
s481825:srodek_akcja
s481825:traktor_osprzet
s481825:roslina&stan
s481825:cleaning
s481825:elastyczna_krata
s481825:ruch_traktora
s481825:zarzadzanie_slotami
s481825:srodowisko_wykonania

11 Commits
refactor ... master

Author SHA1 Message Date
s481825
366716a32b Merge pull request 'Merge master with genetic_algorithms branch' (#29) from genetic_algorithms into master 
Reviewed-on: #29
 2024-06-09 18:40:57 +02:00
s481825
99c709d271 Merge pull request 'Merge genetic_algorithms with final_show branch' (#28) from final_show into genetic_algorithms 
Reviewed-on: #28
 2024-06-09 18:40:24 +02:00
s481825
b78f7f5ee7 Merge pull request 'Merge genetic2 to final_show' (#27) from genetic2 into final_show 
Reviewed-on: #27
 2024-06-09 18:39:27 +02:00
jakzar
eb2529831a This: -added goaltressure in bfs3 call in App.py -changed def value for randomGT in BFS3 in bfs.py -added more context to readme.txt 2024-06-09 18:33:50 +02:00
Mateusz Czajka
d61b585827 Corrected GeneticAlgorithm2 and made a GeneticAlgorithm3 and generated fields using them. Made GeneticAccuracy to check the performance of the algorithms. 2024-06-08 23:25:08 +02:00
Paulina Smierzchalska
6c86eebd89 genetic algorithm 2 with a value of None 2024-06-07 18:41:55 +02:00
jakzar
da1bfe1d8f This: -changed readme.txt 2024-06-07 15:29:26 +02:00
jakzar
4339284c4b This: -changed label for decision -changed goaltressure for BFS3 2024-06-07 15:01:15 +02:00
tafit0902
51a5b13669 ladowanie pola z pliku GA, rozpoznawanie zdjec na polu, decyzja o podlaniu 2024-06-07 00:02:36 +02:00
Mateusz Czajka
0becd1b1f6 Made genetic algorithm and made a field using it. 2024-06-06 08:35:36 +02:00
s481834
eb9744f52f Merge pull request 'refactor' (#26) from refactor into master 
Reviewed-on: #26
 2024-06-04 13:25:07 +02:00
16 changed files with 1671 additions and 15 deletions
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25
App.py
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@ -10,6 +10,7 @@ import Ui
import BFS
import AStar
import neuralnetwork
import json
bfs1_flag=False
@ -20,8 +21,9 @@ Astar2 = False
if bfs3_flag or Astar or Astar2:
Pole.stoneFlag = True
TreeFlag=False
nnFlag=True
nnFlag=False
newModel=False
finalFlag = True
pygame.init()
show_console=True
@ -43,7 +45,15 @@ def init_demo(): #Demo purpose
old_info=""
traktor.draw_tractor()
time.sleep(2)
pole.randomize_colors(nnFlag)
if not finalFlag:
pole.randomize_colors(nnFlag)
else:
population = 120
iterat = 2500
roulette = True
with open(f'pole_pop{population}_iter{iterat}_{roulette}.json', 'r') as file:
garden_data = json.load(file)
pole.setPlantsByList(garden_data)
traktor.draw_tractor()
start_flag=True
while True:
@ -75,7 +85,7 @@ def init_demo(): #Demo purpose
print_to_console("Traktor porusza sie obliczona sciezka BFS")
traktor.move_by_root(bfsRoot2, pole, [traktor.irrigateSlot])
if(bfs3_flag):
bfsRoot3 = BFS.BFS3({'x': 0, 'y': 0, 'direction': "E"})
bfsRoot3 = BFS.BFS3({'x': 0, 'y': 0, 'direction': "E"},goalTreasure)
#displayControler: NUM_X: 20, NUM_Y: 12 (skarb) CHANGE THIS IN DCON BY HAND!!!!!!!!
bfsRoot3.reverse()
print_to_console("Traktor porusza sie obliczona sciezka BFS")
@ -128,11 +138,16 @@ def init_demo(): #Demo purpose
print_to_console("sieć nuronowa nauczona")
print('model został wygenerowany')
else:
model = neuralnetwork.loadModel('model.pth')
model = neuralnetwork.loadModel('model_500_hidden.pth')
print_to_console("model został załądowny")
testset = neuralnetwork.getDataset(False)
print(neuralnetwork.accuracy(model, testset))
traktor.snake_move_predict_plant(pole, model)
traktor.snake_move_predict_plant(pole, model, headers=['Coords','Real plant','Predicted plant','Result','Fertilizer'], actions=[traktor.fertilize_slot])
if(finalFlag):
pass
model = neuralnetwork.loadModel('model_500_hidden.pth')
Tractor.drzewo.treeLearn()
traktor.snake_move_predict_plant(pole, model, headers=['Coords','Real plant','Predicted plant','Result','Water decision'], actions=[traktor.irigate_slot_NN])
start_flag=False
# demo_move()
old_info=get_info(old_info)

8
BFS.py
View File

@ -133,8 +133,12 @@ def check3(tab, state):
return True
def BFS3(istate):
goalTreassuere = (random.randint(0,NUM_X-1), random.randint(0,NUM_Y-1))
def BFS3(istate,GT):
randomGT=False
if(randomGT==True):
goalTreassuere = (random.randint(0,NUM_X-1), random.randint(0,NUM_Y-1))
else:
goalTreassuere=GT
print(goalTreassuere)
fringe = []
explored = []

2
Drzewo.py
View File

@ -8,7 +8,7 @@ class Drzewo:
self.tree=self.treeLearn()
def treeLearn(self):
csvdata=pandas.read_csv('Data/dataTree.csv')
csvdata=pandas.read_csv('Data/dataTree2.csv')
#csvdata = pandas.read_csv('Data/dataTree2.csv')
x=csvdata[atributes]
decision=csvdata['action']

139
GeneticAccuracy.py Normal file
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@ -0,0 +1,139 @@
import json
import random
from displayControler import NUM_Y, NUM_X
iterat = 2500
population = 120
roulette = True
plants = ['corn', 'potato', 'tomato', 'carrot']
initial_yields = {'corn': 38, 'potato': 40, 'tomato': 43, 'carrot': 45}
yield_reduction = {
'corn': {'corn': -4.5, 'potato': -3, 'tomato': -7, 'carrot': -7},
'potato': {'corn': -7, 'potato': -5, 'tomato': -10, 'carrot': -6},
'tomato': {'corn': -4, 'potato': -5, 'tomato': -7, 'carrot': -7},
'carrot': {'corn': -11, 'potato': -5, 'tomato': -4, 'carrot': -7}
}
yield_reduction2 = {
'corn': {'corn': None, 'potato': -4, 'tomato': -2, 'carrot': -4},
'potato': {'corn': None, 'potato': -5, 'tomato': -5, 'carrot': -2},
'tomato': {'corn': -5, 'potato': -3, 'tomato': -7, 'carrot': None},
'carrot': {'corn': -3, 'potato': -6, 'tomato': -4, 'carrot': -9}
}
yield_multiplier = {'corn': 1.25, 'potato': 1.17, 'tomato': 1.22, 'carrot': 1.13}
yield_multiplier2 = {'corn': 1.25, 'potato': 1.19, 'tomato': 1.22, 'carrot': 1.15}
def calculate_yields(garden):
rows = len(garden)
cols = len(garden[0])
total_yields = 0
for i in range(rows):
for j in range(cols):
plant = garden[i][j]
yield_count = initial_yields[plant]
# Sprawdzanie sąsiadów
neighbors = [
(i - 1, j), (i + 1, j), (i, j - 1), (i, j + 1)
]
for ni, nj in neighbors:
if 0 <= ni < rows and 0 <= nj < cols:
neighbor_plant = garden[ni][nj]
yield_count += yield_reduction[plant][neighbor_plant]
yield_count *= yield_multiplier[plant]
total_yields += yield_count
return total_yields
def calculate_yields2(garden):
rows = len(garden)
cols = len(garden[0])
total_yields = 0
for i in range(rows):
for j in range(cols):
plant = garden[i][j]
yield_count = initial_yields[plant]
# Sprawdzanie sąsiadów
neighbors = [
(i - 1, j), (i + 1, j), (i, j - 1), (i, j + 1)
]
neighbor_flag = False
for ni, nj in neighbors:
if 0 <= ni < rows and 0 <= nj < cols:
neighbor_plant = garden[ni][nj]
if yield_reduction2[plant][neighbor_plant] is not None: # jeśli jest wartość None to plony dla tej rośliny będą wyzerowane
yield_count += yield_reduction2[plant][neighbor_plant]
else:
neighbor_flag = True
if not neighbor_flag:
yield_count *= yield_multiplier2[plant]
total_yields += yield_count
return total_yields
def generate_garden(rows=20, cols=12):
return [[random.choice(plants) for _ in range(cols)] for _ in range(rows)]
def generate_garden_with_yields(t, rows=NUM_Y, cols=NUM_X):
garden = generate_garden(rows, cols)
if t == 1:
total_yields = calculate_yields(garden)
else:
total_yields = calculate_yields2(garden)
return [garden, total_yields]
def generate():
s1 = 0
s2 = 0
n = 150
for i in range(n):
x = generate_garden_with_yields(1)
s1 += x[1]
y = generate_garden_with_yields(2)
s2 += y[1]
return [s1/n, s2/n]
data = generate()
# print(data)
# Odczyt z pliku
with open(f'pole_pop{population}_iter{iterat}_{roulette}.json', 'r') as file:
garden_data = json.load(file)
# print("Odczytane dane ogrodu:")
# for row in garden_data:
# print(row)
print("Wygenerowane przy pomocy GA: ", calculate_yields(garden_data))
print(f"Przeciętny ogród wygenerowany randomowo ma {data[0]} plonów")
print("Uśredniony przyrost plonów (ile razy więcej plonów): ", calculate_yields(garden_data)/data[0])
# Odczyt z pliku
with open(f'pole2_pop{population}_iter{iterat}_{roulette}.json', 'r') as file:
garden_data2 = json.load(file)
# print("Odczytane dane ogrodu:")
# for row in garden_data2:
# print(row)
print("Wygenerowane: przy pomocy GA2", calculate_yields2(garden_data2))
print(f"Przeciętny ogród wygenerowany randomowo ma {data[1]} plonów")
print("Uśredniony przyrost plonów (ile razy więcej plonów): ", calculate_yields2(garden_data2)/data[1])

208
GeneticAlgorithm.py Normal file
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@ -0,0 +1,208 @@
import copy
import json
import random
from displayControler import NUM_X, NUM_Y
# Definiowanie stałych dla roślin i plonów
plants = ['corn', 'potato', 'tomato', 'carrot']
initial_yields = {'corn': 38, 'potato': 40, 'tomato': 43, 'carrot': 45}
yield_reduction = {
'corn': {'corn': -4.5, 'potato': -3, 'tomato': -7, 'carrot': -7},
'potato': {'corn': -7, 'potato': -5, 'tomato': -10, 'carrot': -6},
'tomato': {'corn': -4, 'potato': -5, 'tomato': -7, 'carrot': -7},
'carrot': {'corn': -11, 'potato': -5, 'tomato': -4, 'carrot': -7}
}
yield_multiplier = {'corn': 1.25, 'potato': 1.17, 'tomato': 1.22, 'carrot': 1.13}
# Generowanie listy 20x12 z losowo rozmieszczonymi roślinami
def generate_garden(rows=20, cols=12):
return [[random.choice(plants) for _ in range(cols)] for _ in range(rows)]
# Funkcja do obliczania liczby plonów
def calculate_yields(garden):
rows = len(garden)
cols = len(garden[0])
total_yields = 0
for i in range(rows):
for j in range(cols):
plant = garden[i][j]
yield_count = initial_yields[plant]
# Sprawdzanie sąsiadów
neighbors = [
(i - 1, j), (i + 1, j), (i, j - 1), (i, j + 1)
]
for ni, nj in neighbors:
if 0 <= ni < rows and 0 <= nj < cols:
neighbor_plant = garden[ni][nj]
yield_count += yield_reduction[plant][neighbor_plant]
yield_count *= yield_multiplier[plant]
total_yields += yield_count
return total_yields
# Funkcja do generowania planszy/ogrodu i zapisywania go jako lista z liczbą plonów
def generate_garden_with_yields(rows=NUM_Y, cols=NUM_X):
garden = generate_garden(rows, cols)
total_yields = calculate_yields(garden)
return [garden, total_yields]
# Funkcja do generowania linii cięcia i zapisywania jej jako liczba roślin w kolumnie z pierwszej planszy/ogrodu
def line():
path = []
flag = False
x = random.randint(4, 8)
position = (0, x)
path.append(position)
while not flag: # wybór punktu dopóki nie wybierze się skrajnego
# prawdopodobieństwo "ruchu" -> 0.6: w prawo, 0.2: w góre, 0.2: w dół
p = [(position[0] + 1, position[1]), (position[0], position[1] + 1), (position[0], position[1] - 1)]
w = [0.6, 0.2, 0.2]
position2 = random.choices(p, w)[0]
if position2 not in path: # sprawdzenie czy dany punkt nie był już wybrany aby nie zapętlać się
path.append(position2)
position = position2
if position[0] == NUM_X or position[1] == 0 or position[1] == NUM_Y: # sprawdzenie czy osiągnięto skrajny punkt
flag = True
info = [] # przeformatowanie sposobu zapisu na liczbę roślin w kolumnie, które będzię się dzidziczyło z pierwszej planszy/ogrodu
for i in range(len(path) - 1):
if path[i + 1][0] - path[i][0] == 1:
info.append(NUM_Y - path[i][1])
if len(info) < NUM_X: # uzupełnienie informacji o dziedziczeniu z planszy/ogrodu
if path[-1:][0][1] == 0:
x = NUM_Y
else:
x = 0
while len(info) < NUM_X:
info.append(x)
# return path, info
return info
# Funkcja do generowania potomstwa
def divide_gardens(garden1, garden2):
info = line()
new_garden1 = [[] for _ in range(NUM_Y)]
new_garden2 = [[] for _ in range(NUM_Y)]
for i in range(NUM_X):
for j in range(NUM_Y):
# do utworzonych kolumn w nowych planszach/ogrodach dodajemy dziedziczone rośliny
if j < info[i]:
new_garden1[j].append(garden1[j][i])
new_garden2[j].append(garden2[j][i])
else:
new_garden1[j].append(garden2[j][i])
new_garden2[j].append(garden1[j][i])
return [new_garden1, calculate_yields(new_garden1)], [new_garden2, calculate_yields(new_garden2)]
# Funkcja do mutacji danej planszy/ogrodu
def mutation(garden, not_used):
new_garden = copy.deepcopy(garden)
for i in range(NUM_X):
x = random.randint(0, 11) # wybieramy, w którym wierszu w i-tej kolumnie zmieniamy roślinę na inną
other_plants = [plant for plant in plants if plant != new_garden[x][i]]
new_garden[x][i] = random.choice(other_plants)
return [new_garden, calculate_yields(new_garden)]
# Funkcja do generowania pierwszego pokolenia
def generate(n):
generation = []
for i in range(n * 3):
generation.append(generate_garden_with_yields())
generation.sort(reverse=True, key=lambda x: x[1])
return generation[:n]
# Funkcja do implementacji ruletki (sposobu wyboru) - sumuje wszystkie plony generacji
def sum_yields(x):
s = 0
for i in range(len(x)):
s += x[i][1]
return s
if __name__ == '__main__':
roulette = True
attemps = 150
iterat = 2500
population = 120
best = []
for a in range(attemps):
generation = generate(population)
print(generation[0][1])
for i in range(iterat): # ile iteracji - nowych pokoleń
print(a, i)
new_generation = generation[:(population // 7)] # dziedziczenie x najlepszych osobników
j = 0
while j < (
population - (
population // 7)): # dobór reszty osobników do pełnej liczby populacji danego pokolenia
if roulette: # zasada ruletki -> "2 rzuty kulką"
s = sum_yields(generation) # suma wszystkich plnów całego pokolenia
z = []
if s == 0: # wtedy każdy osobnik ma takie same szanse
z.append(random.randint(0, population - 1))
z.append(random.randint(0, population - 1))
else:
weights = [] # wagi prawdopodobieństwa dla każdego osobnika generacji
pos = [] # numery od 0 do 49 odpowiadające numerom osobnikom w generacji
for i in range(population):
weights.append(generation[i][1] / s)
pos.append(i)
z.append(random.choices(pos, weights)[0]) # wybranie osobnika według wag prawdopodobieństwa
z.append(random.choices(pos, weights)[0]) # wybranie osobnika według wag prawdopodobieństwa
else: # metoda rankingu
z = random.sample(range(0, int(population // 1.7)), 2)
# krzyzowanie 90% szans, mutacja 10% szans
function = [divide_gardens, mutation]
weight = [0.9, 0.1]
fun = random.choices(function, weight)[0]
h = fun(generation[z[0]][0], generation[z[1]][0])
if len(h[0]) == 2:
new_generation.append(h[0])
new_generation.append(h[1])
j += 2
else:
new_generation.append(h)
j += 1
new_generation.sort(reverse=True, key=lambda x: x[1]) # sortowanie malejąco listy według wartości plonów
generation = new_generation[:population]
best.append(generation[0])
best.sort(reverse=True, key=lambda x: x[1])
# Zapis do pliku
# for i in range(len(best)):
# print(best[i][1], calculate_yields(best[i][0]))
#
#
# with open(f'pole_pop{population}_iter{iterat}_{roulette}.json', 'w') as file: # zapis planszy/ogrodu do pliku json
# json.dump(best[0][0], file, indent=4)
#
# print("Dane zapisane do pliku")
# Odczyt z pliku
# with open(f'pole_pop{population}_iter{iterat}_{roulette}.json', 'r') as file:
# garden_data = json.load(file)
#
# print("Odczytane dane ogrodu:")
# for row in garden_data:
# print(row)
#
# print(calculate_yields(garden_data))
# if best[0][0] == garden_data:
# print("POPRAWNE: ", calculate_yields(garden_data), calculate_yields(best[0][0]))

213
GeneticAlgorithm2.py Normal file
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@ -0,0 +1,213 @@
import copy
import json
import random
from displayControler import NUM_X, NUM_Y
# Definiowanie stałych dla roślin i plonów
plants = ['corn', 'potato', 'tomato', 'carrot']
initial_yields = {'corn': 38, 'potato': 40, 'tomato': 43, 'carrot': 45}
yield_reduction = {
'corn': {'corn': None, 'potato': -4, 'tomato': -2, 'carrot': -4},
'potato': {'corn': None, 'potato': -5, 'tomato': -5, 'carrot': -2},
'tomato': {'corn': -5, 'potato': -3, 'tomato': -7, 'carrot': None},
'carrot': {'corn': -3, 'potato': -6, 'tomato': -4, 'carrot': -9}
}
yield_multiplier = {'corn': 1.25, 'potato': 1.19, 'tomato': 1.22, 'carrot': 1.15}
# Generowanie listy 20x12 z losowo rozmieszczonymi roślinami
def generate_garden(rows=20, cols=12):
return [[random.choice(plants) for _ in range(cols)] for _ in range(rows)]
# Funkcja do obliczania liczby plonów
def calculate_yields(garden):
rows = len(garden)
cols = len(garden[0])
total_yields = 0
for i in range(rows):
for j in range(cols):
plant = garden[i][j]
yield_count = initial_yields[plant]
# Sprawdzanie sąsiadów
neighbors = [
(i - 1, j), (i + 1, j), (i, j - 1), (i, j + 1)
]
neighbor_flag = False
for ni, nj in neighbors:
if 0 <= ni < rows and 0 <= nj < cols:
neighbor_plant = garden[ni][nj]
if yield_reduction[plant][neighbor_plant] is not None: # jeśli jest wartość None to plony dla tej rośliny będą wyzerowane
yield_count += yield_reduction[plant][neighbor_plant]
else:
neighbor_flag = True
if not neighbor_flag:
yield_count *= yield_multiplier[plant]
total_yields += yield_count
return total_yields
# Funkcja do generowania planszy/ogrodu i zapisywania go jako lista z liczbą plonów
def generate_garden_with_yields(rows=NUM_Y, cols=NUM_X):
garden = generate_garden(rows, cols)
total_yields = calculate_yields(garden)
return [garden, total_yields]
# Funkcja do generowania linii cięcia i zapisywania jej jako liczba roślin w kolumnie z pierwszej planszy/ogrodu
def line():
path = []
flag = False
x = random.randint(4, 8)
position = (0, x)
path.append(position)
while not flag: # wybór punktu dopóki nie wybierze się skrajnego
# prawdopodobieństwo "ruchu" -> 0.6: w prawo, 0.2: w góre, 0.2: w dół
p = [(position[0] + 1, position[1]), (position[0], position[1] + 1), (position[0], position[1] - 1)]
w = [0.6, 0.2, 0.2]
position2 = random.choices(p, w)[0]
if position2 not in path: # sprawdzenie czy dany punkt nie był już wybrany aby nie zapętlać się
path.append(position2)
position = position2
if position[0] == NUM_X or position[1] == 0 or position[1] == NUM_Y: # sprawdzenie czy osiągnięto skrajny punkt
flag = True
info = [] # przeformatowanie sposobu zapisu na liczbę roślin w kolumnie, które będzię się dzidziczyło z pierwszej planszy/ogrodu
for i in range(len(path) - 1):
if path[i + 1][0] - path[i][0] == 1:
info.append(NUM_Y - path[i][1])
if len(info) < NUM_X: # uzupełnienie informacji o dziedziczeniu z planszy/ogrodu
if path[-1:][0][1] == 0:
x = NUM_Y
else:
x = 0
while len(info) < NUM_X:
info.append(x)
# return path, info
return info
# Funkcja do generowania potomstwa
def divide_gardens(garden1, garden2):
info = line()
new_garden1 = [[] for _ in range(NUM_Y)]
new_garden2 = [[] for _ in range(NUM_Y)]
for i in range(NUM_X):
for j in range(NUM_Y):
# do utworzonych kolumn w nowych planszach/ogrodach dodajemy dziedziczone rośliny
if j < info[i]:
new_garden1[j].append(garden1[j][i])
new_garden2[j].append(garden2[j][i])
else:
new_garden1[j].append(garden2[j][i])
new_garden2[j].append(garden1[j][i])
return [new_garden1, calculate_yields(new_garden1)], [new_garden2, calculate_yields(new_garden2)]
# Funkcja do mutacji danej planszy/ogrodu
def mutation(garden, not_used):
new_garden = copy.deepcopy(garden)
for i in range(NUM_X):
x = random.randint(0, 11) # wybieramy, w którym wierszu w i-tej kolumnie zmieniamy roślinę na inną
other_plants = [plant for plant in plants if plant != new_garden[x][i]]
new_garden[x][i] = random.choice(other_plants)
return [new_garden, calculate_yields(new_garden)]
# Funkcja do generowania pierwszego pokolenia
def generate(n):
generation = []
for i in range(n * 3):
generation.append(generate_garden_with_yields())
generation.sort(reverse=True, key=lambda x: x[1])
return generation[:n]
# Funkcja do implementacji ruletki (sposobu wyboru) - sumuje wszystkie plony generacji
def sum_yields(x):
s = 0
for i in range(len(x)):
s += x[i][1]
return s
if __name__ == '__main__':
roulette = True
attemps = 20
iterat = 2500
population = 120
best = []
for a in range(attemps):
generation = generate(population)
print(generation[0][1])
for i in range(iterat): # ile iteracji - nowych pokoleń
print(a, i)
new_generation = generation[:(population // 7)] # dziedziczenie x najlepszych osobników
j = 0
while j < (
population - (
population // 7)): # dobór reszty osobników do pełnej liczby populacji danego pokolenia
if roulette: # zasada ruletki -> "2 rzuty kulką"
s = sum_yields(generation) # suma wszystkich plnów całego pokolenia
z = []
if s == 0: # wtedy każdy osobnik ma takie same szanse
z.append(random.randint(0, population - 1))
z.append(random.randint(0, population - 1))
else:
weights = [] # wagi prawdopodobieństwa dla każdego osobnika generacji
pos = [] # numery od 0 do 49 odpowiadające numerom osobnikom w generacji
for i in range(population):
weights.append(generation[i][1] / s)
pos.append(i)
z.append(random.choices(pos, weights)[0]) # wybranie osobnika według wag prawdopodobieństwa
z.append(random.choices(pos, weights)[0]) # wybranie osobnika według wag prawdopodobieństwa
else: # metoda rankingu
z = random.sample(range(0, int(population // 1.7)), 2)
# krzyzowanie 90% szans, mutacja 10% szans
function = [divide_gardens, mutation]
weight = [0.9, 0.1]
fun = random.choices(function, weight)[0]
h = fun(generation[z[0]][0], generation[z[1]][0])
if len(h[0]) == 2:
new_generation.append(h[0])
new_generation.append(h[1])
j += 2
else:
new_generation.append(h)
j += 1
new_generation.sort(reverse=True, key=lambda x: x[1]) # sortowanie malejąco listy według wartości plonów
generation = new_generation[:population]
best.append(generation[0])
best.sort(reverse=True, key=lambda x: x[1])
# Zapis do pliku
# for i in range(len(best)):
# print(best[i][1], calculate_yields(best[i][0]))
#
#
# with open(f'pole2_pop{population}_iter{iterat}_{roulette}.json', 'w') as file: # zapis planszy/ogrodu do pliku json
# json.dump(best[0][0], file, indent=4)
#
# print("Dane zapisane do pliku")
#
# Odczyt z pliku
# with open(f'pole2_pop{population}_iter{iterat}_{roulette}.json', 'r') as file:
# garden_data = json.load(file)
#
# print("Odczytane dane ogrodu:")
# for row in garden_data:
# print(row)
#
# print(calculate_yields(garden_data))
# if best[0][0] == garden_data:
# print("POPRAWNE: ", calculate_yields(garden_data), calculate_yields(best[0][0]))

211
GeneticAlgorithm3.py Normal file
View File

@ -0,0 +1,211 @@
import copy
import json
import random
from displayControler import NUM_X, NUM_Y
# Definiowanie stałych dla roślin i plonów
plants = ['corn', 'potato', 'tomato', 'carrot']
initial_yields = {'corn': 38, 'potato': 40, 'tomato': 43, 'carrot': 45}
yield_reduction = {
'corn': {'corn': None, 'potato': 0, 'tomato': 0, 'carrot': 0},
'potato': {'corn': None, 'potato': 0, 'tomato': 0, 'carrot': 0},
'tomato': {'corn': 0, 'potato': 0, 'tomato': 0, 'carrot': None},
'carrot': {'corn': 0, 'potato': 0, 'tomato': 0, 'carrot': 0}
}
yield_multiplier = {'corn': 1.25, 'potato': 1.19, 'tomato': 1.22, 'carrot': 1.13}
# Generowanie listy 20x12 z losowo rozmieszczonymi roślinami
def generate_garden(rows=20, cols=12):
return [[random.choice(plants) for _ in range(cols)] for _ in range(rows)]
# Funkcja do obliczania liczby plonów
def calculate_yields(garden):
rows = len(garden)
cols = len(garden[0])
total_yields = 0
for i in range(rows):
for j in range(cols):
plant = garden[i][j]
# Sprawdzanie sąsiadów
neighbors = [
(i - 1, j), (i + 1, j), (i, j - 1), (i, j + 1)
]
neighbor_flag = False
for ni, nj in neighbors:
if 0 <= ni < rows and 0 <= nj < cols:
neighbor_plant = garden[ni][nj]
if yield_reduction[plant][neighbor_plant] is None: # jeśli jest wartość None to plony dla tej rośliny będą wyzerowane
neighbor_flag = True
if not neighbor_flag:
total_yields += 1
return total_yields
# Funkcja do generowania planszy/ogrodu i zapisywania go jako lista z liczbą plonów
def generate_garden_with_yields(rows=NUM_Y, cols=NUM_X):
garden = generate_garden(rows, cols)
total_yields = calculate_yields(garden)
return [garden, total_yields]
# Funkcja do generowania linii cięcia i zapisywania jej jako liczba roślin w kolumnie z pierwszej planszy/ogrodu
def line():
path = []
flag = False
x = random.randint(4, 8)
position = (0, x)
path.append(position)
while not flag: # wybór punktu dopóki nie wybierze się skrajnego
# prawdopodobieństwo "ruchu" -> 0.6: w prawo, 0.2: w góre, 0.2: w dół
p = [(position[0] + 1, position[1]), (position[0], position[1] + 1), (position[0], position[1] - 1)]
w = [0.6, 0.2, 0.2]
position2 = random.choices(p, w)[0]
if position2 not in path: # sprawdzenie czy dany punkt nie był już wybrany aby nie zapętlać się
path.append(position2)
position = position2
if position[0] == NUM_X or position[1] == 0 or position[1] == NUM_Y: # sprawdzenie czy osiągnięto skrajny punkt
flag = True
info = [] # przeformatowanie sposobu zapisu na liczbę roślin w kolumnie, które będzię się dzidziczyło z pierwszej planszy/ogrodu
for i in range(len(path) - 1):
if path[i + 1][0] - path[i][0] == 1:
info.append(NUM_Y - path[i][1])
if len(info) < NUM_X: # uzupełnienie informacji o dziedziczeniu z planszy/ogrodu
if path[-1:][0][1] == 0:
x = NUM_Y
else:
x = 0
while len(info) < NUM_X:
info.append(x)
# return path, info
return info
# Funkcja do generowania potomstwa
def divide_gardens(garden1, garden2):
info = line()
new_garden1 = [[] for _ in range(NUM_Y)]
new_garden2 = [[] for _ in range(NUM_Y)]
for i in range(NUM_X):
for j in range(NUM_Y):
# do utworzonych kolumn w nowych planszach/ogrodach dodajemy dziedziczone rośliny
if j < info[i]:
new_garden1[j].append(garden1[j][i])
new_garden2[j].append(garden2[j][i])
else:
new_garden1[j].append(garden2[j][i])
new_garden2[j].append(garden1[j][i])
return [new_garden1, calculate_yields(new_garden1)], [new_garden2, calculate_yields(new_garden2)]
# Funkcja do mutacji danej planszy/ogrodu
def mutation(garden, not_used):
new_garden = copy.deepcopy(garden)
for i in range(NUM_X):
x = random.randint(0, 11) # wybieramy, w którym wierszu w i-tej kolumnie zmieniamy roślinę na inną
other_plants = [plant for plant in plants if plant != new_garden[x][i]]
new_garden[x][i] = random.choice(other_plants)
return [new_garden, calculate_yields(new_garden)]
# Funkcja do generowania pierwszego pokolenia
def generate(n):
generation = []
for i in range(n * 3):
generation.append(generate_garden_with_yields())
generation.sort(reverse=True, key=lambda x: x[1])
return generation[:n]
# Funkcja do implementacji ruletki (sposobu wyboru) - sumuje wszystkie plony generacji
def sum_yields(x):
s = 0
for i in range(len(x)):
s += x[i][1]
return s
if __name__ == '__main__':
roulette = True
attemps = 1
population = 120
best = []
iter = 0
for a in range(attemps):
generation = generate(population)
print(generation[0][1])
while generation[0][1] != NUM_X*NUM_Y: # ile iteracji - nowych pokoleń
iter += 1
print(iter)
print(generation[0][1])
new_generation = generation[:(population // 7)] # dziedziczenie x najlepszych osobników
j = 0
while j < (
population - (
population // 7)): # dobór reszty osobników do pełnej liczby populacji danego pokolenia
if roulette: # zasada ruletki -> "2 rzuty kulką"
s = sum_yields(generation) # suma wszystkich plnów całego pokolenia
z = []
if s == 0: # wtedy każdy osobnik ma takie same szanse
z.append(random.randint(0, population - 1))
z.append(random.randint(0, population - 1))
else:
weights = [] # wagi prawdopodobieństwa dla każdego osobnika generacji
pos = [] # numery od 0 do 49 odpowiadające numerom osobnikom w generacji
for i in range(population):
weights.append(generation[i][1] / s)
pos.append(i)
z.append(random.choices(pos, weights)[0]) # wybranie osobnika według wag prawdopodobieństwa
z.append(random.choices(pos, weights)[0]) # wybranie osobnika według wag prawdopodobieństwa
else: # metoda rankingu
z = random.sample(range(0, int(population // 1.7)), 2)
# krzyzowanie 90% szans, mutacja 10% szans
function = [divide_gardens, mutation]
weight = [0.9, 0.1]
fun = random.choices(function, weight)[0]
h = fun(generation[z[0]][0], generation[z[1]][0])
if len(h[0]) == 2:
new_generation.append(h[0])
new_generation.append(h[1])
j += 2
else:
new_generation.append(h)
j += 1
new_generation.sort(reverse=True, key=lambda x: x[1]) # sortowanie malejąco listy według wartości plonów
generation = new_generation[:population]
best.append(generation[0])
best.sort(reverse=True, key=lambda x: x[1])
# Zapis do pliku
# for i in range(len(best)):
# print(best[i][1], calculate_yields(best[i][0]))
#
#
# with open(f'pole3_pop{population}_{iter}_{roulette}.json', 'w') as file: # zapis planszy/ogrodu do pliku json
# json.dump(best[0][0], file, indent=4)
#
# print("Dane zapisane do pliku")
#
# Odczyt z pliku
# with open(f'pole3_pop{population}_{iter}_{roulette}.json', 'r') as file:
# garden_data = json.load(file)
#
# print("Odczytane dane ogrodu:")
# for row in garden_data:
# print(row)
#
# print(calculate_yields(garden_data))
# if best[0][0] == garden_data:
# print("POPRAWNE: ", calculate_yields(garden_data), calculate_yields(best[0][0]))

22
Image.py
View File

@ -80,3 +80,25 @@ def getRandomImageFromDataBase():
image = pygame.image.load(imgPath)
image=pygame.transform.scale(image,(dCon.CUBE_SIZE,dCon.CUBE_SIZE))
return image, label, imgPath
def getSpedifiedImageFromDatabase(label):
folderPath = f"dataset/test/{label}"
files = os.listdir(folderPath)
random_image = random.choice(files)
imgPath = os.path.join(folderPath, random_image)
while imgPath in imagePathList:
for event in pygame.event.get():
if event.type == pygame.QUIT:
quit()
label = random.choice(neuralnetwork.labels)
folderPath = f"dataset/test/{label}"
files = os.listdir(folderPath)
random_image = random.choice(files)
imgPath = os.path.join(folderPath, random_image)
imagePathList.append(imgPath)
image = pygame.image.load(imgPath)
image=pygame.transform.scale(image,(dCon.CUBE_SIZE,dCon.CUBE_SIZE))
return image, label, imgPath

8
Pole.py
View File

@ -62,6 +62,14 @@ class Pole:
continue
else:
self.slot_dict[coordinates].set_random_plant(nn)
def setPlantsByList(self, plantList):
pygame.display.update()
time.sleep(3)
for coordinates in self.slot_dict:
if(coordinates==(0,0)):
continue
else:
self.slot_dict[coordinates].set_specifided_plant(plantList[coordinates[1]][coordinates[0]])
def change_color_of_slot(self,coordinates,color): #Coordinates must be tuple (x,y) (left top slot has cord (0,0) ), color has to be from defined in Colors.py or custom in RGB value (R,G,B)
self.get_slot_from_cord(coordinates).color_change(color)

7
Slot.py
View File

@ -49,6 +49,11 @@ class Slot:
# print(self.plant_image)
self.plant=Roslina.Roslina(self.label)
self.set_image()
def set_specifided_plant(self, plant):
self.plant_image, self.label, self.imagePath = self.specified_plant_dataset(plant)
self.plant=Roslina.Roslina(self.label)
self.set_image()
def set_image(self):
if self.plant_image is None:
@ -75,6 +80,8 @@ class Slot:
return self.image_loader.return_random_plant()
def random_plant_dataset(self):
return Image.getRandomImageFromDataBase()
def specified_plant_dataset(self, plant):
return Image.getSpedifiedImageFromDatabase(plant)
def return_plant(self):
return self.plant

24
Tractor.py
View File

@ -30,6 +30,7 @@ class Tractor:
DIRECTION_SOUTH = 'S'
DIRECTION_WEST = 'W'
DIRECTION_EAST = 'E'
def __init__(self,slot,screen, osprzet,clock,bfs2_flag):
self.tractor_images = {
Tractor.DIRECTION_NORTH: pygame.transform.scale(pygame.image.load('images/traktorN.png'),
@ -193,8 +194,7 @@ class Tractor:
self.turn_left()
print("podlanych slotów: ", str(counter))
def snake_move_predict_plant(self, pole, model):
headers=['Coords','Real plant','Predicted plant','Result','Fertilizer']
def snake_move_predict_plant(self, pole, model, headers, actions = None):
print(format_string_nn.format(*headers))
initPos = (self.slot.x_axis, self.slot.y_axis)
count = 0
@ -207,9 +207,11 @@ class Tractor:
predictedLabel = nn.predictLabel(self.slot.imagePath, model)
#print(str("Coords: ({:02d}, {:02d})").format(self.slot.x_axis, self.slot.y_axis), "real:", self.slot.label, "predicted:", predictedLabel, "correct" if (self.slot.label == predictedLabel) else "incorrect", 'nawożę za pomocą:', nn.fertilizer[predictedLabel])
print(format_string_nn.format(f"{self.slot.x_axis,self.slot.y_axis}",self.slot.label,predictedLabel,"correct" if (self.slot.label == predictedLabel) else "incorrect",nn.fertilizer[predictedLabel]))
# print(format_string_nn.format(f"{self.slot.x_axis,self.slot.y_axis}",self.slot.label,predictedLabel,"correct" if (self.slot.label == predictedLabel) else "incorrect",nn.fertilizer[predictedLabel]))
for a in actions:
a(predictedLabel)
if self.slot.label != predictedLabel:
self.slot.mark_visited()
# self.slot.mark_visited()
count += 1
self.move_forward(pole, False)
if i % 2 == 0 and i != dCon.NUM_Y - 1:
@ -220,7 +222,19 @@ class Tractor:
self.turn_left()
self.move_forward(pole, False)
self.turn_left()
print(f"Dobrze nawiezionych roślin: {20*12-count}, źle nawiezionych roślin: {count}")
print(f"Dobrze rozpoznanych roślin: {20*12-count}, źle rozpoznanych roślin: {count}")
def fertilize_slot(self, predictedLabel):
print(format_string_nn.format(f"{self.slot.x_axis,self.slot.y_axis}",self.slot.label,predictedLabel,"correct" if (self.slot.label == predictedLabel) else "incorrect",nn.fertilizer[predictedLabel]))
if self.slot.label != predictedLabel:
self.slot.mark_visited()
def irigate_slot_NN(self, predictedLabel):
attributes=self.get_attributes()
decision = drzewo.makeDecision(attributes)
print(format_string_nn.format(f"{self.slot.x_axis,self.slot.y_axis}",self.slot.label,predictedLabel,"correct" if (self.slot.label == predictedLabel) else "incorrect",decision))
condition.cycle()
self.waterLevel = random.randint(0, 100)
def snake_move(self,pole,x,y):
next_slot_coordinates=(x,y)

2
neuralnetwork.py
View File

@ -77,7 +77,7 @@ def saveModel(model, path):
def loadModel(path):
print("Loading model")
model = getModel()
model.load_state_dict(torch.load(path))
model.load_state_dict(torch.load(path, map_location=torch.device('cpu'))) # musiałem tutaj dodać to ładowanie z mapowaniem na cpu bo u mnie CUDA nie działa wy pewnie możecie to usunąć
return model
def trainNewModel(n_iter=100, batch_size=256):

266
pole2_pop120_iter2500_True.json Normal file
View File

@ -0,0 +1,266 @@
[
[
"tomato",
"corn",
"tomato",
"tomato",
"corn",
"tomato",
"tomato",
"corn",
"carrot",
"potato",
"potato",
"tomato",
"corn",
"tomato",
"corn",
"tomato",
"corn",
"tomato",
"corn",
"tomato"
],
[
"corn",
"carrot",
"potato",
"potato",
"carrot",
"potato",
"potato",
"carrot",
"potato",
"potato",
"carrot",
"corn",
"tomato",
"corn",
"carrot",
"corn",
"tomato",
"corn",
"tomato",
"corn"
],
[
"carrot",
"potato",
"potato",
"carrot",
"corn",
"carrot",
"potato",
"carrot",
"potato",
"carrot",
"corn",
"tomato",
"corn",
"tomato",
"corn",
"tomato",
"corn",
"tomato",
"corn",
"tomato"
],
[
"potato",
"potato",
"carrot",
"corn",
"tomato",
"corn",
"carrot",
"corn",
"carrot",
"corn",
"tomato",
"corn",
"tomato",
"corn",
"tomato",
"corn",
"tomato",
"corn",
"tomato",
"corn"
],
[
"potato",
"carrot",
"corn",
"tomato",
"corn",
"tomato",
"corn",
"tomato",
"corn",
"tomato",
"corn",
"tomato",
"corn",
"tomato",
"corn",
"tomato",
"corn",
"tomato",
"corn",
"tomato"
],
[
"tomato",
"corn",
"tomato",
"corn",
"tomato",
"corn",
"tomato",
"corn",
"tomato",
"corn",
"tomato",
"corn",
"tomato",
"corn",
"tomato",
"corn",
"tomato",
"corn",
"tomato",
"corn"
],
[
"corn",
"tomato",
"corn",
"tomato",
"corn",
"tomato",
"corn",
"tomato",
"corn",
"tomato",
"corn",
"tomato",
"corn",
"tomato",
"corn",
"tomato",
"corn",
"tomato",
"corn",
"tomato"
],
[
"tomato",
"corn",
"tomato",
"corn",
"tomato",
"corn",
"tomato",
"corn",
"tomato",
"corn",
"tomato",
"corn",
"tomato",
"corn",
"tomato",
"corn",
"tomato",
"corn",
"tomato",
"corn"
],
[
"corn",
"tomato",
"corn",
"tomato",
"corn",
"tomato",
"corn",
"tomato",
"corn",
"tomato",
"corn",
"tomato",
"corn",
"tomato",
"corn",
"tomato",
"corn",
"carrot",
"corn",
"tomato"
],
[
"tomato",
"corn",
"tomato",
"corn",
"tomato",
"corn",
"tomato",
"corn",
"tomato",
"corn",
"tomato",
"corn",
"tomato",
"corn",
"tomato",
"corn",
"carrot",
"potato",
"tomato",
"potato"
],
[
"corn",
"tomato",
"corn",
"tomato",
"corn",
"tomato",
"corn",
"tomato",
"corn",
"tomato",
"corn",
"carrot",
"corn",
"carrot",
"corn",
"carrot",
"potato",
"potato",
"tomato",
"potato"
],
[
"tomato",
"corn",
"tomato",
"corn",
"tomato",
"corn",
"tomato",
"corn",
"tomato",
"corn",
"tomato",
"corn",
"tomato",
"corn",
"tomato",
"potato",
"potato",
"carrot",
"corn",
"tomato"
]
]

266
pole3_pop120_365_True.json Normal file
View File

@ -0,0 +1,266 @@
[
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266
pole_pop120_iter2500_True.json Normal file
View File

@ -0,0 +1,266 @@
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19
readme.txt
View File

@ -4,4 +4,21 @@ Required packages:
pip install pygame
pip install matplotlib
pip install scikit-learn
pip install pandas
pip install pandas
How to run:
For BFS3:
-in App.py: -change bfs3_flag to True (other flags need to be disabled) -ensure that in App.py in BFS3 you give goalTreasure
-in Image.py change range in function return_random_plant to (0,5)
For Astar:
in App.py change Astar to True (other flags need to be disabled)
-in Image.py change range in function return_random_plant to (0,7)
For Astar2:
-in App.py change Astar2 flag to True (other flags need to be disabled)
-in Image.py change range in function return_random_plant to (0,7)
For Tree:
-in App.py change TreeFlag to True (other flags need to be disabled)
-in Image.py change range in function return_random_plant to (0,5)
For neuralnetwork:
-in App.py change nnFlag to True (other flags need to be disabled)
For final_show (neuralnetwork+tree+genetic algorithm)
-in App.py change finalFlag to True (other flags need to be disabled)