neural_network #25
21
App.py
21
App.py
@ -9,6 +9,7 @@ import Osprzet
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import Ui
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import BFS
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import AStar
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import neuralnetwork
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bfs1_flag=False
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@ -18,7 +19,9 @@ Astar = False
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Astar2 = False
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if bfs3_flag or Astar or Astar2:
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Pole.stoneFlag = True
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TreeFlag=True
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TreeFlag=False
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nnFlag=True
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newModel=False
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pygame.init()
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show_console=True
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@ -29,7 +32,7 @@ image_loader=Image.Image()
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image_loader.load_images()
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goalTreasure = AStar.getRandomGoalTreasure() # nie wiem czy to najlepsze miejsce, obecnie pole zawiera pole gasStation, które służy do renderowania odpowiedniego zdjęcia
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pole=Pole.Pole(screen,image_loader, goalTreasure)
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pole.draw_grid() #musi byc tutaj wywołane ponieważ inicjalizuje sloty do slownika
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pole.draw_grid(nnFlag) #musi byc tutaj wywołane ponieważ inicjalizuje sloty do slownika
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ui=Ui.Ui(screen)
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#Tractor creation
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traktor_slot = pole.get_slot_from_cord((0, 0))
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@ -40,7 +43,7 @@ def init_demo(): #Demo purpose
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old_info=""
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traktor.draw_tractor()
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time.sleep(2)
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pole.randomize_colors()
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pole.randomize_colors(nnFlag)
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traktor.draw_tractor()
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start_flag=True
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while True:
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@ -116,6 +119,18 @@ def init_demo(): #Demo purpose
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if(TreeFlag):
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traktor.move_forward(pole)
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traktor.tree_move(pole)
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if(nnFlag):
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global model
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if (newModel):
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print_to_console("uczenie sieci neuronowej")
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model = neuralnetwork.trainNewModel()
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neuralnetwork.saveModel(model)
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print('model został wygenerowany')
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else:
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model = neuralnetwork.loadModel('model.pth')
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print_to_console("model został załądowny")
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testset = neuralnetwork.getDataset(False)
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print(neuralnetwork.accuracy(model, testset))
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start_flag=False
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# demo_move()
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old_info=get_info(old_info)
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12
Image.py
12
Image.py
@ -1,6 +1,8 @@
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import pygame
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import displayControler as dCon
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import random
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import neuralnetwork
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import os
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class Image:
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def __init__(self):
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@ -53,3 +55,13 @@ class Image:
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def return_gasStation(self):
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return self.gasStation_image
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def getRandomImageFromDataBase():
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label = random.choice(neuralnetwork.labels)
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folderPath = f"dataset/test/{label}"
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files = os.listdir(folderPath)
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random_image = random.choice(files)
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imgPath = os.path.join(folderPath, random_image)
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return pygame.image.load(imgPath), label, imgPath
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8
Pole.py
8
Pole.py
@ -6,6 +6,8 @@ import time
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import Ui
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import math
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import random
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import neuralnetwork
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import Image
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stoneList = [(3,3), (3,4), (3,5), (3,6), (4,6), (5,6), (6,6), (7,6), (8,6), (9,6), (10,6), (11,6), (12,6), (13,6), (14,6), (15,6), (16,6), (16,7), (16,8), (16,9)]
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stoneFlag = False
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@ -30,7 +32,7 @@ class Pole:
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return self.slot_dict
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#Draw grid and tractor (new one)
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def draw_grid(self):
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def draw_grid(self, nn=False):
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for x in range(0,dCon.NUM_X): #Draw all cubes in X axis
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for y in range(0,dCon.NUM_Y): #Draw all cubes in Y axis
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new_slot=Slot.Slot(x,y,Colors.BROWN,self.screen,self.image_loader) #Creation of empty slot
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@ -48,7 +50,7 @@ class Pole:
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st=self.slot_dict[self.gasStation]
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st.set_gasStation_image()
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def randomize_colors(self):
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def randomize_colors(self, nn = False):
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pygame.display.update()
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time.sleep(3)
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#self.ui.render_text("Randomizing Crops")
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@ -59,7 +61,7 @@ class Pole:
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if(coordinates==(0,0)):
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continue
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else:
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self.slot_dict[coordinates].set_random_plant()
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self.slot_dict[coordinates].set_random_plant(nn)
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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)
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self.get_slot_from_cord(coordinates).color_change(color)
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10
Slot.py
10
Slot.py
@ -16,6 +16,8 @@ class Slot:
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self.field=pygame.Rect(self.x_axis*dCon.CUBE_SIZE,self.y_axis*dCon.CUBE_SIZE,dCon.CUBE_SIZE,dCon.CUBE_SIZE)
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self.image_loader=image_loader
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self.garage_image=None
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self.label = None
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self.imagePath = None
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def draw(self):
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pygame.draw.rect(self.screen,Colors.BROWN,self.field,0) #Draw field
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@ -38,9 +40,13 @@ class Slot:
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self.plant=color
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self.draw()
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def set_random_plant(self):
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def set_random_plant(self, nn=False):
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if not nn:
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(plant_name,self.plant_image)=self.random_plant()
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self.plant=Roslina.Roslina(plant_name)
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else:
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self.plant_image, self.label, self.imagePath = self.random_plant_dataset()
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self.plant=Roslina.Roslina(self.label)
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self.set_image()
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def set_image(self):
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@ -66,6 +72,8 @@ class Slot:
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def random_plant(self): #Probably will not be used later only for demo purpouse
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return self.image_loader.return_random_plant()
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def random_plant_dataset(self):
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return Image.getRandomImageFromDataBase()
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def return_plant(self):
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return self.plant
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111
neuralnetwork.py
Normal file
111
neuralnetwork.py
Normal file
@ -0,0 +1,111 @@
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import torch
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import torch.nn as nn
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from torch.utils.data import DataLoader
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from torchvision import datasets
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from torchvision.transforms import Compose, Lambda, ToTensor
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import torchvision.transforms as transforms
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import matplotlib.pyplot as plt
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from PIL import Image
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import random
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imageSize = (128, 128)
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labels = ['beetroot', 'potato', 'carrot']
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labels.sort()
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torch.manual_seed(42)
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device = torch.device('cuda') if torch.cuda.is_available () else torch.device('cpu')
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def getTransformation():
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transform=transforms.Compose([
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transforms.ToTensor(),
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transforms.Normalize(mean=[0.5, 0.5, 0.5], std=[0.5, 0.5, 0.5]),
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transforms.Resize(imageSize),
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Lambda(lambda x: x.flatten())])
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return transform
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def getDataset(train=True):
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transform = getTransformation()
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if (train):
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trainset = datasets.ImageFolder(root='dataset/train', transform=transform)
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return trainset
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else:
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testset = datasets.ImageFolder(root='dataset/test', transform=transform)
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return testset
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def train(model, dataset, n_iter=100, batch_size=256):
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optimizer = torch.optim.SGD(model.parameters(), lr=0.01)
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criterion = nn.NLLLoss()
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dl = DataLoader(dataset, batch_size=batch_size)
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model.train()
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for epoch in range(n_iter):
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for images, targets in dl:
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optimizer.zero_grad()
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out = model(images.to(device))
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loss = criterion(out, targets.to(device))
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loss.backward()
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optimizer.step()
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if epoch % 10 == 0:
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print('epoch: %3d loss: %.4f' % (epoch, loss))
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return model
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def accuracy(model, dataset):
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model.eval()
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correct = sum([(model(images.to(device)).argmax(dim=1) == targets.to(device)).sum()
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for images, targets in DataLoader(dataset, batch_size=256)])
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return correct.float() / len(dataset)
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def getModel():
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hidden_size = 300
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model = nn.Sequential(
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nn.Linear(imageSize[0] * imageSize[1] * 3, hidden_size),
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nn.ReLU(),
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nn.Linear(hidden_size, len(labels)),
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nn.LogSoftmax(dim=-1)
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).to(device)
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return model
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def saveModel(model):
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torch.save(model.state_dict(), 'model.pth')
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def loadModel(path):
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model = getModel()
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model.load_state_dict(torch.load(path))
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return model
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def trainNewModel(n_iter=100, batch_size=256):
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trainset = getDataset(True)
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model = getModel()
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model = train(model, trainset)
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return model
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def predictLabel(imagePath, model):
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image = Image.open(imagePath).convert("RGB")
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image = preprocess_image(image)
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with torch.no_grad():
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model.eval() # Ustawienie modelu w tryb ewaluacji
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output = model(image)
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# Znalezienie indeksu klasy o największej wartości prawdopodobieństwa
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predicted_class = torch.argmax(output).item()
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return labels[predicted_class]
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def predictLabel(image, model):
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image = preprocess_image(image)
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with torch.no_grad():
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model.eval() # Ustawienie modelu w tryb ewaluacji
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output = model(image)
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# Znalezienie indeksu klasy o największej wartości prawdopodobieństwa
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predicted_class = torch.argmax(output).item()
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return labels[predicted_class]
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def preprocess_image(image):
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transform = getTransformation()
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image = transform(image).unsqueeze(0) # Dodanie wymiaru batch_size
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return image
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