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	import os
	import numpy as np
	import torch
	import torch.nn as nn
	import gradio as gr
	from torchvision.models import efficientnet_v2_m, EfficientNet_V2_M_Weights
	import torch.nn.functional as F
	from torchvision import transforms
	from PIL import Image
	from data_manager import get_dog_description
	from urllib.parse import quote
	# os.system('pip install ultralytics')
	from ultralytics import YOLO
	from PIL import ImageDraw


	# 下載YOLOv8預訓練模型
	model_yolo = YOLO('yolov8n.pt') # 使用 YOLOv8 預訓練模型


	dog_breeds = ["Afghan_Hound", "African_Hunting_Dog", "Airedale", "American_Staffordshire_Terrier",
	"Appenzeller", "Australian_Terrier", "Bedlington_Terrier", "Bernese_Mountain_Dog",
	"Blenheim_Spaniel", "Border_Collie", "Border_Terrier", "Boston_Bull", "Bouvier_Des_Flandres",
	"Brabancon_Griffon", "Brittany_Spaniel", "Cardigan", "Chesapeake_Bay_Retriever",
	"Chihuahua", "Dandie_Dinmont", "Doberman", "English_Foxhound", "English_Setter",
	"English_Springer", "EntleBucher", "Eskimo_Dog", "French_Bulldog", "German_Shepherd",
	"German_Short-Haired_Pointer", "Gordon_Setter", "Great_Dane", "Great_Pyrenees",
	"Greater_Swiss_Mountain_Dog", "Ibizan_Hound", "Irish_Setter", "Irish_Terrier",
	"Irish_Water_Spaniel", "Irish_Wolfhound", "Italian_Greyhound", "Japanese_Spaniel",
	"Kerry_Blue_Terrier", "Labrador_Retriever", "Lakeland_Terrier", "Leonberg", "Lhasa",
	"Maltese_Dog", "Mexican_Hairless", "Newfoundland", "Norfolk_Terrier", "Norwegian_Elkhound",
	"Norwich_Terrier", "Old_English_Sheepdog", "Pekinese", "Pembroke", "Pomeranian",
	"Rhodesian_Ridgeback", "Rottweiler", "Saint_Bernard", "Saluki", "Samoyed",
	"Scotch_Terrier", "Scottish_Deerhound", "Sealyham_Terrier", "Shetland_Sheepdog",
	"Shih-Tzu", "Siberian_Husky", "Staffordshire_Bullterrier", "Sussex_Spaniel",
	"Tibetan_Mastiff", "Tibetan_Terrier", "Walker_Hound", "Weimaraner",
	"Welsh_Springer_Spaniel", "West_Highland_White_Terrier", "Yorkshire_Terrier",
	"Affenpinscher", "Basenji", "Basset", "Beagle", "Black-and-Tan_Coonhound", "Bloodhound",
	"Bluetick", "Borzoi", "Boxer", "Briard", "Bull_Mastiff", "Cairn", "Chow", "Clumber",
	"Cocker_Spaniel", "Collie", "Curly-Coated_Retriever", "Dhole", "Dingo",
	"Flat-Coated_Retriever", "Giant_Schnauzer", "Golden_Retriever", "Groenendael", "Keeshond",
	"Kelpie", "Komondor", "Kuvasz", "Malamute", "Malinois", "Miniature_Pinscher",
	"Miniature_Poodle", "Miniature_Schnauzer", "Otterhound", "Papillon", "Pug", "Redbone",
	"Schipperke", "Silky_Terrier", "Soft-Coated_Wheaten_Terrier", "Standard_Poodle",
	"Standard_Schnauzer", "Toy_Poodle", "Toy_Terrier", "Vizsla", "Whippet",
	"Wire-Haired_Fox_Terrier"]

	class MultiHeadAttention(nn.Module):

	def __init__(self, in_dim, num_heads=8):
	super().__init__()
	self.num_heads = num_heads
	self.head_dim = max(1, in_dim // num_heads)
	self.scaled_dim = self.head_dim * num_heads
	self.fc_in = nn.Linear(in_dim, self.scaled_dim)
	self.query = nn.Linear(self.scaled_dim, self.scaled_dim)
	self.key = nn.Linear(self.scaled_dim, self.scaled_dim)
	self.value = nn.Linear(self.scaled_dim, self.scaled_dim)
	self.fc_out = nn.Linear(self.scaled_dim, in_dim)

	def forward(self, x):
	N = x.shape[0]
	x = self.fc_in(x)
	q = self.query(x).view(N, self.num_heads, self.head_dim)
	k = self.key(x).view(N, self.num_heads, self.head_dim)
	v = self.value(x).view(N, self.num_heads, self.head_dim)

	energy = torch.einsum("nqd,nkd->nqk", [q, k])
	attention = F.softmax(energy / (self.head_dim ** 0.5), dim=2)

	out = torch.einsum("nqk,nvd->nqd", [attention, v])
	out = out.reshape(N, self.scaled_dim)
	out = self.fc_out(out)
	return out

	class BaseModel(nn.Module):
	def __init__(self, num_classes, device='cuda' if torch.cuda.is_available() else 'cpu'):
	super().__init__()
	self.device = device
	self.backbone = efficientnet_v2_m(weights=EfficientNet_V2_M_Weights.IMAGENET1K_V1)
	self.feature_dim = self.backbone.classifier[1].in_features
	self.backbone.classifier = nn.Identity()

	self.num_heads = max(1, min(8, self.feature_dim // 64))
	self.attention = MultiHeadAttention(self.feature_dim, num_heads=self.num_heads)

	self.classifier = nn.Sequential(
	nn.LayerNorm(self.feature_dim),
	nn.Dropout(0.3),
	nn.Linear(self.feature_dim, num_classes)
	)

	self.to(device)

	def forward(self, x):
	x = x.to(self.device)
	features = self.backbone(x)
	attended_features = self.attention(features)
	logits = self.classifier(attended_features)
	return logits, attended_features


	num_classes = 120
	device = torch.device('cuda' if torch.cuda.is_available() else 'cpu')
	model = BaseModel(num_classes=num_classes, device=device)

	checkpoint = torch.load('best_model_81_dog.pth', map_location=torch.device('cpu'))
	model.load_state_dict(checkpoint['model_state_dict'])

	# evaluation mode
	model.eval()

	# Image preprocessing function
	def preprocess_image(image):
	# If the image is numpy.ndarray turn into PIL.Image
	if isinstance(image, np.ndarray):
	image = Image.fromarray(image)

	# Use torchvision.transforms to process images
	transform = transforms.Compose([
	transforms.Resize((224, 224)),
	transforms.ToTensor(),
	transforms.Normalize(mean=[0.485, 0.456, 0.406], std=[0.229, 0.224, 0.225]),
	])

	return transform(image).unsqueeze(0)


	def get_akc_breeds_link():
	return "https://www.akc.org/dog-breeds/"

	# def predict(image):
	# if image is None:
	# return "Please upload an image to get started.", gr.update(visible=False), gr.update(visible=False), gr.update(visible=False)

	# try:
	# image_tensor = preprocess_image(image)
	# with torch.no_grad():
	# output = model(image_tensor)
	# logits = output[0] if isinstance(output, tuple) else output

	# probabilities = F.softmax(logits, dim=1)
	# topk_probs, topk_indices = torch.topk(probabilities, k=3)

	# top1_prob = topk_probs[0][0].item()
	# topk_breeds = [dog_breeds[idx.item()] for idx in topk_indices[0]]
	# topk_probs_percent = [f"{prob.item() * 100:.2f}%" for prob in topk_probs[0]]

	# if top1_prob >= 0.5:
	# breed = topk_breeds[0]
	# description = get_dog_description(breed)
	# return format_description(description, breed), gr.update(visible=False), gr.update(visible=False), gr.update(visible=False)

	# elif top1_prob < 0.2:
	# return ("The image is too unclear or the dog breed is not in the dataset. Please upload a clearer image of the dog.",
	# gr.update(visible=False), gr.update(visible=False), gr.update(visible=False))
	# else:
	# explanation = (
	# f"The model couldn't confidently identify the breed. Here are the top 3 possible breeds:\n\n"
	# f"1. {topk_breeds[0]} ({topk_probs_percent[0]} confidence)\n"
	# f"2. {topk_breeds[1]} ({topk_probs_percent[1]} confidence)\n"
	# f"3. {topk_breeds[2]} ({topk_probs_percent[2]} confidence)\n\n"
	# "Click on a button to view more information about the breed."
	# )
	# return explanation, gr.update(visible=True, value=f"More about {topk_breeds[0]}"), gr.update(visible=True, value=f"More about {topk_breeds[1]}"), gr.update(visible=True, value=f"More about {topk_breeds[2]}")

	# except Exception as e:
	# return f"An error occurred: {e}", gr.update(visible=False), gr.update(visible=False), gr.update(visible=False)


	# def format_description(description, breed):
	# if isinstance(description, dict):
	# formatted_description = "\n\n".join([f"{key}: {value}" for key, value in description.items()])
	# else:
	# formatted_description = description

	# akc_link = get_akc_breeds_link()
	# formatted_description += f"\n\nWant to learn more about dog breeds? [Visit the AKC dog breeds page]({akc_link}) and search for {breed} to find detailed information."

	# disclaimer = ("\n\n*Disclaimer: The external link provided leads to the American Kennel Club (AKC) dog breeds page. "
	# "You may need to search for the specific breed on that page. "
	# "I am not responsible for the content on external sites. "
	# "Please refer to the AKC's terms of use and privacy policy.*")
	# formatted_description += disclaimer

	# return formatted_description

	# def show_details(breed):
	# breed_name = breed.split("More about ")[-1]
	# description = get_dog_description(breed_name)
	# return format_description(description, breed_name)

	# with gr.Blocks(css="""
	# .container {
	# max-width: 900px;
	# margin: 0 auto;
	# padding: 20px;
	# background-color: rgba(255, 255, 255, 0.9);
	# border-radius: 15px;
	# box-shadow: 0 0 20px rgba(0, 0, 0, 0.1);
	# }
	# .gr-form { display: flex; flex-direction: column; align-items: center; }
	# .gr-box { width: 100%; max-width: 500px; }
	# .output-markdown, .output-image {
	# margin-top: 20px;
	# padding: 15px;
	# background-color: #f5f5f5;
	# border-radius: 10px;
	# }
	# .examples {
	# display: flex;
	# justify-content: center;
	# flex-wrap: wrap;
	# gap: 10px;
	# margin-top: 20px;
	# }
	# .examples img {
	# width: 100px;
	# height: 100px;
	# object-fit: cover;
	# }
	# """) as iface:

	# gr.HTML("<h1 style='font-family:Roboto; font-weight:bold; color:#2C3E50; text-align:center;'>🐶 Dog Breed Classifier 🔍</h1>")
	# gr.HTML("<p style='font-family:Open Sans; color:#34495E; text-align:center;'>Upload a picture of a dog, and the model will predict its breed, provide detailed information, and include an extra information link!</p>")

	# with gr.Row():
	# input_image = gr.Image(label="Upload a dog image", type="numpy")
	# output = gr.Markdown(label="Prediction Results")

	# with gr.Row():
	# btn1 = gr.Button("View More 1", visible=False)
	# btn2 = gr.Button("View More 2", visible=False)
	# btn3 = gr.Button("View More 3", visible=False)

	# input_image.change(predict, inputs=input_image, outputs=[output, btn1, btn2, btn3])

	# btn1.click(show_details, inputs=btn1, outputs=output)
	# btn2.click(show_details, inputs=btn2, outputs=output)
	# btn3.click(show_details, inputs=btn3, outputs=output)

	# gr.Examples(
	# examples=['Border_Collie.jpg', 'Golden_Retriever.jpeg', 'Saint_Bernard.jpeg', 'French_Bulldog.jpeg', 'Samoyed.jpg'],
	# inputs=input_image
	# )

	# gr.HTML('For more details on this project and other work, feel free to visit my GitHub <a href="https://github.com/Eric-Chung-0511/Learning-Record/tree/main/Data%20Science%20Projects/Dog%20Breed%20Classifier">Dog Breed Classifier</a>')

	# # launch the program
	# if __name__ == "__main__":
	# iface.launch()


	def detect_dogs(image):
	results = yolo_model(image)
	dogs = []
	for result in results:
	for box in result.boxes:
	if box.cls == 16: # COCO 資料集中的狗類別是 16
	xyxy = box.xyxy[0].tolist()
	confidence = box.conf.item()
	cropped_image = image.crop((xyxy[0], xyxy[1], xyxy[2], xyxy[3]))
	dogs.append((cropped_image, confidence, xyxy))
	return dogs

	def predict_breed(cropped_image):
	image_tensor = preprocess_image(cropped_image)
	with torch.no_grad():
	output = model(image_tensor)
	logits = output[0] if isinstance(output, tuple) else output
	probabilities = F.softmax(logits, dim=1)
	topk_probs, topk_indices = torch.topk(probabilities, k=3)
	top1_prob = topk_probs[0][0].item()
	topk_breeds = [dog_breeds[idx.item()] for idx in topk_indices[0]]
	topk_probs_percent = [f"{prob.item() * 100:.2f}%" for prob in topk_probs[0]]
	return top1_prob, topk_breeds, topk_probs_percent

	def predict(image):
	if image is None:
	return "Please upload an image to start.", None, gr.update(visible=False), gr.update(visible=False), gr.update(visible=False)

	try:
	if isinstance(image, np.ndarray):
	image = Image.fromarray(image)

	dogs = detect_dogs(image)
	if len(dogs) == 0:
	return "No dogs detected or the image is unclear. Please upload a clearer image of a dog.", None, gr.update(visible=False), gr.update(visible=False), gr.update(visible=False)

	explanations = []
	visible_buttons = []
	annotated_image = image.copy()
	draw = ImageDraw.Draw(annotated_image)

	for i, (cropped_image, _, box) in enumerate(dogs):
	top1_prob, topk_breeds, topk_probs_percent = predict_breed(cropped_image)

	draw.rectangle(box, outline="red", width=3)
	draw.text((box[0], box[1]), f"Dog {i+1}", fill="red")

	if top1_prob >= 0.5:
	breed = topk_breeds[0]
	description = get_dog_description(breed)
	explanations.append(f"Dog {i+1}: {breed}\n{format_description(description, breed)}")
	elif 0.2 <= top1_prob < 0.5:
	explanation = (
	f"Dog {i+1}: Detected with moderate confidence. Here are the top 3 possible breeds:\n"
	f"1. {topk_breeds[0]} ({topk_probs_percent[0]})\n"
	f"2. {topk_breeds[1]} ({topk_probs_percent[1]})\n"
	f"3. {topk_breeds[2]} ({topk_probs_percent[2]})\n"
	)
	explanations.append(explanation)
	visible_buttons.extend([f"More about {topk_breeds[0]}", f"More about {topk_breeds[1]}", f"More about {topk_breeds[2]}"])
	else:
	explanations.append(f"Dog {i+1}: The image is unclear or the breed is not in the dataset.")

	final_explanation = "\n\n".join(explanations)
	return final_explanation, annotated_image, gr.update(visible=len(visible_buttons) >= 1, value=visible_buttons[0] if visible_buttons else ""), gr.update(visible=len(visible_buttons) >= 2, value=visible_buttons[1] if len(visible_buttons) >= 2 else ""), gr.update(visible=len(visible_buttons) >= 3, value=visible_buttons[2] if len(visible_buttons) >= 3 else "")

	except Exception as e:
	return f"An error occurred: {e}", None, gr.update(visible=False), gr.update(visible=False), gr.update(visible=False)

	def format_description(description, breed):
	if isinstance(description, dict):
	formatted_description = "\n".join([f"{key}: {value}" for key, value in description.items()])
	else:
	formatted_description = description

	akc_link = get_akc_breeds_link()
	formatted_description += f"\n\nWant to learn more about dog breeds? [Visit the AKC dog breeds page]({akc_link}) and search for {breed} to find detailed information."

	disclaimer = ("\n\n*Disclaimer: The external link provided leads to the American Kennel Club (AKC) dog breeds page. "
	"You may need to search for the specific breed on that page. "
	"I am not responsible for the content on external sites. "
	"Please refer to the AKC's terms of use and privacy policy.*")
	formatted_description += disclaimer

	return formatted_description

	def show_details(breed):
	breed_name = breed.split("More about ")[-1]
	description = get_dog_description(breed_name)
	return format_description(description, breed_name)

	with gr.Blocks(css="""
	.container {
	max-width: 900px;
	margin: 0 auto;
	padding: 20px;
	background-color: rgba(255, 255, 255, 0.9);
	border-radius: 15px;
	box-shadow: 0 0 20px rgba(0, 0, 0, 0.1);
	}
	.gr-form { display: flex; flex-direction: column; align-items: center; }
	.gr-box { width: 100%; max-width: 500px; }
	.output-markdown, .output-image {
	margin-top: 20px;
	padding: 15px;
	background-color: #f5f5f5;
	border-radius: 10px;
	}
	.examples {
	display: flex;
	justify-content: center;
	flex-wrap: wrap;
	gap: 10px;
	margin-top: 20px;
	}
	.examples img {
	width: 100px;
	height: 100px;
	object-fit: cover;
	}
	""") as iface:

	gr.HTML("<h1 style='font-family:Roboto; font-weight:bold; color:#2C3E50; text-align:center;'>🐶 Dog Breed Classifier 🔍</h1>")
	gr.HTML("<p style='font-family:Open Sans; color:#34495E; text-align:center;'>Upload a picture of a dog, and the model will predict its breed, provide detailed information, and include an extra information link!</p>")

	with gr.Row():
	input_image = gr.Image(label="Upload a dog image", type="pil")
	output_image = gr.Image(label="Annotated Image")

	output = gr.Markdown(label="Prediction Results")

	with gr.Row():
	btn1 = gr.Button("View More 1", visible=False)
	btn2 = gr.Button("View More 2", visible=False)
	btn3 = gr.Button("View More 3", visible=False)

	input_image.change(predict, inputs=input_image, outputs=[output, output_image, btn1, btn2, btn3])

	btn1.click(show_details, inputs=btn1, outputs=output)
	btn2.click(show_details, inputs=btn2, outputs=output)
	btn3.click(show_details, inputs=btn3, outputs=output)

	gr.Examples(
	examples=['Border_Collie.jpg', 'Golden_Retriever.jpeg', 'Saint_Bernard.jpeg', 'French_Bulldog.jpeg', 'Samoyed.jpg'],
	inputs=input_image
	)

	gr.HTML('For more details on this project and other work, feel free to visit my GitHub <a href="https://github.com/Eric-Chung-0511/Learning-Record/tree/main/Data%20Science%20Projects/Dog%20Breed%20Classifier">Dog Breed Classifier</a>')

	if __name__ == "__main__":
	iface.launch()