217 lines
7.2 KiB
Python
217 lines
7.2 KiB
Python
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from abc import ABC, abstractmethod
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import torch
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import torch.nn as nn
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import torch.optim as optim
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import time
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import numpy as np
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from sklearn.metrics import classification_report
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from pathlib import Path
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#from unlearning.Strategy import Strategy
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import copy
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from torch.optim.lr_scheduler import CosineAnnealingLR
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import Util
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class Model(ABC):
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# need to add a weight decay here
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def __init__(self, device, size):
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self.device = device
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self.size = size
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self.model = self.get().to(self.device)
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@abstractmethod
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def get(self):
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pass
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'''
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Have to have a new param here as mode, for example it would be base, or retrain
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param mode = "base" or "retrain"
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that way I can save time it takes to train and retrain.
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file would be solved with Util functions
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log_file = Path(f"reports/{mode}/{self.__class__.__name__}/time_metrics.txt")
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Util._initialize_log_file(log_file):
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strt = time.perf_counter()
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end = time.perf_counter()
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and then save logs
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execution_time = end -strt
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Util.log_metric(log_file, execution_time: float):
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'''
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def train(self, epochs, loader, rate, mode = "retrain"):
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criterion = nn.CrossEntropyLoss()
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optimizer = optim.Adam(filter(lambda p: p.requires_grad, self.model.parameters()), lr=rate, weight_decay=0.1)
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scheduler = CosineAnnealingLR(optimizer, T_max=epochs, eta_min=1e-6)
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# to save reports
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# file_path = Path(f"{mode}/{self.__class__.__name__.lower()}/time_metrics.txt")
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# Util._initialize_log_file(file_path)
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print(f"Starting training on {self.device}...")
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# start_time = time.time()
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# training phase
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self.model.train()
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for epoch in range(epochs):
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total_loss = 0.0
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for inputs, labels in loader:
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inputs, labels = inputs.to(self.device), labels.to(self.device)
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# zero param gradients
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optimizer.zero_grad()
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# forward pass
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outputs = self.model(inputs)
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# comoutew loss
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loss = criterion(outputs, labels)
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# backward pass
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loss.backward()
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optimizer.step()
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total_loss += loss.item()
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scheduler.step()
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print(f"Epoch {epoch+1}/{epochs} | Loss: {total_loss / len(loader):.4f}")
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#end_time = time.time()
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#execution_time = end_time - start_time
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#Util.log_metric(log_file=file_path, execution_time=execution_time)
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if self.device.type == 'cuda': torch.cuda.synchronize()
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print(f"Training complete.")
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def save(self, filename=None):
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save_dir = Path("trained_models")
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save_dir.mkdir(parents=True, exist_ok=True)
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# Filename (Default to class name if not provided)
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if filename is None:
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filename = f"{self.__class__.__name__.lower()}.pth"
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if not filename.endswith('.pth'):
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filename += '.pth'
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save_path = save_dir / filename
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torch.save(self.model.state_dict(), save_path)
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print(f'Model saved to {save_path}')
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def load(self, arch):
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file_path = Path("trained_models") / f'{arch.name.lower()}.pth'
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# does file exist
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if not file_path.exists():
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raise FileNotFoundError(f'No checkpoint found at: {file_path}')
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# Load the weights
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state_dict = torch.load(file_path, map_location=self.device, weights_only=True)
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self.model.load_state_dict(state_dict)
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self.model.to(self.device)
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print(f'Model loaded from {file_path}')
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def evaluate(self, loader, mode="eval"):
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"""
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Evaluates the model, prints terminal reports, and routes metrics to
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a file logger based on the current context mode.
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"""
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self.model.eval()
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all_preds, all_labels = [], []
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print(f"\nEvaluating Domain: [{mode}]...")
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with torch.no_grad():
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for inputs, labels in loader:
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inputs, labels = inputs.to(self.device), labels.to(self.device)
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outputs = self.model(inputs)
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_, predicted = torch.max(outputs, 1)
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all_preds.extend(predicted.cpu().numpy())
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all_labels.extend(labels.cpu().numpy())
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# Extract only the active classes evaluated in this loader slice
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classes = sorted(list(set(all_labels)))
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accuracy = 100 * (np.array(all_preds) == np.array(all_labels)).sum() / len(all_labels)
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print(f"Test Accuracy: {accuracy:.2f}%")
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# 1. Print standard text report to terminal
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print(classification_report(all_labels, all_preds, labels=classes, zero_division=0))
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# 2. Extract structured dictionary metrics
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report_dict = classification_report(
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all_labels,
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all_preds,
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labels=classes,
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output_dict=True,
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zero_division=0
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)
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# 3. Delegate file tracking to isolated helper method
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#self._log_to_csv(mode, accuracy,report_dict)
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return accuracy, report_dict
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# factory
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@staticmethod
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def create(arch, device, size):
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print(f'>> MODEL ARCHITECTURE >> {arch.name}.')
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match arch:
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# ResNet18
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case Architecture.RESNET18:
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from architectures.ResNet18 import ResNet18
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return ResNet18(device, size)
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# ResNet34
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case Architecture.RESNET34:
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from architectures.ResNet34 import ResNet34
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return ResNet34(device, size)
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# ResNet50
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case Architecture.RESNET50:
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from architectures.ResNet50 import ResNet50
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return ResNet50(device, size)
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# INCEPTION
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case Architecture.INCEPTION:
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from architectures.Inception import Inception
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return Inception(device, size)
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# DENSENET121
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case Architecture.DENSENET121:
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from architectures.DenseNet121 import DenseNet121
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return DenseNet121(device, size)
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# googleNet
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case Architecture.GOOGLENET:
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from architectures.GoogleNet import GoogleNet
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return GoogleNet(device, size)
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# EfficientNet
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case Architecture.EFFICIENTNET:
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from architectures.EfficentNet import EfficientNet
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return EfficientNet(device, size)
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#ShuffleNet
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case Architecture.SHUFFLENET:
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from architectures.ShuffleNet import ShuffleNet
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return ShuffleNet(device, size)
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# wide ResNet
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case Architecture.WIDE_RESNET:
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from architectures.WideResNet import WideResNet
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return WideResNet(device, size)
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case _:
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raise ValueError(f"Unknown model: {arch}")
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# model architectures
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from enum import Enum, auto
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class Architecture(Enum):
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RESNET18 = auto()
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RESNET50 = auto()
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RESNET34 = auto()
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INCEPTION = auto()
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DENSENET121 = auto()
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GOOGLENET = auto()
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EFFICIENTNET = auto()
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SHUFFLENET = auto()
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WIDE_RESNET = auto() |