138 lines
5.6 KiB
Python
138 lines
5.6 KiB
Python
import torch
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import torch.nn as nn
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import torch.optim as optim
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from torch.utils.data import DataLoader, ConcatDataset, Subset
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from unlearning.Strategy import Strategy
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import numpy as np
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from sklearn.metrics import classification_report
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from architectures.WFNet import WF_Net_Model
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from sets.Data import vertical_split
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class WeightFiltration(Strategy):
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def __init__(self,
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target_class_index: int,
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arch,
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num_classes: int = 20,
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epochs: int = 6,
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lr: float = 100.0,
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gamma: float = 0.01,
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lambda_1 = 25
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):
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super().__init__(target_class_index=target_class_index)
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self.epochs = epochs
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self.lr = lr
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self.gamma = gamma
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self.num_classes = num_classes
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self.wf_model = None
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self.lambda_1 = lambda_1
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self.arch = arch
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def _optimise_filter(self, model: nn.Module, retain_loader: DataLoader, forget_loader: DataLoader, device) -> nn.Module:
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# new WF_Model instance
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wf_model = WF_Net_Model(
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device=device,
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arch=self.arch,
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size=self.num_classes,
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original_model=model,
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target_class_index=self.target_class_index
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)
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wf_net = wf_model.get()
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optimizer = optim.SGD([wf_net.alpha], lr=self.lr)
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# Use reduction='none' so we can manipulate individual item losses
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criterion_none = nn.CrossEntropyLoss(reduction='none')
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criterion_mean = nn.CrossEntropyLoss()
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for epoch in range(self.epochs):
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t_loss_r, t_loss_f = 0.0, 0.0
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steps = 0
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# forget and retain
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for (r_inputs, r_labels), (f_inputs, f_labels) in zip(retain_loader, forget_loader):
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r_inputs, r_labels = r_inputs.to(device), r_labels.to(device)
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f_inputs, f_labels = f_inputs.to(device), f_labels.to(device)
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optimizer.zero_grad()
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# retain data paired with randomly selected rows of alpha to compute the retaining loss
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random_offset = torch.randint(0, self.num_classes - 1, size=r_labels.shape, device=device)
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gate_signals_r = torch.where(random_offset >= r_labels, random_offset + 1, random_offset)
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outputs_r = wf_net(r_inputs, target_class_indices=gate_signals_r)
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loss_r = criterion_mean(outputs_r, r_labels)
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# Forget set is paired with corresponding labels as row selectors for alpha
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# and used to compute unlearning loss
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outputs_f = wf_net(f_inputs, target_class_indices=f_labels)
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# Calculate loss for every single item in the batch at once
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per_item_forget_loss = criterion_none(outputs_f, f_labels)
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# Use a scatter/sum approach to get class-wise losses without a Python loop
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# Create a mask of unique classes present in this batch
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unique_classes, inverse_indices = torch.unique(f_labels, return_inverse=True)
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classes_in_batch = unique_classes.size(0)
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if classes_in_batch > 0:
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# average CE loss per class
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class_loss_sums = torch.zeros(classes_in_batch, device=device)
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class_loss_sums.scatter_add_(0, inverse_indices, per_item_forget_loss)
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class_counts = torch.zeros(classes_in_batch, device=device)
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class_counts.scatter_add_(0, inverse_indices, torch.ones_like(per_item_forget_loss))
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mean_class_ce_loss = class_loss_sums / class_counts
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# Poppi et al. suggest employing reciprocal of the forget loss
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# to avoid shortcomings of negative gradient approach
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loss_f = torch.mean(1.0 / (mean_class_ce_loss + 1e-6))
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else:
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loss_f = torch.tensor(0.0, device=device)
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# Regularisation penalty
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loss_reg = torch.sum(1.0 - torch.sigmoid(wf_net.alpha))
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# Backpropagation
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total_loss = loss_r + (self.lambda_1 * loss_f) + (self.gamma * loss_reg)
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total_loss.backward()
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optimizer.step()
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# Keep tracking stats
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t_loss_r += loss_r.item()
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t_loss_f += loss_f.item()
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steps += 1
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print(f" Epoch {epoch+1}/{self.epochs} | Retain Loss: {t_loss_r/steps:.4f} | Forget Loss: {t_loss_f/steps:.4f}")
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return wf_model
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def _run(self, model: nn.Module, forget_loader: DataLoader, retain_loader: DataLoader) -> nn.Module:
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device = next(model.parameters()).device
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model.eval()
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if self.wf_model is None:
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print("Initializing and compiling global WF-Net matrix (Run Once for all classes)...")
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self.wf_model = self._optimise_filter(
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model,
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retain_loader=retain_loader,
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forget_loader=forget_loader,
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device=device
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)
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else:
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print(f"Gating matrix loaded. Switching layout to target class index: {self.target_class_index}")
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self.wf_model.target_class_index = self.target_class_index
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return self.wf_model
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def _split_data(self, dataset):
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return vertical_split(
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dataset= dataset,
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batch_size=32,
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num_classes=self.num_classes
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)
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