started unlearning setup
This commit is contained in:
4
Data.py
4
Data.py
@@ -80,6 +80,10 @@ def select_top_ids(dataset, class_size):
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# split class images to train and test set.
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def get_indices(dataset, identities, split_at, size = 30):
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if split_at >= size: # debug safety
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raise ValueError(f"Split point ({split_at}) must be less than total size ({size}).")
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train_indices = []
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test_indices = []
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48
OOP.py
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48
OOP.py
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@@ -0,0 +1,48 @@
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# This is from wikipedia pseudocode implementation of a single
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# ThresholdLogic Unit.
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# done to make me understand OOP the Python way
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# no need for brackets if not inheriting
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class ThresholdLogicUnit:
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# define members in init
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def __init__(self, threshold, weights):
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self.threshold = threshold
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self.weights = weights
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# If a function has to make use of member variables
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# it has to have self as param
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def fire(self,inputs):
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tots = 0
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#for i in range(0,inputs.size()):
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for val, weight in zip(inputs, self.weights):
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if val:
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tots+= weight
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return tots > self.threshold
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def main():
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# data
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weights = [0.5, -0.2, 0.8]
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threshold = 1.0
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# Instantiate the class
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tlu = ThresholdLogicUnit(threshold, weights)
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# Test
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test_inputs = [1, 1, 0]
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result = tlu.fire(test_inputs)
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print(f"The unit fired: {result}")
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# The "Guard"
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if __name__ == "__main__":
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main()
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16
Tune.py
16
Tune.py
@@ -12,6 +12,8 @@ from datasets.UniversalIdentitySubset import UniversalIdentitySubset as Identity
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# models
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from architectures.Model import Model, Architecture
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from unlearning import LinearFiltration, WeightFiltration, CertifiedRemoval
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# numbre of classes
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CLASS_SIZE = 20
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# batch
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@@ -145,3 +147,17 @@ print("Evaluating loaded")
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reloaded.evaluate(
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loader = test_loader
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)
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strategies_to_test = [
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LinearFiltration(target_class_idx=12),
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WeightFiltration(target_class_idx=12),
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CertifiedRemoval(target_class_idx=12)
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]
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# Run the comparative benchmark seamlessly
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execution_profiles = {}
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for strategy in strategies_to_test:
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# Each iteration clones weights back to fine-tuned state before running
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runtime = my_model.unlearn(strategy, forget_loader, retain_loader)
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execution_profiles[strategy.__class__.__name__] = runtime
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@@ -7,6 +7,7 @@ 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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class Model(ABC):
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def __init__(self, device, size):
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@@ -92,6 +93,21 @@ class Model(ABC):
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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 unlearn(self, strategy: Strategy, forget_loader, retain_loader):
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""" Executes a targeted unlearning strategy and profiles efficiency """
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print(f"Executing: {strategy.__class__.__name__}...")
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start_time = time.time()
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# Delegate the actual algorithmic weight/logit manipulation to the strategy
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strategy.apply(self.network, forget_loader, retain_loader)
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elapsed_time = time.time() - start_time
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print(f"{strategy.__class__.__name__} completed in {elapsed_time:.4f} seconds.")
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return elapsed_time
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# Using the factory patern here
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@@ -23,14 +23,14 @@ class ResNet50(Model):
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m = models.resnet50(weights=models.ResNet50_Weights.DEFAULT)
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# freez all layers
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for param in m.parameters():
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param.requires_grad = False
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#for param in m.parameters():
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#param.requires_grad = False
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# unfreez the last two
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# NOTE: Freezing everything and unfrizing the last 3 yeilded the best performance
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for param in m.layer2.parameters(): param.requires_grad = True
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for param in m.layer3.parameters(): param.requires_grad = True
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for param in m.layer4.parameters(): param.requires_grad = True
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#for param in m.layer2.parameters(): param.requires_grad = True
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#for param in m.layer3.parameters(): param.requires_grad = True
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#for param in m.layer4.parameters(): param.requires_grad = True
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m.fc = nn.Linear(m.fc.in_features, self.size)
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return m
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111
js_evaluator/JS_Evaluator.py
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111
js_evaluator/JS_Evaluator.py
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@@ -0,0 +1,111 @@
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import torch
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import torch.nn as nn
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import torch.nn.functional as F
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from torch.utils.data import DataLoader
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import torchvision.models as models
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class ZeroRetrainForgettingEvaluator:
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def __init__(self, unlearned_model: nn.Module, num_classes: int):
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"""
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Initializes the ZRF Evaluator.
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Args:
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unlearned_model (nn.Module): Your fine-tuned & unlearned ResNet-50.
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num_classes (int): Number of classes used in your CelebA task.
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"""
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# select device
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if torch.cuda.is_available():
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self.device = torch.device("cuda")
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elif hasattr(torch, "xpu") and torch.xpu.is_available():
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self.device = torch.device("xpu") # For Intel GPUs using IPEX
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else:
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self.device = torch.device("cpu")
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print(f"[INFO] Using device: {self.device}")
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# prepare the unlearned model
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self.unlearned_model = unlearned_model.to(self.device)
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self.unlearned_model.eval()
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# Instantiate a structurally matching, completely random model
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print(f"[INFO] Initializing random baseline ResNet-50 with {num_classes} classes...")
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self.random_model = self.get_random_model(num_classes)
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self.random_model = self.random_model.to(self.device)
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self.random_model.eval()
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# gets randomly initialised model
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# for comparison with unlearned model
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def get_random_model(num_classes):
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print(f"[INFO] Initializing random baseline ResNet-50 with {num_classes} classes...")
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model = models.resnet50(weights=None)
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model.fc = nn.Linear(model.fc.in_features, num_classes)
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return model
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# compute divergence
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def _compute_js_divergence(self, p: torch.Tensor, q: torch.Tensor) -> float:
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"""
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Computes the Jensen-Shannon (JS) Divergence between two probability distributions.
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Args:
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p, q (Tensor): Tensors of shape (batch_size, num_classes) containing probabilities.
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"""
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# Avoid log(0) issues by adding a tiny epsilon
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eps = 1e-12
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p = torch.clamp(p, eps, 1.0)
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q = torch.clamp(q, eps, 1.0)
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# Calculate the midpoint distribution
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m = 0.5 * (p + q)
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# Compute KL Divergence natively: KL(P || M) and KL(Q || M)
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kl_pm = torch.sum(p * (torch.log(p) - torch.log(m)), dim=1)
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kl_qm = torch.sum(q * (torch.log(q) - torch.log(m)), dim=1)
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# JS Divergence is the average of both KL divergences
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js_div = 0.5 * (kl_pm + kl_qm)
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# Return the mean divergence across the entire batch
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return js_div.mean().item()
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def evaluate_forget_class(self, dataset, batch_size: int = 32) -> float:
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"""
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Evaluates the unlearned model against the random model using images
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from the forgotten class/identity.
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Args:
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dataset (Dataset): A PyTorch Dataset containing images of the forget set.
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batch_size (int): Batch size for evaluation.
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Returns:
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float: The ZRF score (JS Divergence). A lower divergence means
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the unlearned model is behaving exactly like a random model.
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"""
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dataloader = DataLoader(dataset, batch_size=batch_size, shuffle=False)
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total_js_div = 0.0
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total_samples = 0
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# No gradients needed for evaluation
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with torch.no_grad():
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for images, _ in dataloader:
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images = images.to(self.device)
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batch_len = images.size(0)
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# Get raw outputs (logits)
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unlearned_logits = self.unlearned_model(images)
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random_logits = self.random_model(images)
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# Convert logits to probability distributions via Softmax
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unlearned_probs = F.softmax(unlearned_logits, dim=1)
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random_probs = F.softmax(random_logits, dim=1)
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# Calculate JS divergence for this batch
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batch_js = self._compute_js_divergence(unlearned_probs, random_probs)
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# Weighted average based on batch size (handles final smaller batches perfectly)
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total_js_div += batch_js * batch_len
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total_samples += batch_len
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final_zrf_score = total_js_div / total_samples
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return final_zrf_score
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0
unlearning/CertifiedRemoval.py
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0
unlearning/CertifiedRemoval.py
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29
unlearning/LinearFiltration.py
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29
unlearning/LinearFiltration.py
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@@ -0,0 +1,29 @@
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import torch
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from Strategy import Strategy
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class NormalizingLinearFiltration(Strategy):
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def __init__(self, target_class_idx):
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self.target_class_idx = target_class_idx
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def apply(self, model, forget_loader, retain_loader):
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model.eval()
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# Freeze parameters structurally
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for param in model.parameters():
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param.requires_grad = False
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with torch.no_grad():
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# we modify only classification head
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# Shape: [num_classes, feature_dim]
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W = model.fc.weight.data
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# Compute the normalization transformation projection matrix (A)
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# (In your full code, calculate A here matching Baumhauer et al.'s equations)
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num_classes = W.shape[0]
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A = torch.eye(num_classes, device=W.device)
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# Mask/blend target class index distribution configurations here...
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A[self.target_class_idx, :] = 0.0
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# 3. Direct weight matrix override: W_filtered = A * W
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sanitized_W = torch.mm(A, W)
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model.fc.weight.copy_(sanitized_W)
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0
unlearning/Strategy.py
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0
unlearning/Strategy.py
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0
unlearning/WeightFiltration.py
Normal file
0
unlearning/WeightFiltration.py
Normal file
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