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@article{He_2025_CVPR,
author = {He, Jiangpeng and Duan, Zhihao and Zhu, Fengqing},
title = {CL-LoRA: Continual Low-Rank Adaptation for Rehearsal-Free Class-Incremental Learning},
journal = {Proceedings of the Computer Vision and Pattern Recognition Conference (CVPR)},
month = {June},
year = {2025},
pages = {30534-30544}
}
Adapted from https://github.com/JiangpengHe/CL-LoRA
"""
import math
import torch
import numpy as np
import torch.nn as nn
from tqdm import tqdm
from torch import optim
from copy import deepcopy
from torch.nn import functional as F
from .backbone.transformer import MultiHeadAttention_CL_LoRA
def _KD_loss(pred, soft, T):
pred = torch.log_softmax(pred / T, dim=1)
soft = torch.softmax(soft / T, dim=1)
return -1 * torch.mul(soft, pred).sum() / pred.shape[0]
def compute_orthogonality_loss(previous_weights_list, current_weights, epsilon=1e-8):
total_ortho_loss = 0.0
current_norm = torch.norm(current_weights.flatten())
current_normalized = current_weights.flatten() / (current_norm + epsilon)
for prev_weights in previous_weights_list:
# Normalize previous weights
prev_norm = torch.norm(prev_weights.flatten())
prev_normalized = prev_weights.flatten() / (prev_norm + epsilon)
# Compute absolute dot product (should be close to 0 for orthogonal vectors)
dot_product = torch.abs(torch.sum(prev_normalized * current_normalized))
total_ortho_loss += dot_product
# Average over all previous tasks
if len(previous_weights_list) > 0:
total_ortho_loss /= len(previous_weights_list)
return total_ortho_loss
class CosineLinearFeature(nn.Module):
def __init__(self, in_features, out_features, nb_proxy=1, to_reduce=False, sigma=True):
super(CosineLinearFeature, self).__init__()
self.in_features = in_features
self.out_features = out_features * nb_proxy
self.nb_proxy = nb_proxy
self.to_reduce = to_reduce
self.weight = nn.Parameter(torch.Tensor(self.out_features, in_features))
if sigma:
self.sigma = nn.Parameter(torch.Tensor(1))
else:
self.register_parameter('sigma', None)
self.reset_parameters()
def reset_parameters(self):
stdv = 1. / math.sqrt(self.weight.size(1))
self.weight.data.uniform_(-stdv, stdv)
if self.sigma is not None:
self.sigma.data.fill_(1)
def reset_parameters_to_zero(self):
self.weight.data.fill_(0)
def forward(self, input):
out = F.linear(F.normalize(input, p=2, dim=1), F.normalize(self.weight, p=2, dim=1))
if self.to_reduce:
# Reduce_proxy
out = reduce_proxies(out, self.nb_proxy)
if self.sigma is not None:
out = self.sigma * out
return {'logits': out}
def forward_diagonal(self, input, cur_task, alpha=0., beta=0.0, init_cls=10, inc=10, out_dim=768, use_init_ptm=False):
for i in range(cur_task + 1):
if i == 0:
start_cls = 0
end_cls = init_cls
else:
start_cls = init_cls + (i - 1) * inc
end_cls = start_cls + inc
input1 = F.normalize(input[:, i * out_dim:(i + 1) * out_dim], p=2, dim=1)
weight1 = F.normalize(self.weight[start_cls:end_cls, i * out_dim:(i + 1) * out_dim], p=2, dim=1)
out = F.linear(input1, weight1)
if i == 0:
out_all = out
else:
out_all = torch.cat((out_all, out), dim=1) if i != 0 else out
if self.to_reduce:
# Reduce_proxy
out_all = reduce_proxies(out_all, self.nb_proxy)
if self.sigma is not None:
out_all = self.sigma * out_all
return {'logits': out_all}
class Model(nn.Module):
def __init__(self, backbone, device, **kwargs):
super().__init__()
self.backbone = backbone
self.inc = kwargs["inc_cls_num"]
self.init_cls = kwargs["init_cls_num"]
self._cur_task = -1
self.out_dim = 768
self.fc = None
self.alpha = 0.
self.beta = 0
self.fc_list = nn.ModuleList()
self.fc_list_task = nn.ModuleList()
self.adapter_list = nn.ModuleList()
self.init_proto = None
self._device = device
def freeze(self):
for name, param in self.named_parameters():
param.requires_grad = False
@property
def feature_dim(self):
return self.out_dim * (self._cur_task + 1)
def update_fc(self, nb_classes):
self._cur_task += 1
if self._cur_task == 0:
self.proxy_fc = self.generate_fc(self.out_dim, self.init_cls).to(self._device)
else:
self.proxy_fc = self.generate_fc(self.out_dim, self.inc).to(self._device)
init_proto = self.generate_fc(self.out_dim, nb_classes).to(self._device)
if self.init_proto is not None:
old_nb_classes = self.init_proto.out_features
weight = deepcopy(self.init_proto.weight.data)
init_proto.weight.data[: old_nb_classes, :] = nn.Parameter(weight)
del self.init_proto
self.init_proto = init_proto
fc = self.generate_fc(self.feature_dim, nb_classes).to(self._device)
fc.reset_parameters_to_zero()
if self.fc is not None:
old_nb_classes = self.fc.out_features
weight = deepcopy(self.fc.weight.data)
fc.sigma.data = self.fc.sigma.data
fc.weight.data[: old_nb_classes, : -self.out_dim] = nn.Parameter(weight)
del self.fc
self.fc = fc
self.fc.requires_grad_(False)
def add_fc(self):
self.fc_list.append(self.proxy_fc.requires_grad_(False))
del self.proxy_fc
def generate_fc(self, in_dim, out_dim):
fc = CosineLinearFeature(in_dim, out_dim)
return fc
def forward_kd(self, x, t_idx):
x_new, x_teacher = self.backbone.forward_general_cls(x, t_idx)
out_new, out_teacher = self.proxy_fc(x_new), self.proxy_fc(x_teacher)
return out_new, out_teacher
def forward(self, x, test=False):
if test == False:
x = self.backbone.forward(x, test=False)
out = self.proxy_fc(x)
out.update({"features": x})
return out
else:
x_input = self.backbone.forward(x, test=True)
out = self.fc.forward_diagonal(x_input, cur_task=self._cur_task, alpha=0., init_cls=self.init_cls, inc=self.inc, use_init_ptm=False, beta=0)
out.update({"features": x_input})
return out
class CL_LoRA(nn.Module):
def __init__(self, backbone, device, **kwargs):
super().__init__()
self.device = device
self.init_cls_num = kwargs["init_cls_num"]
self.inc_cls_num = kwargs["inc_cls_num"]
self.task_num = kwargs["task_num"]
self._known_classes = 0
self._total_classes = 0
self._cur_task = 0
self._network = Model(backbone, device, **kwargs)
self.attention_modules = [module for module in self._network.modules() if isinstance(module, MultiHeadAttention_CL_LoRA)]
self.lora_modules = [[] for _ in range(self.task_num)]
self.lora_scale_weights = [[] for _ in range(self.task_num)]
self.optim = None
def observe(self, data):
x, y = data['image'].to(self.device), data['label'].to(self.device)
aux_targets = y - self._known_classes
logits = self._network(x, test=False)['logits']
loss = F.cross_entropy(logits, aux_targets)
if self._cur_task > 0:
kd_ratio = 5.
Temperature = 2
out_new, out_teacher = self._network.forward_kd(x, self._cur_task)
out_new_logits = out_new["logits"]
out_teacher_logits = out_teacher["logits"]
loss_kd = kd_ratio * _KD_loss(out_new_logits, out_teacher_logits, T=Temperature)
self.optim.zero_grad()
loss_kd.backward()
for j in range(len(self._network.backbone.feat.general_pos)):
pos = self._network.backbone.feat.adapt_pos.index(self._network.backbone.feat.general_pos[j])
for jj in range(len(self._network.backbone.feat.msa)):
if self._network.backbone.feat.msa[jj] == 1:
temp_weights = 1. * torch.norm(self._network.backbone.feat.old_adapter_list[self._cur_task-1][pos][jj].lora_A.weight,dim=1)
temp_weights = 1. * len(temp_weights) * temp_weights / torch.sum(temp_weights)
self._network.backbone.feat.cur_adapter[pos][jj].lora_A.weight.grad = temp_weights.unsqueeze(1) * self._network.backbone.feat.cur_adapter[pos][jj].lora_A.weight.grad
self.optim.step()
orth_loss_specific = compute_orthogonality_loss(self._network.backbone.feat.block_weight_list, self._network.backbone.feat.block_weight)
loss += 0.0001 * orth_loss_specific
preds = logits.max(1)[1]
correct_count = preds.eq(aux_targets).sum().item()
acc = correct_count / y.size(0)
return preds, acc, loss
def inference(self, data):
x, y = data['image'].to(self.device), data['label'].to(self.device)
logits = self._network(x, True)["logits"]
preds = logits.max(1)[1]
correct_count = preds.eq(y).sum().item()
acc = correct_count / y.size(0)
return preds, acc
@torch.no_grad()
def before_task(self, task_idx, buffer, train_loader, test_loaders):
if task_idx > 0:
self._known_classes = self._total_classes
self._network.freeze()
self._network.backbone.add_adapter_to_list()
self._cur_task = task_idx
self._total_classes += self.init_cls_num if task_idx == 0 else self.inc_cls_num
self._network.update_fc(self._total_classes)
for name, param in self._network.named_parameters():
if 'backbone.feat.cur_adapter' in name or 'proxy_fc.' in name or 'init_proto' in name:
param.requires_grad_(True)
else:
param.requires_grad_(False)
param.requires_grad_(False)
if 'lora' in name and 'cur_adapter' in name:
if any(f'er.{i}.' in name for i in range(6)) and 'lora_B' in name and 'cur_adapter':
pass
else:
param.requires_grad_(True)
elif f'proxy_fc' in name:
param.requires_grad_(True)
elif 'init_proto' in name:
param.requires_grad_(True)
elif 'block_weight' in name and 'old' not in name:
param.requires_grad_(True)
self._network = self._network.to(self.device)
@torch.no_grad()
def after_task(self, task_idx, buffer, train_loader, test_loaders):
self._network.add_fc()
train_loader.dataset.trfms = test_loaders[0].dataset.trfms
self.replace_fc(train_loader)
self._known_classes += self.init_cls_num if task_idx == 0 else self.inc_cls_num
def replace_fc(self, train_loader):
model = self._network
model = model.eval()
with torch.no_grad():
for index in range(0, self._cur_task + 1):
embedding_list, label_list = [], []
for i, batch in enumerate(train_loader):
data, label = batch['image'], batch['label']
data = data.to(self.device)
label = label.to(self.device)
embedding = model.backbone.forward_proto(data, adapt_index=index)
embedding_list.append(embedding.cpu())
label_list.append(label.cpu())
embedding_list = torch.cat(embedding_list, dim=0)
label_list = torch.cat(label_list, dim=0)
class_list = np.unique(train_loader.dataset.labels)
for class_index in class_list:
data_index = (label_list == class_index).nonzero().squeeze(-1)
embedding = embedding_list[data_index]
proto = embedding.mean(0)
model.fc.weight.data[class_index, index*self._network.out_dim:(index+1)*self._network.out_dim] = proto
def get_parameters(self, config):
return self._network.parameters()
def set_optim(self, optim):
self.optim = optim |