import time from clip import clip import torch.nn as nn import torch.optim from opts import opts # The options for the project # from trainer import validate # For the validate (test) process from models.DomainClassifierTarget import DClassifierForTarget from models.DomainClassifierSource import DClassifierForSource from utils.loss_utils import TargetDiscrimLoss, ConcatenatedCELoss from utils.utils import prepare_directories, set_seed, get_dataset_loader, configure_clip_encoders, save_model, \ set_adapter_weights, get_text_feature, AverageMeter, accuracy, calculate_zeroshot_weights from Adapter import Weight_Adapter import logging import torch.nn.functional as F def train(classnames, templates, source_train_loader, source_train_loader_batch, model, adapter, optimizer, epoch, args, scheduler, criterion, CLIP_Text, Text_Encoder, CLIP_Image, Image_Encoder): batch_time = AverageMeter() data_time = AverageMeter() losses_classifier = AverageMeter() losses_G = AverageMeter() losses_T = AverageMeter() top1_source = AverageMeter() top1_target = AverageMeter() CLIP_Text.eval() CLIP_Image.eval() Text_Encoder.train() Image_Encoder.train() model.eval() logit_scale = model.logit_scale.exp() adapter.train() new_epoch_flag = False end = time.time() concatenatedCELoss = ConcatenatedCELoss(num_classes=len(classnames)).cuda() try: (image, label, _) = source_train_loader_batch.__next__()[1] except StopIteration: epoch = epoch + 1 new_epoch_flag = True source_train_loader_batch = enumerate(source_train_loader) (image, label, _) = source_train_loader_batch.__next__()[1] target_target = label.cuda() # 自监督标签 label_self_supervised = label.cuda() indices = torch.randperm(len(label)) target_source = label[indices].cuda() # target_source = label.cuda() input_target = image.cuda() input_source = calculate_zeroshot_weights(classnames, target_source, templates, CLIP_Text, Text_Encoder) data_time.update(time.time() - end) target_target_temp = target_target + len(classnames) target_source_temp = target_source + len(classnames) target_target_temp = target_target_temp.cuda() # clip图片编码器 with torch.no_grad(): input_target_temp = CLIP_Image(input_target) input_target_add = Image_Encoder(input_target_temp) # 文本直接输入全连接层 output_source = adapter(input_source) * logit_scale # 图片直接输入全连接层 output_target = adapter(input_target_add) * logit_scale self_input_source = calculate_zeroshot_weights(classnames, label_self_supervised, templates, CLIP_Text, Text_Encoder) # 自监督文本输入全连接层 # self_output_source = adapter(self_input_source) # self_output_source = F.normalize(self_output_source[:,:len(classnames)]) self_output_source = F.normalize(self_input_source) # 自监督图像特征 # self_output_target = output_target / logit_scale # self_output_target = F.normalize(self_output_target[:,len(classnames):]) self_output_target = F.normalize(input_target_add) # # 构造自监督标签0-255 self_supervised_labels = torch.arange(self_output_source.shape[0], device="cuda:0", dtype=torch.long) logits_per_image = logit_scale * self_output_target @ self_output_source.T logits_per_text = logit_scale * self_output_source @ self_output_target.T loss_self_supervised_1 = ( F.cross_entropy(logits_per_image, self_supervised_labels) + F.cross_entropy(logits_per_text, self_supervised_labels) ) / 2 # 自监督文本输入全连接层 self_output_source = adapter(self_input_source) self_output_source = F.normalize(self_output_source[:, :len(classnames)]) # self_output_source = F.normalize(self_input_source) # 自监督图像特征 self_output_target = output_target / logit_scale self_output_target = F.normalize(self_output_target[:, len(classnames):]) # self_output_target = F.normalize(input_target_add) # # 构造自监督标签0-255 self_supervised_labels = torch.arange(self_output_source.shape[0], device="cuda:0", dtype=torch.long) logits_per_image = logit_scale * self_output_target @ self_output_source.T logits_per_text = logit_scale * self_output_source @ self_output_target.T loss_self_supervised_2 = ( F.cross_entropy(logits_per_image, self_supervised_labels) + F.cross_entropy(logits_per_text, self_supervised_labels) ) / 2 loss_self_supervised = loss_self_supervised_2 + loss_self_supervised_1 # 有监督分类的交叉熵损失 loss_task_s_Cs = criterion(output_source[:, :len(classnames)], target_source) loss_task_s_Ct = criterion(output_target[:, len(classnames):], target_target) # 对于源域数据,它希望让分类器上半部分所占的概率尽可能大,对于目标域数据,它希望让分类器下半部分所占的概率尽可能大。 loss_domain_st_Cst_part1 = criterion(output_source, target_source) loss_domain_st_Cst_part2 = criterion(output_target, target_target_temp) # 类级别混淆 loss_category_st_G = 0.5 * criterion(output_target, target_target) + 0.5 * criterion(output_source, target_source_temp) # 域级别混淆 # loss_domain_st_G = 0.5 * criterion_classifier_target(output_source) + 0.5 * criterion_classifier_source( # output_target) lam = 1 # 2 / (1 + math.exp(-1 * 10 * epoch / args.epochs)) - 1 # if(epoch<30): # self_lam= 5 # else: self_lam = 1 loss_confusion_target = concatenatedCELoss(output_target) loss_classifier = loss_task_s_Cs + loss_task_s_Ct + loss_domain_st_Cst_part1 + loss_domain_st_Cst_part2 loss_G = loss_category_st_G + lam * loss_confusion_target loss_T = loss_G + loss_classifier + self_lam * loss_self_supervised prec1_source, _ = accuracy(output_source.data[:, :len(classnames)], target_source, topk=(1, 5)) prec1_target, _ = accuracy(output_target.data[:, len(classnames):], target_target, topk=(1, 5)) losses_classifier.update(loss_classifier.item(), input_source.size(0)) losses_G.update(loss_G.item(), input_source.size(0)) losses_T.update(loss_T.item(), input_source.size(0)) top1_source.update(prec1_source[0], input_source.size(0)) top1_target.update(prec1_target[0], input_source.size(0)) optimizer.zero_grad() loss_T.backward() optimizer.step() scheduler.step() batch_time.update(time.time() - end) if (epoch + 1) % args.print_freq == 0 or epoch == 0: print('Train: [{0}/{1}]\t' 'Time {batch_time.val:.3f} ({batch_time.avg:.3f})\t' 'Data {data_time.val:.3f} ({data_time.avg:.3f})\t' 'Loss@C {loss_c.val:.4f} ({loss_c.avg:.4f})\t' 'Loss@G {loss_g.val:.4f} ({loss_g.avg:.4f})\t' 'Loss@T {loss_t.val:.4f} ({loss_t.avg:.4f})\t' 'top1S {top1S.val:.3f} ({top1S.avg:.3f})\t' 'top1T {top1T.val:.3f} ({top1T.avg:.3f})\t'.format( epoch, args.epochs, batch_time=batch_time, data_time=data_time, loss_c=losses_classifier, loss_g=losses_G, loss_t=losses_T, top1S=top1_source, top1T=top1_target)) return source_train_loader_batch, epoch, new_epoch_flag def validate(best_epoch,classnames, templates, val_loader, model, adapter, epoch, args, criterion, best_prec, CLIP_Text, Text_Encoder, CLIP_Image, Image_Encoder): batch_time = AverageMeter() losses_source = AverageMeter() losses_target = AverageMeter() top1_source = AverageMeter() top1_target = AverageMeter() CLIP_Text.eval() CLIP_Image.eval() Text_Encoder.eval() Image_Encoder.eval() model.eval() adapter.eval() end = time.time() logit_scale = model.logit_scale.exp() for i, (image, label, _) in enumerate(val_loader): image = image.cuda() label = label.cuda() input_source = calculate_zeroshot_weights(classnames, label, templates, CLIP_Text, Text_Encoder) input_target = image.cuda() target_target = label.cuda() target_source = label.cuda() # clip图片编码器 with torch.no_grad(): input_target_temp = CLIP_Image(input_target) input_target_add = Image_Encoder(input_target_temp) # output_source = adapter(input_source) * logit_scale output_target = adapter(input_target_add) * logit_scale output_source = output_target # 3 loss_source = criterion(output_source[:, :len(classnames)], target_target) loss_target = criterion(output_target[:, len(classnames):], target_target) # measure accuracy and record loss prec1_source, _ = accuracy(output_source.data[:, :len(classnames)], target_target, topk=(1, 5)) prec1_target, _ = accuracy(output_target.data[:, len(classnames):], target_target, topk=(1, 5)) losses_source.update(loss_source.item(), image.size(0)) losses_target.update(loss_target.item(), image.size(0)) top1_source.update(prec1_source[0], image.size(0)) top1_target.update(prec1_target[0], image.size(0)) # measure elapsed time batch_time.update(time.time() - end) end = time.time() if i % args.print_freq == 0: print('Test: [{0}][{1}/{2}]\t' 'Time {batch_time.val:.3f} ({batch_time.avg:.3f})\t' 'LS {lossS.val:.4f} ({lossS.avg:.4f})\t' 'LT {lossT.val:.4f} ({lossT.avg:.4f})\t' 'top1S {top1S.val:.3f} ({top1S.avg:.3f})\t' 'top1T {top1T.val:.3f} ({top1T.avg:.3f})'.format( epoch, i, len(val_loader), batch_time=batch_time, lossS=losses_source, lossT=losses_target, top1S=top1_source, top1T=top1_target)) print(' * Top1@S {top1S.avg:.3f} Top1@T {top1T.avg:.3f}' .format(top1S=top1_source, top1T=top1_target)) prec = max(top1_target.avg, top1_source.avg).item() if prec > best_prec: best_prec = max(top1_target.avg, top1_source.avg).item() best_epoch = epoch print('best_epoch', best_epoch, ' * Current_best_target@T:', best_prec) return prec,best_epoch def main(): args = opts() set_seed(2023) model, preprocess = clip.load(args.name) model = model.cuda() model.float( ) classnames, templates, loader, train_loader = get_dataset_loader(args, preprocess) CLIP_Text, Text_Encoder, CLIP_Image, Image_Encoder = configure_clip_encoders(args, model, 0, 1) prepare_directories(args, CLIP_Text, CLIP_Image) # 分类层 weights = set_adapter_weights(model, classnames, templates) adapter = Weight_Adapter(args, classnames, weights).cuda() # 损失函数 criterion = nn.CrossEntropyLoss().cuda() criterion_classifier_target = DClassifierForTarget(nClass=len(classnames)).cuda() criterion_classifier_source = DClassifierForSource(nClass=len(classnames)).cuda() # 为模型的每个部分定义学习率和权重衰减 lr_adapter = 0.0001 lr_image_encoder = 0.00001 lr_text_encoder = 0.00001 weight_decay = 0.00001 # ADAM_BETAS 是用于控制移动平均衰减率的元组 ADAM_BETAS = (0.9, 0.999) # 创建 AdamW 优化器实例 optimizer = torch.optim.AdamW([ {'params': adapter.parameters(), 'lr': lr_adapter, 'weight_decay': weight_decay, 'betas': ADAM_BETAS}, {'params': Image_Encoder.parameters(), 'lr': lr_image_encoder, 'weight_decay': weight_decay, 'betas': ADAM_BETAS}, {'params': Text_Encoder.parameters(), 'lr': lr_text_encoder, 'weight_decay': weight_decay, 'betas': ADAM_BETAS} ], eps=1e-4) # 设置CosineAnnealingLR学习率调度器 # T_max设置为epochs的数量,表示在每个epoch后更新学习率 scheduler = torch.optim.lr_scheduler.CosineAnnealingLR(optimizer, args.epochs * len(train_loader)) source_train_loader_batch = enumerate(train_loader) current_epoch = 0 best_prec = 0 best_epoch=0 while (current_epoch < args.epochs): source_train_loader_batch, current_epoch, new_epoch_flag = train(classnames, templates, train_loader, source_train_loader_batch, model, adapter, optimizer, current_epoch, args, scheduler, criterion, CLIP_Text, Text_Encoder, CLIP_Image, Image_Encoder) if new_epoch_flag: if (current_epoch + 1) % args.test_freq == 0 or current_epoch == 0: if current_epoch >= args.valepoch: prec,best_epoch = validate(best_epoch,classnames, templates, loader, model, adapter, current_epoch, args, criterion, best_prec, CLIP_Text, Text_Encoder, CLIP_Image, Image_Encoder) is_best = prec > best_prec if prec > args.valacc: if is_best: save_model(current_epoch, Text_Encoder, Image_Encoder, adapter,args, prec) best_prec = max(prec, best_prec) # 更新日志 current_time = time.strftime("%Y-%m-%d %H:%M:%S", time.localtime()) logging.info( f"Current Time: {current_time},Epoch: {current_epoch}, Accuracy: {prec}, Best: {best_prec}") if __name__ == '__main__': main()