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# --------------------------------------------------------
# EEG-DINO: Learning EEG Foundation Models via Hierarchical Self-Distillation
# Based on BEiT-v2, timm, DeiT, DINO v2, LaBraM and CBraMod code bases
# https://github.com/microsoft/unilm/tree/master/beitv2
# https://github.com/rwightman/pytorch-image-models/tree/master/timm
# https://github.com/facebookresearch/deit/
# https://github.com/facebookresearch/dinov2
# https://github.com/935963004/LaBraM
# https://github.com/wjq-learning/CBraMod
# ---------------------------------------------------------
import math
import sys
from typing import Iterable, Optional
import torch
from timm.utils import ModelEma
import utils
from einops import rearrange
import os
import numpy as np
import pandas as pd
from sklearn.metrics import confusion_matrix

def train_class_batch(model, samples, target, criterion):
    outputs = model(samples)
    loss = criterion(outputs, target)
    return loss, outputs


def get_loss_scale_for_deepspeed(model):
    optimizer = model.optimizer
    return optimizer.loss_scale if hasattr(optimizer, "loss_scale") else optimizer.cur_scale


def train_one_epoch(model: torch.nn.Module, criterion: torch.nn.Module,
                    data_loader: Iterable, optimizer: torch.optim.Optimizer,
                    device: torch.device, epoch: int, loss_scaler, max_norm: float = 0,
                    model_ema: Optional[ModelEma] = None, log_writer=None,
                    start_steps=None, lr_schedule_values=None, wd_schedule_values=None,
                    num_training_steps_per_epoch=None, update_freq=None, is_binary=True):
    model.train(True)
    metric_logger = utils.MetricLogger(delimiter="  ")
    metric_logger.add_meter('lr', utils.SmoothedValue(window_size=1, fmt='{value:.6f}'))
    metric_logger.add_meter('min_lr', utils.SmoothedValue(window_size=1, fmt='{value:.6f}'))
    header = 'Epoch: [{}]'.format(epoch)
    print_freq = 10

    if loss_scaler is None:
        model.zero_grad()
        model.micro_steps = 0
    else:
        optimizer.zero_grad()

    for data_iter_step, (samples, targets) in enumerate(metric_logger.log_every(data_loader, print_freq, header)):
        step = data_iter_step // update_freq
        if step >= num_training_steps_per_epoch:
            continue
        it = start_steps + step  # global training iteration
        # Update LR & WD for the first acc
        if lr_schedule_values is not None or wd_schedule_values is not None and data_iter_step % update_freq == 0:
            for i, param_group in enumerate(optimizer.param_groups):
                if lr_schedule_values is not None:
                    param_group["lr"] = lr_schedule_values[it] * param_group.get("lr_scale", 1.0)
                if wd_schedule_values is not None and param_group["weight_decay"] > 0:
                    param_group["weight_decay"] = wd_schedule_values[it]

        # print("before", samples.shape)
        samples = samples.float().to(device, non_blocking=True) / 100
        samples = rearrange(samples, 'B N (A T) -> B N A T', T=200)
        # print("after rearrange", samples.shape)
        
        targets = targets.to(device, non_blocking=True)
        if is_binary:
            targets = targets.float().unsqueeze(-1)

        if loss_scaler is None:
            samples = samples.half()
            loss, output = train_class_batch(
                model, samples, targets, criterion)
        else:
            with torch.amp.autocast(device_type='cuda'):
                loss, output = train_class_batch(
                    model, samples, targets, criterion)

        loss_value = loss.item()

        if not math.isfinite(loss_value):
            print("Loss is {}, stopping training".format(loss_value))
            sys.exit(1)

        if loss_scaler is None:
            loss /= update_freq
            model.backward(loss)
            model.step()

            if (data_iter_step + 1) % update_freq == 0:
                # model.zero_grad()
                # Deepspeed will call step() & model.zero_grad() automatic
                if model_ema is not None:
                    model_ema.update(model)
            grad_norm = None
            loss_scale_value = get_loss_scale_for_deepspeed(model)
        else:
            # this attribute is added by timm on one optimizer (adahessian)
            is_second_order = hasattr(optimizer, 'is_second_order') and optimizer.is_second_order
            loss /= update_freq
            grad_norm = loss_scaler(loss, optimizer, clip_grad=max_norm,
                                    parameters=model.parameters(), create_graph=is_second_order,
                                    update_grad=(data_iter_step + 1) % update_freq == 0)
            if (data_iter_step + 1) % update_freq == 0:
                optimizer.zero_grad()
                if model_ema is not None:
                    model_ema.update(model)
            loss_scale_value = loss_scaler.state_dict()["scale"]

        torch.cuda.synchronize()

        if is_binary:
            class_acc = utils.get_metrics(torch.sigmoid(output).detach().cpu().numpy(), targets.detach().cpu().numpy(), ["accuracy"], is_binary)["accuracy"]
        else:
            class_acc = (output.max(-1)[-1] == targets.squeeze()).float().mean()
            
        metric_logger.update(loss=loss_value)
        metric_logger.update(class_acc=class_acc)
        metric_logger.update(loss_scale=loss_scale_value)
        min_lr = 10.
        max_lr = 0.
        for group in optimizer.param_groups:
            min_lr = min(min_lr, group["lr"])
            max_lr = max(max_lr, group["lr"])

        metric_logger.update(lr=max_lr)
        metric_logger.update(min_lr=min_lr)
        weight_decay_value = None
        for group in optimizer.param_groups:
            if group["weight_decay"] > 0:
                weight_decay_value = group["weight_decay"]
        metric_logger.update(weight_decay=weight_decay_value)
        metric_logger.update(grad_norm=grad_norm)

        if log_writer is not None:
            log_writer.update(loss=loss_value, head="loss")
            log_writer.update(class_acc=class_acc, head="loss")
            log_writer.update(loss_scale=loss_scale_value, head="opt")
            log_writer.update(lr=max_lr, head="opt")
            log_writer.update(min_lr=min_lr, head="opt")
            log_writer.update(weight_decay=weight_decay_value, head="opt")
            log_writer.update(grad_norm=grad_norm, head="opt")

            log_writer.set_step()

    # gather the stats from all processes
    metric_logger.synchronize_between_processes()
    print("Averaged stats:", metric_logger)
    return {k: meter.global_avg for k, meter in metric_logger.meters.items()}


@torch.no_grad()
def evaluate(data_loader, model, device, output_dir=None, header='Test:', metrics=['acc'], is_binary=True, epoch=None):
    if is_binary:
        criterion = torch.nn.BCEWithLogitsLoss()
    else:
        criterion = torch.nn.CrossEntropyLoss()

    metric_logger = utils.MetricLogger(delimiter="  ")
    
    # 新增：初始化存储预测和真实值的列表
    all_outputs = []
    all_targets = []
    
    model.eval()
    for step, batch in enumerate(metric_logger.log_every(data_loader, 10, header)):
        EEG = batch[0]
        target = batch[-1]
        EEG = EEG.float().to(device, non_blocking=True) / 100
        EEG = rearrange(EEG, 'B N (A T) -> B N A T', T=200)
        target = target.to(device, non_blocking=True)
        if is_binary:
            target = target.float().unsqueeze(-1)
        
        # compute output
        with torch.amp.autocast(device_type='cuda'):
            output = model(EEG)
            loss = criterion(output, target)
        
        if is_binary:
            output = torch.sigmoid(output).cpu()
        else:
            output = output.cpu()
        target = target.cpu()

        results = utils.get_metrics(output.numpy(), target.numpy(), metrics, is_binary)
        pred = output.numpy()
        true = target.numpy()

        # 新增：收集原始输出
        all_outputs.append(pred)
        all_targets.append(true)

        batch_size = EEG.shape[0]
        metric_logger.update(loss=loss.item())
        for key, value in results.items():
            metric_logger.meters[key].update(value, n=batch_size)
        #metric_logger.meters['acc5'].update(acc5.item(), n=batch_size)
    # gather the stats from all processes
    metric_logger.synchronize_between_processes()
    print('* loss {losses.global_avg:.3f}'
          .format(losses=metric_logger.loss))
    
    # 新增：计算混淆矩阵
    all_outputs = np.concatenate(all_outputs)
    all_targets = np.concatenate(all_targets)
    
    if is_binary:
        y_pred = (all_outputs > 0.5).astype(int)
    else:
        y_pred = np.argmax(all_outputs, axis=1)
    y_true = all_targets.squeeze().astype(int)
    
    cm = confusion_matrix(y_true, y_pred)
    ret = utils.get_metrics(all_outputs, all_targets, metrics, is_binary, 0.5)
    ret['loss'] = metric_logger.loss.global_avg
    ret['confusion_matrix'] = cm.tolist()  # 转换为列表方便保存

    # 新增：保存预测结果和混淆矩阵
    if output_dir and epoch is not None:
        os.makedirs(output_dir, exist_ok=True)
        # 保存分类头原始输出
        np.save(os.path.join(output_dir, f'epoch{epoch}_predictions.npy'), all_outputs)
        # 保存混淆矩阵
        pd.DataFrame(cm).to_csv(os.path.join(output_dir, f'epoch{epoch}_confusion_matrix.csv'))
        
    return ret