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train.py
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train.py
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import argparse
import logging
import math
import os
import random
import shutil
import time
from pathlib import Path
import numpy as np
import torch.distributed as dist
import torch.nn.functional as F
import torch.optim as optim
import torch.optim.lr_scheduler as lr_scheduler
import torch.utils.data
import yaml
from torch.cuda import amp
from torch.nn.parallel import DistributedDataParallel as DDP
from torch.utils.tensorboard import SummaryWriter
from tqdm import tqdm
import test # import test.py to get mAP after each epoch
from models.yolo import Model
#from models.yolo_new import Model #添加了注意力机制
from utils.datasets import create_dataloader
from utils.general import (
torch_distributed_zero_first, labels_to_class_weights, plot_labels, check_anchors, labels_to_image_weights,
compute_loss,compute_loss_kld, plot_images, fitness, strip_optimizer, plot_results, get_latest_run, check_dataset, check_file,
check_git_status, check_img_size, increment_dir, print_mutation, plot_evolution, set_logging, init_seeds)
from utils.google_utils import attempt_download
from utils.torch_utils import ModelEMA, select_device, intersect_dicts
logger = logging.getLogger(__name__)
def train(hyp, opt, device, tb_writer=None):
logger.info(f'Hyperparameters {hyp}')
"""
获取记录训练日志的路径:
训练日志包括:权重、tensorboard文件、超参数hyp、设置的训练参数opt(也就是epochs,batch_size等),result.txt
result.txt包括: 占GPU内存、训练集的GIOU loss, objectness loss, classification loss, 总loss,
targets的数量, 输入图片分辨率, 准确率TP/(TP+FP),召回率TP/P ;
测试集的mAP50, [email protected]:0.95, GIOU loss, objectness loss, classification loss.
还会保存batch<3的ground truth
"""
# 如果设置进化算法则不会传入tb_writer(则为None),设置一个evolve文件夹作为日志目录
log_dir = Path(tb_writer.log_dir) if tb_writer else Path(opt.logdir) / 'evolve' # logging directory
# 设置生成文件的保存路径
wdir = log_dir / 'weights' # weights directory
os.makedirs(wdir, exist_ok=True)
last = wdir / 'last.pt'
best = wdir / 'best.pt'
results_file = str(log_dir / 'results.txt')
# 获取轮次、批次、总批次(涉及到分布式训练)、权重、进程序号(主要用于分布式训练)
epochs, batch_size, total_batch_size, weights, rank = \
opt.epochs, opt.batch_size, opt.total_batch_size, opt.weights, opt.global_rank
# Save run settings
# 保存hyp和opt
with open(log_dir / 'hyp.yaml', 'w') as f:
yaml.dump(hyp, f, sort_keys=False)
with open(log_dir / 'opt.yaml', 'w') as f:
yaml.dump(vars(opt), f, sort_keys=False)
# Configure
# 获取数据路径
cuda = device.type != 'cpu'
# 设置随机种子
# 需要在每一个进程设置相同的随机种子,以便所有模型权重都初始化为相同的值,即确保神经网络每次初始化都相同
init_seeds(2 + rank)
# 加载数据配置信息
with open(opt.data) as f:
data_dict = yaml.load(f, Loader=yaml.FullLoader) # data dict
# torch_distributed_zero_first同步所有进程
# check_dataset检查数据集,如果没找到数据集则下载数据集(仅适用于项目中自带的yaml文件数据集)
with torch_distributed_zero_first(rank):
check_dataset(data_dict) # check
# 获取训练集、测试集图片路径
train_path = data_dict['train']
test_path = data_dict['val']
# 获取类别数量和类别名字
# 如果设置了opt.single_cls则为一类
nc, names = (1, ['ship']) if opt.single_cls else (int(data_dict['nc']), data_dict['names']) # 保存data.yaml中的number classes, names
assert len(names) == nc, '%g names found for nc=%g dataset in %s' % (len(names), nc, opt.data) # check
# Model
# 判断weights字符串是否以'.pt'为结尾。若是,则说明本次训练需要预训练模型
pretrained = weights.endswith('.pt')
if pretrained:
# 加载模型,从google云盘中自动下载模型
# 但通常会下载失败,建议提前下载下来放进weights目录
with torch_distributed_zero_first(rank):
attempt_download(weights) # download if not found locally
ckpt = torch.load(weights, map_location=device) # load checkpoint 导入权重文件
"""
这里模型创建,可通过opt.cfg,也可通过ckpt['model'].yaml
这里的区别在于是否是resume,resume时会将opt.cfg设为空,
则按照ckpt['model'].yaml创建模型;
这也影响着下面是否除去anchor的key(也就是不加载anchor),
如果resume,则加载权重中保存的anchor来继续训练;
主要是预训练权重里面保存了默认coco数据集对应的anchor,
如果用户自定义了anchor,再加载预训练权重进行训练,会覆盖掉用户自定义的anchor;
所以这里主要是设定一个,如果加载预训练权重进行训练的话,就去除掉权重中的anchor,采用用户自定义的;
如果是resume的话,就是不去除anchor,就权重和anchor一起加载, 接着训练;
参考https://github.com/ultralytics/yolov5/issues/459
所以下面设置了intersect_dicts,该函数就是忽略掉exclude中的键对应的值
"""
'''
ckpt:
{'epoch': -1,
'best_fitness': array([ 0.49124]),
'training_results': None,
'model': Model(
...
)
'optimizer': None
}
'''
if hyp.get('anchors'): # 用户自定义的anchors优先级大于权重文件中自带的anchors
ckpt['model'].yaml['anchors'] = round(hyp['anchors']) # force autoanchor
# 创建并初始化yolo模型
model = Model(opt.cfg or ckpt['model'].yaml, ch=3, nc=nc).to(device) # create
'''
model =
Model(
(model): Sequential(
(0): Focus(...)
...
(24): Detect(...)
)
)
'''
# 如果opt.cfg存在,或重新设置了'anchors',则将预训练权重文件中的'anchors'参数清除,使用用户自定义的‘anchors’信息
exclude = ['anchor'] if opt.cfg or hyp.get('anchors') else [] # exclude keys
# state_dict变量存放训练过程中需要学习的权重和偏执系数,state_dict 是一个python的字典格式,以字典的格式存储,然后以字典的格式被加载,而且只加载key匹配的项
# 将ckpt中的‘model’中的”可训练“的每一层的参数建立映射关系(如 'conv1.weight': 数值...)存在state_dict中
state_dict = ckpt['model'].float().state_dict() # to FP32
# 加载除了与exclude以外,所有与key匹配的项的参数 即将权重文件中的参数导入对应层中
state_dict = intersect_dicts(state_dict, model.state_dict(), exclude=exclude) # intersect
# 将最终模型参数导入yolo模型
model.load_state_dict(state_dict, strict=False) # load
logger.info('Transferred %g/%g items from %s' % (len(state_dict), len(model.state_dict()), weights)) # report
else:
# 不进行预训练,则直接创建并初始化yolo模型
model = Model(opt.cfg, ch=3, nc=nc).to(device) # create
# Optimizer
"""
nbs人为模拟的batch_size;
就比如默认的话上面设置的opt.batch_size为16,这个nbs就为64,
也就是模型梯度累积了64/16=4(accumulate)次之后
再更新一次模型,变相的扩大了batch_size
"""
nbs = 64 # nominal batch size
accumulate = max(round(nbs / total_batch_size), 1) # accumulate loss before optimizing
# 根据accumulate设置权重衰减系数
hyp['weight_decay'] *= total_batch_size * accumulate / nbs # scale weight_decay
pg0, pg1, pg2 = [], [], [] # optimizer parameter groups
# 将模型分成三组(w权重参数(非bn层), bias, 其他所有参数)优化
for k, v in model.named_parameters(): # named_parameters:网络层的名字和参数的迭代器
'''
(0): Focus(
(conv): Conv(
(conv): Conv2d(12, 80, kernel_size=(3, 3), stride=(1, 1), padding=(1, 1), bias=False)
(bn): BatchNorm2d(80, eps=0.001, momentum=0.03, affine=True, track_running_stats=True)
(act): Hardswish()
)
)
k: 网络层可训练参数的名字所属 如: model.0.conv.conv.weight 或 model.0.conv.bn.weight 或 model.0.conv.bn.bias (Focus层举例)
v: 对应网络层的具体参数 如:对应model.0.conv.conv.weight的 size为(80,12,3,3)的参数数据 即 卷积核的数量为80,深度为12,size为3×3
'''
v.requires_grad = True # 设置当前参数在训练时保留梯度信息
if '.bias' in k:
pg2.append(v) # biases (所有的偏置参数)
elif '.weight' in k and '.bn' not in k:
pg1.append(v) # apply weight decay (非bn层的权重参数w)
else:
pg0.append(v) # all else (网络层的其他参数)
# 选用优化器,并设置pg0组的优化方式
if opt.adam:
optimizer = optim.Adam(pg0, lr=hyp['lr0'], betas=(hyp['momentum'], 0.999)) # adjust beta1 to momentum
else:
optimizer = optim.SGD(pg0, lr=hyp['lr0'], momentum=hyp['momentum'], nesterov=True)
# 设置权重参数weights(非bn层)的优化方式
optimizer.add_param_group({'params': pg1, 'weight_decay': hyp['weight_decay']}) # add pg1 with weight_decay
# 设置偏置参数bias的优化方式
optimizer.add_param_group({'params': pg2}) # add pg2 (biases)
logger.info('Optimizer groups: %g .bias, %g conv.weight, %g other' % (len(pg2), len(pg1), len(pg0)))
del pg0, pg1, pg2
# Freeze
#freeze = ['', ] # parameter names to freeze (full or partial)
# freeze = ['model.%s.' % x for x in range(10)] # 冻结带有'model.0.'-'model.9.'的所有参数 即冻结0-9层的backbone
# if any(freeze):
# for k, v in model.named_parameters():
# if any(x in k for x in freeze):
# print('freezing %s' % k)
# v.requires_grad = False
# 设置学习率衰减,这里为余弦退火方式进行衰减
# 就是根据以下公式lf,epoch和超参数hyp['lrf']进行衰减
# Scheduler https://arxiv.org/pdf/1812.01187.pdf
# https://pytorch.org/docs/stable/_modules/torch/optim/lr_scheduler.html#OneCycleLR
lf = lambda x: ((1 + math.cos(x * math.pi / epochs)) / 2) * (1 - hyp['lrf']) + hyp['lrf'] # cosine 匿名余弦退火函数
scheduler = lr_scheduler.LambdaLR(optimizer, lr_lambda=lf)
# plot_lr_scheduler(optimizer, scheduler, epochs)
# Resume
# 初始化开始训练的epoch和最好的结果
# best_fitness是以[0.0, 0.0, 0.1, 0.9]为系数并乘以[精确度, 召回率, [email protected], [email protected]:0.95]再求和所得
# 根据best_fitness来保存best.pt
start_epoch, best_fitness = 0, 0.0
if pretrained:
# Optimizer
# 加载优化器与best_fitness
if ckpt['optimizer'] is not None:
optimizer.load_state_dict(ckpt['optimizer'])
best_fitness = ckpt['best_fitness']
# Results
# 加载训练结果result.txt
if ckpt.get('training_results') is not None:
with open(results_file, 'w') as file:
file.write(ckpt['training_results']) # write results.txt
# Epochs
# 加载上次断点模型中训练的轮次,并在此基础上继续训练
start_epoch = ckpt['epoch'] + 1
# 如果使用断点重训的同时发现 start_epoch= 0,则说明上次训练正常结束,不存在断点
if opt.resume:
assert start_epoch > 0, '%s training to %g epochs is finished, nothing to resume.' % (weights, epochs)
shutil.copytree(wdir, wdir.parent / f'weights_backup_epoch{start_epoch - 1}') # save previous weights
# 如果新设置epochs小于加载的epoch,则视新设置的epochs为需要再训练的轮次数而不再是总的轮次数
if epochs < start_epoch:
logger.info('%s has been trained for %g epochs. Fine-tuning for %g additional epochs.' %
(weights, ckpt['epoch'], epochs))
epochs += ckpt['epoch'] # finetune additional epochs
del ckpt, state_dict
# Image sizes
# 获取模型总步长和模型输入图片分辨率
gs = int(max(model.stride)) # grid size (max stride)
# 检查输入图片分辨率确保能够整除总步长gs
imgsz, imgsz_test = [check_img_size(x, gs) for x in opt.img_size] # verify imgsz are gs-multiples
# DP mode
# 分布式训练,参照:https://github.com/ultralytics/yolov5/issues/475
# DataParallel模式,仅支持单机多卡,不支持混合精度训练
# rank为进程编号, 这里应该设置为rank=-1则使用DataParallel模式
# 如果 当前运行设备为gpu 且 进程编号=-1 且gpu数量大于1时 才会进行分布式训练 ,将model对象放入DataParallel容器即可进行分布式训练
if cuda and rank == -1 and torch.cuda.device_count() > 1:
model = torch.nn.DataParallel(model)
# SyncBatchNorm
# 实现多GPU之间的BatchNorm
if opt.sync_bn and cuda and rank != -1:
model = torch.nn.SyncBatchNorm.convert_sync_batchnorm(model).to(device)
logger.info('Using SyncBatchNorm()')
# Exponential moving average
'''
EMA : YOLOv5优化策略之一
EMA + SGD可提高模型鲁棒性
为模型创建EMA指数滑动平均,如果GPU进程数大于1,则不创建
'''
ema = ModelEMA(model) if rank in [-1, 0] else None
# DDP mode
# 如果rank不等于-1,则使用DistributedDataParallel模式
# local_rank为gpu编号,rank为进程,例如rank=3,local_rank=0 表示第 3 个进程内的第 1 块 GPU。
if cuda and rank != -1:
model = DDP(model, device_ids=[opt.local_rank], output_device=opt.local_rank)
# Trainloader
# class dataloader 和 dataset .
dataloader, dataset = create_dataloader(train_path, imgsz, batch_size, gs, opt,
hyp=hyp, augment=True, cache=opt.cache_images, rect=opt.rect,
rank=rank, world_size=opt.world_size, workers=opt.workers)
# 获取标签中最大的类别值,并于类别数作比较, 如果小于类别数则表示有问题
mlc = np.concatenate(dataset.labels, 0)[:, 0].max() # max label class
nb = len(dataloader) # number of batches
assert mlc < nc, 'Label class %g exceeds nc=%g in %s. Possible class labels are 0-%g' % (mlc, nc, opt.data, nc - 1)
'''
dataloader和testloader不同之处在于:
1. testloader:没有数据增强,rect=True(大概是测试图片保留了原图的长宽比)
2. dataloader:数据增强,保留了矩形框训练。
'''
# Process 0
if rank in [-1, 0]:
# local_rank is set to -1. Because only the first process is expected to do evaluation.
# testloader
ema.updates = start_epoch * nb // accumulate # set EMA updates
# testloader = create_dataloader(test_path, imgsz_test, total_batch_size, gs, opt,
# hyp=hyp, augment=False, cache=opt.cache_images and not opt.notest, rect=True,
# rank=-1, world_size=opt.world_size, workers=opt.workers)[0] # testloader
if not opt.resume:
labels = np.concatenate(dataset.labels, 0)
c = torch.tensor(labels[:, 0]) # classes
# cf = torch.bincount(c.long(), minlength=nc) + 1. # frequency
# model._initialize_biases(cf.to(device))
plot_labels(labels, save_dir=log_dir)
if tb_writer:
# tb_writer.add_hparams(hyp, {}) # causes duplicate https://github.com/ultralytics/yolov5/pull/384
tb_writer.add_histogram('classes', c, 0)
# Anchors
if not opt.noautoanchor:
check_anchors(dataset, model=model, thr=hyp['anchor_t'], imgsz=imgsz)
# Model parameters
# 根据自己数据集的类别数设置分类损失的系数
hyp['cls'] *= nc / 80. # scale coco-tuned hyp['cls'] to current dataset
# 设置类别数,超参数
model.nc = nc # attach number of classes to model
model.hyp = hyp # attach hyperparameters to model
"""
设置giou的值在objectness loss中做标签的系数, 使用代码如下
tobj[b, a, gj, gi] = (1.0 - model.gr) + model.gr * giou.detach().clamp(0).type(tobj.dtype)
这里model.gr=1,也就是说完全使用标签框与预测框的giou值来作为该预测框的objectness标签
"""
model.gr = 1.0 # iou loss ratio (obj_loss = 1.0 or iou)
# 根据labels初始化图片采样权重(图像类别所占比例高的采样频率低)
model.class_weights = labels_to_class_weights(dataset.labels, nc).to(device) # attach class weights
# 获取类别的名字
model.names = names
# Start training
t0 = time.time()
# 获取warm-up训练的迭代次数
nw = max(round(hyp['warmup_epochs'] * nb), 1e3) # number of warmup iterations, max(3 epochs, 1k iterations)
# nw = min(nw, (epochs - start_epoch) / 2 * nb) # limit warmup to < 1/2 of training
# 初始化mAP和results
maps = np.zeros(nc) # mAP per class
results = (0, 0, 0, 0, 0, 0, 0, 0) # P, R, [email protected], [email protected], val_loss(box, obj, cls, angleloss)
"""
设置学习率衰减所进行到的轮次,
目的是打断训练后,--resume接着训练也能正常的衔接之前的训练进行学习率衰减
"""
scheduler.last_epoch = start_epoch - 1 # do not move
# 通过torch1.6自带的api设置混合精度训练
scaler = amp.GradScaler(enabled=cuda)
"""
打印训练和测试输入图片分辨率
加载图片时调用的cpu进程数
从哪个epoch开始训练
"""
logger.info('Image sizes %g train, %g test\nUsing %g dataloader workers\nLogging results to %s\n'
'Starting training for %g epochs...' % (imgsz, imgsz_test, dataloader.num_workers, log_dir, epochs))
# 训练
for epoch in range(start_epoch, epochs): # epoch ------------------------------------------------------------------
# model设置为训练模式,其中training属性表示BatchNorm与Dropout层在训练阶段和测试阶段中采取的策略不同,通过判断training值来决定前向传播策略
model.train()
# Update image weights (optional)
# 加载图片权重(可选)
if opt.image_weights:
# Generate indices
"""
如果设置进行图片采样策略,
则根据前面初始化的图片采样权重model.class_weights以及maps配合每张图片包含的类别数
通过random.choices生成图片索引indices从而进行采样
"""
if rank in [-1, 0]:
cw = model.class_weights.cpu().numpy() * (1 - maps) ** 2 # class weights
iw = labels_to_image_weights(dataset.labels, nc=nc, class_weights=cw) # image weights
dataset.indices = random.choices(range(dataset.n), weights=iw, k=dataset.n) # rand weighted idx
# Broadcast if DDP
# 如果是DDP模式,则广播采样策略
if rank != -1:
indices = (torch.tensor(dataset.indices) if rank == 0 else torch.zeros(dataset.n)).int()
dist.broadcast(indices, 0)
if rank != 0:
dataset.indices = indices.cpu().numpy()
# Update mosaic border
# b = int(random.uniform(0.25 * imgsz, 0.75 * imgsz + gs) // gs * gs)
# dataset.mosaic_border = [b - imgsz, -b] # height, width borders
# 初始化训练时打印的平均损失信息
mloss = torch.zeros(5, device=device) # mean losses
if rank != -1:
# DDP模式下打乱数据, ddp.sampler的随机采样数据是基于epoch+seed作为随机种子,
# 每次epoch不同,随机种子就不同
dataloader.sampler.set_epoch(epoch)
pbar = enumerate(dataloader)
logger.info(('\n' + '%10s' * 9) % ('Epoch', 'gpu_mem', 'box', 'obj', 'cls', 'angle', 'total', 'targets', 'img_size'))
if rank in [-1, 0]:
# tqdm 创建进度条,方便训练时 信息的展示
pbar = tqdm(pbar, total=nb) # progress bar
optimizer.zero_grad()
for i, (imgs, targets, paths, _) in pbar: # batch ------------------------------------------------------------
'''
i: batch_index, 第i个batch
imgs : torch.Size([batch_size, 3, resized_height, resized_weight])
targets : torch.Size = (该batch中的目标数量, [该image属于该batch的第几个图片, class, xywh, θ])
paths : List['img1_path','img2_path',......,'img-1_path'] len(paths)=batch_size
shapes : size= batch_size, 不进行mosaic时进行矩形训练时才有值
'''
# ni计算迭代的次数iteration
ni = i + nb * epoch # number integrated batches (since train start)
imgs = imgs.to(device, non_blocking=True).float() / 255.0 # uint8 to float32, 0-255 to 0.0-1.0
# Warmup
"""
warmup训练(前nw次迭代)
在前nw次迭代中,根据以下方式选取accumulate和学习率
"""
if ni <= nw:
xi = [0, nw] # x interp
# model.gr = np.interp(ni, xi, [0.0, 1.0]) # iou loss ratio (obj_loss = 1.0 or iou)
accumulate = max(1, np.interp(ni, xi, [1, nbs / total_batch_size]).round())
for j, x in enumerate(optimizer.param_groups):
"""
bias的学习率从0.1下降到基准学习率lr*lf(epoch),
其他的参数学习率从0增加到lr*lf(epoch).
lf为上面设置的余弦退火的衰减函数
"""
# bias lr falls from 0.1 to lr0, all other lrs rise from 0.0 to lr0
x['lr'] = np.interp(ni, xi, [hyp['warmup_bias_lr'] if j == 2 else 0.0, x['initial_lr'] * lf(epoch)])
if 'momentum' in x:
x['momentum'] = np.interp(ni, xi, [hyp['warmup_momentum'], hyp['momentum']])
# Multi-scale
# 设置多尺度训练,从imgsz * 0.5, imgsz * 1.5 + gs随机选取尺寸
if opt.multi_scale:
sz = random.randrange(imgsz * 0.5, imgsz * 1.5 + gs) // gs * gs # size
sf = sz / max(imgs.shape[2:]) # scale factor
if sf != 1:
ns = [math.ceil(x * sf / gs) * gs for x in imgs.shape[2:]] # new shape (stretched to gs-multiple)
# 采用上采样下采样函数interpolate完成imgs尺寸的转变,模式设置为双线性插值
imgs = F.interpolate(imgs, size=ns, mode='bilinear', align_corners=False)
# Forward
# 前向传播
with amp.autocast(enabled=cuda):
'''
训练时返回x
x list: [small_forward, medium_forward, large_forward] eg:small_forward.size=( batch_size, 3种scale框, size1, size2, no)
'''
pred = model(imgs) # forward
# Loss
# 计算损失,包括分类损失,objectness损失,框的回归损失
# loss为总损失值,loss_items为一个元组(lbox, lobj, lcls, langle, loss)
if opt.use_kld:
loss, loss_items = compute_loss_kld(pred, targets.to(device), model) # loss scaled by batch_size
else:
loss, loss_items = compute_loss(pred, targets.to(device), model, csl_label_flag=True) # loss scaled by batch_size
if rank != -1:
# 平均不同gpu之间的梯度
loss *= opt.world_size # gradient averaged between devices in DDP mode
# Backward
scaler.scale(loss).backward()
# Optimize
# 模型反向传播accumulate次之后再根据累积的梯度更新一次参数
if ni % accumulate == 0:
scaler.step(optimizer) # optimizer.step
scaler.update()
optimizer.zero_grad()
if ema:
ema.update(model)
# Print
if rank in [-1, 0]:
# mloss (lbox, lobj, lcls, langle, loss)
# 打印显存,进行的轮次,损失,target的数量和图片的size等信息
mloss = (mloss * i + loss_items) / (i + 1) # update mean losses
mem = '%.3gG' % (torch.cuda.memory_reserved() / 1E9 if torch.cuda.is_available() else 0) # (GB)
s = ('%10s' * 2 + '%10.4g' * 7) % (
'%g/%g' % (epoch, epochs - 1), mem, *mloss, targets.shape[0], imgs.shape[-1])
# 进度条显示以上信息
pbar.set_description(s)
# Plot
# 将前三次迭代batch的标签框在图片上画出来并保存
if ni < 3:
f = str(log_dir / ('train_batch%g.jpg' % ni)) # filename
result = plot_images(images=imgs, targets=targets, paths=paths, fname=f)
if tb_writer and result is not None:
tb_writer.add_image(f, result, dataformats='HWC', global_step=epoch) # 存储的格式为[H, W, C]
# tb_writer.add_graph(model, imgs) # add model to tensorboard
# end batch ------------------------------------------------------------------------------------------------
# Scheduler
lr = [x['lr'] for x in optimizer.param_groups] # for tensorboard
scheduler.step()
# DDP process 0 or single-GPU
if rank in [-1, 0]:
# mAP
if ema:
# 更新EMA的属性
# 添加include的属性
ema.update_attr(model, include=['yaml', 'nc', 'hyp', 'gr', 'names', 'stride'])
final_epoch = epoch + 1 == epochs
# 判断该epoch是否为最后一轮 # kld 暂时不适合在线评估
#if not opt.notest or final_epoch: # Calculate mAP
# #对测试集进行测试,计算mAP等指标
# #测试时使用的是EMA模型
# if epoch % 10 == 0:
# results, maps, times = test.test(opt.data,
# batch_size=total_batch_size,
# imgsz=imgsz_test,
# model=ema.ema,
# single_cls=opt.single_cls,
# dataloader=testloader,
# save_dir=log_dir,
# plots=epoch == 0 or final_epoch) # plot first and last
# results, maps, times = test.run(data_dict,
# batch_size=total_batch_size,
# imgsz=imgsz_test,
# model=ema.ema,
# single_cls=opt.single_cls,
# dataloader=testloader,
# save_dir=log_dir,
# plots=False) # plot first and last
# Write
# 将测试指标写入result.txt
with open(results_file, 'a') as f:
f.write(s + '%10.4g' * 8 % results + '\n') # P, R, [email protected], [email protected], val_loss(box, obj, cls)
if len(opt.name) and opt.bucket:
os.system('gsutil cp %s gs://%s/results/results%s.txt' % (results_file, opt.bucket, opt.name))
# Tensorboard
# 添加指标,损失等信息到tensorboard显示
if tb_writer:
tags = ['train/box_loss', 'train/obj_loss', 'train/cls_loss', 'train/angle_loss', # train loss
'metrics/precision', 'metrics/recall', 'metrics/mAP_0.5', 'metrics/mAP_0.5:0.95',
'val/box_loss', 'val/obj_loss', 'val/cls_loss', 'val/angle_loss', # val loss
'x/lr0', 'x/lr1', 'x/lr2'] # params
for x, tag in zip(list(mloss[:-1]) + list(results) + lr, tags):
tb_writer.add_scalar(tag, x, epoch)
# Update best mAP
# 更新best_fitness
fi = fitness(np.array(results).reshape(1, -1)) # weighted combination of [P, R, [email protected], [email protected]]
if fi > best_fitness:
best_fitness = fi
# Save model
"""
保存模型,还保存了epoch,results,optimizer等信息,
optimizer信息在最后一轮完成后不会进行保存 未完成训练则保存该信息
model保存的是EMA的模型
"""
save = (not opt.nosave) or (final_epoch and not opt.evolve)
if save:
with open(results_file, 'r') as f: # create checkpoint
ckpt = {'epoch': epoch,
'best_fitness': best_fitness,
'training_results': f.read(),
'model': ema.ema,
'optimizer': None if final_epoch else optimizer.state_dict()}
# Save last, best and delete
torch.save(ckpt, last)
if best_fitness == fi:
torch.save(ckpt, best)
del ckpt
# end epoch ----------------------------------------------------------------------------------------------------
# end training
if rank in [-1, 0]:
# Strip optimizers
"""
模型训练完后,strip_optimizer函数将optimizer从ckpt中去除;
并且对模型进行model.half(), 将Float32的模型->Float16,
可以减少模型大小,提高inference速度
"""
n = opt.name if opt.name.isnumeric() else ''
fresults, flast, fbest = log_dir / f'results{n}.txt', wdir / f'last{n}.pt', wdir / f'best{n}.pt'
for f1, f2 in zip([wdir / 'last.pt', wdir / 'best.pt', results_file], [flast, fbest, fresults]):
if os.path.exists(f1):
os.rename(f1, f2) # rename
if str(f2).endswith('.pt'): # is *.pt
strip_optimizer(f2) # strip optimizer
# 上传结果到谷歌云盘
os.system('gsutil cp %s gs://%s/weights' % (f2, opt.bucket)) if opt.bucket else None # upload
# Finish
# 可视化results.txt文件
if not opt.evolve:
plot_results(save_dir=log_dir) # save as results.png
logger.info('%g epochs completed in %.3f hours.\n' % (epoch - start_epoch + 1, (time.time() - t0) / 3600))
# 释放显存
dist.destroy_process_group() if rank not in [-1, 0] else None
torch.cuda.empty_cache()
return results
if __name__ == '__main__':
"""
opt参数解析:
weights:加载的权重文件
cfg:模型配置文件,网络结构
data:数据集配置文件,数据集路径,类名等
hyp:超参数文件
epochs:训练总轮次
batch-size:批次大小
img-size:输入图片分辨率大小
rect:是否采用矩形训练,默认False
resume:接着打断训练上次的结果接着训练
nosave:不保存模型,默认False
notest:不进行test,默认False
noautoanchor:不自动调整anchor,默认False
evolve:是否进行超参数进化,默认False
bucket:谷歌云盘bucket,一般不会用到
cache-images:是否提前缓存图片到内存,以加快训练速度,默认False
name:数据集名字,如果设置:results.txt to results_name.txt,默认无
device:训练的设备,cpu;0(表示一个gpu设备cuda:0);0,1,2,3(多个gpu设备)
multi-scale:是否进行多尺度训练,默认False
single-cls:数据集是否只有一个类别,默认False
adam:是否使用adam优化器
sync-bn:是否使用跨卡同步BN,在DDP模式使用
local_rank:gpu编号
logdir:存放日志的目录
workers:dataloader的最大worker数量
"""
parser = argparse.ArgumentParser()
parser.add_argument('--weights', type=str, default="",help='initil weights path')#"./weights/yolov5m.pt"
parser.add_argument('--cfg', type=str, default='./models/yolov5m.yaml', help='model.yaml path')
parser.add_argument('--data', type=str, default='data/DOTA_ROTATED.yaml', help='data.yaml path')
parser.add_argument('--hyp', type=str, default='data/hyp.scratch.yaml', help='hyperparameters path')
parser.add_argument('--epochs', type=int, default=300)
parser.add_argument('--batch-size', type=int, default=8, help='total batch size for all GPUs')
parser.add_argument('--use_kld', type=bool, default=True, help='use kld') #默认使用KLD False --使用CSL
parser.add_argument('--img-size', nargs='+', type=int, default=[1024, 1024], help='[train, test] image sizes')
parser.add_argument('--rect', action='store_true', help='rectangular training')
parser.add_argument('--resume', nargs='?', const=True, default=False, help='resume most recent training')
parser.add_argument('--nosave', action='store_true', help='only save final checkpoint')
parser.add_argument('--notest', action='store_true', default=True, help='only test final epoch')
parser.add_argument('--noautoanchor', action='store_true', help='disable autoanchor check')
parser.add_argument('--evolve', action='store_true', help='evolve hyperparameters')
parser.add_argument('--bucket', type=str, default='', help='gsutil bucket')
parser.add_argument('--cache-images', action='store_true', default=False, help='cache images for faster training')
parser.add_argument('--image-weights', action='store_true', help='use weighted image selection for training')
parser.add_argument('--name', default='', help='renames results.txt to results_name.txt if supplied')
parser.add_argument('--device', default='1', help='cuda device, i.e. 0 or 0,1,2,3 or cpu')
parser.add_argument('--multi-scale', action='store_true', help='vary img-size +/- 50%%')
parser.add_argument('--single-cls', action='store_true', help='train as single-class dataset')
parser.add_argument('--adam', action='store_true', default=True, help='use torch.optim.Adam() optimizer')
parser.add_argument('--sync-bn', action='store_true', help='use SyncBatchNorm, only available in DDP mode')
parser.add_argument('--local_rank', type=int, default=-1, help='DDP parameter, do not modify')
parser.add_argument('--logdir', type=str, default='runs_kld/', help='logging directory')
parser.add_argument('--workers', type=int, default=4, help='maximum number of dataloader workers')
opt = parser.parse_args()
# Set DDP variables
"""
设置DDP(Distributed Data Parallel,分布式数据并行)模式的参数
world_size:表示全局进程个数,可认为是gpu的数量
global_rank:进程编号
"""
opt.total_batch_size = opt.batch_size
opt.world_size = int(os.environ['WORLD_SIZE']) if 'WORLD_SIZE' in os.environ else 1
opt.global_rank = int(os.environ['RANK']) if 'RANK' in os.environ else -1
set_logging(opt.global_rank)
if opt.global_rank in [-1, 0]:
check_git_status()
# Resume
'''
是否从断点开始训练
'''
if opt.resume: # resume an interrupted run
# 如果resume的参数是str,则表示传入的是最新的断点模型的路径地址,直接导入last模型进行训练
# get_latest_run()函数获取runs文件夹中最近的last.pt,从断点处导入继续训练
ckpt = opt.resume if isinstance(opt.resume, str) else get_latest_run() # specified or most recent path
log_dir = Path(ckpt).parent.parent # runs/exp0
assert os.path.isfile(ckpt), 'ERROR: --resume checkpoint does not exist'
# opt参数也全部替换
with open(log_dir / 'opt.yaml') as f:
opt = argparse.Namespace(**yaml.load(f, Loader=yaml.FullLoader)) # replace
# opt.cfg设置为'' 对应着train函数里面的操作(加载权重时是否加载权重里的anchor)
opt.cfg, opt.weights, opt.resume = '', ckpt, True
logger.info('Resuming training from %s' % ckpt)
else:
# # 获取超参数列表
# opt.hyp = opt.hyp or ('hyp.finetune.yaml' if opt.weights else 'hyp.scratch.yaml')
# 检查数据集参数信息文件、cfg配置文件、训练超参数信息文件是否存在以及是否存在多个文件
opt.data, opt.cfg, opt.hyp = check_file(opt.data), check_file(opt.cfg), check_file(opt.hyp) # check files
assert len(opt.cfg) or len(opt.weights), 'either --cfg or --weights must be specified'
# 扩展image_size为[image_size, image_size]一个是训练size,一个是测试size
opt.img_size.extend([opt.img_size[-1]] * (2 - len(opt.img_size))) # extend to 2 sizes (train, test)
log_dir = increment_dir(Path(opt.logdir) / 'exp', opt.name) # runs/exp1 训练日志存放路径
# 选择设备
device = select_device(opt.device, batch_size=opt.batch_size)
# DDP mode
if opt.local_rank != -1: # -1 表示cpu
assert torch.cuda.device_count() > opt.local_rank
# 根据gpu编号选择设备
torch.cuda.set_device(opt.local_rank)
device = torch.device('cuda', opt.local_rank)
# 初始化进程组
dist.init_process_group(backend='nccl', init_method='env://') # distributed backend 一般来说使用NCCL对于GPU分布式训练,使用gloo对CPU进行分布式训练
assert opt.batch_size % opt.world_size == 0, '--batch-size must be multiple of CUDA device count'
# 将总批次按照进程数分配给各个gpu
opt.batch_size = opt.total_batch_size // opt.world_size
# 打印opt参数信息
logger.info(opt)
# 加载超参数列表
with open(opt.hyp) as f:
hyp = yaml.load(f, Loader=yaml.FullLoader) # load hyps
# Train
# 如果不进行超参数进化,则直接调用train()函数,开始训练
if not opt.evolve:
tb_writer = None
if opt.global_rank in [-1, 0]:
# 创建tensorboard
logger.info('Start Tensorboard with "tensorboard --logdir %s", view at http://localhost:6006/' % opt.logdir)
tb_writer = SummaryWriter(log_dir=log_dir) # runs/exp0
train(hyp, opt, device, tb_writer)
# Evolve hyperparameters (optional)
else:
# Hyperparameter evolution metadata (mutation scale 0-1, lower_limit, upper_limit)
# 超参数进化列表,括号里分别为(突变规模, 最小值,最大值)
meta = {'lr0': (1, 1e-5, 1e-1), # initial learning rate (SGD=1E-2, Adam=1E-3)
'lrf': (1, 0.01, 1.0), # final OneCycleLR learning rate (lr0 * lrf)
'momentum': (0.3, 0.6, 0.98), # SGD momentum/Adam beta1
'weight_decay': (1, 0.0, 0.001), # optimizer weight decay
'warmup_epochs': (1, 0.0, 5.0), # warmup epochs (fractions ok)
'warmup_momentum': (1, 0.0, 0.95), # warmup initial momentum
'warmup_bias_lr': (1, 0.0, 0.2), # warmup initial bias lr
'box': (1, 0.02, 0.2), # box loss gain
'cls': (1, 0.2, 4.0), # cls loss gain
'cls_pw': (1, 0.5, 2.0), # cls BCELoss positive_weight
'obj': (1, 0.2, 4.0), # obj loss gain (scale with pixels)
'obj_pw': (1, 0.5, 2.0), # obj BCELoss positive_weight
'angle': (1, 0.2, 4.0),
'angle_pw': (1, 0.5, 2.0),
'iou_t': (0, 0.1, 0.7), # IoU training threshold
'anchor_t': (1, 2.0, 8.0), # anchor-multiple threshold
#'anchors': (2, 2.0, 10.0), # anchors per output grid (0 to ignore)
'fl_gamma': (0, 0.0, 2.0), # focal loss gamma (efficientDet default gamma=1.5)
'hsv_h': (1, 0.0, 0.1), # image HSV-Hue augmentation (fraction)
'hsv_s': (1, 0.0, 0.9), # image HSV-Saturation augmentation (fraction)
'hsv_v': (1, 0.0, 0.9), # image HSV-Value augmentation (fraction)
'degrees': (1, 0.0, 45.0), # image rotation (+/- deg)
'translate': (1, 0.0, 0.9), # image translation (+/- fraction)
'scale': (1, 0.0, 0.9), # image scale (+/- gain)
'shear': (1, 0.0, 10.0), # image shear (+/- deg)
'perspective': (0, 0.0, 0.001), # image perspective (+/- fraction), range 0-0.001
'flipud': (1, 0.0, 1.0), # image flip up-down (probability)
'fliplr': (0, 0.0, 1.0), # image flip left-right (probability)
'mosaic': (1, 0.0, 1.0), # image mixup (probability)
'mixup': (1, 0.0, 1.0)} # image mixup (probability)
assert opt.local_rank == -1, 'DDP mode not implemented for --evolve'
opt.notest, opt.nosave = True, True # only test/save final epoch
# ei = [isinstance(x, (int, float)) for x in hyp.values()] # evolvable indices
yaml_file = Path('runs/evolve/hyp_evolved.yaml') # save best result here
if opt.bucket:
os.system('gsutil cp gs://%s/evolve.txt .' % opt.bucket) # download evolve.txt if exists
# 默认进化300次
"""
这里的进化算法是:根据之前训练时的hyp来确定一个base hyp再进行突变;
如何根据?通过之前每次进化得到的results来确定之前每个hyp的权重
有了每个hyp和每个hyp的权重之后有两种进化方式;
1.根据每个hyp的权重随机选择一个之前的hyp作为base hyp,random.choices(range(n), weights=w)
2.根据每个hyp的权重对之前所有的hyp进行融合获得一个base hyp,(x * w.reshape(n, 1)).sum(0) / w.sum()
evolve.txt会记录每次进化之后的results+hyp
每次进化时,hyp会根据之前的results进行从大到小的排序;
再根据fitness函数计算之前每次进化得到的hyp的权重
再确定哪一种进化方式,从而进行进化
"""
for _ in range(20): # generations to evolve
if os.path.exists('evolve.txt'): # if evolve.txt exists: select best hyps and mutate
# Select parent(s)
# 选择进化方式
parent = 'single' # parent selection method: 'single' or 'weighted'
# 加载evolve.txt
x = np.loadtxt('evolve.txt', ndmin=2)
# 选取至多前5次进化的结果
n = min(5, len(x)) # number of previous results to consider
x = x[np.argsort(-fitness(x))][:n] # top n mutations
# 根据results计算hyp的权重
w = fitness(x) - fitness(x).min() # weights
# 根据不同进化方式获得base hyp
if parent == 'single' or len(x) == 1:
# x = x[random.randint(0, n - 1)] # random selection
x = x[random.choices(range(n), weights=w)[0]] # weighted selection
elif parent == 'weighted':
x = (x * w.reshape(n, 1)).sum(0) / w.sum() # weighted combination
# Mutate
# 超参数进化
mp, s = 0.8, 0.2 # mutation probability, sigma
npr = np.random
npr.seed(int(time.time()))
# 获取突变初始值
g = np.array([x[0] for x in meta.values()]) # gains 0-1
ng = len(meta)
v = np.ones(ng)
while all(v == 1): # mutate until a change occurs (prevent duplicates)
v = (g * (npr.random(ng) < mp) * npr.randn(ng) * npr.random() * s + 1).clip(0.3, 3.0)
# 将突变添加到base hyp上
# [i+7]是因为x中前七个数字为results的指标(P, R, mAP, F1, test_losses=(GIoU, obj, cls)),之后才是超参数hyp
for i, k in enumerate(hyp.keys()): # plt.hist(v.ravel(), 300)
hyp[k] = float(x[i + 7] * v[i]) # mutate
# Constrain to limits
# 修剪hyp在规定范围里
for k, v in meta.items():
hyp[k] = max(hyp[k], v[1]) # lower limit
hyp[k] = min(hyp[k], v[2]) # upper limit
hyp[k] = round(hyp[k], 5) # significant digits
# Train mutation
# 训练
results = train(hyp.copy(), opt, device)
# Write mutation results
"""
写入results和对应的hyp到evolve.txt
evolve.txt文件每一行为一次进化的结果
一行中前七个数字为(P, R, mAP, F1, test_losses=(GIoU, obj, cls)),之后为hyp
保存hyp到yaml文件
"""
print_mutation(hyp.copy(), results, yaml_file, opt.bucket)
# Plot results
plot_evolution(yaml_file)
print('Hyperparameter evolution complete. Best results saved as: %s\nCommand to train a new model with these '
'hyperparameters: $ python train.py --hyp %s' % (yaml_file, yaml_file))