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train.py
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# -*- coding: utf-8 -*-
'''
@Time : 2020/05/06 15:07
@Author : Tianxiaomo
@File : train.py
@Noice :
@Modificattion :
@Author :
@Time :
@Detail :
'''
import time
import logging
import os, sys, math
import argparse
from collections import deque
import datetime
import cv2
from tqdm import tqdm
import numpy as np
import torch
import torch.nn as nn
from torch.utils.data import DataLoader
from torch import optim
from torch.nn import functional as F
from tensorboardX import SummaryWriter
from easydict import EasyDict as edict
from dataset import Yolo_dataset
from cfg import Cfg
from models import Yolov4
from tool.darknet2pytorch import Darknet
from tool.tv_reference.utils import collate_fn as val_collate
from tool.tv_reference.coco_utils import convert_to_coco_api
from tool.tv_reference.coco_eval import CocoEvaluator
def bboxes_iou(bboxes_a, bboxes_b, xyxy=True, GIoU=False, DIoU=False, CIoU=False):
"""Calculate the Intersection of Unions (IoUs) between bounding boxes.
IoU is calculated as a ratio of area of the intersection
and area of the union.
Args:
bbox_a (array): An array whose shape is :math:`(N, 4)`.
:math:`N` is the number of bounding boxes.
The dtype should be :obj:`numpy.float32`.
bbox_b (array): An array similar to :obj:`bbox_a`,
whose shape is :math:`(K, 4)`.
The dtype should be :obj:`numpy.float32`.
Returns:
array:
An array whose shape is :math:`(N, K)`. \
An element at index :math:`(n, k)` contains IoUs between \
:math:`n` th bounding box in :obj:`bbox_a` and :math:`k` th bounding \
box in :obj:`bbox_b`.
from: https://github.com/chainer/chainercv
https://github.com/ultralytics/yolov3/blob/eca5b9c1d36e4f73bf2f94e141d864f1c2739e23/utils/utils.py#L262-L282
"""
if bboxes_a.shape[1] != 4 or bboxes_b.shape[1] != 4:
raise IndexError
if xyxy:
# intersection top left
tl = torch.max(bboxes_a[:, None, :2], bboxes_b[:, :2])
# intersection bottom right
br = torch.min(bboxes_a[:, None, 2:], bboxes_b[:, 2:])
# convex (smallest enclosing box) top left and bottom right
con_tl = torch.min(bboxes_a[:, None, :2], bboxes_b[:, :2])
con_br = torch.max(bboxes_a[:, None, 2:], bboxes_b[:, 2:])
# centerpoint distance squared
rho2 = ((bboxes_a[:, None, 0] + bboxes_a[:, None, 2]) - (bboxes_b[:, 0] + bboxes_b[:, 2])) ** 2 / 4 + (
(bboxes_a[:, None, 1] + bboxes_a[:, None, 3]) - (bboxes_b[:, 1] + bboxes_b[:, 3])) ** 2 / 4
w1 = bboxes_a[:, 2] - bboxes_a[:, 0]
h1 = bboxes_a[:, 3] - bboxes_a[:, 1]
w2 = bboxes_b[:, 2] - bboxes_b[:, 0]
h2 = bboxes_b[:, 3] - bboxes_b[:, 1]
area_a = torch.prod(bboxes_a[:, 2:] - bboxes_a[:, :2], 1)
area_b = torch.prod(bboxes_b[:, 2:] - bboxes_b[:, :2], 1)
else:
# intersection top left
tl = torch.max((bboxes_a[:, None, :2] - bboxes_a[:, None, 2:] / 2),
(bboxes_b[:, :2] - bboxes_b[:, 2:] / 2))
# intersection bottom right
br = torch.min((bboxes_a[:, None, :2] + bboxes_a[:, None, 2:] / 2),
(bboxes_b[:, :2] + bboxes_b[:, 2:] / 2))
# convex (smallest enclosing box) top left and bottom right
con_tl = torch.min((bboxes_a[:, None, :2] - bboxes_a[:, None, 2:] / 2),
(bboxes_b[:, :2] - bboxes_b[:, 2:] / 2))
con_br = torch.max((bboxes_a[:, None, :2] + bboxes_a[:, None, 2:] / 2),
(bboxes_b[:, :2] + bboxes_b[:, 2:] / 2))
# centerpoint distance squared
rho2 = ((bboxes_a[:, None, :2] - bboxes_b[:, :2]) ** 2 / 4).sum(dim=-1)
w1 = bboxes_a[:, 2]
h1 = bboxes_a[:, 3]
w2 = bboxes_b[:, 2]
h2 = bboxes_b[:, 3]
area_a = torch.prod(bboxes_a[:, 2:], 1)
area_b = torch.prod(bboxes_b[:, 2:], 1)
en = (tl < br).type(tl.type()).prod(dim=2)
area_i = torch.prod(br - tl, 2) * en # * ((tl < br).all())
area_u = area_a[:, None] + area_b - area_i
iou = area_i / area_u
if GIoU or DIoU or CIoU:
if GIoU: # Generalized IoU https://arxiv.org/pdf/1902.09630.pdf
area_c = torch.prod(con_br - con_tl, 2) # convex area
return iou - (area_c - area_u) / area_c # GIoU
if DIoU or CIoU: # Distance or Complete IoU https://arxiv.org/abs/1911.08287v1
# convex diagonal squared
c2 = torch.pow(con_br - con_tl, 2).sum(dim=2) + 1e-16
if DIoU:
return iou - rho2 / c2 # DIoU
elif CIoU: # https://github.com/Zzh-tju/DIoU-SSD-pytorch/blob/master/utils/box/box_utils.py#L47
v = (4 / math.pi ** 2) * torch.pow(torch.atan(w1 / h1).unsqueeze(1) - torch.atan(w2 / h2), 2)
with torch.no_grad():
alpha = v / (1 - iou + v)
return iou - (rho2 / c2 + v * alpha) # CIoU
return iou
class Yolo_loss(nn.Module):
def __init__(self, n_classes=80, n_anchors=3, device=None, batch=2):
super(Yolo_loss, self).__init__()
self.device = device
self.strides = [8, 16, 32]
image_size = 608
self.n_classes = n_classes
self.n_anchors = n_anchors
self.anchors = [[12, 16], [19, 36], [40, 28], [36, 75], [76, 55], [72, 146], [142, 110], [192, 243], [459, 401]]
self.anch_masks = [[0, 1, 2], [3, 4, 5], [6, 7, 8]]
self.ignore_thre = 0.5
self.masked_anchors, self.ref_anchors, self.grid_x, self.grid_y, self.anchor_w, self.anchor_h = [], [], [], [], [], []
for i in range(3):
all_anchors_grid = [(w / self.strides[i], h / self.strides[i]) for w, h in self.anchors]
masked_anchors = np.array([all_anchors_grid[j] for j in self.anch_masks[i]], dtype=np.float32)
ref_anchors = np.zeros((len(all_anchors_grid), 4), dtype=np.float32)
ref_anchors[:, 2:] = np.array(all_anchors_grid, dtype=np.float32)
ref_anchors = torch.from_numpy(ref_anchors)
# calculate pred - xywh obj cls
fsize = image_size // self.strides[i]
grid_x = torch.arange(fsize, dtype=torch.float).repeat(batch, 3, fsize, 1).to(device)
grid_y = torch.arange(fsize, dtype=torch.float).repeat(batch, 3, fsize, 1).permute(0, 1, 3, 2).to(device)
anchor_w = torch.from_numpy(masked_anchors[:, 0]).repeat(batch, fsize, fsize, 1).permute(0, 3, 1, 2).to(
device)
anchor_h = torch.from_numpy(masked_anchors[:, 1]).repeat(batch, fsize, fsize, 1).permute(0, 3, 1, 2).to(
device)
self.masked_anchors.append(masked_anchors)
self.ref_anchors.append(ref_anchors)
self.grid_x.append(grid_x)
self.grid_y.append(grid_y)
self.anchor_w.append(anchor_w)
self.anchor_h.append(anchor_h)
def build_target(self, pred, labels, batchsize, fsize, n_ch, output_id):
# target assignment
tgt_mask = torch.zeros(batchsize, self.n_anchors, fsize, fsize, 4 + self.n_classes).to(device=self.device)
obj_mask = torch.ones(batchsize, self.n_anchors, fsize, fsize).to(device=self.device)
tgt_scale = torch.zeros(batchsize, self.n_anchors, fsize, fsize, 2).to(self.device)
target = torch.zeros(batchsize, self.n_anchors, fsize, fsize, n_ch).to(self.device)
# labels = labels.cpu().data
nlabel = (labels.sum(dim=2) > 0).sum(dim=1) # number of objects
truth_x_all = (labels[:, :, 2] + labels[:, :, 0]) / (self.strides[output_id] * 2)
truth_y_all = (labels[:, :, 3] + labels[:, :, 1]) / (self.strides[output_id] * 2)
truth_w_all = (labels[:, :, 2] - labels[:, :, 0]) / self.strides[output_id]
truth_h_all = (labels[:, :, 3] - labels[:, :, 1]) / self.strides[output_id]
truth_i_all = truth_x_all.to(torch.int16).cpu().numpy()
truth_j_all = truth_y_all.to(torch.int16).cpu().numpy()
for b in range(batchsize):
n = int(nlabel[b])
if n == 0:
continue
truth_box = torch.zeros(n, 4).to(self.device)
truth_box[:n, 2] = truth_w_all[b, :n]
truth_box[:n, 3] = truth_h_all[b, :n]
truth_i = truth_i_all[b, :n]
truth_j = truth_j_all[b, :n]
# calculate iou between truth and reference anchors
anchor_ious_all = bboxes_iou(truth_box.cpu(), self.ref_anchors[output_id], CIoU=True)
# temp = bbox_iou(truth_box.cpu(), self.ref_anchors[output_id])
best_n_all = anchor_ious_all.argmax(dim=1)
best_n = best_n_all % 3
best_n_mask = ((best_n_all == self.anch_masks[output_id][0]) |
(best_n_all == self.anch_masks[output_id][1]) |
(best_n_all == self.anch_masks[output_id][2]))
if sum(best_n_mask) == 0:
continue
truth_box[:n, 0] = truth_x_all[b, :n]
truth_box[:n, 1] = truth_y_all[b, :n]
pred_ious = bboxes_iou(pred[b].view(-1, 4), truth_box, xyxy=False)
pred_best_iou, _ = pred_ious.max(dim=1)
pred_best_iou = (pred_best_iou > self.ignore_thre)
pred_best_iou = pred_best_iou.view(pred[b].shape[:3])
# set mask to zero (ignore) if pred matches truth
obj_mask[b] = ~ pred_best_iou
for ti in range(best_n.shape[0]):
if best_n_mask[ti] == 1:
i, j = truth_i[ti], truth_j[ti]
a = best_n[ti]
obj_mask[b, a, j, i] = 1
tgt_mask[b, a, j, i, :] = 1
target[b, a, j, i, 0] = truth_x_all[b, ti] - truth_x_all[b, ti].to(torch.int16).to(torch.float)
target[b, a, j, i, 1] = truth_y_all[b, ti] - truth_y_all[b, ti].to(torch.int16).to(torch.float)
target[b, a, j, i, 2] = torch.log(
truth_w_all[b, ti] / torch.Tensor(self.masked_anchors[output_id])[best_n[ti], 0] + 1e-16)
target[b, a, j, i, 3] = torch.log(
truth_h_all[b, ti] / torch.Tensor(self.masked_anchors[output_id])[best_n[ti], 1] + 1e-16)
target[b, a, j, i, 4] = 1
target[b, a, j, i, 5 + labels[b, ti, 4].to(torch.int16).cpu().numpy()] = 1
tgt_scale[b, a, j, i, :] = torch.sqrt(2 - truth_w_all[b, ti] * truth_h_all[b, ti] / fsize / fsize)
return obj_mask, tgt_mask, tgt_scale, target
def forward(self, xin, labels=None):
loss, loss_xy, loss_wh, loss_obj, loss_cls, loss_l2 = 0, 0, 0, 0, 0, 0
for output_id, output in enumerate(xin):
batchsize = output.shape[0]
fsize = output.shape[2]
n_ch = 5 + self.n_classes
output = output.view(batchsize, self.n_anchors, n_ch, fsize, fsize)
output = output.permute(0, 1, 3, 4, 2) # .contiguous()
# logistic activation for xy, obj, cls
output[..., np.r_[:2, 4:n_ch]] = torch.sigmoid(output[..., np.r_[:2, 4:n_ch]])
pred = output[..., :4].clone()
pred[..., 0] += self.grid_x[output_id]
pred[..., 1] += self.grid_y[output_id]
pred[..., 2] = torch.exp(pred[..., 2]) * self.anchor_w[output_id]
pred[..., 3] = torch.exp(pred[..., 3]) * self.anchor_h[output_id]
obj_mask, tgt_mask, tgt_scale, target = self.build_target(pred, labels, batchsize, fsize, n_ch, output_id)
# loss calculation
output[..., 4] *= obj_mask
output[..., np.r_[0:4, 5:n_ch]] *= tgt_mask
output[..., 2:4] *= tgt_scale
target[..., 4] *= obj_mask
target[..., np.r_[0:4, 5:n_ch]] *= tgt_mask
target[..., 2:4] *= tgt_scale
loss_xy += F.binary_cross_entropy(input=output[..., :2], target=target[..., :2],
weight=tgt_scale * tgt_scale, reduction='sum')
loss_wh += F.mse_loss(input=output[..., 2:4], target=target[..., 2:4], reduction='sum') / 2
loss_obj += F.binary_cross_entropy(input=output[..., 4], target=target[..., 4], reduction='sum')
loss_cls += F.binary_cross_entropy(input=output[..., 5:], target=target[..., 5:], reduction='sum')
loss_l2 += F.mse_loss(input=output, target=target, reduction='sum')
loss = loss_xy + loss_wh + loss_obj + loss_cls
return loss, loss_xy, loss_wh, loss_obj, loss_cls, loss_l2
def collate(batch):
images = []
bboxes = []
for img, box in batch:
images.append([img])
bboxes.append([box])
images = np.concatenate(images, axis=0)
images = images.transpose(0, 3, 1, 2)
images = torch.from_numpy(images).div(255.0)
bboxes = np.concatenate(bboxes, axis=0)
bboxes = torch.from_numpy(bboxes)
return images, bboxes
def train(model, device, config, epochs=5, batch_size=1, save_cp=True, log_step=20, img_scale=0.5):
train_dataset = Yolo_dataset(config.train_label, config, train=True)
val_dataset = Yolo_dataset(config.val_label, config, train=False)
n_train = len(train_dataset)
n_val = len(val_dataset)
train_loader = DataLoader(train_dataset, batch_size=config.batch // config.subdivisions, shuffle=True,
num_workers=8, pin_memory=True, drop_last=True, collate_fn=collate)
val_loader = DataLoader(val_dataset, batch_size=config.batch // config.subdivisions, shuffle=True, num_workers=8,
pin_memory=True, drop_last=True, collate_fn=val_collate)
writer = SummaryWriter(log_dir=config.TRAIN_TENSORBOARD_DIR,
filename_suffix=f'OPT_{config.TRAIN_OPTIMIZER}_LR_{config.learning_rate}_BS_{config.batch}_Sub_{config.subdivisions}_Size_{config.width}',
comment=f'OPT_{config.TRAIN_OPTIMIZER}_LR_{config.learning_rate}_BS_{config.batch}_Sub_{config.subdivisions}_Size_{config.width}')
# writer.add_images('legend',
# torch.from_numpy(train_dataset.label2colorlegend2(cfg.DATA_CLASSES).transpose([2, 0, 1])).to(
# device).unsqueeze(0))
max_itr = config.TRAIN_EPOCHS * n_train
# global_step = cfg.TRAIN_MINEPOCH * n_train
global_step = 0
logging.info(f'''Starting training:
Epochs: {epochs}
Batch size: {config.batch}
Subdivisions: {config.subdivisions}
Learning rate: {config.learning_rate}
Training size: {n_train}
Validation size: {n_val}
Checkpoints: {save_cp}
Device: {device.type}
Images size: {config.width}
Optimizer: {config.TRAIN_OPTIMIZER}
Dataset classes: {config.classes}
Train label path:{config.train_label}
Pretrained:
''')
# learning rate setup
def burnin_schedule(i):
if i < config.burn_in:
factor = pow(i / config.burn_in, 4)
elif i < config.steps[0]:
factor = 1.0
elif i < config.steps[1]:
factor = 0.1
else:
factor = 0.01
return factor
if config.TRAIN_OPTIMIZER.lower() == 'adam':
optimizer = optim.Adam(
model.parameters(),
lr=config.learning_rate / config.batch,
betas=(0.9, 0.999),
eps=1e-08,
)
elif config.TRAIN_OPTIMIZER.lower() == 'sgd':
optimizer = optim.SGD(
params=model.parameters(),
lr=config.learning_rate / config.batch,
momentum=config.momentum,
weight_decay=config.decay,
)
scheduler = optim.lr_scheduler.LambdaLR(optimizer, burnin_schedule)
criterion = Yolo_loss(device=device, batch=config.batch // config.subdivisions, n_classes=config.classes)
# scheduler = ReduceLROnPlateau(optimizer, mode='max', verbose=True, patience=6, min_lr=1e-7)
# scheduler = CosineAnnealingWarmRestarts(optimizer, 0.001, 1e-6, 20)
save_prefix = 'Yolov4_epoch'
saved_models = deque()
model.train()
for epoch in range(epochs):
# model.train()
epoch_loss = 0
epoch_step = 0
with tqdm(total=n_train, desc=f'Epoch {epoch + 1}/{epochs}', unit='img', ncols=50) as pbar:
for i, batch in enumerate(train_loader):
global_step += 1
epoch_step += 1
images = batch[0]
bboxes = batch[1]
images = images.to(device=device, dtype=torch.float32)
bboxes = bboxes.to(device=device)
bboxes_pred = model(images)
loss, loss_xy, loss_wh, loss_obj, loss_cls, loss_l2 = criterion(bboxes_pred, bboxes)
# loss = loss / config.subdivisions
loss.backward()
epoch_loss += loss.item()
if global_step % config.subdivisions == 0:
optimizer.step()
scheduler.step()
model.zero_grad()
if global_step % (log_step * config.subdivisions) == 0:
writer.add_scalar('train/Loss', loss.item(), global_step)
writer.add_scalar('train/loss_xy', loss_xy.item(), global_step)
writer.add_scalar('train/loss_wh', loss_wh.item(), global_step)
writer.add_scalar('train/loss_obj', loss_obj.item(), global_step)
writer.add_scalar('train/loss_cls', loss_cls.item(), global_step)
writer.add_scalar('train/loss_l2', loss_l2.item(), global_step)
writer.add_scalar('lr', scheduler.get_lr()[0] * config.batch, global_step)
pbar.set_postfix(**{'loss (batch)': loss.item(), 'loss_xy': loss_xy.item(),
'loss_wh': loss_wh.item(),
'loss_obj': loss_obj.item(),
'loss_cls': loss_cls.item(),
'loss_l2': loss_l2.item(),
'lr': scheduler.get_lr()[0] * config.batch
})
logging.debug('Train step_{}: loss : {},loss xy : {},loss wh : {},'
'loss obj : {},loss cls : {},loss l2 : {},lr : {}'
.format(global_step, loss.item(), loss_xy.item(),
loss_wh.item(), loss_obj.item(),
loss_cls.item(), loss_l2.item(),
scheduler.get_lr()[0] * config.batch))
pbar.update(images.shape[0])
if cfg.use_darknet_cfg:
eval_model = Darknet(cfg.cfgfile, inference=True)
else:
eval_model = Yolov4(cfg.pretrained, n_classes=cfg.classes, inference=True)
# eval_model = Yolov4(yolov4conv137weight=None, n_classes=config.classes, inference=True)
if torch.cuda.device_count() > 1:
eval_model.load_state_dict(model.module.state_dict())
else:
eval_model.load_state_dict(model.state_dict())
eval_model.to(device)
evaluator = evaluate(eval_model, val_loader, config, device)
del eval_model
stats = evaluator.coco_eval['bbox'].stats
writer.add_scalar('train/AP', stats[0], global_step)
writer.add_scalar('train/AP50', stats[1], global_step)
writer.add_scalar('train/AP75', stats[2], global_step)
writer.add_scalar('train/AP_small', stats[3], global_step)
writer.add_scalar('train/AP_medium', stats[4], global_step)
writer.add_scalar('train/AP_large', stats[5], global_step)
writer.add_scalar('train/AR1', stats[6], global_step)
writer.add_scalar('train/AR10', stats[7], global_step)
writer.add_scalar('train/AR100', stats[8], global_step)
writer.add_scalar('train/AR_small', stats[9], global_step)
writer.add_scalar('train/AR_medium', stats[10], global_step)
writer.add_scalar('train/AR_large', stats[11], global_step)
if save_cp:
try:
# os.mkdir(config.checkpoints)
os.makedirs(config.checkpoints, exist_ok=True)
logging.info('Created checkpoint directory')
except OSError:
pass
save_path = os.path.join(config.checkpoints, f'{save_prefix}{epoch + 1}.pth')
if isinstance(model, torch.nn.DataParallel):
torch.save(model.moduel,state_dict(), save_path)
else:
torch.save(model.state_dict(), save_path)
logging.info(f'Checkpoint {epoch + 1} saved !')
saved_models.append(save_path)
if len(saved_models) > config.keep_checkpoint_max > 0:
model_to_remove = saved_models.popleft()
try:
os.remove(model_to_remove)
except:
logging.info(f'failed to remove {model_to_remove}')
writer.close()
@torch.no_grad()
def evaluate(model, data_loader, cfg, device, logger=None, **kwargs):
""" finished, tested
"""
# cpu_device = torch.device("cpu")
model.eval()
# header = 'Test:'
coco = convert_to_coco_api(data_loader.dataset, bbox_fmt='coco')
coco_evaluator = CocoEvaluator(coco, iou_types = ["bbox"], bbox_fmt='coco')
for images, targets in data_loader:
model_input = [[cv2.resize(img, (cfg.w, cfg.h))] for img in images]
model_input = np.concatenate(model_input, axis=0)
model_input = model_input.transpose(0, 3, 1, 2)
model_input = torch.from_numpy(model_input).div(255.0)
model_input = model_input.to(device)
targets = [{k: v.to(device) for k, v in t.items()} for t in targets]
if torch.cuda.is_available():
torch.cuda.synchronize()
model_time = time.time()
outputs = model(model_input)
# outputs = [{k: v.to(cpu_device) for k, v in t.items()} for t in outputs]
model_time = time.time() - model_time
# outputs = outputs.cpu().detach().numpy()
res = {}
# for img, target, output in zip(images, targets, outputs):
for img, target, boxes, confs in zip(images, targets, outputs[0], outputs[1]):
img_height, img_width = img.shape[:2]
# boxes = output[...,:4].copy() # output boxes in yolo format
boxes = boxes.squeeze(2).cpu().detach().numpy()
boxes[...,2:] = boxes[...,2:] - boxes[...,:2] # Transform [x1, y1, x2, y2] to [x1, y1, w, h]
boxes[...,0] = boxes[...,0]*img_width
boxes[...,1] = boxes[...,1]*img_height
boxes[...,2] = boxes[...,2]*img_width
boxes[...,3] = boxes[...,3]*img_height
boxes = torch.as_tensor(boxes, dtype=torch.float32)
# confs = output[...,4:].copy()
confs = confs.cpu().detach().numpy()
labels = np.argmax(confs, axis=1).flatten()
labels = torch.as_tensor(labels, dtype=torch.int64)
scores = np.max(confs, axis=1).flatten()
scores = torch.as_tensor(scores, dtype=torch.float32)
res[target["image_id"].item()] = {
"boxes": boxes,
"scores": scores,
"labels": labels,
}
evaluator_time = time.time()
coco_evaluator.update(res)
evaluator_time = time.time() - evaluator_time
# gather the stats from all processes
coco_evaluator.synchronize_between_processes()
# accumulate predictions from all images
coco_evaluator.accumulate()
coco_evaluator.summarize()
return coco_evaluator
def get_args(**kwargs):
cfg = kwargs
parser = argparse.ArgumentParser(description='Train the Model on images and target masks',
formatter_class=argparse.ArgumentDefaultsHelpFormatter)
# parser.add_argument('-b', '--batch-size', metavar='B', type=int, nargs='?', default=2,
# help='Batch size', dest='batchsize')
parser.add_argument('-l', '--learning-rate', metavar='LR', type=float, nargs='?', default=0.001,
help='Learning rate', dest='learning_rate')
parser.add_argument('-f', '--load', dest='load', type=str, default=None,
help='Load model from a .pth file')
parser.add_argument('-g', '--gpu', metavar='G', type=str, default='-1',
help='GPU', dest='gpu')
parser.add_argument('-dir', '--data-dir', type=str, default=None,
help='dataset dir', dest='dataset_dir')
parser.add_argument('-pretrained', type=str, default=None, help='pretrained yolov4.conv.137')
parser.add_argument('-classes', type=int, default=80, help='dataset classes')
parser.add_argument('-train_label_path', dest='train_label', type=str, default='train.txt', help="train label path")
parser.add_argument(
'-optimizer', type=str, default='adam',
help='training optimizer',
dest='TRAIN_OPTIMIZER')
parser.add_argument(
'-iou-type', type=str, default='iou',
help='iou type (iou, giou, diou, ciou)',
dest='iou_type')
parser.add_argument(
'-keep-checkpoint-max', type=int, default=10,
help='maximum number of checkpoints to keep. If set 0, all checkpoints will be kept',
dest='keep_checkpoint_max')
args = vars(parser.parse_args())
# for k in args.keys():
# cfg[k] = args.get(k)
cfg.update(args)
return edict(cfg)
def init_logger(log_file=None, log_dir=None, log_level=logging.INFO, mode='w', stdout=True):
"""
log_dir: 日志文件的文件夹路径
mode: 'a', append; 'w', 覆盖原文件写入.
"""
def get_date_str():
now = datetime.datetime.now()
return now.strftime('%Y-%m-%d_%H-%M-%S')
fmt = '%(asctime)s %(filename)s[line:%(lineno)d] %(levelname)s: %(message)s'
if log_dir is None:
log_dir = '~/temp/log/'
if log_file is None:
log_file = 'log_' + get_date_str() + '.txt'
if not os.path.exists(log_dir):
os.makedirs(log_dir)
log_file = os.path.join(log_dir, log_file)
# 此处不能使用logging输出
print('log file path:' + log_file)
logging.basicConfig(level=logging.DEBUG,
format=fmt,
filename=log_file,
filemode=mode)
if stdout:
console = logging.StreamHandler(stream=sys.stdout)
console.setLevel(log_level)
formatter = logging.Formatter(fmt)
console.setFormatter(formatter)
logging.getLogger('').addHandler(console)
return logging
def _get_date_str():
now = datetime.datetime.now()
return now.strftime('%Y-%m-%d_%H-%M')
if __name__ == "__main__":
logging = init_logger(log_dir='log')
cfg = get_args(**Cfg)
os.environ["CUDA_VISIBLE_DEVICES"] = cfg.gpu
device = torch.device('cuda' if torch.cuda.is_available() else 'cpu')
logging.info(f'Using device {device}')
if cfg.use_darknet_cfg:
model = Darknet(cfg.cfgfile)
else:
model = Yolov4(cfg.pretrained, n_classes=cfg.classes)
if torch.cuda.device_count() > 1:
model = torch.nn.DataParallel(model)
model.to(device=device)
try:
train(model=model,
config=cfg,
epochs=cfg.TRAIN_EPOCHS,
device=device, )
except KeyboardInterrupt:
if isinstance(model, torch.nn.DataParallel):
torch.save(model.module.state_dict(), 'INTERRUPTED.pth')
else:
torch.save(model.state_dict(), 'INTERRUPTED.pth')
logging.info('Saved interrupt')
try:
sys.exit(0)
except SystemExit:
os._exit(0)