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train_refine.py
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train_refine.py
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"""
Train MattingRefine
Supports multi-GPU training with DistributedDataParallel() and SyncBatchNorm.
Select GPUs through CUDA_VISIBLE_DEVICES environment variable.
Example:
CUDA_VISIBLE_DEVICES=0,1 python train_refine.py \
--dataset-name videomatte240k \
--model-backbone resnet50 \
--model-name mattingrefine-resnet50-videomatte240k \
--model-last-checkpoint "PATH_TO_LAST_CHECKPOINT" \
--epoch-end 1
"""
import argparse
import kornia
import torch
import os
import random
from torch import nn
from torch import distributed as dist
from torch import multiprocessing as mp
from torch.nn import functional as F
from torch.cuda.amp import autocast, GradScaler
from torch.utils.tensorboard import SummaryWriter
from torch.utils.data import DataLoader, Subset
from torch.optim import Adam
from torchvision.utils import make_grid
from tqdm import tqdm
from torchvision import transforms as T
from PIL import Image
from data_path import DATA_PATH
from dataset import ImagesDataset, ZipDataset, VideoDataset, SampleDataset
from dataset import augmentation as A
from model import MattingRefine
from model.utils import load_matched_state_dict
# --------------- Arguments ---------------
parser = argparse.ArgumentParser()
parser.add_argument('--dataset-name', type=str, required=True, choices=DATA_PATH.keys())
parser.add_argument('--model-backbone', type=str, required=True, choices=['resnet101', 'resnet50', 'mobilenetv2'])
parser.add_argument('--model-backbone-scale', type=float, default=0.25)
parser.add_argument('--model-refine-mode', type=str, default='sampling', choices=['full', 'sampling', 'thresholding'])
parser.add_argument('--model-refine-sample-pixels', type=int, default=80_000)
parser.add_argument('--model-refine-thresholding', type=float, default=0.7)
parser.add_argument('--model-refine-kernel-size', type=int, default=3, choices=[1, 3])
parser.add_argument('--model-name', type=str, required=True)
parser.add_argument('--model-last-checkpoint', type=str, default=None)
parser.add_argument('--batch-size', type=int, default=4)
parser.add_argument('--num-workers', type=int, default=16)
parser.add_argument('--epoch-start', type=int, default=0)
parser.add_argument('--epoch-end', type=int, required=True)
parser.add_argument('--log-train-loss-interval', type=int, default=10)
parser.add_argument('--log-train-images-interval', type=int, default=1000)
parser.add_argument('--log-valid-interval', type=int, default=2000)
parser.add_argument('--checkpoint-interval', type=int, default=2000)
args = parser.parse_args()
distributed_num_gpus = torch.cuda.device_count()
assert args.batch_size % distributed_num_gpus == 0
# --------------- Main ---------------
def train_worker(rank, addr, port):
# Distributed Setup
os.environ['MASTER_ADDR'] = addr
os.environ['MASTER_PORT'] = port
dist.init_process_group("nccl", rank=rank, world_size=distributed_num_gpus)
# Training DataLoader
dataset_train = ZipDataset([
ZipDataset([
ImagesDataset(DATA_PATH[args.dataset_name]['train']['pha'], mode='L'),
ImagesDataset(DATA_PATH[args.dataset_name]['train']['fgr'], mode='RGB'),
], transforms=A.PairCompose([
A.PairRandomAffineAndResize((2048, 2048), degrees=(-5, 5), translate=(0.1, 0.1), scale=(0.3, 1), shear=(-5, 5)),
A.PairRandomHorizontalFlip(),
A.PairRandomBoxBlur(0.1, 5),
A.PairRandomSharpen(0.1),
A.PairApplyOnlyAtIndices([1], T.ColorJitter(0.15, 0.15, 0.15, 0.05)),
A.PairApply(T.ToTensor())
]), assert_equal_length=True),
ImagesDataset(DATA_PATH['backgrounds']['train'], mode='RGB', transforms=T.Compose([
A.RandomAffineAndResize((2048, 2048), degrees=(-5, 5), translate=(0.1, 0.1), scale=(1, 2), shear=(-5, 5)),
T.RandomHorizontalFlip(),
A.RandomBoxBlur(0.1, 5),
A.RandomSharpen(0.1),
T.ColorJitter(0.15, 0.15, 0.15, 0.05),
T.ToTensor()
])),
])
dataset_train_len_per_gpu_worker = int(len(dataset_train) / distributed_num_gpus)
dataset_train = Subset(dataset_train, range(rank * dataset_train_len_per_gpu_worker, (rank + 1) * dataset_train_len_per_gpu_worker))
dataloader_train = DataLoader(dataset_train,
shuffle=True,
pin_memory=True,
drop_last=True,
batch_size=args.batch_size // distributed_num_gpus,
num_workers=args.num_workers // distributed_num_gpus)
# Validation DataLoader
if rank == 0:
dataset_valid = ZipDataset([
ZipDataset([
ImagesDataset(DATA_PATH[args.dataset_name]['valid']['pha'], mode='L'),
ImagesDataset(DATA_PATH[args.dataset_name]['valid']['fgr'], mode='RGB')
], transforms=A.PairCompose([
A.PairRandomAffineAndResize((2048, 2048), degrees=(-5, 5), translate=(0.1, 0.1), scale=(0.3, 1), shear=(-5, 5)),
A.PairApply(T.ToTensor())
]), assert_equal_length=True),
ImagesDataset(DATA_PATH['backgrounds']['valid'], mode='RGB', transforms=T.Compose([
A.RandomAffineAndResize((2048, 2048), degrees=(-5, 5), translate=(0.1, 0.1), scale=(1, 1.2), shear=(-5, 5)),
T.ToTensor()
])),
])
dataset_valid = SampleDataset(dataset_valid, 50)
dataloader_valid = DataLoader(dataset_valid,
pin_memory=True,
drop_last=True,
batch_size=args.batch_size // distributed_num_gpus,
num_workers=args.num_workers // distributed_num_gpus)
# Model
model = MattingRefine(args.model_backbone,
args.model_backbone_scale,
args.model_refine_mode,
args.model_refine_sample_pixels,
args.model_refine_thresholding,
args.model_refine_kernel_size).to(rank)
model = nn.SyncBatchNorm.convert_sync_batchnorm(model)
model_distributed = nn.parallel.DistributedDataParallel(model, device_ids=[rank])
if args.model_last_checkpoint is not None:
load_matched_state_dict(model, torch.load(args.model_last_checkpoint))
optimizer = Adam([
{'params': model.backbone.parameters(), 'lr': 5e-5},
{'params': model.aspp.parameters(), 'lr': 5e-5},
{'params': model.decoder.parameters(), 'lr': 1e-4},
{'params': model.refiner.parameters(), 'lr': 3e-4},
])
scaler = GradScaler()
# Logging and checkpoints
if rank == 0:
if not os.path.exists(f'checkpoint/{args.model_name}'):
os.makedirs(f'checkpoint/{args.model_name}')
writer = SummaryWriter(f'log/{args.model_name}')
# Run loop
for epoch in range(args.epoch_start, args.epoch_end):
for i, ((true_pha, true_fgr), true_bgr) in enumerate(tqdm(dataloader_train)):
step = epoch * len(dataloader_train) + i
true_pha = true_pha.to(rank, non_blocking=True)
true_fgr = true_fgr.to(rank, non_blocking=True)
true_bgr = true_bgr.to(rank, non_blocking=True)
true_pha, true_fgr, true_bgr = random_crop(true_pha, true_fgr, true_bgr)
true_src = true_bgr.clone()
# Augment with shadow
aug_shadow_idx = torch.rand(len(true_src)) < 0.3
if aug_shadow_idx.any():
aug_shadow = true_pha[aug_shadow_idx].mul(0.3 * random.random())
aug_shadow = T.RandomAffine(degrees=(-5, 5), translate=(0.2, 0.2), scale=(0.5, 1.5), shear=(-5, 5))(aug_shadow)
aug_shadow = kornia.filters.box_blur(aug_shadow, (random.choice(range(20, 40)),) * 2)
true_src[aug_shadow_idx] = true_src[aug_shadow_idx].sub_(aug_shadow).clamp_(0, 1)
del aug_shadow
del aug_shadow_idx
# Composite foreground onto source
true_src = true_fgr * true_pha + true_src * (1 - true_pha)
# Augment with noise
aug_noise_idx = torch.rand(len(true_src)) < 0.4
if aug_noise_idx.any():
true_src[aug_noise_idx] = true_src[aug_noise_idx].add_(torch.randn_like(true_src[aug_noise_idx]).mul_(0.03 * random.random())).clamp_(0, 1)
true_bgr[aug_noise_idx] = true_bgr[aug_noise_idx].add_(torch.randn_like(true_bgr[aug_noise_idx]).mul_(0.03 * random.random())).clamp_(0, 1)
del aug_noise_idx
# Augment background with jitter
aug_jitter_idx = torch.rand(len(true_src)) < 0.8
if aug_jitter_idx.any():
true_bgr[aug_jitter_idx] = kornia.augmentation.ColorJitter(0.18, 0.18, 0.18, 0.1)(true_bgr[aug_jitter_idx])
del aug_jitter_idx
# Augment background with affine
aug_affine_idx = torch.rand(len(true_bgr)) < 0.3
if aug_affine_idx.any():
true_bgr[aug_affine_idx] = T.RandomAffine(degrees=(-1, 1), translate=(0.01, 0.01))(true_bgr[aug_affine_idx])
del aug_affine_idx
with autocast():
pred_pha, pred_fgr, pred_pha_sm, pred_fgr_sm, pred_err_sm, _ = model_distributed(true_src, true_bgr)
loss = compute_loss(pred_pha, pred_fgr, pred_pha_sm, pred_fgr_sm, pred_err_sm, true_pha, true_fgr)
scaler.scale(loss).backward()
scaler.step(optimizer)
scaler.update()
optimizer.zero_grad()
if rank == 0:
if (i + 1) % args.log_train_loss_interval == 0:
writer.add_scalar('loss', loss, step)
if (i + 1) % args.log_train_images_interval == 0:
writer.add_image('train_pred_pha', make_grid(pred_pha, nrow=5), step)
writer.add_image('train_pred_fgr', make_grid(pred_fgr, nrow=5), step)
writer.add_image('train_pred_com', make_grid(pred_fgr * pred_pha, nrow=5), step)
writer.add_image('train_pred_err', make_grid(pred_err_sm, nrow=5), step)
writer.add_image('train_true_src', make_grid(true_src, nrow=5), step)
del true_pha, true_fgr, true_src, true_bgr
del pred_pha, pred_fgr, pred_pha_sm, pred_fgr_sm, pred_err_sm
if (i + 1) % args.log_valid_interval == 0:
valid(model, dataloader_valid, writer, step)
if (step + 1) % args.checkpoint_interval == 0:
torch.save(model.state_dict(), f'checkpoint/{args.model_name}/epoch-{epoch}-iter-{step}.pth')
if rank == 0:
torch.save(model.state_dict(), f'checkpoint/{args.model_name}/epoch-{epoch}.pth')
# Clean up
dist.destroy_process_group()
# --------------- Utils ---------------
def compute_loss(pred_pha_lg, pred_fgr_lg, pred_pha_sm, pred_fgr_sm, pred_err_sm, true_pha_lg, true_fgr_lg):
true_pha_sm = kornia.resize(true_pha_lg, pred_pha_sm.shape[2:])
true_fgr_sm = kornia.resize(true_fgr_lg, pred_fgr_sm.shape[2:])
true_msk_lg = true_pha_lg != 0
true_msk_sm = true_pha_sm != 0
return F.l1_loss(pred_pha_lg, true_pha_lg) + \
F.l1_loss(pred_pha_sm, true_pha_sm) + \
F.l1_loss(kornia.sobel(pred_pha_lg), kornia.sobel(true_pha_lg)) + \
F.l1_loss(kornia.sobel(pred_pha_sm), kornia.sobel(true_pha_sm)) + \
F.l1_loss(pred_fgr_lg * true_msk_lg, true_fgr_lg * true_msk_lg) + \
F.l1_loss(pred_fgr_sm * true_msk_sm, true_fgr_sm * true_msk_sm) + \
F.mse_loss(kornia.resize(pred_err_sm, true_pha_lg.shape[2:]), \
kornia.resize(pred_pha_sm, true_pha_lg.shape[2:]).sub(true_pha_lg).abs())
def random_crop(*imgs):
H_src, W_src = imgs[0].shape[2:]
W_tgt = random.choice(range(1024, 2048)) // 4 * 4
H_tgt = random.choice(range(1024, 2048)) // 4 * 4
scale = max(W_tgt / W_src, H_tgt / H_src)
results = []
for img in imgs:
img = kornia.resize(img, (int(H_src * scale), int(W_src * scale)))
img = kornia.center_crop(img, (H_tgt, W_tgt))
results.append(img)
return results
def valid(model, dataloader, writer, step):
model.eval()
loss_total = 0
loss_count = 0
with torch.no_grad():
for (true_pha, true_fgr), true_bgr in dataloader:
batch_size = true_pha.size(0)
true_pha = true_pha.cuda(non_blocking=True)
true_fgr = true_fgr.cuda(non_blocking=True)
true_bgr = true_bgr.cuda(non_blocking=True)
true_src = true_pha * true_fgr + (1 - true_pha) * true_bgr
pred_pha, pred_fgr, pred_pha_sm, pred_fgr_sm, pred_err_sm, _ = model(true_src, true_bgr)
loss = compute_loss(pred_pha, pred_fgr, pred_pha_sm, pred_fgr_sm, pred_err_sm, true_pha, true_fgr)
loss_total += loss.cpu().item() * batch_size
loss_count += batch_size
writer.add_scalar('valid_loss', loss_total / loss_count, step)
model.train()
# --------------- Start ---------------
if __name__ == '__main__':
addr = 'localhost'
port = str(random.choice(range(12300, 12400))) # pick a random port.
mp.spawn(train_worker,
nprocs=distributed_num_gpus,
args=(addr, port),
join=True)