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simsiam.py
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simsiam.py
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import argparse
import json
import os
import sys
import time
from copy import deepcopy
import torch
import torch.nn as nn
import torch.nn.parallel
import torch.optim
import torch.utils.data
import torch.utils.data.distributed
from src.data.transform import TwoCropsTransform
import src.data.dataset as datasets
from src.models.knn import KNNEvaluator
from src.models.misc import adjust_learning_rate, save_checkpoint
from src.models.simsiam import SimSiam
import src.models.backbone as models
from src.models.generator import SynDataGenerator
from src.torch_utils.misc import InfiniteSampler
from src.utils.logger import DummyLogger, set_logger
from src.utils.meters import AverageMeter, ProgressMeter
from src.torch_utils.misc import strip_ddp
from src.engine import main, setup_env, get_transform
# add dnnlib and torch_utils to PYTHONPATH
def add_path(path):
if path not in sys.path:
sys.path.insert(0, path)
add_path("./src")
logger = set_logger(__name__, to_console=False)
model_names = sorted(name for name in models.__dict__
if name.islower() and not name.startswith("__")
and callable(models.__dict__[name]))
dataset_names = sorted(name for name in datasets.__dict__
if not name.startswith("__")
and callable(datasets.__dict__[name]))
parser = argparse.ArgumentParser(description='PyTorch CIFAR-10 Training with StyleGAN2-ada')
parser.add_argument('data', metavar='DIR', help='path to dataset')
parser.add_argument('--dataset-name', default='CIFAR10', choices=dataset_names)
parser.add_argument('--output-dir', metavar='OUTPUT_DIR', default="output",
help='path to logging output')
parser.add_argument('-a', '--arch', metavar='ARCH', default='resnet18',
choices=model_names,
help='model architecture: ' +
' | '.join(model_names) +
' (default: resnet18)')
parser.add_argument('-j', '--workers', default=32, type=int, metavar='N',
help='number of data loading workers (default: 32)')
parser.add_argument('--epochs', default=800, type=int, metavar='N',
help='number of total epochs to run')
parser.add_argument('--start-epoch', default=0, type=int, metavar='N',
help='manual epoch number (useful on restarts)')
parser.add_argument('-b', '--batch-size', default=512, type=int,
metavar='N',
help='mini-batch size (default: 512), this is the total '
'batch size of all GPUs on the current node when '
'using Data Parallel or Distributed Data Parallel')
parser.add_argument('--lr', '--learning-rate', default=0.03, type=float,
metavar='LR', help='initial (base) learning rate', dest='lr')
parser.add_argument('--momentum', default=0.9, type=float, metavar='M',
help='momentum of SGD solver')
parser.add_argument('--wd', '--weight-decay', default=5e-4, type=float,
metavar='W', help='weight decay (default: 1e-4)',
dest='weight_decay')
parser.add_argument('--save-freq', default=20, type=int,
metavar='SAVE_FREQ', help='save frequency (default: 20)') # TODO: consider to change it
parser.add_argument('-p', '--print-freq', default=10, type=int,
metavar='N', help='print frequency (default: 10)')
parser.add_argument('--resume', default='', type=str, metavar='PATH',
help='path to latest checkpoint (default: none)')
parser.add_argument('--world-size', default=-1, type=int,
help='number of nodes for distributed training')
parser.add_argument('--rank', default=-1, type=int,
help='node rank for distributed training')
parser.add_argument('--dist-url', default='auto', type=str,
help='url used to set up distributed training')
parser.add_argument('--dist-backend', default='nccl', type=str,
help='distributed backend')
parser.add_argument('--seed', default=None, type=int,
help='seed for initializing training. ')
parser.add_argument('--gpu', default=None, type=int,
help='GPU id to use.')
parser.add_argument('--multiprocessing-distributed', action='store_true',
help='Use multi-processing distributed training to launch '
'N processes per node, which has N GPUs. This is the '
'fastest way to use PyTorch for either single node or '
'multi node data parallel training')
# simsiam specific configs:
parser.add_argument('-i', '--input-scale', default=32, type=int, metavar='N',
help='The input scale which the representation learning'
'network is working on')
parser.add_argument('--dim', default=2048, type=int,
help='feature dimension (default: 2048)')
parser.add_argument('--pred-dim', default=512, type=int,
help='hidden dimension of the predictor (default: 512)')
parser.add_argument('--fix-pred-lr', action='store_true',
help='Fix learning rate for the predictor')
parser.add_argument('--num-proj-layers', default=2, type=int,
help='number of projection layer (default: 2)')
# StyleGAN-ada specific configs:
parser.add_argument('--syn_ratio', type=float, help='If specified, train network with real data as well', default=0.)
parser.add_argument('--gpath', type=str, help='path to stylegan-ada trained pickle')
# knn specific configs
parser.add_argument('--disable-knn', action='store_true', help='')
parser.add_argument('--knn-k', default=200, type=int, help='k in kNN monitor')
parser.add_argument('--knn-t', default=0.1, type=float, help='softmax temperature in kNN monitor')
#----------------------------------------------------------------------------
def main_worker(gpu, ngpus_per_node, args):
# setup
init_lr = setup_env(gpu, ngpus_per_node, args)
args.syn_batch_size = int(args.batch_size * args.syn_ratio)
args.real_batch_size = args.batch_size - args.syn_batch_size
args.logger.info(f"synthetic batch size: {args.syn_batch_size}, real batch size: {args.real_batch_size}")
# create synthetic data generator
syn_transform = get_transform(args.input_scale, real_image=False, cifar=args.dataset_name in ["CIFAR10", "CIFAR100"])
args.logger.info("=> creating stylegan2-ada")
if args.syn_batch_size > 0:
assert os.path.isfile(args.gpath), f"File {args.gpath} does not exist."
G = SynDataGenerator(args.gpath, regex="").eval().requires_grad_(False).cuda(args.gpu)
else:
G = None
# create real data iterator
train_dataset = datasets.__dict__[args.dataset_name](
args.data, 'train', TwoCropsTransform(
get_transform(args.input_scale,
cifar=args.dataset_name in ["CIFAR10", "CIFAR100"])
)
)
train_sampler = InfiniteSampler(train_dataset, rank=args.rank, num_replicas=args.world_size)
if args.real_batch_size > 0:
train_iterator = iter(torch.utils.data.DataLoader(
train_dataset, batch_size=args.real_batch_size, shuffle=False,
num_workers=args.workers, pin_memory=True, sampler=train_sampler, drop_last=False,
))
else:
train_iterator = None
iters_per_epoch = len(train_dataset) // (args.batch_size * ngpus_per_node)
# create model
args.logger.info("=> creating model '{}'".format(args.arch))
model = SimSiam(
models.__dict__[args.arch], args.dim, args.pred_dim,
num_proj_layers=args.num_proj_layers,
)
# wrap ddp
if args.distributed:
# Apply SyncBN
model = torch.nn.SyncBatchNorm.convert_sync_batchnorm(model)
# For multiprocessing distributed, DistributedDataParallel constructor
# should always set the single device scope, otherwise,
# DistributedDataParallel will use all available devices.
if args.gpu is not None:
model.cuda(args.gpu)
model = torch.nn.parallel.DistributedDataParallel(model, device_ids=[args.gpu])
else:
model.cuda()
# DistributedDataParallel will divide and allocate batch_size to all
# available GPUs if device_ids are not set
model = torch.nn.parallel.DistributedDataParallel(model)
else:
model.cuda(args.gpu)
args.logger.info(f"Model: \n{str(model)}\n") # print model
args.logger.info(f"Generator: \n{str(G)}\n") # print G
# define loss function (criterion) and optimizer
criterion = nn.CosineSimilarity(dim=1).cuda(args.gpu)
if args.fix_pred_lr:
optim_params = [{'params': strip_ddp(model).backbone.parameters(), 'fix_lr': False},
# {'params': model.module.projector.parameters(), 'fix_lr': False},
{'params': strip_ddp(model).predictor.parameters(), 'fix_lr': True}]
else:
optim_params = model.parameters()
optimizer = torch.optim.SGD(optim_params, init_lr,
momentum=args.momentum,
weight_decay=args.weight_decay)
# optionally resume from a checkpoint
if args.resume:
if os.path.isfile(args.resume):
args.logger.info("=> loading checkpoint '{}'".format(args.resume))
if args.gpu is None:
checkpoint = torch.load(args.resume)
else:
# Map model to be loaded to specified single gpu.
checkpoint = torch.load(args.resume, map_location=f"cuda:{args.gpu}")
args.start_epoch = checkpoint['epoch']
model.load_state_dict(checkpoint['state_dict'])
optimizer.load_state_dict(checkpoint['optimizer'])
args.logger.info("=> loaded checkpoint '{}' (epoch {})"
.format(args.resume, checkpoint['epoch']))
else:
args.logger.info("=> no checkpoint found at '{}'".format(args.resume))
# knn evaluator
if not args.disable_knn:
knn_evaluator = KNNEvaluator(args.dataset_name, args.data, args.input_scale, args.workers, args.knn_k, args.knn_t)
for epoch in range(args.start_epoch, args.epochs):
model.train().requires_grad_(True)
adjust_learning_rate(optimizer, init_lr, epoch, args.epochs)
# train for one epoch
train(
G, model, criterion, optimizer, syn_transform,
epoch, iters_per_epoch, args, train_iterator
)
if ((not args.multiprocessing_distributed) or (args.multiprocessing_distributed
and args.rank % ngpus_per_node == 0)) and (epoch + 1) % args.save_freq == 0:
# evaluate
model.eval()
with torch.no_grad():
backbone = deepcopy(strip_ddp(model).backbone).eval().requires_grad_(False)
knn_acc = knn_evaluator.evaluate(backbone)
del backbone
args.logger.info("\t".join([f"Epoch: [{epoch:d}]", f"KNN Acc: {knn_acc:6.3f}%"]))
args.tb_writer.add_scalar('Val/KNN_Acc', knn_acc, iters_per_epoch * (epoch + 1))
# record
jsonl_line = json.dumps(dict(knn_acc=knn_acc, epoch=epoch, timestamp=time.time()))
with open(os.path.join(args.run_dir, f'metric-knn-acc.jsonl'), 'at') as f:
f.write(jsonl_line + '\n')
# save
save_checkpoint(
{
'epoch': epoch + 1,
'arch': args.arch,
'state_dict': model.state_dict(),
'optimizer' : optimizer.state_dict(),
}, is_best=False,
filename=os.path.join(args.run_dir, 'checkpoint_epoch{:04d}.pth.tar'.format(epoch))
)
#----------------------------------------------------------------------------
def train(
G,
model,
criterion,
optimizer,
transform,
epoch,
iters_per_epoch,
args,
real_data_iterator,
):
batch_time = AverageMeter('Time', ':6.3f')
data_time = AverageMeter('Data', ':6.3f')
losses = AverageMeter('Loss', ':.4f')
progress = ProgressMeter(
iters_per_epoch,
[batch_time, data_time, losses],
prefix="Epoch: [{}]".format(epoch)
)
if G is not None:
G.eval().requires_grad_(False) # generator always fixed
model.train() # switch to train mode
two_crops_transform = TwoCropsTransform(transform)
end = time.time()
for i in range(iters_per_epoch):
# measure data loading time
data_time.update(time.time() - end)
# synthesize images
images = [[], []]
if args.syn_batch_size > 0:
assert G is not None
z = torch.randn([args.syn_batch_size, G.z_dim]).cuda(args.gpu, non_blocking=True) # latent codes
syn_images, _ = G(z, None) # NCHW, float32, dynamic range [-1, +1]
syn_images = syn_images.clamp(min=-1., max=1.)
syn_images = two_crops_transform(syn_images)
syn_images = [x.contiguous() for x in syn_images]
images[0].append(syn_images[0])
images[1].append(syn_images[1])
# load real images
if args.real_batch_size > 0:
assert real_data_iterator is not None
real_images, _ = next(real_data_iterator)
images[0].append(real_images[0].cuda(args.gpu, non_blocking=True))
images[1].append(real_images[1].cuda(args.gpu, non_blocking=True))
# cat two images
images[0] = torch.cat(images[0], dim=0)
images[1] = torch.cat(images[1], dim=0)
# compute output and loss
p1, p2, z1, z2 = model(images[0], images[1])
loss = -(criterion(p1, z2).mean() + criterion(p2, z1).mean()) * 0.5
losses.update(loss.item(), images[0].size(0))
# compute gradient and do SGD step
optimizer.zero_grad()
loss.backward()
optimizer.step()
# measure elapsed time
batch_time.update(time.time() - end)
end = time.time()
if i % args.print_freq == 0:
args.logger.info(progress.display(i))
args.tb_writer.add_scalar('Train/Loss', loss.item(), iters_per_epoch * epoch + i)
#----------------------------------------------------------------------------
if __name__ == '__main__':
args = parser.parse_args()
main(args, main_worker)
#----------------------------------------------------------------------------