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# Copyright (c) 2021, NVIDIA CORPORATION & AFFILIATES. All rights reserved. | |
# | |
# NVIDIA CORPORATION and its licensors retain all intellectual property | |
# and proprietary rights in and to this software, related documentation | |
# and any modifications thereto. Any use, reproduction, disclosure or | |
# distribution of this software and related documentation without an express | |
# license agreement from NVIDIA CORPORATION is strictly prohibited. | |
"""Main training loop.""" | |
import os | |
import time | |
import copy | |
import json | |
import pickle | |
import psutil | |
import PIL.Image | |
import numpy as np | |
import torch | |
import dnnlib | |
from torch_utils import misc | |
from torch_utils import training_stats | |
from torch_utils.ops import conv2d_gradfix | |
from torch_utils.ops import grid_sample_gradfix | |
import legacy | |
from metrics import metric_main | |
# ---------------------------------------------------------------------------- | |
def setup_snapshot_image_grid(training_set, random_seed=0): | |
rnd = np.random.RandomState(random_seed) | |
gw = np.clip(7680 // training_set.image_shape[2], 7, 32) | |
gh = np.clip(4320 // training_set.image_shape[1], 4, 32) | |
# No labels => show random subset of training samples. | |
if not training_set.has_labels: | |
all_indices = list(range(len(training_set))) | |
rnd.shuffle(all_indices) | |
grid_indices = [all_indices[i % | |
len(all_indices)] for i in range(gw * gh)] | |
else: | |
# Group training samples by label. | |
label_groups = dict() # label => [idx, ...] | |
for idx in range(len(training_set)): | |
label = tuple(training_set.get_details(idx).raw_label.flat[::-1]) | |
if label not in label_groups: | |
label_groups[label] = [] | |
label_groups[label].append(idx) | |
# Reorder. | |
label_order = sorted(label_groups.keys()) | |
for label in label_order: | |
rnd.shuffle(label_groups[label]) | |
# Organize into grid. | |
grid_indices = [] | |
for y in range(gh): | |
label = label_order[y % len(label_order)] | |
indices = label_groups[label] | |
grid_indices += [indices[x % len(indices)] for x in range(gw)] | |
label_groups[label] = [ | |
indices[(i + gw) % len(indices)] for i in range(len(indices))] | |
# Load data. | |
images, labels = zip(*[training_set[i] for i in grid_indices]) | |
return (gw, gh), np.stack(images), np.stack(labels) | |
# ---------------------------------------------------------------------------- | |
def save_image_grid(img, fname, drange, grid_size): | |
lo, hi = drange | |
img = np.asarray(img, dtype=np.float32) | |
img = (img - lo) * (255 / (hi - lo)) | |
img = np.rint(img).clip(0, 255).astype(np.uint8) | |
gw, gh = grid_size | |
_N, C, H, W = img.shape | |
img = img.reshape([gh, gw, C, H, W]) | |
img = img.transpose(0, 3, 1, 4, 2) | |
img = img.reshape([gh * H, gw * W, C]) | |
assert C in [1, 3] | |
if C == 1: | |
PIL.Image.fromarray(img[:, :, 0], 'L').save(fname) | |
if C == 3: | |
PIL.Image.fromarray(img, 'RGB').save(fname) | |
# ---------------------------------------------------------------------------- | |
def training_loop( | |
run_dir='.', # Output directory. | |
training_set_kwargs={}, # Options for training set. | |
data_loader_kwargs={}, # Options for torch.utils.data.DataLoader. | |
G_kwargs={}, # Options for generator network. | |
D_kwargs={}, # Options for discriminator network. | |
G_opt_kwargs={}, # Options for generator optimizer. | |
D_opt_kwargs={}, # Options for discriminator optimizer. | |
# Options for augmentation pipeline. None = disable. | |
augment_kwargs=None, | |
loss_kwargs={}, # Options for loss function. | |
metrics=[], # Metrics to evaluate during training. | |
random_seed=0, # Global random seed. | |
num_gpus=1, # Number of GPUs participating in the training. | |
rank=0, # Rank of the current process in [0, num_gpus[. | |
# Total batch size for one training iteration. Can be larger than batch_gpu * num_gpus. | |
batch_size=4, | |
batch_gpu=4, # Number of samples processed at a time by one GPU. | |
# Half-life of the exponential moving average (EMA) of generator weights. | |
ema_kimg=10, | |
ema_rampup=0.05, # EMA ramp-up coefficient. None = no rampup. | |
# How often to perform regularization for G? None = disable lazy regularization. | |
G_reg_interval=None, | |
# How often to perform regularization for D? None = disable lazy regularization. | |
D_reg_interval=16, | |
augment_p=0, # Initial value of augmentation probability. | |
ada_target=None, # ADA target value. None = fixed p. | |
ada_interval=4, # How often to perform ADA adjustment? | |
# ADA adjustment speed, measured in how many kimg it takes for p to increase/decrease by one unit. | |
ada_kimg=500, | |
# Total length of the training, measured in thousands of real images. | |
total_kimg=25000, | |
kimg_per_tick=4, # Progress snapshot interval. | |
# How often to save image snapshots? None = disable. | |
image_snapshot_ticks=50, | |
# How often to save network snapshots? None = disable. | |
network_snapshot_ticks=50, | |
resume_pkl=None, # Network pickle to resume training from. | |
resume_kimg=0, # First kimg to report when resuming training. | |
cudnn_benchmark=True, # Enable torch.backends.cudnn.benchmark? | |
# Callback function for determining whether to abort training. Must return consistent results across ranks. | |
abort_fn=None, | |
# Callback function for updating training progress. Called for all ranks. | |
progress_fn=None, | |
): | |
# Initialize. | |
start_time = time.time() | |
device = torch.device('cuda', rank) | |
np.random.seed(random_seed * num_gpus + rank) | |
torch.manual_seed(random_seed * num_gpus + rank) | |
# Improves training speed. | |
torch.backends.cudnn.benchmark = cudnn_benchmark | |
# Improves numerical accuracy. | |
torch.backends.cuda.matmul.allow_tf32 = False | |
# Improves numerical accuracy. | |
torch.backends.cudnn.allow_tf32 = False | |
# Improves training speed. | |
conv2d_gradfix.enabled = True | |
# Avoids errors with the augmentation pipe. | |
grid_sample_gradfix.enabled = True | |
# Load training set. | |
if rank == 0: | |
print('Loading training set...') | |
training_set = dnnlib.util.construct_class_by_name( | |
**training_set_kwargs) # subclass of training.dataset.Dataset | |
training_set_sampler = misc.InfiniteSampler( | |
dataset=training_set, rank=rank, num_replicas=num_gpus, seed=random_seed) | |
training_set_iterator = iter(torch.utils.data.DataLoader( | |
dataset=training_set, sampler=training_set_sampler, batch_size=batch_size//num_gpus, **data_loader_kwargs)) | |
if rank == 0: | |
print() | |
print('Num images: ', len(training_set)) | |
print('Image shape:', training_set.image_shape) | |
print('Label shape:', training_set.label_shape) | |
print() | |
# Construct networks. | |
if rank == 0: | |
print('Constructing networks...') | |
common_kwargs = dict(c_dim=training_set.label_dim, | |
img_resolution=training_set.resolution, img_channels=training_set.num_channels) | |
G = dnnlib.util.construct_class_by_name(**G_kwargs, **common_kwargs).train( | |
).requires_grad_(False).to(device) # subclass of torch.nn.Module | |
D = dnnlib.util.construct_class_by_name(**D_kwargs, **common_kwargs).train( | |
).requires_grad_(False).to(device) # subclass of torch.nn.Module | |
G_ema = copy.deepcopy(G).eval() | |
# Resume from existing pickle. | |
if (resume_pkl is not None) and (rank == 0): | |
print(f'Resuming from "{resume_pkl}"') | |
with dnnlib.util.open_url(resume_pkl) as f: | |
resume_data = legacy.load_network_pkl(f) | |
for name, module in [('G', G), ('D', D), ('G_ema', G_ema)]: | |
misc.copy_params_and_buffers( | |
resume_data[name], module, require_all=False) | |
# Print network summary tables. | |
if rank == 0: | |
z = torch.empty([batch_gpu, G.z_dim], device=device) | |
c = torch.empty([batch_gpu, G.c_dim], device=device) | |
img = misc.print_module_summary(G, [z, c]) | |
misc.print_module_summary(D, [img, c]) | |
# Setup augmentation. | |
if rank == 0: | |
print('Setting up augmentation...') | |
augment_pipe = None | |
ada_stats = None | |
if (augment_kwargs is not None) and (augment_p > 0 or ada_target is not None): | |
augment_pipe = dnnlib.util.construct_class_by_name( | |
**augment_kwargs).train().requires_grad_(False).to(device) # subclass of torch.nn.Module | |
augment_pipe.p.copy_(torch.as_tensor(augment_p)) | |
if ada_target is not None: | |
ada_stats = training_stats.Collector(regex='Loss/signs/real') | |
# Distribute across GPUs. | |
if rank == 0: | |
print(f'Distributing across {num_gpus} GPUs...') | |
for module in [G, D, G_ema, augment_pipe]: | |
if module is not None and num_gpus > 1: | |
for param in misc.params_and_buffers(module): | |
torch.distributed.broadcast(param, src=0) | |
# Setup training phases. | |
if rank == 0: | |
print('Setting up training phases...') | |
loss = dnnlib.util.construct_class_by_name( | |
device=device, G=G, D=D, augment_pipe=augment_pipe, **loss_kwargs) # subclass of training.loss.Loss | |
phases = [] | |
for name, module, opt_kwargs, reg_interval in [('G', G, G_opt_kwargs, G_reg_interval), ('D', D, D_opt_kwargs, D_reg_interval)]: | |
if reg_interval is None: | |
opt = dnnlib.util.construct_class_by_name( | |
params=module.parameters(), **opt_kwargs) # subclass of torch.optim.Optimizer | |
phases += [dnnlib.EasyDict(name=name+'both', | |
module=module, opt=opt, interval=1)] | |
else: # Lazy regularization. | |
mb_ratio = reg_interval / (reg_interval + 1) | |
opt_kwargs = dnnlib.EasyDict(opt_kwargs) | |
opt_kwargs.lr = opt_kwargs.lr * mb_ratio | |
opt_kwargs.betas = [beta ** mb_ratio for beta in opt_kwargs.betas] | |
opt = dnnlib.util.construct_class_by_name( | |
module.parameters(), **opt_kwargs) # subclass of torch.optim.Optimizer | |
phases += [dnnlib.EasyDict(name=name+'main', | |
module=module, opt=opt, interval=1)] | |
phases += [dnnlib.EasyDict(name=name+'reg', | |
module=module, opt=opt, interval=reg_interval)] | |
for phase in phases: | |
phase.start_event = None | |
phase.end_event = None | |
if rank == 0: | |
phase.start_event = torch.cuda.Event(enable_timing=True) | |
phase.end_event = torch.cuda.Event(enable_timing=True) | |
# Export sample images. | |
grid_size = None | |
grid_z = None | |
grid_c = None | |
if rank == 0: | |
print('Exporting sample images...') | |
grid_size, images, labels = setup_snapshot_image_grid( | |
training_set=training_set) | |
save_image_grid(images, os.path.join(run_dir, 'reals.png'), | |
drange=[0, 255], grid_size=grid_size) | |
grid_z = torch.randn([labels.shape[0], G.z_dim], | |
device=device).split(batch_gpu) | |
grid_c = torch.from_numpy(labels).to(device).split(batch_gpu) | |
images = torch.cat([G_ema(z=z, c=c, noise_mode='const').cpu() | |
for z, c in zip(grid_z, grid_c)]).numpy() | |
save_image_grid(images, os.path.join( | |
run_dir, 'fakes_init.png'), drange=[-1, 1], grid_size=grid_size) | |
# Initialize logs. | |
if rank == 0: | |
print('Initializing logs...') | |
stats_collector = training_stats.Collector(regex='.*') | |
stats_metrics = dict() | |
stats_jsonl = None | |
stats_tfevents = None | |
if rank == 0: | |
stats_jsonl = open(os.path.join(run_dir, 'stats.jsonl'), 'wt') | |
try: | |
import torch.utils.tensorboard as tensorboard | |
stats_tfevents = tensorboard.SummaryWriter(run_dir) | |
except ImportError as err: | |
print('Skipping tfevents export:', err) | |
# Train. | |
if rank == 0: | |
print(f'Training for {total_kimg} kimg...') | |
print() | |
cur_nimg = resume_kimg * 1000 | |
cur_tick = 0 | |
tick_start_nimg = cur_nimg | |
tick_start_time = time.time() | |
maintenance_time = tick_start_time - start_time | |
batch_idx = 0 | |
if progress_fn is not None: | |
progress_fn(0, total_kimg) | |
while True: | |
# Fetch training data. | |
with torch.autograd.profiler.record_function('data_fetch'): | |
phase_real_img, phase_real_c = next(training_set_iterator) | |
phase_real_img = (phase_real_img.to(device).to( | |
torch.float32) / 127.5 - 1).split(batch_gpu) | |
phase_real_c = phase_real_c.to(device).split(batch_gpu) | |
all_gen_z = torch.randn( | |
[len(phases) * batch_size, G.z_dim], device=device) | |
all_gen_z = [phase_gen_z.split( | |
batch_gpu) for phase_gen_z in all_gen_z.split(batch_size)] | |
all_gen_c = [training_set.get_label(np.random.randint( | |
len(training_set))) for _ in range(len(phases) * batch_size)] | |
all_gen_c = torch.from_numpy( | |
np.stack(all_gen_c)).pin_memory().to(device) | |
all_gen_c = [phase_gen_c.split( | |
batch_gpu) for phase_gen_c in all_gen_c.split(batch_size)] | |
# Execute training phases. | |
for phase, phase_gen_z, phase_gen_c in zip(phases, all_gen_z, all_gen_c): | |
if batch_idx % phase.interval != 0: | |
continue | |
if phase.start_event is not None: | |
phase.start_event.record(torch.cuda.current_stream(device)) | |
# Accumulate gradients. | |
phase.opt.zero_grad(set_to_none=True) | |
phase.module.requires_grad_(True) | |
for real_img, real_c, gen_z, gen_c in zip(phase_real_img, phase_real_c, phase_gen_z, phase_gen_c): | |
loss.accumulate_gradients(phase=phase.name, real_img=real_img, real_c=real_c, | |
gen_z=gen_z, gen_c=gen_c, gain=phase.interval, cur_nimg=cur_nimg) | |
phase.module.requires_grad_(False) | |
# Update weights. | |
with torch.autograd.profiler.record_function(phase.name + '_opt'): | |
params = [param for param in phase.module.parameters() | |
if param.grad is not None] | |
if len(params) > 0: | |
flat = torch.cat([param.grad.flatten() | |
for param in params]) | |
if num_gpus > 1: | |
torch.distributed.all_reduce(flat) | |
flat /= num_gpus | |
misc.nan_to_num(flat, nan=0, posinf=1e5, | |
neginf=-1e5, out=flat) | |
grads = flat.split([param.numel() for param in params]) | |
for param, grad in zip(params, grads): | |
param.grad = grad.reshape(param.shape) | |
phase.opt.step() | |
# Phase done. | |
if phase.end_event is not None: | |
phase.end_event.record(torch.cuda.current_stream(device)) | |
# Update G_ema. | |
with torch.autograd.profiler.record_function('Gema'): | |
ema_nimg = ema_kimg * 1000 | |
if ema_rampup is not None: | |
ema_nimg = min(ema_nimg, cur_nimg * ema_rampup) | |
ema_beta = 0.5 ** (batch_size / max(ema_nimg, 1e-8)) | |
for p_ema, p in zip(G_ema.parameters(), G.parameters()): | |
p_ema.copy_(p.lerp(p_ema, ema_beta)) | |
for b_ema, b in zip(G_ema.buffers(), G.buffers()): | |
b_ema.copy_(b) | |
# Update state. | |
cur_nimg += batch_size | |
batch_idx += 1 | |
# Execute ADA heuristic. | |
if (ada_stats is not None) and (batch_idx % ada_interval == 0): | |
ada_stats.update() | |
adjust = np.sign(ada_stats['Loss/signs/real'] - ada_target) * \ | |
(batch_size * ada_interval) / (ada_kimg * 1000) | |
augment_pipe.p.copy_( | |
(augment_pipe.p + adjust).max(misc.constant(0, device=device))) | |
# Perform maintenance tasks once per tick. | |
done = (cur_nimg >= total_kimg * 1000) | |
if (not done) and (cur_tick != 0) and (cur_nimg < tick_start_nimg + kimg_per_tick * 1000): | |
continue | |
# Print status line, accumulating the same information in training_stats. | |
tick_end_time = time.time() | |
fields = [] | |
fields += [ | |
f"tick {training_stats.report0('Progress/tick', cur_tick):<5d}"] | |
fields += [ | |
f"kimg {training_stats.report0('Progress/kimg', cur_nimg / 1e3):<8.1f}"] | |
fields += [ | |
f"time {dnnlib.util.format_time(training_stats.report0('Timing/total_sec', tick_end_time - start_time)):<12s}"] | |
fields += [ | |
f"sec/tick {training_stats.report0('Timing/sec_per_tick', tick_end_time - tick_start_time):<7.1f}"] | |
fields += [ | |
f"sec/kimg {training_stats.report0('Timing/sec_per_kimg', (tick_end_time - tick_start_time) / (cur_nimg - tick_start_nimg) * 1e3):<7.2f}"] | |
fields += [ | |
f"maintenance {training_stats.report0('Timing/maintenance_sec', maintenance_time):<6.1f}"] | |
fields += [ | |
f"cpumem {training_stats.report0('Resources/cpu_mem_gb', psutil.Process(os.getpid()).memory_info().rss / 2**30):<6.2f}"] | |
fields += [ | |
f"gpumem {training_stats.report0('Resources/peak_gpu_mem_gb', torch.cuda.max_memory_allocated(device) / 2**30):<6.2f}"] | |
fields += [ | |
f"reserved {training_stats.report0('Resources/peak_gpu_mem_reserved_gb', torch.cuda.max_memory_reserved(device) / 2**30):<6.2f}"] | |
torch.cuda.reset_peak_memory_stats() | |
fields += [ | |
f"augment {training_stats.report0('Progress/augment', float(augment_pipe.p.cpu()) if augment_pipe is not None else 0):.3f}"] | |
training_stats.report0('Timing/total_hours', | |
(tick_end_time - start_time) / (60 * 60)) | |
training_stats.report0('Timing/total_days', | |
(tick_end_time - start_time) / (24 * 60 * 60)) | |
if rank == 0: | |
print(' '.join(fields)) | |
# Check for abort. | |
if (not done) and (abort_fn is not None) and abort_fn(): | |
done = True | |
if rank == 0: | |
print() | |
print('Aborting...') | |
# Save image snapshot. | |
if (rank == 0) and (image_snapshot_ticks is not None) and (done or cur_tick % image_snapshot_ticks == 0): | |
images = torch.cat([G_ema(z=z, c=c, noise_mode='const').cpu() | |
for z, c in zip(grid_z, grid_c)]).numpy() | |
save_image_grid(images, os.path.join( | |
run_dir, f'fakes{cur_nimg//1000:06d}.png'), drange=[-1, 1], grid_size=grid_size) | |
# Save network snapshot. | |
snapshot_pkl = None | |
snapshot_data = None | |
if (network_snapshot_ticks is not None) and (done or cur_tick % network_snapshot_ticks == 0): | |
snapshot_data = dict(G=G, D=D, G_ema=G_ema, augment_pipe=augment_pipe, | |
training_set_kwargs=dict(training_set_kwargs)) | |
for key, value in snapshot_data.items(): | |
if isinstance(value, torch.nn.Module): | |
value = copy.deepcopy(value).eval().requires_grad_(False) | |
if num_gpus > 1: | |
misc.check_ddp_consistency( | |
value, ignore_regex=r'.*\.[^.]+_(avg|ema)') | |
for param in misc.params_and_buffers(value): | |
torch.distributed.broadcast(param, src=0) | |
snapshot_data[key] = value.cpu() | |
del value # conserve memory | |
snapshot_pkl = os.path.join( | |
run_dir, f'network-snapshot-{cur_nimg//1000:06d}.pkl') | |
if rank == 0: | |
with open(snapshot_pkl, 'wb') as f: | |
pickle.dump(snapshot_data, f) | |
# Evaluate metrics. | |
if (snapshot_data is not None) and (len(metrics) > 0): | |
if rank == 0: | |
print('Evaluating metrics...') | |
for metric in metrics: | |
result_dict = metric_main.calc_metric(metric=metric, G=snapshot_data['G_ema'], | |
dataset_kwargs=training_set_kwargs, num_gpus=num_gpus, rank=rank, device=device) | |
if rank == 0: | |
metric_main.report_metric( | |
result_dict, run_dir=run_dir, snapshot_pkl=snapshot_pkl) | |
stats_metrics.update(result_dict.results) | |
del snapshot_data # conserve memory | |
# Collect statistics. | |
for phase in phases: | |
value = [] | |
if (phase.start_event is not None) and (phase.end_event is not None): | |
phase.end_event.synchronize() | |
value = phase.start_event.elapsed_time(phase.end_event) | |
training_stats.report0('Timing/' + phase.name, value) | |
stats_collector.update() | |
stats_dict = stats_collector.as_dict() | |
# Update logs. | |
timestamp = time.time() | |
if stats_jsonl is not None: | |
fields = dict(stats_dict, timestamp=timestamp) | |
stats_jsonl.write(json.dumps(fields) + '\n') | |
stats_jsonl.flush() | |
if stats_tfevents is not None: | |
global_step = int(cur_nimg / 1e3) | |
walltime = timestamp - start_time | |
for name, value in stats_dict.items(): | |
stats_tfevents.add_scalar( | |
name, value.mean, global_step=global_step, walltime=walltime) | |
for name, value in stats_metrics.items(): | |
stats_tfevents.add_scalar( | |
f'Metrics/{name}', value, global_step=global_step, walltime=walltime) | |
stats_tfevents.flush() | |
if progress_fn is not None: | |
progress_fn(cur_nimg // 1000, total_kimg) | |
# Update state. | |
cur_tick += 1 | |
tick_start_nimg = cur_nimg | |
tick_start_time = time.time() | |
maintenance_time = tick_start_time - tick_end_time | |
if done: | |
break | |
# Done. | |
if rank == 0: | |
print() | |
print('Exiting...') | |
# ---------------------------------------------------------------------------- | |