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import os
import time
import copy
from datetime import timedelta
import yaml
import torch
import torch.distributed as dist
from omegaconf import OmegaConf
from tqdm import tqdm
from torch.utils.data import IterableDataset, DataLoader
from torch.utils.data.distributed import DistributedSampler
from torch.nn.parallel import DistributedDataParallel
import datasets
import models
import utils
from .trainers import register
from comet_ml import Experiment
from datetime import datetime
@register('base_trainer')
class BaseTrainer():
def __init__(self, env, config):
self.env = env
self.config = config
self.config_dict = OmegaConf.to_container(config, resolve=True)
if config.get('allow_tf32', False):
torch.backends.cuda.matmul.allow_tf32 = True
torch.backends.cudnn.allow_tf32 = True
dist.init_process_group(backend='nccl', timeout=timedelta(minutes=240))
self.rank = int(os.environ['RANK'])
self.local_rank = int(os.environ['LOCAL_RANK'])
self.world_size = int(os.environ['WORLD_SIZE'])
self.node_id = int(os.environ['GROUP_RANK'])
self.node_tot = self.world_size // int(os.environ['LOCAL_WORLD_SIZE'])
self.is_master = (self.rank == 0)
torch.cuda.set_device(self.local_rank)
self.device = torch.device('cuda', torch.cuda.current_device())
if self.is_master:
# Setup path
if env['resume']:
replace = False
force_replace = False
else:
replace = True
force_replace = env['force_replace']
utils.ensure_path(env['save_dir'], replace=replace, force_replace=force_replace)
# Save config
with open(os.path.join(env['save_dir'], 'config.yaml'), 'w') as f:
yaml.dump(self.config_dict, f, sort_keys=False)
# Setup logging
logger = utils.set_logger(os.path.join(env['save_dir'], 'log.txt'))
self.log = logger.info
# Initialize Comet ML experiment
self.experiment = None
if self.is_master: # Only log from master process
self.experiment = Experiment(
project_name=self.config.get("comet_project", "audio-ldm"),
workspace=os.environ.get("COMET_WORKSPACE"),
experiment_name=self.config.get("exp_name", f"audio_ldm_{datetime.now().strftime('%Y%m%d_%H%M%S')}")
)
# Log hyperparameters
self.experiment.log_parameters(self.config)
# Add tags
tags = self.config.get("tags", ["audio", "ldm", "diffusion"])
for tag in tags:
self.experiment.add_tag(tag)
else:
self.log = lambda *args, **kwargs: None
self.experiment = None
dist.barrier()
self.log(f'Environment setup done. World size: {self.world_size}.')
def run(self, eval_only=False):
self.make_datasets()
resume_ckpt = os.path.join(self.env['save_dir'], 'ckpt-last.pth')
resume = (self.env['resume'] and os.path.isfile(resume_ckpt))
if resume:
self.resume_ckpt = torch.load(resume_ckpt, map_location='cpu')
else:
self.resume_ckpt = None
self.make_model()
if resume:
self.model.load_state_dict(self.resume_ckpt['model']['sd'])
self.resume_ckpt['model'] = None
self.log(f'Resumed model from checkpoint {resume_ckpt}.')
if eval_only:
self.model_ddp = self.model
with torch.no_grad():
self.log_buffer = [f'Eval']
self.iter = 0
self.evaluate()
self.visualize()
self.log(', '.join(self.log_buffer))
else:
self.model_ddp = DistributedDataParallel(
self.model,
device_ids=[self.local_rank],
find_unused_parameters=self.config.get('find_unused_parameters', False)
)
self.make_optimizers()
if resume:
for name, optimizer in self.resume_ckpt['optimizers'].items():
self.optimizers[name].load_state_dict(optimizer['sd'])
self.resume_ckpt['optimizers'] = None
self.log(f'Resumed optimizers.')
self.run_training()
self.on_train_end()
def on_train_end(self):
"""Called at the end of training"""
if self.experiment:
# Log final model
model_path = os.path.join(self.env['save_dir'], 'final_model.pt')
torch.save(self.model.state_dict(), model_path)
self.experiment.log_model("final_model", model_path)
# End the experiment
self.experiment.end()
def make_distributed_loader(self, dataset, batch_size, shuffle, drop_last, num_workers, pin_memory):
assert batch_size % self.world_size == 0
assert num_workers % self.world_size == 0
if isinstance(dataset, IterableDataset):
sampler = None
else:
sampler = DistributedSampler(dataset, shuffle=shuffle)
loader = DataLoader(
dataset,
batch_size=batch_size // self.world_size,
drop_last=drop_last,
sampler=sampler,
num_workers=num_workers // self.world_size,
pin_memory=pin_memory
)
return loader, sampler
def make_datasets(self):
self.datasets = dict()
self.loaders = dict()
self.loader_samplers = dict()
for split, spec in self.config.datasets.items():
loader_spec = spec.pop('loader')
dataset = datasets.make(spec)
self.datasets[split] = dataset
if isinstance(dataset, IterableDataset):
self.log(f'Dataset {split}: IterableDataset')
else:
self.log(f'Dataset {split}: len={len(dataset)}')
drop_last = loader_spec.get('drop_last', True)
shuffle = loader_spec.get('shuffle', True)
self.loaders[split], self.loader_samplers[split] = self.make_distributed_loader(
dataset,
loader_spec.batch_size,
shuffle,
drop_last,
loader_spec.num_workers,
loader_spec.get('pin_memory', True)
)
def make_model(self):
model = models.make(self.config.model)
model = torch.nn.SyncBatchNorm.convert_sync_batchnorm(model)
self.model = model.to(self.device)
self.log(f'Model: #params={utils.compute_num_params(model)}')
def make_optimizers(self):
self.optimizers = {'model': utils.make_optimizer(self.model.parameters(), self.config.optimizers['model'])}
def run_training(self):
config = self.config
max_iter = config['max_iter']
epoch_iter = config['epoch_iter']
assert max_iter % epoch_iter == 0
max_epoch = max_iter // epoch_iter
save_iter = config.get('save_iter')
if save_iter is not None:
assert save_iter % epoch_iter == 0
save_epoch = save_iter // epoch_iter
print('save_epoch', save_epoch)
else:
save_epoch = max_epoch + 1
eval_iter = config.get('eval_iter')
if eval_iter is not None:
assert eval_iter % epoch_iter == 0
eval_epoch = eval_iter // epoch_iter
else:
eval_epoch = max_epoch + 1
vis_iter = config.get('vis_iter')
if vis_iter is not None:
assert vis_iter % epoch_iter == 0
vis_epoch = vis_iter // epoch_iter
else:
vis_epoch = max_epoch + 1
if config.get('ckpt_select_metric') is not None:
m = config.ckpt_select_metric
self.ckpt_select_metric = m.name
self.ckpt_select_type = m.type
if m.type == 'min':
self.ckpt_select_v = 1e18
elif m.type == 'max':
self.ckpt_select_v = -1e18
else:
self.ckpt_select_metric = None
self.ckpt_select_v = 0
self.train_loader = self.loaders['train']
self.train_loader_sampler = self.loader_samplers['train']
self.train_loader_epoch = 0
self.train_loader_iter = None
self.iter = 0
if self.resume_ckpt is not None:
for _ in range(self.resume_ckpt['iter']):
self.iter += 1
self.at_train_iter_start()
self.ckpt_select_v = self.resume_ckpt['ckpt_select_v']
self.train_loader_epoch = self.resume_ckpt['train_loader_epoch']
self.train_loader_iter = None
self.resume_ckpt = None
self.log(f'Resumed iter status.')
if config.get('vis_before_training', False):
self.visualize()
start_epoch = self.iter // epoch_iter + 1
epoch_timer = utils.EpochTimer(max_epoch - start_epoch + 1)
for epoch in range(start_epoch, max_epoch + 1):
self.log_buffer = [f'Epoch {epoch}']
for sampler in self.loader_samplers.values():
if sampler is not self.train_loader_sampler:
sampler.set_epoch(epoch)
self.model_ddp.train()
ave_scalars = dict()
pbar = range(1, epoch_iter + 1)
if self.is_master and epoch == start_epoch:
pbar = tqdm(pbar, desc='train', leave=False)
t_data = 0
t_nondata = 0
t_before_data = time.time()
for _ in pbar:
self.iter += 1
self.at_train_iter_start()
try:
if self.train_loader_iter is None:
raise StopIteration
data = next(self.train_loader_iter)
except StopIteration:
self.train_loader_epoch += 1
self.train_loader_sampler.set_epoch(self.train_loader_epoch)
self.train_loader_iter = iter(self.train_loader)
data = next(self.train_loader_iter)
t_after_data = time.time()
t_data += t_after_data - t_before_data
for k, v in data.items():
data[k] = v.to(self.device) if torch.is_tensor(v) else v
ret = self.train_step(data)
t_before_data = time.time()
t_nondata += t_before_data - t_after_data
if self.is_master and epoch == start_epoch:
pbar.set_description(desc=f'train: loss={ret["loss"]:.4f}')
# save the model every 1000 iterations
if self.iter % 100 == 0:
self.save_ckpt(f'ckpt-{self.iter}.pth')
self.save_ckpt('ckpt-last.pth')
if epoch % save_epoch == 0 and epoch != max_epoch:
self.save_ckpt(f'ckpt-{self.iter}.pth')
if epoch % eval_epoch == 0:
with torch.no_grad():
eval_ave_scalars = self.evaluate()
if self.ckpt_select_metric is not None:
v = eval_ave_scalars[self.ckpt_select_metric].item()
if ((self.ckpt_select_type == 'min' and v < self.ckpt_select_v) or
(self.ckpt_select_type == 'max' and v > self.ckpt_select_v)):
self.ckpt_select_v = v
self.save_ckpt('ckpt-best.pth')
if epoch % vis_epoch == 0:
with torch.no_grad():
self.visualize()
def at_train_iter_start(self):
pass
def train_step(self, data, bp=True):
print('data', data)
if self.config.get('autocast_bfloat16', False):
with torch.cuda.amp.autocast(dtype=torch.bfloat16):
ret = self.model_ddp(data)
else:
ret = self.model_ddp(data)
loss = ret.pop('loss')
ret['loss'] = loss.item()
if bp:
self.model_ddp.zero_grad()
loss.backward()
for o in self.optimizers.values():
o.step()
return ret
def evaluate(self):
self.model_ddp.eval()
ave_scalars = dict()
pbar = self.loaders['val']
for data in pbar:
for k, v in data.items():
data[k] = v.to(self.device) if torch.is_tensor(v) else v
ret = self.train_step(data, bp=False)
bs = len(next(iter(data.values())))
for k, v in ret.items():
if ave_scalars.get(k) is None:
ave_scalars[k] = utils.Averager()
ave_scalars[k].add(v, n=bs)
self.sync_ave_scalars(ave_scalars)
logtext = 'val:'
for k, v in ave_scalars.items():
logtext += f' {k}={v.item():.4f}'
self.log_scalar('val/' + k, v.item())
self.log_buffer.append(logtext)
return ave_scalars
def visualize(self):
pass
def save_ckpt(self, filename):
if self.is_master:
model_spec = copy.copy(self.config_dict['model'])
model_spec['sd'] = self.model.state_dict()
optimizers_spec = dict()
for name, spec in self.config_dict['optimizers'].items():
spec = copy.copy(spec)
spec['sd'] = self.optimizers[name].state_dict()
optimizers_spec[name] = spec
ckpt = {
'config': self.config_dict,
'model': model_spec,
'optimizers': optimizers_spec,
'iter': self.iter,
'train_loader_epoch': self.train_loader_epoch,
'ckpt_select_v': self.ckpt_select_v,
}
torch.save(ckpt, os.path.join(self.env['save_dir'], filename))
dist.barrier()
def sync_ave_scalars(self, ave_scalars):
keys = sorted(list(ave_scalars.keys()))
for k in keys:
if not k.startswith('_'):
v = ave_scalars[k]
vt = torch.tensor(v.item(), device=self.device)
dist.all_reduce(vt, op=dist.ReduceOp.SUM)
torch.cuda.synchronize()
ave_scalars[k].v = vt.item() / self.world_size
ave_scalars[k].n *= self.world_size
def log_scalar(self, k, v):
if self.experiment:
self.experiment.log_metric(k, v, step=self.iter)
def log_image(self, k, v):
if self.experiment:
self.experiment.log_image(k, v, step=self.iter)
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