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import copy
import os
import random
from typing import Union, Optional, Tuple, List, Dict, Set
import numpy as np
import torch
import torch.nn as nn
import torch.optim as optim
from torch.utils.data import DataLoader
from torch.utils.data.dataloader import default_collate
from torch.utils.tensorboard import SummaryWriter
from tqdm import tqdm
from models.rgb_part_net import RGBPartNet
from utils.configuration import DataloaderConfiguration, \
HyperparameterConfiguration, DatasetConfiguration, ModelConfiguration, \
SystemConfiguration
from utils.dataset import CASIAB, ClipConditions, ClipViews, ClipClasses
from utils.sampler import TripletSampler
class Model:
def __init__(
self,
system_config: SystemConfiguration,
model_config: ModelConfiguration,
hyperparameter_config: HyperparameterConfiguration
):
self.disable_acc = system_config.get('disable_acc', False)
if self.disable_acc:
self.device = torch.device('cpu')
else: # Enable accelerator
if torch.cuda.is_available():
self.device = torch.device('cuda')
else:
print('No accelerator available, fallback to CPU.')
self.device = torch.device('cpu')
self.save_dir = system_config.get('save_dir', 'runs')
if not os.path.exists(self.save_dir):
os.makedirs(self.save_dir)
self.checkpoint_dir = os.path.join(self.save_dir, 'checkpoint')
self.log_dir = os.path.join(self.save_dir, 'logs')
for dir_ in (self.log_dir, self.checkpoint_dir):
if not os.path.exists(dir_):
os.mkdir(dir_)
self.meta = model_config
self.hp = hyperparameter_config
self.restore_iter = self.curr_iter = self.meta.get('restore_iter', 0)
self.total_iter = self.meta.get('total_iter', 80_000)
self.restore_iters = self.meta.get('restore_iters', (self.curr_iter,))
self.total_iters = self.meta.get('total_iters', (self.total_iter,))
self.is_train: bool = True
self.in_channels: int = 3
self.in_size: Tuple[int, int] = (64, 48)
self.pr: Optional[int] = None
self.k: Optional[int] = None
self._gallery_dataset_meta: Optional[Dict[str, List]] = None
self._probe_datasets_meta: Optional[Dict[str, Dict[str, List]]] = None
self._model_name: str = self.meta.get('name', 'RGB-GaitPart')
self._hp_sig: str = self._make_signature(self.hp)
self._dataset_sig: str = 'undefined'
self.rgb_pn: Optional[RGBPartNet] = None
self.optimizer: Optional[optim.Adam] = None
self.scheduler: Optional[optim.lr_scheduler.StepLR] = None
self.writer: Optional[SummaryWriter] = None
self.image_log_on = system_config.get('image_log_on', False)
self.val_size = system_config.get('val_size', 10)
self.CASIAB_GALLERY_SELECTOR = {
'selector': {'conditions': ClipConditions({r'nm-0[1-4]'})}
}
self.CASIAB_PROBE_SELECTORS = {
'nm': {'selector': {'conditions': ClipConditions({r'nm-0[5-6]'})}},
'bg': {'selector': {'conditions': ClipConditions({r'bg-0[1-2]'})}},
'cl': {'selector': {'conditions': ClipConditions({r'cl-0[1-2]'})}},
}
@property
def _model_sig(self) -> str:
return '_'.join(
(self._model_name, str(self.curr_iter + 1), str(self.total_iter))
)
@property
def _checkpoint_sig(self) -> str:
return '_'.join((self._model_sig, self._hp_sig, self._dataset_sig,
str(self.pr), str(self.k)))
@property
def _checkpoint_name(self) -> str:
return os.path.join(self.checkpoint_dir, self._checkpoint_sig)
@property
def _log_sig(self) -> str:
return '_'.join((self._model_name, str(self.total_iter), self._hp_sig,
self._dataset_sig, str(self.pr), str(self.k)))
@property
def _log_name(self) -> str:
return os.path.join(self.log_dir, self._log_sig)
def fit_all(
self,
dataset_config: DatasetConfiguration,
dataset_selectors: Dict[
str, Dict[str, Union[ClipClasses, ClipConditions, ClipViews]]
],
dataloader_config: DataloaderConfiguration,
):
for (restore_iter, total_iter, (condition, selector)) in zip(
self.restore_iters, self.total_iters, dataset_selectors.items()
):
print(f'Training model {condition} ...')
# Skip finished model
if restore_iter == total_iter:
continue
# Check invalid restore iter
elif restore_iter > total_iter:
raise ValueError("Restore iter '{}' should less than total "
"iter '{}'".format(restore_iter, total_iter))
self.restore_iter = self.curr_iter = restore_iter
self.total_iter = total_iter
self.fit(
dict(**dataset_config, **{'selector': selector}),
dataloader_config
)
def fit(
self,
dataset_config: DatasetConfiguration,
dataloader_config: DataloaderConfiguration,
):
self.is_train = True
# Validation dataset
# (the first `val_size` subjects from evaluation set)
val_dataset_config = copy.deepcopy(dataset_config)
train_size = dataset_config.get('train_size', 74)
val_dataset_config['train_size'] = train_size + self.val_size
val_dataset_config['selector']['classes'] = ClipClasses({
str(c).zfill(3)
for c in range(train_size + 1, train_size + self.val_size + 1)
})
val_dataset = self._parse_dataset_config(val_dataset_config)
val_dataloader = iter(self._parse_dataloader_config(
val_dataset, dataloader_config
))
# Training dataset
train_dataset = self._parse_dataset_config(dataset_config)
train_dataloader = iter(self._parse_dataloader_config(
train_dataset, dataloader_config
))
# Prepare for model, optimizer and scheduler
model_hp: dict = self.hp.get('model', {}).copy()
optim_hp: Dict = self.hp.get('optimizer', {}).copy()
sched_hp = self.hp.get('scheduler', {})
self.rgb_pn = RGBPartNet(self.in_channels, self.in_size, **model_hp,
image_log_on=self.image_log_on)
# Try to accelerate computation using CUDA or others
self.rgb_pn = self.rgb_pn.to(self.device)
self.optimizer = optim.Adam(self.rgb_pn.parameters(), **optim_hp)
start_step = sched_hp.get('start_step', 15_000)
final_gamma = sched_hp.get('final_gamma', 0.001)
all_step = self.total_iter - start_step
self.scheduler = optim.lr_scheduler.LambdaLR(
self.optimizer,
lambda t: final_gamma ** ((t - start_step) / all_step)
if t > start_step else 1,
)
self.writer = SummaryWriter(self._log_name)
# Set seeds for reproducibility
random.seed(0)
torch.manual_seed(0)
self.rgb_pn.train()
# Init weights at first iter
if self.curr_iter == 0:
self.rgb_pn.apply(self.init_weights)
else: # Load saved state dicts
# Offset a iter to load last checkpoint
self.curr_iter -= 1
checkpoint = torch.load(self._checkpoint_name)
random.setstate(checkpoint['rand_states'][0])
torch.set_rng_state(checkpoint['rand_states'][1])
self.rgb_pn.load_state_dict(checkpoint['model_state_dict'])
self.optimizer.load_state_dict(checkpoint['optim_state_dict'])
self.scheduler.load_state_dict(checkpoint['sched_state_dict'])
# Training start
for self.curr_iter in tqdm(range(self.restore_iter, self.total_iter),
desc='Training'):
batch_c1, batch_c2 = next(train_dataloader)
# Zero the parameter gradients
self.optimizer.zero_grad()
# forward + backward + optimize
x_c1 = batch_c1['clip'].to(self.device)
x_c2 = batch_c2['clip'].to(self.device)
losses, features, images = self.rgb_pn(x_c1, x_c2)
loss = losses.sum()
loss.backward()
self.optimizer.step()
self.scheduler.step()
# Learning rate
self.writer.add_scalar(
'Learning rate', self.scheduler.get_last_lr()[0], self.curr_iter
)
# Other stats
self._write_stat('Train', loss, losses)
if self.curr_iter % 100 == 99:
# Write disentangled images
if self.image_log_on:
i_a, i_c, i_p = images
self.writer.add_images(
'Appearance image', i_a, self.curr_iter
)
self.writer.add_images(
'Canonical image', i_c, self.curr_iter
)
for i, (o, p) in enumerate(zip(x_c1, i_p)):
self.writer.add_images(
f'Original image/batch {i}', o, self.curr_iter
)
self.writer.add_images(
f'Pose image/batch {i}', p, self.curr_iter
)
f_a, f_c, f_p = features
for i, (f_a_i, f_c_i, f_p_i) in enumerate(
zip(f_a, f_c, f_p)
):
self.writer.add_images(
f'Appearance features/Layer {i}',
f_a_i[:, :3, :, :], self.curr_iter
)
self.writer.add_images(
f'Canonical features/Layer {i}',
f_c_i[:, :3, :, :], self.curr_iter
)
for j, p in enumerate(f_p_i):
self.writer.add_images(
f'Pose features/Layer {i}/batch{j}',
p[:, :3, :, :], self.curr_iter
)
# Calculate losses on testing batch
batch_c1, batch_c2 = next(val_dataloader)
x_c1 = batch_c1['clip'].to(self.device)
x_c2 = batch_c2['clip'].to(self.device)
with torch.no_grad():
losses, _, _ = self.rgb_pn(x_c1, x_c2)
loss = losses.sum()
self._write_stat('Val', loss, losses)
# Checkpoint
if self.curr_iter % 1000 == 999:
torch.save({
'rand_states': (random.getstate(), torch.get_rng_state()),
'model_state_dict': self.rgb_pn.state_dict(),
'optim_state_dict': self.optimizer.state_dict(),
'sched_state_dict': self.scheduler.state_dict(),
}, self._checkpoint_name)
self.writer.close()
def _write_stat(
self, postfix, loss, losses
):
# Write losses to TensorBoard
self.writer.add_scalar(f'Loss/all {postfix}', loss, self.curr_iter)
self.writer.add_scalars(f'Loss/disentanglement {postfix}', dict(zip((
'Cross reconstruction loss', 'Canonical consistency loss',
'Pose similarity loss'
), losses)), self.curr_iter)
def transform(
self,
iters: Tuple[int],
dataset_config: DatasetConfiguration,
dataset_selectors: Dict[
str, Dict[str, Union[ClipClasses, ClipConditions, ClipViews]]
],
dataloader_config: DataloaderConfiguration,
is_train: bool = False
):
# Split gallery and probe dataset
gallery_dataloader, probe_dataloaders = self._split_gallery_probe(
dataset_config, dataloader_config, is_train
)
# Get pretrained models at iter_
checkpoints = self._load_pretrained(
iters, dataset_config, dataset_selectors
)
# Init models
model_hp: dict = self.hp.get('model', {}).copy()
self.rgb_pn = RGBPartNet(self.in_channels, self.in_size, **model_hp)
# Try to accelerate computation using CUDA or others
self.rgb_pn = self.rgb_pn.to(self.device)
self.rgb_pn.eval()
gallery_samples, probe_samples = {}, {}
for (condition, probe_dataloader) in probe_dataloaders.items():
checkpoint = torch.load(checkpoints[condition])
self.rgb_pn.load_state_dict(checkpoint['model_state_dict'])
# Gallery
gallery_samples_c = []
for sample in tqdm(gallery_dataloader,
desc=f'Transforming gallery {condition}',
unit='clips'):
gallery_samples_c.append(self._get_eval_sample(sample))
gallery_samples[condition] = default_collate(gallery_samples_c)
# Probe
probe_samples_c = []
for sample in tqdm(probe_dataloader,
desc=f'Transforming probe {condition}',
unit='clips'):
probe_samples_c.append(self._get_eval_sample(sample))
probe_samples_c = default_collate(probe_samples_c)
probe_samples_c['meta'] = self._probe_datasets_meta[condition]
probe_samples[condition] = probe_samples_c
gallery_samples['meta'] = self._gallery_dataset_meta
return gallery_samples, probe_samples
def _get_eval_sample(self, sample: Dict[str, Union[List, torch.Tensor]]):
label, condition, view, clip = sample.values()
with torch.no_grad():
feature_c, feature_p = self.rgb_pn(clip.to(self.device))
return {
'label': label.item(),
'condition': condition[0],
'view': view[0],
'feature': torch.cat((feature_c, feature_p)).view(-1)
}
def _load_pretrained(
self,
iters: Tuple[int],
dataset_config: DatasetConfiguration,
dataset_selectors: Dict[
str, Dict[str, Union[ClipClasses, ClipConditions, ClipViews]]
]
) -> Dict[str, str]:
checkpoints = {}
for (iter_, total_iter, (condition, selector)) in zip(
iters, self.total_iters, dataset_selectors.items()
):
self.curr_iter = iter_ - 1
self.total_iter = total_iter
self._dataset_sig = self._make_signature(
dict(**dataset_config, **selector),
popped_keys=['root_dir', 'cache_on']
)
checkpoints[condition] = self._checkpoint_name
return checkpoints
def _split_gallery_probe(
self,
dataset_config: DatasetConfiguration,
dataloader_config: DataloaderConfiguration,
is_train: bool = False
) -> Tuple[DataLoader, Dict[str, DataLoader]]:
dataset_name = dataset_config.get('name', 'CASIA-B')
if dataset_name == 'CASIA-B':
self.is_train = is_train
gallery_dataset = self._parse_dataset_config(
dict(**dataset_config, **self.CASIAB_GALLERY_SELECTOR)
)
probe_datasets = {
condition: self._parse_dataset_config(
dict(**dataset_config, **selector)
)
for (condition, selector) in self.CASIAB_PROBE_SELECTORS.items()
}
self._gallery_dataset_meta = gallery_dataset.metadata
self._probe_datasets_meta = {
condition: dataset.metadata
for (condition, dataset) in probe_datasets.items()
}
self.is_train = False
gallery_dataloader = self._parse_dataloader_config(
gallery_dataset, dataloader_config
)
probe_dataloaders = {
condition: self._parse_dataloader_config(
dataset, dataloader_config
)
for (condition, dataset) in probe_datasets.items()
}
elif dataset_name == 'FVG':
# TODO
gallery_dataloader = None
probe_dataloaders = None
else:
raise ValueError('Invalid dataset: {0}'.format(dataset_name))
return gallery_dataloader, probe_dataloaders
@staticmethod
def init_weights(m):
if isinstance(m, nn.modules.conv._ConvNd):
nn.init.normal_(m.weight, 0.0, 0.01)
elif isinstance(m, nn.modules.batchnorm._NormBase):
nn.init.normal_(m.weight, 1.0, 0.01)
nn.init.zeros_(m.bias)
elif isinstance(m, nn.Linear):
nn.init.xavier_uniform_(m.weight)
def _parse_dataset_config(
self,
dataset_config: DatasetConfiguration
) -> Union[CASIAB]:
self.in_channels = dataset_config.get('num_input_channels', 3)
self.in_size = dataset_config.get('frame_size', (64, 48))
self._dataset_sig = self._make_signature(
dataset_config,
popped_keys=['root_dir', 'cache_on']
)
config: Dict = dataset_config.copy()
name = config.pop('name', 'CASIA-B')
if name == 'CASIA-B':
return CASIAB(**config, is_train=self.is_train)
elif name == 'FVG':
# TODO
pass
raise ValueError('Invalid dataset: {0}'.format(name))
def _parse_dataloader_config(
self,
dataset: Union[CASIAB],
dataloader_config: DataloaderConfiguration
) -> DataLoader:
config: Dict = dataloader_config.copy()
(self.pr, self.k) = config.pop('batch_size', (8, 16))
if self.is_train:
triplet_sampler = TripletSampler(dataset, (self.pr, self.k))
return DataLoader(dataset,
batch_sampler=triplet_sampler,
collate_fn=self._batch_splitter,
**config)
else: # is_test
return DataLoader(dataset, **config)
def _batch_splitter(
self,
batch: List[Dict[str, Union[np.int64, str, torch.Tensor]]]
) -> Tuple[Dict[str, Union[List[str], torch.Tensor]],
Dict[str, Union[List[str], torch.Tensor]]]:
"""
Disentanglement need two random conditions, this function will
split pr * k * 2 samples to 2 dicts each containing pr * k
samples. labels and clip data are tensor, and others are list.
"""
_batch = [[], []]
for i in range(0, self.pr * self.k * 2, self.k * 2):
_batch[0] += batch[i:i + self.k]
_batch[1] += batch[i + self.k:i + self.k * 2]
return default_collate(_batch[0]), default_collate(_batch[1])
def _make_signature(self,
config: Dict,
popped_keys: Optional[List] = None) -> str:
_config = config.copy()
if popped_keys:
for key in popped_keys:
_config.pop(key, None)
return self._gen_sig(list(_config.values()))
def _gen_sig(self, values: Union[Tuple, List, Set, str, int, float]) -> str:
strings = []
for v in values:
if isinstance(v, str):
strings.append(v)
elif isinstance(v, (Tuple, List)):
strings.append(self._gen_sig(v))
elif isinstance(v, Set):
strings.append(self._gen_sig(sorted(list(v))))
elif isinstance(v, Dict):
strings.append(self._gen_sig(list(v.values())))
else:
strings.append(str(v))
return '_'.join(strings)
|