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import os
from datetime import datetime
from typing import Union, Optional, Tuple, List, Dict, Set
import numpy as np
import torch
import torch.nn as nn
import torch.nn.functional as F
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.dataset import CASIAB, ClipConditions, ClipViews, ClipClasses
from utils.sampler import TripletSampler
class Model:
def __init__(
self,
system_config: Dict,
model_config: Dict,
hyperparameter_config: Dict
):
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.curr_iter = self.meta.get('restore_iter', 0)
self.total_iter = self.meta.get('total_iter', 80_000)
self.curr_iters = self.meta.get('restore_iters', (0, 0, 0))
self.total_iters = self.meta.get('total_iters', (80000, 80000, 80000))
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.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), 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: Dict,
dataset_selectors: Dict[
str, Dict[str, Union[ClipClasses, ClipConditions, ClipViews]]
],
dataloader_config: Dict,
):
for (curr_iter, total_iter, (condition, selector)) in zip(
self.curr_iters, self.total_iters, dataset_selectors.items()
):
print(f'Training model {condition} ...')
# Skip finished model
if curr_iter == total_iter:
continue
# Check invalid restore iter
elif curr_iter > total_iter:
raise ValueError("Restore iter '{}' should less than total "
"iter '{}'".format(curr_iter, total_iter))
self.curr_iter = curr_iter
self.total_iter = total_iter
self.fit(
dict(**dataset_config, **{'selector': selector}),
dataloader_config
)
def fit(
self,
dataset_config: Dict,
dataloader_config: Dict,
):
self.is_train = True
dataset = self._parse_dataset_config(dataset_config)
dataloader = self._parse_dataloader_config(dataset, dataloader_config)
# Prepare for model, optimizer and scheduler
model_hp = self.hp.get('model', {})
optim_hp: Dict = self.hp.get('optimizer', {}).copy()
start_iter = optim_hp.pop('start_iter', 0)
ae_optim_hp = optim_hp.pop('auto_encoder', {})
pn_optim_hp = optim_hp.pop('part_net', {})
hpm_optim_hp = optim_hp.pop('hpm', {})
fc_optim_hp = optim_hp.pop('fc', {})
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([
{'params': self.rgb_pn.ae.parameters(), **ae_optim_hp},
{'params': self.rgb_pn.pn.parameters(), **pn_optim_hp},
{'params': self.rgb_pn.hpm.parameters(), **hpm_optim_hp},
{'params': self.rgb_pn.fc_mat, **fc_optim_hp}
], **optim_hp)
sched_gamma = sched_hp.get('gamma', 0.9)
sched_step_size = sched_hp.get('step_size', 500)
self.scheduler = optim.lr_scheduler.LambdaLR(self.optimizer, lr_lambda=[
lambda epoch: sched_gamma ** (epoch // sched_step_size),
lambda epoch: 0 if epoch < start_iter else 1,
lambda epoch: 0 if epoch < start_iter else 1,
lambda epoch: 0 if epoch < start_iter else 1,
])
self.writer = SummaryWriter(self._log_name)
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
checkpoint = torch.load(self._checkpoint_name)
iter_, loss = checkpoint['iter'], checkpoint['loss']
print('{0:5d} loss: {1:.3f}'.format(iter_, loss))
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
start_time = datetime.now()
running_loss = torch.zeros(5, device=self.device)
print(f"{'Time':^8} {'Iter':^5} {'Loss':^6}",
f"{'Xrecon':^8} {'CanoCons':^8} {'PoseSim':^8}",
f"{'BATripH':^8} {'BATripP':^8} {'LRs':^19}")
for (batch_c1, batch_c2) in dataloader:
self.curr_iter += 1
# 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)
y = batch_c1['label'].to(self.device)
# Duplicate labels for each part
y = y.unsqueeze(1).repeat(1, self.rgb_pn.num_total_parts)
losses, images = self.rgb_pn(x_c1, x_c2, y)
loss = losses.sum()
loss.backward()
self.optimizer.step()
# Statistics and checkpoint
running_loss += losses.detach()
# Write losses to TensorBoard
self.writer.add_scalar('Loss/all', loss, self.curr_iter)
self.writer.add_scalars('Loss/details', dict(zip([
'Cross reconstruction loss', 'Canonical consistency loss',
'Pose similarity loss', 'Batch All triplet loss (HPM)',
'Batch All triplet loss (PartNet)'
], losses)), self.curr_iter)
if self.curr_iter % 100 == 0:
lrs = self.scheduler.get_last_lr()
# Write learning rates
self.writer.add_scalar(
'Learning rate/Auto-encoder', lrs[0], self.curr_iter
)
self.writer.add_scalar(
'Learning rate/Others', lrs[1], self.curr_iter
)
# 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
)
time_used = datetime.now() - start_time
remaining_minute, second = divmod(time_used.seconds, 60)
hour, minute = divmod(remaining_minute, 60)
print(f'{hour:02}:{minute:02}:{second:02}',
f'{self.curr_iter:5d} {running_loss.sum() / 100:6.3f}',
'{:f} {:f} {:f} {:f} {:f}'.format(*running_loss / 100),
'{:.3e} {:.3e}'.format(lrs[0], lrs[1]))
running_loss.zero_()
# Step scheduler
self.scheduler.step()
if self.curr_iter % 1000 == 0:
torch.save({
'iter': self.curr_iter,
'model_state_dict': self.rgb_pn.state_dict(),
'optim_state_dict': self.optimizer.state_dict(),
'sched_state_dict': self.scheduler.state_dict(),
'loss': loss,
}, self._checkpoint_name)
if self.curr_iter == self.total_iter:
self.writer.close()
break
def predict_all(
self,
iters: Tuple[int],
dataset_config: Dict,
dataset_selectors: Dict[
str, Dict[str, Union[ClipClasses, ClipConditions, ClipViews]]
],
dataloader_config: Dict,
) -> Dict[str, torch.Tensor]:
# Transform data to features
gallery_samples, probe_samples = self.transform(
iters, dataset_config, dataset_selectors, dataloader_config
)
# Evaluate features
accuracy = self.evaluate(gallery_samples, probe_samples)
return accuracy
def transform(
self,
iters: Tuple[int],
dataset_config: Dict,
dataset_selectors: Dict[
str, Dict[str, Union[ClipClasses, ClipConditions, ClipViews]]
],
dataloader_config: Dict
):
self.is_train = False
# Split gallery and probe dataset
gallery_dataloader, probe_dataloaders = self._split_gallery_probe(
dataset_config, dataloader_config
)
# Get pretrained models at iter_
checkpoints = self._load_pretrained(
iters, dataset_config, dataset_selectors
)
# Init models
model_hp = self.hp.get('model', {})
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 = [], {}
# Gallery
checkpoint = torch.load(list(checkpoints.values())[0])
self.rgb_pn.load_state_dict(checkpoint['model_state_dict'])
for sample in tqdm(gallery_dataloader,
desc='Transforming gallery', unit='clips'):
gallery_samples.append(self._get_eval_sample(sample))
gallery_samples = default_collate(gallery_samples)
# Probe
for (condition, dataloader) in probe_dataloaders.items():
checkpoint = torch.load(checkpoints[condition])
self.rgb_pn.load_state_dict(checkpoint['model_state_dict'])
probe_samples_c = []
for sample in tqdm(dataloader,
desc=f'Transforming probe {condition}',
unit='clips'):
probe_samples_c.append(self._get_eval_sample(sample))
probe_samples[condition] = default_collate(probe_samples_c)
return gallery_samples, probe_samples
def _get_eval_sample(self, sample: Dict[str, Union[List, torch.Tensor]]):
label = sample.pop('label').item()
clip = sample.pop('clip').to(self.device)
feature = self.rgb_pn(clip).detach()
return {
**{'label': label},
**sample,
**{'feature': feature}
}
def evaluate(
self,
gallery_samples: Dict[str, Union[List[str], torch.Tensor]],
probe_samples: Dict[str, Dict[str, Union[List[str], torch.Tensor]]],
num_ranks: int = 5
) -> Dict[str, torch.Tensor]:
probe_conditions = self._probe_datasets_meta.keys()
gallery_views_meta = self._gallery_dataset_meta['views']
probe_views_meta = list(self._probe_datasets_meta.values())[0]['views']
accuracy = {
condition: torch.empty(
len(gallery_views_meta), len(probe_views_meta), num_ranks
)
for condition in self._probe_datasets_meta.keys()
}
(labels_g, _, views_g, features_g) = gallery_samples.values()
views_g = np.asarray(views_g)
for (v_g_i, view_g) in enumerate(gallery_views_meta):
gallery_view_mask = (views_g == view_g)
f_g = features_g[gallery_view_mask]
y_g = labels_g[gallery_view_mask]
for condition in probe_conditions:
probe_samples_c = probe_samples[condition]
accuracy_c = accuracy[condition]
(labels_p, _, views_p, features_p) = probe_samples_c.values()
views_p = np.asarray(views_p)
for (v_p_i, view_p) in enumerate(probe_views_meta):
probe_view_mask = (views_p == view_p)
f_p = features_p[probe_view_mask]
y_p = labels_p[probe_view_mask]
# Euclidean distance
f_p_squared_sum = torch.sum(f_p ** 2, dim=1).unsqueeze(1)
f_g_squared_sum = torch.sum(f_g ** 2, dim=1).unsqueeze(0)
f_p_times_f_g_sum = f_p @ f_g.T
dist = torch.sqrt(F.relu(
f_p_squared_sum - 2*f_p_times_f_g_sum + f_g_squared_sum
))
# Ranked accuracy
rank_mask = dist.argsort(1)[:, :num_ranks]
positive_mat = torch.eq(y_p.unsqueeze(1),
y_g[rank_mask]).cumsum(1).gt(0)
positive_counts = positive_mat.sum(0)
total_counts, _ = dist.size()
accuracy_c[v_g_i, v_p_i, :] = positive_counts / total_counts
return accuracy
def _load_pretrained(
self,
iters: Tuple[int],
dataset_config: Dict,
dataset_selectors: Dict[
str, Dict[str, Union[ClipClasses, ClipConditions, ClipViews]]
]
) -> Dict[str, str]:
checkpoints = {}
for (iter_, (condition, selector)) in zip(
iters, dataset_selectors.items()
):
self.curr_iter = 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: Dict,
dataloader_config: Dict,
) -> Tuple[DataLoader, Dict[str, DataLoader]]:
dataset_name = dataset_config.get('name', 'CASIA-B')
if dataset_name == 'CASIA-B':
gallery_dataset = self._parse_dataset_config(
dict(**dataset_config, **self.CASIAB_GALLERY_SELECTOR)
)
self._gallery_dataset_meta = gallery_dataset.metadata
gallery_dataloader = self._parse_dataloader_config(
gallery_dataset, dataloader_config
)
probe_datasets = {
condition: self._parse_dataset_config(
dict(**dataset_config, **selector)
)
for (condition, selector) in self.CASIAB_PROBE_SELECTORS.items()
}
self._probe_datasets_meta = {
condition: dataset.metadata
for (condition, dataset) in probe_datasets.items()
}
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)
elif isinstance(m, RGBPartNet):
nn.init.xavier_uniform_(m.fc_mat)
def _parse_dataset_config(
self,
dataset_config: Dict
) -> 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: Dict
) -> 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)
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