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# Copyright (c) Meta Platforms, Inc. and affiliates. | |
# All rights reserved. | |
# | |
# This source code is licensed under the license found in the | |
# LICENSE file in the root directory of this source tree. | |
import argparse | |
from functools import partial | |
import json | |
import logging | |
import os | |
import sys | |
from typing import List, Optional | |
import numpy as np | |
import torch | |
import torch.nn as nn | |
from torch.nn.parallel import DistributedDataParallel | |
from fvcore.common.checkpoint import Checkpointer, PeriodicCheckpointer | |
from dinov2.data import SamplerType, make_data_loader, make_dataset | |
from dinov2.data.transforms import make_classification_eval_transform, make_classification_train_transform | |
import dinov2.distributed as distributed | |
from dinov2.eval.metrics import MetricType, build_metric | |
from dinov2.eval.setup import get_args_parser as get_setup_args_parser | |
from dinov2.eval.setup import setup_and_build_model | |
from dinov2.eval.utils import ModelWithIntermediateLayers, evaluate | |
from dinov2.logging import MetricLogger | |
logger = logging.getLogger("dinov2") | |
def get_args_parser( | |
description: Optional[str] = None, | |
parents: Optional[List[argparse.ArgumentParser]] = None, | |
add_help: bool = True, | |
): | |
parents = parents or [] | |
setup_args_parser = get_setup_args_parser(parents=parents, add_help=False) | |
parents = [setup_args_parser] | |
parser = argparse.ArgumentParser( | |
description=description, | |
parents=parents, | |
add_help=add_help, | |
) | |
parser.add_argument( | |
"--train-dataset", | |
dest="train_dataset_str", | |
type=str, | |
help="Training dataset", | |
) | |
parser.add_argument( | |
"--val-dataset", | |
dest="val_dataset_str", | |
type=str, | |
help="Validation dataset", | |
) | |
parser.add_argument( | |
"--test-datasets", | |
dest="test_dataset_strs", | |
type=str, | |
nargs="+", | |
help="Test datasets, none to reuse the validation dataset", | |
) | |
parser.add_argument( | |
"--epochs", | |
type=int, | |
help="Number of training epochs", | |
) | |
parser.add_argument( | |
"--batch-size", | |
type=int, | |
help="Batch Size (per GPU)", | |
) | |
parser.add_argument( | |
"--num-workers", | |
type=int, | |
help="Number de Workers", | |
) | |
parser.add_argument( | |
"--epoch-length", | |
type=int, | |
help="Length of an epoch in number of iterations", | |
) | |
parser.add_argument( | |
"--save-checkpoint-frequency", | |
type=int, | |
help="Number of epochs between two named checkpoint saves.", | |
) | |
parser.add_argument( | |
"--eval-period-iterations", | |
type=int, | |
help="Number of iterations between two evaluations.", | |
) | |
parser.add_argument( | |
"--learning-rates", | |
nargs="+", | |
type=float, | |
help="Learning rates to grid search.", | |
) | |
parser.add_argument( | |
"--no-resume", | |
action="store_true", | |
help="Whether to not resume from existing checkpoints", | |
) | |
parser.add_argument( | |
"--val-metric-type", | |
type=MetricType, | |
choices=list(MetricType), | |
help="Validation metric", | |
) | |
parser.add_argument( | |
"--test-metric-types", | |
type=MetricType, | |
choices=list(MetricType), | |
nargs="+", | |
help="Evaluation metric", | |
) | |
parser.add_argument( | |
"--classifier-fpath", | |
type=str, | |
help="Path to a file containing pretrained linear classifiers", | |
) | |
parser.add_argument( | |
"--val-class-mapping-fpath", | |
type=str, | |
help="Path to a file containing a mapping to adjust classifier outputs", | |
) | |
parser.add_argument( | |
"--test-class-mapping-fpaths", | |
nargs="+", | |
type=str, | |
help="Path to a file containing a mapping to adjust classifier outputs", | |
) | |
parser.set_defaults( | |
train_dataset_str="ImageNet:split=TRAIN", | |
val_dataset_str="ImageNet:split=VAL", | |
test_dataset_strs=None, | |
epochs=10, | |
batch_size=128, | |
num_workers=8, | |
epoch_length=1250, | |
save_checkpoint_frequency=20, | |
eval_period_iterations=1250, | |
learning_rates=[1e-5, 2e-5, 5e-5, 1e-4, 2e-4, 5e-4, 1e-3, 2e-3, 5e-3, 1e-2, 2e-2, 5e-2, 0.1], | |
val_metric_type=MetricType.MEAN_ACCURACY, | |
test_metric_types=None, | |
classifier_fpath=None, | |
val_class_mapping_fpath=None, | |
test_class_mapping_fpaths=[None], | |
) | |
return parser | |
def has_ddp_wrapper(m: nn.Module) -> bool: | |
return isinstance(m, DistributedDataParallel) | |
def remove_ddp_wrapper(m: nn.Module) -> nn.Module: | |
return m.module if has_ddp_wrapper(m) else m | |
def _pad_and_collate(batch): | |
maxlen = max(len(targets) for image, targets in batch) | |
padded_batch = [ | |
(image, np.pad(targets, (0, maxlen - len(targets)), constant_values=-1)) for image, targets in batch | |
] | |
return torch.utils.data.default_collate(padded_batch) | |
def create_linear_input(x_tokens_list, use_n_blocks, use_avgpool): | |
intermediate_output = x_tokens_list[-use_n_blocks:] | |
output = torch.cat([class_token for _, class_token in intermediate_output], dim=-1) | |
if use_avgpool: | |
output = torch.cat( | |
( | |
output, | |
torch.mean(intermediate_output[-1][0], dim=1), # patch tokens | |
), | |
dim=-1, | |
) | |
output = output.reshape(output.shape[0], -1) | |
return output.float() | |
class LinearClassifier(nn.Module): | |
"""Linear layer to train on top of frozen features""" | |
def __init__(self, out_dim, use_n_blocks, use_avgpool, num_classes=1000): | |
super().__init__() | |
self.out_dim = out_dim | |
self.use_n_blocks = use_n_blocks | |
self.use_avgpool = use_avgpool | |
self.num_classes = num_classes | |
self.linear = nn.Linear(out_dim, num_classes) | |
self.linear.weight.data.normal_(mean=0.0, std=0.01) | |
self.linear.bias.data.zero_() | |
def forward(self, x_tokens_list): | |
output = create_linear_input(x_tokens_list, self.use_n_blocks, self.use_avgpool) | |
return self.linear(output) | |
class AllClassifiers(nn.Module): | |
def __init__(self, classifiers_dict): | |
super().__init__() | |
self.classifiers_dict = nn.ModuleDict() | |
self.classifiers_dict.update(classifiers_dict) | |
def forward(self, inputs): | |
return {k: v.forward(inputs) for k, v in self.classifiers_dict.items()} | |
def __len__(self): | |
return len(self.classifiers_dict) | |
class LinearPostprocessor(nn.Module): | |
def __init__(self, linear_classifier, class_mapping=None): | |
super().__init__() | |
self.linear_classifier = linear_classifier | |
self.register_buffer("class_mapping", None if class_mapping is None else torch.LongTensor(class_mapping)) | |
def forward(self, samples, targets): | |
preds = self.linear_classifier(samples) | |
return { | |
"preds": preds[:, self.class_mapping] if self.class_mapping is not None else preds, | |
"target": targets, | |
} | |
def scale_lr(learning_rates, batch_size): | |
return learning_rates * (batch_size * distributed.get_global_size()) / 256.0 | |
def setup_linear_classifiers(sample_output, n_last_blocks_list, learning_rates, batch_size, num_classes=1000): | |
linear_classifiers_dict = nn.ModuleDict() | |
optim_param_groups = [] | |
for n in n_last_blocks_list: | |
for avgpool in [False, True]: | |
for _lr in learning_rates: | |
lr = scale_lr(_lr, batch_size) | |
out_dim = create_linear_input(sample_output, use_n_blocks=n, use_avgpool=avgpool).shape[1] | |
linear_classifier = LinearClassifier( | |
out_dim, use_n_blocks=n, use_avgpool=avgpool, num_classes=num_classes | |
) | |
linear_classifier = linear_classifier.cuda() | |
linear_classifiers_dict[ | |
f"classifier_{n}_blocks_avgpool_{avgpool}_lr_{lr:.5f}".replace(".", "_") | |
] = linear_classifier | |
optim_param_groups.append({"params": linear_classifier.parameters(), "lr": lr}) | |
linear_classifiers = AllClassifiers(linear_classifiers_dict) | |
if distributed.is_enabled(): | |
linear_classifiers = nn.parallel.DistributedDataParallel(linear_classifiers) | |
return linear_classifiers, optim_param_groups | |
def evaluate_linear_classifiers( | |
feature_model, | |
linear_classifiers, | |
data_loader, | |
metric_type, | |
metrics_file_path, | |
training_num_classes, | |
iteration, | |
prefixstring="", | |
class_mapping=None, | |
best_classifier_on_val=None, | |
): | |
logger.info("running validation !") | |
num_classes = len(class_mapping) if class_mapping is not None else training_num_classes | |
metric = build_metric(metric_type, num_classes=num_classes) | |
postprocessors = {k: LinearPostprocessor(v, class_mapping) for k, v in linear_classifiers.classifiers_dict.items()} | |
metrics = {k: metric.clone() for k in linear_classifiers.classifiers_dict} | |
_, results_dict_temp = evaluate( | |
feature_model, | |
data_loader, | |
postprocessors, | |
metrics, | |
torch.cuda.current_device(), | |
) | |
logger.info("") | |
results_dict = {} | |
max_accuracy = 0 | |
best_classifier = "" | |
for i, (classifier_string, metric) in enumerate(results_dict_temp.items()): | |
logger.info(f"{prefixstring} -- Classifier: {classifier_string} * {metric}") | |
if ( | |
best_classifier_on_val is None and metric["top-1"].item() > max_accuracy | |
) or classifier_string == best_classifier_on_val: | |
max_accuracy = metric["top-1"].item() | |
best_classifier = classifier_string | |
results_dict["best_classifier"] = {"name": best_classifier, "accuracy": max_accuracy} | |
logger.info(f"best classifier: {results_dict['best_classifier']}") | |
if distributed.is_main_process(): | |
with open(metrics_file_path, "a") as f: | |
f.write(f"iter: {iteration}\n") | |
for k, v in results_dict.items(): | |
f.write(json.dumps({k: v}) + "\n") | |
f.write("\n") | |
return results_dict | |
def eval_linear( | |
*, | |
feature_model, | |
linear_classifiers, | |
train_data_loader, | |
val_data_loader, | |
metrics_file_path, | |
optimizer, | |
scheduler, | |
output_dir, | |
max_iter, | |
checkpoint_period, # In number of iter, creates a new file every period | |
running_checkpoint_period, # Period to update main checkpoint file | |
eval_period, | |
metric_type, | |
training_num_classes, | |
resume=True, | |
classifier_fpath=None, | |
val_class_mapping=None, | |
): | |
checkpointer = Checkpointer(linear_classifiers, output_dir, optimizer=optimizer, scheduler=scheduler) | |
start_iter = checkpointer.resume_or_load(classifier_fpath or "", resume=resume).get("iteration", -1) + 1 | |
periodic_checkpointer = PeriodicCheckpointer(checkpointer, checkpoint_period, max_iter=max_iter) | |
iteration = start_iter | |
logger.info("Starting training from iteration {}".format(start_iter)) | |
metric_logger = MetricLogger(delimiter=" ") | |
header = "Training" | |
for data, labels in metric_logger.log_every( | |
train_data_loader, | |
10, | |
header, | |
max_iter, | |
start_iter, | |
): | |
data = data.cuda(non_blocking=True) | |
labels = labels.cuda(non_blocking=True) | |
features = feature_model(data) | |
outputs = linear_classifiers(features) | |
losses = {f"loss_{k}": nn.CrossEntropyLoss()(v, labels) for k, v in outputs.items()} | |
loss = sum(losses.values()) | |
# compute the gradients | |
optimizer.zero_grad() | |
loss.backward() | |
# step | |
optimizer.step() | |
scheduler.step() | |
# log | |
if iteration % 10 == 0: | |
torch.cuda.synchronize() | |
metric_logger.update(loss=loss.item()) | |
metric_logger.update(lr=optimizer.param_groups[0]["lr"]) | |
print("lr", optimizer.param_groups[0]["lr"]) | |
if iteration - start_iter > 5: | |
if iteration % running_checkpoint_period == 0: | |
torch.cuda.synchronize() | |
if distributed.is_main_process(): | |
logger.info("Checkpointing running_checkpoint") | |
periodic_checkpointer.save("running_checkpoint_linear_eval", iteration=iteration) | |
torch.cuda.synchronize() | |
periodic_checkpointer.step(iteration) | |
if eval_period > 0 and (iteration + 1) % eval_period == 0 and iteration != max_iter - 1: | |
_ = evaluate_linear_classifiers( | |
feature_model=feature_model, | |
linear_classifiers=remove_ddp_wrapper(linear_classifiers), | |
data_loader=val_data_loader, | |
metrics_file_path=metrics_file_path, | |
prefixstring=f"ITER: {iteration}", | |
metric_type=metric_type, | |
training_num_classes=training_num_classes, | |
iteration=iteration, | |
class_mapping=val_class_mapping, | |
) | |
torch.cuda.synchronize() | |
iteration = iteration + 1 | |
val_results_dict = evaluate_linear_classifiers( | |
feature_model=feature_model, | |
linear_classifiers=remove_ddp_wrapper(linear_classifiers), | |
data_loader=val_data_loader, | |
metrics_file_path=metrics_file_path, | |
metric_type=metric_type, | |
training_num_classes=training_num_classes, | |
iteration=iteration, | |
class_mapping=val_class_mapping, | |
) | |
return val_results_dict, feature_model, linear_classifiers, iteration | |
def make_eval_data_loader(test_dataset_str, batch_size, num_workers, metric_type): | |
test_dataset = make_dataset( | |
dataset_str=test_dataset_str, | |
transform=make_classification_eval_transform(), | |
) | |
test_data_loader = make_data_loader( | |
dataset=test_dataset, | |
batch_size=batch_size, | |
num_workers=num_workers, | |
sampler_type=SamplerType.DISTRIBUTED, | |
drop_last=False, | |
shuffle=False, | |
persistent_workers=False, | |
collate_fn=_pad_and_collate if metric_type == MetricType.IMAGENET_REAL_ACCURACY else None, | |
) | |
return test_data_loader | |
def test_on_datasets( | |
feature_model, | |
linear_classifiers, | |
test_dataset_strs, | |
batch_size, | |
num_workers, | |
test_metric_types, | |
metrics_file_path, | |
training_num_classes, | |
iteration, | |
best_classifier_on_val, | |
prefixstring="", | |
test_class_mappings=[None], | |
): | |
results_dict = {} | |
for test_dataset_str, class_mapping, metric_type in zip(test_dataset_strs, test_class_mappings, test_metric_types): | |
logger.info(f"Testing on {test_dataset_str}") | |
test_data_loader = make_eval_data_loader(test_dataset_str, batch_size, num_workers, metric_type) | |
dataset_results_dict = evaluate_linear_classifiers( | |
feature_model, | |
remove_ddp_wrapper(linear_classifiers), | |
test_data_loader, | |
metric_type, | |
metrics_file_path, | |
training_num_classes, | |
iteration, | |
prefixstring="", | |
class_mapping=class_mapping, | |
best_classifier_on_val=best_classifier_on_val, | |
) | |
results_dict[f"{test_dataset_str}_accuracy"] = 100.0 * dataset_results_dict["best_classifier"]["accuracy"] | |
return results_dict | |
def run_eval_linear( | |
model, | |
output_dir, | |
train_dataset_str, | |
val_dataset_str, | |
batch_size, | |
epochs, | |
epoch_length, | |
num_workers, | |
save_checkpoint_frequency, | |
eval_period_iterations, | |
learning_rates, | |
autocast_dtype, | |
test_dataset_strs=None, | |
resume=True, | |
classifier_fpath=None, | |
val_class_mapping_fpath=None, | |
test_class_mapping_fpaths=[None], | |
val_metric_type=MetricType.MEAN_ACCURACY, | |
test_metric_types=None, | |
): | |
seed = 0 | |
if test_dataset_strs is None: | |
test_dataset_strs = [val_dataset_str] | |
if test_metric_types is None: | |
test_metric_types = [val_metric_type] * len(test_dataset_strs) | |
else: | |
assert len(test_metric_types) == len(test_dataset_strs) | |
assert len(test_dataset_strs) == len(test_class_mapping_fpaths) | |
train_transform = make_classification_train_transform() | |
train_dataset = make_dataset( | |
dataset_str=train_dataset_str, | |
transform=train_transform, | |
) | |
training_num_classes = len(torch.unique(torch.Tensor(train_dataset.get_targets().astype(int)))) | |
sampler_type = SamplerType.SHARDED_INFINITE | |
# sampler_type = SamplerType.INFINITE | |
n_last_blocks_list = [1, 4] | |
n_last_blocks = max(n_last_blocks_list) | |
autocast_ctx = partial(torch.cuda.amp.autocast, enabled=True, dtype=autocast_dtype) | |
feature_model = ModelWithIntermediateLayers(model, n_last_blocks, autocast_ctx) | |
sample_output = feature_model(train_dataset[0][0].unsqueeze(0).cuda()) | |
linear_classifiers, optim_param_groups = setup_linear_classifiers( | |
sample_output, | |
n_last_blocks_list, | |
learning_rates, | |
batch_size, | |
training_num_classes, | |
) | |
optimizer = torch.optim.SGD(optim_param_groups, momentum=0.9, weight_decay=0) | |
max_iter = epochs * epoch_length | |
scheduler = torch.optim.lr_scheduler.CosineAnnealingLR(optimizer, max_iter, eta_min=0) | |
checkpointer = Checkpointer(linear_classifiers, output_dir, optimizer=optimizer, scheduler=scheduler) | |
start_iter = checkpointer.resume_or_load(classifier_fpath or "", resume=resume).get("iteration", -1) + 1 | |
train_data_loader = make_data_loader( | |
dataset=train_dataset, | |
batch_size=batch_size, | |
num_workers=num_workers, | |
shuffle=True, | |
seed=seed, | |
sampler_type=sampler_type, | |
sampler_advance=start_iter, | |
drop_last=True, | |
persistent_workers=True, | |
) | |
val_data_loader = make_eval_data_loader(val_dataset_str, batch_size, num_workers, val_metric_type) | |
checkpoint_period = save_checkpoint_frequency * epoch_length | |
if val_class_mapping_fpath is not None: | |
logger.info(f"Using class mapping from {val_class_mapping_fpath}") | |
val_class_mapping = np.load(val_class_mapping_fpath) | |
else: | |
val_class_mapping = None | |
test_class_mappings = [] | |
for class_mapping_fpath in test_class_mapping_fpaths: | |
if class_mapping_fpath is not None and class_mapping_fpath != "None": | |
logger.info(f"Using class mapping from {class_mapping_fpath}") | |
class_mapping = np.load(class_mapping_fpath) | |
else: | |
class_mapping = None | |
test_class_mappings.append(class_mapping) | |
metrics_file_path = os.path.join(output_dir, "results_eval_linear.json") | |
val_results_dict, feature_model, linear_classifiers, iteration = eval_linear( | |
feature_model=feature_model, | |
linear_classifiers=linear_classifiers, | |
train_data_loader=train_data_loader, | |
val_data_loader=val_data_loader, | |
metrics_file_path=metrics_file_path, | |
optimizer=optimizer, | |
scheduler=scheduler, | |
output_dir=output_dir, | |
max_iter=max_iter, | |
checkpoint_period=checkpoint_period, | |
running_checkpoint_period=epoch_length, | |
eval_period=eval_period_iterations, | |
metric_type=val_metric_type, | |
training_num_classes=training_num_classes, | |
resume=resume, | |
val_class_mapping=val_class_mapping, | |
classifier_fpath=classifier_fpath, | |
) | |
results_dict = {} | |
if len(test_dataset_strs) > 1 or test_dataset_strs[0] != val_dataset_str: | |
results_dict = test_on_datasets( | |
feature_model, | |
linear_classifiers, | |
test_dataset_strs, | |
batch_size, | |
0, # num_workers, | |
test_metric_types, | |
metrics_file_path, | |
training_num_classes, | |
iteration, | |
val_results_dict["best_classifier"]["name"], | |
prefixstring="", | |
test_class_mappings=test_class_mappings, | |
) | |
results_dict["best_classifier"] = val_results_dict["best_classifier"]["name"] | |
results_dict[f"{val_dataset_str}_accuracy"] = 100.0 * val_results_dict["best_classifier"]["accuracy"] | |
logger.info("Test Results Dict " + str(results_dict)) | |
return results_dict | |
def main(args): | |
model, autocast_dtype = setup_and_build_model(args) | |
run_eval_linear( | |
model=model, | |
output_dir=args.output_dir, | |
train_dataset_str=args.train_dataset_str, | |
val_dataset_str=args.val_dataset_str, | |
test_dataset_strs=args.test_dataset_strs, | |
batch_size=args.batch_size, | |
epochs=args.epochs, | |
epoch_length=args.epoch_length, | |
num_workers=args.num_workers, | |
save_checkpoint_frequency=args.save_checkpoint_frequency, | |
eval_period_iterations=args.eval_period_iterations, | |
learning_rates=args.learning_rates, | |
autocast_dtype=autocast_dtype, | |
resume=not args.no_resume, | |
classifier_fpath=args.classifier_fpath, | |
val_metric_type=args.val_metric_type, | |
test_metric_types=args.test_metric_types, | |
val_class_mapping_fpath=args.val_class_mapping_fpath, | |
test_class_mapping_fpaths=args.test_class_mapping_fpaths, | |
) | |
return 0 | |
if __name__ == "__main__": | |
description = "DINOv2 linear evaluation" | |
args_parser = get_args_parser(description=description) | |
args = args_parser.parse_args() | |
sys.exit(main(args)) | |