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kMaX-DeepLab / train_net.py
Qihang Yu
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# Reference: https://github.com/facebookresearch/Mask2Former/blob/main/train_net.py
# Modified by Qihang Yu
try:
# ignore ShapelyDeprecationWarning from fvcore
from shapely.errors import ShapelyDeprecationWarning
import warnings
warnings.filterwarnings('ignore', category=ShapelyDeprecationWarning)
except:
pass
import copy
import itertools
import os
from typing import Any, Dict, List, Set
import torch
import detectron2.utils.comm as comm
from detectron2.checkpoint import DetectionCheckpointer
from detectron2.config import get_cfg
from detectron2.data import MetadataCatalog, build_detection_train_loader, build_detection_test_loader
from detectron2.engine import (
DefaultTrainer,
default_argument_parser,
default_setup,
launch,
)
from detectron2.evaluation import (
COCOEvaluator,
DatasetEvaluators,
SemSegEvaluator,
verify_results,
)
from detectron2.projects.deeplab import add_deeplab_config, build_lr_scheduler
from detectron2.solver.build import maybe_add_gradient_clipping
from detectron2.utils.logger import setup_logger
# MaskFormer
from kmax_deeplab import (
COCOPanoptickMaXDeepLabDatasetMapper,
add_kmax_deeplab_config,
)
from detectron2.data import MetadataCatalog
import train_net_utils
class Trainer(DefaultTrainer):
"""
Extension of the Trainer class adapted to MaskFormer.
"""
@classmethod
def build_evaluator(cls, cfg, dataset_name, output_folder=None):
"""
Create evaluator(s) for a given dataset.
This uses the special metadata "evaluator_type" associated with each
builtin dataset. For your own dataset, you can simply create an
evaluator manually in your script and do not have to worry about the
hacky if-else logic here.
"""
if output_folder is None:
output_folder = os.path.join(cfg.OUTPUT_DIR, "inference")
evaluator_list = []
evaluator_type = MetadataCatalog.get(dataset_name).evaluator_type
# panoptic segmentation
if evaluator_type in [
"coco_panoptic_seg",
]:
if cfg.MODEL.KMAX_DEEPLAB.TEST.PANOPTIC_ON:
evaluator_list.append(train_net_utils.COCOPanopticEvaluatorwithVis(dataset_name, output_folder, save_vis_num=cfg.MODEL.KMAX_DEEPLAB.SAVE_VIS_NUM))
# COCO
if evaluator_type == "coco_panoptic_seg" and cfg.MODEL.KMAX_DEEPLAB.TEST.INSTANCE_ON:
evaluator_list.append(COCOEvaluator(dataset_name, output_dir=output_folder))
if evaluator_type == "coco_panoptic_seg" and cfg.MODEL.KMAX_DEEPLAB.TEST.SEMANTIC_ON:
evaluator_list.append(SemSegEvaluator(dataset_name, distributed=True, output_dir=output_folder))
elif len(evaluator_list) == 1:
return evaluator_list[0]
return DatasetEvaluators(evaluator_list)
@classmethod
def build_train_loader(cls, cfg):
# Semantic segmentation dataset mapper
if cfg.INPUT.DATASET_MAPPER_NAME == "coco_panoptic_lsj":
mapper = COCOPanoptickMaXDeepLabDatasetMapper(cfg, True)
return build_detection_train_loader(cfg, mapper=mapper)
else:
mapper = None
return build_detection_train_loader(cfg, mapper=mapper)
@classmethod
def build_lr_scheduler(cls, cfg, optimizer):
"""
It now calls :func:`detectron2.solver.build_lr_scheduler`.
Overwrite it if you'd like a different scheduler.
"""
name = cfg.SOLVER.LR_SCHEDULER_NAME
if name == "TF2WarmupPolyLR":
return train_net_utils.TF2WarmupPolyLR(
optimizer,
cfg.SOLVER.MAX_ITER,
warmup_factor=cfg.SOLVER.WARMUP_FACTOR,
warmup_iters=cfg.SOLVER.WARMUP_ITERS,
warmup_method=cfg.SOLVER.WARMUP_METHOD,
power=cfg.SOLVER.POLY_LR_POWER,
constant_ending=cfg.SOLVER.POLY_LR_CONSTANT_ENDING,
)
else:
return build_lr_scheduler(cfg, optimizer)
@classmethod
def build_optimizer(cls, cfg, model):
weight_decay_norm = cfg.SOLVER.WEIGHT_DECAY_NORM
weight_decay_embed = cfg.SOLVER.WEIGHT_DECAY_EMBED
defaults = {}
defaults["lr"] = cfg.SOLVER.BASE_LR
defaults["weight_decay"] = cfg.SOLVER.WEIGHT_DECAY
from kmax_deeplab.modeling.backbone.convnext import LayerNorm
norm_module_types = (
torch.nn.BatchNorm1d,
torch.nn.BatchNorm2d,
torch.nn.BatchNorm3d,
torch.nn.SyncBatchNorm,
# NaiveSyncBatchNorm inherits from BatchNorm2d
torch.nn.GroupNorm,
torch.nn.InstanceNorm1d,
torch.nn.InstanceNorm2d,
torch.nn.InstanceNorm3d,
torch.nn.LayerNorm,
torch.nn.LocalResponseNorm,
LayerNorm
)
params: List[Dict[str, Any]] = []
memo: Set[torch.nn.parameter.Parameter] = set()
for module_name, module in model.named_modules():
for module_param_name, value in module.named_parameters(recurse=False):
if not value.requires_grad:
continue
# Avoid duplicating parameters
if value in memo:
continue
memo.add(value)
hyperparams = copy.copy(defaults)
hyperparams["name"] = (module_name, module_param_name)
if "backbone" in module_name:
hyperparams["lr"] = hyperparams["lr"] * cfg.SOLVER.BACKBONE_MULTIPLIER
if (
"relative_position_bias_table" in module_param_name
or "absolute_pos_embed" in module_param_name
):
print(module_param_name)
hyperparams["weight_decay"] = 0.0
if isinstance(module, norm_module_types):
hyperparams["weight_decay"] = weight_decay_norm
if isinstance(module, torch.nn.Embedding):
hyperparams["weight_decay"] = weight_decay_embed
# Rule for kMaX.
if "_rpe" in module_name:
# relative positional embedding in axial attention.
hyperparams["weight_decay"] = 0.0
if "_cluster_centers" in module_name:
# cluster center embeddings.
hyperparams["weight_decay"] = 0.0
if "bias" in module_param_name:
# any bias terms.
hyperparams["weight_decay"] = 0.0
if "gamma" in module_param_name:
# gamma term in convnext
hyperparams["weight_decay"] = 0.0
params.append({"params": [value], **hyperparams})
for param_ in params:
print(param_["name"], param_["lr"], param_["weight_decay"])
def maybe_add_full_model_gradient_clipping(optim):
# detectron2 doesn't have full model gradient clipping now
clip_norm_val = cfg.SOLVER.CLIP_GRADIENTS.CLIP_VALUE
enable = (
cfg.SOLVER.CLIP_GRADIENTS.ENABLED
and cfg.SOLVER.CLIP_GRADIENTS.CLIP_TYPE == "full_model"
and clip_norm_val > 0.0
)
class FullModelGradientClippingOptimizer(optim):
def step(self, closure=None):
all_params = itertools.chain(*[x["params"] for x in self.param_groups])
torch.nn.utils.clip_grad_norm_(all_params, clip_norm_val)
super().step(closure=closure)
return FullModelGradientClippingOptimizer if enable else optim
optimizer_type = cfg.SOLVER.OPTIMIZER
if optimizer_type == "SGD":
optimizer = maybe_add_full_model_gradient_clipping(torch.optim.SGD)(
params, cfg.SOLVER.BASE_LR, momentum=cfg.SOLVER.MOMENTUM
)
elif optimizer_type == "ADAMW":
optimizer = maybe_add_full_model_gradient_clipping(torch.optim.AdamW)(
params, cfg.SOLVER.BASE_LR
)
elif optimizer_type == "ADAM":
optimizer = maybe_add_full_model_gradient_clipping(torch.optim.Adam)(
params, cfg.SOLVER.BASE_LR
)
else:
raise NotImplementedError(f"no optimizer type {optimizer_type}")
if not cfg.SOLVER.CLIP_GRADIENTS.CLIP_TYPE == "full_model":
optimizer = maybe_add_gradient_clipping(cfg, optimizer)
return optimizer
def setup(args):
"""
Create configs and perform basic setups.
"""
cfg = get_cfg()
# for poly lr schedule
add_deeplab_config(cfg)
add_kmax_deeplab_config(cfg)
cfg.merge_from_file(args.config_file)
cfg.merge_from_list(args.opts)
cfg.freeze()
default_setup(cfg, args)
setup_logger(output=cfg.OUTPUT_DIR, distributed_rank=comm.get_rank(), name="kmax_deeplab")
return cfg
def main(args):
cfg = setup(args)
torch.backends.cudnn.enabled = True
if args.eval_only:
model = Trainer.build_model(cfg)
DetectionCheckpointer(model, save_dir=cfg.OUTPUT_DIR).resume_or_load(
cfg.MODEL.WEIGHTS, resume=args.resume
)
res = Trainer.test(cfg, model)
if comm.is_main_process():
verify_results(cfg, res)
return res
trainer = Trainer(cfg)
trainer.resume_or_load(resume=args.resume)
return trainer.train()
if __name__ == "__main__":
args = default_argument_parser().parse_args()
print("Command Line Args:", args)
launch(
main,
args.num_gpus,
num_machines=args.num_machines,
machine_rank=args.machine_rank,
dist_url=args.dist_url,
args=(args,),
)