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train.py
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#!/usr/bin/env python3
#
# Copyright (c) 2018 Intel Corporation
# Portions Copyright (C) 2019-2024 Maxim Integrated Products, Inc.
#
# Licensed under the Apache License, Version 2.0 (the "License");
# you may not use this file except in compliance with the License.
# You may obtain a copy of the License at
#
# http://www.apache.org/licenses/LICENSE-2.0
#
# Unless required by applicable law or agreed to in writing, software
# distributed under the License is distributed on an "AS IS" BASIS,
# WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
# See the License for the specific language governing permissions and
# limitations under the License.
#
# pyright: reportMissingModuleSource=false, reportGeneralTypeIssues=false
# pyright: reportOptionalSubscript=false
"""This is the example training application for MAX7800x.
The application borrows its main flow code from torchvision's ImageNet classification
training sample application (https://github.com/pytorch/examples/tree/master/imagenet).
We tried to keep it similar, in order to make it familiar and easy to understand.
Integrating compression is very simple: simply add invocations of the appropriate
compression_scheduler callbacks, for each stage in the training. The training skeleton
looks like the pseudo code below. The boiler-plate Pytorch classification training
is speckled with invocations of CompressionScheduler.
For each epoch:
compression_scheduler.on_epoch_begin(epoch)
train()
validate()
save_checkpoint()
compression_scheduler.on_epoch_end(epoch)
train():
For each training step:
compression_scheduler.on_minibatch_begin(epoch)
output = model(input)
loss = criterion(output, target)
compression_scheduler.before_backward_pass(epoch)
loss.backward()
compression_scheduler.before_parameter_optimization(epoch)
optimizer.step()
compression_scheduler.on_minibatch_end(epoch)
"""
import copy
import fnmatch
import logging
import operator
import os
import re
# pylint: disable=wrong-import-position
if os.name == 'posix':
import resource # pylint: disable=import-error
# pylint: enable=wrong-import-position
import shutil
import sys
import time
import traceback
from collections import OrderedDict
from pydoc import locate
import numpy as np
import matplotlib
# pylint: disable=wrong-import-position
os.environ["PYTORCH_ENABLE_MPS_FALLBACK"] = "1" # Set this before importing PyTorch
# pylint: enable=wrong-import-position
# TensorFlow 2.x compatibility
try:
import tensorboard # pylint: disable=import-error
import tensorflow # pylint: disable=import-error
tensorflow.io.gfile = tensorboard.compat.tensorflow_stub.io.gfile
except (ModuleNotFoundError, AttributeError):
pass
import torch
import torch.distributed
import torch.optim
import torch.utils.data
from torch import nn
from torch.backends import cudnn
from torch.nn.parallel import DistributedDataParallel
# pylint: disable=wrong-import-order
import distiller
import torchnet.meter as tnt
from distiller import apputils, model_summaries # type: ignore[attr-defined]
from distiller.data_loggers import PythonLogger, TensorBoardLogger
from pytorch_metric_learning import losses as pml_losses
from pytorch_metric_learning import testers
from pytorch_metric_learning.distances import CosineSimilarity
from pytorch_metric_learning.utils.accuracy_calculator import AccuracyCalculator
from pytorch_metric_learning.utils.inference import CustomKNN
from torchmetrics.detection import MeanAveragePrecision
from tqdm import tqdm
import ai8x
import ai8x_nas
import datasets
import nnplot
import parse_qat_yaml
import parsecmd
import sample
import yamlwriter
from losses.dummyloss import DummyLoss
from losses.multiboxloss import MultiBoxLoss
from nas import parse_nas_yaml
from utils import kd_relationbased, model_wrapper, object_detection_utils, parse_obj_detection_yaml
matplotlib.use("pgf")
# Logger handle
msglogger = None
# Globals
weight_min = None
weight_max = None
weight_count = None
weight_sum = None
weight_stddev = None
weight_mean = None
def main():
"""main"""
script_dir = os.path.dirname(__file__)
global msglogger # pylint: disable=global-statement
supported_models = []
supported_sources = []
model_names = []
dataset_names = []
local_rank = None
local_world_size = 1
try:
local_rank = os.environ['LOCAL_RANK']
local_world_size = os.environ['LOCAL_WORLD_SIZE']
except KeyError:
pass
finally:
local_rank = int(local_rank) if local_rank is not None else -1
if local_world_size is not None:
local_world_size = int(local_world_size)
# Dynamically load models
for _, _, files in sorted(os.walk('models')):
for name in sorted(files):
if fnmatch.fnmatch(name, '*.py'):
fn = 'models.' + name[:-3]
m = locate(fn)
try:
for i in m.models:
i['module'] = fn
supported_models += m.models
model_names += [item['name'] for item in m.models]
except AttributeError:
# Skip files that don't have 'models' or 'models.name'
pass
# Dynamically load datasets
for _, _, files in sorted(os.walk('datasets')):
for name in sorted(files):
if fnmatch.fnmatch(name, '*.py'):
ds = locate('datasets.' + name[:-3])
try:
supported_sources += ds.datasets
dataset_names += [item['name'] for item in ds.datasets]
except AttributeError:
# Skip files that don't have 'datasets' or 'datasets.name'
pass
# Parse arguments
args = parsecmd.get_parser(model_names, dataset_names).parse_args()
args.local_world_size = local_world_size
if local_rank <= 0: # not DistributedDataParallel or rank 0
msglogger = apputils.config_pylogger(os.path.join(script_dir, 'logging.conf'), args.name,
args.output_dir)
else:
msglogger = logging.getLogger()
msglogger.log_filename = 'none'
msglogger.setLevel(logging.CRITICAL)
pattern = re.compile(r'.*Profiler function .* will be ignored')
logging.getLogger('torch._dynamo.variables.torch').addFilter(
lambda record: not pattern.search(record.getMessage())
)
# Redirect 'print'
class StdStreamLogger():
"""Stream object to redirect sys.stdout to Python logger"""
def __init__(self, logger, level):
self._logger = logger
self._level = level
self._buf = ''
def write(self, msg):
"""write()"""
self._buf = self._buf + msg
while '\n' in self._buf:
pos = self._buf.find('\n')
self._logger.log(self._level, self._buf[:pos])
self._buf = self._buf[pos + 1:]
def flush(self):
"""flush()"""
if self._buf != '':
self._logger.log(self._level, self._buf)
self._buf = ''
sys.stdout = StdStreamLogger(msglogger, logging.INFO)
if os.name == 'posix':
# Check file descriptor limits
nfiles = resource.getrlimit(resource.RLIMIT_NOFILE)[0]
if nfiles < 4096:
msglogger.warning('The open file limit is %d. '
'Please raise the limit (see documentation).', nfiles)
# Set hardware device
ai8x.set_device(args.device, args.act_mode_8bit, args.avg_pool_rounding)
if args.epochs is None:
args.epochs = 90
if not os.path.exists(args.output_dir) and local_rank <= 0: # not DDP or rank 0
os.makedirs(args.output_dir)
if args.optimizer is None:
args.optimizer = 'SGD'
if not args.evaluate:
msglogger.warning('--optimizer not set, selecting %s.', args.optimizer)
if args.lr is None:
args.lr = 0.1
if not args.evaluate:
msglogger.warning('Initial learning rate (--lr) not set, selecting %f.', args.lr)
if args.generate_sample is not None and not args.act_mode_8bit:
msglogger.warning('Cannot save sample in training mode, ignoring --save-sample option. '
'Use with --evaluate instead.')
# Log various details about the execution environment. It is sometimes useful
# to refer to past experiment executions and this information may be useful.
if local_rank <= 0: # not DistributedDataParallel or rank 0
apputils.log_execution_env_state(args.compress, msglogger.logdir)
msglogger.debug("Distiller: %s", distiller.__version__)
start_epoch = 0
ending_epoch = args.epochs
perf_scores_history = []
if args.evaluate:
args.deterministic = True
if args.deterministic:
# torch.set_deterministic(True)
distiller.set_deterministic(args.seed) # For experiment reproducibility
if args.seed is not None:
distiller.set_seed(args.seed)
else:
# Turn on CUDNN benchmark mode for best performance. This is usually "safe" for image
# classification models, as the input sizes don't change during the run
# See here:
# https://discuss.pytorch.org/t/what-does-torch-backends-cudnn-benchmark-do/5936/3
cudnn.benchmark = True
if args.cpu or (not torch.cuda.is_available() and not torch.backends.mps.is_available()):
if not args.cpu:
# Print warning if no hardware acceleration
msglogger.warning('No CUDA, ROCm, or MPS hardware acceleration, training will be slow')
# Set GPU index to -1 if using CPU
args.device = 'cpu'
args.gpus = -1
elif torch.cuda.is_available():
args.device = 'cuda'
if local_rank >= 0: # DistributedDataParallel
torch.cuda.set_device(local_rank)
args.gpus = local_rank
elif args.gpus is not None:
try:
args.gpus = [int(s) for s in args.gpus.split(',')]
except ValueError as exc:
raise ValueError('ERROR: Argument --gpus must be a comma-separated '
'list of integers only') from exc
available_gpus = torch.cuda.device_count()
for dev_id in args.gpus:
if dev_id >= available_gpus:
raise ValueError(f'ERROR: GPU device ID {dev_id} requested, but only '
f'{available_gpus} devices available')
# Set default device in case the first one on the list != 0
torch.cuda.set_device(args.gpus[0])
elif os.uname().release < '22.3.0':
msglogger.warning('mps disabled, update macOS to Ventura 13.4 or later for mps support')
args.device = 'cpu'
else:
args.device = 'mps'
selected_source = next((item for item in supported_sources if item['name'] == args.dataset))
args.labels = selected_source['output']
args.num_classes = len(args.labels)
# Add background class explicitly for the object detection models
if args.obj_detection:
args.num_classes += 1
if args.num_classes == 1 \
or ('regression' in selected_source and selected_source['regression']):
args.regression = True
dimensions = selected_source['input']
if len(dimensions) == 2:
dimensions += (1, )
args.dimensions = dimensions
args.datasets_fn = selected_source['loader']
args.collate_fn = selected_source.get('collate') # .get returns None if key does not exist
args.visualize_fn = selected_source['visualize'] \
if 'visualize' in selected_source else datasets.visualize_data
if (args.regression or args.obj_detection) and args.display_confusion:
raise ValueError('ERROR: Argument --confusion cannot be used with regression '
'or object detection')
if (args.regression or args.obj_detection) and args.display_prcurves:
raise ValueError('ERROR: Argument --pr-curves cannot be used with regression '
'or object detection')
if (args.regression or args.obj_detection) and args.display_embedding:
raise ValueError('ERROR: Argument --embedding cannot be used with regression '
'or object detection')
model = create_model(supported_models, dimensions, args)
compression_scheduler = None
# Create a couple of logging backends. TensorBoardLogger writes log files in a format
# that can be read by Google's Tensor Board. PythonLogger writes to the Python logger.
pylogger = PythonLogger(msglogger, log_1d=True)
all_loggers = [pylogger]
if args.tblog and local_rank <= 0: # not DistributedDataParallel or rank 0
tflogger = TensorBoardLogger(msglogger.logdir, log_1d=True, comment='_'+args.dataset)
tflogger.tblogger.writer.add_text('Command line', str(args))
if dimensions[2] > 1:
dummy_input = torch.randn((1, ) + dimensions)
else: # 1D input
dummy_input = torch.randn((1, ) + dimensions[:-1])
tflogger.tblogger.writer.add_graph(model.to('cpu'), (dummy_input, ), False)
all_loggers.append(tflogger)
all_tbloggers = [tflogger]
else:
tflogger = None
all_tbloggers = []
# Get policy for quantization aware training
qat_policy = parse_qat_yaml.parse(args.qat_policy) \
if args.qat_policy.lower() != "none" else None
# Get policy for once for all training policy
nas_policy = parse_nas_yaml.parse(args.nas_policy) \
if args.nas and args.nas_policy.lower() != '' else None
# Get object detection params
obj_detection_params = parse_obj_detection_yaml.parse(args.obj_detection_params) \
if args.obj_detection_params else None
# We can optionally resume from a checkpoint
optimizer = None
loss_optimizer = None
if args.resumed_checkpoint_path:
if qat_policy is not None:
checkpoint = torch.load(args.resumed_checkpoint_path,
map_location=lambda storage, loc: storage)
if checkpoint.get('epoch', None) >= qat_policy['start_epoch']:
ai8x.fuse_bn_layers(model)
if args.name:
args.name = f'{args.name}_qat'
else:
args.name = 'qat'
try:
model, compression_scheduler, optimizer, start_epoch = apputils.load_checkpoint(
model, args.resumed_checkpoint_path, model_device=args.device)
except ValueError as exc:
raise ValueError('\n ERROR: Unable to resume from the checkpoint. '
'The reason might be the size mismatch between checkpoint and'
' optimizer. Instead of "--resume-from", "--exp-load-weights-from" '
'argument can be used to load the lean model. ') from exc
elif args.load_model_path:
init_qat = False
update_old_model_params(args.load_model_path, model)
if qat_policy is not None:
checkpoint = torch.load(args.load_model_path,
map_location=lambda storage, loc: storage)
if checkpoint.get('epoch', None) >= qat_policy['start_epoch']:
init_qat = True
ai8x.fuse_bn_layers(model)
if args.name:
args.name = f'{args.name}_qat'
else:
args.name = 'qat'
model = apputils.load_lean_checkpoint(model, args.load_model_path,
model_device=args.device)
# If model is in QAT mode, guarantee that the model is initialized for QATv2
if init_qat:
ai8x.initiate_qat(model, qat_policy)
ai8x.update_model(model)
if args.reset_optimizer:
start_epoch = 0
if optimizer is not None:
optimizer = None
msglogger.info('\nreset_optimizer flag set: Overriding resumed optimizer and '
'resetting epoch count to 0')
# Define loss function (criterion)
if args.obj_detection:
criterion = MultiBoxLoss(priors_cxcy=model.priors_cxcy,
alpha=obj_detection_params['multi_box_loss']['alpha'],
neg_pos_ratio=obj_detection_params['multi_box_loss']
['neg_pos_ratio'], device=args.device).to(args.device)
elif args.dr:
criterion = pml_losses.SubCenterArcFaceLoss(num_classes=args.num_classes,
embedding_size=args.dr,
margin=args.scaf_margin,
scale=args.scaf_scale)
if args.resumed_checkpoint_path:
checkpoint = torch.load(args.resumed_checkpoint_path,
map_location=lambda storage, loc: storage)
criterion.W = checkpoint['extras']['loss_weights']
criterion = criterion.to(args.device)
loss_optimizer = torch.optim.Adam(criterion.parameters(), lr=args.scaf_lr)
if args.resumed_checkpoint_path:
loss_optimizer.load_state_dict(checkpoint['extras']['loss_optimizer_state_dict'])
distance_fn = CosineSimilarity()
custom_knn = CustomKNN(distance_fn, batch_size=args.batch_size)
accuracy_calculator = AccuracyCalculator(knn_func=custom_knn,
include=("precision_at_1",), k=1)
elif args.regression:
criterion = nn.MSELoss().to(args.device)
elif 'weight' in selected_source:
criterion = nn.CrossEntropyLoss(
torch.tensor(selected_source['weight'], dtype=torch.float)
).to(args.device)
else:
criterion = nn.CrossEntropyLoss().to(args.device)
# Override criterion with dummy loss when student weight is 0
if args.kd_student_wt == 0:
criterion = DummyLoss(device=args.device).to(args.device)
msglogger.info("WARNING: kd_student_wt == 0, Overwriting criterion with a dummy loss")
if optimizer is None:
optimizer = create_optimizer(model, args)
msglogger.info('Optimizer Type: %s', type(optimizer))
msglogger.info('Optimizer Args: %s', optimizer.defaults)
# This sample application can be invoked to produce various summary reports.
if args.summary:
return summarize_model(model, args.dataset, which_summary=args.summary,
filename=args.summary_filename)
if args.yaml_template is not None:
return yamlwriter.create(
model,
args.dataset,
args.cnn,
filename=args.yaml_template,
qat_policy=qat_policy,
)
if local_rank >= 0: # DistributedDataParallel
torch.distributed.init_process_group(backend='nccl' if args.device == 'cuda' else 'gloo')
model = DistributedDataParallel(
torch.nn.SyncBatchNorm.convert_sync_batchnorm(model),
device_ids=[local_rank] if args.device == 'cuda' else None,
output_device=local_rank if args.device == 'cuda' else None,
)
if local_rank >= 0: # DistributedDataParallel
# Auto-divide batch size
args.batch_size //= local_world_size
# Create semaphore
tensor = torch.zeros(1).to(args.device)
if local_rank > 0: # DistributedDataParallel and rank > 0
# Wait for rank 0 to take advantage of disk caching and downloading
torch.distributed.broadcast(tensor, src=0)
# Load the datasets
train_loader, val_loader, test_loader, _, train_sampler = apputils.get_data_loaders(
args.datasets_fn, (os.path.expanduser(args.data), args), args.batch_size,
args.workers, args.validation_split, args.deterministic,
1., 1., 1., # effective sizes 100%
test_only=args.evaluate, collate_fn=args.collate_fn, cpu=args.device == 'cpu',
distributed=local_rank >= 0, rank=local_rank, world_size=local_world_size)
assert args.evaluate or train_loader is not None and val_loader is not None, \
"No training and/or validation data in train mode"
assert not args.evaluate or test_loader is not None, "No test data in eval mode"
assert local_rank < 0 or train_sampler is not None
if local_rank == 0: # DistributedDataParallel rank 0
# Notify the other ranks but don't wait
torch.distributed.broadcast(tensor, src=0, async_op=True)
if args.compress:
# The main use-case for this sample application is CNN compression. Compression
# requires a compression schedule configuration file in YAML.
compression_scheduler = distiller.file_config(model, optimizer, args.compress,
compression_scheduler,
(start_epoch-1)
if args.resumed_checkpoint_path
else None, loss_optimizer)
elif compression_scheduler is None:
compression_scheduler = distiller.CompressionScheduler(model)
# Model is re-transferred to GPU in case parameters were added (e.g. PACTQuantizer)
model.to(args.device)
args.kd_policy = None
if args.kd_teacher:
teacher = create_model(supported_models, dimensions, args, mode='kd_teacher')
if args.kd_resume:
teacher = apputils.load_lean_checkpoint(teacher, args.kd_resume)
dlw = distiller.DistillationLossWeights(args.kd_distill_wt, args.kd_student_wt,
args.kd_teacher_wt)
if args.kd_relationbased:
args.kd_policy = kd_relationbased.RelationBasedKDPolicy(model, teacher,
dlw, args.act_mode_8bit)
else:
args.kd_policy = distiller.KnowledgeDistillationPolicy(model, teacher,
args.kd_temp, dlw)
compression_scheduler.add_policy(args.kd_policy, starting_epoch=args.kd_start_epoch,
ending_epoch=args.epochs, frequency=1)
msglogger.info('\nStudent-Teacher knowledge distillation enabled:')
msglogger.info('\tTeacher Model: %s', args.kd_teacher)
msglogger.info('\tTemperature: %s', args.kd_temp)
msglogger.info('\tLoss Weights (distillation | student | teacher): %s',
' | '.join([f'{val:.2f}' for val in dlw]))
msglogger.info('\tStarting from Epoch: %d', args.kd_start_epoch)
if start_epoch >= ending_epoch:
msglogger.error('epoch count is too low, starting epoch is %d but total epochs set '
'to %d', start_epoch, ending_epoch)
raise ValueError('Epochs parameter is too low. Nothing to do.')
if args.nas:
assert isinstance(model, ai8x_nas.OnceForAllModel), 'Model should implement ' \
'OnceForAllModel interface for NAS training!'
if nas_policy:
args.nas_stage_transition_list = create_nas_training_stage_list(model, nas_policy)
args.nas_kd_params = nas_policy['kd_params'] \
if nas_policy and 'kd_params' in nas_policy else None
if args.nas_kd_resume_from == '':
args.nas_kd_policy = None
else:
if args.nas_kd_params['teacher_model'] == 'full_model':
kd_end_epoch = args.epochs
else:
kd_end_epoch = get_next_stage_start_epoch(start_epoch,
args.nas_stage_transition_list,
args.epochs)
create_nas_kd_policy(model, compression_scheduler, start_epoch, kd_end_epoch, args)
if args.compiler_mode.lower() != 'none':
if local_rank >= 0 or args.device == 'cuda' \
and (torch.cuda.device_count() == 1 or args.gpus is not None and len(args.gpus) <= 1):
model = torch.compile(model, mode=args.compiler_mode,
backend=args.compiler_backend)
msglogger.info(
'torch.compile() successful, mode=%s, cache limit=%d',
args.compiler_mode,
torch._dynamo.config.cache_size_limit, # pylint: disable=protected-access
)
else:
msglogger.info('torch.compile() not available, using "eager" mode')
if args.device == 'cuda' and torch.cuda.device_count() > 1:
msglogger.info('Use distributed training to enable torch.compile() '
'with multiple GPUs')
if args.evaluate:
msglogger.info('Dataset sizes:\n\ttest=%d', len(test_loader.sampler))
return test(test_loader, model, criterion, pylogger, args=args)
assert train_loader and val_loader
msglogger.info('Dataset sizes:\n\ttraining=%d\n\tvalidation=%d\n\ttest=%d',
len(train_loader.sampler), len(val_loader.sampler), len(test_loader.sampler))
vloss = 10**6
for epoch in range(start_epoch, ending_epoch):
if local_rank >= 0: # DistributedDataParallel
train_sampler.set_epoch(epoch)
if qat_policy is not None and epoch > 0 and epoch == qat_policy['start_epoch']:
msglogger.info('Initiating quantization aware training (QAT)...')
model, dynamo, ddp = model_wrapper.unwrap(model)
# Fuse the BN parameters into conv layers before Quantization Aware Training (QAT)
ai8x.fuse_bn_layers(model)
ai8x.init_hist(model)
msglogger.info('Collecting statistics for quantization aware training (QAT)...')
stat_collect(train_loader, model, args)
ai8x.init_threshold(model, qat_policy["outlier_removal_z_score"])
ai8x.release_hist(model)
ai8x.apply_scales(model)
# Update the optimizer to reflect fused batchnorm layers
optimizer = ai8x.update_optimizer(model, optimizer)
# Update the compression scheduler to reflect the updated optimizer
for ep, _ in enumerate(compression_scheduler.policies):
for pol in compression_scheduler.policies[ep]:
for attr_key in dir(pol):
attr = getattr(pol, attr_key)
if hasattr(attr, 'optimizer'):
attr.optimizer = optimizer
# Switch model from unquantized to quantized for QAT
ai8x.initiate_qat(model, qat_policy)
# Model is re-transferred to GPU in case parameters were added
model.to(args.device)
if ddp:
model = DistributedDataParallel(
model,
device_ids=[local_rank] if args.device == 'cuda' else None,
output_device=local_rank if args.device == 'cuda' else None,
)
if dynamo:
torch._dynamo.reset() # pylint: disable=protected-access
model = torch.compile(model, mode=args.compiler_mode,
backend=args.compiler_backend)
msglogger.info(
'torch.compile() successful, mode=%s, cache limit=%d',
args.compiler_mode,
torch._dynamo.config.cache_size_limit, # pylint: disable=protected-access
)
# Empty the performance scores list for QAT operation
perf_scores_history = []
if args.name:
args.name = f'{args.name}_qat'
else:
args.name = 'qat'
# This is the main training loop.
msglogger.info('\n')
if compression_scheduler:
compression_scheduler.on_epoch_begin(epoch, metrics=vloss)
# Train for one epoch
train(train_loader, model, criterion, optimizer, epoch, compression_scheduler,
loggers=all_loggers, args=args, loss_optimizer=loss_optimizer)
# evaluate on validation set
run_validation = not args.nas or (args.nas and (epoch < nas_policy['start_epoch']))
run_nas_validation = args.nas and (epoch >= nas_policy['start_epoch']) and \
((epoch+1) % nas_policy['validation_freq'] == 0)
if run_validation or run_nas_validation:
checkpoint_name = args.name
# run pre validation steps if NAS is running
if run_nas_validation:
update_bn_stats(train_loader, model, args)
stage, level = get_nas_training_stage(epoch, args.nas_stage_transition_list)
if args.name:
checkpoint_name = f'{args.name}_nas_stg{stage}_lev{level}'
else:
checkpoint_name = f'nas_stg{stage}_lev{level}'
if not args.dr:
top1, top5, vloss, mAP = validate(val_loader, model, criterion, [pylogger],
args, epoch, tflogger)
else:
top1, top5, vloss, mAP = scaf_test(val_loader, model, accuracy_calculator)
if args.obj_detection:
stats = ('Performance/Validation/', OrderedDict([('Loss', vloss),
('mAP', mAP)]))
elif args.regression:
stats = ('Performance/Validation/', OrderedDict([('Loss', vloss),
('MSE', top1)]))
else:
stats = ('Performance/Validation/', OrderedDict([('Loss', vloss),
('Top1', top1)]))
if args.num_classes > 5 and not args.dr:
stats[1]['Top5'] = top5
distiller.log_training_progress(stats, None, epoch, steps_completed=0, total_steps=1,
log_freq=1, loggers=all_tbloggers)
# Update the list of top scores achieved so far
update_training_scores_history(perf_scores_history, model, top1, top5, mAP, vloss,
epoch, args)
# Save the checkpoint
if run_validation:
is_best = epoch == perf_scores_history[0].epoch
checkpoint_extras = {'current_top1': top1,
'best_top1': perf_scores_history[0].top1,
'current_mAP': mAP,
'best_mAP': perf_scores_history[0].mAP,
'best_epoch': perf_scores_history[0].epoch}
else:
is_best = False
checkpoint_extras = {'current_top1': top1,
'current_mAP': mAP}
if args.dr:
checkpoint_extras['loss_weights'] = criterion.W
checkpoint_extras['loss_optimizer_state_dict'] = loss_optimizer.state_dict()
if local_rank <= 0: # not DistributedDataParallel or rank 0
m, _, _ = model_wrapper.unwrap(model)
apputils.save_checkpoint(epoch, args.cnn, m, optimizer=optimizer,
scheduler=compression_scheduler, extras=checkpoint_extras,
is_best=is_best, name=checkpoint_name,
dir=msglogger.logdir)
if compression_scheduler:
compression_scheduler.on_epoch_end(epoch, optimizer)
# Finally run results on the test set
if not args.dr:
test(test_loader, model, criterion, [pylogger], args=args, mode="ckpt")
test(test_loader, model, criterion, [pylogger], args=args, mode="best",
ckpt_name=checkpoint_name)
if args.copy_output_folder and local_rank <= 0:
msglogger.info('Copying output folder to: %s', args.copy_output_folder)
shutil.copytree(msglogger.logdir, args.copy_output_folder, dirs_exist_ok=True)
return None
OVERALL_LOSS_KEY = 'Overall Loss'
OBJECTIVE_LOSS_KEY = 'Objective Loss'
def create_model(supported_models, dimensions, args, mode='default'):
"""Create the model"""
if mode == 'kd_teacher':
module = next(item for item in supported_models if item['name'] == args.kd_teacher)
else: # including 'default'
module = next(item for item in supported_models if item['name'] == args.cnn)
# Override distiller's input shape detection. This is not a very clean way to do it since
# we're replacing a protected member.
distiller.utils._validate_input_shape = ( # pylint: disable=protected-access
lambda _a, _b: (1, ) + dimensions[:module['dim'] + 1]
)
if mode == 'kd_teacher':
Model = locate(module['module'] + '.' + args.kd_teacher)
if not Model:
raise RuntimeError("Model " + args.kd_teacher + " not found\n")
else: # including 'default'
Model = locate(module['module'] + '.' + args.cnn)
if not Model:
raise RuntimeError("Model " + args.cnn + " not found\n")
if args.dr and ('dr' not in module or not module['dr']):
raise ValueError("Dimensionality reduction is not supported for this model")
# Set model parameters
if args.act_mode_8bit:
weight_bits = 8
bias_bits = 8
quantize_activation = True
else:
weight_bits = None
bias_bits = None
quantize_activation = False
model_args = {}
model_args["pretrained"] = False
model_args["num_classes"] = args.num_classes
model_args["num_channels"] = dimensions[0]
model_args["dimensions"] = (dimensions[1], dimensions[2])
model_args["bias"] = args.use_bias
model_args["weight_bits"] = weight_bits
model_args["bias_bits"] = bias_bits
model_args["quantize_activation"] = quantize_activation
if args.dr:
model_args["dimensionality"] = args.dr
if args.backbone_checkpoint:
model_args["backbone_checkpoint"] = args.backbone_checkpoint
if args.obj_detection:
model_args["device"] = args.device
if module['dim'] > 1 and module['min_input'] > dimensions[2]:
model_args["padding"] = (module['min_input'] - dimensions[2] + 1) // 2
model = Model(**model_args).to(args.device)
return model
def create_optimizer(model, args):
"""Create the optimizer"""
if args.optimizer.lower() == 'sgd':
optimizer = torch.optim.SGD(model.parameters(), lr=args.lr, momentum=args.momentum,
weight_decay=args.weight_decay)
elif args.optimizer.lower() == 'adam':
optimizer = torch.optim.Adam(model.parameters(), lr=args.lr,
weight_decay=args.weight_decay)
else:
assert msglogger is not None
msglogger.info('Unknown optimizer type: %s. SGD is set as optimizer!!!', args.optimizer)
optimizer = torch.optim.SGD(model.parameters(), lr=args.lr, momentum=args.momentum,
weight_decay=args.weight_decay)
return optimizer
def create_nas_kd_policy(model, compression_scheduler, epoch, next_state_start_epoch, args):
"""Create knowledge distillation policy for nas"""
teacher = copy.deepcopy(model)
dlw = distiller.DistillationLossWeights(args.nas_kd_params['distill_loss'],
args.nas_kd_params['student_loss'], 0)
args.nas_kd_policy = distiller.KnowledgeDistillationPolicy(model, teacher,
args.nas_kd_params['temperature'],
dlw)
compression_scheduler.add_policy(args.nas_kd_policy, starting_epoch=epoch,
ending_epoch=next_state_start_epoch, frequency=1)
assert msglogger is not None
msglogger.info('\nStudent-Teacher knowledge distillation enabled for NAS:')
msglogger.info('\tStart Epoch: %d, End Epoch: %d', epoch, next_state_start_epoch)
msglogger.info('\tTemperature: %s', args.nas_kd_params['temperature'])
msglogger.info("\tLoss Weights (distillation | student | teacher): %s",
' | '.join([f'{val:.2f}' for val in dlw]))
@torch.no_grad()
def stat_collect(train_loader, model, args):
"""Collect statistics for quantization aware training"""
model.eval()
for inputs, _ in tqdm(train_loader):
inputs = inputs.to(args.device)
model(inputs)
def train(train_loader, model, criterion, optimizer, epoch,
compression_scheduler, loggers, args, loss_optimizer=None):
"""Training loop for one epoch."""
losses = OrderedDict([(OVERALL_LOSS_KEY, tnt.AverageValueMeter()),
(OBJECTIVE_LOSS_KEY, tnt.AverageValueMeter())])
if not args.regression:
classerr = tnt.ClassErrorMeter(accuracy=True, topk=(1, min(args.num_classes, 5)))
else:
classerr = tnt.MSEMeter()
batch_time = tnt.AverageValueMeter()
data_time = tnt.AverageValueMeter()
total_samples = len(train_loader.sampler)
batch_size = train_loader.batch_size
steps_per_epoch = (total_samples + batch_size - 1) // batch_size
assert msglogger is not None
msglogger.info('Training epoch: %d samples (%d per mini-batch, world size: %d)',
total_samples, batch_size, args.local_world_size)
if args.nas:
if args.nas_stage_transition_list is not None:
stage, level = get_nas_training_stage(epoch, args.nas_stage_transition_list)
prev_stage, _ = get_nas_training_stage(epoch-1, args.nas_stage_transition_list)
else:
stage = prev_stage = 0
level = 0
if prev_stage != stage:
if args.nas_kd_params:
if ('teacher_model' not in args.nas_kd_params) or \
('teacher_model' in args.nas_kd_params and
args.nas_kd_params['teacher_model'] == 'full_model' and prev_stage == 0):
create_nas_kd_policy(model, compression_scheduler, epoch, args.epochs, args)
elif 'teacher_model' in args.nas_kd_params and \
args.nas_kd_params['teacher_model'] == 'prev_stage_model':
next_stage_start_epoch = get_next_stage_start_epoch(
epoch, args.nas_stage_transition_list, args.epochs)
create_nas_kd_policy(model, compression_scheduler, epoch,
next_stage_start_epoch, args)
# Switch to train mode
model.train()
acc_stats = []
end = time.time()
for train_step, (inputs, target_temp) in enumerate(train_loader):
# Measure data loading time
data_time.add(time.time() - end)
if args.obj_detection:
inputs = inputs.to(args.device)
target = tuple()
for target_idx in range(len(target_temp[0])):
temp_list = [elem[target_idx].to(args.device) for elem in target_temp]
target = target + (temp_list, )
else:
inputs, target = inputs.to(args.device), target_temp.to(args.device)
# Set nas parameters if necessary
if args.nas:
if stage == 1:
ai8x_nas.sample_subnet_kernel(model, level)
elif stage == 2:
ai8x_nas.sample_subnet_depth(model, level)
elif stage == 3:
ai8x_nas.sample_subnet_width(model, level)
# Execute the forward phase, compute the output and measure loss
if compression_scheduler:
compression_scheduler.on_minibatch_begin(epoch, train_step, steps_per_epoch, optimizer)
if not hasattr(args, 'kd_policy') or args.kd_policy is None:
if not hasattr(args, 'nas_kd_policy') or args.nas_kd_policy is None:
output = model(inputs)
else:
output = args.nas_kd_policy.forward(inputs)
else:
output = args.kd_policy.forward(inputs)
if args.out_fold_ratio != 1:
output = ai8x.unfold_batch(output, args.out_fold_ratio)
loss = criterion(output, target)
if not args.obj_detection and not args.dr and not args.kd_relationbased:
# Measure accuracy if the conditions are set. For `Last Batch` only accuracy
# calculation last two batches are used as the last batch might include just a few
# samples.
if args.show_train_accuracy == 'full' or \
(args.show_train_accuracy == 'last_batch'
and train_step >= len(train_loader)-2):
if len(output.data.shape) <= 2 or args.regression:
classerr.add(output.data, target)
else:
classerr.add(output.data.permute(0, 2, 3, 1).flatten(start_dim=0, end_dim=2),
target.flatten())
if not args.regression:
acc_stats.append([classerr.value(1),
classerr.value(min(args.num_classes, 5))])
else:
acc_stats.append([classerr.value()])
# Record loss
losses[OBJECTIVE_LOSS_KEY].add(loss.item())
if compression_scheduler:
# Before running the backward phase, we allow the scheduler to modify the loss
# (e.g. add regularization loss)
agg_loss = compression_scheduler.before_backward_pass(epoch, train_step,
steps_per_epoch, loss,
optimizer=optimizer,
return_loss_components=True)
loss = agg_loss.overall_loss
losses[OVERALL_LOSS_KEY].add(loss.item())
for lc in agg_loss.loss_components:
if lc.name not in losses:
losses[lc.name] = tnt.AverageValueMeter()
losses[lc.name].add(lc.value.item())
else:
losses[OVERALL_LOSS_KEY].add(loss.item())
# Compute the gradient and do SGD step
optimizer.zero_grad()
if args.dr:
loss_optimizer.zero_grad()
loss.backward()
if compression_scheduler:
compression_scheduler.before_parameter_optimization(epoch, train_step,
steps_per_epoch, optimizer)
optimizer.step()
if args.dr:
loss_optimizer.step()
if compression_scheduler:
compression_scheduler.on_minibatch_end(epoch, train_step, steps_per_epoch, optimizer)
# Reset elastic sampling wrt NAS stage if necessary
if args.nas:
if stage == 1: