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chore: import upstream snapshot with attribution
2026-07-13 13:36:55 +08:00

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Python

#
# SPDX-FileCopyrightText: Copyright (c) 1993-2023 NVIDIA CORPORATION & AFFILIATES. All rights reserved.
# SPDX-License-Identifier: Apache-2.0
#
# 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.
#
import datetime
import inspect
import os
import sys
import time
import argparse
import warnings
import collections
import subprocess
import torch
import torch.utils.data
from collections import namedtuple
from torch import nn
from tqdm import tqdm
import torchvision
from torchvision import transforms
from torch.hub import load_state_dict_from_url
from pytorch_quantization import nn as quant_nn
from pytorch_quantization import calib
from pytorch_quantization.tensor_quant import QuantDescriptor
from pytorch_quantization import quant_modules
import onnxruntime
import numpy as np
import models.classification as models
from prettytable import PrettyTable
# The following path assumes running in nvcr.io/nvidia/pytorch:20.08-py3
sys.path.insert(0, "/opt/pytorch/vision/references/classification/")
# Import functions from torchvision reference
try:
from train import evaluate, train_one_epoch, load_data, utils
except Exception as e:
raise ModuleNotFoundError(
"Add https://github.com/pytorch/vision/blob/master/references/classification/ to PYTHONPATH")
def get_parser():
"""
Creates an argument parser.
"""
parser = argparse.ArgumentParser(description='Classification quantization flow script')
parser.add_argument('--data-dir', '-d', type=str, help='input data folder', required=True)
parser.add_argument('--model-name', '-m', default='resnet50', help='model name: default resnet50')
parser.add_argument('--disable-pcq',
'-dpcq',
action="store_true",
help='disable per-channel quantization for weights')
parser.add_argument('--out-dir', '-o', default='/tmp', help='output folder: default /tmp')
parser.add_argument('--print-freq', '-pf', type=int, default=20, help='evaluation print frequency: default 20')
parser.add_argument('--threshold',
'-t',
type=float,
default=-1.0,
help='top1 accuracy threshold (less than 0.0 means no comparison): default -1.0')
parser.add_argument('--fp16', action="store_true", help="Enable FP16 model training, evaluation and export")
parser.add_argument('--batch-size-train', type=int, default=128, help='batch size for training: default 128')
parser.add_argument('--batch-size-test', type=int, default=128, help='batch size for testing: default 128')
parser.add_argument('--batch-size-onnx', type=int, default=1, help='batch size for onnx: default 1')
parser.add_argument('--seed', type=int, default=12345, help='random seed: default 12345')
checkpoint = parser.add_mutually_exclusive_group(required=True)
checkpoint.add_argument('--ckpt-path', default='', type=str, help='path to latest checkpoint (default: none)')
checkpoint.add_argument('--ckpt-url', default='', type=str, help='url to latest checkpoint (default: none)')
checkpoint.add_argument('--pretrained', action="store_true")
parser.add_argument('--num-calib-batch',
default=4,
type=int,
help='Number of batches for calibration. 0 will disable calibration. (default: 4)')
parser.add_argument('--num-finetune-epochs',
default=0,
type=int,
help='Number of epochs to fine tune. 0 will disable fine tune. (default: 0)')
parser.add_argument('--calibrator', type=str, choices=["max", "histogram"], default="max")
parser.add_argument('--percentile', nargs='+', type=float, default=[99.9, 99.99, 99.999, 99.9999])
parser.add_argument('--sensitivity', action="store_true", help="Build sensitivity profile")
parser.add_argument('--evaluate-onnx', action="store_true", help="Evaluate exported ONNX")
parser.add_argument('--evaluate-trt', action="store_true", help="Export and evaluate TRT")
return parser
def prepare_model(model_name,
data_dir,
per_channel_quantization,
batch_size_train,
batch_size_test,
batch_size_onnx,
calibrator,
pretrained=True,
ckpt_path=None,
ckpt_url=None,
fp16=False):
"""
Prepare the model for the classification flow.
Arguments:
model_name: name to use when accessing torchvision model dictionary
data_dir: directory with train and val subdirs prepared "imagenet style"
per_channel_quantization: iff true use per channel quantization for weights
note that this isn't currently supported in ONNX-RT/Pytorch
batch_size_train: batch size to use when training
batch_size_test: batch size to use when testing in Pytorch
batch_size_onnx: batch size to use when testing with ONNX-RT
calibrator: calibration type to use (max/histogram)
pretrained: if true a pretrained model will be loaded from torchvision
ckpt_path: path to load a model checkpoint from, if not pretrained
ckpt_url: url to download a model checkpoint from, if not pretrained and no path was given
* at least one of {pretrained, path, url} must be valid
The method returns a the following list:
[
Model object,
data loader for training,
data loader for Pytorch testing,
data loader for onnx testing
]
"""
# Use 'spawn' to avoid CUDA reinitialization with forked subprocess
torch.multiprocessing.set_start_method('spawn')
## Initialize quantization, model and data loaders
if per_channel_quantization:
quant_desc_input = QuantDescriptor(calib_method=calibrator)
quant_nn.QuantConv2d.set_default_quant_desc_input(quant_desc_input)
quant_nn.QuantLinear.set_default_quant_desc_input(quant_desc_input)
else:
## Force per tensor quantization for onnx runtime
quant_desc_input = QuantDescriptor(calib_method=calibrator, axis=None)
quant_nn.QuantConv2d.set_default_quant_desc_input(quant_desc_input)
quant_nn.QuantConvTranspose2d.set_default_quant_desc_input(quant_desc_input)
quant_nn.QuantLinear.set_default_quant_desc_input(quant_desc_input)
quant_desc_weight = QuantDescriptor(calib_method=calibrator, axis=None)
quant_nn.QuantConv2d.set_default_quant_desc_weight(quant_desc_weight)
quant_nn.QuantConvTranspose2d.set_default_quant_desc_weight(quant_desc_weight)
quant_nn.QuantLinear.set_default_quant_desc_weight(quant_desc_weight)
if model_name in models.__dict__:
model = models.__dict__[model_name](pretrained=pretrained, quantize=True)
else:
quant_modules.initialize()
model = torchvision.models.__dict__[model_name](pretrained=pretrained)
quant_modules.deactivate()
if not pretrained:
if ckpt_path:
checkpoint = torch.load(ckpt_path)
else:
checkpoint = load_state_dict_from_url(ckpt_url)
if 'state_dict' in checkpoint.keys():
checkpoint = checkpoint['state_dict']
elif 'model' in checkpoint.keys():
checkpoint = checkpoint['model']
model.load_state_dict(checkpoint)
model.eval()
model.cuda()
if fp16:
model = model.half()
## Prepare the data loaders
traindir = os.path.join(data_dir, 'train')
valdir = os.path.join(data_dir, 'val')
_args = collections.namedtuple("mock_args", [
"model", "distributed", "cache_dataset", "val_resize_size", "val_crop_size", "train_crop_size", "interpolation",
"ra_magnitude", "augmix_severity", "weights", "backend", "use_v2"
])
dataset, dataset_test, train_sampler, test_sampler = load_data(
traindir, valdir,
_args(model=model_name,
distributed=False,
cache_dataset=False,
val_resize_size=256,
val_crop_size=224,
train_crop_size=224,
interpolation="bilinear",
ra_magnitude=9,
augmix_severity=3,
weights=None,
backend="pil",
use_v2=False))
data_loader_train = torch.utils.data.DataLoader(dataset,
batch_size=batch_size_train,
sampler=train_sampler,
num_workers=4,
pin_memory=True)
data_loader_test = torch.utils.data.DataLoader(dataset_test,
batch_size=batch_size_test,
sampler=test_sampler,
num_workers=4,
pin_memory=True)
data_loader_onnx = torch.utils.data.DataLoader(dataset_test,
batch_size=batch_size_onnx,
sampler=test_sampler,
num_workers=4,
pin_memory=True)
return model, data_loader_train, data_loader_test, data_loader_onnx
def main(cmdline_args):
parser = get_parser()
args = parser.parse_args(cmdline_args)
print(parser.description)
print(args)
torch.manual_seed(args.seed)
np.random.seed(args.seed)
## Prepare the pretrained model and data loaders
model, data_loader_train, data_loader_test, data_loader_onnx = prepare_model(
args.model_name, args.data_dir, not args.disable_pcq, args.batch_size_train, args.batch_size_test,
args.batch_size_onnx, args.calibrator, args.pretrained, args.ckpt_path, args.ckpt_url, args.fp16)
## Initial accuracy evaluation
CrossEntropy = nn.CrossEntropyLoss()
# nn.CrossEntropyLoss expects float inputs
def criterion(output, target):
return CrossEntropy(output.float(), target)
with torch.no_grad():
print('Initial evaluation:')
top1_initial = evaluate(model, criterion, data_loader_test, device="cuda", print_freq=args.print_freq)
## Calibrate the model
with torch.no_grad():
calibrate_model(model=model,
model_name=args.model_name,
data_loader=data_loader_train,
num_calib_batch=args.num_calib_batch,
calibrator=args.calibrator,
hist_percentile=args.percentile,
out_dir=args.out_dir)
## Evaluate after calibration
if args.num_calib_batch > 0:
with torch.no_grad():
print('Calibration evaluation:')
top1_calibrated = evaluate(model, criterion, data_loader_test, device="cuda", print_freq=args.print_freq)
else:
top1_calibrated = -1.0
## Build sensitivy profile
if args.sensitivity:
build_sensitivity_profile(model, criterion, data_loader_test)
## Finetune the model
criterion = nn.CrossEntropyLoss()
optimizer = torch.optim.SGD(model.parameters(), lr=0.0001)
lr_scheduler = torch.optim.lr_scheduler.CosineAnnealingLR(optimizer, args.num_finetune_epochs)
for epoch in range(args.num_finetune_epochs):
# Training a single epch
if "print_freq" in inspect.signature(train_one_epoch).parameters:
train_one_epoch(model, criterion, optimizer, data_loader_train, "cuda", 0, 100)
else:
_args = collections.namedtuple("mock_args",
["print_freq", "clip_grad_norm", "model_ema_steps", "lr_warmup_epochs"])
train_one_epoch(model, criterion, optimizer, data_loader_train, "cuda", 0,
_args(print_freq=100, clip_grad_norm=None, model_ema_steps=32, lr_warmup_epochs=0))
lr_scheduler.step()
if args.num_finetune_epochs > 0:
## Evaluate after finetuning
with torch.no_grad():
print('Finetune evaluation:')
top1_finetuned = evaluate(model, criterion, data_loader_test, device="cuda")
else:
top1_finetuned = -1.0
## Export to ONNX
onnx_filename = args.out_dir + '/' + args.model_name + ".onnx"
top1_onnx = -1.0
if args.evaluate_onnx and export_onnx(model, onnx_filename, args.batch_size_onnx, not args.disable_pcq):
## Validate ONNX and evaluate
top1_onnx = evaluate_onnx(onnx_filename, data_loader_onnx, criterion, args.print_freq)
trt_filename = args.out_dir + '/' + args.model_name + ".trt"
top1_trt = -1.0
if args.evaluate_trt and export_trt(model, trt_filename, args.batch_size_onnx, args.fp16):
## Validate TRT and evaluate
top1_trt = evaluate_trt(trt_filename, data_loader_onnx, criterion, args.print_freq)
## Print summary
print("Accuracy summary:")
table = PrettyTable(['Stage', 'Top1'])
table.align['Stage'] = "l"
table.add_row(['Initial', "{:.2f}".format(top1_initial)])
table.add_row(['Calibrated', "{:.2f}".format(top1_calibrated)])
table.add_row(['Finetuned', "{:.2f}".format(top1_finetuned)])
table.add_row(['ONNX', "{:.2f}".format(top1_onnx)])
if args.evaluate_trt:
table.add_row(['TRT', "{:.2f}".format(top1_trt)])
print(table)
## Compare results
if args.threshold >= 0.0:
if args.evaluate_onnx and top1_onnx < 0.0:
print("Failed to export/evaluate ONNX!")
return 1
if args.evaluate_trt and top1_trt < 0.0:
print("Failed to export/evaluate TRT!")
return 1
if args.num_finetune_epochs > 0:
if top1_finetuned >= (top1_onnx - args.threshold):
print("Accuracy threshold was met!")
else:
print("Accuracy threshold was missed!")
return 1
if args.evaluate_trt and top1_finetuned >= (top1_trt - args.threshold):
print("TRT Accuracy threshold was met!")
elif args.evaluate_trt:
print("TRT Accuracy threshold was missed!")
return 1
return 0
def evaluate_onnx(onnx_filename, data_loader, criterion, print_freq):
"""Evaluate accuracy on the given ONNX file using the provided data loader and criterion.
The method returns the average top-1 accuracy on the given dataset.
"""
print("Loading ONNX file: ", onnx_filename)
ort_session = onnxruntime.InferenceSession(onnx_filename, providers=['CUDAExecutionProvider', 'CPUExecutionProvider'])
with torch.no_grad():
metric_logger = utils.MetricLogger(delimiter=" ")
header = 'Test:'
with torch.no_grad():
for image, target in metric_logger.log_every(data_loader, print_freq, header):
image = image.to("cpu", non_blocking=True)
image_data = np.array(image)
input_data = image_data
# run the data through onnx runtime instead of torch model
input_name = ort_session.get_inputs()[0].name
raw_result = ort_session.run([], {input_name: input_data})
output = torch.tensor((raw_result[0])).float()
loss = criterion(output, target)
acc1, acc5 = utils.accuracy(output, target, topk=(1, 5))
batch_size = image.shape[0]
metric_logger.update(loss=loss.item())
metric_logger.meters['acc1'].update(acc1.item(), n=batch_size)
metric_logger.meters['acc5'].update(acc5.item(), n=batch_size)
# gather the stats from all processes
metric_logger.synchronize_between_processes()
print(' ONNXRuntime: Acc@1 {top1.global_avg:.3f} Acc@5 {top5.global_avg:.3f}'.format(top1=metric_logger.acc1,
top5=metric_logger.acc5))
return metric_logger.acc1.global_avg
def evaluate_trt(trt_filename, data_loader, criterion, print_freq):
print("Loading TRT file: ", trt_filename)
import pycuda.driver as cuda
try:
import pycuda.autoprimaryctx
except ModuleNotFoundError:
import pycuda.autoinit
import tensorrt as trt
TRT_LOGGER = trt.Logger()
TRT_tensor = namedtuple('TRT_tensor', ['binding_idx', 'shape', 'dtype', 'device_memory', 'host_memory'])
def load_engine(engine_file_path):
assert os.path.exists(engine_file_path)
print("Reading engine from file {}".format(engine_file_path))
with open(engine_file_path, "rb") as f, trt.Runtime(TRT_LOGGER) as runtime:
return runtime.deserialize_cuda_engine(f.read())
def setup_context(engine):
return engine.create_execution_context()
def allocate_buffers(engine, context):
# Allocate host and device buffers
bindings = []
inputs = {}
outputs = {}
for binding_idx in range(engine.num_bindings):
binding = engine.get_tensor_name(binding_idx)
shape = tuple(context.get_tensor_shape(binding))
size = trt.volume(context.get_tensor_shape(binding))
dtype = np.dtype(trt.nptype(engine.get_tensor_dtype(binding)))
device_memory = cuda.mem_alloc(size * dtype.itemsize)
bindings.append(int(device_memory))
if engine.get_tensor_mode(binding) == trt.TensorIOMode.INPUT:
inputs[binding] = TRT_tensor(binding_idx, shape, dtype, device_memory, None)
else:
host_memory = cuda.pagelocked_empty(size, dtype)
outputs[binding] = TRT_tensor(binding_idx, shape, dtype, device_memory, host_memory)
stream = cuda.Stream()
return bindings, inputs, outputs, stream
def infer(batch, context, bindings, inputs, outputs, stream):
# Transfer input data to the GPU.
for name, trt_in_t in inputs.items():
buffer = np.ascontiguousarray(batch[name])
cuda.memcpy_htod_async(trt_in_t.device_memory, buffer, stream)
# Run inference
context.execute_async_v2(bindings=bindings, stream_handle=stream.handle)
# Transfer predictions back from the GPU.
for _, trt_out_t in outputs.items():
cuda.memcpy_dtoh_async(trt_out_t.host_memory, trt_out_t.device_memory, stream)
# Synchronize the stream
stream.synchronize()
return {k: torch.tensor(v.host_memory).reshape(v.shape) for k, v in outputs.items()}
engine = load_engine(trt_filename)
context = setup_context(engine)
bindings, inputs, outputs, stream = allocate_buffers(engine, context)
with torch.no_grad():
metric_logger = utils.MetricLogger(delimiter=" ")
header = 'Test:'
with torch.no_grad():
for image, target in metric_logger.log_every(data_loader, print_freq, header):
image = image.to("cpu", non_blocking=True)
image_data = np.array(image)
output = infer({"input": image_data}, context, bindings, inputs, outputs, stream)["output"].float()
loss = criterion(output, target)
acc1, acc5 = utils.accuracy(output, target, topk=(1, 5))
batch_size = image.shape[0]
metric_logger.update(loss=loss.item())
metric_logger.meters['acc1'].update(acc1.item(), n=batch_size)
metric_logger.meters['acc5'].update(acc5.item(), n=batch_size)
# gather the stats from all processes
metric_logger.synchronize_between_processes()
print(' TRTRuntime: Acc@1 {top1.global_avg:.3f} Acc@5 {top5.global_avg:.3f}'.format(top1=metric_logger.acc1,
top5=metric_logger.acc5))
return metric_logger.acc1.global_avg
def _export_onnx(model, dummy_input, onnx_filename, opset_version):
try:
if "enable_onnx_checker" in inspect.signature(torch.onnx.export).parameters:
torch.onnx.export(model,
dummy_input,
onnx_filename,
verbose=False,
input_names=["input"],
output_names=["output"],
opset_version=opset_version,
enable_onnx_checker=False,
do_constant_folding=True)
else:
torch.onnx.export(model,
dummy_input,
onnx_filename,
verbose=False,
input_names=["input"],
output_names=["output"],
opset_version=opset_version,
do_constant_folding=True)
except ValueError:
print("Failed to export to ONNX")
return False
return True
def export_onnx(model, onnx_filename, batch_onnx, per_channel_quantization):
model.eval()
if per_channel_quantization:
opset_version = 13
else:
opset_version = 12
# Export ONNX for multiple batch sizes
print("Creating ONNX file: " + onnx_filename)
dummy_input = torch.randn(batch_onnx, 3, 224, 224, device='cuda') #TODO: switch input dims by model
return _export_onnx(model, dummy_input, onnx_filename, opset_version)
def export_trt(model, trt_filename, batch_trt, fp16=False):
model.eval()
# Export TRT for multiple batch sizes
print("Creating TRT file: " + trt_filename)
dummy_input = torch.randn(batch_trt, 3, 224, 224, device='cuda') #TODO: switch input dims by model
OPSET = 17
onnx_filename = trt_filename.replace(".trt", ".onnx")
if not _export_onnx(model, dummy_input, onnx_filename, OPSET):
return False
trt_cmd = f"trtexec --onnx={onnx_filename} --saveEngine={trt_filename} --int8"
if fp16:
trt_cmd += " --fp16"
print(trt_cmd)
try:
trt_stdout = subprocess.check_output(trt_cmd, shell=True).decode("utf-8")
except:
print("Failed to export to TRT")
return False
print(trt_stdout)
return 'PASSED' in trt_stdout
def calibrate_model(model, model_name, data_loader, num_calib_batch, calibrator, hist_percentile, out_dir):
"""
Feed data to the network and calibrate.
Arguments:
model: classification model
model_name: name to use when creating state files
data_loader: calibration data set
num_calib_batch: amount of calibration passes to perform
calibrator: type of calibration to use (max/histogram)
hist_percentile: percentiles to be used for historgram calibration
out_dir: dir to save state files in
"""
if num_calib_batch > 0:
print("Calibrating model")
with torch.no_grad():
collect_stats(model, data_loader, num_calib_batch)
if not calibrator == "histogram":
compute_amax(model, method="max")
calib_output = os.path.join(out_dir, F"{model_name}-max-{num_calib_batch*data_loader.batch_size}.pth")
torch.save(model.state_dict(), calib_output)
else:
for percentile in hist_percentile:
print(F"{percentile} percentile calibration")
compute_amax(model, method="percentile")
calib_output = os.path.join(
out_dir, F"{model_name}-percentile-{percentile}-{num_calib_batch*data_loader.batch_size}.pth")
torch.save(model.state_dict(), calib_output)
for method in ["mse", "entropy"]:
print(F"{method} calibration")
compute_amax(model, method=method)
calib_output = os.path.join(out_dir,
F"{model_name}-{method}-{num_calib_batch*data_loader.batch_size}.pth")
torch.save(model.state_dict(), calib_output)
def collect_stats(model, data_loader, num_batches):
"""Feed data to the network and collect statistics"""
# Enable calibrators
for name, module in model.named_modules():
if isinstance(module, quant_nn.TensorQuantizer):
if module._calibrator is not None:
module.disable_quant()
module.enable_calib()
else:
module.disable()
# Feed data to the network for collecting stats
for i, (image, _) in tqdm(enumerate(data_loader), total=num_batches):
model(image.cuda())
if i >= num_batches:
break
# Disable calibrators
for name, module in model.named_modules():
if isinstance(module, quant_nn.TensorQuantizer):
if module._calibrator is not None:
module.enable_quant()
module.disable_calib()
else:
module.enable()
def compute_amax(model, **kwargs):
# Load calib result
for name, module in model.named_modules():
if isinstance(module, quant_nn.TensorQuantizer):
if module._calibrator is not None:
if isinstance(module._calibrator, calib.MaxCalibrator):
module.load_calib_amax()
else:
module.load_calib_amax(**kwargs)
print(F"{name:40}: {module}")
model.cuda()
def build_sensitivity_profile(model, criterion, data_loader_test):
quant_layer_names = []
for name, module in model.named_modules():
if name.endswith("_quantizer"):
module.disable()
layer_name = name.replace("._input_quantizer", "").replace("._weight_quantizer", "")
if layer_name not in quant_layer_names:
quant_layer_names.append(layer_name)
for i, quant_layer in enumerate(quant_layer_names):
print("Enable", quant_layer)
for name, module in model.named_modules():
if name.endswith("_quantizer") and quant_layer in name:
module.enable()
print(F"{name:40}: {module}")
with torch.no_grad():
evaluate(model, criterion, data_loader_test, device="cuda")
for name, module in model.named_modules():
if name.endswith("_quantizer") and quant_layer in name:
module.disable()
print(F"{name:40}: {module}")
if __name__ == '__main__':
res = main(sys.argv[1:])
exit(res)