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Mobile-SAM / segment_anything /scripts /export_onnx_model.py

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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 torch

	from segment_anything import build_sam, build_sam_vit_b, build_sam_vit_l
	from segment_anything.utils.onnx import SamOnnxModel

	import argparse
	import warnings

	try:
	import onnxruntime # type: ignore

	onnxruntime_exists = True
	except ImportError:
	onnxruntime_exists = False

	parser = argparse.ArgumentParser(
	description="Export the SAM prompt encoder and mask decoder to an ONNX model."
	)

	parser.add_argument(
	"--checkpoint", type=str, required=True, help="The path to the SAM model checkpoint."
	)

	parser.add_argument(
	"--output", type=str, required=True, help="The filename to save the ONNX model to."
	)

	parser.add_argument(
	"--model-type",
	type=str,
	default="default",
	help="In ['default', 'vit_b', 'vit_l']. Which type of SAM model to export.",
	)

	parser.add_argument(
	"--return-single-mask",
	action="store_true",
	help=(
	"If true, the exported ONNX model will only return the best mask, "
	"instead of returning multiple masks. For high resolution images "
	"this can improve runtime when upscaling masks is expensive."
	),
	)

	parser.add_argument(
	"--opset",
	type=int,
	default=17,
	help="The ONNX opset version to use. Must be >=11",
	)

	parser.add_argument(
	"--quantize-out",
	type=str,
	default=None,
	help=(
	"If set, will quantize the model and save it with this name. "
	"Quantization is performed with quantize_dynamic from onnxruntime.quantization.quantize."
	),
	)

	parser.add_argument(
	"--gelu-approximate",
	action="store_true",
	help=(
	"Replace GELU operations with approximations using tanh. Useful "
	"for some runtimes that have slow or unimplemented erf ops, used in GELU."
	),
	)

	parser.add_argument(
	"--use-stability-score",
	action="store_true",
	help=(
	"Replaces the model's predicted mask quality score with the stability "
	"score calculated on the low resolution masks using an offset of 1.0. "
	),
	)

	parser.add_argument(
	"--return-extra-metrics",
	action="store_true",
	help=(
	"The model will return five results: (masks, scores, stability_scores, "
	"areas, low_res_logits) instead of the usual three. This can be "
	"significantly slower for high resolution outputs."
	),
	)


	def run_export(
	model_type: str,
	checkpoint: str,
	output: str,
	opset: int,
	return_single_mask: bool,
	gelu_approximate: bool = False,
	use_stability_score: bool = False,
	return_extra_metrics=False,
	):
	print("Loading model...")
	if model_type == "vit_b":
	sam = build_sam_vit_b(checkpoint)
	elif model_type == "vit_l":
	sam = build_sam_vit_l(checkpoint)
	else:
	sam = build_sam(checkpoint)

	onnx_model = SamOnnxModel(
	model=sam,
	return_single_mask=return_single_mask,
	use_stability_score=use_stability_score,
	return_extra_metrics=return_extra_metrics,
	)

	if gelu_approximate:
	for n, m in onnx_model.named_modules():
	if isinstance(m, torch.nn.GELU):
	m.approximate = "tanh"

	dynamic_axes = {
	"point_coords": {1: "num_points"},
	"point_labels": {1: "num_points"},
	}

	embed_dim = sam.prompt_encoder.embed_dim
	embed_size = sam.prompt_encoder.image_embedding_size
	mask_input_size = [4 * x for x in embed_size]
	dummy_inputs = {
	"image_embeddings": torch.randn(1, embed_dim, *embed_size, dtype=torch.float),
	"point_coords": torch.randint(low=0, high=1024, size=(1, 5, 2), dtype=torch.float),
	"point_labels": torch.randint(low=0, high=4, size=(1, 5), dtype=torch.float),
	"mask_input": torch.randn(1, 1, *mask_input_size, dtype=torch.float),
	"has_mask_input": torch.tensor([1], dtype=torch.float),
	"orig_im_size": torch.tensor([1500, 2250], dtype=torch.float),
	}

	_ = onnx_model(**dummy_inputs)

	output_names = ["masks", "iou_predictions", "low_res_masks"]

	with warnings.catch_warnings():
	warnings.filterwarnings("ignore", category=torch.jit.TracerWarning)
	warnings.filterwarnings("ignore", category=UserWarning)
	with open(output, "wb") as f:
	print(f"Exporing onnx model to {output}...")
	torch.onnx.export(
	onnx_model,
	tuple(dummy_inputs.values()),
	f,
	export_params=True,
	verbose=False,
	opset_version=opset,
	do_constant_folding=True,
	input_names=list(dummy_inputs.keys()),
	output_names=output_names,
	dynamic_axes=dynamic_axes,
	)

	if onnxruntime_exists:
	ort_inputs = {k: to_numpy(v) for k, v in dummy_inputs.items()}
	ort_session = onnxruntime.InferenceSession(output)
	_ = ort_session.run(None, ort_inputs)
	print("Model has successfully been run with ONNXRuntime.")


	def to_numpy(tensor):
	return tensor.cpu().numpy()


	if __name__ == "__main__":
	args = parser.parse_args()
	run_export(
	model_type=args.model_type,
	checkpoint=args.checkpoint,
	output=args.output,
	opset=args.opset,
	return_single_mask=args.return_single_mask,
	gelu_approximate=args.gelu_approximate,
	use_stability_score=args.use_stability_score,
	return_extra_metrics=args.return_extra_metrics,
	)

	if args.quantize_out is not None:
	assert onnxruntime_exists, "onnxruntime is required to quantize the model."
	from onnxruntime.quantization import QuantType # type: ignore
	from onnxruntime.quantization.quantize import quantize_dynamic # type: ignore

	print(f"Quantizing model and writing to {args.quantize_out}...")
	quantize_dynamic(
	model_input=args.output,
	model_output=args.quantize_out,
	optimize_model=True,
	per_channel=False,
	reduce_range=False,
	weight_type=QuantType.QUInt8,
	)
	print("Done!")