python/FunASR-XL.git

			@@ -1,72 +1,199 @@
			import os
			import torch
			import functools

			def export_onnx(model,
			data_in=None,
			quantize: bool = False,
			fallback_num: int = 5,
			calib_num: int = 100,
			opset_version: int = 14,
			**kwargs):
			model_scripts = model.export(**kwargs)
			export_dir = kwargs.get("output_dir", os.path.dirname(kwargs.get("init_param")))
			os.makedirs(export_dir, exist_ok=True)

			if not isinstance(model_scripts, (list, tuple)):
			model_scripts = (model_scripts,)
			for m in model_scripts:
			m.eval()
			_onnx(m,
			data_in=data_in,
			quantize=quantize,
			fallback_num=fallback_num,
			calib_num=calib_num,
			opset_version=opset_version,
			export_dir=export_dir,
			**kwargs
			)
			print("output dir: {}".format(export_dir))

			return export_dir

			def _onnx(model,
			data_in=None,
			quantize: bool = False,
			opset_version: int = 14,
			export_dir:str = None,
			**kwargs):

			dummy_input = model.export_dummy_inputs()

			verbose = kwargs.get("verbose", False)

			export_name = model.export_name() if hasattr(model, "export_name") else "model.onnx"
			model_path = os.path.join(export_dir, export_name)
			torch.onnx.export(
			model,
			dummy_input,
			model_path,
			verbose=verbose,
			opset_version=opset_version,
			input_names=model.export_input_names(),
			output_names=model.export_output_names(),
			dynamic_axes=model.export_dynamic_axes()
			)

			if quantize:
			from onnxruntime.quantization import QuantType, quantize_dynamic
			import onnx
			quant_model_path = model_path.replace(".onnx", "_quant.onnx")
			if not os.path.exists(quant_model_path):
			onnx_model = onnx.load(model_path)
			nodes = [n.name for n in onnx_model.graph.node]
			nodes_to_exclude = [m for m in nodes if 'output' in m or 'bias_encoder' in m or 'bias_decoder' in m]
			quantize_dynamic(
			model_input=model_path,
			model_output=quant_model_path,
			op_types_to_quantize=['MatMul'],
			per_channel=True,
			reduce_range=False,
			weight_type=QuantType.QUInt8,
			nodes_to_exclude=nodes_to_exclude,
			)
			try:
			import torch_blade
			except Exception as e:
			print(f"Warning, if you are exporting bladedisc, please install it and try it again: pip install -U torch_blade\n")


			def export(model, data_in=None, quantize: bool = False, opset_version: int = 14, type='onnx', **kwargs):
			model_scripts = model.export(**kwargs)
			export_dir = kwargs.get("output_dir", os.path.dirname(kwargs.get("init_param")))
			os.makedirs(export_dir, exist_ok=True)

			if not isinstance(model_scripts, (list, tuple)):
			model_scripts = (model_scripts,)
			for m in model_scripts:
			m.eval()
			if type == 'onnx':
			_onnx(
			m,
			data_in=data_in,
			quantize=quantize,
			opset_version=opset_version,
			export_dir=export_dir,
			**kwargs
			)
			elif type == 'torchscripts':
			device = 'cuda' if torch.cuda.is_available() else 'cpu'
			print("Exporting torchscripts on device {}".format(device))
			_torchscripts(
			m,
			path=export_dir,
			device=device
			)
			elif type == "bladedisc":
			assert (
			torch.cuda.is_available()
			), "Currently bladedisc optimization for FunASR only supports GPU"
			# bladedisc only optimizes encoder/decoder modules
			if hasattr(m, "encoder") and hasattr(m, "decoder"):
			_bladedisc_opt_for_encdec(m, path=export_dir, enable_fp16=True)
			else:
			_torchscripts(m, path=export_dir, device="cuda")
			print("output dir: {}".format(export_dir))

			return export_dir


			def _onnx(
			model,
			data_in=None,
			quantize: bool = False,
			opset_version: int = 14,
			export_dir: str = None,
			**kwargs
			):

			dummy_input = model.export_dummy_inputs()

			verbose = kwargs.get("verbose", False)

			export_name = model.export_name + '.onnx'
			model_path = os.path.join(export_dir, export_name)
			torch.onnx.export(
			model,
			dummy_input,
			model_path,
			verbose=verbose,
			opset_version=opset_version,
			input_names=model.export_input_names(),
			output_names=model.export_output_names(),
			dynamic_axes=model.export_dynamic_axes(),
			)

			if quantize:
			from onnxruntime.quantization import QuantType, quantize_dynamic
			import onnx

			quant_model_path = model_path.replace(".onnx", "_quant.onnx")
			if not os.path.exists(quant_model_path):
			onnx_model = onnx.load(model_path)
			nodes = [n.name for n in onnx_model.graph.node]
			nodes_to_exclude = [
			m for m in nodes if "output" in m or "bias_encoder" in m or "bias_decoder" in m
			]
			quantize_dynamic(
			model_input=model_path,
			model_output=quant_model_path,
			op_types_to_quantize=["MatMul"],
			per_channel=True,
			reduce_range=False,
			weight_type=QuantType.QUInt8,
			nodes_to_exclude=nodes_to_exclude,
			)


			def _torchscripts(model, path, device='cuda'):
			dummy_input = model.export_dummy_inputs()

			if device == 'cuda':
			model = model.cuda()
			if isinstance(dummy_input, torch.Tensor):
			dummy_input = dummy_input.cuda()
			else:
			dummy_input = tuple([i.cuda() for i in dummy_input])

			model_script = torch.jit.trace(model, dummy_input)
			model_script.save(os.path.join(path, f'{model.export_name}.torchscripts'))


			def _bladedisc_opt(model, model_inputs, enable_fp16=True):
			model = model.eval()
			torch_config = torch_blade.config.Config()
			torch_config.enable_fp16 = enable_fp16
			with torch.no_grad(), torch_config:
			opt_model = torch_blade.optimize(
			model,
			allow_tracing=True,
			model_inputs=model_inputs,
			)
			return opt_model


			def _rescale_input_hook(m, x, scale):
			if len(x) > 1:
			return (x[0] / scale, *x[1:])
			else:
			return (x[0] / scale,)


			def _rescale_output_hook(m, x, y, scale):
			if isinstance(y, tuple):
			return (y[0] / scale, *y[1:])
			else:
			return y / scale


			def _rescale_encoder_model(model, input_data):
			# Calculate absmax
			absmax = torch.tensor(0).cuda()

			def stat_input_hook(m, x, y):
			val = x[0] if isinstance(x, tuple) else x
			absmax.copy_(torch.max(absmax, val.detach().abs().max()))

			encoders = model.encoder.model.encoders
			hooks = [m.register_forward_hook(stat_input_hook) for m in encoders]
			model = model.cuda()
			model(*input_data)
			for h in hooks:
			h.remove()

			# Rescale encoder modules
			fp16_scale = int(2 * absmax // 65536)
			print(f"rescale encoder modules with factor={fp16_scale}")
			model.encoder.model.encoders0.register_forward_pre_hook(
			functools.partial(_rescale_input_hook, scale=fp16_scale),
			)
			for name, m in model.encoder.model.named_modules():
			if name.endswith("self_attn"):
			m.register_forward_hook(
			functools.partial(_rescale_output_hook, scale=fp16_scale)
			)
			if name.endswith("feed_forward.w_2"):
			state_dict = {k: v / fp16_scale for k, v in m.state_dict().items()}
			m.load_state_dict(state_dict)


			def _bladedisc_opt_for_encdec(model, path, enable_fp16):
			# Get input data
			# TODO: better to use real data
			input_data = model.export_dummy_inputs()
			if isinstance(input_data, torch.Tensor):
			input_data = input_data.cuda()
			else:
			input_data = tuple([i.cuda() for i in input_data])

			# Get input data for decoder module
			decoder_inputs = list()

			def get_input_hook(m, x):
			decoder_inputs.extend(list(x))

			hook = model.decoder.register_forward_pre_hook(get_input_hook)
			model = model.cuda()
			model(*input_data)
			hook.remove()

			# Prevent FP16 overflow
			if enable_fp16:
			_rescale_encoder_model(model, input_data)

			# Export and optimize encoder/decoder modules
			model.encoder = _bladedisc_opt(model.encoder, input_data[:2])
			model.decoder = _bladedisc_opt(model.decoder, tuple(decoder_inputs))
			model_script = torch.jit.trace(model, input_data)
			model_script.save(os.path.join(path, f"{model.export_name}_blade.torchscripts"))