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gpt2_helper.py
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gpt2_helper.py
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# -------------------------------------------------------------------------
# Copyright (c) Microsoft Corporation. All rights reserved.
# Licensed under the MIT License. See License.txt in the project root for
# license information.
# --------------------------------------------------------------------------
# This script helps onnx conversion and validation for GPT2 model with past state.
import os
import logging
import torch
import shutil
import random
import numpy
import time
import re
import pickle
from pathlib import Path
from typing import List, Dict, Tuple, Union
from transformers import GPT2Model, GPT2LMHeadModel, GPT2Config, TFGPT2Model
from benchmark_helper import Precision
logger = logging.getLogger(__name__)
PRETRAINED_GPT2_MODELS = ['distilgpt2', 'gpt2', 'gpt2-medium', 'gpt2-large', 'gpt2-xl']
DEFAULT_TOLERANCE = {Precision.FLOAT32: 0.0005, Precision.FLOAT16: 0.2, Precision.INT8: 3.0}
class GPT2ModelNoPastState(GPT2Model):
""" Here we wrap a class to disable past state output.
"""
def __init__(self, config):
super().__init__(config)
def forward(self, input_ids):
return super().forward(input_ids, use_cache=False, return_dict=False)
class TFGPT2ModelNoPastState(TFGPT2Model):
""" Here we wrap a class to disable past state output.
"""
def __init__(self, config):
config.use_cache = False
super().__init__(config)
def forward(self, input_ids):
return super().call(input_ids, use_cache=False)
class MyGPT2Model(GPT2Model):
""" Here we wrap a class for Onnx model conversion for GPT2Model with past state.
"""
def __init__(self, config):
super().__init__(config)
@staticmethod
def post_process(result, num_layer):
if isinstance(result[1][0], tuple) or isinstance(result[1][0], list):
assert len(result[1]) == num_layer and len(result[1][0]) == 2
#assert len(result[1][0][0].shape) == 4 and result[1][0][0].shape == result[1][0][1].shape
present = []
for i in range(num_layer):
# Since transformers v4.*, past key and values are separated outputs.
# Here we concate them into one tensor to be compatible with Attention operator.
present.append(torch.cat((result[1][i][0].unsqueeze(0), result[1][i][1].unsqueeze(0)), dim=0))
return (result[0], tuple(present))
return result
def forward(self, input_ids, position_ids, attention_mask, *past):
result = super().forward(input_ids,
position_ids=position_ids,
attention_mask=attention_mask,
past_key_values=past,
return_dict=False)
return MyGPT2Model.post_process(result, self.config.n_layer)
class MyGPT2LMHeadModel(GPT2LMHeadModel):
""" Here we wrap a class for Onnx model conversion for GPT2LMHeadModel with past state.
"""
def __init__(self, config):
super().__init__(config)
def forward(self, input_ids, position_ids, attention_mask, *past):
result = super().forward(input_ids,
position_ids=position_ids,
attention_mask=attention_mask,
past_key_values=past,
return_dict=False)
return MyGPT2Model.post_process(result, self.config.n_layer)
class MyGPT2LMHeadModel_NoPadding(GPT2LMHeadModel):
""" Here we wrap a class for Onnx model conversion for GPT2LMHeadModel with past state and no padding.
When you always use batch_size=1 in inference, there is no padding in inputs. In such case, position_ids
and attention_mask need no be in inputs.
"""
def __init__(self, config):
super().__init__(config)
def forward(self, input_ids, *past):
result = super().forward(input_ids, past_key_values=past, return_dict=False)
return MyGPT2Model.post_process(result, self.config.n_layer)
# Maps model class name to a tuple of model class, name of first output and use padding or not
MODEL_CLASSES = {
'GPT2LMHeadModel': (MyGPT2LMHeadModel, 'logits', True),
'GPT2LMHeadModel_NoPadding': (MyGPT2LMHeadModel_NoPadding, 'logits', False),
'GPT2Model': (MyGPT2Model, 'last_state', True),
}
class Gpt2Inputs:
def __init__(self, input_ids, position_ids, attention_mask, past):
self.input_ids: torch.LongTensor = input_ids
self.position_ids: torch.LongTensor = position_ids
self.attention_mask: Union[torch.FloatTensor, torch.HalfTensor] = attention_mask
self.past: Union[List[torch.FloatTensor], List[torch.HalfTensor]] = past
def to_list(self) -> List:
input_list = [v for v in [self.input_ids, self.position_ids, self.attention_mask] if v is not None]
if self.past:
input_list.extend(self.past)
return input_list
def to_tuple(self) -> Tuple:
return tuple(v for v in [self.input_ids, self.position_ids, self.attention_mask, self.past] if v is not None)
def to_fp32(self):
attention_mask = self.attention_mask.to(dtype=torch.float32) if self.attention_mask is not None else None
past = [p.to(dtype=torch.float32) for p in self.past]
return Gpt2Inputs(self.input_ids, self.position_ids, attention_mask, past)
class Gpt2Helper:
""" A helper class for Gpt2 model conversion, inference and verification.
"""
@staticmethod
def get_dummy_inputs(batch_size: int,
past_sequence_length: int,
sequence_length: int,
num_attention_heads: int,
hidden_size: int,
num_layer: int,
vocab_size: int,
device: torch.device,
float16: bool = False,
has_position_ids: bool = True,
has_attention_mask: bool = True) -> Gpt2Inputs:
""" Create random inputs for GPT2 model.
Returns torch tensors of input_ids, position_ids, attention_mask and a list of past state tensors.
"""
float_type = torch.float16 if float16 else torch.float32
past_shape = [2, batch_size, num_attention_heads, past_sequence_length, int(hidden_size / num_attention_heads)]
past = [(torch.rand(past_shape, dtype=float_type, device=device) * 2.0 - 1.0) for _ in range(num_layer)]
input_ids = torch.randint(low=0,
high=vocab_size - 1,
size=(batch_size, sequence_length),
dtype=torch.int64,
device=device)
attention_mask = None
if has_attention_mask:
total_sequence_length = past_sequence_length + sequence_length
attention_mask = torch.ones([batch_size, total_sequence_length], dtype=float_type, device=device)
if total_sequence_length >= 2:
padding_position = random.randint(0, total_sequence_length - 1) # test input with padding.
attention_mask[:, padding_position] = 0
# Deduce position_ids from attention mask
position_ids = None
if has_position_ids:
position_ids = (attention_mask.long().cumsum(-1) - 1)
position_ids.masked_fill_(position_ids < 0, 0)
position_ids = position_ids[:, past_sequence_length:]
return Gpt2Inputs(input_ids, position_ids, attention_mask, past)
@staticmethod
def get_output_shapes(batch_size: int,
past_sequence_length: int,
sequence_length: int,
config: GPT2Config,
model_class: str = "GPT2LMHeadModel") -> Dict[str, List[int]]:
""" Returns a dictionary with output name as key, and shape as value.
"""
num_attention_heads = config.num_attention_heads
hidden_size = config.hidden_size
num_layer = config.num_hidden_layers
vocab_size = config.vocab_size
output_name = MODEL_CLASSES[model_class][1]
last_state_shape = [batch_size, sequence_length, vocab_size if output_name == "logits" else hidden_size]
present_state_shape = [
2, batch_size, num_attention_heads, past_sequence_length + sequence_length,
int(hidden_size / num_attention_heads)
]
output_shapes = {output_name: last_state_shape}
for i in range(num_layer):
output_shapes["present_" + str(i)] = present_state_shape
return output_shapes
@staticmethod
def auto_increase_buffer_size(output_buffers, output_shapes):
for key in output_shapes:
assert key in output_buffers
buffer = output_buffers[key]
if numpy.prod(output_shapes[key]) > buffer.nelement():
output_buffers[key] = torch.empty(numpy.prod(output_shapes[key]),
dtype=buffer.dtype,
device=buffer.device)
@staticmethod
def get_output_buffers(output_shapes, device, is_float16=False):
""" Returns a dictionary of output name as key, and 1D tensor as value. The tensor has enough space for given shape.
"""
data_type = torch.float16 if is_float16 else torch.float32
output_buffers = {}
for name, shape in output_shapes.items():
output_buffers[name] = torch.empty(numpy.prod(shape), dtype=data_type, device=device)
return output_buffers
@staticmethod
def diff_outputs(torch_outputs, ort_outputs, relative=False):
""" Returns the maximum difference between PyTorch and OnnxRuntime outputs.
"""
expected_outputs = torch_outputs[0].cpu().numpy()
diff = numpy.abs(expected_outputs - ort_outputs[0])
if relative:
return numpy.amax(diff / (numpy.abs(expected_outputs) + 1e-6))
else:
return numpy.amax(diff)
@staticmethod
def compare_outputs(torch_outputs, ort_outputs, rtol=1e-03, atol=1e-03):
""" Returns True if torch and ORT outputs are close for given thresholds, and False otherwise.
"""
is_close = numpy.allclose(ort_outputs[0], torch_outputs[0].cpu().numpy(), rtol=rtol, atol=atol)
logger.debug(f'PyTorch and OnnxRuntime output 0 (last_state) are close: {is_close}')
is_all_close = is_close
num_layers = len(ort_outputs) - 1
for layer in range(num_layers):
is_close = numpy.allclose(ort_outputs[1 + layer],
torch_outputs[1][layer].cpu().numpy(),
rtol=rtol,
atol=atol)
logger.debug(f'PyTorch and OnnxRuntime layer {layer} state (present_{layer}) are close:{is_close}')
is_all_close = is_all_close and is_close
if not is_all_close:
max_abs_diff = Gpt2Helper.diff_outputs(torch_outputs, ort_outputs)
logger.info(f'PyTorch and OnnxRuntime results are not all close: max_abs_diff={max_abs_diff:.5f}')
return is_all_close
@staticmethod
def compare_outputs_v2(torch_outputs, ort_outputs, atol=1e-06):
"""Compare outputs from PyTorch and OnnxRuntime
Args:
torch_outputs (Tuple[Torch.Tensor]): PyTorch model output
ort_outputs (List[numpy.ndarray]): OnnxRuntime output
atol (float, optional): Absolute tollerance. Defaults to 1e-06.
Returns:
is_all_close(bool): whether all elements are close.
max_abs_diff(float): maximum absolute difference.
messages(str): a list of debug message for each output
"""
is_all_close = True
is_top1_matched = False
max_diffs = []
messages = []
for i in range(len(ort_outputs)):
ort_output = ort_outputs[i]
torch_output = (torch_outputs[0] if i == 0 else torch_outputs[1][i - 1]).cpu().numpy()
is_close = numpy.allclose(ort_output, torch_output, atol=atol, rtol=0)
max_diffs.append(numpy.amax(numpy.abs(torch_output - ort_output)))
is_all_close = is_all_close and is_close
if numpy.isnan(torch_output).any():
logger.debug(f'PyTorch output {i} has nan')
if numpy.isinf(torch_output).any():
logger.debug(f'PyTorch output {i} has inf')
if numpy.isnan(ort_output).any():
logger.debug(f'ORT output {i} has nan')
if numpy.isinf(ort_output).any():
logger.debug(f'ORT output {i} has inf')
diff = numpy.fabs(ort_output - torch_output)
idx = numpy.unravel_index(diff.argmax(), diff.shape)
messages.append(
f'diff={diff[idx]:.9f} index={idx} ort={ort_output[idx]:.9f} torch={float(torch_output[idx]):.9f}')
if i == 0: # logits
ort_max_index = numpy.unravel_index(numpy.argmax(ort_output, axis=None), ort_output.shape)
torch_max_index = numpy.unravel_index(numpy.argmax(torch_output, axis=None), torch_output.shape)
is_top1_matched = numpy.array_equal(ort_max_index, torch_max_index)
max_diff_output_index = max_diffs.index(max(max_diffs))
return is_all_close, max(max_diffs), max_diff_output_index, messages, is_top1_matched
@staticmethod
def export_onnx(model,
device,
onnx_model_path: str,
verbose: bool = False,
use_external_data_format: bool = False,
has_position_ids: bool = True,
has_attention_mask: bool = True):
""" Export GPT-2 model with past state to ONNX model.
"""
config: GPT2Config = model.config
num_layer = config.n_layer
dummy_inputs = Gpt2Helper.get_dummy_inputs(batch_size=1,
past_sequence_length=1,
sequence_length=1,
num_attention_heads=config.num_attention_heads,
hidden_size=config.hidden_size,
num_layer=num_layer,
vocab_size=config.vocab_size,
device=device,
float16=False,
has_position_ids=has_position_ids,
has_attention_mask=has_attention_mask)
input_list = dummy_inputs.to_list()
with torch.no_grad():
outputs = model(*input_list)
past_names = [f'past_{i}' for i in range(num_layer)]
present_names = [f'present_{i}' for i in range(num_layer)]
# GPT2Model outputs last_state; GPT2LMHeadModel outputs logits (prediction_scores)
assert outputs[0].shape[2] == config.vocab_size or outputs[0].shape[2] == config.hidden_size
output_names = ["logits" if outputs[0].shape[2] == config.vocab_size else "last_state"] + present_names
# Shape of input tensors:
# input_ids: (batch_size, seq_len)
# past_{i}: (2, batch_size, num_heads, past_seq_len, hidden_size/num_heads)
# attention_mask: (batch_size, past_seq_len + seq_len)
# Shape of output tensors:
# last_state: (batch_size, seq_len, hidden_size)
# or logits: (batch_size, seq_len, vocab_size)
# present_{i}: (2, batch_size, num_heads, past_seq_len + seq_len, hidden_size/num_heads)
dynamic_axes = {'input_ids': {0: 'batch_size', 1: 'seq_len'}, output_names[0]: {0: 'batch_size', 1: 'seq_len'}}
for name in past_names:
dynamic_axes[name] = {1: 'batch_size', 3: 'past_seq_len'}
for name in present_names:
dynamic_axes[name] = {1: 'batch_size', 3: 'total_seq_len'}
input_names = ['input_ids']
if has_position_ids:
dynamic_axes['position_ids'] = {0: 'batch_size', 1: 'seq_len'}
input_names.append('position_ids')
if has_attention_mask:
dynamic_axes['attention_mask'] = {0: 'batch_size', 1: 'total_seq_len'}
input_names.append('attention_mask')
input_names.extend(past_names)
assert len(outputs) == 2 and len(outputs[1]) == num_layer
logger.info(
f"Shapes: input_ids={dummy_inputs.input_ids.shape} past={dummy_inputs.past[0].shape} output={outputs[0].shape} present={outputs[1][0].shape}"
)
Path(onnx_model_path).parent.mkdir(parents=True, exist_ok=True)
torch.onnx.export(model,
args=tuple(input_list),
f=onnx_model_path,
input_names=input_names,
output_names=output_names,
example_outputs=outputs,
dynamic_axes=dynamic_axes,
opset_version=11,
do_constant_folding=True,
use_external_data_format=use_external_data_format,
verbose=verbose)
@staticmethod
def optimize_onnx(onnx_model_path,
optimized_model_path,
is_float16,
num_attention_heads,
hidden_size,
use_external_data_format=False,
**kwargs):
""" Optimize ONNX model with an option to convert it to use mixed precision.
"""
from optimizer import optimize_model
from fusion_options import FusionOptions
optimization_options = FusionOptions('gpt2')
#optimization_options.enable_gelu = False
#optimization_options.enable_layer_norm = False
#optimization_options.enable_attention = False
m = optimize_model(onnx_model_path,
model_type='gpt2',
num_heads=num_attention_heads,
hidden_size=hidden_size,
opt_level=0,
optimization_options=optimization_options,
use_gpu=False)
if is_float16:
op_full_list = set([node.op_type for node in m.nodes()])
op_block_list = set(kwargs["op_block_list"]) if "op_block_list" in kwargs else set()
op_remain_list = op_full_list.difference(op_block_list)
logger.info(f"op_block_list={op_block_list} op_remain_list={op_remain_list}")
m.convert_float_to_float16(use_symbolic_shape_infer=True, **kwargs)
m.save_model_to_file(optimized_model_path, use_external_data_format)
@staticmethod
def pytorch_inference(model, inputs: Gpt2Inputs, total_runs: int = 0):
""" Run inference of PyTorch model, and returns average latency in ms when total_runs > 0 besides outputs.
"""
logger.debug("start pytorch_inference")
# Convert it to fp32 as the PyTroch model cannot deal with half input.
input_list = inputs.to_fp32().to_list()
with torch.no_grad():
outputs = model(*input_list)
if total_runs == 0:
return outputs
latency = []
with torch.no_grad():
for _ in range(total_runs):
start = time.time()
outputs = model(*input_list)
latency.append(time.time() - start)
average_latency = sum(latency) * 1000 / len(latency)
logger.debug("PyTorch inference time = {} ms".format(format(average_latency, '.2f')))
return outputs, average_latency
@staticmethod
def onnxruntime_inference(ort_session, inputs: Gpt2Inputs, total_runs: int = 0):
""" Run inference of ONNX model, and returns average latency in ms when total_runs > 0 besides outputs.
"""
logger.debug(f"start onnxruntime_inference")
ort_inputs = {'input_ids': numpy.ascontiguousarray(inputs.input_ids.cpu().numpy())}
if inputs.past is not None:
for i, past_i in enumerate(inputs.past):
ort_inputs[f'past_{i}'] = numpy.ascontiguousarray(past_i.cpu().numpy())
if inputs.attention_mask is not None:
ort_inputs['attention_mask'] = numpy.ascontiguousarray(inputs.attention_mask.cpu().numpy())
if inputs.position_ids is not None:
ort_inputs['position_ids'] = numpy.ascontiguousarray(inputs.position_ids.cpu().numpy())
ort_outputs = ort_session.run(None, ort_inputs)
if total_runs == 0:
return ort_outputs
latency = []
for _ in range(total_runs):
start = time.time()
ort_outputs = ort_session.run(None, ort_inputs)
latency.append(time.time() - start)
average_latency = sum(latency) * 1000 / len(latency)
logger.debug("OnnxRuntime Inference time = {} ms".format(format(average_latency, '.2f')))
return ort_outputs, average_latency
@staticmethod
def prepare_io_binding(ort_session, input_ids, position_ids, attention_mask, past, output_buffers, output_shapes):
""" Returnas IO binding object for a session.
"""
# Bind inputs and outputs to onnxruntime session
io_binding = ort_session.io_binding()
# Bind inputs
assert input_ids.is_contiguous()
io_binding.bind_input('input_ids', input_ids.device.type, 0, numpy.longlong, list(input_ids.size()),
input_ids.data_ptr())
data_type = output_buffers[ort_session.get_outputs()[0].name].dtype
float_type = numpy.float16 if data_type == torch.float16 else numpy.float32
if past is not None:
for i, past_i in enumerate(past):
assert past_i.is_contiguous()
data_ptr = past_i.data_ptr()
if data_ptr == 0:
# When past_sequence_length is 0, its data_ptr will be zero. IO Binding asserts that data_ptr shall not be zero.
# Here we workaround and pass data pointer of input_ids. Actual data is not used for past so it does not matter.
data_ptr = input_ids.data_ptr()
io_binding.bind_input(f'past_{i}', past_i.device.type, 0, float_type, list(past_i.size()), data_ptr)
if attention_mask is not None:
assert attention_mask.is_contiguous()
io_binding.bind_input('attention_mask', attention_mask.device.type, 0, float_type,
list(attention_mask.size()), attention_mask.data_ptr())
if position_ids is not None:
assert position_ids.is_contiguous()
io_binding.bind_input('position_ids', position_ids.device.type, 0, numpy.longlong,
list(position_ids.size()), position_ids.data_ptr())
# Bind outputs
for output in ort_session.get_outputs():
output_name = output.name
output_buffer = output_buffers[output_name]
logger.debug(f"{output_name} device type={output_buffer.device.type} shape={list(output_buffer.size())}")
io_binding.bind_output(output_name, output_buffer.device.type, 0, float_type, output_shapes[output_name],
output_buffer.data_ptr())
return io_binding
@staticmethod
def get_outputs_from_io_binding_buffer(ort_session, output_buffers, output_shapes, return_numpy=True):
""" Copy results to cpu. Returns a list of numpy array.
"""
ort_outputs = []
for output in ort_session.get_outputs():
output_name = output.name
buffer = output_buffers[output_name]
shape = output_shapes[output_name]
copy_tensor = buffer[0:numpy.prod(shape)].reshape(shape).clone().detach()
if return_numpy:
ort_outputs.append(copy_tensor.cpu().numpy())
else:
ort_outputs.append(copy_tensor)
return ort_outputs
@staticmethod
def onnxruntime_inference_with_binded_io(ort_session,
inputs: Gpt2Inputs,
output_buffers: Dict[str, torch.Tensor],
output_shapes: Dict[str, List[int]],
total_runs: int = 0,
return_numpy: bool = True,
include_copy_output_latency: bool = False):
""" Inference with IO binding. Returns outputs, and optional latency when total_runs > 0.
"""
logger.debug(f"start onnxruntime_inference_with_binded_io")
# Bind inputs and outputs to onnxruntime session
io_binding = Gpt2Helper.prepare_io_binding(ort_session, inputs.input_ids, inputs.position_ids,
inputs.attention_mask, inputs.past, output_buffers, output_shapes)
# Run onnxruntime with io binding
ort_session.run_with_iobinding(io_binding)
# Copy results to cpu for verification
ort_outputs = Gpt2Helper.get_outputs_from_io_binding_buffer(ort_session, output_buffers, output_shapes,
return_numpy)
if total_runs == 0:
return ort_outputs
latency = []
for _ in range(total_runs):
start = time.time()
# Run onnxruntime with io binding
ort_session.run_with_iobinding(io_binding)
if include_copy_output_latency:
_ = Gpt2Helper.get_outputs_from_io_binding_buffer(ort_session, output_buffers, output_shapes,
return_numpy)
latency.append(time.time() - start)
average_latency = sum(latency) * 1000 / len(latency)
logger.debug("OnnxRuntime with IO binding inference time = {} ms".format(format(average_latency, '.2f')))
return ort_outputs, average_latency
@staticmethod
def save_outputs(i, ort_outputs, torch_outputs):
with open(f'ort_outputs_{i}.pickle', 'wb') as f:
pickle.dump(ort_outputs, f)
logger.info(f"ORT output are saved to ort_outputs_{i}.pickle")
with open(f'torch_outputs_{i}.pickle', 'wb') as f:
pickle.dump(torch_outputs, f)
logger.info(f"Torch output are saved to torch_outputs_{i}.pickle")
@staticmethod
def save_inputs(i, dummy_inputs, ort_outputs, torch_outputs):
with open(f'dummy_inputs_{i}.pickle', 'wb') as f:
pickle.dump(dummy_inputs, f)
logger.info(f"inputs are saved to dummy_inputs_{i}.pickle")
@staticmethod
def test_parity(ort_session,
model,
device,
is_float16=False,
rtol=5e-4,
atol=5e-4,
test_cases_per_run=10000,
total_runs=1,
use_io_binding=True,
model_class="GPT2LMHeadModel",
has_position_ids=True,
has_attention_mask=True,
verbose=False,
enable_pickle_output=False):
""" Generate random inputs and compare the results of PyTorch and Onnx Runtime.
"""
config: GPT2Config = model.config
logger.info(
f"Running parity test (atol={atol}, test_cases={test_cases_per_run}, runs={total_runs}, use_io_binding={use_io_binding}, model_class={model_class}, is_float16={is_float16}) ..."
)
max_batch_size = 8
max_past_seq_len = 4 # Do not use large number here for higher chance of hitting empty past (past_seq_len=0)
max_seq_len = 2
output_buffers = None
if use_io_binding:
max_output_shapes = Gpt2Helper.get_output_shapes(max_batch_size, max_past_seq_len, max_seq_len, config,
model_class)
output_buffers = Gpt2Helper.get_output_buffers(max_output_shapes, device, is_float16)
passed_test_cases = 0
top1_matched_cases = 0
max_abs_diff_list = []
top1_matched_cases_per_run = [0] * total_runs
total_test_cases = test_cases_per_run * total_runs
for i in range(total_test_cases):
run_id = int(i / test_cases_per_run)
sequence_length = random.randint(1, max_seq_len)
past_sequence_length = random.randint(0, max_past_seq_len)
batch_size = random.randint(1, max_batch_size)
logger.debug(
f"Running parity test for batch_size={batch_size} past_sequence_length={past_sequence_length}...")
dummy_inputs = Gpt2Helper.get_dummy_inputs(batch_size, past_sequence_length, sequence_length,
config.num_attention_heads, config.hidden_size, config.n_layer,
config.vocab_size, device, is_float16, has_position_ids,
has_attention_mask)
outputs = Gpt2Helper.pytorch_inference(model, dummy_inputs)
if use_io_binding:
ort_outputs = Gpt2Helper.onnxruntime_inference(ort_session, dummy_inputs)
else:
output_shapes = Gpt2Helper.get_output_shapes(batch_size, past_sequence_length, sequence_length, config,
model_class)
ort_outputs = Gpt2Helper.onnxruntime_inference_with_binded_io(ort_session, dummy_inputs, output_buffers,
output_shapes)
is_all_close, max_abs_diff, max_diff_output_index, messages, is_top1_matched = Gpt2Helper.compare_outputs_v2(
outputs, ort_outputs, atol=atol)
if not numpy.isnan(max_abs_diff):
max_abs_diff_list.append(max_abs_diff)
if is_all_close:
passed_test_cases += 1
if is_top1_matched:
top1_matched_cases += 1
top1_matched_cases_per_run[run_id] += 1
if verbose and not is_all_close:
logger.info(
f"test_case={i} batch_size={batch_size} past_sequence_length={past_sequence_length} sequence_length={sequence_length} MaxDiff={max_abs_diff}"
)
for i, message in enumerate(messages):
logger.info(f"\t{i}: Name={ort_session.get_outputs()[i].name}, {message}")
# Collect data for debugging
if enable_pickle_output and (numpy.isnan(max_abs_diff) or max_abs_diff > 100 * atol):
Gpt2Helper.save_inputs(i, dummy_inputs)
Gpt2Helper.save_outputs(i, ort_outputs, outputs)
if max_abs_diff_list:
result = {
f"max_diff_percentile_{p}": "{:.5f}".format(numpy.percentile(max_abs_diff_list, p))
for p in [50, 90, 95, 99]
}
else:
result = {f"max_diff_percentile_{p}": "nan" for p in [50, 90, 95, 99]}
result["top1_match_rate"] = top1_matched_cases * 1.0 / total_test_cases
result["top1_match_rate_per_run"] = [x * 1.0 / test_cases_per_run for x in top1_matched_cases_per_run]
result["diff_pass_rate"] = passed_test_cases * 1.0 / total_test_cases
result["nan_rate"] = (total_test_cases - len(max_abs_diff_list)) * 1.0 / total_test_cases
logger.info(
f"Parity Test Cases={total_test_cases}; Passed={passed_test_cases}; Nan={total_test_cases-len(max_abs_diff_list)}; Top1_Matched={top1_matched_cases}"
)
if passed_test_cases > 0.95 * total_test_cases:
logger.info(f"Parity is good: passed rate={int(passed_test_cases*100/total_test_cases):.0f}%")
return result
@staticmethod
def test_performance(ort_session,
model,
device,
is_float16=False,
total_runs=100,
use_io_binding=True,
model_class="GPT2LMHeadModel",
has_position_ids=True,
has_attention_mask=True,
batch_size=8,
sequence_length=1,
past_sequence_length=32):
""" Generate random inputs and measure average latency of Onnx Runtime.
"""
config: GPT2Config = model.config
output_buffers = None
if use_io_binding:
output_shapes = Gpt2Helper.get_output_shapes(batch_size, past_sequence_length, sequence_length, config,
model_class)
output_buffers = Gpt2Helper.get_output_buffers(output_shapes, device, is_float16)
dummy_inputs = Gpt2Helper.get_dummy_inputs(batch_size, past_sequence_length, sequence_length,
config.num_attention_heads, config.hidden_size, config.n_layer,
config.vocab_size, device, is_float16, has_position_ids,
has_attention_mask)
if use_io_binding:
_, latency = Gpt2Helper.onnxruntime_inference(ort_session, dummy_inputs, total_runs)
else:
_, latency = Gpt2Helper.onnxruntime_inference_with_binded_io(ort_session, dummy_inputs, output_buffers,
output_shapes, total_runs)
return latency
@staticmethod
def torchscript(model, config, device, has_position_ids=True, has_attention_mask=True):
""" JIT trace for TorchScript.
"""
input_list = Gpt2Helper.get_dummy_inputs(batch_size=1,
past_sequence_length=1,
sequence_length=1,
num_attention_heads=config.num_attention_heads,
hidden_size=config.hidden_size,
num_layer=config.n_layer,
vocab_size=config.vocab_size,
device=device,
float16=False,
has_position_ids=has_position_ids,
has_attention_mask=has_attention_mask).to_list()
return torch.jit.trace(model, input_list)
@staticmethod
def get_onnx_paths(output_dir,
model_name_or_path,
model_class: str = 'GPT2LMHeadModel',
has_past=True,
new_folder=False,
remove_existing=["raw", "fp32", "fp16", "int8"]):
""" Build a path name for given model based on given attributes.
"""
model_name = model_name_or_path
if not re.match(r'^[\w_-]+$', model_name_or_path): # It is not a name, shall be a path
assert os.path.isdir(model_name_or_path)
model_name = Path(model_name_or_path).parts[-1]
if model_class != 'GPT2LMHeadModel':
model_name += "_" + model_class
if has_past:
model_name += "_past"
if new_folder:
suffix = {"raw": "", "fp32": "_fp32", "fp16": "_fp16", "int8": "_int8"}
# Remove the directories if existed.
for model_type in ["raw", "fp32", "fp16", "int8"]:
new_dir = os.path.join(output_dir, model_name + suffix[model_type])
if os.path.exists(new_dir):
if (model_type in remove_existing):
try:
shutil.rmtree(new_dir)
logger.info(f"Removed the existed directory: {new_dir}")
except OSError as e:
logger.info(f"Failed to remove the directory {new_dir}: {e.strerror}")
else:
logger.info(f"Directory for {model_type} existed: {new_dir}")
# store each model to its own directory (for external data format).
return {
"raw": os.path.join(os.path.join(output_dir, model_name), model_name + ".onnx"),
"fp32": os.path.join(os.path.join(output_dir, model_name + "_fp32"), model_name + "_fp32.onnx"),
"fp16": os.path.join(os.path.join(output_dir, model_name + "_fp16"), model_name + "_fp16.onnx"),
"int8": os.path.join(os.path.join(output_dir, model_name + "_int8"), model_name + "_int8.onnx")
}
return {
"raw": os.path.join(output_dir, model_name + ".onnx"),
"fp32": os.path.join(output_dir, model_name + "_fp32.onnx"),
"fp16": os.path.join(output_dir, model_name + "_fp16.onnx"),
"int8": os.path.join(output_dir, model_name + "_int8.onnx")
}