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onnx_model_bert_tf.py
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onnx_model_bert_tf.py
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#-------------------------------------------------------------------------
# Copyright (c) Microsoft Corporation. All rights reserved.
# Licensed under the MIT License.
#--------------------------------------------------------------------------
import logging
import onnx
import sys
import argparse
import numpy as np
from collections import deque
from onnx import ModelProto, TensorProto, numpy_helper, helper
from onnx_model_bert import BertOnnxModel
logger = logging.getLogger(__name__)
class BertOnnxModelTF(BertOnnxModel):
def __init__(self, model, num_heads, hidden_size):
super().__init__(model, num_heads, hidden_size)
def remove_identity(self):
nodes_to_remove = []
for node in self.nodes():
if node.op_type == 'Identity':
if not self.find_graph_output(node.output[0]):
self.replace_input_of_all_nodes(node.output[0], node.input[0])
nodes_to_remove.append(node)
self.remove_nodes(nodes_to_remove)
logger.info(f"Removed Identity count: {len(nodes_to_remove)}")
def match_mask_path(self, add_or_sub_before_softmax):
mask_nodes = self.match_parent_path(add_or_sub_before_softmax, ['Mul', 'Sub', 'Reshape', 'Cast'],
[1, None, 1, 0])
if mask_nodes is not None:
return mask_nodes
mask_nodes = self.match_parent_path(add_or_sub_before_softmax, ['Mul', 'Sub', 'Cast', 'Slice', 'Unsqueeze'],
[1, 0, 1, 0, 0])
if mask_nodes is not None:
return mask_nodes
mask_nodes = self.match_parent_path(add_or_sub_before_softmax, ['Mul', 'Sub', 'Cast', 'Unsqueeze', 'Unsqueeze'],
[1, None, 1, 0, 0])
return mask_nodes
def get_2d_initializers_from_parent_subgraphs(self, current_node):
"""
Find initializers that is 2D. Returns a dictionary with name as key and shape as value.
"""
parent_nodes = self.get_parent_subgraph_nodes(current_node, [])
initializers = {}
for node in parent_nodes:
for input in node.input:
initializer = self.get_initializer(input)
if initializer:
temp = numpy_helper.to_array(initializer)
if len(temp.shape) == 2:
initializers[initializer.name] = temp.shape
return initializers
def find_segment_ids(self, segment_embedding, input_ids):
input_name_to_nodes = self.input_name_to_nodes()
if segment_embedding not in input_name_to_nodes:
return None
nodes = input_name_to_nodes[segment_embedding]
if len(nodes) != 1:
return None
graph_inputs = self.get_graph_inputs(nodes[0], recursive=True)
if len(graph_inputs) > 1:
print("Found multiple candidates of segment_ids", graph_inputs)
return None
# Find segment ids in graph inputs. The segment id input must not be the same as input_ids.
if len(graph_inputs) == 1 and graph_inputs[0] != input_ids:
return graph_inputs[0]
# If the segment id candidate is the same as the input_ids, try to assign alternative segment ids and simplify the graph if needed.
segment_ids = nodes[0].input[1]
_, segment_id_path, _ = self.match_parent_paths(
nodes[0], [(["ConstantOfShape", "Cast", "Concat", "Slice", "Cast", "Shape"], [1, 0, 0, 0, 0, 0]),
(["ConstantOfShape", "Cast", "Concat", "Unsqueeze", "Squeeze", "Slice", "Cast", "Shape"
], [1, 0, 0, 0, 0, 0, 0, 0])], None)
if segment_id_path and input_ids and input_ids == segment_id_path[-1].input[0]:
logger.debug("Simplify semgent id path...")
constantofshape_node = segment_id_path[0]
graph_name = self.get_graph_by_node(constantofshape_node).name
self.add_node(helper.make_node('Shape', inputs=[input_ids], outputs=["input_shape"]), graph_name)
constantofshape_value = helper.get_attribute_value(constantofshape_node.attribute[0])
self.add_node(
helper.make_node('ConstantOfShape',
inputs=["input_shape"],
outputs=["zeros_for_input_shape"],
value=constantofshape_value), graph_name)
segment_ids = "zeros_for_input_shape"
return segment_ids
def find_input_ids(self, word_embedding):
input_name_to_nodes = self.input_name_to_nodes()
if word_embedding not in input_name_to_nodes:
return None
nodes = input_name_to_nodes[word_embedding]
if len(nodes) != 1:
return None
graph_inputs = self.get_graph_inputs(nodes[0], recursive=True)
if len(graph_inputs) == 1:
return graph_inputs[0]
print("Found multiple candidates of input_ids", graph_inputs)
return None
def find_mask_input(self, excluded_graph_inputs):
for node in self.nodes():
if node.op_type == 'Softmax':
mask_path = self.match_parent_path(node, ['Add', 'Mul', 'Sub', 'Cast', 'Slice', 'Unsqueeze'],
[0, 1, None, 1, 0, 0])
if mask_path is None:
continue
add_node, mul_node, sub_node, cast_node, slice_node, unsqueeze_node = mask_path
if self.has_constant_input(mul_node, -10000) and self.has_constant_input(sub_node, 1):
graph_inputs = self.get_graph_inputs(sub_node, recursive=True)
inputs = [input for input in graph_inputs if input not in excluded_graph_inputs]
if len(inputs) > 1:
print("Found multiple candidates of mask input", inputs)
return None
if len(inputs) == 1:
return inputs[0]
# Duplicated input found. Try to simplify the graph.
path_to_be_simplified = self.match_parent_path(
mask_path[-1],
["ConstantOfShape", "Cast", "Concat", "Unsqueeze", "Squeeze", "Slice", "Cast", "Shape"],
[0, 0, 0, 0, 0, 0, 0, 0])
duplicated_inputs = [input for input in graph_inputs if input in excluded_graph_inputs]
# Simplify graph for dynamic axes.
if path_to_be_simplified and duplicated_inputs and len(
duplicated_inputs) == 1 and duplicated_inputs[0] == path_to_be_simplified[-1].input[0]:
logger.debug("Simplify semgent id path...")
constantofshape_node = path_to_be_simplified[0]
constantofshape_value = helper.get_attribute_value(constantofshape_node.attribute[0])
graph_name = self.get_graph_by_node(constantofshape_node).name
self.add_node(
helper.make_node('Shape', inputs=[duplicated_inputs[0]], outputs=["input_shape_for_mask"]),
graph_name)
self.add_node(
helper.make_node('ConstantOfShape',
inputs=["input_shape_for_mask"],
outputs=[unsqueeze_node.input[0]],
value=constantofshape_value), graph_name)
return unsqueeze_node.input[0]
return None
def create_embedding_subgraph(self, normalize_node, word_embedding, segment_embedding, position_embedding):
input_ids = self.find_input_ids(word_embedding)
if input_ids is None:
logger.info("Failed to find input_ids. Cannot fuse embedding layer.")
return False
segment_ids = self.find_segment_ids(segment_embedding, input_ids)
if segment_ids is None:
logger.info("Failed to find segment_ids. Cannot fuse embedding layer.")
return False
mask_input = self.find_mask_input([segment_ids, input_ids])
if mask_input is None:
logger.info("Failed to find input_mask. Cannot fuse embedding layer.")
return False
self.bert_inputs = [input_ids, segment_ids, mask_input]
mask_index = self.create_node_name('mask_index')
self.attention_mask.set_mask_indice(mask_input, mask_index)
if self.find_graph_input(input_ids).type.tensor_type.elem_type != TensorProto.INT32:
casted, input_ids = self.utils.cast_graph_input_to_int32(input_ids)
if self.find_graph_input(segment_ids):
casted, segment_ids = self.utils.cast_graph_input_to_int32(segment_ids)
else:
segment_ids, segment_id_cast_node = self.utils.cast_input_to_int32(segment_ids)
if self.find_graph_input(mask_input):
casted, mask_input = self.utils.cast_graph_input_to_int32(mask_input)
else:
mask_input, mask_input_cast_node = self.utils.cast_input_to_int32(mask_input)
embed_output = self.create_node_name('embed_output')
embed_node = onnx.helper.make_node(
'EmbedLayerNormalization',
inputs=[
input_ids,
segment_ids,
word_embedding,
position_embedding,
segment_embedding,
normalize_node.input[1], # gamma
normalize_node.input[2], # beta
mask_input
],
outputs=[embed_output, mask_index],
name="EmbedLayer")
embed_node.domain = "com.microsoft"
self.replace_input_of_all_nodes(normalize_node.output[0], embed_output)
self.add_node(embed_node, self.get_graph_by_node(normalize_node).name)
def process_embedding(self):
"""
Automatically detect word, segment and position embeddings.
"""
logger.info("start processing embedding layer...")
output_name_to_node = self.output_name_to_node()
layer_norm_nodes = self.get_nodes_by_op_type("LayerNormalization")
for layer_norm_node in layer_norm_nodes:
pos_embed_path = self.match_parent_path(layer_norm_node, ['Add', 'Reshape', 'Slice'], [0, 1, 0],
output_name_to_node)
if pos_embed_path is None:
continue
add_node, reshape_node, slice_node = pos_embed_path
initializer = self.get_initializer(slice_node.input[0])
if initializer is None:
continue
temp = numpy_helper.to_array(initializer)
if len(temp.shape) == 2:
logger.info("Found position embedding. name:{}, shape:{}".format(initializer.name, temp.shape))
position_embedding = initializer.name
else:
logger.info("Failed to find position embedding. name:{}, shape:{}".format(initializer.name, temp.shape))
return
first_parent = self.get_parent(add_node, 0, output_name_to_node)
if first_parent is not None and first_parent.op_type == "Add":
embeddings = self.get_2d_initializers_from_parent_subgraphs(first_parent)
if len(embeddings) != 2:
logger.warning(
"Failed to find two embeddings (word and segment) from Add node. Found {}".format(embeddings))
return
word_embedding = None
segment_embedding = None
for name, shape in embeddings.items():
if shape[0] == 2:
segment_embedding = name
logger.info("Found segment embedding. name:{}, shape:{}".format(name, shape))
else:
word_embedding = name
logger.info("Found words embedding. name:{}, shape:{}".format(name, shape))
if word_embedding is None or segment_embedding is None:
logger.info("Failed to find both word and segment embedding")
return
logger.info("Create Embedding node")
self.create_embedding_subgraph(layer_norm_node, word_embedding, segment_embedding, position_embedding)
# Prune graph to remove those original embedding nodes.
self.prune_graph()
break
def check_attention_input(self, matmul_q, matmul_k, matmul_v, parent, output_name_to_node):
for x in [matmul_q, matmul_k, matmul_v]:
root_input = x.input[0]
root_node = output_name_to_node[root_input]
if root_node == parent:
continue
logger.debug(f"Check attention input failed:{root_input}, {parent.output[0]}")
return False
return True
def fuse_attention(self):
output_name_to_node = self.output_name_to_node()
nodes_to_remove = []
attention_count = 0
start_nodes = []
skip_layer_norm_nodes = self.get_nodes_by_op_type("SkipLayerNormalization")
layer_norm_nodes = self.get_nodes_by_op_type("LayerNormalization")
# Sometimes we can not fuse skiplayernormalization since the add before layernorm has an output that used by nodes outside skiplayernorm
# Conceptually we treat add before layernorm as skiplayernorm node since they share the same pattern
start_nodes.extend(skip_layer_norm_nodes)
start_nodes.extend(layer_norm_nodes)
for normalize_node in start_nodes:
graph_name = self.get_graph_by_node(normalize_node).name
# SkipLayerNormalization has two inputs, and one of them is the root input for attention.
if normalize_node.op_type == 'LayerNormalization':
add_before_layernorm = self.match_parent(normalize_node, 'Add', 0)
if add_before_layernorm is not None:
normalize_node = add_before_layernorm
else:
continue
parent = self.get_parent(normalize_node, 1)
if parent is None or parent.op_type not in ["SkipLayerNormalization", "LayerNormalization", "Reshape"]:
parent = self.get_parent(normalize_node, 0)
if parent is None or parent.op_type not in ["SkipLayerNormalization", "LayerNormalization", "Reshape"]:
logger.debug("Failed to match parent of normalize_node")
continue
qkv_nodes = self.match_parent_path(normalize_node, ['Add', 'MatMul', 'Reshape', 'Transpose', 'MatMul'],
[0, 0, 0, 0, 0])
if qkv_nodes is None:
qkv_nodes = self.match_parent_path(normalize_node, ['MatMul', 'Reshape', 'Transpose', 'MatMul'],
[1, 0, 0, 0])
if qkv_nodes is None:
qkv_nodes = self.match_parent_path(normalize_node, ['Add', 'Einsum', 'Einsum'], [0, 0, 0])
if qkv_nodes is None:
logger.debug("Failed to match qkv nodes")
continue
matmul_qkv = qkv_nodes[-1]
v_nodes = self.match_parent_path(matmul_qkv, ['Transpose', 'Reshape', 'Add', 'MatMul'], [1, 0, 0, 0])
if v_nodes is None:
v_nodes = self.match_parent_path(matmul_qkv, ['Add', 'Einsum'], [1, 0])
if v_nodes is None:
logger.debug("Failed to match v path")
continue
add_v = v_nodes[-2]
matmul_v = v_nodes[-1]
qk_nodes = self.match_parent_path(matmul_qkv, ['Softmax', 'Add', "Mul", 'MatMul'], [0, 0, 0, 0])
if qk_nodes is None:
qk_nodes = self.match_parent_path(matmul_qkv, ['Softmax', 'Add', 'Einsum'], [0, 0, 0])
if qk_nodes is None:
logger.debug("Failed to match qk_paths")
continue
matmul_qk = qk_nodes[-1]
q_nodes = self.match_parent_path(matmul_qk, ['Transpose', 'Reshape', 'Add', 'MatMul'], [0, 0, 0, 0])
if q_nodes is None:
q_nodes = self.match_parent_path(matmul_qk, ['Add', 'Einsum'], [0, 0])
if q_nodes is None:
logger.debug("Failed to match q path")
continue
add_q = q_nodes[-2]
matmul_q = q_nodes[-1]
k_nodes = self.match_parent_path(matmul_qk, ['Transpose', 'Reshape', 'Add', 'MatMul'], [1, 0, 0, 0])
if k_nodes is None:
k_nodes = self.match_parent_path(matmul_qk, ['Mul', 'Add', 'Einsum'], [1, 0, 0])
if k_nodes is None:
logger.debug("Failed to match k path")
continue
add_k = k_nodes[-2]
matmul_k = k_nodes[-1]
mask_nodes = self.match_mask_path(qk_nodes[1])
if mask_nodes is None:
logger.debug("Cannot find mask_nodes.")
continue
if not self.has_constant_input(mask_nodes[1], 1):
logger.debug("Sub node expected to have an input with constant value 1.0.")
continue
# add a squeeze node to convert a 3-d mask to 2-d
squeeze_node = self.match_parent_path(mask_nodes[-1], ['Squeeze'], [0]) or self.match_parent_path(
mask_nodes[-1], ['Expand'], [0])
squeeze_node_name = "Squeeze_3d_to_2d_mask"
squeeze_output_name = squeeze_node_name + "_output"
if squeeze_node is None and len(mask_nodes) == 5 and self.find_graph_input(mask_nodes[-1].input[0]) is None:
mask_input = mask_nodes[-1].input[1]
self.add_node(
helper.make_node("Squeeze", [mask_input], [squeeze_output_name], squeeze_node_name, axes=[1]),
graph_name)
mask_nodes[-1].input[0] = squeeze_output_name
is_same_root = self.check_attention_input(matmul_q, matmul_k, matmul_v, parent, output_name_to_node)
if is_same_root:
mask_index = self.attention_mask.process_mask(mask_nodes[-1].input[0])
logger.debug("Create an Attention node.")
# For tf models, q and v are flipped.
attention_node = self.attention_fusion.create_attention_node(mask_index, matmul_k, matmul_q, matmul_v,
add_k, add_q, add_v, self.num_heads,
self.hidden_size, parent.output[0],
qkv_nodes[2].output[0], None)
if attention_node is None:
continue
if qkv_nodes[1].op_type == 'Einsum':
# add reshape before einsum
tensor = helper.make_tensor(name=qkv_nodes[1].name + "_newshape",
data_type=TensorProto.INT64,
dims=[4],
vals=np.int64(
[[0, 0, self.num_heads,
int(self.hidden_size / self.num_heads)]]).tobytes(),
raw=True)
self.add_initializer(tensor, graph_name)
reshape_ = helper.make_node("Reshape",
inputs=[attention_node.output[0], qkv_nodes[1].name + "_newshape"],
outputs=[qkv_nodes[1].name + "_reshape_output"],
name=qkv_nodes[1].name + "_reshape")
qkv_nodes[1].input[0] = qkv_nodes[1].name + "_reshape_output"
self.add_node(reshape_, graph_name)
if parent.op_type == 'Reshape':
# Temporary work around: we require the skiplayernorm and attention op be fed with 3-d input
hidden_size = numpy_helper.to_array(self.get_initializer(parent.input[1]))[1]
tensor = helper.make_tensor(name=parent.name + "_modified",
data_type=TensorProto.INT64,
dims=[3],
vals=np.int64([[1, -1, hidden_size]]).tobytes(),
raw=True)
self.add_initializer(tensor, graph_name)
parent.input[1] = parent.name + "_modified"
self.add_node(attention_node, graph_name)
attention_count += 1
nodes_to_remove.extend(qkv_nodes[2:])
nodes_to_remove.extend(qk_nodes)
nodes_to_remove.extend(q_nodes)
nodes_to_remove.extend(k_nodes)
nodes_to_remove.extend(v_nodes)
nodes_to_remove.extend(mask_nodes)
else:
logger.debug("Root node not matched.")
continue
self.remove_nodes(nodes_to_remove)
self.update_graph()
logger.info(f"Fused Attention count:{attention_count}")
def preprocess(self):
self.remove_identity()
self.process_embedding()
self.skip_reshape()
def skip_reshape(self):
count = 0
reshape_nodes = self.get_nodes_by_op_type("Reshape")
for reshape_node in reshape_nodes:
parent = self.get_parent(reshape_node, 0)
if parent is not None and parent.op_type == "Reshape":
reshape_node.input[0] = parent.input[0]
count += 1
if count > 0:
logger.info(f"Skip consequent Reshape count: {count}")
def remove_reshape_before_first_attention(self):
attention_nodes = self.get_nodes_by_op_type("Attention")
for attention_node in attention_nodes:
path = self.match_parent_path(attention_node, ['Reshape', 'EmbedLayerNormalization'], [0, 0])
if path is None:
continue
logger.info("Remove Reshape before first Attention node.")
reshape, _ = path
self.replace_input_of_all_nodes(reshape.output[0], reshape.input[0])
self.remove_node(reshape)
break
def postprocess(self):
self.remove_reshape_before_first_attention()
self.prune_graph()