Tensorflow中float32模型强制转为float16半浮点模型
原创Tensorflow中float32模型强制转为float16半浮点模型
原创
superhua
修改于 2020-12-10 18:03:01
修改于 2020-12-10 18:03:01
文章被收录于专栏:CNN
在Tensorflow框架训练完成后,部署模型时希望对模型进行压缩。一种方案是前面文字介绍的方法《【Ubuntu】Tensorflow对训练后的模型做8位(uint8)量化转换》。另一种方法是半浮点量化,今天我们主要介绍如何通过修改Tensorflow的pb文件中的计算节点和常量(const),将float32数据类型的模型大小压缩减半为float16数据类型的模型。
最近看到一个巨牛的人工智能教程,分享一下给大家。教程不仅是零基础,通俗易懂,而且非常风趣幽默,像看小说一样!觉得太牛了,所以分享给大家。平时碎片时间可以当小说看,【点这里可以去膜拜一下大神的“小说”】。
1 加载pb模型
封装函数,加载pb模型:
def load_graph(model_path):
graph = tf.Graph()
with graph.as_default():
graph_def = tf.GraphDef()
if model_path.endswith("pb"):
with open(model_path, "rb") as f:
graph_def.ParseFromString(f.read())
else:
with open(model_path, "r") as pf:
text_format.Parse(pf.read(), graph_def)
tf.import_graph_def(graph_def, name="")
sess = tf.Session(graph=graph)
ops=graph.get_operations()
for op in ops:
print(op.name)
return sess2 重写BatchNorm
由于BatchNorm对精度比较敏感,需要保持float32类型,因此BatchNorm需要特殊处理。
#用FusedBatchNormV2替换FusedBatchNorm,以保证反向梯度下降计算时使用的是float
def rewrite_batch_norm_node_v2(node, graph_def, target_type='fp16'):
if target_type == 'fp16':
dtype = types_pb2.DT_HALF
elif target_type == 'fp64':
dtype = types_pb2.DT_DOUBLE
else:
dtype = types_pb2.DT_FLOAT
new_node = graph_def.node.add()
new_node.op = "FusedBatchNormV2"
new_node.name = node.name
new_node.input.extend(node.input)
new_node.attr["U"].CopyFrom(attr_value_pb2.AttrValue(type=types_pb2.DT_FLOAT))
for attr in list(node.attr.keys()):
if attr == "T":
node.attr[attr].type = dtype
new_node.attr[attr].CopyFrom(node.attr[attr])
print("rewrite fused_batch_norm done!")3 Graph转换
重新构造graph,参数从原始pb的graph中拷贝,并转为float16
def convert_graph_to_fp16(model_path, save_path, name, as_text=False, target_type='fp16', input_name=None, output_names=None):
#生成新的图数据类型
if target_type == 'fp16':
dtype = types_pb2.DT_HALF
elif target_type == 'fp64':
dtype = types_pb2.DT_DOUBLE
else:
dtype = types_pb2.DT_FLOAT
#加载需要转换的模型
source_sess = load_graph(model_path)
source_graph_def = source_sess.graph.as_graph_def()
#创建新的模图对象
target_graph_def = graph_pb2.GraphDef()
target_graph_def.versions.CopyFrom(source_graph_def.versions)
#对加载的模型遍历计算节点
for node in source_graph_def.node:
# 对FusedBatchNorm计算节点替换为FusedBatchNormV2
if node.op == "FusedBatchNorm":
rewrite_batch_norm_node_v2(node, target_graph_def, target_type=target_type)
continue
# 复制计算节点
new_node = target_graph_def.node.add()
new_node.op = node.op
new_node.name = node.name
new_node.input.extend(node.input)
#对attrs属性进行复制,attrs属性主要关注
attrs = list(node.attr.keys())
# BatchNorm属性保持不变
if ("BatchNorm" in node.name) or ('batch_normalization' in node.name):
for attr in attrs:
new_node.attr[attr].CopyFrom(node.attr[attr])
continue
# 除了BatchNorm以外其他计算节点的属性单独
for attr in attrs:
# 对指定的计算节点保持不变
if node.name in keep_fp32_node_name:
new_node.attr[attr].CopyFrom(node.attr[attr])
continue
#将Float类型修改为设置的目标类型
if node.attr[attr].type == types_pb2.DT_FLOAT:
# modify node dtype
node.attr[attr].type = dtype
#重点关注value,weights都是保存在value属性中
if attr == "value":
tensor = node.attr[attr].tensor
if tensor.dtype == types_pb2.DT_FLOAT:
# if float_val exists
if tensor.float_val:
float_val = tf.make_ndarray(node.attr[attr].tensor)
new_node.attr[attr].tensor.CopyFrom(tf.make_tensor_proto(float_val, dtype=dtype))
continue
# if tensor content exists
if tensor.tensor_content:
tensor_shape = [x.size for x in tensor.tensor_shape.dim]
tensor_weights = tf.make_ndarray(tensor)
# reshape tensor
tensor_weights = np.reshape(tensor_weights, tensor_shape)
tensor_proto = tf.make_tensor_proto(tensor_weights, dtype=dtype)
new_node.attr[attr].tensor.CopyFrom(tensor_proto)
continue
new_node.attr[attr].CopyFrom(node.attr[attr])
# transform graph
if output_names:
if not input_name:
input_name = []
transforms = ["strip_unused_nodes"]
target_graph_def = TransformGraph(target_graph_def, input_name, output_names, transforms)
# write graph_def to model
tf.io.write_graph(target_graph_def, logdir=save_path, name=name, as_text=as_text)
print("Converting done ...")4 完整的代码
import tensorflow as tf
from tensorflow.core.framework import types_pb2, graph_pb2, attr_value_pb2
from tensorflow.tools.graph_transforms import TransformGraph
from google.protobuf import text_format
import numpy as np
# object detection api input and output nodes
input_name = "input_tf"
output_names = ["output:0"]
keep_fp32_node_name = []
def load_graph(model_path):
graph = tf.Graph()
with graph.as_default():
graph_def = tf.GraphDef()
if model_path.endswith("pb"):
with open(model_path, "rb") as f:
graph_def.ParseFromString(f.read())
else:
with open(model_path, "r") as pf:
text_format.Parse(pf.read(), graph_def)
tf.import_graph_def(graph_def, name="")
sess = tf.Session(graph=graph)
ops=graph.get_operations()
for op in ops:
print(op.name)
return sess
#用FusedBatchNormV2替换FusedBatchNorm,以保证反向梯度下降计算时使用的是float
def rewrite_batch_norm_node_v2(node, graph_def, target_type='fp16'):
if target_type == 'fp16':
dtype = types_pb2.DT_HALF
elif target_type == 'fp64':
dtype = types_pb2.DT_DOUBLE
else:
dtype = types_pb2.DT_FLOAT
new_node = graph_def.node.add()
new_node.op = "FusedBatchNormV2"
new_node.name = node.name
new_node.input.extend(node.input)
new_node.attr["U"].CopyFrom(attr_value_pb2.AttrValue(type=types_pb2.DT_FLOAT))
for attr in list(node.attr.keys()):
if attr == "T":
node.attr[attr].type = dtype
new_node.attr[attr].CopyFrom(node.attr[attr])
print("rewrite fused_batch_norm done!")
def convert_graph_to_fp16(model_path, save_path, name, as_text=False, target_type='fp16', input_name=None, output_names=None):
#生成新的图数据类型
if target_type == 'fp16':
dtype = types_pb2.DT_HALF
elif target_type == 'fp64':
dtype = types_pb2.DT_DOUBLE
else:
dtype = types_pb2.DT_FLOAT
#加载需要转换的模型
source_sess = load_graph(model_path)
source_graph_def = source_sess.graph.as_graph_def()
#创建新的模图对象
target_graph_def = graph_pb2.GraphDef()
target_graph_def.versions.CopyFrom(source_graph_def.versions)
#对加载的模型遍历计算节点
for node in source_graph_def.node:
# 对FusedBatchNorm计算节点替换为FusedBatchNormV2
if node.op == "FusedBatchNorm":
rewrite_batch_norm_node_v2(node, target_graph_def, target_type=target_type)
continue
# 复制计算节点
new_node = target_graph_def.node.add()
new_node.op = node.op
new_node.name = node.name
new_node.input.extend(node.input)
#对attrs属性进行复制,attrs属性主要关注
attrs = list(node.attr.keys())
# BatchNorm属性保持不变
if ("BatchNorm" in node.name) or ('batch_normalization' in node.name):
for attr in attrs:
new_node.attr[attr].CopyFrom(node.attr[attr])
continue
# 除了BatchNorm以外其他计算节点的属性单独
for attr in attrs:
# 对指定的计算节点保持不变
if node.name in keep_fp32_node_name:
new_node.attr[attr].CopyFrom(node.attr[attr])
continue
#将Float类型修改为设置的目标类型
if node.attr[attr].type == types_pb2.DT_FLOAT:
# modify node dtype
node.attr[attr].type = dtype
#重点关注value,weights都是保存在value属性中
if attr == "value":
tensor = node.attr[attr].tensor
if tensor.dtype == types_pb2.DT_FLOAT:
# if float_val exists
if tensor.float_val:
float_val = tf.make_ndarray(node.attr[attr].tensor)
new_node.attr[attr].tensor.CopyFrom(tf.make_tensor_proto(float_val, dtype=dtype))
continue
# if tensor content exists
if tensor.tensor_content:
tensor_shape = [x.size for x in tensor.tensor_shape.dim]
tensor_weights = tf.make_ndarray(tensor)
# reshape tensor
tensor_weights = np.reshape(tensor_weights, tensor_shape)
tensor_proto = tf.make_tensor_proto(tensor_weights, dtype=dtype)
new_node.attr[attr].tensor.CopyFrom(tensor_proto)
continue
new_node.attr[attr].CopyFrom(node.attr[attr])
# transform graph
if output_names:
if not input_name:
input_name = []
transforms = ["strip_unused_nodes"]
target_graph_def = TransformGraph(target_graph_def, input_name, output_names, transforms)
# write graph_def to model
tf.io.write_graph(target_graph_def, logdir=save_path, name=name, as_text=as_text)
print("Converting done ...")
save_path = "test"
name = "output_fp16.pb"
model_path="test.pb"
as_text = False
target_type = 'fp16'
convert_graph_to_fp16(model_path, save_path, name, as_text=as_text, target_type=target_type, input_name=input_name, output_names=output_names)
# 测试一下转换后的模型是否能够加载
sess = load_graph(save_path+"/"+name)原创声明:本文系作者授权腾讯云开发者社区发表,未经许可,不得转载。
如有侵权,请联系 cloudcommunity@tencent.com 删除。
原创声明:本文系作者授权腾讯云开发者社区发表,未经许可,不得转载。
如有侵权,请联系 cloudcommunity@tencent.com 删除。
评论
登录后参与评论
推荐阅读
目录
相关产品与服务
文件存储
文件存储(Cloud File Storage,CFS)为您提供安全可靠、可扩展的共享文件存储服务。文件存储可与腾讯云服务器、容器服务、批量计算等服务搭配使用,为多个计算节点提供容量和性能可弹性扩展的高性能共享存储。腾讯云文件存储的管理界面简单、易使用,可实现对现有应用的无缝集成;按实际用量付费,为您节约成本,简化 IT 运维工作。
腾讯云开发者
