Post Training Quantization

Overview

Converting a trained float32 model into an int8 model through quantization after training can reduce the model size and improve the inference performance. In MindSpore Lite, this function is integrated into the model conversion tool converter_lite. The quantized model can be transformed by configuring a quantization profile.

MindSpore Lite quantization after training is classified into two types:

1. Weight quantization: quantizes a weight of a model and compresses only the model size. float32 inference is still performed during inference.

2. Full quantization: quantizes the weight and activation value of a model. The int operation is performed during inference to improve the model inference speed and reduce power consumption.

Configuration Parameter

Post training quantization can be enabled by configuring configFile through Conversion Tool. The configuration file adopts the style of INI, For quantization, configurable parameters include common quantization parameter [common_quant_param], fixed bit weight quantization parameter [weight_quant_param], mixed bit weight quantization parameter [mixed_bit_weight_quant_param],full quantization parameter [full_quant_param], data preprocess parameter [data_preprocess_param] and dynamic quantization parameter [dynamic_quant_param].

Common Quantization Parameter

common quantization parameters are the basic settings for post training quantization, mainly including quant_type, bit_num, min_quant_weight_size, and min_quant_weight_channel. The detailed description of the parameters is as follows:

Parameter	Attribute	Function Description	Parameter Type	Default Value	Value Range
quant_type	Mandatory	The quantization type. When set to WEIGHT_QUANT, weight quantization is enabled; when set to FULL_QUANT, full quantization is enabled; when set to DYNAMIC_QUANT, dynamic quantization is enabled.	String	-	WEIGHT_QUANT, FULL_QUANT, DYNAMIC_QUANT
bit_num	Optional	The number of quantized bits. Currently, weight quantization supports 0-16bit quantization. When it is set to 1-16bit, it is fixed-bit quantization. When it is set to 0bit, mixed-bit quantization is enabled. Full quantization and Dynamic quantization supports 8bit quantization.	Integer	8	WEIGHT_QUANT:[0，16] FULL_QUANT: 8 DYNAMIC_QUANT:8
min_quant_weight_size	Optional	Set the threshold of the weight size for quantization. If the number of weights is greater than this value, the weight will be quantized.	Integer	0	[0, 65535]
min_quant_weight_channel	Optional	Set the threshold of the number of weight channels for quantization. If the number of weight channels is greater than this value, the weight will be quantized.	Integer	16	[0, 65535]
skip_quant_node	Optional	Set the name of the operator that does not need to be quantified, and use , to split between multiple operators.	String	-	-
debug_info_save_path	Optional	Set the folder path where the quantized debug information file is saved.	String	-	-
enable_encode	Optional	The enable switch of compression code for weight quantization.	Boolean	True	True, False

min_quant_weight_size and min_quant_weight_channel are only valid for weight quantization.

Recommendation: When the accuracy of full quantization is not satisfied, you can set debug_info_save_path to turn on the Debug mode to get the relevant statistical report, and set skip_quant_node for operators that are not suitable for quantization to not quantize them.

The common quantization parameter configuration is as follows:

[common_quant_param]
# Supports WEIGHT_QUANT or FULL_QUANT
quant_type=WEIGHT_QUANT
# Weight quantization support the number of bits [0,16], Set to 0 is mixed bit quantization, otherwise it is fixed bit quantization
# Full quantization support 8bit
bit_num=8
# Layers with size of weights exceeds threshold `min_quant_weight_size` will be quantized.
min_quant_weight_size=0
# Layers with channel size of weights exceeds threshold `min_quant_weight_channel` will be quantized.
min_quant_weight_channel=16
# Set the name of the operator that skips the quantization, and use `,` to split between multiple operators.
skip_quant_node=node_name1,node_name2,node_name3
# Set the folder path where the quantization debug information file is saved.
debug_info_save_path=/home/workspace/mindspore/debug_info_save_path
# Enable tensor compression for weight quantization. If parameter bit_num not equal to 8 or 16, it can not be set to false.
enable_encode = true

Fixed Bit Weight Quantization Parameters

The fixed bit weight quantization parameters include dequant_strategy, per_channel, bias_correction. The detailed description of the parameters is as follows:

Parameter	Attribute	Function Description	Parameter Type	Default Value	Value Range
dequant_strategy	Optional	Weight Quantization mode	String	-	ON_THE_FLY. After this parameter is enabled, Ascend online antiquantization mode is activated.
per_channel	Optional	Select PerChannel or PerLayer quantization type.	Boolean	True	True or False. Set to false to enable Perlayer quantization.
bias_correction	Optional	Indicate whether to correct the quantization error.	Boolean	True	True or False. After this parameter is enabled, the accuracy of the quantization model can be improved.

[weight_quant_param]
dequant_strategy=ON_THE_FLY
# If set to true, it will enable PerChannel quantization, or set to false to enable PerLayer quantization.
per_channel=True
# Whether to correct the quantization error. Recommended to set to true.
bias_correction=False

Mixed Bit Weight Quantization Parameter

The mixed bit weight quantization parameters include init_scale. When enable the mixed bit weight quantization, the optimal number of bits will be automatically searched for different layers. The detailed description of the parameters is as follows:

Parameter	Attribute	Function Description	Parameter Type	Default Value	Value Range
init_scale	Optional	Initialize the scale. The larger the value, the greater the compression rate, but it will also cause varying degrees of accuracy loss.	Float	0.02	(0 , 1)
auto_tune	Optional	Automatically search for the init_scale parameter. After setting, it will automatically search for a set of init_scale values whose cosine similarity of the model output Tensor is around 0.995.	Boolean	False	True，False

The mixed bit quantization parameter configuration is as follows:

[mixed_bit_weight_quant_param]
init_scale=0.02
auto_tune=false

Full Quantization Parameters

The full quantization parameters mainly include activation_quant_method, bias_correction and target_device. The detailed description of the parameters is as follows:

Parameter	Attribute	Function Description	Parameter Type	Default Value	Value Range
activation_quant_method	Optional	Activation quantization algorithm	String	MAX_MIN	KL, MAX_MIN, or RemovalOutlier. KL: quantizes and calibrates the data range based on KL divergence. MAX_MIN: data quantization parameter computed based on the maximum and minimum values. RemovalOutlier: removes the maximum and minimum values of data based on a certain proportion and then calculates the quantization parameters. If the calibration dataset is consistent with the input data during actual inference, MAX_MIN is recommended. If the noise of the calibration dataset is large, KL or RemovalOutlier is recommended.
bias_correction	Optional	Indicate whether to correct the quantization error.	Boolean	True	True or False. After this parameter is enabled, the accuracy of the converted model can be improved. You are advised to set this parameter to true.
per_channel	Optional	Select PerChannel or PerLayer quantization type.	Boolean	True	True or False. Set to false to enable Perlayer quantization.
target_device	Optional	Full quantization supports multiple hardware backends. After setting the specific hardware, the converted quantization model can execute the proprietry hardware quantization operator library. If not setting, universal quantization lib will be called.	String	-	NVGPU: The quantized model can perform quantitative inference on the NVIDIA GPU. DSP: The quantized model can perform quantitative inference on the DSP devices. ASCEND: The quantized model can perform quantitative inference on the ASCEND devices.

Data Preprocessing

Full quantization needs to provide 100-500 calibration data sets for pre-inference, which is used to calculate the quantization parameters of full quantization activation values. If there are multiple input Tensors, the calibration dataset for each input Tensor needs to be saved in a separate folder.

For the BIN calibration dataset, the .bin file stores the input data buffer, and the format of the input data needs to be consistent with the format of the input data during inference. For 4D data, the default is NHWC. If the command parameter inputDataFormat of the converter tool is configured, the format of the input Buffer needs to be consistent.

For the image calibration dataset, post training quantization provides data preprocessing functions such as channel conversion, normalization, resize, and center crop.

Parameter	Attribute	Function Description	Parameter Type	Default Value	Value Range
calibrate_path	Mandatory	The directory where the calibration dataset is stored; if the model has multiple inputs, please fill in the directory where the corresponding data is located one by one, and separate the directory paths with ,	String	-	input_name_1:/mnt/image/input_1_dir,input_name_2:input_2_dir
calibrate_size	Mandatory	Calibration data size	Integer	-	[1, 65535]
input_type	Mandatory	Correction data file format type	String	-	IMAGE, BIN IMAGE：image file data BIN：binary .bin file data
image_to_format	Optional	Image format conversion	String	-	RGB, GRAY, BGR
normalize_mean	Optional	Normalized mean dst = (src - mean) / std	Vector	-	Channel 3: [mean_1, mean_2, mean_3] Channel 1: [mean_1]
normalize_std	Optional	Normalized standard deviation dst = (src - mean) / std	Vector	-	Channel 3: [std_1, std_2, std_3] Channel 1: [std_1]
resize_width	Optional	Resize width	Integer	-	[1, 65535]
resize_height	Optional	Resize height	Integer	-	[1, 65535]
resize_method	Optional	Resize algorithm	String	-	LINEAR, NEAREST, CUBIC LINEAR：Bilinear interpolation NEARST：Nearest neighbor interpolation CUBIC：Bicubic interpolation
center_crop_width	Optional	Center crop width	Integer	-	[1, 65535]
center_crop_height	Optional	Center crop height	Integer	-	[1, 65535]

The data preprocessing parameter configuration is as follows:

[data_preprocess_param]
# Calibration dataset path, the format is input_name_1:input_1_dir,input_name_2:input_2_dir
# Full quantification must provide correction dataset
calibrate_path=input_name_1:/mnt/image/input_1_dir,input_name_2:input_2_dir
# Calibration data size
calibrate_size=100
# Input type supports IMAGE or BIN
# When set to IMAGE, the image data will be read
# When set to BIN, the `.bin` binary file will be read
input_type=IMAGE
# The output format of the preprocessed image
# Supports RGB or GRAY or BGR
image_to_format=RGB
# Image normalization
# dst = (src - mean) / std
normalize_mean=[127.5, 127.5, 127.5]
normalize_std=[127.5, 127.5, 127.5]
# Image resize
resize_width=224
resize_height=224
# Resize method supports LINEAR or NEAREST or CUBIC
resize_method=LINEAR
# Image center crop
center_crop_width=224
center_crop_height=224

Dynamic Quantization Parameters

The dynamic quantization parameter quant_strategy sets the dynamic quantizaiton strategy. The detailed description of the parameter is as follows:

Parameter	Attribute	Function Description	Parameter Type	Default Value	Value Range
quant_strategy	Optional	the dynamic quantizaiton strategy	String	ALWC	ALWC: Enable activation perlayer and weight perchannel quantization; ACWL: Enable activation perchannel and weight perlayer quantization.

The dynamic quantization parameter configuration is as follows:：

[dynamic_quant_param]
# If set to ALWC, it will enable activation perlayer and weight perchannel quantization. If set to ACWL, it will enable activation perchannel and weight perlayer quantization. Default value is ALWC.
quant_strategy=ACWL

Weight Quantization

Weight quantization supports mixed bit quantization, as well as fixed bit quantization between 1 and 16. The lower the number of bits, the greater the model compression rate, but the accuracy loss is usually larger. The following describes how to use weight quantization and its effects.

Mixed Bit Weight Quantization

Currently, weight quantization supports mixed bit quantization. According to the distribution of model parameters and the initial value of init_scale set by the user, the number of bits that is most suitable for the current layer will be automatically searched out. When the bit_num of the configuration parameter is set to 0, mixed bit quantization will be enabled.

The general form of the mixed bit weight requantization command is:

./converter_lite --fmk=ModelType --modelFile=ModelFilePath --outputFile=ConvertedModelPath --configFile=/mindspore/lite/tools/converter/quantizer/config/mixed_bit_weight_quant.cfg

The mixed bit weight quantification configuration file is as follows:

[common_quant_param]
quant_type=WEIGHT_QUANT
# Weight quantization support the number of bits [0,16], Set to 0 is mixed bit quantization, otherwise it is fixed bit quantization
bit_num=0
# Layers with size of weights exceeds threshold `min_quant_weight_size` will be quantized.
min_quant_weight_size=5000
# Layers with channel size of weights exceeds threshold `min_quant_weight_channel` will be quantized.
min_quant_weight_channel=5

[mixed_bit_weight_quant_param]
# Initialization scale in (0,1).
# A larger value can get a larger compression ratio, but it may also cause a larger error.
init_scale=0.02

Users can adjust the weighted parameters according to the model and their own needs.

The init_scale default value is 0.02, and the compression rate is equivalent to the compression effect of 6-7 fixed bits quantization.

Mixed bits need to search for the best bit, and the waiting time may be longer. If you need to view the log, you can set export GLOG_v=1 before the execution to print the relevant Info level log.

Fixed Bit Weight Quantization

Fixed-bit weighting supports fixed-bit quantization between 1 and 16, and users can adjust the weighting parameters according to the requirement.

The general form of the fixed bit weight quantization conversion command is:

./converter_lite --fmk=ModelType --modelFile=ModelFilePath --outputFile=ConvertedModelPath --configFile=/mindspore/lite/tools/converter/quantizer/config/fixed_bit_weight_quant.cfg

The fixed bit weight quantization configuration file is as follows:

[common_quant_param]
quant_type=WEIGHT_QUANT
# Weight quantization support the number of bits [0,16], Set to 0 is mixed bit quantization, otherwise it is fixed bit quantization
bit_num=8
# Layers with size of weights exceeds threshold `min_quant_weight_size` will be quantized.
min_quant_weight_size=0
# Layers with channel size of weights exceeds threshold `min_quant_weight_channel` will be quantized.
min_quant_weight_channel=16

Ascend ON_THE_FLY Quantization

Ascend ON_THE_FLY quantization means runtime weight dequantization. At this stage, only the MINDIR model is supported.

We must add configuration about [ascend_context] for Ascend ON_THE_FLY quantification as follow:

[common_quant_param]
quant_type=WEIGHT_QUANT
# Weight quantization support the number of bits (0,16]
bit_num=8
# Layers with size of weights exceeds threshold `min_quant_weight_size` will be quantized.
min_quant_weight_size=5000
# Layers with channel size of weights exceeds threshold `min_quant_weight_channel` will be quantized.
min_quant_weight_channel=5

[weight_quant_param]
dequant_strategy=ON_THE_FLY
# If set to true, it will enable PerChannel quantization, or set to false to enable PerLayer quantization.
per_channel=True
# Whether to correct the quantization error. Recommended to set to true.
bias_correction=False

[ascend_context]
# The converted model is suitable for Ascend GE processes
provider=ge

Partial Model Accuracy Result

Model	Test Dataset	FP32 Model Accuracy	Weight Quantization Accuracy (8 bits)
Inception_V3	ImageNet	77.60%	77.53%
Mobilenet_V1_1.0_224	ImageNet	70.96%	70.56%
Mobilenet_V2_1.0_224	ImageNet	71.56%	71.53%

All the preceding results are obtained in the x86 environment.

Full Quantization

In CV scenarios where the model running speed needs to be improved and the model running power consumption needs to be reduced, the full quantization after training can be used. The following describes how to use full quantization and its effects.

To calculate a quantization parameter of an activation value, you need to provide a calibration dataset. It is recommended that the calibration dataset be obtained from the actual inference scenario and can represent the actual input of a model. The number of data records is about 100 - 500, and the calibration dataset needs to be processed into the Format of NHWC.

For image data, currently supports channel pack, normalization, resize, center crop processing. The user can set the corresponding parameter according to the preprocessing operation requirements.

Full quantization config’s info must include [common_quant_param], [data_preprocess_param], [full_quant_param].

Note:

• The model calibration data must be co-distributed with the training data, and the Format of the calibration data and the inputs of the exported floating-point model need to be consistent.

The general form of the full quantization conversion command is:

./converter_lite --fmk=ModelType --modelFile=ModelFilePath --outputFile=ConvertedModelPath --configFile=/mindspore/lite/tools/converter/quantizer/config/full_quant.cfg

CPU

The full CPU quantization complete configuration file is shown below:

[common_quant_param]
quant_type=FULL_QUANT
# Full quantization support 8bit
bit_num=8

[data_preprocess_param]
# Calibration dataset path, the format is input_name_1:input_1_dir,input_name_2:input_2_dir
# Full quantification must provide correction dataset
calibrate_path=input_name_1:/mnt/image/input_1_dir,input_name_2:input_2_dir
# Calibration data size
calibrate_size=100
# Input type supports IMAGE or BIN
# When set to IMAGE, the image data will be read
# When set to BIN, the `.bin` binary file will be read
input_type=IMAGE
# The output format of the preprocessed image
# Supports RGB or GRAY or BGR
image_to_format=RGB
# Image normalization
# dst = (src - mean) / std
normalize_mean=[127.5, 127.5, 127.5]
normalize_std=[127.5, 127.5, 127.5]
# Image resize
resize_width=224
resize_height=224
# Resize method supports LINEAR or NEAREST or CUBIC
resize_method=LINEAR
# Image center crop
center_crop_width=224
center_crop_height=224

[full_quant_param]
# Activation quantized method supports MAX_MIN or KL or REMOVAL_OUTLIER
activation_quant_method=MAX_MIN
# Whether to correct the quantization error. Recommended to set to true.
bias_correction=true

Full quantization requires the execution of inference, and the waiting time may be long. If you need to view the log, you can set export GLOG_v=1 before execution for printing the related Info level log.

[full_quant_param]
# Activation quantized method supports MAX_MIN or KL or REMOVAL_OUTLIER
activation_quant_method=MAX_MIN
# Whether to correct the quantization error. Recommended to set to true.
bias_correction=true
# If set to true, it will enable PerChannel quantization, or set to false to enable PerLayer quantization.
per_channel=true

The full quantization parameter (PerLayer quantization type) [full_quant_param] configuration is as follows:

[full_quant_param]
# Activation quantized method supports MAX_MIN or KL or REMOVAL_OUTLIER
activation_quant_method=MAX_MIN
# Whether to correct the quantization error. Recommended to set to true.
bias_correction=true
# If set to true, it will enable PerChannel quantization, or set to false to enable PerLayer quantization.
per_channel=false

Partial Model Accuracy Result

Model	Test Dataset	quant_method	FP32 Model Accuracy	Full Quantization Accuracy (8 bits)	Description
Inception_V3	ImageNet	KL	77.60%	77.40%	Randomly select 100 images from the ImageNet Validation dataset as a calibration dataset.
Mobilenet_V1_1.0_224	ImageNet	KL	70.96%	70.31%	Randomly select 100 images from the ImageNet Validation dataset as a calibration dataset.
Mobilenet_V2_1.0_224	ImageNet	MAX_MIN	71.56%	71.16%	Randomly select 100 images from the ImageNet Validation dataset as a calibration dataset.

All the preceding results are obtained in the x86 environment.

NVDIA

NVIDIA GPU full quantization parameter configuration. Just add a new configuration target_device=NVGPU to [full_quant_param]:

[full_quant_param]
# Activation quantized method supports MAX_MIN or KL or REMOVAL_OUTLIER
activation_quant_method=MAX_MIN
# Supports specific hardware backends
target_device=NVGPU

DSP

DSP full quantization parameter configuration only need add target_device=DSP to [full_quant_param], and the command is as follows:

[full_quant_param]
# Activation quantized method supports MAX_MIN or KL or REMOVAL_OUTLIER
activation_quant_method=MAX_MIN
# Whether to correct the quantization error.
bias_correction=false
# Supports specific hardware backends
target_device=DSP

Ascend

Ascend quantization need to set optimize to ascend_oriented for converter tools and we also need to set environment for Ascend.

Ascend quantization static shape parameter configuration

• In the static shape scenario, the general form of the conversion command for Ascend quantization as follow:

  ./converter_lite --fmk=ModelType --modelFile=ModelFilePath --outputFile=ConvertedModelPath --configFile=/mindspore/lite/tools/converter/quantizer/config/full_quant.cfg --optimize=ascend_oriented
  

• Ascend static shape quantizion only need add target_device=ASCEND to [full_quant_param] likes as follows:

  [full_quant_param]
  # Activation quantized method supports MAX_MIN or KL or REMOVAL_OUTLIER
  activation_quant_method=MAX_MIN
  # Whether to correct the quantization error.
  bias_correction=true
  # Supports specific hardware backends
  target_device=ASCEND
  

Ascend quantization also support dynamic shape. It is worth noting that the conversion command must set the same inputShape as the calibration dataset. For details, please refer to Conversion Tool Parameter Description.

• In the dynamic shape scenario, the general form of the conversion command for Ascend quantization as follow:

  ./converter_lite --fmk=ModelType --modelFile=ModelFilePath --outputFile=ConvertedModelPath --configFile=/mindspore/lite/tools/converter/quantizer/config/full_quant.cfg --optimize=ascend_oriented --inputShape="inTensorName_1:1,32,32,4"
  

• We must add configuration about [ascend_context] for dynamic shape as follow:

  [full_quant_param]
  # Activation quantized method supports MAX_MIN or KL or REMOVAL_OUTLIER
  activation_quant_method=MAX_MIN
  # Whether to correct the quantization error.
  bias_correction=true
  # Supports specific hardware backends
  target_device=ASCEND
  
  [ascend_context]
  input_shape=input_1:[-1,32,32,4]
  dynamic_dims=[1~4],[8],[16]
  
  # "-1" in input_shape indicates that the batch size is dynamic.
  

Dynamic Quantization

In NLP scenarios where the model running speed needs to be improved and the model running power consumption needs to be reduced, the dynamic quantization after training can be used. The following describes how to use dynamic quantization and its effects.

In dynamic quantization, the weights are quantized at the convert, and the activation are quantized at the runtime. Compared to static quantization, no calibration dataset is required.

The general form of the dynamic quantization conversion command is:

./converter_lite --fmk=ModelType --modelFile=ModelFilePath --outputFile=ConvertedModelPath --configFile=/mindspore/lite/tools/converter/quantizer/config/dynamic_quant.cfg

The dynamic quantization profile is as follows:

[common_quant_param]
quant_type=DYNAMIC_QUANT
bit_num=8

[dynamic_quant_param]
# If set to ALWC, it will enable activation perlayer and weight perchannel quantization. If set to ACWL, it will enable activation perchannel and weight perlayer quantization. Default value is ALWC.
quant_strategy=ACWL

In order to ensure the quantization accuracy, the dynamic quantization does not support setting the FP16 mode .

The dynamic quantization will have a further acceleration effect on the ARM architecture that supports SDOT instructions.

Partial Model Performance Results

• tinybert_encoder

Model Type	Runtime Mode	Model Size(M)	RAM(K)	Latency(ms)	Cos-Similarity	Compression Ratio	Memory compared to FP32	Latency compared to FP32
FP32	FP32	20	29,029	9.916	1
FP32	FP16	20	18,208	5.75	0.99999	1	-37.28%	-42.01%
FP16	FP16	12	18,105	5.924	0.99999	1.66667	-37.63%	-40.26%
Weight Quant(8 Bit)	FP16	5.3	19,324	5.764	0.99994	3.77358	-33.43%	-41.87%
Dynamic Quant	INT8+FP32	5.2	15,709	4.517	0.99668	3.84615	-45.89%	-54.45%

• tinybert_decoder

Model Type	Runtime Mode	Model Size(M)	RAM(K)	Latency(ms)	Cos-Similarity	Compression Ratio	Memory compared to FP32	Latency compared to FP32
FP32	FP32	43	51,355	4.161	1
FP32	FP16	43	29,462	2.184	0.99999	1	-42.63%	-47.51%
FP16	FP16	22	29,440	2.264	0.99999	1.95455	-42.67%	-45.59%
Weight Quant(8 Bit)	FP16	12	32,285	2.307	0.99998	3.58333	-37.13%	-44.56%
Dynamic Quant	INT8+FP32	12	22,181	2.074	0.9993	3.58333	-56.81%	-50.16%

Quantization Debug

Turn on the quantization Debug function, you can get the data distribution statistics report, which is used to evaluate the quantization error and assist the decision-making model (operator) whether it is suitable for quantization. For full quantification, N data distribution statistics reports will be generated according to the number of correction datasets provided, that is, one report will be generated for each round; for weighting, only one data distribution statistics report will be generated.

When setting the debug_info_save_path parameter, the relevant debug report will be generated in the /home/workspace/mindspore/debug_info_save_path folder:

[common_quant_param]
debug_info_save_path=/home/workspace/mindspore/debug_info_save_path

The quantized output summary report output_summary.csv contains the accuracy information of the output layer Tensor of the entire network. The related fields are as follows：

Type	Name
Round	The calibration training round
TensorName	The tensor name
CosineSimilarity	Cosine similarity compared with the original data

The data distribution statistics report report_*.csvwill count the original data distribution of each Tensor and the data distribution after dequantization of the quantized Tensor. The relevant fields of the data distribution statistics report are as follows:

Type	Name
NodeName	The node name
NodeType	The node type
TensorName	The tensor name
InOutFlag	The input or output tensor
DataTypeFlag	The data type, use Origin for original model, use Dequant for quantization model
TensorTypeFlag	The data types such as input and output, use Activation, and constants, etc., use Weight.
Min	The minimum value
Q1	The 25% quantile
Median	The median
Q3	The 75% quantile
MAX	The maximum
Mean	The mean
Var	The var
Sparsity	The sparsity
Clip	The Clip
CosineSimilarity	Cosine similarity compared with the original data

The quantization parameter report quant_param.csv contains the quantization parameter information of all quantized Tensors. The related fields of the quantization parameter are as follows:

Type	Name
NodeName	The node name
NodeType	The node type
TensorName	The tensor name
ElementsNum	The Tensor elements num
Dims	The tensor dims
Scale	The quantization parameter scale
ZeroPoint	The quantization parameter zeropoint
Bits	The number of quantization bits
CorrectionVar	Bias correction coefficient-variance
CorrectionMean	Bias correction coefficient-mean

Mixed bit quantization is non-standard quantization, the quantization parameter file may not exist.

Skipping Quantization Node

Quantization is to convert the float32 operator to the int8 operator. The current quantization strategy is to quantify all the nodes contained in a certain type of operator that can be supported, but there are some nodes that are more sensitive and will cause larger errors after quantization. At the same time, the inference speed of some layers after quantization is much lower than that of float16. It supports non-quantization of the specified layer, which can effectively improve the accuracy and inference speed.

Below is an example of conv2d_1 add_8 concat_1 without quantifying the three nodes:

[common_quant_param]
# Supports WEIGHT_QUANT or FULL_QUANT
quant_type=FULL_QUANT
# Weight quantization support the number of bits [0,16], Set to 0 is mixed bit quantization, otherwise it is fixed bit quantization
# Full quantization support 8bit
bit_num=8
# Set the name of the operator that skips the quantization, and use `,` to split between multiple operators.
skip_quant_node=conv2d_1,add_8,concat_1

Recommendations

1. By filtering InOutFlag == Output && DataTypeFlag == Dequant, the output layer of all quantization operators can be filtered out, and the accuracy loss of the operator can be judged by looking at the quantized output CosineSimilarity, the closer to 1 the smaller the loss.

2. For merging operators such as Add and Concat, if the distribution of min and max between different input Tensors is quite different, which is likely to cause large errors, you can set skip_quant_node to not quantize them.

3. For operators with a higher cutoff rate Clip, you can set skip_quant_node to not quantize it.