Model Compression Save
micronet, a model compression and deploy lib. compression: 1、quantization: quantization-aware-training(QAT), High-Bit(>2b)(DoReFa/Quantization and Training of Neural Networks for Efficient Integer-Arithmetic-Only Inference)、Low-Bit(≤2b)/Ternary and Binary(TWN/BNN/XNOR-Net); post-training-quantization(PTQ), 8-bit(tensorrt); 2、 pruning: normal、regular and group convolutional channel pruning; 3、 group convolution structure; 4、batch-normalization fuse for quantization. deploy: tensorrt, fp32/fp16/int8(ptq-calibration)、op-adapt(upsample)、dynamic_shape
Project README
micronet
"目前在深度学习领域分类两个派别,一派为学院派,研究强大、复杂的模型网络和实验方法,为了追求更高的性能;另一派为工程派,旨在将算法更稳定、高效的落地在硬件平台上,效率是其追求的目标。复杂的模型固然具有更好的性能,但是高额的存储空间、计算资源消耗是使其难以有效的应用在各硬件平台上的重要原因。所以,深度神经网络日益增长的规模为深度学习在移动端的部署带来了巨大的挑战,深度学习模型压缩与部署成为了学术界和工业界都重点关注的研究领域之一"
项目简介
micronet, a model compression and deploy lib.
压缩
- 量化:High-Bit(>2b): QAT, PTQ, QAFT; Low-Bit(≤2b)/Ternary and Binary: QAT
- 剪枝:正常、规整和分组卷积结构剪枝
- 针对特征(A)二值量化的BN融合(训练量化后,BN参数 —> conv的偏置b)
- High-Bit量化的BN融合(训练量化中,先融合再量化,融合:BN参数 —> conv的权重w和偏置b)
部署
- TensorRT(fp32/fp16/int8(ptq-calibration)、op-adapt(upsample)、dynamic_shape等)
代码结构
micronet
├── __init__.py
├── base_module
│ ├── __init__.py
│ └── op.py
├── compression
│ ├── README.md
│ ├── __init__.py
│ ├── pruning
│ │ ├── README.md
│ │ ├── __init__.py
│ │ ├── gc_prune.py
│ │ ├── main.py
│ │ ├── models_save
│ │ │ └── models_save.txt
│ │ └── normal_regular_prune.py
│ └── quantization
│ ├── README.md
│ ├── __init__.py
│ ├── wbwtab
│ │ ├── __init__.py
│ │ ├── bn_fuse
│ │ │ ├── bn_fuse.py
│ │ │ ├── bn_fused_model_test.py
│ │ │ └── models_save
│ │ │ └── models_save.txt
│ │ ├── main.py
│ │ ├── models_save
│ │ │ └── models_save.txt
│ │ └── quantize.py
│ └── wqaq
│ ├── __init__.py
│ ├── dorefa
│ │ ├── __init__.py
│ │ ├── main.py
│ │ ├── models_save
│ │ │ └── models_save.txt
│ │ ├── quant_model_test
│ │ │ ├── models_save
│ │ │ │ └── models_save.txt
│ │ │ ├── quant_model_para.py
│ │ │ └── quant_model_test.py
│ │ └── quantize.py
│ └── iao
│ ├── __init__.py
│ ├── bn_fuse
│ │ ├── bn_fuse.py
│ │ ├── bn_fused_model_test.py
│ │ └── models_save
│ │ └── models_save.txt
│ ├── main.py
│ ├── models_save
│ │ └── models_save.txt
│ └── quantize.py
├── data
│ └── data.txt
├── deploy
│ ├── README.md
│ ├── __init__.py
│ └── tensorrt
│ ├── README.md
│ ├── __init__.py
│ ├── calibrator.py
│ ├── eval_trt.py
│ ├── models
│ │ ├── __init__.py
│ │ └── models_trt.py
│ ├── models_save
│ │ └── calibration_seg.cache
│ ├── test_trt.py
│ └── util_trt.py
├── models
│ ├── __init__.py
│ ├── nin.py
│ ├── nin_gc.py
│ └── resnet.py
└── readme_imgs
├── code_structure.jpg
└── micronet.xmind
项目进展
- 2019.12.4, 初次提交
- 12.8, DoReFa特征(A)量化前先进行缩放(* 0.1),然后再截断,以减小截断误差
- 12.11, 增加项目代码结构图
- 12.12, 完善使用示例
- 12.14, 增加:1、BN融合量化情况(W三值/二值)可选,即训练量化时选择W三/二值,这里则对应选择; 2、BN融合时对卷积核(conv)不带偏置(bias)的处理
- 12.17, 增加模型压缩前后数据对比(示例)
- 12.20, 增加设备可选(cpu、gpu(单卡、多卡))
- 12.27, 补充相关论文
- 12.29, 取消High-Bit量化8-bit以内的限制,即现在可以量化至10-bit、16-bit等
- 2020.2.17, 1、精简W三值/二值量化代码; 2、加速W三值量化训练
- 2.18, 优化针对特征(A)二值的BN融合:去除对BN层gamma参数的限制,即现在此情况下融合时BN可正常训练
- 2.24, 再次优化三/二值量化代码组织结构,增强可移植性,旧版确实不太好移植。目前移植方法:将想要量化的Conv用compression/quantization/wbwtab/models/util_wbwtab.py中的QuantConv2d替换即可,可参照该路径下nin_gc.py中的使用方法
- 3.1, 新增:1、google的High-Bit量化方法; 2、训练中High-Bit量化的BN融合
- 3.2、3.3, 规整量化代码整体结构,目前所有量化方法都可采取类似的移植方式:将想要量化的Conv(或FC,目前dorefa支持,其他方法类似可写)用models/util_wxax.py中的QuantConv2d(或QuantLinear)替换即可,可分别参照该路径下nin_gc.py中的使用方法进行移植(分类、检测、分割等均适用,但需要据实际情况具体调试)
- 3.4, 规整优化wbwtab/bn_fuse中“针对特征(A)二值的BN融合”的相关实现代码,可进行BN融合及融合前后模型对比测试(精度/速度/(大小))
- 3.11, 调整compression/wqaq/iao中的BN层momentum参数(0.1 —> 0.01),削弱batch统计参数占比,一定程度抑制量化带来的抖动。经实验,量化训练更稳定,acc提升1%左右
- 3.13, 更新代码结构图
- 4.6, 修正二值量化训练中W_clip的相关问题(之前由于这个,导致二值量化训练精度上不去,现在已可正常使用)(同时修正无法找到一些模块如models/util_wxax.py的问题)
- 12.14, 1、improve code structure; 2、add deploy-tensorrt(main module, but not running yet)
- 12.18, 1、improve code structure/module reference/module_name; 2、add transfer-use demo
- 12.21, improve pruning-quantization pipeline and code
- 2021.1.4, add other quant_op
- 1.5, add quant_weight's per-channel and per-layer selection
- 1.7, fix iao's loss-nan bug. The bug is due to per-channel min/max error
- 1.8, 1、improve quant_para save. Now, only save scale and zero_point; 2、add optional weight_observer(MinMaxObserver or MovingAverageMinMaxObserver)
- 1.11, fix bug in binary_a(1/0) and binary_w preprocessing
- 1.12, add "pip install"
- 1.22, add auto_insert_quant_op(this still needs to be improved)
- 1.27, improve auto_insert_quant_op(now you can easily use quantization, as quant_test_auto)
- 1.28, 1、fix prune-quantization pipeline and code; 2、improve code structure
- 2.1, improve wbwtab_bn_fuse
- 2.4, 1、add wqaq_bn_fuse; 2、add quant_model_inference_simulation; 3、improve code format
- 4.30, 1、update code_structure img; 2、fix iao's quant_weight_range, quant_contrans and quant_bn_fuse_conv pretrained_model bn_para load bug
- 5.4, add qaft, it's beneficial to improve the quantization accuracy
- 5.6, add ptq, its quantization accuracy is also good
- 5.11, add bn_fuse_calib flag
- 5.14, 1、change ste to clip_ste, it's beneficial to improve the quant_train;2、remove quant_relu and add quant_leaky_relu
- 5.15, fix bug in quant_model_para post-processing
- 6.7, add quant_add(need use base_module's op) and quant_resnet demo
- 6.9, iao_quant supports multi gpus
- 6.16, fix quant_round() and quant_binary()
- 10.6, format
环境要求
- python >= 3.5
- torch >= 1.1.0
- torchvison >= 0.3.0
- numpy
- onnx == 1.6.0
- tensorrt == 7.0.0.11
安装
pip install micronet -i https://pypi.org/simple
git clone https://github.com/666DZY666/micronet.git
cd micronet
python setup.py install
验证
python -c "import micronet; print(micronet.__version__)"
测试
Install from github
压缩
量化
--refine,可加载预训练浮点模型参数,在其基础上做量化
wbwtab
--W --A, 权重W和特征A量化取值
cd micronet/compression/quantization/wbwtab
- WbAb
python main.py --W 2 --A 2
- WbA32
python main.py --W 2 --A 32
- WtAb
python main.py --W 3 --A 2
- WtA32
python main.py --W 3 --A 32
wqaq
--w_bits --a_bits, 权重W和特征A量化位数
dorefa
cd micronet/compression/quantization/wqaq/dorefa
- W16A16
python main.py --w_bits 16 --a_bits 16
- W8A8
python main.py --w_bits 8 --a_bits 8
- W4A4
python main.py --w_bits 4 --a_bits 4
- 其他bits情况类比
iao
cd micronet/compression/quantization/wqaq/iao
量化位数选择同dorefa
单卡
QAT/PTQ —> QAFT
! 注意,需要在QAT/PTQ之后再做QAFT !
--q_type, 量化类型(0-对称, 1-非对称)
--q_level, 权重量化级别(0-通道级, 1-层级)
--weight_observer, weight_observer选择(0-MinMaxObserver, 1-MovingAverageMinMaxObserver)
--bn_fuse, 量化中bn融合标志
--bn_fuse_calib, 量化中bn融合校准标志
--pretrained_model, 预训练浮点模型
--qaft, qaft标志
--ptq, ptq_observer
--ptq_control, ptq_control
--ptq_batch, ptq的batch数量
--percentile, ptq校准的比例
QAT
- 默认: 对称、(权重)通道级量化, bn不融合, weight_observer-MinMaxObserver, 不加载预训练浮点模型, 进行qat
python main.py --q_type 0 --q_level 0 --weight_observer 0
- 对称、(权重)通道级量化, bn不融合, weight_observer-MovingAverageMinMaxObserver
python main.py --q_type 0 --q_level 0 --weight_observer 1
- 对称、(权重)层级量化, bn不融合
python main.py --q_type 0 --q_level 1
- 非对称、(权重)通道级量化, bn不融合
python main.py --q_type 1 --q_level 0
- 非对称、(权重)层级量化, bn不融合
python main.py --q_type 1 --q_level 1
- 对称、(权重)通道级量化, bn融合
python main.py --q_type 0 --q_level 0 --bn_fuse
- 对称、(权重)层级量化, bn融合
python main.py --q_type 0 --q_level 1 --bn_fuse
- 非对称、(权重)通道级量化, bn融合
python main.py --q_type 1 --q_level 0 --bn_fuse
- 非对称、(权重)层级量化, bn融合
python main.py --q_type 1 --q_level 1 --bn_fuse
- 对称、(权重)通道级量化, bn融合校准
python main.py --q_type 0 --q_level 0 --bn_fuse --bn_fuse_calib
PTQ
需要加载预训练浮点模型,本项目中其可由剪枝中采用正常训练获取
- 对称、(权重)通道级量化, bn融合
python main.py --refine ../../../pruning/models_save/nin_gc.pth --q_level 0 --bn_fuse --pretrained_model --ptq_control --ptq --batch_size 32 --ptq_batch 200 --percentile 0.999999
- 其他情况类比
QAFT
! 注意,需要在QAT/PTQ之后再做QAFT !
QAT —> QAFT
- 对称、(权重)通道级量化, bn融合
python main.py --resume models_save/nin_gc_bn_fused.pth --q_type 0 --q_level 0 --bn_fuse --qaft --lr 0.00001
- 其他情况类比
PTQ —> QAFT
- 对称、(权重)通道级量化, bn融合
python main.py --resume models_save/nin_gc_bn_fused.pth --q_level 0 --bn_fuse --qaft --lr 0.00001 --ptq
- 其他情况类比
剪枝
稀疏训练 —> 剪枝 —> 微调
cd micronet/compression/pruning
稀疏训练
-sr 稀疏标志
--s 稀疏率(需根据dataset、model情况具体调整)
--model_type 模型类型(0-nin, 1-nin_gc)
- nin(正常卷积结构)
python main.py -sr --s 0.0001 --model_type 0
- nin_gc(含分组卷积结构)
python main.py -sr --s 0.001 --model_type 1
剪枝
--percent 剪枝率
--normal_regular 正常、规整剪枝标志及规整剪枝基数(如设置为N,则剪枝后模型每层filter个数即为N的倍数)
--model 稀疏训练后的model路径
--save 剪枝后保存的model路径(路径默认已给出, 可据实际情况更改)
- 正常剪枝(nin)
python normal_regular_prune.py --percent 0.5 --model models_save/nin_sparse.pth --save models_save/nin_prune.pth
- 规整剪枝(nin)
python normal_regular_prune.py --percent 0.5 --normal_regular 8 --model models_save/nin_sparse.pth --save models_save/nin_prune.pth
或
python normal_regular_prune.py --percent 0.5 --normal_regular 16 --model models_save/nin_sparse.pth --save models_save/nin_prune.pth
- 分组卷积结构剪枝(nin_gc)
python gc_prune.py --percent 0.4 --model models_save/nin_gc_sparse.pth
微调
--prune_refine 剪枝后的model路径(在其基础上做微调)
- nin
python main.py --model_type 0 --prune_refine models_save/nin_prune.pth
- nin_gc
需要传入剪枝后得到的新模型的cfg
如
python main.py --model_type 1 --gc_prune_refine 154 162 144 304 320 320 608 584
剪枝 —> 量化(注意剪枝率和量化率平衡)
加载剪枝后的浮点模型再做量化
剪枝 —> 量化(高位)(剪枝率偏大、量化率偏小)
w8a8(dorefa)
cd micronet/compression/quantization/wqaq/dorefa
- nin(正常卷积结构)
python main.py --w_bits 8 --a_bits 8 --model_type 0 --prune_quant ../../../pruning/models_save/nin_finetune.pth
- nin_gc(含分组卷积结构)
python main.py --w_bits 8 --a_bits 8 --model_type 1 --prune_quant ../../../pruning/models_save/nin_gc_retrain.pth
w8a8(iao)
cd micronet/compression/quantization/wqaq/iao
QAT/PTQ —> QAFT
! 注意,需要在QAT/PTQ之后再做QAFT !
QAT
bn不融合
- nin(正常卷积结构)
python main.py --w_bits 8 --a_bits 8 --model_type 0 --prune_quant ../../../pruning/models_save/nin_finetune.pth --lr 0.001
- nin_gc(含分组卷积结构)
python main.py --w_bits 8 --a_bits 8 --model_type 1 --prune_quant ../../../pruning/models_save/nin_gc_retrain.pth --lr 0.001
bn融合
- nin(正常卷积结构)
python main.py --w_bits 8 --a_bits 8 --model_type 0 --prune_quant ../../../pruning/models_save/nin_finetune.pth --bn_fuse --pretrained_model --lr 0.001
- nin_gc(含分组卷积结构)
python main.py --w_bits 8 --a_bits 8 --model_type 1 --prune_quant ../../../pruning/models_save/nin_gc_retrain.pth --bn_fuse --pretrained_model --lr 0.001
PTQ
- nin(正常卷积结构)
python main.py --w_bits 8 --a_bits 8 --model_type 0 --prune_quant ../../../pruning/models_save/nin_finetune.pth --bn_fuse --pretrained_model --ptq_control --ptq --batch_size 32 --ptq_batch 200 --percentile 0.999999
- 其他情况类比
QAFT
! 注意,需要在QAT/PTQ之后再做QAFT !
QAT —> QAFT
bn不融合
- nin(正常卷积结构)
python main.py --w_bits 8 --a_bits 8 --model_type 0 --prune_qaft models_save/nin.pth --qaft --lr 0.00001
- nin_gc(含分组卷积结构)
python main.py --w_bits 8 --a_bits 8 --model_type 1 --prune_qaft models_save/nin_gc.pth --qaft --lr 0.00001
bn融合
- nin(正常卷积结构)
python main.py --w_bits 8 --a_bits 8 --model_type 0 --prune_qaft models_save/nin_bn_fused.pth --bn_fuse --qaft --lr 0.00001
- nin_gc(含分组卷积结构)
python main.py --w_bits 8 --a_bits 8 --model_type 1 --prune_qaft models_save/nin_gc_bn_fused.pth --bn_fuse --qaft --lr 0.00001
PTQ —> QAFT
bn不融合
- nin(正常卷积结构)
python main.py --w_bits 8 --a_bits 8 --model_type 0 --prune_qaft models_save/nin.pth --qaft --lr 0.00001 --ptq
- nin_gc(含分组卷积结构)
python main.py --w_bits 8 --a_bits 8 --model_type 1 --prune_qaft models_save/nin_gc.pth --qaft --lr 0.00001 --ptq
bn融合
- nin(正常卷积结构)
python main.py --w_bits 8 --a_bits 8 --model_type 0 --prune_qaft models_save/nin_bn_fused.pth --bn_fuse --qaft --lr 0.00001 --ptq
- nin_gc(含分组卷积结构)
python main.py --w_bits 8 --a_bits 8 --model_type 1 --prune_qaft models_save/nin_gc_bn_fused.pth --bn_fuse --qaft --lr 0.00001 --ptq
其他可选量化配置类比
剪枝 —> 量化(低位)(剪枝率偏小、量化率偏大)
cd micronet/compression/quantization/wbwtab
wbab
- nin(正常卷积结构)
python main.py --W 2 --A 2 --model_type 0 --prune_quant ../../pruning/models_save/nin_finetune.pth
- nin_gc(含分组卷积结构)
python main.py --W 2 --A 2 --model_type 1 --prune_quant ../../pruning/models_save/nin_gc_retrain.pth
其他取值情况类比
BN融合与量化推理仿真测试
wbwtab
cd micronet/compression/quantization/wbwtab/bn_fuse
bn_fuse(得到quant_model_train和quant_bn_fused_model_inference的结构和参数)
--model_type, 1 - nin_gc(含分组卷积结构); 0 - nin(正常卷积结构)
--prune_quant, 剪枝_量化模型标志
--W, weight量化取值
均需要与量化训练保持一致,可直接用默认
- nin_gc, quant_model, wb
python bn_fuse.py --model_type 1 --W 2
- nin_gc, prune_quant_model, wb
python bn_fuse.py --model_type 1 --prune_quant --W 2
- nin_gc, quant_model, wt
python bn_fuse.py --model_type 1 --W 3
- nin, quant_model, wb
python bn_fuse.py --model_type 0 --W 2
bn_fused_model_test(对quant_model_train和quant_bn_fused_model_inference进行测试)
python bn_fused_model_test.py
dorefa
cd micronet/compression/quantization/wqaq/dorefa/quant_model_test
quant_model_para(得到quant_model_train和quant_model_inference的结构和参数)
--model_type, 1 - nin_gc(含分组卷积结构); 0 - nin(正常卷积结构)
--prune_quant, 剪枝_量化模型标志
--w_bits, weight量化位数; --a_bits, activation量化位数
均需要与量化训练保持一致,可直接用默认
- nin_gc, quant_model, w8a8
python quant_model_para.py --model_type 1 --w_bits 8 --a_bits 8
- nin_gc, prune_quant_model, w8a8
python quant_model_para.py --model_type 1 --prune_quant --w_bits 8 --a_bits 8
- nin, quant_model, w8a8
python quant_model_para.py --model_type 0 --w_bits 8 --a_bits 8
quant_model_test(对quant_model_train和quant_model_inference进行测试)
python quant_model_test.py
iao
注意,量化训练时 --bn_fuse 需要设置为 True
cd micronet/compression/quantization/wqaq/iao/bn_fuse
bn_fuse(得到quant_bn_fused_model_train和quant_bn_fused_model_inference的结构和参数)
--model_type, 1 - nin_gc(含分组卷积结构); 0 - nin(正常卷积结构)
--prune_quant, 剪枝_量化模型标志
--w_bits, weight量化位数; --a_bits, activation量化位数
--q_type, 0 - 对称; 1 - 非对称
--q_level, 0 - 通道级; 1 - 层级
均需要与量化训练保持一致,可直接用默认
- nin_gc, quant_model, w8a8
python bn_fuse.py --model_type 1 --w_bits 8 --a_bits 8
- nin_gc, prune_quant_model, w8a8
python bn_fuse.py --model_type 1 --prune_quant --w_bits 8 --a_bits 8
- nin, quant_model, w8a8
python bn_fuse.py --model_type 0 --w_bits 8 --a_bits 8
- nin_gc, quant_model, w8a8, 非对称, 层级
python bn_fuse.py --model_type 0 --w_bits 8 --a_bits 8 --q_type 1 --q_level 1
bn_fused_model_test(对quant_bn_fused_model_train和quant_bn_fused_model_inference进行测试)
python bn_fused_model_test.py
设备选取
现支持cpu、gpu(单卡、多卡)
--cpu 使用cpu,--gpu_id 使用并选择gpu
- cpu
python main.py --cpu
- gpu单卡
python main.py --gpu_id 0
或
python main.py --gpu_id 1
- gpu多卡
python main.py --gpu_id 0,1
或
python main.py --gpu_id 0,1,2
默认,使用服务器全卡
部署
TensorRT
目前仅提供相关核心模块代码,后续再加入完整可运行demo
相关解读
迁移
量化训练
LeNet example
quant_test_manual.py
A model can be quantized(High-Bit(>2b)、Low-Bit(≤2b)/Ternary and Binary) by simply replacing op with quant_op.
import torch.nn as nn
import torch.nn.functional as F
# some base_op, such as ``Add``、``Concat``
from micronet.base_module.op import *
# ``quantize`` is quant_module, ``QuantConv2d``, ``QuantLinear``, ``QuantMaxPool2d``, ``QuantReLU`` are quant_op
from micronet.compression.quantization.wbwtab.quantize import (
QuantConv2d as quant_conv_wbwtab,
)
from micronet.compression.quantization.wbwtab.quantize import (
ActivationQuantizer as quant_relu_wbwtab,
)
from micronet.compression.quantization.wqaq.dorefa.quantize import (
QuantConv2d as quant_conv_dorefa,
)
from micronet.compression.quantization.wqaq.dorefa.quantize import (
QuantLinear as quant_linear_dorefa,
)
from micronet.compression.quantization.wqaq.iao.quantize import (
QuantConv2d as quant_conv_iao,
)
from micronet.compression.quantization.wqaq.iao.quantize import (
QuantLinear as quant_linear_iao,
)
from micronet.compression.quantization.wqaq.iao.quantize import (
QuantMaxPool2d as quant_max_pool_iao,
)
from micronet.compression.quantization.wqaq.iao.quantize import (
QuantReLU as quant_relu_iao,
)
class LeNet(nn.Module):
def __init__(self):
super(LeNet, self).__init__()
self.conv1 = nn.Conv2d(1, 10, kernel_size=5)
self.conv2 = nn.Conv2d(10, 20, kernel_size=5)
self.fc1 = nn.Linear(320, 50)
self.fc2 = nn.Linear(50, 10)
self.max_pool = nn.MaxPool2d(kernel_size=2)
self.relu = nn.ReLU(inplace=True)
def forward(self, x):
x = self.relu(self.max_pool(self.conv1(x)))
x = self.relu(self.max_pool(self.conv2(x)))
x = x.view(-1, 320)
x = self.relu(self.fc1(x))
x = F.dropout(x, training=self.training)
x = self.fc2(x)
return F.log_softmax(x, dim=1)
class QuantLeNetWbWtAb(nn.Module):
def __init__(self):
super(QuantLeNetWbWtAb, self).__init__()
self.conv1 = quant_conv_wbwtab(1, 10, kernel_size=5)
self.conv2 = quant_conv_wbwtab(10, 20, kernel_size=5)
self.fc1 = nn.Linear(320, 50)
self.fc2 = nn.Linear(50, 10)
self.max_pool = nn.MaxPool2d(kernel_size=2)
self.relu = quant_relu_wbwtab()
def forward(self, x):
x = self.relu(self.max_pool(self.conv1(x)))
x = self.relu(self.max_pool(self.conv2(x)))
x = x.view(-1, 320)
x = self.relu(self.fc1(x))
x = F.dropout(x, training=self.training)
x = self.fc2(x)
return F.log_softmax(x, dim=1)
class QuantLeNetDoReFa(nn.Module):
def __init__(self):
super(QuantLeNetDoReFa, self).__init__()
self.conv1 = quant_conv_dorefa(1, 10, kernel_size=5)
self.conv2 = quant_conv_dorefa(10, 20, kernel_size=5)
self.fc1 = quant_linear_dorefa(320, 50)
self.fc2 = quant_linear_dorefa(50, 10)
self.max_pool = nn.MaxPool2d(kernel_size=2)
self.relu = nn.ReLU(inplace=True)
def forward(self, x):
x = self.relu(self.max_pool(self.conv1(x)))
x = self.relu(self.max_pool(self.conv2(x)))
x = x.view(-1, 320)
x = self.relu(self.fc1(x))
x = F.dropout(x, training=self.training)
x = self.fc2(x)
return F.log_softmax(x, dim=1)
class QuantLeNetIAO(nn.Module):
def __init__(self):
super(QuantLeNetIAO, self).__init__()
self.conv1 = quant_conv_iao(1, 10, kernel_size=5)
self.conv2 = quant_conv_iao(10, 20, kernel_size=5)
self.fc1 = quant_linear_iao(320, 50)
self.fc2 = quant_linear_iao(50, 10)
self.max_pool = quant_max_pool_iao(kernel_size=2)
self.relu = nn.ReLU(inplace=True)
def forward(self, x):
x = self.relu(self.max_pool(self.conv1(x)))
x = self.relu(self.max_pool(self.conv2(x)))
x = x.view(-1, 320)
x = self.relu(self.fc1(x))
x = F.dropout(x, training=self.training)
x = self.fc2(x)
return F.log_softmax(x, dim=1)
lenet = LeNet()
quant_lenet_wbwtab = QuantLeNetWbWtAb()
quant_lenet_dorefa = QuantLeNetDoReFa()
quant_lenet_iao = QuantLeNetIAO()
print("***ori_model***\n", lenet)
print("\n***quant_model_wbwtab***\n", quant_lenet_wbwtab)
print("\n***quant_model_dorefa***\n", quant_lenet_dorefa)
print("\n***quant_model_iao***\n", quant_lenet_iao)
print("\nquant_model is ready")
print("micronet is ready")
quant_test_auto.py
A model can be quantized(High-Bit(>2b)、Low-Bit(≤2b)/Ternary and Binary) by simply using micronet.compression.quantization.quantize.prepare(model).
import torch.nn as nn
import torch.nn.functional as F
# some base_op, such as ``Add``、``Concat``
from micronet.base_module.op import *
import micronet.compression.quantization.wqaq.dorefa.quantize as quant_dorefa
import micronet.compression.quantization.wqaq.iao.quantize as quant_iao
class LeNet(nn.Module):
def __init__(self):
super(LeNet, self).__init__()
self.conv1 = nn.Conv2d(1, 10, kernel_size=5)
self.conv2 = nn.Conv2d(10, 20, kernel_size=5)
self.fc1 = nn.Linear(320, 50)
self.fc2 = nn.Linear(50, 10)
self.max_pool = nn.MaxPool2d(kernel_size=2)
self.relu = nn.ReLU(inplace=True)
def forward(self, x):
x = self.relu(self.max_pool(self.conv1(x)))
x = self.relu(self.max_pool(self.conv2(x)))
x = x.view(-1, 320)
x = self.relu(self.fc1(x))
x = F.dropout(x, training=self.training)
x = self.fc2(x)
return F.log_softmax(x, dim=1)
"""
--w_bits --a_bits, 权重W和特征A量化位数
--q_type, 量化类型(0-对称, 1-非对称)
--q_level, 权重量化级别(0-通道级, 1-层级)
--weight_observer, weight_observer选择(0-MinMaxObserver, 1-MovingAverageMinMaxObserver)
--bn_fuse, 量化中bn融合标志
--bn_fuse_calib, 量化中bn融合校准标志
--pretrained_model, 预训练浮点模型
--qaft, qaft标志
--ptq, ptq标志
--percentile, ptq校准的比例
"""
lenet = LeNet()
quant_lenet_dorefa = quant_dorefa.prepare(lenet, inplace=False, a_bits=8, w_bits=8)
quant_lenet_iao = quant_iao.prepare(
lenet,
inplace=False,
a_bits=8,
w_bits=8,
q_type=0,
q_level=0,
weight_observer=0,
bn_fuse=False,
bn_fuse_calib=False,
pretrained_model=False,
qaft=False,
ptq=False,
percentile=0.9999,
)
# if ptq == False, do qat/qaft, need train
# if ptq == True, do ptq, don't need train
# you can refer to micronet/compression/quantization/wqaq/iao/main.py
print("***ori_model***\n", lenet)
print("\n***quant_model_dorefa***\n", quant_lenet_dorefa)
print("\n***quant_model_iao***\n", quant_lenet_iao)
print("\nquant_model is ready")
print("micronet is ready")
test
quant_test_manual
python -c "import micronet; micronet.quant_test_manual()"
quant_test_auto
python -c "import micronet; micronet.quant_test_auto()"
when outputting "quant_model is ready", micronet is ready.
量化推理
模型压缩数据对比(仅供参考)
以下为cifar10示例,可在更冗余模型、更大数据集上尝试其他组合压缩方式
| 类型 | W(Bits) | A(Bits) | Acc | GFLOPs | Para(M) | Size(MB) | 压缩率 | 损失 |
|---|---|---|---|---|---|---|---|---|
| 原模型(nin) | FP32 | FP32 | 91.01% | 0.15 | 0.67 | 2.68 | *** | *** |
| 采用分组卷积结构(nin_gc) | FP32 | FP32 | 91.04% | 0.15 | 0.58 | 2.32 | 13.43% | -0.03% |
| 剪枝 | FP32 | FP32 | 90.26% | 0.09 | 0.32 | 1.28 | 52.24% | 0.75% |
| 量化 | 1 | FP32 | 90.93% | *** | 0.58 | 0.204 | 92.39% | 0.08% |
| 量化 | 1.5 | FP32 | 91% | *** | 0.58 | 0.272 | 89.85% | 0.01% |
| 量化 | 1 | 1 | 86.23% | *** | 0.58 | 0.204 | 92.39% | 4.78% |
| 量化 | 1.5 | 1 | 86.48% | *** | 0.58 | 0.272 | 89.85% | 4.53% |
| 量化(DoReFa) | 8 | 8 | 91.03% | *** | 0.58 | 0.596 | 77.76% | -0.02% |
| 量化(IAO,全量化,symmetric/per-channel/bn_fuse) | 8 | 8 | 90.99% | *** | 0.58 | 0.596 | 77.76% | 0.02% |
| 分组+剪枝+量化 | 1.5 | 1 | 86.13% | *** | 0.32 | 0.19 | 92.91% | 4.88% |
--train_batch_size 256, 单卡
相关资料
压缩
量化
QAT
二值
-
BinarizedNeuralNetworks: TrainingNeuralNetworkswithWeightsand ActivationsConstrainedto +1 or−1
-
XNOR-Net:ImageNetClassificationUsingBinary ConvolutionalNeuralNetworks
三值
High-Bit
- DoReFa-Net: Training Low Bitwidth Convolutional Neural Networks with Low Bitwidth Gradients
- Quantization and Training of Neural Networks for Efficient Integer-Arithmetic-Only Inference
- Quantizing deep convolutional networks for efficient inference: A whitepaper
PTQ
High-Bit
剪枝
- Learning Efficient Convolutional Networks through Network Slimming
- RETHINKING THE VALUE OF NETWORK PRUNING
适配专用芯片的模型压缩
部署
TensorRT
后续
- tensorrt完整demo
- 其他压缩算法(量化/剪枝/蒸馏/NAS等)
- 其他部署框架(mnn/tnn/tengine等)
- 压缩 —> 部署
Open Source Agenda is not affiliated with "Model Compression" Project. README Source: 666DZY666/micronet
Stars
2,177
Open Issues
92
Last Commit
2 years ago
Repository
License
Tags
Bnn
Convolutional Networks
Dorefa
Group Convolution
Integer Arithmetic Only
Model Compression
Network In Network
Network Slimming
Neuromorphic Computing
Pruning
Pytorch
Quan Batch Normalization Folding
Quantization
Quantization Aware Training
Twn
Xnor Net
Batch Normalization Fuse
Onnx
Post Training Quantization
Tensorrt
Tensorrt Int8 Python
Open Source Agenda Badge
