首页
学习
活动
专区
工具
TVP
发布
社区首页 >专栏 >TVM 加速模型,优化推断

TVM 加速模型,优化推断

作者头像
GoCoding
发布2022-05-27 13:52:34
5600
发布2022-05-27 13:52:34
举报
文章被收录于专栏:GoCodingGoCoding

TVM 是一个开源深度学习编译器,可适用于各类 CPUs, GPUs 及其他专用加速器。它的目标是使得我们能够在任何硬件上优化和运行自己的模型。不同于深度学习框架关注模型生产力,TVM 更关注模型在硬件上的性能和效率。

本文只简单介绍 TVM 的编译流程,及如何自动调优自己的模型。更深入了解,可见 TVM 官方内容:

  • 文档: https://tvm.apache.org/docs/
  • 源码: https://github.com/apache/tvm

编译流程

TVM 文档 Design and Architecture[1] 讲述了实例编译流程、逻辑结构组件、设备目标实现等。其中流程见下图:

从高层次上看,包含了如下步骤:

  • 导入(Import):前端组件将模型提取进 IRModule,其是模型内部表示(IR)的函数集合。
  • 转换(Transformation):编译器将 IRModule 转换为另一个功能等效或近似等效(如量化情况下)的 IRModule。大多转换都是独立于目标(后端)的。TVM 也允许目标影响转换通道的配置。
  • 目标翻译(Target Translation):编译器翻译(代码生成) IRModule 到目标上的可执行格式。目标翻译结果被封装为 runtime.Module,可以在目标运行时环境中导出、加载和执行。
  • 运行时执行(Runtime Execution):用户加载一个 runtime.Module 并在支持的运行时环境中运行编译好的函数。

调优模型

TVM 文档 User Tutorial[2] 从怎么编译优化模型开始,逐步深入到 TE, TensorIR, Relay 等更底层的逻辑结构组件。

这里只讲下如何用 AutoTVM 自动调优模型,实际了解 TVM 编译、调优、运行模型的过程。原文见 Compiling and Optimizing a Model with the Python Interface (AutoTVM)[3]

准备 TVM

首先,安装 TVM。可见文档 Installing TVM[4],或笔记「TVM 安装」[5]

之后,即可通过 TVM Python API 来调优模型。我们先导入如下依赖:

import onnx
from tvm.contrib.download import download_testdata
from PIL import Image
import numpy as np
import tvm.relay as relay
import tvm
from tvm.contrib import graph_executor

准备模型,并加载

获取预训练的 ResNet-50 v2 ONNX 模型,并加载:

model_url = "".join(
    [
        "https://github.com/onnx/models/raw/",
        "main/vision/classification/resnet/model/",
        "resnet50-v2-7.onnx",
    ]
)

model_path = download_testdata(model_url, "resnet50-v2-7.onnx", module="onnx")
onnx_model = onnx.load(model_path)

准备图片,并前处理

获取一张测试图片,并前处理成 224x224 NCHW 格式:

img_url = "https://s3.amazonaws.com/model-server/inputs/kitten.jpg"
img_path = download_testdata(img_url, "imagenet_cat.png", module="data")

# Resize it to 224x224
resized_image = Image.open(img_path).resize((224, 224))
img_data = np.asarray(resized_image).astype("float32")

# Our input image is in HWC layout while ONNX expects CHW input, so convert the array
img_data = np.transpose(img_data, (2, 0, 1))

# Normalize according to the ImageNet input specification
imagenet_mean = np.array([0.485, 0.456, 0.406]).reshape((3, 1, 1))
imagenet_stddev = np.array([0.229, 0.224, 0.225]).reshape((3, 1, 1))
norm_img_data = (img_data / 255 - imagenet_mean) / imagenet_stddev

# Add the batch dimension, as we are expecting 4-dimensional input: NCHW.
img_data = np.expand_dims(norm_img_data, axis=0)

编译模型,用 TVM Relay

TVM 导入 ONNX 模型成 Relay,并创建 TVM 图模型:

target = input("target [llvm]: ")
if not target:
    target = "llvm"
    # target = "llvm -mcpu=core-avx2"
    # target = "llvm -mcpu=skylake-avx512"

# The input name may vary across model types. You can use a tool
# like Netron to check input names
input_name = "data"
shape_dict = {input_name: img_data.shape}

mod, params = relay.frontend.from_onnx(onnx_model, shape_dict)

with tvm.transform.PassContext(opt_level=3):
    lib = relay.build(mod, target=target, params=params)

dev = tvm.device(str(target), 0)
module = graph_executor.GraphModule(lib["default"](dev ""default""))

其中 target 是目标硬件平台。llvm 指用 CPU,建议指明架构指令集,可更优化性能。如下命令可查看 CPU:

$ llc --version | grep CPU
  Host CPU: skylake
$ lscpu

或直接上厂商网站(如 Intel® Products[6])查看产品参数。

运行模型,用 TVM Runtime

用 TVM Runtime 运行模型,进行预测:

dtype = "float32"
module.set_input(input_name, img_data)
module.run()
output_shape = (1, 1000)
tvm_output = module.get_output(0, tvm.nd.empty(output_shape)).numpy()

收集优化前的性能数据

收集优化前的性能数据:

import timeit

timing_number = 10
timing_repeat = 10
unoptimized = (
    np.array(timeit.Timer(lambda: module.run()).repeat(repeat=timing_repeat, number=timing_number))
    * 1000
    / timing_number
)
unoptimized = {
    "mean": np.mean(unoptimized),
    "median": np.median(unoptimized),
    "std": np.std(unoptimized),
}

print(unoptimized)

之后,用以对比优化后的性能。

后处理输出,得知预测结果

输出的预测结果,后处理成可读的分类结果:

from scipy.special import softmax

# Download a list of labels
labels_url = "https://s3.amazonaws.com/onnx-model-zoo/synset.txt"
labels_path = download_testdata(labels_url, "synset.txt", module="data")

with open(labels_path, "r") as f:
    labels = [l.rstrip() for l in f]

# Open the output and read the output tensor
scores = softmax(tvm_output)
scores = np.squeeze(scores)
ranks = np.argsort(scores)[::-1]
for rank in ranks[0:5]:
    print("class='%s' with probability=%f" % (labels[rank], scores[rank]))

调优模型,获取调优数据

于目标硬件平台,用 AutoTVM 自动调优,获取调优数据:

import tvm.auto_scheduler as auto_scheduler
from tvm.autotvm.tuner import XGBTuner
from tvm import autotvm

number = 10
repeat = 1
min_repeat_ms = 0  # since we're tuning on a CPU, can be set to 0
timeout = 10  # in seconds

# create a TVM runner
runner = autotvm.LocalRunner(
    number=number,
    repeat=repeat,
    timeout=timeout,
    min_repeat_ms=min_repeat_ms,
    enable_cpu_cache_flush=True,
)

tuning_option = {
    "tuner": "xgb",
    "trials": 10,
    "early_stopping": 100,
    "measure_option": autotvm.measure_option(
        builder=autotvm.LocalBuilder(build_func="default"), runner=runner
    ),
    "tuning_records": "resnet-50-v2-autotuning.json",
}

# begin by extracting the tasks from the onnx model
tasks = autotvm.task.extract_from_program(mod["main"], target=target, params=params)

# Tune the extracted tasks sequentially.
for i, task in enumerate(tasks):
    prefix = "[Task %2d/%2d] " % (i + 1, len(tasks))
    tuner_obj = XGBTuner(task, loss_type="rank")
    tuner_obj.tune(
        n_trial=min(tuning_option["trials"], len(task.config_space)),
        early_stopping=tuning_option["early_stopping"],
        measure_option=tuning_option["measure_option"],
        callbacks=[
            autotvm.callback.progress_bar(tuning_option["trials"], prefix=prefix),
            autotvm.callback.log_to_file(tuning_option["tuning_records"]),
        ],
    )

上述 tuning_option 选用的 XGBoost Grid 算法进行优化搜索,数据记录进 tuning_records

重编译模型,用调优数据

重新编译出一个优化模型,依据调优数据:

with autotvm.apply_history_best(tuning_option["tuning_records"]):
    with tvm.transform.PassContext(opt_level=3, config={}):
        lib = relay.build(mod, target=target, params=params)

dev = tvm.device(str(target), 0)
module = graph_executor.GraphModule(lib["default"](dev ""default""))


# Verify that the optimized model runs and produces the same results

dtype = "float32"
module.set_input(input_name, img_data)
module.run()
output_shape = (1, 1000)
tvm_output = module.get_output(0, tvm.nd.empty(output_shape)).numpy()

scores = softmax(tvm_output)
scores = np.squeeze(scores)
ranks = np.argsort(scores)[::-1]
for rank in ranks[0:5]:
    print("class='%s' with probability=%f" % (labels[rank], scores[rank]))

对比调优与非调优模型

收集优化后的性能数据,与优化前的对比:

import timeit

timing_number = 10
timing_repeat = 10
optimized = (
    np.array(timeit.Timer(lambda: module.run()).repeat(repeat=timing_repeat, number=timing_number))
    * 1000
    / timing_number
)
optimized = {"mean": np.mean(optimized), "median": np.median(optimized), "std": np.std(optimized)}

print("optimized: %s" % (optimized))
print("unoptimized: %s" % (unoptimized))

调优模型,整个过程的运行结果,如下:

$ time python autotvm_tune.py
# TVM 编译运行模型
## Downloading and Loading the ONNX Model
## Downloading, Preprocessing, and Loading the Test Image
## Compile the Model With Relay
target [llvm]: llvm -mcpu=core-avx2
One or more operators have not been tuned. Please tune your model for better performance. Use DEBUG logging level to see more details.
## Execute on the TVM Runtime
## Collect Basic Performance Data
{'mean': 44.97057118016528, 'median': 42.52320024970686, 'std': 6.870915251002107}
## Postprocess the output
class='n02123045 tabby, tabby cat' with probability=0.621104
class='n02123159 tiger cat' with probability=0.356378
class='n02124075 Egyptian cat' with probability=0.019712
class='n02129604 tiger, Panthera tigris' with probability=0.001215
class='n04040759 radiator' with probability=0.000262
# AutoTVM 调优模型 [Y/n]
## Tune the model
[Task  1/25]  Current/Best:  156.96/ 353.76 GFLOPS | Progress: (10/10) | 4.78 s Done.
[Task  2/25]  Current/Best:   54.66/ 241.25 GFLOPS | Progress: (10/10) | 2.88 s Done.
[Task  3/25]  Current/Best:  116.71/ 241.30 GFLOPS | Progress: (10/10) | 3.48 s Done.
[Task  4/25]  Current/Best:  119.92/ 184.18 GFLOPS | Progress: (10/10) | 3.48 s Done.
[Task  5/25]  Current/Best:   48.92/ 158.38 GFLOPS | Progress: (10/10) | 3.13 s Done.
[Task  6/25]  Current/Best:  156.89/ 230.95 GFLOPS | Progress: (10/10) | 2.82 s Done.
[Task  7/25]  Current/Best:   92.33/ 241.99 GFLOPS | Progress: (10/10) | 2.40 s Done.
[Task  8/25]  Current/Best:   50.04/ 331.82 GFLOPS | Progress: (10/10) | 2.64 s Done.
[Task  9/25]  Current/Best:  188.47/ 409.93 GFLOPS | Progress: (10/10) | 4.44 s Done.
[Task 10/25]  Current/Best:   44.81/ 181.67 GFLOPS | Progress: (10/10) | 2.32 s Done.
[Task 11/25]  Current/Best:   83.74/ 312.66 GFLOPS | Progress: (10/10) | 2.74 s Done.
[Task 12/25]  Current/Best:   96.48/ 294.40 GFLOPS | Progress: (10/10) | 2.82 s Done.
[Task 13/25]  Current/Best:  123.74/ 354.34 GFLOPS | Progress: (10/10) | 2.62 s Done.
[Task 14/25]  Current/Best:   23.76/ 178.71 GFLOPS | Progress: (10/10) | 2.90 s Done.
[Task 15/25]  Current/Best:  119.18/ 534.63 GFLOPS | Progress: (10/10) | 2.49 s Done.
[Task 16/25]  Current/Best:  101.24/ 172.92 GFLOPS | Progress: (10/10) | 2.49 s Done.
[Task 17/25]  Current/Best:  309.85/ 309.85 GFLOPS | Progress: (10/10) | 2.69 s Done.
[Task 18/25]  Current/Best:   54.45/ 368.31 GFLOPS | Progress: (10/10) | 2.46 s Done.
[Task 19/25]  Current/Best:   78.69/ 162.43 GFLOPS | Progress: (10/10) | 3.29 s Done.
[Task 20/25]  Current/Best:   40.78/ 317.50 GFLOPS | Progress: (10/10) | 4.52 s Done.
[Task 21/25]  Current/Best:  169.03/ 296.36 GFLOPS | Progress: (10/10) | 3.95 s Done.
[Task 22/25]  Current/Best:   90.96/ 210.43 GFLOPS | Progress: (10/10) | 2.28 s Done.
[Task 23/25]  Current/Best:   48.93/ 217.36 GFLOPS | Progress: (10/10) | 2.87 s Done.
[Task 25/25]  Current/Best:    0.00/   0.00 GFLOPS | Progress: (0/10) | 0.00 s Done.
[Task 25/25]  Current/Best:   25.50/  33.86 GFLOPS | Progress: (10/10) | 9.28 s Done.
## Compiling an Optimized Model with Tuning Data
class='n02123045 tabby, tabby cat' with probability=0.621104
class='n02123159 tiger cat' with probability=0.356378
class='n02124075 Egyptian cat' with probability=0.019712
class='n02129604 tiger, Panthera tigris' with probability=0.001215
class='n04040759 radiator' with probability=0.000262
## Comparing the Tuned and Untuned Models
optimized: {'mean': 34.736288779822644, 'median': 34.547542000655085, 'std': 0.5144378649382363}
unoptimized: {'mean': 44.97057118016528, 'median': 42.52320024970686, 'std': 6.870915251002107}

real    3m23.904s
user    5m2.900s
sys     5m37.099s

对比性能数据,可以发现:调优模型的运行速度更快、更平稳。

参考

  • 笔记: start-ai-compiler[7]
  • 资料:
    • 2020 / The Deep Learning Compiler: A Comprehensive Survey[8]
      • [译] 深度学习编译器综述[9]
    • 2018 / TVM: An Automated End-to-End Optimizing Compiler for Deep Learning[10]
      • [译] TVM: 一个自动的端到端深度学习优化编译器[11]

脚注

[1]Design and Architecture: https://tvm.apache.org/docs/arch/index.html

[2]User Tutorial: https://tvm.apache.org/docs/tutorial/index.html

[3]Compiling and Optimizing a Model with the Python Interface (AutoTVM): https://tvm.apache.org/docs/tutorial/autotvm_relay_x86.html

[4]Installing TVM: https://tvm.apache.org/docs/tutorial/install.html

[5]「TVM 安装」: https://github.com/ikuokuo/start-ai-compiler/blob/main/docs/tvm/tvm_install.md

[6]Intel® Products: https://www.intel.com/content/www/us/en/products/overview.html

[7]start-ai-compiler: https://github.com/ikuokuo/start-ai-compiler#%E7%AC%94%E8%AE%B0

[8]2020 / The Deep Learning Compiler: A Comprehensive Survey: https://arxiv.org/abs/2002.03794

[9][译] 深度学习编译器综述: https://www.jianshu.com/p/ed372af7ef09

[10]2018 / TVM: An Automated End-to-End Optimizing Compiler for Deep Learning: https://www.usenix.org/conference/osdi18/presentation/chen

[11][译] TVM: 一个自动的端到端深度学习优化编译器: https://zhuanlan.zhihu.com/p/426994569

本文参与 腾讯云自媒体分享计划,分享自微信公众号。
原始发表:2022-05-22,如有侵权请联系 cloudcommunity@tencent.com 删除

本文分享自 GoCoding 微信公众号,前往查看

如有侵权,请联系 cloudcommunity@tencent.com 删除。

本文参与 腾讯云自媒体分享计划  ,欢迎热爱写作的你一起参与!

评论
登录后参与评论
0 条评论
热度
最新
推荐阅读
目录
  • 编译流程
  • 调优模型
    • 准备 TVM
      • 准备模型,并加载
        • 准备图片,并前处理
          • 编译模型,用 TVM Relay
            • 运行模型,用 TVM Runtime
              • 收集优化前的性能数据
                • 后处理输出,得知预测结果
                  • 调优模型,获取调优数据
                    • 重编译模型,用调优数据
                      • 对比调优与非调优模型
                      • 参考
                        • 脚注
                        领券
                        问题归档专栏文章快讯文章归档关键词归档开发者手册归档开发者手册 Section 归档