Skip to content

Latest commit

 

History

History
 
 

classification_and_detection

MLPerf Inference Benchmarks for Image Classification and Object Detection Tasks

This is the reference implementation for MLPerf Inference benchmarks.

You can find a short tutorial how to use this benchmark here.

Supported Models

model framework accuracy dataset model link model source precision notes
resnet50-v1.5 tensorflow 76.456% imagenet2012 validation from zenodo mlperf, tensorflow fp32 NHWC. More information on resnet50 v1.5 can be found here.
resnet50-v1.5 onnx, pytorch 76.456% imagenet2012 validation from zenodo from zenodo converted with this script fp32 NCHW, tested on pytorch and onnxruntime
mobilenet-v1 tensorflow 71.676% imagenet2012 validation from zenodo from tensorflow fp32 NHWC
mobilenet-v1 quantized tensorflow 70.694% imagenet2012 validation from zenodo from tensorflow int8 NHWC
mobilenet-v1 tflite 71.676% imagenet2012 validation from zenodo from tensorflow fp32 NHWC
mobilenet-v1 quantized tflite 70.762% imagenet2012 validation from zenodo from tensorflow int8 NHWC
mobilenet-v1 onnx, pytorch 71.676% imagenet2012 validation from zenodo from tensorflow converted with this script fp32 NCHW, tested on pytorch and onnxruntime
mobilenet-v1 onnx, pytorch 70.9% imagenet2012 validation from zenodo ??? int8 ???
ssd-mobilenet 300x300 tensorflow mAP 0.23 coco resized to 300x300 from tensorflow from tensorflow fp32 NHWC
ssd-mobilenet 300x300 quantized finetuned tensorflow mAP 0.23594 coco resized to 300x300 from zenodo Habana int8 ???
ssd-mobilenet 300x300 symmetrically quantized finetuned tensorflow mAP 0.234 coco resized to 300x300 from zenodo Habana int8 ???
ssd-mobilenet 300x300 pytorch mAP 0.23 coco resized to 300x300 from zenodo from tensorflow fp32 NHWC
ssd-mobilenet 300x300 onnx mAP 0.23 coco resized to 300x300 from zenodo from tensorflow converted with this script fp32 NHWC, tested on onnxruntime, some runtime warnings
ssd-mobilenet 300x300 onnx, pytorch mAP 0.23 coco resized to 300x300 from zenodo ??? int8 ???
ssd-resnet34 1200x1200 tensorflow mAP 0.20 coco resized to 1200x1200 from zenodo from mlperf, training model fp32 NCHW
ssd-resnet34 1200x1200 pytorch mAP 0.20 coco resized to 1200x1200 from zenodo from mlperf fp32 NCHW
ssd-resnet34 1200x1200 onnx mAP 0.20 coco resized to 1200x1200 from zenodo from mlperf converted using the these instructions fp32 Works but needs more testing

Disclaimer

This benchmark app is a reference implementation that is not meant to be the fastest implementation possible. It is written in python which might make it less suitable for lite models like mobilenet or large number of cpu's. We are thinking to provide a c++ implementation with identical functionality in the near future.

Tools for preparing datasets and validating accuracy

The reference implementation includes all required pre-processing of datasets. It also includes a --accuracy option to validate accuracy as required by mlperf. If you are not using the reference implementation, a few scripts will help:

Prepare the coco dataset

The tool is here. You can run it for ssd-mobilenet like:

python upscale_coco.py --inputs /data/coco/ --outputs /data/coco-300 --size 300 300 --format png

and for ssd-resnet34 like:

python upscale_coco.py --inputs /data/coco/ --outputs /data/coco-1200 --size 1200 1200 --format png

Prepare the imagenet dataset

to come.

Validate accuracy for resnet50 and mobilenet benchmarks

The tool is here. You can run it like:

python tools/accuracy-imagenet.py --mlperf-accuracy-file mlperf_log_accuracy.json --imagenet-val-file /data/imagenet2012/val_map.txt

Validate accuracy for ssd-mobilenet and ssd-resnet34 benchmarks

The tool is here. You can run it like:

python tools/accuracy-coco.py --mlperf-accuracy-file mlperf_log_accuracy.json --coco-dir /data/coco

Datasets

dataset download link
imagenet2012 (validation) http://image-net.org/challenges/LSVRC/2012/
coco (validation) http://images.cocodataset.org/zips/val2017.zip

Using Collective Knowledge (CK)

Alternatively, you can download the datasets using the Collective Knowledge framework (CK) for collaborative and reproducible research.

First, install CK and pull its repositories containing dataset packages:

$ python -m pip install ck --user
$ ck version
V1.9.8.1
$ ck pull repo:ck-env

ImageNet 2012 validation dataset

Download the original dataset and auxiliaries:

$ ck install package --tags=image-classification,dataset,imagenet,val,original,full
$ ck install package --tags=image-classification,dataset,imagenet,aux

Copy the labels next to the images:

$ ck locate env --tags=image-classification,dataset,imagenet,val,original,full
/home/dvdt/CK-TOOLS/dataset-imagenet-ilsvrc2012-val
$ ck locate env --tags=image-classification,dataset,imagenet,aux
/home/dvdt/CK-TOOLS/dataset-imagenet-ilsvrc2012-aux
$ cp `ck locate env --tags=aux`/val.txt `ck locate env --tags=val`/val_map.txt

COCO 2017 validation dataset

$ ck install package --tags=object-detection,dataset,coco,2017,val,original
$ ck locate env --tags=object-detection,dataset,coco,2017,val,original
/home/dvdt/CK-TOOLS/dataset-coco-2017-val

Prerequisites and Installation

We support tensorfow+tflite, onnxruntime and pytoch backend's with the same benchmark tool. Support for other backends can be easily added.

The following steps are only needed if you run the benchmark without Docker.

Python 3.5, 3.6 or 3.7 is supported and we recommend to use Anaconda (See Dockerfile for a minimal Anaconda install).

Install the desired backend. For tensorflow:

pip install tensorflow or pip install tensorflow-gpu

For onnxruntime:

pip install onnxruntime or pip install onnxruntime-gpu

Build and install the benchmark:

cd ../../loadgen; CFLAGS="-std=c++14" python setup.py develop --user; cd ../vision/classification_and_detection

python setup.py develop

Running the benchmark

One time setup

Download the model and dataset for the model you want to benchmark.

Both local and docker environment need to set 2 environment variables:

export MODEL_DIR=YourModelFileLocation
export DATA_DIR=YourImageNetLocation

Run local

./run_local.sh backend model device

backend is one of [tf|onnxruntime|pytorch|tflite]
model is one of [resnet50|mobilenet|ssd-mobilenet|ssd-resnet34]
device is one of [cpu|gpu]


For example:

./run_local.sh tf resnet50 gpu

Run as Docker container

./run_and_time.sh backend model device

backend is one of [tf|onnxruntime|pytorch|tflite]
model is one of [resnet50|mobilenet|ssd-mobilenet|ssd-resnet34]
device is one of [cpu|gpu]

For example:

./run_and_time.sh tf resnet50 gpu

This will build and run the benchmark.

Examples for testing

During development running the full benchmark is unpractical. Some options to help:

--count limits the number of items in the dataset used for accuracy pass

--time limits the time the benchmark runs

--accuracy enables accuracy pass

--max-latency the latency used for Server mode

So if you want to tune for example Server mode, try:

./run_local.sh tf resnet50 gpu --count 100 --time 60 --scenario Server --qps 200 --max-latency 0.1
or
./run_local.sh tf ssd-mobilenet gpu --count 100 --time 60 --scenario Server --qps 100 --max-latency 0.1

If you want run with accuracy pass, try:

./run_local.sh tf ssd-mobilenet gpu --accuracy --time 60 --scenario Server --qps 100 --max-latency 0.2

Usage

usage: main.py [-h]
    [--mlperf_conf ../../mlperf.conf]
    [--user_conf user.conf]
    [--dataset {imagenet,imagenet_mobilenet,coco,coco-300,coco-1200,coco-1200-onnx,coco-1200-pt,coco-1200-tf}]
    --dataset-path DATASET_PATH [--dataset-list DATASET_LIST]
    [--data-format {NCHW,NHWC}]
    [--profile {defaults,resnet50-tf,resnet50-onnxruntime,mobilenet-tf,mobilenet-onnxruntime,ssd-mobilenet-tf,ssd-mobilenet-onnxruntime,ssd-resnet34-tf,ssd-resnet34-pytorch,ssd-resnet34-onnxruntime}]
    [--scenario list of SingleStream,MultiStream,Server,Offline]
    [--max-batchsize MAX_BATCHSIZE]
    --model MODEL [--output OUTPUT] [--inputs INPUTS]
    [--outputs OUTPUTS] [--backend BACKEND] [--threads THREADS]
    [--time TIME] [--count COUNT] [--qps QPS]
    [--max-latency MAX_LATENCY] [--cache CACHE] [--accuracy]

--mlperf_conf the mlperf config file to use for rules compliant parameters, defaults to ../../mlperf.conf

--user_conf the user config file to use for user LoadGen settings such as target QPS, defaults to user.conf

--dataset use the specified dataset. Currently we only support ImageNet.

--dataset-path path to the dataset.

--data-format {NCHW,NHWC} data-format of the model (default: the backends prefered format).

--scenario {SingleStream,MultiStream,Server,Offline} comma separated list of benchmark modes.

--profile {resnet50-tf,resnet50-onnxruntime,mobilenet-tf,mobilenet-onnxruntime,ssd-mobilenet-tf,ssd-mobilenet-onnxruntime,ssd-resnet34-tf,ssd-resnet34-onnxruntime} this fills in default command line options with the once specified in the profile. Command line options that follow may override the those.

--model MODEL the model file.

--inputs INPUTS comma separated input name list in case the model format does not provide the input names. This is needed for tensorflow since the graph does not specify the inputs.

--outputs OUTPUTS comma separated output name list in case the model format does not provide the output names. This is needed for tensorflow since the graph does not specify the outputs.

--output OUTPUT] location of the JSON output.

--backend BACKEND which backend to use. Currently supported is tensorflow, onnxruntime, pytorch and tflite.

--threads THREADS number of worker threads to use (default: the number of processors in the system).

--count COUNT Number of images the dataset we use (default: use all images in the dataset).

--qps QPS Expected QPS.

--max-latency MAX_LATENCY comma separated list of which latencies (in seconds) we try to reach in the 99 percentile (deault: 0.01,0.05,0.100).

--max-batchsize MAX_BATCHSIZE maximum batchsize we generate to backend (default: 128).

License

Apache License 2.0