This is a collection of open source benchmarks used to evaluate PyTorch performance.
torchbenchmark/models
contains copies of popular or exemplary workloads which have been modified to:
(a) expose a standardized API for benchmark drivers, (b) optionally, enable backends such as torchinductor/torchscript,
(c) contain a miniature version of train/test data and a dependency install script.
The benchmark suite should be self contained in terms of dependencies, except for the torch products which are intended to be installed separately so different torch versions can be benchmarked.
We support Python 3.8+, and 3.11 is recommended. Conda is optional but suggested. To start with Python 3.11 in conda:
# Using your current conda environment:
conda install -y python=3.11
# Or, using a new conda environment:
conda create -n torchbenchmark python=3.11
conda activate torchbenchmark
If you are running NVIDIA GPU tests, we support both CUDA 11.8 and 12.1, and use CUDA 12.1 as default:
conda install -y -c pytorch magma-cuda121
Then install pytorch, torchvision, and torchaudio using conda:
conda install pytorch torchvision torchaudio pytorch-cuda=12.1 -c pytorch-nightly -c nvidia
Or use pip: (but don't mix and match pip and conda for the torch family of libs! - see notes below)
pip3 install --pre torch torchvision torchaudio --index-url https://download.pytorch.org/whl/nightly/cu121
Install the benchmark suite, which will recursively install dependencies for all the models. Currently, the repo is intended to be installed from the source tree.
git clone https://github.com/pytorch/benchmark
cd benchmark
python3 install.py
if you're interested in running torchbench as a library you can
python3 install.py
pip install git+https://www.github.com:pytorch/benchmark.git
or
python3 install.py
pip install . # add -e for an editable installation
The above
import torchbenchmark.models.densenet121
model, example_inputs = torchbenchmark.models.densenet121.Model(test="eval", device="cuda", batch_size=1).get_module()
model(*example_inputs)
Note that when building PyTorch from source, torchvision and torchaudio must also be built from source to make sure the C APIs match.
See detailed instructions to install torchvision here and torchaudio here.
Make sure to enable CUDA (by USE_CUDA=1
) if using CUDA.
Then,
git clone https://github.com/pytorch/benchmark
cd benchmark
python3 install.py
- Setup steps require network connectivity - make sure to enable a proxy if needed.
- We suggest using the latest PyTorch nightly releases to run the benchmark. Stable versions are NOT tested or maintained.
- torch, torchvision, and torchaudio must all be installed from the same build process. This means it isn't possible to mix conda torchvision with pip torch, or mix built-from-source torch with pip torchvision. It's important to match even the conda channel (nightly vs regular). This is due to the differences in the compilation process used by different packaging systems producing incompatible Python binary extensions.
Various sources of noise, such as interrupts, context switches, clock frequency scaling, etc. can all conspire to make benchmark results variable. It's important to understand the level of noise in your setup before drawing conclusions from benchmark data. While any machine can in principle be tuned up, the steps and end-results vary with OS, kernel, drivers, and hardware. To this end, torchbenchmark picks a favorite machine type it can support well, and provides utilities for automated tuning on that machine. In the future, we may support more machine types and would be happy for contributions here.
The currently supported machine type is an AWS g4dn.metal instance using Amazon Linux. This is one of the subsets of AWS instance types that supports processor state control, with documented tuning guides for Amazon Linux. Most if not all of these steps should be possible on Ubuntu but haven't been automated yet.
To tune your g4dn.metal Amazon Linux machine, run
sudo `which python` torchbenchmark/util/machine_config.py --configure
When running pytest (see below), the machine_config script is invoked to assert a proper configuration and log config info into the output json. It is possible to --ignore_machine_config
if running pytest without tuning is desired.
There are multiple ways for running the model benchmarks.
test.py
offers the simplest wrapper around the infrastructure for iterating through each model and installing and executing it.
test_bench.py
is a pytest-benchmark script that leverages the same infrastructure but collects benchmark statistics and supports pytest filtering.
userbenchmark
allows to develop and run customized benchmarks.
In each model repo, the assumption is that the user would already have all of the torch family of packages installed (torch, torchvision, torchaudio...) but it installs the rest of the dependencies for the model.
python3 test.py
will execute the APIs for each model, as a sanity check. For benchmarking, use test_bench.py
. It is based on unittest, and supports filtering via CLI.
For instance, to run the BERT model on CPU for the train execution mode:
python3 test.py -k "test_BERT_pytorch_train_cpu"
The test name follows the following pattern:
"test_" + <model_name> + "_" + {"train" | "eval" } + "_" + {"cpu" | "cuda"}
pytest test_bench.py
invokes the benchmark driver. See --help
for a complete list of options.
Some useful options include:
--benchmark-autosave
(or other save related flags) to get .json output-k <filter expression>
standard pytest filtering--collect-only
only show what tests would run, useful to see what models there are or debug your filter expression--cpu_only
if running on a local CPU machine and ignoring machine configuration checks
-k "test_train[NAME-cuda]"
for a particular flavor of a particular model-k "(BERT and (not cuda))"
for a more flexible approach to filtering
Note that test_bench.py
will eventually be deprecated as the userbenchmark
work evolve. Users are encouraged to explore and consider using userbenchmark.
The userbenchmark
allows you to develop your customized benchmarks with TorchBench models. Refer to the userbenchmark instructions to learn more on how you can create a new userbenchmark
. You can then use the run_benchmark.py
driver to drive the benchmark. e.g. python run_benchmark.py <benchmark_name>
. Run python run_benchmark.py —help
to find out available options.
Sometimes you may want to just run train or eval on a particular model, e.g. for debugging or profiling. Rather than relying on main implementations inside each model, run.py
provides a lightweight CLI for this purpose, building on top of the standard BenchmarkModel API.
python3 run.py <model> [-d {cpu,cuda}] [-t {eval,train}] [--profile]
Note: <model>
can be a full, exact name, or a partial string match.
If you're interested in using torchbench as a suite of models you can test, the easiest way to integrate it into your code/ci/tests would be something like
import torch
import importlib
import sys
# If your directory looks like this_file.py, benchmark/
sys.path.append("benchmark")
model_name = "torchbenchmark.models.stable_diffusion_text_encoder" # replace this by the name of the model you're working on
module = importlib.import_module(model_name)
benchmark_cls = getattr(module, "Model", None)
benchmark = benchmark_cls(test="eval", device = "cuda") # test = train or eval device = cuda or cpu
model, example = benchmark.get_module()
model(*example)
Currently, the models run on nightly pytorch builds and push data to Meta's internal database. The Nightly CI publishes both V1 and V0 performance scores.
See Unidash (Meta-internal only)
See Adding Models.