A lightweight neural network inferencing engine written in C++. This library was designed with the intention of being used in real-time systems, specifically real-time audio processing.
Currently supported layers:
- Dense
- GRU
- LSTM
- Conv1D
- Conv2D
- MaxPooling
- BatchNorm1D
- BatchNorm2D
Currently supported activations:
- tanh
- ReLU
- Sigmoid
- SoftMax
- ELu
- PReLU
Additional resources:
- RTNeural Discord
- API Reference
- Reference Paper
- Example Plugin
- Comparison Benchmarks
- Experimental Extensions
If you are using RTNeural as part of an academic work, please cite the library as follows:
@article{chowdhury2021rtneural,
title={RTNeural: Fast Neural Inferencing for Real-Time Systems},
author={Jatin Chowdhury},
year={2021},
journal={arXiv preprint arXiv:2106.03037}
}
RTNeural
is capable of taking a neural network that
has already been trained, loading the weights from that
network, and running inference. Some simple examples
are available in the examples/
directory.
Neural networks are typically trained using Python
libraries including Tensorflow or PyTorch. Once you
have trained a neural network using one of these frameworks,
you can "export" the network weights to a json file,
so that RTNeural
can read them. An implementation of
the export process for a "sequential" Tensorflow model is
provided in python/model_utils.py
, and can be used as follows.
# import dependencies
import tensorflow as tf
from tensorflow import keras
from model_utils import save_model
# create Tensrflow model
model = keras.Sequential()
...
# train model
model.train()
# export model weights
save_model(model, 'model_weights.json')
For an example of exporting a model from PyTorch, see this example script.
Next, you can create an inferencing engine in C++ directly from the exported json file:
#include <RTNeural.h>
...
std::ifstream jsonStream("model_weights.json", std::ifstream::binary);
auto model = RTNeural::json_parser::parseJson<double>(jsonStream);
Before running inference, it is recommended to "reset" the state of your model (if the model has state).
model->reset();
Then, you may run inference as follows:
double input[] = { 1.0, 0.5, -0.1 }; // set up input vector
double output = model->forward(input); // compute output
The code shown above will create the inferencing engine dynamically at run-time. If the model architecture is fixed at compile-time, it may be preferable to use RTNeural's API for defining an inferencing engine type at compile-time, which can significantly improve performance.
// define model type
RTNeural::ModelT<double, 8, 1
RTNeural::DenseT<double, 8, 8>,
RTNeural::TanhActivationT<double, 8>,
RTNeural::DenseT<double, 8, 1>
> modelT;
// load model weights from json
std::ifstream jsonStream("model_weights.json", std::ifstream::binary);
modelT.parseJson(jsonStream);
modelT.reset(); // reset state
double input[] = { 1.0, 0.5, -0.1 }; // set up input vector
double output = modelT.forward(input); // compute output
The above example code assumes that the trained model has
been exported from TensorFlow. For loading PyTorch models,
the RTNeural namespace RTNeural::torch_helpers
, provides
helper functions for loading layers exported from PyTorch.
// load model weights from json
std::ifstream jsonStream("model_weights.json", std::ifstream::binary);
nlohmann::json modelJson;
jsonStream >> modelJson;
// load a layer from a static model
RTNeural::ModelT<float, 1, 1, RTNeural::DenseT<float, 1, 1>> model;
RTNeural::torch_helpers::loadDense(modelJson, "name_of_layer.", model.get<0>());
For more examples, see the
examples/torch
directory.
RTNeural
is built with CMake, and the easiest way to link
is to include RTNeural
as a submodule:
...
add_subdirectory(RTNeural)
target_link_libraries(MyCMakeProject LINK_PUBLIC RTNeural)
If you are trying to use RTNeural in a project that does not use CMake, please see the instructions below.
RTNeural
supports three backends,
Eigen
,
xsimd
,
or the C++ STL. You can choose your backend by passing
either -DRTNEURAL_EIGEN=ON
, -DRTNEURAL_XSIMD=ON
,
or -DRTNEURAL_STL=ON
to your CMake configuration. By
default, the Eigen
backend will be used. Alternatively,
you may select your choice of backends in your CMake
configuration as follows:
set(RTNEURAL_XSIMD ON CACHE BOOL "Use RTNeural with this backend" FORCE)
add_subdirectory(modules/RTNeural)
In general, the Eigen
backend typically has the best
performance for larger networks, while smaller networks
may perform better with XSIMD. However, it is recommended
to measure the performance of your network with all the
backends that are available on your target platform
to ensure optimal performance. For more information see the
benchmark results.
Note that you must abide by the licensing rules of whichever backend library you choose.
If you would like to build RTNeural with the AVX SIMD extensions,
you may run CMake with the -DRTNEURAL_USE_AVX=ON
. Note that
this flag will have no effect when compiling for platforms that
do not support AVX instructions.
To build RTNeural's test suite, run cmake -Bbuild -DBUILD_TESTS=ON
, followed
by cmake --build build
. To run the full testing suite, run ctest
from the
build
folder. For more information, see tests/README.md
.
To build the performance benchmarks, run
cmake -Bbuild -DBUILD_BENCH=ON
, followed by
cmake --build build --config Release
. To run the layer benchmarks, run
./build/rtneural_layer_bench <layer> <length> <in_size> <out_size>
. To
run the model benchmark, run ./build/rtneural_model_bench
.
To build the RTNeural examples run:
cmake -Bbuild -DBUILD_EXAMPLES=ON
cmake --build build --config Release
The example programs will then be located in
build/examples_out/
, and may be run from there.
An example of using RTNeural within a real-time audio plugin can be found on GitHub here.
If you wish to use RTNeural in a project that doesn't use CMake, RTNeural can be included as a header-only library, along with a few extra steps.
-
Add a compile-time definition to define a default byte alignment for RTNeural. For most cases this definition will be one of either:
RTNEURAL_DEFAULT_ALIGNMENT=16
RTNEURAL_DEFAULT_ALIGNMENT=32
-
Add a compile-time definition to select a backend. If you wish to use the STL backend, then no definition is required. This definition should be one of the following:
RTNEURAL_USE_EIGEN=1
RTNEURAL_USE_XSIMD=1
-
Add the necessary include paths for your chosen backend. This path will be one of either:
<repo>/modules/Eigen
<repo>/modules/xsimd/include/xsimd
It may also be worth checking out the example Makefile.
Contributions to this project are most welcome! Currently, there is a need for the following improvements:
- Improved support for 2-dimensional input/output data.
- Improved support for "stateless" Conv1D layers.
- More robust support for exporting/loading models.
- Support for more activation layers.
- Any changes that improve overall performance.
General code maintenance and documentation is always appreciated as well! Note that if you are implementing a new layer type, it is not required to provide support for all the backends, though it is recommended to at least provide a "fallback" implementation using the STL backend.
Please thank the following individuals for their important contributions:
- wayne-chen: Softmax activation layer and general API improvements.
- hollance: RTNeural logo.
- stepanmk: Eigen Conv1D layer optimization.
- DamRsn: Eigen implementations for Conv2D and BatchNorm2D layers.
- lHorvalds: Eigen backend optimizations.
- davidtrevelyan: Testing framework upgrade.
- purefunctor: Groups feature for Conv1D.
RTNeural is currently being used by several audio plugins and other projects:
- 4000DB-NeuralAmp: Neural emulation of the pre-amp section from the Akai 4000DB tape machine.
- AIDA-X: An AU/CLAP/LV2/VST2/VST3 audio plugin that loads RTNeural models and cabinet IRs.
- BYOD: A guitar distortion plugin containing several machine learning-based effects.
- Chow Centaur: A guitar pedal emulation plugin, using a real-time recurrent neural network.
- Chow Tape Model: An analog tape emulation, using a real-time dense neural network.
- cppTimbreID: An audio feature extraction library.
- guitarix: A guitarix effects suite, including neural network amplifier models.
- GuitarML: GuitarML plugins use machine learning to model guitar amplifiers and effects.
- MLTerror15: Deeply learned simulator for the Orange Tiny Terror with Recurrent Neural Networks.
- NeuralNote: An audio-to-MIDI transcription plugin using Spotify's basic-pitch model.
- rt-neural-lv2: A headless lv2 plugin using RTNeural to model guitar pedals and amplifiers.
- Tone Empire plugins:
- ToobAmp: Guitar effect plugins for the Raspberry Pi.
If you are using RTNeural in one of your projects, let us know and we will add it to this list!
RTNeural is open source, and is licensed under the BSD 3-clause license.
Enjoy!