tiny-cnn: A header only, dependency-free deep learning framework in C++11

Linux/Mac OS	Windows

tiny-cnn is a C++11 implementation of deep learning. It is suitable for deep learning on limited computational resource, embedded systems and IoT devices.

Features
Comparison with other libraries
Supported networks
Dependencies
Build
Examples
References
License
Mailing list

see Wiki Pages for more info.

Features

fast, without GPU
- with TBB threading and SSE/AVX vectorization
- 98.8% accuracy on MNIST in 13 minutes training (@Core i7-3520M)
header only
- Just include tiny_cnn.h and write your model in c++. There is nothing to install.
small dependency & simple implementation
can import caffe's model

Comparison with other libraries

	tiny-cnn	caffe	Theano	TensorFlow
Prerequisites	Nothing(Optional:TBB,OpenMP)	BLAS,Boost,protobuf,glog,gflags,hdf5, (Optional:CUDA,OpenCV,lmdb,leveldb etc)	Numpy,Scipy,BLAS,(optional:nose,Sphinx,CUDA etc)	numpy,six,protobuf,(optional:CUDA,Bazel)
Modeling By	C++ code	Config File	Python Code	Python Code
GPU Support	No	Yes	Yes	Yes
Installing	Unnecessary	Necessary	Necessary	Necessary
Windows Support	Yes	No*	Yes	No*
Pre-Trained Model	Yes(via caffe-converter)	Yes	No*	No*

*unofficial version is available

Supported networks

layer-types

fully-connected layer
convolutional layer
average pooling layer
max-pooling layer
contrast normalization layer
dropout layer
linear operation layer

activation functions

tanh
sigmoid
softmax
rectified linear(relu)
leaky relu
identity
exponential linear units(elu)

loss functions

cross-entropy
mean-squared-error

optimization algorithm

stochastic gradient descent (with/without L2 normalization and momentum)
stochastic gradient levenberg marquardt
adagrad
rmsprop
adam

Dependencies

Minimum requirements

Nothing.All you need is a C++11 compiler.

Requirements to build sample/test programs

OpenCV

Build

tiny-cnn is header-ony, so there's nothing to build. If you want to execute sample program or unit tests, you need to install cmake and type the following commands:

cmake .

Then open .sln file in visual studio and build(on windows/msvc), or type make command(on linux/mac/windows-mingw).

Some cmake options are available:

options	description	default	additional requirements to use
USE_TBB	Use Intel TBB for parallelization	OFF*	Intel TBB
USE_OMP	Use OpenMP for parallelization	OFF*	OpenMP Compiler
USE_SSE	Use Intel SSE instruction set	ON	Intel CPU which supports SSE
USE_AVX	Use Intel AVX instruction set	ON	Intel CPU which supports AVX
BUILD_TESTS	Build unist tests	OFF	-**
BUILD_EXAMPLES	Build example projects	ON	-

*tiny-cnn use c++11 standard library for parallelization by default **to build tests, type git submodule update --init before build

For example, type the following commands if you want to use intel TBB and build tests:

cmake -DUSE_TBB=ON -DBUILD_EXAMPLES=ON .

Customize configurations

You can edit include/config.h to customize default behavior.

Examples

construct convolutional neural networks

#include "tiny_cnn/tiny_cnn.h"
using namespace tiny_cnn;
using namespace tiny_cnn::activation;

void construct_cnn() {
    using namespace tiny_cnn;

    // specify loss-function and optimization-algorithm
    network<mse, adagrad> net;
    //network<cross_entropy, RMSprop> net;

    // add layers
    net << convolutional_layer<tan_h>(32, 32, 5, 1, 6) // 32x32in, conv5x5, 1-6 f-maps
        << average_pooling_layer<tan_h>(28, 28, 6, 2) // 28x28in, 6 f-maps, pool2x2
        << fully_connected_layer<tan_h>(14 * 14 * 6, 120)
        << fully_connected_layer<identity>(120, 10);

    assert(net.in_dim() == 32 * 32);
    assert(net.out_dim() == 10);
    
    // load MNIST dataset
    std::vector<label_t> train_labels;
    std::vector<vec_t> train_images;
    
    parse_mnist_labels("train-labels.idx1-ubyte", &train_labels);
    parse_mnist_images("train-images.idx3-ubyte", &train_images, -1.0, 1.0, 2, 2);
    
    // train (50-epoch, 30-minibatch)
    net.train(train_images, train_labels, 30, 50);
    
    // save
    std::ofstream ofs("weights");
    ofs << net;
    
    // load
    // std::ifstream ifs("weights");
    // ifs >> net;
}

construct multi-layer perceptron(mlp)

#include "tiny_cnn/tiny_cnn.h"
using namespace tiny_cnn;
using namespace tiny_cnn::activation;

void construct_mlp() {
    network<mse, gradient_descent> net;

    net << fully_connected_layer<sigmoid>(32 * 32, 300)
        << fully_connected_layer<identity>(300, 10);

    assert(net.in_dim() == 32 * 32);
    assert(net.out_dim() == 10);
}

another way to construct mlp

#include "tiny_cnn/tiny_cnn.h"
using namespace tiny_cnn;
using namespace tiny_cnn::activation;

void construct_mlp() {
    auto mynet = make_mlp<mse, gradient_descent, tan_h>({ 32 * 32, 300, 10 });

    assert(mynet.in_dim() == 32 * 32);
    assert(mynet.out_dim() == 10);
}

more sample, read examples/main.cpp or MNIST example page.

References

[1] Y. Bengio, Practical Recommendations for Gradient-Based Training of Deep Architectures. arXiv:1206.5533v2, 2012

[2] Y. LeCun, L. Bottou, Y. Bengio, and P. Haffner, Gradient-based learning applied to document recognition. Proceedings of the IEEE, 86, 2278-2324.

other useful reference lists:

License

The BSD 3-Clause License

Mailing list

google group for questions and discussions:

https://groups.google.com/forum/#!forum/tiny-cnn-users

liu3xing3long / tiny-cnn Goto Github PK

tiny-cnn's Introduction