Awesome
Stereo Matching by Training a Convolutional Neural Network to Compare Image Patches
The repository contains
- procedures to compute the stereo matching cost with a convolutional neural network;
- procedures to train a convolutional neural network on the stereo matching task; and
- a basic stereo method (cross-based cost aggregation, semiglobal matching, left-right consistency check, median filter, and bilateral filter);
A NVIDIA GPU with at least 6 GB of memory is required to run on the KITTI data set and 12 GB to run on the Middlebury data set. We tested the code on GTX Titan (KITTI only), K80, and GTX Titan X. The code is released under the BSD 2-Clause license. Please cite our paper if you use code from this repository in your work.
@article{zbontar2016stereo,
title={Stereo matching by training a convolutional neural network to compare image patches},
author={Zbontar, Jure and LeCun, Yann},
journal={Journal of Machine Learning Research},
volume={17},
pages={1--32},
year={2016}
}
Download trained networks
- KITTI 2012 fast
- KITTI 2012 accurate
- KITTI 2015 fast
- KITTI 2015 accurate
- Middlebury fast
- Middlebury accurate
Compute the Matching Cost
Install Torch, OpenCV 2.4, and png++.
Run the following commands in the same directory as this README file.
Compile the shared libraries:
$ cp Makefile.proto Makefile
$ make
The command should produce two files: libadcensus.so
and libcv.so
.
To run the stereo algorithm on a stereo pair from the KITTI 2012 training set—
- Left input image
<img src="samples/input/kittiL.png" style="width: 25%;"/> - Right input image
<img src="samples/input/kittiR.png" style="width: 25%;"/>
—download the pretrained network and call main.lua
with the following arguments:
$ wget -P net/ https://s3.amazonaws.com/mc-cnn/net_kitti_fast_-a_train_all.t7
$ ./main.lua kitti fast -a predict -net_fname net/net_kitti_fast_-a_train_all.t7 -left samples/input/kittiL.png -right samples/input/kittiR.png -disp_max 70
Writing right.bin, 1 x 70 x 370 x 1226
Writing left.bin, 1 x 70 x 370 x 1226
Writing disp.bin, 1 x 1 x 370 x 1226
The first two arguments (kitti fast
) are used to set the default
hyperparameters of the stereo method. The outputs are stored as three binary
files:
left.bin
: The matching cost after semiglobal matching and cross-based cost aggregation with the left image treated as the reference image.
<img src="samples/output/left.png" style="width: 25%;"/>right.bin
: Same asleft.bin
, but with the right image treated as the reference image.
<img src="samples/output/right.png" style="width: 25%;"/>disp.bin
: The disparity map after the full stereo method.
<img src="samples/output/disp.png" style="width: 25%;"/>
Use the bin2png.lua
script to generate the .png
images like the ones above:
$ luajit samples/bin2png.lua
Writing left.png
Writing right.png
Writing disp.png
If you wish to use the raw convolutional neural network outputs, that is, without applying cross-based cost aggregation and semiglobal matching, run the following command:
$ ./main.lua kitti fast -a predict -net_fname net/net_kitti_fast_-a_train_all.t7 -left samples/input/kittiL.png -right samples/input/kittiR.png -disp_max 70 -sm_terminate cnn
Writing right.bin, 1 x 70 x 370 x 1226
Writing left.bin, 1 x 70 x 370 x 1226
Writing disp.bin, 1 x 1 x 370 x 1226
The resulting disparity maps should look like this:
left.png
<img src="samples/output/left_cnn.png" style="width: 25%;"/>right.png
<img src="samples/output/right_cnn.png" style="width: 25%;"/>
Note that -disp_max 70
is used only as an example. To reproduce our
results on the KITTI data sets use -disp_max 228
.
See the predict_kitti.lua script for how you might
call main.lua
in a loop, for multiple image pairs.
Load the Output Binary Files
You can load the binary files (if, for example, you want to apply different post-processing steps that you have written yourself) by memory mapping them. We include examples of memory mapping for some of the more popular programming languages.
-
Lua
require 'torch' left = torch.FloatTensor(torch.FloatStorage('../left.bin')):view(1, 70, 370, 1226) right = torch.FloatTensor(torch.FloatStorage('../right.bin')):view(1, 70, 370, 1226) disp = torch.FloatTensor(torch.FloatStorage('../disp.bin')):view(1, 1, 370, 1226)
-
Python
import numpy as np left = np.memmap('../left.bin', dtype=np.float32, shape=(1, 70, 370, 1226)) right = np.memmap('../right.bin', dtype=np.float32, shape=(1, 70, 370, 1226)) disp = np.memmap('../disp.bin', dtype=np.float32, shape=(1, 1, 370, 1226))
-
Matlab
left = memmapfile('../left.bin', 'Format', 'single').Data; left = permute(reshape(left, [1226 370 70]), [3 2 1]); right = memmapfile('../right.bin', 'Format', 'single').Data; right = permute(reshape(right, [1226 370 70]), [3 2 1]); disparity = memmapfile('../disp.bin', 'Format', 'single').Data; disparity = reshape(disparity, [1226 370])';
-
C
#include <fcntl.h> #include <stdio.h> #include <sys/mman.h> #include <sys/stat.h> #include <sys/types.h> int main(void) { int fd; float *left, *right, *disp; fd = open("../left.bin", O_RDONLY); left = mmap(NULL, 1 * 70 * 370 * 1226 * sizeof(float), PROT_READ, MAP_SHARED, fd, 0); close(fd); fd = open("../right.bin", O_RDONLY); right = mmap(NULL, 1 * 70 * 370 * 1226 * sizeof(float), PROT_READ, MAP_SHARED, fd, 0); close(fd); fd = open("../disp.bin", O_RDONLY); disp = mmap(NULL, 1 * 1 * 370 * 1226 * sizeof(float), PROT_READ, MAP_SHARED, fd, 0); close(fd); return 0; }
Train
This section explains how to train the convolutional neural network on the KITTI and Middlebury data sets.
KITTI
Download both
- the KITTI 2012 data set and unzip it
into
data.kitti/unzip
(you should end up with a filedata.kitti/unzip/training/image_0/000000_10.png
) and - the KITTI 2015 data set and unzip it
into
data.kitti2015/unzip
(you should end up with a filedata.kitti2015/unzip/training/image_2/000000_10.png
).
Run the preprocessing script:
$ ./preprocess_kitti.lua
dataset 2012
1
...
389
dataset 2015
1
...
400
Run main.lua
to train the network:
$ ./main.lua kitti slow -a train_tr
kitti slow -a train_tr
conv(in=1, out=112, k=3)
cudnn.ReLU
conv(in=112, out=112, k=3)
cudnn.ReLU
conv(in=112, out=112, k=3)
cudnn.ReLU
conv(in=112, out=112, k=3)
cudnn.ReLU
nn.Reshape(128x224)
nn.Linear(224 -> 384)
cudnn.ReLU
nn.Linear(384 -> 384)
cudnn.ReLU
nn.Linear(384 -> 384)
cudnn.ReLU
nn.Linear(384 -> 384)
cudnn.ReLU
nn.Linear(384 -> 1)
cudnn.Sigmoid
...
The network is trained on a subset of all training examples with the remaining examples used for validation; to train on all examples use
$ ./main.lua kitti slow -a train_all
In the previous command, the KITTI 2012 data set is used. If you wish to train on the KITTI 2015 run
$ ./main.lua kitti2015 slow -a train_tr
To train the fast architecture instead use
$ ./main.lua kitti fast -a train_tr
The network is stored in the net/
directory.
$ ls net/
...
net_kitti2012_fast_-action_train_tr.t7
...
Middlebury
Run download_middlebury.sh
to download the training data
(this can take a long time, depending on your internet connection).
$ ./download_middlebury.sh
The data set is downloaded into the data.mb/unzip
directory.
Compile the MiddEval3-SDK. You
should end up with the computemask
binary in one of the directories listed in
your PATH
enviromential variable.
Install ImageMagick; the
preprocessing steps requires the convert
binary to resize the images.
Run the preprocessing script:
$ mkdir data.mb.imperfect_gray
$ ./preprocess_mb.py imperfect gray
Adirondack
Backpack
...
testH/Staircase
The preprocessing is slow (it takes around 30 minutes) the first time it is run, because the images have to be resized.
Use main.lua
to train the network:
$ ./main.lua mb slow -a train_tr
Other Useful Commands
Compute the error rate on the validation set (useful for setting hyperparameters):
$ ./main.lua kitti fast -a test_te -net_fname net/net_kitti_fast_-a_train_tr.t7
kitti fast -a test_te -net_fname net/net_kitti_fast_-a_train_tr.t7
0.86836290359497 0.0082842716717202
...
0.73244595527649 0.024202708004929
0.72730183601379 0.023603160822285
0.030291934952454
The validation error rate of the fast architecture on the KITTI 2012 data set is 3.029%.
***
Compute the error rate on the validation set of one dataset for a network that has been trained on a different dataset.
$ ./main.lua kitti fast -a test_te -net_fname net/net_mb_fast_-a_train_all.t7
kitti fast -a test_te -net_fname net/net_mb_fast_-a_train_all.t7
2.1474301815033 0.0071447750148986
...
1.4276049137115 0.024273838024622
1.4282908439636 0.01881285579564
1.408842086792 0.021741689597834
0.031564540460366
The validation error rate of the fast architecture tested on KITTI 2012 but trained on Middlebury is 3.156%.
***
Prepare files for submission to the KITTI and Middlebury evaluation server.
$ ./main.lua kitti fast -a submit -net_fname net/net_kitti_fast_-a_train_all.t7
kitti fast -a submit -net_fname net/net_kitti_fast_-a_train_all.t7
adding: 000038_10.png (deflated 0%)
adding: 000124_10.png (deflated 0%)
...
adding: 000021_10.png (deflated 0%)
The output is stored in out/submission.zip
and can be used to submit to the
KITTI evaluation
server.
***
Experiment with different network architectures:
$ ./main.lua kitti slow -a train_tr -l1 2 -fm 128 -l2 3 -nh2 512
kitti slow -a train_tr -l1 2 -fm 128 -l2 3 -nh2 512
conv(in=1, out=128, k=3)
cudnn.ReLU
conv(in=128, out=128, k=3)
cudnn.ReLU
nn.Reshape(128x256)
nn.Linear(256 -> 512)
cudnn.ReLU
nn.Linear(512 -> 512)
cudnn.ReLU
nn.Linear(512 -> 512)
cudnn.ReLU
nn.Linear(512 -> 1)
cudnn.Sigmoid
...
***
Measure the runtime on a particular data set:
$ ./main.lua kitti fast -a time
kitti fast -a time
conv(in=1, out=64, k=3)
cudnn.ReLU
conv(in=64, out=64, k=3)
cudnn.ReLU
conv(in=64, out=64, k=3)
cudnn.ReLU
conv(in=64, out=64, k=3)
nn.Normalize2
nn.StereoJoin1
0.73469495773315
It take 0.73 seconds to run the fast architecure on the KITTI 2012 data set. If you care only about the time spent in the neural network, you can terminate the stereo method early:
$ ./main.lua kitti fast -a time -sm_terminate cnn
kitti fast -a time -sm_terminate cnn
conv(in=1, out=64, k=3)
cudnn.ReLU
conv(in=64, out=64, k=3)
cudnn.ReLU
conv(in=64, out=64, k=3)
cudnn.ReLU
conv(in=64, out=64, k=3)
nn.Normalize2
nn.StereoJoin1
0.31126594543457