- Windows Portable Demo
- Operating Systems
- Requirements
- Clone OpenPose
- Update OpenPose
- Installation
- Reinstallation
- Uninstallation
- Optional Settings
This installation section is only intended if you plan to modify the OpenPose code or integrate it with another library or project. If you just want to use the OpenPose demo in Windows, simply use the latest version of the OpenPose binaries which you can find in the Releases section.
- Ubuntu 14 and 16.
- Windows 8 and 10.
- Nvidia Jetson TX2, installation instructions in doc/installation_jetson_tx2.md.
- OpenPose has also been used on Windows 7, Mac, CentOS, and Nvidia Jetson (TK1 and TX1) embedded systems. However, we do not officially support them at the moment.
Requirements for the default configuration (you might need more resources with a greater --net_resolution
and/or scale_number
or less resources by reducing the net resolution and/or using the MPI and MPI_4 models):
- Nvidia GPU version:
- NVIDIA graphics card with at least 1.6 GB available (the
nvidia-smi
command checks the available GPU memory in Ubuntu). - At least 2 GB of free RAM memory.
- Highly recommended: cuDNN.
- NVIDIA graphics card with at least 1.6 GB available (the
- CPU version:
- Around 8GB of free RAM memory.
- Highly recommended: a CPU with at least 8 cores.
The first step is to clone the OpenPose repository.
- Windows: You might use GitHub Desktop.
- Ubuntu:
git clone https://github.com/CMU-Perceptual-Computing-Lab/openpose
OpenPose can be easily updated by:
- Download the latest changes:
- Windows: Clicking the
synchronization
button at the top-right part in GitHub Desktop in Windows. - Ubuntu: running
git pull origin master
.
- Windows: Clicking the
- Perform the Reinstallation section described below.
The instructions in this section describe the steps to build OpenPose using CMake (GUI). There are 3 main steps:
- Prerequisites
- OpenPose Configuration
- OpenPose Building
- OpenPose from other Projects (Ubuntu Only)
- Run OpenPose
- Download and install CMake GUI:
- Ubuntu: run the command
sudo apt-get install cmake-qt-gui
. Note: If you prefer to use CMake through the command line, see Cmake Command Line Build. - Windows: download and install the latest CMake win64-x64 msi installer from the CMake website, called
cmake-X.X.X-win64-x64.msi
.
- Ubuntu: run the command
- Nvidia GPU version prerequisites:
- CUDA 8:
- Ubuntu: Run
sudo ubuntu/install_cuda.sh
or alternatively download and install it from their website. - Windows: Install CUDA 8.0 after Visual Studio 2015 is installed to assure that the CUDA installation will generate all necessary files for VS. If CUDA was already installed, re-install CUDA after installing VS!
- IMPORTANT: As of a recent Windows update, you have to download the Nvidia drivers drivers first, and then install CUDA without the Graphics Driver flag or else your system might hang.
- Ubuntu: Run
- cuDNN 5.1:
- Ubuntu: Run
sudo ubuntu/install_cudnn.sh
or alternatively download and install it from their website. - Windows (and Ubuntu if manual installation): In order to manually install it, just unzip it and copy (merge) the contents on the CUDA folder, usually
/usr/local/cuda/
in Ubuntu andC:\Program Files\NVIDIA GPU Computing Toolkit\CUDA\v8.0
in Windows.
- Ubuntu: Run
- CUDA 8:
- Ubuntu - Other prerequisites:
- Caffe prerequisites: By default, OpenPose uses Caffe under the hood. If you have not used Caffe previously, install its dependencies by running
sudo bash ./ubuntu/install_cmake.sh
. - OpenCV must be already installed on your machine. It can be installed with
apt-get install libopencv-dev
. You can also use your own compiled OpenCV version.
- Caffe prerequisites: By default, OpenPose uses Caffe under the hood. If you have not used Caffe previously, install its dependencies by running
- Windows - Microsoft Visual Studio (VS) 2015 Enterprise Update 3:
- If Visual Studio 2017 Community is desired, we do not officially support it, but it might be compiled by firstly enabling CUDA 8.0 in VS2017 or use VS2017 with CUDA 9 by checking the
.vcxproj
file and changing the necessary paths from CUDA 8 to 9. - VS 2015 Enterprise Update 1 will give some compiler errors and VS 2015 Community has not been tested.
- If Visual Studio 2017 Community is desired, we do not officially support it, but it might be compiled by firstly enabling CUDA 8.0 in VS2017 or use VS2017 with CUDA 9 by checking the
- Windows - Caffe, OpenCV, and Caffe prerequisites:
- CMake automatically downloads all the Windows DLLs. Alternatively, you might prefer to download them manually:
- Models:
- COCO model: download in
models/pose/coco/
. - MPI model: download in
models/pose/mpi/
. - Face model: download in
models/face/
. - Hands model: download in
models/hand/
.
- COCO model: download in
- Dependencies:
- Note: Leave the zip files in
3rdparty/windows/
so that CMake does not try to download them again. - Caffe: Unzip as
3rdparty/windows/caffe/
. - Caffe dependencies: Unzip as
3rdparty/windows/caffe3rdparty/
. - OpenCV 3.1: Unzip as
3rdparty/windows/opencv/
.
- Note: Leave the zip files in
- Models:
- CMake automatically downloads all the Windows DLLs. Alternatively, you might prefer to download them manually:
- Eigen prerequisite:
- Note: This step is optional, only required for some specific extra functionality, such as extrinsic camera calibration.
- If you enable the
WITH_EIGEN
flag when running CMake. You can either:- Do not do anything if you set the
WITH_EIGEN
flag toBUILD
, CMake will automatically download Eigen. Alternatively, you might prefer to download it manually:- Eigen3: Unzip as
3rdparty/eigen/
.
- Eigen3: Unzip as
- Run
sudo apt-get install libeigen3-dev
(Ubuntu only) if you prefer to setWITH_EIGEN
toAPT_GET
(Ubuntu only). - Use your own version of Eigen by setting
WITH_EIGEN
toBUILD
, run CMake so that OpenPose downloads the zip file, and then replace the contents of3rdparty/eigen/
by your own version.
- Do not do anything if you set the
- Open CMake GUI and select the OpenPose directory as project source directory, and a non-existing or empty sub-directory (e.g.,
build
) where the Makefile files (Ubuntu) or Visual Studio solution (Windows) will be generated. Ifbuild
does not exist, it will ask you whether to create it. PressYes
.
- Press the
Configure
button, keep the generator inUnix Makefile
(Ubuntu) or set it toVisual Studio 14 2015 Win64
(Windows), and pressFinish
.
- If this step is successful, the
Configuring done
text will appear in the bottom box in the last line. Otherwise, some red text will appear in that same bottom box.
- Press the
Generate
button and proceed to OpenPose Building. You can now close CMake.
Note: If you prefer to use your own custom Caffe or OpenCV versions, see Custom Caffe or Custom OpenCV respectively.
Finally, build the project by running the following commands.
cd build/
make -j`nproc`
In order to build the project, open the Visual Studio solution (Windows), called build/OpenPose.sln
. Then, set the configuration from Debug
to Release
and press the green triangle icon (alternatively press F5).
If you only intend to use the OpenPose demo, you might skip this step. This step is only recommended if you plan to use the OpenPose API from other projects.
To install the OpenPose headers and libraries into the system environment path (e.g. /usr/local/
or /usr/
), run the following command.
cd build/
sudo make install
Once the installation is completed, you can use OpenPose in your other project using the find_package
cmake command. Below, is a small example CMakeLists.txt
. In order to use this script, you also need to copy FindGFlags.cmake
and FindGlog.cmake
into your <project_root_directory>/cmake/Modules/
(create the directory if necessary).
cmake_minimum_required(VERSION 2.8.7)
add_definitions(-std=c++11)
list(APPEND CMAKE_MODULE_PATH "${CMAKE_CURRENT_SOURCE_DIR}/cmake/Modules")
find_package(GFlags)
find_package(Glog)
find_package(OpenCV)
find_package(OpenPose REQUIRED)
include_directories(${OpenPose_INCLUDE_DIRS} ${GFLAGS_INCLUDE_DIR} ${GLOG_INCLUDE_DIR} ${OpenCV_INCLUDE_DIRS})
add_executable(example.bin example.cpp)
target_link_libraries(example.bin ${OpenPose_LIBS} ${GFLAGS_LIBRARY} ${GLOG_LIBRARY} ${OpenCV_LIBS})
If Caffe was built with OpenPose, it will automatically find it. Otherwise, you will need to link Caffe again as shown below (otherwise, you might get an error like /usr/bin/ld: cannot find -lcaffe
).
link_directories(<path_to_caffe_installation>/caffe/build/install/lib)
Check OpenPose was properly installed by running it on the default images, video, or webcam: doc/quick_start.md#quick-start.
In order to re-install OpenPose:
- (Ubuntu only) If you ran
sudo make install
, then runsudo make uninstall
inbuild/
. - Delete the
build/
folder. - In CMake GUI, click on
File
-->Delete Cache
. - Follow the Installation steps again.
In order to uninstall OpenPose:
- (Ubuntu only) If you ran
sudo make install
, then runsudo make uninstall
inbuild/
. - Remove the OpenPose folder.
OpenPose displays the FPS in the basic GUI. However, more complex speed metrics can be obtained from the command line while running OpenPose. In order to obtain those, compile OpenPose with the PROFILER_ENABLED
flag. OpenPose will automatically display time measurements for each subthread after processing F
frames (by default F = 1000
, but it can be modified with the --profile_speed
flag).
- Time measurement for 1 graphic card: The FPS will be the slowest time displayed in your terminal command line (as OpenPose is multi-threaded). Times are in milliseconds, so
FPS = 1000/millisecond_measurement
. - Time measurement for >1 graphic cards: Assuming
n
graphic cards, you will have to wait up ton
xF
frames to visualize each graphic card speed (as the frames are splitted among them). In addition, the FPS would be:FPS = minFPS(speed_per_GPU/n, worst_time_measurement_other_than_GPUs)
. For < 4 GPUs, this is usuallyFPS = speed_per_GPU/n
.
By default, the body MPI model is not downloaded. You can download it by turning on the DOWNLOAD_MPI_MODEL
. It's slightly faster but less accurate and has less keypoints than the COCO body model.
To manually select the CPU Version, open CMake GUI mentioned above, and set the GPU_MODE
flag to CPU_ONLY
. NOTE: Accuracy of the CPU version is ~1% higher than CUDA version, so the results will vary.
- On Ubuntu, OpenPose will link against the Intel MKL version (Math Kernel Library) of Caffe. Alternatively, the user can choose his own Caffe version, by unselecting
USE_MKL
and selecting his own Caffe path. - On Windows, it will use the default version of Caffe or one provided by the user on the CPU.
The default CPU version takes ~0.2 images per second on Ubuntu (~50x slower than GPU) while the MKL version provides a roughly 2x speedup at ~0.4 images per second. As of now OpenPose does not support MKL on Windows but will at a later date. Also, MKL version does not support unfixed resolution. So a folder of images of different resolutions requires a fixed net resolution (e.g., --net_resolution 656x368
).
The user can configure the environmental variables MKL_NUM_THREADS
and OMP_NUM_THREADS
. They are set at an optimum parameter level by default (i.e., to the number of threads of the machine). However, they can be tweak by running the following commands into the terminal window, right before running any OpenPose application. Eg:
# Optimal number = Number of threads (used by default)
export MKL_NUM_THREADS="8"
export OMP_NUM_THREADS="8"
Do note that increasing the number of threads results in more memory use. You can check the OpenPose benchmark for more information about speed and memory requirements in several CPUs and GPUs.
You can include the 3D reconstruction module by:
- Install the FLIR camera software, Spinnaker SDK. It is a propietary software, so we cannot provide direct download link. Note: You might skip this step if you intend to use the 3-D OpenPose module with a different camera brand.
- Ubuntu: Get and install the latest Spinnaker SKD version in their default path. OpenPose will automatically find it. Otherwise, set the right path with CMake.
- Windows: Donwload the latest Spinnaker SKD version from https://www.ptgrey.com/support/downloads.
- Copy
{PointGreyParentDirectory}\Point Grey Research\Spinnaker\bin64\vs2015\
as{OpenPoseDirectory}\3rdparty\windows\spinnaker\bin\
. You can remove all the *.exe files. - Copy
{PointGreyParentDirectory}\Point Grey Research\Spinnaker\include\
as{OpenPoseDirectory}\3rdparty\windows\spinnaker\include\
. - Copy
Spinnaker_v140.lib
andSpinnakerd_v140.lib
from{PointGreyParentDirectory}\Point Grey Research\Spinnaker\lib64\vs2015\
into{OpenPoseDirectory}\3rdparty\windows\spinnaker\lib\
. - (Optional) Spinnaker SDK overview: https://www.ptgrey.com/spinnaker-sdk.
- Copy
- Install the 3D visualizer, FreeGLUT:
- Ubuntu: run
sudo apt-get update && sudo apt-get install build-essential freeglut3 freeglut3-dev libxmu-dev libxi-dev
and reboot your PC. - Windows:
- It is automatically downloaded by the CMake installer.
- Alternatively, if you prefer to download it yourself, you could either:
- Double click on
3rdparty\windows\getFreeglut.bat
. - Download this version from our server and unzip it in
{OpenPoseDirectory}\3rdparty\windows\freeglut\
. - Download the latest
MSVC Package
from http://www.transmissionzero.co.uk/software/freeglut-devel/.- Copy
{freeglutParentDirectory}\freeglut\bin\x64\
as{OpenPoseDirectory}\3rdparty\windows\freeglut\bin\
. - Copy
{freeglutParentDirectory}\freeglut\include\
as{OpenPoseDirectory}\3rdparty\windows\freeglut\include\
. - Copy
{freeglutParentDirectory}\freeglut\lib\x64\
as{OpenPoseDirectory}\3rdparty\windows\freeglut\lib\
.
- Copy
- Double click on
- Ubuntu: run
- Follow the CMake installation steps. In addition, set the
WITH_FLIR_CAMERA
(only if Spinnaker was installed) andWITH_3D_RENDERER
options. - Increased accuracy with Ceres solver (Ubuntu only): For extra 3-D reconstruction accuracy, run
sudo apt-get install libeigen3-dev
, install Ceres solver, and enableWITH_CERES
in CMake when installing OpenPose. Ceres is harder to install in Windows, so we have not tested it so far in there. Feel free to make a pull request if you do.
After installation, check the doc/3d_reconstruction_demo.md instructions.
The calibration module is included by default, but you must also enable WITH_EIGEN
if you intend to use the extrinsic camera parameter estimation tool. You can set that flag to 2 different values: APT_GET
or BUILD
, check Requirements for more information.
After installation, check the doc/calibration_demo.md instructions.
The cuDNN library is not mandatory, but required for full keypoint detection accuracy. In case your graphics card is not compatible with cuDNN, you can disable it by unchecking USE_CUDNN
in CMake.
Then, you would have to reduce the --net_resolution
flag to fit the model into the GPU memory. You can try values like 640x320
, 320x240
, 320x160
, or 160x80
to see your GPU memory capabilities. After finding the maximum approximate resolution that your GPU can handle without throwing an out-of-memory error, adjust the net_resolution
ratio to your image or video to be processed (see the --net_resolution
explanation from doc/demo_overview.md), or use -1
(e.g. --net_resolution -1x320
).
We only modified some Caffe compilation flags and minor details. You can use your own Caffe distribution, simply specify the Caffe include path and the library as shown below. You will also need to turn off the BUILD_CAFFE
variable. Note that cuDNN is required in order to get the maximum possible accuracy in OpenPose.
If you have built OpenCV from source and OpenPose cannot find it automatically, you can set the OPENCV_DIR
variable to the directory where you build OpenCV.
You can generate the documentation by setting the BUILD_DOCS
flag. The documentation will be generated in doc/doxygen/html/index.html
. You can simply open it with double-click (your default browser should automatically display it).
Note that this step is unnecessary if you already used the CMake GUI alternative.
Create a build
folder in the root OpenPose folder, where you will build the library --
cd openpose
mkdir build
cd build
The next step is to generate the Makefiles. Now there can be multiple scenarios based on what the user already has e.x. Caffe might be already installed and the user might be interested in building OpenPose against that version of Caffe instead of requiring OpenPose to build Caffe from scratch.
In the build directory, run the below command --
cmake ..
In this example, we assume that Caffe and OpenCV are already present. The user needs to supply the paths of the libraries and the include directories to CMake. For OpenCV, specify the include directories and the libraries directory using OpenCV_INCLUDE_DIRS
and OpenCV_LIBS_DIR
variables respectively. Alternatively, the user can also specify the path to the OpenCVConfig.cmake
file by setting the OpenCV_CONFIG_FILE
variable. For Caffe, specify the include directory and library using the Caffe_INCLUDE_DIRS
and Caffe_LIBS
variables. This will be where you installed Caffe. Below is an example of the same.
cmake -DOpenCV_INCLUDE_DIRS=/home/"${USER}"/softwares/opencv/build/install/include \
-DOpenCV_LIBS_DIR=/home/"${USER}"/softwares/opencv/build/install/lib \
-DCaffe_INCLUDE_DIRS=/home/"${USER}"/softwares/caffe/build/install/include \
-DCaffe_LIBS=/home/"${USER}"/softwares/caffe/build/install/lib/libcaffe.so -DBUILD_CAFFE=OFF ..
cmake -DOpenCV_CONFIG_FILE=/home/"${USER}"/softwares/opencv/build/install/share/OpenCV/OpenCVConfig.cmake \
-DCaffe_INCLUDE_DIRS=/home/"${USER}"/softwares/caffe/build/install/include \
-DCaffe_LIBS=/home/"${USER}"/softwares/caffe/build/install/lib/libcaffe.so -DBUILD_CAFFE=OFF ..
If Caffe is not already present but OpenCV is, then use the below command.
cmake -DOpenCV_INCLUDE_DIRS=/home/"${USER}"/softwares/opencv/build/install/include \
-DOpenCV_LIBS_DIR=/home/"${USER}"/softwares/opencv/build/install/lib ..
cmake -DOpenCV_CONFIG_FILE=/home/"${USER}"/softwares/opencv/build/install/share/OpenCV/OpenCVConfig.cmake ..