Some external tools need to be present on your system for Micmac to run properly :
- make for parallel processes management,
- convert, from ImageMagick, for image format conversion,
- exiftool and exiv2, to read/write image meta-data,
- proj4 for coordinate system conversion.
On Debian/Ubuntu distribution you can easily install these tools by calling this command:
sudo apt-get install make imagemagick libimage-exiftool-perl exiv2 proj-bin qt5-default
You can check before-hand that Micmac is able to find those programs by calling the command:
bin/mm3d CheckDependencies
(in Micmac directory)
NOT FOUND near one of the tools indicates either the specified executable is not on your disk or it cannot be found in the directories of the PATH environment variable. There is also a special directory for tool finding which is named binaire-aux, in Micmac directory. When an external program is needed, this directory is always scanned whatever the value of PATH.
You will need Visual C++ 2010 runtime redistribuables to run pre-compiled binaries of micmac. Both pre-compiled and compiled from source executables will need :
One of WINDIR or SystemRoot environment variable must be set to Windows' installation directory (C:\Windows
in much cases).
This prevents Micmac from calling a convert.exe
that is not ImageMagick's convert tool but a network utility used by the system.
Since Windows does not have an easy-to-use package manager, a version of make, convert, exiftool and exiv2 are delivered with
the source and Windows binaries archives. They are placed in the binaire-aux
directory.
In addition of previously named tools, people willing to compile binaries from the source code will need to install the cmake
program. Linux and MacOS X users may also want to get X11 header files in order to generate graphical functionalities like SaisieBasc, SaisieMasque, etc ...
The package of X11 headers is general called libx11-dev
under Linux distributions.
X11-based tools are not available in the Windows version.
Windows users may need Qt5 libraries to generate graphical interfaces such as SaisieMasqQT.
For recompilation optimization, ccache is automatically used if detected.
- clone the git repository :
git clone https://github.com/micmacIGN/micmac.git
- enter 'micmac' directory :
cd micmac
- create a directory for the build's intermediate files, then enter it :
mkdir build & cd build
- generate makefiles using cmake :
cmake ../
- process compilation :
make install -j*cores number*
(ex.:make install -j4
)
The first steps are the same as for a Linux/MacOS build except for the make
call.
Instead of makefiles, Cmake generates a Visual C++ solution, named micmac.sln
. Open it and compile the INSTALL
project.
Be sure to be in Release configuration, for Micmac is much faster built this way than in Debug mode.
Again, do not compile the entire solution but just the INSTALL
project, otherwise compiled binaries won't be copied in the bin
directory and this will prevent Micmac from working.
A precompiled docker image is available and ready to use:
docker pull rupnike/micmac
or build your own image from scratch using the existing Dockerfile:
docker image build -t micmac:1.0 -f Dockerfile
You can also use MicMac on Windows 10 through the Windows Subsystem for Linux (WSL). WSL allows you to run a Linux distribution (e.g. Ubuntu) directly on Windows, unmodified, without the overhead of a traditional virtual machine or dualboot setup. For further information please refer to the instructions in this WSL tutorial.
The website logiciels.ign.fr also provides a test dataset called Boudha_dataset.zip
.
This file contains images and configuration files needed to compute the Boudha example from Micmac's documentation. By calling the script this way :
./boudha_test.sh my_micmac_bin/
assuming your working directory is the Boudha directory contained in the file, you can process all the tool-chain until dense point matching.
'my_micmac_bin' is a path to the 'bin' directory of your installation. ex.: ./boudha_test.sh ../micmac/bin/ This example assumes 'Boudha' directory (containing data) and 'micmac' (installation directory) have the same parent directory. Notice the ending '/', it's mandatory for the script to work. After some computation time, you may find three 'ply' files in the 'MEC-6-Im' directory with the three parts of the dense points cloud of the statue's head. Open the PLY files with a viewer like meshlab to check everything proceeded correctly.
You can append the full path of the bin
directory to PATH
environment variable to call Micmac commands from anywhere. However, it is not necessary to add the binaire-aux
directory to the PATH
variable.
For Linux / MacOSX, you have to append the path to the lib
directory to LD_LIBRARY_PATH
in .bashrc
to be able to use QT tools.
Add the following line: export LD_LIBRARY_PATH=$LD_LIBRARY_PATH:/home/micmac/lib/
For MacOSX, if you want to use QT tools with precompiled binaries available on logiciels.ign.fr, you need to install Qt libraries for Mac from http://download.qt-project.org