Warning: compiling libigl as a static library is considerably more difficult than using it as a header-only library (see ../README.md instead). Do it only if you are experienced with C++, cmake and make, and you want to improve your compilation times.
Libigl is developed most often on Mac OS X, though has current users in Linux and Windows.
Libigl may also be compiled to a static library. This is advantageous when building a project with libigl, since when used as an header-only library can slow down compile times.
To build the entire libigl library producing at least libigl/lib/libigl.a and
possible other (automatically detected) extras, e.g. libigl/lib/libiglcgal.a
from this current directory: issue:
mkdir -p ../lib
cd ../lib
cmake -DCMAKE_BUILD_TYPE=Release ../optional
make
You should expect to see a few linker warnings of the form:
/opt/local/bin/ranlib: file: libigl.a(*.cpp.o) has no symbols
These are (admittedly unpopular) functions that have never been used by us statically so we haven't explicit instantiations (yet).
You can make a slew of examples by issuing:
cd ../examples
make
Finally there are a number of external libraries that we include in
./external/ because they are either difficult to obtain or they have been
patched for easier use with libigl. Please see the respective readmes in those
directories or build the tutorial using cmake, which will recursively build all
dependencies.
To build the embree library and executables on Mac OS X issue:
cd external/embree
mkdir build
cd build
cmake ..
# Or using a different compiler
#cmake .. -DCMAKE_C_COMPILER=/opt/local/bin/gcc -DCMAKE_CXX_COMPILER=/opt/local/bin/g++
make
# Could also install embree to your root, but libigl examples don't expect
# this
#sudo make install
This library extra contains functions for computing Bounded Biharmonic Weights, can
be used with and without the mosek extra via the IGL_NO_MOSEK
macro.
This library extra contains functions for computing mesh-mesh booleans, depending on CGAL and optionally Cork.
This library extra utilizes CGAL's efficient and exact intersection and proximity queries.
This library extra utilizes embree's efficient ray tracing queries.
This library extra provides support for reading and writing .mat workspace
files, interfacing with Matlab at run time and compiling mex functions.
This library extra utilizes mosek's efficient interior-point solver for quadratic programs.
This library extra uses libpng and YImage to read and write .png files.
This library extra provides a simplified wrapper to the tetgen 3d tetrahedral meshing library.
This library extra provides a simplified wrapper to the triangle 2d triangle meshing library.
This library extra utilizes glfw and glew to open an opengl context and launch a simple mesh viewer.
This library extra utilizes tinyxml2 to read and write serialized classes containing Eigen matrices and other standard simple data-structures.
Further documentation for developers is listed in style_guidelines.html.
See LICENSE.txt
Zip this directory without .git litter and binaries using:
git archive -prefix=libigl/ -o libigl.zip master
Special care must be taken by the developers of each function and class in the libigl library that uses C++ templates. If this function is intended to be compiled into the statically linked libigl library then function is only compiled for each explicitly specialized declaration. These should be added at the bottom of the corresponding .cpp file surrounded by a
#ifdef IGL_STATIC_LIBRARY
Of course, a developer may not know ahead of time which specializations should be explicitly included in the igl static lib. One way to find out is to add one explicit specialization for each call in one's own project. This only ever needs to be done once for each template.
The process is somewhat mechanical using a linker with reasonable error output.
Supposed for example we have compiled the igl static lib, including the
cat.h and cat.cpp functions, without any explicit instanciation. Say
using the makefile in the libigl directory:
cd $LIBIGL
make
Now if we try to compile a project and link against it we may get an error like:
Undefined symbols for architecture x86_64:
"Eigen::Matrix<int, -1, -1, 0, -1, -1> igl::cat<Eigen::Matrix<int, -1, -1, 0, -1, -1> >(int, Eigen::Matrix<int, -1, -1, 0, -1, -1> const&, Eigen::Matrix<int, -1, -1, 0, -1, -1> const&)", referenced from:
uniform_sample(Eigen::Matrix<double, -1, -1, 0, -1, -1> const&, Eigen::Matrix<int, -1, -1, 0, -1, -1> const&, int, double, Eigen::Matrix<double, -1, -1, 0, -1, -1>&)in Skinning.o
"Eigen::SparseMatrix<double, 0, int> igl::cat<Eigen::SparseMatrix<double, 0, int> >(int, Eigen::SparseMatrix<double, 0, int> const&, Eigen::SparseMatrix<double, 0, int> const&)", referenced from:
covariance_scatter_matrix(Eigen::Matrix<double, -1, -1, 0, -1, -1> const&, Eigen::Matrix<int, -1, -1, 0, -1, -1> const&, ArapEnergy, Eigen::SparseMatrix<double, 0, int>&)in arap_dof.o
arap_rhs(Eigen::Matrix<double, -1, -1, 0, -1, -1> const&, Eigen::Matrix<int, -1, -1, 0, -1, -1> const&, ArapEnergy, Eigen::SparseMatrix<double, 0, int>&)in arap_dof.o
This looks like a mess, but luckily we don't really need to read it all. Just copy the first part in quotes
Eigen::Matrix<int, -1, -1, 0, -1, -1> igl::cat<Eigen::Matrix<int, -1, -1, 0, -1, -1> >(int, Eigen::Matrix<int, -1, -1, 0, -1, -1> const&, Eigen::Matrix<int, -1, -1, 0, -1, -1> const&)
, then append it
to the list of explicit template specializations at the end of
cat.cpp after the word
template and followed by a semi-colon.
Like this:
#ifdef IGL_STATIC_LIBRARY
// Explicit template specialization
template Eigen::Matrix<int, -1, -1, 0, -1, -1> igl::cat<Eigen::Matrix<int, -1, -1, 0, -1, -1> >(int, Eigen::Matrix<int, -1, -1, 0, -1, -1> const&, Eigen::Matrix<int, -1, -1, 0, -1, -1> const&);
#endif
Then you must recompile the IGL static library.
cd $LIBIGL
make
And try to compile your project again, potentially repeating this process until no more symbols are undefined.
It may be useful to check that you code compiles with no errors first using the headers-only version to be sure that all errors are from missing template specializations.
If you're using make then the following command will reveal each missing symbol on its own line:
make 2>&1 | grep "referenced from" | sed -e "s/, referenced from.*//"
Alternatively you can use the autoexplicit.sh function
which (for well organized .h/.cpp pairs in libigl) automatically
create explicit instanciations from your compiler's error messages.
Repeat this process until convergence:
cd /to/your/project
make 2>$LIBIGL/make.err
cd $LIBIGL
cat make.err | ./autoexplicit.sh
make clean
make
- Faster compile time: Because the libigl library is already compiled, only the new code in ones project must be compiled and then linked to IGL. This means compile times are generally faster.
- Debug or optimized: The IGL static library may be compiled in debug mode or optimized release mode regardless of whether one's project is being optimized or debugged.
- Hard to use templates: Special care (by the developers of the library) needs to be taken when exposing templated functions.
Calling the script:
scripts/compress.sh igl.h igl.cpp
will create a single header igl.h and a single cpp file igl.cpp.
Alternatively, you can also compress everything into a single header file:
scripts/compress.sh igl.h
- Easy incorporation: This can be easily incorporated into external projects.
-
Hard to debug/edit: The compressed files are automatically generated. They're huge and should not be edited. Thus debugging and editting are near impossible.
-
Compounded dependencies: An immediate disadvantage of this seems to be that even to use a single function (e.g.
cotmatrix), compiling and linking againstigl.cppwill require linking to all oflibigl's dependencies (OpenGL,GLUT,AntTweakBar,BLAS). However, because all depencies other than Eigen should be encapsulated between#ifndefguards (e.g.#ifndef IGL_NO_OPENGL, it is possible to ignore certain functions that have such dependencies. -
Long compile: Compiling
igl.cpptakes a long time and isn't easily parallelized (nomake -j12equivalent).
Here's a tiny test example using igl.h and igl.cpp. Save the following in test.cpp:
#include <igl.h>
#include <Eigen/Core>
int main(int argc, char * argv[])
{
Eigen::MatrixXd V;
Eigen::MatrixXi F;
return (argc>=2 && igl::read_triangle_mesh(argv[1],V,F)?0:1);
}
Then compile igl.cpp with:
g++ -o igl.o -c igl.cpp -I/opt/local/include/eigen3 -DIGL_NO_OPENGL -DIGL_NO_ANTTWEAKBAR
Notice that we're using -DIGL_NO_OPENGL -DIGL_NO_ANTTWEAKBAR to disable any libigl dependencies on OpenGL and AntTweakBar.
Now compile test.cpp with:
g++ -g -I/opt/local/include/eigen3/ -I/usr/local/igl/libigl/ -L/usr/local/igl/libigl/ -ligl -DIGL_NO_OPENGL -DIGL_NO_ANTTWEAKBAR -o test
Try running it with:
./test path/to/mesh.obj
The following bash one-liner will find all source files that contain the string OpenGL but don't contain and IGL_NO_OPENGL guard:
grep OpenGL `grep -L IGL_NO_OPENGL include/igl/*`
- OpenGL (disable with
IGL_NO_OPENGL)- OpenGL >= 4 (enable with
IGL_OPENGL_4)
- OpenGL >= 4 (enable with
- AntTweakBar (disable with
IGL_NO_ANTTWEAKBAR) Last tested 1.16 (seelibigl/external/AntTweakBar) - GLEW Windows and Linux
- OpenMP
- libpng libiglpng extra only
- Mosek libiglmosek extra only
- Matlab libiglmatlab extra only
- boost libiglboost, libiglcgal extra only
- SSE/AVX libiglsvd3x3 extra only
- CGAL libiglcgal extra only
- boost
- gmp
- mpfr
- CoMiSo libcomiso extra only
- TetGen libigltetgen extra only
- Embree libiglembree extra only
- tinyxml2 libiglxml extra only
- glfw libviewer extra only
- LIM liblim extra only