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Build-Instruction.md

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NOTE: The build instruction in this article is outdated. Assembly3 now works with official FreeCAD version 0.19 onwards. In addition, you can now install SolveSpave solver backend through pip install py-slvs. The Python wheel repository can be found here.

At the moment of this writing, Assembly3 only works with a forked FreeCAD branch. You need to first checkout this branch and build it yourself.

After that, checkout this repository directly inside the Ext/freecad/ directory of your FreeCAD installation or build directory. Be sure to name the directory as asm3. The Assembly3 workbench supports multiple constraint solver backends. Currently, there are two backends available, SolveSpace and SymPy + SciPy, both of which have external dependency. The current focus is to get SolveSpace backend fully working first, with SymPy + SciPy serving as a reference implementation for future exploration. All backends are optional. But, you'll need at least one installed to be able to do constraint based assembling, unless you are fine with manually movement, which is actually doable because Assembly3 provides a powerful mouse dragger.

SolveSpace

SolveSpace is by itself a standalone CAD software with excellent assembly support. IMO, it has the opposite design principle of FreeCAD, which is big, modular, and fully extensible. SolveSpace, on the other hand is lean and compact, and does extremely well for what it offers. But, you most likely will find something you want that's missing, and have to seek out other software for help. The constraint solver of SolveSpace is available as a small library for integration by third party software, which gives us the opportunity to bring the best from both worlds.

There is no official python binding of SolveSpace at the moment. Besides, some small modification is required to bring out the SolveSpace assembly functionality into the solver library. You can find my fork here. Check out the repository to your local file system,

git clone https://github.com/realthunder/solvespace
cd solvespace

Build for Ubuntu

To build the python binding only

mkdir build
cd build
cmake -DCMAKE_BUILD_TYPE=Release -DBUILD_PYTHON=On ..
make _slvs

If you have more than one version of Python installed, you may want to specify the desired version as follow

cmake -DCMAKE_BUILD_TYPE=Release -DBUILD_PYTHON=On -DPYTHON_EXECUTABLE=/usr/bin/python3 ..

After compilation is done, copy slvs.py and _slvs.so from build/src/swig/python/ to asm3/py_slvs, where asm3 is the directory you install Assembly3 workbench. Be sure to create an empty file named __init__.py at asm3/py_slvs.

Cross Compile for Windows

To build for Windows 64-bit, you have two options. This section shows how to cross compile for Windows on Ubuntu

apt-get install cmake mingw-w64
mkdir build_mingw
cd build_mingw
cmake -DCMAKE_BUILD_TYPE=Release -DBUILD_PYTHON=On -DCMAKE_TOOLCHAIN_FILE=../cmake/Toolchain-mingw64.cmake ..
make _slvs

After finish, copy slvs.py and _slvs.pyd from build/src/swig/python/ to asm3/py_slvs, where asm3 is the directory you install Assembly3 workbench. Be sure to create an empty file named __init__.py at asm3/py_slvs.

Build on Windows

To build on Windows, you should use Visual Studio 2013, the same one FreeCAD uses. Install CMake and Python. If you are building the 64-bit version, make sure you install the Python 64-bit version. I have only tested the build with Python 2.7.14 64-bit. You probably can use the python lib included in FreeCAD libpack by adding the libpack path to PATH environment variable. But it doesn't work for me somehow. CMake only found the debug version python lib in the libpack.

Download and extract the latest swig to some where, and add the path to PATH environment variable. I haven't tested to build with the old version swig that's bundled with FreeCAD libpack.

Be sure to checkout all the submodules of slvs before building. None of them is actually used, but is still needed to satisfy CMake dependency checking,

cd asm3/slvs
git submodule update --init --recursive

Run CMake-gui, select a build directory. Add a BOOL type entry named BUILD_PYTHON, and set it to true. Then click configure and select Visual Studio 2013 Win64, which is what FreeCAD used. If done without error, click generate.

Finally, open the solvespace.sln file in the build directory. You only need to build two projects, first slvs_static_excp, and then _slvs. Once finished, copy the output at the following location to asm/py_slvs

asm/slvs/<your_build_directory>/src/swig/python/slvs.py
asm/slvs/<your_build_directory>/src/swig/python/Release/_slvs.pyd

If you want to build the Debug version, either download Python debug libraries, or put FreeCAD libpack directory in PATH environment variable before configuring CMake, so that CMake can find the debug version Python library. Once built, you must rename _slvs.pyd to _slvs_d.pyd before copying to asm/py_slvs

Build for MacOS

The pre-build binary for MacOS is located at a different sub-module, because MacOS python extension has the same name as Linux one. To build it yourself for use in FreeCAD App bundle, first you need to setup Homebrew according to this wiki, and build FreeCAD App bundle.

Assuming you installed FreeCAD bundle at ~/some/place/FreeCAD.app, then clone Assembly3 repository at ~/some/place/FreeCAD.app/Contents/Ext/freecad/. And very importantly, make sure you name the clone directory as asm3. After that checkout slvs sub-module, and all of its own sub-modules.

cd ~/some/place/FreeCAD.app/Contents/Ext/freecad/asm3
git submodule update --init slvs
cd slvs
git submodule update --init --recursive

Use the following command to configure and build

mkdir build
cd build
cmake \
-DCMAKE_BUILD_TYPE=Release \
-DBUILD_PYTHON=1 \
-DPYTHON_EXECUTABLE:FILEPATH=/usr/local/opt/python@2/Frameworks/Python.framework/Versions/2.7/bin/python2.7 \
-DPYTHON_INCLUDE_DIR=/usr/local/opt/python@2/Frameworks/Python.framework/Headers/ \
-DPYTHON_LIBRARY=/usr/local/opt/python@2/Frameworks/Python.framework/Versions/2.7/lib/libpython2.7.dylib  \
-DPython_FRAMEWORKS=/usr/local/opt/python@2/Frameworks/Python.framework/ ..

make _slvs

After done, create a directory named py_slvs_mac under asm3, and copy out the results

cd ~/some/place/FreeCAD.app/Contents/Ext/freecad/asm3
mkdir py_slvs_mac
touch py_slvs_mac/__init__.py
cp slvs/build/src/swig/python/_slvs.so py_slvs_mac/
cp slvs/build/src/swig/python/slvs.py py_slvs_mac/

Finally, you must make _slvs.so relocatable in order to be able to load it in FreeCAD bundle, with the following command

cd py_slvs_mac
install_name_tool -id "_slvs.so" _slvs.so
install_name_tool -add_rpath "@loader_path/../../../../lib/" _slvs.so
install_name_tool -change \
    "/usr/local/opt/python@2/Frameworks/Python.framework/Versions/2.7/Python" "@rpath/Python" _slvs.so

The last command changes the linked library path to be relative to the bundle's dynamic library loader. In case you used a different CMake configuration, you can find out your linked library path using the following command

otool -L _slvs.so

Done, and you can fire up FreeCAD.app and try out Assembly3.

SymPy + SciPy

The other constraint solver backend uses SymPy and SciPy. They are mostly Python based, with some native acceleration in certain critical parts. The backend implementation models after SolveSpace's solver design, that is, symbolic algebraic + non-linear least square minimization. It can be considered as a python implementation of the SolveSpace's solver.

SciPy offers a dozen of different minimization algorithms, but most of which cannot compete with SolveSpace performance wise. The following list shows some non-formal testing result using default parameters with the sample assembly described later

Algorithm Time
SolveSpace (as reference) 0.006s
Nelder-Mead Not converge
Powell 7.8s
CG 10+37s 1
BFGS 10+0.8 1
Newton-CG 10+61+0.5s 2,3
L-BFGS-B 10+1.5s 1,3
TNC 10+0.8s 1
COBYLA 0.2s 3
SLSQP 10+0.3 1,3
dogleg 10+61+?s 2 Failed to solve, linalg error
trust-ncg 10+61+1.5s 2

[1] Including Jacobian matrix calculation (10s in this test case), which is implemented using sympy lambdify with numpy.

[2] Including Hessian matrix calculation (61s in this test case), in addition to Jacobian matrix.

[3] The obtained solution contains small gaps in some of the coincidence constrained points. Incorrect use of the algorithm?

The reasons for writing this backend are,

  • SolveSpace is under GPL, which is incompatible with FreeCAD's LGPL,
  • To gain more insight of the solver system, and easy experimentation with new ideas due to its python based nature,
  • For future extension, physics based simulation, maybe?

You'll need to install SymPy and SciPy for your platform.

pip install --upgrade sympy scipy