Difference between revisions of "GetDP"

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ONELAB allows to use GetDP as a black-box solver: you don't need to know anything about finite elements or de Rham complexes in order to run your first simulations:
 
ONELAB allows to use GetDP as a black-box solver: you don't need to know anything about finite elements or de Rham complexes in order to run your first simulations:
  
# Download and uncompress the Gmsh/GetDP bundle for [http://onelab.info/files/gmsh-getdp-Windows64.zip Windows64], [http://onelab.info/files/gmsh-getdp-Windows32.zip Windows32], [http://onelab.info/files/gmsh-getdp-Linux64.zip Linux64], [http://onelab.info/files/gmsh-getdp-Linux32.zip Linux32] or [http://onelab.info/files/gmsh-getdp-MacOSX.zip MacOSX]. (If you prefer you can of course also download and install [http://geuz.org/gmsh/#Download Gmsh] and [http://geuz.org/getdp/#Download GetDP] separately. '''The examples below require very recent versions of GetDP and Gmsh: if you don't download the bundles, you have to download the experimental nightly builds.''')
+
<ol>
# Double-click on the Gmsh executable ('''gmsh.exe''' [[File:GmshIcon.png|GmshIcon.png]] on Windows).
+
  <li>Download the ONELAB bundle:
# Load one of the GetDP models ('''.pro''' file) through the '''File/Open''' menu, e.g. '''inductor.pro''' for the [[Inductor|simple inductor/core]] example.
+
  <ul>
# Click on '''Run'''.
+
    <li>Desktop version for [http://onelab.info/files/onelab-Windows64.zip Windows] ([http://onelab.info/files/onelab-Windows32.zip 32 bit]), [http://onelab.info/files/onelab-Linux64.zip Linux] ([http://onelab.info/files/onelab-Linux32.zip 32 bit]) and [http://onelab.info/files/onelab-MacOSX.dmg MacOS]
# ... that's it!
+
    <li>Mobile version for [https://play.google.com/store/apps/details?id=org.geuz.onelab Android] and [https://itunes.apple.com/us/app/onelab/id845930897 iOS]
 +
    <li>[http://onelab.info/files/onelab-source.zip Source code]
 +
  </ul>
 +
  <li>Launch the app <img src="http://geuz.org/gmsh/gallery/icon.png" height=20px>
 +
  <li>Open a GetDP model:
 +
  <ul>
 +
    <li>Desktop version: go to the '''File/Open''' menu and select a GetDP '''.pro''' file, e.g. '''models/magnetometer/magnetometer.pro'''
 +
    <li>Mobile version: select one of the preloaded models
 +
  </ul>
 +
  <li>Press '''Run'''.
 +
</ol>
  
Note that on Windows, depending on your computer security settings, you might have to explicitly allow the GetDP executable to be launched by Gmsh. Manually launch GetDP once by double-clicking on '''getdp.exe''' to allow this.  
+
<!-- Note that on Windows, depending on your computer security settings, you might have to explicitly allow the GetDP executable to be launched by Gmsh. Manually launch GetDP once by double-clicking on '''getdp.exe''' to allow this. -->
  
<gallery widths=320px heights=180px perrow=2>
+
== GetDP models ==
Image:GmshGetDP_1.png|Launch Gmsh and load the GetDP model '''magnet.pro''' with the '''File/Open''' menu.
+
 
Image:GmshGetDP_2.png|Click on '''Run''' to launch a computation. You can change any parameter and then '''Run''' again!
+
=== Basic templates ===
</gallery>
+
 
 +
These are basic physical templates, that can either be used interactively to define new problems from scratch, or be included in other problem definition files.
  
== GetDP models ==
+
{| class="wikitable"
 +
|
 +
* [[Electrostatics template|Electrostatics]]
 +
* [[Magnetostatics template|Magnetostatics]]
 +
|}
  
 
=== Featured physical models ===
 
=== Featured physical models ===
 +
 +
These are complete, parametric application examples, ready to be solved and modified.
  
 
{| class="wikitable"
 
{| class="wikitable"
 
! Acoustics
 
! Acoustics
 
! Electromagnetism
 
! Electromagnetism
 +
! Heat transfer
 
! Multi-physics
 
! Multi-physics
 
|-
 
|-
 
|  
 
|  
* [[Acoustic Scattering|Multiple scattering]]
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* [[Acoustic scattering|Multiple scattering]]
 
* [[Time reversal|Time reversal]]
 
* [[Time reversal|Time reversal]]
 
|  
 
|  
 
* [[Inductor|Simple inductor/core system]]
 
* [[Inductor|Simple inductor/core system]]
 
* [[Magnets|Forces on magnets]]
 
* [[Magnets|Forces on magnets]]
* [[Electric_Machines|Rotating electric machines]]
+
* [[Electric machines|Rotating electric machines]]
 
* [[Antennas]]
 
* [[Antennas]]
 
* [[Waveguides]]
 
* [[Waveguides]]
 
* [[Shielding effectiveness]]
 
* [[Shielding effectiveness]]
 
* [[Bloch modes in periodic waveguides]]
 
* [[Bloch modes in periodic waveguides]]
 +
* [[Superconducting wire]]
 +
* [[Diffraction grating]]
 +
|
 +
* [[Thermal conduction]]
 
|  
 
|  
* [[Electromechanical_Relay|Electromechanical relay]]
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* [[Electromechanical relay]]
 
* [[Magnetodynamics with cohomology conditions|Induction heating (electro-thermal)]]
 
* [[Magnetodynamics with cohomology conditions|Induction heating (electro-thermal)]]
 
* [[Magnetometer|Magnetometer (electromechanical, thermal)]]
 
* [[Magnetometer|Magnetometer (electromechanical, thermal)]]
 +
* [[Magnetostriction|Magnetostriction (magnetic, mechanical)]]
 
|}
 
|}
  
<!-- Remettre ceci dès que c'est prêt :
+
=== Advanced numerical techniques ===
 
 
=== Academic cases ===
 
 
 
These benchmarks are mainly for students and researchers who plan to propose new benchmarks using GetDP.  The codes are as simple as possible in order to make learning the syntax easier.
 
  
 
{| class="wikitable"
 
{| class="wikitable"
!Numerical schemes
 
!Academic benchmarks
 
 
|-
 
|-
| style="width: 50%" |
+
|
 +
* [[Domain decomposition methods for waves]]
 +
|}
 +
 
 +
<!--
 +
=== Featured tutorials ===
 
* [[Numerical schemes: Laplace's equation|Laplace's equation]]
 
* [[Numerical schemes: Laplace's equation|Laplace's equation]]
 
* [[Numerical schemes: Heat equation|Heat equation]]
 
* [[Numerical schemes: Heat equation|Heat equation]]
 
* [[Electrostatics]]
 
* [[Electrostatics]]
 
* [[Numerical_schemes:_Wave_propagation|Wave propagation]]
 
* [[Numerical_schemes:_Wave_propagation|Wave propagation]]
| style="width: 50%" |
 
 
* [[Laplace equation with Neumann boundary condition]]
 
* [[Laplace equation with Neumann boundary condition]]
 
* [[Laplace equation with Dirichlet boundary condition]]
 
* [[Laplace equation with Dirichlet boundary condition]]
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* [[Coupled problems]]
 
* [[Coupled problems]]
 
* Eigenvalues problems
 
* Eigenvalues problems
|}
 
 
 
-->
 
-->
  
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== How does it work? ==
 
== How does it work? ==
  
GetDP input files ('''.pro''' files) can be instrumented to share parameters with the ONELAB server, [[ONELAB_Syntax_for_Gmsh_and_GetDP|through the same syntax as the one used in Gmsh]].  
+
GetDP input files ('''.pro''' files) can be instrumented to share parameters with the ONELAB server, [[ONELAB syntax for Gmsh and GetDP|through the same syntax as the one used in Gmsh]].  
  
 
<!--
 
<!--
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* Hyperbolic equations
 
* Hyperbolic equations
 
** [[Wave equation with Dirichlet boundary control]]
 
** [[Wave equation with Dirichlet boundary control]]
->
+
-->
 +
 
 +
== Building GetDP from the source code ==
 +
 
 +
If you want to recompile GetDP directly from the source code, you should
 +
 
 +
* Download PETSc from http://www.mcs.anl.gov/petsc/petsc-as/download/ and uncompress the archive (in this example, using PETSc 3.7.4):
 +
<source>
 +
tar zxvf petsc-3.7.4.tar.gz
 +
</source>
 +
 
 +
* Configure and build PETSc. The configuration options depend on the calculations you want to perform (complex- or real-valued), as well as your compiler setup. For a sequential build (without MPI), run (remove <code>--with-scalar-type=complex</code> to build in real arithmetic):
 +
<source>
 +
cd petsc-3.7.4
 +
export PETSC_DIR=$PWD
 +
export PETSC_ARCH=complex_mumps_seq
 +
./configure --with-clanguage=cxx --with-debugging=0 --with-mpi=0 --with-mpiuni-fortran-binding=0 --download-mumps=yes --with-mumps-serial --with-shared-libraries=0 --with-x=0 --with-ssl=0 --with-scalar-type=complex
 +
make
 +
cd ..
 +
</source>
 +
 
 +
* Download and unzip the Gmsh and the GetDP source code from the ONELAB bundle  http://onelab.info/files/gmsh-getdp-source.zip (or download the latest source code from http://getdp.info and http://gmsh.info, respectively)
 +
 
 +
* Configure, compile and install a minimal Gmsh library (it will be used by GetDP):
 +
<source>
 +
cd gmsh-xxx
 +
mkdir lib
 +
cd lib
 +
cmake -DDEFAULT=0 -DENABLE_PARSER=1 -DENABLE_POST=1 -DENABLE_BUILD_LIB=1 ..
 +
make lib
 +
sudo make install/fast
 +
cd ../..
 +
</source>
 +
 
 +
* Configure and compile GetDP:
 +
<source>
 +
cd getdp-xxx
 +
mkdir bin
 +
cd bin
 +
cmake ..
 +
make
 +
cd ../..
 +
</source>
 +
 
 +
Instructions for building the parallel (MPI) version of GetDP are available [[GetDDM|here]]

Latest revision as of 18:07, 25 November 2017

GetDP is an open source finite element solver using mixed elements to discretize de Rham-type complexes in one, two and three dimensions. GetDP is developed by the ACE group from the Montefiore Institute at the University of Liège, and is released under the GNU GPL.

Getting started

ONELAB allows to use GetDP as a black-box solver: you don't need to know anything about finite elements or de Rham complexes in order to run your first simulations:

  1. Download the ONELAB bundle:
  2. Launch the app
  3. Open a GetDP model:
    • Desktop version: go to the File/Open menu and select a GetDP .pro file, e.g. models/magnetometer/magnetometer.pro
    • Mobile version: select one of the preloaded models
  4. Press Run.


GetDP models

Basic templates

These are basic physical templates, that can either be used interactively to define new problems from scratch, or be included in other problem definition files.

Featured physical models

These are complete, parametric application examples, ready to be solved and modified.

Acoustics Electromagnetism Heat transfer Multi-physics

Advanced numerical techniques


All models

All GetDP models

How does it work?

GetDP input files (.pro files) can be instrumented to share parameters with the ONELAB server, through the same syntax as the one used in Gmsh.


Building GetDP from the source code

If you want to recompile GetDP directly from the source code, you should

tar zxvf petsc-3.7.4.tar.gz
  • Configure and build PETSc. The configuration options depend on the calculations you want to perform (complex- or real-valued), as well as your compiler setup. For a sequential build (without MPI), run (remove --with-scalar-type=complex to build in real arithmetic):
cd petsc-3.7.4
export PETSC_DIR=$PWD
export PETSC_ARCH=complex_mumps_seq
./configure --with-clanguage=cxx --with-debugging=0 --with-mpi=0 --with-mpiuni-fortran-binding=0 --download-mumps=yes --with-mumps-serial --with-shared-libraries=0 --with-x=0 --with-ssl=0 --with-scalar-type=complex
make
cd ..
  • Configure, compile and install a minimal Gmsh library (it will be used by GetDP):
cd gmsh-xxx
mkdir lib
cd lib
cmake -DDEFAULT=0 -DENABLE_PARSER=1 -DENABLE_POST=1 -DENABLE_BUILD_LIB=1 ..
make lib
sudo make install/fast
cd ../..
  • Configure and compile GetDP:
cd getdp-xxx
mkdir bin
cd bin
cmake ..
make
cd ../..

Instructions for building the parallel (MPI) version of GetDP are available here