CGNS4m, formerly known as mexCGNS, allows you to access virtually all the functionalities provided by the serial API of the mid-level library of CGNS (a.k.a. cgnslib) with the convenience of MATLAB or GNU Octave. It also provides two high-level functions readcgns and writecgns for reading and writing mesh files with node-based or cell-centered data. These high-level functions are entirely written in MATLAB, so you can adapt for your purpose, without writing a single line of C code or a makefile.
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The copyright of CGNS4m belongs to Stony Brook University. CGNS is distributed free of charge under the CGNS License, the same as cgnslib.
The easiest way to install CGNS4m is to download the binary distribution cgns4m-v3.4.1-binary.tar.gz. It contains binary MEX files for 64-bit Linux, Windows, and Mac OS X, and should work for MATLAB R2016b or later. They were built with 64-bit integers enabled to support large files, and they were statically linked with HDF5 1.8.12, which is the same version as the recent releases of MATLAB.
After downloading cgns4m, please run run cgns4m-v3.4.1-binary/startup_cgns4m (or the root directory of cgns4m) within MATLAB to add the cgns4m path in MATLAB.
In Octave, CGNS4m must be built using the HDF5 library bundled within Octave. Hence, a binary distribution is unavailable. You can download the the master branch of the CGNS4m source code. You can also reuse the binary distribution of CGNS4m for MATLAB. The build will have 64-bit integer enabled.
After downloading and untarring cgns4m, please run run cgns4m-master/startup_cgns4m (or the root directory of cgns4m) within Octave. The script will build the MEX file automatically if it does not yet exist and also add the cgns4m path to Octave. The build script has been tested using the binary distributions of Octave 4.2.2 in Ubuntu 18.04 and Octave 5.2.0 in Ubuntu 20.04.
Before using cgns4m, you need to run the startup_cgns4m script each time you start MATLAB/Octave. If you plan to use cgns4m regularly, it is advisable to add the run startup_cgns4m command to your startup script for MATLAB or Octave.
For most users working with structured or unstructured meshes, it would be sufficient to use the high-level functions readcgns and writecgns to read and write CGNS files. For example, use
[xs, elems, typestr, var_nodes, var_cells] = readcgns('tri_mesh.cgns');
to read in the nodal coordinates, element connectivity, element type, nod-based values, and cell-centered field values. The function supports both HDF5 and the legacy ADF formats. The var_nodes and var_cells are MATLAB structures, so you can access the field variables easily.
For additional information about these functions, run
help readcgns
and similarly for writecgns.
Currently, these high-level functions only support meshes with a single zone and with node-based or cell-centered values. For more general purposes, you can adapt these functions by calling any of the mid-level functions of CGNS provided by the MATLAB gateway functions to the MEX. These MATLAB gateway functions have similar API as the C interface of cgnslib, and they handle type-casting automatically. You can also use help command on any of the CGNS functions, such as
help cg_coord_read
The help messages will print out the types of the arguments, and also provide a URL to their official CGNS documentation for the C interface.
CGNS4m, formerly known as mexCGNS, was developed by Prof. Xiangmin Jiao's group at Stony Brook University when he served on the CGNS Steering Committee between 2007 and 2010. The goal of CGNS4m is to facilitate collaborative research activities in computational science, such as meshing, CFD, and multiphysics simulations, etc. As CGNS gains popularity, the demand for a high-level interface for CGNS has grown. The renaming of mexCGNS to CGNS4m is due to an anticipation of a sister package CGNS4py in the future.
Third-party contributions to CGNS4m are welcome. If you have developed an extension to the high-level functions, please create a fork on github and submit a pull request.
Most of the C and MATLAB source codes of CGNS4m were generated automatically from the annotated cgnslib.h using c2mex, a Perl program that extended matwrap developed by Gary R. Holt. A few gateway functions were written by hand and are contained in cgnslib_mex_ext.c. Do not edit the auto-generated C and MATLAB code by hand.
CGNS4m enables 64-bit integer support by default. To regenerate CGNS4m with 32-bit integer support only, run mexUtil/codegen.sh 0 on a UNIX system with bash and perl to regenerate the MATLAB and C codes.
To compile cgns4m from scratch, run build_cgns4m or build_cgns4m -force after running startup_cgns4m. Note that for MATLAB on Microsoft Windows, CGNS4m requires Microsoft Visual Studio (the free community edition suffices). After installing Visual Studio, just run mex -setup in MATLAB to choose Visual C++ as the compiler.
You can generate CGNS4m for a different version of cgnslib (3.1.x or later). To do this, please follow these steps:
- Checkout the barebone branch of cgns4m.
- Download a new copy of
cgnslib.hfor the desired version from https://github.com/CGNS/cgns. Merge the c2mex annotations insrc/cgnslib.hinto the downloadedcgnslib.h, and then copy the merged file to overwritesrc/cgnslib.h. - Change CGNS_VERSION in
mexUtil/codegen.shandmexUtil/build_cgns4m.shto use this new cgnslib version. - Delete the old
cgnslib_mex.mex*files. Run./mexUtil/codegen.shinbashandstartup_cgns4min MATLAB/Octave.