FeenoX for Academics

-   1 What
-   2 How
-   3 Why

  [1 What]: #what
  [2 How]: #how
  [3 Why]: #why

What

FeenoX is a cloud-first Unix stand-alone program (i.e. something your
run, not something you have to link existing code against) that reads an
engineering-related problem in a plain-text file containing definitions
and instructions. That is to say, it reads the problem to be solved at
run time and does not require the user (most of the time these will be
industry engineers and not hackers nor PhDs) to compile and link custom
code in order to solve a problem because it is not a library. It does
not require the users to write a weak form of the PDE they want to
solve, because most of them will not even know what a weak form is (and
they certainly do not need to know that). The user chooses from a set of
built-in PDEs using the PROBLEM definition which internally resolves (at
run time) a set of function pointers to the appropriate locations which
will build the elemental objects which correspond the to chosen PDE. The
list of available PDEs can be peeked by executing the feenox binary with
the --pdes option:

    $ feenox --pdes
    laplace
    mechanical
    modal
    neutron_diffusion
    neutron_sn
    thermal
    $ 

During the compilation procedure (based on Autotools), the source tree
in src/pdes is parsed. For each subdirectory, a new PDE is embedded into
the compiled binary. See below for further details about this
extensibility mechanism.

This program then solves the problem and, eventually, writes the outputs
which the input file requests with explicit instructions (and nothing if
nothing is asked for) and returns back to the Unix shell:

    # NAFEMS Benchmark LE-10: thick plate pressure
    PROBLEM mechanical DIMENSIONS 3
    READ_MESH nafems-le10.msh   # mesh in millimeters

    # LOADING: uniform normal pressure on the upper surface
    BC upper    p=1      # 1 Mpa

    # BOUNDARY CONDITIONS:
    BC DCD'C'   v=0      # Face DCD'C' zero y-displacement
    BC ABA'B'   u=0      # Face ABA'B' zero x-displacement
    BC BCB'C'   u=0 v=0  # Face BCB'C' x and y displ. fixed
    BC midplane w=0      #  z displacements fixed along mid-plane

    # MATERIAL PROPERTIES: isotropic single-material properties
    E = 210e3   # Young modulus in MPa
    nu = 0.3    # Poisson's ratio

    SOLVE_PROBLEM   # solve!

    # print the direct stress y at D (and nothing more)
    PRINT "σ_y @ D = " sigmay(2000,0,300) "MPa"

It can be seen as a Unix filter (or as a transfer function)

                                 +------------+
     mesh (*.msh)  }             |            |             { terminal
     data (*.dat)  } input ----> |   FeenoX   |----> output { data files
     input (*.fee) }             |            |             { post (vtk/msh)
                                 +------------+

which, when zoomed in, acts as a “glue layer” between a mesher (Gmsh)
and a library for solving large sparse problems (PETSc) which for linear
elastic looks as follows:

[] 

Further discussion can be found in the tensile test tutorial. Check out
the section about invocation in the FeenoX manual.

The design responds to a Software Requirements Specification document
that acts as a “request for quotations” of a computational engineering
tool that should satisfy some fictitious (but plausible) requirements.
The Software Design Specification document explains how FeenoX addresses
each requirement of the SRS.

In principle, even though FeenoX can solve generic numerical problems
and systems of ordinary differential/algebraic equations, its main
objective is to solve partial differential equations using the finite
element method—eventually in parallel using the MPI standard. The
current version can solve

-   Basic mathematics
-   Systems of ODEs/DAEs
-   Laplace’s equation
-   Heat conduction
-   Linear elasticity
-   Modal analysis
-   Neutron diffusion
-   Neutron SN

  Heads up! The background of FeenoX’s main author is Nuclear
  Engineering. Hence,

  -   Two of the supported PDEs are related to neutron diffusion and
      transport.
  -   There is a PhD thesis (in Spanish only) that discusses the design
      and implementation of FeenoX in view of core-level neutronics.

As mentioned in the previous section, FeenoX provides a mechanism to add
new types of PDEs by adding a new subdirectory to the src/pdes directory
of the source tree and then re-bootstrapping, re-configuring and
re-compiling the code.

Since in FeenoX’s input file everything is an expression, the code is
especially suited for verification using the method of manufactured
solutions.

-   See FeenoX for Engineers for links to further examples and
    tutorials.
-   See FeenoX for Hackers for more details about the implementation and
    the code.

  [FeenoX]: https://www.seamplex.com/feenox/
  [cloud-first]: https://seamplex.com/feenox/doc/sds.html#cloud-first
  [Unix]: ./README4hackers.md
  [run]: https://www.seamplex.com/feenox/doc/feenox-manual.html#running-feenox
  [engineering-related problem]: ./README4engineers.md
  [plain-text file containing definitions and instructions]: https://seamplex.com/feenox/doc/sds.html#sec:input
  [PROBLEM]: https://www.seamplex.com/feenox/doc/feenox-manual.html#problem
  [src/pdes]: https://github.com/seamplex/feenox/tree/main/src/pdes
  [extensibility mechanism]: https://www.seamplex.com/feenox/doc/sds.html#sec:extensibility
  [explicit instructions]: https://www.seamplex.com/feenox/doc/sds.html#sec:output
  [Gmsh]: http://gmsh.info/
  [PETSc]: https://petsc.org/release/
  [1]: doc/transfer-le10-zoom.svg
  [tensile test tutorial]: https://www.seamplex.com/feenox/doc/tutorials/110-tensile-test/
  [FeenoX manual]: https://www.seamplex.com/feenox/doc/feenox-manual.html
  [Software Requirements Specification]: https://www.seamplex.com/feenox/doc/srs.html
  [Software Design Specification]: https://www.seamplex.com/feenox/doc/sds.html
  [generic numerical problems]: https://seamplex.com/feenox/examples/basic.html
  [systems of ordinary differential/algebraic equations]: https://seamplex.com/feenox/examples/daes.html
  [in parallel using the MPI standard]: https://seamplex.com/feenox/doc/sds.html#sec:scalability
  [Laplace’s equation]: https://seamplex.com/feenox/examples/laplace.html
  [Heat conduction]: https://seamplex.com/feenox/examples/thermal.html
  [Linear elasticity]: https://seamplex.com/feenox/examples/mechanical.html
  [Modal analysis]: https://seamplex.com/feenox/examples/modal.html
  [Neutron diffusion]: https://seamplex.com/feenox/examples/neutron_diffusion.html
  [Neutron SN]: https://seamplex.com/feenox/examples/neutron_sn.html
  [diffusion]: https://www.seamplex.com/feenox/examples/neutron_diffusion.html
  [transport]: https://www.seamplex.com/feenox/examples/neutron_sn.html
  [PhD thesis (in Spanish only)]: https://seamplex.com/thesis/html/
  [directory of the source tree and then re-bootstrapping, re-configuring and re-compiling the code]:
    https://seamplex.com/feenox/doc/sds.html#sec:extensibility
  [everything is an expression]: https://seamplex.com/feenox/doc/sds.html#sec:expression
  [verification using the method of manufactured solutions]: https://github.com/seamplex/feenox/tree/main/tests/mms

How

FeenoX tries to achieve its goals by…

-   standing on both ethical (since it is free) and technical (since it
    is open source) ground while interacting with other free and open
    specimens such as

    -   operating systems
    -   libraries
    -   compilers
    -   pre and post-processing tools thus encouraging science and
        engineering to shift from privative environments into the free
        world.

-   leveraging the Unix programming philosophy to come up with a
    cloud-first tool suitable to be automatically deployed and serve as
    the back end of web-based interfaces (fig. ).

-   providing a ready-to-run program that reads an input file at run
    time (and not a library that has to be linked for each particular
    problem to be solved) as deliberate decision discussed in the
    Software Design Specification.

-   designing and implementing an extensibility mechanism to allow
    hackers and/or academics to add new PDE formulations by adding a new
    subdirectory to src/pdes in the repository and then

    a.  re-bootstrapping with autogen.sh,
    b.  re-configuring with configure, and
    c.  re-compiling with make

In effect, FeenoX provides a general mathematical framework to solve
PDEs with a bunch of entry points (as C functions) where new types of
PDEs (e.g. electromagnetism, fluid mechanics, etc.) can be added to the
set of what FeenoX can solve. This general framework provides means to

-   parse the input file, handle command-line arguments, read mesh
    files, assign variables, evaluate conditionals, write results, etc.

        PROBLEM laplace 2D
        READ_MESH square-$1.msh
        [...]
        WRITE_RESULTS FORMAT vtk

-   handle material properties given as algebraic expressions involving
    pointwise-defined functions of space, temperature, time, etc.

        MATERIAL steel     E=210e3*(1-1e-3*(T(x,y,z)-20))   nu=0.3
        MATERIAL aluminum  E=69e3                           nu=7/25

-   read problem-specific boundary conditions as algebraic expressions

        sigma = 5.670374419e-8  # W m^2 / K^4 as in wikipedia
        e = 0.98      # non-dimensional
        T0 = 1000     # K
        Tinf = 300    # K

        BC left  T=T0
        BC right q=sigma*e*(Tinf^4-T(x,y,z)^4)

-   access shape functions and its derivatives evaluated either at Gauss
    points or at arbitrary locations for computing elementary
    contributions to

    -   stiffness matrix
    -   mass matrix
    -   right-hand side vector

    For example, this snippet would build the elemental stiffness matrix
    for the Laplace problem:

        int build_laplace_Ki(element_t *e, unsigned int q) {
          double wdet = feenox_fem_compute_w_det_at_gauss(e, q);
          gsl_matrix *B = feenox_fem_compute_B_at_gauss(e, q);
          feenox_call(feenox_blas_BtB_accum(B, wdet, feenox.fem.Ki));  
          return FEENOX_OK;
        }

    The calls for computing the weights and the matrices with the shape
    functions and/or their derivatives currently support first and
    second-order iso-geometric elements, but other element types can be
    added as well.
    More complex cases involving non-uniform material properties,
    volumetric sources, etc. can be found in the actual source.

-   solve the discretized equations using the appropriate PETSc/SLEPc
    objects, i.e.

    -   KSP for linear static problems
    -   SNES for non-linear static problems
    -   TS for transient problems
    -   EPS for eigenvalue problems

The particular functions that implement each problem type are located in
subdirectories src/pdes, namely

-   laplace
-   thermal
-   mechanical
-   modal
-   neutron_diffusion
-   neutron_sn

Researchers with both knowledge of mathematical theory of finite
elements and programming skills might, with the aid of the community,
add support for other PDES. They might do that by using one of these
directories (say laplace) as a template and

1.  replace every occurrence of laplace in symbol names with the name of
    the new PDE
2.  modify the initialization functions in init.c and set
    -   the names of the unknowns
    -   the names of the materials
    -   the mathematical type and properties of problem
    -   etc.
3.  modify the contents of the elemental matrices in bulk.c in the FEM
    formulation of the problem being added
4.  modify the contents of how the boundary conditions are parsed and
    set in bc.c
5.  re-run autogen.sh, ./configure and make to get a FeenoX executable
    with support for the new PDE.

As we mentioned in FeenoX for hackers, Alan Kay’s says: “simple things
should be simple and complex things should be possible.” Of course, the
addition of non-trivial PDEs is not straightforward, but possible (at
that time we were discussing the first half of the quote, now we refer
to the second part). The programming guide contains further details
about how to contribute to the code base.

-   See FeenoX for engineers for more details about the problem types
    FeenoX can solve and how to solve them.
-   See FeenoX for hackers for more technical details about how FeenoX
    works.

  [both ethical (since it is free) and technical (since it is open source) ground]:
    https://www.seamplex.com/feenox/doc/sds.html#sec:architecture
  [Unix programming philosophy]: https://seamplex.com/feenox/doc/sds.html#sec:unix
  [cloud-first tool]: https://seamplex.com/feenox/doc/sds.html#cloud-first
  [automatically deployed]: https://seamplex.com/feenox/doc/sds.html#sec:deployment
  [ready-to-run program]: https://seamplex.com/feenox/doc/sds.html#sec:execution
  [an input file at run time]: https://seamplex.com/feenox/doc/sds.html#sec:input
  [Software Design Specification]: https://www.seamplex.com/feenox/doc/sds.html
  [2]:
  [C functions]: https://www.seamplex.com/feenox/doc/programming.html#languages
  [parse the input file]: https://seamplex.com/feenox/doc/sds.html#sec:nouns_verbs
  [handle command-line arguments]: https://seamplex.com/feenox/doc/sds.html#sec:run-time-arguments
  [read mesh files]: https://seamplex.com/feenox/doc/feenox-manual.html#read_mesh
  [assign variables]: https://seamplex.com/feenox/doc/feenox-manual.html#description
  [evaluate conditionals]: https://seamplex.com/feenox/doc/feenox-manual.html#if
  [write results]: https://seamplex.com/feenox/doc/sds.html#sec:output
  [material properties]: https://seamplex.com/feenox/doc/sds.html#sec:flexibility
  [algebraic expressions]: https://seamplex.com/feenox/doc/sds.html#sec:expression
  [space]: https://seamplex.com/feenox/doc/tutorials/320-thermal/#sec:mms
  [temperature]: https://www.seamplex.com/feenox/examples/mechanical.html#temperature-dependent-material-properties
  [time]: https://seamplex.com/feenox/doc/tutorials/320-thermal/#from-a-steady-state
  [boundary conditions as algebraic expressions]: https://seamplex.com/feenox/doc/tutorials/320-thermal/#temperature-dependent-heat-flux-radiation
  [stiffness matrix]: https://github.com/seamplex/feenox/blob/main/src/pdes/laplace/bulk.c#L33
  [mass matrix]: https://github.com/seamplex/feenox/blob/main/src/pdes/modal/bulk.c#L98
  [right-hand side vector]: https://github.com/seamplex/feenox/blob/main/src/pdes/thermal/bulk.c#L41
  [Laplace problem]: https://github.com/seamplex/feenox/tree/main/src/pdes/laplace
  [3]: https://petsc.org/
  [SLEPc]: https://slepc.upv.es/
  [KSP]: https://petsc.org/release/manual/ksp/
  [linear static problems]: https://seamplex.com/feenox/doc/tutorials/320-thermal/#linear-steady-state-problems
  [SNES]: https://petsc.org/release/manual/snes/
  [non-linear static problems]: https://seamplex.com/feenox/doc/tutorials/320-thermal/#non-linear-state-state-problems
  [TS]: https://petsc.org/release/manual/ts/
  [transient problems]: https://seamplex.com/feenox/doc/tutorials/320-thermal/#sec:transient
  [EPS]: https://slepc.upv.es/documentation/current/docs/manualpages/EPS/index.html
  [eigenvalue problems]: https://seamplex.com/feenox/examples/neutron_diffusion.html#iaea-3d-pwr-benchmark
  [src/pdes]: https://github.com/seamplex/feenox/tree/main/src/pdes
  [thermal]: https://github.com/seamplex/feenox/tree/main/src/pdes/thermal
  [mechanical]: https://github.com/seamplex/feenox/tree/main/src/pdes/mechanical
  [modal]: https://github.com/seamplex/feenox/tree/main/src/pdes/modal
  [neutron_diffusion]: https://github.com/seamplex/feenox/tree/main/src/pdes/neutron_difussion
  [neutron_sn]: https://github.com/seamplex/feenox/tree/main/src/pdes/neutron_sn
  [the community]: https://github.com/seamplex/feenox/discussions
  [FeenoX for hackers]: ./README4hackers.md
  [Alan Kay]: https://en.wikipedia.org/wiki/Alan_Kay
  [“simple things should be simple and complex things should be possible.”]:
    https://www.quora.com/What-is-the-story-behind-Alan-Kay-s-adage-Simple-things-should-be-simple-complex-things-should-be-possible
  [programming guide]: doc/programming.md
  [FeenoX for engineers]: ./README4engineers.md

Why

The world is already full of finite-element programs, and every day a
grad student creates a new one from scratch. So why adding FeenoX to the
already-crowded space of FEA tools? Because there are either

a.  libraries which need code to use them such as
    -   Sparselizard
    -   MoFEM
    -   FEniCS
    -   MFEM
b.  end-user programs which need a GUI such as
    -   CalculiX
    -   CodeAster

FeenoX sits in the middle. It is the only free and open-source tool that
satisfies the Software Requirements Specification, including that…

-   in order to solve a problem one needs to prepare an input file (not
    a script) which is read at run-time (not code which calls a library)
-   these input files can expand generic command-line options using Bash
    syntax as $1, $2, etc., which allow parametric or optimization loops
    driven by higher-level scripts
-   for solving PDEs, the input file has to refer to at least one Gmsh
    .msh file that defines the domain where the PDE is solved
-   the material properties and boundary conditions are defined using
    physical groups and not individual nodes nor elements, so the input
    file is independent of the mesh and thus can be tracked with Git to
    increase traceability and repeatability.
-   it uses the Unix philosophy which, among others, separates policy
    from mechanism and thus FeenoX is a natural choice for web-based
    interfaces like CAEplex.

See FeenoX for hackers for another explanation about why FeenoX is
different from other computational tools.

  [Software Requirements Specification]: https://www.seamplex.com/feenox/doc/srs.html
  [input file]: https://seamplex.com/feenox/doc/sds.html#sec:input
  [read at run-time]: https://seamplex.com/feenox/doc/sds.html#sec:execution
  [expand generic command-line options using Bash syntax as $1, $2, etc.]:
    https://seamplex.com/feenox/doc/sds.html#sec:run-time-arguments
  [parametric]: https://seamplex.com/feenox/doc/sds.html#sec:parametric
  [optimization loops]: https://seamplex.com/feenox/doc/sds.html#sec:optimization
  [one Gmsh .msh file]: https://seamplex.com/feenox/doc/sds.html#sec:interoperability
  [material properties and boundary conditions]: https://seamplex.com/feenox/doc/sds.html#nafems-le10-benchmark
  [tracked with Git]: https://seamplex.com/feenox/doc/sds.html#sec:git-friendliness
  [traceability and repeatability]: https://seamplex.com/feenox/doc/sds.html#sec:traceability
  [Unix philosophy]: https://seamplex.com/feenox/doc/sds.html#sec:unix
  [separates policy from mechanism]: https://seamplex.com/feenox/doc/sds.html#sec:unix-separation
  [CAEplex]: https://www.caeplex.com
  [FeenoX for hackers]: ./README4hackers.md
