Even if an error condition occurs, the output parameter should be
initialized to something. This makes the behavior predicatable on error
conditions and prevents uninitialized variable warnings.
This is a flag that functions in the execution environment can return to
report on the status of the operation. This way they can report an error
without forcing the entire invocation to shut down.
Cell operations like interpolate and finding parametric coordinates can
fail under certain conditions. Typically these call RaiseError on the
worklet. But that can make a worklet unstable, so provide paths where no
error is raised.
For polygon cell shapes (that are not triangles or quadrilaterals),
interpolations are done by finding the center point and creating a
triangle fan around that point. Previously, the gradient was computed in
the same way as interpolation: identifying the correct triangle and
computing the gradient for that triangle.
The problem with that approach is that makes the gradient discontinuous
at the boundaries of this implicit triangle fan. To make things worse,
this discontinuity happens right at each vertex where gradient
calculations happen frequently. This means that when you ask for the
gradient at the vertex, you might get wildly different answers based on
floating point imprecision.
Get around this problem by creating a small triangle around the point in
question, interpolating values to that triangle, and use that for the
gradient. This makes for a smoother gradient transition around these
internal boundaries.
The gradient is malformed at the apex of a pyramid. To get around this,
steal a trick from the VTK source where in this case interpolate some
values a little bit into the interior of the cell.
Also expand the gradient worklet tests to include all cell types.
Previously we would compute a 3x3 matrix where each element was a Vec. Using
the jacobain of a single component is sufficient so by using that we safe 2 to
3 times the memory space.
Additionally by moving to doing the derivative as a per component algorithm
we work around the issues found in bug
https://gitlab.kitware.com/vtk/vtk-m/issues/221. In effect when trying to
construct a Vec of Vec from a component of a different floating type e.g.:
Vec3d x(0.0, 1.0, 2.0);
Vec3f a = x;
Vec3x3f b = x;
Vec3x3f c(x, x, x);
Generates bad values vectors such as b which look like:
b: [[0,0,0],[1,1,1],[2,2,2]]
c: [[0,1,2],[0,1,2],[0,1,2]]
When the implementation for the cell derivative functions was made, the
special cases for creating the Jacobian for wedge and pyramid cell
shapes was not working. Instead, it just used the hexahedra case for a
degenerate cell. This fixes the issues with the special cases.
There were multiple issues to be fixed. There were some complaints
by the compiler about types. There was a mistake in the pyramid table.
But the biggest issue was a problem with macro expansions. It was
the classic tale of forgetting that you have to encase parameters
in parenthesis to make sure that operator precedence comes out as
expected.
Sandia National Laboratories recently changed management from the
Sandia Corporation to the National Technology & Engineering Solutions
of Sandia, LLC (NTESS). The copyright statements need to be updated
accordingly.
The cell derivative/gradient functions were all designed with scalars in
mind. Although the field type is templated and you could pass in a
vector type for the field, many of these classes would perform the
computation incorrectly. These changes specifically support derivatives
of vector types.
Change the VTKM_CONT_EXPORT to VTKM_CONT. (Likewise for EXEC and
EXEC_CONT.) Remove the inline from these macros so that they can be
applied to everything, including implementations in a library.
Because inline is not declared in these modifies, you have to add the
keyword to functions and methods where the implementation is not inlined
in the class.
These asserts are consolidated into the unified Assert.h. Also made some
minor edits to add asserts where appropriate and a little bit of
reconfiguring as found.
Scatter in worklets
Add the functionality to perform a scatter operation from input to output in a worklet invocation. This allows you to, for example, specify a variable amount of outputs generated for each input.
See merge request !221
Recent changes to algorithm implementations caused CellDerivative to be
called in a way such that it gave conversion warnings on some compilers.
Fix that.
These cell types are inherited from VTK, but they are basically the same
as quad and hexahedron, respectively. The only useful difference is that
pixel and voxel are supposed to be axis aligned, but you cannot
determine that by the cell shape alone (at least not just from the cell
set).
A big issue with these is that their indexing is different that of quad
and hex. The development team had a long discussion about the benefits
of the alternate indexing, but after consulting with Berk Geveci and
Will Schroder from the VTK team, that indexing is not really taken
advantage of at the cell level. Thus, it is really just a nuisance in
VTK-m.
The original way was overconstrained with respect to the number of
parametric coordinates.
Also implemented WorldCoordinatesToParametricCoordinates for polygons.
The general polygon version is not implemented yet because I need to
change the way it is interpolated.
To get wedge to work correctly, I had to change the interpolation
slightly there. Previously the interpolation had a singularity at
the tip.
The functions for doing interpolations and derivatives were called
CellInterpolate and CellDerivative, but the file names were
Interpolate.h and Derivative. Now the files are CellInterpolate.h and
CellDerivative.h so they are more consistent and a bit easier to find.
The interpolate and derivative functions has the shape tag at end of the
function arguments (just before the "worklet" parameter, which is just
the error handling mechanism). However, the parametric coordinate
functions had the shape tag at the beginning. Moved the shape tag to the
end to be more consistent within these functions and also in other uses
throughtout VTK-m.