Previously, the initilaizer_list of Vec had to be the exact
same number of values as the size of the Vec. Now, we also
accept a single value that is duplicated for all values in
the Vec. That allows you to more easily construct lists
of lists with repeated values.
Add constructors to the `vtkm::Vec` classes that accept
`std::initializer_list`. The main advantage of this addition is that it
makes it much easier to initialize `Vec`s of arbitrary length.
When you have a Vec<Vec<float,3>> it was possible to incorrectly correct
it with the contents of a Vec<double,3>. An example of this is:
using Vec3d = vtkm::Vec<double, 3>;
using Vec3f = vtkm::Vec<float, 3>;
using Vec3x3f = vtkm::Vec<Vec3f, 3>;
Vec3d x(0.0, 1.0, 2.0);
Vec3x3f b(x); // becomes [[0,0,0],[1,1,1],[2,2,2]]
Vec3x3f c(x, x, x); // becomes [[0,1,2],[0,1,2],[0,1,2]]
Vec3x3f d(Vec3f(0.0f,1.0f,2.0f)) //becomes [[0,0,0],[1,1,1],[2,2,2]]
So the solution we have chosen is to disallow the construction of objects such
as b. This still allows the free implicit cast to go from double to float.
So while `Vec3x3 b = x is supported by vtk-m, it produces very incorrect results.
When using vtkm::dot on narrow types you easily rollover the values.
Instead the result type of vtkm::dot should be wide enough to store the results
(32bits) when this occurs.
Fixes#193
For std::copy to optimize a copy to memcpy, the valuetype must be both
trivially constructable and trivially copyable.
The new copy benchmarks highlighted an issue that std::copy'ing pairs
and vecs were not optimized to memcpy. For a 256 MiB buffer on my
laptop w/ GCC, the serial copy speeds were:
UInt8: 10.10 GiB/s
Vec<UInt8, 2> 3.12 GiB/s
Pair<UInt32, Float32> 6.92 GiB/s
After this patch, the optimization occurs and a bitwise copy occurs:
UInt8: 10.12 GiB/s
Vec<UInt8, 2> 9.66 GiB/s
Pair<UInt32, Float32> 9.88 GiB/s
Check were also added to the Vec and Pair unit tests to ensure that
this classes continue to be trivial.
The ArrayHandleSwizzle test was refactored a bit to eliminate a new
'possibly uninitialized memory' warning introduced with the default
Vec ctors.
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.
For some reason when VTK-m was being compiled as an accelerator in VTK,
Visual Studio 2013 gave a bunch of warnings about not being able to generate
assignment operators for many classes. This happened for classes with a
const ivar that could not be automatically set. (Automatic copy constructors
are fine on this count.) I'm not sure why these warnings did not happen
when just compiling VTK-m, nor am I sure why they were generated at all as
no code actually used the copy constructors.
This commit fixes the problems by adding a private declaration for assignment
operators that cannot be automatically created. No implementation is
provided, nor should any be needed.
When using Types or Matrix with the nvcc compiler with Wunused-value
enabled you would get the following warning:
(__builtin_expect(!(rowIndex < (this,NUM_ROWS)), 0)) ?
__assert_rtn(__func__, "vtkm/Matrix.h", 86, "rowIndex < this->NUM_ROWS") :
((void)0);
This is solved by changing this->NUM_ROWS to just NUM_ROWS.
I forgot to add the VTKM_EXEC_CONT modifier to the make_VecC methods,
and that causes them to fail on CUDA devices.
I wish the compiler would have said something. I was calling one of them
from a VTKM_EXEC method.
These structs behave much like Vec except that they work on a short C
array given to them rather than having the statically sized short array
defined within.
I expect to use this in the short term to help implement cell face
classes, but there are probably many other uses.
4de37559 fix a pragma location bug
9048e0ba detect cuda versions and decide if to put a diagnostic inside or outside of a class.
Acked-by: Kitware Robot <kwrobot@kitware.com>
Merge-request: !611
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.
It is common to write template code that needs to operate across both
scalar and vector values. To facilitate code like this we are required
to provide these common operators.
Add in the vtkm namespace an assert macro (technically VTKM_ASSERT) that
basically replicates the functionality of the POSIX assert macro. This
form of assert is set to replace the separate control/exection asserts.
It has been decided that an assert that throws an exception instead of
terminating the program is not all that great of a feature and it causes
some limitations on how it is used. The next commit will remove the
other forms of VTK-m assert.
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
This has been requested on the mailing list to make it easier to
interpolate integer vectors.
There are a couple of downsides to this addition. First, it implicitly
casts doubles back to whatever the vector type is, which can cause a
loss of precision. Second, it makes it more likely to get overload
errors when multiplying with Vec. In particular, the operator to cast
Vec of size 1 to the component class had to be removed.
These changes are basically to support some upcoming changes to
ArrayHandleZip. The major additions are an implementation of VecTraits
for Pair and an overloaded << operator to ostream for Pair.
I also had to declare the operator<< for Pair to be in Types.h. Under
some circumstances the operator has to either be declared before the
template is declared or declared in the vtkm namespace. (The reasons are
described at <http://clang.llvm.org/compatibility.html#dep_lookup> but I
still don't understand.) I tried adding it to the vtkm namespace, but
that caused several of the other operator<< to fail. Since there is no
way to guarantee that Pair.h is declared before, say, ArrayHandle.h, I
moved the implementation to Types.h.
Since I was moving operator<< to Types.h, I went ahead and moved the
TypeTraits and VecTraits to their respective headers. Since Pair is
declared (but not implemented) in Types.h, these templated classes can
be implemented without including Pair.h.
The recently added pragma to suppress warnings about unused local
typedefs caused lots of dashboard failures because many GCC and clang
compiler do not have this warning so did not recognized the pragma to
suppress it. Now only use the pragma on clang compilers with a large
enough version.
I also discovered that the check for VTKM_CLANG was wrong (at least for
the most modern versions of XCode). Fixed that as well as some uses of
VTKM_CLANG that were wrong.
In the special case where you are loading the point coordinates for a
structured grid in a point to cell map (an important use case), create a
VecRectilinearPointCoordinates rather than build a Vec of the values.
This will activate the cell specalizations in previous commits.
These changes also added some flat-to-logical index conversion and vice
versa in ConnectivityStructuredInternals. This change also fixed a bug
in getting cells attached to points in 2D grids. (Actually, technically
someone else fixed it and checked it in first. The changes were merged
during a rebase.)
I also added a specalization to Vec for 1D that implicitly converts
between the 1D Vec and the component. This can be convenient when
templating on the Vec length.