CompactNSearch is a C++ library for parallel computation of neighboring points in a fixed radius in a three-dimensional point cloud. The implemented algorithm is a variant of the Compact Hashing approach proposed by Ihmsen et al. [IABT11]. The neighborhood information can be efficiently updated when the points spatially move. Moreover, the library offers the possibility to reorder the points (and other array-stored per point information) according to a space-filling Z curve to improve the cache efficiency in later queries or accesses.
The library was used to generate all results of the SPH-based fluid simulations presented by Bender and Koschier in [BK15, BK16].
Author: Dan Koschier, License: MIT
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This project is based on CMake. Simply generate project, Makefiles, etc. using CMake and compile the project with the compiler of your choice. The code was tested with the following configurations:
- Windows 10 64-bit, CMake 3.7, Visual Studio 2015
- Debian 8 64-bit, CMake 3.7, GCC 4.9.2.
A data structure to perform a neighborhood search can be created by calling the constructor given a fixed search radius r
.
CompactNSearch::NeighborhoodSearch nsearch(r);
An arbitrary number of point clouds can then be added to the data structure using the method add_point_set
. The library expects the point positions to be contiguously stored in an array-like structure. The method will return a unique id associated with the initialized point set.
// ... Fill array with 3 * n real numbers representing three-dimensional point positions.
std::vector<std::array<Real, 3>> point_set_1;
std::vector<std::array<Real, 3>> point_set_2;
unsigned int point_set_1_id = nsearch.add_point_set(point_set_1.front().data(), positions.size());
unsigned int point_set_2_id = nsearch.add_point_set(point_set_2.front().data(), positions.size());
In order to generate the neighborhood information simply execute the following command
nsearch.find_neighbors();
Finally, the neighborhood information can be accessed as follows
CompactNSearch::PointSet const& ps_1 = nsearch.point_set(point_set_1_id);
for (int i = 0; i < ps_1.n_points(); ++i)
{
// Get point set 1 neighbors of point set 1.
for (size_t j = 0; j < ps_1.n_neighbors(point_set_1_id, i); ++j)
{
// Return the point id of the jth neighbor of the ith particle in the point_set_1.
const unsigned int pid = ps_1.neighbor(point_set_1_id, i, j);
}
// Get point set 2 neighbors of point set 1.
for (size_t j = 0; j < ps_1.n_neighbors(point_set_2_id, i); ++j)
{
// Return the point id of the jth neighbor of the ith particle in the point_set_1.
const unsigned int pid = ps_1.neighbor(point_set_2_id, i, j);
}
}
Besides the basic functionality the library offers to compute a rule for reordering the points according to a space-filling Z curve. The reordering will improve the performance of future neighborhood queries and accesses. The rule can be computed via
nsearch.z_sort();
Please note that the actual reordering must be invoked by the user by
ps_1.sort_field(positions.data());
Assuming that there is additional information stored per-point (e.g. velocity, color, mass etc.) the information must also be reorded using the same method to maintain consistency. Subsequently, the find_neighbors
function has to be invoked again to update the neighborhood information.
Another self-explaining (benchmark) demo is contained in the project.
When maintaining multiple it is sometimes desired that only certain point sets can find points from other point sets. Therefore an activation table is implemented where the user can specify whether a point set i searches points in another point set j. When nothing else is specified all point sets will search points in all other point sets. The activation table can be modified with e.g.
// Point set 2 will not look for neighbors within its own points
nsearch.set_active(point_set_2_id, point_set_2_id, false)
- [IABT11] M. Ihmsen, N. Akinci, M. Becker and M. Teschner, 2011. "A Parallel SPH Implementation on Multi-Core CPUs", Computer Graphics Forum 30, 1, 99-112.
- [BK15] J. Bender and D. Koschier 2015. "Divergence-Free Smoothed Particle Hydrodynamics", ACM SIGGRAPH / Eurographics Symposium on Computer Animation, 1-9
- [BK17] J. Bender and D. Koschier, 2017. "Divergence-Free SPH for Incompressible and Viscous Fluids", IEEE Transactions on Visualization and Computer Graphics.