As I've mentioned in my comments, I think it is the wrong approach to start with this sort of linked list-like structure since pointer chasing will negatively impact performance, especially for large particle lists. But to show this, we have to make a benchmark and a minimum reproducible example. So I modify the shown code for this.

## Original approach

```
struct Boxes
{
int m_NX;
int m_NY;
double m_boxsize;
Eigen::ArrayXi m_boxes;
Boxes(int NX, int NY, double boxsize)
: m_NX(NX),
m_NY(NY),
m_boxsize(boxsize),
m_boxes(Eigen::ArrayXi::Constant(NX * NY, -1))
{}
};
```

Since the original question didn't make this abundantly clear: `m_boxes`

contains the index of one particle in the respective box. I chose to denote the end of the linked list (no particles in the box) as particle index -1.

```
struct Particles
{
Eigen::Array2Xd m_positions;
Eigen::ArrayXi m_nextParticles;
explicit Particles(int N)
: m_positions(Eigen::Array2Xd::Random(2, N).abs()),
m_nextParticles(Eigen::ArrayXi::Constant(N, -1))
{}
int nbParticles() const noexcept
{ return static_cast<int>(m_positions.cols()); }
};
```

Again to explain the original design, `m_nextParticles`

holds, for each particle, the index of the next one in the same box. And again -1 indicates the end of the list.

Two further changes / optimizations:

- The member
`m_nbParticles`

was redundant as both arrays know their size and therefore the number of particles
- I changed the array type to
`Array2Xd`

since we deal with 2D coordinates. One column per particle (`Array2Xd`

instead of `ArrayX2d`

) is more efficient, at least for the processing we do in my example, because Eigen is column-major
- For testing, I build random particles in the range [0, 1)

```
void link_list(Boxes& p_boxes, Particles& p_particles)
{
p_boxes.m_boxes.fill(-1);
p_particles.m_nextParticles.fill(-1);
const double boxscale = 1. / p_boxes.m_boxsize;
for(int i = 0, n = p_particles.m_positions.cols(); i < n; ++i) {
Eigen::Array2i coords =
(p_particles.m_positions.col(i) * boxscale).cast<int>();
int indexBox = coords.y() * p_boxes.m_NX + coords.x();
p_particles.m_nextParticles[i] =
std::exchange(p_boxes.m_boxes[indexBox], i);
}
}
```

A slightly optimized version of the original that avoids the two divisions of the original. It is not parallelized and I don't think it can realistically be done. Maybe by replacing the `std::exchange`

with an atomic exchange. But given the cost of that operation and the constant cache line bouncing it will produce, I doubt this is viable.

For benchmarking, we need some code to actually make use of the list. I chose a simple, parallelized iteration over each box that computes the center of mass per bin. Nothing fancy, nothing realistic, but the access pattern may be close to a real use case:

```
Eigen::Array2Xd traverse_list(const Boxes& p_boxes, Particles& p_particles)
{
const int n = p_boxes.m_boxes.size();
Eigen::Array2Xd center(2, n);
# pragma omp parallel for
for(int i = 0; i < n; ++i) {
Eigen::Array2d sum = Eigen::Array2d::Zero();
int pcount = 0;
int particleIndex = p_boxes.m_boxes[i];
while(particleIndex >= 0) {
sum += p_particles.m_positions.col(particleIndex);
pcount += 1;
particleIndex = p_particles.m_nextParticles[particleIndex];
}
center.col(i) = sum / static_cast<double>(pcount);
}
return center;
}
```

My benchmark run looks like this:

```
int main()
{
int n_particles = 10000000, n_boxes = 200, n_repetitions = 10, n_traversals = 10;
Boxes boxes(n_boxes, n_boxes, 1. / n_boxes);
Particles particles(n_particles);
for(int i = 0; i < n_repetitions; ++i) {
link_list(boxes, particles);
for(int j = 0; j < n_traversals; ++j)
traverse_list(boxes, particles);
}
}
```

Runtime on my 8 core 16 thread system is

```
real 0m7,727s
user 1m56,050s
sys 0m0,385s
```

I expect performance to be worse on systems without hyperthreading where pointer chasing will stall the entire core.

## Alternative approach

Instead of constructing a linked list, we can use a vector of particles per box. That avoids the pointer chasing, makes traversal easier, and allows some more independent operations. The memory requirement stays practically the same. Only the fixed overhead per box grows.

```
struct Boxes
{
int m_NX;
int m_NY;
double m_boxsize;
std::vector<std::vector<int>> m_boxes;
Boxes(int NX, int NY, double boxsize)
: m_NX(NX),
m_NY(NY),
m_boxsize(boxsize),
m_boxes(static_cast<unsigned>(NX * NY))
{}
static Boxes empty_like(const Boxes& p_o)
{ return Boxes(p_o.m_NX, p_o.m_NY, p_o.m_boxsize); }
};
struct Particles
{
Eigen::Array2Xd m_positions;
explicit Particles(int N)
: m_positions(Eigen::Array2Xd::Random(2, N).abs())
{}
};
```

To fill the boxes, we start with a sequential algorithm for comparison:

```
void link_list(Boxes& p_boxes, Particles& p_particles)
{
for(std::vector<int>& box: p_boxes.m_boxes)
box.clear();
const double boxscale = 1. / p_boxes.m_boxsize;
for(int i = 0, n = p_particles.m_positions.cols(); i < n; ++i) {
Eigen::Array2i coords =
(p_particles.m_positions.col(i) * boxscale).cast<int>();
unsigned indexBox = static_cast<unsigned>(
coords.y() * p_boxes.m_NX + coords.x());
p_boxes.m_boxes[indexBox].push_back(i);
}
}
```

And the traversal function:

```
Eigen::Array2Xd traverse_list(const Boxes& p_boxes, Particles& p_particles)
{
const std::size_t n = p_boxes.m_boxes.size();
Eigen::Array2Xd center(2, static_cast<Eigen::Index>(n));
# pragma omp parallel for
for(std::size_t i = 0; i < n; ++i) {
Eigen::Array2d sum = Eigen::Array2d::Zero();
for(int particleIndex: p_boxes.m_boxes[i])
sum += p_particles.m_positions.col(particleIndex);
center.col(static_cast<Eigen::Index>(i)) =
sum / static_cast<double>(p_boxes.m_boxes[i].size());
}
return center;
}
```

We still have a chaotic memory access pattern when reading the coordinates but we got rid of the loop-carried dependency on the next particle index. Instead, this code only has a loop-carried dependency chain on the sum, which of course is part of the example, not the real application. This runs at

```
real 0m5,032s
user 1m6,940s
sys 0m0,394s
```

We can try parallelizing the `link_list`

function, too. However, the best I could come up with requires some temporary memory and cross-thread communication.

```
void link_list(Boxes& p_boxes, Particles& p_particles)
{
const double boxscale = 1. / p_boxes.m_boxsize;
const std::size_t n_boxes = p_boxes.m_boxes.size();
const int n_particles = static_cast<int>(p_particles.m_positions.cols());
using box_ptr = Boxes*;
const std::unique_ptr<box_ptr[]> threadboxes =
std::make_unique<box_ptr[]>(omp_get_max_threads());
# pragma omp parallel
{
const int threadcount = omp_get_num_threads();
const int threadid = omp_get_thread_num();
Boxes own_boxes = Boxes::empty_like(p_boxes);
threadboxes[threadid] = &own_boxes;
# pragma omp for
for(int i = 0; i < n_particles; ++i) {
Eigen::Array2i coords =
(p_particles.m_positions.col(i) * boxscale).cast<int>();
unsigned indexBox = static_cast<unsigned>(
coords.y() * own_boxes.m_NX + coords.x());
own_boxes.m_boxes[indexBox].push_back(i);
}
# pragma omp for
for(std::size_t i = 0; i < n_boxes; ++i) {
// move to local to reduce cache-line bouncing
std::vector<int> box = std::move(p_boxes.m_boxes[i]);
box.clear();
for(int j = 0; j < threadcount; ++j) {
const std::vector<int>& threadbox =
threadboxes[j]->m_boxes[i];
box.insert(box.end(), threadbox.begin(), threadbox.end());
}
p_boxes.m_boxes[i] = std::move(box);
}
}
}
```

The idea is pretty simple. We use two phases:

- We create a
`Boxes`

structure per thread that each thread can fill individually with a subset of all particles
- We concatenate all partial boxes into the final result

This is very similar to how one would parallelize a histogram computation. In fact, we run into many of the same issues and can probably apply the same techniques.

There are four problems with this approach:

- The temporary memory allocations cost performance
- When concatenating, we cause a lot of cross-CPU communication
- We invoke several implicit thread barriers (one per loop)
- The actual work we do to compute the box of each particle is very small. We start with an algorithm that is mostly memory-constrained and then add more memory operations on top

All in all, this is not faster, at least on my system.

```
real 0m5,852s
user 1m26,415s
sys 0m0,757s
```

## Final thoughts

- I already mentioned that this kind of fixed pattern bin may not be ideal. Other structures like R-trees are specifically built for checking nearest neighbours and similar tasks.

Boost's Spatial Indexes have a handy, if not well documented, implementation. A fixed grid can still work fine but mostly for densely packed and equally distributed data where you also know the search radii a-priori

If your particle dataset is mostly read-only, sorting into a k-d tree can be done with zero memory overhead and just `std::nth_element`

- Once you start modifying the particles while iterating over the boxes, performance will suffer through cache-line bouncing and possibly running out of store-buffers. A chaotic write pattern by multiple threads on the same data structure is simply not ideal. If this is something you do, consider actually sorting the particles spatially so that particles in the same box are also located together. This applies to both approaches of traversing the blocks

`#pragma omp atomic read`

, and for the second one try`#pragma omp atomic write`

.`indexBox`

value is obtained in different iterations, then you can't predict which value will be set in`p_boxes.m_boxes[indexBox]`

. Beside, I completely missed that`indexX`

,`indexY`

, and`indexBox`

should be declared as`private`

(or should be declared within the loop).4more comments