I'm trying to write an efficient kernel that would find a min/max along each row in a float matrix. In my case all elements in the matrix are of the same sign - negative, so I arrived at a pretty efficient one-kernel solution:

```
__global__ void min_reduction2D_unified(float * mat, float * out, int col, int row){
// thread and block coordinates ...
int tx = threadIdx.x; int ty = threadIdx.y;
int bx = blockIdx.x; int by = blockIdx.y;
int bDx = blockDim.x; int bDy = blockDim.y;
int gDx = gridDim.x;
//
int Idx = bDx * bx + tx;
int Idy = bDy * by + ty;
int gridSize = gDx * bDx;
//
float2 vec2_load;
float vec1_load;
float pre_accum = FLT_MAX;
//
// massive coalesced vvectorized loading ...
for (int i = 0; i < 32; i++) {
if (Idy < row) {
if (2*Idx+1 < col) {
vec2_load = reinterpret_cast<float2*>(mat)[Idy*(col>>1) + Idx];
pre_accum = min(pre_accum, vec2_load.x);
pre_accum = min(pre_accum, vec2_load.y);
} else if (2*Idx < col) {
vec1_load = mat[Idy*col + 2*Idx];
pre_accum = min(pre_accum, vec1_load);
}
}
Idx += gridSize;
}
// wait for all this loading to finish ...
__syncthreads();
//
// using register shuffling within the warp - blazing fast!
pre_accum = min(pre_accum, __shfl_down(pre_accum,8,16));
pre_accum = min(pre_accum, __shfl_down(pre_accum,4,16));
pre_accum = min(pre_accum, __shfl_down(pre_accum,2,16));
pre_accum = min(pre_accum, __shfl_down(pre_accum,1,16));
// store result back to global ...
if ((tx == 0) && (Idy < row)) {
atomicMax((unsigned int *)&out[Idy], (unsigned int)__float_as_int(pre_accum));
}
// no atomicMin for float so far ...
//
}
```

this is being launched with:

```
dim3 block(16,16);
dim3 grid((COLUMNS-1)/(2*BLOCK.X*32)+1 , (ROWS-1)/BLOCK.Y+1);
```

works very well, achieving >50% of bandwidth for my matrix of (col,rows) = (10000,8192). And atomic hack for negative float works well without slowing down the calculations.

**Now along with the min value of each row I need to store the index of such minimal elements!**
This is a more complicated problem, especially in the latest part when we're storing results back atomically. At first I gave up, on the atomic output and made a 2-stage reduction: I need to make sure that number of blocks grid.x is 16 (block.x) to complete reduction with just 2 stages, and I also need several (two) temporary arrays, to store intermediate results - that's all right, but I still liked the simplicity of the one-kernel atomic solution - it's much cleaner to my taste...

I started digging into custom atomics using atomicCAS, and different mutexes. Essentially I realized that I need to perform several atomic operations on 2 global addresses: first I have to do atomicmin for the min value in a current block, and then, if that min value would turn to be smaller than value at the global address, I also would need to do atomicExch with index of my min value... At the same time I have to make sure somehow that values in global array of mins and their indexes are in sync! I've learned that it's called DCAS - double Compare and Swap - and that is very exotic fruit, almost nonexistent.

So far I came with a working solution with several semaphores(mutexes or locks - i'm very bad at terminology):

```
__global__ void experimental_reduction2D(int *mutexes, float * mat, float * out, int * out_idx, int col_str, int row_seq){
// thread and block coordinates ...
int tx = threadIdx.x; int ty = threadIdx.y;
int bx = blockIdx.x; int by = blockIdx.y;
int bDx = blockDim.x; int bDy = blockDim.y;
int gDx = gridDim.x;
//
int Idx = bDx * bx + tx;
int Idy = bDy * by + ty;
int gridSize = gDx * bDx;
//
float2 vec2_load;
float vec1_load;
float pre_accum = FLT_MAX;
float pre_accum_tmp;
int min_index=0;
int min_index_tmp;
// massive coalsced loading ...
for (int i = 0; i < 32; i++) {
if (Idy < row_seq) {
if (2*Idx+1 < col_str) {
vec2_load = reinterpret_cast<float2*>(mat)[Idy*(col_str>>1) + Idx];
if (pre_accum > vec2_load.x){pre_accum = vec2_load.x; min_index = 2*Idx+0;};
if (pre_accum > vec2_load.y){pre_accum = vec2_load.y; min_index = 2*Idx+1;};
} else if (2*Idx < col_str) {
vec1_load = mat[Idy*col_str + 2*Idx];
if (pre_accum > vec1_load){pre_accum = vec1_load; min_index = 2*Idx;};
}
}
Idx += gridSize;
}
__syncthreads();
// using register shuffling within the warp - blazing fast!
pre_accum_tmp=__shfl_down(pre_accum,8,16);
min_index_tmp=__shfl_down(min_index,8,16);
if (pre_accum > pre_accum_tmp){ pre_accum=pre_accum_tmp; min_index=min_index_tmp;};
pre_accum_tmp=__shfl_down(pre_accum,4,16);
min_index_tmp=__shfl_down(min_index,4,16);
if (pre_accum > pre_accum_tmp){ pre_accum=pre_accum_tmp; min_index=min_index_tmp;};
pre_accum_tmp=__shfl_down(pre_accum,2,16);
min_index_tmp=__shfl_down(min_index,2,16);
if (pre_accum > pre_accum_tmp){ pre_accum=pre_accum_tmp; min_index=min_index_tmp;};
pre_accum_tmp=__shfl_down(pre_accum,1,16);
min_index_tmp=__shfl_down(min_index,1,16);
if (pre_accum > pre_accum_tmp){ pre_accum=pre_accum_tmp; min_index=min_index_tmp;};
//
// global storing to be done atomically ...
if ((tx == 0) && (Idy < row_seq)) {
lock(&mutexes[Idy]);
float old_val = out[Idy];
if (pre_accum < old_val) {
out[Idy] = pre_accum;
out_idx[Idy] = min_index;
}
unlock(&mutexes[Idy]);
}
}
```

and my lock/unlock is a simple copy paste from others:

```
__device__ void lock(int *pmutex) {
while(atomicCAS(pmutex, 0, 1) != 0);
}
__device__ void unlock(int *pmutex) {
atomicExch(pmutex, 0);
}
```

I realized that I need many semaphores because calculation of min in each row is independent and it'd be too expensive to use 1 lock for all global memory stores. So far this kernel works with initialized array of mutexes (ROWS ints initialized to zero). This one-kernel solution yield pretty good performance, but it is slower than 2 stage reduction with temporary arrays by around 15-20%: ~3.3 ms vs ~3.6ms for my matrix dimensions.

So, then question here is actually - can I improve this one-kernel solution with locks somehow? Can anyone comment on 2-stage reduction(with tmp-arrays) vs one-kernel solution(with atomics/locks at the end)? - so far I'm leaning towards one-kernel thing due to cleaner code. Is my reasoning about updating two global addresses correct(?) and DCAS is really needed, or I'm misunderstanding something and this can be solved with simple atromics? Any feedback would be greatly appreciated