When I increase the unrolling from 8 to 9 loops in my kernel, it breaks with an `out of resources`

error.

I read in How do I diagnose a CUDA launch failure due to being out of resources? that a mismatch of parameters and an overuse of registers could be a problem, but that seems not be the case here.

My kernel calculates the distance between `n`

points and `m`

centroids and selects for each point the closest centroid. It works for 8 dimensions but not for 9. When I set `dimensions=9`

and uncomment the two lines for the distance calculation, I get an `pycuda._driver.LaunchError: cuLaunchGrid failed: launch out of resources`

.

**What do you think, could cause this behavior? What other iusses can cause an out of resources*?**

I use an Quadro FX580. Here is the minimal(ish) example. For the unrolling in the real code I use templates.

```
import numpy as np
from pycuda import driver, compiler, gpuarray, tools
import pycuda.autoinit
## preference
np.random.seed(20)
points = 512
dimensions = 8
nclusters = 1
## init data
data = np.random.randn(points,dimensions).astype(np.float32)
clusters = data[:nclusters]
## init cuda
kernel_code = """
// the kernel definition
__device__ __constant__ float centroids[16384];
__global__ void kmeans_kernel(float *idata,float *g_centroids,
int * cluster, float *min_dist, int numClusters, int numDim) {
int valindex = blockIdx.x * blockDim.x + threadIdx.x ;
float increased_distance,distance, minDistance;
minDistance = 10000000 ;
int nearestCentroid = 0;
for(int k=0;k<numClusters;k++){
distance = 0.0;
increased_distance = idata[valindex*numDim] -centroids[k*numDim];
distance = distance +(increased_distance * increased_distance);
increased_distance = idata[valindex*numDim+1] -centroids[k*numDim+1];
distance = distance +(increased_distance * increased_distance);
increased_distance = idata[valindex*numDim+2] -centroids[k*numDim+2];
distance = distance +(increased_distance * increased_distance);
increased_distance = idata[valindex*numDim+3] -centroids[k*numDim+3];
distance = distance +(increased_distance * increased_distance);
increased_distance = idata[valindex*numDim+4] -centroids[k*numDim+4];
distance = distance +(increased_distance * increased_distance);
increased_distance = idata[valindex*numDim+5] -centroids[k*numDim+5];
distance = distance +(increased_distance * increased_distance);
increased_distance = idata[valindex*numDim+6] -centroids[k*numDim+6];
distance = distance +(increased_distance * increased_distance);
increased_distance = idata[valindex*numDim+7] -centroids[k*numDim+7];
distance = distance +(increased_distance * increased_distance);
//increased_distance = idata[valindex*numDim+8] -centroids[k*numDim+8];
//distance = distance +(increased_distance * increased_distance);
if(distance <minDistance) {
minDistance = distance ;
nearestCentroid = k;
}
}
cluster[valindex]=nearestCentroid;
min_dist[valindex]=sqrt(minDistance);
}
"""
mod = compiler.SourceModule(kernel_code)
centroids_adrs = mod.get_global('centroids')[0]
kmeans_kernel = mod.get_function("kmeans_kernel")
clusters_gpu = gpuarray.to_gpu(clusters)
cluster = gpuarray.zeros(points, dtype=np.int32)
min_dist = gpuarray.zeros(points, dtype=np.float32)
driver.memcpy_htod(centroids_adrs,clusters)
distortion = gpuarray.zeros(points, dtype=np.float32)
block_size= 512
## start kernel
kmeans_kernel(
driver.In(data),driver.In(clusters),cluster,min_dist,
np.int32(nclusters),np.int32(dimensions),
grid = (points/block_size,1),
block = (block_size, 1, 1),
)
print cluster
print min_dist
```