# GPU Precision issues for relatively small array sizes?

I have some CUDA code that does some linear algebra to invert a special type of structured matrix. I calculate RMS error using the results of a serialized version of the algorithm. The error grows with problem size to a greater extent that I would expect. Can anyone provide insight as to why this may be the case?

The GPU code is very naive. This is intentional, and I will optimize it very soon - I just wanted a simple baseline kernel that gives the proper results.

`````` __global__ void levinson_durbin_gpu(TYPE *h0_d, TYPE *h_d, TYPE *v_d, TYPE *x_d, TYPE *y_d, int N) //Naive kernel
{
int i;

__shared__ TYPE hn_1[512];
hn_1[j] = h_d[j];

for(i=1; i<N; i++)
{
if(j < i)
{
TYPE hn = h_d[i];
TYPE yn = y_d[i];

//Set up temporary arrays, compute inner products
__shared__ TYPE temp[512]; //Temp for hn_1_J_v
__shared__ TYPE temp2[512]; //Temp for hn_1_J_x
__shared__ TYPE temp3[512]; //Temp for hn_1_v

temp[j] = hn_1[j]*v_d[i-j-1];
temp2[j] = hn_1[j]*x_d[i-j-1];
temp3[j] = hn_1[j]*v_d[j];

//Three reductions at once
for(unsigned int s=1; s<i; s*=2)
{
int index = 2*s*j;
if((index+s) < i)
{
temp[index] += temp[index+s];
temp2[index] += temp2[index+s];
temp3[index] += temp3[index+s];
}
}

TYPE hn_1_J_v = temp[0];
TYPE hn_1_J_x = temp2[0];
TYPE hn_1_v = temp3[0];

TYPE alpha_v = (hn - hn_1_J_v)/(h0_d[0] - hn_1_v);
TYPE alpha_x = (yn - hn_1_J_x)/(h0_d[0] - hn_1_v);

__shared__ TYPE w_v[512];
w_v[j] = v_d[j] - alpha_v*v_d[i-j-1];

__shared__ TYPE w_x[512];
w_x[j] = x_d[j] - alpha_x*v_d[i-j-1];

v_d[j] = w_v[j];
x_d[j] = w_x[j];
if(j == 0)
{
v_d[i] = alpha_v;
x_d[i] = alpha_x;
}

}

}

}
``````

The identifier `TYPE` is either float or double depending on how I compile the code. I'm using 1 block with N threads (again, keeping things naive and simple here). With single precision I see the following results:

N=4: RMS Error = 0.0000000027
N=8: RMS Error = 0.0000001127
N=16: RMS Error = 0.0000008832
N=32: RMS Error = 0.0000009233
N=64: RMS Error = 42.0136776452
N=80: RMS Error = 281371.7533760048

I can't tell if this is an error with my algorithm or some sort of precision issue. If it helps I can show the above results using double precision, the CPU version of the algorithm, or the code that calculates the RMS error. I'm using a GeForce GTX 660 Ti (cc 3.0) GPU. The variable `x_d` contains the end result.

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This probably has nothing at all to do with precision and everything to do with a buffer overflow. It is very hard to guess what might be going wrong without a complete repro case to study, but I would be extremely suspicious of `index = 2*s*j`. If I am reading the code correctly, for your N=80 example you could have i=79, j=78 which would give s=64 and index = 2*64*78 = 9984 which is a big buffer overflow. Have you confirmed no API errors and tried running the code with cuda-memcheck? –  talonmies Dec 3 '12 at 11:22
Thanks for your response @talonmies. I have confirmed that there are no API errors but I have not used cuda-memcheck yet, I'll do that shortly. Just to be clear, why would such a buffer overflow be occurring? Note that I only access the temp arrays when `(index+s) < i` so in your example I only access `temp[0]` through `temp[79]` because `N=80`. –  Adam27X Dec 3 '12 at 15:06
@Adam27X: it seems that the conditional branch 'if(j < i)' is not uniform, while you call syncthreads() inside it. This might lead to unpredicted results –  user1545642 Dec 3 '12 at 15:28
btw I assume this is very likely a synchronization problem in since for N <= 32 (warp size) the algorithm works fine but once you go beyond the warp boundary, the error estimate blows up –  user1545642 Dec 3 '12 at 15:39
@asm Sounds reasonable but how would I solve that problem? Loop iteration `i+1` depends on the results from loop iteration `i` so I do need some sort of a barrier there... –  Adam27X Dec 3 '12 at 16:41

Thanks to the help from the comments section I was able to solve the problem myself, so I'll document it here in case others experience a similar issue.

The problem indeed was synchronization issue - my use of `__syncthreads()` within a divergent control flow block. The solution was to break that control flow block into multiple parts and calling `__syncthreads()` after each part:

``````__global__ void levinson_durbin_gpu(TYPE *h0_d, TYPE *h_d, TYPE *v_d, TYPE *x_d, TYPE *y_d, int N) //Naive kernel
{
int i;

__shared__ TYPE hn_1[512];
hn_1[j] = h_d[j];

//Set up temporary arrays
__shared__ TYPE temp[512]; //Temp for hn_1_J_v
__shared__ TYPE temp2[512]; //Temp for hn_1_J_x
__shared__ TYPE temp3[512]; //Temp for hn_1_v

TYPE hn;
TYPE yn;

for(i=1; i<N; i++)
{
if(j < i)
{
hn = h_d[i];
yn = y_d[i];

//Compute inner products
temp[j] = hn_1[j]*v_d[i-j-1];
temp2[j] = hn_1[j]*x_d[i-j-1];
temp3[j] = hn_1[j]*v_d[j];
}

//Have all threads complete this section to avoid synchronization issues

//Three reductions at once
for(unsigned int s=1; s<i; s*=2)
{
int index = 2*s*j;
if((index+s) < i)
{
temp[index] += temp[index+s];
temp2[index] += temp2[index+s];
temp3[index] += temp3[index+s];
}
}

if(j < i)
{
TYPE hn_1_J_v = temp[0];
TYPE hn_1_J_x = temp2[0];
TYPE hn_1_v = temp3[0];

TYPE alpha_v = (hn - hn_1_J_v)/(h0_d[0] - hn_1_v);
TYPE alpha_x = (yn - hn_1_J_x)/(h0_d[0] - hn_1_v);

__shared__ TYPE w_v[512];
w_v[j] = v_d[j] - alpha_v*v_d[i-j-1];

__shared__ TYPE w_x[512];
w_x[j] = x_d[j] - alpha_x*v_d[i-j-1];

v_d[j] = w_v[j];
x_d[j] = w_x[j];
if(j == 0)
{
v_d[i] = alpha_v;
x_d[i] = alpha_x;
}
}

}

}
``````

N=32: RMS Error = 0.0000009233
N=64: RMS Error = 0.0000027644
N=128: RMS Error = 0.0000058276
N=256: RMS Error = 0.0000117755
N=512: RMS Error = 0.0000237040

what I learned: When you use synchronization mechanisms in CUDA, make sure all threads reach the same barrier point! I feel as though this sort of thing should produce a compiler warning.

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