# 1D Min-convolution in CUDA

I have two arrays, a and b, and I would like to compute the "min convolution" to produce result c. Simple pseudo code looks like the following:

``````for i = 0 to size(a)+size(b)
c[i] = inf
for j = 0 to size(a)
if (i - j >= 0) and (i - j < size(b))
c[i] = min(c[i], a[j] + b[i-j])
``````

(edit: changed loops to start at 0 instead of 1)

If the min were instead a sum, we could use a Fast Fourier Transform (FFT), but in the min case, there is no such analog. Instead, I'd like to make this simple algorithm as fast as possible by using a GPU (CUDA). I'd be happy to find existing code that does this (or code that implements the sum case without FFTs, so that I could adapt it for my purposes), but my search so far hasn't turned up any good results. My use case will involve a's and b's that are of size between 1,000 and 100,000.

Questions:

• Does code to do this efficiently already exist?

• If I am going to implement this myself, structurally, how should the CUDA kernel look so as to maximize efficiency? I've tried a simple solution where each c[i] is computed by a separate thread, but this doesn't seem like the best way. Any tips in terms of how to set up thread block structure and memory access patterns?

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as far as I remember, this is called 'tropical semiring' when + and * are replaced by min and + resp. Note that FFT is not the only orthogonal transform that can be used for convolutions. It might be that there is another one for your case. I'll thing about that –  user1545642 Oct 31 '12 at 17:10
This paper describes how to do 1D min-convolution in subquadratic time. The operating principle seems to be to reconstruct the problem as a normal convolution and perform an FFT. Not sure how it would best work with CUDA. cs.brown.edu/~pff/papers/bf.pdf –  jbarlow Nov 4 '12 at 6:56
I hope you don't mind, I simplified your pseudocode to remove the `continue` -- it was unnecessarily confusing, in my mind. Feel free to undo my edit if for some reason it is necessary... –  harrism Nov 5 '12 at 3:40
BTW, how one would implement this efficiently in parallel depends on the relative values of size(a) and size(b). if size of a is much greater than size of b, then parallelizing just the inner loop is probably sufficient for a good parallel speedup, and it is as simple as repeated min-reduction. –  harrism Nov 5 '12 at 3:42
@jbarlow thanks for the link, but I've seen that paper, and I'm pretty sure it only deals with the case where one of the arrays takes on value either 0 or infinity, so it isn't applicable to my case. –  dan_x Nov 6 '12 at 3:58

An alternative which might be useful for large `a` and `b` would be to use a block per output entry in `c`. Using a block allows for memory coalescing, which will be important in what is a memory bandwidth limited operation, and a fairly efficient shared memory reduction can be used to combine per thread partial results into a final per block result. Probably the best strategy is to launch as many blocks per MP as will run concurrently and have each block emit multiple output points. This eliminates some of the scheduling overheads associated with launching and retiring many blocks with relatively low total instruction counts.

An example of how this might be done:

``````#include <math.h>

template<int bsz>
__global__ __launch_bounds__(512)
void minconv(const float *a, int sizea, const float *b, int sizeb, float *c)
{
__shared__ volatile float buff[bsz];
for(int i = blockIdx.x; i<(sizea + sizeb); i+=(gridDim.x*blockDim.x)) {
float cval = INFINITY;
for(int j=threadIdx.x; j<sizea; j+= blockDim.x) {
int t = i - j;
if ((t>=0) && (t<sizeb))
cval = min(cval, a[j] + b[t]);
}
if (bsz > 256) {
}
if (bsz > 128) {
}
if (bsz > 64) {
}
if (threadIdx.x == 0) c[i] = buff[0];
}
}
}

// Instances for all valid block sizes.
template __global__ void minconv<64>(const float *, int, const float *, int, float *);
template __global__ void minconv<128>(const float *, int, const float *, int, float *);
template __global__ void minconv<256>(const float *, int, const float *, int, float *);
template __global__ void minconv<512>(const float *, int, const float *, int, float *);
``````

[disclaimer: not tested or benchmarked, use at own risk]

This is single precision floating point, but the same idea should work for double precision floating point. For integer, you would need to replace the C99 `INFINITY` macro with something like `INT_MAX` or `LONG_MAX`, but the principle remains the same otherwise.

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Thanks! This is about 4x faster than my naive baseline on 1000x through of problems of size (1000,1000). Baseline: 852.6 ms; This: 225.3 ms –  dan_x Nov 7 '12 at 0:38
It would be faster if you do register float cval?, All that if's are the reduction right? Cuda do not have any native reduction function like MPI reduction for example?. Another thing all that conditional and __syncthreads(); does not have a high overhead?. Sorry all the question xD. –  dreamcrash Nov 7 '12 at 3:12
@dan_x sorry for all the questions, what sort of GPU are you running on ? –  Robert Crovella Nov 7 '12 at 3:14
@RobertCrovella happy to answer. I have access to a few, but right now I'm primarily running on a Tesla C1060. –  dan_x Nov 7 '12 at 3:47
@dreamcrash: no the problem is when not every thread in a warp doesn't evaluate a conditional expression or branch uniformly. Then divergence occurs. An if-then-else construct can be perfectly ok as long as all threads in a warp follow the same branch of the code. –  talonmies Nov 7 '12 at 17:36

An faster version:

``````__global__ void convAgB(double *a, double *b, double *c, int sa, int sb)
{
int i = (threadIdx.x + blockIdx.x * blockDim.x);
int out,j;

__shared__ double c_local [512];

c_local[idT] = c[i];

out = (i > sa) ? sa : i + 1;
j   = (i > sb) ? i - sb + 1 : 1;

for(; j < out; j++)
{
if(c_local[idT] > a[j] + b[i-j])
c_local[idT] = a[j] + b[i-j];
}

c[i] = c_local[idT];
}

**Benckmark:**
Size A Size B Size C Time (s)
1000   1000   2000   0.0008
10k    10k    20k    0.0051
100k   100k   200k   0.3436
1M     1M     1M     43,327
``````

Old Version, For sizes between 1000 and 100000 i tested this naive version.

``````__global__ void convAgB(double *a, double *b, double *c, int sa, int sb)
{
int size = sa+sb;

int idT = (threadIdx.x + blockIdx.x * blockDim.x);
int out,j;

for(int i = idT; i < size; i += blockDim.x * gridDim.x)
{
if(i > sa) out = sa;
else out = i + 1;

if(i > sb) j = i - sb + 1;
else j = 1;

for(; j < out; j++)
{
if(c[i] > a[j] + b[i-j])
c[i] = a[j] + b[i-j];
}
}
}
``````

I populate array a and b with some random double numbers and c with 999999 (just for testing). And i validate c using your function (without any modifications) in cpu .

I also took it out the conditionals from the inside of the inner loop, so it will only test them once.

I am not 100% sure but i think it makes since, you had i - j >= 0, which is the same as i >= j, this means that as soon as j > i it will never enter this block 'X' (since j++):

``````if(c[i] > a[j] + b[i-j])
c[i] = a[j] + b[i-j];
``````

So i calculate on variable out, the loop conditional if i > sa this means that the loop with finish when j == sa, if i < sa this means the loop will finish
(earlier) on i + 1 because of the condition i>=j.

The other condition i - j < size(b) means that you will start the execution of the block 'X' when i > size(b) + 1 since j starts always = 1. So we can put j with the value that should begin, thus

``````if(i > sb) j = i - sb + 1;
else j = 1;
``````

See if you can test with real arrays of data, and give me feedback. Also any improvement are welcome

EDIT : A new optimization can be implemented, but this one does make much of difference, it would in the case of an if and else, nevertheless i will post anyway:

``````if(c[i] > a[j] + b[i-j])
c[i] = a[j] + b[i-j];
``````

we can eliminate the if, by:

``````double add;
...

for(; j < out; j++)
{
}
``````

Having:

``````if(a > b) c = b;
else c = a;
``````

it the same of having c = (a < b) * a + (b <= a) * b.

if a > b then c = 0 * a + 1 * b; => c = b; if a <= b then c = 1*a + 0 *b; => c = a;

``````**Benckmark:**
Size A Size B Size C Time (s)
1000   1000   2000   0.0013
10k    10k    20k    0.0051
100k   100k   200k   0.4436
1M     1M     1M     47,327
``````

I am measuring the time of copy from CPU to GPU, running the kernel and copy from GPU to CPU. With doubles.

``````GPU Specifications
Device                       Tesla C2050
CUDA Capability Major/Minor  2.0
Global Memory                2687 MB
Cores                        448 CUDA Cores
Warp size                    32
``````
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Thanks! At a glance this looks smarter than my naive attempt. I'll understand exactly what you are doing and will run it on some real examples tomorrow. –  dan_x Nov 6 '12 at 4:08
Ok, if you need, i can also give you the function that calls the kernel with the blocks/threads already specified. –  dreamcrash Nov 6 '12 at 14:16
Hi, I tested this out a bit. I made some slight modifications to your code, like changing doubles to floats, but mostly left it unchanged. For a baseline where I run 1000x on problems of size (1000,1000), I get these results: Baseline: Time for kernel: 12870.9 ms dreamcrash 1: Time for kernel: 12248.9 ms dreamcrash 2: Time for kernel: 19395.1 ms dreamcrash (tmp var for min): Time for kernel: 12290.0 ms ... (to be continued) –  dan_x Nov 6 '12 at 16:09
So it looks like your edit actually hurts performance because of additional accesses to c. When I replace c[i] with a temporary variable, (the (tmp var for min) case), it goes back down to being about as good as the original. Unfortunately, all of these are only slightly faster than my naive baseline that just launches a thread for each result i. For larger problems, I get the same qualitative result versus the baseline. –  dan_x Nov 6 '12 at 16:10
Yep, that optimization it good but in another types of problems. How much time it takes to Array A= 1M, Array B = 1M ? how much threads/blocks are you using for this case? –  dreamcrash Nov 6 '12 at 16:24

``````const int Length=1000;

__global__ void OneD(float *Ad,float *Bd,float *Cd){
int i=blockIdx.x;
Cd[i]=99999.99;
for(int k=0;k<Length/500;k++){
}}}
``````

I have taken 500 Threads per block. And, 500 blocks per Grid. As, the number of threads per block in my device is restricted to 512, i used 500 threads. I have taken the size of all the arrays as `Length` (=1000).

Working: 1. `i` stores the Block Index and `j` stores the Thread Index.

1. The `for` loop is used as the number of threads are less than the size of the arrays.
2. The while loop is used for iterating `Cd[n]`.
3. I have not used Shared Memory because, I have taken lots of blocks and threads. So, the amount of Shared Memory required for each block is low.

PS: If your device supports more Threads and Blocks, replace `k<Length/500` with `k<Length/(supported number of threads)`

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