# Vectorization for `meshgrid`

and `ndgrid`

If you are still interested in finding a vectorized implementation to make the `meshgrid`

based code in the problem faster, let me suggest a vectorized method with `bsxfun`

and it's GPU ported version. I strongly believe that people must look into `vectorization with GPUs`

as a promising option to speed up `MATLAB`

codes. Codes that employ `meshgrid`

or `ndgrid`

and whose outputs are to be operated with some elementwise operation setup a perfect ground to employ `bsxfun`

into those codes. To add to that, the use of GPU with `bsxfun`

, that lets it work on the elements independently with hundreds and thousands of CUDA cores available, makes it just perfect for GPU implementation.

For your specific problem, the inputs were -

```
x = -2:0.01:2;
y = -2:0.01:2;
```

Next, you had -

```
[xx,yy] = meshgrid(x,y);
z = sin(xx.^2-yy.^2);
```

With `bsxfun`

, this becomes a one-liner -

```
z = sin(bsxfun(@minus,x.^2,y.^2.'));
```

# Benchmarking

GPU benchmarking tips were taken from Measure and Improve GPU Performance.

```
%// Warm up GPU call with insignificant small scalar inputs
temp1 = sin_sqdiff_vect2(0,0);
N_arr = [50 100 200 500 1000 2000 3000]; %// array elements for N (datasize)
timeall = zeros(3,numel(N_arr));
for k = 1:numel(N_arr)
N = N_arr(k);
x = linspace(-20,20,N);
y = linspace(-20,20,N);
f = @() sin_sqdiff_org(x,y);%// Original CPU code
timeall(1,k) = timeit(f);
clear f
f = @() sin_sqdiff_vect1(x,y);%// Vectorized CPU code
timeall(2,k) = timeit(f);
clear f
f = @() sin_sqdiff_vect2(x,y);%// Vectorized GPU(GTX 750Ti) code
timeall(3,k) = gputimeit(f);
clear f
end
%// Display benchmark results
figure,hold on, grid on
plot(N_arr,timeall(1,:),'-b.')
plot(N_arr,timeall(2,:),'-ro')
plot(N_arr,timeall(3,:),'-kx')
legend('Original CPU','Vectorized CPU','Vectorized GPU (GTX 750 Ti)')
xlabel('Datasize (N) ->'),ylabel('Time(sec) ->')
```

**Associated functions**

```
%// Original code
function z = sin_sqdiff_org(x,y)
[xx,yy] = meshgrid(x,y);
z = sin(xx.^2-yy.^2);
return;
%// Vectorized CPU code
function z = sin_sqdiff_vect1(x,y)
z = sin(bsxfun(@minus,x.^2,y.^2.')); %//'
return;
%// Vectorized GPU code
function z = sin_sqdiff_vect2(x,y)
gx = gpuArray(x);
gy = gpuArray(y);
gz = sin(bsxfun(@minus,gx.^2,gy.^2.')); %//'
z = gather(gz);
return;
```

# Results

# Conclusions

As the results show, vectorized method with GPU shows good performance improvement which is about `4.3x`

against the vectorized CPU code and `6x`

against the original code. Please keep in mind that GPU has to overcome a minimum overhead that is required with it's setting up, so at least a decent sized input is needed to see the improvement. Hopefully, people would explore more of `vectorization with GPUs`

, as it could not be stressed enough!

`bsxfun`

implementation, that also talks about using GPU here