If this is the serial code:
int i, j;
for(j=0; j<ny; j++)
for(i=0; i<nx; i++)
x[i + j*nx] *= y[i];
then you should be doing this:
__global__ void fn(float *x, int nx)
int tid = blockIdx.x * blockDim.x + threadIdx.x;
int j = tid/nx, i = tid - j * nx;
x[tid] *= y[i];
fn<<<nx*ny/B, B>>>(x, nx); // with B = 256, 512, etc.
What you're doing is fairly bizarre: you're instructing each thread of the CUDA kernel to iterate over all values of tid between 0 and nx*ny, and compute the same function as your CPU version! Moreover, instead of just iterating over the indices, you're actually doing the loop less efficiently than you did for the CPU version; in other words, you do the same thing in each thread, just less efficiently, than you are doing in 1 thread on the CPU. It's no wonder that this is slower; it should be much, much slower. Your CUDA kernel is:
int **tid** = blockIdx.x * blockDim.x + threadIdx.x;
for(**tid** = 0; **tid** <nx*ny; **tid**++)
j = tid/nx;
i = tid - j*nx;
x[tid] *= y[i];
This does nx*ny iterations, same as your host code, for each thread; you lose all benefit of the parallelism, since each thread is doing the same thing; you would get the same performance using one thread on the GPU, and the same result!
If this is the verbatim code from your CUDA source file, you need to change it and redo the comparison; if this is code you have written to help explain what your code is doing for a lay non-CUDA audience, then you need to present your actual CUDA code so that we can see what's going on... as it is, the performance analysis I have done - the trivial one - is all you can expect.