I made some attempts to implement an efficient of rc4 cipher algorithm in cuda. I used shared memory to store the internal permutation state, taking care of the banked memory layout to time penalty with parallel thread accesses in the warp. I also tried to minimize the number of accesses exploiting the fact that read/write accesses with the 'i' index are contiguous and can be packed in 32-bits words. Last, I made use of constant memory to initialize the permutation state.

Despite these 'clever' tricks, i can expect to achieve only roughly 50% of throughput of the best reported implementations (see guapdf cracker for example), even taking into consideration that unblocked communication between host and gpu could be used to partially cover the computation. I can't figure why and I am looking for new improvement ideas or comments on bad assumptions i could have made.

Here is a toy implementation of my KSA (key setting) kernel with a key reduced to 4 bytes.

```
__constant__ unsigned int c_init[256*32/4];
__global__ void rc4Block(unsigned int *d_out, unsigned int *d_in)
{
__shared__ unsigned int s_data[256*32/4];
int inOffset = blockDim.x * blockIdx.x;
int in = inOffset + threadIdx.x;
unsigned int key, u;
// initialization
key = d_in[in];
for(int i=0; i<(256/4); i++) { // read from constant memory
s_data[i*32+threadIdx.x] = c_init[i*32+threadIdx.x];
}
// key mixing
unsigned char j = 0;
unsigned char k0 = key & 0xFF;
unsigned char k1 = (key >> 8) & 0xFF;
unsigned char k2 = (key >> 8) & 0xFF;
unsigned char k3 = (key >> 8) & 0xFF;
for(int i=0; i<256; i+=4) { // unrolled
unsigned int u, sj, v;
unsigned int si = s_data[(i/4)*32+threadIdx.x];
unsigned int shiftj;
u = si & 0xff;
j = (j + k0 + u) & 0xFF;
sj = s_data[(j/4)*32+threadIdx.x];
shiftj = 8*(j%4);
v = (sj >> shiftj) & 0xff;
si = (si & 0xffffff00) | v;
sj = (sj & ~(0xFFu << (8*(j%4)))) | (u << shiftj);
s_data[(j/4)*32+threadIdx.x] = sj;
u = (si >> 8) & 0xff;
j = (j + k1 + u) & 0xFF;
sj = s_data[(j/4)*32+threadIdx.x];
shiftj = 8*(j%4);
v = (sj >> shiftj) & 0xff;
si = (si & 0xffff00ff) | (v<<8);
sj = (sj & ~(0xFFu << (8*(j%4)))) | (u << shiftj);
s_data[(j/4)*32+threadIdx.x] = sj;
u = (si >> 16) & 0xff;
j = (j + k2 +u) & 0xFF;
sj = s_data[(j/4)*32+threadIdx.x];
shiftj = 8*(j%4);
v = (sj >> shiftj) & 0xff;
si = (si & 0xff00ffff) | (v<<16);
sj = (sj & ~(0xFFu << (8*(j%4)))) | (u << shiftj);
s_data[(j/4)*32+threadIdx.x] = sj;
u = (si >> 24) & 0xff;
j = (j + k3 + u) & 0xFF;
sj = s_data[(j/4)*32+threadIdx.x];
shiftj = 8*(j%4);
v = (sj >> shiftj) & 0xff;
si = (si & 0xffffff) | (v<<24);
sj = (sj & ~(0xFFu << (8*(j%4)))) | (u << shiftj);
s_data[(j/4)*32+threadIdx.x] = sj;
s_data[(i/4)*32+threadIdx.x] = si;
}
d_out[in] = s_data[threadIdx.x]; // unrelevant debug output
}
```