I have been working on a C# implementation of 2048 for the purpose of implementing reinforcement learning.

The "slide" operation for each move requires that tiles be moved and combined according to specific rules. Doing so involves a number of transformations on a 2d array of values.

Until recently I was using a 4x4 byte matrix:

```
var field = new byte[4,4];
```

Each value was an exponent of 2, so `0=0`

, `1=2`

, `2=4`

, `3=8`

, and so forth. The 2048 tile would be represented by 11.

Because the (practical) maximum value for a given tile is 15 (which only requires 4 bits), it is possible to shove the contents of this 4x4 byte array into a `ulong`

value.

It turns out that certain operations are vastly more efficient with this representation. For example, I commonly have to invert arrays like this:

```
//flip horizontally
const byte SZ = 4;
public static byte[,] Invert(this byte[,] squares)
{
var tmp = new byte[SZ, SZ];
for (byte x = 0; x < SZ; x++)
for (byte y = 0; y < SZ; y++)
tmp[x, y] = squares[x, SZ - y - 1];
return tmp;
}
```

I can do this inversion to a `ulong`

~15x faster:

```
public static ulong Invert(this ulong state)
{
ulong c1 = state & 0xF000F000F000F000L;
ulong c2 = state & 0x0F000F000F000F00L;
ulong c3 = state & 0x00F000F000F000F0L;
ulong c4 = state & 0x000F000F000F000FL;
return (c1 >> 12) | (c2 >> 4) | (c3 << 4) | (c4 << 12);
}
```

Note the use of hex, which is extremely useful because each character represents a tile.

The operation I've having the most trouble with is `Transpose`

, which flipped the `x`

and `y`

coordinates of values in the 2d array, like this:

```
public static byte[,] Transpose(this byte[,] squares)
{
var tmp = new byte[SZ, SZ];
for (byte x = 0; x < SZ; x++)
for (byte y = 0; y < SZ; y++)
tmp[y, x] = squares[x, y];
return tmp;
}
```

The fastest way I've found to do this is using this bit of ridiculousness:

```
public static ulong Transpose(this ulong state)
{
ulong result = state & 0xF0000F0000F0000FL; //unchanged diagonals
result |= (state & 0x0F00000000000000L) >> 12;
result |= (state & 0x00F0000000000000L) >> 24;
result |= (state & 0x000F000000000000L) >> 36;
result |= (state & 0x0000F00000000000L) << 12;
result |= (state & 0x000000F000000000L) >> 12;
result |= (state & 0x0000000F00000000L) >> 24;
result |= (state & 0x00000000F0000000L) << 24;
result |= (state & 0x000000000F000000L) << 12;
result |= (state & 0x00000000000F0000L) >> 12;
result |= (state & 0x000000000000F000L) << 36;
result |= (state & 0x0000000000000F00L) << 24;
result |= (state & 0x00000000000000F0L) << 12;
return result;
}
```

Shockingly, this is still nearly 3x faster than the loop version. However, I'm looking for a more performant method either using leveraging a pattern inherent in transposition or more efficient management of the bits I'm moving around.

shockingly" in an ironic manner. Anyway, the purpose of my comment is not to doubt my irony detector. ;-P I don't know how clever the JIT optimizer is, but perhaps you could make your unrolled Transpose fractionally faster by avoiding setting result repeatedly but rather do something`ulong result = (state & mask1) | ((state & mask 2) >> 12) | ((state & mask3) >> 24) | ...`

. By the way, .NETCore 3.0 (release planned in 2019) will likely feature support for SSE/AVX hardware intrinsics, which would probably be of benefit to accelerate things further.isfaster) to release (where it is not).`ulong`

result with the`ulong`

state (both local variables) can be all done within/accross registers, minimizing cache accesses. Unless the JIT is really genious, i don't think the byte array would be hold entirely in a register, thus leading to more cache accesses and more cycles spent...