Bit interleaving essentially takes two `n`

bit input numbers and produces one `2n`

bit output number that alternately takes bits from the two input numbers. That is, bits from one number goes into the odd indices, and bits from the other goes into the even indices.

So for your specific example:

```
x = 100101 = 1 0 0 1 0 1
y = 010101 = 0 1 0 1 0 1
interleaved = 011000110011
```

Here we use the convention that bits from `x`

goes into the even indices (0, 2, 4...) and bits from `y`

goes into the odd indices (1, 3, 5...). That is, bit interleaving is not a commutative operation; `interleave(x, y)`

is generally not equal to `interleave(y, x)`

.

You can also generalize the bit interleaving operation to involve more than just 2 numbers.

Bit-interleaved numbers exhibit structural properties that can be taken advantage of in many important spatial algorithms/data structures.

### See also

### Related questions

### "Obvious" algorithm

The algorithm essentially goes through every bits of the input numbers, checking if it's 1 or 0 with bitwise-and, combining the two bits with bitwise-or, and concatenating them together with proper shifts.

To understand how the bits are rearranged, just work on a simple 4-bit example. Here `xi`

denotes the `i`

-th (0-based) bit of `x`

.

```
x = x3 x2 x1 x0
y = y3 y2 y1 y0
Mapping:
z = y3 x3 y2 x2 y1 x1 y0 x0 x[i] --> z[i+i]
z7 z6 z5 z4 z3 z2 z1 z0 y[i] --> y[i+i+1]
```

Once you convinced yourself that the mapping pattern is correct, implementing it is simply a matter of understanding how bitwise operations are performed.

Here's the algorithm rewritten in Java for clarity (see also on ideone.com):

```
int x = Integer.parseInt("100101", 2);
int y = Integer.parseInt("010101", 2);
int z = 0;
for (int i = 0; i < Integer.SIZE; i++) {
int x_masked_i = (x & (1 << i));
int y_masked_i = (y & (1 << i));
z |= (x_masked_i << i);
z |= (y_masked_i << (i + 1));
}
System.out.println(Integer.toBinaryString(z));
// prints "11000110011"
```

### See also