**EXPLANATION OF THE bitwiseAdd METHOD:**

I know this question was asked a while back but since no complete answer has been given regarding how the bitwiseAdd method works here is one.

The key to understanding the logic encapsulated in bitwiseAdd is found in the relationship between **addition** operations and **xor** and **and** bitwise operations. That relationship is defined by the following equation (see appendix 1 for a numeric example of this equation):

```
x + y = 2 * (x&y)+(x^y) (1.1)
```

Or more simply:

```
x + y = 2 * and + xor (1.2)
with
and = x & y
xor = x ^ y
```

You might have noticed something familiar in this equation: the **and** and **xor** variables are the same as those defined at the beginning of bitwiseAdd. There is also a multiplication by two, which in bitwiseAdd is done at the beginning of the while loop. But I will come back to that later.

**Let me also make a quick side note about the '&' bitwise operator before we proceed further.** This operator basically "captures" the intersection of the bit sequences against which it is applied. For example, 9 & 13 = 1001 & 1101 = 1001 (=9). You can see from this result that only those bits common to both bit sequences are copied to the result. It derives from this that when two bit sequences have no common bit, the result of applying '&' on them yields **0**. *This has an important consequence on the addition-bitwise relationship which shall become clear soon*

Now the problem we have is that equation 1.2 uses the '+' operator whereas bitwiseAdd doesn't (it only uses '^', '&' and '<<'). So how do we make the '+' in equation 1.2 somehow disappear? Answer: by 'forcing' the **and** expression to return 0. And the way we do that is by using **recursion**.

To demonstrate this I am going to recurse equation 1.2 one time (this step might be a bit challenging at first but if needed there's a detailed step by step result in appendix 2):

```
x + y = 2*(2*and & xor) + (2*and ^ xor) (1.3)
```

Or more simply:

```
x + y = 2 * and[1] + xor[1] (1.4)
with
and[1] = 2*and & xor,
xor[1] = 2*and ^ xor,
[1] meaning 'recursed one time'
```

There's a couple of interesting things to note here. First you noticed how the concept of recursion sounds close to that of a loop, like the one found in bitwiseAdd in fact. This connection becomes even more obvious when you consider what **and[1]** and **xor[1]** are: they are the same expressions as the **and** and **xor** expressions defined **INSIDE** the while loop in bitwiseAdd. We also note that a pattern emerges: equation 1.4 looks exactly like equation 1.2!

As a result of this, doing further recursions is a breeze, if one keeps the recursive notation. Here we recurse equation 1.2 two more times:

```
x + y = 2 * and[2] + xor[2]
x + y = 2 * and[3] + xor[3]
```

This should now highlight the role of the 'temp' variable found in bitwiseAdd: **temp** allows to pass from one recursion level to the next.

We also notice the multiplication by two in all those equations. As mentioned earlier this multiplication is done at the begin of the while loop in bitwiseAdd using the **and <<= 1** statement. This multiplication has a consequence on the next recursion stage since the bits in and[i] are different from those in the and[i] of the previous stage (and if you recall the little side note I made earlier about the '&' operator you probably see where this is going now).

The general form of equation 1.4 now becomes:

```
x + y = 2 * and[x] + xor[x] (1.5)
with x the nth recursion
```

**FINALY:**

So when does this recursion business end exactly?

**Answer:** it ends when the intersection between the two bit sequences in the **and[x]** expression of equation 1.5 returns **0**. The equivalent of this in bitwiseAdd happens when the while loop condition becomes false. At this point equation 1.5 becomes:

```
x + y = xor[x] (1.6)
```

And that explains why in bitwiseAdd we only return **xor** at the end!

And we are done! A pretty clever piece of code this bitwiseAdd I must say :)

I hope this helped

**APPENDIX:**

**1) A numeric example of equation 1.1**

equation 1.1 says:

```
x + y = 2(x&y)+(x^y) (1.1)
```

To verify this statement one can take a simple example, say adding 9 and 13 together. The steps are shown below (the bitwise representations are in parenthesis):

We have

```
x = 9 (1001)
y = 13 (1101)
```

And

```
x + y = 9 + 13 = 22
x & y = 9 & 13 = 9 (1001 & 1101 = 1001)
x ^ y = 9^13 = 4 (1001 ^ 1101 = 0100)
```

pluging that back into equation 1.1 we find:

```
9 + 13 = 2 * 9 + 4 = 22 et voila!
```

**2) Demonstrating the first recursion step**

The first recursion equation in the presentation (equation 1.3) says that

if

```
x + y = 2 * and + xor (equation 1.2)
```

then

```
x + y = 2*(2*and & xor) + (2*and ^ xor) (equation 1.3)
```

To get to this result, we simply took the **2* and + xor** part of equation 1.2 above and applied the **addition/bitwise operands relationship** given by equation 1.1 to it. This is demonstrated as follow:

if

```
x + y = 2(x&y) + (x^y) (equation 1.1)
```

then

```
[2(x&y)] + (x^y) = 2 ([2(x&y)] & (x^y)) + ([2(x&y)] ^ (x^y))
(left side of equation 1.1) (after applying the addition/bitwise operands relationship)
```

Simplifying this with the definitions of the **and** and **xor** variables of equation 1.2 gives equation 1.3's result:

```
[2(x&y)] + (x^y) = 2*(2*and & xor) + (2*and ^ xor)
with
and = x&y
xor = x^y
```

And using that same simplification gives equation 1.4's result:

```
2*(2*and & xor) + (2*and ^ xor) = 2*and[1] + xor[1]
with
and[1] = 2*and & xor
xor[1] = 2*and ^ xor
[1] meaning 'recursed one time'
```