It's not just about the leading bit. It's about *all* the bits.

# Starting with addition

First let's look at how addition is done in 4-bit binary for 2 + 7:

```
10 +
111
____
1001
```

It's the same as long addition in decimal: bit by bit, right to left.

- In the rightmost place we add 0 and 1, it makes 1, no carry.
- In the second place from the right, we add 1 and 1, that makes 2 in decimal or 10 in binary - we write the 0, carry the 1.
- In the third place from the right, we add the 1 we carried to the 1 already there, it makes binary 10. We write the 0, carry the 1.
- The 1 that just got carried gets written in the fourth place from the right.

# Long subtraction

Now we know that binary 10 + 111 = 1001, we should be able to work backwards and prove that 1001 - 10 = 111. Again, this is exactly the same as in decimal long subtraction.

```
1001 -
10
____
111
```

Here's what we did, working right to left again:

- In the rightmost place, 1 - 0 = 1, we write that down.
- In the second place, we have 0 - 1, so we need to borrow an extra bit. We now do binary 10 - 1, which leaves 1. We write this down.
- In the third place, remember we borrowed an extra bit - so again we have 0 - 1. We use the same trick to borrow an extra bit, giving us 10 - 1 = 1, which we put in the third place of the result.
- In the fourth place, we again have a borrowed bit to deal with. Subtract the borrowed bit from the 1 already there: 1 - 1 = 0. We could write this down in front of the result, but since it's the end of the subtraction there's no need.

# There's a number less than zero?!

Do you remember how you learnt about negative numbers? Part of the idea is that you can subtract any number from any other number and still get a number. So 7 - 5 is 2; 6 - 5 is 1; 5 - 5 is 0; What is 4 - 5? Well, one way to reason about such numbers is simply to apply the same method as above to do the subtraction.

As an example, let's try 2 - 7 in binary:

```
10 -
111
_______
...1011
```

I started in the same way as before:

- In the rightmost place, subtract 1 from 0, which requires a borrowed bit. 10 - 1 = 1, so the last bit of the result is 1.
- In the second-rightmost place, we have 1 - 1 with an extra borrow bit, so we have to subtract another 1. This means we need to borrow our own bit, giving 11 - 1 - 1 = 1. We write 1 in the second-rightmost spot.
- In the third place, there are no more bits in the top number! But we know we can pretend there's a 0 in front, just like we would do if the bottom number ran out of bits. So we have 0 - 1 - 1 because of the borrow bit from second place. We have to borrow a bit again! Anyway we have 10 - 1 - 1 = 0, which we write down in the third place from the right.
Now something very interesting has happened - both the operands of the subtraction have no more digits, but we still have a borrow bit to take care of! Oh well, let's just carry on as we have been doing. We have 0 - 0, since neither the top or bottom operand have any bits here, but because of the borrow bit it's actually 0 - 1.

(We have to borrow again! If we keep borrowing like this we'll have to declare bankruptcy soon.)

Anyway, we borrow the bit, and we get 10 - 1 = 1, which we write in the fourth place from the right.

Now anyone with half a mind is about to see that we are going to keep borrowing bits until the cows come home, because there ain't no more bits to go around! We ran out of them two places ago if you forgot. But if you tried to keep going it'd look like this:

```
...00000010
...00000111
___________
...11111011
```

- In the fifth place we get 0 - 0 - 1, and we borrow a bit to get 10 - 0 - 1 = 1.
- In the sixth place we get 0 - 0 - 1, and we borrow a bit to get 10 - 0 - 1 = 1.
- In the seventh place we get 0 - 0 - 1, and we borrow a bit to get 10 - 0 - 1 = 1.

...And so it goes on for as many places as you like. *By the way, we just derived the two's complement binary form of -5*.

You could try this for any pair of numbers you like, and generate the two's complement form of any negative number. If you try to do 0 - 1, you'll see why -1 is represented as `...11111111`

. You'll also realise why all two's complement negative numbers have a 1 as their most significant bit (the "leading bit" in the original question).

In practice, your computer doesn't have infinitely many bits to store negative numbers in, so it usually stops after some more reasonable number, like 32. What do we do with the extra borrow bit in position 33? Eh, we just quietly ignore it and hope no one notices. When some does notice that our new number system doesn't work, we call it **integer overflow**.

# Final notes

This isn't the only way to make our number system work, of course. After all, if I owe you $5, I wouldn't say that your current balance with me was $...999999995.

But there are some cool things about the system we just derived, like the fact that subtraction gives you the right result in this system, even if you ignore the fact that one of the numbers is negative. Normally, we have to think about subtractions with conditional steps: to calculate 2 - 7, we first have to figure out that 2 is less than 7, so instead we calculate 7 - 2 = 5, and then stick a minus sign in front to get 2 - 7 = -5. But with two's complement we just go ahead do the subtraction and don't care about which number is bigger, and the right result comes out by itself. And others have mentioned that addition works nicely, and so does multiplication.

nbits, but you want to store negative and non-negative numbers. How wouldyoudo it? It'd make sense to divide your integer range in half and map half to negatives, half to non-negatives. Representing non-negative numbers is straightforward, and there's no reason why that shouldn't just be a direct mapping. That's one half of your range. The other half happens to have 1 as the most significant bit.1more comment