To find the base-2 representation of a number, we seek bits `b0...bn`

such that

```
n = bn * 2^n + b_(n - 1) * 2^(n - 1) + ... + b1 * 2^1 + b0 * 2^0
```

Now we focus on finding `b0, b1, ..., bn`

. Note that

```
(bn * 2^n + b_(n - 1) * 2^(n - 1) + ... + b1 * 2^1 + b0 * 2^0) % 2 = b0
```

because `b0 * 2^0 % 2 = b0`

and `bj * 2^j % 2 = 0`

when `j >= 1`

since `2^j % 2 = 0`

if `j >= 1`

. So,

```
n = bn * 2^n + b_(n - 1) * 2^(n - 1) + ... + b1 * 2^1 + b0 * 2^0
=> n % 2 = (bn * 2^n + b_(n - 1) * 2^(n - 1) + ... + b1 * 2^1 + b0 * 2^0) % 2 = b0
```

we've found that `b0 = n % 2`

. **This key fact number one**.

Now, let's divide by 2:

```
n / 2 = (bn * 2^n + b_(n - 1) * 2^(n - 1) + ... + b1 * 2^1 + b0 * 2^0)
= bn * 2^(n - 1) + b_(n - 1) * 2^(n - 2) + ... + b1 * 2^1
```

Now, let's stop right here. Let's take a close look at the binary representation for `n / 2`

. Note that it is exactly equal to the binary representation of `n`

just with the last bit chopped off. That is

```
n = bn b_(n-1) ... b1 b0
n / 2 = b_n b_(n-1) ... b1
```

**This is key fact number two**.

So, let's put together what we've learned.

The binary representation of `n`

is the binary representation of `n / 2`

with the last digit of the binary representation of `n`

appended. **This is from key fact number two**.

The last digit of the binary representation of `n`

can be computed by calculating `n % 2`

. **This is from key fact number one**.

All of this true except for one case: when `n = 0`

. In that case, the binary representation of `n`

is `0`

. If we tried to use the rule of dividing by `2`

, we'd never stop dividing by 2. So, we need a rule that catches when `n = 0`

.

So, to compute the binary representation of `n`

, first compute the binary representation of `n / 2`

, then append the result of `n % 2`

but be sure to handle the case when `n = 0`

. Let's write that in code:

```
// print binary representation of n
void ToBin(int n) {
if(n > 1) { // this is to handle zero!
ToBin(n / 2); // this will print the binary representation of n
}
print(n % 2); // this will print the the last digit
}
```