Given an integer

`p`

and a destination base`b`

, return a string representation of`p`

in base`b`

. The string should have the least significant bit at the end

^ This is the problem I'm giving myself.

The naive recursive algorithm (in C++) I came up with is as follows:

```
string convertIntToBaseRecursive(int number, int base) {
// Base case
if (!number) return "";
// Adding least significant digit to "the rest" computed recursively
// Could reverse these operations if we wanted the string backwards.
return convertToBaseRecursive(number / base, base) + to_string(number % base);
}
```

While the algorithm is incredibly simple, I want to make sure I understand the complexity breakdown. My thoughts are below and I would like to know if they are correct, or wrong, and if they are wrong then knowing where I'm off track would be nice!

### Claim:

`n = logb(p)`

is the length of return string- Time complexity:
`O(n^2)`

- Space complexity:
`O(n)`

### Reasoning:

In order to keep the least significant bit at the end of a string when it is the value we calculate before anything else, we'd either have to:

- Compute the string recursively as we are
- Keep "shifting" the array every time we calculate a bit so we can add the most recent bit to the front of the string, not the end
- Write the string backwards, and reverse it before we return (most efficient)

We're doing the first method in the above C++ algorithm, and the `+`

operator creates a new string at each stack frame. The initial frame creates and returns a string of length `n`

, the next frame creates a string of length `n-1`

, `n-2`

, `n-3`

, and so on. Following this trend (without going into a proof of why `1 + 2 + 3 ... + n = O(n^2)`

, it is clear the time complexity is `O(n^2) = O(logb^2(p))`

. We'll also only need to be storing `O(n)`

things in memory at any time. When the original stack frame resolves (just before algorithm completes) we'll have the memory in terms of a raw string, but before it resolves it will be in terms of a single character (`O(1)`

) + recursive stack frames (`O(n)`

). We do this at each level storing `n`

amounts of single characters until we complete. Therefore the space complexity is `O(n)`

.

Of course the more efficient version of this solution would be

```
string convertIntToBaseIterative(int number, int base) {
string retString = "";
while (number) {
retString += to_string(number % base);
number /= base;
}
// Only needed if least significant
reverse(retString.begin(), retString.end());
return retString;
}
```

I believe this above solution , where `n = logb(p)`

has:

- Time complexity:
`O(n)`

- Space complexity:
`O(n)`

Are these analysis correct or am I off somewhere?