This is actually an interesting problem. Obviously what you want to do to make this more than just a brute force is to use the most significant digits and put them in the least significant digit locations to form a palindrome. (I'm going to refer to the difference between the palindrome and the original as the "distance")

From that I'm going to say that we can ignore the least significant half of the numbers because it really doesn't matter (it matters when determining the distance, but that's all).

I'm going to take an abstract number: `ABCDEF`

. Where A,B,C,D,E,F are all random digits. Again as I said D,E,F are not needed for determining the palindrome as what we want is to mirror the first half of the digits onto the second half. Obviously we don't want to do it the other way around or we'd be modifying more significant digits resulting in a greater distance from the original.

So a palindrome would be `ABCCBA`

, however as you've already stated this doesn't always you the shortest distance. However the "solution" is still of the form `XYZZYX`

so if we think about minimizing the "significance" of the digits we're modifying that would mean we'd want to modify C (or the middle most digit).

Lets take a step back and look at why: `ABCCBA`

- At first it might be tempting to modify
`A`

because it's in the least significant position: the far right. However in order to modify the least significant we need to modify the most significant. So `A`

is out.
- The same can be said for
`B`

, so `C`

ends up being our digit of choice.

Okay so now that we've worked out that we want to modify `C`

to get our potentially closer number we need to think about bounds. `ABCDEF`

is our original number, and if `ABCCBA`

isn't the closest palindrome, then what could be? Based on our little detour above we can find it by modifying `C`

. So there are two cases, `ABCDEF`

is greater than `ABCCBA`

or that is less than `ABCCBA`

.

If `ABCDEF`

is greater than `ABCCBA`

then lets add 1 to `C`

. We'll say `T = C+1`

so now we have a number `ABTTBA`

. So we'll test to make sure that `ABCDEF - ABCCBA > ABCDEF - ABTTBA`

and if so we know that `ABTTBA`

is the nearest palindrome. As any more modifications to C would just take us more and more distant.

Alternately if `ABCDEF`

is less than `ABCCBA`

then we'll subtract 1 from `C`

. Let's say `V = C-1`

. So we have `ABVVBA`

, which just like above we'll test: `ABCDEF - ABCCBA > ABCDEF - ABVVBA`

and you'll have the same solution.

The trick is that `ABCDEF`

is always between `ABTTBA`

and `ABVVBA`

and the only other palindrome between those numbers is `ABCCBA`

. So you only have 3 options for a solution. and if you compare `ABCDEF`

to `ABCCBA`

you only need to check 2.

I don't think it will be hard for you to adapt this to numbers of any size. and in the case of an odd number of digits you'd simply have `ABCBA`

, `ABVBA`

and `ABTBA`

and so on...

So just like your examples: lets take 911.

- Ignore the last 1 we only take the first half (round up). so 91X.
- Replace X with 9. we have 919. this is out mid point.
- We know our original 911 is less than 919 so subtract 1 from our middle number so we get our second (lower bound) 909.
- Compare
`911 - 919`

and `911 - 909`

- return the one with the smallest difference.

So this gives us a constant time algorithm :)

This appears to be what you have, but I thought I'd elaborate to hopefully shed light on the issue as it seems to be a small programming error on your part otherwise.