Here I will describe briefly an algorithm. It should be noted that many details needed to be filled in.

The basic idea is to look at the first and last digit of `M`

to determine the sum of the first and last digit of `N`

, and then subtract this quantity from `M`

to reduce to the case of a shorter number.

Let us call a number **good** if it can be written as `N + reverse(N)`

.

(EDIT: in implementation, one will probably need a function `IsGood(M, k)`

which judges whether `M`

can be written as `N + reverse(N)`

for some `N < 10^k`

. But let's skip this detail for the moment.)

The algorithm for determining whether a given number `M`

is good goes as follows:

Let `c`

and `d`

be the first and last digit of `M`

, and let `R`

be the middle part. That is, `M`

has digital expression `cRd`

.

There are two cases:

`c`

is not equal to `1`

`c`

is equal to `1`

In the case where `c`

is not equal to `1`

, the digit `c`

cannot be a carry. This is the **normal case**. Now look at `d`

.

If `d`

is equal to `c`

, then `M`

is good if and only if `R`

is good.

If `d`

is equal to `c - 1`

, then there is a carry from `R`

to `c`

, so `M`

is good if and only if `1R`

is good in the **carry case** (see below).

If `d`

is equal to anything else, then `M`

is not good.

In the case where `c`

is equal to `1`

, there is the additional possibility that `c`

is a carry.

Let `e`

be the first digit of `R`

, and write `M`

as `1eTd`

.

If `d = 9`

or `e < d`

, then the carry case is not possible.

(EDIT: this is wrong, the case `d = 9`

is possible if `e = 0`

.)

Otherwise, the carry case is possible if and only if `(e - d)(T - 1)`

is good.

If either the carry case hold, or the normal case hold, then `M`

is good.

Example:

Let us start with `M = 12001`

.

Since `c = 1`

, there is the normal case and the carry case.

In the normal case, we have `d = 1`

, so we need to test whether `200`

is good. For `M = 200`

, we have `c = 2`

and `d = 0`

, so the number `200`

is not good, hence the normal case for `M = 12001`

fails.

In the carry case, we need to test whether `(12001 - 11000 - 11) / 10 = 99`

is good. For `M = 99`

, we have `c = 9`

and `d = 9`

, so this again reduces to whether `0`

is good, which obviously is true. Hence the carry case holds.

The conclusion is then `M`

is good.

Time complexity:

With some detailed arguments (which I don't want to present here), it can be proved that the algorithm runs in `O(log_10(M))`

time.

`base * #digits`

? – G. Bach Apr 28 '16 at 14:33