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Let N be an integer. If N = 2536, the reversed N is 6352. If N = 1000000, the reversed N is 1.
We are given an integer M, where 1 <= M <= 10^(100000).
We need to find whether an integer N exists, where N + reversed(N) = M.

Any ideas, besides brute force ?

  • What's brute force here? Would it be brute force if you could do it in time proportional to base * #digits? – G. Bach Apr 28 '16 at 14:33
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    this can be done with pen and paper – Sklivvz Apr 28 '16 at 14:39
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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.

  • What would be the case if R is empty? Take M=11 – Rishit Sanmukhani Apr 28 '16 at 14:51
  • I got to the same solution. Also, since N has 6 digits (or the reverse of N does), M must either have the form dddddd (d = 1..9) or 1dddddd (carry). 1ddddq is a carry only if q = 1 (if I'm not mistaken) – Sklivvz Apr 28 '16 at 14:51
  • @RishitSanmukhani I didn't write down all the details, but from the example it should be clear that we put R = 0 if it's empty. – WhatsUp Apr 28 '16 at 14:51
  • @WhatsUp can you tell how the carry case works there is a bit confusion in it – 1shubhamjoshi1 Apr 28 '16 at 15:43
  • The answer is actually a brief idea. In fact, you should write a function IsGood(M, k), which returns True if and only if M can be written as N + reversed(N) for some N < 10^k. To calculate IsGood(M, k), you just follow the idea of the answer, noting that the first and last digit of M can determine the sum of the first and last digit of N, hence reducing the length of M. – WhatsUp Apr 29 '16 at 15:41

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