# Dynamic programming algorithm N, K problem

An algorithm which will take two positive numbers N and K and calculate the biggest possible number we can get by transforming N into another number via removing K digits from N.

For ex, let say we have N=12345 and K=3 so the biggest possible number we can get by removing 3 digits from N is 45 (other transformations would be 12, 15, 35 but 45 is the biggest). Also you cannot change the order of the digits in N (so 54 is NOT a solution). Another example would be N=66621542 and K=3 so the solution will be 66654.

I know this is a dynamic programming related problem and I can't get any idea about solving it. I need to solve this for 2 days, so any help is appreciated. If you don't want to solve this for me you don't have to but please point me to the trick or at least some materials where i can read up more about some similar issues.

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The trick to solving a dynamic programming problem is usually to figuring out what the structure of a solution looks like, and more specifically if it exhibits optimal substructure.

In this case, it seems to me that the optimal solution with N=12345 and K=3 would have an optimal solution to N=12345 and K=2 as part of the solution. If you can convince yourself that this holds, then you should be able to express a solution to the problem recursively. Then either implement this with memoisation or bottom-up.

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Alternatively N=2345 and K=2. –  Vatine Feb 12 '10 at 11:10

Well, to solve any dynamic programming problem, you need to break it down into recurring subsolutions.

Say we define your problem as A(n, k), which returns the largest number possible by removing k digits from n.

We can define a simple recursive algorithm from this.

Using your example, A(12345, 3) = max { A(2345, 2), A(1345, 2), A(1245, 2), A(1234, 2) }

More generally, A(n, k) = max { A(n with 1 digit removed, k - 1) }

And you base case is A(n, 0) = n.

Using this approach, you can create a table that caches the values of n and k.

``````int A(int n, int k)
{
typedef std::pair<int, int> input;
static std::map<input, int> cache;

if (k == 0) return n;

input i(n, k);
if (cache.find(i) != cache.end())
return cache[i];

cache[i] = /* ... as above ... */

return cache[i];
}
``````

Now, that's the straight forward solution, but there is a better solution that works with a very small one-dimensional cache. Consider rephrasing the question like this: "Given a string n and integer k, find the lexicographically greatest subsequence in n of length k". This is essentially what your problem is, and the solution is much more simple.

We can now define a different function B(i, j), which gives the largest lexicographical sequence of length (i - j), using only the first i digits of n (in other words, having removed j digits from the first i digits of n).

Using your example again, we would have:

B(1, 0) = 1

B(2, 0) = 12

B(3, 0) = 123

B(3, 1) = 23

B(3, 2) = 3

etc.

With a little bit of thinking, we can find the recurrence relation:

B(i, j) = max( 10B(i-1, j) + ni , B(i-1, j-1) )

or, if j = i then B(i, j) = B(i-1, j-1)

and B(0, 0) = 0

And you can code that up in a very similar way to the above.

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This can be solved in O(L) where L = number of digits. Why use complicated DP formulas when we can use a stack to do this:

For: 66621542 Add a digit on the stack while there are less than or equal to L - K digits on the stack: 66621. Now, remove digits from the stack while they are less than the currently read digit and put the current digit on the stack:

read 5: 5 > 2, pop 1 off the stack. 5 > 2, pop 2 also. put 5: 6665 read 4: stack isnt full, put 4: 66654 read 2: 2 < 4, do nothing.

You need one more condition: be sure not to pop off more items from the stack than there are digits left in your number, otherwise your solution will be incomplete!

Another example: 12345 L = 5, K = 3 put L - K = 2 digits on the stack: 12

read 3, 3 > 2, pop 2, 3 > 1, pop 1, put 3. stack: 3 read 4, 4 > 3, pop 3, put 4: 4 read 5: 5 > 4, but we can't pop 4, otherwise we won't have enough digits left. so push 5: 45.

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62785656. Stack = 62785. Read 6. Stack = 62786. Read 5. Stack unchanged. Read 6. Stack unchanged. Answer = 62786? No, answer should be 85656. –  indiv Feb 11 '10 at 16:33
My bad. You don't just add the first L - K characters just like that. You add them while doing the operations I described. So you start off like this: 6 | 6 2 | 7 | 8 | 8 5 | 8 5 6 | 8 5 6 5 | 8 5 6 5 6 | –  IVlad Feb 11 '10 at 16:36
With that clarification, this solution looks good to me. Nice work. –  indiv Feb 11 '10 at 17:33

The two most important elements of any dynamic programming solution are:

1. Defining the right subproblems
2. Defining a recurrence relation between the answer to a sub-problem and the answer to smaller sub-problems
3. Finding base cases, the smallest sub-problems whose answer does not depend on any other answers
4. Figuring out the scan order in which you must solve the sub-problems (so that you never use the recurrence relation based on uninitialized data)

You'll know that you have the right subproblems defined when

• The problem you need the answer to is one of them
• The base cases really are trivial
• The recurrence is easy to evaluate
• The scan order is straightforward

In your case, it is straightforward to specify the subproblems. Since this is probably homework, I will just give you the hint that you might wish that N had fewer digits to start off with.

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