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In programming contests, the following pattern occurs in a lot of tasks:

Given numbers A and B that are huge (maybe 20 decimal digits or more), determine the number of integers X with A ≤ X ≤ B that have a certain property P

SPOJ has lots of tasks like these for practice.

Where examples of interesting properties include:

  • "the digit sum of X is 60"
  • "X consists only of the digits 4 and 7"
  • "X is palindromic", which means that the decimal representation of X equals its reverse (for example, X = 1234321)

I know that if we define f(Y) to be the number of such integers X ≤ Y, then the answer to our question is f(B) - f(A - 1). The reduced problem is how to compute the function f efficiently. In some cases we can make use of certain mathematical properties to come up with a formula, but often the properties are more complicated and we don't have enough time for that in a contest.

Is there a more general approach that works in a lot of cases? And can it also be used to enumerate the numbers with the given property or compute some aggregation on them?

A variation of this is to find the k-th number with a given property, which of course can be solved by using binary search together with a counting function.

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    @JuanLopes: Yes. The idea is to document your ideas and results so that other people can profit from it, just like a blog :) I'm also trying to make the competitive programming community interested in Stack Overflow more, so maybe this will help set an example that questions like these are in fact welcome and on-topic here (and obviously I hope others will find this interesting as well) – Niklas B. Mar 14 '14 at 1:19
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    @JuanLopes: I'm also open to alternative answers of course – Niklas B. Mar 14 '14 at 1:21
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    @arunmoezhi You mean, self-answered questions? Because those occur all across SO (there is even a checkbox in the "Ask a question" dialog that lets you write an answer even before posting the question). Or do you mean competitive programming? I think I invented a tag for that already just now – Niklas B. Mar 14 '14 at 1:36
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    @Charles: Or to put it otherwise, this is pretty much a competitive-programming-specific question, because it describes a trick that is only useful in that setting and not in the "real world" – Niklas B. Mar 14 '14 at 4:55
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    @RobNeuhaus There's also programming-contest, so there is some confusion there, but both are meta-tags so I think it's probably best to get rid of them. Dukeling and others have a point – Niklas B. Mar 15 '14 at 18:00
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Indeed, there is an approach to this pattern which turns out to work quite often. It can also be used to enumerate all the X with the given property, provided that their number is reasonably small. You can even use it to aggregate some associative operator over all the X with the given property, for example to find their sum.

To understand the general idea, let us try to formulate the condition X ≤ Y in terms of the decimal representations of X and Y.

Say we have X = x1 x2 ... xn - 1 xn and Y = y1 y2 ... yn - 1 yn, where xi and yi are the decimal digits of X and Y. If the numbers have a different length, we can always add zero digits to the front of the shorter one.

Let us define leftmost_lo as the smallest i with xi < yi. We define leftmost_lo as n + 1 if there is no such i. Analogously, we define leftmost_hi as the smallest i with xi > yi, or n + 1 otherwise.

Now X ≤ Y is true if and exactly if leftmost_lo <= leftmost_hi. With that observation it becomes possible to apply a dynamic programming approach to the problem, that "sets" the digits of X one after another. I will demonstrate this with your example problems:

Compute the number f(Y) of integers X with the property X ≤ Y and X has the digit sum 60

Let n be the number of Y's digits and y[i] be the i-th decimal digit of Y according to the definition above. The following recursive algorithm solves the problem:

count(i, sum_so_far, leftmost_lo, leftmost_hi):
    if i == n + 1:
        # base case of the recursion, we have recursed beyond the last digit
        # now we check whether the number X we built is a valid solution
        if sum_so_far == 60 and leftmost_lo <= leftmost_hi:
            return 1
        else: 
            return 0
    result = 0
    # we need to decide which digit to use for x[i]
    for d := 0 to 9
        leftmost_lo' = leftmost_lo
        leftmost_hi' = leftmost_hi
        if d < y[i] and i < leftmost_lo': leftmost_lo' = i
        if d > y[i] and i < leftmost_hi': leftmost_hi' = i
        result += count(i + 1, sum_so_far + d, leftmost_lo', leftmost_hi')
    return result

Now we have f(Y) = count(1, 0, n + 1, n + 1) and we have solved the problem. We can add memoization to the function to make it fast. The runtime is O(n4) for this particular implementation. In fact we can cleverly optimize the idea to make it O(n). This is left as an exercise to the reader (Hint: You can compress the information stored in leftmost_lo and leftmost_hi into a single bit and you can prune if sum_so_far > 60). The solution can be found at the end of this post.

If you watch closely, sum_so_far here is just an example of an arbitrary function computing a value from the digit sequence of X. It could be any function that can be computed digit by digit and outputs a small enough result. It could be the product of digits, a bitmask of the set of digits that fulfill a certain property or a lot of other things.

It could also just be a function that returns 1 or 0, depending on whether the number consists only of digits 4 and 7, which solves the second example trivially. We have to be a bit careful here because we are allowed to have leading zeroes at the beginning, so we need to carry an additional bit through the recursive function calls telling us whether we are still allowed to use zero as a digit.

Compute the number f(Y) of integers X with the property X ≤ Y and X is palindromic

This one is slightly tougher. We need to be careful with leading zeroes: The mirror point of a palindromic number depends on how many leading zeroes we have, so we would need to keep track of the number of leading zeroes.

There is a trick to simplify it a bit though: If we can count the f(Y) with the additional restriction that all numbers X must have the same digit count as Y, then we can solve the original problem as well, by iterating over all possible digit counts and adding up the results.

So we can just assume that we don't have leading zeroes at all:

count(i, leftmost_lo, leftmost_hi):
    if i == ceil(n/2) + 1: # we stop after we have placed one half of the number
        if leftmost_lo <= leftmost_hi:
            return 1
        else: 
            return 0
    result = 0
    start = (i == 1) ? 1 : 0    # no leading zero, remember?
    for d := start to 9
        leftmost_lo' = leftmost_lo
        leftmost_hi' = leftmost_hi
        # digit n - i + 1 is the mirrored place of index i, so we place both at 
        # the same time here
        if d < y[i]     and i     < leftmost_lo': leftmost_lo' = i
        if d < y[n-i+1] and n-i+1 < leftmost_lo': leftmost_lo' = n-i+1
        if d > y[i]     and i     < leftmost_hi': leftmost_hi' = i
        if d > y[n-i+1] and n-i+1 < leftmost_hi': leftmost_hi' = n-i+1
        result += count(i + 1, leftmost_lo', leftmost_hi')
    return result

The result will again be f(Y) = count(1, n + 1, n + 1).

UPDATE: If we don't only want to count the numbers, but maybe enumerate them or compute some aggregate function from them which does not expose group structure, we need to enforce the lower bound on X as well during the recursion. This adds a few more parameters.

UPDATE 2: O(n) Solution for the "digit sum 60" example:

In this application we place the digits from left to right. Since we are only interested in whether leftmost_lo < leftmost_hi holds true, let us add a new parameter lo. lo is true iif leftmost_lo < i and false otherwise. If lo is true, we can use any digit for the position i. If it is false, we can only use the digits 0 to Y[i], since any larger digit would cause leftmost_hi = i < leftmost_lo and can thus not lead to a solution. Code:

def f(i, sum_so_far, lo):
    if i == n + 1: return sum_so_far == 60
    if sum_so_far > 60: return 0
    res = 0
    for d := 0 to (lo ? 9 : y[i]):
         res += f(i + 1, sum + d, lo || d < y[i])
    return res

Arguably, this way of looking at it is somewhat simpler, but also a bit less explicit than the leftmost_lo/leftmost_hi approach. It also doesn't work immediately for somewhat more complicated scenarios like the palindrome problem (although it can be used there as well).

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    Your algorithm for Compute the number f(Y) of integers X with the property X ≤ Y and X has the digit sum 60 looks like it has a complexity of O(10^n). I can't see how it is O(n^4). The recursion level can go upto n and in each recursion there's a loop from 0 to 9. Am I missing something here? – Rushil Paul May 19 '14 at 19:11
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    @Rushil As I said, you need to add memoization to make it fast. There are only O(n^4) different assignments of the parameters, so the function body is executed at most O(n^4) times, each time doing only constant work apart from the recursive calls (the loop from 0 to 9 can be considered constant time). Or in other words: There are 10^n branches, but only O(n^4) of those are actually distinct subproblems. Since we don't solve a branch more than once, there are only O(n^4) nodes in the recursion tree – Niklas B. May 19 '14 at 19:57
  • So the O(10^n) complexity can be reduced to O(n^4) with memoization. How do you make it O(n^2) or better ? – Rushil Paul May 20 '14 at 5:46
  • @Rushil First realize that if sum_so_far > 60, you can return 0 immediately. This gets the runtime down to O(n^3). Also realize that we're only interested in leftmost_lo < leftmost_hi, so if we set the digits from left to right like in this case, we just need one state bit to remember whether we have already placed a digit smaller than the upper bound. Example: pastie.org/9199021 with memoization, you get O(n) runtime – Niklas B. May 22 '14 at 13:06
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    @NiklasB. didn't you have to memoize on both i and sum_so_far so it becomes O(n*n)? correct me if I am wrong – harish.venkat May 23 '14 at 19:34

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