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This is the problem in question: Problem #78

This is driving me crazy. I've been working on this for a few hours now and I've been able to reduce the complexity of finding the number of ways to stack n coins to O(n/2), but even with those improvements and starting from an n for which p(n) is close to one-million, I still can't reach the answer in under a minute. Not at all, actually.

Are there any hints that could help me with this?

Keep in mind that I don't want a full solution and there shouldn't be any functional solutions posted here, so as not to spoil the problem for other people. This is why I haven't included any code either.

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Any particular reason you're trying to solve in a less than a minute? –  Dean J Nov 19 '09 at 18:20
That's sort of the rule of thumb at Project Euler. Bluntly put: If the algorithm can't solve it in under a minute, it sucks, and is therefore not a good solution. I want a good solution. –  Marc Müller Nov 19 '09 at 18:44
I can't give you any specific advice, but I posted some general advice a while ago: stackoverflow.com/questions/1537306/… –  starblue Nov 19 '09 at 18:49

4 Answers 4

up vote 9 down vote accepted

Wikipedia can help you here. I assume that the solution you already have is a recursion such as the one in the section "intermediate function". This can be used to find the solution to the Euler problem, but isn't fast.

A much better way is to use the recursion based on the pentagonal number theorem in the next section. The proof of this theorem isn't straight forward, so I don't think the authors of the problem expect that you come up with the theorem by yourself. Rather it is one of the problems, where they expect some literature search.

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Have you done problems 31 or 76 yet? They form a nice set that is an generalization of the same base problem each time. Doing the easier questions may give you insight into a solution for 78.

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sadly, divisible by 1000000 is way too big. I cannot solve it using the solution to problem 76 –  蒋艾伦 Jun 13 '13 at 9:13

This problem is really asking to find the first term in the sequence of integer partitions that’s divisible by 1,000,000.

A partition of an integer, n, is one way of describing how many ways the sum of positive integers, ≤ n, can be added together to equal n, regardless of order. The function p(n) is used to denote the number of partitions for n. Below we show our 5 “coins” as addends to evaluate 7 partitions, that is p(5)=7.

5 = 5 = 4+1 = 3+2 = 3+1+1 = 2+2+1 = 2+1+1+1 = 1+1+1+1+1

We use a generating function to create the series until we find the required n. The generating function requires at most 500 so-called generalized pentagonal numbers, given by n(3n – 1)/2 with 0, ± 1, ± 2, ± 3…, the first few of which are 0, 1, 2, 5, 7, 12, 15, 22, 26, 35, … (Sloane’s A001318).

We have the following generating function which uses our pentagonal numbers as exponents:

1 - q - q^2 + q^5 + q^7 - q^12 - q^15 + q^22 + q^26 + ...

my blog at blog.dreamshire.com has a perl program that solves this in under 10 sec.

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here some hints:

  1. Divisibility by one million is not the same thing as just being larger than one million. 1 million = 1,000,000 = 10^6 = 2^6 * 5^6.

  2. So the question is to find a lowest n so that the factors of p(n) contain six 2's and six 5's.

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Are you sure about (2.)? This would be a reasonable (or even the best) approach if (2) were true, but AFAIK there is no multiplicative identity for p(n): en.wikipedia.org/wiki/Partition_%28number_theory%29 –  ShreevatsaR Nov 19 '09 at 19:04

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