# Project Euler #14

I am currently solving, Project Euler problem 14:

The following iterative sequence is defined for the set of positive integers:

``````n → n/2 (n is even)
n → 3n + 1 (n is odd)

Using the rule above and starting with 13, we generate the following sequence:
13 → 40 → 20 → 10 → 5 → 16 → 8 → 4 → 2 → 1

Which starting number, under one million, produces the longest chain?
``````

I devised the following algorithm to solve the problem:

• Instead of finding series for each number separately, which will contain lots of redundant calculation, I try to develop the series backwards from 1. That is, start from number and predict the element before it.
• Since multiple series can be generated, store the recent number of all series using a linked list. (The idea is to store only those elements that have longer series.)
• I will loop this, until I find all the numbers under the given limit; the last number under the limit will have the longest series.

Here is my code:

``````void series_generate(long num)
{
long n = 1;
while (n < num)
{
series *p;
for (p = head; p != NULL; p = p->next)
{
long bf = p->num - 1;
if (p->num%2 == 0 && bf != 0 && bf%3 == 0) {
bf /= 3;
if (bf != 1)
if (bf < num)
n++;
}
p->num *= 2;
if ( p->num < num)
n++;

}
}
}
``````

Here is the link to complete code. However, I don't get the answers as I expected. Can anyone expain why this algorithm won't work?

-
What does your algorithm return and how does it differ from your expectations? –  gary Jul 4 '12 at 16:15
You should use the debugger to step through your program line-by-line, in order to find the first line whose behaviour diverges from what you intended. –  Oli Charlesworth Jul 4 '12 at 16:19
i calculated the answer to the problem using brute force. I expect 837799 –  mohit Jul 4 '12 at 16:21
BTW: This is the Collatz-cycle // series. –  wildplasser Jul 4 '12 at 16:37
@nhahtdh: The largest value in the chain is almost 57 billion and takes 36 bits. This problem requires a 64-bit integer type. –  Blastfurnace Jul 4 '12 at 16:47

You're trying to build the Collatz tree backwards, level per level. Thus after the `k`-th iteration of the inner loop, the list contains (while no overflow occurred) all numbers needing exactly `k` steps to reach 1 in their Collatz sequence.

That approach has two serious problems.

1. The size of the levels increases exponentially, the size doubles roughly every three levels. You don't have enough memory to store levels past not much over 100.
2. The largest member in level `k` is 2k. Depending on the used type for the `num` member, you get overflow at level 31, 32, 63 or 64. Then, if you use a signed type, you have undefined behaviour, probably negative numbers in the list, and all goes haywire. If you use unsigned types, your list contains a 0, and all goes haywire.

Since 27 needs 111 steps to reach 1, you have overflow whenever `num > 27`, therefore you get wrong results.

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When talking about the steps in this sequence, is it common to omit `1` as one of the steps ie not count it? Never had heard of this sequence until today, now I'm somewhat curious –  Levon Jul 4 '12 at 19:52
By "steps", I mean the transitions, `n -> n/2` resp. `n -> 3*n + 1`. Thus I avoid the problem whether to include 1. When talking about the chain length, I don't think there's a clear convention whether it's the numbers `[3,10,5,16,8,4,2,1]` (length 8) or the transitions (7) that count. The sequence(s) is(are) also known as the hailstone sequence(s). –  Daniel Fischer Jul 4 '12 at 20:01
thanks .. very informative. –  Levon Jul 4 '12 at 20:16