# How to represent a Pascal-esque (equilateral) triangle in memory

I was working on Project Euler Problem 18 (I did solve the problem; I'm not cheating. "Proof" here) and found myself in need of a way to represent a data structure that looks like a Pascal triangle, but with different values. It looks very similar to a binary tree, but there's a very important distinction: a node's children are not exclusively its children. So the first three rows look like this:

``````    75
/  \
95  64
/  \ / \
17  47  82
``````

Note that 47 has two parents.

It's pretty easy to represent this as a linked structure, or even a two-dimensional array, but I'm hoping that there's a more elegant way. I love binary trees, mainly for how you can allocate a single chunk of memory, treat it as an array, and navigate between children and parent with a couple of arithmetic operations or integer division. Is there a way to do the same for this data structure?

My best solution involved using a two-dimensional array (where it's very easy to find children and parents). I dislike this implementation because (at least the way I did it) I called `malloc` for every row, even though I knew how big the structure would be ahead of time.

My question is very similar to this one, but I wasn't happy with the accepted answer. A comment alludes to the solution I seek, but no explanation is given.

Edit: To clarify, I'm looking for a way to index into a one-dimensional array in the same way that an binary tree stuffed sequentially into an array (starting at 1) gives the property that the children of a node at index i are at indexes 2 * i and 2 * i + 1. I'm also not very concerned about being able to find parents, so don't worry too much about the weird two parent.

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That's not a "tree" as far as I know, that's a cyclic graph. This question looks like what you want, or at least a good starting point –  Alex Nov 5 '12 at 14:57