# proper data structure for nested hashes

What is the proper data structure to represent a relationship like below? Am I better of representing this as a tree instead for instance? If so, how would that three look like? My goal is to have instances of class A in memory with the best memory foot print and also fast inserts to any level of the nest.

Each of the nested dictionaries cloud have several millions of items and class E size can be about 10MB per class.

``````    public class A
{
private Dictionary<int, B> someName;
}

public class B
{
private Dictionary<int, C> someName;
}

public class C
{
private Dictionary<int, D> someName;
}

public class D
{
private Dictionary<int, E> someName;
}

public class E
{
//10 Mb worth of properties
}
``````
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What about the range of your int? –  StarPinkER Feb 14 '13 at 5:05
That's random. Any 32 bit int –  iCode Feb 14 '13 at 9:01

There are many algorithms and datastructures on external memory, which may contain what you want since your data size is very large.

We commonly use I/O per operation to evaluate the effectiveness of a datastructure when we are dealing with external memory problems.

You are thinking about representing this as a tree, which I think is a promising solution. Basically, we need a search tree, something like a B-tree. More specifically, a balanced B-tree on external memory.

I think you can use weight-balanced B-tree, which is a combination of B-tree and BB[α]-tree, to solve this problem.

A Weight-balanced B-tree with parameters b and k(b>8,k≥8) holds the following constraints:

1. All leaves on same level and contain between k/4 and k elements.

2. Internal node v at level l has w(v) < b^l * k.

3. Except for the root, internal node v at level l has w(v)> 1/4 * b^l * k.

4. The root has more than one child.

We can infer that internal node degree are between (1/4 * b^l * k) / (b^l*k) = 1/4b and (b^l * k) / (1/4 * b^l-1 * k) = 4b.

The Weight-balanced B-tree with branching parameter b and leaf parameter k=Ω(B) has following properties:

1. Space: O(N/B)
2. Height: O(log(b, N/k))
3. O(log(b, N)) rebalancing operations after an update

The proof is not very complicated and can be seen in External Memory Geometric Data Structures written by Lars Arge. The notes on external memory data strucutres is very good and I highly recommend you to read. You can start by reading some of the lecture notes by L.Arge, which can quickly help you to understand this data structure and make your decision.

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Many thanks for the great answer. Buy what if my instance class A could actually fit in memory? Would I still use same data structure? –  iCode Feb 15 '13 at 21:31
I thought you are requesting some data structures to handle a int->E mapping. Then if the data size is very large, this data structure is very good. But I realize you want to remain the int->B(int->C(...)) mapping. Since A single instance of A/B/C/D can fit in memory, I think you can use directly use the code you posted in that question. –  StarPinkER Feb 16 '13 at 2:10