Each node of the tree might have an arbitrary number of children. I need a way to construct and traverse such trees, but to implement them using one dimensional vector or a list.
If you only can use one vector (not specified in question), and Nodes should not contain it's own list, only some pointers (addresses in vector), then you can try this:
So for tree like this:
Your vector would look like:
For that approach given tree would look like:
That way you can easily find children of any randomly given node and reorganize array without moving all elements (just copy children to end of table, update pointer and add next child to end of table)
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What you basically do is write the beginnings of a memory manager for a Lisp interpreter by pairing off the vector's elements into cons cells. Here is such a thing I threw together in C just now:
$ cc -std=c99 try.c $ ./a.out (1 (2 (3 4)) (5 (6 7 8)))
You can implement it using one dimensional linked list with little overhead.
Every parent will contain pointers to its children.(But this requires deciding if the max number of nodes are know before hand).
For a tree having A as root node and B,C,D as children its representation will be as below.
A -> B A -> C A -> D
Note that there are 3 links from A.
One way to overcome the upperlimit on the number of nodes is having additional pointer in the nodes.
So, now A ->(child) B ->(adj) ->(adj) C ->(adj) -> D
In this case, its quite complex to update the tree, when deletion occurs.
Its even easier to design better data structures if you could tell your time bounds on the various operations.
With no restrictions on the values of the nodes, and assuming you can use only a single list, I would construct it as follows:
Represent each node as
Traversal is very slow.
The standard way of storing a full binary tree in an array (as is used for binary heap implementations) is nice because you can represent the tree with an array of elements in the order of a level-order tree traversal. Using that scheme, there are quick tricks for computing the parent and child node positions. Moving to a tree in which each node can have an arbitrary number of elements throws a wrench into that kind of scheme.
There are, however, several schemes for representing arbitrary trees as binary trees. They are discussed in great detail in Donald Knuth's Art of Computer Programming, Volume I, Section 2.3.
If the nodes themselves are permitted to contain a pointer, you could store a list of child indicies for each node. Is that possible in your case?