# Algorithm to implement non-binary trees using 1-dimensional vector?

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.

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homework?...... –  Juliano Jan 20 '10 at 15:43
Is there any restriction on the values of the nodes? –  danben Jan 20 '10 at 15:45
@Juliano I wish.. My homework days are long gone :) @danben No restriction. –  GabiMe Jan 20 '10 at 15:48
Any tree can be transformed into a binary tree (and back into its original form). The transformed binary tree has, for every node, a linked list of its original children as first child, and the pointer to the next sibling in as the second child. –  Juliano Jan 20 '10 at 15:51
Can you give some background? Why do you need to do this? Perhaps we can better help by backing up a step. –  PeterAllenWebb Jan 20 '10 at 16:10
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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:

1. each node holds address of its sibling
2. first node after given (if it is not its sibling) is child, with pointer to second child and so on
3. each of its child has it's own children

So for tree like this:

``````A
| \
B  E ___
|\  \ \ \
C D  F G H
``````

Your vector would look like:

``````idx:    0 1 2 3 4 5 6 7
nodes:  A B C D E F G H
next:   _ 4 3 _ _ 6 7 _
``````

where `_` is null pointer

Edit:
Another approach:

1. every node holds address of region in vector occupied by its children
2. children are next to each other
3. there exists null node in vector, marking end of siblings group

For that approach given tree would look like:

``````idx:    0 1 2 3 4 5 6 7 8 9 A B
nodex:  A _ B E _ C D _ F G H _
child:  2   5 8   _ _   _ _ _
``````

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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Doesn't that make E the child of D in your example, then? –  danben Jan 20 '10 at 15:54
And also of C [15 chars] –  danben Jan 20 '10 at 15:54
@danben Only if you try to traverse from any randomly node. If you go from root (index 0), then it should not be possible. It's not ideal, by it was my first guess after seeing this question –  MBO Jan 20 '10 at 15:57
Ok, I see. I still think the OP wanted a single list, though - otherwise you could just have one list per sibling group and be done with it. –  danben Jan 20 '10 at 16:02
The two approaches in this answer are duals. To represent an n-ary tree you need at least two links: firstChild and nextSibling. (They're available in DOM trees, and also in the Inform 6 text adventure programming environment: inform-fiction.org/manual/html/s3.html#s3_2 .) You can either store both links in every node, or store just one and let the sequence of the vector encode the other. –  Jason Orendorff Jan 20 '10 at 18:46
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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:

``````#include <stdbool.h>
#include <iso646.h>
#include <stdlib.h>
#include <stdio.h>
#include <assert.h>

#define MEMORY_SIZE 1024
#define NIL 0

struct pair
{
bool allocated;
size_t first;
size_t second;
};

size_t allocate_pair(struct pair vector[])
{
for (size_t i = 1; i < MEMORY_SIZE; i++)
{
if (not vector[i].allocated)
{
vector[i].allocated = true;
return i;
}
}

return NIL;
}

size_t make_pair(struct pair vector[], size_t a, size_t b)
{
size_t the_pair = allocate_pair(vector);

if (the_pair != NIL)
{
vector[the_pair].first = a;
vector[the_pair].second = b;
return the_pair;
}
else
{
fprintf(stderr,
"Out of pairs -- make_pair(%p, %zu, %zu)",
vector,
a,
b);
exit(EXIT_FAILURE);
}
}

size_t first(struct pair vector[], size_t index)
{
assert(vector[index].allocated);

return vector[index].first;
}

size_t second(struct pair vector[], size_t index)
{
assert(vector[index].allocated);

return vector[index].second;
}

void print_pair_aux(struct pair[], size_t, size_t);
void print_pair(struct pair vector[], size_t p)
{
assert(vector[p].allocated);

size_t a = first(vector, p);
size_t b = second(vector, p);

printf("(");

print_pair_aux(vector, a, b);

printf(")");
}

void print_pair_aux(struct pair vector[], size_t a, size_t b)
{
if (a == NIL)
printf("NIL");
else if (a >= IVAL_MASK)
printf("%zu", a &~ IVAL_MASK);
else
print_pair(vector, a);

if (b == NIL)
printf("");
else if (b >= IVAL_MASK)
printf(" . %zu", b &~ IVAL_MASK);
else
{
printf(" ");
print_pair_aux(vector,
first(vector, b),
second(vector, b));
}

}

int main(void)
{
struct pair *vector = calloc(MEMORY_SIZE, sizeof *vector);

#define cons(A,B) make_pair(vector, (A), (B))
#define ival(x) ((x) | IVAL_MASK)

size_t a = cons(ival(3), cons(ival(4), NIL));
size_t b = cons(ival(2), cons(a, NIL));
size_t c = cons(ival(6), cons(ival(7), cons(ival(8), NIL)));
size_t d = cons(ival(5), cons(c, NIL));
size_t e = cons(ival(1), cons(b, cons(d, NIL)));

print_pair(vector, e);
puts("");
}
``````
```\$ cc -std=c99 try.c
\$ ./a.out
(1 (2 (3 4)) (5 (6 7 8)))
```
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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.

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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 `( val ; [ int ; ...] )` where val is the node's value and each int is the position in the list of one of it's children. Use a non-printable separator if necessary.

Traversal is very slow.

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