A binary tree can be defined recursively like this:
- Every single node (a node without subtrees) is a binary tree itself.
- If a node has a left subtree, a right one or both, it is a binary tree.
The definition of
struct node follows this recursive definition of a binary tree.
The above image represents a binary tree. We can represent this binary tree in C in the following way:
The node with value 2 is a node that has no subtrees and can be represented as a struct like this:
struct node* node2 = malloc(sizeof(struct node));
node2->info = 2;
node2->llink = NULL;
node2->rlink = NULL;
NULL value for
rlink means that the node has no subtrees. Notice that we can represent the nodes with values 5 (the bottom left one, not the top right one), 11 and 4.
The node with value 6 has two subtrees (remember that all nodes are subtrees themselves) and, assuming that the nodes with value 5 and 11 respectively are represented by
struct node* node5 = malloc(sizeof(struct node));
node5->info = 5;
node5->llink = NULL;
node5->rlink = NULL;
struct node* node11 = malloc(sizeof(struct node));
node11->info = 11;
node11->llink = NULL;
node11->rlink = NULL;
we can repsesent our node like this:
struct node* node6 = malloc(sizeof(struct node));
node6->info = 6;
node6->llink = node5; /* Pointer to node with value 5 */
node6->rlink = node11; /* Pointer to node with value 11 */
The same goes for all the other nodes of the binary tree.
Notice that we are using pointers for the subtrees. The reason is that the use of NULL allows the tree to have a finite number of elements, otherwise, the binary tree would require infinite amount of memory (a struct that contains itself, which contains itself, which contains itself, which contains itself... requires an infinite amount of memory).
(Image taken from the Wikipedia article for Binary Tree and, specifically, from http://upload.wikimedia.org/wikipedia/commons/thumb/f/f7/Binary_tree.svg/200px-Binary_tree.svg.png)