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struct node
     int         info;
     struct node *llink;
     struct node *rlink;

typedef node *nodep;

What does it mean to have a structure's pointer inside that structure itself?
Please explain the above structure in detail.

I am NOT talking about the trees logic. I am talking about the C struct and the pointer's behaviour.


struct node *llink How does the memory gets allocated to this? This is a type which hasn't yet come into existence?

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nodep is a pointer of one structre. which use in whole porgram as a pointer of this structre(node), like suppose we create like one pointer of any integer same as like this here *nodep is a pointer of node structure –  user1089679 Jan 30 '12 at 10:12
Is this homework? –  Martin Jan 30 '12 at 10:12
@Martin Huh? No I am not in school. Just trying to "understand" the basics rather than "mugging" them up. –  TheIndependentAquarius Jan 30 '12 at 10:13
@user1089679 I am NOT talking about nodep. I was talking about struct node *llink; struct node *rlink; they are inside the their their type's struct. –  TheIndependentAquarius Jan 30 '12 at 10:14
@AnishaKaul Sorry for maybe confusing you, I just learned from Alex Reynolds answer that in a binary tree the children are named "left" and "right" (foreign languages and naming conventions...), so just ignore my previous comment. –  Martin Jan 30 '12 at 10:27

4 Answers 4

up vote 7 down vote accepted

A pointer is just a reference to a location in memory ("address"). In the case of a node, a pointer to an instance of a node is a reference to the location in memory where that node instance is stored.

For your struct as defined, if you have an instance of a node that resides in one memory location, it can point to two other node instances that reside in their own memory locations (*llink, *rlink).

Using a real-world tree as a metaphor, the *llink and *rlink are pointers to left and right "branches" of a root node of a tree structure, respectively. Those pointers themselves may branch off into further and deeper left and right "subtrees".

Have a read of this introduction to binary trees.

binary tree

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The first two paragraphs made me understand what I wanted to. This is like struct k { int *m}; this means that the instance of struct k can contain a pointer to a instance of an int? Right? Similarily it can also contain a pointer to an instance of some other struct? After all, even if the types are same the locations will be different, so it is NOT struct node { struct node *llink; }; a pointer to "itself"? Is it? –  TheIndependentAquarius Jan 30 '12 at 10:27
@AnishaKaul "so it is NOT struct node { struct node *llink; }; a pointer to "itself"?" -> Correct. llink can hold a pointer to an instance of a struct node. This doesn't have to be the same instance, although of course it could. (With nodes a, b and c: a.left > b and a.right > c is normal, but a.right > a would be possible, too.) –  Martin Jan 30 '12 at 10:32
@Martin thanks, that explains it. All this while it seemed to me like a recursive pointer (always pointing to itself), hence asked finally. Thanks. –  TheIndependentAquarius Jan 30 '12 at 10:35
@Martin How do the memory allocations work for this type of structs? I mean struct node *llink how does the memory gets allocated to this? Since this is a type which hasn't yet come into existence? –  TheIndependentAquarius Jan 30 '12 at 10:54
@AnishaKaul What we're looking at is the type declaration, not the variable definition. The first time you use that type to define a variable (e.g. node *rootNode), the type is fully declared. –  Martin Jan 30 '12 at 10:58

Since there is some contradictory information in the webs regarding 'declaration' vs. 'definition', I'll stick to the definition :-) of these two terms following this post.

struct node

This is the beginning of the definition of the struct "node". It also introduces the type node.

     int         info;
     struct node *llink;
     struct node *rlink;

Here are some field declarations. The type must be known and it is known, because it has been introduced already. The actual size of node is irrelevant.


Now the definition of node is complete, and it can be used as a type:

typedef node *nodep;

When defining a variable of type node, the memory gets allocated:

node n = {42, NULL, NULL};
// or
nodep np = (struct node *)malloc(sizeof(struct node));

With C++: But what if you want to use two types within each other? Then you introduce type B, define type A and define type B:

class B;

class A
    class B *pointerToB;

class B
    class A *pointerToA;

-> This is supposed to show the idea, not be production code. I'm not sure if you can use it in C with struct instead of class in the last example. If this is not 100% correct, please comment and I'll correct.

Here is a great followup to the post from the beginning of my answer.

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You said: The type must be known and it is known, because it has been introduced already. and I thought a type gets known when the compiler knows how much memory to allocate to it>? and with struct k inside struct k, the compiler doesn't know the size of the first struct k, so..? am I wrong? –  TheIndependentAquarius Jan 30 '12 at 11:35
That would be true if it wasn't a pointer. But to declare a pointer, the compiler is only interested in the type of the pointer, not the size of the structure it can point to. (After all, the size of a pointer is always 16/32/64 bit, depending on your OS.) –  Martin Jan 30 '12 at 11:45
Yes I had forgotten that. Well, pointers have a size of 4 bytes! Hmm. So, the size is know here. Yeah I get it now. Thanks, –  TheIndependentAquarius Jan 30 '12 at 11:49
Also, it means that I can't delacre struct k obj; inside struct k? –  TheIndependentAquarius Jan 30 '12 at 11:50
@AnishaKaul "that I can't delacre struct k obj; inside struct k?" -> I'm not absolutely sure. It might work this way: struct k; struct k { struct k obj; }; (First a forward declaration, then the actual definition of the struct.) –  Martin Jan 30 '12 at 12:06

This page has information on what a tree data structure is:


A tree node holds the data value (the info member) and pointers to the left and right subtrees (llink and rlink pointers). The subtrees are also nodes so the pointers are pointers to struct node objects. Having pointers let you walk the tree because all nodes are linked through the presence of the pointers.

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I know about the trees behaviour. Here I was asking about the C struct and the pointers in it. In C terms, not in tree terms. –  TheIndependentAquarius Jan 30 '12 at 10:32

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.

For example:

Binary tree Example

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;

A NULL value for llink and 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)

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Well, you have explained here the trees, whereas all I wanted was the C struct, pointers, and memory allocations. No tree explanations. –  TheIndependentAquarius Jan 30 '12 at 11:09
@AnishaKaul: I was trying to explain how each part of the struct corresponds to a specific element of a binary tree. –  Alexandros Jan 30 '12 at 11:30
Yeah, but I had a different question. :) –  TheIndependentAquarius Jan 30 '12 at 11:31

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