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My question is in regards to the following code.

#include <stdio.h>
#include <stdlib.h>

struct node
    int v;
    struct node * left;
    struct node * right;

typedef struct node Node;

struct bst
    Node * root;

typedef struct bst BST;

BST * bst_insert(BST * tree, int newValue);
Node * bst_insert_node(Node * node, int newValue);
void bst_traverseInOrder(BST * tree); 
void bst_traverseInOrderNode(Node * node);

int main(void)
    BST * t;

    bst_insert(t, 5);
    bst_insert(t, 8);
    bst_insert(t, 6);
    bst_insert(t, 3);
    bst_insert(t, 12);


    return 0;

BST * bst_insert(BST * tree, int newValue)
    if (tree == NULL)
        tree = (BST *) malloc(sizeof(BST));
        tree->root = (Node *) malloc(sizeof(Node));
        tree->root->v = newValue;
        tree->root->left = NULL;
        tree->root->right = NULL;

        return tree;

    tree->root = bst_insert_node(tree->root, newValue);
    return tree;

Node * bst_insert_node(Node * node, int newValue)
    if (node == NULL)
        Node * new = (Node *) malloc(sizeof(Node));
        new->v = newValue;
        new->left = NULL;
        new->right = NULL;
        return new;
    else if (newValue < node->v)
        node->left = bst_insert_node(node->left, newValue);
        node->right = bst_insert_node(node->right, newValue);

    return node;

void bst_traverseInOrder(BST * tree)
    if (tree == NULL)

void bst_traverseInOrderNode(Node * node)
    if (node == NULL)
        printf("%d ", node->v);

So, the code works perfectly as is. It will insert each value into BST correctly, and the traversal function will traverse the tree inorder correctly. However, when I am initially declaring t to be a BST (e.g. line 27), if I also assign t to be NULL (e.g. BST * t = NULL), then the insertion does not work anymore. But, if I then reassign t for the first insertion (e.g. t = bst_insert(t, 5)), then everything works again. Is there a particular reason for this?

Secondly, how do I know when I need to pass a pointer to a pointer to a structure? If I want to change the value that int i points to, then I need to pass &i to a function, correct? But if I want to change the values within struct node n, then why do I need to pass a **node to a function, and not just a *node?

Thank you so much for taking a look.

share|improve this question
up vote 5 down vote accepted

In C, everything is passed by value, there is no exception to this.

You can emulate pass-by-reference by passing the pointer and dereferencing it in the function but this is a poor cousin to real pass-by-reference.

The bottom line is, if you want to change anything passed to a function, you have to provide its pointer for dereferencing and, for changing pointers themselves, that means passing the pointer of the pointer. Note that:

t = modifyAndReturn (t);

is not really the same thing - the function itself does not modify t, it simply returns something which the caller then assigns to t.

So, you've done it the latter way, where you can do something like this:

int add42 (int n) { return n + 42; }
x = add42 (x);

Using the emulated pass-by-reference, that would be (with pointers and dereferencing):

void add42 (int *n) { *n += 42; }
add42 (&x);

For changing pointers, as mentioned earlier, you need to pass the pointer to the pointer. Let's say you want to change a char pointer so that it points to the next character. You would do something like:

#include <stdio.h>

void pointToNextChar (char **pChPtr) {
    *pChPtr += 1;              // advance the pointer being pointed to.

int main (void) {
    char plugh[] = "hello";
    char *xyzzy = plugh;
    pointToNextChar (&xyzzy);
    puts (xyzzy);              // outputs "ello".

C++ actually provides proper pass-by-reference with the & "modifier" such as:

void add42 (int &n) { n += 42; }

and you don't have to then worry about derefencing within the function, any changes are immediately echoed back to the original passed parameter. I rather hope that C21 will have this feature, it will save a lot of trouble for people unfamiliar with the pointer gymnastics we have to endure in C :-)

By the way, you have a rather serious problem with that code. Within main, the line:

BST * t;

will set t to an arbitrary value which is unlikely to be what you want. You should set it initially to NULL so that bst_insert correctly initialises it.

share|improve this answer
Sorry to have so many questions, but one more thing - after I set t to NULL, bst_insert will not modify t (e.g. when I traverseInOrder t, nothing happens). However, if I assign t to the first insert function (e.g. t = bst_insert(t, 5)), but don't assign to the rest of the insert functions, even the insert functions that t isn't reassigned to still modify t. Why does this happen? – dyxh Aug 30 '13 at 4:42
@dyxh : traversal requires just the root address initially rest addresses are pointed by right & left. So you should not reassign t to return value of every insert. – Don't You Worry Child Aug 30 '13 at 4:49
@dyxh, that's probably best for another question. That way, you'll get more responses. If you ask a question within a comment box as you have, very few people will see it. – paxdiablo Aug 30 '13 at 4:50

Actually your code is incorrect as it is, because you are not allocating memory for t in your main. You will get undefined behavior when you try to access the value pointed in bst_insert_node. The correct way to do it would be to set it to NULL and then

t = bst_insert(t, 5);  
share|improve this answer

BST *t; // It declares a pointer of type BST
BST *t = NULL; // Declares pointer same way and pointer points to mem location "0"


bst_insert(t, 5); // Now "tree" pointer inside "bst_insert" definition points to location pointed by "t" i.e. NULL (in 2nd case above)

tree = malloc(<some memory>); // Allocates some memory and stores its base address inside "tree"

Now see, above statement changes the location pointed by tree in bst_insert(), but not by t in main().

So when you write t = bst_insert(t, 5) you return the value pointed by tree explicitly to store in tree, So code works fine.

If you do not use the return value, t is still NULL.

Either use this way, or you can do like this:

bst_insert(BST **tree, int new_val);

And in main()

bst_insert(&t, 5);

What happens now!!

Now you will use *tree = malloc(<some mem>);

So you directly assign base address of memory allocated to: *tree which is actually t itself. Now you need not return the mem address.

This is same as code below, written inside one function:

BST **tree;
BST *t;

tree = &t;
*tree = malloc(<some mem>);  // You are allocating memory and storing address
                             // actually at "t"

Hope you understand what I want to explain.

share|improve this answer

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