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I am looking at the following paragraph in the book "Programming Interviews Exposed" in reference to the implementation of a linked list stack in C:

typedef struct Element {
   struct Element *next;
   void *data; 
} Element;

void push( Element *stack, void *data ); 
void *pop( Element *stack );

Now consider what will happen in these routines in terms of proper functionality and error handling. Both operations change the first element of the list. The calling routine’s stack pointer must be modified to reflect this change, but any change you make to the pointer that is passed to these functions won’t be propagated back to the calling routine. You can solve this problem by having both routines take a pointer to a pointer to the stack. This way, you can change the calling routine’s pointer so that it continues to point at the first element of the list. Implementing this change results in the following:

void push( Element **stack, void *data ); 
void *pop( Element **stack);

Could someone explain, in different words, why we need to use a double pointer here? I'm a bit unsure about the explanation provided.

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4 Answers 4

up vote 3 down vote accepted

It is similar to the famous swap() function in C.

Case 1:

void swapFails(int x, int y) {
    int temp = x;
    x = y;
    y = temp;

Case 2:

void swapOk(int *x, int *y) {
    int temp = *x;
    *x = *y;
    *y = temp;

and we invoke swap like this:

int x = 10;
int y = 20;

Case 1:

swapFails(x, y);

Case 2:

swapOk(&x, &y);

Remember, we wanted to CHANGE the values of x and y. For CHANGING values of a datatype, we need pointers. Take this to the next level for pointers. For CHANGING values of a pointer, we would need double pointers.

For Stack using linked list: If you push values 10, 20 and 30, they are stored like this:

top --- bottom
30 -> 20 -> 10

So you see every time you push or pop values from the stack, which is a linked list, the top or the first node of the linked list changes. Hence you need double pointers.

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The first version sends a copy of the pointer, if it's changed inside the function then the local copy would only be changed, when the function returns to the caller the caller still has a pointer to the old address.

Element *stack =...
push (stack)
void push( Element *stack, void *data ) {
  stack = ... // this changes the local pointer allocated on the function's stack
//call returns
stack //still points to old memory

The second version, however, passes a pointer to the stack pointer, so when that is changed, it changes the stack pointer in the calling function.

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In C everything is passed by value, let's say that I have this function:

void foo(void* ptr)

If you call this method in the main, the pointer that you pass will not be NULL (unless it wat already NULL).Because a copy of the pointer is made before passing it to the function.So if you want to modify it's value, you have to pass a double pointer:

void foo(void** ptr)

The same is valid for the stack, of which you want to modify the value.

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With the single-pointer signature you can imagine using the code as follows

Element *myStack = NULL ;

.... bla bla bla ....

push(myStack, something);

Then in the push call you're telling the stack implementation where the old head element of the stack was, but there's no way for the implementation of push to tell you where the new head is. It cannot change your myStack variable, because parameter passing in C is always by value -- i.e., the push function get told what the value of myStack happens to be, but get no chance to change the caller's variable.

In order for things to work, you need to tell the push primitive the address of your local variable that it needs to change:

push(&myStack, something);

and since myStack itself has type Element *, a pointer to the myStack variable has type Element **.

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