I was wondering if anyone has ever used linked lists to do heap sort and if they have could they provide the code. I have been able to do heapsort using arrays, but trying to do it in linked lists seems unpractical and just a pain in the you know where. I have to implement linked lists for a project Im doing, any help would be greatly appreciated.

Also I am using C.

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Kind of flies right in the face of the definition of 'heap'. You could do it in a tree, but the heap via array was an intended abstraction to improve on that idea. You can do it in a linked list, but it will either be very slow (since you'll treat it like an array), or have so much extra book-keeping that it will become a tree (whether it is recognizable as one at that point is something else entirely. :) ) –  Joe Jun 4 '12 at 17:39
If you're not tied to a Heap sort, then I suggest a mergesort for linked lists. Reasonably easy to implement and rather efficient. Heap sorting linked lists, I'd rather not think about. –  Daniel Fischer Jun 4 '12 at 17:48
How is this different from your other question? –  Caleb Jun 4 '12 at 18:42

The answer is "you don't want to implement heap sort on a linked list."

Heapsort is a good sorting algorithm because it's `O(n log n)` and it's in-place. However, when you have a linked list heapsort is no longer `O(n log n)` because it relies on random access to the array, which you do not have in a linked list. So you either lose your in-place attribute (but needing to define a tree-like structure is `O(n)` space). Or you will need to do without them, but remember that a linked list is `O(n)` for member lookup. Which brings the runtime complexity to something like `O(n^2 log n)` which is worse than bubblesort.

Just use mergesort instead. You already have the `O(n)` memory overhead requirement.

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Thank you. That cleared up some questions I had about complexity, I didnt realize that o (n log n) didnt apply to heapsort when using linked list. –  Lane Fujikado Jun 4 '12 at 19:50
@OmnipotentEntity i think linked list implementation will become O(n^2) rather than O(n^2 log n). Since each heapify operation will take O(n) time and we have n such passes –  David Aug 1 '13 at 5:48
``````//Heap Sort using Linked List
//This is the raw one
//This getRoot function will replace the root with number in the last node, after the main prints the largest number in the heap
//The heapSort function will reconstruct the heap
//addNode function is as same as in binary search tree
//Note addNode and heapSort are recursive functions
//You may wonder about the for loop used in main, this actually tells the depth of the tree (i.e log base2 N)
//With this value these functions find where to trverse whether left or right(direction), with help of macro GETBIT (0-left,1-right)

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

#define GETBIT(num,pos) (num >> pos & 1)

struct node
{
int data;
struct node *left;
struct node *right;
};
typedef struct node node;

int nodes;
node *first, *tmp, *current;

void swap(int *, int *);
void getRoot(node *, int);
void heapSort(node *);

int main()
{
int num;
int cont,i,j;

while(1)                                                //It gets number from user if previous value is non zero number
{
printf("Enter a number\n");
scanf("%d",&num);
if(!num)                                            //i'm using 0 as terminating condition to stop adding nodes
break;                                          //edit this as you wish

current = (node *)malloc(sizeof(node));
if(current ==  0)
return 0;

current->data = num;
nodes++;

for(i=nodes,j=-1; i; i >>= 1,j++);

if(first == 0)
{
first = current;
first->left = 0;
first->right = 0;
}
else

}
printf("Number of nodes added : %d\n",nodes);

while(nodes)
{
printf(" %d -> ",first->data);                                        //prints the largest number in the heap

for(i=nodes,j=-1; i; i >>= 1,j++);                                    //Updating the height of the tree
getRoot(first,j-1);
nodes--;

heapSort(first);
}

printf("\n\n");
return 0;
}

void swap(int *a,int *b)
{
*a = *a + *b;
*b = *a - *b;
*a = *a - *b;
}

void addNode(node *tmp1,node *parent, int pos)
{
int dirxn = GETBIT(nodes,pos);                                   // 0 - go left, 1 - go right

if(!pos)
{
if(dirxn)
tmp1->right = current;
else
tmp1->left = current;

current->left = 0;
current->right = 0;

if(current->data > tmp1->data)
swap(&current->data, &tmp1->data);
}

else
if(dirxn)
else

if(tmp1->data > parent->data)
swap(&parent->data,&tmp1->data);
}

void getRoot(node *tmp,int pos)
{
int dirxn;

if(nodes == 1)
return ;

while(pos)
{
dirxn = GETBIT(nodes,pos);

if(dirxn)
tmp = tmp->right;
else
tmp = tmp->left;
pos--;
}

dirxn = GETBIT(nodes,pos);

if(dirxn)
{
first->data = tmp->right->data;
free(tmp->right);
tmp->right = 0;
}
else
{
first->data = tmp->left->data;
free(tmp->left);
tmp->left = 0;
}
}

void heapSort(node *tmp)
{
if(!tmp->right && !tmp->left)
return;

if(!tmp->right)
{
if(tmp->left->data > tmp->data)
swap(&tmp->left->data, &tmp->data);
}
else
{
if(tmp->right->data > tmp->left->data)
{
if(tmp->right->data > tmp->data)
{
swap(&tmp->right->data, &tmp->data);
heapSort(tmp->right);
}
}
else
{
if(tmp->left->data > tmp->data)
{
swap(&tmp->left->data, &tmp->data);
heapSort(tmp->left);
}
}
}
}
``````
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