# Reversing a singly linked list without using any pointers

When I say without using any pointers, I mean we still use the 'next' pointer field to traverse through the list, but not changing them when reversing a linked list.

From what I could figure out there seem to be ways to this:

• One way is to reverse the data in the nodes without changing the pointers themselves.
• The second would be to create a new linked list which is a reverse of the original linked list.

I would be grateful if anyone could help me on how to proceed with the first method. Other methods are also welcomed.

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What have you tried so far? –  Oli Charlesworth Jul 23 '13 at 21:01
@OliCharlesworth: I have reversed a linked list both recursively and iteratively. But I am manipulating pointers. –  Jack Jul 23 '13 at 21:02
possible duplicate of How to reverse a singly linked list using only two pointers? –  Grijesh Chauhan Jul 23 '13 at 21:02
have you tried magic? –  James Morris Jul 23 '13 at 21:03
@GrijeshChauhan: That would be changing the pointers. I don't want that. –  Jack Jul 23 '13 at 21:04

This problem is not much different from any other reversal problem. One solution is to walk the list, and place each data item into an array. Then, walk the list again, but start at the end of the array, and you overwrite the list data with the values from the array in reverse order.

``````for (n in list) arr[i++] = n->data
for (n in list) n->data = arr[--i]
``````

If you are not allowed to store anything, then recursion is also out, since it acts as an auxiliary array to store your reversed list. Then a silly solution would be to implement a random access interface to the list:

``````Node * nth_list_item (Node *list, int n);
``````

Which returns the `n`th item of the list. Then, you reverse the list with this interface that lets access it like an array (with a time penalty of course). The reversal no longer takes O(n) time, but is now O(n2).

If recursion is okay, then to satisfy the spirit of the "without storing elements" requirement, you need to walk the list recursively, and then reverse the list as you unwind. This can be accomplished by allowing another parameter to the recursive call to provide the pointer needed to walk through the beginning the list as the recursive calls are unwinding from the end. This implementation uses no extra local variables per recursive call, only the variables provided in the parameters.

``````void swap_left (node *a, node *b, int tmp) {
a->data = b->data;
b->data = tmp;
}

void reverse_recursively (node *cur, node **tail) {
if (cur) {
reverse_recursively(cur->next, tail);
if (*tail) {
swap_left(cur, *tail, cur->data);
if (cur != *tail) *tail = (*tail)->next;
if (cur == *tail) *tail = 0;
}
}
}

void reverse (node *list) {
reverse_recursively(list, &list);
}
``````

If we are allowed to encroach upon the spirit of the "without storing elements" requirement when using recursion, then there is a more straight forward (but more space hungry) solution. Basically, a copy of the reversed linked list can be created while recursively traversing it. When the end of it is reached, the list can be traversed again, copying in the elements from the reversed copy.

``````#define make_node(n, d) (node){ n, d }

void reverse_recursively (node *list, node *cur, node copy) {
if (!cur) {
for (cur = &copy; cur; cur = cur->next, list = list->next) {
list->data = cur->data;
}
return;
}
reverse_recursively(list, cur->next, make_node(&copy, cur->data));
}

void reverse (node *list) {
if (list == 0) return;
reverse_recursively(list, list->next, make_node(0, list->data));
}
``````
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Yes, that is a solution. Could we do it without storing the elements? –  Jack Jul 23 '13 at 21:18
Recursion is allowed. But storing the elements in an array isn't. (I know I am being very specific. It's just that I am preparing for an interview.) :) –  Jack Jul 23 '13 at 21:27
Can recursion be used to solve this? –  Jack Jul 23 '13 at 21:28
@Jack: Recursion is just an iteration mechanism with an implicit auxiliary storage area (the local activation record at each recursive function call). Try to implement the recursive solution. If it doesn't work and you don't know why, post that question instead of this one. –  jxh Jul 23 '13 at 21:29
Nice work on the recursive function without locals... but is not adding an extra function call and parameters just really cloaking local variables as parameters instead? –  James Morris Jul 24 '13 at 21:41

Today at work I kept coming back to this question trying to make sense of it. I found your restrictions somewhat baffling, hence the 'have you tried magic?' comment. Eventually I got over the block...

It might help to visualize the problem. Let's start with the ideas in Julio Moreno's code, somewhat simplified: step through the list and swap each node data with the tail data.

``````A B C D E
E B C D A
E A C D B
E A B D C
E A B C D

E D B C A
E D A C B
E D A B C

E D C B A
``````

(At work I concluded the process wouldn't work out, but now I have more time I can see it does). If we then take a closer look at his function we can see that on top of this, it also works recursively. I am not keen to visualize a recursive function called from a for loop. This process is clearly not going to win any prizes for efficiency.

So then let's look at what we could do if we didn't want to restrict ourselves to not modifying the node positions:

``````A B C D E
B C D E A
C D E B A
D E C B A
E D C B A
``````

Here we take tail node E, and remember it. We now take node A and insert it after E, then B and insert it again after E but before A, stepping through the entire list inserting immediately after E until E is the first node (head) of the list. It works, but we're not allowed to do it.

Let's take the pretense one step further and pretend it's a doubly linked list, we maintain two pointers, one at the start of the list, and one at the end, and we swap the data of both and then increment the one and decrement the other, respectively.

``````A B C D E
E B C D A
E D C B A
``````

So how could we do that with a single-linked list? What do we need to know? How can we step backwards while simultaneously stepping forward?

Let's start with how we could get the last node by stepping through the entire list.

``````A B C D E F G H
``````

And swap them:

``````H B C D E F G A
``````

and then if we remember both the nodes we swapped the data of, we can start at B and step along until node->next points to the node now holding data A.

``````B C D E F G
``````

and swap them:

``````G C D E F B
F D E C
E D
``````

However I'm still uncomfortable with the idea of repeatedly stepping through the list - even if the range of the stepping shrinks on each iteration of the process. What if we had a LIFO (last-in-first-out) or stack as it's otherwise known?

``````A B C D E F G H
B C D E F G H ... A
C D E F G H ... B
D E F G H ... C
E F G H ... D
F G H ... E
G H ... F
H ... G...F...E...D...C...B...A
``````

But that's auxiliary data storage and we're not allowed that, but it's not too difficult to see how a LIFO could be implemented with recursive function calls and a linked list. So how could we step forwards and backwards with a recursive function call and a linked list? Don't we need an extra parameter? When we get to the end of the list, we still need to know how it begins.

``````A B C D E F G H
A,B             ^ return 0
A,C           ^ return 0
A,D         ^ return 0
A,E       ^ swap D E done, return 0
A,F     ^ swap C F return D
A,G   ^ swap B G return C
A,H ^ swap A H return B
``````

I've not actually tested this yet to prove it so it could be wrong. I'll go test it now and if requested may post the code. Hopefully I won't have to edit this post to say it doesn't work ;-)

EDIT: Can confirm it works.

``````static lnode* list_private_reverse(lnode* list, lnode* node)
{
lnode* next = node->next;

if (next)
{
lnode* swap = list_private_reverse(list, next);

if (swap)
{
int c = swap->c;

swap->c = node->c;
node->c = c;

if (swap->next == node || swap->next->next == node)
return 0;

return swap->next;
}
return 0;
}
else
{
int c = node->c;
node->c = list->c;
list->c = c;
}

return list->next;
}

lnode* list_reverse(lnode* list)
{
list_private_reverse(list, list);
return list;
}
``````

`list_private_reverse` is called only as many times as there are elements in the list.

-
+1 for analysis of an algorithm –  jxh Jul 24 '13 at 21:50
I couldn't have got a better explaination. Thanks a ton! :) –  Jack Jul 27 '13 at 0:08

Something like this would work, the first function doesn't actually switches (sorry for the confusing name), it works much like an insertion algorithm, it takes the list's last element and inserts it into "current" position. I have serious doubts about the efficiency of this algorithm:

``````    typedef struct node node;
struct node {
node *next;
void *value;
};

node *switch_with_end(node *c)
{
if (c->next) {
node *t = switch_with_end(c->next);
void *temp = t->value;
t->value = c->value;
c->value = temp;
}
return c;
}

{
node *c;
for (c = l; c->next; c = c->next)
switch_with_end(c);
}
``````
-

@ames Morris -- very nicely explained. But well what would be the difference between your and mine code ...

Uses 2 pointers at max ...

``````Node* reverseLL (Node *curr, Node *prev)
{
Node *nxt = NULL;
if (curr)
{
nxt = curr->next;
curr->next = prev;
curr = reverseLL (nxt, curr);
}
else
return prev;
}

{
Node *prev = NULL;
curr = reverseLL (curr, prev);