One method which I can think of is to reverse the list and then read it. But this involves changing the list which is bad.
OR I can make a copy of the list and then reverse it, but this uses additional O(n) memory. Is there any better method which doesn't use extra memory and doesn't modify the list and runs in O(n) time

reverse linked list code is something like this in c#

{
Node prev= null;
Node nextNode = null;

while (current!=null)
{
nextNode = current.Next;
current.Next = prev;
prev=current;
current = nextNode;

}

}

Recursive solution is

{
if (n==null)
return;
else

Console.WriteLine(n.Data);

}
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Recursion is your friend –  anon Jul 12 '09 at 19:38
@Neil: Can you suggest some pseudo code using recursion –  Learner Jul 12 '09 at 19:42
But recursion uses O(n) memory –  Nathan Fellman Jul 12 '09 at 20:19
From below answers we can solve this in O(n) time only if we use O(n) extra memory. See answers below.... Thanks guys for all the help....SO is really awesome and you guys rock !!!.... –  Learner Jul 12 '09 at 20:21
Neil: Check my recursive implementation –  Learner Jul 12 '09 at 21:22

To use O(n) memory and O(n) performance, create a stack; push everything on as you iterate in the forwards direction, then pop everything off, yielding the results.

To use O(n^2) performance (but O(1) extra memory), read it forwards each time, up the the node before the last one you got to.

Example:

Stack<Node> nodes = new Stack<Node>();
}
while(nodes.Count > 0) {
yield return nodes.Pop().Value;
}
}
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This is equivalent to creating a reversed copy of the list. –  sanity Jul 12 '09 at 19:43
this is a better solution, but it uses same O(n) memory, which is same as having a copy of list and reversing it and reading it –  Learner Jul 12 '09 at 19:45
Not necessarily. You only have to push the pointers onto the stack, not the entire items. –  rein Jul 12 '09 at 19:46
This is fundamentally identical to recursion. The only difference is an explicit stack vs. recursion's implicit stack. –  Greg D Jul 12 '09 at 19:55
With recursion you also typically need to push additional state representing the call position. Using an explicit stack is generally more efficient. –  Marc Gravell Jul 12 '09 at 20:04

One of the hallmarks of a singly-linked list is that it is, in fact, singly linked. It is a one-way street, and there's no way to overcome that unless you turn it into something else (such as a reversed singly-linked list, a stack, a doubly-linked list...). One must be true to the nature of things.

As has been pointed out earlier; if you need to traverse a list both ways; you need to have a doubly-linked list. That is the nature of a doubly linked list, it goes both ways.

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+1 sigh. Why is simplicity, which is championed by those who built SO, so verily ignored? –  Chris Kaminski Jul 21 '09 at 17:28

Really you should be using a doubly-linked list.

If this isn't possible, I think your best option will be to construct a copy of the list that has been reversed.

Other options, such as relying on recursion (effectively copying the list to the stack) could cause you to run out of stack space if the list is too long.

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See tag - "interview-questions" :) –  Lucas Jones Jul 12 '09 at 19:43
I think changing the list to a doubly linked list is less bad that coming up with other mechanisms to fix the issue. –  RichardOD Jul 12 '09 at 20:22

If you short of memory you can reverse list, iterate over it and reverse it again. Alternatively you can make a stack of pointers to nodes (or whatever is like a pointer in C#).

-
{

// Reverse the link list O(n) time O(1) space
while(cur){
}

// Print the list O(n) time O(1) space
while(cur) {
printf(" %d", cur->val);
cur = cur->next;
}

// Reverse the link list again O(n) time O(1) space
while(cur){
}
// Total complexity O(n) time O(1) space
}
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best algo for reverse printing, saves time and space –  Prashant Singh Dec 11 '11 at 10:36

There is a third solution, this time using O(log(n)) memory and O(n log(n)) time, thus occupying the middle ground between the two solutions in Marc's answer.

It is effectively a reverse in-order descent of a binary tree [O(log(n))], except at each step you need to find the top of the tree [O(n)]:

1. Split the list in two
2. Recurse into the second half of the list
3. Print the value at the midpoint
4. Recurse into the first half

Here is the solution in Python (I don't know C#):

while pos is not tail and pos.next is not tail:
pos, mid = pos.next.next, mid.next
return mid

printReversed(mid.next, tail)
print mid.value,

This could be recast using iteration instead of recursion, but at the cost of clarity.

For example, for a million-entry list, the three solutions take on the order of:

Solution   Memory       Performance
=========================================
Marc #1     4MB    1 million operations
Mine       80B    20 million operations
Marc #2      4B    1 trillion operations
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@chrispy: A tree with n nodes needs O(n) memory and not O(log n) as you have mentioned. Did I understand something wrong? –  Lazer Apr 3 '10 at 2:32
@eSKay The code is traversing the list as if there was an associated tree, not actually creating the tree in memory –  chrispy Apr 7 '10 at 13:51
@Lazer: Ignore the word "tree", and think in terms of divide-and-conquer: if you keep track of the halfway point, you can process the second half of the list just as efficiently as the first half. In processing the first second of the list, if you keep track of the 3/4 point, you can process the four quarter as quickly as the third quarter. Then when processing the first half, keep the 1/4 point so you can process the second quarter as efficiently as the first. –  supercat Feb 5 '11 at 21:27

Assuming your singly-linked list implements IEnumerable<T>, you can utilize LINQ's Reverse extension method:

You'll need to add a using System.Linq; directive at the top of the code file to use LINQ's extension methods.

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... Which is exactly what the OP suggested but wanted a better solution than. Just because you don't allocate the extra memory yourself does not mean it doesn't happen. –  erikkallen Nov 4 '09 at 22:37
Reverse is lazily-loaded, executed when the items are requested. It's not the same as the OP. –  Judah Himango Nov 4 '09 at 23:22

A variation of creating a stack and pushing all the elements onto the stack is to use recursion (and the system's built in stack), this is probably not the way to go with production code but serves as a better (IMHO) interview answer for the following reasons:

1. It shows that you grok recursion
2. It's less code and appears more elegant
3. A naive interviewer may not realize that there is a space overhead (if this is the case you may want to consider whether you want to work there).
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I like item #3. :) –  Mike Eshva Sep 24 '12 at 12:56

Well, the naive solution would be to keep track of which node you're currently at, then iterate from the start until you find that node, always saving the node you just left. Then each time you find the node you're currently at, you produce the node you just left, save that node as the one you're currently at, then re-iterate from the start.

This would of course be horribly bad performance-wise.

I'm sure some smarter people have a better solution.

Pseudo-code (with bugs even):

current node = nothing
while current node is not first node
node = start
while node is not current node
previous node = node
node = next node
produce previous node
set current node to previous node
-

you could read it in O(n^2) -- every time go to the last node read and print out the previous one

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This is messy but works:

int pos;
this.pos = pos;
}
if (startNode == this) return null;
if (startNode.next == this)	return startNode;
else return previous(startNode.next);
}

static int count = 0;
public static void main (String [] args) {
init();

System.out.println("Tail: " + tail.pos);

System.out.print("List forwards: ");
while (list != null) {
System.out.print(list.pos + ",");
list = list.next;
}

list = tail;
System.out.print("\nList backwards: ");
System.out.print(list.pos + ",");
}
}
static void init() {
while (count < 100) {
list = list.next;
}
tail = list;
}

}

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What's wrong with: