They are four possible ways to achieve this, each of which having its own merits.

## Recursion

```
void print_list(node* traverse)
{
if (traverse == NULL) return;
print_list(traverse->next);
std::cout << traverse->data << std::endl;
}
```

This is maybe the first answer to come in mind. However, the process stack size is limited, so recursion has a pretty low limit. A big list will provoke a stack overflow. This is not a very good design in C++.

## Iteration

```
void print_list(node *n)
{
using namespace std;
deque<node*> res;
for(;n != NULL; n = n->next) res.push_back(n);
for_each(res.rbegin(), res.rend(), [](node* n){cout << n->data << endl;});
}
```

Of course, if you want to make it the iterative way, you will need to stack the node pointers yourself (on the process heap) and not delegate this job to the *call stack*. This method lets you print far bigger lists, and is O(n) in computations. It is, however O(n) in memory usage, but you already have a list which use O(n) memory. So this should not be an issue. However, you may really need to avoid memory consumption. Which brings us to the next idea.

## Double iteration

```
void print_list(node *head)
{
node* last = NULL;
while(last != head)
{
node* current = head;
while(current->next != last)
current = current->next;
std::cout << current->data << std::endl;
last = current;
}
}
```

This may seem a dumb solution, as it has O(n^2) complexity, but that is computation-complexity. It has O(1) memory complexity and, depending on the actual context and exact problem, it may be the answer you need. But this O(n^2) complexity is a lot to pay. Especially if n is so big you wanted to avoid another O(n) allocation. Which brings us to the last idea.

## Hack the container

```
void print_list(node *head)
{
node* last = NULL;
for(node* next; head != NULL; head = next)
{
next = head->next;
head->next = last;
last = head;
}
for(node* next; last != NULL; last = next)
{
next = last->next;
last->next = head;
head = last;
cout << last->data << endl;
}
}
```

You first modify the container, then iterate in your new order. On a single-linked list, you can just reverse the links, then reverse-iterate while reversing the links again. The beauty of it is it stays O(n) in computing, and O(1) in memory. The problem is that you invalidate the full container while doing this : your outputing operation does not leave the list constant : this is not exception-safe: if your operation fails in middle of iteration, the list is not valid anymore. This may or may not be an issue depending on the problem.