I need to sort a doubly-linked list. According to the almighty wikipedia, mergesort is the way to go for that.

The recursive algorithm works reasonably well, but as I'm writing a general-purpose implementation, performance might be an issue.

Porting the iterative version for arrays will kill performance as rescanning the list to divide it into sublists is slow; for anyone interested - here's the code:

```
static void sort(struct linked_list *list,
int (*cmp)(const void *, const void *))
{
size_t slice_size = 1;
for(; slice_size < list->size; slice_size *= 2)
{
struct node *tail = list->first;
while(tail)
{
struct node *head = tail;
size_t count = slice_size;
while(tail && count--) // performance killer
tail = tail->next;
count = slice_size;
while(head != tail && tail && count)
{
if(cmp(head->data, tail->data) <= 0)
head = head->next;
else
{
struct node *node = tail;
tail = tail->next;
remove_node(node, list);
insert_before(node, list, head);
--count;
}
}
while(tail && count--) // performance killer
tail = tail->next;
}
}
}
```

But there's another iterative version using a stack-based approach:

```
struct slice
{
struct node *head;
size_t size;
};
static void sort(struct linked_list *list,
int (*cmp)(const void *, const void *))
{
if(list->size < 2) return;
struct slice stack[32];
size_t top = -1;
struct node *current = list->first;
for(; current; current = current->next)
{
stack[++top] = (struct slice){ current, 1 };
for(; top && stack[top-1].size <= stack[top].size; --top)
merge_down(list, cmp, stack + top);
}
for(; top; --top)
merge_down(list, cmp, stack + top);
}
```

This will push size 1 lists onto the stack and merges down as long as the top list is of greater or equal size than its predecessor.

Unfortunately, there's a bug somewhere as for some input lists, `merge_down()`

will fail a sanity check:

```
static void merge_down(struct linked_list *list,
int (*cmp)(const void *, const void *), struct slice *top)
{
struct node *right = top->head;
size_t count = top->size;
--top;
struct node *left = top->head;
top->size += count;
{
// sanity check: count nodes in right list
int i = count;
struct node *node = right;
for(; i--; node = node->next) if(!node)
{
puts("too few right nodes");
exit(0);
}
}
// determine merged list's head
if(cmp(left->data, right->data) <= 0)
{
top->head = left;
left = left->next;
}
else
{
top->head = right;
struct node *node = right;
right = right->next;
remove_node(node, list);
insert_before(node, list, left);
--count;
}
while(left != right && count)
{
if(cmp(left->data, right->data) <= 0)
left = left->next;
else
{
struct node *node = right;
right = right->next;
remove_node(node, list);
insert_before(node, list, left);
--count;
}
}
}
```

The linked list implementation might be relevant as well:

```
struct node
{
struct node *prev;
struct node *next;
long long data[]; // use `long long` for alignment
};
struct linked_list
{
struct _list _list; // ignore
size_t size;
struct node *first;
struct node *last;
};
static void insert_before(struct node *node, struct linked_list *list,
struct node *ref_node)
{
if(ref_node)
{
node->next = ref_node;
node->prev = ref_node->prev;
if(ref_node->prev) ref_node->prev->next = node;
else list->first = node;
ref_node->prev = node;
}
else // empty list
{
node->next = NULL;
node->prev = NULL;
list->first = node;
list->last = node;
}
++list->size;
}
static void remove_node(struct node *node, struct linked_list *list)
{
if(node->prev) node->prev->next = node->next;
else list->first = node->next;
if(node->next) node->next->prev = node->prev;
else list->last = node->prev;
--list->size;
}
```

What am I missing here?