This question may be old, but I couldn't think of an answer.
Say, there are two lists of different lengths, merging at a point; how do we know where the merging point is?
Conditions:
 We don't know the length
 We should parse each list only once.
This question may be old, but I couldn't think of an answer.
Say, there are two lists of different lengths, merging at a point; how do we know where the merging point is?
Conditions:
If
the following algorithm would be the solution.
First, the numbers. Assume the first list is of length a+c
and the second one is of length b+c
, where c
is the length of their common "tail" (after the mergepoint). Let's denote them as follows:
x = a+c
y = b+c
Since we don't know the length, we will calculate x
and y
without additional iterations; you'll see how.
Then, we iterate each list and reverse them while iterating! If both iterators reach the merge point at the same time, then we find it out by mere comparing. Otherwise, one pointer will reach the merge point before the other one.
After that, when the other iterator reaches the merge point, it won't proceed to the common tail. Instead will go back to the former beginning of the list that had reached mergepoint before! So, before it reaches the end of the changed list (i.e. the former beginning of the other list), he will make a+b+1
iterations total. Let's call it z+1
.
The pointer that reached the mergepoint first, will keep iterating, until reaches the end of the list. The number of iterations it made should be calculated and is equal to x
.
Then, this pointer iterates back and reverses the lists again. But now it won't go back to the beginning of the list it originally started from! Instead, it will go to the beginning of the other list! The number of iterations it made should be calculated and equal to y
.
So we know the following numbers:
x = a+c
y = b+c
z = a+b
From which we determine that
a = (+xy+z)/2
b = (x+y+z)/2
c = (+x+yz)/2
Which solves the problem.
The following is by far the greatest of all I have seen  O(N), no counters. I got it during an interview to a candidate S.N. at VisionMap.
Make an interating pointer like this: it goes forward every time till the end, and then jumps to the beginning of the opposite list, and so on. Create two of these, pointing to two heads. Advance each of the pointers by 1 every time, until they meet. This will happen after either one or two passes.
I still use this question in the interviews  but to see how long it takes someone to understand why this solution works.
Pavel's answer requires modification of the lists as well as iterating each list twice.
Here's a solution that only requires iterating each list twice (the first time to calculate their length; if the length is given you only need to iterate once).
The idea is to ignore the starting entries of the longer list (merge point can't be there), so that the two pointers are an equal distance from the end of the list. Then move them forwards until they merge.
lenA = count(listA) //iterates list A
lenB = count(listB) //iterates list B
ptrA = listA
ptrB = listB
//now we adjust either ptrA or ptrB so that they are equally far from the end
while(lenA > lenB):
ptrA = ptrA>next
lenA
while(lenB > lenA):
prtB = ptrB>next
lenB
while(ptrA != NULL):
if (ptrA == ptrB):
return ptrA //found merge point
ptrA = ptrA>next
ptrB = ptrB>next
This is asymptotically the same (linear time) as my other answer but probably has smaller constants, so is probably faster. But I think my other answer is cooler.
Well, if you know that they will merge:
Say you start with:
A>B>C

V
1>2>3>4>5
1) Go through the first list setting each next pointer to NULL.
Now you have:
A B C
1>2>3 4 5
2) Now go through the second list and wait until you see a NULL, that is your merge point.
If you can't be sure that they merge you can use a sentinel value for the pointer value, but that isn't as elegant.
If we could iterate lists exactly twice, than I can provide method for determining merge point:
Here's a solution, computationally quick (iterates each list once) but uses a lot of memory:
for each item in list a
push pointer to item onto stack_a
for each item in list b
push pointer to item onto stack_b
while (stack_a top == stack_b top) // where top is the item to be popped next
pop stack_a
pop stack_b
// values at the top of each stack are the items prior to the merged item
This arguably violates the "parse each list only once" condition, but implement the tortoise and hare algorithm (used to find the merge point and cycle length of a cyclic list) so you start at List A, and when you reach the NULL at the end you pretend it's a pointer to the beginning of list B, thus creating the appearance of a cyclic list. The algorithm will then tell you exactly how far down List A the merge is (the variable 'mu' according to the Wikipedia description).
Also, the "lambda" value tells you the length of list B, and if you want, you can work out the length of list A during the algorithm (when you redirect the NULL link).
You can use a set of Nodes. Iterate through one list and add each Node to the set. Then iterate through the second list and for every iteration, check if the Node exists in the set. If it does, you've found your merge point :)
Maybe I am over simplifying this, but simply iterate the smallest list and use the last nodes Link
as the merging point?
So, where Data>Link>Link == NULL
is the end point, giving Data>Link
as the merging point (at the end of the list).
EDIT:
Okay, from the picture you posted, you parse the two lists, the smallest first. With the smallest list you can maintain the references to the following node. Now, when you parse the second list you do a comparison on the reference to find where Reference [i] is the reference at LinkedList[i]>Link. This will give the merge point. Time to explain with pictures (superimpose the values on the picture the OP).
You have a linked list (references shown below):
A>B>C>D>E
You have a second linked list:
1>2>
With the merged list, the references would then go as follows:
1>2>D>E>
Therefore, you map the first "smaller" list (as the merged list, which is what we are counting has a length of 4 and the main list 5)
Loop through the first list, maintain a reference of references.
The list will contain the following references Pointers { 1, 2, D, E }
.
We now go through the second list:
> A  Contains reference in Pointers? No, move on
> B  Contains reference in Pointers? No, move on
> C  Contains reference in Pointers? No, move on
> D  Contains reference in Pointers? Yes, merge point found, break.
Sure, you maintain a new list of pointers, but thats not outside the specification. However the first list is parsed exactly once, and the second list will only be fully parsed if there is no merge point. Otherwise, it will end sooner (at the merge point).
I have tested a merge case on my FC9 x86_64, and print every node address as shown below:
Head A 0x7fffb2f3c4b0
0x214f010
0x214f030
0x214f050
0x214f070
0x214f090
0x214f0f0
0x214f110
0x214f130
0x214f150
0x214f170
Head B 0x7fffb2f3c4a0
0x214f0b0
0x214f0d0
0x214f0f0
0x214f110
0x214f130
0x214f150
0x214f170
Note becase I had aligned the node structure, so when malloc() a node, the address is aligned w/ 16 bytes, see the least 4 bits. The least bits are 0s, i.e., 0x0 or 000b. So if your are in the same special case (aligned node address) too, you can use these least 4 bits. For example when travel both lists from head to tail, set 1 or 2 of the 4 bits of the visiting node address, that is, set a flag;
next_node = node>next;
node = (struct node*)((unsigned long)node  0x1UL);
Note above flags won't affect the real node address but only your SAVED node pointer value.
Once found somebody had set the flag bit(s), then the first found node should be the merge point. after done, you'd restore the node address by clear the flag bits you had set. while an important thing is that you should be careful when iterate (e.g. node = node>next) to do clean. remember you had set flag bits, so do this way
real_node = (struct node*)((unsigned long)node) & ~0x1UL);
real_node = real_node>next;
node = real_node;
Because this proposal will restore the modified node addresses, it could be considered as "no modification".
this solution iterates each list only once...no modification of list required too..though you may complain about space..
1) Basically you iterate in list1 and store the address of each node in an array(which stores unsigned int value)
2) Then you iterate list2, and for each node's address > you search through the array that you find a match or not...if you do then this is the merging node
//pseudocode
//for the first list
p1=list1;
unsigned int addr[];//to store addresses
i=0;
while(p1!=null){
addr[i]=&p1;
p1=p1>next;
}
int len=sizeof(addr)/sizeof(int);//calculates length of array addr
//for the second list
p2=list2;
while(p2!=null){
if(search(addr[],len,&p2)==1)//match found
{
//this is the merging node
return (p2);
}
p2=p2>next;
}
int search(addr,len,p2){
i=0;
while(i<len){
if(addr[i]==p2)
return 1;
i++;
}
return 0;
}
Hope it is a valid solution...
There can be a simple solution but will require an auxilary space. The idea is to traverse a list and store each address in a hash map, now traverse the other list and match if the address lies in the hash map or not. Each list is traversed only once. There's no modification to any list. Length is still unknown. Auxiliary space used: O(n) where 'n' is the length of first list traversed.
There is no need to modify any list. There is a solution in which we only have to traverse each list once.
Here is naive solution , No neeed to traverse whole lists.
if your structured node has three fields like
struct node {
int data;
int flag; //initially set the flag to zero for all nodes
struct node *next;
};
say you have two heads (head1 and head2) pointing to head of two lists.
Traverse both the list at same pace and put the flag =1(visited flag) for that node ,
if (node>next>field==1)//possibly longer list will have this opportunity
//this will be your required node.
How about this:
If you are only allowed to traverse each list only once, you can create a new node, traverse the first list to have every node point to this new node, and traverse the second list to see if any node is pointing to your new node (that's your merge point). If the second traversal doesn't lead to your new node then the original lists don't have a merge point.
If you are allowed to traverse the lists more than once, then you can traverse each list to find our their lengths and if they are different, omit the "extra" nodes at the beginning of the longer list. Then just traverse both lists one step at a time and find the first merging node.
Steps in Java:
We can efficiently solve it by introducing "isVisited" field. Traverse first list and set "isVisited" value to "true" for all nodes till end. Now start from second and find first node where flag is true and Boom ,its your merging point.
Step 1: find lenght of both the list Step 2 : Find the diff and move the biggest list with the difference Step 3 : Now both list will be in similar position. Step 4 : Iterate through list to find the merge point
//Psuedocode
def findmergepoint(list1, list2):
lendiff = list1.length() > list2.length() : list1.length()  list2.length() ? list2.lenght()list1.lenght()
biggerlist = list1.length() > list2.length() : list1 ? list2 # list with biggest length
smallerlist = list1.length() < list2.length() : list2 ? list1 # list with smallest length
# move the biggest length to the diff position to level both the list at the same position
for i in range(0,lendiff1):
biggerlist = biggerlist.next
#Looped only once.
while ( biggerlist is not None and smallerlist is not None ):
if biggerlist == smallerlist :
return biggerlist #point of intersection
return None // No intersection found
int FindMergeNode(Node *headA, Node *headB)
{
Node *tempB=new Node;
tempB=headB;
while(headA>next!=NULL)
{
while(tempB>next!=NULL)
{
if(tempB==headA)
return tempB>data;
tempB=tempB>next;
}
headA=headA>next;
tempB=headB;
}
return headA>data;
}
Use Map or Dictionary to store the addressess vs value of node. if the address alread exists in the Map/Dictionary then the value of the key is the answer. I did this:
int FindMergeNode(Node headA, Node headB) {
Map<Object, Integer> map = new HashMap<Object, Integer>();
while(headA != null  headB != null)
{
if(headA != null && map.containsKey(headA.next))
{
return map.get(headA.next);
}
if(headA != null && headA.next != null)
{
map.put(headA.next, headA.next.data);
headA = headA.next;
}
if(headB != null && map.containsKey(headB.next))
{
return map.get(headB.next);
}
if(headB != null && headB.next != null)
{
map.put(headB.next, headB.next.data);
headB = headB.next;
}
}
return 0;
}
A O(n) complexity solution. But based on an assumption.
assumption is: both nodes are having only positive integers.
logic : make all the integer of list1 to negative. Then walk through the list2, till you get a negative integer. Once found => take it, change the sign back to positive and return.
static int findMergeNode(SinglyLinkedListNode head1, SinglyLinkedListNode head2) {
SinglyLinkedListNode current = head1; //head1 is give to be not null.
//mark all head1 nodes as negative
while(true){
current.data = current.data;
current = current.next;
if(current==null) break;
}
current=head2; //given as not null
while(true){
if(current.data<0) return current.data;
current = current.next;
}
}
This is a real problem! If we have a tree structure in sql database. We want to find the LCA in a SQL trigger.
In trigger environment we cannot create temporary table because it will implicitly commit transaction. So we have to do it in O(1) memory, i.e. we can only use variable.