# Algorithm to find duplicates in multiple linked lists

What is the fastest method of finding duplicates across multiple (large) linked lists. I will attempt to illustrate the problem with arrays instead just to make it a bit more readable. (I used numbers from 0-9 for simplicity instead of pointers).

``````list1[] = {1,2,3,4,5,6,7,8,9,0};
list2[] = {0,2,3,4,5,6,7,8,9,1};
list3[] = {4,5,6,7,8,9,0,1,2,3};
list4[] = {8,2,5};
list5[] = {1,1,2,2,3,3,4,4,5,5};
``````

If I now ask: 'does the number 8 exist in list1-5?' I could sort the lists, remove duplicates, repeat this for all lists and merge them into a "superlist" and see if the number of (new) duplicates equal the number of lists that I search through. Assuming that I got the correct number of duplicates I can assume that what I searched for (8) exists in all of the lists. If I instead searched for 1 I will only get four duplicates—ergo not found in all of the lists.

Is there a faster/smarter/better way to achieve the above without sorting and/or changing the lists in any way?

P.S.: This question is asked mostly out of pure curiosity and nothing else! :)

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Why wouldn't you just traverse all lists and search for 8 instead of that sorting/removing duplicates story? –  Klark May 9 '11 at 22:13
@Klark I think he knows the cost for any one query is O(n), using that trivial algorithm, and wants to amortize the cost over multiple queries. @Waxhead I think you're best off re-representing the data by placing it in a tree, hash table, or counting bloom filter. –  Thomas M. DuBuisson May 10 '11 at 19:05

Define an array `hash` and set all the location values to 0

``````define hash[MAX_SYMBOLS] = {0};
define new_list[LENGTH]
defile list[LENGTH] and populate
``````

Now for each element in your `list`, use this number as an index in `hash` and increment that location of `hash` . Each presence of that number would increment the value at that `hash` location once. So a duplicate value `i` would have `hash[i] > 1`

``````for i=0 to (n - 1)
do
increment hash[list[i]]
endfor
``````

If you want to remove the duplicates and create a new list then scan the `hash` array and for each presence of `i` ie. if `hash[i] > 0` load them into a new list in the order in which they appeared in the original list.

``````define j = 0
for i=0 to (n - 1)
do
if hash[list[i]] is not 0
then
new_list[j] := i
increment j
endif
endfor
``````

Note that when using with negative numbers you will not be able to use the values directly to index. To use negative numbers, first we can find the largest magnitude of the negative numbers and use that magnitude to add to all the numbers when we use them to index the `hash` array.

``````find the highest magnitude of negative value into min_neg

for i=0 to (n - 1)
do
increment hash[list[i + min_neg]]
endfor
``````

Or in implementation you can allocate contiguous memory and then define a pointer at the middle of the allocated memory block, so that you could move in both front and back directions so that you can use negative index with it. You need to make sure that you have enough memory to use in front and back of the pointer.

``````int *hash = malloc (sizeof (int) * SYMBOLS)
int *hash_ptr = hash + (int)(SYMBOLS/2)
``````

now you can do `hash_ptr[-6]` or some `hash_ptr[i]` with `-SYMBOLS/2 < i < SUMBOLS/2 + 1`

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Just put each number into a hash table and store the number of occurrences for that item in the table. When you find another, just increment the counter. O(n) algorithm (n items across all the lists).

If you want to store the lists that each occurs in, then you need a set representation to be stored under each item as well. YOu can use any set representation -- bit vector, list, array etc. This will tell you the lists that that item is a member of. This does not change it from O(n), just increases the work by a constant factor.

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The question is a bit vague, so the answer depends on what you want.

A hash table is the correct answer for asking general questions about duplicates, because it allows you to go through each list just once to build a table that will answer most questions; however, some questions will not require one.