# (Algorithm) Find if two unsorted arrays have any common elements in O(n) time without sorting?

We have two unsorted arrays and each array has a length of n. These arrays contain random integers in the range of 0-n100. How to find if these two arrays have any common elements in O(n)/linear time? Sorting is not allowed.

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Smells like homework. If it is, mark it as such. –  Andrew Sledge Dec 28 '10 at 16:19
So the answer is just yes/no, yes if they have any elements in common, no otherwise? –  GregS Dec 28 '10 at 16:20
How about storage? O(n)? –  GregS Dec 28 '10 at 16:23
Storage is not important. And you are right, this is a yes/no question. –  Omerta Dec 28 '10 at 16:40
IMO, The current accepted answer by meriton is useless. (Apologies to meriton). –  Aryabhatta Dec 31 '10 at 23:57

You have not defined the model of computation. Assuming you can only read O(1) bits in O(1) time (anything else would be a rather exotic model of computation), there can be no algorithm solving the problem in O(n) worst case time complexity.

Proof Sketch: Each number in the input takes O(log(n ^ 100)) = O(100 log n) = O(log n) bits. The entire input therefore O(n log n) bits, which can not be read in O(n) time. Any O(n) algorithm can therefore not read the entire input, and hence not react if these bits matter.

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+1, seems right to me. –  GregS Dec 28 '10 at 17:15
This question can be solved in O(n) time using radix sort or similar sorting algorithms. But the problem here is that sorting is not allowed. –  Omerta Dec 28 '10 at 17:46
@Omerta: It cannot be solved in O(n) worst case even with radix sorting unless you use some unusual computational model. –  GregS Dec 28 '10 at 17:53
Radix sort is O(kn) where n is the count of numbers, and k the length of the numbers. If k is constant, that is O(n), but k is O(log n) here ... –  meriton Dec 28 '10 at 17:54
-1: This is defeating the spirit of the question. Besides, Word RAM Model is not that exotic. In fact, most algorithm time complexity analyses implicitly use that when unspecified: O(1) time array accesses, O(1) addition of two integers which fit in a register etc. –  Aryabhatta Dec 30 '10 at 8:09

Hashtable will save you. Really, it's like a swiss knife for algorithms.
Just put in it all values from the first array and then check if any value from the second array is present.

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Using hashtable is O(nlog n). –  Neil Dec 28 '10 at 16:26
@Neil: Searches are usually O(1), building is O(n). –  GregS Dec 28 '10 at 16:27
While this is a good aproach in practice, it doesn't achieve O(n) worst case performance. First because a hashtable lookup is O(n) in the worst case (bad hash function, and for every hash function, there is an input with many hash collisions), and second because you implicitly assume the hash function can be computed in constant time, even though the number of bits used to hold an number is not constant. –  meriton Dec 28 '10 at 16:30
@Neil It is O(1), with provided conditions. There's a simple proof: en.wikipedia.org/wiki/Hashtable#Performance_analysis Not to mention, hashtables have nothing to do with logarithms in general. –  Nikita Rybak Dec 28 '10 at 16:37
@Nikita: Each entry is at most n^100, which can be stored I think with 100*log(n) storage. So I guess the storage is O(n log n). This is my third answer on this, so nobody should trust it. –  GregS Dec 28 '10 at 16:39

Answering Neil: Since you know at start what is your N (two arrays of size N), you can create a hash with array size of 2*N*some_ratio (for example: some_ratio= 1.5). With this size, almost all simple hash functions will provide you good spread of the entities.

You can also implement find_or_insert to search for existing or insert a new one at the same action, this will reduce the hash function and comparison calls. (c++ stl find_or_insert is not good enough since it doesnt tell you whether the item was there before or not).

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Neil - your answer is wrong. There are N elements, but their value is in much larger range (Original question said: 0 to N^100, in most cases it will be the full range of 32 or 64 bit values...) –  Guy Nir Dec 28 '10 at 16:55
He said storage wasn't an issue. Hashtable is a compromise between storage and speed of access. Why should I compromise storage if I don't have to? –  Neil Dec 28 '10 at 17:13
If the values range can fit into RAM memory - then yes, your approach is good, but 32 bit range is 4G range which is considered very large, even today. (4GB Ram are not enough since you need extra memory, so not every computer can run this on RAM). If you take 64 bit range - no doubt you will never have enough memory. –  Guy Nir Dec 28 '10 at 18:07

Put the elements of the first array in an hash table, and check for existence scanning the second array. This gives you a solution in O(N) average case.

If you want a truly O(N) worst case solution then instead of using an hash table use a linear array in the range 0-n^100. Note that you need to use just a single bit per entry.

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Not wrong, but it takes O(n log n) just to initialize the array. –  GregS Dec 28 '10 at 17:16
How would you initialize that array of size O(n^100) in O(n) time? Your algorithm assumes that all bits in the array are initially 0. –  meriton Dec 28 '10 at 17:18
@GregS: in our theoretical model memory accesses should be O(1), the same for allocations on the heap: O(1) amortized time. So initializing the array with all zeros should just take O(N) time. –  antirez Dec 28 '10 at 17:18
Sorry there was a misunderstanding here. When I say O(N), N is not the n^100 stuff, but with N being the number of elements in the range 0-n^100. Sorry for the imprecision. Now that I look at this the original poster question looks a bit stranger... –  antirez Dec 28 '10 at 17:20
@antirez: What theoretical memory model? None was provided. –  GregS Dec 28 '10 at 17:22

Linearity Test

Using Mathematica hash function and arbitrary length integers.

Tested until n=2^20, generating random numbers till (2^20)^100 = (approx 10^602)

Just in case ... the program is:

k = {};
For[t = 1, t < 21, t++,
i = 2^t;
Clear[a, b];
Table[a[RandomInteger[i^100]] = 1, {i}];
b = Table[RandomInteger[i^100], {i}];
Contains = False;
AppendTo[k,
{i, First@Timing@For[j = 2, j <= i, j++,
Contains = Contains || (NumericQ[a[b[[j]]]]);
]}]];
ListLinePlot[k, PlotRange -> All, AxesLabel -> {"n", "Time(secs)"}]

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Hehe, man shows up with a graph and the room gets quiet. Well we knew that the hash table had linear average case performance. –  GregS Dec 28 '10 at 19:58
@GregS The case is for arbitrary length integers. We all knew the hash part. –  belisarius Dec 28 '10 at 19:59
Evaluating a[b[j]] takes O(log n) steps since b[j] contains O(log n) digits. On average, the first duplicate in b occurs at position n/2. And in fact your example likely produces no duplicates between the lists, so you'd have to iterate through the entire list before failure. Sounds like O(n log n) to me no matter what the graph shows. –  GregS Dec 28 '10 at 20:09
@GregS That's why I made the graphics in first place. My bet was not linear. Perhaps we can come to another test that shows your insight? –  belisarius Dec 28 '10 at 20:17

Have you tried a counting sort? It is simple to implement, uses O(n) space and also has a \theta(n) time complexity.

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... for numbers whose length does not depend on input size. But here, the numbers get bigger as the input grows longer ... –  meriton Dec 28 '10 at 17:17
The question stated, "These arrays contain random integers in the range of 0-n100." So, we know the distribution of the numbers, so counting sort is an alternative. You are correct that if the numbers are sparse, then this sort is a huge waste of space. I was just giving an idea that no one else had given yet. –  Davidann Dec 28 '10 at 17:22

If storage is not important, then scratch hash table in favor for an array of n in length. Flag to true when you come across that number in first array. In pass through second array, if you find any of them to be true, you have your answer. O(n).

Define largeArray(n)
// First pass
for(element i in firstArray)
largeArray[i] = true;

// Second pass
Define hasFound = false;
for(element i in secondArray)
if(largeArray[i] == true)
hasFound = true;
break;

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Huh? Define the operation "when you come across that number in the first array". This sounds like a linear search. –  GregS Dec 28 '10 at 16:55
Hashtable is not an option as it'll cost you O(n^2) time in the worst case scenario. –  Omerta Dec 28 '10 at 16:55
I meant, if you do array[currentNumber] and it's true, it means the same number existed in the first array and therefore you have your solution. You're not searching all values in the array because the index itself is the number you're searching for. –  Neil Dec 28 '10 at 17:11
... by that logic, all algorithms are O(n), you just have to use the right definition of n. What you are overlooking is that n represents the length of the input. You can't choose it because the input determines it. I recommend you read up on O-Notation if you don't believe me; this is clearly outside the scope of this question. –  meriton Dec 28 '10 at 17:39
@Neil: The point is it your array is O(n log n) in size, not O(n). So it takes O(n log n) just to initialize your array. –  GregS Dec 28 '10 at 19:53

Based on the ideas posted till date.We can store the one array integer elements into a hash map . Maximum number of different integers can be stored in RAM . Hash map will have only unique integer values. Duplicates are ignored.

Here is the implementation in Perl language.

#!/usr/bin/perl
use strict;
use warnings;
sub find_common_elements{ # function that prints common elements in two unsorted array
my (@arr1,@array2)=@_; # array elements assumed to be filled and passed as function arguments

my $hash; # hash map to store value of one array # runtime to prepare hash map is O(n). foreach my$ele ($arr1){$hash->{$ele}=true; # true here element exists key is integer number and value is true, duplicate elements will be overwritten # size of array will fit in memory as duplicate integers are ignored ( mx size will be 2 ^( 32) -1 or 2^(64) -1 based on operating system) which can be stored in RAM. } # O(n ) to traverse second array and finding common elements in two array foreach my$ele2($arr2){ # search in hash map is O(1), if all integers of array are same then hash map will have only one entry and still search tim is O(1) if( defined$hash->{$ele}){ print "\n$ele is common in both array \n";
}
}
}


I hope it helps.

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