# Which one is faster? List.contains() or Map.containsKey()

I'm writing an algorithm where I look for pairs of values which when added together results in another value I'm looking for.

I figured out that using a Map will speed up my algorithm from O(n²). I later realized that I don't really use the values contained in my Map so a List will suffice.

I did a power search on Google but I did not find any information on the asymptotic running time of those methods in the title of my question.

Can you point out where should I look for such information?

• A fairer comparison would be Set.contians() vs Map.containsKey(), which is basically equal - for every type of Map there's a corresponding Set type used in its impl – Bohemian Jul 23 '12 at 13:26
• I know I know, but I think that It would be a several hour project to perform an asymptotic analysis on the JCF code. – Adam Arold Jul 23 '12 at 13:29
• Sounds like you want to put the values into a list and iterate from both ends irregularly trying to match the sum. Still O(n). For more complex pairs, a Bloom filter may be appropriate. – Tom Hawtin - tackline Jul 23 '12 at 14:06

list.contains is O(n) whereas map.containsKey is O(1) for hashmaps, O(logn) for treemaps. For hashmaps, google for hashtable. For treemaps, google for binary tree or similar. Wikipedia has good entries on these subjects.

If you don't need a map, you can use the corresponding set. Inside they are implemented in terms of corresponding maps, where the value is just some dummy singleton object.

Be careful, however, to avoid the class Hashtable. It's an archaeological artefact in the modern library. For your case HashSet is probably the best choice.

• Although the two are not comparable because List permits duplicate entries and Map doesn't. If the OP wants this Set behaviour he can also use HashSet which should be O(1) and TreeSet which should be O(log(n)). – user268396 Jul 23 '12 at 13:26
• Thanks for the lightning-fast answer. I can not accept it though, because of the 10 minute rule. :) I never used Hashtable / Vector though but thanks for pointing that out. – Adam Arold Jul 23 '12 at 13:31

Mapand List are interfaces, so there is no information on their implementation nor their performance. But if you use the most current implementations (LinkedList or ArrayList for List, and HashMap for Map), the contains() method must, in the worst case, go through the entire list, and compare your element with each entry. It is an O(n) operation.

If you use an HashMap, the implementation is radically different : the HashMap contains an array with more entries than elements in it (in practice, you have an array size of between 4n/3 an 3n/2 for n elements in the map). It computes the hash of the key, which is an int, and wrap it between 0 and your array size (let's say this number is i). Then it will put the element at the index i of the array (or i+1, i+2… if previous indexes are already taken). So, when you check for the key presence with containsKey, it will re-compute the hash and the i value, and check the i, i+1… indexes until it finds an empty array cell. Theorically, you can have an O(n) worst-case, if the array is almost full, are all the keys have almost identicals i values, but with a good hash function, you have constant-time contains and get functions. (However, adding elements is fast if you don't need to resize the array, which is REALLY slow - I think you need to recompute the indexes of each key).

So a map is really faster if you need to check the key appearance in a collection, and do not need to keep the order (there is a SortedHashMap for that, but I don't know it's performance), but it will take more memory.

Also, if you don't need the key-value thing, you can use a HashSet (which is internally the same as an HashMap).

• That's because I wanted to know all of the implementations' speeds. – Adam Arold Jul 23 '12 at 13:47

Map.containsKey() considering that you are using a HashMap since searching in HashMap is done in O(1).

List.contains() generally should resort to sequential search or a binary search thus the complexity will be atleast O(log n)