Basically I have about 1,000,000 strings, for each request I have to check if a String belongs to the list or not.

I'm worried about the performance, so what's the best method? ArrayList? Hash?

  • 5
    A good exercise would be to try both different lists/sets/maps and then see if you can figure out why you get different times by reading the java docs for the collections :) Jul 22, 2010 at 9:49
  • 3
    In order to be CERTAIN that you are doing this right, learn to use a profiler well. The lowest hanging fruit is the jvisualvm one in the JDK. Jul 22, 2010 at 11:04

10 Answers 10


Your best bet is to use a HashSet and check if a string exists in the set via the contains() method. HashSets are built for fast access via the use of Object methods hashCode() and equals(). The Javadoc for HashSet states:

This class offers constant time performance for the basic operations (add, remove, contains and size),

HashSet stores objects in hash buckets which is to say that the value returned by the hashCode method will determine which bucket an object is stored in. This way, the amount of equality checks the HashSet has to perform via the equals() method is reduced to just the other Objects in the same hash bucket.

To use HashSets and HashMaps effectively, you must conform to the equals and hashCode contract outlined in the javadoc. In the case of java.lang.String these methods have already been implemented to do this.

  • 1
    What else? It has O(1) for add and contains. Jul 22, 2010 at 9:57
  • thanks @Andreas_D, I added the quote from the Javadoc which states it has constant time performance.
    – krock
    Jul 22, 2010 at 10:20
  • 14
    The fun part comes when the million strings won't fit in main memory anymore. Jul 22, 2010 at 11:03

In general, a HashSet will give you better performance, since it does not have to look through each element and compare, like an ArrayList does, but typically compares at most a few elements, where the hashcodes are equal.

However, for 1M strings, the performance of hashSet may still not be optimal. A lot of cache misses will slow down searching the set. If all strings are equally likely, then this is unavoidable. However, if some strings are more often requested than others, then you can place the common strings into a small hashSet, and check that first, before checking the larger set. The small hashset should be sized to fit in cache (e.g. a few hundred K at most). Hits to the small hashset will then be very fast, while hits to the larger hashset proceed at speed limited by the memory bandwidth.

  • +1: Although, it occurs to me that since strings are individually allocated, it may not be particularly relevant how many, total, are in a specific hashmap, since a search is only going to hit a tiny percentage of them. More relevant might be the actually allocation pattern of the char arrays in the strings themselves, which the Java programmer has zero control over anyway (and that's a good thing). Jul 22, 2010 at 14:33
  • @Software Monkey - the intent is that by putting the most frequently searched strings in it's own map, that there will be a high degree of hits for that map. A smaller hashmap with frequently used strings will have a higher cache hit rate than a larger map, since each cache line will correspond in the map backing array to several frequently used strings. Of course, as you say, this doesn't help with the allocation of the strings themselves. If that is a problem, then allocating the most common strings first may give better cache use, since the VM may allocate from the same region of the heap.
    – mdma
    Jul 22, 2010 at 14:42

Before going further, please consider this: Why are you worried about performance? How often is this check called?

As for possible solutions:

  • If the list is already sorted, then you can use java.util.Collections.binarySearch which offers the same performance characteristics as a java.util.TreeSet.

  • Otherwise you can use a java.util.HashSet that as a performance characteristic of O(1). Note that calculating the hash code for a string that doesn't have one calculated yet is an O(m) operation with m=string.length(). Also keep in mind that hashtables only work well until they reach a given load factor, i.e. hashtables will use more memory than plain lists. The default load factor used by HashSet is .75, meaning that internally a HashSet for 1e6 objects will use an array with 1.3e6 entries.

  • If the HashSet does not work for you (e.g. because there are lots of hash-collisions, because memory is tight or because there are lots of insertions), than consider using a Trie. Lookup in a Trie has a worst-case complexity of O(m) where m=string.length(). A Trie has also some extra-benefits that might be useful for you: e.g., it can give you the closest fit for a search string. But keep in mind that the best code is no code, so only roll your own Trie implementiation if the benefits outweight the costs.

  • Consider using a database if you want more complex queries, e.g. match for a substring or a regular expression.

  • 10
    -1: He's worried about performance because he (a) has a huge data set, and (b) any 1/2 way decent programmer worth his salt should always consider the whether performance characteristics of an algorithm or data structure is appropriate to the task. Jul 22, 2010 at 14:28

I'd use a Set, in most cases HashSet is fine.

  • 1
    krock's answer is slightly better at nudging the OP to an optimal solution: A TreeSet has O(log2(N)) performance, while a HashSet ideally has O(1). Jul 22, 2010 at 9:57
  • @Carl, assuming that both equals and hashCode() are O(1), i.e. not considering string lengths. Jul 22, 2010 at 11:06

With such a huge number of Strings, I immediately think of a Trie. It works better with a more limited set of characters (such as letters) and/or when the start of many string overlap.


Having run the exercise here are my results.

private static final int TEST_CYCLES = 4000;
private static final long RAND_ELEMENT_COUNT = 1000000l;
private static final int RAND_STR_LEN = 20;
//Mean time
Array list:18.55425
Array list not contains:17.113
Hash set:5.0E-4
Hash set not contains:7.5E-4

I believe the numbers speak for themselves. The lookup time of the hash set is way, wayyyy faster.


Perhaps it isn't required for your case but I think it's useful to mention that there are some space-efficient probabilistic algorithms. For example Bloom filter.


If you are having such a large amount of strings, the best opportunity for you is to use a database. Look for MySQL.

  • 1
    In general I'd agree with you, but he's worried about lookup performance - won't that add lots of overhead?
    – Rup
    Jul 22, 2010 at 9:51
  • 1
    Network latency is added, but you have the full power of SQL at your disposal. Another consideration is memory - a million strings at 32 chars each means ~64MB of RAM. It's a classic CPU versus memory trade-off. I'd benchmark it and see.
    – duffymo
    Jul 22, 2010 at 9:53
  • 1
    @Rup: Absolutely. And lots of opportunities for errors. If the data fits in memory (and it must, as they've already crammed it in) then it should be sought in memory. Jul 22, 2010 at 9:53
  • 2
    @duffymo: For a straight test on existence, nothing you can do in a DB server will ever approach the performance of a contains() in a hash. Jul 22, 2010 at 9:55
  • @Carl Smotricz&Rup: I didn't know that. So thank you for your comments.
    – oopbase
    Jul 22, 2010 at 9:56

Not only for String, you can use Set for any case you need unique items.

If the type of items is primitive or wrapper, you may not care. But if it is a class, you must override two methods:

  1. hashCode()
  2. equals()

Sometimes you want to check if an object is in the list/set and at the same time you want the list/set to be ordered. If you are looking to also retrieve objects easily without using an enumeration or iterator, you may consider using both an ArrayList<String> and HashMap<String, Integer>. The list is backed by the map.

Example from some work I recently did:

public class NodeKey<K> implements Serializable, Cloneable{
private static final long serialVersionUID = -634779076519943311L;

private NodeKey<K> parent;
private List<K> children = new ArrayList<K>();
private Map<K, Integer> childrenToListMap = new HashMap<K, Integer>();

public NodeKey() {}

public NodeKey(Collection<? extends K> c){
    List<K> childHierarchy = new ArrayList<K>(c);
    K childLevel0 = childHierarchy.remove(0);

        childrenToListMap.put(childLevel0, children.size()-1);


In this case, parameter K would be a String for you. The map (childrenToMapList) stores Strings inserted into the list (children) as the key, and the map values are the index position in the list.

The reason for the list and the map is so that you can retrieve indexed values of the list, without having to do an iteration over a HashSet<String>.

Your Answer

By clicking “Post Your Answer”, you agree to our terms of service, privacy policy and cookie policy

Not the answer you're looking for? Browse other questions tagged or ask your own question.