Take the 2-minute tour ×
Stack Overflow is a question and answer site for professional and enthusiast programmers. It's 100% free, no registration required.

I have a streaming time series, of which I am interested in keeping the last 4 elements, which means I want to be able to pop the first, and add to the end. Which Java Collection is the best for this? Vector ?

share|improve this question
LinkedList seems like a reasonable choice for O(1) inserts and removes, do you need O(1) indexing, too? –  Mark Elliot Sep 1 '11 at 4:13
Thread safe? Not thread safe? For removing from the end and adding in the beginning a LinkedList is usually the best option. –  Maurício Linhares Sep 1 '11 at 4:13

7 Answers 7

Use a Queue

Queue<String> qe=new LinkedList<String>();


System.out.println(qe.poll()); //returns a
System.out.println(qe.poll()); //returns b
System.out.println(qe.poll()); //returns c
System.out.println(qe.poll()); //returns d

There's five simple methods of a Queue

  • element() -- Retrieves, but does not remove, the head of this queue.

  • offer(E o) -- Inserts the specified element into this queue, if

  • peek() -- Retrieves, but does not remove, the head of this queue, returning null if this queue is empty.

  • poll() -- Retrieves and removes the head of this queue, or null if this queue is empty.

  • remove() -- Retrieves and removes the head of this queue.
share|improve this answer
This keeps all elements, not just the last 4 –  dkneller Nov 17 '12 at 2:07

Consider CircularFifoBuffer from Common.Collections. Unlike Queue you don't have to maintain the limited size of underlying collection and wrap it once you hit the limit.

Buffer buf = new CircularFifoBuffer(4);
buf.add("D"); //ABCD
buf.add("E"); //BCDE

CircularFifoBuffer will do this for you because of the following properties:

  • CircularFifoBuffer is a first in first out buffer with a fixed size that replaces its oldest element if full.
  • The removal order of a CircularFifoBuffer is based on the insertion order; elements are removed in the same order in which they were added. The iteration order is the same as the removal order.
  • The add(Object), BoundedFifoBuffer.remove() and BoundedFifoBuffer.get() operations all perform in constant time. All other operations perform in linear time or worse.

However you should consider it's limitations as well - for example, you can't add missing timeseries to this collection becaue it doens't allow nulls.

share|improve this answer
there seems now to be a version derived from the original Commons Collections which makes use of generics: sourceforge.net/projects/collections (it looks like the project was moved to github) –  Andre Holzner Apr 4 '12 at 8:45
Commons Collections 4.0 includes CircularFifoQueue which has the same properties, and supports generics. –  Pete Aug 22 at 16:12
I noticed the CircularFifoQueue doesn't work like this. When I put "HELLO" into a 3 unit sized Queue, I go from "HEL" to "LEL" to "LOL". What happened to the feature described by @AndryTaptunov? –  E.S. Sep 17 at 21:23

Since Java 1.5 you have the ArrayBlockingQueue that does this job.

share|improve this answer
This blocks after N elements. It doesn't keep the last M elements –  dkneller Nov 17 '12 at 2:07

I had the same problem some time ago and was disappointed because I couldn't find any solution that suites my needs so I wrote my own class. Honestly, I did found some code back then, but even that wasn't what I was searching for so I adapted it and now I'm sharing it, just like the author of that piece of code did.

EDIT: This is the original (although slightly different) code: CircularArrayList for java

I don't have the link of the source because it was time ago, but here's the code:

import java.util.AbstractList;
import java.util.ArrayList;
import java.util.Collections;
import java.util.List;
import java.util.RandomAccess;

public class CircularArrayList<E> extends AbstractList<E> implements RandomAccess {

private final int n; // buffer length
private final List<E> buf; // a List implementing RandomAccess
private int leader = 0;
private int size = 0;

public CircularArrayList(int capacity) {
    n = capacity + 1;
    buf = new ArrayList<E>(Collections.nCopies(n, (E) null));

public int capacity() {
    return n - 1;

private int wrapIndex(int i) {
    int m = i % n;
    if (m < 0) { // modulus can be negative
        m += n;
    return m;

public int size() {
    return this.size;

public E get(int i) {
    if (i < 0 || i >= n-1) throw new IndexOutOfBoundsException();

    if(i > size()) throw new NullPointerException("Index is greater than size.");

    return buf.get(wrapIndex(leader + i));

public E set(int i, E e) {
    if (i < 0 || i >= n-1) {
        throw new IndexOutOfBoundsException();
    if(i == size()) // assume leader's position as invalid (should use insert(e))
        throw new IndexOutOfBoundsException("The size of the list is " + size() + " while the index was " + i
                +". Please use insert(e) method to fill the list.");
    return buf.set(wrapIndex(leader - size + i), e);

public void insert(E e)
    int s = size();     
    buf.set(wrapIndex(leader), e);
    leader = wrapIndex(++leader);
    buf.set(leader, null);
    if(s == n-1)
        return; // we have replaced the eldest element.


public void clear()
    int cnt = wrapIndex(leader-size());
    for(; cnt != leader; cnt = wrapIndex(++cnt))
        this.buf.set(cnt, null);
    this.size = 0;      

public E removeOldest() {
    int i = wrapIndex(leader+1);

    for(;;i = wrapIndex(++i)) {
        if(buf.get(i) != null) break;
        if(i == leader)
            throw new IllegalStateException("Cannot remove element."
                    + " CircularArrayList is empty.");

    return buf.set(i, null);

public String toString()
    int i = wrapIndex(leader - size());
    StringBuilder str = new StringBuilder(size());

    for(; i != leader; i = wrapIndex(++i)){
    return str.toString();

public E getOldest(){
    int i = wrapIndex(leader+1);

    for(;;i = wrapIndex(++i)) {
        if(buf.get(i) != null) break;
        if(i == leader)
            throw new IllegalStateException("Cannot remove element."
                    + " CircularArrayList is empty.");

    return buf.get(i);

public E getNewest(){
    int i = wrapIndex(leader-1);
    if(buf.get(i) == null)
        throw new IndexOutOfBoundsException("Error while retrieving the newest element. The Circular Array list is empty.");
    return buf.get(i);
share|improve this answer
This might be the source you're referring to: museful.net/2011/software-development/… –  Lorne Laliberte Mar 21 '12 at 2:48
Yes, that is the original source. (I'll edit my post now.) –  vgfeit May 10 '12 at 13:18
I tried this code. CircularArrayList<String> buf = new CircularArrayList<String>(4); buf.insert("A"); buf.insert("B"); System.out.println(buf); //[null, null] buf.insert("C"); buf.insert("D"); System.out.println(buf); //[null, A, B, C] String res = buf.get(0); //null The code at museful.net/2011/software-development/… works better for me. –  Mauro Zallocco Mar 27 at 15:11

If you need

  • O(1) insertion and removal
  • O(1) indexing to interior elements
  • access from a single thread only
  • generic element type

then you can use this CircularArrayList for Java in this way (for example):

CircularArrayList<String> buf = new CircularArrayList<String>(4);

buf.add("D"); // ABCD

String pop = buf.remove(0); // A <- BCD
buf.add("E"); // BCDE

String interiorElement = buf.get(i);

All these methods run in O(1).

share|improve this answer

Since Java 1.6, there is ArrayDeque, which implements Queue and seems to be faster and more memory efficient than a LinkedList and doesn't have the thread synchronization overhead of the ArrayBlockingQueue: from the API docs: "This class is likely to be faster than Stack when used as a stack, and faster than LinkedList when used as a queue."

final Queue<Object> q = new ArrayDeque<Object>();
q.add(new Object()); //insert element
q.poll(); //remove element
share|improve this answer

Since Guava 15.0 (released September 2013) there's EvictingQueue:

A non-blocking queue which automatically evicts elements from the head of the queue when attempting to add new elements onto the queue and it is full. An evicting queue must be configured with a maximum size. Each time an element is added to a full queue, the queue automatically removes its head element. This is different from conventional bounded queues, which either block or reject new elements when full.

This class is not thread-safe, and does not accept null elements.

Example use:

EvictingQueue<String> queue = EvictingQueue.create(2);
System.out.print(queue); //outputs [c, d]
share|improve this answer

Your Answer


By posting your answer, you agree to the privacy policy and terms of service.

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