I may be teaching a "Java crash-course" soon. While it is probably safe to assume that the audience members will know Big-O notation, it is probably not safe to assume that they will know what the order of the various operations on various collection implementations is.

I could take time to generate a summary matrix myself, but if it's already out there in the public domain somewhere, I'd sure like to reuse it (with proper credit, of course.)

Anyone have any pointers?

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up vote 127 down vote accepted

This website is pretty good but not specific to Java: http://bigocheatsheet.com/ Here is an image in case this link won't work

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    And this is why we don't use URL's as answers. That document/server, as far as I can tell, is no longer available! – Jason Mock Apr 10 '13 at 16:01
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    @Ben J Links are no more working – Vikas V Apr 28 '13 at 12:08
  • The web archive links are now also broken. – MikeFHay Jul 24 '13 at 9:46
  • Seems new working URLs added. Thanks for taking the effort, it is very helpful. – Tejas C Dec 4 '14 at 0:10
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    @AndreaZilio LinkedList.remove(Object) is constant time, assuming you know the neighbor already. If you don't know the neighbor, it's linear time to find it first. – Paul Evans Dec 10 '15 at 15:33

The book Java Generics and Collections has this information (pages: 188, 211, 222, 240).

List implementations:

                      get  add  contains next remove(0) iterator.remove
ArrayList             O(1) O(1) O(n)     O(1) O(n)      O(n)
LinkedList            O(n) O(1) O(n)     O(1) O(1)      O(1)
CopyOnWrite-ArrayList O(1) O(n) O(n)     O(1) O(n)      O(n)

Set implementations:

                      add      contains next     notes
HashSet               O(1)     O(1)     O(h/n)   h is the table capacity
LinkedHashSet         O(1)     O(1)     O(1) 
CopyOnWriteArraySet   O(n)     O(n)     O(1) 
EnumSet               O(1)     O(1)     O(1) 
TreeSet               O(log n) O(log n) O(log n)
ConcurrentSkipListSet O(log n) O(log n) O(1)

Map implementations:

                      get      containsKey next     Notes
HashMap               O(1)     O(1)        O(h/n)   h is the table capacity
LinkedHashMap         O(1)     O(1)        O(1) 
IdentityHashMap       O(1)     O(1)        O(h/n)   h is the table capacity 
EnumMap               O(1)     O(1)        O(1) 
TreeMap               O(log n) O(log n)    O(log n) 
ConcurrentHashMap     O(1)     O(1)        O(h/n)   h is the table capacity 
ConcurrentSkipListMap O(log n) O(log n)    O(1)

Queue implementations:

                      offer    peek poll     size
PriorityQueue         O(log n) O(1) O(log n) O(1)
ConcurrentLinkedQueue O(1)     O(1) O(1)     O(n)
ArrayBlockingQueue    O(1)     O(1) O(1)     O(1)
LinkedBlockingQueue   O(1)     O(1) O(1)     O(1)
PriorityBlockingQueue O(log n) O(1) O(log n) O(1)
DelayQueue            O(log n) O(1) O(log n) O(1)
LinkedList            O(1)     O(1) O(1)     O(1)
ArrayDeque            O(1)     O(1) O(1)     O(1)
LinkedBlockingDeque   O(1)     O(1) O(1)     O(1)

The bottom of the javadoc for the java.util package contains some good links:

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    You have to specify for which case scenario are those figures, for example, delete from Arraylist could take O(n), if you delete element in middle or end of array. – Popeye Jul 25 '17 at 19:59

The Javadocs from Sun for each collection class will generally tell you exactly what you want. HashMap, for example:

This implementation provides constant-time performance for the basic operations (get and put), assuming the hash function disperses the elements properly among the buckets. Iteration over collection views requires time proportional to the "capacity" of the HashMap instance (the number of buckets) plus its size (the number of key-value mappings).

TreeMap:

This implementation provides guaranteed log(n) time cost for the containsKey, get, put and remove operations.

TreeSet:

This implementation provides guaranteed log(n) time cost for the basic operations (add, remove and contains).

(emphasis mine)

  • I disagree with the HashMap part. I know Sun's position, but... get for example must call obj.equals(key), which could be linear in the size of the objects contained. Consider that you typically have to read the fields for this comparison. The exceptions would be integers or strings (interned)??? – Overflown Feb 18 '09 at 7:03
  • First of all, if they were wrong, it ought to be not too hard for you to create a test case that disproves the constant-time performance? Second, if you look at the source code for HashMap, it does not call equals() against each key in the map - only when the hashcodes are equal. – matt b Feb 18 '09 at 14:11
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    If you read the quote above, it says it's constant-time "assuming the hash function disperses the elements properly among the buckets". From CS theory, hash tables have constant time operations when the hash function is "good" (which happens on average), but may take linear time in the worst case. – newacct May 2 '09 at 0:46
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    @Overflown - technically, it doesn't matter how long obj.equals() takes from a complexity perspective, as that is just part of the "constant" with relation to the number of items in the collection. – mikera Sep 12 '10 at 19:37

The guy above gave comparison for HashMap / HashSet vs. TreeMap / TreeSet.

I will talk about ArrayList vs. LinkedList:

ArrayList:

  • O(1) get()
  • amortized O(1) add()
  • if you insert or delete an element in the middle using ListIterator.add() or Iterator.remove(), it will be O(n) to shift all the following elements

LinkedList:

  • O(n) get()
  • O(1) add()
  • if you insert or delete an element in the middle using ListIterator.add() or Iterator.remove(), it will be O(1)
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    if you insert or delete an element in the middle using ListIterator.add() or Iterator.remove(), it will be O(1) why? first we need to find element in the middle, so why it not O(n)? – MyTitle Jun 21 '13 at 17:48
  • @MyTitle: read it again. "using ListIterator.add() or Iterator.remove()" We have an iterator. – newacct Jun 21 '13 at 18:24

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