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I am trying to list time complexities of operations of common data structures like Arrays, Binary Search Tree, Heap, Linked List, etc. and especially I am referring to Java. They are very common, but I guess some of us are not 100% confident about the exact answer. Any help, especially references, is greatly appreciated.

E.g. For singly linked list: Changing an internal element is O(1). How can you do it? You HAVE to search the element before changing it. Also, for the Vector, adding an internal element is given as O(n). But why can't we do it in amortized constant time using the index? Please correct me if I am missing something.

I am posting my findings/guesses as the first answer.

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When you vote a question to close, at least add a comment. –  Bhushan Sep 3 '11 at 18:29
    
Downvoted for the reason given in my answer. –  EJP Sep 4 '11 at 9:54
    
Time and Space Complexities for all data structures Big O cheat sheet –  vbp Feb 26 at 16:25
    
In case someone else steps into this, take a minute to also check this link: infotechgems.blogspot.gr/2011/11/… –  vefthym Apr 7 at 8:12
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1 Answer

up vote 38 down vote accepted

Arrays

  • Inserting: O(1) for all the positions, since it is done with indexes
  • Deleting: O(n) if we have to find the element, O(1) if we know position of the element
  • Searching: O(n) if array is unsorted and O(log n) if array is sorted and something like a binary search is used.

Linked List:

  • Inserting: O(1), if done at the head, O(n) if anywhere else since we have to reach that position by traveseing the linkedlist linearly.
  • Deleting: O(1), if done at the head, O(n) if anywhere else since we have to reach that position by traveseing the linkedlist linearly.
  • Searching: O(n)

Doubly-Linked List:

  • Inserting: O(1), if done at the head, O(n) if anywhere else since we have to reach that position by traveseing the linkedlist linearly.
  • Deleting: O(1), if done at the head, O(n) if anywhere else since we have to reach that position by traveseing the linkedlist linearly.
  • Searching: O(n)

Stack:

  • Push: O(1)
  • Pop: O(1)
  • Top: O(1)
  • Search (Something like lookup, as a special operation): O(n) (I guess so)

Queue/Deque/Circular Queue:

  • Insert: O(1)
  • Remove: O(1)
  • Size: O(1)

Binary Search Tree:

  • Insert, delete and search: Average case: O(log n), Worst Case: O(n)

Heap/PriorityQueue (min/max):

  • findMin/findMax: O(1)
  • insert: O(log n)
  • deleteMin/Max: O(log n)
  • lookup, delete (if at all provided): O(n), we will have to scan all the elements as they are not ordered like BST

HashMap/Hashtable/HashSet:

  • Insert/Delete: O(1) amortized
  • Re-size/hash: O(n)
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awesome answer. Thanks a lot +1 for you. –  Nikhil Agrawal Apr 24 '13 at 8:58
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Good reference, to recall things... –  Dreamer Jul 6 at 19:09
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