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I'm implementing a priority queue and want to iterate through the list to insert at the right spot. In the documentation it states that C# List<T>.Item Property is O(1): List<T>.Item Property

e.g.

int retrivedValue = myIntList[5];

How is this possible since add also is O(1)? It's like eating the cookie and still have it. Normal lists in my head have O(n) for accessing an element.

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Add is O(1) only as long as the capacity of the backing array suffices. If it needs to be expanded, the complexity is O(n). –  Heinzi Apr 3 '14 at 5:04
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@Heinzi It's amortized O(1). –  Timothy Shields Apr 3 '14 at 16:24
    
@Heinzi When backing list has to be extended, it's content is copied using Array.Copy which copies entire array at once, so it's still O(1). –  MarcinJuraszek Apr 3 '14 at 16:35
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@MarcinJuraszek No, that operation is indeed O(n), because the array copy's speed is dependent on the amount of memory it needs to copy. However, when amortizing these rare O(n) operations among the other O(1) operations it actually turns out that each add is O(1), not O(n). So a single add is technically O(n), but n adds is actually also O(n), not O(n ^ 2). –  Servy Apr 3 '14 at 17:27

7 Answers 7

up vote 20 down vote accepted

List<T> is a list in representation, as the documentation says, it represents a typed list of objects that can be accessed by index. Its elements can be accessed by index directly and does not require element-by-element traversal, ergo, it's time complexity to access an element is O(1). It's implemented internally as a dynamic array, the kind that doubles its size when it fills up (thanks to comments!).

You may be confusing it with LinkedList<T>, which is implemented as a linked list...

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You seem to be saying that accessing the element is O(n) rather than O(1) is this correct or is this a typo? Your argument to me suggests O(1) which is why I thought it might be a typo. –  Chris Apr 3 '14 at 8:14
    
Yeah, thanks for that, it is a typo. –  ArthurChamz Apr 3 '14 at 15:08
    
I'd like to mention that the ability to access elements in the list based on index does not imply that the operation can be done in O(1). For example, the Java LinkedList allows retrieval based on index, but requires O(n) time. –  JakeP Apr 3 '14 at 17:08
    
Well, I meant directly without traversing the list... Which now that I mention it, it should be the main idea of my answer. Didn't know that about Java, sounds nice. –  ArthurChamz Apr 3 '14 at 17:24
    
You are so correct! All the comments here did really help and the pointer to LinkedList is my next step since that exactly what i need. –  Johan Holtby Apr 3 '14 at 20:33

You only have O(n) if you have to iterate across the list to retrive the item.

For this example you are accessing an internal array by index, so do not have to iterate.

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The standard List type is backed by an internal array with O(1) access performance.

List does not use a linked list implementation.

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List internally uses an array, so indexing is a direct operation. Also, add at the end is fast (unless a realoc is required). Insert and Remove are O(n) though, because all elements of the array need to be moved around. In practice, this isn't so bad as well, because the move is implemented as a single block-move of the right part of the array.

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The List<T> is backed by an array.

The Add operation is O(1) amortized across all adds, meaning that most operations are O(1), but some are O(N). Whenever the backing array fills up it gets copied to a new array of double the size.

As an example of how it works, assume the backing array starts with 4 elements. The first 4 additions are O(1), but the 5th will have to copy the existing 4 elements and add the 5th, making it O(5). Adding elements 6, 7, and 8 are O(1), while adding element 9 will be O(9). Then elements 10-16 will also be O(1).

By the time you've added 16 elements to the array, you've done O(28) operations, making adding N elements take almost O(2N) operations. Thus, adding a single element is O(2) = O(1) on average.

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I wish to expand a little bit on this. You should emphasize that most operations (adding) are O(1), not some, some is too weak. Also your final conclusion should be that adding a single element is O(2) = O(1) on average. (You forgot to divide by the fact that you have added N elements) –  skiwi Apr 3 '14 at 8:39
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" making adding N elements take almost O(2N) operations. Thus, adding a single element is O(2N) = O(N) on average." what now, either its adding N or adding a single element... –  PlasmaHH Apr 3 '14 at 9:46
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-1. Big-O notation talks about asymptotic behaviour. So I have to ask; when you say 'but the 5th will have to copy the existing 4 elements and add the 5th, making it O(5)' what is the opertation O(5) in respect to? The correct wording is; 'once for every power of two operations we will need to do an operation with run time proportional to the current length of the list. O(1+2+4+8+16+...+x^2)=O(2*x^2)=O(n^2), so only the final such operation is interesting. This is an O(n) operation, and O(n+1+1+1+...(n ones))=O(2n)=O(n). So we have O(n) time to make n insertions. –  Taemyr Apr 3 '14 at 12:56
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@Taemyr: Do you mean 2^x rather than x^2? –  cHao Apr 3 '14 at 13:51
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It would have been possible to design List<T> such that every append or indexing operation would take constant time, if when one doubles the size of the list, one keeps the previous list and, each time an item is added to the new list, an item is moved from the old one. Once the list needs to be re-expanded, the old list may be abandoned. This approach would end up doing the same work as List<T> does; the advantages List<T> has stem from the fact that items may be copied faster in bulk than piecemeal, and look-ups require examining one array rather than two. –  supercat Apr 3 '14 at 17:29

Despite attractive List Search complexity based on element index, I wonder if your needs might be better served by a SkipList as described in An Extensive Examination of Data Structures Using C# 2.0 alluded to here, as the ordering priority is not unique.

Dynamically extending an Array for n insertions (n unbounded) is in fact O(n)

If an array backing of a list is doubled in size every time and n is allowed to grow without bound then the number of times the array will be re-allocated will be O(logn) and at each point will be size 2^k; k = 1,2,3...

enter image description here

List<T>.Item versus List<T>.Contains

Access to elements in a List is O(1) if the index is known, but to keep the correct order based on priority, you would need to either use some external ordering mechanism, or use .Contains, but that 2nd method is not O(1).

Skiplists have O(logn) Search complexity; allows a PriorityQueue O(logn) enqueue and O(1) dequeue

The idea is that a SkipList is a linked list with randomly inserted "fast forward" pointers to overcome a link list's O(n) Search complexity. Every node has a height K and K next pointers. Without going into detail, heights are distributed and the next() function selects the appropriate pointer in such a way to make the search O(logn). However, the node to remove from the queue is always going to be at one end of the linked list.

Online behavior

Memory is finite and practically speaking a priority queue is not going to grow forever. One could argue that the queue grows to a certain size and then never gets reallocated. But then, does it shrink? If the list becomes fragmented, a shrink operation sounds even more costly than the grow operation. If shrink is supported, then the cost will be paid every time the List grows too small and then subsequently the grow cost will be paid when the List grows too large. If it's not supported then the memory associated with the largest queue size will remain allocated. This being a priority queue, it does in fact sound possible that a queue could grow as work is fed into it, then shrink (logically) to 0,. There may be rare circumstances that it will grow very large if the consumer side lags.

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"Every time that occurs, the copy will be O(n)." No, you're miscomputing. The first time, you copy one element (if you start from size one), the second time two, and so on, so when n = 2^k the total cost is 1 + 2 + 4 + ... + n = 2 * n - 1. The sum has indeed log n addends, but that's it. This material is for instance covered in Cormen et al. –  Blaisorblade Apr 3 '14 at 20:32
    
@Blaisorblade ... yep! I owe an edit now, I think. –  waTeim Apr 3 '14 at 20:49

You might want to have a look at this in order to understand and yet use the most suitable data structure.

Below is the summary table:

enter image description here

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Nice one! :) Where is the source? –  Johan Holtby Apr 7 '14 at 19:11
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The source is within the answer :) –  yazanpro Apr 7 '14 at 22:11

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