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For example:

List<MyClass> myList = new List<MyClass>();
...
// add lots of members...
...
MyClass myClass = myList[25];

Will asking for index 25 take much longer than asking for index 1, or does it use some quick algorithm to jump straight to the 25th item?

Thanks!

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Accessing a List<T> item by index is O(1) but not removing by RemoveAt which is O(n). –  nawfal Nov 24 '12 at 19:35

5 Answers 5

up vote 2 down vote accepted

Internally List<T> is implemented as array (which grows when you're adding new items) so accessing of n-th element will be O(1) operation. (Therefore there will be no difference in speed between getting myList[1] and myList[25].)

Excerpt from the List<T>.Item property documentation:

Retrieving the value of this property is an O(1) operation; setting the property is also an O(1) operation.

I can imagine how slow would be .NET applications if List<T> had to jump through all items before getting n-th...

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Just to clarify, when you say "which grows when you're adding new items" - whilst the List<> can grow the underlying array cannot: instead the array is replaced with a new, larger array and the contents copied across. Thus a List<> grows by using additional elements of the underlying array or, when these are exhausted, by creating a new, larger array. –  Paul Ruane Sep 8 '10 at 10:39
    
@Paul Ruane, thank you for your comment, your are absolutely right (it creates a new doubled in size array each time it runs out of current capacity); I just wanted to keep the answer simple. –  Regent Sep 8 '10 at 12:58

From the Item property of List<T>

Retrieving the value of this property is an O(1) operation; setting the property is also an O(1) operation.

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No, it's very fast. In fact it's not an algorithm at all*; the backing store for List<T> is just a T[] array; so all it has to do is jump to a known location in memory.

In abstract terms, think of it like this: since the elements of an array reside in a contiguous block of memory, you can imagine the array as a number line. Does it take you any longer to find "10" on a number line than "1"? No -- you know exactly how the numbers are laid out, so all you have to do is look straight at 10. You don't have to scroll your eyes through 1, 2, 3, etc., in other words.

Granted, that's a highly non-technical analogy; but it's pretty consistent with how accessing an element of an array works.

*A calculation is required, yes: the address of the first element in the array plus the product the element size with the index. But to call this an "algorithm" would be a stretch; and anyway, it is a constant-time operation regardless.

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A small, and very pedantic, nitpick: A calculation is required, just not at the C#/IL level. Something like addressOfElement = baseAddress + (index * sizeOfElement). This is, as you say, blindingly fast and constant regardless of index (if we disregard ultra-nitpicky concerns like whether the required element is currently in cache, main memory or swap etc). –  LukeH Sep 8 '10 at 12:14
    
@LukeH: Yeah, valid point. I guess whether this conflicts with my answer depends on how strict your definition of "algorithm" is. I'd still stick by my analogy, though, as one could say that in order to be able to immediately "find" a point on a line you would at least need to know what units you're working with (sizeOfElement in your example). –  Dan Tao Sep 8 '10 at 12:25

No, removing and insertion on the other hand is dependent on where you remove an element, since it is a dynamic array.

http://en.wikipedia.org/wiki/Dynamic_array

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List<T> uses T[] internally so indexing is supported directly by the underlying data structure.

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