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I have a collection of int values with which I populate a HashSet<int> in the following manner -

var hashSet = new HashSet<int>(myIEnumerable);

Assuming that iterating the IEnumerable is O(n), what will be the worst case complexity of creating a HashSet<int> in such a way?

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3 Answers 3

The documentation actually states:

This constructor is an O(n) operation, where n is the number of elements in the collection parameter.

http://msdn.microsoft.com/en-us/library/bb301504.aspx

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1  
But is it worst-case complexity or amortized complexity? –  UghSegment Dec 28 '12 at 15:17
2  
@UghSegment You mean "average" complexity not "amortized". "Amortized" is used for operations which are sometimes expensive (for example a doubling of the backing store) and cheap for the rest. That concept is orthogonal to average vs. worstcase. –  CodesInChaos Dec 28 '12 at 15:19
    
@UghSegment To add to CodeInChaos' answer, it is both the worst case and the amortized complexity. (Given that he explained why it's possible for it to be both, I'm stating that's actually the case here.) –  Servy Dec 28 '12 at 15:24
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No, in general worst case is quadratic of course, but this is for objects with the same GetHashCode() output. I'm wondering about int's. –  SergeyS Dec 28 '12 at 15:34
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@JeppeStigNielsen I used .NET Reflector to find out how the HashSet gets the modulus value it uses in the hashing calculation. I used this information to provide the constructor with various values that all fall into the same index and the performance degradation in my tests seemed to be almost perfectly quadratic. It seems after all that the worst case complexity is indeed O(n^2), even without collisions in the hash values. –  UghSegment Dec 28 '12 at 16:29

You can bring the worst case to O(N^2) by supplying objects that all hash to the same bucket when the set reaches its maximum size. For example, if you pass a sequence of 17519 ints constructed as

x[i] = i * 17519

for i between 1 and 17519, inclusive, all numbers will hash to the initial bucket on Microsoft's implementation of HashSet<int>, taking O(N^2) to insert:

var h = new HashSet<int>(Enumerable.Range(1, 17519).Select(i => i*17519));

Set a brea kpoint, and examine h in the debugger. Look at Raw View / Non-public members / m_buckets. Observe that the initial bucket has 17519 elements, while the remaining 17518 all have zeros.

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1  
I wouldn't be surprised if it's O(N^2) –  CodesInChaos Dec 28 '12 at 15:15
    
But what about non-amortized, worst case complexity? –  UghSegment Dec 28 '12 at 15:17
    
You can force worse than O(n^2) time if you assume a custom time with a poor or malicious GetHashCode. You could have a GetHashCode that never returns, for example, and never ever be able to complete the task, or you could have a GetHashCode method that takes O(n^2) time to compute, thus making the HashSet methods...worse than that. –  Servy Dec 28 '12 at 15:39
    
@Servy My point is that since you have no control over .NET's GetHashCode of Int32, you cannot force new HashSet<int>(myIEnumerable) from the OP into the O(N^2) territory. When you have control over GetHashCode, you can force HashSet<T> to block indefinitely :) HashSet<long> is the middle of the road: the worst you can do is O(N^2) by supplying a particularly bad sequence for the .NET implementation of Int64.GetHashCode. –  dasblinkenlight Dec 28 '12 at 15:43
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For ints you still can create collisions of the bucket index. Simply add ints that are a multiple of the Capacity. I expect O(n^2) addition performance in such a scenario, but I'm too lazy to figure out the preferred capacities of HashSet<T>. –  CodesInChaos Dec 28 '12 at 15:52

A quick experiment with degenerate hashcode (a constant) shows that it's quadratic.

for(int n=0;n<100;n++)
{
    var start=DateTime.UtcNow;
    var s=new HashSet<Dumb>(Enumerable.Range(0,n*10000).Select(_=>new Dumb()));
    Console.Write(n+" ");
    Console.WriteLine((int)((DateTime.UtcNow-start).TotalSeconds*10));
}

outputs:

0 0
1 8
2 34
3 73
4 131

Now some claim that you don't get multi collisions of the HashCode for ints. While that's technically true, what matters for performance isn't a collision of the HashCode, but a collision of the bucket index. I think HashSet<T> uses something like bucket = (hash&0x7FFFFFFF)%Capacity. So if you add a sequence of integers that's a multiple of a preferred bucket size, it'll still be very slow.

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Please provide code –  SergeyS Dec 28 '12 at 15:26
    
If all objects return the same hashcode, than yes, this is O(n*n), because of collisions. But the OP's question was about collection of int's. So I'm wondering how difficult (possible?) would be to choose pair of int's with equal hashcodes. –  SergeyS Dec 28 '12 at 15:33
    
I don't think the test you performed is the same as what I described in my question. I am specifically interested in the worst case complexity of passing a collection with a known amount of elements to the HashSet constructor, not the complexity of multiple Add calls. –  UghSegment Dec 28 '12 at 15:38
    
@SergeyS int is one of just a handful of types that has no collisions. The number of possible int values is not larger than the number of possible int values, so the hash code for int values is actually unique for different values. (In other words, it's hash code can just return itself.) Other types such as byte and char also have less values than int and so will never collide. –  Servy Dec 28 '12 at 15:41
    
Even with it it's possible to cause collisions of the bucket index. It's just more annoying to pull off. | @UghSegment it's the same with the constructor. See updated code. –  CodesInChaos Dec 28 '12 at 15:49

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