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Three different implementations of finding the sum of an IEnumerable < int> source are given below along with the time taken when the source has 10,000 integers.

source.Aggregate(0, (result, element) => result + element);  

takes 3 ms

source.Sum(c => c);

takes 12 ms

source.Sum();

takes 1 ms

I am wondering why the second implementation is four times more expensive than the first one. Shouldn't it be same as the third implementation.

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What are your test conditions ? –  Raphaël Althaus Jun 14 '12 at 9:21
3  
how did you get these times? How many time did you try the results? –  Felice Pollano Jun 14 '12 at 9:22
    
I profiled it using dotTrace. I ran it once, but the three runs are independent. –  Gopal Jun 14 '12 at 9:28
    
try to run each test in a loop, this remove all the times taken for jitting and so on, the test will be more accurate. –  Felice Pollano Jun 14 '12 at 9:32
    
The results remain same after couple of runs also. –  Gopal Jun 14 '12 at 9:35

1 Answer 1

up vote 38 down vote accepted

Note: My computer is running .Net 4.5 RC, so it's possible that my results are affected by this.

Measuring the time it takes to execute a method just once is usually not very useful. It can be easily dominated by things like JIT compilation, which are not actual bottlenecks in real code. Because of this, I measured executing each method 100× (in Release mode without debugger attached). My results are:

  • Aggregate(): 9 ms
  • Sum(lambda): 12 ms
  • Sum(): 6 ms

The fact that Sum() is the fastest is not surprising: it contains a simple loop without any delegate invocations, which is really fast. The difference between Sum(lambda) and Aggregate() is not nearly as prominent as what you measured, but it's still there. What could be the reason for it? Let's look at decompiled code for the two methods:

public static TAccumulate Aggregate<TSource, TAccumulate>(this IEnumerable<TSource> source, TAccumulate seed, Func<TAccumulate, TSource, TAccumulate> func)
{
    if (source == null)
        throw Error.ArgumentNull("source");
    if (func == null)
        throw Error.ArgumentNull("func");

    TAccumulate local = seed;
    foreach (TSource local2 in source)
        local = func(local, local2);
    return local;
}

public static int Sum<TSource>(this IEnumerable<TSource> source, Func<TSource, int> selector)
{
    return source.Select<TSource, int>(selector).Sum();
}

As you can see, Aggregate() uses a loop but Sum(lambda) uses Select(), which in turn uses an iterator. And using an iterator means there is some overhead: creating the iterator object and (probably more importantly) one more method invocation for each item.

Let's verify that using Select() is actually the reason by writing our own Sum(lambda) twice, once using Select(), which should behave the same as Sum(lambda) from the framework, and once without using Select():

public static int SlowSum<T>(this IEnumerable<T> source, Func<T, int> selector)
{
    return source.Select(selector).Sum();
}

public static int FastSum<T>(this IEnumerable<T> source, Func<T, int> selector)
{
    if (source == null)
        throw new ArgumentNullException("source");
    if (selector == null)
        throw new ArgumentNullException("selector");

    int num = 0;
    foreach (T item in source)
        num += selector(item);
    return num;
}

My measurements confirm what I thought:

  • SlowSum(lambda): 12 ms
  • FastSum(lambda): 9 ms
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Very insightful. Thanks for the detailed response. –  Gopal Jun 14 '12 at 10:57
    
This is one of the best answers I've seen on SO, perfectly explained and well crafted. (+1 obviously) –  RichK Jun 14 '12 at 16:06

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