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I can sort a list using Sort or OrderBy. Which one is faster? Are both working on same algorithm?

List<Person> persons = new List<Person>();
persons.Add(new Person("P005", "Janson"));
persons.Add(new Person("P002", "Aravind"));
persons.Add(new Person("P007", "Kazhal"));

1.

persons.Sort((p1,p2)=>string.Compare(p1.Name,p2.Name,true));

2.

var query = persons.OrderBy(n => n.Name, new NameComparer());

class NameComparer : IComparer<string>
{
    public int Compare(string x,string y)
    {
      return  string.Compare(x, y, true);
    }
}
share|improve this question

5 Answers 5

up vote 47 down vote accepted

Why not measure it:

class Program
{
    class NameComparer : IComparer<string>
    {
        public int Compare(string x, string y)
        {
            return string.Compare(x, y, true);
        }
    }

    class Person
    {
        public Person(string id, string name)
        {
            Id = id;
            Name = name;
        }
        public string Id { get; set; }
        public string Name { get; set; }
    }

    static void Main()
    {
        List<Person> persons = new List<Person>();
        persons.Add(new Person("P005", "Janson"));
        persons.Add(new Person("P002", "Aravind"));
        persons.Add(new Person("P007", "Kazhal"));

        Sort(persons);
        OrderBy(persons);

        const int COUNT = 1000000;
        Stopwatch watch = Stopwatch.StartNew();
        for (int i = 0; i < COUNT; i++)
        {
            Sort(persons);
        }
        watch.Stop();
        Console.WriteLine("Sort: {0}ms", watch.ElapsedMilliseconds);

        watch = Stopwatch.StartNew();
        for (int i = 0; i < COUNT; i++)
        {
            OrderBy(persons);
        }
        watch.Stop();
        Console.WriteLine("OrderBy: {0}ms", watch.ElapsedMilliseconds);
    }

    static void Sort(List<Person> list)
    {
        list.Sort((p1, p2) => string.Compare(p1.Name, p2.Name, true));
    }

    static void OrderBy(List<Person> list)
    {
        var result = list.OrderBy(n => n.Name, new NameComparer()).ToArray();
    }
}

On my computer when compiled in Release mode this program prints:

Sort: 1162ms
OrderBy: 1269ms


UPDATE:

As suggested by @Stefan here are the results of sorting a big list fewer times:

List<Person> persons = new List<Person>();
for (int i = 0; i < 100000; i++)
{
    persons.Add(new Person("P" + i.ToString(), "Janson" + i.ToString()));
}

Sort(persons);
OrderBy(persons);

const int COUNT = 30;
Stopwatch watch = Stopwatch.StartNew();
for (int i = 0; i < COUNT; i++)
{
    Sort(persons);
}
watch.Stop();
Console.WriteLine("Sort: {0}ms", watch.ElapsedMilliseconds);

watch = Stopwatch.StartNew();
for (int i = 0; i < COUNT; i++)
{
    OrderBy(persons);
}
watch.Stop();
Console.WriteLine("OrderBy: {0}ms", watch.ElapsedMilliseconds);

Prints:

Sort: 8965ms
OrderBy: 8460ms

In this scenario it looks like OrderBy performs better.


UPDATE2:

And using random names:

List<Person> persons = new List<Person>();
for (int i = 0; i < 100000; i++)
{
    persons.Add(new Person("P" + i.ToString(), RandomString(5, true)));
}

Where:

private static Random randomSeed = new Random();
public static string RandomString(int size, bool lowerCase)
{
    var sb = new StringBuilder(size);
    int start = (lowerCase) ? 97 : 65;
    for (int i = 0; i < size; i++)
    {
        sb.Append((char)(26 * randomSeed.NextDouble() + start));
    }
    return sb.ToString();
}

Yields:

Sort: 8968ms
OrderBy: 8728ms

Still OrderBy is faster

share|improve this answer
    
....herein lies the reason for my answer. –  James Dec 2 '09 at 12:51
1  
I think, it's much different of sorting a very small list (3 items) 1000000 times, or by sorting a very large list (1000000 items) just a few times. Both is very relevant. In practice, medium size of list (what's medium? ... let's say 1000 items for now) is most interesting. IMHO, sorting lists with 3 items is not very meaningful. –  Stefan Steinegger Dec 2 '09 at 12:58
    
@Stefan, in reality the list may indeed be more. The point is it demonstrates the speed difference. –  James Dec 2 '09 at 13:06
5  
Note that there is a difference between "faster" and "noticably faster". In your last example the difference was about a quarter of a second. Is the user going to notice? Is it unacceptable for the user to wait almost nine seconds for the result? If the answers to both questions are "no" then it really doesn't matter which one you pick from a performance perspective. –  Eric Lippert Dec 2 '09 at 16:10
3  
Note also that the test here sorts the list before starting the stopwatch, so we are comparing how the two algorithms compare when faced with sorted input. This may be quite different than their relative performance with unsorted input. –  phoog Feb 6 '12 at 6:00

No, they aren't the same algorithm. For starters, the LINQ OrderBy is documented as stable (i.e. if two items have the same Name, they'll appear in their original order).

It also depends on whether you buffer the query vs iterate it several times (LINQ-to-Objects, unless you buffer the result, will re-order per foreach).

For the OrderBy query, I would also be tempted to use:

OrderBy(n => n.Name, StringComparer.{yourchoice}IgnoreCase);

(for {yourchoice} one of CurrentCulture, Ordinal or InvariantCulture).

List<T>.Sort

This method uses Array.Sort, which uses the QuickSort algorithm. This implementation performs an unstable sort; that is, if two elements are equal, their order might not be preserved. In contrast, a stable sort preserves the order of elements that are equal.

Enumerable.OrderBy

This method performs a stable sort; that is, if the keys of two elements are equal, the order of the elements is preserved. In contrast, an unstable sort does not preserve the order of elements that have the same key. sort; that is, if two elements are equal, their order might not be preserved. In contrast, a stable sort preserves the order of elements that are equal.

share|improve this answer
1  
deleted my incorrect answer. +1. –  Jimmeh Dec 2 '09 at 12:49
    
+1 for "OrderBy is documented as stable" –  Nightwish91 Sep 18 '12 at 12:17
2  
If you use .NET Reflector or ILSpy to crack open Enumerable.OrderBy and drill down into its internal implementation, you can see that the OrderBy sorting algorithm is a variant of QuickSort that does a stable sort. (See System.Linq.EnumerableSorter<TElement>.) Thus, Array.Sort and Enumerable.OrderBy can both be expected to have O(N log N) execution times, where N is the number of elements in the collection. –  John Beyer Jun 26 '13 at 16:25
    
@Marc I don't quite follow what the difference would be if two elements were equal and their order was not preserved. This certainly does not look like a problem for primitive data types. But even for a reference type, why would it matter, if I were to sort, person with name Marc Gravell appeared before another person with name Marc Gravell (for instance :))? I am not questioning your answer/knowledge, rather looking for an application of this scenario. –  Mukus Mar 17 at 2:58
    
@Mukus imagine you sort a company address book by name (or indeed by date of birth) - there are inevitably going to be duplicates. The question is ultimately: what happens for them? Is the sub-order defined? –  Marc Gravell Mar 17 at 7:45

Darin Dimitrov's answer shows that OrderBy is slightly faster than List.Sort when faced with already-sorted input. I modified his code so it repeatedly sorts the unsorted data, and OrderBy is in most cases slightly slower.

Furthermore, the OrderBy test uses ToArray to force enumeration of the Linq enumerator, but that obviously returns a type (Person[]) which is different from the input type (List<Person>). I therefore re-ran the test using ToList rather than ToArray and got an even bigger difference:

Sort: 25175ms
OrderBy: 30259ms
OrderByWithToList: 31458ms

The code:

using System;
using System.Collections.Generic;
using System.Diagnostics;
using System.Linq;
using System.Text;

class Program
{
    class NameComparer : IComparer<string>
    {
        public int Compare(string x, string y)
        {
            return string.Compare(x, y, true);
        }
    }

    class Person
    {
        public Person(string id, string name)
        {
            Id = id;
            Name = name;
        }
        public string Id { get; set; }
        public string Name { get; set; }
        public override string ToString()
        {
            return Id + ": " + Name;
        }
    }

    private static Random randomSeed = new Random();
    public static string RandomString(int size, bool lowerCase)
    {
        var sb = new StringBuilder(size);
        int start = (lowerCase) ? 97 : 65;
        for (int i = 0; i < size; i++)
        {
            sb.Append((char)(26 * randomSeed.NextDouble() + start));
        }
        return sb.ToString();
    }

    private class PersonList : List<Person>
    {
        public PersonList(IEnumerable<Person> persons)
           : base(persons)
        {
        }

        public PersonList()
        {
        }

        public override string ToString()
        {
            var names = Math.Min(Count, 5);
            var builder = new StringBuilder();
            for (var i = 0; i < names; i++)
                builder.Append(this[i]).Append(", ");
            return builder.ToString();
        }
    }

    static void Main()
    {
        var persons = new PersonList();
        for (int i = 0; i < 100000; i++)
        {
            persons.Add(new Person("P" + i.ToString(), RandomString(5, true)));
        } 

        var unsortedPersons = new PersonList(persons);

        const int COUNT = 30;
        Stopwatch watch = new Stopwatch();
        for (int i = 0; i < COUNT; i++)
        {
            watch.Start();
            Sort(persons);
            watch.Stop();
            persons.Clear();
            persons.AddRange(unsortedPersons);
        }
        Console.WriteLine("Sort: {0}ms", watch.ElapsedMilliseconds);

        watch = new Stopwatch();
        for (int i = 0; i < COUNT; i++)
        {
            watch.Start();
            OrderBy(persons);
            watch.Stop();
            persons.Clear();
            persons.AddRange(unsortedPersons);
        }
        Console.WriteLine("OrderBy: {0}ms", watch.ElapsedMilliseconds);

        watch = new Stopwatch();
        for (int i = 0; i < COUNT; i++)
        {
            watch.Start();
            OrderByWithToList(persons);
            watch.Stop();
            persons.Clear();
            persons.AddRange(unsortedPersons);
        }
        Console.WriteLine("OrderByWithToList: {0}ms", watch.ElapsedMilliseconds);
    }

    static void Sort(List<Person> list)
    {
        list.Sort((p1, p2) => string.Compare(p1.Name, p2.Name, true));
    }

    static void OrderBy(List<Person> list)
    {
        var result = list.OrderBy(n => n.Name, new NameComparer()).ToArray();
    }

    static void OrderByWithToList(List<Person> list)
    {
        var result = list.OrderBy(n => n.Name, new NameComparer()).ToList();
    }
}
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1  
I wonder why this hasn't been upvoted... –  t3rse Oct 12 '12 at 22:40
5  
@t3rse perhaps because I added this answer 38 months after the question was posted. –  phoog Oct 13 '12 at 18:25

I think it's important to note another difference between Sort and OrderBy:

Suppose there exists a Person.CalculateSalary() method, which takes a lot of time; possibly more than even the operation of sorting a large list.

Compare

// Option 1
persons.Sort((p1, p2) => Compare(p1.CalculateSalary(), p2.CalculateSalary()));
// Option 2
var query = persons.OrderBy(p => p.CalculateSalary()); 

Option 2 may have superior performance, because it only calls the CalculateSalary method n times, whereas the Sort option might call CalculateSalary up to 2n log(n) times, depending on the sort algorithm's success.

share|improve this answer

you should calculate the complexity of algorithms used by the methods OrderBy and Sort. QuickSort has a complexity of n (log n) as i remember, where n is the length of the array.

i've searched for orderby's too, but i could not find any information even in msdn library. if you have not any same values and sorting related to only one property, i prefer to use Sort() method; if not than use OrderBy.

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