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I have two generic lists of type T. Both lists contain same type, and I'd like to create a third list (or a filtered version of list 2) based on the items in list two that do not exist in List 1, based on the ID of each item.

Each list holds a "Package" object, which has an ID property.

Right now I mocked up the code using For Each loops, which I know is horrible (the Big O is constant time) so I'd like a more efficent method.

this code is in VB per project requirments, but I prefer C# - so either code sample would work for me.

Private Sub RemoveStockPackagesFromSelection()

    Dim p As Package
    Dim packageList As List(Of Package) = New List(Of Package)
    Dim stockPackageList As List(Of Package) = New List(Of Package)
    Dim result As List(Of Package) = New List(Of Package)

    ' Fill list with User's Packages
    For i As Integer = 0 To ListBox2.Items.Count - 1
        p = New Package
        p.Id = CInt(ListBox2.Items(i).Value)
        p.Name = ListBox2.Items(i).Text

    ' Fill list with Stock Packages to compare:
    Dim ds As DataSet = DAL.GetStandardPackages()

    For Each dr As DataRow In ds.Tables(0).Rows
        p = New Package
        p.Id = CInt(dr.Item("id"))

    ' Do Compare and Filter
    For Each p1 As Package In packageList
        For Each p2 As Package In stockPackageList
            If Not p1.Id = p2.Id Then
            End If

    ' Here is our new trimmed list:

End Sub

What is a nice and clean LINQ or Lamda way of doing this filtering? What is the Big O of my method and what would be the Big O of the proposed method (just to satify my curiosity).


share|improve this question
Have you tried your code? It doesn't work the way you describe it should. – svick Jun 19 '11 at 22:12
Shawn, for a question like this you can omit the filling of the base lists. We believe you have two lists. – Henk Holterman Jun 19 '11 at 22:17
There are some amazing answers here composed in an amazingly short amount of time. I love this forum. I will build a sample using IEqualityComparer and Zebi's LINQ query, as this is what mainly I was looking for, but I appricate the advise on using HashSets, Dictionaries, and the .Except() extension method. All very solid and interesting solutions. I am trying to grasp Big O (which seems to be the Hot Topic of the day in CSE), so thanks for your insight guys. Great answers... – nocarrier Jun 19 '11 at 22:27
time (and memory) complexity always was and most likely always will be a hot topic in CS. – svick Jun 19 '11 at 22:30
True, algorithmic programming has always been around and always will be, regardless of what new languages emerge - Big O will always be a "hot topic". Guess that was kinda a dumb thing to say... UndoSelfDepricatingComment() :) – nocarrier Jun 19 '11 at 22:40
up vote 8 down vote accepted

LINQ Except Method

This would be the cleanest way, as suggested by Maxim and svick but requires an overridden Equals method which equals on ID or you have to provide a comparer (see svicks answer).

var result = stockPackageList.Except(packageList).ToList();

Resources Many LINQ samles can be found in the msdn at

I'll leave the initial parts of my answer for reference:

Brute force way:

var result = stockPackageList
              .Where(x => packageList.All(package => x.Id != package.Id))

should do the trick. You just have to translate the lambda syntax to

This query will filter all items from stockPackageList which IDs are not present in all items of packageList.

You may invert the query:

var result = stockPackageList
              .Where(x => packageList.Any(package => x.Id == package.Id) == false)

The Any query will return true if any item in packageList has a matching id. This query should run a little faster because it has not to traverse the whole collection, as All has to.

Using Eqality:

If your package object implements IEquatable<Package> you can shorten the code down to

var result = stockPackageList
              .Where(x => packageList.Contains(x) == false)

Using a Hash Set:

If you want to use a hash set you can do

var hash = new HashSet<string>(packageList.Select(x=>x.Id));
var result = stockPackageList.Where(x => hash.Contains(x.Id) == false).ToList();

This saves computation time when the lists become large, as faester and Ivan Danilov pointed out.

share|improve this answer
Your LINQ skills are top notch Zebi; thanks for the solution. I'm looking forward to being able to compose lamda syntax as easily and quickly as you have here. Can you help me understand what reads in human syntax? package => x => x.Id != package.Id - I'm not familiar with double => operators in a query. – nocarrier Jun 19 '11 at 22:33
Sorry, the double => was a typo :( If you want to learn about linq try this link:, I will edit my answer, too. – Zebi Jun 19 '11 at 23:22
And take a look at the Except method, examples are provided as answers, too. – Zebi Jun 19 '11 at 23:30

Can't really read you VB code but if you want to get the items in l2 that not in l1 -

Her's a sample C# code

   public class SomeObject
        public string ID { get; set; }

    public class SomeObjectComparer : IEqualityComparer<SomeObject>
        public bool Equals(SomeObject x, SomeObject y)
            return x.ID == y.ID;

        public int GetHashCode(SomeObject obj)
            return obj.ID.GetHashCode();

    class Program
        static void Main(string[] args)
            List<SomeObject> l1, l2;
            // lists init ...

            IEqualityComparer<SomeObject> comparer = new SomeObjectComparer();

            List<SomeObject> l3 = l2.Except(l1, comparer).ToList();

share|improve this answer
Except is slow on general lists as each comparison is linear. – Ivan Danilov Jun 19 '11 at 22:17
@Ivan Except uses Set operations internally – Magnus Jun 19 '11 at 22:20
You're right. Good point. – Ivan Danilov Jun 19 '11 at 22:29
This seems like it would be the "best Practice" method - very clean, readable, and OOP-y. I will use this in my production code. Thank you much @Maxim! – nocarrier Jun 19 '11 at 22:35
Thanks. I'll appreciate if you'll mark this answer as 'accepted'. – Maxim Jun 19 '11 at 22:38

Your method has asymptotic running time of O(m*n) where m and n are the sizes of your collections.

You should strive for O(m lg n). You will of course need to search both collections, but you can build a hashset of one of them in O(n) and perform queries in O(1) on average, so you should copy one list to a hashset and traverse the second looking up values in the former.

    static void Sort()
        List<Package> a = new List<Package>();
        List<Package> b = new List<Package>();

        Func<Package, int> idExtractor = x => x.ID;

        var hash = new HashSet<Package>(a, new IDComparer<Package, int>(idExtractor));

        a.AddRange(b.Where(x => !hash.Contains(x)));

    class IDComparer<ObjectType, KeyType>
        : IEqualityComparer<ObjectType>
        where KeyType : IComparable
        private Func<ObjectType, KeyType> idExtractor;

        public IDComparer(Func<ObjectType, KeyType> idExtractor)
            this.idExtractor = idExtractor;

        public bool Equals(ObjectType x, ObjectType y)
            return idExtractor(x).Equals(idExtractor(y));

        public int GetHashCode(ObjectType obj)
            return idExtractor(obj).GetHashCode();
share|improve this answer
Creating a hash set is O(N), not O(N lg N). – svick Jun 19 '11 at 22:29
@swick: Sorry, you are right. I was confusing trees and hashsets which I shouldn't. The case where I guess O(n lg n) is vaguely justified is if the hashset needs to resize during the build up. If the initial size isn't set correctly and the strategy is to double the size each time the capacity is exceeded you will have O(lg n) such rebuilds with additional copying of the n elements. But given that I don't know if this is the strategy in the .NET hashset I should probably just assume O(n). – faester Jun 19 '11 at 22:43
this is the strategy .Net uses, but it still makes the total time complexity O(N). See Wikipedia. – svick Jun 19 '11 at 23:17
@swick: now I feel plain stupid though also somewhat wiser. I actually did a project on amortized analysis in university explaining the exact problem. Memory is deceptive. Thanks again! – faester Jun 20 '11 at 4:55

You can use Except():

result = stockpackageList.Except(PackageList).ToList();

This assumes Package has overloaded Equals() to compare Ids. If it doesn't, you have to use IEqualityComparer, e.g. the one from this answer:

result = stockpackageList.Except(PackageList, 
                                 new KeyEqualityComparer<Package, int>(p => p.Id))

As for time complexity, your solution doesn't work correctly, so it's complexity is irrelevant. The complexity of Except() is O(N+M), because it first creates a hash set from the first collection (O(N)), then tries to remove each item from the second collection (O(M)) and then returns the result.

share|improve this answer
var dic = new Dictionary<string, Package>(p1.Count); // capacity here is important
foreach (var p in p1) 
    dic.Add(p.Id, p);
var result = p2.Where(p => !dic.ContainsKey(p.Id)).ToList();

Filling dictionary is almost O(n) by p1.Count. And each search is O(1). So we have something close to linear complexity.

share|improve this answer
Filling dictionary is O(N), where did this notion that it's O(N log N) came from? Dictionary is implemented as a hash table. – svick Jun 19 '11 at 22:34
It was my guess of word 'almost' in the Add() method documentation. I checked the sources with Reflector. n log n is incorrect I have to admit, but it is not O(N) either. Depending on hash collisions count single addition could be anything from O(1) to O(N). Fixed my answer, thanks. – Ivan Danilov Jun 19 '11 at 22:40
@Ivan, yeah, but it's not single addition that matters, it's the total time. And that's on average O(N), assuming the hash function has a uniform distribution. – svick Jun 19 '11 at 22:43
Could you point any analysis of the dictionary filling? – Ivan Danilov Jun 19 '11 at 22:46
@Ivan, yeah, but resizing works the same as with List<T>, that is, most additions are O(1), some of them are O(current size), but the amortized time per addition is O(1) and so the total time is O(N). – svick Jun 19 '11 at 23:13

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