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Why should I use IEnumerable<T> when I can make do with...say List<T>? What's the advantage of the former over the latter?

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This must be a duplicate. – Steven Jun 6 '11 at 20:34
See this:… – Rezoan Sep 17 '13 at 11:37

9 Answers 9

IEnumerable<T> is an interface that tells us that we can enumerate over a sequence of T instances. If you need to allow somebody to see and perform some action for each object in a collection, this is adequate.

List<T>, on the other hand, is a specific implementation of IEnumerable<T> that stores the objects in a specific, known manner. Internally, this may be a very good way to store your values that you expose via IEnumerable<T>, but a List<T> is not always appropriate. For example, if you do not need to access items by index, but constantly insert items at the beginning of your collection and then remove items from the end, a Queue<T> would be far more appropriate to use.

By using IEnumerable<T> in your API, you provide yourself the flexibility to change the internal implementation at any time without changing any other code. This has huge benefits in terms of allowing your code to be flexible and maintainable.

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I agree strongly with your point about decoupling from the implementation, but I also think there's a point for making clear the expected usage; even if I have a List<T>, referring to it as IEnumerable<T> makes it clear that the functionality I'm expecting from the collection in that usage is the enumerability functionality, and not any of the other List functionality. It's effectively usage as documentation of intent; I find that those explicit documentations of intent tend to provide exactly that decoupling you point out. – Paul Sonier Jun 6 '11 at 19:55
@Paul: I agree, though I would suggest IList<T> vs. IEnumerable<T> in that case, not List<T>. – Reed Copsey Jun 6 '11 at 20:23
Good point, although that brings up a whole other question of "interface vs. concrete instance", which I think is a different question. – Paul Sonier Jun 6 '11 at 20:37

On this point Jeffrey-Richter writes:

When declaring a method’s parameter types, you should specify the weakest type possible, preferring interfaces over base classes. For example, if you are writing a method that manipulates a collection of items, it would be best to declare the method’s parameter by using an interface such as IEnumerable<T> rather than using a strong data type such as List<T> or even a stronger interface type such as ICollection<T> or IList<T>:

// Desired: This method uses a weak parameter type   
public void ManipulateItems<T>(IEnumerable<T> collection) { ... }  

// Undesired: This method uses a strong parameter type   
public void ManipulateItems<T>(List<T> collection) { ... }

The reason, of course, is that someone can call the first method passing in an array object, a List<T> object, a String object, and so on — any object whose type implements IEnumerable<T>. The second method allows only List<T> objects to be passed in; it will not accept an array or a String object. Obviously, the first method is better because it is much more flexible and can be used in a much wider range of scenarios.

Naturally, if you are writing a method that requires a list (not just any enumerable object), then you should declare the parameter type as an IList<T>. You should still avoid declaring the parameter type as List<T>. Using IList<T> allows the caller to pass arrays and any other objects whose type implements IList<T>.

On the flip side, it is usually best to declare a method’s return type by using the strongest type possible (trying not to commit yourself to a specific type).

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Yes, but be careful with IList<T> since arrays implement it only partially, i.e. calling Add or Remove for instance will throw exceptions with arrays. – Olivier Jacot-Descombes Jun 5 '13 at 11:51
@OlivierJacot-Descombes: Arrays have an even more subtle problem: a Cat[] will may be passed as IList<Animal> myList, and if Animal someAnimal is either null or happens to hold a reference to a Cat, myList[0]=someAnimal will succeed. If someAnimal is a non-null reference to something other than a Cat, however, the operation will fail. – supercat Sep 27 '13 at 16:56
@OlivierJacot-Descombes: Short of using Reflection, there's no way of knowing whether an IList<T> which allows anything of a given type to be stored by index will allow everything of that type to be stored by index. – supercat Sep 27 '13 at 16:59
@supercat: Yes, making arrays co- and contravariant is a serious design flaw in my eyes. Also arrays should not implement IList<T>. Instead, there should be a IArray<T> interface, which IList<T> would extend. – Olivier Jacot-Descombes Sep 27 '13 at 17:05
@OlivierJacot-Descombes: Arrays are covariant only; defining an interface for arrays which would allow an efficient type-agnostic way of permuting them is difficult; simply allowing allowing array covariance is easier by comparison. What would have been ideal would have been to have multiple storage-location types for arrays (e.g. given S:T:U and T[] foo; T+[] bar, T-[] boz;, foo could only hold instances of T[], bar could hold T[] or S[], and boz could hold T[] or U[]) but .NET expects a strong correlation between storage-location types from heap object types. – supercat Sep 27 '13 at 17:28

Different implementations of collections can be enumerable; using IEnumerable makes it clear that what you're interested in is the enumerability, and not the structure of the underlying implementation of the collection.

As mentioned by Mr. Copsey, this has the benefit of providing decoupling from the implementation, but I'm of the contention that a clear definition of the smallest subset of interface functionality as possible (i.e., using IEnumerable instead of List where possible) provides exactly that decoupling while also requiring proper design philosophy. That is to say, you can achieve decoupling but not achieve minimal dependency, but you cannot achieve minimal dependency without achieving maximal decoupling.

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Using the concept of iterators you can achieve major improvement in algorithm quality, both in terms of speed and memory usage.

Let's consider the following two code examples. Both parse the file, one stores lines in collection, the other uses enumerable.

First example takes C * O(N) time, and memory O(N)

IEnumerable<string> lines = SelectLines();
List<Item> items = lines.Select(l=>ParseToItem(l)).ToList();
var itemOfIterest = items.FirstOrDefault(IsItemOfIterest); 

Second example takes 1/2 C * O(N) time, and constant memory.

var itemOfIterest = lines.FirstOrDefault(l=>IsItemOfIterest(ParseToItem(l));

Here is the code of SelectLines()

 IEnumerable<string> SelectLines()
  using(var reader = ...)
   yield return line;

Here is why 1/2 of time. Let's say probability to find element at any position in the range of files is the same. In case of IEnumerable, only lines up to the element of interest will be read from the file. In case of ToList call over the enumerable, all the file will be read.

Of course, the List will hold all the items in memory, that is why O(N) memory usage.

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If you plan to build a public API, it's better to use IEnumerable than List<T>, because you better use the most minimalistic interface/class. List<T> lets you access objects by index if that's required.

Here is a pretty good guideline when to use IEnumerable, ICollection, List<T> and so on.

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Usually you don't use IEunumerable directly. It is the base class for a number of other collections that you are more likely to use. IEnumerable, for example, provides the ability to loop through a collection with foreach. That is used by many inheriting classes such as List<T>. But IEnumerable doesn't offer a sort method (though you can use Linq for that) while some other generic collections like List<T> do have that method.

Oh sure, you can use it to create your own custom collection types. But for everyday stuff, it probably isn't as useful as the collections derived from it.

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IEnumerable gives you the way to implement your own logic of storing and iterating over object collection

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Implementation of IEnumerable<T> is generally the preferred way for a class to indicate that it should be usable with a "foreach" loop, and that multiple "foreach" loops on the same object should operate independently. Although there are uses of IEnumerable<T> other than "foreach", the normal indication that one should implement IEnumerable is that the class is one where it would make sense to say "foreach foo in classItem {foo.do_something();}.

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  1. IEnumerable is taking advantage of deferred execution as explained here: IEnumerable vs List - What to Use? How do they work?

  2. IEnumerable enable implicit reference conversion for array types which known as Covariance. Consider the following example:

public abstract class Vehicle { }

public class Car :Vehicle

private void doSomething1(IEnumerable<Vehicle> vehicles)


private void doSomething2(List<Vehicle> vehicles)


var vec = new List<Car>();
doSomething1(vec); // this is ok 
doSomething2(vec); // this will give a compilation error 
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