I found this article about Lazy<T>: Laziness in C# 4.0 – Lazy

Can someone point me to a practical use of the Lazy<T> class in a real application? In other words, when should I use it?

  • 51
    Replaces: get { if (foo == null) foo = new Foo(); return foo; }. And there are zillions of possible places to use it...
    – Kirk Woll
    Jul 27, 2011 at 16:15
  • 68
    Note that get { if (foo == null) foo = new Foo(); return foo; } is not thread-safe, while Lazy<T> is thread-safe by default.
    – Matthew
    Jul 11, 2013 at 23:00
  • 26
    From MSDN: IMPORTANT: Lazy initialization is thread-safe, but it doesn't protect the object after creation. You must lock the object before accessing it, unless the type is thread safe. Mar 24, 2014 at 14:50

7 Answers 7


You typically use it when you want to instantiate something the first time its actually used. This delays the cost of creating it till if/when it's needed instead of always incurring the cost.

Usually this is preferable when the object may or may not be used and the cost of constructing it is non-trivial.

  • 146
    why not just ALWAYS use Lazy?
    – TruthOf42
    Jun 11, 2013 at 13:33
  • 56
    It incurs the cost at first use and may use some locking overhead (or sacrifices thread safety if not) to do so. Thus, it should be chosen carefully and not used unless needed. Jun 11, 2013 at 20:23
  • 3
    James could you please expand on "and the cost of constructing is non-trivial"? In my case I have 19 properties in my class and in most cases only 2 or 3 will ever need to be looked at. Therefore I am considering implementing each property using Lazy<T>. However, to create each property I am doing a linear interpolation (or a bilinear interpolation) which is fairly trivial but does have some cost. (Are you going to suggest that I go and do my own experiment?)
    – Ben
    Jan 31, 2014 at 16:59
  • 3
    James, taking my own advice I did my own experiment. See my post.
    – Ben
    Jan 31, 2014 at 22:20
  • 26
    You may want to initialize/instantiate everything "during" system start-up to prevent user latency in high throughput, low latency systems. This is just one of the many reasons to not "always" use Lazy.
    – Derrick
    Sep 30, 2014 at 12:34

You should try to avoid using Singletons, but if you ever do need to, Lazy<T> makes implementing lazy, thread-safe singletons easy:

public sealed class Singleton
    // Because Singleton's constructor is private, we must explicitly
    // give the Lazy<Singleton> a delegate for creating the Singleton.
    static readonly Lazy<Singleton> instanceHolder =
        new Lazy<Singleton>(() => new Singleton());

        // Explicit private constructor to prevent default public constructor.

    public static Singleton Instance => instanceHolder.Value;
  • 49
    I hate reading You should try to avoid using Singletons when I'm using them :D ... now I need to learn why I should try to avoid them :D Aug 29, 2013 at 5:58
  • 42
    I'll stop using Singletons when Microsoft stops using them in their examples.
    – eaglei22
    May 2, 2017 at 17:16
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    I tend to disagree with the notion of needing to avoid Singletons. When following the dependency injection paradigm, it shouldn't matter either way. Ideally, all of your dependencies should only be created once. This reduces pressure on the GC in high load scenarios. Therefore, making them a Singleton from within the class itself is fine. Most (if not all) modern DI containers can handle it either way you choose. Jun 29, 2017 at 20:17
  • 2
    You dont have to use a singleton pattern like that, instead use any di container configure your class for singleton. The container will take care of the overhead for you.
    – VivekDev
    Nov 8, 2017 at 12:22
  • 5
    Everything has a purpose, there is situations where singletons are a good approach and situations where it is not :).
    – Hawkzey
    Mar 4, 2020 at 14:39

A great real-world example of where lazy loading comes in handy is with ORM's (Object Relation Mappers) such as Entity Framework and NHibernate.

Say you have an entity Customer which has properties for Name, PhoneNumber, and Orders. Name and PhoneNumber are regular strings but Orders is a navigation property that returns a list of every order the customer ever made.

You often might want to go through all your customer's and get their name and phone number to call them. This is a very quick and simple task, but imagine if each time you created a customer it automatically went and did a complex join to return thousands of orders. The worst part is that you aren't even going to use the orders so it is a complete waste of resources!

This is the perfect place for lazy loading because if the Order property is lazy it will not go fetch all the customer's order unless you actually need them. You can enumerate the Customer objects getting only their Name and Phone Number while the Order property is patiently sleeping, ready for when you need it.

  • 48
    Bad example, as such lazy loading is usually already built into the ORM. You shouldn't start to add Lazy<T> values to your POCOs to get lazy loading, but use the ORM-specific way to do that.
    – Dynalon
    May 23, 2013 at 5:42
  • 74
    @Dyna This example is referring to the built-in lazy loading of an ORM because I think this exemplifies the usefulness of lazy loading in a clear and simple way.
    – Despertar
    May 23, 2013 at 6:49
  • SO if you are making use of Entity Framework should one enforce their own lazy? Or does EF do it for you? Jan 14, 2014 at 9:17
  • 8
    @Zapnologica EF does all this for you by default. In fact, if you want eager loading (the opposite of lazy loading), you must explicitly tell EF by using Db.Customers.Include("Orders"). This will cause the order join to be executed at that moment rather than when the Customer.Orders property is first used. Lazy Loading can also be disabled via the DbContext.
    – Despertar
    Jan 15, 2014 at 0:18
  • 3
    Actually this is a good example, as one might want to add this functionality when using something like Dapper.
    – tbone
    Aug 26, 2015 at 21:58

I have been considering using Lazy<T> properties to help improve the performance of my own code (and to learn a bit more about it). I came here looking for answers about when to use it but it seems that everywhere I go there are phrases like:

Use lazy initialization to defer the creation of a large or resource-intensive object, or the execution of a resource-intensive task, particularly when such creation or execution might not occur during the lifetime of the program.

from MSDN Lazy<T> Class

I am left a bit confused because I am not sure where to draw the line. For example, I consider linear interpolation as a fairly quick computation but if I don't need to do it then can lazy initialisation help me to avoid doing it and is it worth it?

In the end I decided to try my own test and I thought I would share the results here. Unfortunately I am not really an expert at doing these sort of tests and so I am happy to get comments that suggest improvements.


For my case, I was particularly interested to see if Lazy Properties could help improve a part of my code that does a lot of interpolation (most of it being unused) and so I have created a test that compared 3 approaches.

I created a separate test class with 20 test properties (lets call them t-properties) for each approach.

  • GetInterp Class: Runs linear interpolation every time a t-property is got.
  • InitInterp Class: Initialises the t-properties by running the linear interpolation for each one in the constructor. The get just returns a double.
  • InitLazy Class: Sets up the t-properties as Lazy properties so that linear interpolation is run once when the property is first got. Subsequent gets should just return an already calculated double.

The test results are measured in ms and are the average of 50 instantiations or 20 property gets. Each test was then run 5 times.

Test 1 Results: Instantiation (average of 50 instantiations)

Class      1        2        3        4        5        Avg       %
GetInterp  0.005668 0.005722 0.006704 0.006652 0.005572 0.0060636 6.72
InitInterp 0.08481  0.084908 0.099328 0.098626 0.083774 0.0902892 100.00
InitLazy   0.058436 0.05891  0.068046 0.068108 0.060648 0.0628296 69.59

Test 2 Results: First Get (average of 20 property gets)

Class      1        2        3        4        5        Avg       %
GetInterp  0.263    0.268725 0.31373  0.263745 0.279675 0.277775 54.38
InitInterp 0.16316  0.161845 0.18675  0.163535 0.173625 0.169783 33.24
InitLazy   0.46932  0.55299  0.54726  0.47878  0.505635 0.510797 100.00

Test 3 Results: Second Get (average of 20 property gets)

Class      1        2        3        4        5        Avg       %
GetInterp  0.08184  0.129325 0.112035 0.097575 0.098695 0.103894 85.30
InitInterp 0.102755 0.128865 0.111335 0.10137  0.106045 0.110074 90.37
InitLazy   0.19603  0.105715 0.107975 0.10034  0.098935 0.121799 100.00


GetInterp is fastest to instantiate as expected because its not doing anything. InitLazy is faster to instantiate than InitInterp suggesting that the overhead in setting up lazy properties is faster than my linear interpolation calculation. However, I am a bit confused here because InitInterp should be doing 20 linear interpolations (to set up it's t-properties) but it is only taking 0.09 ms to instantiate (test 1), compared to GetInterp which takes 0.28 ms to do just one linear interpolation the first time (test 2), and 0.1 ms to do it the second time (test 3).

It takes InitLazy almost 2 times longer than GetInterp to get a property the first time, while InitInterp is the fastest, because it populated its properties during instantiation. (At least that is what it should have done but why was it's instantiation result so much quicker than a single linear interpolation? When exactly is it doing these interpolations?)

Unfortunately it looks like there is some automatic code optimisation going on in my tests. It should take GetInterp the same time to get a property the first time as it does the second time, but it is showing as more than 2x faster. It looks like this optimisation is also affecting the other classes as well since they are all taking about the same amount of time for test 3. However, such optimisations may also take place in my own production code which may also be an important consideration.


While some results are as expected, there are also some very interesting unexpected results probably due to code optimisations. Even for classes that look like they are doing a lot of work in the constructor, the instantiation results show that they may still be very quick to create, compared to getting a double property. While experts in this field may be able to comment and investigate more thoroughly, my personal feeling is that I need to do this test again but on my production code in order to examine what sort of optimisations may be taking place there too. However, I am expecting that InitInterp may be the way to go.

  • 36
    maybe you should post your test code for reproducing your output, because without knowing your code it will be hard to suggest anything
    – WiiMaxx
    Nov 27, 2014 at 11:04
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    I believe the main trade-off is between memory usage (lazy) and cpu usage (not-lazy). Because lazy has to do some extra book-keeping, InitLazy would use more memory than the other solutions. It also might have a minor performance hit on each access, while it checks whether it already has a value or not; clever tricks could remove that overhead, but it would require special support in IL. (Haskell does this by making every lazy value a function call; once the value is generated, it's replaced with a function which returns that value every time.)
    – jpaugh
    Aug 28, 2017 at 16:03

Just to expand upon the example posted by Matthew:

public sealed class Singleton
    // Because Singleton's constructor is private, we must explicitly
    // give the Lazy<Singleton> a delegate for creating the Singleton.
    private static readonly Lazy<Singleton> instanceHolder =
        new Lazy<Singleton>(() => new Singleton());

    private Singleton()

    public static Singleton Instance
        get { return instanceHolder.Value; }

Before the Lazy was part of the framework, we would have done it this way:

private static object lockingObject = new object();
public static LazySample InstanceCreation()
    if (lazilyInitObject == null)
         lock (lockingObject)
              if (lazilyInitObject == null)
                   lazilyInitObject = new LazySample();
    return lazilyInitObject;
  • 7
    I always use a IoC container for this.
    – Jowen
    Feb 2, 2015 at 13:57
  • 1
    I agree strongly on considering an IoC container for this. If however you want a simple lazy initialized object singleton also consider that if you do not need this to be thread safe doing it manually with an If may be best considering the performance overhead of how Lazy handles itself. Jul 2, 2015 at 6:28

From MSDN:

Use an instance of Lazy to defer the creation of a large or resource-intensive object or the execution of a resource-intensive task, particularly when such creation or execution might not occur during the lifetime of the program.

In addition to James Michael Hare's answer, Lazy provides thread-safe initialization of your value. Take a look at LazyThreadSafetyMode enumeration MSDN entry describing various types of thread safety modes for this class.


You should look this example to understand Lazy Loading architecture

private readonly Lazy<List<int>> list = new Lazy<List<int>>(() =>
    List<int> configList = new List<int>(Thread.CurrentThread.ManagedThreadId);
    return configList;
public void Execute()
    if (list.IsValueCreated)

        foreach (var item in list.Value)
        Console.WriteLine("Value not created");

--> output --> 0 1 2

but if this code dont write "list.Value.Add(0);"

output --> Value not created

  • This is a terrible example. Creating an empty List<T> is an extremely fast operation, and the List<T> is not thread-safe. There is no scenario where initializing lazily an empty List<T> would make sense. Nov 29, 2023 at 23:15

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