This article is part of a series on the SOLID design principles. You can start here or jump around using the links below!

S – Single Responsibility
O – Open/Closed Principle
L – Liskov Substitution Principle
I – Interface Segregation Principle
D – Dependency Inversion

The interface segregation principle can be a bit subjective at times, but the most common definition you will find out there is :

 No client should be forced to depend on methods it does not use

In simple terms, if you implement an interface in C# and have to throw NotImplementedExceptions you are probably doing something wrong.

While the above is the “definition”, what you will generally see this principle described as is “create multiple smaller interfaces instead of one large interface”. This is still correct, but that’s more of a means to achieve Interface Segregation rather than the principle itself.

Interface Segregation Principle In Practice

Let’s look at an example. If we can imagine that I have an interface called IRepository, and from this we are reading and writing from a database. For some data however, we are reading from a local XML file. This file is uneditable and so we can’t write to it (essentially readonly).

We still want to share an interface however because at some point we will move the data in the XML file to a database table, so it would be great if at that point we could just swap the XML repository for a database repository.

Our code is going to look a bit like this :

interface IRepository
{
    void WriteData(object data);
    object ReadData();
}

public class DatabaseRepository : IRepository
{
    public object ReadData()
    {
        //Go to the database and read data
        return new object();
    }

    public void WriteData(object data)
    {
        //Go to the database and write data
    }
}

public class XmlFileRepository : IRepository
{
    public object ReadData()
    {
        //Go to the database and read data
        return new object();
    }

    public void WriteData(object data)
    {
        //Don't allow a user to write data to the XML Repository.
        throw new NotImplementedException();
    }
}

Makes sense. But as we can see for our XMLFileRepository, because we don’t allow writing, we have to throw an exception (An alternative would to just have an empty method which is probably even worse). Clearly we are violating the Interface Segregation Principle because we are implementing an interface whose methods we don’t actually implement. How could we implement this more efficiently?

interface IReadOnlyRepository
{
    object ReadData();
}

interface IRepository : IReadOnlyRepository
{
    void WriteData(object data);
}

public class DatabaseRepository : IRepository
{
    public object ReadData()
    {
        //Go to the database and read data
        return new object();
    }

    public void WriteData(object data)
    {
        //Go to the database and write data
    }
}

public class XmlFileRepository : IReadOnlyRepository
{
    public object ReadData()
    {
        //Go to the database and read data
        return new object();
    }
}

interface IReadRepository
{
    object ReadData();
}

interface IWriteRepository
{
    void WriteData(object data);
}

public class DatabaseRepository : IReadRepository, IWriteRepository
{
    public object ReadData()
    {
        //Go to the database and read data
        return new object();
    }

    public void WriteData(object data)
    {
        //Go to the database and write data
    }
}

public class MyService
{
    //What if this service also writes? I have to inject the write repository as well?
    public MyService(IReadRepository readRepository, IWriteRepository writeRepository) 
    {

    }
}

This article is part of a series on the SOLID design principles. You can start here or jump around using the links below!

S – Single Responsibility
O – Open/Closed Principle
L – Liskov Substitution Principle
I – Interface Segregation Principle
D – Dependency Inversion

What Is The Liskov Principle?

The Liskov Principle has a simple definition, but a hard explanation. First, the definition :

Types can be replaced by their subtypes without altering the desirable properties of the program.

So basically if I have something like this :

class MyType
{
    //Some code here
}

class MySubType : MyType
{
    //Some code here
}

class MyService
{
    private readonly MyType _myType;

    public MyService(MyType myType)
    {
        _myType = myType;
    }
}

If in the future I decide that MyService should depend on MySubType instead of MyType, theoretically I shouldn’t alter “the desirable properties of the program”. I put that in quotes because what does that actually mean? A large part of inheritance is extending functionality and therefore by definition it will alter the behaviour of the program in some way.

That last part might be controversial because I’ve seen plenty of examples of Liskov that state that overriding a method in a sub class (which is pretty common) to be a violation of the principle but I feel like in reality, that’s just going to happen and isn’t a design flaw. For example :

class MyType
{
    public virtual void DoSomething()
    {

    }
}

class MySubType : MyType
{
    public override void DoSomething()
    {
        //Do some extended functionality. 

        //Maybe I leave this here. But should it go at the start or at the end?
        base.DoSomething();
    }
}

Is this a violation? It could be because substituting the subtype may not “break” functionality, but it certainly changes how the program functions and could lead to unintended consequences. Some would argue that Liskov is all about behavioural traits, which we will look at later, but for now let’s look at some “hard” breaks. e.g. Things that are black and white wrong.

Liskov On Method Signatures

The thing is, C# is actually very hard to violate Liskov and that’s why you might find that examples out there are very contrived. Indeed, for the black and white rules that we will talk about below, you’ll notice that they are things that you really need to go out of your way (e.g. ignore compiler warnings) to break. (And don’t worry, I’ll show you how!).

Our black and white rules that no one will argue with you on Stackoverflow about are….

A method of a subclass can accept a parent type as a parameter (Contravariance)

The “idea” of this is that a subclass can override a method and accept a more general parameter, but not the opposite. So for example in theory Liskov allows for something like this :

class MyParamType
{

}
class MyType
{
    public virtual void DoSomething(MyParamType something)
    {

    }
}

class MySubType : MyType
{
    public override void DoSomething(object something)
    {
    }
}

But actually if you try this, it will blow up because in C# when overriding a method the method signature must be exactly the same. Infact if we remove the override keyword it just acts as a method overload and both would be available to someone calling the MySubType class.

A method of a subclass can return a sub type as a parameter (Covariance)

So almost the opposite of the above, when we return a type from a method in a subclass, Liskov allows it to be “more” specific than the original return type. So again, theoretically this should be OK :

class MyReturnType
{

}
class MyType
{
    public object DoSomething()
    {
        return new object();
    }
}

class MySubType : MyType
{
    public MyReturnType DoSomething()
    {
        return new MyReturnType();
    }
}

This actually compiles but we do get a warning :

'MySubType.DoSomething()' hides inherited member 'MyType.DoSomething()'. Use the new keyword if hiding was intended.

Yikes. We can get rid of this error message by following the instruction and changing our SubType to the following :

class MySubType : MyType
{
    public new MyReturnType DoSomething()
    {
        return new MyReturnType();
    }
}

Pretty nasty. I can honestly say in over a decade of using C#, I have never used the new  keyword to override a method like this. Never. And I feel like if you are having to do this, you should stop and think if there is another way to do it.

But the obvious issue now is that anything that was expecting an object back is now getting this weird “MyReturnType” back. Exceptions galore will soon follow. This is why it makes it to a hard rule because it’s highly likely your code will not compile doing this.

Liskov On Method Behaviours

Let’s jump into the murky waters on how changing the behaviour of a method might violate Liskov. As mentioned earlier, I find this a hard sell because the intention of overriding a method in C#, when the original is marked as virtual, is that you want to change it’s behaviour. It’s not that C# has been designed as an infallible language, but there are pros to inheritance.

Our behavioural rules are :

Eceptions that would not be thrown normally in the parent type can’t then be thrown in the sub type

To me this depends on your coding style but does make sense in some ways. Consider the following code :

class MyType
{
    public virtual void DoSomething()
    {
        throw new ArgumentException();
    }
}

class MySubType : MyType
{
    public override void DoSomething()
    {
        throw new NullReferenceException();
    }
}

If you have been using the original type for some time, and you are following the “Gotta catch ’em all” strategy of exceptions and trying to catch each and every exception, then you may be intending to catch the ArgumentException. But now when you switch to the subtype, it’s throwing a NullReferenceException which you weren’t expecting.

Makes sense, but the reality is that if you are overriding a method to change the behaviour in some way it’s an almost certainty that new exceptions will occur. I’m not particularly big on this rule, but I can see why it exists.

Pre-Conditions cannot be strengthened and Post-Conditions cannot be weakened in the sub type

Let’s look at pre-conditions first. The idea behind this is that if you were previously able to call a method with a particular input parameter, new “rules” should not be in place that now rejects those parameters. A trivial example might be :

class MyType
{
    public virtual void DoSomething(object input)
    {
    }
}

class MySubType : MyType
{
    public override void DoSomething(object input)
    {
        if (input == null)
            throw new NullReferenceException();
    }
}

Where previously there was no restriction on null values, there now is.

Conversely, we shouldn’t weaken the ruleset for returning objects. For example :

class MyType
{
    public virtual object DoSomething()
    {
        object output = null;
        //Do something

        //If our ouput it still null, return a new object. 
        return output ?? new object();
    }
}

class MySubType : MyType
{
    public override object DoSomething()
    {
        object output = null;
        //Do something
        return output;

    }
}

We could previously rely on the return object never being null, but now we may be returned a null object.

Similar to the exceptions rule, it makes sense that when extending behaviour we might have no choice but to change how we handle inputs and outputs. But unlike the exceptions rule, I really like this rule and try and abide by it.

Limiting General Behaviour Changes

I just want to quickly show another example that possibly violates the Liskov principle, but is up to interpretation. Take a look at the following code :

class Jar
{
    public virtual void Pour()
    {
        //Pour out the jar. 
    }
}

class JarWithLid : Jar
{
    public bool IsOpen { get; set; }

    public override void Pour()
    {
       if(IsOpen)
       {
            //Only pour if the jar is open. 
       }
    }
}

A somewhat trivial example but if someone is depending on the class of “Jar” and calling Pour, everything is going fine. But if they then switch to using JarWithLid, their code will no longer function as intended because they are required to open the Jar first.

In some ways, this is covered by the “pre-Conditions cannot be strengthened” rule. It’s clearly adding a pre-existing condition that the jar must be opened before it can be poured. But on the other hand, in a more complex example a method may be hundreds of lines of code and have various new behaviours that affect how the caller might interact with the object. We might classify some of them as “pre-conditions” but we may also just classify them as behavioural changes that are inline with typical inheritance scenarios.

Overall, I feel like Liskov principle should be about limiting “breaking” changes when swapping types for subtypes, whether that “breaking” change is an outright compiler error, logic issue, or unexpected behavioural change.

What’s Next?

Up next is the I in SOLID. That is, The Interface Segregation Principle.

This article is part of a series on the SOLID design principles. You can start here or jump around using the links below!

S – Single Responsibility
O – Open/Closed Principle
L – Liskov Substitution Principle
I – Interface Segregation Principle
D – Dependency Inversion

What Is The Open/Closed Principle?

Like our post on Single Responsibility, let’s start off with the Wikipedia definition of the Open/Closed Principle :

Software entities (classes, modules, functions, etc.) should be open for extension, but closed for modification

Probably not that helpful to be honest. It’s sort of an open ended statement that could be taken to mean different things for different developers.

In looking at resources for this article, I actually found many write ups talking about how being able to substitute one implementation of an interface for another was an example of being Open/Closed, and indeed Wikipedia touches on this :

During the 1990s, the open/closed principle became popularly redefined to refer to the use of abstracted interfaces, where the implementations can be changed and multiple implementations could be created and polymorphically substituted for each other.

I’m not the right person to start redefining decades of research into software design, but I personally don’t like this definition as I feel like it very closely resembles the Liskov Principle (Which we will talk about in our next article in this series). Instead I’ll describe it more loosely as :

Can I extend this code and add more functionality without modifying the original code in any way.

I’m going to take this explanation and run with it.

Open/Closed Principle In Practice

Let’s take our code example that we finished with from the Single Responsibility article. It ended up looking like this :

public class RegisterService
{
	private readonly IUserRepository _userRepository;
	private readonly IEmailService _emailService;

	public RegisterService(IUserRepository userRepository, IEmailService emailService)
	{
		_userRepository = userRepository;
		_emailService = emailService;
	}

	public void RegisterUser(string username)
	{
		if (username == "admin")
			throw new InvalidOperationException();

		_userRepository.Insert(new UserModel());

		_emailService.SendEmail(new Email())
	}
}

Looks OK. But what happens if we want to also check other usernames and reject the registration if they fail? We might end up with a statement like so :

if (username == "admin" || username == "administrator")
	throw new InvalidOperationException();

Is this just continue on forever? Each time we are actually modifying the logic of our app and we are probably going to have to regression test that past use cases are still valid every time we edit this method.

So is there a way to refactor this class so that we are able to add functionality (Add blacklisted usernames for example), but not have to modify the logic every time?

How about this! We create an interface that provides a list of Blacklisted Usernames :

public interface IRegistrationServiceConfiguration
{
    public List<string> BlacklistedUsernames { get; }
}

Then we inject this into our RegisterService class and modify our register method to simply check against this list.

public class RegisterService
{
    private readonly IUserRepository _userRepository;
    private readonly IEmailService _emailService;
    private readonly IRegistrationServiceConfiguration _registrationServiceConfiguration;

    public RegisterService(IUserRepository userRepository, IEmailService emailService, IRegistrationServiceConfiguration registrationServiceConfiguration)
    {
        _userRepository = userRepository;
        _emailService = emailService;
        _registrationServiceConfiguration = registrationServiceConfiguration;
    }

    public void RegisterUser(string username)
    {
        if (_registrationServiceConfiguration.BlacklistedUsernames.Contains(username))
            throw new InvalidOperationException();

        _userRepository.Insert(new UserModel());

        _emailService.SendEmail(new Email())
    }
}

Better right? Not only have we removed having hardcoded strings in our code (which is obviously beneficial), but now when we extend that list out of usernames we don’t want to allow, our code actually doesn’t change at all.

This is the Open/Closed Principle.

Extending Our Example

The thing is, we’ve taken a list of hardcoded strings and made them be more configuration driven. I mean yeah, we are demonstrating the principle correctly, but we are probably also just demonstrating that we aren’t a junior developer. Let’s try and take our example that one step further to make it a bit more “real world”.

What if instead of just checking against a blacklisted set of usernames, we have a set of “pre-registration checks”. These could grow over time and we don’t want to have a huge if/else statement littered through our method. For example changing our code to look like this would be a bad idea :

public void RegisterUser(string username)
{
    if (_registrationServiceConfiguration.BlacklistedUsernames.Contains(username))
        throw new InvalidOperationException();

    if (_userRepository.CheckUserExists(username))
        throw new InvalidOperationException("User already exists");

    _userRepository.Insert(new UserModel());

    _emailService.SendEmail(new Email())
}

How many statements are we going to add like this? And each time we are subtly changing the logic for this method that requires even more regression testing.

How about this instead, let’s create an interface for registration pre checks and implement it like so :

public interface IRegistrationPreCheck
{
    void Check(string username);
}

public class RegistrationPreCheckBlacklistedUsernames : IRegistrationPreCheck
{
    private readonly IRegistrationServiceConfiguration _registrationServiceConfiguration;

    public RegistrationPreCheckBlacklistedUsernames(IRegistrationServiceConfiguration registrationServiceConfiguration)
    {
        _registrationServiceConfiguration = registrationServiceConfiguration;
    }

    public void Check(string username)
    {
        if (_registrationServiceConfiguration.BlacklistedUsernames.Contains(username))
            throw new InvalidOperationException();
    }
}

Now we can modify our RegisterService class to instead take a list of pre checks and simply check all of them in our RegisterUser method :

public class RegisterService
{
    private readonly IUserRepository _userRepository;
    private readonly IEmailService _emailService;
    private readonly IEnumerable<IRegistrationPreCheck> _registrationPreChecks;

    public RegisterService(IUserRepository userRepository, IEmailService emailService, IEnumerable<IRegistrationPreCheck> registrationPreChecks)
    {
        _userRepository = userRepository;
        _emailService = emailService;
        _registrationPreChecks = registrationPreChecks;
    }

    public void RegisterUser(string username)
    {
        _registrationPreChecks.ToList().ForEach(x => x.Check(username));

        _userRepository.Insert(new UserModel());

        _emailService.SendEmail(new Email())
    }
}

Now if we add another pre-check, instead of changing the logic of our RegisterUser method, we just add it to the list of pre-checks passed into the constructor and there is no modification necessary. This is probably a better example of the Open/Closed Principle that demonstrates the ability to add functionality to a class that doesn’t require changes to the existing logic.

What’s Next?

Up next is the L in SOLID. That is, The Liskov Principle.

This article is part of a series on the SOLID design principles. You can start here or jump around using the links below!

S – Single Responsibility
O – Open/Closed Principle
L – Liskov Substitution Principle
I – Interface Segregation Principle
D – Dependency Inversion

What Is SOLID?

SOLID is a set of 5 design principles in software engineering intended to make software development more flexible, easier to maintain, and easier to understand. While sometimes seen as a “read up on this before my job interview” type of topic, SOLID actually has some great fundamentals for software design that I think is applicable at all levels. For example, I commonly tell my Intermediate developers that when doing a code review, don’t think about “How would I implement this?” but instead “Does this follow SOLID principles?”. Not that things are ever as black and white as that, but it forms a good starting point for looking at software design objectively.

Like all “patterns” and “principle” type articles. Nothing should be taken as being “do this or else”, but hopefully throughout this series we can take a look at the SOLID principles at a high level, and you can then take that and see how it might apply to your day to day programming life. First up is the “Single Responsibility Principle”.

What Is Single Responsibility?

I remember reading a definition of Single Responsibility as being :

A class should have only one reason to change

And all I could think was… And what is that reason? Was the quote cut off? Was there more to this?

And I don’t think I’m alone. I feel like this definition is a somewhat backwards way of saying what we probably all intuitively think of when we see “Single Responsibility”. But once we explore the full picture, it’s actually quite a succinct way of describing the principle. Let’s dive right in.

Single Responsibility In Practice

If we can, let’s ignore the above definition for a moment and look at how the single responsibility principle would actually work in practice.

Say I have a class that registers a new user on my website. The service might look a bit like so :

public class RegisterService
{
    public void RegisterUser(string username)
    {
        if (username == "admin")
            throw new InvalidOperationException();

        SqlConnection connection = new SqlConnection();
        connection.Open();
        SqlCommand command = new SqlCommand("INSERT INTO [...]");//Insert user into database. 

        SmtpClient client = new SmtpClient("smtp.myhost.com");
        client.Send(new MailMessage()); //Send a welcome email. 
    }
}

Pretty simple :

• Check to see if the user is an admin, if it is throw an exception.
• Open a connection to the database and insert that user into it.
• Send a welcome email.

How does this violate the single responsibility principle? Well while theoretically this is doing “one” thing in that it registers a user, it’s also handling various parts of that process at a low level.

• It’s controlling how we connect to a database, opening a database connection, and the SQL statement that goes along with it.
• It’s controlling how the email is sent. Specifically that we are using a direct connection to an SMTP server and not using a third party API or similar to send an email.

It can become a bit of a “splitting hairs” type argument and I’ve intentionally left the logic statement for checking the username in there as a bit of a red herring. I mean theoretically you could get to the point where you go One Class -> One Method -> One Line. So you have to use your judgement and in my opinion, the admin check there is fine (But feel free to disagree!).

Another way to look at it is the saying “Are we doing one thing only, and doing that one thing well”. Well we are directing the flow of registering a user well, but we are also doing a bunch of database/SMTP work mixed in with it that frankly we probably aren’t doing “well”.

A Class Should Have Only One Reason To Change

Let’s get back to our original definition.

A class should have only one reason to change

If we take the above code, what things could come up that would cause us to have to rewrite/change this code?

• The flow of registering a user changes
• The restricted usernames change
• The database schema/connection details change (Connection String, Table Schema, Statement changes to a Stored Proc etc)
• We stop using a SQL database all together for storing users and instead use a hosted solution (Auth0, Azure B2C etc)
• Our SMTP/Email details change (From Email, Subject, Email contents, SMTP server etc)
• We use a third party API to send emails (Sendgrid for example)

So as we can see, there are things that could change that have absolutely nothing about registering a user. If we move to using a different method of sending emails, we are going to edit the “RegisterUser” method? Doesn’t make sense right!

While the statement of having only “one” reason to change might be extreme, we should work towards abstracting code so that changes unrelated to our core responsibility of registering users affects minimal change to our code. The only reason why our class should change is because the way in which users register changes. But changes to how we send emails or which database we decide to use shouldn’t change the RegisterService at all.

With that in mind, what we would typically end up with is something like so :

public void RegisterUser(string username)
{
	if (username == "admin")
		throw new InvalidOperationException();

	_userRepository.Insert(...);
	
	_emailService.Send(...);
}

You probably already have code like this so it’s not going to be ground breaking stuff. But having split out code into separate classes, we are now on our way to abiding by the statement “A class should only have one reason to change”.

What Does Single Responsibility Give Us?

It’s all well and good throwing out names of patterns and principles, but what is the actual effect of Single Responsibility?

• Code being broken apart with each class having a single purpose makes code easier to maintain, easier to read, and easier to modify.
• Unit testing code suddenly becomes easier when a class is trying to only do one thing.
• A side effect of this means that code re-useability jumps up as you are splitting code into succinct blocks that other classes can make use of.
• The complexity of a single class often goes drastically down because you only have to worry about “one” piece of logic (For example how a user is registered, rather than also worrying about how an email is sent).

Simply put, splitting code up into smaller chunks where each piece just focuses on the one thing it’s supposed to be doing makes a developers life a hell of a lot easier.

What’s Next?

Up next is the O in SOLID. That is, The Open/Closed Principle.

Similar to the Singleton and Mediator Patterns, the Factory Pattern is part of the “Gang Of Four” design patterns that basically became the bible of patterns in OOP Programming.

The Factory Pattern is a type of “Creational Pattern” that deals with the problem of creating an object when you aren’t quite sure on the “requirements” to create said object. That’s probably a little bit of a confusing way to explain it. But in general, think of it like a class that’s sole purpose when called, is to create an object and return it to you and you don’t need to know “how” the creation of that object actually happens.

The Factory Pattern In C#

Let’s drive right in. First, let’s look at a plain C# example in code :

public interface IVehicle
{
    VehicleType VehicleType { get; }
    int WheelCount { get; }
}

public class Car : IVehicle
{
    public VehicleType VehicleType => VehicleType.Car;
    public int WheelCount => 4;
}

public class Motorbike : IVehicle
{
    public VehicleType VehicleType => VehicleType.Motorbike;
    public int WheelCount => 2;
}

public enum VehicleType
{
    Car, 
    Motorbike
}

class VehicleFactory
{
    public IVehicle Create(VehicleType vehicleType)
    {
        switch(vehicleType)
        {
            case VehicleType.Car:
                return new Car();
            case VehicleType.Motorbike:
                return new Motorbike();
            default:
                throw new NotImplementedException();
        }
    }
}

Let’s walk through bit by bit.

First, we have an interface called IVehicle which is implemented by both the Car and Motorbike classes. We also have a vehicle enum type which we later use in our factory.

Next comes our actual factory. This has a single method called “Create” on it. I personally prefer my factories to only ever have a single method called “Create” just to keep them simple. It takes in a vehicle type and spits out an instance of a vehicle.

Now the point here is that the caller to the factory doesn’t need to know “how” we are creating these objects, just that it can call them and it will get back the “right” one. It doesn’t need to know that it can simply call “new Car()” to get a car, maybe the creation of a car is actually more complex than that, but it let’s the factory work it out. Let’s illustrate that further…

Illustrating The Abstraction

Let’s take our above example and imagine we add another vehicle type. But it’s a complex one. Infact, we are adding a “Quad Bike”.

public enum VehicleType
{
    Car, 
    Motorbike, 
    QuadBike
}

Now we actually want our QuadBike to still return a MotorBike object, just with a few changes. For that, we change our Motorbike object to the following :

public class Motorbike : IVehicle
{
    public Motorbike(bool isQuadBike)
    {
        VehicleType = isQuadBike ? VehicleType.QuadBike : VehicleType.Motorbike;
        WheelCount = isQuadBike ? 4 : 2;
    }

    public VehicleType VehicleType { get; private set; }
    public int WheelCount {get; private set;}
}

Now imagine if everyone who was already creating motorbikes now needed to change their creation to pass in false. But with our handy factory…

class VehicleFactory
{
    public IVehicle Create(VehicleType vehicleType)
    {
        switch(vehicleType)
        {
            case VehicleType.Car:
                return new Car();
            case VehicleType.Motorbike:
                return new Motorbike(false);
            case VehicleType.QuadBike:
                return new Motorbike(true);
            default:
                throw new NotImplementedException();
        }
    }
}

So we’ve actually completely changed how the creation of an object happens, but because it’s abstracted away behind a factory, we don’t need to worry about any of it (Well… except to change the factory itself). That’s essentially the factory in a nutshell. Let’s look at how .NET Core makes use of this pattern in a different way.

Factories In The .NET Core Service Collection

You may be here because you’ve seen the intellisense for “implementationFactory” popup when using .NET Core’s inbuilt dependency injection :

So in this context what does factory mean? Actually… The exact same thing as above.

Let’s say I have a service that has a simple constructor that takes one parameter. This is pretty common when you are using a third party library and don’t have much control over modifying a constructor to your specific needs.  Let’s say the service looks like so :

public class MyService
{
    public MyService(bool constructorParam)
    {

    }
}

If we bound this service in our service collection like so :

services.AddTransient<MyService, MyService>();

That’s not gonna fly. The only constructor available has a boolean parameter, and there are no parameterless constructors to use. So we have two options, we can use some janky injection for the boolean value or we can create a factory to wrap the constructor.

Similar to the above, we can actually create a real factory that has a Create method that returns our object :

public static class MyServiceFactory
{
    public static MyService Create(IServiceProvider serviceProvider)
    {
        return new MyService(true);
    }
}

And we bind it like so :

services.AddTransient<MyService>(MyServiceFactory.Create);

Now whenever MyService is requested, our factory method will run. If creating a full on factory is a bit much, you can just create the Func on the fly in your AddTransient call :

services.AddTransient<MyService>((serviceProvider) => new MyService(true));

The use case for a “factory” here can be a little different because you might have an actual need to constantly create the object using a custom method at runtime and that’s why you are binding a custom method to create your object, compared to the “pattern” of abstracting away your constructor, but both can be called the “Factory Pattern”.

When Should I Use The Factory Pattern?

Dependency Injection/Inversion has at times taken the wind out of the sails of the factory pattern. Loading up a constructor with dependencies isn’t such a big deal because the caller is typically depending on an interface, and dependency injection is taking care of the rest.

However, I do typically end up using a factory when the creation of an object is dependent on runtime variables/state and I want to contain this logic in a parameter. Aslong as you know what the factory pattern is and don’t try and “force” it anywhere it shouldn’t be, you will find it comes in useful a couple of times in ever .NET project.

I recently made an appearance on an Adventures In .NET Podcast. The podcast is ran by devchat.tv who you may also know from the Javascript Jabber podcast (As well as a tonne of other really great programming podcasts!).

I was a bit of a last minute guest so a whole range of topics are discussed all the way from how I got into programming, how this blog started, and the things I’m most excited about in the .NET Core 3.0 release. You can check out the podcast from :

• Adventures in .NET Website
• Stitcher
• iTunes

Or just use the player below!

This article is part of a series on creating Windows Services in .NET Core.

Part 1 – The “Microsoft” Way
Part 2 – The “Topshelf” Way
Part 3 – The “.NET Core Worker” Way

In our previous piece on creating Windows Services in .NET Core, we talked about how to do things the “Microsoft” way. What we found was that while it was simple to get up and running, it was much harder to debug our service. Infact I would say borderline impossible.

And that’s where Topshelf comes in. Topshelf is a .NET Standard library that takes a tonne of the hassle out of creating Windows Services in both .NET Framework and .NET Core. But rather than recite the sales pitch to you, let’s jump right in!

Setup

Similar to our “Microsoft” method, there is no Windows Service or Topshelf “Visual Studio Template”. We instead just create a regular old .NET Core console application.

Then from our Package Manager Console, we run the following to install the Topshelf libraries.

Install-Package Topshelf

The Code

We essentially want to recreate our previous code sample to work with Topshelf. Here’s how we do that :

public class LoggingService : ServiceControl
{
    private const string _logFileLocation = @"C:\temp\servicelog.txt";

    private void Log(string logMessage)
    {
        Directory.CreateDirectory(Path.GetDirectoryName(_logFileLocation));
        File.AppendAllText(_logFileLocation, DateTime.UtcNow.ToString() + " : " + logMessage + Environment.NewLine);
    }

    public bool Start(HostControl hostControl)
    {
        Log("Starting");
        return true;
    }

    public bool Stop(HostControl hostControl)
    {
        Log("Stopping");
        return true;
    }
}

All rather simple.

We inherit from the “ServiceControl” class (Which isn’t actually needed but it just provides a good base for us to work off). We have to implement the two methods to start and stop, and we just log those methods as we did before.

In our Main method of program.cs, it’s actually really easy. We can just use the HostFactory.Run method to kick off our service with minimal effort :

static void Main(string[] args)
{
    HostFactory.Run(x => x.Service<LoggingService>());
}

Crazy simple. But that’s not the only thing HostFactory can do, for example I may want to say that when my service crashes, I want to restart the service after 10 seconds, give it a nicer name, and set it to start automatically.

static void Main(string[] args)
{
    HostFactory.Run(x =>
        {
            x.Service<LoggingService>();
            x.EnableServiceRecovery(r => r.RestartService(TimeSpan.FromSeconds(10)));
            x.SetServiceName("TestService");
            x.StartAutomatically();
         }
    );
}

I could go on and on but just take a look through the Topshelf documentation for some configuration options. Essentially anything you would normally have to painfully do through the windows command line, you can set in code : https://topshelf.readthedocs.io/en/latest/configuration/config_api.html

Deploying Our Service

Same as before, we need to publish our app specifically for a Windows environment. From a command prompt, in your project directory, run the following :

dotnet publish -r win-x64 -c Release

Now we can check out the output directory at bin\Release\netcoreappX.X\win-x64\publish and we should find that we have a nice little exe waiting for us to be installed.

Previously we would use typical SC windows commands to install our service, but Topshelf utilizes it’s own command line parameters for installing as a service. Almost all configuration that you can do in code you can also do from the command line (Like setting recovery options, service name/description etc). You can check out the full documentation here :

For us, we are just going to do a bog standard simple install. So in our output directory, I’m going to run the following from the command line : http://docs.topshelf-project.com/en/latest/overview/commandline.html

WindowsServiceExample.exe install

Where WindowsServiceExample.exe is my project output. All going well my service should be installed! I often find that even when setting the service to startup automatically, it doesn’t always happen. We can actually start the service from the command line after installation by running :

WindowsServiceExample.exe start

In deployment scenarios I often find I have to install the service, wait 10 seconds, then attempt to start it using the above and we are away laughing.

Debugging Our Service

So when doing things the “Microsoft” way, we ran into issues around debugging. Mostly that we had to either use command line flags, #IF DEBUG directives, or config values to first work out if we are even running inside a service or not. And then find hacky ways to try and emulate the service from a console app.

Well, that’s what Topshelf is for!

If we have our code open in Visual Studio and we just start debugging (e.g. Press F5), it actually emulates starting the service in a console window. We should be met with a message saying :

The TestService service is now running, press Control+C to exit.

This does exactly what it says on the tin. It’s started our “service” and runs it in the background as if it was running as a Windows Service. We can set breakpoints as per normal and it will basically follow the same flow as if it was installed normally.

We can hit Ctrl+C and it will close our application, but not before running our “Stop” method of our service, allowing us to also debug our shutdown procedure if required. Compared to debug directives and config flags, this is a hell of a lot easier!

There is just one single gotcha to look out for. if you get a message similar to the following :

The TestService service is running and must be stopped before running via the console

This means that the service you are trying to debug in Visual Studio is actually installed and running as a Windows Service on the same PC. If you stop the Windows Service from running (You don’t have to uninstall, just stop it), then you can debug as normal.

What’s Next

A helpful reader pointed out in the previous article that .NET Core actually has a completely different way of running Windows Services. It essentially utilizes the “Hosted Services” model that has been introduced into ASP.NET Core and allows them to run as Windows Services which is pretty nifty!

While helping a friend get used to EF Core, I noticed that he wasn’t using “Projections” in his LINQ code. That is, he was essentially doing a “SELECT *” and grabbing the entire model instead of just getting the few fields he needed.

“You’ll create a lot of Key Lookups doing that though…”
“What’s a Key Lookup?”

I guess I had forgotten that people starting software development these days often think that they don’t need to learn SQL because they have a fan-dangle ORM that does all the heavy lifting for them! So this is for them. Here’s what a Key Lookup is from a developer’s perspective!

This is a pretty light explanation because it reads more like a brain dump trying to help a friend understand what I’m saying rather than a tutorial, but it should be a great kickstart.

An Index Tuning Crash Course

The easiest way to understand a key lookup is to understand how indexes get used. We’ll start that by creating a table that looks like so :

Id		INT
FirstName	NVARCHAR(250)
LastName	NVARCHAR(250)
Birthday	DATETIME

You don’t need to actually create this table as we’ll be just looking at the theory more than anything!

Now let’s say that we want to find all lastnames where someone has a firstname of “John”. We know that our SQL would look like :

SELECT LastName FROM Person WHERE FirstName = 'John'

Now we probably already know that if we have a WHERE clause on a non-PK column, we are going to want to create an index so we can find the data easier. A beginner developer might think that the following index is suitable :

CREATE NONCLUSTERED INDEX IX_Person_FirstName 
ON Person (FirstName)

Afterall, we’ve now created an index on the Person table with “FirstName”. But with a large amount of data in this table, and us running that query again, we can check the execution path and see the following :

So we get our seek on our index, but for some reason we then do what’s called a “Key Lookup” back on our Clustered Index. Why?

If we mouse over the Key Lookup and look at the “Output List”, it tells us what it was trying to find. In this case, it’s the “LastName”.

What has happened is that our query asks for the LastName of a person, where the Firstname is John. It can query on our index to find people named John, but once it finds them, because our index only contains Firstname (And by default the Id), it has to go back to the Clustered Index to actually find the data we want.

What we can instead do is change our index to “Include” the LastName column. The Include keyword tells SQL that we want the “data” of the column included in the index, but it doesn’t actually need to be searchable. Essentially exactly what our query is doing. It’s “searching” on FirstName, but actually needs the “data” LastName.

CREATE NONCLUSTERED INDEX IX_Person_FirstName_I_LastName 
ON Person (FirstName) INCLUDE (LastName)

Notice that we also renamed the Index to include what columns we are using in the “Include”. This is something I like to do but it can get unweildy as you add columns so your mileage could vary.

If we re-run this query and check the execution plan :

We are now going to the index, getting the exact data we need and returning. We don’t need to go anywhere else to fetch our data because it’s right there in the index.

Over Selecting And SELECT *

So that brings us to what I call Over Selecting and the notorious SELECT * issue. If we think about the above, what if instead of just getting the LastName, let’s say I ran the following :

SELECT * FROM Person WHERE FirstName = 'John'

Well now we are back to doing Key Lookups even if we include LastName in the index because we are missing DateOfBirth in the Index. Since it will be included in the SELECT * result set even if we don’t use it in our C# code, we would need to add it in.

But then we add another column. So we have to add that to the Index. And repeat. But are we even using those extra fields? And our index is getting pretty big now, and BLAH.

This is the key reason (for me atleast), why I only select the exact columns I need and never use SELECT *

Memory Footprint And Data Transfer

While I won’t dive into it too much, SELECT * also has performance implications just because of the amount of wasted data you are both fetching and transfering. Even if it’s in the Index, you are working with data you actually don’t need.

Here’s a great article on the amazingly named blog “Use The Index Luke” : https://use-the-index-luke.com/blog/2013-08/its-not-about-the-star-stupid. It should hopefully explain it 10x better than I ever could.

The thing is, once you start digging into SQL performance you’ll quickly realize that there are all these performance counters that you *could* measure, but you’ll have no idea which ones you *should* measure. A really good overview of all things performance monitoring can be found here in this article : 15 SQL Server Performance Counters to Monitor.

Projecting Entities

Here is where I would normally write about the zillion ways to “Project Entities” in EF Core so that you don’t run into Key Lookups, but while having a quick google around for what’s out there already, I found this incredible tutorial on Projection Magic For EF Core : https://benjii.me/2018/01/expression-projection-magic-entity-framework-core/

Again, written a heck of a lot better than I could and it’s a great reference any time you are struggling with complex projections.

An Actual SQL Tutorial

Where did I learn all of this? By the SQL Master himself “Pinal Dave” on PluralSight over here : https://www.pluralsight.com/courses/query-tuning-introduction. If the name Pinal Dave doesn’t ring a bell, his website (https://blog.sqlauthority.com/) probably does. You can’t google a SQL error message without his blog showing up on the first page. The course on Pluralsight does a great job of explaining complex SQL tuning topics in bite size chunks (Often less than 5 minutes at a time), and I highly recommend it.

This article is part of a series on creating Windows Services in .NET Core.

Part 1 – The “Microsoft” Way
Part 2 – The “Topshelf” Way
Part 3 – The “.NET Core Worker” Way

Creating Windows Services to do batch jobs or in general do background work used to be a pretty common pattern, but you don’t often come across them anymore due to the proliferation of cloud services such as Amazon Lambda, Azure WebJobs or Azure Functions taking their place. Personally, I’m a big fan of using Azure WebJobs these days as it basically means I can write a console application without any thought to running it in the cloud, and then with a single batch file, turn it into an automated job that can run 24/7.

But maybe you’re still on bare metal. Or maybe you have a bunch of legacy apps that are running as Windows Services that you want to convert to .NET Core, but not go the whole way to converting them to “serverless”. This is the tutorial for you.

In many respects, a Windows Service in .NET Core is exactly the same as one in .NET Framework. But there are a few little tricks that you might stumble across along the way. Furthermore, there is the “Microsoft” way of building a Windows Service which we will look at in this article, and 3rd party libraries such as TopShelf that make the process much easier (We will look at Topshelf in Part 2).

Setup

There is no Visual Studio “template” for creating a Windows Service, so instead create a regular .NET Core console application project.

Once created, we need to install a nuget package that adds in a bunch of Windows specific API’s into .NET Core. These are API’s that are actually already available in full framework, but many of them are very specific to Windows e.x. Windows Services. For that reason they aren’t in the .NET Core base, but can be added via a single handy dandy package. (You can read more about the package here : https://devblogs.microsoft.com/dotnet/announcing-the-windows-compatibility-pack-for-net-core/)

Let’s go ahead and run the following from our Package Manager Console :

Install-Package Microsoft.Windows.Compatibility

The Code

What we are most interested in from the above Nuget is the ServiceBase class. This is a base class for writing Windows Services, and provides “hooks” for events involved in the service e.g. Start, Stop, Pause etc.

We are going to create a class in our code that does a simple logging job to a temp file, just so we can see how it works. Our code looks like :

class LoggingService : ServiceBase
{
    private const string _logFileLocation = @"C:\temp\servicelog.txt";

    private void Log(string logMessage)
    {
        Directory.CreateDirectory(Path.GetDirectoryName(_logFileLocation));
        File.AppendAllText(_logFileLocation, DateTime.UtcNow.ToString() + " : " + logMessage + Environment.NewLine);
    }

    protected override void OnStart(string[] args)
    {
        Log("Starting");
        base.OnStart(args);
    }

    protected override void OnStop()
    {
        Log("Stopping");
        base.OnStop();
    }

    protected override void OnPause()
    {
        Log("Pausing");
        base.OnPause();
    }
}

So you’ll notice we are inheriting from the “ServiceBase”, and we are just overriding a couple of events to log. A typical pattern would involve kicking off a background thread “OnStart”, and then aborting that thread “OnStop”. Heavy lifting should not be happening inside the OnStart event at all!

From our Main entry method, we want to kick off this service. It’s actually pretty easy :

static void Main(string[] args)
{
    ServiceBase.Run(new LoggingService());
}

That’s it!

Deploying Our Service

When publishing our service, we can’t just rely on a bog standard Visual Studio build to get what we want, we need to be building specifically for the Windows Runtime. To do that, we can run the following from a command prompt in the root of our project. Notice that we pass in the -r flag to tell it which platform to build for.

dotnet publish -r win-x64 -c Release

If we check our /bin/release/netcoreappX.X/publish directory, we will have the output from our publish, but most importantly we will have an exe of our application in here. If we didn’t specify the runtime, we would instead get a .NET Core .dll which we are unable to use as a Windows Service.

We can move this publish directory anywhere to install, but let’s just work directly from the publish folder for now.

For this next part, you will need to open a command prompt as an administrator. Then use the following command :

sc create TestService BinPath=C:\full\path\to\publish\dir\WindowsServiceExample.exe

The SC command is a bog standard windows command (Has nothing to do with .NET Core), that installs a windows service. We say that we are creating a windows service, and we want to call it “TestService”. Importantly, we pass in the full path to our windows service exe.

We should be greeted with :

[SC] CreateService SUCCESS

Then all we need to do is start our service :

sc start TestService

We can now check our log file and see our service running!

To stop and delete our service, all we need to do is :

sc stop TestService
sc delete TestService

Debugging Our Service

Here is where I really think doing things the Microsoft way falls down. Debugging our service becomes a real chore.

For starters our overridden methods from the ServiceBase are set to be protected. This means that we can’t access them outside our class, which makes debugging them even harder. The best way I found was to have a public method for each event that the protected method also calls. Bit confusing, but works like this :

public void OnStartPublic(string[] args)
{
    Log("Starting");
}

protected override void OnStart(string[] args)
{
    OnStartPublic(args);
    base.OnStart(args);
}

This atleast allows us to do things like :

static void Main(string[] args)
{
    var loggingService = new LoggingService();
    if (true)   //Some check to see if we are in debug mode (Either #IF Debug etc or an app setting)
    {
        loggingService.OnStartPublic(new string[0]);
        while(true)
        {
            //Just spin wait here. 
            Thread.Sleep(1000);
        }
        //Call stop here etc. 
    }
    else
    {
        ServiceBase.Run(new LoggingService());
    }
}

This to me is rough as hell involves lots of jiggery pokery to get things going.

Your other option is to do a release in debug mode, actually install the service, and then attach the debugger. This is actually how Microsoft recommends you debug your services, but I think it’s just a hell of a lot of messing about.

What’s Next

There’s actually some other really helpful things we could do here. Like creating an install.bat file that runs our SC Create  command for us, but in my opinion, the debugging issues we’ve seen above are enough for me to immediately tap out. Luckily there is a helpful library called Topshelf that takes a tonne of the pain away, and in the next part of this series we will be looking at how we can get going with that.