LightInject provides two distribution models via NuGet
PM> Install-Package LightInject
This adds a reference to the LightInject.dll in the target project.
PM> Install-Package LightInject.Source
This will install a single file (LightInject.cs) into the current project.
var container = new LightInject.ServiceContainer();
The container implements IDisposable and should be disposed after usage has completed. It can also be used inside of a using statement for a constrained scope.
public interface IFoo {}
public class Foo : IFoo {}
container.Register<IFoo, Foo>();
var instance = container.GetInstance<IFoo>();
Assert.IsInstanceOfType(instance, typeof(Foo));
public class Foo : IFoo {}
public class AnotherFoo : IFoo {}
container.Register<IFoo, Foo>();
container.Register<IFoo, AnotherFoo>("AnotherFoo");
var instance = container.GetInstance<IFoo>("AnotherFoo");
Assert.IsInstanceOfType(instance, typeof(AnotherFoo));
If only one named registration exists, LightInject is capable of resolving this as the default service.
container.Register<IFoo, AnotherFoo>("AnotherFoo");
var instance = container.GetInstance<IFoo>();
Assert.IsInstanceOfType(instance, typeof(AnotherFoo));
LightInject can resolve services that are not registered with the container using the RegisterFallback method.
var container = new ServiceContainer();
container.RegisterFallback((type, s) => true, request => new Foo());
var foo = container.GetInstance<IFoo>();
The first argument to the RegisterFallback method makes it possible to possible to decide if the service can be "late-resolved". The second argument is a ServiceRequest instance that provides the requested service type and service name.
When we register multiple services with the same service type, LightInject is capable of resolving these services as an IEnumerable<T>.
public class Foo : IFoo {}
public class AnotherFoo : IFoo {}
container.Register<IFoo, Foo>();
container.Register<IFoo, AnotherFoo>("AnotherFoo");
var instances = container.GetInstance<IEnumerable<IFoo>>()
Assert.AreEqual(2, instances.Count());
Alternatively using the GetAllInstances method.
var instances = container.GetAllInstances<IFoo>();
Assert.AreEqual(2, instances.Count());
In addition, LightInject supports the following IEnumerable<T> sub-types.
- Array
- ICollection<T>
- IList<T>
- IReadOnlyCollection<T> (Net 4.5 and Windows Runtime);
- IReadOnlyList<T> (Net 4.5 and Windows Runtime)
By default, LightInject will resolve all services that are compatible with the requested element type.
container.Register<Foo>();
container.Register<DerivedFoo>();
var instances = container.GetAllInstances<Foo>();
Assert.AreEqual(2, instances.Count());
This behavior can be overridden using the EnableVariance container option.
var container = new ServiceContainer(new ContainerOptions { EnableVariance = false });
container.Register<Foo>();
container.Register<DerivedFoo>();
var instances = container.GetAllInstances<Foo>();
Assert.AreEqual(1, instances.Count());
We can also selectively decide to apply variance only for certain IEnumerable<T>
services.
options.VarianceFilter = (enumerableType) => enumerableType.GetGenericArguments()[0] == typeof(IFoo);
Sometimes the ordering of the resolved services are important and LightInject solves this by ordering services by their service name.
container.Register<IFoo, Foo1>("A");
container.Register<IFoo, Foo2>("B");
container.Register<IFoo, Foo3>("C");
var instances = container.GetAllInstances<IFoo>().ToArray();
Assert.IsType<Foo1>(instances[0]);
Assert.IsType<Foo2>(instances[1]);
Assert.IsType<Foo3>(instances[2]);
We can also register multiple implementations for a given service type using the RegisterOrdered
method.
var container = CreateContainer();
container.RegisterOrdered(typeof(IFoo), new[] {typeof(Foo1), typeof(Foo2), typeof(Foo3)},
type => new PerContainerLifetime());
var instances = container.GetAllInstances<IFoo>().ToArray();
Assert.IsType<Foo1>(instances[0]);
Assert.IsType<Foo2>(instances[1]);
Assert.IsType<Foo3>(instances[2]);
The RegisterOrdered
method gives each implementation a service name that can be used for ordering when resolving these services. By default the service name is formatted like 001
, 002
and so on.
If we need so change this convention, we can do this by passing a format function to the RegisterOrdered
method.
container.RegisterOrdered(typeof(IFoo<>), new[] { typeof(Foo1<>), typeof(Foo2<>), typeof(Foo3<>) },
type => new PerContainerLifetime(), i => $"A{i.ToString().PadLeft(3,'0')}");
var services = container.AvailableServices.Where(sr => sr.ServiceType == typeof(IFoo<>))
.OrderBy(sr => sr.ServiceName).ToArray();
Assert.Equal("A001", services[0].ServiceName);
Assert.Equal("A002", services[1].ServiceName);
Assert.Equal("A003", services[2].ServiceName);
Registers the value as a constant.
container.RegisterInstance<string>("SomeValue");
var value = container.GetInstance<string>();
Assert.AreEqual("SomeValue, value);
LightInject uses dynamic code compilation either in the form of System.Reflection.Emit or compiled expression trees. When a service is requested from the container, the code needed for creating the service instance is generated and compiled and a delegate for that code is stored for lookup later on so that we only compile it once. These delegates are stored in an AVL tree that ensures maximal performance when looking up a delegate for a given service type. If fact, looking up these delegates is what sets the top performing containers apart. Most high performance container emits approximately the same code, but the approach to storing these delegates may differ.
LightInject provides lock-free service lookup meaning that no locks are involved for getting a service instance after its initial generation and compilation. The only time LightInject actually creates a lock is when generating the code for a given service. That does however mean a potential lock contention problem when many concurrent requests asks for services for the first time.
LightInject deals with this potential problem by providing an API for compilation typically used when an application starts.
The following example shows how to compile all registered services.
container.Compile();
One thing to be aware of is that not all services are backed by its own delegate.
Consider the following service:
public class Foo
{
public Foo(Bar bar)
{
Bar = bar;
}
}
Registered and resolved like this:
container.Register<Foo>();
container.Register<Bar>();
var foo = container.GetInstance<Foo>();
In this case we only create a delegate for resolving Foo
since that is the only service that is directly requested from the container. The code for creating the Bar
instance is embedded inside the code for creating the Foo
instance and hence there is only one delegate created.
We call Foo
a root service since it is directly requested from the container.
In fact lets just have a look at the IL generated for creating the Foo
instance.
newobj Void .ctor() // Bar
newobj Void .ctor(LightInject.SampleLibrary.IBar) //Foo
What happens here is that a new instance of Bar
is created and pushed onto the stack and then we create the Foo
instance. This is the code that the delegate for Foo
points to.
The reason for such a relatively detailed explanation is to illustrate that we don't always create a delegate for a given service and by simply doing a container.Compile()
we might create a lot of delegates that is never actually executed. Probably no big deal as long as we don't have tens of thousands of services, but just something to be aware of.
LightInject does not attempt to identify root services as that would be very difficult for various reasons.
We can instead use a predicate when compiling services up front.
container.Compile(sr => sr.ServiceType == typeof(Foo));
LightInject cannot compile open generic services since the actual generic arguments are not known at "compile" time.
We can however specify the generic arguments like this:
container.Compile<Foo<int>>()
LightInject will create a log entry every time a new delegate is created so that information can be used to identify root services that could be compiled up front. In addition to this, a log entry (warning) is also created when trying to compile an open generic service up front.
The default behavior in LightInject is to treat all objects as transients unless otherwise specified.
container.Register<IFoo,Foo>();
var firstInstance = container.GetInstance<IFoo>();
var secondInstance = container.GetInstance<IFoo>();
Assert.AreNotSame(firstInstance, secondInstance);
Ensures that only one instance of a given service can exists within a scope. The container will call the Dispose method on all disposable objects created within the scope.
container.Register<IFoo,Foo>(new PerScopeLifetime());
using(container.BeginScope())
{
var firstInstance = container.GetInstance<IFoo>();
var secondInstance = container.GetInstance<IFoo>();
Assert.AreSame(firstInstance, secondInstance);
}
Note: An InvalidOperationException is thrown if a service registered with the PerScopeLifetime is requested outside the scope.
Ensures that only one instance of a given service can exist within the container. The container will call the Dispose method on all disposable objects when the container itself is disposed.
using(container = new ServiceContainer())
{
container.Register<IFoo,Foo>(new PerContainerLifetime());
var firstInstance = container.GetInstance<IFoo>();
var secondInstance = container.GetInstance<IFoo>();
Assert.AreSame(firstInstance, secondInstance);
}
A new instance is created for each request and the container calls Dispose when the scope ends. This lifetime is used when the conrete class implements IDisposable.
container.Register<IFoo,Foo>(new PerRequestLifeTime());
using(container.BeginScope())
{
var firstInstance = container.GetInstance<IFoo>();
var secondInstance = container.GetInstance<IFoo>();
Assert.AreNotSame(firstInstance, secondInstance);
}
Note: An InvalidOperationException is thrown if a service registered with the PerRequestLifeTime is requested outside the scope.
A custom lifetime is created by implementing the ILifetime interface
internal interface ILifetime
{
object GetInstance(Func<object> instanceFactory, Scope currentScope);
}
The following example shows to create a custom lifetime that ensures only one instance per thread.
public class PerThreadLifetime : ILifetime
{
ThreadLocal<object> instances = new ThreadLocal<object>();
public object GetInstance(Func<object> instanceFactory, Scope currentScope)
{
if (instances.value == null)
{
instances.value = instanceFactory();
}
return instances.value;
}
}
That is all it takes to create a custom lifetime, but what about disposable services?
public class PerThreadLifetime : ILifetime
{
ThreadLocal<object> instances = new ThreadLocal<object>();
public object GetInstance(Func<object> instanceFactory, Scope currentScope)
{
if (instances.value == null)
{
object instance = instanceFactory();
IDisposable disposable = instance as IDisposable;
if (disposable != null)
{
if (currentScope == null)
{
throw new InvalidOperationException("Attempt to create an disposable object
without a current scope.")
}
currentScope.TrackInstance(disposable);
}
instances.value = instance;
}
return instance.value;
}
}
A lifetime object controls the lifetime of a single service and can never be shared for multiple service registrations.
Wrong
ILifetime lifetime = new PerContainerLifeTime();
container.Register<IFoo,Foo>(lifetime);
container.Register<IBar,Bar>(lifetime);
Right
container.Register<IFoo,Foo>(new PerContainerLifeTime());
container.Register<IBar,Bar>(new PerContainerLifeTime());
A lifetime object is also shared across threads and that is something we must take into consideration when developing new lifetime implementations.
By default scopes are managed per thread which means that when the container looks for the current scope, it will look for a scope that is associated with the current thread.
With the introduction of the async/await pattern chances are that the code that is requesting a service instance is running on another thread.
To illustrate this lets consider an example that is going to cause an instance to be resolved on another thread.
We start of by creating an interface that returns a Task<IBar>
public interface IAsyncFoo
{
Task<IBar> GetBar();
}
Next we implement this interface in such a way that the IBar instance is requested on another thread.
public class AsyncFoo : IAsyncFoo
{
private readonly Lazy<IBar> lazyBar;
public AsyncFoo(Lazy<IBar> lazyBar)
{
this.lazyBar = lazyBar;
}
public async Task<IBar> GetBar()
{
await Task.Delay(10);
return lazyBar.Value; <--This code is executed on another thread (continuation).
}
}
The we register the dependency (IBar) with the PerScopeLifetime that is going to cause the container to ask for the current scope so that the instance can be registered with that scope.
var container = new ServiceContainer();
container.Register<IBar, Bar>(new PerScopeLifetime());
container.Register<IAsyncFoo, AsyncFoo>();
using (container.BeginScope())
{
var instance = container.GetInstance<IAsyncFoo>();
ExceptionAssert.Throws<AggregateException>(() => instance.GetBar().Wait());
}
This will throw an exception that states the following:
Attempt to create a scoped instance without a current scope.
The reason that this is happening is that the current scope is associated with the thread that created it and when the continuation executes, we are essentially requesting an instance on another thread.
To deal with this issue, LightInject now supports scopes across the logical CallContext.
var container = new ServiceContainer();
container.ScopeManagerProvider = new PerLogicalCallContextScopeManagerProvider();
container.Register<IBar, Bar>(new PerScopeLifetime());
container.Register<IAsyncFoo, AsyncFoo>();
using (container.BeginScope())
{
var instance = container.GetInstance<IAsyncFoo>();
var bar = instance.GetBar().Result;
Assert.IsInstanceOfType(bar, typeof(IBar));
}
Note that the PerLogicalCallContextScopeManagerProvider is only available when running under .Net 4.5. For more information, please refer to the following article by Stephen Cleary.
The purpose of the scope is to track the services created within the scope. For instance, the PerScopeLifetime
uses the scope to ensure that we only create a single service instance even if it requested multiple times.
One of the most canonical examples would be in a web application where we need to inject IDbConnection
into different services. Let say that we have an OrderController
and we need two services to process the order.
public class CustomerService : ICustomerService
{
public CustomerService(IDbConnection dbConnection)
{
}
}
public class OrderService : IOrderService
{
public OrderService(IDbConnection dbConnection)
{
}
}
public class OrderController
{
public OrderController(ICustomerService customerService, IOrderService orderService)
{
}
}
As we can see the OrderController
depends on both the CustomerService
and the OrderService
which are both dependant upon an IDbConnection
.
By registering the IDbConnection
as a scoped service we ensure two things.
- Only a single instance of
IDbConnection
will ever be created inside a scope. - The
IDbConnection
instance is disposed when the scope ends.
container.RegisterScoped<IDbConnection>(factory => new ProviderSpecificConnection());
So when and how do we start these scopes?
She short answer is that most of the time, we don't. For instance, in AspNetCore, the scopes are started and ended by the AspNetCore infrastructure so we don't have to think about that when developing web application. A scope is started when the web request starts and it ended when the web request ends. It is really that simple, one request equals one scope.
So in LightInject, we register a scoped service using RegisterScoped
without really thinking about when and how the scopes are started and ended. In a web application this usually means a web request, but for other applications it can mean something else. Maybe for a UI application it means a page/window/form or something similar.
To start a scope manually we can create scope using the BeginScope
method
using (container.BeginScope())
{
var dbConnection = container.GetInstance<IDbConnection>();
}
Note: The
Scope
implementIDisposable
and should always be wrapped in a using block to ensure its disposal
In this example we start a new scope and retrieve the service from the container which means that LightInject uses the "current" scope to resolve the service. This is only supported for backwards compatibility and should be avoided if possible. The recommended approach is to retrieve services directly from the scope.
using (var scope = container.BeginScope())
{
var dbConnection = scope.GetInstance<IDbConnection>();
}
Since we are retrieving the service directly from the scope, the current scope is ignored and we simply use the scope from which the service was requested. This is not only much faster, but it is also a much safer way to deal with scopes.
This also allows for multiple active scopes.
using (var outerScope = container.BeginScope())
{
using (var innerScope = container.BeginScope())
{
var outerDbConnection = outerScope.GetInstance<IDbConnection>();
var innerDbConnection = innerScope.GetInstance<IDbConnection>();
}
}
In addition to the PerScopeLifetime
which ensures disposal and a single instance within a scope, we also have the PerRequestLifetime
. This lifetime behaves just a transient meaning that we get a new instance for every time it is requested with the only difference to transients being that instances are disposed when the scope ends.
Note: The
PerRequestLifetime
has NO relation to the notion of a web request.
If we don't need access to an ambient scope, we can disable this in the ContainerOptions
var container = new ServiceContainer(o => o.EnableCurrentScope = false);
This also improves performance ever so slightly as we don't need to maintain a current scope when scopes are started and ended.
public interface IFoo {}
public interface IBar {}
public class Foo : IFoo
{
public Foo(IBar bar)
{
Bar = bar;
}
public IBar Bar { get; private set; }
}
public class Bar : IBar {}
Registers a service without specifying any information about how to resolve the constructor dependencies of the implementing type.
container.Register<IFoo, Foo>();
container.Register<IBar, Bar>();
var foo = (Foo)container.GetInstance<IFoo>();
Assert.IsInstanceOfType(foo.Bar, typeof(Bar));
Note: In the case where the implementing type(Foo) has more than one constructor, LightInject will choose the constructor with the most parameters.
For fine grained control of the injected constructor dependencies, we can provide a factory that makes it possible to create an instance of a given constructor dependency.
container.RegisterConstructorDependency<IBar>((factory, parameterInfo) => new Bar());
This tells the container to inject a new Bar instance whenever it sees an IBar constructor dependency.
Registers a service by providing explicit information about how to create the service instance and how to resolve the constructor dependencies.
​
​ container.Register<IBar, Bar>();
​ container.Register(factory => new Foo(factory.GetInstance));
​ var foo = (Foo)container.GetInstance();
​ Assert.IsNotNull(foo.Bar);
Parameters are used when we want to supply one or more values when the service is resolved.
public class Foo : IFoo
{
public Foo(int value)
{
Value = value;
}
public int Value { get; private set; }
}
container.Register<int, IFoo>((arg, factory) => new Foo(arg));
var foo = (Foo)container.GetInstance<int, IFoo>(42);
Assert.AreEqual(42,foo.Value);
We can also do a combination of supplied values and dependencies.
public class Foo : IFoo
{
public Foo(int value, IBar bar)
{
Value = value;
}
public int Value { get; private set; }
public IBar Bar { get; private set; }
}
container.Register<IBar, Bar>();
container.Register<int, IFoo>((factory, value) => new Foo(value, factory.GetInstance<IBar>()));
var foo = (Foo)container.GetInstance<int, IFoo>(42);
Assert.AreEqual(42, foo.Value);
Assert.IsNotNull(foo.Bar);
public interface IFoo {}
public interface IBar {}
public class Foo : IFoo
{
public IBar Bar { get; set; }
}
public class Bar : IBar {}
Registers the service without specifying any information about how to resolve the property dependencies.
container.Register<IFoo, Foo>();
container.Register<IBar, Bar>();
var foo = (Foo)container.GetInstance<IFoo>();
Assert.IsNotNull(foo.bar);
Note: LightInject considers all read/write properties a dependency, but implements a loose strategy around property dependencies, meaning that it will NOT throw an exception in the case of an unresolved property dependency.
For fine grained control of the injected property dependencies, we can provide a factory that makes it possible to create an instance of a given property dependency.
container.RegisterPropertyDependency<IBar>((factory, propertyInfo) => new Bar());
This tells the container to inject a new Bar instance whenever it sees an IBar property dependency.
Registers a service by providing explicit information about how to create the service instance and how to resolve the property dependencies.
container.Register<IBar, Bar>();
container.Register<IFoo>(factory => new Foo() {Bar = factory.GetInstance<IBar>()})
var foo = (Foo)container.GetInstance<IFoo>();
Assert.IsNotNull(foo.bar);
In the cases where we don't control the creation of the service instance, LightInject can inject property dependencies into an existing instance.
container.Register<IBar, Bar>();
var foo = new Foo();
container.InjectProperties(foo);
Assert.IsNotNull(foo);
Property injection is enabled by default in LightInject, but it can be disabled like this.
var container = new ServiceContainer(new ContainerOptions { EnablePropertyInjection = false });
It is actually recommended to turn off property injection unless it is really needed. Backward compatibility is the only reason that this is not the default.
Use the Initialize method to perform service instance initialization/post-processing.
container.Register<IFoo, FooWithPropertyDependency>();
container.Initialize(registration => registration.ServiceType == typeof(IFoo),
(factory, instance) => ((FooWithPropertyDependency)instance).Bar = new Bar());
var foo = (FooWithProperyDependency)container.GetInstance<IFoo>();
Assert.IsInstanceOfType(foo.Bar, typeof(Bar));
LightInject is capable of registering services by looking at the types of a given assembly.
container.RegisterAssembly(typeof(IFoo).Assembly)
To filter out the services to be registered with the container, we can provide a predicate that makes it possible to inspect the service type and the implementing type.
container.RegisterAssembly(typeof(IFoo).Assembly, (serviceType, implementingType) => serviceType.NameSpace == "SomeNamespace");
It is also possible to scan a set assembly files based on a search pattern.
container.RegisterAssembly("SomeAssemblyName*.dll");
When scanning assemblies, LightInject will register services using a service name that by default is the implementing type name. This behavior can be changed by specifying a function delegate to provide the name based on the service type and the implementing type.
container.RegisterAssembly(typeof(IFoo).Assembly, () => new PerContainerLifetime(), (serviceType, implementingType) => serviceType.NameSpace == "SomeNamespace", (serviceType, implementingType) => "Provide custom service name here");
We can also change this behavior globally for all registrations by implementing the IServiceNameProvider interface.
public class CustomServiceNameProvider : IServiceNameProvider
{
public string GetServiceName(Type serviceType, Type implementingType)
{
return "Provide custom service name here";
}
}
To change the default behavior for all registrations we simply change this dependency on the container before we start scanning assemblies.
container.ServiceNameProvider = new CustomServiceNameProvider();
When LightInject scans an assembly it will look for an implementation of the ICompositionRoot interface.
public class SampleCompositionRoot : ICompositionRoot
{
public void Compose(IServiceRegistry serviceRegistry)
{
serviceRegistry.Register(typeof(IFoo),typeof(Foo));
}
}
If one or more implementations of the ICompositionRoot interface is found, they will be created and executed.
Note: Any other services contained within the target assembly that is not registered in the composition root, will NOT be registered.
Rather that having a single composition root that basically needs to reference all other assemblies, having multiple composition roots makes it possible to group services naturally together. Another advantage of registering services in a ICompositionRoot, is that they can easily be reused in automated tests.
LightInject is capable of registering services on a need to have basis. For a large application that has a lot of services, it might not be the best solution to register all these services up front as this could seriously hurt the startup time of our application due to extensive assembly loading.
If an unregistered service is requested, LightInject will scan the assembly where this service is contained.
When an assembly is being scanned, LightInject will look for implementations of the ICompositionRoot interface. For large assemblies that contains many type, this might be an expensive operation. The CompositionRootAttribute is an assembly level attribute that simply helps LightInject to locate the compostion root.
[assembly: CompositionRootType(typeof(SampleCompositionRoot))]
Allows explicit execution of a composition root.
container.RegisterFrom<SampleCompositionRoot>();
public interface IFoo<T> {};
public class Foo<T> : IFoo<T> {};
The container creates the closed generic type based on the service request.
container.Register(typeof(IFoo<>), typeof(Foo<>));
var instance = container.GetInstance(typeof(IFoo<int>));
Assert.IsInstanceOfType(instance, typeof(Foo<int>));
LightInject enforces generic constrains
LightInject can resolve a service as an instance of Lazy<T> when we want to postpone resolving the underlying service until it is needed.
public interface IFoo {}
public class Foo : IFoo {}
container.Register<IFoo, Foo>();
var lazyFoo = container.GetInstance<Lazy<IFoo>>();
Assert.IsNotNull(lazyFoo.Value);
Function factories allows services to resolved as a function delegate that in turn is capable of returning the underlying service instance. We can think of this as an alternative to the Service Locator (anti)pattern.
public interface IFoo {}
public class Foo : IFoo {}
container.Register<IFoo,Foo>();
var func = container.GetInstance<Func<IFoo>>();
var foo = func();
Assert.IsNotNull(foo);
Note: A function factory is effectively a delegate that redirects back to the corresponding GetInstance method on the service container.
The container returns a function delegate that represents calling the GetInstance method with "SomeFoo" as the service name argument.
container.Register<IFoo, Foo>("SomeFoo");
var func = container.GetInstance<Func<IFoo>>("SomeFoo");
var foo = func();
Assert.IsNotNull(foo);
Function factories can also take parameters that will be used create the service instance.
public class Foo : IFoo
{
public Foo(int value)
{
Value = value;
}
public int Value { get; private set; }
}
container.Register<int, IFoo>((factory, value) => new Foo(value));
var fooFactory = container.GetInstance<Func<int, IFoo>>();
var foo = (Foo)fooFactory(42);
Assert.AreEqual(foo.Value, 42);
Note : The service must be explicitly registered in order for the container to resolve it as a parameterized function factory.
The only way to deal with disposable objects when using function factories, is to let the service type inherit from IDisposable.
public interface IFoo : IDisposable {}
public class Foo : IFoo {}
container.Register<IFoo, Foo>();
var fooFactory = container.GetInstance<Func<IFoo>>();
using(IFoo foo = fooFactory())
{
} <--Instance is disposed here
Note: Although this is common practice even in the BCL, this kind of interfaces are often referred to as leaky abstractions.
A typed factory is a class that wraps the function factory that is used to create the underlying service instance. As opposed to just function factories, typed factories provides better expressiveness to the consumer of the factory.
public interface IFooFactory
{
IFoo GetFoo();
}
public class FooFactory : IFooFactory
{
private Func<IFoo> createFoo;
public FooFactory(Func<IFoo> createFoo)
{
this.createFoo = createFoo;
}
public IFoo GetFoo()
{
return createFoo();
}
}
container.Register<IFoo, Foo>();
container.Register<IFooFactory, FooFactory>(new PerContainerLifetime());
var fooFactory = container.GetInstance<IFooFactory>();
var foo = fooFactory.GetFoo();
Assert.IsNotNull(foo);
Note: Register typed factories with the PerContainerLifetime unless a compelling reason exists to choose a different lifetime.
Types factories can also wrap a parameterized function factory and allows us to pass arguments.
public class Foo : IFoo
{
public Foo(int value)
{
Value = value;
}
public int Value { get; private set; }
}
public interface IFooFactory
{
IFoo GetFoo(int value);
}
public class FooFactory : IFooFactory
{
private Func<int, IFoo> createFoo;
public FooFactory(Func<int, IFoo> createFoo)
{
this.createFoo = createFoo;
}
public IFoo GetFoo(int value)
{
return createFoo(value);
}
}
container.Register<int, IFoo>((factory, value) => new Foo(value));
container.Register<IFooFactory, FooFactory>(new PerContainerLifetime());
var typedFooFactory = container.GetInstance<IFooFactory>();
var foo = typedFooFactory.GetFoo(42);
Assert.AreEqual(foo.Value, 42);
Working with typed factories gives us the possibility to release disposable services registered as transients without exposing a leaky abstraction.
public interface IFooFactory
{
IFoo GetFoo(int value);
void Release(IFoo foo);
}
public class FooFactory : IFooFactory
{
private Func<IFoo> createFoo;
public FooFactory(Func<IFoo> createFoo)
{
this.createFoo = createFoo;
}
public IFoo GetFoo(int value)
{
return createFoo(value);
}
public void Release(IFoo foo)
{
var disposable = foo as IDisposable;
if (disposable != null)
{
disposable.Dispose();
}
}
}
A recursive dependency graph is when a service depends directly or indirectly on itself.
public class FooWithRecursiveDependency : IFoo
{
public FooWithRecursiveDependency(IFoo foo)
{
}
}
The following code will throw an InvalidOperationException stating that there are existing recursive dependencies.
container.Register(typeof(IFoo), typeof(FooWithRecursiveDependency));
container.GetInstance<IFoo>()
When running under the .Net platform, LightInject is capable of creating instances of classes that has the internal modifier.
The only requirement is that the internal class exposes a public constructor.
internal class InternalFooWithPublicConstructor : IFoo
{
public InternalFooWithPublicConstructor () {}
}
Sometimes it might be useful to obtain information about what is going on inside the container and LightInject provides a very simple log abstraction that is used to log information and warnings from within the container.
var containerOptions = new ContainerOptions();
containerOptions.LogFactory = (type) => logEntry => Console.WriteLine(logEntry.Message);
Sometimes it might be useful to use the service container within our unit tests. LightInject also provides the LightInject.xUnit extension that enables dependencies to be injected into test methods. One side effect of using that extension is that it is tightly coupled to xUnit and it we have less control with regards to container instances.
Instead consider this simple base class
public class ContainerFixture : IDisposable
{
public ContainerFixture()
{
var container = CreateContainer();
Configure(container);
container.RegisterFrom<CompositionRoot>();
ServiceFactory = container.BeginScope();
InjectPrivateFields();
}
private void InjectPrivateFields()
{
var privateInstanceFields = this.GetType().GetFields(BindingFlags.Public | BindingFlags.NonPublic | BindingFlags.Instance);
foreach (var privateInstanceField in privateInstanceFields)
{
privateInstanceField.SetValue(this, GetInstance(ServiceFactory, privateInstanceField));
}
}
internal Scope ServiceFactory { get; }
public void Dispose() => ServiceFactory.Dispose();
public TService GetInstance<TService>(string name = "")
=> ServiceFactory.GetInstance<TService>(name);
private object GetInstance(IServiceFactory factory, FieldInfo field)
=> ServiceFactory.TryGetInstance(field.FieldType) ?? ServiceFactory.GetInstance(field.FieldType, field.Name);
internal virtual IServiceContainer CreateContainer() => new ServiceContainer();
internal virtual void Configure(IServiceRegistry serviceRegistry) {}
}
This can be use with any test framework as long as it creates a new instance of the test class for each test method and that it calls Dispose
after the test completes. For xUnit
this is the default behaviour.
Injecting services now becomes incredible easy. Just declare the service to test as a private field like this.
public class SampleTests : ContainerFixture
{
private ICalculator calculator;
[Fact]
public void ShouldAddNumbers()
{
calculator.Add(2,2).ShouldBe(2);
}
}
If we need to configure the container before executing the test, we can do that by simply overriding the Configure
method. This could for instance be used to register mock services into the container.
public class SampleTests : ContainerFixture
{
private ICalculator calculator;
[Fact]
public void ShouldAddNumbers()
{
calculator.Add(2,2).ShouldBe(2);
}
internal override Configure(IServiceRegistry serviceRegistry)
{
// Add registrations related to testing here
}
}