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I'm trying to use dependency injection with MVP injecting the required dependencies into the constructor. The problem I have is if I use dependency injection on the root MainWindowPresenter, all it's sub-presenters and their sub-presenters, views and services would be loaded at startup. As everything is loaded directly or indirectly from the MainWindowPresenter, that then means the entire application will be loaded into memory at startup.

I know it might not cost a lot in .NET to create all the objects at startup but I can't help thinking that it's a waste of memory as they are never all going to be used at the same time. There are some like AboutPresenter or HelpPresenter that may never be used at all. Am I missing or is this how dependency injection is supposed to work? Is there a way around this?

The only way I can find to get around this is to use factories which can then create the sub-presenters/views/services when needed. e.g.:

class HelpFactory : AbstractHelpFactory
{
    public IHelpPresenter Create()
    {
         IHelpService helpService = new ConcreteHelpService();
         IHelpView helpView = new ConcreteHelpView();

         HelpSearchPresenter searchPresenter = HelpSearchFactory.Create();

         return HelpPresenter(helpView, helpService, searchPresenter);
    }
}

Which is basically the same thing as the factories then depend on sub-factories but at least they are lighter than presenters/views/services and they don't need to load the sub-factories until they are needed.

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2 Answers 2

up vote 2 down vote accepted

There are several possible solutions (arranged from general to specific):

Composition root

Determine a Composition Root. This is a (preferably) unique location in an application where modules are composed together. This is preferable solution to compose all your dependencies.

Abstract Factory

Instead of injecting dependencies you could inject factory of similar dependencies. This will help you to postpone dependencies creation and resolve only dependencies required for current situation. Example using ninject.extension.factory:

kernel.Bind<IDependencyFactory>().ToFactory();

kernel
    .Bind<IDependency>()
    .To<DependencyImpl1>()
    .NamedLikeFactoryMethod((IDependencyFactory f) => f.GetJob());

var abstractFactory = kernel.Get<IDependencyFactory>();

var dependency = abstractFactory.GetJob(); 

public abstract class IDependency { }
public class DependencyImpl1 : IDependency { }

public interface IDependencyFactory
{
    IDependency GetJob();
    Lazy<IDependency> GetLazyJob();
}

This will also helps to avoid over-injection of your classes, for example constructor over-injection

Aggregate Services

Instead of injection of dependencies, inject service that aggregates processing routines. Read more at Refactoring to Aggregate Services

Lazy loading

Sometimes it is necessary to defer the resolution of a dependency for reasons such being overly expensive to create during startup and/or being rarely used. In these cases, one can have a Lazy injected instead of IDependency. Example using Ninject.Extension.Factory:

kernel
    .Bind<Lazy<IDependency>>()
    .To<Lazy<IDependency>>()
    .NamedLikeFactoryMethod((IDependencyFactory f) => f.GetLazyJob());

var abstractFactory = kernel.Get<IDependencyFactory>();

var lazyDependencyUsingFactory = abstractFactory.GetLazyJob();

Example using lazy-loading w/o factory:

kernel
    .Bind<IDependency>()
    .To<DependencyImpl1>();

kernel
    .Bind(typeof (Lazy<>))
    .ToMethod(context =>
            ((ILazyLoader) Activator.CreateInstance(typeof (LazyLoader<>).MakeGenericType(context.GenericArguments),
                                                    new object[] { context.Kernel })).Loader);

var lazyDependency = kernel.Get<Lazy<IDependency>>();

lazyDependency.Dump();
lazyDependency.Value.Dump();

ps: full sample available here

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Thanks for the help, I think the best approach for me is lazy loading. –  User Jan 22 '13 at 1:35

… it might not cost a lot in .NET to create all the objects at startup …

Unfortunately, it can be costly, especially when their types are spread out over several assemblies. If you have something like a Composition Root, i.e. one single place typically right at the start of your application where all DI type registrations happen (and you haven't payed close attention to the registrations), then all involved assemblies will have to be loaded at once by the runtime, which can take quite some time.

I am currently investigating ways of avoiding this issue, and have so far found the following three solutions, which work on two levels: (a) assembly (loading by the runtime), and (t) type (object instantiation).

1. (a) Ensure that the method(s) containing the DI container type registrations do not directly reference implementation types.

For example, with Autofac it suffices to replace:

containerBuilder.RegisterType<Foo>().As<IFoo>();
//                            ^^^       ^^^^
// assemblies for both `IFoo` and `Foo` will be loaded before the method executes.

with an equivalent lambda registration:

containerBuilder.Register<IFoo>(c => new Foo(…));
//                        ^^^^
// only assembly for `IFoo` will be loaded, but not the one containing `Foo`!

Whenever a method executes, all types directly referenced by it must be available, which means that their containing assemblies are loaded before method execution begins. Since lambdas are compiled into separate classes, using a lambda registration defers loading of the implementation assembly for Foo until that lambda is called for the first time.

2. (a) Put all required interfaces/contracts in as few assemblies as possible.

(This follows directly from the above:)

Because the interface types are what is required during the DI container's type registration, they will have to be loaded there and then. If you put them in only a few assemblies, the runtime will only have to load those during application startup (i.e. at the composition root). And since interface types do not have implementations, these assemblies are likely to remain fairly light-weight.

For implementation types, the issue of assembly loading time is usually mitigated because an application typically won't need everything at the same time; some classes are used in screen A, some are used in screen B, and these display at different times. So you can spread out your implementation types over more assemblies and it won't be felt as badly, because their loading time is more evenly distributed over time.

However, by the same reasoning applied to your abstract interfaces (see above), you could decide to package all implementation types of screen A into one assembly, and all types for screen B into another, since they are likely to be loaded at the same time.

Tip: If you want your solution structure to be different at development time than during deployment, you can integrate a tool such as ILMerge in your post-build process to package several assemblies together into one.

3. (t) Use factories, or inject Func<T> or Lazy<T> instead of T:

This is what you've already been thinking about when injecting factories instead of the actual objects. Essentially it's what might solve your problem, because it means that some instance of T will only have to be instantiated when the consumer actually requires it:

class Bar
{
    public Bar(Func<IFoo> getFoo, …) // no `Foo` is instantiated for this.
    {
        this.getFoo = getFoo;
        …
    }

    private readonly Func<IFoo> getFoo;

    void MuchMuchLaterInTime()
    {
        IFoo foo = getFoo(); // only now must a `Foo` become available!
    }
}
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