NuGet package pages:
A segmented visitor library to solidify the visitor pattern. The origin of the idea will be discussed in the background section, together with the problem in regards to the SOLID design principles. It will briefly touch upon one of original NuGet versions of this library in regards to the so-called V1/V2 approach. Further sections will explain how the approach works.
Specific use-cases for this library can be found in section Which Problems to solve, specifically in subsection Possible UseCases.
❗ NOTE |
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The current version of the software is drastically different from where it all began. The V1/V2 approach is no longer available as the V2 approach has been appointed to be the standard for this library. Note that the library has undertaken a major overhaul. For the original version, inspect the README_(old-version).md |
❗ ANOTHER NOTE |
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Be aware of the other NOTEs in the document, it contains some pretty specific details that can help a lot with developing and answering questions. |
Use of Accepter object and visiting of all types of objects available since version 3.1.0.
❗ NOTE |
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As of version 4.0.0, there is a split between Async and Sync version of the components with the library. The Xtender.Async namespaces replace the previous standard, the async approach. The Xtender.Sync namespaces are new and provide a synchronous version of Xtender, which can be used when there is not a single instance in the extender-chain that requires the use of async code. |
Table of contents generated with markdown-toc
Xtender, obviously named after the ability to extend, is a library developed to solidify (conform to the SOLID design principles) the Visitor design pattern which is used to separate an algorithm from an object structure, or simply adding a new algorithm to such an object in a flexible way.
Where the visitor in the visitor pattern is just a single class containing the Visit methods for every concrete type in the object structure, the segmented visitor pattern separate this class into segments (separate classes. A class per visit method). Each segment (defined by an abstract definition) defines one of the Visit method, which each accept a certain concrete type that needs to be accessed. While this concrete type is visited, it can be extended by applying some additional logic, provided by the visitor segment itself.
❗ NOTE |
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Be aware that at the start the visitor is always passed to the Accept method of the to be visited object. That is because each overload of the Visit method of the visitor in the visitor pattern contains a signature with a concrete type. When an abstraction is pass to the visitor, it will probably not have an overloaded Visit method for it. However, there could be one, but that would most likely be a default case. |
What this adds to the already consistent visitor pattern are improvements to adhere even more to the SOLID design principles, which most notably are:
- Single-responsibility principle: Every segment applies an operation for a single concrete type.
- Open-closed principle: When the object structure (consisting of some objects with a common parent) is extended with more concrete typed objects, the visitor structure could simply be extended by adding a new segment to the collection of visitor segments instead of modifying the visitor class.
- Liskov's substitution principle: The abstractions of the segments are simple and generic enough that these abstractions work perfectly as a basis for every type of segment that is added to the structure. A segment abstraction does not contain more methods or data than what is commonly understood between segments.
- Interface segregation principle: The interface of the segments does only contain what is necessary. More behaviors are separated into multiple different abstractions when needed.
- Dependency inversion principle: The library components are all depending on abstractions instead of concrete implementations.
The first version that was considered when implementing the Xtender library has been the use of the Decorator Pattern/Chain-of-responsibility Pattern, because of its pipeline and request-handler-style-as-segments approach. It provides a natural way of extension by linking the segments and checking the input.
It comes down to an approach where a client is used that holds a reference to the root-segment in the chain. The client executes the operation process by simply calling the entry-point on the root-segment and then traverses through the chain until it finds the suitable segment that can accept the type of the object that is inputted and puts that object into the Extend method of the selected segment. This detection is achieved by doing a type check, and when matching, casting the object to the specific concrete implementation it is specified to be. For a short chain there is no major problem in this approach, although, when adding more segments to the chain, it takes longer on average to find the matching segment. The complexity of this solution is therefore of O(n). It has the tendency to move away from a constant efficiency.
A second version was established to solve the aforementioned disadvantage in efficiency. The main difference with this version and the aformentioned one is that the handlers/segments are stored in a dictionary instead of chaining them together.
The dictionary (a map-like structure implemented with a hash-map) is a well-known collective data-structure that can save a value on a location that is linked to a key. The key can be of any data-type and the dictionary calculates a hash-value for that key, which indicates its index in memory. The search functionality of the dictionary is known to be of complexity O(1). Implementing a dictionary as a registry for storing the different segments greatly increases search-efficiency by reducing the complexity introduced by the chain-based version. This version operates more constantly in speed and efficiency.
From version 3.1.0. of the Xtender.DependencyInjection package on, the control on the capacity of the dictionaries in the full Xtender library packages is improved. Instead of having a default capacity of 31 records, the capacities of the dictionaries are now configured by means of the amount of registered extensions.
This section emphasizes the important components of the library through some coding examples. We first start with the definition of some of the components in regard to their purpose and location within an application. Be aware of both the stateful (with TState generics) and stateless versions of the library. The state property that is provided by the stateful IExtender/IAsyncExtender is nothing more than a simple storage container for temporary data, because a normal visitor could also save such data inside its class fields/properties, so this is a nod to that ability. Nevertheless, the stateless version is there to support visiting without state storing.
What has to be noted is that the stateful version of the IExtender/IAsyncExtender can be registered with both stateful and stateless versions of the extensions, though the stateless IExtender/IAsyncExtender can only use stateless extensions. The cause for this difference is that the stateful extensions could depend on state from the stateful IExtender/IAsyncExtender version, so the stateless IExtender/IAsyncExtender version is incompatible with that, whereas the stateless extensions do accept a higher abstraction of IExtender/IAsyncExtender, which the stateful IExtender/IAsyncExtender extends from, so nothing will be harmed there.
The accepter is the object that can be visited/extended. In most cases this would be an object that is part of a composite structure. The base of the composite should define that the concrete implementations would each implement an Accept(...) method that accepts the extender. The reason for this not being abstracted away is that every concrete implementation has to provide itself to the extender, so that the extender can determine the right implementation (concrete type) it should be working on.
Sync:
public abstract Component : IAccepter
{
public abstract void Accept(IExtender extender);
}
public class Item : Component
{
public string Context { get; set; }
public override void Accept(IExtender extender) => extender.Extend(this);
}
public class Composite : Component
{
public IList<Component> Components { get; set; }
public override void Accept(IExtender extender) => extender.Extend(this);
}
Async:
public abstract Component : IAsyncAccepter
{
public abstract Task Accept(IAsyncExtender extender);
}
public class Item : Component
{
public string Context { get; set; }
public override Task Accept(IAsyncExtender extender) => extender.Extend(this);
}
public class Composite : Component
{
public IList<Component> Components { get; set; }
public override Task Accept(IAsyncExtender extender) => extender.Extend(this);
}
Here the Composite Pattern Component implements the IAccepter/IAsyncAccepter interface and provides the Accept(...) method as an abstract method, though it is a restated version of the same method defined by the interface. This enable the implementations (Item, Composite) to implement the correct version of the method.
❗ IMPORTANT NOTE |
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Since version 3.1.0. it is also possible to accept all types of objects, so the IAccepter/IAsyncAccepter interface is not necessary by default, although the functionality in the form of an extension method requires the use of the Accepter/AsyncAccepter object, which encapsulates the desired, visitable object. The extender can extend both direct IAccepter/IAsyncAccepter implemented objects of Accepter/AsyncAccepter objects. |
Sync:
int integer = 3;
new Accepter<int>(integer).Accept(extender);
// OR by the us of the extension-method:
integer.Accept(extender); // signature: void Accept<TValue>(this TValue value, IExtender extender)...
Async:
int integer = 3;
new AsyncAccepter<int>(integer).Accept(extender);
// OR by the us of the extension-method:
await integer.Accept(extender); // signature: Task Accept<TValue>(this TValue value, IAsyncExtender extender)...
The extensions are the definitions of the so-called visitor segments. In the example: Each handles a concrete implementation that is used to visit (and extend) the functionality of a specific implementation of the aforementioned composite Component class.
Sync:
// A version with state
public class ItemExtension : IExtension<string, Item>
{
public void Extend(Item context, IExtender<string> extender)
{
System.Console.WriteLine("Entered ItemExtension");
if (extender.State is null)
{
extender.State = "Encountered an Item regarding Component.";
return;
}
extender.State += "Encountered an Item regarding Component.";
}
}
// A version without state
public class ItemExtension : IExtension<Item>
{
public void Extend(Item context, IExtender extender)
{
System.Console.WriteLine("Entered ItemExtension");
}
}
Async:
// A version with state
public class ItemExtension : IAsyncExtension<string, Item>
{
public Task Extend(Item context, IAsyncExtender<string> extender)
{
System.Console.WriteLine("Entered ItemExtension");
if (extender.State is null)
{
extender.State = "Encountered an Item regarding Component.";
return Task.CompletedTask;
}
extender.State += "Encountered an Item regarding Component.";
return Task.CompletedTask;
}
}
// A version without state
public class ItemExtension : IAsyncExtension<Item>
{
public Task Extend(Item context, IAsyncExtender extender)
{
System.Console.WriteLine("Entered ItemExtension");
return Task.CompletedTask;
}
}
Here the ItemExtension is an example of an extension that is responsible for processing the Item implementations.
❗ NOTE |
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The Extend(...) method has a second parameter, the extender (the actual Visitor) itself. The reapplication of the extender/visitor is to further extend/visit other components. BE AWARE: The official Extender/AsyncExtender implementation (also for the stateless version, but stateful is used in the note) passes an IExtender/IAsyncExtender proxy to the extension instead of itself. This ensures that the accepters are always first accepting the extender before the extender extends/visits these accepters. However, when the incoming object in the Extend method of the extender is a concrete implementation, the proxy will directly pass the object to the extender. This is added for when a developer confuses the visitor-has-to-be-accepted-by-the-object approach with a request-inputted-into-a-client approach |
BE AWARE: The stateless version of the extension can be registered for both the stateful and stateless versions of the extenders, while the stateful version can only be registered for a stateful extender. |
To make life as a developer easier, the library (Specifically: Xtender.DependencyInjection) comes with ServiceCollection extensions that can be used to easily implement the extender components by building up the Extender/AsyncExtender clients with their segments/extensions.
❗ IMPORTANT NOTE |
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RESTATEMENT OF A PREVIOUS NOTE: The IExtender/IAsyncExtender interface (also for the stateless version, but stateful is used in the note) is first implemented by the ExtenderProxy/AsyncExtenderProxy class and then the real Extender class. The proxy is introduced as a mechanism to ensure that the IExtender/IAsyncExtender instance is always first past to the Accept(...) method of the IAccepter/IAsyncAccepter implementation and not the other way around. When the accepter that is passed into the Extend(...) method is not an interface or an abstract class, this step is skipped and the real extender instance is called directly. |
This proxy is constructed by instantiating it and passing a lambda as parameter to its constructor. This lambda accepts the proxy itself as parameter and expects another (the real) instance of IExtender/IAsyncExtender to return. Why the proxy is passed to the lambda is because the Extender/AsyncExtender constructor expects the proxy to be passed into one of the parameters. This is to ensure that the extender itself can reuse the proxy when passing it to the extensions. |
Sync:
// Stateful version: both extension types can be registered here.
var serviceProvider = new ServiceCollection()
.AddXtender<string>((builder, provider) =>
{
builder
.Default<MyDefaultExtension>()
.Attach<Item, StatefulItemExtension>()
.Attach<Composite, CompositeExtension>(() => new CompositeExtension());
})
.BuildServiceProvider();
// Stateless version: only stateless versions can be registered here.
var serviceProvider = new ServiceCollection()
.AddXtender((builder, provider) =>
{
builder
.Default<MyDefaultExtension>()
.Attach<Item, ItemExtension>()
.Attach<Composite, CompositeExtension>(() => new CompositeExtension());
})
.BuildServiceProvider();
Async:
// Stateful version: both extension types can be registered here.
var serviceProvider = new ServiceCollection()
.AddAsyncXtender<string>((builder, provider) =>
{
builder
.Default<MyDefaultExtension>()
.Attach<Item, StatefulItemExtension>()
.Attach<Composite, CompositeExtension>(() => new CompositeExtension());
})
.BuildServiceProvider();
// Stateless version: only stateless versions can be registered here.
var serviceProvider = new ServiceCollection()
.AddAsyncXtender((builder, provider) =>
{
builder
.Default<MyDefaultExtension>()
.Attach<Item, ItemExtension>()
.Attach<Composite, CompositeExtension>(() => new CompositeExtension());
})
.BuildServiceProvider();
Here both the aforementioned ItemExtension and the CompositeExtension are linked to the extender by the builder object. The extensions themselves are constructed this way to ensure that they preserve update-to-date dependencies (dependencies with a short lifetime and/or specific temporary data should be retrieved in update-to-date form and should not be inserted while disposed). The IServiceProvider (marked as provider in the example) can be used next to the builder to determine the extension dependencies, though this is not always recommended. By that, be careful with Scoped dependencies.
Notice:
- The builder always starts with Default() (this method has an override) that ensures that there is a default extension being set for when a lookup for a certain extension for a specific concrete type results in it not being found. Then this default extension could handle these 'default' cases.
- The builder will give rise to a specific extender-core which will be registered as a Singleton dependency, though, the refreshment of the extensions is ensured by letting the extender replay a providing-lambda stored in the dictionary on the given key. It should be noted that when a developer wants to store multiple extenders with the same visitor-state, he/she should use the ExtenderFactory methodology or use libraries like: ModulR.
Sync:
// Stateful version: both extension types can be registered here.
var serviceProvider = new ServiceCollection()
.AddXtenderFactory<string, OrderCreateRequest>((builder, provider) =>
{
builder.WithExtender("build-up", bldr =>
{
bldr.Default()
.Attach<Order, OrderCreateExtension>()
.Attach<OrderLine, StatefulOrderLineCreateExtension>()
.Attach<Address, OrderAddressCreateExtension>()
});
builder.WithExtender("attachments", bldr =>
{
bldr.Default()
.Attach<OrderAttachment, StatefulOrderAttachmentCreateExtension>()
.Attach<Address, OrderAttachmentAddressCreateExtension>()
});
})
.BuildServiceProvider();
// Stateless version: only stateless versions can be registered here.
var serviceProvider = new ServiceCollection()
.AddXtenderFactory<string>((builder, provider) =>
{
builder.WithExtender("build-up", bldr =>
{
bldr.Default()
.Attach<Order, OrderCreateExtension>()
.Attach<OrderLine, OrderLineCreateExtension>()
.Attach<Address, OrderAddressCreateExtension>()
});
builder.WithExtender("attachments", bldr =>
{
bldr.Default()
.Attach<OrderAttachment, OrderAttachmentCreateExtension>()
.Attach<Address, OrderAttachmentAddressCreateExtension>()
});
})
.BuildServiceProvider();
Async:
// Stateful version: both extension types can be registered here.
var serviceProvider = new ServiceCollection()
.AddAsyncXtenderFactory<string, OrderCreateRequest>((builder, provider) =>
{
builder.WithExtender("build-up", bldr =>
{
bldr.Default()
.Attach<Order, OrderCreateExtension>()
.Attach<OrderLine, StatefulOrderLineCreateExtension>()
.Attach<Address, OrderAddressCreateExtension>()
});
builder.WithExtender("attachments", bldr =>
{
bldr.Default()
.Attach<OrderAttachment, StatefulOrderAttachmentCreateExtension>()
.Attach<Address, OrderAttachmentAddressCreateExtension>()
});
})
.BuildServiceProvider();
// Stateless version: only stateless versions can be registered here.
var serviceProvider = new ServiceCollection()
.AddAsyncXtenderFactory<string>((builder, provider) =>
{
builder.WithExtender("build-up", bldr =>
{
bldr.Default()
.Attach<Order, OrderCreateExtension>()
.Attach<OrderLine, OrderLineCreateExtension>()
.Attach<Address, OrderAddressCreateExtension>()
});
builder.WithExtender("attachments", bldr =>
{
bldr.Default()
.Attach<OrderAttachment, OrderAttachmentCreateExtension>()
.Attach<Address, OrderAttachmentAddressCreateExtension>()
});
})
.BuildServiceProvider();
OrderCreateRequest is used here to function as an object of state for the visitor/extender and the extensions can choose to modify it. What happens here is that the factory is created and two extenders are being build up, both using the same type of state. The difference with this and the single registration example (seen further above) is that these here are not dependent on a singleton core. The cores created for these extenders are stored with the factory. Although, the extenders are not singleton dependent, the ExtenderFactory/AsyncExtenderFactory is. The names given within the registrations for the extenders ("build-up" and "attachments") are functioning as keys for which these extenders are stored within ExtenderFactory /AsyncExtenderFactory (the factory utilizes a dictionary to find specific lambda's by key as factories that create the extenders). The keys can then be used to query the factory for the creation of the right extender setup. The keys are strings because the first of the generics given for AddXtenderFactory /AddAsyncXtenderFactory describes the key-type.
❗ NOTE |
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The builders for the extenders in this example all utilize the Default method without generic. This will provide the respected extender with a really default (do-nothing) type of default-extension. This is the so-called DefaultExtension/AsyncDefaultExtension that is provided out of the box by the Xtender library. |
-
Attach methods have to give both the context type and the extension type. The context type is the concrete type/implementation type or whatever object that implements the IAccepter/IAsyncAccepter interface and has to be visited/extended by this extender.
-
❗ NOTE The way the visitor pattern works is that the visitor is passed to the accepter, so here in this library: to pass Extender/AsyncExtender to the accepter. The other way around, the Extender/AsyncExtender could originally not find the right type for the accepter and would directly utilize the default extension, however the proxy implementation in this library does now enable both ways as stated before. It is recommended to implement the Accept method of the accepting-object to directly pass itself to the extender Extend method.
The extender itself has already been defined within the library and carries the extensions as well as the visitor-state. This state type is determined by the AddXtender(...)/AddSyncXtender(...) method, where the TState serves this purpose. The state is used to carry specific data that would, when using the standard Visitor Pattern, have been preserved by the visitor class itself and could be updated when visiting the accepting-objects. So the state in this implementation provides its take on that regard as well as a differentiating key for creating multiple extenders with different configuration through defining a differently typed state.
Sync:
// An example composition.
var composition = new Composite
{
Components = new List<Component>
{
new Item(),
new Item(),
new Composite()
{
new Item(),
new Item(),
new Item()
}
}
};
// Getting the extender from the ServiceProvider from the DI.
var extender = services.GetRequiredService<IExtender<string>>();
// The extension process here as adding new operations. NOTE: Best practice is to always pass Extender to Accepter.
composition.Accept(extender);
// Though, because of the proxy it is also possible to do this:
extender.Extend(composition);
Async:
// An example composition.
var composition = new Composite
{
Components = new List<Component>
{
new Item(),
new Item(),
new Composite()
{
new Item(),
new Item(),
new Item()
}
}
};
// Getting the extender from the ServiceProvider from the DI.
var extender = services.GetRequiredService<IAsyncExtender<string>>();
// The extension process here as adding new operations. NOTE: Best practice is to always pass Extender to Accepter.
await composition.Accept(extender);
// Though, because of the proxy it is also possible to do this:
await extender.Extend(composition);
And the same example when the ExtenderFactory/AsyncExtenderFactory has been registered:
Sync:
// An example composition.
var composition = new Composite
{
Components = new List<Component>
{
new Item(),
new Item(),
new Composite()
{
new Item(),
new Item(),
new Item()
}
}
};
// Getting the ExtenderFactory from the ServiceProvider from the DI.
var factory = services.GetRequiredService<IExtenderFactory<string, string>>(); // 1st generic is the key, 2nd generic the state, when using the stateful version, otherwise not a 2nd generic.
// Letting the extender be created for a saved core by the ExtenderFactory.
var extender = factory.Create("component-traverser");
// The extension process here as adding new operations.
composition.Accept(extender);
Async:
// An example composition.
var composition = new Composite
{
Components = new List<Component>
{
new Item(),
new Item(),
new Composite()
{
new Item(),
new Item(),
new Item()
}
}
};
// Getting the ExtenderFactory from the ServiceProvider from the DI.
var factory = services.GetRequiredService<IAsyncExtenderFactory<string, string>>(); // 1st generic is the key, 2nd generic the state, when using the stateful version, otherwise not a 2nd generic.
// Letting the extender be created for a saved core by the ExtenderFactory.
var extender = factory.Create("component-traverser");
// The extension process here as adding new operations.
await composition.Accept(extender);
The Xtender.Trees package provides the means of creating tree-structures where the tree-nodes implement the IAccepter and IAsyncAccepter interfaces, so the Xtender functionality can be applied to this tree. This tree-structure is provided because of it being one of the ultimate structures that can be visited. As stated before, the composite pattern works quite well with the visitor pattern because of the abstract fashion of composites and the abililty for the visitor pattern to traverse and visit these nodes in their concrete form.
The Xtender.Trees package provides the tree and node interfaces as well as a tree-builder and a node-builder to quickly construct trees and nodes.
Possible cases for which this library can be used:
- Using a more dynamic version of the Visitor Pattern that conforms more to the SOLID design principles.
- When needed to traverse a tree-structure/composition where the amount of concrete component implementations could change.
- Recycle algorithmic components and compose a client (extender) with a custom set of combinations regarding these components.
- Extensive validation purposes.
- Using it as an intermediate layer in between services and domain models, where the domain models could be composed into a compositional structure. For a lot of developers and designers it is often the idea to always communicate with a concrete model. The reason is that an interface or an abstract class would be hiding the implementation of an domain model which is not preferred. Nevertheless, with the visitor approach (and especially with the dynamics of this library) it is no longer a far stretch to be open minded for the idea of using the composite pattern, because the negative effects of not being able to directly access the discrete implementation of the model are now mostly removed, because that can now be achieved through the Visit method (or Extend methods in the context of this library).
Be aware that even though this solution is quite performant with the key-value data structure, the standard Visitor Pattern is still a good fit for more direct and easy to solve problems. Nevertheless, this library takes a modern and dynamic way with the request-to-handler approach and provides a closer focus to the SOLID design principles.
Possible use-cases for when to use this algorithm could, for example, be something like a school-system or an health-insurance system.
-
The school-system could for example house many new registered schools which signed an alignment with your school-administration application. Now consider that a lot of different schools have a lot of different layouts in, i.e., their learning paths and subject ordering to name a few instances. At that point it would be quite obvious to use the composite pattern to map all the different possible components to define a varying constructible school-layout modelling system so that every school registration can be established to the heart-desire of the school itself.
Now it would be quite difficult to apply rules directly on the composite structure, so the visitor pattern would be an obvious choice to achieve accessibility. Now with multiple schools being attached at different times and schools that are already registered having differentiating demands in their structures could be problematic to maintain with a simple visitor. That has to do with a lot of changes that have to be applied, while this could also bring a lot of new problems. So a nice solution would be to use the Xtender library to solve those problems as well.
-
The health-insurance system would take quite a similar approach as the school-system. Now instead of school-layouts this would be the something like the layout of different policies or customizable declarations/contracts in regards to treatments for patients that can be more fine-grained and flexible. Consider for moment that those structures would be quite extensive as multiple hundreds of different combinations are possible. So again to apply rules, operations, validations or whatever to the structure, it would be quite useful to apply the Xtender library for this specific use-case.