MVVM / PRISM: Where should dialog box strings be stored? - wpf

I'm building an application using PRISM and MVVM. I have a view model that needs to display a non-modal dialog box to the user indicating an operation is in progress. I'm using essentially an abstracted IDialogService.
My question is: where should I store the strings for the title and the message shown in this dialog box? The view model's logic causes the dialog box to be displayed and determines when it should be closed. Hence, I have code that looks like this in my view model:
let! closeDlgAction =
dialogSvc.ShowDialogModeless (
"Opening File",
"Please wait while your selected file is opened.") |> Async.AwaitTask
I'm thinking about localization scenarios. WPF has its own mechanism for providing localization through resource dictionary, etc. It seems like these strings belong in a resource dictionary, but the view model shouldn't have a dependency on WPF resource directories - especially because the same view model is going to be used on a Xamarin Forms application later.
The best solution that comes to mind is to use a service that abstracts the resource library away (e.g. IDialogStringService), but I wonder if there's a better or more preferred approach?

You shouldn't use resource dictionaries (xaml) to store text. Instead you have to use Resources (*.resx). In VS:
Right click on project
Add -> New Item...
Find "Resources File" template, type name, and click Add
Opt. Open this file (special editor will opened) and on top bar switch Access Modifier to Public, if you want get access to text from another project or from XAML. Add some key\value strings.
Right click on resource file and click Run Custom Tool. New class will generated with static properties with names based on your keys from Step 4.
How to use (if file has name Localizations.resx and has string with key "AppTitle")
From code:
let! closeDlgAction =
dialogSvc.ShowDialogModeless (
Localizations.AppTitle,
"Please wait while your selected file is opened.") |> Async.AwaitTask
From xaml:
<Window
x:Class="MainWindow"
xmlns="http://schemas.microsoft.com/winfx/2006/xaml/presentation"
xmlns:x="http://schemas.microsoft.com/winfx/2006/xaml"
Title="{x:Static Localizations.AppTitle}"/>
*.resx file and *.cs file that is generated both don't depend on any WPF assemblies, so you can use them in different assemblies: in shared view models, from wpf views and from xamarin views. Just put you *.resx file in separate netstandard assembly and refer to it where do you need it from
Cons of this way:
resx generates class with strings and each string is public property, so static code analyze works
You don't have add new abstraction level
You can ref strings from code files or from XAML

I liked Vadim's answer, and I have used that approach before. If my View Models lived in the same project as the WPF project, that would be the best solution.
However, my View Models are in a different library (and a different language) and will be shared between a Prism MVVM WPF project and a Prism MVVM Xamarin Forms project. I could still use resources in the View Model library, but then localization concerns would exist separately in both the WPF project (for the Views) and the View Model library. IMO the localization concern should be centralized.
As such, I decided to abstract the resources behind a service. Implementing the resource service turned out to be more straightforward than I thought. To use an indexer intuitively, I defined a "resource container object" that is returned by IResourceService, as seen below:
public struct ResourceContainer
{
private readonly Func<string, string> _resourceGetter;
public string this[string resourceId] => _resourceGetter(resourceId);
public ResourceContainer(Func<string, string> resourceGetter) => _resourceGetter = resourceGetter;
}
public interface IResourceService
{
ResourceContainer Resources { get; }
}
And the service implementation in the WPF library is as follows:
public class ResourceService : IResourceService
{
public ResourceService()
{
Resources = new ResourceContainer((s) => Application.Current.Resources[s] as string);
}
public ResourceContainer Resources { get; }
}
In the WPF layer's XAML resource directory:
<s:String x:Key="FileOpenDialogTitle">Opening File</s:String>
<s:String x:Key="FileOpenDialogMessage">Please wait while your selected file is opened.</s:String>
And, finally, the View Model consumes this service by requesting IResourceService on its constructor, and is used as follows:
let! closeDlgAction =
dialogSvc.ShowDialogModeless (
resourceSvc.Resources.["FileOpenDialogTitle"],
resourceSvc.Resources.["FileOpenDialogMessage"]) |> Async.AwaitTask
This approach will ultimately require implementing the resources twice - once for the WPF project and once for the XF project, but I have to implement the Views twice, anyway. At least the localization concerns are centralized in both cases (or perhaps a shared resource library can be used between both projects).
EDIT: This technique could also leverage Vadim's suggestion by putting the localization resource (.resx) in the WPF project as well, and either having the XAML resource directory reference the static resources, or have the ResourceService return the resource directly. Having the resources in .resx format may make sharing them between multiple projects more straightforward.

Related

How do you access to your image resources in MVVM WPF applications?

I have been integrating image resources to my WPF assemblies for quite a time, but I never really found a really pretty way of binding them in my MVVM applications.
So I was wondering if some you, stackoverflow users, could share their own practice when it comes to assembly ressources:
How do you reference them in C#/VB and XAML?
When exposing them from code, what type do you expose? (BitmapImage, Uri, string, ...)
Do you prefer referencing them from the view or binding them through view-model?
Do you use a specific assembly to store them? How do you organize them?
Thanks for your help ;-)
This is what I do...
Images are kept in some folder such as Images in project's root folder. You can keep them in any assembly.
Individual image has Build Action property set to Resource type.
The ViewModel holds image name in string (say property MyImageName) and I convert it as a relative path when bound to the Source of Image object in XAML...
public class ImagePathConverter
{
public void Convert(...)
{
return "pack://application:,,,/MyApplicationName;component/Images/" + value.ToString();
}
}
where MyApplicationName is the short assembly's name that is having the Images folder under it.
In XAML, assuming the view model instance is bound to the data context of the entire view and / or atleast to the image's data contect ....
<Image Source="{Binding Path=MyImageName, Converter={StaticResource ImagePathConverter}}" />
But then thats one of the typical ways to refer images in a WPF project via MVVM. Other ways include an Image's binary stream loaded (from resx or Content type images or from binary database). In such case your converter will convert it into a BitMapImageSource.

What is a ViewModelLocator and what are its pros/cons compared to DataTemplates?

Can someone give me a quick summary of what a ViewModelLocator is, how it works, and what the pros/cons are for using it compared to DataTemplates?
I have tried finding info on Google but there seems to be many different implementations of it and no striaght list as to what it is and the pros/cons of using it.
Intro
In MVVM the usual practice is to have the Views find their ViewModels by resolving them from a dependency injection (DI) container. This happens automatically when the container is asked to provide (resolve) an instance of the View class. The container injects the ViewModel into the View by calling a constructor of the View which accepts a ViewModel parameter; this scheme is called inversion of control (IoC).
Benefits of DI
The main benefit here is that the container can be configured at run time with instructions on how to resolve the types that we request from it. This allows for greater testability by instructing it to resolve the types (Views and ViewModels) we use when our application actually runs, but instructing it differently when running the unit tests for the application. In the latter case the application will not even have a UI (it's not running; just the tests are) so the container will resolve mocks in place of the "normal" types used when the application runs.
Problems stemming from DI
So far we have seen that the DI approach allows easy testability for the application by adding an abstraction layer over the creation of application components. There is one problem with this approach: it doesn't play well with visual designers such as Microsoft Expression Blend.
The problem is that in both normal application runs and unit test runs, someone has to set up the container with instructions on what types to resolve; additionally, someone has to ask the container to resolve the Views so that the ViewModels can be injected into them.
However, in design time there is no code of ours running. The designer attempts to use reflection to create instances of our Views, which means that:
If the View constructor requires a ViewModel instance the designer won't be able to instantiate the View at all -- it will error out in some controlled manner
If the View has a parameterless constructor the View will be instantiated, but its DataContext will be null so we 'll get an "empty" view in the designer -- which is not very useful
Enter ViewModelLocator
The ViewModelLocator is an additional abstraction used like this:
The View itself instantiates a ViewModelLocator as part of its resources and databinds its DataContext to the ViewModel property of the locator
The locator somehow detects if we are in design mode
If not in design mode, the locator returns a ViewModel that it resolves from the DI container, as explained above
If in design mode, the locator returns a fixed "dummy" ViewModel using its own logic (remember: there is no container in design time!); this ViewModel typically comes prepopulated with dummy data
Of course this means that the View must have a parameterless constructor to begin with (otherwise the designer won't be able to instantiate it).
Summary
ViewModelLocator is an idiom that lets you keep the benefits of DI in your MVVM application while also allowing your code to play well with visual designers. This is sometimes called the "blendability" of your application (referring to Expression Blend).
After digesting the above, see a practical example here.
Finally, using data templates is not an alternative to using ViewModelLocator, but an alternative to using explicit View/ViewModel pairs for parts of your UI. Often you may find that there's no need to define a View for a ViewModel because you can use a data template instead.
An example implementation of #Jon's answer
I have a view model locator class. Each property is going to be an instance of the view model that I'm going to allocate on my view. I can check if the code is running in design mode or not using DesignerProperties.GetIsInDesignMode. This allows me to use a mock model during designing time and the real object when I'm running the application.
public class ViewModelLocator
{
private DependencyObject dummy = new DependencyObject();
public IMainViewModel MainViewModel
{
get
{
if (IsInDesignMode())
{
return new MockMainViewModel();
}
return MyIoC.Container.GetExportedValue<IMainViewModel>();
}
}
// returns true if editing .xaml file in VS for example
private bool IsInDesignMode()
{
return DesignerProperties.GetIsInDesignMode(dummy);
}
}
And to use it I can add my locator to App.xaml resources:
xmlns:core="clr-namespace:MyViewModelLocatorNamespace"
<Application.Resources>
<core:ViewModelLocator x:Key="ViewModelLocator" />
</Application.Resources>
And then to wire up your view (ex: MainView.xaml) to your viewmodel:
<Window ...
DataContext="{Binding Path=MainViewModel, Source={StaticResource ViewModelLocator}}">
I don't understand why the other answers of this question wrap around the Designer.
The purpose of the View Model Locator is to allow your View to instantiate this (yes, View Model Locator = View First):
public void MyWindowViewModel(IService someService)
{
}
instead of just this:
public void MyWindowViewModel()
{
}
by declaring this:
DataContext="{Binding MainWindowModel, Source={StaticResource ViewModelLocator}}"
Where ViewModelLocator is class, which references a IoC and that's how it solves the MainWindowModel property it exposes.
It has nothing to do with providing Mock view models to your view. If you want that, just do
d:DataContext="{d:DesignInstance MockViewModels:MockMainWindowModel, IsDesignTimeCreatable=True}"
The View Model Locator is a wrapper around some (any) Inversion of Control container, such as Unity for example.
Refer to:
How to handle dependency injection in a WPF/MVVM application
http://blog.qmatteoq.com/the-mvvm-pattern-dependency-injection/

I don't understand the syntax to inherit a wpf user control

I have read multiple posts on the subject but still cannot manage to make it work.
I want 2 user controls slidertype1 and slidertype2 which should inherit from slidercommontype, all are in same namespacecommon, can someone knows the syntax for this simple use case ?
Inspiring from http://jamescrisp.org/2008/05/26/wpf-control-inheritance-with-generics/
I tried:
<namespacecommon:slidercommontype x:Class="namespacecommon.slidertype1">
but I got namespacecommon:slidercommontyp doesn't exist in xml namespace.
As long as the base class doesn't have a XAML file associated with it, it's pretty easy. Trying to incorporate the visual aspect of the user control using XAML is not really a supported scenario.
Having said that, just create your class SliderCommonType (although I would call it SliderBase or something.)
namespace MyControls {
public class SliderBase : UserControl {
}
}
Then create your two controls based on it. I'll show one example and the other should be obvious.
<Local:SliderBase x:Class="MyControls.SliderType1"
xmlns:Local="clr-namespace:MyControls">
</Local:SliderBase>
And the code-behind would look like this:
namespace MyControls {
public class SliderType1 : SliderBase {
}
}
The key point being that your XAML file has to reference the base class which requires changing the <UserControl> element to <Local:SliderBase> which in turn requires a XAML namespace import.
When you add a UserControl using the default template, you can just change the code it creates to reflect the above changes. It's much easier than trying to create it from scratch.
One last thing to note - you will need your application to compile successfully before you can use the visual designer on your derived controls. This is because the designer needs to be able to instantiate SliderBase at design-time.

Silverlight Custom Control in F# DefaultStyleKey

Wondering how to accomplish setting the Style xaml with the code in F#. The code is simple enough:
this.DefaultStyleKey <- typeof<MyControl>
In a C# project the build options allow you to mark the XAML as a resource custom build command of: MSBuild:Compile
I don't see it in the properties panel, so I tried to add it by hand to the project file myself...
Any ideas? The application loads - the custom control has no output (but the code executes).
Thanks
UPDATE:
I checked the manifests and the resource was included as expected between my project and the project I am porting... Looking for a next step.
UPDATE 2:
Well it may be included in the manifest OK - but it is not being "compiled" as the C# version of the project throws an error in the build process when I malform the XML while the F# version allows the malformed XML to be brought into the application.
UPDATE 3:
Loading the XAML is fine now (i guess) however I am having some issues with the properties of the control:
static member ItemsProperty : DependencyProperty =
DependencyProperty.Register(
"Items",
typeof<MyMenuItemCollection>,
typeof<MyMenu>,
null);
member this.Items
with get () : MyMenuItemCollection = this.GetValue(MyMenu.ItemsProperty) :?> MyMenuItemCollection
and set (value: MyMenuItemCollection) = this.SetValue(MyMenu.ItemsProperty, value);
The problem occurs on access:
for menuItem in this.Items do
let contentElement: FrameworkElement = menuItem.Content
where I get a null pointer exception on this.Items; however I have it initialized in the constructor:
do
this.Items <- new CoolMenuItemCollection()
The C# style of compilation of XAML files is not supported by the F# tools for Visual Studio, so there is no way to get the same behavior as in C#. I think you have two options:
Create a C# project with XAML files and reference F# library which implements the core functionality (or reference C# library from F# and load user interface from the C# library in your F# application)
Use XamlReader object (see MSDN) and load the XAML file (embedded in resources in the simple way) programmatically. You won't get any of the C#-compiler generated features (e.g. named properties for all objects with x:Name), but otherwise, it should work in the usual way.

Open File Dialog MVVM

Ok I really would like to know how expert MVVM developers handle an openfile dialog in WPF.
I don't really want to do this in my ViewModel(where 'Browse' is referenced via a DelegateCommand)
void Browse(object param)
{
//Add code here
OpenFileDialog d = new OpenFileDialog();
if (d.ShowDialog() == true)
{
//Do stuff
}
}
Because I believe that goes against MVVM methodology.
What do I do?
Long story short:
The solution is to show user interactions from a class, that is part of the view component.
This means, such a class must be a class that is unknown to the view model and therefore can't be invoked by the view model.
The solution of course can involve code-behind implementations as code-behind is not relevant when evaluating whether a solution complies with MVVM or not.
Beside answering the original question, this answer also tries to provide an alternative view on the general problem why controlling a UI component like a dialog from the view model violates the MVVM design pattern and why workarounds like a dialog service don't solve the problem.
1 MVVM and dialogs
1.1 Critique of common suggestions
Almost all answers are following the misconception that MVVM is a pattern, that targets class level dependencies and also requires empty code-behind files. But it's an architectural pattern, that tries to solve a different problem - on application/component level: keeping the business domain decoupled from the UI.
Most people (here on SO) agree that the view model should not handle dialogs, but then propose to move the UI related logic to a helper class (doesn't matter if it's called helper or service), which is still controlled by the view model.
This (especially the service version) is also known as dependency hiding. Many patterns do this. Such patterns are considered anti-patterns. Service Locator is the most famous dependency hiding anti-pattern.
That is why I would call any pattern that involves extraction of the UI logic from the view model class to a separate class an anti-pattern too. It does not solve the original problem: how to change the application structure or class design in order to remove the UI related responsibilities from a view model (or model) class and move it back to a view related class.
In other words: the critical logic remains being a part of the view model component.
For this reason, I do not recommend to implement solutions, like the accepted one, that involve a dialog service (whether it is hidden behind an interface or not). If you are concerned to write code that complies with the MVVM design pattern, then simply don't handle dialog views or messaging inside the view model.
Introducing an interface to decouple class level dependencies, for example an IFileDialogService interface, is called Dependency Inversion principle (the D in SOLID) and has nothing to do with MVVM. When it has no relevance in terms of MVVM, it can't solve an MVVM related problem. When room temperature does not have any relevance whether a structure is a four story building or a skyscraper, then changing the room temperature can never turn any building into a skyscraper. MVVM is not a synonym for Dependency Inversion.
MVVM is an architectural pattern while Dependency Inversion is an OO language principle that has nothing to do with structuring an application (aka software architecture). It's not the interface (or the abstract type) that structures an application, but abstract objects or entities like components or modules e.g. Model - View - View Model. An interface can only help to "physically" decouple the components or modules. It doesn't remove component associations.
1.2 Why dialogs or handling Window in general feels so odd?
We have to keep in mind that the dialog controls like Microsoft.Win32.OpenFileDialog are "low level" native Windows controls. They don't have the necessary API to smoothly integrate them into a MVVM environment. Because of their true nature, they have some limitations the way they can integrate into a high level framework like WPF. Dialogs or native window hosts in general, are a known "weakness" of all high level frameworks like WPF.
Dialogs are commonly based on the Window or the abstract CommonDialog class. The Window class is a ContentControl and therefore allows styles and templates to target the content.
One big limitation is, that a Window must always be the root element. You can't add it as a child to the visual tree and e.g. show/launch it using triggers or host it in a DataTemplate.
In case of the CommonDialog, it can't be added to the visual tree, because it doesn't extend UIElement.
Therefore, Window or CommonDialog based types must always be shown from code-behind, which I guess is the reason for the big confusion about handling this kind of controls properly.
In addition, many developers, especially beginners that are new to MVVM, have the perception that code-behind violates MVVM.
For some irrational reason, they find it less violating to handle the dialog views in the view model component.
Due to it's API, a Window looks like a simple control (in fact, it extends ContentControl). But underneath, it hooks into to the low level of the OS. There is a lot of unmanaged code necessary to achieve this. Developers that are coming from low level C++ frameworks like MFC know exactly what's going on under the hoods.
The Window and CommonDialog class are both true hybrids: they are part of the WPF framework, but in order to behave like or actually to be a native OS window, they must be also part of the low level OS infrastructure.
The WPF Window, as well as the CommonDialog class, is basically a wrapper around the complex low level OS API. That's why this controls have sometimes a strange feel (from the developer point of view), when compared to common and pure framework controls.
That Window is sold as a simple ContentControl is quite deceptive. But since WPF is a high level framework, all low level details are hidden from the API by design.
We have to accept that we have to handle controls based on Window and CommonDialog using C# only - and that code-behind does not violate any design pattern at all.
If you are willing to waive the native look and feel and the general OS integration to get the native features like theming and task bar, you can improve the handling by creating a custom dialog e.g., by extending Control or Popup, that exposes relevant properties as DependencyProperty. You can then set up data bindings and XAML triggers to control the visibility, like you usually would.
1.3 Why MVVM?
Without a sophisticated design pattern or application structure, developers would e.g., directly load database data to a table control and mix UI logic with business logic. In such a scenario, changing to a different database would break the UI. But even worse, changing the UI would require to change the logic that deals with the database. And when changing the logic, you would also need to change the related unit tests.
The real application is the business logic and not the fancy GUI.
You want to write unit tests for the business logic - without being forced to include any UI.
You want to modify the UI without modifying the business logic and unit tests.
MVVM is a pattern that solves this problems and allows to decouple the UI from the business logic i.e. data from views. It does this more efficiently than the related design patterns MVC and MVP.
We don't want to have the UI bleed into the lower levels of the application. We want to separate data from data presentation and especially their rendering (data views). For example, we want to handle database access without having to care which libraries or controls are used to view the data. That's why we choose MVVM. For this sake, we can't allow to implement UI logic in components other than the view.
1.4 Why moving UI logic from a class named ViewModel to a separate class still violates MVVM
By applying MVVM, you effectively structuring the application into three components: model, view and view model. It is very important to understand that this partitioning or structure is not about classes. It's about application components.
You may follow the widely spread pattern to name or suffix a class ViewModel, but you must know that the view model component usually contains many classes of which some are not named or suffixed with ViewModel - View Model is an abstract component.
Example:
when you extract functionality, like creating a data source collection, from a big class named MainViewModel and you move this functionality to a new class named ItemCreator, then this class ItemCreator is logically still part of the view model component.
On class level the functionality is now outside the MainViewModel class (while MainViewModel now has a strong reference to the new class, in order to invoke the code). On application level (architecture level), the functionality is still in the same component.
You can project this example onto the often proposed dialog service: extracting the dialog logic from the view model to a dedicated class named DialogService doesn't move the logic outside the view model component: the view model still depends on this extracted functionality.
The view model still participates in the UI logic e.g by explicitly invoking the "service" to control when dialog is shown and to control the dialog type itself (e.g., file open, folder select, color picker etc.).
This all requires knowledge of the UI's business details. Knowledge, that per definition does not belong into the view model component. Of course, such knowlegde introduces a coupling/dependency from the view model component to the view component.
Responsibilities simply don't change because you name a class DialogService instead of e.g. DialogViewModel.
The DialogService is therefore an anti-pattern, which hides the real problem: having implemented view model classes, that depend on UI and execute UI logic.
1.5 Does writing code-behind violates the MVVM design pattern?
MVVM is a design pattern and design patterns are per definition library independent, framework independent and language or compiler independent. Therefore, code-behind is not a topic when talking about MVVM.
The code-behind file is absolutely a valid context to write UI code. It's just another file that contains C# code. Code-behind means "a file with a .xaml.cs extension". It's also the only place for event handlers. And you don't want to stay away from events.
Why does the mantra "No code in code-behind" exist?
For people that are new to WPF, UWP or Xamarin, like those skilled and experienced developers coming from frameworks like WinForms, we have to stress that using XAML should be the preferred way to write UI code. Implementing a Style or DataTemplate using C# (e.g. in the code-behind file) is too complicated and produces code that is very difficult to read => difficult to understand => difficult to maintain.
XAML is just perfect for such tasks. The visually verbose markup style perfectly expresses the UI's structure. It does this far better, than for example C# could ever do. Despite markup languages like XAML may feel inferior to some or not worth learning it, it's definitely the first choice when implementing GUI. We should strive to write as much GUI code as possible using XAML.
But such considerations are absolutely irrelevant in terms of the MVVM design pattern.
Code-behind is simply a compiler concept, realized by the partial directive (in C#). That's why code-behind has nothing to do with any design pattern. That's why neither XAML nor C# can't have anything to do with any design pattern.
2 Solution
Like the OP correctly concludes:
"I don't really want to do this [open a file picker dialog] in my
ViewModel(where 'Browse' is referenced via a DelegateCommand).
Because I believe that goes against MVVM methodology.
2.1 Some fundamental considerations
A dialog is a UI control: a view.
The handling of a dialog control or a control in general e.g. showing/hiding is UI logic.
MVVM requirement: the view model does not know about the existence of an UI or users. Because of this, a control flow that requires the view model to actively wait or call for user input, really requires some re-design: it is a critical violation and breaks the architectural boundaries dictated by MVVM.
Showing a dialog requires knowledge about when to show it and when to close it.
Showing the dialog requires to know about the UI and user, because the only reason to show a dialog is to interact with the user.
Showing the dialog requires knowledge about the current UI context (in order to choose the appropriate dialog type).
It is not the dependency on assemblies or classes like OpenFileDialog or UIElement that breaks the MVVM pattern, but the implementation or reference of UI logic in the view model component or model component (although such a dependency can be a valuable hint).
For the same reasons, it would be wrong to show the dialog from the model component too.
The only component responsible for UI logic is the view component.
From an MVVM point of view, there is nothing like C#, XAML, C++ or VB.NET. Which means, there is nothing like partial or the related infamous code-behind file (*.xaml.cs). The concept of code-behind exists to allow the compiler to merge the XAML part of a class with its C# part. After that merge, both files are treated as a single class: it's a pure compiler concept. partial is the magic that enables to write class code using XAML (the true compiler language is still C# or any other IL compliant language).
ICommand is an interface of the .NET library and therefore not a topic when talking about MVVM. It's wrong to believe that every action has to be triggered by an ICommand implementation in the view model.
Events are still a very useful concept that conform with MVVM, as long as the unidirectional dependency between the components is maintained. Always forcing the use of ICommand instead of using events leads to unnatural and smelly code like the code presented by the OP.
There is no such "rule" that ICommand must only be implemented by a view model class. It can be implemented by a view class too.
In fact, views commonly implement RoutedCommand (or RoutedUICommand), which both are implementions of ICommand, and can also be used to trigger the display of a dialog from e.g., a Window or any other control.
We have data binding to allow the UI to exchange data with the view model (anonymously, from the data source point of view). But since data binding can't invoke operations (at least in WPF - e.g., UWP allows this), we have ICommand and ICommandSource to realize this.
Interfaces in general are not a relevant concept of MVVM. Therefore, introducing an interface (e.g., IFileDialogService) can never solve a MVVM related problem.
Services or helper classes are not a concept of MVVM. Therefore, introducing services or helper classes can never solve a MVVM related problem.
Classes an their names or type names in general are not relevant in terms of MVVM. Moving view model code to a separate class, even if that class is not named or suffixed with ViewModel, can't solve a MVVM related problem.
2.2 Conclusion
The solution is to show user interactions from a class, that is part of the view component.
This means, such a class must be a class that is unknown to the view model and therefore can't be invoked by the view model.
This logic could be implemented directly in the code-behind file or inside any other class (file). The implementation can be a simple helper class or a more sophisticated (attached) behavior.
The point is: the dialog i.e. the UI component must be handled by the view component alone, as this is the only component that contains UI related logic. Since the view model does not have any knowledge of a view, it can't act actively to communicate with the view. Only passive communication is allowed (data binding, events).
We can always implement a certain flow using events raised by the view model that can be observed by the view in order to take actions like interacting with the user using a dialog.
There exist solutions using the view-model-first approach, which is does not violate MVVM in the first place. But still, badly designed responsibilities can turn this solution into an anti-pattern too.
3 How to fix the need for certain dialog requests
Most of the times, we can eliminate the need to show dialogs from within the application by fixing the application's design.
Since dialogs are a UI concept to enable interaction with the user, we must evaluate dialogs using UI design rules.
Maybe the most famous design rules for UI design are the 10 rules postulated by Nielsen and Molich in the 90's.
One important rule is about error prevention: it states that
a) we must prevent any kind of errors, especially input related, because
b) the user does not like his productivity to be interrupted by error messages and dialogs.
a) means: input data validation. Don't allow invalid data to enter the business logic.
b) means: avoid showing dialogs to the user, whenever possible. Never show a dialog from within the application and let the user trigger dialogs explicitly e.g., on mouse click (no unexpected interruption).
Following this simple rule certainly always eliminates the need to show a dialog triggered by the view model.
From the user's perspective, an application is a black box: it outputs data, accepts data and processes the input data. If we control the data input to guard against invalid data, we eliminate undefined or illegal states and ensure data integrity. This would mean that there is no need to ever show a dialog to the user from inside the application. Only those explicitly triggered by the user.
For example, a common scenario is that our model needs to persist data in a file. If the destination file already exists, we want to ask the user to confirm to overwrite this file.
Following the rule of error prevention, we always let the user pick files in the first place: whether it is a source file or a destination file, it's always the user who specifies this file by explicitly picking it via a file dialog. This means, the user must also explicitly trigger the file operation, for example by clicking on a "Save As" button.
This way, we can use a file picker or file save dialog to ensure only existing files are selected. As a bonus, we additionally eliminate the need to warn the user about overwriting existing files.
Following this approach, we have satisfied a) "[...]prevent any kind of errors, especially input related" and b) "[...]the user does not like to be interrupted by error messages and dialogs".
Update
Since people are questioning the fact that you don't need a view model to handle the dialog views, by coming up with extra "complicated" requirements like data validation to proof their point, I am forced to provide more complex examples to address these more complex scenarios (that were not initially requested by the OP).
4 Examples
4.1 Overview
The scenario is a simple input form to collect a user input like an album name and then use the OpenFileDialog to pick a destination file where the album name is saved to.
Three simple solutions:
Solution 1: Very simple and basic scenario, that meets the exact requirements of the question.
Solution 2: Solution that enables to use data validation in the view model. To keep the example simple, the implementation of INotifyDataErrorInfo is omitted.
Solution 3: Another, more elegant solution that uses an ICommand and the ICommandSource.CommandParameter to send the dialog result to the view model and execute the persistence operation.
Solution 1
The following example provides a simple and intuitive solution to show the OpenFileDialog in a MVVM compliant way.
The solution allows the view model to remain unaware of any UI components or logic.
You can even consider to pass a FileStream to the view model instead of the file path. This way, you can handle any errors, while creating the stream, directly in the UI e.g., by showing a dialog if needed.
View
MainWindow.xaml
<Window>
<Window.DataContext>
<MainViewModel />
</Window.DataContext>
<StackPanel>
<!-- The data to persist -->
<TextBox Text="{Binding AlbumName}" />
<!-- Show the file dialog.
Let user explicitly trigger the file save operation.
This button will be disabled until the required input is valid -->
<Button Content="Save as"
Click="SaveAlbumNameToFile_OnClick" />
</StackPanel>
</Window>
MainWindow.xaml.cs
partial class MainWindow : Window
{
public MainWindow()
=> InitializeComponent();
private void SaveAlbumNameToFile_OnClick(object sender, EventArgs e)
{
var dialog = new OpenFileDialog();
if (dialog.ShowDialog() == true)
{
// Consider to create the FileStream here to handle errors
// related to the user's picked file in the view.
// If opening the FileStream succeeds, we can pass it over to the viewmodel.
string destinationFilePath = dialog.FileName;
(this.DataContext as MainViewModel)?.SaveAlbumName(destinationFilePath);
}
}
}
View Model
MainViewModel.cs
class MainViewModel : INotifyPropertyChanged
{
// Raises PropertyChanged
public string AlbumName { get; set; }
// A model class that is responsible to persist and load data
private DataRepository DataRepository { get; }
public MainViewModel() => this.DataRepository = new DataRepository();
// Since 'destinationFilePath' was picked using a file dialog,
// this method can't fail.
public void SaveAlbumName(string destinationFilePath)
=> this.DataRepository.SaveData(this.AlbumName, destinationFilePath);
}
Solution 2
A more realistic solution is to add a dedicated TextBox as input field to enable collection of the destination file path via copy&paste.
This TextBox is bound to the view model class, which ideally implements INotifyDataErrorInfo to validate the file path before it is used.
An additional button will open the optional file picker view to allow the user to alternatively browse the file system to pick a destination.
Finally, the persistence operation is triggered by a "Save As" button:
View
MainWindow.xaml
<Window>
<Window.DataContext>
<MainViewModel />
</Window.DataContext>
<StackPanel>
<!-- The data to persist -->
<TextBox Text="{Binding AlbumName}" />
<!-- Alternative file path input, validated using INotifyDataErrorInfo validation
e.g. using File.Exists to validate the file path -->
<TextBox x:Name="FilePathTextBox"
Text="{Binding DestinationPath, ValidatesOnNotifyDataErrors=True}" />
<!-- Option to search a file using the file picker dialog -->
<Button Content="Browse" Click="PickFile_OnClick" />
<!-- Let user explicitly trigger the file save operation.
This button will be disabled until the required input is valid -->
<Button Content="Save as"
Command="{Binding SaveAlbumNameCommand}" />
</StackPanel>
</Window>
MainWindow.xaml.cs
partial class MainWindow : Window
{
public MainWindow()
{
InitializeComponent();
}
private void PickFile_OnClick(object sender, EventArgs e)
{
var dialog = new OpenFileDialog();
if (dialog.ShowDialog() == true)
{
this.FilePathTextBox.Text = dialog.FileName;
// Since setting the property explicitly bypasses the data binding,
// we must explicitly update it by calling BindingExpression.UpdateSource()
this.FilePathTextBox
.GetBindingExpression(TextBox.TextProperty)
.UpdateSource();
}
}
}
View Model
MainViewModel.cs
class MainViewModel : INotifyPropertyChanged, INotifyDataErrorInfo
{
private string albumName;
public string AlbumName
{
get => this.albumName;
set
{
this.albumName = value;
OnPropertyChanged();
}
}
private string destinationPath;
public string DestinationPath
{
get => this.destinationPath;
set
{
this.destinationPath = value;
OnPropertyChanged();
ValidateDestinationFilePath();
}
}
public ICommand SaveAlbumNameCommand => new RelayCommand(
commandParameter => ExecuteSaveAlbumName(this.TextValue),
commandParameter => true);
// A model class that is responsible to persist and load data
private DataRepository DataRepository { get; }
// Default constructor
public MainViewModel() => this.DataRepository = new DataRepository();
private void ExecuteSaveAlbumName(string destinationFilePath)
{
// Use a aggregated/composed model class to persist the data
this.DataRepository.SaveData(this.AlbumName, destinationFilePath);
}
}
Solution 3
The following solution is a more elegant version of the second scenario. It uses the ICommandSource.CommandParameter property to send the dialog result to the view model (instead of the data binding used in the previous example).
The validation of the optional user input (e.g. copy&paste) is validated using binding validation:
View
MainWindow.xaml
<Window x:Name="Window">
<Window.DataContext>
<MainViewModel />
</Window.DataContext>
<StackPanel>
<!-- The data to persist -->
<TextBox Text="{Binding AlbumName}" />
<!-- Alternative file path input, validated using binding validation
e.g. using File.Exists to validate the file path -->
<TextBox x:Name="FilePathTextBox">
<TextBox.Text>
<Binding ElementName="Window" Path="DestinationPath">
<Binding.ValidationRules>
<FilePathValidationRule />
</Binding.ValidationRules>
</Binding>
</TextBox.Text>
</TextBox>
<!-- Option to search a file using the file picker dialog -->
<Button Content="Browse" Click="PickFile_OnClick" />
<!-- Let user explicitly trigger the file save operation.
This button will be disabled until the required input is valid -->
<Button Content="Save as"
CommandParameter="{Binding ElementName=Window, Path=DestinationPath}"
Command="{Binding SaveAlbumNameCommand}" />
</StackPanel>
</Window>
FilePathValidationRule.cs
class FilePathValidationRule : ValidationRule
{
public override ValidationResult Validate(object value, CultureInfo cultureInfo)
=> value is string filePath && File.Exists(filePath)
? ValidationResult.ValidResult
: new ValidationResult(false, "File path does not exist.");
}
MainWindow.xaml.cs
partial class MainWindow : Window
{
public static readonly DependencyProperty DestinationPathProperty = DependencyProperty.Register(
"DestinationPath",
typeof(string),
typeof(MainWindow),
new PropertyMetadata(default(string)));
public string DestinationPath
{
get => (string)GetValue(MainWindow.DestinationPathProperty);
set => SetValue(MainWindow.DestinationPathProperty, value);
}
public MainWindow()
{
InitializeComponent();
}
private void PickFile_OnClick(object sender, EventArgs e)
{
var dialog = new OpenFileDialog();
if (dialog.ShowDialog() == true)
{
this.DestinationPath = dialog.FileName;
}
}
}
View Model
MainViewModel.cs
class MainViewModel : INotifyPropertyChanged, INotifyDataErrorInfo
{
private string albumName;
public string AlbumName
{
get => this.albumName;
set
{
this.albumName = value;
OnPropertyChanged();
}
}
public ICommand SaveAlbumNameCommand => new RelayCommand(
commandParameter => ExecuteSaveAlbumName(commandParameter as string),
commandParameter => true);
// A model class that is responsible to persist and load data
private DataRepository DataRepository { get; }
// Default constructor
public MainViewModel() => this.DataRepository = new DataRepository();
private void ExecuteSaveAlbumName(string destinationFilePath)
{
// Use a aggregated/composed model class to persist the data
this.DataRepository.SaveData(this.AlbumName, destinationFilePath);
}
}
The best thing to do here is use a service.
A service is just a class that you access from a central repository of services, often an IOC container. The service then implements what you need like the OpenFileDialog.
So, assuming you have an IFileDialogService in a Unity container, you could do...
void Browse(object param)
{
var fileDialogService = container.Resolve<IFileDialogService>();
string path = fileDialogService.OpenFileDialog();
if (!string.IsNullOrEmpty(path))
{
//Do stuff
}
}
I would have liked to comment on one of the answers, but alas, my reputation is not high enough to do so.
Having a call such as OpenFileDialog() violates the MVVM pattern because it implies a view (dialog) in the view model. The view model can call something like GetFileName() (that is, if simple binding is not sufficient), but it should not care how the file name is obtained.
The ViewModel should not open dialogs or even know of their existence. If the VM is housed in a separate DLL, the project should not have a reference to PresentationFramework.
I like to use a helper class in the view for common dialogs.
The helper class exposes a command (not an event) which the window binds to in XAML. This implies the use of RelayCommand within the view. The helper class is a DepencyObject so it can bind to the view model.
class DialogHelper : DependencyObject
{
public ViewModel ViewModel
{
get { return (ViewModel)GetValue(ViewModelProperty); }
set { SetValue(ViewModelProperty, value); }
}
public static readonly DependencyProperty ViewModelProperty =
DependencyProperty.Register("ViewModel", typeof(ViewModel), typeof(DialogHelper),
new UIPropertyMetadata(new PropertyChangedCallback(ViewModelProperty_Changed)));
private static void ViewModelProperty_Changed(DependencyObject d, DependencyPropertyChangedEventArgs e)
{
if (ViewModelProperty != null)
{
Binding myBinding = new Binding("FileName");
myBinding.Source = e.NewValue;
myBinding.Mode = BindingMode.OneWayToSource;
BindingOperations.SetBinding(d, FileNameProperty, myBinding);
}
}
private string FileName
{
get { return (string)GetValue(FileNameProperty); }
set { SetValue(FileNameProperty, value); }
}
private static readonly DependencyProperty FileNameProperty =
DependencyProperty.Register("FileName", typeof(string), typeof(DialogHelper),
new UIPropertyMetadata(new PropertyChangedCallback(FileNameProperty_Changed)));
private static void FileNameProperty_Changed(DependencyObject d, DependencyPropertyChangedEventArgs e)
{
Debug.WriteLine("DialogHelper.FileName = {0}", e.NewValue);
}
public ICommand OpenFile { get; private set; }
public DialogHelper()
{
OpenFile = new RelayCommand(OpenFileAction);
}
private void OpenFileAction(object obj)
{
OpenFileDialog dlg = new OpenFileDialog();
if (dlg.ShowDialog() == true)
{
FileName = dlg.FileName;
}
}
}
The helper class needs a reference to the ViewModel instance. See the resource dictionary. Just after construction, the ViewModel property is set (in the same line of XAML). This is when the FileName property on the helper class is bound to the FileName property on the view model.
<Window x:Class="DialogExperiment.MainWindow"
xmlns="http://schemas.microsoft.com/winfx/2006/xaml/presentation"
xmlns:x="http://schemas.microsoft.com/winfx/2006/xaml"
xmlns:local="clr-namespace:DialogExperiment"
xmlns:vm="clr-namespace:DialogExperimentVM;assembly=DialogExperimentVM"
Title="MainWindow" Height="350" Width="525">
<Window.Resources>
<vm:ViewModel x:Key="viewModel" />
<local:DialogHelper x:Key="helper" ViewModel="{StaticResource viewModel}"/>
</Window.Resources>
<DockPanel DataContext="{StaticResource viewModel}">
<Menu DockPanel.Dock="Top">
<MenuItem Header="File">
<MenuItem Header="Open" Command="{Binding Source={StaticResource helper}, Path=OpenFile}" />
</MenuItem>
</Menu>
</DockPanel>
</Window>
I use a service which i for example can pass into the constructor of my viewModel or resolve via dependency injection.
e.g.
public interface IOpenFileService
{
string FileName { get; }
bool OpenFileDialog()
}
and a class implementing it, using OpenFileDialog under the hood. In the viewModel, i only use the interface and thus can mock/replace it if needed.
I have solved it for me this way:
In ViewModel I have defined an interface and work with it in
ViewModel
In View I have implemented this interface.
CommandImpl is not implemented in code below.
ViewModel:
namespace ViewModels.Interfaces
{
using System.Collections.Generic;
public interface IDialogWindow
{
List<string> ExecuteFileDialog(object owner, string extFilter);
}
}
namespace ViewModels
{
using ViewModels.Interfaces;
public class MyViewModel
{
public ICommand DoSomeThingCmd { get; } = new CommandImpl((dialogType) =>
{
var dlgObj = Activator.CreateInstance(dialogType) as IDialogWindow;
var fileNames = dlgObj?.ExecuteFileDialog(null, "*.txt");
//Do something with fileNames..
});
}
}
View:
namespace Views
{
using ViewModels.Interfaces;
using Microsoft.Win32;
using System.Collections.Generic;
using System.Linq;
using System.Windows;
public class OpenFilesDialog : IDialogWindow
{
public List<string> ExecuteFileDialog(object owner, string extFilter)
{
var fd = new OpenFileDialog();
fd.Multiselect = true;
if (!string.IsNullOrWhiteSpace(extFilter))
{
fd.Filter = extFilter;
}
fd.ShowDialog(owner as Window);
return fd.FileNames.ToList();
}
}
}
XAML:
<Window xmlns:views="clr-namespace:Views"
xmlns:viewModels="clr-namespace:ViewModels">
<Window.DataContext>
<viewModels:MyViewModel/>
</Window.DataContext>
<Grid>
<Button Content = "Open files.." Command="{Binding DoSomeThingCmd}"
CommandParameter="{x:Type views:OpenFilesDialog}"/>
</Grid>
</Window>
Having a service is like opening up a view from viewmodel.
I have a Dependency property in view, and on the chnage of the property, I open up FileDialog and read the path, update the property and consequently the bound property of the VM

Resources