- If you want to add an app's icon to your Dock to make opening the app easier, read: How to add apps to the Dock on Mac. How to add an alias/shortcut to the Finder sidebar Adding an alias to the.
- Creating an Apple app is essential to the success of your business. By creating an Apple app, you’re not only tapping into a pool of millions of potential customers, you’re also guaranteeing that your business won’t get left in the dust. An app lets you compete not only.
This walkthrough shows how to create a traditional Windows desktop application in Visual Studio. The example application you'll create uses the Windows API to display 'Hello, Windows desktop!' in a window. You can use the code that you develop in this walkthrough as a pattern to create other Windows desktop applications.
Create your first Java application. In this tutorial, you will learn how to create, run, and package a simple Java application that prints Hello, World! To the system output. Along the way, you will get familiar with IntelliJ IDEA features for boosting your productivity as a. Aug 27, 2012 Choose a folder in your computer and click “Create”. The project is ready, and you should have a Mac Application with an single empty window. Let’s check out how it looks. Find the “Run” button, which is located in the left side of the toolbar at the top of XCode.
The Windows API (also known as the Win32 API, Windows Desktop API, and Windows Classic API) is a C-language-based framework for creating Windows applications. It has been in existence since the 1980s and has been used to create Windows applications for decades. More advanced and easier-to-program frameworks have been built on top of the Windows API. For example, MFC, ATL, the .NET frameworks. Even the most modern Windows Runtime code for UWP and Store apps written in C++/WinRT uses the Windows API underneath. For more information about the Windows API, see Windows API Index. There are many ways to create Windows applications, but the process above was the first.
Important
For the sake of brevity, some code statements are omitted in the text. The Build the code section at the end of this document shows the complete code.
Prerequisites
A computer that runs Microsoft Windows 7 or later versions. We recommend Windows 10 for the best development experience.
A copy of Visual Studio. For information on how to download and install Visual Studio, see Install Visual Studio. When you run the installer, make sure that the Desktop development with C++ workload is checked. Don't worry if you didn't install this workload when you installed Visual Studio. You can run the installer again and install it now.
An understanding of the basics of using the Visual Studio IDE. If you've used Windows desktop apps before, you can probably keep up. For an introduction, see Visual Studio IDE feature tour.
An understanding of enough of the fundamentals of the C++ language to follow along. Don't worry, we don't do anything too complicated.
Create a Windows desktop project
Follow these steps to create your first Windows desktop project. As you go, you'll enter the code for a working Windows desktop application. To see the documentation for your preferred version of Visual Studio, use the Version selector control. It's found at the top of the table of contents on this page.
To create a Windows desktop project in Visual Studio 2019
From the main menu, choose File > New > Project to open the Create a New Project dialog box.
At the top of the dialog, set Language to C++, set Platform to Windows, and set Project type to Desktop.
From the filtered list of project types, choose Windows Desktop Wizard then choose Next. In the next page, enter a name for the project, for example, DesktopApp.
Choose the Create button to create the project.
The Windows Desktop Project dialog now appears. Under Application type, select Desktop application (.exe). Under Additional options, select Empty project. Choose OK to create the project.
In Solution Explorer, right-click the DesktopApp project, choose Add, and then choose New Item.
In the Add New Item dialog box, select C++ File (.cpp). In the Name box, type a name for the file, for example, HelloWindowsDesktop.cpp. Choose Add.
Your project is now created and your source file is opened in the editor. To continue, skip ahead to Create the code.
To create a Windows desktop project in Visual Studio 2017
On the File menu, choose New and then choose Project.
In the New Project dialog box, in the left pane, expand Installed > Visual C++, then select Windows Desktop. In the middle pane, select Windows Desktop Wizard.
In the Name box, type a name for the project, for example, DesktopApp. Choose OK.
In the Windows Desktop Project dialog, under Application type, select Windows application (.exe). Under Additional options, select Empty project. Make sure Precompiled Header isn't selected. Choose OK to create the project.
In Solution Explorer, right-click the DesktopApp project, choose Add, and then choose New Item.
In the Add New Item dialog box, select C++ File (.cpp). In the Name box, type a name for the file, for example, HelloWindowsDesktop.cpp. Choose Add.
Your project is now created and your source file is opened in the editor. To continue, skip ahead to Create the code.
To create a Windows desktop project in Visual Studio 2015
On the File menu, choose New and then choose Project.
In the New Project dialog box, in the left pane, expand Installed > Templates > Visual C++, and then select Win32. In the middle pane, select Win32 Project.
In the Name box, type a name for the project, for example, DesktopApp. Choose OK.
On the Overview page of the Win32 Application Wizard, choose Next.
On the Application Settings page, under Application type, select Windows application. Under Additional options, uncheck Precompiled header, then select Empty project. Choose Finish to create the project.
In Solution Explorer, right-click the DesktopApp project, choose Add, and then choose New Item.
In the Add New Item dialog box, select C++ File (.cpp). In the Name box, type a name for the file, for example, HelloWindowsDesktop.cpp. Choose Add.
Your project is now created and your source file is opened in the editor.
Create the code
Next, you'll learn how to create the code for a Windows desktop application in Visual Studio.
To start a Windows desktop application
Just as every C application and C++ application must have a
main
function as its starting point, every Windows desktop application must have aWinMain
function.WinMain
has the following syntax.For information about the parameters and return value of this function, see WinMain entry point.
Note
What are all those extra words, such as
CALLBACK
, orHINSTANCE
, or_In_
? The traditional Windows API uses typedefs and preprocessor macros extensively to abstract away some of the details of types and platform-specific code, such as calling conventions, __declspec declarations, and compiler pragmas. In Visual Studio, you can use the IntelliSense Quick Info feature to see what these typedefs and macros define. Hover your mouse over the word of interest, or select it and press Ctrl+K, Ctrl+I for a small pop-up window that contains the definition. For more information, see Using IntelliSense. Parameters and return types often use SAL Annotations to help you catch programming errors. For more information, see Using SAL Annotations to Reduce C/C++ Code Defects.Windows desktop programs require <windows.h>. <tchar.h> defines the
TCHAR
macro, which resolves ultimately to wchar_t if the UNICODE symbol is defined in your project, otherwise it resolves to char. If you always build with UNICODE enabled, you don't need TCHAR and can just use wchar_t directly.Along with the
WinMain
function, every Windows desktop application must also have a window-procedure function. This function is typically namedWndProc
, but you can name it whatever you like.WndProc
has the following syntax.In this function, you write code to handle messages that the application receives from Windows when events occur. For example, if a user chooses an OK button in your application, Windows will send a message to you and you can write code inside your
WndProc
function that does whatever work is appropriate. It's called handling an event. You only handle the events that are relevant for your application.For more information, see Window Procedures.
To add functionality to the WinMain function
In the
WinMain
function, you populate a structure of type WNDCLASSEX. The structure contains information about the window: the application icon, the background color of the window, the name to display in the title bar, among other things. Importantly, it contains a function pointer to your window procedure. The following example shows a typicalWNDCLASSEX
structure.For information about the fields of the structure above, see WNDCLASSEX.
Register the
WNDCLASSEX
with Windows so that it knows about your window and how to send messages to it. Use the RegisterClassEx function and pass the window class structure as an argument. The_T
macro is used because we use theTCHAR
type.Now you can create a window. Use the CreateWindow function.
This function returns an
HWND
, which is a handle to a window. A handle is somewhat like a pointer that Windows uses to keep track of open windows. For more information, see Windows Data Types.At this point, the window has been created, but we still need to tell Windows to make it visible. That's what this code does:
The displayed window doesn't have much content because you haven't yet implemented the
WndProc
function. In other words, the application isn't yet handling the messages that Windows is now sending to it.To handle the messages, we first add a message loop to listen for the messages that Windows sends. When the application receives a message, this loop dispatches it to your
WndProc
function to be handled. The message loop resembles the following code.For more information about the structures and functions in the message loop, see MSG, GetMessage, TranslateMessage, and DispatchMessage.
At this point, the
WinMain
function should resemble the following code.
To add functionality to the WndProc function
To enable the
WndProc
function to handle the messages that the application receives, implement a switch statement.One important message to handle is the WM_PAINT message. The application receives the
WM_PAINT
message when part of its displayed window must be updated. The event can occur when a user moves a window in front of your window, then moves it away again. Your application doesn't know when these events occur. Only Windows knows, so it notifies your app with aWM_PAINT
message. When the window is first displayed, all of it must be updated.To handle a
WM_PAINT
message, first call BeginPaint, then handle all the logic to lay out the text, buttons, and other controls in the window, and then call EndPaint. For the application, the logic between the beginning call and the ending call displays the string 'Hello, Windows desktop!' in the window. In the following code, the TextOut function is used to display the string.HDC
in the code is a handle to a device context, which is used to draw in the window's client area. Use theBeginPaint
andEndPaint
functions to prepare for and complete the drawing in the client area.BeginPaint
returns a handle to the display device context used for drawing in the client area;EndPaint
ends the paint request and releases the device context.An application typically handles many other messages. For example, WM_CREATE when a window is first created, and WM_DESTROY when the window is closed. The following code shows a basic but complete
WndProc
function.
Build the code
As promised, here's the complete code for the working application.
To build this example
Delete any code you've entered in HelloWindowsDesktop.cpp in the editor. Copy this example code and then paste it into HelloWindowsDesktop.cpp:
On the Build menu, choose Build Solution. The results of the compilation should appear in the Output window in Visual Studio.
To run the application, press F5. A window that contains the text 'Hello, Windows desktop!' should appear in the upper-left corner of the display.
Congratulations! You've completed this walkthrough and built a traditional Windows desktop application.
See also
-->Xamarin.Mac allows for the development of fully native Mac apps in C# and .NET using the same macOS APIs that are used when developing in Objective-C or Swift. Because Xamarin.Mac integrates directly with Xcode, the developer can use Xcode's Interface Builder to create an app's user interfaces (or optionally create them directly in C# code).
Additionally, since Xamarin.Mac applications are written in C# and .NET, code can be shared with Xamarin.iOS and Xamarin.Android mobile apps; all while delivering a native experience on each platform.
This article will introduce the key concepts needed to create a Mac app using Xamarin.Mac, Visual Studio for Mac and Xcode's Interface Builder by walking through the process of building a simple Hello, Mac app that counts the number of times a button has been clicked:
The following concepts will be covered:
- Visual Studio for Mac – Introduction to the Visual Studio for Mac and how to create Xamarin.Mac applications with it.
- Anatomy of a Xamarin.Mac Application – What a Xamarin.Mac application consists of.
- Xcode’s Interface Builder – How to use Xcode’s Interface Builder to define an app’s user interface.
- Outlets and Actions – How to use Outlets and Actions to wire up controls in the user interface.
- Deployment/Testing – How to run and test a Xamarin.Mac app.
Requirements
Xamarin.Mac application development requires:
- A Mac computer running macOS High Sierra (10.13) or higher.
- Xcode 10 or higher.
- The latest version of Xamarin.Mac and Visual Studio for Mac.
To run an application built with Xamarin.Mac, you will need:
- A Mac computer running macOS 10.7 or greater.
Warning
The upcoming Xamarin.Mac 4.8 release will only support macOS 10.9 or higher.Previous versions of Xamarin.Mac supported macOS 10.7 or higher, butthese older macOS versions lack sufficient TLS infrastructure to supportTLS 1.2. To target macOS 10.7 or macOS 10.8, use Xamarin.Mac 4.6 orearlier.
Starting a new Xamarin.Mac App in Visual Studio for Mac
As stated above, this guide will walk through the steps to create a Mac app called Hello_Mac
that adds a single button and label to the main window. When the button is clicked, the label will display the number of times it has been clicked.
To get started, do the following steps:
Start Visual Studio for Mac:
Click on the New Project.. button to open the New Project dialog box, then select Mac > App > Cocoa App and click the Next button:
Enter
Hello_Mac
for the App Name, and keep everything else as default. Click Next:Confirm the location of the new project on your computer:
Click the Create button.
Visual Studio for Mac will create the new Xamarin.Mac app and display the default files that get added to the app's solution:
Visual Studio for Mac uses the same Solution and Project structure as Visual Studio 2019. A solution is a container that can hold one or more projects; projects can include applications, supporting libraries, test applications, etc. The File > New Project template creates a solution and an application project automatically.
Anatomy of a Xamarin.Mac Application
Xamarin.Mac application programming is very similar to working with Xamarin.iOS. iOS uses the CocoaTouch framework, which is a slimmed-down version of Cocoa, used by Mac.
Take a look at the files in the project:
- Main.cs contains the main entry point of the app. When the app is launched, the
Main
class contains the very first method that is run. - AppDelegate.cs contains the
AppDelegate
class that is responsible for listening to events from the operating system. - Info.plist contains app properties such as the application name, icons, etc.
- Entitlements.plist contains the entitlements for the app and allows access to things such as Sandboxing and iCloud support.
- Main.storyboard defines the user interface (Windows and Menus) for an app and lays out the interconnections between Windows via Segues. Storyboards are XML files that contain the definition of views (user interface elements). This file can be created and maintained by Interface Builder inside of Xcode.
- ViewController.cs is the controller for the main window. Controllers will be covered in detail in another article, but for now, a controller can be thought of the main engine of any particular view.
- ViewController.designer.cs contains plumbing code that helps integrate with the main screen’s user interface.
The following sections, will take a quick look through some of these files. Later, they will be explored in more detail, but it’s a good idea to understand their basics now.
Main.cs
The Main.cs file is very simple. It contains a static Main
method which creates a new Xamarin.Mac app instance and passes the name of the class that will handle OS events, which in this case is the AppDelegate
class:
AppDelegate.cs
The AppDelegate.cs
file contains an AppDelegate
class, which is responsible for creating windows and listening to OS events:
This code is probably unfamiliar unless the developer has built an iOS app before, but it’s fairly simple.
The DidFinishLaunching
method runs after the app has been instantiated, and it’s responsible for actually creating the app's window and beginning the process of displaying the view in it.
The WillTerminate
method will be called when the user or the system has instantiated a shutdown of the app. The developer should use this method to finalize the app before it quits (such as saving user preferences or window size and location).
ViewController.cs
Cocoa (and by derivation, CocoaTouch) uses what’s known as the Model View Controller (MVC) pattern. The ViewController
declaration represents the object that controls the actual app window. Generally, for every window created (and for many other things within windows), there is a controller, which is responsible for the window’s lifecycle, such as showing it, adding new views (controls) to it, etc.
The ViewController
class is the main window’s controller. The controller is responsible for the life cycle of the main window. This will be examined in detail later, for now take a quick look at it:
ViewController.Designer.cs
The designer file for the Main Window class is initially empty, but it will be automatically populated by Visual Studio for Mac as the user interface is created with Xcode Interface Builder:
Designer files should not be edited directly, as they’re automatically managed by Visual Studio for Mac to provide the plumbing code that allows access to controls that have been added to any window or view in the app.
With the Xamarin.Mac app project created and a basic understanding of its components, switch to Xcode to create the user interface using Interface Builder.
Info.plist
The Info.plist
file contains information about the Xamarin.Mac app such as its Name and Bundle Identifier:
It also defines the Storyboard that will be used to display the user interface for the Xamarin.Mac app under the Main Interface dropdown. In example above, Main
in the dropdown relates to the Main.storyboard
in the project's source tree in the Solution Explorer. It also defines the app's icons by specifying the Asset Catalog that contains them (AppIcon in this case).
Entitlements.plist
The app's Entitlements.plist
file controls entitlements that the Xamarin.Mac app has such as Sandboxing and iCloud:
For the Hello World example, no entitlements will be required. The next section shows how to use Xcode's Interface Builder to edit the Main.storyboard file and define the Xamarin.Mac app's UI.
Introduction to Xcode and Interface Builder
As part of Xcode, Apple has created a tool called Interface Builder, which allows a developer to create a user interface visually in a designer. Xamarin.Mac integrates fluently with Interface Builder, allowing UI to be created with the same tools as Objective-C users.
To get started, double-click the Main.storyboard
file in the Solution Explorer to open it for editing in Xcode and Interface Builder:
This should launch Xcode and look like this screenshot:
Before starting to design the interface, take a quick overview of Xcode to orient with the main features that will be used.
Note
The developer doesn't have to use Xcode and Interface Builder to create the user interface for a Xamarin.Mac app, the UI can be created directly from C# code but that is beyond the scope of this article. For the sake of simplicity, it will be using Interface Builder to create the user interface throughout the rest of this tutorial.
Components of Xcode
When opening a .storyboard file in Xcode from Visual Studio for Mac, it opens with a Project Navigator on the left, the Interface Hierarchy and Interface Editor in the middle, and a Properties & Utilities section on the right:
The following sections take a look at what each of these Xcode features do and how to use them to create the interface for a Xamarin.Mac app.
Project Navigation
When opening a .storyboard file for editing in Xcode, Visual Studio for Mac creates a Xcode Project File in the background to communicate changes between itself and Xcode. Later, when the developer switches back to Visual Studio for Mac from Xcode, any changes made to this project are synchronized with the Xamarin.Mac project by Visual Studio for Mac.
The Project Navigation section allows the developer to navigate between all of the files that make up this shim Xcode project. Typically, they will only be interested in the .storyboard
files in this list such as Main.storyboard
.
Interface Hierarchy
The Interface Hierarchy section allows the developer to easily access several key properties of the user interface such as its Placeholders and main Window. This section can be used to access the individual elements (views) that make up the user interface and to adjust the way they are nested by dragging them around within the hierarchy.
Interface Editor
The Interface Editor section provides the surface on which the user interface is graphically laid out. Drag elements from the Library section of the Properties & Utilities section to create the design. As user interface elements (views) are added to the design surface, they will be added to the Interface Hierarchy section in the order that they appear in the Interface Editor.
Properties & Utilities
The Properties & Utilities section is divided into two main sections, Properties (also called Inspectors) and the Library:
Initially this section is almost empty, however if the developer selects an element in the Interface Editor or Interface Hierarchy, the Properties section will be populated with information about the given element and properties that they can adjust.
Within the Properties section, there are eight different Inspector Tabs, as shown in the following illustration:
Properties & Utility Types
From left-to-right, these tabs are:
- File Inspector – The File Inspector shows file information, such as the file name and location of the Xib file that is being edited.
- Quick Help – The Quick Help tab provides contextual help based on what is selected in Xcode.
- Identity Inspector – The Identity Inspector provides information about the selected control/view.
- Attributes Inspector – The Attributes Inspector allows the developer to customize various attributes of the selected control/view.
- Size Inspector – The Size Inspector allows the developer to control the size and resizing behavior of the selected control/view.
- Connections Inspector – The Connections Inspector shows the Outlet and Action connections of the selected controls. Outlets and Actions will be discussed in detail below.
- Bindings Inspector – The Bindings Inspector allows the developer to configure controls so that their values are automatically bound to data models.
- View Effects Inspector – The View Effects Inspector allows the developer to specify effects on the controls, such as animations.
Use the Library section to find controls and objects to place into the designer to graphically build the user interface:
Creating the Interface
With the basics of the Xcode IDE and Interface Builder covered, the developer can create the user interface for the main view.
Follow these steps to use Interface Builder:
In Xcode, drag a Push Button from the Library Section:
Download the Shadow app for Windows, macOS, Android and Linux. Join now and access your Shadow gaming PC everywhere. Turn any screen into a high-end PC! Shadow is a gaming PC you stream through a simple app! Subscribe and get your remote high-end computer to play on any Windows laptop, Mac, Android tablet or phone. May 29, 2019 Popular Alternatives to Parsec for Windows, Android, Android Tablet, iPhone, Mac and more. Explore 12 games like Parsec, all suggested and ranked by the AlternativeTo user community. Thanks to the Shadow apps, any under-powered PC, old Mac or smartphone becomes a high-end Windows 10 machine. Start a game in front of the television and finish it on the go. Work with 3D rendering software on a tablet. Give the best you have to give. Software like shadowtech for mac os.
Drop the button onto the View (under the Window Controller) in the Interface Editor:
Click on the Title property in the Attribute Inspector and change the button's title to Click Me:
Drag a Label from the Library Section:
Drop the label onto the Window beside the button in the Interface Editor:
Grab the right handle on the label and drag it until it is near the edge of the window:
Select the Button just added in the Interface Editor, and click the Constraints Editor icon at the bottom of the window:
At the top of the editor, click the Red I-Beams at the top and left. As the window is resized, this will keep the button in the same location at the top left corner of the screen.
Next, check the Height and Width boxes and use the default sizes. This keeps the button at the same size when the window resizes.
Click the Add 4 Constraints button to add the constraints and close the editor.
Select the label and click the Constraints Editor icon again:
By clicking Red I-Beams at the top, right and left of the Constraints Editor, tells the label to be stuck to its given X and Y locations and to grow and shrink as the window is resized in the running application.
Again, check the Height box and use the default size, then click the Add 4 Constraints button to add the constraints and close the editor.
Save the changes to the user interface.
While resizing and moving controls around, notice that Interface Builder gives helpful snap hints that are based on macOS Human Interface Guidelines. These guidelines will help the developer to create high quality apps that will have a familiar look and feel for Mac users.
Look in the Interface Hierarchy section to see how the layout and hierarchy of the elements that make up the user interface are shown:
From here the developer can select items to edit or drag to reorder UI elements if needed. For example, if a UI element was being covered by another element, they could drag it to the bottom of the list to make it the top-most item on the window.
With the user interface created, the developer will need to expose the UI items so that Xamarin.Mac can access and interact with them in C# code. The next section, Outlets and Actions, shows how to do this.
Outlets and Actions
So what are Outlets and Actions? In traditional .NET user interface programming, a control in the user interface is automatically exposed as a property when it’s added. Things work differently in Mac, simply adding a control to a view doesn’t make it accessible to code. The developer must explicitly expose the UI element to code. In order do this, Apple provides two options:
- Outlets – Outlets are analogous to properties. If the developer wires up a control to an Outlet, it’s exposed to the code via a property, so they can do things like attach event handlers, call methods on it, etc.
- Actions – Actions are analogous to the command pattern in WPF. For example, when an Action is performed on a control, say a button click, the control will automatically call a method in the code. Actions are powerful and convenient because the developer can wire up many controls to the same Action.
In Xcode, Outlets and Actions are added directly in code via Control-dragging. More specifically, this means that to create an Outlet or Action, the developer will choose a control element to add an Outlet or Action to, hold down the Control key on the keyboard, and drag that control directly into the code.
For Xamarin.Mac developers, this means that the developer will drag into the Objective-C stub files that correspond to the C# file where they want to create the Outlet or Action. Visual Studio for Mac created a file called ViewController.h
as part of the shim Xcode Project it generated to use Interface Builder:
This stub .h
file mirrors the ViewController.designer.cs
that is automatically added to a Xamarin.Mac project when a new NSWindow
is created. This file will be used to synchronize the changes made by Interface Builder and is where the Outlets and Actions are created so that UI elements are exposed to C# code.
Adding an Outlet
With a basic understanding of what Outlets and Actions are, create an Outlet to expose the Label created to our C# code.
Do the following:
In Xcode at the far right top-hand corner of the screen, click the Double Circle button to open the Assistant Editor:
The Xcode will switch to a split-view mode with the Interface Editor on one side and a Code Editor on the other.
Notice that Xcode has automatically picked the ViewController.m file in the Code Editor, which is incorrect. From the discussion on what Outlets and Actions are above, the developer will need to have the ViewController.h selected.
At the top of the Code Editor click on the Automatic Link and select the
ViewController.h
file:Xcode should now have the correct file selected:
The last step was very important!: if you didn't have the correct file selected, you won't be able to create Outlets and Actions, or they will be exposed to the wrong class in C#!
In the Interface Editor, hold down the Control key on the keyboard and click-drag the label created above onto the code editor just below the
@interface ViewController : NSViewController {}
code:A dialog box will be displayed. Leave the Connection set to Outlet and enter
ClickedLabel
for the Name:Click the Connect button to create the Outlet:
Save the changes to the file.
Adding an Action
Next, expose the button to C# code. Just like the Label above, the developer could wire the button up to an Outlet. Since we only want to respond to the button being clicked, use an Action instead.
Do the following:
Ensure that Xcode is still in the Assistant Editor and the ViewController.h file is visible in the Code Editor.
In the Interface Editor, hold down the Control key on the keyboard and click-drag the button created above onto the code editor just below the
@property (assign) IBOutlet NSTextField *ClickedLabel;
code:Change the Connection type to Action:
Enter
ClickedButton
as the Name:Click the Connect button to create Action:
Save the changes to the file.
With the user interface wired-up and exposed to C# code, switch back to Visual Studio for Mac and let it synchronize the changes made in Xcode and Interface Builder.
Note
It probably took a long time to create the user interface and Outlets and Actions for this first app, and it may seem like a lot of work, but a lot of new concepts were introduced and a lot of time was spent covering new ground. After practicing for a while and working with Interface Builder, this interface and all its Outlets and Actions can be created in just a minute or two.
Synchronizing Changes with Xcode
When the developer switches back to Visual Studio for Mac from Xcode, any changes that they have made in Xcode will automatically be synchronized with the Xamarin.Mac project.
Select the ViewController.designer.cs in the Solution Explorer to see how the Outlet and Action have been wired up in the C# code:
Notice how the two definitions in the ViewController.designer.cs file:
Line up with the definitions in the ViewController.h
file in Xcode:
Visual Studio for Mac listens for changes to the .h file, and then automatically synchronizes those changes in the respective .designer.cs file to expose them to the app. Notice that ViewController.designer.cs is a partial class, so that Visual Studio for Mac doesn't have to modify ViewController.cs which would overwrite any changes that the developer has made to the class.
Normally, the developer will never need to open the ViewController.designer.cs, it was presented here for educational purposes only.
Remote Desktop Mac App Store
Note
In most situations, Visual Studio for Mac will automatically see any changes made in Xcode and sync them to the Xamarin.Mac project. In the off occurrence that synchronization doesn't automatically happen, switch back to Xcode and then back to Visual Studio for Mac again. This will normally kick off a synchronization cycle.
Writing the Code
With the user interface created and its UI elements exposed to code via Outlets and Actions, we are finally ready to write the code to bring the program to life.
For this sample app, every time the first button is clicked, the label will be updated to show how many times the button has been clicked. To accomplish this, open the ViewController.cs
file for editing by double-clicking it in the Solution Explorer:
First, create a class-level variable in the ViewController
class to track the number of clicks that have happened. Edit the class definition and make it look like the following:
Next, in the same class (ViewController
), override the ViewDidLoad
method and add some code to set the initial message for the label:
Use ViewDidLoad
, instead of another method such as Initialize
, because ViewDidLoad
is called after the OShas loaded and instantiated the user interface from the .storyboard file. If the developer tried to access the label control before the .storyboard file has been fully loaded and instantiated, they would get a NullReferenceException
error because the label control would not exist yet.
Next, add the code to respond to the user clicking the button. Add the following partial method to the ViewController
class:
This code attaches to the Action created in Xcode and Interface Builder and will be called any time the user clicks the button.
Testing the Application
It’s time to build and run the app to make sure it runs as expected. The developer can build and run all in one step, or they can build it without running it.
Whenever an app is built, the developer can choose what kind of build they want:
- Debug – A debug build is compiled into an .app (application) file with a bunch of extra metadata that allows the developer to debug what’s happening while the app is running.
- Release – A release build also creates an .app file, but it doesn’t include debug information, so it’s smaller and executes faster.
Hulu Desktop App Mac
The developer can select the type of build from the Configuration Selector at the upper left-hand corner of the Visual Studio for Mac screen:
Building the Application
In the case of this example, we just want a debug build, so ensure that Debug is selected. Build the app first by either pressing ⌘B, or from the Build menu, choose Build All.
If there weren't any errors, a Build Succeeded message will be displayed in Visual Studio for Mac's status bar. If there were errors, review the project and make sure that the steps above have been followed correctly. Start by confirming that the code (both in Xcode and in Visual Studio for Mac) matches the code in the tutorial.
Running the Application
There are three ways to run the app:
- Press ⌘+Enter.
- From the Run menu, choose Debug.
- Click the Play button in the Visual Studio for Mac toolbar (just above the Solution Explorer).
The app will build (if it hasn’t been built already), start in debug mode and display its main interface window:
If the button is clicked a few times, the label should be updated with the count:
Where to Next
With the basics of working with a Xamarin.Mac application down, take a look at the following documents to get a deeper understanding:
- Introduction to Storyboards - This article provides an introduction to working with Storyboards in a Xamarin.Mac app. It covers creating and maintaining the app's UI using storyboards and Xcode's Interface Builder.
- Windows - This article covers working with Windows and Panels in a Xamarin.Mac application. It covers creating and maintaining Windows and Panels in Xcode and Interface builder, loading Windows and Panels from .xib files, using Windows and responding to Windows in C# code.
- Dialogs - This article covers working with Dialogs and Modal Windows in a Xamarin.Mac application. It covers creating and maintaining Modal Windows in Xcode and Interface builder, working with standard dialogs, displaying and responding to Windows in C# code.
- Alerts - This article covers working with Alerts in a Xamarin.Mac application. It covers creating and displaying Alerts from C# code and responding to Alerts.
- Menus - Menus are used in various parts of a Mac application's user interface; from the application's main menu at the top of the screen to pop up and contextual menus that can appear anywhere in a window. Menus are an integral part of a Mac application's user experience. This article covers working with Cocoa Menus in a Xamarin.Mac application.
- Toolbars - This article covers working with Toolbars in a Xamarin.Mac application. It covers creating and maintaining. Toolbars in Xcode and Interface builder, how to expose the Toolbar Items to code using Outlets and Actions, enabling and disabling Toolbar Items and finally responding to Toolbar Items in C# code.
- Table Views - This article covers working with Table Views in a Xamarin.Mac application. It covers creating and maintaining Table Views in Xcode and Interface builder, how to expose the Table View Items to code using Outlets and Actions, populating Table Items and finally responding to Table View Items in C# code.
- Outline Views - This article covers working with Outline Views in a Xamarin.Mac application. It covers creating and maintaining Outline Views in Xcode and Interface builder, how to expose the Outline View Items to code using Outlets and Actions, populating Outline Items and finally responding to Outline View Items in C# code.
- Source Lists - This article covers working with Source Lists in a Xamarin.Mac application. It covers creating and maintaining Source Lists in Xcode and Interface builder, how to expose the Source Lists Items to code using Outlets and Actions, populating Source List Items and finally responding to Source List Items in C# code.
- Collection Views - This article covers working with Collection Views in a Xamarin.Mac application. It covers creating and maintaining Collection Views in Xcode and Interface builder, how to expose the Collection View elements to code using Outlets and Actions, populating Collection Views and finally responding to Collection Views in C# code.
- Working with Images - This article covers working with Images and Icons in a Xamarin.Mac application. It covers creating and maintaining the images needed to create an app's Icon and using Images in both C# code and Xcode's Interface Builder.
The Mac Samples Gallery contains ready-to-use code examples to help learn Xamarin.Mac.
One complete Xamarin.Mac app that includes many of the features a user would expect to find in a typical Mac application is the SourceWriter Sample App. SourceWriter is a simple source code editor that provides support for code completion and simple syntax highlighting.
The SourceWriter code has been fully commented and, where available, links have been provided from key technologies or methods to relevant information in the Xamarin.Mac documentation.
Creating A Mac Desktop Apps
Summary
This article covered the basics of a standard Xamarin.Mac app. It covered creating a new app in Visual Studio for Mac, designing the user interface in Xcode and Interface Builder, exposing UI elements to C# code using Outlets and Actions, adding code to work with the UI elements and finally, building and testing a Xamarin.Mac app.