Dev C++ Hello World Example
C/C++ support for Visual Studio Code is provided by a Microsoft C/C++ extension to enable cross-platform C and C++ development on Windows, Linux, and macOS.
Dec 01, 2018 How to build OpenCV C and run hello world example 2018 in windows. Romualdo Villalobos. Now that we have compiled all the needed OpenCV modules for run our hello world. Mar 18, 2020 Now, Dev C is installed successfully on your Windows. Select ' Run Dev C' to run it and click on ' Finish' button. Now you are ready to compile your C or C programs with Dev C compiler. C Hello World Program. If this is your first time running C, you will see the following screen. Step 1) Select create the cache now option.
Getting started
Dev C++ Hello World Example Pdf
- May 29, 2011 i was trying to do a simple Hello world in C in Dev-C but it keeps on get a error. Here's is the code i used Code: #include int main.
- Dev-C Dev-C is a free IDE for Windows that uses either MinGW or TDM-GCC as underlying compiler. Originally released by Bloodshed Software, but abandoned in 2006, it has recently been forked by Orwell, including a choice of more recent compilers.
- How 'Hello, World!' Program works? The #include is a preprocessor command that tells the compiler to include the contents of stdio.h (standard input and output) file in the program. The stdio.h file contains functions such as scanf and printf to take input and display output respectively.
C/C++ compiler and debugger
The C/C++ extension does not include a C++ compiler or debugger. You will need to install these tools or use those already installed on your computer.
Popular C++ compilers are:
- GCC on Linux
- GCC via Mingw-w64 on Windows
- Microsoft C++ compiler on Windows
- Clang for XCode on macOS
Make sure your compiler executable is in your platform path so the extension can find it. You can check availability of your C++ tools by opening the Integrated Terminal (⌃` (Windows, Linux Ctrl+`)) in VS Code and try running the executable (for example g++ --help
).
Install the Microsoft C/C++ extension
- Open VS Code.
- Click the Extensions view icon on the Sidebar (⇧⌘X (Windows, Linux Ctrl+Shift+X)).
- Search for
c++
. - Click Install.
Hello World tutorials
Get started with C++ and VS Code with Hello World tutorials for your environment:
Documentation
You can find more documentation on using the Microsoft C/C++ extension under the C++ section, where you'll find topics on:
Remote Development
VS Code and the C++ extension support Remote Development allowing you to work over SSH on a remote machine or VM, inside a Docker container, or in the Windows Subsystem for Linux (WSL).
To install support for Remote Development:
- Install the VS Code Remote Development Extension Pack.
- If the remote source files are hosted in WSL, use the Remote - WSL extension.
- If you are connecting to a remote machine with SSH, use the Remote - SSH extension.
- If the remote source files are hosted in a container (for example, Docker), use the Remote - Containers extension.
Feedback
If you run into any issues or have suggestions for the Microsoft C/C++ extension, please file issues and suggestions on GitHub. If you haven't already provided feedback, please take this quick survey to help shape this extension for your needs.
-->Important
This tutorial uses C++/CX. Microsoft has released C++/WinRT: an entirely standard modern C++17 language projection for Windows Runtime (WinRT) APIs. For more information on this language, please see C++/WinRT.
With Microsoft Visual Studio, you can use C++/CX to develop an app that runs on Windows 10 with a UI that's defined in Extensible Application Markup Language (XAML).
Note
This tutorial uses Visual Studio Community 2019. If you are using a different version of Visual Studio, it may look a little different for you.
Before you start
- To complete this tutorial, you must use Visual Studio Community, or one of the non-Community versions of Visual Studio, on a computer that's running Windows 10. To download, see Get the tools.
- We assume you have a basic understanding of C++/CX, XAML, and the concepts in the XAML overview.
- We assume you're using the default window layout in Visual Studio. To reset to the default layout, on the menu bar, choose Window > Reset Window Layout.
Comparing C++ desktop apps to Windows apps
If you're coming from a background in Windows desktop programming in C++, you'll probably find that some aspects of writing apps for the UWP are familiar, but other aspects require some learning.
What's the same?
You can use the STL, the CRT (with some exceptions), and any other C++ library as long as the code only calls Windows functions that are accessible from the Windows Runtime environment.
If you're accustomed to visual designers, you can still use the designer built into Microsoft Visual Studio, or you can use the more full-featured Blend for Visual Studio. If you're accustomed to coding UI by hand, you can hand-code your XAML.
You're still creating apps that use Windows operating system types and your own custom types.
You're still using the Visual Studio debugger, profiler, and other development tools.
You're still creating apps that are compiled to native machine code by the Visual C++ compiler. UWP apps in C++/CX don't execute in a managed runtime environment.
What's new?
The design principles for UWP apps and Universal Windows apps are very different from those for desktop apps. Window borders, labels, dialog boxes, and so on, are de-emphasized. Content is foremost. Great Universal Windows apps incorporate these principles from the very beginning of the planning stage.
You're using XAML to define the entire UI. The separation between UI and core program logic is much clearer in a Windows Universal app than in an MFC or Win32 app. Other people can work on the appearance of the UI in the XAML file while you're working on the behavior in the code file.
You're primarily programming against a new, easy-to-navigate, object-oriented API, the Windows Runtime, although on Windows devices Win32 is still available for some functionality.
You use C++/CX to consume and create Windows Runtime objects. C++/CX enables C++ exception handling, delegates, events, and automatic reference counting of dynamically created objects. When you use C++/CX, the details of the underlying COM and Windows architecture are hidden from your app code. For more information, see C++/CX Language Reference.
Your app is compiled into a package that also contains metadata about the types that your app contains, the resources that it uses, and the capabilities that it requires (file access, internet access, camera access, and so forth).
In the Microsoft Store and Windows Phone Store your app is verified as safe by a certification process and made discoverable to millions of potential customers.
Hello World Store app in C++/CX
Our first app is a 'Hello World' that demonstrates some basic features of interactivity, layout, and styles. We'll create an app from the Windows Universal app project template. If you've developed apps for Windows 8.1 and Windows Phone 8.1 before, you might remember that you had to have three projects in Visual Studio, one for the Windows app, one for the phone app, and another with shared code. The Windows 10 Universal Windows Platform (UWP) makes it possible to have just one project, which runs on all devices, including desktop and laptop computers running Windows 10, devices such as tablets, mobile phones, VR devices and so on.
We'll start with the basics:
How to create a Universal Windows project in Visual Studio.
How to understand the projects and files that are created.
How to understand the extensions in Visual C++ component extensions (C++/CX), and when to use them.
First, create a solution in Visual Studio
In Visual Studio, on the menu bar, choose File > New > Project...
In the Create a new project dialog box, select Blank App (Universal Windows - C++/CX). If you don't see this option, make sure you have the Universal Windows App Development Tools installed. See Get set up for more information.
Choose Next, and then enter a name for the project. We'll name it HelloWorld.
Choose the Create button.
Note
If this is the first time you have used Visual Studio, you might see a Settings dialog asking you to enable Developer mode. Developer mode is a special setting that enables certain features, such as permission to run apps directly, rather than only from the Store. For more information, please read Enable your device for development. To continue with this guide, select Developer mode, click Yes, and close the dialog.
Your project files are created.
Before we go on, let's look at what's in the solution.
About the project files
Every .xaml file in a project folder has a corresponding .xaml.h file and .xaml.cpp file in the same folder and a .g file and a .g.hpp file in the Generated Files folder, which is on disk but not part of the project. You modify the XAML files to create UI elements and connect them to data sources (DataBinding). You modify the .h and .cpp files to add custom logic for event handlers. The auto-generated files represent the transformation of the XAML markup into C++/CX. Don't modify these files, but you can study them to better understand how the code-behind works. Basically, the generated file contains a partial class definition for a XAML root element; this class is the same class that you modify in the *.xaml.h and .cpp files. The generated files declare the XAML UI child elements as class members so that you can reference them in the code you write. At build time, the generated code and your code are merged into a complete class definition and then compiled.
Let's look first at the project files.
- App.xaml, App.xaml.h, App.xaml.cpp: Represent the Application object, which is an app's entry point. App.xaml contains no page-specific UI markup, but you can add UI styles and other elements that you want to be accessible from any page. The code-behind files contain handlers for the OnLaunched and OnSuspending events. Typically, you add custom code here to initialize your app when it starts and perform cleanup when it's suspended or terminated.
- **MainPage.xaml, MainPage.xaml.h, MainPage.xaml.cpp:**Contain the XAML markup and code-behind for the default 'start' page in an app. It has no navigation support or built-in controls.
- pch.h, pch.cpp: A precompiled header file and the file that includes it in your project. In pch.h, you can include any headers that do not change often and are included in other files in the solution.
- Package.appxmanifest: An XML file that describes the device capabilities that your app requires, and the app version info and other metadata. To open this file in the Manifest Designer, just double-click it.
- **HelloWorld_TemporaryKey.pfx:**A key that enables deployment of the app on this machine, from Visual Studio.
A first look at the code
If you examine the code in App.xaml.h, App.xaml.cpp in the shared project, you'll notice that it's mostly C++ code that looks familiar. However, some syntax elements might not be as familiar if you are new to Windows Runtime apps, or you've worked with C++/CLI. Here are the most common non-standard syntax elements you'll see in C++/CX:
Ref classes
Almost all Windows Runtime classes, which includes all the types in the Windows API--XAML controls, the pages in your app, the App class itself, all device and network objects, all container types--are declared as a ref class. (A few Windows types are value class or value struct). A ref class is consumable from any language. In C++/CX, the lifetime of these types is governed by automatic reference counting (not garbage collection) so that you never explicitly delete these objects. You can create your own ref classes as well.
All Windows Runtime types must be declared within a namespace and unlike in ISO C++ the types themselves have an accessibility modifier. The public modifier makes the class visible to Windows Runtime components outside the namespace. The sealed keyword means the class cannot serve as a base class. Almost all ref classes are sealed; class inheritance is not broadly used because Javascript does not understand it.
ref new and ^ (hats)
You declare a variable of a ref class by using the ^ (hat) operator, and you instantiate the object with the ref new keyword. Thereafter you access the object's instance methods with the -> operator just like a C++ pointer. Static methods are accessed with the :: operator just as in ISO C++.
In the following code, we use the fully qualified name to instantiate an object, and use the -> operator to call an instance method.
Typically, in a .cpp file we would add a using namespace Windows::UI::Xaml::Media::Imaging
directive and the auto keyword, so that the same code would look like this:
Properties
A ref class can have properties, which, just as in managed languages, are special member functions that appear as fields to consuming code.
Delegates
Just as in managed languages, a delegate is a reference type that encapsulates a function with a specific signature. They are most often used with events and event handlers
Adding content to the app
Let's add some content to the app.
Step 1: Modify your start page
In Solution Explorer, open MainPage.xaml.
Create controls for the UI by adding the following XAML to the root Grid, immediately before its closing tag. It contains a StackPanel that has a TextBlock that asks the user's name, a TextBox element that accepts the user's name, a Button, and another TextBlock element.
At this point, you have created a very basic Universal Windows app. To see what the UWP app looks like, press F5 to build, deploy, and run the app in debugging mode.
The default splash screen appears first. It has an image—AssetsSplashScreen.scale-100.png—and a background color that are specified in the app's manifest file. To learn how to customize the splash screen, see Adding a splash screen.
When the splash screen disappears, your app appears. It displays the main page of the App.
It doesn't do much—yet—but congratulations, you've built your first Universal Windows Platform app!
To stop debugging and close the app, return to Visual Studio and press Shift+F5. Little snitch downloa.
For more information, see Run a Store app from Visual Studio.
In the app, you can type in the TextBox, but clicking the Button doesn't do anything. In later steps, you create an event handler for the button's Click event, which displays a personalized greeting.
Step 2: Create an event handler
In MainPage.xaml, in either XAML or design view, select the 'Say Hello' Button in the StackPanel you added earlier.
Open the Properties Window by pressing F4, and then choose the Events button ().
Find the Click event. In its text box, type the name of the function that handles the Click event. For this example, type 'Button_Click'.
Press Enter. The event handler method is created in MainPage.xaml.cpp and opened so that you can add the code that's executed when the event occurs.
At the same time, in MainPage.xaml, the XAML for the Button is updated to declare the Click event handler, like this:
You could also have simply added this to the xaml code manually, which can be helpful if the designer doesn't load. If you enter this manually, type 'Click' and then let IntelliSense pop up the option to add a new event handler. That way, Visual Studio creates the necessary method declaration and stub.
The designer fails to load if an unhandled exception occurs during rendering. Rendering in the designer involves running a design-time version of the page. It can be helpful to disable running user code. You can do this by changing the setting in the Tools, Options dialog box. Under XAML Designer, uncheck Run project code in XAML designer (if supported).
In MainPage.xaml.cpp, add the following code to the Button_Click event handler that you just created. This code retrieves the user's name from the
nameInput
TextBox control and uses it to create a greeting. ThegreetingOutput
TextBlock displays the result.Set the project as the startup, and then press F5 to build and run the app. When you type a name in the text box and click the button, the app displays a personalized greeting.
Step 3: Style the start page
Choosing a theme
It's easy to customize the look and feel of your app. By default, your app uses resources that have a light style. The system resources also include a light theme. Let's try it out and see what it looks like.
To switch to the dark theme
Open App.xaml.
In the opening Application tag, edit the RequestedTheme property and set its value to Dark:
Here's the full Application tag with the dark theme :
Press F5 to build and run it. Notice that it uses the dark theme.
Which theme should you use? Whichever one you want. Here's our take: for apps that mostly display images or video, we recommend the dark theme; for apps that contain a lot of text, we recommend the light theme. If you're using a custom color scheme, use the theme that goes best with your app's look and feel. In the rest of this tutorial, we use the Light theme in screenshots.
Note The theme is applied when the app is started and can't be changed while the app is running.
Using system styles
Right now, in the Windows app the text is very small and difficult to read. Let's fix that by applying a system style.
To change the style of an element
In the Windows project, open MainPage.xaml.
In either XAML or design view, select the 'What's your name?'TextBlock that you added earlier.
In the Properties window (F4), choose the Properties button () in the upper right.
Expand the Text group and set the font size to 18 px.
Expand the Miscellaneous group and find the Style property.
Click the property marker (the green box to the right of the Style property), and then, on the menu, choose System Resource > BaseTextBlockStyle.
BaseTextBlockStyle is a resource that's defined in the ResourceDictionary in
Program FilesWindows Kits10Includewinrtxamldesigngeneric.xaml. On the XAML design surface, the appearance of the text changes. In the XAML editor, the XAML for the TextBlock is updated:
Repeat the process to set the font size and assign the BaseTextBlockStyle to the
greetingOutput
TextBlock element.Tip Although there's no text in this TextBlock, when you move the pointer over the XAML design surface, a blue outline shows where it is so that you can select it.
Your XAML now looks like this:
Press F5 to build and run the app. It now looks like this:
Step 4: Adapt the UI to different window sizes
Now we'll make the UI adapt to different screen sizes so it looks good on mobile devices. To do this, you add a VisualStateManager and set properties that are applied for different visual states.
To adjust the UI layout
In the XAML editor, add this block of XAML after the opening tag of the root Grid element.
Debug the app on the local machine. Notice that the UI looks the same as before unless the window gets narrower than 641 device-independent pixels (DIPs).
Debug the app on the mobile device emulator. Notice that the UI uses the properties you defined in the
narrowState
and appears correctly on the small screen.
If you've used a VisualStateManager in previous versions of XAML, you might notice that the XAML here uses a simplified syntax.
The VisualState named wideState
has an AdaptiveTrigger with its MinWindowWidth property set to 641. This means that the state is to be applied only when the window width is not less than the minimum of 641 DIPs. You don't define any Setter objects for this state, so it uses the layout properties you defined in the XAML for the page content.
C++ Hello World Tutorial
The second VisualState, narrowState
, has an AdaptiveTrigger with its MinWindowWidth property set to 0. This state is applied when the window width is greater than 0, but less than 641 DIPs. (At 641 DIPs, the wideState
is applied.) In this state, you do define some Setter objects to change the layout properties of controls in the UI:
- You reduce the left margin of the
contentPanel
element from 120 to 20. - You change the Orientation of the
inputPanel
element from Horizontal to Vertical. - You add a top margin of 4 DIPs to the
inputButton
element.
Summary
Congratulations, you've completed the first tutorial! It taught how to add content to Windows Universal apps, how to add interactivity to them, and how to change their appearance.
Next steps
Dev C++ Code Hello World
If you have a Windows Universal app project that targets Windows 8.1 and/or Windows Phone 8.1, you can port it to Windows 10. There is no automatic process for this, but you can do it manually. Start with a new Windows Universal project to get the latest project system structure and manifest files, copy your code files into the project's directory structure, add the items to your project, and rewrite your XAML using the VisualStateManager according to the guidance in this topic. For more information, see Porting a Windows Runtime 8 project to a Universal Windows Platform (UWP) project and Porting to the Universal Windows Platform (C++).
If you have existing C++ code that you want to integrate with a UWP app, such as to create a new UWP UI for an existing application, see How to: Use existing C++ code in a Universal Windows project.