Get started with R Tools for Visual Studio
Once you have R Tools for Visual Studio (RTVS) installed (see Installation), you can quickly get a taste of the experience that those tools provide.
Create an R project
Open Visual Studio.
Choose File > New > Project (Ctrl+Shift+N)
Select "R Project" from under Templates > R, give the project a name and location, and select OK:
Once the project is created, you see the following windows:
- On the right is Visual Studio Solution Explorer, where you see your project inside a containing solution. (Solutions can contain any number of projects of different types; see Projects for details.
- On the top left is a new R file (
script.R) where you can edit source code with all of Visual Studio's editing features.
- On the bottom left is the R Interactive window in which you can interactively develop and test code.
You can use the R Interactive window without having any projects open, and even when a different project type is loaded. Just select R Tools > Windows > R Interactive at any time.
Explore the Interactive Window and IntelliSense
Test that the interactive window is working by typing in
3 + 4and then Enter to see the result:
Enter something a little more complicated,
ds <- c(1.5, 6.7, 8.9) * 1:12, and then enter
dsto see the result:
mean(ds)but notice that as soon as you type
me, Visual Studio IntelliSense provides auto-completion options. When the completion you want is selected in the list, press Tab to insert it; you can change the selection with the arrow keys or the mouse.
mean, type the opening parenthesis
(and note how IntelliSense gives you inline help for the function:
Complete the line
mean(ds)and press Enter to see the result (
The Interactive window is integrated with help, so entering
?meandisplays help for that function in the R Help window in Visual Studio. For details, see Help in R Tools for Visual Studio.
Some commands, such as
plot(1:100), open a new window in Visual Studio when the output can't be displayed directly in the interactive window:
The interactive window also lets you review your history, load and save workspaces, attach to a debugger, and interact with source code files instead of using copy-paste. See Working with the R Interactive Window for details.
Experience code editing features
Working briefly with the interactive window demonstrates basic editing features like IntelliSense that also work in the code editor. If you enter the same code as before, you see the same auto-completion and IntelliSense prompts, but not the output.
Writing code in a .R file lets you see all your code at once, and makes it easier to make small changes and then quickly see the result by running the code in the interactive window. You can also have as many files as you want in a project. When code is in a file, you can also run it step-by-step in the debugger (discussed later in this article). These capabilities are helpful when you're developing computational algorithms and writing code to manipulate one or more datasets, especially when you want to examine all intermediate results.
As an example, the following steps create a little code to explore the Central Limit Theorem (Wikipedia). (This example is adapted from the R Cookbook by Paul Teetor.)
script.Reditor, enter the following code:
mu <- 50 stddev <- 1 N <- 10000 pop <- rnorm(N, mean = mu, sd = stddev) plot(density(pop), main = "Population Density", xlab = "X", ylab = "")
To quickly see the results, select all the code (Ctrl+A), then press Ctrl+Enter or right-click and select Execute In Interactive. All the selected code is run in the interactive window as if you typed it directly, showing the result in a plot window:
For a single line, just press Ctrl+Enter at any time to run that line in the interactive window.
Learn the pattern of making edits and pressing Ctrl+Enter (or selecting everything with Ctrl+A and then pressing Ctrl+Enter) to quickly run the code. Doing so is much more efficient than using the mouse for the same operations.
In addition, you can drag and drop the plot window out of the Visual Studio frame and place it whenever else you want on your display. You can then resize the plot window to the dimensions you want and then save it to an image or PDF file.
Add a few more lines of code to include a second plot:
n <- 30 samp.means <- rnorm(N, mean = mu, sd = stddev / sqrt(n)) lines(density(samp.means))
Press Ctrl+A and Ctrl+Enter again to run the code, producing the following result:
The problem is that the first plot determines the vertical scale, so the second plot (with
lines) doesn't fit. To correct this problem, we need to set the
ylimparameter on the
plotcall, but do so that properly we need to add code to calculate the maximum vertical value. Doing this line-by-line in the interactive window is inconvenient because we need to rearrange the code to use
plot. In a code file, though, we can easily make the appropriate edits:
mu <- 50 stddev <- 1 N <- 10000 pop <- rnorm(N, mean = mu, sd = stddev) n <- 30 samp.means <- rnorm(N, mean = mu, sd = stddev / sqrt(n)) max.samp.means <- max(density(samp.means)$y) plot(density(pop), main = "Population Density", ylim = c(0, max.samp.means), xlab = "X", ylab = "") lines(density(samp.means))
Ctrl+A and Ctrl+Enter again to see the result:
Debug your code
One of the key strengths of Visual Studio is its debugging UI. RTVS builds on top of this strong foundation and adds innovative UI such as the Variable Explorer. Here, let's just take a first look at debugging.
To begin, reset the current workspace to clear everything you've done so far by using the R Tools > Session > Reset menu command. By default, everything you do in the interactive window accrues to the current session, which is then also used by the debugger. By resetting the session, you ensure that the debugging session starts with no pre-existing data. The Reset command, however, doesn't affect your script.R source file, because that's managed and saved outside of the workspace.
With the script.R file created in the previous section, set a breakpoint on the line that begins with
pop <-by placing the caret on that line and then pressing F9, or selecting the Debug > Toggle Breakpoint menu command. Alternately, simply click in the left-hand margin (or gutter) for that line where the red breakpoint dot appears:
Launch the debugger with the code in script.R by either selecting the Source startup file button on the toolbar, selecting the Debug > Source startup file menu items, or pressing F5. Visual Studio enters its debugging mode and starts running the code. It stops, however, on the line where you set the breakpoint:
During debugging, Visual Studio provides the ability to step through your code line by line. You can also step into functions, step over them, or step out of them to the calling context. These capabilities, along with others, can be found on the Debug menu, the right-click context menu in the editor, and the Debug toolbar:
When stopped at a breakpoint, you can examine the values of variables. Locate the Autos window in Visual Studio and select the tab along the bottom named Locals. The Locals window shows local variables at the current point in the program. If you're stopped on the breakpoint set earlier, you see that the
popvariable isn't yet defined. Now use the Debug > Step Over command (F10), and you see the value for
To examine variables in different scopes, including the global scope and package scopes, use the Variable Explorer. The Variable Explorer also gives you the ability to switch to a tabular view with sortable columns and to export data to a CSV file.
You can continue stepping through the program line by line, or select Continue (F5) to run it to completion (or the next breakpoint).
In this walkthrough you've learned the basics of R projects, using the interactive window, code editing, and debugging in Visual Studio. To continue exploring more capabilities, see the following articles as well as articles shown in the table of contents:
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