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Historical Debugging

Note

This article applies to Visual Studio 2015. If you're looking for the latest Visual Studio documentation, see Visual Studio documentation. We recommend upgrading to the latest version of Visual Studio. Download it here

Historical debugging is a mode of debugging that depends on the information collected by IntelliTrace. It allows you to move backward and forward through the execution of your application and inspect its state.

You can use IntelliTrace in Visual Studio Enterprise edition (but not the Professional or Community editions).

Why use Historical Debugging?

Setting breakpoints to find bugs can be a rather hit-or-miss affair. You set a breakpoint close to the place in your code where you suspect the bug to be, then run the application in the debugger and hope your breakpoint gets hit, and that the place where execution breaks can reveal the source of the bug. If not, you’ll have to try setting a breakpoint somewhere else in the code and rerun the debugger, executing your test steps over and over until you find the problem.

setting a breakpoint

You can use IntelliTrace and Historical Debugging to roam around in your application and inspect its state (call stack and local variables) without having to set breakpoints, restart debugging, and repeat test steps. This can save you a lot of time, especially when the bug is located deep in a test scenario that takes a long time to execute.

How do I start using Historical Debugging?

IntelliTrace is on by default. All you have to do is decide which events and function calls are of interest to you. For more information about defining what you want to look for, see IntelliTrace Features. For a step-by-step account of debugging with IntelliTrace, see Walkthrough: Using IntelliTrace.

Let’s start with a simple program that has a bug. In a C# console application, add the following code:

static void Main(string[] args)  
{  
    int testInt = 0;  
    int resultInt = AddAll(testInt);  
    Console.WriteLine(resultInt);  
}  
private static int AddAll(int j)  
{  
    for (int i = 0; i < 20; i++)  
    {  
        j = AddInt(j);  
    }  
    return j;  
}  
  
private static int AddInt(int add)  
{  
    if (add == 10)  
    {  
        return add += 25;  
    }  
    return ++add;  
}  

We’ll assume that the expected value of resultInt after calling AddAll() is 20 (the result of incrementing testInt 20 times). (We’ll also assume that you can’t see the bug in AddInt()).But the result is actually 44. How can we find the bug without stepping through AddAll() 10 times? We can use Historical Debugging to find the bug faster and more easily. Here’s how:

  1. In Tools / Options / IntelliTrace / General, make sure that IntelliTrace is enabled, and select the IntelliTrace events and call information option. If you do not select this option, you will not be able to see the navigation gutter (as explained below).

  2. Set a breakpoint on the Console.WriteLine(resultInt); line.

  3. Start debugging. The code executes to the breakpoint. In the Locals window, you can see that the value of resultInt is 44.

  4. Open the Diagnostic Tools window (Debug / Show Diagnostic Tools). The code window should look like this:

    Code window at the breakpoint

  5. You should see a double arrow next to the left margin, just above the breakpoint. This area is called the navigation gutter, and is used for Historical Debugging. Click the arrow.

    In the code window, you should see that the preceding line of code (int resultInt = AddIterative(testInt);) is colored pink. Above the window, you should see a message that you are now in Historical Debugging.

    The code window now looks like this:

    code window in historical debugging mode

  6. Now you can step into the AddAll() method (F11, or the Step Into button in the navigation gutter. Step forward (F10, or Go to Next Call in the navigation gutter. The pink line is now on the j = AddInt(j); line. F10 in this case does not step to the next line of code. Instead, it steps to the next function call. Historical debugging navigates from call to call, and it skips lines of code that do not include a function call.

  7. Now step into the AddInt() method. You should see the bug in this code immediately.

    This procedure just scratched the surface of what you can do with Historical Debugging. To find out more about the different settings and the effects of the different buttons in the navigation gutter, see IntelliTrace Features.