Error Handling and Debugging Tips for Access 2007, VB, and VBA
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Summary: Experienced developers use a variety of techniques to simplify their coding and maintenance efforts. Some of the tricks are general programming styles and conventions, while others are specific to the characteristics of Microsoft Visual Basic 6.0 and Visual Basic for Applications (VBA). Hopefully, by adopting such "best practices" techniques, you'll be able to write code that's easier to write, debug, and understand. Not only can you reduce bugs during development, you can also significantly reduce the effort required to replicate and fix bugs your users encounter. A consistent coding style is critical for efficient application development in multi-developer environments. It also increases the chance that future developers can understand your work to fix or enhance it. (20 printed pages)
Luke Chung, President of FMS, Inc.
August 2009
Applies to: Microsoft Office Access 2007
Contents
Introduction to Debugging and Error Handling
Debugging Goals
Basic Error Handling
Debugger
Debugging Views
Writing Code for Debugging
Advanced Error Handling
Automate the Application Delivery Process
Automated Code Analysis
Conclusions
Additional Resources from Microsoft
About the Author
Introduction to Debugging and Error Handling
Debugging is one of the most important skills for a developer. Software development is all about writing code, making mistakes, and fixing them. Strong debugging skills minimize the development cycle by allowing developers to pinpoint bugs quicker, make fixes that actually address the problems encountered, and verify the modifications are correct. This is particularly important as the code gets more complex.
Debugging doesn’t end when the application is shipped. Having the proper error handling in place is critical to providing quick support when users encounter crashes. At the very least you want to verify it’s a problem in your application, and if so, as much information as possible so you can minimize the need for user recall on how to reproduce the bug.
Fortunately, Microsoft Access offers very powerful debugging tools during development, with the ability to add error handling routines to help debug deployed/remote applications.
Debugging Goals
Fixing Bugs
The most common use of the debugger is to diagnose the code when a crash is encountered. If no error handling is in place, when an Access application crashes, you or your user are prompted with a message box similar to the one in Figure 1.
Figure 1. VBA/VB6 default error message
Assuming that you’re not running an MDE, when you click Debug, you open the IDE at the line where the crash occurred and have the opportunity to examine the problem.
Analysis During Development
Another important use of the debugger is during system development to verify the code is working correctly even if a crash doesn’t occur, or to narrow down the situations where a crash occurs. The Access/VB6 debugger lets you step through each line of code as it runs, examine the environment (including all variables), and even change variable values and lines of code! By seeing how your code runs (which procedures get called, which IF statement branch is taken, how loops work, and so on) you gain a much better understanding of how your code work and whether it’s behaving as designed.
Supporting Deployed Applications
By including a consistent error handler design with a central error handler, you can deploy applications that document the crashes your users encounter. This is particularly important if you have many remote customers and can’t easily go to the offending desktop when the user calls. With a sophisticated error handler, you can document not only the error, but other important information such as the procedure name, procedure call stack, line number where the crash occurred, and other Access environment information. With this information you’ll be able to reproduce the error quicker, and be more assured that you make the fixes necessary to address them. Most importantly, you’ll minimize the often frustrating process that developers and users face when trying to reproduce crashes.
Basic Error Handling
Professional applications need to include error handling to trap unexpected errors. By using a consistent error handler, you can make sure that when crashes occur, the user is properly informed and your program exits gracefully. Basic error handling just hides the default behavior and exits the program. Advanced error handling can include all sorts of features such as saving information about the cause of the error and the environment at the time, attempts to address the problem, and information for the user on what they need to do next.
Verify Error Handling Setting
Before you can use error handling, you need to understand the Error Trapping setting. Visual Basic 6.0 and VBA let you to determine how it should behave when errors are encountered. From the IDE, look under the Tools Options setting.
Figure 2. Setting error trapping/handling options for Visual Basic and VBA
Make sure that error trapping is not set to Break On All Errors. That setting will cause your code to stop on every error, even errors you are properly handling with On Error Resume Next.
Break on Unhandled Errors works in most cases but is problematic while debugging class modules. During development, if Error Trapping is set to Break on Unhandled Errors and an error occurs in a class module, the debugger stops on the line calling the class rather than the offending line in the class. This makes finding and fixing the problem difficult.
I recommend using Break in Class Modules, which stops on the actual crashing line. However, be aware that this does not work if you use raise errors in your classes via the Err.Raise command. This command actually causes an “error” and makes your program stop if Error Trapping is set to Break in Class Modules.
Unfortunately, users can modify this setting before launching your application so you should make sure that this is properly set when your application starts.
Programmatically, the option settings can be viewed and modified by using the Application.GetOption and Application.SetOption methods.
Function GetErrorTrappingOption() As String
Dim strSetting As String
Select Case Application.GetOption("Error Trapping")
Case 0
strSetting = "Break on All Errors"
Case 1
strSetting = "Break in Class Modules"
Case 2
strSetting = "Break on Unhandled Errors"
End Select
GetErrorTrappingOption = strSetting
End Function
Always include code in your startup routines to set the appropriate error handling level.
Sub SafeStart()
Application.SetOption "Error Trapping", 1
End Sub
Make Sure that Every Procedure Has Error Handling
Once the Error Trapping issue is resolved, you need to add error handling to your application. Unfortunately, Visual Basic 6.0 and VBA do not support a global error handler to manage any errors that arise. You actually have to set error handling in every procedure.
Without you explicitly adding error handling, Visual Basic and VBA show the default error message and then allow the user to debug your code, or just crash.
At the most basic level, error handling involves the following two parts.
Error Enabler
The following section invokes the error handler.
On Error GoTo PROC_ERR
If an error occurs in the procedure, the code jumps to the line where the label “PROC_ERR” is defined. For consistency, use the same label name in every procedure.
Error Handler
The following section is where the code goes if an error occurs in the procedure.
PROC_ERR:
MsgBox "Error: (" & Err.Number & ") " & Err.Description, vbCritical
Here you can manage the error and determine what to do next. Examine the error object (Err) to see what occurred. For example, Err.Number is the error number, Err.Description is the error description, and so on.
Disabling Error Handling
In some situations, you need to turn off error handling. For example, you might want to see if a file exists. By looking for it and managing the error if it can’t be found, you can determine whether it exists or not.
Disable error handling with the following code.
On Error Resume Next
Turn Off Error Handling During Development and Testing
Without error handling, if an error is encountered, the debugger automatically stops on the offending line. This is great for debugging and correcting mistakes. However, if error handling exists in the procedure, when an error occurs, rather than stopping on the offending line, the code in the Error Handling section is invoked. This makes debugging much more difficult.
An easy way to avoid this problem is to add a global constant or variable that controls when error handling is active. So instead of using the following code…
On Error GoTo PROC_ERR
…use this code…
If gcfHandleErrors Then On Error GoTo PROC_ERR
…and then define a global constant by using the following code.
Public Const gcfHandleErrors As Boolean = False
Set this constant to False during development, and then to True when you deliver your application. That way, your users get the benefit of the error handling and you can get your work done without it.
Getting Information from the Error Object
When an error occurs, get information about the problem in the Error Object. This object is named Err and contains several properties. The following are the properties that you should check:
Number The error number, which is useful for testing. A value of zero means no error.
Description The built-in description of the error. Sometimes this doesn’t exist and this text “Application-defined or object-defined error” is given.
The error object lets you easily inform the user of the problem. For example, rather than display a simple message that an error occurred, you can specify the exact error number and message to display.
MsgBox "Error: (" & Err.Number & ") " & Err.Description, vbCritical
The user still might not understand it, but it can be very helpful in diagnosing the problem.
For a complete list, see Microsoft Access Error Numbers and Descriptions Reference.
Clearing the Error Object
There might be situations where you test for an error number but cannot be sure the Err object doesn’t already contain an error. In such cases, use the Clear method to clear the object.
Err.Clear
Alternatively, you can set the error number to zero (Err.Number = 0), but is not as effective as the Clear method since it does not clear the description property.
Using Error Handling for Testing
Error handling can also be used to test a condition. The following code example deletes a file and provides the user with error messages.
Sub DeleteFile(strFileName As String)
Dim lngSaveErr As Long
Dim strSaveErr As String
Const clngErrNoFile As Long = 53
Const clngErrFileInUse As Long = 75
On Error Resume Next
Kill strFileName
lngSaveErr = Err.Number
strSaveErr = Err.Description
On Error GoTo PROC_ERR
Select Case lngSaveErr
Case 0
' No error
Case clngErrNoFile
MsgBox "The file " & strFileName & " does not exist."
Case clngErrFileInUse
MsgBox "The file " & strFileName & " is in use."
Case Else
MsgBox "Unknown error: " & strSaveErr
End Select
PROC_EXIT:
Exit Sub
PROC_ERR:
MsgBox "Error " & Err.Number & " " & Err.Description
Resume PROC_EXIT
End Sub
Notice how the following syntax allows the program to continue (that is, go to the next line) even when a command cannot be executed.
On Error Resume Next
The Kill command triggers an error if the file being deleted doesn’t exist or is locked. We don’t care whether the object exists or not. We just want to delete it if it does. Therefore, the command to ignore the error (Resume Next) is appropriate.
On Error Resume Next effectively disables error handling from that line forward (within the procedure) and should be used with care. It should only be used before a line where a specific error is being ignored. To reset error handling, use the following code.
On Error GoTo 0
Alternatively, the following standard error handler has an extra clause to handle situations where error handling is not being used.
If gcfHandleErrors Then
On Error GoTo PROC_ERR
Else
On Error GoTo 0
End If
Notice that a test of the error number is conducted to determine if a specific error occurred. That is, we consider it okay if the object could not be found. However, there are other reasons that might cause a failure to delete an object that exists (for example another user has the object open, insufficient rights to delete it, and so on).
What Error Handling Cannot Trap
Error handling only handles well-behaved errors; that is, errors that trigger an error number in code. Technically, these are the only types of errors you can have, but we all know that Access can crash with an IPF or GPF. Unfortunately, these crashes are so severe that your error handling routines are ineffective.
Debugger
The following parts of the debugger work together to let you analyze how your code runs:
Integrated Development Environment (IDE)
Breakpoints
Stepping Through and Over Code
Integrated Development Environment (IDE)
From the IDE, there are several things that you can do.
Current Definition [Shift + F2]
Put the cursor on the variable, procedure, or property in question and press SHIFT+F2 to see where it’s defined. You’ll jump directly to it. You can do this as often as you like to understand how your code works. Press CTRL+SHIFT+F2 to go back to where you came.
Run the Current Procedure
Highlight the procedure that you want to run and press F5 to run it. If you want to step into it line-by-line, press F8. More explanations on running code line-by-line is given later. Of course, running a procedure this way only works if you don’t have to pass parameters to it. If you need to, consider using the Immediate Window.
Breakpoints
Breakpoints are placed on the lines in your code so that the debugger is invoked when the program tries to execute that line. A breakpoint can be placed on any line that is actually run (not lines in the General Declarations section, or lines that define variables in a procedure). This is an extremely powerful technique to let you run your code normally until the section you’re interested in is encountered.
Breakpoints can be added by moving to the line desired and pressing F9, clicking with the mouse on the left border, or from the Debug menu. Multiple breakpoints can be added during your debugging session. Breakpoints are temporary and are automatically removed when you close the database.
Stepping Through Code
Once you are in the debugger and stopped on a line whether it’s from selecting Debug from the crash menu or a breakpoint, you have the opportunity to see the “guts” of your program. Simply move your cursor over variables to see their current values. You can also use the Immediate Window or the other Watch windows to be described later to understand all the values.
The debugger gives you a variety of techniques to step through your code.
Step Into (F8)
Run the current line and go to the next one.
Step Over (SHIFT+F8)
Used for a line that calls a procedure to run that procedure without going into it. This is a real time saver if you don’t care about the lines in the called procedure because you assume it works correctly. The command lets you run the procedure (and any procedures it might call), and go to the next line in the calling procedure.
Step Out (CTRL+SHIFT+F8)
Run the current procedure and go to the line after the line that called the procedure. This is basically a way to simplify the debugging process by letting you skip the remainder of the current procedure once you realize you don’t need to step into it any more.
Set Next Statement (CTRL+F9)
This command lets you set the next statement as any line in the current procedure including lines you’ve already run. This is extremely powerful and quite amazing when you think about it. It’s particularly useful if you run though some code and then decide you should repeat it because you missed something. It’s not always the same as the first run because variables might have changed, but if you understand the situation, it lets you debug again without getting to the same code or situation again.
Show Next Statement
Sometimes you examine different procedures as you debug your code, so the Show Next Statement menu command makes it easy to go to the currently highlighted line.
Debugging Views
In addition to seeing which line of code runs and evaluating variables as you debug, there are several other views that help you diagnose your development environment:
Call Stack
Immediate Window
Locals Window
Watch Window
Call Stack (CTRL+L)
The call stack keeps track of the procedure calling chain so you can easily see how you got to the current procedure through all the other procedures. Retrieve it under View, Call Stack, or press CTRL+L.
Figure 3. Call Stack window to see the procedure-calling chain
From this dialog box, you can click any procedure and jump immediately to it. Before analyzing the details of the current procedure, it might be more important to understand how and why you got there since the problem might be there rather than in the current procedure.
Immediate Window (CTRL+G)
This is the most basic debugging area. You can use the Immediate Window whether your code is running or not. Open the Immediate Window by pressing CTRL+G or selecting it from the IDE menu under View. The Immediate window lets you do the following:
Evaluate expressions unrelated to your code (for example, math equations)
Evaluate variables or expressions in your code (for example, a current variable value)
Run code
For items that return a value, use a question mark (the old Print command) followed by the expression, similar to the following example.
? 10/3
Press ENTER to see the value. If your code is currently running and stopped, you can use this method to evaluate the current value of a variable.
? strSQL
You can also use it to launch a VB6/VBA function or your function with the parameters that you want.
? MsgBox("Choose a button", vbCritical+vbYesNo)
The Immediate Window runs the function, then shows its return value.
If you want to run a sub, none of which return a value, do not include the "?" and just type the subroutine name.
MsgBox "Choose a button"
Figure 4. Immediate window for calculations and running code
Locals Window
Rather than examining variable values individually by typing them in the Immediate Window, you can see all the local variables by selecting Locals Window from the Views menu. This displays the entire list of local variables and their current values. Local variables are variables defined in the current procedure and module declaration section.
Figure 5. Locals window to see and debug your variables
Notice how each array element is shown by expanding the treeview for that variable.
You can modify the value held by a variable by clicking on the Value column and editing it. This is an alternative to modifying values from the Immediate Window.
Watch Window
The Watch Window is similar to the Locals Window, but you specify the variables you want to track. You can track variables across modules and procedures and keep them in your Watch Window to see their value no matter where the current line is.
The first step is to add a variable to the Watch Window by placing the cursor in the variable that you want to track and selecting Debug, Add Watch to open the following dialog box.
Figure 6. Add Watch window to monitor variables in your application
The current variable is added to the Expression section, and the current procedure and module added to the Context sections. If you click OK, this variable is added to the Watch Window and you can see its value whenever you look at the Watch Window.
What’s most powerful about adding watches is that in addition to variables, you can also add expressions, and options to break when the value changes. The latter is particularly powerful when you are having trouble determining why a particular situation arises in your application. Maybe a variable is set in multiple places and you can’t tell which instance is causing the value to change. By setting the Watch Type option, you can quickly stop when this occurs.
Break When Value Changes
This stops the debugger on the line immediately after the value of the variable/expression changes.
Break When Value Is True
This stops the debugger on the line immediately after the value of the variable/expression evaluates as True. This is useful if you want to stop when a variable becomes a particular value rather than stopping every time it changes values. For example, if you want the program to stop so that you can debug when the variable reaches 500, type the following line of code in the Expression section.
intCounter = 500
Writing Code for Debugging
So far, we’ve explored ways to debug an Access application without changing any behavior with the program itself. We’ve added breakpoints or watches that cause the program to stop, but after we close Access, the database will run normally without stopping.
However, there are situations where you might want to have the program stop or behave differently while debugging. Some examples include adding:
Testing code
Debug.Print statements
Debug.Assert statements
Stop statements
Testing Code
Sometimes using the Immediate Window is insufficient for testing a function or procedure. Maybe you want to test it multiple times and don’t want to type it each time on the Immediate Window, or maybe the procedure call is too complex to use in the Immediate Window. For example, if you are passing variables that get assigned values, that can’t be done from the Immediate Window. Similarly, the procedure you are testing might require calling lots of other procedures in advance to set up the environment before you can run it.
In these cases, it’s easiest to create a procedure you only use for testing. This can be a real time saver if the code you are testing is buried deep in a process and you don’t want to run the whole program to get there.
Debug.Print Statements
The Debug.Print statement lets you write output to the Immediate Window. Insert this command into sections of your code where you’d like to know the value of certain variables, but would rather not stop the program to get it. For example, if you’re moving through a recordset and would like to know the values of a few fields as the processing occurs, you might have code similar to the following before the other processing of the record occurs.
Debug.Print intCount & ": " & rst![ID] & ", " & rst![Name]
intCount = intCount + 1
It’s not as good as stepping through each line, but maybe this is all you need initially to see if a particular routine is running properly before narrowing your search further.
Debug.Assert Statements
The Debug.Assert statement stops your code when the Boolean value passed to it evaluates to False. For example, if you add the following code, the debugger stops when x is 5.
Debug.Assert x <> 5
Stop Statement
The alternative to using Debug.Assert is to use a Stop statement inside an If clause. The equivalent to the previous code is the following.
If x = 5 Then Stop
Stop statements are rare but some developers like to add it to the end of Select Case statements for what should be an impossible branch.
Select Case strType
Case "Hot"
Case "Cold"
Case "Warm"
Case Else
Stop
End Select
One could argue that during development and testing, if the value should not be one of the acceptable ones, the program should stop. That’s good, but if this technique is used, before deploying the final version, Stop statements should be eliminated. Far better to have an error arise and trap for that than a program simply stop for the end-user.
Advanced Error Handling
The error handling examples shown so far only manage errors in the current procedure. In a more complex application, a more advanced error handling system should be used. A single (global) error handler should process unexpected errors and reveal information beyond the error number and description. This section will reveal how your error handler can document the following:
The procedure name where the error occurred.
The procedure call stack to see how the procedure was invoked.
The line number where the error occurred.
Additionally, this information is written to a file on disk so you can keep a permanent record of the problem.
Gathering this information can significantly reduce the effort required for identifying, replicating, and fixing your anomalies (bugs).
Creating a Procedure Call Stack
Unfortunately, while Visual Basic 6.0 and VBA track the procedure call stack and let you examine it under the View, Call Stack menu item while debugging, this information is not available to your code. The only way to generate this is to track it yourself.
To do this, you need to keep your own Call Stack of procedure names by doing the following.
Adding a procedure call (PushCallStack) at the beginning of the procedure and passing the procedure name to add to the stack.
Adding a procedure call (PopCallStack) to the end of each procedure to remove the procedure name from the stack.
Since Visual Basic 6.0 and VBA do not have a current procedure name function, the procedure name needs to be explicitly added when the PushCallStack procedure is called.
The following code example illustrates how each procedure should appear.
Sub AdvancedErrorStructure()
' Use a call stack and global error handler
If gcfHandleErrors Then On Error GoTo PROC_ERR
PushCallStack "AdvancedErrorStructure"
' << Your code here >>
PROC_EXIT:
PopCallStack
Exit Sub
PROC_ERR:
GlobalErrHandler
Resume PROC_EXIT
End Sub
Notice how the PushCallStack procedure is invoked at the beginning of the procedure with the name of the current procedure as a parameter. The PopCallStack is called at the end of the procedure to remove the current procedure name from the stack when the procedure completes successfully. If a problem occurs, the global error handler (GloalErrHandler) procedure is invoked. In most cases, the global error handler will exit the program, but if for some reason it doesn’t the code is designed to exit this procedure.
Avoid Exits before the End of the Procedure
For this process to work, procedures might not quit without going to the bottom of the procedure. That is, you can’t have code such as “Exit Sub” or “Exit Function” in the middle of your procedure; otherwise, the PopDebugStack routine will not be invoked and the procedure name remains on the stack.
Error Handling Module
An error module should contain your error handling routines.
General Declarations
The declarations section should define some variables used by the routines similar to the following code.
' Current pointer to the array element of the call stack
Private mintStackPointer As Integer
' Array of procedure names in the call stack
Private mastrCallStack() As String
' The number of elements to increase the array
Private Const mcintIncrementStackSize As Integer = 10
Procedure PushCallStack
Adds the current procedure to the call stack array. Needs to be called at the beginning of each procedure.
Sub PushCallStack(strProcName As String)
' Comments: Add the current procedure name to the Call Stack.
' Should be called whenever a procedure is called
On Error Resume Next
' Verify the stack array can handle the current array element
If mintStackPointer > UBound(mastrCallStack) Then
' If array has not been defined, initialize the error handler
If Err.Number = 9 Then
ErrorHandlerInit
Else
' Increase the size of the array to not go out of bounds
ReDim Preserve mastrCallStack(UBound(mastrCallStack) + _
mcintIncrementStackSize)
End If
End If
On Error GoTo 0
mastrCallStack(mintStackPointer) = strProcName
' Increment pointer to next element
mintStackPointer = mintStackPointer + 1
End Sub
Private Sub ErrorHandlerInit()
mfInErrorHandler = False
mintStackPointer = 1
ReDim mastrCallStack(1 To mcintIncrementStackSize)
End Sub
Procedure PopCallStack
Removes the current procedure from the call stack array. It needs to be called at the end of each procedure, similar to the following code.
Sub PopCallStack()
' Comments: Remove a procedure name from the call stack
If mintStackPointer <= UBound(mastrCallStack) Then
mastrCallStack(mintStackPointer) = ""
End If
' Reset pointer to previous element
mintStackPointer = mintStackPointer - 1
End Sub
Track Line Numbers to Pinpoint the Location of a Crash
After you know which procedure crashed, it is extremely valuable to know where the error occurred. Use the Erl function to find which line of code generated the error. In many cases, if you know the error and the exact line where it occurred, you can immediately understand the problem and fix it. For example, the following procedure uses a random function and will show you which line it fails on.
Sub SampleErrorWithLineNumbers()
Dim dblNum As Double
10 On Error GoTo PROC_ERR
' Crashes if table doesn't exist
20 Select Case Rnd()
Case Is < 0.2
30 dblNum = 5 / 0
40 Case Is < 0.4
50 dblNum = 5 / 0
60 Case Is < 0.6
70 dblNum = 5 / 0
80 Case Is < 0.8
90 dblNum = 5 / 0
100 Case Else
End Select
110 Exit Sub
PROC_ERR:
120 MsgBox "Error Line: " & Erl & vbCrLf & vbCrLf & _"Error: (" & _
Err.Number & ") " & Err.Description, vbCritical
End Sub
Of course in a simple procedure, the line number does not offer much, but in a larger more complicated subroutine, knowing which line crashed can save considerable time and effort replicating and fixing the problem.
Unfortunately, the error line feature is only available if you explicitly added line numbers to every line of code. This is nearly impossible to do manually for all but the simplest databases. Use the Total Visual CodeTools program from FMS to do this.
Global Error Handler
All procedures should call the global error handler when an error is encountered. From this procedure, you centralize your response to handling errors. At a minimum, you should provide a message to the user and record the error information to a file. This should include the following:
How to notify you of the error (contact information such as phone number, fax, email).
The error number and description.
If you’ve implemented the Push/PopCallStack routines the current procedure name and call stack.
If you’ve added line numbers to your code, the error line number.
Any other information about Access, the Access workspace, operating system, memory, disk space, DLLs, where files are located, and so on that might be useful for your diagnoses.
A more sophisticated response might include links to web site technical support pages and product update patches. Customize this to best serve your customers based on their abilities to troubleshoot errors.
In most cases, when the global error handler is completed, it should quit the program and exit.
Sub GlobalErrHandler()
' Comments: Main procedure to handle errors that occur.
Dim strError As String
Dim lngError As Long
Dim intErl As Integer
Dim strMsg As String
' Variables to preserve error information
strError = Err.Description
lngError = Err.Number
intErl = Erl
' Reset workspace, close open objects
ResetWorkspace
' Prompt the user with information on the error:
strMsg = "Procedure: " & CurrentProcName() & vbCrLf & _
"Line : " & intErl & vbCrLf & _
"Error : (" & lngError & ")" & strError
MsgBox strMsg, vbCritical
' Write error to file:
WriteErrorToFile lngError, strError, intErl
' Exit Access without saving any changes
' (you might want to change this to save all changes)
Application.Quit acExit
End Sub
The following function returns the current procedure name.
Private Function CurrentProcName() As String
CurrentProcName = mastrCallStack(mintStackPointer - 1)
End Function
Resetting the Workspace
When an unexpected error occurs, you often need to cleanup the workspace in Access before showing the messages. The following code is a simple routine that handles some basic tasks.
Private Sub ResetWorkspace()
Dim intCounter As Integer
On Error Resume Next
Application.MenuBar = ""
DoCmd.SetWarnings False
DoCmd.Hourglass False
DoCmd.Echo True
' Clean up workspace by closing open forms and reports
For intCounter = 0 To Forms.Count - 1
DoCmd.Close acForm, Forms(intCounter).Name
Next intCounter
For intCounter = 0 To Reports.Count - 1
DoCmd.Close acReport, Reports(intCounter).Name
Next intCounter
End Sub
Documenting Crashes to a Text File
To write to a text file, simply use the Print # command. You need to determine the name of the text file and which directory it should be placed. In general, we place the error.txt file in the same directory as the application database. However, you might want to put it in a shared network directory (such as where the linked data database is located) or a specific error location.
A text file is the best option for storing error information. Other options such as writing the data to a table or sending an email might fail in error situations (especially out of memory errors). Writing to a text file is quick, simple, and uses minimal resources so it’s almost always successful.
Automate the Application Delivery Process
Write Code to Prepare the Application
Most applications require some “clean-up” before they can be distributed. Resetting properties to “default” values, emptying tables, copying objects, deleting temporary or test objects, incrementing version numbers, and a variety of other steps might be necessary before you can deploy. Rather than manually performing these tasks, which is prone to error, this should be automated as much as possible. Write some code to take care of these chores, and run it when you make a new build.
Disable or Eliminate Debugging Code
Before delivering your application, make sure that your debugging code is removed or disabled. Code such as Stop; Debug.Print; Debug.Assert; should be eliminated or put into sections that won’t be invoked.
Add Line Numbers
For your error handler to pinpoint the exact line where an error occurs, add line numbers to every line of code. Obviously, this would be difficult to do manually. This is one of many features in FMS’s Total Visual CodeTools.
Automated Code Analysis
To maintain your application over time and to track changes by version, you need to document it. Some of this can only be done manually, but automated tools can help you not only document your application, but also detect problems that would otherwise be very difficult to detect.
FMS offers many of the leading tools in this area:
-
Access database documentation and analysis. Generates complete object and code cross-reference. Know where procedures and variables are used. Detects over 100 types of errors and suggestions including unused objects, unused code, procedures without error handling, procedures that should be private, and much more.
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Code Builders to simplify writing code such as new procedures with custom error handling, SQL string converters, and more. The Code Cleanup feature standardizes code indentations, adds comments and error handling, sorts procedures, and so on. It also adds line numbers to your code.
Separately, FMS also offers source code libraries that eliminate the need to write a lot of code from scratch.
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Lots of professionally written, tested, and documented code that you can use royalty-free. Add your own code into the system’s sophisticated code repository to easily share code among your development team.
FMS also offers related tools for Visual Studio .NET and SQL Server developers.
Conclusions
Hopefully, the tips and techniques presented here will help you create better Access and Visual Basic 6.0 applications faster. Access and Visual Basic 6.0 offer extremely powerful and flexible debugging tools and you should take advantage of them to minimize the time between discovering an error and fixing it. With the proper error handling methodology and delivery preparation with line numbers, you can also debug and fix errors in deployed applications.
Happy application developing!
Additional Resources from Microsoft
For more information, see the following resources:
About the Author
Luke Chung
Luke Chung founded FMS, Inc., in 1986 to provide custom database solutions. He has directed the company’s product development and consulting services efforts as the database industry evolved. In addition to being a primary author and designer of many FMS commercial products, Luke has personally provided consulting services to a wide range of clients. A recognized database expert and highly regarded authority in the Microsoft Access developer community, Luke was featured by Microsoft as an Access Hero during the Access 10-year anniversary celebration. Luke is a popular speaker at conferences in the US and Europe, and has published many articles in industry magazines. He is a past president of the Washington, DC chapter of the Entrepreneurs Organization (EO Network), serves on the Fairfax County School Superintendent's Community Advisory Council, and is a graduate of Harvard University with Bachelor and Master Degrees in Engineering and Applied Sciences.