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Develop IPlugin implementations as stateless

Category: Design, Performance

Potential risk: High

Symptoms

Members of classes that implement the IPlugin interface are exposed to potential thread-safety issues which could lead to:

  • Data inconsistencies
  • Slower plug-in executions

Guidance

When implementing IPlugin, don't use member fields and properties and write the Execute method as a stateless operation. All per invocation state information should be accessed via the execution context only.

Don't attempt to store any execution state data in member fields or properties for use during the current or next plug-in invocation unless that data was obtained from the configuration parameter provided to the overloaded constructor.

Don't use code that registers to AppDomain events. Plugin logic shouldn't rely on any AppDomain events or properties, since the internal implementation of the plugin infrastructure can change the execution behavior at any point of time. Registering to AppDomain events can cause failures even if the code worked at some point in time.

Read-only, static, and constant members are inherently thread-safe and can also be used reliably within a plug-in class. The following are some examples on how to maintain thread-safe plug-ins:

Constant field members

public class Valid_ClassConstantMember : IPlugin
{
   public const string validConstantMember = "Plugin registration not valid for {0} message.";

   public void Execute(IServiceProvider serviceProvider)
   {
      var context = (IPluginExecutionContext)serviceProvider.GetService(typeof(IPluginExecutionContext));

      if (context.MessageName.ToLower() != "create")
            throw new InvalidPluginExecutionException(String.Format(Valid_ClassConstantMember.validConstantMember, context.MessageName));
   }
}

Storing configuration data assigned or set in plug-in class constructor

public class Valid_ClassFieldConfigMember : IPlugin
{
   private string validConfigField;

   public Valid_ClassFieldConfigMember(string unsecure, string secure)
   {
      this.validConfigField = String.IsNullOrEmpty(secure)
            ? unsecure
            : secure;
   }

   public void Execute(IServiceProvider serviceProvider)
   {
      if (!String.IsNullOrEmpty(this.validConfigField))
      {
            var message = ValidHelperMethod();
      }
   }

   private string ValidHelperMethod()
   {
      return String.Format("{0} is the config value.", this.validConfigField);
   }
}

Stateless method implementation

public class Valid_ClassStatelessMethodMember : IPlugin
{
   public void Execute(IServiceProvider serviceProvider)
   {
      var context = (IPluginExecutionContext)serviceProvider.GetService(typeof(IPluginExecutionContext));

      if (ValidMemberMethod(context))
      {
            //Then continue with execution
      }
   }

   private bool ValidMemberMethod(IPluginExecutionContext context)
   {
      if (context.MessageName.ToLower() == "create")
            return true;
      else
            return false;
   }
}

Problematic patterns

Warning

These patterns should be avoided.

Assigning plug-in class field member during plug-in execution

public class Violation_ClassAssignFieldMember : IPlugin
{
   //The instance member used in multiple violation patterns
   internal IOrganizationService service = null;
   internal IPluginExecutionContext context = null;

   public void Execute(IServiceProvider serviceProvider)
   {
      this.context = (IPluginExecutionContext)serviceProvider.GetService(typeof(IPluginExecutionContext));
      var factory = (IOrganizationServiceFactory)serviceProvider.GetService(typeof(IOrganizationServiceFactory));

      //The violation
      this.service = factory.CreateOrganizationService(this.context.UserId);

      //Invoke another violation in method member
      AccessViolationProperties();
   }

   private void AccessViolationProperties()
   {
      //Accessing the context and service fields exposes this IPlugin implementation to thread-safety issues
      var entity = new Entity("task");
      entity["regardingid"] = new EntityReference(this.context.PrimaryEntityName, this.context.PrimaryEntityId);

      var id = this.service.Create(entity);
   }
}

Setting plug-in class property member during plug-in execution

public class Violation_ClassAssignPropertyMember : IPlugin
{
   //The instance member used in multiple violation patterns
   internal IOrganizationService Service { get; set; }
   internal IPluginExecutionContext Context { get; set; }

   public void Execute(IServiceProvider serviceProvider)
   {
      this.Context = (IPluginExecutionContext)serviceProvider.GetService(typeof(IPluginExecutionContext));
      var factory = (IOrganizationServiceFactory)serviceProvider.GetService(typeof(IOrganizationServiceFactory));

      //The violation
      this.Service = factory.CreateOrganizationService(context.UserId);

      //Invoke another violation in method member
      AccessViolationProperties();
   }

   private void AccessViolationProperties()
   {
      //Accessing the Context and Service properties exposes this IPlugin implementation to thread-safety issues
      var entity = new Entity("task");
      entity["regardingid"] = new EntityReference(this.Context.PrimaryEntityName, this.Context.PrimaryEntityId);

      var id = this.Service.Create(entity);
   }
}

Additional information

After Microsoft Dataverse instantiates the plug-in class, the platform caches that plug-in instance for performance reasons. Dataverse manages the length of time that a plug-in instance is held in cache. Certain operations, such as changing a plug-in's registration properties, trigger a notification to the platform to refresh the cache. In these scenarios, the plug-in is reinitialized.

Because the platform caches plug-in class instances, the constructor isn't called for every invocation of plug-in execution. For this reason, IPlugin implementations shouldn't depend on the timing of operations in the constructor apart from obtaining static configuration data.

Another reason IPlugins should be stateless is that multiple system threads could execute the same, shared, plug-in instance concurrently. This anti-pattern opens up members of classes that implement IPlugin to potential thread-safety issues, which could lead to data inconsistency or performance problems.

See also

Write a plug-in