Application Isolation

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When writing applications it is often necessary to isolate parts of them so that a failure of one part does not cause a failure in another. In Windows, application isolation has been at the process level. In other words, if a process is stopped or crashes, other processes will be unaffected. Unless shared memory is used, one process cannot directly address memory in another process's address space.

For an application to use separate processes to achieve isolation is expensive. To switch from one process to another, the contents of the machine registers must be saved and restored. This includes a thread and process switch. A thread switch requires saving registers, such as the instruction pointer, and loading the information for a new thread, as well as updating the scheduling information for the threads. A process switch includes, accounting information and processor rights that have to be saved for the old process and restored for the new one.

Application Domain

The .NET Application Domain is a more lightweight unit for application isolation, fault tolerance, and security. Multiple application domains can run in one process. Since the .NET code can be checked for type safety and security, the CLR can guarantee that one App Domain can run without interference from another App Domain in the same process. No process switch is required to achieve application isolation.

Application Domains can have multiple contexts, but a context exists in only one AppDomain. Although a thread runs in one context of one application domain at a time, the Threading example Step 3 demonstrates that a thread can execute in more than one context. One or more threads can run in an App Domain at the same time. An object lives in only one context.

Each AppDomain starts with a single thread and one context. Additional threads and contexts are added as needed.

There is no relationship between the number of application domains and threads. A Web server might require an application domain for each hosted application that runs in its process. The number of threads in that process would be far fewer, depending on how much actual concurrency the process can support.

To enforce application isolation, code in one application domain cannot make direct calls into the code (or even reference resources) in another application domain. They must use proxies.

Application Domains and Assemblies

Applications are built from one or more assemblies, but each assembly is loaded into a particular application domain. Each application domain can be unloaded independently of the others, but you cannot unload an individual assembly from an App Domain. The assembly will be unloaded when the App Domain is unloaded. Unloading an App Domain also frees all resources associated with that App Domain.

Each process has a default application domain that is created when the process is started. This default domain can be unloaded only when the process shuts down.

Applications such as ASP.NET or Internet Explorer critically depend on preventing the various applications that run under it from interfering with each other. By never loading application code into the default domain, they can ensure that a crashing program will not bring down a host.

AppDomain Class

The AppDomain class abstracts application domains. The AppDomain sample illustrates the use of application domains.

This class has static methods for creating and unloading application domains:

 AppDomain domain = AppDmain.CreateDomain("CreatedDomain2",                                                null, null);  . . .  AppDomain.Unload(domain); 

While the CreateDomain method is overloaded, one signature illustrates application-domain isolation:

 AppDomain CreateDomain(string Name, Evidence securityInfo,                         AppDomainSetup info) 

The Evidence parameter is a collection of the security constraints on the application domain. While we will discuss this in greater detail in the Security chapter, the domain's creator can modify this collection to control the permissions that the executing app domain can have. The AppDomainSetup parameter specifies setup information about the domain. Among the information specified is the location of the App Domain's configuration file and where private assemblies are loaded. Hence, each App Domain can be configured independently of every other. Code isolation, setup isolation, and control over security combine to ensure that application domains are independent of each other.

App Domain Events

To help in maintaining application isolation, the AppDomain class allows you to set up event handlers for:

  • when a domain unloads

  • when the process exits

  • when an unhandled exception occurs

  • when attempts to resolve assemblies, types, and resources fail

AppDomain Example

The AppDomain example lets us examine various aspects of application domains. If you run the example you will get the output in Figure 8-1.

Figure 8-1. Output of AppDomain example.

graphics/08fig01.gif

First, the name, thread, and context of the default domain are written out.

 AppDomain currentDomain = AppDomain.CurrentDomain;  Console.WriteLine("At startup, Default AppDomain is {0}                        ThreadId: {1} ContextId {2}\n",                        currentDomain.FriendlyName,                        Thread.CurrentThread.GetHashCode(),                        Thread.CurrentContext.ContextID); 

We then load and execute an assembly. The code in this assembly just prints out a string and its domain's name, thread, and context. Notice that it executes in the default domain.

 int val = currentDomain.ExecuteAssembly("TestApp.exe"); 

We then create an instance of the Customers type from the Customer assembly in the default domain. The CreateInstance method of the AppDomain class returns an ObjectHandle instance. You can pass this ObjectHandle between application domains without loading the metadata associated with the wrapped type. When you want to use the object as its actual type instead of as an opaque object instance, you must unwrap it by calling the Unwrap method on the ObjectHandle instance.

 ObjectHandle oh = currentDomain.CreateInstance("Customer",                                 "OI.NetCs.Acme.Customers");  . . .  Customers custs = (Customers)oh.Unwrap(); 

We add a new customer and then list all the existing customers. Notice that both the constructor of this type and the methods execute in the same thread and context that the default domain does.

We then create a new domain and create an instance of the same type as before in that new domain.

 AppDomain domain = AppDmain.CreateDomain("CreatedDomain1",                                 null, null);  . . .  oh = domain.CreateInstance("Customer",                                 "OI.NetCs.Acme.Customers");  . . .  Customers custs2 = (Customers)oh.Unwrap(); 

Note that the constructor call that results from the CreateInstance method executes in the new domain and is therefore in a different context from where the CreateInstance call was made, but it is executing on the same thread that made the CreateInstance call.

When we list the customers in this new object, we get a different list of customers. This is not surprising, since it is a different Customers object. Nonetheless, the customer list method executes in the default domain!

Using RemotingServices.IsTransparentProxy , we see that the ObjectHandle is a proxy to the Customers object that lives in the newly created AppDomain. However, when you unwrap the object to get an instance handle, you do not get a proxy, but you get an actual object reference. By default, objects are marshaled by value ( copied ) from one AppDomain to another.

If the Customers object is not serializable, you will get an exception when you try to copy it because the runtime will not know how to make the copy. This exception would be thrown when you do the Unwrap , not the CreateInstance . The latter returns a reference; the copy is made only when the ObjectHandle is unwrapped. If the object cannot be serialized, it cannot be copied from one AppDomain to another.

Next we create a new thread, and that thread creates a new application domain, loads, and executes an assembly. The assembly starts executing at its entry point, the Main routine of the AppDomainTest class.

 AppDomain domain = AppDmain.CreateDomain("CreatedDomain2",                                                null, null);  . . .  string[] args = new String[1];  args[0] = "MakeReservation";  int val = domain.ExecuteAssembly("TestApp.exe", null,                                                      args);  . . .  AppDomain.Unload(domain); 

The Main routine loads the Hotel assembly into the newly created App Domain. It then queries the metadata of the assembly for the HotelBroker type information. It uses that type information to create a HotelBroker object. The HotelBroker class is marked with a synchronization attribute. As a result, the HotelBroker constructor and the MakeReservation method run in a different context than the default context.

 Assembly a = AppDomain.CurrentDomain.Load("Hotel");  Type typeHotelBroker =     a.GetType("OI.NetCs.Acme.HotelBroker");  HotelBroker hotelBroker =  (HotelBroker)Activator.CreateInstance(typeHotelBroker);  DateTime date = DateTime.Parse("12/2/2001");  ReservationResult rr = hotelBroker.MakeReservation(1,                             "Boston", "Sheraton", date, 3);  Console.WriteLine("\tReservation Id: {0}",                                          rr.ReservationId); 

Marshaling, AppDomains, and Contexts

By default, objects are copied from one App Domain to another (marshal by value). The Remoting section will show how to marshal by reference between App Domains. This ensures that code in one application domain is isolated from another.

Objects are marshaled by reference between contexts. This allows the CLR to enforce the requirements (such as synchronization or transactions) of different objects. This is true whether the client of the object is in the same application domain or not.

Since most objects do not derive from ContextBoundObject , they can reside or move from one context to another as required. Threads can cross application domain and context boundaries within the same Win32 process.

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Application Development Using C# and .NET
Application Development Using C# and .NET
ISBN: 013093383X
EAN: 2147483647
Year: 2001
Pages: 158

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