I have this Entity class:
public class Foo{
[Key]
[Column("ENT_ID")]
public int Id { set; get; }
.....
[NotMapped]
public virtual Employee Employee{ set; get; }
[NotMapped]
public virtual List<Car> Cars{ set; get; }
[NotMapped]
public virtual List<Book> Books{ set; get; }
public Foo()
{
Books= new List<Book>();
Cars= new List<Car>();
}
}
I would to exclude virtual properties from serialization, using [NotMapped] worked but I am not able to navigate to this properties!
I tried to use [XMLIgnore] but did not help.
I use this serialize class:
public class XmlSerializer<T> where T : class
{
public static string Serialize(T data)
{
var sw = new StringWriter();
var xmlSerializer = new XmlSerializer(typeof(T));
xmlSerializer.Serialize(sw, data);
return sw.ToString();
}
public static T Deserialize(string data)
{
var ser = new XmlSerializer(typeof(T));
var sr = new StringReader(data);
return (T)ser.Deserialize(sr);
}
}
How to exclude virtual properties from serialization and still use them as navigation properties?
You need to remove the generated proxy from the entity before serializing. To get the object without EF generating the proxy you'll have to disable the proxy creation and than convert it to an object. Like so:
dbCcontext.Configuration.ProxyCreationEnabled = false;
Foo foo = dbContext.Entry(fooLoadedWithEF).CurrentValues.ToObject() as Foo;
// Do your serialization of 'foo'
Don't forget to set the ProxyCreationEnabled back to it's original value afterwards.
There's a nice method that does this in an answer about removing the proxy here: https://stackoverflow.com/a/25774651/31722
Related
TL;DR: what's the most concise method to load a single navigation property on an entity?
Suppose I already have an instance entity Foo with a child Child. Instance of Foo I have has ChildId set but Child was not loaded, i.e. foo.ChildId == 1234 but foo.Child == null.
I want to get Child if it is missing. I know I can do:
if (foo.Child is null) {
foo.Child = _dbContext.Foos.Include(f => f.Child).Single(f => f.Id == foo.Id).Child;
}
but I am looking for a lazy way (pun!) to load it on-demand (I don't want to load all properties on-demand, however, just the one I want to load explicitly), something like:
var child = _dbContext.EnsureLoaded(da, e => e.Child);
Is there a way to do this?
Probably you are looking for Explicit Loading of Related Data
_dbContext.Entry(foo).Reference(f => f.Child).Load();
Lazy Loading is already available. There are two options:
using proxy objects generated by EF Core to automagically load related entities or
use the ILazyLoader service with POCOs to load related entities when requested
Proxies
To use proxies, the DbContext has to be configured first :
.AddDbContext<BloggingContext>(
b => b.UseLazyLoadingProxies()
.UseSqlServer(myConnectionString));
After that, any properties that need to be lazy loaded have to be made virtual :
public class Blog
{
public int Id { get; set; }
public string Name { get; set; }
public virtual ICollection<Post> Posts { get; set; }
}
public class Post
{
public int Id { get; set; }
public string Title { get; set; }
public string Content { get; set; }
public virtual Blog Blog { get; set; }
}
At runtime EF will return proxy objects that inherit from the entity classes and overload the lazy properties to load the related object when first requested.
ILazyLoader service
Another option, that doesn't require inheritance, is to use POCOs and the ILazyLoader service to load the entities when needed :
public class Blog
{
private ICollection<Post> _posts;
public Blog()
{
}
private Blog(ILazyLoader lazyLoader)
{
LazyLoader = lazyLoader;
}
private ILazyLoader LazyLoader { get; set; }
public int Id { get; set; }
public string Name { get; set; }
public ICollection<Post> Posts
{
get => LazyLoader.Load(this, ref _posts);
set => _posts = value;
}
}
This adds a dependency on the ILazyLoader interface itself, which in turn adds a dependency to EF Core in domain or business models.
This can be avoided by injecting the loader as a lambda, along with some convention magic :
public class Blog
{
private ICollection<Post> _posts;
public Blog()
{
}
private Blog(Action<object, string> lazyLoader)
{
LazyLoader = lazyLoader;
}
private Action<object, string> LazyLoader { get; set; }
public int Id { get; set; }
public string Name { get; set; }
public ICollection<Post> Posts
{
get => LazyLoader.Load(this, ref _posts);
set => _posts = value;
}
}
This is used in combination with an extension method that actually calls the loader using the property's name and sets its backing field :
public static class PocoLoadingExtensions
{
public static TRelated Load<TRelated>(
this Action<object, string> loader,
object entity,
ref TRelated navigationField,
[CallerMemberName] string navigationName = null)
where TRelated : class
{
loader?.Invoke(entity, navigationName);
return navigationField;
}
}
As the docs warn:
The constructor parameter for the lazy-loading delegate must be called "lazyLoader". Configuration to use a different name than this is planned for a future release.
In Entity Framework Code First, when I declare entities I have to use DbSet<> type of properties for that. For example:
public DbSet<Product> Products { get; set; }
public DbSet<Customer> Customers { get; set; }
Recently I've met DbSet<> declared as virtual.
public virtual DbSet<Product> Products { get; set; }
public virtual DbSet<Customer> Customers { get; set; }
What is the difference? What EF functionalities is enabled?
public class AppContext : DbContext
{
public AppContext()
{
Configuration.LazyLoadingEnabled = true;
}
public virtual DbSet<AccountType> AccountTypes { get; set; }
}
public class AccountType
{
public Guid Id { get; set; }
public string Name { get; set; }
public virtual ICollection<AccountCode> AccountCodes { get; set; }
}
public class AccountCode
{
public Guid Id { get; set; }
public string Name { get; set; }
public Guid AccountTypeId { get; set; }
public virtual AccountType AccountType { get; set; }
}
The virtual keyword on the navigation properties are used to enable lazy loading mechanism, but the LazyLoadingEnabled property of the configuration must be enabled.
The virtual keyword on AccountType::AccountCodes navigation property will load all account codes the moment there is a programmatically access to that property while the db context are still alive.
using (var context = new AppContext())
{
var accountType = context.AccountTypes.FirstOrDefault();
var accountCodes = accountType.AccountCodes;
}
While the virtual keyword on the derived DbContext class (virtual DbSet<>) is used for testing purpose (mocking the DbSet property), virtual keyword in this case is not related to lazy loading.
===== update =====
Usually we are doing the testing against the service / logic, for example we have another layer for the account type service as follow. And the service accepts the db context instance using some kind of dependency injection through the constructor.
public class AccountTypeService
{
public AppContext _context;
public AccountTypeService(AppContext context)
{
_context = context;
}
public AccountType AddAccountType(string name)
{
var accountType = new AccountType { Id = Guid.NewGuid(), Name = name };
_context.AccountTypes.Add(accountType);
_context.SaveChanges();
return accountType;
}
}
And now we need to test the account type service, in this case I used mstest and automoq to create the mock class.
[TestClass]
public class AccountTypeServiceTest
{
[TestMethod]
public void AddAccountType_NormalTest()
{
// Arranges.
var accountTypes = new List<AccountType>();
var accountTypeSetMock = new Mock<DbSet<AccountType>>();
accountTypeSetMock.Setup(m => m.Add(It.IsAny<AccountType>())).Callback<AccountType>(accountType => accountTypes.Add(accountType));
var appContextMock = new Mock<AppContext>();
appContextMock.Setup(m => m.AccountTypes).Returns(accountTypeSetMock.Object);
var target = new AccountTypeService(appContextMock.Object);
// Acts.
var newAccountType = target.AddAccountType("test");
// Asserts.
accountTypeSetMock.Verify(m => m.Add(It.IsAny<AccountType>()), Times.Once());
appContextMock.Verify(m => m.SaveChanges(), Times.Once());
Assert.AreEqual(1, accountTypes.Count);
Assert.IsNotNull(newAccountType);
Assert.AreNotEqual(Guid.Empty, newAccountType.Id);
Assert.AreEqual("test", newAccountType.Name);
}
}
Note that in EF Core (currently 1.0 and 2.0) still not supporting LazyLoading scheme, so using with "virtual" or without does not make a different.
FYI. The scaffolding generate "virtual" keyword may be supporting LazyLoading technique in the future version of EF Core!
In EF Core 2.1 the developer team added support for LazyLoading.
More information is here
I have a simple BreezeController that returns a unit of work repository object. The object is a DbSet entity object of the class below:
public int OrderId { get; set; }
public string Customer { get; set; }
public virtual ICollection<OrderLine> OrderLines { get; set; }
The Unit of Work class is as follows:
private readonly EFContextProvider<ESpaDBEntities> _contextProvider;
public UoW()
{
_contextProvider = new EFContextProvider<ESpaDBEntities>();
Orders = new Repository<Order>(_contextProvider.Context);
OrderLine = new Repository<OrderLine>(_contextProvider.Context);
Products = new Repository<Product>(_contextProvider.Context);
}
public IRepository<Order> Orders { get; set; }
public IRepository<OrderLine> OrderLine { get; set; }
public IRepository<Product> Products { get; set; }
public SaveResult Commit(JObject changeSet)
{
return _contextProvider.SaveChanges(changeSet);
}
The BreezeController action is as follows:
[HttpGet]
public IQueryable<Order> Orders()
{
return uow.Orders.All();
}
When I access this method from my browser the following Json object is returned:
$id: "1",$type: "KoDurandalBreeze.DomainModel.Order, KoDurandalBreeze",OrderId: 1,Customer: "Bob",OrderLines: [ ]
For whatever reason, orderlines are not populated even though virtual is specified. Does anyone have any ideas of why the JSON object would not contain any OrderLine objects?
You will need to either perform the equivalent of an EF 'Include' on the server or if this is an EF Queryable you can call 'extend' on your client side EntityQuery, i.e.
var query = EntityQuery.from("Orders").expand("OrderDetails");
var myEntityManager.executeQuery(query).then(...)
I know this may be a simple question, but I'm pretty new to architecture and I want to do it right. So, thank you for your comprehension.
I'm also new to Castle Windsor and not used with Unit Of Work neither Repository patterns - And I even don't know if I need them to solve the problem I'm having at the moment.
What I'm trying to accomplish:
I have an interface called IDomain with just some properties and a concrete POCO class Domain that implements it.
IDomain interface:
public interface IDomain : IPersistentObject
{
int DomainId { get; set; }
string Name { get; set; }
[LocalizedString]
string ItemName { get; set; }
[LocalizedString]
string ItemDescription { get; set; }
int ItemValue { get; set; }
}
Domain POCO Class:
public class Domain : AbstractDefault, IDomain, ILocalizedEntity
{
public virtual int DomainId { get; set; }
public virtual string Name { get; set; }
[LocalizedString]
public virtual string ItemName { get; set; }
[LocalizedString]
public virtual string ItemDescription { get; set; }
public virtual int ItemValue { get; set; }
}
My DomainService.cs class does this:
public void Insert(IDomain param)
{
using (var db = new DefaultContext())
{
new DomainValidation(new DbMetaData().GetMetaData, Settings.Default.CultureName).Validate(param);
db.Domains.Add((Domain)param);
}
}
Another important info is that I'm using AOC, i.e., I'm intercepting method calls to my Domain class. See my Windsor container Installer:
public class Installers : IWindsorInstaller
{
public void Install(IWindsorContainer container, IConfigurationStore store)
{
container.Register(Component
.For<IInterceptor>()
.ImplementedBy<Class1>()
.Named("DomainInterceptor"))
.Register(Component
.For<IDomain>()
.ImplementedBy<Domain>()
.LifestyleTransient()
.Interceptors(InterceptorReference.ForKey("DomainInterceptor")).Anywhere);
}
}
In my Unit Test I am doing:
var domain = container.Resolve<IDomain>(); // Returns IDomainProxy, not IDomain
domain.Name = "MIN_MAX";
domain.ItemName = new LocalizedProperty("en-US", "Mininum").Serialize();
domain.ItemValue = (int)MinMax.Minimum;
new DomainService().Insert(domain); // If I try to cast by doing .Insert(domain as Domain), I get a null
But when my code reaches the ".Add(Domain)param)" (DomainService.cs) I get the error: "Unable to cast object of type 'Castle.Proxies.IDomainProxy' to type 'Model.Domain'."
Why am I getting this error and how am I supposed to fix it, considering that I do want to use IoC, Windsor, etc?
Best regards.
In those situations Castle Windsor creates new instances with a "proxy" interface. I ended up using AutoMapper in my Service class.
From what I understand on several posts the TPT architecure, with EF, does not create the necessary ON DELETE CASCADE when using a shared primary key.... It was also said that the EF context will handle the proper order of deletion of the sub-classed tables (however I do get an error that it breaks the constraint and that I can fix it with adding the ON DELETE CASCADE on the sub-class table)...
more background info...
I have a Section class, which has a number, title, and a list of pages. The page is designed using a super class which holds basic page properties. I have about 10+ sub-classes of the page class. The Section class holds an ICollection of these pages. The DB is created properly with the exception of no ON DELETE CASCADE on the sub-classed tables.
My code will create the entities and adds to the DB fine. However, if I try to delete a section (or all sections) it fails todelete due to the FK constraint on my sub-class page table...
public abstract BaseContent
{
... common properties which are Ignored in the DB ...
}
public class Course : BaseContent
{
public int Id {get;set;}
public string Name {get;set;}
public string Descripiton {get;set;}
public virtual ICollection<Chapter> Chapters{get;set;}
...
}
public class Chapter : BaseContent
{
public int Id {get;set;}
public int Number {get;set;}
public string Title {get;set;}
public virtual Course MyCourse{get;set;}
public virtual ICollection<Section> Sections{get;set;}
...
}
public class Section : BaseContent
{
public int Id {get;set;}
public int Number {get;set;}
public string Title {get;set;}
public virtual Chapter MyChapter {get;set;}
public virtual ICollection<BasePage> Pages {get;set;}
...
}
public abstract class BasePage : BaseContent, IComparable
{
public int Id { get; set; }
public string Title { get; set; }
public string PageImageRef { get; set; }
public ePageImageLocation ImageLocationOnPage { get; set; }
public int PageNumber { get; set; }
public virtual Section MySection { get; set; }
...
}
public class ChapterPage : BasePage
{
public virtual int ChapterNumber { get; set; }
public virtual string ChapterTitle { get; set; }
public virtual string AudioRef { get; set; }
}
public class SectionPage : BasePage
{
public virtual int SectionNumber { get; set; }
public virtual string SectionTitle { get; set; }
public virtual string SectionIntroduction { get; set; }
}
... plus about 8 other BasePage sub-classes...
public class MyContext: DbContext
{
...
public DbSet<Course> Courses { get; set; }
public DbSet<Chapter> Chapters { get; set; }
public DbSet<Section> Sections { get; set; }
public DbSet<BasePage> Pages { get; set; }
...
}
.. Fluent API ... (note Schema is defined to "" for SqlServer, for Oracle its the schema name)
private EntityTypeConfiguration<T> configureTablePerType<T>(string tableName) where T : BaseContent
{
var config = new EntityTypeConfiguration<T>();
config.ToTable(tableName, Schema);
// This adds the appropriate Ignore calls on config for the base class BaseContent
DataAccessUtilityClass.IgnoreAllBaseContentProperties<T>(config);
return config;
}
public virtual EntityTypeConfiguration<BasePage> ConfigurePageContent()
{
var config = configureTablePerType<BasePage>("PageContent");
config.HasKey(pg => pg.Id);
config.HasRequired(pg => pg.Title);
config.HasOptional(pg => pg.PageImageRef);
config.Ignore(pg => pg.ImageLocationOnPage);
return config;
}
public virtual EntityTypeConfiguration<ChapterPage> ConfigureChapterPage()
{
var config = configureTablePerType<ChapterPage>("ChapterPage");
config.HasOptional(pg => pg.AudioRef);
config.Ignore(pg => pg.ChapterNumber);
config.Ignore(pg => pg.ChapterTitle);
return config;
}
public virtual EntityTypeConfiguration<SectionPage> ConfigureSectionPage()
{
var config = configureTablePerType<SectionPage>("SectionPage");
config.HasOptional(pg => pg.AudioRef);
config.Ignore(pg => pg.SectionNumber);
config.Ignore(pg => pg.SectionTitle);
return config;
}
... other code to model other tables...
So the app is able to populate content and the relationships are properly set up. However, when I try to delete the course, I get the error that the delete failed due to the constraint on the ChapterPage to PageContent table..
Here is the code which deletes the Course (actually I delete all courses)...
using (MyContext ctx = new MyContext())
{
ctx.Courses.ToList().ForEach(crs => ctx.Courses.Remove(crs));
AttachLookupEntities(ctx);
ctx.SaveChanges();
}
If I add the 'ON DELETE CASCADE' in the ChapterPage and SectionPage table for its shared primary with PageContent, the delete goes through.
In summary,
The only solution that I have seen is to manually alter the constraints to add the ON DELETE CASCADE for all of my sub-class page tables. I can implement the change, as I have code which generates the DB script for the EF tables I need (a small subset of our whole DB) since we will not use EF to create or instantiate the DB (since it does not properly support migrations as yet...).
I sincerely hope that I have miscoded something, or forgot some setting in the model builder logic. Because if not, the EF designers have defined an architecure (TPT design approach) which cannot be used in any real world situation without a hack workaround. It's a half finished solution. Do not get me wrong, I like the work that has been done, and like most MSFT solutions its works for 70% of most basic application usages. It just is not ready for more complex situations.
I was trying to keep the DB design all within the EF fluent API and self-contained. It's about 98% there for me, just would be nice if they finished the job, maybe in the next release. At least it saves me all the CRUD operations.
Ciao!
Jim Shaw
I have reproduced the problem with a little bit simpler example:
using System;
using System.Collections.Generic;
using System.Linq;
using System.Data.Entity;
namespace EFTPT
{
public class Parent
{
public int Id { get; set; }
public string Name { get; set; }
public ICollection<BasePage> Pages { get; set; }
}
public abstract class BasePage
{
public int Id { get; set; }
public string Name { get; set; }
public Parent Parent { get; set; }
}
public class DerivedPage : BasePage
{
public string DerivedName { get; set; }
}
public class MyContext : DbContext
{
public DbSet<Parent> Parents { get; set; }
public DbSet<BasePage> BasePages { get; set; }
protected override void OnModelCreating(DbModelBuilder modelBuilder)
{
modelBuilder.Entity<Parent>()
.HasMany(p => p.Pages)
.WithRequired(p => p.Parent); // creates casc. delete in DB
modelBuilder.Entity<BasePage>()
.ToTable("BasePages");
modelBuilder.Entity<DerivedPage>()
.ToTable("DerivedPages");
}
}
class Program
{
static void Main(string[] args)
{
using (var ctx = new MyContext())
{
var parent = new Parent { Pages = new List<BasePage>() };
var derivedPage = new DerivedPage();
parent.Pages.Add(derivedPage);
ctx.Parents.Add(parent);
ctx.SaveChanges();
}
using (var ctx = new MyContext())
{
var parent = ctx.Parents.FirstOrDefault();
ctx.Parents.Remove(parent);
ctx.SaveChanges(); // exception here
}
}
}
}
This gives the same exception that you had too. Only solutions seem to be:
Either setup cascading delete for the TPT constraint in the DB manually, as you already tested (or put an appropriate SQL command into the Seed method).
Or load the entites which are involved in the TPT inheritance into memory. In my example code:
var parent = ctx.Parents.Include(p => p.Pages).FirstOrDefault();
When the entities are loaded into the context, EF creates actually two DELETE statements - one for the base table and one for the derived table. In your case, this is a terrible solution because you had to load a much more complex object graph before you can get the TPT entities.
Even more problematic is if Parent has an ICollection<DerivedPage> (and the inverse Parent property is in DerivedPage then):
public class Parent
{
public int Id { get; set; }
public string Name { get; set; }
public ICollection<DerivedPage> Pages { get; set; }
}
public abstract class BasePage
{
public int Id { get; set; }
public string Name { get; set; }
}
public class DerivedPage : BasePage
{
public string DerivedName { get; set; }
public Parent Parent { get; set; }
}
The example code wouldn't throw an exception but instead delete the row from the derived table but not from the base table, leaving a phantom row which cannot represent an entity anymore because BasePage is abstract. This problem is not solvable by a cascading delete but you were actually forced to load the collection into the context before you can delete the parent to avoid such a nonsense in the database.
A similar question and analysis was here: http://social.msdn.microsoft.com/Forums/en-US/adodotnetentityframework/thread/3c27d761-4d0a-4704-85f3-8566fa37d14e/