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DbContext Lifetime, Configuration, and Initialization

This article shows basic patterns for initialization and configuration of a DbContext instance.

Warning

This article uses a local database that doesn't require the user to be authenticated. Production apps should use the most secure authentication flow available. For more information on authentication for deployed test and production apps, see Secure authentication flows.

The DbContext lifetime

The lifetime of a DbContext begins when the instance is created and ends when the instance is disposed. A DbContext instance is designed to be used for a single unit-of-work. This means that the lifetime of a DbContext instance is usually very short.

Tip

To quote Martin Fowler from the link above, "A Unit of Work keeps track of everything you do during a business transaction that can affect the database. When you're done, it figures out everything that needs to be done to alter the database as a result of your work."

A typical unit-of-work when using Entity Framework Core (EF Core) involves:

Important

  • It is important to dispose the DbContext after use. This ensures any:
    • Unmanaged resources are freed.
    • Events or other hooks are unregistered. Unregistering prevents memory leaks when the instance remains referenced.
  • DbContext is Not thread-safe. Don't share contexts between threads. Make sure to await all async calls before continuing to use the context instance.
  • An InvalidOperationException thrown by EF Core code can put the context into an unrecoverable state. Such exceptions indicate a program error and are not designed to be recovered from.

DbContext in dependency injection for ASP.NET Core

In many web applications, each HTTP request corresponds to a single unit-of-work. This makes tying the context lifetime to that of the request a good default for web applications.

ASP.NET Core applications are configured using dependency injection. EF Core can be added to this configuration using AddDbContext in Program.cs. For example:

var connectionString =
    builder.Configuration.GetConnectionString("DefaultConnection")
        ?? throw new InvalidOperationException("Connection string"
        + "'DefaultConnection' not found.");

builder.Services.AddDbContext<ApplicationDbContext>(options =>
    options.UseSqlServer(connectionString));

The preceding code registers ApplicationDbContext, a subclass of DbContext, as a scoped service in the ASP.NET Core app service provider. The service provider is also known as the dependency injection container. The context is configured to use the SQL Server database provider and reads the connection string from ASP.NET Core configuration.

The ApplicationDbContext class must expose a public constructor with a DbContextOptions<ApplicationDbContext> parameter. This is how context configuration from AddDbContext is passed to the DbContext. For example:

public class ApplicationDbContext : DbContext
{
    public ApplicationDbContext(DbContextOptions<ApplicationDbContext> options)
        : base(options)
    {
    }
}

ApplicationDbContext can be used in ASP.NET Core controllers or other services through constructor injection:

public class MyController
{
    private readonly ApplicationDbContext _context;

    public MyController(ApplicationDbContext context)
    {
        _context = context;
    }
}

The final result is an ApplicationDbContext instance created for each request and passed to the controller to perform a unit-of-work before being disposed when the request ends.

Read further in this article to learn more about configuration options. See Dependency injection in ASP.NET Core for more information.

Basic DbContext initialization with 'new'

DbContext instances can be constructed with new in C#. Configuration can be performed by overriding the OnConfiguring method, or by passing options to the constructor. For example:

public class ApplicationDbContext : DbContext
{
    protected override void OnConfiguring(DbContextOptionsBuilder optionsBuilder)
    {
        optionsBuilder.UseSqlServer(
            @"Server=(localdb)\mssqllocaldb;Database=Test;ConnectRetryCount=0");
    }
}

This pattern also makes it easy to pass configuration like the connection string via the DbContext constructor. For example:

public class ApplicationDbContext : DbContext
{
    private readonly string _connectionString;

    public ApplicationDbContext(string connectionString)
    {
        _connectionString = connectionString;
    }

    protected override void OnConfiguring(DbContextOptionsBuilder optionsBuilder)
    {
        optionsBuilder.UseSqlServer(_connectionString);
    }
}

Alternately, DbContextOptionsBuilder can be used to create a DbContextOptions object that is then passed to the DbContext constructor. This allows a DbContext configured for dependency injection to also be constructed explicitly. For example, when using ApplicationDbContext defined for ASP.NET Core web apps above:

public class ApplicationDbContext : DbContext
{
    public ApplicationDbContext(DbContextOptions<ApplicationDbContext> options)
        : base(options)
    {
    }
}

The DbContextOptions can be created and the constructor can be called explicitly:

var contextOptions = new DbContextOptionsBuilder<ApplicationDbContext>()
    .UseSqlServer(@"Server=(localdb)\mssqllocaldb;Database=Test;ConnectRetryCount=0")
    .Options;

using var context = new ApplicationDbContext(contextOptions);

Use a DbContext factory

Some application types (e.g. ASP.NET Core Blazor) use dependency injection but do not create a service scope that aligns with the desired DbContext lifetime. Even where such an alignment does exist, the application may need to perform multiple units-of-work within this scope. For example, multiple units-of-work within a single HTTP request.

In these cases, AddDbContextFactory can be used to register a factory for creation of DbContext instances. For example:

public void ConfigureServices(IServiceCollection services)
{
    services.AddDbContextFactory<ApplicationDbContext>(
        options => options.UseSqlServer(
            @"Server=(localdb)\mssqllocaldb;Database=Test;ConnectRetryCount=0"));
}

The ApplicationDbContext class must expose a public constructor with a DbContextOptions<ApplicationDbContext> parameter. This is the same pattern as used in the traditional ASP.NET Core section above.

public class ApplicationDbContext : DbContext
{
    public ApplicationDbContext(DbContextOptions<ApplicationDbContext> options)
        : base(options)
    {
    }
}

The DbContextFactory factory can then be used in other services through constructor injection. For example:

private readonly IDbContextFactory<ApplicationDbContext> _contextFactory;

public MyController(IDbContextFactory<ApplicationDbContext> contextFactory)
{
    _contextFactory = contextFactory;
}

The injected factory can then be used to construct DbContext instances in the service code. For example:

public void DoSomething()
{
    using (var context = _contextFactory.CreateDbContext())
    {
        // ...
    }
}

Notice that the DbContext instances created in this way are not managed by the application's service provider and therefore must be disposed by the application.

See ASP.NET Core Blazor Server with Entity Framework Core for more information on using EF Core with Blazor.

DbContextOptions

The starting point for all DbContext configuration is DbContextOptionsBuilder. There are three ways to get this builder:

  • In AddDbContext and related methods
  • In OnConfiguring
  • Constructed explicitly with new

Examples of each of these are shown in the preceding sections. The same configuration can be applied regardless of where the builder comes from. In addition, OnConfiguring is always called regardless of how the context is constructed. This means OnConfiguring can be used to perform additional configuration even when AddDbContext is being used.

Configuring the database provider

Each DbContext instance must be configured to use one and only one database provider. (Different instances of a DbContext subtype can be used with different database providers, but a single instance must only use one.) A database provider is configured using a specific Use* call. For example, to use the SQL Server database provider:

public class ApplicationDbContext : DbContext
{
    protected override void OnConfiguring(DbContextOptionsBuilder optionsBuilder)
    {
        optionsBuilder.UseSqlServer(
            @"Server=(localdb)\mssqllocaldb;Database=Test;ConnectRetryCount=0");
    }
}

These Use* methods are extension methods implemented by the database provider. This means that the database provider NuGet package must be installed before the extension method can be used.

Tip

EF Core database providers make extensive use of extension methods. If the compiler indicates that a method cannot be found, then make sure that the provider's NuGet package is installed and that you have using Microsoft.EntityFrameworkCore; in your code.

The following table contains examples for common database providers.

Database system Example configuration NuGet package
SQL Server or Azure SQL .UseSqlServer(connectionString) Microsoft.EntityFrameworkCore.SqlServer
Azure Cosmos DB .UseCosmos(connectionString, databaseName) Microsoft.EntityFrameworkCore.Cosmos
SQLite .UseSqlite(connectionString) Microsoft.EntityFrameworkCore.Sqlite
EF Core in-memory database .UseInMemoryDatabase(databaseName) Microsoft.EntityFrameworkCore.InMemory
PostgreSQL* .UseNpgsql(connectionString) Npgsql.EntityFrameworkCore.PostgreSQL
MySQL/MariaDB* .UseMySql(connectionString) Pomelo.EntityFrameworkCore.MySql
Oracle* .UseOracle(connectionString) Oracle.EntityFrameworkCore

*These database providers are not shipped by Microsoft. See Database Providers for more information about database providers.

Warning

The EF Core in-memory database is not designed for production use. In addition, it may not be the best choice even for testing. See Testing Code That Uses EF Core for more information.

See Connection Strings for more information on using connection strings with EF Core.

Optional configuration specific to the database provider is performed in an additional provider-specific builder. For example, using EnableRetryOnFailure to configure retries for connection resiliency when connecting to Azure SQL:

public class ApplicationDbContext : DbContext
{
    protected override void OnConfiguring(DbContextOptionsBuilder optionsBuilder)
    {
        optionsBuilder
            .UseSqlServer(
                @"Server=(localdb)\mssqllocaldb;Database=Test",
                providerOptions => { providerOptions.EnableRetryOnFailure(); });
    }
}

Tip

The same database provider is used for SQL Server and Azure SQL. However, it is recommended that connection resiliency be used when connecting to SQL Azure.

See Database Providers for more information on provider-specific configuration.

Other DbContext configuration

Other DbContext configuration can be chained either before or after (it makes no difference which) the Use* call. For example, to turn on sensitive-data logging:

public class ApplicationDbContext : DbContext
{
    protected override void OnConfiguring(DbContextOptionsBuilder optionsBuilder)
    {
        optionsBuilder
            .EnableSensitiveDataLogging()
            .UseSqlServer(@"Server=(localdb)\mssqllocaldb;Database=Test;ConnectRetryCount=0");
    }
}

The following table contains examples of common methods called on DbContextOptionsBuilder.

DbContextOptionsBuilder method What it does Learn more
UseQueryTrackingBehavior Sets the default tracking behavior for queries Query Tracking Behavior
LogTo A simple way to get EF Core logs Logging, Events, and Diagnostics
UseLoggerFactory Registers an Microsoft.Extensions.Logging factory Logging, Events, and Diagnostics
EnableSensitiveDataLogging Includes application data in exceptions and logging Logging, Events, and Diagnostics
EnableDetailedErrors More detailed query errors (at the expense of performance) Logging, Events, and Diagnostics
ConfigureWarnings Ignore or throw for warnings and other events Logging, Events, and Diagnostics
AddInterceptors Registers EF Core interceptors Logging, Events, and Diagnostics
UseLazyLoadingProxies Use dynamic proxies for lazy-loading Lazy Loading
UseChangeTrackingProxies Use dynamic proxies for change-tracking Coming soon...

Note

UseLazyLoadingProxies and UseChangeTrackingProxies are extension methods from the Microsoft.EntityFrameworkCore.Proxies NuGet package. This kind of ".UseSomething()" call is the recommended way to configure and/or use EF Core extensions contained in other packages.

DbContextOptions versus DbContextOptions<TContext>

Most DbContext subclasses that accept a DbContextOptions should use the generic DbContextOptions<TContext> variation. For example:

public sealed class SealedApplicationDbContext : DbContext
{
    public SealedApplicationDbContext(DbContextOptions<SealedApplicationDbContext> contextOptions)
        : base(contextOptions)
    {
    }
}

This ensures that the correct options for the specific DbContext subtype are resolved from dependency injection, even when multiple DbContext subtypes are registered.

Tip

Your DbContext does not need to be sealed, but sealing is best practice to do so for classes not designed to be inherited from.

However, if the DbContext subtype is itself intended to be inherited from, then it should expose a protected constructor taking a non-generic DbContextOptions. For example:

public abstract class ApplicationDbContextBase : DbContext
{
    protected ApplicationDbContextBase(DbContextOptions contextOptions)
        : base(contextOptions)
    {
    }
}

This allows multiple concrete subclasses to call this base constructor using their different generic DbContextOptions<TContext> instances. For example:

public sealed class ApplicationDbContext1 : ApplicationDbContextBase
{
    public ApplicationDbContext1(DbContextOptions<ApplicationDbContext1> contextOptions)
        : base(contextOptions)
    {
    }
}

public sealed class ApplicationDbContext2 : ApplicationDbContextBase
{
    public ApplicationDbContext2(DbContextOptions<ApplicationDbContext2> contextOptions)
        : base(contextOptions)
    {
    }
}

Notice that this is exactly the same pattern as when inheriting from DbContext directly. That is, the DbContext constructor itself accepts a non-generic DbContextOptions for this reason.

A DbContext subclass intended to be both instantiated and inherited from should expose both forms of constructor. For example:

public class ApplicationDbContext : DbContext
{
    public ApplicationDbContext(DbContextOptions<ApplicationDbContext> contextOptions)
        : base(contextOptions)
    {
    }

    protected ApplicationDbContext(DbContextOptions contextOptions)
        : base(contextOptions)
    {
    }
}

Design-time DbContext configuration

EF Core design-time tools such as those for EF Core migrations need to be able to discover and create a working instance of a DbContext type in order to gather details about the application's entity types and how they map to a database schema. This process can be automatic as long as the tool can easily create the DbContext in such a way that it will be configured similarly to how it would be configured at run-time.

While any pattern that provides the necessary configuration information to the DbContext can work at run-time, tools that require using a DbContext at design-time can only work with a limited number of patterns. These are covered in more detail in Design-Time Context Creation.

Avoiding DbContext threading issues

Entity Framework Core does not support multiple parallel operations being run on the same DbContext instance. This includes both parallel execution of async queries and any explicit concurrent use from multiple threads. Therefore, always await async calls immediately, or use separate DbContext instances for operations that execute in parallel.

When EF Core detects an attempt to use a DbContext instance concurrently, you'll see an InvalidOperationException with a message like this:

A second operation started on this context before a previous operation completed. This is usually caused by different threads using the same instance of DbContext, however instance members are not guaranteed to be thread safe.

When concurrent access goes undetected, it can result in undefined behavior, application crashes and data corruption.

There are common mistakes that can inadvertently cause concurrent access on the same DbContext instance:

Asynchronous operation pitfalls

Asynchronous methods enable EF Core to initiate operations that access the database in a non-blocking way. But if a caller does not await the completion of one of these methods, and proceeds to perform other operations on the DbContext, the state of the DbContext can be, (and very likely will be) corrupted.

Always await EF Core asynchronous methods immediately.

Implicitly sharing DbContext instances via dependency injection

The AddDbContext extension method registers DbContext types with a scoped lifetime by default.

This is safe from concurrent access issues in most ASP.NET Core applications because there is only one thread executing each client request at a given time, and because each request gets a separate dependency injection scope (and therefore a separate DbContext instance). For Blazor Server hosting model, one logical request is used for maintaining the Blazor user circuit, and thus only one scoped DbContext instance is available per user circuit if the default injection scope is used.

Any code that explicitly executes multiple threads in parallel should ensure that DbContext instances aren't ever accessed concurrently.

Using dependency injection, this can be achieved by either registering the context as scoped, and creating scopes (using IServiceScopeFactory) for each thread, or by registering the DbContext as transient (using the overload of AddDbContext which takes a ServiceLifetime parameter).

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