.NET Core开发日志——依赖注入
依赖注入(DI)不是一个新的话题,它的出现是伴随着系统解耦的需要而几乎必然产生的。
在SOLID设计原则中,DIP(Dependency inversion principle)——依赖倒置,规定了“需依赖抽象,而非实现”的准则,该原则主要目的是通过引入抽象(比如接口)的方式降低模块之间的耦合性。与此原则相拟而又有所不同的是IoC(inversion of control)——控制反转设计原则。这项原则定义了应该由通用框架而非外部代码决定控制流(control flow)的概念。对控制反转的实现有数种技术,DI(Dependency injection)——依赖注入便是其中之一,而依赖注入技术同时又支持依赖倒置的设计原则,所以它被广泛使用并不是件令人意外的事情。
依赖注入的基本特性是借由一个对象提供对另一对象的依赖。这样的一个对象通常又被称为容器。容器负责被依赖对象的注册(register),解析(resolve)与释放(release),并具有将被依赖对象注入到依赖对象内部的功能。
在之前的ASP.NET开发过程中,要想使用到依赖注入技术必需依赖第三方类库,而在ASP.NET Core中,这项技术已经被引入到其自身的框架中。
容器
ASP.NET Core中使用ServiceProvider作为依赖注入的容器,它是在WebHostBuilder类中被引入的。
public IWebHost Build()
{
...
IServiceProvider GetProviderFromFactory(IServiceCollection collection)
{
var provider = collection.BuildServiceProvider();
var factory = provider.GetService<IServiceProviderFactory<IServiceCollection>>();
if (factory != null)
{
using (provider)
{
return factory.CreateServiceProvider(factory.CreateBuilder(collection));
}
}
return provider;
}
}
注册
所需依赖的对象通过ServiceCollectionServiceExtensions中的各种扩展方法被加入到ServiceCollection类中。ServiceCollection类内部维护着一个ServiceDescriptor集合。而ServiceCollection又会被传入ServiceProvider的构造方法。
public static IServiceCollection AddTransient(
this IServiceCollection services,
Type serviceType,
Type implementationType)
{
...
return Add(services, serviceType, implementationType, ServiceLifetime.Transient);
}
public static IServiceCollection AddScoped(
this IServiceCollection services,
Type serviceType,
Type implementationType)
{
...
return Add(services, serviceType, implementationType, ServiceLifetime.Scoped);
}
public static IServiceCollection AddSingleton(
this IServiceCollection services,
Type serviceType,
Type implementationType)
{
...
return Add(services, serviceType, implementationType, ServiceLifetime.Singleton);
}
private static IServiceCollection Add(
IServiceCollection collection,
Type serviceType,
Type implementationType,
ServiceLifetime lifetime)
{
var descriptor = new ServiceDescriptor(serviceType, implementationType, lifetime);
collection.Add(descriptor);
return collection;
}
解析
要想获得已注册的对象,可以通过ServiceProviderServiceExtensions类的扩展方法GetService。
public static T GetService<T>(this IServiceProvider provider)
{
if (provider == null)
{
throw new ArgumentNullException(nameof(provider));
}
return (T)provider.GetService(typeof(T));
}
ServiceProvider的GetService方法其实是调用了它内部各种引擎的父类ServiceProviderEngine的方法。这些引擎间区别在于实现方式以及性能上,功能方面都是一样的。默认引擎是DynamicServiceProviderEngine。
private readonly IServiceProviderEngine _engine;
internal ServiceProvider(IEnumerable<ServiceDescriptor> serviceDescriptors, ServiceProviderOptions options)
{
IServiceProviderEngineCallback callback = null;
if (options.ValidateScopes)
{
callback = this;
_callSiteValidator = new CallSiteValidator();
}
switch (options.Mode)
{
case ServiceProviderMode.Dynamic:
_engine = new DynamicServiceProviderEngine(serviceDescriptors, callback);
break;
case ServiceProviderMode.Runtime:
_engine = new RuntimeServiceProviderEngine(serviceDescriptors, callback);
break;
#if IL_EMIT
case ServiceProviderMode.ILEmit:
_engine = new ILEmitServiceProviderEngine(serviceDescriptors, callback);
break;
#endif
case ServiceProviderMode.Expressions:
_engine = new ExpressionsServiceProviderEngine(serviceDescriptors, callback);
break;
default:
throw new NotSupportedException(nameof(options.Mode));
}
}
public object GetService(Type serviceType) => _engine.GetService(serviceType);
ServiceProviderEngine类的CreateServiceAccessor方法创建了CallSite。
internal object GetService(Type serviceType, ServiceProviderEngineScope serviceProviderEngineScope)
{
if (_disposed)
{
ThrowHelper.ThrowObjectDisposedException();
}
var realizedService = RealizedServices.GetOrAdd(serviceType, _createServiceAccessor);
_callback?.OnResolve(serviceType, serviceProviderEngineScope);
return realizedService.Invoke(serviceProviderEngineScope);
}
private Func<ServiceProviderEngineScope, object> CreateServiceAccessor(Type serviceType)
{
var callSite = CallSiteFactory.CreateCallSite(serviceType, new CallSiteChain());
if (callSite != null)
{
_callback?.OnCreate(callSite);
return RealizeService(callSite);
}
return _ => null;
}
假设注册是用的public static IServiceCollection AddSingleton(this IServiceCollection services, Type serviceType, Type implementationType)
方法,那么之后的处理会生成一个SingletonCallSite对象并且包含ConstructorCallSite参数值。
private IServiceCallSite TryCreateExact(ServiceDescriptor descriptor, Type serviceType, CallSiteChain callSiteChain)
{
if (serviceType == descriptor.ServiceType)
{
IServiceCallSite callSite;
if (descriptor.ImplementationInstance != null)
{
callSite = new ConstantCallSite(descriptor.ServiceType, descriptor.ImplementationInstance);
}
else if (descriptor.ImplementationFactory != null)
{
callSite = new FactoryCallSite(descriptor.ServiceType, descriptor.ImplementationFactory);
}
else if (descriptor.ImplementationType != null)
{
callSite = CreateConstructorCallSite(descriptor.ServiceType, descriptor.ImplementationType, callSiteChain);
}
else
{
throw new InvalidOperationException("Invalid service descriptor");
}
return ApplyLifetime(callSite, descriptor, descriptor.Lifetime);
}
return null;
}
private IServiceCallSite CreateConstructorCallSite(Type serviceType, Type implementationType, CallSiteChain callSiteChain)
{
callSiteChain.Add(serviceType, implementationType);
var constructors = implementationType.GetTypeInfo()
.DeclaredConstructors
.Where(constructor => constructor.IsPublic)
.ToArray();
IServiceCallSite[] parameterCallSites = null;
if (constructors.Length == 0)
{
throw new InvalidOperationException(Resources.FormatNoConstructorMatch(implementationType));
}
else if (constructors.Length == 1)
{
var constructor = constructors[0];
var parameters = constructor.GetParameters();
if (parameters.Length == 0)
{
return new CreateInstanceCallSite(serviceType, implementationType);
}
parameterCallSites = CreateArgumentCallSites(
serviceType,
implementationType,
callSiteChain,
parameters,
throwIfCallSiteNotFound: true);
return new ConstructorCallSite(serviceType, constructor, parameterCallSites);
}
...
}
private IServiceCallSite ApplyLifetime(IServiceCallSite serviceCallSite, object cacheKey, ServiceLifetime descriptorLifetime)
{
if (serviceCallSite is ConstantCallSite)
{
return serviceCallSite;
}
switch (descriptorLifetime)
{
case ServiceLifetime.Transient:
return new TransientCallSite(serviceCallSite);
case ServiceLifetime.Scoped:
return new ScopedCallSite(serviceCallSite, cacheKey);
case ServiceLifetime.Singleton:
return new SingletonCallSite(serviceCallSite, cacheKey);
default:
throw new ArgumentOutOfRangeException(nameof(descriptorLifetime));
}
}
ServiceProvider真正解析的是这个生成出来的CallSite对象。
protected override Func<ServiceProviderEngineScope, object> RealizeService(IServiceCallSite callSite)
{
var callCount = 0;
return scope =>
{
if (Interlocked.Increment(ref callCount) == 2)
{
Task.Run(() => base.RealizeService(callSite));
}
return RuntimeResolver.Resolve(callSite, scope);
};
}
public object Resolve(IServiceCallSite callSite, ServiceProviderEngineScope scope)
{
return VisitCallSite(callSite, scope);
}
protected virtual TResult VisitCallSite(IServiceCallSite callSite, TArgument argument)
{
switch (callSite.Kind)
{
case CallSiteKind.Factory:
return VisitFactory((FactoryCallSite)callSite, argument);
case CallSiteKind.IEnumerable:
return VisitIEnumerable((IEnumerableCallSite)callSite, argument);
case CallSiteKind.Constructor:
return VisitConstructor((ConstructorCallSite)callSite, argument);
case CallSiteKind.Transient:
return VisitTransient((TransientCallSite)callSite, argument);
case CallSiteKind.Singleton:
return VisitSingleton((SingletonCallSite)callSite, argument);
case CallSiteKind.Scope:
return VisitScoped((ScopedCallSite)callSite, argument);
case CallSiteKind.Constant:
return VisitConstant((ConstantCallSite)callSite, argument);
case CallSiteKind.CreateInstance:
return VisitCreateInstance((CreateInstanceCallSite)callSite, argument);
case CallSiteKind.ServiceProvider:
return VisitServiceProvider((ServiceProviderCallSite)callSite, argument);
case CallSiteKind.ServiceScopeFactory:
return VisitServiceScopeFactory((ServiceScopeFactoryCallSite)callSite, argument);
default:
throw new NotSupportedException($"Call site type {callSite.GetType()} is not supported");
}
}
因为上例中CallSite的类型是Constructor,所以最终通过VisitConstructor方法获得所依赖的对象。
protected override object VisitConstructor(ConstructorCallSite constructorCallSite, ServiceProviderEngineScope scope)
{
object[] parameterValues = new object[constructorCallSite.ParameterCallSites.Length];
for (var index = 0; index < parameterValues.Length; index++)
{
parameterValues[index] = VisitCallSite(constructorCallSite.ParameterCallSites[index], scope);
}
try
{
return constructorCallSite.ConstructorInfo.Invoke(parameterValues);
}
catch (Exception ex) when (ex.InnerException != null)
{
ExceptionDispatchInfo.Capture(ex.InnerException).Throw();
// The above line will always throw, but the compiler requires we throw explicitly.
throw;
}
}
至于创建对象的方法是用反射,表达式树(Expression Tree)还是IL Emit,则取决于所使用的内部引擎。
释放
创建ServiceProviderEngine的时候会为其Root属性绑定ServiceProviderEngineScope类型的值,Root = new ServiceProviderEngineScope(this);
。
在ServiceProviderEngineScope类内部有着用于释放资源的Dispose方法。
public void Dispose()
{
lock (ResolvedServices)
{
if (_disposed)
{
return;
}
_disposed = true;
if (_disposables != null)
{
for (var i = _disposables.Count - 1; i >= 0; i--)
{
var disposable = _disposables[i];
disposable.Dispose();
}
_disposables.Clear();
}
ResolvedServices.Clear();
}
}
internal object CaptureDisposable(object service)
{
_captureDisposableCallback?.Invoke(service);
if (!ReferenceEquals(this, service))
{
if (service is IDisposable disposable)
{
lock (ResolvedServices)
{
if (_disposables == null)
{
_disposables = new List<IDisposable>();
}
_disposables.Add(disposable);
}
}
}
return service;
}
并不是所有对象都会通过ServiceProvider容器释放资源,只有容器自己创建的才可以。如果是新建对象再传入容器,容器不会为其作处理。
public void ConfigureServices(IServiceCollection services)
{
// 容器创建了实例所以会释放它。
services.AddScoped<Service1>();
services.AddSingleton<Service2>();
services.AddSingleton<ISomeService>(sp => new SomeServiceImplementation());
// 容器没有创建实例所以不会释放它。
services.AddSingleton<Service3>(new Service3());
services.AddSingleton(new Service3());
}
注入
ASP.NET Core中最常用的是Constructor Inject(构造器注入)方式。在其MVC框架中,通过DefaultControllerActivator生成Controller时,就可以跟踪到依赖注入是如何被其使用的。
public virtual object Create(ControllerContext controllerContext)
{
...
var serviceProvider = controllerContext.HttpContext.RequestServices;
return _typeActivatorCache.CreateInstance<object>(serviceProvider, controllerTypeInfo.AsType());
}
DefaultControllerActivator的Create方法使用了TypeActivatorCache类,其内部用到了ActivatorUtilities.CreateFactory方法。
public class TypeActivatorCache : ITypeActivatorCache
{
private readonly Func<Type, ObjectFactory> _createFactory =
(type) => ActivatorUtilities.CreateFactory(type, Type.EmptyTypes);
private readonly ConcurrentDictionary<Type, ObjectFactory> _typeActivatorCache =
new ConcurrentDictionary<Type, ObjectFactory>();
public TInstance CreateInstance<TInstance>(
IServiceProvider serviceProvider,
Type implementationType)
{
...
var createFactory = _typeActivatorCache.GetOrAdd(implementationType, _createFactory);
return (TInstance)createFactory(serviceProvider, arguments: null);
}
}
ActivatorUtilities类位于ServiceProvider同样的程序集中。
public static ObjectFactory CreateFactory(Type instanceType, Type[] argumentTypes)
{
FindApplicableConstructor(instanceType, argumentTypes, out ConstructorInfo constructor, out int?[] parameterMap);
var provider = Expression.Parameter(typeof(IServiceProvider), "provider");
var argumentArray = Expression.Parameter(typeof(object[]), "argumentArray");
var factoryExpressionBody = BuildFactoryExpression(constructor, parameterMap, provider, argumentArray);
var factoryLamda = Expression.Lambda<Func<IServiceProvider, object[], object>>(
factoryExpressionBody, provider, argumentArray);
var result = factoryLamda.Compile();
return result.Invoke;
}
留意BuildFactoryExpression方法中GetServiceInfo变量。
private static Expression BuildFactoryExpression(
ConstructorInfo constructor,
int?[] parameterMap,
Expression serviceProvider,
Expression factoryArgumentArray)
{
var constructorParameters = constructor.GetParameters();
var constructorArguments = new Expression[constructorParameters.Length];
for (var i = 0; i < constructorParameters.Length; i++)
{
var constructorParameter = constructorParameters[i];
var parameterType = constructorParameter.ParameterType;
var hasDefaultValue = ParameterDefaultValue.TryGetDefaultValue(constructorParameter, out var defaultValue);
if (parameterMap[i] != null)
{
constructorArguments[i] = Expression.ArrayAccess(factoryArgumentArray, Expression.Constant(parameterMap[i]));
}
else
{
var parameterTypeExpression = new Expression[] { serviceProvider,
Expression.Constant(parameterType, typeof(Type)),
Expression.Constant(constructor.DeclaringType, typeof(Type)),
Expression.Constant(hasDefaultValue) };
constructorArguments[i] = Expression.Call(GetServiceInfo, parameterTypeExpression);
}
...
}
return Expression.New(constructor, constructorArguments);
}
GetServiceInfo变量申明了对GetService方法的调用,而此GetService其实正是对ServiceProvider的调用。
private static readonly MethodInfo GetServiceInfo =
GetMethodInfo<Func<IServiceProvider, Type, Type, bool, object>>((sp, t, r, c) => GetService(sp, t, r, c));
private static object GetService(IServiceProvider sp, Type type, Type requiredBy, bool isDefaultParameterRequired)
{
var service = sp.GetService(type);
...
return service;
}
通过以上的处理,在创建Controller时,其构造方法中所需参数的类型也会被容器解析,创建相应实例,从而实现依赖注入功能。
生命周期
ASP.NET Core容器可以创建三种生命周期的对象:
- Transient, 每次取得的都是新的对象。
- Scoped, 每次ASP.NET请求生成不同的对象。
- Singleton,同一对象只会生成一次。
检视这三者类型的构造方法,可以很容易理解Scoped与Singleton是通过缓存的方式实现对象的重用。
public TransientCallSite(IServiceCallSite serviceCallSite)
{
ServiceCallSite = serviceCallSite;
}
public ScopedCallSite(IServiceCallSite serviceCallSite, object cacheKey)
{
ServiceCallSite = serviceCallSite;
CacheKey = cacheKey;
}
public SingletonCallSite(IServiceCallSite serviceCallSite, object cacheKey) : base(serviceCallSite, cacheKey)
{
}
性能
由于ServiceProvider容器使用了反射,表达式树以及IL Emit方式创建对象,可能会对其性能有所担忧,但实际检测的结果,除了Runtime引擎表现不尽如人意外,其它引擎的性能还是在可接受范围内的。
public class GetServiceBenchmark
{
private const int OperationsPerInvoke = 50000;
private IServiceProvider _transientSp;
private ServiceProviderMode _mode;
[Params("Expressions", "Dynamic", "Runtime", "ILEmit")]
public string Mode {
set {
_mode = (ServiceProviderMode)Enum.Parse(typeof(ServiceProviderMode), value);
}
}
[Benchmark(Baseline = true, OperationsPerInvoke = OperationsPerInvoke)]
public void NoDI()
{
for (int i = 0; i < OperationsPerInvoke; i++)
{
var temp = new A(new B(new C()));
temp.Foo();
}
}
[GlobalSetup(Target = nameof(Transient))]
public void SetupTransient()
{
var services = new ServiceCollection();
services.AddTransient<A>();
services.AddTransient<B>();
services.AddTransient<C>();
_transientSp = services.BuildServiceProvider(new ServiceProviderOptions()
{
Mode = _mode
});
}
[Benchmark(OperationsPerInvoke = OperationsPerInvoke)]
public void Transient()
{
for (int i = 0; i < OperationsPerInvoke; i++)
{
var temp = _transientSp.GetService<A>();
temp.Foo();
}
}
private class A
{
public A(B b)
{
}
[MethodImpl(MethodImplOptions.NoInlining)]
public void Foo()
{
}
}
private class B
{
public B(C c)
{
}
}
private class C
{
}
}
// ***** BenchmarkRunner: Finish *****
// * Export *
// * Detailed results *
GetServiceBenchmark.NoDI: Job-NHLENA(Toolchain=InProcessToolchain, RunStrategy=Throughput) [Mode=Dynamic]
Runtime = ; GC =
Mean = 5.5175 ns, StdErr = 0.0116 ns (0.21%); N = 15, StdDev = 0.0449 ns
Min = 5.4490 ns, Q1 = 5.4860 ns, Median = 5.5207 ns, Q3 = 5.5641 ns, Max = 5.5972 ns
IQR = 0.0781 ns, LowerFence = 5.3688 ns, UpperFence = 5.6813 ns
ConfidenceInterval = [5.4695 ns; 5.5654 ns] (CI 99.9%), Margin = 0.0480 ns (0.87% of Mean)
Skewness = 0.15, Kurtosis = 1.67
GetServiceBenchmark.Transient: Job-NHLENA(Toolchain=InProcessToolchain, RunStrategy=Throughput) [Mode=Dynamic]
Runtime = ; GC =
Mean = 43.1601 ns, StdErr = 0.0677 ns (0.16%); N = 15, StdDev = 0.2620 ns
Min = 42.7731 ns, Q1 = 42.9117 ns, Median = 43.2403 ns, Q3 = 43.3580 ns, Max = 43.5392 ns
IQR = 0.4464 ns, LowerFence = 42.2421 ns, UpperFence = 44.0276 ns
ConfidenceInterval = [42.8800 ns; 43.4402 ns] (CI 99.9%), Margin = 0.2801 ns (0.65% of Mean)
Skewness = -0.2, Kurtosis = 1.59
GetServiceBenchmark.NoDI: Job-NHLENA(Toolchain=InProcessToolchain, RunStrategy=Throughput) [Mode=Expressions]
Runtime = ; GC =
Mean = 5.6964 ns, StdErr = 0.0388 ns (0.68%); N = 33, StdDev = 0.2226 ns
Min = 5.5148 ns, Q1 = 5.5603 ns, Median = 5.6042 ns, Q3 = 5.6769 ns, Max = 6.2460 ns
IQR = 0.1166 ns, LowerFence = 5.3854 ns, UpperFence = 5.8518 ns
ConfidenceInterval = [5.5561 ns; 5.8368 ns] (CI 99.9%), Margin = 0.1404 ns (2.46% of Mean)
Skewness = 1.48, Kurtosis = 3.69
GetServiceBenchmark.Transient: Job-NHLENA(Toolchain=InProcessToolchain, RunStrategy=Throughput) [Mode=Expressions]
Runtime = ; GC =
Mean = 43.6662 ns, StdErr = 0.0995 ns (0.23%); N = 13, StdDev = 0.3586 ns
Min = 43.1083 ns, Q1 = 43.5089 ns, Median = 43.6051 ns, Q3 = 43.7178 ns, Max = 44.6669 ns
IQR = 0.2089 ns, LowerFence = 43.1956 ns, UpperFence = 44.0311 ns
ConfidenceInterval = [43.2368 ns; 44.0957 ns] (CI 99.9%), Margin = 0.4295 ns (0.98% of Mean)
Skewness = 1.41, Kurtosis = 5.18
GetServiceBenchmark.NoDI: Job-NHLENA(Toolchain=InProcessToolchain, RunStrategy=Throughput) [Mode=ILEmit]
Runtime = ; GC =
Mean = 5.6016 ns, StdErr = 0.0071 ns (0.13%); N = 13, StdDev = 0.0255 ns
Min = 5.5547 ns, Q1 = 5.5896 ns, Median = 5.5996 ns, Q3 = 5.6226 ns, Max = 5.6400 ns
IQR = 0.0330 ns, LowerFence = 5.5401 ns, UpperFence = 5.6721 ns
ConfidenceInterval = [5.5712 ns; 5.6321 ns] (CI 99.9%), Margin = 0.0305 ns (0.54% of Mean)
Skewness = -0.47, Kurtosis = 2.12
GetServiceBenchmark.Transient: Job-NHLENA(Toolchain=InProcessToolchain, RunStrategy=Throughput) [Mode=ILEmit]
Runtime = ; GC =
Mean = 43.1397 ns, StdErr = 0.0726 ns (0.17%); N = 15, StdDev = 0.2812 ns
Min = 42.7061 ns, Q1 = 42.9064 ns, Median = 43.1052 ns, Q3 = 43.3093 ns, Max = 43.6443 ns
IQR = 0.4028 ns, LowerFence = 42.3022 ns, UpperFence = 43.9135 ns
ConfidenceInterval = [42.8392 ns; 43.4403 ns] (CI 99.9%), Margin = 0.3006 ns (0.70% of Mean)
Skewness = 0.28, Kurtosis = 1.9
GetServiceBenchmark.NoDI: Job-NHLENA(Toolchain=InProcessToolchain, RunStrategy=Throughput) [Mode=Runtime]
Runtime = ; GC =
Mean = 6.4814 ns, StdErr = 0.0762 ns (1.18%); N = 100, StdDev = 0.7617 ns
Min = 5.4979 ns, Q1 = 5.8327 ns, Median = 6.3039 ns, Q3 = 6.9775 ns, Max = 8.0420 ns
IQR = 1.1448 ns, LowerFence = 4.1155 ns, UpperFence = 8.6947 ns
ConfidenceInterval = [6.2231 ns; 6.7397 ns] (CI 99.9%), Margin = 0.2583 ns (3.99% of Mean)
Skewness = 0.52, Kurtosis = 1.94
GetServiceBenchmark.Transient: Job-NHLENA(Toolchain=InProcessToolchain, RunStrategy=Throughput) [Mode=Runtime]
Runtime = ; GC =
Mean = 581.5066 ns, StdErr = 1.6962 ns (0.29%); N = 15, StdDev = 6.5695 ns
Min = 571.4934 ns, Q1 = 576.3829 ns, Median = 580.8121 ns, Q3 = 587.2645 ns, Max = 596.3317 ns
IQR = 10.8816 ns, LowerFence = 560.0605 ns, UpperFence = 603.5869 ns
ConfidenceInterval = [574.4834 ns; 588.5297 ns] (CI 99.9%), Margin = 7.0232 ns (1.21% of Mean)
Skewness = 0.58, Kurtosis = 2.48
Total time: 00:03:11 (191.85 sec)
第三方容器
如果想用第三方容器替换ASP.NET Core原有的容器也是可以办到的。以最常见的Autofac为例,有两种实现方式:
借助ConfigureContainer方法,要先在Program类中挂载AddAutofac方法。
public class Program
{
public static void Main(string[] args)
{
CreateWebHostBuilder(args).Build().Run();
}
public static IWebHostBuilder CreateWebHostBuilder(string[] args) =>
WebHost.CreateDefaultBuilder(args).ConfigureServices(services => services.AddAutofac())
.UseStartup<Startup>();
}
然后在Startup类中加入ConfigureContainer方法。
public void ConfigureContainer(ContainerBuilder builder)
{
builder.RegisterModule(new DefaultModule());
}
例中的DefaultModule类按照Autofac的通用方式实现。
public class DefaultModule : Module
{
protected override void Load(ContainerBuilder builder)
{
builder.RegisterType<HelloWorld>().As<IHelloWorld>();
}
}
如果不想使用ConfigureContainer方法,也可以直接利用ConfigureServices方法:
public IServiceProvider ConfigureServices(IServiceCollection services)
{
services.AddMvc();
var containerBuilder = new ContainerBuilder();
containerBuilder.RegisterModule<DefaultModule>();
containerBuilder.Populate(services);
var container = containerBuilder.Build();
return new AutofacServiceProvider(container);
}
需要注意的是,使用这种方式时,ConfigureServices方法的返回类型要从void改成IServiceProvider。
出处:http://www.cnblogs.com/kenwoo
本文版权归作者和博客园共有,欢迎转载,但必须给出原文链接,并保留此段声明,否则保留追究法律责任的权利。