AOP
视频讲解
面向切面编程AOP的对面向对象编程OOP的一个补充,它的特点是将系统逻辑和业务逻辑采取《非侵入式》分离。我们把系统封装成一个一个的切面(单一职责)进行顺意编排组合,插入(织入)到业务逻辑的执行过程(织入点)。
系统逻辑:异常处理,身份认证,授权,mvc,数据校验,事务处理。
业务逻辑:就是我们的业务Service。
切面:用于封装系统逻辑,比如身份认证filter,或者中间件
切入点:就是管道的位置。名词
织入:就是插入到管道的切入点的过程。动词
AOP的特点:
1.非侵入式
2.低耦合
3.代码服用
4.单一职责
5.可插拔
实现方式:
1.管道链,比如aspnetcore的中间件,mvc中的Filter
2.静态代理:思考如何加强一个List,使得在插入时打印日志?
3.动态代理:Emit
4.三种模式都需要通过一些技术进行串联,实现链式调用,构成管道。静态代理通过接口进行串联,动态代理通过反射进行串联。管道通过接口获取委托进行串联。委托本质也是接口。
代理:就是增强,代理对象必须尽量实现目标对象的功能,在此基础上进行加强。比如vpn,你的电脑的网络就是目标对象,vpn就是代理服务,代理服务起码得实现联网功能吧,然后对网络进行加强,访问到一些你的本机网络访问不到的东西。
掌握了AOP技术我们可以实现很多好处,做到非侵入式的增强业务逻辑。
//侵入式方案,把这个看懂。后面就是围绕这个开展,高出非侵入式
public static void A()
{
Console.WriteLine("A:开始");
B();//A,B的调用关系强行绑定,有侵入性
Console.WriteLine("A:结束");
}
public static void B()
{
Console.WriteLine("B:开始");
C();
Console.WriteLine("B:结束");
}
public static void C()
{
Console.WriteLine("Hello World");
}
public static void Dobasic()
{
A();
}
静态代理
1.代理就是实现目标对象的标准(接口),在目标方法执行之前和之后进行逻辑织入的过程。代理的目的就是为了加强。代理不负责实现接口,一般通过target来实现接口。即代理除了可以增强之外还能简化接口的实现。
2.静态代理就是在代理之前就已经确定了代理关系。需要自己实现标准并编写代理类。代理类中的逻辑只能代理一些标准(实现多个接口)。无法代理所有标准。
3.静态代理可以实现不改变目标对象的源码的情况下进行加强,完成目标对象的能力,并且在此基础之上进行加强。
4.可以简化实现的成本,不改变业务代码,只需要编写额外的增强逻辑。不需要关系具体的业务实现。
5.代理和代理直接通过接口可以进行互相代理,链式调用,顺意编排组合,实现系统的多样化。
/// <summary>
/// 定义标准1
/// </summary>
public interface IPhoneService
{
string Mobile { get; set; }
string Message { get; set; }
void Send();
}
//实现标准-不是代理模式
public class PhoneService : IPhoneService
{
public string Mobile { get; set; }
public string Message { get; set; }
public PhoneService(string mobile, string message)
{
Mobile = mobile;
Message = message;
}
public virtual void Send()
{
Console.WriteLine($"已发送短信:{Message}到{Mobile}");
}
}
//代理模式:
//1.实现目标对象的标准
//2.依赖目标对象(被代理对象)
//3.业务织入
public class PhoneServiceProxy : IPhoneService//实现标准
{
private readonly IPhoneService _target;
public PhoneServiceProxy1(IPhoneService target)
{
_target = target;
}
public string Mobile { get => _target.Mobile; set => _target.Mobile = value; }
public string Message { get => _target.Message; set => _target.Message = value; }
/// <summary>
/// 子类重写父类方法
/// </summary>
public void Send()
{
Console.WriteLine("Proxy1:已对手机号进行验证");
_target.Send();
Console.WriteLine("Proxy1:已确认对方已经收到");
}
}
/// <summary>
/// 定义标准1
/// </summary>
public interface IPhoneService
{
string Mobile { get; set; }
string Message { get; set; }
void Send();
}
/// <summary>
/// 定义标准2
/// </summary>
public interface IEmailService
{
string Email { get; set; }
string Message { get; set; }
void Send();
}
/// <summary>
/// 业务逻辑1
/// </summary>
public class PhoneService : IPhoneService
{
public string Mobile { get; set; }
public string Message { get; set; }
public PhoneService(string mobile, string message)
{
Mobile = mobile;
Message = message;
}
public virtual void Send()
{
Console.WriteLine($"已发送短信:{Message}到{Mobile}");
}
}
/// <summary>
/// 业务逻辑2
/// </summary>
public class EmailService : IEmailService
{
public string Email { get; set; }
public string Message { get; set; }
public EmailService(string email, string message)
{
Email = email;
Message = message;
}
public virtual void Send()
{
Console.WriteLine($"已发送邮件:{Message}到{Email}");
}
}
/// <summary>
/// 切面1:校验能力(系统逻辑)
/// taget方式
/// </summary>
public class PhoneServiceProxy1
: IPhoneService//实现标准1
{
private readonly IPhoneService _target;
public PhoneServiceProxy1(IPhoneService target)
{
_target = target;
}
/// <summary>
/// 子类重写父类方法
/// </summary>
public void Send()
{
Console.WriteLine("Proxy1:已对手机号进行验证");
_target.Send();
Console.WriteLine("Proxy1:已确认对方已经收到");
}
}
/// <summary>
/// 切面2:加速能力(系统逻辑)
/// </summary>
public class PhoneServiceProxy2
: IPhoneService//实现标准1
{
private readonly IPhoneService _target;
public PhoneServiceProxy2(IPhoneService target)
{
_target = target;
}
/// <summary>
/// 子类重写父类方法
/// </summary>
public void Send()
{
Console.WriteLine("Proxy2:已开启加速通道");
_target.Send();
Console.WriteLine("Proxy2:已关闭加速通道");
}
}
//test
public static void TestStaticProxy()
{
//目标对象
IPhoneService target = new PhoneService("10088", "你好啊!");
//切面1:验证,对target进行代理
IPhoneService proxy1 = new PhoneServiceProxy1(target);
//切面2:加速,对proxy1进行代理
IPhoneService proxy2 = new PhoneServiceProxy2(proxy1);
//执行
proxy2.Send();
//思考如果要实现IEmailService标准,是不是要重写实现类了?
}
动态代理
Castle.Core
动态代理和静态代理的区别就是,代理类由工具生成,需要在运行时确认代理类已经代理关系。代理类中的逻辑写到拦截器里面,可以进行复用。缺点是性能差。里面涉及到大量反射技术。
Castle.Core:原理就是通过子类继承父类或者实现父类标准,通过Castle.Core自动帮你生成代理类,通过一个叫拦截器的东西编写代理类要执行的业务逻辑。Castle.Core会帮你生成代理类,并将拦截器织入到代理类中。
动态代理通过invocation进行串联,本质是反射。
/// <summary>
/// 定义标准1
/// </summary>
public interface IPhoneService
{
string Mobile { get; set; }
string Message { get; set; }
void Send();
}
/// <summary>
/// 定义标准2
/// </summary>
public interface IEmailService
{
string Email { get; set; }
string Message { get; set; }
void Send();
}
/// <summary>
/// 业务逻辑1
/// </summary>
public class PhoneService : IPhoneService
{
public string Mobile { get; set; }
public string Message { get; set; }
public PhoneService(string mobile, string message)
{
Mobile = mobile;
Message = message;
}
public virtual void Send()
{
Console.WriteLine($"已发送短信:{Message}到{Mobile}");
}
}
/// <summary>
/// 业务逻辑2
/// </summary>
public class EmailService : IEmailService
{
public string Email { get; set; }
public string Message { get; set; }
public EmailService(string email, string message)
{
Email = email;
Message = message;
}
public virtual void Send()
{
Console.WriteLine($"已发送邮件:{Message}到{Email}");
}
}
/// <summary>
/// 代理1:任意标准
/// </summary>
public class ShareInterceptor1 : IInterceptor
{
public void Intercept(IInvocation invocation)
{
Console.WriteLine("Proxy1:已对接收方进行验证");
invocation.Proceed();//执行下一个拦截器或者目标方法
Console.WriteLine("Proxy1:已确认对方已经收到");
}
}
/// <summary>
/// 代理2:任意标准
/// </summary>
public class ShareInterceptor2 : IInterceptor
{
public void Intercept(IInvocation invocation)
{
Console.WriteLine("Proxy2:已开启加速通道");
invocation.Proceed();//执行下一个拦截器或者目标方法
Console.WriteLine("Proxy2:已关闭加速通道");
}
}
//通过Castel生成代理类
public static void TestDynamicProxy1()
{
//创建代理生成器
var generator = new ProxyGenerator();
var target1 = new PhoneService("10088", "你好啊!");
var target2 = new EmailService("1123@116.com", "你好啊!");
var interceptor1 = new ShareInterceptor1();//代理1,拦截器1,不需要去实现指定的标准
var interceptor2 = new ShareInterceptor2();//代理2,拦截器2,不需要去实现指定的标准
//使用代理1和代理2去代理手机的标准
IPhoneService dynamicProxy1 = generator.CreateInterfaceProxyWithTarget<IPhoneService>(target1, interceptor1, interceptor2);
dynamicProxy1.Send();
//代理邮件的标准
IEmailService dynamicProxy2 = generator.CreateInterfaceProxyWithTarget<IEmailService>(target2, interceptor1, interceptor2);
dynamicProxy2.Send();
}
手写Castle.Core的代理类
思考:
generator创建的是什么类型的实列?显然不可能是已有的类型。因为它把拦截器织入进去了。而且没有修改我们的代码,站在面向对象的角度来看只能是实现了我们的接口,Emit动态实现了下面的代码
多个拦截器和目标对象(被代理者)通过Invocation进行串联。Invocation中的Arguments完成链式调用。
手动通过Invocation进行串联
//假设有三个拦截器
//第一个拦截器invocation1:Proxy=interceptor2,Method=Intercept,argument=invocation2
//第二个拦截器invocation2:Proxy=interceptor3,Method=Intercept,argument=invocation3
//第三个拦截器invocation2:Proxy=target,Method=method,argument=arguments
//手动实现
public IInvocation GetInvocation(Stack<IInterceptor> stack, object target, Method method, objuect arguments)
{
var invocation1 = new Invocation()
{
Proxy = interceptor2,
Method = typeof(IInterceptor).GetMethod(nameof(IInterceptor.Intercept)),
Arguments = new object[]
{
new Invocation()
{
Proxy = interceptor3,
Method = typeof(IInterceptor).GetMethod(nameof(IInterceptor.Intercept)),
Arguments = new object[]
{
new Invocation()
{
Proxy = target,
Method = method,
Arguments = arguments
}
}
}
}
}
}
//递归实现
public IInvocation GetInvocation(Stack<IInterceptor> stack, object target, Method method, objuect arguments)
{
if(stack.Any())
{
var proxy = stack.Pop();
return new Invocation()
{
Proxy = proxy,
Method = typeof(IInterceptor).GetMethod(nameof(IInterceptor.Intercept)),
Agrumtns = GetInvocation(stack,method,argumtns)
};
}
else
{
return new Invocation()
{
Proxy = target,
Method = method,
Agrumtns = arguments
};
}
}
//Castel.Core自动帮我们生成了下面这个类
public class CastelPhoneServiceProxy : IPhoneService
{
private IPhoneService _taget;
private IInterceptor[] _interceptors;
public CastelPhoneServiceProxy(IPhoneService taget, IInterceptor[] interceptors)
{
_taget = taget;
_interceptors = interceptors;
}
public string Mobile { get => _taget.Mobile; set => _taget.Mobile = value; }
public string Message { get => _taget.Message; set => _taget.Message = value; }
public void Send()
{
var stack = new Stack<IInterceptor>(_interceptors.Reverse());
if (stack.Any())
{
var item = stack.Pop();
var invocation = GetNextInvocation(stack);
item.Intercept(invocation);
}
else
{
_taget.Send();
}
}
/// <summary>
/// 递归获取Invocaltion
/// </summary>
/// <param name="stack"></param>
/// <returns></returns>
private IInvocation GetNextInvocation(Stack<IInterceptor> stack)
{
if (stack.Any())
{
var next = stack.Pop();
return new Invocaltion
{
Arguments = new object[]
{
//递归
GetNextInvocation(stack)
},
Proxy = next,
Method = typeof(IInterceptor).GetMethod(nameof(IInterceptor.Intercept)) ?? throw new NullReferenceException()
};
}
else
{
return new Invocaltion
{
Arguments = new object[]
{
},
Proxy = _taget,
Method = _taget.GetType().GetMethod(nameof(IPhoneService.Send)) ?? throw new NullReferenceException()
};
}
}
}
//实现一些castle.core的接口
public class Invocaltion : IInvocation
{
public object[] Arguments { get; set; }
public Type[] GenericArguments { get; set; }
public object InvocationTarget { get; set; }
public MethodInfo Method { get; set; }
public MethodInfo MethodInvocationTarget { get; set; }
public object Proxy { get; set; }
public object ReturnValue { get; set; }
public Type TargetType { get; set; }
public IInvocationProceedInfo CaptureProceedInfo()
{
throw new NotImplementedException();
}
public object GetArgumentValue(int index)
{
throw new NotImplementedException();
}
public MethodInfo GetConcreteMethod()
{
throw new NotImplementedException();
}
public MethodInfo GetConcreteMethodInvocationTarget()
{
throw new NotImplementedException();
}
public void Proceed()
{
Method.Invoke(Proxy, Arguments);
}
public void SetArgumentValue(int index, object value)
{
throw new NotImplementedException();
}
}
EMIT实现
//链路器
public class EmitInvocation
{
private object? proxy;
private MethodInfo? method;
private object[]? arguments;
public EmitInvocation(object? proxy, MethodInfo? method, object[]? arguments)
{
this.proxy = proxy;
this.method = method;
this.arguments = arguments;
}
public void Proceed()
{
method?.Invoke(proxy, arguments);
}
}
//拦截器
public interface IEmitInteceptor
{
void Intercept(EmitInvocation invocation);
}
//实现拦截器1
public class EmitInteceptor1 : IEmitInteceptor
{
public void Intercept(EmitInvocation invocation)
{
Console.WriteLine("prox1:start");
invocation.Proceed();
Console.WriteLine("prox1:end");
}
}
//实现拦截器1
public class EmitInteceptor2 : IEmitInteceptor
{
public void Intercept(EmitInvocation invocation)
{
Console.WriteLine("prox2:start");
invocation.Proceed();
Console.WriteLine("prox2:end");
}
}
//该工具类帮助我们少写emit代码
public static class EmitProxyInvoker
{
public static EmitInvocation GetNextInvocation(Stack<IEmitInteceptor> stack, MethodInfo method, object target, object[] arguments)
{
if (stack.Any())
{
var next = stack.Pop();
arguments = new object[]
{
//递归
GetNextInvocation(stack, method, target, arguments)
};
return new EmitInvocation(next, typeof(IEmitInteceptor).GetMethod(nameof(IEmitInteceptor.Intercept)), arguments);
}
else
{
return new EmitInvocation(target, method, arguments);
}
}
public static void Invoke(IEmitInteceptor[] interceptors, MethodInfo method, object target, object[] arguments)
{
var stack = new Stack<IEmitInteceptor>(interceptors.Reverse());
if (stack.Any())
{
var item = stack.Pop();
var invocation = GetNextInvocation(stack, method, target, arguments);
item.Intercept(invocation);
}
else
{
method.Invoke(target, arguments);
}
}
}
//业务接口
public interface IEmitService
{
void Send();
}
//将来要生成的代理类
public class EmitServiceProxy : IEmitService
{
private object _target;
private IEmitInteceptor[] _inteceptors;
public EmitService()
{
}
public void Send()
{
var method = _target.GetType().GetMethod(nameof(EmitService.Send));
var arguments = new object[] { };
EmitProxyInvoker.Invoke(_inteceptors, method, _target, new object[] { });
}
}
public static class EmitProxyGenerator
{
static AssemblyBuilder _assemblyBuilder;
static ModuleBuilder _moduleBuilder;
static EmitProxyGenerator()
{
//创建一个程序集
var assemblyName = new AssemblyName("DynamicProxies");
_assemblyBuilder = AssemblyBuilder
.DefineDynamicAssembly(assemblyName, AssemblyBuilderAccess.Run);
//创建一个模块
_moduleBuilder = _assemblyBuilder.DefineDynamicModule("Proxies");
}
public static TInterface Create<TInterface>(object target, params IEmitInteceptor[] inteceptor)
where TInterface : class
{
#region 定义类型
//定义一个class,如果这个类型已定义直接返回,缓存
var typeName = $"{target.GetType().Name}EmitProxy";
var typeBuilder = _moduleBuilder.DefineType(
typeName,
TypeAttributes.Public,typeof(object),
new Type[]
{
typeof(TInterface)
});
#endregion
#region 定义字段
//定义字段
var targetFieldBuilder = typeBuilder.DefineField("target", typeof(object), FieldAttributes.Private);
var inteceptorFieldBuilder = typeBuilder.DefineField("inteceptor", typeof(IEmitInteceptor[]), FieldAttributes.Private);
#endregion
#region 定义构造器
//定义构造器
var constructorBuilder = typeBuilder.DefineConstructor(MethodAttributes.Public, CallingConventions.ExplicitThis, new Type[]
{
typeof(object),
typeof(IEmitInteceptor[])
});
//获取IL编辑器
var generator = constructorBuilder.GetILGenerator();
generator.Emit(OpCodes.Ldarg_0);//加载this
generator.Emit(OpCodes.Call, typeof(object).GetConstructor(Type.EmptyTypes) ?? throw new InvalidOperationException());
generator.Emit(OpCodes.Nop);
generator.Emit(OpCodes.Nop);
// this.age = age;
generator.Emit(OpCodes.Ldarg_0);//加载this
generator.Emit(OpCodes.Ldarg_1);//加载target参数
generator.Emit(OpCodes.Stfld, targetFieldBuilder);//加载target字段
// this.name = name;
generator.Emit(OpCodes.Ldarg_0);//加载this
generator.Emit(OpCodes.Ldarg_2);//加载inteceptor参数
generator.Emit(OpCodes.Stfld, inteceptorFieldBuilder);//加载inteceptor字段
generator.Emit(OpCodes.Ret);
#endregion
#region 实现接口
var methods = typeof(TInterface).GetMethods();
foreach (var item in methods)
{
var parameterTypes = item.GetParameters().Select(s => s.ParameterType).ToArray();
var methodBuilder = typeBuilder.DefineMethod(item.Name,
MethodAttributes.Public| MethodAttributes.Final |MethodAttributes.Virtual | MethodAttributes.NewSlot | MethodAttributes.HideBySig,
CallingConventions.Standard|CallingConventions.HasThis,
item.ReturnType,
parameterTypes);
var generator1 = methodBuilder.GetILGenerator();
//init
var methodInfoLocal = generator1.DeclareLocal(typeof(MethodInfo));
var argumentLocal = generator1.DeclareLocal(typeof(object[]));
generator1.Emit(OpCodes.Nop);
generator1.Emit(OpCodes.Ldarg_0);
generator1.Emit(OpCodes.Ldfld, targetFieldBuilder);
generator1.Emit(OpCodes.Callvirt, typeof(Type).GetMethod(nameof(Type.GetType),Type.EmptyTypes));
generator1.Emit(OpCodes.Ldstr, item.Name);
generator1.Emit(OpCodes.Callvirt, typeof(Type).GetMethod(nameof(Type.GetMethod), new Type[] { typeof(string) }));
generator1.Emit(OpCodes.Stloc, methodInfoLocal);
generator1.Emit(OpCodes.Ldc_I4_0);
generator1.Emit(OpCodes.Newarr, typeof(object));
generator1.Emit(OpCodes.Stloc, argumentLocal);
generator1.Emit(OpCodes.Ldarg_0);
generator1.Emit(OpCodes.Ldfld, inteceptorFieldBuilder);
generator1.Emit(OpCodes.Ldloc_0);
generator1.Emit(OpCodes.Ldarg_0);
generator1.Emit(OpCodes.Ldfld, targetFieldBuilder);
generator1.Emit(OpCodes.Ldc_I4_0);
generator1.Emit(OpCodes.Newarr, typeof(object));
generator1.Emit(OpCodes.Call, typeof(EmitProxyInvoker).GetMethod(nameof(EmitProxyUtil.Invoke)));
generator1.Emit(OpCodes.Nop);
generator1.Emit(OpCodes.Ret);
}
#endregion
//创建:这个type可以用一个线程安全的字典缓存起来,第二次需要这个代理类的时候,就不需要在生成一次emit代码了。
var type = typeBuilder.CreateType() ?? throw new ArgumentException();
var instance = Activator.CreateInstance(type, target, inteceptor);
return (TInterface)instance;
}
}
容器支持
public class DbContext
{
}
public class AService
{
public DbContext DbContext { get; }
public AService(DbContext context)
{
DbContext = context;
}
}
public static void Test()
{
var services = new ServiceCollection();
services.AddScoped<DbContext>();
var generator = new ProxyGenerator();
//泛型-不支持动态注入
services.AddScoped(sp =>
{
//通过容器解析依赖
var target = ActivatorUtilities.CreateInstance<AService>(sp);
return generator.CreateClassProxyWithTarget(target);
});
//反射-可以扫描批量注入
services.AddScoped(typeof(AService), sp =>
{
//通过容器解析依赖
var target = ActivatorUtilities.CreateInstance(sp, typeof(AService));
return generator.CreateClassProxyWithTarget(target);
});
}
管道方式
委托方式
1.通过委托构建管道
public delegate Task RequestDelegate(HttpContext context);
public class HttpContext
{
}
public class ApplicationBuilder
{
private readonly List<Func<RequestDelegate, RequestDelegate>> _componen
public void Use(Func<RequestDelegate, RequestDelegate> middleware)
{
_components.Add(middleware);
}
public void Use(Func<HttpContext, Func<Task>, Task> middleware)
{
_components.Add((next) =>
{
return async c =>
{
await middleware(c, () => next(c));
};
});
}
public void Use(Func<HttpContext, RequestDelegate, Task> middleware)
{
_components.Add((next) =>
{
return async c =>
{
await middleware(c, next);
};
});
}
public void Run(RequestDelegate handler)
{
_components.Add((next) =>
{
return async c =>
{
await handler(c);
};
});
}
//构建管道
public RequestDelegate Build()
{
RequestDelegate app = c =>
{
throw new InvalidOperationException("无效的管道");
};
for (int i = _components.Count - 1; i > -1; i--)
{
app = _components[i](app);
}
return app;
}
}
接口方式
2.通过接口构建管道
有点类型动态代理,动态代理是通过Invocation进行反射,而下面的方式是通过接口的方式。反射更加灵活,性能不行。
public interface IChain
{
Task NextAsync();
}
public class FilterChain : IChain
{
private readonly IFilter _filter;
private readonly HttpContext _context;
private readonly IChain _next;
public FilterChain(IFilter filter, HttpContext context, IChain next)
{
_filter = filter;
_context = context;
_next = next;
}
public async Task NextAsync()
{
await _filter.InvokeAsync(_context, _next);
}
}
public class ServletChain : IChain
{
private readonly IServlet _servlet;
private readonly HttpContext _context;
public ServletChain(IServlet servlet, HttpContext context)
{
_servlet = servlet;
_context = context;
}
public async Task NextAsync()
{
await _servlet.DoPostAsync(_context);
}
}
public interface IFilter
{
Task InvokeAsync(HttpContext context, IChain chain);
}
public class Filter1 : IFilter
{
public async Task InvokeAsync(HttpContext context, IChain chain)
{
Console.WriteLine("身份认证开始");
await chain.NextAsync();
Console.WriteLine("身份认证结束");
}
}
public class Filter2 : IFilter
{
public async Task InvokeAsync(HttpContext context, IChain chain)
{
Console.WriteLine("授权认证开始");
await chain.NextAsync();
Console.WriteLine("授权认证结束");
}
}
public interface IServlet
{
Task DoPostAsync(HttpContext context);
}
public class HelloServlet : IServlet
{
public Task DoPostAsync(HttpContext context)
{
Console.WriteLine("Hello World");
return Task.CompletedTask;
}
}
public class WebHost
{
private readonly List<IFilter> _filters = new List<IFilter>();
public void AddFilter(IFilter filter)
{
_filters.Add(filter);
}
public void Exeucte(HttpContext context, IServlet servlet)
{
//自行处理filter为空的情况,就是直接执行serlvet就好了
var stack = new Stack<IFilter>(_filters);
var filter = stack.Pop();
var chain = GetFilterChain(context, servlet,stack);
filter.InvokeAsync(context, chain);
}
private IChain GetFilterChain(HttpContext context, IServlet servlet, Stack<IFilter> filters)
{
if (filters.Any())
{
var filter = filters.Pop();
var chain = GetFilterChain(context, servlet, filters);
return new FilterChain(filter, context, chain);
}
else
{
return new ServletChain(servlet, context);
}
}
}
AOP总结
1.代理分为静态代理和动态代理,静态代理需要自己编写代理类,动态代理由框架生成代理类。
2.代理和管道都需要通过接口(委托)进行链接,串联,形成链式调用。
3.动态代理慎用,因为涉及到反射技术,而且对异步支持不友好。
4.静态代理常用于加强已有类型,比如接口要求一个IList,我们已经拥有了一个list实列,我们需要在在list.Add方法时打印日志,此时我们可以不改变原有的list,通过静态代理实现IList接口来进行对原有的list加强。这个方法在更改框架的时候很有用。我们可以对原有的HttpContext,进行加强。
