和所有的服务器一样,KestrelServer最终需要解决的是网络传输的问题。在《网络连接的创建》,我们介绍了KestrelServer如何利用连接接听器的建立网络连接,并再次基础上演示了如何直接利用建立的连接接收请求和回复响应。本篇更进一步,我们根据其总体设计,定义了迷你版的KestrelServer让读者看看这个重要的服务器大体是如何实现的。本文提供的示例演示已经同步到《ASP.NET Core 6框架揭秘-实例演示版》)
一、ConnectionDelegate一、ConnectionDelegate
二、IConnectionBuilder
三、HTTP 1.x/HTTP 2.x V.S. HTTP 3
四、MiniKestrelServer
ASP.NET CORE在“应用”层将针对请求的处理抽象成由中间件构建的管道,实际上KestrelServer面向“传输”层的连接也采用了这样的设计。当代表连接的ConnectionContext上下文创建出来之后,后续的处理将交给由连接中间件构建的管道进行处理。我们可以根据需要注册任意的中间件来处理连接,比如可以将并发连结的控制实现在专门的连接中间件中。ASP.NET CORE管道利用RequestDelegate委托来表示请求处理器,连接管道同样定义了如下这个ConnectionDelegate委托。
public delegate Task ConnectionDelegate(ConnectionContext connection);二、IConnectionBuilder
ASP.NET CORE管道中的中间件体现为一个Func<RequestDelegate, RequestDelegate>委托,连接管道的中间件同样可以利用Func<ConnectionDelegate, ConnectionDelegate>委托来表示。ASP.NET CORE管道中的中间件注册到IApplicationBuilder对象上并利用它将管道构建出来。连接管道依然具有如下这个IConnectionBuilder接口,ConnectionBuilder实现了该接口。
public interface IConnectionBuilder { IServiceProvider ApplicationServices { get; } IConnectionBuilder Use(Func<ConnectionDelegate, ConnectionDelegate> middleware); ConnectionDelegate Build(); } public class ConnectionBuilder : IConnectionBuilder { public IServiceProvider ApplicationServices { get; } public ConnectionDelegate Build(); public IConnectionBuilder Use(Func<ConnectionDelegate, ConnectionDelegate> middleware); }
IConnectionBuilder接口还定义了如下三个扩展方法来注册连接中间件。第一个Use方法使用Func<ConnectionContext, Func<Task>, Task>委托来表示中间件。其余两个方法用来注册管道末端的中间件,这样的中间件本质上就是一个ConnectionDelegate委托,我们可以将其定义成一个派生于ConnectionHandler的类型。
public static class ConnectionBuilderExtensions { public static IConnectionBuilder Use(this IConnectionBuilder connectionBuilder,Func<ConnectionContext, Func<Task>, Task> middleware); public static IConnectionBuilder Run(this IConnectionBuilder connectionBuilder,Func<ConnectionContext, Task> middleware); public static IConnectionBuilder UseConnectionHandler<TConnectionHandler>(this IConnectionBuilder connectionBuilder) where TConnectionHandler : ConnectionHandler; } public abstract class ConnectionHandler { public abstract Task OnConnectedAsync(ConnectionContext connection); }三、HTTP 1.x/HTTP 2.x V.S. HTTP 3
KestrelServer针对HTTP 1.X/2和HTTP 3的设计和实现基本上独立的,这一点从监听器的定义就可以看出来。就连接管道来说,基于HTTP 3的多路复用连接通过MultiplexedConnectionContext表示,它也具有“配套”的MultiplexedConnectionDelegate委托和IMultiplexedConnectionBuilder接口。ListenOptions类型同时实现了IConnectionBuilder和IMultiplexedConnectionBuilder接口,意味着我们在注册终结点的时候还可以注册任意中间件。
public delegate Task MultiplexedConnectionDelegate(MultiplexedConnectionContext connection); public interface IMultiplexedConnectionBuilder { IServiceProvider ApplicationServices { get; } IMultiplexedConnectionBuilder Use(Func<MultiplexedConnectionDelegate, MultiplexedConnectionDelegate> middleware); MultiplexedConnectionDelegate Build(); } public class MultiplexedConnectionBuilder : IMultiplexedConnectionBuilder { public IServiceProvider ApplicationServices { get; } public IMultiplexedConnectionBuilder Use(Func<MultiplexedConnectionDelegate, MultiplexedConnectionDelegate> middleware); public MultiplexedConnectionDelegate Build(); } public class ListenOptions : IConnectionBuilder, IMultiplexedConnectionBuilder四、MiniKestrelServer
在了解了KestrelServer的连接管道后,我们来简单模拟一下这种服务器类型的实现,为此我们定义了一个名为MiniKestrelServer的服务器类型。简单起见,MiniKestrelServer只提供针对HTTP 1.1的支持。对于任何一个服务来说,它需要将请求交付给一个IHttpApplication<TContext>对象进行处理,MiniKestrelServer将这项工作实现在如下这个HostedApplication<TContext>类型中。
public class HostedApplication<TContext> : ConnectionHandler where TContext : notnull { private readonly IHttpApplication<TContext> _application; public HostedApplication(IHttpApplication<TContext> application) => _application = application; public override async Task OnConnectedAsync(ConnectionContext connection) { var reader = connection!.Transport.Input; while (true) { var result = await reader.ReadAsync(); using (var body = new MemoryStream()) { var (features, request, response) = CreateFeatures(result, body); var closeConnection = request.Headers.TryGetValue("Connection", out var vallue) && vallue == "Close"; reader.AdvanceTo(result.Buffer.End); var context = _application.CreateContext(features); Exception? exception = null; try { await _application.ProcessRequestAsync(context); await ApplyResponseAsync(connection, response, body); } catch (Exception ex) { exception = ex; } finally { _application.DisposeContext(context, exception); } if (closeConnection) { await connection.DisposeAsync(); return; } } if (result.IsCompleted) { break; } } static (IFeatureCollection, IHttpRequestFeature, IHttpResponseFeature) CreateFeatures(ReadResult result, Stream body) { var handler = new HttpParserHandler(); var parserHandler = new HttpParser(handler); var length = (int)result.Buffer.Length; var array = ArrayPool<byte>.Shared.Rent(length); try { result.Buffer.CopyTo(array); parserHandler.Execute(new ArraySegment<byte>(array, 0, length)); } finally { ArrayPool<byte>.Shared.Return(array); } var bodyFeature = new StreamBodyFeature(body); var features = new FeatureCollection(); var responseFeature = new HttpResponseFeature(); features.Set<IHttpRequestFeature>(handler.Request); features.Set<IHttpResponseFeature>(responseFeature); features.Set<IHttpResponseBodyFeature>(bodyFeature); return (features, handler.Request, responseFeature); } static async Task ApplyResponseAsync(ConnectionContext connection, IHttpResponseFeature response, Stream body) { var builder = new StringBuilder(); builder.AppendLine($"HTTP/1.1 {response.StatusCode} {response.ReasonPhrase}"); foreach (var kv in response.Headers) { builder.AppendLine($"{kv.Key}: {kv.Value}"); } builder.AppendLine($"Content-Length: {body.Length}"); builder.AppendLine(); var bytes = Encoding.UTF8.GetBytes(builder.ToString()); var writer = connection.Transport.Output; await writer.WriteAsync(bytes); body.Position = 0; await body.CopyToAsync(writer); } } }
HostedApplication<TContext>是对一个IHttpApplication<TContext>对象的封装。它派生于抽象类ConnectionHandler,重写的OnConnectedAsync方法将针对请求的读取和处理置于一个无限循环中。为了将读取的请求转交给IHostedApplication<TContext>对象进行处理,它需要根据特性集合将TContext上下文创建出来。这里提供的特性集合只包含三种核心的特性,一个是描述请求的HttpRequestFeature特性,它是利用HttpParser解析请求荷载内容得到的。另一个是描述响应的HttpResponseFeature特性,至于提供响应主体的特性由如下所示的StreamBodyFeature对象来表示。这三个特性的创建实现在CreateFeatures方法中。
public class StreamBodyFeature : IHttpResponseBodyFeature { public Stream Stream { get; } public PipeWriter Writer { get; } public StreamBodyFeature(Stream stream) { Stream = stream; Writer = PipeWriter.Create(Stream); } public Task CompleteAsync() => Task.CompletedTask; public void DisableBuffering() { } public Task SendFileAsync(string path, long offset, long? count, CancellationToken cancellationToken = default)=> throw new NotImplementedException(); public Task StartAsync(CancellationToken cancellationToken = default) => Task.CompletedTask; }
包含三大特性的集合随后作为参数调用了IHostedApplication<TContext>对象的CreateContext方法将TContext上下文创建出来,此上下文作为参数传入了同一对象的ProcessRequestAsync方法,此时中间件管道接管请求。待中间件管道完成处理后, ApplyResponseAsync方法被调用以完成最终的响应工作。ApplyResponseAsync方法将响应状态从HttpResponseFeature特性中提取并生成首行响应内容(“HTTP/1.1 {StatusCode} {ReasonPhrase}”),然后再从这个特性中将响应报头提取出来并生成相应的文本。响应报文的首行内容和报头文本按照UTF-8编码生成二进制数组后利用ConnectionContext上下文的Transport属性返回的IDuplexPipe对象发送出去后,它再将StreamBodyFeature特性收集到的响应主体输出流“拷贝”到这个IDuplexPipe对象中,进而完成了针对响应主体内容的输出。
如下所示的是MiniKestrelServer类型的完整定义。该类型的构造函数中注入了用于提供配置选项的IOptions<KestrelServerOptions>特性和IConnectionListenerFactory工厂,并且创建了一个ServerAddressesFeature对象并注册到Features属性返回的特性集合中。
public class MiniKestrelServer : IServer { private readonly KestrelServerOptions _options; private readonly IConnectionListenerFactory _factory; private readonly List<IConnectionListener> _listeners = new(); public IFeatureCollection Features { get; } = new FeatureCollection(); public MiniKestrelServer(IOptions<KestrelServerOptions> optionsAccessor, IConnectionListenerFactory factory) { _factory = factory; _options = optionsAccessor.Value; Features.Set<IServerAddressesFeature>(new ServerAddressesFeature()); } public void Dispose() => StopAsync(CancellationToken.None).GetAwaiter().GetResult(); public Task StartAsync<TContext>(IHttpApplication<TContext> application, CancellationToken cancellationToken) where TContext : notnull { var feature = Features.Get<IServerAddressesFeature>()!; IEnumerable<ListenOptions> listenOptions; if (feature.PreferHostingUrls) { listenOptions = BuildListenOptions(feature); } else { listenOptions = _options.GetListenOptions(); if (!listenOptions.Any()) { listenOptions = BuildListenOptions(feature); } } foreach (var options in listenOptions) { _ = StartAsync(options); } return Task.CompletedTask; async Task StartAsync(ListenOptions litenOptions) { var listener = await _factory.BindAsync(litenOptions.EndPoint,cancellationToken); _listeners.Add(listener!);
var hostedApplication = new HostedApplication<TContext>(application); var pipeline = litenOptions.Use(next => context => hostedApplication.OnConnectedAsync(context)).Build();
while (true) { var connection = await listener.AcceptAsync(); if (connection != null) { _ = pipeline(connection); } } } IEnumerable<ListenOptions> BuildListenOptions(IServerAddressesFeature feature) { var options = new KestrelServerOptions(); foreach (var address in feature.Addresses) { var url = new Uri(address); if (string.Compare("localhost", url.Host, true) == 0) { options.ListenLocalhost(url.Port); } else { options.Listen(IPAddress.Parse(url.Host), url.Port); } } return options.GetListenOptions(); } } public Task StopAsync(CancellationToken cancellationToken) => Task.WhenAll(_listeners.Select(it => it.DisposeAsync().AsTask())); }
实现的StartAsync<TContext>方法先将IServerAddressesFeature特性提取出来,并利用其PreferHostingUrls属性决定应该使用直接注册到KestrelOptions配置选项上的终结点还是使用注册在该特定上的监听地址。如果使用后者,注册的监听地址会利用BuildListenOptions方法转换成对应的ListenOptions列表,否则直接从KestrelOptions对象的ListenOptions属性提取所有的ListenOptions列表,由于这是一个内部属性,不得不利用如下这个扩展方法以反射的方式获取这个列表。
public static class KestrelServerOptionsExtensions { public static IEnumerable<ListenOptions> GetListenOptions(this KestrelServerOptions options) { var property = typeof(KestrelServerOptions).GetProperty("ListenOptions",BindingFlags.NonPublic | BindingFlags.Instance); return (IEnumerable<ListenOptions>)property!.GetValue(options)!; } }
对于每一个表示注册终结点的ListenOptions配置选项,StartAsync<TContext>方法利用IConnectionListenerFactory工厂将对应的IConnectionListener监听器创建出来,并绑定到指定的终结点上监听连接请求。表示连接的ConnectionContext上下文一旦被创建出来后,该方法便会利用构建的连接管道对它进行处理。在调用ListenOptions配置选项的Build方法构建连接管道前,StartAsync<TContext>方法将HostedApplication<TContext>对象创建出来并作为中间件进行了注册。所以针对连接的处理将被这个HostedApplication<TContext>对象接管。
using App; using Microsoft.AspNetCore.Hosting.Server; using Microsoft.Extensions.DependencyInjection.Extensions; var builder = WebApplication.CreateBuilder(); builder.WebHost.UseKestrel(kestrel => kestrel.ListenLocalhost(5000)); builder.Services.Replace(ServiceDescriptor.Singleton<IServer, MiniKestrelServer>()); var app = builder.Build(); app.Run(context => context.Response.WriteAsync("Hello World!")); app.Run();
如上所示的演示程序将替换了针对IServer的服务注册,意味着默认的KestrelServer将被替换成自定义的MiniKestrelServer。启动该程序后,由浏览器发送的HTTP请求(不支持HTTPS)同样会被正常处理,并得到如图18-6所示的响应内容。需要强调一下,MiniKestrelServer仅仅用来模拟KestrelServer的实现原理,不要觉得真实的实现会如此简单。
图1 由MiniKestrelServer回复的响应内容