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Java 分布式跟踪系统 Zipkin(四):Brave 源码分析 —— HttpTracing

上一篇博文中,我们分析了Tracing的相关源代码,这一篇我们来看看Brave是如何在Web项目中使用的

我们先来看看普通的servlet项目中,如何使用Brave,这对我们后面分析和理解Brave和SpringMVC等框架整合有帮助

首先Chapter1/servlet25项目中配置了FrontServlet和BackendServlet以及TracingFilter

web.xml

<web-app xmlns="http://java.sun.com/xml/ns/javaee"
    xmlns:xsi="http://www.w3.org/2001/XMLSchema-instance"
    xsi:schemaLocation="http://java.sun.com/xml/ns/javaee
	http://java.sun.com/xml/ns/javaee/web-app_2_5.xsd"
    version="2.5">

  <display-name>Servlet2.5 Application</display-name>

  <filter>
    <filter-name>TracingFilter</filter-name>
    <filter-class>org.mozhu.zipkin.filter.BraveTracingFilter</filter-class>
  </filter>
  <filter-mapping>
    <filter-name>TracingFilter</filter-name>
    <url-pattern>/*</url-pattern>
  </filter-mapping>

  <servlet>
    <servlet-name>BackendServlet</servlet-name>
    <servlet-class>org.mozhu.zipkin.servlet.BackendServlet</servlet-class>
    <load-on-startup>1</load-on-startup>
  </servlet>
  <servlet-mapping>
    <servlet-name>BackendServlet</servlet-name>
    <url-pattern>/api</url-pattern>
  </servlet-mapping>

  <servlet>
    <servlet-name>FrontendServlet</servlet-name>
    <servlet-class>org.mozhu.zipkin.servlet.FrontendServlet</servlet-class>
    <load-on-startup>1</load-on-startup>
  </servlet>
  <servlet-mapping>
    <servlet-name>FrontendServlet</servlet-name>
    <url-pattern>/</url-pattern>
  </servlet-mapping>
</web-app>

TracingFilter

我们使用自定义的BraveTracingFilter作为入口,其init方法中,我们初始化了Tracing,然后创建HttpTracing对象,最后调用TracingFilter.create(httpTracing)创建了tracingFilter。 doFilter方法中,所有请求将被tracingFilter来处理

BraveTracingFilter

package org.mozhu.zipkin.filter;

import brave.Tracing;
import brave.context.log4j2.ThreadContextCurrentTraceContext;
import brave.http.HttpTracing;
import brave.propagation.B3Propagation;
import brave.propagation.ExtraFieldPropagation;
import brave.servlet.TracingFilter;
import zipkin2.codec.SpanBytesEncoder;
import zipkin2.reporter.AsyncReporter;
import zipkin2.reporter.Sender;
import zipkin2.reporter.okhttp3.OkHttpSender;

import javax.servlet.*;
import java.io.IOException;
import java.util.concurrent.TimeUnit;

public class BraveTracingFilter implements Filter {
    Filter tracingFilter;

    @Override
    public void init(FilterConfig filterConfig) throws ServletException {
        Sender sender = OkHttpSender.create("http://localhost:9411/api/v2/spans");
        AsyncReporter asyncReporter = AsyncReporter.builder(sender)
                .closeTimeout(500, TimeUnit.MILLISECONDS)
                .build(SpanBytesEncoder.JSON_V2);

        Tracing tracing = Tracing.newBuilder()
                .localServiceName(System.getProperty("zipkin.service", "servlet25-demo"))
                .spanReporter(asyncReporter)
                .propagationFactory(ExtraFieldPropagation.newFactory(B3Propagation.FACTORY, "user-name"))
                .currentTraceContext(ThreadContextCurrentTraceContext.create())
                .build();

        HttpTracing httpTracing = HttpTracing.create(tracing);
        filterConfig.getServletContext().setAttribute("TRACING", httpTracing);
        tracingFilter = TracingFilter.create(httpTracing);
        tracingFilter.init(filterConfig);
    }

    @Override
    public void doFilter(ServletRequest servletRequest, ServletResponse servletResponse, FilterChain filterChain) throws IOException, ServletException {
        tracingFilter.doFilter(servletRequest, servletResponse, filterChain);
    }

    @Override
    public void destroy() {
        tracingFilter.destroy();
    }

}

TracingFilter

TracingFilter在brave-instrumentation-servlet包中

public final class TracingFilter implements Filter {
  public static Filter create(Tracing tracing) {
    return new TracingFilter(HttpTracing.create(tracing));
  }

  public static Filter create(HttpTracing httpTracing) {
    return new TracingFilter(httpTracing);
  }

  final ServletRuntime servlet = ServletRuntime.get();
  final Tracer tracer;
  final HttpServerHandler<HttpServletRequest, HttpServletResponse> handler;
  final TraceContext.Extractor<HttpServletRequest> extractor;

  TracingFilter(HttpTracing httpTracing) {
    tracer = httpTracing.tracing().tracer();
    handler = HttpServerHandler.create(httpTracing, new HttpServletAdapter());
    extractor = httpTracing.tracing().propagation().extractor(HttpServletRequest::getHeader);
  }
}

TracingFilter中几个重要的类

  • HttpTracing – 包含Http处理相关的组件,clientParser,serverParser,clientSampler,serverSampler
  • ServletRuntime – Servlet运行时类,包含根据环境来判断是否支持Servlet3异步调用等方法
  • HttpServerHandler – Http处理的核心组件,基本上所有和trace相关的操作均在此类中完成
  • HttpServletAdapter – HttpServlet的适配器接口,此类的引入可以让httpServerHandler类变得更为通用,因为它是一个泛型接口,跟具体的request和response无关,能和更多框架进行整合
  • TraceContext.Extractor – TraceContext的数据提取器

doFilter方法

@Override
  public void doFilter(ServletRequest request, ServletResponse response, FilterChain chain)
      throws IOException, ServletException {
    HttpServletRequest httpRequest = (HttpServletRequest) request;
    HttpServletResponse httpResponse = servlet.httpResponse(response);

    Span span = handler.handleReceive(extractor, httpRequest);
    Throwable error = null;
    try (Tracer.SpanInScope ws = tracer.withSpanInScope(span)) {
      chain.doFilter(httpRequest, httpResponse); // any downstream filters see Tracer.currentSpan
    } catch (IOException | ServletException | RuntimeException | Error e) {
      error = e;
      throw e;
    } finally {
      if (servlet.isAsync(httpRequest)) { // we don't have the actual response, handle later
        servlet.handleAsync(handler, httpRequest, span);
      } else { // we have a synchronous response, so we can finish the span
        handler.handleSend(httpResponse, error, span);
      }
    }
  }
  • 首先调用handler.handleReceive(extractor, httpRequest)从request中提取Span信息
  • 然后调用tracer.withSpanInScope(span)将Span包装成Tracer.SpanInScope,而Tracer.SpanInScope和前面博文中分析的CurrentTraceContext.Scope比较像,都实现了Closeable接口,这里的目的也一样,都是为了利用JDK7的try-with-resources的特性,JVM会自动调用close方法,做一些线程对象的清理工作。其区别是后者是SPI(Service Provider Interface),不适合暴露给真正的使用者。 这样使得chain.doFilter(httpRequest, httpResponse)里的代码能用Tracer.currentSpan拿到从请求中提取(extract)的Span信息。
  • 最后调用handler.handleSend(httpResponse, error, span)

下面来仔细分析下handler中handleReceive和handleSend两个方法 handleReceive方法

public Span handleReceive(TraceContext.Extractor<Req> extractor, Req request) {
  return handleReceive(extractor, request, request);
}

public <C> Span handleReceive(TraceContext.Extractor<C> extractor, C carrier, Req request) {
  Span span = nextSpan(extractor.extract(carrier), request);
  if (span.isNoop()) return span;

  // all of the parsing here occur before a timestamp is recorded on the span
  span.kind(Span.Kind.SERVER);

  // Ensure user-code can read the current trace context
  Tracer.SpanInScope ws = tracer.withSpanInScope(span);
  try {
    parser.request(adapter, request, span);
  } finally {
    ws.close();
  }

  boolean parsedEndpoint = false;
  if (Platform.get().zipkinV1Present()) {
    zipkin.Endpoint.Builder deprecatedEndpoint = zipkin.Endpoint.builder().serviceName("");
    if ((parsedEndpoint = adapter.parseClientAddress(request, deprecatedEndpoint))) {
      span.remoteEndpoint(deprecatedEndpoint.build());
    }
  }
  if (!parsedEndpoint) {
    Endpoint.Builder remoteEndpoint = Endpoint.newBuilder();
    if (adapter.parseClientAddress(request, remoteEndpoint)) {
      span.remoteEndpoint(remoteEndpoint.build());
    }
  }
  return span.start();
}
  • 首先调用nextSpan(extractor.extract(carrier), request)从request中提取TraceContextOrSamplingFlags,并创建Span,并将Span的kind类型设置为SERVER
  • 然后调用parser.request(adapter, request, span),将request的内容,将span的name改为request的method即GET或者POST,而且会将当前请求的路径以Tag(http.path)写入Span中,这样我们就能在Zipkin的UI界面中能清晰的看出某个Span是发起了什么请求。
  • 最后为Span设置Endpoint信息,并调用start设置开始时间

handleSend方法

public void handleSend(@Nullable Resp response, @Nullable Throwable error, Span span) {
  if (span.isNoop()) return;

  // Ensure user-code can read the current trace context
  Tracer.SpanInScope ws = tracer.withSpanInScope(span);
  try {
    parser.response(adapter, response, error, span);
  } finally {
    ws.close();
    span.finish();
  }
}

handleSend比较简单,调用parser.response(adapter, response, error, span),会将HTTP状态码写入Span的Tag(http.status_code)中,如果有出错,则会将错误信息写入Tag(error)中 最后会调用Span的finish方法,而finish方法中,会调用Reporter的report方法将Span信息上报到Zipkin。

接着看下nextSpan方法

Span nextSpan(TraceContextOrSamplingFlags extracted, Req request) {
  if (extracted.sampled() == null) { // Otherwise, try to make a new decision
    extracted = extracted.sampled(sampler.trySample(adapter, request));
  }
  return extracted.context() != null
      ? tracer.joinSpan(extracted.context())
      : tracer.nextSpan(extracted);
}

从请求里提取的对象extracted(TraceContextOrSamplingFlags),如果没有sampled信息,则由HttpSampler的trySample方法来决定是否采样 如果extracted中含有TraceContext信息,则由tracer调用joinSpan,加入已存在的trace,这种情况一般是客户端代码使用将trace信息放入header,而服务端收到请求后,则自动加入客户端发起的trace中,所以当backend的请求运行到这段代码,会joinSpan 如果extracted中不含TraceContext信息,则由tracer调用nextSpan,这种情况一般是我们用户发起的请求,比如浏览器发起,则请求header中肯定是没有trace信息的,所以当frontend的请求运行到这段代码,会新建一个span

joinSpan方法

public final Span joinSpan(TraceContext context) {
  if (context == null) throw new NullPointerException("context == null");
  if (!supportsJoin) return newChild(context);
  // If we are joining a trace, we are sharing IDs with the caller
  // If the sampled flag was left unset, we need to make the decision here
  TraceContext.Builder builder = context.toBuilder();
  if (context.sampled() == null) {
    builder.sampled(sampler.isSampled(context.traceId()));
  } else {
    builder.shared(true);
  }
  return toSpan(builder.build());
}

public Span newChild(TraceContext parent) {
  if (parent == null) throw new NullPointerException("parent == null");
  return nextSpan(TraceContextOrSamplingFlags.create(parent));
}

在joinSpan方法中,会共享调用方的traceId,如果调用者没有传入sampled信息,则由服务端自己决定是否采样,即sampler.isSampled(context.traceId())

nextSpan方法

public Span nextSpan(TraceContextOrSamplingFlags extracted) {
  TraceContext parent = extracted.context();
  if (extracted.samplingFlags() != null) {
    TraceContext implicitParent = currentTraceContext.get();
    if (implicitParent == null) {
      return toSpan(newRootContext(extracted.samplingFlags(), extracted.extra()));
    }
    // fall through, with an implicit parent, not an extracted one
    parent = appendExtra(implicitParent, extracted.extra());
  }
  long nextId = Platform.get().randomLong();
  if (parent != null) {
    return toSpan(parent.toBuilder() // copies "extra" from the parent
        .spanId(nextId)
        .parentId(parent.spanId())
        .shared(false)
        .build());
  }
  TraceIdContext traceIdContext = extracted.traceIdContext();
  if (extracted.traceIdContext() != null) {
    Boolean sampled = traceIdContext.sampled();
    if (sampled == null) sampled = sampler.isSampled(traceIdContext.traceId());
    return toSpan(TraceContext.newBuilder()
        .sampled(sampled)
        .debug(traceIdContext.debug())
        .traceIdHigh(traceIdContext.traceIdHigh()).traceId(traceIdContext.traceId())
        .spanId(nextId)
        .extra(extracted.extra()).build());
  }
  // TraceContextOrSamplingFlags is a union of 3 types, we've checked all three
  throw new AssertionError("should not reach here");
}

在nextSpan方法中,首先找出合适的parent,当parent存在时,则新建一个child Span,否则返回new Span

到这里服务端接受到请求后,是如何记录Span信息的代码已经分析完毕,接下来我们看看作为客户端,我们是如何上报Span信息

FrontServlet

首先我们看到FrontServet中init方法里,我们初始化了OkHttpClient,并将TracingInterceptor拦截器添加到OkHttpClient的NetworkInterceptor拦截器栈中,然后还用CurrentTraceContext中的ExecutorService的包装方法,将Dispatcher中的ExecutorService包装后设置到OkHttpClient中。

package org.mozhu.zipkin.servlet;

import brave.http.HttpTracing;
import brave.okhttp3.TracingInterceptor;
import okhttp3.Dispatcher;
import okhttp3.OkHttpClient;
import okhttp3.Request;
import okhttp3.Response;
import org.slf4j.Logger;
import org.slf4j.LoggerFactory;

import javax.servlet.ServletConfig;
import javax.servlet.ServletException;
import javax.servlet.http.HttpServlet;
import javax.servlet.http.HttpServletRequest;
import javax.servlet.http.HttpServletResponse;
import java.io.IOException;
import java.io.PrintWriter;

public class FrontendServlet extends HttpServlet {

    private final static Logger LOGGER = LoggerFactory.getLogger(FrontendServlet.class);

    private OkHttpClient client;

    @Override
    public void init(ServletConfig config) throws ServletException {
        super.init(config);
        HttpTracing httpTracing = (HttpTracing) config.getServletContext().getAttribute("TRACING");
        client = new OkHttpClient.Builder()
                .dispatcher(new Dispatcher(
                        httpTracing.tracing().currentTraceContext()
                                .executorService(new Dispatcher().executorService())
                ))
                .addNetworkInterceptor(TracingInterceptor.create(httpTracing))
                .build();
    }

    @Override
    protected void service(HttpServletRequest req, HttpServletResponse resp) throws ServletException, IOException {
        LOGGER.info("frontend receive request");
        Request request = new Request.Builder()
                .url("http://localhost:9000/api")
                .build();

        Response response = client.newCall(request).execute();
        if (!response.isSuccessful()) throw new IOException("Unexpected code " + response);

        PrintWriter writer = resp.getWriter();
        writer.write(response.body().string());
        writer.flush();
        writer.close();
    }

}
public final class TracingInterceptor implements Interceptor {
  // ...

  final Tracer tracer;
  final String remoteServiceName;
  final HttpClientHandler<Request, Response> handler;
  final TraceContext.Injector<Request.Builder> injector;

  TracingInterceptor(HttpTracing httpTracing) {
    if (httpTracing == null) throw new NullPointerException("HttpTracing == null");
    tracer = httpTracing.tracing().tracer();
    remoteServiceName = httpTracing.serverName();
    handler = HttpClientHandler.create(httpTracing, new HttpAdapter());
    injector = httpTracing.tracing().propagation().injector(SETTER);
  }
}

TracingInterceptor中依赖Tracer,TraceContext.Injector,HttpClientHandler,HttpAdapter。

  • TraceContext.Injector – 将Trace信息注入到HTTP Request中,即放到Http headers中
  • HttpClientHandler – 和HttpServerHandler对应,也是Http处理的核心组件,基本上所有和trace相关的操作均在此类中完成
  • HttpAdapter – 能从Http request中获得各种数据,比如method,请求Path,header值等
@Override public Response intercept(Chain chain) throws IOException {
  Request request = chain.request();
  Request.Builder requestBuilder = request.newBuilder();

  Span span = handler.handleSend(injector, requestBuilder, request);
  parseServerAddress(chain.connection(), span);
  Response response = null;
  Throwable error = null;
  try (Tracer.SpanInScope ws = tracer.withSpanInScope(span)) {
    return response = chain.proceed(requestBuilder.build());
  } catch (IOException | RuntimeException | Error e) {
    error = e;
    throw e;
  } finally {
    handler.handleReceive(response, error, span);
  }
}

这里代码和TracingFilter中doFilter比较相似,是一个相反的过程

  • 首先将trace信息注入到request中,并创建Span对象
  • 然后调用chain.proceed(requestBuilder.build())来执行发送http请求
  • 最后handler.handleReceive(response, error, span)

接下来看看HttpClientHandler的handleSend方法和handleReceive方法 handleSend方法

public Span handleSend(TraceContext.Injector<Req> injector, Req request, Span span) {
  return handleSend(injector, request, request, span);
}

public <C> Span handleSend(TraceContext.Injector<C> injector, C carrier, Req request, Span span) {
  injector.inject(span.context(), carrier);
  if (span.isNoop()) return span;

  // all of the parsing here occur before a timestamp is recorded on the span
  span.kind(Span.Kind.CLIENT);

  // Ensure user-code can read the current trace context
  Tracer.SpanInScope ws = tracer.withSpanInScope(span);
  try {
    parser.request(adapter, request, span);
  } finally {
    ws.close();
  }

  boolean parsedEndpoint = false;
  if (Platform.get().zipkinV1Present()) {
    zipkin.Endpoint.Builder deprecatedEndpoint = zipkin.Endpoint.builder()
        .serviceName(serverNameSet ? serverName : "");
    if ((parsedEndpoint = adapter.parseServerAddress(request, deprecatedEndpoint))) {
      span.remoteEndpoint(deprecatedEndpoint.serviceName(serverName).build());
    }
  }
  if (!parsedEndpoint) {
    Endpoint.Builder remoteEndpoint = Endpoint.newBuilder().serviceName(serverName);
    if (adapter.parseServerAddress(request, remoteEndpoint) || serverNameSet) {
      span.remoteEndpoint(remoteEndpoint.build());
    }
  }
  return span.start();
}
  • 首先调用injector.inject(span.context(), carrier)将Trace信息注入request中,并将Span的kind类型设置为CLIENT
  • 然后调用parser.request(adapter, request, span),将request的内容,将span的name改为request的method即GET或者POST,而且会将当前请求的路径以Tag(http.path)写入Span中,这样我们就能在Zipkin的UI界面中能清晰的看出某个Span是发起了什么请求。
  • 最后为Span设置Endpoint信息,并调用start设置开始时间

handleReceive方法

public void handleReceive(@Nullable Resp response, @Nullable Throwable error, Span span) {
  if (span.isNoop()) return;
  Tracer.SpanInScope ws = tracer.withSpanInScope(span);
  try {
    parser.response(adapter, response, error, span);
  } finally {
    ws.close();
    span.finish();
  }
}

handleReceive比较简单,当客户端收到服务端的响应后handleReceive方法会被调用,即调用parser.response(adapter, response, error, span),会将HTTP状态码写入Span的Tag(http.status_code)中,如果有出错,则会将错误信息写入Tag(error)中 最后会调用Span的finish方法,而finish方法中,会调用Reporter的report方法将Span信息上报到Zipkin。

BackendServlet

最后看看BackendServlet,在收到请求后,将请求的header中参数user-name取出,添加到时间戳字符串尾部,并返回。 在上一篇博文中,我们看到如果我们向Frontend发送的请求中带有header user-name参数,Frontend会将这个值传递给Backend,然后backend会将它放到响应字符串中返回,以表明接收到该header。

package org.mozhu.zipkin.servlet;

import org.slf4j.Logger;
import org.slf4j.LoggerFactory;

import javax.servlet.ServletException;
import javax.servlet.http.HttpServlet;
import javax.servlet.http.HttpServletRequest;
import javax.servlet.http.HttpServletResponse;
import java.io.IOException;
import java.io.PrintWriter;
import java.util.Date;

public class BackendServlet extends HttpServlet {

    private final static Logger LOGGER = LoggerFactory.getLogger(BackendServlet.class);

    @Override
    protected void service(HttpServletRequest req, HttpServletResponse resp) throws ServletException, IOException {
        LOGGER.info("backend receive request");
        String username = req.getHeader("user-name");
        String result;
        if (username != null) {
            result = new Date().toString() + " " + username;
        } else {
            result = new Date().toString();
        }
        PrintWriter writer = resp.getWriter();
        writer.write(result);
        writer.flush();
        writer.close();
    }

}

至此,我们已经分析完Brave是如何在普通的web项目中使用的,分析了TracingFilter拦截请求处理请求的逻辑,也分析了OkHttpClient是如何将Trace信息放入request中的。 后面博文中,我们还会继续分析Brave和Spring Web项目的整合方法。

作者:v墨竹v | 来源:http://blog.mozhu.org

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