OkHttp3源码分析

重点

本文打算从三点来剖析OkHttp3:

  • 网络请求的整理流程-会使用
  • 拦截器模式-易扩展
  • 缓存和连接池-高性能

整体流程

我们在阅读某一类源码之前,首先要学会怎么使用,其次才是去了解内部的实现原理,实现方案上有什么技巧。

okhttp的一张流程图:


image

官方用例

  1. get使用方式
OkHttpClient client = new OkHttpClient();

String run(String url) throws IOException {
  Request request = new Request.Builder()
      .url(url)
      .build();

  Response response = client.newCall(request).execute();
  return response.body().string();
}
  1. post使用的方式
public static final MediaType JSON
    = MediaType.parse("application/json; charset=utf-8");

OkHttpClient client = new OkHttpClient();

String post(String url, String json) throws IOException {
  RequestBody body = RequestBody.create(JSON, json);
  Request request = new Request.Builder()
      .url(url)
      .post(body)
      .build();
  Response response = client.newCall(request).execute();
  return response.body().string();
}

OkHttp 官方网址

请求过程

从上面的用例和流程图可以总结出OkHttp的请求过程为:

  1. 创建OkHttpClient
  2. 创建Request
  3. 同步或者异步发出请求,并经过Interceptors处理
  4. 得到Response

然后一步一步来分析

1. 创建OkHttpClient

通过new OkHttpClient()来创建一个OkHttpClient对象,当然这个是简单的写法,通常情况下,我们需要设置缓存策略、超时时长、拦截器等等。看下源码:

public OkHttpClient() {
    this(new Builder());
  }

  OkHttpClient(Builder builder) {
    this.dispatcher = builder.dispatcher;
    this.proxy = builder.proxy;
    this.protocols = builder.protocols;
    this.connectionSpecs = builder.connectionSpecs;
    this.interceptors = Util.immutableList(builder.interceptors);
    this.networkInterceptors = Util.immutableList(builder.networkInterceptors);
    this.eventListenerFactory = builder.eventListenerFactory;
    this.proxySelector = builder.proxySelector;
    this.cookieJar = builder.cookieJar;
    this.cache = builder.cache;
    this.internalCache = builder.internalCache;
    this.socketFactory = builder.socketFactory;

    boolean isTLS = false;
    for (ConnectionSpec spec : connectionSpecs) {
      isTLS = isTLS || spec.isTls();
    }

    if (builder.sslSocketFactory != null || !isTLS) {
      this.sslSocketFactory = builder.sslSocketFactory;
      this.certificateChainCleaner = builder.certificateChainCleaner;
    } else {
      X509TrustManager trustManager = systemDefaultTrustManager();
      this.sslSocketFactory = systemDefaultSslSocketFactory(trustManager);
      this.certificateChainCleaner = CertificateChainCleaner.get(trustManager);
    }

    this.hostnameVerifier = builder.hostnameVerifier;
    this.certificatePinner = builder.certificatePinner.withCertificateChainCleaner(
        certificateChainCleaner);
    this.proxyAuthenticator = builder.proxyAuthenticator;
    this.authenticator = builder.authenticator;
    this.connectionPool = builder.connectionPool;
    this.dns = builder.dns;
    this.followSslRedirects = builder.followSslRedirects;
    this.followRedirects = builder.followRedirects;
    this.retryOnConnectionFailure = builder.retryOnConnectionFailure;
    this.connectTimeout = builder.connectTimeout;
    this.readTimeout = builder.readTimeout;
    this.writeTimeout = builder.writeTimeout;
    this.pingInterval = builder.pingInterval;
  }

第一眼看到这么多参数,是不是被吓到了,源码比较长,但是它本身没有特定的功能,Builder作为一个载体,记录下各种初始化的信息。例如,缓存地址、超时的时长、自定义拦截器等等。

这里使用了Builder设计模式,更加易读,关于Builder设计模式,可以看看这篇文章

2. 创建Request

Request类是一个纯粹的载体,封装了一个请求的Header、Method、url和body。这里源码就不贴出来了。

3. 发起请求

Request request = new Request.Builder().url(url).build();
Response response = client.newCall(request).execute();
response.body().string();

OkHttpClient实现了Call.Factory,负责创建新的Call,Call是OkHttp抽象出一个满足请求的模型。

/**
   * Prepares the {@code request} to be executed at some point in the future.
   */
  @Override 
  public Call newCall(Request request) {
    return new RealCall(this, request, false /* for web socket */);
  }

上面是OkHttpClient创建Call的过程,可以看到,RealCall是真正请求网络的类。

  1. 同步请求网络:execute()
 @Override 
 public Response execute() throws IOException {
    synchronized (this) {
    // 从这里可以看到,一个call只能执行一次,如果需要多次执行,可以使用clone()方法。
      if (executed) throw new IllegalStateException("Already Executed");
      executed = true;
    }
    captureCallStackTrace();
    try {
      client.dispatcher().executed(this);
      Response result = getResponseWithInterceptorChain();
      if (result == null) throw new IOException("Canceled");
      return result;
    } finally {
      client.dispatcher().finished(this);
    }
  }
  1. 异步请求网络:enqueue(callBack)
@Override 
public void enqueue(Callback responseCallback) {
    synchronized (this) {
      if (executed) throw new IllegalStateException("Already Executed");
      executed = true;
    }
    captureCallStackTrace();
    client.dispatcher().enqueue(new AsyncCall(responseCallback));
  }

上面的同步和异步的网络请求做了四件事情:

  1. 判断是否执行过,每个call请求只能请求一次,如果需要重复执行可以使用clone()方法
  2. 获取分发器dispatcher,执行execute()或者enqueue(new AsyncCall(callback))
  3. 调用getResponseWithInterceptorChain()方法,获取网络请求的结果,异步请求都在AsyncCall中执行了。
  4. 最后通知dispatcher执行完毕。

上面的四个步骤中涉及到了Dispatcher和AsyncCall两个类,这里做个简单的介绍:

  • Dispatcher
    Disaptcher是一个分发器,它持有线程池、异步任务队列和同步任务队列,会依照不同的策略执行。
  • AsyncCall
    ,AsyncCall是RealCall的内部类,持有RealCall的引用,实质上是一个Runnable,对RealCall做了一层封装。

拦截器

OkHttpClient中真正发出网络请求,解析返回结果的步骤是getResponseWithInterceptorChain()这个方法.

Response getResponseWithInterceptorChain() throws IOException {
    // Build a full stack of interceptors.
    List<Interceptor> interceptors = new ArrayList<>();
    interceptors.addAll(client.interceptors());
    interceptors.add(retryAndFollowUpInterceptor);
    interceptors.add(new BridgeInterceptor(client.cookieJar()));
    interceptors.add(new CacheInterceptor(client.internalCache()));
    interceptors.add(new ConnectInterceptor(client));
    if (!forWebSocket) {
      interceptors.addAll(client.networkInterceptors());
    }
    interceptors.add(new CallServerInterceptor(forWebSocket));

    Interceptor.Chain chain = new RealInterceptorChain(
        interceptors, null, null, null, 0, originalRequest);
    return chain.proceed(originalRequest);
  }

Interceptor是OkHttp最核心的一个东西,采用了责任链的设计模式,不要误以为它只是负责拦截请求进行一些额外的处理(例如cookie),实际上它把时机的网络请求、缓存、透明压缩等功能都统一了起来,每一个功能只是一个Interceptor,它们再连接成为Interceptor.Chain,环环相扣,最终圆满完成一次网络请求。interceptor的顺序也很重要,比如负责网络请求的Interceptor必须放在最后,负责缓存策略的Inteceptor需要放到前面。

/**
 * A concrete interceptor chain that carries the entire interceptor chain: all application
 * interceptors, the OkHttp core, all network interceptors, and finally the network caller.
 */
public final class RealInterceptorChain implements Interceptor.Chain {
  private final List<Interceptor> interceptors;
  private final StreamAllocation streamAllocation;
  private final HttpCodec httpCodec;
  private final RealConnection connection;
  private final int index;
  private final Request request;
  private int calls;

  public RealInterceptorChain(List<Interceptor> interceptors, StreamAllocation streamAllocation,
      HttpCodec httpCodec, RealConnection connection, int index, Request request) {
    this.interceptors = interceptors;
    this.connection = connection;
    this.streamAllocation = streamAllocation;
    this.httpCodec = httpCodec;
    this.index = index;
    this.request = request;
  }

  @Override public Connection connection() {
    return connection;
  }

  public StreamAllocation streamAllocation() {
    return streamAllocation;
  }

  public HttpCodec httpStream() {
    return httpCodec;
  }

  @Override public Request request() {
    return request;
  }

  @Override public Response proceed(Request request) throws IOException {
    return proceed(request, streamAllocation, httpCodec, connection);
  }

  public Response proceed(Request request, StreamAllocation streamAllocation, HttpCodec httpCodec,
      RealConnection connection) throws IOException {
    if (index >= interceptors.size()) throw new AssertionError();

    calls++;

    // If we already have a stream, confirm that the incoming request will use it.
    if (this.httpCodec != null && !this.connection.supportsUrl(request.url())) {
      throw new IllegalStateException("network interceptor " + interceptors.get(index - 1)
          + " must retain the same host and port");
    }

    // If we already have a stream, confirm that this is the only call to chain.proceed().
    if (this.httpCodec != null && calls > 1) {
      throw new IllegalStateException("network interceptor " + interceptors.get(index - 1)
          + " must call proceed() exactly once");
    }

    // Call the next interceptor in the chain.
    RealInterceptorChain next = new RealInterceptorChain(
        interceptors, streamAllocation, httpCodec, connection, index + 1, request);
    Interceptor interceptor = interceptors.get(index);
    Response response = interceptor.intercept(next);

    // Confirm that the next interceptor made its required call to chain.proceed().
    if (httpCodec != null && index + 1 < interceptors.size() && next.calls != 1) {
      throw new IllegalStateException("network interceptor " + interceptor
          + " must call proceed() exactly once");
    }

    // Confirm that the intercepted response isn't null.
    if (response == null) {
      throw new NullPointerException("interceptor " + interceptor + " returned null");
    }

    return response;
  }
}

RealInterceptorChain的主要作用是传递参数和一个一个执行拦截器,并且设定一些条件,例如,每个拦截器只能调用一次chain.proceed这个方法。

OkHttp拦截器分析

先列出之前在getResponseWithInterceptorChain方法中添加的各Interceptor,概括一下它们分别负责什么功能:

  • client.interceptors()用户自定义的Interceptor,能拦截到所有的请求
  • RetryAndFollowUpInterceptor负责失败重连和重定向相关
  • BridgeInterceptor负责配置请求的头信息,比如Keep-Alive、gzip、Cookie等可以优化请求
  • CacheInterceptor负责缓存管理,使用DiskLruCache做本地缓存,CacheStrategy决定缓存策略
  • ConnectInterceptor开始与目标服务器建立连接,获得RealConnection
  • client.networkInterceptors()用户自定义的Interceptor,仅在生产网络请求时生效
  • CallServerInterceptor向服务器发出一次网络请求的地方。

RetryAndFollowUpInterceptor

public Response intercept(Chain chain) throws IOException {
    Request request = chain.request();

    streamAllocation = new StreamAllocation(
        client.connectionPool(), createAddress(request.url()), callStackTrace);

    int followUpCount = 0;
    Response priorResponse = null;
    while (true) {
      if (canceled) {
        streamAllocation.release();
        throw new IOException("Canceled");
      }

      Response response = null;
      boolean releaseConnection = true;
      try {
        response = ((RealInterceptorChain) chain).proceed(request, streamAllocation, null, null);
        releaseConnection = false;
      } catch (RouteException e) {
        // The attempt to connect via a route failed. The request will not have been sent.
        if (!recover(e.getLastConnectException(), false, request)) {
          throw e.getLastConnectException();
        }
        releaseConnection = false;
        continue;
      } catch (IOException e) {
        // An attempt to communicate with a server failed. The request may have been sent.
        boolean requestSendStarted = !(e instanceof ConnectionShutdownException);
        if (!recover(e, requestSendStarted, request)) throw e;
        releaseConnection = false;
        continue;
      } finally {
        // We're throwing an unchecked exception. Release any resources.
        if (releaseConnection) {
          streamAllocation.streamFailed(null);
          streamAllocation.release();
        }
      }

      // Attach the prior response if it exists. Such responses never have a body.
      if (priorResponse != null) {
        response = response.newBuilder()
            .priorResponse(priorResponse.newBuilder()
                    .body(null)
                    .build())
            .build();
      }

      Request followUp = followUpRequest(response);

      if (followUp == null) {
        if (!forWebSocket) {
          streamAllocation.release();
        }
        return response;
      }

      closeQuietly(response.body());

      if (++followUpCount > MAX_FOLLOW_UPS) {
        streamAllocation.release();
        throw new ProtocolException("Too many follow-up requests: " + followUpCount);
      }

      if (followUp.body() instanceof UnrepeatableRequestBody) {
        streamAllocation.release();
        throw new HttpRetryException("Cannot retry streamed HTTP body", response.code());
      }

      if (!sameConnection(response, followUp.url())) {
        streamAllocation.release();
        streamAllocation = new StreamAllocation(
            client.connectionPool(), createAddress(followUp.url()), callStackTrace);
      } else if (streamAllocation.codec() != null) {
        throw new IllegalStateException("Closing the body of " + response
            + " didn't close its backing stream. Bad interceptor?");
      }

      request = followUp;
      priorResponse = response;
    }
  }
  • streamAllocation对象是在这个Interceptor中创建的
  • 在followUpRequest方法中判断了是否需要重定向以及是否需要重连,需要重连时会返回一个request
  • request为null说明不需要重连,则直接返回response,否则轮训重走网络请求的流程。

BridgeInterceptor

public Response intercept(Chain chain) throws IOException {
    Request userRequest = chain.request();
    Request.Builder requestBuilder = userRequest.newBuilder();

    RequestBody body = userRequest.body();
    if (body != null) {
      MediaType contentType = body.contentType();
      if (contentType != null) {
        requestBuilder.header("Content-Type", contentType.toString());
      }

      long contentLength = body.contentLength();
      if (contentLength != -1) {
        requestBuilder.header("Content-Length", Long.toString(contentLength));
        requestBuilder.removeHeader("Transfer-Encoding");
      } else {
        requestBuilder.header("Transfer-Encoding", "chunked");
        requestBuilder.removeHeader("Content-Length");
      }
    }

    if (userRequest.header("Host") == null) {
      requestBuilder.header("Host", hostHeader(userRequest.url(), false));
    }

    if (userRequest.header("Connection") == null) {
      requestBuilder.header("Connection", "Keep-Alive");
    }

    // If we add an "Accept-Encoding: gzip" header field we're responsible for also decompressing
    // the transfer stream.
    boolean transparentGzip = false;
    if (userRequest.header("Accept-Encoding") == null && userRequest.header("Range") == null) {
      transparentGzip = true;
      requestBuilder.header("Accept-Encoding", "gzip");
    }

    List<Cookie> cookies = cookieJar.loadForRequest(userRequest.url());
    if (!cookies.isEmpty()) {
      requestBuilder.header("Cookie", cookieHeader(cookies));
    }

    if (userRequest.header("User-Agent") == null) {
      requestBuilder.header("User-Agent", Version.userAgent());
    }

    Response networkResponse = chain.proceed(requestBuilder.build());

    HttpHeaders.receiveHeaders(cookieJar, userRequest.url(), networkResponse.headers());

    Response.Builder responseBuilder = networkResponse.newBuilder()
        .request(userRequest);

    if (transparentGzip
        && "gzip".equalsIgnoreCase(networkResponse.header("Content-Encoding"))
        && HttpHeaders.hasBody(networkResponse)) {
      GzipSource responseBody = new GzipSource(networkResponse.body().source());
      Headers strippedHeaders = networkResponse.headers().newBuilder()
          .removeAll("Content-Encoding")
          .removeAll("Content-Length")
          .build();
      responseBuilder.headers(strippedHeaders);
      responseBuilder.body(new RealResponseBody(strippedHeaders, Okio.buffer(responseBody)));
    }

    return responseBuilder.build();
  }
  • BridgeInteceptor的Interceptor基本上都是添加请求的头信息,例如启动是否使用长连接Keep-Alive,设置Cookie,启动压缩与解压gzip等。

CacheInterceptor

public Response intercept(Chain chain) throws IOException {
    Response cacheCandidate = cache != null
        ? cache.get(chain.request())
        : null;

    long now = System.currentTimeMillis();

    CacheStrategy strategy = new CacheStrategy.Factory(now, chain.request(), cacheCandidate).get();
    Request networkRequest = strategy.networkRequest;
    Response cacheResponse = strategy.cacheResponse;

    if (cache != null) {
      cache.trackResponse(strategy);
    }

    if (cacheCandidate != null && cacheResponse == null) {
      closeQuietly(cacheCandidate.body()); // The cache candidate wasn't applicable. Close it.
    }

    // If we're forbidden from using the network and the cache is insufficient, fail.
    if (networkRequest == null && cacheResponse == null) {
      return new Response.Builder()
          .request(chain.request())
          .protocol(Protocol.HTTP_1_1)
          .code(504)
          .message("Unsatisfiable Request (only-if-cached)")
          .body(Util.EMPTY_RESPONSE)
          .sentRequestAtMillis(-1L)
          .receivedResponseAtMillis(System.currentTimeMillis())
          .build();
    }

    // If we don't need the network, we're done.
    if (networkRequest == null) {
      return cacheResponse.newBuilder()
          .cacheResponse(stripBody(cacheResponse))
          .build();
    }

    Response networkResponse = null;
    try {
      networkResponse = chain.proceed(networkRequest);
    } finally {
      // If we're crashing on I/O or otherwise, don't leak the cache body.
      if (networkResponse == null && cacheCandidate != null) {
        closeQuietly(cacheCandidate.body());
      }
    }

    // If we have a cache response too, then we're doing a conditional get.
    if (cacheResponse != null) {
      if (networkResponse.code() == HTTP_NOT_MODIFIED) {
        Response response = cacheResponse.newBuilder()
            .headers(combine(cacheResponse.headers(), networkResponse.headers()))
            .sentRequestAtMillis(networkResponse.sentRequestAtMillis())
            .receivedResponseAtMillis(networkResponse.receivedResponseAtMillis())
            .cacheResponse(stripBody(cacheResponse))
            .networkResponse(stripBody(networkResponse))
            .build();
        networkResponse.body().close();

        // Update the cache after combining headers but before stripping the
        // Content-Encoding header (as performed by initContentStream()).
        cache.trackConditionalCacheHit();
        cache.update(cacheResponse, response);
        return response;
      } else {
        closeQuietly(cacheResponse.body());
      }
    }

    Response response = networkResponse.newBuilder()
        .cacheResponse(stripBody(cacheResponse))
        .networkResponse(stripBody(networkResponse))
        .build();

    if (cache != null) {
      if (HttpHeaders.hasBody(response) && CacheStrategy.isCacheable(response, networkRequest)) {
        // Offer this request to the cache.
        CacheRequest cacheRequest = cache.put(response);
        return cacheWritingResponse(cacheRequest, response);
      }

      if (HttpMethod.invalidatesCache(networkRequest.method())) {
        try {
          cache.remove(networkRequest);
        } catch (IOException ignored) {
          // The cache cannot be written.
        }
      }
    }

    return response;
  }
  • 首先根据request从cache中取response
  • 将request和respnse传入CacheStrategy根据缓存策略(比如仅适用网络加载,仅适用缓存,缓存时效等)得到有策略处理后的networkRequestcacheResponse
  • 若缓存策略要求仅从缓存中加载,且缓存未命中,则本次请求失败
  • 若缓存策略不要求仅从网络获取数据,则直接返回缓存内容
  • 以上条件不满足,则把获得response的任务交给下一个Chain,开始执行网络请求。
  • 得到网络请求结果后,如果已经有缓存了,则用最新的网络数据更新缓存。
  • 最后将本次请求的结果response根据cacheRequest写入缓存

ConnectInterceptor

public Response intercept(Chain chain) throws IOException {
    RealInterceptorChain realChain = (RealInterceptorChain) chain;
    Request request = realChain.request();
    StreamAllocation streamAllocation = realChain.streamAllocation();

    // We need the network to satisfy this request. Possibly for validating a conditional GET.
    boolean doExtensiveHealthChecks = !request.method().equals("GET");
    HttpCodec httpCodec = streamAllocation.newStream(client, doExtensiveHealthChecks);
    RealConnection connection = streamAllocation.connection();

    return realChain.proceed(request, streamAllocation, httpCodec, connection);
  }
  • 主要为下一步最终进行网络请求做铺垫,这里获得了HttpCodecRealConnection,然后将这些参数传入下一个Chain。
  • newStream方法中会去先尝试从RealConnectionPool中寻找已经存在的连接,若未命中则创建一个连接并与服务器握手对接。
  • 在完成连接后会将Socket对象通过Okio封装成BufferedSource和BufferedSink,并将两者传入HttpCodec,在下一步网络请求时会用到。
source = Okio.buffer(Okio.source(rawSocket));
sink = Okio.buffer(Okio.sink(rawSocket));

CallServerInterceptor

public Response intercept(Chain chain) throws IOException {
    RealInterceptorChain realChain = (RealInterceptorChain) chain;
    HttpCodec httpCodec = realChain.httpStream();
    StreamAllocation streamAllocation = realChain.streamAllocation();
    RealConnection connection = (RealConnection) realChain.connection();
    Request request = realChain.request();

    long sentRequestMillis = System.currentTimeMillis();
    httpCodec.writeRequestHeaders(request);

    Response.Builder responseBuilder = null;
    if (HttpMethod.permitsRequestBody(request.method()) && request.body() != null) {
      // If there's a "Expect: 100-continue" header on the request, wait for a "HTTP/1.1 100
      // Continue" response before transmitting the request body. If we don't get that, return what
      // we did get (such as a 4xx response) without ever transmitting the request body.
      if ("100-continue".equalsIgnoreCase(request.header("Expect"))) {
        httpCodec.flushRequest();
        responseBuilder = httpCodec.readResponseHeaders(true);
      }

      if (responseBuilder == null) {
        // Write the request body if the "Expect: 100-continue" expectation was met.
        Sink requestBodyOut = httpCodec.createRequestBody(request, request.body().contentLength());
        BufferedSink bufferedRequestBody = Okio.buffer(requestBodyOut);
        request.body().writeTo(bufferedRequestBody);
        bufferedRequestBody.close();
      } else if (!connection.isMultiplexed()) {
        // If the "Expect: 100-continue" expectation wasn't met, prevent the HTTP/1 connection from
        // being reused. Otherwise we're still obligated to transmit the request body to leave the
        // connection in a consistent state.
        streamAllocation.noNewStreams();
      }
    }

    httpCodec.finishRequest();

    if (responseBuilder == null) {
      responseBuilder = httpCodec.readResponseHeaders(false);
    }

    Response response = responseBuilder
        .request(request)
        .handshake(streamAllocation.connection().handshake())
        .sentRequestAtMillis(sentRequestMillis)
        .receivedResponseAtMillis(System.currentTimeMillis())
        .build();

    int code = response.code();
    if (forWebSocket && code == 101) {
      // Connection is upgrading, but we need to ensure interceptors see a non-null response body.
      response = response.newBuilder()
          .body(Util.EMPTY_RESPONSE)
          .build();
    } else {
      response = response.newBuilder()
          .body(httpCodec.openResponseBody(response))
          .build();
    }

    if ("close".equalsIgnoreCase(response.request().header("Connection"))
        || "close".equalsIgnoreCase(response.header("Connection"))) {
      streamAllocation.noNewStreams();
    }

    if ((code == 204 || code == 205) && response.body().contentLength() > 0) {
      throw new ProtocolException(
          "HTTP " + code + " had non-zero Content-Length: " + response.body().contentLength());
    }

    return response;
  }
  • 可以发现具体的实现都交给了HttpCodec,它是对Http协议操作的一种抽象,针对HTTP/1.1与HTTP2有Http1CodecHttp2Codec两种实现。
  • 方法的命名都是read和write,因为HttpCodec中最后的请求和响应是由上一步封装的BufferedSource和BufferedSink来完成的,sink负责输出流,将写入的数据交由socket发出,source负责输入流,从socket中读取响应数据。

OkHttp缓存相关

  • 缓存策略CacheStrategy
  • 连接池RealConnectPool

缓存策略

缓存策略主要是是CacheStrategy这个类,依赖于本地缓存CacheHttp Header缓存配置。
Cache使用了DiskLruCache作为缓存容器,以request.url作为key来存储和读取response,这是一种很常见的缓存方式。
Http HEader使用Http协议中约定的Cache-ControlExpiresETag、Last-ModifiedDate`等字段和服务端交互,由这些字段信息决定是否使用缓存,关于这些字段的含义可以查看Http协议中的定义。

public final class CacheStrategy {
  /** The request to send on the network, or null if this call doesn't use the network. */
  public final @Nullable Request networkRequest;

  /** The cached response to return or validate; or null if this call doesn't use a cache. */
  public final @Nullable Response cacheResponse;

  CacheStrategy(Request networkRequest, Response cacheResponse) {
    this.networkRequest = networkRequest;
    this.cacheResponse = cacheResponse;
  }

  /** Returns true if {@code response} can be stored to later serve another request. */
  public static boolean isCacheable(Response response, Request request) {
    // Always go to network for uncacheable response codes (RFC 7231 section 6.1),
    // This implementation doesn't support caching partial content.
    switch (response.code()) {
      case HTTP_OK:
      case HTTP_NOT_AUTHORITATIVE:
      case HTTP_NO_CONTENT:
      case HTTP_MULT_CHOICE:
      case HTTP_MOVED_PERM:
      case HTTP_NOT_FOUND:
      case HTTP_BAD_METHOD:
      case HTTP_GONE:
      case HTTP_REQ_TOO_LONG:
      case HTTP_NOT_IMPLEMENTED:
      case StatusLine.HTTP_PERM_REDIRECT:
        // These codes can be cached unless headers forbid it.
        break;

      case HTTP_MOVED_TEMP:
      case StatusLine.HTTP_TEMP_REDIRECT:
        // These codes can only be cached with the right response headers.
        // http://tools.ietf.org/html/rfc7234#section-3
        // s-maxage is not checked because OkHttp is a private cache that should ignore s-maxage.
        if (response.header("Expires") != null
            || response.cacheControl().maxAgeSeconds() != -1
            || response.cacheControl().isPublic()
            || response.cacheControl().isPrivate()) {
          break;
        }
        // Fall-through.

      default:
        // All other codes cannot be cached.
        return false;
    }

    // A 'no-store' directive on request or response prevents the response from being cached.
    return !response.cacheControl().noStore() && !request.cacheControl().noStore();
  }

  public static class Factory {
    final long nowMillis;
    final Request request;
    final Response cacheResponse;

    /** The server's time when the cached response was served, if known. */
    private Date servedDate;
    private String servedDateString;

    /** The last modified date of the cached response, if known. */
    private Date lastModified;
    private String lastModifiedString;

    /**
     * The expiration date of the cached response, if known. If both this field and the max age are
     * set, the max age is preferred.
     */
    private Date expires;

    /**
     * Extension header set by OkHttp specifying the timestamp when the cached HTTP request was
     * first initiated.
     */
    private long sentRequestMillis;

    /**
     * Extension header set by OkHttp specifying the timestamp when the cached HTTP response was
     * first received.
     */
    private long receivedResponseMillis;

    /** Etag of the cached response. */
    private String etag;

    /** Age of the cached response. */
    private int ageSeconds = -1;

    public Factory(long nowMillis, Request request, Response cacheResponse) {
      this.nowMillis = nowMillis;
      this.request = request;
      this.cacheResponse = cacheResponse;

      if (cacheResponse != null) {
        this.sentRequestMillis = cacheResponse.sentRequestAtMillis();
        this.receivedResponseMillis = cacheResponse.receivedResponseAtMillis();
        Headers headers = cacheResponse.headers();
        for (int i = 0, size = headers.size(); i < size; i++) {
          String fieldName = headers.name(i);
          String value = headers.value(i);
          if ("Date".equalsIgnoreCase(fieldName)) {
            servedDate = HttpDate.parse(value);
            servedDateString = value;
          } else if ("Expires".equalsIgnoreCase(fieldName)) {
            expires = HttpDate.parse(value);
          } else if ("Last-Modified".equalsIgnoreCase(fieldName)) {
            lastModified = HttpDate.parse(value);
            lastModifiedString = value;
          } else if ("ETag".equalsIgnoreCase(fieldName)) {
            etag = value;
          } else if ("Age".equalsIgnoreCase(fieldName)) {
            ageSeconds = HttpHeaders.parseSeconds(value, -1);
          }
        }
      }
    }

    /**
     * Returns a strategy to satisfy {@code request} using the a cached response {@code response}.
     */
    public CacheStrategy get() {
      CacheStrategy candidate = getCandidate();

      if (candidate.networkRequest != null && request.cacheControl().onlyIfCached()) {
        // 禁止使用网络请求,并且没有渠道cache
        return new CacheStrategy(null, null);
      }

      return candidate;
    }

    /** 假设可以使用网络,返回一个策略. */
    private CacheStrategy getCandidate() {
      // No cached response.
      if (cacheResponse == null) {
        return new CacheStrategy(request, null);
      }

      // 缓存结果缺少握手信息,直接走网络请求流程.
      if (request.isHttps() && cacheResponse.handshake() == null) {
        return new CacheStrategy(request, null);
      }

      // 根据当前缓存Response的code值,http header等信息判断本次缓存是否过期,是否可用,如果不可用则直接走网络请求流程
      if (!isCacheable(cacheResponse, request)) {
        return new CacheStrategy(request, null);
      }
 //本次请求header包含`no-cache`,`If-Modified-Since`,`If-None-Match`等字段直接走网络请求
      
      CacheControl requestCaching = request.cacheControl();
      if (requestCaching.noCache() || hasConditions(request)) {
        return new CacheStrategy(request, null);
      }

      long ageMillis = cacheResponseAge();
      long freshMillis = computeFreshnessLifetime();

      if (requestCaching.maxAgeSeconds() != -1) {
        freshMillis = Math.min(freshMillis, SECONDS.toMillis(requestCaching.maxAgeSeconds()));
      }

      long minFreshMillis = 0;
      if (requestCaching.minFreshSeconds() != -1) {
        minFreshMillis = SECONDS.toMillis(requestCaching.minFreshSeconds());
      }

      long maxStaleMillis = 0;
      CacheControl responseCaching = cacheResponse.cacheControl();
      if (!responseCaching.mustRevalidate() && requestCaching.maxStaleSeconds() != -1) {
        maxStaleMillis = SECONDS.toMillis(requestCaching.maxStaleSeconds());
      }

      if (!responseCaching.noCache() && ageMillis + minFreshMillis < freshMillis + maxStaleMillis) {
        Response.Builder builder = cacheResponse.newBuilder();
        if (ageMillis + minFreshMillis >= freshMillis) {
          builder.addHeader("Warning", "110 HttpURLConnection \"Response is stale\"");
        }
        long oneDayMillis = 24 * 60 * 60 * 1000L;
        if (ageMillis > oneDayMillis && isFreshnessLifetimeHeuristic()) {
          builder.addHeader("Warning", "113 HttpURLConnection \"Heuristic expiration\"");
        }
        return new CacheStrategy(null, builder.build());
      }

      // Find a condition to add to the request. If the condition is satisfied, the response body
      // will not be transmitted.
      String conditionName;
      String conditionValue;
      if (etag != null) {
        conditionName = "If-None-Match";
        conditionValue = etag;
      } else if (lastModified != null) {
        conditionName = "If-Modified-Since";
        conditionValue = lastModifiedString;
      } else if (servedDate != null) {
        conditionName = "If-Modified-Since";
        conditionValue = servedDateString;
      } else {
        return new CacheStrategy(request, null); // No condition! Make a regular request.
      }

      Headers.Builder conditionalRequestHeaders = request.headers().newBuilder();
      Internal.instance.addLenient(conditionalRequestHeaders, conditionName, conditionValue);

      Request conditionalRequest = request.newBuilder()
          .headers(conditionalRequestHeaders.build())
          .build();
      return new CacheStrategy(conditionalRequest, cacheResponse);
    }

    /**
     * Returns the number of milliseconds that the response was fresh for, starting from the served
     * date.
     */
    private long computeFreshnessLifetime() {
      CacheControl responseCaching = cacheResponse.cacheControl();
      if (responseCaching.maxAgeSeconds() != -1) {
        return SECONDS.toMillis(responseCaching.maxAgeSeconds());
      } else if (expires != null) {
        long servedMillis = servedDate != null
            ? servedDate.getTime()
            : receivedResponseMillis;
        long delta = expires.getTime() - servedMillis;
        return delta > 0 ? delta : 0;
      } else if (lastModified != null
          && cacheResponse.request().url().query() == null) {
        // As recommended by the HTTP RFC and implemented in Firefox, the
        // max age of a document should be defaulted to 10% of the
        // document's age at the time it was served. Default expiration
        // dates aren't used for URIs containing a query.
        long servedMillis = servedDate != null
            ? servedDate.getTime()
            : sentRequestMillis;
        long delta = servedMillis - lastModified.getTime();
        return delta > 0 ? (delta / 10) : 0;
      }
      return 0;
    }

    /**
     * Returns the current age of the response, in milliseconds. The calculation is specified by RFC
     * 2616, 13.2.3 Age Calculations.
     */
    private long cacheResponseAge() {
      long apparentReceivedAge = servedDate != null
          ? Math.max(0, receivedResponseMillis - servedDate.getTime())
          : 0;
      long receivedAge = ageSeconds != -1
          ? Math.max(apparentReceivedAge, SECONDS.toMillis(ageSeconds))
          : apparentReceivedAge;
      long responseDuration = receivedResponseMillis - sentRequestMillis;
      long residentDuration = nowMillis - receivedResponseMillis;
      return receivedAge + responseDuration + residentDuration;
    }

    /**
     * Returns true if computeFreshnessLifetime used a heuristic. If we used a heuristic to serve a
     * cached response older than 24 hours, we are required to attach a warning.
     */
    private boolean isFreshnessLifetimeHeuristic() {
      return cacheResponse.cacheControl().maxAgeSeconds() == -1 && expires == null;
    }

    /**
     * Returns true if the request contains conditions that save the server from sending a response
     * that the client has locally. When a request is enqueued with its own conditions, the built-in
     * response cache won't be used.
     */
    private static boolean hasConditions(Request request) {
      return request.header("If-Modified-Since") != null || request.header("If-None-Match") != null;
    }
  }
}
  • 首先在Factory方法中获取它所依赖的参数,就是我们之前提到过的Cache中渠道的缓存和Http Header配置信息。
  • 然后进入比较核心的方法getCandidate,在这里会根据之前拿到的依赖参数通过各种if判断返回不同的CacheStrategy对象
  • 本职上其实返回不同的networkRequestcacheResponse,这样上层只需要关注这两个参数就知道下一步该如何做处理,复杂的判断都封装到了CacheStrategy对外透明,具体判断过程在代码中做了注释。

连接池

okHttp利用连接池来复用连接,避免反复握手建立连接,并且具备在合适的时候挥手连接的能力,这也是okhttp设计出彩的地方之一。

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