撸Retrofit2源码

本文使用Retrofit-2.6.2源码

切入点：

• retrofit对象构造

• new Retrofit.Builder()
                  .baseUrl(Constants.BASE_URL)
                  .client(getOkHttpClient())
                  .addConverterFactory(GsonConverterFactory.create())
                  .addCallAdapterFactory(RxJava2CallAdapterFactory.create())
                  .build();

• 调用请求接口retrofit.create(final Class<T> service)

---

Retrofit对象构造

Retrofit对象构造使用的是构造者模式，主要看retrofit2.Retrofit.Builder类：

public static final class Builder {
    private final Platform platform;
    private @Nullable okhttp3.Call.Factory callFactory;
    private @Nullable HttpUrl baseUrl;
    private final List<Converter.Factory> converterFactories = new ArrayList<>();
    private final List<CallAdapter.Factory> callAdapterFactories = new ArrayList<>();
    private @Nullable Executor callbackExecutor;
    private boolean validateEagerly;
		...
  }

Builder主要构造的几个成员变量：

• platform：Android平台还是非Android平台（Java8）
• callFactory：实现newCall方法的类，一般是OkHttpClient
• baseUrl：hostUrl
• converterFactories：对网络请求对响应进行转化
• callAdapterFactories；对请求的封装
• callbackExecutor：Android平台下默认为主线程handler执行
• validateEagerly：默认为false，为true的时候提前加载请求方法

retrofit.create()

整个Retrofit的使用就是从create方法开始的：

public <T> T create(final Class<T> service) {
  // 1 监测service请求接口是不是有效的
  Utils.validateServiceInterface(service);
  if (validateEagerly) {
    // 2 如果validateEagerly=true，那么预加载请求的方法
    eagerlyValidateMethods(service);
  }
  //3 使用动态代理处理service请求接口
  return (T) Proxy.newProxyInstance(service.getClassLoader(), new Class<?>[] { service },
      new InvocationHandler() {
        private final Platform platform = Platform.get();
        private final Object[] emptyArgs = new Object[0];

        @Override public @Nullable Object invoke(Object proxy, Method method,
            @Nullable Object[] args) throws Throwable {
          // If the method is a method from Object then defer to normal invocation.
          if (method.getDeclaringClass() == Object.class) {
            return method.invoke(this, args);
          }
          if (platform.isDefaultMethod(method)) {
            return platform.invokeDefaultMethod(method, service, proxy, args);
          }
          return loadServiceMethod(method).invoke(args != null ? args : emptyArgs);
        }
      });
}

1. 注释1处，监测service请求接口是不是有效的：

   • 条件一：service类是一个接口

   • 条件二：service接口中不包含其他子接口

     则认为有效，否则直接抛异常

   static <T> void validateServiceInterface(Class<T> service) {
     if (!service.isInterface()) {
     	//如果不是接口直接抛出异常
       throw new IllegalArgumentException("API declarations must be interfaces.");
     }
       
     if (service.getInterfaces().length > 0) {
     // 如果service中包含其他子接口，抛出异常
       throw new IllegalArgumentException("API interfaces must not extend other interfaces.");
     }
   }

2. 注释2处，如果validateEagerly=true，那么预加载请求的方法（默认validateEagerly=false，不会执行这个方法）：

   private void eagerlyValidateMethods(Class<?> service) {
     //获取当前的平台，Android端开发的时候是Android（）
     Platform platform = Platform.get();
     //遍历接口中的所有方法，挑选不是默认、静态的方法
     for (Method method : service.getDeclaredMethods()) {
       if (!platform.isDefaultMethod(method) && !Modifier.isStatic(method.getModifiers())) {
         // 将挑选出的方法进行包装，加入缓存
         loadServiceMethod(method);
       }
     }
   }

3. 注释3处，使用动态代理处理service请求接口，在动态代理的invoke()方法中实现了请求接口的封装：

   @Override public @Nullable Object invoke(Object proxy, Method method,
                    @Nullable Object[] args) throws Throwable {
   // If the method is a method from Object then defer to normal invocation.
   if (method.getDeclaringClass() == Object.class) {
        // 如果这个方法是继承自object，那么这个方法不做处理，直接返回被代理的方法
    return method.invoke(this, args);
   }
      if (platform.isDefaultMethod(method)) {
       // 默认方法只会在Java8中出现，Android平台上直接会抛异常
    return platform.invokeDefaultMethod(method, service, proxy, args);
   }
        // 4 这里将请求进行封装、加入缓存，最后invoke调用
   return loadServiceMethod(method).invoke(args != null ? args : emptyArgs);
      }

   
4. 注释4处，将请求进行封装、加入缓存，最后invoke调用：

   ```java
     ServiceMethod<?> loadServiceMethod(Method method) {
       // 在缓存中获取请求方法，如果存在直接返回
       ServiceMethod<?> result = serviceMethodCache.get(method);
       if (result != null) return result;
   
       synchronized (serviceMethodCache) {
         result = serviceMethodCache.get(method);
         if (result == null) {
           // 5 将请求方法进行封装得到一个ServiceMethod对象
           result = ServiceMethod.parseAnnotations(this, method);
           serviceMethodCache.put(method, result);
         }
       }
       return result;
     }

5. 注释5处，通过ServiceMethod的静态方法parseAnnotations()将请求方法进行封装得到一个ServiceMethod对象：

   static <T> ServiceMethod<T> parseAnnotations(Retrofit retrofit, Method method) {
     // 将请求方法的注解、参数、参数的注解等提取并生成requestFactory对象
     RequestFactory requestFactory = RequestFactory.parseAnnotations(retrofit, method);
   // 获取请求方法的返回类型
     Type returnType = method.getGenericReturnType();
     if (Utils.hasUnresolvableType(returnType)) {
       // 如果是不是一个Class的类型或者不是参数化的Class类型，你就抛出异常
       throw methodError(method,
           "Method return type must not include a type variable or wildcard: %s", returnType);
     }
     if (returnType == void.class) {
       // 如果返回类型为空，抛出异常
       throw methodError(method, "Service methods cannot return void.");
     }
      
     return HttpServiceMethod.parseAnnotations(retrofit, method, requestFactory);
   }

   parseAnnotations()的RequestFactory requestFactory = RequestFactory.parseAnnotations(retrofit, method);这句话将请求方法的注解、参数、参数的注解等提取并生成requestFactory对象：

   static RequestFactory parseAnnotations(Retrofit retrofit, Method method) {
     return new Builder(retrofit, method).build();
   }
   
       RequestFactory build() {
       for (Annotation annotation : methodAnnotations) {
       // 这里解析请求方法的注解：请求类型、是否有请求体、请求的url、请求头
         parseMethodAnnotation(annotation);
       }
   	...
       int parameterCount = parameterAnnotationsArray.length;
       parameterHandlers = new ParameterHandler<?>[parameterCount];
         // 逐一解析参数
       for (int p = 0, lastParameter = parameterCount - 1; p < parameterCount; p++) {
         parameterHandlers[p] =
             parseParameter(p, parameterTypes[p], parameterAnnotationsArray[p], p == lastParameter);
       }
   	...
       return new RequestFactory(this);
     }

   到此，完成了请求方法的request部分的封装。但是ServiceMethod对象还缺少返回参数的封装，所有ServiceMethod.parseAnnotations()方法最终调用return HttpServiceMethod.parseAnnotations(retrofit, method, requestFactory);做后续处理，返回一个完整的ServiceMethod对象。

   static <ResponseT, ReturnT> HttpServiceMethod<ResponseT, ReturnT> parseAnnotations(
       Retrofit retrofit, Method method, RequestFactory requestFactory) {
   // 6 获取请求方法的返回类型
     adapterType = method.getGenericReturnType();
   // 7 通过方法的返回类型去创建callAdapter
     CallAdapter<ResponseT, ReturnT> callAdapter =
         createCallAdapter(retrofit, method, adapterType, annotations);
     // 8 响应的类型
     Type responseType = callAdapter.responseType();
   // 9 构建响应的转换器
     Converter<ResponseBody, ResponseT> responseConverter =
         createResponseConverter(retrofit, method, responseType);
      
     okhttp3.Call.Factory callFactory = retrofit.callFactory;
      
     return new CallAdapted<>(requestFactory, callFactory, responseConverter, callAdapter);
   }

   注释6处，获取请求方法的返回类型，一般情况下是：Call<xxxBean>或Observable<xxxBean>这样的封装类型。通过这个返回类型，注释7处得到了callAdapter：

   private static <ResponseT, ReturnT> CallAdapter<ResponseT, ReturnT> createCallAdapter(
       Retrofit retrofit, Method method, Type returnType, Annotation[] annotations) {
   return (CallAdapter<ResponseT, ReturnT>) retrofit.callAdapter(returnType, annotations);
   }

   这里调用哦那个retrofit类的callAdapter()方法：

   public CallAdapter<?, ?> callAdapter(Type returnType, Annotation[] annotations) {
   	// 调用nextCallAdapter()方法
     return nextCallAdapter(null, returnType, annotations);
   }
   public CallAdapter<?, ?> nextCallAdapter(@Nullable CallAdapter.Factory skipPast, Type returnType,
       Annotation[] annotations) {
     int start = callAdapterFactories.indexOf(skipPast) + 1;
     for (int i = start, count = callAdapterFactories.size(); i < count; i++) {
       // 遍历callAdapterFactories找到合适的callAdapter返回
       CallAdapter<?, ?> adapter = callAdapterFactories.get(i).get(returnType, annotations, this);
       if (adapter != null) {
         return adapter;
       }
     }
   }

   callAdapterFactories.get(i).get(returnType, annotations, this)因为callAdapterFactories中可能有多个Factory，且它们的实现都不一样，一下对比两个：

   • DefaultCallAdapterFactory.class

     @Override public @Nullable CallAdapter<?, ?> get(
         Type returnType, Annotation[] annotations, Retrofit retrofit) {
       if (getRawType(returnType) != Call.class) {
         return null;
       }
       final Type responseType = Utils.getParameterUpperBound(0, (ParameterizedType) returnType);
           
      return new CallAdapter<Object, Call<?>>() {
         @Override public Type responseType() {
           return responseType;
         }
        @Override public Call<Object> adapt(Call<Object> call) {
           return executor == null
               ? call
               : new ExecutorCallbackCall<>(executor, call);
         }
      };
     }

如果返回类型不是Call的包装类型，那么直接返回null。

• CompletableFutureCallAdapterFactory.class （Java8）

  @Override public @Nullable CallAdapter<?, ?> get(
      Type returnType, Annotation[] annotations, Retrofit retrofit) {
    if (getRawType(returnType) != CompletableFuture.class) {
      return null;
    }
  
    Type innerType = getParameterUpperBound(0, (ParameterizedType) returnType);
    if (getRawType(innerType) != Response.class) {
      // Generic type is not Response<T>. Use it for body-only adapter.
      return new BodyCallAdapter<>(innerType);
    }
    Type responseType = getParameterUpperBound(0, (ParameterizedType) innerType);
    return new ResponseCallAdapter<>(responseType);
  }

如果返回类型的被包装类不是CompletableFuture，那么直接返回null

最终从callAdapterFactories筛选出合适的Fractory。

注释8处，获取响应的类型：

return Utils.getParameterUpperBound(index, type);

注释9处，构建响应的转换器：

private static <ResponseT> Converter<ResponseBody, ResponseT> createResponseConverter(
    Retrofit retrofit, Method method, Type responseType) {
  Annotation[] annotations = method.getAnnotations();
  return retrofit.responseBodyConverter(responseType, annotations);
}

使用的retrofit的responseBodyConverter()方法：

public <T> Converter<ResponseBody, T> responseBodyConverter(Type type, Annotation[] annotations) {
  return nextResponseBodyConverter(null, type, annotations);
}
   
public <T> Converter<ResponseBody, T> nextResponseBodyConverter(
    @Nullable Converter.Factory skipPast, Type type, Annotation[] annotations) {
  checkNotNull(type, "type == null");
  checkNotNull(annotations, "annotations == null");
   
  int start = converterFactories.indexOf(skipPast) + 1;
  for (int i = start, count = converterFactories.size(); i < count; i++) {
    Converter<ResponseBody, ?> converter =
        converterFactories.get(i).responseBodyConverter(type, annotations, this);
    if (converter != null) {
      //noinspection unchecked
      return (Converter<ResponseBody, T>) converter;
    }
  }
}

responseBodyConverter()方法调用了nextResponseBodyConverter()方法，与之前callAdapter的创建类似，也是从factories中获取合适的Factory然后创建出converter对象。

最终通过responseConverter 、callAdapter、入参传入的requestFactory以及retrofit.callFactory构造出请求方法独有的HttpServiceMethod对象。

至此，请求方法的封装过程已经完毕。

---

请求调用：ServiceMethod.invoke()

ServiceMethod是一个抽象类，invoke()方法的实现在它的子类HttpServiceMethod中：

@Override final @Nullable ReturnT invoke(Object[] args) {
  Call<ResponseT> call = new OkHttpCall<>(requestFactory, args, callFactory, responseConverter);
  return adapt(call, args);
}
   
protected abstract @Nullable ReturnT adapt(Call<ResponseT> call, Object[] args);

从上面创建HttpServiceMethod的代码可以看出，HttpServiceMethod的实现类为CallAdapted，所以adapt()也是在CallAdapted中实现的：

@Override protected ReturnT adapt(Call<ResponseT> call, Object[] args) {
  return callAdapter.adapt(call);
}

adapt的最终实现有回到了HttpServiceMethod对象的成员变量callAdapter的adapt()方法中了，callAdapter

接口有多个实现类，这里看两个实现类的adapt：

• D efaultCallAdapterFactory.call

  new CallAdapter<Object, Call<?>>() {
                  public Type responseType() {
                      return responseType;
                  }
  
                  public Call<Object> adapt(Call<Object> call) {
                      return (Call)(executor == null ? call : new DefaultCallAdapterFactory.ExecutorCallbackCall(executor, call));
                  }
              }
              
      static final class ExecutorCallbackCall<T> implements Call<T> {
          final Executor callbackExecutor;
          final Call<T> delegate;
  
          ExecutorCallbackCall(Executor callbackExecutor, Call<T> delegate) {
              this.callbackExecutor = callbackExecutor;
              this.delegate = delegate;
          }
  
          public void enqueue(final Callback<T> callback) {
              Utils.checkNotNull(callback, "callback == null");
              this.delegate.enqueue(new Callback<T>() {
                  public void onResponse(Call<T> call, final Response<T> response) {
                      ExecutorCallbackCall.this.callbackExecutor.execute(new Runnable() {
                          public void run() {
                              if (ExecutorCallbackCall.this.delegate.isCanceled()) {
                                  callback.onFailure(ExecutorCallbackCall.this, new IOException("Canceled"));
                              } else {
                                  callback.onResponse(ExecutorCallbackCall.this, response);
                              }
  
                          }
                      });
                  }
  
                  public void onFailure(Call<T> call, final Throwable t) {
                      ExecutorCallbackCall.this.callbackExecutor.execute(new Runnable() {
                          public void run() {
                              callback.onFailure(ExecutorCallbackCall.this, t);
                          }
                      });
                  }
              });
          }
      }

这是默认情况的callAdapter，直接在ExecutorCallbackCall中执行call.callback（主线程）。

• RxJava2CallAdapter

  @Override public Object adapt(Call<R> call) {
    Observable<Response<R>> responseObservable = isAsync
        ? new CallEnqueueObservable<>(call)
        : new CallExecuteObservable<>(call);
       
    Observable<?> observable;
    if (isResult) {
      observable = new ResultObservable<>(responseObservable);
    } else if (isBody) {
      observable = new BodyObservable<>(responseObservable);
    } else {
      observable = responseObservable;
    }
  //添加调度器
    if (scheduler != null) {
      observable = observable.subscribeOn(scheduler);
    }
       
    if (isFlowable) {
      return observable.toFlowable(BackpressureStrategy.LATEST);
    }
    if (isSingle) {
      return observable.singleOrError();
    }
    if (isMaybe) {
      return observable.singleElement();
    }
    if (isCompletable) {
      return observable.ignoreElements();
    }
    return RxJavaPlugins.onAssembly(observable);
  }

通过判断是同步还是异步，创建对应的Observable对象，然后根据类型不同返回不同的Observable对象。

至此，整个retrofit调用请求的过程全部完成。

总结

• Retrofit 库主要使用了运行时注解+动态代理实现对网络请求接口的封装
• 使用适配器模式对请求的结果进行转换，以实现与不同框架的搭配使用