本文是对之前写的两篇文章的综合概述及全流程梳理
Android 利用RxJava和Retrofit搭建网络请求组件——监听回调及部分源码解析
Android 利用RxJava和Retrofit搭建网络请求组件——基础配置及部分源码解析
基础配置
一.定义网络请求方法的接口文件:ApiService.class(名字随意)
ApiService.class定义了各个请求方法,请求方式及参数类型均以注解形式标识,示例文件仅描述了GET与POST请求方式
/**
* 注意:ApiService 必须是接口,且不能实现其他接口
* Created by cuiyan on 16-10-18.
*/
public interface ApiService {
/*************************GET 请求方式*************************/
/**
* ApiConstants.QQ_SPORT_API 请求接口地址api(相对路径)
* 域名或ip部分会在构建Retrofit时设置
* 返回Observable对象(内部包装了Call实例),订阅(subscribe)执行时会调用Call.execute()方法发送网络请求。
* 默认情况下,返回结果为retrofit2.Call对象,只有在构建Retrofit实例时设置了RxJava2CallAdapterFactory才支持请求方法返回Observable对象
*/
@GET(ApiConstants.QQ_SPORT_API)
Observable<NewsResult> getQQSportNews(@Query("baid") String baid, @Query("apikey") String apiKey);
@GET(ApiConstants.QQ_SPORT_API)
Observable<NewsResult> getQQSportNews1(@QueryMap Map<String, String> paramsMap);
/*************************POST 请求方式*************************/
/**
* @Body 注解参数均表示以实体形式提交请求数据
*/
@POST(ApiConstants.QQ_SPORT_API)
Observable<NewsResult> getQQSportNews2(@Body NewsResult bodyParam);
/**
* @Field 或 @FieldMap 注解参数均表示以表单形式提交参数,相应的,
* 请求方法必须添加 @FormUrlEncoded 注解
*/
@FormUrlEncoded
@POST(ApiConstants.QQ_SPORT_API)
Observable<NewsResult> getQQSportNews3(@Field("baid") String baid, @Field("apikey") String apiKey);
@FormUrlEncoded
@POST(ApiConstants.QQ_SPORT_API)
Observable<NewsResult> getQQSportNews4(@FieldMap Map<String, String> paramsMap);
}
二.ApiService实例构建及相关配置
public class BaseServiceUtil {
private static final int DEFAULT_TIMEOUT = 10;
/**
@param serviceClass 网络请求接口描述文件类,步骤一中的ApiService.class或其他类似class
@return S S实例,即ApiService实例
*/
public static synchronized <S> S createService(Class<S> serviceClass) {
return createService(serviceClass, null);
}
public static <S> S createService(Class<S> serviceClass, String baseUrl) {
CommonInterceptor interceptor = new CommonInterceptor();
OkHttpClient.Builder clientBuilder = new OkHttpClient.Builder()
.connectTimeout(DEFAULT_TIMEOUT, TimeUnit.SECONDS)
.readTimeout(DEFAULT_TIMEOUT, TimeUnit.SECONDS);
Retrofit.Builder retrofitBuilder = new Retrofit.Builder()
.addConverterFactory(GsonConverterFactory.create()) // 设置Converter.Factory(请求响应数据转换器),我们设置的是GsonConverterFactory
.addCallAdapterFactory(RxJava2CallAdapterFactory.create()); // 重点1:为Retrofit设置CallAdapter.Factory,这里我们设置的是RxJava2CallAdapterFactory。ApiService 中网络请求方法默认返回retrofit2.Call对象,添加RxJava2CallAdapterFactory后支持返回Observable对象
// retrofitBuilder.callFactory()
// 一定要设置且必须格式正确的baseUrl
if (!TextUtils.isEmpty(baseUrl)) {
retrofitBuilder.baseUrl(baseUrl);
} else {
retrofitBuilder.baseUrl(BuildConfig.BASE_URL);
}
clientBuilder.interceptors().clear();
clientBuilder.interceptors().add(interceptor); // 重点2:为OkHttpClient(实现了okhttp3.Call.Factory接口)设置拦截器
// 设置https证书
// try {
// clientBuilder.sslSocketFactory(RqbTrustManager.getInstance().getSSLSocketFactory("BKS", R.raw.rqb_ssl));
// } catch (Exception e) {
// e.printStackTrace();
// }
OkHttpClient client = clientBuilder.build();
// 重点3:为Retrofit设置okhttp3.Call.Factory,OkHttpClient实现了okhttp3.Call.Factory接口,该方法内实际调用了
// callFactory(okhttp3.Call.Factory factory)方法为Retrofit设置okhttp3.Call.Factory。此行与下一行可合并,此处有意拆开做标注
retrofitBuilder.client(client);
// 重点4:构建Retrofit实例
Retrofit retrofit = retrofitBuilder.build();
// 重点5:构建ApiService实例
return retrofit.create(serviceClass);
}
}
三.网络请求订阅者(观察者)
/**
* 网络请求订阅者
* Created by cuiyan on 16/6/2 14:09
*/
public class NetRequestSubscriber<T> implements Observer<T> {
private Dialog progressDialog;
private Disposable disposable;
private NetRequestCallback<T> netRequestCallback;
private Context context;
/**
* @param netRequestCallback 网络请求回调
*/
public NetRequestSubscriber(@NonNull NetRequestCallback<T> netRequestCallback, Context context) {
this(netRequestCallback, context, false, null);
}
/**
* @param netRequestCallback 网络请求回调
* @param showProgress 是否显示网络请求加载对话框
* @param progressTip loading提示语
* @see NetProgressDialog
*/
public NetRequestSubscriber(@NonNull final NetRequestCallback<T> netRequestCallback, Context context, boolean showProgress, String progressTip) {
this.netRequestCallback = netRequestCallback;
this.context = context;
if (showProgress) {
progressDialog = NetProgressDialog.getInstance(context, progressTip, new OnNetProgressCancelListener() {
@Override
public void onCancelRequest() {
cancelRequest()
}
});
}
}
/**
* @param netRequestCallback 网络请求回调
* @param progressDialog dialog 自定义对话框
*/
public NetRequestSubscriber(@NonNull NetRequestCallback<T> netRequestCallback, Context context, @NonNull Dialog progressDialog) {
this.netRequestCallback = netRequestCallback;
this.context = context;
this.progressDialog = progressDialog;
}
@Override
public void onSubscribe(@NonNull Disposable d) {
this.disposable = d;
showProgress();
onRequestStart();
}
@Override
public synchronized void onNext(final T t) {
if (t == null) {
onRequestResultNull();
} else {
if (t instanceof BaseResult && !Config.REQUEST_SUCCESS_CODE.equals(((BaseResult) t).getCode())) {
ToastUtil.showToast(context, ((BaseResult) t).getMessage());
}
onRequestSuccess(t);
}
}
@Override
public synchronized void onError(Throwable throwable) {
dismissProgress();
onRequestError(throwable);
if (throwable instanceof HttpException) {
ToastUtil.showToast(context, ((HttpException) throwable).message() + ((HttpException) throwable).code());
} else {
if (BuildConfig.DEBUG) {
ToastUtil.showToast(context, "error:" + throwable.getMessage());
} else {
ToastUtil.showToast(context, context.getString(R.string.error_net_request_failed));
}
}
}
/**
* {@link NetRequestSubscriber#onError(Throwable)}
* {@link Observer#onError(Throwable)}
* {@link Observer#onComplete()} (Throwable)}
* 该方法与onError方法互斥
*/
@Override
public void onComplete() {
dismissProgress();
netRequestCallback.onFinish();
}
private void onRequestStart() {
if (Looper.myLooper() != context.getMainLooper()) {
Handler handler = new Handler(context.getMainLooper());
handler.post(new Runnable() {
@Override
public void run() {
netRequestCallback.onStart();
}
});
} else {
netRequestCallback.onStart();
}
}
private void onRequestSuccess(final T t) {
if (Looper.myLooper() != context.getMainLooper()) {
Handler handler = new Handler(context.getMainLooper());
handler.post(new Runnable() {
@Override
public void run() {
netRequestCallback.onSuccess(t);
}
});
} else {
netRequestCallback.onSuccess(t);
}
}
private void onRequestResultNull() {
if (Looper.myLooper() != context.getMainLooper()) {
Handler handler = new Handler(context.getMainLooper());
handler.post(new Runnable() {
@Override
public void run() {
netRequestCallback.onResultNull();
}
});
} else {
netRequestCallback.onResultNull();
}
}
private void onRequestError(final Throwable throwable) {
throwable.printStackTrace();
if (Looper.myLooper() != context.getMainLooper()) {
Handler handler = new Handler(context.getMainLooper());
handler.post(new Runnable() {
@Override
public void run() {
netRequestCallback.onError(throwable);
netRequestCallback.onFinish();
}
});
} else {
netRequestCallback.onError(throwable);
netRequestCallback.onFinish();
}
}
/**
*
*
*/
private void showProgress() {
if (progressDialog != null && !progressDialog.isShowing()) {
progressDialog.show();
}
}
private void dismissProgress() {
if (progressDialog != null && progressDialog.isShowing()) {
progressDialog.dismiss();
}
}
public void cancelRequest() {
dismissProgress();
if (disposable != null && !disposable.isDisposed()) {
disposable.dispose();
}
netRequestCallback.onCancel();
netRequestCallback.onFinish();
}
}
四.网络请求控制器
public class BaseController {
/**
* @param subscriber 订阅者
*/
@SuppressWarnings("unchecked")
public static synchronized void sendRequest(final NetRequestSubscriber subscriber, Observable observable) {
observable.subscribeOn(Schedulers.io())
.unsubscribeOn(Schedulers.io())
.observeOn(AndroidSchedulers.mainThread())
.subscribeWith(subscriber);
}
/**
* @param activity 用于与observable绑定,activity生命周期结束时,自动取消订阅
* @param observable 被观察者
* @param subscriber 订阅者
*/
@SuppressWarnings("unchecked")
public static synchronized void sendRequest(RxActivity activity, final NetRequestSubscriber subscriber, Observable observable) {
observable.subscribeOn(Schedulers.io())
.compose(activity.bindToLifecycle()) //防止内存泄漏,activity生命周期结束后取消订阅
.unsubscribeOn(Schedulers.io())
.observeOn(AndroidSchedulers.mainThread())
.subscribe(subscriber);
}
/**
* @param fragment 用于与observable绑定,fragment生命周期结束时,自动取消订阅
* @param subscriber 订阅者
*/
@SuppressWarnings("unchecked")
public static synchronized void sendRequest(RxFragment fragment, final NetRequestSubscriber subscriber, Observable observable) {
observable.compose(fragment.bindToLifecycle()) //防止内存泄漏,fragment生命周期结束后取消订阅
.subscribeOn(Schedulers.io())
.unsubscribeOn(Schedulers.io())
.observeOn(AndroidSchedulers.mainThread())
.subscribe(subscriber);
}
}
上述代码构建了完整网络请求功能,下面贴出应用示例。完整示例:https://github.com/670832188/TestApp
private void getNews() {
NetRequestSubscriber<NewsResult> subscriber = new NetRequestSubscriber<>(new NetRequestCallback<NewsResult>() {
@Override
public void onStart() {
setContentState(STATE_NET_PROGRESS);
}
@Override
public void onSuccess(@NonNull NewsResult newsResult) {
if (newsResult.getData() != null && newsResult.getData().size() > 0) {
setContentState(STATE_DATA_CONTENT);
newsAdapter.updateDataList(newsResult.getData());
} else {
setContentState(STATE_DATA_EMPTY);
}
}
@Override
public void onResultNull() {
setContentState(STATE_NET_ERROR);
}
@Override
public void onError(Throwable throwable) {
setContentState(STATE_NET_ERROR);
}
@Override
public void onCancel() {
super.onCancel();
}
@Override
public void onFinish() {
super.onFinish();
}
}, this);
Observable<NewsResult> observable = BaseServiceUtil.createService(ApiService.class, ApiConstants.JUHE_BASE_URL).getQQSportNews("69", Constant.JUHE_API_KEY);
BaseController.sendRequest(this, subscriber, observable);
}
流程梳理
上述代码中标注了五处重点:
1.Retrofit设置RxJava2CallAdapterFactory;
2.OkHttpClient(okhttp3.Call.Factory)设置Interceptor;
3.Retrofit设置OkHttpClient(okhttp3.Call.Factory);
4.构建Retrofit实例
5.构建ApiService实例
下面从Retrofit和ApiService实例构建为入口,分析基本流程及上述上述几个配置是如何工作的
先看一下创建Retrofit实例的方法Retrofit.build()源码
1. public Retrofit build() {
2. if (baseUrl == null) {
3. throw new IllegalStateException("Base URL required.");
4. }
5. okhttp3.Call.Factory callFactory = this.callFactory;
6. if (callFactory == null) {
7. callFactory = new OkHttpClient();
8. }
9. Executor callbackExecutor = this.callbackExecutor;
10. if (callbackExecutor == null) {
11. callbackExecutor = platform.defaultCallbackExecutor();
12. }
13. // Make a defensive copy of the adapters and add the default Call adapter.
14. List<CallAdapter.Factory> adapterFactories = new ArrayList<>(this.adapterFactories);
15. adapterFactories.add(platform.defaultCallAdapterFactory(callbackExecutor));
16. // Make a defensive copy of the converters.
17. List<Converter.Factory> converterFactories = new ArrayList<>(this.converterFactories);
18. return new Retrofit(callFactory, baseUrl, converterFactories, adapterFactories,callbackExecutor, validateEagerly);
19. }
第1-第3行:首先检测了之前设置的baseUrl,没有设置的话直接抛出异常。
第5-第8行:检测是否设置了okhttp3.Call.Factory,没有设置的话使用默认的OkHttpClient实例(前述代码中说过OkHttpClient实现了okhttp3.Call.Factory接口)。我们在代码中创建、配置了OkHttpClient实例(设置超时时间、拦截器),并设置于Retrofit实例。之所以没有使用默认的OkHttpClient,是因为我们需要根据需求自定义超时时间、拦截器等
第14-15行:获取CallAdapter.Factory列表,包括我们设置的RxJava2CallAdapterFactory和框架内置的默认CallAdapter.Factory,追踪源码可以看到,内置的是ExecutorCallAdapterFactory.ExecutorCallbackCall。
注意:列表的顺序,先添加的是我们设置的RxJava2CallAdapterFactory,请记住我们的RxJava2CallAdapterFactory是NO.1 NO.1 NO.1
第17行:获取Converter.Factory列表,包括我们设置的GsonConverterFactory和内置的Converter.Factory(参见Rerofit.Builder构造方法)。
第18行:callFactory、adapterFactories 等作为构建参数传入Retrofit构造方法创建Retrofit实例,看一下其构造方法:
Retrofit(okhttp3.Call.Factory callFactory, HttpUrl baseUrl,
List<Converter.Factory> converterFactories, List<CallAdapter.Factory> adapterFactories,
@Nullable Executor callbackExecutor, boolean validateEagerly) {
this.callFactory = callFactory;
this.baseUrl = baseUrl;
this.converterFactories = unmodifiableList(converterFactories); // Defensive copy at call site.
this.adapterFactories = unmodifiableList(adapterFactories); // Defensive copy at call site.
this.callbackExecutor = callbackExecutor;
this.validateEagerly = validateEagerly;
}
成员变量callFactory 是我们设置的OkHttpClient;converterFactories包含了我们设置的GsonConverterFactory;adapterFactories 包含了我们设置的RxJava2CallAdapterFactory。暂且先有些印象,方便后续分析。
下面看ApiService实例构建方法Retrofit .create(final Class<T> service)源码:
1. public <T> T create(final Class<T> service) {
2. Utils.validateServiceInterface(service);
3. if (validateEagerly) {
4. eagerlyValidateMethods(service);
5. }
6. return (T) Proxy.newProxyInstance(service.getClassLoader(), new Class<?>[] { service },
7. new InvocationHandler() {
8. private final Platform platform = Platform.get();
9. @Override
10 public Object invoke(Object proxy, Method method, @Nullable Object[] args) throws Throwable {
11. // If the method is a method from Object then defer to normal invocation.
12. if (method.getDeclaringClass() == Object.class) {
13. return method.invoke(this, args);
14. }
15. if (platform.isDefaultMethod(method)) {
16. return platform.invokeDefaultMethod(method, service, proxy, args);
17. }
18. ServiceMethod<Object, Object> serviceMethod = (ServiceMethod<Object, Object>) loadServiceMethod(method);
19. OkHttpCall<Object> okHttpCall = new OkHttpCall<>(serviceMethod, args); // 请留意okHttpCall
20. return serviceMethod.callAdapter.adapt(okHttpCall); // 请留心callAdapter
21. }
22. });
23. }
很直接、很暴力啊,利用Proxy创建的ApiService代理对象。查看InvocationHandler的invoke方法,看看代理操作做了什么处理。我们只关心我们的网络请求方法,我们的网络请求方法都是ApiService定义的,第12行判断条件不满足,pass;第15行判断条件也不成立,具体原因可查看platform的创建方法。
现在只剩下18-20行是我们需要关心的。先看第20行,我们的网络请求被万恶的代理商劫持了,返回结果是serviceMethod.callAdapter.adapt(okHttpCall),如果你的记忆不是很差的话,应该记得我们的请求方法返回的Observable对象。是很明显,我们需要知道这个callAdapter是什么,了解它的adapt方法起到了什么作用。定位到第18行,深入loadServiceMethod方法窥视一下
1. ServiceMethod<?, ?> loadServiceMethod(Method method) {
2. ServiceMethod<?, ?> result = serviceMethodCache.get(method);
3. if (result != null) return result;
4. synchronized (serviceMethodCache) {
5. result = serviceMethodCache.get(method);
6. if (result == null) {
7. result = new ServiceMethod.Builder<>(this, method).build();
8. serviceMethodCache.put(method, result);
9. }
10. }
11. return result;
12. }
很遗憾,这个方法没有窥测到ServiceMethod是神马角色。定位到上述代码第7行,继续追击ServiceMethod(ServiceMethod.class)
1. Builder(Retrofit retrofit, Method method) {
2. this.retrofit = retrofit;
3. this.method = method;
4. this.methodAnnotations = method.getAnnotations();
5. this.parameterTypes = method.getGenericParameterTypes();
6. this.parameterAnnotationsArray = method.getParameterAnnotations();
7. }
8. public ServiceMethod build() {
9. callAdapter = createCallAdapter();
10. responseType = callAdapter.responseType();
11. if (responseType == Response.class || responseType == okhttp3.Response.class) {
12. throw methodError("'"+ Utils.getRawType(responseType).getName() + "' is not a valid response body type. Did you mean ResponseBody?");
13. }
14. responseConverter = createResponseConverter();
15. for (Annotation annotation : methodAnnotations) {
16 parseMethodAnnotation(annotation);
17. }
18. // 此处省略一万个字...
19. return new ServiceMethod<>(this); // 此处要记住,后面有用
20. }
// 构造方法一并看了
21. ServiceMethod(Builder<R, T> builder) {
22. this.callFactory = builder.retrofit.callFactory(); // 此处请留意
23. this.callAdapter = builder.callAdapter;
24. this.baseUrl = builder.retrofit.baseUrl();
25. this.responseConverter = builder.responseConverter;
26. this.httpMethod = builder.httpMethod;
27. this.relativeUrl = builder.relativeUrl;
28. this.headers = builder.headers;
29. this.contentType = builder.contentType;
30. this.hasBody = builder.hasBody;
31. this.isFormEncoded = builder.isFormEncoded;
32. this.isMultipart = builder.isMultipart;
33. this.parameterHandlers = builder.parameterHandlers;
34. }
看Builder构造方法第2行,ServiceMethod持有我们之前创建的Retrofit实例。再看第9行callAdapter = createCallAdapter(); 我们要找的callAdapter(CallAdapter)终于浮出水面。我们之前说过,创建Retrofit实例的时候我们为其设置了CallAdapter.Factory,就是那个RxJava2CallAdapterFactory...(此处伏笔~~)。
从第9行继续追踪源码,最终定位到Retrofit的nextCallAdapter方法,此方法返回的CallAdapter就是我们要寻找的目标了
1. public CallAdapter<?, ?> nextCallAdapter(@Nullable CallAdapter.Factory skipPast, Type returnType, Annotation[] annotations) {
2. checkNotNull(returnType, "returnType == null");
3. checkNotNull(annotations, "annotations == null");
4. int start = adapterFactories.indexOf(skipPast) + 1;
5. for (int i = start, count = adapterFactories.size(); i < count; i++) {
6. CallAdapter<?, ?> adapter = adapterFactories.get(i).get(returnType, annotations, this);
7. if (adapter != null) {
8. return adapter;
9. }
10. }
11. // 此处省略一万字(异常处理相关)
12. }
这段代码很就容易看懂了~。遍历CallAdapter.Factory列表,通过Factory的get方法获取匹配的CallAdapter,一猜就是通过我们设置的RxJava2CallAdapterFactory获取的。为什么这么说呢?还记得之前我们说过,我们设置的RxJava2CallAdapterFactory是第一顺位,状元郎。看一下第4行,遍历起点位置start值是多少?如果你自己追踪到这块代码,就会知道skipPast为null,所以start等于0,因此是从头到尾遍历列表,而我们的RxJava2CallAdapterFactory处于列表第一位。那就看一看RxJava2CallAdapterFactory部分源码吧
public final class RxJava2CallAdapterFactory extends CallAdapter.Factory {
/**
* Returns an instance which creates synchronous observables that do not operate on any scheduler
* by default.
*/
public static RxJava2CallAdapterFactory create() {
return new RxJava2CallAdapterFactory(null, false);
}
private final @Nullable Scheduler scheduler;
private final boolean isAsync;
private RxJava2CallAdapterFactory(@Nullable Scheduler scheduler, boolean isAsync) {
this.scheduler = scheduler;
this.isAsync = isAsync;
}
@Override
public CallAdapter<?, ?> get(Type returnType, Annotation[] annotations, Retrofit retrofit) {
Class<?> rawType = getRawType(returnType);
if (rawType == Completable.class) {
// Completable is not parameterized (which is what the rest of this method deals with) so it
// can only be created with a single configuration.
return new RxJava2CallAdapter(Void.class, scheduler, isAsync, false, true, false, false,
false, true);
}
boolean isFlowable = rawType == Flowable.class;
boolean isSingle = rawType == Single.class;
boolean isMaybe = rawType == Maybe.class;
if (rawType != Observable.class && !isFlowable && !isSingle && !isMaybe) {
return null;
}
boolean isResult = false;
boolean isBody = false;
Type responseType;
if (!(returnType instanceof ParameterizedType)) {
String name = isFlowable ? "Flowable"
: isSingle ? "Single"
: isMaybe ? "Maybe" : "Observable";
throw new IllegalStateException(name + " return type must be parameterized"
+ " as " + name + "<Foo> or " + name + "<? extends Foo>");
}
Type observableType = getParameterUpperBound(0, (ParameterizedType) returnType);
Class<?> rawObservableType = getRawType(observableType);
if (rawObservableType == Response.class) {
if (!(observableType instanceof ParameterizedType)) {
throw new IllegalStateException("Response must be parameterized"
+ " as Response<Foo> or Response<? extends Foo>");
}
responseType = getParameterUpperBound(0, (ParameterizedType) observableType);
} else if (rawObservableType == Result.class) {
if (!(observableType instanceof ParameterizedType)) {
throw new IllegalStateException("Result must be parameterized"
+ " as Result<Foo> or Result<? extends Foo>");
}
responseType = getParameterUpperBound(0, (ParameterizedType) observableType);
isResult = true;
} else {
responseType = observableType;
isBody = true;
}
return new RxJava2CallAdapter(responseType, scheduler, isAsync, isResult, isBody, isFlowable,
isSingle, isMaybe, false);
}
}
上述源码做了删减,只保留了我们关心的部分。我们在设置RxJava2CallAdapterFactory时,使用的是RxJava2CallAdapterFactory无参静态方法create()创建的RxJava2CallAdapterFactory实例,显然scheduler为null,isAsync为false。继续看get方法,定位到return语句,返回的是RxJava2CallAdapter,构造RxJava2CallAdapter实例时传入了一堆参数,我们关心一下scheduler、isAsync和isBody参数,不过多解析该方法,请自行深度查阅。scheduler为null,isAsync为false,isBody为true,以此为基础继续看RxJava2CallAdapter源码,代码不多,全部贴出
final class RxJava2CallAdapter<R> implements CallAdapter<R, Object> {
private final Type responseType;
private final @Nullable Scheduler scheduler;
private final boolean isAsync;
private final boolean isResult;
private final boolean isBody;
private final boolean isFlowable;
private final boolean isSingle;
private final boolean isMaybe;
private final boolean isCompletable;
// 构造方法
RxJava2CallAdapter(Type responseType, @Nullable Scheduler scheduler, boolean isAsync,
boolean isResult, boolean isBody, boolean isFlowable, boolean isSingle, boolean isMaybe,
boolean isCompletable) {
this.responseType = responseType;
this.scheduler = scheduler;
this.isAsync = isAsync;
this.isResult = isResult;
this.isBody = isBody;
this.isFlowable = isFlowable;
this.isSingle = isSingle;
this.isMaybe = isMaybe;
this.isCompletable = isCompletable;
}
@Override public Type responseType() {
return responseType;
}
@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) {
// 这个是该方法最终返回的Observable对象
observable = new BodyObservable<>(responseObservable);
} else {
observable = responseObservable;
}
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 observable;
}
}
直接看adapt方法第一行responseObservable,是一个Observable对象,该方法最终返回的也是Observable对象,且与responseObservable相关。先看看responseObservable吧,前述说过isAsync为false,所以responseObservable是CallExecuteObservable实例,感兴趣您也可以看看CallEnqueueObservable源码(Android 利用RxJava和Retrofit搭建网络请求组件——监听回调及部分源码解析中有所提及)。之前还说过scheduler为null,isBody为true,综合下来,最终return的是BodyObservable对象(对于其他情形可自行查阅相关代码),该BodyObservable实例的构造参数是responseObservable(CallExecuteObservable)。不管怎样,BodyObservable确实是Observable,看来代理商并没有做什么坏事,真的与ApiService中我们期望的结果一样。到此为止,我们已经知晓ApiService是如何返回Observable对象了,主动脉已经打通。不再分析BodyObservable源码,读者可自行查看,只是做了相关封装处理,相对比较简单。接下来继续分析CallExecuteObservable源码
final class CallExecuteObservable<T> extends Observable<Response<T>> {
private final Call<T> originalCall;
CallExecuteObservable(Call<T> originalCall) {
this.originalCall = originalCall;
}
@Override protected void subscribeActual(Observer<? super Response<T>> observer) {
// Since Call is a one-shot type, clone it for each new observer.
1. Call<T> call = originalCall.clone();
2. observer.onSubscribe(new CallDisposable(call));
3. boolean terminated = false;
4. try {
5. Response<T> response = call.execute();
if (!call.isCanceled()) {
observer.onNext(response);
}
if (!call.isCanceled()) {
terminated = true;
observer.onComplete();
}
} catch (Throwable t) {
Exceptions.throwIfFatal(t);
if (terminated) {
RxJavaPlugins.onError(t);
} else if (!call.isCanceled()) {
try {
observer.onError(t);
} catch (Throwable inner) {
Exceptions.throwIfFatal(inner);
RxJavaPlugins.onError(new CompositeException(t, inner));
}
}
}
}
private static final class CallDisposable implements Disposable {
private final Call<?> call;
CallDisposable(Call<?> call) {
this.call = call;
}
@Override public void dispose() {
call.cancel();
}
@Override public boolean isDisposed() {
return call.isCanceled();
}
}
先看一下我标记的第5行Response<T> response = call.execute();这行代码就是执行网络请求了,至于call实例的具体实现方式稍后分析,目前您只需要知道这么多。
继续分析该方法之前,我们先回忆一下,还记得订阅者NetRequestSubscriber中有个cancelRequest()方法吗,调用了onSubscribe(@NonNull Disposable d)方法中传入的Disposable对象的dispose()方法来取消网络请求,为什么这个方法能取消网络请求呢?回答这个问题要继续看一下subscribeActual方法。看我标记的第2行observer.onSubscribe(new CallDisposable(call));CallDisposable是CallExecuteObservable定义的内部类,实现了Disposable接口,dispose()方法中调用了call.cancel()方法来取消网络请求,是不是与NetRequestSubscriber中的取消请求方法对上号了~。
到此为止,通过分析Retrofit实例、ApiService实例的构建及RxJava2CallAdapterFactory源码追踪,我们已经知道了网络请求的执行、取消以及如何返回的Observable,之前提及的几处重点已经粗略了解大半。但是我们还不知道拦截器如何被触发工作的。下面继续分析一下call实例是如何实现的,call.execute()方法到底做了什么勾当,或许它与拦截器暗中勾结呢
回顾ApiService实例的构建方法,第18行
OkHttpCall<Object> okHttpCall = new OkHttpCall<>(serviceMethod, args); // 请留意okHttpCall
上面提及的call实例就是这个okHttpCall啦。没办法,只能再看一看OkHttpCall源码了,做一下简单了解,打入OkHttpCall内部,直接定位到execute()方法
@Override public Response<T> execute() throws IOException {
okhttp3.Call call;
synchronized (this) {
if (executed) throw new IllegalStateException("Already executed.");
executed = true;
if (creationFailure != null) {
if (creationFailure instanceof IOException) {
throw (IOException) creationFailure;
} else {
throw (RuntimeException) creationFailure;
}
}
call = rawCall;
if (call == null) {
try {
// 注释1:继续追踪createRawCall()方法吧...
call = rawCall = createRawCall();
} catch (IOException | RuntimeException e) {
creationFailure = e;
throw e;
}
}
}
if (canceled) {
call.cancel();
}
// 此处请关联上述注释1
return parseResponse(call.execute());
}
看过源码很头疼,显然我们还要继续追踪createRawCall()方法,继续吧
1. private okhttp3.Call createRawCall() throws IOException {
2. Request request = serviceMethod.toRequest(args);
// 此处想哭
3. okhttp3.Call call = serviceMethod.callFactory.newCall(request);
4. if (call == null) {
5. throw new NullPointerException("Call.Factory returned null.");
6. }
7. return call;
8. }
代码简洁明了,继续调查第3行吧,如果您的记忆不算差,应该记得之前我们为了寻找CallAdapter简单分析过此serviceMethod的创建过程,现在它又回来了:我马三立又回来了...
在ServiceMethod的构造方法中,可以知道callFactory其实是Retrofit实例的callFactory,而Retrofit实例的callFactory是我们设置的OkHttpClient实例,如果您已经没有印象请返回查看。好啦,直接看OkHttpClient的newwCall(Request request)方法,了解Call实例时如何创建的
@Override
public Call newCall(Request request) {
// 心中一万个草泥马,又牵涉到RealCall这个类
return new RealCall(this, request, false /* for web socket */);
}
哎,没办法,继续查看RealCall这个类吧,直接定位其execute()方法及相关联方法
1. final class RealCall implements Call {
2. @Override
3. public Response execute() throws IOException {
4. synchronized (this) {
5. if (executed) throw new IllegalStateException("Already Executed");
6. executed = true;
7. }
8. captureCallStackTrace();
9. try {
10. client.dispatcher().executed(this);
11. Response result = getResponseWithInterceptorChain();
12. if (result == null) throw new IOException("Canceled");
13. return result;
14. } finally {
15. client.dispatcher().finished(this);
16. }
17. }
18. Response getResponseWithInterceptorChain() throws IOException {
19. // Build a full stack of interceptors.
20. List<Interceptor> interceptors = new ArrayList<>();
21. interceptors.addAll(client.interceptors()); // 我们设置的拦截器,处于列表第一位
// 以下几个为内置拦截器
22. interceptors.add(retryAndFollowUpInterceptor);
23. interceptors.add(new BridgeInterceptor(client.cookieJar()));
24. interceptors.add(new CacheInterceptor(client.internalCache()));
25. interceptors.add(new ConnectInterceptor(client));
26. if (!forWebSocket) {
27. interceptors.addAll(client.networkInterceptors());
28. }
29. interceptors.add(new CallServerInterceptor(forWebSocket));
// 注意此处传入的index参数为0,拦截器列表也被传入RealInterceptorChain构造方法
30. Interceptor.Chain chain = new RealInterceptorChain(interceptors, null, null, null, 0, originalRequest);
31. return chain.proceed(originalRequest);
32. }
33. }
看一下第11行代码,执行这行代码获取网络请求响应数据,但是仍然看不出拦截器是如何起作用的,但是请注意注释部分,追击getResponseWithInterceptorChain()方法试试。看第31行代码:执行chain.proceed(originalRequest)获取的响应数据,硬着头皮看看chain是什么鬼。定位到第30行,查阅一下RealInterceptorChain构造方法及proceed方法
1. public RealInterceptorChain(List<Interceptor> interceptors, StreamAllocation streamAllocation, HttpCodec httpCodec, RealConnection connection, int index, Request request) {
2. this.interceptors = interceptors;
3. this.connection = connection;
4. this.streamAllocation = streamAllocation;
5. this.httpCodec = httpCodec;
6. // 上一步传入此处的index为0
7. this.index = index;
8. this.request = request;
9. }
10. public Response proceed(Request request, StreamAllocation streamAllocation, HttpCodec httpCodec, RealConnection connection) throws IOException {
11. if (index >= interceptors.size()) throw new AssertionError();
12. calls++;
13. // If we already have a stream, confirm that the incoming request will use it.
14. if (this.httpCodec != null && !this.connection.supportsUrl(request.url())) {
15. throw new IllegalStateException("network interceptor " + interceptors.get(index - 1)
+ " must retain the same host and port");
16. }
17. // If we already have a stream, confirm that this is the only call to chain.proceed().
18. if (this.httpCodec != null && calls > 1) {
throw new IllegalStateException("network interceptor " + interceptors.get(index - 1)
+ " must call proceed() exactly once");
19 }
20. // Call the next interceptor in the chain.
21. RealInterceptorChain next = new RealInterceptorChain( interceptors, streamAllocation, httpCodec, connection, index + 1, request);
// 上一步传入的index 为0,因此取我们设置的拦截器
22. Interceptor interceptor = interceptors.get(index);
23. Response response = interceptor.intercept(next);
24. // Confirm that the next interceptor made its required call to chain.proceed().
25. if (httpCodec != null && index + 1 < interceptors.size() && next.calls != 1) {
throw new IllegalStateException("network interceptor " + interceptor
+ " must call proceed() exactly once");
26. }
27. // Confirm that the intercepted response isn't null.
28. if (response == null) {
throw new NullPointerException("interceptor " + interceptor + " returned null");
29. }
30. return response;
31. }
定位到第22行,终于看到了拦截器,取index为0,所以取第一个,就是我们设置的拦截器了;再看第23行,执行interceptor.intercept(next)拦截请求。拦截器触发流程解析就此终结,至于拦截器的用法请参考Retrofit Interceptor(拦截器) 拦截请求并做相关处理
到此为止,我们已经梳理了网络请求大致流程,我们做的配置也做了解析,本文也到此结束
