Glide 缓存流程

发布时间:2020-06-20 09:27:33 作者:vivo互联网
来源:网络 阅读:217

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链接:https://mp.weixin.qq.com/s/cPLkefpEb3w12-uoiqzTig
作者:连凌能

Android上图片加载的解决方案有多种,但是官方认可的是Glide。Glide提供简洁易用的api,整个框架也方便扩展,比如可以替换网络请求库,同时也提供了完备的缓存机制,应用层不需要自己去管理图片的缓存与获取,框架会分成内存缓存,文件缓存和远程缓存。本文不会从简单的使用着手,会把重点放在缓存机制的分析上。

一、综述

开始之前,关于Glide缓存请先思考几个问题:

加载开始入口从Engine.load()开始,先看下对这个方法的注释,

* Starts a load for the given arguments.
*
* <p>Must be called on the main thread.
*
* <p>The flow for any request is as follows:
* <ul>
*   <li>Check the current set of actively used resources, return the active resource if
*   present, and move any newly inactive resources into the memory cache.</li>
*   <li>Check the memory cache and provide the cached resource if present.</li>
*   <li>Check the current set of in progress loads and add the cb to the in progress load if
*   one is present.</li>
*   <li>Start a new load.</li>
* </ul>

ok, find the source code.

二、内存缓存

public <R> LoadStatus load(
    GlideContext glideContext,
    Object model,
    Key signature,
    int width,
    int height,
    Class<?> resourceClass,
    Class<R> transcodeClass,
    Priority priority,
    DiskCacheStrategy diskCacheStrategy,
    Map<Class<?>, Transformation<?>> transformations,
    boolean isTransformationRequired,
    boolean isScaleOnlyOrNoTransform,
    Options options,
    boolean isMemoryCacheable,
    boolean useUnlimitedSourceExecutorPool,
    boolean useAnimationPool,
    boolean onlyRetrieveFromCache,
    ResourceCallback cb) {
  Util.assertMainThread();
  long startTime = VERBOSE_IS_LOGGABLE ? LogTime.getLogTime() : 0;

  EngineKey key = keyFactory.buildKey(model, signature, width, height, transformations,
      resourceClass, transcodeClass, options);

  // focus 1
  EngineResource<?> active = loadFromActiveResources(key, isMemoryCacheable);
  if (active != null) {
    cb.onResourceReady(active, DataSource.MEMORY_CACHE);
    if (VERBOSE_IS_LOGGABLE) {
      logWithTimeAndKey("Loaded resource from active resources", startTime, key);
    }
    return null;
  }
  // focus 2
  EngineResource<?> cached = loadFromCache(key, isMemoryCacheable);
  if (cached != null) {
    cb.onResourceReady(cached, DataSource.MEMORY_CACHE);
    if (VERBOSE_IS_LOGGABLE) {
      logWithTimeAndKey("Loaded resource from cache", startTime, key);
    }
    return null;
  }

  // focus 3
  EngineJob<?> current = jobs.get(key, onlyRetrieveFromCache);
  if (current != null) {
    current.addCallback(cb);
    if (VERBOSE_IS_LOGGABLE) {
      logWithTimeAndKey("Added to existing load", startTime, key);
    }
    return new LoadStatus(cb, current);
  }

  EngineJob<R> engineJob =
      engineJobFactory.build(
          key,
          isMemoryCacheable,
          useUnlimitedSourceExecutorPool,
          useAnimationPool,
          onlyRetrieveFromCache);

  DecodeJob<R> decodeJob =
      decodeJobFactory.build(
          glideContext,
          model,
          key,
          signature,
          width,
          height,
          resourceClass,
          transcodeClass,
          priority,
          diskCacheStrategy,
          transformations,
          isTransformationRequired,
          isScaleOnlyOrNoTransform,
          onlyRetrieveFromCache,
          options,
          engineJob);

  jobs.put(key, engineJob);

  engineJob.addCallback(cb);
  // focus 4
  engineJob.start(decodeJob);

  if (VERBOSE_IS_LOGGABLE) {
    logWithTimeAndKey("Started new load", startTime, key);
  }
  return new LoadStatus(cb, engineJob);
}

先看到 focus 1,这一步会从 ActiveResources 中加载资源,首先判断是否使用内存缓存,否的话返回null;否则到 ActiveResources 中取数据:

// Engine.java
 @Nullable
 private EngineResource<?> loadFromActiveResources(Key key, boolean isMemoryCacheable) {
   if (!isMemoryCacheable) {
     return null;
   }
   EngineResource<?> active = activeResources.get(key);
   if (active != null) {
     active.acquire();
   }

   return active;
 }

接下来看下ActiveResources, 其实是用过弱引用保存使用过的资源。

final class ActiveResources {

  ...
  private final Handler mainHandler = new Handler(Looper.getMainLooper(), new Callback() {
    @Override
    public boolean handleMessage(Message msg) {
      if (msg.what == MSG_CLEAN_REF) {
        cleanupActiveReference((ResourceWeakReference) msg.obj);
        return true;
      }
      return false;
    }
  });
  @VisibleForTesting
  final Map<Key, ResourceWeakReference> activeEngineResources = new HashMap<>();

  ...
}

成功取到数据后回调类型也是内存缓存:


EngineResource<?> cached = loadFromCache(key, isMemoryCacheable);
if (cached != null) {
   cb.onResourceReady(cached, DataSource.MEMORY_CACHE);
   return null;
}

接着回到Engine.load()中继续看到focus 2,如果在cache中找到就是remove掉,然后返回EngineResource,其中需要EngineResource进行acquire一下,这个后面再看,然后会把资源移到ActiveResources中,也就是上面提到的缓存:

// Engine.java
  private final MemoryCache cache;

  private EngineResource<?> loadFromCache(Key key, boolean isMemoryCacheable) {
    if (!isMemoryCacheable) {
      return null;
    }

    EngineResource<?> cached = getEngineResourceFromCache(key);
    if (cached != null) {
      cached.acquire();
      activeResources.activate(key, cached);
    }
    return cached;
  }

  private EngineResource<?> getEngineResourceFromCache(Key key) {
    Resource<?> cached = cache.remove(key);

    final EngineResource<?> result;
    if (cached == null) {
      result = null;
    } else if (cached instanceof EngineResource) {
      // Save an object allocation if we've cached an EngineResource (the typical case).
      result = (EngineResource<?>) cached;
    } else {
      result = new EngineResource<>(cached, true /*isMemoryCacheable*/, true /*isRecyclable*/);
    }
    return result;
  }

其中cache是MemoryCache接口的实现,如果没设置,默认在build的时候是LruResourceCache, 也就是熟悉的LRU Cache:

// GlideBuilder.java
if (memoryCache == null) {
   memoryCache = new LruResourceCache(memorySizeCalculator.getMemoryCacheSize());
}

再看下EngineResource,主要是对资源增加了引用计数的功能:

// EngineResource.java
private final boolean isCacheable;
  private final boolean isRecyclable;
  private ResourceListener listener;
  private Key key;
  private int acquired;
  private boolean isRecycled;
  private final Resource<Z> resource;

  interface ResourceListener {
    void onResourceReleased(Key key, EngineResource<?> resource);
  }

  EngineResource(Resource<Z> toWrap, boolean isCacheable, boolean isRecyclable) {
    resource = Preconditions.checkNotNull(toWrap);
    this.isCacheable = isCacheable;
    this.isRecyclable = isRecyclable;
  }

  void setResourceListener(Key key, ResourceListener listener) {
    this.key = key;
    this.listener = listener;
  }

  Resource<Z> getResource() {
    return resource;
  }

  boolean isCacheable() {
    return isCacheable;
  }

  @NonNull
  @Override
  public Class<Z> getResourceClass() {
    return resource.getResourceClass();
  }

  @NonNull
  @Override
  public Z get() {
    return resource.get();
  }

  @Override
  public int getSize() {
    return resource.getSize();
  }

  @Override
  public void recycle() {
    if (acquired > 0) {
      throw new IllegalStateException("Cannot recycle a resource while it is still acquired");
    }
    if (isRecycled) {
      throw new IllegalStateException("Cannot recycle a resource that has already been recycled");
    }
    isRecycled = true;
    if (isRecyclable) {
      resource.recycle();
    }
  }

  void acquire() {
    if (isRecycled) {
      throw new IllegalStateException("Cannot acquire a recycled resource");
    }
    if (!Looper.getMainLooper().equals(Looper.myLooper())) {
      throw new IllegalThreadStateException("Must call acquire on the main thread");
    }
    ++acquired;
  }

  void release() {
    if (acquired <= 0) {
      throw new IllegalStateException("Cannot release a recycled or not yet acquired resource");
    }
    if (!Looper.getMainLooper().equals(Looper.myLooper())) {
      throw new IllegalThreadStateException("Must call release on the main thread");
    }
    if (--acquired == 0) {
      listener.onResourceReleased(key, this);
    }
  }

在release后会判断引用计数是否为0,如果是0就会回调onResourceReleased,在这里就是Engine,然后会把资源从ActiveResources中移除,资源默认是可缓存的,因此会把资源放到LruCache中。

// Engine.java
  @Override
  public void onResourceReleased(Key cacheKey, EngineResource<?> resource) {
    Util.assertMainThread();
    activeResources.deactivate(cacheKey);
    if (resource.isCacheable()) {
      cache.put(cacheKey, resource);
    } else {
      resourceRecycler.recycle(resource);
    }
  }

// ActiveResources.java
  void activate(Key key, EngineResource<?> resource) {
    ResourceWeakReference toPut =
        new ResourceWeakReference(
            key,
            resource,
            getReferenceQueue(),
            isActiveResourceRetentionAllowed);

    ResourceWeakReference removed = activeEngineResources.put(key, toPut);
    if (removed != null) {
      removed.reset();
    }
  }

  void deactivate(Key key) {
    ResourceWeakReference removed = activeEngineResources.remove(key);
    if (removed != null) {
      removed.reset();
    }
  }

如果是回收呢,看看上面的EngineResource,如果引用计数为0并且还没与回收,就会调用真正的Resource.recycle(),看其中的一个BitmapResource是怎么回收的,就是放到Bitmap池中,也是用的LRU Cache,这个和今天的主题不相关,就不继续往下拓展。

// BitmapResource.java
 @Override
 public void recycle() {
   bitmapPool.put(bitmap);
 }

思路再拉到Engine.load()的流程中,接下来该看focus 3,这里再贴一下代码,如果job已经在运行了,那么直接添加一个回调后返回LoadStatus,这个可以允许用户取消任务:

// Engine.java
EngineJob<?> current = jobs.get(key, onlyRetrieveFromCache);
if (current != null) {
   current.addCallback(cb);
   if (VERBOSE_IS_LOGGABLE) {
      logWithTimeAndKey("Added to existing load", startTime, key);
    }
   return new LoadStatus(cb, current);
}

// LoadStatus
  public static class LoadStatus {
    private final EngineJob<?> engineJob;
    private final ResourceCallback cb;

    LoadStatus(ResourceCallback cb, EngineJob<?> engineJob) {
      this.cb = cb;
      this.engineJob = engineJob;
    }

    public void cancel() {
      engineJob.removeCallback(cb);
    }
  }

接着往下看到focus 4, 到这里就需要创建后台任务去拉取磁盘文件或者发起网络请求。

三、磁盘缓存

// Engine.java
   EngineJob<R> engineJob =
        engineJobFactory.build(
            key,
            isMemoryCacheable,
            useUnlimitedSourceExecutorPool,
            useAnimationPool,
            onlyRetrieveFromCache);

    DecodeJob<R> decodeJob =
        decodeJobFactory.build(
            glideContext,
            model,
            key,
            signature,
            width,
            height,
            resourceClass,
            transcodeClass,
            priority,
            diskCacheStrategy,
            transformations,
            isTransformationRequired,
            isScaleOnlyOrNoTransform,
            onlyRetrieveFromCache,
            options,
            engineJob);

    jobs.put(key, engineJob);

    engineJob.addCallback(cb);
    engineJob.start(decodeJob);
    return new LoadStatus(cb, engineJob);

先构造两个job,一个是EngineJob,另外一个DecodeJob,其中DecodeJob会根据需要解码的资源来源分成下面几个阶段:

// DecodeJob.java
  /**
   * Where we're trying to decode data from.
   */
  private enum Stage {
    /** The initial stage. */
    INITIALIZE,
    /** Decode from a cached resource. */
    RESOURCE_CACHE,
    /** Decode from cached source data. */
    DATA_CACHE,
    /** Decode from retrieved source. */
    SOURCE,
    /** Encoding transformed resources after a successful load. */
    ENCODE,
    /** No more viable stages. */
    FINISHED,
  }

在构造DecodeJob时会把状态置为INITIALIZE。

构造完两个 Job 后会调用 EngineJob.start(DecodeJob),首先会调用getNextStage来确定下一个阶段,这里面跟DiskCacheStrategy这个传入的磁盘缓存策略有关。

磁盘策略有下面几种:

默认的AUTOMATIC方式是允许解码缓存的RESOURCE:

public static final DiskCacheStrategy AUTOMATIC = new DiskCacheStrategy() {
    @Override
    public boolean isDataCacheable(DataSource dataSource) {
      return dataSource == DataSource.REMOTE;
    }

    @Override
    public boolean isResourceCacheable(boolean isFromAlternateCacheKey, DataSource dataSource,
        EncodeStrategy encodeStrategy) {
      return ((isFromAlternateCacheKey && dataSource == DataSource.DATA_DISK_CACHE)
          || dataSource == DataSource.LOCAL)
          && encodeStrategy == EncodeStrategy.TRANSFORMED;
    }

    @Override
    public boolean decodeCachedResource() {
      return true;
    }

    @Override
    public boolean decodeCachedData() {
      return true;
    }
  };

所以在 getNextStage 会先返回Stage.RESOURCE_CACHE,然后在start中会返回diskCacheExecutor,然后开始执行DecodeJob:

// EngineJob.java
public void start(DecodeJob<R> decodeJob) {
    this.decodeJob = decodeJob;
    GlideExecutor executor = decodeJob.willDecodeFromCache()
        ? diskCacheExecutor
        : getActiveSourceExecutor();
    executor.execute(decodeJob);
}

// DecodeJob.java
  boolean willDecodeFromCache() {
    Stage firstStage = getNextStage(Stage.INITIALIZE);
    return firstStage == Stage.RESOURCE_CACHE || firstStage == Stage.DATA_CACHE;
  }

  private Stage getNextStage(Stage current) {
    switch (current) {
      case INITIALIZE:
        return diskCacheStrategy.decodeCachedResource()
            ? Stage.RESOURCE_CACHE : getNextStage(Stage.RESOURCE_CACHE);
      case RESOURCE_CACHE:
        return diskCacheStrategy.decodeCachedData()
            ? Stage.DATA_CACHE : getNextStage(Stage.DATA_CACHE);
      case DATA_CACHE:
        // Skip loading from source if the user opted to only retrieve the resource from cache.
        return onlyRetrieveFromCache ? Stage.FINISHED : Stage.SOURCE;
      case SOURCE:
      case FINISHED:
        return Stage.FINISHED;
      default:
        throw new IllegalArgumentException("Unrecognized stage: " + current);
    }
  }

DecodeJob会回调run()开始执行, run()中调用runWrapped执行工作,这里runReason还是RunReason.INITIALIZE ,根据前面的分析指导这里会获得一个ResourceCacheGenerator,然后调用runGenerators:

// DecodeJob.java 
private void runWrapped() {
    switch (runReason) {
      case INITIALIZE:
        stage = getNextStage(Stage.INITIALIZE);
        currentGenerator = getNextGenerator();
        runGenerators();
        break;
      case SWITCH_TO_SOURCE_SERVICE:
        runGenerators();
        break;
      case DECODE_DATA:
        decodeFromRetrievedData();
        break;
      default:
        throw new IllegalStateException("Unrecognized run reason: " + runReason);
    }
  }

  private DataFetcherGenerator getNextGenerator() {
    switch (stage) {
      case RESOURCE_CACHE:
        return new ResourceCacheGenerator(decodeHelper, this);
      case DATA_CACHE:
        return new DataCacheGenerator(decodeHelper, this);
      case SOURCE:
        return new SourceGenerator(decodeHelper, this);
      case FINISHED:
        return null;
      default:
        throw new IllegalStateException("Unrecognized stage: " + stage);
    }
  }

在 runGenerators 中,会调用 startNext,目前currentGenerator是ResourceCacheGenerator, 那么就是调用它的startNext方法:

// DecodeJob.java 
private void runGenerators() {
    currentThread = Thread.currentThread();
    startFetchTime = LogTime.getLogTime();
    boolean isStarted = false;
    while (!isCancelled && currentGenerator != null
        && !(isStarted = currentGenerator.startNext())) {
      stage = getNextStage(stage);
      currentGenerator = getNextGenerator();

      if (stage == Stage.SOURCE) {
        reschedule();
        return;
      }
    }
    // We've run out of stages and generators, give up.
    if ((stage == Stage.FINISHED || isCancelled) && !isStarted) {
      notifyFailed();
    }
  }

看下ResourceCacheGenerator.startNext(), 这里面就是重点逻辑了,首先从Registry中获取支持资源类型的ModelLoader(其中ModelLoader是在构造Glide的时候传进去), 然后从ModelLoader中构造LoadData,接着就能拿到DataFetcher,(关于ModelLoader/LoadData/DataFetcher之间的关系不在本次范围内,后面有机会再另写)通过它的loadData方法加载数据:

@Override
 public boolean startNext() {
   List<Key> sourceIds = helper.getCacheKeys();
   if (sourceIds.isEmpty()) {
     return false;
   }
   List<Class<?>> resourceClasses = helper.getRegisteredResourceClasses();
   if (resourceClasses.isEmpty()) {
     if (File.class.equals(helper.getTranscodeClass())) {
       return false;
     }
   }
   while (modelLoaders == null || !hasNextModelLoader()) {
     resourceClassIndex++;
     if (resourceClassIndex >= resourceClasses.size()) {
       sourceIdIndex++;
       if (sourceIdIndex >= sourceIds.size()) {
         return false;
       }
       resourceClassIndex = 0;
     }

     Key sourceId = sourceIds.get(sourceIdIndex);
     Class<?> resourceClass = resourceClasses.get(resourceClassIndex);
     Transformation<?> transformation = helper.getTransformation(resourceClass);
     currentKey =
         new ResourceCacheKey(// NOPMD AvoidInstantiatingObjectsInLoops
             helper.getArrayPool(),
             sourceId,
             helper.getSignature(),
             helper.getWidth(),
             helper.getHeight(),
             transformation,
             resourceClass,
             helper.getOptions());
     cacheFile = helper.getDiskCache().get(currentKey);
     if (cacheFile != null) {
       sourceKey = sourceId;
       modelLoaders = helper.getModelLoaders(cacheFile);
       modelLoaderIndex = 0;
     }
   }

   loadData = null;
   boolean started = false;
   while (!started && hasNextModelLoader()) {
     ModelLoader<File, ?> modelLoader = modelLoaders.get(modelLoaderIndex++);
     loadData = modelLoader.buildLoadData(cacheFile,
         helper.getWidth(), helper.getHeight(), helper.getOptions());
     if (loadData != null && helper.hasLoadPath(loadData.fetcher.getDataClass())) {
       started = true;
       loadData.fetcher.loadData(helper.getPriority(), this);
     }
   }

   return started;
 }

如果在Resource中找不到需要的资源,那么startNext就会返回false,在runGenerators中就会进入循环体内:

四、网络缓存

在Stage.SOURCE阶段,通过getNextGenerator返回的是SourceGenerator,所以目前的currentGenerator就是它。

流程还是一样的,SourceGenerator还是调用startNext方法,获取到对应的DataFetcher,这里其实是HttpUrlFetcher,发起网络请求。

// DecodeJob.java 
private void runGenerators() {
   ...
    while (!isCancelled && currentGenerator != null
        && !(isStarted = currentGenerator.startNext())) {
      stage = getNextStage(stage);
      currentGenerator = getNextGenerator();

      if (stage == Stage.SOURCE) {
        reschedule();
        return;
      }
    }
   ...
  }

  @Override
  public void reschedule() {
    runReason = RunReason.SWITCH_TO_SOURCE_SERVICE;
    callback.reschedule(this);
  }

// EngineJob.java
  @Override
  public void reschedule(DecodeJob<?> job) {
    getActiveSourceExecutor().execute(job);
  }

先缓一缓,本文其实到了上面已经可以结束了,Glide涉及到的五级缓存都已经涉及到了,是真的就可以结束了吗?不是的,网络请求回来和缓存还有关系吗?接着看到HttpUrlFetcher,下载成功后回调onDataReady,其中callback是SourceGenerator:

// HttpUrlFetcher.java
@Override
  public void loadData(@NonNull Priority priority,
      @NonNull DataCallback<? super InputStream> callback) {
    long startTime = LogTime.getLogTime();
    try {
      InputStream result = loadDataWithRedirects(glideUrl.toURL(), 0, null, glideUrl.getHeaders());
      callback.onDataReady(result);
    } catch (IOException e) {
      if (Log.isLoggable(TAG, Log.DEBUG)) {
        Log.d(TAG, "Failed to load data for url", e);
      }
      callback.onLoadFailed(e);
    } finally {
      if (Log.isLoggable(TAG, Log.VERBOSE)) {
        Log.v(TAG, "Finished http url fetcher fetch in " + LogTime.getElapsedMillis(startTime));
      }
    }
  }

// EngineJob.java
  @Override
  public void reschedule(DecodeJob<?> job) {
    getActiveSourceExecutor().execute(job);
  }

正常情况会进入if判断逻辑里面,赋值dataToCache,然后回调cb.reschedule,而cb就是DecodeJob构造SourceGenerator的时候传入,cb是DecodeJob。

// SourceGenerator.java
  @Override
  public void onDataReady(Object data) {
    DiskCacheStrategy diskCacheStrategy = helper.getDiskCacheStrategy();
    if (data != null && diskCacheStrategy.isDataCacheable(loadData.fetcher.getDataSource())) {
      dataToCache = data;
      cb.reschedule();
    } else {
      cb.onDataFetcherReady(loadData.sourceKey, data, loadData.fetcher,
          loadData.fetcher.getDataSource(), originalKey);
    }
  }

DecodeJob在reschedule回调EngineJob,最后还是回到SourceGenerator中的startNext()逻辑。

// DecodeJob.java
  private DataFetcherGenerator getNextGenerator() {
    switch (stage) {
      case RESOURCE_CACHE:
        return new ResourceCacheGenerator(decodeHelper, this);
      case DATA_CACHE:
        return new DataCacheGenerator(decodeHelper, this);
      case SOURCE:
        return new SourceGenerator(decodeHelper, this);
      case FINISHED:
        return null;
      default:
        throw new IllegalStateException("Unrecognized stage: " + stage);
    }
  }

  @Override
  public void reschedule() {
    runReason = RunReason.SWITCH_TO_SOURCE_SERVICE;
    callback.reschedule(this);
  }

和第一次进来的逻辑不一样,现在dataToCache != null,进入第一个if逻辑。

在逻辑里面调用cacheData,逻辑很明显,保持数据到本地,然后会构造一个DataCacheGenerator。

而DataCacheGenerator前面已经分析过了,就是用来加载本地原始数据的,这回会加载成功,返回true。

// SourceGenerator.java
@Override
  public boolean startNext() {
    if (dataToCache != null) {
      Object data = dataToCache;
      dataToCache = null;
      cacheData(data);
    }

    if (sourceCacheGenerator != null && sourceCacheGenerator.startNext()) {
      return true;
    }
    ...
  }

  private void cacheData(Object dataToCache) {
    long startTime = LogTime.getLogTime();
    try {
      Encoder<Object> encoder = helper.getSourceEncoder(dataToCache);
      DataCacheWriter<Object> writer =
          new DataCacheWriter<>(encoder, dataToCache, helper.getOptions());
      originalKey = new DataCacheKey(loadData.sourceKey, helper.getSignature());
      helper.getDiskCache().put(originalKey, writer);
    } finally {
      loadData.fetcher.cleanup();
    }

    sourceCacheGenerator =
        new DataCacheGenerator(Collections.singletonList(loadData.sourceKey), helper, this);
  }

接下来就是一系列的回调了:

DataCacheGenerator的startNext逻辑里面会给DataFetcher传递自身作为callback,在加载本地数据成功后回调onDataReady。

// DataCacheGenerator
  @Override
  public boolean startNext() {
    ...

    loadData = null;
    boolean started = false;
    while (!started && hasNextModelLoader()) {
      ...
      if (loadData != null && helper.hasLoadPath(loadData.fetcher.getDataClass())) {
        started = true;
        loadData.fetcher.loadData(helper.getPriority(), this);
      }
    }
    return started;
  }

  @Override
  public void onDataReady(Object data) {
    cb.onDataFetcherReady(sourceKey, data, loadData.fetcher, DataSource.DATA_DISK_CACHE, sourceKey);
  }

而cb现在是SourceGenerator传递过来,SourceGenerator再回调它自己的cb,是DecodeJob在构造它的时候传过来。

// SourceGenerator.java
  @Override
  public void onDataFetcherReady(Key sourceKey, Object data, DataFetcher<?> fetcher,
      DataSource dataSource, Key attemptedKey) {
    cb.onDataFetcherReady(sourceKey, data, fetcher, loadData.fetcher.getDataSource(), sourceKey);
  }

// DecodeJob.java
  @Override
  public void onDataFetcherReady(Key sourceKey, Object data, DataFetcher<?> fetcher,
      DataSource dataSource, Key attemptedKey) {
    this.currentSourceKey = sourceKey;
    this.currentData = data;
    this.currentFetcher = fetcher;
    this.currentDataSource = dataSource;
    this.currentAttemptingKey = attemptedKey;
    if (Thread.currentThread() != currentThread) {
      runReason = RunReason.DECODE_DATA;
      callback.reschedule(this);
    } else {
      try {
        decodeFromRetrievedData();
      } finally {
        GlideTrace.endSection();
      }
    }
  }

在上面SourceGenerator把DecodeJob切换到ActiveSourceExecutor线程中执行,还记得一开始DecodeJob是在哪启动的吗?在EngineJob中启动,然后是把DecodeJob放到diskCacheExecutor中执行。

// EngineJob.java
  public void start(DecodeJob<R> decodeJob) {
    this.decodeJob = decodeJob;
    GlideExecutor executor = decodeJob.willDecodeFromCache()
        ? diskCacheExecutor
        : getActiveSourceExecutor();
    executor.execute(decodeJob);
  }

所以上面在DecodeJob的onDataFetcherReady会走到第一个if逻辑里面,然后赋值runReason = RunReason.DECODE_DATA,再一次回调Engine.reschedule,将工作线程切换到ActiveSourceExecutor。

// Engine.java
  @Override
  public void reschedule(DecodeJob<?> job) {
    // Even if the job is cancelled here, it still needs to be scheduled so that it can clean itself
    // up.
    getActiveSourceExecutor().execute(job);
  }

//

然后还是走到DecodeJob, 现在会进入DECODE_DATA分支,在这里面会调用ResourceDecoder把数据解码:

private void runWrapped() {
    switch (runReason) {
      case INITIALIZE:
        stage = getNextStage(Stage.INITIALIZE);
        currentGenerator = getNextGenerator();
        runGenerators();
        break;
      case SWITCH_TO_SOURCE_SERVICE:
        runGenerators();
        break;
      case DECODE_DATA:
        decodeFromRetrievedData();
        break;
      default:
        throw new IllegalStateException("Unrecognized run reason: " + runReason);
    }
  }

解码成功后调用notifyComplete(result, dataSource);

private void notifyComplete(Resource<R> resource, DataSource dataSource) {
  setNotifiedOrThrow();
  callback.onResourceReady(resource, dataSource);
}

五、总结

现在回答一下开头的几个问题。

1、有几级缓存?五级,分别是什么?

2、Glide内存缓存之间是什么关系?

专门画了一幅图表明这个关系,言简意赅。

Glide 缓存流程

3、Glide本地文件IO和网络请求是一个线程吗?

明显不是,本地IO通过diskCacheExecutor,而网络IO通过ActiveSourceExecutor

4、Glide网络请求回来后数据直接返回给用户还是先存再返回?

不是直接返回给用户,会在SourceGenerator中构造一个DataCacheGenerator来取数据。

推荐阅读:
  1. Glide生命周期原理
  2. 原来面试的时候写精通Glide,这样问我这样答

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glide缓存流程 内存缓存 网络缓存

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