前文分析了Glide的with（）、load（）以及into（）方法中的大部分逻辑，今天我们来分析Glide的核心图片加载逻辑。因为Glide的封装程度比较高，之前三篇文章分析完毕其外围逻辑（参阅：〔两行哥〕提纲挈领，带你梳理Glide主要源码逻辑（一），〔两行哥〕提纲挈领，带你梳理Glide主要源码逻辑（二），〔两行哥〕提纲挈领，带你梳理Glide主要源码逻辑（三））。
那么Glide图片加载的核心逻辑在哪儿呢？就是上文结尾所说的engine.load（）方法，在engine.load（）方法中传入了上文已经分析过的DataFetcher实例、LoadProvider实例以及ResourceTransCoder实例。让我们进入源码分析看看。

Engine.java

    /**
     * Starts a load for the given arguments. Must be called on the main thread.
     *
     * <p>
     *     The flow for any request is as follows:
     *     <ul>
     *         <li>Check the memory cache and provide the cached resource if present</li>
     *         <li>Check the current set of actively used resources and return the active resource if present</li>
     *         <li>Check the current set of in progress loads and add the cb to the in progress load if present</li>
     *         <li>Start a new load</li>
     *     </ul>
     * </p>
     *
     * <p>
     *     Active resources are those that have been provided to at least one request and have not yet been released.
     *     Once all consumers of a resource have released that resource, the resource then goes to cache. If the
     *     resource is ever returned to a new consumer from cache, it is re-added to the active resources. If the
     *     resource is evicted from the cache, its resources are recycled and re-used if possible and the resource is
     *     discarded. There is no strict requirement that consumers release their resources so active resources are
     *     held weakly.
     * </p>
     *
     * @param signature A non-null unique key to be mixed into the cache key that identifies the version of the data to
     *                  be loaded.
     * @param width The target width in pixels of the desired resource.
     * @param height The target height in pixels of the desired resource.
     * @param fetcher The fetcher to use to retrieve data not in the disk cache.
     * @param loadProvider The load provider containing various encoders and decoders use to decode and encode data.
     * @param transformation The transformation to use to transform the decoded resource.
     * @param transcoder The transcoder to use to transcode the decoded and transformed resource.
     * @param priority The priority with which the request should run.
     * @param isMemoryCacheable True if the transcoded resource can be cached in memory.
     * @param diskCacheStrategy The strategy to use that determines what type of data, if any,
     *                          will be cached in the local disk cache.
     * @param cb The callback that will be called when the load completes.
     *
     * @param <T> The type of data the resource will be decoded from.
     * @param <Z> The type of the resource that will be decoded.
     * @param <R> The type of the resource that will be transcoded from the decoded resource.
     */
    public <T, Z, R> LoadStatus load(Key signature, int width, int height, DataFetcher<T> fetcher,
            DataLoadProvider<T, Z> loadProvider, Transformation<Z> transformation, ResourceTranscoder<Z, R> transcoder,
            Priority priority, boolean isMemoryCacheable, DiskCacheStrategy diskCacheStrategy, ResourceCallback cb) {
        Util.assertMainThread();
        long startTime = LogTime.getLogTime();

        final String id = fetcher.getId();
        EngineKey key = keyFactory.buildKey(id, signature, width, height, loadProvider.getCacheDecoder(),
                loadProvider.getSourceDecoder(), transformation, loadProvider.getEncoder(),
                transcoder, loadProvider.getSourceEncoder());

        EngineResource<?> cached = loadFromCache(key, isMemoryCacheable);
        if (cached != null) {
            cb.onResourceReady(cached);
            if (Log.isLoggable(TAG, Log.VERBOSE)) {
                logWithTimeAndKey("Loaded resource from cache", startTime, key);
            }
            return null;
        }

        EngineResource<?> active = loadFromActiveResources(key, isMemoryCacheable);
        if (active != null) {
            cb.onResourceReady(active);
            if (Log.isLoggable(TAG, Log.VERBOSE)) {
                logWithTimeAndKey("Loaded resource from active resources", startTime, key);
            }
            return null;
        }

        EngineJob current = jobs.get(key);
        if (current != null) {
            current.addCallback(cb);
            if (Log.isLoggable(TAG, Log.VERBOSE)) {
                logWithTimeAndKey("Added to existing load", startTime, key);
            }
            return new LoadStatus(cb, current);
        }

        EngineJob engineJob = engineJobFactory.build(key, isMemoryCacheable);
        DecodeJob<T, Z, R> decodeJob = new DecodeJob<T, Z, R>(key, width, height, fetcher, loadProvider, transformation,
                transcoder, diskCacheProvider, diskCacheStrategy, priority);
        EngineRunnable runnable = new EngineRunnable(engineJob, decodeJob, priority);
        jobs.put(key, engineJob);
        engineJob.addCallback(cb);
        engineJob.start(runnable);

        if (Log.isLoggable(TAG, Log.VERBOSE)) {
            logWithTimeAndKey("Started new load", startTime, key);
        }
        return new LoadStatus(cb, engineJob);
    }

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

        EngineResource<?> active = null;
        WeakReference<EngineResource<?>> activeRef = activeResources.get(key);
        if (activeRef != null) {
            active = activeRef.get();
            if (active != null) {
                active.acquire();
            } else {
                activeResources.remove(key);
            }
        }

        return active;
    }

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

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

首先先做一下知识的铺垫。我们知道Glide中有三级缓存机制，拥有内存缓存和硬盘缓存。而内存缓存同时采用了两种机制，一种是前文讲过的LruCache算法机制（什么是LruCache算法？请参阅前文），另外一种就是弱引用机制。缓存的作用是什么呢？内存缓存的作用就是防止把图片重复加载到内存中，而硬盘缓存的作用就是防止重复从网络中获取图片。

一、内存缓存

让我们回到load（）方法中。首先调用了fetcher.getId()获得了一个唯一标识Id。这个Id是图片加载的唯一标识Id（如果是网络图片加载请求，那么其实就是图片的Url）。接着通过EngineKey的构建者模式，传入了获取到的Id、Width、Height、transformation等参数，构建了另外一个标识Key。这个Key是什么呢？上文讲到Glide的内存缓存，这个Key就是内存缓存的唯一标识Key，与传入的Id、Width、Height、transformation参数相关。为什么要与这么多参数相关呢？大家想一下，需要加载的图片只有与内存缓存中的某图片Url、宽高、解码方式等一致，才可以直接取用内存缓存。如果需要加载的图片改变了Url或者宽高或者解码方式，那么原有旧的内存缓存就不能使用了，需要重新缓存。那么在EngineKey的构建方法中传入如此多的参数也可以理解了。
接着往下看。上文说过Glide的内存缓存同时使用了两种缓存机制，一种是LruCache缓存机制，一种是弱引用缓存机制，让我们一一分析。首先，load（）方法内部调用了loadFromCache（）方法，源码如下：

Engine.java

    private final MemoryCache cache;
    private final Map<Key, WeakReference<EngineResource<?>>> activeResources;

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

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

    @SuppressWarnings("unchecked")
    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 /*isCacheable*/);
        }
        return result;
    }

可以看到逻辑是从cache中获取到缓存（cache中存储的是曾经使用过，而当前没有在使用中的缓存。通过调用cache.remove（key）方法删除缓存并返回被删除的缓存），如果获取到的缓存result不为null，调用 activeResources.put（）方法将此缓存放入激活缓存Map中（正在使用中的缓存）。而这里的cache为实现了MemoryCache接口的LruResourceCache类的实例。我们稍微看一下LruResourceCache类的源码：

LruResourceCache.java

public class LruResourceCache extends LruCache<Key, Resource<?>> implements MemoryCache {
    private ResourceRemovedListener listener;

    /**
     * Constructor for LruResourceCache.
     *
     * @param size The maximum size in bytes the in memory cache can use.
     */
    public LruResourceCache(int size) {
        super(size);
    }

    @Override
    public void setResourceRemovedListener(ResourceRemovedListener listener) {
        this.listener = listener;
    }

    @Override
    protected void onItemEvicted(Key key, Resource<?> item) {
        if (listener != null) {
            listener.onResourceRemoved(item);
        }
    }

    @Override
    protected int getSize(Resource<?> item) {
        return item.getSize();
    }

    @SuppressLint("InlinedApi")
    @Override
    public void trimMemory(int level) {
        if (level >= android.content.ComponentCallbacks2.TRIM_MEMORY_MODERATE) {
            // Nearing middle of list of cached background apps
            // Evict our entire bitmap cache
            clearMemory();
        } else if (level >= android.content.ComponentCallbacks2.TRIM_MEMORY_BACKGROUND) {
            // Entering list of cached background apps
            // Evict oldest half of our bitmap cache
            trimToSize(getCurrentSize() / 2);
        }
    }
}

留意一下isMemoryCacheable变量，这个布尔值是在配置Glide参数的时候设置的，决定了Glide是否使用内存缓存。如果为false，这里获取内存缓存的方法就会返回false。LruResourceCache类就不再赘述，之前的文章就已经分析过LruCache，只要知道cache是基于LruCache算法，内部是基于LinkedHashMap实现的。
回到load（）方法中，如果loadFromCache（）方法返回的cached对象不为null，则执行onResourceReady（）回调。如果获取到的cached为null（没有从LruCache中的LinkedHashMap中获取到缓存），则调用loadFromActiveResources（）方法，再去激活缓存的Map中（使用中的缓存）去寻找是否有缓存，看看内部源码的逻辑：

Engine.java

    private final Map<Key, WeakReference<EngineResource<?>>> activeResources;
    private EngineResource<?> loadFromActiveResources(Key key, boolean isMemoryCacheable) {
        if (!isMemoryCacheable) {
            return null;
        }

        EngineResource<?> active = null;
        WeakReference<EngineResource<?>> activeRef = activeResources.get(key);
        if (activeRef != null) {
            active = activeRef.get();
            if (active != null) {
                active.acquire();
            } else {
                activeResources.remove(key);
            }
        }

        return active;
    }

activeResources是持有了缓存弱引用的HashMap，而这里的逻辑主要是从activeResources这个HashMap中获取到图片的缓存。如果调用loadFromActiveResources（）方法返回的缓存不为null，同样执行onResourceReady（）回调方法，如果返回的缓存为null，则进入下一步，从磁盘中或者网络去获取图片。

二、磁盘缓存及图片获取

Glide磁盘缓存与内存缓存类似，也采用了LruCache算法。首先让我们追踪一下Glide读取磁盘缓存的逻辑。
在读取内存缓存之后，如果没有获取到内存缓存，Glide就会去读取磁盘缓存，如下代码：

EngineJob engineJob = engineJobFactory.build(key, isMemoryCacheable);
EngineRunnable runnable = new EngineRunnable(engineJob, decodeJob, priority);
jobs.put(key, engineJob);
engineJob.addCallback(cb);
engineJob.start(runnable);

首先创建了一个EngineJob并放入jobs集合，然后engineJob开始执行传入的EngineRunnable任务。本地磁盘缓存的逻辑就隐藏在EngineRunnable中，让我们看看这个Runnable对象中覆写的run（）方法：

EngineRunnable.java

    @Override
    public void run() {
        if (isCancelled) {
            return;
        }

        Exception exception = null;
        Resource<?> resource = null;
        try {
            resource = decode();
        } catch (OutOfMemoryError e) {
            if (Log.isLoggable(TAG, Log.VERBOSE)) {
                Log.v(TAG, "Out Of Memory Error decoding", e);
            }
            exception = new ErrorWrappingGlideException(e);
        } catch (Exception e) {
            if (Log.isLoggable(TAG, Log.VERBOSE)) {
                Log.v(TAG, "Exception decoding", e);
            }
            exception = e;
        }

        if (isCancelled) {
            if (resource != null) {
                resource.recycle();
            }
            return;
        }

        if (resource == null) {
            onLoadFailed(exception);
        } else {
            onLoadComplete(resource);
        }
    }

可以看到run（）方法中执行了decode（）方法，并在执行结束后根据执行的结果，调用了onLoadFailed（）或者onLoadComplete（）回调。再让我们看看decode（）方法到底做了哪些工作。

EngineRunnable.java

    private Resource<?> decode() throws Exception {
        ...
        private boolean isDecodingFromCache() {
            return stage == Stage.CACHE;
        }
        ...
        if (isDecodingFromCache()) {
            return decodeFromCache();
        } else {
            return decodeFromSource();
        }
        ...
    }

decode（）方法根据isDecodingFromCache（）方法的返回值（这个参数在初始化Glile的时候进行过配置，是否使用磁盘缓存），分别调用decodeFromCache（）和decodeFromSource（）。磁盘缓存的逻辑终于被找到了，就在decodeFromCache（）中！

EngineRunnable.java

    private Resource<?> decodeFromCache() throws Exception {
        Resource<?> result = null;
        try {
            result = decodeJob.decodeResultFromCache();
        } catch (Exception e) {
            if (Log.isLoggable(TAG, Log.DEBUG)) {
                Log.d(TAG, "Exception decoding result from cache: " + e);
            }
        }

        if (result == null) {
            result = decodeJob.decodeSourceFromCache();
        }
        return result;
    }

可以看到decodeFromCache（）方法中执行了decodeResultFromCache（）或decodeSourceFromCache（）方法。首先调用decodeResultFromCache（）方法获取缓存，如果获取不到，就调用decodeSourceFromCache（）方法获取缓存。至于什么时候执行第一个方法，什么时候又会执行到第二个方法，与我们在第一篇中讲的磁盘缓存配置策略有关：

diskCacheStrategy(DiskCacheStrategy.RESULT)//缓存处理后的图像（如尺寸调整、裁剪后的图像）
diskCacheStrategy(DiskCacheStrategy.SOURCE)//缓存原尺寸的图像
diskCacheStrategy(DiskCacheStrategy.ALL)//缓存所有图像

见名知意，两行哥就不再深入讲解了，让我们看一下源码：

DecodeJob.java

     public Resource<Z> decodeResultFromCache() throws Exception {
        if (!diskCacheStrategy.cacheResult()) {
            return null;
        }

        long startTime = LogTime.getLogTime();
        Resource<T> transformed = loadFromCache(resultKey);
        if (Log.isLoggable(TAG, Log.VERBOSE)) {
            logWithTimeAndKey("Decoded transformed from cache", startTime);
        }
        startTime = LogTime.getLogTime();
        Resource<Z> result = transcode(transformed);
        if (Log.isLoggable(TAG, Log.VERBOSE)) {
            logWithTimeAndKey("Transcoded transformed from cache", startTime);
        }
        return result;
    }

    public Resource<Z> decodeSourceFromCache() throws Exception {
        if (!diskCacheStrategy.cacheSource()) {
            return null;
        }

        long startTime = LogTime.getLogTime();
        Resource<T> decoded = loadFromCache(resultKey.getOriginalKey());
        if (Log.isLoggable(TAG, Log.VERBOSE)) {
            logWithTimeAndKey("Decoded source from cache", startTime);
        }
        return transformEncodeAndTranscode(decoded);
    }

可以看到，它们内部都调用了loadFromCache（）方法从缓存当中获取数据，如果是decodeResultFromCache（）方法就直接将数据解码并返回，如果是decodeSourceFromCache（）方法，还要调用一下transformEncodeAndTranscode（）方法转换数据后再解码并返回。
再者，它们调用loadFromCache（）方法时传入的参数却不一样，一个传入的是resultKey，另外一个却又调用了resultKey的getOriginalKey（）方法，分别对应处理后图片缓存Key和原图缓存Key。上文讲过，Glide的缓存Key是由多个参数共同组成的，包括图片的width、height等。但如果我们如果缓存的原始图片，其实并不需要这么多的参数，因为并没有对原始图片进行过尺寸缩放等额外处理。那么我们来看一下getOriginalKey()方法的源码：

OriginalKey.java

    public Key getOriginalKey() {
        if (originalKey == null) {
            originalKey = new OriginalKey(id, signature);
        }
        return originalKey;
    }

可以看到，这里忽略了大部分的参数，只使用了id和signature两个参数来构成Key，而signature参数大多数情况下都是用不到的，因此几乎是由id（也就是图片url）来决定OriginalKey。
接下来让我们回到loadFromCache（）方法，看看内部的源码：

DecodeJob.java

    private Resource<T> loadFromCache(Key key) throws IOException {
        File cacheFile = diskCacheProvider.getDiskCache().get(key);
        if (cacheFile == null) {
            return null;
        }

        Resource<T> result = null;
        try {
            result = loadProvider.getCacheDecoder().decode(cacheFile, width, height);
        } finally {
            if (result == null) {
                diskCacheProvider.getDiskCache().delete(key);
            }
        }
        return result;
    }

loadFromCache（）方法调用getDiskCache()方法获取到的就是Glide自己编写的DiskLruCache工具类的实例，然后调用它的get（）方法并把缓存key传入，得到硬盘缓存的文件。如果文件为null就返回null，如果文件不为空则将它解码成Resource对象后返回。
让我们重新回到decode（）方法，看看方法中另一个else分支decodeFromSource（）方法执行了什么逻辑：
DecodeJob.java

    public Resource<Z> decodeFromSource() throws Exception {
        Resource<T> decoded = decodeSource();
        return transformEncodeAndTranscode(decoded);
    }

    private Resource<T> decodeSource() throws Exception {
        Resource<T> decoded = null;
        try {
            long startTime = LogTime.getLogTime();
            final A data = fetcher.loadData(priority);
            if (Log.isLoggable(TAG, Log.VERBOSE)) {
                logWithTimeAndKey("Fetched data", startTime);
            }
            if (isCancelled) {
                return null;
            }
            decoded = decodeFromSourceData(data);
        } finally {
            fetcher.cleanup();
        }
        return decoded;
    }

    private Resource<Z> transformEncodeAndTranscode(Resource<T> decoded) {
        long startTime = LogTime.getLogTime();
        Resource<T> transformed = transform(decoded);
        if (Log.isLoggable(TAG, Log.VERBOSE)) {
            logWithTimeAndKey("Transformed resource from source", startTime);
        }

        writeTransformedToCache(transformed);

        startTime = LogTime.getLogTime();
        Resource<Z> result = transcode(transformed);
        if (Log.isLoggable(TAG, Log.VERBOSE)) {
            logWithTimeAndKey("Transcoded transformed from source", startTime);
        }
        return result;
    }

decodeFromSource（）中只有两行代码，decodeSource（）顾名思义是用来解析原图片的，而transformEncodeAndTranscode（）则是用来对图片进行转换和转码的。decodeSource（）方法中主要做了如下逻辑：
1.通过 fetcher.loadData(priority)方法来获取到图片数据，比如从网络获取图片资源；
2.通过decodeFromSourceData(data)方法来解码数据：
3.decodeFromSourceData()方法中，判断配置的缓存策略是否支持磁盘缓存，如果支持的话，则调用cacheAndDecodeSourceData()方法来缓存数据及解码。Glide提供了DiskCacheProvider类，其本质是封装后的DiskLruCache实例。
相关代码如下：
HttpUrlFetcher.java

    @Override
    public InputStream loadData(Priority priority) throws Exception {
        return loadDataWithRedirects(glideUrl.toURL(), 0 /*redirects*/, null /*lastUrl*/, glideUrl.getHeaders());
    }

    private InputStream loadDataWithRedirects(URL url, int redirects, URL lastUrl, Map<String, String> headers)
            throws IOException {
        if (redirects >= MAXIMUM_REDIRECTS) {
            throw new IOException("Too many (> " + MAXIMUM_REDIRECTS + ") redirects!");
        } else {
            // Comparing the URLs using .equals performs additional network I/O and is generally broken.
            // See http://michaelscharf.blogspot.com/2006/11/javaneturlequals-and-hashcode-make.html.
            try {
                if (lastUrl != null && url.toURI().equals(lastUrl.toURI())) {
                    throw new IOException("In re-direct loop");
                }
            } catch (URISyntaxException e) {
                // Do nothing, this is best effort.
            }
        }
        urlConnection = connectionFactory.build(url);
        for (Map.Entry<String, String> headerEntry : headers.entrySet()) {
          urlConnection.addRequestProperty(headerEntry.getKey(), headerEntry.getValue());
        }
        urlConnection.setConnectTimeout(2500);
        urlConnection.setReadTimeout(2500);
        urlConnection.setUseCaches(false);
        urlConnection.setDoInput(true);

        // Connect explicitly to avoid errors in decoders if connection fails.
        urlConnection.connect();
        if (isCancelled) {
            return null;
        }
        final int statusCode = urlConnection.getResponseCode();
        if (statusCode / 100 == 2) {
            return getStreamForSuccessfulRequest(urlConnection);
        } else if (statusCode / 100 == 3) {
            String redirectUrlString = urlConnection.getHeaderField("Location");
            if (TextUtils.isEmpty(redirectUrlString)) {
                throw new IOException("Received empty or null redirect url");
            }
            URL redirectUrl = new URL(url, redirectUrlString);
            return loadDataWithRedirects(redirectUrl, redirects + 1, url, headers);
        } else {
            if (statusCode == -1) {
                throw new IOException("Unable to retrieve response code from HttpUrlConnection.");
            }
            throw new IOException("Request failed " + statusCode + ": " + urlConnection.getResponseMessage());
        }
    }

DecodeJob.java

    private Resource<T> decodeFromSourceData(A data) throws IOException {
        final Resource<T> decoded;
        if (diskCacheStrategy.cacheSource()) {
            decoded = cacheAndDecodeSourceData(data);
        } else {
            long startTime = LogTime.getLogTime();
            decoded = loadProvider.getSourceDecoder().decode(data, width, height);
            if (Log.isLoggable(TAG, Log.VERBOSE)) {
                logWithTimeAndKey("Decoded from source", startTime);
            }
        }
        return decoded;
    }

    private Resource<T> cacheAndDecodeSourceData(A data) throws IOException {
        long startTime = LogTime.getLogTime();
        SourceWriter<A> writer = new SourceWriter<A>(loadProvider.getSourceEncoder(), data);
        diskCacheProvider.getDiskCache().put(resultKey.getOriginalKey(), writer);
        if (Log.isLoggable(TAG, Log.VERBOSE)) {
            logWithTimeAndKey("Wrote source to cache", startTime);
        }

        startTime = LogTime.getLogTime();
        Resource<T> result = loadFromCache(resultKey.getOriginalKey());
        if (Log.isLoggable(TAG, Log.VERBOSE) && result != null) {
            logWithTimeAndKey("Decoded source from cache", startTime);
        }
        return result;
    }

注意，diskCacheProvider调用了getDiskCache（）方法获取DiskLruCache实例，接着调用它的put（）方法写入硬盘缓存，这里原始图片的缓存key用的是resultKey.getOriginalKey（），最后让我们再看一下decodeFromSource（）方法中第二行transformEncodeAndTranscode(decoded)方法内部做了哪些逻辑：
DecodeJob.java

    private Resource<Z> transformEncodeAndTranscode(Resource<T> decoded) {
        long startTime = LogTime.getLogTime();
        Resource<T> transformed = transform(decoded);
        if (Log.isLoggable(TAG, Log.VERBOSE)) {
            logWithTimeAndKey("Transformed resource from source", startTime);
        }

        writeTransformedToCache(transformed);

        startTime = LogTime.getLogTime();
        Resource<Z> result = transcode(transformed);
        if (Log.isLoggable(TAG, Log.VERBOSE)) {
            logWithTimeAndKey("Transcoded transformed from source", startTime);
        }
        return result;
    }

    private void writeTransformedToCache(Resource<T> transformed) {
        if (transformed == null || !diskCacheStrategy.cacheResult()) {
            return;
        }
        long startTime = LogTime.getLogTime();
        SourceWriter<Resource<T>> writer = new SourceWriter<Resource<T>>(loadProvider.getEncoder(), transformed);
        diskCacheProvider.getDiskCache().put(resultKey, writer);
        if (Log.isLoggable(TAG, Log.VERBOSE)) {
            logWithTimeAndKey("Wrote transformed from source to cache", startTime);
        }
    }

transformEncodeAndTranscode（）方法首先调用transform()方法来对图片进行转换，然后在writeTransformedToCache（）方法中将转换过后的图片写入到硬盘缓存中，调用的同样是DiskLruCache实例的put（）方法，不过这里用的缓存key是resultKey。

至此，我们已经把Glide内部主要逻辑分析完毕，可以说Glide是Android现有开源框架出色封装的典范，封装后用户完全感觉不到内部复杂的逻辑，仅仅通过一行链式调用就完成了很多逻辑。不得不惊叹作者的高超代码艺术。让我们下次再会。