Tinker热修复原理浅析

Tinker实现原理和源码分析

Tinker工程结构

直接从github上clone Tinker的源码进行食用如下:


Tinker热修复原理浅析_第1张图片
image

接入流程

  1. gradle相关配置主项目中build.gradle加入
buildscript {
    dependencies {
        classpath ('com.tencent.tinker:tinker-patch-gradle-plugin:1.8.1')
    }
}

在app工程中build.gradle加入

dependencies {
    //可选,用于生成application类 
    provided('com.tencent.tinker:tinker-android-anno:1.8.1')
    //tinker的核心库
    compile('com.tencent.tinker:tinker-android-lib:1.8.1') 
}
...
...
//apply tinker插件
apply plugin: 'com.tencent.tinker.patch'

这里需要注意tinker编译阶段会判断一个TinkerId的字段,该字段默认由git提交记录生成HEAD(git rev-parse --short HEAD)而且是在rootproject中执行的git命令,所以个别工程可能在rootproject目录没有git init过,可以选择在那初始化git或者自定义gradle修改gitSha方法。

出包还是使用正常的build过程,测试阶段选择assembleDebug,Tinker产出patch使用gradle tinkerPatchDebug同样也支持Flavor和Variant,Tiner会在主工程build目录下创建bakApk,下面会有一个app-yydd-hh-mm-ss的目录里面对应有Favor子目录里面包含了通过assemble出的apk包。在build目录下的outputs中有tinkerPatch里面同样也区分了build variant产物。

Tinker热修复原理浅析_第2张图片
image

需要注意的是在debug出包测试过程中需要修改gradle的参数

ext {
    //for some reason, you may want to ignore tinkerBuild, such as instant run debug build?
    tinkerEnabled = true

    //for normal build
    //old apk file to build patch apk
    tinkerOldApkPath = "${bakPath}/app-debug-1018-17-58-54.apk"
    //proguard mapping file to build patch apk
    tinkerApplyMappingPath = "${bakPath}/app-debug-1018-17-32-47-mapping.txt"
    //resource R.txt to build patch apk, must input if there is resource changed
    tinkerApplyResourcePath = "${bakPath}/app-debug-1018-17-32-47-R.txt"

    //使用buildvariants修改此处app信息作为基准包
    tinkerBuildFlavorDirectory = "${bakPath}/app-1020-11-52-37"
}

release出包可以直接在gradle命令带上后缀-POLD_APK= -PAPPLY_MAPPING= -PAPPLY_RESOURCE=

  1. Application改造

Tinker采用了代码框架的方案来解决应用启动加载默认Application导致patch无法修复它。原理就是使用一个ApplicationLike代理类来完成原Application的功能,把所有原理Application中的代码逻辑移动到ApplicationLike中,然后删除原来的Application类通过注解让Tinker自动生成默认Application。

@DefaultLifeCycle(application = "com.*.Application",
        flags = ShareConstants.TINKER_ENABLE_ALL,
        loadVerifyFlag = false)
public class ApplicationLike extends DefaultApplicationLike {
    @Override
    public void onBaseContextAttached(Context base) {
        super.onBaseContextAttached(base);
        //you must install multiDex whatever tinker is installed!
        MultiDex.install(base);

        TinkerManager.setTinkerApplicationLike(this);

        TinkerManager.initFastCrashProtect();
        //should set before tinker is installed
        TinkerManager.setUpgradeRetryEnable(true);

        //installTinker after load multiDex
        //or you can put com.tencent.tinker.** to main dex
        TinkerManager.installTinker(this);
    }
    
}

TinkerManager.java

public static void installTinker(ApplicationLike appLike) {
        if (isInstalled) {
            TinkerLog.w(TAG, "install tinker, but has installed, ignore");
            return;
        }
        //or you can just use DefaultLoadReporter
        LoadReporter loadReporter = new TinkerLoadReporter(appLike.getApplication());
        //or you can just use DefaultPatchReporter
        PatchReporter patchReporter = new TinkerPatchReporter(appLike.getApplication());
        //or you can just use DefaultPatchListener
        PatchListener patchListener = new TinkerPatchListener(appLike.getApplication());
        //you can set your own upgrade patch if you need
        AbstractPatch upgradePatchProcessor = new UpgradePatch();

        TinkerInstaller.install(appLike,
                loadReporter, patchReporter, patchListener,
                TinkerResultService.class, upgradePatchProcessor);

        isInstalled = true;
    }

其中参数application代表自动生成的application包名路径,flags代表tinker作用域包括res、so、dex,loadVerifyFlag代表是否开启加载patch前各个文件进行md5校验,还有一个loaderClass默认是"com.tencent.tinker.loader.TinkerLoader"表示加载Tinker的主类名。

onBaseContextAttached方法里需要初始化一些Tinker相关回调(在installTinker方法中)PatchReporter是对patch进程中合成过程的回调接口实现,LoadReporter是对主进程加载patch dex补丁过程的回调接口实现。PatchListener可以对接收到patch补丁后做自定义的check操作比如渠道检查和存储空间检查。

设置AbstractResultService的实现类TinkerResultService作为合成补丁完成后的处理重启逻辑的IntentService。

设置AbstractPatch的实现类UpgradePatch类作为合成patch方法tryPatch实现类。

Tinker原理

先上github官方首页的图


Tinker热修复原理浅析_第3张图片
image

BaseApk就是我们的基准包,也就是渠道上线的包。

NewApk就是我们的hotfix包,包括修复的代码资源以及so文件。

Tinker做了对应的DexDiff、ResDiff、BsDiff来产出一个patch.apk,里面具体内容也是由lib、res和dex文件组成,assets中还有对应的dex、res和so信息


Tinker热修复原理浅析_第4张图片
image

然后Tinker通过找到基准包data/app/packagename/base.apk通过DexPatch合成新的dex,并且合成一个tinker_classN.apk(其实就是包含了所有合成dex的zip包)接着在运行时通过反射把这个合成dex文件插入到PathClassLoader中的dexElements数组的前面,保证类加载时优先加载补丁dex中的class。

接下来我们就从加载patch和合成patch来弄清Tinker的整个工作流程。

Tinker源码分析之加载补丁Patch流程

默认情况如果使用了Tinker注解产生Application可以看到它继承了TinkerApplication

/**
 *
 * Generated application for tinker life cycle
 *
 */
public class Application extends TinkerApplication {

    public Application() {
        super(7, "com.jiuyan.infashion.ApplicationLike", "com.tencent.tinker.loader.TinkerLoader", false);
    }

}

跟踪到TinkerApplication在方法attachBaseContext中找到最终会调用loadTinker方法来,最后反射调用了变量loaderClassName定义类中的tryLoad方法,默认是com.tencent.tinker.loader.TinkerLoader这个类中的tryLoad方法。该方法调用tryLoadPatchFilesInternal来执行相关代码逻辑。

private void tryLoadPatchFilesInternal(TinkerApplication app, Intent resultIntent) {
    //..省略一大段校验相关逻辑代码
    
    //now we can load patch jar
    if (isEnabledForDex) {
        boolean loadTinkerJars = TinkerDexLoader.loadTinkerJars(app, patchVersionDirectory, oatDex, resultIntent, isSystemOTA);
        if (isSystemOTA) {
            // update fingerprint after load success
            patchInfo.fingerPrint = Build.FINGERPRINT;
            patchInfo.oatDir = loadTinkerJars ? ShareConstants.INTERPRET_DEX_OPTIMIZE_PATH : ShareConstants.DEFAULT_DEX_OPTIMIZE_PATH;
            // reset to false
            oatModeChanged = false;

            if (!SharePatchInfo.rewritePatchInfoFileWithLock(patchInfoFile, patchInfo, patchInfoLockFile)) {
                ShareIntentUtil.setIntentReturnCode(resultIntent, ShareConstants.ERROR_LOAD_PATCH_REWRITE_PATCH_INFO_FAIL);
                Log.w(TAG, "tryLoadPatchFiles:onReWritePatchInfoCorrupted");
                    return;
                }
                // update oat dir
                resultIntent.putExtra(ShareIntentUtil.INTENT_PATCH_OAT_DIR, patchInfo.oatDir);
            }
            if (!loadTinkerJars) {
                Log.w(TAG, "tryLoadPatchFiles:onPatchLoadDexesFail");
                return;
            }
    }

    //now we can load patch resource
    if (isEnabledForResource) {
        boolean loadTinkerResources = TinkerResourceLoader.loadTinkerResources(app, patchVersionDirectory, resultIntent);
            if (!loadTinkerResources) {
                Log.w(TAG, "tryLoadPatchFiles:onPatchLoadResourcesFail");
                return;
            }
        }
        // kill all other process if oat mode change
        if (oatModeChanged) {
            ShareTinkerInternals.killAllOtherProcess(app);
            Log.i(TAG, "tryLoadPatchFiles:oatModeChanged, try to kill all other process");
    }
    //all is ok!
    ShareIntentUtil.setIntentReturnCode(resultIntent, ShareConstants.ERROR_LOAD_OK);
    Log.i(TAG, "tryLoadPatchFiles: load end, ok!");
    return;
}

这里省略了非常多的Tinker校验,一共有包括tinker自身enable属性以及md5和文件存在等相关检查。

先看加载dex部分,TinkerDexLoader.loadTinkerJars传入四个参数,分别为application,patchVersionDirectory当前patch文件目录,oatDir当前patch的oat文件目录,intent,当前patch是否需要进行oat(由于系统OTA更新需要dex oat重新生成缓存)。

/**
 * Load tinker JARs and add them to
 * the Application ClassLoader.
 *
 * @param application The application.
 */
@TargetApi(Build.VERSION_CODES.ICE_CREAM_SANDWICH)
public static boolean loadTinkerJars(final TinkerApplication application, String directory, String oatDir, Intent intentResult, boolean isSystemOTA) {
    if (loadDexList.isEmpty() && classNDexInfo.isEmpty()) {
            Log.w(TAG, "there is no dex to load");
            return true;
    }

    PathClassLoader classLoader = (PathClassLoader) TinkerDexLoader.class.getClassLoader();
    if (classLoader != null) {
            Log.i(TAG, "classloader: " + classLoader.toString());
    } else {
            Log.e(TAG, "classloader is null");
            ShareIntentUtil.setIntentReturnCode(intentResult, ShareConstants.ERROR_LOAD_PATCH_VERSION_DEX_CLASSLOADER_NULL);
            return false;
    }
    String dexPath = directory + "/" + DEX_PATH + "/";

    ArrayList legalFiles = new ArrayList<>();

    for (ShareDexDiffPatchInfo info : loadDexList) {
        //for dalvik, ignore art support dex
        if (isJustArtSupportDex(info)) {
            continue;
        }

        String path = dexPath + info.realName;
        File file = new File(path);

        //...check md5
        legalFiles.add(file);
    }
    //... verify merge classN.apk
    
    File optimizeDir = new File(directory + "/" + oatDir);

    if (isSystemOTA) {
        final boolean[] parallelOTAResult = {true};
        final Throwable[] parallelOTAThrowable = new Throwable[1];
        String targetISA;
        try {
            targetISA = ShareTinkerInternals.getCurrentInstructionSet();
        } catch (Throwable throwable) {
            Log.i(TAG, "getCurrentInstructionSet fail:" + throwable);
//                try {
//                    targetISA = ShareOatUtil.getOatFileInstructionSet(testOptDexFile);
//                } catch (Throwable throwable) {
                // don't ota on the front
            deleteOutOfDateOATFile(directory);

            intentResult.putExtra(ShareIntentUtil.INTENT_PATCH_INTERPRET_EXCEPTION, throwable);
            ShareIntentUtil.setIntentReturnCode(intentResult, ShareConstants.ERROR_LOAD_PATCH_GET_OTA_INSTRUCTION_SET_EXCEPTION);
            return false;
//               }
        }

        deleteOutOfDateOATFile(directory);

        Log.w(TAG, "systemOTA, try parallel oat dexes, targetISA:" + targetISA);
        // change dir
        optimizeDir = new File(directory + "/" + INTERPRET_DEX_OPTIMIZE_PATH);

        TinkerDexOptimizer.optimizeAll(
            legalFiles, optimizeDir, true, targetISA,
            new TinkerDexOptimizer.ResultCallback() {
                //... callback
            }
        );


        if (!parallelOTAResult[0]) {
            Log.e(TAG, "parallel oat dexes failed");
            intentResult.putExtra(ShareIntentUtil.INTENT_PATCH_INTERPRET_EXCEPTION, parallelOTAThrowable[0]);
            ShareIntentUtil.setIntentReturnCode(intentResult, ShareConstants.ERROR_LOAD_PATCH_OTA_INTERPRET_ONLY_EXCEPTION);
            return false;
        }
    }
    try {
        SystemClassLoaderAdder.installDexes(application, classLoader, optimizeDir, legalFiles);
    } catch (Throwable e) {
        Log.e(TAG, "install dexes failed");
//            e.printStackTrace();
        intentResult.putExtra(ShareIntentUtil.INTENT_PATCH_EXCEPTION, e);
        ShareIntentUtil.setIntentReturnCode(intentResult, ShareConstants.ERROR_LOAD_PATCH_VERSION_DEX_LOAD_EXCEPTION);
        return false;
    }

    return true;
}

省略了几处md5校验代码,首先获取到PathClassLoader并且通过判断系统是否art过滤出对应legalFiles,如果发现系统进行过OTA升级则通过ProcessBuilder命令行执行dex2oat进行并行的oat优化dex,最后调用installDexes来安装dex。

 @SuppressLint("NewApi")
public static void installDexes(Application application, PathClassLoader loader, File dexOptDir, List files)
        throws Throwable {
    Log.i(TAG, "installDexes dexOptDir: " + dexOptDir.getAbsolutePath() + ", dex size:" + files.size());

    if (!files.isEmpty()) {
        files = createSortedAdditionalPathEntries(files);
        ClassLoader classLoader = loader;
        if (Build.VERSION.SDK_INT >= 24 && !checkIsProtectedApp(files)) {
            classLoader = AndroidNClassLoader.inject(loader, application);
        }
        //because in dalvik, if inner class is not the same classloader with it wrapper class.
        //it won't fail at dex2opt
        if (Build.VERSION.SDK_INT >= 23) {
            V23.install(classLoader, files, dexOptDir);
        } else if (Build.VERSION.SDK_INT >= 19) {
            V19.install(classLoader, files, dexOptDir);
        } else if (Build.VERSION.SDK_INT >= 14) {
            V14.install(classLoader, files, dexOptDir);
        } else {
            V4.install(classLoader, files, dexOptDir);
        }
        //install done
        sPatchDexCount = files.size();
        Log.i(TAG, "after loaded classloader: " + classLoader + ", dex size:" + sPatchDexCount);

        if (!checkDexInstall(classLoader)) {
            //reset patch dex
            SystemClassLoaderAdder.uninstallPatchDex(classLoader);
            throw new TinkerRuntimeException(ShareConstants.CHECK_DEX_INSTALL_FAIL);
        }
    }
}

针对不同的Android版本需要对DexPathList中的dexElements生成方法makeDexElements进行适配。

主要做的事情就是获取当前app运行时PathClassLoader的父类BaseDexClassLoader中的pathList对象,通过反射它的makePathElements方法传入对应的path参数构造出Element[]数组对象,然后拿到pathList中的Element[]数组对象dexElements两者进行合并排序,把patch的相关dex信息放在数组前端,最后合并数组结果赋值给pathList保证classloader优先到patch中查找加载。

Tinker源码分析之合成补丁Patch流程

合并代码入口

Tinker.with(context).getPatchListener().onPatchReceived(patchLocation);

传入patch文件所在位置即可,推荐通过服务端下发下载到对应的/data/data/应用目录下防止被三方软件清理,onPatchReceived方法在DefaultPatchListener.java中。

@Override
public int onPatchReceived(String path) {
    File patchFile = new File(path);

    int returnCode = patchCheck(path, SharePatchFileUtil.getMD5(patchFile));

    if (returnCode == ShareConstants.ERROR_PATCH_OK) {
        TinkerPatchService.runPatchService(context, path);
    } else {
        Tinker.with(context).getLoadReporter().onLoadPatchListenerReceiveFail(new File(path), returnCode);
    }
    return returnCode;
}

先进行tinker的一些初始化配置检查还有patch文件的md5校验。如果check通过returnCode为0则执行runPatchService启动一个IntentService的子类TinkerPatchService来处理patch的合成。接下来看Service执行任务代码:

@Override
protected void onHandleIntent(Intent intent) {
    final Context context = getApplicationContext();
    Tinker tinker = Tinker.with(context);
    tinker.getPatchReporter().onPatchServiceStart(intent);

    if (intent == null) {
        TinkerLog.e(TAG, "TinkerPatchService received a null intent, ignoring.");
        return;
    }
    String path = getPatchPathExtra(intent);
    if (path == null) {
        TinkerLog.e(TAG, "TinkerPatchService can't get the path extra, ignoring.");
        return;
    }
    File patchFile = new File(path);

    long begin = SystemClock.elapsedRealtime();
    boolean result;
    long cost;
    Throwable e = null;

    increasingPriority();
    PatchResult patchResult = new PatchResult();
    try {
        if (upgradePatchProcessor == null) {
            throw new TinkerRuntimeException("upgradePatchProcessor is null.");
        }
        result = upgradePatchProcessor.tryPatch(context, path, patchResult);
    } catch (Throwable throwable) {
        e = throwable;
        result = false;
        tinker.getPatchReporter().onPatchException(patchFile, e);
    }

    cost = SystemClock.elapsedRealtime() - begin;
    tinker.getPatchReporter().
    onPatchResult(patchFile, result, cost);

    patchResult.isSuccess = result;
    patchResult.rawPatchFilePath = path;
    patchResult.costTime = cost;
    patchResult.e = e;

    AbstractResultService.runResultService(context, patchResult, getPatchResultExtra(intent));

}

回调PatchReporter接口的onPatchServiceStart方法,然后取到patch文件同时调用increasingPriority启动一个不可见前台Service保活这个TinkerPatchService,最后开始合成patchupgradePatchProcessor.tryPatch。同样省略一些常规check代码:

@Override
public boolean tryPatch(Context context, String tempPatchPath, PatchResult patchResult) {
    Tinker manager = Tinker.with(context);
    final File patchFile = new File(tempPatchPath);
    //...省略
    
    //check ok, we can real recover a new patch
    final String patchDirectory = manager.getPatchDirectory().getAbsolutePath();

    File patchInfoLockFile = SharePatchFileUtil.getPatchInfoLockFile(patchDirectory);
    File patchInfoFile = SharePatchFileUtil.getPatchInfoFile(patchDirectory);

    SharePatchInfo oldInfo = SharePatchInfo.readAndCheckPropertyWithLock(patchInfoFile, patchInfoLockFile);

    //it is a new patch, so we should not find a exist
    SharePatchInfo newInfo;

    //already have patch
    if (oldInfo != null) {
        if (oldInfo.oldVersion == null || oldInfo.newVersion == null || oldInfo.oatDir == null) {
            TinkerLog.e(TAG, "UpgradePatch tryPatch:onPatchInfoCorrupted");
            manager.getPatchReporter().onPatchInfoCorrupted(patchFile, oldInfo.oldVersion, oldInfo.newVersion);
            return false;
        }

        if (!SharePatchFileUtil.checkIfMd5Valid(patchMd5)) {
            TinkerLog.e(TAG, "UpgradePatch tryPatch:onPatchVersionCheckFail md5 %s is valid", patchMd5);
            manager.getPatchReporter().onPatchVersionCheckFail(patchFile, oldInfo, patchMd5);
            return false;
        }
        // if it is interpret now, use changing flag to wait main process
        final String finalOatDir = oldInfo.oatDir.equals(ShareConstants.INTERPRET_DEX_OPTIMIZE_PATH)
            ? ShareConstants.CHANING_DEX_OPTIMIZE_PATH : oldInfo.oatDir;
        newInfo = new SharePatchInfo(oldInfo.oldVersion, patchMd5, Build.FINGERPRINT, finalOatDir);
    } else {
        newInfo = new SharePatchInfo("", patchMd5, Build.FINGERPRINT, ShareConstants.DEFAULT_DEX_OPTIMIZE_PATH);
    }
    
    //it is a new patch, we first delete if there is any files
    //don't delete dir for faster retry
//        SharePatchFileUtil.deleteDir(patchVersionDirectory);
    final String patchName = SharePatchFileUtil.getPatchVersionDirectory(patchMd5);

    final String patchVersionDirectory = patchDirectory + "/" + patchName;

    TinkerLog.i(TAG, "UpgradePatch tryPatch:patchVersionDirectory:%s", patchVersionDirectory);

    //copy file
    File destPatchFile = new File(patchVersionDirectory + "/" + SharePatchFileUtil.getPatchVersionFile(patchMd5));

    //...省略
    
    if (!DexDiffPatchInternal.tryRecoverDexFiles(manager, signatureCheck, context, patchVersionDirectory, destPatchFile)) {
        TinkerLog.e(TAG, "UpgradePatch tryPatch:new patch recover, try patch dex failed");
        return false;
    }

    if (!BsDiffPatchInternal.tryRecoverLibraryFiles(manager, signatureCheck, context, patchVersionDirectory, destPatchFile)) {
        TinkerLog.e(TAG, "UpgradePatch tryPatch:new patch recover, try patch library failed");
        return false;
    }

    if (!ResDiffPatchInternal.tryRecoverResourceFiles(manager, signatureCheck, context, patchVersionDirectory, destPatchFile)) {
        TinkerLog.e(TAG, "UpgradePatch tryPatch:new patch recover, try patch resource failed");
        return false;
    }
    
    //...省略
}

1.检查是否有之前的patch信息oldInfo,查看旧补丁是否正在执行oat过程,后续会等待主进程oat执行完毕。
2.拷贝new patch到app的data目录的tinker目录下,防止被三方软件删除。
3.分别判断执行tryRecoverDexFiles合成dex,tryRecoverLibraryFiles合成so以及tryRecoverResourceFiles合成资源。

主要看下dex合成过程,这也是我们最关心的地方。

protected static boolean tryRecoverDexFiles(Tinker manager, ShareSecurityCheck checker, Context context,
                                                String patchVersionDirectory, File patchFile) {
    if (!manager.isEnabledForDex()) {
        TinkerLog.w(TAG, "patch recover, dex is not enabled");
            return true;
    }
    String dexMeta = checker.getMetaContentMap().get(DEX_META_FILE);

    if (dexMeta == null) {
        TinkerLog.w(TAG, "patch recover, dex is not contained");
        return true;
    }

    long begin = SystemClock.elapsedRealtime();
    boolean result = patchDexExtractViaDexDiff(context, patchVersionDirectory, dexMeta, patchFile);
    long cost = SystemClock.elapsedRealtime() - begin;
    TinkerLog.i(TAG, "recover dex result:%b, cost:%d", result, cost);
    return result;
}

读取patch包assets/dex_meta.txt信息转换成String,进入patchDexExtractViaDexDiff方法。

private static boolean patchDexExtractViaDexDiff(Context context, String patchVersionDirectory, String meta, final File patchFile) {
        String dir = patchVersionDirectory + "/" + DEX_PATH + "/";

    if (!extractDexDiffInternals(context, dir, meta, patchFile, TYPE_DEX)) {
        TinkerLog.w(TAG, "patch recover, extractDiffInternals fail");
        return false;
    }

    File dexFiles = new File(dir);
    File[] files = dexFiles.listFiles();
    List dexList = files != null ? Arrays.asList(files) : null;

    final String optimizeDexDirectory = patchVersionDirectory + "/" + DEX_OPTIMIZE_PATH + "/";
    return dexOptimizeDexFiles(context, dexList, optimizeDexDirectory, patchFile);

}

首先执行方法extractDexDiffInternals传入了合成后dex路径,前面读取的dex_meta信息,patch文件以及type类型dex。为了节约篇幅只提取了主要的代码,详细代码参考github。

private static boolean extractDexDiffInternals(Context context, String dir, String meta, File patchFile, int type) {
    //parse
    patchList.clear();
    ShareDexDiffPatchInfo.parseDexDiffPatchInfo(meta, patchList);    
    //获取base.apk
    String apkPath = applicationInfo.sourceDir;
    apk = new ZipFile(apkPath);
    patch = new ZipFile(patchFile);
    for (ShareDexDiffPatchInfo info : patchList) {
        String patchRealPath;
        if (infoPath.equals("")) {
            patchRealPath = info.rawName;
        } else {
            patchRealPath = info.path + "/" + info.rawName;
        }
        File extractedFile = new File(dir + info.realName);
        //..省略
        
        ZipEntry patchFileEntry = patch.getEntry(patchRealPath);
        ZipEntry rawApkFileEntry = apk.getEntry(patchRealPath);
        
        patchDexFile(apk, patch, rawApkFileEntry, patchFileEntry, info, extractedFile);
    }
    
    if (!mergeClassNDexFiles(context, patchFile, dir)) {
        return false;
    }
}

1.解析dex_meta内容

Tinker热修复原理浅析_第5张图片
image

对应的 ShareDexDiffPatchInfo信息

final String name = kv[0].trim();
final String path = kv[1].trim();
final String destMd5InDvm = kv[2].trim();
final String destMd5InArt = kv[3].trim();
final String dexDiffMd5 = kv[4].trim();
final String oldDexCrc = kv[5].trim();
final String newDexCrc = kv[6].trim();
final String dexMode = kv[7].trim();

2.循环遍历获取到patch中各个classes.dex的crc和md5信息以及一大片校验代码,调用patchDexFile方法对base.apk和patch中的dex做合并生成新的dex。

3.把合成的dex压缩为一个tinker_classN.apk

接下来看patchDexFile方法,同样只提取了关键代码。

private static void patchDexFile(
        ZipFile baseApk, ZipFile patchPkg, ZipEntry oldDexEntry, ZipEntry patchFileEntry,
        ShareDexDiffPatchInfo patchInfo, File patchedDexFile) throws IOException {
    InputStream oldDexStream = null;
    InputStream patchFileStream = null;

    oldDexStream = new BufferedInputStream(baseApk.getInputStream(oldDexEntry));
    patchFileStream = (patchFileEntry != null ? new BufferedInputStream(patchPkg.getInputStream(patchFileEntry)) : null);
    
    //...省略判断dex是否是jar类型或者是raw类型,做不同处理

    new DexPatchApplier(oldDexStream, patchFileStream).executeAndSaveTo(patchedDexFile);    
}

下面是github官网上对raw和jar区别的解释

Tinker中的dex配置'raw'与'jar'模式应该如何选择?
它们应该说各有优劣势,大概应该有以下几条原则:
如果你的minSdkVersion小于14, 那你务必要选择'jar'模式;
以一个10M的dex为例,它压缩成jar大约为4M,即'jar'模式能节省6M的ROM空间。
对于'jar'模式,我们需要验证压缩包流中dex的md5,这会更耗时,在小米2S上数据大约为'raw'模式126ms, 'jar'模式为246ms。
因为在合成过程中我们已经校验了各个文件的Md5,并将它们存放在/data/data/..目录中。默认每次加载时我们并不会去校验tinker文件的Md5,但是你也可通过开启loadVerifyFlag强制每次加载时校验,但是这会带来一定的时间损耗。
简单来说,'jar'模式更省空间,但是运行时校验的耗时大约为'raw'模式的两倍。如果你没有打开运行时校验,推荐使用'jar'模式。

最后通过ZipFile拿到base.apk和patch中对应dex文件进行合成为patchedDexFile。核心部分是如何把差分的dex和基准dex做合成处理产生新的dex,这部分涉及到了dex文件结构、DexDiff和DexPatch算法,官方wiki里提供了一篇分析文章。

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