1. TinkerInstaller # install()
TinkerInstaller主要提供了两个install()方法,一个简单的,另一个复杂一点的适用于需要自定义更多功能的。
1-1 多参数的install()
先看这个多参数的install(),主要:
- 使用传入参数构建了一个Tinker对象,Tinker使用了构建者模式。
- 调用了Tinker的create()和install()。
public static Tinker install(ApplicationLike applicationLike, LoadReporter loadReporter, PatchReporter patchReporter,
PatchListener listener, Class<? extends AbstractResultService> resultServiceClass, AbstractPatch upgradePatchProcessor) {
Tinker tinker = new Tinker.Builder(applicationLike.getApplication())
.tinkerFlags(applicationLike.getTinkerFlags())
.loadReport(loadReporter)
.listener(listener)
.patchReporter(patchReporter)
.tinkerLoadVerifyFlag(applicationLike.getTinkerLoadVerifyFlag()).build();
Tinker.create(tinker);
tinker.install(applicationLike.getTinkerResultIntent(), resultServiceClass, upgradePatchProcessor);
return tinker;
}
1-2 单参数的install()
单参数的install()也是相同的,只是构建Tinker对象时没有设置那些传入的参数。
public static Tinker install(ApplicationLike applicationLike) {
Tinker tinker = new Tinker.Builder(applicationLike.getApplication()).build();
Tinker.create(tinker);
tinker.install(applicationLike.getTinkerResultIntent());
return tinker;
}
这里就能看出来TinkerInstaller是一个外观模式,并没有执行初始化的工作,真正工作的是Tinker类,所以我们来看Tinker。
1-3 Tinker的单例模式
Tinker类是一个单例,用得是DCL,没有处理DCL失效问题,可能是因为发生的概率太小了且处理会让效率降低。最后是用Builder去构造对象,使用了构建者模式,Builder是Tinker内部类,去管理Tinker的参数。
public static Tinker with(Context context) {
if (!sInstalled) {
throw new TinkerRuntimeException("you must install tinker before get tinker sInstance");
}
if (sInstance == null) {
synchronized (Tinker.class) {
if (sInstance == null) {
sInstance = new Builder(context).build();
}
}
}
return sInstance;
}
Builder在Tinker的内部,统一管理了一些参数,包括多参数install()传入的Reporter和Listener等。
private final Context context;
private final boolean mainProcess;
private final boolean patchProcess;
private int status = -1;
private LoadReporter loadReporter;
private PatchReporter patchReporter;
private PatchListener listener;
private File patchDirectory;
private File patchInfoFile;
private File patchInfoLockFile;
private Boolean tinkerLoadVerifyFlag;
1-4 Builder的构造器
在构造方法中会先初始化一些,主要是context所在线程的判断和各种目录的初始。
public Builder(Context context) {
if (context == null) {
throw new TinkerRuntimeException("Context must not be null.");
}
this.context = context;
this.mainProcess = TinkerServiceInternals.isInMainProcess(context);
this.patchProcess = TinkerServiceInternals.isInTinkerPatchServiceProcess(context);
this.patchDirectory = SharePatchFileUtil.getPatchDirectory(context);
if (this.patchDirectory == null) {
TinkerLog.e(TAG, "patchDirectory is null!");
return;
}
this.patchInfoFile = SharePatchFileUtil.getPatchInfoFile(patchDirectory.getAbsolutePath());
this.patchInfoLockFile = SharePatchFileUtil.getPatchInfoLockFile(patchDirectory.getAbsolutePath());
TinkerLog.w(TAG, "tinker patch directory: %s", patchDirectory);
}
1-5 Builder # patchReporter()
之后就是构建者模式,提供了一系列设置参数的方法。比如这个设置patchReporter的方法。设置的方法不要多次调用,并不会覆盖掉之前的设置,只会抛已经设置过的异常。
public Builder patchReporter(PatchReporter patchReporter) {
if (patchReporter == null) {
throw new TinkerRuntimeException("patchReporter must not be null.");
}
if (this.patchReporter != null) {
throw new TinkerRuntimeException("patchReporter is already set.");
}
this.patchReporter = patchReporter;
return this;
}
1-6 Builder # build()
在build()中会判空,如果是之前还没有初始赋值的参数,就赋默认值。最后调用Tinker构造器传入初始化的参数创建Tinker对象并返回。
public Tinker build() {
if (status == -1) {
status = ShareConstants.TINKER_ENABLE_ALL;
}
// 如果调用的是但参数的install()就会在这里赋默认值
if (loadReporter == null) {
loadReporter = new DefaultLoadReporter(context);
}
if (patchReporter == null) {
patchReporter = new DefaultPatchReporter(context);
}
if (listener == null) {
listener = new DefaultPatchListener(context);
}
if (tinkerLoadVerifyFlag == null) {
tinkerLoadVerifyFlag = false;
}
return new Tinker(context, status, loadReporter, patchReporter, listener, patchDirectory,
patchInfoFile, patchInfoLockFile, mainProcess, patchProcess, tinkerLoadVerifyFlag);
}
1-7 Tinker # create()
回到1-2,Tinker对象初始化好后传入Tinker的create(),来看create()。这个方法就是赋值单例sInstance。
public static void create(Tinker tinker) {
if (sInstance != null) {
throw new TinkerRuntimeException("Tinker instance is already set.");
}
sInstance = tinker;
}
1-8 Tinker # install()
1-2在调用完create()后就会调用install(),Tinker的install()也有两个,单参数的TinkerInstaller#install()调用单参数的install(),多参数的调用多参数的,单参数也是调用多参数的install(),后面两个参数就生成默认对象传入了。
public void install(Intent intentResult) {
install(intentResult, DefaultTinkerResultService.class, new UpgradePatch());
}
再看多参数的install(),它完成真正install的逻辑。主要工作:
- 置标记sInstalled为true。
- 将两个参数注入到TinkerPatchService中。
- 初始化TinkerLoadResult,调用onLoadResult()。
public void install(Intent intentResult, Class<? extends AbstractResultService> serviceClass,
AbstractPatch upgradePatch) {
sInstalled = true;
TinkerPatchService.setPatchProcessor(upgradePatch, serviceClass);
TinkerLog.i(TAG, "try to install tinker, isEnable: %b, version: %s", isTinkerEnabled(), ShareConstants.TINKER_VERSION);
if (!isTinkerEnabled()) {
TinkerLog.e(TAG, "tinker is disabled");
return;
}
if (intentResult == null) {
throw new TinkerRuntimeException("intentResult must not be null.");
}
tinkerLoadResult = new TinkerLoadResult();
tinkerLoadResult.parseTinkerResult(getContext(), intentResult);
//after load code set
loadReporter.onLoadResult(patchDirectory, tinkerLoadResult.loadCode, tinkerLoadResult.costTime);
if (!loaded) {
TinkerLog.w(TAG, "tinker load fail!");
}
}
2. TinkerInstaller # onReceiveUpgradePatch()
同样因为外观模式,所以TinkerInstaller没有任何处理,直接交给Tinker对象中已经初始化好的PatchListener的onPatchReceived()处理。
public static void onReceiveUpgradePatch(Context context, String patchLocation) {
Tinker.with(context).getPatchListener().onPatchReceived(patchLocation);
}
2-1 PatchListener # onPatchReceived()
PatchListener是一个接口,只有一个onPatchReceived()接口方法。DefaultPatchListener是PatchListener实现类。
public interface PatchListener {
int onPatchReceived(String path);
}
2-2 DefaultPatchListener # onPatchReceived()
可以自己去实现PatchListener,但总归需要处理的工作是相似的。我们看一个默认实现,DefaultPatchListener。在onPatchReceived()方法里:
- 调用patchCheck()对patch文件进行一系列的安全性检查,去重写这个方法也就可以实现自己的检查逻辑了。
- 如果检查是安全地就开启TinkerPatchService,开始合并补丁包。
- 如果检查没通过就调用LoadReporter的相关方法通知。
@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;
}
到这里中心就要转去TinkerPatchService了。
总结一下:
- TinkerInstaller使用了外观模式,没有真正逻辑处理,只是封装了Tinker的各种调用,真正处理的逻辑在Tinker中。
- Tinker使用了单例模式(DCL) + 构建者模式。
- TinkerInstaller提供了两个api:
- install()用来创建并初始化Tinker对象,并调用了Tinker对象的create()和install()。
- onReceiveUpgradePatch()中调用了Tinker对象中PatchListener的onPatchReceived()。
- Tinker的install()中也初始了TinkerPatchService,为后面做准备。
- PatchListener的onPatchReceived()用来检查patch文件合法性并开启执行修复工作的TinkerPatchService。
3. TinkerPatchService
TinkerPatchService就是加载合并patch文件的Service,继承了IntentService。
3-1 TinkerPatchService # setPatchProcessor()
回顾一下Tinker的install(),在install()中就传入了两个参数调用了setPatchProcessor()。再追溯参数来源其实是在我们自己编写代码调用TinkerInstaller的复杂install()传入的或是调用简单install()时Tinker的Builder为我们默认创建的。
多参数的源头:
// 回顾我们自己编写的代码,调用 TinkerInstaller#install()。
// 最终最后两个参数被注入到TinkerPatchService中。
AbstractPatch upgradePatchProcessor = new UpgradePatch();
TinkerInstaller.install(mAppLike, loadReporter,
patchReporter, mPatchListener,
CustomResultService.class,// 决定在patch文件安装完毕后的操作
upgradePatchProcessor// 决定patch文件的安装策略
);// 复杂的初始化方法
单参数的源头:
// Tinker # install()
public void install(Intent intentResult) {
// 传入的是为我们默认实例的对象。
install(intentResult, DefaultTinkerResultService.class, new UpgradePatch());
}
一直传递到setPatchProcessor(),最后向TinkerPatchService注入了这两个对象。
- upgradePatch是我们直接创建的UpgradePatch()对象,表示patch文件的安装策略。
- serviceClass是我们自定义的DefaultTinkerResultService类,表示修复完毕后的动作。
public static void setPatchProcessor(AbstractPatch upgradePatch, Class<? extends AbstractResultService> serviceClass) {
upgradePatchProcessor = upgradePatch;
resultServiceClass = serviceClass;
//try to load
try {
Class.forName(serviceClass.getName());
} catch (ClassNotFoundException e) {
e.printStackTrace();
}
}
3-2 TinkerPatchService # runPatchService()
接着上面看一下runPatchService(),就是启动TinkerPatchService的代码,intent中还传了一个patch文件路径path和一个在Tinker#install()中传入的一个ResultService类名。
public static void runPatchService(Context context, String path) {
try {
Intent intent = new Intent(context, TinkerPatchService.class);
intent.putExtra(PATCH_PATH_EXTRA, path);
intent.putExtra(RESULT_CLASS_EXTRA, resultServiceClass.getName());
context.startService(intent);
} catch (Throwable throwable) {
TinkerLog.e(TAG, "start patch service fail, exception:" + throwable);
}
}
3-3 TinkerPatchService # onHandleIntent()
- 在这个方法中最重要的就是调用了tryPatch(),也就是更近一步的修复逻辑,因为onHandleIntent()是支持耗时操作的,所以完全可以猜想tryPatch()是同步方法。
- 其次重要就是在处理完tryPatch()之后会开启ResultService,执行修复完毕后的工作。
@Override
protected void onHandleIntent(Intent intent) {
final Context context = getApplicationContext();
Tinker tinker = Tinker.with(context);
// PatchReporter回调
tinker.getPatchReporter().onPatchServiceStart(intent);
// ...一些异常判断处理...
// 提升进程优先级,尽可能保证此Service不被kill
increasingPriority();
PatchResult patchResult = new PatchResult();
try {
if (upgradePatchProcessor == null) {
throw new TinkerRuntimeException("upgradePatchProcessor is null.");
}
// 核心调用tryPatch()
result = upgradePatchProcessor.tryPatch(context, path, patchResult);
} catch (Throwable throwable) {
e = throwable;
result = false;
// PatchReporter回调
tinker.getPatchReporter().onPatchException(patchFile, e);
}
cost = SystemClock.elapsedRealtime() - begin;
// PatchReporter回调
tinker.getPatchReporter().onPatchResult(patchFile, result, cost);
patchResult.isSuccess = result;
patchResult.rawPatchFilePath = path;
patchResult.costTime = cost;
patchResult.e = e;
// 开始执行ResultService,执行修复完毕后的工作
AbstractResultService.runResultService(context, patchResult, getPatchResultExtra(intent));
}
3-4 TinkerPatchService # increasingPriority()
在说两个核心过程之前先来看这个方法,这个方法在tryPatch()之前被调用,主要是利用系统漏洞让Service优先级高一些避免轻易被回收。
private void increasingPriority() {
TinkerLog.i(TAG, "try to increase patch process priority");
try {
Notification notification = new Notification();
if (Build.VERSION.SDK_INT < 18) {
startForeground(notificationId, notification);
} else {
startForeground(notificationId, notification);
// start InnerService
startService(new Intent(this, InnerService.class));
}
} catch (Throwable e) {
TinkerLog.i(TAG, "try to increase patch process priority error:" + e);
}
}
public static class InnerService extends Service {
@Override
public void onCreate() {
super.onCreate();
try {
startForeground(notificationId, new Notification());
} catch (Throwable e) {
TinkerLog.e(TAG, "InnerService set service for push exception:%s.", e);
}
// kill
stopSelf();
}
@Override
public void onDestroy() {
stopForeground(true);
super.onDestroy();
}
@Override
public IBinder onBind(Intent intent) {
return null;
}
}
4. UpgradePatch # tryPatch()
在上面分析的TinkerPatchService#onHanleIntent():
result = upgradePatchProcessor.tryPatch(context, path, patchResult);
4-1 AbstractPatch
upgradePatchProcessor是AbstractPatch类的,只有一个抽象方法tryPatch()。
public abstract class AbstractPatch {
public abstract boolean tryPatch(Context context, String tempPatchPath, PatchResult patchResult);
}
upgradePatchProcessor是AbstractPatch的实例对象,在Tinker的install()调用时传入,也就是多参数TinkerInstaller的install()传入的,实现类是UpgradePatch,看tryPatch()实现,真的是非常长,我们分成两个部分来看,显示检查再是算法调用。
4-2 UpgradePatch # tryPatch()中的检查逻辑
tryPatch()的返回值便是合成Patch成功与否,在方法的开始都是一些判断,对Tinker的检查、文件的检查、签名检查、TinkerId检查、文件md5检查等,一旦检查不安全就直接返回false。
@Override
public boolean tryPatch(Context context, String tempPatchPath, PatchResult patchResult) {
Tinker manager = Tinker.with(context);
final File patchFile = new File(tempPatchPath);
// 检查Tinker参数和SharedPreferences是否可用
if (!manager.isTinkerEnabled() || !ShareTinkerInternals.isTinkerEnableWithSharedPreferences(context)) {
TinkerLog.e(TAG, "UpgradePatch tryPatch:patch is disabled, just return");
return false;
}
// 判断patch存在、可读、是文件、大小大于0
if (!SharePatchFileUtil.isLegalFile(patchFile)) {
TinkerLog.e(TAG, "UpgradePatch tryPatch:patch file is not found, just return");
return false;
}
//check the signature, we should create a new checker
ShareSecurityCheck signatureCheck = new ShareSecurityCheck(context);
// 解压patch去检查签名、TinkerId、和patch压缩包中文件全不全
int returnCode = ShareTinkerInternals.checkTinkerPackage(context, manager.getTinkerFlags(), patchFile, signatureCheck);
if (returnCode != ShareConstants.ERROR_PACKAGE_CHECK_OK) {
TinkerLog.e(TAG, "UpgradePatch tryPatch:onPatchPackageCheckFail");
manager.getPatchReporter().onPatchPackageCheckFail(patchFile, returnCode);
return false;
}
// 获取patch的md5
String patchMd5 = SharePatchFileUtil.getMD5(patchFile);
if (patchMd5 == null) {
TinkerLog.e(TAG, "UpgradePatch tryPatch:patch md5 is null, just return");
return false;
}
//use md5 as version
// 存patch文件的md5
patchResult.patchVersion = patchMd5;
TinkerLog.i(TAG, "UpgradePatch tryPatch:patchMd5:%s", patchMd5);
//check ok, we can real recover a new patch
// 从缓存之前存过的取文件信息
final String patchDirectory = manager.getPatchDirectory().getAbsolutePath();
File patchInfoLockFile = SharePatchFileUtil.getPatchInfoLockFile(patchDirectory);
File patchInfoFile = SharePatchFileUtil.getPatchInfoFile(patchDirectory);
// 看之前是不是有patch
SharePatchInfo oldInfo = SharePatchInfo.readAndCheckPropertyWithLock(patchInfoFile, patchInfoLockFile);
//it is a new patch, so we should not find a exist
SharePatchInfo newInfo;
//already have patch
// 构建newInfo
if (oldInfo != null) {
// 如果有就检查信息全不全
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;
}
// 检查md5不空且长度正确
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);
}
// ......
//copy file
File destPatchFile = new File(patchVersionDirectory + "/" + SharePatchFileUtil.getPatchVersionFile(patchMd5));
try {
// check md5 first
if (!patchMd5.equals(SharePatchFileUtil.getMD5(destPatchFile))) {
// 检查md5正确后拷贝文件,因为后面操作可能会发生以外而删除patch文件。
// 所以在这里拷贝一份,后面的操作对拷贝的patch来操作。
SharePatchFileUtil.copyFileUsingStream(patchFile, destPatchFile);
TinkerLog.w(TAG, "UpgradePatch copy patch file, src file: %s size: %d, dest file: %s size:%d", patchFile.getAbsolutePath(), patchFile.lengt
destPatchFile.getAbsolutePath(), destPatchFile.length());
}
} catch (IOException e) {
e.printStackTrace();
TinkerLog.e(TAG, "UpgradePatch tryPatch:copy patch file fail from %s to %s", patchFile.getPath(), destPatchFile.getPath());
manager.getPatchReporter().onPatchTypeExtractFail(patchFile, destPatchFile, patchFile.getName(), ShareConstants.TYPE_PATCH_FILE);
return false;
}
// ......检查成功的后序合并算法调用
}
4-3 UpgradePatch # tryPatch()中合并算法的调用
在通过了这一系列检查之后就到了真正合并文件算法的时候了,合并的文件分为三种:dex文件、.so文件和资源文件分别对应下面三个调用,只要一个修复工作失败了,就返回false,修复算法我们在下一篇分析。
@Override
public boolean tryPatch(Context context, String tempPatchPath, PatchResult patchResult) {
// ......一系列检查工作
//we use destPatchFile instead of patchFile, because patchFile may be deleted during the patch process
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;
}
// check dex opt file at last, some phone such as VIVO/OPPO like to change dex2oat to interpreted
if (!DexDiffPatchInternal.waitAndCheckDexOptFile(patchFile, manager)) {
TinkerLog.e(TAG, "UpgradePatch tryPatch:new patch recover, check dex opt file failed");
return false;
}
// ......写新的合并Patch信息
}
5. AbstractResultService
回顾3-3,在tryPatch()调用完成后,最后一句:
AbstractResultService.runResultService(context, patchResult, getPatchResultExtra(intent));
开启了修复完成后的工作Service,DefaultTinkerResultService是默认实现,或者也可以自定义,在TinkerInstaller#install()传入。
5-1 AbstractResultService # runResultService()
resultServiceClass是一路传递过来的类名,到这里就是启动了,默认给的是DefaultTinkerResultService
public static void runResultService(Context context, PatchResult result, String resultServiceClass) {
if (resultServiceClass == null) {
throw new TinkerRuntimeException("resultServiceClass is null.");
}
try {
Intent intent = new Intent();
intent.setClassName(context, resultServiceClass);
intent.putExtra(RESULT_EXTRA, result);
context.startService(intent);
} catch (Throwable throwable) {
TinkerLog.e(TAG, "run result service fail, exception:" + throwable);
}
}
5-2 DefaultTinkerResultService # onHandleIntent()
DefaultTinkerResultService没有重写该方法,父类实现直接调用的onPatchResult()
@Override
protected void onHandleIntent(Intent intent) {
if (intent == null) {
TinkerLog.e(TAG, "AbstractResultService received a null intent, ignoring.");
return;
}
PatchResult result = (PatchResult) ShareIntentUtil.getSerializableExtra(intent, RESULT_EXTRA);
onPatchResult(result);
}
5-3 DefaultTinkerResultService # onPatchResult()
首先会关闭PatchService,然后删除patch文件,最后将应用进程杀死,再开就生效了。但是这样的体验不好,所以如果想要自己的逻辑,就可以自定义DefaultTinkerResultService,重写onPatchService()。
@Override
public void onPatchResult(PatchResult result) {
// ......一些判断和日志打印
//first, we want to kill the recover process
// 关闭TinkerPatchService
TinkerServiceInternals.killTinkerPatchServiceProcess(getApplicationContext());
// if success and newPatch, it is nice to delete the raw file, and restart at once
// only main process can load an upgrade patch!
if (result.isSuccess) {
// 如果修复成功了,就把patch删掉
deleteRawPatchFile(new File(result.rawPatchFilePath));
if (checkIfNeedKill(result)) {
// 这就是为什么不自定义ResultService时,修复完成应用会闪退
android.os.Process.killProcess(android.os.Process.myPid());
} else {
TinkerLog.i(TAG, "I have already install the newly patch version!");
}
}
}
到这里整个流程就结束了,默认的话此时进程已被杀死,再次启动才能够生效。就再分析分析启动过程中发生的事情。