Most developers will not implement this class directly, instead using the * aidl tool to describe the desired * interface, having it generate the appropriate Binder subclass. You can, * however, derive directly from Binder to implement your own custom RPC * protocol or simply instantiate a raw Binder object directly to use as a * token that can be shared across processes. * *
This class is just a basic IPC primitive; it has no impact on an application's * lifecycle, and is valid only as long as the process that created it continues to run. * To use this correctly, you must be doing so within the context of a top-level * application component (a {@link android.app.Service}, {@link android.app.Activity}, * or {@link android.content.ContentProvider}) that lets the system know your process * should remain running.
* *You must keep in mind the situations in which your process * could go away, and thus require that you later re-create a new Binder and re-attach * it when the process starts again. For example, if you are using this within an * {@link android.app.Activity}, your activity's process may be killed any time the * activity is not started; if the activity is later re-created you will need to * create a new Binder and hand it back to the correct place again; you need to be * aware that your process may be started for another reason (for example to receive * a broadcast) that will not involve re-creating the activity and thus run its code * to create a new Binder.
* * @see IBinder */ public class Binder implements IBinder { /* * Set this flag to true to detect anonymous, local or member classes * that extend this Binder class and that are not static. These kind * of classes can potentially create leaks. */ private static final boolean FIND_POTENTIAL_LEAKS = false; private static final boolean CHECK_PARCEL_SIZE = false; static final String TAG = "Binder"; /** * Control whether dump() calls are allowed. */ private static String sDumpDisabled = null; /* mObject is used by native code, do not remove or rename */ private long mObject; private IInterface mOwner; private String mDescriptor; /** * Return the ID of the process that sent you the current transaction * that is being processed. This pid can be used with higher-level * system services to determine its identity and check permissions. * If the current thread is not currently executing an incoming transaction, * then its own pid is returned. */ public static final native int getCallingPid(); /** * Return the Linux uid assigned to the process that sent you the * current transaction that is being processed. This uid can be used with * higher-level system services to determine its identity and check * permissions. If the current thread is not currently executing an * incoming transaction, then its own uid is returned. */ public static final native int getCallingUid(); /** * Return the UserHandle assigned to the process that sent you the * current transaction that is being processed. This is the user * of the caller. It is distinct from {@link #getCallingUid()} in that a * particular user will have multiple distinct apps running under it each * with their own uid. If the current thread is not currently executing an * incoming transaction, then its own UserHandle is returned. */ public static final UserHandle getCallingUserHandle() { return new UserHandle(UserHandle.getUserId(getCallingUid())); } /** * Reset the identity of the incoming IPC on the current thread. This can * be useful if, while handling an incoming call, you will be calling * on interfaces of other objects that may be local to your process and * need to do permission checks on the calls coming into them (so they * will check the permission of your own local process, and not whatever * process originally called you). * * @return Returns an opaque token that can be used to restore the * original calling identity by passing it to * {@link #restoreCallingIdentity(long)}. * * @see #getCallingPid() * @see #getCallingUid() * @see #restoreCallingIdentity(long) */ public static final native long clearCallingIdentity(); /** * Restore the identity of the incoming IPC on the current thread * back to a previously identity that was returned by {@link * #clearCallingIdentity}. * * @param token The opaque token that was previously returned by * {@link #clearCallingIdentity}. * * @see #clearCallingIdentity */ public static final native void restoreCallingIdentity(long token); /** * Sets the native thread-local StrictMode policy mask. * *The StrictMode settings are kept in two places: a Java-level * threadlocal for libcore/Dalvik, and a native threadlocal (set * here) for propagation via Binder calls. This is a little * unfortunate, but necessary to break otherwise more unfortunate * dependencies either of Dalvik on Android, or Android * native-only code on Dalvik. * * @see StrictMode * @hide */ public static final native void setThreadStrictModePolicy(int policyMask); /** * Gets the current native thread-local StrictMode policy mask. * * @see #setThreadStrictModePolicy * @hide */ public static final native int getThreadStrictModePolicy(); /** * Flush any Binder commands pending in the current thread to the kernel * driver. This can be * useful to call before performing an operation that may block for a long * time, to ensure that any pending object references have been released * in order to prevent the process from holding on to objects longer than * it needs to. */ public static final native void flushPendingCommands(); /** * Add the calling thread to the IPC thread pool. This function does * not return until the current process is exiting. */ public static final native void joinThreadPool(); /** * Returns true if the specified interface is a proxy. * @hide */ public static final boolean isProxy(IInterface iface) { return iface.asBinder() != iface; } /** * Default constructor initializes the object. */ public Binder() { init(); if (FIND_POTENTIAL_LEAKS) { final Class klass = getClass(); if ((klass.isAnonymousClass() || klass.isMemberClass() || klass.isLocalClass()) && (klass.getModifiers() & Modifier.STATIC) == 0) { Log.w(TAG, "The following Binder class should be static or leaks might occur: " + klass.getCanonicalName()); } } } /** * Convenience method for associating a specific interface with the Binder. * After calling, queryLocalInterface() will be implemented for you * to return the given owner IInterface when the corresponding * descriptor is requested. */ public void attachInterface(IInterface owner, String descriptor) { mOwner = owner; mDescriptor = descriptor; } /** * Default implementation returns an empty interface name. */ public String getInterfaceDescriptor() { return mDescriptor; } /** * Default implementation always returns true -- if you got here, * the object is alive. */ public boolean pingBinder() { return true; } /** * {@inheritDoc} * * Note that if you're calling on a local binder, this always returns true * because your process is alive if you're calling it. */ public boolean isBinderAlive() { return true; } /** * Use information supplied to attachInterface() to return the * associated IInterface if it matches the requested * descriptor. */ public IInterface queryLocalInterface(String descriptor) { if (mDescriptor.equals(descriptor)) { return mOwner; } return null; } /** * Control disabling of dump calls in this process. This is used by the system * process watchdog to disable incoming dump calls while it has detecting the system * is hung and is reporting that back to the activity controller. This is to * prevent the controller from getting hung up on bug reports at this point. * @hide * * @param msg The message to show instead of the dump; if null, dumps are * re-enabled. */ public static void setDumpDisabled(String msg) { synchronized (Binder.class) { sDumpDisabled = msg; } } /** * Default implementation is a stub that returns false. You will want * to override this to do the appropriate unmarshalling of transactions. * *
If you want to call this, call transact(). */ protected boolean onTransact(int code, Parcel data, Parcel reply, int flags) throws RemoteException { if (code == INTERFACE_TRANSACTION) { reply.writeString(getInterfaceDescriptor()); return true; } else if (code == DUMP_TRANSACTION) { ParcelFileDescriptor fd = data.readFileDescriptor(); String[] args = data.readStringArray(); if (fd != null) { try { dump(fd.getFileDescriptor(), args); } finally { try { fd.close(); } catch (IOException e) { // swallowed, not propagated back to the caller } } } // Write the StrictMode header. if (reply != null) { reply.writeNoException(); } else { StrictMode.clearGatheredViolations(); } return true; } return false; } /** * Implemented to call the more convenient version * {@link #dump(FileDescriptor, PrintWriter, String[])}. */ public void dump(FileDescriptor fd, String[] args) { FileOutputStream fout = new FileOutputStream(fd); PrintWriter pw = new FastPrintWriter(fout); try { final String disabled; synchronized (Binder.class) { disabled = sDumpDisabled; } if (disabled == null) { try { dump(fd, pw, args); } catch (SecurityException e) { pw.println("Security exception: " + e.getMessage()); throw e; } catch (Throwable e) { // Unlike usual calls, in this case if an exception gets thrown // back to us we want to print it back in to the dump data, since // that is where the caller expects all interesting information to // go. pw.println(); pw.println("Exception occurred while dumping:"); e.printStackTrace(pw); } } else { pw.println(sDumpDisabled); } } finally { pw.flush(); } } /** * Like {@link #dump(FileDescriptor, String[])}, but ensures the target * executes asynchronously. */ public void dumpAsync(final FileDescriptor fd, final String[] args) { final FileOutputStream fout = new FileOutputStream(fd); final PrintWriter pw = new FastPrintWriter(fout); Thread thr = new Thread("Binder.dumpAsync") { public void run() { try { dump(fd, pw, args); } finally { pw.flush(); } } }; thr.start(); } /** * Print the object's state into the given stream. * * @param fd The raw file descriptor that the dump is being sent to. * @param fout The file to which you should dump your state. This will be * closed for you after you return. * @param args additional arguments to the dump request. */ protected void dump(FileDescriptor fd, PrintWriter fout, String[] args) { } /** * Default implementation rewinds the parcels and calls onTransact. On * the remote side, transact calls into the binder to do the IPC. */ public final boolean transact(int code, Parcel data, Parcel reply, int flags) throws RemoteException { if (false) Log.v("Binder", "Transact: " + code + " to " + this); if (data != null) { data.setDataPosition(0); } boolean r = onTransact(code, data, reply, flags); if (reply != null) { reply.setDataPosition(0); } return r; } /** * Local implementation is a no-op. */ public void linkToDeath(DeathRecipient recipient, int flags) { } /** * Local implementation is a no-op. */ public boolean unlinkToDeath(DeathRecipient recipient, int flags) { return true; } protected void finalize() throws Throwable { try { destroy(); } finally { super.finalize(); } } static void checkParcel(IBinder obj, int code, Parcel parcel, String msg) { if (CHECK_PARCEL_SIZE && parcel.dataSize() >= 800*1024) { // Trying to send > 800k, this is way too much StringBuilder sb = new StringBuilder(); sb.append(msg); sb.append(": on "); sb.append(obj); sb.append(" calling "); sb.append(code); sb.append(" size "); sb.append(parcel.dataSize()); sb.append(" (data: "); parcel.setDataPosition(0); sb.append(parcel.readInt()); sb.append(", "); sb.append(parcel.readInt()); sb.append(", "); sb.append(parcel.readInt()); sb.append(")"); Slog.wtfStack(TAG, sb.toString()); } } private native final void init(); private native final void destroy(); // Entry point from android_util_Binder.cpp's onTransact private boolean execTransact(int code, long dataObj, long replyObj, int flags) { Parcel data = Parcel.obtain(dataObj); Parcel reply = Parcel.obtain(replyObj); // theoretically, we should call transact, which will call onTransact, // but all that does is rewind it, and we just got these from an IPC, // so we'll just call it directly. boolean res; // Log any exceptions as warnings, don't silently suppress them. // If the call was FLAG_ONEWAY then these exceptions disappear into the ether. try { res = onTransact(code, data, reply, flags); } catch (RemoteException e) { if ((flags & FLAG_ONEWAY) != 0) { Log.w(TAG, "Binder call failed.", e); } else { reply.setDataPosition(0); reply.writeException(e); } res = true; } catch (RuntimeException e) { if ((flags & FLAG_ONEWAY) != 0) { Log.w(TAG, "Caught a RuntimeException from the binder stub implementation.", e); } else { reply.setDataPosition(0); reply.writeException(e); } res = true; } catch (OutOfMemoryError e) { // Unconditionally log this, since this is generally unrecoverable. Log.e(TAG, "Caught an OutOfMemoryError from the binder stub implementation.", e); RuntimeException re = new RuntimeException("Out of memory", e); reply.setDataPosition(0); reply.writeException(re); res = true; } checkParcel(this, code, reply, "Unreasonably large binder reply buffer"); reply.recycle(); data.recycle(); // Just in case -- we are done with the IPC, so there should be no more strict // mode violations that have gathered for this thread. Either they have been // parceled and are now in transport off to the caller, or we are returning back // to the main transaction loop to wait for another incoming transaction. Either // way, strict mode begone! StrictMode.clearGatheredViolations(); return res; } } final class BinderProxy implements IBinder { public native boolean pingBinder(); public native boolean isBinderAlive(); public IInterface queryLocalInterface(String descriptor) { return null; } public boolean transact(int code, Parcel data, Parcel reply, int flags) throws RemoteException { Binder.checkParcel(this, code, data, "Unreasonably large binder buffer"); return transactNative(code, data, reply, flags); } public native String getInterfaceDescriptor() throws RemoteException; public native boolean transactNative(int code, Parcel data, Parcel reply, int flags) throws RemoteException; public native void linkToDeath(DeathRecipient recipient, int flags) throws RemoteException; public native boolean unlinkToDeath(DeathRecipient recipient, int flags); public void dump(FileDescriptor fd, String[] args) throws RemoteException { Parcel data = Parcel.obtain(); Parcel reply = Parcel.obtain(); data.writeFileDescriptor(fd); data.writeStringArray(args); try { transact(DUMP_TRANSACTION, data, reply, 0); reply.readException(); } finally { data.recycle(); reply.recycle(); } } public void dumpAsync(FileDescriptor fd, String[] args) throws RemoteException { Parcel data = Parcel.obtain(); Parcel reply = Parcel.obtain(); data.writeFileDescriptor(fd); data.writeStringArray(args); try { transact(DUMP_TRANSACTION, data, reply, FLAG_ONEWAY); } finally { data.recycle(); reply.recycle(); } } BinderProxy() { mSelf = new WeakReference(this); } @Override protected void finalize() throws Throwable { try { destroy(); } finally { super.finalize(); } } private native final void destroy(); private static final void sendDeathNotice(DeathRecipient recipient) { if (false) Log.v("JavaBinder", "sendDeathNotice to " + recipient); try { recipient.binderDied(); } catch (RuntimeException exc) { Log.w("BinderNative", "Uncaught exception from death notification", exc); } } final private WeakReference mSelf; private long mObject; private long mOrgue; }