Java tutorial
/* * Copyright (C) 2006 The Android Open Source Project * * Licensed under the Apache License, Version 2.0 (the "License"); * you may not use this file except in compliance with the License. * You may obtain a copy of the License at * * http://www.apache.org/licenses/LICENSE-2.0 * * Unless required by applicable law or agreed to in writing, software * distributed under the License is distributed on an "AS IS" BASIS, * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. * See the License for the specific language governing permissions and * limitations under the License. */ package android.os; import android.annotation.Nullable; import android.annotation.UnsupportedAppUsage; import android.text.TextUtils; import android.util.ArrayMap; import android.util.ArraySet; import android.util.ExceptionUtils; import android.util.Log; import android.util.Size; import android.util.SizeF; import android.util.SparseArray; import android.util.SparseBooleanArray; import android.util.SparseIntArray; import dalvik.annotation.optimization.CriticalNative; import dalvik.annotation.optimization.FastNative; import dalvik.system.VMRuntime; import libcore.util.ArrayUtils; import libcore.util.SneakyThrow; import java.io.ByteArrayInputStream; import java.io.ByteArrayOutputStream; import java.io.FileDescriptor; import java.io.IOException; import java.io.ObjectInputStream; import java.io.ObjectOutputStream; import java.io.ObjectStreamClass; import java.io.Serializable; import java.lang.reflect.Array; import java.lang.reflect.Field; import java.lang.reflect.Modifier; import java.util.ArrayList; import java.util.HashMap; import java.util.List; import java.util.Map; import java.util.Set; /** * Container for a message (data and object references) that can * be sent through an IBinder. A Parcel can contain both flattened data * that will be unflattened on the other side of the IPC (using the various * methods here for writing specific types, or the general * {@link Parcelable} interface), and references to live {@link IBinder} * objects that will result in the other side receiving a proxy IBinder * connected with the original IBinder in the Parcel. * * <p class="note">Parcel is <strong>not</strong> a general-purpose * serialization mechanism. This class (and the corresponding * {@link Parcelable} API for placing arbitrary objects into a Parcel) is * designed as a high-performance IPC transport. As such, it is not * appropriate to place any Parcel data in to persistent storage: changes * in the underlying implementation of any of the data in the Parcel can * render older data unreadable.</p> * * <p>The bulk of the Parcel API revolves around reading and writing data * of various types. There are six major classes of such functions available.</p> * * <h3>Primitives</h3> * * <p>The most basic data functions are for writing and reading primitive * data types: {@link #writeByte}, {@link #readByte}, {@link #writeDouble}, * {@link #readDouble}, {@link #writeFloat}, {@link #readFloat}, {@link #writeInt}, * {@link #readInt}, {@link #writeLong}, {@link #readLong}, * {@link #writeString}, {@link #readString}. Most other * data operations are built on top of these. The given data is written and * read using the endianess of the host CPU.</p> * * <h3>Primitive Arrays</h3> * * <p>There are a variety of methods for reading and writing raw arrays * of primitive objects, which generally result in writing a 4-byte length * followed by the primitive data items. The methods for reading can either * read the data into an existing array, or create and return a new array. * These available types are:</p> * * <ul> * <li> {@link #writeBooleanArray(boolean[])}, * {@link #readBooleanArray(boolean[])}, {@link #createBooleanArray()} * <li> {@link #writeByteArray(byte[])}, * {@link #writeByteArray(byte[], int, int)}, {@link #readByteArray(byte[])}, * {@link #createByteArray()} * <li> {@link #writeCharArray(char[])}, {@link #readCharArray(char[])}, * {@link #createCharArray()} * <li> {@link #writeDoubleArray(double[])}, {@link #readDoubleArray(double[])}, * {@link #createDoubleArray()} * <li> {@link #writeFloatArray(float[])}, {@link #readFloatArray(float[])}, * {@link #createFloatArray()} * <li> {@link #writeIntArray(int[])}, {@link #readIntArray(int[])}, * {@link #createIntArray()} * <li> {@link #writeLongArray(long[])}, {@link #readLongArray(long[])}, * {@link #createLongArray()} * <li> {@link #writeStringArray(String[])}, {@link #readStringArray(String[])}, * {@link #createStringArray()}. * <li> {@link #writeSparseBooleanArray(SparseBooleanArray)}, * {@link #readSparseBooleanArray()}. * </ul> * * <h3>Parcelables</h3> * * <p>The {@link Parcelable} protocol provides an extremely efficient (but * low-level) protocol for objects to write and read themselves from Parcels. * You can use the direct methods {@link #writeParcelable(Parcelable, int)} * and {@link #readParcelable(ClassLoader)} or * {@link #writeParcelableArray} and * {@link #readParcelableArray(ClassLoader)} to write or read. These * methods write both the class type and its data to the Parcel, allowing * that class to be reconstructed from the appropriate class loader when * later reading.</p> * * <p>There are also some methods that provide a more efficient way to work * with Parcelables: {@link #writeTypedObject}, {@link #writeTypedArray}, * {@link #writeTypedList}, {@link #readTypedObject}, * {@link #createTypedArray} and {@link #createTypedArrayList}. These methods * do not write the class information of the original object: instead, the * caller of the read function must know what type to expect and pass in the * appropriate {@link Parcelable.Creator Parcelable.Creator} instead to * properly construct the new object and read its data. (To more efficient * write and read a single Parcelable object that is not null, you can directly * call {@link Parcelable#writeToParcel Parcelable.writeToParcel} and * {@link Parcelable.Creator#createFromParcel Parcelable.Creator.createFromParcel} * yourself.)</p> * * <h3>Bundles</h3> * * <p>A special type-safe container, called {@link Bundle}, is available * for key/value maps of heterogeneous values. This has many optimizations * for improved performance when reading and writing data, and its type-safe * API avoids difficult to debug type errors when finally marshalling the * data contents into a Parcel. The methods to use are * {@link #writeBundle(Bundle)}, {@link #readBundle()}, and * {@link #readBundle(ClassLoader)}. * * <h3>Active Objects</h3> * * <p>An unusual feature of Parcel is the ability to read and write active * objects. For these objects the actual contents of the object is not * written, rather a special token referencing the object is written. When * reading the object back from the Parcel, you do not get a new instance of * the object, but rather a handle that operates on the exact same object that * was originally written. There are two forms of active objects available.</p> * * <p>{@link Binder} objects are a core facility of Android's general cross-process * communication system. The {@link IBinder} interface describes an abstract * protocol with a Binder object. Any such interface can be written in to * a Parcel, and upon reading you will receive either the original object * implementing that interface or a special proxy implementation * that communicates calls back to the original object. The methods to use are * {@link #writeStrongBinder(IBinder)}, * {@link #writeStrongInterface(IInterface)}, {@link #readStrongBinder()}, * {@link #writeBinderArray(IBinder[])}, {@link #readBinderArray(IBinder[])}, * {@link #createBinderArray()}, * {@link #writeBinderList(List)}, {@link #readBinderList(List)}, * {@link #createBinderArrayList()}.</p> * * <p>FileDescriptor objects, representing raw Linux file descriptor identifiers, * can be written and {@link ParcelFileDescriptor} objects returned to operate * on the original file descriptor. The returned file descriptor is a dup * of the original file descriptor: the object and fd is different, but * operating on the same underlying file stream, with the same position, etc. * The methods to use are {@link #writeFileDescriptor(FileDescriptor)}, * {@link #readFileDescriptor()}. * * <h3>Untyped Containers</h3> * * <p>A final class of methods are for writing and reading standard Java * containers of arbitrary types. These all revolve around the * {@link #writeValue(Object)} and {@link #readValue(ClassLoader)} methods * which define the types of objects allowed. The container methods are * {@link #writeArray(Object[])}, {@link #readArray(ClassLoader)}, * {@link #writeList(List)}, {@link #readList(List, ClassLoader)}, * {@link #readArrayList(ClassLoader)}, * {@link #writeMap(Map)}, {@link #readMap(Map, ClassLoader)}, * {@link #writeSparseArray(SparseArray)}, * {@link #readSparseArray(ClassLoader)}. */ public final class Parcel { private static final boolean DEBUG_RECYCLE = false; private static final boolean DEBUG_ARRAY_MAP = false; private static final String TAG = "Parcel"; @UnsupportedAppUsage @SuppressWarnings({ "UnusedDeclaration" }) private long mNativePtr; // used by native code /** * Flag indicating if {@link #mNativePtr} was allocated by this object, * indicating that we're responsible for its lifecycle. */ private boolean mOwnsNativeParcelObject; private long mNativeSize; private ArrayMap<Class, Object> mClassCookies; private RuntimeException mStack; /** * Whether or not to parcel the stack trace of an exception. This has a performance * impact, so should only be included in specific processes and only on debug builds. */ private static boolean sParcelExceptionStackTrace; private static final int POOL_SIZE = 6; private static final Parcel[] sOwnedPool = new Parcel[POOL_SIZE]; private static final Parcel[] sHolderPool = new Parcel[POOL_SIZE]; // Keep in sync with frameworks/native/include/private/binder/ParcelValTypes.h. private static final int VAL_NULL = -1; private static final int VAL_STRING = 0; private static final int VAL_INTEGER = 1; private static final int VAL_MAP = 2; private static final int VAL_BUNDLE = 3; private static final int VAL_PARCELABLE = 4; private static final int VAL_SHORT = 5; private static final int VAL_LONG = 6; private static final int VAL_FLOAT = 7; private static final int VAL_DOUBLE = 8; private static final int VAL_BOOLEAN = 9; private static final int VAL_CHARSEQUENCE = 10; private static final int VAL_LIST = 11; private static final int VAL_SPARSEARRAY = 12; private static final int VAL_BYTEARRAY = 13; private static final int VAL_STRINGARRAY = 14; private static final int VAL_IBINDER = 15; private static final int VAL_PARCELABLEARRAY = 16; private static final int VAL_OBJECTARRAY = 17; private static final int VAL_INTARRAY = 18; private static final int VAL_LONGARRAY = 19; private static final int VAL_BYTE = 20; private static final int VAL_SERIALIZABLE = 21; private static final int VAL_SPARSEBOOLEANARRAY = 22; private static final int VAL_BOOLEANARRAY = 23; private static final int VAL_CHARSEQUENCEARRAY = 24; private static final int VAL_PERSISTABLEBUNDLE = 25; private static final int VAL_SIZE = 26; private static final int VAL_SIZEF = 27; private static final int VAL_DOUBLEARRAY = 28; // The initial int32 in a Binder call's reply Parcel header: // Keep these in sync with libbinder's binder/Status.h. private static final int EX_SECURITY = -1; private static final int EX_BAD_PARCELABLE = -2; private static final int EX_ILLEGAL_ARGUMENT = -3; private static final int EX_NULL_POINTER = -4; private static final int EX_ILLEGAL_STATE = -5; private static final int EX_NETWORK_MAIN_THREAD = -6; private static final int EX_UNSUPPORTED_OPERATION = -7; private static final int EX_SERVICE_SPECIFIC = -8; private static final int EX_PARCELABLE = -9; private static final int EX_HAS_REPLY_HEADER = -128; // special; see below // EX_TRANSACTION_FAILED is used exclusively in native code. // see libbinder's binder/Status.h private static final int EX_TRANSACTION_FAILED = -129; @CriticalNative private static native int nativeDataSize(long nativePtr); @CriticalNative private static native int nativeDataAvail(long nativePtr); @CriticalNative private static native int nativeDataPosition(long nativePtr); @CriticalNative private static native int nativeDataCapacity(long nativePtr); @FastNative private static native long nativeSetDataSize(long nativePtr, int size); @CriticalNative private static native void nativeSetDataPosition(long nativePtr, int pos); @FastNative private static native void nativeSetDataCapacity(long nativePtr, int size); @CriticalNative private static native boolean nativePushAllowFds(long nativePtr, boolean allowFds); @CriticalNative private static native void nativeRestoreAllowFds(long nativePtr, boolean lastValue); private static native void nativeWriteByteArray(long nativePtr, byte[] b, int offset, int len); private static native void nativeWriteBlob(long nativePtr, byte[] b, int offset, int len); @FastNative private static native void nativeWriteInt(long nativePtr, int val); @FastNative private static native void nativeWriteLong(long nativePtr, long val); @FastNative private static native void nativeWriteFloat(long nativePtr, float val); @FastNative private static native void nativeWriteDouble(long nativePtr, double val); static native void nativeWriteString(long nativePtr, String val); private static native void nativeWriteStrongBinder(long nativePtr, IBinder val); private static native long nativeWriteFileDescriptor(long nativePtr, FileDescriptor val); private static native byte[] nativeCreateByteArray(long nativePtr); private static native boolean nativeReadByteArray(long nativePtr, byte[] dest, int destLen); private static native byte[] nativeReadBlob(long nativePtr); @CriticalNative private static native int nativeReadInt(long nativePtr); @CriticalNative private static native long nativeReadLong(long nativePtr); @CriticalNative private static native float nativeReadFloat(long nativePtr); @CriticalNative private static native double nativeReadDouble(long nativePtr); static native String nativeReadString(long nativePtr); private static native IBinder nativeReadStrongBinder(long nativePtr); private static native FileDescriptor nativeReadFileDescriptor(long nativePtr); private static native long nativeCreate(); private static native long nativeFreeBuffer(long nativePtr); private static native void nativeDestroy(long nativePtr); private static native byte[] nativeMarshall(long nativePtr); private static native long nativeUnmarshall(long nativePtr, byte[] data, int offset, int length); private static native int nativeCompareData(long thisNativePtr, long otherNativePtr); private static native long nativeAppendFrom(long thisNativePtr, long otherNativePtr, int offset, int length); @CriticalNative private static native boolean nativeHasFileDescriptors(long nativePtr); private static native void nativeWriteInterfaceToken(long nativePtr, String interfaceName); private static native void nativeEnforceInterface(long nativePtr, String interfaceName); /** Last time exception with a stack trace was written */ private static volatile long sLastWriteExceptionStackTrace; /** Used for throttling of writing stack trace, which is costly */ private static final int WRITE_EXCEPTION_STACK_TRACE_THRESHOLD_MS = 1000; @CriticalNative private static native long nativeGetBlobAshmemSize(long nativePtr); public final static Parcelable.Creator<String> STRING_CREATOR = new Parcelable.Creator<String>() { public String createFromParcel(Parcel source) { return source.readString(); } public String[] newArray(int size) { return new String[size]; } }; /** * @hide */ public static class ReadWriteHelper { public static final ReadWriteHelper DEFAULT = new ReadWriteHelper(); /** * Called when writing a string to a parcel. Subclasses wanting to write a string * must use {@link #writeStringNoHelper(String)} to avoid * infinity recursive calls. */ public void writeString(Parcel p, String s) { nativeWriteString(p.mNativePtr, s); } /** * Called when reading a string to a parcel. Subclasses wanting to read a string * must use {@link #readStringNoHelper()} to avoid * infinity recursive calls. */ public String readString(Parcel p) { return nativeReadString(p.mNativePtr); } } private ReadWriteHelper mReadWriteHelper = ReadWriteHelper.DEFAULT; /** * Retrieve a new Parcel object from the pool. */ public static Parcel obtain() { final Parcel[] pool = sOwnedPool; synchronized (pool) { Parcel p; for (int i = 0; i < POOL_SIZE; i++) { p = pool[i]; if (p != null) { pool[i] = null; if (DEBUG_RECYCLE) { p.mStack = new RuntimeException(); } p.mReadWriteHelper = ReadWriteHelper.DEFAULT; return p; } } } return new Parcel(0); } /** * Put a Parcel object back into the pool. You must not touch * the object after this call. */ public final void recycle() { if (DEBUG_RECYCLE) mStack = null; freeBuffer(); final Parcel[] pool; if (mOwnsNativeParcelObject) { pool = sOwnedPool; } else { mNativePtr = 0; pool = sHolderPool; } synchronized (pool) { for (int i = 0; i < POOL_SIZE; i++) { if (pool[i] == null) { pool[i] = this; return; } } } } /** * Set a {@link ReadWriteHelper}, which can be used to avoid having duplicate strings, for * example. * * @hide */ public void setReadWriteHelper(ReadWriteHelper helper) { mReadWriteHelper = helper != null ? helper : ReadWriteHelper.DEFAULT; } /** * @return whether this parcel has a {@link ReadWriteHelper}. * * @hide */ public boolean hasReadWriteHelper() { return (mReadWriteHelper != null) && (mReadWriteHelper != ReadWriteHelper.DEFAULT); } /** @hide */ @UnsupportedAppUsage public static native long getGlobalAllocSize(); /** @hide */ @UnsupportedAppUsage public static native long getGlobalAllocCount(); /** * Returns the total amount of data contained in the parcel. */ public final int dataSize() { return nativeDataSize(mNativePtr); } /** * Returns the amount of data remaining to be read from the * parcel. That is, {@link #dataSize}-{@link #dataPosition}. */ public final int dataAvail() { return nativeDataAvail(mNativePtr); } /** * Returns the current position in the parcel data. Never * more than {@link #dataSize}. */ public final int dataPosition() { return nativeDataPosition(mNativePtr); } /** * Returns the total amount of space in the parcel. This is always * >= {@link #dataSize}. The difference between it and dataSize() is the * amount of room left until the parcel needs to re-allocate its * data buffer. */ public final int dataCapacity() { return nativeDataCapacity(mNativePtr); } /** * Change the amount of data in the parcel. Can be either smaller or * larger than the current size. If larger than the current capacity, * more memory will be allocated. * * @param size The new number of bytes in the Parcel. */ public final void setDataSize(int size) { updateNativeSize(nativeSetDataSize(mNativePtr, size)); } /** * Move the current read/write position in the parcel. * @param pos New offset in the parcel; must be between 0 and * {@link #dataSize}. */ public final void setDataPosition(int pos) { nativeSetDataPosition(mNativePtr, pos); } /** * Change the capacity (current available space) of the parcel. * * @param size The new capacity of the parcel, in bytes. Can not be * less than {@link #dataSize} -- that is, you can not drop existing data * with this method. */ public final void setDataCapacity(int size) { nativeSetDataCapacity(mNativePtr, size); } /** @hide */ public final boolean pushAllowFds(boolean allowFds) { return nativePushAllowFds(mNativePtr, allowFds); } /** @hide */ public final void restoreAllowFds(boolean lastValue) { nativeRestoreAllowFds(mNativePtr, lastValue); } /** * Returns the raw bytes of the parcel. * * <p class="note">The data you retrieve here <strong>must not</strong> * be placed in any kind of persistent storage (on local disk, across * a network, etc). For that, you should use standard serialization * or another kind of general serialization mechanism. The Parcel * marshalled representation is highly optimized for local IPC, and as * such does not attempt to maintain compatibility with data created * in different versions of the platform. */ public final byte[] marshall() { return nativeMarshall(mNativePtr); } /** * Set the bytes in data to be the raw bytes of this Parcel. */ public final void unmarshall(byte[] data, int offset, int length) { updateNativeSize(nativeUnmarshall(mNativePtr, data, offset, length)); } public final void appendFrom(Parcel parcel, int offset, int length) { updateNativeSize(nativeAppendFrom(mNativePtr, parcel.mNativePtr, offset, length)); } /** @hide */ public final int compareData(Parcel other) { return nativeCompareData(mNativePtr, other.mNativePtr); } /** @hide */ public final void setClassCookie(Class clz, Object cookie) { if (mClassCookies == null) { mClassCookies = new ArrayMap<>(); } mClassCookies.put(clz, cookie); } /** @hide */ public final Object getClassCookie(Class clz) { return mClassCookies != null ? mClassCookies.get(clz) : null; } /** @hide */ public final void adoptClassCookies(Parcel from) { mClassCookies = from.mClassCookies; } /** @hide */ public Map<Class, Object> copyClassCookies() { return new ArrayMap<>(mClassCookies); } /** @hide */ public void putClassCookies(Map<Class, Object> cookies) { if (cookies == null) { return; } if (mClassCookies == null) { mClassCookies = new ArrayMap<>(); } mClassCookies.putAll(cookies); } /** * Report whether the parcel contains any marshalled file descriptors. */ public final boolean hasFileDescriptors() { return nativeHasFileDescriptors(mNativePtr); } /** * Store or read an IBinder interface token in the parcel at the current * {@link #dataPosition}. This is used to validate that the marshalled * transaction is intended for the target interface. */ public final void writeInterfaceToken(String interfaceName) { nativeWriteInterfaceToken(mNativePtr, interfaceName); } public final void enforceInterface(String interfaceName) { nativeEnforceInterface(mNativePtr, interfaceName); } /** * Write a byte array into the parcel at the current {@link #dataPosition}, * growing {@link #dataCapacity} if needed. * @param b Bytes to place into the parcel. */ public final void writeByteArray(byte[] b) { writeByteArray(b, 0, (b != null) ? b.length : 0); } /** * Write a byte array into the parcel at the current {@link #dataPosition}, * growing {@link #dataCapacity} if needed. * @param b Bytes to place into the parcel. * @param offset Index of first byte to be written. * @param len Number of bytes to write. */ public final void writeByteArray(byte[] b, int offset, int len) { if (b == null) { writeInt(-1); return; } ArrayUtils.throwsIfOutOfBounds(b.length, offset, len); nativeWriteByteArray(mNativePtr, b, offset, len); } /** * Write a blob of data into the parcel at the current {@link #dataPosition}, * growing {@link #dataCapacity} if needed. * @param b Bytes to place into the parcel. * {@hide} * {@SystemApi} */ @UnsupportedAppUsage public final void writeBlob(byte[] b) { writeBlob(b, 0, (b != null) ? b.length : 0); } /** * Write a blob of data into the parcel at the current {@link #dataPosition}, * growing {@link #dataCapacity} if needed. * @param b Bytes to place into the parcel. * @param offset Index of first byte to be written. * @param len Number of bytes to write. * {@hide} * {@SystemApi} */ public final void writeBlob(byte[] b, int offset, int len) { if (b == null) { writeInt(-1); return; } ArrayUtils.throwsIfOutOfBounds(b.length, offset, len); nativeWriteBlob(mNativePtr, b, offset, len); } /** * Write an integer value into the parcel at the current dataPosition(), * growing dataCapacity() if needed. */ public final void writeInt(int val) { nativeWriteInt(mNativePtr, val); } /** * Write a long integer value into the parcel at the current dataPosition(), * growing dataCapacity() if needed. */ public final void writeLong(long val) { nativeWriteLong(mNativePtr, val); } /** * Write a floating point value into the parcel at the current * dataPosition(), growing dataCapacity() if needed. */ public final void writeFloat(float val) { nativeWriteFloat(mNativePtr, val); } /** * Write a double precision floating point value into the parcel at the * current dataPosition(), growing dataCapacity() if needed. */ public final void writeDouble(double val) { nativeWriteDouble(mNativePtr, val); } /** * Write a string value into the parcel at the current dataPosition(), * growing dataCapacity() if needed. */ public final void writeString(String val) { mReadWriteHelper.writeString(this, val); } /** * Write a string without going though a {@link ReadWriteHelper}. Subclasses of * {@link ReadWriteHelper} must use this method instead of {@link #writeString} to avoid * infinity recursive calls. * * @hide */ public void writeStringNoHelper(String val) { nativeWriteString(mNativePtr, val); } /** @hide */ public final void writeBoolean(boolean val) { writeInt(val ? 1 : 0); } /** * Write a CharSequence value into the parcel at the current dataPosition(), * growing dataCapacity() if needed. * @hide */ @UnsupportedAppUsage public final void writeCharSequence(CharSequence val) { TextUtils.writeToParcel(val, this, 0); } /** * Write an object into the parcel at the current dataPosition(), * growing dataCapacity() if needed. */ public final void writeStrongBinder(IBinder val) { nativeWriteStrongBinder(mNativePtr, val); } /** * Write an object into the parcel at the current dataPosition(), * growing dataCapacity() if needed. */ public final void writeStrongInterface(IInterface val) { writeStrongBinder(val == null ? null : val.asBinder()); } /** * Write a FileDescriptor into the parcel at the current dataPosition(), * growing dataCapacity() if needed. * * <p class="caution">The file descriptor will not be closed, which may * result in file descriptor leaks when objects are returned from Binder * calls. Use {@link ParcelFileDescriptor#writeToParcel} instead, which * accepts contextual flags and will close the original file descriptor * if {@link Parcelable#PARCELABLE_WRITE_RETURN_VALUE} is set.</p> */ public final void writeFileDescriptor(FileDescriptor val) { updateNativeSize(nativeWriteFileDescriptor(mNativePtr, val)); } private void updateNativeSize(long newNativeSize) { if (mOwnsNativeParcelObject) { if (newNativeSize > Integer.MAX_VALUE) { newNativeSize = Integer.MAX_VALUE; } if (newNativeSize != mNativeSize) { int delta = (int) (newNativeSize - mNativeSize); if (delta > 0) { VMRuntime.getRuntime().registerNativeAllocation(delta); } else { VMRuntime.getRuntime().registerNativeFree(-delta); } mNativeSize = newNativeSize; } } } /** * {@hide} * This will be the new name for writeFileDescriptor, for consistency. **/ public final void writeRawFileDescriptor(FileDescriptor val) { nativeWriteFileDescriptor(mNativePtr, val); } /** * {@hide} * Write an array of FileDescriptor objects into the Parcel. * * @param value The array of objects to be written. */ public final void writeRawFileDescriptorArray(FileDescriptor[] value) { if (value != null) { int N = value.length; writeInt(N); for (int i = 0; i < N; i++) { writeRawFileDescriptor(value[i]); } } else { writeInt(-1); } } /** * Write a byte value into the parcel at the current dataPosition(), * growing dataCapacity() if needed. */ public final void writeByte(byte val) { writeInt(val); } /** * Please use {@link #writeBundle} instead. Flattens a Map into the parcel * at the current dataPosition(), * growing dataCapacity() if needed. The Map keys must be String objects. * The Map values are written using {@link #writeValue} and must follow * the specification there. * * <p>It is strongly recommended to use {@link #writeBundle} instead of * this method, since the Bundle class provides a type-safe API that * allows you to avoid mysterious type errors at the point of marshalling. */ public final void writeMap(Map val) { writeMapInternal((Map<String, Object>) val); } /** * Flatten a Map into the parcel at the current dataPosition(), * growing dataCapacity() if needed. The Map keys must be String objects. */ /* package */ void writeMapInternal(Map<String, Object> val) { if (val == null) { writeInt(-1); return; } Set<Map.Entry<String, Object>> entries = val.entrySet(); int size = entries.size(); writeInt(size); for (Map.Entry<String, Object> e : entries) { writeValue(e.getKey()); writeValue(e.getValue()); size--; } if (size != 0) { throw new BadParcelableException("Map size does not match number of entries!"); } } /** * Flatten an ArrayMap into the parcel at the current dataPosition(), * growing dataCapacity() if needed. The Map keys must be String objects. */ /* package */ void writeArrayMapInternal(ArrayMap<String, Object> val) { if (val == null) { writeInt(-1); return; } // Keep the format of this Parcel in sync with writeToParcelInner() in // frameworks/native/libs/binder/PersistableBundle.cpp. final int N = val.size(); writeInt(N); if (DEBUG_ARRAY_MAP) { RuntimeException here = new RuntimeException("here"); here.fillInStackTrace(); Log.d(TAG, "Writing " + N + " ArrayMap entries", here); } int startPos; for (int i = 0; i < N; i++) { if (DEBUG_ARRAY_MAP) startPos = dataPosition(); writeString(val.keyAt(i)); writeValue(val.valueAt(i)); if (DEBUG_ARRAY_MAP) Log.d(TAG, " Write #" + i + " " + (dataPosition() - startPos) + " bytes: key=0x" + Integer.toHexString(val.keyAt(i) != null ? val.keyAt(i).hashCode() : 0) + " " + val.keyAt(i)); } } /** * @hide For testing only. */ @UnsupportedAppUsage public void writeArrayMap(ArrayMap<String, Object> val) { writeArrayMapInternal(val); } /** * Write an array set to the parcel. * * @param val The array set to write. * * @hide */ @UnsupportedAppUsage public void writeArraySet(@Nullable ArraySet<? extends Object> val) { final int size = (val != null) ? val.size() : -1; writeInt(size); for (int i = 0; i < size; i++) { writeValue(val.valueAt(i)); } } /** * Flatten a Bundle into the parcel at the current dataPosition(), * growing dataCapacity() if needed. */ public final void writeBundle(Bundle val) { if (val == null) { writeInt(-1); return; } val.writeToParcel(this, 0); } /** * Flatten a PersistableBundle into the parcel at the current dataPosition(), * growing dataCapacity() if needed. */ public final void writePersistableBundle(PersistableBundle val) { if (val == null) { writeInt(-1); return; } val.writeToParcel(this, 0); } /** * Flatten a Size into the parcel at the current dataPosition(), * growing dataCapacity() if needed. */ public final void writeSize(Size val) { writeInt(val.getWidth()); writeInt(val.getHeight()); } /** * Flatten a SizeF into the parcel at the current dataPosition(), * growing dataCapacity() if needed. */ public final void writeSizeF(SizeF val) { writeFloat(val.getWidth()); writeFloat(val.getHeight()); } /** * Flatten a List into the parcel at the current dataPosition(), growing * dataCapacity() if needed. The List values are written using * {@link #writeValue} and must follow the specification there. */ public final void writeList(List val) { if (val == null) { writeInt(-1); return; } int N = val.size(); int i = 0; writeInt(N); while (i < N) { writeValue(val.get(i)); i++; } } /** * Flatten an Object array into the parcel at the current dataPosition(), * growing dataCapacity() if needed. The array values are written using * {@link #writeValue} and must follow the specification there. */ public final void writeArray(Object[] val) { if (val == null) { writeInt(-1); return; } int N = val.length; int i = 0; writeInt(N); while (i < N) { writeValue(val[i]); i++; } } /** * Flatten a generic SparseArray into the parcel at the current * dataPosition(), growing dataCapacity() if needed. The SparseArray * values are written using {@link #writeValue} and must follow the * specification there. */ public final void writeSparseArray(SparseArray<Object> val) { if (val == null) { writeInt(-1); return; } int N = val.size(); writeInt(N); int i = 0; while (i < N) { writeInt(val.keyAt(i)); writeValue(val.valueAt(i)); i++; } } public final void writeSparseBooleanArray(SparseBooleanArray val) { if (val == null) { writeInt(-1); return; } int N = val.size(); writeInt(N); int i = 0; while (i < N) { writeInt(val.keyAt(i)); writeByte((byte) (val.valueAt(i) ? 1 : 0)); i++; } } /** * @hide */ public final void writeSparseIntArray(SparseIntArray val) { if (val == null) { writeInt(-1); return; } int N = val.size(); writeInt(N); int i = 0; while (i < N) { writeInt(val.keyAt(i)); writeInt(val.valueAt(i)); i++; } } public final void writeBooleanArray(boolean[] val) { if (val != null) { int N = val.length; writeInt(N); for (int i = 0; i < N; i++) { writeInt(val[i] ? 1 : 0); } } else { writeInt(-1); } } public final boolean[] createBooleanArray() { int N = readInt(); // >>2 as a fast divide-by-4 works in the create*Array() functions // because dataAvail() will never return a negative number. 4 is // the size of a stored boolean in the stream. if (N >= 0 && N <= (dataAvail() >> 2)) { boolean[] val = new boolean[N]; for (int i = 0; i < N; i++) { val[i] = readInt() != 0; } return val; } else { return null; } } public final void readBooleanArray(boolean[] val) { int N = readInt(); if (N == val.length) { for (int i = 0; i < N; i++) { val[i] = readInt() != 0; } } else { throw new RuntimeException("bad array lengths"); } } public final void writeCharArray(char[] val) { if (val != null) { int N = val.length; writeInt(N); for (int i = 0; i < N; i++) { writeInt((int) val[i]); } } else { writeInt(-1); } } public final char[] createCharArray() { int N = readInt(); if (N >= 0 && N <= (dataAvail() >> 2)) { char[] val = new char[N]; for (int i = 0; i < N; i++) { val[i] = (char) readInt(); } return val; } else { return null; } } public final void readCharArray(char[] val) { int N = readInt(); if (N == val.length) { for (int i = 0; i < N; i++) { val[i] = (char) readInt(); } } else { throw new RuntimeException("bad array lengths"); } } public final void writeIntArray(int[] val) { if (val != null) { int N = val.length; writeInt(N); for (int i = 0; i < N; i++) { writeInt(val[i]); } } else { writeInt(-1); } } public final int[] createIntArray() { int N = readInt(); if (N >= 0 && N <= (dataAvail() >> 2)) { int[] val = new int[N]; for (int i = 0; i < N; i++) { val[i] = readInt(); } return val; } else { return null; } } public final void readIntArray(int[] val) { int N = readInt(); if (N == val.length) { for (int i = 0; i < N; i++) { val[i] = readInt(); } } else { throw new RuntimeException("bad array lengths"); } } public final void writeLongArray(long[] val) { if (val != null) { int N = val.length; writeInt(N); for (int i = 0; i < N; i++) { writeLong(val[i]); } } else { writeInt(-1); } } public final long[] createLongArray() { int N = readInt(); // >>3 because stored longs are 64 bits if (N >= 0 && N <= (dataAvail() >> 3)) { long[] val = new long[N]; for (int i = 0; i < N; i++) { val[i] = readLong(); } return val; } else { return null; } } public final void readLongArray(long[] val) { int N = readInt(); if (N == val.length) { for (int i = 0; i < N; i++) { val[i] = readLong(); } } else { throw new RuntimeException("bad array lengths"); } } public final void writeFloatArray(float[] val) { if (val != null) { int N = val.length; writeInt(N); for (int i = 0; i < N; i++) { writeFloat(val[i]); } } else { writeInt(-1); } } public final float[] createFloatArray() { int N = readInt(); // >>2 because stored floats are 4 bytes if (N >= 0 && N <= (dataAvail() >> 2)) { float[] val = new float[N]; for (int i = 0; i < N; i++) { val[i] = readFloat(); } return val; } else { return null; } } public final void readFloatArray(float[] val) { int N = readInt(); if (N == val.length) { for (int i = 0; i < N; i++) { val[i] = readFloat(); } } else { throw new RuntimeException("bad array lengths"); } } public final void writeDoubleArray(double[] val) { if (val != null) { int N = val.length; writeInt(N); for (int i = 0; i < N; i++) { writeDouble(val[i]); } } else { writeInt(-1); } } public final double[] createDoubleArray() { int N = readInt(); // >>3 because stored doubles are 8 bytes if (N >= 0 && N <= (dataAvail() >> 3)) { double[] val = new double[N]; for (int i = 0; i < N; i++) { val[i] = readDouble(); } return val; } else { return null; } } public final void readDoubleArray(double[] val) { int N = readInt(); if (N == val.length) { for (int i = 0; i < N; i++) { val[i] = readDouble(); } } else { throw new RuntimeException("bad array lengths"); } } public final void writeStringArray(String[] val) { if (val != null) { int N = val.length; writeInt(N); for (int i = 0; i < N; i++) { writeString(val[i]); } } else { writeInt(-1); } } public final String[] createStringArray() { int N = readInt(); if (N >= 0) { String[] val = new String[N]; for (int i = 0; i < N; i++) { val[i] = readString(); } return val; } else { return null; } } public final void readStringArray(String[] val) { int N = readInt(); if (N == val.length) { for (int i = 0; i < N; i++) { val[i] = readString(); } } else { throw new RuntimeException("bad array lengths"); } } public final void writeBinderArray(IBinder[] val) { if (val != null) { int N = val.length; writeInt(N); for (int i = 0; i < N; i++) { writeStrongBinder(val[i]); } } else { writeInt(-1); } } /** * @hide */ public final void writeCharSequenceArray(CharSequence[] val) { if (val != null) { int N = val.length; writeInt(N); for (int i = 0; i < N; i++) { writeCharSequence(val[i]); } } else { writeInt(-1); } } /** * @hide */ public final void writeCharSequenceList(ArrayList<CharSequence> val) { if (val != null) { int N = val.size(); writeInt(N); for (int i = 0; i < N; i++) { writeCharSequence(val.get(i)); } } else { writeInt(-1); } } public final IBinder[] createBinderArray() { int N = readInt(); if (N >= 0) { IBinder[] val = new IBinder[N]; for (int i = 0; i < N; i++) { val[i] = readStrongBinder(); } return val; } else { return null; } } public final void readBinderArray(IBinder[] val) { int N = readInt(); if (N == val.length) { for (int i = 0; i < N; i++) { val[i] = readStrongBinder(); } } else { throw new RuntimeException("bad array lengths"); } } /** * Flatten a List containing a particular object type into the parcel, at * the current dataPosition() and growing dataCapacity() if needed. The * type of the objects in the list must be one that implements Parcelable. * Unlike the generic writeList() method, however, only the raw data of the * objects is written and not their type, so you must use the corresponding * readTypedList() to unmarshall them. * * @param val The list of objects to be written. * * @see #createTypedArrayList * @see #readTypedList * @see Parcelable */ public final <T extends Parcelable> void writeTypedList(List<T> val) { writeTypedList(val, 0); } /** * @hide */ public <T extends Parcelable> void writeTypedList(List<T> val, int parcelableFlags) { if (val == null) { writeInt(-1); return; } int N = val.size(); int i = 0; writeInt(N); while (i < N) { writeTypedObject(val.get(i), parcelableFlags); i++; } } /** * Flatten a List containing String objects into the parcel, at * the current dataPosition() and growing dataCapacity() if needed. They * can later be retrieved with {@link #createStringArrayList} or * {@link #readStringList}. * * @param val The list of strings to be written. * * @see #createStringArrayList * @see #readStringList */ public final void writeStringList(List<String> val) { if (val == null) { writeInt(-1); return; } int N = val.size(); int i = 0; writeInt(N); while (i < N) { writeString(val.get(i)); i++; } } /** * Flatten a List containing IBinder objects into the parcel, at * the current dataPosition() and growing dataCapacity() if needed. They * can later be retrieved with {@link #createBinderArrayList} or * {@link #readBinderList}. * * @param val The list of strings to be written. * * @see #createBinderArrayList * @see #readBinderList */ public final void writeBinderList(List<IBinder> val) { if (val == null) { writeInt(-1); return; } int N = val.size(); int i = 0; writeInt(N); while (i < N) { writeStrongBinder(val.get(i)); i++; } } /** * Flatten a {@code List} containing arbitrary {@code Parcelable} objects into this parcel * at the current position. They can later be retrieved using * {@link #readParcelableList(List, ClassLoader)} if required. * * @see #readParcelableList(List, ClassLoader) * @hide */ @UnsupportedAppUsage public final <T extends Parcelable> void writeParcelableList(List<T> val, int flags) { if (val == null) { writeInt(-1); return; } int N = val.size(); int i = 0; writeInt(N); while (i < N) { writeParcelable(val.get(i), flags); i++; } } /** * Flatten a homogeneous array containing a particular object type into * the parcel, at * the current dataPosition() and growing dataCapacity() if needed. The * type of the objects in the array must be one that implements Parcelable. * Unlike the {@link #writeParcelableArray} method, however, only the * raw data of the objects is written and not their type, so you must use * {@link #readTypedArray} with the correct corresponding * {@link Parcelable.Creator} implementation to unmarshall them. * * @param val The array of objects to be written. * @param parcelableFlags Contextual flags as per * {@link Parcelable#writeToParcel(Parcel, int) Parcelable.writeToParcel()}. * * @see #readTypedArray * @see #writeParcelableArray * @see Parcelable.Creator */ public final <T extends Parcelable> void writeTypedArray(T[] val, int parcelableFlags) { if (val != null) { int N = val.length; writeInt(N); for (int i = 0; i < N; i++) { writeTypedObject(val[i], parcelableFlags); } } else { writeInt(-1); } } /** * Flatten the Parcelable object into the parcel. * * @param val The Parcelable object to be written. * @param parcelableFlags Contextual flags as per * {@link Parcelable#writeToParcel(Parcel, int) Parcelable.writeToParcel()}. * * @see #readTypedObject */ public final <T extends Parcelable> void writeTypedObject(T val, int parcelableFlags) { if (val != null) { writeInt(1); val.writeToParcel(this, parcelableFlags); } else { writeInt(0); } } /** * Flatten a generic object in to a parcel. The given Object value may * currently be one of the following types: * * <ul> * <li> null * <li> String * <li> Byte * <li> Short * <li> Integer * <li> Long * <li> Float * <li> Double * <li> Boolean * <li> String[] * <li> boolean[] * <li> byte[] * <li> int[] * <li> long[] * <li> Object[] (supporting objects of the same type defined here). * <li> {@link Bundle} * <li> Map (as supported by {@link #writeMap}). * <li> Any object that implements the {@link Parcelable} protocol. * <li> Parcelable[] * <li> CharSequence (as supported by {@link TextUtils#writeToParcel}). * <li> List (as supported by {@link #writeList}). * <li> {@link SparseArray} (as supported by {@link #writeSparseArray(SparseArray)}). * <li> {@link IBinder} * <li> Any object that implements Serializable (but see * {@link #writeSerializable} for caveats). Note that all of the * previous types have relatively efficient implementations for * writing to a Parcel; having to rely on the generic serialization * approach is much less efficient and should be avoided whenever * possible. * </ul> * * <p class="caution">{@link Parcelable} objects are written with * {@link Parcelable#writeToParcel} using contextual flags of 0. When * serializing objects containing {@link ParcelFileDescriptor}s, * this may result in file descriptor leaks when they are returned from * Binder calls (where {@link Parcelable#PARCELABLE_WRITE_RETURN_VALUE} * should be used).</p> */ public final void writeValue(Object v) { if (v == null) { writeInt(VAL_NULL); } else if (v instanceof String) { writeInt(VAL_STRING); writeString((String) v); } else if (v instanceof Integer) { writeInt(VAL_INTEGER); writeInt((Integer) v); } else if (v instanceof Map) { writeInt(VAL_MAP); writeMap((Map) v); } else if (v instanceof Bundle) { // Must be before Parcelable writeInt(VAL_BUNDLE); writeBundle((Bundle) v); } else if (v instanceof PersistableBundle) { writeInt(VAL_PERSISTABLEBUNDLE); writePersistableBundle((PersistableBundle) v); } else if (v instanceof Parcelable) { // IMPOTANT: cases for classes that implement Parcelable must // come before the Parcelable case, so that their specific VAL_* // types will be written. writeInt(VAL_PARCELABLE); writeParcelable((Parcelable) v, 0); } else if (v instanceof Short) { writeInt(VAL_SHORT); writeInt(((Short) v).intValue()); } else if (v instanceof Long) { writeInt(VAL_LONG); writeLong((Long) v); } else if (v instanceof Float) { writeInt(VAL_FLOAT); writeFloat((Float) v); } else if (v instanceof Double) { writeInt(VAL_DOUBLE); writeDouble((Double) v); } else if (v instanceof Boolean) { writeInt(VAL_BOOLEAN); writeInt((Boolean) v ? 1 : 0); } else if (v instanceof CharSequence) { // Must be after String writeInt(VAL_CHARSEQUENCE); writeCharSequence((CharSequence) v); } else if (v instanceof List) { writeInt(VAL_LIST); writeList((List) v); } else if (v instanceof SparseArray) { writeInt(VAL_SPARSEARRAY); writeSparseArray((SparseArray) v); } else if (v instanceof boolean[]) { writeInt(VAL_BOOLEANARRAY); writeBooleanArray((boolean[]) v); } else if (v instanceof byte[]) { writeInt(VAL_BYTEARRAY); writeByteArray((byte[]) v); } else if (v instanceof String[]) { writeInt(VAL_STRINGARRAY); writeStringArray((String[]) v); } else if (v instanceof CharSequence[]) { // Must be after String[] and before Object[] writeInt(VAL_CHARSEQUENCEARRAY); writeCharSequenceArray((CharSequence[]) v); } else if (v instanceof IBinder) { writeInt(VAL_IBINDER); writeStrongBinder((IBinder) v); } else if (v instanceof Parcelable[]) { writeInt(VAL_PARCELABLEARRAY); writeParcelableArray((Parcelable[]) v, 0); } else if (v instanceof int[]) { writeInt(VAL_INTARRAY); writeIntArray((int[]) v); } else if (v instanceof long[]) { writeInt(VAL_LONGARRAY); writeLongArray((long[]) v); } else if (v instanceof Byte) { writeInt(VAL_BYTE); writeInt((Byte) v); } else if (v instanceof Size) { writeInt(VAL_SIZE); writeSize((Size) v); } else if (v instanceof SizeF) { writeInt(VAL_SIZEF); writeSizeF((SizeF) v); } else if (v instanceof double[]) { writeInt(VAL_DOUBLEARRAY); writeDoubleArray((double[]) v); } else { Class<?> clazz = v.getClass(); if (clazz.isArray() && clazz.getComponentType() == Object.class) { // Only pure Object[] are written here, Other arrays of non-primitive types are // handled by serialization as this does not record the component type. writeInt(VAL_OBJECTARRAY); writeArray((Object[]) v); } else if (v instanceof Serializable) { // Must be last writeInt(VAL_SERIALIZABLE); writeSerializable((Serializable) v); } else { throw new RuntimeException("Parcel: unable to marshal value " + v); } } } /** * Flatten the name of the class of the Parcelable and its contents * into the parcel. * * @param p The Parcelable object to be written. * @param parcelableFlags Contextual flags as per * {@link Parcelable#writeToParcel(Parcel, int) Parcelable.writeToParcel()}. */ public final void writeParcelable(Parcelable p, int parcelableFlags) { if (p == null) { writeString(null); return; } writeParcelableCreator(p); p.writeToParcel(this, parcelableFlags); } /** @hide */ @UnsupportedAppUsage public final void writeParcelableCreator(Parcelable p) { String name = p.getClass().getName(); writeString(name); } /** * Write a generic serializable object in to a Parcel. It is strongly * recommended that this method be avoided, since the serialization * overhead is extremely large, and this approach will be much slower than * using the other approaches to writing data in to a Parcel. */ public final void writeSerializable(Serializable s) { if (s == null) { writeString(null); return; } String name = s.getClass().getName(); writeString(name); ByteArrayOutputStream baos = new ByteArrayOutputStream(); try { ObjectOutputStream oos = new ObjectOutputStream(baos); oos.writeObject(s); oos.close(); writeByteArray(baos.toByteArray()); } catch (IOException ioe) { throw new RuntimeException( "Parcelable encountered " + "IOException writing serializable object (name = " + name + ")", ioe); } } /** @hide For debugging purposes */ public static void setStackTraceParceling(boolean enabled) { sParcelExceptionStackTrace = enabled; } /** * Special function for writing an exception result at the header of * a parcel, to be used when returning an exception from a transaction. * Note that this currently only supports a few exception types; any other * exception will be re-thrown by this function as a RuntimeException * (to be caught by the system's last-resort exception handling when * dispatching a transaction). * * <p>The supported exception types are: * <ul> * <li>{@link BadParcelableException} * <li>{@link IllegalArgumentException} * <li>{@link IllegalStateException} * <li>{@link NullPointerException} * <li>{@link SecurityException} * <li>{@link UnsupportedOperationException} * <li>{@link NetworkOnMainThreadException} * </ul> * * @param e The Exception to be written. * * @see #writeNoException * @see #readException */ public final void writeException(Exception e) { int code = 0; if (e instanceof Parcelable && (e.getClass().getClassLoader() == Parcelable.class.getClassLoader())) { // We only send Parcelable exceptions that are in the // BootClassLoader to ensure that the receiver can unpack them code = EX_PARCELABLE; } else if (e instanceof SecurityException) { code = EX_SECURITY; } else if (e instanceof BadParcelableException) { code = EX_BAD_PARCELABLE; } else if (e instanceof IllegalArgumentException) { code = EX_ILLEGAL_ARGUMENT; } else if (e instanceof NullPointerException) { code = EX_NULL_POINTER; } else if (e instanceof IllegalStateException) { code = EX_ILLEGAL_STATE; } else if (e instanceof NetworkOnMainThreadException) { code = EX_NETWORK_MAIN_THREAD; } else if (e instanceof UnsupportedOperationException) { code = EX_UNSUPPORTED_OPERATION; } else if (e instanceof ServiceSpecificException) { code = EX_SERVICE_SPECIFIC; } writeInt(code); StrictMode.clearGatheredViolations(); if (code == 0) { if (e instanceof RuntimeException) { throw (RuntimeException) e; } throw new RuntimeException(e); } writeString(e.getMessage()); final long timeNow = sParcelExceptionStackTrace ? SystemClock.elapsedRealtime() : 0; if (sParcelExceptionStackTrace && (timeNow - sLastWriteExceptionStackTrace > WRITE_EXCEPTION_STACK_TRACE_THRESHOLD_MS)) { sLastWriteExceptionStackTrace = timeNow; final int sizePosition = dataPosition(); writeInt(0); // Header size will be filled in later StackTraceElement[] stackTrace = e.getStackTrace(); final int truncatedSize = Math.min(stackTrace.length, 5); StringBuilder sb = new StringBuilder(); for (int i = 0; i < truncatedSize; i++) { sb.append("\tat ").append(stackTrace[i]).append('\n'); } writeString(sb.toString()); final int payloadPosition = dataPosition(); setDataPosition(sizePosition); // Write stack trace header size. Used in native side to skip the header writeInt(payloadPosition - sizePosition); setDataPosition(payloadPosition); } else { writeInt(0); } switch (code) { case EX_SERVICE_SPECIFIC: writeInt(((ServiceSpecificException) e).errorCode); break; case EX_PARCELABLE: // Write parceled exception prefixed by length final int sizePosition = dataPosition(); writeInt(0); writeParcelable((Parcelable) e, Parcelable.PARCELABLE_WRITE_RETURN_VALUE); final int payloadPosition = dataPosition(); setDataPosition(sizePosition); writeInt(payloadPosition - sizePosition); setDataPosition(payloadPosition); break; } } /** * Special function for writing information at the front of the Parcel * indicating that no exception occurred. * * @see #writeException * @see #readException */ public final void writeNoException() { // Despite the name of this function ("write no exception"), // it should instead be thought of as "write the RPC response // header", but because this function name is written out by // the AIDL compiler, we're not going to rename it. // // The response header, in the non-exception case (see also // writeException above, also called by the AIDL compiler), is // either a 0 (the default case), or EX_HAS_REPLY_HEADER if // StrictMode has gathered up violations that have occurred // during a Binder call, in which case we write out the number // of violations and their details, serialized, before the // actual RPC respons data. The receiving end of this is // readException(), below. if (StrictMode.hasGatheredViolations()) { writeInt(EX_HAS_REPLY_HEADER); final int sizePosition = dataPosition(); writeInt(0); // total size of fat header, to be filled in later StrictMode.writeGatheredViolationsToParcel(this); final int payloadPosition = dataPosition(); setDataPosition(sizePosition); writeInt(payloadPosition - sizePosition); // header size setDataPosition(payloadPosition); } else { writeInt(0); } } /** * Special function for reading an exception result from the header of * a parcel, to be used after receiving the result of a transaction. This * will throw the exception for you if it had been written to the Parcel, * otherwise return and let you read the normal result data from the Parcel. * * @see #writeException * @see #writeNoException */ public final void readException() { int code = readExceptionCode(); if (code != 0) { String msg = readString(); readException(code, msg); } } /** * Parses the header of a Binder call's response Parcel and * returns the exception code. Deals with lite or fat headers. * In the common successful case, this header is generally zero. * In less common cases, it's a small negative number and will be * followed by an error string. * * This exists purely for android.database.DatabaseUtils and * insulating it from having to handle fat headers as returned by * e.g. StrictMode-induced RPC responses. * * @hide */ @UnsupportedAppUsage public final int readExceptionCode() { int code = readInt(); if (code == EX_HAS_REPLY_HEADER) { int headerSize = readInt(); if (headerSize == 0) { Log.e(TAG, "Unexpected zero-sized Parcel reply header."); } else { // Currently the only thing in the header is StrictMode stacks, // but discussions around event/RPC tracing suggest we might // put that here too. If so, switch on sub-header tags here. // But for now, just parse out the StrictMode stuff. StrictMode.readAndHandleBinderCallViolations(this); } // And fat response headers are currently only used when // there are no exceptions, so return no error: return 0; } return code; } /** * Throw an exception with the given message. Not intended for use * outside the Parcel class. * * @param code Used to determine which exception class to throw. * @param msg The exception message. */ public final void readException(int code, String msg) { String remoteStackTrace = null; final int remoteStackPayloadSize = readInt(); if (remoteStackPayloadSize > 0) { remoteStackTrace = readString(); } Exception e = createException(code, msg); // Attach remote stack trace if availalble if (remoteStackTrace != null) { RemoteException cause = new RemoteException("Remote stack trace:\n" + remoteStackTrace, null, false, false); try { Throwable rootCause = ExceptionUtils.getRootCause(e); if (rootCause != null) { rootCause.initCause(cause); } } catch (RuntimeException ex) { Log.e(TAG, "Cannot set cause " + cause + " for " + e, ex); } } SneakyThrow.sneakyThrow(e); } /** * Creates an exception with the given message. * * @param code Used to determine which exception class to throw. * @param msg The exception message. */ private Exception createException(int code, String msg) { switch (code) { case EX_PARCELABLE: if (readInt() > 0) { return (Exception) readParcelable(Parcelable.class.getClassLoader()); } else { return new RuntimeException(msg + " [missing Parcelable]"); } case EX_SECURITY: return new SecurityException(msg); case EX_BAD_PARCELABLE: return new BadParcelableException(msg); case EX_ILLEGAL_ARGUMENT: return new IllegalArgumentException(msg); case EX_NULL_POINTER: return new NullPointerException(msg); case EX_ILLEGAL_STATE: return new IllegalStateException(msg); case EX_NETWORK_MAIN_THREAD: return new NetworkOnMainThreadException(); case EX_UNSUPPORTED_OPERATION: return new UnsupportedOperationException(msg); case EX_SERVICE_SPECIFIC: return new ServiceSpecificException(readInt(), msg); } return new RuntimeException("Unknown exception code: " + code + " msg " + msg); } /** * Read an integer value from the parcel at the current dataPosition(). */ public final int readInt() { return nativeReadInt(mNativePtr); } /** * Read a long integer value from the parcel at the current dataPosition(). */ public final long readLong() { return nativeReadLong(mNativePtr); } /** * Read a floating point value from the parcel at the current * dataPosition(). */ public final float readFloat() { return nativeReadFloat(mNativePtr); } /** * Read a double precision floating point value from the parcel at the * current dataPosition(). */ public final double readDouble() { return nativeReadDouble(mNativePtr); } /** * Read a string value from the parcel at the current dataPosition(). */ public final String readString() { return mReadWriteHelper.readString(this); } /** * Read a string without going though a {@link ReadWriteHelper}. Subclasses of * {@link ReadWriteHelper} must use this method instead of {@link #readString} to avoid * infinity recursive calls. * * @hide */ public String readStringNoHelper() { return nativeReadString(mNativePtr); } /** @hide */ public final boolean readBoolean() { return readInt() != 0; } /** * Read a CharSequence value from the parcel at the current dataPosition(). * @hide */ @UnsupportedAppUsage public final CharSequence readCharSequence() { return TextUtils.CHAR_SEQUENCE_CREATOR.createFromParcel(this); } /** * Read an object from the parcel at the current dataPosition(). */ public final IBinder readStrongBinder() { return nativeReadStrongBinder(mNativePtr); } /** * Read a FileDescriptor from the parcel at the current dataPosition(). */ public final ParcelFileDescriptor readFileDescriptor() { FileDescriptor fd = nativeReadFileDescriptor(mNativePtr); return fd != null ? new ParcelFileDescriptor(fd) : null; } /** {@hide} */ @UnsupportedAppUsage public final FileDescriptor readRawFileDescriptor() { return nativeReadFileDescriptor(mNativePtr); } /** * {@hide} * Read and return a new array of FileDescriptors from the parcel. * @return the FileDescriptor array, or null if the array is null. **/ public final FileDescriptor[] createRawFileDescriptorArray() { int N = readInt(); if (N < 0) { return null; } FileDescriptor[] f = new FileDescriptor[N]; for (int i = 0; i < N; i++) { f[i] = readRawFileDescriptor(); } return f; } /** * {@hide} * Read an array of FileDescriptors from a parcel. * The passed array must be exactly the length of the array in the parcel. * @return the FileDescriptor array, or null if the array is null. **/ public final void readRawFileDescriptorArray(FileDescriptor[] val) { int N = readInt(); if (N == val.length) { for (int i = 0; i < N; i++) { val[i] = readRawFileDescriptor(); } } else { throw new RuntimeException("bad array lengths"); } } /** * Read a byte value from the parcel at the current dataPosition(). */ public final byte readByte() { return (byte) (readInt() & 0xff); } /** * Please use {@link #readBundle(ClassLoader)} instead (whose data must have * been written with {@link #writeBundle}. Read into an existing Map object * from the parcel at the current dataPosition(). */ public final void readMap(Map outVal, ClassLoader loader) { int N = readInt(); readMapInternal(outVal, N, loader); } /** * Read into an existing List object from the parcel at the current * dataPosition(), using the given class loader to load any enclosed * Parcelables. If it is null, the default class loader is used. */ public final void readList(List outVal, ClassLoader loader) { int N = readInt(); readListInternal(outVal, N, loader); } /** * Please use {@link #readBundle(ClassLoader)} instead (whose data must have * been written with {@link #writeBundle}. Read and return a new HashMap * object from the parcel at the current dataPosition(), using the given * class loader to load any enclosed Parcelables. Returns null if * the previously written map object was null. */ public final HashMap readHashMap(ClassLoader loader) { int N = readInt(); if (N < 0) { return null; } HashMap m = new HashMap(N); readMapInternal(m, N, loader); return m; } /** * Read and return a new Bundle object from the parcel at the current * dataPosition(). Returns null if the previously written Bundle object was * null. */ public final Bundle readBundle() { return readBundle(null); } /** * Read and return a new Bundle object from the parcel at the current * dataPosition(), using the given class loader to initialize the class * loader of the Bundle for later retrieval of Parcelable objects. * Returns null if the previously written Bundle object was null. */ public final Bundle readBundle(ClassLoader loader) { int length = readInt(); if (length < 0) { if (Bundle.DEBUG) Log.d(TAG, "null bundle: length=" + length); return null; } final Bundle bundle = new Bundle(this, length); if (loader != null) { bundle.setClassLoader(loader); } return bundle; } /** * Read and return a new Bundle object from the parcel at the current * dataPosition(). Returns null if the previously written Bundle object was * null. */ public final PersistableBundle readPersistableBundle() { return readPersistableBundle(null); } /** * Read and return a new Bundle object from the parcel at the current * dataPosition(), using the given class loader to initialize the class * loader of the Bundle for later retrieval of Parcelable objects. * Returns null if the previously written Bundle object was null. */ public final PersistableBundle readPersistableBundle(ClassLoader loader) { int length = readInt(); if (length < 0) { if (Bundle.DEBUG) Log.d(TAG, "null bundle: length=" + length); return null; } final PersistableBundle bundle = new PersistableBundle(this, length); if (loader != null) { bundle.setClassLoader(loader); } return bundle; } /** * Read a Size from the parcel at the current dataPosition(). */ public final Size readSize() { final int width = readInt(); final int height = readInt(); return new Size(width, height); } /** * Read a SizeF from the parcel at the current dataPosition(). */ public final SizeF readSizeF() { final float width = readFloat(); final float height = readFloat(); return new SizeF(width, height); } /** * Read and return a byte[] object from the parcel. */ public final byte[] createByteArray() { return nativeCreateByteArray(mNativePtr); } /** * Read a byte[] object from the parcel and copy it into the * given byte array. */ public final void readByteArray(byte[] val) { boolean valid = nativeReadByteArray(mNativePtr, val, (val != null) ? val.length : 0); if (!valid) { throw new RuntimeException("bad array lengths"); } } /** * Read a blob of data from the parcel and return it as a byte array. * {@hide} * {@SystemApi} */ @UnsupportedAppUsage public final byte[] readBlob() { return nativeReadBlob(mNativePtr); } /** * Read and return a String[] object from the parcel. * {@hide} */ @UnsupportedAppUsage public final String[] readStringArray() { String[] array = null; int length = readInt(); if (length >= 0) { array = new String[length]; for (int i = 0; i < length; i++) { array[i] = readString(); } } return array; } /** * Read and return a CharSequence[] object from the parcel. * {@hide} */ public final CharSequence[] readCharSequenceArray() { CharSequence[] array = null; int length = readInt(); if (length >= 0) { array = new CharSequence[length]; for (int i = 0; i < length; i++) { array[i] = readCharSequence(); } } return array; } /** * Read and return an ArrayList<CharSequence> object from the parcel. * {@hide} */ public final ArrayList<CharSequence> readCharSequenceList() { ArrayList<CharSequence> array = null; int length = readInt(); if (length >= 0) { array = new ArrayList<CharSequence>(length); for (int i = 0; i < length; i++) { array.add(readCharSequence()); } } return array; } /** * Read and return a new ArrayList object from the parcel at the current * dataPosition(). Returns null if the previously written list object was * null. The given class loader will be used to load any enclosed * Parcelables. */ public final ArrayList readArrayList(ClassLoader loader) { int N = readInt(); if (N < 0) { return null; } ArrayList l = new ArrayList(N); readListInternal(l, N, loader); return l; } /** * Read and return a new Object array from the parcel at the current * dataPosition(). Returns null if the previously written array was * null. The given class loader will be used to load any enclosed * Parcelables. */ public final Object[] readArray(ClassLoader loader) { int N = readInt(); if (N < 0) { return null; } Object[] l = new Object[N]; readArrayInternal(l, N, loader); return l; } /** * Read and return a new SparseArray object from the parcel at the current * dataPosition(). Returns null if the previously written list object was * null. The given class loader will be used to load any enclosed * Parcelables. */ public final SparseArray readSparseArray(ClassLoader loader) { int N = readInt(); if (N < 0) { return null; } SparseArray sa = new SparseArray(N); readSparseArrayInternal(sa, N, loader); return sa; } /** * Read and return a new SparseBooleanArray object from the parcel at the current * dataPosition(). Returns null if the previously written list object was * null. */ public final SparseBooleanArray readSparseBooleanArray() { int N = readInt(); if (N < 0) { return null; } SparseBooleanArray sa = new SparseBooleanArray(N); readSparseBooleanArrayInternal(sa, N); return sa; } /** * Read and return a new SparseIntArray object from the parcel at the current * dataPosition(). Returns null if the previously written array object was null. * @hide */ public final SparseIntArray readSparseIntArray() { int N = readInt(); if (N < 0) { return null; } SparseIntArray sa = new SparseIntArray(N); readSparseIntArrayInternal(sa, N); return sa; } /** * Read and return a new ArrayList containing a particular object type from * the parcel that was written with {@link #writeTypedList} at the * current dataPosition(). Returns null if the * previously written list object was null. The list <em>must</em> have * previously been written via {@link #writeTypedList} with the same object * type. * * @return A newly created ArrayList containing objects with the same data * as those that were previously written. * * @see #writeTypedList */ public final <T> ArrayList<T> createTypedArrayList(Parcelable.Creator<T> c) { int N = readInt(); if (N < 0) { return null; } ArrayList<T> l = new ArrayList<T>(N); while (N > 0) { l.add(readTypedObject(c)); N--; } return l; } /** * Read into the given List items containing a particular object type * that were written with {@link #writeTypedList} at the * current dataPosition(). The list <em>must</em> have * previously been written via {@link #writeTypedList} with the same object * type. * * @return A newly created ArrayList containing objects with the same data * as those that were previously written. * * @see #writeTypedList */ public final <T> void readTypedList(List<T> list, Parcelable.Creator<T> c) { int M = list.size(); int N = readInt(); int i = 0; for (; i < M && i < N; i++) { list.set(i, readTypedObject(c)); } for (; i < N; i++) { list.add(readTypedObject(c)); } for (; i < M; i++) { list.remove(N); } } /** * Read and return a new ArrayList containing String objects from * the parcel that was written with {@link #writeStringList} at the * current dataPosition(). Returns null if the * previously written list object was null. * * @return A newly created ArrayList containing strings with the same data * as those that were previously written. * * @see #writeStringList */ public final ArrayList<String> createStringArrayList() { int N = readInt(); if (N < 0) { return null; } ArrayList<String> l = new ArrayList<String>(N); while (N > 0) { l.add(readString()); N--; } return l; } /** * Read and return a new ArrayList containing IBinder objects from * the parcel that was written with {@link #writeBinderList} at the * current dataPosition(). Returns null if the * previously written list object was null. * * @return A newly created ArrayList containing strings with the same data * as those that were previously written. * * @see #writeBinderList */ public final ArrayList<IBinder> createBinderArrayList() { int N = readInt(); if (N < 0) { return null; } ArrayList<IBinder> l = new ArrayList<IBinder>(N); while (N > 0) { l.add(readStrongBinder()); N--; } return l; } /** * Read into the given List items String objects that were written with * {@link #writeStringList} at the current dataPosition(). * * @see #writeStringList */ public final void readStringList(List<String> list) { int M = list.size(); int N = readInt(); int i = 0; for (; i < M && i < N; i++) { list.set(i, readString()); } for (; i < N; i++) { list.add(readString()); } for (; i < M; i++) { list.remove(N); } } /** * Read into the given List items IBinder objects that were written with * {@link #writeBinderList} at the current dataPosition(). * * @see #writeBinderList */ public final void readBinderList(List<IBinder> list) { int M = list.size(); int N = readInt(); int i = 0; for (; i < M && i < N; i++) { list.set(i, readStrongBinder()); } for (; i < N; i++) { list.add(readStrongBinder()); } for (; i < M; i++) { list.remove(N); } } /** * Read the list of {@code Parcelable} objects at the current data position into the * given {@code list}. The contents of the {@code list} are replaced. If the serialized * list was {@code null}, {@code list} is cleared. * * @see #writeParcelableList(List, int) * @hide */ @UnsupportedAppUsage public final <T extends Parcelable> List<T> readParcelableList(List<T> list, ClassLoader cl) { final int N = readInt(); if (N == -1) { list.clear(); return list; } final int M = list.size(); int i = 0; for (; i < M && i < N; i++) { list.set(i, (T) readParcelable(cl)); } for (; i < N; i++) { list.add((T) readParcelable(cl)); } for (; i < M; i++) { list.remove(N); } return list; } /** * Read and return a new array containing a particular object type from * the parcel at the current dataPosition(). Returns null if the * previously written array was null. The array <em>must</em> have * previously been written via {@link #writeTypedArray} with the same * object type. * * @return A newly created array containing objects with the same data * as those that were previously written. * * @see #writeTypedArray */ public final <T> T[] createTypedArray(Parcelable.Creator<T> c) { int N = readInt(); if (N < 0) { return null; } T[] l = c.newArray(N); for (int i = 0; i < N; i++) { l[i] = readTypedObject(c); } return l; } public final <T> void readTypedArray(T[] val, Parcelable.Creator<T> c) { int N = readInt(); if (N == val.length) { for (int i = 0; i < N; i++) { val[i] = readTypedObject(c); } } else { throw new RuntimeException("bad array lengths"); } } /** * @deprecated * @hide */ @Deprecated public final <T> T[] readTypedArray(Parcelable.Creator<T> c) { return createTypedArray(c); } /** * Read and return a typed Parcelable object from a parcel. * Returns null if the previous written object was null. * The object <em>must</em> have previous been written via * {@link #writeTypedObject} with the same object type. * * @return A newly created object of the type that was previously * written. * * @see #writeTypedObject */ public final <T> T readTypedObject(Parcelable.Creator<T> c) { if (readInt() != 0) { return c.createFromParcel(this); } else { return null; } } /** * Write a heterogeneous array of Parcelable objects into the Parcel. * Each object in the array is written along with its class name, so * that the correct class can later be instantiated. As a result, this * has significantly more overhead than {@link #writeTypedArray}, but will * correctly handle an array containing more than one type of object. * * @param value The array of objects to be written. * @param parcelableFlags Contextual flags as per * {@link Parcelable#writeToParcel(Parcel, int) Parcelable.writeToParcel()}. * * @see #writeTypedArray */ public final <T extends Parcelable> void writeParcelableArray(T[] value, int parcelableFlags) { if (value != null) { int N = value.length; writeInt(N); for (int i = 0; i < N; i++) { writeParcelable(value[i], parcelableFlags); } } else { writeInt(-1); } } /** * Read a typed object from a parcel. The given class loader will be * used to load any enclosed Parcelables. If it is null, the default class * loader will be used. */ public final Object readValue(ClassLoader loader) { int type = readInt(); switch (type) { case VAL_NULL: return null; case VAL_STRING: return readString(); case VAL_INTEGER: return readInt(); case VAL_MAP: return readHashMap(loader); case VAL_PARCELABLE: return readParcelable(loader); case VAL_SHORT: return (short) readInt(); case VAL_LONG: return readLong(); case VAL_FLOAT: return readFloat(); case VAL_DOUBLE: return readDouble(); case VAL_BOOLEAN: return readInt() == 1; case VAL_CHARSEQUENCE: return readCharSequence(); case VAL_LIST: return readArrayList(loader); case VAL_BOOLEANARRAY: return createBooleanArray(); case VAL_BYTEARRAY: return createByteArray(); case VAL_STRINGARRAY: return readStringArray(); case VAL_CHARSEQUENCEARRAY: return readCharSequenceArray(); case VAL_IBINDER: return readStrongBinder(); case VAL_OBJECTARRAY: return readArray(loader); case VAL_INTARRAY: return createIntArray(); case VAL_LONGARRAY: return createLongArray(); case VAL_BYTE: return readByte(); case VAL_SERIALIZABLE: return readSerializable(loader); case VAL_PARCELABLEARRAY: return readParcelableArray(loader); case VAL_SPARSEARRAY: return readSparseArray(loader); case VAL_SPARSEBOOLEANARRAY: return readSparseBooleanArray(); case VAL_BUNDLE: return readBundle(loader); // loading will be deferred case VAL_PERSISTABLEBUNDLE: return readPersistableBundle(loader); case VAL_SIZE: return readSize(); case VAL_SIZEF: return readSizeF(); case VAL_DOUBLEARRAY: return createDoubleArray(); default: int off = dataPosition() - 4; throw new RuntimeException( "Parcel " + this + ": Unmarshalling unknown type code " + type + " at offset " + off); } } /** * Read and return a new Parcelable from the parcel. The given class loader * will be used to load any enclosed Parcelables. If it is null, the default * class loader will be used. * @param loader A ClassLoader from which to instantiate the Parcelable * object, or null for the default class loader. * @return Returns the newly created Parcelable, or null if a null * object has been written. * @throws BadParcelableException Throws BadParcelableException if there * was an error trying to instantiate the Parcelable. */ @SuppressWarnings("unchecked") public final <T extends Parcelable> T readParcelable(ClassLoader loader) { Parcelable.Creator<?> creator = readParcelableCreator(loader); if (creator == null) { return null; } if (creator instanceof Parcelable.ClassLoaderCreator<?>) { Parcelable.ClassLoaderCreator<?> classLoaderCreator = (Parcelable.ClassLoaderCreator<?>) creator; return (T) classLoaderCreator.createFromParcel(this, loader); } return (T) creator.createFromParcel(this); } /** @hide */ @UnsupportedAppUsage @SuppressWarnings("unchecked") public final <T extends Parcelable> T readCreator(Parcelable.Creator<?> creator, ClassLoader loader) { if (creator instanceof Parcelable.ClassLoaderCreator<?>) { Parcelable.ClassLoaderCreator<?> classLoaderCreator = (Parcelable.ClassLoaderCreator<?>) creator; return (T) classLoaderCreator.createFromParcel(this, loader); } return (T) creator.createFromParcel(this); } /** @hide */ @UnsupportedAppUsage public final Parcelable.Creator<?> readParcelableCreator(ClassLoader loader) { String name = readString(); if (name == null) { return null; } Parcelable.Creator<?> creator; HashMap<String, Parcelable.Creator<?>> map; synchronized (mCreators) { map = mCreators.get(loader); if (map == null) { map = new HashMap<>(); mCreators.put(loader, map); } creator = map.get(name); } if (creator != null) { return creator; } try { // If loader == null, explicitly emulate Class.forName(String) "caller // classloader" behavior. ClassLoader parcelableClassLoader = (loader == null ? getClass().getClassLoader() : loader); // Avoid initializing the Parcelable class until we know it implements // Parcelable and has the necessary CREATOR field. http://b/1171613. Class<?> parcelableClass = Class.forName(name, false /* initialize */, parcelableClassLoader); if (!Parcelable.class.isAssignableFrom(parcelableClass)) { throw new BadParcelableException( "Parcelable protocol requires subclassing " + "from Parcelable on class " + name); } Field f = parcelableClass.getField("CREATOR"); if ((f.getModifiers() & Modifier.STATIC) == 0) { throw new BadParcelableException( "Parcelable protocol requires " + "the CREATOR object to be static on class " + name); } Class<?> creatorType = f.getType(); if (!Parcelable.Creator.class.isAssignableFrom(creatorType)) { // Fail before calling Field.get(), not after, to avoid initializing // parcelableClass unnecessarily. throw new BadParcelableException("Parcelable protocol requires a " + "Parcelable.Creator object called " + "CREATOR on class " + name); } creator = (Parcelable.Creator<?>) f.get(null); } catch (IllegalAccessException e) { Log.e(TAG, "Illegal access when unmarshalling: " + name, e); throw new BadParcelableException("IllegalAccessException when unmarshalling: " + name); } catch (ClassNotFoundException e) { Log.e(TAG, "Class not found when unmarshalling: " + name, e); throw new BadParcelableException("ClassNotFoundException when unmarshalling: " + name); } catch (NoSuchFieldException e) { throw new BadParcelableException("Parcelable protocol requires a " + "Parcelable.Creator object called " + "CREATOR on class " + name); } if (creator == null) { throw new BadParcelableException("Parcelable protocol requires a " + "non-null Parcelable.Creator object called " + "CREATOR on class " + name); } synchronized (mCreators) { map.put(name, creator); } return creator; } /** * Read and return a new Parcelable array from the parcel. * The given class loader will be used to load any enclosed * Parcelables. * @return the Parcelable array, or null if the array is null */ public final Parcelable[] readParcelableArray(ClassLoader loader) { int N = readInt(); if (N < 0) { return null; } Parcelable[] p = new Parcelable[N]; for (int i = 0; i < N; i++) { p[i] = readParcelable(loader); } return p; } /** @hide */ public final <T extends Parcelable> T[] readParcelableArray(ClassLoader loader, Class<T> clazz) { int N = readInt(); if (N < 0) { return null; } T[] p = (T[]) Array.newInstance(clazz, N); for (int i = 0; i < N; i++) { p[i] = readParcelable(loader); } return p; } /** * Read and return a new Serializable object from the parcel. * @return the Serializable object, or null if the Serializable name * wasn't found in the parcel. */ public final Serializable readSerializable() { return readSerializable(null); } private final Serializable readSerializable(final ClassLoader loader) { String name = readString(); if (name == null) { // For some reason we were unable to read the name of the Serializable (either there // is nothing left in the Parcel to read, or the next value wasn't a String), so // return null, which indicates that the name wasn't found in the parcel. return null; } byte[] serializedData = createByteArray(); ByteArrayInputStream bais = new ByteArrayInputStream(serializedData); try { ObjectInputStream ois = new ObjectInputStream(bais) { @Override protected Class<?> resolveClass(ObjectStreamClass osClass) throws IOException, ClassNotFoundException { // try the custom classloader if provided if (loader != null) { Class<?> c = Class.forName(osClass.getName(), false, loader); if (c != null) { return c; } } return super.resolveClass(osClass); } }; return (Serializable) ois.readObject(); } catch (IOException ioe) { throw new RuntimeException( "Parcelable encountered " + "IOException reading a Serializable object (name = " + name + ")", ioe); } catch (ClassNotFoundException cnfe) { throw new RuntimeException("Parcelable encountered " + "ClassNotFoundException reading a Serializable object (name = " + name + ")", cnfe); } } // Cache of previously looked up CREATOR.createFromParcel() methods for // particular classes. Keys are the names of the classes, values are // Method objects. private static final HashMap<ClassLoader, HashMap<String, Parcelable.Creator<?>>> mCreators = new HashMap<>(); /** @hide for internal use only. */ static protected final Parcel obtain(int obj) { throw new UnsupportedOperationException(); } /** @hide */ static protected final Parcel obtain(long obj) { final Parcel[] pool = sHolderPool; synchronized (pool) { Parcel p; for (int i = 0; i < POOL_SIZE; i++) { p = pool[i]; if (p != null) { pool[i] = null; if (DEBUG_RECYCLE) { p.mStack = new RuntimeException(); } p.init(obj); return p; } } } return new Parcel(obj); } private Parcel(long nativePtr) { if (DEBUG_RECYCLE) { mStack = new RuntimeException(); } //Log.i(TAG, "Initializing obj=0x" + Integer.toHexString(obj), mStack); init(nativePtr); } private void init(long nativePtr) { if (nativePtr != 0) { mNativePtr = nativePtr; mOwnsNativeParcelObject = false; } else { mNativePtr = nativeCreate(); mOwnsNativeParcelObject = true; } } private void freeBuffer() { if (mOwnsNativeParcelObject) { updateNativeSize(nativeFreeBuffer(mNativePtr)); } mReadWriteHelper = ReadWriteHelper.DEFAULT; } private void destroy() { if (mNativePtr != 0) { if (mOwnsNativeParcelObject) { nativeDestroy(mNativePtr); updateNativeSize(0); } mNativePtr = 0; } mReadWriteHelper = null; } @Override protected void finalize() throws Throwable { if (DEBUG_RECYCLE) { if (mStack != null) { Log.w(TAG, "Client did not call Parcel.recycle()", mStack); } } destroy(); } /* package */ void readMapInternal(Map outVal, int N, ClassLoader loader) { while (N > 0) { Object key = readValue(loader); Object value = readValue(loader); outVal.put(key, value); N--; } } /* package */ void readArrayMapInternal(ArrayMap outVal, int N, ClassLoader loader) { if (DEBUG_ARRAY_MAP) { RuntimeException here = new RuntimeException("here"); here.fillInStackTrace(); Log.d(TAG, "Reading " + N + " ArrayMap entries", here); } int startPos; while (N > 0) { if (DEBUG_ARRAY_MAP) startPos = dataPosition(); String key = readString(); Object value = readValue(loader); if (DEBUG_ARRAY_MAP) Log.d(TAG, " Read #" + (N - 1) + " " + (dataPosition() - startPos) + " bytes: key=0x" + Integer.toHexString((key != null ? key.hashCode() : 0)) + " " + key); outVal.append(key, value); N--; } outVal.validate(); } /* package */ void readArrayMapSafelyInternal(ArrayMap outVal, int N, ClassLoader loader) { if (DEBUG_ARRAY_MAP) { RuntimeException here = new RuntimeException("here"); here.fillInStackTrace(); Log.d(TAG, "Reading safely " + N + " ArrayMap entries", here); } while (N > 0) { String key = readString(); if (DEBUG_ARRAY_MAP) Log.d(TAG, " Read safe #" + (N - 1) + ": key=0x" + (key != null ? key.hashCode() : 0) + " " + key); Object value = readValue(loader); outVal.put(key, value); N--; } } /** * @hide For testing only. */ @UnsupportedAppUsage public void readArrayMap(ArrayMap outVal, ClassLoader loader) { final int N = readInt(); if (N < 0) { return; } readArrayMapInternal(outVal, N, loader); } /** * Reads an array set. * * @param loader The class loader to use. * * @hide */ @UnsupportedAppUsage public @Nullable ArraySet<? extends Object> readArraySet(ClassLoader loader) { final int size = readInt(); if (size < 0) { return null; } ArraySet<Object> result = new ArraySet<>(size); for (int i = 0; i < size; i++) { Object value = readValue(loader); result.append(value); } return result; } private void readListInternal(List outVal, int N, ClassLoader loader) { while (N > 0) { Object value = readValue(loader); //Log.d(TAG, "Unmarshalling value=" + value); outVal.add(value); N--; } } private void readArrayInternal(Object[] outVal, int N, ClassLoader loader) { for (int i = 0; i < N; i++) { Object value = readValue(loader); //Log.d(TAG, "Unmarshalling value=" + value); outVal[i] = value; } } private void readSparseArrayInternal(SparseArray outVal, int N, ClassLoader loader) { while (N > 0) { int key = readInt(); Object value = readValue(loader); //Log.i(TAG, "Unmarshalling key=" + key + " value=" + value); outVal.append(key, value); N--; } } private void readSparseBooleanArrayInternal(SparseBooleanArray outVal, int N) { while (N > 0) { int key = readInt(); boolean value = this.readByte() == 1; //Log.i(TAG, "Unmarshalling key=" + key + " value=" + value); outVal.append(key, value); N--; } } private void readSparseIntArrayInternal(SparseIntArray outVal, int N) { while (N > 0) { int key = readInt(); int value = readInt(); outVal.append(key, value); N--; } } /** * @hide For testing */ public long getBlobAshmemSize() { return nativeGetBlobAshmemSize(mNativePtr); } }