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* DO NOT ALTER OR REMOVE COPYRIGHT NOTICES OR THIS FILE HEADER.
*
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*
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* FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License
* version 2 for more details (a copy is included in the LICENSE file that
* accompanied this code).
*
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package jdk.nashorn.internal.runtime.arrays;
import static jdk.nashorn.internal.codegen.CompilerConstants.staticCall;
import java.lang.invoke.MethodHandle;
import java.lang.invoke.MethodHandles;
import java.lang.reflect.Array;
import java.nio.ByteBuffer;
import java.util.ArrayList;
import java.util.Iterator;
import java.util.List;
import jdk.dynalink.CallSiteDescriptor;
import jdk.dynalink.linker.GuardedInvocation;
import jdk.dynalink.linker.LinkRequest;
import jdk.nashorn.internal.codegen.CompilerConstants;
import jdk.nashorn.internal.codegen.types.Type;
import jdk.nashorn.internal.objects.Global;
import jdk.nashorn.internal.runtime.JSType;
import jdk.nashorn.internal.runtime.PropertyDescriptor;
import jdk.nashorn.internal.runtime.ScriptRuntime;
import jdk.nashorn.internal.runtime.UnwarrantedOptimismException;
/**
* ArrayData - abstraction for wrapping array elements
*/
public abstract class ArrayData {
/** Minimum chunk size for underlying arrays */
protected static final int CHUNK_SIZE = 32;
/** Untouched data - still link callsites as IntArrayData, but expands to
* a proper ArrayData when we try to write to it */
public static final ArrayData EMPTY_ARRAY = new UntouchedArrayData();
/**
* Length of the array data. Not necessarily length of the wrapped array.
* This is private to ensure that no one in a subclass is able to touch the length
* without going through {@link #setLength}. This is used to implement
* {@link LengthNotWritableFilter}s, ensuring that there are no ways past
* a {@link #setLength} function replaced by a nop
*/
private long length;
/**
* Method handle to throw an {@link UnwarrantedOptimismException} when getting an element
* of the wrong type
*/
protected static final CompilerConstants.Call THROW_UNWARRANTED = staticCall(MethodHandles.lookup(), ArrayData.class, "throwUnwarranted", void.class, ArrayData.class, int.class, int.class);
/**
* Immutable empty array to get ScriptObjects started.
* Use the same array and convert it to mutable as soon as it is modified
*/
private static class UntouchedArrayData extends ContinuousArrayData {
private UntouchedArrayData() {
super(0);
}
private ArrayData toRealArrayData() {
return new IntArrayData(0);
}
private ArrayData toRealArrayData(final int index) {
final IntArrayData newData = new IntArrayData(index + 1);
return new DeletedRangeArrayFilter(newData, 0, index);
}
@Override
public ContinuousArrayData copy() {
assert length() == 0;
return this;
}
@Override
public Object asArrayOfType(final Class<?> componentType) {
return Array.newInstance(componentType, 0);
}
@Override
public Object[] asObjectArray() {
return ScriptRuntime.EMPTY_ARRAY;
}
@Override
public ArrayData ensure(final long safeIndex) {
assert safeIndex >= 0L;
if (safeIndex >= SparseArrayData.MAX_DENSE_LENGTH) {
return new SparseArrayData(this, safeIndex + 1);
}
//known to fit in int
return toRealArrayData((int)safeIndex);
}
@Override
public ArrayData convert(final Class<?> type) {
return toRealArrayData().convert(type);
}
@Override
public ArrayData delete(final int index) {
return new DeletedRangeArrayFilter(this, index, index);
}
@Override
public ArrayData delete(final long fromIndex, final long toIndex) {
return new DeletedRangeArrayFilter(this, fromIndex, toIndex);
}
@Override
public ArrayData shiftLeft(final int by) {
return this; //nop, always empty or we wouldn't be of this class
}
@Override
public ArrayData shiftRight(final int by) {
return this; //always empty or we wouldn't be of this class
}
@Override
public ArrayData shrink(final long newLength) {
return this;
}
@Override
public ArrayData set(final int index, final Object value, final boolean strict) {
return toRealArrayData(index).set(index, value, strict);
}
@Override
public ArrayData set(final int index, final int value, final boolean strict) {
return toRealArrayData(index).set(index, value, strict);
}
@Override
public ArrayData set(final int index, final double value, final boolean strict) {
return toRealArrayData(index).set(index, value, strict);
}
@Override
public int getInt(final int index) {
throw new ArrayIndexOutOfBoundsException(index); //empty
}
@Override
public double getDouble(final int index) {
throw new ArrayIndexOutOfBoundsException(index); //empty
}
@Override
public Object getObject(final int index) {
throw new ArrayIndexOutOfBoundsException(index); //empty
}
@Override
public boolean has(final int index) {
return false; //empty
}
@Override
public Object pop() {
return ScriptRuntime.UNDEFINED;
}
@Override
public ArrayData push(final boolean strict, final Object item) {
return toRealArrayData().push(strict, item);
}
@Override
public ArrayData slice(final long from, final long to) {
return this; //empty
}
@Override
public ContinuousArrayData fastConcat(final ContinuousArrayData otherData) {
return otherData.copy();
}
//no need to override fastPopInt, as the default behavior is to throw classcast exception so we
//can relink and return an undefined, this is the IntArrayData default behavior
@Override
public String toString() {
return getClass().getSimpleName();
}
@Override
public MethodHandle getElementGetter(final Class<?> returnType, final int programPoint) {
return null;
}
@Override
public MethodHandle getElementSetter(final Class<?> elementType) {
return null;
}
@Override
public Class<?> getElementType() {
return int.class;
}
@Override
public Class<?> getBoxedElementType() {
return Integer.class;
}
}
/**
* Constructor
* @param length Virtual length of the array.
*/
protected ArrayData(final long length) {
this.length = length;
}
/**
* Factory method for unspecified array - start as int
* @return ArrayData
*/
public static ArrayData initialArray() {
return new IntArrayData();
}
/**
* Unwarranted thrower
*
* @param data array data
* @param programPoint program point
* @param index array index
*/
protected static void throwUnwarranted(final ArrayData data, final int programPoint, final int index) {
throw new UnwarrantedOptimismException(data.getObject(index), programPoint);
}
/**
* Align an array size up to the nearest array chunk size
* @param size size required
* @return size given, always >= size
*/
protected static int alignUp(final int size) {
return size + CHUNK_SIZE - 1 & ~(CHUNK_SIZE - 1);
}
/**
* Factory method for unspecified array with given length - start as int array data
*
* @param length the initial length
* @return ArrayData
*/
public static ArrayData allocate(final long length) {
if (length == 0L) {
return new IntArrayData();
} else if (length >= SparseArrayData.MAX_DENSE_LENGTH) {
return new SparseArrayData(EMPTY_ARRAY, length);
} else {
return new DeletedRangeArrayFilter(new IntArrayData((int) length), 0, length - 1);
}
}
/**
* Factory method for unspecified given an array object
*
* @param array the array
* @return ArrayData wrapping this array
*/
public static ArrayData allocate(final Object array) {
final Class<?> clazz = array.getClass();
if (clazz == int[].class) {
return new IntArrayData((int[])array, ((int[])array).length);
} else if (clazz == double[].class) {
return new NumberArrayData((double[])array, ((double[])array).length);
} else {
return new ObjectArrayData((Object[])array, ((Object[])array).length);
}
}
/**
* Allocate an ArrayData wrapping a given array
*
* @param array the array to use for initial elements
* @return the ArrayData
*/
public static ArrayData allocate(final int[] array) {
return new IntArrayData(array, array.length);
}
/**
* Allocate an ArrayData wrapping a given array
*
* @param array the array to use for initial elements
* @return the ArrayData
*/
public static ArrayData allocate(final double[] array) {
return new NumberArrayData(array, array.length);
}
/**
* Allocate an ArrayData wrapping a given array
*
* @param array the array to use for initial elements
* @return the ArrayData
*/
public static ArrayData allocate(final Object[] array) {
return new ObjectArrayData(array, array.length);
}
/**
* Allocate an ArrayData wrapping a given nio ByteBuffer
*
* @param buf the nio ByteBuffer to wrap
* @return the ArrayData
*/
public static ArrayData allocate(final ByteBuffer buf) {
return new ByteBufferArrayData(buf);
}
/**
* Apply a freeze filter to an ArrayData.
*
* @param underlying the underlying ArrayData to wrap in the freeze filter
* @return the frozen ArrayData
*/
public static ArrayData freeze(final ArrayData underlying) {
return new FrozenArrayFilter(underlying);
}
/**
* Apply a seal filter to an ArrayData.
*
* @param underlying the underlying ArrayData to wrap in the seal filter
* @return the sealed ArrayData
*/
public static ArrayData seal(final ArrayData underlying) {
return new SealedArrayFilter(underlying);
}
/**
* Prevent this array from being extended
*
* @param underlying the underlying ArrayData to wrap in the non extensible filter
* @return new array data, filtered
*/
public static ArrayData preventExtension(final ArrayData underlying) {
return new NonExtensibleArrayFilter(underlying);
}
/**
* Prevent this array from having its length reset
*
* @param underlying the underlying ArrayDAta to wrap in the non extensible filter
* @return new array data, filtered
*/
public static ArrayData setIsLengthNotWritable(final ArrayData underlying) {
return new LengthNotWritableFilter(underlying);
}
/**
* Return the length of the array data. This may differ from the actual
* length of the array this wraps as length may be set or gotten as any
* other JavaScript Property
*
* Even though a JavaScript array length may be a long, we only store
* int parts for the optimized array access. For long lengths there
* are special cases anyway.
*
* TODO: represent arrays with "long" lengths as a special ArrayData
* that basically maps to the ScriptObject directly for better abstraction
*
* @return the length of the data
*/
public final long length() {
return length;
}
/**
* Return a copy of the array that can be modified without affecting this instance.
* It is safe to return themselves for immutable subclasses.
*
* @return a new array
*/
public abstract ArrayData copy();
/**
* Return a copy of the array data as an Object array.
*
* @return an Object array
*/
public abstract Object[] asObjectArray();
/**
* Return a copy of the array data as an array of the specified type.
*
* @param componentType the type of elements in the array
* @return and array of the given type
*/
public Object asArrayOfType(final Class<?> componentType) {
return JSType.convertArray(asObjectArray(), componentType);
}
/**
* Set the length of the data array
*
* @param length the new length for the data array
*/
public void setLength(final long length) {
this.length = length;
}
/**
* Increase length by 1
* @return the new length, not the old one (i.e. pre-increment)
*/
protected final long increaseLength() {
return ++this.length;
}
/**
* Decrease length by 1.
* @return the new length, not the old one (i.e. pre-decrement)
*/
protected final long decreaseLength() {
return --this.length;
}
/**
* Shift the array data left
*
* TODO: This is used for Array.prototype.shift() which only shifts by 1,
* so we might consider dropping the offset parameter.
*
* @param by offset to shift
* @return New arraydata (or same)
*/
public abstract ArrayData shiftLeft(final int by);
/**
* Shift the array right
*
* @param by offset to shift
* @return New arraydata (or same)
*/
public abstract ArrayData shiftRight(final int by);
/**
* Ensure that the given index exists and won't fail in a subsequent access.
* If {@code safeIndex} is equal or greater than the current length the length is
* updated to {@code safeIndex + 1}.
*
* @param safeIndex the index to ensure wont go out of bounds
* @return new array data (or same)
*/
public abstract ArrayData ensure(final long safeIndex);
/**
* Shrink the array to a new length, may or may not retain the
* inner array
*
* @param newLength new max length
*
* @return new array data (or same)
*/
public abstract ArrayData shrink(final long newLength);
/**
* Set an object value at a given index
*
* @param index the index
* @param value the value
* @param strict are we in strict mode
* @return new array data (or same)
*/
public abstract ArrayData set(final int index, final Object value, final boolean strict);
/**
* Set an int value at a given index
*
* @param index the index
* @param value the value
* @param strict are we in strict mode
* @return new array data (or same)
*/
public abstract ArrayData set(final int index, final int value, final boolean strict);
/**
* Set an double value at a given index
*
* @param index the index
* @param value the value
* @param strict are we in strict mode
* @return new array data (or same)
*/
public abstract ArrayData set(final int index, final double value, final boolean strict);
/**
* Set an empty value at a given index. Should only affect Object array.
*
* @param index the index
* @return new array data (or same)
*/
public ArrayData setEmpty(final int index) {
// Do nothing.
return this;
}
/**
* Set an empty value for a given range. Should only affect Object array.
*
* @param lo range low end
* @param hi range high end
* @return new array data (or same)
*/
public ArrayData setEmpty(final long lo, final long hi) {
// Do nothing.
return this;
}
/**
* Get an int value from a given index
*
* @param index the index
* @return the value
*/
public abstract int getInt(final int index);
/**
* Returns the optimistic type of this array data. Basically, when an array data object needs to throw an
* {@link UnwarrantedOptimismException}, this type is used as the actual type of the return value.
* @return the optimistic type of this array data.
*/
public Type getOptimisticType() {
return Type.OBJECT;
}
/**
* Get optimistic int - default is that it's impossible. Overridden
* by arrays that actually represents ints
*
* @param index the index
* @param programPoint program point
* @return the value
*/
public int getIntOptimistic(final int index, final int programPoint) {
throw new UnwarrantedOptimismException(getObject(index), programPoint, getOptimisticType());
}
/**
* Get a double value from a given index
*
* @param index the index
* @return the value
*/
public abstract double getDouble(final int index);
/**
* Get optimistic double - default is that it's impossible. Overridden
* by arrays that actually represents doubles or narrower
*
* @param index the index
* @param programPoint program point
* @return the value
*/
public double getDoubleOptimistic(final int index, final int programPoint) {
throw new UnwarrantedOptimismException(getObject(index), programPoint, getOptimisticType());
}
/**
* Get an Object value from a given index
*
* @param index the index
* @return the value
*/
public abstract Object getObject(final int index);
/**
* Tests to see if an entry exists (avoids boxing.)
* @param index the index
* @return true if entry exists
*/
public abstract boolean has(final int index);
/**
* Returns if element at specific index can be deleted or not.
*
* @param index the index of the element
* @param strict are we in strict mode
*
* @return true if element can be deleted
*/
public boolean canDelete(final int index, final boolean strict) {
return true;
}
/**
* Returns if element at specific index can be deleted or not.
*
* @param longIndex the index
* @param strict are we in strict mode
*
* @return true if range can be deleted
*/
public boolean canDelete(final long longIndex, final boolean strict) {
return true;
}
/**
* Delete a range from the array if {@code fromIndex} is less than or equal to {@code toIndex}
* and the array supports deletion.
*
* @param fromIndex the start index (inclusive)
* @param toIndex the end index (inclusive)
* @param strict are we in strict mode
* @return an array with the range deleted, or this array if no deletion took place
*/
public final ArrayData safeDelete(final long fromIndex, final long toIndex, final boolean strict) {
if (fromIndex <= toIndex && canDelete(fromIndex, strict)) {
return delete(fromIndex, toIndex);
}
return this;
}
/**
* Returns property descriptor for element at a given index
*
* @param global the global object
* @param index the index
*
* @return property descriptor for element
*/
public PropertyDescriptor getDescriptor(final Global global, final int index) {
return global.newDataDescriptor(getObject(index), true, true, true);
}
/**
* Delete an array value at the given index, substituting
* for an undefined
*
* @param index the index
* @return new array data (or same)
*/
public abstract ArrayData delete(final int index);
/**
* Delete a given range from this array;
*
* @param fromIndex from index (inclusive)
* @param toIndex to index (inclusive)
*
* @return new ArrayData after deletion
*/
public abstract ArrayData delete(final long fromIndex, final long toIndex);
/**
* Convert the ArrayData to one with a different element type
* Currently Arrays are not collapsed to narrower types, just to
* wider ones. Attempting to narrow an array will assert
*
* @param type new element type
* @return new array data
*/
public abstract ArrayData convert(final Class<?> type);
/**
* Push an array of items to the end of the array
*
* @param strict are we in strict mode
* @param items the items
* @return new array data (or same)
*/
public ArrayData push(final boolean strict, final Object... items) {
if (items.length == 0) {
return this;
}
final Class<?> widest = widestType(items);
ArrayData newData = convert(widest);
long pos = newData.length;
for (final Object item : items) {
newData = newData.ensure(pos); //avoid sparse array
newData.set((int)pos++, item, strict);
}
return newData;
}
/**
* Push an array of items to the end of the array
*
* @param strict are we in strict mode
* @param item the item
* @return new array data (or same)
*/
public ArrayData push(final boolean strict, final Object item) {
return push(strict, new Object[] { item });
}
/**
* Pop an element from the end of the array
*
* @return the popped element
*/
public abstract Object pop();
/**
* Slice out a section of the array and return that
* subsection as a new array data: [from, to)
*
* @param from start index
* @param to end index + 1
* @return new array data
*/
public abstract ArrayData slice(final long from, final long to);
/**
* Fast splice operation. This just modifies the array according to the number of
* elements added and deleted but does not insert the added elements. Throws
* {@code UnsupportedOperationException} if fast splice operation is not supported
* for this class or arguments.
*
* @param start start index of splice operation
* @param removed number of removed elements
* @param added number of added elements
* @throws UnsupportedOperationException if fast splice is not supported for the class or arguments.
* @return new arraydata, but this never happens because we always throw an exception
*/
public ArrayData fastSplice(final int start, final int removed, final int added) throws UnsupportedOperationException {
throw new UnsupportedOperationException();
}
static Class<?> widestType(final Object... items) {
assert items.length > 0;
Class<?> widest = Integer.class;
for (final Object item : items) {
if (item == null) {
return Object.class;
}
final Class<?> itemClass = item.getClass();
if (itemClass == Double.class || itemClass == Float.class || itemClass == Long.class) {
if (widest == Integer.class) {
widest = Double.class;
}
} else if (itemClass != Integer.class && itemClass != Short.class && itemClass != Byte.class) {
return Object.class;
}
}
return widest;
}
/**
* Return a list of keys in the array for the iterators
* @return iterator key list
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