/*
* Copyright (c) 2000, 2019, Oracle and/or its affiliates. All rights reserved.
* DO NOT ALTER OR REMOVE COPYRIGHT NOTICES OR THIS FILE HEADER.
*
* This code is free software; you can redistribute it and/or modify it
* under the terms of the GNU General Public License version 2 only, as
* published by the Free Software Foundation. Oracle designates this
* particular file as subject to the "Classpath" exception as provided
* by Oracle in the LICENSE file that accompanied this code.
*
* This code is distributed in the hope that it will be useful, but WITHOUT
* ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or
* 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).
*
* You should have received a copy of the GNU General Public License version
* 2 along with this work; if not, write to the Free Software Foundation,
* Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA.
*
* Please contact Oracle, 500 Oracle Parkway, Redwood Shores, CA 94065 USA
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package jdk.internal.misc;
import jdk.internal.HotSpotIntrinsicCandidate;
import jdk.internal.ref.Cleaner;
import jdk.internal.vm.annotation.ForceInline;
import sun.nio.ch.DirectBuffer;
import java.lang.reflect.Field;
import java.security.ProtectionDomain;
import static jdk.internal.misc.UnsafeConstants.*;
A collection of methods for performing low-level, unsafe operations.
Although the class and all methods are public, use of this class is
limited because only trusted code can obtain instances of it.
Note: It is the resposibility of the caller to make sure
arguments are checked before methods of this class are
called. While some rudimentary checks are performed on the input,
the checks are best effort and when performance is an overriding
priority, as when methods of this class are optimized by the
runtime compiler, some or all checks (if any) may be elided. Hence,
the caller must not rely on the checks and corresponding
exceptions!
Author: John R. Rose See Also:
/**
* A collection of methods for performing low-level, unsafe operations.
* Although the class and all methods are public, use of this class is
* limited because only trusted code can obtain instances of it.
*
* <em>Note:</em> It is the resposibility of the caller to make sure
* arguments are checked before methods of this class are
* called. While some rudimentary checks are performed on the input,
* the checks are best effort and when performance is an overriding
* priority, as when methods of this class are optimized by the
* runtime compiler, some or all checks (if any) may be elided. Hence,
* the caller must not rely on the checks and corresponding
* exceptions!
*
* @author John R. Rose
* @see #getUnsafe
*/
public final class Unsafe {
private static native void registerNatives();
static {
registerNatives();
}
private Unsafe() {}
private static final Unsafe theUnsafe = new Unsafe();
Provides the caller with the capability of performing unsafe
operations.
The returned Unsafe
object should be carefully guarded by the caller, since it can be used to read and write data at arbitrary memory addresses. It must never be passed to untrusted code.
Most methods in this class are very low-level, and correspond to a
small number of hardware instructions (on typical machines). Compilers
are encouraged to optimize these methods accordingly.
Here is a suggested idiom for using unsafe operations:
class MyTrustedClass {
private static final Unsafe unsafe = Unsafe.getUnsafe();
...
private long myCountAddress = ...;
public int getCount() { return unsafe.getByte(myCountAddress); }
}
(It may assist compilers to make the local variable final
.) /**
* Provides the caller with the capability of performing unsafe
* operations.
*
* <p>The returned {@code Unsafe} object should be carefully guarded
* by the caller, since it can be used to read and write data at arbitrary
* memory addresses. It must never be passed to untrusted code.
*
* <p>Most methods in this class are very low-level, and correspond to a
* small number of hardware instructions (on typical machines). Compilers
* are encouraged to optimize these methods accordingly.
*
* <p>Here is a suggested idiom for using unsafe operations:
*
* <pre> {@code
* class MyTrustedClass {
* private static final Unsafe unsafe = Unsafe.getUnsafe();
* ...
* private long myCountAddress = ...;
* public int getCount() { return unsafe.getByte(myCountAddress); }
* }}</pre>
*
* (It may assist compilers to make the local variable {@code final}.)
*/
public static Unsafe getUnsafe() {
return theUnsafe;
}
/// peek and poke operations
/// (compilers should optimize these to memory ops)
// These work on object fields in the Java heap.
// They will not work on elements of packed arrays.
Fetches a value from a given Java variable. More specifically, fetches a field or array element within the given object o
at the given offset, or (if o
is null) from the memory address whose numerical value is the given offset.
The results are undefined unless one of the following cases is true:
- The offset was obtained from
objectFieldOffset
on the Field
of some Java field and the object referred to by o
is of a class compatible with that field's class. - The offset and object reference
o
(either null or non-null) were both obtained via staticFieldOffset
and staticFieldBase
(respectively) from the reflective Field
representation of some Java field. - The object referred to by
o
is an array, and the offset is an integer of the form B+N*S
, where N
is a valid index into the array, and B
and S
are the values obtained by arrayBaseOffset
and arrayIndexScale
(respectively) from the array's class. The value referred to is the N
th element of the array.
If one of the above cases is true, the call references a specific Java
variable (field or array element). However, the results are undefined
if that variable is not in fact of the type returned by this method.
This method refers to a variable by means of two parameters, and so
it provides (in effect) a double-register addressing mode for Java variables. When the object reference is null, this method uses its offset as an absolute address. This is similar in operation to methods such as getInt(long)
, which provide (in effect) a single-register addressing mode for non-Java variables.
However, because Java variables may have a different layout in memory
from non-Java variables, programmers should not assume that these
two addressing modes are ever equivalent. Also, programmers should
remember that offsets from the double-register addressing mode cannot
be portably confused with longs used in the single-register addressing
mode.
Params: - o – Java heap object in which the variable resides, if any, else
null
- offset – indication of where the variable resides in a Java heap
object, if any, else a memory address locating the variable
statically
Throws: - RuntimeException – No defined exceptions are thrown, not even
NullPointerException
Returns: the value fetched from the indicated Java variable
/**
* Fetches a value from a given Java variable.
* More specifically, fetches a field or array element within the given
* object {@code o} at the given offset, or (if {@code o} is null)
* from the memory address whose numerical value is the given offset.
* <p>
* The results are undefined unless one of the following cases is true:
* <ul>
* <li>The offset was obtained from {@link #objectFieldOffset} on
* the {@link java.lang.reflect.Field} of some Java field and the object
* referred to by {@code o} is of a class compatible with that
* field's class.
*
* <li>The offset and object reference {@code o} (either null or
* non-null) were both obtained via {@link #staticFieldOffset}
* and {@link #staticFieldBase} (respectively) from the
* reflective {@link Field} representation of some Java field.
*
* <li>The object referred to by {@code o} is an array, and the offset
* is an integer of the form {@code B+N*S}, where {@code N} is
* a valid index into the array, and {@code B} and {@code S} are
* the values obtained by {@link #arrayBaseOffset} and {@link
* #arrayIndexScale} (respectively) from the array's class. The value
* referred to is the {@code N}<em>th</em> element of the array.
*
* </ul>
* <p>
* If one of the above cases is true, the call references a specific Java
* variable (field or array element). However, the results are undefined
* if that variable is not in fact of the type returned by this method.
* <p>
* This method refers to a variable by means of two parameters, and so
* it provides (in effect) a <em>double-register</em> addressing mode
* for Java variables. When the object reference is null, this method
* uses its offset as an absolute address. This is similar in operation
* to methods such as {@link #getInt(long)}, which provide (in effect) a
* <em>single-register</em> addressing mode for non-Java variables.
* However, because Java variables may have a different layout in memory
* from non-Java variables, programmers should not assume that these
* two addressing modes are ever equivalent. Also, programmers should
* remember that offsets from the double-register addressing mode cannot
* be portably confused with longs used in the single-register addressing
* mode.
*
* @param o Java heap object in which the variable resides, if any, else
* null
* @param offset indication of where the variable resides in a Java heap
* object, if any, else a memory address locating the variable
* statically
* @return the value fetched from the indicated Java variable
* @throws RuntimeException No defined exceptions are thrown, not even
* {@link NullPointerException}
*/
@HotSpotIntrinsicCandidate
public native int getInt(Object o, long offset);
Stores a value into a given Java variable.
The first two parameters are interpreted exactly as with getInt(Object, long)
to refer to a specific Java variable (field or array element). The given value is stored into that variable.
The variable must be of the same type as the method parameter x
.
Params: - o – Java heap object in which the variable resides, if any, else
null
- offset – indication of where the variable resides in a Java heap
object, if any, else a memory address locating the variable
statically
- x – the value to store into the indicated Java variable
Throws: - RuntimeException – No defined exceptions are thrown, not even
NullPointerException
/**
* Stores a value into a given Java variable.
* <p>
* The first two parameters are interpreted exactly as with
* {@link #getInt(Object, long)} to refer to a specific
* Java variable (field or array element). The given value
* is stored into that variable.
* <p>
* The variable must be of the same type as the method
* parameter {@code x}.
*
* @param o Java heap object in which the variable resides, if any, else
* null
* @param offset indication of where the variable resides in a Java heap
* object, if any, else a memory address locating the variable
* statically
* @param x the value to store into the indicated Java variable
* @throws RuntimeException No defined exceptions are thrown, not even
* {@link NullPointerException}
*/
@HotSpotIntrinsicCandidate
public native void putInt(Object o, long offset, int x);
Fetches a reference value from a given Java variable.
See Also: - getInt(Object, long)
/**
* Fetches a reference value from a given Java variable.
* @see #getInt(Object, long)
*/
@HotSpotIntrinsicCandidate
public native Object getReference(Object o, long offset);
Stores a reference value into a given Java variable.
Unless the reference x
being stored is either null or matches the field type, the results are undefined. If the reference o
is non-null, card marks or other store barriers for that object (if the VM requires them) are updated.
See Also:
/**
* Stores a reference value into a given Java variable.
* <p>
* Unless the reference {@code x} being stored is either null
* or matches the field type, the results are undefined.
* If the reference {@code o} is non-null, card marks or
* other store barriers for that object (if the VM requires them)
* are updated.
* @see #putInt(Object, long, int)
*/
@HotSpotIntrinsicCandidate
public native void putReference(Object o, long offset, Object x);
See Also:
/** @see #getInt(Object, long) */
@HotSpotIntrinsicCandidate
public native boolean getBoolean(Object o, long offset);
See Also:
/** @see #putInt(Object, long, int) */
@HotSpotIntrinsicCandidate
public native void putBoolean(Object o, long offset, boolean x);
See Also:
/** @see #getInt(Object, long) */
@HotSpotIntrinsicCandidate
public native byte getByte(Object o, long offset);
See Also:
/** @see #putInt(Object, long, int) */
@HotSpotIntrinsicCandidate
public native void putByte(Object o, long offset, byte x);
See Also:
/** @see #getInt(Object, long) */
@HotSpotIntrinsicCandidate
public native short getShort(Object o, long offset);
See Also:
/** @see #putInt(Object, long, int) */
@HotSpotIntrinsicCandidate
public native void putShort(Object o, long offset, short x);
See Also:
/** @see #getInt(Object, long) */
@HotSpotIntrinsicCandidate
public native char getChar(Object o, long offset);
See Also:
/** @see #putInt(Object, long, int) */
@HotSpotIntrinsicCandidate
public native void putChar(Object o, long offset, char x);
See Also:
/** @see #getInt(Object, long) */
@HotSpotIntrinsicCandidate
public native long getLong(Object o, long offset);
See Also:
/** @see #putInt(Object, long, int) */
@HotSpotIntrinsicCandidate
public native void putLong(Object o, long offset, long x);
See Also:
/** @see #getInt(Object, long) */
@HotSpotIntrinsicCandidate
public native float getFloat(Object o, long offset);
See Also:
/** @see #putInt(Object, long, int) */
@HotSpotIntrinsicCandidate
public native void putFloat(Object o, long offset, float x);
See Also:
/** @see #getInt(Object, long) */
@HotSpotIntrinsicCandidate
public native double getDouble(Object o, long offset);
See Also:
/** @see #putInt(Object, long, int) */
@HotSpotIntrinsicCandidate
public native void putDouble(Object o, long offset, double x);
Fetches a native pointer from a given memory address. If the address is zero, or does not point into a block obtained from allocateMemory
, the results are undefined. If the native pointer is less than 64 bits wide, it is extended as an unsigned number to a Java long. The pointer may be indexed by any given byte offset, simply by adding that offset (as a simple integer) to the long representing the pointer. The number of bytes actually read from the target address may be determined by consulting addressSize
.
See Also:
/**
* Fetches a native pointer from a given memory address. If the address is
* zero, or does not point into a block obtained from {@link
* #allocateMemory}, the results are undefined.
*
* <p>If the native pointer is less than 64 bits wide, it is extended as
* an unsigned number to a Java long. The pointer may be indexed by any
* given byte offset, simply by adding that offset (as a simple integer) to
* the long representing the pointer. The number of bytes actually read
* from the target address may be determined by consulting {@link
* #addressSize}.
*
* @see #allocateMemory
* @see #getInt(Object, long)
*/
@ForceInline
public long getAddress(Object o, long offset) {
if (ADDRESS_SIZE == 4) {
return Integer.toUnsignedLong(getInt(o, offset));
} else {
return getLong(o, offset);
}
}
Stores a native pointer into a given memory address. If the address is zero, or does not point into a block obtained from allocateMemory
, the results are undefined. The number of bytes actually written at the target address may be determined by consulting addressSize
.
See Also:
/**
* Stores a native pointer into a given memory address. If the address is
* zero, or does not point into a block obtained from {@link
* #allocateMemory}, the results are undefined.
*
* <p>The number of bytes actually written at the target address may be
* determined by consulting {@link #addressSize}.
*
* @see #allocateMemory
* @see #putInt(Object, long, int)
*/
@ForceInline
public void putAddress(Object o, long offset, long x) {
if (ADDRESS_SIZE == 4) {
putInt(o, offset, (int)x);
} else {
putLong(o, offset, x);
}
}
// These read VM internal data.
Fetches an uncompressed reference value from a given native variable
ignoring the VM's compressed references mode.
Params: - address – a memory address locating the variable
Returns: the value fetched from the indicated native variable
/**
* Fetches an uncompressed reference value from a given native variable
* ignoring the VM's compressed references mode.
*
* @param address a memory address locating the variable
* @return the value fetched from the indicated native variable
*/
public native Object getUncompressedObject(long address);
// These work on values in the C heap.
Fetches a value from a given memory address. If the address is zero, or does not point into a block obtained from allocateMemory
, the results are undefined. See Also:
/**
* Fetches a value from a given memory address. If the address is zero, or
* does not point into a block obtained from {@link #allocateMemory}, the
* results are undefined.
*
* @see #allocateMemory
*/
@ForceInline
public byte getByte(long address) {
return getByte(null, address);
}
Stores a value into a given memory address. If the address is zero, or does not point into a block obtained from allocateMemory
, the results are undefined. See Also:
/**
* Stores a value into a given memory address. If the address is zero, or
* does not point into a block obtained from {@link #allocateMemory}, the
* results are undefined.
*
* @see #getByte(long)
*/
@ForceInline
public void putByte(long address, byte x) {
putByte(null, address, x);
}
See Also:
/** @see #getByte(long) */
@ForceInline
public short getShort(long address) {
return getShort(null, address);
}
See Also:
/** @see #putByte(long, byte) */
@ForceInline
public void putShort(long address, short x) {
putShort(null, address, x);
}
See Also:
/** @see #getByte(long) */
@ForceInline
public char getChar(long address) {
return getChar(null, address);
}
See Also:
/** @see #putByte(long, byte) */
@ForceInline
public void putChar(long address, char x) {
putChar(null, address, x);
}
See Also:
/** @see #getByte(long) */
@ForceInline
public int getInt(long address) {
return getInt(null, address);
}
See Also:
/** @see #putByte(long, byte) */
@ForceInline
public void putInt(long address, int x) {
putInt(null, address, x);
}
See Also:
/** @see #getByte(long) */
@ForceInline
public long getLong(long address) {
return getLong(null, address);
}
See Also:
/** @see #putByte(long, byte) */
@ForceInline
public void putLong(long address, long x) {
putLong(null, address, x);
}
See Also:
/** @see #getByte(long) */
@ForceInline
public float getFloat(long address) {
return getFloat(null, address);
}
See Also:
/** @see #putByte(long, byte) */
@ForceInline
public void putFloat(long address, float x) {
putFloat(null, address, x);
}
See Also:
/** @see #getByte(long) */
@ForceInline
public double getDouble(long address) {
return getDouble(null, address);
}
See Also:
/** @see #putByte(long, byte) */
@ForceInline
public void putDouble(long address, double x) {
putDouble(null, address, x);
}
See Also:
/** @see #getAddress(Object, long) */
@ForceInline
public long getAddress(long address) {
return getAddress(null, address);
}
See Also:
/** @see #putAddress(Object, long, long) */
@ForceInline
public void putAddress(long address, long x) {
putAddress(null, address, x);
}
/// helper methods for validating various types of objects/values
Create an exception reflecting that some of the input was invalid
Note: It is the resposibility of the caller to make
sure arguments are checked before the methods are called. While
some rudimentary checks are performed on the input, the checks
are best effort and when performance is an overriding priority,
as when methods of this class are optimized by the runtime
compiler, some or all checks (if any) may be elided. Hence, the
caller must not rely on the checks and corresponding
exceptions!
Returns: an exception object
/**
* Create an exception reflecting that some of the input was invalid
*
* <em>Note:</em> It is the resposibility of the caller to make
* sure arguments are checked before the methods are called. While
* some rudimentary checks are performed on the input, the checks
* are best effort and when performance is an overriding priority,
* as when methods of this class are optimized by the runtime
* compiler, some or all checks (if any) may be elided. Hence, the
* caller must not rely on the checks and corresponding
* exceptions!
*
* @return an exception object
*/
private RuntimeException invalidInput() {
return new IllegalArgumentException();
}
Check if a value is 32-bit clean (32 MSB are all zero)
Params: - value – the 64-bit value to check
Returns: true if the value is 32-bit clean
/**
* Check if a value is 32-bit clean (32 MSB are all zero)
*
* @param value the 64-bit value to check
*
* @return true if the value is 32-bit clean
*/
private boolean is32BitClean(long value) {
return value >>> 32 == 0;
}
Check the validity of a size (the equivalent of a size_t)
Throws: - RuntimeException – if the size is invalid
(Note: after optimization, invalid inputs may
go undetected, which will lead to unpredictable
behavior)
/**
* Check the validity of a size (the equivalent of a size_t)
*
* @throws RuntimeException if the size is invalid
* (<em>Note:</em> after optimization, invalid inputs may
* go undetected, which will lead to unpredictable
* behavior)
*/
private void checkSize(long size) {
if (ADDRESS_SIZE == 4) {
// Note: this will also check for negative sizes
if (!is32BitClean(size)) {
throw invalidInput();
}
} else if (size < 0) {
throw invalidInput();
}
}
Check the validity of a native address (the equivalent of void*)
Throws: - RuntimeException – if the address is invalid
(Note: after optimization, invalid inputs may
go undetected, which will lead to unpredictable
behavior)
/**
* Check the validity of a native address (the equivalent of void*)
*
* @throws RuntimeException if the address is invalid
* (<em>Note:</em> after optimization, invalid inputs may
* go undetected, which will lead to unpredictable
* behavior)
*/
private void checkNativeAddress(long address) {
if (ADDRESS_SIZE == 4) {
// Accept both zero and sign extended pointers. A valid
// pointer will, after the +1 below, either have produced
// the value 0x0 or 0x1. Masking off the low bit allows
// for testing against 0.
if ((((address >> 32) + 1) & ~1) != 0) {
throw invalidInput();
}
}
}
Check the validity of an offset, relative to a base object
Params: - o – the base object
- offset – the offset to check
Throws: - RuntimeException – if the size is invalid
(Note: after optimization, invalid inputs may
go undetected, which will lead to unpredictable
behavior)
/**
* Check the validity of an offset, relative to a base object
*
* @param o the base object
* @param offset the offset to check
*
* @throws RuntimeException if the size is invalid
* (<em>Note:</em> after optimization, invalid inputs may
* go undetected, which will lead to unpredictable
* behavior)
*/
private void checkOffset(Object o, long offset) {
if (ADDRESS_SIZE == 4) {
// Note: this will also check for negative offsets
if (!is32BitClean(offset)) {
throw invalidInput();
}
} else if (offset < 0) {
throw invalidInput();
}
}
Check the validity of a double-register pointer
Note: This code deliberately does *not* check for NPE for (at
least) three reasons:
1) NPE is not just NULL/0 - there is a range of values all
resulting in an NPE, which is not trivial to check for
2) It is the responsibility of the callers of Unsafe methods
to verify the input, so throwing an exception here is not really
useful - passing in a NULL pointer is a critical error and the
must not expect an exception to be thrown anyway.
3) the actual operations will detect NULL pointers anyway by
means of traps and signals (like SIGSEGV).
Params: - o – Java heap object, or null
- offset – indication of where the variable resides in a Java heap
object, if any, else a memory address locating the variable
statically
Throws: - RuntimeException – if the pointer is invalid
(Note: after optimization, invalid inputs may
go undetected, which will lead to unpredictable
behavior)
/**
* Check the validity of a double-register pointer
*
* Note: This code deliberately does *not* check for NPE for (at
* least) three reasons:
*
* 1) NPE is not just NULL/0 - there is a range of values all
* resulting in an NPE, which is not trivial to check for
*
* 2) It is the responsibility of the callers of Unsafe methods
* to verify the input, so throwing an exception here is not really
* useful - passing in a NULL pointer is a critical error and the
* must not expect an exception to be thrown anyway.
*
* 3) the actual operations will detect NULL pointers anyway by
* means of traps and signals (like SIGSEGV).
*
* @param o Java heap object, or null
* @param offset indication of where the variable resides in a Java heap
* object, if any, else a memory address locating the variable
* statically
*
* @throws RuntimeException if the pointer is invalid
* (<em>Note:</em> after optimization, invalid inputs may
* go undetected, which will lead to unpredictable
* behavior)
*/
private void checkPointer(Object o, long offset) {
if (o == null) {
checkNativeAddress(offset);
} else {
checkOffset(o, offset);
}
}
Check if a type is a primitive array type
Params: - c – the type to check
Returns: true if the type is a primitive array type
/**
* Check if a type is a primitive array type
*
* @param c the type to check
*
* @return true if the type is a primitive array type
*/
private void checkPrimitiveArray(Class<?> c) {
Class<?> componentType = c.getComponentType();
if (componentType == null || !componentType.isPrimitive()) {
throw invalidInput();
}
}
Check that a pointer is a valid primitive array type pointer
Note: pointers off-heap are considered to be primitive arrays
Throws: - RuntimeException – if the pointer is invalid
(Note: after optimization, invalid inputs may
go undetected, which will lead to unpredictable
behavior)
/**
* Check that a pointer is a valid primitive array type pointer
*
* Note: pointers off-heap are considered to be primitive arrays
*
* @throws RuntimeException if the pointer is invalid
* (<em>Note:</em> after optimization, invalid inputs may
* go undetected, which will lead to unpredictable
* behavior)
*/
private void checkPrimitivePointer(Object o, long offset) {
checkPointer(o, offset);
if (o != null) {
// If on heap, it must be a primitive array
checkPrimitiveArray(o.getClass());
}
}
/// wrappers for malloc, realloc, free:
Allocates a new block of native memory, of the given size in bytes. The contents of the memory are uninitialized; they will generally be garbage. The resulting native pointer will never be zero, and will be aligned for all value types. Dispose of this memory by calling freeMemory
, or resize it with reallocateMemory
. Note: It is the resposibility of the caller to make
sure arguments are checked before the methods are called. While
some rudimentary checks are performed on the input, the checks
are best effort and when performance is an overriding priority,
as when methods of this class are optimized by the runtime
compiler, some or all checks (if any) may be elided. Hence, the
caller must not rely on the checks and corresponding
exceptions!
Throws: - RuntimeException – if the size is negative or too large
for the native size_t type
- OutOfMemoryError – if the allocation is refused by the system
See Also:
/**
* Allocates a new block of native memory, of the given size in bytes. The
* contents of the memory are uninitialized; they will generally be
* garbage. The resulting native pointer will never be zero, and will be
* aligned for all value types. Dispose of this memory by calling {@link
* #freeMemory}, or resize it with {@link #reallocateMemory}.
*
* <em>Note:</em> It is the resposibility of the caller to make
* sure arguments are checked before the methods are called. While
* some rudimentary checks are performed on the input, the checks
* are best effort and when performance is an overriding priority,
* as when methods of this class are optimized by the runtime
* compiler, some or all checks (if any) may be elided. Hence, the
* caller must not rely on the checks and corresponding
* exceptions!
*
* @throws RuntimeException if the size is negative or too large
* for the native size_t type
*
* @throws OutOfMemoryError if the allocation is refused by the system
*
* @see #getByte(long)
* @see #putByte(long, byte)
*/
public long allocateMemory(long bytes) {
allocateMemoryChecks(bytes);
if (bytes == 0) {
return 0;
}
long p = allocateMemory0(bytes);
if (p == 0) {
throw new OutOfMemoryError();
}
return p;
}
Validate the arguments to allocateMemory
Throws: - RuntimeException – if the arguments are invalid
(Note: after optimization, invalid inputs may
go undetected, which will lead to unpredictable
behavior)
/**
* Validate the arguments to allocateMemory
*
* @throws RuntimeException if the arguments are invalid
* (<em>Note:</em> after optimization, invalid inputs may
* go undetected, which will lead to unpredictable
* behavior)
*/
private void allocateMemoryChecks(long bytes) {
checkSize(bytes);
}
Resizes a new block of native memory, to the given size in bytes. The contents of the new block past the size of the old block are uninitialized; they will generally be garbage. The resulting native pointer will be zero if and only if the requested size is zero. The resulting native pointer will be aligned for all value types. Dispose of this memory by calling freeMemory
, or resize it with reallocateMemory
. The address passed to this method may be null, in which case an allocation will be performed. Note: It is the resposibility of the caller to make
sure arguments are checked before the methods are called. While
some rudimentary checks are performed on the input, the checks
are best effort and when performance is an overriding priority,
as when methods of this class are optimized by the runtime
compiler, some or all checks (if any) may be elided. Hence, the
caller must not rely on the checks and corresponding
exceptions!
Throws: - RuntimeException – if the size is negative or too large
for the native size_t type
- OutOfMemoryError – if the allocation is refused by the system
See Also:
/**
* Resizes a new block of native memory, to the given size in bytes. The
* contents of the new block past the size of the old block are
* uninitialized; they will generally be garbage. The resulting native
* pointer will be zero if and only if the requested size is zero. The
* resulting native pointer will be aligned for all value types. Dispose
* of this memory by calling {@link #freeMemory}, or resize it with {@link
* #reallocateMemory}. The address passed to this method may be null, in
* which case an allocation will be performed.
*
* <em>Note:</em> It is the resposibility of the caller to make
* sure arguments are checked before the methods are called. While
* some rudimentary checks are performed on the input, the checks
* are best effort and when performance is an overriding priority,
* as when methods of this class are optimized by the runtime
* compiler, some or all checks (if any) may be elided. Hence, the
* caller must not rely on the checks and corresponding
* exceptions!
*
* @throws RuntimeException if the size is negative or too large
* for the native size_t type
*
* @throws OutOfMemoryError if the allocation is refused by the system
*
* @see #allocateMemory
*/
public long reallocateMemory(long address, long bytes) {
reallocateMemoryChecks(address, bytes);
if (bytes == 0) {
freeMemory(address);
return 0;
}
long p = (address == 0) ? allocateMemory0(bytes) : reallocateMemory0(address, bytes);
if (p == 0) {
throw new OutOfMemoryError();
}
return p;
}
Validate the arguments to reallocateMemory
Throws: - RuntimeException – if the arguments are invalid
(Note: after optimization, invalid inputs may
go undetected, which will lead to unpredictable
behavior)
/**
* Validate the arguments to reallocateMemory
*
* @throws RuntimeException if the arguments are invalid
* (<em>Note:</em> after optimization, invalid inputs may
* go undetected, which will lead to unpredictable
* behavior)
*/
private void reallocateMemoryChecks(long address, long bytes) {
checkPointer(null, address);
checkSize(bytes);
}
Sets all bytes in a given block of memory to a fixed value
(usually zero).
This method determines a block's base address by means of two parameters,
and so it provides (in effect) a double-register addressing mode, as discussed in getInt(Object, long)
. When the object reference is null, the offset supplies an absolute base address.
The stores are in coherent (atomic) units of a size determined
by the address and length parameters. If the effective address and
length are all even modulo 8, the stores take place in 'long' units.
If the effective address and length are (resp.) even modulo 4 or 2,
the stores take place in units of 'int' or 'short'.
Note: It is the resposibility of the caller to make
sure arguments are checked before the methods are called. While
some rudimentary checks are performed on the input, the checks
are best effort and when performance is an overriding priority,
as when methods of this class are optimized by the runtime
compiler, some or all checks (if any) may be elided. Hence, the
caller must not rely on the checks and corresponding
exceptions!
Throws: - RuntimeException – if any of the arguments is invalid
Since: 1.7
/**
* Sets all bytes in a given block of memory to a fixed value
* (usually zero).
*
* <p>This method determines a block's base address by means of two parameters,
* and so it provides (in effect) a <em>double-register</em> addressing mode,
* as discussed in {@link #getInt(Object,long)}. When the object reference is null,
* the offset supplies an absolute base address.
*
* <p>The stores are in coherent (atomic) units of a size determined
* by the address and length parameters. If the effective address and
* length are all even modulo 8, the stores take place in 'long' units.
* If the effective address and length are (resp.) even modulo 4 or 2,
* the stores take place in units of 'int' or 'short'.
*
* <em>Note:</em> It is the resposibility of the caller to make
* sure arguments are checked before the methods are called. While
* some rudimentary checks are performed on the input, the checks
* are best effort and when performance is an overriding priority,
* as when methods of this class are optimized by the runtime
* compiler, some or all checks (if any) may be elided. Hence, the
* caller must not rely on the checks and corresponding
* exceptions!
*
* @throws RuntimeException if any of the arguments is invalid
*
* @since 1.7
*/
public void setMemory(Object o, long offset, long bytes, byte value) {
setMemoryChecks(o, offset, bytes, value);
if (bytes == 0) {
return;
}
setMemory0(o, offset, bytes, value);
}
Sets all bytes in a given block of memory to a fixed value
(usually zero). This provides a single-register addressing mode, as discussed in getInt(Object, long)
. Equivalent to setMemory(null, address, bytes, value)
.
/**
* Sets all bytes in a given block of memory to a fixed value
* (usually zero). This provides a <em>single-register</em> addressing mode,
* as discussed in {@link #getInt(Object,long)}.
*
* <p>Equivalent to {@code setMemory(null, address, bytes, value)}.
*/
public void setMemory(long address, long bytes, byte value) {
setMemory(null, address, bytes, value);
}
Validate the arguments to setMemory
Throws: - RuntimeException – if the arguments are invalid
(Note: after optimization, invalid inputs may
go undetected, which will lead to unpredictable
behavior)
/**
* Validate the arguments to setMemory
*
* @throws RuntimeException if the arguments are invalid
* (<em>Note:</em> after optimization, invalid inputs may
* go undetected, which will lead to unpredictable
* behavior)
*/
private void setMemoryChecks(Object o, long offset, long bytes, byte value) {
checkPrimitivePointer(o, offset);
checkSize(bytes);
}
Sets all bytes in a given block of memory to a copy of another
block.
This method determines each block's base address by means of two parameters,
and so it provides (in effect) a double-register addressing mode, as discussed in getInt(Object, long)
. When the object reference is null, the offset supplies an absolute base address.
The transfers are in coherent (atomic) units of a size determined
by the address and length parameters. If the effective addresses and
length are all even modulo 8, the transfer takes place in 'long' units.
If the effective addresses and length are (resp.) even modulo 4 or 2,
the transfer takes place in units of 'int' or 'short'.
Note: It is the resposibility of the caller to make
sure arguments are checked before the methods are called. While
some rudimentary checks are performed on the input, the checks
are best effort and when performance is an overriding priority,
as when methods of this class are optimized by the runtime
compiler, some or all checks (if any) may be elided. Hence, the
caller must not rely on the checks and corresponding
exceptions!
Throws: - RuntimeException – if any of the arguments is invalid
Since: 1.7
/**
* Sets all bytes in a given block of memory to a copy of another
* block.
*
* <p>This method determines each block's base address by means of two parameters,
* and so it provides (in effect) a <em>double-register</em> addressing mode,
* as discussed in {@link #getInt(Object,long)}. When the object reference is null,
* the offset supplies an absolute base address.
*
* <p>The transfers are in coherent (atomic) units of a size determined
* by the address and length parameters. If the effective addresses and
* length are all even modulo 8, the transfer takes place in 'long' units.
* If the effective addresses and length are (resp.) even modulo 4 or 2,
* the transfer takes place in units of 'int' or 'short'.
*
* <em>Note:</em> It is the resposibility of the caller to make
* sure arguments are checked before the methods are called. While
* some rudimentary checks are performed on the input, the checks
* are best effort and when performance is an overriding priority,
* as when methods of this class are optimized by the runtime
* compiler, some or all checks (if any) may be elided. Hence, the
* caller must not rely on the checks and corresponding
* exceptions!
*
* @throws RuntimeException if any of the arguments is invalid
*
* @since 1.7
*/
public void copyMemory(Object srcBase, long srcOffset,
Object destBase, long destOffset,
long bytes) {
copyMemoryChecks(srcBase, srcOffset, destBase, destOffset, bytes);
if (bytes == 0) {
return;
}
copyMemory0(srcBase, srcOffset, destBase, destOffset, bytes);
}
Sets all bytes in a given block of memory to a copy of another
block. This provides a single-register addressing mode, as discussed in getInt(Object, long)
. Equivalent to copyMemory(null, srcAddress, null, destAddress, bytes)
. /**
* Sets all bytes in a given block of memory to a copy of another
* block. This provides a <em>single-register</em> addressing mode,
* as discussed in {@link #getInt(Object,long)}.
*
* Equivalent to {@code copyMemory(null, srcAddress, null, destAddress, bytes)}.
*/
public void copyMemory(long srcAddress, long destAddress, long bytes) {
copyMemory(null, srcAddress, null, destAddress, bytes);
}
Validate the arguments to copyMemory
Throws: - RuntimeException – if any of the arguments is invalid
(Note: after optimization, invalid inputs may
go undetected, which will lead to unpredictable
behavior)
/**
* Validate the arguments to copyMemory
*
* @throws RuntimeException if any of the arguments is invalid
* (<em>Note:</em> after optimization, invalid inputs may
* go undetected, which will lead to unpredictable
* behavior)
*/
private void copyMemoryChecks(Object srcBase, long srcOffset,
Object destBase, long destOffset,
long bytes) {
checkSize(bytes);
checkPrimitivePointer(srcBase, srcOffset);
checkPrimitivePointer(destBase, destOffset);
}
Copies all elements from one block of memory to another block,
*unconditionally* byte swapping the elements on the fly.
This method determines each block's base address by means of two parameters,
and so it provides (in effect) a double-register addressing mode, as discussed in getInt(Object, long)
. When the object reference is null, the offset supplies an absolute base address. Note: It is the resposibility of the caller to make
sure arguments are checked before the methods are called. While
some rudimentary checks are performed on the input, the checks
are best effort and when performance is an overriding priority,
as when methods of this class are optimized by the runtime
compiler, some or all checks (if any) may be elided. Hence, the
caller must not rely on the checks and corresponding
exceptions!
Throws: - RuntimeException – if any of the arguments is invalid
Since: 9
/**
* Copies all elements from one block of memory to another block,
* *unconditionally* byte swapping the elements on the fly.
*
* <p>This method determines each block's base address by means of two parameters,
* and so it provides (in effect) a <em>double-register</em> addressing mode,
* as discussed in {@link #getInt(Object,long)}. When the object reference is null,
* the offset supplies an absolute base address.
*
* <em>Note:</em> It is the resposibility of the caller to make
* sure arguments are checked before the methods are called. While
* some rudimentary checks are performed on the input, the checks
* are best effort and when performance is an overriding priority,
* as when methods of this class are optimized by the runtime
* compiler, some or all checks (if any) may be elided. Hence, the
* caller must not rely on the checks and corresponding
* exceptions!
*
* @throws RuntimeException if any of the arguments is invalid
*
* @since 9
*/
public void copySwapMemory(Object srcBase, long srcOffset,
Object destBase, long destOffset,
long bytes, long elemSize) {
copySwapMemoryChecks(srcBase, srcOffset, destBase, destOffset, bytes, elemSize);
if (bytes == 0) {
return;
}
copySwapMemory0(srcBase, srcOffset, destBase, destOffset, bytes, elemSize);
}
private void copySwapMemoryChecks(Object srcBase, long srcOffset,
Object destBase, long destOffset,
long bytes, long elemSize) {
checkSize(bytes);
if (elemSize != 2 && elemSize != 4 && elemSize != 8) {
throw invalidInput();
}
if (bytes % elemSize != 0) {
throw invalidInput();
}
checkPrimitivePointer(srcBase, srcOffset);
checkPrimitivePointer(destBase, destOffset);
}
Copies all elements from one block of memory to another block, byte swapping the
elements on the fly.
This provides a single-register addressing mode, as discussed in getInt(Object, long)
. Equivalent to copySwapMemory(null, srcAddress, null, destAddress, bytes, elemSize)
. /**
* Copies all elements from one block of memory to another block, byte swapping the
* elements on the fly.
*
* This provides a <em>single-register</em> addressing mode, as
* discussed in {@link #getInt(Object,long)}.
*
* Equivalent to {@code copySwapMemory(null, srcAddress, null, destAddress, bytes, elemSize)}.
*/
public void copySwapMemory(long srcAddress, long destAddress, long bytes, long elemSize) {
copySwapMemory(null, srcAddress, null, destAddress, bytes, elemSize);
}
Disposes of a block of native memory, as obtained from allocateMemory
or reallocateMemory
. The address passed to this method may be null, in which case no action is taken. Note: It is the resposibility of the caller to make
sure arguments are checked before the methods are called. While
some rudimentary checks are performed on the input, the checks
are best effort and when performance is an overriding priority,
as when methods of this class are optimized by the runtime
compiler, some or all checks (if any) may be elided. Hence, the
caller must not rely on the checks and corresponding
exceptions!
Throws: - RuntimeException – if any of the arguments is invalid
See Also:
/**
* Disposes of a block of native memory, as obtained from {@link
* #allocateMemory} or {@link #reallocateMemory}. The address passed to
* this method may be null, in which case no action is taken.
*
* <em>Note:</em> It is the resposibility of the caller to make
* sure arguments are checked before the methods are called. While
* some rudimentary checks are performed on the input, the checks
* are best effort and when performance is an overriding priority,
* as when methods of this class are optimized by the runtime
* compiler, some or all checks (if any) may be elided. Hence, the
* caller must not rely on the checks and corresponding
* exceptions!
*
* @throws RuntimeException if any of the arguments is invalid
*
* @see #allocateMemory
*/
public void freeMemory(long address) {
freeMemoryChecks(address);
if (address == 0) {
return;
}
freeMemory0(address);
}
Validate the arguments to freeMemory
Throws: - RuntimeException – if the arguments are invalid
(Note: after optimization, invalid inputs may
go undetected, which will lead to unpredictable
behavior)
/**
* Validate the arguments to freeMemory
*
* @throws RuntimeException if the arguments are invalid
* (<em>Note:</em> after optimization, invalid inputs may
* go undetected, which will lead to unpredictable
* behavior)
*/
private void freeMemoryChecks(long address) {
checkPointer(null, address);
}
/// random queries
This constant differs from all results that will ever be returned from staticFieldOffset
, objectFieldOffset
, or arrayBaseOffset
. /**
* This constant differs from all results that will ever be returned from
* {@link #staticFieldOffset}, {@link #objectFieldOffset},
* or {@link #arrayBaseOffset}.
*/
public static final int INVALID_FIELD_OFFSET = -1;
Reports the location of a given field in the storage allocation of its
class. Do not expect to perform any sort of arithmetic on this offset;
it is just a cookie which is passed to the unsafe heap memory accessors.
Any given field will always have the same offset and base, and no
two distinct fields of the same class will ever have the same offset
and base.
As of 1.4.1, offsets for fields are represented as long values, although the Sun JVM does not use the most significant 32 bits. However, JVM implementations which store static fields at absolute addresses can use long offsets and null base pointers to express the field locations in a form usable by getInt(Object, long)
. Therefore, code which will be ported to such JVMs on 64-bit platforms must preserve all bits of static field offsets.
See Also:
/**
* Reports the location of a given field in the storage allocation of its
* class. Do not expect to perform any sort of arithmetic on this offset;
* it is just a cookie which is passed to the unsafe heap memory accessors.
*
* <p>Any given field will always have the same offset and base, and no
* two distinct fields of the same class will ever have the same offset
* and base.
*
* <p>As of 1.4.1, offsets for fields are represented as long values,
* although the Sun JVM does not use the most significant 32 bits.
* However, JVM implementations which store static fields at absolute
* addresses can use long offsets and null base pointers to express
* the field locations in a form usable by {@link #getInt(Object,long)}.
* Therefore, code which will be ported to such JVMs on 64-bit platforms
* must preserve all bits of static field offsets.
* @see #getInt(Object, long)
*/
public long objectFieldOffset(Field f) {
if (f == null) {
throw new NullPointerException();
}
return objectFieldOffset0(f);
}
Reports the location of the field with a given name in the storage
allocation of its class.
Throws: - NullPointerException – if any parameter is
null
. - InternalError – if there is no field named
name
declared in class c
, i.e., if c.getDeclaredField(name)
would throw java.lang.NoSuchFieldException
.
See Also:
/**
* Reports the location of the field with a given name in the storage
* allocation of its class.
*
* @throws NullPointerException if any parameter is {@code null}.
* @throws InternalError if there is no field named {@code name} declared
* in class {@code c}, i.e., if {@code c.getDeclaredField(name)}
* would throw {@code java.lang.NoSuchFieldException}.
*
* @see #objectFieldOffset(Field)
*/
public long objectFieldOffset(Class<?> c, String name) {
if (c == null || name == null) {
throw new NullPointerException();
}
return objectFieldOffset1(c, name);
}
Reports the location of a given static field, in conjunction with staticFieldBase
. Do not expect to perform any sort of arithmetic on this offset;
it is just a cookie which is passed to the unsafe heap memory accessors.
Any given field will always have the same offset, and no two distinct
fields of the same class will ever have the same offset.
As of 1.4.1, offsets for fields are represented as long values,
although the Sun JVM does not use the most significant 32 bits.
It is hard to imagine a JVM technology which needs more than
a few bits to encode an offset within a non-array object,
However, for consistency with other methods in this class,
this method reports its result as a long value.
See Also:
/**
* Reports the location of a given static field, in conjunction with {@link
* #staticFieldBase}.
* <p>Do not expect to perform any sort of arithmetic on this offset;
* it is just a cookie which is passed to the unsafe heap memory accessors.
*
* <p>Any given field will always have the same offset, and no two distinct
* fields of the same class will ever have the same offset.
*
* <p>As of 1.4.1, offsets for fields are represented as long values,
* although the Sun JVM does not use the most significant 32 bits.
* It is hard to imagine a JVM technology which needs more than
* a few bits to encode an offset within a non-array object,
* However, for consistency with other methods in this class,
* this method reports its result as a long value.
* @see #getInt(Object, long)
*/
public long staticFieldOffset(Field f) {
if (f == null) {
throw new NullPointerException();
}
return staticFieldOffset0(f);
}
Reports the location of a given static field, in conjunction with staticFieldOffset
. Fetch the base "Object", if any, with which static fields of the given class can be accessed via methods like getInt(Object, long)
. This value may be null. This value may refer to an object which is a "cookie", not guaranteed to be a real Object, and it should not be used in any way except as argument to the get and put routines in this class.
/**
* Reports the location of a given static field, in conjunction with {@link
* #staticFieldOffset}.
* <p>Fetch the base "Object", if any, with which static fields of the
* given class can be accessed via methods like {@link #getInt(Object,
* long)}. This value may be null. This value may refer to an object
* which is a "cookie", not guaranteed to be a real Object, and it should
* not be used in any way except as argument to the get and put routines in
* this class.
*/
public Object staticFieldBase(Field f) {
if (f == null) {
throw new NullPointerException();
}
return staticFieldBase0(f);
}
Detects if the given class may need to be initialized. This is often
needed in conjunction with obtaining the static field base of a
class.
Returns: false only if a call to ensureClassInitialized
would have no effect
/**
* Detects if the given class may need to be initialized. This is often
* needed in conjunction with obtaining the static field base of a
* class.
* @return false only if a call to {@code ensureClassInitialized} would have no effect
*/
public boolean shouldBeInitialized(Class<?> c) {
if (c == null) {
throw new NullPointerException();
}
return shouldBeInitialized0(c);
}
Ensures the given class has been initialized. This is often
needed in conjunction with obtaining the static field base of a
class.
/**
* Ensures the given class has been initialized. This is often
* needed in conjunction with obtaining the static field base of a
* class.
*/
public void ensureClassInitialized(Class<?> c) {
if (c == null) {
throw new NullPointerException();
}
ensureClassInitialized0(c);
}
Reports the offset of the first element in the storage allocation of a given array class. If arrayIndexScale
returns a non-zero value for the same class, you may use that scale factor, together with this base offset, to form new offsets to access elements of arrays of the given class. See Also:
/**
* Reports the offset of the first element in the storage allocation of a
* given array class. If {@link #arrayIndexScale} returns a non-zero value
* for the same class, you may use that scale factor, together with this
* base offset, to form new offsets to access elements of arrays of the
* given class.
*
* @see #getInt(Object, long)
* @see #putInt(Object, long, int)
*/
public int arrayBaseOffset(Class<?> arrayClass) {
if (arrayClass == null) {
throw new NullPointerException();
}
return arrayBaseOffset0(arrayClass);
}
The value of arrayBaseOffset(boolean[].class)
/** The value of {@code arrayBaseOffset(boolean[].class)} */
public static final int ARRAY_BOOLEAN_BASE_OFFSET
= theUnsafe.arrayBaseOffset(boolean[].class);
The value of arrayBaseOffset(byte[].class)
/** The value of {@code arrayBaseOffset(byte[].class)} */
public static final int ARRAY_BYTE_BASE_OFFSET
= theUnsafe.arrayBaseOffset(byte[].class);
The value of arrayBaseOffset(short[].class)
/** The value of {@code arrayBaseOffset(short[].class)} */
public static final int ARRAY_SHORT_BASE_OFFSET
= theUnsafe.arrayBaseOffset(short[].class);
The value of arrayBaseOffset(char[].class)
/** The value of {@code arrayBaseOffset(char[].class)} */
public static final int ARRAY_CHAR_BASE_OFFSET
= theUnsafe.arrayBaseOffset(char[].class);
The value of arrayBaseOffset(int[].class)
/** The value of {@code arrayBaseOffset(int[].class)} */
public static final int ARRAY_INT_BASE_OFFSET
= theUnsafe.arrayBaseOffset(int[].class);
The value of arrayBaseOffset(long[].class)
/** The value of {@code arrayBaseOffset(long[].class)} */
public static final int ARRAY_LONG_BASE_OFFSET
= theUnsafe.arrayBaseOffset(long[].class);
The value of arrayBaseOffset(float[].class)
/** The value of {@code arrayBaseOffset(float[].class)} */
public static final int ARRAY_FLOAT_BASE_OFFSET
= theUnsafe.arrayBaseOffset(float[].class);
The value of arrayBaseOffset(double[].class)
/** The value of {@code arrayBaseOffset(double[].class)} */
public static final int ARRAY_DOUBLE_BASE_OFFSET
= theUnsafe.arrayBaseOffset(double[].class);
The value of arrayBaseOffset(Object[].class)
/** The value of {@code arrayBaseOffset(Object[].class)} */
public static final int ARRAY_OBJECT_BASE_OFFSET
= theUnsafe.arrayBaseOffset(Object[].class);
Reports the scale factor for addressing elements in the storage allocation of a given array class. However, arrays of "narrow" types will generally not work properly with accessors like getByte(Object, long)
, so the scale factor for such classes is reported as zero. See Also:
/**
* Reports the scale factor for addressing elements in the storage
* allocation of a given array class. However, arrays of "narrow" types
* will generally not work properly with accessors like {@link
* #getByte(Object, long)}, so the scale factor for such classes is reported
* as zero.
*
* @see #arrayBaseOffset
* @see #getInt(Object, long)
* @see #putInt(Object, long, int)
*/
public int arrayIndexScale(Class<?> arrayClass) {
if (arrayClass == null) {
throw new NullPointerException();
}
return arrayIndexScale0(arrayClass);
}
The value of arrayIndexScale(boolean[].class)
/** The value of {@code arrayIndexScale(boolean[].class)} */
public static final int ARRAY_BOOLEAN_INDEX_SCALE
= theUnsafe.arrayIndexScale(boolean[].class);
The value of arrayIndexScale(byte[].class)
/** The value of {@code arrayIndexScale(byte[].class)} */
public static final int ARRAY_BYTE_INDEX_SCALE
= theUnsafe.arrayIndexScale(byte[].class);
The value of arrayIndexScale(short[].class)
/** The value of {@code arrayIndexScale(short[].class)} */
public static final int ARRAY_SHORT_INDEX_SCALE
= theUnsafe.arrayIndexScale(short[].class);
The value of arrayIndexScale(char[].class)
/** The value of {@code arrayIndexScale(char[].class)} */
public static final int ARRAY_CHAR_INDEX_SCALE
= theUnsafe.arrayIndexScale(char[].class);
The value of arrayIndexScale(int[].class)
/** The value of {@code arrayIndexScale(int[].class)} */
public static final int ARRAY_INT_INDEX_SCALE
= theUnsafe.arrayIndexScale(int[].class);
The value of arrayIndexScale(long[].class)
/** The value of {@code arrayIndexScale(long[].class)} */
public static final int ARRAY_LONG_INDEX_SCALE
= theUnsafe.arrayIndexScale(long[].class);
The value of arrayIndexScale(float[].class)
/** The value of {@code arrayIndexScale(float[].class)} */
public static final int ARRAY_FLOAT_INDEX_SCALE
= theUnsafe.arrayIndexScale(float[].class);
The value of arrayIndexScale(double[].class)
/** The value of {@code arrayIndexScale(double[].class)} */
public static final int ARRAY_DOUBLE_INDEX_SCALE
= theUnsafe.arrayIndexScale(double[].class);
The value of arrayIndexScale(Object[].class)
/** The value of {@code arrayIndexScale(Object[].class)} */
public static final int ARRAY_OBJECT_INDEX_SCALE
= theUnsafe.arrayIndexScale(Object[].class);
Reports the size in bytes of a native pointer, as stored via putAddress
. This value will be either 4 or 8. Note that the sizes of other primitive types (as stored in native memory blocks) is determined fully by their information content. /**
* Reports the size in bytes of a native pointer, as stored via {@link
* #putAddress}. This value will be either 4 or 8. Note that the sizes of
* other primitive types (as stored in native memory blocks) is determined
* fully by their information content.
*/
public int addressSize() {
return ADDRESS_SIZE;
}
The value of addressSize()
/** The value of {@code addressSize()} */
public static final int ADDRESS_SIZE = ADDRESS_SIZE0;
Reports the size in bytes of a native memory page (whatever that is).
This value will always be a power of two.
/**
* Reports the size in bytes of a native memory page (whatever that is).
* This value will always be a power of two.
*/
public int pageSize() { return PAGE_SIZE; }
/// random trusted operations from JNI:
Tells the VM to define a class, without security checks. By default, the
class loader and protection domain come from the caller's class.
/**
* Tells the VM to define a class, without security checks. By default, the
* class loader and protection domain come from the caller's class.
*/
public Class<?> defineClass(String name, byte[] b, int off, int len,
ClassLoader loader,
ProtectionDomain protectionDomain) {
if (b == null) {
throw new NullPointerException();
}
if (len < 0) {
throw new ArrayIndexOutOfBoundsException();
}
return defineClass0(name, b, off, len, loader, protectionDomain);
}
public native Class<?> defineClass0(String name, byte[] b, int off, int len,
ClassLoader loader,
ProtectionDomain protectionDomain);
Defines a class but does not make it known to the class loader or system dictionary.
For each CP entry, the corresponding CP patch must either be null or have
the a format that matches its tag:
- Integer, Long, Float, Double: the corresponding wrapper object type from java.lang
- Utf8: a string (must have suitable syntax if used as signature or name)
- Class: any java.lang.Class object
- String: any object (not just a java.lang.String)
- InterfaceMethodRef: (NYI) a method handle to invoke on that call site's arguments
Params: - hostClass – context for linkage, access control, protection domain, and class loader
- data – bytes of a class file
- cpPatches – where non-null entries exist, they replace corresponding CP entries in data
/**
* Defines a class but does not make it known to the class loader or system dictionary.
* <p>
* For each CP entry, the corresponding CP patch must either be null or have
* the a format that matches its tag:
* <ul>
* <li>Integer, Long, Float, Double: the corresponding wrapper object type from java.lang
* <li>Utf8: a string (must have suitable syntax if used as signature or name)
* <li>Class: any java.lang.Class object
* <li>String: any object (not just a java.lang.String)
* <li>InterfaceMethodRef: (NYI) a method handle to invoke on that call site's arguments
* </ul>
* @param hostClass context for linkage, access control, protection domain, and class loader
* @param data bytes of a class file
* @param cpPatches where non-null entries exist, they replace corresponding CP entries in data
*/
public Class<?> defineAnonymousClass(Class<?> hostClass, byte[] data, Object[] cpPatches) {
if (hostClass == null || data == null) {
throw new NullPointerException();
}
if (hostClass.isArray() || hostClass.isPrimitive()) {
throw new IllegalArgumentException();
}
return defineAnonymousClass0(hostClass, data, cpPatches);
}
Allocates an instance but does not run any constructor.
Initializes the class if it has not yet been.
/**
* Allocates an instance but does not run any constructor.
* Initializes the class if it has not yet been.
*/
@HotSpotIntrinsicCandidate
public native Object allocateInstance(Class<?> cls)
throws InstantiationException;
Allocates an array of a given type, but does not do zeroing.
This method should only be used in the very rare cases where a high-performance code
overwrites the destination array completely, and compilers cannot assist in zeroing elimination.
In an overwhelming majority of cases, a normal Java allocation should be used instead.
Users of this method are required to overwrite the initial (garbage) array contents
before allowing untrusted code, or code in other threads, to observe the reference
to the newly allocated array. In addition, the publication of the array reference must be
safe according to the Java Memory Model requirements.
The safest approach to deal with an uninitialized array is to keep the reference to it in local
variable at least until the initialization is complete, and then publish it once, either
by writing it to a volatile field, or storing it into a final field in constructor, or issuing a storeFence
before publishing the reference.
Params: - componentType – array component type to allocate
- length – array size to allocate
Throws: - IllegalArgumentException – if component type is null, or not a primitive class;
or the length is negative
@implnote This method can only allocate primitive arrays, to avoid garbage reference
elements that could break heap integrity.
/**
* Allocates an array of a given type, but does not do zeroing.
* <p>
* This method should only be used in the very rare cases where a high-performance code
* overwrites the destination array completely, and compilers cannot assist in zeroing elimination.
* In an overwhelming majority of cases, a normal Java allocation should be used instead.
* <p>
* Users of this method are <b>required</b> to overwrite the initial (garbage) array contents
* before allowing untrusted code, or code in other threads, to observe the reference
* to the newly allocated array. In addition, the publication of the array reference must be
* safe according to the Java Memory Model requirements.
* <p>
* The safest approach to deal with an uninitialized array is to keep the reference to it in local
* variable at least until the initialization is complete, and then publish it <b>once</b>, either
* by writing it to a <em>volatile</em> field, or storing it into a <em>final</em> field in constructor,
* or issuing a {@link #storeFence} before publishing the reference.
* <p>
* @implnote This method can only allocate primitive arrays, to avoid garbage reference
* elements that could break heap integrity.
*
* @param componentType array component type to allocate
* @param length array size to allocate
* @throws IllegalArgumentException if component type is null, or not a primitive class;
* or the length is negative
*/
public Object allocateUninitializedArray(Class<?> componentType, int length) {
if (componentType == null) {
throw new IllegalArgumentException("Component type is null");
}
if (!componentType.isPrimitive()) {
throw new IllegalArgumentException("Component type is not primitive");
}
if (length < 0) {
throw new IllegalArgumentException("Negative length");
}
return allocateUninitializedArray0(componentType, length);
}
@HotSpotIntrinsicCandidate
private Object allocateUninitializedArray0(Class<?> componentType, int length) {
// These fallbacks provide zeroed arrays, but intrinsic is not required to
// return the zeroed arrays.
if (componentType == byte.class) return new byte[length];
if (componentType == boolean.class) return new boolean[length];
if (componentType == short.class) return new short[length];
if (componentType == char.class) return new char[length];
if (componentType == int.class) return new int[length];
if (componentType == float.class) return new float[length];
if (componentType == long.class) return new long[length];
if (componentType == double.class) return new double[length];
return null;
}
Throws the exception without telling the verifier. /** Throws the exception without telling the verifier. */
public native void throwException(Throwable ee);
Atomically updates Java variable to x
if it is currently holding expected
. This operation has memory semantics of a volatile
read and write. Corresponds to C11 atomic_compare_exchange_strong.
Returns: true
if successful
/**
* Atomically updates Java variable to {@code x} if it is currently
* holding {@code expected}.
*
* <p>This operation has memory semantics of a {@code volatile} read
* and write. Corresponds to C11 atomic_compare_exchange_strong.
*
* @return {@code true} if successful
*/
@HotSpotIntrinsicCandidate
public final native boolean compareAndSetReference(Object o, long offset,
Object expected,
Object x);
@HotSpotIntrinsicCandidate
public final native Object compareAndExchangeReference(Object o, long offset,
Object expected,
Object x);
@HotSpotIntrinsicCandidate
public final Object compareAndExchangeReferenceAcquire(Object o, long offset,
Object expected,
Object x) {
return compareAndExchangeReference(o, offset, expected, x);
}
@HotSpotIntrinsicCandidate
public final Object compareAndExchangeReferenceRelease(Object o, long offset,
Object expected,
Object x) {
return compareAndExchangeReference(o, offset, expected, x);
}
@HotSpotIntrinsicCandidate
public final boolean weakCompareAndSetReferencePlain(Object o, long offset,
Object expected,
Object x) {
return compareAndSetReference(o, offset, expected, x);
}
@HotSpotIntrinsicCandidate
public final boolean weakCompareAndSetReferenceAcquire(Object o, long offset,
Object expected,
Object x) {
return compareAndSetReference(o, offset, expected, x);
}
@HotSpotIntrinsicCandidate
public final boolean weakCompareAndSetReferenceRelease(Object o, long offset,
Object expected,
Object x) {
return compareAndSetReference(o, offset, expected, x);
}
@HotSpotIntrinsicCandidate
public final boolean weakCompareAndSetReference(Object o, long offset,
Object expected,
Object x) {
return compareAndSetReference(o, offset, expected, x);
}
Atomically updates Java variable to x
if it is currently holding expected
. This operation has memory semantics of a volatile
read and write. Corresponds to C11 atomic_compare_exchange_strong.
Returns: true
if successful
/**
* Atomically updates Java variable to {@code x} if it is currently
* holding {@code expected}.
*
* <p>This operation has memory semantics of a {@code volatile} read
* and write. Corresponds to C11 atomic_compare_exchange_strong.
*
* @return {@code true} if successful
*/
@HotSpotIntrinsicCandidate
public final native boolean compareAndSetInt(Object o, long offset,
int expected,
int x);
@HotSpotIntrinsicCandidate
public final native int compareAndExchangeInt(Object o, long offset,
int expected,
int x);
@HotSpotIntrinsicCandidate
public final int compareAndExchangeIntAcquire(Object o, long offset,
int expected,
int x) {
return compareAndExchangeInt(o, offset, expected, x);
}
@HotSpotIntrinsicCandidate
public final int compareAndExchangeIntRelease(Object o, long offset,
int expected,
int x) {
return compareAndExchangeInt(o, offset, expected, x);
}
@HotSpotIntrinsicCandidate
public final boolean weakCompareAndSetIntPlain(Object o, long offset,
int expected,
int x) {
return compareAndSetInt(o, offset, expected, x);
}
@HotSpotIntrinsicCandidate
public final boolean weakCompareAndSetIntAcquire(Object o, long offset,
int expected,
int x) {
return compareAndSetInt(o, offset, expected, x);
}
@HotSpotIntrinsicCandidate
public final boolean weakCompareAndSetIntRelease(Object o, long offset,
int expected,
int x) {
return compareAndSetInt(o, offset, expected, x);
}
@HotSpotIntrinsicCandidate
public final boolean weakCompareAndSetInt(Object o, long offset,
int expected,
int x) {
return compareAndSetInt(o, offset, expected, x);
}
@HotSpotIntrinsicCandidate
public final byte compareAndExchangeByte(Object o, long offset,
byte expected,
byte x) {
long wordOffset = offset & ~3;
int shift = (int) (offset & 3) << 3;
if (BIG_ENDIAN) {
shift = 24 - shift;
}
int mask = 0xFF << shift;
int maskedExpected = (expected & 0xFF) << shift;
int maskedX = (x & 0xFF) << shift;
int fullWord;
do {
fullWord = getIntVolatile(o, wordOffset);
if ((fullWord & mask) != maskedExpected)
return (byte) ((fullWord & mask) >> shift);
} while (!weakCompareAndSetInt(o, wordOffset,
fullWord, (fullWord & ~mask) | maskedX));
return expected;
}
@HotSpotIntrinsicCandidate
public final boolean compareAndSetByte(Object o, long offset,
byte expected,
byte x) {
return compareAndExchangeByte(o, offset, expected, x) == expected;
}
@HotSpotIntrinsicCandidate
public final boolean weakCompareAndSetByte(Object o, long offset,
byte expected,
byte x) {
return compareAndSetByte(o, offset, expected, x);
}
@HotSpotIntrinsicCandidate
public final boolean weakCompareAndSetByteAcquire(Object o, long offset,
byte expected,
byte x) {
return weakCompareAndSetByte(o, offset, expected, x);
}
@HotSpotIntrinsicCandidate
public final boolean weakCompareAndSetByteRelease(Object o, long offset,
byte expected,
byte x) {
return weakCompareAndSetByte(o, offset, expected, x);
}
@HotSpotIntrinsicCandidate
public final boolean weakCompareAndSetBytePlain(Object o, long offset,
byte expected,
byte x) {
return weakCompareAndSetByte(o, offset, expected, x);
}
@HotSpotIntrinsicCandidate
public final byte compareAndExchangeByteAcquire(Object o, long offset,
byte expected,
byte x) {
return compareAndExchangeByte(o, offset, expected, x);
}
@HotSpotIntrinsicCandidate
public final byte compareAndExchangeByteRelease(Object o, long offset,
byte expected,
byte x) {
return compareAndExchangeByte(o, offset, expected, x);
}
@HotSpotIntrinsicCandidate
public final short compareAndExchangeShort(Object o, long offset,
short expected,
short x) {
if ((offset & 3) == 3) {
throw new IllegalArgumentException("Update spans the word, not supported");
}
long wordOffset = offset & ~3;
int shift = (int) (offset & 3) << 3;
if (BIG_ENDIAN) {
shift = 16 - shift;
}
int mask = 0xFFFF << shift;
int maskedExpected = (expected & 0xFFFF) << shift;
int maskedX = (x & 0xFFFF) << shift;
int fullWord;
do {
fullWord = getIntVolatile(o, wordOffset);
if ((fullWord & mask) != maskedExpected) {
return (short) ((fullWord & mask) >> shift);
}
} while (!weakCompareAndSetInt(o, wordOffset,
fullWord, (fullWord & ~mask) | maskedX));
return expected;
}
@HotSpotIntrinsicCandidate
public final boolean compareAndSetShort(Object o, long offset,
short expected,
short x) {
return compareAndExchangeShort(o, offset, expected, x) == expected;
}
@HotSpotIntrinsicCandidate
public final boolean weakCompareAndSetShort(Object o, long offset,
short expected,
short x) {
return compareAndSetShort(o, offset, expected, x);
}
@HotSpotIntrinsicCandidate
public final boolean weakCompareAndSetShortAcquire(Object o, long offset,
short expected,
short x) {
return weakCompareAndSetShort(o, offset, expected, x);
}
@HotSpotIntrinsicCandidate
public final boolean weakCompareAndSetShortRelease(Object o, long offset,
short expected,
short x) {
return weakCompareAndSetShort(o, offset, expected, x);
}
@HotSpotIntrinsicCandidate
public final boolean weakCompareAndSetShortPlain(Object o, long offset,
short expected,
short x) {
return weakCompareAndSetShort(o, offset, expected, x);
}
@HotSpotIntrinsicCandidate
public final short compareAndExchangeShortAcquire(Object o, long offset,
short expected,
short x) {
return compareAndExchangeShort(o, offset, expected, x);
}
@HotSpotIntrinsicCandidate
public final short compareAndExchangeShortRelease(Object o, long offset,
short expected,
short x) {
return compareAndExchangeShort(o, offset, expected, x);
}
@ForceInline
private char s2c(short s) {
return (char) s;
}
@ForceInline
private short c2s(char s) {
return (short) s;
}
@ForceInline
public final boolean compareAndSetChar(Object o, long offset,
char expected,
char x) {
return compareAndSetShort(o, offset, c2s(expected), c2s(x));
}
@ForceInline
public final char compareAndExchangeChar(Object o, long offset,
char expected,
char x) {
return s2c(compareAndExchangeShort(o, offset, c2s(expected), c2s(x)));
}
@ForceInline
public final char compareAndExchangeCharAcquire(Object o, long offset,
char expected,
char x) {
return s2c(compareAndExchangeShortAcquire(o, offset, c2s(expected), c2s(x)));
}
@ForceInline
public final char compareAndExchangeCharRelease(Object o, long offset,
char expected,
char x) {
return s2c(compareAndExchangeShortRelease(o, offset, c2s(expected), c2s(x)));
}
@ForceInline
public final boolean weakCompareAndSetChar(Object o, long offset,
char expected,
char x) {
return weakCompareAndSetShort(o, offset, c2s(expected), c2s(x));
}
@ForceInline
public final boolean weakCompareAndSetCharAcquire(Object o, long offset,
char expected,
char x) {
return weakCompareAndSetShortAcquire(o, offset, c2s(expected), c2s(x));
}
@ForceInline
public final boolean weakCompareAndSetCharRelease(Object o, long offset,
char expected,
char x) {
return weakCompareAndSetShortRelease(o, offset, c2s(expected), c2s(x));
}
@ForceInline
public final boolean weakCompareAndSetCharPlain(Object o, long offset,
char expected,
char x) {
return weakCompareAndSetShortPlain(o, offset, c2s(expected), c2s(x));
}
The JVM converts integral values to boolean values using two
different conventions, byte testing against zero and truncation
to least-significant bit.
The JNI documents specify that, at least for returning
values from native methods, a Java boolean value is converted
to the value-set 0..1 by first truncating to a byte (0..255 or
maybe -128..127) and then testing against zero. Thus, Java
booleans in non-Java data structures are by convention
represented as 8-bit containers containing either zero (for
false) or any non-zero value (for true).
Java booleans in the heap are also stored in bytes, but are
strongly normalized to the value-set 0..1 (i.e., they are
truncated to the least-significant bit).
The main reason for having different conventions for
conversion is performance: Truncation to the least-significant
bit can be usually implemented with fewer (machine)
instructions than byte testing against zero.
A number of Unsafe methods load boolean values from the heap as bytes. Unsafe converts those values according to the JNI rules (i.e, using the "testing against zero" convention). The method byte2bool
implements that conversion.
Params: - b – the byte to be converted to boolean
Returns: the result of the conversion
/**
* The JVM converts integral values to boolean values using two
* different conventions, byte testing against zero and truncation
* to least-significant bit.
*
* <p>The JNI documents specify that, at least for returning
* values from native methods, a Java boolean value is converted
* to the value-set 0..1 by first truncating to a byte (0..255 or
* maybe -128..127) and then testing against zero. Thus, Java
* booleans in non-Java data structures are by convention
* represented as 8-bit containers containing either zero (for
* false) or any non-zero value (for true).
*
* <p>Java booleans in the heap are also stored in bytes, but are
* strongly normalized to the value-set 0..1 (i.e., they are
* truncated to the least-significant bit).
*
* <p>The main reason for having different conventions for
* conversion is performance: Truncation to the least-significant
* bit can be usually implemented with fewer (machine)
* instructions than byte testing against zero.
*
* <p>A number of Unsafe methods load boolean values from the heap
* as bytes. Unsafe converts those values according to the JNI
* rules (i.e, using the "testing against zero" convention). The
* method {@code byte2bool} implements that conversion.
*
* @param b the byte to be converted to boolean
* @return the result of the conversion
*/
@ForceInline
private boolean byte2bool(byte b) {
return b != 0;
}
Convert a boolean value to a byte. The return value is strongly normalized to the value-set 0..1 (i.e., the value is truncated to the least-significant bit). See byte2bool(byte)
for more details on conversion conventions. Params: - b – the boolean to be converted to byte (and then normalized)
Returns: the result of the conversion
/**
* Convert a boolean value to a byte. The return value is strongly
* normalized to the value-set 0..1 (i.e., the value is truncated
* to the least-significant bit). See {@link #byte2bool(byte)} for
* more details on conversion conventions.
*
* @param b the boolean to be converted to byte (and then normalized)
* @return the result of the conversion
*/
@ForceInline
private byte bool2byte(boolean b) {
return b ? (byte)1 : (byte)0;
}
@ForceInline
public final boolean compareAndSetBoolean(Object o, long offset,
boolean expected,
boolean x) {
return compareAndSetByte(o, offset, bool2byte(expected), bool2byte(x));
}
@ForceInline
public final boolean compareAndExchangeBoolean(Object o, long offset,
boolean expected,
boolean x) {
return byte2bool(compareAndExchangeByte(o, offset, bool2byte(expected), bool2byte(x)));
}
@ForceInline
public final boolean compareAndExchangeBooleanAcquire(Object o, long offset,
boolean expected,
boolean x) {
return byte2bool(compareAndExchangeByteAcquire(o, offset, bool2byte(expected), bool2byte(x)));
}
@ForceInline
public final boolean compareAndExchangeBooleanRelease(Object o, long offset,
boolean expected,
boolean x) {
return byte2bool(compareAndExchangeByteRelease(o, offset, bool2byte(expected), bool2byte(x)));
}
@ForceInline
public final boolean weakCompareAndSetBoolean(Object o, long offset,
boolean expected,
boolean x) {
return weakCompareAndSetByte(o, offset, bool2byte(expected), bool2byte(x));
}
@ForceInline
public final boolean weakCompareAndSetBooleanAcquire(Object o, long offset,
boolean expected,
boolean x) {
return weakCompareAndSetByteAcquire(o, offset, bool2byte(expected), bool2byte(x));
}
@ForceInline
public final boolean weakCompareAndSetBooleanRelease(Object o, long offset,
boolean expected,
boolean x) {
return weakCompareAndSetByteRelease(o, offset, bool2byte(expected), bool2byte(x));
}
@ForceInline
public final boolean weakCompareAndSetBooleanPlain(Object o, long offset,
boolean expected,
boolean x) {
return weakCompareAndSetBytePlain(o, offset, bool2byte(expected), bool2byte(x));
}
Atomically updates Java variable to x
if it is currently holding expected
. This operation has memory semantics of a volatile
read and write. Corresponds to C11 atomic_compare_exchange_strong.
Returns: true
if successful
/**
* Atomically updates Java variable to {@code x} if it is currently
* holding {@code expected}.
*
* <p>This operation has memory semantics of a {@code volatile} read
* and write. Corresponds to C11 atomic_compare_exchange_strong.
*
* @return {@code true} if successful
*/
@ForceInline
public final boolean compareAndSetFloat(Object o, long offset,
float expected,
float x) {
return compareAndSetInt(o, offset,
Float.floatToRawIntBits(expected),
Float.floatToRawIntBits(x));
}
@ForceInline
public final float compareAndExchangeFloat(Object o, long offset,
float expected,
float x) {
int w = compareAndExchangeInt(o, offset,
Float.floatToRawIntBits(expected),
Float.floatToRawIntBits(x));
return Float.intBitsToFloat(w);
}
@ForceInline
public final float compareAndExchangeFloatAcquire(Object o, long offset,
float expected,
float x) {
int w = compareAndExchangeIntAcquire(o, offset,
Float.floatToRawIntBits(expected),
Float.floatToRawIntBits(x));
return Float.intBitsToFloat(w);
}
@ForceInline
public final float compareAndExchangeFloatRelease(Object o, long offset,
float expected,
float x) {
int w = compareAndExchangeIntRelease(o, offset,
Float.floatToRawIntBits(expected),
Float.floatToRawIntBits(x));
return Float.intBitsToFloat(w);
}
@ForceInline
public final boolean weakCompareAndSetFloatPlain(Object o, long offset,
float expected,
float x) {
return weakCompareAndSetIntPlain(o, offset,
Float.floatToRawIntBits(expected),
Float.floatToRawIntBits(x));
}
@ForceInline
public final boolean weakCompareAndSetFloatAcquire(Object o, long offset,
float expected,
float x) {
return weakCompareAndSetIntAcquire(o, offset,
Float.floatToRawIntBits(expected),
Float.floatToRawIntBits(x));
}
@ForceInline
public final boolean weakCompareAndSetFloatRelease(Object o, long offset,
float expected,
float x) {
return weakCompareAndSetIntRelease(o, offset,
Float.floatToRawIntBits(expected),
Float.floatToRawIntBits(x));
}
@ForceInline
public final boolean weakCompareAndSetFloat(Object o, long offset,
float expected,
float x) {
return weakCompareAndSetInt(o, offset,
Float.floatToRawIntBits(expected),
Float.floatToRawIntBits(x));
}
Atomically updates Java variable to x
if it is currently holding expected
. This operation has memory semantics of a volatile
read and write. Corresponds to C11 atomic_compare_exchange_strong.
Returns: true
if successful
/**
* Atomically updates Java variable to {@code x} if it is currently
* holding {@code expected}.
*
* <p>This operation has memory semantics of a {@code volatile} read
* and write. Corresponds to C11 atomic_compare_exchange_strong.
*
* @return {@code true} if successful
*/
@ForceInline
public final boolean compareAndSetDouble(Object o, long offset,
double expected,
double x) {
return compareAndSetLong(o, offset,
Double.doubleToRawLongBits(expected),
Double.doubleToRawLongBits(x));
}
@ForceInline
public final double compareAndExchangeDouble(Object o, long offset,
double expected,
double x) {
long w = compareAndExchangeLong(o, offset,
Double.doubleToRawLongBits(expected),
Double.doubleToRawLongBits(x));
return Double.longBitsToDouble(w);
}
@ForceInline
public final double compareAndExchangeDoubleAcquire(Object o, long offset,
double expected,
double x) {
long w = compareAndExchangeLongAcquire(o, offset,
Double.doubleToRawLongBits(expected),
Double.doubleToRawLongBits(x));
return Double.longBitsToDouble(w);
}
@ForceInline
public final double compareAndExchangeDoubleRelease(Object o, long offset,
double expected,
double x) {
long w = compareAndExchangeLongRelease(o, offset,
Double.doubleToRawLongBits(expected),
Double.doubleToRawLongBits(x));
return Double.longBitsToDouble(w);
}
@ForceInline
public final boolean weakCompareAndSetDoublePlain(Object o, long offset,
double expected,
double x) {
return weakCompareAndSetLongPlain(o, offset,
Double.doubleToRawLongBits(expected),
Double.doubleToRawLongBits(x));
}
@ForceInline
public final boolean weakCompareAndSetDoubleAcquire(Object o, long offset,
double expected,
double x) {
return weakCompareAndSetLongAcquire(o, offset,
Double.doubleToRawLongBits(expected),
Double.doubleToRawLongBits(x));
}
@ForceInline
public final boolean weakCompareAndSetDoubleRelease(Object o, long offset,
double expected,
double x) {
return weakCompareAndSetLongRelease(o, offset,
Double.doubleToRawLongBits(expected),
Double.doubleToRawLongBits(x));
}
@ForceInline
public final boolean weakCompareAndSetDouble(Object o, long offset,
double expected,
double x) {
return weakCompareAndSetLong(o, offset,
Double.doubleToRawLongBits(expected),
Double.doubleToRawLongBits(x));
}
Atomically updates Java variable to x
if it is currently holding expected
. This operation has memory semantics of a volatile
read and write. Corresponds to C11 atomic_compare_exchange_strong.
Returns: true
if successful
/**
* Atomically updates Java variable to {@code x} if it is currently
* holding {@code expected}.
*
* <p>This operation has memory semantics of a {@code volatile} read
* and write. Corresponds to C11 atomic_compare_exchange_strong.
*
* @return {@code true} if successful
*/
@HotSpotIntrinsicCandidate
public final native boolean compareAndSetLong(Object o, long offset,
long expected,
long x);
@HotSpotIntrinsicCandidate
public final native long compareAndExchangeLong(Object o, long offset,
long expected,
long x);
@HotSpotIntrinsicCandidate
public final long compareAndExchangeLongAcquire(Object o, long offset,
long expected,
long x) {
return compareAndExchangeLong(o, offset, expected, x);
}
@HotSpotIntrinsicCandidate
public final long compareAndExchangeLongRelease(Object o, long offset,
long expected,
long x) {
return compareAndExchangeLong(o, offset, expected, x);
}
@HotSpotIntrinsicCandidate
public final boolean weakCompareAndSetLongPlain(Object o, long offset,
long expected,
long x) {
return compareAndSetLong(o, offset, expected, x);
}
@HotSpotIntrinsicCandidate
public final boolean weakCompareAndSetLongAcquire(Object o, long offset,
long expected,
long x) {
return compareAndSetLong(o, offset, expected, x);
}
@HotSpotIntrinsicCandidate
public final boolean weakCompareAndSetLongRelease(Object o, long offset,
long expected,
long x) {
return compareAndSetLong(o, offset, expected, x);
}
@HotSpotIntrinsicCandidate
public final boolean weakCompareAndSetLong(Object o, long offset,
long expected,
long x) {
return compareAndSetLong(o, offset, expected, x);
}
Fetches a reference value from a given Java variable, with volatile load semantics. Otherwise identical to getReference(Object, long)
/**
* Fetches a reference value from a given Java variable, with volatile
* load semantics. Otherwise identical to {@link #getReference(Object, long)}
*/
@HotSpotIntrinsicCandidate
public native Object getReferenceVolatile(Object o, long offset);
Stores a reference value into a given Java variable, with volatile store semantics. Otherwise identical to putReference(Object, long, Object)
/**
* Stores a reference value into a given Java variable, with
* volatile store semantics. Otherwise identical to {@link #putReference(Object, long, Object)}
*/
@HotSpotIntrinsicCandidate
public native void putReferenceVolatile(Object o, long offset, Object x);
Volatile version of getInt(Object, long)
/** Volatile version of {@link #getInt(Object, long)} */
@HotSpotIntrinsicCandidate
public native int getIntVolatile(Object o, long offset);
Volatile version of putInt(Object, long, int)
/** Volatile version of {@link #putInt(Object, long, int)} */
@HotSpotIntrinsicCandidate
public native void putIntVolatile(Object o, long offset, int x);
Volatile version of getBoolean(Object, long)
/** Volatile version of {@link #getBoolean(Object, long)} */
@HotSpotIntrinsicCandidate
public native boolean getBooleanVolatile(Object o, long offset);
Volatile version of putBoolean(Object, long, boolean)
/** Volatile version of {@link #putBoolean(Object, long, boolean)} */
@HotSpotIntrinsicCandidate
public native void putBooleanVolatile(Object o, long offset, boolean x);
Volatile version of getByte(Object, long)
/** Volatile version of {@link #getByte(Object, long)} */
@HotSpotIntrinsicCandidate
public native byte getByteVolatile(Object o, long offset);
Volatile version of putByte(Object, long, byte)
/** Volatile version of {@link #putByte(Object, long, byte)} */
@HotSpotIntrinsicCandidate
public native void putByteVolatile(Object o, long offset, byte x);
Volatile version of getShort(Object, long)
/** Volatile version of {@link #getShort(Object, long)} */
@HotSpotIntrinsicCandidate
public native short getShortVolatile(Object o, long offset);
Volatile version of putShort(Object, long, short)
/** Volatile version of {@link #putShort(Object, long, short)} */
@HotSpotIntrinsicCandidate
public native void putShortVolatile(Object o, long offset, short x);
Volatile version of getChar(Object, long)
/** Volatile version of {@link #getChar(Object, long)} */
@HotSpotIntrinsicCandidate
public native char getCharVolatile(Object o, long offset);
Volatile version of putChar(Object, long, char)
/** Volatile version of {@link #putChar(Object, long, char)} */
@HotSpotIntrinsicCandidate
public native void putCharVolatile(Object o, long offset, char x);
Volatile version of getLong(Object, long)
/** Volatile version of {@link #getLong(Object, long)} */
@HotSpotIntrinsicCandidate
public native long getLongVolatile(Object o, long offset);
Volatile version of putLong(Object, long, long)
/** Volatile version of {@link #putLong(Object, long, long)} */
@HotSpotIntrinsicCandidate
public native void putLongVolatile(Object o, long offset, long x);
Volatile version of getFloat(Object, long)
/** Volatile version of {@link #getFloat(Object, long)} */
@HotSpotIntrinsicCandidate
public native float getFloatVolatile(Object o, long offset);
Volatile version of putFloat(Object, long, float)
/** Volatile version of {@link #putFloat(Object, long, float)} */
@HotSpotIntrinsicCandidate
public native void putFloatVolatile(Object o, long offset, float x);
Volatile version of getDouble(Object, long)
/** Volatile version of {@link #getDouble(Object, long)} */
@HotSpotIntrinsicCandidate
public native double getDoubleVolatile(Object o, long offset);
Volatile version of putDouble(Object, long, double)
/** Volatile version of {@link #putDouble(Object, long, double)} */
@HotSpotIntrinsicCandidate
public native void putDoubleVolatile(Object o, long offset, double x);
Acquire version of getReferenceVolatile(Object, long)
/** Acquire version of {@link #getReferenceVolatile(Object, long)} */
@HotSpotIntrinsicCandidate
public final Object getReferenceAcquire(Object o, long offset) {
return getReferenceVolatile(o, offset);
}
Acquire version of getBooleanVolatile(Object, long)
/** Acquire version of {@link #getBooleanVolatile(Object, long)} */
@HotSpotIntrinsicCandidate
public final boolean getBooleanAcquire(Object o, long offset) {
return getBooleanVolatile(o, offset);
}
Acquire version of getByteVolatile(Object, long)
/** Acquire version of {@link #getByteVolatile(Object, long)} */
@HotSpotIntrinsicCandidate
public final byte getByteAcquire(Object o, long offset) {
return getByteVolatile(o, offset);
}
Acquire version of getShortVolatile(Object, long)
/** Acquire version of {@link #getShortVolatile(Object, long)} */
@HotSpotIntrinsicCandidate
public final short getShortAcquire(Object o, long offset) {
return getShortVolatile(o, offset);
}
Acquire version of getCharVolatile(Object, long)
/** Acquire version of {@link #getCharVolatile(Object, long)} */
@HotSpotIntrinsicCandidate
public final char getCharAcquire(Object o, long offset) {
return getCharVolatile(o, offset);
}
Acquire version of getIntVolatile(Object, long)
/** Acquire version of {@link #getIntVolatile(Object, long)} */
@HotSpotIntrinsicCandidate
public final int getIntAcquire(Object o, long offset) {
return getIntVolatile(o, offset);
}
Acquire version of getFloatVolatile(Object, long)
/** Acquire version of {@link #getFloatVolatile(Object, long)} */
@HotSpotIntrinsicCandidate
public final float getFloatAcquire(Object o, long offset) {
return getFloatVolatile(o, offset);
}
Acquire version of getLongVolatile(Object, long)
/** Acquire version of {@link #getLongVolatile(Object, long)} */
@HotSpotIntrinsicCandidate
public final long getLongAcquire(Object o, long offset) {
return getLongVolatile(o, offset);
}
Acquire version of getDoubleVolatile(Object, long)
/** Acquire version of {@link #getDoubleVolatile(Object, long)} */
@HotSpotIntrinsicCandidate
public final double getDoubleAcquire(Object o, long offset) {
return getDoubleVolatile(o, offset);
}
/*
* Versions of {@link #putReferenceVolatile(Object, long, Object)}
* that do not guarantee immediate visibility of the store to
* other threads. This method is generally only useful if the
* underlying field is a Java volatile (or if an array cell, one
* that is otherwise only accessed using volatile accesses).
*
* Corresponds to C11 atomic_store_explicit(..., memory_order_release).
*/
Release version of putReferenceVolatile(Object, long, Object)
/** Release version of {@link #putReferenceVolatile(Object, long, Object)} */
@HotSpotIntrinsicCandidate
public final void putReferenceRelease(Object o, long offset, Object x) {
putReferenceVolatile(o, offset, x);
}
Release version of putBooleanVolatile(Object, long, boolean)
/** Release version of {@link #putBooleanVolatile(Object, long, boolean)} */
@HotSpotIntrinsicCandidate
public final void putBooleanRelease(Object o, long offset, boolean x) {
putBooleanVolatile(o, offset, x);
}
Release version of putByteVolatile(Object, long, byte)
/** Release version of {@link #putByteVolatile(Object, long, byte)} */
@HotSpotIntrinsicCandidate
public final void putByteRelease(Object o, long offset, byte x) {
putByteVolatile(o, offset, x);
}
Release version of putShortVolatile(Object, long, short)
/** Release version of {@link #putShortVolatile(Object, long, short)} */
@HotSpotIntrinsicCandidate
public final void putShortRelease(Object o, long offset, short x) {
putShortVolatile(o, offset, x);
}
Release version of putCharVolatile(Object, long, char)
/** Release version of {@link #putCharVolatile(Object, long, char)} */
@HotSpotIntrinsicCandidate
public final void putCharRelease(Object o, long offset, char x) {
putCharVolatile(o, offset, x);
}
Release version of putIntVolatile(Object, long, int)
/** Release version of {@link #putIntVolatile(Object, long, int)} */
@HotSpotIntrinsicCandidate
public final void putIntRelease(Object o, long offset, int x) {
putIntVolatile(o, offset, x);
}
Release version of putFloatVolatile(Object, long, float)
/** Release version of {@link #putFloatVolatile(Object, long, float)} */
@HotSpotIntrinsicCandidate
public final void putFloatRelease(Object o, long offset, float x) {
putFloatVolatile(o, offset, x);
}
Release version of putLongVolatile(Object, long, long)
/** Release version of {@link #putLongVolatile(Object, long, long)} */
@HotSpotIntrinsicCandidate
public final void putLongRelease(Object o, long offset, long x) {
putLongVolatile(o, offset, x);
}
Release version of putDoubleVolatile(Object, long, double)
/** Release version of {@link #putDoubleVolatile(Object, long, double)} */
@HotSpotIntrinsicCandidate
public final void putDoubleRelease(Object o, long offset, double x) {
putDoubleVolatile(o, offset, x);
}
// ------------------------------ Opaque --------------------------------------
Opaque version of getReferenceVolatile(Object, long)
/** Opaque version of {@link #getReferenceVolatile(Object, long)} */
@HotSpotIntrinsicCandidate
public final Object getReferenceOpaque(Object o, long offset) {
return getReferenceVolatile(o, offset);
}
Opaque version of getBooleanVolatile(Object, long)
/** Opaque version of {@link #getBooleanVolatile(Object, long)} */
@HotSpotIntrinsicCandidate
public final boolean getBooleanOpaque(Object o, long offset) {
return getBooleanVolatile(o, offset);
}
Opaque version of getByteVolatile(Object, long)
/** Opaque version of {@link #getByteVolatile(Object, long)} */
@HotSpotIntrinsicCandidate
public final byte getByteOpaque(Object o, long offset) {
return getByteVolatile(o, offset);
}
Opaque version of getShortVolatile(Object, long)
/** Opaque version of {@link #getShortVolatile(Object, long)} */
@HotSpotIntrinsicCandidate
public final short getShortOpaque(Object o, long offset) {
return getShortVolatile(o, offset);
}
Opaque version of getCharVolatile(Object, long)
/** Opaque version of {@link #getCharVolatile(Object, long)} */
@HotSpotIntrinsicCandidate
public final char getCharOpaque(Object o, long offset) {
return getCharVolatile(o, offset);
}
Opaque version of getIntVolatile(Object, long)
/** Opaque version of {@link #getIntVolatile(Object, long)} */
@HotSpotIntrinsicCandidate
public final int getIntOpaque(Object o, long offset) {
return getIntVolatile(o, offset);
}
Opaque version of getFloatVolatile(Object, long)
/** Opaque version of {@link #getFloatVolatile(Object, long)} */
@HotSpotIntrinsicCandidate
public final float getFloatOpaque(Object o, long offset) {
return getFloatVolatile(o, offset);
}
Opaque version of getLongVolatile(Object, long)
/** Opaque version of {@link #getLongVolatile(Object, long)} */
@HotSpotIntrinsicCandidate
public final long getLongOpaque(Object o, long offset) {
return getLongVolatile(o, offset);
}
Opaque version of getDoubleVolatile(Object, long)
/** Opaque version of {@link #getDoubleVolatile(Object, long)} */
@HotSpotIntrinsicCandidate
public final double getDoubleOpaque(Object o, long offset) {
return getDoubleVolatile(o, offset);
}
Opaque version of putReferenceVolatile(Object, long, Object)
/** Opaque version of {@link #putReferenceVolatile(Object, long, Object)} */
@HotSpotIntrinsicCandidate
public final void putReferenceOpaque(Object o, long offset, Object x) {
putReferenceVolatile(o, offset, x);
}
Opaque version of putBooleanVolatile(Object, long, boolean)
/** Opaque version of {@link #putBooleanVolatile(Object, long, boolean)} */
@HotSpotIntrinsicCandidate
public final void putBooleanOpaque(Object o, long offset, boolean x) {
putBooleanVolatile(o, offset, x);
}
Opaque version of putByteVolatile(Object, long, byte)
/** Opaque version of {@link #putByteVolatile(Object, long, byte)} */
@HotSpotIntrinsicCandidate
public final void putByteOpaque(Object o, long offset, byte x) {
putByteVolatile(o, offset, x);
}
Opaque version of putShortVolatile(Object, long, short)
/** Opaque version of {@link #putShortVolatile(Object, long, short)} */
@HotSpotIntrinsicCandidate
public final void putShortOpaque(Object o, long offset, short x) {
putShortVolatile(o, offset, x);
}
Opaque version of putCharVolatile(Object, long, char)
/** Opaque version of {@link #putCharVolatile(Object, long, char)} */
@HotSpotIntrinsicCandidate
public final void putCharOpaque(Object o, long offset, char x) {
putCharVolatile(o, offset, x);
}
Opaque version of putIntVolatile(Object, long, int)
/** Opaque version of {@link #putIntVolatile(Object, long, int)} */
@HotSpotIntrinsicCandidate
public final void putIntOpaque(Object o, long offset, int x) {
putIntVolatile(o, offset, x);
}
Opaque version of putFloatVolatile(Object, long, float)
/** Opaque version of {@link #putFloatVolatile(Object, long, float)} */
@HotSpotIntrinsicCandidate
public final void putFloatOpaque(Object o, long offset, float x) {
putFloatVolatile(o, offset, x);
}
Opaque version of putLongVolatile(Object, long, long)
/** Opaque version of {@link #putLongVolatile(Object, long, long)} */
@HotSpotIntrinsicCandidate
public final void putLongOpaque(Object o, long offset, long x) {
putLongVolatile(o, offset, x);
}
Opaque version of putDoubleVolatile(Object, long, double)
/** Opaque version of {@link #putDoubleVolatile(Object, long, double)} */
@HotSpotIntrinsicCandidate
public final void putDoubleOpaque(Object o, long offset, double x) {
putDoubleVolatile(o, offset, x);
}
Unblocks the given thread blocked on park
, or, if it is not blocked, causes the subsequent call to park
not to block. Note: this operation is "unsafe" solely because the caller must somehow ensure that the thread has not been destroyed. Nothing special is usually required to ensure this when called from Java (in which there will ordinarily be a live reference to the thread) but this is not nearly-automatically so when calling from native code. Params: - thread – the thread to unpark.
/**
* Unblocks the given thread blocked on {@code park}, or, if it is
* not blocked, causes the subsequent call to {@code park} not to
* block. Note: this operation is "unsafe" solely because the
* caller must somehow ensure that the thread has not been
* destroyed. Nothing special is usually required to ensure this
* when called from Java (in which there will ordinarily be a live
* reference to the thread) but this is not nearly-automatically
* so when calling from native code.
*
* @param thread the thread to unpark.
*/
@HotSpotIntrinsicCandidate
public native void unpark(Object thread);
Blocks current thread, returning when a balancing unpark
occurs, or a balancing unpark
has already occurred, or the thread is interrupted, or, if not absolute and time is not zero, the given time nanoseconds have elapsed, or if absolute, the given deadline in milliseconds since Epoch has passed, or spuriously (i.e., returning for no "reason"). Note: This operation is in the Unsafe class only because unpark
is, so it would be strange to place it elsewhere. /**
* Blocks current thread, returning when a balancing
* {@code unpark} occurs, or a balancing {@code unpark} has
* already occurred, or the thread is interrupted, or, if not
* absolute and time is not zero, the given time nanoseconds have
* elapsed, or if absolute, the given deadline in milliseconds
* since Epoch has passed, or spuriously (i.e., returning for no
* "reason"). Note: This operation is in the Unsafe class only
* because {@code unpark} is, so it would be strange to place it
* elsewhere.
*/
@HotSpotIntrinsicCandidate
public native void park(boolean isAbsolute, long time);
Gets the load average in the system run queue assigned to the available processors averaged over various periods of time. This method retrieves the given nelem
samples and assigns to the elements of the given loadavg
array. The system imposes a maximum of 3 samples, representing averages over the last 1, 5, and 15 minutes, respectively. Params: - loadavg – an array of double of size nelems
- nelems – the number of samples to be retrieved and
must be 1 to 3.
Returns: the number of samples actually retrieved; or -1
if the load average is unobtainable.
/**
* Gets the load average in the system run queue assigned
* to the available processors averaged over various periods of time.
* This method retrieves the given {@code nelem} samples and
* assigns to the elements of the given {@code loadavg} array.
* The system imposes a maximum of 3 samples, representing
* averages over the last 1, 5, and 15 minutes, respectively.
*
* @param loadavg an array of double of size nelems
* @param nelems the number of samples to be retrieved and
* must be 1 to 3.
*
* @return the number of samples actually retrieved; or -1
* if the load average is unobtainable.
*/
public int getLoadAverage(double[] loadavg, int nelems) {
if (nelems < 0 || nelems > 3 || nelems > loadavg.length) {
throw new ArrayIndexOutOfBoundsException();
}
return getLoadAverage0(loadavg, nelems);
}
// The following contain CAS-based Java implementations used on
// platforms not supporting native instructions
Atomically adds the given value to the current value of a field or array element within the given object o
at the given offset
. Params: - o – object/array to update the field/element in
- offset – field/element offset
- delta – the value to add
Returns: the previous value Since: 1.8
/**
* Atomically adds the given value to the current value of a field
* or array element within the given object {@code o}
* at the given {@code offset}.
*
* @param o object/array to update the field/element in
* @param offset field/element offset
* @param delta the value to add
* @return the previous value
* @since 1.8
*/
@HotSpotIntrinsicCandidate
public final int getAndAddInt(Object o, long offset, int delta) {
int v;
do {
v = getIntVolatile(o, offset);
} while (!weakCompareAndSetInt(o, offset, v, v + delta));
return v;
}
@ForceInline
public final int getAndAddIntRelease(Object o, long offset, int delta) {
int v;
do {
v = getInt(o, offset);
} while (!weakCompareAndSetIntRelease(o, offset, v, v + delta));
return v;
}
@ForceInline
public final int getAndAddIntAcquire(Object o, long offset, int delta) {
int v;
do {
v = getIntAcquire(o, offset);
} while (!weakCompareAndSetIntAcquire(o, offset, v, v + delta));
return v;
}
Atomically adds the given value to the current value of a field or array element within the given object o
at the given offset
. Params: - o – object/array to update the field/element in
- offset – field/element offset
- delta – the value to add
Returns: the previous value Since: 1.8
/**
* Atomically adds the given value to the current value of a field
* or array element within the given object {@code o}
* at the given {@code offset}.
*
* @param o object/array to update the field/element in
* @param offset field/element offset
* @param delta the value to add
* @return the previous value
* @since 1.8
*/
@HotSpotIntrinsicCandidate
public final long getAndAddLong(Object o, long offset, long delta) {
long v;
do {
v = getLongVolatile(o, offset);
} while (!weakCompareAndSetLong(o, offset, v, v + delta));
return v;
}
@ForceInline
public final long getAndAddLongRelease(Object o, long offset, long delta) {
long v;
do {
v = getLong(o, offset);
} while (!weakCompareAndSetLongRelease(o, offset, v, v + delta));
return v;
}
@ForceInline
public final long getAndAddLongAcquire(Object o, long offset, long delta) {
long v;
do {
v = getLongAcquire(o, offset);
} while (!weakCompareAndSetLongAcquire(o, offset, v, v + delta));
return v;
}
@HotSpotIntrinsicCandidate
public final byte getAndAddByte(Object o, long offset, byte delta) {
byte v;
do {
v = getByteVolatile(o, offset);
} while (!weakCompareAndSetByte(o, offset, v, (byte) (v + delta)));
return v;
}
@ForceInline
public final byte getAndAddByteRelease(Object o, long offset, byte delta) {
byte v;
do {
v = getByte(o, offset);
} while (!weakCompareAndSetByteRelease(o, offset, v, (byte) (v + delta)));
return v;
}
@ForceInline
public final byte getAndAddByteAcquire(Object o, long offset, byte delta) {
byte v;
do {
v = getByteAcquire(o, offset);
} while (!weakCompareAndSetByteAcquire(o, offset, v, (byte) (v + delta)));
return v;
}
@HotSpotIntrinsicCandidate
public final short getAndAddShort(Object o, long offset, short delta) {
short v;
do {
v = getShortVolatile(o, offset);
} while (!weakCompareAndSetShort(o, offset, v, (short) (v + delta)));
return v;
}
@ForceInline
public final short getAndAddShortRelease(Object o, long offset, short delta) {
short v;
do {
v = getShort(o, offset);
} while (!weakCompareAndSetShortRelease(o, offset, v, (short) (v + delta)));
return v;
}
@ForceInline
public final short getAndAddShortAcquire(Object o, long offset, short delta) {
short v;
do {
v = getShortAcquire(o, offset);
} while (!weakCompareAndSetShortAcquire(o, offset, v, (short) (v + delta)));
return v;
}
@ForceInline
public final char getAndAddChar(Object o, long offset, char delta) {
return (char) getAndAddShort(o, offset, (short) delta);
}
@ForceInline
public final char getAndAddCharRelease(Object o, long offset, char delta) {
return (char) getAndAddShortRelease(o, offset, (short) delta);
}
@ForceInline
public final char getAndAddCharAcquire(Object o, long offset, char delta) {
return (char) getAndAddShortAcquire(o, offset, (short) delta);
}
@ForceInline
public final float getAndAddFloat(Object o, long offset, float delta) {
int expectedBits;
float v;
do {
// Load and CAS with the raw bits to avoid issues with NaNs and
// possible bit conversion from signaling NaNs to quiet NaNs that
// may result in the loop not terminating.
expectedBits = getIntVolatile(o, offset);
v = Float.intBitsToFloat(expectedBits);
} while (!weakCompareAndSetInt(o, offset,
expectedBits, Float.floatToRawIntBits(v + delta)));
return v;
}
@ForceInline
public final float getAndAddFloatRelease(Object o, long offset, float delta) {
int expectedBits;
float v;
do {
// Load and CAS with the raw bits to avoid issues with NaNs and
// possible bit conversion from signaling NaNs to quiet NaNs that
// may result in the loop not terminating.
expectedBits = getInt(o, offset);
v = Float.intBitsToFloat(expectedBits);
} while (!weakCompareAndSetIntRelease(o, offset,
expectedBits, Float.floatToRawIntBits(v + delta)));
return v;
}
@ForceInline
public final float getAndAddFloatAcquire(Object o, long offset, float delta) {
int expectedBits;
float v;
do {
// Load and CAS with the raw bits to avoid issues with NaNs and
// possible bit conversion from signaling NaNs to quiet NaNs that
// may result in the loop not terminating.
expectedBits = getIntAcquire(o, offset);
v = Float.intBitsToFloat(expectedBits);
} while (!weakCompareAndSetIntAcquire(o, offset,
expectedBits, Float.floatToRawIntBits(v + delta)));
return v;
}
@ForceInline
public final double getAndAddDouble(Object o, long offset, double delta) {
long expectedBits;
double v;
do {
// Load and CAS with the raw bits to avoid issues with NaNs and
// possible bit conversion from signaling NaNs to quiet NaNs that
// may result in the loop not terminating.
expectedBits = getLongVolatile(o, offset);
v = Double.longBitsToDouble(expectedBits);
} while (!weakCompareAndSetLong(o, offset,
expectedBits, Double.doubleToRawLongBits(v + delta)));
return v;
}
@ForceInline
public final double getAndAddDoubleRelease(Object o, long offset, double delta) {
long expectedBits;
double v;
do {
// Load and CAS with the raw bits to avoid issues with NaNs and
// possible bit conversion from signaling NaNs to quiet NaNs that
// may result in the loop not terminating.
expectedBits = getLong(o, offset);
v = Double.longBitsToDouble(expectedBits);
} while (!weakCompareAndSetLongRelease(o, offset,
expectedBits, Double.doubleToRawLongBits(v + delta)));
return v;
}
@ForceInline
public final double getAndAddDoubleAcquire(Object o, long offset, double delta) {
long expectedBits;
double v;
do {
// Load and CAS with the raw bits to avoid issues with NaNs and
// possible bit conversion from signaling NaNs to quiet NaNs that
// may result in the loop not terminating.
expectedBits = getLongAcquire(o, offset);
v = Double.longBitsToDouble(expectedBits);
} while (!weakCompareAndSetLongAcquire(o, offset,
expectedBits, Double.doubleToRawLongBits(v + delta)));
return v;
}
Atomically exchanges the given value with the current value of a field or array element within the given object o
at the given offset
. Params: - o – object/array to update the field/element in
- offset – field/element offset
- newValue – new value
Returns: the previous value Since: 1.8
/**
* Atomically exchanges the given value with the current value of
* a field or array element within the given object {@code o}
* at the given {@code offset}.
*
* @param o object/array to update the field/element in
* @param offset field/element offset
* @param newValue new value
* @return the previous value
* @since 1.8
*/
@HotSpotIntrinsicCandidate
public final int getAndSetInt(Object o, long offset, int newValue) {
int v;
do {
v = getIntVolatile(o, offset);
} while (!weakCompareAndSetInt(o, offset, v, newValue));
return v;
}
@ForceInline
public final int getAndSetIntRelease(Object o, long offset, int newValue) {
int v;
do {
v = getInt(o, offset);
} while (!weakCompareAndSetIntRelease(o, offset, v, newValue));
return v;
}
@ForceInline
public final int getAndSetIntAcquire(Object o, long offset, int newValue) {
int v;
do {
v = getIntAcquire(o, offset);
} while (!weakCompareAndSetIntAcquire(o, offset, v, newValue));
return v;
}
Atomically exchanges the given value with the current value of a field or array element within the given object o
at the given offset
. Params: - o – object/array to update the field/element in
- offset – field/element offset
- newValue – new value
Returns: the previous value Since: 1.8
/**
* Atomically exchanges the given value with the current value of
* a field or array element within the given object {@code o}
* at the given {@code offset}.
*
* @param o object/array to update the field/element in
* @param offset field/element offset
* @param newValue new value
* @return the previous value
* @since 1.8
*/
@HotSpotIntrinsicCandidate
public final long getAndSetLong(Object o, long offset, long newValue) {
long v;
do {
v = getLongVolatile(o, offset);
} while (!weakCompareAndSetLong(o, offset, v, newValue));
return v;
}
@ForceInline
public final long getAndSetLongRelease(Object o, long offset, long newValue) {
long v;
do {
v = getLong(o, offset);
} while (!weakCompareAndSetLongRelease(o, offset, v, newValue));
return v;
}
@ForceInline
public final long getAndSetLongAcquire(Object o, long offset, long newValue) {
long v;
do {
v = getLongAcquire(o, offset);
} while (!weakCompareAndSetLongAcquire(o, offset, v, newValue));
return v;
}
Atomically exchanges the given reference value with the current reference value of a field or array element within the given object o
at the given offset
. Params: - o – object/array to update the field/element in
- offset – field/element offset
- newValue – new value
Returns: the previous value Since: 1.8
/**
* Atomically exchanges the given reference value with the current
* reference value of a field or array element within the given
* object {@code o} at the given {@code offset}.
*
* @param o object/array to update the field/element in
* @param offset field/element offset
* @param newValue new value
* @return the previous value
* @since 1.8
*/
@HotSpotIntrinsicCandidate
public final Object getAndSetReference(Object o, long offset, Object newValue) {
Object v;
do {
v = getReferenceVolatile(o, offset);
} while (!weakCompareAndSetReference(o, offset, v, newValue));
return v;
}
@ForceInline
public final Object getAndSetReferenceRelease(Object o, long offset, Object newValue) {
Object v;
do {
v = getReference(o, offset);
} while (!weakCompareAndSetReferenceRelease(o, offset, v, newValue));
return v;
}
@ForceInline
public final Object getAndSetReferenceAcquire(Object o, long offset, Object newValue) {
Object v;
do {
v = getReferenceAcquire(o, offset);
} while (!weakCompareAndSetReferenceAcquire(o, offset, v, newValue));
return v;
}
@HotSpotIntrinsicCandidate
public final byte getAndSetByte(Object o, long offset, byte newValue) {
byte v;
do {
v = getByteVolatile(o, offset);
} while (!weakCompareAndSetByte(o, offset, v, newValue));
return v;
}
@ForceInline
public final byte getAndSetByteRelease(Object o, long offset, byte newValue) {
byte v;
do {
v = getByte(o, offset);
} while (!weakCompareAndSetByteRelease(o, offset, v, newValue));
return v;
}
@ForceInline
public final byte getAndSetByteAcquire(Object o, long offset, byte newValue) {
byte v;
do {
v = getByteAcquire(o, offset);
} while (!weakCompareAndSetByteAcquire(o, offset, v, newValue));
return v;
}
@ForceInline
public final boolean getAndSetBoolean(Object o, long offset, boolean newValue) {
return byte2bool(getAndSetByte(o, offset, bool2byte(newValue)));
}
@ForceInline
public final boolean getAndSetBooleanRelease(Object o, long offset, boolean newValue) {
return byte2bool(getAndSetByteRelease(o, offset, bool2byte(newValue)));
}
@ForceInline
public final boolean getAndSetBooleanAcquire(Object o, long offset, boolean newValue) {
return byte2bool(getAndSetByteAcquire(o, offset, bool2byte(newValue)));
}
@HotSpotIntrinsicCandidate
public final short getAndSetShort(Object o, long offset, short newValue) {
short v;
do {
v = getShortVolatile(o, offset);
} while (!weakCompareAndSetShort(o, offset, v, newValue));
return v;
}
@ForceInline
public final short getAndSetShortRelease(Object o, long offset, short newValue) {
short v;
do {
v = getShort(o, offset);
} while (!weakCompareAndSetShortRelease(o, offset, v, newValue));
return v;
}
@ForceInline
public final short getAndSetShortAcquire(Object o, long offset, short newValue) {
short v;
do {
v = getShortAcquire(o, offset);
} while (!weakCompareAndSetShortAcquire(o, offset, v, newValue));
return v;
}
@ForceInline
public final char getAndSetChar(Object o, long offset, char newValue) {
return s2c(getAndSetShort(o, offset, c2s(newValue)));
}
@ForceInline
public final char getAndSetCharRelease(Object o, long offset, char newValue) {
return s2c(getAndSetShortRelease(o, offset, c2s(newValue)));
}
@ForceInline
public final char getAndSetCharAcquire(Object o, long offset, char newValue) {
return s2c(getAndSetShortAcquire(o, offset, c2s(newValue)));
}
@ForceInline
public final float getAndSetFloat(Object o, long offset, float newValue) {
int v = getAndSetInt(o, offset, Float.floatToRawIntBits(newValue));
return Float.intBitsToFloat(v);
}
@ForceInline
public final float getAndSetFloatRelease(Object o, long offset, float newValue) {
int v = getAndSetIntRelease(o, offset, Float.floatToRawIntBits(newValue));
return Float.intBitsToFloat(v);
}
@ForceInline
public final float getAndSetFloatAcquire(Object o, long offset, float newValue) {
int v = getAndSetIntAcquire(o, offset, Float.floatToRawIntBits(newValue));
return Float.intBitsToFloat(v);
}
@ForceInline
public final double getAndSetDouble(Object o, long offset, double newValue) {
long v = getAndSetLong(o, offset, Double.doubleToRawLongBits(newValue));
return Double.longBitsToDouble(v);
}
@ForceInline
public final double getAndSetDoubleRelease(Object o, long offset, double newValue) {
long v = getAndSetLongRelease(o, offset, Double.doubleToRawLongBits(newValue));
return Double.longBitsToDouble(v);
}
@ForceInline
public final double getAndSetDoubleAcquire(Object o, long offset, double newValue) {
long v = getAndSetLongAcquire(o, offset, Double.doubleToRawLongBits(newValue));
return Double.longBitsToDouble(v);
}
// The following contain CAS-based Java implementations used on
// platforms not supporting native instructions
@ForceInline
public final boolean getAndBitwiseOrBoolean(Object o, long offset, boolean mask) {
return byte2bool(getAndBitwiseOrByte(o, offset, bool2byte(mask)));
}
@ForceInline
public final boolean getAndBitwiseOrBooleanRelease(Object o, long offset, boolean mask) {
return byte2bool(getAndBitwiseOrByteRelease(o, offset, bool2byte(mask)));
}
@ForceInline
public final boolean getAndBitwiseOrBooleanAcquire(Object o, long offset, boolean mask) {
return byte2bool(getAndBitwiseOrByteAcquire(o, offset, bool2byte(mask)));
}
@ForceInline
public final boolean getAndBitwiseAndBoolean(Object o, long offset, boolean mask) {
return byte2bool(getAndBitwiseAndByte(o, offset, bool2byte(mask)));
}
@ForceInline
public final boolean getAndBitwiseAndBooleanRelease(Object o, long offset, boolean mask) {
return byte2bool(getAndBitwiseAndByteRelease(o, offset, bool2byte(mask)));
}
@ForceInline
public final boolean getAndBitwiseAndBooleanAcquire(Object o, long offset, boolean mask) {
return byte2bool(getAndBitwiseAndByteAcquire(o, offset, bool2byte(mask)));
}
@ForceInline
public final boolean getAndBitwiseXorBoolean(Object o, long offset, boolean mask) {
return byte2bool(getAndBitwiseXorByte(o, offset, bool2byte(mask)));
}
@ForceInline
public final boolean getAndBitwiseXorBooleanRelease(Object o, long offset, boolean mask) {
return byte2bool(getAndBitwiseXorByteRelease(o, offset, bool2byte(mask)));
}
@ForceInline
public final boolean getAndBitwiseXorBooleanAcquire(Object o, long offset, boolean mask) {
return byte2bool(getAndBitwiseXorByteAcquire(o, offset, bool2byte(mask)));
}
@ForceInline
public final byte getAndBitwiseOrByte(Object o, long offset, byte mask) {
byte current;
do {
current = getByteVolatile(o, offset);
} while (!weakCompareAndSetByte(o, offset,
current, (byte) (current | mask)));
return current;
}
@ForceInline
public final byte getAndBitwiseOrByteRelease(Object o, long offset, byte mask) {
byte current;
do {
current = getByte(o, offset);
} while (!weakCompareAndSetByteRelease(o, offset,
current, (byte) (current | mask)));
return current;
}
@ForceInline
public final byte getAndBitwiseOrByteAcquire(Object o, long offset, byte mask) {
byte current;
do {
// Plain read, the value is a hint, the acquire CAS does the work
current = getByte(o, offset);
} while (!weakCompareAndSetByteAcquire(o, offset,
current, (byte) (current | mask)));
return current;
}
@ForceInline
public final byte getAndBitwiseAndByte(Object o, long offset, byte mask) {
byte current;
do {
current = getByteVolatile(o, offset);
} while (!weakCompareAndSetByte(o, offset,
current, (byte) (current & mask)));
return current;
}
@ForceInline
public final byte getAndBitwiseAndByteRelease(Object o, long offset, byte mask) {
byte current;
do {
current = getByte(o, offset);
} while (!weakCompareAndSetByteRelease(o, offset,
current, (byte) (current & mask)));
return current;
}
@ForceInline
public final byte getAndBitwiseAndByteAcquire(Object o, long offset, byte mask) {
byte current;
do {
// Plain read, the value is a hint, the acquire CAS does the work
current = getByte(o, offset);
} while (!weakCompareAndSetByteAcquire(o, offset,
current, (byte) (current & mask)));
return current;
}
@ForceInline
public final byte getAndBitwiseXorByte(Object o, long offset, byte mask) {
byte current;
do {
current = getByteVolatile(o, offset);
} while (!weakCompareAndSetByte(o, offset,
current, (byte) (current ^ mask)));
return current;
}
@ForceInline
public final byte getAndBitwiseXorByteRelease(Object o, long offset, byte mask) {
byte current;
do {
current = getByte(o, offset);
} while (!weakCompareAndSetByteRelease(o, offset,
current, (byte) (current ^ mask)));
return current;
}
@ForceInline
public final byte getAndBitwiseXorByteAcquire(Object o, long offset, byte mask) {
byte current;
do {
// Plain read, the value is a hint, the acquire CAS does the work
current = getByte(o, offset);
} while (!weakCompareAndSetByteAcquire(o, offset,
current, (byte) (current ^ mask)));
return current;
}
@ForceInline
public final char getAndBitwiseOrChar(Object o, long offset, char mask) {
return s2c(getAndBitwiseOrShort(o, offset, c2s(mask)));
}
@ForceInline
public final char getAndBitwiseOrCharRelease(Object o, long offset, char mask) {
return s2c(getAndBitwiseOrShortRelease(o, offset, c2s(mask)));
}
@ForceInline
public final char getAndBitwiseOrCharAcquire(Object o, long offset, char mask) {
return s2c(getAndBitwiseOrShortAcquire(o, offset, c2s(mask)));
}
@ForceInline
public final char getAndBitwiseAndChar(Object o, long offset, char mask) {
return s2c(getAndBitwiseAndShort(o, offset, c2s(mask)));
}
@ForceInline
public final char getAndBitwiseAndCharRelease(Object o, long offset, char mask) {
return s2c(getAndBitwiseAndShortRelease(o, offset, c2s(mask)));
}
@ForceInline
public final char getAndBitwiseAndCharAcquire(Object o, long offset, char mask) {
return s2c(getAndBitwiseAndShortAcquire(o, offset, c2s(mask)));
}
@ForceInline
public final char getAndBitwiseXorChar(Object o, long offset, char mask) {
return s2c(getAndBitwiseXorShort(o, offset, c2s(mask)));
}
@ForceInline
public final char getAndBitwiseXorCharRelease(Object o, long offset, char mask) {
return s2c(getAndBitwiseXorShortRelease(o, offset, c2s(mask)));
}
@ForceInline
public final char getAndBitwiseXorCharAcquire(Object o, long offset, char mask) {
return s2c(getAndBitwiseXorShortAcquire(o, offset, c2s(mask)));
}
@ForceInline
public final short getAndBitwiseOrShort(Object o, long offset, short mask) {
short current;
do {
current = getShortVolatile(o, offset);
} while (!weakCompareAndSetShort(o, offset,
current, (short) (current | mask)));
return current;
}
@ForceInline
public final short getAndBitwiseOrShortRelease(Object o, long offset, short mask) {
short current;
do {
current = getShort(o, offset);
} while (!weakCompareAndSetShortRelease(o, offset,
current, (short) (current | mask)));
return current;
}
@ForceInline
public final short getAndBitwiseOrShortAcquire(Object o, long offset, short mask) {
short current;
do {
// Plain read, the value is a hint, the acquire CAS does the work
current = getShort(o, offset);
} while (!weakCompareAndSetShortAcquire(o, offset,
current, (short) (current | mask)));
return current;
}
@ForceInline
public final short getAndBitwiseAndShort(Object o, long offset, short mask) {
short current;
do {
current = getShortVolatile(o, offset);
} while (!weakCompareAndSetShort(o, offset,
current, (short) (current & mask)));
return current;
}
@ForceInline
public final short getAndBitwiseAndShortRelease(Object o, long offset, short mask) {
short current;
do {
current = getShort(o, offset);
} while (!weakCompareAndSetShortRelease(o, offset,
current, (short) (current & mask)));
return current;
}
@ForceInline
public final short getAndBitwiseAndShortAcquire(Object o, long offset, short mask) {
short current;
do {
// Plain read, the value is a hint, the acquire CAS does the work
current = getShort(o, offset);
} while (!weakCompareAndSetShortAcquire(o, offset,
current, (short) (current & mask)));
return current;
}
@ForceInline
public final short getAndBitwiseXorShort(Object o, long offset, short mask) {
short current;
do {
current = getShortVolatile(o, offset);
} while (!weakCompareAndSetShort(o, offset,
current, (short) (current ^ mask)));
return current;
}
@ForceInline
public final short getAndBitwiseXorShortRelease(Object o, long offset, short mask) {
short current;
do {
current = getShort(o, offset);
} while (!weakCompareAndSetShortRelease(o, offset,
current, (short) (current ^ mask)));
return current;
}
@ForceInline
public final short getAndBitwiseXorShortAcquire(Object o, long offset, short mask) {
short current;
do {
// Plain read, the value is a hint, the acquire CAS does the work
current = getShort(o, offset);
} while (!weakCompareAndSetShortAcquire(o, offset,
current, (short) (current ^ mask)));
return current;
}
@ForceInline
public final int getAndBitwiseOrInt(Object o, long offset, int mask) {
int current;
do {
current = getIntVolatile(o, offset);
} while (!weakCompareAndSetInt(o, offset,
current, current | mask));
return current;
}
@ForceInline
public final int getAndBitwiseOrIntRelease(Object o, long offset, int mask) {
int current;
do {
current = getInt(o, offset);
} while (!weakCompareAndSetIntRelease(o, offset,
current, current | mask));
return current;
}
@ForceInline
public final int getAndBitwiseOrIntAcquire(Object o, long offset, int mask) {
int current;
do {
// Plain read, the value is a hint, the acquire CAS does the work
current = getInt(o, offset);
} while (!weakCompareAndSetIntAcquire(o, offset,
current, current | mask));
return current;
}
Atomically replaces the current value of a field or array element within
the given object with the result of bitwise AND between the current value
and mask.
Params: - o – object/array to update the field/element in
- offset – field/element offset
- mask – the mask value
Returns: the previous value Since: 9
/**
* Atomically replaces the current value of a field or array element within
* the given object with the result of bitwise AND between the current value
* and mask.
*
* @param o object/array to update the field/element in
* @param offset field/element offset
* @param mask the mask value
* @return the previous value
* @since 9
*/
@ForceInline
public final int getAndBitwiseAndInt(Object o, long offset, int mask) {
int current;
do {
current = getIntVolatile(o, offset);
} while (!weakCompareAndSetInt(o, offset,
current, current & mask));
return current;
}
@ForceInline
public final int getAndBitwiseAndIntRelease(Object o, long offset, int mask) {
int current;
do {
current = getInt(o, offset);
} while (!weakCompareAndSetIntRelease(o, offset,
current, current & mask));
return current;
}
@ForceInline
public final int getAndBitwiseAndIntAcquire(Object o, long offset, int mask) {
int current;
do {
// Plain read, the value is a hint, the acquire CAS does the work
current = getInt(o, offset);
} while (!weakCompareAndSetIntAcquire(o, offset,
current, current & mask));
return current;
}
@ForceInline
public final int getAndBitwiseXorInt(Object o, long offset, int mask) {
int current;
do {
current = getIntVolatile(o, offset);
} while (!weakCompareAndSetInt(o, offset,
current, current ^ mask));
return current;
}
@ForceInline
public final int getAndBitwiseXorIntRelease(Object o, long offset, int mask) {
int current;
do {
current = getInt(o, offset);
} while (!weakCompareAndSetIntRelease(o, offset,
current, current ^ mask));
return current;
}
@ForceInline
public final int getAndBitwiseXorIntAcquire(Object o, long offset, int mask) {
int current;
do {
// Plain read, the value is a hint, the acquire CAS does the work
current = getInt(o, offset);
} while (!weakCompareAndSetIntAcquire(o, offset,
current, current ^ mask));
return current;
}
@ForceInline
public final long getAndBitwiseOrLong(Object o, long offset, long mask) {
long current;
do {
current = getLongVolatile(o, offset);
} while (!weakCompareAndSetLong(o, offset,
current, current | mask));
return current;
}
@ForceInline
public final long getAndBitwiseOrLongRelease(Object o, long offset, long mask) {
long current;
do {
current = getLong(o, offset);
} while (!weakCompareAndSetLongRelease(o, offset,
current, current | mask));
return current;
}
@ForceInline
public final long getAndBitwiseOrLongAcquire(Object o, long offset, long mask) {
long current;
do {
// Plain read, the value is a hint, the acquire CAS does the work
current = getLong(o, offset);
} while (!weakCompareAndSetLongAcquire(o, offset,
current, current | mask));
return current;
}
@ForceInline
public final long getAndBitwiseAndLong(Object o, long offset, long mask) {
long current;
do {
current = getLongVolatile(o, offset);
} while (!weakCompareAndSetLong(o, offset,
current, current & mask));
return current;
}
@ForceInline
public final long getAndBitwiseAndLongRelease(Object o, long offset, long mask) {
long current;
do {
current = getLong(o, offset);
} while (!weakCompareAndSetLongRelease(o, offset,
current, current & mask));
return current;
}
@ForceInline
public final long getAndBitwiseAndLongAcquire(Object o, long offset, long mask) {
long current;
do {
// Plain read, the value is a hint, the acquire CAS does the work
current = getLong(o, offset);
} while (!weakCompareAndSetLongAcquire(o, offset,
current, current & mask));
return current;
}
@ForceInline
public final long getAndBitwiseXorLong(Object o, long offset, long mask) {
long current;
do {
current = getLongVolatile(o, offset);
} while (!weakCompareAndSetLong(o, offset,
current, current ^ mask));
return current;
}
@ForceInline
public final long getAndBitwiseXorLongRelease(Object o, long offset, long mask) {
long current;
do {
current = getLong(o, offset);
} while (!weakCompareAndSetLongRelease(o, offset,
current, current ^ mask));
return current;
}
@ForceInline
public final long getAndBitwiseXorLongAcquire(Object o, long offset, long mask) {
long current;
do {
// Plain read, the value is a hint, the acquire CAS does the work
current = getLong(o, offset);
} while (!weakCompareAndSetLongAcquire(o, offset,
current, current ^ mask));
return current;
}
Ensures that loads before the fence will not be reordered with loads and
stores after the fence; a "LoadLoad plus LoadStore barrier".
Corresponds to C11 atomic_thread_fence(memory_order_acquire)
(an "acquire fence").
A pure LoadLoad fence is not provided, since the addition of LoadStore
is almost always desired, and most current hardware instructions that
provide a LoadLoad barrier also provide a LoadStore barrier for free.
Since: 1.8
/**
* Ensures that loads before the fence will not be reordered with loads and
* stores after the fence; a "LoadLoad plus LoadStore barrier".
*
* Corresponds to C11 atomic_thread_fence(memory_order_acquire)
* (an "acquire fence").
*
* A pure LoadLoad fence is not provided, since the addition of LoadStore
* is almost always desired, and most current hardware instructions that
* provide a LoadLoad barrier also provide a LoadStore barrier for free.
* @since 1.8
*/
@HotSpotIntrinsicCandidate
public native void loadFence();
Ensures that loads and stores before the fence will not be reordered with
stores after the fence; a "StoreStore plus LoadStore barrier".
Corresponds to C11 atomic_thread_fence(memory_order_release)
(a "release fence").
A pure StoreStore fence is not provided, since the addition of LoadStore
is almost always desired, and most current hardware instructions that
provide a StoreStore barrier also provide a LoadStore barrier for free.
Since: 1.8
/**
* Ensures that loads and stores before the fence will not be reordered with
* stores after the fence; a "StoreStore plus LoadStore barrier".
*
* Corresponds to C11 atomic_thread_fence(memory_order_release)
* (a "release fence").
*
* A pure StoreStore fence is not provided, since the addition of LoadStore
* is almost always desired, and most current hardware instructions that
* provide a StoreStore barrier also provide a LoadStore barrier for free.
* @since 1.8
*/
@HotSpotIntrinsicCandidate
public native void storeFence();
Ensures that loads and stores before the fence will not be reordered
with loads and stores after the fence. Implies the effects of both
loadFence() and storeFence(), and in addition, the effect of a StoreLoad
barrier.
Corresponds to C11 atomic_thread_fence(memory_order_seq_cst).
Since: 1.8
/**
* Ensures that loads and stores before the fence will not be reordered
* with loads and stores after the fence. Implies the effects of both
* loadFence() and storeFence(), and in addition, the effect of a StoreLoad
* barrier.
*
* Corresponds to C11 atomic_thread_fence(memory_order_seq_cst).
* @since 1.8
*/
@HotSpotIntrinsicCandidate
public native void fullFence();
Ensures that loads before the fence will not be reordered with
loads after the fence.
/**
* Ensures that loads before the fence will not be reordered with
* loads after the fence.
*/
public final void loadLoadFence() {
loadFence();
}
Ensures that stores before the fence will not be reordered with
stores after the fence.
/**
* Ensures that stores before the fence will not be reordered with
* stores after the fence.
*/
public final void storeStoreFence() {
storeFence();
}
Throws IllegalAccessError; for use by the VM for access control
error support.
Since: 1.8
/**
* Throws IllegalAccessError; for use by the VM for access control
* error support.
* @since 1.8
*/
private static void throwIllegalAccessError() {
throw new IllegalAccessError();
}
Throws NoSuchMethodError; for use by the VM for redefinition support.
Since: 13
/**
* Throws NoSuchMethodError; for use by the VM for redefinition support.
* @since 13
*/
private static void throwNoSuchMethodError() {
throw new NoSuchMethodError();
}
Returns: Returns true if the native byte ordering of this
platform is big-endian, false if it is little-endian.
/**
* @return Returns true if the native byte ordering of this
* platform is big-endian, false if it is little-endian.
*/
public final boolean isBigEndian() { return BIG_ENDIAN; }
Returns: Returns true if this platform is capable of performing
accesses at addresses which are not aligned for the type of the
primitive type being accessed, false otherwise.
/**
* @return Returns true if this platform is capable of performing
* accesses at addresses which are not aligned for the type of the
* primitive type being accessed, false otherwise.
*/
public final boolean unalignedAccess() { return UNALIGNED_ACCESS; }
Fetches a value at some byte offset into a given Java object.
More specifically, fetches a value within the given object
o
at the given offset, or (if o
is
null) from the memory address whose numerical value is the
given offset. The specification of this method is the same as getLong(Object, long)
except that the offset does not need to have been obtained from objectFieldOffset
on the Field
of some Java field. The value in memory is raw data, and need not correspond to any Java variable. Unless o
is null, the value accessed
must be entirely within the allocated object. The endianness
of the value in memory is the endianness of the native platform.
The read will be atomic with respect to the largest power
of two that divides the GCD of the offset and the storage size.
For example, getLongUnaligned will make atomic reads of 2-, 4-,
or 8-byte storage units if the offset is zero mod 2, 4, or 8,
respectively. There are no other guarantees of atomicity.
8-byte atomicity is only guaranteed on platforms on which
support atomic accesses to longs.
Params: - o – Java heap object in which the value resides, if any, else
null
- offset – The offset in bytes from the start of the object
Throws: - RuntimeException – No defined exceptions are thrown, not even
NullPointerException
Returns: the value fetched from the indicated object Since: 9
/**
* Fetches a value at some byte offset into a given Java object.
* More specifically, fetches a value within the given object
* <code>o</code> at the given offset, or (if <code>o</code> is
* null) from the memory address whose numerical value is the
* given offset. <p>
*
* The specification of this method is the same as {@link
* #getLong(Object, long)} except that the offset does not need to
* have been obtained from {@link #objectFieldOffset} on the
* {@link java.lang.reflect.Field} of some Java field. The value
* in memory is raw data, and need not correspond to any Java
* variable. Unless <code>o</code> is null, the value accessed
* must be entirely within the allocated object. The endianness
* of the value in memory is the endianness of the native platform.
*
* <p> The read will be atomic with respect to the largest power
* of two that divides the GCD of the offset and the storage size.
* For example, getLongUnaligned will make atomic reads of 2-, 4-,
* or 8-byte storage units if the offset is zero mod 2, 4, or 8,
* respectively. There are no other guarantees of atomicity.
* <p>
* 8-byte atomicity is only guaranteed on platforms on which
* support atomic accesses to longs.
*
* @param o Java heap object in which the value resides, if any, else
* null
* @param offset The offset in bytes from the start of the object
* @return the value fetched from the indicated object
* @throws RuntimeException No defined exceptions are thrown, not even
* {@link NullPointerException}
* @since 9
*/
@HotSpotIntrinsicCandidate
public final long getLongUnaligned(Object o, long offset) {
if ((offset & 7) == 0) {
return getLong(o, offset);
} else if ((offset & 3) == 0) {
return makeLong(getInt(o, offset),
getInt(o, offset + 4));
} else if ((offset & 1) == 0) {
return makeLong(getShort(o, offset),
getShort(o, offset + 2),
getShort(o, offset + 4),
getShort(o, offset + 6));
} else {
return makeLong(getByte(o, offset),
getByte(o, offset + 1),
getByte(o, offset + 2),
getByte(o, offset + 3),
getByte(o, offset + 4),
getByte(o, offset + 5),
getByte(o, offset + 6),
getByte(o, offset + 7));
}
}
As getLongUnaligned(Object, long)
but with an additional argument which specifies the endianness of the value as stored in memory. Params: - o – Java heap object in which the variable resides
- offset – The offset in bytes from the start of the object
- bigEndian – The endianness of the value
Returns: the value fetched from the indicated object Since: 9
/**
* As {@link #getLongUnaligned(Object, long)} but with an
* additional argument which specifies the endianness of the value
* as stored in memory.
*
* @param o Java heap object in which the variable resides
* @param offset The offset in bytes from the start of the object
* @param bigEndian The endianness of the value
* @return the value fetched from the indicated object
* @since 9
*/
public final long getLongUnaligned(Object o, long offset, boolean bigEndian) {
return convEndian(bigEndian, getLongUnaligned(o, offset));
}
See Also:
/** @see #getLongUnaligned(Object, long) */
@HotSpotIntrinsicCandidate
public final int getIntUnaligned(Object o, long offset) {
if ((offset & 3) == 0) {
return getInt(o, offset);
} else if ((offset & 1) == 0) {
return makeInt(getShort(o, offset),
getShort(o, offset + 2));
} else {
return makeInt(getByte(o, offset),
getByte(o, offset + 1),
getByte(o, offset + 2),
getByte(o, offset + 3));
}
}
See Also:
/** @see #getLongUnaligned(Object, long, boolean) */
public final int getIntUnaligned(Object o, long offset, boolean bigEndian) {
return convEndian(bigEndian, getIntUnaligned(o, offset));
}
See Also:
/** @see #getLongUnaligned(Object, long) */
@HotSpotIntrinsicCandidate
public final short getShortUnaligned(Object o, long offset) {
if ((offset & 1) == 0) {
return getShort(o, offset);
} else {
return makeShort(getByte(o, offset),
getByte(o, offset + 1));
}
}
See Also:
/** @see #getLongUnaligned(Object, long, boolean) */
public final short getShortUnaligned(Object o, long offset, boolean bigEndian) {
return convEndian(bigEndian, getShortUnaligned(o, offset));
}
See Also:
/** @see #getLongUnaligned(Object, long) */
@HotSpotIntrinsicCandidate
public final char getCharUnaligned(Object o, long offset) {
if ((offset & 1) == 0) {
return getChar(o, offset);
} else {
return (char)makeShort(getByte(o, offset),
getByte(o, offset + 1));
}
}
See Also:
/** @see #getLongUnaligned(Object, long, boolean) */
public final char getCharUnaligned(Object o, long offset, boolean bigEndian) {
return convEndian(bigEndian, getCharUnaligned(o, offset));
}
Stores a value at some byte offset into a given Java object.
The specification of this method is the same as getLong(Object, long)
except that the offset does not need to have been obtained from objectFieldOffset
on the Field
of some Java field. The value in memory is raw data, and need not correspond to any Java variable. The endianness of the value in memory is the endianness of the native platform.
The write will be atomic with respect to the largest power of
two that divides the GCD of the offset and the storage size.
For example, putLongUnaligned will make atomic writes of 2-, 4-,
or 8-byte storage units if the offset is zero mod 2, 4, or 8,
respectively. There are no other guarantees of atomicity.
8-byte atomicity is only guaranteed on platforms on which
support atomic accesses to longs.
Params: - o – Java heap object in which the value resides, if any, else
null
- offset – The offset in bytes from the start of the object
- x – the value to store
Throws: - RuntimeException – No defined exceptions are thrown, not even
NullPointerException
Since: 9
/**
* Stores a value at some byte offset into a given Java object.
* <p>
* The specification of this method is the same as {@link
* #getLong(Object, long)} except that the offset does not need to
* have been obtained from {@link #objectFieldOffset} on the
* {@link java.lang.reflect.Field} of some Java field. The value
* in memory is raw data, and need not correspond to any Java
* variable. The endianness of the value in memory is the
* endianness of the native platform.
* <p>
* The write will be atomic with respect to the largest power of
* two that divides the GCD of the offset and the storage size.
* For example, putLongUnaligned will make atomic writes of 2-, 4-,
* or 8-byte storage units if the offset is zero mod 2, 4, or 8,
* respectively. There are no other guarantees of atomicity.
* <p>
* 8-byte atomicity is only guaranteed on platforms on which
* support atomic accesses to longs.
*
* @param o Java heap object in which the value resides, if any, else
* null
* @param offset The offset in bytes from the start of the object
* @param x the value to store
* @throws RuntimeException No defined exceptions are thrown, not even
* {@link NullPointerException}
* @since 9
*/
@HotSpotIntrinsicCandidate
public final void putLongUnaligned(Object o, long offset, long x) {
if ((offset & 7) == 0) {
putLong(o, offset, x);
} else if ((offset & 3) == 0) {
putLongParts(o, offset,
(int)(x >> 0),
(int)(x >>> 32));
} else if ((offset & 1) == 0) {
putLongParts(o, offset,
(short)(x >>> 0),
(short)(x >>> 16),
(short)(x >>> 32),
(short)(x >>> 48));
} else {
putLongParts(o, offset,
(byte)(x >>> 0),
(byte)(x >>> 8),
(byte)(x >>> 16),
(byte)(x >>> 24),
(byte)(x >>> 32),
(byte)(x >>> 40),
(byte)(x >>> 48),
(byte)(x >>> 56));
}
}
As putLongUnaligned(Object, long, long)
but with an additional argument which specifies the endianness of the value as stored in memory. Params: - o – Java heap object in which the value resides
- offset – The offset in bytes from the start of the object
- x – the value to store
- bigEndian – The endianness of the value
Throws: - RuntimeException – No defined exceptions are thrown, not even
NullPointerException
Since: 9
/**
* As {@link #putLongUnaligned(Object, long, long)} but with an additional
* argument which specifies the endianness of the value as stored in memory.
* @param o Java heap object in which the value resides
* @param offset The offset in bytes from the start of the object
* @param x the value to store
* @param bigEndian The endianness of the value
* @throws RuntimeException No defined exceptions are thrown, not even
* {@link NullPointerException}
* @since 9
*/
public final void putLongUnaligned(Object o, long offset, long x, boolean bigEndian) {
putLongUnaligned(o, offset, convEndian(bigEndian, x));
}
See Also:
/** @see #putLongUnaligned(Object, long, long) */
@HotSpotIntrinsicCandidate
public final void putIntUnaligned(Object o, long offset, int x) {
if ((offset & 3) == 0) {
putInt(o, offset, x);
} else if ((offset & 1) == 0) {
putIntParts(o, offset,
(short)(x >> 0),
(short)(x >>> 16));
} else {
putIntParts(o, offset,
(byte)(x >>> 0),
(byte)(x >>> 8),
(byte)(x >>> 16),
(byte)(x >>> 24));
}
}
See Also:
/** @see #putLongUnaligned(Object, long, long, boolean) */
public final void putIntUnaligned(Object o, long offset, int x, boolean bigEndian) {
putIntUnaligned(o, offset, convEndian(bigEndian, x));
}
See Also:
/** @see #putLongUnaligned(Object, long, long) */
@HotSpotIntrinsicCandidate
public final void putShortUnaligned(Object o, long offset, short x) {
if ((offset & 1) == 0) {
putShort(o, offset, x);
} else {
putShortParts(o, offset,
(byte)(x >>> 0),
(byte)(x >>> 8));
}
}
See Also:
/** @see #putLongUnaligned(Object, long, long, boolean) */
public final void putShortUnaligned(Object o, long offset, short x, boolean bigEndian) {
putShortUnaligned(o, offset, convEndian(bigEndian, x));
}
See Also:
/** @see #putLongUnaligned(Object, long, long) */
@HotSpotIntrinsicCandidate
public final void putCharUnaligned(Object o, long offset, char x) {
putShortUnaligned(o, offset, (short)x);
}
See Also:
/** @see #putLongUnaligned(Object, long, long, boolean) */
public final void putCharUnaligned(Object o, long offset, char x, boolean bigEndian) {
putCharUnaligned(o, offset, convEndian(bigEndian, x));
}
private static int pickPos(int top, int pos) { return BIG_ENDIAN ? top - pos : pos; }
// These methods construct integers from bytes. The byte ordering
// is the native endianness of this platform.
private static long makeLong(byte i0, byte i1, byte i2, byte i3, byte i4, byte i5, byte i6, byte i7) {
return ((toUnsignedLong(i0) << pickPos(56, 0))
| (toUnsignedLong(i1) << pickPos(56, 8))
| (toUnsignedLong(i2) << pickPos(56, 16))
| (toUnsignedLong(i3) << pickPos(56, 24))
| (toUnsignedLong(i4) << pickPos(56, 32))
| (toUnsignedLong(i5) << pickPos(56, 40))
| (toUnsignedLong(i6) << pickPos(56, 48))
| (toUnsignedLong(i7) << pickPos(56, 56)));
}
private static long makeLong(short i0, short i1, short i2, short i3) {
return ((toUnsignedLong(i0) << pickPos(48, 0))
| (toUnsignedLong(i1) << pickPos(48, 16))
| (toUnsignedLong(i2) << pickPos(48, 32))
| (toUnsignedLong(i3) << pickPos(48, 48)));
}
private static long makeLong(int i0, int i1) {
return (toUnsignedLong(i0) << pickPos(32, 0))
| (toUnsignedLong(i1) << pickPos(32, 32));
}
private static int makeInt(short i0, short i1) {
return (toUnsignedInt(i0) << pickPos(16, 0))
| (toUnsignedInt(i1) << pickPos(16, 16));
}
private static int makeInt(byte i0, byte i1, byte i2, byte i3) {
return ((toUnsignedInt(i0) << pickPos(24, 0))
| (toUnsignedInt(i1) << pickPos(24, 8))
| (toUnsignedInt(i2) << pickPos(24, 16))
| (toUnsignedInt(i3) << pickPos(24, 24)));
}
private static short makeShort(byte i0, byte i1) {
return (short)((toUnsignedInt(i0) << pickPos(8, 0))
| (toUnsignedInt(i1) << pickPos(8, 8)));
}
private static byte pick(byte le, byte be) { return BIG_ENDIAN ? be : le; }
private static short pick(short le, short be) { return BIG_ENDIAN ? be : le; }
private static int pick(int le, int be) { return BIG_ENDIAN ? be : le; }
// These methods write integers to memory from smaller parts
// provided by their caller. The ordering in which these parts
// are written is the native endianness of this platform.
private void putLongParts(Object o, long offset, byte i0, byte i1, byte i2, byte i3, byte i4, byte i5, byte i6, byte i7) {
putByte(o, offset + 0, pick(i0, i7));
putByte(o, offset + 1, pick(i1, i6));
putByte(o, offset + 2, pick(i2, i5));
putByte(o, offset + 3, pick(i3, i4));
putByte(o, offset + 4, pick(i4, i3));
putByte(o, offset + 5, pick(i5, i2));
putByte(o, offset + 6, pick(i6, i1));
putByte(o, offset + 7, pick(i7, i0));
}
private void putLongParts(Object o, long offset, short i0, short i1, short i2, short i3) {
putShort(o, offset + 0, pick(i0, i3));
putShort(o, offset + 2, pick(i1, i2));
putShort(o, offset + 4, pick(i2, i1));
putShort(o, offset + 6, pick(i3, i0));
}
private void putLongParts(Object o, long offset, int i0, int i1) {
putInt(o, offset + 0, pick(i0, i1));
putInt(o, offset + 4, pick(i1, i0));
}
private void putIntParts(Object o, long offset, short i0, short i1) {
putShort(o, offset + 0, pick(i0, i1));
putShort(o, offset + 2, pick(i1, i0));
}
private void putIntParts(Object o, long offset, byte i0, byte i1, byte i2, byte i3) {
putByte(o, offset + 0, pick(i0, i3));
putByte(o, offset + 1, pick(i1, i2));
putByte(o, offset + 2, pick(i2, i1));
putByte(o, offset + 3, pick(i3, i0));
}
private void putShortParts(Object o, long offset, byte i0, byte i1) {
putByte(o, offset + 0, pick(i0, i1));
putByte(o, offset + 1, pick(i1, i0));
}
// Zero-extend an integer
private static int toUnsignedInt(byte n) { return n & 0xff; }
private static int toUnsignedInt(short n) { return n & 0xffff; }
private static long toUnsignedLong(byte n) { return n & 0xffl; }
private static long toUnsignedLong(short n) { return n & 0xffffl; }
private static long toUnsignedLong(int n) { return n & 0xffffffffl; }
// Maybe byte-reverse an integer
private static char convEndian(boolean big, char n) { return big == BIG_ENDIAN ? n : Character.reverseBytes(n); }
private static short convEndian(boolean big, short n) { return big == BIG_ENDIAN ? n : Short.reverseBytes(n) ; }
private static int convEndian(boolean big, int n) { return big == BIG_ENDIAN ? n : Integer.reverseBytes(n) ; }
private static long convEndian(boolean big, long n) { return big == BIG_ENDIAN ? n : Long.reverseBytes(n) ; }
private native long allocateMemory0(long bytes);
private native long reallocateMemory0(long address, long bytes);
private native void freeMemory0(long address);
private native void setMemory0(Object o, long offset, long bytes, byte value);
@HotSpotIntrinsicCandidate
private native void copyMemory0(Object srcBase, long srcOffset, Object destBase, long destOffset, long bytes);
private native void copySwapMemory0(Object srcBase, long srcOffset, Object destBase, long destOffset, long bytes, long elemSize);
private native long objectFieldOffset0(Field f);
private native long objectFieldOffset1(Class<?> c, String name);
private native long staticFieldOffset0(Field f);
private native Object staticFieldBase0(Field f);
private native boolean shouldBeInitialized0(Class<?> c);
private native void ensureClassInitialized0(Class<?> c);
private native int arrayBaseOffset0(Class<?> arrayClass);
private native int arrayIndexScale0(Class<?> arrayClass);
private native Class<?> defineAnonymousClass0(Class<?> hostClass, byte[] data, Object[] cpPatches);
private native int getLoadAverage0(double[] loadavg, int nelems);
Invokes the given direct byte buffer's cleaner, if any.
Params: - directBuffer – a direct byte buffer
Throws: - NullPointerException – if
directBuffer
is null - IllegalArgumentException – if
directBuffer
is non-direct, or is a slice
, or is a duplicate
/**
* Invokes the given direct byte buffer's cleaner, if any.
*
* @param directBuffer a direct byte buffer
* @throws NullPointerException if {@code directBuffer} is null
* @throws IllegalArgumentException if {@code directBuffer} is non-direct,
* or is a {@link java.nio.Buffer#slice slice}, or is a
* {@link java.nio.Buffer#duplicate duplicate}
*/
public void invokeCleaner(java.nio.ByteBuffer directBuffer) {
if (!directBuffer.isDirect())
throw new IllegalArgumentException("buffer is non-direct");
DirectBuffer db = (DirectBuffer) directBuffer;
if (db.attachment() != null)
throw new IllegalArgumentException("duplicate or slice");
Cleaner cleaner = db.cleaner();
if (cleaner != null) {
cleaner.clean();
}
}
// The following deprecated methods are used by JSR 166.
@Deprecated(since="12", forRemoval=true)
public final Object getObject(Object o, long offset) {
return getReference(o, offset);
}
@Deprecated(since="12", forRemoval=true)
public final Object getObjectVolatile(Object o, long offset) {
return getReferenceVolatile(o, offset);
}
@Deprecated(since="12", forRemoval=true)
public final Object getObjectAcquire(Object o, long offset) {
return getReferenceAcquire(o, offset);
}
@Deprecated(since="12", forRemoval=true)
public final Object getObjectOpaque(Object o, long offset) {
return getReferenceOpaque(o, offset);
}
@Deprecated(since="12", forRemoval=true)
public final void putObject(Object o, long offset, Object x) {
putReference(o, offset, x);
}
@Deprecated(since="12", forRemoval=true)
public final void putObjectVolatile(Object o, long offset, Object x) {
putReferenceVolatile(o, offset, x);
}
@Deprecated(since="12", forRemoval=true)
public final void putObjectOpaque(Object o, long offset, Object x) {
putReferenceOpaque(o, offset, x);
}
@Deprecated(since="12", forRemoval=true)
public final void putObjectRelease(Object o, long offset, Object x) {
putReferenceRelease(o, offset, x);
}
@Deprecated(since="12", forRemoval=true)
public final Object getAndSetObject(Object o, long offset, Object newValue) {
return getAndSetReference(o, offset, newValue);
}
@Deprecated(since="12", forRemoval=true)
public final Object getAndSetObjectAcquire(Object o, long offset, Object newValue) {
return getAndSetReferenceAcquire(o, offset, newValue);
}
@Deprecated(since="12", forRemoval=true)
public final Object getAndSetObjectRelease(Object o, long offset, Object newValue) {
return getAndSetReferenceRelease(o, offset, newValue);
}
@Deprecated(since="12", forRemoval=true)
public final boolean compareAndSetObject(Object o, long offset, Object expected, Object x) {
return compareAndSetReference(o, offset, expected, x);
}
@Deprecated(since="12", forRemoval=true)
public final Object compareAndExchangeObject(Object o, long offset, Object expected, Object x) {
return compareAndExchangeReference(o, offset, expected, x);
}
@Deprecated(since="12", forRemoval=true)
public final Object compareAndExchangeObjectAcquire(Object o, long offset, Object expected, Object x) {
return compareAndExchangeReferenceAcquire(o, offset, expected, x);
}
@Deprecated(since="12", forRemoval=true)
public final Object compareAndExchangeObjectRelease(Object o, long offset, Object expected, Object x) {
return compareAndExchangeReferenceRelease(o, offset, expected, x);
}
@Deprecated(since="12", forRemoval=true)
public final boolean weakCompareAndSetObject(Object o, long offset, Object expected, Object x) {
return weakCompareAndSetReference(o, offset, expected, x);
}
@Deprecated(since="12", forRemoval=true)
public final boolean weakCompareAndSetObjectAcquire(Object o, long offset, Object expected, Object x) {
return weakCompareAndSetReferenceAcquire(o, offset, expected, x);
}
@Deprecated(since="12", forRemoval=true)
public final boolean weakCompareAndSetObjectPlain(Object o, long offset, Object expected, Object x) {
return weakCompareAndSetReferencePlain(o, offset, expected, x);
}
@Deprecated(since="12", forRemoval=true)
public final boolean weakCompareAndSetObjectRelease(Object o, long offset, Object expected, Object x) {
return weakCompareAndSetReferenceRelease(o, offset, expected, x);
}
}