A small toolkit of classes that support lock-free thread-safe
programming on single variables. In essence, the classes in this
package extend the notion of volatile values, fields, and
array elements to those that also provide an atomic conditional update
operation of the form:
This method (which varies in argument types across different
classes) atomically sets a variable to the updateValue if it
currently holds the expectedValue, reporting true on
success. The classes in this package also contain methods to get and
unconditionally set values, as well as a weaker conditional atomic
update operation weakCompareAndSet. The weak version may be
more efficient in the normal case, but differs in that any given
invocation of weakCompareAndSet method may fail, even
spuriously (that is, for no apparent reason). A false return
means only that the operation may be retried if desired, relying on
the guarantee that repeated invocation when the variable holds
expectedValue and no other thread is also attempting to set
the variable will eventually succeed.
The specifications of these methods enable implementations to
employ efficient machine-level atomic instructions that are available
on contemporary processors. However on some platforms, support may
entail some form of internal locking. Thus the methods are not
strictly guaranteed to be non-blocking --
a thread may block transiently before performing the operation.
Instances of classes AtomicBoolean , AtomicInteger , AtomicLong , and AtomicReference each provide access and
updates to a single variable of the corresponding type. Each class
also provides appropriate utility methods for that type. For example,
classes AtomicLong and AtomicInteger provide atomic
increment methods. One application is to generate sequence numbers,
as in:
class Sequencer {
private AtomicLong sequenceNumber = new AtomicLong(0);
public long next() { return sequenceNumber.getAndIncrement(); }
}
get has the memory effects of reading a
volatile variable.
set has the memory effects of writing (assigning) a
volatile variable.
lazySet has the memory effects of writing (assigning)
a volatile variable except that it permits reorderings with
subsequent (but not previous) memory actions that do not themselves
impose reordering constraints with ordinary non-volatile
writes. Among other usage contexts, lazySet may apply when
nulling out, for the sake of garbage collection, a reference that is
never accessed again.
weakCompareAndSet atomically reads and conditionally
writes a variable, is ordered with respect to other
memory operations on that variable, but otherwise acts as an
ordinary non-volatile memory operation.
compareAndSet
and all other read-and-update operations such as getAndIncrement
have the memory effects of both reading and
writing volatile variables.
The AtomicIntegerArray , AtomicLongArray , and AtomicReferenceArray classes further
extend atomic operation support to arrays of these types. These
classes are also notable in providing volatile access
semantics for their array elements, which is not supported for
ordinary arrays.
The AtomicMarkableReference
class associates a single boolean with a reference. For example, this
bit might be used inside a data structure to mean that the object
being referenced has logically been deleted. The AtomicStampedReference class associates
an integer value with a reference. This may be used for example, to
represent version numbers corresponding to series of updates.
Atomic classes are designed primarily as building blocks for
implementing non-blocking data structures and related infrastructure
classes. The compareAndSet method is not a general
replacement for locking. It applies only when critical updates for an
object are confined to a single variable.
Atomic classes are not general purpose replacements for
java.lang.Integer and related classes. They do not
define methods such as hashCode and
compareTo. (Because atomic variables are expected to be
mutated, they are poor choices for hash table keys.) Additionally,
classes are provided only for those types that are commonly useful in
intended applications. For example, there is no atomic class for
representing byte. In those infrequent cases where you would
like to do so, you can use an AtomicInteger to hold
byte values, and cast appropriately. You can also hold floats
using Float.floatToIntBits and Float.intBitstoFloat
conversions, and doubles using Double.doubleToLongBits and
Double.longBitsToDouble conversions.
This method (which varies in argument types across different classes) atomically sets a variable to the updateValue if it currently holds the expectedValue, reporting true on success. The classes in this package also contain methods to get and unconditionally set values, as well as a weaker conditional atomic update operation weakCompareAndSet. The weak version may be more efficient in the normal case, but differs in that any given invocation of weakCompareAndSet method may fail, even spuriously (that is, for no apparent reason). A false return means only that the operation may be retried if desired, relying on the guarantee that repeated invocation when the variable holds expectedValue and no other thread is also attempting to set the variable will eventually succeed.
The specifications of these methods enable implementations to employ efficient machine-level atomic instructions that are available on contemporary processors. However on some platforms, support may entail some form of internal locking. Thus the methods are not strictly guaranteed to be non-blocking -- a thread may block transiently before performing the operation.
Instances of classes AtomicBoolean , AtomicInteger , AtomicLong , and AtomicReference each provide access and updates to a single variable of the corresponding type. Each class also provides appropriate utility methods for that type. For example, classes AtomicLong and AtomicInteger provide atomic increment methods. One application is to generate sequence numbers, as in:
class Sequencer { private AtomicLong sequenceNumber = new AtomicLong(0); public long next() { return sequenceNumber.getAndIncrement(); } }The memory effects for accesses and updates of atomics generally follow the rules for volatiles, as stated in The Java Language Specification, Third Edition (17.4 Memory Model):
The AtomicIntegerArray , AtomicLongArray , and AtomicReferenceArray classes further extend atomic operation support to arrays of these types. These classes are also notable in providing volatile access semantics for their array elements, which is not supported for ordinary arrays.
The AtomicMarkableReference class associates a single boolean with a reference. For example, this bit might be used inside a data structure to mean that the object being referenced has logically been deleted. The AtomicStampedReference class associates an integer value with a reference. This may be used for example, to represent version numbers corresponding to series of updates.
Atomic classes are designed primarily as building blocks for implementing non-blocking data structures and related infrastructure classes. The compareAndSet method is not a general replacement for locking. It applies only when critical updates for an object are confined to a single variable.
Atomic classes are not general purpose replacements for java.lang.Integer and related classes. They do not define methods such as hashCode and compareTo. (Because atomic variables are expected to be mutated, they are poor choices for hash table keys.) Additionally, classes are provided only for those types that are commonly useful in intended applications. For example, there is no atomic class for representing byte. In those infrequent cases where you would like to do so, you can use an AtomicInteger to hold byte values, and cast appropriately. You can also hold floats using Float.floatToIntBits and Float.intBitstoFloat conversions, and doubles using Double.doubleToLongBits and Double.longBitsToDouble conversions.