package parallel
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- trait AdaptiveWorkStealingForkJoinTasks extends ForkJoinTasks with AdaptiveWorkStealingTasks
-
trait
AdaptiveWorkStealingTasks
extends Tasks
This trait implements scheduling by employing an adaptive work stealing technique.
-
implicit
class
CollectionsHaveToParArray
[C, T] extends AnyRef
Adds toParArray method to collection classes.
-
trait
Combiner
[-Elem, +To] extends Builder[Elem, To] with Sizing with Parallel
The base trait for all combiners.
The base trait for all combiners. A combiner incremental collection construction just like a regular builder, but also implements an efficient merge operation of two builders via
combine
method. Once the collection is constructed, it may be obtained by invoking theresult
method.The complexity of the
combine
method should be less than linear for best performance. Theresult
method doesn't have to be a constant time operation, but may be performed in parallel.- Elem
the type of the elements added to the builder
- To
the type of the collection the builder produces
- Since
2.9
- trait CombinerFactory [U, Repr] extends AnyRef
-
class
ExecutionContextTaskSupport
extends TaskSupport with ExecutionContextTasks
A task support that uses an execution context to schedule tasks.
A task support that uses an execution context to schedule tasks.
It can be used with the default execution context implementation in the
scala.concurrent
package. It internally forwards the call to either a forkjoin based task support or a thread pool executor one, depending on what the execution context uses.By default, parallel collections are parameterized with this task support object, so parallel collections share the same execution context backend as the rest of the
scala.concurrent
package.- See also
scala.collection.parallel.TaskSupport for more information.
-
trait
ExecutionContextTasks
extends Tasks
This tasks implementation uses execution contexts to spawn a parallel computation.
This tasks implementation uses execution contexts to spawn a parallel computation.
As an optimization, it internally checks whether the execution context is the standard implementation based on fork/join pools, and if it is, creates a
ForkJoinTaskSupport
that shares the same pool to forward its request to it.Otherwise, it uses an execution context exclusive
Tasks
implementation to divide the tasks into smaller chunks and execute operations on it. - trait FactoryOps [From, Elem, To] extends AnyRef
-
class
ForkJoinTaskSupport
extends TaskSupport with AdaptiveWorkStealingForkJoinTasks
A task support that uses a fork join pool to schedule tasks.
A task support that uses a fork join pool to schedule tasks.
- See also
scala.collection.parallel.TaskSupport for more information.
-
trait
ForkJoinTasks
extends Tasks with HavingForkJoinPool
An implementation trait for parallel tasks based on the fork/join framework.
-
trait
HavingForkJoinPool
extends AnyRef
A trait describing objects that provide a fork/join pool.
-
trait
IterableSplitter
[+T] extends AugmentedIterableIterator[T] with Splitter[T] with Signalling with DelegatedSignalling
Parallel iterators allow splitting and provide a
remaining
method to obtain the number of elements remaining in the iterator.Parallel iterators allow splitting and provide a
remaining
method to obtain the number of elements remaining in the iterator.- T
type of the elements iterated.
-
trait
ParIterable
[+T] extends GenIterable[T] with GenericParTemplate[T, ParIterable] with ParIterableLike[T, ParIterable[T], scala.Iterable[T]]
A template trait for parallel iterable collections.
A template trait for parallel iterable collections.
This is a base trait for Scala parallel collections. It defines behaviour common to all parallel collections. Concrete parallel collections should inherit this trait and
ParIterable
if they want to define specific combiner factories.Parallel operations are implemented with divide and conquer style algorithms that parallelize well. The basic idea is to split the collection into smaller parts until they are small enough to be operated on sequentially.
All of the parallel operations are implemented as tasks within this trait. Tasks rely on the concept of splitters, which extend iterators. Every parallel collection defines:
def splitter: IterableSplitter[T]
which returns an instance of
IterableSplitter[T]
, which is a subtype ofSplitter[T]
. Splitters have a methodremaining
to check the remaining number of elements, and methodsplit
which is defined by splitters. Methodsplit
divides the splitters iterate over into disjunct subsets:def split: Seq[Splitter]
which splits the splitter into a sequence of disjunct subsplitters. This is typically a very fast operation which simply creates wrappers around the receiver collection. This can be repeated recursively.
Tasks are scheduled for execution through a scala.collection.parallel.TaskSupport object, which can be changed through the
tasksupport
setter of the collection.Method
newCombiner
produces a new combiner. Combiners are an extension of builders. They provide a methodcombine
which combines two combiners and returns a combiner containing elements of both combiners. This method can be implemented by aggressively copying all the elements into the new combiner or by lazily binding their results. It is recommended to avoid copying all of the elements for performance reasons, although that cost might be negligible depending on the use case. Standard parallel collection combiners avoid copying when merging results, relying either on a two-step lazy construction or specific data-structure properties.Methods:
def seq: Sequential def par: Repr
produce the sequential or parallel implementation of the collection, respectively. Method
par
just returns a reference to this parallel collection. Methodseq
is efficient - it will not copy the elements. Instead, it will create a sequential version of the collection using the same underlying data structure. Note that this is not the case for sequential collections in general - they may copy the elements and produce a different underlying data structure.The combination of methods
toMap
,toSeq
ortoSet
along withpar
andseq
is a flexible way to change between different collection types.Since this trait extends the
GenIterable
trait, methods likesize
must also be implemented in concrete collections, whileiterator
forwards tosplitter
by default.Each parallel collection is bound to a specific fork/join pool, on which dormant worker threads are kept. The fork/join pool contains other information such as the parallelism level, that is, the number of processors used. When a collection is created, it is assigned the default fork/join pool found in the
scala.parallel
package object.Parallel collections are not necessarily ordered in terms of the
foreach
operation (seeTraversable
). Parallel sequences have a well defined order for iterators - creating an iterator and traversing the elements linearly will always yield the same order. However, bulk operations such asforeach
,map
orfilter
always occur in undefined orders for all parallel collections.Existing parallel collection implementations provide strict parallel iterators. Strict parallel iterators are aware of the number of elements they have yet to traverse. It's also possible to provide non-strict parallel iterators, which do not know the number of elements remaining. To do this, the new collection implementation must override
isStrictSplitterCollection
tofalse
. This will make some operations unavailable.To create a new parallel collection, extend the
ParIterable
trait, and implementsize
,splitter
,newCombiner
andseq
. Having an implicit combiner factory requires extending this trait in addition, as well as providing a companion object, as with regular collections.Method
size
is implemented as a constant time operation for parallel collections, and parallel collection operations rely on this assumption.The higher-order functions passed to certain operations may contain side-effects. Since implementations of bulk operations may not be sequential, this means that side-effects may not be predictable and may produce data-races, deadlocks or invalidation of state if care is not taken. It is up to the programmer to either avoid using side-effects or to use some form of synchronization when accessing mutable data.
- T
the element type of the collection
- Since
2.9
-
trait
ParIterableLike
[+T, +Repr <: ParIterable[T], +Sequential <: scala.Iterable[T] with IterableLike[T, Sequential]] extends GenIterableLike[T, Repr] with CustomParallelizable[T, Repr] with Parallel with HasNewCombiner[T, Repr]
A template trait for parallel collections of type
ParIterable[T]
.A template trait for parallel collections of type
ParIterable[T]
.This is a base trait for Scala parallel collections. It defines behaviour common to all parallel collections. Concrete parallel collections should inherit this trait and
ParIterable
if they want to define specific combiner factories.Parallel operations are implemented with divide and conquer style algorithms that parallelize well. The basic idea is to split the collection into smaller parts until they are small enough to be operated on sequentially.
All of the parallel operations are implemented as tasks within this trait. Tasks rely on the concept of splitters, which extend iterators. Every parallel collection defines:
def splitter: IterableSplitter[T]
which returns an instance of
IterableSplitter[T]
, which is a subtype ofSplitter[T]
. Splitters have a methodremaining
to check the remaining number of elements, and methodsplit
which is defined by splitters. Methodsplit
divides the splitters iterate over into disjunct subsets:def split: Seq[Splitter]
which splits the splitter into a sequence of disjunct subsplitters. This is typically a very fast operation which simply creates wrappers around the receiver collection. This can be repeated recursively.
Tasks are scheduled for execution through a scala.collection.parallel.TaskSupport object, which can be changed through the
tasksupport
setter of the collection.Method
newCombiner
produces a new combiner. Combiners are an extension of builders. They provide a methodcombine
which combines two combiners and returns a combiner containing elements of both combiners. This method can be implemented by aggressively copying all the elements into the new combiner or by lazily binding their results. It is recommended to avoid copying all of the elements for performance reasons, although that cost might be negligible depending on the use case. Standard parallel collection combiners avoid copying when merging results, relying either on a two-step lazy construction or specific data-structure properties.Methods:
def seq: Sequential def par: Repr
produce the sequential or parallel implementation of the collection, respectively. Method
par
just returns a reference to this parallel collection. Methodseq
is efficient - it will not copy the elements. Instead, it will create a sequential version of the collection using the same underlying data structure. Note that this is not the case for sequential collections in general - they may copy the elements and produce a different underlying data structure.The combination of methods
toMap
,toSeq
ortoSet
along withpar
andseq
is a flexible way to change between different collection types.Since this trait extends the
GenIterable
trait, methods likesize
must also be implemented in concrete collections, whileiterator
forwards tosplitter
by default.Each parallel collection is bound to a specific fork/join pool, on which dormant worker threads are kept. The fork/join pool contains other information such as the parallelism level, that is, the number of processors used. When a collection is created, it is assigned the default fork/join pool found in the
scala.parallel
package object.Parallel collections are not necessarily ordered in terms of the
foreach
operation (seeTraversable
). Parallel sequences have a well defined order for iterators - creating an iterator and traversing the elements linearly will always yield the same order. However, bulk operations such asforeach
,map
orfilter
always occur in undefined orders for all parallel collections.Existing parallel collection implementations provide strict parallel iterators. Strict parallel iterators are aware of the number of elements they have yet to traverse. It's also possible to provide non-strict parallel iterators, which do not know the number of elements remaining. To do this, the new collection implementation must override
isStrictSplitterCollection
tofalse
. This will make some operations unavailable.To create a new parallel collection, extend the
ParIterable
trait, and implementsize
,splitter
,newCombiner
andseq
. Having an implicit combiner factory requires extending this trait in addition, as well as providing a companion object, as with regular collections.Method
size
is implemented as a constant time operation for parallel collections, and parallel collection operations rely on this assumption.The higher-order functions passed to certain operations may contain side-effects. Since implementations of bulk operations may not be sequential, this means that side-effects may not be predictable and may produce data-races, deadlocks or invalidation of state if care is not taken. It is up to the programmer to either avoid using side-effects or to use some form of synchronization when accessing mutable data.
- T
the element type of the collection
- Repr
the type of the actual collection containing the elements
-
trait
ParMap
[K, +V] extends GenMap[K, V] with GenericParMapTemplate[K, V, ParMap] with ParIterable[(K, V)] with ParMapLike[K, V, ParMap[K, V], Map[K, V]]
A template trait for parallel maps.
A template trait for parallel maps.
The higher-order functions passed to certain operations may contain side-effects. Since implementations of bulk operations may not be sequential, this means that side-effects may not be predictable and may produce data-races, deadlocks or invalidation of state if care is not taken. It is up to the programmer to either avoid using side-effects or to use some form of synchronization when accessing mutable data.
- K
the key type of the map
- V
the value type of the map
- Since
2.9
-
trait
ParMapLike
[K, +V, +Repr <: ParMapLike[K, V, Repr, Sequential] with ParMap[K, V], +Sequential <: Map[K, V] with MapLike[K, V, Sequential]] extends GenMapLike[K, V, Repr] with ParIterableLike[(K, V), Repr, Sequential]
A template trait for mutable parallel maps.
A template trait for mutable parallel maps. This trait is to be mixed in with concrete parallel maps to override the representation type.
The higher-order functions passed to certain operations may contain side-effects. Since implementations of bulk operations may not be sequential, this means that side-effects may not be predictable and may produce data-races, deadlocks or invalidation of state if care is not taken. It is up to the programmer to either avoid using side-effects or to use some form of synchronization when accessing mutable data.
- K
the key type of the map
- V
the value type of the map
-
trait
ParSeq
[+T] extends GenSeq[T] with ParIterable[T] with GenericParTemplate[T, ParSeq] with ParSeqLike[T, ParSeq[T], scala.Seq[T]]
A template trait for parallel sequences.
A template trait for parallel sequences.
Parallel sequences inherit the
Seq
trait. Their indexing and length computations are defined to be efficient. Like their sequential counterparts they always have a defined order of elements. This means they will produce resulting parallel sequences in the same way sequential sequences do. However, the order in which they perform bulk operations on elements to produce results is not defined and is generally nondeterministic. If the higher-order functions given to them produce no sideeffects, then this won't be noticeable.This trait defines a new, more general
split
operation and reimplements thesplit
operation ofParallelIterable
trait using the newsplit
operation.The higher-order functions passed to certain operations may contain side-effects. Since implementations of bulk operations may not be sequential, this means that side-effects may not be predictable and may produce data-races, deadlocks or invalidation of state if care is not taken. It is up to the programmer to either avoid using side-effects or to use some form of synchronization when accessing mutable data.
- T
the type of the elements in this parallel sequence
-
trait
ParSeqLike
[+T, +Repr <: ParSeq[T], +Sequential <: scala.Seq[T] with SeqLike[T, Sequential]] extends GenSeqLike[T, Repr] with ParIterableLike[T, Repr, Sequential]
A template trait for sequences of type
ParSeq[T]
, representing parallel sequences with element typeT
.A template trait for sequences of type
ParSeq[T]
, representing parallel sequences with element typeT
.Parallel sequences inherit the
Seq
trait. Their indexing and length computations are defined to be efficient. Like their sequential counterparts they always have a defined order of elements. This means they will produce resulting parallel sequences in the same way sequential sequences do. However, the order in which they perform bulk operations on elements to produce results is not defined and is generally nondeterministic. If the higher-order functions given to them produce no sideeffects, then this won't be noticeable.This trait defines a new, more general
split
operation and reimplements thesplit
operation ofParallelIterable
trait using the newsplit
operation.- T
the type of the elements contained in this collection
- Repr
the type of the actual collection containing the elements
- Sequential
the type of the sequential version of this parallel collection
-
trait
ParSet
[T] extends GenSet[T] with GenericParTemplate[T, ParSet] with ParIterable[T] with ParSetLike[T, ParSet[T], Set[T]]
A template trait for parallel sets.
A template trait for parallel sets.
The higher-order functions passed to certain operations may contain side-effects. Since implementations of bulk operations may not be sequential, this means that side-effects may not be predictable and may produce data-races, deadlocks or invalidation of state if care is not taken. It is up to the programmer to either avoid using side-effects or to use some form of synchronization when accessing mutable data.
- T
the element type of the set
- Since
2.9
-
trait
ParSetLike
[T, +Repr <: ParSetLike[T, Repr, Sequential] with ParSet[T], +Sequential <: Set[T] with SetLike[T, Sequential]] extends GenSetLike[T, Repr] with ParIterableLike[T, Repr, Sequential]
A template trait for parallel sets.
A template trait for parallel sets. This trait is mixed in with concrete parallel sets to override the representation type.
The higher-order functions passed to certain operations may contain side-effects. Since implementations of bulk operations may not be sequential, this means that side-effects may not be predictable and may produce data-races, deadlocks or invalidation of state if care is not taken. It is up to the programmer to either avoid using side-effects or to use some form of synchronization when accessing mutable data.
- T
the element type of the set
-
trait
PreciseSplitter
[+T] extends Splitter[T]
A precise splitter (or a precise split iterator) can be split into arbitrary number of splitters that traverse disjoint subsets of arbitrary sizes.
A precise splitter (or a precise split iterator) can be split into arbitrary number of splitters that traverse disjoint subsets of arbitrary sizes.
Implementors might want to override the parameterless
split
method for efficiency.- T
type of the elements this splitter traverses
- Since
2.9
-
trait
SeqSplitter
[+T] extends IterableSplitter[T] with AugmentedSeqIterator[T] with PreciseSplitter[T]
Parallel sequence iterators allow splitting into arbitrary subsets.
Parallel sequence iterators allow splitting into arbitrary subsets.
- T
type of the elements iterated.
-
trait
Splitter
[+T] extends Iterator[T]
A splitter (or a split iterator) can be split into more splitters that traverse over disjoint subsets of elements.
A splitter (or a split iterator) can be split into more splitters that traverse over disjoint subsets of elements.
- T
type of the elements this splitter traverses
- Since
2.9
- trait Task [R, +Tp] extends AnyRef
-
trait
TaskSupport
extends Tasks
A trait implementing the scheduling of a parallel collection operation.
A trait implementing the scheduling of a parallel collection operation.
Parallel collections are modular in the way operations are scheduled. Each parallel collection is parameterized with a task support object which is responsible for scheduling and load-balancing tasks to processors.
A task support object can be changed in a parallel collection after it has been created, but only during a quiescent period, i.e. while there are no concurrent invocations to parallel collection methods.
There are currently a few task support implementations available for parallel collections. The scala.collection.parallel.ForkJoinTaskSupport uses a fork-join pool internally.
The scala.collection.parallel.ExecutionContextTaskSupport uses the default execution context implementation found in scala.concurrent, and it reuses the thread pool used in scala.concurrent.
The execution context task support is set to each parallel collection by default, so parallel collections reuse the same fork-join pool as the future API.
Here is a way to change the task support of a parallel collection:
import scala.collection.parallel._ val pc = mutable.ParArray(1, 2, 3) pc.tasksupport = new ForkJoinTaskSupport( new java.util.concurrent.ForkJoinPool(2))
- See also
Configuring Parallel Collections section on the parallel collection's guide for more information.
-
trait
Tasks
extends AnyRef
A trait that declares task execution capabilities used by parallel collections.
- trait TraversableOps [T] extends AnyRef
-
trait
AdaptiveWorkStealingThreadPoolTasks
extends ThreadPoolTasks with AdaptiveWorkStealingTasks
- Annotations
- @deprecated
- Deprecated
(Since version 2.11.0) use
AdaptiveWorkStealingForkJoinTasks
instead
-
final
case class
CompositeThrowable
(throwables: Set[Throwable]) extends Exception with Product with Serializable
Composite throwable - thrown when multiple exceptions are thrown at the same time.
Composite throwable - thrown when multiple exceptions are thrown at the same time.
- Annotations
- @deprecated
- Deprecated
(Since version 2.11.0) this class will be removed.
-
class
ThreadPoolTaskSupport
extends TaskSupport with AdaptiveWorkStealingThreadPoolTasks
A task support that uses a thread pool executor to schedule tasks.
A task support that uses a thread pool executor to schedule tasks.
- Annotations
- @deprecated
- Deprecated
(Since version 2.11.0) use
ForkJoinTaskSupport
instead- See also
scala.collection.parallel.TaskSupport for more information.
-
trait
ThreadPoolTasks
extends Tasks
An implementation of tasks objects based on the Java thread pooling API.
An implementation of tasks objects based on the Java thread pooling API.
- Annotations
- @deprecated
- Deprecated
(Since version 2.11.0) use
ForkJoinTasks
instead
-
trait
ThrowableOps
extends AnyRef
- Annotations
- @deprecated
- Deprecated
(Since version 2.11.0) this trait will be removed
Value Members
- val CHECK_RATE: Int
- val MIN_FOR_COPY: Int
- val SQRT2: Double
- val availableProcessors: Int
- val defaultTaskSupport: TaskSupport
- def setTaskSupport[Coll](c: Coll, t: TaskSupport): Coll
-
def
thresholdFromSize(sz: Int, parallelismLevel: Int): Int
Computes threshold from the size of the collection and the parallelism level.
- object ForkJoinTasks
- object FutureThreadPoolTasks
-
object
ParIterable
extends ParFactory[ParIterable]
This object provides a set of operations to create
values.ParIterable
- object ParMap extends ParMapFactory[ParMap]
- object ParSeq extends ParFactory[ParSeq]
- object ParSet extends ParSetFactory[ParSet]
- object Splitter
Deprecated Value Members
-
object
ThreadPoolTasks
- Annotations
- @deprecated
- Deprecated
(Since version 2.11.0) use
ForkJoinTasks
instead
This is the documentation for the Scala standard library.
Package structure
The scala package contains core types like
Int
,Float
,Array
orOption
which are accessible in all Scala compilation units without explicit qualification or imports.Notable packages include:
scala.collection
and its sub-packages contain Scala's collections frameworkscala.collection.immutable
- Immutable, sequential data-structures such asVector
,List
,Range
,HashMap
orHashSet
scala.collection.mutable
- Mutable, sequential data-structures such asArrayBuffer
,StringBuilder
,HashMap
orHashSet
scala.collection.concurrent
- Mutable, concurrent data-structures such asTrieMap
scala.collection.parallel.immutable
- Immutable, parallel data-structures such asParVector
,ParRange
,ParHashMap
orParHashSet
scala.collection.parallel.mutable
- Mutable, parallel data-structures such asParArray
,ParHashMap
,ParTrieMap
orParHashSet
scala.concurrent
- Primitives for concurrent programming such asFutures
andPromises
scala.io
- Input and output operationsscala.math
- Basic math functions and additional numeric types likeBigInt
andBigDecimal
scala.sys
- Interaction with other processes and the operating systemscala.util.matching
- Regular expressionsOther packages exist. See the complete list on the right.
Additional parts of the standard library are shipped as separate libraries. These include:
scala.reflect
- Scala's reflection API (scala-reflect.jar)scala.xml
- XML parsing, manipulation, and serialization (scala-xml.jar)scala.swing
- A convenient wrapper around Java's GUI framework called Swing (scala-swing.jar)scala.util.parsing
- Parser combinators (scala-parser-combinators.jar)Automatic imports
Identifiers in the scala package and the
scala.Predef
object are always in scope by default.Some of these identifiers are type aliases provided as shortcuts to commonly used classes. For example,
List
is an alias forscala.collection.immutable.List
.Other aliases refer to classes provided by the underlying platform. For example, on the JVM,
String
is an alias forjava.lang.String
.