8014393: Minor typo in the spec for j.u.stream.Stream.findFirst()
Reviewed-by: alanb, chegar
/*
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* DO NOT ALTER OR REMOVE COPYRIGHT NOTICES OR THIS FILE HEADER.
*
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*
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* accompanied this code).
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*
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package java.util.stream;
import java.util.AbstractMap;
import java.util.AbstractSet;
import java.util.ArrayList;
import java.util.Collection;
import java.util.Collections;
import java.util.Comparator;
import java.util.Comparators;
import java.util.DoubleSummaryStatistics;
import java.util.EnumSet;
import java.util.HashMap;
import java.util.HashSet;
import java.util.IntSummaryStatistics;
import java.util.Iterator;
import java.util.List;
import java.util.LongSummaryStatistics;
import java.util.Map;
import java.util.NoSuchElementException;
import java.util.Objects;
import java.util.Set;
import java.util.StringJoiner;
import java.util.concurrent.ConcurrentHashMap;
import java.util.concurrent.ConcurrentMap;
import java.util.function.BiFunction;
import java.util.function.BinaryOperator;
import java.util.function.Function;
import java.util.function.Predicate;
import java.util.function.Supplier;
import java.util.function.ToDoubleFunction;
import java.util.function.ToIntFunction;
import java.util.function.ToLongFunction;
/**
* Implementations of {@link Collector} that implement various useful reduction
* operations, such as accumulating elements into collections, summarizing
* elements according to various criteria, etc.
*
* <p>The following are examples of using the predefined {@code Collector}
* implementations in {@link Collectors} with the {@code Stream} API to perform
* mutable reduction tasks:
*
* <pre>{@code
* // Accumulate elements into a List
* List<Person> list = people.collect(Collectors.toList());
*
* // Accumulate elements into a TreeSet
* List<Person> list = people.collect(Collectors.toCollection(TreeSet::new));
*
* // Convert elements to strings and concatenate them, separated by commas
* String joined = stream.map(Object::toString)
* .collect(Collectors.toStringJoiner(", "))
* .toString();
*
* // Find highest-paid employee
* Employee highestPaid = employees.stream()
* .collect(Collectors.maxBy(Comparators.comparing(Employee::getSalary)));
*
* // Group employees by department
* Map<Department, List<Employee>> byDept
* = employees.stream()
* .collect(Collectors.groupingBy(Employee::getDepartment));
*
* // Find highest-paid employee by department
* Map<Department, Employee> highestPaidByDept
* = employees.stream()
* .collect(Collectors.groupingBy(Employee::getDepartment,
* Collectors.maxBy(Comparators.comparing(Employee::getSalary))));
*
* // Partition students into passing and failing
* Map<Boolean, List<Student>> passingFailing =
* students.stream()
* .collect(Collectors.partitioningBy(s -> s.getGrade() >= PASS_THRESHOLD);
*
* }</pre>
*
* TODO explanation of parallel collection
*
* @since 1.8
*/
public final class Collectors {
private static final Set<Collector.Characteristics> CH_CONCURRENT
= Collections.unmodifiableSet(EnumSet.of(Collector.Characteristics.CONCURRENT,
Collector.Characteristics.STRICTLY_MUTATIVE,
Collector.Characteristics.UNORDERED));
private static final Set<Collector.Characteristics> CH_STRICT
= Collections.unmodifiableSet(EnumSet.of(Collector.Characteristics.STRICTLY_MUTATIVE));
private static final Set<Collector.Characteristics> CH_STRICT_UNORDERED
= Collections.unmodifiableSet(EnumSet.of(Collector.Characteristics.STRICTLY_MUTATIVE,
Collector.Characteristics.UNORDERED));
private Collectors() { }
/**
* Returns a merge function, suitable for use in
* {@link Map#merge(Object, Object, BiFunction) Map.merge()} or
* {@link #toMap(Function, Function, BinaryOperator) toMap()}, which always
* throws {@code IllegalStateException}. This can be used to enforce the
* assumption that the elements being collected are distinct.
*
* @param <T> the type of input arguments to the merge function
* @return a merge function which always throw {@code IllegalStateException}
*
* @see #firstWinsMerger()
* @see #lastWinsMerger()
*/
public static <T> BinaryOperator<T> throwingMerger() {
return (u,v) -> { throw new IllegalStateException(String.format("Duplicate key %s", u)); };
}
/**
* Returns a merge function, suitable for use in
* {@link Map#merge(Object, Object, BiFunction) Map.merge()} or
* {@link #toMap(Function, Function, BinaryOperator) toMap()},
* which implements a "first wins" policy.
*
* @param <T> the type of input arguments to the merge function
* @return a merge function which always returns its first argument
* @see #lastWinsMerger()
* @see #throwingMerger()
*/
public static <T> BinaryOperator<T> firstWinsMerger() {
return (u,v) -> u;
}
/**
* Returns a merge function, suitable for use in
* {@link Map#merge(Object, Object, BiFunction) Map.merge()} or
* {@link #toMap(Function, Function, BinaryOperator) toMap()},
* which implements a "last wins" policy.
*
* @param <T> the type of input arguments to the merge function
* @return a merge function which always returns its second argument
* @see #firstWinsMerger()
* @see #throwingMerger()
*/
public static <T> BinaryOperator<T> lastWinsMerger() {
return (u,v) -> v;
}
/**
* Simple implementation class for {@code Collector}.
*
* @param <T> the type of elements to be collected
* @param <R> the type of the result
*/
private static final class CollectorImpl<T, R> implements Collector<T,R> {
private final Supplier<R> resultSupplier;
private final BiFunction<R, T, R> accumulator;
private final BinaryOperator<R> combiner;
private final Set<Characteristics> characteristics;
CollectorImpl(Supplier<R> resultSupplier,
BiFunction<R, T, R> accumulator,
BinaryOperator<R> combiner,
Set<Characteristics> characteristics) {
this.resultSupplier = resultSupplier;
this.accumulator = accumulator;
this.combiner = combiner;
this.characteristics = characteristics;
}
CollectorImpl(Supplier<R> resultSupplier,
BiFunction<R, T, R> accumulator,
BinaryOperator<R> combiner) {
this(resultSupplier, accumulator, combiner, Collections.emptySet());
}
@Override
public BiFunction<R, T, R> accumulator() {
return accumulator;
}
@Override
public Supplier<R> resultSupplier() {
return resultSupplier;
}
@Override
public BinaryOperator<R> combiner() {
return combiner;
}
@Override
public Set<Characteristics> characteristics() {
return characteristics;
}
}
/**
* Returns a {@code Collector} that accumulates the input elements into a
* new {@code Collection}, in encounter order. The {@code Collection} is
* created by the provided factory.
*
* @param <T> the type of the input elements
* @param <C> the type of the resulting {@code Collection}
* @param collectionFactory a {@code Supplier} which returns a new, empty
* {@code Collection} of the appropriate type
* @return a {@code Collector} which collects all the input elements into a
* {@code Collection}, in encounter order
*/
public static <T, C extends Collection<T>>
Collector<T, C> toCollection(Supplier<C> collectionFactory) {
return new CollectorImpl<>(collectionFactory,
(r, t) -> { r.add(t); return r; },
(r1, r2) -> { r1.addAll(r2); return r1; },
CH_STRICT);
}
/**
* Returns a {@code Collector} that accumulates the input elements into a
* new {@code List}. There are no guarantees on the type, mutability,
* serializability, or thread-safety of the {@code List} returned.
*
* @param <T> the type of the input elements
* @return a {@code Collector} which collects all the input elements into a
* {@code List}, in encounter order
*/
public static <T>
Collector<T, List<T>> toList() {
BiFunction<List<T>, T, List<T>> accumulator = (list, t) -> {
switch (list.size()) {
case 0:
return Collections.singletonList(t);
case 1:
List<T> newList = new ArrayList<>();
newList.add(list.get(0));
newList.add(t);
return newList;
default:
list.add(t);
return list;
}
};
BinaryOperator<List<T>> combiner = (left, right) -> {
switch (left.size()) {
case 0:
return right;
case 1:
List<T> newList = new ArrayList<>(left.size() + right.size());
newList.addAll(left);
newList.addAll(right);
return newList;
default:
left.addAll(right);
return left;
}
};
return new CollectorImpl<>(Collections::emptyList, accumulator, combiner);
}
/**
* Returns a {@code Collector} that accumulates the input elements into a
* new {@code Set}. There are no guarantees on the type, mutability,
* serializability, or thread-safety of the {@code Set} returned.
*
* <p>This is an {@link Collector.Characteristics#UNORDERED unordered}
* Collector.
*
* @param <T> the type of the input elements
* @return a {@code Collector} which collects all the input elements into a
* {@code Set}
*/
public static <T>
Collector<T, Set<T>> toSet() {
return new CollectorImpl<>((Supplier<Set<T>>) HashSet::new,
(r, t) -> { r.add(t); return r; },
(r1, r2) -> { r1.addAll(r2); return r1; },
CH_STRICT_UNORDERED);
}
/**
* Returns a {@code Collector} that concatenates the input elements into a
* new {@link StringBuilder}.
*
* @return a {@code Collector} which collects String elements into a
* {@code StringBuilder}, in encounter order
*/
public static Collector<String, StringBuilder> toStringBuilder() {
return new CollectorImpl<>(StringBuilder::new,
(r, t) -> { r.append(t); return r; },
(r1, r2) -> { r1.append(r2); return r1; },
CH_STRICT);
}
/**
* Returns a {@code Collector} that concatenates the input elements into a
* new {@link StringJoiner}, using the specified delimiter.
*
* @param delimiter the delimiter to be used between each element
* @return A {@code Collector} which collects String elements into a
* {@code StringJoiner}, in encounter order
*/
public static Collector<CharSequence, StringJoiner> toStringJoiner(CharSequence delimiter) {
BinaryOperator<StringJoiner> merger = (sj, other) -> {
if (other.length() > 0)
sj.add(other.toString());
return sj;
};
return new CollectorImpl<>(() -> new StringJoiner(delimiter),
(r, t) -> { r.add(t); return r; },
merger, CH_STRICT);
}
/**
* {@code BinaryOperator<Map>} that merges the contents of its right
* argument into its left argument, using the provided merge function to
* handle duplicate keys.
*
* @param <K> type of the map keys
* @param <V> type of the map values
* @param <M> type of the map
* @param mergeFunction A merge function suitable for
* {@link Map#merge(Object, Object, BiFunction) Map.merge()}
* @return a merge function for two maps
*/
private static <K, V, M extends Map<K,V>>
BinaryOperator<M> mapMerger(BinaryOperator<V> mergeFunction) {
return (m1, m2) -> {
for (Map.Entry<K,V> e : m2.entrySet())
m1.merge(e.getKey(), e.getValue(), mergeFunction);
return m1;
};
}
/**
* Adapts a {@code Collector<U,R>} to a {@code Collector<T,R>} by applying
* a mapping function to each input element before accumulation.
*
* @apiNote
* The {@code mapping()} collectors are most useful when used in a
* multi-level reduction, downstream of {@code groupingBy} or
* {@code partitioningBy}. For example, given a stream of
* {@code Person}, to accumulate the set of last names in each city:
* <pre>{@code
* Map<City, Set<String>> lastNamesByCity
* = people.stream().collect(groupingBy(Person::getCity,
* mapping(Person::getLastName, toSet())));
* }</pre>
*
* @param <T> the type of the input elements
* @param <U> type of elements accepted by downstream collector
* @param <R> result type of collector
* @param mapper a function to be applied to the input elements
* @param downstream a collector which will accept mapped values
* @return a collector which applies the mapping function to the input
* elements and provides the mapped results to the downstream collector
*/
public static <T, U, R> Collector<T, R>
mapping(Function<? super T, ? extends U> mapper, Collector<? super U, R> downstream) {
BiFunction<R, ? super U, R> downstreamAccumulator = downstream.accumulator();
return new CollectorImpl<>(downstream.resultSupplier(),
(r, t) -> downstreamAccumulator.apply(r, mapper.apply(t)),
downstream.combiner(), downstream.characteristics());
}
/**
* Returns a {@code Collector<T, Long>} that counts the number of input
* elements.
*
* @implSpec
* This produces a result equivalent to:
* <pre>{@code
* reducing(0L, e -> 1L, Long::sum)
* }</pre>
*
* @param <T> the type of the input elements
* @return a {@code Collector} that counts the input elements
*/
public static <T> Collector<T, Long>
counting() {
return reducing(0L, e -> 1L, Long::sum);
}
/**
* Returns a {@code Collector<T, T>} that produces the minimal element
* according to a given {@code Comparator}.
*
* @implSpec
* This produces a result equivalent to:
* <pre>{@code
* reducing(Comparators.lesserOf(comparator))
* }</pre>
*
* @param <T> the type of the input elements
* @param comparator a {@code Comparator} for comparing elements
* @return a {@code Collector} that produces the minimal value
*/
public static <T> Collector<T, T>
minBy(Comparator<? super T> comparator) {
return reducing(Comparators.lesserOf(comparator));
}
/**
* Returns a {@code Collector<T, T>} that produces the maximal element
* according to a given {@code Comparator}.
*
* @implSpec
* This produces a result equivalent to:
* <pre>{@code
* reducing(Comparators.greaterOf(comparator))
* }</pre>
*
* @param <T> the type of the input elements
* @param comparator a {@code Comparator} for comparing elements
* @return a {@code Collector} that produces the maximal value
*/
public static <T> Collector<T, T>
maxBy(Comparator<? super T> comparator) {
return reducing(Comparators.greaterOf(comparator));
}
/**
* Returns a {@code Collector<T, Long>} that produces the sum of a
* long-valued function applied to the input element.
*
* @implSpec
* This produces a result equivalent to:
* <pre>{@code
* reducing(0L, mapper, Long::sum)
* }</pre>
*
* @param <T> the type of the input elements
* @param mapper a function extracting the property to be summed
* @return a {@code Collector} that produces the sum of a derived property
*/
public static <T> Collector<T, Long>
sumBy(Function<? super T, Long> mapper) {
return reducing(0L, mapper, Long::sum);
}
/**
* Returns a {@code Collector<T,T>} which performs a reduction of its
* input elements under a specified {@code BinaryOperator}.
*
* @apiNote
* The {@code reducing()} collectors are most useful when used in a
* multi-level reduction, downstream of {@code groupingBy} or
* {@code partitioningBy}. To perform a simple reduction on a stream,
* use {@link Stream#reduce(BinaryOperator)} instead.
*
* @param <T> element type for the input and output of the reduction
* @param identity the identity value for the reduction (also, the value
* that is returned when there are no input elements)
* @param op a {@code BinaryOperator<T>} used to reduce the input elements
* @return a {@code Collector} which implements the reduction operation
*
* @see #reducing(BinaryOperator)
* @see #reducing(Object, Function, BinaryOperator)
*/
public static <T> Collector<T, T>
reducing(T identity, BinaryOperator<T> op) {
return new CollectorImpl<>(() -> identity, (r, t) -> (r == null ? t : op.apply(r, t)), op);
}
/**
* Returns a {@code Collector<T,T>} which performs a reduction of its
* input elements under a specified {@code BinaryOperator}.
*
* @apiNote
* The {@code reducing()} collectors are most useful when used in a
* multi-level reduction, downstream of {@code groupingBy} or
* {@code partitioningBy}. To perform a simple reduction on a stream,
* use {@link Stream#reduce(BinaryOperator)} instead.
*
* <p>For example, given a stream of {@code Person}, to calculate tallest
* person in each city:
* <pre>{@code
* Comparator<Person> byHeight = Comparators.comparing(Person::getHeight);
* BinaryOperator<Person> tallerOf = Comparators.greaterOf(byHeight);
* Map<City, Person> tallestByCity
* = people.stream().collect(groupingBy(Person::getCity, reducing(tallerOf)));
* }</pre>
*
* @implSpec
* The default implementation is equivalent to:
* <pre>{@code
* reducing(null, op);
* }</pre>
*
* @param <T> element type for the input and output of the reduction
* @param op a {@code BinaryOperator<T>} used to reduce the input elements
* @return a {@code Collector} which implements the reduction operation
*
* @see #reducing(Object, BinaryOperator)
* @see #reducing(Object, Function, BinaryOperator)
*/
public static <T> Collector<T, T>
reducing(BinaryOperator<T> op) {
return reducing(null, op);
}
/**
* Returns a {@code Collector<T,U>} which performs a reduction of its
* input elements under a specified mapping function and
* {@code BinaryOperator}. This is a generalization of
* {@link #reducing(Object, BinaryOperator)} which allows a transformation
* of the elements before reduction.
*
* @apiNote
* The {@code reducing()} collectors are most useful when used in a
* multi-level reduction, downstream of {@code groupingBy} or
* {@code partitioningBy}. To perform a simple reduction on a stream,
* use {@link Stream#reduce(BinaryOperator)} instead.
*
* <p>For example, given a stream of {@code Person}, to calculate the longest
* last name of residents in each city:
* <pre>{@code
* Comparator<String> byLength = Comparators.comparing(String::length);
* BinaryOperator<String> longerOf = Comparators.greaterOf(byLength);
* Map<City, String> longestLastNameByCity
* = people.stream().collect(groupingBy(Person::getCity,
* reducing(Person::getLastName, longerOf)));
* }</pre>
*
* @param <T> the type of the input elements
* @param <U> the type of the mapped values
* @param identity the identity value for the reduction (also, the value
* that is returned when there are no input elements)
* @param mapper a mapping function to apply to each input value
* @param op a {@code BinaryOperator<U>} used to reduce the mapped values
* @return a {@code Collector} implementing the map-reduce operation
*
* @see #reducing(Object, BinaryOperator)
* @see #reducing(BinaryOperator)
*/
public static <T, U>
Collector<T, U> reducing(U identity,
Function<? super T, ? extends U> mapper,
BinaryOperator<U> op) {
return new CollectorImpl<>(() -> identity,
(r, t) -> (r == null ? mapper.apply(t) : op.apply(r, mapper.apply(t))),
op);
}
/**
* Returns a {@code Collector} implementing a "group by" operation on
* input elements of type {@code T}, grouping elements according to a
* classification function.
*
* <p>The classification function maps elements to some key type {@code K}.
* The collector produces a {@code Map<K, List<T>>} whose keys are the
* values resulting from applying the classification function to the input
* elements, and whose corresponding values are {@code List}s containing the
* input elements which map to the associated key under the classification
* function.
*
* <p>There are no guarantees on the type, mutability, serializability, or
* thread-safety of the {@code Map} or {@code List} objects returned.
* @implSpec
* This produces a result similar to:
* <pre>{@code
* groupingBy(classifier, toList());
* }</pre>
*
* @param <T> the type of the input elements
* @param <K> the type of the keys
* @param classifier the classifier function mapping input elements to keys
* @return a {@code Collector} implementing the group-by operation
*
* @see #groupingBy(Function, Collector)
* @see #groupingBy(Function, Supplier, Collector)
* @see #groupingByConcurrent(Function)
*/
public static <T, K>
Collector<T, Map<K, List<T>>> groupingBy(Function<? super T, ? extends K> classifier) {
return groupingBy(classifier, HashMap::new, toList());
}
/**
* Returns a {@code Collector} implementing a cascaded "group by" operation
* on input elements of type {@code T}, grouping elements according to a
* classification function, and then performing a reduction operation on
* the values associated with a given key using the specified downstream
* {@code Collector}.
*
* <p>The classification function maps elements to some key type {@code K}.
* The downstream collector operates on elements of type {@code T} and
* produces a result of type {@code D}. The resulting collector produces a
* {@code Map<K, D>}.
*
* <p>There are no guarantees on the type, mutability,
* serializability, or thread-safety of the {@code Map} returned.
*
* <p>For example, to compute the set of last names of people in each city:
* <pre>{@code
* Map<City, Set<String>> namesByCity
* = people.stream().collect(groupingBy(Person::getCity,
* mapping(Person::getLastName, toSet())));
* }</pre>
*
* @param <T> the type of the input elements
* @param <K> the type of the keys
* @param <D> the result type of the downstream reduction
* @param classifier a classifier function mapping input elements to keys
* @param downstream a {@code Collector} implementing the downstream reduction
* @return a {@code Collector} implementing the cascaded group-by operation
* @see #groupingBy(Function)
*
* @see #groupingBy(Function, Supplier, Collector)
* @see #groupingByConcurrent(Function, Collector)
*/
public static <T, K, D>
Collector<T, Map<K, D>> groupingBy(Function<? super T, ? extends K> classifier,
Collector<? super T, D> downstream) {
return groupingBy(classifier, HashMap::new, downstream);
}
/**
* Returns a {@code Collector} implementing a cascaded "group by" operation
* on input elements of type {@code T}, grouping elements according to a
* classification function, and then performing a reduction operation on
* the values associated with a given key using the specified downstream
* {@code Collector}. The {@code Map} produced by the Collector is created
* with the supplied factory function.
*
* <p>The classification function maps elements to some key type {@code K}.
* The downstream collector operates on elements of type {@code T} and
* produces a result of type {@code D}. The resulting collector produces a
* {@code Map<K, D>}.
*
* <p>For example, to compute the set of last names of people in each city,
* where the city names are sorted:
* <pre>{@code
* Map<City, Set<String>> namesByCity
* = people.stream().collect(groupingBy(Person::getCity, TreeMap::new,
* mapping(Person::getLastName, toSet())));
* }</pre>
*
* @param <T> the type of the input elements
* @param <K> the type of the keys
* @param <D> the result type of the downstream reduction
* @param <M> the type of the resulting {@code Map}
* @param classifier a classifier function mapping input elements to keys
* @param downstream a {@code Collector} implementing the downstream reduction
* @param mapFactory a function which, when called, produces a new empty
* {@code Map} of the desired type
* @return a {@code Collector} implementing the cascaded group-by operation
*
* @see #groupingBy(Function, Collector)
* @see #groupingBy(Function)
* @see #groupingByConcurrent(Function, Supplier, Collector)
*/
public static <T, K, D, M extends Map<K, D>>
Collector<T, M> groupingBy(Function<? super T, ? extends K> classifier,
Supplier<M> mapFactory,
Collector<? super T, D> downstream) {
Supplier<D> downstreamSupplier = downstream.resultSupplier();
BiFunction<D, ? super T, D> downstreamAccumulator = downstream.accumulator();
BiFunction<M, T, M> accumulator = (m, t) -> {
K key = Objects.requireNonNull(classifier.apply(t), "element cannot be mapped to a null key");
D oldContainer = m.computeIfAbsent(key, k -> downstreamSupplier.get());
D newContainer = downstreamAccumulator.apply(oldContainer, t);
if (newContainer != oldContainer)
m.put(key, newContainer);
return m;
};
return new CollectorImpl<>(mapFactory, accumulator, mapMerger(downstream.combiner()), CH_STRICT);
}
/**
* Returns a {@code Collector} implementing a concurrent "group by"
* operation on input elements of type {@code T}, grouping elements
* according to a classification function.
*
* <p>This is a {@link Collector.Characteristics#CONCURRENT concurrent} and
* {@link Collector.Characteristics#UNORDERED unordered} Collector.
*
* <p>The classification function maps elements to some key type {@code K}.
* The collector produces a {@code ConcurrentMap<K, List<T>>} whose keys are the
* values resulting from applying the classification function to the input
* elements, and whose corresponding values are {@code List}s containing the
* input elements which map to the associated key under the classification
* function.
*
* <p>There are no guarantees on the type, mutability, or serializability
* of the {@code Map} or {@code List} objects returned, or of the
* thread-safety of the {@code List} objects returned.
* @implSpec
* This produces a result similar to:
* <pre>{@code
* groupingByConcurrent(classifier, toList());
* }</pre>
*
* @param <T> the type of the input elements
* @param <K> the type of the keys
* @param classifier a classifier function mapping input elements to keys
* @return a {@code Collector} implementing the group-by operation
*
* @see #groupingBy(Function)
* @see #groupingByConcurrent(Function, Collector)
* @see #groupingByConcurrent(Function, Supplier, Collector)
*/
public static <T, K>
Collector<T, ConcurrentMap<K, List<T>>> groupingByConcurrent(Function<? super T, ? extends K> classifier) {
return groupingByConcurrent(classifier, ConcurrentHashMap::new, toList());
}
/**
* Returns a {@code Collector} implementing a concurrent cascaded "group by"
* operation on input elements of type {@code T}, grouping elements
* according to a classification function, and then performing a reduction
* operation on the values associated with a given key using the specified
* downstream {@code Collector}.
*
* <p>This is a {@link Collector.Characteristics#CONCURRENT concurrent} and
* {@link Collector.Characteristics#UNORDERED unordered} Collector.
*
* <p>The classification function maps elements to some key type {@code K}.
* The downstream collector operates on elements of type {@code T} and
* produces a result of type {@code D}. The resulting collector produces a
* {@code Map<K, D>}.
*
* <p>For example, to compute the set of last names of people in each city,
* where the city names are sorted:
* <pre>{@code
* ConcurrentMap<City, Set<String>> namesByCity
* = people.stream().collect(groupingByConcurrent(Person::getCity, TreeMap::new,
* mapping(Person::getLastName, toSet())));
* }</pre>
*
* @param <T> the type of the input elements
* @param <K> the type of the keys
* @param <D> the result type of the downstream reduction
* @param classifier a classifier function mapping input elements to keys
* @param downstream a {@code Collector} implementing the downstream reduction
* @return a {@code Collector} implementing the cascaded group-by operation
*
* @see #groupingBy(Function, Collector)
* @see #groupingByConcurrent(Function)
* @see #groupingByConcurrent(Function, Supplier, Collector)
*/
public static <T, K, D>
Collector<T, ConcurrentMap<K, D>> groupingByConcurrent(Function<? super T, ? extends K> classifier,
Collector<? super T, D> downstream) {
return groupingByConcurrent(classifier, ConcurrentHashMap::new, downstream);
}
/**
* Returns a concurrent {@code Collector} implementing a cascaded "group by"
* operation on input elements of type {@code T}, grouping elements
* according to a classification function, and then performing a reduction
* operation on the values associated with a given key using the specified
* downstream {@code Collector}. The {@code ConcurrentMap} produced by the
* Collector is created with the supplied factory function.
*
* <p>This is a {@link Collector.Characteristics#CONCURRENT concurrent} and
* {@link Collector.Characteristics#UNORDERED unordered} Collector.
*
* <p>The classification function maps elements to some key type {@code K}.
* The downstream collector operates on elements of type {@code T} and
* produces a result of type {@code D}. The resulting collector produces a
* {@code Map<K, D>}.
*
* <p>For example, to compute the set of last names of people in each city,
* where the city names are sorted:
* <pre>{@code
* ConcurrentMap<City, Set<String>> namesByCity
* = people.stream().collect(groupingBy(Person::getCity, ConcurrentSkipListMap::new,
* mapping(Person::getLastName, toSet())));
* }</pre>
*
*
* @param <T> the type of the input elements
* @param <K> the type of the keys
* @param <D> the result type of the downstream reduction
* @param <M> the type of the resulting {@code ConcurrentMap}
* @param classifier a classifier function mapping input elements to keys
* @param downstream a {@code Collector} implementing the downstream reduction
* @param mapFactory a function which, when called, produces a new empty
* {@code ConcurrentMap} of the desired type
* @return a {@code Collector} implementing the cascaded group-by operation
*
* @see #groupingByConcurrent(Function)
* @see #groupingByConcurrent(Function, Collector)
* @see #groupingBy(Function, Supplier, Collector)
*/
public static <T, K, D, M extends ConcurrentMap<K, D>>
Collector<T, M> groupingByConcurrent(Function<? super T, ? extends K> classifier,
Supplier<M> mapFactory,
Collector<? super T, D> downstream) {
Supplier<D> downstreamSupplier = downstream.resultSupplier();
BiFunction<D, ? super T, D> downstreamAccumulator = downstream.accumulator();
BinaryOperator<M> combiner = mapMerger(downstream.combiner());
if (downstream.characteristics().contains(Collector.Characteristics.CONCURRENT)) {
BiFunction<M, T, M> accumulator = (m, t) -> {
K key = Objects.requireNonNull(classifier.apply(t), "element cannot be mapped to a null key");
downstreamAccumulator.apply(m.computeIfAbsent(key, k -> downstreamSupplier.get()), t);
return m;
};
return new CollectorImpl<>(mapFactory, accumulator, combiner, CH_CONCURRENT);
} else if (downstream.characteristics().contains(Collector.Characteristics.STRICTLY_MUTATIVE)) {
BiFunction<M, T, M> accumulator = (m, t) -> {
K key = Objects.requireNonNull(classifier.apply(t), "element cannot be mapped to a null key");
D resultContainer = m.computeIfAbsent(key, k -> downstreamSupplier.get());
synchronized (resultContainer) {
downstreamAccumulator.apply(resultContainer, t);
}
return m;
};
return new CollectorImpl<>(mapFactory, accumulator, combiner, CH_CONCURRENT);
} else {
BiFunction<M, T, M> accumulator = (m, t) -> {
K key = Objects.requireNonNull(classifier.apply(t), "element cannot be mapped to a null key");
do {
D oldResult = m.computeIfAbsent(key, k -> downstreamSupplier.get());
if (oldResult == null) {
if (m.putIfAbsent(key, downstreamAccumulator.apply(null, t)) == null)
return m;
} else {
synchronized (oldResult) {
if (m.get(key) != oldResult)
continue;
D newResult = downstreamAccumulator.apply(oldResult, t);
if (oldResult != newResult)
m.put(key, newResult);
return m;
}
}
} while (true);
};
return new CollectorImpl<>(mapFactory, accumulator, combiner, CH_CONCURRENT);
}
}
/**
* Returns a {@code Collector} which partitions the input elements according
* to a {@code Predicate}, and organizes them into a
* {@code Map<Boolean, List<T>>}.
*
* There are no guarantees on the type, mutability,
* serializability, or thread-safety of the {@code Map} returned.
*
* @param <T> the type of the input elements
* @param predicate a predicate used for classifying input elements
* @return a {@code Collector} implementing the partitioning operation
*
* @see #partitioningBy(Predicate, Collector)
*/
public static <T>
Collector<T, Map<Boolean, List<T>>> partitioningBy(Predicate<? super T> predicate) {
return partitioningBy(predicate, toList());
}
/**
* Returns a {@code Collector} which partitions the input elements according
* to a {@code Predicate}, reduces the values in each partition according to
* another {@code Collector}, and organizes them into a
* {@code Map<Boolean, D>} whose values are the result of the downstream
* reduction.
*
* <p>There are no guarantees on the type, mutability,
* serializability, or thread-safety of the {@code Map} returned.
*
* @param <T> the type of the input elements
* @param <D> the result type of the downstream reduction
* @param predicate a predicate used for classifying input elements
* @param downstream a {@code Collector} implementing the downstream
* reduction
* @return a {@code Collector} implementing the cascaded partitioning
* operation
*
* @see #partitioningBy(Predicate)
*/
public static <T, D>
Collector<T, Map<Boolean, D>> partitioningBy(Predicate<? super T> predicate,
Collector<? super T, D> downstream) {
BiFunction<D, ? super T, D> downstreamAccumulator = downstream.accumulator();
BiFunction<Map<Boolean, D>, T, Map<Boolean, D>> accumulator = (result, t) -> {
Partition<D> asPartition = ((Partition<D>) result);
if (predicate.test(t)) {
D newResult = downstreamAccumulator.apply(asPartition.forTrue, t);
if (newResult != asPartition.forTrue)
asPartition.forTrue = newResult;
} else {
D newResult = downstreamAccumulator.apply(asPartition.forFalse, t);
if (newResult != asPartition.forFalse)
asPartition.forFalse = newResult;
}
return result;
};
return new CollectorImpl<>(() -> new Partition<>(downstream.resultSupplier().get(),
downstream.resultSupplier().get()),
accumulator, partitionMerger(downstream.combiner()), CH_STRICT);
}
/**
* Merge function for two partitions, given a merge function for the
* elements.
*/
private static <D> BinaryOperator<Map<Boolean, D>> partitionMerger(BinaryOperator<D> op) {
return (m1, m2) -> {
Partition<D> left = (Partition<D>) m1;
Partition<D> right = (Partition<D>) m2;
if (left.forFalse == null)
left.forFalse = right.forFalse;
else if (right.forFalse != null)
left.forFalse = op.apply(left.forFalse, right.forFalse);
if (left.forTrue == null)
left.forTrue = right.forTrue;
else if (right.forTrue != null)
left.forTrue = op.apply(left.forTrue, right.forTrue);
return left;
};
}
/**
* Accumulate elements into a {@code Map} whose keys and values are the
* result of applying mapping functions to the input elements.
* If the mapped keys contains duplicates (according to
* {@link Object#equals(Object)}), an {@code IllegalStateException} is
* thrown when the collection operation is performed. If the mapped keys
* may have duplicates, use {@link #toMap(Function, Function, BinaryOperator)}
* instead.
*
* @apiNote
* It is common for either the key or the value to be the input elements.
* In this case, the utility method
* {@link java.util.function.Function#identity()} may be helpful.
* For example, the following produces a {@code Map} mapping
* students to their grade point average:
* <pre>{@code
* Map<Student, Double> studentToGPA
* students.stream().collect(toMap(Functions.identity(),
* student -> computeGPA(student)));
* }</pre>
* And the following produces a {@code Map} mapping a unique identifier to
* students:
* <pre>{@code
* Map<String, Student> studentIdToStudent
* students.stream().collect(toMap(Student::getId,
* Functions.identity());
* }</pre>
*
* @param <T> the type of the input elements
* @param <K> the output type of the key mapping function
* @param <U> the output type of the value mapping function
* @param keyMapper a mapping function to produce keys
* @param valueMapper a mapping function to produce values
* @return a {@code Collector} which collects elements into a {@code Map}
* whose keys and values are the result of applying mapping functions to
* the input elements
*
* @see #toMap(Function, Function, BinaryOperator)
* @see #toMap(Function, Function, BinaryOperator, Supplier)
* @see #toConcurrentMap(Function, Function)
*/
public static <T, K, U>
Collector<T, Map<K,U>> toMap(Function<? super T, ? extends K> keyMapper,
Function<? super T, ? extends U> valueMapper) {
return toMap(keyMapper, valueMapper, throwingMerger(), HashMap::new);
}
/**
* Accumulate elements into a {@code Map} whose keys and values are the
* result of applying mapping functions to the input elements. If the mapped
* keys contains duplicates (according to {@link Object#equals(Object)}),
* the value mapping function is applied to each equal element, and the
* results are merged using the provided merging function.
*
* @apiNote
* There are multiple ways to deal with collisions between multiple elements
* mapping to the same key. There are some predefined merging functions,
* such as {@link #throwingMerger()}, {@link #firstWinsMerger()}, and
* {@link #lastWinsMerger()}, that implement common policies, or you can
* implement custom policies easily. For example, if you have a stream
* of {@code Person}, and you want to produce a "phone book" mapping name to
* address, but it is possible that two persons have the same name, you can
* do as follows to gracefully deals with these collisions, and produce a
* {@code Map} mapping names to a concatenated list of addresses:
* <pre>{@code
* Map<String, String> phoneBook
* people.stream().collect(toMap(Person::getName,
* Person::getAddress,
* (s, a) -> s + ", " + a));
* }</pre>
*
* @param <T> the type of the input elements
* @param <K> the output type of the key mapping function
* @param <U> the output type of the value mapping function
* @param keyMapper a mapping function to produce keys
* @param valueMapper a mapping function to produce values
* @param mergeFunction a merge function, used to resolve collisions between
* values associated with the same key, as supplied
* to {@link Map#merge(Object, Object, BiFunction)}
* @return a {@code Collector} which collects elements into a {@code Map}
* whose keys are the result of applying a key mapping function to the input
* elements, and whose values are the result of applying a value mapping
* function to all input elements equal to the key and combining them
* using the merge function
*
* @see #toMap(Function, Function)
* @see #toMap(Function, Function, BinaryOperator, Supplier)
* @see #toConcurrentMap(Function, Function, BinaryOperator)
*/
public static <T, K, U>
Collector<T, Map<K,U>> toMap(Function<? super T, ? extends K> keyMapper,
Function<? super T, ? extends U> valueMapper,
BinaryOperator<U> mergeFunction) {
return toMap(keyMapper, valueMapper, mergeFunction, HashMap::new);
}
/**
* Accumulate elements into a {@code Map} whose keys and values are the
* result of applying mapping functions to the input elements. If the mapped
* keys contains duplicates (according to {@link Object#equals(Object)}),
* the value mapping function is applied to each equal element, and the
* results are merged using the provided merging function. The {@code Map}
* is created by a provided supplier function.
*
* @param <T> the type of the input elements
* @param <K> the output type of the key mapping function
* @param <U> the output type of the value mapping function
* @param <M> the type of the resulting {@code Map}
* @param keyMapper a mapping function to produce keys
* @param valueMapper a mapping function to produce values
* @param mergeFunction a merge function, used to resolve collisions between
* values associated with the same key, as supplied
* to {@link Map#merge(Object, Object, BiFunction)}
* @param mapSupplier a function which returns a new, empty {@code Map} into
* which the results will be inserted
* @return a {@code Collector} which collects elements into a {@code Map}
* whose keys are the result of applying a key mapping function to the input
* elements, and whose values are the result of applying a value mapping
* function to all input elements equal to the key and combining them
* using the merge function
*
* @see #toMap(Function, Function)
* @see #toMap(Function, Function, BinaryOperator)
* @see #toConcurrentMap(Function, Function, BinaryOperator, Supplier)
*/
public static <T, K, U, M extends Map<K, U>>
Collector<T, M> toMap(Function<? super T, ? extends K> keyMapper,
Function<? super T, ? extends U> valueMapper,
BinaryOperator<U> mergeFunction,
Supplier<M> mapSupplier) {
BiFunction<M, T, M> accumulator
= (map, element) -> {
map.merge(keyMapper.apply(element), valueMapper.apply(element), mergeFunction);
return map;
};
return new CollectorImpl<>(mapSupplier, accumulator, mapMerger(mergeFunction), CH_STRICT);
}
/**
* Accumulate elements into a {@code ConcurrentMap} whose keys and values
* are the result of applying mapping functions to the input elements.
* If the mapped keys contains duplicates (according to
* {@link Object#equals(Object)}), an {@code IllegalStateException} is
* thrown when the collection operation is performed. If the mapped keys
* may have duplicates, use
* {@link #toConcurrentMap(Function, Function, BinaryOperator)} instead.
*
* @apiNote
* It is common for either the key or the value to be the input elements.
* In this case, the utility method
* {@link java.util.function.Function#identity()} may be helpful.
* For example, the following produces a {@code Map} mapping
* students to their grade point average:
* <pre>{@code
* Map<Student, Double> studentToGPA
* students.stream().collect(toMap(Functions.identity(),
* student -> computeGPA(student)));
* }</pre>
* And the following produces a {@code Map} mapping a unique identifier to
* students:
* <pre>{@code
* Map<String, Student> studentIdToStudent
* students.stream().collect(toConcurrentMap(Student::getId,
* Functions.identity());
* }</pre>
*
* <p>This is a {@link Collector.Characteristics#CONCURRENT concurrent} and
* {@link Collector.Characteristics#UNORDERED unordered} Collector.
*
* @param <T> the type of the input elements
* @param <K> the output type of the key mapping function
* @param <U> the output type of the value mapping function
* @param keyMapper the mapping function to produce keys
* @param valueMapper the mapping function to produce values
* @return a concurrent {@code Collector} which collects elements into a
* {@code ConcurrentMap} whose keys are the result of applying a key mapping
* function to the input elements, and whose values are the result of
* applying a value mapping function to the input elements
*
* @see #toMap(Function, Function)
* @see #toConcurrentMap(Function, Function, BinaryOperator)
* @see #toConcurrentMap(Function, Function, BinaryOperator, Supplier)
*/
public static <T, K, U>
Collector<T, ConcurrentMap<K,U>> toConcurrentMap(Function<? super T, ? extends K> keyMapper,
Function<? super T, ? extends U> valueMapper) {
return toConcurrentMap(keyMapper, valueMapper, throwingMerger(), ConcurrentHashMap::new);
}
/**
* Accumulate elements into a {@code ConcurrentMap} whose keys and values
* are the result of applying mapping functions to the input elements. If
* the mapped keys contains duplicates (according to {@link Object#equals(Object)}),
* the value mapping function is applied to each equal element, and the
* results are merged using the provided merging function.
*
* @apiNote
* There are multiple ways to deal with collisions between multiple elements
* mapping to the same key. There are some predefined merging functions,
* such as {@link #throwingMerger()}, {@link #firstWinsMerger()}, and
* {@link #lastWinsMerger()}, that implement common policies, or you can
* implement custom policies easily. For example, if you have a stream
* of {@code Person}, and you want to produce a "phone book" mapping name to
* address, but it is possible that two persons have the same name, you can
* do as follows to gracefully deals with these collisions, and produce a
* {@code Map} mapping names to a concatenated list of addresses:
* <pre>{@code
* Map<String, String> phoneBook
* people.stream().collect(toConcurrentMap(Person::getName,
* Person::getAddress,
* (s, a) -> s + ", " + a));
* }</pre>
*
* <p>This is a {@link Collector.Characteristics#CONCURRENT concurrent} and
* {@link Collector.Characteristics#UNORDERED unordered} Collector.
*
* @param <T> the type of the input elements
* @param <K> the output type of the key mapping function
* @param <U> the output type of the value mapping function
* @param keyMapper a mapping function to produce keys
* @param valueMapper a mapping function to produce values
* @param mergeFunction a merge function, used to resolve collisions between
* values associated with the same key, as supplied
* to {@link Map#merge(Object, Object, BiFunction)}
* @return a concurrent {@code Collector} which collects elements into a
* {@code ConcurrentMap} whose keys are the result of applying a key mapping
* function to the input elements, and whose values are the result of
* applying a value mapping function to all input elements equal to the key
* and combining them using the merge function
*
* @see #toConcurrentMap(Function, Function)
* @see #toConcurrentMap(Function, Function, BinaryOperator, Supplier)
* @see #toMap(Function, Function, BinaryOperator)
*/
public static <T, K, U>
Collector<T, ConcurrentMap<K,U>> toConcurrentMap(Function<? super T, ? extends K> keyMapper,
Function<? super T, ? extends U> valueMapper,
BinaryOperator<U> mergeFunction) {
return toConcurrentMap(keyMapper, valueMapper, mergeFunction, ConcurrentHashMap::new);
}
/**
* Accumulate elements into a {@code ConcurrentMap} whose keys and values
* are the result of applying mapping functions to the input elements. If
* the mapped keys contains duplicates (according to {@link Object#equals(Object)}),
* the value mapping function is applied to each equal element, and the
* results are merged using the provided merging function. The
* {@code ConcurrentMap} is created by a provided supplier function.
*
* <p>This is a {@link Collector.Characteristics#CONCURRENT concurrent} and
* {@link Collector.Characteristics#UNORDERED unordered} Collector.
*
* @param <T> the type of the input elements
* @param <K> the output type of the key mapping function
* @param <U> the output type of the value mapping function
* @param <M> the type of the resulting {@code ConcurrentMap}
* @param keyMapper a mapping function to produce keys
* @param valueMapper a mapping function to produce values
* @param mergeFunction a merge function, used to resolve collisions between
* values associated with the same key, as supplied
* to {@link Map#merge(Object, Object, BiFunction)}
* @param mapSupplier a function which returns a new, empty {@code Map} into
* which the results will be inserted
* @return a concurrent {@code Collector} which collects elements into a
* {@code ConcurrentMap} whose keys are the result of applying a key mapping
* function to the input elements, and whose values are the result of
* applying a value mapping function to all input elements equal to the key
* and combining them using the merge function
*
* @see #toConcurrentMap(Function, Function)
* @see #toConcurrentMap(Function, Function, BinaryOperator)
* @see #toMap(Function, Function, BinaryOperator, Supplier)
*/
public static <T, K, U, M extends ConcurrentMap<K, U>>
Collector<T, M> toConcurrentMap(Function<? super T, ? extends K> keyMapper,
Function<? super T, ? extends U> valueMapper,
BinaryOperator<U> mergeFunction,
Supplier<M> mapSupplier) {
BiFunction<M, T, M> accumulator = (map, element) -> {
map.merge(keyMapper.apply(element), valueMapper.apply(element), mergeFunction);
return map;
};
return new CollectorImpl<>(mapSupplier, accumulator, mapMerger(mergeFunction), CH_CONCURRENT);
}
/**
* Returns a {@code Collector} which applies an {@code int}-producing
* mapping function to each input element, and returns summary statistics
* for the resulting values.
*
* @param <T> the type of the input elements
* @param mapper a mapping function to apply to each element
* @return a {@code Collector} implementing the summary-statistics reduction
*
* @see #toDoubleSummaryStatistics(ToDoubleFunction)
* @see #toLongSummaryStatistics(ToLongFunction)
*/
public static <T>
Collector<T, IntSummaryStatistics> toIntSummaryStatistics(ToIntFunction<? super T> mapper) {
return new CollectorImpl<>(IntSummaryStatistics::new,
(r, t) -> { r.accept(mapper.applyAsInt(t)); return r; },
(l, r) -> { l.combine(r); return l; }, CH_STRICT);
}
/**
* Returns a {@code Collector} which applies an {@code long}-producing
* mapping function to each input element, and returns summary statistics
* for the resulting values.
*
* @param <T> the type of the input elements
* @param mapper the mapping function to apply to each element
* @return a {@code Collector} implementing the summary-statistics reduction
*
* @see #toDoubleSummaryStatistics(ToDoubleFunction)
* @see #toIntSummaryStatistics(ToIntFunction)
*/
public static <T>
Collector<T, LongSummaryStatistics> toLongSummaryStatistics(ToLongFunction<? super T> mapper) {
return new CollectorImpl<>(LongSummaryStatistics::new,
(r, t) -> { r.accept(mapper.applyAsLong(t)); return r; },
(l, r) -> { l.combine(r); return l; }, CH_STRICT);
}
/**
* Returns a {@code Collector} which applies an {@code double}-producing
* mapping function to each input element, and returns summary statistics
* for the resulting values.
*
* @param <T> the type of the input elements
* @param mapper a mapping function to apply to each element
* @return a {@code Collector} implementing the summary-statistics reduction
*
* @see #toLongSummaryStatistics(ToLongFunction)
* @see #toIntSummaryStatistics(ToIntFunction)
*/
public static <T>
Collector<T, DoubleSummaryStatistics> toDoubleSummaryStatistics(ToDoubleFunction<? super T> mapper) {
return new CollectorImpl<>(DoubleSummaryStatistics::new,
(r, t) -> { r.accept(mapper.applyAsDouble(t)); return r; },
(l, r) -> { l.combine(r); return l; }, CH_STRICT);
}
/**
* Implementation class used by partitioningBy.
*/
private static final class Partition<T>
extends AbstractMap<Boolean, T>
implements Map<Boolean, T> {
T forTrue;
T forFalse;
Partition(T forTrue, T forFalse) {
this.forTrue = forTrue;
this.forFalse = forFalse;
}
@Override
public Set<Map.Entry<Boolean, T>> entrySet() {
return new AbstractSet<Map.Entry<Boolean, T>>() {
@Override
public Iterator<Map.Entry<Boolean, T>> iterator() {
return new Iterator<Map.Entry<Boolean, T>>() {
int state = 0;
@Override
public boolean hasNext() {
return state < 2;
}
@Override
public Map.Entry<Boolean, T> next() {
if (state >= 2)
throw new NoSuchElementException();
return (state++ == 0)
? new SimpleImmutableEntry<>(false, forFalse)
: new SimpleImmutableEntry<>(true, forTrue);
}
};
}
@Override
public int size() {
return 2;
}
};
}
}
}