SplittableUniformRandomProvider.java
/*
* Licensed to the Apache Software Foundation (ASF) under one or more
* contributor license agreements. See the NOTICE file distributed with
* this work for additional information regarding copyright ownership.
* The ASF licenses this file to You under the Apache License, Version 2.0
* (the "License"); you may not use this file except in compliance with
* the License. You may obtain a copy of the License at
*
* http://www.apache.org/licenses/LICENSE-2.0
*
* Unless required by applicable law or agreed to in writing, software
* distributed under the License is distributed on an "AS IS" BASIS,
* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
* See the License for the specific language governing permissions and
* limitations under the License.
*/
package org.apache.commons.rng;
import java.util.Objects;
import java.util.stream.DoubleStream;
import java.util.stream.IntStream;
import java.util.stream.LongStream;
import java.util.stream.Stream;
import java.util.stream.StreamSupport;
/**
* Applies to generators that can be split into two objects (the original and a new instance)
* each of which implements the same interface (and can be recursively split indefinitely).
* It is assumed that the two generators resulting from a split can be used concurrently on
* different threads.
*
* <p>Ideally all generators produced by recursive splitting from the original object are
* statistically independent and individually uniform. In this case it would be expected that
* the set of values collectively generated from a group of split generators would have the
* same statistical properties as the same number of values produced from a single generator
* object.
*
* @since 1.5
*/
public interface SplittableUniformRandomProvider extends UniformRandomProvider {
/**
* Creates a new random generator, split off from this one, that implements
* the {@link SplittableUniformRandomProvider} interface.
*
* <p>The current generator may be used a source of randomness to initialise the new instance.
* In this case repeat invocations of this method will return objects with a different
* initial state that are expected to be statistically independent.
*
* @return A new instance.
*/
default SplittableUniformRandomProvider split() {
return split(this);
}
/**
* Creates a new random generator, split off from this one, that implements
* the {@link SplittableUniformRandomProvider} interface.
*
* @param source A source of randomness used to initialise the new instance.
* @return A new instance.
* @throws NullPointerException if {@code source} is null
*/
SplittableUniformRandomProvider split(UniformRandomProvider source);
/**
* Returns an effectively unlimited stream of new random generators, each of which
* implements the {@link SplittableUniformRandomProvider} interface.
*
* <p>The current generator may be used a source of randomness to initialise the new instances.
*
* @return a stream of random generators.
*/
default Stream<SplittableUniformRandomProvider> splits() {
return splits(Long.MAX_VALUE, this);
}
/**
* Returns an effectively unlimited stream of new random generators, each of which
* implements the {@link SplittableUniformRandomProvider} interface.
*
* @param source A source of randomness used to initialise the new instances; this may
* be split to provide a source of randomness across a parallel stream.
* @return a stream of random generators.
* @throws NullPointerException if {@code source} is null
*/
default Stream<SplittableUniformRandomProvider> splits(SplittableUniformRandomProvider source) {
return this.splits(Long.MAX_VALUE, source);
}
/**
* Returns a stream producing the given {@code streamSize} number of new random
* generators, each of which implements the {@link SplittableUniformRandomProvider}
* interface.
*
* <p>The current generator may be used a source of randomness to initialise the new instances.
*
* @param streamSize Number of objects to generate.
* @return a stream of random generators; the stream is limited to the given
* {@code streamSize}.
* @throws IllegalArgumentException if {@code streamSize} is negative.
*/
default Stream<SplittableUniformRandomProvider> splits(long streamSize) {
return splits(streamSize, this);
}
/**
* Returns a stream producing the given {@code streamSize} number of new random
* generators, each of which implements the {@link SplittableUniformRandomProvider}
* interface.
*
* @param streamSize Number of objects to generate.
* @param source A source of randomness used to initialise the new instances; this may
* be split to provide a source of randomness across a parallel stream.
* @return a stream of random generators; the stream is limited to the given
* {@code streamSize}.
* @throws IllegalArgumentException if {@code streamSize} is negative.
* @throws NullPointerException if {@code source} is null
*/
default Stream<SplittableUniformRandomProvider> splits(long streamSize,
SplittableUniformRandomProvider source) {
UniformRandomProviderSupport.validateStreamSize(streamSize);
Objects.requireNonNull(source, "source");
return StreamSupport.stream(
new UniformRandomProviderSupport.ProviderSplitsSpliterator(0, streamSize, source, this), false);
}
@Override
default IntStream ints() {
return ints(Long.MAX_VALUE);
}
@Override
default IntStream ints(int origin, int bound) {
return ints(Long.MAX_VALUE, origin, bound);
}
@Override
default IntStream ints(long streamSize) {
UniformRandomProviderSupport.validateStreamSize(streamSize);
return StreamSupport.intStream(
new UniformRandomProviderSupport.ProviderIntsSpliterator(
0, streamSize, this, UniformRandomProvider::nextInt), false);
}
@Override
default IntStream ints(long streamSize, int origin, int bound) {
UniformRandomProviderSupport.validateStreamSize(streamSize);
UniformRandomProviderSupport.validateRange(origin, bound);
return StreamSupport.intStream(
new UniformRandomProviderSupport.ProviderIntsSpliterator(
0, streamSize, this, rng -> rng.nextInt(origin, bound)), false);
}
@Override
default LongStream longs() {
return longs(Long.MAX_VALUE);
}
@Override
default LongStream longs(long origin, long bound) {
return longs(Long.MAX_VALUE, origin, bound);
}
@Override
default LongStream longs(long streamSize) {
UniformRandomProviderSupport.validateStreamSize(streamSize);
return StreamSupport.longStream(
new UniformRandomProviderSupport.ProviderLongsSpliterator(
0, streamSize, this, UniformRandomProvider::nextLong), false);
}
@Override
default LongStream longs(long streamSize, long origin, long bound) {
UniformRandomProviderSupport.validateStreamSize(streamSize);
UniformRandomProviderSupport.validateRange(origin, bound);
return StreamSupport.longStream(
new UniformRandomProviderSupport.ProviderLongsSpliterator(
0, streamSize, this, rng -> rng.nextLong(origin, bound)), false);
}
@Override
default DoubleStream doubles() {
return doubles(Long.MAX_VALUE);
}
@Override
default DoubleStream doubles(double origin, double bound) {
return doubles(Long.MAX_VALUE, origin, bound);
}
@Override
default DoubleStream doubles(long streamSize) {
UniformRandomProviderSupport.validateStreamSize(streamSize);
return StreamSupport.doubleStream(
new UniformRandomProviderSupport.ProviderDoublesSpliterator(
0, streamSize, this, UniformRandomProvider::nextDouble), false);
}
@Override
default DoubleStream doubles(long streamSize, double origin, double bound) {
UniformRandomProviderSupport.validateStreamSize(streamSize);
UniformRandomProviderSupport.validateRange(origin, bound);
return StreamSupport.doubleStream(
new UniformRandomProviderSupport.ProviderDoublesSpliterator(
0, streamSize, this, rng -> rng.nextDouble(origin, bound)), false);
}
}