ojluni/src/test/java/util/stream/TestDoubleSumAverage.java - platform/libcore - Git at Google

 /*
  * Copyright (c) 2013, 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.
  *
  * 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
  * or visit www.oracle.com if you need additional information or have any
  * questions.
  */

 import java.util.*;
 import java.util.function.*;
 import java.util.stream.*;

 import static java.lang.Double.*;

 /*
  * @test
  * @bug 8006572 8030212
  * @summary Test for use of non-naive summation in stream-related sum and average operations.
  */
 public class TestDoubleSumAverage {
     public static void main(String... args) {
         int failures = 0;

         failures += testZeroAverageOfNonEmptyStream();
         failures += testForCompenstation();
         failures += testNonfiniteSum();

         if (failures > 0) {
             throw new RuntimeException("Found " + failures + " numerical failure(s).");
         }
     }

     /**
      * Test to verify that a non-empty stream with a zero average is non-empty.
      */
     private static int testZeroAverageOfNonEmptyStream() {
         Supplier<DoubleStream> ds = () -> DoubleStream.iterate(0.0, e -> 0.0).limit(10);

         return  compareUlpDifference(0.0, ds.get().average().getAsDouble(), 0);
     }

     /**
      * Compute the sum and average of a sequence of double values in
      * various ways and report an error if naive summation is used.
      */
     private static int testForCompenstation() {
         int failures = 0;

         /*
          * The exact sum of the test stream is 1 + 1e6*ulp(1.0) but a
          * naive summation algorithm will return 1.0 since (1.0 +
          * ulp(1.0)/2) will round to 1.0 again.
          */
         double base = 1.0;
         double increment = Math.ulp(base)/2.0;
         int count = 1_000_001;

         double expectedSum = base + (increment * (count - 1));
         double expectedAvg = expectedSum / count;

         // Factory for double a stream of [base, increment, ..., increment] limited to a size of count
         Supplier<DoubleStream> ds = () -> DoubleStream.iterate(base, e -> increment).limit(count);

         DoubleSummaryStatistics stats = ds.get().collect(DoubleSummaryStatistics::new,
                                                          DoubleSummaryStatistics::accept,
                                                          DoubleSummaryStatistics::combine);

         failures += compareUlpDifference(expectedSum, stats.getSum(), 3);
         failures += compareUlpDifference(expectedAvg, stats.getAverage(), 3);

         failures += compareUlpDifference(expectedSum,
                                          ds.get().sum(), 3);
         failures += compareUlpDifference(expectedAvg,
                                          ds.get().average().getAsDouble(), 3);

         failures += compareUlpDifference(expectedSum,
                                          ds.get().boxed().collect(Collectors.summingDouble(d -> d)), 3);
         failures += compareUlpDifference(expectedAvg,
                                          ds.get().boxed().collect(Collectors.averagingDouble(d -> d)),3);
         return failures;
     }

     private static int testNonfiniteSum() {
         int failures = 0;

         Map<Supplier<DoubleStream>, Double> testCases = new LinkedHashMap<>();
         testCases.put(() -> DoubleStream.of(MAX_VALUE, MAX_VALUE),   POSITIVE_INFINITY);
         testCases.put(() -> DoubleStream.of(-MAX_VALUE, -MAX_VALUE), NEGATIVE_INFINITY);

         testCases.put(() -> DoubleStream.of(1.0d, POSITIVE_INFINITY, 1.0d), POSITIVE_INFINITY);
         testCases.put(() -> DoubleStream.of(POSITIVE_INFINITY),             POSITIVE_INFINITY);
         testCases.put(() -> DoubleStream.of(POSITIVE_INFINITY, POSITIVE_INFINITY), POSITIVE_INFINITY);
         testCases.put(() -> DoubleStream.of(POSITIVE_INFINITY, POSITIVE_INFINITY, 0.0), POSITIVE_INFINITY);

         testCases.put(() -> DoubleStream.of(1.0d, NEGATIVE_INFINITY, 1.0d), NEGATIVE_INFINITY);
         testCases.put(() -> DoubleStream.of(NEGATIVE_INFINITY),             NEGATIVE_INFINITY);
         testCases.put(() -> DoubleStream.of(NEGATIVE_INFINITY, NEGATIVE_INFINITY), NEGATIVE_INFINITY);
         testCases.put(() -> DoubleStream.of(NEGATIVE_INFINITY, NEGATIVE_INFINITY, 0.0), NEGATIVE_INFINITY);

         testCases.put(() -> DoubleStream.of(1.0d, NaN, 1.0d),               NaN);
         testCases.put(() -> DoubleStream.of(NaN),                           NaN);
         testCases.put(() -> DoubleStream.of(1.0d, NEGATIVE_INFINITY, POSITIVE_INFINITY, 1.0d), NaN);
         testCases.put(() -> DoubleStream.of(1.0d, POSITIVE_INFINITY, NEGATIVE_INFINITY, 1.0d), NaN);
         testCases.put(() -> DoubleStream.of(POSITIVE_INFINITY, NaN), NaN);
         testCases.put(() -> DoubleStream.of(NEGATIVE_INFINITY, NaN), NaN);
         testCases.put(() -> DoubleStream.of(NaN, POSITIVE_INFINITY), NaN);
         testCases.put(() -> DoubleStream.of(NaN, NEGATIVE_INFINITY), NaN);

         for(Map.Entry<Supplier<DoubleStream>, Double> testCase : testCases.entrySet()) {
             Supplier<DoubleStream> ds = testCase.getKey();
             double expected = testCase.getValue();

             DoubleSummaryStatistics stats = ds.get().collect(DoubleSummaryStatistics::new,
                                                              DoubleSummaryStatistics::accept,
                                                              DoubleSummaryStatistics::combine);

             failures += compareUlpDifference(expected, stats.getSum(), 0);
             failures += compareUlpDifference(expected, stats.getAverage(), 0);

             failures += compareUlpDifference(expected, ds.get().sum(), 0);
             failures += compareUlpDifference(expected, ds.get().average().getAsDouble(), 0);

             failures += compareUlpDifference(expected, ds.get().boxed().collect(Collectors.summingDouble(d -> d)), 0);
             failures += compareUlpDifference(expected, ds.get().boxed().collect(Collectors.averagingDouble(d -> d)), 0);
         }

         return failures;
     }

     /**
      * Compute the ulp difference of two double values and compare against an error threshold.
      */
     private static int compareUlpDifference(double expected, double computed, double threshold) {
         if (!Double.isFinite(expected)) {
             // Handle NaN and infinity cases
             if (Double.compare(expected, computed) == 0)
                 return 0;
             else {
                 System.err.printf("Unexpected sum, %g rather than %g.%n",
                                   computed, expected);
                 return 1;
             }
         }

         double ulpDifference = Math.abs(expected - computed) / Math.ulp(expected);

         if (ulpDifference > threshold) {
             System.err.printf("Numerical summation error too large, %g ulps rather than %g.%n",
                               ulpDifference, threshold);
             return 1;
         } else
             return 0;
     }
 }
	/*
	* Copyright (c) 2013, 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.
	*
	* 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
	* or visit www.oracle.com if you need additional information or have any
	* questions.
	*/

	import java.util.*;
	import java.util.function.*;
	import java.util.stream.*;

	import static java.lang.Double.*;

	/*
	* @test
	* @bug 8006572 8030212
	* @summary Test for use of non-naive summation in stream-related sum and average operations.
	*/
	public class TestDoubleSumAverage {
	public static void main(String... args) {
	int failures = 0;

	failures += testZeroAverageOfNonEmptyStream();
	failures += testForCompenstation();
	failures += testNonfiniteSum();

	if (failures > 0) {
	throw new RuntimeException("Found " + failures + " numerical failure(s).");
	}
	}

	/**
	* Test to verify that a non-empty stream with a zero average is non-empty.
	*/
	private static int testZeroAverageOfNonEmptyStream() {
	Supplier<DoubleStream> ds = () -> DoubleStream.iterate(0.0, e -> 0.0).limit(10);

	return compareUlpDifference(0.0, ds.get().average().getAsDouble(), 0);
	}

	/**
	* Compute the sum and average of a sequence of double values in
	* various ways and report an error if naive summation is used.
	*/
	private static int testForCompenstation() {
	int failures = 0;

	/*
	* The exact sum of the test stream is 1 + 1e6*ulp(1.0) but a
	* naive summation algorithm will return 1.0 since (1.0 +
	* ulp(1.0)/2) will round to 1.0 again.
	*/
	double base = 1.0;
	double increment = Math.ulp(base)/2.0;
	int count = 1_000_001;

	double expectedSum = base + (increment * (count - 1));
	double expectedAvg = expectedSum / count;

	// Factory for double a stream of [base, increment, ..., increment] limited to a size of count
	Supplier<DoubleStream> ds = () -> DoubleStream.iterate(base, e -> increment).limit(count);

	DoubleSummaryStatistics stats = ds.get().collect(DoubleSummaryStatistics::new,
	DoubleSummaryStatistics::accept,
	DoubleSummaryStatistics::combine);

	failures += compareUlpDifference(expectedSum, stats.getSum(), 3);
	failures += compareUlpDifference(expectedAvg, stats.getAverage(), 3);

	failures += compareUlpDifference(expectedSum,
	ds.get().sum(), 3);
	failures += compareUlpDifference(expectedAvg,
	ds.get().average().getAsDouble(), 3);

	failures += compareUlpDifference(expectedSum,
	ds.get().boxed().collect(Collectors.summingDouble(d -> d)), 3);
	failures += compareUlpDifference(expectedAvg,
	ds.get().boxed().collect(Collectors.averagingDouble(d -> d)),3);
	return failures;
	}

	private static int testNonfiniteSum() {
	int failures = 0;

	Map<Supplier<DoubleStream>, Double> testCases = new LinkedHashMap<>();
	testCases.put(() -> DoubleStream.of(MAX_VALUE, MAX_VALUE), POSITIVE_INFINITY);
	testCases.put(() -> DoubleStream.of(-MAX_VALUE, -MAX_VALUE), NEGATIVE_INFINITY);

	testCases.put(() -> DoubleStream.of(1.0d, POSITIVE_INFINITY, 1.0d), POSITIVE_INFINITY);
	testCases.put(() -> DoubleStream.of(POSITIVE_INFINITY), POSITIVE_INFINITY);
	testCases.put(() -> DoubleStream.of(POSITIVE_INFINITY, POSITIVE_INFINITY), POSITIVE_INFINITY);
	testCases.put(() -> DoubleStream.of(POSITIVE_INFINITY, POSITIVE_INFINITY, 0.0), POSITIVE_INFINITY);

	testCases.put(() -> DoubleStream.of(1.0d, NEGATIVE_INFINITY, 1.0d), NEGATIVE_INFINITY);
	testCases.put(() -> DoubleStream.of(NEGATIVE_INFINITY), NEGATIVE_INFINITY);
	testCases.put(() -> DoubleStream.of(NEGATIVE_INFINITY, NEGATIVE_INFINITY), NEGATIVE_INFINITY);
	testCases.put(() -> DoubleStream.of(NEGATIVE_INFINITY, NEGATIVE_INFINITY, 0.0), NEGATIVE_INFINITY);

	testCases.put(() -> DoubleStream.of(1.0d, NaN, 1.0d), NaN);
	testCases.put(() -> DoubleStream.of(NaN), NaN);
	testCases.put(() -> DoubleStream.of(1.0d, NEGATIVE_INFINITY, POSITIVE_INFINITY, 1.0d), NaN);
	testCases.put(() -> DoubleStream.of(1.0d, POSITIVE_INFINITY, NEGATIVE_INFINITY, 1.0d), NaN);
	testCases.put(() -> DoubleStream.of(POSITIVE_INFINITY, NaN), NaN);
	testCases.put(() -> DoubleStream.of(NEGATIVE_INFINITY, NaN), NaN);
	testCases.put(() -> DoubleStream.of(NaN, POSITIVE_INFINITY), NaN);
	testCases.put(() -> DoubleStream.of(NaN, NEGATIVE_INFINITY), NaN);

	for(Map.Entry<Supplier<DoubleStream>, Double> testCase : testCases.entrySet()) {
	Supplier<DoubleStream> ds = testCase.getKey();
	double expected = testCase.getValue();

	DoubleSummaryStatistics stats = ds.get().collect(DoubleSummaryStatistics::new,
	DoubleSummaryStatistics::accept,
	DoubleSummaryStatistics::combine);

	failures += compareUlpDifference(expected, stats.getSum(), 0);
	failures += compareUlpDifference(expected, stats.getAverage(), 0);

	failures += compareUlpDifference(expected, ds.get().sum(), 0);
	failures += compareUlpDifference(expected, ds.get().average().getAsDouble(), 0);

	failures += compareUlpDifference(expected, ds.get().boxed().collect(Collectors.summingDouble(d -> d)), 0);
	failures += compareUlpDifference(expected, ds.get().boxed().collect(Collectors.averagingDouble(d -> d)), 0);
	}

	return failures;
	}

	/**
	* Compute the ulp difference of two double values and compare against an error threshold.
	*/
	private static int compareUlpDifference(double expected, double computed, double threshold) {
	if (!Double.isFinite(expected)) {
	// Handle NaN and infinity cases
	if (Double.compare(expected, computed) == 0)
	return 0;
	else {
	System.err.printf("Unexpected sum, %g rather than %g.%n",
	computed, expected);
	return 1;
	}
	}

	double ulpDifference = Math.abs(expected - computed) / Math.ulp(expected);

	if (ulpDifference > threshold) {
	System.err.printf("Numerical summation error too large, %g ulps rather than %g.%n",
	ulpDifference, threshold);
	return 1;
	} else
	return 0;
	}
	}