/* * Written by Doug Lea with assistance from members of JCP JSR-166 * Expert Group and released to the public domain, as explained at * http://creativecommons.org/publicdomain/zero/1.0/ */ import junit.framework.*; import java.util.*; import java.util.function.*; import java.util.concurrent.atomic.LongAdder; import java.util.concurrent.ConcurrentHashMap; public class ConcurrentHashMap8Test extends JSR166TestCase { public static void main(String[] args) { junit.textui.TestRunner.run(suite()); } public static Test suite() { return new TestSuite(ConcurrentHashMap8Test.class); } /** * Returns a new map from Integers 1-5 to Strings "A"-"E". */ private static ConcurrentHashMap map5() { ConcurrentHashMap map = new ConcurrentHashMap(5); assertTrue(map.isEmpty()); map.put(one, "A"); map.put(two, "B"); map.put(three, "C"); map.put(four, "D"); map.put(five, "E"); assertFalse(map.isEmpty()); assertEquals(5, map.size()); return map; } /** * getOrDefault returns value if present, else default */ public void testGetOrDefault() { ConcurrentHashMap map = map5(); assertEquals(map.getOrDefault(one, "Z"), "A"); assertEquals(map.getOrDefault(six, "Z"), "Z"); } /** * computeIfAbsent adds when the given key is not present */ public void testComputeIfAbsent() { ConcurrentHashMap map = map5(); map.computeIfAbsent(six, (x) -> "Z"); assertTrue(map.containsKey(six)); } /** * computeIfAbsent does not replace if the key is already present */ public void testComputeIfAbsent2() { ConcurrentHashMap map = map5(); assertEquals("A", map.computeIfAbsent(one, (x) -> "Z")); } /** * computeIfAbsent does not add if function returns null */ public void testComputeIfAbsent3() { ConcurrentHashMap map = map5(); map.computeIfAbsent(six, (x) -> null); assertFalse(map.containsKey(six)); } /** * computeIfPresent does not replace if the key is already present */ public void testComputeIfPresent() { ConcurrentHashMap map = map5(); map.computeIfPresent(six, (x, y) -> "Z"); assertFalse(map.containsKey(six)); } /** * computeIfPresent adds when the given key is not present */ public void testComputeIfPresent2() { ConcurrentHashMap map = map5(); assertEquals("Z", map.computeIfPresent(one, (x, y) -> "Z")); } /** * compute does not replace if the function returns null */ public void testCompute() { ConcurrentHashMap map = map5(); map.compute(six, (x, y) -> null); assertFalse(map.containsKey(six)); } /** * compute adds when the given key is not present */ public void testCompute2() { ConcurrentHashMap map = map5(); assertEquals("Z", map.compute(six, (x, y) -> "Z")); } /** * compute replaces when the given key is present */ public void testCompute3() { ConcurrentHashMap map = map5(); assertEquals("Z", map.compute(one, (x, y) -> "Z")); } /** * compute removes when the given key is present and function returns null */ public void testCompute4() { ConcurrentHashMap map = map5(); map.compute(one, (x, y) -> null); assertFalse(map.containsKey(one)); } /** * merge adds when the given key is not present */ public void testMerge1() { ConcurrentHashMap map = map5(); assertEquals("Y", map.merge(six, "Y", (x, y) -> "Z")); } /** * merge replaces when the given key is present */ public void testMerge2() { ConcurrentHashMap map = map5(); assertEquals("Z", map.merge(one, "Y", (x, y) -> "Z")); } /** * merge removes when the given key is present and function returns null */ public void testMerge3() { ConcurrentHashMap map = map5(); map.merge(one, "Y", (x, y) -> null); assertFalse(map.containsKey(one)); } static Set populatedSet(int n) { Set a = ConcurrentHashMap.newKeySet(); assertTrue(a.isEmpty()); for (int i = 0; i < n; i++) a.add(i); assertFalse(a.isEmpty()); assertEquals(n, a.size()); return a; } static Set populatedSet(Integer[] elements) { Set a = ConcurrentHashMap.newKeySet(); assertTrue(a.isEmpty()); for (int i = 0; i < elements.length; i++) a.add(elements[i]); assertFalse(a.isEmpty()); assertEquals(elements.length, a.size()); return a; } /** * Default-constructed set is empty */ public void testNewKeySet() { Set a = ConcurrentHashMap.newKeySet(); assertTrue(a.isEmpty()); } /** * keySet.addAll adds each element from the given collection */ public void testAddAll() { Set full = populatedSet(3); Vector v = new Vector(); v.add(three); v.add(four); v.add(five); full.addAll(v); assertEquals(6, full.size()); } /** * keySet.addAll adds each element from the given collection that did not * already exist in the set */ public void testAddAll2() { Set full = populatedSet(3); Vector v = new Vector(); v.add(three); v.add(four); v.add(one); // will not add this element full.addAll(v); assertEquals(5, full.size()); } /** * keySet.add will not add the element if it already exists in the set */ public void testAdd2() { Set full = populatedSet(3); full.add(one); assertEquals(3, full.size()); } /** * keySet.add adds the element when it does not exist in the set */ public void testAdd3() { Set full = populatedSet(3); full.add(three); assertTrue(full.contains(three)); } /** * keyset.clear removes all elements from the set */ public void testClear() { Set full = populatedSet(3); full.clear(); assertEquals(0, full.size()); } /** * keyset.contains returns true for added elements */ public void testContains() { Set full = populatedSet(3); assertTrue(full.contains(one)); assertFalse(full.contains(five)); } /** * KeySets with equal elements are equal */ public void testEquals() { Set a = populatedSet(3); Set b = populatedSet(3); assertTrue(a.equals(b)); assertTrue(b.equals(a)); assertEquals(a.hashCode(), b.hashCode()); a.add(m1); assertFalse(a.equals(b)); assertFalse(b.equals(a)); b.add(m1); assertTrue(a.equals(b)); assertTrue(b.equals(a)); assertEquals(a.hashCode(), b.hashCode()); } /** * KeySet.containsAll returns true for collections with subset of elements */ public void testContainsAll() { Set full = populatedSet(3); Vector v = new Vector(); v.add(one); v.add(two); assertTrue(full.containsAll(v)); v.add(six); assertFalse(full.containsAll(v)); } /** * KeySet.isEmpty is true when empty, else false */ public void testIsEmpty() { Set empty = ConcurrentHashMap.newKeySet(); Set full = populatedSet(3); assertTrue(empty.isEmpty()); assertFalse(full.isEmpty()); } /** * KeySet.iterator() returns an iterator containing the elements of the * set */ public void testIterator() { Collection empty = ConcurrentHashMap.newKeySet(); int size = 20; assertFalse(empty.iterator().hasNext()); try { empty.iterator().next(); shouldThrow(); } catch (NoSuchElementException success) {} Integer[] elements = new Integer[size]; for (int i = 0; i < size; i++) elements[i] = i; Collections.shuffle(Arrays.asList(elements)); Collection full = populatedSet(elements); Iterator it = full.iterator(); for (int j = 0; j < size; j++) { assertTrue(it.hasNext()); it.next(); } assertFalse(it.hasNext()); try { it.next(); shouldThrow(); } catch (NoSuchElementException success) {} } /** * KeySet.iterator.remove removes current element */ public void testIteratorRemove() { Set q = populatedSet(3); Iterator it = q.iterator(); Object removed = it.next(); it.remove(); it = q.iterator(); assertFalse(it.next().equals(removed)); assertFalse(it.next().equals(removed)); assertFalse(it.hasNext()); } /** * KeySet.toString holds toString of elements */ public void testToString() { assertEquals("[]", ConcurrentHashMap.newKeySet().toString()); Set full = populatedSet(3); String s = full.toString(); for (int i = 0; i < 3; ++i) assertTrue(s.contains(String.valueOf(i))); } /** * KeySet.removeAll removes all elements from the given collection */ public void testRemoveAll() { Set full = populatedSet(3); Vector v = new Vector(); v.add(one); v.add(two); full.removeAll(v); assertEquals(1, full.size()); } /** * KeySet.remove removes an element */ public void testRemove() { Set full = populatedSet(3); full.remove(one); assertFalse(full.contains(one)); assertEquals(2, full.size()); } /** * keySet.size returns the number of elements */ public void testSize() { Set empty = ConcurrentHashMap.newKeySet(); Set full = populatedSet(3); assertEquals(3, full.size()); assertEquals(0, empty.size()); } /** * KeySet.toArray() returns an Object array containing all elements from * the set */ public void testToArray() { Object[] a = ConcurrentHashMap.newKeySet().toArray(); assertTrue(Arrays.equals(new Object[0], a)); assertSame(Object[].class, a.getClass()); int size = 20; Integer[] elements = new Integer[size]; for (int i = 0; i < size; i++) elements[i] = i; Collections.shuffle(Arrays.asList(elements)); Collection full = populatedSet(elements); assertTrue(Arrays.asList(elements).containsAll(Arrays.asList(full.toArray()))); assertTrue(full.containsAll(Arrays.asList(full.toArray()))); assertSame(Object[].class, full.toArray().getClass()); } /** * toArray(Integer array) returns an Integer array containing all * elements from the set */ public void testToArray2() { Collection empty = ConcurrentHashMap.newKeySet(); Integer[] a; int size = 20; a = new Integer[0]; assertSame(a, empty.toArray(a)); a = new Integer[size/2]; Arrays.fill(a, 42); assertSame(a, empty.toArray(a)); assertNull(a[0]); for (int i = 1; i < a.length; i++) assertEquals(42, (int) a[i]); Integer[] elements = new Integer[size]; for (int i = 0; i < size; i++) elements[i] = i; Collections.shuffle(Arrays.asList(elements)); Collection full = populatedSet(elements); Arrays.fill(a, 42); assertTrue(Arrays.asList(elements).containsAll(Arrays.asList(full.toArray(a)))); for (int i = 0; i < a.length; i++) assertEquals(42, (int) a[i]); assertSame(Integer[].class, full.toArray(a).getClass()); a = new Integer[size]; Arrays.fill(a, 42); assertSame(a, full.toArray(a)); assertTrue(Arrays.asList(elements).containsAll(Arrays.asList(full.toArray(a)))); } /** * A deserialized serialized set is equal */ public void testSerialization() throws Exception { int size = 20; Set x = populatedSet(size); Set y = serialClone(x); assertNotSame(x, y); assertEquals(x.size(), y.size()); assertEquals(x.toString(), y.toString()); assertTrue(Arrays.equals(x.toArray(), y.toArray())); assertEquals(x, y); assertEquals(y, x); } static final int SIZE = 10000; static ConcurrentHashMap longMap; static ConcurrentHashMap longMap() { if (longMap == null) { longMap = new ConcurrentHashMap(SIZE); for (int i = 0; i < SIZE; ++i) longMap.put(Long.valueOf(i), Long.valueOf(2 *i)); } return longMap; } // explicit function class to avoid type inference problems static class AddKeys implements BiFunction, Map.Entry, Map.Entry> { public Map.Entry apply(Map.Entry x, Map.Entry y) { return new AbstractMap.SimpleEntry (Long.valueOf(x.getKey().longValue() + y.getKey().longValue()), Long.valueOf(1L)); } } /** * forEachKeySequentially traverses all keys */ public void testForEachKeySequentially() { LongAdder adder = new LongAdder(); ConcurrentHashMap m = longMap(); m.forEachKey(Long.MAX_VALUE, (Long x) -> adder.add(x.longValue())); assertEquals(adder.sum(), SIZE * (SIZE - 1) / 2); } /** * forEachValueSequentially traverses all values */ public void testForEachValueSequentially() { LongAdder adder = new LongAdder(); ConcurrentHashMap m = longMap(); m.forEachValue(Long.MAX_VALUE, (Long x) -> adder.add(x.longValue())); assertEquals(adder.sum(), SIZE * (SIZE - 1)); } /** * forEachSequentially traverses all mappings */ public void testForEachSequentially() { LongAdder adder = new LongAdder(); ConcurrentHashMap m = longMap(); m.forEach(Long.MAX_VALUE, (Long x, Long y) -> adder.add(x.longValue() + y.longValue())); assertEquals(adder.sum(), 3 * SIZE * (SIZE - 1) / 2); } /** * forEachEntrySequentially traverses all entries */ public void testForEachEntrySequentially() { LongAdder adder = new LongAdder(); ConcurrentHashMap m = longMap(); m.forEachEntry(Long.MAX_VALUE, (Map.Entry e) -> adder.add(e.getKey().longValue() + e.getValue().longValue())); assertEquals(adder.sum(), 3 * SIZE * (SIZE - 1) / 2); } /** * forEachKeyInParallel traverses all keys */ public void testForEachKeyInParallel() { LongAdder adder = new LongAdder(); ConcurrentHashMap m = longMap(); m.forEachKey(1L, (Long x) -> adder.add(x.longValue())); assertEquals(adder.sum(), SIZE * (SIZE - 1) / 2); } /** * forEachValueInParallel traverses all values */ public void testForEachValueInParallel() { LongAdder adder = new LongAdder(); ConcurrentHashMap m = longMap(); m.forEachValue(1L, (Long x) -> adder.add(x.longValue())); assertEquals(adder.sum(), SIZE * (SIZE - 1)); } /** * forEachInParallel traverses all mappings */ public void testForEachInParallel() { LongAdder adder = new LongAdder(); ConcurrentHashMap m = longMap(); m.forEach(1L, (Long x, Long y) -> adder.add(x.longValue() + y.longValue())); assertEquals(adder.sum(), 3 * SIZE * (SIZE - 1) / 2); } /** * forEachEntryInParallel traverses all entries */ public void testForEachEntryInParallel() { LongAdder adder = new LongAdder(); ConcurrentHashMap m = longMap(); m.forEachEntry(1L, (Map.Entry e) -> adder.add(e.getKey().longValue() + e.getValue().longValue())); assertEquals(adder.sum(), 3 * SIZE * (SIZE - 1) / 2); } /** * Mapped forEachKeySequentially traverses the given * transformations of all keys */ public void testMappedForEachKeySequentially() { LongAdder adder = new LongAdder(); ConcurrentHashMap m = longMap(); m.forEachKey(Long.MAX_VALUE, (Long x) -> Long.valueOf(4 * x.longValue()), (Long x) -> adder.add(x.longValue())); assertEquals(adder.sum(), 4 * SIZE * (SIZE - 1) / 2); } /** * Mapped forEachValueSequentially traverses the given * transformations of all values */ public void testMappedForEachValueSequentially() { LongAdder adder = new LongAdder(); ConcurrentHashMap m = longMap(); m.forEachValue(Long.MAX_VALUE, (Long x) -> Long.valueOf(4 * x.longValue()), (Long x) -> adder.add(x.longValue())); assertEquals(adder.sum(), 4 * SIZE * (SIZE - 1)); } /** * Mapped forEachSequentially traverses the given * transformations of all mappings */ public void testMappedForEachSequentially() { LongAdder adder = new LongAdder(); ConcurrentHashMap m = longMap(); m.forEach(Long.MAX_VALUE, (Long x, Long y) -> Long.valueOf(x.longValue() + y.longValue()), (Long x) -> adder.add(x.longValue())); assertEquals(adder.sum(), 3 * SIZE * (SIZE - 1) / 2); } /** * Mapped forEachEntrySequentially traverses the given * transformations of all entries */ public void testMappedForEachEntrySequentially() { LongAdder adder = new LongAdder(); ConcurrentHashMap m = longMap(); m.forEachEntry(Long.MAX_VALUE, (Map.Entry e) -> Long.valueOf(e.getKey().longValue() + e.getValue().longValue()), (Long x) -> adder.add(x.longValue())); assertEquals(adder.sum(), 3 * SIZE * (SIZE - 1) / 2); } /** * Mapped forEachKeyInParallel traverses the given * transformations of all keys */ public void testMappedForEachKeyInParallel() { LongAdder adder = new LongAdder(); ConcurrentHashMap m = longMap(); m.forEachKey(1L, (Long x) -> Long.valueOf(4 * x.longValue()), (Long x) -> adder.add(x.longValue())); assertEquals(adder.sum(), 4 * SIZE * (SIZE - 1) / 2); } /** * Mapped forEachValueInParallel traverses the given * transformations of all values */ public void testMappedForEachValueInParallel() { LongAdder adder = new LongAdder(); ConcurrentHashMap m = longMap(); m.forEachValue(1L, (Long x) -> Long.valueOf(4 * x.longValue()), (Long x) -> adder.add(x.longValue())); assertEquals(adder.sum(), 4 * SIZE * (SIZE - 1)); } /** * Mapped forEachInParallel traverses the given * transformations of all mappings */ public void testMappedForEachInParallel() { LongAdder adder = new LongAdder(); ConcurrentHashMap m = longMap(); m.forEach(1L, (Long x, Long y) -> Long.valueOf(x.longValue() + y.longValue()), (Long x) -> adder.add(x.longValue())); assertEquals(adder.sum(), 3 * SIZE * (SIZE - 1) / 2); } /** * Mapped forEachEntryInParallel traverses the given * transformations of all entries */ public void testMappedForEachEntryInParallel() { LongAdder adder = new LongAdder(); ConcurrentHashMap m = longMap(); m.forEachEntry(1L, (Map.Entry e) -> Long.valueOf(e.getKey().longValue() + e.getValue().longValue()), (Long x) -> adder.add(x.longValue())); assertEquals(adder.sum(), 3 * SIZE * (SIZE - 1) / 2); } /** * reduceKeysSequentially accumulates across all keys, */ public void testReduceKeysSequentially() { ConcurrentHashMap m = longMap(); Long r; r = m.reduceKeys(Long.MAX_VALUE, (Long x, Long y) -> Long.valueOf(x.longValue() + y.longValue())); assertEquals((long)r, (long)SIZE * (SIZE - 1) / 2); } /** * reduceValuesSequentially accumulates across all values */ public void testReduceValuesSequentially() { ConcurrentHashMap m = longMap(); Long r; r = m.reduceKeys(Long.MAX_VALUE, (Long x, Long y) -> Long.valueOf(x.longValue() + y.longValue())); assertEquals((long)r, (long)SIZE * (SIZE - 1) / 2); } /** * reduceEntriesSequentially accumulates across all entries */ public void testReduceEntriesSequentially() { ConcurrentHashMap m = longMap(); Map.Entry r; r = m.reduceEntries(Long.MAX_VALUE, new AddKeys()); assertEquals(r.getKey().longValue(), (long)SIZE * (SIZE - 1) / 2); } /** * reduceKeysInParallel accumulates across all keys */ public void testReduceKeysInParallel() { ConcurrentHashMap m = longMap(); Long r; r = m.reduceKeys(1L, (Long x, Long y) -> Long.valueOf(x.longValue() + y.longValue())); assertEquals((long)r, (long)SIZE * (SIZE - 1) / 2); } /** * reduceValuesInParallel accumulates across all values */ public void testReduceValuesInParallel() { ConcurrentHashMap m = longMap(); Long r; r = m.reduceValues(1L, (Long x, Long y) -> Long.valueOf(x.longValue() + y.longValue())); assertEquals((long)r, (long)SIZE * (SIZE - 1)); } /** * reduceEntriesInParallel accumulate across all entries */ public void testReduceEntriesInParallel() { ConcurrentHashMap m = longMap(); Map.Entry r; r = m.reduceEntries(1L, new AddKeys()); assertEquals(r.getKey().longValue(), (long)SIZE * (SIZE - 1) / 2); } /** * Mapped reduceKeysSequentially accumulates mapped keys */ public void testMapReduceKeysSequentially() { ConcurrentHashMap m = longMap(); Long r = m.reduceKeys(Long.MAX_VALUE, (Long x) -> Long.valueOf(4 * x.longValue()), (Long x, Long y) -> Long.valueOf(x.longValue() + y.longValue())); assertEquals((long)r, (long)4 * SIZE * (SIZE - 1) / 2); } /** * Mapped reduceValuesSequentially accumulates mapped values */ public void testMapReduceValuesSequentially() { ConcurrentHashMap m = longMap(); Long r = m.reduceValues(Long.MAX_VALUE, (Long x) -> Long.valueOf(4 * x.longValue()), (Long x, Long y) -> Long.valueOf(x.longValue() + y.longValue())); assertEquals((long)r, (long)4 * SIZE * (SIZE - 1)); } /** * reduceSequentially accumulates across all transformed mappings */ public void testMappedReduceSequentially() { ConcurrentHashMap m = longMap(); Long r = m.reduce(Long.MAX_VALUE, (Long x, Long y) -> Long.valueOf(x.longValue() + y.longValue()), (Long x, Long y) -> Long.valueOf(x.longValue() + y.longValue())); assertEquals((long)r, (long)3 * SIZE * (SIZE - 1) / 2); } /** * Mapped reduceKeysInParallel, accumulates mapped keys */ public void testMapReduceKeysInParallel() { ConcurrentHashMap m = longMap(); Long r = m.reduceKeys(1L, (Long x) -> Long.valueOf(4 * x.longValue()), (Long x, Long y) -> Long.valueOf(x.longValue() + y.longValue())); assertEquals((long)r, (long)4 * SIZE * (SIZE - 1) / 2); } /** * Mapped reduceValuesInParallel accumulates mapped values */ public void testMapReduceValuesInParallel() { ConcurrentHashMap m = longMap(); Long r = m.reduceValues(1L, (Long x) -> Long.valueOf(4 * x.longValue()), (Long x, Long y) -> Long.valueOf(x.longValue() + y.longValue())); assertEquals((long)r, (long)4 * SIZE * (SIZE - 1)); } /** * reduceInParallel accumulate across all transformed mappings */ public void testMappedReduceInParallel() { ConcurrentHashMap m = longMap(); Long r; r = m.reduce(1L, (Long x, Long y) -> Long.valueOf(x.longValue() + y.longValue()), (Long x, Long y) -> Long.valueOf(x.longValue() + y.longValue())); assertEquals((long)r, (long)3 * SIZE * (SIZE - 1) / 2); } /** * reduceKeysToLongSequentially accumulates mapped keys */ public void testReduceKeysToLongSequentially() { ConcurrentHashMap m = longMap(); long lr = m.reduceKeysToLong(Long.MAX_VALUE, (Long x) -> x.longValue(), 0L, Long::sum); assertEquals(lr, (long)SIZE * (SIZE - 1) / 2); } /** * reduceKeysToIntSequentially accumulates mapped keys */ public void testReduceKeysToIntSequentially() { ConcurrentHashMap m = longMap(); int ir = m.reduceKeysToInt(Long.MAX_VALUE, (Long x) -> x.intValue(), 0, Integer::sum); assertEquals(ir, SIZE * (SIZE - 1) / 2); } /** * reduceKeysToDoubleSequentially accumulates mapped keys */ public void testReduceKeysToDoubleSequentially() { ConcurrentHashMap m = longMap(); double dr = m.reduceKeysToDouble(Long.MAX_VALUE, (Long x) -> x.doubleValue(), 0.0, Double::sum); assertEquals(dr, (double)SIZE * (SIZE - 1) / 2); } /** * reduceValuesToLongSequentially accumulates mapped values */ public void testReduceValuesToLongSequentially() { ConcurrentHashMap m = longMap(); long lr = m.reduceValuesToLong(Long.MAX_VALUE, (Long x) -> x.longValue(), 0L, Long::sum); assertEquals(lr, (long)SIZE * (SIZE - 1)); } /** * reduceValuesToIntSequentially accumulates mapped values */ public void testReduceValuesToIntSequentially() { ConcurrentHashMap m = longMap(); int ir = m.reduceValuesToInt(Long.MAX_VALUE, (Long x) -> x.intValue(), 0, Integer::sum); assertEquals(ir, SIZE * (SIZE - 1)); } /** * reduceValuesToDoubleSequentially accumulates mapped values */ public void testReduceValuesToDoubleSequentially() { ConcurrentHashMap m = longMap(); double dr = m.reduceValuesToDouble(Long.MAX_VALUE, (Long x) -> x.doubleValue(), 0.0, Double::sum); assertEquals(dr, (double)SIZE * (SIZE - 1)); } /** * reduceKeysToLongInParallel accumulates mapped keys */ public void testReduceKeysToLongInParallel() { ConcurrentHashMap m = longMap(); long lr = m.reduceKeysToLong(1L, (Long x) -> x.longValue(), 0L, Long::sum); assertEquals(lr, (long)SIZE * (SIZE - 1) / 2); } /** * reduceKeysToIntInParallel accumulates mapped keys */ public void testReduceKeysToIntInParallel() { ConcurrentHashMap m = longMap(); int ir = m.reduceKeysToInt(1L, (Long x) -> x.intValue(), 0, Integer::sum); assertEquals(ir, SIZE * (SIZE - 1) / 2); } /** * reduceKeysToDoubleInParallel accumulates mapped values */ public void testReduceKeysToDoubleInParallel() { ConcurrentHashMap m = longMap(); double dr = m.reduceKeysToDouble(1L, (Long x) -> x.doubleValue(), 0.0, Double::sum); assertEquals(dr, (double)SIZE * (SIZE - 1) / 2); } /** * reduceValuesToLongInParallel accumulates mapped values */ public void testReduceValuesToLongInParallel() { ConcurrentHashMap m = longMap(); long lr = m.reduceValuesToLong(1L, (Long x) -> x.longValue(), 0L, Long::sum); assertEquals(lr, (long)SIZE * (SIZE - 1)); } /** * reduceValuesToIntInParallel accumulates mapped values */ public void testReduceValuesToIntInParallel() { ConcurrentHashMap m = longMap(); int ir = m.reduceValuesToInt(1L, (Long x) -> x.intValue(), 0, Integer::sum); assertEquals(ir, SIZE * (SIZE - 1)); } /** * reduceValuesToDoubleInParallel accumulates mapped values */ public void testReduceValuesToDoubleInParallel() { ConcurrentHashMap m = longMap(); double dr = m.reduceValuesToDouble(1L, (Long x) -> x.doubleValue(), 0.0, Double::sum); assertEquals(dr, (double)SIZE * (SIZE - 1)); } /** * searchKeysSequentially returns a non-null result of search * function, or null if none */ public void testSearchKeysSequentially() { ConcurrentHashMap m = longMap(); Long r; r = m.searchKeys(Long.MAX_VALUE, (Long x) -> x.longValue() == (long)(SIZE/2) ? x : null); assertEquals((long)r, (long)(SIZE/2)); r = m.searchKeys(Long.MAX_VALUE, (Long x) -> x.longValue() < 0L ? x : null); assertNull(r); } /** * searchValuesSequentially returns a non-null result of search * function, or null if none */ public void testSearchValuesSequentially() { ConcurrentHashMap m = longMap(); Long r; r = m.searchValues(Long.MAX_VALUE, (Long x) -> x.longValue() == (long)(SIZE/2)? x : null); assertEquals((long)r, (long)(SIZE/2)); r = m.searchValues(Long.MAX_VALUE, (Long x) -> x.longValue() < 0L ? x : null); assertNull(r); } /** * searchSequentially returns a non-null result of search * function, or null if none */ public void testSearchSequentially() { ConcurrentHashMap m = longMap(); Long r; r = m.search(Long.MAX_VALUE, (Long x, Long y) -> x.longValue() == (long)(SIZE/2) ? x : null); assertEquals((long)r, (long)(SIZE/2)); r = m.search(Long.MAX_VALUE, (Long x, Long y) -> x.longValue() < 0L ? x : null); assertNull(r); } /** * searchEntriesSequentially returns a non-null result of search * function, or null if none */ public void testSearchEntriesSequentially() { ConcurrentHashMap m = longMap(); Long r; r = m.searchEntries(Long.MAX_VALUE, (Map.Entry e) -> e.getKey().longValue() == (long)(SIZE/2) ? e.getKey() : null); assertEquals((long)r, (long)(SIZE/2)); r = m.searchEntries(Long.MAX_VALUE, (Map.Entry e) -> e.getKey().longValue() < 0L ? e.getKey() : null); assertNull(r); } /** * searchKeysInParallel returns a non-null result of search * function, or null if none */ public void testSearchKeysInParallel() { ConcurrentHashMap m = longMap(); Long r; r = m.searchKeys(1L, (Long x) -> x.longValue() == (long)(SIZE/2) ? x : null); assertEquals((long)r, (long)(SIZE/2)); r = m.searchKeys(1L, (Long x) -> x.longValue() < 0L ? x : null); assertNull(r); } /** * searchValuesInParallel returns a non-null result of search * function, or null if none */ public void testSearchValuesInParallel() { ConcurrentHashMap m = longMap(); Long r; r = m.searchValues(1L, (Long x) -> x.longValue() == (long)(SIZE/2) ? x : null); assertEquals((long)r, (long)(SIZE/2)); r = m.searchValues(1L, (Long x) -> x.longValue() < 0L ? x : null); assertNull(r); } /** * searchInParallel returns a non-null result of search function, * or null if none */ public void testSearchInParallel() { ConcurrentHashMap m = longMap(); Long r; r = m.search(1L, (Long x, Long y) -> x.longValue() == (long)(SIZE/2) ? x : null); assertEquals((long)r, (long)(SIZE/2)); r = m.search(1L, (Long x, Long y) -> x.longValue() < 0L ? x : null); assertNull(r); } /** * searchEntriesInParallel returns a non-null result of search * function, or null if none */ public void testSearchEntriesInParallel() { ConcurrentHashMap m = longMap(); Long r; r = m.searchEntries(1L, (Map.Entry e) -> e.getKey().longValue() == (long)(SIZE/2) ? e.getKey() : null); assertEquals((long)r, (long)(SIZE/2)); r = m.searchEntries(1L, (Map.Entry e) -> e.getKey().longValue() < 0L ? e.getKey() : null); assertNull(r); } }