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root/jsr166/jsr166/src/test/tck/ArrayBlockingQueueTest.java

Comparing jsr166/src/test/tck/ArrayBlockingQueueTest.java (file contents):
Revision 1.72 by jsr166, Sun Oct 16 20:44:18 2016 UTC vs.
Revision 1.75 by jsr166, Sat Nov 5 23:38:21 2016 UTC

#	Line 19 | Line 19 | import java.util.concurrent.BlockingQueu
19		import java.util.concurrent.CountDownLatch;
20		import java.util.concurrent.Executors;
21		import java.util.concurrent.ExecutorService;
22	+	import java.util.concurrent.ThreadLocalRandom;
23
24		import junit.framework.Test;
25
#	Line 26 | Line 27 | public class ArrayBlockingQueueTest exte
27
28		public static class Fair extends BlockingQueueTest {
29		protected BlockingQueue emptyCollection() {
30	<	return new ArrayBlockingQueue(SIZE, true);
30	>	return populatedQueue(0, SIZE, 2 * SIZE, true);
31		}
32		}
33
34		public static class NonFair extends BlockingQueueTest {
35		protected BlockingQueue emptyCollection() {
36	<	return new ArrayBlockingQueue(SIZE, false);
36	>	return populatedQueue(0, SIZE, 2 * SIZE, false);
37		}
38		}
39
#	Line 41 | Line 42 | public class ArrayBlockingQueueTest exte
42		}
43
44		public static Test suite() {
45	+	class Implementation implements CollectionImplementation {
46	+	public Class<?> klazz() { return ArrayBlockingQueue.class; }
47	+	public Collection emptyCollection() {
48	+	boolean fair = ThreadLocalRandom.current().nextBoolean();
49	+	return populatedQueue(0, SIZE, 2 * SIZE, fair);
50	+	}
51	+	public Object makeElement(int i) { return i; }
52	+	public boolean isConcurrent() { return true; }
53	+	public boolean permitsNulls() { return false; }
54	+	}
55		return newTestSuite(ArrayBlockingQueueTest.class,
56		new Fair().testSuite(),
57	<	new NonFair().testSuite());
57	>	new NonFair().testSuite(),
58	>	CollectionTest.testSuite(new Implementation()));
59		}
60
61		/**
62		* Returns a new queue of given size containing consecutive
63		* Integers 0 ... n - 1.
64		*/
65	<	private ArrayBlockingQueue<Integer> populatedQueue(int n) {
66	<	ArrayBlockingQueue<Integer> q = new ArrayBlockingQueue<Integer>(n);
65	>	static ArrayBlockingQueue<Integer> populatedQueue(int n) {
66	>	return populatedQueue(n, n, n, false);
67	>	}
68	>
69	>	/**
70	>	* Returns a new queue of given size containing consecutive
71	>	* Integers 0 ... n - 1, with given capacity range and fairness.
72	>	*/
73	>	static ArrayBlockingQueue<Integer> populatedQueue(
74	>	int size, int minCapacity, int maxCapacity, boolean fair) {
75	>	ThreadLocalRandom rnd = ThreadLocalRandom.current();
76	>	int capacity = rnd.nextInt(minCapacity, maxCapacity + 1);
77	>	ArrayBlockingQueue<Integer> q = new ArrayBlockingQueue<>(capacity);
78		assertTrue(q.isEmpty());
79	<	for (int i = 0; i < n; i++)
80	<	assertTrue(q.offer(new Integer(i)));
81	<	assertFalse(q.isEmpty());
82	<	assertEquals(0, q.remainingCapacity());
83	<	assertEquals(n, q.size());
84	<	assertEquals((Integer) 0, q.peek());
79	>	// shuffle circular array elements so they wrap
80	>	{
81	>	int n = rnd.nextInt(capacity);
82	>	for (int i = 0; i < n; i++) q.add(42);
83	>	for (int i = 0; i < n; i++) q.remove();
84	>	}
85	>	for (int i = 0; i < size; i++)
86	>	assertTrue(q.offer((Integer) i));
87	>	assertEquals(size == 0, q.isEmpty());
88	>	assertEquals(capacity - size, q.remainingCapacity());
89	>	assertEquals(size, q.size());
90	>	if (size > 0)
91	>	assertEquals((Integer) 0, q.peek());
92		return q;
93		}
94
#	Line 592 | Line 622 | public class ArrayBlockingQueueTest exte
622		}
623		}
624
625	<	void checkToArray(ArrayBlockingQueue q) {
625	>	void checkToArray(ArrayBlockingQueue<Integer> q) {
626		int size = q.size();
627	<	Object[] o = q.toArray();
628	<	assertEquals(size, o.length);
627	>	Object[] a1 = q.toArray();
628	>	assertEquals(size, a1.length);
629	>	Integer[] a2 = q.toArray(new Integer[0]);
630	>	assertEquals(size, a2.length);
631	>	Integer[] a3 = q.toArray(new Integer[Math.max(0, size - 1)]);
632	>	assertEquals(size, a3.length);
633	>	Integer[] a4 = new Integer[size];
634	>	assertSame(a4, q.toArray(a4));
635	>	Integer[] a5 = new Integer[size + 1];
636	>	Arrays.fill(a5, 42);
637	>	assertSame(a5, q.toArray(a5));
638	>	Integer[] a6 = new Integer[size + 2];
639	>	Arrays.fill(a6, 42);
640	>	assertSame(a6, q.toArray(a6));
641	>	Object[][] as = { a1, a2, a3, a4, a5, a6 };
642	>	for (Object[] a : as) {
643	>	if (a.length > size) assertNull(a[size]);
644	>	if (a.length > size + 1) assertEquals(42, a[size + 1]);
645	>	}
646		Iterator it = q.iterator();
647	+	Integer s = q.peek();
648		for (int i = 0; i < size; i++) {
649		Integer x = (Integer) it.next();
650	<	assertEquals((Integer)o[0] + i, (int) x);
651	<	assertSame(o[i], x);
650	>	assertEquals(s + i, (int) x);
651	>	for (Object[] a : as)
652	>	assertSame(a1[i], x);
653		}
654		}
655
656		/**
657	<	* toArray() contains all elements in FIFO order
657	>	* toArray() and toArray(a) contain all elements in FIFO order
658		*/
659		public void testToArray() {
660	<	ArrayBlockingQueue q = new ArrayBlockingQueue(SIZE);
661	<	for (int i = 0; i < SIZE; i++) {
660	>	final ThreadLocalRandom rnd = ThreadLocalRandom.current();
661	>	final int size = rnd.nextInt(6);
662	>	final int capacity = Math.max(1, size + rnd.nextInt(size + 1));
663	>	ArrayBlockingQueue<Integer> q = new ArrayBlockingQueue<>(capacity);
664	>	for (int i = 0; i < size; i++) {
665		checkToArray(q);
666		q.add(i);
667		}
668		// Provoke wraparound
669	<	for (int i = 0; i < SIZE; i++) {
669	>	int added = size * 2;
670	>	for (int i = 0; i < added; i++) {
671		checkToArray(q);
672	<	assertEquals(i, q.poll());
673	<	checkToArray(q);
621	<	q.add(SIZE + i);
672	>	assertEquals((Integer) i, q.poll());
673	>	q.add(size + i);
674		}
623	–	for (int i = 0; i < SIZE; i++) {
624	–	checkToArray(q);
625	–	assertEquals(SIZE + i, q.poll());
626	–	}
627	–	}
628	–
629	–	void checkToArray2(ArrayBlockingQueue q) {
630	–	int size = q.size();
631	–	Integer[] a1 = (size == 0) ? null : new Integer[size - 1];
632	–	Integer[] a2 = new Integer[size];
633	–	Integer[] a3 = new Integer[size + 2];
634	–	if (size > 0) Arrays.fill(a1, 42);
635	–	Arrays.fill(a2, 42);
636	–	Arrays.fill(a3, 42);
637	–	Integer[] b1 = (size == 0) ? null : (Integer[]) q.toArray(a1);
638	–	Integer[] b2 = (Integer[]) q.toArray(a2);
639	–	Integer[] b3 = (Integer[]) q.toArray(a3);
640	–	assertSame(a2, b2);
641	–	assertSame(a3, b3);
642	–	Iterator it = q.iterator();
675		for (int i = 0; i < size; i++) {
676	<	Integer x = (Integer) it.next();
677	<	assertSame(b1[i], x);
646	<	assertEquals(b1[0] + i, (int) x);
647	<	assertSame(b2[i], x);
648	<	assertSame(b3[i], x);
649	<	}
650	<	assertNull(a3[size]);
651	<	assertEquals(42, (int) a3[size + 1]);
652	<	if (size > 0) {
653	<	assertNotSame(a1, b1);
654	<	assertEquals(size, b1.length);
655	<	for (int i = 0; i < a1.length; i++) {
656	<	assertEquals(42, (int) a1[i]);
657	<	}
658	<	}
659	<	}
660	<
661	<	/**
662	<	* toArray(a) contains all elements in FIFO order
663	<	*/
664	<	public void testToArray2() {
665	<	ArrayBlockingQueue q = new ArrayBlockingQueue(SIZE);
666	<	for (int i = 0; i < SIZE; i++) {
667	<	checkToArray2(q);
668	<	q.add(i);
669	<	}
670	<	// Provoke wraparound
671	<	for (int i = 0; i < SIZE; i++) {
672	<	checkToArray2(q);
673	<	assertEquals(i, q.poll());
674	<	checkToArray2(q);
675	<	q.add(SIZE + i);
676	<	}
677	<	for (int i = 0; i < SIZE; i++) {
678	<	checkToArray2(q);
679	<	assertEquals(SIZE + i, q.poll());
676	>	checkToArray(q);
677	>	assertEquals((Integer) (added + i), q.poll());
678		}
679		}
680
681		/**
682		* toArray(incompatible array type) throws ArrayStoreException
683		*/
684	<	public void testToArray1_BadArg() {
684	>	public void testToArray_incompatibleArrayType() {
685		ArrayBlockingQueue q = populatedQueue(SIZE);
686		try {
687		q.toArray(new String[10]);
688		shouldThrow();
689		} catch (ArrayStoreException success) {}
690	+	try {
691	+	q.toArray(new String[0]);
692	+	shouldThrow();
693	+	} catch (ArrayStoreException success) {}
694		}
695
696		/**

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