/* * 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.harmony.tests.java.util; import org.apache.harmony.testframework.serialization.SerializationTest; import org.apache.harmony.testframework.serialization.SerializationTest.SerializableAssert; import tests.support.Support_CollectionTest; import tests.support.Support_ListTest; import tests.support.Support_SetTest; import tests.support.Support_UnmodifiableCollectionTest; import java.io.Serializable; import java.lang.reflect.Array; import java.lang.reflect.InvocationTargetException; import java.lang.reflect.Method; import java.util.ArrayDeque; import java.util.ArrayList; import java.util.Arrays; import java.util.Collection; import java.util.Collections; import java.util.Comparator; import java.util.Deque; import java.util.Enumeration; import java.util.HashMap; import java.util.HashSet; import java.util.Iterator; import java.util.LinkedHashMap; import java.util.LinkedList; import java.util.List; import java.util.ListIterator; import java.util.Map; import java.util.NoSuchElementException; import java.util.Queue; import java.util.Random; import java.util.RandomAccess; import java.util.Set; import java.util.SortedSet; import java.util.TreeMap; import java.util.TreeSet; public class CollectionsTest extends junit.framework.TestCase { private LinkedList ll; private LinkedList myll; private LinkedList reversedLinkedList; private LinkedList myReversedLinkedList; private Set s; private Set mys; private HashMap hm; private Integer[] objArray; private Object[] myobjArray; public static class ReversedMyIntComparator implements Comparator { public int compare(Object o1, Object o2) { return -((MyInt) o1).compareTo((MyInt) o2); } public int equals(Object o1, Object o2) { return ((MyInt) o1).compareTo((MyInt) o2); } } public static class SynchCollectionChecker implements Runnable { Collection col; int colSize; int totalToRun; boolean offset; volatile int numberOfChecks = 0; boolean result = true; ArrayList normalCountingList; ArrayList offsetCountingList; public void run() { // ensure the list either contains the numbers from 0 to size-1 or // the numbers from size to 2*size -1 while (numberOfChecks < totalToRun) { synchronized (col) { if (!(col.isEmpty() || col.containsAll(normalCountingList) || col .containsAll(offsetCountingList))) result = false; col.clear(); } if (offset) col.addAll(offsetCountingList); else col.addAll(normalCountingList); numberOfChecks++; } } public SynchCollectionChecker(Collection c, boolean offset, int totalChecks) { // The collection to test, whether to offset the filler values by // size or not, and the min number of iterations to run totalToRun = totalChecks; col = c; colSize = c.size(); normalCountingList = new ArrayList(colSize); offsetCountingList = new ArrayList(colSize); for (int i = 0; i < colSize; i++) normalCountingList.add(new Integer(i)); for (int i = 0; i < colSize; i++) offsetCountingList.add(new Integer(i + colSize)); col.clear(); if (offset) col.addAll(offsetCountingList); else col.addAll(normalCountingList); } public boolean offset() { // answer true iff the list is filled with a counting sequence // starting at the value size to 2*size - 1 // else the list with be filled starting at 0 to size - 1 return offset; } public boolean getResult() { // answer true iff no corruption has been found in the collection return result; } public int getNumberOfChecks() { // answer the number of checks that have been performed on the list return numberOfChecks; } } public static class SynchMapChecker implements Runnable { Map map; int mapSize; int totalToRun; boolean offset; volatile int numberOfChecks = 0; boolean result = true; Map normalCountingMap; Map offsetCountingMap; public void run() { Object firstNormalValue = normalCountingMap.get(new Integer(0)); Object lastNormalValue = normalCountingMap.get(new Integer( mapSize - 1)); Object firstOffsetValue = offsetCountingMap .get(new Integer(mapSize)); Object lastOffsetValue = offsetCountingMap.get(new Integer( 2 * mapSize - 1)); // ensure the list either contains the numbers from 0 to size-1 or // the numbers from size to 2*size -1 while (numberOfChecks < totalToRun) { synchronized (map) { if (!(map.isEmpty() || (map.containsValue(firstNormalValue) && map .containsValue(lastNormalValue)) || (map .containsValue(firstOffsetValue) && map .containsValue(lastOffsetValue)))) result = false; map.clear(); } if (offset) map.putAll(offsetCountingMap); else map.putAll(normalCountingMap); numberOfChecks++; } } public SynchMapChecker(Map m, boolean offset, int totalChecks) { // The collection to test, whether to offset the filler values by // size or not, and the min number of iterations to run Integer myInt; totalToRun = totalChecks; map = m; mapSize = m.size(); normalCountingMap = new HashMap(mapSize); offsetCountingMap = new HashMap(mapSize); for (int i = 0; i < mapSize; i++) { myInt = new Integer(i); normalCountingMap.put(myInt, myInt); } for (int i = 0; i < mapSize; i++) { myInt = new Integer(i + mapSize); offsetCountingMap.put(myInt, myInt); } map.clear(); if (offset) map.putAll(offsetCountingMap); else map.putAll(normalCountingMap); } public boolean offset() { // answer true iff the list is filled with a counting sequence // starting at the value size to 2*size - 1 // else the list with be filled starting at 0 to size - 1 return offset; } public boolean getResult() { // answer true iff no corruption has been found in the collection return result; } public int getNumberOfChecks() { // answer the number of checks that have been performed on the list return numberOfChecks; } } static class MyInt { int data; public MyInt(int value) { data = value; } public int compareTo(MyInt object) { return data > object.data ? 1 : (data < object.data ? -1 : 0); } } public void test_binarySearchLjava_util_ListLjava_lang_Object() { // Test for method int // java.util.Collections.binarySearch(java.util.List, java.lang.Object) // assumes ll is sorted and has no duplicate keys final int llSize = ll.size(); // Ensure a NPE is thrown if the list is NULL try { Collections.binarySearch(null, new Object()); fail("Expected NullPointerException for null list parameter"); } catch (NullPointerException e) { //Expected } for (int i = 0; i < llSize; i++) { assertEquals("Returned incorrect binary search item position", ll .get(i), ll.get(Collections.binarySearch(ll, ll .get(i)))); } } public void test_binarySearchLjava_util_ListLjava_lang_ObjectLjava_util_Comparator() { // Test for method int // java.util.Collections.binarySearch(java.util.List, java.lang.Object, // java.util.Comparator) // assumes reversedLinkedList is sorted in reversed order and has no // duplicate keys final int rSize = myReversedLinkedList.size(); ReversedMyIntComparator comp = new ReversedMyIntComparator(); // Ensure a NPE is thrown if the list is NULL try { Collections.binarySearch(null, new Object(), comp); fail("Expected NullPointerException for null list parameter"); } catch (NullPointerException e) { //Expected } for (int i = 0; i < rSize; i++) { assertEquals( "Returned incorrect binary search item position using custom comparator", myReversedLinkedList.get(i), myReversedLinkedList .get(Collections.binarySearch(myReversedLinkedList, myReversedLinkedList.get(i), comp))); } } class Mock_ArrayList extends ArrayList { @Override public Object set (int index, Object o){ throw new UnsupportedOperationException(); } } public void test_copyLjava_util_ListLjava_util_List() { // Test for method void java.util.Collections.copy(java.util.List, // java.util.List) // Ensure a NPE is thrown if the list is NULL try { Collections.copy(null, ll); fail("Expected NullPointerException for null list first parameter"); } catch (NullPointerException e) { //Expected } try { Collections.copy(ll, null); fail("Expected NullPointerException for null list second parameter"); } catch (NullPointerException e) { //Expected } final int llSize = ll.size(); ll.set(25, null); ArrayList al = new ArrayList(); Integer extraElement = new Integer(1); Integer extraElement2 = new Integer(2); al.addAll(myReversedLinkedList); al.add(extraElement); al.add(extraElement2); Collections.copy(al, ll); for (int i = 0; i < llSize; i++) { assertEquals("Elements do not match after copying collection", ll .get(i), al.get(i)); } assertTrue("Elements after copied elements affected by copy", extraElement == al.get(llSize) && extraElement2 == al.get(llSize + 1)); ArrayList ar1 = new ArrayList(); ArrayList ar2 = new ArrayList(); int i; for(i = 0; i < 5; i ++) { ar2.add(new Integer(i)); } for(i = 0; i < 10; i ++) { ar1.add(new Integer(i)); } try { Collections.copy(ar2, ar1); fail("IndexOutOfBoundsException expected"); } catch (IndexOutOfBoundsException e) { //expected } Mock_ArrayList mal1 = new Mock_ArrayList(); Mock_ArrayList mal2 = new Mock_ArrayList(); for(i = 0; i < 10; i ++) { mal1.add(new Integer(i)); mal2.add(new Integer(10 - i)); } try { Collections.copy(mal1, mal2); fail("UnsupportedOperationException expected"); } catch (UnsupportedOperationException e) { //expected } } public void test_copy_check_index() { ArrayList a1 = new ArrayList(); a1.add("one"); a1.add("two"); ArrayList a2 = new ArrayList(); a2.add("aa"); try { Collections.copy(a2, a1); fail("Expected IndexOutOfBoundsException"); } catch (IndexOutOfBoundsException e) { //Expected } assertEquals("aa", a2.get(0)); } public void test_enumerationLjava_util_Collection() { // Test for method java.util.Enumeration // java.util.Collections.enumeration(java.util.Collection) TreeSet ts = new TreeSet(); ts.addAll(s); Enumeration e = Collections.enumeration(ts); int count = 0; while (e.hasMoreElements()) { assertEquals("Returned incorrect enumeration", e.nextElement(), objArray[count++]); } assertEquals("Enumeration missing elements: " + count, objArray.length, count); } public void test_fillLjava_util_ListLjava_lang_Object() { // Test for method void java.util.Collections.fill(java.util.List, // java.lang.Object) try { Collections.fill(null, new Object()); fail("Expected NullPointerException for null list parameter"); } catch (NullPointerException e) { //Expected } final int size = ll.size(); Collections.fill(ll, "k"); assertEquals("Fill modified list size", size, ll.size()); Iterator i = ll.iterator(); while (i.hasNext()) assertEquals("Failed to fill elements", "k", i.next()); Collections.fill(ll, null); assertEquals("Fill with nulls modified list size", size, ll.size()); i = ll.iterator(); while (i.hasNext()) assertNull("Failed to fill with nulls", i.next()); Mock_ArrayList mal = new Mock_ArrayList(); mal.add("one"); mal.add("two"); try { Collections.fill(mal, "value"); fail("UnsupportedOperationException ecpected"); } catch (UnsupportedOperationException e) { //expected } } public void test_maxLjava_util_Collection() { // Test for method java.lang.Object // java.util.Collections.max(java.util.Collection) // assumes s, objArray are sorted assertEquals("Returned incorrect max element", Collections.max(s), objArray[objArray.length - 1]); ArrayList al = new ArrayList(); try { Collections.max(al); fail("NoSuchElementException expected"); } catch (NoSuchElementException e) { //expected } al.add("String"); al.add(new Integer(1)); al.add(new Double(3.14)); try { Collections.max(al); fail("ClassCastException expected"); } catch (ClassCastException e) { //expected } } public void test_maxLjava_util_CollectionLjava_util_Comparator() { // Test for method java.lang.Object // java.util.Collections.max(java.util.Collection, java.util.Comparator) // assumes s, objArray are sorted // With this custom (backwards) comparator the 'max' element should be // the smallest in the list assertEquals("Returned incorrect max element using custom comparator", Collections.max(mys, new ReversedMyIntComparator()), myobjArray[0]); } public void test_minLjava_util_Collection() { // Test for method java.lang.Object // java.util.Collections.min(java.util.Collection) // assumes s, objArray are sorted assertEquals("Returned incorrect min element", Collections.min(s), objArray[0]); } public void test_minLjava_util_CollectionLjava_util_Comparator() { // Test for method java.lang.Object // java.util.Collections.min(java.util.Collection, java.util.Comparator) // assumes s, objArray are sorted // With this custom (backwards) comparator the 'min' element should be // the largest in the list assertEquals("Returned incorrect min element using custom comparator", Collections.min(mys, new ReversedMyIntComparator()), myobjArray[objArray.length - 1]); } public void test_nCopiesILjava_lang_Object() { // Test for method java.util.List java.util.Collections.nCopies(int, // java.lang.Object) Object o = new Object(); List l = Collections.nCopies(100, o); Iterator iterator = l.iterator(); Object first = iterator.next(); assertEquals("Returned list consists of copies not refs", first, o); assertEquals("Returned list of incorrect size", 100, l.size()); assertTrue("Contains", l.contains(o)); assertFalse("Contains null", l.contains(null)); assertFalse("null nCopies contains", Collections.nCopies(2, null) .contains(o)); assertTrue("null nCopies contains null", Collections.nCopies(2, null) .contains(null)); l = Collections.nCopies(20, null); iterator = l.iterator(); for (int i = 0; iterator.hasNext(); i++) { assertTrue("List is too large", i < 20); assertNull("Element should be null: " + i, iterator.next()); } try { l.add(o); fail("Returned list is not immutable"); } catch (UnsupportedOperationException e) { // Expected } try { Collections.nCopies(-2, new HashSet()); fail("nCopies with negative arg didn't throw IAE"); } catch (IllegalArgumentException e) { // Expected } } public void test_reverseLjava_util_List() { // Test for method void java.util.Collections.reverse(java.util.List) try { Collections.reverse(null); fail("Expected NullPointerException for null list parameter"); } catch (NullPointerException e) { //Expected } Collections.reverse(ll); Iterator i = ll.iterator(); int count = objArray.length - 1; while (i.hasNext()) { assertEquals("Failed to reverse collection", objArray[count], i .next()); --count; } ArrayList myList = new ArrayList(); myList.add(null); myList.add(new Integer(20)); Collections.reverse(myList); assertEquals("Did not reverse correctly--first element is: " + myList.get(0), new Integer(20), myList.get(0)); assertNull("Did not reverse correctly--second element is: " + myList.get(1), myList.get(1)); } public void test_reverseOrder() { // Test for method java.util.Comparator // java.util.Collections.reverseOrder() // assumes no duplicates in ll Comparator comp = Collections.reverseOrder(); LinkedList list2 = new LinkedList(ll); Collections.sort(list2, comp); final int llSize = ll.size(); for (int i = 0; i < llSize; i++) assertEquals("New comparator does not reverse sorting order", list2 .get(llSize - i - 1), ll.get(i)); } public void test_shuffleLjava_util_List() { // Test for method void java.util.Collections.shuffle(java.util.List) // Assumes ll is sorted and has no duplicate keys and is large ( > 20 // elements) // test shuffling a Sequential Access List try { Collections.shuffle(null); fail("Expected NullPointerException for null list parameter"); } catch (NullPointerException e) { //Expected } ArrayList al = new ArrayList(); al.addAll(ll); testShuffle(al, "Sequential Access", false); // test shuffling a Random Access List LinkedList ll2 = new LinkedList(); ll2.addAll(ll); testShuffle(ll2, "Random Access", false); } public void testShuffleRandomAccessWithSeededRandom() { List list = Arrays.asList("A", "B", "C", "D", "E", "F", "G"); Collections.shuffle(list, new Random(0)); assertEquals(Arrays.asList("B", "A", "D", "C", "G", "E", "F"), list); } public void testShuffleWithSeededRandom() { List list = new LinkedList(Arrays.asList( "A", "B", "C", "D", "E", "F", "G")); Collections.shuffle(list, new Random(0)); assertEquals(Arrays.asList("B", "A", "D", "C", "G", "E", "F"), list); } private void testShuffle(List list, String type, boolean random) { boolean sorted = true; boolean allMatch = true; int index = 0; final int size = list.size(); if (random) Collections.shuffle(list); else Collections.shuffle(list, new Random(200)); for (int i = 0; i < size - 1; i++) { if (((Integer) list.get(i)).compareTo((Integer) list.get(i + 1)) > 0) { sorted = false; } } assertFalse("Shuffling sorted " + type + " list resulted in sorted list (should be unlikely)", sorted); for (int i = 0; i < 20; i++) { index = 30031 * i % (size + 1); // 30031 is a large prime if (list.get(index) != ll.get(index)) allMatch = false; } assertFalse("Too many element positions match in shuffled " + type + " list", allMatch); } public void test_shuffleLjava_util_ListLjava_util_Random() { // Test for method void java.util.Collections.shuffle(java.util.List, // java.util.Random) // Assumes ll is sorted and has no duplicate keys and is large ( > 20 // elements) // test shuffling a Sequential Access List try { Collections.shuffle(null, new Random(200)); fail("Expected NullPointerException for null list parameter"); } catch (NullPointerException e) { //Excepted } ArrayList al = new ArrayList(); al.addAll(ll); testShuffle(al, "Sequential Access", true); // test shuffling a Random Access List LinkedList ll2 = new LinkedList(); ll2.addAll(ll); testShuffle(ll2, "Random Access", true); List l = new ArrayList(); l.add('a'); l.add('b'); l.add('c'); Collections.shuffle(l, new Random(12345678921L)); assertEquals("acb", l.get(0).toString() + l.get(1) + l.get(2)); } public void test_singletonLjava_lang_Object() { // Test for method java.util.Set // java.util.Collections.singleton(java.lang.Object) Object o = new Object(); Set single = Collections.singleton(o); assertEquals("Wrong size", 1, single.size()); assertTrue("Contains", single.contains(o)); assertFalse("Contains null", single.contains(null)); assertFalse("null nCopies contains", Collections.singleton(null) .contains(o)); assertTrue("null nCopies contains null", Collections.singleton(null) .contains(null)); try { single.add("l"); fail("Allowed modification of singleton"); } catch (UnsupportedOperationException e) { // Excepted } } public void test_sortLjava_util_List() { // Test for method void java.util.Collections.sort(java.util.List) // assumes no duplicate keys in ll final int llSize = ll.size(); final int rllSize = reversedLinkedList.size(); try { Collections.sort((List) null); fail("Expected NullPointerException for null list parameter"); } catch (NullPointerException e) { //Expected } Collections.shuffle(ll); Collections.sort(ll); Collections.sort(reversedLinkedList); for (int i = 0; i < llSize - 1; i++) { assertTrue( "Sorting shuffled list resulted in unsorted list", ((Integer) ll.get(i)).compareTo((Integer) ll.get(i + 1)) < 0); } for (int i = 0; i < rllSize - 1; i++) { assertTrue("Sorting reversed list resulted in unsorted list", ((Integer) reversedLinkedList.get(i)) .compareTo((Integer) reversedLinkedList.get(i + 1)) < 0); } } public void test_sortLjava_util_ListLjava_util_Comparator() { // Test for method void java.util.Collections.sort(java.util.List, // java.util.Comparator) Comparator comp = new ReversedMyIntComparator(); try { Collections.sort(null, comp); fail("Expected NullPointerException for null list parameter"); } catch (NullPointerException e) { //Expected } Collections.shuffle(myll); Collections.sort(myll, comp); final int llSize = myll.size(); for (int i = 0; i < llSize - 1; i++) { assertTrue( "Sorting shuffled list with custom comparator resulted in unsorted list", ((MyInt) myll.get(i)).compareTo((MyInt) myll .get(i + 1)) >= 0); } ArrayList al = new ArrayList(); al.add("String"); al.add(new Integer(1)); al.add(new Double(3.14)); try { Collections.sort(al, comp); fail("ClassCastException expected"); } catch (ClassCastException e) { //expected } Mock_ArrayList mal = new Mock_ArrayList(); mal.add(new MyInt(1)); mal.add(new MyInt(2)); try { Collections.sort(mal, comp); fail("UnsupportedOperationException expected"); } catch (UnsupportedOperationException e) { //expected } } public void test_swapLjava_util_ListII() { // Test for method swap(java.util.List, int, int) LinkedList smallList = new LinkedList(); for (int i = 0; i < 10; i++) { smallList.add(objArray[i]); } // test exception cases try { Collections.swap(smallList, -1, 6); fail("Expected IndexOutOfBoundsException for -1"); } catch (IndexOutOfBoundsException e) { //Expected } try { Collections.swap(smallList, 6, -1); fail("Expected IndexOutOfBoundsException for -1"); } catch (IndexOutOfBoundsException e) { //Expected } try { Collections.swap(smallList, 6, 11); fail("Expected IndexOutOfBoundsException for 11"); } catch (IndexOutOfBoundsException e) { //Expected } try { Collections.swap(smallList, 11, 6); fail("Expected IndexOutOfBoundsException for 11"); } catch (IndexOutOfBoundsException e) { //Expected } // Ensure a NPE is thrown if the list is NULL try { Collections.swap(null, 1, 1); fail("Expected NullPointerException for null list parameter"); } catch (NullPointerException e) { //Expected } // test with valid parameters Collections.swap(smallList, 4, 7); assertEquals("Didn't Swap the element at position 4 ", new Integer(7), smallList.get(4)); assertEquals("Didn't Swap the element at position 7 ", new Integer(4), smallList.get(7)); // make sure other elements didn't get swapped by mistake for (int i = 0; i < 10; i++) { if (i != 4 && i != 7) assertEquals("shouldn't have swapped the element at position " + i, new Integer(i), smallList.get(i)); } } public void test_replaceAllLjava_util_ListLjava_lang_ObjectLjava_lang_Object() { // Test for method replaceAll(java.util.List, java.lang.Object, // java.lang.Object) String string1 = "A-B-C-D-E-S-JF-SUB-G-H-I-J-SUBL-K-L-LIST-M-N--S-S-O-SUBLIS-P-Q-R-SUBLIST-S-T-U-V-W-X-Y-Z"; char[] chars = string1.toCharArray(); List list = new ArrayList(); for (int i = 0; i < chars.length; i++) { list.add(new Character(chars[i])); } try { Collections.replaceAll(null, new Object(), new Object()); fail("Expected NullPointerException for null list parameter"); } catch (NullPointerException e) { //Expected } // test replace for an element that is not in the list boolean result = Collections.replaceAll(list, new Character('1'), new Character('Z')); assertFalse("Test1: Collections.replaceAll() returned wrong result", result); assertEquals("Test2 : ReplaceAll modified the list incorrectly", string1, getString(list)); // test replace for an element that is in the list result = Collections.replaceAll(list, new Character('S'), new Character('K')); assertTrue("Test3: Collections.replaceAll() returned wrong result", result); assertEquals("Test4: ReplaceAll modified the list incorrectly", (string1 = string1.replace('S', 'K')), getString(list)); // test replace for the last element in the list result = Collections.replaceAll(list, new Character('Z'), new Character('N')); assertTrue("Test5: Collections.replaceAll() returned wrong result", result); assertEquals("Test6: ReplaceAll modified the list incorrectly", (string1 = string1.replace('Z', 'N')), getString(list)); // test replace for the first element in the list result = Collections.replaceAll(list, new Character('A'), new Character('B')); assertTrue("Test7: Collections.replaceAll() returned wrong result", result); assertEquals("Test8: ReplaceAll modified the list incorrectly", (string1 = string1.replace('A', 'B')), getString(list)); // test replacing elements with null LinkedList smallList = new LinkedList(); for (int i = 0; i < 10; i++) { smallList.add(objArray[i]); } smallList.set(4, new Integer(5)); result = Collections.replaceAll(smallList, new Integer(5), null); assertTrue("Test9: Collections.replaceAll() returned wrong result", result); for (int i = 0; i < smallList.size(); i++) { if (i == 4 || i == 5) assertSame("Test9: ReplaceAll didn't replace element at " + i, null, smallList.get(i)); else assertEquals( "Test9: ReplaceAll shouldn't have replaced element at " + i, new Integer(i), smallList.get(i)); } // test replacing null elements with another value result = Collections.replaceAll(smallList, null, new Integer(99)); assertTrue("Test10: Collections.replaceAll() returned wrong result", result); for (int i = 0; i < smallList.size(); i++) { if (i == 4 || i == 5) assertEquals("Test10: ReplaceAll didn't replace element at " + i, new Integer(99), smallList.get(i)); else assertEquals( "Test10: ReplaceAll shouldn't have replaced element at " + i, new Integer(i), smallList.get(i)); } Mock_ArrayList mal = new Mock_ArrayList(); mal.add("First"); mal.add("Second"); try { Collections.replaceAll(mal, "Second", null); fail("UnsupportedOperationException expected"); } catch (UnsupportedOperationException e) { //expected } } public void test_rotateLjava_util_ListI() { // Test for method rotate(java.util.List, int) try { Collections.rotate(null, 0); fail("Expected NullPointerException for null list parameter"); } catch (NullPointerException e) { //Expected } // Test rotating a Sequential Access List LinkedList list1 = new LinkedList(); for (int i = 0; i < 10; i++) { list1.add(objArray[i]); } testRotate(list1, "Sequential Access"); // Test rotating a Random Access List ArrayList list2 = new ArrayList(); for (int i = 0; i < 10; i++) { list2.add(objArray[i]); } testRotate(list2, "Random Access"); } private void testRotate(List list, String type) { // rotate with positive distance Collections.rotate(list, 7); assertEquals("Test1: rotate modified the " + type + " list incorrectly,", "3456789012", getString(list)); // rotate with negative distance Collections.rotate(list, -2); assertEquals("Test2: rotate modified the " + type + " list incorrectly,", "5678901234", getString(list)); // rotate sublist with negative distance List subList = list.subList(1, 5); Collections.rotate(subList, -1); assertEquals("Test3: rotate modified the " + type + " list incorrectly,", "5789601234", getString(list)); // rotate sublist with positive distance Collections.rotate(subList, 2); assertEquals("Test4: rotate modified the " + type + " list incorrectly,", "5967801234", getString(list)); // rotate with positive distance that is larger than list size Collections.rotate(list, 23); assertEquals("Test5: rotate modified the " + type + " list incorrectly,", "2345967801", getString(list)); // rotate with negative distance that is larger than list size Collections.rotate(list, -23); assertEquals("Test6: rotate modified the " + type + " list incorrectly,", "5967801234", getString(list)); // rotate with 0 and equivalent distances, this should make no // modifications to the list Collections.rotate(list, 0); assertEquals("Test7: rotate modified the " + type + " list incorrectly,", "5967801234", getString(list)); Collections.rotate(list, -30); assertEquals("Test8: rotate modified the " + type + " list incorrectly,", "5967801234", getString(list)); Collections.rotate(list, 30); assertEquals("Test9: rotate modified the " + type + " list incorrectly,", "5967801234", getString(list)); } private String getString(List list) { StringBuffer buffer = new StringBuffer(); for (int i = 0; i < list.size(); i++) { buffer.append(list.get(i)); } return buffer.toString(); } public void test_rotate2() { List list = new ArrayList(); try { Collections.rotate(list, 5); } catch (UnsupportedOperationException e) { fail("Unexpected UnsupportedOperationException for empty list, " + e); } list.add(0, "zero"); list.add(1, "one"); list.add(2, "two"); list.add(3, "three"); list.add(4, "four"); Collections.rotate(list, Integer.MIN_VALUE); assertEquals("Rotated incorrectly at position 0, ", "three", (String) list.get(0)); assertEquals("Rotated incorrectly at position 1, ", "four", (String) list.get(1)); assertEquals("Rotated incorrectly at position 2, ", "zero", (String) list.get(2)); assertEquals("Rotated incorrectly at position 3, ", "one", (String) list.get(3)); assertEquals("Rotated incorrectly at position 4, ", "two", (String) list.get(4)); } public void test_indexOfSubListLjava_util_ListLjava_util_List() { // Test for method int indexOfSubList(java.util.List, java.util.List) List list = new ArrayList(); try { Collections.indexOfSubList(null, list); fail("Expected NullPointerException for null list first parameter"); } catch (NullPointerException e) { //Expected } try { Collections.indexOfSubList(list, null); fail("Expected NullPointerException for null list second parameter"); } catch (NullPointerException e) { //Expected } String string1 = "A-B-C-D-E-S-JF-SUB-G-H-I-J-SUBL-K-L-LIST-M-N--S-S-O-SUBLIS-P-Q-R-SUBLIST-S-T-U-V-W-X-Y-Z"; testwithCharList(1, string1, "B", true); testwithCharList(2, string1, "LIST", true); testwithCharList(3, string1, "SUBLIST", true); testwithCharList(4, string1, "NONE", true); testwithCharList(5, string1, "END", true); // test boundary conditions: testwithCharList(6, "", "", true); testwithCharList(7, "LIST", "", true); testwithCharList(8, "", "SUBLIST", true); } public void test_indexOfSubList2() { ArrayList sub = new ArrayList(); sub.add(new Integer(1)); sub.add(new Integer(2)); sub.add(new Integer(3)); ArrayList sub2 = new ArrayList(); sub2.add(new Integer(7)); sub2.add(new Integer(8)); ArrayList src = new ArrayList(); src.addAll(sub); src.addAll(sub); src.addAll(sub); src.add(new Integer(5)); src.add(new Integer(6)); // so src becomes a list like this: // [1, 2, 3, 1, 2, 3, 1, 2, 3, 5, 6] sub = new ArrayList(src.subList(3, 11)); // [1, 2, 3, 1, 2, 3, 5, 6] assertEquals("TestA : Returned wrong indexOfSubList, ", 3, Collections .indexOfSubList(src, sub)); sub = new ArrayList(src.subList(6, 11)); // [1, 2, 3, 5, 6] assertEquals("TestB : Returned wrong indexOfSubList, ", 6, Collections .indexOfSubList(src, sub)); sub = new ArrayList(src.subList(0, 3)); // [1, 2, 3] assertEquals("TestCC : Returned wrong indexOfSubList, ", 0, Collections .indexOfSubList(src, sub)); sub = new ArrayList(src.subList(9, 11)); // [5, 6] assertEquals("TestD : Returned wrong indexOfSubList, ", 9, Collections .indexOfSubList(src, sub)); sub = new ArrayList(src.subList(10, 11)); // [6] assertEquals("TestE : Returned wrong indexOfSubList, ", 10, Collections .indexOfSubList(src, sub)); sub = new ArrayList(src.subList(0, 11)); // the whole list assertEquals("TestH : Returned wrong indexIndexOfSubList, ", 0, Collections.indexOfSubList(src, sub)); // a non-matching list assertEquals("TestI : Returned wrong indexOfSubList, ", -1, Collections .indexOfSubList(src, sub2)); } private void testwithCharList(int count, String string1, String string2, boolean first) { char[] chars = string1.toCharArray(); List list = new ArrayList(); for (int i = 0; i < chars.length; i++) { list.add(new Character(chars[i])); } chars = string2.toCharArray(); List sublist = new ArrayList(); for (int i = 0; i < chars.length; i++) { sublist.add(new Character(chars[i])); } if (first) assertEquals("Test " + count + ": Returned wrong index:", string1 .indexOf(string2), Collections .indexOfSubList(list, sublist)); else assertEquals("Test " + count + ": Returned wrong index:", string1 .lastIndexOf(string2), Collections.lastIndexOfSubList(list, sublist)); } public void test_lastIndexOfSubListLjava_util_ListLjava_util_List() { // Test for method int lastIndexOfSubList(java.util.List, // java.util.List) String string1 = "A-B-C-D-E-S-JF-SUB-G-H-I-J-SUBL-K-L-LIST-M-N--S-S-O-SUBLIS-P-Q-R-SUBLIST-S-T-U-V-W-X-Y-Z-END"; List list = new ArrayList(); try { Collections.lastIndexOfSubList(null, list); fail("Expected NullPointerException for null list first parameter"); } catch (NullPointerException e) { //Expected } try { Collections.lastIndexOfSubList(list, null); fail("Expected NullPointerException for null list second parameter"); } catch (NullPointerException e) { //Expected } testwithCharList(1, string1, "B", false); testwithCharList(2, string1, "LIST", false); testwithCharList(3, string1, "SUBLIST", false); testwithCharList(4, string1, "END", false); testwithCharList(5, string1, "NONE", false); // test boundary conditions testwithCharList(6, "", "", false); testwithCharList(7, "LIST", "", false); testwithCharList(8, "", "SUBLIST", false); } public void test_lastIndexOfSubList2() { ArrayList sub = new ArrayList(); sub.add(new Integer(1)); sub.add(new Integer(2)); sub.add(new Integer(3)); ArrayList sub2 = new ArrayList(); sub2.add(new Integer(7)); sub2.add(new Integer(8)); ArrayList src = new ArrayList(); src.addAll(sub); src.addAll(sub); src.addAll(sub); src.add(new Integer(5)); src.add(new Integer(6)); // so src is a list like this: // [1, 2, 3, 1, 2, 3, 1, 2, 3, 5, 6] Collections.reverse(src); // it becomes like this : // [6, 5, 3, 2, 1, 3, 2, 1, 3, 2, 1] sub = new ArrayList(src.subList(0, 8)); // [6, 5, 3, 2, 1, 3, 2, 1] assertEquals("TestA : Returned wrong lastIndexOfSubList, ", 0, Collections.lastIndexOfSubList(src, sub)); sub = new ArrayList(src.subList(0, 5)); // [6, 5, 3, 2, 1] assertEquals("TestB : Returned wrong lastIndexOfSubList, ", 0, Collections.lastIndexOfSubList(src, sub)); sub = new ArrayList(src.subList(2, 5)); // [3, 2, 1] assertEquals("TestC : Returned wrong lastIndexOfSubList, ", 8, Collections.lastIndexOfSubList(src, sub)); sub = new ArrayList(src.subList(9, 11)); // [2, 1] assertEquals("TestD : Returned wrong lastIndexOfSubList, ", 9, Collections.lastIndexOfSubList(src, sub)); sub = new ArrayList(src.subList(10, 11)); // [1] assertEquals("TestE : Returned wrong lastIndexOfSubList, ", 10, Collections.lastIndexOfSubList(src, sub)); sub = new ArrayList(src.subList(0, 2)); // [6, 5] assertEquals("TestF : Returned wrong lastIndexOfSubList, ", 0, Collections.lastIndexOfSubList(src, sub)); sub = new ArrayList(src.subList(0, 1)); // [6] assertEquals("TestG : Returned wrong lastIndexOfSubList, ", 0, Collections.lastIndexOfSubList(src, sub)); sub = new ArrayList(src.subList(0, 11)); // the whole list assertEquals("TestH : Returned wrong lastIndexOfSubList, ", 0, Collections.lastIndexOfSubList(src, sub)); // a non-matching list assertEquals("TestI : Returned wrong lastIndexOfSubList, ", -1, Collections.lastIndexOfSubList(src, sub2)); } public void test_listLjava_util_Enumeration() { // Test for method java.util.ArrayList list(java.util.Enumeration) Enumeration e = Collections.enumeration(ll); ArrayList al = Collections.list(e); int size = al.size(); assertEquals("Wrong size", ll.size(), size); for (int i = 0; i < size; i++) { assertEquals("wrong element at position " + i + ",", ll.get(i), al .get(i)); } } public void test_synchronizedCollectionLjava_util_Collection() { // Test for method java.util.Collection // java.util.Collections.synchronizedCollection(java.util.Collection) LinkedList smallList = new LinkedList(); for (int i = 0; i < 50; i++) { smallList.add(objArray[i]); } final int numberOfLoops = 200; Collection synchCol = Collections.synchronizedCollection(smallList); // Replacing the previous line with the line below *should* cause the // test to fail--the collecion below isn't synchronized // Collection synchCol = smallList; SynchCollectionChecker normalSynchChecker = new SynchCollectionChecker( synchCol, false, numberOfLoops); SynchCollectionChecker offsetSynchChecker = new SynchCollectionChecker( synchCol, true, numberOfLoops); Thread normalThread = new Thread(normalSynchChecker); Thread offsetThread = new Thread(offsetSynchChecker); normalThread.start(); offsetThread.start(); while ((normalSynchChecker.getNumberOfChecks() < numberOfLoops) || (offsetSynchChecker.getNumberOfChecks() < numberOfLoops)) { try { Thread.sleep(10); } catch (InterruptedException e) { } } assertTrue("Returned collection corrupted by multiple thread access", normalSynchChecker.getResult() && offsetSynchChecker.getResult()); try { normalThread.join(5000); offsetThread.join(5000); } catch (InterruptedException e) { fail("join() interrupted"); } synchCol.add(null); assertTrue("Trying to use nulls in collection failed", synchCol .contains(null)); smallList = new LinkedList(); for (int i = 0; i < 100; i++) { smallList.add(objArray[i]); } new Support_CollectionTest("", Collections .synchronizedCollection(smallList)).runTest(); //Test self reference synchCol = Collections.synchronizedCollection(smallList); synchCol.add(smallList); assertTrue("should contain self ref", synchCol.toString().indexOf("(this") > -1); } public void test_synchronizedListLjava_util_List() { try { Collections.synchronizedList(null); fail("Expected NullPointerException for null list parameter"); } catch (NullPointerException e) { //Expected } // test with a Sequential Access List List smallList = new LinkedList(); testSynchronizedList(smallList, "Sequential Access"); smallList = new LinkedList(); List myList; for (int i = 0; i < 100; i++) { smallList.add(objArray[i]); } myList = Collections.synchronizedList(smallList); new Support_ListTest("", myList).runTest(); // test with a Random Access List smallList = new ArrayList(); testSynchronizedList(smallList, "Random Access"); smallList = new ArrayList(); for (int i = 0; i < 100; i++) { smallList.add(objArray[i]); } myList = Collections.synchronizedList(smallList); new Support_ListTest("", myList).runTest(); //Test self reference myList = Collections.synchronizedList(smallList); myList.add(smallList); assertTrue("should contain self ref", myList.toString().indexOf("(this") > -1); } private void testSynchronizedList(List smallList, String type) { for (int i = 0; i < 50; i++) { smallList.add(objArray[i]); } final int numberOfLoops = 200; List synchList = Collections.synchronizedList(smallList); if (type.equals("Random Access")) assertTrue( "Returned synchronized list should implement the Random Access interface", synchList instanceof RandomAccess); else assertTrue( "Returned synchronized list should not implement the Random Access interface", !(synchList instanceof RandomAccess)); // Replacing the previous line with the line below *should* cause the // test to fail--the list below isn't synchronized // List synchList = smallList; SynchCollectionChecker normalSynchChecker = new SynchCollectionChecker( synchList, false, numberOfLoops); SynchCollectionChecker offsetSynchChecker = new SynchCollectionChecker( synchList, true, numberOfLoops); Thread normalThread = new Thread(normalSynchChecker); Thread offsetThread = new Thread(offsetSynchChecker); normalThread.start(); offsetThread.start(); while ((normalSynchChecker.getNumberOfChecks() < numberOfLoops) || (offsetSynchChecker.getNumberOfChecks() < numberOfLoops)) { try { Thread.sleep(10); } catch (InterruptedException e) { //Expected } } assertTrue( type + " list tests: Returned list corrupted by multiple thread access", normalSynchChecker.getResult() && offsetSynchChecker.getResult()); try { normalThread.join(5000); offsetThread.join(5000); } catch (InterruptedException e) { fail(type + " list tests: join() interrupted"); } synchList.set(25, null); assertNull(type + " list tests: Trying to use nulls in list failed", synchList.get(25)); } public void test_synchronizedMapLjava_util_Map() { // Test for method java.util.Map // java.util.Collections.synchronizedMap(java.util.Map) HashMap smallMap = new HashMap(); for (int i = 0; i < 50; i++) { smallMap.put(objArray[i], objArray[i]); } final int numberOfLoops = 200; Map synchMap = Collections.synchronizedMap(smallMap); // Replacing the previous line with the line below should cause the test // to fail--the list below isn't synchronized // Map synchMap = smallMap; SynchMapChecker normalSynchChecker = new SynchMapChecker(synchMap, false, numberOfLoops); SynchMapChecker offsetSynchChecker = new SynchMapChecker(synchMap, true, numberOfLoops); Thread normalThread = new Thread(normalSynchChecker); Thread offsetThread = new Thread(offsetSynchChecker); normalThread.start(); offsetThread.start(); while ((normalSynchChecker.getNumberOfChecks() < numberOfLoops) || (offsetSynchChecker.getNumberOfChecks() < numberOfLoops)) { try { Thread.sleep(10); } catch (InterruptedException e) { //Expected } } assertTrue("Returned map corrupted by multiple thread access", normalSynchChecker.getResult() && offsetSynchChecker.getResult()); try { normalThread.join(5000); offsetThread.join(5000); } catch (InterruptedException e) { fail("join() interrupted"); } // synchronized map does not have to permit null keys or values synchMap.put(new Long(25), null); synchMap.put(null, new Long(30)); assertNull("Trying to use a null value in map failed", synchMap .get(new Long(25))); assertTrue("Trying to use a null key in map failed", synchMap.get(null) .equals(new Long(30))); smallMap = new HashMap(); for (int i = 0; i < 100; i++) { smallMap.put(objArray[i].toString(), objArray[i]); } synchMap = Collections.synchronizedMap(smallMap); new MapTestSupport(synchMap).runTest(); synchMap.keySet().remove(objArray[50].toString()); assertNull( "Removing a key from the keySet of the synchronized map did not remove it from the synchronized map: ", synchMap.get(objArray[50].toString())); assertNull( "Removing a key from the keySet of the synchronized map did not remove it from the original map", smallMap.get(objArray[50].toString())); } public void test_unmodifiableMap_LinkedHashMap() { // LinkedHashMap has a well defined iteration order and shows ordering issues with // entrySet() / keySet() methods: iterator(), toArray(T[]) and toArray(). See bug 72073. LinkedHashMap smallMap = new LinkedHashMap(); for (int i = 0; i < 100; i++) { Integer object = objArray[i]; smallMap.put(object.toString(), object); } new MapTestSupport(smallMap).runTest(); } public void test_synchronizedSetLjava_util_Set() { // Test for method java.util.Set // java.util.Collections.synchronizedSet(java.util.Set) HashSet smallSet = new HashSet(); for (int i = 0; i < 50; i++) { smallSet.add(objArray[i]); } final int numberOfLoops = 200; Set synchSet = Collections.synchronizedSet(smallSet); // Replacing the previous line with the line below should cause the test // to fail--the set below isn't synchronized // Set synchSet = smallSet; SynchCollectionChecker normalSynchChecker = new SynchCollectionChecker( synchSet, false, numberOfLoops); SynchCollectionChecker offsetSynchChecker = new SynchCollectionChecker( synchSet, true, numberOfLoops); Thread normalThread = new Thread(normalSynchChecker); Thread offsetThread = new Thread(offsetSynchChecker); normalThread.start(); offsetThread.start(); while ((normalSynchChecker.getNumberOfChecks() < numberOfLoops) || (offsetSynchChecker.getNumberOfChecks() < numberOfLoops)) { try { Thread.sleep(10); } catch (InterruptedException e) { //Expected } } assertTrue("Returned set corrupted by multiple thread access", normalSynchChecker.getResult() && offsetSynchChecker.getResult()); try { normalThread.join(5000); offsetThread.join(5000); } catch (InterruptedException e) { fail("join() interrupted"); } Set mySet = Collections.synchronizedSet(smallSet); mySet.add(null); assertTrue("Trying to use nulls in list failed", mySet.contains(null)); smallSet = new HashSet(); for (int i = 0; i < 100; i++) { smallSet.add(objArray[i]); } new Support_SetTest("", Collections.synchronizedSet(smallSet)) .runTest(); //Test self reference mySet = Collections.synchronizedSet(smallSet); mySet.add(smallSet); assertTrue("should contain self ref", mySet.toString().indexOf("(this") > -1); } public void test_synchronizedSortedMapLjava_util_SortedMap() { // Test for method java.util.SortedMap // java.util.Collections.synchronizedSortedMap(java.util.SortedMap) TreeMap smallMap = new TreeMap(); for (int i = 0; i < 50; i++) { smallMap.put(objArray[i], objArray[i]); } final int numberOfLoops = 200; Map synchMap = Collections.synchronizedMap(smallMap); // Replacing the previous line with the line below should cause the test // to fail--the list below isn't synchronized // Map synchMap = smallMap; SynchMapChecker normalSynchChecker = new SynchMapChecker(synchMap, false, numberOfLoops); SynchMapChecker offsetSynchChecker = new SynchMapChecker(synchMap, true, numberOfLoops); Thread normalThread = new Thread(normalSynchChecker); Thread offsetThread = new Thread(offsetSynchChecker); normalThread.start(); offsetThread.start(); while ((normalSynchChecker.getNumberOfChecks() < numberOfLoops) || (offsetSynchChecker.getNumberOfChecks() < numberOfLoops)) { try { Thread.sleep(10); } catch (InterruptedException e) { //Expected } } assertTrue("Returned map corrupted by multiple thread access", normalSynchChecker.getResult() && offsetSynchChecker.getResult()); try { normalThread.join(5000); offsetThread.join(5000); } catch (InterruptedException e) { fail("join() interrupted"); } smallMap = new TreeMap(); for (int i = 0; i < 100; i++) { smallMap.put(objArray[i].toString(), objArray[i]); } synchMap = Collections.synchronizedSortedMap(smallMap); new MapTestSupport(synchMap).runTest(); synchMap.keySet().remove(objArray[50].toString()); assertNull( "Removing a key from the keySet of the synchronized map did not remove it from the synchronized map", synchMap.get(objArray[50].toString())); assertNull( "Removing a key from the keySet of the synchronized map did not remove it from the original map", smallMap.get(objArray[50].toString())); } public void test_synchronizedSortedSetLjava_util_SortedSet() { // Test for method java.util.SortedSet // java.util.Collections.synchronizedSortedSet(java.util.SortedSet) TreeSet smallSet = new TreeSet(); for (int i = 0; i < 50; i++) { smallSet.add(objArray[i]); } final int numberOfLoops = 200; Set synchSet = Collections.synchronizedSet(smallSet); // Replacing the previous line with the line below should cause the test // to fail--the list below isn't synchronized // Set synchSet = smallSet; SynchCollectionChecker normalSynchChecker = new SynchCollectionChecker( synchSet, false, numberOfLoops); SynchCollectionChecker offsetSynchChecker = new SynchCollectionChecker( synchSet, true, numberOfLoops); Thread normalThread = new Thread(normalSynchChecker); Thread offsetThread = new Thread(offsetSynchChecker); normalThread.start(); offsetThread.start(); while ((normalSynchChecker.getNumberOfChecks() < numberOfLoops) || (offsetSynchChecker.getNumberOfChecks() < numberOfLoops)) { try { Thread.sleep(10); } catch (InterruptedException e) { //Expected } } assertTrue("Returned set corrupted by multiple thread access", normalSynchChecker.getResult() && offsetSynchChecker.getResult()); try { normalThread.join(5000); offsetThread.join(5000); } catch (InterruptedException e) { fail("join() interrupted"); } } public void test_unmodifiableCollectionLjava_util_Collection() { // Test for method java.util.Collection // java.util.Collections.unmodifiableCollection(java.util.Collection) boolean exception = false; Collection c = Collections.unmodifiableCollection(ll); assertTrue("Returned collection is of incorrect size", c.size() == ll .size()); Iterator iterator = ll.iterator(); while (iterator.hasNext()) assertTrue("Returned list missing elements", c.contains(iterator.next())); try { c.add(new Object()); } catch (UnsupportedOperationException e) { exception = true; // Correct } if (!exception) { fail("Allowed modification of collection"); } try { c.remove(new Object()); fail("Allowed modification of collection"); } catch (UnsupportedOperationException e) { // Correct } Collection myCollection = new ArrayList(); myCollection.add(new Integer(20)); myCollection.add(null); c = Collections.unmodifiableCollection(myCollection); assertTrue("Collection should contain null", c.contains(null)); assertTrue("Collection should contain Integer(20)", c .contains(new Integer(20))); myCollection = new ArrayList(); for (int i = 0; i < 100; i++) { myCollection.add(objArray[i]); } new Support_UnmodifiableCollectionTest("", Collections .unmodifiableCollection(myCollection)).runTest(); } public void test_unmodifiableListLjava_util_List() { // Test for method java.util.List // java.util.Collections.unmodifiableList(java.util.List) // test with a Sequential Access List boolean exception = false; List c = Collections.unmodifiableList(ll); // Ensure a NPE is thrown if the list is NULL try { Collections.unmodifiableList(null); fail("Expected NullPointerException for null list parameter"); } catch (NullPointerException e) { } assertTrue("Returned list is of incorrect size", c.size() == ll.size()); assertTrue( "Returned List should not implement Random Access interface", !(c instanceof RandomAccess)); Iterator iterator = ll.iterator(); while (iterator.hasNext()) assertTrue("Returned list missing elements", c.contains(iterator.next())); try { c.add(new Object()); } catch (UnsupportedOperationException e) { exception = true; // Correct } if (!exception) { fail("Allowed modification of list"); } try { c.remove(new Object()); fail("Allowed modification of list"); } catch (UnsupportedOperationException e) { // Correct } // test with a Random Access List List smallList = new ArrayList(); smallList.add(null); smallList.add("yoink"); c = Collections.unmodifiableList(smallList); assertNull("First element should be null", c.get(0)); assertTrue("List should contain null", c.contains(null)); assertTrue( "T1. Returned List should implement Random Access interface", c instanceof RandomAccess); smallList = new ArrayList(); for (int i = 0; i < 100; i++) { smallList.add(objArray[i]); } List myList = Collections.unmodifiableList(smallList); assertTrue("List should not contain null", !myList.contains(null)); assertTrue( "T2. Returned List should implement Random Access interface", myList instanceof RandomAccess); assertTrue("get failed on unmodifiable list", myList.get(50).equals( new Integer(50))); ListIterator listIterator = myList.listIterator(); for (int i = 0; listIterator.hasNext(); i++) { assertTrue("List has wrong elements", ((Integer) listIterator .next()).intValue() == i); } new Support_UnmodifiableCollectionTest("", smallList).runTest(); } public void test_unmodifiableMapLjava_util_Map() { // Test for method java.util.Map // java.util.Collections.unmodifiableMap(java.util.Map) boolean exception = false; Map c = Collections.unmodifiableMap(hm); assertTrue("Returned map is of incorrect size", c.size() == hm.size()); Iterator iterator = hm.keySet().iterator(); while (iterator.hasNext()) { Object x = iterator.next(); assertTrue("Returned map missing elements", c.get(x).equals( hm.get(x))); } try { c.put(new Object(), ""); } catch (UnsupportedOperationException e) { exception = true; // Correct } assertTrue("Allowed modification of map", exception); exception = false; try { c.remove(new Object()); } catch (UnsupportedOperationException e) { // Correct exception = true; } assertTrue("Allowed modification of map", exception); exception = false; Iterator entrySetIterator = c.entrySet().iterator(); Map.Entry entry = (Map.Entry) entrySetIterator.next(); try { entry.setValue("modified"); } catch (UnsupportedOperationException e) { // Correct exception = true; } assertTrue("Allowed modification of entry", exception); exception = false; Object[] array = c.entrySet().toArray(); try { ((Map.Entry) array[0]).setValue("modified"); } catch (UnsupportedOperationException e) { // Correct exception = true; } assertTrue("Allowed modification of array entry", exception); exception = false; Map.Entry[] array2 = (Map.Entry[]) c.entrySet().toArray( new Map.Entry[0]); try { array2[0].setValue("modified"); } catch (UnsupportedOperationException e) { // Correct exception = true; } assertTrue("Allowed modification of array entry2", exception); HashMap smallMap = new HashMap(); smallMap.put(null, new Long(30)); smallMap.put(new Long(25), null); Map unmodMap = Collections.unmodifiableMap(smallMap); assertNull("Trying to use a null value in map failed", unmodMap .get(new Long(25))); assertTrue("Trying to use a null key in map failed", unmodMap.get(null) .equals(new Long(30))); smallMap = new HashMap(); for (int i = 0; i < 100; i++) { smallMap.put(objArray[i].toString(), objArray[i]); } new MapTestSupport(smallMap).runTest(); } public void test_unmodifiableSetLjava_util_Set() { // Test for method java.util.Set // java.util.Collections.unmodifiableSet(java.util.Set) boolean exception = false; Set c = Collections.unmodifiableSet(s); assertTrue("Returned set is of incorrect size", c.size() == s.size()); Iterator iterator = ll.iterator(); while (iterator.hasNext()) assertTrue("Returned set missing elements", c.contains(iterator.next())); try { c.add(new Object()); } catch (UnsupportedOperationException e) { exception = true; // Correct } if (!exception) { fail("Allowed modification of set"); } try { c.remove(new Object()); fail("Allowed modification of set"); } catch (UnsupportedOperationException e) { // Correct } Set mySet = Collections.unmodifiableSet(new HashSet()); assertTrue("Should not contain null", !mySet.contains(null)); mySet = Collections.unmodifiableSet(Collections.singleton(null)); assertTrue("Should contain null", mySet.contains(null)); mySet = new TreeSet(); for (int i = 0; i < 100; i++) { mySet.add(objArray[i]); } new Support_UnmodifiableCollectionTest("", Collections .unmodifiableSet(mySet)).runTest(); } public void test_unmodifiableSortedMapLjava_util_SortedMap() { // Test for method java.util.SortedMap // java.util.Collections.unmodifiableSortedMap(java.util.SortedMap) boolean exception = false; TreeMap tm = new TreeMap(); tm.putAll(hm); Map c = Collections.unmodifiableSortedMap(tm); assertTrue("Returned map is of incorrect size", c.size() == tm.size()); Iterator i = hm.keySet().iterator(); while (i.hasNext()) { Object x = i.next(); assertTrue("Returned map missing elements", c.get(x).equals( tm.get(x))); } try { c.put(new Object(), ""); } catch (UnsupportedOperationException e) { exception = true; // Correct } if (!exception) { fail("Allowed modification of map"); } try { c.remove(new Object()); } catch (UnsupportedOperationException e) { // Correct return; } fail("Allowed modification of map"); } public void test_unmodifiableSortedSetLjava_util_SortedSet() { // Test for method java.util.SortedSet // java.util.Collections.unmodifiableSortedSet(java.util.SortedSet) boolean exception = false; SortedSet ss = new TreeSet(); ss.addAll(s); SortedSet c = Collections.unmodifiableSortedSet(ss); assertTrue("Returned set is of incorrect size", c.size() == ss.size()); Iterator i = ll.iterator(); while (i.hasNext()) assertTrue("Returned set missing elements", c.contains(i.next())); try { c.add(new Object()); } catch (UnsupportedOperationException e) { exception = true; // Correct } if (!exception) { fail("Allowed modification of set"); } try { c.remove(new Object()); } catch (UnsupportedOperationException e) { // Correct return; } fail("Allowed modification of set"); } /** * Test unmodifiable objects toString methods */ public void test_unmodifiable_toString_methods() { // Regression for HARMONY-552 ArrayList al = new ArrayList(); al.add("a"); al.add("b"); Collection uc = Collections.unmodifiableCollection(al); assertEquals("[a, b]", uc.toString()); HashMap m = new HashMap(); m.put("one", "1"); m.put("two", "2"); Map um = Collections.unmodifiableMap(m); assertTrue("{one=1, two=2}".equals(um.toString()) || "{two=2, one=1}".equals(um.toString())); } public void test_singletonListLjava_lang_Object() { // Test for method java.util.Set // java.util.Collections.singleton(java.lang.Object) String str = "Singleton"; List single = Collections.singletonList(str); assertEquals(1, single.size()); assertTrue(single.contains(str)); assertFalse(single.contains(null)); assertFalse(Collections.singletonList(null).contains(str)); assertTrue(Collections.singletonList(null).contains(null)); try { single.add("New element"); fail("UnsupportedOperationException expected"); } catch (UnsupportedOperationException e) { //expected } } public void test_singletonMapLjava_lang_Object() { // Test for method java.util.Set // java.util.Collections.singleton(java.lang.Object) Double key = new Double (3.14); String value = "Fundamental constant"; Map single = Collections.singletonMap(key, value); assertEquals(1, single.size()); assertTrue(single.containsKey(key)); assertTrue(single.containsValue(value)); assertFalse(single.containsKey(null)); assertFalse(single.containsValue(null)); assertFalse(Collections.singletonMap(null, null).containsKey(key)); assertFalse(Collections.singletonMap(null, null).containsValue(value)); assertTrue(Collections.singletonMap(null, null).containsKey(null)); assertTrue(Collections.singletonMap(null, null).containsValue(null)); try { single.clear(); fail("UnsupportedOperationException expected"); } catch (UnsupportedOperationException e) { //expected } try { single.put(new Double(1), "one wrong value"); fail("UnsupportedOperationException expected"); } catch (UnsupportedOperationException e) { //expected } } public void test_checkType_Ljava_lang_Object_Ljava_lang_Class() throws Exception { Method m = Collections.class.getDeclaredMethod("checkType", Object.class, Class.class); m.setAccessible(true); m.invoke(null, new Object(), Object.class); try { m.invoke(null, new Object(), int.class); fail(); } catch (InvocationTargetException expected) { } } public void test_binarySearch_asymmetry_with_comparator() throws Exception { List list = new ArrayList(); String s1 = new String("a"); String s2 = new String("aa"); String s3 = new String("aaa"); list.add(s1); list.add(s2); list.add(s3); Collections.sort(list); Object o = Collections.binarySearch(list, 1, new StringComparator()); assertSame(0, o); } public void test_binarySearch_asymmetry() throws Exception { List list = new LinkedList(); String s1 = new String("a"); String s2 = new String("aa"); String s3 = new String("aaa"); list.add(new MyComparable(s1)); list.add(new MyComparable(s2)); list.add(new MyComparable(s3)); Collections.sort(list); Object o = Collections.binarySearch(list, 1); assertSame(0, o); } private class MyComparable implements Comparable { public String s; public MyComparable(String s) { this.s = s; } public int compareTo(Object another) { int length = 0; if (another instanceof MyComparable) { length = (((MyComparable) another).s).length(); } else { length = (Integer) another; } return s.length() - length; } } private class StringComparator implements Comparator { public int compare(Object object1, Object object2) { String s = (String) object1; int length; if (object2 instanceof String) { length = ((String) object2).length(); } else { length = (Integer) object2; } return s.length() - length; } } public void test_newSetFromMap_LMap() throws Exception { Integer testInt[] = new Integer[100]; for (int i = 0; i < testInt.length; i++) { testInt[i] = new Integer(i); } Map map = new HashMap(); Set set = Collections.newSetFromMap(map); for (int i = 0; i < testInt.length; i++) { map.put(testInt[i], true); } // operater on map successed map.put(testInt[1], false); assertTrue(map.containsKey(testInt[1])); assertEquals(100, map.size()); assertFalse(map.get(testInt[1])); assertEquals(100, set.size()); assertTrue(set.contains(testInt[16])); Iterator setIter = set.iterator(); Iterator mapIter = map.keySet().iterator(); int i = 0; // in the same order while (setIter.hasNext()) { assertEquals(mapIter.next(), setIter.next()); } // operator on set successed Integer testInt101 = new Integer(101); Integer testInt102 = new Integer(102); set.add(testInt101); assertTrue(set.contains(testInt101)); assertTrue(map.get(testInt101)); // operator on map still passes map.put(testInt102, false); assertTrue(set.contains(testInt102)); assertFalse(map.get(testInt102)); // exception thrown try { Collections.newSetFromMap(map); fail("should throw IllegalArgumentException"); } catch (IllegalArgumentException e) { // expected } } /** * serialization/deserialization. */ @SuppressWarnings({ "unchecked", "boxing" }) public void testSerializationSelf_newSetFromMap() throws Exception { Integer testInt[] = new Integer[100]; for (int i = 0; i < testInt.length; i++) { testInt[i] = new Integer(i); } Map map = new HashMap(); Set set = Collections.newSetFromMap(map); for (int i = 0; i < testInt.length; i++) { map.put(testInt[i], true); } SerializationTest.verifySelf(set); } public void test_asLifoQueue() throws Exception { Integer testInt[] = new Integer[100]; Integer test101 = new Integer(101); for (int i = 0; i < testInt.length; i++) { testInt[i] = new Integer(i); } Deque deque = new ArrayDeque(); Queue que = Collections.asLifoQueue(deque); for (int i = 0; i < testInt.length; i++) { que.add(testInt[i]); } assertEquals(100, deque.size()); assertEquals(100, que.size()); for (int i = testInt.length - 1; i >= 0; i--) { assertEquals(testInt[i], deque.pop()); } assertEquals(0, deque.size()); assertEquals(0, que.size()); for (int i = 0; i < testInt.length; i++) { deque.push(testInt[i]); } assertEquals(100, deque.size()); assertEquals(100, que.size()); Collection col = new LinkedList(); col.add(test101); que.addAll(col); assertEquals(test101, que.remove()); for (int i = testInt.length - 1; i >= 0; i--) { assertEquals(testInt[i], que.remove()); } assertEquals(0, deque.size()); assertEquals(0, que.size()); } /** * serialization/deserialization. */ @SuppressWarnings({ "unchecked", "boxing" }) public void testSerializationSelf_asLifoQueue() throws Exception { Integer testInt[] = new Integer[100]; for (int i = 0; i < testInt.length; i++) { testInt[i] = new Integer(i); } Deque deque = new ArrayDeque(); Queue que = Collections.asLifoQueue(deque); for (int i = 0; i < testInt.length; i++) { que.add(testInt[i]); } SerializationTest.verifySelf(que, new SerializableAssert() { public void assertDeserialized(Serializable initial, Serializable deserialized) { Queue initque = (Queue) initial; Queue deserque = (Queue) deserialized; while (!initque.isEmpty()) { assertEquals(initque.remove(), deserque.remove()); } } }); } public void test_emptyList() { List list = Collections.emptyList(); assertTrue("should be true", list.isEmpty()); } @Override protected void setUp() throws Exception { super.setUp(); objArray = new Integer[1000]; myobjArray = new Object[1000]; for (int i = 0; i < objArray.length; i++) { objArray[i] = i; myobjArray[i] = new MyInt(i); } ll = new LinkedList(); myll = new LinkedList(); s = new HashSet(); mys = new HashSet(); reversedLinkedList = new LinkedList(); // to be sorted in reverse order myReversedLinkedList = new LinkedList(); // to be sorted in reverse // order hm = new HashMap(); for (int i = 0; i < objArray.length; i++) { ll.add(objArray[i]); myll.add(myobjArray[i]); s.add(objArray[i]); mys.add(myobjArray[i]); reversedLinkedList.add(objArray[objArray.length - i - 1]); myReversedLinkedList.add(myobjArray[myobjArray.length - i - 1]); hm.put(objArray[i].toString(), objArray[i]); } } /** * A class shared by various Map-related tests that checks the properties and contents of a * supplied Map and compares the some methods to the same map when wrapped with * {@link Collections#unmodifiableMap(java.util.Map)}. */ static class MapTestSupport { // must be a map containing the string keys "0"-"99" paired with the Integer // values Integer(0) to Integer(99) private final Map modifiableMap; private final Map unmodifiableMap; public MapTestSupport(Map modifiableMap) { this.modifiableMap = modifiableMap; unmodifiableMap = Collections.unmodifiableMap(modifiableMap); } public void runTest() { testContents(modifiableMap); testContents(unmodifiableMap); // values() new Support_UnmodifiableCollectionTest("values() from map test", modifiableMap.values()) .runTest(); new Support_UnmodifiableCollectionTest("values() from unmodifiable map test", unmodifiableMap.values()).runTest(); // entrySet() testEntrySet(modifiableMap.entrySet(), unmodifiableMap.entrySet()); // keySet() testKeySet(modifiableMap.keySet(), unmodifiableMap.keySet()); } private static void testContents(Map map) { // size assertTrue("Size should return 100, returned: " + map.size(), map.size() == 100); // containsKey assertTrue("Should contain the key \"0\"", map.containsKey("0")); assertTrue("Should contain the key \"50\"", map.containsKey("50")); assertTrue("Should not contain the key \"100\"", !map.containsKey("100")); // containsValue assertTrue("Should contain the value 0", map.containsValue(0)); assertTrue("Should contain the value 50", map.containsValue(50)); assertTrue("Should not contain value 100", !map.containsValue(100)); // get assertTrue("getting \"0\" didn't return 0", map.get("0") == 0); assertTrue("getting \"50\" didn't return 50", map.get("50") == 50); assertNull("getting \"100\" didn't return null", map.get("100")); // isEmpty assertTrue("should have returned false to isEmpty", !map.isEmpty()); } private static void testEntrySet( Set> referenceEntrySet, Set> entrySet) { // entrySet should be a set of mappings {"0", 0}, {"1",1}... {"99", 99} assertEquals(100, referenceEntrySet.size()); assertEquals(100, entrySet.size()); // The ordering may be undefined for a map implementation but the ordering must be the // same across iterator(), toArray() and toArray(T[]) for a given map *and* the same for the // modifiable and unmodifiable map. crossCheckOrdering(referenceEntrySet, entrySet, Map.Entry.class); } private static void testKeySet(Set referenceKeySet, Set keySet) { // keySet should be a set of the strings "0" to "99" testKeySetContents(referenceKeySet); testKeySetContents(keySet); // The ordering may be undefined for a map implementation but the ordering must be the // same across iterator(), toArray() and toArray(T[]) for a given map *and* the same for the // modifiable and unmodifiable map. crossCheckOrdering(referenceKeySet, keySet, String.class); } private static void testKeySetContents(Set keySet) { // contains assertTrue("should contain \"0\"", keySet.contains("0")); assertTrue("should contain \"50\"", keySet.contains("50")); assertTrue("should not contain \"100\"", !keySet.contains("100")); // containsAll HashSet hs = new HashSet(); hs.add("0"); hs.add("25"); hs.add("99"); assertTrue("Should contain set of \"0\", \"25\", and \"99\"", keySet.containsAll(hs)); hs.add("100"); assertTrue("Should not contain set of \"0\", \"25\", \"99\" and \"100\"", !keySet.containsAll(hs)); // isEmpty assertTrue("Should not be empty", !keySet.isEmpty()); // size assertEquals("Returned wrong size.", 100, keySet.size()); } private static void crossCheckOrdering(Set set1, Set set2, Class elementType) { Iterator set1Iterator = set1.iterator(); Iterator set2Iterator = set2.iterator(); T[] zeroLengthArray = createArray(elementType, 0); T[] set1TypedArray1 = set1.toArray(zeroLengthArray); assertEquals(set1.size(), set1TypedArray1.length); // Compare set1.iterator(), set2.iterator() and set1.toArray(new T[0]) int entryCount = 0; while (set1Iterator.hasNext()) { T set1Entry = set1Iterator.next(); T set2Entry = set2Iterator.next(); // Compare set1 with set2 assertEquals(set1Entry, set2Entry); // Compare the iterator with the array. The arrays will be checked against each other. assertEquals(set1Entry, set1TypedArray1[entryCount]); entryCount++; } assertFalse(set2Iterator.hasNext()); assertEquals(set1.size(), entryCount); // Compare the various arrays with each other. // set1.toArray(new T[size]) T[] parameterArray1 = createArray(elementType, set1.size()); T[] set1TypedArray2 = set1.toArray(parameterArray1); assertSame(set1TypedArray2, parameterArray1); assertArrayEquals(set1TypedArray1, set1TypedArray2); // set1.toArray() Object[] set1UntypedArray = set1.toArray(); assertEquals(set1.size(), set1UntypedArray.length); assertArrayEquals(set1TypedArray1, set1UntypedArray); // set2.toArray(new T[0]) T[] set2TypedArray1 = set2.toArray(zeroLengthArray); assertEquals(set1.size(), set2TypedArray1.length); assertArrayEquals(set1TypedArray1, set2TypedArray1); // set2.toArray(new T[size]) T[] parameterArray2 = createArray(elementType, set2.size()); T[] set2TypedArray2 = set1.toArray(parameterArray2); assertSame(set2TypedArray2, parameterArray2); assertArrayEquals(set1TypedArray1, set1TypedArray2); // set2.toArray() Object[] set2UntypedArray = set2.toArray(); assertArrayEquals(set1TypedArray1, set2UntypedArray); } private static void assertArrayEquals(T[] array1, T[] array2) { assertTrue(Arrays.equals(array1, array2)); } @SuppressWarnings("unchecked") private static T[] createArray(Class elementType, int size) { return (T[]) Array.newInstance(elementType, size); } } }