Java tutorial
package org.dcm4chee.archive.conf; import java.lang.reflect.Array; import java.lang.reflect.Field; import java.lang.reflect.Modifier; import java.util.ArrayList; import java.util.Arrays; import java.util.Collection; import java.util.Collections; import java.util.HashMap; import java.util.HashSet; import java.util.Iterator; import java.util.LinkedList; import java.util.List; import java.util.Map; import java.util.Set; import java.util.SortedMap; import java.util.SortedSet; import java.util.concurrent.ConcurrentHashMap; import org.apache.commons.lang3.ClassUtils; /** * Test two objects for equivalence with a 'deep' comparison. This will traverse * the Object graph and perform either a field-by-field comparison on each * object (if no .equals() method has been overridden from Object), or it * will call the customized .equals() method if it exists. This method will * allow object graphs loaded at different times (with different object ids) * to be reliably compared. Object.equals() / Object.hashCode() rely on the * object's identity, which would not consider two equivalent objects necessarily * equals. This allows graphs containing instances of Classes that did not * overide .equals() / .hashCode() to be compared. For example, testing for * existence in a cache. Relying on an object's identity will not locate an * equivalent object in a cache.<br/><br/> * * This method will handle cycles correctly, for example A->B->C->A. Suppose a and * a' are two separate instances of A with the same values for all fields on * A, B, and C. Then a.deepEquals(a') will return true. It uses cycle detection * storing visited objects in a Set to prevent endless loops. * * @author John DeRegnaucourt (jdereg@gmail.com) * <br/> * Copyright [2010] John DeRegnaucourt * <br/><br/> * Licensed 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 * <br/><br/> * http://www.apache.org/licenses/LICENSE-2.0 * <br/><br/> * 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. */ public class DeepEquals { private static final Map<Class, Boolean> _customEquals = new ConcurrentHashMap<Class, Boolean>(); private static final Map<Class, Boolean> _customHash = new ConcurrentHashMap<Class, Boolean>(); private static final Map<Class, Collection<Field>> _reflectedFields = new ConcurrentHashMap<Class, Collection<Field>>(); private static class DualKey { private final Object _key1; private final Object _key2; public String fieldName; private DualKey(Object k1, Object k2) { _key1 = k1; _key2 = k2; } private DualKey(Object k1, Object k2, String string) { this(k1, k2); fieldName = string; } public boolean equals(Object other) { if (other == null) { return false; } if (!(other instanceof DualKey)) { return false; } DualKey that = (DualKey) other; return _key1 == that._key1 && _key2 == that._key2; } public int hashCode() { int h1 = _key1 != null ? _key1.hashCode() : 0; int h2 = _key2 != null ? _key2.hashCode() : 0; return h1 + h2; } @Override public String toString() { return "Field " + fieldName + ": \n " + (_key1 == null ? "null" : _key1.toString()) + " \n " + (_key2 == null ? "null" : _key2.toString()) + " \n ------- \n"; } } public interface CustomDeepEquals { public boolean deepEquals(Object first, Object second); } public static Map<Class<?>, CustomDeepEquals> customDeepEquals; public static DualKey lastDualKey; public static String lastClass; /** * Compare two objects with a 'deep' comparison. This will traverse the * Object graph and perform either a field-by-field comparison on each * object (if no .equals() method has been overridden from Object), or it * will call the customized .equals() method if it exists. This method will * allow object graphs loaded at different times (with different object ids) * to be reliably compared. Object.equals() / Object.hashCode() rely on the * object's identity, which would not consider to equivalent objects necessarily * equals. This allows graphs containing instances of Classes that did no * overide .equals() / .hashCode() to be compared. For example, testing for * existence in a cache. Relying on an objects identity will not locate an * object in cache, yet relying on it being equivalent will.<br/><br/> * * This method will handle cycles correctly, for example A->B->C->A. Suppose a and * a' are two separate instances of the A with the same values for all fields on * A, B, and C. Then a.deepEquals(a') will return true. It uses cycle detection * storing visited objects in a Set to prevent endless loops. * @param a Object one to compare * @param b Object two to compare * @return true if a is equivalent to b, false otherwise. Equivalent means that * all field values of both subgraphs are the same, either at the field level * or via the respectively encountered overridden .equals() methods during * traversal. */ public static boolean deepEquals(Object a, Object b) { Set visited = new HashSet<DualKey>(); LinkedList<DualKey> stack = new LinkedList<DualKey>(); stack.addFirst(new DualKey(a, b)); while (!stack.isEmpty()) { DualKey dualKey = stack.removeFirst(); lastDualKey = dualKey; visited.add(dualKey); if (dualKey._key1 == dualKey._key2) { // Same instance is always equal to itself. continue; } if (dualKey._key1 == null || dualKey._key2 == null) { // check if one is null and another is an empty array if (dualKey._key1 == null) { if (dualKey._key2.getClass().isArray() && ((Object[]) dualKey._key2).length == 0) continue; } if (dualKey._key2 == null) { if (dualKey._key1.getClass().isArray() && ((Object[]) dualKey._key1).length == 0) continue; } // If either one is null, not equal (both can't be null, due to above comparison). return false; } if (!dualKey._key1.getClass().equals(dualKey._key2.getClass())) { // Must be same class return false; } // Handle all [] types. In order to be equal, the arrays must be the same // length, be of the same type, be in the same order, and all elements within // the array must be deeply equivalent. if (dualKey._key1.getClass().isArray()) { if (!compareArrays(dualKey._key1, dualKey._key2, stack, visited)) { return false; } continue; } // Special handle SortedSets because they are fast to compare because their // elements must be in the same order to be equivalent Sets. if (dualKey._key1 instanceof SortedSet) { if (!compareOrderedCollection((Collection) dualKey._key1, (Collection) dualKey._key2, stack, visited)) { return false; } continue; } // Handled unordered Sets. This is a slightly more expensive comparison because order cannot // be assumed, a temporary Map must be created, however the comparison still runs in O(N) time. if (dualKey._key1 instanceof Set) { if (!compareUnorderedCollection((Collection) dualKey._key1, (Collection) dualKey._key2, stack, visited)) { return false; } continue; } // Check any Collection that is not a Set. In these cases, element order // matters, therefore this comparison is faster than using unordered comparison. if (dualKey._key1 instanceof Collection) { if (!compareOrderedCollection((Collection) dualKey._key1, (Collection) dualKey._key2, stack, visited)) { return false; } continue; } // Compare two SortedMaps. This takes advantage of the fact that these // Maps can be compared in O(N) time due to their ordering. if (dualKey._key1 instanceof SortedMap) { if (!compareSortedMap((SortedMap) dualKey._key1, (SortedMap) dualKey._key2, stack, visited)) { return false; } continue; } // Compare two Unordered Maps. This is a slightly more expensive comparison because // order cannot be assumed, therefore a temporary Map must be created, however the // comparison still runs in O(N) time. if (dualKey._key1 instanceof Map) { if (!compareUnorderedMap((Map) dualKey._key1, (Map) dualKey._key2, stack, visited)) { return false; } continue; } if (hasCustomEquals(dualKey._key1.getClass())) { if (!dualKey._key1.equals(dualKey._key2)) { return false; } continue; } lastClass = dualKey._key1.getClass().toString(); // check if we have a custom deepequals method for this class CustomDeepEquals de = customDeepEquals.get(dualKey._key1.getClass()); if (de != null) { if (!de.deepEquals(dualKey._key1, dualKey._key2)) return false; } else { Collection<Field> fields = getDeepDeclaredFields(dualKey._key1.getClass()); for (Field field : fields) { try { DualKey dk = new DualKey(field.get(dualKey._key1), field.get(dualKey._key2), field.getName()); if (!visited.contains(dk)) { stack.addFirst(dk); } } catch (Exception ignored) { } } } } return true; } /** * Deeply compare to Arrays []. Both arrays must be of the same type, same length, and all * elements within the arrays must be deeply equal in order to return true. * @param array1 [] type (Object[], String[], etc.) * @param array2 [] type (Object[], String[], etc.) * @param stack add items to compare to the Stack (Stack versus recursion) * @param visited Set of objects already compared (prevents cycles) * @return true if the two arrays are the same length and contain deeply equivalent items. */ private static boolean compareArrays(Object array1, Object array2, LinkedList stack, Set visited) { // Same instance check already performed... int len = Array.getLength(array1); if (len != Array.getLength(array2)) { return false; } // try sorting if (len > 0) { if (Array.get(array1, 0) instanceof Comparable) { Class<?> c = Array.get(array1, 0).getClass(); if (ClassUtils.isPrimitiveOrWrapper(c)) { /* Arrays.sort(array1); Arrays.sort((Object[]) array2);*/ } else { Arrays.sort((Object[]) array1); Arrays.sort((Object[]) array2); } } } for (int i = 0; i < len; i++) { DualKey dk = new DualKey(Array.get(array1, i), Array.get(array2, i)); if (!visited.contains(dk)) { // push contents for further comparison stack.addFirst(dk); } } return true; } /** * Deeply compare two Collections that must be same length and in same order. * @param col1 First collection of items to compare * @param col2 Second collection of items to compare * @param stack add items to compare to the Stack (Stack versus recursion) * @param visited Set of objects already compared (prevents cycles) * value of 'true' indicates that the Collections may be equal, and the sets * items will be added to the Stack for further comparison. */ private static boolean compareOrderedCollection(Collection col1, Collection col2, LinkedList stack, Set visited) { // Same instance check already performed... if (col1.size() != col2.size()) { return false; } // try sorting if (col1 instanceof List) { if (!col1.isEmpty()) { Object el = ((List) col1).get(0); if (el instanceof Comparable) { Collections.sort((List) col1); Collections.sort((List) col1); } } } Iterator i1 = col1.iterator(); Iterator i2 = col2.iterator(); while (i1.hasNext()) { DualKey dk = new DualKey(i1.next(), i2.next()); if (!visited.contains(dk)) { // push contents for further comparison stack.addFirst(dk); } } return true; } /** * Deeply compare the two sets referenced by dualKey. This method attempts * to quickly determine inequality by length, then if lengths match, it * places one collection into a temporary Map by deepHashCode(), so that it * can walk the other collection and look for each item in the map, which * runs in O(N) time, rather than an O(N^2) lookup that would occur if each * item from collection one was scanned for in collection two. * @param col1 First collection of items to compare * @param col2 Second collection of items to compare * @param stack add items to compare to the Stack (Stack versus recursion) * @param visited Set containing items that have already been compared, * so as to prevent cycles. * @return boolean false if the Collections are for certain not equals. A * value of 'true' indicates that the Collections may be equal, and the sets * items will be added to the Stack for further comparison. */ private static boolean compareUnorderedCollection(Collection col1, Collection col2, LinkedList stack, Set visited) { // Same instance check already performed... if (col1.size() != col2.size()) { return false; } Map fastLookup = new HashMap(); for (Object o : col2) { fastLookup.put(deepHashCode(o), o); } for (Object o : col1) { Object other = fastLookup.get(deepHashCode(o)); if (other == null) { // Item not even found in other Collection, no need to continue. return false; } DualKey dk = new DualKey(o, other); if (!visited.contains(dk)) { // Place items on 'stack' for further comparison. stack.addFirst(dk); } } return true; } /** * Deeply compare two SortedMap instances. This method walks the Maps in order, * taking advantage of the fact that they Maps are SortedMaps. * @param map1 SortedMap one * @param map2 SortedMap two * @param stack add items to compare to the Stack (Stack versus recursion) * @param visited Set containing items that have already been compared, to prevent cycles. * @return false if the Maps are for certain not equals. 'true' indicates that 'on the surface' the maps * are equal, however, it will place the contents of the Maps on the stack for further comparisons. */ private static boolean compareSortedMap(SortedMap map1, SortedMap map2, LinkedList stack, Set visited) { // Same instance check already performed... if (map1.size() != map2.size()) { return false; } Iterator i1 = map1.entrySet().iterator(); Iterator i2 = map2.entrySet().iterator(); while (i1.hasNext()) { Map.Entry entry1 = (Map.Entry) i1.next(); Map.Entry entry2 = (Map.Entry) i2.next(); // Must split the Key and Value so that Map.Entry's equals() method is not used. DualKey dk = new DualKey(entry1.getKey(), entry2.getKey()); if (!visited.contains(dk)) { // Push Keys for further comparison stack.addFirst(dk); } dk = new DualKey(entry1.getValue(), entry2.getValue()); if (!visited.contains(dk)) { // Push values for further comparison stack.addFirst(dk); } } return true; } /** * Deeply compare two Map instances. After quick short-circuit tests, this method * uses a temporary Map so that this method can run in O(N) time. * @param map1 Map one * @param map2 Map two * @param stack add items to compare to the Stack (Stack versus recursion) * @param visited Set containing items that have already been compared, to prevent cycles. * @return false if the Maps are for certain not equals. 'true' indicates that 'on the surface' the maps * are equal, however, it will place the contents of the Maps on the stack for further comparisons. */ private static boolean compareUnorderedMap(Map map1, Map map2, LinkedList stack, Set visited) { // Same instance check already performed... if (map1.size() != map2.size()) { return false; } Map fastLookup = new HashMap(); for (Map.Entry entry : (Set<Map.Entry>) map2.entrySet()) { fastLookup.put(entry.getKey(), entry); } for (Map.Entry entry : (Set<Map.Entry>) map1.entrySet()) { Map.Entry other = (Map.Entry) fastLookup.get(entry.getKey()); if (other == null) { return false; } DualKey dk = new DualKey(entry.getKey(), other.getKey()); if (!visited.contains(dk)) { // Push keys for further comparison stack.addFirst(dk); } dk = new DualKey(entry.getValue(), other.getValue()); if (!visited.contains(dk)) { // Push values for further comparison stack.addFirst(dk); } } return true; } /** * Determine if the passed in class has a non-Object.equals() method. This * method caches its results in static ConcurrentHashMap to benefit * execution performance. * @param c Class to check. * @return true, if the passed in Class has a .equals() method somewhere between * itself and just below Object in it's inheritance. */ public static boolean hasCustomEquals(Class c) { Class origClass = c; if (_customEquals.containsKey(c)) { return _customEquals.get(c); } while (!Object.class.equals(c)) { try { c.getDeclaredMethod("equals", Object.class); _customEquals.put(origClass, true); return true; } catch (Exception ignored) { } c = c.getSuperclass(); } _customEquals.put(origClass, false); return false; } /** * Get a deterministic hashCode (int) value for an Object, regardless of * when it was created or where it was loaded into memory. The problem * with java.lang.Object.hashCode() is that it essentially relies on * memory location of an object (what identity it was assigned), whereas * this method will produce the same hashCode for any object graph, regardless * of how many times it is created.<br/><br/> * * This method will handle cycles correctly (A->B->C->A). In this case, * Starting with object A, B, or C would yield the same hashCode. If an * object encountered (root, suboject, etc.) has a hashCode() method on it * (that is not Object.hashCode()), that hashCode() method will be called * and it will stop traversal on that branch. * @param obj Object who hashCode is desired. * @return the 'deep' hashCode value for the passed in object. */ public static int deepHashCode(Object obj) { Set visited = new HashSet(); LinkedList<Object> stack = new LinkedList<Object>(); stack.addFirst(obj); int hash = 0; while (!stack.isEmpty()) { obj = stack.removeFirst(); if (obj == null || visited.contains(obj)) { continue; } visited.add(obj); if (obj.getClass().isArray()) { int len = Array.getLength(obj); for (int i = 0; i < len; i++) { stack.addFirst(Array.get(obj, i)); } continue; } if (obj instanceof Collection) { stack.addAll(0, (Collection) obj); continue; } if (obj instanceof Map) { stack.addAll(0, ((Map) obj).keySet()); stack.addAll(0, ((Map) obj).values()); continue; } if (hasCustomHashCode(obj.getClass())) { // A real hashCode() method exists, call it. hash += obj.hashCode(); continue; } Collection<Field> fields = getDeepDeclaredFields(obj.getClass()); for (Field field : fields) { try { stack.addFirst(field.get(obj)); } catch (Exception ignored) { } } } return hash; } /** * Determine if the passed in class has a non-Object.hashCode() method. This * method caches its results in static ConcurrentHashMap to benefit * execution performance. * @param c Class to check. * @return true, if the passed in Class has a .hashCode() method somewhere between * itself and just below Object in it's inheritance. */ public static boolean hasCustomHashCode(Class c) { Class origClass = c; if (_customHash.containsKey(c)) { return _customHash.get(c); } while (!Object.class.equals(c)) { try { c.getDeclaredMethod("hashCode"); _customHash.put(origClass, true); return true; } catch (Exception ignored) { } c = c.getSuperclass(); } _customHash.put(origClass, false); return false; } /** * Get all non static, non transient, fields of the passed in class. * The special this$ field is also not returned. The result is cached * in a static ConcurrentHashMap to benefit execution performance. * @param c Class instance * @return Collection of only the fields in the passed in class * that would need further processing (reference fields). This * makes field traversal on a class faster as it does not need to * continually process known fields like primitives. */ public static Collection<Field> getDeepDeclaredFields(Class c) { if (_reflectedFields.containsKey(c)) { return _reflectedFields.get(c); } Collection<Field> fields = new ArrayList<Field>(); Class curr = c; while (curr != null) { try { Field[] local = curr.getDeclaredFields(); for (Field field : local) { if (!field.isAccessible()) { try { field.setAccessible(true); } catch (Exception ignored) { } } int modifiers = field.getModifiers(); if (!Modifier.isStatic(modifiers) && !field.getName().startsWith("this$") && !Modifier.isTransient(modifiers)) { // speed up: do not count static fields, not go back up to enclosing object in nested case fields.add(field); } } } catch (ThreadDeath t) { throw t; } catch (Throwable ignored) { } curr = curr.getSuperclass(); } _reflectedFields.put(c, fields); return fields; } }