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Rhino is an open-source implementation of JavaScript written entirely in Java. It is typically
embedded into Java applications to provide scripting to end users.
/* -*- Mode: java; tab-width: 8; indent-tabs-mode: nil; c-basic-offset: 4 -*-
*
* This Source Code Form is subject to the terms of the Mozilla Public
* License, v. 2.0. If a copy of the MPL was not distributed with this
* file, You can obtain one at http://mozilla.org/MPL/2.0/. */
package org.mozilla.javascript;
import java.util.Arrays;
import java.util.Collections;
import java.util.HashSet;
import java.util.IdentityHashMap;
import java.util.Iterator;
import java.util.List;
import java.util.Map;
import java.util.Objects;
import java.util.Set;
import java.util.SortedMap;
import java.util.TreeMap;
import org.mozilla.javascript.debug.DebuggableObject;
/**
* An object that implements deep equality test of objects, including their reference graph
* topology, that is in addition to establishing by-value equality of objects, it also establishes
* that their reachable object graphs have identical shape. It is capable of custom-comparing a wide
* range of various objects, including various Rhino Scriptables, Java arrays, Java Lists, and to
* some degree Java Maps and Sets (sorted Maps are okay, as well as Sets with elements that can be
* sorted using their Comparable implementation, and Maps whose keysets work the same). The
* requirement for sortable maps and sets is to ensure deterministic order of traversal, which is
* necessary for establishing structural equality of object graphs.
*
* An instance of this object is stateful in that it memoizes pairs of objects that already
* compared equal, so reusing an instance for repeated equality tests of potentially overlapping
* object graph is beneficial for performance as long as all equality test invocations returns true.
* Reuse is not advised after an equality test returned false since there is a heuristic in
* comparing cyclic data structures that can memoize false equalities if two cyclic data structures
* end up being unequal.
*/
final class EqualObjectGraphs {
private static final ThreadLocal instance = new ThreadLocal<>();
private static final Set> valueClasses =
Collections.unmodifiableSet(
new HashSet<>(
Arrays.asList(
Boolean.class,
Byte.class,
Character.class,
Double.class,
Float.class,
Integer.class,
Long.class,
Short.class)));
// Object pairs already known to be equal. Used to short-circuit repeated traversals of objects
// reachable through
// different paths as well as to detect structural inequality.
private final Map knownEquals = new IdentityHashMap<>();
// Currently compared objects; used to avoid infinite recursion over cyclic object graphs.
private final Map currentlyCompared = new IdentityHashMap<>();
static T withThreadLocal(java.util.function.Function action) {
final EqualObjectGraphs currEq = instance.get();
if (currEq == null) {
final EqualObjectGraphs eq = new EqualObjectGraphs();
instance.set(eq);
try {
return action.apply(eq);
} finally {
instance.set(null);
}
}
return action.apply(currEq);
}
boolean equalGraphs(Object o1, Object o2) {
if (o1 == o2) {
return true;
} else if (o1 == null || o2 == null) {
return false;
// String (and ConsStrings), Booleans, and Doubles are considered
// JavaScript primitive values and are thus compared by value and
// with no regard to their object identity.
} else if (o1 instanceof String) {
if (o2 instanceof ConsString) {
return o1.equals(o2.toString());
}
return o1.equals(o2);
} else if (o1 instanceof ConsString) {
if (o2 instanceof String || o2 instanceof ConsString) {
return o1.toString().equals(o2.toString());
}
return false;
} else if (valueClasses.contains(o1.getClass())) {
return o1.equals(o2);
}
final Object curr2 = currentlyCompared.get(o1);
if (curr2 == o2) {
// Provisionally afford that if we're already recursively comparing
// (o1, o2) that they'll be equal. NOTE: this is the heuristic
// mentioned in the class JavaDoc that can drive memoizing false
// equalities if cyclic data structures end up being unequal.
// While it would be possible to fix that with additional code, the
// usual usage of equality comparisons is short-circuit-on-false anyway,
// so this edge case should not arise in normal usage and the additional
// code complexity to guard against it is not worth it.
return true;
} else if (curr2 != null) {
// If we're already recursively comparing o1 to some other object,
// this comparison is structurally false.
return false;
}
final Object prev2 = knownEquals.get(o1);
if (prev2 == o2) {
// o1 known to be equal to o2.
return true;
} else if (prev2 != null) {
// o1 known to be equal to something other than o2.
return false;
}
final Object prev1 = knownEquals.get(o2);
assert prev1 != o1; // otherwise we would've already returned at prev2 == o2
if (prev1 != null) {
// o2 known to be equal to something other than o1.
return false;
}
currentlyCompared.put(o1, o2);
final boolean eq = equalGraphsNoMemo(o1, o2);
if (eq) {
knownEquals.put(o1, o2);
knownEquals.put(o2, o1);
}
currentlyCompared.remove(o1);
return eq;
}
private boolean equalGraphsNoMemo(Object o1, Object o2) {
if (o1 instanceof Wrapper) {
return o2 instanceof Wrapper
&& equalGraphs(((Wrapper) o1).unwrap(), ((Wrapper) o2).unwrap());
} else if (o1 instanceof NativeJavaTopPackage) {
// stateless objects, must check before Scriptable
return o2 instanceof NativeJavaTopPackage;
} else if (o1 instanceof Scriptable) {
return o2 instanceof Scriptable && equalScriptables((Scriptable) o1, (Scriptable) o2);
} else if (o1 instanceof SymbolKey) {
return o2 instanceof SymbolKey
&& equalGraphs(((SymbolKey) o1).getName(), ((SymbolKey) o2).getName());
} else if (o1 instanceof Object[]) {
return o2 instanceof Object[] && equalObjectArrays((Object[]) o1, (Object[]) o2);
} else if (o1.getClass().isArray()) {
return Objects.deepEquals(o1, o2);
} else if (o1 instanceof List>) {
return o2 instanceof List> && equalLists((List>) o1, (List>) o2);
} else if (o1 instanceof Map, ?>) {
return o2 instanceof Map, ?> && equalMaps((Map, ?>) o1, (Map, ?>) o2);
} else if (o1 instanceof Set>) {
return o2 instanceof Set> && equalSets((Set>) o1, (Set>) o2);
} else if (o1 instanceof NativeGlobal) {
return o2 instanceof NativeGlobal; // stateless objects
} else if (o1 instanceof JavaAdapter) {
return o2 instanceof JavaAdapter; // stateless objects
}
// Fallback case for everything else.
return o1.equals(o2);
}
private boolean equalScriptables(final Scriptable s1, final Scriptable s2) {
final Object[] ids1 = getSortedIds(s1);
final Object[] ids2 = getSortedIds(s2);
if (!equalObjectArrays(ids1, ids2)) {
return false;
}
final int l = ids1.length;
for (int i = 0; i < l; ++i) {
if (!equalGraphs(getValue(s1, ids1[i]), getValue(s2, ids2[i]))) {
return false;
}
}
if (!equalGraphs(s1.getPrototype(), s2.getPrototype())) {
return false;
} else if (!equalGraphs(s1.getParentScope(), s2.getParentScope())) {
return false;
}
// Handle special Scriptable implementations
if (s1 instanceof NativeContinuation) {
return s2 instanceof NativeContinuation
&& NativeContinuation.equalImplementations(
(NativeContinuation) s1, (NativeContinuation) s2);
} else if (s1 instanceof NativeJavaPackage) {
return s1.equals(s2); // Overridden appropriately
} else if (s1 instanceof IdFunctionObject) {
return s2 instanceof IdFunctionObject
&& IdFunctionObject.equalObjectGraphs(
(IdFunctionObject) s1, (IdFunctionObject) s2, this);
} else if (s1 instanceof InterpretedFunction) {
return s2 instanceof InterpretedFunction
&& equalInterpretedFunctions(
(InterpretedFunction) s1, (InterpretedFunction) s2);
} else if (s1 instanceof ArrowFunction) {
return s2 instanceof ArrowFunction
&& ArrowFunction.equalObjectGraphs(
(ArrowFunction) s1, (ArrowFunction) s2, this);
} else if (s1 instanceof BoundFunction) {
return s2 instanceof BoundFunction
&& BoundFunction.equalObjectGraphs(
(BoundFunction) s1, (BoundFunction) s2, this);
} else if (s1 instanceof NativeSymbol) {
return s2 instanceof NativeSymbol
&& equalGraphs(((NativeSymbol) s1).getKey(), ((NativeSymbol) s2).getKey());
}
return true;
}
private boolean equalObjectArrays(final Object[] a1, final Object[] a2) {
if (a1.length != a2.length) {
return false;
}
for (int i = 0; i < a1.length; ++i) {
if (!equalGraphs(a1[i], a2[i])) {
return false;
}
}
return true;
}
private boolean equalLists(final List> l1, final List> l2) {
if (l1.size() != l2.size()) {
return false;
}
final Iterator> i1 = l1.iterator();
final Iterator> i2 = l2.iterator();
while (i1.hasNext() && i2.hasNext()) {
if (!equalGraphs(i1.next(), i2.next())) {
return false;
}
}
assert !(i1.hasNext() || i2.hasNext());
return true;
}
@SuppressWarnings("rawtypes")
private boolean equalMaps(final Map, ?> m1, final Map, ?> m2) {
if (m1.size() != m2.size()) {
return false;
}
final Iterator i1 = sortedEntries(m1);
final Iterator i2 = sortedEntries(m2);
while (i1.hasNext() && i2.hasNext()) {
final Map.Entry kv1 = i1.next();
final Map.Entry kv2 = i2.next();
if (!(equalGraphs(kv1.getKey(), kv2.getKey())
&& equalGraphs(kv1.getValue(), kv2.getValue()))) {
return false;
}
}
assert !(i1.hasNext() || i2.hasNext());
// TODO: assert linked maps traversal order?
return true;
}
@SuppressWarnings({"rawtypes", "unchecked"})
private static Iterator sortedEntries(final Map m) {
// Yes, this throws ClassCastException if the keys aren't comparable. That's okay. We only
// support maps with
// deterministic traversal order.
final Map sortedMap = (m instanceof SortedMap, ?> ? m : new TreeMap(m));
return sortedMap.entrySet().iterator();
}
private boolean equalSets(final Set> s1, final Set> s2) {
return equalObjectArrays(sortedSet(s1), sortedSet(s2));
}
private static Object[] sortedSet(final Set> s) {
final Object[] a = s.toArray();
Arrays.sort(a); // ClassCastException possible
return a;
}
private static boolean equalInterpretedFunctions(
final InterpretedFunction f1, final InterpretedFunction f2) {
return Objects.equals(f1.getEncodedSource(), f2.getEncodedSource());
}
// Sort IDs deterministically
private static Object[] getSortedIds(final Scriptable s) {
final Object[] ids = getIds(s);
Arrays.sort(
ids,
(a, b) -> {
if (a instanceof Integer) {
if (b instanceof Integer) {
return ((Integer) a).compareTo((Integer) b);
} else if (b instanceof String || b instanceof Symbol) {
return -1; // ints before strings or symbols
}
} else if (a instanceof String) {
if (b instanceof String) {
return ((String) a).compareTo((String) b);
} else if (b instanceof Integer) {
return 1; // strings after ints
} else if (b instanceof Symbol) {
return -1; // strings before symbols
}
} else if (a instanceof Symbol) {
if (b instanceof Symbol) {
// As long as people bother to reasonably name their symbols,
// this will work. If there's clashes in symbol names (e.g.
// lots of unnamed symbols) it can lead to false inequalities.
return getSymbolName((Symbol) a).compareTo(getSymbolName((Symbol) b));
} else if (b instanceof Integer || b instanceof String) {
return 1; // symbols after ints and strings
}
}
// We can only compare Rhino key types: Integer, String, Symbol
throw new ClassCastException();
});
return ids;
}
private static String getSymbolName(final Symbol s) {
if (s instanceof SymbolKey) {
return ((SymbolKey) s).getName();
} else if (s instanceof NativeSymbol) {
return ((NativeSymbol) s).getKey().getName();
} else {
// We can only handle native Rhino Symbol types
throw new ClassCastException();
}
}
private static Object[] getIds(final Scriptable s) {
if (s instanceof ScriptableObject) {
// Grabs symbols too
return ((ScriptableObject) s).getIds(true, true);
} else if (s instanceof DebuggableObject) {
return ((DebuggableObject) s).getAllIds();
} else {
return s.getIds();
}
}
private static Object getValue(final Scriptable s, final Object id) {
if (id instanceof Symbol) {
return ScriptableObject.getProperty(s, (Symbol) id);
} else if (id instanceof Integer) {
return ScriptableObject.getProperty(s, (Integer) id);
} else if (id instanceof String) {
return ScriptableObject.getProperty(s, (String) id);
} else {
throw new ClassCastException();
}
}
}