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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.
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/* -*- 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;
public class NativeSet extends IdScriptableObject {
private static final long serialVersionUID = -8442212766987072986L;
private static final Object SET_TAG = "Set";
static final String ITERATOR_TAG = "Set Iterator";
static final SymbolKey GETSIZE = new SymbolKey("[Symbol.getSize]");
private final Hashtable entries = new Hashtable();
private boolean instanceOfSet = false;
static void init(Context cx, Scriptable scope, boolean sealed) {
NativeSet obj = new NativeSet();
IdFunctionObject constructor = obj.exportAsJSClass(MAX_PROTOTYPE_ID, scope, false);
ScriptableObject desc = (ScriptableObject) cx.newObject(scope);
desc.put("enumerable", desc, Boolean.FALSE);
desc.put("configurable", desc, Boolean.TRUE);
desc.put("get", desc, obj.get(GETSIZE, obj));
obj.defineOwnProperty(cx, "size", desc);
ScriptRuntimeES6.addSymbolSpecies(cx, scope, constructor);
if (sealed) {
obj.sealObject();
}
}
@Override
public String getClassName() {
return "Set";
}
@Override
public Object execIdCall(
IdFunctionObject f, Context cx, Scriptable scope, Scriptable thisObj, Object[] args) {
if (!f.hasTag(SET_TAG)) {
return super.execIdCall(f, cx, scope, thisObj, args);
}
final int id = f.methodId();
switch (id) {
case Id_constructor:
if (thisObj == null) {
NativeSet ns = new NativeSet();
ns.instanceOfSet = true;
if (args.length > 0) {
loadFromIterable(cx, scope, ns, NativeMap.key(args));
}
return ns;
} else {
throw ScriptRuntime.typeErrorById("msg.no.new", "Set");
}
case Id_add:
return realThis(thisObj, f).js_add(NativeMap.key(args));
case Id_delete:
return realThis(thisObj, f).js_delete(NativeMap.key(args));
case Id_has:
return realThis(thisObj, f).js_has(NativeMap.key(args));
case Id_clear:
return realThis(thisObj, f).js_clear();
case Id_values:
return realThis(thisObj, f)
.js_iterator(scope, NativeCollectionIterator.Type.VALUES);
case Id_entries:
return realThis(thisObj, f).js_iterator(scope, NativeCollectionIterator.Type.BOTH);
case Id_forEach:
return realThis(thisObj, f)
.js_forEach(
cx,
scope,
NativeMap.key(args),
args.length > 1 ? args[1] : Undefined.instance);
case SymbolId_getSize:
return realThis(thisObj, f).js_getSize();
}
throw new IllegalArgumentException("Set.prototype has no method: " + f.getFunctionName());
}
private Object js_add(Object k) {
// Special handling of "negative zero" from the spec.
Object key = k;
if ((key instanceof Number) && ((Number) key).doubleValue() == ScriptRuntime.negativeZero) {
key = ScriptRuntime.zeroObj;
}
entries.put(key, key);
return this;
}
private Object js_delete(Object arg) {
return Boolean.valueOf(entries.deleteEntry(arg));
}
private Object js_has(Object arg) {
return Boolean.valueOf(entries.has(arg));
}
private Object js_clear() {
entries.clear();
return Undefined.instance;
}
private Object js_getSize() {
return Integer.valueOf(entries.size());
}
private Object js_iterator(Scriptable scope, NativeCollectionIterator.Type type) {
return new NativeCollectionIterator(scope, ITERATOR_TAG, type, entries.iterator());
}
private Object js_forEach(Context cx, Scriptable scope, Object arg1, Object arg2) {
if (!(arg1 instanceof Callable)) {
throw ScriptRuntime.notFunctionError(arg1);
}
final Callable f = (Callable) arg1;
boolean isStrict = cx.isStrictMode();
for (Hashtable.Entry entry : entries) {
// Per spec must convert every time so that primitives are always regenerated...
Scriptable thisObj = ScriptRuntime.toObjectOrNull(cx, arg2, scope);
if (thisObj == null && !isStrict) {
thisObj = scope;
}
if (thisObj == null) {
thisObj = Undefined.SCRIPTABLE_UNDEFINED;
}
final Hashtable.Entry e = entry;
f.call(cx, scope, thisObj, new Object[] {e.value, e.value, this});
}
return Undefined.instance;
}
/**
* If an "iterable" object was passed to the constructor, there are many many things to do. This
* is common code with NativeWeakSet.
*/
static void loadFromIterable(Context cx, Scriptable scope, ScriptableObject set, Object arg1) {
if ((arg1 == null) || Undefined.instance.equals(arg1)) {
return;
}
// Call the "[Symbol.iterator]" property as a function.
Object ito = ScriptRuntime.callIterator(arg1, cx, scope);
if (Undefined.instance.equals(ito)) {
// Per spec, ignore if the iterator returns undefined
return;
}
// Find the "add" function of our own prototype, since it might have
// been replaced. Since we're not fully constructed yet, create a dummy instance
// so that we can get our own prototype.
ScriptableObject dummy = ensureScriptableObject(cx.newObject(scope, set.getClassName()));
final Callable add =
ScriptRuntime.getPropFunctionAndThis(dummy.getPrototype(), "add", cx, scope);
// Clean up the value left around by the previous function
ScriptRuntime.lastStoredScriptable(cx);
// Finally, run through all the iterated values and add them!
try (IteratorLikeIterable it = new IteratorLikeIterable(cx, scope, ito)) {
for (Object val : it) {
final Object finalVal = val == Scriptable.NOT_FOUND ? Undefined.instance : val;
add.call(cx, scope, set, new Object[] {finalVal});
}
}
}
private static NativeSet realThis(Scriptable thisObj, IdFunctionObject f) {
final NativeSet ns = ensureType(thisObj, NativeSet.class, f);
if (!ns.instanceOfSet) {
// If we get here, then this object doesn't have the "Set internal data slot."
throw ScriptRuntime.typeErrorById("msg.incompat.call", f.getFunctionName());
}
return ns;
}
@Override
protected void initPrototypeId(int id) {
switch (id) {
case SymbolId_getSize:
initPrototypeMethod(SET_TAG, id, GETSIZE, "get size", 0);
return;
case SymbolId_toStringTag:
initPrototypeValue(
SymbolId_toStringTag,
SymbolKey.TO_STRING_TAG,
getClassName(),
DONTENUM | READONLY);
return;
// fallthrough
}
String s, fnName = null;
int arity;
switch (id) {
case Id_constructor:
arity = 0;
s = "constructor";
break;
case Id_add:
arity = 1;
s = "add";
break;
case Id_delete:
arity = 1;
s = "delete";
break;
case Id_has:
arity = 1;
s = "has";
break;
case Id_clear:
arity = 0;
s = "clear";
break;
case Id_entries:
arity = 0;
s = "entries";
break;
case Id_values:
arity = 0;
s = "values";
break;
case Id_forEach:
arity = 1;
s = "forEach";
break;
default:
throw new IllegalArgumentException(String.valueOf(id));
}
initPrototypeMethod(SET_TAG, id, s, fnName, arity);
}
@Override
protected int findPrototypeId(Symbol k) {
if (GETSIZE.equals(k)) {
return SymbolId_getSize;
}
if (SymbolKey.ITERATOR.equals(k)) {
return Id_values;
}
if (SymbolKey.TO_STRING_TAG.equals(k)) {
return SymbolId_toStringTag;
}
return 0;
}
@Override
protected int findPrototypeId(String s) {
int id;
switch (s) {
case "constructor":
id = Id_constructor;
break;
case "add":
id = Id_add;
break;
case "delete":
id = Id_delete;
break;
case "has":
id = Id_has;
break;
case "clear":
id = Id_clear;
break;
case "keys":
id = Id_keys;
break;
case "values":
id = Id_values;
break;
case "entries":
id = Id_entries;
break;
case "forEach":
id = Id_forEach;
break;
default:
id = 0;
break;
}
return id;
}
// Note that SymbolId_iterator is not present because it is required to have the
// same value as the "values" entry.
// Similarly, "keys" is supposed to have the same value as "values," which is why
// both have the same ID.
private static final int Id_constructor = 1,
Id_add = 2,
Id_delete = 3,
Id_has = 4,
Id_clear = 5,
Id_keys = 6,
Id_values = 6, // These are deliberately the same to match the spec
Id_entries = 7,
Id_forEach = 8,
SymbolId_getSize = 9,
SymbolId_toStringTag = 10,
MAX_PROTOTYPE_ID = SymbolId_toStringTag;
}
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