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565 lines
14 KiB
565 lines
14 KiB
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/* FIXME: bound function cases */
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/*
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* Parsing tests for 'new' expressions. These are rather detailed because
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* the grammar for the following productions is a bit awkward:
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*
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* - LeftHandSideExpression
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* - CallExpression
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* - NewExpression
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* - MemberExpression
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*/
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var t;
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/*===
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Basic1
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Basic1
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Basic2 arg1 arg2
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Basic3 arg1 arg2
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Basic3 arg1 arg2
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Basic4 arg1 arg2
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===*/
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/* Basic cases where constructor is from a MemberExpression (but not another 'new') */
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function Basic1() {
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}
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Basic1.prototype = { 'name': 'Basic1' };
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function Basic2(x,y) {
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this.x = x;
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this.y = y;
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}
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Basic2.prototype = { 'name': 'Basic2' };
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basic3 = {
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'constructor': function(x,y) {
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this.x = x;
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this.y = y;
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}
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};
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basic3.constructor.prototype = { 'name': 'Basic3' };
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try {
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// without parenthesis (arguments)
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eval("t = new Basic1; print(t.name);");
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} catch (e) {
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print(e.name);
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}
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try {
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// with no arguments (semantically same as above)
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eval("t = new Basic1(); print(t.name);");
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} catch (e) {
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print(e.name);
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}
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try {
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// with arguments
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eval("t = new Basic2('arg1', 'arg2'); print(t.name, t.x, t.y);");
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} catch (e) {
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print(e.name);
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}
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try {
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// constructor from a property access (MemberExpression)
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eval("t = new basic3.constructor ('arg1', 'arg2'); print(t.name, t.x, t.y);");
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} catch (e) {
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print(e.name);
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}
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try {
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// constructor from a property access (MemberExpression), bracket syntax
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eval("t = new basic3['constructor'] ('arg1', 'arg2'); print(t.name, t.x, t.y);");
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} catch (e) {
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print(e.name);
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}
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try {
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// constructor from a function expression (from MemberExpression)
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// Note: here the 'name' property is not inherited from prototype
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eval("t = new function(x,y) {this.x=x;this.y=y;this.name='Basic4';} ('arg1', 'arg2'); print(t.name, t.x, t.y);");
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} catch (e) {
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print(e.name);
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}
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/*===
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TypeError
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getTarget/f
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===*/
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/* The target for 'new' may be any MemberExpression, but it cannot be a
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* CallExpression. Thus:
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*
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* new foo() ()
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*
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* Will be parsed as ( new foo() ) (). For the intended effect, parenthesis
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* are needed:
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*
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* new (foo()) ()
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*/
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function getTarget() {
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var f = function() {
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}
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f.prototype = { 'name': 'getTarget/f' };
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return f;
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}
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try {
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// this will evaluate "new getTarget ()" and then attempt to call the
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// instance, which is not callable -> TypeError
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eval("t = new getTarget() (); print(t.name);");
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} catch (e) {
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print(e.name);
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}
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try {
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// this will first evaluate "getTarget()" to get the constructor,
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// and then call the constructor
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eval("t = new (getTarget()) (); print(t.name);");
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} catch (e) {
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print(e.name);
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}
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/*===
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NewNew2 arg1
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===*/
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/* The 'new' operator may occur multiple times, although this is
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* quite unusual. It binds more loosely than MemberExpressions
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* and acts right associative.
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*
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* Example below:
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*
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* new new Foo()
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* === new (new Foo())
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*
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* This is derived as (using parenthesis for illustration):
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*
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* NewExpression => new NewExpression
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* => new (MemberExpression)
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* => new (new MemberExpression Arguments)
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* => new (new Foo ())
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*/
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function NewNew1(x) {
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function f() {
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// snatch 'x' from closure
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this.x = x;
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}
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f.prototype = { 'name': 'NewNew2' };
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return f;
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}
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NewNew1.prototype = { 'name': 'NewNew1' };
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try {
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eval("t = new new NewNew1 ('arg1'); print(t.name, t.x);");
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} catch (e) {
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print(e.name);
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}
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/*===
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Bal1A called, this.name=Bal1A
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Bal1A
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Bal1A called, this.name=Bal1A
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Bal1A
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Bal1B called, this.name=Bal1B
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Bal1B/f called, this.Number.POSITIVE_INFINITY=Infinity
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Bal1B/f return value
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Bal1C called, this.name=Bal1C
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Bal1C/f called, this.Number.POSITIVE_INFINITY=Infinity
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Bal1C/f/g called, this.Number.POSITIVE_INFINITY=Infinity
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Bal1C/f/g return value
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===*/
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/*
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* Parenthesis "balance tests".
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*
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* new Foo basic case
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* new Foo () parens associated with 'new', not a func call
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* new Foo () () (new Foo ()) ()
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* new Foo () () () ((new Foo ()) ()) ()
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*/
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function Bal1A() {
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// printing out this.name indicates whether we're being
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// called as a constructor or as a function
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print("Bal1A called, this.name=" + this.name);
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}
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Bal1A.prototype = { 'name': 'Bal1A' };
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function Bal1B() {
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print("Bal1B called, this.name=" + this.name);
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function f() {
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// f() is called as a normal function, this is bound to the
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// global object; printing out a specific value accessible
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// through the global object proves the point.
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print("Bal1B/f called, this.Number.POSITIVE_INFINITY=" + this.Number.POSITIVE_INFINITY);
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return "Bal1B/f return value";
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}
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f.name = "Bal1B/f"; // not inherited
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// Returned value replaces default constructed object; this return
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// value does not have Bal1B.prototype as its internal prototype.
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return f;
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}
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Bal1B.prototype = { 'name': 'Bal1B' }; // has no effect
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function Bal1C() {
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print("Bal1C called, this.name=" + this.name);
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function f() {
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print("Bal1C/f called, this.Number.POSITIVE_INFINITY=" + this.Number.POSITIVE_INFINITY);
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function g() {
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print("Bal1C/f/g called, this.Number.POSITIVE_INFINITY=" + this.Number.POSITIVE_INFINITY);
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return "Bal1C/f/g return value";
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}
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return g;
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}
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f.name = "Bal1C/f"; // not inherited
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return f;
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}
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Bal1C.prototype = { 'name': 'Bal1C' }; // has no effect
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try {
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eval("var t = new Bal1A; print(t.name);");
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} catch (e) {
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print(e.name);
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}
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try {
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eval("var t = new Bal1A (); print(t.name);");
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} catch (e) {
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print(e.name);
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}
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try {
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eval("var t = new Bal1B () (); print(t);"); // here 't' is return value from Bal1B/f
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} catch (e) {
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print(e.name);
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}
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try {
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eval("var t = new Bal1C () () (); print(t);");
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} catch (e) {
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print(e.name);
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}
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/*===
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Bal2A called, this.name=Bal2A
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Bal2A/f called, this.name=Bal2A/f
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Bal2A/f
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Bal2B called, this.name=Bal2B
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Bal2B/f called, this.name=Bal2B/f
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Bal2B/f/g called, this.name=Bal2B/f/g
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Bal2B/f/g
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Bal2B called, this.name=Bal2B
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Bal2B/f called, this.name=Bal2B/f
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Bal2B/f/g called, this.name=Bal2B/f/g
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Bal2B/f/g
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Bal2B called, this.name=Bal2B
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Bal2B/f called, this.name=Bal2B/f
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Bal2B/f/g called, this.name=Bal2B/f/g
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Bal2B/f/g
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Bal2B called, this.name=Bal2B
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Bal2B/f called, this.name=Bal2B/f
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Bal2B/f/g called, this.name=Bal2B/f/g
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Bal2B/f/g
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Bal2C called, this.name=Bal2C
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Bal2C/f called, this.name=Bal2C/f
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Bal2C/f/g called, this.name=Bal2C/f/g
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Bal2C/f/g/h called, this.Number.POSITIVE_INFINITY=Infinity
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Bal2C/f/g/h return value
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===*/
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/*
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* Parenthesis and 'new' "balance tests".
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*
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* new new Foo new (new Foo)
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* new new new Foo new (new (new Foo))
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* new new new Foo () new (new (new Foo ()))
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* new new new Foo () () new (new (new Foo ()) ())
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* new new new Foo () () () new (new (new Foo ()) ()) () up to this point, parens associated with 'new' calls
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* new new new Foo () () () () (new (new (new Foo ()) ()) ()) () last is a func call
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*/
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function Bal2A() {
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print('Bal2A called, this.name=' + this.name);
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function f() {
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print("Bal2A/f called, this.name=" + this.name);
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}
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f.prototype = { 'name': 'Bal2A/f' };
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// return value (instance) of inner ("new Bal2A") is used as the
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// constructor for the outer "new" call.
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return f;
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}
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Bal2A.prototype = { 'name': 'Bal2A' };
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function Bal2B() {
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print('Bal2B called, this.name=' + this.name);
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function f() {
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print('Bal2B/f called, this.name=' + this.name);
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function g() {
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print('Bal2B/f/g called, this.name=' + this.name);
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}
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g.prototype = { 'name': 'Bal2B/f/g' };
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return g;
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}
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f.prototype = { 'name': 'Bal2B/f' };
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return f;
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}
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Bal2B.prototype = { 'name': 'Bal2B' };
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function Bal2C() {
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print('Bal2C called, this.name=' + this.name);
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function f() {
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print('Bal2C/f called, this.name=' + this.name);
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function g() {
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print('Bal2C/f/g called, this.name=' + this.name);
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function h() {
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print('Bal2C/f/g/h called, this.Number.POSITIVE_INFINITY=' + this.Number.POSITIVE_INFINITY);
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return 'Bal2C/f/g/h return value';
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}
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return h;
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}
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g.prototype = { 'name': 'Bal2C/f/g' };
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return g;
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}
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f.prototype = { 'name': 'Bal2C/f' };
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return f;
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}
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Bal2C.prototype = { 'name': 'Bal2C' };
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try {
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eval("t = new new Bal2A; print(t.name);");
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} catch (e) {
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print(e.name);
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}
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try {
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eval("t = new new new Bal2B; print(t.name);");
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} catch (e) {
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print(e.name);
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}
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try {
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eval("t = new new new Bal2B (); print(t.name);");
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} catch (e) {
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print(e.name);
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}
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try {
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eval("t = new new new Bal2B () (); print(t.name);");
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} catch (e) {
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print(e.name);
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}
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try {
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eval("t = new new new Bal2B () () (); print(t.name);");
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} catch (e) {
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print(e.name);
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}
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try {
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eval("t = new new new Bal2C () () () (); print(t);");
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} catch (e) {
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print(e.name);
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}
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/*===
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Bal3A called, this.name=Bal3A, x=1, y=2, z=3
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Bal3A/f called, this.name=Bal3A/f, x=4, y=5
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z is from outer scope: z=3
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Bal3A/f/g called, this.Number.POSITIVE_INFINITY=Infinity, a=6, b=7
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the following are from outer scope: x=4, y=5, z=3
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Bal3A/f/g return value
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===*/
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/* Parenthesis association test with argument values:
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*
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* new new Foo (1,2,3) (4,5) (6,7) last parens are a call
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*/
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function Bal3A(x,y,z) {
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print("Bal3A called, this.name=" + this.name +
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", x=" + x + ", y=" + y + ", z=" + z);
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function f(x,y) {
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print("Bal3A/f called, this.name=" + this.name +
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", x=" + x + ", y=" + y);
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print("z is from outer scope: z=" + z);
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function g(a,b) {
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print("Bal3A/f/g called, this.Number.POSITIVE_INFINITY=" + this.Number.POSITIVE_INFINITY +
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", a=" + a + ", b=" + b);
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print("the following are from outer scope: " +
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"x=" + x + ", y=" + y + ", z=" + z);
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return "Bal3A/f/g return value";
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}
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// replace created object with function g
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return g;
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}
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f.prototype = { 'name': 'Bal3A/f' };
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return f;
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}
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Bal3A.prototype = { 'name': 'Bal3A' };
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try {
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eval("t = new new Bal3A (1,2,3) (4,5) (6,7); print(t);");
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} catch (e) {
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print(e.name);
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}
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/*===
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Misc1 called, this.name=Misc1
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foo getter called
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Misc1/f called, this.name=Misc1/f
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Misc1/f
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Misc1 called, this.name=Misc1
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foo getter called
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Misc1/f called, this.name=Misc1/f
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Misc1/f
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Misc2 called, this.name=Misc2
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foo getter called
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Misc2/f called, this.name=Misc2/f, x=1, y=2
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Misc2/f
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===*/
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/*
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* Consider the following:
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*
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* new new Foo () . foo
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*
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* If we start from LeftHandSideExpression and choose CallExpression,
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* it is not possible to create any 'new' expression without arguments,
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* like the outer 'new' above. More specifically:
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*
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* LeftHandSideExpression => CallExpression
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* => CallExpression '.' IdentifierName
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* => MemberExpression '.' IdentifierName
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*
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* At this point there is no way to expand MemberExpression and create
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* two 'new' tokens and only one set of arguments.
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*
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* If we start from LeftHandSideExpression and choose NewExpression
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* (brackets for emphasis):
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*
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* LeftHandSideExpression => NewExpression
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* => 'new' NewExpression
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* => 'new' MemberExpression
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* => 'new' [ MemberExpression '.' IdentifierName ]
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* => 'new' [ [ 'new' MemberExpression Arguments ] '.' IdentifierName ]
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* => 'new' [ [ 'new' 'Foo' '(' ')' ] '.' 'foo' ]
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*
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* So, in other words, we get:
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*
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* new new Foo () . foo == new ((new Foo ()) . foo)
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*
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* And:
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*
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* new new Foo () . foo () == new ((new Foo ()) . foo) ()
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*
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* where the last parens are related to the outer 'new'.
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*/
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function Misc1() {
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print('Misc1 called, this.name=' + this.name);
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function f() {
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print('Misc1/f called, this.name=' + this.name);
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}
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f.prototype = { 'name': 'Misc1/f' };
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// return an object whose 'foo' property is read by the caller
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// and used as the next constructor
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return { get foo() { print ('foo getter called'); return f } };
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}
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Misc1.prototype = { 'name': 'Misc1' };
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function Misc2() {
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print('Misc2 called, this.name=' + this.name);
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function f(x,y) {
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print('Misc2/f called, this.name=' + this.name +
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', x=' + x + ', y=' + y);
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}
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f.prototype = { 'name': 'Misc2/f' };
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// return an object whose 'foo' property is read by the caller
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// and used as the next constructor
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return { get foo() { print ('foo getter called'); return f } };
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}
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Misc2.prototype = { 'name': 'Misc2' };
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try {
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eval("t = new new Misc1 () . foo; print(t.name);");
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} catch (e) {
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print(e.name);
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}
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try {
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// exactly same, explicit parens
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eval("t = new ((new Misc1 ()) . foo); print(t.name);");
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} catch (e) {
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print(e.name);
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}
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try {
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// add arguments to outer 'new'
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eval("t = new new Misc2 () . foo (1,2); print(t.name);");
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} catch (e) {
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print(e.name);
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}
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/*===
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1 2 3 4
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1 2 undefined undefined
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true
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===*/
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/* If a constructor returns a replacement value, the internal prototype
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* of that object will not be set by the 'new' call.
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*/
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function Cons1() {
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this.foo = 1;
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this.bar = 2;
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}
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Cons1.prototype = { quux: 3, baz: 4 };
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function Cons2() {
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return { foo: 1, bar: 2 };
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}
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Cons2.prototype = { quux: 3, baz: 4 };
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try {
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t = new Cons1();
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print(t.foo, t.bar, t.quux, t.baz);
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// the internal prototype of 't' will be Object.prototype here
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t = new Cons2();
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print(t.foo, t.bar, t.quux, t.baz);
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print(Object.getPrototypeOf(t) === Object.prototype);
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} catch (e) {
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print(e.name);
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}
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