You can not select more than 25 topics Topics must start with a letter or number, can include dashes ('-') and can be up to 35 characters long.
tdelibs/kjs/array_object.cpp

869 lines
26 KiB

/*
* This file is part of the KDE libraries
* Copyright (C) 1999-2000 Harri Porten (porten@kde.org)
* Copyright (C) 2003 Apple Computer, Inc.
*
* This library is free software; you can redistribute it and/or
* modify it under the terms of the GNU Lesser General Public
* License as published by the Free Software Foundation; either
* version 2 of the License, or (at your option) any later version.
*
* This library is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
* Lesser General Public License for more details.
*
* You should have received a copy of the GNU Lesser General Public
* License along with this library; if not, write to the Free Software
* Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA
*
*/
#include "value.h"
#include "object.h"
#include "types.h"
#include "interpreter.h"
#include "operations.h"
#include "array_object.h"
#include "internal.h"
#include "error_object.h"
#include "array_object.lut.h"
#include <stdio.h>
#include <string.h>
#include <assert.h>
#define MAX_INDEX 4294967294U // 2^32-2
using namespace KJS;
// ------------------------------ ArrayInstanceImp -----------------------------
const unsigned sparseArrayCutoff = 10000;
const ClassInfo ArrayInstanceImp::info = {"Array", 0, 0, 0};
ArrayInstanceImp::ArrayInstanceImp(ObjectImp *proto, unsigned initialLength)
: ObjectImp(proto)
, length(initialLength)
, storageLength(initialLength < sparseArrayCutoff ? initialLength : 0)
, capacity(storageLength)
, storage(capacity ? (ValueImp **)calloc(capacity, sizeof(ValueImp *)) : 0)
{
}
ArrayInstanceImp::ArrayInstanceImp(ObjectImp *proto, const List &list)
: ObjectImp(proto)
, length(list.size())
, storageLength(length)
, capacity(storageLength)
, storage(capacity ? (ValueImp **)malloc(sizeof(ValueImp *) * capacity) : 0)
{
ListIterator it = list.begin();
unsigned l = length;
for (unsigned i = 0; i < l; ++i) {
storage[i] = (it++).imp();
}
}
ArrayInstanceImp::~ArrayInstanceImp()
{
free(storage);
}
Value ArrayInstanceImp::get(ExecState *exec, const Identifier &propertyName) const
{
if (propertyName == lengthPropertyName)
return Number(length);
bool ok;
unsigned index = propertyName.toArrayIndex(&ok);
if (ok) {
if (index >= length)
return Undefined();
if (index < storageLength) {
ValueImp *v = storage[index];
return v ? Value(v) : Undefined();
}
}
return ObjectImp::get(exec, propertyName);
}
Value ArrayInstanceImp::getPropertyByIndex(ExecState *exec,
unsigned index) const
{
if (index > MAX_INDEX)
return ObjectImp::get(exec, Identifier::from(index));
if (index >= length)
return Undefined();
if (index < storageLength) {
ValueImp *v = storage[index];
return v ? Value(v) : Undefined();
}
return ObjectImp::get(exec, Identifier::from(index));
}
// Special implementation of [[Put]] - see ECMA 15.4.5.1
void ArrayInstanceImp::put(ExecState *exec, const Identifier &propertyName, const Value &value, int attr)
{
if (propertyName == lengthPropertyName) {
unsigned int newLen = value.toUInt32(exec);
if (value.toNumber(exec) != double(newLen)) {
Object err = Error::create(exec, RangeError, "Invalid array length.");
exec->setException(err);
return;
}
setLength(newLen, exec);
return;
}
bool ok;
unsigned index = propertyName.toArrayIndex(&ok);
if (ok) {
putPropertyByIndex(exec, index, value, attr);
return;
}
ObjectImp::put(exec, propertyName, value, attr);
}
void ArrayInstanceImp::putPropertyByIndex(ExecState *exec, unsigned index,
const Value &value, int attr)
{
if (index < sparseArrayCutoff && index >= storageLength) {
resizeStorage(index + 1);
}
if (index >= length && index <= MAX_INDEX) {
length = index + 1;
}
if (index < storageLength) {
storage[index] = value.imp();
return;
}
assert(index >= sparseArrayCutoff);
ObjectImp::put(exec, Identifier::from(index), value, attr);
}
bool ArrayInstanceImp::hasProperty(ExecState *exec, const Identifier &propertyName) const
{
if (propertyName == lengthPropertyName)
return true;
bool ok;
unsigned index = propertyName.toArrayIndex(&ok);
if (ok) {
if (index >= length)
return false;
if (index < storageLength) {
ValueImp *v = storage[index];
return v && v != UndefinedImp::staticUndefined;
}
}
return ObjectImp::hasProperty(exec, propertyName);
}
bool ArrayInstanceImp::hasPropertyByIndex(ExecState *exec, unsigned index) const
{
if (index > MAX_INDEX)
return ObjectImp::hasProperty(exec, Identifier::from(index));
if (index >= length)
return false;
if (index < storageLength) {
ValueImp *v = storage[index];
return v && v != UndefinedImp::staticUndefined;
}
return ObjectImp::hasProperty(exec, Identifier::from(index));
}
bool ArrayInstanceImp::deleteProperty(ExecState *exec, const Identifier &propertyName)
{
if (propertyName == lengthPropertyName)
return false;
bool ok;
unsigned index = propertyName.toArrayIndex(&ok);
if (ok) {
if (index >= length)
return true;
if (index < storageLength) {
storage[index] = 0;
return true;
}
}
return ObjectImp::deleteProperty(exec, propertyName);
}
bool ArrayInstanceImp::deletePropertyByIndex(ExecState *exec, unsigned index)
{
if (index > MAX_INDEX)
return ObjectImp::deleteProperty(exec, Identifier::from(index));
if (index >= length)
return true;
if (index < storageLength) {
storage[index] = 0;
return true;
}
return ObjectImp::deleteProperty(exec, Identifier::from(index));
}
ReferenceList ArrayInstanceImp::propList(ExecState *exec, bool recursive)
{
ReferenceList properties = ObjectImp::propList(exec,recursive);
// avoid fetching this every time through the loop
ValueImp *undefined = UndefinedImp::staticUndefined;
for (unsigned i = 0; i < storageLength; ++i) {
ValueImp *imp = storage[i];
if (imp && imp != undefined && !ObjectImp::hasProperty(exec,Identifier::from(i))) {
properties.append(Reference(this, i));
}
}
return properties;
}
void ArrayInstanceImp::resizeStorage(unsigned newLength)
{
if (newLength < storageLength) {
memset(storage + newLength, 0, sizeof(ValueImp *) * (storageLength - newLength));
}
if (newLength > capacity) {
unsigned newCapacity;
if (newLength > sparseArrayCutoff) {
newCapacity = newLength;
} else {
newCapacity = (newLength * 3 + 1) / 2;
if (newCapacity > sparseArrayCutoff) {
newCapacity = sparseArrayCutoff;
}
}
storage = (ValueImp **)realloc(storage, newCapacity * sizeof (ValueImp *));
memset(storage + capacity, 0, sizeof(ValueImp *) * (newCapacity - capacity));
capacity = newCapacity;
}
storageLength = newLength;
}
void ArrayInstanceImp::setLength(unsigned newLength, ExecState *exec)
{
if (newLength <= storageLength) {
resizeStorage(newLength);
}
if (newLength < length) {
ReferenceList sparseProperties;
_prop.addSparseArrayPropertiesToReferenceList(sparseProperties, Object(this));
ReferenceListIterator it = sparseProperties.begin();
while (it != sparseProperties.end()) {
Reference ref = it++;
bool ok;
unsigned index = ref.getPropertyName(exec).toArrayIndex(&ok);
if (ok && index > newLength) {
ref.deleteValue(exec);
}
}
}
length = newLength;
}
void ArrayInstanceImp::mark()
{
ObjectImp::mark();
unsigned l = storageLength;
for (unsigned i = 0; i < l; ++i) {
ValueImp *imp = storage[i];
if (imp && !imp->marked())
imp->mark();
}
}
static ExecState *execForCompareByStringForQSort;
static int compareByStringForQSort(const void *a, const void *b)
{
ExecState *exec = execForCompareByStringForQSort;
ValueImp *va = *(ValueImp **)a;
ValueImp *vb = *(ValueImp **)b;
if (va->dispatchType() == UndefinedType) {
return vb->dispatchType() == UndefinedType ? 0 : 1;
}
if (vb->dispatchType() == UndefinedType) {
return -1;
}
return compare(va->dispatchToString(exec), vb->dispatchToString(exec));
}
void ArrayInstanceImp::sort(ExecState *exec)
{
int lengthNotIncludingUndefined = pushUndefinedObjectsToEnd(exec);
execForCompareByStringForQSort = exec;
qsort(storage, lengthNotIncludingUndefined, sizeof(ValueImp *), compareByStringForQSort);
execForCompareByStringForQSort = 0;
}
namespace KJS {
struct CompareWithCompareFunctionArguments {
CompareWithCompareFunctionArguments(ExecState *e, ObjectImp *cf)
: exec(e)
, compareFunction(cf)
, globalObject(e->dynamicInterpreter()->globalObject())
{
arguments.append(Undefined());
arguments.append(Undefined());
}
ExecState *exec;
ObjectImp *compareFunction;
List arguments;
Object globalObject;
};
}
static CompareWithCompareFunctionArguments *compareWithCompareFunctionArguments;
static int compareWithCompareFunctionForQSort(const void *a, const void *b)
{
CompareWithCompareFunctionArguments *args = compareWithCompareFunctionArguments;
ValueImp *va = *(ValueImp **)a;
ValueImp *vb = *(ValueImp **)b;
if (va->dispatchType() == UndefinedType) {
return vb->dispatchType() == UndefinedType ? 0 : 1;
}
if (vb->dispatchType() == UndefinedType) {
return -1;
}
args->arguments.clear();
args->arguments.append(va);
args->arguments.append(vb);
double compareResult = args->compareFunction->call
(args->exec, args->globalObject, args->arguments).toNumber(args->exec);
return compareResult < 0 ? -1 : compareResult > 0 ? 1 : 0;
}
void ArrayInstanceImp::sort(ExecState *exec, Object &compareFunction)
{
int lengthNotIncludingUndefined = pushUndefinedObjectsToEnd(exec);
CompareWithCompareFunctionArguments args(exec, compareFunction.imp());
compareWithCompareFunctionArguments = &args;
qsort(storage, lengthNotIncludingUndefined, sizeof(ValueImp *), compareWithCompareFunctionForQSort);
compareWithCompareFunctionArguments = 0;
}
unsigned ArrayInstanceImp::pushUndefinedObjectsToEnd(ExecState *exec)
{
ValueImp *undefined = UndefinedImp::staticUndefined;
unsigned o = 0;
for (unsigned i = 0; i != storageLength; ++i) {
ValueImp *v = storage[i];
if (v && v != undefined) {
if (o != i)
storage[o] = v;
o++;
}
}
ReferenceList sparseProperties;
_prop.addSparseArrayPropertiesToReferenceList(sparseProperties, Object(this));
unsigned newLength = o + sparseProperties.length();
if (newLength > storageLength) {
resizeStorage(newLength);
}
ReferenceListIterator it = sparseProperties.begin();
while (it != sparseProperties.end()) {
Reference ref = it++;
storage[o] = ref.getValue(exec).imp();
ObjectImp::deleteProperty(exec, ref.getPropertyName(exec));
o++;
}
if (newLength != storageLength)
memset(storage + o, 0, sizeof(ValueImp *) * (storageLength - o));
return o;
}
// ------------------------------ ArrayPrototypeImp ----------------------------
const ClassInfo ArrayPrototypeImp::info = {"Array", &ArrayInstanceImp::info, &arrayTable, 0};
/* Source for array_object.lut.h
@begin arrayTable 17
toString ArrayProtoFuncImp::ToString DontEnum|Function 0
toLocaleString ArrayProtoFuncImp::ToLocaleString DontEnum|Function 0
concat ArrayProtoFuncImp::Concat DontEnum|Function 1
join ArrayProtoFuncImp::Join DontEnum|Function 1
pop ArrayProtoFuncImp::Pop DontEnum|Function 0
push ArrayProtoFuncImp::Push DontEnum|Function 1
reverse ArrayProtoFuncImp::Reverse DontEnum|Function 0
shift ArrayProtoFuncImp::Shift DontEnum|Function 0
slice ArrayProtoFuncImp::Slice DontEnum|Function 2
sort ArrayProtoFuncImp::Sort DontEnum|Function 1
splice ArrayProtoFuncImp::Splice DontEnum|Function 2
unshift ArrayProtoFuncImp::UnShift DontEnum|Function 1
@end
*/
// ECMA 15.4.4
ArrayPrototypeImp::ArrayPrototypeImp(ExecState */*exec*/,
ObjectPrototypeImp *objProto)
: ArrayInstanceImp(objProto, 0)
{
Value protect(this);
setInternalValue(Null());
}
Value ArrayPrototypeImp::get(ExecState *exec, const Identifier &propertyName) const
{
//fprintf( stderr, "[kjs-array_object] ArrayPrototypeImp::get(%s)\n", propertyName.ascii() );
return lookupGetFunction<ArrayProtoFuncImp, ArrayInstanceImp>( exec, propertyName, &arrayTable, this );
}
// ------------------------------ ArrayProtoFuncImp ----------------------------
ArrayProtoFuncImp::ArrayProtoFuncImp(ExecState *exec, int i, int len)
: InternalFunctionImp(
static_cast<FunctionPrototypeImp*>(exec->lexicalInterpreter()->builtinFunctionPrototype().imp())
), id(i)
{
Value protect(this);
put(exec,lengthPropertyName,Number(len),DontDelete|ReadOnly|DontEnum);
}
bool ArrayProtoFuncImp::implementsCall() const
{
return true;
}
// ECMA 15.4.4
Value ArrayProtoFuncImp::call(ExecState *exec, Object &thisObj, const List &args)
{
unsigned int length = thisObj.get(exec,lengthPropertyName).toUInt32(exec);
Value result;
switch (id) {
case ToLocaleString:
case ToString:
if (!thisObj.inherits(&ArrayInstanceImp::info)) {
Object err = Error::create(exec,TypeError);
exec->setException(err);
return err;
}
// fall through
case Join: {
UString separator = ",";
UString str = "";
if (id == Join && args.size() > 0 && !args[0].isA(UndefinedType))
separator = args[0].toString(exec);
for (unsigned int k = 0; k < length; k++) {
if (k >= 1)
str += separator;
Value element = thisObj.get(exec, k);
if (element.type() == UndefinedType || element.type() == NullType)
continue;
bool fallback = false;
if (id == ToLocaleString) {
Object o = element.toObject(exec);
Object conversionFunction =
Object::dynamicCast(o.get(exec, toLocaleStringPropertyName));
if (conversionFunction.isValid() &&
conversionFunction.implementsCall()) {
str += conversionFunction.call(exec, o, List()).toString(exec);
} else {
// try toString() fallback
fallback = true;
}
}
if (id == ToString || id == Join || fallback) {
if (element.type() == ObjectType) {
Object o = Object::dynamicCast(element);
Object conversionFunction =
Object::dynamicCast(o.get(exec, toStringPropertyName));
if (conversionFunction.isValid() &&
conversionFunction.implementsCall()) {
str += conversionFunction.call(exec, o, List()).toString(exec);
} else {
UString msg = "Can't convert " + o.className() +
" object to string";
Object error = Error::create(exec, RangeError,
msg.cstring().c_str());
exec->setException(error);
return error;
}
} else {
str += element.toString(exec);
}
}
if ( exec->hadException() )
break;
}
result = String(str);
break;
}
case Concat: {
Object arr = Object::dynamicCast(exec->lexicalInterpreter()->builtinArray().construct(exec,List::empty()));
int n = 0;
Value curArg = thisObj;
Object curObj = Object::dynamicCast(thisObj);
ListIterator it = args.begin();
for (;;) {
if (curArg.type() == ObjectType &&
curObj.inherits(&ArrayInstanceImp::info)) {
unsigned int k = 0;
// Older versions tried to optimize out getting the length of thisObj
// by checking for n != 0, but that doesn't work if thisObj is an empty array.
length = curObj.get(exec,lengthPropertyName).toUInt32(exec);
while (k < length) {
if (curObj.hasProperty(exec,k))
arr.put(exec, n, curObj.get(exec, k));
n++;
k++;
}
} else {
arr.put(exec, n, curArg);
n++;
}
if (it == args.end())
break;
curArg = *it;
curObj = Object::dynamicCast(it++); // may be 0
}
arr.put(exec,lengthPropertyName, Number(n), DontEnum | DontDelete);
result = arr;
break;
}
case Pop:{
if (length == 0) {
thisObj.put(exec, lengthPropertyName, Number(length), DontEnum | DontDelete);
result = Undefined();
} else {
result = thisObj.get(exec, length - 1);
thisObj.put(exec, lengthPropertyName, Number(length - 1), DontEnum | DontDelete);
}
break;
}
case Push: {
for (int n = 0; n < args.size(); n++)
thisObj.put(exec, length + n, args[n]);
length += args.size();
thisObj.put(exec,lengthPropertyName, Number(length), DontEnum | DontDelete);
result = Number(length);
break;
}
case Reverse: {
unsigned int middle = length / 2;
for (unsigned int k = 0; k < middle; k++) {
unsigned lk1 = length - k - 1;
Value obj = thisObj.get(exec,k);
Value obj2 = thisObj.get(exec,lk1);
if (thisObj.hasProperty(exec,lk1)) {
if (thisObj.hasProperty(exec,k)) {
thisObj.put(exec, k, obj2);
thisObj.put(exec, lk1, obj);
} else {
thisObj.put(exec, k, obj2);
thisObj.deleteProperty(exec, lk1);
}
} else {
if (thisObj.hasProperty(exec, k)) {
thisObj.deleteProperty(exec, k);
thisObj.put(exec, lk1, obj);
} else {
// why delete something that's not there ? Strange.
thisObj.deleteProperty(exec, k);
thisObj.deleteProperty(exec, lk1);
}
}
}
result = thisObj;
break;
}
case Shift: {
if (length == 0) {
thisObj.put(exec, lengthPropertyName, Number(length), DontEnum | DontDelete);
result = Undefined();
} else {
result = thisObj.get(exec, 0);
for(unsigned int k = 1; k < length; k++) {
if (thisObj.hasProperty(exec, k)) {
Value obj = thisObj.get(exec, k);
thisObj.put(exec, k-1, obj);
} else
thisObj.deleteProperty(exec, k-1);
}
thisObj.deleteProperty(exec, length - 1);
thisObj.put(exec, lengthPropertyName, Number(length - 1), DontEnum | DontDelete);
}
break;
}
case Slice: {
// http://developer.netscape.com/docs/manuals/js/client/jsref/array.htm#1193713 or 15.4.4.10
// We return a new array
Object resObj = Object::dynamicCast(exec->lexicalInterpreter()->builtinArray().construct(exec,List::empty()));
result = resObj;
int begin = 0;
if (args[0].type() != UndefinedType) {
begin = args[0].toInteger(exec);
if ( begin < 0 )
begin = maxInt( begin + length, 0 );
else
begin = minInt( begin, length );
}
int end = length;
if (args[1].type() != UndefinedType)
{
end = args[1].toInteger(exec);
if ( end < 0 )
end = maxInt( end + length, 0 );
else
end = minInt( end, length );
}
//printf( "Slicing from %d to %d \n", begin, end );
int n = 0;
for(int k = begin; k < end; k++, n++) {
if (thisObj.hasProperty(exec, k)) {
Value obj = thisObj.get(exec, k);
resObj.put(exec, n, obj);
}
}
resObj.put(exec, lengthPropertyName, Number(n), DontEnum | DontDelete);
break;
}
case Sort:{
#if 0
printf("KJS Array::Sort length=%d\n", length);
for ( unsigned int i = 0 ; i<length ; ++i )
printf("KJS Array::Sort: %d: %s\n", i, thisObj.get(exec, i).toString(exec).ascii() );
#endif
Object sortFunction;
bool useSortFunction = (args[0].type() != UndefinedType);
if (useSortFunction)
{
sortFunction = args[0].toObject(exec);
if (!sortFunction.implementsCall())
useSortFunction = false;
}
if (thisObj.imp()->classInfo() == &ArrayInstanceImp::info) {
if (useSortFunction)
((ArrayInstanceImp *)thisObj.imp())->sort(exec, sortFunction);
else
((ArrayInstanceImp *)thisObj.imp())->sort(exec);
result = thisObj;
break;
}
if (length == 0) {
thisObj.put(exec, lengthPropertyName, Number(0), DontEnum | DontDelete);
result = thisObj;
break;
}
// "Min" sort. Not the fastest, but definitely less code than heapsort
// or quicksort, and much less swapping than bubblesort/insertionsort.
for ( unsigned int i = 0 ; i<length-1 ; ++i )
{
Value iObj = thisObj.get(exec,i);
unsigned int themin = i;
Value minObj = iObj;
for ( unsigned int j = i+1 ; j<length ; ++j )
{
Value jObj = thisObj.get(exec,j);
double cmp;
if (jObj.type() == UndefinedType) {
cmp = 1; // don't check minObj because there's no need to differentiate == (0) from > (1)
} else if (minObj.type() == UndefinedType) {
cmp = -1;
} else if (useSortFunction) {
List l;
l.append(jObj);
l.append(minObj);
cmp = sortFunction.call(exec, exec->dynamicInterpreter()->globalObject(), l).toNumber(exec);
} else {
cmp = (jObj.toString(exec) < minObj.toString(exec)) ? -1 : 1;
}
if ( cmp < 0 )
{
themin = j;
minObj = jObj;
}
}
// Swap themin and i
if ( themin > i )
{
//printf("KJS Array::Sort: swapping %d and %d\n", i, themin );
thisObj.put( exec, i, minObj );
thisObj.put( exec, themin, iObj );
}
}
#if 0
printf("KJS Array::Sort -- Resulting array:\n");
for ( unsigned int i = 0 ; i<length ; ++i )
printf("KJS Array::Sort: %d: %s\n", i, thisObj.get(exec, i).toString(exec).ascii() );
#endif
result = thisObj;
break;
}
case Splice: {
// 15.4.4.12 - oh boy this is huge
Object resObj = Object::dynamicCast(exec->lexicalInterpreter()->builtinArray().construct(exec,List::empty()));
result = resObj;
int begin = args[0].toUInt32(exec);
if ( begin < 0 )
begin = maxInt( begin + length, 0 );
else
begin = minInt( begin, length );
unsigned int deleteCount = minInt( maxInt( args[1].toUInt32(exec), 0 ), length - begin );
//printf( "Splicing from %d, deleteCount=%d \n", begin, deleteCount );
for(unsigned int k = 0; k < deleteCount; k++) {
if (thisObj.hasProperty(exec,k+begin)) {
Value obj = thisObj.get(exec, k+begin);
resObj.put(exec, k, obj);
}
}
resObj.put(exec, lengthPropertyName, Number(deleteCount), DontEnum | DontDelete);
unsigned int additionalArgs = maxInt( args.size() - 2, 0 );
if ( additionalArgs != deleteCount )
{
if ( additionalArgs < deleteCount )
{
for ( unsigned int k = begin; k < length - deleteCount; ++k )
{
if (thisObj.hasProperty(exec,k+deleteCount)) {
Value obj = thisObj.get(exec, k+deleteCount);
thisObj.put(exec, k+additionalArgs, obj);
}
else
thisObj.deleteProperty(exec, k+additionalArgs);
}
for ( unsigned int k = length ; k > length - deleteCount + additionalArgs; --k )
thisObj.deleteProperty(exec, k-1);
}
else
{
for ( unsigned int k = length - deleteCount; (int)k > begin; --k )
{
if (thisObj.hasProperty(exec,k+deleteCount-1)) {
Value obj = thisObj.get(exec, k+deleteCount-1);
thisObj.put(exec, k+additionalArgs-1, obj);
}
else
thisObj.deleteProperty(exec, k+additionalArgs-1);
}
}
}
for ( unsigned int k = 0; k < additionalArgs; ++k )
{
thisObj.put(exec, k+begin, args[k+2]);
}
thisObj.put(exec, lengthPropertyName, Number(length - deleteCount + additionalArgs), DontEnum | DontDelete);
break;
}
case UnShift: { // 15.4.4.13
unsigned int nrArgs = args.size();
for ( unsigned int k = length; k > 0; --k )
{
if (thisObj.hasProperty(exec,k-1)) {
Value obj = thisObj.get(exec, k-1);
thisObj.put(exec, k+nrArgs-1, obj);
} else {
thisObj.deleteProperty(exec, k+nrArgs-1);
}
}
for ( unsigned int k = 0; k < nrArgs; ++k )
thisObj.put(exec, k, args[k]);
result = Number(length + nrArgs);
thisObj.put(exec, lengthPropertyName, result, DontEnum | DontDelete);
break;
}
default:
assert(0);
break;
}
return result;
}
// ------------------------------ ArrayObjectImp -------------------------------
ArrayObjectImp::ArrayObjectImp(ExecState *exec,
FunctionPrototypeImp *funcProto,
ArrayPrototypeImp *arrayProto)
: InternalFunctionImp(funcProto)
{
Value protect(this);
// ECMA 15.4.3.1 Array.prototype
put(exec,prototypePropertyName, Object(arrayProto), DontEnum|DontDelete|ReadOnly);
// no. of arguments for constructor
put(exec,lengthPropertyName, Number(1), ReadOnly|DontDelete|DontEnum);
}
bool ArrayObjectImp::implementsConstruct() const
{
return true;
}
// ECMA 15.4.2
Object ArrayObjectImp::construct(ExecState *exec, const List &args)
{
// a single numeric argument denotes the array size (!)
if (args.size() == 1 && args[0].type() == NumberType) {
unsigned int n = args[0].toUInt32(exec);
if (n != args[0].toNumber(exec)) {
Object error = Error::create(exec, RangeError, "Invalid array length.");
exec->setException(error);
return error;
}
return Object(new ArrayInstanceImp(exec->lexicalInterpreter()->builtinArrayPrototype().imp(), n));
}
// otherwise the array is constructed with the arguments in it
return Object(new ArrayInstanceImp(exec->lexicalInterpreter()->builtinArrayPrototype().imp(), args));
}
bool ArrayObjectImp::implementsCall() const
{
return true;
}
// ECMA 15.6.1
Value ArrayObjectImp::call(ExecState *exec, Object &/*thisObj*/, const List &args)
{
// equivalent to 'new Array(....)'
return construct(exec,args);
}