/**************************************************************************** ** ** Copyright (C) 2016 The Qt Company Ltd. ** Contact: https://www.qt.io/licensing/ ** ** This file is part of the QtQml module of the Qt Toolkit. ** ** $QT_BEGIN_LICENSE:LGPL$ ** Commercial License Usage ** Licensees holding valid commercial Qt licenses may use this file in ** accordance with the commercial license agreement provided with the ** Software or, alternatively, in accordance with the terms contained in ** a written agreement between you and The Qt Company. For licensing terms ** and conditions see https://www.qt.io/terms-conditions. For further ** information use the contact form at https://www.qt.io/contact-us. ** ** GNU Lesser General Public License Usage ** Alternatively, this file may be used under the terms of the GNU Lesser ** General Public License version 3 as published by the Free Software ** Foundation and appearing in the file LICENSE.LGPL3 included in the ** packaging of this file. Please review the following information to ** ensure the GNU Lesser General Public License version 3 requirements ** will be met: https://www.gnu.org/licenses/lgpl-3.0.html. ** ** GNU General Public License Usage ** Alternatively, this file may be used under the terms of the GNU ** General Public License version 2.0 or (at your option) the GNU General ** Public license version 3 or any later version approved by the KDE Free ** Qt Foundation. The licenses are as published by the Free Software ** Foundation and appearing in the file LICENSE.GPL2 and LICENSE.GPL3 ** included in the packaging of this file. Please review the following ** information to ensure the GNU General Public License requirements will ** be met: https://www.gnu.org/licenses/gpl-2.0.html and ** https://www.gnu.org/licenses/gpl-3.0.html. ** ** $QT_END_LICENSE$ ** ****************************************************************************/ #include "qv4global_p.h" #include "qv4engine_p.h" #include "qv4runtime_p.h" #ifndef V4_BOOTSTRAP #include "qv4object_p.h" #include "qv4objectproto_p.h" #include "qv4globalobject_p.h" #include "qv4stringobject_p.h" #include "qv4argumentsobject_p.h" #include "qv4objectiterator_p.h" #include "qv4dateobject_p.h" #include "qv4lookup_p.h" #include "qv4function_p.h" #include "qv4numberobject_p.h" #include "qv4regexp_p.h" #include "qv4regexpobject_p.h" #include "private/qlocale_tools_p.h" #include "qv4scopedvalue_p.h" #include "qv4jscall_p.h" #include #include #include #include #include "qv4qobjectwrapper_p.h" #include "qv4symbol_p.h" #include "qv4generatorobject_p.h" #endif #include #include #include #include #include #ifdef QV4_COUNT_RUNTIME_FUNCTIONS # include # include #endif // QV4_COUNT_RUNTIME_FUNCTIONS QT_BEGIN_NAMESPACE namespace QV4 { #ifdef QV4_COUNT_RUNTIME_FUNCTIONS struct RuntimeCounters::Data { enum Type { None = 0, Undefined = 1, Null = 2, Boolean = 3, Integer = 4, Managed = 5, Double = 7 }; static const char *pretty(Type t) { switch (t) { case None: return ""; case Undefined: return "Undefined"; case Null: return "Null"; case Boolean: return "Boolean"; case Integer: return "Integer"; case Managed: return "Managed"; case Double: return "Double"; default: return "Unknown"; } } static unsigned mangle(unsigned tag) { switch (tag) { case Value::Undefined_Type: return Undefined; case Value::Null_Type: return Null; case Value::Boolean_Type: return Boolean; case Value::Integer_Type: return Integer; case Value::Managed_Type: return Managed; default: return Double; } } static unsigned mangle(unsigned tag1, unsigned tag2) { return (mangle(tag1) << 3) | mangle(tag2); } static void unmangle(unsigned signature, Type &tag1, Type &tag2) { tag1 = Type((signature >> 3) & 7); tag2 = Type(signature & 7); } typedef QVector Counters; QHash counters; inline void count(const char *func) { QVector &cnt = counters[func]; if (cnt.isEmpty()) cnt.resize(64); cnt[0] += 1; } inline void count(const char *func, unsigned tag) { QVector &cnt = counters[func]; if (cnt.isEmpty()) cnt.resize(64); cnt[mangle(tag)] += 1; } inline void count(const char *func, unsigned tag1, unsigned tag2) { QVector &cnt = counters[func]; if (cnt.isEmpty()) cnt.resize(64); cnt[mangle(tag1, tag2)] += 1; } struct Line { const char *func; Type tag1, tag2; quint64 count; static bool less(const Line &line1, const Line &line2) { return line1.count > line2.count; } }; void dump() const { QBuffer buf; buf.open(QIODevice::WriteOnly); QTextStream outs(&buf); QList lines; for (auto it = counters.cbegin(), end = counters.cend(); it != end; ++it) { const Counters &fCount = it.value(); for (int i = 0, ei = fCount.size(); i != ei; ++i) { quint64 count = fCount[i]; if (!count) continue; Line line; line.func = it.key(); unmangle(i, line.tag1, line.tag2); line.count = count; lines.append(line); } } std::sort(lines.begin(), lines.end(), Line::less); outs << lines.size() << " counters:" << endl; for (const Line &line : qAsConst(lines)) outs << qSetFieldWidth(10) << line.count << qSetFieldWidth(0) << " | " << line.func << " | " << pretty(line.tag1) << " | " << pretty(line.tag2) << endl; qDebug("%s", buf.data().constData()); } }; RuntimeCounters *RuntimeCounters::instance = 0; static RuntimeCounters runtimeCountersInstance; RuntimeCounters::RuntimeCounters() : d(new Data) { if (!instance) instance = this; } RuntimeCounters::~RuntimeCounters() { d->dump(); delete d; } void RuntimeCounters::count(const char *func) { d->count(func); } void RuntimeCounters::count(const char *func, uint tag) { d->count(func, tag); } void RuntimeCounters::count(const char *func, uint tag1, uint tag2) { d->count(func, tag1, tag2); } #endif // QV4_COUNT_RUNTIME_FUNCTIONS #ifndef V4_BOOTSTRAP void RuntimeHelpers::numberToString(QString *result, double num, int radix) { Q_ASSERT(result); if (std::isnan(num)) { *result = QStringLiteral("NaN"); return; } else if (qt_is_inf(num)) { *result = num < 0 ? QStringLiteral("-Infinity") : QStringLiteral("Infinity"); return; } if (radix == 10) { // We cannot use our usual locale->toString(...) here, because EcmaScript has special rules // about the longest permissible number, depending on if it's <0 or >0. const int ecma_shortest_low = -6; const int ecma_shortest_high = 21; const QLatin1Char zero('0'); const QLatin1Char dot('.'); int decpt = 0; int sign = 0; *result = qdtoa(num, &decpt, &sign); if (decpt <= ecma_shortest_low || decpt > ecma_shortest_high) { if (result->length() > 1) result->insert(1, dot); result->append(QLatin1Char('e')); if (decpt > 0) result->append(QLatin1Char('+')); result->append(QString::number(decpt - 1)); } else if (decpt <= 0) { result->prepend(QLatin1String("0.") + QString(-decpt, zero)); } else if (decpt < result->length()) { result->insert(decpt, dot); } else { result->append(QString(decpt - result->length(), zero)); } if (sign && num) result->prepend(QLatin1Char('-')); return; } result->clear(); bool negative = false; if (num < 0) { negative = true; num = -num; } double frac = num - ::floor(num); num = Value::toInteger(num); do { char c = (char)::fmod(num, radix); c = (c < 10) ? (c + '0') : (c - 10 + 'a'); result->prepend(QLatin1Char(c)); num = ::floor(num / radix); } while (num != 0); if (frac != 0) { result->append(QLatin1Char('.')); double magnitude = 1; double next = frac; do { next *= radix; const int floored = ::floor(next); char c = char(floored); c = (c < 10) ? (c + '0') : (c - 10 + 'a'); result->append(QLatin1Char(c)); magnitude /= radix; frac -= double(floored) * magnitude; next -= double(floored); // The next digit still makes a difference // if a value of "radix" for it would change frac. // Otherwise we've reached the limit of numerical precision. } while (frac > 0 && frac - magnitude != frac); } if (negative) result->prepend(QLatin1Char('-')); } ReturnedValue Runtime::Closure::call(ExecutionEngine *engine, int functionId) { QV4::Function *clos = static_cast(engine->currentStackFrame->v4Function->compilationUnit)->runtimeFunctions[functionId]; Q_ASSERT(clos); ExecutionContext *current = static_cast(&engine->currentStackFrame->jsFrame->context); if (clos->isGenerator()) return GeneratorFunction::create(current, clos)->asReturnedValue(); return FunctionObject::createScriptFunction(current, clos)->asReturnedValue(); } Bool Runtime::DeleteProperty_NoThrow::call(ExecutionEngine *engine, const Value &base, const Value &index) { Scope scope(engine); ScopedObject o(scope, base.toObject(engine)); if (scope.engine->hasException) return Encode::undefined(); Q_ASSERT(o); ScopedPropertyKey key(scope, index.toPropertyKey(engine)); if (engine->hasException) return false; return o->deleteProperty(key); } ReturnedValue Runtime::DeleteProperty::call(ExecutionEngine *engine, QV4::Function *function, const QV4::Value &base, const QV4::Value &index) { if (!Runtime::DeleteProperty_NoThrow::call(engine, base, index)) { if (function->isStrict()) engine->throwTypeError(); return Encode(false); } else { return Encode(true); } } Bool Runtime::DeleteName_NoThrow::call(ExecutionEngine *engine, int nameIndex) { Scope scope(engine); ScopedString name(scope, engine->currentStackFrame->v4Function->compilationUnit->runtimeStrings[nameIndex]); return static_cast(engine->currentStackFrame->jsFrame->context).deleteProperty(name); } ReturnedValue Runtime::DeleteName::call(ExecutionEngine *engine, Function *function, int name) { if (!Runtime::DeleteName_NoThrow::call(engine, name)) { if (function->isStrict()) engine->throwTypeError(); return Encode(false); } else { return Encode(true); } } QV4::ReturnedValue Runtime::Instanceof::call(ExecutionEngine *engine, const Value &lval, const Value &rval) { // 11.8.6, 5: rval must be an Object const Object *rhs = rval.as(); if (!rhs) return engine->throwTypeError(); const FunctionObject *f = rhs->as(); // shortcut hasInstance evaluation. In this case we know that we are calling the regular hasInstance() // method of the FunctionPrototype if (f && f->d()->prototype() == engine->functionPrototype()->d() && !f->hasHasInstanceProperty()) return Object::checkedInstanceOf(engine, f, lval); Scope scope(engine); ScopedValue hasInstance(scope, rhs->get(engine->symbol_hasInstance())); if (hasInstance->isUndefined()) return rhs->instanceOf(lval); FunctionObject *fHasInstance = hasInstance->as(); if (!fHasInstance) return engine->throwTypeError(); ScopedValue result(scope, fHasInstance->call(&rval, &lval, 1)); return Encode(result->toBoolean()); } QV4::ReturnedValue Runtime::In::call(ExecutionEngine *engine, const Value &left, const Value &right) { Object *ro = right.objectValue(); if (!ro) return engine->throwTypeError(); Scope scope(engine); ScopedPropertyKey s(scope, left.toPropertyKey(engine)); if (scope.hasException()) return Encode::undefined(); bool r = ro->hasProperty(s); return Encode(r); } double RuntimeHelpers::stringToNumber(const QString &string) { const QStringRef s = QStringRef(&string).trimmed(); if (s.startsWith(QLatin1Char('0'))) { int base = -1; if (s.startsWith(QLatin1String("0x")) || s.startsWith(QLatin1String("0X"))) base = 16; else if (s.startsWith(QLatin1String("0o")) || s.startsWith(QLatin1String("0O"))) base = 8; else if (s.startsWith(QLatin1String("0b")) || s.startsWith(QLatin1String("0B"))) base = 2; if (base > 0) { bool ok = true; qlonglong num; num = s.mid(2).toLongLong(&ok, base); if (!ok) return qQNaN(); return num; } } bool ok = false; QByteArray ba = s.toLatin1(); const char *begin = ba.constData(); const char *end = nullptr; double d = qstrtod(begin, &end, &ok); if (end - begin != ba.size()) { if (ba == "Infinity" || ba == "+Infinity") d = Q_INFINITY; else if (ba == "-Infinity") d = -Q_INFINITY; else d = std::numeric_limits::quiet_NaN(); } return d; } Heap::String *RuntimeHelpers::stringFromNumber(ExecutionEngine *engine, double number) { QString qstr; RuntimeHelpers::numberToString(&qstr, number, 10); return engine->newString(qstr); } ReturnedValue RuntimeHelpers::objectDefaultValue(const Object *object, int typeHint) { ExecutionEngine *engine = object->internalClass()->engine; if (engine->hasException) return Encode::undefined(); String *hint; switch (typeHint) { case STRING_HINT: hint = engine->id_string(); break; case NUMBER_HINT: hint = engine->id_number(); break; default: hint = engine->id_default(); break; } Scope scope(engine); ScopedFunctionObject toPrimitive(scope, object->get(engine->symbol_toPrimitive())); if (engine->hasException) return Encode::undefined(); if (toPrimitive) { ScopedValue result(scope, toPrimitive->call(object, hint, 1)); if (engine->hasException) return Encode::undefined(); if (!result->isPrimitive()) return engine->throwTypeError(); return result->asReturnedValue(); } if (hint == engine->id_default()) hint = engine->id_number(); return ordinaryToPrimitive(engine, object, hint); } ReturnedValue RuntimeHelpers::ordinaryToPrimitive(ExecutionEngine *engine, const Object *object, String *typeHint) { Q_ASSERT(!engine->hasException); String *meth1 = engine->id_toString(); String *meth2 = engine->id_valueOf(); if (typeHint->propertyKey() == engine->id_number()->propertyKey()) { qSwap(meth1, meth2); } else { Q_ASSERT(typeHint->propertyKey() == engine->id_string()->propertyKey()); } Scope scope(engine); ScopedValue result(scope); ScopedValue conv(scope, object->get(meth1)); if (FunctionObject *o = conv->as()) { result = o->call(object, nullptr, 0); if (result->isPrimitive()) return result->asReturnedValue(); } if (engine->hasException) return Encode::undefined(); conv = object->get(meth2); if (FunctionObject *o = conv->as()) { result = o->call(object, nullptr, 0); if (result->isPrimitive()) return result->asReturnedValue(); } return engine->throwTypeError(); } Heap::Object *RuntimeHelpers::convertToObject(ExecutionEngine *engine, const Value &value) { Q_ASSERT(!value.isObject()); switch (value.type()) { case Value::Undefined_Type: engine->throwTypeError(QLatin1String("Value is undefined and could not be converted to an object")); return nullptr; case Value::Null_Type: engine->throwTypeError(QLatin1String("Value is null and could not be converted to an object")); return nullptr; case Value::Boolean_Type: return engine->newBooleanObject(value.booleanValue()); case Value::Managed_Type: Q_ASSERT(value.isStringOrSymbol()); if (!value.isString()) return engine->newSymbolObject(value.symbolValue()); return engine->newStringObject(value.stringValue()); case Value::Integer_Type: default: // double return engine->newNumberObject(value.asDouble()); } } Heap::String *RuntimeHelpers::convertToString(ExecutionEngine *engine, Value value, TypeHint hint) { redo: switch (value.type()) { case Value::Empty_Type: Q_ASSERT(!"empty Value encountered"); Q_UNREACHABLE(); case Value::Undefined_Type: return engine->id_undefined()->d(); case Value::Null_Type: return engine->id_null()->d(); case Value::Boolean_Type: if (value.booleanValue()) return engine->id_true()->d(); else return engine->id_false()->d(); case Value::Managed_Type: { if (value.isString()) return static_cast(value).d(); if (value.isSymbol()) { engine->throwTypeError(QLatin1String("Cannot convert a symbol to a string.")); return nullptr; } value = Value::fromReturnedValue(RuntimeHelpers::toPrimitive(value, hint)); Q_ASSERT(value.isPrimitive()); if (value.isString()) return static_cast(value).d(); goto redo; } case Value::Integer_Type: return RuntimeHelpers::stringFromNumber(engine, value.int_32()); default: // double return RuntimeHelpers::stringFromNumber(engine, value.doubleValue()); } // switch } // This is slightly different from the method above, as // the + operator requires a slightly different conversion static Heap::String *convert_to_string_add(ExecutionEngine *engine, Value value) { return RuntimeHelpers::convertToString(engine, value, PREFERREDTYPE_HINT); } QV4::ReturnedValue RuntimeHelpers::addHelper(ExecutionEngine *engine, const Value &left, const Value &right) { Scope scope(engine); ScopedValue pleft(scope, RuntimeHelpers::toPrimitive(left, PREFERREDTYPE_HINT)); ScopedValue pright(scope, RuntimeHelpers::toPrimitive(right, PREFERREDTYPE_HINT)); String *sleft = pleft->stringValue(); String *sright = pright->stringValue(); if (sleft || sright) { if (!sleft) { pleft = convert_to_string_add(engine, pleft); sleft = static_cast(pleft.ptr); } if (!sright) { pright = convert_to_string_add(engine, pright); sright = static_cast(pright.ptr); } if (engine->hasException) return Encode::undefined(); if (!sleft->d()->length()) return sright->asReturnedValue(); if (!sright->d()->length()) return sleft->asReturnedValue(); MemoryManager *mm = engine->memoryManager; return (mm->alloc(sleft->d(), sright->d()))->asReturnedValue(); } double x = RuntimeHelpers::toNumber(pleft); double y = RuntimeHelpers::toNumber(pright); return Encode(x + y); } ReturnedValue Runtime::GetTemplateObject::call(Function *function, int index) { return function->compilationUnit->templateObjectAt(index)->asReturnedValue(); } void Runtime::StoreProperty::call(ExecutionEngine *engine, const Value &object, int nameIndex, const Value &value) { Scope scope(engine); QV4::Function *v4Function = engine->currentStackFrame->v4Function; ScopedString name(scope, v4Function->compilationUnit->runtimeStrings[nameIndex]); ScopedObject o(scope, object); if (!o) { if (v4Function->isStrict()) { engine->throwTypeError(); return; } o = object.toObject(engine); } if ((!o || !o->put(name, value)) && v4Function->isStrict()) engine->throwTypeError(); } static Q_NEVER_INLINE ReturnedValue getElementIntFallback(ExecutionEngine *engine, const Value &object, uint idx) { Q_ASSERT(idx < UINT_MAX); Scope scope(engine); ScopedObject o(scope, object); if (!o) { if (const String *str = object.as()) { if (idx >= (uint)str->toQString().length()) { return Encode::undefined(); } const QString s = str->toQString().mid(idx, 1); return scope.engine->newString(s)->asReturnedValue(); } if (object.isNullOrUndefined()) { QString message = QStringLiteral("Cannot read property '%1' of %2").arg(idx).arg(object.toQStringNoThrow()); return engine->throwTypeError(message); } o = RuntimeHelpers::convertToObject(scope.engine, object); Q_ASSERT(!!o); // can't fail as null/undefined is covered above } if (o->arrayData() && !o->arrayData()->attrs) { ScopedValue v(scope, o->arrayData()->get(idx)); if (!v->isEmpty()) return v->asReturnedValue(); } return o->get(idx); } static Q_NEVER_INLINE ReturnedValue getElementFallback(ExecutionEngine *engine, const Value &object, const Value &index) { Q_ASSERT(!index.isPositiveInt()); Scope scope(engine); ScopedObject o(scope, object); if (!o) { if (object.isNullOrUndefined()) { QString message = QStringLiteral("Cannot read property '%1' of %2").arg(index.toQStringNoThrow()).arg(object.toQStringNoThrow()); return engine->throwTypeError(message); } o = RuntimeHelpers::convertToObject(scope.engine, object); Q_ASSERT(!!o); // can't fail as null/undefined is covered above } ScopedPropertyKey name(scope, index.toPropertyKey(engine)); if (scope.hasException()) return Encode::undefined(); return o->get(name); } ReturnedValue Runtime::LoadElement::call(ExecutionEngine *engine, const Value &object, const Value &index) { if (index.isPositiveInt()) { uint idx = static_cast(index.int_32()); if (Heap::Base *b = object.heapObject()) { if (b->internalClass->vtable->isObject) { Heap::Object *o = static_cast(b); if (o->arrayData && o->arrayData->type == Heap::ArrayData::Simple) { Heap::SimpleArrayData *s = o->arrayData.cast(); if (idx < s->values.size) if (!s->data(idx).isEmpty()) return s->data(idx).asReturnedValue(); } } } return getElementIntFallback(engine, object, idx); } return getElementFallback(engine, object, index); } static Q_NEVER_INLINE bool setElementFallback(ExecutionEngine *engine, const Value &object, const Value &index, const Value &value) { Scope scope(engine); ScopedObject o(scope, object); if (!o) { if (engine->currentStackFrame->v4Function->isStrict()) { engine->throwTypeError(); return false; } o = object.toObject(engine); } if (engine->hasException) return false; if (index.isPositiveInt()) { uint idx = static_cast(index.int_32()); if (o->d()->arrayData && o->d()->arrayData->type == Heap::ArrayData::Simple) { Heap::SimpleArrayData *s = o->d()->arrayData.cast(); if (idx < s->values.size) { s->setData(engine, idx, value); return true; } } return o->put(idx, value); } ScopedPropertyKey name(scope, index.toPropertyKey(engine)); if (engine->hasException) return false; return o->put(name, value); } void Runtime::StoreElement::call(ExecutionEngine *engine, const Value &object, const Value &index, const Value &value) { if (index.isPositiveInt()) { uint idx = static_cast(index.int_32()); if (Heap::Base *b = object.heapObject()) { if (b->internalClass->vtable->isObject) { Heap::Object *o = static_cast(b); if (o->arrayData && o->arrayData->type == Heap::ArrayData::Simple) { Heap::SimpleArrayData *s = o->arrayData.cast(); if (idx < s->values.size) { s->setData(engine, idx, value); return; } } } } } if (!setElementFallback(engine, object, index, value) && engine->currentStackFrame->v4Function->isStrict()) engine->throwTypeError(); } ReturnedValue Runtime::GetIterator::call(ExecutionEngine *engine, const Value &in, int iterator) { Scope scope(engine); ScopedObject o(scope, (Object *)nullptr); if (!in.isNullOrUndefined()) o = in.toObject(engine); if (engine->hasException) return Encode::undefined(); if (iterator == static_cast(QQmlJS::AST::ForEachType::Of)) { if (!o) return engine->throwTypeError(); ScopedFunctionObject f(scope, o->get(engine->symbol_iterator())); if (!f) return engine->throwTypeError(); JSCallData cData(scope, 0, nullptr, o); ScopedObject it(scope, f->call(cData)); if (!it) return engine->throwTypeError(); return it->asReturnedValue(); } return engine->newForInIteratorObject(o)->asReturnedValue(); } ReturnedValue Runtime::IteratorNext::call(ExecutionEngine *engine, const Value &iterator, Value *value) { // if we throw an exception from here, return true, not undefined. This is to ensure iteratorDone is set to true // and the stack unwinding won't close the iterator Q_ASSERT(iterator.isObject()); Scope scope(engine); ScopedFunctionObject f(scope, static_cast(iterator).get(engine->id_next())); if (!f) { engine->throwTypeError(); return Encode(true); } JSCallData cData(scope, 0, nullptr, &iterator); ScopedObject o(scope, f->call(cData)); if (scope.hasException()) return Encode(true); if (!o) { engine->throwTypeError(); return Encode(true); } ScopedValue d(scope, o->get(engine->id_done())); if (scope.hasException()) return Encode(true); bool done = d->toBoolean(); if (done) { *value = Encode::undefined(); return Encode(true); } *value = o->get(engine->id_value()); if (scope.hasException()) return Encode(true); return Encode(false); } ReturnedValue Runtime::IteratorNextForYieldStar::call(ExecutionEngine *engine, const Value &received, const Value &iterator, Value *object) { // the return value encodes how to continue the yield* iteration. // true implies iteration is done, false for iteration to continue // a return value of undefines is a special marker, that the iterator has been invoked with return() Scope scope(engine); Q_ASSERT(iterator.isObject()); const Value *arg = &received; bool returnCalled = false; FunctionObject *f = nullptr; if (engine->hasException) { if (engine->exceptionValue->isEmpty()) { // generator called with return() *engine->exceptionValue = Encode::undefined(); engine->hasException = false; ScopedValue ret(scope, static_cast(iterator).get(engine->id_return())); if (ret->isUndefined()) { // propagate return() return Encode::undefined(); } returnCalled = true; f = ret->as(); } else { // generator called with throw ScopedValue exceptionValue(scope, *engine->exceptionValue); *engine->exceptionValue = Encode::undefined(); engine->hasException = false; ScopedValue t(scope, static_cast(iterator).get(engine->id_throw())); if (engine->hasException) return Encode::undefined(); if (t->isUndefined()) { // no throw method on the iterator ScopedValue done(scope, Encode(false)); IteratorClose::call(engine, iterator, done); if (engine->hasException) return Encode::undefined(); return engine->throwTypeError(); } f = t->as(); arg = exceptionValue; } } else { // generator called with next() ScopedFunctionObject next(scope, static_cast(iterator).get(engine->id_next())); f = next->as(); } if (!f) return engine->throwTypeError(); ScopedObject o(scope, f->call(&iterator, arg, 1)); if (scope.hasException()) return Encode(true); if (!o) return engine->throwTypeError(); ScopedValue d(scope, o->get(engine->id_done())); if (scope.hasException()) return Encode(true); bool done = d->toBoolean(); if (done) { *object = o->get(engine->id_value()); return returnCalled ? Encode::undefined() : Encode(true); } *object = o; return Encode(false); } ReturnedValue Runtime::IteratorClose::call(ExecutionEngine *engine, const Value &iterator, const Value &done) { Q_ASSERT(iterator.isObject()); Q_ASSERT(done.isBoolean()); if (done.booleanValue()) return Encode::undefined(); Scope scope(engine); ScopedValue e(scope); bool hadException = engine->hasException; if (hadException) { e = *engine->exceptionValue; engine->hasException = false; } auto originalCompletion = [=]() { if (hadException) { *engine->exceptionValue = e; engine->hasException = hadException; } return Encode::undefined(); }; ScopedValue ret(scope, static_cast(iterator).get(engine->id_return())); ScopedObject o(scope); if (!ret->isUndefined()) { FunctionObject *f = ret->as(); o = f->call(&iterator, nullptr, 0); if (engine->hasException && !hadException) return Encode::undefined(); } if (hadException || ret->isUndefined()) return originalCompletion(); if (!o) return engine->throwTypeError(); return originalCompletion(); } ReturnedValue Runtime::DestructureRestElement::call(ExecutionEngine *engine, const Value &iterator) { Q_ASSERT(iterator.isObject()); Scope scope(engine); ScopedArrayObject array(scope, engine->newArrayObject()); array->arrayCreate(); uint index = 0; while (1) { ScopedValue n(scope); ScopedValue done(scope, IteratorNext::call(engine, iterator, n)); if (engine->hasException) return Encode::undefined(); Q_ASSERT(done->isBoolean()); if (done->booleanValue()) break; array->arraySet(index, n); ++index; } return array->asReturnedValue(); } void Runtime::StoreNameSloppy::call(ExecutionEngine *engine, int nameIndex, const Value &value) { Scope scope(engine); ScopedString name(scope, engine->currentStackFrame->v4Function->compilationUnit->runtimeStrings[nameIndex]); ExecutionContext::Error e = static_cast(engine->currentStackFrame->jsFrame->context).setProperty(name, value); if (e == ExecutionContext::RangeError) engine->globalObject->put(name, value); } void Runtime::StoreNameStrict::call(ExecutionEngine *engine, int nameIndex, const Value &value) { Scope scope(engine); ScopedString name(scope, engine->currentStackFrame->v4Function->compilationUnit->runtimeStrings[nameIndex]); ExecutionContext::Error e = static_cast(engine->currentStackFrame->jsFrame->context).setProperty(name, value); if (e == ExecutionContext::TypeError) engine->throwTypeError(); else if (e == ExecutionContext::RangeError) engine->throwReferenceError(name); } ReturnedValue Runtime::LoadProperty::call(ExecutionEngine *engine, const Value &object, int nameIndex) { Scope scope(engine); ScopedString name(scope, engine->currentStackFrame->v4Function->compilationUnit->runtimeStrings[nameIndex]); ScopedObject o(scope, object); if (o) return o->get(name); if (object.isNullOrUndefined()) { QString message = QStringLiteral("Cannot read property '%1' of %2").arg(name->toQString()).arg(object.toQStringNoThrow()); return engine->throwTypeError(message); } o = RuntimeHelpers::convertToObject(scope.engine, object); if (!o) // type error return Encode::undefined(); return o->get(name); } ReturnedValue Runtime::LoadName::call(ExecutionEngine *engine, int nameIndex) { Scope scope(engine); ScopedString name(scope, engine->currentStackFrame->v4Function->compilationUnit->runtimeStrings[nameIndex]); return static_cast(engine->currentStackFrame->jsFrame->context).getProperty(name); } static Object *getSuperBase(Scope &scope) { if (scope.engine->currentStackFrame->jsFrame->thisObject.isEmpty()) { scope.engine->throwReferenceError(QStringLiteral("Missing call to super()."), QString(), 0, 0); return nullptr; } ScopedFunctionObject f(scope, scope.engine->currentStackFrame->jsFrame->function); ScopedObject homeObject(scope, f->getHomeObject()); if (!homeObject) { ScopedContext ctx(scope, static_cast(&scope.engine->currentStackFrame->jsFrame->context)); Q_ASSERT(ctx); while (ctx) { if (CallContext *c = ctx->asCallContext()) { f = c->d()->function; QV4::Function *fn = f->function(); if (fn && !fn->isArrowFunction() && !fn->isEval) break; } ctx = ctx->d()->outer; } homeObject = f->getHomeObject(); } if (!homeObject) { scope.engine->throwTypeError(); return nullptr; } Q_ASSERT(homeObject); ScopedObject proto(scope, homeObject->getPrototypeOf()); if (!proto) { scope.engine->throwTypeError(); return nullptr; } return proto; } ReturnedValue Runtime::LoadSuperProperty::call(ExecutionEngine *engine, const Value &property) { Scope scope(engine); Object *base = getSuperBase(scope); if (!base) return Encode::undefined(); ScopedPropertyKey key(scope, property.toPropertyKey(engine)); if (engine->hasException) return Encode::undefined(); return base->get(key, &engine->currentStackFrame->jsFrame->thisObject); } void Runtime::StoreSuperProperty::call(ExecutionEngine *engine, const Value &property, const Value &value) { Scope scope(engine); Object *base = getSuperBase(scope); if (!base) return; ScopedPropertyKey key(scope, property.toPropertyKey(engine)); if (engine->hasException) return; bool result = base->put(key, value, &engine->currentStackFrame->jsFrame->thisObject); if (!result && engine->currentStackFrame->v4Function->isStrict()) engine->throwTypeError(); } ReturnedValue Runtime::LoadGlobalLookup::call(ExecutionEngine *engine, Function *f, int index) { Lookup *l = f->compilationUnit->runtimeLookups + index; return l->globalGetter(l, engine); } ReturnedValue Runtime::LoadQmlContextPropertyLookup::call(ExecutionEngine *engine, uint index) { Lookup *l = engine->currentStackFrame->v4Function->compilationUnit->runtimeLookups + index; return l->qmlContextPropertyGetter(l, engine, nullptr); } ReturnedValue Runtime::GetLookup::call(ExecutionEngine *engine, Function *f, const Value &base, int index) { Lookup *l = f->compilationUnit->runtimeLookups + index; return l->getter(l, engine, base); } void Runtime::SetLookupSloppy::call(Function *f, const Value &base, int index, const Value &value) { ExecutionEngine *engine = f->internalClass->engine; QV4::Lookup *l = f->compilationUnit->runtimeLookups + index; l->setter(l, engine, const_cast(base), value); } void Runtime::SetLookupStrict::call(Function *f, const Value &base, int index, const Value &value) { ExecutionEngine *engine = f->internalClass->engine; QV4::Lookup *l = f->compilationUnit->runtimeLookups + index; if (!l->setter(l, engine, const_cast(base), value)) engine->throwTypeError(); } ReturnedValue Runtime::LoadSuperConstructor::call(ExecutionEngine *engine, const Value &t) { if (engine->currentStackFrame->thisObject() != Value::emptyValue().asReturnedValue()) { return engine->throwReferenceError(QStringLiteral("super() already called."), QString(), 0, 0); // ### fix line number } const FunctionObject *f = t.as(); if (!f) return engine->throwTypeError(); Heap::Object *c = static_cast(t).getPrototypeOf(); if (!c->vtable()->isFunctionObject || !static_cast(c)->isConstructor()) return engine->throwTypeError(); return c->asReturnedValue(); } #endif // V4_BOOTSTRAP uint RuntimeHelpers::equalHelper(const Value &x, const Value &y) { Q_ASSERT(x.type() != y.type() || (x.isManaged() && (x.isString() != y.isString()))); if (x.isNumber() && y.isNumber()) return x.asDouble() == y.asDouble(); if (x.isNull() && y.isUndefined()) { return true; } else if (x.isUndefined() && y.isNull()) { return true; } else if (x.isNumber() && y.isString()) { double dy = RuntimeHelpers::toNumber(y); return x.asDouble() == dy; } else if (x.isString() && y.isNumber()) { double dx = RuntimeHelpers::toNumber(x); return dx == y.asDouble(); } else if (x.isBoolean()) { return Runtime::CompareEqual::call(Value::fromDouble((double) x.booleanValue()), y); } else if (y.isBoolean()) { return Runtime::CompareEqual::call(x, Value::fromDouble((double) y.booleanValue())); } else { #ifdef V4_BOOTSTRAP Q_UNIMPLEMENTED(); #else Object *xo = x.objectValue(); Object *yo = y.objectValue(); if (yo && (x.isNumber() || x.isString())) { Scope scope(yo->engine()); ScopedValue py(scope, RuntimeHelpers::objectDefaultValue(yo, PREFERREDTYPE_HINT)); return Runtime::CompareEqual::call(x, py); } else if (xo && (y.isNumber() || y.isString())) { Scope scope(xo->engine()); ScopedValue px(scope, RuntimeHelpers::objectDefaultValue(xo, PREFERREDTYPE_HINT)); return Runtime::CompareEqual::call(px, y); } #endif } return false; } Bool RuntimeHelpers::strictEqual(const Value &x, const Value &y) { TRACE2(x, y); if (x.rawValue() == y.rawValue()) // NaN != NaN return !x.isNaN(); if (x.isNumber()) return y.isNumber() && x.asDouble() == y.asDouble(); if (x.isManaged()) return y.isManaged() && x.cast()->isEqualTo(y.cast()); return false; } QV4::Bool Runtime::CompareGreaterThan::call(const Value &l, const Value &r) { TRACE2(l, r); if (l.isInteger() && r.isInteger()) return l.integerValue() > r.integerValue(); if (l.isNumber() && r.isNumber()) return l.asDouble() > r.asDouble(); String *sl = l.stringValue(); String *sr = r.stringValue(); if (sl && sr) { #ifdef V4_BOOTSTRAP Q_UNIMPLEMENTED(); return false; #else return sr->lessThan(sl); #endif } Object *ro = r.objectValue(); Object *lo = l.objectValue(); if (ro || lo) { #ifdef V4_BOOTSTRAP Q_UNIMPLEMENTED(); #else QV4::ExecutionEngine *e = (lo ? lo : ro)->engine(); QV4::Scope scope(e); QV4::ScopedValue pl(scope, lo ? RuntimeHelpers::objectDefaultValue(lo, QV4::NUMBER_HINT) : l.asReturnedValue()); QV4::ScopedValue pr(scope, ro ? RuntimeHelpers::objectDefaultValue(ro, QV4::NUMBER_HINT) : r.asReturnedValue()); return Runtime::CompareGreaterThan::call(pl, pr); #endif } double dl = RuntimeHelpers::toNumber(l); double dr = RuntimeHelpers::toNumber(r); return dl > dr; } QV4::Bool Runtime::CompareLessThan::call(const Value &l, const Value &r) { TRACE2(l, r); if (l.isInteger() && r.isInteger()) return l.integerValue() < r.integerValue(); if (l.isNumber() && r.isNumber()) return l.asDouble() < r.asDouble(); String *sl = l.stringValue(); String *sr = r.stringValue(); if (sl && sr) { #ifdef V4_BOOTSTRAP Q_UNIMPLEMENTED(); return false; #else return sl->lessThan(sr); #endif } Object *ro = r.objectValue(); Object *lo = l.objectValue(); if (ro || lo) { #ifdef V4_BOOTSTRAP Q_UNIMPLEMENTED(); #else QV4::ExecutionEngine *e = (lo ? lo : ro)->engine(); QV4::Scope scope(e); QV4::ScopedValue pl(scope, lo ? RuntimeHelpers::objectDefaultValue(lo, QV4::NUMBER_HINT) : l.asReturnedValue()); QV4::ScopedValue pr(scope, ro ? RuntimeHelpers::objectDefaultValue(ro, QV4::NUMBER_HINT) : r.asReturnedValue()); return Runtime::CompareLessThan::call(pl, pr); #endif } double dl = RuntimeHelpers::toNumber(l); double dr = RuntimeHelpers::toNumber(r); return dl < dr; } QV4::Bool Runtime::CompareGreaterEqual::call(const Value &l, const Value &r) { TRACE2(l, r); if (l.isInteger() && r.isInteger()) return l.integerValue() >= r.integerValue(); if (l.isNumber() && r.isNumber()) return l.asDouble() >= r.asDouble(); String *sl = l.stringValue(); String *sr = r.stringValue(); if (sl && sr) { #ifdef V4_BOOTSTRAP Q_UNIMPLEMENTED(); return false; #else return !sl->lessThan(sr); #endif } Object *ro = r.objectValue(); Object *lo = l.objectValue(); if (ro || lo) { #ifdef V4_BOOTSTRAP Q_UNIMPLEMENTED(); #else QV4::ExecutionEngine *e = (lo ? lo : ro)->engine(); QV4::Scope scope(e); QV4::ScopedValue pl(scope, lo ? RuntimeHelpers::objectDefaultValue(lo, QV4::NUMBER_HINT) : l.asReturnedValue()); QV4::ScopedValue pr(scope, ro ? RuntimeHelpers::objectDefaultValue(ro, QV4::NUMBER_HINT) : r.asReturnedValue()); return Runtime::CompareGreaterEqual::call(pl, pr); #endif } double dl = RuntimeHelpers::toNumber(l); double dr = RuntimeHelpers::toNumber(r); return dl >= dr; } QV4::Bool Runtime::CompareLessEqual::call(const Value &l, const Value &r) { TRACE2(l, r); if (l.isInteger() && r.isInteger()) return l.integerValue() <= r.integerValue(); if (l.isNumber() && r.isNumber()) return l.asDouble() <= r.asDouble(); String *sl = l.stringValue(); String *sr = r.stringValue(); if (sl && sr) { #ifdef V4_BOOTSTRAP Q_UNIMPLEMENTED(); return false; #else return !sr->lessThan(sl); #endif } Object *ro = r.objectValue(); Object *lo = l.objectValue(); if (ro || lo) { #ifdef V4_BOOTSTRAP Q_UNIMPLEMENTED(); #else QV4::ExecutionEngine *e = (lo ? lo : ro)->engine(); QV4::Scope scope(e); QV4::ScopedValue pl(scope, lo ? RuntimeHelpers::objectDefaultValue(lo, QV4::NUMBER_HINT) : l.asReturnedValue()); QV4::ScopedValue pr(scope, ro ? RuntimeHelpers::objectDefaultValue(ro, QV4::NUMBER_HINT) : r.asReturnedValue()); return Runtime::CompareLessEqual::call(pl, pr); #endif } double dl = RuntimeHelpers::toNumber(l); double dr = RuntimeHelpers::toNumber(r); return dl <= dr; } #ifndef V4_BOOTSTRAP Bool Runtime::CompareInstanceof::call(ExecutionEngine *engine, const Value &left, const Value &right) { TRACE2(left, right); Scope scope(engine); ScopedValue v(scope, Instanceof::call(engine, left, right)); return v->booleanValue(); } uint Runtime::CompareIn::call(ExecutionEngine *engine, const Value &left, const Value &right) { TRACE2(left, right); Scope scope(engine); ScopedValue v(scope, In::call(engine, left, right)); return v->booleanValue(); } static ReturnedValue throwPropertyIsNotAFunctionTypeError(ExecutionEngine *engine, Value *thisObject, const QString &propertyName) { QString objectAsString = QStringLiteral("[null]"); if (!thisObject->isUndefined()) objectAsString = thisObject->toQStringNoThrow(); QString msg = QStringLiteral("Property '%1' of object %2 is not a function") .arg(propertyName, objectAsString); return engine->throwTypeError(msg); } ReturnedValue Runtime::CallGlobalLookup::call(ExecutionEngine *engine, uint index, Value argv[], int argc) { Scope scope(engine); Lookup *l = engine->currentStackFrame->v4Function->compilationUnit->runtimeLookups + index; Value function = Value::fromReturnedValue(l->globalGetter(l, engine)); Value thisObject = Value::undefinedValue(); if (!function.isFunctionObject()) return throwPropertyIsNotAFunctionTypeError(engine, &thisObject, engine->currentStackFrame->v4Function->compilationUnit->runtimeStrings[l->nameIndex]->toQString()); return static_cast(function).call(&thisObject, argv, argc); } ReturnedValue Runtime::CallQmlContextPropertyLookup::call(ExecutionEngine *engine, uint index, Value *argv, int argc) { Scope scope(engine); ScopedValue thisObject(scope); Lookup *l = engine->currentStackFrame->v4Function->compilationUnit->runtimeLookups + index; Value function = Value::fromReturnedValue(l->qmlContextPropertyGetter(l, engine, thisObject)); if (!function.isFunctionObject()) return throwPropertyIsNotAFunctionTypeError(engine, thisObject, engine->currentStackFrame->v4Function->compilationUnit->runtimeStrings[l->nameIndex]->toQString()); return static_cast(function).call(thisObject, argv, argc); } ReturnedValue Runtime::CallPossiblyDirectEval::call(ExecutionEngine *engine, Value *argv, int argc) { Scope scope(engine); ScopedValue thisObject(scope); ExecutionContext &ctx = static_cast(engine->currentStackFrame->jsFrame->context); ScopedFunctionObject function(scope, ctx.getPropertyAndBase(engine->id_eval(), thisObject)); if (engine->hasException) return Encode::undefined(); if (!function) return throwPropertyIsNotAFunctionTypeError(engine, thisObject, QLatin1String("eval")); if (function->d() == engine->evalFunction()->d()) return static_cast(function.getPointer())->evalCall(thisObject, argv, argc, true); return function->call(thisObject, argv, argc); } ReturnedValue Runtime::CallName::call(ExecutionEngine *engine, int nameIndex, Value *argv, int argc) { Scope scope(engine); ScopedValue thisObject(scope); ScopedString name(scope, engine->currentStackFrame->v4Function->compilationUnit->runtimeStrings[nameIndex]); ExecutionContext &ctx = static_cast(engine->currentStackFrame->jsFrame->context); ScopedFunctionObject f(scope, ctx.getPropertyAndBase(name, thisObject)); if (engine->hasException) return Encode::undefined(); if (!f) return throwPropertyIsNotAFunctionTypeError(engine, thisObject, engine->currentStackFrame->v4Function->compilationUnit->runtimeStrings[nameIndex]->toQString()); return f->call(thisObject, argv, argc); } ReturnedValue Runtime::CallProperty::call(ExecutionEngine *engine, const Value &baseRef, int nameIndex, Value *argv, int argc) { const Value *base = &baseRef; Scope scope(engine); ScopedString name(scope, engine->currentStackFrame->v4Function->compilationUnit->runtimeStrings[nameIndex]); ScopedObject lookupObject(scope, base); if (!lookupObject) { Q_ASSERT(!base->isEmpty()); if (base->isNullOrUndefined()) { QString message = QStringLiteral("Cannot call method '%1' of %2") .arg(name->toQString(), base->toQStringNoThrow()); return engine->throwTypeError(message); } if (base->isManaged()) { const Managed *m = static_cast(base); lookupObject = m->internalClass()->prototype; Q_ASSERT(m->internalClass()->prototype); } else { lookupObject = RuntimeHelpers::convertToObject(engine, *base); if (engine->hasException) // type error return Encode::undefined(); if (!engine->currentStackFrame->v4Function->isStrict()) base = lookupObject; } } ScopedFunctionObject f(scope, static_cast(lookupObject)->get(name)); if (!f) { QString error = QStringLiteral("Property '%1' of object %2 is not a function") .arg(name->toQString(), base->toQStringNoThrow()); return engine->throwTypeError(error); } return f->call(base, argv, argc); } ReturnedValue Runtime::CallPropertyLookup::call(ExecutionEngine *engine, const Value &base, uint index, Value *argv, int argc) { Lookup *l = engine->currentStackFrame->v4Function->compilationUnit->runtimeLookups + index; // ok to have the value on the stack here Value f = Value::fromReturnedValue(l->getter(l, engine, base)); if (!f.isFunctionObject()) return engine->throwTypeError(); return static_cast(f).call(&base, argv, argc); } ReturnedValue Runtime::CallElement::call(ExecutionEngine *engine, const Value &baseRef, const Value &index, Value *argv, int argc) { const Value *base = &baseRef; Scope scope(engine); ScopedValue thisObject(scope, base->toObject(engine)); base = thisObject; ScopedPropertyKey str(scope, index.toPropertyKey(engine)); if (engine->hasException) return Encode::undefined(); ScopedFunctionObject f(scope, static_cast(base)->get(str)); if (!f) return engine->throwTypeError(); return f->call(base, argv, argc); } ReturnedValue Runtime::CallValue::call(ExecutionEngine *engine, const Value &func, Value *argv, int argc) { if (!func.isFunctionObject()) return engine->throwTypeError(QStringLiteral("%1 is not a function").arg(func.toQStringNoThrow())); Value undef = Value::undefinedValue(); return static_cast(func).call(&undef, argv, argc); } ReturnedValue Runtime::CallWithReceiver::call(ExecutionEngine *engine, const Value &func, const Value &thisObject, Value argv[], int argc) { if (!func.isFunctionObject()) return engine->throwTypeError(QStringLiteral("%1 is not a function").arg(func.toQStringNoThrow())); return static_cast(func).call(&thisObject, argv, argc); } struct CallArgs { Value *argv; int argc; }; static CallArgs createSpreadArguments(Scope &scope, Value *argv, int argc) { ScopedValue it(scope); ScopedValue done(scope); int argCount = 0; Value *v = scope.alloc(); Value *arguments = v; for (int i = 0; i < argc; ++i) { if (!argv[i].isEmpty()) { *v = argv[i]; ++argCount; v = scope.alloc(); continue; } // spread element ++i; it = Runtime::GetIterator::call(scope.engine, argv[i], /* ForInIterator */ 1); if (scope.engine->hasException) return { nullptr, 0 }; while (1) { done = Runtime::IteratorNext::call(scope.engine, it, v); if (scope.engine->hasException) return { nullptr, 0 }; Q_ASSERT(done->isBoolean()); if (done->booleanValue()) break; ++argCount; v = scope.alloc(); } } return { arguments, argCount }; } ReturnedValue Runtime::CallWithSpread::call(ExecutionEngine *engine, const Value &function, const Value &thisObject, Value *argv, int argc) { Q_ASSERT(argc >= 1); if (!function.isFunctionObject()) return engine->throwTypeError(); Scope scope(engine); CallArgs arguments = createSpreadArguments(scope, argv, argc); if (engine->hasException) return Encode::undefined(); return static_cast(function).call(&thisObject, arguments.argv, arguments.argc); } ReturnedValue Runtime::Construct::call(ExecutionEngine *engine, const Value &function, const Value &newTarget, Value *argv, int argc) { if (!function.isFunctionObject()) return engine->throwTypeError(); return static_cast(function).callAsConstructor(argv, argc, &newTarget); } ReturnedValue Runtime::ConstructWithSpread::call(ExecutionEngine *engine, const Value &function, const Value &newTarget, Value *argv, int argc) { if (!function.isFunctionObject()) return engine->throwTypeError(); Scope scope(engine); CallArgs arguments = createSpreadArguments(scope, argv, argc); if (engine->hasException) return Encode::undefined(); return static_cast(function).callAsConstructor(arguments.argv, arguments.argc, &newTarget); } ReturnedValue Runtime::TailCall::call(CppStackFrame *frame, ExecutionEngine *engine) { // IMPORTANT! The JIT assumes that this method has the same amount (or less) arguments than // the jitted function, so it can safely do a tail call. Value *tos = engine->jsStackTop; const Value &function = tos[StackOffsets::tailCall_function]; const Value &thisObject = tos[StackOffsets::tailCall_thisObject]; Value *argv = reinterpret_cast(frame->jsFrame) + tos[StackOffsets::tailCall_argv].int_32(); int argc = tos[StackOffsets::tailCall_argc].int_32(); Q_ASSERT(argc >= 0); if (!function.isFunctionObject()) return engine->throwTypeError(); const FunctionObject &fo = static_cast(function); if (!frame->callerCanHandleTailCall || !fo.canBeTailCalled() || engine->debugger() || unsigned(argc) > fo.formalParameterCount()) { // Cannot tailcall, do a normal call: return fo.call(&thisObject, argv, argc); } memcpy(frame->jsFrame->args, argv, argc * sizeof(Value)); frame->init(engine, fo.function(), frame->jsFrame->args, argc, frame->callerCanHandleTailCall); frame->setupJSFrame(frame->savedStackTop, fo, fo.scope(), thisObject, Primitive::undefinedValue()); engine->jsStackTop = frame->savedStackTop + frame->requiredJSStackFrameSize(); frame->pendingTailCall = true; return Encode::undefined(); } void Runtime::ThrowException::call(ExecutionEngine *engine, const Value &value) { if (!value.isEmpty()) engine->throwError(value); } ReturnedValue Runtime::TypeofValue::call(ExecutionEngine *engine, const Value &value) { Scope scope(engine); ScopedString res(scope); switch (value.type()) { case Value::Undefined_Type: res = engine->id_undefined(); break; case Value::Null_Type: res = engine->id_object(); break; case Value::Boolean_Type: res = engine->id_boolean(); break; case Value::Managed_Type: if (value.isString()) res = engine->id_string(); else if (value.isSymbol()) res = engine->id_symbol(); else if (value.objectValue()->as()) res = engine->id_function(); else res = engine->id_object(); // ### implementation-defined break; default: res = engine->id_number(); break; } return res.asReturnedValue(); } QV4::ReturnedValue Runtime::TypeofName::call(ExecutionEngine *engine, int nameIndex) { Scope scope(engine); ScopedString name(scope, engine->currentStackFrame->v4Function->compilationUnit->runtimeStrings[nameIndex]); ScopedValue prop(scope, static_cast(engine->currentStackFrame->jsFrame->context).getProperty(name)); // typeof doesn't throw. clear any possible exception scope.engine->hasException = false; return TypeofValue::call(engine, prop); } void Runtime::PushCallContext::call(CppStackFrame *frame) { frame->jsFrame->context = ExecutionContext::newCallContext(frame)->asReturnedValue(); } ReturnedValue Runtime::PushWithContext::call(ExecutionEngine *engine, const Value &acc) { CallData *jsFrame = engine->currentStackFrame->jsFrame; Value &newAcc = jsFrame->accumulator; newAcc = Value::fromHeapObject(acc.toObject(engine)); if (!engine->hasException) { Q_ASSERT(newAcc.isObject()); const Object &obj = static_cast(newAcc); Value &context = jsFrame->context; auto ec = static_cast(&context); context = ec->newWithContext(obj.d())->asReturnedValue(); } return newAcc.asReturnedValue(); } void Runtime::PushCatchContext::call(ExecutionEngine *engine, int blockIndex, int exceptionVarNameIndex) { auto name = engine->currentStackFrame->v4Function->compilationUnit->runtimeStrings[exceptionVarNameIndex]; engine->currentStackFrame->jsFrame->context = ExecutionContext::newCatchContext(engine->currentStackFrame, blockIndex, name)->asReturnedValue(); } void Runtime::PushBlockContext::call(ExecutionEngine *engine, int index) { engine->currentStackFrame->jsFrame->context = ExecutionContext::newBlockContext(engine->currentStackFrame, index)->asReturnedValue(); } void Runtime::CloneBlockContext::call(ExecutionEngine *engine) { auto frame = engine->currentStackFrame; auto context = static_cast(frame->jsFrame->context.m()); frame->jsFrame->context = ExecutionContext::cloneBlockContext(engine, context)->asReturnedValue(); } void Runtime::PushScriptContext::call(ExecutionEngine *engine, int index) { Q_ASSERT(engine->currentStackFrame->context()->d()->type == Heap::ExecutionContext::Type_GlobalContext || engine->currentStackFrame->context()->d()->type == Heap::ExecutionContext::Type_QmlContext); ReturnedValue c = ExecutionContext::newBlockContext(engine->currentStackFrame, index)->asReturnedValue(); engine->setScriptContext(c); engine->currentStackFrame->jsFrame->context = c; } void Runtime::PopScriptContext::call(ExecutionEngine *engine) { ReturnedValue root = engine->rootContext()->asReturnedValue(); engine->setScriptContext(root); engine->currentStackFrame->jsFrame->context = root; } void Runtime::ThrowReferenceError::call(ExecutionEngine *engine, int nameIndex) { Scope scope(engine); ScopedString name(scope, engine->currentStackFrame->v4Function->compilationUnit->runtimeStrings[nameIndex]); engine->throwReferenceError(name); } void Runtime::ThrowOnNullOrUndefined::call(ExecutionEngine *engine, const Value &v) { if (v.isNullOrUndefined()) engine->throwTypeError(); } ReturnedValue Runtime::ConvertThisToObject::call(ExecutionEngine *engine, const Value &t) { if (!t.isObject()) { if (t.isNullOrUndefined()) { return engine->globalObject->asReturnedValue(); } else { return t.toObject(engine)->asReturnedValue(); } } return t.asReturnedValue(); } void Runtime::DeclareVar::call(ExecutionEngine *engine, Bool deletable, int nameIndex) { Scope scope(engine); ScopedString name(scope, engine->currentStackFrame->v4Function->compilationUnit->runtimeStrings[nameIndex]); static_cast(engine->currentStackFrame->jsFrame->context).createMutableBinding(name, deletable); } ReturnedValue Runtime::ArrayLiteral::call(ExecutionEngine *engine, Value *values, uint length) { return engine->newArrayObject(values, length)->asReturnedValue(); } ReturnedValue Runtime::ObjectLiteral::call(ExecutionEngine *engine, int classId, QV4::Value args[], int argc) { Scope scope(engine); Scoped klass(scope, engine->currentStackFrame->v4Function->compilationUnit->runtimeClasses[classId]); ScopedObject o(scope, engine->newObject(klass->d())); Q_ASSERT(uint(argc) >= klass->d()->size); for (uint i = 0; i < klass->d()->size; ++i) o->setProperty(i, *args++); Q_ASSERT((argc - klass->d()->size) % 3 == 0); int additionalArgs = (argc - int(klass->d()->size))/3; if (!additionalArgs) return o->asReturnedValue(); ScopedPropertyKey name(scope); ScopedProperty pd(scope); ScopedFunctionObject fn(scope); ScopedString fnName(scope); ScopedValue value(scope); for (int i = 0; i < additionalArgs; ++i) { Q_ASSERT(args->isInteger()); ObjectLiteralArgument arg = ObjectLiteralArgument(args->integerValue()); name = args[1].toPropertyKey(engine); value = args[2]; if (engine->hasException) return Encode::undefined(); if (arg != ObjectLiteralArgument::Value) { Q_ASSERT(args[2].isInteger()); int functionId = args[2].integerValue(); QV4::Function *clos = static_cast(engine->currentStackFrame->v4Function->compilationUnit)->runtimeFunctions[functionId]; Q_ASSERT(clos); PropertyKey::FunctionNamePrefix prefix = PropertyKey::None; if (arg == ObjectLiteralArgument::Getter) prefix = PropertyKey::Getter; else if (arg == ObjectLiteralArgument::Setter) prefix = PropertyKey::Setter; else arg = ObjectLiteralArgument::Value; fnName = name->asFunctionName(engine, prefix); ExecutionContext *current = static_cast(&engine->currentStackFrame->jsFrame->context); if (clos->isGenerator()) value = MemberGeneratorFunction::create(current, clos, o, fnName)->asReturnedValue(); else value = FunctionObject::createMemberFunction(current, clos, o, fnName)->asReturnedValue(); } else if (args[2].isFunctionObject()) { fn = static_cast(args[2]); fnName = name->asFunctionName(engine, PropertyKey::None); fn->setName(fnName); } Q_ASSERT(arg != ObjectLiteralArgument::Method); Q_ASSERT(arg == ObjectLiteralArgument::Value || value->isFunctionObject()); if (arg == ObjectLiteralArgument::Value || arg == ObjectLiteralArgument::Getter) { pd->value = value; pd->set = Value::emptyValue(); } else { pd->value = Value::emptyValue(); pd->set = value; } bool ok = o->defineOwnProperty(name, pd, (arg == ObjectLiteralArgument::Value ? Attr_Data : Attr_Accessor)); if (!ok) return engine->throwTypeError(); args += 3; } return o.asReturnedValue(); } ReturnedValue Runtime::CreateClass::call(ExecutionEngine *engine, int classIndex, const Value &superClass, Value computedNames[]) { const CompiledData::CompilationUnit *unit = engine->currentStackFrame->v4Function->compilationUnit; const QV4::CompiledData::Class *cls = unit->unitData()->classAt(classIndex); Scope scope(engine); ScopedObject protoParent(scope, engine->objectPrototype()); ScopedObject constructorParent(scope, engine->functionPrototype()); if (!superClass.isEmpty()) { if (superClass.isNull()) { protoParent = Encode::null(); } else { const FunctionObject *superFunction = superClass.as(); // ### check that the heritage object is a constructor if (!superFunction || !superFunction->isConstructor()) return engine->throwTypeError(QStringLiteral("The superclass is not a function object.")); const FunctionObject *s = static_cast(&superClass); ScopedValue result(scope, s->get(scope.engine->id_prototype())); if (!result->isObject() && !result->isNull()) return engine->throwTypeError(QStringLiteral("The value of the superclass's prototype property is not an object.")); protoParent = *result; constructorParent = superClass; } } ScopedObject proto(scope, engine->newObject()); proto->setPrototypeUnchecked(protoParent); ExecutionContext *current = static_cast(&engine->currentStackFrame->jsFrame->context); ScopedFunctionObject constructor(scope); QV4::Function *f = cls->constructorFunction != UINT_MAX ? unit->runtimeFunctions[cls->constructorFunction] : nullptr; constructor = FunctionObject::createConstructorFunction(current, f, proto, !superClass.isEmpty())->asReturnedValue(); constructor->setPrototypeUnchecked(constructorParent); Value argCount = Value::fromInt32(f ? f->nFormals : 0); constructor->defineReadonlyConfigurableProperty(scope.engine->id_length(), argCount); constructor->defineReadonlyConfigurableProperty(engine->id_prototype(), proto); proto->defineDefaultProperty(engine->id_constructor(), constructor); ScopedString name(scope); if (cls->nameIndex != UINT_MAX) { name = unit->runtimeStrings[cls->nameIndex]; constructor->defineReadonlyConfigurableProperty(engine->id_name(), name); } ScopedObject receiver(scope, *constructor); ScopedPropertyKey propertyName(scope); ScopedFunctionObject function(scope); ScopedProperty property(scope); const CompiledData::Method *methods = cls->methodTable(); for (uint i = 0; i < cls->nStaticMethods + cls->nMethods; ++i) { if (i == cls->nStaticMethods) receiver = proto; if (methods[i].name == UINT_MAX) { propertyName = computedNames->toPropertyKey(engine); if (propertyName == scope.engine->id_prototype()->propertyKey() && receiver->d() == constructor->d()) return engine->throwTypeError(QStringLiteral("Cannot declare a static method named 'prototype'.")); if (engine->hasException) return Encode::undefined(); ++computedNames; } else { name = unit->runtimeStrings[methods[i].name]; propertyName = name->toPropertyKey(); } QV4::Function *f = unit->runtimeFunctions[methods[i].function]; Q_ASSERT(f); PropertyKey::FunctionNamePrefix prefix = PropertyKey::None; if (methods[i].type == CompiledData::Method::Getter) prefix = PropertyKey::Getter; else if (methods[i].type == CompiledData::Method::Setter) prefix = PropertyKey::Setter; name = propertyName->asFunctionName(engine, prefix); if (f->isGenerator()) function = MemberGeneratorFunction::create(current, f, receiver, name); else function = FunctionObject::createMemberFunction(current, f, receiver, name); Q_ASSERT(function); PropertyAttributes attributes; switch (methods[i].type) { case CompiledData::Method::Getter: property->setGetter(function); property->set = Value::emptyValue(); attributes = Attr_Accessor|Attr_NotEnumerable; break; case CompiledData::Method::Setter: property->value = Value::emptyValue(); property->setSetter(function); attributes = Attr_Accessor|Attr_NotEnumerable; break; default: // Regular property->value = function; property->set = Value::emptyValue(); attributes = Attr_Data|Attr_NotEnumerable; break; } receiver->defineOwnProperty(propertyName, property, attributes); } return constructor->asReturnedValue(); } QV4::ReturnedValue Runtime::CreateMappedArgumentsObject::call(ExecutionEngine *engine) { Q_ASSERT(engine->currentContext()->d()->type == Heap::ExecutionContext::Type_CallContext); Heap::InternalClass *ic = engine->internalClasses(EngineBase::Class_ArgumentsObject); return engine->memoryManager->allocObject(ic, engine->currentStackFrame)->asReturnedValue(); } QV4::ReturnedValue Runtime::CreateUnmappedArgumentsObject::call(ExecutionEngine *engine) { Heap::InternalClass *ic = engine->internalClasses(EngineBase::Class_StrictArgumentsObject); return engine->memoryManager->allocObject(ic, engine->currentStackFrame)->asReturnedValue(); } QV4::ReturnedValue Runtime::CreateRestParameter::call(ExecutionEngine *engine, int argIndex) { const Value *values = engine->currentStackFrame->originalArguments + argIndex; int nValues = engine->currentStackFrame->originalArgumentsCount - argIndex; if (nValues <= 0) return engine->newArrayObject(0)->asReturnedValue(); return engine->newArrayObject(values, nValues)->asReturnedValue(); } ReturnedValue Runtime::RegexpLiteral::call(ExecutionEngine *engine, int id) { Heap::RegExpObject *ro = engine->newRegExpObject(engine->currentStackFrame->v4Function->compilationUnit->runtimeRegularExpressions[id].as()); return ro->asReturnedValue(); } ReturnedValue Runtime::ToObject::call(ExecutionEngine *engine, const Value &obj) { if (obj.isObject()) return obj.asReturnedValue(); return obj.toObject(engine)->asReturnedValue(); } Bool Runtime::ToBoolean::call(const Value &obj) { return obj.toBoolean(); } ReturnedValue Runtime::ToNumber::call(ExecutionEngine *, const Value &v) { return Encode(v.toNumber()); } #endif // V4_BOOTSTRAP ReturnedValue Runtime::UMinus::call(const Value &value) { TRACE1(value); // +0 != -0, so we need to convert to double when negating 0 if (value.isInteger() && value.integerValue() && value.integerValue() != std::numeric_limits::min()) return Encode(-value.integerValue()); else { double n = RuntimeHelpers::toNumber(value); return Encode(-n); } } // binary operators #ifndef V4_BOOTSTRAP ReturnedValue Runtime::Add::call(ExecutionEngine *engine, const Value &left, const Value &right) { TRACE2(left, right); if (Q_LIKELY(left.integerCompatible() && right.integerCompatible())) return add_int32(left.integerValue(), right.integerValue()); if (left.isNumber() && right.isNumber()) return Value::fromDouble(left.asDouble() + right.asDouble()).asReturnedValue(); return RuntimeHelpers::addHelper(engine, left, right); } ReturnedValue Runtime::Sub::call(const Value &left, const Value &right) { TRACE2(left, right); if (Q_LIKELY(left.integerCompatible() && right.integerCompatible())) return sub_int32(left.integerValue(), right.integerValue()); double lval = left.isNumber() ? left.asDouble() : left.toNumberImpl(); double rval = right.isNumber() ? right.asDouble() : right.toNumberImpl(); return Value::fromDouble(lval - rval).asReturnedValue(); } ReturnedValue Runtime::Mul::call(const Value &left, const Value &right) { TRACE2(left, right); if (Q_LIKELY(left.integerCompatible() && right.integerCompatible())) return mul_int32(left.integerValue(), right.integerValue()); double lval = left.isNumber() ? left.asDouble() : left.toNumberImpl(); double rval = right.isNumber() ? right.asDouble() : right.toNumberImpl(); return Value::fromDouble(lval * rval).asReturnedValue(); } ReturnedValue Runtime::Div::call(const Value &left, const Value &right) { TRACE2(left, right); if (Value::integerCompatible(left, right)) { int lval = left.integerValue(); int rval = right.integerValue(); if (rval != 0 // division by zero should result in a NaN && !(lval == std::numeric_limits::min() && rval == -1) // doesn't fit in int && (lval % rval == 0) // fractions can't be stored in an int && !(lval == 0 && rval < 0)) // 0 / -something results in -0.0 return Encode(int(lval / rval)); else return Encode(double(lval) / rval); } double lval = left.toNumber(); double rval = right.toNumber(); return Value::fromDouble(lval / rval).asReturnedValue(); } ReturnedValue Runtime::Mod::call(const Value &left, const Value &right) { TRACE2(left, right); if (Value::integerCompatible(left, right) && left.integerValue() >= 0 && right.integerValue() > 0) { // special cases are handled by fmod, among them: // - arithmic execeptions for ints in c++, eg: INT_MIN % -1 // - undefined behavior in c++, e.g.: anything % 0 // - uncommon cases which would complicate the condition, e.g.: negative integers // (this makes sure that -1 % 1 == -0 by passing it to fmod) return Encode(left.integerValue() % right.integerValue()); } double lval = RuntimeHelpers::toNumber(left); double rval = RuntimeHelpers::toNumber(right); #ifdef fmod # undef fmod #endif return Value::fromDouble(std::fmod(lval, rval)).asReturnedValue(); } ReturnedValue Runtime::Exp::call(const Value &base, const Value &exp) { double b = base.toNumber(); double e = exp.toNumber(); if (qt_is_inf(e) && (b == 1 || b == -1)) return Encode(qt_snan()); return Encode(pow(b,e)); } ReturnedValue Runtime::BitAnd::call(const Value &left, const Value &right) { TRACE2(left, right); int lval = left.toInt32(); int rval = right.toInt32(); return Encode((int)(lval & rval)); } ReturnedValue Runtime::BitOr::call(const Value &left, const Value &right) { TRACE2(left, right); int lval = left.toInt32(); int rval = right.toInt32(); return Encode((int)(lval | rval)); } ReturnedValue Runtime::BitXor::call(const Value &left, const Value &right) { TRACE2(left, right); int lval = left.toInt32(); int rval = right.toInt32(); return Encode((int)(lval ^ rval)); } ReturnedValue Runtime::Shl::call(const Value &left, const Value &right) { TRACE2(left, right); int lval = left.toInt32(); int rval = right.toInt32() & 0x1f; return Encode((int)(lval << rval)); } ReturnedValue Runtime::Shr::call(const Value &left, const Value &right) { TRACE2(left, right); int lval = left.toInt32(); unsigned rval = right.toUInt32() & 0x1f; return Encode((int)(lval >> rval)); } ReturnedValue Runtime::UShr::call(const Value &left, const Value &right) { TRACE2(left, right); unsigned lval = left.toUInt32(); unsigned rval = right.toUInt32() & 0x1f; uint res = lval >> rval; return Encode(res); } #endif // V4_BOOTSTRAP ReturnedValue Runtime::GreaterThan::call(const Value &left, const Value &right) { TRACE2(left, right); bool r = CompareGreaterThan::call(left, right); return Encode(r); } ReturnedValue Runtime::LessThan::call(const Value &left, const Value &right) { TRACE2(left, right); bool r = CompareLessThan::call(left, right); return Encode(r); } ReturnedValue Runtime::GreaterEqual::call(const Value &left, const Value &right) { TRACE2(left, right); bool r = CompareGreaterEqual::call(left, right); return Encode(r); } ReturnedValue Runtime::LessEqual::call(const Value &left, const Value &right) { TRACE2(left, right); bool r = CompareLessEqual::call(left, right); return Encode(r); } struct LazyScope { ExecutionEngine *engine = nullptr; Value *stackMark = nullptr; ~LazyScope() { if (engine) engine->jsStackTop = stackMark; } template void set(Value **scopedValue, T value, ExecutionEngine *e) { if (!engine) { engine = e; stackMark = engine->jsStackTop; } if (!*scopedValue) *scopedValue = e->jsAlloca(1); **scopedValue = value; } }; Bool Runtime::CompareEqual::call(const Value &left, const Value &right) { TRACE2(left, right); Value lhs = left; Value rhs = right; #ifndef V4_BOOTSTRAP LazyScope scope; Value *lhsGuard = nullptr; Value *rhsGuard = nullptr; #endif redo: if (lhs.asReturnedValue() == rhs.asReturnedValue()) return !lhs.isNaN(); int lt = lhs.quickType(); int rt = rhs.quickType(); if (rt < lt) { qSwap(lhs, rhs); qSwap(lt, rt); } switch (lt) { case QV4::Value::QT_ManagedOrUndefined: if (lhs.isUndefined()) return rhs.isNullOrUndefined(); Q_FALLTHROUGH(); case QV4::Value::QT_ManagedOrUndefined1: case QV4::Value::QT_ManagedOrUndefined2: case QV4::Value::QT_ManagedOrUndefined3: // LHS: Managed switch (rt) { case QV4::Value::QT_ManagedOrUndefined: if (rhs.isUndefined()) return false; Q_FALLTHROUGH(); case QV4::Value::QT_ManagedOrUndefined1: case QV4::Value::QT_ManagedOrUndefined2: case QV4::Value::QT_ManagedOrUndefined3: { #ifndef V4_BOOTSTRAP // RHS: Managed Heap::Base *l = lhs.m(); Heap::Base *r = rhs.m(); Q_ASSERT(l); Q_ASSERT(r); if (l->internalClass->vtable->isStringOrSymbol == r->internalClass->vtable->isStringOrSymbol) return static_cast(lhs).isEqualTo(&static_cast(rhs)); if (l->internalClass->vtable->isStringOrSymbol) { scope.set(&rhsGuard, RuntimeHelpers::objectDefaultValue(&static_cast(rhs), PREFERREDTYPE_HINT), r->internalClass->engine); rhs = rhsGuard->asReturnedValue(); break; } else { Q_ASSERT(r->internalClass->vtable->isStringOrSymbol); scope.set(&lhsGuard, RuntimeHelpers::objectDefaultValue(&static_cast(lhs), PREFERREDTYPE_HINT), l->internalClass->engine); lhs = lhsGuard->asReturnedValue(); break; } #endif return false; } case QV4::Value::QT_Empty: Q_UNREACHABLE(); case QV4::Value::QT_Null: return false; case QV4::Value::QT_Bool: case QV4::Value::QT_Int: rhs = Value::fromDouble(rhs.int_32()); // fall through default: // double #ifndef V4_BOOTSTRAP if (lhs.m()->internalClass->vtable->isStringOrSymbol) { return lhs.m()->internalClass->vtable->isString ? (RuntimeHelpers::toNumber(lhs) == rhs.doubleValue()) : false; } else { scope.set(&lhsGuard, RuntimeHelpers::objectDefaultValue(&static_cast(lhs), PREFERREDTYPE_HINT), lhs.m()->internalClass->engine); lhs = lhsGuard->asReturnedValue(); } #else Q_UNIMPLEMENTED(); #endif } goto redo; case QV4::Value::QT_Empty: Q_UNREACHABLE(); case QV4::Value::QT_Null: return rhs.isNull(); case QV4::Value::QT_Bool: case QV4::Value::QT_Int: switch (rt) { case QV4::Value::QT_ManagedOrUndefined: case QV4::Value::QT_ManagedOrUndefined1: case QV4::Value::QT_ManagedOrUndefined2: case QV4::Value::QT_ManagedOrUndefined3: case QV4::Value::QT_Empty: case QV4::Value::QT_Null: Q_UNREACHABLE(); case QV4::Value::QT_Bool: case QV4::Value::QT_Int: return lhs.int_32() == rhs.int_32(); default: // double return lhs.int_32() == rhs.doubleValue(); } default: // double Q_ASSERT(rhs.isDouble()); return lhs.doubleValue() == rhs.doubleValue(); } } ReturnedValue Runtime::Equal::call(const Value &left, const Value &right) { TRACE2(left, right); bool r = CompareEqual::call(left, right); return Encode(r); } ReturnedValue Runtime::NotEqual::call(const Value &left, const Value &right) { TRACE2(left, right); bool r = !CompareEqual::call(left, right); return Encode(r); } ReturnedValue Runtime::StrictEqual::call(const Value &left, const Value &right) { TRACE2(left, right); bool r = RuntimeHelpers::strictEqual(left, right); return Encode(r); } ReturnedValue Runtime::StrictNotEqual::call(const Value &left, const Value &right) { TRACE2(left, right); bool r = ! RuntimeHelpers::strictEqual(left, right); return Encode(r); } Bool Runtime::CompareNotEqual::call(const Value &left, const Value &right) { TRACE2(left, right); return !Runtime::CompareEqual::call(left, right); } Bool Runtime::CompareStrictEqual::call(const Value &left, const Value &right) { TRACE2(left, right); return RuntimeHelpers::strictEqual(left, right); } Bool Runtime::CompareStrictNotEqual::call(const Value &left, const Value &right) { TRACE2(left, right); return ! RuntimeHelpers::strictEqual(left, right); } } // namespace QV4 QT_END_NAMESPACE