https://github.com/mozilla/gecko-dev
Tip revision: af7f01cfce490ee23b821dec5aa43afda7cfb627 authored by tbirdbld on 05 October 2012, 21:06:08 UTC
Added THUNDERBIRD_16_0_RELEASE THUNDERBIRD_16_0_BUILD1 tag(s) for changeset ddb22ac6c03b. DONTBUILD CLOSED TREE a=release
Added THUNDERBIRD_16_0_RELEASE THUNDERBIRD_16_0_BUILD1 tag(s) for changeset ddb22ac6c03b. DONTBUILD CLOSED TREE a=release
Tip revision: af7f01c
jsinterpinlines.h
/* -*- Mode: C; tab-width: 8; indent-tabs-mode: nil; c-basic-offset: 4 -*-
* vim: set ts=4 sw=4 et tw=99:
*
* This Source Code Form is subject to the terms of the Mozilla Public
* License, v. 2.0. If a copy of the MPL was not distributed with this
* file, You can obtain one at http://mozilla.org/MPL/2.0/. */
#ifndef jsinterpinlines_h__
#define jsinterpinlines_h__
#include "jsapi.h"
#include "jsbool.h"
#include "jscompartment.h"
#include "jsinfer.h"
#include "jsinterp.h"
#include "jslibmath.h"
#include "jsnum.h"
#include "jsprobes.h"
#include "jsstr.h"
#include "methodjit/MethodJIT.h"
#include "jsfuninlines.h"
#include "jsinferinlines.h"
#include "jspropertycacheinlines.h"
#include "jstypedarrayinlines.h"
#include "vm/Stack-inl.h"
namespace js {
/*
* Compute the implicit |this| parameter for a call expression where the callee
* funval was resolved from an unqualified name reference to a property on obj
* (an object on the scope chain).
*
* We can avoid computing |this| eagerly and push the implicit callee-coerced
* |this| value, undefined, if any of these conditions hold:
*
* 1. The nominal |this|, obj, is a global object.
*
* 2. The nominal |this|, obj, has one of Block, Call, or DeclEnv class (this
* is what IsCacheableNonGlobalScope tests). Such objects-as-scopes must be
* censored with undefined.
*
* Otherwise, we bind |this| to obj->thisObject(). Only names inside |with|
* statements and embedding-specific scope objects fall into this category.
*
* If the callee is a strict mode function, then code implementing JSOP_THIS
* in the interpreter and JITs will leave undefined as |this|. If funval is a
* function not in strict mode, JSOP_THIS code replaces undefined with funval's
* global.
*
* We set *vp to undefined early to reduce code size and bias this code for the
* common and future-friendly cases.
*/
inline bool
ComputeImplicitThis(JSContext *cx, JSObject *obj, Value *vp)
{
vp->setUndefined();
if (obj->isGlobal())
return true;
if (IsCacheableNonGlobalScope(obj))
return true;
obj = obj->thisObject(cx);
if (!obj)
return false;
vp->setObject(*obj);
return true;
}
inline bool
ComputeThis(JSContext *cx, StackFrame *fp)
{
Value &thisv = fp->thisValue();
if (thisv.isObject())
return true;
if (fp->isFunctionFrame()) {
if (fp->fun()->inStrictMode())
return true;
/*
* Eval function frames have their own |this| slot, which is a copy of the function's
* |this| slot. If we lazily wrap a primitive |this| in an eval function frame, the
* eval's frame will get the wrapper, but the function's frame will not. To prevent
* this, we always wrap a function's |this| before pushing an eval frame, and should
* thus never see an unwrapped primitive in a non-strict eval function frame.
*/
JS_ASSERT(!fp->isEvalFrame());
}
return BoxNonStrictThis(cx, fp->callReceiver());
}
/*
* Every possible consumer of MagicValue(JS_OPTIMIZED_ARGUMENTS) (as determined
* by ScriptAnalysis::needsArgsObj) must check for these magic values and, when
* one is received, act as if the value were the function's ArgumentsObject.
* Additionally, it is possible that, after 'arguments' was copied into a
* temporary, the arguments object has been created a some other failed guard
* that called JSScript::argumentsOptimizationFailed. In this case, it is
* always valid (and necessary) to replace JS_OPTIMIZED_ARGUMENTS with the real
* arguments object.
*/
static inline bool
IsOptimizedArguments(StackFrame *fp, Value *vp)
{
if (vp->isMagic(JS_OPTIMIZED_ARGUMENTS) && fp->script()->needsArgsObj())
*vp = ObjectValue(fp->argsObj());
return vp->isMagic(JS_OPTIMIZED_ARGUMENTS);
}
/*
* One optimized consumer of MagicValue(JS_OPTIMIZED_ARGUMENTS) is f.apply.
* However, this speculation must be guarded before calling 'apply' in case it
* is not the builtin Function.prototype.apply.
*/
static inline bool
GuardFunApplyArgumentsOptimization(JSContext *cx)
{
FrameRegs ®s = cx->regs();
if (IsOptimizedArguments(regs.fp(), ®s.sp[-1])) {
CallArgs args = CallArgsFromSp(GET_ARGC(regs.pc), regs.sp);
if (!IsNativeFunction(args.calleev(), js_fun_apply)) {
if (!JSScript::argumentsOptimizationFailed(cx, regs.fp()->script()))
return false;
regs.sp[-1] = ObjectValue(regs.fp()->argsObj());
}
}
return true;
}
/*
* Return an object on which we should look for the properties of |value|.
* This helps us implement the custom [[Get]] method that ES5's GetValue
* algorithm uses for primitive values, without actually constructing the
* temporary object that the specification does.
*
* For objects, return the object itself. For string, boolean, and number
* primitive values, return the appropriate constructor's prototype. For
* undefined and null, throw an error and return NULL, attributing the
* problem to the value at |spindex| on the stack.
*/
JS_ALWAYS_INLINE JSObject *
ValuePropertyBearer(JSContext *cx, StackFrame *fp, const Value &v, int spindex)
{
if (v.isObject())
return &v.toObject();
GlobalObject &global = fp->global();
if (v.isString())
return global.getOrCreateStringPrototype(cx);
if (v.isNumber())
return global.getOrCreateNumberPrototype(cx);
if (v.isBoolean())
return global.getOrCreateBooleanPrototype(cx);
JS_ASSERT(v.isNull() || v.isUndefined());
js_ReportIsNullOrUndefined(cx, spindex, v, NULL);
return NULL;
}
inline bool
NativeGet(JSContext *cx, Handle<JSObject*> obj, Handle<JSObject*> pobj, Shape *shape,
unsigned getHow, Value *vp)
{
if (shape->isDataDescriptor() && shape->hasDefaultGetter()) {
/* Fast path for Object instance properties. */
JS_ASSERT(shape->hasSlot());
*vp = pobj->nativeGetSlot(shape->slot());
} else {
if (!js_NativeGet(cx, obj, pobj, shape, getHow, vp))
return false;
}
return true;
}
#if defined(DEBUG) && !defined(JS_THREADSAFE) && !defined(JSGC_ROOT_ANALYSIS)
extern void
AssertValidPropertyCacheHit(JSContext *cx, JSObject *start, JSObject *found,
PropertyCacheEntry *entry);
#else
inline void
AssertValidPropertyCacheHit(JSContext *cx, JSObject *start, JSObject *found,
PropertyCacheEntry *entry)
{}
#endif
inline bool
GetPropertyGenericMaybeCallXML(JSContext *cx, JSOp op, HandleObject obj, HandleId id, Value *vp)
{
/*
* Various XML properties behave differently when accessed in a
* call vs. normal context, and getGeneric will not work right.
*/
#if JS_HAS_XML_SUPPORT
if (op == JSOP_CALLPROP && obj->isXML())
return js_GetXMLMethod(cx, obj, id, vp);
#endif
return obj->getGeneric(cx, id, vp);
}
inline bool
GetPropertyOperation(JSContext *cx, JSScript *script, jsbytecode *pc, Value &lval, Value *vp)
{
JS_ASSERT(vp != &lval);
JSOp op = JSOp(*pc);
if (op == JSOP_LENGTH) {
/* Optimize length accesses on strings, arrays, and arguments. */
if (lval.isString()) {
*vp = Int32Value(lval.toString()->length());
return true;
}
if (IsOptimizedArguments(cx->fp(), &lval)) {
*vp = Int32Value(cx->fp()->numActualArgs());
return true;
}
if (lval.isObject()) {
JSObject *obj = &lval.toObject();
if (obj->isArray()) {
uint32_t length = obj->getArrayLength();
*vp = NumberValue(length);
return true;
}
if (obj->isArguments()) {
ArgumentsObject *argsobj = &obj->asArguments();
if (!argsobj->hasOverriddenLength()) {
uint32_t length = argsobj->initialLength();
JS_ASSERT(length < INT32_MAX);
*vp = Int32Value(int32_t(length));
return true;
}
}
if (obj->isTypedArray()) {
*vp = Int32Value(TypedArray::length(obj));
return true;
}
}
}
RootedObject obj(cx, ValueToObject(cx, lval));
if (!obj)
return false;
PropertyCacheEntry *entry;
Rooted<JSObject*> obj2(cx);
PropertyName *name;
JS_PROPERTY_CACHE(cx).test(cx, pc, obj.get(), obj2.get(), entry, name);
if (!name) {
AssertValidPropertyCacheHit(cx, obj, obj2, entry);
if (!NativeGet(cx, obj, obj2, entry->prop, JSGET_CACHE_RESULT, vp))
return false;
return true;
}
RootedId id(cx, NameToId(name));
if (obj->getOps()->getProperty) {
if (!GetPropertyGenericMaybeCallXML(cx, op, obj, id, vp))
return false;
} else {
if (!GetPropertyHelper(cx, obj, id, JSGET_CACHE_RESULT, vp))
return false;
}
#if JS_HAS_NO_SUCH_METHOD
if (op == JSOP_CALLPROP &&
JS_UNLIKELY(vp->isPrimitive()) &&
lval.isObject())
{
if (!OnUnknownMethod(cx, obj, IdToValue(id), vp))
return false;
}
#endif
return true;
}
inline bool
SetPropertyOperation(JSContext *cx, jsbytecode *pc, const Value &lval, const Value &rval)
{
RootedObject obj(cx, ValueToObject(cx, lval));
if (!obj)
return false;
JS_ASSERT_IF(*pc == JSOP_SETNAME || *pc == JSOP_SETGNAME, lval.isObject());
JS_ASSERT_IF(*pc == JSOP_SETGNAME, obj == &cx->fp()->global());
PropertyCacheEntry *entry;
JSObject *obj2;
PropertyName *name;
if (JS_PROPERTY_CACHE(cx).testForSet(cx, pc, obj, &entry, &obj2, &name)) {
/*
* Property cache hit, only partially confirmed by testForSet. We
* know that the entry applies to regs.pc and that obj's shape
* matches.
*
* The entry predicts a set either an existing "own" property, or
* on a prototype property that has a setter.
*/
Shape *shape = entry->prop;
JS_ASSERT_IF(shape->isDataDescriptor(), shape->writable());
JS_ASSERT_IF(shape->hasSlot(), entry->isOwnPropertyHit());
if (entry->isOwnPropertyHit() ||
((obj2 = obj->getProto()) && obj2->lastProperty() == entry->pshape)) {
#ifdef DEBUG
if (entry->isOwnPropertyHit()) {
JS_ASSERT(obj->nativeLookupNoAllocation(shape->propid()) == shape);
} else {
JS_ASSERT(obj2->nativeLookupNoAllocation(shape->propid()) == shape);
JS_ASSERT(entry->isPrototypePropertyHit());
JS_ASSERT(entry->kshape != entry->pshape);
JS_ASSERT(!shape->hasSlot());
}
#endif
if (shape->hasDefaultSetter() && shape->hasSlot()) {
/* Fast path for, e.g., plain Object instance properties. */
obj->nativeSetSlotWithType(cx, shape, rval);
} else {
RootedValue rref(cx, rval);
bool strict = cx->stack.currentScript()->strictModeCode;
if (!js_NativeSet(cx, obj, obj, shape, false, strict, rref.address()))
return false;
}
return true;
}
GET_NAME_FROM_BYTECODE(cx->stack.currentScript(), pc, 0, name);
}
bool strict = cx->stack.currentScript()->strictModeCode;
RootedValue rref(cx, rval);
JSOp op = JSOp(*pc);
RootedId id(cx, NameToId(name));
if (JS_LIKELY(!obj->getOps()->setProperty)) {
unsigned defineHow = (op == JSOP_SETNAME)
? DNP_CACHE_RESULT | DNP_UNQUALIFIED
: DNP_CACHE_RESULT;
if (!baseops::SetPropertyHelper(cx, obj, obj, id, defineHow, rref.address(), strict))
return false;
} else {
if (!obj->setGeneric(cx, obj, id, rref.address(), strict))
return false;
}
return true;
}
inline bool
NameOperation(JSContext *cx, JSScript *script, jsbytecode *pc, Value *vp)
{
RootedObject obj(cx, cx->stack.currentScriptedScopeChain());
/*
* Skip along the scope chain to the enclosing global object. This is
* used for GNAME opcodes where the bytecode emitter has determined a
* name access must be on the global. It also insulates us from bugs
* in the emitter: type inference will assume that GNAME opcodes are
* accessing the global object, and the inferred behavior should match
* the actual behavior even if the id could be found on the scope chain
* before the global object.
*/
if (js_CodeSpec[*pc].format & JOF_GNAME)
obj = &obj->global();
PropertyCacheEntry *entry;
Rooted<JSObject*> obj2(cx);
RootedPropertyName name(cx);
JS_PROPERTY_CACHE(cx).test(cx, pc, obj.get(), obj2.get(), entry, name.get());
if (!name) {
AssertValidPropertyCacheHit(cx, obj, obj2, entry);
if (!NativeGet(cx, obj, obj2, entry->prop, 0, vp))
return false;
return true;
}
RootedShape shape(cx);
if (!FindPropertyHelper(cx, name, true, obj, &obj, &obj2, &shape))
return false;
if (!shape) {
/* Kludge to allow (typeof foo == "undefined") tests. */
JSOp op2 = JSOp(pc[JSOP_NAME_LENGTH]);
if (op2 == JSOP_TYPEOF) {
vp->setUndefined();
return true;
}
JSAutoByteString printable;
if (js_AtomToPrintableString(cx, name, &printable))
js_ReportIsNotDefined(cx, printable.ptr());
return false;
}
/* Take the slow path if shape was not found in a native object. */
if (!obj->isNative() || !obj2->isNative()) {
Rooted<jsid> id(cx, NameToId(name));
if (!obj->getGeneric(cx, id, vp))
return false;
} else {
Rooted<JSObject*> normalized(cx, obj);
if (normalized->getClass() == &WithClass && !shape->hasDefaultGetter())
normalized = &normalized->asWith().object();
if (!NativeGet(cx, normalized, obj2, shape, 0, vp))
return false;
}
return true;
}
inline bool
DefVarOrConstOperation(JSContext *cx, HandleObject varobj, HandlePropertyName dn, unsigned attrs)
{
JS_ASSERT(varobj->isVarObj());
JS_ASSERT(!varobj->getOps()->defineProperty || varobj->isDebugScope());
RootedShape prop(cx);
RootedObject obj2(cx);
if (!varobj->lookupProperty(cx, dn, &obj2, &prop))
return false;
/* Steps 8c, 8d. */
if (!prop || (obj2 != varobj && varobj->isGlobal())) {
if (!varobj->defineProperty(cx, dn, UndefinedValue(), JS_PropertyStub,
JS_StrictPropertyStub, attrs)) {
return false;
}
} else {
/*
* Extension: ordinarily we'd be done here -- but for |const|. If we
* see a redeclaration that's |const|, we consider it a conflict.
*/
unsigned oldAttrs;
if (!varobj->getPropertyAttributes(cx, dn, &oldAttrs))
return false;
if (attrs & JSPROP_READONLY) {
JSAutoByteString bytes;
if (js_AtomToPrintableString(cx, dn, &bytes)) {
JS_ALWAYS_FALSE(JS_ReportErrorFlagsAndNumber(cx, JSREPORT_ERROR,
js_GetErrorMessage,
NULL, JSMSG_REDECLARED_VAR,
(oldAttrs & JSPROP_READONLY)
? "const"
: "var",
bytes.ptr()));
}
return false;
}
}
return true;
}
inline void
InterpreterFrames::enableInterruptsIfRunning(JSScript *script)
{
if (script == regs->fp()->script())
enabler.enableInterrupts();
}
static JS_ALWAYS_INLINE bool
AddOperation(JSContext *cx, const Value &lhs, const Value &rhs, Value *res)
{
if (lhs.isInt32() && rhs.isInt32()) {
int32_t l = lhs.toInt32(), r = rhs.toInt32();
int32_t sum = l + r;
if (JS_UNLIKELY(bool((l ^ sum) & (r ^ sum) & 0x80000000))) {
res->setDouble(double(l) + double(r));
types::TypeScript::MonitorOverflow(cx);
} else {
res->setInt32(sum);
}
} else
#if JS_HAS_XML_SUPPORT
if (IsXML(lhs) && IsXML(rhs)) {
if (!js_ConcatenateXML(cx, &lhs.toObject(), &rhs.toObject(), res))
return false;
types::TypeScript::MonitorUnknown(cx);
} else
#endif
{
RootedValue lval_(cx, lhs);
RootedValue rval_(cx, rhs);
Value &lval = lval_.get();
Value &rval = rval_.get();
/*
* If either operand is an object, any non-integer result must be
* reported to inference.
*/
bool lIsObject = lval.isObject(), rIsObject = rval.isObject();
if (!ToPrimitive(cx, &lval))
return false;
if (!ToPrimitive(cx, &rval))
return false;
bool lIsString, rIsString;
if ((lIsString = lval.isString()) | (rIsString = rval.isString())) {
RootedString lstr(cx), rstr(cx);
if (lIsString) {
lstr = lval.toString();
} else {
lstr = ToString(cx, lval);
if (!lstr)
return false;
}
if (rIsString) {
rstr = rval.toString();
} else {
rstr = ToString(cx, rval);
if (!rstr)
return false;
}
JSString *str = js_ConcatStrings(cx, lstr, rstr);
if (!str)
return false;
if (lIsObject || rIsObject)
types::TypeScript::MonitorString(cx);
res->setString(str);
} else {
double l, r;
if (!ToNumber(cx, lval, &l) || !ToNumber(cx, rval, &r))
return false;
l += r;
if (!res->setNumber(l) &&
(lIsObject || rIsObject || (!lval.isDouble() && !rval.isDouble()))) {
types::TypeScript::MonitorOverflow(cx);
}
}
}
return true;
}
static JS_ALWAYS_INLINE bool
SubOperation(JSContext *cx, HandleValue lhs, HandleValue rhs, Value *res)
{
double d1, d2;
if (!ToNumber(cx, lhs, &d1) || !ToNumber(cx, rhs, &d2))
return false;
double d = d1 - d2;
if (!res->setNumber(d) && !(lhs.isDouble() || rhs.isDouble()))
types::TypeScript::MonitorOverflow(cx);
return true;
}
static JS_ALWAYS_INLINE bool
MulOperation(JSContext *cx, HandleValue lhs, HandleValue rhs, Value *res)
{
double d1, d2;
if (!ToNumber(cx, lhs, &d1) || !ToNumber(cx, rhs, &d2))
return false;
double d = d1 * d2;
if (!res->setNumber(d) && !(lhs.isDouble() || rhs.isDouble()))
types::TypeScript::MonitorOverflow(cx);
return true;
}
static JS_ALWAYS_INLINE bool
DivOperation(JSContext *cx, HandleValue lhs, HandleValue rhs, Value *res)
{
double d1, d2;
if (!ToNumber(cx, lhs, &d1) || !ToNumber(cx, rhs, &d2))
return false;
res->setNumber(NumberDiv(d1, d2));
if (d2 == 0 || (res->isDouble() && !(lhs.isDouble() || rhs.isDouble())))
types::TypeScript::MonitorOverflow(cx);
return true;
}
static JS_ALWAYS_INLINE bool
ModOperation(JSContext *cx, HandleValue lhs, HandleValue rhs, Value *res)
{
int32_t l, r;
if (lhs.isInt32() && rhs.isInt32() &&
(l = lhs.toInt32()) >= 0 && (r = rhs.toInt32()) > 0) {
int32_t mod = l % r;
res->setInt32(mod);
return true;
}
double d1, d2;
if (!ToNumber(cx, lhs, &d1) || !ToNumber(cx, rhs, &d2))
return false;
if (d2 == 0)
res->setDouble(js_NaN);
else
res->setDouble(js_fmod(d1, d2));
types::TypeScript::MonitorOverflow(cx);
return true;
}
static inline bool
FetchElementId(JSContext *cx, JSObject *obj, const Value &idval, jsid *idp, Value *vp)
{
int32_t i_;
if (ValueFitsInInt32(idval, &i_) && INT_FITS_IN_JSID(i_)) {
*idp = INT_TO_JSID(i_);
return true;
}
return !!InternNonIntElementId(cx, obj, idval, idp, vp);
}
static JS_ALWAYS_INLINE bool
ToIdOperation(JSContext *cx, const Value &objval, const Value &idval, Value *res)
{
if (idval.isInt32()) {
*res = idval;
return true;
}
JSObject *obj = ValueToObject(cx, objval);
if (!obj)
return false;
jsid dummy;
if (!InternNonIntElementId(cx, obj, idval, &dummy, res))
return false;
if (!res->isInt32())
types::TypeScript::MonitorUnknown(cx);
return true;
}
static JS_ALWAYS_INLINE bool
GetObjectElementOperation(JSContext *cx, JSOp op, HandleObject obj, const Value &rref, Value *res)
{
#if JS_HAS_XML_SUPPORT
if (op == JSOP_CALLELEM && JS_UNLIKELY(obj->isXML())) {
jsid id;
if (!FetchElementId(cx, obj, rref, &id, res))
return false;
return js_GetXMLMethod(cx, obj, id, res);
}
#endif
uint32_t index;
if (IsDefinitelyIndex(rref, &index)) {
do {
if (obj->isDenseArray()) {
if (index < obj->getDenseArrayInitializedLength()) {
*res = obj->getDenseArrayElement(index);
if (!res->isMagic())
break;
}
} else if (obj->isArguments()) {
if (obj->asArguments().maybeGetElement(index, res))
break;
}
if (!obj->getElement(cx, index, res))
return false;
} while(0);
} else {
JSScript *script;
jsbytecode *pc;
types::TypeScript::GetPcScript(cx, &script, &pc);
if (script->hasAnalysis())
script->analysis()->getCode(pc).getStringElement = true;
SpecialId special;
*res = rref;
if (ValueIsSpecial(obj, res, &special, cx)) {
if (!obj->getSpecial(cx, obj, special, res))
return false;
} else {
JSAtom *name = ToAtom(cx, *res);
if (!name)
return false;
if (name->isIndex(&index)) {
if (!obj->getElement(cx, index, res))
return false;
} else {
if (!obj->getProperty(cx, name->asPropertyName(), res))
return false;
}
}
}
assertSameCompartment(cx, *res);
return true;
}
static JS_ALWAYS_INLINE bool
GetElementOperation(JSContext *cx, JSOp op, Value &lref, const Value &rref, Value *res)
{
JS_ASSERT(op == JSOP_GETELEM || op == JSOP_CALLELEM);
if (lref.isString() && rref.isInt32()) {
JSString *str = lref.toString();
int32_t i = rref.toInt32();
if (size_t(i) < str->length()) {
str = cx->runtime->staticStrings.getUnitStringForElement(cx, str, size_t(i));
if (!str)
return false;
res->setString(str);
return true;
}
}
StackFrame *fp = cx->fp();
if (IsOptimizedArguments(fp, &lref)) {
if (rref.isInt32()) {
int32_t i = rref.toInt32();
if (i >= 0 && uint32_t(i) < fp->numActualArgs()) {
*res = fp->unaliasedActual(i);
return true;
}
}
if (!JSScript::argumentsOptimizationFailed(cx, fp->script()))
return false;
lref = ObjectValue(fp->argsObj());
}
bool isObject = lref.isObject();
RootedObject obj(cx, ValueToObject(cx, lref));
if (!obj)
return false;
if (!GetObjectElementOperation(cx, op, obj, rref, res))
return false;
#if JS_HAS_NO_SUCH_METHOD
if (op == JSOP_CALLELEM && JS_UNLIKELY(res->isPrimitive()) && isObject) {
if (!OnUnknownMethod(cx, obj, rref, res))
return false;
}
#endif
return true;
}
static JS_ALWAYS_INLINE bool
SetObjectElementOperation(JSContext *cx, Handle<JSObject*> obj, HandleId id, const Value &value, bool strict)
{
types::TypeScript::MonitorAssign(cx, obj, id);
do {
if (obj->isDenseArray() && JSID_IS_INT(id)) {
uint32_t length = obj->getDenseArrayInitializedLength();
int32_t i = JSID_TO_INT(id);
if ((uint32_t)i < length) {
if (obj->getDenseArrayElement(i).isMagic(JS_ARRAY_HOLE)) {
if (js_PrototypeHasIndexedProperties(cx, obj))
break;
if ((uint32_t)i >= obj->getArrayLength())
obj->setArrayLength(cx, i + 1);
}
obj->setDenseArrayElementWithType(cx, i, value);
return true;
} else {
JSScript *script;
jsbytecode *pc;
types::TypeScript::GetPcScript(cx, &script, &pc);
if (script->hasAnalysis())
script->analysis()->getCode(pc).arrayWriteHole = true;
}
}
} while (0);
RootedValue tmp(cx, value);
return obj->setGeneric(cx, obj, id, tmp.address(), strict);
}
#define RELATIONAL_OP(OP) \
JS_BEGIN_MACRO \
RootedValue lvalRoot(cx, lhs), rvalRoot(cx, rhs); \
Value &lval = lvalRoot.get(); \
Value &rval = rvalRoot.get(); \
/* Optimize for two int-tagged operands (typical loop control). */ \
if (lval.isInt32() && rval.isInt32()) { \
*res = lval.toInt32() OP rval.toInt32(); \
} else { \
if (!ToPrimitive(cx, JSTYPE_NUMBER, &lval)) \
return false; \
if (!ToPrimitive(cx, JSTYPE_NUMBER, &rval)) \
return false; \
if (lval.isString() && rval.isString()) { \
JSString *l = lval.toString(), *r = rval.toString(); \
int32_t result; \
if (!CompareStrings(cx, l, r, &result)) \
return false; \
*res = result OP 0; \
} else { \
double l, r; \
if (!ToNumber(cx, lval, &l) || !ToNumber(cx, rval, &r)) \
return false;; \
*res = (l OP r); \
} \
} \
return true; \
JS_END_MACRO
static JS_ALWAYS_INLINE bool
LessThanOperation(JSContext *cx, const Value &lhs, const Value &rhs, bool *res) {
RELATIONAL_OP(<);
}
static JS_ALWAYS_INLINE bool
LessThanOrEqualOperation(JSContext *cx, const Value &lhs, const Value &rhs, bool *res) {
RELATIONAL_OP(<=);
}
static JS_ALWAYS_INLINE bool
GreaterThanOperation(JSContext *cx, const Value &lhs, const Value &rhs, bool *res) {
RELATIONAL_OP(>);
}
static JS_ALWAYS_INLINE bool
GreaterThanOrEqualOperation(JSContext *cx, const Value &lhs, const Value &rhs, bool *res) {
RELATIONAL_OP(>=);
}
#undef RELATIONAL_OP
} /* namespace js */
#endif /* jsinterpinlines_h__ */
