https://github.com/mozilla/gecko-dev
Tip revision: 48eb17ba6bb3ce3198ee136785487c26cb64a025 authored by alwu on 05 April 2024, 01:28:30 UTC
Bug 1887971 : always set 'isHardwareDecryption' on MFCDMCapabilitiesIPDL. r=jolin
Bug 1887971 : always set 'isHardwareDecryption' on MFCDMCapabilitiesIPDL. r=jolin
Tip revision: 48eb17b
jsfun.cpp
/* -*- Mode: C++; tab-width: 8; indent-tabs-mode: nil; c-basic-offset: 4 -*-
* vim: set ts=8 sts=4 et sw=4 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/. */
/*
* JS function support.
*/
#include "jsfuninlines.h"
#include "mozilla/ArrayUtils.h"
#include "mozilla/CheckedInt.h"
#include "mozilla/Maybe.h"
#include "mozilla/PodOperations.h"
#include "mozilla/Range.h"
#include <string.h>
#include "jsapi.h"
#include "jsarray.h"
#include "jsatom.h"
#include "jscntxt.h"
#include "jsobj.h"
#include "jsscript.h"
#include "jsstr.h"
#include "jstypes.h"
#include "jswrapper.h"
#include "builtin/Eval.h"
#include "builtin/Object.h"
#include "builtin/SelfHostingDefines.h"
#include "frontend/BytecodeCompiler.h"
#include "frontend/TokenStream.h"
#include "gc/Marking.h"
#include "gc/Policy.h"
#include "jit/InlinableNatives.h"
#include "jit/Ion.h"
#include "jit/JitFrameIterator.h"
#include "js/CallNonGenericMethod.h"
#include "js/Proxy.h"
#include "vm/AsyncFunction.h"
#include "vm/Debugger.h"
#include "vm/GlobalObject.h"
#include "vm/Interpreter.h"
#include "vm/SelfHosting.h"
#include "vm/Shape.h"
#include "vm/SharedImmutableStringsCache.h"
#include "vm/StringBuffer.h"
#include "vm/WrapperObject.h"
#include "vm/Xdr.h"
#include "jsscriptinlines.h"
#include "vm/Interpreter-inl.h"
#include "vm/Stack-inl.h"
using namespace js;
using namespace js::gc;
using namespace js::frontend;
using mozilla::ArrayLength;
using mozilla::Maybe;
using mozilla::PodCopy;
using mozilla::RangedPtr;
using mozilla::Some;
static bool
fun_enumerate(JSContext* cx, HandleObject obj)
{
MOZ_ASSERT(obj->is<JSFunction>());
RootedId id(cx);
bool found;
if (!obj->isBoundFunction() && !obj->as<JSFunction>().isArrow()) {
id = NameToId(cx->names().prototype);
if (!HasProperty(cx, obj, id, &found))
return false;
}
id = NameToId(cx->names().length);
if (!HasProperty(cx, obj, id, &found))
return false;
id = NameToId(cx->names().name);
if (!HasProperty(cx, obj, id, &found))
return false;
return true;
}
bool
IsFunction(HandleValue v)
{
return v.isObject() && v.toObject().is<JSFunction>();
}
static bool
AdvanceToActiveCallLinear(JSContext* cx, NonBuiltinScriptFrameIter& iter, HandleFunction fun)
{
MOZ_ASSERT(!fun->isBuiltin());
for (; !iter.done(); ++iter) {
if (!iter.isFunctionFrame())
continue;
if (iter.matchCallee(cx, fun))
return true;
}
return false;
}
static void
ThrowTypeErrorBehavior(JSContext* cx)
{
JS_ReportErrorFlagsAndNumberASCII(cx, JSREPORT_ERROR, GetErrorMessage, nullptr,
JSMSG_THROW_TYPE_ERROR);
}
static bool
IsFunctionInStrictMode(JSFunction* fun)
{
// Interpreted functions have a strict flag.
if (fun->isInterpreted() && fun->strict())
return true;
// Only asm.js functions can also be strict.
return IsAsmJSStrictModeModuleOrFunction(fun);
}
static bool
IsNewerTypeFunction(JSFunction* fun) {
return fun->isArrow() ||
fun->isStarGenerator() ||
fun->isLegacyGenerator() ||
fun->isAsync() ||
fun->isMethod();
}
// Beware: this function can be invoked on *any* function! That includes
// natives, strict mode functions, bound functions, arrow functions,
// self-hosted functions and constructors, asm.js functions, functions with
// destructuring arguments and/or a rest argument, and probably a few more I
// forgot. Turn back and save yourself while you still can. It's too late for
// me.
static bool
ArgumentsRestrictions(JSContext* cx, HandleFunction fun)
{
// Throw if the function is a builtin (note: this doesn't include asm.js),
// a strict mode function, or a bound function.
// TODO (bug 1057208): ensure semantics are correct for all possible
// pairings of callee/caller.
if (fun->isBuiltin() || IsFunctionInStrictMode(fun) ||
fun->isBoundFunction() || IsNewerTypeFunction(fun))
{
ThrowTypeErrorBehavior(cx);
return false;
}
// Otherwise emit a strict warning about |f.arguments| to discourage use of
// this non-standard, performance-harmful feature.
if (!JS_ReportErrorFlagsAndNumberASCII(cx, JSREPORT_WARNING | JSREPORT_STRICT, GetErrorMessage,
nullptr, JSMSG_DEPRECATED_USAGE, js_arguments_str))
{
return false;
}
return true;
}
bool
ArgumentsGetterImpl(JSContext* cx, const CallArgs& args)
{
MOZ_ASSERT(IsFunction(args.thisv()));
RootedFunction fun(cx, &args.thisv().toObject().as<JSFunction>());
if (!ArgumentsRestrictions(cx, fun))
return false;
// Return null if this function wasn't found on the stack.
NonBuiltinScriptFrameIter iter(cx);
if (!AdvanceToActiveCallLinear(cx, iter, fun)) {
args.rval().setNull();
return true;
}
Rooted<ArgumentsObject*> argsobj(cx, ArgumentsObject::createUnexpected(cx, iter));
if (!argsobj)
return false;
// Disabling compiling of this script in IonMonkey. IonMonkey doesn't
// guarantee |f.arguments| can be fully recovered, so we try to mitigate
// observing this behavior by detecting its use early.
JSScript* script = iter.script();
jit::ForbidCompilation(cx, script);
args.rval().setObject(*argsobj);
return true;
}
static bool
ArgumentsGetter(JSContext* cx, unsigned argc, Value* vp)
{
CallArgs args = CallArgsFromVp(argc, vp);
return CallNonGenericMethod<IsFunction, ArgumentsGetterImpl>(cx, args);
}
bool
ArgumentsSetterImpl(JSContext* cx, const CallArgs& args)
{
MOZ_ASSERT(IsFunction(args.thisv()));
RootedFunction fun(cx, &args.thisv().toObject().as<JSFunction>());
if (!ArgumentsRestrictions(cx, fun))
return false;
// If the function passes the gauntlet, return |undefined|.
args.rval().setUndefined();
return true;
}
static bool
ArgumentsSetter(JSContext* cx, unsigned argc, Value* vp)
{
CallArgs args = CallArgsFromVp(argc, vp);
return CallNonGenericMethod<IsFunction, ArgumentsSetterImpl>(cx, args);
}
// Beware: this function can be invoked on *any* function! That includes
// natives, strict mode functions, bound functions, arrow functions,
// self-hosted functions and constructors, asm.js functions, functions with
// destructuring arguments and/or a rest argument, and probably a few more I
// forgot. Turn back and save yourself while you still can. It's too late for
// me.
static bool
CallerRestrictions(JSContext* cx, HandleFunction fun)
{
// Throw if the function is a builtin (note: this doesn't include asm.js),
// a strict mode function, or a bound function.
// TODO (bug 1057208): ensure semantics are correct for all possible
// pairings of callee/caller.
if (fun->isBuiltin() || IsFunctionInStrictMode(fun) ||
fun->isBoundFunction() || IsNewerTypeFunction(fun))
{
ThrowTypeErrorBehavior(cx);
return false;
}
// Otherwise emit a strict warning about |f.caller| to discourage use of
// this non-standard, performance-harmful feature.
if (!JS_ReportErrorFlagsAndNumberASCII(cx, JSREPORT_WARNING | JSREPORT_STRICT, GetErrorMessage,
nullptr, JSMSG_DEPRECATED_USAGE, js_caller_str))
{
return false;
}
return true;
}
bool
CallerGetterImpl(JSContext* cx, const CallArgs& args)
{
MOZ_ASSERT(IsFunction(args.thisv()));
// Beware! This function can be invoked on *any* function! It can't
// assume it'll never be invoked on natives, strict mode functions, bound
// functions, or anything else that ordinarily has immutable .caller
// defined with [[ThrowTypeError]].
RootedFunction fun(cx, &args.thisv().toObject().as<JSFunction>());
if (!CallerRestrictions(cx, fun))
return false;
// Also return null if this function wasn't found on the stack.
NonBuiltinScriptFrameIter iter(cx);
if (!AdvanceToActiveCallLinear(cx, iter, fun)) {
args.rval().setNull();
return true;
}
++iter;
while (!iter.done() && iter.isEvalFrame())
++iter;
if (iter.done() || !iter.isFunctionFrame()) {
args.rval().setNull();
return true;
}
RootedObject caller(cx, iter.callee(cx));
if (caller->is<JSFunction>() && caller->as<JSFunction>().isAsync())
caller = GetWrappedAsyncFunction(&caller->as<JSFunction>());
if (!cx->compartment()->wrap(cx, &caller))
return false;
// Censor the caller if we don't have full access to it. If we do, but the
// caller is a function with strict mode code, throw a TypeError per ES5.
// If we pass these checks, we can return the computed caller.
{
JSObject* callerObj = CheckedUnwrap(caller);
if (!callerObj) {
args.rval().setNull();
return true;
}
JSFunction* callerFun = &callerObj->as<JSFunction>();
if (IsWrappedAsyncFunction(callerFun))
callerFun = GetUnwrappedAsyncFunction(callerFun);
MOZ_ASSERT(!callerFun->isBuiltin(), "non-builtin iterator returned a builtin?");
if (callerFun->strict()) {
JS_ReportErrorFlagsAndNumberASCII(cx, JSREPORT_ERROR, GetErrorMessage, nullptr,
JSMSG_CALLER_IS_STRICT);
return false;
}
}
args.rval().setObject(*caller);
return true;
}
static bool
CallerGetter(JSContext* cx, unsigned argc, Value* vp)
{
CallArgs args = CallArgsFromVp(argc, vp);
return CallNonGenericMethod<IsFunction, CallerGetterImpl>(cx, args);
}
bool
CallerSetterImpl(JSContext* cx, const CallArgs& args)
{
MOZ_ASSERT(IsFunction(args.thisv()));
// Beware! This function can be invoked on *any* function! It can't
// assume it'll never be invoked on natives, strict mode functions, bound
// functions, or anything else that ordinarily has immutable .caller
// defined with [[ThrowTypeError]].
RootedFunction fun(cx, &args.thisv().toObject().as<JSFunction>());
if (!CallerRestrictions(cx, fun))
return false;
// Return |undefined| unless an error must be thrown.
args.rval().setUndefined();
// We can almost just return |undefined| here -- but if the caller function
// was strict mode code, we still have to throw a TypeError. This requires
// computing the caller, checking that no security boundaries are crossed,
// and throwing a TypeError if the resulting caller is strict.
NonBuiltinScriptFrameIter iter(cx);
if (!AdvanceToActiveCallLinear(cx, iter, fun))
return true;
++iter;
while (!iter.done() && iter.isEvalFrame())
++iter;
if (iter.done() || !iter.isFunctionFrame())
return true;
RootedObject caller(cx, iter.callee(cx));
// |caller| is only used for security access-checking and for its
// strictness. An unwrapped async function has its wrapped async
// function's security access and strictness, so don't bother calling
// |GetUnwrappedAsyncFunction|.
if (!cx->compartment()->wrap(cx, &caller)) {
cx->clearPendingException();
return true;
}
// If we don't have full access to the caller, or the caller is not strict,
// return undefined. Otherwise throw a TypeError.
JSObject* callerObj = CheckedUnwrap(caller);
if (!callerObj)
return true;
JSFunction* callerFun = &callerObj->as<JSFunction>();
MOZ_ASSERT(!callerFun->isBuiltin(), "non-builtin iterator returned a builtin?");
if (callerFun->strict()) {
JS_ReportErrorFlagsAndNumberASCII(cx, JSREPORT_ERROR, GetErrorMessage, nullptr,
JSMSG_CALLER_IS_STRICT);
return false;
}
return true;
}
static bool
CallerSetter(JSContext* cx, unsigned argc, Value* vp)
{
CallArgs args = CallArgsFromVp(argc, vp);
return CallNonGenericMethod<IsFunction, CallerSetterImpl>(cx, args);
}
static const JSPropertySpec function_properties[] = {
JS_PSGS("arguments", ArgumentsGetter, ArgumentsSetter, 0),
JS_PSGS("caller", CallerGetter, CallerSetter, 0),
JS_PS_END
};
static bool
ResolveInterpretedFunctionPrototype(JSContext* cx, HandleFunction fun, HandleId id)
{
MOZ_ASSERT(fun->isInterpreted() || fun->isAsmJSNative());
MOZ_ASSERT(id == NameToId(cx->names().prototype));
// Assert that fun is not a compiler-created function object, which
// must never leak to script or embedding code and then be mutated.
// Also assert that fun is not bound, per the ES5 15.3.4.5 ref above.
MOZ_ASSERT(!IsInternalFunctionObject(*fun));
MOZ_ASSERT(!fun->isBoundFunction());
// Make the prototype object an instance of Object with the same parent as
// the function object itself, unless the function is an ES6 generator. In
// that case, per the 15 July 2013 ES6 draft, section 15.19.3, its parent is
// the GeneratorObjectPrototype singleton.
bool isStarGenerator = fun->isStarGenerator();
Rooted<GlobalObject*> global(cx, &fun->global());
RootedObject objProto(cx);
if (isStarGenerator)
objProto = GlobalObject::getOrCreateStarGeneratorObjectPrototype(cx, global);
else
objProto = GlobalObject::getOrCreateObjectPrototype(cx, global);
if (!objProto)
return false;
RootedPlainObject proto(cx, NewObjectWithGivenProto<PlainObject>(cx, objProto,
SingletonObject));
if (!proto)
return false;
// Per ES5 13.2 the prototype's .constructor property is configurable,
// non-enumerable, and writable. However, per the 15 July 2013 ES6 draft,
// section 15.19.3, the .prototype of a generator function does not link
// back with a .constructor.
if (!isStarGenerator) {
RootedValue objVal(cx, ObjectValue(*fun));
if (!DefineProperty(cx, proto, cx->names().constructor, objVal, nullptr, nullptr, 0))
return false;
}
// Per ES5 15.3.5.2 a user-defined function's .prototype property is
// initially non-configurable, non-enumerable, and writable.
RootedValue protoVal(cx, ObjectValue(*proto));
return DefineProperty(cx, fun, id, protoVal, nullptr, nullptr,
JSPROP_PERMANENT | JSPROP_RESOLVING);
}
static bool
fun_mayResolve(const JSAtomState& names, jsid id, JSObject*)
{
if (!JSID_IS_ATOM(id))
return false;
JSAtom* atom = JSID_TO_ATOM(id);
return atom == names.prototype || atom == names.length || atom == names.name;
}
static bool
fun_resolve(JSContext* cx, HandleObject obj, HandleId id, bool* resolvedp)
{
if (!JSID_IS_ATOM(id))
return true;
RootedFunction fun(cx, &obj->as<JSFunction>());
if (JSID_IS_ATOM(id, cx->names().prototype)) {
/*
* Built-in functions do not have a .prototype property per ECMA-262,
* or (Object.prototype, Function.prototype, etc.) have that property
* created eagerly.
*
* ES5 15.3.4.5: bound functions don't have a prototype property. The
* isBuiltin() test covers this case because bound functions are native
* (and thus built-in) functions by definition/construction.
*
* ES6 9.2.8 MakeConstructor defines the .prototype property on constructors.
* Generators are not constructors, but they have a .prototype property anyway,
* according to errata to ES6. See bug 1191486.
*
* Thus all of the following don't get a .prototype property:
* - Methods (that are not class-constructors or generators)
* - Arrow functions
* - Function.prototype
*/
if (fun->isBuiltin())
return true;
if (!fun->isConstructor()) {
if (!fun->isStarGenerator() && !fun->isLegacyGenerator() && !fun->isAsync())
return true;
}
if (!ResolveInterpretedFunctionPrototype(cx, fun, id))
return false;
*resolvedp = true;
return true;
}
bool isLength = JSID_IS_ATOM(id, cx->names().length);
if (isLength || JSID_IS_ATOM(id, cx->names().name)) {
MOZ_ASSERT(!IsInternalFunctionObject(*obj));
RootedValue v(cx);
// Since f.length and f.name are configurable, they could be resolved
// and then deleted:
// function f(x) {}
// assertEq(f.length, 1);
// delete f.length;
// assertEq(f.name, "f");
// delete f.name;
// Afterwards, asking for f.length or f.name again will cause this
// resolve hook to run again. Defining the property again the second
// time through would be a bug.
// assertEq(f.length, 0); // gets Function.prototype.length!
// assertEq(f.name, ""); // gets Function.prototype.name!
// We use the RESOLVED_LENGTH and RESOLVED_NAME flags as a hack to prevent this
// bug.
if (isLength) {
if (fun->hasResolvedLength())
return true;
if (!JSFunction::getUnresolvedLength(cx, fun, &v))
return false;
} else {
if (fun->hasResolvedName())
return true;
// Don't define an own .name property for unnamed functions.
JSAtom* name = fun->getUnresolvedName(cx);
if (name == nullptr)
return true;
v.setString(name);
}
if (!NativeDefineProperty(cx, fun, id, v, nullptr, nullptr,
JSPROP_READONLY | JSPROP_RESOLVING))
{
return false;
}
if (isLength)
fun->setResolvedLength();
else
fun->setResolvedName();
*resolvedp = true;
return true;
}
return true;
}
template<XDRMode mode>
bool
js::XDRInterpretedFunction(XDRState<mode>* xdr, HandleScope enclosingScope,
HandleScriptSource sourceObject, MutableHandleFunction objp)
{
enum FirstWordFlag {
HasAtom = 0x1,
HasStarGeneratorProto = 0x2,
IsLazy = 0x4,
HasSingletonType = 0x8
};
/* NB: Keep this in sync with CloneInnerInterpretedFunction. */
RootedAtom atom(xdr->cx());
uint32_t firstword = 0; /* bitmask of FirstWordFlag */
uint32_t flagsword = 0; /* word for argument count and fun->flags */
JSContext* cx = xdr->cx();
RootedFunction fun(cx);
RootedScript script(cx);
Rooted<LazyScript*> lazy(cx);
if (mode == XDR_ENCODE) {
fun = objp;
if (!fun->isInterpreted())
return xdr->fail(JS::TranscodeResult_Failure_NotInterpretedFun);
if (fun->explicitName() || fun->hasCompileTimeName() || fun->hasGuessedAtom())
firstword |= HasAtom;
if (fun->isStarGenerator() || fun->isAsync())
firstword |= HasStarGeneratorProto;
if (fun->isInterpretedLazy()) {
// Encode a lazy script.
firstword |= IsLazy;
lazy = fun->lazyScript();
} else {
// Encode the script.
script = fun->nonLazyScript();
}
if (fun->isSingleton())
firstword |= HasSingletonType;
atom = fun->displayAtom();
flagsword = (fun->nargs() << 16) |
(fun->flags() & ~JSFunction::NO_XDR_FLAGS);
// The environment of any function which is not reused will always be
// null, it is later defined when a function is cloned or reused to
// mirror the scope chain.
MOZ_ASSERT_IF(fun->isSingleton() &&
!((lazy && lazy->hasBeenCloned()) || (script && script->hasBeenCloned())),
fun->environment() == nullptr);
}
// Everything added below can substituted by the non-lazy-script version of
// this function later.
js::AutoXDRTree funTree(xdr, xdr->getTreeKey(fun));
if (!xdr->codeUint32(&firstword))
return false;
if ((firstword & HasAtom) && !XDRAtom(xdr, &atom))
return false;
if (!xdr->codeUint32(&flagsword))
return false;
if (mode == XDR_DECODE) {
RootedObject proto(cx);
if (firstword & HasStarGeneratorProto) {
// If we are off thread, the generator meta-objects have
// already been created by js::StartOffThreadParseTask, so
// JSContext* will not be necessary.
JSContext* context = cx->helperThread() ? nullptr : cx;
proto = GlobalObject::getOrCreateStarGeneratorFunctionPrototype(context, cx->global());
if (!proto)
return false;
}
gc::AllocKind allocKind = gc::AllocKind::FUNCTION;
if (uint16_t(flagsword) & JSFunction::EXTENDED)
allocKind = gc::AllocKind::FUNCTION_EXTENDED;
fun = NewFunctionWithProto(cx, nullptr, 0, JSFunction::INTERPRETED,
/* enclosingDynamicScope = */ nullptr, nullptr, proto,
allocKind, TenuredObject);
if (!fun)
return false;
script = nullptr;
}
if (firstword & IsLazy) {
if (!XDRLazyScript(xdr, enclosingScope, sourceObject, fun, &lazy))
return false;
} else {
if (!XDRScript(xdr, enclosingScope, sourceObject, fun, &script))
return false;
}
if (mode == XDR_DECODE) {
fun->setArgCount(flagsword >> 16);
fun->setFlags(uint16_t(flagsword));
fun->initAtom(atom);
if (firstword & IsLazy) {
MOZ_ASSERT(fun->lazyScript() == lazy);
} else {
MOZ_ASSERT(fun->nonLazyScript() == script);
MOZ_ASSERT(fun->nargs() == script->numArgs());
}
bool singleton = firstword & HasSingletonType;
if (!JSFunction::setTypeForScriptedFunction(cx, fun, singleton))
return false;
objp.set(fun);
}
return true;
}
template bool
js::XDRInterpretedFunction(XDRState<XDR_ENCODE>*, HandleScope, HandleScriptSource,
MutableHandleFunction);
template bool
js::XDRInterpretedFunction(XDRState<XDR_DECODE>*, HandleScope, HandleScriptSource,
MutableHandleFunction);
/* ES6 (04-25-16) 19.2.3.6 Function.prototype [ @@hasInstance ] */
bool
js::fun_symbolHasInstance(JSContext* cx, unsigned argc, Value* vp)
{
CallArgs args = CallArgsFromVp(argc, vp);
if (args.length() < 1) {
args.rval().setBoolean(false);
return true;
}
/* Step 1. */
HandleValue func = args.thisv();
// Primitives are non-callable and will always return false from
// OrdinaryHasInstance.
if (!func.isObject()) {
args.rval().setBoolean(false);
return true;
}
RootedObject obj(cx, &func.toObject());
/* Step 2. */
bool result;
if (!OrdinaryHasInstance(cx, obj, args[0], &result))
return false;
args.rval().setBoolean(result);
return true;
}
/*
* ES6 (4-25-16) 7.3.19 OrdinaryHasInstance
*/
bool
JS::OrdinaryHasInstance(JSContext* cx, HandleObject objArg, HandleValue v, bool* bp)
{
RootedObject obj(cx, objArg);
/* Step 1. */
if (!obj->isCallable()) {
*bp = false;
return true;
}
/* Step 2. */
if (obj->is<JSFunction>() && obj->isBoundFunction()) {
/* Steps 2a-b. */
obj = obj->as<JSFunction>().getBoundFunctionTarget();
return InstanceOfOperator(cx, obj, v, bp);
}
/* Step 3. */
if (!v.isObject()) {
*bp = false;
return true;
}
/* Step 4. */
RootedValue pval(cx);
if (!GetProperty(cx, obj, obj, cx->names().prototype, &pval))
return false;
/* Step 5. */
if (pval.isPrimitive()) {
/*
* Throw a runtime error if instanceof is called on a function that
* has a non-object as its .prototype value.
*/
RootedValue val(cx, ObjectValue(*obj));
ReportValueError(cx, JSMSG_BAD_PROTOTYPE, -1, val, nullptr);
return false;
}
/* Step 6. */
RootedObject pobj(cx, &pval.toObject());
bool isDelegate;
if (!IsDelegate(cx, pobj, v, &isDelegate))
return false;
*bp = isDelegate;
return true;
}
inline void
JSFunction::trace(JSTracer* trc)
{
if (isExtended()) {
TraceRange(trc, ArrayLength(toExtended()->extendedSlots),
(GCPtrValue*)toExtended()->extendedSlots, "nativeReserved");
}
TraceNullableEdge(trc, &atom_, "atom");
if (isInterpreted()) {
// Functions can be be marked as interpreted despite having no script
// yet at some points when parsing, and can be lazy with no lazy script
// for self-hosted code.
if (hasScript() && !hasUncompiledScript())
TraceManuallyBarrieredEdge(trc, &u.i.s.script_, "script");
else if (isInterpretedLazy() && u.i.s.lazy_)
TraceManuallyBarrieredEdge(trc, &u.i.s.lazy_, "lazyScript");
if (u.i.env_)
TraceManuallyBarrieredEdge(trc, &u.i.env_, "fun_environment");
}
}
static void
fun_trace(JSTracer* trc, JSObject* obj)
{
obj->as<JSFunction>().trace(trc);
}
static bool
ThrowTypeError(JSContext* cx, unsigned argc, Value* vp)
{
ThrowTypeErrorBehavior(cx);
return false;
}
static JSObject*
CreateFunctionConstructor(JSContext* cx, JSProtoKey key)
{
Rooted<GlobalObject*> global(cx, cx->global());
RootedObject functionProto(cx, &global->getPrototype(JSProto_Function).toObject());
RootedObject functionCtor(cx,
NewFunctionWithProto(cx, Function, 1, JSFunction::NATIVE_CTOR,
nullptr, HandlePropertyName(cx->names().Function),
functionProto, AllocKind::FUNCTION, SingletonObject));
if (!functionCtor)
return nullptr;
return functionCtor;
}
static JSObject*
CreateFunctionPrototype(JSContext* cx, JSProtoKey key)
{
Rooted<GlobalObject*> self(cx, cx->global());
RootedObject objectProto(cx, &self->getPrototype(JSProto_Object).toObject());
/*
* Bizarrely, |Function.prototype| must be an interpreted function, so
* give it the guts to be one.
*/
RootedObject enclosingEnv(cx, &self->lexicalEnvironment());
JSObject* functionProto_ =
NewFunctionWithProto(cx, nullptr, 0, JSFunction::INTERPRETED,
enclosingEnv, nullptr, objectProto, AllocKind::FUNCTION,
SingletonObject);
if (!functionProto_)
return nullptr;
RootedFunction functionProto(cx, &functionProto_->as<JSFunction>());
const char* rawSource = "function () {\n}";
size_t sourceLen = strlen(rawSource);
size_t begin = 9;
MOZ_ASSERT(rawSource[begin] == '(');
mozilla::UniquePtr<char16_t[], JS::FreePolicy> source(InflateString(cx, rawSource, &sourceLen));
if (!source)
return nullptr;
ScriptSource* ss = cx->new_<ScriptSource>();
if (!ss)
return nullptr;
ScriptSourceHolder ssHolder(ss);
if (!ss->setSource(cx, mozilla::Move(source), sourceLen))
return nullptr;
CompileOptions options(cx);
options.setIntroductionType("Function.prototype")
.setNoScriptRval(true)
.setVersion(JSVERSION_DEFAULT);
if (!ss->initFromOptions(cx, options))
return nullptr;
RootedScriptSource sourceObject(cx, ScriptSourceObject::create(cx, ss));
if (!sourceObject || !ScriptSourceObject::initFromOptions(cx, sourceObject, options))
return nullptr;
RootedScript script(cx, JSScript::Create(cx,
options,
sourceObject,
begin,
ss->length(),
0));
if (!script || !JSScript::initFunctionPrototype(cx, script, functionProto))
return nullptr;
functionProto->initScript(script);
ObjectGroup* protoGroup = JSObject::getGroup(cx, functionProto);
if (!protoGroup)
return nullptr;
protoGroup->setInterpretedFunction(functionProto);
/*
* The default 'new' group of Function.prototype is required by type
* inference to have unknown properties, to simplify handling of e.g.
* NewFunctionClone.
*/
if (!JSObject::setNewGroupUnknown(cx, &JSFunction::class_, functionProto))
return nullptr;
// Set the prototype before we call NewFunctionWithProto below. This
// ensures EmptyShape::getInitialShape can share function shapes.
self->setPrototype(key, ObjectValue(*functionProto));
// Construct the unique [[%ThrowTypeError%]] function object, used only for
// "callee" and "caller" accessors on strict mode arguments objects. (The
// spec also uses this for "arguments" and "caller" on various functions,
// but we're experimenting with implementing them using accessors on
// |Function.prototype| right now.)
//
// Note that we can't use NewFunction here, even though we want the normal
// Function.prototype for our proto, because we're still in the middle of
// creating that as far as the world is concerned, so things will get all
// confused.
RootedFunction throwTypeError(cx,
NewFunctionWithProto(cx, ThrowTypeError, 0, JSFunction::NATIVE_FUN,
nullptr, nullptr, functionProto, AllocKind::FUNCTION,
SingletonObject));
if (!throwTypeError || !PreventExtensions(cx, throwTypeError))
return nullptr;
// The "length" property of %ThrowTypeError% is non-configurable, adjust
// the default property attributes accordingly.
Rooted<PropertyDescriptor> nonConfigurableDesc(cx);
nonConfigurableDesc.setAttributes(JSPROP_PERMANENT | JSPROP_IGNORE_READONLY |
JSPROP_IGNORE_ENUMERATE | JSPROP_IGNORE_VALUE);
RootedId lengthId(cx, NameToId(cx->names().length));
ObjectOpResult lengthResult;
if (!NativeDefineProperty(cx, throwTypeError, lengthId, nonConfigurableDesc, lengthResult))
return nullptr;
MOZ_ASSERT(lengthResult);
// Non-standard: Also change "name" to non-configurable. ECMAScript defines
// %ThrowTypeError% as an anonymous function, i.e. it shouldn't actually
// get an own "name" property. To be consistent with other built-in,
// anonymous functions, we don't delete %ThrowTypeError%'s "name" property.
RootedId nameId(cx, NameToId(cx->names().name));
ObjectOpResult nameResult;
if (!NativeDefineProperty(cx, throwTypeError, nameId, nonConfigurableDesc, nameResult))
return nullptr;
MOZ_ASSERT(nameResult);
self->setThrowTypeError(throwTypeError);
return functionProto;
}
static const ClassOps JSFunctionClassOps = {
nullptr, /* addProperty */
nullptr, /* delProperty */
nullptr, /* getProperty */
nullptr, /* setProperty */
fun_enumerate,
fun_resolve,
fun_mayResolve,
nullptr, /* finalize */
nullptr, /* call */
nullptr,
nullptr, /* construct */
fun_trace,
};
static const ClassSpec JSFunctionClassSpec = {
CreateFunctionConstructor,
CreateFunctionPrototype,
nullptr,
nullptr,
function_methods,
function_properties
};
const Class JSFunction::class_ = {
js_Function_str,
JSCLASS_HAS_CACHED_PROTO(JSProto_Function),
&JSFunctionClassOps,
&JSFunctionClassSpec
};
const Class* const js::FunctionClassPtr = &JSFunction::class_;
JSString*
js::FunctionToString(JSContext* cx, HandleFunction fun, bool prettyPrint)
{
if (fun->isInterpretedLazy() && !JSFunction::getOrCreateScript(cx, fun))
return nullptr;
if (IsAsmJSModule(fun))
return AsmJSModuleToString(cx, fun, !prettyPrint);
if (IsAsmJSFunction(fun))
return AsmJSFunctionToString(cx, fun);
if (IsWrappedAsyncFunction(fun)) {
RootedFunction unwrapped(cx, GetUnwrappedAsyncFunction(fun));
return FunctionToString(cx, unwrapped, prettyPrint);
}
StringBuffer out(cx);
RootedScript script(cx);
if (fun->hasScript()) {
script = fun->nonLazyScript();
if (script->isGeneratorExp()) {
if (!out.append("function genexp() {") ||
!out.append("\n [generator expression]\n") ||
!out.append("}"))
{
return nullptr;
}
return out.finishString();
}
}
bool funIsNonArrowLambda = fun->isLambda() && !fun->isArrow();
bool haveSource = fun->isInterpreted() && !fun->isSelfHostedBuiltin();
// If we're not in pretty mode, put parentheses around lambda functions
// so that eval returns lambda, not function statement.
if (haveSource && !prettyPrint && funIsNonArrowLambda) {
if (!out.append("("))
return nullptr;
}
if (haveSource && !script->scriptSource()->hasSourceData() &&
!JSScript::loadSource(cx, script->scriptSource(), &haveSource))
{
return nullptr;
}
auto AppendPrelude = [&out, &fun]() {
if (fun->isAsync()) {
if (!out.append("async "))
return false;
}
if (!fun->isArrow()) {
if (!out.append("function"))
return false;
if (fun->isStarGenerator()) {
if (!out.append('*'))
return false;
}
}
if (fun->explicitName()) {
if (!out.append(' '))
return false;
if (!out.append(fun->explicitName()))
return false;
}
return true;
};
if (haveSource) {
Rooted<JSFlatString*> src(cx, JSScript::sourceDataWithPrelude(cx, script));
if (!src)
return nullptr;
if (!out.append(src))
return nullptr;
if (!prettyPrint && funIsNonArrowLambda) {
if (!out.append(")"))
return nullptr;
}
} else if (fun->isInterpreted() && !fun->isSelfHostedBuiltin()) {
if (!AppendPrelude() ||
!out.append("() {\n ") ||
!out.append("[sourceless code]") ||
!out.append("\n}"))
{
return nullptr;
}
} else {
bool derived = fun->infallibleIsDefaultClassConstructor(cx);
if (derived && fun->isDerivedClassConstructor()) {
if (!AppendPrelude() ||
!out.append("(...args) {\n ") ||
!out.append("super(...args);\n}"))
{
return nullptr;
}
} else {
if (!AppendPrelude() ||
!out.append("() {\n "))
return nullptr;
if (!derived) {
if (!out.append("[native code]"))
return nullptr;
}
if (!out.append("\n}"))
return nullptr;
}
}
return out.finishString();
}
JSString*
fun_toStringHelper(JSContext* cx, HandleObject obj, unsigned indent)
{
if (!obj->is<JSFunction>()) {
if (JSFunToStringOp op = obj->getOpsFunToString())
return op(cx, obj, indent);
JS_ReportErrorNumberASCII(cx, GetErrorMessage, nullptr,
JSMSG_INCOMPATIBLE_PROTO,
js_Function_str, js_toString_str, "object");
return nullptr;
}
RootedFunction fun(cx, &obj->as<JSFunction>());
return FunctionToString(cx, fun, indent != JS_DONT_PRETTY_PRINT);
}
bool
js::FunctionHasDefaultHasInstance(JSFunction* fun, const WellKnownSymbols& symbols)
{
jsid id = SYMBOL_TO_JSID(symbols.hasInstance);
Shape* shape = fun->lookupPure(id);
if (shape) {
if (!shape->hasSlot() || !shape->hasDefaultGetter())
return false;
const Value hasInstance = fun->as<NativeObject>().getSlot(shape->slot());
return IsNativeFunction(hasInstance, js::fun_symbolHasInstance);
}
return true;
}
bool
js::fun_toString(JSContext* cx, unsigned argc, Value* vp)
{
CallArgs args = CallArgsFromVp(argc, vp);
MOZ_ASSERT(IsFunctionObject(args.calleev()));
uint32_t indent = 0;
if (args.length() != 0 && !ToUint32(cx, args[0], &indent))
return false;
RootedObject obj(cx, ToObject(cx, args.thisv()));
if (!obj)
return false;
RootedString str(cx, fun_toStringHelper(cx, obj, indent));
if (!str)
return false;
args.rval().setString(str);
return true;
}
#if JS_HAS_TOSOURCE
static bool
fun_toSource(JSContext* cx, unsigned argc, Value* vp)
{
CallArgs args = CallArgsFromVp(argc, vp);
MOZ_ASSERT(IsFunctionObject(args.calleev()));
RootedObject obj(cx, ToObject(cx, args.thisv()));
if (!obj)
return false;
RootedString str(cx);
if (obj->isCallable())
str = fun_toStringHelper(cx, obj, JS_DONT_PRETTY_PRINT);
else
str = ObjectToSource(cx, obj);
if (!str)
return false;
args.rval().setString(str);
return true;
}
#endif
bool
js::fun_call(JSContext* cx, unsigned argc, Value* vp)
{
CallArgs args = CallArgsFromVp(argc, vp);
HandleValue func = args.thisv();
// We don't need to do this -- Call would do it for us -- but the error
// message is *much* better if we do this here. (Without this,
// JSDVG_SEARCH_STACK tries to decompile |func| as if it were |this| in
// the scripted caller's frame -- so for example
//
// Function.prototype.call.call({});
//
// would identify |{}| as |this| as being the result of evaluating
// |Function.prototype.call| and would conclude, "Function.prototype.call
// is not a function". Grotesque.)
if (!IsCallable(func)) {
ReportIncompatibleMethod(cx, args, &JSFunction::class_);
return false;
}
size_t argCount = args.length();
if (argCount > 0)
argCount--; // strip off provided |this|
InvokeArgs iargs(cx);
if (!iargs.init(cx, argCount))
return false;
for (size_t i = 0; i < argCount; i++)
iargs[i].set(args[i + 1]);
return Call(cx, func, args.get(0), iargs, args.rval());
}
// ES5 15.3.4.3
bool
js::fun_apply(JSContext* cx, unsigned argc, Value* vp)
{
CallArgs args = CallArgsFromVp(argc, vp);
// Step 1.
//
// Note that we must check callability here, not at actual call time,
// because extracting argument values from the provided arraylike might
// have side effects or throw an exception.
HandleValue fval = args.thisv();
if (!IsCallable(fval)) {
ReportIncompatibleMethod(cx, args, &JSFunction::class_);
return false;
}
// Step 2.
if (args.length() < 2 || args[1].isNullOrUndefined())
return fun_call(cx, (args.length() > 0) ? 1 : 0, vp);
InvokeArgs args2(cx);
// A JS_OPTIMIZED_ARGUMENTS magic value means that 'arguments' flows into
// this apply call from a scripted caller and, as an optimization, we've
// avoided creating it since apply can simply pull the argument values from
// the calling frame (which we must do now).
if (args[1].isMagic(JS_OPTIMIZED_ARGUMENTS)) {
// Step 3-6.
ScriptFrameIter iter(cx);
MOZ_ASSERT(iter.numActualArgs() <= ARGS_LENGTH_MAX);
if (!args2.init(cx, iter.numActualArgs()))
return false;
// Steps 7-8.
iter.unaliasedForEachActual(cx, CopyTo(args2.array()));
} else {
// Step 3.
if (!args[1].isObject()) {
JS_ReportErrorNumberASCII(cx, GetErrorMessage, nullptr,
JSMSG_BAD_APPLY_ARGS, js_apply_str);
return false;
}
// Steps 4-5 (note erratum removing steps originally numbered 5 and 7 in
// original version of ES5).
RootedObject aobj(cx, &args[1].toObject());
uint32_t length;
if (!GetLengthProperty(cx, aobj, &length))
return false;
// Step 6.
if (!args2.init(cx, length))
return false;
MOZ_ASSERT(length <= ARGS_LENGTH_MAX);
// Steps 7-8.
if (!GetElements(cx, aobj, length, args2.array()))
return false;
}
// Step 9.
return Call(cx, fval, args[0], args2, args.rval());
}
bool
JSFunction::infallibleIsDefaultClassConstructor(JSContext* cx) const
{
if (!isSelfHostedBuiltin())
return false;
bool isDefault = false;
if (isInterpretedLazy()) {
JSAtom* name = &getExtendedSlot(LAZY_FUNCTION_NAME_SLOT).toString()->asAtom();
isDefault = name == cx->names().DefaultDerivedClassConstructor ||
name == cx->names().DefaultBaseClassConstructor;
} else {
isDefault = nonLazyScript()->isDefaultClassConstructor();
}
MOZ_ASSERT_IF(isDefault, isConstructor());
MOZ_ASSERT_IF(isDefault, isClassConstructor());
return isDefault;
}
bool
JSFunction::isDerivedClassConstructor()
{
bool derived;
if (isInterpretedLazy()) {
// There is only one plausible lazy self-hosted derived
// constructor.
if (isSelfHostedBuiltin()) {
JSAtom* name = &getExtendedSlot(LAZY_FUNCTION_NAME_SLOT).toString()->asAtom();
// This function is called from places without access to a
// JSContext. Trace some plumbing to get what we want.
derived = name == compartment()->runtimeFromAnyThread()->
commonNames->DefaultDerivedClassConstructor;
} else {
derived = lazyScript()->isDerivedClassConstructor();
}
} else {
derived = nonLazyScript()->isDerivedClassConstructor();
}
MOZ_ASSERT_IF(derived, isClassConstructor());
return derived;
}
/* static */ bool
JSFunction::getLength(JSContext* cx, HandleFunction fun, uint16_t* length)
{
MOZ_ASSERT(!fun->isBoundFunction());
if (fun->isInterpretedLazy() && !getOrCreateScript(cx, fun))
return false;
*length = fun->isNative() ? fun->nargs() : fun->nonLazyScript()->funLength();
return true;
}
/* static */ bool
JSFunction::getUnresolvedLength(JSContext* cx, HandleFunction fun, MutableHandleValue v)
{
MOZ_ASSERT(!IsInternalFunctionObject(*fun));
MOZ_ASSERT(!fun->hasResolvedLength());
// Bound functions' length can have values up to MAX_SAFE_INTEGER, so
// they're handled differently from other functions.
if (fun->isBoundFunction()) {
MOZ_ASSERT(fun->getExtendedSlot(BOUND_FUN_LENGTH_SLOT).isNumber());
v.set(fun->getExtendedSlot(BOUND_FUN_LENGTH_SLOT));
return true;
}
uint16_t length;
if (!JSFunction::getLength(cx, fun, &length))
return false;
v.setInt32(length);
return true;
}
JSAtom*
JSFunction::getUnresolvedName(JSContext* cx)
{
MOZ_ASSERT(!IsInternalFunctionObject(*this));
MOZ_ASSERT(!hasResolvedName());
if (isClassConstructor()) {
// It's impossible to have an empty named class expression. We use
// empty as a sentinel when creating default class constructors.
MOZ_ASSERT(explicitOrCompileTimeName() != cx->names().empty);
// Unnamed class expressions should not get a .name property at all.
return explicitOrCompileTimeName();
}
return explicitOrCompileTimeName() != nullptr ? explicitOrCompileTimeName()
: cx->names().empty;
}
static const js::Value&
BoundFunctionEnvironmentSlotValue(const JSFunction* fun, uint32_t slotIndex)
{
MOZ_ASSERT(fun->isBoundFunction());
MOZ_ASSERT(fun->environment()->is<CallObject>());
CallObject* callObject = &fun->environment()->as<CallObject>();
return callObject->getSlot(slotIndex);
}
JSObject*
JSFunction::getBoundFunctionTarget() const
{
js::Value targetVal = BoundFunctionEnvironmentSlotValue(this, JSSLOT_BOUND_FUNCTION_TARGET);
MOZ_ASSERT(IsCallable(targetVal));
return &targetVal.toObject();
}
const js::Value&
JSFunction::getBoundFunctionThis() const
{
return BoundFunctionEnvironmentSlotValue(this, JSSLOT_BOUND_FUNCTION_THIS);
}
static ArrayObject*
GetBoundFunctionArguments(const JSFunction* boundFun)
{
js::Value argsVal = BoundFunctionEnvironmentSlotValue(boundFun, JSSLOT_BOUND_FUNCTION_ARGS);
return &argsVal.toObject().as<ArrayObject>();
}
const js::Value&
JSFunction::getBoundFunctionArgument(unsigned which) const
{
MOZ_ASSERT(which < getBoundFunctionArgumentCount());
return GetBoundFunctionArguments(this)->getDenseElement(which);
}
size_t
JSFunction::getBoundFunctionArgumentCount() const
{
return GetBoundFunctionArguments(this)->length();
}
/* static */ bool
JSFunction::createScriptForLazilyInterpretedFunction(JSContext* cx, HandleFunction fun)
{
MOZ_ASSERT(fun->isInterpretedLazy());
Rooted<LazyScript*> lazy(cx, fun->lazyScriptOrNull());
if (lazy) {
RootedScript script(cx, lazy->maybeScript());
// Only functions without inner functions or direct eval are
// re-lazified. Functions with either of those are on the static scope
// chain of their inner functions, or in the case of eval, possibly
// eval'd inner functions. This prohibits re-lazification as
// StaticScopeIter queries needsCallObject of those functions, which
// requires a non-lazy script. Note that if this ever changes,
// XDRRelazificationInfo will have to be fixed.
bool canRelazify = !lazy->numInnerFunctions() && !lazy->hasDirectEval();
if (script) {
fun->setUnlazifiedScript(script);
// Remember the lazy script on the compiled script, so it can be
// stored on the function again in case of re-lazification.
if (canRelazify)
script->setLazyScript(lazy);
return true;
}
if (fun != lazy->functionNonDelazifying()) {
if (!LazyScript::functionDelazifying(cx, lazy))
return false;
script = lazy->functionNonDelazifying()->nonLazyScript();
if (!script)
return false;
fun->setUnlazifiedScript(script);
return true;
}
// Lazy script caching is only supported for leaf functions. If a
// script with inner functions was returned by the cache, those inner
// functions would be delazified when deep cloning the script, even if
// they have never executed.
//
// Additionally, the lazy script cache is not used during incremental
// GCs, to avoid resurrecting dead scripts after incremental sweeping
// has started.
if (canRelazify && !JS::IsIncrementalGCInProgress(cx)) {
LazyScriptCache::Lookup lookup(cx, lazy);
cx->caches().lazyScriptCache.lookup(lookup, script.address());
}
if (script) {
RootedScope enclosingScope(cx, lazy->enclosingScope());
RootedScript clonedScript(cx, CloneScriptIntoFunction(cx, enclosingScope, fun, script));
if (!clonedScript)
return false;
clonedScript->setSourceObject(lazy->sourceObject());
fun->initAtom(script->functionNonDelazifying()->displayAtom());
if (!lazy->maybeScript())
lazy->initScript(clonedScript);
return true;
}
MOZ_ASSERT(lazy->scriptSource()->hasSourceData());
// Parse and compile the script from source.
size_t lazyLength = lazy->end() - lazy->begin();
UncompressedSourceCache::AutoHoldEntry holder;
const char16_t* chars = lazy->scriptSource()->chars(cx, holder, lazy->begin(), lazyLength);
if (!chars)
return false;
if (!frontend::CompileLazyFunction(cx, lazy, chars, lazyLength)) {
// The frontend may have linked the function and the non-lazy
// script together during bytecode compilation. Reset it now on
// error.
fun->initLazyScript(lazy);
if (lazy->hasScript())
lazy->resetScript();
return false;
}
script = fun->nonLazyScript();
// Remember the compiled script on the lazy script itself, in case
// there are clones of the function still pointing to the lazy script.
if (!lazy->maybeScript())
lazy->initScript(script);
// Try to insert the newly compiled script into the lazy script cache.
if (canRelazify) {
// A script's starting column isn't set by the bytecode emitter, so
// specify this from the lazy script so that if an identical lazy
// script is encountered later a match can be determined.
script->setColumn(lazy->column());
LazyScriptCache::Lookup lookup(cx, lazy);
cx->caches().lazyScriptCache.insert(lookup, script);
// Remember the lazy script on the compiled script, so it can be
// stored on the function again in case of re-lazification.
// Only functions without inner functions are re-lazified.
script->setLazyScript(lazy);
}
return true;
}
/* Lazily cloned self-hosted script. */
MOZ_ASSERT(fun->isSelfHostedBuiltin());
RootedAtom funAtom(cx, &fun->getExtendedSlot(LAZY_FUNCTION_NAME_SLOT).toString()->asAtom());
if (!funAtom)
return false;
Rooted<PropertyName*> funName(cx, funAtom->asPropertyName());
return cx->runtime()->cloneSelfHostedFunctionScript(cx, funName, fun);
}
void
JSFunction::maybeRelazify(JSRuntime* rt)
{
// Try to relazify functions with a non-lazy script. Note: functions can be
// marked as interpreted despite having no script yet at some points when
// parsing.
if (!hasScript() || !u.i.s.script_)
return;
// Don't relazify functions in compartments that are active.
JSCompartment* comp = compartment();
if (comp->hasBeenEntered() && !rt->allowRelazificationForTesting)
return;
// The caller should have checked we're not in the self-hosting zone (it's
// shared with worker runtimes so relazifying functions in it will race).
MOZ_ASSERT(!comp->isSelfHosting);
// Don't relazify if the compartment is being debugged.
if (comp->isDebuggee())
return;
// Don't relazify if the compartment and/or runtime is instrumented to
// collect code coverage for analysis.
if (comp->collectCoverageForDebug())
return;
// Don't relazify functions with JIT code.
if (!u.i.s.script_->isRelazifiable())
return;
// To delazify self-hosted builtins we need the name of the function
// to clone. This name is stored in the first extended slot. Since
// that slot is sometimes also used for other purposes, make sure it
// contains a string.
if (isSelfHostedBuiltin() &&
(!isExtended() || !getExtendedSlot(LAZY_FUNCTION_NAME_SLOT).isString()))
{
return;
}
JSScript* script = nonLazyScript();
flags_ &= ~INTERPRETED;
flags_ |= INTERPRETED_LAZY;
LazyScript* lazy = script->maybeLazyScript();
u.i.s.lazy_ = lazy;
if (lazy) {
MOZ_ASSERT(!isSelfHostedBuiltin());
} else {
MOZ_ASSERT(isSelfHostedBuiltin());
MOZ_ASSERT(isExtended());
MOZ_ASSERT(getExtendedSlot(LAZY_FUNCTION_NAME_SLOT).toString()->isAtom());
}
comp->scheduleDelazificationForDebugger();
}
static bool
fun_isGenerator(JSContext* cx, unsigned argc, Value* vp)
{
CallArgs args = CallArgsFromVp(argc, vp);
JSFunction* fun;
if (!IsFunctionObject(args.thisv(), &fun)) {
args.rval().setBoolean(false);
return true;
}
args.rval().setBoolean(fun->isStarGenerator() || fun->isLegacyGenerator());
return true;
}
const JSFunctionSpec js::function_methods[] = {
#if JS_HAS_TOSOURCE
JS_FN(js_toSource_str, fun_toSource, 0,0),
#endif
JS_FN(js_toString_str, fun_toString, 0,0),
JS_FN(js_apply_str, fun_apply, 2,0),
JS_FN(js_call_str, fun_call, 1,0),
JS_FN("isGenerator", fun_isGenerator,0,0),
JS_SELF_HOSTED_FN("bind", "FunctionBind", 2, 0),
JS_SYM_FN(hasInstance, fun_symbolHasInstance, 1, JSPROP_READONLY | JSPROP_PERMANENT),
JS_FS_END
};
// ES 2017 draft rev 0f10dba4ad18de92d47d421f378233a2eae8f077 19.2.1.1.1.
static bool
FunctionConstructor(JSContext* cx, const CallArgs& args, GeneratorKind generatorKind,
FunctionAsyncKind asyncKind)
{
// Block this call if security callbacks forbid it.
Rooted<GlobalObject*> global(cx, &args.callee().global());
if (!GlobalObject::isRuntimeCodeGenEnabled(cx, global)) {
JS_ReportErrorNumberASCII(cx, GetErrorMessage, nullptr, JSMSG_CSP_BLOCKED_FUNCTION);
return false;
}
bool isStarGenerator = generatorKind == StarGenerator;
bool isAsync = asyncKind == AsyncFunction;
MOZ_ASSERT(generatorKind != LegacyGenerator);
RootedScript maybeScript(cx);
const char* filename;
unsigned lineno;
bool mutedErrors;
uint32_t pcOffset;
DescribeScriptedCallerForCompilation(cx, &maybeScript, &filename, &lineno, &pcOffset,
&mutedErrors);
const char* introductionType = "Function";
if (isAsync)
introductionType = "AsyncFunction";
else if (generatorKind != NotGenerator)
introductionType = "GeneratorFunction";
const char* introducerFilename = filename;
if (maybeScript && maybeScript->scriptSource()->introducerFilename())
introducerFilename = maybeScript->scriptSource()->introducerFilename();
CompileOptions options(cx);
options.setMutedErrors(mutedErrors)
.setFileAndLine(filename, 1)
.setNoScriptRval(false)
.setIntroductionInfo(introducerFilename, introductionType, lineno, maybeScript, pcOffset);
StringBuffer sb(cx);
if (isAsync) {
if (!sb.append("async "))
return false;
}
if (!sb.append("function"))
return false;
if (isStarGenerator && !isAsync) {
if (!sb.append('*'))
return false;
}
if (!sb.append(" anonymous("))
return false;
if (args.length() > 1) {
RootedString str(cx);
// Steps 5-6, 9.
unsigned n = args.length() - 1;
for (unsigned i = 0; i < n; i++) {
// Steps 9.a-b, 9.d.i-ii.
str = ToString<CanGC>(cx, args[i]);
if (!str)
return false;
// Steps 9.b, 9.d.iii.
if (!sb.append(str))
return false;
if (i < args.length() - 2) {
// Step 9.d.iii.
if (!sb.append(","))
return false;
}
}
}
if (!sb.append('\n'))
return false;
// Remember the position of ")".
Maybe<uint32_t> parameterListEnd = Some(uint32_t(sb.length()));
MOZ_ASSERT(FunctionConstructorMedialSigils[0] == ')');
if (!sb.append(FunctionConstructorMedialSigils))
return false;
if (args.length() > 0) {
// Steps 7-8, 10.
RootedString body(cx, ToString<CanGC>(cx, args[args.length() - 1]));
if (!body || !sb.append(body))
return false;
}
if (!sb.append(FunctionConstructorFinalBrace))
return false;
// The parser only accepts two byte strings.
if (!sb.ensureTwoByteChars())
return false;
RootedString functionText(cx, sb.finishString());
if (!functionText)
return false;
/*
* NB: (new Function) is not lexically closed by its caller, it's just an
* anonymous function in the top-level scope that its constructor inhabits.
* Thus 'var x = 42; f = new Function("return x"); print(f())' prints 42,
* and so would a call to f from another top-level's script or function.
*/
RootedAtom anonymousAtom(cx, cx->names().anonymous);
// Step 24.
RootedObject proto(cx);
if (!isAsync) {
if (!GetPrototypeFromCallableConstructor(cx, args, &proto))
return false;
}
// Step 4.d, use %Generator% as the fallback prototype.
// Also use %Generator% for the unwrapped function of async functions.
if (!proto && (isStarGenerator || isAsync)) {
proto = GlobalObject::getOrCreateStarGeneratorFunctionPrototype(cx, global);
if (!proto)
return false;
}
// Step 25-32 (reordered).
RootedObject globalLexical(cx, &global->lexicalEnvironment());
AllocKind allocKind = isAsync ? AllocKind::FUNCTION_EXTENDED : AllocKind::FUNCTION;
RootedFunction fun(cx, NewFunctionWithProto(cx, nullptr, 0,
JSFunction::INTERPRETED_LAMBDA, globalLexical,
anonymousAtom, proto,
allocKind, TenuredObject));
if (!fun)
return false;
if (!JSFunction::setTypeForScriptedFunction(cx, fun))
return false;
// Steps 2.a-b, 3.a-b, 4.a-b, 11-23.
AutoStableStringChars stableChars(cx);
if (!stableChars.initTwoByte(cx, functionText))
return false;
mozilla::Range<const char16_t> chars = stableChars.twoByteRange();
SourceBufferHolder::Ownership ownership = stableChars.maybeGiveOwnershipToCaller()
? SourceBufferHolder::GiveOwnership
: SourceBufferHolder::NoOwnership;
bool ok;
SourceBufferHolder srcBuf(chars.begin().get(), chars.length(), ownership);
if (isAsync)
ok = frontend::CompileStandaloneAsyncFunction(cx, &fun, options, srcBuf, parameterListEnd);
else if (isStarGenerator)
ok = frontend::CompileStandaloneGenerator(cx, &fun, options, srcBuf, parameterListEnd);
else
ok = frontend::CompileStandaloneFunction(cx, &fun, options, srcBuf, parameterListEnd);
// Step 33.
args.rval().setObject(*fun);
return ok;
}
bool
js::Function(JSContext* cx, unsigned argc, Value* vp)
{
CallArgs args = CallArgsFromVp(argc, vp);
return FunctionConstructor(cx, args, NotGenerator, SyncFunction);
}
bool
js::Generator(JSContext* cx, unsigned argc, Value* vp)
{
CallArgs args = CallArgsFromVp(argc, vp);
return FunctionConstructor(cx, args, StarGenerator, SyncFunction);
}
bool
js::AsyncFunctionConstructor(JSContext* cx, unsigned argc, Value* vp)
{
CallArgs args = CallArgsFromVp(argc, vp);
// Save the callee before its reset in FunctionConstructor().
RootedObject newTarget(cx);
if (args.isConstructing())
newTarget = &args.newTarget().toObject();
else
newTarget = &args.callee();
if (!FunctionConstructor(cx, args, NotGenerator, AsyncFunction))
return false;
// ES2017, draft rev 0f10dba4ad18de92d47d421f378233a2eae8f077
// 19.2.1.1.1 Runtime Semantics: CreateDynamicFunction, step 24.
RootedObject proto(cx);
if (!GetPrototypeFromConstructor(cx, newTarget, &proto))
return false;
// 19.2.1.1.1, step 4.d, use %AsyncFunctionPrototype% as the fallback.
if (!proto) {
proto = GlobalObject::getOrCreateAsyncFunctionPrototype(cx, cx->global());
if (!proto)
return false;
}
RootedFunction unwrapped(cx, &args.rval().toObject().as<JSFunction>());
RootedObject wrapped(cx, WrapAsyncFunctionWithProto(cx, unwrapped, proto));
if (!wrapped)
return false;
args.rval().setObject(*wrapped);
return true;
}
bool
JSFunction::isBuiltinFunctionConstructor()
{
return maybeNative() == Function || maybeNative() == Generator;
}
bool
JSFunction::needsExtraBodyVarEnvironment() const
{
MOZ_ASSERT(!isInterpretedLazy());
if (isNative())
return false;
if (!nonLazyScript()->functionHasExtraBodyVarScope())
return false;
return nonLazyScript()->functionExtraBodyVarScope()->hasEnvironment();
}
bool
JSFunction::needsNamedLambdaEnvironment() const
{
MOZ_ASSERT(!isInterpretedLazy());
if (!isNamedLambda())
return false;
LexicalScope* scope = nonLazyScript()->maybeNamedLambdaScope();
if (!scope)
return false;
return scope->hasEnvironment();
}
JSFunction*
js::NewNativeFunction(JSContext* cx, Native native, unsigned nargs, HandleAtom atom,
gc::AllocKind allocKind /* = AllocKind::FUNCTION */,
NewObjectKind newKind /* = SingletonObject */)
{
MOZ_ASSERT(native);
return NewFunctionWithProto(cx, native, nargs, JSFunction::NATIVE_FUN,
nullptr, atom, nullptr, allocKind, newKind);
}
JSFunction*
js::NewNativeConstructor(JSContext* cx, Native native, unsigned nargs, HandleAtom atom,
gc::AllocKind allocKind /* = AllocKind::FUNCTION */,
NewObjectKind newKind /* = SingletonObject */,
JSFunction::Flags flags /* = JSFunction::NATIVE_CTOR */)
{
MOZ_ASSERT(native);
MOZ_ASSERT(flags & JSFunction::NATIVE_CTOR);
return NewFunctionWithProto(cx, native, nargs, flags, nullptr, atom,
nullptr, allocKind, newKind);
}
JSFunction*
js::NewScriptedFunction(JSContext* cx, unsigned nargs,
JSFunction::Flags flags, HandleAtom atom,
HandleObject proto /* = nullptr */,
gc::AllocKind allocKind /* = AllocKind::FUNCTION */,
NewObjectKind newKind /* = GenericObject */,
HandleObject enclosingEnvArg /* = nullptr */)
{
RootedObject enclosingEnv(cx, enclosingEnvArg);
if (!enclosingEnv)
enclosingEnv = &cx->global()->lexicalEnvironment();
return NewFunctionWithProto(cx, nullptr, nargs, flags, enclosingEnv,
atom, proto, allocKind, newKind);
}
#ifdef DEBUG
static bool
NewFunctionEnvironmentIsWellFormed(JSContext* cx, HandleObject env)
{
// Assert that the terminating environment is null, global, or a debug
// scope proxy. All other cases of polluting global scope behavior are
// handled by EnvironmentObjects (viz. non-syntactic DynamicWithObject and
// NonSyntacticVariablesObject).
RootedObject terminatingEnv(cx, SkipEnvironmentObjects(env));
return !terminatingEnv || terminatingEnv == cx->global() ||
terminatingEnv->is<DebugEnvironmentProxy>();
}
#endif
JSFunction*
js::NewFunctionWithProto(JSContext* cx, Native native,
unsigned nargs, JSFunction::Flags flags, HandleObject enclosingEnv,
HandleAtom atom, HandleObject proto,
gc::AllocKind allocKind /* = AllocKind::FUNCTION */,
NewObjectKind newKind /* = GenericObject */,
NewFunctionProtoHandling protoHandling /* = NewFunctionClassProto */)
{
MOZ_ASSERT(allocKind == AllocKind::FUNCTION || allocKind == AllocKind::FUNCTION_EXTENDED);
MOZ_ASSERT_IF(native, !enclosingEnv);
MOZ_ASSERT(NewFunctionEnvironmentIsWellFormed(cx, enclosingEnv));
RootedObject funobj(cx);
if (protoHandling == NewFunctionClassProto) {
funobj = NewObjectWithClassProto(cx, &JSFunction::class_, proto, allocKind,
newKind);
} else {
funobj = NewObjectWithGivenTaggedProto(cx, &JSFunction::class_, AsTaggedProto(proto),
allocKind, newKind);
}
if (!funobj)
return nullptr;
RootedFunction fun(cx, &funobj->as<JSFunction>());
if (allocKind == AllocKind::FUNCTION_EXTENDED)
flags = JSFunction::Flags(flags | JSFunction::EXTENDED);
/* Initialize all function members. */
fun->setArgCount(uint16_t(nargs));
fun->setFlags(flags);
if (fun->isInterpreted()) {
MOZ_ASSERT(!native);
if (fun->isInterpretedLazy())
fun->initLazyScript(nullptr);
else
fun->initScript(nullptr);
fun->initEnvironment(enclosingEnv);
} else {
MOZ_ASSERT(fun->isNative());
MOZ_ASSERT(native);
fun->initNative(native, nullptr);
}
if (allocKind == AllocKind::FUNCTION_EXTENDED)
fun->initializeExtended();
fun->initAtom(atom);
return fun;
}
bool
js::CanReuseScriptForClone(JSCompartment* compartment, HandleFunction fun,
HandleObject newParent)
{
if (compartment != fun->compartment() ||
fun->isSingleton() ||
ObjectGroup::useSingletonForClone(fun))
{
return false;
}
if (newParent->is<GlobalObject>())
return true;
// Don't need to clone the script if newParent is a syntactic scope, since
// in that case we have some actual scope objects on our scope chain and
// whatnot; whoever put them there should be responsible for setting our
// script's flags appropriately. We hit this case for JSOP_LAMBDA, for
// example.
if (IsSyntacticEnvironment(newParent))
return true;
// We need to clone the script if we're interpreted and not already marked
// as having a non-syntactic scope. If we're lazy, go ahead and clone the
// script; see the big comment at the end of CopyScriptInternal for the
// explanation of what's going on there.
return !fun->isInterpreted() ||
(fun->hasScript() && fun->nonLazyScript()->hasNonSyntacticScope());
}
static inline JSFunction*
NewFunctionClone(JSContext* cx, HandleFunction fun, NewObjectKind newKind,
gc::AllocKind allocKind, HandleObject proto)
{
RootedObject cloneProto(cx, proto);
if (!proto && (fun->isStarGenerator() || fun->isAsync())) {
cloneProto = GlobalObject::getOrCreateStarGeneratorFunctionPrototype(cx, cx->global());
if (!cloneProto)
return nullptr;
}
JSObject* cloneobj = NewObjectWithClassProto(cx, &JSFunction::class_, cloneProto,
allocKind, newKind);
if (!cloneobj)
return nullptr;
RootedFunction clone(cx, &cloneobj->as<JSFunction>());
uint16_t flags = fun->flags() & ~JSFunction::EXTENDED;
if (allocKind == AllocKind::FUNCTION_EXTENDED)
flags |= JSFunction::EXTENDED;
clone->setArgCount(fun->nargs());
clone->setFlags(flags);
clone->initAtom(fun->displayAtom());
if (allocKind == AllocKind::FUNCTION_EXTENDED) {
if (fun->isExtended() && fun->compartment() == cx->compartment()) {
for (unsigned i = 0; i < FunctionExtended::NUM_EXTENDED_SLOTS; i++)
clone->initExtendedSlot(i, fun->getExtendedSlot(i));
} else {
clone->initializeExtended();
}
}
return clone;
}
JSFunction*
js::CloneFunctionReuseScript(JSContext* cx, HandleFunction fun, HandleObject enclosingEnv,
gc::AllocKind allocKind /* = FUNCTION */ ,
NewObjectKind newKind /* = GenericObject */,
HandleObject proto /* = nullptr */)
{
MOZ_ASSERT(NewFunctionEnvironmentIsWellFormed(cx, enclosingEnv));
MOZ_ASSERT(!fun->isBoundFunction());
MOZ_ASSERT(CanReuseScriptForClone(cx->compartment(), fun, enclosingEnv));
RootedFunction clone(cx, NewFunctionClone(cx, fun, newKind, allocKind, proto));
if (!clone)
return nullptr;
if (fun->hasScript()) {
clone->initScript(fun->nonLazyScript());
clone->initEnvironment(enclosingEnv);
} else if (fun->isInterpretedLazy()) {
MOZ_ASSERT(fun->compartment() == clone->compartment());
LazyScript* lazy = fun->lazyScriptOrNull();
clone->initLazyScript(lazy);
clone->initEnvironment(enclosingEnv);
} else {
clone->initNative(fun->native(), fun->jitInfo());
}
/*
* Clone the function, reusing its script. We can use the same group as
* the original function provided that its prototype is correct.
*/
if (fun->staticPrototype() == clone->staticPrototype())
clone->setGroup(fun->group());
return clone;
}
JSFunction*
js::CloneFunctionAndScript(JSContext* cx, HandleFunction fun, HandleObject enclosingEnv,
HandleScope newScope, gc::AllocKind allocKind /* = FUNCTION */,
HandleObject proto /* = nullptr */)
{
MOZ_ASSERT(NewFunctionEnvironmentIsWellFormed(cx, enclosingEnv));
MOZ_ASSERT(!fun->isBoundFunction());
JSScript::AutoDelazify funScript(cx);
if (fun->isInterpreted()) {
funScript = fun;
if (!funScript)
return nullptr;
}
RootedFunction clone(cx, NewFunctionClone(cx, fun, SingletonObject, allocKind, proto));
if (!clone)
return nullptr;
if (fun->hasScript()) {
clone->initScript(nullptr);
clone->initEnvironment(enclosingEnv);
} else {
clone->initNative(fun->native(), fun->jitInfo());
}
/*
* Across compartments or if we have to introduce a non-syntactic scope we
* have to clone the script for interpreted functions. Cross-compartment
* cloning only happens via JSAPI (JS::CloneFunctionObject) which
* dynamically ensures that 'script' has no enclosing lexical scope (only
* the global scope or other non-lexical scope).
*/
#ifdef DEBUG
RootedObject terminatingEnv(cx, enclosingEnv);
while (IsSyntacticEnvironment(terminatingEnv))
terminatingEnv = terminatingEnv->enclosingEnvironment();
MOZ_ASSERT_IF(!terminatingEnv->is<GlobalObject>(),
newScope->hasOnChain(ScopeKind::NonSyntactic));
#endif
if (clone->isInterpreted()) {
RootedScript script(cx, fun->nonLazyScript());
MOZ_ASSERT(script->compartment() == fun->compartment());
MOZ_ASSERT(cx->compartment() == clone->compartment(),
"Otherwise we could relazify clone below!");
RootedScript clonedScript(cx, CloneScriptIntoFunction(cx, newScope, clone, script));
if (!clonedScript)
return nullptr;
Debugger::onNewScript(cx, clonedScript);
}
return clone;
}
/*
* Return an atom for use as the name of a builtin method with the given
* property id.
*
* Function names are always strings. If id is the well-known @@iterator
* symbol, this returns "[Symbol.iterator]". If a prefix is supplied the final
* name is |prefix + " " + name|. A prefix cannot be supplied if id is a
* symbol value.
*
* Implements steps 3-5 of 9.2.11 SetFunctionName in ES2016.
*/
JSAtom*
js::IdToFunctionName(JSContext* cx, HandleId id,
FunctionPrefixKind prefixKind /* = FunctionPrefixKind::None */)
{
// No prefix fastpath.
if (JSID_IS_ATOM(id) && prefixKind == FunctionPrefixKind::None)
return JSID_TO_ATOM(id);
// Step 3 (implicit).
// Step 4.
if (JSID_IS_SYMBOL(id)) {
// Step 4.a.
RootedAtom desc(cx, JSID_TO_SYMBOL(id)->description());
// Step 4.b, no prefix fastpath.
if (!desc && prefixKind == FunctionPrefixKind::None)
return cx->names().empty;
// Step 5 (reordered).
StringBuffer sb(cx);
if (prefixKind == FunctionPrefixKind::Get) {
if (!sb.append("get "))
return nullptr;
} else if (prefixKind == FunctionPrefixKind::Set) {
if (!sb.append("set "))
return nullptr;
}
// Step 4.b.
if (desc) {
// Step 4.c.
if (!sb.append('[') || !sb.append(desc) || !sb.append(']'))
return nullptr;
}
return sb.finishAtom();
}
RootedValue idv(cx, IdToValue(id));
RootedAtom name(cx, ToAtom<CanGC>(cx, idv));
if (!name)
return nullptr;
// Step 5.
return NameToFunctionName(cx, name, prefixKind);
}
JSAtom*
js::NameToFunctionName(JSContext* cx, HandleAtom name,
FunctionPrefixKind prefixKind /* = FunctionPrefixKind::None */)
{
if (prefixKind == FunctionPrefixKind::None)
return name;
StringBuffer sb(cx);
if (prefixKind == FunctionPrefixKind::Get) {
if (!sb.append("get "))
return nullptr;
} else {
if (!sb.append("set "))
return nullptr;
}
if (!sb.append(name))
return nullptr;
return sb.finishAtom();
}
bool
js::SetFunctionNameIfNoOwnName(JSContext* cx, HandleFunction fun, HandleValue name,
FunctionPrefixKind prefixKind)
{
MOZ_ASSERT(name.isString() || name.isSymbol() || name.isNumber());
if (fun->isClassConstructor()) {
// A class may have static 'name' method or accessor.
RootedId nameId(cx, NameToId(cx->names().name));
bool result;
if (!HasOwnProperty(cx, fun, nameId, &result))
return false;
if (result)
return true;
} else {
// Anonymous function shouldn't have own 'name' property at this point.
MOZ_ASSERT(!fun->containsPure(cx->names().name));
}
RootedId id(cx);
if (!ValueToId<CanGC>(cx, name, &id))
return false;
RootedAtom funNameAtom(cx, IdToFunctionName(cx, id, prefixKind));
if (!funNameAtom)
return false;
RootedValue funNameVal(cx, StringValue(funNameAtom));
if (!NativeDefineProperty(cx, fun, cx->names().name, funNameVal, nullptr, nullptr,
JSPROP_READONLY))
{
return false;
}
return true;
}
JSFunction*
js::DefineFunction(JSContext* cx, HandleObject obj, HandleId id, Native native,
unsigned nargs, unsigned flags, AllocKind allocKind /* = AllocKind::FUNCTION */)
{
GetterOp gop;
SetterOp sop;
if (flags & JSFUN_STUB_GSOPS) {
/*
* JSFUN_STUB_GSOPS is a request flag only, not stored in fun->flags or
* the defined property's attributes. This allows us to encode another,
* internal flag using the same bit, JSFUN_EXPR_CLOSURE -- see jsfun.h
* for more on this.
*/
flags &= ~JSFUN_STUB_GSOPS;
gop = nullptr;
sop = nullptr;
} else {
gop = obj->getClass()->getGetProperty();
sop = obj->getClass()->getSetProperty();
MOZ_ASSERT(gop != JS_PropertyStub);
MOZ_ASSERT(sop != JS_StrictPropertyStub);
}
RootedAtom atom(cx, IdToFunctionName(cx, id));
if (!atom)
return nullptr;
RootedFunction fun(cx);
if (!native)
fun = NewScriptedFunction(cx, nargs,
JSFunction::INTERPRETED_LAZY, atom,
/* proto = */ nullptr,
allocKind, GenericObject, obj);
else if (flags & JSFUN_CONSTRUCTOR)
fun = NewNativeConstructor(cx, native, nargs, atom, allocKind);
else
fun = NewNativeFunction(cx, native, nargs, atom, allocKind);
if (!fun)
return nullptr;
RootedValue funVal(cx, ObjectValue(*fun));
if (!DefineProperty(cx, obj, id, funVal, gop, sop, flags & ~JSFUN_FLAGS_MASK))
return nullptr;
return fun;
}
void
js::ReportIncompatibleMethod(JSContext* cx, const CallArgs& args, const Class* clasp)
{
RootedValue thisv(cx, args.thisv());
#ifdef DEBUG
if (thisv.isObject()) {
MOZ_ASSERT(thisv.toObject().getClass() != clasp ||
!thisv.toObject().isNative() ||
!thisv.toObject().staticPrototype() ||
thisv.toObject().staticPrototype()->getClass() != clasp);
} else if (thisv.isString()) {
MOZ_ASSERT(clasp != &StringObject::class_);
} else if (thisv.isNumber()) {
MOZ_ASSERT(clasp != &NumberObject::class_);
} else if (thisv.isBoolean()) {
MOZ_ASSERT(clasp != &BooleanObject::class_);
} else if (thisv.isSymbol()) {
MOZ_ASSERT(clasp != &SymbolObject::class_);
} else {
MOZ_ASSERT(thisv.isUndefined() || thisv.isNull());
}
#endif
if (JSFunction* fun = ReportIfNotFunction(cx, args.calleev())) {
JSAutoByteString funNameBytes;
if (const char* funName = GetFunctionNameBytes(cx, fun, &funNameBytes)) {
JS_ReportErrorNumberLatin1(cx, GetErrorMessage, nullptr, JSMSG_INCOMPATIBLE_PROTO,
clasp->name, funName, InformalValueTypeName(thisv));
}
}
}
void
js::ReportIncompatible(JSContext* cx, const CallArgs& args)
{
if (JSFunction* fun = ReportIfNotFunction(cx, args.calleev())) {
JSAutoByteString funNameBytes;
if (const char* funName = GetFunctionNameBytes(cx, fun, &funNameBytes)) {
JS_ReportErrorNumberLatin1(cx, GetErrorMessage, nullptr, JSMSG_INCOMPATIBLE_METHOD,
funName, "method", InformalValueTypeName(args.thisv()));
}
}
}
namespace JS {
namespace detail {
JS_PUBLIC_API(void)
CheckIsValidConstructible(const Value& calleev)
{
JSObject* callee = &calleev.toObject();
if (callee->is<JSFunction>())
MOZ_ASSERT(callee->as<JSFunction>().isConstructor());
else
MOZ_ASSERT(callee->constructHook() != nullptr);
}
} // namespace detail
} // namespace JS
