gecko/js/xpconnect/wrappers/WrapperFactory.cpp
Terrence Cole c9aa76bb68 Bug 878160 - GC: post barrier weak references in the browser - part 2 browser r=terrence r=billm
--HG--
extra : rebase_source : a1856a7dce28da5086f6fbeaeda15596193aa7ad
2013-06-05 16:40:02 -07:00

736 lines
29 KiB
C++

/* -*- Mode: C++; tab-width: 4; indent-tabs-mode: nil; c-basic-offset: 4 -*-
* vim: set ts=4 sw=4 et tw=99 ft=cpp:
*
* 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/. */
#include "WaiveXrayWrapper.h"
#include "FilteringWrapper.h"
#include "XrayWrapper.h"
#include "AccessCheck.h"
#include "XPCWrapper.h"
#include "ChromeObjectWrapper.h"
#include "WrapperFactory.h"
#include "xpcprivate.h"
#include "XPCMaps.h"
#include "mozilla/dom/BindingUtils.h"
#include "jsfriendapi.h"
#include "mozilla/Likely.h"
#include "nsContentUtils.h"
using namespace js;
using namespace mozilla;
namespace xpc {
// When chrome pulls a naked property across the membrane using
// .wrappedJSObject, we want it to cross the membrane into the
// chrome compartment without automatically being wrapped into an
// X-ray wrapper. We achieve this by wrapping it into a special
// transparent wrapper in the origin (non-chrome) compartment. When
// an object with that special wrapper applied crosses into chrome,
// we know to not apply an X-ray wrapper.
Wrapper XrayWaiver(WrapperFactory::WAIVE_XRAY_WRAPPER_FLAG);
// When objects for which we waived the X-ray wrapper cross into
// chrome, we wrap them into a special cross-compartment wrapper
// that transitively extends the waiver to all properties we get
// off it.
WaiveXrayWrapper WaiveXrayWrapper::singleton(0);
bool
WrapperFactory::IsCOW(JSObject *obj)
{
return IsWrapper(obj) &&
Wrapper::wrapperHandler(obj) == &ChromeObjectWrapper::singleton;
}
JSObject *
WrapperFactory::GetXrayWaiver(JSObject *obj)
{
// Object should come fully unwrapped but outerized.
MOZ_ASSERT(obj == UncheckedUnwrap(obj));
MOZ_ASSERT(!js::GetObjectClass(obj)->ext.outerObject);
XPCWrappedNativeScope *scope = GetObjectScope(obj);
MOZ_ASSERT(scope);
if (!scope->mWaiverWrapperMap)
return NULL;
return xpc_UnmarkGrayObject(scope->mWaiverWrapperMap->Find(obj));
}
JSObject *
WrapperFactory::CreateXrayWaiver(JSContext *cx, HandleObject obj)
{
// The caller is required to have already done a lookup.
// NB: This implictly performs the assertions of GetXrayWaiver.
MOZ_ASSERT(!GetXrayWaiver(obj));
XPCWrappedNativeScope *scope = GetObjectScope(obj);
// Get a waiver for the proto.
RootedObject proto(cx);
if (!js::GetObjectProto(cx, obj, &proto))
return nullptr;
if (proto && !(proto = WaiveXray(cx, proto)))
return nullptr;
// Create the waiver.
JSAutoCompartment ac(cx, obj);
if (!JS_WrapObject(cx, proto.address()))
return nullptr;
JSObject *waiver = Wrapper::New(cx, obj, proto,
JS_GetGlobalForObject(cx, obj),
&XrayWaiver);
if (!waiver)
return nullptr;
// Add the new waiver to the map. It's important that we only ever have
// one waiver for the lifetime of the target object.
if (!scope->mWaiverWrapperMap) {
scope->mWaiverWrapperMap =
JSObject2JSObjectMap::newMap(XPC_WRAPPER_MAP_SIZE);
MOZ_ASSERT(scope->mWaiverWrapperMap);
}
if (!scope->mWaiverWrapperMap->Add(cx, obj, waiver))
return nullptr;
return waiver;
}
JSObject *
WrapperFactory::WaiveXray(JSContext *cx, JSObject *objArg)
{
RootedObject obj(cx, objArg);
obj = UncheckedUnwrap(obj);
MOZ_ASSERT(!js::IsInnerObject(obj));
JSObject *waiver = GetXrayWaiver(obj);
if (waiver)
return waiver;
return CreateXrayWaiver(cx, obj);
}
// DoubleWrap is called from PrepareForWrapping to maintain the state that
// we're supposed to waive Xray wrappers for the given on. On entrance, it
// expects |cx->compartment != obj->compartment()|. The returned object will
// be in the same compartment as |obj|.
JSObject *
WrapperFactory::DoubleWrap(JSContext *cx, HandleObject obj, unsigned flags)
{
if (flags & WrapperFactory::WAIVE_XRAY_WRAPPER_FLAG) {
JSAutoCompartment ac(cx, obj);
return WaiveXray(cx, obj);
}
return obj;
}
JSObject *
WrapperFactory::PrepareForWrapping(JSContext *cx, HandleObject scope,
HandleObject objArg, unsigned flags)
{
RootedObject obj(cx, objArg);
// Outerize any raw inner objects at the entry point here, so that we don't
// have to worry about them for the rest of the wrapping code.
if (js::IsInnerObject(obj)) {
JSAutoCompartment ac(cx, obj);
obj = JS_ObjectToOuterObject(cx, obj);
NS_ENSURE_TRUE(obj, nullptr);
// The outerization hook wraps, which means that we can end up with a
// CCW here if |obj| was a navigated-away-from inner. Strip any CCWs.
obj = js::UncheckedUnwrap(obj);
MOZ_ASSERT(js::IsOuterObject(obj));
}
// If we've got an outer window, there's nothing special that needs to be
// done here, and we can move on to the next phase of wrapping. We handle
// this case first to allow us to assert against wrappers below.
if (js::IsOuterObject(obj))
return DoubleWrap(cx, obj, flags);
// Here are the rules for wrapping:
// We should never get a proxy here (the JS engine unwraps those for us).
MOZ_ASSERT(!IsWrapper(obj));
// If the object being wrapped is a prototype for a standard class and the
// wrapper does not subsumes the wrappee, use the one from the content
// compartment. This is generally safer all-around, and in the COW case this
// lets us safely take advantage of things like .forEach() via the
// ChromeObjectWrapper machinery.
//
// If the prototype chain of chrome object |obj| looks like this:
//
// obj => foo => bar => chromeWin.StandardClass.prototype
//
// The prototype chain of COW(obj) looks lke this:
//
// COW(obj) => COW(foo) => COW(bar) => contentWin.StandardClass.prototype
//
// NB: We now remap all non-subsuming access of standard prototypes.
//
// NB: We need to ignore domain here so that the security relationship we
// compute here can't change over time. See the comment above the other
// subsumesIgnoringDomain call below.
bool subsumes = AccessCheck::subsumesIgnoringDomain(js::GetContextCompartment(cx),
js::GetObjectCompartment(obj));
XrayType xrayType = GetXrayType(obj);
if (!subsumes && xrayType == NotXray) {
JSProtoKey key = JSProto_Null;
{
JSAutoCompartment ac(cx, obj);
key = JS_IdentifyClassPrototype(cx, obj);
}
if (key != JSProto_Null) {
RootedObject homeProto(cx);
if (!JS_GetClassPrototype(cx, key, homeProto.address()))
return nullptr;
MOZ_ASSERT(homeProto);
// No need to double-wrap here. We should never have waivers to
// COWs.
return homeProto;
}
}
// Now, our object is ready to be wrapped, but several objects (notably
// nsJSIIDs) have a wrapper per scope. If we are about to wrap one of
// those objects in a security wrapper, then we need to hand back the
// wrapper for the new scope instead. Also, global objects don't move
// between scopes so for those we also want to return the wrapper. So...
if (!IS_WN_REFLECTOR(obj) || !js::GetObjectParent(obj))
return DoubleWrap(cx, obj, flags);
XPCWrappedNative *wn = XPCWrappedNative::Get(obj);
JSAutoCompartment ac(cx, obj);
XPCCallContext ccx(JS_CALLER, cx, obj);
RootedObject wrapScope(cx, scope);
{
if (NATIVE_HAS_FLAG(&ccx, WantPreCreate)) {
// We have a precreate hook. This object might enforce that we only
// ever create JS object for it.
// Note: this penalizes objects that only have one wrapper, but are
// being accessed across compartments. We would really prefer to
// replace the above code with a test that says "do you only have one
// wrapper?"
nsresult rv = wn->GetScriptableInfo()->GetCallback()->
PreCreate(wn->Native(), cx, scope, wrapScope.address());
NS_ENSURE_SUCCESS(rv, DoubleWrap(cx, obj, flags));
// If the handed back scope differs from the passed-in scope and is in
// a separate compartment, then this object is explicitly requesting
// that we don't create a second JS object for it: create a security
// wrapper.
if (js::GetObjectCompartment(scope) != js::GetObjectCompartment(wrapScope))
return DoubleWrap(cx, obj, flags);
RootedObject currentScope(cx, JS_GetGlobalForObject(cx, obj));
if (MOZ_UNLIKELY(wrapScope != currentScope)) {
// The wrapper claims it wants to be in the new scope, but
// currently has a reflection that lives in the old scope. This
// can mean one of two things, both of which are rare:
//
// 1 - The object has a PreCreate hook (we checked for it above),
// but is deciding to request one-wrapper-per-scope (rather than
// one-wrapper-per-native) for some reason. Usually, a PreCreate
// hook indicates one-wrapper-per-native. In this case we want to
// make a new wrapper in the new scope.
//
// 2 - We're midway through wrapper reparenting. The document has
// moved to a new scope, but |wn| hasn't been moved yet, and
// we ended up calling JS_WrapObject() on its JS object. In this
// case, we want to return the existing wrapper.
//
// So we do a trick: call PreCreate _again_, but say that we're
// wrapping for the old scope, rather than the new one. If (1) is
// the case, then PreCreate will return the scope we pass to it
// (the old scope). If (2) is the case, PreCreate will return the
// scope of the document (the new scope).
RootedObject probe(cx);
rv = wn->GetScriptableInfo()->GetCallback()->
PreCreate(wn->Native(), cx, currentScope, probe.address());
// Check for case (2).
if (probe != currentScope) {
MOZ_ASSERT(probe == wrapScope);
return DoubleWrap(cx, obj, flags);
}
// Ok, must be case (1). Fall through and create a new wrapper.
}
// Nasty hack for late-breaking bug 781476. This will confuse identity checks,
// but it's probably better than any of our alternatives.
//
// Note: We have to ignore domain here. The JS engine assumes that, given a
// compartment c, if c->wrap(x) returns a cross-compartment wrapper at time t0,
// it will also return a cross-compartment wrapper for any time t1 > t0 unless
// an explicit transplant is performed. In particular, wrapper recomputation
// assumes that recomputing a wrapper will always result in a wrapper.
//
// This doesn't actually pose a security issue, because we'll still compute
// the correct (opaque) wrapper for the object below given the security
// characteristics of the two compartments.
if (!AccessCheck::isChrome(js::GetObjectCompartment(wrapScope)) &&
AccessCheck::subsumesIgnoringDomain(js::GetObjectCompartment(wrapScope),
js::GetObjectCompartment(obj)))
{
return DoubleWrap(cx, obj, flags);
}
}
}
// NB: Passing a holder here inhibits slim wrappers under
// WrapNativeToJSVal.
nsCOMPtr<nsIXPConnectJSObjectHolder> holder;
// This public WrapNativeToJSVal API enters the compartment of 'wrapScope'
// so we don't have to.
RootedValue v(cx);
nsresult rv =
nsXPConnect::XPConnect()->WrapNativeToJSVal(cx, wrapScope, wn->Native(), nullptr,
&NS_GET_IID(nsISupports), false,
v.address(), getter_AddRefs(holder));
NS_ENSURE_SUCCESS(rv, nullptr);
obj = JSVAL_TO_OBJECT(v);
NS_ASSERTION(IS_WN_REFLECTOR(obj), "bad object");
// Because the underlying native didn't have a PreCreate hook, we had
// to a new (or possibly pre-existing) XPCWN in our compartment.
// This could be a problem for chrome code that passes XPCOM objects
// across compartments, because the effects of QI would disappear across
// compartments.
//
// So whenever we pull an XPCWN across compartments in this manner, we
// give the destination object the union of the two native sets. We try
// to do this cleverly in the common case to avoid too much overhead.
XPCWrappedNative *newwn = XPCWrappedNative::Get(obj);
XPCNativeSet *unionSet = XPCNativeSet::GetNewOrUsed(newwn->GetSet(),
wn->GetSet(), false);
if (!unionSet)
return nullptr;
newwn->SetSet(unionSet);
return DoubleWrap(cx, obj, flags);
}
#ifdef DEBUG
static void
DEBUG_CheckUnwrapSafety(HandleObject obj, js::Wrapper *handler,
JSCompartment *origin, JSCompartment *target)
{
if (AccessCheck::isChrome(target) || xpc::IsUniversalXPConnectEnabled(target)) {
// If the caller is chrome (or effectively so), unwrap should always be allowed.
MOZ_ASSERT(handler->isSafeToUnwrap());
} else if (WrapperFactory::IsComponentsObject(obj)) {
// The Components object that is restricted regardless of origin.
MOZ_ASSERT(!handler->isSafeToUnwrap());
} else if (handler == &FilteringWrapper<CrossCompartmentSecurityWrapper, GentlyOpaque>::singleton) {
// We explicitly use a SecurityWrapper to protect privileged callers from
// less-privileged objects that they should never see. Skip the check in
// this case.
} else {
// Otherwise, it should depend on whether the target subsumes the origin.
MOZ_ASSERT(handler->isSafeToUnwrap() == AccessCheck::subsumes(target, origin));
}
}
#else
#define DEBUG_CheckUnwrapSafety(obj, handler, origin, target) {}
#endif
static Wrapper *
SelectWrapper(bool securityWrapper, bool wantXrays, XrayType xrayType,
bool waiveXrays)
{
// Waived Xray uses a modified CCW that has transparent behavior but
// transitively waives Xrays on arguments.
if (waiveXrays) {
MOZ_ASSERT(!securityWrapper);
return &WaiveXrayWrapper::singleton;
}
// If we don't want or can't use Xrays, select a wrapper that's either
// entirely transparent or entirely opaque.
if (!wantXrays || xrayType == NotXray) {
if (!securityWrapper)
return &CrossCompartmentWrapper::singleton;
return &FilteringWrapper<CrossCompartmentSecurityWrapper, Opaque>::singleton;
}
// Ok, we're using Xray. If this isn't a security wrapper, use the permissive
// version and skip the filter.
if (!securityWrapper) {
if (xrayType == XrayForWrappedNative)
return &PermissiveXrayXPCWN::singleton;
return &PermissiveXrayDOM::singleton;
}
// This is a security wrapper. Use the security versions and filter.
if (xrayType == XrayForWrappedNative)
return &FilteringWrapper<SecurityXrayXPCWN,
CrossOriginAccessiblePropertiesOnly>::singleton;
return &FilteringWrapper<SecurityXrayDOM,
CrossOriginAccessiblePropertiesOnly>::singleton;
}
JSObject *
WrapperFactory::Rewrap(JSContext *cx, HandleObject existing, HandleObject obj,
HandleObject wrappedProto, HandleObject parent,
unsigned flags)
{
MOZ_ASSERT(!IsWrapper(obj) ||
GetProxyHandler(obj) == &XrayWaiver ||
js::GetObjectClass(obj)->ext.innerObject,
"wrapped object passed to rewrap");
MOZ_ASSERT(JS_GetClass(obj) != &XrayUtils::HolderClass, "trying to wrap a holder");
MOZ_ASSERT(!js::IsInnerObject(obj));
// We sometimes end up here after nsContentUtils has been shut down but before
// XPConnect has been shut down, so check the context stack the roundabout way.
MOZ_ASSERT(XPCJSRuntime::Get()->GetJSContextStack()->Peek() == cx);
// Compute the information we need to select the right wrapper.
JSCompartment *origin = js::GetObjectCompartment(obj);
JSCompartment *target = js::GetContextCompartment(cx);
bool originIsChrome = AccessCheck::isChrome(origin);
bool targetIsChrome = AccessCheck::isChrome(target);
bool originSubsumesTarget = AccessCheck::subsumes(origin, target);
bool targetSubsumesOrigin = AccessCheck::subsumes(target, origin);
bool sameOrigin = targetSubsumesOrigin && originSubsumesTarget;
XrayType xrayType = GetXrayType(obj);
bool waiveXrayFlag = flags & WAIVE_XRAY_WRAPPER_FLAG;
// By default we use the wrapped proto of the underlying object as the
// prototype for our wrapper, but we may select something different below.
RootedObject proxyProto(cx, wrappedProto);
Wrapper *wrapper;
CompartmentPrivate *targetdata = EnsureCompartmentPrivate(target);
//
// First, handle the special cases.
//
// If UniversalXPConnect is enabled, this is just some dumb mochitest. Use
// a vanilla CCW.
if (xpc::IsUniversalXPConnectEnabled(target)) {
wrapper = &CrossCompartmentWrapper::singleton;
// If this is a chrome object being exposed to content without Xrays, use
// a COW.
} else if (originIsChrome && !targetIsChrome && xrayType == NotXray) {
wrapper = &ChromeObjectWrapper::singleton;
// If content is accessing a Components object or NAC, we need a special filter,
// even if the object is same origin. Note that we allow access to NAC for
// remote-XUL whitelisted domains, since they don't have XBL scopes.
} else if (IsComponentsObject(obj) && !AccessCheck::isChrome(target)) {
wrapper = &FilteringWrapper<CrossCompartmentSecurityWrapper,
ComponentsObjectPolicy>::singleton;
} else if (AccessCheck::needsSystemOnlyWrapper(obj) &&
xpc::AllowXBLScope(target) &&
!(targetIsChrome || (targetSubsumesOrigin && nsContentUtils::IsCallerXBL())))
{
wrapper = &FilteringWrapper<CrossCompartmentSecurityWrapper, Opaque>::singleton;
}
// Normally, a non-xrayable non-waived content object that finds itself in
// a privileged scope is wrapped with a CrossCompartmentWrapper, even though
// the lack of a waiver _really_ should give it an opaque wrapper. This is
// a bit too entrenched to change for content-chrome, but we can at least fix
// it for XBL scopes.
//
// See bug 843829.
else if (targetSubsumesOrigin && !originSubsumesTarget &&
!waiveXrayFlag && xrayType == NotXray &&
IsXBLScope(target))
{
wrapper = &FilteringWrapper<CrossCompartmentSecurityWrapper, GentlyOpaque>::singleton;
}
//
// Now, handle the regular cases.
//
// These are wrappers we can compute using a rule-based approach. In order
// to do so, we need to compute some parameters.
//
else {
// The wrapper is a security wrapper (protecting the wrappee) if and
// only if the target does not subsume the origin.
bool securityWrapper = !targetSubsumesOrigin;
// Xrays are warranted if either the target or the origin don't trust
// each other. This is generally the case, unless the two are same-origin
// and the caller has not requested same-origin Xrays.
//
// Xrays are a bidirectional protection, since it affords clarity to the
// caller and privacy to the callee.
bool wantXrays = !(sameOrigin && !targetdata->wantXrays);
// If Xrays are warranted, the caller may waive them for non-security
// wrappers.
bool waiveXrays = wantXrays && !securityWrapper && waiveXrayFlag;
wrapper = SelectWrapper(securityWrapper, wantXrays, xrayType, waiveXrays);
}
if (wrapper == &ChromeObjectWrapper::singleton) {
// This shouldn't happen, but do a quick check to make some dumb addon
// doesn't expose chrome eval or Function().
JSFunction *fun = JS_GetObjectFunction(obj);
if (fun) {
if (JS_IsBuiltinEvalFunction(fun) || JS_IsBuiltinFunctionConstructor(fun)) {
JS_ReportError(cx, "Not allowed to access chrome eval or Function from content");
return nullptr;
}
}
}
DEBUG_CheckUnwrapSafety(obj, wrapper, origin, target);
if (existing && proxyProto == wrappedProto)
return Wrapper::Renew(cx, existing, obj, wrapper);
return Wrapper::New(cx, obj, proxyProto, parent, wrapper);
}
JSObject *
WrapperFactory::WrapForSameCompartment(JSContext *cx, HandleObject objArg)
{
RootedObject obj(cx, objArg);
MOZ_ASSERT(js::IsObjectInContextCompartment(obj, cx));
// NB: The contract of WrapForSameCompartment says that |obj| may or may not
// be a security wrapper. These checks implicitly handle the security
// wrapper case.
// Outerize if necessary. This, in combination with the check in
// PrepareForUnwrapping, means that calling JS_Wrap* always outerizes.
obj = JS_ObjectToOuterObject(cx, obj);
NS_ENSURE_TRUE(obj, nullptr);
if (dom::GetSameCompartmentWrapperForDOMBinding(*obj.address())) {
return obj;
}
MOZ_ASSERT(!dom::IsDOMObject(obj));
if (!IS_WN_REFLECTOR(obj))
return obj;
// Extract the WN. It should exist.
XPCWrappedNative *wn = XPCWrappedNative::Get(obj);
MOZ_ASSERT(wn, "Trying to wrap a dead WN!");
// The WN knows what to do.
RootedObject wrapper(cx, wn->GetSameCompartmentSecurityWrapper(cx));
MOZ_ASSERT_IF(wrapper != obj && IsComponentsObject(js::UncheckedUnwrap(obj)),
!Wrapper::wrapperHandler(wrapper)->isSafeToUnwrap());
return wrapper;
}
// Call WaiveXrayAndWrap when you have a JS object that you don't want to be
// wrapped in an Xray wrapper. cx->compartment is the compartment that will be
// using the returned object. If the object to be wrapped is already in the
// correct compartment, then this returns the unwrapped object.
bool
WrapperFactory::WaiveXrayAndWrap(JSContext *cx, jsval *vp)
{
if (JSVAL_IS_PRIMITIVE(*vp))
return JS_WrapValue(cx, vp);
JSObject *obj = js::UncheckedUnwrap(JSVAL_TO_OBJECT(*vp));
MOZ_ASSERT(!js::IsInnerObject(obj));
if (js::IsObjectInContextCompartment(obj, cx)) {
*vp = OBJECT_TO_JSVAL(obj);
return true;
}
// Even though waivers have no effect on access by scopes that don't subsume
// the underlying object, good defense-in-depth dictates that we should avoid
// handing out waivers to callers that can't use them. The transitive waiving
// machinery unconditionally calls WaiveXrayAndWrap on return values from
// waived functions, even though the return value might be not be same-origin
// with the function. So if we find ourselves trying to create a waiver for
// |cx|, we should check whether the caller has any business with waivers
// to things in |obj|'s compartment.
JSCompartment *target = js::GetContextCompartment(cx);
JSCompartment *origin = js::GetObjectCompartment(obj);
obj = AccessCheck::subsumes(target, origin) ? WaiveXray(cx, obj) : obj;
if (!obj)
return false;
*vp = OBJECT_TO_JSVAL(obj);
return JS_WrapValue(cx, vp);
}
JSObject *
WrapperFactory::WrapSOWObject(JSContext *cx, JSObject *objArg)
{
RootedObject obj(cx, objArg);
RootedObject proto(cx);
// If we're not allowing XBL scopes, that means we're running as a remote
// XUL domain, in which we can't have SOWs. We should never be called in
// that case.
MOZ_ASSERT(xpc::AllowXBLScope(js::GetContextCompartment(cx)));
if (!JS_GetPrototype(cx, obj, proto.address()))
return NULL;
JSObject *wrapperObj =
Wrapper::New(cx, obj, proto, JS_GetGlobalForObject(cx, obj),
&FilteringWrapper<SameCompartmentSecurityWrapper,
Opaque>::singleton);
return wrapperObj;
}
bool
WrapperFactory::IsComponentsObject(JSObject *obj)
{
const char *name = js::GetObjectClass(obj)->name;
return name[0] == 'n' && !strcmp(name, "nsXPCComponents");
}
JSObject *
WrapperFactory::WrapComponentsObject(JSContext *cx, HandleObject obj)
{
RootedObject proto(cx);
if (!JS_GetPrototype(cx, obj, proto.address()))
return NULL;
JSObject *wrapperObj =
Wrapper::New(cx, obj, proto, JS_GetGlobalForObject(cx, obj),
&FilteringWrapper<SameCompartmentSecurityWrapper, ComponentsObjectPolicy>::singleton);
return wrapperObj;
}
JSObject *
WrapperFactory::WrapForSameCompartmentXray(JSContext *cx, JSObject *obj)
{
// We should be same-compartment here.
MOZ_ASSERT(js::IsObjectInContextCompartment(obj, cx));
// Sort out what kind of Xray we can do. If we can't Xray, bail.
XrayType type = GetXrayType(obj);
if (type == NotXray)
return NULL;
// Select the appropriate proxy handler.
Wrapper *wrapper = NULL;
if (type == XrayForWrappedNative)
wrapper = &SCPermissiveXrayXPCWN::singleton;
else if (type == XrayForDOMObject)
wrapper = &SCPermissiveXrayDOM::singleton;
else
MOZ_ASSUME_UNREACHABLE("Bad Xray type");
// Make the Xray.
JSObject *parent = JS_GetGlobalForObject(cx, obj);
return Wrapper::New(cx, obj, NULL, parent, wrapper);
}
bool
WrapperFactory::XrayWrapperNotShadowing(JSObject *wrapper, jsid id)
{
ResolvingId *rid = ResolvingId::getResolvingIdFromWrapper(wrapper);
return rid->isXrayShadowing(id);
}
/*
* Calls to JS_TransplantObject* should go through these helpers here so that
* waivers get fixed up properly.
*/
static bool
FixWaiverAfterTransplant(JSContext *cx, HandleObject oldWaiver, HandleObject newobj)
{
MOZ_ASSERT(Wrapper::wrapperHandler(oldWaiver) == &XrayWaiver);
MOZ_ASSERT(!js::IsCrossCompartmentWrapper(newobj));
// Create a waiver in the new compartment. We know there's not one already
// because we _just_ transplanted, which means that |newobj| was either
// created from scratch, or was previously cross-compartment wrapper (which
// should have no waiver). CreateXrayWaiver asserts this.
JSObject *newWaiver = WrapperFactory::CreateXrayWaiver(cx, newobj);
if (!newWaiver)
return false;
// Update all the cross-compartment references to oldWaiver to point to
// newWaiver.
if (!js::RemapAllWrappersForObject(cx, oldWaiver, newWaiver))
return false;
// There should be no same-compartment references to oldWaiver, and we
// just remapped all cross-compartment references. It's dead, so we can
// remove it from the map.
XPCWrappedNativeScope *scope = GetObjectScope(oldWaiver);
JSObject *key = Wrapper::wrappedObject(oldWaiver);
MOZ_ASSERT(scope->mWaiverWrapperMap->Find(key));
scope->mWaiverWrapperMap->Remove(key);
return true;
}
JSObject *
TransplantObject(JSContext *cx, JS::HandleObject origobj, JS::HandleObject target)
{
RootedObject oldWaiver(cx, WrapperFactory::GetXrayWaiver(origobj));
RootedObject newIdentity(cx, JS_TransplantObject(cx, origobj, target));
if (!newIdentity || !oldWaiver)
return newIdentity;
if (!FixWaiverAfterTransplant(cx, oldWaiver, newIdentity))
return NULL;
return newIdentity;
}
JSObject *
TransplantObjectWithWrapper(JSContext *cx,
HandleObject origobj, HandleObject origwrapper,
HandleObject targetobj, HandleObject targetwrapper)
{
RootedObject oldWaiver(cx, WrapperFactory::GetXrayWaiver(origobj));
RootedObject newSameCompartmentWrapper(cx,
js_TransplantObjectWithWrapper(cx, origobj, origwrapper, targetobj,
targetwrapper));
if (!newSameCompartmentWrapper || !oldWaiver)
return newSameCompartmentWrapper;
RootedObject newIdentity(cx, Wrapper::wrappedObject(newSameCompartmentWrapper));
MOZ_ASSERT(js::IsWrapper(newIdentity));
if (!FixWaiverAfterTransplant(cx, oldWaiver, newIdentity))
return NULL;
return newSameCompartmentWrapper;
}
nsIGlobalObject *
GetNativeForGlobal(JSObject *obj)
{
MOZ_ASSERT(JS_IsGlobalObject(obj));
if (!EnsureCompartmentPrivate(obj)->scope)
return nullptr;
// Every global needs to hold a native as its private.
MOZ_ASSERT(GetObjectClass(obj)->flags & (JSCLASS_PRIVATE_IS_NSISUPPORTS |
JSCLASS_HAS_PRIVATE));
nsISupports *native =
static_cast<nsISupports *>(js::GetObjectPrivate(obj));
MOZ_ASSERT(native);
// In some cases (like for windows) it is a wrapped native,
// in other cases (sandboxes, backstage passes) it's just
// a direct pointer to the native. If it's a wrapped native
// let's unwrap it first.
if (nsCOMPtr<nsIXPConnectWrappedNative> wn = do_QueryInterface(native)) {
native = wn->Native();
}
nsCOMPtr<nsIGlobalObject> global = do_QueryInterface(native);
MOZ_ASSERT(global, "Native held by global needs to implement nsIGlobalObject!");
return global;
}
}