/* -*- Mode: C++; tab-width: 8; indent-tabs-mode: nil; c-basic-offset: 2 -*- */ /* 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 "nsCOMPtr.h" #include "nsIAtom.h" #include "nsXBLDocumentInfo.h" #include "nsIInputStream.h" #include "nsNameSpaceManager.h" #include "nsIURI.h" #include "nsIURL.h" #include "nsIChannel.h" #include "nsXPIDLString.h" #include "nsReadableUtils.h" #include "plstr.h" #include "nsIContent.h" #include "nsIDocument.h" #include "nsContentUtils.h" #include "ChildIterator.h" #ifdef MOZ_XUL #include "nsIXULDocument.h" #endif #include "nsIXMLContentSink.h" #include "nsContentCID.h" #include "mozilla/dom/XMLDocument.h" #include "jsapi.h" #include "nsXBLService.h" #include "nsIXPConnect.h" #include "nsIScriptContext.h" #include "nsCRT.h" // Event listeners #include "mozilla/EventListenerManager.h" #include "nsIDOMEventListener.h" #include "nsAttrName.h" #include "nsGkAtoms.h" #include "nsXBLPrototypeHandler.h" #include "nsXBLPrototypeBinding.h" #include "nsXBLBinding.h" #include "nsIPrincipal.h" #include "nsIScriptSecurityManager.h" #include "mozilla/dom/XBLChildrenElement.h" #include "prprf.h" #include "nsNodeUtils.h" #include "nsJSUtils.h" // Nasty hack. Maybe we could move some of the classinfo utility methods // (e.g. WrapNative) over to nsContentUtils? #include "nsDOMClassInfo.h" #include "mozilla/DeferredFinalize.h" #include "mozilla/dom/Element.h" #include "mozilla/dom/ScriptSettings.h" #include "mozilla/dom/ShadowRoot.h" #include "mozilla/ServoStyleSet.h" using namespace mozilla; using namespace mozilla::dom; // Helper classes /***********************************************************************/ // // The JS class for XBLBinding // static void XBLFinalize(JSFreeOp *fop, JSObject *obj) { nsXBLDocumentInfo* docInfo = static_cast(::JS_GetPrivate(obj)); DeferredFinalize(docInfo); } static bool XBLEnumerate(JSContext *cx, JS::Handle obj) { nsXBLPrototypeBinding* protoBinding = static_cast(::JS_GetReservedSlot(obj, 0).toPrivate()); MOZ_ASSERT(protoBinding); return protoBinding->ResolveAllFields(cx, obj); } static const JSClassOps gPrototypeJSClassOps = { nullptr, nullptr, nullptr, nullptr, XBLEnumerate, nullptr, nullptr, XBLFinalize, nullptr, nullptr, nullptr, nullptr }; static const JSClass gPrototypeJSClass = { "XBL prototype JSClass", JSCLASS_HAS_PRIVATE | JSCLASS_PRIVATE_IS_NSISUPPORTS | JSCLASS_FOREGROUND_FINALIZE | // Our one reserved slot holds the relevant nsXBLPrototypeBinding JSCLASS_HAS_RESERVED_SLOTS(1), &gPrototypeJSClassOps }; // Implementation ///////////////////////////////////////////////////////////////// // Constructors/Destructors nsXBLBinding::nsXBLBinding(nsXBLPrototypeBinding* aBinding) : mMarkedForDeath(false) , mUsingContentXBLScope(false) , mIsShadowRootBinding(false) , mPrototypeBinding(aBinding) { NS_ASSERTION(mPrototypeBinding, "Must have a prototype binding!"); // Grab a ref to the document info so the prototype binding won't die NS_ADDREF(mPrototypeBinding->XBLDocumentInfo()); } // Constructor used by web components. nsXBLBinding::nsXBLBinding(ShadowRoot* aShadowRoot, nsXBLPrototypeBinding* aBinding) : mMarkedForDeath(false), mUsingContentXBLScope(false), mIsShadowRootBinding(true), mPrototypeBinding(aBinding), mContent(aShadowRoot) { NS_ASSERTION(mPrototypeBinding, "Must have a prototype binding!"); // Grab a ref to the document info so the prototype binding won't die NS_ADDREF(mPrototypeBinding->XBLDocumentInfo()); } nsXBLBinding::~nsXBLBinding(void) { if (mContent && !mIsShadowRootBinding) { // It is unnecessary to uninstall anonymous content in a shadow tree // because the ShadowRoot itself is a DocumentFragment and does not // need any additional cleanup. nsXBLBinding::UninstallAnonymousContent(mContent->OwnerDoc(), mContent); } nsXBLDocumentInfo* info = mPrototypeBinding->XBLDocumentInfo(); NS_RELEASE(info); } NS_IMPL_CYCLE_COLLECTION_CLASS(nsXBLBinding) NS_IMPL_CYCLE_COLLECTION_UNLINK_BEGIN(nsXBLBinding) // XXX Probably can't unlink mPrototypeBinding->XBLDocumentInfo(), because // mPrototypeBinding is weak. if (tmp->mContent && !tmp->mIsShadowRootBinding) { nsXBLBinding::UninstallAnonymousContent(tmp->mContent->OwnerDoc(), tmp->mContent); } NS_IMPL_CYCLE_COLLECTION_UNLINK(mContent) NS_IMPL_CYCLE_COLLECTION_UNLINK(mNextBinding) NS_IMPL_CYCLE_COLLECTION_UNLINK(mDefaultInsertionPoint) NS_IMPL_CYCLE_COLLECTION_UNLINK(mInsertionPoints) NS_IMPL_CYCLE_COLLECTION_UNLINK(mAnonymousContentList) NS_IMPL_CYCLE_COLLECTION_UNLINK_END NS_IMPL_CYCLE_COLLECTION_TRAVERSE_BEGIN(nsXBLBinding) NS_CYCLE_COLLECTION_NOTE_EDGE_NAME(cb, "mPrototypeBinding->XBLDocumentInfo()"); cb.NoteXPCOMChild(tmp->mPrototypeBinding->XBLDocumentInfo()); NS_IMPL_CYCLE_COLLECTION_TRAVERSE(mContent) NS_IMPL_CYCLE_COLLECTION_TRAVERSE(mNextBinding) NS_IMPL_CYCLE_COLLECTION_TRAVERSE(mDefaultInsertionPoint) NS_IMPL_CYCLE_COLLECTION_TRAVERSE(mInsertionPoints) NS_IMPL_CYCLE_COLLECTION_TRAVERSE(mAnonymousContentList) NS_IMPL_CYCLE_COLLECTION_TRAVERSE_END NS_IMPL_CYCLE_COLLECTION_ROOT_NATIVE(nsXBLBinding, AddRef) NS_IMPL_CYCLE_COLLECTION_UNROOT_NATIVE(nsXBLBinding, Release) void nsXBLBinding::SetBaseBinding(nsXBLBinding* aBinding) { if (mNextBinding) { NS_ERROR("Base XBL binding is already defined!"); return; } mNextBinding = aBinding; // Comptr handles rel/add } nsXBLBinding* nsXBLBinding::GetBindingWithContent() { if (mContent) { return this; } return mNextBinding ? mNextBinding->GetBindingWithContent() : nullptr; } void nsXBLBinding::InstallAnonymousContent(nsIContent* aAnonParent, nsIContent* aElement, bool aChromeOnlyContent) { // We need to ensure two things. // (1) The anonymous content should be fooled into thinking it's in the bound // element's document, assuming that the bound element is in a document // Note that we don't change the current doc of aAnonParent here, since that // quite simply does not matter. aAnonParent is just a way of keeping refs // to all its kids, which are anonymous content from the point of view of // aElement. // (2) The children's parent back pointer should not be to this synthetic root // but should instead point to the enclosing parent element. nsIDocument* doc = aElement->GetUncomposedDoc(); bool allowScripts = AllowScripts(); nsAutoScriptBlocker scriptBlocker; for (nsIContent* child = aAnonParent->GetFirstChild(); child; child = child->GetNextSibling()) { child->UnbindFromTree(); if (aChromeOnlyContent) { child->SetFlags(NODE_CHROME_ONLY_ACCESS | NODE_IS_ROOT_OF_CHROME_ONLY_ACCESS); } nsresult rv = child->BindToTree(doc, aElement, mBoundElement, allowScripts); if (NS_FAILED(rv)) { // Oh, well... Just give up. // XXXbz This really shouldn't be a void method! child->UnbindFromTree(); return; } child->SetFlags(NODE_IS_ANONYMOUS_ROOT); #ifdef MOZ_XUL // To make XUL templates work (and other goodies that happen when // an element is added to a XUL document), we need to notify the // XUL document using its special API. nsCOMPtr xuldoc(do_QueryInterface(doc)); if (xuldoc) xuldoc->AddSubtreeToDocument(child); #endif } } void nsXBLBinding::UninstallAnonymousContent(nsIDocument* aDocument, nsIContent* aAnonParent) { nsAutoScriptBlocker scriptBlocker; // Hold a strong ref while doing this, just in case. nsCOMPtr anonParent = aAnonParent; #ifdef MOZ_XUL nsCOMPtr xuldoc = do_QueryInterface(aDocument); #endif for (nsIContent* child = aAnonParent->GetFirstChild(); child; child = child->GetNextSibling()) { child->UnbindFromTree(); #ifdef MOZ_XUL if (xuldoc) { xuldoc->RemoveSubtreeFromDocument(child); } #endif } } void nsXBLBinding::SetBoundElement(nsIContent* aElement) { mBoundElement = aElement; if (mNextBinding) mNextBinding->SetBoundElement(aElement); if (!mBoundElement) { return; } // Compute whether we're using an XBL scope. // // We disable XBL scopes for remote XUL, where we care about compat more // than security. So we need to know whether we're using an XBL scope so that // we can decide what to do about untrusted events when "allowuntrusted" // is not given in the handler declaration. nsCOMPtr go = mBoundElement->OwnerDoc()->GetScopeObject(); NS_ENSURE_TRUE_VOID(go && go->GetGlobalJSObject()); mUsingContentXBLScope = xpc::UseContentXBLScope(js::GetObjectCompartment(go->GetGlobalJSObject())); } bool nsXBLBinding::HasStyleSheets() const { // Find out if we need to re-resolve style. We'll need to do this // if we have additional stylesheets in our binding document. if (mPrototypeBinding->HasStyleSheets()) return true; return mNextBinding ? mNextBinding->HasStyleSheets() : false; } void nsXBLBinding::GenerateAnonymousContent() { NS_ASSERTION(!nsContentUtils::IsSafeToRunScript(), "Someone forgot a script blocker"); // Fetch the content element for this binding. nsIContent* content = mPrototypeBinding->GetImmediateChild(nsGkAtoms::content); if (!content) { // We have no anonymous content. if (mNextBinding) mNextBinding->GenerateAnonymousContent(); return; } // Find out if we're really building kids or if we're just // using the attribute-setting shorthand hack. uint32_t contentCount = content->GetChildCount(); // Plan to build the content by default. bool hasContent = (contentCount > 0); if (hasContent) { nsIDocument* doc = mBoundElement->OwnerDoc(); nsCOMPtr clonedNode; nsCOMArray nodesWithProperties; nsNodeUtils::Clone(content, true, doc->NodeInfoManager(), nodesWithProperties, getter_AddRefs(clonedNode)); mContent = clonedNode->AsElement(); // Search for elements in the XBL content. In the presence // of multiple default insertion points, we use the last one in document // order. for (nsIContent* child = mContent; child; child = child->GetNextNode(mContent)) { if (child->NodeInfo()->Equals(nsGkAtoms::children, kNameSpaceID_XBL)) { XBLChildrenElement* point = static_cast(child); if (point->IsDefaultInsertion()) { mDefaultInsertionPoint = point; } else { mInsertionPoints.AppendElement(point); } } } // Do this after looking for as this messes up the parent // pointer which would make the GetNextNode call above fail InstallAnonymousContent(mContent, mBoundElement, mPrototypeBinding->ChromeOnlyContent()); // Insert explicit children into insertion points if (mDefaultInsertionPoint && mInsertionPoints.IsEmpty()) { ExplicitChildIterator iter(mBoundElement); for (nsIContent* child = iter.GetNextChild(); child; child = iter.GetNextChild()) { mDefaultInsertionPoint->AppendInsertedChild(child); } } else { // It is odd to come into this code if mInsertionPoints is not empty, but // we need to make sure to do the compatibility hack below if the bound // node has any non or children. ExplicitChildIterator iter(mBoundElement); for (nsIContent* child = iter.GetNextChild(); child; child = iter.GetNextChild()) { XBLChildrenElement* point = FindInsertionPointForInternal(child); if (point) { point->AppendInsertedChild(child); } else { NodeInfo *ni = child->NodeInfo(); if (ni->NamespaceID() != kNameSpaceID_XUL || (!ni->Equals(nsGkAtoms::_template) && !ni->Equals(nsGkAtoms::observes))) { // Compatibility hack. For some reason the original XBL // implementation dropped the content of a binding if any child of // the bound element didn't match any of the in the // binding. This became a pseudo-API that we have to maintain. // Undo InstallAnonymousContent UninstallAnonymousContent(doc, mContent); // Clear out our children elements to avoid dangling references. ClearInsertionPoints(); // Pretend as though there was no content in the binding. mContent = nullptr; return; } } } } // Set binding parent on default content if need if (mDefaultInsertionPoint) { mDefaultInsertionPoint->MaybeSetupDefaultContent(); } for (uint32_t i = 0; i < mInsertionPoints.Length(); ++i) { mInsertionPoints[i]->MaybeSetupDefaultContent(); } mPrototypeBinding->SetInitialAttributes(mBoundElement, mContent); } // Always check the content element for potential attributes. // This shorthand hack always happens, even when we didn't // build anonymous content. BorrowedAttrInfo attrInfo; for (uint32_t i = 0; (attrInfo = content->GetAttrInfoAt(i)); ++i) { int32_t namespaceID = attrInfo.mName->NamespaceID(); // Hold a strong reference here so that the atom doesn't go away during // UnsetAttr. nsCOMPtr name = attrInfo.mName->LocalName(); if (name != nsGkAtoms::includes) { if (!nsContentUtils::HasNonEmptyAttr(mBoundElement, namespaceID, name)) { nsAutoString value2; attrInfo.mValue->ToString(value2); mBoundElement->SetAttr(namespaceID, name, attrInfo.mName->GetPrefix(), value2, false); } } // Conserve space by wiping the attributes off the clone. if (mContent) mContent->UnsetAttr(namespaceID, name, false); } // Now that we've finished shuffling the tree around, go ahead and restyle it // since frame construction is about to happen. nsIPresShell* presShell = mBoundElement->OwnerDoc()->GetShell(); ServoStyleSet* servoSet = presShell->StyleSet()->GetAsServo(); if (servoSet) { mBoundElement->SetHasDirtyDescendantsForServo(); servoSet->StyleNewChildren(mBoundElement); } } nsIURI* nsXBLBinding::GetSourceDocURI() { nsIContent* targetContent = mPrototypeBinding->GetImmediateChild(nsGkAtoms::content); if (!targetContent) { return nullptr; } return targetContent->OwnerDoc()->GetDocumentURI(); } XBLChildrenElement* nsXBLBinding::FindInsertionPointFor(nsIContent* aChild) { // XXX We should get rid of this function as it causes us to traverse the // binding chain multiple times if (mContent) { return FindInsertionPointForInternal(aChild); } return mNextBinding ? mNextBinding->FindInsertionPointFor(aChild) : nullptr; } XBLChildrenElement* nsXBLBinding::FindInsertionPointForInternal(nsIContent* aChild) { for (uint32_t i = 0; i < mInsertionPoints.Length(); ++i) { XBLChildrenElement* point = mInsertionPoints[i]; if (point->Includes(aChild)) { return point; } } return mDefaultInsertionPoint; } void nsXBLBinding::ClearInsertionPoints() { if (mDefaultInsertionPoint) { mDefaultInsertionPoint->ClearInsertedChildren(); } for (uint32_t i = 0; i < mInsertionPoints.Length(); ++i) { mInsertionPoints[i]->ClearInsertedChildren(); } } nsAnonymousContentList* nsXBLBinding::GetAnonymousNodeList() { if (!mContent) { return mNextBinding ? mNextBinding->GetAnonymousNodeList() : nullptr; } if (!mAnonymousContentList) { mAnonymousContentList = new nsAnonymousContentList(mContent); } return mAnonymousContentList; } void nsXBLBinding::InstallEventHandlers() { // Don't install handlers if scripts aren't allowed. if (AllowScripts()) { // Fetch the handlers prototypes for this binding. nsXBLPrototypeHandler* handlerChain = mPrototypeBinding->GetPrototypeHandlers(); if (handlerChain) { EventListenerManager* manager = mBoundElement->GetOrCreateListenerManager(); if (!manager) return; bool isChromeDoc = nsContentUtils::IsChromeDoc(mBoundElement->OwnerDoc()); bool isChromeBinding = mPrototypeBinding->IsChrome(); nsXBLPrototypeHandler* curr; for (curr = handlerChain; curr; curr = curr->GetNextHandler()) { // Fetch the event type. nsCOMPtr eventAtom = curr->GetEventName(); if (!eventAtom || eventAtom == nsGkAtoms::keyup || eventAtom == nsGkAtoms::keydown || eventAtom == nsGkAtoms::keypress) continue; nsXBLEventHandler* handler = curr->GetEventHandler(); if (handler) { // Figure out if we're using capturing or not. EventListenerFlags flags; flags.mCapture = (curr->GetPhase() == NS_PHASE_CAPTURING); // If this is a command, add it in the system event group if ((curr->GetType() & (NS_HANDLER_TYPE_XBL_COMMAND | NS_HANDLER_TYPE_SYSTEM)) && (isChromeBinding || mBoundElement->IsInNativeAnonymousSubtree())) { flags.mInSystemGroup = true; } bool hasAllowUntrustedAttr = curr->HasAllowUntrustedAttr(); if ((hasAllowUntrustedAttr && curr->AllowUntrustedEvents()) || (!hasAllowUntrustedAttr && !isChromeDoc && !mUsingContentXBLScope)) { flags.mAllowUntrustedEvents = true; } manager->AddEventListenerByType(handler, nsDependentAtomString(eventAtom), flags); } } const nsCOMArray* keyHandlers = mPrototypeBinding->GetKeyEventHandlers(); int32_t i; for (i = 0; i < keyHandlers->Count(); ++i) { nsXBLKeyEventHandler* handler = keyHandlers->ObjectAt(i); handler->SetIsBoundToChrome(isChromeDoc); handler->SetUsingContentXBLScope(mUsingContentXBLScope); nsAutoString type; handler->GetEventName(type); // If this is a command, add it in the system event group, otherwise // add it to the standard event group. // Figure out if we're using capturing or not. EventListenerFlags flags; flags.mCapture = (handler->GetPhase() == NS_PHASE_CAPTURING); if ((handler->GetType() & (NS_HANDLER_TYPE_XBL_COMMAND | NS_HANDLER_TYPE_SYSTEM)) && (isChromeBinding || mBoundElement->IsInNativeAnonymousSubtree())) { flags.mInSystemGroup = true; } // For key handlers we have to set mAllowUntrustedEvents flag. // Whether the handling of the event is allowed or not is handled in // nsXBLKeyEventHandler::HandleEvent flags.mAllowUntrustedEvents = true; manager->AddEventListenerByType(handler, type, flags); } } } if (mNextBinding) mNextBinding->InstallEventHandlers(); } nsresult nsXBLBinding::InstallImplementation() { // Always install the base class properties first, so that // derived classes can reference the base class properties. if (mNextBinding) { nsresult rv = mNextBinding->InstallImplementation(); NS_ENSURE_SUCCESS(rv, rv); } // iterate through each property in the prototype's list and install the property. if (AllowScripts()) return mPrototypeBinding->InstallImplementation(this); return NS_OK; } nsIAtom* nsXBLBinding::GetBaseTag(int32_t* aNameSpaceID) { nsIAtom *tag = mPrototypeBinding->GetBaseTag(aNameSpaceID); if (!tag && mNextBinding) return mNextBinding->GetBaseTag(aNameSpaceID); return tag; } void nsXBLBinding::AttributeChanged(nsIAtom* aAttribute, int32_t aNameSpaceID, bool aRemoveFlag, bool aNotify) { // XXX Change if we ever allow multiple bindings in a chain to contribute anonymous content if (!mContent) { if (mNextBinding) mNextBinding->AttributeChanged(aAttribute, aNameSpaceID, aRemoveFlag, aNotify); } else { mPrototypeBinding->AttributeChanged(aAttribute, aNameSpaceID, aRemoveFlag, mBoundElement, mContent, aNotify); } } void nsXBLBinding::ExecuteAttachedHandler() { if (mNextBinding) mNextBinding->ExecuteAttachedHandler(); if (AllowScripts()) mPrototypeBinding->BindingAttached(mBoundElement); } void nsXBLBinding::ExecuteDetachedHandler() { if (AllowScripts()) mPrototypeBinding->BindingDetached(mBoundElement); if (mNextBinding) mNextBinding->ExecuteDetachedHandler(); } void nsXBLBinding::UnhookEventHandlers() { nsXBLPrototypeHandler* handlerChain = mPrototypeBinding->GetPrototypeHandlers(); if (handlerChain) { EventListenerManager* manager = mBoundElement->GetExistingListenerManager(); if (!manager) { return; } bool isChromeBinding = mPrototypeBinding->IsChrome(); nsXBLPrototypeHandler* curr; for (curr = handlerChain; curr; curr = curr->GetNextHandler()) { nsXBLEventHandler* handler = curr->GetCachedEventHandler(); if (!handler) { continue; } nsCOMPtr eventAtom = curr->GetEventName(); if (!eventAtom || eventAtom == nsGkAtoms::keyup || eventAtom == nsGkAtoms::keydown || eventAtom == nsGkAtoms::keypress) continue; // Figure out if we're using capturing or not. EventListenerFlags flags; flags.mCapture = (curr->GetPhase() == NS_PHASE_CAPTURING); // If this is a command, remove it from the system event group, // otherwise remove it from the standard event group. if ((curr->GetType() & (NS_HANDLER_TYPE_XBL_COMMAND | NS_HANDLER_TYPE_SYSTEM)) && (isChromeBinding || mBoundElement->IsInNativeAnonymousSubtree())) { flags.mInSystemGroup = true; } manager->RemoveEventListenerByType(handler, nsDependentAtomString(eventAtom), flags); } const nsCOMArray* keyHandlers = mPrototypeBinding->GetKeyEventHandlers(); int32_t i; for (i = 0; i < keyHandlers->Count(); ++i) { nsXBLKeyEventHandler* handler = keyHandlers->ObjectAt(i); nsAutoString type; handler->GetEventName(type); // Figure out if we're using capturing or not. EventListenerFlags flags; flags.mCapture = (handler->GetPhase() == NS_PHASE_CAPTURING); // If this is a command, remove it from the system event group, otherwise // remove it from the standard event group. if ((handler->GetType() & (NS_HANDLER_TYPE_XBL_COMMAND | NS_HANDLER_TYPE_SYSTEM)) && (isChromeBinding || mBoundElement->IsInNativeAnonymousSubtree())) { flags.mInSystemGroup = true; } manager->RemoveEventListenerByType(handler, type, flags); } } } static void UpdateInsertionParent(XBLChildrenElement* aPoint, nsIContent* aOldBoundElement) { if (aPoint->IsDefaultInsertion()) { return; } for (size_t i = 0; i < aPoint->InsertedChildrenLength(); ++i) { nsIContent* child = aPoint->InsertedChild(i); MOZ_ASSERT(child->GetParentNode()); // Here, we're iterating children that we inserted. There are two cases: // either |child| is an explicit child of |aOldBoundElement| and is no // longer inserted anywhere or it's a child of a element // parented to |aOldBoundElement|. In the former case, the child is no // longer inserted anywhere, so we set its insertion parent to null. In the // latter case, the child is now inserted into |aOldBoundElement| from some // binding above us, so we set its insertion parent to aOldBoundElement. if (child->GetParentNode() == aOldBoundElement) { child->SetXBLInsertionParent(nullptr); } else { child->SetXBLInsertionParent(aOldBoundElement); } } } void nsXBLBinding::ChangeDocument(nsIDocument* aOldDocument, nsIDocument* aNewDocument) { if (aOldDocument == aNewDocument) return; // Now the binding dies. Unhook our prototypes. if (mPrototypeBinding->HasImplementation()) { AutoJSAPI jsapi; // Init might fail here if we've cycle-collected the global object, since // the Unlink phase of cycle collection happens after JS GC finalization. // But in that case, we don't care about fixing the prototype chain, since // everything's going away immediately. if (jsapi.Init(aOldDocument->GetScopeObject())) { JSContext* cx = jsapi.cx(); JS::Rooted scriptObject(cx, mBoundElement->GetWrapper()); if (scriptObject) { // XXX Stay in sync! What if a layered binding has an // ?! // XXXbz what does that comment mean, really? It seems to date // back to when there was such a thing as an , whever // that was... // Find the right prototype. JSAutoCompartment ac(cx, scriptObject); JS::Rooted base(cx, scriptObject); JS::Rooted proto(cx); for ( ; true; base = proto) { // Will break out on null proto if (!JS_GetPrototype(cx, base, &proto)) { return; } if (!proto) { break; } if (JS_GetClass(proto) != &gPrototypeJSClass) { // Clearly not the right class continue; } RefPtr docInfo = static_cast(::JS_GetPrivate(proto)); if (!docInfo) { // Not the proto we seek continue; } JS::Value protoBinding = ::JS_GetReservedSlot(proto, 0); if (protoBinding.toPrivate() != mPrototypeBinding) { // Not the right binding continue; } // Alright! This is the right prototype. Pull it out of the // proto chain. JS::Rooted grandProto(cx); if (!JS_GetPrototype(cx, proto, &grandProto)) { return; } ::JS_SetPrototype(cx, base, grandProto); break; } mPrototypeBinding->UndefineFields(cx, scriptObject); // Don't remove the reference from the document to the // wrapper here since it'll be removed by the element // itself when that's taken out of the document. } } } // Remove our event handlers UnhookEventHandlers(); { nsAutoScriptBlocker scriptBlocker; // Then do our ancestors. This reverses the construction order, so that at // all times things are consistent as far as everyone is concerned. if (mNextBinding) { mNextBinding->ChangeDocument(aOldDocument, aNewDocument); } // Update the anonymous content. // XXXbz why not only for style bindings? if (mContent && !mIsShadowRootBinding) { nsXBLBinding::UninstallAnonymousContent(aOldDocument, mContent); } // Now that we've unbound our anonymous content from the tree and updated // its binding parent, update the insertion parent for content inserted // into our elements. if (mDefaultInsertionPoint) { UpdateInsertionParent(mDefaultInsertionPoint, mBoundElement); } for (size_t i = 0; i < mInsertionPoints.Length(); ++i) { UpdateInsertionParent(mInsertionPoints[i], mBoundElement); } // Now that our inserted children no longer think they're inserted // anywhere, make sure our internal state reflects that as well. ClearInsertionPoints(); } } bool nsXBLBinding::InheritsStyle() const { // XXX Will have to change if we ever allow multiple bindings to contribute anonymous content. // Most derived binding with anonymous content determines style inheritance for now. // XXX What about bindings with but no kids, e.g., my treecell-text binding? if (mContent) return mPrototypeBinding->InheritsStyle(); if (mNextBinding) return mNextBinding->InheritsStyle(); return true; } void nsXBLBinding::WalkRules(nsIStyleRuleProcessor::EnumFunc aFunc, void* aData) { if (mNextBinding) mNextBinding->WalkRules(aFunc, aData); nsIStyleRuleProcessor *rules = mPrototypeBinding->GetRuleProcessor(); if (rules) (*aFunc)(rules, aData); } // Internal helper methods //////////////////////////////////////////////////////////////// // Get or create a WeakMap object on a given XBL-hosting global. // // The scheme is as follows. XBL-hosting globals (either privileged content // Windows or XBL scopes) get two lazily-defined WeakMap properties. Each // WeakMap is keyed by the grand-proto - i.e. the original prototype of the // content before it was bound, and the prototype of the class object that we // splice in. The values in the WeakMap are simple dictionary-style objects, // mapping from XBL class names to class objects. static JSObject* GetOrCreateClassObjectMap(JSContext *cx, JS::Handle scope, const char *mapName) { AssertSameCompartment(cx, scope); MOZ_ASSERT(JS_IsGlobalObject(scope)); MOZ_ASSERT(scope == xpc::GetXBLScopeOrGlobal(cx, scope)); // First, see if the map is already defined. JS::Rooted desc(cx); if (!JS_GetOwnPropertyDescriptor(cx, scope, mapName, &desc)) { return nullptr; } if (desc.object() && desc.value().isObject() && JS::IsWeakMapObject(&desc.value().toObject())) { return &desc.value().toObject(); } // It's not there. Create and define it. JS::Rooted map(cx, JS::NewWeakMapObject(cx)); if (!map || !JS_DefineProperty(cx, scope, mapName, map, JSPROP_PERMANENT | JSPROP_READONLY, JS_STUBGETTER, JS_STUBSETTER)) { return nullptr; } return map; } static JSObject* GetOrCreateMapEntryForPrototype(JSContext *cx, JS::Handle proto) { AssertSameCompartment(cx, proto); // We want to hang our class objects off the XBL scope. But since we also // hoist anonymous content into the XBL scope, this creates the potential for // tricky collisions, since we can simultaneously have a bound in-content // node with grand-proto HTMLDivElement and a bound anonymous node whose // grand-proto is the XBL scope's cross-compartment wrapper to HTMLDivElement. // Since we have to wrap the WeakMap keys into its scope, this distinction // would be lost if we don't do something about it. // // So we define two maps - one class objects that live in content (prototyped // to content prototypes), and the other for class objects that live in the // XBL scope (prototyped to cross-compartment-wrapped content prototypes). const char* name = xpc::IsInContentXBLScope(proto) ? "__ContentClassObjectMap__" : "__XBLClassObjectMap__"; // Now, enter the XBL scope, since that's where we need to operate, and wrap // the proto accordingly. We hang the map off of the content XBL scope for // content, and the Window for chrome (whether add-ons are involved or not). JS::Rooted scope(cx, xpc::GetXBLScopeOrGlobal(cx, proto)); NS_ENSURE_TRUE(scope, nullptr); MOZ_ASSERT(js::GetGlobalForObjectCrossCompartment(scope) == scope); JS::Rooted wrappedProto(cx, proto); JSAutoCompartment ac(cx, scope); if (!JS_WrapObject(cx, &wrappedProto)) { return nullptr; } // Grab the appropriate WeakMap. JS::Rooted map(cx, GetOrCreateClassObjectMap(cx, scope, name)); if (!map) { return nullptr; } // See if we already have a map entry for that prototype. JS::Rooted val(cx); if (!JS::GetWeakMapEntry(cx, map, wrappedProto, &val)) { return nullptr; } if (val.isObject()) { return &val.toObject(); } // We don't have an entry. Create one and stick it in the map. JS::Rooted entry(cx); entry = JS_NewObjectWithGivenProto(cx, nullptr, nullptr); if (!entry) { return nullptr; } JS::Rooted entryVal(cx, JS::ObjectValue(*entry)); if (!JS::SetWeakMapEntry(cx, map, wrappedProto, entryVal)) { NS_WARNING("SetWeakMapEntry failed, probably due to non-preservable WeakMap " "key. XBL binding will fail for this element."); return nullptr; } return entry; } static nsXBLPrototypeBinding* GetProtoBindingFromClassObject(JSObject* obj) { MOZ_ASSERT(JS_GetClass(obj) == &gPrototypeJSClass); return static_cast(::JS_GetReservedSlot(obj, 0).toPrivate()); } // static nsresult nsXBLBinding::DoInitJSClass(JSContext *cx, JS::Handle obj, const nsAFlatString& aClassName, nsXBLPrototypeBinding* aProtoBinding, JS::MutableHandle aClassObject, bool* aNew) { MOZ_ASSERT(obj); // Note that, now that NAC reflectors are created in the XBL scope, the // reflector is not necessarily same-compartment with the document. So we'll // end up creating a separate instance of the oddly-named XBL class object // and defining it as a property on the XBL scope's global. This works fine, // but we need to make sure never to assume that the the reflector and // prototype are same-compartment with the bound document. JS::Rooted global(cx, js::GetGlobalForObjectCrossCompartment(obj)); // We never store class objects in add-on scopes. JS::Rooted xblScope(cx, xpc::GetXBLScopeOrGlobal(cx, global)); NS_ENSURE_TRUE(xblScope, NS_ERROR_UNEXPECTED); JS::Rooted parent_proto(cx); { JS::RootedObject wrapped(cx, obj); JSAutoCompartment ac(cx, xblScope); if (!JS_WrapObject(cx, &wrapped)) { return NS_ERROR_FAILURE; } if (!JS_GetPrototype(cx, wrapped, &parent_proto)) { return NS_ERROR_FAILURE; } } if (!JS_WrapObject(cx, &parent_proto)) { return NS_ERROR_FAILURE; } // Get the map entry for the parent prototype. In the one-off case that the // parent prototype is null, we somewhat hackily just use the WeakMap itself // as a property holder. JS::Rooted holder(cx); if (parent_proto) { holder = GetOrCreateMapEntryForPrototype(cx, parent_proto); } else { JSAutoCompartment innerAC(cx, xblScope); holder = GetOrCreateClassObjectMap(cx, xblScope, "__ContentClassObjectMap__"); } if (NS_WARN_IF(!holder)) { return NS_ERROR_FAILURE; } js::AssertSameCompartment(holder, xblScope); JSAutoCompartment ac(cx, holder); // Look up the class on the property holder. The only properties on the // holder should be class objects. If we don't find the class object, we need // to create and define it. JS::Rooted proto(cx); JS::Rooted desc(cx); if (!JS_GetOwnUCPropertyDescriptor(cx, holder, aClassName.get(), aClassName.Length(), &desc)) { return NS_ERROR_OUT_OF_MEMORY; } *aNew = !desc.object(); if (desc.object()) { proto = &desc.value().toObject(); DebugOnly cachedBinding = GetProtoBindingFromClassObject(js::UncheckedUnwrap(proto)); MOZ_ASSERT(cachedBinding == aProtoBinding); } else { // We need to create the prototype. First, enter the compartment where it's // going to live, and create it. JSAutoCompartment ac2(cx, global); proto = JS_NewObjectWithGivenProto(cx, &gPrototypeJSClass, parent_proto); if (!proto) { return NS_ERROR_OUT_OF_MEMORY; } // Keep this proto binding alive while we're alive. Do this first so that // we can guarantee that in XBLFinalize this will be non-null. // Note that we can't just store aProtoBinding in the private and // addref/release the nsXBLDocumentInfo through it, because cycle // collection doesn't seem to work right if the private is not an // nsISupports. nsXBLDocumentInfo* docInfo = aProtoBinding->XBLDocumentInfo(); ::JS_SetPrivate(proto, docInfo); NS_ADDREF(docInfo); JS_SetReservedSlot(proto, 0, JS::PrivateValue(aProtoBinding)); // Next, enter the compartment of the property holder, wrap the proto, and // stick it on. JSAutoCompartment ac3(cx, holder); if (!JS_WrapObject(cx, &proto) || !JS_DefineUCProperty(cx, holder, aClassName.get(), -1, proto, JSPROP_READONLY | JSPROP_PERMANENT, JS_STUBGETTER, JS_STUBSETTER)) { return NS_ERROR_OUT_OF_MEMORY; } } // Whew. We have the proto. Wrap it back into the compartment of |obj|, // splice it in, and return it. JSAutoCompartment ac4(cx, obj); if (!JS_WrapObject(cx, &proto) || !JS_SetPrototype(cx, obj, proto)) { return NS_ERROR_FAILURE; } aClassObject.set(proto); return NS_OK; } bool nsXBLBinding::AllowScripts() { return mBoundElement && mPrototypeBinding->GetAllowScripts(); } nsXBLBinding* nsXBLBinding::RootBinding() { if (mNextBinding) return mNextBinding->RootBinding(); return this; } bool nsXBLBinding::ResolveAllFields(JSContext *cx, JS::Handle obj) const { if (!mPrototypeBinding->ResolveAllFields(cx, obj)) { return false; } if (mNextBinding) { return mNextBinding->ResolveAllFields(cx, obj); } return true; } bool nsXBLBinding::LookupMember(JSContext* aCx, JS::Handle aId, JS::MutableHandle aDesc) { // We should never enter this function with a pre-filled property descriptor. MOZ_ASSERT(!aDesc.object()); // Get the string as an nsString before doing anything, so we can make // convenient comparisons during our search. if (!JSID_IS_STRING(aId)) { return true; } nsAutoJSString name; if (!name.init(aCx, JSID_TO_STRING(aId))) { return false; } // We have a weak reference to our bound element, so make sure it's alive. if (!mBoundElement || !mBoundElement->GetWrapper()) { return false; } // Get the scope of mBoundElement and the associated XBL scope. We should only // be calling into this machinery if we're running in a separate XBL scope. // // Note that we only end up in LookupMember for XrayWrappers from XBL scopes // into content. So for NAC reflectors that live in the XBL scope, we should // never get here. But on the off-chance that someone adds new callsites to // LookupMember, we do a release-mode assertion as belt-and-braces. // We do a release-mode assertion here to be extra safe. // // This code is only called for content XBL, so we don't have to worry about // add-on scopes here. JS::Rooted boundScope(aCx, js::GetGlobalForObjectCrossCompartment(mBoundElement->GetWrapper())); MOZ_RELEASE_ASSERT(!xpc::IsInAddonScope(boundScope)); MOZ_RELEASE_ASSERT(!xpc::IsInContentXBLScope(boundScope)); JS::Rooted xblScope(aCx, xpc::GetXBLScope(aCx, boundScope)); NS_ENSURE_TRUE(xblScope, false); MOZ_ASSERT(boundScope != xblScope); // Enter the xbl scope and invoke the internal version. { JSAutoCompartment ac(aCx, xblScope); JS::Rooted id(aCx, aId); if (!LookupMemberInternal(aCx, name, id, aDesc, xblScope)) { return false; } } // Wrap into the caller's scope. return JS_WrapPropertyDescriptor(aCx, aDesc); } bool nsXBLBinding::LookupMemberInternal(JSContext* aCx, nsString& aName, JS::Handle aNameAsId, JS::MutableHandle aDesc, JS::Handle aXBLScope) { // First, see if we have an implementation. If we don't, it means that this // binding doesn't have a class object, and thus doesn't have any members. // Skip it. if (!PrototypeBinding()->HasImplementation()) { if (!mNextBinding) { return true; } return mNextBinding->LookupMemberInternal(aCx, aName, aNameAsId, aDesc, aXBLScope); } // Find our class object. It's in a protected scope and permanent just in case, // so should be there no matter what. JS::Rooted classObject(aCx); if (!JS_GetUCProperty(aCx, aXBLScope, PrototypeBinding()->ClassName().get(), -1, &classObject)) { return false; } // The bound element may have been adoped by a document and have a different // wrapper (and different xbl scope) than when the binding was applied, in // this case getting the class object will fail. Behave as if the class // object did not exist. if (classObject.isUndefined()) { return true; } MOZ_ASSERT(classObject.isObject()); // Look for the property on this binding. If it's not there, try the next // binding on the chain. nsXBLProtoImpl* impl = mPrototypeBinding->GetImplementation(); JS::Rooted object(aCx, &classObject.toObject()); if (impl && !impl->LookupMember(aCx, aName, aNameAsId, aDesc, object)) { return false; } if (aDesc.object() || !mNextBinding) { return true; } return mNextBinding->LookupMemberInternal(aCx, aName, aNameAsId, aDesc, aXBLScope); } bool nsXBLBinding::HasField(nsString& aName) { // See if this binding has such a field. return mPrototypeBinding->FindField(aName) || (mNextBinding && mNextBinding->HasField(aName)); } void nsXBLBinding::MarkForDeath() { mMarkedForDeath = true; ExecuteDetachedHandler(); } bool nsXBLBinding::ImplementsInterface(REFNSIID aIID) const { return mPrototypeBinding->ImplementsInterface(aIID) || (mNextBinding && mNextBinding->ImplementsInterface(aIID)); }