/* -*- Mode: C++; tab-width: 2; indent-tabs-mode: nil; c-basic-offset: 2 -*- */ /* vim: set ts=2 sw=2 et tw=79: */ /* 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 "nsBindingManager.h" #include "nsCOMPtr.h" #include "nsXBLService.h" #include "nsIInputStream.h" #include "nsIURI.h" #include "nsIURL.h" #include "nsIChannel.h" #include "nsXPIDLString.h" #include "nsNetUtil.h" #include "plstr.h" #include "nsIContent.h" #include "nsIDOMElement.h" #include "nsIDocument.h" #include "nsContentUtils.h" #include "nsIPresShell.h" #include "nsIXMLContentSink.h" #include "nsContentCID.h" #include "mozilla/dom/XMLDocument.h" #include "nsIStreamListener.h" #include "ChildIterator.h" #include "nsXBLBinding.h" #include "nsXBLPrototypeBinding.h" #include "nsXBLDocumentInfo.h" #include "mozilla/dom/XBLChildrenElement.h" #include "nsIStyleRuleProcessor.h" #include "nsRuleProcessorData.h" #include "nsIWeakReference.h" #include "nsWrapperCacheInlines.h" #include "nsIXPConnect.h" #include "nsDOMCID.h" #include "nsIDOMScriptObjectFactory.h" #include "nsIScriptGlobalObject.h" #include "nsTHashtable.h" #include "nsIScriptContext.h" #include "xpcpublic.h" #include "jswrapper.h" #include "nsCxPusher.h" #include "nsThreadUtils.h" #include "mozilla/dom/NodeListBinding.h" using namespace mozilla; using namespace mozilla::dom; // Implement our nsISupports methods NS_IMPL_CYCLE_COLLECTION_CLASS(nsBindingManager) NS_IMPL_CYCLE_COLLECTION_UNLINK_BEGIN(nsBindingManager) tmp->mDestroyed = true; if (tmp->mBoundContentSet) tmp->mBoundContentSet->Clear(); if (tmp->mDocumentTable) tmp->mDocumentTable->Clear(); if (tmp->mLoadingDocTable) tmp->mLoadingDocTable->Clear(); if (tmp->mWrapperTable) { tmp->mWrapperTable->Clear(); tmp->mWrapperTable = nullptr; } NS_IMPL_CYCLE_COLLECTION_UNLINK(mAttachedStack) if (tmp->mProcessAttachedQueueEvent) { tmp->mProcessAttachedQueueEvent->Revoke(); } NS_IMPL_CYCLE_COLLECTION_UNLINK_END static PLDHashOperator DocumentInfoHashtableTraverser(nsIURI* key, nsXBLDocumentInfo* di, void* userArg) { nsCycleCollectionTraversalCallback *cb = static_cast(userArg); NS_CYCLE_COLLECTION_NOTE_EDGE_NAME(*cb, "mDocumentTable value"); cb->NoteXPCOMChild(di); return PL_DHASH_NEXT; } static PLDHashOperator LoadingDocHashtableTraverser(nsIURI* key, nsIStreamListener* sl, void* userArg) { nsCycleCollectionTraversalCallback *cb = static_cast(userArg); NS_CYCLE_COLLECTION_NOTE_EDGE_NAME(*cb, "mLoadingDocTable value"); cb->NoteXPCOMChild(sl); return PL_DHASH_NEXT; } NS_IMPL_CYCLE_COLLECTION_TRAVERSE_BEGIN(nsBindingManager) // The hashes keyed on nsIContent are traversed from the nsIContent itself. if (tmp->mDocumentTable) tmp->mDocumentTable->EnumerateRead(&DocumentInfoHashtableTraverser, &cb); if (tmp->mLoadingDocTable) tmp->mLoadingDocTable->EnumerateRead(&LoadingDocHashtableTraverser, &cb); NS_IMPL_CYCLE_COLLECTION_TRAVERSE(mAttachedStack) // No need to traverse mProcessAttachedQueueEvent, since it'll just // fire at some point or become revoke and drop its ref to us. NS_IMPL_CYCLE_COLLECTION_TRAVERSE_END NS_INTERFACE_MAP_BEGIN_CYCLE_COLLECTION(nsBindingManager) NS_INTERFACE_MAP_ENTRY(nsIMutationObserver) NS_INTERFACE_MAP_ENTRY(nsISupports) NS_INTERFACE_MAP_END NS_IMPL_CYCLE_COLLECTING_ADDREF(nsBindingManager) NS_IMPL_CYCLE_COLLECTING_RELEASE(nsBindingManager) // Constructors/Destructors nsBindingManager::nsBindingManager(nsIDocument* aDocument) : mProcessingAttachedStack(false), mDestroyed(false), mAttachedStackSizeOnOutermost(0), mDocument(aDocument) { } nsBindingManager::~nsBindingManager(void) { mDestroyed = true; } nsXBLBinding* nsBindingManager::GetBindingWithContent(nsIContent* aContent) { nsXBLBinding* binding = aContent ? aContent->GetXBLBinding() : nullptr; return binding ? binding->GetBindingWithContent() : nullptr; } void nsBindingManager::AddBoundContent(nsIContent* aContent) { if (!mBoundContentSet) { mBoundContentSet = new nsTHashtable >; } mBoundContentSet->PutEntry(aContent); } void nsBindingManager::RemoveBoundContent(nsIContent* aContent) { if (mBoundContentSet) { mBoundContentSet->RemoveEntry(aContent); } // The death of the bindings means the death of the JS wrapper. SetWrappedJS(aContent, nullptr); } nsIXPConnectWrappedJS* nsBindingManager::GetWrappedJS(nsIContent* aContent) { if (!mWrapperTable) { return nullptr; } if (!aContent || !aContent->HasFlag(NODE_MAY_BE_IN_BINDING_MNGR)) { return nullptr; } return mWrapperTable->GetWeak(aContent); } nsresult nsBindingManager::SetWrappedJS(nsIContent* aContent, nsIXPConnectWrappedJS* aWrappedJS) { if (mDestroyed) { return NS_OK; } if (aWrappedJS) { // lazily create the table, but only when adding elements if (!mWrapperTable) { mWrapperTable = new WrapperHashtable(); } aContent->SetFlags(NODE_MAY_BE_IN_BINDING_MNGR); NS_ASSERTION(aContent, "key must be non-null"); if (!aContent) return NS_ERROR_INVALID_ARG; mWrapperTable->Put(aContent, aWrappedJS); return NS_OK; } // no value, so remove the key from the table if (mWrapperTable) { mWrapperTable->Remove(aContent); } return NS_OK; } void nsBindingManager::RemovedFromDocumentInternal(nsIContent* aContent, nsIDocument* aOldDocument) { NS_PRECONDITION(aOldDocument != nullptr, "no old document"); nsRefPtr binding = aContent->GetXBLBinding(); if (binding) { // The binding manager may have been destroyed before a runnable // has had a chance to reach this point. If so, we bail out on calling // BindingDetached (which may invoke a XBL destructor) and // ChangeDocument, but we still want to clear out the binding // and insertion parent that may hold references. if (!mDestroyed) { binding->PrototypeBinding()->BindingDetached(binding->GetBoundElement()); binding->ChangeDocument(aOldDocument, nullptr); } aContent->SetXBLBinding(nullptr, this); } // Clear out insertion parent and content lists. aContent->SetXBLInsertionParent(nullptr); } nsIAtom* nsBindingManager::ResolveTag(nsIContent* aContent, int32_t* aNameSpaceID) { nsXBLBinding *binding = aContent->GetXBLBinding(); if (binding) { nsIAtom* base = binding->GetBaseTag(aNameSpaceID); if (base) { return base; } } *aNameSpaceID = aContent->GetNameSpaceID(); return aContent->Tag(); } nsresult nsBindingManager::GetAnonymousNodesFor(nsIContent* aContent, nsIDOMNodeList** aResult) { NS_IF_ADDREF(*aResult = GetAnonymousNodesFor(aContent)); return NS_OK; } nsINodeList* nsBindingManager::GetAnonymousNodesFor(nsIContent* aContent) { nsXBLBinding* binding = GetBindingWithContent(aContent); return binding ? binding->GetAnonymousNodeList() : nullptr; } nsresult nsBindingManager::ClearBinding(nsIContent* aContent) { // Hold a ref to the binding so it won't die when we remove it from our table nsRefPtr binding = aContent ? aContent->GetXBLBinding() : nullptr; if (!binding) { return NS_OK; } // For now we can only handle removing a binding if it's the only one NS_ENSURE_FALSE(binding->GetBaseBinding(), NS_ERROR_FAILURE); // Hold strong ref in case removing the binding tries to close the // window or something. // XXXbz should that be ownerdoc? Wouldn't we need a ref to the // currentdoc too? What's the one that should be passed to // ChangeDocument? nsCOMPtr doc = aContent->OwnerDoc(); // Finally remove the binding... // XXXbz this doesn't remove the implementation! Should fix! Until // then we need the explicit UnhookEventHandlers here. binding->UnhookEventHandlers(); binding->ChangeDocument(doc, nullptr); aContent->SetXBLBinding(nullptr, this); binding->MarkForDeath(); // ...and recreate its frames. We need to do this since the frames may have // been removed and style may have changed due to the removal of the // anonymous children. // XXXbz this should be using the current doc (if any), not the owner doc. nsIPresShell *presShell = doc->GetShell(); NS_ENSURE_TRUE(presShell, NS_ERROR_FAILURE); return presShell->RecreateFramesFor(aContent);; } nsresult nsBindingManager::LoadBindingDocument(nsIDocument* aBoundDoc, nsIURI* aURL, nsIPrincipal* aOriginPrincipal) { NS_PRECONDITION(aURL, "Must have a URI to load!"); // First we need to load our binding. nsXBLService* xblService = nsXBLService::GetInstance(); if (!xblService) return NS_ERROR_FAILURE; // Load the binding doc. nsRefPtr info; xblService->LoadBindingDocumentInfo(nullptr, aBoundDoc, aURL, aOriginPrincipal, true, getter_AddRefs(info)); if (!info) return NS_ERROR_FAILURE; return NS_OK; } void nsBindingManager::RemoveFromAttachedQueue(nsXBLBinding* aBinding) { // Don't remove items here as that could mess up an executing // ProcessAttachedQueue. Instead, null the entry in the queue. size_t index = mAttachedStack.IndexOf(aBinding); if (index != mAttachedStack.NoIndex) { mAttachedStack[index] = nullptr; } } nsresult nsBindingManager::AddToAttachedQueue(nsXBLBinding* aBinding) { if (!mAttachedStack.AppendElement(aBinding)) return NS_ERROR_OUT_OF_MEMORY; // If we're in the middle of processing our queue already, don't // bother posting the event. if (!mProcessingAttachedStack && !mProcessAttachedQueueEvent) { PostProcessAttachedQueueEvent(); } // Make sure that flushes will flush out the new items as needed. mDocument->SetNeedStyleFlush(); return NS_OK; } void nsBindingManager::PostProcessAttachedQueueEvent() { mProcessAttachedQueueEvent = NS_NewRunnableMethod(this, &nsBindingManager::DoProcessAttachedQueue); nsresult rv = NS_DispatchToCurrentThread(mProcessAttachedQueueEvent); if (NS_SUCCEEDED(rv) && mDocument) { mDocument->BlockOnload(); } } void nsBindingManager::DoProcessAttachedQueue() { if (!mProcessingAttachedStack) { ProcessAttachedQueue(); NS_ASSERTION(mAttachedStack.Length() == 0, "Shouldn't have pending bindings!"); mProcessAttachedQueueEvent = nullptr; } else { // Someone's doing event processing from inside a constructor. // They're evil, but we'll fight back! Just poll on them being // done and repost the attached queue event. PostProcessAttachedQueueEvent(); } // No matter what, unblock onload for the event that's fired. if (mDocument) { // Hold a strong reference while calling UnblockOnload since that might // run script. nsCOMPtr doc = mDocument; doc->UnblockOnload(true); } } void nsBindingManager::ProcessAttachedQueue(uint32_t aSkipSize) { if (mProcessingAttachedStack || mAttachedStack.Length() <= aSkipSize) return; mProcessingAttachedStack = true; // Excute constructors. Do this from high index to low while (mAttachedStack.Length() > aSkipSize) { uint32_t lastItem = mAttachedStack.Length() - 1; nsRefPtr binding = mAttachedStack.ElementAt(lastItem); mAttachedStack.RemoveElementAt(lastItem); if (binding) { binding->ExecuteAttachedHandler(); } } // If NodeWillBeDestroyed has run we don't want to clobber // mProcessingAttachedStack set there. if (mDocument) { mProcessingAttachedStack = false; } NS_ASSERTION(mAttachedStack.Length() == aSkipSize, "How did we get here?"); mAttachedStack.Compact(); } // Keep bindings and bound elements alive while executing detached handlers. struct BindingTableReadClosure { nsCOMArray mBoundElements; nsBindingList mBindings; }; static PLDHashOperator AccumulateBindingsToDetach(nsRefPtrHashKey *aKey, void* aClosure) { nsXBLBinding *binding = aKey->GetKey()->GetXBLBinding(); BindingTableReadClosure* closure = static_cast(aClosure); if (binding && closure->mBindings.AppendElement(binding)) { if (!closure->mBoundElements.AppendObject(binding->GetBoundElement())) { closure->mBindings.RemoveElementAt(closure->mBindings.Length() - 1); } } return PL_DHASH_NEXT; } void nsBindingManager::ExecuteDetachedHandlers() { // Walk our hashtable of bindings. if (mBoundContentSet) { BindingTableReadClosure closure; mBoundContentSet->EnumerateEntries(AccumulateBindingsToDetach, &closure); uint32_t i, count = closure.mBindings.Length(); for (i = 0; i < count; ++i) { closure.mBindings[i]->ExecuteDetachedHandler(); } } } nsresult nsBindingManager::PutXBLDocumentInfo(nsXBLDocumentInfo* aDocumentInfo) { NS_PRECONDITION(aDocumentInfo, "Must have a non-null documentinfo!"); if (!mDocumentTable) { mDocumentTable = new nsRefPtrHashtable(16); } mDocumentTable->Put(aDocumentInfo->DocumentURI(), aDocumentInfo); return NS_OK; } void nsBindingManager::RemoveXBLDocumentInfo(nsXBLDocumentInfo* aDocumentInfo) { if (mDocumentTable) { mDocumentTable->Remove(aDocumentInfo->DocumentURI()); } } nsXBLDocumentInfo* nsBindingManager::GetXBLDocumentInfo(nsIURI* aURL) { if (!mDocumentTable) return nullptr; return mDocumentTable->GetWeak(aURL); } nsresult nsBindingManager::PutLoadingDocListener(nsIURI* aURL, nsIStreamListener* aListener) { NS_PRECONDITION(aListener, "Must have a non-null listener!"); if (!mLoadingDocTable) { mLoadingDocTable = new nsInterfaceHashtable(16); } mLoadingDocTable->Put(aURL, aListener); return NS_OK; } nsIStreamListener* nsBindingManager::GetLoadingDocListener(nsIURI* aURL) { if (!mLoadingDocTable) return nullptr; return mLoadingDocTable->GetWeak(aURL); } void nsBindingManager::RemoveLoadingDocListener(nsIURI* aURL) { if (mLoadingDocTable) { mLoadingDocTable->Remove(aURL); } } static PLDHashOperator MarkForDeath(nsRefPtrHashKey *aKey, void* aClosure) { nsXBLBinding *binding = aKey->GetKey()->GetXBLBinding(); if (binding->MarkedForDeath()) return PL_DHASH_NEXT; // Already marked for death. nsAutoCString path; binding->PrototypeBinding()->DocURI()->GetPath(path); if (!strncmp(path.get(), "/skin", 5)) binding->MarkForDeath(); return PL_DHASH_NEXT; } void nsBindingManager::FlushSkinBindings() { if (mBoundContentSet) { mBoundContentSet->EnumerateEntries(MarkForDeath, nullptr); } } // Used below to protect from recurring in QI calls through XPConnect. struct AntiRecursionData { nsIContent* element; REFNSIID iid; AntiRecursionData* next; AntiRecursionData(nsIContent* aElement, REFNSIID aIID, AntiRecursionData* aNext) : element(aElement), iid(aIID), next(aNext) {} }; nsresult nsBindingManager::GetBindingImplementation(nsIContent* aContent, REFNSIID aIID, void** aResult) { *aResult = nullptr; nsXBLBinding *binding = aContent ? aContent->GetXBLBinding() : nullptr; if (binding) { // The binding should not be asked for nsISupports NS_ASSERTION(!aIID.Equals(NS_GET_IID(nsISupports)), "Asking a binding for nsISupports"); if (binding->ImplementsInterface(aIID)) { nsCOMPtr wrappedJS = GetWrappedJS(aContent); if (wrappedJS) { // Protect from recurring in QI calls through XPConnect. // This can happen when a second binding is being resolved. // At that point a wrappedJS exists, but it doesn't yet know about // the iid we are asking for. So, without this protection, // AggregatedQueryInterface would end up recurring back into itself // through this code. // // With this protection, when we detect the recursion we return // NS_NOINTERFACE in the inner call. The outer call will then fall // through (see below) and build a new chained wrappedJS for the iid. // // We're careful to not assume that only one direct nesting can occur // because there is a call into JS in the middle and we can't assume // that this code won't be reached by some more complex nesting path. // // NOTE: We *assume* this is single threaded, so we can use a // static linked list to do the check. static AntiRecursionData* list = nullptr; for (AntiRecursionData* p = list; p; p = p->next) { if (p->element == aContent && p->iid.Equals(aIID)) { *aResult = nullptr; return NS_NOINTERFACE; } } AntiRecursionData item(aContent, aIID, list); list = &item; nsresult rv = wrappedJS->AggregatedQueryInterface(aIID, aResult); list = item.next; if (*aResult) return rv; // No result was found, so this must be another XBL interface. // Fall through to create a new wrapper. } // We have never made a wrapper for this implementation. // Create an XPC wrapper for the script object and hand it back. nsIDocument* doc = aContent->OwnerDoc(); nsCOMPtr global = do_QueryInterface(doc->GetWindow()); if (!global) return NS_NOINTERFACE; nsIScriptContext *context = global->GetContext(); if (!context) return NS_NOINTERFACE; AutoPushJSContext cx(context->GetNativeContext()); if (!cx) return NS_NOINTERFACE; nsIXPConnect *xpConnect = nsContentUtils::XPConnect(); JS::Rooted jsobj(cx, aContent->GetWrapper()); NS_ENSURE_TRUE(jsobj, NS_NOINTERFACE); // If we're using an XBL scope, we need to use the Xray view to the bound // content in order to view the full array of methods defined in the // binding, some of which may not be exposed on the prototype of // untrusted content. // // If there's no separate XBL scope, or if the reflector itself lives in // the XBL scope, we'll end up with the global of the reflector, and this // will all be a no-op. JS::Rooted xblScope(cx, xpc::GetXBLScopeOrGlobal(cx, jsobj)); JSAutoCompartment ac(cx, xblScope); bool ok = JS_WrapObject(cx, &jsobj); NS_ENSURE_TRUE(ok, NS_ERROR_OUT_OF_MEMORY); MOZ_ASSERT_IF(js::IsWrapper(jsobj), xpc::IsXrayWrapper(jsobj)); nsresult rv = xpConnect->WrapJSAggregatedToNative(aContent, cx, jsobj, aIID, aResult); if (NS_FAILED(rv)) return rv; // We successfully created a wrapper. We will own this wrapper for as long as the binding remains // alive. At the time the binding is cleared out of the bindingManager, we will remove the wrapper // from the bindingManager as well. nsISupports* supp = static_cast(*aResult); wrappedJS = do_QueryInterface(supp); SetWrappedJS(aContent, wrappedJS); return rv; } } *aResult = nullptr; return NS_NOINTERFACE; } nsresult nsBindingManager::WalkRules(nsIStyleRuleProcessor::EnumFunc aFunc, ElementDependentRuleProcessorData* aData, bool* aCutOffInheritance) { *aCutOffInheritance = false; NS_ASSERTION(aData->mElement, "How did that happen?"); // Walk the binding scope chain, starting with the binding attached to our // content, up till we run out of scopes or we get cut off. nsIContent *content = aData->mElement; do { nsXBLBinding *binding = content->GetXBLBinding(); if (binding) { aData->mTreeMatchContext.mScopedRoot = content; binding->WalkRules(aFunc, aData); // If we're not looking at our original content, allow the binding to cut // off style inheritance if (content != aData->mElement) { if (!binding->InheritsStyle()) { // Go no further; we're not inheriting style from anything above here break; } } } if (content->IsRootOfNativeAnonymousSubtree()) { break; // Deliberately cut off style inheritance here. } content = content->GetBindingParent(); } while (content); // If "content" is non-null that means we cut off inheritance at some point // in the loop. *aCutOffInheritance = (content != nullptr); // Null out the scoped root that we set repeatedly aData->mTreeMatchContext.mScopedRoot = nullptr; return NS_OK; } typedef nsTHashtable > RuleProcessorSet; static PLDHashOperator EnumRuleProcessors(nsRefPtrHashKey *aKey, void* aClosure) { nsIContent *boundContent = aKey->GetKey(); nsAutoPtr *set = static_cast*>(aClosure); for (nsXBLBinding *binding = boundContent->GetXBLBinding(); binding; binding = binding->GetBaseBinding()) { nsIStyleRuleProcessor *ruleProc = binding->PrototypeBinding()->GetRuleProcessor(); if (ruleProc) { if (!(*set)) { *set = new RuleProcessorSet; } (*set)->PutEntry(ruleProc); } } return PL_DHASH_NEXT; } struct WalkAllRulesData { nsIStyleRuleProcessor::EnumFunc mFunc; ElementDependentRuleProcessorData* mData; }; static PLDHashOperator EnumWalkAllRules(nsPtrHashKey *aKey, void* aClosure) { nsIStyleRuleProcessor *ruleProcessor = aKey->GetKey(); WalkAllRulesData *data = static_cast(aClosure); (*(data->mFunc))(ruleProcessor, data->mData); return PL_DHASH_NEXT; } void nsBindingManager::WalkAllRules(nsIStyleRuleProcessor::EnumFunc aFunc, ElementDependentRuleProcessorData* aData) { if (!mBoundContentSet) { return; } nsAutoPtr set; mBoundContentSet->EnumerateEntries(EnumRuleProcessors, &set); if (!set) return; WalkAllRulesData data = { aFunc, aData }; set->EnumerateEntries(EnumWalkAllRules, &data); } struct MediumFeaturesChangedData { nsPresContext *mPresContext; bool *mRulesChanged; }; static PLDHashOperator EnumMediumFeaturesChanged(nsPtrHashKey *aKey, void* aClosure) { nsIStyleRuleProcessor *ruleProcessor = aKey->GetKey(); MediumFeaturesChangedData *data = static_cast(aClosure); bool thisChanged = ruleProcessor->MediumFeaturesChanged(data->mPresContext); *data->mRulesChanged = *data->mRulesChanged || thisChanged; return PL_DHASH_NEXT; } nsresult nsBindingManager::MediumFeaturesChanged(nsPresContext* aPresContext, bool* aRulesChanged) { *aRulesChanged = false; if (!mBoundContentSet) { return NS_OK; } nsAutoPtr set; mBoundContentSet->EnumerateEntries(EnumRuleProcessors, &set); if (!set) { return NS_OK; } MediumFeaturesChangedData data = { aPresContext, aRulesChanged }; set->EnumerateEntries(EnumMediumFeaturesChanged, &data); return NS_OK; } static PLDHashOperator EnumAppendAllSheets(nsRefPtrHashKey *aKey, void* aClosure) { nsIContent *boundContent = aKey->GetKey(); nsTArray* array = static_cast*>(aClosure); for (nsXBLBinding *binding = boundContent->GetXBLBinding(); binding; binding = binding->GetBaseBinding()) { nsXBLPrototypeResources::sheet_array_type* sheets = binding->PrototypeBinding()->GetStyleSheets(); if (sheets) { // Copy from nsTArray > to // nsTArray. array->AppendElements(*sheets); } } return PL_DHASH_NEXT; } void nsBindingManager::AppendAllSheets(nsTArray& aArray) { if (mBoundContentSet) { mBoundContentSet->EnumerateEntries(EnumAppendAllSheets, &aArray); } } static void InsertAppendedContent(XBLChildrenElement* aPoint, nsIContent* aFirstNewContent) { size_t insertionIndex; if (nsIContent* prevSibling = aFirstNewContent->GetPreviousSibling()) { // If we have a previous sibling, then it must already be in aPoint. Find // it and insert after it. insertionIndex = aPoint->IndexOfInsertedChild(prevSibling); MOZ_ASSERT(insertionIndex != aPoint->NoIndex); // Our insertion index is one after our previous sibling's index. ++insertionIndex; } else { // Otherwise, we append. // TODO This is wrong for nested insertion points. In that case, we need to // keep track of the right index to insert into. insertionIndex = aPoint->mInsertedChildren.Length(); } // Do the inserting. for (nsIContent* currentChild = aFirstNewContent; currentChild; currentChild = currentChild->GetNextSibling()) { aPoint->InsertInsertedChildAt(currentChild, insertionIndex++); } } void nsBindingManager::ContentAppended(nsIDocument* aDocument, nsIContent* aContainer, nsIContent* aFirstNewContent, int32_t aNewIndexInContainer) { if (aNewIndexInContainer == -1) { return; } // Try to find insertion points for all the new kids. XBLChildrenElement* point = nullptr; nsIContent* parent = aContainer; bool first = true; do { nsXBLBinding* binding = GetBindingWithContent(parent); if (!binding) { break; } if (binding->HasFilteredInsertionPoints()) { // There are filtered insertion points involved, handle each child // separately. // We could optimize this in the case when we've nested a few levels // deep already, without hitting bindings that have filtered insertion // points. int32_t currentIndex = aNewIndexInContainer; for (nsIContent* currentChild = aFirstNewContent; currentChild; currentChild = currentChild->GetNextSibling()) { HandleChildInsertion(aContainer, currentChild, currentIndex++, true); } return; } point = binding->GetDefaultInsertionPoint(); if (!point) { break; } // Even though we're in ContentAppended, nested insertion points force us // to deal with this append as an insertion except in the outermost // binding. if (first) { first = false; for (nsIContent* child = aFirstNewContent; child; child = child->GetNextSibling()) { point->AppendInsertedChild(child); } } else { InsertAppendedContent(point, aFirstNewContent); } nsIContent* newParent = point->GetParent(); if (newParent == parent) { break; } parent = newParent; } while (parent); } void nsBindingManager::ContentInserted(nsIDocument* aDocument, nsIContent* aContainer, nsIContent* aChild, int32_t aIndexInContainer) { if (aIndexInContainer == -1) { return; } HandleChildInsertion(aContainer, aChild, aIndexInContainer, false); } void nsBindingManager::ContentRemoved(nsIDocument* aDocument, nsIContent* aContainer, nsIContent* aChild, int32_t aIndexInContainer, nsIContent* aPreviousSibling) { aChild->SetXBLInsertionParent(nullptr); XBLChildrenElement* point = nullptr; nsIContent* parent = aContainer; do { nsXBLBinding* binding = GetBindingWithContent(parent); if (!binding) { // If aChild is XBL content, it might have elements // somewhere under it. We need to inform those elements that they're no // longer in the tree so they can tell their distributed children that // they're no longer distributed under them. // XXX This is wrong. We need to do far more work to update the parent // binding's list of insertion points and to get the new insertion parent // for the newly-distributed children correct. if (aChild->GetBindingParent()) { ClearInsertionPointsRecursively(aChild); } return; } point = binding->FindInsertionPointFor(aChild); if (!point) { break; } point->RemoveInsertedChild(aChild); nsIContent* newParent = point->GetParent(); if (newParent == parent) { break; } parent = newParent; } while (parent); } void nsBindingManager::ClearInsertionPointsRecursively(nsIContent* aContent) { if (aContent->NodeInfo()->Equals(nsGkAtoms::children, kNameSpaceID_XBL)) { static_cast(aContent)->ClearInsertedChildren(); } for (nsIContent* child = aContent->GetFirstChild(); child; child = child->GetNextSibling()) { ClearInsertionPointsRecursively(child); } } void nsBindingManager::DropDocumentReference() { mDestroyed = true; // Make sure to not run any more XBL constructors mProcessingAttachedStack = true; if (mProcessAttachedQueueEvent) { mProcessAttachedQueueEvent->Revoke(); } if (mBoundContentSet) { mBoundContentSet->Clear(); } mDocument = nullptr; } void nsBindingManager::Traverse(nsIContent *aContent, nsCycleCollectionTraversalCallback &cb) { if (!aContent->HasFlag(NODE_MAY_BE_IN_BINDING_MNGR) || !aContent->IsElement()) { // Don't traverse if content is not in this binding manager. // We also don't traverse non-elements because there should not // be bindings (checking the flag alone is not sufficient because // the flag is also set on children of insertion points that may be // non-elements). return; } if (mBoundContentSet && mBoundContentSet->Contains(aContent)) { NS_CYCLE_COLLECTION_NOTE_EDGE_NAME(cb, "[via binding manager] mBoundContentSet entry"); cb.NoteXPCOMChild(aContent); } nsIXPConnectWrappedJS *value = GetWrappedJS(aContent); if (value) { NS_CYCLE_COLLECTION_NOTE_EDGE_NAME(cb, "[via binding manager] mWrapperTable key"); cb.NoteXPCOMChild(aContent); NS_CYCLE_COLLECTION_NOTE_EDGE_NAME(cb, "[via binding manager] mWrapperTable value"); cb.NoteXPCOMChild(value); } } void nsBindingManager::BeginOutermostUpdate() { mAttachedStackSizeOnOutermost = mAttachedStack.Length(); } void nsBindingManager::EndOutermostUpdate() { if (!mProcessingAttachedStack) { ProcessAttachedQueue(mAttachedStackSizeOnOutermost); mAttachedStackSizeOnOutermost = 0; } } void nsBindingManager::HandleChildInsertion(nsIContent* aContainer, nsIContent* aChild, uint32_t aIndexInContainer, bool aAppend) { NS_PRECONDITION(aChild, "Must have child"); NS_PRECONDITION(!aContainer || uint32_t(aContainer->IndexOf(aChild)) == aIndexInContainer, "Child not at the right index?"); XBLChildrenElement* point = nullptr; nsIContent* parent = aContainer; while (parent) { nsXBLBinding* binding = GetBindingWithContent(parent); if (!binding) { break; } point = binding->FindInsertionPointFor(aChild); if (!point) { break; } // Insert the child into the proper insertion point. // TODO If there were multiple insertion points, this approximation can be // wrong. We need to re-run the distribution algorithm. In the meantime, // this should work well enough. size_t index = aAppend ? point->mInsertedChildren.Length() : 0; for (nsIContent* currentSibling = aChild->GetPreviousSibling(); currentSibling; currentSibling = currentSibling->GetPreviousSibling()) { // If we find one of our previous siblings in the insertion point, the // index following it is the correct insertion point. Otherwise, we guess // based on whether we're appending or inserting. size_t pointIndex = point->IndexOfInsertedChild(currentSibling); if (pointIndex != point->NoIndex) { index = pointIndex + 1; break; } } point->InsertInsertedChildAt(aChild, index); nsIContent* newParent = point->GetParent(); if (newParent == parent) { break; } parent = newParent; } } nsIContent* nsBindingManager::FindNestedInsertionPoint(nsIContent* aContainer, nsIContent* aChild) { NS_PRECONDITION(aChild->GetParent() == aContainer, "Wrong container"); nsIContent* parent = aContainer; if (aContainer->IsActiveChildrenElement()) { if (static_cast(aContainer)-> HasInsertedChildren()) { return nullptr; } parent = aContainer->GetParent(); } while (parent) { nsXBLBinding* binding = GetBindingWithContent(parent); if (!binding) { break; } XBLChildrenElement* point = binding->FindInsertionPointFor(aChild); if (!point) { return nullptr; } nsIContent* newParent = point->GetParent(); if (newParent == parent) { break; } parent = newParent; } return parent; } nsIContent* nsBindingManager::FindNestedSingleInsertionPoint(nsIContent* aContainer, bool* aMulti) { *aMulti = false; nsIContent* parent = aContainer; if (aContainer->IsActiveChildrenElement()) { if (static_cast(aContainer)-> HasInsertedChildren()) { return nullptr; } parent = aContainer->GetParent(); } while(parent) { nsXBLBinding* binding = GetBindingWithContent(parent); if (!binding) { break; } if (binding->HasFilteredInsertionPoints()) { *aMulti = true; return nullptr; } XBLChildrenElement* point = binding->GetDefaultInsertionPoint(); if (!point) { return nullptr; } nsIContent* newParent = point->GetParent(); if (newParent == parent) { break; } parent = newParent; } return parent; }