/* -*- Mode: C++; tab-width: 8; indent-tabs-mode: nil; c-basic-offset: 2 -*- */ /* vim: set ts=8 sts=2 et sw=2 tw=80: */ /* 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 "SharedMap.h" #include "SharedMapChangeEvent.h" #include "MemMapSnapshot.h" #include "ScriptPreloader-inl.h" #include "mozilla/dom/ContentParent.h" #include "mozilla/dom/ContentProcessMessageManager.h" #include "mozilla/dom/IPCBlobUtils.h" #include "mozilla/dom/ScriptSettings.h" #include "mozilla/ScriptPreloader.h" using namespace mozilla::loader; namespace mozilla { using namespace ipc; namespace dom { namespace ipc { // Align to size of uintptr_t here, to be safe. It's probably not strictly // necessary, though. constexpr size_t kStructuredCloneAlign = sizeof(uintptr_t); static inline void AlignTo(size_t* aOffset, size_t aAlign) { if (auto mod = *aOffset % aAlign) { *aOffset += aAlign - mod; } } SharedMap::SharedMap() : DOMEventTargetHelper() {} SharedMap::SharedMap(nsIGlobalObject* aGlobal, const FileDescriptor& aMapFile, size_t aMapSize, nsTArray>&& aBlobs) : DOMEventTargetHelper(aGlobal), mBlobImpls(std::move(aBlobs)) { mMapFile.reset(new FileDescriptor(aMapFile)); mMapSize = aMapSize; } bool SharedMap::Has(const nsACString& aName) { Unused << MaybeRebuild(); return mEntries.Contains(aName); } void SharedMap::Get(JSContext* aCx, const nsACString& aName, JS::MutableHandleValue aRetVal, ErrorResult& aRv) { auto res = MaybeRebuild(); if (res.isErr()) { aRv.Throw(res.unwrapErr()); return; } Entry* entry = mEntries.Get(aName); if (!entry) { aRetVal.setNull(); return; } entry->Read(aCx, aRetVal, aRv); } void SharedMap::Entry::Read(JSContext* aCx, JS::MutableHandleValue aRetVal, ErrorResult& aRv) { if (mData.is()) { // We have a temporary buffer for a key that was changed after the last // snapshot. Just decode it directly. auto& holder = mData.as(); holder.Read(aCx, aRetVal, aRv); return; } // We have a pointer to a shared memory region containing our structured // clone data. Create a temporary buffer to decode that data, and then // discard it so that we don't keep a separate process-local copy around any // longer than necessary. StructuredCloneData holder; if (!holder.CopyExternalData(Data(), Size())) { aRv.Throw(NS_ERROR_OUT_OF_MEMORY); return; } if (mBlobCount) { holder.BlobImpls().AppendElements(Blobs()); } holder.Read(aCx, aRetVal, aRv); } FileDescriptor SharedMap::CloneMapFile() const { if (mMap.initialized()) { return mMap.cloneHandle(); } return *mMapFile; } void SharedMap::Update(const FileDescriptor& aMapFile, size_t aMapSize, nsTArray>&& aBlobs, nsTArray&& aChangedKeys) { MOZ_DIAGNOSTIC_ASSERT(!mWritable); mMap.reset(); if (mMapFile) { *mMapFile = aMapFile; } else { mMapFile.reset(new FileDescriptor(aMapFile)); } mMapSize = aMapSize; mEntries.Clear(); mEntryArray.reset(); mBlobImpls = std::move(aBlobs); AutoEntryScript aes(GetParentObject(), "SharedMap change event"); JSContext* cx = aes.cx(); RootedDictionary init(cx); if (!init.mChangedKeys.SetCapacity(aChangedKeys.Length(), fallible)) { NS_WARNING("Failed to dispatch SharedMap change event"); return; } for (auto& key : aChangedKeys) { Unused << init.mChangedKeys.AppendElement(NS_ConvertUTF8toUTF16(key), fallible); } RefPtr event = SharedMapChangeEvent::Constructor( this, NS_LITERAL_STRING("change"), init); event->SetTrusted(true); DispatchEvent(*event); } const nsTArray& SharedMap::EntryArray() const { if (mEntryArray.isNothing()) { MaybeRebuild(); mEntryArray.emplace(mEntries.Count()); auto& array = mEntryArray.ref(); for (auto& entry : IterHash(mEntries)) { array.AppendElement(entry); } } return mEntryArray.ref(); } const nsString SharedMap::GetKeyAtIndex(uint32_t aIndex) const { return NS_ConvertUTF8toUTF16(EntryArray()[aIndex]->Name()); } bool SharedMap::GetValueAtIndex(JSContext* aCx, uint32_t aIndex, JS::MutableHandle aResult) const { ErrorResult rv; EntryArray()[aIndex]->Read(aCx, aResult, rv); if (rv.MaybeSetPendingException(aCx)) { return false; } return true; } void SharedMap::Entry::TakeData(StructuredCloneData&& aHolder) { mData = AsVariant(std::move(aHolder)); mSize = Holder().Data().Size(); mBlobCount = Holder().BlobImpls().Length(); } void SharedMap::Entry::ExtractData(char* aDestPtr, uint32_t aNewOffset, uint16_t aNewBlobOffset) { if (mData.is()) { char* ptr = aDestPtr; Holder().Data().ForEachDataChunk([&](const char* aData, size_t aSize) { memcpy(ptr, aData, aSize); ptr += aSize; return true; }); MOZ_ASSERT(uint32_t(ptr - aDestPtr) == mSize); } else { memcpy(aDestPtr, Data(), mSize); } mData = AsVariant(aNewOffset); mBlobOffset = aNewBlobOffset; } Result SharedMap::MaybeRebuild() { if (!mMapFile) { return Ok(); } // This function maps a shared memory region created by Serialize() and reads // its header block to build a new mEntries hashtable of its contents. // // The entries created by this function contain a pointer to this SharedMap // instance, and the offsets and sizes of their structured clone data within // its shared memory region. When needed, that structured clone data is // retrieved directly as indexes into the SharedMap's shared memory region. MOZ_TRY(mMap.initWithHandle(*mMapFile, mMapSize)); mMapFile.reset(); // We should be able to pass this range as an initializer list or an immediate // param, but gcc currently chokes on that if optimization is enabled, and // initializes everything to 0. Range range(&mMap.get()[0], mMap.size()); InputBuffer buffer(range); uint32_t count; buffer.codeUint32(count); for (uint32_t i = 0; i < count; i++) { auto entry = MakeUnique(*this); entry->Code(buffer); // This buffer was created at runtime, during this session, so any errors // indicate memory corruption, and are fatal. MOZ_RELEASE_ASSERT(!buffer.error()); // Note: Order of evaluation of function arguments is not guaranteed, so we // can't use entry.release() in place of entry.get() without entry->Name() // sometimes resulting in a null dereference. mEntries.Put(entry->Name(), entry.get()); Unused << entry.release(); } return Ok(); } void SharedMap::MaybeRebuild() const { Unused << const_cast(this)->MaybeRebuild(); } WritableSharedMap::WritableSharedMap() : SharedMap() { mWritable = true; // Serialize the initial empty contents of the map immediately so that we // always have a file descriptor to send to callers of CloneMapFile(). Unused << Serialize(); MOZ_RELEASE_ASSERT(mMap.initialized()); } SharedMap* WritableSharedMap::GetReadOnly() { if (!mReadOnly) { nsTArray> blobs(mBlobImpls); mReadOnly = new SharedMap(ContentProcessMessageManager::Get()->GetParentObject(), CloneMapFile(), MapSize(), std::move(blobs)); } return mReadOnly; } Result WritableSharedMap::Serialize() { // Serializes a new snapshot of the map, initializes a new read-only shared // memory region with its contents, and updates all entries to point to that // new snapshot. // // The layout of the snapshot is as follows: // // - A header containing a uint32 count field containing the number of // entries in the map, followed by that number of serialized entry headers, // as produced by Entry::Code. // // - A data block containing structured clone data for each of the entries' // values. This data is referenced by absolute byte offsets from the start // of the shared memory region, encoded in each of the entry header values. // Each entry's data is aligned to kStructuredCloneAlign, and therefore may // have alignment padding before it. // // This serialization format is decoded by the MaybeRebuild() method of // read-only SharedMap() instances, and used to populate their mEntries // hashtables. // // Writable instances never read the header blocks, but instead directly // update their Entry instances to point to the appropriate offsets in the // shared memory region created by this function. uint32_t count = mEntries.Count(); size_t dataSize = 0; size_t headerSize = sizeof(count); size_t blobCount = 0; for (auto& entry : IterHash(mEntries)) { headerSize += entry->HeaderSize(); blobCount += entry->BlobCount(); dataSize += entry->Size(); AlignTo(&dataSize, kStructuredCloneAlign); } size_t offset = headerSize; AlignTo(&offset, kStructuredCloneAlign); OutputBuffer header; header.codeUint32(count); MemMapSnapshot mem; MOZ_TRY(mem.Init(offset + dataSize)); auto ptr = mem.Get(); // We need to build the new array of blobs before we overwrite the existing // one, since previously-serialized entries will store their blob references // as indexes into our blobs array. nsTArray> blobImpls(blobCount); for (auto& entry : IterHash(mEntries)) { AlignTo(&offset, kStructuredCloneAlign); size_t blobOffset = blobImpls.Length(); if (entry->BlobCount()) { blobImpls.AppendElements(entry->Blobs()); } entry->ExtractData(&ptr[offset], offset, blobOffset); entry->Code(header); offset += entry->Size(); } mBlobImpls = std::move(blobImpls); // FIXME: We should create a separate OutputBuffer class which can encode to // a static memory region rather than dynamically allocating and then // copying. MOZ_ASSERT(header.cursor() == headerSize); memcpy(ptr.get(), header.Get(), header.cursor()); // We've already updated offsets at this point. We need this to succeed. mMap.reset(); MOZ_RELEASE_ASSERT(mem.Finalize(mMap).isOk()); return Ok(); } void WritableSharedMap::SendTo(ContentParent* aParent) const { nsTArray blobs(mBlobImpls.Length()); for (auto& blobImpl : mBlobImpls) { nsresult rv = IPCBlobUtils::Serialize(blobImpl, aParent, *blobs.AppendElement()); if (NS_WARN_IF(NS_FAILED(rv))) { continue; } } Unused << aParent->SendUpdateSharedData(CloneMapFile(), mMap.size(), blobs, mChangedKeys); } void WritableSharedMap::BroadcastChanges() { if (mChangedKeys.IsEmpty()) { return; } if (!Serialize().isOk()) { return; } nsTArray parents; ContentParent::GetAll(parents); for (auto& parent : parents) { SendTo(parent); } if (mReadOnly) { nsTArray> blobImpls(mBlobImpls); mReadOnly->Update(CloneMapFile(), mMap.size(), std::move(blobImpls), std::move(mChangedKeys)); } mChangedKeys.Clear(); } void WritableSharedMap::Delete(const nsACString& aName) { if (mEntries.Remove(aName)) { KeyChanged(aName); } } void WritableSharedMap::Set(JSContext* aCx, const nsACString& aName, JS::HandleValue aValue, ErrorResult& aRv) { StructuredCloneData holder; holder.Write(aCx, aValue, aRv); if (aRv.Failed()) { return; } if (!holder.InputStreams().IsEmpty()) { aRv.Throw(NS_ERROR_INVALID_ARG); return; } Entry* entry = mEntries.LookupOrAdd(aName, *this, aName); entry->TakeData(std::move(holder)); KeyChanged(aName); } void WritableSharedMap::Flush() { BroadcastChanges(); } void WritableSharedMap::IdleFlush() { mPendingFlush = false; Flush(); } nsresult WritableSharedMap::KeyChanged(const nsACString& aName) { if (!mChangedKeys.ContainsSorted(aName)) { mChangedKeys.InsertElementSorted(aName); } mEntryArray.reset(); if (!mPendingFlush) { MOZ_TRY(NS_DispatchToCurrentThreadQueue( NewRunnableMethod("WritableSharedMap::IdleFlush", this, &WritableSharedMap::IdleFlush), EventQueuePriority::Idle)); mPendingFlush = true; } return NS_OK; } JSObject* SharedMap::WrapObject(JSContext* aCx, JS::HandleObject aGivenProto) { return MozSharedMap_Binding::Wrap(aCx, this, aGivenProto); } JSObject* WritableSharedMap::WrapObject(JSContext* aCx, JS::HandleObject aGivenProto) { return MozWritableSharedMap_Binding::Wrap(aCx, this, aGivenProto); } /* static */ already_AddRefed SharedMapChangeEvent::Constructor( EventTarget* aEventTarget, const nsAString& aType, const MozSharedMapChangeEventInit& aInit) { RefPtr event = new SharedMapChangeEvent(aEventTarget); bool trusted = event->Init(aEventTarget); event->InitEvent(aType, aInit.mBubbles, aInit.mCancelable); event->SetTrusted(trusted); event->SetComposed(aInit.mComposed); event->mChangedKeys = aInit.mChangedKeys; return event.forget(); } NS_IMPL_CYCLE_COLLECTION_INHERITED(WritableSharedMap, SharedMap, mReadOnly) NS_INTERFACE_MAP_BEGIN_CYCLE_COLLECTION(WritableSharedMap) NS_INTERFACE_MAP_END_INHERITING(SharedMap) NS_IMPL_ADDREF_INHERITED(WritableSharedMap, SharedMap) NS_IMPL_RELEASE_INHERITED(WritableSharedMap, SharedMap) } // namespace ipc } // namespace dom } // namespace mozilla