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/* -*- 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,
#ifndef mozilla_dom_BindingUtils_h__
#define mozilla_dom_BindingUtils_h__
#include <type_traits>
#include "jsfriendapi.h"
#include "js/CharacterEncoding.h"
#include "js/Conversions.h"
#include "js/experimental/BindingAllocs.h"
#include "js/experimental/JitInfo.h" // JSJitGetterOp, JSJitInfo
#include "js/friend/WindowProxy.h" // js::IsWindow, js::IsWindowProxy, js::ToWindowProxyIfWindow
#include "js/MemoryFunctions.h"
#include "js/Object.h" // JS::GetClass, JS::GetCompartment, JS::GetReservedSlot, JS::SetReservedSlot
#include "js/RealmOptions.h"
#include "js/String.h" // JS::GetLatin1LinearStringChars, JS::GetTwoByteLinearStringChars, JS::GetLinearStringLength, JS::LinearStringHasLatin1Chars, JS::StringHasLatin1Chars
#include "js/Wrapper.h"
#include "js/Zone.h"
#include "mozilla/ArrayUtils.h"
#include "mozilla/Array.h"
#include "mozilla/Assertions.h"
#include "mozilla/DeferredFinalize.h"
#include "mozilla/EnumTypeTraits.h"
#include "mozilla/EnumeratedRange.h"
#include "mozilla/UniquePtr.h"
#include "mozilla/dom/BindingCallContext.h"
#include "mozilla/dom/BindingDeclarations.h"
#include "mozilla/dom/DOMJSClass.h"
#include "mozilla/dom/DOMJSProxyHandler.h"
#include "mozilla/dom/JSSlots.h"
#include "mozilla/dom/NonRefcountedDOMObject.h"
#include "mozilla/dom/Nullable.h"
#include "mozilla/dom/PrototypeList.h"
#include "mozilla/dom/RemoteObjectProxy.h"
#include "mozilla/SegmentedVector.h"
#include "mozilla/ErrorResult.h"
#include "mozilla/Likely.h"
#include "mozilla/MemoryReporting.h"
#include "nsIGlobalObject.h"
#include "nsJSUtils.h"
#include "nsISupportsImpl.h"
#include "xpcObjectHelper.h"
#include "xpcpublic.h"
#include "nsIVariant.h"
#include "mozilla/dom/FakeString.h"
#include "mozilla/ProfilerLabels.h"
#include "nsWrapperCacheInlines.h"
class nsGlobalWindowInner;
class nsGlobalWindowOuter;
class nsIInterfaceRequestor;
namespace mozilla {
enum UseCounter : int16_t;
enum class UseCounterWorker : int16_t;
namespace dom {
class CustomElementReactionsStack;
class Document;
class EventTarget;
class MessageManagerGlobal;
class ObservableArrayProxyHandler;
class DedicatedWorkerGlobalScope;
template <typename KeyType, typename ValueType>
class Record;
class WindowProxyHolder;
enum class DeprecatedOperations : uint16_t;
nsresult UnwrapArgImpl(JSContext* cx, JS::Handle<JSObject*> src,
const nsIID& iid, void** ppArg);
/** Convert a jsval to an XPCOM pointer. Caller must not assume that src will
keep the XPCOM pointer rooted. */
template <class Interface>
inline nsresult UnwrapArg(JSContext* cx, JS::Handle<JSObject*> src,
Interface** ppArg) {
return UnwrapArgImpl(cx, src, NS_GET_TEMPLATE_IID(Interface),
reinterpret_cast<void**>(ppArg));
}
nsresult UnwrapWindowProxyArg(JSContext* cx, JS::Handle<JSObject*> src,
WindowProxyHolder& ppArg);
// Returns true if the JSClass is used for DOM objects.
inline bool IsDOMClass(const JSClass* clasp) {
return clasp->flags & JSCLASS_IS_DOMJSCLASS;
}
// Return true if the JSClass is used for non-proxy DOM objects.
inline bool IsNonProxyDOMClass(const JSClass* clasp) {
return IsDOMClass(clasp) && clasp->isNativeObject();
}
// Returns true if the JSClass is used for DOM interface and interface
// prototype objects.
inline bool IsDOMIfaceAndProtoClass(const JSClass* clasp) {
return clasp->flags & JSCLASS_IS_DOMIFACEANDPROTOJSCLASS;
}
static_assert(DOM_OBJECT_SLOT == 0,
"DOM_OBJECT_SLOT doesn't match the proxy private slot. "
"Expect bad things");
template <class T>
inline T* UnwrapDOMObject(JSObject* obj) {
MOZ_ASSERT(IsDOMClass(JS::GetClass(obj)),
"Don't pass non-DOM objects to this function");
JS::Value val = JS::GetReservedSlot(obj, DOM_OBJECT_SLOT);
return static_cast<T*>(val.toPrivate());
}
template <class T>
inline T* UnwrapPossiblyNotInitializedDOMObject(JSObject* obj) {
// This is used by the OjectMoved JSClass hook which can be called before
// JS_NewObject has returned and so before we have a chance to set
// DOM_OBJECT_SLOT to anything useful.
MOZ_ASSERT(IsDOMClass(JS::GetClass(obj)),
"Don't pass non-DOM objects to this function");
JS::Value val = JS::GetReservedSlot(obj, DOM_OBJECT_SLOT);
if (val.isUndefined()) {
return nullptr;
}
return static_cast<T*>(val.toPrivate());
}
inline const DOMJSClass* GetDOMClass(const JSClass* clasp) {
return IsDOMClass(clasp) ? DOMJSClass::FromJSClass(clasp) : nullptr;
}
inline const DOMJSClass* GetDOMClass(JSObject* obj) {
return GetDOMClass(JS::GetClass(obj));
}
inline nsISupports* UnwrapDOMObjectToISupports(JSObject* aObject) {
const DOMJSClass* clasp = GetDOMClass(aObject);
if (!clasp || !clasp->mDOMObjectIsISupports) {
return nullptr;
}
return UnwrapPossiblyNotInitializedDOMObject<nsISupports>(aObject);
}
inline bool IsDOMObject(JSObject* obj) { return IsDOMClass(JS::GetClass(obj)); }
// There are two valid ways to use UNWRAP_OBJECT: Either obj needs to
// be a MutableHandle<JSObject*>, or value needs to be a strong-reference
// smart pointer type (OwningNonNull or RefPtr or nsCOMPtr), in which case obj
// can be anything that converts to JSObject*.
//
// This can't be used with Window, EventTarget, or Location as the "Interface"
// argument (and will fail a static_assert if you try to do that). Use
// UNWRAP_MAYBE_CROSS_ORIGIN_OBJECT to unwrap to those interfaces.
#define UNWRAP_OBJECT(Interface, obj, value) \
mozilla::dom::binding_detail::UnwrapObjectWithCrossOriginAsserts< \
mozilla::dom::prototypes::id::Interface, \
mozilla::dom::Interface##_Binding::NativeType>(obj, value)
// UNWRAP_MAYBE_CROSS_ORIGIN_OBJECT is just like UNWRAP_OBJECT but requires a
// JSContext in a Realm that represents "who is doing the unwrapping?" to
// properly unwrap the object.
#define UNWRAP_MAYBE_CROSS_ORIGIN_OBJECT(Interface, obj, value, cx) \
mozilla::dom::UnwrapObject<mozilla::dom::prototypes::id::Interface, \
mozilla::dom::Interface##_Binding::NativeType>( \
obj, value, cx)
// Test whether the given object is an instance of the given interface.
#define IS_INSTANCE_OF(Interface, obj) \
mozilla::dom::IsInstanceOf<mozilla::dom::prototypes::id::Interface, \
mozilla::dom::Interface##_Binding::NativeType>( \
obj)
// Unwrap the given non-wrapper object. This can be used with any obj that
// converts to JSObject*; as long as that JSObject* is live the return value
// will be valid.
#define UNWRAP_NON_WRAPPER_OBJECT(Interface, obj, value) \
mozilla::dom::UnwrapNonWrapperObject< \
mozilla::dom::prototypes::id::Interface, \
mozilla::dom::Interface##_Binding::NativeType>(obj, value)
// Some callers don't want to set an exception when unwrapping fails
// (for example, overload resolution uses unwrapping to tell what sort
// of thing it's looking at).
// U must be something that a T* can be assigned to (e.g. T* or an RefPtr<T>).
//
// The obj argument will be mutated to point to CheckedUnwrap of itself if the
// passed-in value is not a DOM object and CheckedUnwrap succeeds.
//
// If mayBeWrapper is true, there are three valid ways to invoke
// UnwrapObjectInternal: Either obj needs to be a class wrapping a
// MutableHandle<JSObject*>, with an assignment operator that sets the handle to
// the given object, or U needs to be a strong-reference smart pointer type
// (OwningNonNull or RefPtr or nsCOMPtr), or the value being stored in "value"
// must not escape past being tested for falsiness immediately after the
// UnwrapObjectInternal call.
//
// If mayBeWrapper is false, obj can just be a JSObject*, and U anything that a
// T* can be assigned to.
//
// The cx arg is in practice allowed to be either nullptr or JSContext* or a
// BindingCallContext reference. If it's nullptr we will do a
// CheckedUnwrapStatic and it's the caller's responsibility to make sure they're
// not trying to work with Window or Location objects. Otherwise we'll do a
// CheckedUnwrapDynamic. This all only matters if mayBeWrapper is true; if it's
// false just pass nullptr for the cx arg.
namespace binding_detail {
template <class T, bool mayBeWrapper, typename U, typename V, typename CxType>
MOZ_ALWAYS_INLINE nsresult UnwrapObjectInternal(V& obj, U& value,
prototypes::ID protoID,
uint32_t protoDepth,
const CxType& cx) {
static_assert(std::is_same_v<CxType, JSContext*> ||
std::is_same_v<CxType, BindingCallContext> ||
std::is_same_v<CxType, decltype(nullptr)>,
"Unexpected CxType");
/* First check to see whether we have a DOM object */
const DOMJSClass* domClass = GetDOMClass(obj);
if (domClass) {
/* This object is a DOM object. Double-check that it is safely
castable to T by checking whether it claims to inherit from the
class identified by protoID. */
if (domClass->mInterfaceChain[protoDepth] == protoID) {
value = UnwrapDOMObject<T>(obj);
return NS_OK;
}
}
/* Maybe we have a security wrapper or outer window? */
if (!mayBeWrapper || !js::IsWrapper(obj)) {
// For non-cross-origin-accessible methods and properties, remote object
// proxies should behave the same as opaque wrappers.
if (IsRemoteObjectProxy(obj)) {
return NS_ERROR_XPC_SECURITY_MANAGER_VETO;
}
/* Not a DOM object, not a wrapper, just bail */
return NS_ERROR_XPC_BAD_CONVERT_JS;
}
JSObject* unwrappedObj;
if (std::is_same_v<CxType, decltype(nullptr)>) {
unwrappedObj = js::CheckedUnwrapStatic(obj);
} else {
unwrappedObj =
js::CheckedUnwrapDynamic(obj, cx, /* stopAtWindowProxy = */ false);
}
if (!unwrappedObj) {
return NS_ERROR_XPC_SECURITY_MANAGER_VETO;
}
if (std::is_same_v<CxType, decltype(nullptr)>) {
// We might still have a windowproxy here. But it shouldn't matter, because
// that's not what the caller is looking for, so we're going to fail out
// anyway below once we do the recursive call to ourselves with wrapper
// unwrapping disabled.
MOZ_ASSERT(!js::IsWrapper(unwrappedObj) || js::IsWindowProxy(unwrappedObj));
} else {
// We shouldn't have a wrapper by now.
MOZ_ASSERT(!js::IsWrapper(unwrappedObj));
}
// Recursive call is OK, because now we're using false for mayBeWrapper and
// we never reach this code if that boolean is false, so can't keep calling
// ourselves.
//
// Unwrap into a temporary pointer, because in general unwrapping into
// something of type U might trigger GC (e.g. release the value currently
// stored in there, with arbitrary consequences) and invalidate the
// "unwrappedObj" pointer.
T* tempValue = nullptr;
nsresult rv = UnwrapObjectInternal<T, false>(unwrappedObj, tempValue, protoID,
protoDepth, nullptr);
if (NS_SUCCEEDED(rv)) {
// Suppress a hazard related to keeping tempValue alive across
// UnwrapObjectInternal, because the analysis can't tell that this function
// will not GC if maybeWrapped=False and we've already gone through a level
// of unwrapping so unwrappedObj will be !IsWrapper.
JS::AutoSuppressGCAnalysis suppress;
// It's very important to not update "obj" with the "unwrappedObj" value
// until we know the unwrap has succeeded. Otherwise, in a situation in
// which we have an overload of object and primitive we could end up
// converting to the primitive from the unwrappedObj, whereas we want to do
// it from the original object.
obj = unwrappedObj;
// And now assign to "value"; at this point we don't care if a GC happens
// and invalidates unwrappedObj.
value = tempValue;
return NS_OK;
}
/* It's the wrong sort of DOM object */
return NS_ERROR_XPC_BAD_CONVERT_JS;
}
struct MutableObjectHandleWrapper {
explicit MutableObjectHandleWrapper(JS::MutableHandle<JSObject*> aHandle)
: mHandle(aHandle) {}
void operator=(JSObject* aObject) {
MOZ_ASSERT(aObject);
mHandle.set(aObject);
}
operator JSObject*() const { return mHandle; }
private:
JS::MutableHandle<JSObject*> mHandle;
};
struct MutableValueHandleWrapper {
explicit MutableValueHandleWrapper(JS::MutableHandle<JS::Value> aHandle)
: mHandle(aHandle) {}
void operator=(JSObject* aObject) {
MOZ_ASSERT(aObject);
#ifdef ENABLE_RECORD_TUPLE
MOZ_ASSERT(!js::gc::MaybeForwardedIsExtendedPrimitive(*aObject));
#endif
mHandle.setObject(*aObject);
}
operator JSObject*() const { return &mHandle.toObject(); }
private:
JS::MutableHandle<JS::Value> mHandle;
};
} // namespace binding_detail
// UnwrapObject overloads that ensure we have a MutableHandle to keep it alive.
template <prototypes::ID PrototypeID, class T, typename U, typename CxType>
MOZ_ALWAYS_INLINE nsresult UnwrapObject(JS::MutableHandle<JSObject*> obj,
U& value, const CxType& cx) {
binding_detail::MutableObjectHandleWrapper wrapper(obj);
return binding_detail::UnwrapObjectInternal<T, true>(
wrapper, value, PrototypeID, PrototypeTraits<PrototypeID>::Depth, cx);
}
template <prototypes::ID PrototypeID, class T, typename U, typename CxType>
MOZ_ALWAYS_INLINE nsresult UnwrapObject(JS::MutableHandle<JS::Value> obj,
U& value, const CxType& cx) {
MOZ_ASSERT(obj.isObject());
binding_detail::MutableValueHandleWrapper wrapper(obj);
return binding_detail::UnwrapObjectInternal<T, true>(
wrapper, value, PrototypeID, PrototypeTraits<PrototypeID>::Depth, cx);
}
// UnwrapObject overloads that ensure we have a strong ref to keep it alive.
template <prototypes::ID PrototypeID, class T, typename U, typename CxType>
MOZ_ALWAYS_INLINE nsresult UnwrapObject(JSObject* obj, RefPtr<U>& value,
const CxType& cx) {
return binding_detail::UnwrapObjectInternal<T, true>(
obj, value, PrototypeID, PrototypeTraits<PrototypeID>::Depth, cx);
}
template <prototypes::ID PrototypeID, class T, typename U, typename CxType>
MOZ_ALWAYS_INLINE nsresult UnwrapObject(JSObject* obj, nsCOMPtr<U>& value,
const CxType& cx) {
return binding_detail::UnwrapObjectInternal<T, true>(
obj, value, PrototypeID, PrototypeTraits<PrototypeID>::Depth, cx);
}
template <prototypes::ID PrototypeID, class T, typename U, typename CxType>
MOZ_ALWAYS_INLINE nsresult UnwrapObject(JSObject* obj, OwningNonNull<U>& value,
const CxType& cx) {
return binding_detail::UnwrapObjectInternal<T, true>(
obj, value, PrototypeID, PrototypeTraits<PrototypeID>::Depth, cx);
}
template <prototypes::ID PrototypeID, class T, typename U, typename CxType>
MOZ_ALWAYS_INLINE nsresult UnwrapObject(JSObject* obj, NonNull<U>& value,
const CxType& cx) {
return binding_detail::UnwrapObjectInternal<T, true>(
obj, value, PrototypeID, PrototypeTraits<PrototypeID>::Depth, cx);
}
// An UnwrapObject overload that just calls one of the JSObject* ones.
template <prototypes::ID PrototypeID, class T, typename U, typename CxType>
MOZ_ALWAYS_INLINE nsresult UnwrapObject(JS::Handle<JS::Value> obj, U& value,
const CxType& cx) {
MOZ_ASSERT(obj.isObject());
return UnwrapObject<PrototypeID, T>(&obj.toObject(), value, cx);
}
template <prototypes::ID PrototypeID, class T, typename U, typename CxType>
MOZ_ALWAYS_INLINE nsresult UnwrapObject(JS::Handle<JS::Value> obj,
NonNull<U>& value, const CxType& cx) {
MOZ_ASSERT(obj.isObject());
return UnwrapObject<PrototypeID, T>(&obj.toObject(), value, cx);
}
template <prototypes::ID PrototypeID>
MOZ_ALWAYS_INLINE void AssertStaticUnwrapOK() {
static_assert(PrototypeID != prototypes::id::Window,
"Can't do static unwrap of WindowProxy; use "
"UNWRAP_MAYBE_CROSS_ORIGIN_OBJECT or a cross-origin-object "
"aware version of IS_INSTANCE_OF");
static_assert(PrototypeID != prototypes::id::EventTarget,
"Can't do static unwrap of WindowProxy (which an EventTarget "
"might be); use UNWRAP_MAYBE_CROSS_ORIGIN_OBJECT or a "
"cross-origin-object aware version of IS_INSTANCE_OF");
static_assert(PrototypeID != prototypes::id::Location,
"Can't do static unwrap of Location; use "
"UNWRAP_MAYBE_CROSS_ORIGIN_OBJECT or a cross-origin-object "
"aware version of IS_INSTANCE_OF");
}
namespace binding_detail {
// This function is just here so we can do some static asserts in a centralized
// place instead of putting them in every single UnwrapObject overload.
template <prototypes::ID PrototypeID, class T, typename U, typename V>
MOZ_ALWAYS_INLINE nsresult UnwrapObjectWithCrossOriginAsserts(V&& obj,
U& value) {
AssertStaticUnwrapOK<PrototypeID>();
return UnwrapObject<PrototypeID, T>(obj, value, nullptr);
}
} // namespace binding_detail
template <prototypes::ID PrototypeID, class T>
MOZ_ALWAYS_INLINE bool IsInstanceOf(JSObject* obj) {
AssertStaticUnwrapOK<PrototypeID>();
void* ignored;
nsresult unwrapped = binding_detail::UnwrapObjectInternal<T, true>(
obj, ignored, PrototypeID, PrototypeTraits<PrototypeID>::Depth, nullptr);
return NS_SUCCEEDED(unwrapped);
}
template <prototypes::ID PrototypeID, class T, typename U>
MOZ_ALWAYS_INLINE nsresult UnwrapNonWrapperObject(JSObject* obj, U& value) {
MOZ_ASSERT(!js::IsWrapper(obj));
return binding_detail::UnwrapObjectInternal<T, false>(
obj, value, PrototypeID, PrototypeTraits<PrototypeID>::Depth, nullptr);
}
MOZ_ALWAYS_INLINE bool IsConvertibleToDictionary(JS::Handle<JS::Value> val) {
return val.isNullOrUndefined() || val.isObject();
}
// The items in the protoAndIfaceCache are indexed by the prototypes::id::ID,
// constructors::id::ID and namedpropertiesobjects::id::ID enums, in that order.
// The end of the prototype objects should be the start of the interface
// objects, and the end of the interface objects should be the start of the
// named properties objects.
static_assert((size_t)constructors::id::_ID_Start ==
(size_t)prototypes::id::_ID_Count &&
(size_t)namedpropertiesobjects::id::_ID_Start ==
(size_t)constructors::id::_ID_Count,
"Overlapping or discontiguous indexes.");
const size_t kProtoAndIfaceCacheCount = namedpropertiesobjects::id::_ID_Count;
class ProtoAndIfaceCache {
// The caching strategy we use depends on what sort of global we're dealing
// with. For a window-like global, we want everything to be as fast as
// possible, so we use a flat array, indexed by prototype/constructor ID.
// For everything else (e.g. globals for JSMs), space is more important than
// speed, so we use a two-level lookup table.
class ArrayCache
: public Array<JS::Heap<JSObject*>, kProtoAndIfaceCacheCount> {
public:
bool HasEntryInSlot(size_t i) {
// Do an explicit call to the Heap<…> bool conversion operator. Because
// that operator is marked explicit we'd otherwise end up doing an
// implicit cast to JSObject* first, causing an unnecessary call to
// exposeToActiveJS().
return bool((*this)[i]);
}
JS::Heap<JSObject*>& EntrySlotOrCreate(size_t i) { return (*this)[i]; }
JS::Heap<JSObject*>& EntrySlotMustExist(size_t i) { return (*this)[i]; }
void Trace(JSTracer* aTracer) {
for (size_t i = 0; i < std::size(*this); ++i) {
JS::TraceEdge(aTracer, &(*this)[i], "protoAndIfaceCache[i]");
}
}
size_t SizeOfIncludingThis(MallocSizeOf aMallocSizeOf) {
return aMallocSizeOf(this);
}
};
class PageTableCache {
public:
PageTableCache() { memset(mPages.begin(), 0, sizeof(mPages)); }
~PageTableCache() {
for (size_t i = 0; i < std::size(mPages); ++i) {
delete mPages[i];
}
}
bool HasEntryInSlot(size_t i) {
MOZ_ASSERT(i < kProtoAndIfaceCacheCount);
size_t pageIndex = i / kPageSize;
size_t leafIndex = i % kPageSize;
Page* p = mPages[pageIndex];
if (!p) {
return false;
}
// Do an explicit call to the Heap<…> bool conversion operator. Because
// that operator is marked explicit we'd otherwise end up doing an
// implicit cast to JSObject* first, causing an unnecessary call to
// exposeToActiveJS().
return bool((*p)[leafIndex]);
}
JS::Heap<JSObject*>& EntrySlotOrCreate(size_t i) {
MOZ_ASSERT(i < kProtoAndIfaceCacheCount);
size_t pageIndex = i / kPageSize;
size_t leafIndex = i % kPageSize;
Page* p = mPages[pageIndex];
if (!p) {
p = new Page;
mPages[pageIndex] = p;
}
return (*p)[leafIndex];
}
JS::Heap<JSObject*>& EntrySlotMustExist(size_t i) {
MOZ_ASSERT(i < kProtoAndIfaceCacheCount);
size_t pageIndex = i / kPageSize;
size_t leafIndex = i % kPageSize;
Page* p = mPages[pageIndex];
MOZ_ASSERT(p);
return (*p)[leafIndex];
}
void Trace(JSTracer* trc) {
for (size_t i = 0; i < std::size(mPages); ++i) {
Page* p = mPages[i];
if (p) {
for (size_t j = 0; j < std::size(*p); ++j) {
JS::TraceEdge(trc, &(*p)[j], "protoAndIfaceCache[i]");
}
}
}
}
size_t SizeOfIncludingThis(MallocSizeOf aMallocSizeOf) {
size_t n = aMallocSizeOf(this);
for (size_t i = 0; i < std::size(mPages); ++i) {
n += aMallocSizeOf(mPages[i]);
}
return n;
}
private:
static const size_t kPageSize = 16;
typedef Array<JS::Heap<JSObject*>, kPageSize> Page;
static const size_t kNPages =
kProtoAndIfaceCacheCount / kPageSize +
size_t(bool(kProtoAndIfaceCacheCount % kPageSize));
Array<Page*, kNPages> mPages;
};
public:
enum Kind { WindowLike, NonWindowLike };
explicit ProtoAndIfaceCache(Kind aKind) : mKind(aKind) {
MOZ_COUNT_CTOR(ProtoAndIfaceCache);
if (aKind == WindowLike) {
mArrayCache = new ArrayCache();
} else {
mPageTableCache = new PageTableCache();
}
}
~ProtoAndIfaceCache() {
if (mKind == WindowLike) {
delete mArrayCache;
} else {
delete mPageTableCache;
}
MOZ_COUNT_DTOR(ProtoAndIfaceCache);
}
#define FORWARD_OPERATION(opName, args) \
do { \
if (mKind == WindowLike) { \
return mArrayCache->opName args; \
} else { \
return mPageTableCache->opName args; \
} \
} while (0)
// Return whether slot i contains an object. This doesn't return the object
// itself because in practice consumers just want to know whether it's there
// or not, and that doesn't require barriering, which returning the object
// pointer does.
bool HasEntryInSlot(size_t i) { FORWARD_OPERATION(HasEntryInSlot, (i)); }
// Return a reference to slot i, creating it if necessary. There
// may not be an object in the returned slot.
JS::Heap<JSObject*>& EntrySlotOrCreate(size_t i) {
FORWARD_OPERATION(EntrySlotOrCreate, (i));
}
// Return a reference to slot i, which is guaranteed to already
// exist. There may not be an object in the slot, if prototype and
// constructor initialization for one of our bindings failed.
JS::Heap<JSObject*>& EntrySlotMustExist(size_t i) {
FORWARD_OPERATION(EntrySlotMustExist, (i));
}
void Trace(JSTracer* aTracer) { FORWARD_OPERATION(Trace, (aTracer)); }
size_t SizeOfIncludingThis(MallocSizeOf aMallocSizeOf) {
size_t n = aMallocSizeOf(this);
n += (mKind == WindowLike
? mArrayCache->SizeOfIncludingThis(aMallocSizeOf)
: mPageTableCache->SizeOfIncludingThis(aMallocSizeOf));
return n;
}
#undef FORWARD_OPERATION
private:
union {
ArrayCache* mArrayCache;
PageTableCache* mPageTableCache;
};
Kind mKind;
};
inline void AllocateProtoAndIfaceCache(JSObject* obj,
ProtoAndIfaceCache::Kind aKind) {
MOZ_ASSERT(JS::GetClass(obj)->flags & JSCLASS_DOM_GLOBAL);
MOZ_ASSERT(JS::GetReservedSlot(obj, DOM_PROTOTYPE_SLOT).isUndefined());
ProtoAndIfaceCache* protoAndIfaceCache = new ProtoAndIfaceCache(aKind);
JS::SetReservedSlot(obj, DOM_PROTOTYPE_SLOT,
JS::PrivateValue(protoAndIfaceCache));
}
#ifdef DEBUG
struct VerifyTraceProtoAndIfaceCacheCalledTracer : public JS::CallbackTracer {
bool ok;
explicit VerifyTraceProtoAndIfaceCacheCalledTracer(JSContext* cx)
: JS::CallbackTracer(cx, JS::TracerKind::VerifyTraceProtoAndIface),
ok(false) {}
void onChild(JS::GCCellPtr, const char* name) override {
// We don't do anything here, we only want to verify that
// TraceProtoAndIfaceCache was called.
}
};
#endif
inline void TraceProtoAndIfaceCache(JSTracer* trc, JSObject* obj) {
MOZ_ASSERT(JS::GetClass(obj)->flags & JSCLASS_DOM_GLOBAL);
#ifdef DEBUG
if (trc->kind() == JS::TracerKind::VerifyTraceProtoAndIface) {
// We don't do anything here, we only want to verify that
// TraceProtoAndIfaceCache was called.
static_cast<VerifyTraceProtoAndIfaceCacheCalledTracer*>(trc)->ok = true;
return;
}
#endif
if (!DOMGlobalHasProtoAndIFaceCache(obj)) return;
ProtoAndIfaceCache* protoAndIfaceCache = GetProtoAndIfaceCache(obj);
protoAndIfaceCache->Trace(trc);
}
inline void DestroyProtoAndIfaceCache(JSObject* obj) {
MOZ_ASSERT(JS::GetClass(obj)->flags & JSCLASS_DOM_GLOBAL);
if (!DOMGlobalHasProtoAndIFaceCache(obj)) {
return;
}
ProtoAndIfaceCache* protoAndIfaceCache = GetProtoAndIfaceCache(obj);
delete protoAndIfaceCache;
}
/**
* Add constants to an object.
*/
bool DefineConstants(JSContext* cx, JS::Handle<JSObject*> obj,
const ConstantSpec* cs);
struct JSNativeHolder {
JSNative mNative;
const NativePropertyHooks* mPropertyHooks;
};
// Struct for holding information for WebIDL interface objects (which are
// function objects). A pointer to this struct is held in the first reserved
// slot of the function object.
struct DOMInterfaceInfo {
JSNativeHolder nativeHolder;
ProtoHandleGetter mGetParentProto;
const uint32_t mDepth;
const prototypes::ID mPrototypeID; // uint16_t
// Boolean indicating whether this object wants a isInstance property
// pointing to InterfaceIsInstance defined on it. Only ever true for
// interfaces.
bool wantsInterfaceIsInstance;
uint8_t mConstructorArgs;
const char* mConstructorName;
};
struct LegacyFactoryFunction {
const char* mName;
const JSNativeHolder mHolder;
uint8_t mNargs;
};
namespace binding_detail {
void CreateInterfaceObjects(
JSContext* cx, JS::Handle<JSObject*> global,
JS::Handle<JSObject*> protoProto, const DOMIfaceAndProtoJSClass* protoClass,
JS::Heap<JSObject*>* protoCache, JS::Handle<JSObject*> interfaceProto,
const DOMInterfaceInfo* interfaceInfo, unsigned ctorNargs,
bool isConstructorChromeOnly,
const Span<const LegacyFactoryFunction>& legacyFactoryFunctions,
JS::Heap<JSObject*>* constructorCache, const NativeProperties* properties,
const NativeProperties* chromeOnlyProperties, const char* name,
bool defineOnGlobal, const char* const* unscopableNames, bool isGlobal,
const char* const* legacyWindowAliases);
} // namespace binding_detail
// clang-format off
/*
* Create a DOM interface object (if constructorClass is non-null) and/or a
* DOM interface prototype object (if protoClass is non-null).
*
* global is used as the parent of the interface object and the interface
* prototype object
* protoProto is the prototype to use for the interface prototype object.
* protoClass is the JSClass to use for the interface prototype object.
* This is null if we should not create an interface prototype
* object.
* protoCache a pointer to a JSObject pointer where we should cache the
* interface prototype object. This must be null if protoClass is and
* vice versa.
* interfaceProto is the prototype to use for the interface object. This can be
* null if interfaceInfo is null (as in, if we're not creating an
* interface object at all).
* interfaceInfo is the info to use for the interface object. This can be null
* if we're not creating an interface object.
* ctorNargs is the length of the constructor function; 0 if no constructor
* isConstructorChromeOnly if true, the constructor is ChromeOnly.
* legacyFactoryFunctions the legacy factory functions (can be empty)
* constructorCache a pointer to a JSObject pointer where we should cache the
* interface object. This must be null if both constructorClass
* and constructor are null, and non-null otherwise.
* properties contains the methods, attributes and constants to be defined on
* objects in any compartment.
* chromeProperties contains the methods, attributes and constants to be defined
* on objects in chrome compartments. This must be null if the
* interface doesn't have any ChromeOnly properties or if the
* object is being created in non-chrome compartment.
* name the name to use for 1) the WebIDL class string, which is the value
* that's used for @@toStringTag, 2) the name property for interface
* objects and 3) the property on the global object that would be set to
* the interface object. In general this is the interface identifier.
* LegacyNamespace would expect something different for 1), but we don't
* support that. The class string for default iterator objects is not
* usable as 2) or 3), but default iterator objects don't have an interface
* object.
* defineOnGlobal controls whether properties should be defined on the given
* global for the interface object (if any) and named
* constructors (if any) for this interface. This can be
* false in situations where we want the properties to only
* appear on privileged Xrays but not on the unprivileged
* underlying global.
* unscopableNames if not null it points to a null-terminated list of const
* char* names of the unscopable properties for this interface.
* isGlobal if true, we're creating interface objects for a [Global] interface,
* and hence shouldn't define properties on the prototype object.
* legacyWindowAliases if not null it points to a null-terminated list of const
* char* names of the legacy window aliases for this
* interface.
*
* At least one of protoClass or interfaceInfo should be non-null. If
* interfaceInfo is non-null, the resulting interface object will be defined on
* the given global with property name |name|, which must also be non-null.
*/
// clang-format on
template <size_t N>
inline void CreateInterfaceObjects(
JSContext* cx, JS::Handle<JSObject*> global,
JS::Handle<JSObject*> protoProto, const DOMIfaceAndProtoJSClass* protoClass,
JS::Heap<JSObject*>* protoCache, JS::Handle<JSObject*> interfaceProto,
const DOMInterfaceInfo* interfaceInfo, unsigned ctorNargs,
bool isConstructorChromeOnly,
const Span<const LegacyFactoryFunction, N>& legacyFactoryFunctions,
JS::Heap<JSObject*>* constructorCache, const NativeProperties* properties,
const NativeProperties* chromeOnlyProperties, const char* name,
bool defineOnGlobal, const char* const* unscopableNames, bool isGlobal,
const char* const* legacyWindowAliases) {
// We're using 1 slot for the interface info already, so we only have
// INTERFACE_OBJECT_MAX_SLOTS - 1 slots for legacy factory functions.
static_assert(N <= INTERFACE_OBJECT_MAX_SLOTS -
INTERFACE_OBJECT_FIRST_LEGACY_FACTORY_FUNCTION);
return binding_detail::CreateInterfaceObjects(
cx, global, protoProto, protoClass, protoCache, interfaceProto,
interfaceInfo, ctorNargs, isConstructorChromeOnly, legacyFactoryFunctions,
constructorCache, properties, chromeOnlyProperties, name, defineOnGlobal,
unscopableNames, isGlobal, legacyWindowAliases);
}
/*
* Create a namespace object.
*
* global the global on which to install a property named with name pointing to
* the namespace object if defineOnGlobal is true.
* namespaceProto is the prototype to use for the namespace object.
* namespaceClass is the JSClass to use for the namespace object.
* namespaceCache a pointer to a JSObject pointer where we should cache the
* namespace object.
* properties contains the methods, attributes and constants to be defined on
* objects in any compartment.
* chromeProperties contains the methods, attributes and constants to be defined
* on objects in chrome compartments. This must be null if the
* namespace doesn't have any ChromeOnly properties or if the
* object is being created in non-chrome compartment.
* name the name to use for the WebIDL class string, which is the value
* that's used for @@toStringTag, and the name of the property on the
* global object that would be set to the namespace object.
* defineOnGlobal controls whether properties should be defined on the given
* global for the namespace object. This can be false in
* situations where we want the properties to only appear on
* privileged Xrays but not on the unprivileged underlying
* global.
*/
void CreateNamespaceObject(JSContext* cx, JS::Handle<JSObject*> global,
JS::Handle<JSObject*> namespaceProto,
const DOMIfaceAndProtoJSClass& namespaceClass,
JS::Heap<JSObject*>* namespaceCache,
const NativeProperties* properties,
const NativeProperties* chromeOnlyProperties,
const char* name, bool defineOnGlobal);
/**
* Define the properties (regular and chrome-only) on obj.
*
* obj the object to install the properties on. This should be the interface
* prototype object for regular interfaces and the instance object for
* interfaces marked with Global.
* properties contains the methods, attributes and constants to be defined on
* objects in any compartment.
* chromeProperties contains the methods, attributes and constants to be defined
* on objects in chrome compartments. This must be null if the
* interface doesn't have any ChromeOnly properties or if the
* object is being created in non-chrome compartment.
*/
bool DefineProperties(JSContext* cx, JS::Handle<JSObject*> obj,
const NativeProperties* properties,
const NativeProperties* chromeOnlyProperties);
/*
* Define the legacy unforgeable methods on an object.
*/
bool DefineLegacyUnforgeableMethods(
JSContext* cx, JS::Handle<JSObject*> obj,
const Prefable<const JSFunctionSpec>* props);
/*
* Define the legacy unforgeable attributes on an object.
*/
bool DefineLegacyUnforgeableAttributes(
JSContext* cx, JS::Handle<JSObject*> obj,
const Prefable<const JSPropertySpec>* props);
#define HAS_MEMBER_TYPEDEFS \
private: \
typedef char yes[1]; \
typedef char no[2]
#ifdef _MSC_VER
# define HAS_MEMBER_CHECK(_name) \
template <typename V> \
static yes& Check##_name(char(*)[(&V::_name == 0) + 1])
#else
# define HAS_MEMBER_CHECK(_name) \
template <typename V> \
static yes& Check##_name(char(*)[sizeof(&V::_name) + 1])
#endif
#define HAS_MEMBER(_memberName, _valueName) \
private: \
HAS_MEMBER_CHECK(_memberName); \
template <typename V> \
static no& Check##_memberName(...); \
\
public: \
static bool const _valueName = \
sizeof(Check##_memberName<T>(nullptr)) == sizeof(yes)
template <class T>
struct NativeHasMember {
HAS_MEMBER_TYPEDEFS;
HAS_MEMBER(GetParentObject, GetParentObject);
HAS_MEMBER(WrapObject, WrapObject);
};
template <class T>
struct IsSmartPtr {
HAS_MEMBER_TYPEDEFS;
HAS_MEMBER(get, value);
};
template <class T>
struct IsRefcounted {
HAS_MEMBER_TYPEDEFS;
HAS_MEMBER(AddRef, HasAddref);
HAS_MEMBER(Release, HasRelease);
public:
static bool const value = HasAddref && HasRelease;
private:
// This struct only works if T is fully declared (not just forward declared).
// The std::is_base_of check will ensure that, we don't really need it for any
// other reason (the static assert will of course always be true).
static_assert(!std::is_base_of<nsISupports, T>::value || IsRefcounted::value,
"Classes derived from nsISupports are refcounted!");
};
#undef HAS_MEMBER
#undef HAS_MEMBER_CHECK
#undef HAS_MEMBER_TYPEDEFS
#ifdef DEBUG
template <class T, bool isISupports = std::is_base_of<nsISupports, T>::value>
struct CheckWrapperCacheCast {
static bool Check() {
return reinterpret_cast<uintptr_t>(
static_cast<nsWrapperCache*>(reinterpret_cast<T*>(1))) == 1;
}
};
template <class T>
struct CheckWrapperCacheCast<T, true> {
static bool Check() { return true; }
};
#endif
inline bool TryToOuterize(JS::MutableHandle<JS::Value> rval) {
#ifdef ENABLE_RECORD_TUPLE
if (rval.isExtendedPrimitive()) {
return true;
}
#endif
MOZ_ASSERT(rval.isObject());
if (js::IsWindow(&rval.toObject())) {
JSObject* obj = js::ToWindowProxyIfWindow(&rval.toObject());
MOZ_ASSERT(obj);
rval.set(JS::ObjectValue(*obj));
}
return true;
}
inline bool TryToOuterize(JS::MutableHandle<JSObject*> obj) {
if (js::IsWindow(obj)) {
JSObject* proxy = js::ToWindowProxyIfWindow(obj);
MOZ_ASSERT(proxy);
obj.set(proxy);
}
return true;
}
// Make sure to wrap the given string value into the right compartment, as
// needed.
MOZ_ALWAYS_INLINE
bool MaybeWrapStringValue(JSContext* cx, JS::MutableHandle<JS::Value> rval) {
MOZ_ASSERT(rval.isString());
JSString* str = rval.toString();
if (JS::GetStringZone(str) != js::GetContextZone(cx)) {
return JS_WrapValue(cx, rval);
}
return true;
}
// Make sure to wrap the given object value into the right compartment as
// needed. This will work correctly, but possibly slowly, on all objects.
MOZ_ALWAYS_INLINE
bool MaybeWrapObjectValue(JSContext* cx, JS::MutableHandle<JS::Value> rval) {
MOZ_ASSERT(rval.hasObjectPayload());
// Cross-compartment always requires wrapping.
JSObject* obj = &rval.getObjectPayload();
if (JS::GetCompartment(obj) != js::GetContextCompartment(cx)) {
return JS_WrapValue(cx, rval);
}
// We're same-compartment, but we might still need to outerize if we
// have a Window.
return TryToOuterize(rval);
}
// Like MaybeWrapObjectValue, but working with a
// JS::MutableHandle<JSObject*> which must be non-null.
MOZ_ALWAYS_INLINE
bool MaybeWrapObject(JSContext* cx, JS::MutableHandle<JSObject*> obj) {
if (JS::GetCompartment(obj) != js::GetContextCompartment(cx)) {
return JS_WrapObject(cx, obj);
}
// We're same-compartment, but we might still need to outerize if we
// have a Window.
return TryToOuterize(obj);
}
// Like MaybeWrapObjectValue, but also allows null
MOZ_ALWAYS_INLINE
bool MaybeWrapObjectOrNullValue(JSContext* cx,
JS::MutableHandle<JS::Value> rval) {
MOZ_ASSERT(rval.isObjectOrNull());
if (rval.isNull()) {
return true;
}
return MaybeWrapObjectValue(cx, rval);
}
// Wrapping for objects that are known to not be DOM objects
MOZ_ALWAYS_INLINE
bool MaybeWrapNonDOMObjectValue(JSContext* cx,
JS::MutableHandle<JS::Value> rval) {
MOZ_ASSERT(rval.isObject());
// Compared to MaybeWrapObjectValue we just skip the TryToOuterize call. The
// only reason it would be needed is if we have a Window object, which would
// have a DOM class. Assert that we don't have any DOM-class objects coming
// through here.
MOZ_ASSERT(!GetDOMClass(&rval.toObject()));
JSObject* obj = &rval.toObject();
if (JS::GetCompartment(obj) == js::GetContextCompartment(cx)) {
return true;
}
return JS_WrapValue(cx, rval);
}
// Like MaybeWrapNonDOMObjectValue but allows null
MOZ_ALWAYS_INLINE
bool MaybeWrapNonDOMObjectOrNullValue(JSContext* cx,
JS::MutableHandle<JS::Value> rval) {
MOZ_ASSERT(rval.isObjectOrNull());
if (rval.isNull()) {
return true;
}
return MaybeWrapNonDOMObjectValue(cx, rval);
}
// If rval is a gcthing and is not in the compartment of cx, wrap rval
// into the compartment of cx (typically by replacing it with an Xray or
// cross-compartment wrapper around the original object).
MOZ_ALWAYS_INLINE bool MaybeWrapValue(JSContext* cx,
JS::MutableHandle<JS::Value> rval) {
if (rval.isGCThing()) {
if (rval.isString()) {
return MaybeWrapStringValue(cx, rval);
}
if (rval.hasObjectPayload()) {
return MaybeWrapObjectValue(cx, rval);
}
// This could be optimized by checking the zone first, similar to
// the way strings are handled. At present, this is used primarily
// for structured cloning, so avoiding the overhead of JS_WrapValue
// calls is less important than for other types.
if (rval.isBigInt()) {
return JS_WrapValue(cx, rval);
}
MOZ_ASSERT(rval.isSymbol());
JS_MarkCrossZoneId(cx, JS::PropertyKey::Symbol(rval.toSymbol()));
}
return true;
}
namespace binding_detail {
enum GetOrCreateReflectorWrapBehavior {
eWrapIntoContextCompartment,
eDontWrapIntoContextCompartment
};
template <class T>
struct TypeNeedsOuterization {
// We only need to outerize Window objects, so anything inheriting from
// nsGlobalWindow (which inherits from EventTarget itself).
static const bool value = std::is_base_of<nsGlobalWindowInner, T>::value ||
std::is_base_of<nsGlobalWindowOuter, T>::value ||
std::is_same_v<EventTarget, T>;
};
#ifdef DEBUG
template <typename T, bool isISupports = std::is_base_of<nsISupports, T>::value>
struct CheckWrapperCacheTracing {
static inline void Check(T* aObject) {}
};
template <typename T>
struct CheckWrapperCacheTracing<T, true> {
static void Check(T* aObject) {
// Rooting analysis thinks QueryInterface may GC, but we're dealing with
// a subset of QueryInterface, C++ only types here.
JS::AutoSuppressGCAnalysis nogc;
nsWrapperCache* wrapperCacheFromQI = nullptr;
aObject->QueryInterface(NS_GET_IID(nsWrapperCache),
reinterpret_cast<void**>(&wrapperCacheFromQI));
MOZ_ASSERT(wrapperCacheFromQI,
"Missing nsWrapperCache from QueryInterface implementation?");
if (!wrapperCacheFromQI->GetWrapperPreserveColor()) {
// Can't assert that we trace the wrapper, since we don't have any
// wrapper to trace.
return;
}
nsISupports* ccISupports = nullptr;
aObject->QueryInterface(NS_GET_IID(nsCycleCollectionISupports),
reinterpret_cast<void**>(&ccISupports));
MOZ_ASSERT(ccISupports,
"nsWrapperCache object which isn't cycle collectable?");
nsXPCOMCycleCollectionParticipant* participant = nullptr;
CallQueryInterface(ccISupports, &participant);
MOZ_ASSERT(participant, "Can't QI to CycleCollectionParticipant?");
wrapperCacheFromQI->CheckCCWrapperTraversal(ccISupports, participant);
}
};
void AssertReflectorHasGivenProto(JSContext* aCx, JSObject* aReflector,
JS::Handle<JSObject*> aGivenProto);
#endif // DEBUG
template <class T, GetOrCreateReflectorWrapBehavior wrapBehavior>
MOZ_ALWAYS_INLINE bool DoGetOrCreateDOMReflector(
JSContext* cx, T* value, JS::Handle<JSObject*> givenProto,
JS::MutableHandle<JS::Value> rval) {
MOZ_ASSERT(value);
MOZ_ASSERT_IF(givenProto, js::IsObjectInContextCompartment(givenProto, cx));
JSObject* obj = value->GetWrapper();
if (obj) {
#ifdef DEBUG
AssertReflectorHasGivenProto(cx, obj, givenProto);
// Have to reget obj because AssertReflectorHasGivenProto can
// trigger gc so the pointer may now be invalid.
obj = value->GetWrapper();
#endif
} else {
obj = value->WrapObject(cx, givenProto);
if (!obj) {
// At this point, obj is null, so just return false.
// Callers seem to be testing JS_IsExceptionPending(cx) to
// figure out whether WrapObject() threw.
return false;
}
#ifdef DEBUG
if (std::is_base_of<nsWrapperCache, T>::value) {
CheckWrapperCacheTracing<T>::Check(value);
}
#endif
}
#ifdef DEBUG
const DOMJSClass* clasp = GetDOMClass(obj);
// clasp can be null if the cache contained a non-DOM object.
if (clasp) {
// Some sanity asserts about our object. Specifically:
// 1) If our class claims we're nsISupports, we better be nsISupports
// XXXbz ideally, we could assert that reinterpret_cast to nsISupports
// does the right thing, but I don't see a way to do it. :(
// 2) If our class doesn't claim we're nsISupports we better be
// reinterpret_castable to nsWrapperCache.
MOZ_ASSERT(clasp, "What happened here?");
MOZ_ASSERT_IF(clasp->mDOMObjectIsISupports,
(std::is_base_of<nsISupports, T>::value));
MOZ_ASSERT(CheckWrapperCacheCast<T>::Check());
}
#endif
#ifdef ENABLE_RECORD_TUPLE
MOZ_ASSERT(!js::gc::MaybeForwardedIsExtendedPrimitive(*obj));
#endif
rval.set(JS::ObjectValue(*obj));
if (JS::GetCompartment(obj) == js::GetContextCompartment(cx)) {
return TypeNeedsOuterization<T>::value ? TryToOuterize(rval) : true;
}
if (wrapBehavior == eDontWrapIntoContextCompartment) {
if (TypeNeedsOuterization<T>::value) {
JSAutoRealm ar(cx, obj);
return TryToOuterize(rval);
}
return true;
}
return JS_WrapValue(cx, rval);
}
} // namespace binding_detail
// Create a JSObject wrapping "value", if there isn't one already, and store it
// in rval. "value" must be a concrete class that implements a
// GetWrapperPreserveColor() which can return its existing wrapper, if any, and
// a WrapObject() which will try to create a wrapper. Typically, this is done by
// having "value" inherit from nsWrapperCache.
//
// The value stored in rval will be ready to be exposed to whatever JS
// is running on cx right now. In particular, it will be in the
// compartment of cx, and outerized as needed.
template <class T>
MOZ_ALWAYS_INLINE bool GetOrCreateDOMReflector(
JSContext* cx, T* value, JS::MutableHandle<JS::Value> rval,
JS::Handle<JSObject*> givenProto = nullptr) {
using namespace binding_detail;
return DoGetOrCreateDOMReflector<T, eWrapIntoContextCompartment>(
cx, value, givenProto, rval);
}
// Like GetOrCreateDOMReflector but doesn't wrap into the context compartment,
// and hence does not actually require cx to be in a compartment.
template <class T>
MOZ_ALWAYS_INLINE bool GetOrCreateDOMReflectorNoWrap(
JSContext* cx, T* value, JS::MutableHandle<JS::Value> rval) {
using namespace binding_detail;
return DoGetOrCreateDOMReflector<T, eDontWrapIntoContextCompartment>(
cx, value, nullptr, rval);
}
// Helper for different overloadings of WrapNewBindingNonWrapperCachedObject()
inline bool FinishWrapping(JSContext* cx, JS::Handle<JSObject*> obj,
JS::MutableHandle<JS::Value> rval) {
#ifdef ENABLE_RECORD_TUPLE
// If calling an (object) value's WrapObject() method returned a record/tuple,
// then something is very wrong.
MOZ_ASSERT(!js::gc::MaybeForwardedIsExtendedPrimitive(*obj));
#endif
// We can end up here in all sorts of compartments, per comments in
// WrapNewBindingNonWrapperCachedObject(). Make sure to JS_WrapValue!
rval.set(JS::ObjectValue(*obj));
return MaybeWrapObjectValue(cx, rval);
}
// Create a JSObject wrapping "value", for cases when "value" is a
// non-wrapper-cached object using WebIDL bindings. "value" must implement a
// WrapObject() method taking a JSContext and a prototype (possibly null) and
// returning the resulting object via a MutableHandle<JSObject*> outparam.
template <class T>
inline bool WrapNewBindingNonWrapperCachedObject(
JSContext* cx, JS::Handle<JSObject*> scopeArg, T* value,
JS::MutableHandle<JS::Value> rval,
JS::Handle<JSObject*> givenProto = nullptr) {
static_assert(IsRefcounted<T>::value, "Don't pass owned classes in here.");
MOZ_ASSERT(value);
// We try to wrap in the realm of the underlying object of "scope"
JS::Rooted<JSObject*> obj(cx);
{
// scope for the JSAutoRealm so that we restore the realm
// before we call JS_WrapValue.
Maybe<JSAutoRealm> ar;
// Maybe<Handle> doesn't so much work, and in any case, adding
// more Maybe (one for a Rooted and one for a Handle) adds more
// code (and branches!) than just adding a single rooted.
JS::Rooted<JSObject*> scope(cx, scopeArg);
JS::Rooted<JSObject*> proto(cx, givenProto);
if (js::IsWrapper(scope)) {
// We are working in the Realm of cx and will be producing our reflector
// there, so we need to succeed if that realm has access to the scope.
scope =
js::CheckedUnwrapDynamic(scope, cx, /* stopAtWindowProxy = */ false);
if (!scope) return false;
ar.emplace(cx, scope);
if (!JS_WrapObject(cx, &proto)) {
return false;
}
} else {
// cx and scope are same-compartment, but they might still be
// different-Realm. Enter the Realm of scope, since that's
// where we want to create our object.
ar.emplace(cx, scope);
}
MOZ_ASSERT_IF(proto, js::IsObjectInContextCompartment(proto, cx));
MOZ_ASSERT(js::IsObjectInContextCompartment(scope, cx));
if (!value->WrapObject(cx, proto, &obj)) {
return false;
}
}
return FinishWrapping(cx, obj, rval);
}
// Create a JSObject wrapping "value", for cases when "value" is a
// non-wrapper-cached owned object using WebIDL bindings. "value" must
// implement a WrapObject() method taking a taking a JSContext and a prototype
// (possibly null) and returning two pieces of information: the resulting object
// via a MutableHandle<JSObject*> outparam and a boolean return value that is
// true if the JSObject took ownership
template <class T>
inline bool WrapNewBindingNonWrapperCachedObject(
JSContext* cx, JS::Handle<JSObject*> scopeArg, UniquePtr<T>& value,
JS::MutableHandle<JS::Value> rval,
JS::Handle<JSObject*> givenProto = nullptr) {
static_assert(!IsRefcounted<T>::value, "Only pass owned classes in here.");
// We do a runtime check on value, because otherwise we might in
// fact end up wrapping a null and invoking methods on it later.
if (!value) {
MOZ_CRASH("Don't try to wrap null objects");
}
// We try to wrap in the realm of the underlying object of "scope"
JS::Rooted<JSObject*> obj(cx);
{
// scope for the JSAutoRealm so that we restore the realm
// before we call JS_WrapValue.
Maybe<JSAutoRealm> ar;
// Maybe<Handle> doesn't so much work, and in any case, adding
// more Maybe (one for a Rooted and one for a Handle) adds more
// code (and branches!) than just adding a single rooted.
JS::Rooted<JSObject*> scope(cx, scopeArg);
JS::Rooted<JSObject*> proto(cx, givenProto);
if (js::IsWrapper(scope)) {
// We are working in the Realm of cx and will be producing our reflector
// there, so we need to succeed if that realm has access to the scope.
scope =
js::CheckedUnwrapDynamic(scope, cx, /* stopAtWindowProxy = */ false);
if (!scope) return false;
ar.emplace(cx, scope);
if (!JS_WrapObject(cx, &proto)) {
return false;
}
} else {
// cx and scope are same-compartment, but they might still be
// different-Realm. Enter the Realm of scope, since that's
// where we want to create our object.
ar.emplace(cx, scope);
}
MOZ_ASSERT_IF(proto, js::IsObjectInContextCompartment(proto, cx));
MOZ_ASSERT(js::IsObjectInContextCompartment(scope, cx));
if (!value->WrapObject(cx, proto, &obj)) {
return false;
}
// JS object took ownership
Unused << value.release();
}
return FinishWrapping(cx, obj, rval);
}
// Helper for smart pointers (nsRefPtr/nsCOMPtr).
template <template <typename> class SmartPtr, typename T,
typename U = std::enable_if_t<IsRefcounted<T>::value, T>,
typename V = std::enable_if_t<IsSmartPtr<SmartPtr<T>>::value, T>>
inline bool WrapNewBindingNonWrapperCachedObject(
JSContext* cx, JS::Handle<JSObject*> scope, const SmartPtr<T>& value,
JS::MutableHandle<JS::Value> rval,
JS::Handle<JSObject*> givenProto = nullptr) {
return WrapNewBindingNonWrapperCachedObject(cx, scope, value.get(), rval,
givenProto);
}
// Helper for object references (as opposed to pointers).
template <typename T, typename U = std::enable_if_t<!IsSmartPtr<T>::value, T>>
inline bool WrapNewBindingNonWrapperCachedObject(
JSContext* cx, JS::Handle<JSObject*> scope, T& value,
JS::MutableHandle<JS::Value> rval,
JS::Handle<JSObject*> givenProto = nullptr) {
return WrapNewBindingNonWrapperCachedObject(cx, scope, &value, rval,
givenProto);
}
template <bool Fatal>
inline bool EnumValueNotFound(BindingCallContext& cx, JS::Handle<JSString*> str,
const char* type, const char* sourceDescription);
template <>
inline bool EnumValueNotFound<false>(BindingCallContext& cx,
JS::Handle<JSString*> str,
const char* type,
const char* sourceDescription) {
// TODO: Log a warning to the console.
return true;
}
template <>
inline bool EnumValueNotFound<true>(BindingCallContext& cx,
JS::Handle<JSString*> str, const char* type,
const char* sourceDescription) {
JS::UniqueChars deflated = JS_EncodeStringToUTF8(cx, str);
if (!deflated) {
return false;
}
return cx.ThrowErrorMessage<MSG_INVALID_ENUM_VALUE>(sourceDescription,
deflated.get(), type);
}
namespace binding_detail {
template <typename CharT>
inline int FindEnumStringIndexImpl(const CharT* chars, size_t length,
const Span<const nsLiteralCString>& values) {
for (size_t i = 0; i < values.Length(); ++i) {
const nsLiteralCString& value = values[i];
if (length != value.Length()) {
continue;
}
bool equal = true;
for (size_t j = 0; j != length; ++j) {
if (unsigned(value.CharAt(j)) != unsigned(chars[j])) {
equal = false;
break;
}
}
if (equal) {
return (int)i;
}
}
return -1;
}
template <bool InvalidValueFatal>
inline bool FindEnumStringIndex(BindingCallContext& cx, JS::Handle<JS::Value> v,
const Span<const nsLiteralCString>& values,
const char* type, const char* sourceDescription,
int* index) {
// JS_StringEqualsAscii is slow as molasses, so don't use it here.
JS::Rooted<JSString*> str(cx, JS::ToString(cx, v));
if (!str) {
return false;
}
{
size_t length;
JS::AutoCheckCannotGC nogc;
if (JS::StringHasLatin1Chars(str)) {
const JS::Latin1Char* chars =
JS_GetLatin1StringCharsAndLength(cx, nogc, str, &length);
if (!chars) {
return false;
}
*index = FindEnumStringIndexImpl(chars, length, values);
} else {
const char16_t* chars =
JS_GetTwoByteStringCharsAndLength(cx, nogc, str, &length);
if (!chars) {
return false;
}
*index = FindEnumStringIndexImpl(chars, length, values);
}
if (*index >= 0) {
return true;
}
}
return EnumValueNotFound<InvalidValueFatal>(cx, str, type, sourceDescription);
}
} // namespace binding_detail
template <typename Enum, class StringT>
inline Maybe<Enum> StringToEnum(const StringT& aString) {
int index = binding_detail::FindEnumStringIndexImpl(
aString.BeginReading(), aString.Length(),
binding_detail::EnumStrings<Enum>::Values);
return index >= 0 ? Some(static_cast<Enum>(index)) : Nothing();
}
template <typename Enum>
inline constexpr const nsLiteralCString& GetEnumString(Enum stringId) {
MOZ_RELEASE_ASSERT(static_cast<size_t>(stringId) <
std::size(binding_detail::EnumStrings<Enum>::Values));
return binding_detail::EnumStrings<Enum>::Values[static_cast<size_t>(
stringId)];
}
template <typename Enum>
constexpr mozilla::detail::EnumeratedRange<Enum> MakeWebIDLEnumeratedRange() {
return MakeInclusiveEnumeratedRange(ContiguousEnumValues<Enum>::min,
ContiguousEnumValues<Enum>::max);
}
inline nsWrapperCache* GetWrapperCache(const ParentObject& aParentObject) {
return aParentObject.mWrapperCache;
}
template <class T>
inline T* GetParentPointer(T* aObject) {
return aObject;
}
inline nsISupports* GetParentPointer(const ParentObject& aObject) {
return aObject.mObject;
}
template <typename T>
inline mozilla::dom::ReflectionScope GetReflectionScope(T* aParentObject) {
return mozilla::dom::ReflectionScope::Content;
}
inline mozilla::dom::ReflectionScope GetReflectionScope(
const ParentObject& aParentObject) {
return aParentObject.mReflectionScope;
}
template <class T>
inline void ClearWrapper(T* p, nsWrapperCache* cache, JSObject* obj) {
MOZ_ASSERT(cache->GetWrapperMaybeDead() == obj ||
(js::RuntimeIsBeingDestroyed() && !cache->GetWrapperMaybeDead()));
cache->ClearWrapper(obj);
}
template <class T>
inline void ClearWrapper(T* p, void*, JSObject* obj) {
// QueryInterface to nsWrapperCache can't GC, we hope.
JS::AutoSuppressGCAnalysis nogc;
nsWrapperCache* cache;
CallQueryInterface(p, &cache);
ClearWrapper(p, cache, obj);
}
template <class T>
inline void UpdateWrapper(T* p, nsWrapperCache* cache, JSObject* obj,
const JSObject* old) {
JS::AutoAssertGCCallback inCallback;
cache->UpdateWrapper(obj, old);
}
template <class T>
inline void UpdateWrapper(T* p, void*, JSObject* obj, const JSObject* old) {
JS::AutoAssertGCCallback inCallback;
nsWrapperCache* cache;
CallQueryInterface(p, &cache);
UpdateWrapper(p, cache, obj, old);
}
// Attempt to preserve the wrapper, if any, for a Paris DOM bindings object.
// Return true if we successfully preserved the wrapper, or there is no wrapper
// to preserve. In the latter case we don't need to preserve the wrapper,
// because the object can only be obtained by JS once, or they cannot be
// meaningfully owned from the native side.
//
// This operation will return false only for non-nsISupports cycle-collected
// objects, because we cannot determine if they are wrappercached or not.
bool TryPreserveWrapper(JS::Handle<JSObject*> obj);
bool HasReleasedWrapper(JS::Handle<JSObject*> obj);
// Can only be called with a DOM JSClass.
bool InstanceClassHasProtoAtDepth(const JSClass* clasp, uint32_t protoID,
uint32_t depth);
// Only set allowNativeWrapper to false if you really know you need it; if in
// doubt use true. Setting it to false disables security wrappers.
bool XPCOMObjectToJsval(JSContext* cx, JS::Handle<JSObject*> scope,
xpcObjectHelper& helper, const nsIID* iid,
bool allowNativeWrapper,
JS::MutableHandle<JS::Value> rval);
// Special-cased wrapping for variants
bool VariantToJsval(JSContext* aCx, nsIVariant* aVariant,
JS::MutableHandle<JS::Value> aRetval);
// Wrap an object "p" which is not using WebIDL bindings yet. This _will_
// actually work on WebIDL binding objects that are wrappercached, but will be
// much slower than GetOrCreateDOMReflector. "cache" must either be null or be
// the nsWrapperCache for "p".
template <class T>
inline bool WrapObject(JSContext* cx, T* p, nsWrapperCache* cache,
const nsIID* iid, JS::MutableHandle<JS::Value> rval) {
if (xpc_FastGetCachedWrapper(cx, cache, rval)) return true;
xpcObjectHelper helper(ToSupports(p), cache);
JS::Rooted<JSObject*> scope(cx, JS::CurrentGlobalOrNull(cx));
return XPCOMObjectToJsval(cx, scope, helper, iid, true, rval);
}
// A specialization of the above for nsIVariant, because that needs to
// do something different.
template <>
inline bool WrapObject<nsIVariant>(JSContext* cx, nsIVariant* p,
nsWrapperCache* cache, const nsIID* iid,
JS::MutableHandle<JS::Value> rval) {
MOZ_ASSERT(iid);
MOZ_ASSERT(iid->Equals(NS_GET_IID(nsIVariant)));
return VariantToJsval(cx, p, rval);
}
// Wrap an object "p" which is not using WebIDL bindings yet. Just like the
// variant that takes an nsWrapperCache above, but will try to auto-derive the
// nsWrapperCache* from "p".
template <class T>
inline bool WrapObject(JSContext* cx, T* p, const nsIID* iid,
JS::MutableHandle<JS::Value> rval) {
return WrapObject(cx, p, GetWrapperCache(p), iid, rval);
}
// Just like the WrapObject above, but without requiring you to pick which
// interface you're wrapping as. This should only be used for objects that have
// classinfo, for which it doesn't matter what IID is used to wrap.
template <class T>
inline bool WrapObject(JSContext* cx, T* p, JS::MutableHandle<JS::Value> rval) {
return WrapObject(cx, p, nullptr, rval);
}
// Helper to make it possible to wrap directly out of an nsCOMPtr
template <class T>
inline bool WrapObject(JSContext* cx, const nsCOMPtr<T>& p, const nsIID* iid,
JS::MutableHandle<JS::Value> rval) {
return WrapObject(cx, p.get(), iid, rval);
}
// Helper to make it possible to wrap directly out of an nsCOMPtr
template <class T>
inline bool WrapObject(JSContext* cx, const nsCOMPtr<T>& p,
JS::MutableHandle<JS::Value> rval) {
return WrapObject(cx, p, nullptr, rval);
}
// Helper to make it possible to wrap directly out of an nsRefPtr
template <class T>
inline bool WrapObject(JSContext* cx, const RefPtr<T>& p, const nsIID* iid,
JS::MutableHandle<JS::Value> rval) {
return WrapObject(cx, p.get(), iid, rval);
}
// Helper to make it possible to wrap directly out of an nsRefPtr
template <class T>
inline bool WrapObject(JSContext* cx, const RefPtr<T>& p,
JS::MutableHandle<JS::Value> rval) {
return WrapObject(cx, p, nullptr, rval);
}
// Specialization to make it easy to use WrapObject in codegen.
template <>
inline bool WrapObject<JSObject>(JSContext* cx, JSObject* p,
JS::MutableHandle<JS::Value> rval) {
rval.set(JS::ObjectOrNullValue(p));
return true;
}
inline bool WrapObject(JSContext* cx, JSObject& p,
JS::MutableHandle<JS::Value> rval) {
rval.set(JS::ObjectValue(p));
return true;
}
bool WrapObject(JSContext* cx, const WindowProxyHolder& p,
JS::MutableHandle<JS::Value> rval);
// Given an object "p" that inherits from nsISupports, wrap it and return the
// result. Null is returned on wrapping failure. This is somewhat similar to
// WrapObject() above, but does NOT allow Xrays around the result, since we
// don't want those for our parent object.
template <typename T>
static inline JSObject* WrapNativeISupports(JSContext* cx, T* p,
nsWrapperCache* cache) {
JS::Rooted<JSObject*> retval(cx);
{
xpcObjectHelper helper(ToSupports(p), cache);
JS::Rooted<JSObject*> scope(cx, JS::CurrentGlobalOrNull(cx));
JS::Rooted<JS::Value> v(cx);
retval = XPCOMObjectToJsval(cx, scope, helper, nullptr, false, &v)
? v.toObjectOrNull()
: nullptr;
}
return retval;
}
// Wrapping of our native parent, for cases when it's a WebIDL object.
template <typename T, bool hasWrapObject = NativeHasMember<T>::WrapObject>
struct WrapNativeHelper {
static inline JSObject* Wrap(JSContext* cx, T* parent,
nsWrapperCache* cache) {
MOZ_ASSERT(cache);
JSObject* obj;
if ((obj = cache->GetWrapper())) {
// GetWrapper always unmarks gray.
JS::AssertObjectIsNotGray(obj);
return obj;
}
// WrapObject never returns a gray thing.
obj = parent->WrapObject(cx, nullptr);
JS::AssertObjectIsNotGray(obj);
return obj;
}
};
// Wrapping of our native parent, for cases when it's not a WebIDL object. In
// this case it must be nsISupports.
template <typename T>
struct WrapNativeHelper<T, false> {
static inline JSObject* Wrap(JSContext* cx, T* parent,
nsWrapperCache* cache) {
JSObject* obj;
if (cache && (obj = cache->GetWrapper())) {
#ifdef DEBUG
JS::Rooted<JSObject*> rootedObj(cx, obj);
NS_ASSERTION(WrapNativeISupports(cx, parent, cache) == rootedObj,
"Unexpected object in nsWrapperCache");
obj = rootedObj;
#endif
JS::AssertObjectIsNotGray(obj);
return obj;
}
obj = WrapNativeISupports(cx, parent, cache);
JS::AssertObjectIsNotGray(obj);
return obj;
}
};
// Finding the associated global for an object.
template <typename T>
static inline JSObject* FindAssociatedGlobal(
JSContext* cx, T* p, nsWrapperCache* cache,
mozilla::dom::ReflectionScope scope =
mozilla::dom::ReflectionScope::Content) {
if (!p) {
return JS::CurrentGlobalOrNull(cx);
}
JSObject* obj = WrapNativeHelper<T>::Wrap(cx, p, cache);
if (!obj) {
return nullptr;
}
JS::AssertObjectIsNotGray(obj);
// The object is never a CCW but it may not be in the current compartment of
// the JSContext.
obj = JS::GetNonCCWObjectGlobal(obj);
switch (scope) {
case mozilla::dom::ReflectionScope::NAC: {
return xpc::NACScope(obj);
}
case mozilla::dom::ReflectionScope::UAWidget: {
// If scope is set to UAWidgetScope, it means that the canonical reflector
// for this native object should live in the UA widget scope.
if (xpc::IsInUAWidgetScope(obj)) {
return obj;
}
JS::Rooted<JSObject*> rootedObj(cx, obj);
JSObject* uaWidgetScope = xpc::GetUAWidgetScope(cx, rootedObj);
MOZ_ASSERT_IF(uaWidgetScope, JS_IsGlobalObject(uaWidgetScope));
JS::AssertObjectIsNotGray(uaWidgetScope);
return uaWidgetScope;
}
case ReflectionScope::Content:
return obj;
}
MOZ_CRASH("Unknown ReflectionScope variant");
return nullptr;
}
// Finding of the associated global for an object, when we don't want to
// explicitly pass in things like the nsWrapperCache for it.
template <typename T>
static inline JSObject* FindAssociatedGlobal(JSContext* cx, const T& p) {
return FindAssociatedGlobal(cx, GetParentPointer(p), GetWrapperCache(p),
GetReflectionScope(p));
}
// Specialization for the case of nsIGlobalObject, since in that case
// we can just get the JSObject* directly.
template <>
inline JSObject* FindAssociatedGlobal(JSContext* cx,
nsIGlobalObject* const& p) {
if (!p) {
return JS::CurrentGlobalOrNull(cx);
}
JSObject* global = p->GetGlobalJSObject();
if (!global) {
// nsIGlobalObject doesn't have a JS object anymore,
// fallback to the current global.
return JS::CurrentGlobalOrNull(cx);
}
MOZ_ASSERT(JS_IsGlobalObject(global));
JS::AssertObjectIsNotGray(global);
return global;
}
template <typename T,
bool hasAssociatedGlobal = NativeHasMember<T>::GetParentObject>
struct FindAssociatedGlobalForNative {
static JSObject* Get(JSContext* cx, JS::Handle<JSObject*> obj) {
MOZ_ASSERT(js::IsObjectInContextCompartment(obj, cx));
T* native = UnwrapDOMObject<T>(obj);
return FindAssociatedGlobal(cx, native->GetParentObject());
}
};
template <typename T>
struct FindAssociatedGlobalForNative<T, false> {
static JSObject* Get(JSContext* cx, JS::Handle<JSObject*> obj) {
MOZ_CRASH();
return nullptr;
}
};
// Helper for calling GetOrCreateDOMReflector with smart pointers
// (UniquePtr/RefPtr/nsCOMPtr) or references.
template <class T, bool isSmartPtr = IsSmartPtr<T>::value>
struct GetOrCreateDOMReflectorHelper {
static inline bool GetOrCreate(JSContext* cx, const T& value,
JS::Handle<JSObject*> givenProto,
JS::MutableHandle<JS::Value> rval) {
return GetOrCreateDOMReflector(cx, value.get(), rval, givenProto);
}
};
template <class T>
struct GetOrCreateDOMReflectorHelper<T, false> {
static inline bool GetOrCreate(JSContext* cx, T& value,
JS::Handle<JSObject*> givenProto,
JS::MutableHandle<JS::Value> rval) {
static_assert(IsRefcounted<T>::value, "Don't pass owned classes in here.");
return GetOrCreateDOMReflector(cx, &value, rval, givenProto);
}
};
template <class T>
inline bool GetOrCreateDOMReflector(
JSContext* cx, T& value, JS::MutableHandle<JS::Value> rval,
JS::Handle<JSObject*> givenProto = nullptr) {
return GetOrCreateDOMReflectorHelper<T>::GetOrCreate(cx, value, givenProto,
rval);
}
// Helper for calling GetOrCreateDOMReflectorNoWrap with smart pointers
// (UniquePtr/RefPtr/nsCOMPtr) or references.
template <class T, bool isSmartPtr = IsSmartPtr<T>::value>
struct GetOrCreateDOMReflectorNoWrapHelper {
static inline bool GetOrCreate(JSContext* cx, const T& value,
JS::MutableHandle<JS::Value> rval) {
return GetOrCreateDOMReflectorNoWrap(cx, value.get(), rval);
}
};
template <class T>
struct GetOrCreateDOMReflectorNoWrapHelper<T, false> {
static inline bool GetOrCreate(JSContext* cx, T& value,
JS::MutableHandle<JS::Value> rval) {
return GetOrCreateDOMReflectorNoWrap(cx, &value, rval);
}
};
template <class T>
inline bool GetOrCreateDOMReflectorNoWrap(JSContext* cx, T& value,
JS::MutableHandle<JS::Value> rval) {
return GetOrCreateDOMReflectorNoWrapHelper<T>::GetOrCreate(cx, value, rval);
}
template <class T>
inline JSObject* GetCallbackFromCallbackObject(JSContext* aCx, T* aObj) {
return aObj->Callback(aCx);
}
// Helper for getting the callback JSObject* of a smart ptr around a
// CallbackObject or a reference to a CallbackObject or something like
// that.
template <class T, bool isSmartPtr = IsSmartPtr<T>::value>
struct GetCallbackFromCallbackObjectHelper {
static inline JSObject* Get(JSContext* aCx, const T& aObj) {
return GetCallbackFromCallbackObject(aCx, aObj.get());
}
};
template <class T>
struct GetCallbackFromCallbackObjectHelper<T, false> {
static inline JSObject* Get(JSContext* aCx, T& aObj) {
return GetCallbackFromCallbackObject(aCx, &aObj);
}
};
template <class T>
inline JSObject* GetCallbackFromCallbackObject(JSContext* aCx, T& aObj) {
return GetCallbackFromCallbackObjectHelper<T>::Get(aCx, aObj);
}
static inline bool AtomizeAndPinJSString(JSContext* cx, jsid& id,
const char* chars) {
if (JSString* str = ::JS_AtomizeAndPinString(cx, chars)) {
id = JS::PropertyKey::fromPinnedString(str);
return true;
}
return false;
}
void GetInterfaceImpl(JSContext* aCx, nsIInterfaceRequestor* aRequestor,
nsWrapperCache* aCache, JS::Handle<JS::Value> aIID,
JS::MutableHandle<JS::Value> aRetval,
ErrorResult& aError);
template <class T>
void GetInterface(JSContext* aCx, T* aThis, JS::Handle<JS::Value> aIID,
JS::MutableHandle<JS::Value> aRetval, ErrorResult& aError) {
GetInterfaceImpl(aCx, aThis, aThis, aIID, aRetval, aError);
}
bool ThrowingConstructor(JSContext* cx, unsigned argc, JS::Value* vp);
bool ThrowConstructorWithoutNew(JSContext* cx, const char* name);
// Helper for throwing an "invalid this" exception.
bool ThrowInvalidThis(JSContext* aCx, const JS::CallArgs& aArgs,
bool aSecurityError, prototypes::ID aProtoId);
bool GetPropertyOnPrototype(JSContext* cx, JS::Handle<JSObject*> proxy,
JS::Handle<JS::Value> receiver, JS::Handle<jsid> id,
bool* found, JS::MutableHandle<JS::Value> vp);
//
bool HasPropertyOnPrototype(JSContext* cx, JS::Handle<JSObject*> proxy,
JS::Handle<jsid> id, bool* has);
// Append the property names in "names" to "props". If
// shadowPrototypeProperties is false then skip properties that are also
// present on the proto chain of proxy. If shadowPrototypeProperties is true,
// then the "proxy" argument is ignored.
bool AppendNamedPropertyIds(JSContext* cx, JS::Handle<JSObject*> proxy,
nsTArray<nsString>& names,
bool shadowPrototypeProperties,
JS::MutableHandleVector<jsid> props);
enum StringificationBehavior { eStringify, eEmpty, eNull };
static inline JSString* ConvertJSValueToJSString(JSContext* cx,
JS::Handle<JS::Value> v) {
if (MOZ_LIKELY(v.isString())) {
return v.toString();
}
return JS::ToString(cx, v);
}
template <typename T>
static inline bool ConvertJSValueToString(
JSContext* cx, JS::Handle<JS::Value> v,
StringificationBehavior nullBehavior,
StringificationBehavior undefinedBehavior, T& result) {
JSString* s;
if (v.isString()) {
s = v.toString();
} else {
StringificationBehavior behavior;
if (v.isNull()) {
behavior = nullBehavior;
} else if (v.isUndefined()) {
behavior = undefinedBehavior;
} else {
behavior = eStringify;
}
if (behavior != eStringify) {
if (behavior == eEmpty) {
result.Truncate();
} else {
result.SetIsVoid(true);
}
return true;
}
s = JS::ToString(cx, v);
if (!s) {
return false;
}
}
return AssignJSString(cx, result, s);
}
template <typename T>
static inline bool ConvertJSValueToString(
JSContext* cx, JS::Handle<JS::Value> v,
const char* /* unused sourceDescription */, T& result) {
return ConvertJSValueToString(cx, v, eStringify, eStringify, result);
}
[[nodiscard]] bool NormalizeUSVString(nsAString& aString);
[[nodiscard]] bool NormalizeUSVString(
binding_detail::FakeString<char16_t>& aString);
template <typename T>
static inline bool ConvertJSValueToUSVString(
JSContext* cx, JS::Handle<JS::Value> v,
const char* /* unused sourceDescription */, T& result) {
if (!ConvertJSValueToString(cx, v, eStringify, eStringify, result)) {
return false;
}
if (!NormalizeUSVString(result)) {
JS_ReportOutOfMemory(cx);
return false;
}
return true;
}
template <typename T>
inline bool ConvertIdToString(JSContext* cx, JS::Handle<JS::PropertyKey> id,
T& result, bool& isSymbol) {
if (MOZ_LIKELY(id.isString())) {
if (!AssignJSString(cx, result, id.toString())) {
return false;
}
} else if (id.isSymbol()) {
isSymbol = true;
return true;
} else {
JS::Rooted<JS::Value> nameVal(cx, js::IdToValue(id));
if (!ConvertJSValueToString(cx, nameVal, eStringify, eStringify, result)) {
return false;
}
}
isSymbol = false;
return true;
}
bool ConvertJSValueToByteString(BindingCallContext& cx, JS::Handle<JS::Value> v,
bool nullable, const char* sourceDescription,
nsACString& result);
inline bool ConvertJSValueToByteString(BindingCallContext& cx,
JS::Handle<JS::Value> v,
const char* sourceDescription,
nsACString& result) {
return ConvertJSValueToByteString(cx, v, false, sourceDescription, result);
}
template <typename T>
void DoTraceSequence(JSTracer* trc, FallibleTArray<T>& seq);
template <typename T>
void DoTraceSequence(JSTracer* trc, nsTArray<T>& seq);
// Class used to trace sequences, with specializations for various
// sequence types.
template <typename T, bool isDictionary = is_dom_dictionary<T>,
bool isTypedArray = is_dom_typed_array<T>,
bool isOwningUnion = is_dom_owning_union<T>>
class SequenceTracer {
explicit SequenceTracer() = delete; // Should never be instantiated
};
// sequence<object> or sequence<object?>
template <>
class SequenceTracer<JSObject*, false, false, false> {
explicit SequenceTracer() = delete; // Should never be instantiated
public:
static void TraceSequence(JSTracer* trc, JSObject** objp, JSObject** end) {
for (; objp != end; ++objp) {
JS::TraceRoot(trc, objp, "sequence<object>");
}
}
};
// sequence<any>
template <>
class SequenceTracer<JS::Value, false, false, false> {
explicit SequenceTracer() = delete; // Should never be instantiated
public:
static void TraceSequence(JSTracer* trc, JS::Value* valp, JS::Value* end) {
for (; valp != end; ++valp) {
JS::TraceRoot(trc, valp, "sequence<any>");
}
}
};
// sequence<sequence<T>>
template <typename T>
class SequenceTracer<Sequence<T>, false, false, false> {
explicit SequenceTracer() = delete; // Should never be instantiated
public:
static void TraceSequence(JSTracer* trc, Sequence<T>* seqp,
Sequence<T>* end) {
for (; seqp != end; ++seqp) {
DoTraceSequence(trc, *seqp);
}
}
};
// sequence<sequence<T>> as return value
template <typename T>
class SequenceTracer<nsTArray<T>, false, false, false> {
explicit SequenceTracer() = delete; // Should never be instantiated
public:
static void TraceSequence(JSTracer* trc, nsTArray<T>* seqp,
nsTArray<T>* end) {
for (; seqp != end; ++seqp) {
DoTraceSequence(trc, *seqp);
}
}
};
// sequence<someDictionary>
template <typename T>
class SequenceTracer<T, true, false, false> {
explicit SequenceTracer() = delete; // Should never be instantiated
public:
static void TraceSequence(JSTracer* trc, T* dictp, T* end) {
for (; dictp != end; ++dictp) {
dictp->TraceDictionary(trc);
}
}
};
// sequence<SomeTypedArray>
template <typename T>
class SequenceTracer<T, false, true, false> {
explicit SequenceTracer() = delete; // Should never be instantiated
public:
static void TraceSequence(JSTracer* trc, T* arrayp, T* end) {
for (; arrayp != end; ++arrayp) {
arrayp->TraceSelf(trc);
}
}
};
// sequence<SomeOwningUnion>
template <typename T>
class SequenceTracer<T, false, false, true> {
explicit SequenceTracer() = delete; // Should never be instantiated
public:
static void TraceSequence(JSTracer* trc, T* arrayp, T* end) {
for (; arrayp != end; ++arrayp) {
arrayp->TraceUnion(trc);
}
}
};
// sequence<T?> with T? being a Nullable<T>
template <typename T>
class SequenceTracer<Nullable<T>, false, false, false> {
explicit SequenceTracer() = delete; // Should never be instantiated
public:
static void TraceSequence(JSTracer* trc, Nullable<T>* seqp,
Nullable<T>* end) {
for (; seqp != end; ++seqp) {
if (!seqp->IsNull()) {
// Pretend like we actually have a length-one sequence here so
// we can do template instantiation correctly for T.
T& val = seqp->Value();
T* ptr = &val;
SequenceTracer<T>::TraceSequence(trc, ptr, ptr + 1);
}
}
}
};
template <typename K, typename V>
void TraceRecord(JSTracer* trc, Record<K, V>& record) {
for (auto& entry : record.Entries()) {
// Act like it's a one-element sequence to leverage all that infrastructure.
SequenceTracer<V>::TraceSequence(trc, &entry.mValue, &entry.mValue + 1);
}
}
// sequence<record>
template <typename K, typename V>
class SequenceTracer<Record<K, V>, false, false, false> {
explicit SequenceTracer() = delete; // Should never be instantiated
public:
static void TraceSequence(JSTracer* trc, Record<K, V>* seqp,
Record<K, V>* end) {
for (; seqp != end; ++seqp) {
TraceRecord(trc, *seqp);
}
}
};
template <typename T>
void DoTraceSequence(JSTracer* trc, FallibleTArray<T>& seq) {
SequenceTracer<T>::TraceSequence(trc, seq.Elements(),
seq.Elements() + seq.Length());
}
template <typename T>
void DoTraceSequence(JSTracer* trc, nsTArray<T>& seq) {
SequenceTracer<T>::TraceSequence(trc, seq.Elements(),
seq.Elements() + seq.Length());
}
// Rooter class for sequences; this is what we mostly use in the codegen
template <typename T>
class MOZ_RAII SequenceRooter final : private JS::CustomAutoRooter {
public:
template <typename CX>
SequenceRooter(const CX& cx, FallibleTArray<T>* aSequence)
: JS::CustomAutoRooter(cx),
mFallibleArray(aSequence),
mSequenceType(eFallibleArray) {}
template <typename CX>
SequenceRooter(const CX& cx, nsTArray<T>* aSequence)
: JS::CustomAutoRooter(cx),
mInfallibleArray(aSequence),
mSequenceType(eInfallibleArray) {}
template <typename CX>
SequenceRooter(const CX& cx, Nullable<nsTArray<T>>* aSequence)
: JS::CustomAutoRooter(cx),
mNullableArray(aSequence),
mSequenceType(eNullableArray) {}
private:
enum SequenceType { eInfallibleArray, eFallibleArray, eNullableArray };
virtual void trace(JSTracer* trc) override {
if (mSequenceType == eFallibleArray) {
DoTraceSequence(trc, *mFallibleArray);
} else if (mSequenceType == eInfallibleArray) {
DoTraceSequence(trc, *mInfallibleArray);
} else {
MOZ_ASSERT(mSequenceType == eNullableArray);
if (!mNullableArray->IsNull()) {
DoTraceSequence(trc, mNullableArray->Value());
}
}
}
union {
nsTArray<T>* mInfallibleArray;
FallibleTArray<T>* mFallibleArray;
Nullable<nsTArray<T>>* mNullableArray;
};
SequenceType mSequenceType;
};
// Rooter class for Record; this is what we mostly use in the codegen.
template <typename K, typename V>
class MOZ_RAII RecordRooter final : private JS::CustomAutoRooter {
public:
template <typename CX>
RecordRooter(const CX& cx, Record<K, V>* aRecord)
: JS::CustomAutoRooter(cx), mRecord(aRecord), mRecordType(eRecord) {}
template <typename CX>
RecordRooter(const CX& cx, Nullable<Record<K, V>>* aRecord)
: JS::CustomAutoRooter(cx),
mNullableRecord(aRecord),
mRecordType(eNullableRecord) {}
private:
enum RecordType { eRecord, eNullableRecord };
virtual void trace(JSTracer* trc) override {
if (mRecordType == eRecord) {
TraceRecord(trc, *mRecord);
} else {
MOZ_ASSERT(mRecordType == eNullableRecord);
if (!mNullableRecord->IsNull()) {
TraceRecord(trc, mNullableRecord->Value());
}
}
}
union {
Record<K, V>* mRecord;
Nullable<Record<K, V>>* mNullableRecord;
};
RecordType mRecordType;
};
template <typename T>
class MOZ_RAII RootedUnion : public T, private JS::CustomAutoRooter {
public:
template <typename CX>
explicit RootedUnion(const CX& cx) : T(), JS::CustomAutoRooter(cx) {}
virtual void trace(JSTracer* trc) override { this->TraceUnion(trc); }
};
template <typename T>
class MOZ_STACK_CLASS NullableRootedUnion : public Nullable<T>,
private JS::CustomAutoRooter {
public:
template <typename CX>
explicit NullableRootedUnion(const CX& cx)
: Nullable<T>(), JS::CustomAutoRooter(cx) {}
virtual void trace(JSTracer* trc) override {
if (!this->IsNull()) {
this->Value().TraceUnion(trc);
}
}
};
inline bool AddStringToIDVector(JSContext* cx,
JS::MutableHandleVector<jsid> vector,
const char* name) {
return vector.growBy(1) &&
AtomizeAndPinJSString(cx, *(vector[vector.length() - 1]).address(),
name);
}
// We use one JSNative to represent all DOM interface objects (so we can easily
// detect when we need to wrap them in an Xray wrapper). A pointer to the
// relevant DOMInterfaceInfo is stored in the
// INTERFACE_OBJECT_INFO_RESERVED_SLOT slot of the JSFunction object for a
// specific interface object. We store the real JSNative and the
// NativeProperties in a JSNativeHolder, held by the DOMInterfaceInfo.
bool InterfaceObjectJSNative(JSContext* cx, unsigned argc, JS::Value* vp);
inline bool IsInterfaceObject(JSObject* obj) {
return JS_IsNativeFunction(obj, InterfaceObjectJSNative);
}
inline const DOMInterfaceInfo* InterfaceInfoFromObject(JSObject* obj) {
MOZ_ASSERT(IsInterfaceObject(obj));
const JS::Value& v =
js::GetFunctionNativeReserved(obj, INTERFACE_OBJECT_INFO_RESERVED_SLOT);
return static_cast<const DOMInterfaceInfo*>(v.toPrivate());
}
inline const JSNativeHolder* NativeHolderFromInterfaceObject(JSObject* obj) {
MOZ_ASSERT(IsInterfaceObject(obj));
return &InterfaceInfoFromObject(obj)->nativeHolder;
}
// We use one JSNative to represent all legacy factory functions (so we can
// easily detect when we need to wrap them in an Xray wrapper). We store the
// real JSNative and the NativeProperties in a JSNativeHolder in a
// LegacyFactoryFunction in the LEGACY_FACTORY_FUNCTION_RESERVED_SLOT slot of
// the JSFunction object.
bool LegacyFactoryFunctionJSNative(JSContext* cx, unsigned argc, JS::Value* vp);
inline bool IsLegacyFactoryFunction(JSObject* obj) {
return JS_IsNativeFunction(obj, LegacyFactoryFunctionJSNative);
}
inline const LegacyFactoryFunction* LegacyFactoryFunctionFromObject(
JSObject* obj) {
MOZ_ASSERT(IsLegacyFactoryFunction(obj));
const JS::Value& v =
js::GetFunctionNativeReserved(obj, LEGACY_FACTORY_FUNCTION_RESERVED_SLOT);
return static_cast<const LegacyFactoryFunction*>(v.toPrivate());
}
inline const JSNativeHolder* NativeHolderFromLegacyFactoryFunction(
JSObject* obj) {
return &LegacyFactoryFunctionFromObject(obj)->mHolder;
}
inline const JSNativeHolder* NativeHolderFromObject(JSObject* obj) {
return IsInterfaceObject(obj) ? NativeHolderFromInterfaceObject(obj)
: NativeHolderFromLegacyFactoryFunction(obj);
}
// Implementation of the bits that XrayWrapper needs
/**
* This resolves operations, attributes and constants of the interfaces for obj.
*
* wrapper is the Xray JS object.
* obj is the target object of the Xray, a binding's instance object or a
* interface or interface prototype object.
*/
bool XrayResolveOwnProperty(
JSContext* cx, JS::Handle<JSObject*> wrapper, JS::Handle<JSObject*> obj,
JS::Handle<jsid> id,
JS::MutableHandle<mozilla::Maybe<JS::PropertyDescriptor>> desc,
bool& cacheOnHolder);
/**
* Define a property on obj through an Xray wrapper.
*
* wrapper is the Xray JS object.
* obj is the target object of the Xray, a binding's instance object or a
* interface or interface prototype object.
* id and desc are the parameters for the property to be defined.
* result is the out-parameter indicating success (read it only if
* this returns true and also sets *done to true).
* done will be set to true if a property was set as a result of this call
* or if we want to always avoid setting this property
* (i.e. indexed properties on DOM objects)
*/
bool XrayDefineProperty(JSContext* cx, JS::Handle<JSObject*> wrapper,
JS::Handle<JSObject*> obj, JS::Handle<jsid> id,
JS::Handle<JS::PropertyDescriptor> desc,
JS::ObjectOpResult& result, bool* done);
/**
* Add to props the property keys of all indexed or named properties of obj and
* operations, attributes and constants of the interfaces for obj.
*
* wrapper is the Xray JS object.
* obj is the target object of the Xray, a binding's instance object or a
* interface or interface prototype object.
* flags are JSITER_* flags.
*/
bool XrayOwnPropertyKeys(JSContext* cx, JS::Handle<JSObject*> wrapper,
JS::Handle<JSObject*> obj, unsigned flags,
JS::MutableHandleVector<jsid> props);
/**
* Returns the prototype to use for an Xray for a DOM object, wrapped in cx's
* compartment. This always returns the prototype that would be used for a DOM
* object if we ignore any changes that might have been done to the prototype
* chain by JS, the XBL code or plugins.
*
* cx should be in the Xray's compartment.
* obj is the target object of the Xray, a binding's instance object or an
* interface or interface prototype object.
*/
inline bool XrayGetNativeProto(JSContext* cx, JS::Handle<JSObject*> obj,
JS::MutableHandle<JSObject*> protop) {
JS::Rooted<JSObject*> global(cx, JS::GetNonCCWObjectGlobal(obj));
{
JSAutoRealm ar(cx, global);
const DOMJSClass* domClass = GetDOMClass(obj);
if (domClass) {
ProtoHandleGetter protoGetter = domClass->mGetProto;
if (protoGetter) {
protop.set(protoGetter(cx));
} else {
protop.set(JS::GetRealmObjectPrototype(cx));
}
} else if (JS_ObjectIsFunction(obj)) {
if (IsLegacyFactoryFunction(obj)) {
protop.set(JS::GetRealmFunctionPrototype(cx));
} else {
protop.set(InterfaceInfoFromObject(obj)->mGetParentProto(cx));
}
} else {
const JSClass* clasp = JS::GetClass(obj);
MOZ_ASSERT(IsDOMIfaceAndProtoClass(clasp));
ProtoGetter protoGetter =
DOMIfaceAndProtoJSClass::FromJSClass(clasp)->mGetParentProto;
protop.set(protoGetter(cx));
}
}
return JS_WrapObject(cx, protop);
}
/**
* Get the Xray expando class to use for the given DOM object.
*/
const JSClass* XrayGetExpandoClass(JSContext* cx, JS::Handle<JSObject*> obj);
/**
* Delete a named property, if any. Return value is false if exception thrown,
* true otherwise. The caller should not do any more work after calling this
* function, because it has no way whether a deletion was performed and hence
* opresult already has state set on it. If callers ever need to change that,
* add a "bool* found" argument and change the generated DeleteNamedProperty to
* use it instead of a local variable.
*/
bool XrayDeleteNamedProperty(JSContext* cx, JS::Handle<JSObject*> wrapper,
JS::Handle<JSObject*> obj, JS::Handle<jsid> id,
JS::ObjectOpResult& opresult);
namespace binding_detail {
// Default implementations of the NativePropertyHooks' mResolveOwnProperty and
// mEnumerateOwnProperties for WebIDL bindings implemented as proxies.
bool ResolveOwnProperty(
JSContext* cx, JS::Handle<JSObject*> wrapper, JS::Handle<JSObject*> obj,
JS::Handle<jsid> id,
JS::MutableHandle<mozilla::Maybe<JS::PropertyDescriptor>> desc);
bool EnumerateOwnProperties(JSContext* cx, JS::Handle<JSObject*> wrapper,
JS::Handle<JSObject*> obj,
JS::MutableHandleVector<jsid> props);
} // namespace binding_detail
/**
* Get the object which should be used to cache the return value of a property
* getter in the case of a [Cached] or [StoreInSlot] property. `obj` is the
* `this` value for our property getter that we're working with.
*
* This function can return null on failure to allocate the object, throwing on
* the JSContext in the process.
*
* The isXray outparam will be set to true if obj is an Xray and false
* otherwise.
*
* Note that the Slow version should only be called from
* GetCachedSlotStorageObject.
*/
JSObject* GetCachedSlotStorageObjectSlow(JSContext* cx,
JS::Handle<JSObject*> obj,
bool* isXray);
inline JSObject* GetCachedSlotStorageObject(JSContext* cx,
JS::Handle<JSObject*> obj,
bool* isXray) {
if (IsDOMObject(obj)) {
*isXray = false;
return obj;
}
return GetCachedSlotStorageObjectSlow(cx, obj, isXray);
}
extern NativePropertyHooks sEmptyNativePropertyHooks;
inline bool IsDOMConstructor(JSObject* obj) {
return IsInterfaceObject(obj) || IsLegacyFactoryFunction(obj);
}
inline bool UseDOMXray(JSObject* obj) {
const JSClass* clasp = JS::GetClass(obj);
return IsDOMClass(clasp) || IsDOMConstructor(obj) ||
IsDOMIfaceAndProtoClass(clasp);
}
// Helpers for creating a const version of a type.
template <typename T>
const T& Constify(T& arg) {
return arg;
}
// Helper for turning (Owning)NonNull<T> into T&
template <typename T>
T& NonNullHelper(T& aArg) {
return aArg;
}
template <typename T>
T& NonNullHelper(NonNull<T>& aArg) {
return aArg;
}
template <typename T>
const T& NonNullHelper(const NonNull<T>& aArg) {
return aArg;
}
template <typename T>
T& NonNullHelper(OwningNonNull<T>& aArg) {
return aArg;
}
template <typename T>
const T& NonNullHelper(const OwningNonNull<T>& aArg) {
return aArg;
}
template <typename CharT>
inline void NonNullHelper(NonNull<binding_detail::FakeString<CharT>>& aArg) {
// This overload is here to make sure that we never end up applying
// NonNullHelper to a NonNull<binding_detail::FakeString>. If we
// try to, it should fail to compile, since presumably the caller will try to
// use our nonexistent return value.
}
template <typename CharT>
inline void NonNullHelper(
const NonNull<binding_detail::FakeString<CharT>>& aArg) {
// This overload is here to make sure that we never end up applying
// NonNullHelper to a NonNull<binding_detail::FakeString>. If we
// try to, it should fail to compile, since presumably the caller will try to
// use our nonexistent return value.
}
template <typename CharT>
inline void NonNullHelper(binding_detail::FakeString<CharT>& aArg) {
// This overload is here to make sure that we never end up applying
// NonNullHelper to a FakeString before we've constified it. If we
// try to, it should fail to compile, since presumably the caller will try to
// use our nonexistent return value.
}
template <typename CharT>
MOZ_ALWAYS_INLINE const nsTSubstring<CharT>& NonNullHelper(
const binding_detail::FakeString<CharT>& aArg) {
return aArg;
}
// Given a DOM reflector aObj, give its underlying DOM object a reflector in
// whatever global that underlying DOM object now thinks it should be in. If
// this is in a different compartment from aObj, aObj will become a
// cross-compatment wrapper for the new object. Otherwise, aObj will become the
// new object (via a brain transplant). If the new global is the same as the
// old global, we just keep using the same object.
//
// On entry to this method, aCx and aObj must be same-compartment.
void UpdateReflectorGlobal(JSContext* aCx, JS::Handle<JSObject*> aObj,
ErrorResult& aError);
// Helper for lenient getters/setters to report to console. If this
// returns false, we couldn't even get a global.
bool ReportLenientThisUnwrappingFailure(JSContext* cx, JSObject* obj);
// Given a JSObject* that represents the chrome side of a JS-implemented WebIDL
// interface, get the nsIGlobalObject corresponding to the content side, if any.
// A false return means an exception was thrown.
bool GetContentGlobalForJSImplementedObject(BindingCallContext& cx,
JS::Handle<JSObject*> obj,
nsIGlobalObject** global);
void ConstructJSImplementation(const char* aContractId,
nsIGlobalObject* aGlobal,
JS::MutableHandle<JSObject*> aObject,
ErrorResult& aRv);
// XXX Avoid pulling in the whole ScriptSettings.h, however there should be a
// unique declaration of this function somewhere else.
JS::RootingContext* RootingCx();
template <typename T>
already_AddRefed<T> ConstructJSImplementation(const char* aContractId,
nsIGlobalObject* aGlobal,
ErrorResult& aRv) {
JS::RootingContext* cx = RootingCx();
JS::Rooted<JSObject*> jsImplObj(cx);
ConstructJSImplementation(aContractId, aGlobal, &jsImplObj, aRv);
if (aRv.Failed()) {
return nullptr;
}
MOZ_RELEASE_ASSERT(!js::IsWrapper(jsImplObj));
JS::Rooted<JSObject*> jsImplGlobal(cx, JS::GetNonCCWObjectGlobal(jsImplObj));
RefPtr<T> newObj = new T(jsImplObj, jsImplGlobal, aGlobal);
return newObj.forget();
}
template <typename T>
already_AddRefed<T> ConstructJSImplementation(const char* aContractId,
const GlobalObject& aGlobal,
ErrorResult& aRv) {
nsCOMPtr<nsIGlobalObject> global = do_QueryInterface(aGlobal.GetAsSupports());
if (!global) {
aRv.Throw(NS_ERROR_FAILURE);
return nullptr;
}
return ConstructJSImplementation<T>(aContractId, global, aRv);
}
/**
* Convert an nsCString to jsval, returning true on success.
* These functions are intended for ByteString implementations.
* As such, the string is not UTF-8 encoded. Any UTF8 strings passed to these
* methods will be mangled.
*/
inline bool NonVoidByteStringToJsval(JSContext* cx, const nsACString& str,
JS::MutableHandle<JS::Value> rval) {
return xpc::NonVoidLatin1StringToJsval(cx, str, rval);
}
inline bool ByteStringToJsval(JSContext* cx, const nsACString& str,
JS::MutableHandle<JS::Value> rval) {
if (str.IsVoid()) {
rval.setNull();
return true;
}
return NonVoidByteStringToJsval(cx, str, rval);
}
// Convert an utf-8 encoded nsCString to jsval, returning true on success.
//
inline bool NonVoidUTF8StringToJsval(JSContext* cx, const nsACString& str,
JS::MutableHandle<JS::Value> rval) {
return xpc::NonVoidUTF8StringToJsval(cx, str, rval);
}
inline bool UTF8StringToJsval(JSContext* cx, const nsACString& str,
JS::MutableHandle<JS::Value> rval) {
if (str.IsVoid()) {
rval.setNull();
return true;
}
return NonVoidUTF8StringToJsval(cx, str, rval);
}
template <class T, bool isISupports = std::is_base_of<nsISupports, T>::value>
struct PreserveWrapperHelper {
static void PreserveWrapper(T* aObject) {
aObject->PreserveWrapper(aObject, NS_CYCLE_COLLECTION_PARTICIPANT(T));
}
};
template <class T>
struct PreserveWrapperHelper<T, true> {
static void PreserveWrapper(T* aObject) {
aObject->PreserveWrapper(reinterpret_cast<nsISupports*>(aObject));
}
};
template <class T>
void PreserveWrapper(T* aObject) {
PreserveWrapperHelper<T>::PreserveWrapper(aObject);
}
template <class T, bool isISupports = std::is_base_of<nsISupports, T>::value>
struct CastingAssertions {
static bool ToSupportsIsCorrect(T*) { return true; }
static bool ToSupportsIsOnPrimaryInheritanceChain(T*, nsWrapperCache*) {
return true;
}
};
template <class T>
struct CastingAssertions<T, true> {
static bool ToSupportsIsCorrect(T* aObject) {
return ToSupports(aObject) == reinterpret_cast<nsISupports*>(aObject);
}
static bool ToSupportsIsOnPrimaryInheritanceChain(T* aObject,
nsWrapperCache* aCache) {
return reinterpret_cast<void*>(aObject) != aCache;
}
};
template <class T>
bool ToSupportsIsCorrect(T* aObject) {
return CastingAssertions<T>::ToSupportsIsCorrect(aObject);
}
template <class T>
bool ToSupportsIsOnPrimaryInheritanceChain(T* aObject, nsWrapperCache* aCache) {
return CastingAssertions<T>::ToSupportsIsOnPrimaryInheritanceChain(aObject,
aCache);
}
// Get the size of allocated memory to associate with a binding JSObject for a
// native object. This is supplied to the JS engine to allow it to schedule GC
// when necessary.
//
// This function supplies a default value and is overloaded for specific native
// object types.
inline size_t BindingJSObjectMallocBytes(void* aNativePtr) { return 0; }
// The BindingJSObjectCreator class is supposed to be used by a caller that
// wants to create and initialise a binding JSObject. After initialisation has
// been successfully completed it should call InitializationSucceeded().
// The BindingJSObjectCreator object will root the JSObject until
// InitializationSucceeded() is called on it. If the native object for the
// binding is refcounted it will also hold a strong reference to it, that
// reference is transferred to the JSObject (which holds the native in a slot)
// when InitializationSucceeded() is called. If the BindingJSObjectCreator
// object is destroyed and InitializationSucceeded() was never called on it then
// the JSObject's slot holding the native will be set to undefined, and for a
// refcounted native the strong reference will be released.
template <class T>
class MOZ_STACK_CLASS BindingJSObjectCreator {
public:
explicit BindingJSObjectCreator(JSContext* aCx) : mReflector(aCx) {}
~BindingJSObjectCreator() {
if (mReflector) {
JS::SetReservedSlot(mReflector, DOM_OBJECT_SLOT, JS::UndefinedValue());
}
}
void CreateProxyObject(JSContext* aCx, const JSClass* aClass,
const DOMProxyHandler* aHandler,
JS::Handle<JSObject*> aProto, bool aLazyProto,
T* aNative, JS::Handle<JS::Value> aExpandoValue,
JS::MutableHandle<JSObject*> aReflector) {
js::ProxyOptions options;
options.setClass(aClass);
options.setLazyProto(aLazyProto);
aReflector.set(
js::NewProxyObject(aCx, aHandler, aExpandoValue, aProto, options));
if (aReflector) {
js::SetProxyReservedSlot(aReflector, DOM_OBJECT_SLOT,
JS::PrivateValue(aNative));
mNative = aNative;
mReflector = aReflector;
if (size_t mallocBytes = BindingJSObjectMallocBytes(aNative)) {
JS::AddAssociatedMemory(aReflector, mallocBytes,
JS::MemoryUse::DOMBinding);
}
}
}
void CreateObject(JSContext* aCx, const JSClass* aClass,
JS::Handle<JSObject*> aProto, T* aNative,
JS::MutableHandle<JSObject*> aReflector) {
aReflector.set(
JS_NewObjectWithGivenProtoAndUseAllocSite(aCx, aClass, aProto));
if (aReflector) {
JS::SetReservedSlot(aReflector, DOM_OBJECT_SLOT,
JS::PrivateValue(aNative));
mNative = aNative;
mReflector = aReflector;
if (size_t mallocBytes = BindingJSObjectMallocBytes(aNative)) {
JS::AddAssociatedMemory(aReflector, mallocBytes,
JS::MemoryUse::DOMBinding);
}
}
}
void InitializationSucceeded() {
T* pointer;
mNative.forget(&pointer);
mReflector = nullptr;
}
private:
struct OwnedNative {
// Make sure the native objects inherit from NonRefcountedDOMObject so
// that we log their ctor and dtor.
static_assert(std::is_base_of<NonRefcountedDOMObject, T>::value,
"Non-refcounted objects with DOM bindings should inherit "
"from NonRefcountedDOMObject.");
OwnedNative& operator=(T* aNative) {
mNative = aNative;
return *this;
}
// This signature sucks, but it's the only one that will make a nsRefPtr
// just forget about its pointer without warning.
void forget(T** aResult) {
*aResult = mNative;
mNative = nullptr;
}
// Keep track of the pointer for use in InitializationSucceeded().
// The caller (or, after initialization succeeds, the JS object) retains
// ownership of the object.
T* mNative;
};
JS::Rooted<JSObject*> mReflector;
std::conditional_t<IsRefcounted<T>::value, RefPtr<T>, OwnedNative> mNative;
};
template <class T>
struct DeferredFinalizerImpl {
using SmartPtr = std::conditional_t<
std::is_same_v<T, nsISupports>, nsCOMPtr<T>,
std::conditional_t<IsRefcounted<T>::value, RefPtr<T>, UniquePtr<T>>>;
typedef SegmentedVector<SmartPtr> SmartPtrArray;
static_assert(
std::is_same_v<T, nsISupports> || !std::is_base_of<nsISupports, T>::value,
"nsISupports classes should all use the nsISupports instantiation");
static inline void AppendAndTake(
SegmentedVector<nsCOMPtr<nsISupports>>& smartPtrArray, nsISupports* ptr) {
smartPtrArray.InfallibleAppend(dont_AddRef(ptr));
}
template <class U>
static inline void AppendAndTake(SegmentedVector<RefPtr<U>>& smartPtrArray,
U* ptr) {
smartPtrArray.InfallibleAppend(dont_AddRef(ptr));
}
template <class U>
static inline void AppendAndTake(SegmentedVector<UniquePtr<U>>& smartPtrArray,
U* ptr) {
smartPtrArray.InfallibleAppend(ptr);
}
static void* AppendDeferredFinalizePointer(void* aData, void* aObject) {
SmartPtrArray* pointers = static_cast<SmartPtrArray*>(aData);
if (!pointers) {
pointers = new SmartPtrArray();
}
AppendAndTake(*pointers, static_cast<T*>(aObject));
return pointers;
}
static bool DeferredFinalize(uint32_t aSlice, void* aData) {
MOZ_ASSERT(aSlice > 0, "nonsensical/useless call with aSlice == 0");
SmartPtrArray* pointers = static_cast<SmartPtrArray*>(aData);
uint32_t oldLen = pointers->Length();
if (oldLen < aSlice) {
aSlice = oldLen;
}
uint32_t newLen = oldLen - aSlice;
pointers->PopLastN(aSlice);
if (newLen == 0) {
delete pointers;
return true;
}
return false;
}
};
template <class T, bool isISupports = std::is_base_of<nsISupports, T>::value>
struct DeferredFinalizer {
static void AddForDeferredFinalization(T* aObject) {
typedef DeferredFinalizerImpl<T> Impl;
DeferredFinalize(Impl::AppendDeferredFinalizePointer,
Impl::DeferredFinalize, aObject);
}
};
template <class T>
struct DeferredFinalizer<T, true> {
static void AddForDeferredFinalization(T* aObject) {
DeferredFinalize(reinterpret_cast<nsISupports*>(aObject));
}
};
template <class T>
static void AddForDeferredFinalization(T* aObject) {
DeferredFinalizer<T>::AddForDeferredFinalization(aObject);
}
// This returns T's CC participant if it participates in CC and does not inherit
// from nsISupports. Otherwise, it returns null. QI should be used to get the
// participant if T inherits from nsISupports.
template <class T, bool isISupports = std::is_base_of<nsISupports, T>::value>
class GetCCParticipant {
// Helper for GetCCParticipant for classes that participate in CC.
template <class U>
static constexpr nsCycleCollectionParticipant* GetHelper(
int, typename U::NS_CYCLE_COLLECTION_INNERCLASS* dummy = nullptr) {
return T::NS_CYCLE_COLLECTION_INNERCLASS::GetParticipant();
}
// Helper for GetCCParticipant for classes that don't participate in CC.
template <class U>
static constexpr nsCycleCollectionParticipant* GetHelper(double) {
return nullptr;
}
public:
static constexpr nsCycleCollectionParticipant* Get() {
// Passing int() here will try to call the GetHelper that takes an int as
// its first argument. If T doesn't participate in CC then substitution for
// the second argument (with a default value) will fail and because of
// SFINAE the next best match (the variant taking a double) will be called.
return GetHelper<T>(int());
}
};
template <class T>
class GetCCParticipant<T, true> {
public:
static constexpr nsCycleCollectionParticipant* Get() { return nullptr; }
};
void FinalizeGlobal(JS::GCContext* aGcx, JSObject* aObj);
bool ResolveGlobal(JSContext* aCx, JS::Handle<JSObject*> aObj,
JS::Handle<jsid> aId, bool* aResolvedp);
bool MayResolveGlobal(const JSAtomState& aNames, jsid aId, JSObject* aMaybeObj);
bool EnumerateGlobal(JSContext* aCx, JS::Handle<JSObject*> aObj,
JS::MutableHandleVector<jsid> aProperties,
bool aEnumerableOnly);
struct CreateGlobalOptionsGeneric {
static void TraceGlobal(JSTracer* aTrc, JSObject* aObj) {
mozilla::dom::TraceProtoAndIfaceCache(aTrc, aObj);
}
static bool PostCreateGlobal(JSContext* aCx, JS::Handle<JSObject*> aGlobal) {
MOZ_ALWAYS_TRUE(TryPreserveWrapper(aGlobal));
return true;
}
};
struct CreateGlobalOptionsWithXPConnect {
static void TraceGlobal(JSTracer* aTrc, JSObject* aObj);
static bool PostCreateGlobal(JSContext* aCx, JS::Handle<JSObject*> aGlobal);
};
template <class T>
using IsGlobalWithXPConnect =
std::integral_constant<bool,
std::is_base_of<nsGlobalWindowInner, T>::value ||
std::is_base_of<MessageManagerGlobal, T>::value>;
template <class T>
struct CreateGlobalOptions
: std::conditional_t<IsGlobalWithXPConnect<T>::value,
CreateGlobalOptionsWithXPConnect,
CreateGlobalOptionsGeneric> {
static constexpr ProtoAndIfaceCache::Kind ProtoAndIfaceCacheKind =
ProtoAndIfaceCache::NonWindowLike;
};
template <>
struct CreateGlobalOptions<nsGlobalWindowInner>
: public CreateGlobalOptionsWithXPConnect {
static constexpr ProtoAndIfaceCache::Kind ProtoAndIfaceCacheKind =
ProtoAndIfaceCache::WindowLike;
};
uint64_t GetWindowID(void* aGlobal);
uint64_t GetWindowID(nsGlobalWindowInner* aGlobal);
uint64_t GetWindowID(DedicatedWorkerGlobalScope* aGlobal);
// The return value is true if we created and successfully performed our part of
// the setup for the global, false otherwise.
//
// Typically this method's caller will want to ensure that
// xpc::InitGlobalObjectOptions is called before, and xpc::InitGlobalObject is
// called after, this method, to ensure that this global object and its
// compartment are consistent with other global objects.
template <class T, ProtoHandleGetter GetProto>
bool CreateGlobal(JSContext* aCx, T* aNative, nsWrapperCache* aCache,
const JSClass* aClass, JS::RealmOptions& aOptions,
JSPrincipals* aPrincipal,
JS::MutableHandle<JSObject*> aGlobal) {
AUTO_PROFILER_LABEL_RELEVANT_FOR_JS("Create global object", JS);
aOptions.creationOptions()
.setTrace(CreateGlobalOptions<T>::TraceGlobal)
.setProfilerRealmID(GetWindowID(aNative));
xpc::SetPrefableRealmOptions(aOptions);
aGlobal.set(JS_NewGlobalObject(aCx, aClass, aPrincipal,
JS::DontFireOnNewGlobalHook, aOptions));
if (!aGlobal) {
NS_WARNING("Failed to create global");
return false;
}
JSAutoRealm ar(aCx, aGlobal);
{
JS::SetReservedSlot(aGlobal, DOM_OBJECT_SLOT, JS::PrivateValue(aNative));
NS_ADDREF(aNative);
aCache->SetWrapper(aGlobal);
dom::AllocateProtoAndIfaceCache(
aGlobal, CreateGlobalOptions<T>::ProtoAndIfaceCacheKind);
if (!CreateGlobalOptions<T>::PostCreateGlobal(aCx, aGlobal)) {
return false;
}
// Initializing this at this point for nsGlobalWindowInner makes no sense,
// because GetRTPCallerType doesn't return the correct result before
// the global is completely initialized with a document.
if constexpr (!std::is_base_of_v<nsGlobalWindowInner, T>) {
JS::SetRealmReduceTimerPrecisionCallerType(
js::GetNonCCWObjectRealm(aGlobal),
RTPCallerTypeToToken(aNative->GetRTPCallerType()));
}
}
JS::Handle<JSObject*> proto = GetProto(aCx);
if (!proto || !JS_SetPrototype(aCx, aGlobal, proto)) {
NS_WARNING("Failed to set proto");
return false;
}
bool succeeded;
if (!JS_SetImmutablePrototype(aCx, aGlobal, &succeeded)) {
return false;
}
MOZ_ASSERT(succeeded,
"making a fresh global object's [[Prototype]] immutable can "
"internally fail, but it should never be unsuccessful");
return true;
}
namespace binding_detail {
/**
* WebIDL getters have a "generic" JSNative that is responsible for the
* following things:
*
* 1) Determining the "this" pointer for the C++ call.
* 2) Extracting the "specialized" getter from the jitinfo on the JSFunction.
* 3) Calling the specialized getter.
* 4) Handling exceptions as needed.
*
* There are several variants of (1) depending on the interface involved and
* there are two variants of (4) depending on whether the return type is a
* Promise. We handle this by templating our generic getter on a
* this-determination policy and an exception handling policy, then explicitly
* instantiating the relevant template specializations.
*/
template <typename ThisPolicy, typename ExceptionPolicy>
bool GenericGetter(JSContext* cx, unsigned argc, JS::Value* vp);
/**
* WebIDL setters have a "generic" JSNative that is responsible for the
* following things:
*
* 1) Determining the "this" pointer for the C++ call.
* 2) Extracting the "specialized" setter from the jitinfo on the JSFunction.
* 3) Calling the specialized setter.
*
* There are several variants of (1) depending on the interface
* involved. We handle this by templating our generic setter on a
* this-determination policy, then explicitly instantiating the
* relevant template specializations.
*/
template <typename ThisPolicy>
bool GenericSetter(JSContext* cx, unsigned argc, JS::Value* vp);
/**
* WebIDL methods have a "generic" JSNative that is responsible for the
* following things:
*
* 1) Determining the "this" pointer for the C++ call.
* 2) Extracting the "specialized" method from the jitinfo on the JSFunction.
* 3) Calling the specialized methodx.
* 4) Handling exceptions as needed.
*
* There are several variants of (1) depending on the interface involved and
* there are two variants of (4) depending on whether the return type is a
* Promise. We handle this by templating our generic method on a
* this-determination policy and an exception handling policy, then explicitly
* instantiating the relevant template specializations.
*/
template <typename ThisPolicy, typename ExceptionPolicy>
bool GenericMethod(JSContext* cx, unsigned argc, JS::Value* vp);
// A this-extraction policy for normal getters/setters/methods.
struct NormalThisPolicy;
// A this-extraction policy for getters/setters/methods on interfaces
// that are on some global's proto chain.
struct MaybeGlobalThisPolicy;
// A this-extraction policy for lenient getters/setters.
struct LenientThisPolicy;
// A this-extraction policy for cross-origin getters/setters/methods.
struct CrossOriginThisPolicy;
// A this-extraction policy for getters/setters/methods that should
// not be allowed to be called cross-origin but expect objects that
// _can_ be cross-origin.
struct MaybeCrossOriginObjectThisPolicy;
// A this-extraction policy which is just like
// MaybeCrossOriginObjectThisPolicy but has lenient-this behavior.
struct MaybeCrossOriginObjectLenientThisPolicy;
// An exception-reporting policy for normal getters/setters/methods.
struct ThrowExceptions;
// An exception-handling policy for Promise-returning getters/methods.
struct ConvertExceptionsToPromises;
} // namespace binding_detail
bool StaticMethodPromiseWrapper(JSContext* cx, unsigned argc, JS::Value* vp);
// ConvertExceptionToPromise should only be called when we have an error
// condition (e.g. returned false from a JSAPI method). Note that there may be
// no exception on cx, in which case this is an uncatchable failure that will
// simply be propagated. Otherwise this method will attempt to convert the
// exception to a Promise rejected with the exception that it will store in
// rval.
bool ConvertExceptionToPromise(JSContext* cx,
JS::MutableHandle<JS::Value> rval);
#ifdef DEBUG
void AssertReturnTypeMatchesJitinfo(const JSJitInfo* aJitinfo,
JS::Handle<JS::Value> aValue);
#endif
bool CallerSubsumes(JSObject* aObject);
MOZ_ALWAYS_INLINE bool CallerSubsumes(JS::Handle<JS::Value> aValue) {
if (!aValue.isObject()) {
return true;
}
return CallerSubsumes(&aValue.toObject());
}
template <class T, class S>
inline RefPtr<T> StrongOrRawPtr(already_AddRefed<S>&& aPtr) {
return std::move(aPtr);
}
template <class T, class S>
inline RefPtr<T> StrongOrRawPtr(RefPtr<S>&& aPtr) {
return std::move(aPtr);
}
template <class T, typename = std::enable_if_t<IsRefcounted<T>::value>>
inline T* StrongOrRawPtr(T* aPtr) {
return aPtr;
}
template <class T, class S,
typename = std::enable_if_t<!IsRefcounted<S>::value>>
inline UniquePtr<T> StrongOrRawPtr(UniquePtr<S>&& aPtr) {
return std::move(aPtr);
}
template <class T, template <typename> class SmartPtr, class S>
inline void StrongOrRawPtr(SmartPtr<S>&& aPtr) = delete;
template <class T>
using StrongPtrForMember =
std::conditional_t<IsRefcounted<T>::value, RefPtr<T>, UniquePtr<T>>;
namespace binding_detail {
inline JSObject* GetHackedNamespaceProtoObject(JSContext* aCx) {
return JS_NewPlainObject(aCx);
}
} // namespace binding_detail
// Resolve an id on the given global object that wants to be included in
// Exposed=System webidl annotations. False return value means exception
// thrown.
bool SystemGlobalResolve(JSContext* cx, JS::Handle<JSObject*> obj,
JS::Handle<jsid> id, bool* resolvedp);
// Enumerate all ids on the given global object that wants to be included in
// Exposed=System webidl annotations. False return value means exception
// thrown.
bool SystemGlobalEnumerate(JSContext* cx, JS::Handle<JSObject*> obj);
// Slot indexes for maplike/setlike forEach functions
#define FOREACH_CALLBACK_SLOT 0
#define FOREACH_MAPLIKEORSETLIKEOBJ_SLOT 1
// Backing function for running .forEach() on maplike/setlike interfaces.
// Unpacks callback and maplike/setlike object from reserved slots, then runs
// callback for each key (and value, for maplikes)
bool ForEachHandler(JSContext* aCx, unsigned aArgc, JS::Value* aVp);
// Unpacks backing object (ES6 map/set) from the reserved slot of a reflector
// for a maplike/setlike interface. If backing object does not exist, creates
// backing object in the compartment of the reflector involved, making this safe
// to use across compartments/via xrays. Return values of these methods will
// always be in the context compartment.
bool GetMaplikeBackingObject(JSContext* aCx, JS::Handle<JSObject*> aObj,
size_t aSlotIndex,
JS::MutableHandle<JSObject*> aBackingObj,
bool* aBackingObjCreated);
bool GetSetlikeBackingObject(JSContext* aCx, JS::Handle<JSObject*> aObj,
size_t aSlotIndex,
JS::MutableHandle<JSObject*> aBackingObj,
bool* aBackingObjCreated);
// Unpacks backing object (ES Proxy exotic object) from the reserved slot of a
// reflector for a observableArray attribute. If backing object does not exist,
// creates backing object in the compartment of the reflector involved, making
// this safe to use across compartments/via xrays. Return values of these
// methods will always be in the context compartment.
bool GetObservableArrayBackingObject(
JSContext* aCx, JS::Handle<JSObject*> aObj, size_t aSlotIndex,
JS::MutableHandle<JSObject*> aBackingObj, bool* aBackingObjCreated,
const ObservableArrayProxyHandler* aHandler, void* aOwner);
// Get the desired prototype object for an object construction from the given
// CallArgs. The CallArgs must be for a constructor call. The
// aProtoId/aCreator arguments are used to get a default if we don't find a
// prototype on the newTarget of the callargs.
bool GetDesiredProto(JSContext* aCx, const JS::CallArgs& aCallArgs,
prototypes::id::ID aProtoId,
CreateInterfaceObjectsMethod aCreator,
JS::MutableHandle<JSObject*> aDesiredProto);
// This function is expected to be called from the constructor function for an
// HTML or XUL element interface; the global/callargs need to be whatever was
// passed to that constructor function.
already_AddRefed<Element> CreateXULOrHTMLElement(
const GlobalObject& aGlobal, const JS::CallArgs& aCallArgs,
JS::Handle<JSObject*> aGivenProto, ErrorResult& aRv);
void SetUseCounter(JSObject* aObject, UseCounter aUseCounter);
void SetUseCounter(UseCounterWorker aUseCounter);
// Warnings
void DeprecationWarning(JSContext* aCx, JSObject* aObject,
DeprecatedOperations aOperation);
void DeprecationWarning(const GlobalObject& aGlobal,
DeprecatedOperations aOperation);
namespace binding_detail {
// Get a JS global object that can be used for some temporary allocations. The
// idea is that this should be used for situations when you need to operate in
// _some_ compartment but don't care which one. A typical example is when you
// have non-JS input, non-JS output, but have to go through some sort of JS
// representation in the middle, so need a compartment to allocate things in.
//
// It's VERY important that any consumers of this function only do things that
// are guaranteed to be side-effect-free, even in the face of a script
// environment controlled by a hostile adversary. This is because in the worker
// case the global is in fact the worker global, so it and its standard objects
// are controlled by the worker script. This is why this function is in the
// binding_detail namespace. Any use of this function MUST be very carefully
// reviewed by someone who is sufficiently devious and has a very good
// understanding of all the code that will run while we're using the return
// value, including the SpiderMonkey parts.
JSObject* UnprivilegedJunkScopeOrWorkerGlobal(const fallible_t&);
// Implementation of the [HTMLConstructor] extended attribute.
bool HTMLConstructor(JSContext* aCx, unsigned aArgc, JS::Value* aVp,
constructors::id::ID aConstructorId,
prototypes::id::ID aProtoId,
CreateInterfaceObjectsMethod aCreator);
// A method to test whether an attribute with the given JSJitGetterOp getter is
// enabled in the given set of prefable proeprty specs. For use for toJSON
// conversions. aObj is the object that would be used as the "this" value.
bool IsGetterEnabled(JSContext* aCx, JS::Handle<JSObject*> aObj,
JSJitGetterOp aGetter,
const Prefable<const JSPropertySpec>* aAttributes);
// A class that can be used to examine the chars of a linear string.
class StringIdChars {
public:
// Require a non-const ref to an AutoRequireNoGC to prevent callers
// from passing temporaries.
StringIdChars(JS::AutoRequireNoGC& nogc, JSLinearString* str) {
mIsLatin1 = JS::LinearStringHasLatin1Chars(str);
if (mIsLatin1) {
mLatin1Chars = JS::GetLatin1LinearStringChars(nogc, str);
} else {
mTwoByteChars = JS::GetTwoByteLinearStringChars(nogc, str);
}
#ifdef DEBUG
mLength = JS::GetLinearStringLength(str);
#endif // DEBUG
}
MOZ_ALWAYS_INLINE char16_t operator[](size_t index) {
MOZ_ASSERT(index < mLength);
if (mIsLatin1) {
return mLatin1Chars[index];
}
return mTwoByteChars[index];
}
private:
bool mIsLatin1;
union {
const JS::Latin1Char* mLatin1Chars;
const char16_t* mTwoByteChars;
};
#ifdef DEBUG
size_t mLength;
#endif // DEBUG
};
already_AddRefed<Promise> CreateRejectedPromiseFromThrownException(
JSContext* aCx, ErrorResult& aError);
template <auto ConstructorEnabled>
inline bool ShouldExpose(JSContext* aCx, JS::Handle<JSObject*> aGlobal,
DefineInterfaceProperty aDefine) {
return aDefine == DefineInterfaceProperty::Always ||
(aDefine == DefineInterfaceProperty::CheckExposure &&
ConstructorEnabled(aCx, aGlobal));
}
class ReflectedHTMLAttributeSlotsBase {
protected:
static void ForEachXrayReflectedHTMLAttributeSlots(
JS::RootingContext* aCx, JSObject* aObject, size_t aSlotIndex,
size_t aArrayIndex, void (*aFunc)(void* aSlots, size_t aArrayIndex));
static void XrayExpandoObjectFinalize(JS::GCContext* aCx, JSObject* aObject);
};
template <size_t SlotIndex, size_t XrayExpandoSlotIndex, size_t Count>
class ReflectedHTMLAttributeSlots : public Array<JS::Heap<JS::Value>, Count>,
private ReflectedHTMLAttributeSlotsBase {
public:
using Array<JS::Heap<JS::Value>, Count>::Array;
static ReflectedHTMLAttributeSlots& GetOrCreate(JSObject* aSlotStorage,
bool aIsXray) {
size_t slotIndex = aIsXray ? XrayExpandoSlotIndex : SlotIndex;
JS::Value v = JS::GetReservedSlot(aSlotStorage, slotIndex);
ReflectedHTMLAttributeSlots* array;
if (v.isUndefined()) {
array = new ReflectedHTMLAttributeSlots();
JS::SetReservedSlot(aSlotStorage, slotIndex, JS::PrivateValue(array));
} else {
array = static_cast<ReflectedHTMLAttributeSlots*>(v.toPrivate());
}
return *array;
}
static void Clear(JSObject* aObject, size_t aArrayIndex) {
JS::Value array = JS::GetReservedSlot(aObject, SlotIndex);
if (!array.isUndefined()) {
ReflectedHTMLAttributeSlots& slots =
*static_cast<ReflectedHTMLAttributeSlots*>(array.toPrivate());
slots[aArrayIndex] = JS::UndefinedValue();
}
}
static void ClearInXrays(JS::RootingContext* aCx, JSObject* aObject,
size_t aArrayIndex) {
ReflectedHTMLAttributeSlotsBase::ForEachXrayReflectedHTMLAttributeSlots(
aCx, aObject, XrayExpandoSlotIndex, aArrayIndex,
[](void* aSlots, size_t aArrayIndex) {
ReflectedHTMLAttributeSlots& slots =
*static_cast<ReflectedHTMLAttributeSlots*>(aSlots);
slots[aArrayIndex] = JS::UndefinedValue();
});
}
static void Trace(JSTracer* aTracer, JSObject* aObject) {
Trace(aTracer, aObject, SlotIndex);
}
static void Finalize(JSObject* aObject) { Finalize(aObject, SlotIndex); }
static void XrayExpandoObjectTrace(JSTracer* aTracer, JSObject* aObject) {
Trace(aTracer, aObject, XrayExpandoSlotIndex);
}
static void XrayExpandoObjectFinalize(JS::GCContext* aCx, JSObject* aObject) {
Finalize(aObject, XrayExpandoSlotIndex);
ReflectedHTMLAttributeSlotsBase::XrayExpandoObjectFinalize(aCx, aObject);
}
static constexpr JSClassOps sXrayExpandoObjectClassOps = {
nullptr, /* addProperty */
nullptr, /* delProperty */
nullptr, /* enumerate */
nullptr, /* newEnumerate */
nullptr, /* resolve */
nullptr, /* mayResolve */
XrayExpandoObjectFinalize,
nullptr, /* call */
nullptr, /* construct */
XrayExpandoObjectTrace,
};
private:
static void Trace(JSTracer* aTracer, JSObject* aObject, size_t aSlotIndex) {
JS::Value slotValue = JS::GetReservedSlot(aObject, aSlotIndex);
if (!slotValue.isUndefined()) {
auto* array =
static_cast<ReflectedHTMLAttributeSlots*>(slotValue.toPrivate());
for (JS::Heap<JS::Value>& v : *array) {
JS::TraceEdge(aTracer, &v, "ReflectedHTMLAttributeSlots[i]");
}
}
}
static void Finalize(JSObject* aObject, size_t aSlotIndex) {
JS::Value slotValue = JS::GetReservedSlot(aObject, aSlotIndex);
if (!slotValue.isUndefined()) {
delete static_cast<ReflectedHTMLAttributeSlots*>(slotValue.toPrivate());
JS::SetReservedSlot(aObject, aSlotIndex, JS::UndefinedValue());
}
}
};
void ClearXrayExpandoSlots(JS::RootingContext* aCx, JSObject* aObject,
size_t aSlotIndex);
} // namespace binding_detail
} // namespace dom
} // namespace mozilla
#endif /* mozilla_dom_BindingUtils_h__ */