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tenfourfox/js/xpconnect/src/XPCJSRuntime.cpp

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/* -*- Mode: C++; tab-width: 8; indent-tabs-mode: nil; c-basic-offset: 4 -*- */
/* vim: set ts=8 sts=4 et sw=4 tw=99: */
/* This Source Code Form is subject to the terms of the Mozilla Public
* License, v. 2.0. If a copy of the MPL was not distributed with this
* file, You can obtain one at http://mozilla.org/MPL/2.0/. */
/* Per JSRuntime object */
#include "mozilla/MemoryReporting.h"
#include "mozilla/UniquePtr.h"
#include "xpcprivate.h"
#include "xpcpublic.h"
#include "XPCWrapper.h"
#include "XPCJSMemoryReporter.h"
#include "WrapperFactory.h"
#include "mozJSComponentLoader.h"
#include "nsNetUtil.h"
#include "nsIMemoryInfoDumper.h"
#include "nsIMemoryReporter.h"
#include "nsIObserverService.h"
#include "nsIDebug2.h"
#include "nsIDocShell.h"
#include "amIAddonManager.h"
#include "nsPIDOMWindow.h"
#include "nsPrintfCString.h"
#include "mozilla/Preferences.h"
#include "mozilla/Telemetry.h"
#include "mozilla/Services.h"
#include "mozilla/dom/ScriptSettings.h"
#include "nsContentUtils.h"
#include "nsCCUncollectableMarker.h"
#include "nsCycleCollectionNoteRootCallback.h"
#include "nsCycleCollector.h"
#include "nsScriptLoader.h"
#include "jsapi.h"
#include "jsprf.h"
#include "js/MemoryMetrics.h"
#include "mozilla/dom/GeneratedAtomList.h"
#include "mozilla/dom/BindingUtils.h"
#include "mozilla/dom/Element.h"
#include "mozilla/dom/WindowBinding.h"
#include "mozilla/Atomics.h"
#include "mozilla/Attributes.h"
#include "mozilla/ProcessHangMonitor.h"
#include "AccessCheck.h"
#include "nsGlobalWindow.h"
#include "nsAboutProtocolUtils.h"
#include "GeckoProfiler.h"
#include "nsIXULRuntime.h"
#include "nsJSPrincipals.h"
#ifdef MOZ_CRASHREPORTER
#include "nsExceptionHandler.h"
#endif
#if defined(MOZ_JEMALLOC4)
#include "mozmemory.h"
#endif
#ifdef XP_WIN
#include <windows.h>
#endif
using namespace mozilla;
using namespace xpc;
using namespace JS;
using mozilla::dom::PerThreadAtomCache;
using mozilla::dom::AutoEntryScript;
/***************************************************************************/
const char* const XPCJSRuntime::mStrings[] = {
"constructor", // IDX_CONSTRUCTOR
"toString", // IDX_TO_STRING
"toSource", // IDX_TO_SOURCE
"lastResult", // IDX_LAST_RESULT
"returnCode", // IDX_RETURN_CODE
"value", // IDX_VALUE
"QueryInterface", // IDX_QUERY_INTERFACE
"Components", // IDX_COMPONENTS
"wrappedJSObject", // IDX_WRAPPED_JSOBJECT
"Object", // IDX_OBJECT
"Function", // IDX_FUNCTION
"prototype", // IDX_PROTOTYPE
"createInstance", // IDX_CREATE_INSTANCE
"item", // IDX_ITEM
"__proto__", // IDX_PROTO
"__iterator__", // IDX_ITERATOR
"__exposedProps__", // IDX_EXPOSEDPROPS
"eval", // IDX_EVAL
"controllers", // IDX_CONTROLLERS
"realFrameElement", // IDX_REALFRAMEELEMENT
"length", // IDX_LENGTH
"name", // IDX_NAME
"undefined", // IDX_UNDEFINED
"", // IDX_EMPTYSTRING
"fileName", // IDX_FILENAME
"lineNumber", // IDX_LINENUMBER
"columnNumber", // IDX_COLUMNNUMBER
"stack", // IDX_STACK
"message", // IDX_MESSAGE
"lastIndex" // IDX_LASTINDEX
};
/***************************************************************************/
static mozilla::Atomic<bool> sDiscardSystemSource(false);
bool
xpc::ShouldDiscardSystemSource() { return sDiscardSystemSource; }
#ifdef DEBUG
static mozilla::Atomic<bool> sExtraWarningsForSystemJS(false);
bool xpc::ExtraWarningsForSystemJS() { return sExtraWarningsForSystemJS; }
#else
bool xpc::ExtraWarningsForSystemJS() { return false; }
#endif
// *Some* NativeSets are referenced from mClassInfo2NativeSetMap.
// *All* NativeSets are referenced from mNativeSetMap.
// So, in mClassInfo2NativeSetMap we just clear references to the unmarked.
// In mNativeSetMap we clear the references to the unmarked *and* delete them.
bool
XPCJSRuntime::CustomContextCallback(JSContext* cx, unsigned operation)
{
if (operation == JSCONTEXT_NEW) {
if (!OnJSContextNew(cx)) {
return false;
}
} else if (operation == JSCONTEXT_DESTROY) {
delete XPCContext::GetXPCContext(cx);
}
return true;
}
class AsyncFreeSnowWhite : public nsRunnable
{
public:
NS_IMETHOD Run()
{
//TimeStamp start = TimeStamp::Now();
bool hadSnowWhiteObjects = nsCycleCollector_doDeferredDeletion();
//Telemetry::Accumulate(Telemetry::CYCLE_COLLECTOR_ASYNC_SNOW_WHITE_FREEING,
// uint32_t((TimeStamp::Now() - start).ToMilliseconds()));
if (hadSnowWhiteObjects && !mContinuation) {
mContinuation = true;
if (NS_FAILED(NS_DispatchToCurrentThread(this))) {
mActive = false;
}
} else {
#if defined(MOZ_JEMALLOC4)
if (mPurge) {
/* Jemalloc purges dirty pages regularly during free() when the
* ratio of dirty pages compared to active pages is higher than
* 1 << lg_dirty_mult. A high ratio can have an impact on
* performance, so we use the default ratio of 8, but force a
* regular purge of all remaining dirty pages, after cycle
* collection. */
Telemetry::AutoTimer<Telemetry::MEMORY_FREE_PURGED_PAGES_MS> timer;
jemalloc_free_dirty_pages();
}
#endif
mActive = false;
}
return NS_OK;
}
void Dispatch(bool aContinuation = false, bool aPurge = false)
{
if (mContinuation) {
mContinuation = aContinuation;
}
mPurge = aPurge;
if (!mActive && NS_SUCCEEDED(NS_DispatchToCurrentThread(this))) {
mActive = true;
}
}
AsyncFreeSnowWhite() : mContinuation(false), mActive(false), mPurge(false) {}
public:
bool mContinuation;
bool mActive;
bool mPurge;
};
namespace xpc {
CompartmentPrivate::CompartmentPrivate(JSCompartment* c)
: wantXrays(false)
, allowWaivers(true)
, writeToGlobalPrototype(false)
, skipWriteToGlobalPrototype(false)
, isWebExtensionContentScript(false)
, waiveInterposition(false)
, universalXPConnectEnabled(false)
, forcePermissiveCOWs(false)
, scriptability(c)
, scope(nullptr)
, mWrappedJSMap(JSObject2WrappedJSMap::newMap(XPC_JS_MAP_LENGTH))
{
MOZ_COUNT_CTOR(xpc::CompartmentPrivate);
mozilla::PodArrayZero(wrapperDenialWarnings);
}
CompartmentPrivate::~CompartmentPrivate()
{
MOZ_COUNT_DTOR(xpc::CompartmentPrivate);
mWrappedJSMap->ShutdownMarker();
delete mWrappedJSMap;
}
static bool
TryParseLocationURICandidate(const nsACString& uristr,
CompartmentPrivate::LocationHint aLocationHint,
nsIURI** aURI)
{
static NS_NAMED_LITERAL_CSTRING(kGRE, "resource://gre/");
static NS_NAMED_LITERAL_CSTRING(kToolkit, "chrome://global/");
static NS_NAMED_LITERAL_CSTRING(kBrowser, "chrome://browser/");
if (aLocationHint == CompartmentPrivate::LocationHintAddon) {
// Blacklist some known locations which are clearly not add-on related.
if (StringBeginsWith(uristr, kGRE) ||
StringBeginsWith(uristr, kToolkit) ||
StringBeginsWith(uristr, kBrowser))
return false;
// -- GROSS HACK ALERT --
// The Yandex Elements 8.10.2 extension implements its own "xb://" URL
// scheme. If we call NS_NewURI() on an "xb://..." URL, we'll end up
// calling into the extension's own JS-implemented nsIProtocolHandler
// object, which we can't allow while we're iterating over the JS heap.
// So just skip any such URL.
// -- GROSS HACK ALERT --
if (StringBeginsWith(uristr, NS_LITERAL_CSTRING("xb")))
return false;
}
nsCOMPtr<nsIURI> uri;
if (NS_FAILED(NS_NewURI(getter_AddRefs(uri), uristr)))
return false;
nsAutoCString scheme;
if (NS_FAILED(uri->GetScheme(scheme)))
return false;
// Cannot really map data: and blob:.
// Also, data: URIs are pretty memory hungry, which is kinda bad
// for memory reporter use.
if (scheme.EqualsLiteral("data") || scheme.EqualsLiteral("blob"))
return false;
uri.forget(aURI);
return true;
}
bool CompartmentPrivate::TryParseLocationURI(CompartmentPrivate::LocationHint aLocationHint,
nsIURI** aURI)
{
if (!aURI)
return false;
// Need to parse the URI.
if (location.IsEmpty())
return false;
// Handle Sandbox location strings.
// A sandbox string looks like this:
// <sandboxName> (from: <js-stack-frame-filename>:<lineno>)
// where <sandboxName> is user-provided via Cu.Sandbox()
// and <js-stack-frame-filename> and <lineno> is the stack frame location
// from where Cu.Sandbox was called.
// <js-stack-frame-filename> furthermore is "free form", often using a
// "uri -> uri -> ..." chain. The following code will and must handle this
// common case.
// It should be noted that other parts of the code may already rely on the
// "format" of these strings, such as the add-on SDK.
static const nsDependentCString from("(from: ");
static const nsDependentCString arrow(" -> ");
static const size_t fromLength = from.Length();
static const size_t arrowLength = arrow.Length();
// See: XPCComponents.cpp#AssembleSandboxMemoryReporterName
int32_t idx = location.Find(from);
if (idx < 0)
return TryParseLocationURICandidate(location, aLocationHint, aURI);
// When parsing we're looking for the right-most URI. This URI may be in
// <sandboxName>, so we try this first.
if (TryParseLocationURICandidate(Substring(location, 0, idx), aLocationHint,
aURI))
return true;
// Not in <sandboxName> so we need to inspect <js-stack-frame-filename> and
// the chain that is potentially contained within and grab the rightmost
// item that is actually a URI.
// First, hack off the :<lineno>) part as well
int32_t ridx = location.RFind(NS_LITERAL_CSTRING(":"));
nsAutoCString chain(Substring(location, idx + fromLength,
ridx - idx - fromLength));
// Loop over the "->" chain. This loop also works for non-chains, or more
// correctly chains with only one item.
for (;;) {
idx = chain.RFind(arrow);
if (idx < 0) {
// This is the last chain item. Try to parse what is left.
return TryParseLocationURICandidate(chain, aLocationHint, aURI);
}
// Try to parse current chain item
if (TryParseLocationURICandidate(Substring(chain, idx + arrowLength),
aLocationHint, aURI))
return true;
// Current chain item couldn't be parsed.
// Strip current item and continue.
chain = Substring(chain, 0, idx);
}
MOZ_CRASH("Chain parser loop does not terminate");
}
static bool
PrincipalImmuneToScriptPolicy(nsIPrincipal* aPrincipal)
{
// System principal gets a free pass.
if (nsXPConnect::SecurityManager()->IsSystemPrincipal(aPrincipal))
return true;
// nsExpandedPrincipal gets a free pass.
nsCOMPtr<nsIExpandedPrincipal> ep = do_QueryInterface(aPrincipal);
if (ep)
return true;
// Check whether our URI is an "about:" URI that allows scripts. If it is,
// we need to allow JS to run.
nsCOMPtr<nsIURI> principalURI;
aPrincipal->GetURI(getter_AddRefs(principalURI));
MOZ_ASSERT(principalURI);
bool isAbout;
nsresult rv = principalURI->SchemeIs("about", &isAbout);
if (NS_SUCCEEDED(rv) && isAbout) {
nsCOMPtr<nsIAboutModule> module;
rv = NS_GetAboutModule(principalURI, getter_AddRefs(module));
if (NS_SUCCEEDED(rv)) {
uint32_t flags;
rv = module->GetURIFlags(principalURI, &flags);
if (NS_SUCCEEDED(rv) &&
(flags & nsIAboutModule::ALLOW_SCRIPT)) {
return true;
}
}
}
return false;
}
Scriptability::Scriptability(JSCompartment* c) : mScriptBlocks(0)
, mDocShellAllowsScript(true)
, mScriptBlockedByPolicy(false)
{
nsIPrincipal* prin = nsJSPrincipals::get(JS_GetCompartmentPrincipals(c));
mImmuneToScriptPolicy = PrincipalImmuneToScriptPolicy(prin);
// If we're not immune, we should have a real principal with a codebase URI.
// Check the URI against the new-style domain policy.
if (!mImmuneToScriptPolicy) {
nsCOMPtr<nsIURI> codebase;
nsresult rv = prin->GetURI(getter_AddRefs(codebase));
bool policyAllows;
if (NS_SUCCEEDED(rv) && codebase &&
NS_SUCCEEDED(nsXPConnect::SecurityManager()->PolicyAllowsScript(codebase, &policyAllows)))
{
mScriptBlockedByPolicy = !policyAllows;
} else {
// Something went wrong - be safe and block script.
mScriptBlockedByPolicy = true;
}
}
}
bool
Scriptability::Allowed()
{
return mDocShellAllowsScript && !mScriptBlockedByPolicy &&
mScriptBlocks == 0;
}
bool
Scriptability::IsImmuneToScriptPolicy()
{
return mImmuneToScriptPolicy;
}
void
Scriptability::Block()
{
++mScriptBlocks;
}
void
Scriptability::Unblock()
{
MOZ_ASSERT(mScriptBlocks > 0);
--mScriptBlocks;
}
void
Scriptability::SetDocShellAllowsScript(bool aAllowed)
{
mDocShellAllowsScript = aAllowed || mImmuneToScriptPolicy;
}
/* static */
Scriptability&
Scriptability::Get(JSObject* aScope)
{
return CompartmentPrivate::Get(aScope)->scriptability;
}
bool
IsContentXBLScope(JSCompartment* compartment)
{
// We always eagerly create compartment privates for XBL scopes.
CompartmentPrivate* priv = CompartmentPrivate::Get(compartment);
if (!priv || !priv->scope)
return false;
return priv->scope->IsContentXBLScope();
}
bool
IsInContentXBLScope(JSObject* obj)
{
return IsContentXBLScope(js::GetObjectCompartment(obj));
}
bool
IsInAddonScope(JSObject* obj)
{
return ObjectScope(obj)->IsAddonScope();
}
bool
IsUniversalXPConnectEnabled(JSCompartment* compartment)
{
CompartmentPrivate* priv = CompartmentPrivate::Get(compartment);
if (!priv)
return false;
return priv->universalXPConnectEnabled;
}
bool
IsUniversalXPConnectEnabled(JSContext* cx)
{
JSCompartment* compartment = js::GetContextCompartment(cx);
if (!compartment)
return false;
return IsUniversalXPConnectEnabled(compartment);
}
bool
EnableUniversalXPConnect(JSContext* cx)
{
JSCompartment* compartment = js::GetContextCompartment(cx);
if (!compartment)
return true;
// Never set universalXPConnectEnabled on a chrome compartment - it confuses
// the security wrapping code.
if (AccessCheck::isChrome(compartment))
return true;
CompartmentPrivate* priv = CompartmentPrivate::Get(compartment);
if (!priv)
return true;
if (priv->universalXPConnectEnabled)
return true;
priv->universalXPConnectEnabled = true;
// Recompute all the cross-compartment wrappers leaving the newly-privileged
// compartment.
bool ok = js::RecomputeWrappers(cx, js::SingleCompartment(compartment),
js::AllCompartments());
NS_ENSURE_TRUE(ok, false);
// The Components object normally isn't defined for unprivileged web content,
// but we define it when UniversalXPConnect is enabled to support legacy
// tests.
XPCWrappedNativeScope* scope = priv->scope;
if (!scope)
return true;
scope->ForcePrivilegedComponents();
return scope->AttachComponentsObject(cx);
}
JSObject*
UnprivilegedJunkScope()
{
return XPCJSRuntime::Get()->UnprivilegedJunkScope();
}
JSObject*
PrivilegedJunkScope()
{
return XPCJSRuntime::Get()->PrivilegedJunkScope();
}
JSObject*
CompilationScope()
{
return XPCJSRuntime::Get()->CompilationScope();
}
nsGlobalWindow*
WindowOrNull(JSObject* aObj)
{
MOZ_ASSERT(aObj);
MOZ_ASSERT(!js::IsWrapper(aObj));
nsGlobalWindow* win = nullptr;
UNWRAP_OBJECT(Window, aObj, win);
return win;
}
nsGlobalWindow*
WindowGlobalOrNull(JSObject* aObj)
{
MOZ_ASSERT(aObj);
JSObject* glob = js::GetGlobalForObjectCrossCompartment(aObj);
return WindowOrNull(glob);
}
nsGlobalWindow*
AddonWindowOrNull(JSObject* aObj)
{
if (!IsInAddonScope(aObj))
return nullptr;
JSObject* global = js::GetGlobalForObjectCrossCompartment(aObj);
JSObject* proto = js::GetPrototypeNoProxy(global);
// Addons could theoretically change the prototype of the addon scope, but
// we pretty much just want to crash if that happens so that we find out
// about it and get them to change their code.
MOZ_RELEASE_ASSERT(js::IsCrossCompartmentWrapper(proto) ||
xpc::IsSandboxPrototypeProxy(proto));
JSObject* mainGlobal = js::UncheckedUnwrap(proto, /* stopAtWindowProxy = */ false);
MOZ_RELEASE_ASSERT(JS_IsGlobalObject(mainGlobal));
return WindowOrNull(mainGlobal);
}
nsGlobalWindow*
CurrentWindowOrNull(JSContext* cx)
{
JSObject* glob = JS::CurrentGlobalOrNull(cx);
return glob ? WindowOrNull(glob) : nullptr;
}
} // namespace xpc
static void
CompartmentDestroyedCallback(JSFreeOp* fop, JSCompartment* compartment)
{
// NB - This callback may be called in JS_DestroyRuntime, which happens
// after the XPCJSRuntime has been torn down.
// Get the current compartment private into an AutoPtr (which will do the
// cleanup for us), and null out the private (which may already be null).
nsAutoPtr<CompartmentPrivate> priv(CompartmentPrivate::Get(compartment));
JS_SetCompartmentPrivate(compartment, nullptr);
}
void XPCJSRuntime::TraceNativeBlackRoots(JSTracer* trc)
{
// Skip this part if XPConnect is shutting down. We get into
// bad locking problems with the thread iteration otherwise.
if (!nsXPConnect::XPConnect()->IsShuttingDown()) {
// Trace those AutoMarkingPtr lists!
if (AutoMarkingPtr* roots = Get()->mAutoRoots)
roots->TraceJSAll(trc);
}
// XPCJSObjectHolders don't participate in cycle collection, so always
// trace them here.
XPCRootSetElem* e;
for (e = mObjectHolderRoots; e; e = e->GetNextRoot())
static_cast<XPCJSObjectHolder*>(e)->TraceJS(trc);
dom::TraceBlackJS(trc, JS_GetGCParameter(Runtime(), JSGC_NUMBER),
nsXPConnect::XPConnect()->IsShuttingDown());
}
void XPCJSRuntime::TraceAdditionalNativeGrayRoots(JSTracer* trc)
{
XPCWrappedNativeScope::TraceWrappedNativesInAllScopes(trc, this);
for (XPCRootSetElem* e = mVariantRoots; e ; e = e->GetNextRoot())
static_cast<XPCTraceableVariant*>(e)->TraceJS(trc);
for (XPCRootSetElem* e = mWrappedJSRoots; e ; e = e->GetNextRoot())
static_cast<nsXPCWrappedJS*>(e)->TraceJS(trc);
}
void
XPCJSRuntime::TraverseAdditionalNativeRoots(nsCycleCollectionNoteRootCallback& cb)
{
XPCWrappedNativeScope::SuspectAllWrappers(this, cb);
for (XPCRootSetElem* e = mVariantRoots; e ; e = e->GetNextRoot()) {
XPCTraceableVariant* v = static_cast<XPCTraceableVariant*>(e);
if (nsCCUncollectableMarker::InGeneration(cb,
v->CCGeneration())) {
JS::Value val = v->GetJSValPreserveColor();
if (val.isObject() && !JS::ObjectIsMarkedGray(&val.toObject()))
continue;
}
cb.NoteXPCOMRoot(v);
}
for (XPCRootSetElem* e = mWrappedJSRoots; e ; e = e->GetNextRoot()) {
cb.NoteXPCOMRoot(ToSupports(static_cast<nsXPCWrappedJS*>(e)));
}
}
void
XPCJSRuntime::UnmarkSkippableJSHolders()
{
CycleCollectedJSRuntime::UnmarkSkippableJSHolders();
}
void
XPCJSRuntime::PrepareForForgetSkippable()
{
nsCOMPtr<nsIObserverService> obs = mozilla::services::GetObserverService();
if (obs) {
obs->NotifyObservers(nullptr, "cycle-collector-forget-skippable", nullptr);
}
}
void
XPCJSRuntime::BeginCycleCollectionCallback()
{
nsJSContext::BeginCycleCollectionCallback();
nsCOMPtr<nsIObserverService> obs = mozilla::services::GetObserverService();
if (obs) {
obs->NotifyObservers(nullptr, "cycle-collector-begin", nullptr);
}
}
void
XPCJSRuntime::EndCycleCollectionCallback(CycleCollectorResults& aResults)
{
nsJSContext::EndCycleCollectionCallback(aResults);
nsCOMPtr<nsIObserverService> obs = mozilla::services::GetObserverService();
if (obs) {
obs->NotifyObservers(nullptr, "cycle-collector-end", nullptr);
}
}
void
XPCJSRuntime::DispatchDeferredDeletion(bool aContinuation, bool aPurge)
{
mAsyncSnowWhiteFreer->Dispatch(aContinuation, aPurge);
}
void
xpc_UnmarkSkippableJSHolders()
{
if (nsXPConnect::XPConnect()->GetRuntime()) {
nsXPConnect::XPConnect()->GetRuntime()->UnmarkSkippableJSHolders();
}
}
/* static */ void
XPCJSRuntime::GCSliceCallback(JSRuntime* rt,
JS::GCProgress progress,
const JS::GCDescription& desc)
{
XPCJSRuntime* self = nsXPConnect::GetRuntimeInstance();
if (!self)
return;
#ifdef MOZ_CRASHREPORTER
CrashReporter::SetGarbageCollecting(progress == JS::GC_CYCLE_BEGIN ||
progress == JS::GC_SLICE_BEGIN);
#endif
if (self->mPrevGCSliceCallback)
(*self->mPrevGCSliceCallback)(rt, progress, desc);
}
void
XPCJSRuntime::CustomGCCallback(JSGCStatus status)
{
nsTArray<xpcGCCallback> callbacks(extraGCCallbacks);
for (uint32_t i = 0; i < callbacks.Length(); ++i)
callbacks[i](status);
}
/* static */ void
XPCJSRuntime::FinalizeCallback(JSFreeOp* fop,
JSFinalizeStatus status,
bool isCompartmentGC,
void* data)
{
XPCJSRuntime* self = nsXPConnect::GetRuntimeInstance();
if (!self)
return;
switch (status) {
case JSFINALIZE_GROUP_START:
{
MOZ_ASSERT(!self->mDoingFinalization, "bad state");
MOZ_ASSERT(!self->mGCIsRunning, "bad state");
self->mGCIsRunning = true;
self->mDoingFinalization = true;
break;
}
case JSFINALIZE_GROUP_END:
{
MOZ_ASSERT(self->mDoingFinalization, "bad state");
self->mDoingFinalization = false;
// Sweep scopes needing cleanup
XPCWrappedNativeScope::KillDyingScopes();
MOZ_ASSERT(self->mGCIsRunning, "bad state");
self->mGCIsRunning = false;
break;
}
case JSFINALIZE_COLLECTION_END:
{
MOZ_ASSERT(!self->mGCIsRunning, "bad state");
self->mGCIsRunning = true;
// We use this occasion to mark and sweep NativeInterfaces,
// NativeSets, and the WrappedNativeJSClasses...
// Do the marking...
XPCWrappedNativeScope::MarkAllWrappedNativesAndProtos();
for (auto i = self->mDetachedWrappedNativeProtoMap->Iter(); !i.Done(); i.Next()) {
auto entry = static_cast<XPCWrappedNativeProtoMap::Entry*>(i.Get());
static_cast<const XPCWrappedNativeProto*>(entry->key)->Mark();
}
// Mark the sets used in the call contexts. There is a small
// chance that a wrapper's set will change *while* a call is
// happening which uses that wrapper's old interfface set. So,
// we need to do this marking to avoid collecting those sets
// that might no longer be otherwise reachable from the wrappers
// or the wrapperprotos.
// Skip this part if XPConnect is shutting down. We get into
// bad locking problems with the thread iteration otherwise.
if (!nsXPConnect::XPConnect()->IsShuttingDown()) {
// Mark those AutoMarkingPtr lists!
if (AutoMarkingPtr* roots = Get()->mAutoRoots)
roots->MarkAfterJSFinalizeAll();
XPCCallContext* ccxp = XPCJSRuntime::Get()->GetCallContext();
while (ccxp) {
// Deal with the strictness of callcontext that
// complains if you ask for a set when
// it is in a state where the set could not
// possibly be valid.
if (ccxp->CanGetSet()) {
XPCNativeSet* set = ccxp->GetSet();
if (set)
set->Mark();
}
if (ccxp->CanGetInterface()) {
XPCNativeInterface* iface = ccxp->GetInterface();
if (iface)
iface->Mark();
}
ccxp = ccxp->GetPrevCallContext();
}
}
// Do the sweeping. During a compartment GC, only
// WrappedNativeProtos in collected compartments will be
// marked. Therefore, some reachable NativeInterfaces will not be
// marked, so it is not safe to sweep them. We still need to unmark
// them, since the ones pointed to by WrappedNativeProtos in a
// compartment being collected will be marked.
//
// Ideally, if NativeInterfaces from different compartments were
// kept separate, we could sweep only the ones belonging to
// compartments being collected. Currently, though, NativeInterfaces
// are shared between compartments. This ought to be fixed.
bool doSweep = !isCompartmentGC;
// We don't want to sweep the JSClasses at shutdown time.
// At this point there may be JSObjects using them that have
// been removed from the other maps.
if (!nsXPConnect::XPConnect()->IsShuttingDown()) {
for (auto i = self->mNativeScriptableSharedMap->Iter(); !i.Done(); i.Next()) {
auto entry = static_cast<XPCNativeScriptableSharedMap::Entry*>(i.Get());
XPCNativeScriptableShared* shared = entry->key;
if (shared->IsMarked()) {
shared->Unmark();
} else if (doSweep) {
delete shared;
i.Remove();
}
}
}
if (!isCompartmentGC) {
for (auto i = self->mClassInfo2NativeSetMap->Iter(); !i.Done(); i.Next()) {
auto entry = static_cast<ClassInfo2NativeSetMap::Entry*>(i.Get());
if (!entry->value->IsMarked())
i.Remove();
}
}
for (auto i = self->mNativeSetMap->Iter(); !i.Done(); i.Next()) {
auto entry = static_cast<NativeSetMap::Entry*>(i.Get());
XPCNativeSet* set = entry->key_value;
if (set->IsMarked()) {
set->Unmark();
} else if (doSweep) {
XPCNativeSet::DestroyInstance(set);
i.Remove();
}
}
for (auto i = self->mIID2NativeInterfaceMap->Iter(); !i.Done(); i.Next()) {
auto entry = static_cast<IID2NativeInterfaceMap::Entry*>(i.Get());
XPCNativeInterface* iface = entry->value;
if (iface->IsMarked()) {
iface->Unmark();
} else if (doSweep) {
XPCNativeInterface::DestroyInstance(iface);
i.Remove();
}
}
#ifdef DEBUG
XPCWrappedNativeScope::ASSERT_NoInterfaceSetsAreMarked();
#endif
// Now we are going to recycle any unused WrappedNativeTearoffs.
// We do this by iterating all the live callcontexts
// and marking the tearoffs in use. And then we
// iterate over all the WrappedNative wrappers and sweep their
// tearoffs.
//
// This allows us to perhaps minimize the growth of the
// tearoffs. And also makes us not hold references to interfaces
// on our wrapped natives that we are not actually using.
//
// XXX We may decide to not do this on *every* gc cycle.
// Skip this part if XPConnect is shutting down. We get into
// bad locking problems with the thread iteration otherwise.
if (!nsXPConnect::XPConnect()->IsShuttingDown()) {
// Do the marking...
XPCCallContext* ccxp = XPCJSRuntime::Get()->GetCallContext();
while (ccxp) {
// Deal with the strictness of callcontext that
// complains if you ask for a tearoff when
// it is in a state where the tearoff could not
// possibly be valid.
if (ccxp->CanGetTearOff()) {
XPCWrappedNativeTearOff* to =
ccxp->GetTearOff();
if (to)
to->Mark();
}
ccxp = ccxp->GetPrevCallContext();
}
// Do the sweeping...
XPCWrappedNativeScope::SweepAllWrappedNativeTearOffs();
}
// Now we need to kill the 'Dying' XPCWrappedNativeProtos.
// We transfered these native objects to this table when their
// JSObject's were finalized. We did not destroy them immediately
// at that point because the ordering of JS finalization is not
// deterministic and we did not yet know if any wrappers that
// might still be referencing the protos where still yet to be
// finalized and destroyed. We *do* know that the protos'
// JSObjects would not have been finalized if there were any
// wrappers that referenced the proto but where not themselves
// slated for finalization in this gc cycle. So... at this point
// we know that any and all wrappers that might have been
// referencing the protos in the dying list are themselves dead.
// So, we can safely delete all the protos in the list.
for (auto i = self->mDyingWrappedNativeProtoMap->Iter(); !i.Done(); i.Next()) {
auto entry = static_cast<XPCWrappedNativeProtoMap::Entry*>(i.Get());
delete static_cast<const XPCWrappedNativeProto*>(entry->key);
i.Remove();
}
MOZ_ASSERT(self->mGCIsRunning, "bad state");
self->mGCIsRunning = false;
break;
}
}
}
/* static */ void
XPCJSRuntime::WeakPointerZoneGroupCallback(JSRuntime* rt, void* data)
{
// Called before each sweeping slice -- after processing any final marking
// triggered by barriers -- to clear out any references to things that are
// about to be finalized and update any pointers to moved GC things.
XPCJSRuntime* self = static_cast<XPCJSRuntime*>(data);
self->mWrappedJSMap->UpdateWeakPointersAfterGC(self);
XPCWrappedNativeScope::UpdateWeakPointersAfterGC(self);
}
/* static */ void
XPCJSRuntime::WeakPointerCompartmentCallback(JSRuntime* rt, JSCompartment* comp, void* data)
{
// Called immediately after the ZoneGroup weak pointer callback, but only
// once for each compartment that is being swept.
XPCJSRuntime* self = static_cast<XPCJSRuntime*>(data);
CompartmentPrivate* xpcComp = CompartmentPrivate::Get(comp);
if (xpcComp)
xpcComp->UpdateWeakPointersAfterGC(self);
}
void
CompartmentPrivate::UpdateWeakPointersAfterGC(XPCJSRuntime* runtime)
{
mWrappedJSMap->UpdateWeakPointersAfterGC(runtime);
}
static void WatchdogMain(void* arg);
class Watchdog;
class WatchdogManager;
class AutoLockWatchdog {
Watchdog* const mWatchdog;
public:
explicit AutoLockWatchdog(Watchdog* aWatchdog);
~AutoLockWatchdog();
};
class Watchdog
{
public:
explicit Watchdog(WatchdogManager* aManager)
: mManager(aManager)
, mLock(nullptr)
, mWakeup(nullptr)
, mThread(nullptr)
, mHibernating(false)
, mInitialized(false)
, mShuttingDown(false)
, mMinScriptRunTimeSeconds(1)
{}
~Watchdog() { MOZ_ASSERT(!Initialized()); }
WatchdogManager* Manager() { return mManager; }
bool Initialized() { return mInitialized; }
bool ShuttingDown() { return mShuttingDown; }
PRLock* GetLock() { return mLock; }
bool Hibernating() { return mHibernating; }
void WakeUp()
{
MOZ_ASSERT(Initialized());
MOZ_ASSERT(Hibernating());
mHibernating = false;
PR_NotifyCondVar(mWakeup);
}
//
// Invoked by the main thread only.
//
void Init()
{
MOZ_ASSERT(NS_IsMainThread());
mLock = PR_NewLock();
if (!mLock)
NS_RUNTIMEABORT("PR_NewLock failed.");
mWakeup = PR_NewCondVar(mLock);
if (!mWakeup)
NS_RUNTIMEABORT("PR_NewCondVar failed.");
{
AutoLockWatchdog lock(this);
mThread = PR_CreateThread(PR_USER_THREAD, WatchdogMain, this,
PR_PRIORITY_NORMAL, PR_GLOBAL_THREAD,
PR_UNJOINABLE_THREAD, 0);
if (!mThread)
NS_RUNTIMEABORT("PR_CreateThread failed!");
// WatchdogMain acquires the lock and then asserts mInitialized. So
// make sure to set mInitialized before releasing the lock here so
// that it's atomic with the creation of the thread.
mInitialized = true;
}
}
void Shutdown()
{
MOZ_ASSERT(NS_IsMainThread());
MOZ_ASSERT(Initialized());
{ // Scoped lock.
AutoLockWatchdog lock(this);
// Signal to the watchdog thread that it's time to shut down.
mShuttingDown = true;
// Wake up the watchdog, and wait for it to call us back.
PR_NotifyCondVar(mWakeup);
PR_WaitCondVar(mWakeup, PR_INTERVAL_NO_TIMEOUT);
MOZ_ASSERT(!mShuttingDown);
}
// Destroy state.
mThread = nullptr;
PR_DestroyCondVar(mWakeup);
mWakeup = nullptr;
PR_DestroyLock(mLock);
mLock = nullptr;
// All done.
mInitialized = false;
}
void SetMinScriptRunTimeSeconds(int32_t seconds)
{
// This variable is atomic, and is set from the main thread without
// locking.
MOZ_ASSERT(seconds > 0);
mMinScriptRunTimeSeconds = seconds;
}
//
// Invoked by the watchdog thread only.
//
void Hibernate()
{
MOZ_ASSERT(!NS_IsMainThread());
mHibernating = true;
Sleep(PR_INTERVAL_NO_TIMEOUT);
}
void Sleep(PRIntervalTime timeout)
{
MOZ_ASSERT(!NS_IsMainThread());
MOZ_ALWAYS_TRUE(PR_WaitCondVar(mWakeup, timeout) == PR_SUCCESS);
}
void Finished()
{
MOZ_ASSERT(!NS_IsMainThread());
mShuttingDown = false;
PR_NotifyCondVar(mWakeup);
}
int32_t MinScriptRunTimeSeconds()
{
return mMinScriptRunTimeSeconds;
}
private:
WatchdogManager* mManager;
PRLock* mLock;
PRCondVar* mWakeup;
PRThread* mThread;
bool mHibernating;
bool mInitialized;
bool mShuttingDown;
mozilla::Atomic<int32_t> mMinScriptRunTimeSeconds;
};
#ifdef MOZ_NUWA_PROCESS
#include "ipc/Nuwa.h"
#endif
#define PREF_MAX_SCRIPT_RUN_TIME_CHILD "dom.max_child_script_run_time"
#define PREF_MAX_SCRIPT_RUN_TIME_CONTENT "dom.max_script_run_time"
#define PREF_MAX_SCRIPT_RUN_TIME_CHROME "dom.max_chrome_script_run_time"
class WatchdogManager : public nsIObserver
{
public:
NS_DECL_ISUPPORTS
explicit WatchdogManager(XPCJSRuntime* aRuntime) : mRuntime(aRuntime)
, mRuntimeState(RUNTIME_INACTIVE)
{
// All the timestamps start at zero except for runtime state change.
PodArrayZero(mTimestamps);
mTimestamps[TimestampRuntimeStateChange] = PR_Now();
// Enable the watchdog, if appropriate.
RefreshWatchdog();
// Register ourselves as an observer to get updates on the pref.
mozilla::Preferences::AddStrongObserver(this, "dom.use_watchdog");
mozilla::Preferences::AddStrongObserver(this, PREF_MAX_SCRIPT_RUN_TIME_CONTENT);
mozilla::Preferences::AddStrongObserver(this, PREF_MAX_SCRIPT_RUN_TIME_CHROME);
mozilla::Preferences::AddStrongObserver(this, PREF_MAX_SCRIPT_RUN_TIME_CHILD);
}
protected:
virtual ~WatchdogManager()
{
// Shutting down the watchdog requires context-switching to the watchdog
// thread, which isn't great to do in a destructor. So we require
// consumers to shut it down manually before releasing it.
MOZ_ASSERT(!mWatchdog);
mozilla::Preferences::RemoveObserver(this, "dom.use_watchdog");
mozilla::Preferences::RemoveObserver(this, PREF_MAX_SCRIPT_RUN_TIME_CONTENT);
mozilla::Preferences::RemoveObserver(this, PREF_MAX_SCRIPT_RUN_TIME_CHROME);
mozilla::Preferences::RemoveObserver(this, PREF_MAX_SCRIPT_RUN_TIME_CHILD);
}
public:
NS_IMETHOD Observe(nsISupports* aSubject, const char* aTopic,
const char16_t* aData) override
{
RefreshWatchdog();
return NS_OK;
}
// Runtime statistics. These live on the watchdog manager, are written
// from the main thread, and are read from the watchdog thread (holding
// the lock in each case).
void
RecordRuntimeActivity(bool active)
{
// The watchdog reads this state, so acquire the lock before writing it.
MOZ_ASSERT(NS_IsMainThread());
Maybe<AutoLockWatchdog> lock;
if (mWatchdog)
lock.emplace(mWatchdog);
// Write state.
mTimestamps[TimestampRuntimeStateChange] = PR_Now();
mRuntimeState = active ? RUNTIME_ACTIVE : RUNTIME_INACTIVE;
// The watchdog may be hibernating, waiting for the runtime to go
// active. Wake it up if necessary.
if (active && mWatchdog && mWatchdog->Hibernating())
mWatchdog->WakeUp();
}
bool IsRuntimeActive() { return mRuntimeState == RUNTIME_ACTIVE; }
PRTime TimeSinceLastRuntimeStateChange()
{
return PR_Now() - GetTimestamp(TimestampRuntimeStateChange);
}
// Note - Because of the runtime activity timestamp, these are read and
// written from both threads.
void RecordTimestamp(WatchdogTimestampCategory aCategory)
{
// The watchdog thread always holds the lock when it runs.
Maybe<AutoLockWatchdog> maybeLock;
if (NS_IsMainThread() && mWatchdog)
maybeLock.emplace(mWatchdog);
mTimestamps[aCategory] = PR_Now();
}
PRTime GetTimestamp(WatchdogTimestampCategory aCategory)
{
// The watchdog thread always holds the lock when it runs.
Maybe<AutoLockWatchdog> maybeLock;
if (NS_IsMainThread() && mWatchdog)
maybeLock.emplace(mWatchdog);
return mTimestamps[aCategory];
}
XPCJSRuntime* Runtime() { return mRuntime; }
Watchdog* GetWatchdog() { return mWatchdog; }
void RefreshWatchdog()
{
bool wantWatchdog = Preferences::GetBool("dom.use_watchdog", true);
if (wantWatchdog != !!mWatchdog) {
if (wantWatchdog)
StartWatchdog();
else
StopWatchdog();
}
if (mWatchdog) {
int32_t contentTime = Preferences::GetInt(PREF_MAX_SCRIPT_RUN_TIME_CONTENT, 10);
if (contentTime <= 0)
contentTime = INT32_MAX;
int32_t chromeTime = Preferences::GetInt(PREF_MAX_SCRIPT_RUN_TIME_CHROME, 20);
if (chromeTime <= 0)
chromeTime = INT32_MAX;
int32_t childTime = Preferences::GetInt(PREF_MAX_SCRIPT_RUN_TIME_CHILD, 3);
if (childTime <= 0)
childTime = INT32_MAX;
mWatchdog->SetMinScriptRunTimeSeconds(std::min(std::min(contentTime, chromeTime), childTime));
}
}
void StartWatchdog()
{
MOZ_ASSERT(!mWatchdog);
mWatchdog = new Watchdog(this);
mWatchdog->Init();
}
void StopWatchdog()
{
MOZ_ASSERT(mWatchdog);
mWatchdog->Shutdown();
mWatchdog = nullptr;
}
private:
XPCJSRuntime* mRuntime;
nsAutoPtr<Watchdog> mWatchdog;
enum { RUNTIME_ACTIVE, RUNTIME_INACTIVE } mRuntimeState;
PRTime mTimestamps[TimestampCount];
};
NS_IMPL_ISUPPORTS(WatchdogManager, nsIObserver)
AutoLockWatchdog::AutoLockWatchdog(Watchdog* aWatchdog) : mWatchdog(aWatchdog)
{
PR_Lock(mWatchdog->GetLock());
}
AutoLockWatchdog::~AutoLockWatchdog()
{
PR_Unlock(mWatchdog->GetLock());
}
static void
WatchdogMain(void* arg)
{
PR_SetCurrentThreadName("JS Watchdog");
#ifdef MOZ_NUWA_PROCESS
if (IsNuwaProcess()) {
NuwaMarkCurrentThread(nullptr, nullptr);
NuwaFreezeCurrentThread();
}
#endif
Watchdog* self = static_cast<Watchdog*>(arg);
WatchdogManager* manager = self->Manager();
// Lock lasts until we return
AutoLockWatchdog lock(self);
MOZ_ASSERT(self->Initialized());
MOZ_ASSERT(!self->ShuttingDown());
while (!self->ShuttingDown()) {
// Sleep only 1 second if recently (or currently) active; otherwise, hibernate
if (manager->IsRuntimeActive() ||
manager->TimeSinceLastRuntimeStateChange() <= PRTime(2*PR_USEC_PER_SEC))
{
self->Sleep(PR_TicksPerSecond());
} else {
manager->RecordTimestamp(TimestampWatchdogHibernateStart);
self->Hibernate();
manager->RecordTimestamp(TimestampWatchdogHibernateStop);
}
// Rise and shine.
manager->RecordTimestamp(TimestampWatchdogWakeup);
// Don't request an interrupt callback unless the current script has
// been running long enough that we might show the slow script dialog.
// Triggering the callback from off the main thread can be expensive.
// We want to avoid showing the slow script dialog if the user's laptop
// goes to sleep in the middle of running a script. To ensure this, we
// invoke the interrupt callback after only half the timeout has
// elapsed. The callback simply records the fact that it was called in
// the mSlowScriptSecondHalf flag. Then we wait another (timeout/2)
// seconds and invoke the callback again. This time around it sees
// mSlowScriptSecondHalf is set and so it shows the slow script
// dialog. If the computer is put to sleep during one of the (timeout/2)
// periods, the script still has the other (timeout/2) seconds to
// finish.
PRTime usecs = self->MinScriptRunTimeSeconds() * PR_USEC_PER_SEC / 2;
if (manager->IsRuntimeActive() &&
manager->TimeSinceLastRuntimeStateChange() >= usecs)
{
bool debuggerAttached = false;
nsCOMPtr<nsIDebug2> dbg = do_GetService("@mozilla.org/xpcom/debug;1");
if (dbg)
dbg->GetIsDebuggerAttached(&debuggerAttached);
if (!debuggerAttached)
JS_RequestInterruptCallback(manager->Runtime()->Runtime());
}
}
// Tell the manager that we've shut down.
self->Finished();
}
PRTime
XPCJSRuntime::GetWatchdogTimestamp(WatchdogTimestampCategory aCategory)
{
return mWatchdogManager->GetTimestamp(aCategory);
}
void
xpc::SimulateActivityCallback(bool aActive)
{
XPCJSRuntime::ActivityCallback(XPCJSRuntime::Get(), aActive);
}
void
XPCJSRuntime::EnvironmentPreparer::invoke(HandleObject scope, js::ScriptEnvironmentPreparer::Closure& closure)
{
MOZ_ASSERT(NS_IsMainThread());
nsIGlobalObject* global = NativeGlobal(scope);
// Not much we can do if we simply don't have a usable global here...
NS_ENSURE_TRUE_VOID(global && global->GetGlobalJSObject());
AutoEntryScript aes(global, "JS-engine-initiated execution");
aes.TakeOwnershipOfErrorReporting();
MOZ_ASSERT(!JS_IsExceptionPending(aes.cx()));
DebugOnly<bool> ok = closure(aes.cx());
MOZ_ASSERT_IF(ok, !JS_IsExceptionPending(aes.cx()));
// The AutoEntryScript will check for JS_IsExceptionPending on the
// JSContext and report it as needed as it comes off the stack.
}
// static
void
XPCJSRuntime::ActivityCallback(void* arg, bool active)
{
if (!active) {
ProcessHangMonitor::ClearHang();
}
XPCJSRuntime* self = static_cast<XPCJSRuntime*>(arg);
self->mWatchdogManager->RecordRuntimeActivity(active);
}
// static
bool
XPCJSRuntime::InterruptCallback(JSContext* cx)
{
XPCJSRuntime* self = XPCJSRuntime::Get();
// Normally we record mSlowScriptCheckpoint when we start to process an
// event. However, we can run JS outside of event handlers. This code takes
// care of that case.
if (self->mSlowScriptCheckpoint.IsNull()) {
self->mSlowScriptCheckpoint = TimeStamp::NowLoRes();
self->mSlowScriptSecondHalf = false;
return true;
}
// Sometimes we get called back during XPConnect initialization, before Gecko
// has finished bootstrapping. Avoid crashing in nsContentUtils below.
if (!nsContentUtils::IsInitialized())
return true;
bool contentProcess = XRE_IsContentProcess();
// This is at least the second interrupt callback we've received since
// returning to the event loop. See how long it's been, and what the limit
// is.
TimeDuration duration = TimeStamp::NowLoRes() - self->mSlowScriptCheckpoint;
bool chrome = nsContentUtils::IsCallerChrome();
const char* prefName = contentProcess ? PREF_MAX_SCRIPT_RUN_TIME_CHILD
: chrome ? PREF_MAX_SCRIPT_RUN_TIME_CHROME
: PREF_MAX_SCRIPT_RUN_TIME_CONTENT;
int32_t limit = Preferences::GetInt(prefName, chrome ? 20 : 10);
// If there's no limit, or we're within the limit, let it go.
if (limit == 0 || duration.ToSeconds() < limit / 2.0)
return true;
// In order to guard against time changes or laptops going to sleep, we
// don't trigger the slow script warning until (limit/2) seconds have
// elapsed twice.
if (!self->mSlowScriptSecondHalf) {
self->mSlowScriptCheckpoint = TimeStamp::NowLoRes();
self->mSlowScriptSecondHalf = true;
return true;
}
//
// This has gone on long enough! Time to take action. ;-)
//
// Get the DOM window associated with the running script. If the script is
// running in a non-DOM scope, we have to just let it keep running.
RootedObject global(cx, JS::CurrentGlobalOrNull(cx));
RefPtr<nsGlobalWindow> win = WindowOrNull(global);
if (!win && IsSandbox(global)) {
// If this is a sandbox associated with a DOMWindow via a
// sandboxPrototype, use that DOMWindow. This supports GreaseMonkey
// and JetPack content scripts.
JS::Rooted<JSObject*> proto(cx);
if (!JS_GetPrototype(cx, global, &proto))
return false;
if (proto && IsSandboxPrototypeProxy(proto) &&
(proto = js::CheckedUnwrap(proto, /* stopAtWindowProxy = */ false)))
{
win = WindowGlobalOrNull(proto);
}
}
if (!win) {
NS_WARNING("No active window");
return true;
}
MOZ_ASSERT(!win->IsDying());
if (win->GetIsPrerendered()) {
// We cannot display a dialog if the page is being prerendered, so
// just kill the page.
mozilla::dom::HandlePrerenderingViolation(win);
return false;
}
// Show the prompt to the user, and kill if requested.
nsGlobalWindow::SlowScriptResponse response = win->ShowSlowScriptDialog();
if (response == nsGlobalWindow::KillSlowScript)
return false;
// The user chose to continue the script. Reset the timer, and disable this
// machinery with a pref of the user opted out of future slow-script dialogs.
if (response != nsGlobalWindow::ContinueSlowScriptAndKeepNotifying)
self->mSlowScriptCheckpoint = TimeStamp::NowLoRes();
if (response == nsGlobalWindow::AlwaysContinueSlowScript)
Preferences::SetInt(prefName, 0);
return true;
}
void
XPCJSRuntime::CustomOutOfMemoryCallback()
{
if (!Preferences::GetBool("memory.dump_reports_on_oom")) {
return;
}
nsCOMPtr<nsIMemoryInfoDumper> dumper =
do_GetService("@mozilla.org/memory-info-dumper;1");
if (!dumper) {
return;
}
// If this fails, it fails silently.
dumper->DumpMemoryInfoToTempDir(NS_LITERAL_STRING("due-to-JS-OOM"),
/* anonymize = */ false,
/* minimizeMemoryUsage = */ false);
}
void
XPCJSRuntime::CustomLargeAllocationFailureCallback()
{
nsCOMPtr<nsIObserverService> os = mozilla::services::GetObserverService();
if (os) {
os->NotifyObservers(nullptr, "memory-pressure", MOZ_UTF16("heap-minimize"));
}
}
size_t
XPCJSRuntime::SizeOfIncludingThis(MallocSizeOf mallocSizeOf)
{
size_t n = 0;
n += mallocSizeOf(this);
n += mWrappedJSMap->SizeOfIncludingThis(mallocSizeOf);
n += mIID2NativeInterfaceMap->SizeOfIncludingThis(mallocSizeOf);
n += mClassInfo2NativeSetMap->ShallowSizeOfIncludingThis(mallocSizeOf);
n += mNativeSetMap->SizeOfIncludingThis(mallocSizeOf);
n += CycleCollectedJSRuntime::SizeOfExcludingThis(mallocSizeOf);
// There are other XPCJSRuntime members that could be measured; the above
// ones have been seen by DMD to be worth measuring. More stuff may be
// added later.
return n;
}
size_t
CompartmentPrivate::SizeOfIncludingThis(MallocSizeOf mallocSizeOf)
{
return mallocSizeOf(this) + mWrappedJSMap->SizeOfWrappedJS(mallocSizeOf);
}
/***************************************************************************/
void XPCJSRuntime::DestroyJSContextStack()
{
delete mJSContextStack;
mJSContextStack = nullptr;
}
void XPCJSRuntime::SystemIsBeingShutDown()
{
for (auto i = mDetachedWrappedNativeProtoMap->Iter(); !i.Done(); i.Next()) {
auto entry = static_cast<XPCWrappedNativeProtoMap::Entry*>(i.Get());
auto proto = const_cast<XPCWrappedNativeProto*>(static_cast<const XPCWrappedNativeProto*>(entry->key));
proto->SystemIsBeingShutDown();
}
}
#define JS_OPTIONS_DOT_STR "javascript.options."
static void
ReloadPrefsCallback(const char* pref, void* data)
{
XPCJSRuntime* runtime = reinterpret_cast<XPCJSRuntime*>(data);
JSRuntime* rt = runtime->Runtime();
bool safeMode = false;
nsCOMPtr<nsIXULRuntime> xr = do_GetService("@mozilla.org/xre/runtime;1");
if (xr) {
xr->GetInSafeMode(&safeMode);
}
bool useBaseline = Preferences::GetBool(JS_OPTIONS_DOT_STR "baselinejit") && !safeMode;
bool useIon = Preferences::GetBool(JS_OPTIONS_DOT_STR "ion") && !safeMode;
bool useAsmJS = Preferences::GetBool(JS_OPTIONS_DOT_STR "asmjs") && !safeMode;
bool throwOnAsmJSValidationFailure = Preferences::GetBool(JS_OPTIONS_DOT_STR
"throw_on_asmjs_validation_failure");
bool useNativeRegExp = Preferences::GetBool(JS_OPTIONS_DOT_STR "native_regexp") && !safeMode;
bool parallelParsing = Preferences::GetBool(JS_OPTIONS_DOT_STR "parallel_parsing");
bool offthreadIonCompilation = Preferences::GetBool(JS_OPTIONS_DOT_STR
"ion.offthread_compilation");
bool useBaselineEager = Preferences::GetBool(JS_OPTIONS_DOT_STR
"baselinejit.unsafe_eager_compilation");
bool useIonEager = Preferences::GetBool(JS_OPTIONS_DOT_STR "ion.unsafe_eager_compilation");
sDiscardSystemSource = Preferences::GetBool(JS_OPTIONS_DOT_STR "discardSystemSource");
bool useAsyncStack = Preferences::GetBool(JS_OPTIONS_DOT_STR "asyncstack");
bool useAsyncFuncs = Preferences::GetBool(JS_OPTIONS_DOT_STR "asyncfuncs");
bool werror = Preferences::GetBool(JS_OPTIONS_DOT_STR "werror");
bool extraWarnings = Preferences::GetBool(JS_OPTIONS_DOT_STR "strict");
#ifdef DEBUG
sExtraWarningsForSystemJS = Preferences::GetBool(JS_OPTIONS_DOT_STR "strict.debug");
#endif
JS::RuntimeOptionsRef(rt).setBaseline(useBaseline)
.setIon(useIon)
.setAsmJS(useAsmJS)
.setThrowOnAsmJSValidationFailure(throwOnAsmJSValidationFailure)
.setNativeRegExp(useNativeRegExp)
.setAsyncStack(useAsyncStack)
.setAsyncFuncs(useAsyncFuncs)
.setWerror(werror)
.setExtraWarnings(extraWarnings);
JS_SetParallelParsingEnabled(rt, parallelParsing);
JS_SetOffthreadIonCompilationEnabled(rt, offthreadIonCompilation);
JS_SetGlobalJitCompilerOption(rt, JSJITCOMPILER_BASELINE_WARMUP_TRIGGER,
useBaselineEager ? 0 : -1);
JS_SetGlobalJitCompilerOption(rt, JSJITCOMPILER_ION_WARMUP_TRIGGER,
useIonEager ? 0 : -1);
}
XPCJSRuntime::~XPCJSRuntime()
{
// This destructor runs before ~CycleCollectedJSRuntime, which does the
// actual JS_DestroyRuntime() call. But destroying the runtime triggers
// one final GC, which can call back into the runtime with various
// callback if we aren't careful. Null out the relevant callbacks.
js::SetActivityCallback(Runtime(), nullptr, nullptr);
JS_RemoveFinalizeCallback(Runtime(), FinalizeCallback);
JS_RemoveWeakPointerZoneGroupCallback(Runtime(), WeakPointerZoneGroupCallback);
JS_RemoveWeakPointerCompartmentCallback(Runtime(), WeakPointerCompartmentCallback);
// Clear any pending exception. It might be an XPCWrappedJS, and if we try
// to destroy it later we will crash.
SetPendingException(nullptr);
JS::SetGCSliceCallback(Runtime(), mPrevGCSliceCallback);
xpc_DelocalizeRuntime(Runtime());
if (mWatchdogManager->GetWatchdog())
mWatchdogManager->StopWatchdog();
if (mCallContext)
mCallContext->SystemIsBeingShutDown();
auto rtPrivate = static_cast<PerThreadAtomCache*>(JS_GetRuntimePrivate(Runtime()));
delete rtPrivate;
JS_SetRuntimePrivate(Runtime(), nullptr);
// clean up and destroy maps...
mWrappedJSMap->ShutdownMarker();
delete mWrappedJSMap;
mWrappedJSMap = nullptr;
delete mWrappedJSClassMap;
mWrappedJSClassMap = nullptr;
delete mIID2NativeInterfaceMap;
mIID2NativeInterfaceMap = nullptr;
delete mClassInfo2NativeSetMap;
mClassInfo2NativeSetMap = nullptr;
delete mNativeSetMap;
mNativeSetMap = nullptr;
delete mThisTranslatorMap;
mThisTranslatorMap = nullptr;
delete mNativeScriptableSharedMap;
mNativeScriptableSharedMap = nullptr;
delete mDyingWrappedNativeProtoMap;
mDyingWrappedNativeProtoMap = nullptr;
delete mDetachedWrappedNativeProtoMap;
mDetachedWrappedNativeProtoMap = nullptr;
#ifdef MOZ_ENABLE_PROFILER_SPS
// Tell the profiler that the runtime is gone
if (PseudoStack* stack = mozilla_get_pseudo_stack())
stack->sampleRuntime(nullptr);
#endif
Preferences::UnregisterCallback(ReloadPrefsCallback, JS_OPTIONS_DOT_STR, this);
}
// If |*anonymizeID| is non-zero and this is a user compartment, the name will
// be anonymized.
static void
GetCompartmentName(JSCompartment* c, nsCString& name, int* anonymizeID,
bool replaceSlashes)
{
if (js::IsAtomsCompartment(c)) {
name.AssignLiteral("atoms");
} else if (*anonymizeID && !js::IsSystemCompartment(c)) {
name.AppendPrintf("<anonymized-%d>", *anonymizeID);
*anonymizeID += 1;
} else if (JSPrincipals* principals = JS_GetCompartmentPrincipals(c)) {
nsJSPrincipals::get(principals)->GetScriptLocation(name);
// If the compartment's location (name) differs from the principal's
// script location, append the compartment's location to allow
// differentiation of multiple compartments owned by the same principal
// (e.g. components owned by the system or null principal).
CompartmentPrivate* compartmentPrivate = CompartmentPrivate::Get(c);
if (compartmentPrivate) {
const nsACString& location = compartmentPrivate->GetLocation();
if (!location.IsEmpty() && !location.Equals(name)) {
name.AppendLiteral(", ");
name.Append(location);
}
}
if (*anonymizeID) {
// We might have a file:// URL that includes a path from the local
// filesystem, which should be omitted if we're anonymizing.
static const char* filePrefix = "file://";
int filePos = name.Find(filePrefix);
if (filePos >= 0) {
int pathPos = filePos + strlen(filePrefix);
int lastSlashPos = -1;
for (int i = pathPos; i < int(name.Length()); i++) {
if (name[i] == '/' || name[i] == '\\') {
lastSlashPos = i;
}
}
if (lastSlashPos != -1) {
name.ReplaceASCII(pathPos, lastSlashPos - pathPos,
"<anonymized>");
} else {
// Something went wrong. Anonymize the entire path to be
// safe.
name.Truncate(pathPos);
name += "<anonymized?!>";
}
}
// We might have a location like this:
// inProcessTabChildGlobal?ownedBy=http://www.example.com/
// The owner should be omitted if it's not a chrome: URI and we're
// anonymizing.
static const char* ownedByPrefix =
"inProcessTabChildGlobal?ownedBy=";
int ownedByPos = name.Find(ownedByPrefix);
if (ownedByPos >= 0) {
const char* chrome = "chrome:";
int ownerPos = ownedByPos + strlen(ownedByPrefix);
const nsDependentCSubstring& ownerFirstPart =
Substring(name, ownerPos, strlen(chrome));
if (!ownerFirstPart.EqualsASCII(chrome)) {
name.Truncate(ownerPos);
name += "<anonymized>";
}
}
}
// A hack: replace forward slashes with '\\' so they aren't
// treated as path separators. Users of the reporters
// (such as about:memory) have to undo this change.
if (replaceSlashes)
name.ReplaceChar('/', '\\');
} else {
name.AssignLiteral("null-principal");
}
}
extern void
xpc::GetCurrentCompartmentName(JSContext* cx, nsCString& name)
{
RootedObject global(cx, JS::CurrentGlobalOrNull(cx));
if (!global) {
name.AssignLiteral("no global");
return;
}
JSCompartment* compartment = GetObjectCompartment(global);
int anonymizeID = 0;
GetCompartmentName(compartment, name, &anonymizeID, false);
}
JSRuntime*
xpc::GetJSRuntime()
{
return XPCJSRuntime::Get()->Runtime();
}
void
xpc::AddGCCallback(xpcGCCallback cb)
{
XPCJSRuntime::Get()->AddGCCallback(cb);
}
void
xpc::RemoveGCCallback(xpcGCCallback cb)
{
XPCJSRuntime::Get()->RemoveGCCallback(cb);
}
static int64_t
JSMainRuntimeGCHeapDistinguishedAmount()
{
JSRuntime* rt = nsXPConnect::GetRuntimeInstance()->Runtime();
return int64_t(JS_GetGCParameter(rt, JSGC_TOTAL_CHUNKS)) *
js::gc::ChunkSize;
}
static int64_t
JSMainRuntimeTemporaryPeakDistinguishedAmount()
{
JSRuntime* rt = nsXPConnect::GetRuntimeInstance()->Runtime();
return JS::PeakSizeOfTemporary(rt);
}
static int64_t
JSMainRuntimeCompartmentsSystemDistinguishedAmount()
{
JSRuntime* rt = nsXPConnect::GetRuntimeInstance()->Runtime();
return JS::SystemCompartmentCount(rt);
}
static int64_t
JSMainRuntimeCompartmentsUserDistinguishedAmount()
{
JSRuntime* rt = nsXPConnect::GetRuntimeInstance()->Runtime();
return JS::UserCompartmentCount(rt);
}
class JSMainRuntimeTemporaryPeakReporter final : public nsIMemoryReporter
{
~JSMainRuntimeTemporaryPeakReporter() {}
public:
NS_DECL_ISUPPORTS
NS_IMETHOD CollectReports(nsIHandleReportCallback* aHandleReport,
nsISupports* aData, bool aAnonymize) override
{
return MOZ_COLLECT_REPORT("js-main-runtime-temporary-peak",
KIND_OTHER, UNITS_BYTES,
JSMainRuntimeTemporaryPeakDistinguishedAmount(),
"Peak transient data size in the main JSRuntime (the current size "
"of which is reported as "
"'explicit/js-non-window/runtime/temporary').");
}
};
NS_IMPL_ISUPPORTS(JSMainRuntimeTemporaryPeakReporter, nsIMemoryReporter)
// The REPORT* macros do an unconditional report. The ZCREPORT* macros are for
// compartments and zones; they aggregate any entries smaller than
// SUNDRIES_THRESHOLD into the "sundries/gc-heap" and "sundries/malloc-heap"
// entries for the compartment.
#define SUNDRIES_THRESHOLD js::MemoryReportingSundriesThreshold()
#define REPORT(_path, _kind, _units, _amount, _desc) \
do { \
nsresult rv; \
rv = cb->Callback(EmptyCString(), _path, \
nsIMemoryReporter::_kind, \
nsIMemoryReporter::_units, \
_amount, \
NS_LITERAL_CSTRING(_desc), \
closure); \
NS_ENSURE_SUCCESS(rv, rv); \
} while (0)
#define REPORT_BYTES(_path, _kind, _amount, _desc) \
REPORT(_path, _kind, UNITS_BYTES, _amount, _desc);
#define REPORT_GC_BYTES(_path, _amount, _desc) \
do { \
size_t amount = _amount; /* evaluate _amount only once */ \
nsresult rv; \
rv = cb->Callback(EmptyCString(), _path, \
nsIMemoryReporter::KIND_NONHEAP, \
nsIMemoryReporter::UNITS_BYTES, amount, \
NS_LITERAL_CSTRING(_desc), closure); \
NS_ENSURE_SUCCESS(rv, rv); \
gcTotal += amount; \
} while (0)
// Report compartment/zone non-GC (KIND_HEAP) bytes.
#define ZCREPORT_BYTES(_path, _amount, _desc) \
do { \
/* Assign _descLiteral plus "" into a char* to prove that it's */ \
/* actually a literal. */ \
size_t amount = _amount; /* evaluate _amount only once */ \
if (amount >= SUNDRIES_THRESHOLD) { \
nsresult rv; \
rv = cb->Callback(EmptyCString(), _path, \
nsIMemoryReporter::KIND_HEAP, \
nsIMemoryReporter::UNITS_BYTES, amount, \
NS_LITERAL_CSTRING(_desc), closure); \
NS_ENSURE_SUCCESS(rv, rv); \
} else { \
sundriesMallocHeap += amount; \
} \
} while (0)
// Report compartment/zone GC bytes.
#define ZCREPORT_GC_BYTES(_path, _amount, _desc) \
do { \
size_t amount = _amount; /* evaluate _amount only once */ \
if (amount >= SUNDRIES_THRESHOLD) { \
nsresult rv; \
rv = cb->Callback(EmptyCString(), _path, \
nsIMemoryReporter::KIND_NONHEAP, \
nsIMemoryReporter::UNITS_BYTES, amount, \
NS_LITERAL_CSTRING(_desc), closure); \
NS_ENSURE_SUCCESS(rv, rv); \
gcTotal += amount; \
} else { \
sundriesGCHeap += amount; \
} \
} while (0)
// Report runtime bytes.
#define RREPORT_BYTES(_path, _kind, _amount, _desc) \
do { \
size_t amount = _amount; /* evaluate _amount only once */ \
nsresult rv; \
rv = cb->Callback(EmptyCString(), _path, \
nsIMemoryReporter::_kind, \
nsIMemoryReporter::UNITS_BYTES, amount, \
NS_LITERAL_CSTRING(_desc), closure); \
NS_ENSURE_SUCCESS(rv, rv); \
rtTotal += amount; \
} while (0)
// Report GC thing bytes.
#define MREPORT_BYTES(_path, _kind, _amount, _desc) \
do { \
size_t amount = _amount; /* evaluate _amount only once */ \
nsresult rv; \
rv = cb->Callback(EmptyCString(), _path, \
nsIMemoryReporter::_kind, \
nsIMemoryReporter::UNITS_BYTES, amount, \
NS_LITERAL_CSTRING(_desc), closure); \
NS_ENSURE_SUCCESS(rv, rv); \
gcThingTotal += amount; \
} while (0)
MOZ_DEFINE_MALLOC_SIZE_OF(JSMallocSizeOf)
namespace xpc {
static nsresult
ReportZoneStats(const JS::ZoneStats& zStats,
const xpc::ZoneStatsExtras& extras,
nsIMemoryReporterCallback* cb,
nsISupports* closure,
bool anonymize,
size_t* gcTotalOut = nullptr)
{
const nsCString& pathPrefix = extras.pathPrefix;
size_t gcTotal = 0, sundriesGCHeap = 0, sundriesMallocHeap = 0;
MOZ_ASSERT(!gcTotalOut == zStats.isTotals);
ZCREPORT_GC_BYTES(pathPrefix + NS_LITERAL_CSTRING("symbols/gc-heap"),
zStats.symbolsGCHeap,
"Symbols.");
ZCREPORT_GC_BYTES(pathPrefix + NS_LITERAL_CSTRING("gc-heap-arena-admin"),
zStats.gcHeapArenaAdmin,
"Bookkeeping information and alignment padding within GC arenas.");
ZCREPORT_GC_BYTES(pathPrefix + NS_LITERAL_CSTRING("unused-gc-things"),
zStats.unusedGCThings.totalSize(),
"Unused GC thing cells within non-empty arenas.");
ZCREPORT_BYTES(pathPrefix + NS_LITERAL_CSTRING("unique-id-map"),
zStats.uniqueIdMap,
"Address-independent cell identities.");
ZCREPORT_GC_BYTES(pathPrefix + NS_LITERAL_CSTRING("lazy-scripts/gc-heap"),
zStats.lazyScriptsGCHeap,
"Scripts that haven't executed yet.");
ZCREPORT_BYTES(pathPrefix + NS_LITERAL_CSTRING("lazy-scripts/malloc-heap"),
zStats.lazyScriptsMallocHeap,
"Lazy script tables containing free variables or inner functions.");
ZCREPORT_GC_BYTES(pathPrefix + NS_LITERAL_CSTRING("jit-codes-gc-heap"),
zStats.jitCodesGCHeap,
"References to executable code pools used by the JITs.");
ZCREPORT_GC_BYTES(pathPrefix + NS_LITERAL_CSTRING("object-groups/gc-heap"),
zStats.objectGroupsGCHeap,
"Classification and type inference information about objects.");
ZCREPORT_BYTES(pathPrefix + NS_LITERAL_CSTRING("object-groups/malloc-heap"),
zStats.objectGroupsMallocHeap,
"Object group addenda.");
ZCREPORT_BYTES(pathPrefix + NS_LITERAL_CSTRING("type-pool"),
zStats.typePool,
"Type sets and related data.");
ZCREPORT_BYTES(pathPrefix + NS_LITERAL_CSTRING("baseline/optimized-stubs"),
zStats.baselineStubsOptimized,
"The Baseline JIT's optimized IC stubs (excluding code).");
size_t stringsNotableAboutMemoryGCHeap = 0;
size_t stringsNotableAboutMemoryMallocHeap = 0;
#define MAYBE_INLINE \
"The characters may be inline or on the malloc heap."
#define MAYBE_OVERALLOCATED \
"Sometimes over-allocated to simplify string concatenation."
for (size_t i = 0; i < zStats.notableStrings.length(); i++) {
const JS::NotableStringInfo& info = zStats.notableStrings[i];
MOZ_ASSERT(!zStats.isTotals);
// We don't do notable string detection when anonymizing, because
// there's a good chance its for crash submission, and the memory
// required for notable string detection is high.
MOZ_ASSERT(!anonymize);
nsDependentCString notableString(info.buffer);
// Viewing about:memory generates many notable strings which contain
// "string(length=". If we report these as notable, then we'll create
// even more notable strings the next time we open about:memory (unless
// there's a GC in the meantime), and so on ad infinitum.
//
// To avoid cluttering up about:memory like this, we stick notable
// strings which contain "string(length=" into their own bucket.
# define STRING_LENGTH "string(length="
if (FindInReadable(NS_LITERAL_CSTRING(STRING_LENGTH), notableString)) {
stringsNotableAboutMemoryGCHeap += info.gcHeapLatin1;
stringsNotableAboutMemoryGCHeap += info.gcHeapTwoByte;
stringsNotableAboutMemoryMallocHeap += info.mallocHeapLatin1;
stringsNotableAboutMemoryMallocHeap += info.mallocHeapTwoByte;
continue;
}
// Escape / to \ before we put notableString into the memory reporter
// path, because we don't want any forward slashes in the string to
// count as path separators.
nsCString escapedString(notableString);
escapedString.ReplaceSubstring("/", "\\");
bool truncated = notableString.Length() < info.length;
nsCString path = pathPrefix +
nsPrintfCString("strings/" STRING_LENGTH "%d, copies=%d, \"%s\"%s)/",
info.length, info.numCopies, escapedString.get(),
truncated ? " (truncated)" : "");
if (info.gcHeapLatin1 > 0) {
REPORT_GC_BYTES(path + NS_LITERAL_CSTRING("gc-heap/latin1"),
info.gcHeapLatin1,
"Latin1 strings. " MAYBE_INLINE);
}
if (info.gcHeapTwoByte > 0) {
REPORT_GC_BYTES(path + NS_LITERAL_CSTRING("gc-heap/two-byte"),
info.gcHeapTwoByte,
"TwoByte strings. " MAYBE_INLINE);
}
if (info.mallocHeapLatin1 > 0) {
REPORT_BYTES(path + NS_LITERAL_CSTRING("malloc-heap/latin1"),
KIND_HEAP, info.mallocHeapLatin1,
"Non-inline Latin1 string characters. " MAYBE_OVERALLOCATED);
}
if (info.mallocHeapTwoByte > 0) {
REPORT_BYTES(path + NS_LITERAL_CSTRING("malloc-heap/two-byte"),
KIND_HEAP, info.mallocHeapTwoByte,
"Non-inline TwoByte string characters. " MAYBE_OVERALLOCATED);
}
}
nsCString nonNotablePath = pathPrefix;
nonNotablePath += (zStats.isTotals || anonymize)
? NS_LITERAL_CSTRING("strings/")
: NS_LITERAL_CSTRING("strings/string(<non-notable strings>)/");
if (zStats.stringInfo.gcHeapLatin1 > 0) {
REPORT_GC_BYTES(nonNotablePath + NS_LITERAL_CSTRING("gc-heap/latin1"),
zStats.stringInfo.gcHeapLatin1,
"Latin1 strings. " MAYBE_INLINE);
}
if (zStats.stringInfo.gcHeapTwoByte > 0) {
REPORT_GC_BYTES(nonNotablePath + NS_LITERAL_CSTRING("gc-heap/two-byte"),
zStats.stringInfo.gcHeapTwoByte,
"TwoByte strings. " MAYBE_INLINE);
}
if (zStats.stringInfo.mallocHeapLatin1 > 0) {
REPORT_BYTES(nonNotablePath + NS_LITERAL_CSTRING("malloc-heap/latin1"),
KIND_HEAP, zStats.stringInfo.mallocHeapLatin1,
"Non-inline Latin1 string characters. " MAYBE_OVERALLOCATED);
}
if (zStats.stringInfo.mallocHeapTwoByte > 0) {
REPORT_BYTES(nonNotablePath + NS_LITERAL_CSTRING("malloc-heap/two-byte"),
KIND_HEAP, zStats.stringInfo.mallocHeapTwoByte,
"Non-inline TwoByte string characters. " MAYBE_OVERALLOCATED);
}
if (stringsNotableAboutMemoryGCHeap > 0) {
MOZ_ASSERT(!zStats.isTotals);
REPORT_GC_BYTES(pathPrefix + NS_LITERAL_CSTRING("strings/string(<about-memory>)/gc-heap"),
stringsNotableAboutMemoryGCHeap,
"Strings that contain the characters '" STRING_LENGTH "', which "
"are probably from about:memory itself." MAYBE_INLINE
" We filter them out rather than display them, because displaying "
"them would create even more such strings every time about:memory "
"is refreshed.");
}
if (stringsNotableAboutMemoryMallocHeap > 0) {
MOZ_ASSERT(!zStats.isTotals);
REPORT_BYTES(pathPrefix + NS_LITERAL_CSTRING("strings/string(<about-memory>)/malloc-heap"),
KIND_HEAP, stringsNotableAboutMemoryMallocHeap,
"Non-inline string characters of strings that contain the "
"characters '" STRING_LENGTH "', which are probably from "
"about:memory itself. " MAYBE_OVERALLOCATED
" We filter them out rather than display them, because displaying "
"them would create even more such strings every time about:memory "
"is refreshed.");
}
if (sundriesGCHeap > 0) {
// We deliberately don't use ZCREPORT_GC_BYTES here.
REPORT_GC_BYTES(pathPrefix + NS_LITERAL_CSTRING("sundries/gc-heap"),
sundriesGCHeap,
"The sum of all 'gc-heap' measurements that are too small to be "
"worth showing individually.");
}
if (sundriesMallocHeap > 0) {
// We deliberately don't use ZCREPORT_BYTES here.
REPORT_BYTES(pathPrefix + NS_LITERAL_CSTRING("sundries/malloc-heap"),
KIND_HEAP, sundriesMallocHeap,
"The sum of all 'malloc-heap' measurements that are too small to "
"be worth showing individually.");
}
if (gcTotalOut)
*gcTotalOut += gcTotal;
return NS_OK;
# undef STRING_LENGTH
}
static nsresult
ReportClassStats(const ClassInfo& classInfo, const nsACString& path,
nsIHandleReportCallback* cb, nsISupports* closure,
size_t& gcTotal)
{
// We deliberately don't use ZCREPORT_BYTES, so that these per-class values
// don't go into sundries.
if (classInfo.objectsGCHeap > 0) {
REPORT_GC_BYTES(path + NS_LITERAL_CSTRING("objects/gc-heap"),
classInfo.objectsGCHeap,
"Objects, including fixed slots.");
}
if (classInfo.objectsMallocHeapSlots > 0) {
REPORT_BYTES(path + NS_LITERAL_CSTRING("objects/malloc-heap/slots"),
KIND_HEAP, classInfo.objectsMallocHeapSlots,
"Non-fixed object slots.");
}
if (classInfo.objectsMallocHeapElementsNonAsmJS > 0) {
REPORT_BYTES(path + NS_LITERAL_CSTRING("objects/malloc-heap/elements/non-asm.js"),
KIND_HEAP, classInfo.objectsMallocHeapElementsNonAsmJS,
"Non-asm.js indexed elements.");
}
// asm.js arrays are heap-allocated on some platforms and
// non-heap-allocated on others. We never put them under sundries,
// because (a) in practice they're almost always larger than the sundries
// threshold, and (b) we'd need a third category of sundries ("non-heap"),
// which would be a pain.
size_t mallocHeapElementsAsmJS = classInfo.objectsMallocHeapElementsAsmJS;
size_t nonHeapElementsAsmJS = classInfo.objectsNonHeapElementsAsmJS;
MOZ_ASSERT(mallocHeapElementsAsmJS == 0 || nonHeapElementsAsmJS == 0);
if (mallocHeapElementsAsmJS > 0) {
REPORT_BYTES(path + NS_LITERAL_CSTRING("objects/malloc-heap/elements/asm.js"),
KIND_HEAP, mallocHeapElementsAsmJS,
"asm.js array buffer elements on the malloc heap.");
}
if (nonHeapElementsAsmJS > 0) {
REPORT_BYTES(path + NS_LITERAL_CSTRING("objects/non-heap/elements/asm.js"),
KIND_NONHEAP, nonHeapElementsAsmJS,
"asm.js array buffer elements outside both the malloc heap and "
"the GC heap.");
}
if (classInfo.objectsNonHeapElementsMapped > 0) {
REPORT_BYTES(path + NS_LITERAL_CSTRING("objects/non-heap/elements/mapped"),
KIND_NONHEAP, classInfo.objectsNonHeapElementsMapped,
"Memory-mapped array buffer elements.");
}
if (classInfo.objectsNonHeapCodeAsmJS > 0) {
REPORT_BYTES(path + NS_LITERAL_CSTRING("objects/non-heap/code/asm.js"),
KIND_NONHEAP, classInfo.objectsNonHeapCodeAsmJS,
"AOT-compiled asm.js code.");
}
if (classInfo.objectsMallocHeapMisc > 0) {
REPORT_BYTES(path + NS_LITERAL_CSTRING("objects/malloc-heap/misc"),
KIND_HEAP, classInfo.objectsMallocHeapMisc,
"Miscellaneous object data.");
}
if (classInfo.shapesGCHeapTree > 0) {
REPORT_GC_BYTES(path + NS_LITERAL_CSTRING("shapes/gc-heap/tree"),
classInfo.shapesGCHeapTree,
"Shapes in a property tree.");
}
if (classInfo.shapesGCHeapDict > 0) {
REPORT_GC_BYTES(path + NS_LITERAL_CSTRING("shapes/gc-heap/dict"),
classInfo.shapesGCHeapDict,
"Shapes in dictionary mode.");
}
if (classInfo.shapesGCHeapBase > 0) {
REPORT_GC_BYTES(path + NS_LITERAL_CSTRING("shapes/gc-heap/base"),
classInfo.shapesGCHeapBase,
"Base shapes, which collate data common to many shapes.");
}
if (classInfo.shapesMallocHeapTreeTables > 0) {
REPORT_BYTES(path + NS_LITERAL_CSTRING("shapes/malloc-heap/tree-tables"),
KIND_HEAP, classInfo.shapesMallocHeapTreeTables,
"Property tables of shapes in a property tree.");
}
if (classInfo.shapesMallocHeapDictTables > 0) {
REPORT_BYTES(path + NS_LITERAL_CSTRING("shapes/malloc-heap/dict-tables"),
KIND_HEAP, classInfo.shapesMallocHeapDictTables,
"Property tables of shapes in dictionary mode.");
}
if (classInfo.shapesMallocHeapTreeKids > 0) {
REPORT_BYTES(path + NS_LITERAL_CSTRING("shapes/malloc-heap/tree-kids"),
KIND_HEAP, classInfo.shapesMallocHeapTreeKids,
"Kid hashes of shapes in a property tree.");
}
return NS_OK;
}
static nsresult
ReportCompartmentStats(const JS::CompartmentStats& cStats,
const xpc::CompartmentStatsExtras& extras,
amIAddonManager* addonManager,
nsIMemoryReporterCallback* cb,
nsISupports* closure, size_t* gcTotalOut = nullptr)
{
static const nsDependentCString addonPrefix("explicit/add-ons/");
size_t gcTotal = 0, sundriesGCHeap = 0, sundriesMallocHeap = 0;
nsAutoCString cJSPathPrefix(extras.jsPathPrefix);
nsAutoCString cDOMPathPrefix(extras.domPathPrefix);
nsresult rv;
MOZ_ASSERT(!gcTotalOut == cStats.isTotals);
// Only attempt to prefix if we got a location and the path wasn't already
// prefixed.
if (extras.location && addonManager &&
cJSPathPrefix.Find(addonPrefix, false, 0, 0) != 0) {
nsAutoCString addonId;
bool ok;
if (NS_SUCCEEDED(addonManager->MapURIToAddonID(extras.location,
addonId, &ok))
&& ok) {
// Insert the add-on id as "add-ons/@id@/" after "explicit/" to
// aggregate add-on compartments.
static const size_t explicitLength = strlen("explicit/");
addonId.Insert(NS_LITERAL_CSTRING("add-ons/"), 0);
addonId += "/";
cJSPathPrefix.Insert(addonId, explicitLength);
cDOMPathPrefix.Insert(addonId, explicitLength);
}
}
nsCString nonNotablePath = cJSPathPrefix;
nonNotablePath += cStats.isTotals
? NS_LITERAL_CSTRING("classes/")
: NS_LITERAL_CSTRING("classes/class(<non-notable classes>)/");
rv = ReportClassStats(cStats.classInfo, nonNotablePath, cb, closure,
gcTotal);
NS_ENSURE_SUCCESS(rv, rv);
for (size_t i = 0; i < cStats.notableClasses.length(); i++) {
MOZ_ASSERT(!cStats.isTotals);
const JS::NotableClassInfo& classInfo = cStats.notableClasses[i];
nsCString classPath = cJSPathPrefix +
nsPrintfCString("classes/class(%s)/", classInfo.className_);
rv = ReportClassStats(classInfo, classPath, cb, closure, gcTotal);
NS_ENSURE_SUCCESS(rv, rv);
}
// Note that we use cDOMPathPrefix here. This is because we measure orphan
// DOM nodes in the JS reporter, but we want to report them in a "dom"
// sub-tree rather than a "js" sub-tree.
ZCREPORT_BYTES(cDOMPathPrefix + NS_LITERAL_CSTRING("orphan-nodes"),
cStats.objectsPrivate,
"Orphan DOM nodes, i.e. those that are only reachable from JavaScript "
"objects.");
ZCREPORT_BYTES(cDOMPathPrefix + NS_LITERAL_CSTRING("private-data"),
extras.sizeOfXPCPrivate,
"Extra data attached to the compartment by XPConnect, including "\
"wrapped-js that is local to a single compartment.");
ZCREPORT_GC_BYTES(cJSPathPrefix + NS_LITERAL_CSTRING("scripts/gc-heap"),
cStats.scriptsGCHeap,
"JSScript instances. There is one per user-defined function in a "
"script, and one for the top-level code in a script.");
ZCREPORT_BYTES(cJSPathPrefix + NS_LITERAL_CSTRING("scripts/malloc-heap/data"),
cStats.scriptsMallocHeapData,
"Various variable-length tables in JSScripts.");
ZCREPORT_BYTES(cJSPathPrefix + NS_LITERAL_CSTRING("baseline/data"),
cStats.baselineData,
"The Baseline JIT's compilation data (BaselineScripts).");
ZCREPORT_BYTES(cJSPathPrefix + NS_LITERAL_CSTRING("baseline/fallback-stubs"),
cStats.baselineStubsFallback,
"The Baseline JIT's fallback IC stubs (excluding code).");
ZCREPORT_BYTES(cJSPathPrefix + NS_LITERAL_CSTRING("ion-data"),
cStats.ionData,
"The IonMonkey JIT's compilation data (IonScripts).");
ZCREPORT_BYTES(cJSPathPrefix + NS_LITERAL_CSTRING("type-inference/type-scripts"),
cStats.typeInferenceTypeScripts,
"Type sets associated with scripts.");
ZCREPORT_BYTES(cJSPathPrefix + NS_LITERAL_CSTRING("type-inference/allocation-site-tables"),
cStats.typeInferenceAllocationSiteTables,
"Tables of type objects associated with allocation sites.");
ZCREPORT_BYTES(cJSPathPrefix + NS_LITERAL_CSTRING("type-inference/array-type-tables"),
cStats.typeInferenceArrayTypeTables,
"Tables of type objects associated with array literals.");
ZCREPORT_BYTES(cJSPathPrefix + NS_LITERAL_CSTRING("type-inference/object-type-tables"),
cStats.typeInferenceObjectTypeTables,
"Tables of type objects associated with object literals.");
ZCREPORT_BYTES(cJSPathPrefix + NS_LITERAL_CSTRING("compartment-object"),
cStats.compartmentObject,
"The JSCompartment object itself.");
ZCREPORT_BYTES(cJSPathPrefix + NS_LITERAL_CSTRING("compartment-tables"),
cStats.compartmentTables,
"Compartment-wide tables storing shape and type object information.");
ZCREPORT_BYTES(cJSPathPrefix + NS_LITERAL_CSTRING("inner-views"),
cStats.innerViewsTable,
"The table for array buffer inner views.");
ZCREPORT_BYTES(cJSPathPrefix + NS_LITERAL_CSTRING("lazy-array-buffers"),
cStats.lazyArrayBuffersTable,
"The table for typed object lazy array buffers.");
ZCREPORT_BYTES(cJSPathPrefix + NS_LITERAL_CSTRING("object-metadata"),
cStats.objectMetadataTable,
"The table used by debugging tools for tracking object metadata");
ZCREPORT_BYTES(cJSPathPrefix + NS_LITERAL_CSTRING("cross-compartment-wrapper-table"),
cStats.crossCompartmentWrappersTable,
"The cross-compartment wrapper table.");
ZCREPORT_BYTES(cJSPathPrefix + NS_LITERAL_CSTRING("regexp-compartment"),
cStats.regexpCompartment,
"The regexp compartment and regexp data.");
ZCREPORT_BYTES(cJSPathPrefix + NS_LITERAL_CSTRING("saved-stacks-set"),
cStats.savedStacksSet,
"The saved stacks set.");
if (sundriesGCHeap > 0) {
// We deliberately don't use ZCREPORT_GC_BYTES here.
REPORT_GC_BYTES(cJSPathPrefix + NS_LITERAL_CSTRING("sundries/gc-heap"),
sundriesGCHeap,
"The sum of all 'gc-heap' measurements that are too small to be "
"worth showing individually.");
}
if (sundriesMallocHeap > 0) {
// We deliberately don't use ZCREPORT_BYTES here.
REPORT_BYTES(cJSPathPrefix + NS_LITERAL_CSTRING("sundries/malloc-heap"),
KIND_HEAP, sundriesMallocHeap,
"The sum of all 'malloc-heap' measurements that are too small to "
"be worth showing individually.");
}
if (gcTotalOut)
*gcTotalOut += gcTotal;
return NS_OK;
}
static nsresult
ReportScriptSourceStats(const ScriptSourceInfo& scriptSourceInfo,
const nsACString& path,
nsIHandleReportCallback* cb, nsISupports* closure,
size_t& rtTotal)
{
if (scriptSourceInfo.compressed > 0) {
RREPORT_BYTES(path + NS_LITERAL_CSTRING("compressed"),
KIND_HEAP, scriptSourceInfo.compressed,
"Compressed JavaScript source code.");
}
if (scriptSourceInfo.uncompressed > 0) {
RREPORT_BYTES(path + NS_LITERAL_CSTRING("uncompressed"),
KIND_HEAP, scriptSourceInfo.uncompressed,
"Uncompressed JavaScript source code.");
}
if (scriptSourceInfo.misc > 0) {
RREPORT_BYTES(path + NS_LITERAL_CSTRING("misc"),
KIND_HEAP, scriptSourceInfo.misc,
"Miscellaneous data relating to JavaScript source code.");
}
return NS_OK;
}
static nsresult
ReportJSRuntimeExplicitTreeStats(const JS::RuntimeStats& rtStats,
const nsACString& rtPath,
amIAddonManager* addonManager,
nsIMemoryReporterCallback* cb,
nsISupports* closure,
bool anonymize,
size_t* rtTotalOut)
{
nsresult rv;
size_t gcTotal = 0;
for (size_t i = 0; i < rtStats.zoneStatsVector.length(); i++) {
const JS::ZoneStats& zStats = rtStats.zoneStatsVector[i];
const xpc::ZoneStatsExtras* extras =
static_cast<const xpc::ZoneStatsExtras*>(zStats.extra);
rv = ReportZoneStats(zStats, *extras, cb, closure, anonymize, &gcTotal);
NS_ENSURE_SUCCESS(rv, rv);
}
for (size_t i = 0; i < rtStats.compartmentStatsVector.length(); i++) {
const JS::CompartmentStats& cStats = rtStats.compartmentStatsVector[i];
const xpc::CompartmentStatsExtras* extras =
static_cast<const xpc::CompartmentStatsExtras*>(cStats.extra);
rv = ReportCompartmentStats(cStats, *extras, addonManager, cb, closure,
&gcTotal);
NS_ENSURE_SUCCESS(rv, rv);
}
// Report the rtStats.runtime numbers under "runtime/", and compute their
// total for later.
size_t rtTotal = 0;
RREPORT_BYTES(rtPath + NS_LITERAL_CSTRING("runtime/runtime-object"),
KIND_HEAP, rtStats.runtime.object,
"The JSRuntime object.");
RREPORT_BYTES(rtPath + NS_LITERAL_CSTRING("runtime/atoms-table"),
KIND_HEAP, rtStats.runtime.atomsTable,
"The atoms table.");
RREPORT_BYTES(rtPath + NS_LITERAL_CSTRING("runtime/contexts"),
KIND_HEAP, rtStats.runtime.contexts,
"JSContext objects and structures that belong to them.");
RREPORT_BYTES(rtPath + NS_LITERAL_CSTRING("runtime/dtoa"),
KIND_HEAP, rtStats.runtime.dtoa,
"The DtoaState object, which is used for converting strings to "
"numbers and vice versa.");
RREPORT_BYTES(rtPath + NS_LITERAL_CSTRING("runtime/temporary"),
KIND_HEAP, rtStats.runtime.temporary,
"Transient data (mostly parse nodes) held by the JSRuntime during "
"compilation.");
RREPORT_BYTES(rtPath + NS_LITERAL_CSTRING("runtime/interpreter-stack"),
KIND_HEAP, rtStats.runtime.interpreterStack,
"JS interpreter frames.");
RREPORT_BYTES(rtPath + NS_LITERAL_CSTRING("runtime/math-cache"),
KIND_HEAP, rtStats.runtime.mathCache,
"The math cache.");
RREPORT_BYTES(rtPath + NS_LITERAL_CSTRING("runtime/uncompressed-source-cache"),
KIND_HEAP, rtStats.runtime.uncompressedSourceCache,
"The uncompressed source code cache.");
RREPORT_BYTES(rtPath + NS_LITERAL_CSTRING("runtime/compressed-source-sets"),
KIND_HEAP, rtStats.runtime.compressedSourceSet,
"The table indexing compressed source code in the runtime.");
RREPORT_BYTES(rtPath + NS_LITERAL_CSTRING("runtime/script-data"),
KIND_HEAP, rtStats.runtime.scriptData,
"The table holding script data shared in the runtime.");
nsCString nonNotablePath =
rtPath + nsPrintfCString("runtime/script-sources/source(scripts=%d, <non-notable files>)/",
rtStats.runtime.scriptSourceInfo.numScripts);
rv = ReportScriptSourceStats(rtStats.runtime.scriptSourceInfo,
nonNotablePath, cb, closure, rtTotal);
NS_ENSURE_SUCCESS(rv, rv);
for (size_t i = 0; i < rtStats.runtime.notableScriptSources.length(); i++) {
const JS::NotableScriptSourceInfo& scriptSourceInfo =
rtStats.runtime.notableScriptSources[i];
// Escape / to \ before we put the filename into the memory reporter
// path, because we don't want any forward slashes in the string to
// count as path separators. Consumers of memory reporters (e.g.
// about:memory) will convert them back to / after doing path
// splitting.
nsCString escapedFilename;
if (anonymize) {
escapedFilename.AppendPrintf("<anonymized-source-%d>", int(i));
} else {
nsDependentCString filename(scriptSourceInfo.filename_);
escapedFilename.Append(filename);
escapedFilename.ReplaceSubstring("/", "\\");
}
nsCString notablePath = rtPath +
nsPrintfCString("runtime/script-sources/source(scripts=%d, %s)/",
scriptSourceInfo.numScripts, escapedFilename.get());
rv = ReportScriptSourceStats(scriptSourceInfo, notablePath,
cb, closure, rtTotal);
NS_ENSURE_SUCCESS(rv, rv);
}
RREPORT_BYTES(rtPath + NS_LITERAL_CSTRING("runtime/code/ion"),
KIND_NONHEAP, rtStats.runtime.code.ion,
"Code generated by the IonMonkey JIT.");
RREPORT_BYTES(rtPath + NS_LITERAL_CSTRING("runtime/code/baseline"),
KIND_NONHEAP, rtStats.runtime.code.baseline,
"Code generated by the Baseline JIT.");
RREPORT_BYTES(rtPath + NS_LITERAL_CSTRING("runtime/code/regexp"),
KIND_NONHEAP, rtStats.runtime.code.regexp,
"Code generated by the regexp JIT.");
RREPORT_BYTES(rtPath + NS_LITERAL_CSTRING("runtime/code/other"),
KIND_NONHEAP, rtStats.runtime.code.other,
"Code generated by the JITs for wrappers and trampolines.");
RREPORT_BYTES(rtPath + NS_LITERAL_CSTRING("runtime/code/unused"),
KIND_NONHEAP, rtStats.runtime.code.unused,
"Memory allocated by one of the JITs to hold code, but which is "
"currently unused.");
RREPORT_BYTES(rtPath + NS_LITERAL_CSTRING("runtime/gc/marker"),
KIND_HEAP, rtStats.runtime.gc.marker,
"The GC mark stack and gray roots.");
RREPORT_BYTES(rtPath + NS_LITERAL_CSTRING("runtime/gc/nursery-committed"),
KIND_NONHEAP, rtStats.runtime.gc.nurseryCommitted,
"Memory being used by the GC's nursery.");
RREPORT_BYTES(rtPath + NS_LITERAL_CSTRING("runtime/gc/nursery-malloced-buffers"),
KIND_HEAP, rtStats.runtime.gc.nurseryMallocedBuffers,
"Out-of-line slots and elements belonging to objects in the nursery.");
RREPORT_BYTES(rtPath + NS_LITERAL_CSTRING("runtime/gc/store-buffer/vals"),
KIND_HEAP, rtStats.runtime.gc.storeBufferVals,
"Values in the store buffer.");
RREPORT_BYTES(rtPath + NS_LITERAL_CSTRING("runtime/gc/store-buffer/cells"),
KIND_HEAP, rtStats.runtime.gc.storeBufferCells,
"Cells in the store buffer.");
RREPORT_BYTES(rtPath + NS_LITERAL_CSTRING("runtime/gc/store-buffer/slots"),
KIND_HEAP, rtStats.runtime.gc.storeBufferSlots,
"Slots in the store buffer.");
RREPORT_BYTES(rtPath + NS_LITERAL_CSTRING("runtime/gc/store-buffer/whole-cells"),
KIND_HEAP, rtStats.runtime.gc.storeBufferWholeCells,
"Whole cells in the store buffer.");
RREPORT_BYTES(rtPath + NS_LITERAL_CSTRING("runtime/gc/store-buffer/generics"),
KIND_HEAP, rtStats.runtime.gc.storeBufferGenerics,
"Generic things in the store buffer.");
if (rtTotalOut)
*rtTotalOut = rtTotal;
// Report GC numbers that don't belong to a compartment.
// We don't want to report decommitted memory in "explicit", so we just
// change the leading "explicit/" to "decommitted/".
nsCString rtPath2(rtPath);
rtPath2.Replace(0, strlen("explicit"), NS_LITERAL_CSTRING("decommitted"));
REPORT_GC_BYTES(rtPath2 + NS_LITERAL_CSTRING("gc-heap/decommitted-arenas"),
rtStats.gcHeapDecommittedArenas,
"GC arenas in non-empty chunks that is decommitted, i.e. it takes up "
"address space but no physical memory or swap space.");
REPORT_BYTES(rtPath2 + NS_LITERAL_CSTRING("runtime/gc/nursery-decommitted"),
KIND_NONHEAP, rtStats.runtime.gc.nurseryDecommitted,
"Memory allocated to the GC's nursery that is decommitted, i.e. it takes up "
"address space but no physical memory or swap space.");
REPORT_GC_BYTES(rtPath + NS_LITERAL_CSTRING("gc-heap/unused-chunks"),
rtStats.gcHeapUnusedChunks,
"Empty GC chunks which will soon be released unless claimed for new "
"allocations.");
REPORT_GC_BYTES(rtPath + NS_LITERAL_CSTRING("gc-heap/unused-arenas"),
rtStats.gcHeapUnusedArenas,
"Empty GC arenas within non-empty chunks.");
REPORT_GC_BYTES(rtPath + NS_LITERAL_CSTRING("gc-heap/chunk-admin"),
rtStats.gcHeapChunkAdmin,
"Bookkeeping information within GC chunks.");
// gcTotal is the sum of everything we've reported for the GC heap. It
// should equal rtStats.gcHeapChunkTotal.
MOZ_ASSERT(gcTotal == rtStats.gcHeapChunkTotal);
return NS_OK;
}
nsresult
ReportJSRuntimeExplicitTreeStats(const JS::RuntimeStats& rtStats,
const nsACString& rtPath,
nsIMemoryReporterCallback* cb,
nsISupports* closure,
bool anonymize,
size_t* rtTotalOut)
{
nsCOMPtr<amIAddonManager> am;
if (XRE_IsParentProcess()) {
// Only try to access the service from the main process.
am = do_GetService("@mozilla.org/addons/integration;1");
}
return ReportJSRuntimeExplicitTreeStats(rtStats, rtPath, am.get(),
cb, closure, anonymize, rtTotalOut);
}
} // namespace xpc
class JSMainRuntimeCompartmentsReporter final : public nsIMemoryReporter
{
~JSMainRuntimeCompartmentsReporter() {}
public:
NS_DECL_ISUPPORTS
struct Data {
int anonymizeID;
js::Vector<nsCString, 0, js::SystemAllocPolicy> paths;
};
static void CompartmentCallback(JSRuntime* rt, void* vdata, JSCompartment* c) {
// silently ignore OOM errors
Data* data = static_cast<Data*>(vdata);
nsCString path;
GetCompartmentName(c, path, &data->anonymizeID, /* replaceSlashes = */ true);
path.Insert(js::IsSystemCompartment(c)
? NS_LITERAL_CSTRING("js-main-runtime-compartments/system/")
: NS_LITERAL_CSTRING("js-main-runtime-compartments/user/"),
0);
data->paths.append(path);
}
NS_IMETHOD CollectReports(nsIMemoryReporterCallback* cb,
nsISupports* closure, bool anonymize) override
{
// First we collect the compartment paths. Then we report them. Doing
// the two steps interleaved is a bad idea, because calling |cb|
// from within CompartmentCallback() leads to all manner of assertions.
Data data;
data.anonymizeID = anonymize ? 1 : 0;
JS_IterateCompartments(nsXPConnect::GetRuntimeInstance()->Runtime(),
&data, CompartmentCallback);
for (size_t i = 0; i < data.paths.length(); i++)
REPORT(nsCString(data.paths[i]), KIND_OTHER, UNITS_COUNT, 1,
"A live compartment in the main JSRuntime.");
return NS_OK;
}
};
NS_IMPL_ISUPPORTS(JSMainRuntimeCompartmentsReporter, nsIMemoryReporter)
MOZ_DEFINE_MALLOC_SIZE_OF(OrphanMallocSizeOf)
namespace xpc {
static size_t
SizeOfTreeIncludingThis(nsINode* tree)
{
size_t n = tree->SizeOfIncludingThis(OrphanMallocSizeOf);
for (nsIContent* child = tree->GetFirstChild(); child; child = child->GetNextNode(tree))
n += child->SizeOfIncludingThis(OrphanMallocSizeOf);
return n;
}
class OrphanReporter : public JS::ObjectPrivateVisitor
{
public:
explicit OrphanReporter(GetISupportsFun aGetISupports)
: JS::ObjectPrivateVisitor(aGetISupports)
{
}
virtual size_t sizeOfIncludingThis(nsISupports* aSupports) override {
size_t n = 0;
nsCOMPtr<nsINode> node = do_QueryInterface(aSupports);
// https://bugzilla.mozilla.org/show_bug.cgi?id=773533#c11 explains
// that we have to skip XBL elements because they violate certain
// assumptions. Yuk.
if (node && !node->IsInDoc() &&
!(node->IsElement() && node->AsElement()->IsInNamespace(kNameSpaceID_XBL)))
{
// This is an orphan node. If we haven't already handled the
// sub-tree that this node belongs to, measure the sub-tree's size
// and then record its root so we don't measure it again.
nsCOMPtr<nsINode> orphanTree = node->SubtreeRoot();
if (!mAlreadyMeasuredOrphanTrees.Contains(orphanTree)) {
n += SizeOfTreeIncludingThis(orphanTree);
mAlreadyMeasuredOrphanTrees.PutEntry(orphanTree);
}
}
return n;
}
private:
nsTHashtable <nsISupportsHashKey> mAlreadyMeasuredOrphanTrees;
};
#ifdef DEBUG
static bool
StartsWithExplicit(nsACString& s)
{
return StringBeginsWith(s, NS_LITERAL_CSTRING("explicit/"));
}
#endif
class XPCJSRuntimeStats : public JS::RuntimeStats
{
WindowPaths* mWindowPaths;
WindowPaths* mTopWindowPaths;
bool mGetLocations;
int mAnonymizeID;
public:
XPCJSRuntimeStats(WindowPaths* windowPaths, WindowPaths* topWindowPaths,
bool getLocations, bool anonymize)
: JS::RuntimeStats(JSMallocSizeOf),
mWindowPaths(windowPaths),
mTopWindowPaths(topWindowPaths),
mGetLocations(getLocations),
mAnonymizeID(anonymize ? 1 : 0)
{}
~XPCJSRuntimeStats() {
for (size_t i = 0; i != compartmentStatsVector.length(); ++i)
delete static_cast<xpc::CompartmentStatsExtras*>(compartmentStatsVector[i].extra);
for (size_t i = 0; i != zoneStatsVector.length(); ++i)
delete static_cast<xpc::ZoneStatsExtras*>(zoneStatsVector[i].extra);
}
virtual void initExtraZoneStats(JS::Zone* zone, JS::ZoneStats* zStats) override {
// Get the compartment's global.
nsXPConnect* xpc = nsXPConnect::XPConnect();
AutoSafeJSContext cx;
JSCompartment* comp = js::GetAnyCompartmentInZone(zone);
xpc::ZoneStatsExtras* extras = new xpc::ZoneStatsExtras;
extras->pathPrefix.AssignLiteral("explicit/js-non-window/zones/");
RootedObject global(cx, JS_GetGlobalForCompartmentOrNull(cx, comp));
if (global) {
// Need to enter the compartment, otherwise GetNativeOfWrapper()
// might crash.
JSAutoCompartment ac(cx, global);
nsISupports* native = xpc->GetNativeOfWrapper(cx, global);
if (nsCOMPtr<nsPIDOMWindow> piwindow = do_QueryInterface(native)) {
// The global is a |window| object. Use the path prefix that
// we should have already created for it.
if (mTopWindowPaths->Get(piwindow->WindowID(),
&extras->pathPrefix))
extras->pathPrefix.AppendLiteral("/js-");
}
}
extras->pathPrefix += nsPrintfCString("zone(0x%p)/", (void*)zone);
MOZ_ASSERT(StartsWithExplicit(extras->pathPrefix));
zStats->extra = extras;
}
virtual void initExtraCompartmentStats(JSCompartment* c,
JS::CompartmentStats* cstats) override
{
xpc::CompartmentStatsExtras* extras = new xpc::CompartmentStatsExtras;
nsCString cName;
GetCompartmentName(c, cName, &mAnonymizeID, /* replaceSlashes = */ true);
CompartmentPrivate* cp = CompartmentPrivate::Get(c);
if (cp) {
if (mGetLocations) {
cp->GetLocationURI(CompartmentPrivate::LocationHintAddon,
getter_AddRefs(extras->location));
}
// Note: cannot use amIAddonManager implementation at this point,
// as it is a JS service and the JS heap is currently not idle.
// Otherwise, we could have computed the add-on id at this point.
extras->sizeOfXPCPrivate = cp->SizeOfIncludingThis(mallocSizeOf_);
}
// Get the compartment's global.
nsXPConnect* xpc = nsXPConnect::XPConnect();
AutoSafeJSContext cx;
bool needZone = true;
RootedObject global(cx, JS_GetGlobalForCompartmentOrNull(cx, c));
if (global) {
// Need to enter the compartment, otherwise GetNativeOfWrapper()
// might crash.
JSAutoCompartment ac(cx, global);
nsISupports* native = xpc->GetNativeOfWrapper(cx, global);
if (nsCOMPtr<nsPIDOMWindow> piwindow = do_QueryInterface(native)) {
// The global is a |window| object. Use the path prefix that
// we should have already created for it.
if (mWindowPaths->Get(piwindow->WindowID(),
&extras->jsPathPrefix)) {
extras->domPathPrefix.Assign(extras->jsPathPrefix);
extras->domPathPrefix.AppendLiteral("/dom/");
extras->jsPathPrefix.AppendLiteral("/js-");
needZone = false;
} else {
extras->jsPathPrefix.AssignLiteral("explicit/js-non-window/zones/");
extras->domPathPrefix.AssignLiteral("explicit/dom/unknown-window-global?!/");
}
} else {
extras->jsPathPrefix.AssignLiteral("explicit/js-non-window/zones/");
extras->domPathPrefix.AssignLiteral("explicit/dom/non-window-global?!/");
}
} else {
extras->jsPathPrefix.AssignLiteral("explicit/js-non-window/zones/");
extras->domPathPrefix.AssignLiteral("explicit/dom/no-global?!/");
}
if (needZone)
extras->jsPathPrefix += nsPrintfCString("zone(0x%p)/", (void*)js::GetCompartmentZone(c));
extras->jsPathPrefix += NS_LITERAL_CSTRING("compartment(") + cName + NS_LITERAL_CSTRING(")/");
// extras->jsPathPrefix is used for almost all the compartment-specific
// reports. At this point it has the form
// "<something>compartment(<cname>)/".
//
// extras->domPathPrefix is used for DOM orphan nodes, which are
// counted by the JS reporter but reported as part of the DOM
// measurements. At this point it has the form "<something>/dom/" if
// this compartment belongs to an nsGlobalWindow, and
// "explicit/dom/<something>?!/" otherwise (in which case it shouldn't
// be used, because non-nsGlobalWindow compartments shouldn't have
// orphan DOM nodes).
MOZ_ASSERT(StartsWithExplicit(extras->jsPathPrefix));
MOZ_ASSERT(StartsWithExplicit(extras->domPathPrefix));
cstats->extra = extras;
}
};
nsresult
JSReporter::CollectReports(WindowPaths* windowPaths,
WindowPaths* topWindowPaths,
nsIMemoryReporterCallback* cb,
nsISupports* closure,
bool anonymize)
{
XPCJSRuntime* xpcrt = nsXPConnect::GetRuntimeInstance();
// In the first step we get all the stats and stash them in a local
// data structure. In the second step we pass all the stashed stats to
// the callback. Separating these steps is important because the
// callback may be a JS function, and executing JS while getting these
// stats seems like a bad idea.
nsCOMPtr<amIAddonManager> addonManager;
if (XRE_IsParentProcess()) {
// Only try to access the service from the main process.
addonManager = do_GetService("@mozilla.org/addons/integration;1");
}
bool getLocations = !!addonManager;
XPCJSRuntimeStats rtStats(windowPaths, topWindowPaths, getLocations,
anonymize);
OrphanReporter orphanReporter(XPCConvert::GetISupportsFromJSObject);
if (!JS::CollectRuntimeStats(xpcrt->Runtime(), &rtStats, &orphanReporter,
anonymize))
{
return NS_ERROR_FAILURE;
}
size_t xpcJSRuntimeSize = xpcrt->SizeOfIncludingThis(JSMallocSizeOf);
size_t wrappedJSSize = xpcrt->GetMultiCompartmentWrappedJSMap()->SizeOfWrappedJS(JSMallocSizeOf);
XPCWrappedNativeScope::ScopeSizeInfo sizeInfo(JSMallocSizeOf);
XPCWrappedNativeScope::AddSizeOfAllScopesIncludingThis(&sizeInfo);
mozJSComponentLoader* loader = mozJSComponentLoader::Get();
size_t jsComponentLoaderSize = loader ? loader->SizeOfIncludingThis(JSMallocSizeOf) : 0;
// This is the second step (see above). First we report stuff in the
// "explicit" tree, then we report other stuff.
nsresult rv;
size_t rtTotal = 0;
rv = xpc::ReportJSRuntimeExplicitTreeStats(rtStats,
NS_LITERAL_CSTRING("explicit/js-non-window/"),
addonManager, cb, closure,
anonymize, &rtTotal);
NS_ENSURE_SUCCESS(rv, rv);
// Report the sums of the compartment numbers.
xpc::CompartmentStatsExtras cExtrasTotal;
cExtrasTotal.jsPathPrefix.AssignLiteral("js-main-runtime/compartments/");
cExtrasTotal.domPathPrefix.AssignLiteral("window-objects/dom/");
rv = ReportCompartmentStats(rtStats.cTotals, cExtrasTotal, addonManager,
cb, closure);
NS_ENSURE_SUCCESS(rv, rv);
xpc::ZoneStatsExtras zExtrasTotal;
zExtrasTotal.pathPrefix.AssignLiteral("js-main-runtime/zones/");
rv = ReportZoneStats(rtStats.zTotals, zExtrasTotal, cb, closure, anonymize);
NS_ENSURE_SUCCESS(rv, rv);
// Report the sum of the runtime/ numbers.
REPORT_BYTES(NS_LITERAL_CSTRING("js-main-runtime/runtime"),
KIND_OTHER, rtTotal,
"The sum of all measurements under 'explicit/js-non-window/runtime/'.");
// Report the numbers for memory outside of compartments.
REPORT_BYTES(NS_LITERAL_CSTRING("js-main-runtime/gc-heap/unused-chunks"),
KIND_OTHER, rtStats.gcHeapUnusedChunks,
"The same as 'explicit/js-non-window/gc-heap/unused-chunks'.");
REPORT_BYTES(NS_LITERAL_CSTRING("js-main-runtime/gc-heap/unused-arenas"),
KIND_OTHER, rtStats.gcHeapUnusedArenas,
"The same as 'explicit/js-non-window/gc-heap/unused-arenas'.");
REPORT_BYTES(NS_LITERAL_CSTRING("js-main-runtime/gc-heap/chunk-admin"),
KIND_OTHER, rtStats.gcHeapChunkAdmin,
"The same as 'explicit/js-non-window/gc-heap/chunk-admin'.");
// Report a breakdown of the committed GC space.
REPORT_BYTES(NS_LITERAL_CSTRING("js-main-runtime-gc-heap-committed/unused/chunks"),
KIND_OTHER, rtStats.gcHeapUnusedChunks,
"The same as 'explicit/js-non-window/gc-heap/unused-chunks'.");
REPORT_BYTES(NS_LITERAL_CSTRING("js-main-runtime-gc-heap-committed/unused/arenas"),
KIND_OTHER, rtStats.gcHeapUnusedArenas,
"The same as 'explicit/js-non-window/gc-heap/unused-arenas'.");
REPORT_BYTES(NS_LITERAL_CSTRING("js-main-runtime-gc-heap-committed/unused/gc-things/objects"),
KIND_OTHER, rtStats.zTotals.unusedGCThings.object,
"Unused object cells within non-empty arenas.");
REPORT_BYTES(NS_LITERAL_CSTRING("js-main-runtime-gc-heap-committed/unused/gc-things/strings"),
KIND_OTHER, rtStats.zTotals.unusedGCThings.string,
"Unused string cells within non-empty arenas.");
REPORT_BYTES(NS_LITERAL_CSTRING("js-main-runtime-gc-heap-committed/unused/gc-things/symbols"),
KIND_OTHER, rtStats.zTotals.unusedGCThings.symbol,
"Unused symbol cells within non-empty arenas.");
REPORT_BYTES(NS_LITERAL_CSTRING("js-main-runtime-gc-heap-committed/unused/gc-things/shapes"),
KIND_OTHER, rtStats.zTotals.unusedGCThings.shape,
"Unused shape cells within non-empty arenas.");
REPORT_BYTES(NS_LITERAL_CSTRING("js-main-runtime-gc-heap-committed/unused/gc-things/base-shapes"),
KIND_OTHER, rtStats.zTotals.unusedGCThings.baseShape,
"Unused base shape cells within non-empty arenas.");
REPORT_BYTES(NS_LITERAL_CSTRING("js-main-runtime-gc-heap-committed/unused/gc-things/object-groups"),
KIND_OTHER, rtStats.zTotals.unusedGCThings.objectGroup,
"Unused object group cells within non-empty arenas.");
REPORT_BYTES(NS_LITERAL_CSTRING("js-main-runtime-gc-heap-committed/unused/gc-things/scripts"),
KIND_OTHER, rtStats.zTotals.unusedGCThings.script,
"Unused script cells within non-empty arenas.");
REPORT_BYTES(NS_LITERAL_CSTRING("js-main-runtime-gc-heap-committed/unused/gc-things/lazy-scripts"),
KIND_OTHER, rtStats.zTotals.unusedGCThings.lazyScript,
"Unused lazy script cells within non-empty arenas.");
REPORT_BYTES(NS_LITERAL_CSTRING("js-main-runtime-gc-heap-committed/unused/gc-things/jitcode"),
KIND_OTHER, rtStats.zTotals.unusedGCThings.jitcode,
"Unused jitcode cells within non-empty arenas.");
REPORT_BYTES(NS_LITERAL_CSTRING("js-main-runtime-gc-heap-committed/used/chunk-admin"),
KIND_OTHER, rtStats.gcHeapChunkAdmin,
"The same as 'explicit/js-non-window/gc-heap/chunk-admin'.");
REPORT_BYTES(NS_LITERAL_CSTRING("js-main-runtime-gc-heap-committed/used/arena-admin"),
KIND_OTHER, rtStats.zTotals.gcHeapArenaAdmin,
"The same as 'js-main-runtime/zones/gc-heap-arena-admin'.");
size_t gcThingTotal = 0;
MREPORT_BYTES(NS_LITERAL_CSTRING("js-main-runtime-gc-heap-committed/used/gc-things/objects"),
KIND_OTHER, rtStats.cTotals.classInfo.objectsGCHeap,
"Used object cells.");
MREPORT_BYTES(NS_LITERAL_CSTRING("js-main-runtime-gc-heap-committed/used/gc-things/strings"),
KIND_OTHER, rtStats.zTotals.stringInfo.sizeOfLiveGCThings(),
"Used string cells.");
MREPORT_BYTES(NS_LITERAL_CSTRING("js-main-runtime-gc-heap-committed/used/gc-things/symbols"),
KIND_OTHER, rtStats.zTotals.symbolsGCHeap,
"Used symbol cells.");
MREPORT_BYTES(NS_LITERAL_CSTRING("js-main-runtime-gc-heap-committed/used/gc-things/shapes"),
KIND_OTHER,
rtStats.cTotals.classInfo.shapesGCHeapTree + rtStats.cTotals.classInfo.shapesGCHeapDict,
"Used shape cells.");
MREPORT_BYTES(NS_LITERAL_CSTRING("js-main-runtime-gc-heap-committed/used/gc-things/base-shapes"),
KIND_OTHER, rtStats.cTotals.classInfo.shapesGCHeapBase,
"Used base shape cells.");
MREPORT_BYTES(NS_LITERAL_CSTRING("js-main-runtime-gc-heap-committed/used/gc-things/object-groups"),
KIND_OTHER, rtStats.zTotals.objectGroupsGCHeap,
"Used object group cells.");
MREPORT_BYTES(NS_LITERAL_CSTRING("js-main-runtime-gc-heap-committed/used/gc-things/scripts"),
KIND_OTHER, rtStats.cTotals.scriptsGCHeap,
"Used script cells.");
MREPORT_BYTES(NS_LITERAL_CSTRING("js-main-runtime-gc-heap-committed/used/gc-things/lazy-scripts"),
KIND_OTHER, rtStats.zTotals.lazyScriptsGCHeap,
"Used lazy script cells.");
MREPORT_BYTES(NS_LITERAL_CSTRING("js-main-runtime-gc-heap-committed/used/gc-things/jitcode"),
KIND_OTHER, rtStats.zTotals.jitCodesGCHeap,
"Used jitcode cells.");
MOZ_ASSERT(gcThingTotal == rtStats.gcHeapGCThings);
// Report xpconnect.
REPORT_BYTES(NS_LITERAL_CSTRING("explicit/xpconnect/runtime"),
KIND_HEAP, xpcJSRuntimeSize,
"The XPConnect runtime.");
REPORT_BYTES(NS_LITERAL_CSTRING("explicit/xpconnect/wrappedjs"),
KIND_HEAP, wrappedJSSize,
"Wrappers used to implement XPIDL interfaces with JS.");
REPORT_BYTES(NS_LITERAL_CSTRING("explicit/xpconnect/scopes"),
KIND_HEAP, sizeInfo.mScopeAndMapSize,
"XPConnect scopes.");
REPORT_BYTES(NS_LITERAL_CSTRING("explicit/xpconnect/proto-iface-cache"),
KIND_HEAP, sizeInfo.mProtoAndIfaceCacheSize,
"Prototype and interface binding caches.");
REPORT_BYTES(NS_LITERAL_CSTRING("explicit/xpconnect/js-component-loader"),
KIND_HEAP, jsComponentLoaderSize,
"XPConnect's JS component loader.");
return NS_OK;
}
static nsresult
JSSizeOfTab(JSObject* objArg, size_t* jsObjectsSize, size_t* jsStringsSize,
size_t* jsPrivateSize, size_t* jsOtherSize)
{
JSRuntime* rt = nsXPConnect::GetRuntimeInstance()->Runtime();
JS::RootedObject obj(rt, objArg);
TabSizes sizes;
OrphanReporter orphanReporter(XPCConvert::GetISupportsFromJSObject);
NS_ENSURE_TRUE(JS::AddSizeOfTab(rt, obj, moz_malloc_size_of,
&orphanReporter, &sizes),
NS_ERROR_OUT_OF_MEMORY);
*jsObjectsSize = sizes.objects;
*jsStringsSize = sizes.strings;
*jsPrivateSize = sizes.private_;
*jsOtherSize = sizes.other;
return NS_OK;
}
} // namespace xpc
static void
AccumulateTelemetryCallback(int id, uint32_t sample, const char* key)
{
#if(0)
switch (id) {
case JS_TELEMETRY_GC_REASON:
Telemetry::Accumulate(Telemetry::GC_REASON_2, sample);
break;
case JS_TELEMETRY_GC_IS_COMPARTMENTAL:
Telemetry::Accumulate(Telemetry::GC_IS_COMPARTMENTAL, sample);
break;
case JS_TELEMETRY_GC_MS:
Telemetry::Accumulate(Telemetry::GC_MS, sample);
break;
case JS_TELEMETRY_GC_BUDGET_MS:
Telemetry::Accumulate(Telemetry::GC_BUDGET_MS, sample);
break;
case JS_TELEMETRY_GC_ANIMATION_MS:
Telemetry::Accumulate(Telemetry::GC_ANIMATION_MS, sample);
break;
case JS_TELEMETRY_GC_MAX_PAUSE_MS:
Telemetry::Accumulate(Telemetry::GC_MAX_PAUSE_MS, sample);
break;
case JS_TELEMETRY_GC_MARK_MS:
Telemetry::Accumulate(Telemetry::GC_MARK_MS, sample);
break;
case JS_TELEMETRY_GC_SWEEP_MS:
Telemetry::Accumulate(Telemetry::GC_SWEEP_MS, sample);
break;
case JS_TELEMETRY_GC_MARK_ROOTS_MS:
Telemetry::Accumulate(Telemetry::GC_MARK_ROOTS_MS, sample);
break;
case JS_TELEMETRY_GC_MARK_GRAY_MS:
Telemetry::Accumulate(Telemetry::GC_MARK_GRAY_MS, sample);
break;
case JS_TELEMETRY_GC_SLICE_MS:
Telemetry::Accumulate(Telemetry::GC_SLICE_MS, sample);
break;
case JS_TELEMETRY_GC_SLOW_PHASE:
Telemetry::Accumulate(Telemetry::GC_SLOW_PHASE, sample);
break;
case JS_TELEMETRY_GC_MMU_50:
Telemetry::Accumulate(Telemetry::GC_MMU_50, sample);
break;
case JS_TELEMETRY_GC_RESET:
Telemetry::Accumulate(Telemetry::GC_RESET, sample);
break;
case JS_TELEMETRY_GC_INCREMENTAL_DISABLED:
Telemetry::Accumulate(Telemetry::GC_INCREMENTAL_DISABLED, sample);
break;
case JS_TELEMETRY_GC_NON_INCREMENTAL:
Telemetry::Accumulate(Telemetry::GC_NON_INCREMENTAL, sample);
break;
case JS_TELEMETRY_GC_SCC_SWEEP_TOTAL_MS:
Telemetry::Accumulate(Telemetry::GC_SCC_SWEEP_TOTAL_MS, sample);
break;
case JS_TELEMETRY_GC_SCC_SWEEP_MAX_PAUSE_MS:
Telemetry::Accumulate(Telemetry::GC_SCC_SWEEP_MAX_PAUSE_MS, sample);
break;
case JS_TELEMETRY_GC_MINOR_REASON:
Telemetry::Accumulate(Telemetry::GC_MINOR_REASON, sample);
break;
case JS_TELEMETRY_GC_MINOR_REASON_LONG:
Telemetry::Accumulate(Telemetry::GC_MINOR_REASON_LONG, sample);
break;
case JS_TELEMETRY_GC_MINOR_US:
Telemetry::Accumulate(Telemetry::GC_MINOR_US, sample);
break;
case JS_TELEMETRY_DEPRECATED_LANGUAGE_EXTENSIONS_IN_CONTENT:
Telemetry::Accumulate(Telemetry::JS_DEPRECATED_LANGUAGE_EXTENSIONS_IN_CONTENT, sample);
break;
case JS_TELEMETRY_DEPRECATED_LANGUAGE_EXTENSIONS_IN_ADDONS:
Telemetry::Accumulate(Telemetry::JS_DEPRECATED_LANGUAGE_EXTENSIONS_IN_ADDONS, sample);
break;
case JS_TELEMETRY_ADDON_EXCEPTIONS:
Telemetry::Accumulate(Telemetry::JS_TELEMETRY_ADDON_EXCEPTIONS, nsDependentCString(key), sample);
break;
default:
MOZ_ASSERT_UNREACHABLE("Unexpected JS_TELEMETRY id");
}
#endif
}
static void
CompartmentNameCallback(JSRuntime* rt, JSCompartment* comp,
char* buf, size_t bufsize)
{
nsCString name;
// This is called via the JSAPI and isn't involved in memory reporting, so
// we don't need to anonymize compartment names.
int anonymizeID = 0;
GetCompartmentName(comp, name, &anonymizeID, /* replaceSlashes = */ false);
if (name.Length() >= bufsize)
name.Truncate(bufsize - 1);
memcpy(buf, name.get(), name.Length() + 1);
}
static bool
PreserveWrapper(JSContext* cx, JSObject* obj)
{
MOZ_ASSERT(cx);
MOZ_ASSERT(obj);
MOZ_ASSERT(IS_WN_REFLECTOR(obj) || mozilla::dom::IsDOMObject(obj));
return mozilla::dom::IsDOMObject(obj) && mozilla::dom::TryPreserveWrapper(obj);
}
static nsresult
ReadSourceFromFilename(JSContext* cx, const char* filename, char16_t** src, size_t* len)
{
nsresult rv;
// mozJSSubScriptLoader prefixes the filenames of the scripts it loads with
// the filename of its caller. Axe that if present.
const char* arrow;
while ((arrow = strstr(filename, " -> ")))
filename = arrow + strlen(" -> ");
// Get the URI.
nsCOMPtr<nsIURI> uri;
rv = NS_NewURI(getter_AddRefs(uri), filename);
NS_ENSURE_SUCCESS(rv, rv);
nsCOMPtr<nsIChannel> scriptChannel;
rv = NS_NewChannel(getter_AddRefs(scriptChannel),
uri,
nsContentUtils::GetSystemPrincipal(),
nsILoadInfo::SEC_ALLOW_CROSS_ORIGIN_DATA_IS_NULL,
nsIContentPolicy::TYPE_OTHER);
NS_ENSURE_SUCCESS(rv, rv);
// Only allow local reading.
nsCOMPtr<nsIURI> actualUri;
rv = scriptChannel->GetURI(getter_AddRefs(actualUri));
NS_ENSURE_SUCCESS(rv, rv);
nsCString scheme;
rv = actualUri->GetScheme(scheme);
NS_ENSURE_SUCCESS(rv, rv);
if (!scheme.EqualsLiteral("file") && !scheme.EqualsLiteral("jar"))
return NS_OK;
// Explicitly set the content type so that we don't load the
// exthandler to guess it.
scriptChannel->SetContentType(NS_LITERAL_CSTRING("text/plain"));
nsCOMPtr<nsIInputStream> scriptStream;
rv = scriptChannel->Open2(getter_AddRefs(scriptStream));
NS_ENSURE_SUCCESS(rv, rv);
uint64_t rawLen;
rv = scriptStream->Available(&rawLen);
NS_ENSURE_SUCCESS(rv, rv);
if (!rawLen)
return NS_ERROR_FAILURE;
// Technically, this should be SIZE_MAX, but we don't run on machines
// where that would be less than UINT32_MAX, and the latter is already
// well beyond a reasonable limit.
if (rawLen > UINT32_MAX)
return NS_ERROR_FILE_TOO_BIG;
// Allocate an internal buf the size of the file.
nsAutoArrayPtr<unsigned char> buf(new unsigned char[rawLen]);
if (!buf)
return NS_ERROR_OUT_OF_MEMORY;
unsigned char* ptr = buf;
unsigned char* end = ptr + rawLen;
while (ptr < end) {
uint32_t bytesRead;
rv = scriptStream->Read(reinterpret_cast<char*>(ptr), end - ptr, &bytesRead);
if (NS_FAILED(rv))
return rv;
MOZ_ASSERT(bytesRead > 0, "stream promised more bytes before EOF");
ptr += bytesRead;
}
rv = nsScriptLoader::ConvertToUTF16(scriptChannel, buf, rawLen, EmptyString(),
nullptr, *src, *len);
NS_ENSURE_SUCCESS(rv, rv);
if (!*src)
return NS_ERROR_FAILURE;
// Historically this method used JS_malloc() which updates the GC memory
// accounting. Since ConvertToUTF16() now uses js_malloc() instead we
// update the accounting manually after the fact.
JS_updateMallocCounter(cx, *len);
return NS_OK;
}
// The JS engine calls this object's 'load' member function when it needs
// the source for a chrome JS function. See the comment in the XPCJSRuntime
// constructor.
class XPCJSSourceHook: public js::SourceHook {
bool load(JSContext* cx, const char* filename, char16_t** src, size_t* length) {
*src = nullptr;
*length = 0;
if (!nsContentUtils::IsCallerChrome())
return true;
if (!filename)
return true;
nsresult rv = ReadSourceFromFilename(cx, filename, src, length);
if (NS_FAILED(rv)) {
xpc::Throw(cx, rv);
return false;
}
return true;
}
};
#ifdef XP_WIN
static size_t
GetWindowsStackSize()
{
// First, get the stack base. Because the stack grows down, this is the top
// of the stack.
const uint8_t* stackTop;
#ifdef _WIN64
PNT_TIB64 pTib = reinterpret_cast<PNT_TIB64>(NtCurrentTeb());
stackTop = reinterpret_cast<const uint8_t*>(pTib->StackBase);
#else
PNT_TIB pTib = reinterpret_cast<PNT_TIB>(NtCurrentTeb());
stackTop = reinterpret_cast<const uint8_t*>(pTib->StackBase);
#endif
// Now determine the stack bottom. Note that we can't use tib->StackLimit,
// because that's the size of the committed area and we're also interested
// in the reserved pages below that.
MEMORY_BASIC_INFORMATION mbi;
if (!VirtualQuery(&mbi, &mbi, sizeof(mbi)))
MOZ_CRASH("VirtualQuery failed");
const uint8_t* stackBottom = reinterpret_cast<const uint8_t*>(mbi.AllocationBase);
// Do some sanity checks.
size_t stackSize = size_t(stackTop - stackBottom);
MOZ_RELEASE_ASSERT(stackSize >= 1 * 1024 * 1024);
MOZ_RELEASE_ASSERT(stackSize <= 32 * 1024 * 1024);
// Subtract 40 KB (Win32) or 80 KB (Win64) to account for things like
// the guard page and large PGO stack frames.
return stackSize - 10 * sizeof(uintptr_t) * 1024;
}
#endif
static const JSWrapObjectCallbacks WrapObjectCallbacks = {
xpc::WrapperFactory::Rewrap,
xpc::WrapperFactory::PrepareForWrapping
};
XPCJSRuntime::XPCJSRuntime(nsXPConnect* aXPConnect)
: CycleCollectedJSRuntime(nullptr, JS::DefaultHeapMaxBytes, JS::DefaultNurseryBytes),
mJSContextStack(new XPCJSContextStack(this)),
mCallContext(nullptr),
mAutoRoots(nullptr),
mResolveName(JSID_VOID),
mResolvingWrapper(nullptr),
mWrappedJSMap(JSObject2WrappedJSMap::newMap(XPC_JS_MAP_LENGTH)),
mWrappedJSClassMap(IID2WrappedJSClassMap::newMap(XPC_JS_CLASS_MAP_LENGTH)),
mIID2NativeInterfaceMap(IID2NativeInterfaceMap::newMap(XPC_NATIVE_INTERFACE_MAP_LENGTH)),
mClassInfo2NativeSetMap(ClassInfo2NativeSetMap::newMap(XPC_NATIVE_SET_MAP_LENGTH)),
mNativeSetMap(NativeSetMap::newMap(XPC_NATIVE_SET_MAP_LENGTH)),
mThisTranslatorMap(IID2ThisTranslatorMap::newMap(XPC_THIS_TRANSLATOR_MAP_LENGTH)),
mNativeScriptableSharedMap(XPCNativeScriptableSharedMap::newMap(XPC_NATIVE_JSCLASS_MAP_LENGTH)),
mDyingWrappedNativeProtoMap(XPCWrappedNativeProtoMap::newMap(XPC_DYING_NATIVE_PROTO_MAP_LENGTH)),
mDetachedWrappedNativeProtoMap(XPCWrappedNativeProtoMap::newMap(XPC_DETACHED_NATIVE_PROTO_MAP_LENGTH)),
mGCIsRunning(false),
mNativesToReleaseArray(),
mDoingFinalization(false),
mVariantRoots(nullptr),
mWrappedJSRoots(nullptr),
mObjectHolderRoots(nullptr),
mWatchdogManager(new WatchdogManager(this)),
mUnprivilegedJunkScope(this->Runtime(), nullptr),
mPrivilegedJunkScope(this->Runtime(), nullptr),
mCompilationScope(this->Runtime(), nullptr),
mAsyncSnowWhiteFreer(new AsyncFreeSnowWhite()),
mSlowScriptSecondHalf(false)
{
// these jsids filled in later when we have a JSContext to work with.
mStrIDs[0] = JSID_VOID;
MOZ_ASSERT(Runtime());
JSRuntime* runtime = Runtime();
auto rtPrivate = new PerThreadAtomCache();
memset(rtPrivate, 0, sizeof(PerThreadAtomCache));
JS_SetRuntimePrivate(runtime, rtPrivate);
// Unconstrain the runtime's threshold on nominal heap size, to avoid
// triggering GC too often if operating continuously near an arbitrary
// finite threshold (0xffffffff is infinity for uint32_t parameters).
// This leaves the maximum-JS_malloc-bytes threshold still in effect
// to cause period, and we hope hygienic, last-ditch GCs from within
// the GC's allocator.
JS_SetGCParameter(runtime, JSGC_MAX_BYTES, 0xffffffff);
// The JS engine permits us to set different stack limits for system code,
// trusted script, and untrusted script. We have tests that ensure that
// we can always execute 10 "heavy" (eval+with) stack frames deeper in
// privileged code. Our stack sizes vary greatly in different configurations,
// so satisfying those tests requires some care. Manual measurements of the
// number of heavy stack frames achievable gives us the following rough data,
// ordered by the effective categories in which they are grouped in the
// JS_SetNativeStackQuota call (which predates this analysis).
//
// (NB: These numbers may have drifted recently - see bug 938429)
// OSX 64-bit Debug: 7MB stack, 636 stack frames => ~11.3k per stack frame
// OSX64 Opt: 7MB stack, 2440 stack frames => ~3k per stack frame
//
// Linux 32-bit Debug: 2MB stack, 426 stack frames => ~4.8k per stack frame
// Linux 64-bit Debug: 4MB stack, 455 stack frames => ~9.0k per stack frame
//
// Windows (Opt+Debug): 900K stack, 235 stack frames => ~3.4k per stack frame
//
// Linux 32-bit Opt: 1MB stack, 272 stack frames => ~3.8k per stack frame
// Linux 64-bit Opt: 2MB stack, 316 stack frames => ~6.5k per stack frame
//
// We tune the trusted/untrusted quotas for each configuration to achieve our
// invariants while attempting to minimize overhead. In contrast, our buffer
// between system code and trusted script is a very unscientific 10k.
const size_t kSystemCodeBuffer = 10 * 1024;
// Our "default" stack is what we use in configurations where we don't have
// a compelling reason to do things differently. This is effectively 512KB
// on 32-bit platforms and 1MB on 64-bit platforms.
const size_t kDefaultStackQuota = 128 * sizeof(size_t) * 1024;
// Set stack sizes for different configurations. It's probably not great for
// the web to base this decision primarily on the default stack size that the
// underlying platform makes available, but that seems to be what we do. :-(
#if defined(XP_MACOSX) || defined(DARWIN)
#ifdef __ppc__
// TenFourFox has over 1GB of stack to play with, necessary due to PPC
// stack redzones and much larger prologues.
const size_t kStackQuota = 32768 * 1024;
const size_t kTrustedScriptBuffer = 16384 * 1024;
#else
// MacOS has a gargantuan default stack size of 8MB. Go wild with 7MB,
// and give trusted script 180k extra. The stack is huge on mac anyway.
const size_t kStackQuota = 7 * 1024 * 1024;
const size_t kTrustedScriptBuffer = 180 * 1024;
#endif
#elif defined(MOZ_ASAN)
// ASan requires more stack space due to red-zones, so give it double the
// default (1MB on 32-bit, 2MB on 64-bit). ASAN stack frame measurements
// were not taken at the time of this writing, so we hazard a guess that
// ASAN builds have roughly thrice the stack overhead as normal builds.
// On normal builds, the largest stack frame size we might encounter is
// 9.0k (see above), so let's use a buffer of 9.0 * 5 * 10 = 450k.
const size_t kStackQuota = 2 * kDefaultStackQuota;
const size_t kTrustedScriptBuffer = 450 * 1024;
#elif defined(XP_WIN)
// 1MB is the default stack size on Windows. We use the /STACK linker flag
// to request a larger stack, so we determine the stack size at runtime.
const size_t kStackQuota = GetWindowsStackSize();
const size_t kTrustedScriptBuffer = (sizeof(size_t) == 8) ? 180 * 1024 //win64
: 120 * 1024; //win32
// The following two configurations are linux-only. Given the numbers above,
// we use 50k and 100k trusted buffers on 32-bit and 64-bit respectively.
#elif defined(DEBUG)
// Bug 803182: account for the 4x difference in the size of js::Interpret
// between optimized and debug builds.
// XXXbholley - Then why do we only account for 2x of difference?
const size_t kStackQuota = 2 * kDefaultStackQuota;
const size_t kTrustedScriptBuffer = sizeof(size_t) * 12800;
#else
const size_t kStackQuota = kDefaultStackQuota;
const size_t kTrustedScriptBuffer = sizeof(size_t) * 12800;
#endif
// Avoid an unused variable warning on platforms where we don't use the
// default.
(void) kDefaultStackQuota;
JS_SetNativeStackQuota(runtime,
kStackQuota,
kStackQuota - kSystemCodeBuffer,
kStackQuota - kSystemCodeBuffer - kTrustedScriptBuffer);
JS_SetErrorReporter(runtime, xpc::SystemErrorReporter);
JS_SetDestroyCompartmentCallback(runtime, CompartmentDestroyedCallback);
JS_SetCompartmentNameCallback(runtime, CompartmentNameCallback);
mPrevGCSliceCallback = JS::SetGCSliceCallback(runtime, GCSliceCallback);
JS_AddFinalizeCallback(runtime, FinalizeCallback, nullptr);
JS_AddWeakPointerZoneGroupCallback(runtime, WeakPointerZoneGroupCallback, this);
JS_AddWeakPointerCompartmentCallback(runtime, WeakPointerCompartmentCallback, this);
JS_SetWrapObjectCallbacks(runtime, &WrapObjectCallbacks);
js::SetPreserveWrapperCallback(runtime, PreserveWrapper);
#ifdef MOZ_ENABLE_PROFILER_SPS
if (PseudoStack* stack = mozilla_get_pseudo_stack())
stack->sampleRuntime(runtime);
#endif
//JS_SetAccumulateTelemetryCallback(runtime, AccumulateTelemetryCallback);
js::SetScriptEnvironmentPreparer(runtime, &mEnvironmentPreparer);
js::SetActivityCallback(runtime, ActivityCallback, this);
JS_SetInterruptCallback(runtime, InterruptCallback);
js::SetWindowProxyClass(runtime, &OuterWindowProxyClass);
// The JS engine needs to keep the source code around in order to implement
// Function.prototype.toSource(). It'd be nice to not have to do this for
// chrome code and simply stub out requests for source on it. Life is not so
// easy, unfortunately. Nobody relies on chrome toSource() working in core
// browser code, but chrome tests use it. The worst offenders are addons,
// which like to monkeypatch chrome functions by calling toSource() on them
// and using regular expressions to modify them. We avoid keeping most browser
// JS source code in memory by setting LAZY_SOURCE on JS::CompileOptions when
// compiling some chrome code. This causes the JS engine not save the source
// code in memory. When the JS engine is asked to provide the source for a
// function compiled with LAZY_SOURCE, it calls SourceHook to load it.
///
// Note we do have to retain the source code in memory for scripts compiled in
// isRunOnce mode and compiled function bodies (from
// JS::CompileFunction). In practice, this means content scripts and event
// handlers.
UniquePtr<XPCJSSourceHook> hook(new XPCJSSourceHook);
js::SetSourceHook(runtime, Move(hook));
// Set up locale information and callbacks for the newly-created runtime so
// that the various toLocaleString() methods, localeCompare(), and other
// internationalization APIs work as desired.
if (!xpc_LocalizeRuntime(runtime))
NS_RUNTIMEABORT("xpc_LocalizeRuntime failed.");
// Register memory reporters and distinguished amount functions.
RegisterStrongMemoryReporter(new JSMainRuntimeCompartmentsReporter());
RegisterStrongMemoryReporter(new JSMainRuntimeTemporaryPeakReporter());
RegisterJSMainRuntimeGCHeapDistinguishedAmount(JSMainRuntimeGCHeapDistinguishedAmount);
RegisterJSMainRuntimeTemporaryPeakDistinguishedAmount(JSMainRuntimeTemporaryPeakDistinguishedAmount);
RegisterJSMainRuntimeCompartmentsSystemDistinguishedAmount(JSMainRuntimeCompartmentsSystemDistinguishedAmount);
RegisterJSMainRuntimeCompartmentsUserDistinguishedAmount(JSMainRuntimeCompartmentsUserDistinguishedAmount);
mozilla::RegisterJSSizeOfTab(JSSizeOfTab);
// Watch for the JS boolean options.
ReloadPrefsCallback(nullptr, this);
Preferences::RegisterCallback(ReloadPrefsCallback, JS_OPTIONS_DOT_STR, this);
}
// static
XPCJSRuntime*
XPCJSRuntime::newXPCJSRuntime(nsXPConnect* aXPConnect)
{
NS_PRECONDITION(aXPConnect,"bad param");
XPCJSRuntime* self = new XPCJSRuntime(aXPConnect);
if (self &&
self->Runtime() &&
self->GetMultiCompartmentWrappedJSMap() &&
self->GetWrappedJSClassMap() &&
self->GetIID2NativeInterfaceMap() &&
self->GetClassInfo2NativeSetMap() &&
self->GetNativeSetMap() &&
self->GetThisTranslatorMap() &&
self->GetNativeScriptableSharedMap() &&
self->GetDyingWrappedNativeProtoMap() &&
self->mWatchdogManager) {
return self;
}
NS_RUNTIMEABORT("new XPCJSRuntime failed to initialize.");
delete self;
return nullptr;
}
bool
XPCJSRuntime::OnJSContextNew(JSContext* cx)
{
// If we were the first cx ever created (like the SafeJSContext), the caller
// would have had no way to enter a request. Enter one now before doing the
// rest of the cx setup.
JSAutoRequest ar(cx);
// if it is our first context then we need to generate our string ids
if (JSID_IS_VOID(mStrIDs[0])) {
RootedString str(cx);
for (unsigned i = 0; i < IDX_TOTAL_COUNT; i++) {
str = JS_AtomizeAndPinString(cx, mStrings[i]);
if (!str) {
mStrIDs[0] = JSID_VOID;
return false;
}
mStrIDs[i] = INTERNED_STRING_TO_JSID(cx, str);
mStrJSVals[i].setString(str);
}
if (!mozilla::dom::DefineStaticJSVals(cx)) {
return false;
}
}
XPCContext* xpc = new XPCContext(this, cx);
if (!xpc)
return false;
return true;
}
bool
XPCJSRuntime::DescribeCustomObjects(JSObject* obj, const js::Class* clasp,
char (&name)[72]) const
{
XPCNativeScriptableInfo* si = nullptr;
if (!IS_PROTO_CLASS(clasp)) {
return false;
}
XPCWrappedNativeProto* p =
static_cast<XPCWrappedNativeProto*>(xpc_GetJSPrivate(obj));
si = p->GetScriptableInfo();
if (!si) {
return false;
}
JS_snprintf(name, sizeof(name), "JS Object (%s - %s)",
clasp->name, si->GetJSClass()->name);
return true;
}
bool
XPCJSRuntime::NoteCustomGCThingXPCOMChildren(const js::Class* clasp, JSObject* obj,
nsCycleCollectionTraversalCallback& cb) const
{
if (clasp != &XPC_WN_Tearoff_JSClass) {
return false;
}
// A tearoff holds a strong reference to its native object
// (see XPCWrappedNative::FlatJSObjectFinalized). Its XPCWrappedNative
// will be held alive through the parent of the JSObject of the tearoff.
XPCWrappedNativeTearOff* to =
static_cast<XPCWrappedNativeTearOff*>(xpc_GetJSPrivate(obj));
NS_CYCLE_COLLECTION_NOTE_EDGE_NAME(cb, "xpc_GetJSPrivate(obj)->mNative");
cb.NoteXPCOMChild(to->GetNative());
return true;
}
void
XPCJSRuntime::BeforeProcessTask(bool aMightBlock)
{
MOZ_ASSERT(NS_IsMainThread());
// If ProcessNextEvent was called during a Promise "then" callback, we
// must process any pending microtasks before blocking in the event loop,
// otherwise we may deadlock until an event enters the queue later.
if (aMightBlock) {
if (Promise::PerformMicroTaskCheckpoint()) {
// If any microtask was processed, we post a dummy event in order to
// force the ProcessNextEvent call not to block. This is required
// to support nested event loops implemented using a pattern like
// "while (condition) thread.processNextEvent(true)", in case the
// condition is triggered here by a Promise "then" callback.
class DummyRunnable : public nsRunnable {
public:
NS_IMETHOD Run() { return NS_OK; }
};
NS_DispatchToMainThread(new DummyRunnable());
}
}
// Start the slow script timer.
mSlowScriptCheckpoint = mozilla::TimeStamp::NowLoRes();
mSlowScriptSecondHalf = false;
// As we may be entering a nested event loop, we need to
// cancel any ongoing performance measurement.
js::ResetPerformanceMonitoring(Get()->Runtime());
// Push a null JSContext so that we don't see any script during
// event processing.
PushNullJSContext();
CycleCollectedJSRuntime::BeforeProcessTask(aMightBlock);
}
void
XPCJSRuntime::AfterProcessTask(uint32_t aNewRecursionDepth)
{
// Now that we're back to the event loop, reset the slow script checkpoint.
mSlowScriptCheckpoint = mozilla::TimeStamp();
mSlowScriptSecondHalf = false;
// Call cycle collector occasionally.
MOZ_ASSERT(NS_IsMainThread());
nsJSContext::MaybePokeCC();
CycleCollectedJSRuntime::AfterProcessTask(aNewRecursionDepth);
// Now that we are certain that the event is complete,
// we can flush any ongoing performance measurement.
js::FlushPerformanceMonitoring(Get()->Runtime());
PopNullJSContext();
}
/***************************************************************************/
void
XPCJSRuntime::DebugDump(int16_t depth)
{
#ifdef DEBUG
depth--;
XPC_LOG_ALWAYS(("XPCJSRuntime @ %x", this));
XPC_LOG_INDENT();
XPC_LOG_ALWAYS(("mJSRuntime @ %x", Runtime()));
int cxCount = 0;
JSContext* iter = nullptr;
while (JS_ContextIterator(Runtime(), &iter))
++cxCount;
XPC_LOG_ALWAYS(("%d JS context(s)", cxCount));
iter = nullptr;
while (JS_ContextIterator(Runtime(), &iter)) {
XPCContext* xpc = XPCContext::GetXPCContext(iter);
XPC_LOG_INDENT();
xpc->DebugDump(depth);
XPC_LOG_OUTDENT();
}
XPC_LOG_ALWAYS(("mWrappedJSClassMap @ %x with %d wrapperclasses(s)",
mWrappedJSClassMap, mWrappedJSClassMap->Count()));
// iterate wrappersclasses...
if (depth && mWrappedJSClassMap->Count()) {
XPC_LOG_INDENT();
for (auto i = mWrappedJSClassMap->Iter(); !i.Done(); i.Next()) {
auto entry = static_cast<IID2WrappedJSClassMap::Entry*>(i.Get());
entry->value->DebugDump(depth);
}
XPC_LOG_OUTDENT();
}
// iterate wrappers...
XPC_LOG_ALWAYS(("mWrappedJSMap @ %x with %d wrappers(s)",
mWrappedJSMap, mWrappedJSMap->Count()));
if (depth && mWrappedJSMap->Count()) {
XPC_LOG_INDENT();
mWrappedJSMap->Dump(depth);
XPC_LOG_OUTDENT();
}
XPC_LOG_ALWAYS(("mIID2NativeInterfaceMap @ %x with %d interface(s)",
mIID2NativeInterfaceMap,
mIID2NativeInterfaceMap->Count()));
XPC_LOG_ALWAYS(("mClassInfo2NativeSetMap @ %x with %d sets(s)",
mClassInfo2NativeSetMap,
mClassInfo2NativeSetMap->Count()));
XPC_LOG_ALWAYS(("mThisTranslatorMap @ %x with %d translator(s)",
mThisTranslatorMap, mThisTranslatorMap->Count()));
XPC_LOG_ALWAYS(("mNativeSetMap @ %x with %d sets(s)",
mNativeSetMap, mNativeSetMap->Count()));
// iterate sets...
if (depth && mNativeSetMap->Count()) {
XPC_LOG_INDENT();
for (auto i = mNativeSetMap->Iter(); !i.Done(); i.Next()) {
auto entry = static_cast<NativeSetMap::Entry*>(i.Get());
entry->key_value->DebugDump(depth);
}
XPC_LOG_OUTDENT();
}
XPC_LOG_OUTDENT();
#endif
}
/***************************************************************************/
void
XPCRootSetElem::AddToRootSet(XPCRootSetElem** listHead)
{
MOZ_ASSERT(!mSelfp, "Must be not linked");
mSelfp = listHead;
mNext = *listHead;
if (mNext) {
MOZ_ASSERT(mNext->mSelfp == listHead, "Must be list start");
mNext->mSelfp = &mNext;
}
*listHead = this;
}
void
XPCRootSetElem::RemoveFromRootSet()
{
nsXPConnect* xpc = nsXPConnect::XPConnect();
JS::PokeGC(xpc->GetRuntime()->Runtime());
MOZ_ASSERT(mSelfp, "Must be linked");
MOZ_ASSERT(*mSelfp == this, "Link invariant");
*mSelfp = mNext;
if (mNext)
mNext->mSelfp = mSelfp;
#ifdef DEBUG
mSelfp = nullptr;
mNext = nullptr;
#endif
}
void
XPCJSRuntime::AddGCCallback(xpcGCCallback cb)
{
MOZ_ASSERT(cb, "null callback");
extraGCCallbacks.AppendElement(cb);
}
void
XPCJSRuntime::RemoveGCCallback(xpcGCCallback cb)
{
MOZ_ASSERT(cb, "null callback");
bool found = extraGCCallbacks.RemoveElement(cb);
if (!found) {
NS_ERROR("Removing a callback which was never added.");
}
}
void
XPCJSRuntime::InitSingletonScopes()
{
// This all happens very early, so we don't bother with cx pushing.
JSContext* cx = GetJSContextStack()->GetSafeJSContext();
JSAutoRequest ar(cx);
RootedValue v(cx);
nsresult rv;
// Create the Unprivileged Junk Scope.
SandboxOptions unprivilegedJunkScopeOptions;
unprivilegedJunkScopeOptions.sandboxName.AssignLiteral("XPConnect Junk Compartment");
unprivilegedJunkScopeOptions.invisibleToDebugger = true;
rv = CreateSandboxObject(cx, &v, nullptr, unprivilegedJunkScopeOptions);
MOZ_RELEASE_ASSERT(NS_SUCCEEDED(rv));
mUnprivilegedJunkScope = js::UncheckedUnwrap(&v.toObject());
// Create the Privileged Junk Scope.
SandboxOptions privilegedJunkScopeOptions;
privilegedJunkScopeOptions.sandboxName.AssignLiteral("XPConnect Privileged Junk Compartment");
privilegedJunkScopeOptions.invisibleToDebugger = true;
privilegedJunkScopeOptions.wantComponents = false;
rv = CreateSandboxObject(cx, &v, nsXPConnect::SystemPrincipal(), privilegedJunkScopeOptions);
MOZ_RELEASE_ASSERT(NS_SUCCEEDED(rv));
mPrivilegedJunkScope = js::UncheckedUnwrap(&v.toObject());
// Create the Compilation Scope.
SandboxOptions compilationScopeOptions;
compilationScopeOptions.sandboxName.AssignLiteral("XPConnect Compilation Compartment");
compilationScopeOptions.invisibleToDebugger = true;
compilationScopeOptions.discardSource = ShouldDiscardSystemSource();
rv = CreateSandboxObject(cx, &v, /* principal = */ nullptr, compilationScopeOptions);
MOZ_RELEASE_ASSERT(NS_SUCCEEDED(rv));
mCompilationScope = js::UncheckedUnwrap(&v.toObject());
}
void
XPCJSRuntime::DeleteSingletonScopes()
{
mUnprivilegedJunkScope = nullptr;
mPrivilegedJunkScope = nullptr;
mCompilationScope = nullptr;
}
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