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/* -*- Mode: C++; tab-width: 8; indent-tabs-mode: nil; c-basic-offset: 2 -*-
* vim: set ts=8 sts=2 et sw=2 tw=80:
* This Source Code Form is subject to the terms of the Mozilla Public
* License, v. 2.0. If a copy of the MPL was not distributed with this
* file, You can obtain one at http://mozilla.org/MPL/2.0/. */
#include "jit/CompileWrappers.h"
#include "gc/Heap.h"
#include "gc/Zone.h"
#include "jit/Ion.h"
#include "jit/JitRuntime.h"
#include "vm/Realm.h"
using namespace js;
using namespace js::jit;
JSRuntime* CompileRuntime::runtime() {
return reinterpret_cast<JSRuntime*>(this);
}
/* static */
CompileRuntime* CompileRuntime::get(JSRuntime* rt) {
return reinterpret_cast<CompileRuntime*>(rt);
}
#ifdef JS_GC_ZEAL
const uint32_t* CompileRuntime::addressOfGCZealModeBits() {
return runtime()->gc.addressOfZealModeBits();
}
#endif
const JitRuntime* CompileRuntime::jitRuntime() {
return runtime()->jitRuntime();
}
GeckoProfilerRuntime& CompileRuntime::geckoProfiler() {
return runtime()->geckoProfiler();
}
bool CompileRuntime::hadOutOfMemory() { return runtime()->hadOutOfMemory; }
bool CompileRuntime::profilingScripts() { return runtime()->profilingScripts; }
const JSAtomState& CompileRuntime::names() { return *runtime()->commonNames; }
const PropertyName* CompileRuntime::emptyString() {
return runtime()->emptyString;
}
const StaticStrings& CompileRuntime::staticStrings() {
return *runtime()->staticStrings;
}
const WellKnownSymbols& CompileRuntime::wellKnownSymbols() {
return *runtime()->wellKnownSymbols;
}
const JSClass* CompileRuntime::maybeWindowProxyClass() {
return runtime()->maybeWindowProxyClass();
}
const void* CompileRuntime::mainContextPtr() {
return runtime()->mainContextFromAnyThread();
}
const void* CompileRuntime::addressOfJitStackLimit() {
return runtime()->mainContextFromAnyThread()->addressOfJitStackLimit();
}
const void* CompileRuntime::addressOfInterruptBits() {
return runtime()->mainContextFromAnyThread()->addressOfInterruptBits();
}
const void* CompileRuntime::addressOfZone() {
return runtime()->mainContextFromAnyThread()->addressOfZone();
}
const void* CompileRuntime::addressOfMegamorphicCache() {
return &runtime()->caches().megamorphicCache;
}
const void* CompileRuntime::addressOfMegamorphicSetPropCache() {
return runtime()->caches().megamorphicSetPropCache.get();
}
const void* CompileRuntime::addressOfStringToAtomCache() {
return &runtime()->caches().stringToAtomCache;
}
const void* CompileRuntime::addressOfLastBufferedWholeCell() {
return runtime()->gc.addressOfLastBufferedWholeCell();
}
const void* CompileRuntime::addressOfHasSeenObjectEmulateUndefinedFuse() {
// We're merely accessing the address of the fuse here, and so we don't need
// the MainThreadData check here.
return runtime()->hasSeenObjectEmulateUndefinedFuse.refNoCheck().fuseRef();
}
bool CompileRuntime::hasSeenObjectEmulateUndefinedFuseIntact() {
// Note: This accesses the bit; this would be unsafe off-thread, however
// this should only be accessed by CompileInfo in its constructor on main
// thread and so should be safe.
//
// (This value is also checked by ref() rather than skipped like the address
// call above.)
return runtime()->hasSeenObjectEmulateUndefinedFuse.ref().intact();
}
const DOMCallbacks* CompileRuntime::DOMcallbacks() {
return runtime()->DOMcallbacks;
}
bool CompileRuntime::runtimeMatches(JSRuntime* rt) { return rt == runtime(); }
Zone* CompileZone::zone() { return reinterpret_cast<Zone*>(this); }
/* static */
CompileZone* CompileZone::get(Zone* zone) {
return reinterpret_cast<CompileZone*>(zone);
}
CompileRuntime* CompileZone::runtime() {
return CompileRuntime::get(zone()->runtimeFromAnyThread());
}
bool CompileZone::isAtomsZone() { return zone()->isAtomsZone(); }
#ifdef DEBUG
const void* CompileRuntime::addressOfIonBailAfterCounter() {
return runtime()->jitRuntime()->addressOfIonBailAfterCounter();
}
#endif
const uint32_t* CompileZone::addressOfNeedsIncrementalBarrier() {
// Cast away relaxed atomic wrapper for JIT access to barrier state.
const mozilla::Atomic<uint32_t, mozilla::Relaxed>* ptr =
zone()->addressOfNeedsIncrementalBarrier();
return reinterpret_cast<const uint32_t*>(ptr);
}
uint32_t* CompileZone::addressOfTenuredAllocCount() {
return zone()->addressOfTenuredAllocCount();
}
gc::FreeSpan** CompileZone::addressOfFreeList(gc::AllocKind allocKind) {
return zone()->arenas.addressOfFreeList(allocKind);
}
bool CompileZone::allocNurseryObjects() {
return zone()->allocNurseryObjects();
}
bool CompileZone::allocNurseryStrings() {
return zone()->allocNurseryStrings();
}
bool CompileZone::allocNurseryBigInts() {
return zone()->allocNurseryBigInts();
}
void* CompileZone::addressOfNurseryPosition() {
return zone()->runtimeFromAnyThread()->gc.addressOfNurseryPosition();
}
void* CompileZone::addressOfNurseryAllocatedSites() {
JSRuntime* rt = zone()->runtimeFromAnyThread();
return rt->gc.nursery().addressOfNurseryAllocatedSites();
}
bool CompileZone::canNurseryAllocateStrings() {
return zone()->allocNurseryStrings();
}
bool CompileZone::canNurseryAllocateBigInts() {
return zone()->allocNurseryBigInts();
}
gc::AllocSite* CompileZone::catchAllAllocSite(JS::TraceKind traceKind,
gc::CatchAllAllocSite siteKind) {
if (siteKind == gc::CatchAllAllocSite::Optimized) {
return zone()->optimizedAllocSite();
}
return zone()->unknownAllocSite(traceKind);
}
JS::Realm* CompileRealm::realm() { return reinterpret_cast<JS::Realm*>(this); }
/* static */
CompileRealm* CompileRealm::get(JS::Realm* realm) {
return reinterpret_cast<CompileRealm*>(realm);
}
CompileZone* CompileRealm::zone() { return CompileZone::get(realm()->zone()); }
CompileRuntime* CompileRealm::runtime() {
return CompileRuntime::get(realm()->runtimeFromAnyThread());
}
const mozilla::non_crypto::XorShift128PlusRNG*
CompileRealm::addressOfRandomNumberGenerator() {
return realm()->addressOfRandomNumberGenerator();
}
const JitZone* CompileZone::jitZone() { return zone()->jitZone(); }
const GlobalObject* CompileRealm::maybeGlobal() {
// This uses unsafeUnbarrieredMaybeGlobal() so as not to trigger the read
// barrier on the global from off thread. This is safe because we
// abort Ion compilation when we GC.
return realm()->unsafeUnbarrieredMaybeGlobal();
}
const uint32_t* CompileRealm::addressOfGlobalWriteBarriered() {
return &realm()->globalWriteBarriered;
}
bool CompileZone::hasRealmWithAllocMetadataBuilder() {
return zone()->hasRealmWithAllocMetadataBuilder();
}
JitCompileOptions::JitCompileOptions()
: profilerSlowAssertionsEnabled_(false),
offThreadCompilationAvailable_(false) {}
JitCompileOptions::JitCompileOptions(JSContext* cx) {
profilerSlowAssertionsEnabled_ =
cx->runtime()->geckoProfiler().enabled() &&
cx->runtime()->geckoProfiler().slowAssertionsEnabled();
offThreadCompilationAvailable_ = OffThreadCompilationAvailable(cx);
#ifdef DEBUG
ionBailAfterEnabled_ = cx->runtime()->jitRuntime()->ionBailAfterEnabled();
#endif
}
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