/* -*- 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/. */ #include "vm/EnvironmentObject-inl.h" #include "mozilla/PodOperations.h" #include "mozilla/ScopeExit.h" #include "mozilla/SizePrintfMacros.h" #include "jscompartment.h" #include "jsiter.h" #include "builtin/ModuleObject.h" #include "frontend/ParseNode.h" #include "gc/Policy.h" #include "vm/ArgumentsObject.h" #include "vm/AsyncFunction.h" #include "vm/GlobalObject.h" #include "vm/ProxyObject.h" #include "vm/Shape.h" #include "vm/Xdr.h" #include "jsatominlines.h" #include "jsobjinlines.h" #include "jsscriptinlines.h" #include "vm/Stack-inl.h" using namespace js; using namespace js::gc; using mozilla::PodZero; using mozilla::Maybe; using mozilla::Some; using mozilla::Nothing; using mozilla::MakeScopeExit; typedef Rooted RootedArgumentsObject; typedef MutableHandle MutableHandleArgumentsObject; /*****************************************************************************/ Shape* js::EnvironmentCoordinateToEnvironmentShape(JSScript* script, jsbytecode* pc) { MOZ_ASSERT(JOF_OPTYPE(JSOp(*pc)) == JOF_ENVCOORD); ScopeIter si(script->innermostScope(pc)); uint32_t hops = EnvironmentCoordinate(pc).hops(); while (true) { MOZ_ASSERT(!si.done()); if (si.hasSyntacticEnvironment()) { if (!hops) break; hops--; } si++; } return si.environmentShape(); } static const uint32_t ENV_COORDINATE_NAME_THRESHOLD = 20; void EnvironmentCoordinateNameCache::purge() { shape = nullptr; if (map.initialized()) map.finish(); } PropertyName* js::EnvironmentCoordinateName(EnvironmentCoordinateNameCache& cache, JSScript* script, jsbytecode* pc) { Shape* shape = EnvironmentCoordinateToEnvironmentShape(script, pc); if (shape != cache.shape && shape->slot() >= ENV_COORDINATE_NAME_THRESHOLD) { cache.purge(); if (cache.map.init(shape->slot())) { cache.shape = shape; Shape::Range r(shape); while (!r.empty()) { if (!cache.map.putNew(r.front().slot(), r.front().propid())) { cache.purge(); break; } r.popFront(); } } } jsid id; EnvironmentCoordinate ec(pc); if (shape == cache.shape) { EnvironmentCoordinateNameCache::Map::Ptr p = cache.map.lookup(ec.slot()); id = p->value(); } else { Shape::Range r(shape); while (r.front().slot() != ec.slot()) r.popFront(); id = r.front().propidRaw(); } /* Beware nameless destructuring formal. */ if (!JSID_IS_ATOM(id)) return script->runtimeFromAnyThread()->commonNames->empty; return JSID_TO_ATOM(id)->asPropertyName(); } JSScript* js::EnvironmentCoordinateFunctionScript(JSScript* script, jsbytecode* pc) { MOZ_ASSERT(JOF_OPTYPE(JSOp(*pc)) == JOF_ENVCOORD); ScopeIter si(script->innermostScope(pc)); uint32_t hops = EnvironmentCoordinate(pc).hops(); while (true) { if (si.hasSyntacticEnvironment()) { if (!hops) break; hops--; } si++; } if (si.kind() != ScopeKind::Function) return nullptr; return si.scope()->as().script(); } /*****************************************************************************/ CallObject* CallObject::create(JSContext* cx, HandleShape shape, HandleObjectGroup group) { MOZ_ASSERT(!group->singleton(), "passed a singleton group to create() (use createSingleton() " "instead)"); gc::AllocKind kind = gc::GetGCObjectKind(shape->numFixedSlots()); MOZ_ASSERT(CanBeFinalizedInBackground(kind, &CallObject::class_)); kind = gc::GetBackgroundAllocKind(kind); JSObject* obj = JSObject::create(cx, kind, gc::DefaultHeap, shape, group); if (!obj) return nullptr; return &obj->as(); } CallObject* CallObject::createSingleton(JSContext* cx, HandleShape shape) { gc::AllocKind kind = gc::GetGCObjectKind(shape->numFixedSlots()); MOZ_ASSERT(CanBeFinalizedInBackground(kind, &CallObject::class_)); kind = gc::GetBackgroundAllocKind(kind); RootedObjectGroup group(cx, ObjectGroup::lazySingletonGroup(cx, &class_, TaggedProto(nullptr))); if (!group) return nullptr; RootedObject obj(cx, JSObject::create(cx, kind, gc::TenuredHeap, shape, group)); if (!obj) return nullptr; MOZ_ASSERT(obj->isSingleton(), "group created inline above must be a singleton"); return &obj->as(); } /* * Create a CallObject for a JSScript that is not initialized to any particular * callsite. This object can either be initialized (with an enclosing scope and * callee) or used as a template for jit compilation. */ CallObject* CallObject::createTemplateObject(JSContext* cx, HandleScript script, HandleObject enclosing, gc::InitialHeap heap) { Rooted scope(cx, &script->bodyScope()->as()); RootedShape shape(cx, scope->environmentShape()); MOZ_ASSERT(shape->getObjectClass() == &class_); RootedObjectGroup group(cx, ObjectGroup::defaultNewGroup(cx, &class_, TaggedProto(nullptr))); if (!group) return nullptr; gc::AllocKind kind = gc::GetGCObjectKind(shape->numFixedSlots()); MOZ_ASSERT(CanBeFinalizedInBackground(kind, &class_)); kind = gc::GetBackgroundAllocKind(kind); JSObject* obj = JSObject::create(cx, kind, heap, shape, group); if (!obj) return nullptr; CallObject* callObj = &obj->as(); callObj->initEnclosingEnvironment(enclosing); if (scope->hasParameterExprs()) { // If there are parameter expressions, all parameters are lexical and // have TDZ. for (BindingIter bi(script->bodyScope()); bi; bi++) { BindingLocation loc = bi.location(); if (loc.kind() == BindingLocation::Kind::Environment && BindingKindIsLexical(bi.kind())) callObj->initSlot(loc.slot(), MagicValue(JS_UNINITIALIZED_LEXICAL)); } } return callObj; } /* * Construct a call object for the given bindings. If this is a call object * for a function invocation, callee should be the function being called. * Otherwise it must be a call object for eval of strict mode code, and callee * must be null. */ CallObject* CallObject::create(JSContext* cx, HandleFunction callee, HandleObject enclosing) { RootedScript script(cx, callee->nonLazyScript()); gc::InitialHeap heap = script->treatAsRunOnce() ? gc::TenuredHeap : gc::DefaultHeap; CallObject* callobj = CallObject::createTemplateObject(cx, script, enclosing, heap); if (!callobj) return nullptr; callobj->initFixedSlot(CALLEE_SLOT, ObjectValue(*callee)); if (script->treatAsRunOnce()) { Rooted ncallobj(cx, callobj); if (!JSObject::setSingleton(cx, ncallobj)) return nullptr; return ncallobj; } return callobj; } CallObject* CallObject::create(JSContext* cx, AbstractFramePtr frame) { MOZ_ASSERT(frame.isFunctionFrame()); assertSameCompartment(cx, frame); RootedObject envChain(cx, frame.environmentChain()); RootedFunction callee(cx, frame.callee()); CallObject* callobj = create(cx, callee, envChain); if (!callobj) return nullptr; if (!frame.script()->bodyScope()->as().hasParameterExprs()) { // If there are no defaults, copy the aliased arguments into the call // object manually. If there are defaults, bytecode is generated to do // the copying. for (PositionalFormalParameterIter fi(frame.script()); fi; fi++) { if (!fi.closedOver()) continue; callobj->setAliasedBinding(cx, fi, frame.unaliasedFormal(fi.argumentSlot(), DONT_CHECK_ALIASING)); } } return callobj; } CallObject* CallObject::createHollowForDebug(JSContext* cx, HandleFunction callee) { MOZ_ASSERT(!callee->needsCallObject()); RootedScript script(cx, callee->nonLazyScript()); Rooted scope(cx, &script->bodyScope()->as()); RootedShape shape(cx, FunctionScope::getEmptyEnvironmentShape(cx, scope->hasParameterExprs())); if (!shape) return nullptr; RootedObjectGroup group(cx, ObjectGroup::defaultNewGroup(cx, &class_, TaggedProto(nullptr))); if (!group) return nullptr; Rooted callobj(cx, create(cx, shape, group)); if (!callobj) return nullptr; // This environment's enclosing link is never used: the // DebugEnvironmentProxy that refers to this scope carries its own // enclosing link, which is what Debugger uses to construct the tree of // Debugger.Environment objects. callobj->initEnclosingEnvironment(&cx->global()->lexicalEnvironment()); callobj->initFixedSlot(CALLEE_SLOT, ObjectValue(*callee)); RootedValue optimizedOut(cx, MagicValue(JS_OPTIMIZED_OUT)); RootedId id(cx); for (Rooted bi(cx, BindingIter(script)); bi; bi++) { id = NameToId(bi.name()->asPropertyName()); if (!SetProperty(cx, callobj, id, optimizedOut)) return nullptr; } return callobj; } const Class CallObject::class_ = { "Call", JSCLASS_IS_ANONYMOUS | JSCLASS_HAS_RESERVED_SLOTS(CallObject::RESERVED_SLOTS) }; /*****************************************************************************/ /* static */ VarEnvironmentObject* VarEnvironmentObject::create(JSContext* cx, HandleShape shape, HandleObject enclosing, gc::InitialHeap heap) { MOZ_ASSERT(shape->getObjectClass() == &class_); RootedObjectGroup group(cx, ObjectGroup::defaultNewGroup(cx, &class_, TaggedProto(nullptr))); if (!group) return nullptr; gc::AllocKind kind = gc::GetGCObjectKind(shape->numFixedSlots()); MOZ_ASSERT(CanBeFinalizedInBackground(kind, &class_)); kind = gc::GetBackgroundAllocKind(kind); NativeObject* obj = MaybeNativeObject(JSObject::create(cx, kind, heap, shape, group)); if (!obj) return nullptr; MOZ_ASSERT(!obj->inDictionaryMode()); MOZ_ASSERT(obj->isDelegate()); VarEnvironmentObject* env = &obj->as(); env->initEnclosingEnvironment(enclosing); return env; } /* static */ VarEnvironmentObject* VarEnvironmentObject::create(JSContext* cx, HandleScope scope, AbstractFramePtr frame) { #ifdef DEBUG if (frame.isEvalFrame()) { MOZ_ASSERT(scope->is() && scope == frame.script()->bodyScope()); MOZ_ASSERT_IF(frame.isInterpreterFrame(), cx->interpreterFrame() == frame.asInterpreterFrame()); MOZ_ASSERT_IF(frame.isInterpreterFrame(), cx->interpreterRegs().pc == frame.script()->code()); } else { MOZ_ASSERT(frame.environmentChain()); MOZ_ASSERT_IF(frame.callee()->needsCallObject(), &frame.environmentChain()->as().callee() == frame.callee()); } #endif RootedScript script(cx, frame.script()); RootedObject envChain(cx, frame.environmentChain()); gc::InitialHeap heap = script->treatAsRunOnce() ? gc::TenuredHeap : gc::DefaultHeap; RootedShape shape(cx, scope->environmentShape()); VarEnvironmentObject* env = create(cx, shape, envChain, heap); if (!env) return nullptr; env->initScope(scope); return env; } /* static */ VarEnvironmentObject* VarEnvironmentObject::createHollowForDebug(JSContext* cx, Handle scope) { MOZ_ASSERT(!scope->hasEnvironment()); RootedShape shape(cx, VarScope::getEmptyEnvironmentShape(cx)); if (!shape) return nullptr; // This environment's enclosing link is never used: the // DebugEnvironmentProxy that refers to this scope carries its own // enclosing link, which is what Debugger uses to construct the tree of // Debugger.Environment objects. RootedObject enclosingEnv(cx, &cx->global()->lexicalEnvironment()); Rooted env(cx, create(cx, shape, enclosingEnv, gc::TenuredHeap)); if (!env) return nullptr; RootedValue optimizedOut(cx, MagicValue(JS_OPTIMIZED_OUT)); RootedId id(cx); for (Rooted bi(cx, BindingIter(scope)); bi; bi++) { id = NameToId(bi.name()->asPropertyName()); if (!SetProperty(cx, env, id, optimizedOut)) return nullptr; } env->initScope(scope); return env; } const Class VarEnvironmentObject::class_ = { "Var", JSCLASS_IS_ANONYMOUS | JSCLASS_HAS_RESERVED_SLOTS(VarEnvironmentObject::RESERVED_SLOTS) }; /*****************************************************************************/ const ObjectOps ModuleEnvironmentObject::objectOps_ = { ModuleEnvironmentObject::lookupProperty, nullptr, /* defineProperty */ ModuleEnvironmentObject::hasProperty, ModuleEnvironmentObject::getProperty, ModuleEnvironmentObject::setProperty, ModuleEnvironmentObject::getOwnPropertyDescriptor, ModuleEnvironmentObject::deleteProperty, nullptr, nullptr, /* watch/unwatch */ nullptr, /* getElements */ ModuleEnvironmentObject::enumerate, nullptr }; const Class ModuleEnvironmentObject::class_ = { "ModuleEnvironmentObject", JSCLASS_HAS_RESERVED_SLOTS(ModuleEnvironmentObject::RESERVED_SLOTS) | JSCLASS_IS_ANONYMOUS, JS_NULL_CLASS_OPS, JS_NULL_CLASS_SPEC, JS_NULL_CLASS_EXT, &ModuleEnvironmentObject::objectOps_ }; /* static */ ModuleEnvironmentObject* ModuleEnvironmentObject::create(ExclusiveContext* cx, HandleModuleObject module) { RootedScript script(cx, module->script()); RootedShape shape(cx, script->bodyScope()->as().environmentShape()); MOZ_ASSERT(shape->getObjectClass() == &class_); RootedObjectGroup group(cx, ObjectGroup::defaultNewGroup(cx, &class_, TaggedProto(nullptr))); if (!group) return nullptr; gc::AllocKind kind = gc::GetGCObjectKind(shape->numFixedSlots()); MOZ_ASSERT(CanBeFinalizedInBackground(kind, &class_)); kind = gc::GetBackgroundAllocKind(kind); JSObject* obj = JSObject::create(cx, kind, TenuredHeap, shape, group); if (!obj) return nullptr; RootedModuleEnvironmentObject env(cx, &obj->as()); env->initReservedSlot(MODULE_SLOT, ObjectValue(*module)); if (!JSObject::setSingleton(cx, env)) return nullptr; // Initialize this early so that we can manipulate the env object without // causing assertions. env->initEnclosingEnvironment(&cx->global()->lexicalEnvironment()); // Initialize all lexical bindings and imports as uninitialized. Imports // get uninitialized because they have a special TDZ for cyclic imports. for (BindingIter bi(script); bi; bi++) { BindingLocation loc = bi.location(); if (loc.kind() == BindingLocation::Kind::Environment && BindingKindIsLexical(bi.kind())) env->initSlot(loc.slot(), MagicValue(JS_UNINITIALIZED_LEXICAL)); } // It is not be possible to add or remove bindings from a module environment // after this point as module code is always strict. #ifdef DEBUG for (Shape::Range r(env->lastProperty()); !r.empty(); r.popFront()) MOZ_ASSERT(!r.front().configurable()); MOZ_ASSERT(env->lastProperty()->getObjectFlags() & BaseShape::NOT_EXTENSIBLE); MOZ_ASSERT(!env->inDictionaryMode()); #endif return env; } ModuleObject& ModuleEnvironmentObject::module() { return getReservedSlot(MODULE_SLOT).toObject().as(); } IndirectBindingMap& ModuleEnvironmentObject::importBindings() { return module().importBindings(); } bool ModuleEnvironmentObject::createImportBinding(JSContext* cx, HandleAtom importName, HandleModuleObject module, HandleAtom localName) { RootedId importNameId(cx, AtomToId(importName)); RootedId localNameId(cx, AtomToId(localName)); RootedModuleEnvironmentObject env(cx, module->environment()); if (!importBindings().putNew(cx, importNameId, env, localNameId)) { ReportOutOfMemory(cx); return false; } return true; } bool ModuleEnvironmentObject::hasImportBinding(HandlePropertyName name) { return importBindings().has(NameToId(name)); } bool ModuleEnvironmentObject::lookupImport(jsid name, ModuleEnvironmentObject** envOut, Shape** shapeOut) { return importBindings().lookup(name, envOut, shapeOut); } void ModuleEnvironmentObject::fixEnclosingEnvironmentAfterCompartmentMerge(GlobalObject& global) { setEnclosingEnvironment(&global.lexicalEnvironment()); } /* static */ bool ModuleEnvironmentObject::lookupProperty(JSContext* cx, HandleObject obj, HandleId id, MutableHandleObject objp, MutableHandleShape propp) { const IndirectBindingMap& bindings = obj->as().importBindings(); Shape* shape; ModuleEnvironmentObject* env; if (bindings.lookup(id, &env, &shape)) { objp.set(env); propp.set(shape); return true; } RootedNativeObject target(cx, &obj->as()); if (!NativeLookupOwnProperty(cx, target, id, propp)) return false; objp.set(obj); return true; } /* static */ bool ModuleEnvironmentObject::hasProperty(JSContext* cx, HandleObject obj, HandleId id, bool* foundp) { if (obj->as().importBindings().has(id)) { *foundp = true; return true; } RootedNativeObject self(cx, &obj->as()); return NativeHasProperty(cx, self, id, foundp); } /* static */ bool ModuleEnvironmentObject::getProperty(JSContext* cx, HandleObject obj, HandleValue receiver, HandleId id, MutableHandleValue vp) { const IndirectBindingMap& bindings = obj->as().importBindings(); Shape* shape; ModuleEnvironmentObject* env; if (bindings.lookup(id, &env, &shape)) { vp.set(env->getSlot(shape->slot())); return true; } RootedNativeObject self(cx, &obj->as()); return NativeGetProperty(cx, self, receiver, id, vp); } /* static */ bool ModuleEnvironmentObject::setProperty(JSContext* cx, HandleObject obj, HandleId id, HandleValue v, HandleValue receiver, JS::ObjectOpResult& result) { RootedModuleEnvironmentObject self(cx, &obj->as()); if (self->importBindings().has(id)) return result.failReadOnly(); return NativeSetProperty(cx, self, id, v, receiver, Qualified, result); } /* static */ bool ModuleEnvironmentObject::getOwnPropertyDescriptor(JSContext* cx, HandleObject obj, HandleId id, MutableHandle desc) { const IndirectBindingMap& bindings = obj->as().importBindings(); Shape* shape; ModuleEnvironmentObject* env; if (bindings.lookup(id, &env, &shape)) { desc.setAttributes(JSPROP_ENUMERATE | JSPROP_PERMANENT); desc.object().set(obj); RootedValue value(cx, env->getSlot(shape->slot())); desc.setValue(value); desc.assertComplete(); return true; } RootedNativeObject self(cx, &obj->as()); return NativeGetOwnPropertyDescriptor(cx, self, id, desc); } /* static */ bool ModuleEnvironmentObject::deleteProperty(JSContext* cx, HandleObject obj, HandleId id, ObjectOpResult& result) { return result.failCantDelete(); } /* static */ bool ModuleEnvironmentObject::enumerate(JSContext* cx, HandleObject obj, AutoIdVector& properties, bool enumerableOnly) { RootedModuleEnvironmentObject self(cx, &obj->as()); const IndirectBindingMap& bs(self->importBindings()); MOZ_ASSERT(properties.length() == 0); size_t count = bs.count() + self->slotSpan() - RESERVED_SLOTS; if (!properties.reserve(count)) { ReportOutOfMemory(cx); return false; } bs.forEachExportedName([&] (jsid name) { properties.infallibleAppend(name); }); for (Shape::Range r(self->lastProperty()); !r.empty(); r.popFront()) properties.infallibleAppend(r.front().propid()); MOZ_ASSERT(properties.length() == count); return true; } /*****************************************************************************/ WithEnvironmentObject* WithEnvironmentObject::create(JSContext* cx, HandleObject object, HandleObject enclosing, Handle scope) { Rooted obj(cx); obj = NewObjectWithNullTaggedProto(cx, GenericObject, BaseShape::DELEGATE); if (!obj) return nullptr; Value thisv = GetThisValue(object); obj->initEnclosingEnvironment(enclosing); obj->initReservedSlot(OBJECT_SLOT, ObjectValue(*object)); obj->initReservedSlot(THIS_SLOT, thisv); if (scope) obj->initReservedSlot(SCOPE_SLOT, PrivateGCThingValue(scope)); else obj->initReservedSlot(SCOPE_SLOT, NullValue()); return obj; } WithEnvironmentObject* WithEnvironmentObject::createNonSyntactic(JSContext* cx, HandleObject object, HandleObject enclosing) { return create(cx, object, enclosing, nullptr); } static inline bool IsUnscopableDotName(JSContext* cx, HandleId id) { return JSID_IS_ATOM(id, cx->names().dotThis) || JSID_IS_ATOM(id, cx->names().dotGenerator); } /* Implements ES6 8.1.1.2.1 HasBinding steps 7-9. */ static bool CheckUnscopables(JSContext *cx, HandleObject obj, HandleId id, bool *scopable) { RootedId unscopablesId(cx, SYMBOL_TO_JSID(cx->wellKnownSymbols() .get(JS::SymbolCode::unscopables))); RootedValue v(cx); if (!GetProperty(cx, obj, obj, unscopablesId, &v)) return false; if (v.isObject()) { RootedObject unscopablesObj(cx, &v.toObject()); if (!GetProperty(cx, unscopablesObj, unscopablesObj, id, &v)) return false; *scopable = !ToBoolean(v); } else { *scopable = true; } return true; } static bool with_LookupProperty(JSContext* cx, HandleObject obj, HandleId id, MutableHandleObject objp, MutableHandleShape propp) { // SpiderMonkey-specific: consider internal '.generator' and '.this' names // to be unscopable. if (IsUnscopableDotName(cx, id)) { objp.set(nullptr); propp.set(nullptr); return true; } RootedObject actual(cx, &obj->as().object()); if (!LookupProperty(cx, actual, id, objp, propp)) return false; if (propp) { bool scopable; if (!CheckUnscopables(cx, actual, id, &scopable)) return false; if (!scopable) { objp.set(nullptr); propp.set(nullptr); } } return true; } static bool with_DefineProperty(JSContext* cx, HandleObject obj, HandleId id, Handle desc, ObjectOpResult& result) { MOZ_ASSERT(!IsUnscopableDotName(cx, id)); RootedObject actual(cx, &obj->as().object()); return DefineProperty(cx, actual, id, desc, result); } static bool with_HasProperty(JSContext* cx, HandleObject obj, HandleId id, bool* foundp) { MOZ_ASSERT(!IsUnscopableDotName(cx, id)); RootedObject actual(cx, &obj->as().object()); // ES 8.1.1.2.1 step 3-5. if (!HasProperty(cx, actual, id, foundp)) return false; if (!*foundp) return true; // Steps 7-10. (Step 6 is a no-op.) return CheckUnscopables(cx, actual, id, foundp); } static bool with_GetProperty(JSContext* cx, HandleObject obj, HandleValue receiver, HandleId id, MutableHandleValue vp) { MOZ_ASSERT(!IsUnscopableDotName(cx, id)); RootedObject actual(cx, &obj->as().object()); RootedValue actualReceiver(cx, receiver); if (receiver.isObject() && &receiver.toObject() == obj) actualReceiver.setObject(*actual); return GetProperty(cx, actual, actualReceiver, id, vp); } static bool with_SetProperty(JSContext* cx, HandleObject obj, HandleId id, HandleValue v, HandleValue receiver, ObjectOpResult& result) { MOZ_ASSERT(!IsUnscopableDotName(cx, id)); RootedObject actual(cx, &obj->as().object()); RootedValue actualReceiver(cx, receiver); if (receiver.isObject() && &receiver.toObject() == obj) actualReceiver.setObject(*actual); return SetProperty(cx, actual, id, v, actualReceiver, result); } static bool with_GetOwnPropertyDescriptor(JSContext* cx, HandleObject obj, HandleId id, MutableHandle desc) { MOZ_ASSERT(!IsUnscopableDotName(cx, id)); RootedObject actual(cx, &obj->as().object()); return GetOwnPropertyDescriptor(cx, actual, id, desc); } static bool with_DeleteProperty(JSContext* cx, HandleObject obj, HandleId id, ObjectOpResult& result) { MOZ_ASSERT(!IsUnscopableDotName(cx, id)); RootedObject actual(cx, &obj->as().object()); return DeleteProperty(cx, actual, id, result); } static const ObjectOps WithEnvironmentObjectOps = { with_LookupProperty, with_DefineProperty, with_HasProperty, with_GetProperty, with_SetProperty, with_GetOwnPropertyDescriptor, with_DeleteProperty, nullptr, nullptr, /* watch/unwatch */ nullptr, /* getElements */ nullptr, /* enumerate (native enumeration of target doesn't work) */ nullptr, }; const Class WithEnvironmentObject::class_ = { "With", JSCLASS_HAS_RESERVED_SLOTS(WithEnvironmentObject::RESERVED_SLOTS) | JSCLASS_IS_ANONYMOUS, JS_NULL_CLASS_OPS, JS_NULL_CLASS_SPEC, JS_NULL_CLASS_EXT, &WithEnvironmentObjectOps }; /* static */ NonSyntacticVariablesObject* NonSyntacticVariablesObject::create(JSContext* cx) { Rooted obj(cx, NewObjectWithNullTaggedProto(cx, TenuredObject, BaseShape::DELEGATE)); if (!obj) return nullptr; MOZ_ASSERT(obj->isUnqualifiedVarObj()); if (!obj->setQualifiedVarObj(cx)) return nullptr; obj->initEnclosingEnvironment(&cx->global()->lexicalEnvironment()); return obj; } const Class NonSyntacticVariablesObject::class_ = { "NonSyntacticVariablesObject", JSCLASS_HAS_RESERVED_SLOTS(NonSyntacticVariablesObject::RESERVED_SLOTS) | JSCLASS_IS_ANONYMOUS }; /*****************************************************************************/ /* static */ LexicalEnvironmentObject* LexicalEnvironmentObject::createTemplateObject(JSContext* cx, HandleShape shape, HandleObject enclosing, gc::InitialHeap heap) { MOZ_ASSERT(shape->getObjectClass() == &LexicalEnvironmentObject::class_); RootedObjectGroup group(cx, ObjectGroup::defaultNewGroup(cx, &LexicalEnvironmentObject::class_, TaggedProto(nullptr))); if (!group) return nullptr; gc::AllocKind allocKind = gc::GetGCObjectKind(shape->numFixedSlots()); MOZ_ASSERT(CanBeFinalizedInBackground(allocKind, &LexicalEnvironmentObject::class_)); allocKind = GetBackgroundAllocKind(allocKind); RootedNativeObject obj(cx, MaybeNativeObject(JSObject::create(cx, allocKind, heap, shape, group))); if (!obj) return nullptr; MOZ_ASSERT(!obj->inDictionaryMode()); MOZ_ASSERT(obj->isDelegate()); LexicalEnvironmentObject* env = &obj->as(); if (enclosing) env->initEnclosingEnvironment(enclosing); return env; } /* static */ LexicalEnvironmentObject* LexicalEnvironmentObject::createTemplateObject(JSContext* cx, Handle scope, HandleObject enclosing, gc::InitialHeap heap) { assertSameCompartment(cx, enclosing); MOZ_ASSERT(scope->hasEnvironment()); RootedShape shape(cx, scope->environmentShape()); LexicalEnvironmentObject* env = createTemplateObject(cx, shape, enclosing, heap); if (!env) return nullptr; // All lexical bindings start off uninitialized for TDZ. uint32_t lastSlot = shape->slot(); MOZ_ASSERT(lastSlot == env->lastProperty()->slot()); for (uint32_t slot = JSSLOT_FREE(&class_); slot <= lastSlot; slot++) env->initSlot(slot, MagicValue(JS_UNINITIALIZED_LEXICAL)); env->initScopeUnchecked(scope); return env; } /* static */ LexicalEnvironmentObject* LexicalEnvironmentObject::create(JSContext* cx, Handle scope, AbstractFramePtr frame) { RootedObject enclosing(cx, frame.environmentChain()); return createTemplateObject(cx, scope, enclosing, gc::DefaultHeap); } /* static */ LexicalEnvironmentObject* LexicalEnvironmentObject::createGlobal(JSContext* cx, Handle global) { MOZ_ASSERT(global); RootedShape shape(cx, LexicalScope::getEmptyExtensibleEnvironmentShape(cx)); if (!shape) return nullptr; Rooted env(cx, LexicalEnvironmentObject::createTemplateObject(cx, shape, global, gc::TenuredHeap)); if (!env) return nullptr; if (!JSObject::setSingleton(cx, env)) return nullptr; env->initThisValue(global); return env; } /* static */ LexicalEnvironmentObject* LexicalEnvironmentObject::createNonSyntactic(JSContext* cx, HandleObject enclosing) { MOZ_ASSERT(enclosing); MOZ_ASSERT(!IsSyntacticEnvironment(enclosing)); RootedShape shape(cx, LexicalScope::getEmptyExtensibleEnvironmentShape(cx)); if (!shape) return nullptr; LexicalEnvironmentObject* env = LexicalEnvironmentObject::createTemplateObject(cx, shape, enclosing, gc::TenuredHeap); if (!env) return nullptr; env->initThisValue(enclosing); return env; } /* static */ LexicalEnvironmentObject* LexicalEnvironmentObject::createHollowForDebug(JSContext* cx, Handle scope) { MOZ_ASSERT(!scope->hasEnvironment()); RootedShape shape(cx, LexicalScope::getEmptyExtensibleEnvironmentShape(cx)); if (!shape) return nullptr; // This environment's enclosing link is never used: the // DebugEnvironmentProxy that refers to this scope carries its own // enclosing link, which is what Debugger uses to construct the tree of // Debugger.Environment objects. RootedObject enclosingEnv(cx, &cx->global()->lexicalEnvironment()); Rooted env(cx, createTemplateObject(cx, shape, enclosingEnv, gc::TenuredHeap)); if (!env) return nullptr; RootedValue optimizedOut(cx, MagicValue(JS_OPTIMIZED_OUT)); RootedId id(cx); for (Rooted bi(cx, BindingIter(scope)); bi; bi++) { id = NameToId(bi.name()->asPropertyName()); if (!SetProperty(cx, env, id, optimizedOut)) return nullptr; } if (!env->setFlags(cx, BaseShape::NOT_EXTENSIBLE, JSObject::GENERATE_SHAPE)) return nullptr; env->initScopeUnchecked(scope); return env; } /* static */ LexicalEnvironmentObject* LexicalEnvironmentObject::clone(JSContext* cx, Handle env) { Rooted scope(cx, &env->scope()); RootedObject enclosing(cx, &env->enclosingEnvironment()); Rooted copy(cx, createTemplateObject(cx, scope, enclosing, gc::TenuredHeap)); if (!copy) return nullptr; // We can't assert that the clone has the same shape, because it could // have been reshaped by PurgeEnvironmentChain. MOZ_ASSERT(env->slotSpan() == copy->slotSpan()); for (uint32_t i = JSSLOT_FREE(&class_); i < copy->slotSpan(); i++) copy->setSlot(i, env->getSlot(i)); return copy; } /* static */ LexicalEnvironmentObject* LexicalEnvironmentObject::recreate(JSContext* cx, Handle env) { Rooted scope(cx, &env->scope()); RootedObject enclosing(cx, &env->enclosingEnvironment()); return createTemplateObject(cx, scope, enclosing, gc::TenuredHeap); } bool LexicalEnvironmentObject::isExtensible() const { return nonProxyIsExtensible(); } Value LexicalEnvironmentObject::thisValue() const { MOZ_ASSERT(isExtensible()); Value v = getReservedSlot(THIS_VALUE_OR_SCOPE_SLOT); if (v.isObject()) { // If `v` is a Window, return the WindowProxy instead. We called // GetThisValue (which also does ToWindowProxyIfWindow) when storing // the value in THIS_VALUE_OR_SCOPE_SLOT, but it's possible the // WindowProxy was attached to the global *after* we set // THIS_VALUE_OR_SCOPE_SLOT. return ObjectValue(*ToWindowProxyIfWindow(&v.toObject())); } return v; } const Class LexicalEnvironmentObject::class_ = { "LexicalEnvironment", JSCLASS_HAS_RESERVED_SLOTS(LexicalEnvironmentObject::RESERVED_SLOTS) | JSCLASS_IS_ANONYMOUS, JS_NULL_CLASS_OPS, JS_NULL_CLASS_SPEC, JS_NULL_CLASS_EXT, JS_NULL_OBJECT_OPS }; /* static */ NamedLambdaObject* NamedLambdaObject::create(JSContext* cx, HandleFunction callee, HandleFunction func, HandleObject enclosing, gc::InitialHeap heap) { MOZ_ASSERT(callee->isNamedLambda()); RootedScope scope(cx, callee->nonLazyScript()->maybeNamedLambdaScope()); MOZ_ASSERT(scope && scope->environmentShape()); MOZ_ASSERT(scope->environmentShape()->slot() == lambdaSlot()); MOZ_ASSERT(!scope->environmentShape()->writable()); #ifdef DEBUG // There should be exactly one binding in the named lambda scope. BindingIter bi(scope); bi++; MOZ_ASSERT(bi.done()); #endif LexicalEnvironmentObject* obj = LexicalEnvironmentObject::createTemplateObject(cx, scope.as(), enclosing, heap); if (!obj) return nullptr; obj->initFixedSlot(lambdaSlot(), ObjectValue(*func)); return static_cast(obj); } /* static */ NamedLambdaObject* NamedLambdaObject::createTemplateObject(JSContext* cx, HandleFunction callee, gc::InitialHeap heap) { return create(cx, callee, callee, nullptr, heap); } /* static */ NamedLambdaObject* NamedLambdaObject::create(JSContext* cx, AbstractFramePtr frame) { RootedFunction fun(cx, frame.callee()); RootedObject enclosing(cx, frame.environmentChain()); return create(cx, fun, fun, enclosing, gc::DefaultHeap); } /* static */ NamedLambdaObject* NamedLambdaObject::create(JSContext* cx, AbstractFramePtr frame, HandleFunction replacement) { RootedFunction fun(cx, frame.callee()); RootedObject enclosing(cx, frame.environmentChain()); return create(cx, fun, replacement, enclosing, gc::DefaultHeap); } /* static */ size_t NamedLambdaObject::lambdaSlot() { // Named lambda environments have exactly one name. return JSSLOT_FREE(&LexicalEnvironmentObject::class_); } /* static */ RuntimeLexicalErrorObject* RuntimeLexicalErrorObject::create(JSContext* cx, HandleObject enclosing, unsigned errorNumber) { RuntimeLexicalErrorObject* obj = NewObjectWithNullTaggedProto(cx, GenericObject, BaseShape::DELEGATE); if (!obj) return nullptr; obj->initEnclosingEnvironment(enclosing); obj->initReservedSlot(ERROR_SLOT, Int32Value(int32_t(errorNumber))); return obj; } static void ReportRuntimeLexicalErrorId(JSContext* cx, unsigned errorNumber, HandleId id) { if (JSID_IS_ATOM(id)) { RootedPropertyName name(cx, JSID_TO_ATOM(id)->asPropertyName()); ReportRuntimeLexicalError(cx, errorNumber, name); return; } MOZ_CRASH("RuntimeLexicalErrorObject should only be used with property names"); } static bool lexicalError_LookupProperty(JSContext* cx, HandleObject obj, HandleId id, MutableHandleObject objp, MutableHandleShape propp) { ReportRuntimeLexicalErrorId(cx, obj->as().errorNumber(), id); return false; } static bool lexicalError_HasProperty(JSContext* cx, HandleObject obj, HandleId id, bool* foundp) { ReportRuntimeLexicalErrorId(cx, obj->as().errorNumber(), id); return false; } static bool lexicalError_GetProperty(JSContext* cx, HandleObject obj, HandleValue receiver, HandleId id, MutableHandleValue vp) { ReportRuntimeLexicalErrorId(cx, obj->as().errorNumber(), id); return false; } static bool lexicalError_SetProperty(JSContext* cx, HandleObject obj, HandleId id, HandleValue v, HandleValue receiver, ObjectOpResult& result) { ReportRuntimeLexicalErrorId(cx, obj->as().errorNumber(), id); return false; } static bool lexicalError_GetOwnPropertyDescriptor(JSContext* cx, HandleObject obj, HandleId id, MutableHandle desc) { ReportRuntimeLexicalErrorId(cx, obj->as().errorNumber(), id); return false; } static bool lexicalError_DeleteProperty(JSContext* cx, HandleObject obj, HandleId id, ObjectOpResult& result) { ReportRuntimeLexicalErrorId(cx, obj->as().errorNumber(), id); return false; } static const ObjectOps RuntimeLexicalErrorObjectObjectOps = { lexicalError_LookupProperty, nullptr, /* defineProperty */ lexicalError_HasProperty, lexicalError_GetProperty, lexicalError_SetProperty, lexicalError_GetOwnPropertyDescriptor, lexicalError_DeleteProperty, nullptr, nullptr, /* watch/unwatch */ nullptr, /* getElements */ nullptr, /* enumerate (native enumeration of target doesn't work) */ nullptr, /* this */ }; const Class RuntimeLexicalErrorObject::class_ = { "RuntimeLexicalError", JSCLASS_HAS_RESERVED_SLOTS(RuntimeLexicalErrorObject::RESERVED_SLOTS) | JSCLASS_IS_ANONYMOUS, JS_NULL_CLASS_OPS, JS_NULL_CLASS_SPEC, JS_NULL_CLASS_EXT, &RuntimeLexicalErrorObjectObjectOps }; /*****************************************************************************/ EnvironmentIter::EnvironmentIter(JSContext* cx, const EnvironmentIter& ei MOZ_GUARD_OBJECT_NOTIFIER_PARAM_IN_IMPL) : si_(cx, ei.si_.get()), env_(cx, ei.env_), frame_(ei.frame_) { MOZ_GUARD_OBJECT_NOTIFIER_INIT; } EnvironmentIter::EnvironmentIter(JSContext* cx, JSObject* env, Scope* scope MOZ_GUARD_OBJECT_NOTIFIER_PARAM_IN_IMPL) : si_(cx, ScopeIter(scope)), env_(cx, env), frame_(NullFramePtr()) { settle(); MOZ_GUARD_OBJECT_NOTIFIER_INIT; } EnvironmentIter::EnvironmentIter(JSContext* cx, AbstractFramePtr frame, jsbytecode* pc MOZ_GUARD_OBJECT_NOTIFIER_PARAM_IN_IMPL) : si_(cx, frame.script()->innermostScope(pc)), env_(cx, frame.environmentChain()), frame_(frame) { assertSameCompartment(cx, frame); settle(); MOZ_GUARD_OBJECT_NOTIFIER_INIT; } void EnvironmentIter::incrementScopeIter() { if (si_.scope()->is()) { // GlobalScopes may be syntactic or non-syntactic. Non-syntactic // GlobalScopes correspond to zero or more non-syntactic // EnvironmentsObjects followed by the global lexical scope, then the // GlobalObject or another non-EnvironmentObject object. if (!env_->is()) si_++; } else { si_++; } } void EnvironmentIter::settle() { // Check for trying to iterate a function or eval frame before the prologue has // created the CallObject, in which case we have to skip. if (frame_ && frame_.script()->initialEnvironmentShape() && !frame_.hasInitialEnvironment()) { // Skip until we're at the enclosing scope of the script. while (si_.scope() != frame_.script()->enclosingScope()) { if (env_->is() && !env_->as().isExtensible() && &env_->as().scope() == si_.scope()) { MOZ_ASSERT(si_.kind() == ScopeKind::NamedLambda || si_.kind() == ScopeKind::StrictNamedLambda); env_ = &env_->as().enclosingEnvironment(); } incrementScopeIter(); } } // Check if we have left the extent of the initial frame after we've // settled on a static scope. if (frame_ && (!si_ || si_.scope() == frame_.script()->enclosingScope())) frame_ = NullFramePtr(); #ifdef DEBUG if (si_) { if (hasSyntacticEnvironment()) { Scope* scope = si_.scope(); if (scope->is()) { MOZ_ASSERT(scope == &env_->as().scope()); } else if (scope->is()) { MOZ_ASSERT(scope->as().script() == env_->as().callee().existingScriptNonDelazifying()); } else if (scope->is()) { MOZ_ASSERT(scope == &env_->as().scope()); } else if (scope->is()) { MOZ_ASSERT(scope == &env_->as().scope()); } else if (scope->is()) { MOZ_ASSERT(scope == &env_->as().scope()); } else if (scope->is()) { MOZ_ASSERT(env_->is() || IsGlobalLexicalEnvironment(env_)); } } else if (hasNonSyntacticEnvironmentObject()) { if (env_->is()) { // The global lexical environment still encloses non-syntactic // environment objects. MOZ_ASSERT(!env_->as().isSyntactic() || env_->as().isGlobal()); } else if (env_->is()) { MOZ_ASSERT(!env_->as().isSyntactic()); } else { MOZ_ASSERT(env_->is()); } } } #endif } JSObject& EnvironmentIter::enclosingEnvironment() const { // As an engine invariant (maintained internally and asserted by Execute), // EnvironmentObjects and non-EnvironmentObjects cannot be interleaved on // the scope chain; every scope chain must start with zero or more // EnvironmentObjects and terminate with one or more // non-EnvironmentObjects (viz., GlobalObject). MOZ_ASSERT(done()); MOZ_ASSERT(!env_->is()); return *env_; } bool EnvironmentIter::hasNonSyntacticEnvironmentObject() const { // The case we're worrying about here is a NonSyntactic static scope // which has 0+ corresponding non-syntactic WithEnvironmentObject // scopes, a NonSyntacticVariablesObject, or a non-syntactic // LexicalEnvironmentObject. if (si_.kind() == ScopeKind::NonSyntactic) { MOZ_ASSERT_IF(env_->is(), !env_->as().isSyntactic()); return env_->is(); } return false; } /* static */ HashNumber MissingEnvironmentKey::hash(MissingEnvironmentKey ek) { return size_t(ek.frame_.raw()) ^ size_t(ek.scope_); } /* static */ bool MissingEnvironmentKey::match(MissingEnvironmentKey ek1, MissingEnvironmentKey ek2) { return ek1.frame_ == ek2.frame_ && ek1.scope_ == ek2.scope_; } bool LiveEnvironmentVal::needsSweep() { if (scope_) MOZ_ALWAYS_FALSE(IsAboutToBeFinalized(&scope_)); return false; } // Live EnvironmentIter values may be added to DebugEnvironments::liveEnvs, as // LiveEnvironmentVal instances. They need to have write barriers when they are added // to the hash table, but no barriers when rehashing inside GC. It's a nasty // hack, but the important thing is that LiveEnvironmentVal and MissingEnvironmentKey need to // alias each other. void LiveEnvironmentVal::staticAsserts() { static_assert(sizeof(LiveEnvironmentVal) == sizeof(MissingEnvironmentKey), "LiveEnvironmentVal must be same size of MissingEnvironmentKey"); static_assert(offsetof(LiveEnvironmentVal, scope_) == offsetof(MissingEnvironmentKey, scope_), "LiveEnvironmentVal.scope_ must alias MissingEnvironmentKey.scope_"); } /*****************************************************************************/ namespace { static void ReportOptimizedOut(JSContext* cx, HandleId id) { JSAutoByteString printable; if (ValueToPrintable(cx, IdToValue(id), &printable)) { JS_ReportErrorNumberLatin1(cx, GetErrorMessage, nullptr, JSMSG_DEBUG_OPTIMIZED_OUT, printable.ptr()); } } /* * DebugEnvironmentProxy is the handler for DebugEnvironmentProxy proxy * objects. Having a custom handler (rather than trying to reuse js::Wrapper) * gives us several important abilities: * - We want to pass the EnvironmentObject as the receiver to forwarded scope * property ops on aliased variables so that Call/Block/With ops do not all * require a 'normalization' step. * - The debug scope proxy can directly manipulate the stack frame to allow * the debugger to read/write args/locals that were otherwise unaliased. * - The debug scope proxy can store unaliased variables after the stack frame * is popped so that they may still be read/written by the debugger. * - The engine has made certain assumptions about the possible reads/writes * in a scope. DebugEnvironmentProxy allows us to prevent the debugger from * breaking those assumptions. * - The engine makes optimizations that are observable to the debugger. The * proxy can either hide these optimizations or make the situation more * clear to the debugger. An example is 'arguments'. */ class DebugEnvironmentProxyHandler : public BaseProxyHandler { enum Action { SET, GET }; enum AccessResult { ACCESS_UNALIASED, ACCESS_GENERIC, ACCESS_LOST }; /* * This function handles access to unaliased locals/formals. Since they * are unaliased, the values of these variables are not stored in the * slots of the normal CallObject and LexicalEnvironmentObject * environments and thus must be recovered from somewhere else: * + if the invocation for which the env was created is still executing, * there is a JS frame live on the stack holding the values; * + if the invocation for which the env was created finished executing: * - and there was a DebugEnvironmentProxy associated with env, then * the DebugEnvironments::onPop(Call|Lexical) handler copied out the * unaliased variables. In both cases, a dense array is created in * onPop(Call|Lexical) to hold the unaliased values and attached to * the DebugEnvironmentProxy; * - and there was not a DebugEnvironmentProxy yet associated with the * scope, then the unaliased values are lost and not recoverable. * * Callers should check accessResult for non-failure results: * - ACCESS_UNALIASED if the access was unaliased and completed * - ACCESS_GENERIC if the access was aliased or the property not found * - ACCESS_LOST if the value has been lost to the debugger and the * action is GET; if the action is SET, we assign to the * name of the variable on the environment object */ bool handleUnaliasedAccess(JSContext* cx, Handle debugEnv, Handle env, HandleId id, Action action, MutableHandleValue vp, AccessResult* accessResult) const { MOZ_ASSERT(&debugEnv->environment() == env); MOZ_ASSERT_IF(action == SET, !debugEnv->isOptimizedOut()); *accessResult = ACCESS_GENERIC; LiveEnvironmentVal* maybeLiveEnv = DebugEnvironments::hasLiveEnvironment(*env); if (env->is()) { /* Everything is aliased and stored in the environment object. */ return true; } /* Handle unaliased formals, vars, lets, and consts at function scope. */ if (env->is()) { CallObject& callobj = env->as(); RootedFunction fun(cx, &callobj.callee()); RootedScript script(cx, JSFunction::getOrCreateScript(cx, fun)); if (!script->ensureHasTypes(cx) || !script->ensureHasAnalyzedArgsUsage(cx)) return false; BindingIter bi(script); while (bi && NameToId(bi.name()->asPropertyName()) != id) bi++; if (!bi) return true; if (!bi.hasArgumentSlot()) { if (bi.closedOver()) return true; uint32_t i = bi.location().slot(); if (maybeLiveEnv) { AbstractFramePtr frame = maybeLiveEnv->frame(); if (action == GET) vp.set(frame.unaliasedLocal(i)); else frame.unaliasedLocal(i) = vp; } else if (NativeObject* snapshot = debugEnv->maybeSnapshot()) { if (action == GET) vp.set(snapshot->getDenseElement(script->numArgs() + i)); else snapshot->setDenseElement(script->numArgs() + i, vp); } else { /* The unaliased value has been lost to the debugger. */ if (action == GET) { *accessResult = ACCESS_LOST; return true; } } } else { unsigned i = bi.argumentSlot(); if (bi.closedOver()) return true; if (maybeLiveEnv) { AbstractFramePtr frame = maybeLiveEnv->frame(); if (script->argsObjAliasesFormals() && frame.hasArgsObj()) { if (action == GET) vp.set(frame.argsObj().arg(i)); else frame.argsObj().setArg(i, vp); } else { if (action == GET) vp.set(frame.unaliasedFormal(i, DONT_CHECK_ALIASING)); else frame.unaliasedFormal(i, DONT_CHECK_ALIASING) = vp; } } else if (NativeObject* snapshot = debugEnv->maybeSnapshot()) { if (action == GET) vp.set(snapshot->getDenseElement(i)); else snapshot->setDenseElement(i, vp); } else { /* The unaliased value has been lost to the debugger. */ if (action == GET) { *accessResult = ACCESS_LOST; return true; } } if (action == SET) TypeScript::SetArgument(cx, script, i, vp); } // It is possible that an optimized out value flows to this // location due to Debugger.Frame.prototype.eval operating on a // live bailed-out Baseline frame. In that case, treat the access // as lost. if (vp.isMagic() && vp.whyMagic() == JS_OPTIMIZED_OUT) *accessResult = ACCESS_LOST; else *accessResult = ACCESS_UNALIASED; return true; } /* * Handle unaliased vars in functions with parameter expressions and * lexical bindings at block scope. */ if (env->is() || env->is()) { // Currently consider all global and non-syntactic top-level lexical // bindings to be aliased. if (env->is() && env->as().isExtensible()) { MOZ_ASSERT(IsGlobalLexicalEnvironment(env) || !IsSyntacticEnvironment(env)); return true; } // Currently all vars inside eval var environments are aliased. if (env->is() && env->as().isForEval()) return true; RootedScope scope(cx, getEnvironmentScope(*env)); uint32_t firstFrameSlot; if (env->is()) firstFrameSlot = scope->as().firstFrameSlot(); else firstFrameSlot = scope->as().firstFrameSlot(); BindingIter bi(scope); while (bi && NameToId(bi.name()->asPropertyName()) != id) bi++; if (!bi) return true; BindingLocation loc = bi.location(); if (loc.kind() == BindingLocation::Kind::Environment) return true; // Named lambdas that are not closed over are lost. if (loc.kind() == BindingLocation::Kind::NamedLambdaCallee) { if (action == GET) *accessResult = ACCESS_LOST; return true; } MOZ_ASSERT(loc.kind() == BindingLocation::Kind::Frame); if (maybeLiveEnv) { AbstractFramePtr frame = maybeLiveEnv->frame(); uint32_t local = loc.slot(); MOZ_ASSERT(local < frame.script()->nfixed()); if (action == GET) vp.set(frame.unaliasedLocal(local)); else frame.unaliasedLocal(local) = vp; } else if (NativeObject* snapshot = debugEnv->maybeSnapshot()) { // Indices in the frame snapshot are offset by the first frame // slot. See DebugEnvironments::takeFrameSnapshot. MOZ_ASSERT(loc.slot() >= firstFrameSlot); uint32_t snapshotIndex = loc.slot() - firstFrameSlot; if (action == GET) vp.set(snapshot->getDenseElement(snapshotIndex)); else snapshot->setDenseElement(snapshotIndex, vp); } else { if (action == GET) { // A {Lexical,Var}EnvironmentObject whose static scope // does not have an environment shape at all is a "hollow" // block object reflected for missing block scopes. Their // slot values are lost. if (!scope->hasEnvironment()) { *accessResult = ACCESS_LOST; return true; } if (!GetProperty(cx, env, env, id, vp)) return false; } else { if (!SetProperty(cx, env, id, vp)) return false; } } // See comment above in analogous CallObject case. if (vp.isMagic() && vp.whyMagic() == JS_OPTIMIZED_OUT) *accessResult = ACCESS_LOST; else *accessResult = ACCESS_UNALIASED; return true; } /* The rest of the internal scopes do not have unaliased vars. */ MOZ_ASSERT(!IsSyntacticEnvironment(env) || env->is()); return true; } static bool isArguments(JSContext* cx, jsid id) { return id == NameToId(cx->names().arguments); } static bool isThis(JSContext* cx, jsid id) { return id == NameToId(cx->names().dotThis); } static bool isFunctionEnvironment(const JSObject& env) { return env.is(); } static bool isNonExtensibleLexicalEnvironment(const JSObject& env) { return env.is() && !env.as().isExtensible(); } static Scope* getEnvironmentScope(const JSObject& env) { if (isFunctionEnvironment(env)) return env.as().callee().nonLazyScript()->bodyScope(); if (isNonExtensibleLexicalEnvironment(env)) return &env.as().scope(); if (env.is()) return &env.as().scope(); return nullptr; } /* * In theory, every non-arrow function scope contains an 'arguments' * bindings. However, the engine only adds a binding if 'arguments' is * used in the function body. Thus, from the debugger's perspective, * 'arguments' may be missing from the list of bindings. */ static bool isMissingArgumentsBinding(EnvironmentObject& env) { return isFunctionEnvironment(env) && !env.as().callee().nonLazyScript()->argumentsHasVarBinding(); } /* * Similar to 'arguments' above, we don't add a 'this' binding to * non-arrow functions if it's not used. */ static bool isMissingThisBinding(EnvironmentObject& env) { return isFunctionEnvironmentWithThis(env) && !env.as().callee().nonLazyScript()->functionHasThisBinding(); } /* * This function checks if an arguments object needs to be created when * the debugger requests 'arguments' for a function scope where the * arguments object has been optimized away (either because the binding is * missing altogether or because !ScriptAnalysis::needsArgsObj). */ static bool isMissingArguments(JSContext* cx, jsid id, EnvironmentObject& env) { return isArguments(cx, id) && isFunctionEnvironment(env) && !env.as().callee().nonLazyScript()->needsArgsObj(); } static bool isMissingThis(JSContext* cx, jsid id, EnvironmentObject& env) { return isThis(cx, id) && isMissingThisBinding(env); } /* * Check if the value is the magic value JS_OPTIMIZED_ARGUMENTS. The * arguments analysis may have optimized out the 'arguments', and this * magic value could have propagated to other local slots. e.g., * * function f() { var a = arguments; h(); } * function h() { evalInFrame(1, "a.push(0)"); } * * where evalInFrame(N, str) means to evaluate str N frames up. * * In this case we don't know we need to recover a missing arguments * object until after we've performed the property get. */ static bool isMagicMissingArgumentsValue(JSContext* cx, EnvironmentObject& env, HandleValue v) { bool isMagic = v.isMagic() && v.whyMagic() == JS_OPTIMIZED_ARGUMENTS; #ifdef DEBUG // The |env| object here is not limited to CallObjects but may also // be lexical envs in case of the following: // // function f() { { let a = arguments; } } // // We need to check that |env|'s scope's nearest function scope has an // 'arguments' var binding. The environment chain is not sufficient: // |f| above will not have a CallObject because there are no aliased // body-level bindings. if (isMagic) { JSFunction* callee = nullptr; if (isFunctionEnvironment(env)) { callee = &env.as().callee(); } else { // We will never have a WithEnvironmentObject here because no // binding accesses on with scopes are unaliased. for (ScopeIter si(getEnvironmentScope(env)); si; si++) { if (si.kind() == ScopeKind::Function) { callee = si.scope()->as().canonicalFunction(); break; } } } MOZ_ASSERT(callee && callee->nonLazyScript()->argumentsHasVarBinding()); } #endif return isMagic; } /* * If the value of |this| is requested before the this-binding has been * initialized by JSOP_FUNCTIONTHIS, the this-binding will be |undefined|. * In that case, we have to call createMissingThis to initialize the * this-binding. * * Note that an |undefined| this-binding is perfectly valid in strict-mode * code, but that's fine: createMissingThis will do the right thing in that * case. */ static bool isMaybeUninitializedThisValue(JSContext* cx, jsid id, const Value& v) { return isThis(cx, id) && v.isUndefined(); } /* * Create a missing arguments object. If the function returns true but * argsObj is null, it means the env is dead. */ static bool createMissingArguments(JSContext* cx, EnvironmentObject& env, MutableHandleArgumentsObject argsObj) { argsObj.set(nullptr); LiveEnvironmentVal* maybeEnv = DebugEnvironments::hasLiveEnvironment(env); if (!maybeEnv) return true; argsObj.set(ArgumentsObject::createUnexpected(cx, maybeEnv->frame())); return !!argsObj; } /* * Create a missing this Value. If the function returns true but * *success is false, it means the scope is dead. */ static bool createMissingThis(JSContext* cx, EnvironmentObject& env, MutableHandleValue thisv, bool* success) { *success = false; LiveEnvironmentVal* maybeEnv = DebugEnvironments::hasLiveEnvironment(env); if (!maybeEnv) return true; if (!GetFunctionThis(cx, maybeEnv->frame(), thisv)) return false; // Update the this-argument to avoid boxing primitive |this| more // than once. maybeEnv->frame().thisArgument() = thisv; *success = true; return true; } public: static const char family; static const DebugEnvironmentProxyHandler singleton; constexpr DebugEnvironmentProxyHandler() : BaseProxyHandler(&family) {} static bool isFunctionEnvironmentWithThis(const JSObject& env) { // All functions except arrows and generator expression lambdas should // have their own this binding. return isFunctionEnvironment(env) && !env.as().callee().hasLexicalThis(); } bool getPrototypeIfOrdinary(JSContext* cx, HandleObject proxy, bool* isOrdinary, MutableHandleObject protop) const override { MOZ_CRASH("shouldn't be possible to access the prototype chain of a DebugEnvironmentProxyHandler"); } bool preventExtensions(JSContext* cx, HandleObject proxy, ObjectOpResult& result) const override { // always [[Extensible]], can't be made non-[[Extensible]], like most // proxies return result.fail(JSMSG_CANT_CHANGE_EXTENSIBILITY); } bool isExtensible(JSContext* cx, HandleObject proxy, bool* extensible) const override { // See above. *extensible = true; return true; } bool getPropertyDescriptor(JSContext* cx, HandleObject proxy, HandleId id, MutableHandle desc) const override { return getOwnPropertyDescriptor(cx, proxy, id, desc); } bool getMissingArgumentsPropertyDescriptor(JSContext* cx, Handle debugEnv, EnvironmentObject& env, MutableHandle desc) const { RootedArgumentsObject argsObj(cx); if (!createMissingArguments(cx, env, &argsObj)) return false; if (!argsObj) { JS_ReportErrorNumberASCII(cx, GetErrorMessage, nullptr, JSMSG_DEBUG_NOT_LIVE, "Debugger scope"); return false; } desc.object().set(debugEnv); desc.setAttributes(JSPROP_READONLY | JSPROP_ENUMERATE | JSPROP_PERMANENT); desc.value().setObject(*argsObj); desc.setGetter(nullptr); desc.setSetter(nullptr); return true; } bool getMissingThisPropertyDescriptor(JSContext* cx, Handle debugEnv, EnvironmentObject& env, MutableHandle desc) const { RootedValue thisv(cx); bool success; if (!createMissingThis(cx, env, &thisv, &success)) return false; if (!success) { JS_ReportErrorNumberASCII(cx, GetErrorMessage, nullptr, JSMSG_DEBUG_NOT_LIVE, "Debugger scope"); return false; } desc.object().set(debugEnv); desc.setAttributes(JSPROP_READONLY | JSPROP_ENUMERATE | JSPROP_PERMANENT); desc.value().set(thisv); desc.setGetter(nullptr); desc.setSetter(nullptr); return true; } bool getOwnPropertyDescriptor(JSContext* cx, HandleObject proxy, HandleId id, MutableHandle desc) const override { Rooted debugEnv(cx, &proxy->as()); Rooted env(cx, &debugEnv->environment()); if (isMissingArguments(cx, id, *env)) return getMissingArgumentsPropertyDescriptor(cx, debugEnv, *env, desc); if (isMissingThis(cx, id, *env)) return getMissingThisPropertyDescriptor(cx, debugEnv, *env, desc); RootedValue v(cx); AccessResult access; if (!handleUnaliasedAccess(cx, debugEnv, env, id, GET, &v, &access)) return false; switch (access) { case ACCESS_UNALIASED: if (isMagicMissingArgumentsValue(cx, *env, v)) return getMissingArgumentsPropertyDescriptor(cx, debugEnv, *env, desc); desc.object().set(debugEnv); desc.setAttributes(JSPROP_READONLY | JSPROP_ENUMERATE | JSPROP_PERMANENT); desc.value().set(v); desc.setGetter(nullptr); desc.setSetter(nullptr); return true; case ACCESS_GENERIC: return JS_GetOwnPropertyDescriptorById(cx, env, id, desc); case ACCESS_LOST: ReportOptimizedOut(cx, id); return false; default: MOZ_CRASH("bad AccessResult"); } } bool getMissingArguments(JSContext* cx, EnvironmentObject& env, MutableHandleValue vp) const { RootedArgumentsObject argsObj(cx); if (!createMissingArguments(cx, env, &argsObj)) return false; if (!argsObj) { JS_ReportErrorNumberASCII(cx, GetErrorMessage, nullptr, JSMSG_DEBUG_NOT_LIVE, "Debugger env"); return false; } vp.setObject(*argsObj); return true; } bool getMissingThis(JSContext* cx, EnvironmentObject& env, MutableHandleValue vp) const { RootedValue thisv(cx); bool success; if (!createMissingThis(cx, env, &thisv, &success)) return false; if (!success) { JS_ReportErrorNumberASCII(cx, GetErrorMessage, nullptr, JSMSG_DEBUG_NOT_LIVE, "Debugger env"); return false; } vp.set(thisv); return true; } bool get(JSContext* cx, HandleObject proxy, HandleValue receiver, HandleId id, MutableHandleValue vp) const override { Rooted debugEnv(cx, &proxy->as()); Rooted env(cx, &proxy->as().environment()); if (isMissingArguments(cx, id, *env)) return getMissingArguments(cx, *env, vp); if (isMissingThis(cx, id, *env)) return getMissingThis(cx, *env, vp); AccessResult access; if (!handleUnaliasedAccess(cx, debugEnv, env, id, GET, vp, &access)) return false; switch (access) { case ACCESS_UNALIASED: if (isMagicMissingArgumentsValue(cx, *env, vp)) return getMissingArguments(cx, *env, vp); if (isMaybeUninitializedThisValue(cx, id, vp)) return getMissingThis(cx, *env, vp); return true; case ACCESS_GENERIC: if (!GetProperty(cx, env, env, id, vp)) return false; if (isMaybeUninitializedThisValue(cx, id, vp)) return getMissingThis(cx, *env, vp); return true; case ACCESS_LOST: ReportOptimizedOut(cx, id); return false; default: MOZ_CRASH("bad AccessResult"); } } bool getMissingArgumentsMaybeSentinelValue(JSContext* cx, EnvironmentObject& env, MutableHandleValue vp) const { RootedArgumentsObject argsObj(cx); if (!createMissingArguments(cx, env, &argsObj)) return false; vp.set(argsObj ? ObjectValue(*argsObj) : MagicValue(JS_OPTIMIZED_ARGUMENTS)); return true; } bool getMissingThisMaybeSentinelValue(JSContext* cx, EnvironmentObject& env, MutableHandleValue vp) const { RootedValue thisv(cx); bool success; if (!createMissingThis(cx, env, &thisv, &success)) return false; vp.set(success ? thisv : MagicValue(JS_OPTIMIZED_OUT)); return true; } /* * Like 'get', but returns sentinel values instead of throwing on * exceptional cases. */ bool getMaybeSentinelValue(JSContext* cx, Handle debugEnv, HandleId id, MutableHandleValue vp) const { Rooted env(cx, &debugEnv->environment()); if (isMissingArguments(cx, id, *env)) return getMissingArgumentsMaybeSentinelValue(cx, *env, vp); if (isMissingThis(cx, id, *env)) return getMissingThisMaybeSentinelValue(cx, *env, vp); AccessResult access; if (!handleUnaliasedAccess(cx, debugEnv, env, id, GET, vp, &access)) return false; switch (access) { case ACCESS_UNALIASED: if (isMagicMissingArgumentsValue(cx, *env, vp)) return getMissingArgumentsMaybeSentinelValue(cx, *env, vp); if (isMaybeUninitializedThisValue(cx, id, vp)) return getMissingThisMaybeSentinelValue(cx, *env, vp); return true; case ACCESS_GENERIC: if (!GetProperty(cx, env, env, id, vp)) return false; if (isMaybeUninitializedThisValue(cx, id, vp)) return getMissingThisMaybeSentinelValue(cx, *env, vp); return true; case ACCESS_LOST: vp.setMagic(JS_OPTIMIZED_OUT); return true; default: MOZ_CRASH("bad AccessResult"); } } bool set(JSContext* cx, HandleObject proxy, HandleId id, HandleValue v, HandleValue receiver, ObjectOpResult& result) const override { Rooted debugEnv(cx, &proxy->as()); Rooted env(cx, &proxy->as().environment()); if (debugEnv->isOptimizedOut()) return Throw(cx, id, JSMSG_DEBUG_CANT_SET_OPT_ENV); AccessResult access; RootedValue valCopy(cx, v); if (!handleUnaliasedAccess(cx, debugEnv, env, id, SET, &valCopy, &access)) return false; switch (access) { case ACCESS_UNALIASED: return result.succeed(); case ACCESS_GENERIC: { RootedValue envVal(cx, ObjectValue(*env)); return SetProperty(cx, env, id, v, envVal, result); } default: MOZ_CRASH("bad AccessResult"); } } bool defineProperty(JSContext* cx, HandleObject proxy, HandleId id, Handle desc, ObjectOpResult& result) const override { Rooted env(cx, &proxy->as().environment()); bool found; if (!has(cx, proxy, id, &found)) return false; if (found) return Throw(cx, id, JSMSG_CANT_REDEFINE_PROP); return JS_DefinePropertyById(cx, env, id, desc, result); } bool ownPropertyKeys(JSContext* cx, HandleObject proxy, AutoIdVector& props) const override { Rooted env(cx, &proxy->as().environment()); if (isMissingArgumentsBinding(*env)) { if (!props.append(NameToId(cx->names().arguments))) return false; } if (isMissingThisBinding(*env)) { if (!props.append(NameToId(cx->names().dotThis))) return false; } // WithEnvironmentObject isn't a very good proxy. It doesn't have a // JSNewEnumerateOp implementation, because if it just delegated to the // target object, the object would indicate that native enumeration is // the thing to do, but native enumeration over the WithEnvironmentObject // wrapper yields no properties. So instead here we hack around the // issue: punch a hole through to the with object target, then manually // examine @@unscopables. RootedObject target(cx); bool isWith = env->is(); if (isWith) target = &env->as().object(); else target = env; if (!GetPropertyKeys(cx, target, JSITER_OWNONLY, &props)) return false; if (isWith) { size_t j = 0; for (size_t i = 0; i < props.length(); i++) { bool inScope; if (!CheckUnscopables(cx, env, props[i], &inScope)) return false; if (inScope) props[j++].set(props[i]); } if (!props.resize(j)) return false; } /* * Environments with Scopes are optimized to not contain unaliased * variables so they must be manually appended here. */ if (Scope* scope = getEnvironmentScope(*env)) { for (Rooted bi(cx, BindingIter(scope)); bi; bi++) { if (!bi.closedOver() && !props.append(NameToId(bi.name()->asPropertyName()))) return false; } } return true; } bool has(JSContext* cx, HandleObject proxy, HandleId id_, bool* bp) const override { RootedId id(cx, id_); EnvironmentObject& envObj = proxy->as().environment(); if (isArguments(cx, id) && isFunctionEnvironment(envObj)) { *bp = true; return true; } // Be careful not to look up '.this' as a normal binding below, it will // assert in with_HasProperty. if (isThis(cx, id)) { *bp = isFunctionEnvironmentWithThis(envObj); return true; } bool found; RootedObject env(cx, &envObj); if (!JS_HasPropertyById(cx, env, id, &found)) return false; if (!found) { if (Scope* scope = getEnvironmentScope(*env)) { for (BindingIter bi(scope); bi; bi++) { if (!bi.closedOver() && NameToId(bi.name()->asPropertyName()) == id) { found = true; break; } } } } *bp = found; return true; } bool delete_(JSContext* cx, HandleObject proxy, HandleId id, ObjectOpResult& result) const override { return result.fail(JSMSG_CANT_DELETE); } }; } /* anonymous namespace */ template<> bool JSObject::is() const { return IsDerivedProxyObject(this, &DebugEnvironmentProxyHandler::singleton); } const char DebugEnvironmentProxyHandler::family = 0; const DebugEnvironmentProxyHandler DebugEnvironmentProxyHandler::singleton; /* static */ DebugEnvironmentProxy* DebugEnvironmentProxy::create(JSContext* cx, EnvironmentObject& env, HandleObject enclosing) { MOZ_ASSERT(env.compartment() == cx->compartment()); MOZ_ASSERT(!enclosing->is()); RootedValue priv(cx, ObjectValue(env)); JSObject* obj = NewProxyObject(cx, &DebugEnvironmentProxyHandler::singleton, priv, nullptr /* proto */); if (!obj) return nullptr; DebugEnvironmentProxy* debugEnv = &obj->as(); debugEnv->setExtra(ENCLOSING_EXTRA, ObjectValue(*enclosing)); debugEnv->setExtra(SNAPSHOT_EXTRA, NullValue()); return debugEnv; } EnvironmentObject& DebugEnvironmentProxy::environment() const { return target()->as(); } JSObject& DebugEnvironmentProxy::enclosingEnvironment() const { return extra(ENCLOSING_EXTRA).toObject(); } ArrayObject* DebugEnvironmentProxy::maybeSnapshot() const { JSObject* obj = extra(SNAPSHOT_EXTRA).toObjectOrNull(); return obj ? &obj->as() : nullptr; } void DebugEnvironmentProxy::initSnapshot(ArrayObject& o) { MOZ_ASSERT(maybeSnapshot() == nullptr); setExtra(SNAPSHOT_EXTRA, ObjectValue(o)); } bool DebugEnvironmentProxy::isForDeclarative() const { EnvironmentObject& e = environment(); return e.is() || e.is() || e.is() || e.is(); } bool DebugEnvironmentProxy::getMaybeSentinelValue(JSContext* cx, HandleId id, MutableHandleValue vp) { Rooted self(cx, this); return DebugEnvironmentProxyHandler::singleton.getMaybeSentinelValue(cx, self, id, vp); } bool DebugEnvironmentProxy::isFunctionEnvironmentWithThis() { return DebugEnvironmentProxyHandler::isFunctionEnvironmentWithThis(environment()); } bool DebugEnvironmentProxy::isOptimizedOut() const { EnvironmentObject& e = environment(); if (DebugEnvironments::hasLiveEnvironment(e)) return false; if (e.is()) { return !e.as().isExtensible() && !e.as().scope().hasEnvironment(); } if (e.is()) { return !e.as().callee().needsCallObject() && !maybeSnapshot(); } return false; } /*****************************************************************************/ DebugEnvironments::DebugEnvironments(JSContext* cx) : proxiedEnvs(cx), missingEnvs(cx->runtime()), liveEnvs(cx->runtime()) {} DebugEnvironments::~DebugEnvironments() { MOZ_ASSERT_IF(missingEnvs.initialized(), missingEnvs.empty()); } bool DebugEnvironments::init() { return proxiedEnvs.init() && missingEnvs.init() && liveEnvs.init(); } void DebugEnvironments::mark(JSTracer* trc) { proxiedEnvs.trace(trc); } void DebugEnvironments::sweep(JSRuntime* rt) { /* * missingEnvs points to debug envs weakly so that debug envs can be * released more eagerly. */ for (MissingEnvironmentMap::Enum e(missingEnvs); !e.empty(); e.popFront()) { if (IsAboutToBeFinalized(&e.front().value())) { /* * Note that onPopCall, onPopVar, and onPopLexical rely on * missingEnvs to find environment objects that we synthesized for * the debugger's sake, and clean up the synthetic environment * objects' entries in liveEnvs. So if we remove an entry from * missingEnvs here, we must also remove the corresponding * liveEnvs entry. * * Since the DebugEnvironmentProxy is the only thing using its environment * object, and the DSO is about to be finalized, you might assume * that the synthetic SO is also about to be finalized too, and thus * the loop below will take care of things. But complex GC behavior * means that marks are only conservative approximations of * liveness; we should assume that anything could be marked. * * Thus, we must explicitly remove the entries from both liveEnvs * and missingEnvs here. */ liveEnvs.remove(&e.front().value().unbarrieredGet()->environment()); e.removeFront(); } else { MissingEnvironmentKey key = e.front().key(); if (IsForwarded(key.scope())) { key.updateScope(Forwarded(key.scope())); e.rekeyFront(key); } } } /* * Scopes can be finalized when a debugger-synthesized EnvironmentObject is * no longer reachable via its DebugEnvironmentProxy. */ liveEnvs.sweep(); } void DebugEnvironments::finish() { proxiedEnvs.clear(); } #ifdef JSGC_HASH_TABLE_CHECKS void DebugEnvironments::checkHashTablesAfterMovingGC(JSRuntime* runtime) { /* * This is called at the end of StoreBuffer::mark() to check that our * postbarriers have worked and that no hashtable keys (or values) are left * pointing into the nursery. */ proxiedEnvs.checkAfterMovingGC(); for (MissingEnvironmentMap::Range r = missingEnvs.all(); !r.empty(); r.popFront()) { CheckGCThingAfterMovingGC(r.front().key().scope()); CheckGCThingAfterMovingGC(r.front().value().get()); } for (LiveEnvironmentMap::Range r = liveEnvs.all(); !r.empty(); r.popFront()) { CheckGCThingAfterMovingGC(r.front().key()); CheckGCThingAfterMovingGC(r.front().value().scope_.get()); } } #endif /* * Unfortunately, GetDebugEnvironmentForFrame needs to work even outside debug mode * (in particular, JS_GetFrameScopeChain does not require debug mode). Since * DebugEnvironments::onPop* are only called in debuggee frames, this means we * cannot use any of the maps in DebugEnvironments. This will produce debug scope * chains that do not obey the debugger invariants but that is just fine. */ static bool CanUseDebugEnvironmentMaps(JSContext* cx) { return cx->compartment()->isDebuggee(); } DebugEnvironments* DebugEnvironments::ensureCompartmentData(JSContext* cx) { JSCompartment* c = cx->compartment(); if (c->debugEnvs) return c->debugEnvs; auto debugEnvs = cx->make_unique(cx); if (!debugEnvs || !debugEnvs->init()) { ReportOutOfMemory(cx); return nullptr; } c->debugEnvs = debugEnvs.release(); return c->debugEnvs; } /* static */ DebugEnvironmentProxy* DebugEnvironments::hasDebugEnvironment(JSContext* cx, EnvironmentObject& env) { DebugEnvironments* envs = env.compartment()->debugEnvs; if (!envs) return nullptr; if (JSObject* obj = envs->proxiedEnvs.lookup(&env)) { MOZ_ASSERT(CanUseDebugEnvironmentMaps(cx)); return &obj->as(); } return nullptr; } /* static */ bool DebugEnvironments::addDebugEnvironment(JSContext* cx, Handle env, Handle debugEnv) { MOZ_ASSERT(cx->compartment() == env->compartment()); MOZ_ASSERT(cx->compartment() == debugEnv->compartment()); if (!CanUseDebugEnvironmentMaps(cx)) return true; DebugEnvironments* envs = ensureCompartmentData(cx); if (!envs) return false; return envs->proxiedEnvs.add(cx, env, debugEnv); } /* static */ DebugEnvironmentProxy* DebugEnvironments::hasDebugEnvironment(JSContext* cx, const EnvironmentIter& ei) { MOZ_ASSERT(!ei.hasSyntacticEnvironment()); DebugEnvironments* envs = cx->compartment()->debugEnvs; if (!envs) return nullptr; if (MissingEnvironmentMap::Ptr p = envs->missingEnvs.lookup(MissingEnvironmentKey(ei))) { MOZ_ASSERT(CanUseDebugEnvironmentMaps(cx)); return p->value(); } return nullptr; } /* static */ bool DebugEnvironments::addDebugEnvironment(JSContext* cx, const EnvironmentIter& ei, Handle debugEnv) { MOZ_ASSERT(!ei.hasSyntacticEnvironment()); MOZ_ASSERT(cx->compartment() == debugEnv->compartment()); // Generators should always have environments. MOZ_ASSERT_IF(ei.scope().is(), !ei.scope().as().canonicalFunction()->isGenerator()); if (!CanUseDebugEnvironmentMaps(cx)) return true; DebugEnvironments* envs = ensureCompartmentData(cx); if (!envs) return false; MissingEnvironmentKey key(ei); MOZ_ASSERT(!envs->missingEnvs.has(key)); if (!envs->missingEnvs.put(key, ReadBarriered(debugEnv))) { ReportOutOfMemory(cx); return false; } // Only add to liveEnvs if we synthesized the debug env on a live // frame. if (ei.withinInitialFrame()) { MOZ_ASSERT(!envs->liveEnvs.has(&debugEnv->environment())); if (!envs->liveEnvs.put(&debugEnv->environment(), LiveEnvironmentVal(ei))) { ReportOutOfMemory(cx); return false; } } return true; } /* static */ void DebugEnvironments::takeFrameSnapshot(JSContext* cx, Handle debugEnv, AbstractFramePtr frame) { /* * When the JS stack frame is popped, the values of unaliased variables * are lost. If there is any debug env referring to this environment, save a * copy of the unaliased variables' values in an array for later debugger * access via DebugEnvironmentProxy::handleUnaliasedAccess. * * Note: since it is simplest for this function to be infallible, failure * in this code will be silently ignored. This does not break any * invariants since DebugEnvironmentProxy::maybeSnapshot can already be nullptr. */ // Act like no snapshot was taken if we run OOM while taking the snapshot. Rooted> vec(cx, GCVector(cx)); if (debugEnv->environment().is()) { JSScript* script = frame.script(); FunctionScope* scope = &script->bodyScope()->as(); uint32_t frameSlotCount = scope->nextFrameSlot(); MOZ_ASSERT(frameSlotCount <= script->nfixed()); // For simplicity, copy all frame slots from 0 to the frameSlotCount, // even if we don't need all of them (like in the case of a defaults // parameter scope having frame slots). uint32_t numFormals = frame.numFormalArgs(); if (!vec.resize(numFormals + frameSlotCount)) { cx->recoverFromOutOfMemory(); return; } mozilla::PodCopy(vec.begin(), frame.argv(), numFormals); for (uint32_t slot = 0; slot < frameSlotCount; slot++) vec[slot + frame.numFormalArgs()].set(frame.unaliasedLocal(slot)); /* * Copy in formals that are not aliased via the scope chain * but are aliased via the arguments object. */ if (script->analyzedArgsUsage() && script->needsArgsObj() && frame.hasArgsObj()) { for (unsigned i = 0; i < frame.numFormalArgs(); ++i) { if (script->formalLivesInArgumentsObject(i)) vec[i].set(frame.argsObj().arg(i)); } } } else { uint32_t frameSlotStart; uint32_t frameSlotEnd; if (debugEnv->environment().is()) { LexicalScope* scope = &debugEnv->environment().as().scope(); frameSlotStart = scope->firstFrameSlot(); frameSlotEnd = scope->nextFrameSlot(); } else { VarEnvironmentObject* env = &debugEnv->environment().as(); if (frame.isFunctionFrame()) { VarScope* scope = &env->scope().as(); frameSlotStart = scope->firstFrameSlot(); frameSlotEnd = scope->nextFrameSlot(); } else { EvalScope* scope = &env->scope().as(); MOZ_ASSERT(scope == frame.script()->bodyScope()); frameSlotStart = 0; frameSlotEnd = scope->nextFrameSlot(); } } uint32_t frameSlotCount = frameSlotEnd - frameSlotStart; MOZ_ASSERT(frameSlotCount <= frame.script()->nfixed()); if (!vec.resize(frameSlotCount)) { cx->recoverFromOutOfMemory(); return; } for (uint32_t slot = frameSlotStart; slot < frameSlotCount; slot++) vec[slot - frameSlotStart].set(frame.unaliasedLocal(slot)); } if (vec.length() == 0) return; /* * Use a dense array as storage (since proxies do not have trace * hooks). This array must not escape into the wild. */ RootedArrayObject snapshot(cx, NewDenseCopiedArray(cx, vec.length(), vec.begin())); if (!snapshot) { cx->recoverFromOutOfMemory(); return; } debugEnv->initSnapshot(*snapshot); } /* static */ void DebugEnvironments::onPopCall(JSContext* cx, AbstractFramePtr frame) { assertSameCompartment(cx, frame); DebugEnvironments* envs = cx->compartment()->debugEnvs; if (!envs) return; Rooted debugEnv(cx, nullptr); FunctionScope* funScope = &frame.script()->bodyScope()->as(); if (funScope->hasEnvironment()) { MOZ_ASSERT(frame.callee()->needsCallObject()); /* * The frame may be observed before the prologue has created the * CallObject. See EnvironmentIter::settle. */ if (!frame.environmentChain()->is()) return; if (frame.callee()->isGenerator()) return; CallObject& callobj = frame.environmentChain()->as(); envs->liveEnvs.remove(&callobj); if (JSObject* obj = envs->proxiedEnvs.lookup(&callobj)) debugEnv = &obj->as(); } else { MissingEnvironmentKey key(frame, funScope); if (MissingEnvironmentMap::Ptr p = envs->missingEnvs.lookup(key)) { debugEnv = p->value(); envs->liveEnvs.remove(&debugEnv->environment().as()); envs->missingEnvs.remove(p); } } if (debugEnv) DebugEnvironments::takeFrameSnapshot(cx, debugEnv, frame); } void DebugEnvironments::onPopLexical(JSContext* cx, AbstractFramePtr frame, jsbytecode* pc) { assertSameCompartment(cx, frame); DebugEnvironments* envs = cx->compartment()->debugEnvs; if (!envs) return; EnvironmentIter ei(cx, frame, pc); onPopLexical(cx, ei); } template void DebugEnvironments::onPopGeneric(JSContext* cx, const EnvironmentIter& ei) { DebugEnvironments* envs = cx->compartment()->debugEnvs; if (!envs) return; MOZ_ASSERT(ei.withinInitialFrame()); MOZ_ASSERT(ei.scope().is()); Rooted env(cx); if (MissingEnvironmentMap::Ptr p = envs->missingEnvs.lookup(MissingEnvironmentKey(ei))) { env = &p->value()->environment().as(); envs->missingEnvs.remove(p); } else if (ei.hasSyntacticEnvironment()) { env = &ei.environment().as(); } if (env) { envs->liveEnvs.remove(env); if (JSObject* obj = envs->proxiedEnvs.lookup(env)) { Rooted debugEnv(cx, &obj->as()); DebugEnvironments::takeFrameSnapshot(cx, debugEnv, ei.initialFrame()); } } } void DebugEnvironments::onPopLexical(JSContext* cx, const EnvironmentIter& ei) { onPopGeneric(cx, ei); } void DebugEnvironments::onPopVar(JSContext* cx, AbstractFramePtr frame, jsbytecode* pc) { assertSameCompartment(cx, frame); DebugEnvironments* envs = cx->compartment()->debugEnvs; if (!envs) return; EnvironmentIter ei(cx, frame, pc); onPopVar(cx, ei); } void DebugEnvironments::onPopVar(JSContext* cx, const EnvironmentIter& ei) { if (ei.scope().is()) onPopGeneric(cx, ei); else onPopGeneric(cx, ei); } void DebugEnvironments::onPopWith(AbstractFramePtr frame) { if (DebugEnvironments* envs = frame.compartment()->debugEnvs) envs->liveEnvs.remove(&frame.environmentChain()->as()); } void DebugEnvironments::onCompartmentUnsetIsDebuggee(JSCompartment* c) { if (DebugEnvironments* envs = c->debugEnvs) { envs->proxiedEnvs.clear(); envs->missingEnvs.clear(); envs->liveEnvs.clear(); } } bool DebugEnvironments::updateLiveEnvironments(JSContext* cx) { JS_CHECK_RECURSION(cx, return false); /* * Note that we must always update the top frame's environment objects' * entries in liveEnvs because we can't be sure code hasn't run in that * frame to change the environment chain since we were last called. The * fp->prevUpToDate() flag indicates whether the environments of frames * older than fp are already included in liveEnvs. It might seem simpler * to have fp instead carry a flag indicating whether fp itself is * accurately described, but then we would need to clear that flag * whenever fp ran code. By storing the 'up to date' bit for fp->prev() in * fp, simply popping fp effectively clears the flag for us, at exactly * the time when execution resumes fp->prev(). */ for (AllFramesIter i(cx); !i.done(); ++i) { if (!i.hasUsableAbstractFramePtr()) continue; AbstractFramePtr frame = i.abstractFramePtr(); if (frame.environmentChain()->compartment() != cx->compartment()) continue; if (frame.isFunctionFrame() && frame.callee()->isGenerator()) continue; if (!frame.isDebuggee()) continue; for (EnvironmentIter ei(cx, frame, i.pc()); ei.withinInitialFrame(); ei++) { if (ei.hasSyntacticEnvironment() && !ei.scope().is()) { MOZ_ASSERT(ei.environment().compartment() == cx->compartment()); DebugEnvironments* envs = ensureCompartmentData(cx); if (!envs) return false; if (!envs->liveEnvs.put(&ei.environment(), LiveEnvironmentVal(ei))) return false; } } if (frame.prevUpToDate()) return true; MOZ_ASSERT(frame.environmentChain()->compartment()->isDebuggee()); frame.setPrevUpToDate(); } return true; } LiveEnvironmentVal* DebugEnvironments::hasLiveEnvironment(EnvironmentObject& env) { DebugEnvironments* envs = env.compartment()->debugEnvs; if (!envs) return nullptr; if (LiveEnvironmentMap::Ptr p = envs->liveEnvs.lookup(&env)) return &p->value(); return nullptr; } /* static */ void DebugEnvironments::unsetPrevUpToDateUntil(JSContext* cx, AbstractFramePtr until) { // This are two exceptions where fp->prevUpToDate() is cleared without // popping the frame. When a frame is rematerialized or has its // debuggeeness toggled off->on, all frames younger than the frame must // have their prevUpToDate set to false. This is because unrematerialized // Ion frames and non-debuggee frames are skipped by updateLiveEnvironments. If // in the future a frame suddenly gains a usable AbstractFramePtr via // rematerialization or becomes a debuggee, the prevUpToDate invariant // will no longer hold for older frames on its stack. for (AllFramesIter i(cx); !i.done(); ++i) { if (!i.hasUsableAbstractFramePtr()) continue; AbstractFramePtr frame = i.abstractFramePtr(); if (frame == until) return; if (frame.environmentChain()->compartment() != cx->compartment()) continue; frame.unsetPrevUpToDate(); } } /* static */ void DebugEnvironments::forwardLiveFrame(JSContext* cx, AbstractFramePtr from, AbstractFramePtr to) { DebugEnvironments* envs = cx->compartment()->debugEnvs; if (!envs) return; for (MissingEnvironmentMap::Enum e(envs->missingEnvs); !e.empty(); e.popFront()) { MissingEnvironmentKey key = e.front().key(); if (key.frame() == from) { key.updateFrame(to); e.rekeyFront(key); } } for (LiveEnvironmentMap::Enum e(envs->liveEnvs); !e.empty(); e.popFront()) { LiveEnvironmentVal& val = e.front().value(); if (val.frame() == from) val.updateFrame(to); } } /* static */ void DebugEnvironments::markLiveFrame(JSTracer* trc, AbstractFramePtr frame) { for (MissingEnvironmentMap::Enum e(missingEnvs); !e.empty(); e.popFront()) { if (e.front().key().frame() == frame) TraceEdge(trc, &e.front().value(), "debug-env-live-frame-missing-env"); } } /*****************************************************************************/ static JSObject* GetDebugEnvironment(JSContext* cx, const EnvironmentIter& ei); static DebugEnvironmentProxy* GetDebugEnvironmentForEnvironmentObject(JSContext* cx, const EnvironmentIter& ei) { Rooted env(cx, &ei.environment()); if (DebugEnvironmentProxy* debugEnv = DebugEnvironments::hasDebugEnvironment(cx, *env)) return debugEnv; EnvironmentIter copy(cx, ei); RootedObject enclosingDebug(cx, GetDebugEnvironment(cx, ++copy)); if (!enclosingDebug) return nullptr; Rooted debugEnv(cx, DebugEnvironmentProxy::create(cx, *env, enclosingDebug)); if (!debugEnv) return nullptr; if (!DebugEnvironments::addDebugEnvironment(cx, env, debugEnv)) return nullptr; return debugEnv; } static DebugEnvironmentProxy* GetDebugEnvironmentForMissing(JSContext* cx, const EnvironmentIter& ei) { MOZ_ASSERT(!ei.hasSyntacticEnvironment() && (ei.scope().is() || ei.scope().is() || ei.scope().is())); if (DebugEnvironmentProxy* debugEnv = DebugEnvironments::hasDebugEnvironment(cx, ei)) return debugEnv; EnvironmentIter copy(cx, ei); RootedObject enclosingDebug(cx, GetDebugEnvironment(cx, ++copy)); if (!enclosingDebug) return nullptr; /* * Create the missing environment object. For lexical environment objects, * this takes care of storing variable values after the stack frame has * been popped. For call objects, we only use the pretend call object to * access callee, bindings and to receive dynamically added * properties. Together, this provides the nice invariant that every * DebugEnvironmentProxy has a EnvironmentObject. * * Note: to preserve envChain depth invariants, these lazily-reified * envs must not be put on the frame's environment chain; instead, they are * maintained via DebugEnvironments hooks. */ Rooted debugEnv(cx); if (ei.scope().is()) { RootedFunction callee(cx, ei.scope().as().canonicalFunction()); // Generators should always reify their scopes. MOZ_ASSERT(!callee->isGenerator()); JS::ExposeObjectToActiveJS(callee); Rooted callobj(cx, CallObject::createHollowForDebug(cx, callee)); if (!callobj) return nullptr; debugEnv = DebugEnvironmentProxy::create(cx, *callobj, enclosingDebug); } else if (ei.scope().is()) { Rooted lexicalScope(cx, &ei.scope().as()); Rooted env(cx, LexicalEnvironmentObject::createHollowForDebug(cx, lexicalScope)); if (!env) return nullptr; debugEnv = DebugEnvironmentProxy::create(cx, *env, enclosingDebug); } else { Rooted varScope(cx, &ei.scope().as()); Rooted env(cx, VarEnvironmentObject::createHollowForDebug(cx, varScope)); if (!env) return nullptr; debugEnv = DebugEnvironmentProxy::create(cx, *env, enclosingDebug); } if (!debugEnv) return nullptr; if (!DebugEnvironments::addDebugEnvironment(cx, ei, debugEnv)) return nullptr; return debugEnv; } static JSObject* GetDebugEnvironmentForNonEnvironmentObject(const EnvironmentIter& ei) { JSObject& enclosing = ei.enclosingEnvironment(); #ifdef DEBUG JSObject* o = &enclosing; while ((o = o->enclosingEnvironment())) MOZ_ASSERT(!o->is()); #endif return &enclosing; } static JSObject* GetDebugEnvironment(JSContext* cx, const EnvironmentIter& ei) { JS_CHECK_RECURSION(cx, return nullptr); if (ei.done()) return GetDebugEnvironmentForNonEnvironmentObject(ei); if (ei.hasAnyEnvironmentObject()) return GetDebugEnvironmentForEnvironmentObject(cx, ei); if (ei.scope().is() || ei.scope().is() || ei.scope().is()) { return GetDebugEnvironmentForMissing(cx, ei); } EnvironmentIter copy(cx, ei); return GetDebugEnvironment(cx, ++copy); } JSObject* js::GetDebugEnvironmentForFunction(JSContext* cx, HandleFunction fun) { assertSameCompartment(cx, fun); MOZ_ASSERT(CanUseDebugEnvironmentMaps(cx)); if (!DebugEnvironments::updateLiveEnvironments(cx)) return nullptr; JSScript* script = JSFunction::getOrCreateScript(cx, fun); if (!script) return nullptr; EnvironmentIter ei(cx, fun->environment(), script->enclosingScope()); return GetDebugEnvironment(cx, ei); } JSObject* js::GetDebugEnvironmentForFrame(JSContext* cx, AbstractFramePtr frame, jsbytecode* pc) { assertSameCompartment(cx, frame); if (CanUseDebugEnvironmentMaps(cx) && !DebugEnvironments::updateLiveEnvironments(cx)) return nullptr; EnvironmentIter ei(cx, frame, pc); return GetDebugEnvironment(cx, ei); } JSObject* js::GetDebugEnvironmentForGlobalLexicalEnvironment(JSContext* cx) { EnvironmentIter ei(cx, &cx->global()->lexicalEnvironment(), &cx->global()->emptyGlobalScope()); return GetDebugEnvironment(cx, ei); } // See declaration and documentation in jsfriendapi.h JS_FRIEND_API(JSObject*) js::GetNearestEnclosingWithEnvironmentObjectForFunction(JSFunction* fun) { if (!fun->isInterpreted()) return &fun->global(); JSObject* env = fun->environment(); while (env && !env->is()) env = env->enclosingEnvironment(); if (!env) return &fun->global(); return &env->as().object(); } bool js::CreateObjectsForEnvironmentChain(JSContext* cx, AutoObjectVector& chain, HandleObject terminatingEnv, MutableHandleObject envObj) { #ifdef DEBUG for (size_t i = 0; i < chain.length(); ++i) { assertSameCompartment(cx, chain[i]); MOZ_ASSERT(!chain[i]->is()); } #endif // Construct With object wrappers for the things on this environment chain // and use the result as the thing to scope the function to. Rooted withEnv(cx); RootedObject enclosingEnv(cx, terminatingEnv); for (size_t i = chain.length(); i > 0; ) { withEnv = WithEnvironmentObject::createNonSyntactic(cx, chain[--i], enclosingEnv); if (!withEnv) return false; enclosingEnv = withEnv; } envObj.set(enclosingEnv); return true; } JSObject& WithEnvironmentObject::object() const { return getReservedSlot(OBJECT_SLOT).toObject(); } JSObject* WithEnvironmentObject::withThis() const { return &getReservedSlot(THIS_SLOT).toObject(); } bool WithEnvironmentObject::isSyntactic() const { Value v = getReservedSlot(SCOPE_SLOT); MOZ_ASSERT(v.isPrivateGCThing() || v.isNull()); return v.isPrivateGCThing(); } WithScope& WithEnvironmentObject::scope() const { MOZ_ASSERT(isSyntactic()); return *static_cast(getReservedSlot(SCOPE_SLOT).toGCThing()); } ModuleEnvironmentObject* js::GetModuleEnvironmentForScript(JSScript* script) { for (ScopeIter si(script); si; si++) { if (si.kind() == ScopeKind::Module) return si.scope()->as().module()->environment(); } return nullptr; } bool js::GetThisValueForDebuggerMaybeOptimizedOut(JSContext* cx, AbstractFramePtr frame, jsbytecode* pc, MutableHandleValue res) { for (EnvironmentIter ei(cx, frame, pc); ei; ei++) { if (ei.scope().kind() == ScopeKind::Module) { res.setUndefined(); return true; } if (!ei.scope().is() || ei.scope().as().canonicalFunction()->hasLexicalThis()) { continue; } RootedScript script(cx, ei.scope().as().script()); // Figure out if we executed JSOP_FUNCTIONTHIS and set it. bool executedInitThisOp = false; if (script->functionHasThisBinding()) { for (jsbytecode* it = script->code(); it < script->codeEnd(); it = GetNextPc(it)) { if (*it == JSOP_FUNCTIONTHIS) { // The next op after JSOP_FUNCTIONTHIS always sets it. executedInitThisOp = pc > GetNextPc(it); break; } } } if (ei.withinInitialFrame() && !executedInitThisOp) { // Either we're yet to initialize the this-binding // (JSOP_FUNCTIONTHIS), or the script does not have a this-binding // (because it doesn't use |this|). // If our this-argument is an object, or we're in strict mode, // the this-binding is always the same as our this-argument. if (frame.thisArgument().isObject() || script->strict()) { res.set(frame.thisArgument()); return true; } // We didn't initialize the this-binding yet. Determine the // correct |this| value for this frame (box primitives if not // in strict mode), and assign it to the this-argument slot so // JSOP_FUNCTIONTHIS will use it and not box a second time. if (!GetFunctionThis(cx, frame, res)) return false; frame.thisArgument() = res; return true; } if (!script->functionHasThisBinding()) { res.setMagic(JS_OPTIMIZED_OUT); return true; } for (Rooted bi(cx, BindingIter(script)); bi; bi++) { if (bi.name() != cx->names().dotThis) continue; BindingLocation loc = bi.location(); if (loc.kind() == BindingLocation::Kind::Environment) { RootedObject callObj(cx, &ei.environment().as()); return GetProperty(cx, callObj, callObj, bi.name()->asPropertyName(), res); } if (loc.kind() == BindingLocation::Kind::Frame && ei.withinInitialFrame()) res.set(frame.unaliasedLocal(loc.slot())); else res.setMagic(JS_OPTIMIZED_OUT); return true; } MOZ_CRASH("'this' binding must be found"); } RootedObject scopeChain(cx, frame.environmentChain()); return GetNonSyntacticGlobalThis(cx, scopeChain, res); } bool js::CheckLexicalNameConflict(JSContext* cx, Handle lexicalEnv, HandleObject varObj, HandlePropertyName name) { const char* redeclKind = nullptr; RootedId id(cx, NameToId(name)); RootedShape shape(cx); if (varObj->is() && varObj->compartment()->isInVarNames(name)) { // ES 15.1.11 step 5.a redeclKind = "var"; } else if ((shape = lexicalEnv->lookup(cx, name))) { // ES 15.1.11 step 5.b redeclKind = shape->writable() ? "let" : "const"; } else if (varObj->isNative() && (shape = varObj->as().lookup(cx, name))) { // Faster path for ES 15.1.11 step 5.c-d when the shape can be found // without going through a resolve hook. if (!shape->configurable()) redeclKind = "non-configurable global property"; } else { // ES 15.1.11 step 5.c-d Rooted desc(cx); if (!GetOwnPropertyDescriptor(cx, varObj, id, &desc)) return false; if (desc.object() && desc.hasConfigurable() && !desc.configurable()) redeclKind = "non-configurable global property"; } if (redeclKind) { ReportRuntimeRedeclaration(cx, name, redeclKind); return false; } return true; } bool js::CheckVarNameConflict(JSContext* cx, Handle lexicalEnv, HandlePropertyName name) { if (Shape* shape = lexicalEnv->lookup(cx, name)) { ReportRuntimeRedeclaration(cx, name, shape->writable() ? "let" : "const"); return false; } return true; } static void ReportCannotDeclareGlobalBinding(JSContext* cx, HandlePropertyName name, const char* reason) { JSAutoByteString printable; if (AtomToPrintableString(cx, name, &printable)) { JS_ReportErrorNumberLatin1(cx, GetErrorMessage, nullptr, JSMSG_CANT_DECLARE_GLOBAL_BINDING, printable.ptr(), reason); } } bool js::CheckCanDeclareGlobalBinding(JSContext* cx, Handle global, HandlePropertyName name, bool isFunction) { RootedId id(cx, NameToId(name)); Rooted desc(cx); if (!GetOwnPropertyDescriptor(cx, global, id, &desc)) return false; // ES 8.1.1.4.15 CanDeclareGlobalVar // ES 8.1.1.4.16 CanDeclareGlobalFunction // Step 4. if (!desc.object()) { // 8.1.14.15 step 6. // 8.1.14.16 step 5. if (global->nonProxyIsExtensible()) return true; ReportCannotDeclareGlobalBinding(cx, name, "global is non-extensible"); return false; } // Global functions have additional restrictions. if (isFunction) { // 8.1.14.16 step 6. if (desc.configurable()) return true; // 8.1.14.16 step 7. if (desc.isDataDescriptor() && desc.writable() && desc.enumerable()) return true; ReportCannotDeclareGlobalBinding(cx, name, "property must be configurable or " "both writable and enumerable"); return false; } return true; } bool js::CheckGlobalDeclarationConflicts(JSContext* cx, HandleScript script, Handle lexicalEnv, HandleObject varObj) { // Due to the extensibility of the global lexical environment, we must // check for redeclaring a binding. // // In the case of non-syntactic environment chains, we are checking // redeclarations against the non-syntactic lexical environment and the // variables object that the lexical environment corresponds to. RootedPropertyName name(cx); Rooted bi(cx, BindingIter(script)); // ES 15.1.11 GlobalDeclarationInstantiation // Step 6. // // Check 'var' declarations do not conflict with existing bindings in the // global lexical environment. for (; bi; bi++) { if (bi.kind() != BindingKind::Var) break; name = bi.name()->asPropertyName(); if (!CheckVarNameConflict(cx, lexicalEnv, name)) return false; // Step 10 and 12. // // Check that global functions and vars may be declared. if (varObj->is()) { Handle global = varObj.as(); if (!CheckCanDeclareGlobalBinding(cx, global, name, bi.isTopLevelFunction())) return false; } } // Step 5. // // Check that lexical bindings do not conflict. for (; bi; bi++) { name = bi.name()->asPropertyName(); if (!CheckLexicalNameConflict(cx, lexicalEnv, varObj, name)) return false; } return true; } static bool CheckVarNameConflictsInEnv(JSContext* cx, HandleScript script, HandleObject obj) { Rooted env(cx); if (obj->is()) { env = &obj->as(); } else if (obj->is() && obj->as().environment().is()) { env = &obj->as().environment().as(); } else { // Environment cannot contain lexical bindings. return true; } if (env->isSyntactic() && !env->isGlobal() && env->scope().kind() == ScopeKind::SimpleCatch) { // Annex B.3.5 allows redeclaring simple (non-destructured) catch // parameters with var declarations, except when it appears in a // for-of. The for-of allowance is computed in // Parser::isVarRedeclaredInEval. return true; } RootedPropertyName name(cx); for (BindingIter bi(script); bi; bi++) { name = bi.name()->asPropertyName(); if (!CheckVarNameConflict(cx, env, name)) return false; } return true; } bool js::CheckEvalDeclarationConflicts(JSContext* cx, HandleScript script, HandleObject scopeChain, HandleObject varObj) { if (!script->bodyScope()->as().hasBindings()) return true; RootedObject obj(cx, scopeChain); // ES 18.2.1.3. // Step 5. // // Check that a direct eval will not hoist 'var' bindings over lexical // bindings with the same name. while (obj != varObj) { if (!CheckVarNameConflictsInEnv(cx, script, obj)) return false; obj = obj->enclosingEnvironment(); } // Step 8. // // Check that global functions may be declared. if (varObj->is()) { Handle global = varObj.as(); RootedPropertyName name(cx); for (Rooted bi(cx, BindingIter(script)); bi; bi++) { name = bi.name()->asPropertyName(); if (!CheckCanDeclareGlobalBinding(cx, global, name, bi.isTopLevelFunction())) return false; } } return true; } bool js::InitFunctionEnvironmentObjects(JSContext* cx, AbstractFramePtr frame) { MOZ_ASSERT(frame.isFunctionFrame()); MOZ_ASSERT(frame.callee()->needsSomeEnvironmentObject()); RootedFunction callee(cx, frame.callee()); // Named lambdas may have an environment that holds itself for recursion. if (callee->needsNamedLambdaEnvironment()) { NamedLambdaObject* declEnv; if (callee->isAsync()) { // Named async function needs special environment to return // wrapped function for the binding. RootedFunction fun(cx, GetWrappedAsyncFunction(callee)); declEnv = NamedLambdaObject::create(cx, frame, fun); } else { declEnv = NamedLambdaObject::create(cx, frame); } if (!declEnv) return false; frame.pushOnEnvironmentChain(*declEnv); } // If the function has parameter default expressions, there may be an // extra environment to hold the parameters. if (callee->needsCallObject()) { CallObject* callObj = CallObject::create(cx, frame); if (!callObj) return false; frame.pushOnEnvironmentChain(*callObj); } return true; } bool js::PushVarEnvironmentObject(JSContext* cx, HandleScope scope, AbstractFramePtr frame) { VarEnvironmentObject* env = VarEnvironmentObject::create(cx, scope, frame); if (!env) return false; frame.pushOnEnvironmentChain(*env); return true; } #ifdef DEBUG typedef HashSet PropertyNameSet; static bool RemoveReferencedNames(JSContext* cx, HandleScript script, PropertyNameSet& remainingNames) { // Remove from remainingNames --- the closure variables in some outer // script --- any free variables in this script. This analysis isn't perfect: // // - It will not account for free variables in an inner script which are // actually accessing some name in an intermediate script between the // inner and outer scripts. This can cause remainingNames to be an // underapproximation. // // - It will not account for new names introduced via eval. This can cause // remainingNames to be an overapproximation. This would be easy to fix // but is nice to have as the eval will probably not access these // these names and putting eval in an inner script is bad news if you // care about entraining variables unnecessarily. for (jsbytecode* pc = script->code(); pc != script->codeEnd(); pc += GetBytecodeLength(pc)) { PropertyName* name; switch (JSOp(*pc)) { case JSOP_GETNAME: case JSOP_SETNAME: case JSOP_STRICTSETNAME: name = script->getName(pc); break; case JSOP_GETGNAME: case JSOP_SETGNAME: case JSOP_STRICTSETGNAME: if (script->hasNonSyntacticScope()) name = script->getName(pc); else name = nullptr; break; case JSOP_GETALIASEDVAR: case JSOP_SETALIASEDVAR: name = EnvironmentCoordinateName(cx->caches.envCoordinateNameCache, script, pc); break; default: name = nullptr; break; } if (name) remainingNames.remove(name); } if (script->hasObjects()) { ObjectArray* objects = script->objects(); RootedFunction fun(cx); RootedScript innerScript(cx); for (size_t i = 0; i < objects->length; i++) { JSObject* obj = objects->vector[i]; if (obj->is() && obj->as().isInterpreted()) { fun = &obj->as(); innerScript = JSFunction::getOrCreateScript(cx, fun); if (!innerScript) return false; if (!RemoveReferencedNames(cx, innerScript, remainingNames)) return false; } } } return true; } static bool AnalyzeEntrainedVariablesInScript(JSContext* cx, HandleScript script, HandleScript innerScript) { PropertyNameSet remainingNames(cx); if (!remainingNames.init()) return false; for (BindingIter bi(script); bi; bi++) { if (bi.closedOver()) { PropertyName* name = bi.name()->asPropertyName(); PropertyNameSet::AddPtr p = remainingNames.lookupForAdd(name); if (!p && !remainingNames.add(p, name)) return false; } } if (!RemoveReferencedNames(cx, innerScript, remainingNames)) return false; if (!remainingNames.empty()) { Sprinter buf(cx); if (!buf.init()) return false; buf.printf("Script "); if (JSAtom* name = script->functionNonDelazifying()->displayAtom()) { buf.putString(name); buf.printf(" "); } buf.printf("(%s:%" PRIuSIZE ") has variables entrained by ", script->filename(), script->lineno()); if (JSAtom* name = innerScript->functionNonDelazifying()->displayAtom()) { buf.putString(name); buf.printf(" "); } buf.printf("(%s:%" PRIuSIZE ") ::", innerScript->filename(), innerScript->lineno()); for (PropertyNameSet::Range r = remainingNames.all(); !r.empty(); r.popFront()) { buf.printf(" "); buf.putString(r.front()); } printf("%s\n", buf.string()); } if (innerScript->hasObjects()) { ObjectArray* objects = innerScript->objects(); RootedFunction fun(cx); RootedScript innerInnerScript(cx); for (size_t i = 0; i < objects->length; i++) { JSObject* obj = objects->vector[i]; if (obj->is() && obj->as().isInterpreted()) { fun = &obj->as(); innerInnerScript = JSFunction::getOrCreateScript(cx, fun); if (!innerInnerScript || !AnalyzeEntrainedVariablesInScript(cx, script, innerInnerScript)) { return false; } } } } return true; } // Look for local variables in script or any other script inner to it, which are // part of the script's call object and are unnecessarily entrained by their own // inner scripts which do not refer to those variables. An example is: // // function foo() { // var a, b; // function bar() { return a; } // function baz() { return b; } // } // // |bar| unnecessarily entrains |b|, and |baz| unnecessarily entrains |a|. bool js::AnalyzeEntrainedVariables(JSContext* cx, HandleScript script) { if (!script->hasObjects()) return true; ObjectArray* objects = script->objects(); RootedFunction fun(cx); RootedScript innerScript(cx); for (size_t i = 0; i < objects->length; i++) { JSObject* obj = objects->vector[i]; if (obj->is() && obj->as().isInterpreted()) { fun = &obj->as(); innerScript = JSFunction::getOrCreateScript(cx, fun); if (!innerScript) return false; if (script->functionDelazifying() && script->functionDelazifying()->needsCallObject()) { if (!AnalyzeEntrainedVariablesInScript(cx, script, innerScript)) return false; } if (!AnalyzeEntrainedVariables(cx, innerScript)) return false; } } return true; } #endif