The Tor Browser: js/src/jsinferinlines.h@6474c204b198 (annotated)

js/src/jsinferinlines.h@6474c204b198 (annotated)

js/src/jsinferinlines.h

Wed, 31 Dec 2014 06:09:35 +0100

author: Michael Schloh von Bennewitz <michael@schloh.com>
date: Wed, 31 Dec 2014 06:09:35 +0100
changeset 0: 6474c204b198
permissions: -rw-r--r--

Cloned upstream origin tor-browser at tor-browser-31.3.0esr-4.5-1-build1
revision ID fc1c9ff7c1b2defdbc039f12214767608f46423f for hacking purpose.

 /* -*- 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/. */
 /* Inline members for javascript type inference. */
 #ifndef jsinferinlines_h
 #define jsinferinlines_h
 #include "jsinfer.h"
 #include "mozilla/PodOperations.h"
 #include "jsanalyze.h"
 #include "vm/ArrayObject.h"
 #include "vm/BooleanObject.h"
 #include "vm/NumberObject.h"
 #include "vm/SharedArrayObject.h"
 #include "vm/StringObject.h"
 #include "vm/TypedArrayObject.h"
 #include "jscntxtinlines.h"
 #include "jit/ExecutionMode-inl.h"
 namespace js {
 namespace types {
 /////////////////////////////////////////////////////////////////////
 // CompilerOutput & RecompileInfo
 /////////////////////////////////////////////////////////////////////
 inline jit::IonScript *
 CompilerOutput::ion() const
 {
 #ifdef JS_ION
     // Note: If type constraints are generated before compilation has finished
     // (i.e. after IonBuilder but before CodeGenerator::link) then a valid
     // CompilerOutput may not yet have an associated IonScript.
     JS_ASSERT(isValid());
     jit::IonScript *ion = jit::GetIonScript(script(), mode());
     JS_ASSERT(ion != ION_COMPILING_SCRIPT);
     return ion;
 #endif
     MOZ_ASSUME_UNREACHABLE("Invalid kind of CompilerOutput");
 }
 inline CompilerOutput*
 RecompileInfo::compilerOutput(TypeZone &types) const
 {
     if (!types.compilerOutputs || outputIndex >= types.compilerOutputs->length())
         return nullptr;
     return &(*types.compilerOutputs)[outputIndex];
 }
 inline CompilerOutput*
 RecompileInfo::compilerOutput(JSContext *cx) const
 {
     return compilerOutput(cx->zone()->types);
 }
 inline bool
 RecompileInfo::shouldSweep(TypeZone &types)
 {
     CompilerOutput *output = compilerOutput(types);
     if (!output || !output->isValid())
         return true;
     // Update this info for the output's new index in the zone's compiler outputs.
     outputIndex = output->sweepIndex();
     return false;
 }
 /////////////////////////////////////////////////////////////////////
 // Types
 /////////////////////////////////////////////////////////////////////
 /* static */ inline Type
 Type::ObjectType(JSObject *obj)
 {
     if (obj->hasSingletonType())
         return Type(uintptr_t(obj) | 1);
     return Type(uintptr_t(obj->type()));
 }
 /* static */ inline Type
 Type::ObjectType(TypeObject *obj)
 {
     if (obj->singleton())
         return Type(uintptr_t(obj->singleton()) | 1);
     return Type(uintptr_t(obj));
 }
 /* static */ inline Type
 Type::ObjectType(TypeObjectKey *obj)
 {
     return Type(uintptr_t(obj));
 }
 inline Type
 GetValueType(const Value &val)
 {
     if (val.isDouble())
         return Type::DoubleType();
     if (val.isObject())
         return Type::ObjectType(&val.toObject());
     return Type::PrimitiveType(val.extractNonDoubleType());
 }
 inline Type
 GetMaybeOptimizedOutValueType(const Value &val)
 {
     if (val.isMagic() && val.whyMagic() == JS_OPTIMIZED_OUT)
         return Type::UnknownType();
     return GetValueType(val);
 }
 inline TypeFlags
 PrimitiveTypeFlag(JSValueType type)
 {
     switch (type) {
       case JSVAL_TYPE_UNDEFINED:
         return TYPE_FLAG_UNDEFINED;
       case JSVAL_TYPE_NULL:
         return TYPE_FLAG_NULL;
       case JSVAL_TYPE_BOOLEAN:
         return TYPE_FLAG_BOOLEAN;
       case JSVAL_TYPE_INT32:
         return TYPE_FLAG_INT32;
       case JSVAL_TYPE_DOUBLE:
         return TYPE_FLAG_DOUBLE;
       case JSVAL_TYPE_STRING:
         return TYPE_FLAG_STRING;
       case JSVAL_TYPE_MAGIC:
         return TYPE_FLAG_LAZYARGS;
       default:
         MOZ_ASSUME_UNREACHABLE("Bad type");
     }
 }
 inline JSValueType
 TypeFlagPrimitive(TypeFlags flags)
 {
     switch (flags) {
       case TYPE_FLAG_UNDEFINED:
         return JSVAL_TYPE_UNDEFINED;
       case TYPE_FLAG_NULL:
         return JSVAL_TYPE_NULL;
       case TYPE_FLAG_BOOLEAN:
         return JSVAL_TYPE_BOOLEAN;
       case TYPE_FLAG_INT32:
         return JSVAL_TYPE_INT32;
       case TYPE_FLAG_DOUBLE:
         return JSVAL_TYPE_DOUBLE;
       case TYPE_FLAG_STRING:
         return JSVAL_TYPE_STRING;
       case TYPE_FLAG_LAZYARGS:
         return JSVAL_TYPE_MAGIC;
       default:
         MOZ_ASSUME_UNREACHABLE("Bad type");
     }
 }
 /*
  * Get the canonical representation of an id to use when doing inference.  This
  * maintains the constraint that if two different jsids map to the same property
  * in JS (e.g. 3 and "3"), they have the same type representation.
  */
 inline jsid
 IdToTypeId(jsid id)
 {
     JS_ASSERT(!JSID_IS_EMPTY(id));
     /*
      * All integers must map to the aggregate property for index types, including
      * negative integers.
      */
     if (JSID_IS_INT(id))
         return JSID_VOID;
     /*
      * Check for numeric strings, as in js_StringIsIndex, but allow negative
      * and overflowing integers.
      */
     if (JSID_IS_STRING(id)) {
         JSAtom *atom = JSID_TO_ATOM(id);
         JS::TwoByteChars cp = atom->range();
         if (cp.length() > 0 && (JS7_ISDEC(cp[0]) || cp[0] == '-')) {
             for (size_t i = 1; i < cp.length(); ++i) {
                 if (!JS7_ISDEC(cp[i]))
                     return id;
             }
             return JSID_VOID;
         }
         return id;
     }
     return JSID_VOID;
 }
 const char * TypeIdStringImpl(jsid id);
 /* Convert an id for printing during debug. */
 static inline const char *
 TypeIdString(jsid id)
 {
 #ifdef DEBUG
     return TypeIdStringImpl(id);
 #else
     return "(missing)";
 #endif
 }
 /*
  * Structure for type inference entry point functions. All functions which can
  * change type information must use this, and functions which depend on
  * intermediate types (i.e. JITs) can use this to ensure that intermediate
  * information is not collected and does not change.
  *
  * Pins inference results so that intermediate type information, TypeObjects
  * and JSScripts won't be collected during GC. Does additional sanity checking
  * that inference is not reentrant and that recompilations occur properly.
  */
 struct AutoEnterAnalysis
 {
     /* Prevent GC activity in the middle of analysis. */
     gc::AutoSuppressGC suppressGC;
     FreeOp *freeOp;
     JSCompartment *compartment;
     bool oldActiveAnalysis;
     AutoEnterAnalysis(ExclusiveContext *cx)
       : suppressGC(cx)
     {
         init(cx->defaultFreeOp(), cx->compartment());
     }
     AutoEnterAnalysis(FreeOp *fop, JSCompartment *comp)
       : suppressGC(comp)
     {
         init(fop, comp);
     }
     ~AutoEnterAnalysis()
     {
         compartment->activeAnalysis = oldActiveAnalysis;
         /*
          * If there are no more type inference activations on the stack,
          * process any triggered recompilations. Note that we should not be
          * invoking any scripted code while type inference is running.
          */
         if (!compartment->activeAnalysis) {
             TypeZone &types = compartment->zone()->types;
             if (types.pendingRecompiles)
                 types.processPendingRecompiles(freeOp);
         }
     }
   private:
     void init(FreeOp *fop, JSCompartment *comp) {
         freeOp = fop;
         compartment = comp;
         oldActiveAnalysis = compartment->activeAnalysis;
         compartment->activeAnalysis = true;
     }
 };
 /////////////////////////////////////////////////////////////////////
 // Interface functions
 /////////////////////////////////////////////////////////////////////
 inline const Class *
 GetClassForProtoKey(JSProtoKey key)
 {
     switch (key) {
       case JSProto_Object:
         return &JSObject::class_;
       case JSProto_Array:
         return &ArrayObject::class_;
       case JSProto_Number:
         return &NumberObject::class_;
       case JSProto_Boolean:
         return &BooleanObject::class_;
       case JSProto_String:
         return &StringObject::class_;
       case JSProto_RegExp:
         return &RegExpObject::class_;
       case JSProto_Int8Array:
       case JSProto_Uint8Array:
       case JSProto_Int16Array:
       case JSProto_Uint16Array:
       case JSProto_Int32Array:
       case JSProto_Uint32Array:
       case JSProto_Float32Array:
       case JSProto_Float64Array:
       case JSProto_Uint8ClampedArray:
         return &TypedArrayObject::classes[key - JSProto_Int8Array];
       case JSProto_ArrayBuffer:
         return &ArrayBufferObject::class_;
       case JSProto_SharedArrayBuffer:
         return &SharedArrayBufferObject::class_;
       case JSProto_DataView:
         return &DataViewObject::class_;
       default:
         MOZ_ASSUME_UNREACHABLE("Bad proto key");
     }
 }
 /*
  * Get the default 'new' object for a given standard class, per the currently
  * active global.
  */
 inline TypeObject *
 GetTypeNewObject(JSContext *cx, JSProtoKey key)
 {
     RootedObject proto(cx);
     if (!GetBuiltinPrototype(cx, key, &proto))
         return nullptr;
     return cx->getNewType(GetClassForProtoKey(key), proto.get());
 }
 /* Get a type object for the immediate allocation site within a native. */
 inline TypeObject *
 GetTypeCallerInitObject(JSContext *cx, JSProtoKey key)
 {
     jsbytecode *pc;
     RootedScript script(cx, cx->currentScript(&pc));
     if (script)
         return TypeScript::InitObject(cx, script, pc, key);
     return GetTypeNewObject(cx, key);
 }
 void MarkIteratorUnknownSlow(JSContext *cx);
 void TypeMonitorCallSlow(JSContext *cx, JSObject *callee, const CallArgs &args,
                          bool constructing);
 /*
  * Monitor a javascript call, either on entry to the interpreter or made
  * from within the interpreter.
  */
 inline void
 TypeMonitorCall(JSContext *cx, const js::CallArgs &args, bool constructing)
 {
     if (args.callee().is<JSFunction>()) {
         JSFunction *fun = &args.callee().as<JSFunction>();
         if (fun->isInterpreted() && fun->nonLazyScript()->types)
             TypeMonitorCallSlow(cx, &args.callee(), args, constructing);
     }
 }
 inline bool
 TrackPropertyTypes(ExclusiveContext *cx, JSObject *obj, jsid id)
 {
     if (obj->hasLazyType() || obj->type()->unknownProperties())
         return false;
     if (obj->hasSingletonType() && !obj->type()->maybeGetProperty(id))
         return false;
     return true;
 }
 inline void
 EnsureTrackPropertyTypes(JSContext *cx, JSObject *obj, jsid id)
 {
     id = IdToTypeId(id);
     if (obj->hasSingletonType()) {
         AutoEnterAnalysis enter(cx);
         if (obj->hasLazyType() && !obj->getType(cx)) {
             CrashAtUnhandlableOOM("Could not allocate TypeObject in EnsureTrackPropertyTypes");
             return;
         }
         if (!obj->type()->unknownProperties() && !obj->type()->getProperty(cx, id)) {
             MOZ_ASSERT(obj->type()->unknownProperties());
             return;
         }
     }
     JS_ASSERT(obj->type()->unknownProperties() || TrackPropertyTypes(cx, obj, id));
 }
 inline bool
 CanHaveEmptyPropertyTypesForOwnProperty(JSObject *obj)
 {
     // Per the comment on TypeSet::propertySet, property type sets for global
     // objects may be empty for 'own' properties if the global property still
     // has its initial undefined value.
     return obj->is<GlobalObject>();
 }
 inline bool
 HasTypePropertyId(JSObject *obj, jsid id, Type type)
 {
     if (obj->hasLazyType())
         return true;
     if (obj->type()->unknownProperties())
         return true;
     if (HeapTypeSet *types = obj->type()->maybeGetProperty(IdToTypeId(id)))
         return types->hasType(type);
     return false;
 }
 inline bool
 HasTypePropertyId(JSObject *obj, jsid id, const Value &value)
 {
     return HasTypePropertyId(obj, id, GetValueType(value));
 }
 /* Add a possible type for a property of obj. */
 inline void
 AddTypePropertyId(ExclusiveContext *cx, JSObject *obj, jsid id, Type type)
 {
     id = IdToTypeId(id);
     if (TrackPropertyTypes(cx, obj, id))
         obj->type()->addPropertyType(cx, id, type);
 }
 inline void
 AddTypePropertyId(ExclusiveContext *cx, JSObject *obj, jsid id, const Value &value)
 {
     id = IdToTypeId(id);
     if (TrackPropertyTypes(cx, obj, id))
         obj->type()->addPropertyType(cx, id, value);
 }
 inline void
 AddTypePropertyId(ExclusiveContext *cx, TypeObject *obj, jsid id, Type type)
 {
     if (!obj->unknownProperties())
         obj->addPropertyType(cx, id, type);
 }
 inline void
 AddTypePropertyId(ExclusiveContext *cx, TypeObject *obj, jsid id, const Value &value)
 {
     if (!obj->unknownProperties())
         obj->addPropertyType(cx, id, value);
 }
 /* Set one or more dynamic flags on a type object. */
 inline void
 MarkTypeObjectFlags(ExclusiveContext *cx, JSObject *obj, TypeObjectFlags flags)
 {
     if (!obj->hasLazyType() && !obj->type()->hasAllFlags(flags))
         obj->type()->setFlags(cx, flags);
 }
 /*
  * Mark all properties of a type object as unknown. If markSetsUnknown is set,
  * scan the entire compartment and mark all type sets containing it as having
  * an unknown object. This is needed for correctness in dealing with mutable
  * __proto__, which can change the type of an object dynamically.
  */
 inline void
 MarkTypeObjectUnknownProperties(JSContext *cx, TypeObject *obj,
                                 bool markSetsUnknown = false)
 {
     if (!obj->unknownProperties())
         obj->markUnknown(cx);
     if (markSetsUnknown && !(obj->flags() & OBJECT_FLAG_SETS_MARKED_UNKNOWN))
         cx->compartment()->types.markSetsUnknown(cx, obj);
 }
 inline void
 MarkTypePropertyNonData(ExclusiveContext *cx, JSObject *obj, jsid id)
 {
     id = IdToTypeId(id);
     if (TrackPropertyTypes(cx, obj, id))
         obj->type()->markPropertyNonData(cx, id);
 }
 inline void
 MarkTypePropertyNonWritable(ExclusiveContext *cx, JSObject *obj, jsid id)
 {
     id = IdToTypeId(id);
     if (TrackPropertyTypes(cx, obj, id))
         obj->type()->markPropertyNonWritable(cx, id);
 }
 inline bool
 IsTypePropertyIdMarkedNonData(JSObject *obj, jsid id)
 {
     return obj->type()->isPropertyNonData(id);
 }
 inline bool
 IsTypePropertyIdMarkedNonWritable(JSObject *obj, jsid id)
 {
     return obj->type()->isPropertyNonWritable(id);
 }
 /* Mark a state change on a particular object. */
 inline void
 MarkObjectStateChange(ExclusiveContext *cx, JSObject *obj)
 {
     if (!obj->hasLazyType() && !obj->type()->unknownProperties())
         obj->type()->markStateChange(cx);
 }
 /*
  * For an array or object which has not yet escaped and been referenced elsewhere,
  * pick a new type based on the object's current contents.
  */
 inline void
 FixArrayType(ExclusiveContext *cx, HandleObject obj)
 {
     cx->compartment()->types.fixArrayType(cx, obj);
 }
 inline void
 FixObjectType(ExclusiveContext *cx, HandleObject obj)
 {
     cx->compartment()->types.fixObjectType(cx, obj);
 }
 /* Interface helpers for JSScript*. */
 extern void TypeMonitorResult(JSContext *cx, JSScript *script, jsbytecode *pc,
                               const js::Value &rval);
 extern void TypeDynamicResult(JSContext *cx, JSScript *script, jsbytecode *pc,
                               js::types::Type type);
 /////////////////////////////////////////////////////////////////////
 // Script interface functions
 /////////////////////////////////////////////////////////////////////
 /* static */ inline unsigned
 TypeScript::NumTypeSets(JSScript *script)
 {
     return script->nTypeSets() + analyze::LocalSlot(script, 0);
 }
 /* static */ inline StackTypeSet *
 TypeScript::ThisTypes(JSScript *script)
 {
     return script->types->typeArray() + script->nTypeSets() + analyze::ThisSlot();
 }
 /*
  * Note: for non-escaping arguments and locals, argTypes/localTypes reflect
  * only the initial type of the variable (e.g. passed values for argTypes,
  * or undefined for localTypes) and not types from subsequent assignments.
  */
 /* static */ inline StackTypeSet *
 TypeScript::ArgTypes(JSScript *script, unsigned i)
 {
     JS_ASSERT(i < script->functionNonDelazifying()->nargs());
     return script->types->typeArray() + script->nTypeSets() + analyze::ArgSlot(i);
 }
 template <typename TYPESET>
 /* static */ inline TYPESET *
 TypeScript::BytecodeTypes(JSScript *script, jsbytecode *pc, uint32_t *bytecodeMap,
                           uint32_t *hint, TYPESET *typeArray)
 {
     JS_ASSERT(js_CodeSpec[*pc].format & JOF_TYPESET);
     uint32_t offset = script->pcToOffset(pc);
     // See if this pc is the next typeset opcode after the last one looked up.
     if ((*hint + 1) < script->nTypeSets() && bytecodeMap[*hint + 1] == offset) {
         (*hint)++;
         return typeArray + *hint;
     }
     // See if this pc is the same as the last one looked up.
     if (bytecodeMap[*hint] == offset)
         return typeArray + *hint;
     // Fall back to a binary search.
     size_t bottom = 0;
     size_t top = script->nTypeSets() - 1;
     size_t mid = bottom + (top - bottom) / 2;
     while (mid < top) {
         if (bytecodeMap[mid] < offset)
             bottom = mid + 1;
         else if (bytecodeMap[mid] > offset)
             top = mid;
         else
             break;
         mid = bottom + (top - bottom) / 2;
     }
     // We should have have zeroed in on either the exact offset, unless there
     // are more JOF_TYPESET opcodes than nTypeSets in the script (as can happen
     // if the script is very long).
     JS_ASSERT(bytecodeMap[mid] == offset || mid == top);
     *hint = mid;
     return typeArray + *hint;
 }
 /* static */ inline StackTypeSet *
 TypeScript::BytecodeTypes(JSScript *script, jsbytecode *pc)
 {
     JS_ASSERT(CurrentThreadCanAccessRuntime(script->runtimeFromMainThread()));
 #ifdef JS_ION
     uint32_t *hint = script->baselineScript()->bytecodeTypeMap() + script->nTypeSets();
     return BytecodeTypes(script, pc, script->baselineScript()->bytecodeTypeMap(),
                          hint, script->types->typeArray());
 #else
     MOZ_CRASH();
 #endif
 }
 struct AllocationSiteKey : public DefaultHasher<AllocationSiteKey> {
     JSScript *script;
     uint32_t offset : 24;
     JSProtoKey kind : 8;
     static const uint32_t OFFSET_LIMIT = (1 << 23);
     AllocationSiteKey() { mozilla::PodZero(this); }
     static inline uint32_t hash(AllocationSiteKey key) {
         return uint32_t(size_t(key.script->offsetToPC(key.offset)) ^ key.kind);
     }
     static inline bool match(const AllocationSiteKey &a, const AllocationSiteKey &b) {
         return a.script == b.script && a.offset == b.offset && a.kind == b.kind;
     }
 };
 /* Whether to use a new type object for an initializer opcode at script/pc. */
 js::NewObjectKind
 UseNewTypeForInitializer(JSScript *script, jsbytecode *pc, JSProtoKey key);
 js::NewObjectKind
 UseNewTypeForInitializer(JSScript *script, jsbytecode *pc, const Class *clasp);
 /* static */ inline TypeObject *
 TypeScript::InitObject(JSContext *cx, JSScript *script, jsbytecode *pc, JSProtoKey kind)
 {
     JS_ASSERT(!UseNewTypeForInitializer(script, pc, kind));
     /* :XXX: Limit script->length so we don't need to check the offset up front? */
     uint32_t offset = script->pcToOffset(pc);
     if (!script->compileAndGo() || offset >= AllocationSiteKey::OFFSET_LIMIT)
         return GetTypeNewObject(cx, kind);
     AllocationSiteKey key;
     key.script = script;
     key.offset = offset;
     key.kind = kind;
     if (!cx->compartment()->types.allocationSiteTable)
         return cx->compartment()->types.addAllocationSiteTypeObject(cx, key);
     AllocationSiteTable::Ptr p = cx->compartment()->types.allocationSiteTable->lookup(key);
     if (p)
         return p->value();
     return cx->compartment()->types.addAllocationSiteTypeObject(cx, key);
 }
 /* Set the type to use for obj according to the site it was allocated at. */
 static inline bool
 SetInitializerObjectType(JSContext *cx, HandleScript script, jsbytecode *pc, HandleObject obj, NewObjectKind kind)
 {
     JSProtoKey key = JSCLASS_CACHED_PROTO_KEY(obj->getClass());
     JS_ASSERT(key != JSProto_Null);
     JS_ASSERT(kind == UseNewTypeForInitializer(script, pc, key));
     if (kind == SingletonObject) {
         JS_ASSERT(obj->hasSingletonType());
         /*
          * Inference does not account for types of run-once initializer
          * objects, as these may not be created until after the script
          * has been analyzed.
          */
         TypeScript::Monitor(cx, script, pc, ObjectValue(*obj));
     } else {
         types::TypeObject *type = TypeScript::InitObject(cx, script, pc, key);
         if (!type)
             return false;
         obj->uninlinedSetType(type);
     }
     return true;
 }
 /* static */ inline void
 TypeScript::Monitor(JSContext *cx, JSScript *script, jsbytecode *pc, const js::Value &rval)
 {
     TypeMonitorResult(cx, script, pc, rval);
 }
 /* static */ inline void
 TypeScript::Monitor(JSContext *cx, const js::Value &rval)
 {
     jsbytecode *pc;
     RootedScript script(cx, cx->currentScript(&pc));
     Monitor(cx, script, pc, rval);
 }
 /* static */ inline void
 TypeScript::MonitorAssign(JSContext *cx, HandleObject obj, jsid id)
 {
     if (!obj->hasSingletonType()) {
         /*
          * Mark as unknown any object which has had dynamic assignments to
          * non-integer properties at SETELEM opcodes. This avoids making large
          * numbers of type properties for hashmap-style objects. We don't need
          * to do this for objects with singleton type, because type properties
          * are only constructed for them when analyzed scripts depend on those
          * specific properties.
          */
         uint32_t i;
         if (js_IdIsIndex(id, &i))
             return;
         // But if we don't have too many properties yet, don't do anything.  The
         // idea here is that normal object initialization should not trigger
         // deoptimization in most cases, while actual usage as a hashmap should.
         TypeObject* type = obj->type();
         if (type->getPropertyCount() < 8)
             return;
         MarkTypeObjectUnknownProperties(cx, type);
     }
 }
 /* static */ inline void
 TypeScript::SetThis(JSContext *cx, JSScript *script, Type type)
 {
     if (!script->types)
         return;
     if (!ThisTypes(script)->hasType(type)) {
         AutoEnterAnalysis enter(cx);
         InferSpew(ISpewOps, "externalType: setThis #%u: %s",
                   script->id(), TypeString(type));
         ThisTypes(script)->addType(cx, type);
     }
 }
 /* static */ inline void
 TypeScript::SetThis(JSContext *cx, JSScript *script, const js::Value &value)
 {
     SetThis(cx, script, GetValueType(value));
 }
 /* static */ inline void
 TypeScript::SetArgument(JSContext *cx, JSScript *script, unsigned arg, Type type)
 {
     if (!script->types)
         return;
     if (!ArgTypes(script, arg)->hasType(type)) {
         AutoEnterAnalysis enter(cx);
         InferSpew(ISpewOps, "externalType: setArg #%u %u: %s",
                   script->id(), arg, TypeString(type));
         ArgTypes(script, arg)->addType(cx, type);
     }
 }
 /* static */ inline void
 TypeScript::SetArgument(JSContext *cx, JSScript *script, unsigned arg, const js::Value &value)
 {
     Type type = GetValueType(value);
     SetArgument(cx, script, arg, type);
 }
 /////////////////////////////////////////////////////////////////////
 // TypeCompartment
 /////////////////////////////////////////////////////////////////////
 inline JSCompartment *
 TypeCompartment::compartment()
 {
     return (JSCompartment *)((char *)this - offsetof(JSCompartment, types));
 }
 /////////////////////////////////////////////////////////////////////
 // TypeSet
 /////////////////////////////////////////////////////////////////////
 /*
  * The sets of objects and scripts in a type set grow monotonically, are usually
  * empty, almost always small, and sometimes big.  For empty or singleton sets,
  * the pointer refers directly to the value.  For sets fitting into SET_ARRAY_SIZE,
  * an array of this length is used to store the elements.  For larger sets, a hash
  * table filled to 25%-50% of capacity is used, with collisions resolved by linear
  * probing.  TODO: replace these with jshashtables.
  */
 const unsigned SET_ARRAY_SIZE = 8;
 const unsigned SET_CAPACITY_OVERFLOW = 1u << 30;
 /* Get the capacity of a set with the given element count. */
 static inline unsigned
 HashSetCapacity(unsigned count)
 {
     JS_ASSERT(count >= 2);
     JS_ASSERT(count < SET_CAPACITY_OVERFLOW);
     if (count <= SET_ARRAY_SIZE)
         return SET_ARRAY_SIZE;
     return 1u << (mozilla::FloorLog2(count) + 2);
 }
 /* Compute the FNV hash for the low 32 bits of v. */
 template <class T, class KEY>
 static inline uint32_t
 HashKey(T v)
 {
     uint32_t nv = KEY::keyBits(v);
     uint32_t hash = 84696351 ^ (nv & 0xff);
     hash = (hash * 16777619) ^ ((nv >> 8) & 0xff);
     hash = (hash * 16777619) ^ ((nv >> 16) & 0xff);
     return (hash * 16777619) ^ ((nv >> 24) & 0xff);
 }
 /*
  * Insert space for an element into the specified set and grow its capacity if needed.
  * returned value is an existing or new entry (nullptr if new).
  */
 template <class T, class U, class KEY>
 static U **
 HashSetInsertTry(LifoAlloc &alloc, U **&values, unsigned &count, T key)
 {
     unsigned capacity = HashSetCapacity(count);
     unsigned insertpos = HashKey<T,KEY>(key) & (capacity - 1);
     /* Whether we are converting from a fixed array to hashtable. */
     bool converting = (count == SET_ARRAY_SIZE);
     if (!converting) {
         while (values[insertpos] != nullptr) {
             if (KEY::getKey(values[insertpos]) == key)
                 return &values[insertpos];
             insertpos = (insertpos + 1) & (capacity - 1);
         }
     }
     if (count >= SET_CAPACITY_OVERFLOW)
         return nullptr;
     count++;
     unsigned newCapacity = HashSetCapacity(count);
     if (newCapacity == capacity) {
         JS_ASSERT(!converting);
         return &values[insertpos];
     }
     U **newValues = alloc.newArray<U*>(newCapacity);
     if (!newValues)
         return nullptr;
     mozilla::PodZero(newValues, newCapacity);
     for (unsigned i = 0; i < capacity; i++) {
         if (values[i]) {
             unsigned pos = HashKey<T,KEY>(KEY::getKey(values[i])) & (newCapacity - 1);
             while (newValues[pos] != nullptr)
                 pos = (pos + 1) & (newCapacity - 1);
             newValues[pos] = values[i];
         }
     }
     values = newValues;
     insertpos = HashKey<T,KEY>(key) & (newCapacity - 1);
     while (values[insertpos] != nullptr)
         insertpos = (insertpos + 1) & (newCapacity - 1);
     return &values[insertpos];
 }
 /*
  * Insert an element into the specified set if it is not already there, returning
  * an entry which is nullptr if the element was not there.
  */
 template <class T, class U, class KEY>
 static inline U **
 HashSetInsert(LifoAlloc &alloc, U **&values, unsigned &count, T key)
 {
     if (count == 0) {
         JS_ASSERT(values == nullptr);
         count++;
         return (U **) &values;
     }
     if (count == 1) {
         U *oldData = (U*) values;
         if (KEY::getKey(oldData) == key)
             return (U **) &values;
         values = alloc.newArray<U*>(SET_ARRAY_SIZE);
         if (!values) {
             values = (U **) oldData;
             return nullptr;
         }
         mozilla::PodZero(values, SET_ARRAY_SIZE);
         count++;
         values[0] = oldData;
         return &values[1];
     }
     if (count <= SET_ARRAY_SIZE) {
         for (unsigned i = 0; i < count; i++) {
             if (KEY::getKey(values[i]) == key)
                 return &values[i];
         }
         if (count < SET_ARRAY_SIZE) {
             count++;
             return &values[count - 1];
         }
     }
     return HashSetInsertTry<T,U,KEY>(alloc, values, count, key);
 }
 /* Lookup an entry in a hash set, return nullptr if it does not exist. */
 template <class T, class U, class KEY>
 static inline U *
 HashSetLookup(U **values, unsigned count, T key)
 {
     if (count == 0)
         return nullptr;
     if (count == 1)
         return (KEY::getKey((U *) values) == key) ? (U *) values : nullptr;
     if (count <= SET_ARRAY_SIZE) {
         for (unsigned i = 0; i < count; i++) {
             if (KEY::getKey(values[i]) == key)
                 return values[i];
         }
         return nullptr;
     }
     unsigned capacity = HashSetCapacity(count);
     unsigned pos = HashKey<T,KEY>(key) & (capacity - 1);
     while (values[pos] != nullptr) {
         if (KEY::getKey(values[pos]) == key)
             return values[pos];
         pos = (pos + 1) & (capacity - 1);
     }
     return nullptr;
 }
 inline TypeObjectKey *
 Type::objectKey() const
 {
     JS_ASSERT(isObject());
     if (isTypeObject())
         TypeObject::readBarrier((TypeObject *) data);
     else
         JSObject::readBarrier((JSObject *) (data ^ 1));
     return (TypeObjectKey *) data;
 }
 inline JSObject *
 Type::singleObject() const
 {
     JS_ASSERT(isSingleObject());
     JSObject::readBarrier((JSObject *) (data ^ 1));
     return (JSObject *) (data ^ 1);
 }
 inline TypeObject *
 Type::typeObject() const
 {
     JS_ASSERT(isTypeObject());
     TypeObject::readBarrier((TypeObject *) data);
     return (TypeObject *) data;
 }
 inline bool
 TypeSet::hasType(Type type) const
 {
     if (unknown())
         return true;
     if (type.isUnknown()) {
         return false;
     } else if (type.isPrimitive()) {
         return !!(flags & PrimitiveTypeFlag(type.primitive()));
     } else if (type.isAnyObject()) {
         return !!(flags & TYPE_FLAG_ANYOBJECT);
     } else {
         return !!(flags & TYPE_FLAG_ANYOBJECT) ||
             HashSetLookup<TypeObjectKey*,TypeObjectKey,TypeObjectKey>
             (objectSet, baseObjectCount(), type.objectKey()) != nullptr;
     }
 }
 inline void
 TypeSet::setBaseObjectCount(uint32_t count)
 {
     JS_ASSERT(count <= TYPE_FLAG_OBJECT_COUNT_LIMIT);
     flags = (flags & ~TYPE_FLAG_OBJECT_COUNT_MASK)
           | (count << TYPE_FLAG_OBJECT_COUNT_SHIFT);
 }
 inline void
 HeapTypeSet::newPropertyState(ExclusiveContext *cxArg)
 {
     /* Propagate the change to all constraints. */
     if (JSContext *cx = cxArg->maybeJSContext()) {
         TypeConstraint *constraint = constraintList;
         while (constraint) {
             constraint->newPropertyState(cx, this);
             constraint = constraint->next;
         }
     } else {
         JS_ASSERT(!constraintList);
     }
 }
 inline void
 HeapTypeSet::setNonDataPropertyIgnoringConstraints()
 {
     flags |= TYPE_FLAG_NON_DATA_PROPERTY;
 }
 inline void
 HeapTypeSet::setNonDataProperty(ExclusiveContext *cx)
 {
     if (flags & TYPE_FLAG_NON_DATA_PROPERTY)
         return;
     setNonDataPropertyIgnoringConstraints();
     newPropertyState(cx);
 }
 inline void
 HeapTypeSet::setNonWritableProperty(ExclusiveContext *cx)
 {
     if (flags & TYPE_FLAG_NON_WRITABLE_PROPERTY)
         return;
     flags |= TYPE_FLAG_NON_WRITABLE_PROPERTY;
     newPropertyState(cx);
 }
 inline unsigned
 TypeSet::getObjectCount() const
 {
     JS_ASSERT(!unknownObject());
     uint32_t count = baseObjectCount();
     if (count > SET_ARRAY_SIZE)
         return HashSetCapacity(count);
     return count;
 }
 inline TypeObjectKey *
 TypeSet::getObject(unsigned i) const
 {
     JS_ASSERT(i < getObjectCount());
     if (baseObjectCount() == 1) {
         JS_ASSERT(i == 0);
         return (TypeObjectKey *) objectSet;
     }
     return objectSet[i];
 }
 inline JSObject *
 TypeSet::getSingleObject(unsigned i) const
 {
     TypeObjectKey *key = getObject(i);
     return (key && key->isSingleObject()) ? key->asSingleObject() : nullptr;
 }
 inline TypeObject *
 TypeSet::getTypeObject(unsigned i) const
 {
     TypeObjectKey *key = getObject(i);
     return (key && key->isTypeObject()) ? key->asTypeObject() : nullptr;
 }
 inline const Class *
 TypeSet::getObjectClass(unsigned i) const
 {
     if (JSObject *object = getSingleObject(i))
         return object->getClass();
     if (TypeObject *object = getTypeObject(i))
         return object->clasp();
     return nullptr;
 }
 /////////////////////////////////////////////////////////////////////
 // TypeObject
 /////////////////////////////////////////////////////////////////////
 inline TypeObject::TypeObject(const Class *clasp, TaggedProto proto, TypeObjectFlags initialFlags)
 {
     mozilla::PodZero(this);
     /* Inner objects may not appear on prototype chains. */
     JS_ASSERT_IF(proto.isObject(), !proto.toObject()->getClass()->ext.outerObject);
     this->clasp_ = clasp;
     this->proto_ = proto.raw();
     this->flags_ = initialFlags;
     InferSpew(ISpewOps, "newObject: %s", TypeObjectString(this));
 }
 inline uint32_t
 TypeObject::basePropertyCount() const
 {
     return (flags() & OBJECT_FLAG_PROPERTY_COUNT_MASK) >> OBJECT_FLAG_PROPERTY_COUNT_SHIFT;
 }
 inline void
 TypeObject::setBasePropertyCount(uint32_t count)
 {
     // Note: Callers must ensure they are performing threadsafe operations.
     JS_ASSERT(count <= OBJECT_FLAG_PROPERTY_COUNT_LIMIT);
     flags_ = (flags() & ~OBJECT_FLAG_PROPERTY_COUNT_MASK)
            | (count << OBJECT_FLAG_PROPERTY_COUNT_SHIFT);
 }
 inline HeapTypeSet *
 TypeObject::getProperty(ExclusiveContext *cx, jsid id)
 {
     JS_ASSERT(cx->compartment()->activeAnalysis);
     JS_ASSERT(JSID_IS_VOID(id) || JSID_IS_EMPTY(id) || JSID_IS_STRING(id));
     JS_ASSERT_IF(!JSID_IS_EMPTY(id), id == IdToTypeId(id));
     JS_ASSERT(!unknownProperties());
     if (HeapTypeSet *types = maybeGetProperty(id))
         return types;
     Property *base = cx->typeLifoAlloc().new_<Property>(id);
     if (!base) {
         markUnknown(cx);
         return nullptr;
     }
     uint32_t propertyCount = basePropertyCount();
     Property **pprop = HashSetInsert<jsid,Property,Property>
         (cx->typeLifoAlloc(), propertySet, propertyCount, id);
     if (!pprop) {
         markUnknown(cx);
         return nullptr;
     }
     JS_ASSERT(!*pprop);
     setBasePropertyCount(propertyCount);
     *pprop = base;
     updateNewPropertyTypes(cx, id, &base->types);
     if (propertyCount == OBJECT_FLAG_PROPERTY_COUNT_LIMIT) {
         // We hit the maximum number of properties the object can have, mark
         // the object unknown so that new properties will not be added in the
         // future.
         markUnknown(cx);
     }
     return &base->types;
 }
 inline HeapTypeSet *
 TypeObject::maybeGetProperty(jsid id)
 {
     JS_ASSERT(JSID_IS_VOID(id) || JSID_IS_EMPTY(id) || JSID_IS_STRING(id));
     JS_ASSERT_IF(!JSID_IS_EMPTY(id), id == IdToTypeId(id));
     JS_ASSERT(!unknownProperties());
     Property *prop = HashSetLookup<jsid,Property,Property>
         (propertySet, basePropertyCount(), id);
     return prop ? &prop->types : nullptr;
 }
 inline unsigned
 TypeObject::getPropertyCount()
 {
     uint32_t count = basePropertyCount();
     if (count > SET_ARRAY_SIZE)
         return HashSetCapacity(count);
     return count;
 }
 inline Property *
 TypeObject::getProperty(unsigned i)
 {
     JS_ASSERT(i < getPropertyCount());
     if (basePropertyCount() == 1) {
         JS_ASSERT(i == 0);
         return (Property *) propertySet;
     }
     return propertySet[i];
 }
 inline void
 TypeObjectAddendum::writeBarrierPre(TypeObjectAddendum *type)
 {
 #ifdef JSGC_INCREMENTAL
     if (!type)
         return;
     switch (type->kind) {
       case NewScript:
         return TypeNewScript::writeBarrierPre(type->asNewScript());
       case TypedObject:
         return TypeTypedObject::writeBarrierPre(type->asTypedObject());
     }
 #endif
 }
 inline void
 TypeNewScript::writeBarrierPre(TypeNewScript *newScript)
 {
 #ifdef JSGC_INCREMENTAL
     if (!newScript || !newScript->fun->runtimeFromAnyThread()->needsBarrier())
         return;
     JS::Zone *zone = newScript->fun->zoneFromAnyThread();
     if (zone->needsBarrier()) {
         MarkObject(zone->barrierTracer(), &newScript->fun, "write barrier");
         MarkObject(zone->barrierTracer(), &newScript->templateObject, "write barrier");
     }
 #endif
 }
 } } /* namespace js::types */
 inline bool
 JSScript::ensureHasTypes(JSContext *cx)
 {
     return types || makeTypes(cx);
 }
 namespace js {
 template <>
 struct GCMethods<const types::Type>
 {
     static types::Type initial() { return types::Type::UnknownType(); }
     static ThingRootKind kind() { return THING_ROOT_TYPE; }
     static bool poisoned(const types::Type &v) {
         return (v.isTypeObject() && IsPoisonedPtr(v.typeObject()))
             || (v.isSingleObject() && IsPoisonedPtr(v.singleObject()));
     }
 };
 template <>
 struct GCMethods<types::Type>
 {
     static types::Type initial() { return types::Type::UnknownType(); }
     static ThingRootKind kind() { return THING_ROOT_TYPE; }
     static bool poisoned(const types::Type &v) {
         return (v.isTypeObject() && IsPoisonedPtr(v.typeObject()))
             || (v.isSingleObject() && IsPoisonedPtr(v.singleObject()));
     }
 };
 } // namespace js
 namespace JS {
 template<> class AnchorPermitted<js::types::TypeObject *> { };
 }  // namespace JS
 #endif /* jsinferinlines_h */

The Tor Browser / annotate

js/src/jsinferinlines.h@6474c204b198 (annotated)

js/src/jsinferinlines.h