axmol/external/spidermonkey/include/win32/jsfriendapi.h

1832 lines
57 KiB
C++

/* -*- 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/. */
#ifndef jsfriendapi_h
#define jsfriendapi_h
#include "mozilla/MemoryReporting.h"
#include "jsclass.h"
#include "jsprvtd.h"
#include "jspubtd.h"
#include "js/CallArgs.h"
/*
* This macro checks if the stack pointer has exceeded a given limit. If
* |tolerance| is non-zero, it returns true only if the stack pointer has
* exceeded the limit by more than |tolerance| bytes.
*/
#if JS_STACK_GROWTH_DIRECTION > 0
# define JS_CHECK_STACK_SIZE_WITH_TOLERANCE(limit, sp, tolerance) \
((uintptr_t)(sp) < (limit)+(tolerance))
#else
# define JS_CHECK_STACK_SIZE_WITH_TOLERANCE(limit, sp, tolerance) \
((uintptr_t)(sp) > (limit)-(tolerance))
#endif
#define JS_CHECK_STACK_SIZE(limit, lval) JS_CHECK_STACK_SIZE_WITH_TOLERANCE(limit, lval, 0)
namespace JS {
template <class T>
class Heap;
} /* namespace JS */
extern JS_FRIEND_API(void)
JS_SetGrayGCRootsTracer(JSRuntime *rt, JSTraceDataOp traceOp, void *data);
extern JS_FRIEND_API(JSString *)
JS_GetAnonymousString(JSRuntime *rt);
extern JS_FRIEND_API(JSObject *)
JS_FindCompilationScope(JSContext *cx, JSObject *obj);
extern JS_FRIEND_API(JSFunction *)
JS_GetObjectFunction(JSObject *obj);
extern JS_FRIEND_API(JSBool)
JS_SplicePrototype(JSContext *cx, JSObject *obj, JSObject *proto);
extern JS_FRIEND_API(JSObject *)
JS_NewObjectWithUniqueType(JSContext *cx, JSClass *clasp, JSObject *proto, JSObject *parent);
extern JS_FRIEND_API(uint32_t)
JS_ObjectCountDynamicSlots(JS::HandleObject obj);
extern JS_FRIEND_API(size_t)
JS_SetProtoCalled(JSContext *cx);
extern JS_FRIEND_API(size_t)
JS_GetCustomIteratorCount(JSContext *cx);
extern JS_FRIEND_API(JSBool)
JS_NondeterministicGetWeakMapKeys(JSContext *cx, JSObject *obj, JSObject **ret);
/*
* Determine whether the given object is backed by a DeadObjectProxy.
*
* Such objects hold no other objects (they have no outgoing reference edges)
* and will throw if you touch them (e.g. by reading/writing a property).
*/
extern JS_FRIEND_API(JSBool)
JS_IsDeadWrapper(JSObject *obj);
/*
* Used by the cycle collector to trace through the shape and all
* shapes it reaches, marking all non-shape children found in the
* process. Uses bounded stack space.
*/
extern JS_FRIEND_API(void)
JS_TraceShapeCycleCollectorChildren(JSTracer *trc, void *shape);
enum {
JS_TELEMETRY_GC_REASON,
JS_TELEMETRY_GC_IS_COMPARTMENTAL,
JS_TELEMETRY_GC_MS,
JS_TELEMETRY_GC_MAX_PAUSE_MS,
JS_TELEMETRY_GC_MARK_MS,
JS_TELEMETRY_GC_SWEEP_MS,
JS_TELEMETRY_GC_MARK_ROOTS_MS,
JS_TELEMETRY_GC_MARK_GRAY_MS,
JS_TELEMETRY_GC_SLICE_MS,
JS_TELEMETRY_GC_MMU_50,
JS_TELEMETRY_GC_RESET,
JS_TELEMETRY_GC_INCREMENTAL_DISABLED,
JS_TELEMETRY_GC_NON_INCREMENTAL,
JS_TELEMETRY_GC_SCC_SWEEP_TOTAL_MS,
JS_TELEMETRY_GC_SCC_SWEEP_MAX_PAUSE_MS
};
typedef void
(* JSAccumulateTelemetryDataCallback)(int id, uint32_t sample);
extern JS_FRIEND_API(void)
JS_SetAccumulateTelemetryCallback(JSRuntime *rt, JSAccumulateTelemetryDataCallback callback);
extern JS_FRIEND_API(JSPrincipals *)
JS_GetCompartmentPrincipals(JSCompartment *compartment);
extern JS_FRIEND_API(void)
JS_SetCompartmentPrincipals(JSCompartment *compartment, JSPrincipals *principals);
/* Safe to call with input obj == NULL. Returns non-NULL iff obj != NULL. */
extern JS_FRIEND_API(JSObject *)
JS_ObjectToInnerObject(JSContext *cx, JSObject *obj);
/* Requires obj != NULL. */
extern JS_FRIEND_API(JSObject *)
JS_ObjectToOuterObject(JSContext *cx, JSObject *obj);
extern JS_FRIEND_API(JSObject *)
JS_CloneObject(JSContext *cx, JSObject *obj, JSObject *proto, JSObject *parent);
extern JS_FRIEND_API(JSString *)
JS_BasicObjectToString(JSContext *cx, JS::HandleObject obj);
extern JS_FRIEND_API(JSBool)
js_GetterOnlyPropertyStub(JSContext *cx, JS::HandleObject obj, JS::HandleId id, JSBool strict,
JS::MutableHandleValue vp);
JS_FRIEND_API(void)
js_ReportOverRecursed(JSContext *maybecx);
JS_FRIEND_API(bool)
js_ObjectClassIs(JSContext *cx, JS::HandleObject obj, js::ESClassValue classValue);
JS_FRIEND_API(const char *)
js_ObjectClassName(JSContext *cx, JS::HandleObject obj);
JS_FRIEND_API(bool)
js_AddObjectRoot(JSRuntime *rt, JSObject **objp);
JS_FRIEND_API(void)
js_RemoveObjectRoot(JSRuntime *rt, JSObject **objp);
#ifdef DEBUG
/*
* Routines to print out values during debugging. These are FRIEND_API to help
* the debugger find them and to support temporarily hacking js_Dump* calls
* into other code.
*/
extern JS_FRIEND_API(void)
js_DumpString(JSString *str);
extern JS_FRIEND_API(void)
js_DumpAtom(JSAtom *atom);
extern JS_FRIEND_API(void)
js_DumpObject(JSObject *obj);
extern JS_FRIEND_API(void)
js_DumpChars(const jschar *s, size_t n);
#endif
extern JS_FRIEND_API(bool)
JS_CopyPropertiesFrom(JSContext *cx, JSObject *target, JSObject *obj);
extern JS_FRIEND_API(JSBool)
JS_WrapPropertyDescriptor(JSContext *cx, js::PropertyDescriptor *desc);
extern JS_FRIEND_API(JSBool)
JS_WrapAutoIdVector(JSContext *cx, JS::AutoIdVector &props);
extern JS_FRIEND_API(JSBool)
JS_EnumerateState(JSContext *cx, JS::HandleObject obj, JSIterateOp enum_op,
js::MutableHandleValue statep, js::MutableHandleId idp);
struct JSFunctionSpecWithHelp {
const char *name;
JSNative call;
uint16_t nargs;
uint16_t flags;
const char *usage;
const char *help;
};
#define JS_FN_HELP(name,call,nargs,flags,usage,help) \
{name, call, nargs, (flags) | JSPROP_ENUMERATE | JSFUN_STUB_GSOPS, usage, help}
#define JS_FS_HELP_END \
{NULL, NULL, 0, 0, NULL, NULL}
extern JS_FRIEND_API(bool)
JS_DefineFunctionsWithHelp(JSContext *cx, JSObject *obj, const JSFunctionSpecWithHelp *fs);
typedef bool (* JS_SourceHook)(JSContext *cx, JS::Handle<JSScript*> script,
jschar **src, uint32_t *length);
extern JS_FRIEND_API(void)
JS_SetSourceHook(JSRuntime *rt, JS_SourceHook hook);
namespace js {
inline JSRuntime *
GetRuntime(const JSContext *cx)
{
return ContextFriendFields::get(cx)->runtime_;
}
inline JSCompartment *
GetContextCompartment(const JSContext *cx)
{
return ContextFriendFields::get(cx)->compartment_;
}
inline JS::Zone *
GetContextZone(const JSContext *cx)
{
return ContextFriendFields::get(cx)->zone_;
}
extern JS_FRIEND_API(JS::Zone *)
GetCompartmentZone(JSCompartment *comp);
typedef bool
(* PreserveWrapperCallback)(JSContext *cx, JSObject *obj);
/*
* Dump the complete object graph of heap-allocated things.
* fp is the file for the dump output.
*/
extern JS_FRIEND_API(void)
DumpHeapComplete(JSRuntime *rt, FILE *fp);
#ifdef OLD_GETTER_SETTER_METHODS
JS_FRIEND_API(JSBool) obj_defineGetter(JSContext *cx, unsigned argc, js::Value *vp);
JS_FRIEND_API(JSBool) obj_defineSetter(JSContext *cx, unsigned argc, js::Value *vp);
#endif
extern JS_FRIEND_API(bool)
IsSystemCompartment(JSCompartment *comp);
extern JS_FRIEND_API(bool)
IsSystemZone(JS::Zone *zone);
extern JS_FRIEND_API(bool)
IsAtomsCompartment(JSCompartment *comp);
/*
* Check whether it is OK to assign an undeclared variable with the name
* |propname| at the current location in script. It is not an error if there is
* no current script location, or if that location is not an assignment to an
* undeclared variable. Reports an error if one needs to be reported (and,
* particularly, always reports when it returns false).
*/
extern JS_FRIEND_API(bool)
ReportIfUndeclaredVarAssignment(JSContext *cx, HandleString propname);
/*
* Returns whether we're in a non-strict property set (in that we're in a
* non-strict script and the bytecode we're on is a property set). The return
* value does NOT indicate any sort of exception was thrown: it's just a
* boolean.
*/
extern JS_FRIEND_API(bool)
IsInNonStrictPropertySet(JSContext *cx);
struct WeakMapTracer;
/*
* Weak map tracer callback, called once for every binding of every
* weak map that was live at the time of the last garbage collection.
*
* m will be NULL if the weak map is not contained in a JS Object.
*/
typedef void
(* WeakMapTraceCallback)(WeakMapTracer *trc, JSObject *m,
void *k, JSGCTraceKind kkind,
void *v, JSGCTraceKind vkind);
struct WeakMapTracer {
JSRuntime *runtime;
WeakMapTraceCallback callback;
WeakMapTracer(JSRuntime *rt, WeakMapTraceCallback cb)
: runtime(rt), callback(cb) {}
};
extern JS_FRIEND_API(void)
TraceWeakMaps(WeakMapTracer *trc);
extern JS_FRIEND_API(bool)
AreGCGrayBitsValid(JSRuntime *rt);
typedef void
(*GCThingCallback)(void *closure, void *gcthing);
extern JS_FRIEND_API(void)
VisitGrayWrapperTargets(JS::Zone *zone, GCThingCallback callback, void *closure);
extern JS_FRIEND_API(JSObject *)
GetWeakmapKeyDelegate(JSObject *key);
JS_FRIEND_API(JSGCTraceKind)
GCThingTraceKind(void *thing);
/*
* Invoke cellCallback on every gray JS_OBJECT in the given zone.
*/
extern JS_FRIEND_API(void)
IterateGrayObjects(JS::Zone *zone, GCThingCallback cellCallback, void *data);
#ifdef JS_HAS_CTYPES
extern JS_FRIEND_API(size_t)
SizeOfDataIfCDataObject(mozilla::MallocSizeOf mallocSizeOf, JSObject *obj);
#endif
extern JS_FRIEND_API(JSCompartment *)
GetAnyCompartmentInZone(JS::Zone *zone);
/*
* Shadow declarations of JS internal structures, for access by inline access
* functions below. Do not use these structures in any other way. When adding
* new fields for access by inline methods, make sure to add static asserts to
* the original header file to ensure that offsets are consistent.
*/
namespace shadow {
struct TypeObject {
Class *clasp;
JSObject *proto;
};
struct BaseShape {
js::Class *clasp;
JSObject *parent;
JSObject *_1;
JSCompartment *compartment;
};
class Shape {
public:
shadow::BaseShape *base;
jsid _1;
uint32_t slotInfo;
static const uint32_t FIXED_SLOTS_SHIFT = 27;
};
struct Object {
shadow::Shape *shape;
shadow::TypeObject *type;
js::Value *slots;
js::Value *_1;
size_t numFixedSlots() const { return shape->slotInfo >> Shape::FIXED_SLOTS_SHIFT; }
Value *fixedSlots() const {
return (Value *)(uintptr_t(this) + sizeof(shadow::Object));
}
js::Value &slotRef(size_t slot) const {
size_t nfixed = numFixedSlots();
if (slot < nfixed)
return fixedSlots()[slot];
return slots[slot - nfixed];
}
};
struct Function {
Object base;
uint16_t nargs;
uint16_t flags;
/* Used only for natives */
Native native;
const JSJitInfo *jitinfo;
void *_1;
};
struct Atom {
static const size_t LENGTH_SHIFT = 4;
size_t lengthAndFlags;
const jschar *chars;
};
} /* namespace shadow */
// These are equal to |&{Function,Object,OuterWindow}ProxyObject::class_|. Use
// them in places where you don't want to #include vm/ProxyObject.h.
extern JS_FRIEND_DATA(js::Class* const) FunctionProxyClassPtr;
extern JS_FRIEND_DATA(js::Class* const) ObjectProxyClassPtr;
extern JS_FRIEND_DATA(js::Class* const) OuterWindowProxyClassPtr;
// This is equal to |&JSObject::class_|. Use it in places where you don't want
// to #include jsobj.h.
extern JS_FRIEND_DATA(js::Class* const) ObjectClassPtr;
inline js::Class *
GetObjectClass(JSObject *obj)
{
return reinterpret_cast<const shadow::Object*>(obj)->type->clasp;
}
inline JSClass *
GetObjectJSClass(JSObject *obj)
{
return js::Jsvalify(GetObjectClass(obj));
}
inline bool
IsInnerObject(JSObject *obj) {
return !!GetObjectClass(obj)->ext.outerObject;
}
inline bool
IsOuterObject(JSObject *obj) {
return !!GetObjectClass(obj)->ext.innerObject;
}
JS_FRIEND_API(bool)
IsFunctionObject(JSObject *obj);
JS_FRIEND_API(bool)
IsScopeObject(JSObject *obj);
JS_FRIEND_API(bool)
IsCallObject(JSObject *obj);
inline JSObject *
GetObjectParent(JSObject *obj)
{
JS_ASSERT(!IsScopeObject(obj));
return reinterpret_cast<shadow::Object*>(obj)->shape->base->parent;
}
static JS_ALWAYS_INLINE JSCompartment *
GetObjectCompartment(JSObject *obj)
{
return reinterpret_cast<shadow::Object*>(obj)->shape->base->compartment;
}
JS_FRIEND_API(JSObject *)
GetObjectParentMaybeScope(JSObject *obj);
JS_FRIEND_API(JSObject *)
GetGlobalForObjectCrossCompartment(JSObject *obj);
// For legacy consumers only. This whole concept is going away soon.
JS_FRIEND_API(JSObject *)
DefaultObjectForContextOrNull(JSContext *cx);
JS_FRIEND_API(void)
SetDefaultObjectForContext(JSContext *cx, JSObject *obj);
JS_FRIEND_API(void)
NotifyAnimationActivity(JSObject *obj);
JS_FRIEND_API(bool)
IsOriginalScriptFunction(JSFunction *fun);
/*
* Return the outermost enclosing function (script) of the scripted caller.
* This function returns NULL in several cases:
* - no script is running on the context
* - the caller is in global or eval code
* In particular, this function will "stop" its outermost search at eval() and
* thus it will really return the outermost enclosing function *since the
* innermost eval*.
*/
JS_FRIEND_API(JSScript *)
GetOutermostEnclosingFunctionOfScriptedCaller(JSContext *cx);
JS_FRIEND_API(JSFunction *)
DefineFunctionWithReserved(JSContext *cx, JSObject *obj, const char *name, JSNative call,
unsigned nargs, unsigned attrs);
JS_FRIEND_API(JSFunction *)
NewFunctionWithReserved(JSContext *cx, JSNative call, unsigned nargs, unsigned flags,
JSObject *parent, const char *name);
JS_FRIEND_API(JSFunction *)
NewFunctionByIdWithReserved(JSContext *cx, JSNative native, unsigned nargs, unsigned flags,
JSObject *parent, jsid id);
JS_FRIEND_API(JSObject *)
InitClassWithReserved(JSContext *cx, JSObject *obj, JSObject *parent_proto,
JSClass *clasp, JSNative constructor, unsigned nargs,
const JSPropertySpec *ps, const JSFunctionSpec *fs,
const JSPropertySpec *static_ps, const JSFunctionSpec *static_fs);
JS_FRIEND_API(const Value &)
GetFunctionNativeReserved(JSObject *fun, size_t which);
JS_FRIEND_API(void)
SetFunctionNativeReserved(JSObject *fun, size_t which, const Value &val);
inline bool
GetObjectProto(JSContext *cx, JS::Handle<JSObject*> obj, JS::MutableHandle<JSObject*> proto)
{
js::Class *clasp = GetObjectClass(obj);
if (clasp == js::ObjectProxyClassPtr ||
clasp == js::OuterWindowProxyClassPtr ||
clasp == js::FunctionProxyClassPtr)
{
return JS_GetPrototype(cx, obj, proto);
}
proto.set(reinterpret_cast<const shadow::Object*>(obj.get())->type->proto);
return true;
}
inline void *
GetObjectPrivate(JSObject *obj)
{
const shadow::Object *nobj = reinterpret_cast<const shadow::Object*>(obj);
void **addr = reinterpret_cast<void**>(&nobj->fixedSlots()[nobj->numFixedSlots()]);
return *addr;
}
/*
* Get a slot that is both reserved for object's clasp *and* is fixed (fits
* within the maximum capacity for the object's fixed slots).
*/
inline const Value &
GetReservedSlot(JSObject *obj, size_t slot)
{
JS_ASSERT(slot < JSCLASS_RESERVED_SLOTS(GetObjectClass(obj)));
return reinterpret_cast<const shadow::Object *>(obj)->slotRef(slot);
}
JS_FRIEND_API(void)
SetReservedSlotWithBarrier(JSObject *obj, size_t slot, const Value &value);
inline void
SetReservedSlot(JSObject *obj, size_t slot, const Value &value)
{
JS_ASSERT(slot < JSCLASS_RESERVED_SLOTS(GetObjectClass(obj)));
shadow::Object *sobj = reinterpret_cast<shadow::Object *>(obj);
if (sobj->slotRef(slot).isMarkable()
#ifdef JSGC_GENERATIONAL
|| value.isMarkable()
#endif
)
{
SetReservedSlotWithBarrier(obj, slot, value);
} else {
sobj->slotRef(slot) = value;
}
}
JS_FRIEND_API(uint32_t)
GetObjectSlotSpan(JSObject *obj);
inline const Value &
GetObjectSlot(JSObject *obj, size_t slot)
{
JS_ASSERT(slot < GetObjectSlotSpan(obj));
return reinterpret_cast<const shadow::Object *>(obj)->slotRef(slot);
}
inline const jschar *
GetAtomChars(JSAtom *atom)
{
return reinterpret_cast<shadow::Atom *>(atom)->chars;
}
inline size_t
GetAtomLength(JSAtom *atom)
{
using shadow::Atom;
return reinterpret_cast<Atom*>(atom)->lengthAndFlags >> Atom::LENGTH_SHIFT;
}
inline JSLinearString *
AtomToLinearString(JSAtom *atom)
{
return reinterpret_cast<JSLinearString *>(atom);
}
static inline js::PropertyOp
CastAsJSPropertyOp(JSObject *object)
{
return JS_DATA_TO_FUNC_PTR(js::PropertyOp, object);
}
static inline js::StrictPropertyOp
CastAsJSStrictPropertyOp(JSObject *object)
{
return JS_DATA_TO_FUNC_PTR(js::StrictPropertyOp, object);
}
JS_FRIEND_API(bool)
GetPropertyNames(JSContext *cx, JSObject *obj, unsigned flags, js::AutoIdVector *props);
JS_FRIEND_API(bool)
AppendUnique(JSContext *cx, AutoIdVector &base, AutoIdVector &others);
JS_FRIEND_API(bool)
GetGeneric(JSContext *cx, JSObject *obj, JSObject *receiver, jsid id, Value *vp);
JS_FRIEND_API(bool)
StringIsArrayIndex(JSLinearString *str, uint32_t *indexp);
JS_FRIEND_API(void)
SetPreserveWrapperCallback(JSRuntime *rt, PreserveWrapperCallback callback);
JS_FRIEND_API(bool)
IsObjectInContextCompartment(JSObject *obj, const JSContext *cx);
/*
* NB: these flag bits are encoded into the bytecode stream in the immediate
* operand of JSOP_ITER, so don't change them without advancing vm/Xdr.h's
* XDR_BYTECODE_VERSION.
*/
#define JSITER_ENUMERATE 0x1 /* for-in compatible hidden default iterator */
#define JSITER_FOREACH 0x2 /* return [key, value] pair rather than key */
#define JSITER_KEYVALUE 0x4 /* destructuring for-in wants [key, value] */
#define JSITER_OWNONLY 0x8 /* iterate over obj's own properties only */
#define JSITER_HIDDEN 0x10 /* also enumerate non-enumerable properties */
#define JSITER_FOR_OF 0x20 /* harmony for-of loop */
inline uintptr_t
GetNativeStackLimit(const JSRuntime *rt)
{
return PerThreadDataFriendFields::getMainThread(rt)->nativeStackLimit;
}
inline uintptr_t
GetNativeStackLimit(JSContext *cx)
{
return GetNativeStackLimit(GetRuntime(cx));
}
/*
* These macros report a stack overflow and run |onerror| if we are close to
* using up the C stack. The JS_CHECK_CHROME_RECURSION variant gives us a little
* extra space so that we can ensure that crucial code is able to run.
*/
#define JS_CHECK_RECURSION(cx, onerror) \
JS_BEGIN_MACRO \
int stackDummy_; \
if (!JS_CHECK_STACK_SIZE(js::GetNativeStackLimit(cx), &stackDummy_)) { \
js_ReportOverRecursed(cx); \
onerror; \
} \
JS_END_MACRO
#define JS_CHECK_RECURSION_WITH_SP_DONT_REPORT(cx, sp, onerror) \
JS_BEGIN_MACRO \
if (!JS_CHECK_STACK_SIZE(js::GetNativeStackLimit(cx), sp)) { \
onerror; \
} \
JS_END_MACRO
#define JS_CHECK_CHROME_RECURSION(cx, onerror) \
JS_BEGIN_MACRO \
int stackDummy_; \
if (!JS_CHECK_STACK_SIZE_WITH_TOLERANCE(js::GetNativeStackLimit(cx), \
&stackDummy_, \
1024 * sizeof(size_t))) \
{ \
js_ReportOverRecursed(cx); \
onerror; \
} \
JS_END_MACRO
JS_FRIEND_API(void)
StartPCCountProfiling(JSContext *cx);
JS_FRIEND_API(void)
StopPCCountProfiling(JSContext *cx);
JS_FRIEND_API(void)
PurgePCCounts(JSContext *cx);
JS_FRIEND_API(size_t)
GetPCCountScriptCount(JSContext *cx);
JS_FRIEND_API(JSString *)
GetPCCountScriptSummary(JSContext *cx, size_t script);
JS_FRIEND_API(JSString *)
GetPCCountScriptContents(JSContext *cx, size_t script);
/*
* A call stack can be specified to the JS engine such that all JS entry/exits
* to functions push/pop an entry to/from the specified stack.
*
* For more detailed information, see vm/SPSProfiler.h
*/
class ProfileEntry
{
/*
* All fields are marked volatile to prevent the compiler from re-ordering
* instructions. Namely this sequence:
*
* entry[size] = ...;
* size++;
*
* If the size modification were somehow reordered before the stores, then
* if a sample were taken it would be examining bogus information.
*
* A ProfileEntry represents both a C++ profile entry and a JS one. Both use
* the string as a description, but JS uses the sp as NULL to indicate that
* it is a JS entry. The script_ is then only ever examined for a JS entry,
* and the idx is used by both, but with different meanings.
*/
const char * volatile string; // Descriptive string of this entry
void * volatile sp; // Relevant stack pointer for the entry
JSScript * volatile script_; // if js(), non-null script which is running
int32_t volatile idx; // if js(), idx of pc, otherwise line number
public:
/*
* All of these methods are marked with the 'volatile' keyword because SPS's
* representation of the stack is stored such that all ProfileEntry
* instances are volatile. These methods would not be available unless they
* were marked as volatile as well
*/
bool js() volatile {
JS_ASSERT_IF(sp == NULL, script_ != NULL);
return sp == NULL;
}
uint32_t line() volatile { JS_ASSERT(!js()); return idx; }
JSScript *script() volatile { JS_ASSERT(js()); return script_; }
void *stackAddress() volatile { return sp; }
const char *label() volatile { return string; }
void setLine(uint32_t aLine) volatile { JS_ASSERT(!js()); idx = aLine; }
void setLabel(const char *aString) volatile { string = aString; }
void setStackAddress(void *aSp) volatile { sp = aSp; }
void setScript(JSScript *aScript) volatile { script_ = aScript; }
/* we can't know the layout of JSScript, so look in vm/SPSProfiler.cpp */
JS_FRIEND_API(jsbytecode *) pc() volatile;
JS_FRIEND_API(void) setPC(jsbytecode *pc) volatile;
static size_t offsetOfString() { return offsetof(ProfileEntry, string); }
static size_t offsetOfStackAddress() { return offsetof(ProfileEntry, sp); }
static size_t offsetOfPCIdx() { return offsetof(ProfileEntry, idx); }
static size_t offsetOfScript() { return offsetof(ProfileEntry, script_); }
/*
* The index used in the entry can either be a line number or the offset of
* a pc into a script's code. To signify a NULL pc, use a -1 index. This is
* checked against in pc() and setPC() to set/get the right pc.
*/
static const int32_t NullPCIndex = -1;
};
JS_FRIEND_API(void)
SetRuntimeProfilingStack(JSRuntime *rt, ProfileEntry *stack, uint32_t *size,
uint32_t max);
JS_FRIEND_API(void)
EnableRuntimeProfilingStack(JSRuntime *rt, bool enabled);
JS_FRIEND_API(jsbytecode*)
ProfilingGetPC(JSRuntime *rt, JSScript *script, void *ip);
#ifdef JS_THREADSAFE
JS_FRIEND_API(bool)
ContextHasOutstandingRequests(const JSContext *cx);
#endif
JS_FRIEND_API(bool)
HasUnrootedGlobal(const JSContext *cx);
typedef void
(* ActivityCallback)(void *arg, JSBool active);
/*
* Sets a callback that is run whenever the runtime goes idle - the
* last active request ceases - and begins activity - when it was
* idle and a request begins.
*/
JS_FRIEND_API(void)
SetActivityCallback(JSRuntime *rt, ActivityCallback cb, void *arg);
extern JS_FRIEND_API(const JSStructuredCloneCallbacks *)
GetContextStructuredCloneCallbacks(JSContext *cx);
extern JS_FRIEND_API(bool)
CanCallContextDebugHandler(JSContext *cx);
extern JS_FRIEND_API(JSTrapStatus)
CallContextDebugHandler(JSContext *cx, JSScript *script, jsbytecode *bc, Value *rval);
extern JS_FRIEND_API(bool)
IsContextRunningJS(JSContext *cx);
typedef void
(* AnalysisPurgeCallback)(JSRuntime *rt, JS::Handle<JSFlatString*> desc);
extern JS_FRIEND_API(AnalysisPurgeCallback)
SetAnalysisPurgeCallback(JSRuntime *rt, AnalysisPurgeCallback callback);
typedef JSBool
(* DOMInstanceClassMatchesProto)(JS::HandleObject protoObject, uint32_t protoID,
uint32_t depth);
struct JSDOMCallbacks {
DOMInstanceClassMatchesProto instanceClassMatchesProto;
};
typedef struct JSDOMCallbacks DOMCallbacks;
extern JS_FRIEND_API(void)
SetDOMCallbacks(JSRuntime *rt, const DOMCallbacks *callbacks);
extern JS_FRIEND_API(const DOMCallbacks *)
GetDOMCallbacks(JSRuntime *rt);
extern JS_FRIEND_API(JSObject *)
GetTestingFunctions(JSContext *cx);
/*
* Helper to convert FreeOp to JSFreeOp when the definition of FreeOp is not
* available and the compiler does not know that FreeOp inherits from
* JSFreeOp.
*/
inline JSFreeOp *
CastToJSFreeOp(FreeOp *fop)
{
return reinterpret_cast<JSFreeOp *>(fop);
}
/* Implemented in jsexn.cpp. */
/*
* Get an error type name from a JSExnType constant.
* Returns NULL for invalid arguments and JSEXN_INTERNALERR
*/
extern JS_FRIEND_API(const jschar*)
GetErrorTypeName(JSContext* cx, int16_t exnType);
#ifdef DEBUG
extern JS_FRIEND_API(unsigned)
GetEnterCompartmentDepth(JSContext* cx);
#endif
/* Implemented in jswrapper.cpp. */
typedef enum NukeReferencesToWindow {
NukeWindowReferences,
DontNukeWindowReferences
} NukeReferencesToWindow;
/*
* These filters are designed to be ephemeral stack classes, and thus don't
* do any rooting or holding of their members.
*/
struct CompartmentFilter {
virtual bool match(JSCompartment *c) const = 0;
};
struct AllCompartments : public CompartmentFilter {
virtual bool match(JSCompartment *c) const { return true; }
};
struct ContentCompartmentsOnly : public CompartmentFilter {
virtual bool match(JSCompartment *c) const {
return !IsSystemCompartment(c);
}
};
struct ChromeCompartmentsOnly : public CompartmentFilter {
virtual bool match(JSCompartment *c) const {
return IsSystemCompartment(c);
}
};
struct SingleCompartment : public CompartmentFilter {
JSCompartment *ours;
SingleCompartment(JSCompartment *c) : ours(c) {}
virtual bool match(JSCompartment *c) const { return c == ours; }
};
struct CompartmentsWithPrincipals : public CompartmentFilter {
JSPrincipals *principals;
CompartmentsWithPrincipals(JSPrincipals *p) : principals(p) {}
virtual bool match(JSCompartment *c) const {
return JS_GetCompartmentPrincipals(c) == principals;
}
};
extern JS_FRIEND_API(JSBool)
NukeCrossCompartmentWrappers(JSContext* cx,
const CompartmentFilter& sourceFilter,
const CompartmentFilter& targetFilter,
NukeReferencesToWindow nukeReferencesToWindow);
/* Specify information about DOMProxy proxies in the DOM, for use by ICs. */
/*
* The DOMProxyShadowsCheck function will be called to check if the property for
* id should be gotten from the prototype, or if there is an own property that
* shadows it.
* If DoesntShadow is returned then the slot at listBaseExpandoSlot should
* either be undefined or point to an expando object that would contain the own
* property.
* If DoesntShadowUnique is returned then the slot at listBaseExpandoSlot should
* contain a private pointer to a ExpandoAndGeneration, which contains a
* JS::Value that should either be undefined or point to an expando object, and
* a uint32 value. If that value changes then the IC for getting a property will
* be invalidated.
*/
struct ExpandoAndGeneration {
ExpandoAndGeneration()
: expando(UndefinedValue()),
generation(0)
{}
void Unlink()
{
++generation;
expando.setUndefined();
}
JS::Heap<JS::Value> expando;
uint32_t generation;
};
typedef enum DOMProxyShadowsResult {
ShadowCheckFailed,
Shadows,
DoesntShadow,
DoesntShadowUnique
} DOMProxyShadowsResult;
typedef DOMProxyShadowsResult
(* DOMProxyShadowsCheck)(JSContext* cx, JS::HandleObject object, JS::HandleId id);
JS_FRIEND_API(void)
SetDOMProxyInformation(void *domProxyHandlerFamily, uint32_t domProxyExpandoSlot,
DOMProxyShadowsCheck domProxyShadowsCheck);
void *GetDOMProxyHandlerFamily();
uint32_t GetDOMProxyExpandoSlot();
DOMProxyShadowsCheck GetDOMProxyShadowsCheck();
} /* namespace js */
/* Implemented in jsdate.cpp. */
/*
* Detect whether the internal date value is NaN. (Because failure is
* out-of-band for js_DateGet*)
*/
extern JS_FRIEND_API(JSBool)
js_DateIsValid(JSObject* obj);
extern JS_FRIEND_API(double)
js_DateGetMsecSinceEpoch(JSObject *obj);
/* Implemented in jscntxt.cpp. */
/*
* Report an exception, which is currently realized as a printf-style format
* string and its arguments.
*/
typedef enum JSErrNum {
#define MSG_DEF(name, number, count, exception, format) \
name = number,
#include "js.msg"
#undef MSG_DEF
JSErr_Limit
} JSErrNum;
extern JS_FRIEND_API(const JSErrorFormatString *)
js_GetErrorMessage(void *userRef, const char *locale, const unsigned errorNumber);
/* Implemented in jsclone.cpp. */
extern JS_FRIEND_API(uint64_t)
js_GetSCOffset(JSStructuredCloneWriter* writer);
/* Typed Array functions, implemented in jstypedarray.cpp */
namespace js {
namespace ArrayBufferView {
enum ViewType {
TYPE_INT8 = 0,
TYPE_UINT8,
TYPE_INT16,
TYPE_UINT16,
TYPE_INT32,
TYPE_UINT32,
TYPE_FLOAT32,
TYPE_FLOAT64,
/*
* Special type that is a uint8_t, but assignments are clamped to [0, 256).
* Treat the raw data type as a uint8_t.
*/
TYPE_UINT8_CLAMPED,
/*
* Type returned for a DataView. Note that there is no single element type
* in this case.
*/
TYPE_DATAVIEW,
TYPE_MAX
};
} /* namespace ArrayBufferView */
/*
* A helper for building up an ArrayBuffer object's data
* before creating the ArrayBuffer itself. Will do doubling
* based reallocation, up to an optional maximum growth given.
*
* When all the data has been appended, call getArrayBuffer,
* passing in the JSContext* for which the ArrayBuffer object
* is to be created. This also implicitly resets the builder,
* or it can be reset explicitly at any point by calling reset().
*/
class ArrayBufferBuilder
{
void *rawcontents_;
uint8_t *dataptr_;
uint32_t capacity_;
uint32_t length_;
public:
ArrayBufferBuilder()
: rawcontents_(NULL),
dataptr_(NULL),
capacity_(0),
length_(0)
{
}
~ArrayBufferBuilder() {
reset();
}
void reset() {
if (rawcontents_)
JS_free(NULL, rawcontents_);
rawcontents_ = dataptr_ = NULL;
capacity_ = length_ = 0;
}
// will truncate if newcap is < length()
bool setCapacity(uint32_t newcap) {
if (!JS_ReallocateArrayBufferContents(NULL, newcap, &rawcontents_, &dataptr_))
return false;
capacity_ = newcap;
if (length_ > newcap)
length_ = newcap;
return true;
}
// Append datalen bytes from data to the current buffer. If we
// need to grow the buffer, grow by doubling the size up to a
// maximum of maxgrowth (if given). If datalen is greater than
// what the new capacity would end up as, then grow by datalen.
//
// The data parameter must not overlap with anything beyond the
// builder's current valid contents [0..length)
bool append(const uint8_t *newdata, uint32_t datalen, uint32_t maxgrowth = 0) {
if (length_ + datalen > capacity_) {
uint32_t newcap;
// double while under maxgrowth or if not specified
if (!maxgrowth || capacity_ < maxgrowth)
newcap = capacity_ * 2;
else
newcap = capacity_ + maxgrowth;
// but make sure there's always enough to satisfy our request
if (newcap < length_ + datalen)
newcap = length_ + datalen;
// did we overflow?
if (newcap < capacity_)
return false;
if (!setCapacity(newcap))
return false;
}
// assert that the region isn't overlapping so we can memcpy;
JS_ASSERT(!areOverlappingRegions(newdata, datalen, dataptr_ + length_, datalen));
memcpy(dataptr_ + length_, newdata, datalen);
length_ += datalen;
return true;
}
uint8_t *data() {
return dataptr_;
}
uint32_t length() {
return length_;
}
uint32_t capacity() {
return capacity_;
}
JSObject* getArrayBuffer(JSContext *cx) {
// we need to check for length_ == 0, because nothing may have been
// added
if (capacity_ > length_ || length_ == 0) {
if (!setCapacity(length_))
return NULL;
}
JSObject* obj = JS_NewArrayBufferWithContents(cx, rawcontents_);
if (!obj)
return NULL;
rawcontents_ = dataptr_ = NULL;
length_ = capacity_ = 0;
return obj;
}
protected:
static bool areOverlappingRegions(const uint8_t *start1, uint32_t length1,
const uint8_t *start2, uint32_t length2)
{
const uint8_t *end1 = start1 + length1;
const uint8_t *end2 = start2 + length2;
const uint8_t *max_start = start1 > start2 ? start1 : start2;
const uint8_t *min_end = end1 < end2 ? end1 : end2;
return max_start < min_end;
}
};
} /* namespace js */
typedef js::ArrayBufferView::ViewType JSArrayBufferViewType;
/*
* Create a new typed array with nelements elements.
*
* These functions (except the WithBuffer variants) fill in the array with zeros.
*/
extern JS_FRIEND_API(JSObject *)
JS_NewInt8Array(JSContext *cx, uint32_t nelements);
extern JS_FRIEND_API(JSObject *)
JS_NewUint8Array(JSContext *cx, uint32_t nelements);
extern JS_FRIEND_API(JSObject *)
JS_NewUint8ClampedArray(JSContext *cx, uint32_t nelements);
extern JS_FRIEND_API(JSObject *)
JS_NewInt16Array(JSContext *cx, uint32_t nelements);
extern JS_FRIEND_API(JSObject *)
JS_NewUint16Array(JSContext *cx, uint32_t nelements);
extern JS_FRIEND_API(JSObject *)
JS_NewInt32Array(JSContext *cx, uint32_t nelements);
extern JS_FRIEND_API(JSObject *)
JS_NewUint32Array(JSContext *cx, uint32_t nelements);
extern JS_FRIEND_API(JSObject *)
JS_NewFloat32Array(JSContext *cx, uint32_t nelements);
extern JS_FRIEND_API(JSObject *)
JS_NewFloat64Array(JSContext *cx, uint32_t nelements);
/*
* Create a new typed array and copy in values from the given object. The
* object is used as if it were an array; that is, the new array (if
* successfully created) will have length given by array.length, and its
* elements will be those specified by array[0], array[1], and so on, after
* conversion to the typed array element type.
*/
extern JS_FRIEND_API(JSObject *)
JS_NewInt8ArrayFromArray(JSContext *cx, JSObject *array);
extern JS_FRIEND_API(JSObject *)
JS_NewUint8ArrayFromArray(JSContext *cx, JSObject *array);
extern JS_FRIEND_API(JSObject *)
JS_NewUint8ClampedArrayFromArray(JSContext *cx, JSObject *array);
extern JS_FRIEND_API(JSObject *)
JS_NewInt16ArrayFromArray(JSContext *cx, JSObject *array);
extern JS_FRIEND_API(JSObject *)
JS_NewUint16ArrayFromArray(JSContext *cx, JSObject *array);
extern JS_FRIEND_API(JSObject *)
JS_NewInt32ArrayFromArray(JSContext *cx, JSObject *array);
extern JS_FRIEND_API(JSObject *)
JS_NewUint32ArrayFromArray(JSContext *cx, JSObject *array);
extern JS_FRIEND_API(JSObject *)
JS_NewFloat32ArrayFromArray(JSContext *cx, JSObject *array);
extern JS_FRIEND_API(JSObject *)
JS_NewFloat64ArrayFromArray(JSContext *cx, JSObject *array);
/*
* Create a new typed array using the given ArrayBuffer for storage. The
* length value is optional; if -1 is passed, enough elements to use up the
* remainder of the byte array is used as the default value.
*/
extern JS_FRIEND_API(JSObject *)
JS_NewInt8ArrayWithBuffer(JSContext *cx, JSObject *arrayBuffer,
uint32_t byteOffset, int32_t length);
extern JS_FRIEND_API(JSObject *)
JS_NewUint8ArrayWithBuffer(JSContext *cx, JSObject *arrayBuffer,
uint32_t byteOffset, int32_t length);
extern JS_FRIEND_API(JSObject *)
JS_NewUint8ClampedArrayWithBuffer(JSContext *cx, JSObject *arrayBuffer,
uint32_t byteOffset, int32_t length);
extern JS_FRIEND_API(JSObject *)
JS_NewInt16ArrayWithBuffer(JSContext *cx, JSObject *arrayBuffer,
uint32_t byteOffset, int32_t length);
extern JS_FRIEND_API(JSObject *)
JS_NewUint16ArrayWithBuffer(JSContext *cx, JSObject *arrayBuffer,
uint32_t byteOffset, int32_t length);
extern JS_FRIEND_API(JSObject *)
JS_NewInt32ArrayWithBuffer(JSContext *cx, JSObject *arrayBuffer,
uint32_t byteOffset, int32_t length);
extern JS_FRIEND_API(JSObject *)
JS_NewUint32ArrayWithBuffer(JSContext *cx, JSObject *arrayBuffer,
uint32_t byteOffset, int32_t length);
extern JS_FRIEND_API(JSObject *)
JS_NewFloat32ArrayWithBuffer(JSContext *cx, JSObject *arrayBuffer,
uint32_t byteOffset, int32_t length);
extern JS_FRIEND_API(JSObject *)
JS_NewFloat64ArrayWithBuffer(JSContext *cx, JSObject *arrayBuffer,
uint32_t byteOffset, int32_t length);
/*
* Create a new ArrayBuffer with the given byte length.
*/
extern JS_FRIEND_API(JSObject *)
JS_NewArrayBuffer(JSContext *cx, uint32_t nbytes);
/*
* Check whether obj supports JS_GetTypedArray* APIs. Note that this may return
* false if a security wrapper is encountered that denies the unwrapping. If
* this test or one of the JS_Is*Array tests succeeds, then it is safe to call
* the various accessor JSAPI calls defined below.
*/
extern JS_FRIEND_API(JSBool)
JS_IsTypedArrayObject(JSObject *obj);
/*
* Check whether obj supports JS_GetArrayBufferView* APIs. Note that this may
* return false if a security wrapper is encountered that denies the
* unwrapping. If this test or one of the more specific tests succeeds, then it
* is safe to call the various ArrayBufferView accessor JSAPI calls defined
* below.
*/
extern JS_FRIEND_API(JSBool)
JS_IsArrayBufferViewObject(JSObject *obj);
/*
* Test for specific typed array types (ArrayBufferView subtypes)
*/
extern JS_FRIEND_API(JSBool)
JS_IsInt8Array(JSObject *obj);
extern JS_FRIEND_API(JSBool)
JS_IsUint8Array(JSObject *obj);
extern JS_FRIEND_API(JSBool)
JS_IsUint8ClampedArray(JSObject *obj);
extern JS_FRIEND_API(JSBool)
JS_IsInt16Array(JSObject *obj);
extern JS_FRIEND_API(JSBool)
JS_IsUint16Array(JSObject *obj);
extern JS_FRIEND_API(JSBool)
JS_IsInt32Array(JSObject *obj);
extern JS_FRIEND_API(JSBool)
JS_IsUint32Array(JSObject *obj);
extern JS_FRIEND_API(JSBool)
JS_IsFloat32Array(JSObject *obj);
extern JS_FRIEND_API(JSBool)
JS_IsFloat64Array(JSObject *obj);
/*
* Unwrap Typed arrays all at once. Return NULL without throwing if the object
* cannot be viewed as the correct typed array, or the typed array object on
* success, filling both outparameters.
*/
extern JS_FRIEND_API(JSObject *)
JS_GetObjectAsInt8Array(JSObject *obj, uint32_t *length, int8_t **data);
extern JS_FRIEND_API(JSObject *)
JS_GetObjectAsUint8Array(JSObject *obj, uint32_t *length, uint8_t **data);
extern JS_FRIEND_API(JSObject *)
JS_GetObjectAsUint8ClampedArray(JSObject *obj, uint32_t *length, uint8_t **data);
extern JS_FRIEND_API(JSObject *)
JS_GetObjectAsInt16Array(JSObject *obj, uint32_t *length, int16_t **data);
extern JS_FRIEND_API(JSObject *)
JS_GetObjectAsUint16Array(JSObject *obj, uint32_t *length, uint16_t **data);
extern JS_FRIEND_API(JSObject *)
JS_GetObjectAsInt32Array(JSObject *obj, uint32_t *length, int32_t **data);
extern JS_FRIEND_API(JSObject *)
JS_GetObjectAsUint32Array(JSObject *obj, uint32_t *length, uint32_t **data);
extern JS_FRIEND_API(JSObject *)
JS_GetObjectAsFloat32Array(JSObject *obj, uint32_t *length, float **data);
extern JS_FRIEND_API(JSObject *)
JS_GetObjectAsFloat64Array(JSObject *obj, uint32_t *length, double **data);
extern JS_FRIEND_API(JSObject *)
JS_GetObjectAsArrayBufferView(JSObject *obj, uint32_t *length, uint8_t **data);
extern JS_FRIEND_API(JSObject *)
JS_GetObjectAsArrayBuffer(JSObject *obj, uint32_t *length, uint8_t **data);
/*
* Get the type of elements in a typed array, or TYPE_DATAVIEW if a DataView.
*
* |obj| must have passed a JS_IsArrayBufferView/JS_Is*Array test, or somehow
* be known that it would pass such a test: it is an ArrayBufferView or a
* wrapper of an ArrayBufferView, and the unwrapping will succeed.
*/
extern JS_FRIEND_API(JSArrayBufferViewType)
JS_GetArrayBufferViewType(JSObject *obj);
/*
* Check whether obj supports the JS_GetArrayBuffer* APIs. Note that this may
* return false if a security wrapper is encountered that denies the
* unwrapping. If this test succeeds, then it is safe to call the various
* accessor JSAPI calls defined below.
*/
extern JS_FRIEND_API(JSBool)
JS_IsArrayBufferObject(JSObject *obj);
/*
* Return the available byte length of an array buffer.
*
* |obj| must have passed a JS_IsArrayBufferObject test, or somehow be known
* that it would pass such a test: it is an ArrayBuffer or a wrapper of an
* ArrayBuffer, and the unwrapping will succeed.
*/
extern JS_FRIEND_API(uint32_t)
JS_GetArrayBufferByteLength(JSObject *obj);
/*
* Return a pointer to an array buffer's data. The buffer is still owned by the
* array buffer object, and should not be modified on another thread. The
* returned pointer is stable across GCs.
*
* |obj| must have passed a JS_IsArrayBufferObject test, or somehow be known
* that it would pass such a test: it is an ArrayBuffer or a wrapper of an
* ArrayBuffer, and the unwrapping will succeed.
*/
extern JS_FRIEND_API(uint8_t *)
JS_GetArrayBufferData(JSObject *obj);
/*
* Return the number of elements in a typed array.
*
* |obj| must have passed a JS_IsTypedArrayObject/JS_Is*Array test, or somehow
* be known that it would pass such a test: it is a typed array or a wrapper of
* a typed array, and the unwrapping will succeed.
*/
extern JS_FRIEND_API(uint32_t)
JS_GetTypedArrayLength(JSObject *obj);
/*
* Return the byte offset from the start of an array buffer to the start of a
* typed array view.
*
* |obj| must have passed a JS_IsTypedArrayObject/JS_Is*Array test, or somehow
* be known that it would pass such a test: it is a typed array or a wrapper of
* a typed array, and the unwrapping will succeed.
*/
extern JS_FRIEND_API(uint32_t)
JS_GetTypedArrayByteOffset(JSObject *obj);
/*
* Return the byte length of a typed array.
*
* |obj| must have passed a JS_IsTypedArrayObject/JS_Is*Array test, or somehow
* be known that it would pass such a test: it is a typed array or a wrapper of
* a typed array, and the unwrapping will succeed.
*/
extern JS_FRIEND_API(uint32_t)
JS_GetTypedArrayByteLength(JSObject *obj);
/*
* Check whether obj supports JS_ArrayBufferView* APIs. Note that this may
* return false if a security wrapper is encountered that denies the
* unwrapping.
*/
extern JS_FRIEND_API(JSBool)
JS_IsArrayBufferViewObject(JSObject *obj);
/*
* More generic name for JS_GetTypedArrayByteLength to cover DataViews as well
*/
extern JS_FRIEND_API(uint32_t)
JS_GetArrayBufferViewByteLength(JSObject *obj);
/*
* Return a pointer to the start of the data referenced by a typed array. The
* data is still owned by the typed array, and should not be modified on
* another thread.
*
* |obj| must have passed a JS_Is*Array test, or somehow be known that it would
* pass such a test: it is a typed array or a wrapper of a typed array, and the
* unwrapping will succeed.
*/
extern JS_FRIEND_API(int8_t *)
JS_GetInt8ArrayData(JSObject *obj);
extern JS_FRIEND_API(uint8_t *)
JS_GetUint8ArrayData(JSObject *obj);
extern JS_FRIEND_API(uint8_t *)
JS_GetUint8ClampedArrayData(JSObject *obj);
extern JS_FRIEND_API(int16_t *)
JS_GetInt16ArrayData(JSObject *obj);
extern JS_FRIEND_API(uint16_t *)
JS_GetUint16ArrayData(JSObject *obj);
extern JS_FRIEND_API(int32_t *)
JS_GetInt32ArrayData(JSObject *obj);
extern JS_FRIEND_API(uint32_t *)
JS_GetUint32ArrayData(JSObject *obj);
extern JS_FRIEND_API(float *)
JS_GetFloat32ArrayData(JSObject *obj);
extern JS_FRIEND_API(double *)
JS_GetFloat64ArrayData(JSObject *obj);
/*
* Same as above, but for any kind of ArrayBufferView. Prefer the type-specific
* versions when possible.
*/
extern JS_FRIEND_API(void *)
JS_GetArrayBufferViewData(JSObject *obj);
/*
* Return the ArrayBuffer underlying an ArrayBufferView. If the buffer has been
* neutered, this will still return the neutered buffer. |obj| must be an
* object that would return true for JS_IsArrayBufferViewObject().
*/
extern JS_FRIEND_API(JSObject *)
JS_GetArrayBufferViewBuffer(JSObject *obj);
/*
* Check whether obj supports JS_GetDataView* APIs.
*/
JS_FRIEND_API(JSBool)
JS_IsDataViewObject(JSObject *obj);
/*
* Return the byte offset of a data view into its array buffer. |obj| must be a
* DataView.
*
* |obj| must have passed a JS_IsDataViewObject test, or somehow be known that
* it would pass such a test: it is a data view or a wrapper of a data view,
* and the unwrapping will succeed.
*/
JS_FRIEND_API(uint32_t)
JS_GetDataViewByteOffset(JSObject *obj);
/*
* Return the byte length of a data view.
*
* |obj| must have passed a JS_IsDataViewObject test, or somehow be known that
* it would pass such a test: it is a data view or a wrapper of a data view,
* and the unwrapping will succeed. If cx is NULL, then DEBUG builds may be
* unable to assert when unwrapping should be disallowed.
*/
JS_FRIEND_API(uint32_t)
JS_GetDataViewByteLength(JSObject *obj);
/*
* Return a pointer to the beginning of the data referenced by a DataView.
*
* |obj| must have passed a JS_IsDataViewObject test, or somehow be known that
* it would pass such a test: it is a data view or a wrapper of a data view,
* and the unwrapping will succeed. If cx is NULL, then DEBUG builds may be
* unable to assert when unwrapping should be disallowed.
*/
JS_FRIEND_API(void *)
JS_GetDataViewData(JSObject *obj);
/*
* A class, expected to be passed by value, which represents the CallArgs for a
* JSJitGetterOp.
*/
class JSJitGetterCallArgs : protected JS::MutableHandleValue
{
public:
explicit JSJitGetterCallArgs(const JS::CallArgs& args)
: JS::MutableHandleValue(args.rval())
{}
explicit JSJitGetterCallArgs(JS::Rooted<JS::Value>* rooted)
: JS::MutableHandleValue(rooted)
{}
JS::MutableHandleValue rval() {
return *this;
}
};
/*
* A class, expected to be passed by value, which represents the CallArgs for a
* JSJitSetterOp.
*/
class JSJitSetterCallArgs : protected JS::MutableHandleValue
{
public:
explicit JSJitSetterCallArgs(const JS::CallArgs& args)
: JS::MutableHandleValue(args[0])
{}
JS::MutableHandleValue operator[](unsigned i) {
MOZ_ASSERT(i == 0);
return *this;
}
unsigned length() const { return 1; }
// Add get() or maybe hasDefined() as needed
};
struct JSJitMethodCallArgsTraits;
/*
* A class, expected to be passed by reference, which represents the CallArgs
* for a JSJitMethodOp.
*/
class JSJitMethodCallArgs : protected JS::detail::CallArgsBase<JS::detail::NoUsedRval>
{
private:
typedef JS::detail::CallArgsBase<JS::detail::NoUsedRval> Base;
friend struct JSJitMethodCallArgsTraits;
public:
explicit JSJitMethodCallArgs(const JS::CallArgs& args) {
argv_ = args.array();
argc_ = args.length();
}
JS::MutableHandleValue rval() const {
return Base::rval();
}
unsigned length() const { return Base::length(); }
JS::MutableHandleValue operator[](unsigned i) const {
return Base::operator[](i);
}
bool hasDefined(unsigned i) const {
return Base::hasDefined(i);
}
// Add get() as needed
};
struct JSJitMethodCallArgsTraits
{
static const size_t offsetOfArgv = offsetof(JSJitMethodCallArgs, argv_);
static const size_t offsetOfArgc = offsetof(JSJitMethodCallArgs, argc_);
};
/*
* This struct contains metadata passed from the DOM to the JS Engine for JIT
* optimizations on DOM property accessors. Eventually, this should be made
* available to general JSAPI users, but we are not currently ready to do so.
*/
typedef bool
(* JSJitGetterOp)(JSContext *cx, JS::HandleObject thisObj,
void *specializedThis, JSJitGetterCallArgs args);
typedef bool
(* JSJitSetterOp)(JSContext *cx, JS::HandleObject thisObj,
void *specializedThis, JSJitSetterCallArgs args);
typedef bool
(* JSJitMethodOp)(JSContext *cx, JS::HandleObject thisObj,
void *specializedThis, const JSJitMethodCallArgs& args);
struct JSJitInfo {
enum OpType {
Getter,
Setter,
Method,
OpType_None
};
union {
JSJitGetterOp getter;
JSJitSetterOp setter;
JSJitMethodOp method;
};
uint32_t protoID;
uint32_t depth;
OpType type;
bool isInfallible; /* Is op fallible? False in setters. */
bool isConstant; /* Getting a construction-time constant? */
bool isPure; /* As long as no non-pure DOM things happen, will
keep returning the same value for the given
"this" object" */
JSValueType returnType; /* The return type tag. Might be JSVAL_TYPE_UNKNOWN */
/* An alternative native that's safe to call in parallel mode. */
JSParallelNative parallelNative;
};
#define JS_JITINFO_NATIVE_PARALLEL(op) \
{{NULL},0,0,JSJitInfo::OpType_None,false,false,false,JSVAL_TYPE_MISSING,op}
static JS_ALWAYS_INLINE const JSJitInfo *
FUNCTION_VALUE_TO_JITINFO(const JS::Value& v)
{
JS_ASSERT(js::GetObjectClass(&v.toObject()) == js::FunctionClassPtr);
return reinterpret_cast<js::shadow::Function *>(&v.toObject())->jitinfo;
}
/* Statically asserted in jsfun.h. */
static const unsigned JS_FUNCTION_INTERPRETED_BIT = 0x1;
static JS_ALWAYS_INLINE void
SET_JITINFO(JSFunction * func, const JSJitInfo *info)
{
js::shadow::Function *fun = reinterpret_cast<js::shadow::Function *>(func);
JS_ASSERT(!(fun->flags & JS_FUNCTION_INTERPRETED_BIT));
fun->jitinfo = info;
}
/*
* Engine-internal extensions of jsid. This code is here only until we
* eliminate Gecko's dependencies on it!
*/
static JS_ALWAYS_INLINE jsid
JSID_FROM_BITS(size_t bits)
{
jsid id;
JSID_BITS(id) = bits;
return id;
}
/*
* Must not be used on atoms that are representable as integer jsids.
* Prefer NameToId or AtomToId over this function:
*
* A PropertyName is an atom that does not contain an integer in the range
* [0, UINT32_MAX]. However, jsid can only hold an integer in the range
* [0, JSID_INT_MAX] (where JSID_INT_MAX == 2^31-1). Thus, for the range of
* integers (JSID_INT_MAX, UINT32_MAX], to represent as a jsid 'id', it must be
* the case JSID_IS_ATOM(id) and !JSID_TO_ATOM(id)->isPropertyName(). In most
* cases when creating a jsid, code does not have to care about this corner
* case because:
*
* - When given an arbitrary JSAtom*, AtomToId must be used, which checks for
* integer atoms representable as integer jsids, and does this conversion.
*
* - When given a PropertyName*, NameToId can be used which which does not need
* to do any dynamic checks.
*
* Thus, it is only the rare third case which needs this function, which
* handles any JSAtom* that is known not to be representable with an int jsid.
*/
static JS_ALWAYS_INLINE jsid
NON_INTEGER_ATOM_TO_JSID(JSAtom *atom)
{
JS_ASSERT(((size_t)atom & 0x7) == 0);
jsid id = JSID_FROM_BITS((size_t)atom);
JS_ASSERT(id == INTERNED_STRING_TO_JSID(NULL, (JSString*)atom));
return id;
}
/* All strings stored in jsids are atomized, but are not necessarily property names. */
static JS_ALWAYS_INLINE JSBool
JSID_IS_ATOM(jsid id)
{
return JSID_IS_STRING(id);
}
static JS_ALWAYS_INLINE JSBool
JSID_IS_ATOM(jsid id, JSAtom *atom)
{
return id == JSID_FROM_BITS((size_t)atom);
}
static JS_ALWAYS_INLINE JSAtom *
JSID_TO_ATOM(jsid id)
{
return (JSAtom *)JSID_TO_STRING(id);
}
JS_STATIC_ASSERT(sizeof(jsid) == JS_BYTES_PER_WORD);
namespace js {
static JS_ALWAYS_INLINE Value
IdToValue(jsid id)
{
if (JSID_IS_STRING(id))
return StringValue(JSID_TO_STRING(id));
if (JS_LIKELY(JSID_IS_INT(id)))
return Int32Value(JSID_TO_INT(id));
if (JS_LIKELY(JSID_IS_OBJECT(id)))
return ObjectValue(*JSID_TO_OBJECT(id));
JS_ASSERT(JSID_IS_VOID(id));
return UndefinedValue();
}
static JS_ALWAYS_INLINE jsval
IdToJsval(jsid id)
{
return IdToValue(id);
}
extern JS_FRIEND_API(bool)
IsReadOnlyDateMethod(JS::IsAcceptableThis test, JS::NativeImpl method);
extern JS_FRIEND_API(bool)
IsTypedArrayThisCheck(JS::IsAcceptableThis test);
enum CTypesActivityType {
CTYPES_CALL_BEGIN,
CTYPES_CALL_END,
CTYPES_CALLBACK_BEGIN,
CTYPES_CALLBACK_END
};
typedef void
(* CTypesActivityCallback)(JSContext *cx, CTypesActivityType type);
/*
* Sets a callback that is run whenever js-ctypes is about to be used when
* calling into C.
*/
JS_FRIEND_API(void)
SetCTypesActivityCallback(JSRuntime *rt, CTypesActivityCallback cb);
class JS_FRIEND_API(AutoCTypesActivityCallback) {
private:
JSContext *cx;
CTypesActivityCallback callback;
CTypesActivityType endType;
MOZ_DECL_USE_GUARD_OBJECT_NOTIFIER
public:
AutoCTypesActivityCallback(JSContext *cx, CTypesActivityType beginType,
CTypesActivityType endType
MOZ_GUARD_OBJECT_NOTIFIER_PARAM);
~AutoCTypesActivityCallback() {
DoEndCallback();
}
void DoEndCallback() {
if (callback) {
callback(cx, endType);
callback = NULL;
}
}
};
#ifdef DEBUG
extern JS_FRIEND_API(void)
assertEnteredPolicy(JSContext *cx, JSObject *obj, jsid id);
#else
inline void assertEnteredPolicy(JSContext *cx, JSObject *obj, jsid id) {};
#endif
typedef bool
(* ObjectMetadataCallback)(JSContext *cx, JSObject **pmetadata);
/*
* Specify a callback to invoke when creating each JS object in the current
* compartment, which may return a metadata object to associate with the
* object. Objects with different metadata have different shape hierarchies,
* so for efficiency, objects should generally try to share metadata objects.
*/
JS_FRIEND_API(void)
SetObjectMetadataCallback(JSContext *cx, ObjectMetadataCallback callback);
/* Manipulate the metadata associated with an object. */
JS_FRIEND_API(bool)
SetObjectMetadata(JSContext *cx, JS::HandleObject obj, JS::HandleObject metadata);
JS_FRIEND_API(JSObject *)
GetObjectMetadata(JSObject *obj);
/* ES5 8.12.8. */
extern JS_FRIEND_API(JSBool)
DefaultValue(JSContext *cx, JS::HandleObject obj, JSType hint, MutableHandleValue vp);
/*
* Helper function. To approximate a call to the [[DefineOwnProperty]] internal
* method described in ES5, first call this, then call JS_DefinePropertyById.
*
* JS_DefinePropertyById by itself does not enforce the invariants on
* non-configurable properties when obj->isNative(). This function performs the
* relevant checks (specified in ES5 8.12.9 [[DefineOwnProperty]] steps 1-11),
* but only if obj is native.
*
* The reason for the messiness here is that ES5 uses [[DefineOwnProperty]] as
* a sort of extension point, but there is no hook in js::Class,
* js::ProxyHandler, or the JSAPI with precisely the right semantics for it.
*/
extern JS_FRIEND_API(bool)
CheckDefineProperty(JSContext *cx, HandleObject obj, HandleId id, HandleValue value,
PropertyOp getter, StrictPropertyOp setter, unsigned attrs);
} /* namespace js */
extern JS_FRIEND_API(JSBool)
js_DefineOwnProperty(JSContext *cx, JSObject *objArg, jsid idArg,
const js::PropertyDescriptor& descriptor, JSBool *bp);
extern JS_FRIEND_API(JSBool)
js_ReportIsNotFunction(JSContext *cx, const JS::Value& v);
#ifdef JSGC_GENERATIONAL
extern JS_FRIEND_API(void)
JS_StoreObjectPostBarrierCallback(JSContext* cx,
void (*callback)(JSTracer *trc, void *key, void *data),
JSObject *key, void *data);
extern JS_FRIEND_API(void)
JS_StoreStringPostBarrierCallback(JSContext* cx,
void (*callback)(JSTracer *trc, void *key, void *data),
JSString *key, void *data);
#else
inline void
JS_StoreObjectPostBarrierCallback(JSContext* cx,
void (*callback)(JSTracer *trc, void *key, void *data),
JSObject *key, void *data) {}
inline void
JS_StoreStringPostBarrierCallback(JSContext* cx,
void (*callback)(JSTracer *trc, void *key, void *data),
JSString *key, void *data) {}
#endif /* JSGC_GENERATIONAL */
#endif /* jsfriendapi_h */