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cobalt / cobalt / 308ed6b84664d59944cd65f4b4359c28a2443be6 / . / src / third_party / mozjs-45 / js / src / jsapi.h
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/* -*- Mode: C++; tab-width: 8; indent-tabs-mode: nil; c-basic-offset: 4 -*-
* vim: set ts=8 sts=4 et sw=4 tw=99:
* This Source Code Form is subject to the terms of the Mozilla Public
* License, v. 2.0. If a copy of the MPL was not distributed with this
* file, You can obtain one at http://mozilla.org/MPL/2.0/. */
/* JavaScript API. */
#ifndef jsapi_h
#define jsapi_h
#include "mozilla/AlreadyAddRefed.h"
#include "mozilla/FloatingPoint.h"
#include "mozilla/MemoryReporting.h"
#include "mozilla/Range.h"
#include "mozilla/RangedPtr.h"
#include "mozilla/RefPtr.h"
#include <stdarg.h>
#include <stddef.h>
#include <stdint.h>
#include <stdio.h>
#include "jsalloc.h"
#include "jspubtd.h"
#include "js/CallArgs.h"
#include "js/Class.h"
#include "js/HashTable.h"
#include "js/Id.h"
#include "js/Principals.h"
#include "js/RootingAPI.h"
#include "js/TraceableVector.h"
#include "js/TracingAPI.h"
#include "js/Utility.h"
#include "js/Value.h"
#include "js/Vector.h"
#if defined(STARBOARD)
#include "starboard/file.h"
#endif
#include "cobalt/configuration/configuration.h"
/************************************************************************/
namespace JS {
class TwoByteChars;
#ifdef JS_DEBUG
class JS_PUBLIC_API(AutoCheckRequestDepth)
{
JSContext* cx;
public:
explicit AutoCheckRequestDepth(JSContext* cx);
explicit AutoCheckRequestDepth(js::ContextFriendFields* cx);
~AutoCheckRequestDepth();
};
# define CHECK_REQUEST(cx) \
JS::AutoCheckRequestDepth _autoCheckRequestDepth(cx)
#else
# define CHECK_REQUEST(cx) \
((void) 0)
#endif /* JS_DEBUG */
/** AutoValueArray roots an internal fixed-size array of Values. */
template <size_t N>
class MOZ_RAII AutoValueArray : public AutoGCRooter
{
const size_t length_;
Value elements_[N];
public:
explicit AutoValueArray(JSContext* cx
MOZ_GUARD_OBJECT_NOTIFIER_PARAM)
: AutoGCRooter(cx, VALARRAY), length_(N)
{
/* Always initialize in case we GC before assignment. */
mozilla::PodArrayZero(elements_);
MOZ_GUARD_OBJECT_NOTIFIER_INIT;
}
unsigned length() const { return length_; }
const Value* begin() const { return elements_; }
Value* begin() { return elements_; }
HandleValue operator[](unsigned i) const {
MOZ_ASSERT(i < N);
return HandleValue::fromMarkedLocation(&elements_[i]);
}
MutableHandleValue operator[](unsigned i) {
MOZ_ASSERT(i < N);
return MutableHandleValue::fromMarkedLocation(&elements_[i]);
}
MOZ_DECL_USE_GUARD_OBJECT_NOTIFIER
};
template<class T>
class MOZ_RAII AutoVectorRooterBase : protected AutoGCRooter
{
typedef js::Vector<T, 8> VectorImpl;
VectorImpl vector;
public:
explicit AutoVectorRooterBase(JSContext* cx, ptrdiff_t tag
MOZ_GUARD_OBJECT_NOTIFIER_PARAM)
: AutoGCRooter(cx, tag), vector(cx)
{
MOZ_GUARD_OBJECT_NOTIFIER_INIT;
}
explicit AutoVectorRooterBase(js::ContextFriendFields* cx, ptrdiff_t tag
MOZ_GUARD_OBJECT_NOTIFIER_PARAM)
: AutoGCRooter(cx, tag), vector(cx)
{
MOZ_GUARD_OBJECT_NOTIFIER_INIT;
}
typedef T ElementType;
typedef typename VectorImpl::Range Range;
size_t length() const { return vector.length(); }
bool empty() const { return vector.empty(); }
bool append(const T& v) { return vector.append(v); }
bool appendN(const T& v, size_t len) { return vector.appendN(v, len); }
bool append(const T* ptr, size_t len) { return vector.append(ptr, len); }
bool appendAll(const AutoVectorRooterBase<T>& other) {
return vector.appendAll(other.vector);
}
bool insert(T* p, const T& val) { return vector.insert(p, val); }
/* For use when space has already been reserved. */
void infallibleAppend(const T& v) { vector.infallibleAppend(v); }
void popBack() { vector.popBack(); }
T popCopy() { return vector.popCopy(); }
bool growBy(size_t inc) {
size_t oldLength = vector.length();
if (!vector.growByUninitialized(inc))
return false;
makeRangeGCSafe(oldLength);
return true;
}
bool resize(size_t newLength) {
size_t oldLength = vector.length();
if (newLength <= oldLength) {
vector.shrinkBy(oldLength - newLength);
return true;
}
if (!vector.growByUninitialized(newLength - oldLength))
return false;
makeRangeGCSafe(oldLength);
return true;
}
void clear() { vector.clear(); }
bool reserve(size_t newLength) {
return vector.reserve(newLength);
}
JS::MutableHandle<T> operator[](size_t i) {
return JS::MutableHandle<T>::fromMarkedLocation(&vector[i]);
}
JS::Handle<T> operator[](size_t i) const {
return JS::Handle<T>::fromMarkedLocation(&vector[i]);
}
const T* begin() const { return vector.begin(); }
T* begin() { return vector.begin(); }
const T* end() const { return vector.end(); }
T* end() { return vector.end(); }
Range all() { return vector.all(); }
const T& back() const { return vector.back(); }
friend void AutoGCRooter::trace(JSTracer* trc);
private:
void makeRangeGCSafe(size_t oldLength) {
T* t = vector.begin() + oldLength;
for (size_t i = oldLength; i < vector.length(); ++i, ++t)
memset(t, 0, sizeof(T));
}
MOZ_DECL_USE_GUARD_OBJECT_NOTIFIER
};
template <typename T>
class MOZ_RAII AutoVectorRooter : public AutoVectorRooterBase<T>
{
public:
explicit AutoVectorRooter(JSContext* cx
MOZ_GUARD_OBJECT_NOTIFIER_PARAM)
: AutoVectorRooterBase<T>(cx, this->GetTag(T()))
{
MOZ_GUARD_OBJECT_NOTIFIER_INIT;
}
explicit AutoVectorRooter(js::ContextFriendFields* cx
MOZ_GUARD_OBJECT_NOTIFIER_PARAM)
: AutoVectorRooterBase<T>(cx, this->GetTag(T()))
{
MOZ_GUARD_OBJECT_NOTIFIER_INIT;
}
MOZ_DECL_USE_GUARD_OBJECT_NOTIFIER
};
typedef AutoVectorRooter<Value> AutoValueVector;
typedef AutoVectorRooter<jsid> AutoIdVector;
typedef AutoVectorRooter<JSObject*> AutoObjectVector;
using ValueVector = js::TraceableVector<JS::Value>;
using IdVector = js::TraceableVector<jsid>;
using ScriptVector = js::TraceableVector<JSScript*>;
template<class Key, class Value>
class MOZ_RAII AutoHashMapRooter : protected AutoGCRooter
{
private:
typedef js::HashMap<Key, Value> HashMapImpl;
public:
explicit AutoHashMapRooter(JSContext* cx, ptrdiff_t tag
MOZ_GUARD_OBJECT_NOTIFIER_PARAM)
: AutoGCRooter(cx, tag), map(cx)
{
MOZ_GUARD_OBJECT_NOTIFIER_INIT;
}
typedef Key KeyType;
typedef Value ValueType;
typedef typename HashMapImpl::Entry Entry;
typedef typename HashMapImpl::Lookup Lookup;
typedef typename HashMapImpl::Ptr Ptr;
typedef typename HashMapImpl::AddPtr AddPtr;
bool init(uint32_t len = 16) {
return map.init(len);
}
bool initialized() const {
return map.initialized();
}
Ptr lookup(const Lookup& l) const {
return map.lookup(l);
}
void remove(Ptr p) {
map.remove(p);
}
AddPtr lookupForAdd(const Lookup& l) const {
return map.lookupForAdd(l);
}
template<typename KeyInput, typename ValueInput>
bool add(AddPtr& p, const KeyInput& k, const ValueInput& v) {
return map.add(p, k, v);
}
bool add(AddPtr& p, const Key& k) {
return map.add(p, k);
}
template<typename KeyInput, typename ValueInput>
bool relookupOrAdd(AddPtr& p, const KeyInput& k, const ValueInput& v) {
return map.relookupOrAdd(p, k, v);
}
typedef typename HashMapImpl::Range Range;
Range all() const {
return map.all();
}
typedef typename HashMapImpl::Enum Enum;
void clear() {
map.clear();
}
void finish() {
map.finish();
}
bool empty() const {
return map.empty();
}
uint32_t count() const {
return map.count();
}
size_t capacity() const {
return map.capacity();
}
size_t sizeOfExcludingThis(mozilla::MallocSizeOf mallocSizeOf) const {
return map.sizeOfExcludingThis(mallocSizeOf);
}
size_t sizeOfIncludingThis(mozilla::MallocSizeOf mallocSizeOf) const {
return map.sizeOfIncludingThis(mallocSizeOf);
}
/************************************************** Shorthand operations */
bool has(const Lookup& l) const {
return map.has(l);
}
template<typename KeyInput, typename ValueInput>
bool put(const KeyInput& k, const ValueInput& v) {
return map.put(k, v);
}
template<typename KeyInput, typename ValueInput>
bool putNew(const KeyInput& k, const ValueInput& v) {
return map.putNew(k, v);
}
Ptr lookupWithDefault(const Key& k, const Value& defaultValue) {
return map.lookupWithDefault(k, defaultValue);
}
void remove(const Lookup& l) {
map.remove(l);
}
friend void AutoGCRooter::trace(JSTracer* trc);
private:
AutoHashMapRooter(const AutoHashMapRooter& hmr) = delete;
AutoHashMapRooter& operator=(const AutoHashMapRooter& hmr) = delete;
HashMapImpl map;
MOZ_DECL_USE_GUARD_OBJECT_NOTIFIER
};
template<class T>
class MOZ_RAII AutoHashSetRooter : protected AutoGCRooter
{
private:
typedef js::HashSet<T> HashSetImpl;
public:
explicit AutoHashSetRooter(JSContext* cx, ptrdiff_t tag
MOZ_GUARD_OBJECT_NOTIFIER_PARAM)
: AutoGCRooter(cx, tag), set(cx)
{
MOZ_GUARD_OBJECT_NOTIFIER_INIT;
}
typedef typename HashSetImpl::Lookup Lookup;
typedef typename HashSetImpl::Ptr Ptr;
typedef typename HashSetImpl::AddPtr AddPtr;
bool init(uint32_t len = 16) {
return set.init(len);
}
bool initialized() const {
return set.initialized();
}
Ptr lookup(const Lookup& l) const {
return set.lookup(l);
}
void remove(Ptr p) {
set.remove(p);
}
AddPtr lookupForAdd(const Lookup& l) const {
return set.lookupForAdd(l);
}
bool add(AddPtr& p, const T& t) {
return set.add(p, t);
}
bool relookupOrAdd(AddPtr& p, const Lookup& l, const T& t) {
return set.relookupOrAdd(p, l, t);
}
typedef typename HashSetImpl::Range Range;
Range all() const {
return set.all();
}
typedef typename HashSetImpl::Enum Enum;
void clear() {
set.clear();
}
void finish() {
set.finish();
}
bool empty() const {
return set.empty();
}
uint32_t count() const {
return set.count();
}
size_t capacity() const {
return set.capacity();
}
size_t sizeOfExcludingThis(mozilla::MallocSizeOf mallocSizeOf) const {
return set.sizeOfExcludingThis(mallocSizeOf);
}
size_t sizeOfIncludingThis(mozilla::MallocSizeOf mallocSizeOf) const {
return set.sizeOfIncludingThis(mallocSizeOf);
}
/************************************************** Shorthand operations */
bool has(const Lookup& l) const {
return set.has(l);
}
bool put(const T& t) {
return set.put(t);
}
bool putNew(const T& t) {
return set.putNew(t);
}
void remove(const Lookup& l) {
set.remove(l);
}
friend void AutoGCRooter::trace(JSTracer* trc);
private:
AutoHashSetRooter(const AutoHashSetRooter& hmr) = delete;
AutoHashSetRooter& operator=(const AutoHashSetRooter& hmr) = delete;
HashSetImpl set;
MOZ_DECL_USE_GUARD_OBJECT_NOTIFIER
};
/**
* Custom rooting behavior for internal and external clients.
*/
class MOZ_RAII JS_PUBLIC_API(CustomAutoRooter) : private AutoGCRooter
{
public:
template <typename CX>
explicit CustomAutoRooter(CX* cx MOZ_GUARD_OBJECT_NOTIFIER_PARAM)
: AutoGCRooter(cx, CUSTOM)
{
MOZ_GUARD_OBJECT_NOTIFIER_INIT;
}
friend void AutoGCRooter::trace(JSTracer* trc);
protected:
/** Supplied by derived class to trace roots. */
virtual void trace(JSTracer* trc) = 0;
private:
MOZ_DECL_USE_GUARD_OBJECT_NOTIFIER
};
/** A handle to an array of rooted values. */
class HandleValueArray
{
const size_t length_;
const Value * const elements_;
HandleValueArray(size_t len, const Value* elements) : length_(len), elements_(elements) {}
public:
explicit HandleValueArray(const RootedValue& value) : length_(1), elements_(value.address()) {}
MOZ_IMPLICIT HandleValueArray(const AutoValueVector& values)
: length_(values.length()), elements_(values.begin()) {}
template <size_t N>
MOZ_IMPLICIT HandleValueArray(const AutoValueArray<N>& values) : length_(N), elements_(values.begin()) {}
/** CallArgs must already be rooted somewhere up the stack. */
MOZ_IMPLICIT HandleValueArray(const JS::CallArgs& args) : length_(args.length()), elements_(args.array()) {}
/** Use with care! Only call this if the data is guaranteed to be marked. */
static HandleValueArray fromMarkedLocation(size_t len, const Value* elements) {
return HandleValueArray(len, elements);
}
static HandleValueArray subarray(const HandleValueArray& values, size_t startIndex, size_t len) {
MOZ_ASSERT(startIndex + len <= values.length());
return HandleValueArray(len, values.begin() + startIndex);
}
static HandleValueArray empty() {
return HandleValueArray(0, nullptr);
}
size_t length() const { return length_; }
const Value* begin() const { return elements_; }
HandleValue operator[](size_t i) const {
MOZ_ASSERT(i < length_);
return HandleValue::fromMarkedLocation(&elements_[i]);
}
};
} /* namespace JS */
/************************************************************************/
struct JSFreeOp {
private:
JSRuntime* runtime_;
protected:
explicit JSFreeOp(JSRuntime* rt)
: runtime_(rt) { }
public:
JSRuntime* runtime() const {
return runtime_;
}
};
/* Callbacks and their arguments. */
/************************************************************************/
typedef enum JSContextOp {
JSCONTEXT_NEW,
JSCONTEXT_DESTROY
} JSContextOp;
/**
* The possible values for contextOp when the runtime calls the callback are:
* JSCONTEXT_NEW JS_NewContext successfully created a new JSContext
* instance. The callback can initialize the instance as
* required. If the callback returns false, the instance
* will be destroyed and JS_NewContext returns null. In
* this case the callback is not called again.
* JSCONTEXT_DESTROY One of JS_DestroyContext* methods is called. The
* callback may perform its own cleanup and must always
* return true.
* Any other value For future compatibility the callback must do nothing
* and return true in this case.
*/
typedef bool
(* JSContextCallback)(JSContext* cx, unsigned contextOp, void* data);
typedef enum JSGCStatus {
JSGC_BEGIN,
JSGC_END
} JSGCStatus;
typedef void
(* JSGCCallback)(JSRuntime* rt, JSGCStatus status, void* data);
typedef enum JSFinalizeStatus {
/**
* Called when preparing to sweep a group of compartments, before anything
* has been swept. The collector will not yield to the mutator before
* calling the callback with JSFINALIZE_GROUP_END status.
*/
JSFINALIZE_GROUP_START,
/**
* Called when preparing to sweep a group of compartments. Weak references
* to unmarked things have been removed and things that are not swept
* incrementally have been finalized at this point. The collector may yield
* to the mutator after this point.
*/
JSFINALIZE_GROUP_END,
/**
* Called at the end of collection when everything has been swept.
*/
JSFINALIZE_COLLECTION_END
} JSFinalizeStatus;
typedef void
(* JSFinalizeCallback)(JSFreeOp* fop, JSFinalizeStatus status, bool isCompartment, void* data);
typedef void
(* JSWeakPointerZoneGroupCallback)(JSRuntime* rt, void* data);
typedef void
(* JSWeakPointerCompartmentCallback)(JSRuntime* rt, JSCompartment* comp, void* data);
typedef bool
(* JSInterruptCallback)(JSContext* cx);
typedef void
(* JSErrorReporter)(JSContext* cx, const char* message, JSErrorReport* report);
/**
* Possible exception types. These types are part of a JSErrorFormatString
* structure. They define which error to throw in case of a runtime error.
* JSEXN_NONE marks an unthrowable error.
*/
typedef enum JSExnType {
JSEXN_NONE = -1,
JSEXN_ERR,
JSEXN_INTERNALERR,
JSEXN_EVALERR,
JSEXN_RANGEERR,
JSEXN_REFERENCEERR,
JSEXN_SYNTAXERR,
JSEXN_TYPEERR,
JSEXN_URIERR,
JSEXN_LIMIT
} JSExnType;
typedef struct JSErrorFormatString {
/** The error format string in ASCII. */
const char* format;
/** The number of arguments to expand in the formatted error message. */
uint16_t argCount;
/** One of the JSExnType constants above. */
int16_t exnType;
} JSErrorFormatString;
typedef const JSErrorFormatString*
(* JSErrorCallback)(void* userRef, const unsigned errorNumber);
typedef bool
(* JSLocaleToUpperCase)(JSContext* cx, JS::HandleString src, JS::MutableHandleValue rval);
typedef bool
(* JSLocaleToLowerCase)(JSContext* cx, JS::HandleString src, JS::MutableHandleValue rval);
typedef bool
(* JSLocaleCompare)(JSContext* cx, JS::HandleString src1, JS::HandleString src2,
JS::MutableHandleValue rval);
typedef bool
(* JSLocaleToUnicode)(JSContext* cx, const char* src, JS::MutableHandleValue rval);
/**
* Callback used to ask the embedding for the cross compartment wrapper handler
* that implements the desired prolicy for this kind of object in the
* destination compartment. |obj| is the object to be wrapped. If |existing| is
* non-nullptr, it will point to an existing wrapper object that should be
* re-used if possible. |existing| is guaranteed to be a cross-compartment
* wrapper with a lazily-defined prototype and the correct global. It is
* guaranteed not to wrap a function.
*/
typedef JSObject*
(* JSWrapObjectCallback)(JSContext* cx, JS::HandleObject existing, JS::HandleObject obj);
/**
* Callback used by the wrap hook to ask the embedding to prepare an object
* for wrapping in a context. This might include unwrapping other wrappers
* or even finding a more suitable object for the new compartment.
*/
typedef JSObject*
(* JSPreWrapCallback)(JSContext* cx, JS::HandleObject scope, JS::HandleObject obj,
JS::HandleObject objectPassedToWrap);
struct JSWrapObjectCallbacks
{
JSWrapObjectCallback wrap;
JSPreWrapCallback preWrap;
};
typedef void
(* JSDestroyCompartmentCallback)(JSFreeOp* fop, JSCompartment* compartment);
typedef void
(* JSZoneCallback)(JS::Zone* zone);
typedef void
(* JSCompartmentNameCallback)(JSRuntime* rt, JSCompartment* compartment,
char* buf, size_t bufsize);
/************************************************************************/
static MOZ_ALWAYS_INLINE JS::Value
JS_NumberValue(double d)
{
int32_t i;
d = JS::CanonicalizeNaN(d);
if (mozilla::NumberIsInt32(d, &i))
return JS::Int32Value(i);
return JS::DoubleValue(d);
}
/************************************************************************/
JS_PUBLIC_API(bool)
JS_StringHasBeenPinned(JSContext* cx, JSString* str);
namespace JS {
/**
* Container class for passing in script source buffers to the JS engine. This
* not only groups the buffer and length values, it also provides a way to
* optionally pass ownership of the buffer to the JS engine without copying.
* Rules for use:
*
* 1) The data array must be allocated with js_malloc() or js_realloc() if
* ownership is being granted to the SourceBufferHolder.
* 2) If ownership is not given to the SourceBufferHolder, then the memory
* must be kept alive until the JS compilation is complete.
* 3) Any code calling SourceBufferHolder::take() must guarantee to keep the
* memory alive until JS compilation completes. Normally only the JS
* engine should be calling take().
*
* Example use:
*
* size_t length = 512;
* char16_t* chars = static_cast<char16_t*>(js_malloc(sizeof(char16_t) * length));
* JS::SourceBufferHolder srcBuf(chars, length, JS::SourceBufferHolder::GiveOwnership);
* JS::Compile(cx, options, srcBuf);
*/
class MOZ_STACK_CLASS SourceBufferHolder final
{
public:
enum Ownership {
NoOwnership,
GiveOwnership
};
SourceBufferHolder(const char16_t* data, size_t dataLength, Ownership ownership)
: data_(data),
length_(dataLength),
ownsChars_(ownership == GiveOwnership)
{
// Ensure that null buffers properly return an unowned, empty,
// null-terminated string.
static const char16_t NullChar_ = 0;
if (!get()) {
data_ = &NullChar_;
length_ = 0;
ownsChars_ = false;
}
}
~SourceBufferHolder() {
if (ownsChars_)
js_free(const_cast<char16_t*>(data_));
}
// Access the underlying source buffer without affecting ownership.
const char16_t* get() const { return data_; }
// Length of the source buffer in char16_t code units (not bytes)
size_t length() const { return length_; }
// Returns true if the SourceBufferHolder owns the buffer and will free
// it upon destruction. If true, it is legal to call take().
bool ownsChars() const { return ownsChars_; }
// Retrieve and take ownership of the underlying data buffer. The caller
// is now responsible for calling js_free() on the returned value, *but only
// after JS script compilation has completed*.
//
// After the buffer has been taken the SourceBufferHolder functions as if
// it had been constructed on an unowned buffer; get() and length() still
// work. In order for this to be safe the taken buffer must be kept alive
// until after JS script compilation completes as noted above.
//
// Note, it's the caller's responsibility to check ownsChars() before taking
// the buffer. Taking and then free'ing an unowned buffer will have dire
// consequences.
char16_t* take() {
MOZ_ASSERT(ownsChars_);
ownsChars_ = false;
return const_cast<char16_t*>(data_);
}
private:
SourceBufferHolder(SourceBufferHolder&) = delete;
SourceBufferHolder& operator=(SourceBufferHolder&) = delete;
const char16_t* data_;
size_t length_;
bool ownsChars_;
};
} /* namespace JS */
/************************************************************************/
/* Property attributes, set in JSPropertySpec and passed to API functions.
*
* NB: The data structure in which some of these values are stored only uses
* a uint8_t to store the relevant information. Proceed with caution if
* trying to reorder or change the the first byte worth of flags.
*/
#define JSPROP_ENUMERATE 0x01 /* property is visible to for/in loop */
#define JSPROP_READONLY 0x02 /* not settable: assignment is no-op.
This flag is only valid when neither
JSPROP_GETTER nor JSPROP_SETTER is
set. */
#define JSPROP_PERMANENT 0x04 /* property cannot be deleted */
#define JSPROP_PROPOP_ACCESSORS 0x08 /* Passed to JS_Define(UC)Property* and
JS_DefineElement if getters/setters
are JSGetterOp/JSSetterOp */
#define JSPROP_GETTER 0x10 /* property holds getter function */
#define JSPROP_SETTER 0x20 /* property holds setter function */
#define JSPROP_SHARED 0x40 /* don't allocate a value slot for this
property; don't copy the property on
set of the same-named property in an
object that delegates to a prototype
containing this property */
#define JSPROP_INTERNAL_USE_BIT 0x80 /* internal JS engine use only */
#define JSPROP_DEFINE_LATE 0x100 /* Don't define property when initially creating
the constructor. Some objects like Function/Object
have self-hosted functions that can only be defined
after the initialization is already finished. */
#define JSFUN_STUB_GSOPS 0x200 /* use JS_PropertyStub getter/setter
instead of defaulting to class gsops
for property holding function */
#define JSFUN_CONSTRUCTOR 0x400 /* native that can be called as a ctor */
/*
* Specify a generic native prototype methods, i.e., methods of a class
* prototype that are exposed as static methods taking an extra leading
* argument: the generic |this| parameter.
*
* If you set this flag in a JSFunctionSpec struct's flags initializer, then
* that struct must live at least as long as the native static method object
* created due to this flag by JS_DefineFunctions or JS_InitClass. Typically
* JSFunctionSpec structs are allocated in static arrays.
*/
#define JSFUN_GENERIC_NATIVE 0x800
#define JSFUN_FLAGS_MASK 0xe00 /* | of all the JSFUN_* flags */
/*
* If set, will allow redefining a non-configurable property, but only on a
* non-DOM global. This is a temporary hack that will need to go away in bug
* 1105518.
*/
#define JSPROP_REDEFINE_NONCONFIGURABLE 0x1000
/*
* Resolve hooks and enumerate hooks must pass this flag when calling
* JS_Define* APIs to reify lazily-defined properties.
*
* JSPROP_RESOLVING is used only with property-defining APIs. It tells the
* engine to skip the resolve hook when performing the lookup at the beginning
* of property definition. This keeps the resolve hook from accidentally
* triggering itself: unchecked recursion.
*
* For enumerate hooks, triggering the resolve hook would be merely silly, not
* fatal, except in some cases involving non-configurable properties.
*/
#define JSPROP_RESOLVING 0x2000
#define JSPROP_IGNORE_ENUMERATE 0x4000 /* ignore the value in JSPROP_ENUMERATE.
This flag only valid when defining over
an existing property. */
#define JSPROP_IGNORE_READONLY 0x8000 /* ignore the value in JSPROP_READONLY.
This flag only valid when defining over
an existing property. */
#define JSPROP_IGNORE_PERMANENT 0x10000 /* ignore the value in JSPROP_PERMANENT.
This flag only valid when defining over
an existing property. */
#define JSPROP_IGNORE_VALUE 0x20000 /* ignore the Value in the descriptor. Nothing was
specified when passed to Object.defineProperty
from script. */
/**
* The first call to JS_CallOnce by any thread in a process will call 'func'.
* Later calls to JS_CallOnce with the same JSCallOnceType object will be
* suppressed.
*
* Equivalently: each distinct JSCallOnceType object will allow one JS_CallOnce
* to invoke its JSInitCallback.
*/
extern JS_PUBLIC_API(bool)
JS_CallOnce(JSCallOnceType* once, JSInitCallback func);
/** Microseconds since the epoch, midnight, January 1, 1970 UTC. */
extern JS_PUBLIC_API(int64_t)
JS_Now(void);
/** Don't want to export data, so provide accessors for non-inline Values. */
extern JS_PUBLIC_API(JS::Value)
JS_GetNaNValue(JSContext* cx);
extern JS_PUBLIC_API(JS::Value)
JS_GetNegativeInfinityValue(JSContext* cx);
extern JS_PUBLIC_API(JS::Value)
JS_GetPositiveInfinityValue(JSContext* cx);
extern JS_PUBLIC_API(JS::Value)
JS_GetEmptyStringValue(JSContext* cx);
extern JS_PUBLIC_API(JSString*)
JS_GetEmptyString(JSRuntime* rt);
extern JS_PUBLIC_API(bool)
JS_ValueToObject(JSContext* cx, JS::HandleValue v, JS::MutableHandleObject objp);
extern JS_PUBLIC_API(JSFunction*)
JS_ValueToFunction(JSContext* cx, JS::HandleValue v);
extern JS_PUBLIC_API(JSFunction*)
JS_ValueToConstructor(JSContext* cx, JS::HandleValue v);
extern JS_PUBLIC_API(JSString*)
JS_ValueToSource(JSContext* cx, JS::Handle<JS::Value> v);
extern JS_PUBLIC_API(bool)
JS_DoubleIsInt32(double d, int32_t* ip);
extern JS_PUBLIC_API(JSType)
JS_TypeOfValue(JSContext* cx, JS::Handle<JS::Value> v);
extern JS_PUBLIC_API(bool)
JS_StrictlyEqual(JSContext* cx, JS::Handle<JS::Value> v1, JS::Handle<JS::Value> v2, bool* equal);
extern JS_PUBLIC_API(bool)
JS_LooselyEqual(JSContext* cx, JS::Handle<JS::Value> v1, JS::Handle<JS::Value> v2, bool* equal);
extern JS_PUBLIC_API(bool)
JS_SameValue(JSContext* cx, JS::Handle<JS::Value> v1, JS::Handle<JS::Value> v2, bool* same);
/** True iff fun is the global eval function. */
extern JS_PUBLIC_API(bool)
JS_IsBuiltinEvalFunction(JSFunction* fun);
/** True iff fun is the Function constructor. */
extern JS_PUBLIC_API(bool)
JS_IsBuiltinFunctionConstructor(JSFunction* fun);
/************************************************************************/
/*
* Locking, contexts, and memory allocation.
*
* It is important that SpiderMonkey be initialized, and the first runtime and
* first context be created, in a single-threaded fashion. Otherwise the
* behavior of the library is undefined.
* See: http://developer.mozilla.org/en/docs/Category:JSAPI_Reference
*/
extern JS_PUBLIC_API(JSRuntime*)
JS_NewRuntime(uint32_t maxbytes,
uint32_t maxNurseryBytes = JS::DefaultNurseryBytes,
JSRuntime* parentRuntime = nullptr);
extern JS_PUBLIC_API(void)
JS_DestroyRuntime(JSRuntime* rt);
typedef double (*JS_CurrentEmbedderTimeFunction)();
/**
* The embedding can specify a time function that will be used in some
* situations. The function can return the time however it likes; but
* the norm is to return times in units of milliseconds since an
* arbitrary, but consistent, epoch. If the time function is not set,
* a built-in default will be used.
*/
JS_PUBLIC_API(void)
JS_SetCurrentEmbedderTimeFunction(JS_CurrentEmbedderTimeFunction timeFn);
/**
* Return the time as computed using the current time function, or a
* suitable default if one has not been set.
*/
JS_PUBLIC_API(double)
JS_GetCurrentEmbedderTime();
JS_PUBLIC_API(void*)
JS_GetRuntimePrivate(JSRuntime* rt);
extern JS_PUBLIC_API(JSRuntime*)
JS_GetRuntime(JSContext* cx);
extern JS_PUBLIC_API(JSRuntime*)
JS_GetParentRuntime(JSContext* cx);
JS_PUBLIC_API(void)
JS_SetRuntimePrivate(JSRuntime* rt, void* data);
extern JS_PUBLIC_API(void)
JS_BeginRequest(JSContext* cx);
extern JS_PUBLIC_API(void)
JS_EndRequest(JSContext* cx);
namespace js {
void
AssertHeapIsIdle(JSRuntime* rt);
void
AssertHeapIsIdle(JSContext* cx);
} /* namespace js */
class MOZ_RAII JSAutoRequest
{
public:
explicit JSAutoRequest(JSContext* cx
MOZ_GUARD_OBJECT_NOTIFIER_PARAM)
: mContext(cx)
{
MOZ_GUARD_OBJECT_NOTIFIER_INIT;
JS_BeginRequest(mContext);
}
~JSAutoRequest() {
JS_EndRequest(mContext);
}
protected:
JSContext* mContext;
MOZ_DECL_USE_GUARD_OBJECT_NOTIFIER
#if 0
private:
static void* operator new(size_t) CPP_THROW_NEW { return 0; }
static void operator delete(void*, size_t) { }
#endif
};
extern JS_PUBLIC_API(void)
JS_SetContextCallback(JSRuntime* rt, JSContextCallback cxCallback, void* data);
extern JS_PUBLIC_API(JSContext*)
JS_NewContext(JSRuntime* rt, size_t stackChunkSize);
extern JS_PUBLIC_API(void)
JS_DestroyContext(JSContext* cx);
extern JS_PUBLIC_API(void)
JS_DestroyContextNoGC(JSContext* cx);
extern JS_PUBLIC_API(void*)
JS_GetContextPrivate(JSContext* cx);
extern JS_PUBLIC_API(void)
JS_SetContextPrivate(JSContext* cx, void* data);
extern JS_PUBLIC_API(void*)
JS_GetSecondContextPrivate(JSContext* cx);
extern JS_PUBLIC_API(void)
JS_SetSecondContextPrivate(JSContext* cx, void* data);
extern JS_PUBLIC_API(JSRuntime*)
JS_GetRuntime(JSContext* cx);
extern JS_PUBLIC_API(JSContext*)
JS_ContextIterator(JSRuntime* rt, JSContext** iterp);
extern JS_PUBLIC_API(JSVersion)
JS_GetVersion(JSContext* cx);
/**
* Mutate the version on the compartment. This is generally discouraged, but
* necessary to support the version mutation in the js and xpc shell command
* set.
*
* It would be nice to put this in jsfriendapi, but the linkage requirements
* of the shells make that impossible.
*/
JS_PUBLIC_API(void)
JS_SetVersionForCompartment(JSCompartment* compartment, JSVersion version);
extern JS_PUBLIC_API(const char*)
JS_VersionToString(JSVersion version);
extern JS_PUBLIC_API(JSVersion)
JS_StringToVersion(const char* string);
namespace JS {
class JS_PUBLIC_API(RuntimeOptions) {
public:
RuntimeOptions()
:
throwOnAsmJSValidationFailure_(false),
unboxedArrays_(false),
asyncStack_(true),
werror_(false),
strictMode_(false),
extraWarnings_(false)
{
bool enable_jit = cobalt::configuration::Configuration::GetInstance()
->CobaltEnableJit();
baseline_ = enable_jit;
ion_ = enable_jit;
asmJS_ = enable_jit;
nativeRegExp_ = enable_jit;
}
bool baseline() const { return baseline_; }
RuntimeOptions& setBaseline(bool flag) {
baseline_ = flag;
return *this;
}
RuntimeOptions& toggleBaseline() {
baseline_ = !baseline_;
return *this;
}
bool ion() const { return ion_; }
RuntimeOptions& setIon(bool flag) {
ion_ = flag;
return *this;
}
RuntimeOptions& toggleIon() {
ion_ = !ion_;
return *this;
}
bool asmJS() const { return asmJS_; }
RuntimeOptions& setAsmJS(bool flag) {
asmJS_ = flag;
return *this;
}
RuntimeOptions& toggleAsmJS() {
asmJS_ = !asmJS_;
return *this;
}
bool throwOnAsmJSValidationFailure() const { return throwOnAsmJSValidationFailure_; }
RuntimeOptions& setThrowOnAsmJSValidationFailure(bool flag) {
throwOnAsmJSValidationFailure_ = flag;
return *this;
}
RuntimeOptions& toggleThrowOnAsmJSValidationFailure() {
throwOnAsmJSValidationFailure_ = !throwOnAsmJSValidationFailure_;
return *this;
}
bool nativeRegExp() const { return nativeRegExp_; }
RuntimeOptions& setNativeRegExp(bool flag) {
nativeRegExp_ = flag;
return *this;
}
bool unboxedArrays() const { return unboxedArrays_; }
RuntimeOptions& setUnboxedArrays(bool flag) {
unboxedArrays_ = flag;
return *this;
}
bool asyncStack() const { return asyncStack_; }
RuntimeOptions& setAsyncStack(bool flag) {
asyncStack_ = flag;
return *this;
}
bool werror() const { return werror_; }
RuntimeOptions& setWerror(bool flag) {
werror_ = flag;
return *this;
}
RuntimeOptions& toggleWerror() {
werror_ = !werror_;
return *this;
}
bool strictMode() const { return strictMode_; }
RuntimeOptions& setStrictMode(bool flag) {
strictMode_ = flag;
return *this;
}
RuntimeOptions& toggleStrictMode() {
strictMode_ = !strictMode_;
return *this;
}
bool extraWarnings() const { return extraWarnings_; }
RuntimeOptions& setExtraWarnings(bool flag) {
extraWarnings_ = flag;
return *this;
}
RuntimeOptions& toggleExtraWarnings() {
extraWarnings_ = !extraWarnings_;
return *this;
}
private:
bool baseline_ : 1;
bool ion_ : 1;
bool asmJS_ : 1;
bool throwOnAsmJSValidationFailure_ : 1;
bool nativeRegExp_ : 1;
bool unboxedArrays_ : 1;
bool asyncStack_ : 1;
bool werror_ : 1;
bool strictMode_ : 1;
bool extraWarnings_ : 1;
};
JS_PUBLIC_API(RuntimeOptions&)
RuntimeOptionsRef(JSRuntime* rt);
JS_PUBLIC_API(RuntimeOptions&)
RuntimeOptionsRef(JSContext* cx);
class JS_PUBLIC_API(ContextOptions) {
public:
ContextOptions()
: privateIsNSISupports_(false),
dontReportUncaught_(false),
autoJSAPIOwnsErrorReporting_(false)
{
}
bool privateIsNSISupports() const { return privateIsNSISupports_; }
ContextOptions& setPrivateIsNSISupports(bool flag) {
privateIsNSISupports_ = flag;
return *this;
}
ContextOptions& togglePrivateIsNSISupports() {
privateIsNSISupports_ = !privateIsNSISupports_;
return *this;
}
bool dontReportUncaught() const { return dontReportUncaught_; }
ContextOptions& setDontReportUncaught(bool flag) {
dontReportUncaught_ = flag;
return *this;
}
ContextOptions& toggleDontReportUncaught() {
dontReportUncaught_ = !dontReportUncaught_;
return *this;
}
bool autoJSAPIOwnsErrorReporting() const { return autoJSAPIOwnsErrorReporting_; }
ContextOptions& setAutoJSAPIOwnsErrorReporting(bool flag) {
autoJSAPIOwnsErrorReporting_ = flag;
return *this;
}
ContextOptions& toggleAutoJSAPIOwnsErrorReporting() {
autoJSAPIOwnsErrorReporting_ = !autoJSAPIOwnsErrorReporting_;
return *this;
}
private:
bool privateIsNSISupports_ : 1;
bool dontReportUncaught_ : 1;
// dontReportUncaught isn't respected by all JSAPI codepaths, particularly the
// JS_ReportError* functions that eventually report the error even when dontReportUncaught is
// set, if script is not running. We want a way to indicate that the embedder will always
// handle any exceptions, and that SpiderMonkey should just leave them on the context. This is
// the way we want to do all future error handling in Gecko - stealing the exception explicitly
// from the context and handling it as per the situation. This will eventually become the
// default and these 2 flags should go away.
bool autoJSAPIOwnsErrorReporting_ : 1;
};
JS_PUBLIC_API(ContextOptions&)
ContextOptionsRef(JSContext* cx);
class JS_PUBLIC_API(AutoSaveContextOptions) {
public:
explicit AutoSaveContextOptions(JSContext* cx)
: cx_(cx),
oldOptions_(ContextOptionsRef(cx_))
{
}
~AutoSaveContextOptions()
{
ContextOptionsRef(cx_) = oldOptions_;
}
private:
JSContext* cx_;
JS::ContextOptions oldOptions_;
};
} /* namespace JS */
extern JS_PUBLIC_API(const char*)
JS_GetImplementationVersion(void);
extern JS_PUBLIC_API(void)
JS_SetDestroyCompartmentCallback(JSRuntime* rt, JSDestroyCompartmentCallback callback);
extern JS_PUBLIC_API(void)
JS_SetDestroyZoneCallback(JSRuntime* rt, JSZoneCallback callback);
extern JS_PUBLIC_API(void)
JS_SetSweepZoneCallback(JSRuntime* rt, JSZoneCallback callback);
extern JS_PUBLIC_API(void)
JS_SetCompartmentNameCallback(JSRuntime* rt, JSCompartmentNameCallback callback);
extern JS_PUBLIC_API(void)
JS_SetWrapObjectCallbacks(JSRuntime* rt, const JSWrapObjectCallbacks* callbacks);
extern JS_PUBLIC_API(void)
JS_SetCompartmentPrivate(JSCompartment* compartment, void* data);
extern JS_PUBLIC_API(void*)
JS_GetCompartmentPrivate(JSCompartment* compartment);
extern JS_PUBLIC_API(void)
JS_SetZoneUserData(JS::Zone* zone, void* data);
extern JS_PUBLIC_API(void*)
JS_GetZoneUserData(JS::Zone* zone);
extern JS_PUBLIC_API(bool)
JS_WrapObject(JSContext* cx, JS::MutableHandleObject objp);
extern JS_PUBLIC_API(bool)
JS_WrapValue(JSContext* cx, JS::MutableHandleValue vp);
extern JS_PUBLIC_API(JSObject*)
JS_TransplantObject(JSContext* cx, JS::HandleObject origobj, JS::HandleObject target);
extern JS_PUBLIC_API(bool)
JS_RefreshCrossCompartmentWrappers(JSContext* cx, JS::Handle<JSObject*> obj);
/*
* At any time, a JSContext has a current (possibly-nullptr) compartment.
* Compartments are described in:
*
* developer.mozilla.org/en-US/docs/SpiderMonkey/SpiderMonkey_compartments
*
* The current compartment of a context may be changed. The preferred way to do
* this is with JSAutoCompartment:
*
* void foo(JSContext* cx, JSObject* obj) {
* // in some compartment 'c'
* {
* JSAutoCompartment ac(cx, obj); // constructor enters
* // in the compartment of 'obj'
* } // destructor leaves
* // back in compartment 'c'
* }
*
* For more complicated uses that don't neatly fit in a C++ stack frame, the
* compartment can entered and left using separate function calls:
*
* void foo(JSContext* cx, JSObject* obj) {
* // in 'oldCompartment'
* JSCompartment* oldCompartment = JS_EnterCompartment(cx, obj);
* // in the compartment of 'obj'
* JS_LeaveCompartment(cx, oldCompartment);
* // back in 'oldCompartment'
* }
*
* Note: these calls must still execute in a LIFO manner w.r.t all other
* enter/leave calls on the context. Furthermore, only the return value of a
* JS_EnterCompartment call may be passed as the 'oldCompartment' argument of
* the corresponding JS_LeaveCompartment call.
*/
class MOZ_RAII JS_PUBLIC_API(JSAutoCompartment)
{
JSContext* cx_;
JSCompartment* oldCompartment_;
public:
JSAutoCompartment(JSContext* cx, JSObject* target
MOZ_GUARD_OBJECT_NOTIFIER_PARAM);
JSAutoCompartment(JSContext* cx, JSScript* target
MOZ_GUARD_OBJECT_NOTIFIER_PARAM);
~JSAutoCompartment();
MOZ_DECL_USE_GUARD_OBJECT_NOTIFIER
};
class MOZ_RAII JS_PUBLIC_API(JSAutoNullableCompartment)
{
JSContext* cx_;
JSCompartment* oldCompartment_;
public:
explicit JSAutoNullableCompartment(JSContext* cx, JSObject* targetOrNull
MOZ_GUARD_OBJECT_NOTIFIER_PARAM);
~JSAutoNullableCompartment();
MOZ_DECL_USE_GUARD_OBJECT_NOTIFIER
};
/** NB: This API is infallible; a nullptr return value does not indicate error. */
extern JS_PUBLIC_API(JSCompartment*)
JS_EnterCompartment(JSContext* cx, JSObject* target);
extern JS_PUBLIC_API(void)
JS_LeaveCompartment(JSContext* cx, JSCompartment* oldCompartment);
typedef void (*JSIterateCompartmentCallback)(JSRuntime* rt, void* data, JSCompartment* compartment);
/**
* This function calls |compartmentCallback| on every compartment. Beware that
* there is no guarantee that the compartment will survive after the callback
* returns. Also, barriers are disabled via the TraceSession.
*/
extern JS_PUBLIC_API(void)
JS_IterateCompartments(JSRuntime* rt, void* data,
JSIterateCompartmentCallback compartmentCallback);
/**
* Initialize standard JS class constructors, prototypes, and any top-level
* functions and constants associated with the standard classes (e.g. isNaN
* for Number).
*
* NB: This sets cx's global object to obj if it was null.
*/
extern JS_PUBLIC_API(bool)
JS_InitStandardClasses(JSContext* cx, JS::Handle<JSObject*> obj);
/**
* Resolve id, which must contain either a string or an int, to a standard
* class name in obj if possible, defining the class's constructor and/or
* prototype and storing true in *resolved. If id does not name a standard
* class or a top-level property induced by initializing a standard class,
* store false in *resolved and just return true. Return false on error,
* as usual for bool result-typed API entry points.
*
* This API can be called directly from a global object class's resolve op,
* to define standard classes lazily. The class's enumerate op should call
* JS_EnumerateStandardClasses(cx, obj), to define eagerly during for..in
* loops any classes not yet resolved lazily.
*/
extern JS_PUBLIC_API(bool)
JS_ResolveStandardClass(JSContext* cx, JS::HandleObject obj, JS::HandleId id, bool* resolved);
extern JS_PUBLIC_API(bool)
JS_MayResolveStandardClass(const JSAtomState& names, jsid id, JSObject* maybeObj);
extern JS_PUBLIC_API(bool)
JS_EnumerateStandardClasses(JSContext* cx, JS::HandleObject obj);
extern JS_PUBLIC_API(bool)
JS_GetClassObject(JSContext* cx, JSProtoKey key, JS::MutableHandle<JSObject*> objp);
extern JS_PUBLIC_API(bool)
JS_GetClassPrototype(JSContext* cx, JSProtoKey key, JS::MutableHandle<JSObject*> objp);
namespace JS {
/*
* Determine if the given object is an instance/prototype/constructor for a standard
* class. If so, return the associated JSProtoKey. If not, return JSProto_Null.
*/
extern JS_PUBLIC_API(JSProtoKey)
IdentifyStandardInstance(JSObject* obj);
extern JS_PUBLIC_API(JSProtoKey)
IdentifyStandardPrototype(JSObject* obj);
extern JS_PUBLIC_API(JSProtoKey)
IdentifyStandardInstanceOrPrototype(JSObject* obj);
extern JS_PUBLIC_API(JSProtoKey)
IdentifyStandardConstructor(JSObject* obj);
extern JS_PUBLIC_API(void)
ProtoKeyToId(JSContext* cx, JSProtoKey key, JS::MutableHandleId idp);
} /* namespace JS */
extern JS_PUBLIC_API(JSProtoKey)
JS_IdToProtoKey(JSContext* cx, JS::HandleId id);
/**
* Returns the original value of |Function.prototype| from the global object in
* which |forObj| was created.
*/
extern JS_PUBLIC_API(JSObject*)
JS_GetFunctionPrototype(JSContext* cx, JS::HandleObject forObj);
/**
* Returns the original value of |Object.prototype| from the global object in
* which |forObj| was created.
*/
extern JS_PUBLIC_API(JSObject*)
JS_GetObjectPrototype(JSContext* cx, JS::HandleObject forObj);
/**
* Returns the original value of |Array.prototype| from the global object in
* which |forObj| was created.
*/
extern JS_PUBLIC_API(JSObject*)
JS_GetArrayPrototype(JSContext* cx, JS::HandleObject forObj);
/**
* Returns the original value of |Error.prototype| from the global
* object of the current compartment of cx.
*/
extern JS_PUBLIC_API(JSObject*)
JS_GetErrorPrototype(JSContext* cx);
/**
* Returns the %IteratorPrototype% object that all built-in iterator prototype
* chains go through for the global object of the current compartment of cx.
*/
extern JS_PUBLIC_API(JSObject*)
JS_GetIteratorPrototype(JSContext* cx);
extern JS_PUBLIC_API(JSObject*)
JS_GetGlobalForObject(JSContext* cx, JSObject* obj);
extern JS_PUBLIC_API(bool)
JS_IsGlobalObject(JSObject* obj);
extern JS_PUBLIC_API(JSObject*)
JS_GlobalLexicalScope(JSObject* obj);
extern JS_PUBLIC_API(bool)
JS_HasExtensibleLexicalScope(JSObject* obj);
extern JS_PUBLIC_API(JSObject*)
JS_ExtensibleLexicalScope(JSObject* obj);
/**
* May return nullptr, if |c| never had a global (e.g. the atoms compartment),
* or if |c|'s global has been collected.
*/
extern JS_PUBLIC_API(JSObject*)
JS_GetGlobalForCompartmentOrNull(JSContext* cx, JSCompartment* c);
namespace JS {
extern JS_PUBLIC_API(JSObject*)
CurrentGlobalOrNull(JSContext* cx);
} // namespace JS
/**
* Add 'Reflect.parse', a SpiderMonkey extension, to the Reflect object on the
* given global.
*/
extern JS_PUBLIC_API(bool)
JS_InitReflectParse(JSContext* cx, JS::HandleObject global);
/**
* Add various profiling-related functions as properties of the given object.
* Defined in builtin/Profilers.cpp.
*/
extern JS_PUBLIC_API(bool)
JS_DefineProfilingFunctions(JSContext* cx, JS::HandleObject obj);
/* Defined in vm/Debugger.cpp. */
extern JS_PUBLIC_API(bool)
JS_DefineDebuggerObject(JSContext* cx, JS::HandleObject obj);
#ifdef JS_HAS_CTYPES
/**
* Initialize the 'ctypes' object on a global variable 'obj'. The 'ctypes'
* object will be sealed.
*/
extern JS_PUBLIC_API(bool)
JS_InitCTypesClass(JSContext* cx, JS::HandleObject global);
/**
* Convert a unicode string 'source' of length 'slen' to the platform native
* charset, returning a null-terminated string allocated with JS_malloc. On
* failure, this function should report an error.
*/
typedef char*
(* JSCTypesUnicodeToNativeFun)(JSContext* cx, const char16_t* source, size_t slen);
/**
* Set of function pointers that ctypes can use for various internal functions.
* See JS_SetCTypesCallbacks below. Providing nullptr for a function is safe,
* and will result in the applicable ctypes functionality not being available.
*/
struct JSCTypesCallbacks {
JSCTypesUnicodeToNativeFun unicodeToNative;
};
typedef struct JSCTypesCallbacks JSCTypesCallbacks;
/**
* Set the callbacks on the provided 'ctypesObj' object. 'callbacks' should be a
* pointer to static data that exists for the lifetime of 'ctypesObj', but it
* may safely be altered after calling this function and without having
* to call this function again.
*/
extern JS_PUBLIC_API(void)
JS_SetCTypesCallbacks(JSObject* ctypesObj, const JSCTypesCallbacks* callbacks);
#endif
extern JS_PUBLIC_API(void*)
JS_malloc(JSContext* cx, size_t nbytes);
extern JS_PUBLIC_API(void*)
JS_realloc(JSContext* cx, void* p, size_t oldBytes, size_t newBytes);
/**
* A wrapper for js_free(p) that may delay js_free(p) invocation as a
* performance optimization.
* cx may be nullptr.
*/
extern JS_PUBLIC_API(void)
JS_free(JSContext* cx, void* p);
/**
* A wrapper for js_free(p) that may delay js_free(p) invocation as a
* performance optimization as specified by the given JSFreeOp instance.
*/
extern JS_PUBLIC_API(void)
JS_freeop(JSFreeOp* fop, void* p);
extern JS_PUBLIC_API(JSFreeOp*)
JS_GetDefaultFreeOp(JSRuntime* rt);
extern JS_PUBLIC_API(void)
JS_updateMallocCounter(JSContext* cx, size_t nbytes);
extern JS_PUBLIC_API(char*)
JS_strdup(JSContext* cx, const char* s);
/** Duplicate a string. Does not report an error on failure. */
extern JS_PUBLIC_API(char*)
JS_strdup(JSRuntime* rt, const char* s);
/**
* Register externally maintained GC roots.
*
* traceOp: the trace operation. For each root the implementation should call
* JS_CallTracer whenever the root contains a traceable thing.
* data: the data argument to pass to each invocation of traceOp.
*/
extern JS_PUBLIC_API(bool)
JS_AddExtraGCRootsTracer(JSRuntime* rt, JSTraceDataOp traceOp, void* data);
/** Undo a call to JS_AddExtraGCRootsTracer. */
extern JS_PUBLIC_API(void)
JS_RemoveExtraGCRootsTracer(JSRuntime* rt, JSTraceDataOp traceOp, void* data);
/*
* Garbage collector API.
*/
extern JS_PUBLIC_API(void)
JS_GC(JSRuntime* rt);
extern JS_PUBLIC_API(void)
JS_MaybeGC(JSContext* cx);
extern JS_PUBLIC_API(void)
JS_SetGCCallback(JSRuntime* rt, JSGCCallback cb, void* data);
extern JS_PUBLIC_API(bool)
JS_AddFinalizeCallback(JSRuntime* rt, JSFinalizeCallback cb, void* data);
extern JS_PUBLIC_API(void)
JS_RemoveFinalizeCallback(JSRuntime* rt, JSFinalizeCallback cb);
/*
* Weak pointers and garbage collection
*
* Weak pointers are by their nature not marked as part of garbage collection,
* but they may need to be updated in two cases after a GC:
*
* 1) Their referent was found not to be live and is about to be finalized
* 2) Their referent has been moved by a compacting GC
*
* To handle this, any part of the system that maintain weak pointers to
* JavaScript GC things must register a callback with
* JS_(Add,Remove)WeakPointer{ZoneGroup,Compartment}Callback(). This callback
* must then call JS_UpdateWeakPointerAfterGC() on all weak pointers it knows
* about.
*
* Since sweeping is incremental, we have several callbacks to avoid repeatedly
* having to visit all embedder structures. The WeakPointerZoneGroupCallback is
* called once for each strongly connected group of zones, whereas the
* WeakPointerCompartmentCallback is called once for each compartment that is
* visited while sweeping. Structures that cannot contain references in more
* than one compartment should sweep the relevant per-compartment structures
* using the latter callback to minimizer per-slice overhead.
*
* The argument to JS_UpdateWeakPointerAfterGC() is an in-out param. If the
* referent is about to be finalized the pointer will be set to null. If the
* referent has been moved then the pointer will be updated to point to the new
* location.
*
* Callers of this method are responsible for updating any state that is
* dependent on the object's address. For example, if the object's address is
* used as a key in a hashtable, then the object must be removed and
* re-inserted with the correct hash.
*/
extern JS_PUBLIC_API(bool)
JS_AddWeakPointerZoneGroupCallback(JSRuntime* rt, JSWeakPointerZoneGroupCallback cb, void* data);
extern JS_PUBLIC_API(void)
JS_RemoveWeakPointerZoneGroupCallback(JSRuntime* rt, JSWeakPointerZoneGroupCallback cb);
extern JS_PUBLIC_API(bool)
JS_AddWeakPointerCompartmentCallback(JSRuntime* rt, JSWeakPointerCompartmentCallback cb,
void* data);
extern JS_PUBLIC_API(void)
JS_RemoveWeakPointerCompartmentCallback(JSRuntime* rt, JSWeakPointerCompartmentCallback cb);
extern JS_PUBLIC_API(void)
JS_UpdateWeakPointerAfterGC(JS::Heap<JSObject*>* objp);
extern JS_PUBLIC_API(void)
JS_UpdateWeakPointerAfterGCUnbarriered(JSObject** objp);
typedef enum JSGCParamKey {
/** Maximum nominal heap before last ditch GC. */
JSGC_MAX_BYTES = 0,
/** Number of JS_malloc bytes before last ditch GC. */
JSGC_MAX_MALLOC_BYTES = 1,
/** Amount of bytes allocated by the GC. */
JSGC_BYTES = 3,
/** Number of times GC has been invoked. Includes both major and minor GC. */
JSGC_NUMBER = 4,
/** Max size of the code cache in bytes. */
JSGC_MAX_CODE_CACHE_BYTES = 5,
/** Select GC mode. */
JSGC_MODE = 6,
/** Number of cached empty GC chunks. */
JSGC_UNUSED_CHUNKS = 7,
/** Total number of allocated GC chunks. */
JSGC_TOTAL_CHUNKS = 8,
/** Max milliseconds to spend in an incremental GC slice. */
JSGC_SLICE_TIME_BUDGET = 9,
/** Maximum size the GC mark stack can grow to. */
JSGC_MARK_STACK_LIMIT = 10,
/**
* GCs less than this far apart in time will be considered 'high-frequency GCs'.
* See setGCLastBytes in jsgc.cpp.
*/
JSGC_HIGH_FREQUENCY_TIME_LIMIT = 11,
/** Start of dynamic heap growth. */
JSGC_HIGH_FREQUENCY_LOW_LIMIT = 12,
/** End of dynamic heap growth. */
JSGC_HIGH_FREQUENCY_HIGH_LIMIT = 13,
/** Upper bound of heap growth. */
JSGC_HIGH_FREQUENCY_HEAP_GROWTH_MAX = 14,
/** Lower bound of heap growth. */
JSGC_HIGH_FREQUENCY_HEAP_GROWTH_MIN = 15,
/** Heap growth for low frequency GCs. */
JSGC_LOW_FREQUENCY_HEAP_GROWTH = 16,
/**
* If false, the heap growth factor is fixed at 3. If true, it is determined
* based on whether GCs are high- or low- frequency.
*/
JSGC_DYNAMIC_HEAP_GROWTH = 17,
/** If true, high-frequency GCs will use a longer mark slice. */
JSGC_DYNAMIC_MARK_SLICE = 18,
/** Lower limit after which we limit the heap growth. */
JSGC_ALLOCATION_THRESHOLD = 19,
/**
* We decommit memory lazily. If more than this number of megabytes is
* available to be decommitted, then JS_MaybeGC will trigger a shrinking GC
* to decommit it.
*/
JSGC_DECOMMIT_THRESHOLD = 20,
/**
* We try to keep at least this many unused chunks in the free chunk pool at
* all times, even after a shrinking GC.
*/
JSGC_MIN_EMPTY_CHUNK_COUNT = 21,
/** We never keep more than this many unused chunks in the free chunk pool. */
JSGC_MAX_EMPTY_CHUNK_COUNT = 22,
/** Whether compacting GC is enabled. */
JSGC_COMPACTING_ENABLED = 23
} JSGCParamKey;
extern JS_PUBLIC_API(void)
JS_SetGCParameter(JSRuntime* rt, JSGCParamKey key, uint32_t value);
extern JS_PUBLIC_API(uint32_t)
JS_GetGCParameter(JSRuntime* rt, JSGCParamKey key);
extern JS_PUBLIC_API(void)
JS_SetGCParameterForThread(JSContext* cx, JSGCParamKey key, uint32_t value);
extern JS_PUBLIC_API(uint32_t)
JS_GetGCParameterForThread(JSContext* cx, JSGCParamKey key);
extern JS_PUBLIC_API(void)
JS_SetGCParametersBasedOnAvailableMemory(JSRuntime* rt, uint32_t availMem);
/**
* Create a new JSString whose chars member refers to external memory, i.e.,
* memory requiring application-specific finalization.
*/
extern JS_PUBLIC_API(JSString*)
JS_NewExternalString(JSContext* cx, const char16_t* chars, size_t length,
const JSStringFinalizer* fin);
/**
* Return whether 'str' was created with JS_NewExternalString or
* JS_NewExternalStringWithClosure.
*/
extern JS_PUBLIC_API(bool)
JS_IsExternalString(JSString* str);
/**
* Return the 'fin' arg passed to JS_NewExternalString.
*/
extern JS_PUBLIC_API(const JSStringFinalizer*)
JS_GetExternalStringFinalizer(JSString* str);
/**
* Set the size of the native stack that should not be exceed. To disable
* stack size checking pass 0.
*
* SpiderMonkey allows for a distinction between system code (such as GCs, which
* may incidentally be triggered by script but are not strictly performed on
* behalf of such script), trusted script (as determined by JS_SetTrustedPrincipals),
* and untrusted script. Each kind of code may have a different stack quota,
* allowing embedders to keep higher-priority machinery running in the face of
* scripted stack exhaustion by something else.
*
* The stack quotas for each kind of code should be monotonically descending,
* and may be specified with this function. If 0 is passed for a given kind
* of code, it defaults to the value of the next-highest-priority kind.
*
* This function may only be called immediately after the runtime is initialized
* and before any code is executed and/or interrupts requested.
*/
extern JS_PUBLIC_API(void)
JS_SetNativeStackQuota(JSRuntime* cx, size_t systemCodeStackSize,
size_t trustedScriptStackSize = 0,
size_t untrustedScriptStackSize = 0);
/************************************************************************/
extern JS_PUBLIC_API(bool)
JS_ValueToId(JSContext* cx, JS::HandleValue v, JS::MutableHandleId idp);
extern JS_PUBLIC_API(bool)
JS_StringToId(JSContext* cx, JS::HandleString s, JS::MutableHandleId idp);
extern JS_PUBLIC_API(bool)
JS_IdToValue(JSContext* cx, jsid id, JS::MutableHandle<JS::Value> vp);
namespace JS {
/**
* Convert obj to a primitive value. On success, store the result in vp and
* return true.
*
* The hint argument must be JSTYPE_STRING, JSTYPE_NUMBER, or JSTYPE_VOID (no
* hint).
*
* Implements: ES6 7.1.1 ToPrimitive(input, [PreferredType]).
*/
extern JS_PUBLIC_API(bool)
ToPrimitive(JSContext* cx, JS::HandleObject obj, JSType hint, JS::MutableHandleValue vp);
/**
* If args.get(0) is one of the strings "string", "number", or "default", set
* *result to JSTYPE_STRING, JSTYPE_NUMBER, or JSTYPE_VOID accordingly and
* return true. Otherwise, return false with a TypeError pending.
*
* This can be useful in implementing a @@toPrimitive method.
*/
extern JS_PUBLIC_API(bool)
GetFirstArgumentAsTypeHint(JSContext* cx, CallArgs args, JSType *result);
} /* namespace JS */
extern JS_PUBLIC_API(bool)
JS_PropertyStub(JSContext* cx, JS::HandleObject obj, JS::HandleId id,
JS::MutableHandleValue vp);
extern JS_PUBLIC_API(bool)
JS_StrictPropertyStub(JSContext* cx, JS::HandleObject obj, JS::HandleId id,
JS::MutableHandleValue vp, JS::ObjectOpResult& result);
template<typename T>
struct JSConstScalarSpec {
const char* name;
T val;
};
typedef JSConstScalarSpec<double> JSConstDoubleSpec;
typedef JSConstScalarSpec<int32_t> JSConstIntegerSpec;
struct JSJitInfo;
/**
* Wrapper to relace JSNative for JSPropertySpecs and JSFunctionSpecs. This will
* allow us to pass one JSJitInfo per function with the property/function spec,
* without additional field overhead.
*/
typedef struct JSNativeWrapper {
JSNative op;
const JSJitInfo* info;
} JSNativeWrapper;
/*
* Macro static initializers which make it easy to pass no JSJitInfo as part of a
* JSPropertySpec or JSFunctionSpec.
*/
#define JSNATIVE_WRAPPER(native) { {native, nullptr} }
/**
* Description of a property. JS_DefineProperties and JS_InitClass take arrays
* of these and define many properties at once. JS_PSG, JS_PSGS and JS_PS_END
* are helper macros for defining such arrays.
*/
struct JSPropertySpec {
struct SelfHostedWrapper {
void* unused;
const char* funname;
};
const char* name;
uint8_t flags;
union {
JSNativeWrapper native;
SelfHostedWrapper selfHosted;
} getter;
union {
JSNativeWrapper native;
SelfHostedWrapper selfHosted;
} setter;
bool isSelfHosted() const {
#ifdef DEBUG
// Verify that our accessors match our JSPROP_GETTER flag.
if (flags & JSPROP_GETTER)
checkAccessorsAreSelfHosted();
else
checkAccessorsAreNative();
#endif
return (flags & JSPROP_GETTER);
}
static_assert(sizeof(SelfHostedWrapper) == sizeof(JSNativeWrapper),
"JSPropertySpec::getter/setter must be compact");
static_assert(offsetof(SelfHostedWrapper, funname) == offsetof(JSNativeWrapper, info),
"JS_SELF_HOSTED* macros below require that "
"SelfHostedWrapper::funname overlay "
"JSNativeWrapper::info");
private:
void checkAccessorsAreNative() const {
MOZ_ASSERT(getter.native.op);
// We may not have a setter at all. So all we can assert here, for the
// native case is that if we have a jitinfo for the setter then we have
// a setter op too. This is good enough to make sure we don't have a
// SelfHostedWrapper for the setter.
MOZ_ASSERT_IF(setter.native.info, setter.native.op);
}
void checkAccessorsAreSelfHosted() const {
MOZ_ASSERT(!getter.selfHosted.unused);
MOZ_ASSERT(!setter.selfHosted.unused);
}
};
namespace JS {
namespace detail {
/* NEVER DEFINED, DON'T USE. For use by JS_CAST_NATIVE_TO only. */
inline int CheckIsNative(JSNative native);
/* NEVER DEFINED, DON'T USE. For use by JS_CAST_STRING_TO only. */
template<size_t N>
inline int
CheckIsCharacterLiteral(const char (&arr)[N]);
/* NEVER DEFINED, DON'T USE. For use by JS_PROPERTYOP_GETTER only. */
inline int CheckIsGetterOp(JSGetterOp op);
/* NEVER DEFINED, DON'T USE. For use by JS_PROPERTYOP_SETTER only. */
inline int CheckIsSetterOp(JSSetterOp op);
} // namespace detail
} // namespace JS
#define JS_CAST_NATIVE_TO(v, To) \
(static_cast<void>(sizeof(JS::detail::CheckIsNative(v))), \
reinterpret_cast<To>(v))
#define JS_CAST_STRING_TO(s, To) \
(static_cast<void>(sizeof(JS::detail::CheckIsCharacterLiteral(s))), \
reinterpret_cast<To>(s))
#define JS_CHECK_ACCESSOR_FLAGS(flags) \
(static_cast<mozilla::EnableIf<((flags) & ~(JSPROP_ENUMERATE | JSPROP_PERMANENT)) == 0>::Type>(0), \
(flags))
#define JS_PROPERTYOP_GETTER(v) \
(static_cast<void>(sizeof(JS::detail::CheckIsGetterOp(v))), \
reinterpret_cast<JSNative>(v))
#define JS_PROPERTYOP_SETTER(v) \
(static_cast<void>(sizeof(JS::detail::CheckIsSetterOp(v))), \
reinterpret_cast<JSNative>(v))
#define JS_STUBGETTER JS_PROPERTYOP_GETTER(JS_PropertyStub)
#define JS_STUBSETTER JS_PROPERTYOP_SETTER(JS_StrictPropertyStub)
/*
* JSPropertySpec uses JSNativeWrapper. These macros encapsulate the definition
* of JSNative-backed JSPropertySpecs, by defining the JSNativeWrappers for
* them.
*/
#define JS_PSG(name, getter, flags) \
{name, \
uint8_t(JS_CHECK_ACCESSOR_FLAGS(flags) | JSPROP_SHARED), \
JSNATIVE_WRAPPER(getter), \
JSNATIVE_WRAPPER(nullptr)}
#define JS_PSGS(name, getter, setter, flags) \
{name, \
uint8_t(JS_CHECK_ACCESSOR_FLAGS(flags) | JSPROP_SHARED), \
JSNATIVE_WRAPPER(getter), \
JSNATIVE_WRAPPER(setter)}
#define JS_SELF_HOSTED_GET(name, getterName, flags) \
{name, \
uint8_t(JS_CHECK_ACCESSOR_FLAGS(flags) | JSPROP_SHARED | JSPROP_GETTER), \
{ { nullptr, JS_CAST_STRING_TO(getterName, const JSJitInfo*) } }, \
JSNATIVE_WRAPPER(nullptr) }
#define JS_SELF_HOSTED_GETSET(name, getterName, setterName, flags) \
{name, \
uint8_t(JS_CHECK_ACCESSOR_FLAGS(flags) | JSPROP_SHARED | JSPROP_GETTER | JSPROP_SETTER), \
{ nullptr, JS_CAST_STRING_TO(getterName, const JSJitInfo*) }, \
{ nullptr, JS_CAST_STRING_TO(setterName, const JSJitInfo*) } }
#define JS_PS_END { nullptr, 0, JSNATIVE_WRAPPER(nullptr), JSNATIVE_WRAPPER(nullptr) }
#define JS_SELF_HOSTED_SYM_GET(symbol, getterName, flags) \
{reinterpret_cast<const char*>(uint32_t(::JS::SymbolCode::symbol) + 1), \
uint8_t(JS_CHECK_ACCESSOR_FLAGS(flags) | JSPROP_SHARED | JSPROP_GETTER), \
{ { nullptr, JS_CAST_STRING_TO(getterName, const JSJitInfo*) } }, \
JSNATIVE_WRAPPER(nullptr) }
/**
* To define a native function, set call to a JSNativeWrapper. To define a
* self-hosted function, set selfHostedName to the name of a function
* compiled during JSRuntime::initSelfHosting.
*/
struct JSFunctionSpec {
const char* name;
JSNativeWrapper call;
uint16_t nargs;
uint16_t flags;
const char* selfHostedName;
};
/*
* Terminating sentinel initializer to put at the end of a JSFunctionSpec array
* that's passed to JS_DefineFunctions or JS_InitClass.
*/
#define JS_FS_END JS_FS(nullptr,nullptr,0,0)
/*
* Initializer macros for a JSFunctionSpec array element. JS_FN (whose name pays
* homage to the old JSNative/JSFastNative split) simply adds the flag
* JSFUN_STUB_GSOPS. JS_FNINFO allows the simple adding of
* JSJitInfos. JS_SELF_HOSTED_FN declares a self-hosted function.
* JS_INLINABLE_FN allows specifying an InlinableNative enum value for natives
* inlined or specialized by the JIT. Finally JS_FNSPEC has slots for all the
* fields.
*
* The _SYM variants allow defining a function with a symbol key rather than a
* string key. For example, use JS_SYM_FN(iterator, ...) to define an
* @@iterator method.
*/
#define JS_FS(name,call,nargs,flags) \
JS_FNSPEC(name, call, nullptr, nargs, flags, nullptr)
#define JS_FN(name,call,nargs,flags) \
JS_FNSPEC(name, call, nullptr, nargs, (flags) | JSFUN_STUB_GSOPS, nullptr)
#define JS_INLINABLE_FN(name,call,nargs,flags,native) \
JS_FNSPEC(name, call, &js::jit::JitInfo_##native, nargs, (flags) | JSFUN_STUB_GSOPS, nullptr)
#define JS_SYM_FN(symbol,call,nargs,flags) \
JS_SYM_FNSPEC(symbol, call, nullptr, nargs, (flags) | JSFUN_STUB_GSOPS, nullptr)
#define JS_FNINFO(name,call,info,nargs,flags) \
JS_FNSPEC(name, call, info, nargs, flags, nullptr)
#define JS_SELF_HOSTED_FN(name,selfHostedName,nargs,flags) \
JS_FNSPEC(name, nullptr, nullptr, nargs, flags, selfHostedName)
#define JS_SELF_HOSTED_SYM_FN(symbol, selfHostedName, nargs, flags) \
JS_SYM_FNSPEC(symbol, nullptr, nullptr, nargs, flags, selfHostedName)
#define JS_SYM_FNSPEC(symbol, call, info, nargs, flags, selfHostedName) \
JS_FNSPEC(reinterpret_cast<const char*>( \
uint32_t(::JS::SymbolCode::symbol) + 1), \
call, info, nargs, flags, selfHostedName)
#define JS_FNSPEC(name,call,info,nargs,flags,selfHostedName) \
{name, {call, info}, nargs, flags, selfHostedName}
extern JS_PUBLIC_API(JSObject*)
JS_InitClass(JSContext* cx, JS::HandleObject obj, JS::HandleObject parent_proto,
const JSClass* clasp, JSNative constructor, unsigned nargs,
const JSPropertySpec* ps, const JSFunctionSpec* fs,
const JSPropertySpec* static_ps, const JSFunctionSpec* static_fs);
/**
* Set up ctor.prototype = proto and proto.constructor = ctor with the
* right property flags.
*/
extern JS_PUBLIC_API(bool)
JS_LinkConstructorAndPrototype(JSContext* cx, JS::Handle<JSObject*> ctor,
JS::Handle<JSObject*> proto);
extern JS_PUBLIC_API(const JSClass*)
JS_GetClass(JSObject* obj);
extern JS_PUBLIC_API(bool)
JS_InstanceOf(JSContext* cx, JS::Handle<JSObject*> obj, const JSClass* clasp, JS::CallArgs* args);
extern JS_PUBLIC_API(bool)
JS_HasInstance(JSContext* cx, JS::Handle<JSObject*> obj, JS::Handle<JS::Value> v, bool* bp);
extern JS_PUBLIC_API(void*)
JS_GetPrivate(JSObject* obj);
extern JS_PUBLIC_API(void)
JS_SetPrivate(JSObject* obj, void* data);
extern JS_PUBLIC_API(void*)
JS_GetInstancePrivate(JSContext* cx, JS::Handle<JSObject*> obj, const JSClass* clasp,
JS::CallArgs* args);
extern JS_PUBLIC_API(JSObject*)
JS_GetConstructor(JSContext* cx, JS::Handle<JSObject*> proto);
namespace JS {
enum ZoneSpecifier {
FreshZone = 0,
SystemZone = 1
};
class JS_PUBLIC_API(CompartmentOptions)
{
public:
class Override {
public:
Override() : mode_(Default) {}
bool get(bool defaultValue) const {
if (mode_ == Default)
return defaultValue;
return mode_ == ForceTrue;
}
void set(bool overrideValue) {
mode_ = overrideValue ? ForceTrue : ForceFalse;
}
void reset() {
mode_ = Default;
}
private:
enum Mode {
Default,
ForceTrue,
ForceFalse
};
Mode mode_;
};
explicit CompartmentOptions()
: version_(JSVERSION_UNKNOWN)
, invisibleToDebugger_(false)
, mergeable_(false)
, discardSource_(false)
, disableLazyParsing_(false)
, cloneSingletons_(false)
, traceGlobal_(nullptr)
, singletonsAsTemplates_(true)
, addonId_(nullptr)
, preserveJitCode_(false)
{
zone_.spec = JS::FreshZone;
}
JSVersion version() const { return version_; }
CompartmentOptions& setVersion(JSVersion aVersion) {
MOZ_ASSERT(aVersion != JSVERSION_UNKNOWN);
version_ = aVersion;
return *this;
}
// Certain scopes (i.e. XBL compilation scopes) are implementation details
// of the embedding, and references to them should never leak out to script.
// This flag causes the this compartment to skip firing onNewGlobalObject
// and makes addDebuggee a no-op for this global.
bool invisibleToDebugger() const { return invisibleToDebugger_; }
CompartmentOptions& setInvisibleToDebugger(bool flag) {
invisibleToDebugger_ = flag;
return *this;
}
// Compartments used for off-thread compilation have their contents merged
// into a target compartment when the compilation is finished. This is only
// allowed if this flag is set. The invisibleToDebugger flag must also be
// set for such compartments.
bool mergeable() const { return mergeable_; }
CompartmentOptions& setMergeable(bool flag) {
mergeable_ = flag;
return *this;
}
// For certain globals, we know enough about the code that will run in them
// that we can discard script source entirely.
bool discardSource() const { return discardSource_; }
CompartmentOptions& setDiscardSource(bool flag) {
discardSource_ = flag;
return *this;
}
bool disableLazyParsing() const { return disableLazyParsing_; }
CompartmentOptions& setDisableLazyParsing(bool flag) {
disableLazyParsing_ = flag;
return *this;
}
bool cloneSingletons() const { return cloneSingletons_; }
CompartmentOptions& setCloneSingletons(bool flag) {
cloneSingletons_ = flag;
return *this;
}
bool extraWarnings(JSRuntime* rt) const;
bool extraWarnings(JSContext* cx) const;
Override& extraWarningsOverride() { return extraWarningsOverride_; }
void* zonePointer() const {
MOZ_ASSERT(uintptr_t(zone_.pointer) > uintptr_t(JS::SystemZone));
return zone_.pointer;
}
ZoneSpecifier zoneSpecifier() const { return zone_.spec; }
CompartmentOptions& setZone(ZoneSpecifier spec);
CompartmentOptions& setSameZoneAs(JSObject* obj);
void setSingletonsAsValues() {
singletonsAsTemplates_ = false;
}
bool getSingletonsAsTemplates() const {
return singletonsAsTemplates_;
}
// A null add-on ID means that the compartment is not associated with an
// add-on.
JSAddonId* addonIdOrNull() const { return addonId_; }
CompartmentOptions& setAddonId(JSAddonId* id) {
addonId_ = id;
return *this;
}
CompartmentOptions& setTrace(JSTraceOp op) {
traceGlobal_ = op;
return *this;
}
JSTraceOp getTrace() const {
return traceGlobal_;
}
bool preserveJitCode() const { return preserveJitCode_; }
CompartmentOptions& setPreserveJitCode(bool flag) {
preserveJitCode_ = flag;
return *this;
}
private:
JSVersion version_;
bool invisibleToDebugger_;
bool mergeable_;
bool discardSource_;
bool disableLazyParsing_;
bool cloneSingletons_;
Override extraWarningsOverride_;
union {
ZoneSpecifier spec;
void* pointer; // js::Zone* is not exposed in the API.
} zone_;
JSTraceOp traceGlobal_;
// To XDR singletons, we need to ensure that all singletons are all used as
// templates, by making JSOP_OBJECT return a clone of the JSScript
// singleton, instead of returning the value which is baked in the JSScript.
bool singletonsAsTemplates_;
JSAddonId* addonId_;
bool preserveJitCode_;
};
JS_PUBLIC_API(CompartmentOptions&)
CompartmentOptionsRef(JSCompartment* compartment);
JS_PUBLIC_API(CompartmentOptions&)
CompartmentOptionsRef(JSObject* obj);
JS_PUBLIC_API(CompartmentOptions&)
CompartmentOptionsRef(JSContext* cx);
/**
* During global creation, we fire notifications to callbacks registered
* via the Debugger API. These callbacks are arbitrary script, and can touch
* the global in arbitrary ways. When that happens, the global should not be
* in a half-baked state. But this creates a problem for consumers that need
* to set slots on the global to put it in a consistent state.
*
* This API provides a way for consumers to set slots atomically (immediately
* after the global is created), before any debugger hooks are fired. It's
* unfortunately on the clunky side, but that's the way the cookie crumbles.
*
* If callers have no additional state on the global to set up, they may pass
* |FireOnNewGlobalHook| to JS_NewGlobalObject, which causes that function to
* fire the hook as its final act before returning. Otherwise, callers should
* pass |DontFireOnNewGlobalHook|, which means that they are responsible for
* invoking JS_FireOnNewGlobalObject upon successfully creating the global. If
* an error occurs and the operation aborts, callers should skip firing the
* hook. But otherwise, callers must take care to fire the hook exactly once
* before compiling any script in the global's scope (we have assertions in
* place to enforce this). This lets us be sure that debugger clients never miss
* breakpoints.
*/
enum OnNewGlobalHookOption {
FireOnNewGlobalHook,
DontFireOnNewGlobalHook
};
} /* namespace JS */
extern JS_PUBLIC_API(JSObject*)
JS_NewGlobalObject(JSContext* cx, const JSClass* clasp, JSPrincipals* principals,
JS::OnNewGlobalHookOption hookOption,
const JS::CompartmentOptions& options = JS::CompartmentOptions());
/**
* Spidermonkey does not have a good way of keeping track of what compartments should be marked on
* their own. We can mark the roots unconditionally, but marking GC things only relevant in live
* compartments is hard. To mitigate this, we create a static trace hook, installed on each global
* object, from which we can be sure the compartment is relevant, and mark it.
*
* It is still possible to specify custom trace hooks for global object classes. They can be
* provided via the CompartmentOptions passed to JS_NewGlobalObject.
*/
extern JS_PUBLIC_API(void)
JS_GlobalObjectTraceHook(JSTracer* trc, JSObject* global);
extern JS_PUBLIC_API(void)
JS_FireOnNewGlobalObject(JSContext* cx, JS::HandleObject global);
extern JS_PUBLIC_API(JSObject*)
JS_NewObject(JSContext* cx, const JSClass* clasp);
extern JS_PUBLIC_API(bool)
JS_IsNative(JSObject* obj);
extern JS_PUBLIC_API(JSRuntime*)
JS_GetObjectRuntime(JSObject* obj);
/**
* Unlike JS_NewObject, JS_NewObjectWithGivenProto does not compute a default
* proto. If proto is nullptr, the JS object will have `null` as [[Prototype]].
*/
extern JS_PUBLIC_API(JSObject*)
JS_NewObjectWithGivenProto(JSContext* cx, const JSClass* clasp, JS::Handle<JSObject*> proto);
/** Creates a new plain object, like `new Object()`, with Object.prototype as [[Prototype]]. */
extern JS_PUBLIC_API(JSObject*)
JS_NewPlainObject(JSContext* cx);
/**
* Freeze obj, and all objects it refers to, recursively. This will not recurse
* through non-extensible objects, on the assumption that those are already
* deep-frozen.
*/
extern JS_PUBLIC_API(bool)
JS_DeepFreezeObject(JSContext* cx, JS::Handle<JSObject*> obj);
/**
* Freezes an object; see ES5's Object.freeze(obj) method.
*/
extern JS_PUBLIC_API(bool)
JS_FreezeObject(JSContext* cx, JS::Handle<JSObject*> obj);
/*** Property descriptors ************************************************************************/
struct JSPropertyDescriptor : public JS::Traceable {
JSObject* obj;
unsigned attrs;
JSGetterOp getter;
JSSetterOp setter;
JS::Value value;
JSPropertyDescriptor()
: obj(nullptr), attrs(0), getter(nullptr), setter(nullptr), value(JS::UndefinedValue())
{}
static void trace(JSPropertyDescriptor* self, JSTracer* trc) { self->trace(trc); }
void trace(JSTracer* trc);
};
namespace JS {
template <typename Outer>
class PropertyDescriptorOperations
{
const JSPropertyDescriptor& desc() const { return static_cast<const Outer*>(this)->get(); }
bool has(unsigned bit) const {
MOZ_ASSERT(bit != 0);
MOZ_ASSERT((bit & (bit - 1)) == 0); // only a single bit
return (desc().attrs & bit) != 0;
}
bool hasAny(unsigned bits) const {
return (desc().attrs & bits) != 0;
}
bool hasAll(unsigned bits) const {
return (desc().attrs & bits) == bits;
}
// Non-API attributes bit used internally for arguments objects.
enum { SHADOWABLE = JSPROP_INTERNAL_USE_BIT };
public:
// Descriptors with JSGetterOp/JSSetterOp are considered data
// descriptors. It's complicated.
bool isAccessorDescriptor() const { return hasAny(JSPROP_GETTER | JSPROP_SETTER); }
bool isGenericDescriptor() const {
return (desc().attrs&
(JSPROP_GETTER | JSPROP_SETTER | JSPROP_IGNORE_READONLY | JSPROP_IGNORE_VALUE)) ==
(JSPROP_IGNORE_READONLY | JSPROP_IGNORE_VALUE);
}
bool isDataDescriptor() const { return !isAccessorDescriptor() && !isGenericDescriptor(); }
bool hasConfigurable() const { return !has(JSPROP_IGNORE_PERMANENT); }
bool configurable() const { MOZ_ASSERT(hasConfigurable()); return !has(JSPROP_PERMANENT); }
bool hasEnumerable() const { return !has(JSPROP_IGNORE_ENUMERATE); }
bool enumerable() const { MOZ_ASSERT(hasEnumerable()); return has(JSPROP_ENUMERATE); }
bool hasValue() const { return !isAccessorDescriptor() && !has(JSPROP_IGNORE_VALUE); }
JS::HandleValue value() const {
return JS::HandleValue::fromMarkedLocation(&desc().value);
}
bool hasWritable() const { return !isAccessorDescriptor() && !has(JSPROP_IGNORE_READONLY); }
bool writable() const { MOZ_ASSERT(hasWritable()); return !has(JSPROP_READONLY); }
bool hasGetterObject() const { return has(JSPROP_GETTER); }
JS::HandleObject getterObject() const {
MOZ_ASSERT(hasGetterObject());
return JS::HandleObject::fromMarkedLocation(
reinterpret_cast<JSObject* const*>(&desc().getter));
}
bool hasSetterObject() const { return has(JSPROP_SETTER); }
JS::HandleObject setterObject() const {
MOZ_ASSERT(hasSetterObject());
return JS::HandleObject::fromMarkedLocation(
reinterpret_cast<JSObject* const*>(&desc().setter));
}
bool hasGetterOrSetter() const { return desc().getter || desc().setter; }
bool isShared() const { return has(JSPROP_SHARED); }
JS::HandleObject object() const {
return JS::HandleObject::fromMarkedLocation(&desc().obj);
}
unsigned attributes() const { return desc().attrs; }
JSGetterOp getter() const { return desc().getter; }
JSSetterOp setter() const { return desc().setter; }
void assertValid() const {
#ifdef DEBUG
MOZ_ASSERT((attributes() & ~(JSPROP_ENUMERATE | JSPROP_IGNORE_ENUMERATE |
JSPROP_PERMANENT | JSPROP_IGNORE_PERMANENT |
JSPROP_READONLY | JSPROP_IGNORE_READONLY |
JSPROP_IGNORE_VALUE |
JSPROP_GETTER |
JSPROP_SETTER |
JSPROP_SHARED |
JSPROP_REDEFINE_NONCONFIGURABLE |
JSPROP_RESOLVING |
SHADOWABLE)) == 0);
MOZ_ASSERT(!hasAll(JSPROP_IGNORE_ENUMERATE | JSPROP_ENUMERATE));
MOZ_ASSERT(!hasAll(JSPROP_IGNORE_PERMANENT | JSPROP_PERMANENT));
if (isAccessorDescriptor()) {
MOZ_ASSERT(has(JSPROP_SHARED));
MOZ_ASSERT(!has(JSPROP_READONLY));
MOZ_ASSERT(!has(JSPROP_IGNORE_READONLY));
MOZ_ASSERT(!has(JSPROP_IGNORE_VALUE));
MOZ_ASSERT(!has(SHADOWABLE));
MOZ_ASSERT(value().isUndefined());
MOZ_ASSERT_IF(!has(JSPROP_GETTER), !getter());
MOZ_ASSERT_IF(!has(JSPROP_SETTER), !setter());
} else {
MOZ_ASSERT(!hasAll(JSPROP_IGNORE_READONLY | JSPROP_READONLY));
MOZ_ASSERT_IF(has(JSPROP_IGNORE_VALUE), value().isUndefined());
}
MOZ_ASSERT(getter() != JS_PropertyStub);
MOZ_ASSERT(setter() != JS_StrictPropertyStub);
MOZ_ASSERT_IF(has(JSPROP_RESOLVING), !has(JSPROP_IGNORE_ENUMERATE));
MOZ_ASSERT_IF(has(JSPROP_RESOLVING), !has(JSPROP_IGNORE_PERMANENT));
MOZ_ASSERT_IF(has(JSPROP_RESOLVING), !has(JSPROP_IGNORE_READONLY));
MOZ_ASSERT_IF(has(JSPROP_RESOLVING), !has(JSPROP_IGNORE_VALUE));
MOZ_ASSERT_IF(has(JSPROP_RESOLVING), !has(JSPROP_REDEFINE_NONCONFIGURABLE));
#endif
}
void assertComplete() const {
#ifdef DEBUG
assertValid();
MOZ_ASSERT((attributes() & ~(JSPROP_ENUMERATE |
JSPROP_PERMANENT |
JSPROP_READONLY |
JSPROP_GETTER |
JSPROP_SETTER |
JSPROP_SHARED |
JSPROP_REDEFINE_NONCONFIGURABLE |
JSPROP_RESOLVING |
SHADOWABLE)) == 0);
MOZ_ASSERT_IF(isAccessorDescriptor(), has(JSPROP_GETTER) && has(JSPROP_SETTER));
#endif
}
void assertCompleteIfFound() const {
#ifdef DEBUG
if (object())
assertComplete();
#endif
}
};
template <typename Outer>
class MutablePropertyDescriptorOperations : public PropertyDescriptorOperations<Outer>
{
JSPropertyDescriptor& desc() { return static_cast<Outer*>(this)->get(); }
public:
void clear() {
object().set(nullptr);
setAttributes(0);
setGetter(nullptr);
setSetter(nullptr);
value().setUndefined();
}
void initFields(HandleObject obj, HandleValue v, unsigned attrs,
JSGetterOp getterOp, JSSetterOp setterOp) {
MOZ_ASSERT(getterOp != JS_PropertyStub);
MOZ_ASSERT(setterOp != JS_StrictPropertyStub);
object().set(obj);
value().set(v);
setAttributes(attrs);
setGetter(getterOp);
setSetter(setterOp);
}
void assign(JSPropertyDescriptor& other) {
object().set(other.obj);
setAttributes(other.attrs);
setGetter(other.getter);
setSetter(other.setter);
value().set(other.value);
}
void setDataDescriptor(HandleValue v, unsigned attrs) {
MOZ_ASSERT((attrs & ~(JSPROP_ENUMERATE |
JSPROP_PERMANENT |
JSPROP_READONLY |
JSPROP_IGNORE_ENUMERATE |
JSPROP_IGNORE_PERMANENT |
JSPROP_IGNORE_READONLY)) == 0);
object().set(nullptr);
setAttributes(attrs);
setGetter(nullptr);
setSetter(nullptr);
value().set(v);
}
JS::MutableHandleObject object() {
return JS::MutableHandleObject::fromMarkedLocation(&desc().obj);
}
unsigned& attributesRef() { return desc().attrs; }
JSGetterOp& getter() { return desc().getter; }
JSSetterOp& setter() { return desc().setter; }
JS::MutableHandleValue value() {
return JS::MutableHandleValue::fromMarkedLocation(&desc().value);
}
void setValue(JS::HandleValue v) {
MOZ_ASSERT(!(desc().attrs & (JSPROP_GETTER | JSPROP_SETTER)));
attributesRef() &= ~JSPROP_IGNORE_VALUE;
value().set(v);
}
void setConfigurable(bool configurable) {
setAttributes((desc().attrs & ~(JSPROP_IGNORE_PERMANENT | JSPROP_PERMANENT)) |
(configurable ? 0 : JSPROP_PERMANENT));
}
void setEnumerable(bool enumerable) {
setAttributes((desc().attrs & ~(JSPROP_IGNORE_ENUMERATE | JSPROP_ENUMERATE)) |
(enumerable ? JSPROP_ENUMERATE : 0));
}
void setWritable(bool writable) {
MOZ_ASSERT(!(desc().attrs & (JSPROP_GETTER | JSPROP_SETTER)));
setAttributes((desc().attrs & ~(JSPROP_IGNORE_READONLY | JSPROP_READONLY)) |
(writable ? 0 : JSPROP_READONLY));
}
void setAttributes(unsigned attrs) { desc().attrs = attrs; }
void setGetter(JSGetterOp op) {
MOZ_ASSERT(op != JS_PropertyStub);
desc().getter = op;
}
void setSetter(JSSetterOp op) {
MOZ_ASSERT(op != JS_StrictPropertyStub);
desc().setter = op;
}
void setGetterObject(JSObject* obj) {
desc().getter = reinterpret_cast<JSGetterOp>(obj);
desc().attrs &= ~(JSPROP_IGNORE_VALUE | JSPROP_IGNORE_READONLY | JSPROP_READONLY);
desc().attrs |= JSPROP_GETTER | JSPROP_SHARED;
}
void setSetterObject(JSObject* obj) {
desc().setter = reinterpret_cast<JSSetterOp>(obj);
desc().attrs &= ~(JSPROP_IGNORE_VALUE | JSPROP_IGNORE_READONLY | JSPROP_READONLY);
desc().attrs |= JSPROP_SETTER | JSPROP_SHARED;
}
JS::MutableHandleObject getterObject() {
MOZ_ASSERT(this->hasGetterObject());
return JS::MutableHandleObject::fromMarkedLocation(
reinterpret_cast<JSObject**>(&desc().getter));
}
JS::MutableHandleObject setterObject() {
MOZ_ASSERT(this->hasSetterObject());
return JS::MutableHandleObject::fromMarkedLocation(
reinterpret_cast<JSObject**>(&desc().setter));
}
};
} /* namespace JS */
namespace js {
template <>
class RootedBase<JSPropertyDescriptor>
: public JS::MutablePropertyDescriptorOperations<JS::Rooted<JSPropertyDescriptor>>
{};
template <>
class HandleBase<JSPropertyDescriptor>
: public JS::PropertyDescriptorOperations<JS::Handle<JSPropertyDescriptor>>
{};
template <>
class MutableHandleBase<JSPropertyDescriptor>
: public JS::MutablePropertyDescriptorOperations<JS::MutableHandle<JSPropertyDescriptor>>
{};
} /* namespace js */
namespace JS {
extern JS_PUBLIC_API(bool)
ObjectToCompletePropertyDescriptor(JSContext* cx,
JS::HandleObject obj,
JS::HandleValue descriptor,
JS::MutableHandle<JSPropertyDescriptor> desc);
} // namespace JS
/*** Standard internal methods ********************************************************************
*
* The functions below are the fundamental operations on objects.
*
* ES6 specifies 14 internal methods that define how objects behave. The
* standard is actually quite good on this topic, though you may have to read
* it a few times. See ES6 sections 6.1.7.2 and 6.1.7.3.
*
* When 'obj' is an ordinary object, these functions have boring standard
* behavior as specified by ES6 section 9.1; see the section about internal
* methods in js/src/vm/NativeObject.h.
*
* Proxies override the behavior of internal methods. So when 'obj' is a proxy,
* any one of the functions below could do just about anything. See
* js/public/Proxy.h.
*/
/**
* Get the prototype of obj, storing it in result.
*
* Implements: ES6 [[GetPrototypeOf]] internal method.
*/
extern JS_PUBLIC_API(bool)
JS_GetPrototype(JSContext* cx, JS::HandleObject obj, JS::MutableHandleObject result);
/**
* Change the prototype of obj.
*
* Implements: ES6 [[SetPrototypeOf]] internal method.
*
* In cases where ES6 [[SetPrototypeOf]] returns false without an exception,
* JS_SetPrototype throws a TypeError and returns false.
*
* Performance warning: JS_SetPrototype is very bad for performance. It may
* cause compiled jit-code to be invalidated. It also causes not only obj but
* all other objects in the same "group" as obj to be permanently deoptimized.
* It's better to create the object with the right prototype from the start.
*/
extern JS_PUBLIC_API(bool)
JS_SetPrototype(JSContext* cx, JS::HandleObject obj, JS::HandleObject proto);
/**
* Determine whether obj is extensible. Extensible objects can have new
* properties defined on them. Inextensible objects can't, and their
* [[Prototype]] slot is fixed as well.
*
* Implements: ES6 [[IsExtensible]] internal method.
*/
extern JS_PUBLIC_API(bool)
JS_IsExtensible(JSContext* cx, JS::HandleObject obj, bool* extensible);
/**
* Attempt to make |obj| non-extensible.
*
* Not all failures are treated as errors. See the comment on
* JS::ObjectOpResult in js/public/Class.h.
*
* Implements: ES6 [[PreventExtensions]] internal method.
*/
extern JS_PUBLIC_API(bool)
JS_PreventExtensions(JSContext* cx, JS::HandleObject obj, JS::ObjectOpResult& result);
/**
* Attempt to make the [[Prototype]] of |obj| immutable, such that any attempt
* to modify it will fail. If an error occurs during the attempt, return false
* (with a pending exception set, depending upon the nature of the error). If
* no error occurs, return true with |*succeeded| set to indicate whether the
* attempt successfully made the [[Prototype]] immutable.
*
* This is a nonstandard internal method.
*/
extern JS_PUBLIC_API(bool)
JS_SetImmutablePrototype(JSContext* cx, JS::HandleObject obj, bool* succeeded);
/**
* Get a description of one of obj's own properties. If no such property exists
* on obj, return true with desc.object() set to null.
*
* Implements: ES6 [[GetOwnProperty]] internal method.
*/
extern JS_PUBLIC_API(bool)
JS_GetOwnPropertyDescriptorById(JSContext* cx, JS::HandleObject obj, JS::HandleId id,
JS::MutableHandle<JSPropertyDescriptor> desc);
extern JS_PUBLIC_API(bool)
JS_GetOwnPropertyDescriptor(JSContext* cx, JS::HandleObject obj, const char* name,
JS::MutableHandle<JSPropertyDescriptor> desc);
extern JS_PUBLIC_API(bool)
JS_GetOwnUCPropertyDescriptor(JSContext* cx, JS::HandleObject obj, const char16_t* name,
JS::MutableHandle<JSPropertyDescriptor> desc);
/**
* Like JS_GetOwnPropertyDescriptorById, but also searches the prototype chain
* if no own property is found directly on obj. The object on which the
* property is found is returned in desc.object(). If the property is not found
* on the prototype chain, this returns true with desc.object() set to null.
*/
extern JS_PUBLIC_API(bool)
JS_GetPropertyDescriptorById(JSContext* cx, JS::HandleObject obj, JS::HandleId id,
JS::MutableHandle<JSPropertyDescriptor> desc);
extern JS_PUBLIC_API(bool)
JS_GetPropertyDescriptor(JSContext* cx, JS::HandleObject obj, const char* name,
JS::MutableHandle<JSPropertyDescriptor> desc);
/**
* Define a property on obj.
*
* This function uses JS::ObjectOpResult to indicate conditions that ES6
* specifies as non-error failures. This is inconvenient at best, so use this
* function only if you are implementing a proxy handler's defineProperty()
* method. For all other purposes, use one of the many DefineProperty functions
* below that throw an exception in all failure cases.
*
* Implements: ES6 [[DefineOwnProperty]] internal method.
*/
extern JS_PUBLIC_API(bool)
JS_DefinePropertyById(JSContext* cx, JS::HandleObject obj, JS::HandleId id,
JS::Handle<JSPropertyDescriptor> desc,
JS::ObjectOpResult& result);
/**
* Define a property on obj, throwing a TypeError if the attempt fails.
* This is the C++ equivalent of `Object.defineProperty(obj, id, desc)`.
*/
extern JS_PUBLIC_API(bool)
JS_DefinePropertyById(JSContext* cx, JS::HandleObject obj, JS::HandleId id,
JS::Handle<JSPropertyDescriptor> desc);
extern JS_PUBLIC_API(bool)
JS_DefinePropertyById(JSContext* cx, JS::HandleObject obj, JS::HandleId id, JS::HandleValue value,
unsigned attrs, JSNative getter = nullptr, JSNative setter = nullptr);
extern JS_PUBLIC_API(bool)
JS_DefinePropertyById(JSContext* cx, JS::HandleObject obj, JS::HandleId id, JS::HandleObject value,
unsigned attrs, JSNative getter = nullptr, JSNative setter = nullptr);
extern JS_PUBLIC_API(bool)
JS_DefinePropertyById(JSContext* cx, JS::HandleObject obj, JS::HandleId id, JS::HandleString value,
unsigned attrs, JSNative getter = nullptr, JSNative setter = nullptr);
extern JS_PUBLIC_API(bool)
JS_DefinePropertyById(JSContext* cx, JS::HandleObject obj, JS::HandleId id, int32_t value,
unsigned attrs, JSNative getter = nullptr, JSNative setter = nullptr);
extern JS_PUBLIC_API(bool)
JS_DefinePropertyById(JSContext* cx, JS::HandleObject obj, JS::HandleId id, uint32_t value,
unsigned attrs, JSNative getter = nullptr, JSNative setter = nullptr);
extern JS_PUBLIC_API(bool)
JS_DefinePropertyById(JSContext* cx, JS::HandleObject obj, JS::HandleId id, double value,
unsigned attrs, JSNative getter = nullptr, JSNative setter = nullptr);
extern JS_PUBLIC_API(bool)
JS_DefineProperty(JSContext* cx, JS::HandleObject obj, const char* name, JS::HandleValue value,
unsigned attrs, JSNative getter = nullptr, JSNative setter = nullptr);
extern JS_PUBLIC_API(bool)
JS_DefineProperty(JSContext* cx, JS::HandleObject obj, const char* name, JS::HandleObject value,
unsigned attrs, JSNative getter = nullptr, JSNative setter = nullptr);
extern JS_PUBLIC_API(bool)
JS_DefineProperty(JSContext* cx, JS::HandleObject obj, const char* name, JS::HandleString value,
unsigned attrs, JSNative getter = nullptr, JSNative setter = nullptr);
extern JS_PUBLIC_API(bool)
JS_DefineProperty(JSContext* cx, JS::HandleObject obj, const char* name, int32_t value,
unsigned attrs, JSNative getter = nullptr, JSNative setter = nullptr);
extern JS_PUBLIC_API(bool)
JS_DefineProperty(JSContext* cx, JS::HandleObject obj, const char* name, uint32_t value,
unsigned attrs, JSNative getter = nullptr, JSNative setter = nullptr);
extern JS_PUBLIC_API(bool)
JS_DefineProperty(JSContext* cx, JS::HandleObject obj, const char* name, double value,
unsigned attrs, JSNative getter = nullptr, JSNative setter = nullptr);
extern JS_PUBLIC_API(bool)
JS_DefineUCProperty(JSContext* cx, JS::HandleObject obj, const char16_t* name, size_t namelen,
JS::Handle<JSPropertyDescriptor> desc,
JS::ObjectOpResult& result);
extern JS_PUBLIC_API(bool)
JS_DefineUCProperty(JSContext* cx, JS::HandleObject obj, const char16_t* name, size_t namelen,
JS::Handle<JSPropertyDescriptor> desc);
extern JS_PUBLIC_API(bool)
JS_DefineUCProperty(JSContext* cx, JS::HandleObject obj, const char16_t* name, size_t namelen,
JS::HandleValue value, unsigned attrs,
JSNative getter = nullptr, JSNative setter = nullptr);
extern JS_PUBLIC_API(bool)
JS_DefineUCProperty(JSContext* cx, JS::HandleObject obj, const char16_t* name, size_t namelen,
JS::HandleObject value, unsigned attrs,
JSNative getter = nullptr, JSNative setter = nullptr);
extern JS_PUBLIC_API(bool)
JS_DefineUCProperty(JSContext* cx, JS::HandleObject obj, const char16_t* name, size_t namelen,
JS::HandleString value, unsigned attrs,
JSNative getter = nullptr, JSNative setter = nullptr);
extern JS_PUBLIC_API(bool)
JS_DefineUCProperty(JSContext* cx, JS::HandleObject obj, const char16_t* name, size_t namelen,
int32_t value, unsigned attrs,
JSNative getter = nullptr, JSNative setter = nullptr);
extern JS_PUBLIC_API(bool)
JS_DefineUCProperty(JSContext* cx, JS::HandleObject obj, const char16_t* name, size_t namelen,
uint32_t value, unsigned attrs,
JSNative getter = nullptr, JSNative setter = nullptr);
extern JS_PUBLIC_API(bool)
JS_DefineUCProperty(JSContext* cx, JS::HandleObject obj, const char16_t* name, size_t namelen,
double value, unsigned attrs,
JSNative getter = nullptr, JSNative setter = nullptr);
extern JS_PUBLIC_API(bool)
JS_DefineElement(JSContext* cx, JS::HandleObject obj, uint32_t index, JS::HandleValue value,
unsigned attrs, JSNative getter = nullptr, JSNative setter = nullptr);
extern JS_PUBLIC_API(bool)
JS_DefineElement(JSContext* cx, JS::HandleObject obj, uint32_t index, JS::HandleObject value,
unsigned attrs, JSNative getter = nullptr, JSNative setter = nullptr);
extern JS_PUBLIC_API(bool)
JS_DefineElement(JSContext* cx, JS::HandleObject obj, uint32_t index, JS::HandleString value,
unsigned attrs, JSNative getter = nullptr, JSNative setter = nullptr);
extern JS_PUBLIC_API(bool)
JS_DefineElement(JSContext* cx, JS::HandleObject obj, uint32_t index, int32_t value,
unsigned attrs, JSNative getter = nullptr, JSNative setter = nullptr);
extern JS_PUBLIC_API(bool)
JS_DefineElement(JSContext* cx, JS::HandleObject obj, uint32_t index, uint32_t value,
unsigned attrs, JSNative getter = nullptr, JSNative setter = nullptr);
extern JS_PUBLIC_API(bool)
JS_DefineElement(JSContext* cx, JS::HandleObject obj, uint32_t index, double value,
unsigned attrs, JSNative getter = nullptr, JSNative setter = nullptr);
/**
* Compute the expression `id in obj`.
*
* If obj has an own or inherited property obj[id], set *foundp = true and
* return true. If not, set *foundp = false and return true. On error, return
* false with an exception pending.
*
* Implements: ES6 [[Has]] internal method.
*/
extern JS_PUBLIC_API(bool)
JS_HasPropertyById(JSContext* cx, JS::HandleObject obj, JS::HandleId id, bool* foundp);
extern JS_PUBLIC_API(bool)
JS_HasProperty(JSContext* cx, JS::HandleObject obj, const char* name, bool* foundp);
extern JS_PUBLIC_API(bool)
JS_HasUCProperty(JSContext* cx, JS::HandleObject obj, const char16_t* name, size_t namelen,
bool* vp);
extern JS_PUBLIC_API(bool)
JS_HasElement(JSContext* cx, JS::HandleObject obj, uint32_t index, bool* foundp);
/**
* Determine whether obj has an own property with the key `id`.
*
* Implements: ES6 7.3.11 HasOwnProperty(O, P).
*/
extern JS_PUBLIC_API(bool)
JS_HasOwnPropertyById(JSContext* cx, JS::HandleObject obj, JS::HandleId id, bool* foundp);
extern JS_PUBLIC_API(bool)
JS_HasOwnProperty(JSContext* cx, JS::HandleObject obj, const char* name, bool* foundp);
/**
* Get the value of the property `obj[id]`, or undefined if no such property
* exists. This is the C++ equivalent of `vp = Reflect.get(obj, id, receiver)`.
*
* Most callers don't need the `receiver` argument. Consider using
* JS_GetProperty instead. (But if you're implementing a proxy handler's set()
* method, it's often correct to call this function and pass the receiver
* through.)
*
* Implements: ES6 [[Get]] internal method.
*/
extern JS_PUBLIC_API(bool)
JS_ForwardGetPropertyTo(JSContext* cx, JS::HandleObject obj, JS::HandleId id,
JS::HandleValue receiver, JS::MutableHandleValue vp);
extern JS_PUBLIC_API(bool)
JS_ForwardGetElementTo(JSContext* cx, JS::HandleObject obj, uint32_t index,
JS::HandleObject receiver, JS::MutableHandleValue vp);
/**
* Get the value of the property `obj[id]`, or undefined if no such property
* exists. The result is stored in vp.
*
* Implements: ES6 7.3.1 Get(O, P).
*/
extern JS_PUBLIC_API(bool)
JS_GetPropertyById(JSContext* cx, JS::HandleObject obj, JS::HandleId id,
JS::MutableHandleValue vp);
extern JS_PUBLIC_API(bool)
JS_GetProperty(JSContext* cx, JS::HandleObject obj, const char* name, JS::MutableHandleValue vp);
extern JS_PUBLIC_API(bool)
JS_GetUCProperty(JSContext* cx, JS::HandleObject obj, const char16_t* name, size_t namelen,
JS::MutableHandleValue vp);
extern JS_PUBLIC_API(bool)
JS_GetElement(JSContext* cx, JS::HandleObject obj, uint32_t index, JS::MutableHandleValue vp);
/**
* Perform the same property assignment as `Reflect.set(obj, id, v, receiver)`.
*
* This function has a `receiver` argument that most callers don't need.
* Consider using JS_SetProperty instead.
*
* Implements: ES6 [[Set]] internal method.
*/
extern JS_PUBLIC_API(bool)
JS_ForwardSetPropertyTo(JSContext* cx, JS::HandleObject obj, JS::HandleId id, JS::HandleValue v,
JS::HandleValue receiver, JS::ObjectOpResult& result);
/**
* Perform the assignment `obj[id] = v`.
*
* This function performs non-strict assignment, so if the property is
* read-only, nothing happens and no error is thrown.
*/
extern JS_PUBLIC_API(bool)
JS_SetPropertyById(JSContext* cx, JS::HandleObject obj, JS::HandleId id, JS::HandleValue v);
extern JS_PUBLIC_API(bool)
JS_SetProperty(JSContext* cx, JS::HandleObject obj, const char* name, JS::HandleValue v);
extern JS_PUBLIC_API(bool)
JS_SetUCProperty(JSContext* cx, JS::HandleObject obj, const char16_t* name, size_t namelen,
JS::HandleValue v);
extern JS_PUBLIC_API(bool)
JS_SetElement(JSContext* cx, JS::HandleObject obj, uint32_t index, JS::HandleValue v);
extern JS_PUBLIC_API(bool)
JS_SetElement(JSContext* cx, JS::HandleObject obj, uint32_t index, JS::HandleObject v);
extern JS_PUBLIC_API(bool)
JS_SetElement(JSContext* cx, JS::HandleObject obj, uint32_t index, JS::HandleString v);
extern JS_PUBLIC_API(bool)
JS_SetElement(JSContext* cx, JS::HandleObject obj, uint32_t index, int32_t v);
extern JS_PUBLIC_API(bool)
JS_SetElement(JSContext* cx, JS::HandleObject obj, uint32_t index, uint32_t v);
extern JS_PUBLIC_API(bool)
JS_SetElement(JSContext* cx, JS::HandleObject obj, uint32_t index, double v);
/**
* Delete a property. This is the C++ equivalent of
* `result = Reflect.deleteProperty(obj, id)`.
*
* This function has a `result` out parameter that most callers don't need.
* Unless you can pass through an ObjectOpResult provided by your caller, it's
* probably best to use the JS_DeletePropertyById signature with just 3
* arguments.
*
* Implements: ES6 [[Delete]] internal method.
*/
extern JS_PUBLIC_API(bool)
JS_DeletePropertyById(JSContext* cx, JS::HandleObject obj, JS::HandleId id,
JS::ObjectOpResult& result);
extern JS_PUBLIC_API(bool)
JS_DeleteProperty(JSContext* cx, JS::HandleObject obj, const char* name,
JS::ObjectOpResult& result);
extern JS_PUBLIC_API(bool)
JS_DeleteUCProperty(JSContext* cx, JS::HandleObject obj, const char16_t* name, size_t namelen,
JS::ObjectOpResult& result);
extern JS_PUBLIC_API(bool)
JS_DeleteElement(JSContext* cx, JS::HandleObject obj, uint32_t index, JS::ObjectOpResult& result);
/**
* Delete a property, ignoring strict failures. This is the C++ equivalent of
* the JS `delete obj[id]` in non-strict mode code.
*/
extern JS_PUBLIC_API(bool)
JS_DeletePropertyById(JSContext* cx, JS::HandleObject obj, jsid id);
extern JS_PUBLIC_API(bool)
JS_DeleteProperty(JSContext* cx, JS::HandleObject obj, const char* name);
extern JS_PUBLIC_API(bool)
JS_DeleteElement(JSContext* cx, JS::HandleObject obj, uint32_t index);
/**
* Get an array of the non-symbol enumerable properties of obj.
* This function is roughly equivalent to:
*
* var result = [];
* for (key in obj)
* result.push(key);
* return result;
*
* This is the closest thing we currently have to the ES6 [[Enumerate]]
* internal method.
*
* The JSIdArray returned by JS_Enumerate must be rooted to protect its
* contents from garbage collection. Use JS::AutoIdArray.
*/
extern JS_PUBLIC_API(bool)
JS_Enumerate(JSContext* cx, JS::HandleObject obj, JS::MutableHandle<JS::IdVector> props);
/*
* API for determining callability and constructability. [[Call]] and
* [[Construct]] are internal methods that aren't present on all objects, so it
* is useful to ask if they are there or not. The standard itself asks these
* questions routinely.
*/
namespace JS {
/**
* Return true if the given object is callable. In ES6 terms, an object is
* callable if it has a [[Call]] internal method.
*
* Implements: ES6 7.2.3 IsCallable(argument).
*
* Functions are callable. A scripted proxy or wrapper is callable if its
* target is callable. Most other objects aren't callable.
*/
extern JS_PUBLIC_API(bool)
IsCallable(JSObject* obj);
/**
* Return true if the given object is a constructor. In ES6 terms, an object is
* a constructor if it has a [[Construct]] internal method. The expression
* `new obj()` throws a TypeError if obj is not a constructor.
*
* Implements: ES6 7.2.4 IsConstructor(argument).
*
* JS functions and classes are constructors. Arrow functions and most builtin
* functions are not. A scripted proxy or wrapper is a constructor if its
* target is a constructor.
*/
extern JS_PUBLIC_API(bool)
IsConstructor(JSObject* obj);
} /* namespace JS */
/**
* Call a function, passing a this-value and arguments. This is the C++
* equivalent of `rval = Reflect.apply(fun, obj, args)`.
*
* Implements: ES6 7.3.12 Call(F, V, [argumentsList]).
* Use this function to invoke the [[Call]] internal method.
*/
extern JS_PUBLIC_API(bool)
JS_CallFunctionValue(JSContext* cx, JS::HandleObject obj, JS::HandleValue fval,
const JS::HandleValueArray& args, JS::MutableHandleValue rval);
extern JS_PUBLIC_API(bool)
JS_CallFunction(JSContext* cx, JS::HandleObject obj, JS::HandleFunction fun,
const JS::HandleValueArray& args, JS::MutableHandleValue rval);
/**
* Perform the method call `rval = obj[name](args)`.
*/
extern JS_PUBLIC_API(bool)
JS_CallFunctionName(JSContext* cx, JS::HandleObject obj, const char* name,
const JS::HandleValueArray& args, JS::MutableHandleValue rval);
namespace JS {
static inline bool
Call(JSContext* cx, JS::HandleObject thisObj, JS::HandleFunction fun,
const JS::HandleValueArray& args, MutableHandleValue rval)
{
return !!JS_CallFunction(cx, thisObj, fun, args, rval);
}
static inline bool
Call(JSContext* cx, JS::HandleObject thisObj, JS::HandleValue fun, const JS::HandleValueArray& args,
MutableHandleValue rval)
{
return !!JS_CallFunctionValue(cx, thisObj, fun, args, rval);
}
static inline bool
Call(JSContext* cx, JS::HandleObject thisObj, const char* name, const JS::HandleValueArray& args,
MutableHandleValue rval)
{
return !!JS_CallFunctionName(cx, thisObj, name, args, rval);
}
extern JS_PUBLIC_API(bool)
Call(JSContext* cx, JS::HandleValue thisv, JS::HandleValue fun, const JS::HandleValueArray& args,
MutableHandleValue rval);
static inline bool
Call(JSContext* cx, JS::HandleValue thisv, JS::HandleObject funObj, const JS::HandleValueArray& args,
MutableHandleValue rval)
{
MOZ_ASSERT(funObj);
JS::RootedValue fun(cx, JS::ObjectValue(*funObj));
return Call(cx, thisv, fun, args, rval);
}
/**
* Invoke a constructor. This is the C++ equivalent of
* `rval = Reflect.construct(fun, args, newTarget)`.
*
* JS::Construct() takes a `newTarget` argument that most callers don't need.
* Consider using the four-argument Construct signature instead. (But if you're
* implementing a subclass or a proxy handler's construct() method, this is the
* right function to call.)
*
* Implements: ES6 7.3.13 Construct(F, [argumentsList], [newTarget]).
* Use this function to invoke the [[Construct]] internal method.
*/
extern JS_PUBLIC_API(bool)
Construct(JSContext* cx, JS::HandleValue fun, HandleObject newTarget,
const JS::HandleValueArray &args, MutableHandleValue rval);
/**
* Invoke a constructor. This is the C++ equivalent of
* `rval = new fun(...args)`.
*
* The value left in rval on success is always an object in practice,
* though at the moment this is not enforced by the C++ type system.
*
* Implements: ES6 7.3.13 Construct(F, [argumentsList], [newTarget]), when
* newTarget is omitted.
*/
extern JS_PUBLIC_API(bool)
Construct(JSContext* cx, JS::HandleValue fun, const JS::HandleValueArray& args,
MutableHandleValue rval);
} /* namespace JS */
/**
* Invoke a constructor, like the JS expression `new ctor(...args)`. Returns
* the new object, or null on error.
*/
extern JS_PUBLIC_API(JSObject*)
JS_New(JSContext* cx, JS::HandleObject ctor, const JS::HandleValueArray& args);
/*** Other property-defining functions ***********************************************************/
extern JS_PUBLIC_API(JSObject*)
JS_DefineObject(JSContext* cx, JS::HandleObject obj, const char* name,
const JSClass* clasp = nullptr, unsigned attrs = 0);
extern JS_PUBLIC_API(bool)
JS_DefineConstDoubles(JSContext* cx, JS::HandleObject obj, const JSConstDoubleSpec* cds);
extern JS_PUBLIC_API(bool)
JS_DefineConstIntegers(JSContext* cx, JS::HandleObject obj, const JSConstIntegerSpec* cis);
extern JS_PUBLIC_API(bool)
JS_DefineProperties(JSContext* cx, JS::HandleObject obj, const JSPropertySpec* ps);
/* * */
extern JS_PUBLIC_API(bool)
JS_AlreadyHasOwnPropertyById(JSContext* cx, JS::HandleObject obj, JS::HandleId id,
bool* foundp);
extern JS_PUBLIC_API(bool)
JS_AlreadyHasOwnProperty(JSContext* cx, JS::HandleObject obj, const char* name,
bool* foundp);
extern JS_PUBLIC_API(bool)
JS_AlreadyHasOwnUCProperty(JSContext* cx, JS::HandleObject obj, const char16_t* name,
size_t namelen, bool* foundp);
extern JS_PUBLIC_API(bool)
JS_AlreadyHasOwnElement(JSContext* cx, JS::HandleObject obj, uint32_t index, bool* foundp);
extern JS_PUBLIC_API(JSObject*)
JS_NewArrayObject(JSContext* cx, const JS::HandleValueArray& contents);
extern JS_PUBLIC_API(JSObject*)
JS_NewArrayObject(JSContext* cx, size_t length);
/**
* Returns true and sets |*isArray| indicating whether |value| is an Array
* object or a wrapper around one, otherwise returns false on failure.
*
* This method returns true with |*isArray == false| when passed a proxy whose
* target is an Array, or when passed a revoked proxy.
*/
extern JS_PUBLIC_API(bool)
JS_IsArrayObject(JSContext* cx, JS::HandleValue value, bool* isArray);
/**
* Returns true and sets |*isArray| indicating whether |obj| is an Array object
* or a wrapper around one, otherwise returns false on failure.
*
* This method returns true with |*isArray == false| when passed a proxy whose
* target is an Array, or when passed a revoked proxy.
*/
extern JS_PUBLIC_API(bool)
JS_IsArrayObject(JSContext* cx, JS::HandleObject obj, bool* isArray);
extern JS_PUBLIC_API(bool)
JS_GetArrayLength(JSContext* cx, JS::Handle<JSObject*> obj, uint32_t* lengthp);
extern JS_PUBLIC_API(bool)
JS_SetArrayLength(JSContext* cx, JS::Handle<JSObject*> obj, uint32_t length);
/**
* Assign 'undefined' to all of the object's non-reserved slots. Note: this is
* done for all slots, regardless of the associated property descriptor.
*/
JS_PUBLIC_API(void)
JS_SetAllNonReservedSlotsToUndefined(JSContext* cx, JSObject* objArg);
/**
* Create a new array buffer with the given contents. It must be legal to pass
* these contents to free(). On success, the ownership is transferred to the
* new array buffer.
*/
extern JS_PUBLIC_API(JSObject*)
JS_NewArrayBufferWithContents(JSContext* cx, size_t nbytes, void* contents);
/**
* Steal the contents of the given array buffer. The array buffer has its
* length set to 0 and its contents array cleared. The caller takes ownership
* of the return value and must free it or transfer ownership via
* JS_NewArrayBufferWithContents when done using it.
*/
extern JS_PUBLIC_API(void*)
JS_StealArrayBufferContents(JSContext* cx, JS::HandleObject obj);
/**
* Create a new mapped array buffer with the given memory mapped contents. It
* must be legal to free the contents pointer by unmapping it. On success,
* ownership is transferred to the new mapped array buffer.
*/
extern JS_PUBLIC_API(JSObject*)
JS_NewMappedArrayBufferWithContents(JSContext* cx, size_t nbytes, void* contents);
/**
* Create memory mapped array buffer contents.
* Caller must take care of closing fd after calling this function.
*/
extern JS_PUBLIC_API(void*)
JS_CreateMappedArrayBufferContents(int fd, size_t offset, size_t length);
/**
* Release the allocated resource of mapped array buffer contents before the
* object is created.
* If a new object has been created by JS_NewMappedArrayBufferWithContents()
* with this content, then JS_NeuterArrayBuffer() should be used instead to
* release the resource used by the object.
*/
extern JS_PUBLIC_API(void)
JS_ReleaseMappedArrayBufferContents(void* contents, size_t length);
extern JS_PUBLIC_API(JS::Value)
JS_GetReservedSlot(JSObject* obj, uint32_t index);
extern JS_PUBLIC_API(void)
JS_SetReservedSlot(JSObject* obj, uint32_t index, JS::Value v);
/************************************************************************/
/*
* Functions and scripts.
*/
extern JS_PUBLIC_API(JSFunction*)
JS_NewFunction(JSContext* cx, JSNative call, unsigned nargs, unsigned flags,
const char* name);
namespace JS {
extern JS_PUBLIC_API(JSFunction*)
GetSelfHostedFunction(JSContext* cx, const char* selfHostedName, HandleId id,
unsigned nargs);
/**
* Create a new function based on the given JSFunctionSpec, *fs.
* id is the result of a successful call to
* `PropertySpecNameToPermanentId(cx, fs->name, &id)`.
*
* Unlike JS_DefineFunctions, this does not treat fs as an array.
* *fs must not be JS_FS_END.
*/
extern JS_PUBLIC_API(JSFunction*)
NewFunctionFromSpec(JSContext* cx, const JSFunctionSpec* fs, HandleId id);
} /* namespace JS */
extern JS_PUBLIC_API(JSObject*)
JS_GetFunctionObject(JSFunction* fun);
/**
* Return the function's identifier as a JSString, or null if fun is unnamed.
* The returned string lives as long as fun, so you don't need to root a saved
* reference to it if fun is well-connected or rooted, and provided you bound
* the use of the saved reference by fun's lifetime.
*/
extern JS_PUBLIC_API(JSString*)
JS_GetFunctionId(JSFunction* fun);
/**
* Return a function's display name. This is the defined name if one was given
* where the function was defined, or it could be an inferred name by the JS
* engine in the case that the function was defined to be anonymous. This can
* still return nullptr if a useful display name could not be inferred. The
* same restrictions on rooting as those in JS_GetFunctionId apply.
*/
extern JS_PUBLIC_API(JSString*)
JS_GetFunctionDisplayId(JSFunction* fun);
/*
* Return the arity (length) of fun.
*/
extern JS_PUBLIC_API(uint16_t)
JS_GetFunctionArity(JSFunction* fun);
/**
* Infallible predicate to test whether obj is a function object (faster than
* comparing obj's class name to "Function", but equivalent unless someone has
* overwritten the "Function" identifier with a different constructor and then
* created instances using that constructor that might be passed in as obj).
*/
extern JS_PUBLIC_API(bool)
JS_ObjectIsFunction(JSContext* cx, JSObject* obj);
extern JS_PUBLIC_API(bool)
JS_IsNativeFunction(JSObject* funobj, JSNative call);
/** Return whether the given function is a valid constructor. */
extern JS_PUBLIC_API(bool)
JS_IsConstructor(JSFunction* fun);
/**
* This enum is used to select if properties with JSPROP_DEFINE_LATE flag
* should be defined on the object.
* Normal JSAPI consumers probably always want DefineAllProperties here.
*/
enum PropertyDefinitionBehavior {
DefineAllProperties,
OnlyDefineLateProperties,
DontDefineLateProperties
};
extern JS_PUBLIC_API(bool)
JS_DefineFunctions(JSContext* cx, JS::Handle<JSObject*> obj, const JSFunctionSpec* fs,
PropertyDefinitionBehavior behavior = DefineAllProperties);
extern JS_PUBLIC_API(JSFunction*)
JS_DefineFunction(JSContext* cx, JS::Handle<JSObject*> obj, const char* name, JSNative call,
unsigned nargs, unsigned attrs);
extern JS_PUBLIC_API(JSFunction*)
JS_DefineUCFunction(JSContext* cx, JS::Handle<JSObject*> obj,
const char16_t* name, size_t namelen, JSNative call,
unsigned nargs, unsigned attrs);
extern JS_PUBLIC_API(JSFunction*)
JS_DefineFunctionById(JSContext* cx, JS::Handle<JSObject*> obj, JS::Handle<jsid> id, JSNative call,
unsigned nargs, unsigned attrs);
namespace JS {
/**
* Clone a top-level function into cx's global. This function will dynamically
* fail if funobj was lexically nested inside some other function.
*/
extern JS_PUBLIC_API(JSObject*)
CloneFunctionObject(JSContext* cx, HandleObject funobj);
/**
* As above, but providing an explicit scope chain. scopeChain must not include
* the global object on it; that's implicit. It needs to contain the other
* objects that should end up on the clone's scope chain.
*/
extern JS_PUBLIC_API(JSObject*)
CloneFunctionObject(JSContext* cx, HandleObject funobj, AutoObjectVector& scopeChain);
} // namespace JS
/**
* Given a buffer, return false if the buffer might become a valid
* javascript statement with the addition of more lines. Otherwise return
* true. The intent is to support interactive compilation - accumulate
* lines in a buffer until JS_BufferIsCompilableUnit is true, then pass it to
* the compiler.
*/
extern JS_PUBLIC_API(bool)
JS_BufferIsCompilableUnit(JSContext* cx, JS::Handle<JSObject*> obj, const char* utf8,
size_t length);
/**
* |script| will always be set. On failure, it will be set to nullptr.
*/
extern JS_PUBLIC_API(bool)
JS_CompileScript(JSContext* cx, const char* ascii, size_t length,
const JS::CompileOptions& options,
JS::MutableHandleScript script);
/**
* |script| will always be set. On failure, it will be set to nullptr.
*/
extern JS_PUBLIC_API(bool)
JS_CompileUCScript(JSContext* cx, const char16_t* chars, size_t length,
const JS::CompileOptions& options,
JS::MutableHandleScript script);
extern JS_PUBLIC_API(JSObject*)
JS_GetGlobalFromScript(JSScript* script);
extern JS_PUBLIC_API(const char*)
JS_GetScriptFilename(JSScript* script);
extern JS_PUBLIC_API(unsigned)
JS_GetScriptBaseLineNumber(JSContext* cx, JSScript* script);
extern JS_PUBLIC_API(JSScript*)
JS_GetFunctionScript(JSContext* cx, JS::HandleFunction fun);
namespace JS {
/* Options for JavaScript compilation. */
/*
* In the most common use case, a CompileOptions instance is allocated on the
* stack, and holds non-owning references to non-POD option values: strings;
* principals; objects; and so on. The code declaring the instance guarantees
* that such option values will outlive the CompileOptions itself: objects are
* otherwise rooted; principals have had their reference counts bumped; strings
* will not be freed until the CompileOptions goes out of scope. In this
* situation, CompileOptions only refers to things others own, so it can be
* lightweight.
*
* In some cases, however, we need to hold compilation options with a
* non-stack-like lifetime. For example, JS::CompileOffThread needs to save
* compilation options where a worker thread can find them, and then return
* immediately. The worker thread will come along at some later point, and use
* the options.
*
* The compiler itself just needs to be able to access a collection of options;
* it doesn't care who owns them, or what's keeping them alive. It does its own
* addrefs/copies/tracing/etc.
*
* Furthermore, in some cases compile options are propagated from one entity to
* another (e.g. from a scriipt to a function defined in that script). This
* involves copying over some, but not all, of the options.
*
* So, we have a class hierarchy that reflects these four use cases:
*
* - TransitiveCompileOptions is the common base class, representing options
* that should get propagated from a script to functions defined in that
* script. This is never instantiated directly.
*
* - ReadOnlyCompileOptions is the only subclass of TransitiveCompileOptions,
* representing a full set of compile options. It can be used by code that
* simply needs to access options set elsewhere, like the compiler. This,
* again, is never instantiated directly.
*
* - The usual CompileOptions class must be stack-allocated, and holds
* non-owning references to the filename, element, and so on. It's derived
* from ReadOnlyCompileOptions, so the compiler can use it.
*
* - OwningCompileOptions roots / copies / reference counts of all its values,
* and unroots / frees / releases them when it is destructed. It too is
* derived from ReadOnlyCompileOptions, so the compiler accepts it.
*/
enum class AsmJSOption : uint8_t { Enabled, Disabled, DisabledByDebugger };
/**
* The common base class for the CompileOptions hierarchy.
*
* Use this in code that needs to propagate compile options from one compilation
* unit to another.
*/
class JS_FRIEND_API(TransitiveCompileOptions)
{
protected:
// The Web Platform allows scripts to be loaded from arbitrary cross-origin
// sources. This allows an attack by which a malicious website loads a
// sensitive file (say, a bank statement) cross-origin (using the user's
// cookies), and sniffs the generated syntax errors (via a window.onerror
// handler) for juicy morsels of its contents.
//
// To counter this attack, HTML5 specifies that script errors should be
// sanitized ("muted") when the script is not same-origin with the global
// for which it is loaded. Callers should set this flag for cross-origin
// scripts, and it will be propagated appropriately to child scripts and
// passed back in JSErrorReports.
bool mutedErrors_;
const char* filename_;
const char* introducerFilename_;
const char16_t* sourceMapURL_;
// This constructor leaves 'version' set to JSVERSION_UNKNOWN. The structure
// is unusable until that's set to something more specific; the derived
// classes' constructors take care of that, in ways appropriate to their
// purpose.
TransitiveCompileOptions()
: mutedErrors_(false),
filename_(nullptr),
introducerFilename_(nullptr),
sourceMapURL_(nullptr),
version(JSVERSION_UNKNOWN),
versionSet(false),
utf8(false),
selfHostingMode(false),
canLazilyParse(true),
strictOption(false),
extraWarningsOption(false),
werrorOption(false),
asmJSOption(AsmJSOption::Disabled),
throwOnAsmJSValidationFailureOption(false),
forceAsync(false),
installedFile(false),
sourceIsLazy(false),
introductionType(nullptr),
introductionLineno(0),
introductionOffset(0),
hasIntroductionInfo(false)
{ }
// Set all POD options (those not requiring reference counts, copies,
// rooting, or other hand-holding) to their values in |rhs|.
void copyPODTransitiveOptions(const TransitiveCompileOptions& rhs);
public:
// Read-only accessors for non-POD options. The proper way to set these
// depends on the derived type.
bool mutedErrors() const { return mutedErrors_; }
const char* filename() const { return filename_; }
const char* introducerFilename() const { return introducerFilename_; }
const char16_t* sourceMapURL() const { return sourceMapURL_; }
virtual JSObject* element() const = 0;
virtual JSString* elementAttributeName() const = 0;
virtual JSScript* introductionScript() const = 0;
// POD options.
JSVersion version;
bool versionSet;
bool utf8;
bool selfHostingMode;
bool canLazilyParse;
bool strictOption;
bool extraWarningsOption;
bool werrorOption;
AsmJSOption asmJSOption;
bool throwOnAsmJSValidationFailureOption;
bool forceAsync;
bool installedFile; // 'true' iff pre-compiling js file in packaged app
bool sourceIsLazy;
// |introductionType| is a statically allocated C string:
// one of "eval", "Function", or "GeneratorFunction".
const char* introductionType;
unsigned introductionLineno;
uint32_t introductionOffset;
bool hasIntroductionInfo;
private:
void operator=(const TransitiveCompileOptions&) = delete;
};
/**
* The class representing a full set of compile options.
*
* Use this in code that only needs to access compilation options created
* elsewhere, like the compiler. Don't instantiate this class (the constructor
* is protected anyway); instead, create instances only of the derived classes:
* CompileOptions and OwningCompileOptions.
*/
class JS_FRIEND_API(ReadOnlyCompileOptions) : public TransitiveCompileOptions
{
friend class CompileOptions;
protected:
ReadOnlyCompileOptions()
: TransitiveCompileOptions(),
lineno(1),
column(0),
isRunOnce(false),
forEval(false),
noScriptRval(false)
{ }
// Set all POD options (those not requiring reference counts, copies,
// rooting, or other hand-holding) to their values in |rhs|.
void copyPODOptions(const ReadOnlyCompileOptions& rhs);
public:
// Read-only accessors for non-POD options. The proper way to set these
// depends on the derived type.
bool mutedErrors() const { return mutedErrors_; }
const char* filename() const { return filename_; }
const char* introducerFilename() const { return introducerFilename_; }
const char16_t* sourceMapURL() const { return sourceMapURL_; }
virtual JSObject* element() const = 0;
virtual JSString* elementAttributeName() const = 0;
virtual JSScript* introductionScript() const = 0;
// POD options.
unsigned lineno;
unsigned column;
// isRunOnce only applies to non-function scripts.
bool isRunOnce;
bool forEval;
bool noScriptRval;
private:
void operator=(const ReadOnlyCompileOptions&) = delete;
};
/**
* Compilation options, with dynamic lifetime. An instance of this type
* makes a copy of / holds / roots all dynamically allocated resources
* (principals; elements; strings) that it refers to. Its destructor frees
* / drops / unroots them. This is heavier than CompileOptions, below, but
* unlike CompileOptions, it can outlive any given stack frame.
*
* Note that this *roots* any JS values it refers to - they're live
* unconditionally. Thus, instances of this type can't be owned, directly
* or indirectly, by a JavaScript object: if any value that this roots ever
* comes to refer to the object that owns this, then the whole cycle, and
* anything else it entrains, will never be freed.
*/
class JS_FRIEND_API(OwningCompileOptions) : public ReadOnlyCompileOptions
{
JSRuntime* runtime;
PersistentRootedObject elementRoot;
PersistentRootedString elementAttributeNameRoot;
PersistentRootedScript introductionScriptRoot;
public:
// A minimal constructor, for use with OwningCompileOptions::copy. This
// leaves |this.version| set to JSVERSION_UNKNOWN; the instance
// shouldn't be used until we've set that to something real (as |copy|
// will).
explicit OwningCompileOptions(JSContext* cx);
~OwningCompileOptions();
JSObject* element() const override { return elementRoot; }
JSString* elementAttributeName() const override { return elementAttributeNameRoot; }
JSScript* introductionScript() const override { return introductionScriptRoot; }
// Set this to a copy of |rhs|. Return false on OOM.
bool copy(JSContext* cx, const ReadOnlyCompileOptions& rhs);
/* These setters make copies of their string arguments, and are fallible. */
bool setFile(JSContext* cx, const char* f);
bool setFileAndLine(JSContext* cx, const char* f, unsigned l);
bool setSourceMapURL(JSContext* cx, const char16_t* s);
bool setIntroducerFilename(JSContext* cx, const char* s);
/* These setters are infallible, and can be chained. */
OwningCompileOptions& setLine(unsigned l) { lineno = l; return *this; }
OwningCompileOptions& setElement(JSObject* e) {
elementRoot = e;
return *this;
}
OwningCompileOptions& setElementAttributeName(JSString* p) {
elementAttributeNameRoot = p;
return *this;
}
OwningCompileOptions& setIntroductionScript(JSScript* s) {
introductionScriptRoot = s;
return *this;
}
OwningCompileOptions& setMutedErrors(bool mute) {
mutedErrors_ = mute;
return *this;
}
OwningCompileOptions& setVersion(JSVersion v) {
version = v;
versionSet = true;
return *this;
}
OwningCompileOptions& setUTF8(bool u) { utf8 = u; return *this; }
OwningCompileOptions& setColumn(unsigned c) { column = c; return *this; }
OwningCompileOptions& setIsRunOnce(bool once) { isRunOnce = once; return *this; }
OwningCompileOptions& setForEval(bool eval) { forEval = eval; return *this; }
OwningCompileOptions& setNoScriptRval(bool nsr) { noScriptRval = nsr; return *this; }
OwningCompileOptions& setSelfHostingMode(bool shm) { selfHostingMode = shm; return *this; }
OwningCompileOptions& setCanLazilyParse(bool clp) { canLazilyParse = clp; return *this; }
OwningCompileOptions& setSourceIsLazy(bool l) { sourceIsLazy = l; return *this; }
OwningCompileOptions& setIntroductionType(const char* t) { introductionType = t; return *this; }
bool setIntroductionInfo(JSContext* cx, const char* introducerFn, const char* intro,
unsigned line, JSScript* script, uint32_t offset)
{
if (!setIntroducerFilename(cx, introducerFn))
return false;
introductionType = intro;
introductionLineno = line;
introductionScriptRoot = script;
introductionOffset = offset;
hasIntroductionInfo = true;
return true;
}
private:
void operator=(const CompileOptions& rhs) = delete;
};
/**
* Compilation options stored on the stack. An instance of this type
* simply holds references to dynamically allocated resources (element;
* filename; source map URL) that are owned by something else. If you
* create an instance of this type, it's up to you to guarantee that
* everything you store in it will outlive it.
*/
class MOZ_STACK_CLASS JS_FRIEND_API(CompileOptions) : public ReadOnlyCompileOptions
{
RootedObject elementRoot;
RootedString elementAttributeNameRoot;
RootedScript introductionScriptRoot;
public:
explicit CompileOptions(JSContext* cx, JSVersion version = JSVERSION_UNKNOWN);
CompileOptions(js::ContextFriendFields* cx, const ReadOnlyCompileOptions& rhs)
: ReadOnlyCompileOptions(), elementRoot(cx), elementAttributeNameRoot(cx),
introductionScriptRoot(cx)
{
copyPODOptions(rhs);
filename_ = rhs.filename();
introducerFilename_ = rhs.introducerFilename();
sourceMapURL_ = rhs.sourceMapURL();
elementRoot = rhs.element();
elementAttributeNameRoot = rhs.elementAttributeName();
introductionScriptRoot = rhs.introductionScript();
}
CompileOptions(js::ContextFriendFields* cx, const TransitiveCompileOptions& rhs)
: ReadOnlyCompileOptions(), elementRoot(cx), elementAttributeNameRoot(cx),
introductionScriptRoot(cx)
{
copyPODTransitiveOptions(rhs);
filename_ = rhs.filename();
introducerFilename_ = rhs.introducerFilename();
sourceMapURL_ = rhs.sourceMapURL();
elementRoot = rhs.element();
elementAttributeNameRoot = rhs.elementAttributeName();
introductionScriptRoot = rhs.introductionScript();
}
JSObject* element() const override { return elementRoot; }
JSString* elementAttributeName() const override { return elementAttributeNameRoot; }
JSScript* introductionScript() const override { return introductionScriptRoot; }
CompileOptions& setFile(const char* f) { filename_ = f; return *this; }
CompileOptions& setLine(unsigned l) { lineno = l; return *this; }
CompileOptions& setFileAndLine(const char* f, unsigned l) {
filename_ = f; lineno = l; return *this;
}
CompileOptions& setSourceMapURL(const char16_t* s) { sourceMapURL_ = s; return *this; }
CompileOptions& setElement(JSObject* e) { elementRoot = e; return *this; }
CompileOptions& setElementAttributeName(JSString* p) {
elementAttributeNameRoot = p;
return *this;
}
CompileOptions& setIntroductionScript(JSScript* s) {
introductionScriptRoot = s;
return *this;
}
CompileOptions& setMutedErrors(bool mute) {
mutedErrors_ = mute;
return *this;
}
CompileOptions& setVersion(JSVersion v) {
version = v;
versionSet = true;
return *this;
}
CompileOptions& setUTF8(bool u) { utf8 = u; return *this; }
CompileOptions& setColumn(unsigned c) { column = c; return *this; }
CompileOptions& setIsRunOnce(bool once) { isRunOnce = once; return *this; }
CompileOptions& setForEval(bool eval) { forEval = eval; return *this; }
CompileOptions& setNoScriptRval(bool nsr) { noScriptRval = nsr; return *this; }
CompileOptions& setSelfHostingMode(bool shm) { selfHostingMode = shm; return *this; }
CompileOptions& setCanLazilyParse(bool clp) { canLazilyParse = clp; return *this; }
CompileOptions& setSourceIsLazy(bool l) { sourceIsLazy = l; return *this; }
CompileOptions& setIntroductionType(const char* t) { introductionType = t; return *this; }
CompileOptions& setIntroductionInfo(const char* introducerFn, const char* intro,
unsigned line, JSScript* script, uint32_t offset)
{
introducerFilename_ = introducerFn;
introductionType = intro;
introductionLineno = line;
introductionScriptRoot = script;
introductionOffset = offset;
hasIntroductionInfo = true;
return *this;
}
CompileOptions& maybeMakeStrictMode(bool strict) {
strictOption = strictOption || strict;
return *this;
}
private:
void operator=(const CompileOptions& rhs) = delete;
};
/**
* |script| will always be set. On failure, it will be set to nullptr.
*/
extern JS_PUBLIC_API(bool)
Compile(JSContext* cx, const ReadOnlyCompileOptions& options,
SourceBufferHolder& srcBuf, JS::MutableHandleScript script);
extern JS_PUBLIC_API(bool)
Compile(JSContext* cx, const ReadOnlyCompileOptions& options,
const char* bytes, size_t length, JS::MutableHandleScript script);
extern JS_PUBLIC_API(bool)
Compile(JSContext* cx, const ReadOnlyCompileOptions& options,
const char16_t* chars, size_t length, JS::MutableHandleScript script);
#if defined(STARBOARD)
extern JS_PUBLIC_API(bool)
Compile(JSContext* cx, const ReadOnlyCompileOptions& options,
SbFile file, JS::MutableHandleScript script);
#else
extern JS_PUBLIC_API(bool)
Compile(JSContext* cx, const ReadOnlyCompileOptions& options,
FILE* file, JS::MutableHandleScript script);
#endif
extern JS_PUBLIC_API(bool)
Compile(JSContext* cx, const ReadOnlyCompileOptions& options,
const char* filename, JS::MutableHandleScript script);
extern JS_PUBLIC_API(bool)
CompileForNonSyntacticScope(JSContext* cx, const ReadOnlyCompileOptions& options,
SourceBufferHolder& srcBuf, JS::MutableHandleScript script);
extern JS_PUBLIC_API(bool)
CompileForNonSyntacticScope(JSContext* cx, const ReadOnlyCompileOptions& options,
const char* bytes, size_t length, JS::MutableHandleScript script);
extern JS_PUBLIC_API(bool)
CompileForNonSyntacticScope(JSContext* cx, const ReadOnlyCompileOptions& options,
const char16_t* chars, size_t length, JS::MutableHandleScript script);
#if defined(STARBOARD)
extern JS_PUBLIC_API(bool)
CompileForNonSyntacticScope(JSContext* cx, const ReadOnlyCompileOptions& options,
SbFile file, JS::MutableHandleScript script);
#else
extern JS_PUBLIC_API(bool)
CompileForNonSyntacticScope(JSContext* cx, const ReadOnlyCompileOptions& options,
FILE* file, JS::MutableHandleScript script);
#endif
extern JS_PUBLIC_API(bool)
CompileForNonSyntacticScope(JSContext* cx, const ReadOnlyCompileOptions& options,
const char* filename, JS::MutableHandleScript script);
extern JS_PUBLIC_API(bool)
CanCompileOffThread(JSContext* cx, const ReadOnlyCompileOptions& options, size_t length);
/*
* Off thread compilation control flow.
*
* After successfully triggering an off thread compile of a script, the
* callback will eventually be invoked with the specified data and a token
* for the compilation. The callback will be invoked while off the main thread,
* so must ensure that its operations are thread safe. Afterwards,
* FinishOffThreadScript must be invoked on the main thread to get the result
* script or nullptr. If maybecx is not specified, the resources will be freed,
* but no script will be returned.
*
* The characters passed in to CompileOffThread must remain live until the
* callback is invoked, and the resulting script will be rooted until the call
* to FinishOffThreadScript.
*/
extern JS_PUBLIC_API(bool)
CompileOffThread(JSContext* cx, const ReadOnlyCompileOptions& options,
const char16_t* chars, size_t length,
OffThreadCompileCallback callback, void* callbackData);
extern JS_PUBLIC_API(JSScript*)
FinishOffThreadScript(JSContext* maybecx, JSRuntime* rt, void* token);
/**
* Compile a function with scopeChain plus the global as its scope chain.
* scopeChain must contain objects in the current compartment of cx. The actual
* scope chain used for the function will consist of With wrappers for those
* objects, followed by the current global of the compartment cx is in. This
* global must not be explicitly included in the scope chain.
*/
extern JS_PUBLIC_API(bool)
CompileFunction(JSContext* cx, AutoObjectVector& scopeChain,
const ReadOnlyCompileOptions& options,
const char* name, unsigned nargs, const char* const* argnames,
const char16_t* chars, size_t length, JS::MutableHandleFunction fun);
/**
* Same as above, but taking a SourceBufferHolder for the function body.
*/
extern JS_PUBLIC_API(bool)
CompileFunction(JSContext* cx, AutoObjectVector& scopeChain,
const ReadOnlyCompileOptions& options,
const char* name, unsigned nargs, const char* const* argnames,
SourceBufferHolder& srcBuf, JS::MutableHandleFunction fun);
/**
* Same as above, but taking a const char * for the function body.
*/
extern JS_PUBLIC_API(bool)
CompileFunction(JSContext* cx, AutoObjectVector& scopeChain,
const ReadOnlyCompileOptions& options,
const char* name, unsigned nargs, const char* const* argnames,
const char* bytes, size_t length, JS::MutableHandleFunction fun);
} /* namespace JS */
extern JS_PUBLIC_API(JSString*)
JS_DecompileScript(JSContext* cx, JS::Handle<JSScript*> script, const char* name, unsigned indent);
/*
* API extension: OR this into indent to avoid pretty-printing the decompiled
* source resulting from JS_DecompileFunction.
*/
#define JS_DONT_PRETTY_PRINT ((unsigned)0x8000)
extern JS_PUBLIC_API(JSString*)
JS_DecompileFunction(JSContext* cx, JS::Handle<JSFunction*> fun, unsigned indent);
/*
* NB: JS_ExecuteScript and the JS::Evaluate APIs come in two flavors: either
* they use the global as the scope, or they take an AutoObjectVector of objects
* to use as the scope chain. In the former case, the global is also used as
* the "this" keyword value and the variables object (ECMA parlance for where
* 'var' and 'function' bind names) of the execution context for script. In the
* latter case, the first object in the provided list is used, unless the list
* is empty, in which case the global is used.
*
* Why a runtime option? The alternative is to add APIs duplicating those
* for the other value of flags, and that doesn't seem worth the code bloat
* cost. Such new entry points would probably have less obvious names, too, so
* would not tend to be used. The RuntimeOptionsRef adjustment, OTOH, can be
* more easily hacked into existing code that does not depend on the bug; such
* code can continue to use the familiar JS::Evaluate, etc., entry points.
*/
/**
* Evaluate a script in the scope of the current global of cx.
*/
extern JS_PUBLIC_API(bool)
JS_ExecuteScript(JSContext* cx, JS::HandleScript script, JS::MutableHandleValue rval);
extern JS_PUBLIC_API(bool)
JS_ExecuteScript(JSContext* cx, JS::HandleScript script);
/**
* As above, but providing an explicit scope chain. scopeChain must not include
* the global object on it; that's implicit. It needs to contain the other
* objects that should end up on the script's scope chain.
*/
extern JS_PUBLIC_API(bool)
JS_ExecuteScript(JSContext* cx, JS::AutoObjectVector& scopeChain,
JS::HandleScript script, JS::MutableHandleValue rval);
extern JS_PUBLIC_API(bool)
JS_ExecuteScript(JSContext* cx, JS::AutoObjectVector& scopeChain, JS::HandleScript script);
namespace JS {
/**
* Like the above, but handles a cross-compartment script. If the script is
* cross-compartment, it is cloned into the current compartment before executing.
*/
extern JS_PUBLIC_API(bool)
CloneAndExecuteScript(JSContext* cx, JS::Handle<JSScript*> script);
} /* namespace JS */
namespace JS {
/**
* Evaluate the given source buffer in the scope of the current global of cx.
*/
extern JS_PUBLIC_API(bool)
Evaluate(JSContext* cx, const ReadOnlyCompileOptions& options,
SourceBufferHolder& srcBuf, JS::MutableHandleValue rval);
/**
* As above, but providing an explicit scope chain. scopeChain must not include
* the global object on it; that's implicit. It needs to contain the other
* objects that should end up on the script's scope chain.
*/
extern JS_PUBLIC_API(bool)
Evaluate(JSContext* cx, AutoObjectVector& scopeChain, const ReadOnlyCompileOptions& options,
SourceBufferHolder& srcBuf, JS::MutableHandleValue rval);
/**
* Evaluate the given character buffer in the scope of the current global of cx.
*/
extern JS_PUBLIC_API(bool)
Evaluate(JSContext* cx, const ReadOnlyCompileOptions& options,
const char16_t* chars, size_t length, JS::MutableHandleValue rval);
/**
* As above, but providing an explicit scope chain. scopeChain must not include
* the global object on it; that's implicit. It needs to contain the other
* objects that should end up on the script's scope chain.
*/
extern JS_PUBLIC_API(bool)
Evaluate(JSContext* cx, AutoObjectVector& scopeChain, const ReadOnlyCompileOptions& options,
const char16_t* chars, size_t length, JS::MutableHandleValue rval);
/**
* Evaluate the given byte buffer in the scope of the current global of cx.
*/
extern JS_PUBLIC_API(bool)
Evaluate(JSContext* cx, const ReadOnlyCompileOptions& options,
const char* bytes, size_t length, JS::MutableHandleValue rval);
/**
* Evaluate the given file in the scope of the current global of cx.
*/
extern JS_PUBLIC_API(bool)
Evaluate(JSContext* cx, const ReadOnlyCompileOptions& options,
const char* filename, JS::MutableHandleValue rval);
} /* namespace JS */
extern JS_PUBLIC_API(bool)
JS_CheckForInterrupt(JSContext* cx);
/*
* These functions allow setting an interrupt callback that will be called
* from the JS thread some time after any thread triggered the callback using
* JS_RequestInterruptCallback(rt).
*
* To schedule the GC and for other activities the engine internally triggers
* interrupt callbacks. The embedding should thus not rely on callbacks being
* triggered through the external API only.
*
* Important note: Additional callbacks can occur inside the callback handler
* if it re-enters the JS engine. The embedding must ensure that the callback
* is disconnected before attempting such re-entry.
*/
extern JS_PUBLIC_API(JSInterruptCallback)
JS_SetInterruptCallback(JSRuntime* rt, JSInterruptCallback callback);
extern JS_PUBLIC_API(JSInterruptCallback)
JS_GetInterruptCallback(JSRuntime* rt);
extern JS_PUBLIC_API(void)
JS_RequestInterruptCallback(JSRuntime* rt);
extern JS_PUBLIC_API(bool)
JS_IsRunning(JSContext* cx);
/*
* Saving and restoring frame chains.
*
* These two functions are used to set aside cx's call stack while that stack
* is inactive. After a call to JS_SaveFrameChain, it looks as if there is no
* code running on cx. Before calling JS_RestoreFrameChain, cx's call stack
* must be balanced and all nested calls to JS_SaveFrameChain must have had
* matching JS_RestoreFrameChain calls.
*
* JS_SaveFrameChain deals with cx not having any code running on it.
*/
extern JS_PUBLIC_API(bool)
JS_SaveFrameChain(JSContext* cx);
extern JS_PUBLIC_API(void)
JS_RestoreFrameChain(JSContext* cx);
namespace JS {
/**
* This class can be used to store a pointer to the youngest frame of a saved
* stack in the specified JSContext. This reference will be picked up by any new
* calls performed until the class is destroyed, with the specified asyncCause,
* that must not be empty.
*
* Any stack capture initiated during these new calls will go through the async
* stack instead of the current stack.
*
* Capturing the stack before a new call is performed will not be affected.
*
* The provided chain of SavedFrame objects can live in any compartment,
* although it will be copied to the compartment where the stack is captured.
*
* See also `js/src/doc/SavedFrame/SavedFrame.md` for documentation on async
* stack frames.
*/
class MOZ_STACK_CLASS JS_PUBLIC_API(AutoSetAsyncStackForNewCalls)
{
JSContext* cx;
RootedObject oldAsyncStack;
RootedString oldAsyncCause;
bool oldAsyncCallIsExplicit;
public:
enum class AsyncCallKind {
// The ordinary kind of call, where we may apply an async
// parent if there is no ordinary parent.
IMPLICIT,
// An explicit async parent, e.g., callFunctionWithAsyncStack,
// where we always want to override any ordinary parent.
EXPLICIT
};
// The stack parameter cannot be null by design, because it would be
// ambiguous whether that would clear any scheduled async stack and make the
// normal stack reappear in the new call, or just keep the async stack
// already scheduled for the new call, if any.
AutoSetAsyncStackForNewCalls(JSContext* cx, HandleObject stack,
HandleString asyncCause,
AsyncCallKind kind = AsyncCallKind::IMPLICIT);
~AutoSetAsyncStackForNewCalls();
};
} // namespace JS
/************************************************************************/
/*
* Strings.
*
* NB: JS_NewUCString takes ownership of bytes on success, avoiding a copy;
* but on error (signified by null return), it leaves chars owned by the
* caller. So the caller must free bytes in the error case, if it has no use
* for them. In contrast, all the JS_New*StringCopy* functions do not take
* ownership of the character memory passed to them -- they copy it.
*/
extern JS_PUBLIC_API(JSString*)
JS_NewStringCopyN(JSContext* cx, const char* s, size_t n);
extern JS_PUBLIC_API(JSString*)
JS_NewStringCopyZ(JSContext* cx, const char* s);
extern JS_PUBLIC_API(JSString*)
JS_AtomizeAndPinJSString(JSContext* cx, JS::HandleString str);
extern JS_PUBLIC_API(JSString*)
JS_AtomizeAndPinStringN(JSContext* cx, const char* s, size_t length);
extern JS_PUBLIC_API(JSString*)
JS_AtomizeAndPinString(JSContext* cx, const char* s);
extern JS_PUBLIC_API(JSString*)
JS_NewUCString(JSContext* cx, char16_t* chars, size_t length);
extern JS_PUBLIC_API(JSString*)
JS_NewUCStringCopyN(JSContext* cx, const char16_t* s, size_t n);
extern JS_PUBLIC_API(JSString*)
JS_NewUCStringCopyZ(JSContext* cx, const char16_t* s);
extern JS_PUBLIC_API(JSString*)
JS_AtomizeAndPinUCStringN(JSContext* cx, const char16_t* s, size_t length);
extern JS_PUBLIC_API(JSString*)
JS_AtomizeAndPinUCString(JSContext* cx, const char16_t* s);
extern JS_PUBLIC_API(bool)
JS_CompareStrings(JSContext* cx, JSString* str1, JSString* str2, int32_t* result);
extern JS_PUBLIC_API(bool)
JS_StringEqualsAscii(JSContext* cx, JSString* str, const char* asciiBytes, bool* match);
extern JS_PUBLIC_API(size_t)
JS_PutEscapedString(JSContext* cx, char* buffer, size_t size, JSString* str, char quote);
extern JS_PUBLIC_API(bool)
JS_FileEscapedString(FILE* fp, JSString* str, char quote);
/*
* Extracting string characters and length.
*
* While getting the length of a string is infallible, getting the chars can
* fail. As indicated by the lack of a JSContext parameter, there are two
* special cases where getting the chars is infallible:
*
* The first case is for strings that have been atomized, e.g. directly by
* JS_AtomizeAndPinString or implicitly because it is stored in a jsid.
*
* The second case is "flat" strings that have been explicitly prepared in a
* fallible context by JS_FlattenString. To catch errors, a separate opaque
* JSFlatString type is returned by JS_FlattenString and expected by
* JS_GetFlatStringChars. Note, though, that this is purely a syntactic
* distinction: the input and output of JS_FlattenString are the same actual
* GC-thing. If a JSString is known to be flat, JS_ASSERT_STRING_IS_FLAT can be
* used to make a debug-checked cast. Example:
*
* // in a fallible context
* JSFlatString* fstr = JS_FlattenString(cx, str);
* if (!fstr)
* return false;
* MOZ_ASSERT(fstr == JS_ASSERT_STRING_IS_FLAT(str));
*
* // in an infallible context, for the same 'str'
* AutoCheckCannotGC nogc;
* const char16_t* chars = JS_GetTwoByteFlatStringChars(nogc, fstr)
* MOZ_ASSERT(chars);
*
* Flat strings and interned strings are always null-terminated, so
* JS_FlattenString can be used to get a null-terminated string.
*
* Additionally, string characters are stored as either Latin1Char (8-bit)
* or char16_t (16-bit). Clients can use JS_StringHasLatin1Chars and can then
* call either the Latin1* or TwoByte* functions. Some functions like
* JS_CopyStringChars and JS_GetStringCharAt accept both Latin1 and TwoByte
* strings.
*/
extern JS_PUBLIC_API(size_t)
JS_GetStringLength(JSString* str);
extern JS_PUBLIC_API(bool)
JS_StringIsFlat(JSString* str);
/** Returns true iff the string's characters are stored as Latin1. */
extern JS_PUBLIC_API(bool)
JS_StringHasLatin1Chars(JSString* str);
extern JS_PUBLIC_API(const JS::Latin1Char*)
JS_GetLatin1StringCharsAndLength(JSContext* cx, const JS::AutoCheckCannotGC& nogc, JSString* str,
size_t* length);
extern JS_PUBLIC_API(const char16_t*)
JS_GetTwoByteStringCharsAndLength(JSContext* cx, const JS::AutoCheckCannotGC& nogc, JSString* str,
size_t* length);
extern JS_PUBLIC_API(bool)
JS_GetStringCharAt(JSContext* cx, JSString* str, size_t index, char16_t* res);
extern JS_PUBLIC_API(char16_t)
JS_GetFlatStringCharAt(JSFlatString* str, size_t index);
extern JS_PUBLIC_API(const char16_t*)
JS_GetTwoByteExternalStringChars(JSString* str);
extern JS_PUBLIC_API(bool)
JS_CopyStringChars(JSContext* cx, mozilla::Range<char16_t> dest, JSString* str);
extern JS_PUBLIC_API(JSFlatString*)
JS_FlattenString(JSContext* cx, JSString* str);
extern JS_PUBLIC_API(const JS::Latin1Char*)
JS_GetLatin1FlatStringChars(const JS::AutoCheckCannotGC& nogc, JSFlatString* str);
extern JS_PUBLIC_API(const char16_t*)
JS_GetTwoByteFlatStringChars(const JS::AutoCheckCannotGC& nogc, JSFlatString* str);
static MOZ_ALWAYS_INLINE JSFlatString*
JSID_TO_FLAT_STRING(jsid id)
{
MOZ_ASSERT(JSID_IS_STRING(id));
return (JSFlatString*)(JSID_BITS(id));
}
static MOZ_ALWAYS_INLINE JSFlatString*
JS_ASSERT_STRING_IS_FLAT(JSString* str)
{
MOZ_ASSERT(JS_StringIsFlat(str));
return (JSFlatString*)str;
}
static MOZ_ALWAYS_INLINE JSString*
JS_FORGET_STRING_FLATNESS(JSFlatString* fstr)
{
return (JSString*)fstr;
}
/*
* Additional APIs that avoid fallibility when given a flat string.
*/
extern JS_PUBLIC_API(bool)
JS_FlatStringEqualsAscii(JSFlatString* str, const char* asciiBytes);
extern JS_PUBLIC_API(size_t)
JS_PutEscapedFlatString(char* buffer, size_t size, JSFlatString* str, char quote);
/**
* Create a dependent string, i.e., a string that owns no character storage,
* but that refers to a slice of another string's chars. Dependent strings
* are mutable by definition, so the thread safety comments above apply.
*/
extern JS_PUBLIC_API(JSString*)
JS_NewDependentString(JSContext* cx, JS::HandleString str, size_t start,
size_t length);
/**
* Concatenate two strings, possibly resulting in a rope.
* See above for thread safety comments.
*/
extern JS_PUBLIC_API(JSString*)
JS_ConcatStrings(JSContext* cx, JS::HandleString left, JS::HandleString right);
/**
* For JS_DecodeBytes, set *dstlenp to the size of the destination buffer before
* the call; on return, *dstlenp contains the number of characters actually
* stored. To determine the necessary destination buffer size, make a sizing
* call that passes nullptr for dst.
*
* On errors, the functions report the error. In that case, *dstlenp contains
* the number of characters or bytes transferred so far. If cx is nullptr, no
* error is reported on failure, and the functions simply return false.
*
* NB: This function does not store an additional zero byte or char16_t after the
* transcoded string.
*/
JS_PUBLIC_API(bool)
JS_DecodeBytes(JSContext* cx, const char* src, size_t srclen, char16_t* dst,
size_t* dstlenp);
/**
* A variation on JS_EncodeCharacters where a null terminated string is
* returned that you are expected to call JS_free on when done.
*/
JS_PUBLIC_API(char*)
JS_EncodeString(JSContext* cx, JSString* str);
/**
* Same behavior as JS_EncodeString(), but encode into UTF-8 string
*/
JS_PUBLIC_API(char*)
JS_EncodeStringToUTF8(JSContext* cx, JS::HandleString str);
/**
* Get number of bytes in the string encoding (without accounting for a
* terminating zero bytes. The function returns (size_t) -1 if the string
* can not be encoded into bytes and reports an error using cx accordingly.
*/
JS_PUBLIC_API(size_t)
JS_GetStringEncodingLength(JSContext* cx, JSString* str);
/**
* Encode string into a buffer. The function does not stores an additional
* zero byte. The function returns (size_t) -1 if the string can not be
* encoded into bytes with no error reported. Otherwise it returns the number
* of bytes that are necessary to encode the string. If that exceeds the
* length parameter, the string will be cut and only length bytes will be
* written into the buffer.
*/
JS_PUBLIC_API(size_t)
JS_EncodeStringToBuffer(JSContext* cx, JSString* str, char* buffer, size_t length);
class MOZ_RAII JSAutoByteString
{
public:
JSAutoByteString(JSContext* cx, JSString* str
MOZ_GUARD_OBJECT_NOTIFIER_PARAM)
: mBytes(JS_EncodeString(cx, str))
{
MOZ_ASSERT(cx);
MOZ_GUARD_OBJECT_NOTIFIER_INIT;
}
explicit JSAutoByteString(MOZ_GUARD_OBJECT_NOTIFIER_ONLY_PARAM)
: mBytes(nullptr)
{
MOZ_GUARD_OBJECT_NOTIFIER_INIT;
}
~JSAutoByteString() {
js_free(mBytes);
}
/* Take ownership of the given byte array. */
void initBytes(char* bytes) {
MOZ_ASSERT(!mBytes);
mBytes = bytes;
}
char* encodeLatin1(JSContext* cx, JSString* str) {
MOZ_ASSERT(!mBytes);
MOZ_ASSERT(cx);
mBytes = JS_EncodeString(cx, str);
return mBytes;
}
char* encodeLatin1(js::ExclusiveContext* cx, JSString* str);
char* encodeUtf8(JSContext* cx, JS::HandleString str) {
MOZ_ASSERT(!mBytes);
MOZ_ASSERT(cx);
mBytes = JS_EncodeStringToUTF8(cx, str);
return mBytes;
}
void clear() {
js_free(mBytes);
mBytes = nullptr;
}
char* ptr() const {
return mBytes;
}
bool operator!() const {
return !mBytes;
}
size_t length() const {
if (!mBytes)
return 0;
return strlen(mBytes);
}
private:
char* mBytes;
MOZ_DECL_USE_GUARD_OBJECT_NOTIFIER
/* Copy and assignment are not supported. */
JSAutoByteString(const JSAutoByteString& another);
JSAutoByteString& operator=(const JSAutoByteString& another);
};
namespace JS {
extern JS_PUBLIC_API(JSAddonId*)
NewAddonId(JSContext* cx, JS::HandleString str);
extern JS_PUBLIC_API(JSString*)
StringOfAddonId(JSAddonId* id);
extern JS_PUBLIC_API(JSAddonId*)
AddonIdOfObject(JSObject* obj);
} // namespace JS
/************************************************************************/
/*
* Symbols
*/
namespace JS {
/**
* Create a new Symbol with the given description. This function never returns
* a Symbol that is in the Runtime-wide symbol registry.
*
* If description is null, the new Symbol's [[Description]] attribute is
* undefined.
*/
JS_PUBLIC_API(Symbol*)
NewSymbol(JSContext* cx, HandleString description);
/**
* Symbol.for as specified in ES6.
*
* Get a Symbol with the description 'key' from the Runtime-wide symbol registry.
* If there is not already a Symbol with that description in the registry, a new
* Symbol is created and registered. 'key' must not be null.
*/
JS_PUBLIC_API(Symbol*)
GetSymbolFor(JSContext* cx, HandleString key);
/**
* Get the [[Description]] attribute of the given symbol.
*
* This function is infallible. If it returns null, that means the symbol's
* [[Description]] is undefined.
*/
JS_PUBLIC_API(JSString*)
GetSymbolDescription(HandleSymbol symbol);
/* Well-known symbols. */
enum class SymbolCode : uint32_t {
iterator, // well-known symbols
match,
species,
toPrimitive,
InSymbolRegistry = 0xfffffffe, // created by Symbol.for() or JS::GetSymbolFor()
UniqueSymbol = 0xffffffff // created by Symbol() or JS::NewSymbol()
};
/* For use in loops that iterate over the well-known symbols. */
const size_t WellKnownSymbolLimit = 4;
/**
* Return the SymbolCode telling what sort of symbol `symbol` is.
*
* A symbol's SymbolCode never changes once it is created.
*/
JS_PUBLIC_API(SymbolCode)
GetSymbolCode(Handle<Symbol*> symbol);
/**
* Get one of the well-known symbols defined by ES6. A single set of well-known
* symbols is shared by all compartments in a JSRuntime.
*
* `which` must be in the range [0, WellKnownSymbolLimit).
*/
JS_PUBLIC_API(Symbol*)
GetWellKnownSymbol(JSContext* cx, SymbolCode which);
/**
* Return true if the given JSPropertySpec::name or JSFunctionSpec::name value
* is actually a symbol code and not a string. See JS_SYM_FN.
*/
inline bool
PropertySpecNameIsSymbol(const char* name)
{
uintptr_t u = reinterpret_cast<uintptr_t>(name);
return u != 0 && u - 1 < WellKnownSymbolLimit;
}
JS_PUBLIC_API(bool)
PropertySpecNameEqualsId(const char* name, HandleId id);
/**
* Create a jsid that does not need to be marked for GC.
*
* 'name' is a JSPropertySpec::name or JSFunctionSpec::name value. The
* resulting jsid, on success, is either an interned string or a well-known
* symbol; either way it is immune to GC so there is no need to visit *idp
* during GC marking.
*/
JS_PUBLIC_API(bool)
PropertySpecNameToPermanentId(JSContext* cx, const char* name, jsid* idp);
} /* namespace JS */
/************************************************************************/
/*
* JSON functions
*/
typedef bool (* JSONWriteCallback)(const char16_t* buf, uint32_t len, void* data);
/**
* JSON.stringify as specified by ES5.
*/
JS_PUBLIC_API(bool)
JS_Stringify(JSContext* cx, JS::MutableHandleValue value, JS::HandleObject replacer,
JS::HandleValue space, JSONWriteCallback callback, void* data);
/**
* JSON.parse as specified by ES5.
*/
JS_PUBLIC_API(bool)
JS_ParseJSON(JSContext* cx, const char16_t* chars, uint32_t len, JS::MutableHandleValue vp);
JS_PUBLIC_API(bool)
JS_ParseJSON(JSContext* cx, JS::HandleString str, JS::MutableHandleValue vp);
JS_PUBLIC_API(bool)
JS_ParseJSONWithReviver(JSContext* cx, const char16_t* chars, uint32_t len, JS::HandleValue reviver,
JS::MutableHandleValue vp);
JS_PUBLIC_API(bool)
JS_ParseJSONWithReviver(JSContext* cx, JS::HandleString str, JS::HandleValue reviver,
JS::MutableHandleValue vp);
/************************************************************************/
/**
* The default locale for the ECMAScript Internationalization API
* (Intl.Collator, Intl.NumberFormat, Intl.DateTimeFormat).
* Note that the Internationalization API encourages clients to
* specify their own locales.
* The locale string remains owned by the caller.
*/
extern JS_PUBLIC_API(bool)
JS_SetDefaultLocale(JSRuntime* rt, const char* locale);
/**
* Reset the default locale to OS defaults.
*/
extern JS_PUBLIC_API(void)
JS_ResetDefaultLocale(JSRuntime* rt);
/**
* Locale specific string conversion and error message callbacks.
*/
struct JSLocaleCallbacks {
JSLocaleToUpperCase localeToUpperCase;
JSLocaleToLowerCase localeToLowerCase;
JSLocaleCompare localeCompare; // not used #if EXPOSE_INTL_API
JSLocaleToUnicode localeToUnicode;
};
/**
* Establish locale callbacks. The pointer must persist as long as the
* JSRuntime. Passing nullptr restores the default behaviour.
*/
extern JS_PUBLIC_API(void)
JS_SetLocaleCallbacks(JSRuntime* rt, const JSLocaleCallbacks* callbacks);
/**
* Return the address of the current locale callbacks struct, which may
* be nullptr.
*/
extern JS_PUBLIC_API(const JSLocaleCallbacks*)
JS_GetLocaleCallbacks(JSRuntime* rt);
/************************************************************************/
/*
* Error reporting.
*/
namespace JS {
const uint16_t MaxNumErrorArguments = 10;
};
/**
* Report an exception represented by the sprintf-like conversion of format
* and its arguments. This exception message string is passed to a pre-set
* JSErrorReporter function (set by JS_SetErrorReporter).
*/
extern JS_PUBLIC_API(void)
JS_ReportError(JSContext* cx, const char* format, ...);
/*
* Use an errorNumber to retrieve the format string, args are char*
*/
extern JS_PUBLIC_API(void)
JS_ReportErrorNumber(JSContext* cx, JSErrorCallback errorCallback,
void* userRef, const unsigned errorNumber, ...);
#ifdef va_start
extern JS_PUBLIC_API(void)
JS_ReportErrorNumberVA(JSContext* cx, JSErrorCallback errorCallback,
void* userRef, const unsigned errorNumber, va_list ap);
#endif
/*
* Use an errorNumber to retrieve the format string, args are char16_t*
*/
extern JS_PUBLIC_API(void)
JS_ReportErrorNumberUC(JSContext* cx, JSErrorCallback errorCallback,
void* userRef, const unsigned errorNumber, ...);
extern JS_PUBLIC_API(void)
JS_ReportErrorNumberUCArray(JSContext* cx, JSErrorCallback errorCallback,
void* userRef, const unsigned errorNumber,
const char16_t** args);
/**
* As above, but report a warning instead (JSREPORT_IS_WARNING(report.flags)).
* Return true if there was no error trying to issue the warning, and if the
* warning was not converted into an error due to the JSOPTION_WERROR option
* being set, false otherwise.
*/
extern JS_PUBLIC_API(bool)
JS_ReportWarning(JSContext* cx, const char* format, ...);
extern JS_PUBLIC_API(bool)
JS_ReportErrorFlagsAndNumber(JSContext* cx, unsigned flags,
JSErrorCallback errorCallback, void* userRef,
const unsigned errorNumber, ...);
extern JS_PUBLIC_API(bool)
JS_ReportErrorFlagsAndNumberUC(JSContext* cx, unsigned flags,
JSErrorCallback errorCallback, void* userRef,
const unsigned errorNumber, ...);
/**
* Complain when out of memory.
*/
extern JS_PUBLIC_API(void)
JS_ReportOutOfMemory(JSContext* cx);
/**
* Complain when an allocation size overflows the maximum supported limit.
*/
extern JS_PUBLIC_API(void)
JS_ReportAllocationOverflow(JSContext* cx);
class JSErrorReport
{
// Offending source line without final '\n'.
const char16_t* linebuf_;
// Number of chars in linebuf_. Does not include trailing '\0'.
size_t linebufLength_;
// The 0-based offset of error token in linebuf_.
size_t tokenOffset_;
public:
JSErrorReport()
: linebuf_(nullptr), linebufLength_(0), tokenOffset_(0),
filename(nullptr), lineno(0), column(0), isMuted(false),
flags(0), errorNumber(0), ucmessage(nullptr),
messageArgs(nullptr), exnType(0)
{}
const char* filename; /* source file name, URL, etc., or null */
unsigned lineno; /* source line number */
unsigned column; /* zero-based column index in line */
bool isMuted; /* See the comment in ReadOnlyCompileOptions. */
unsigned flags; /* error/warning, etc. */
unsigned errorNumber; /* the error number, e.g. see js.msg */
const char16_t* ucmessage; /* the (default) error message */
const char16_t** messageArgs; /* arguments for the error message */
int16_t exnType; /* One of the JSExnType constants */
const char16_t* linebuf() const {
return linebuf_;
}
size_t linebufLength() const {
return linebufLength_;
}
size_t tokenOffset() const {
return tokenOffset_;
}
void initLinebuf(const char16_t* linebuf, size_t linebufLength, size_t tokenOffset);
};
/*
* JSErrorReport flag values. These may be freely composed.
*/
#define JSREPORT_ERROR 0x0 /* pseudo-flag for default case */
#define JSREPORT_WARNING 0x1 /* reported via JS_ReportWarning */
#define JSREPORT_EXCEPTION 0x2 /* exception was thrown */
#define JSREPORT_STRICT 0x4 /* error or warning due to strict option */
/*
* This condition is an error in strict mode code, a warning if
* JS_HAS_STRICT_OPTION(cx), and otherwise should not be reported at
* all. We check the strictness of the context's top frame's script;
* where that isn't appropriate, the caller should do the right checks
* itself instead of using this flag.
*/
#define JSREPORT_STRICT_MODE_ERROR 0x8
/*
* If JSREPORT_EXCEPTION is set, then a JavaScript-catchable exception
* has been thrown for this runtime error, and the host should ignore it.
* Exception-aware hosts should also check for JS_IsExceptionPending if
* JS_ExecuteScript returns failure, and signal or propagate the exception, as
* appropriate.
*/
#define JSREPORT_IS_WARNING(flags) (((flags) & JSREPORT_WARNING) != 0)
#define JSREPORT_IS_EXCEPTION(flags) (((flags) & JSREPORT_EXCEPTION) != 0)
#define JSREPORT_IS_STRICT(flags) (((flags) & JSREPORT_STRICT) != 0)
#define JSREPORT_IS_STRICT_MODE_ERROR(flags) (((flags) & \
JSREPORT_STRICT_MODE_ERROR) != 0)
extern JS_PUBLIC_API(JSErrorReporter)
JS_GetErrorReporter(JSRuntime* rt);
extern JS_PUBLIC_API(JSErrorReporter)
JS_SetErrorReporter(JSRuntime* rt, JSErrorReporter er);
namespace JS {
extern JS_PUBLIC_API(bool)
CreateError(JSContext* cx, JSExnType type, HandleObject stack,
HandleString fileName, uint32_t lineNumber, uint32_t columnNumber,
JSErrorReport* report, HandleString message, MutableHandleValue rval);
/************************************************************************/
/*
* Weak Maps.
*/
extern JS_PUBLIC_API(JSObject*)
NewWeakMapObject(JSContext* cx);
extern JS_PUBLIC_API(bool)
IsWeakMapObject(JSObject* obj);
extern JS_PUBLIC_API(bool)
GetWeakMapEntry(JSContext* cx, JS::HandleObject mapObj, JS::HandleObject key,
JS::MutableHandleValue val);
extern JS_PUBLIC_API(bool)
SetWeakMapEntry(JSContext* cx, JS::HandleObject mapObj, JS::HandleObject key,
JS::HandleValue val);
/*
* Map
*/
extern JS_PUBLIC_API(JSObject*)
NewMapObject(JSContext* cx);
extern JS_PUBLIC_API(uint32_t)
MapSize(JSContext* cx, HandleObject obj);
extern JS_PUBLIC_API(bool)
MapGet(JSContext* cx, HandleObject obj,
HandleValue key, MutableHandleValue rval);
extern JS_PUBLIC_API(bool)
MapHas(JSContext* cx, HandleObject obj, HandleValue key, bool* rval);
extern JS_PUBLIC_API(bool)
MapSet(JSContext* cx, HandleObject obj, HandleValue key, HandleValue val);
extern JS_PUBLIC_API(bool)
MapDelete(JSContext *cx, HandleObject obj, HandleValue key, bool *rval);
extern JS_PUBLIC_API(bool)
MapClear(JSContext* cx, HandleObject obj);
extern JS_PUBLIC_API(bool)
MapKeys(JSContext* cx, HandleObject obj, MutableHandleValue rval);
extern JS_PUBLIC_API(bool)
MapValues(JSContext* cx, HandleObject obj, MutableHandleValue rval);
extern JS_PUBLIC_API(bool)
MapEntries(JSContext* cx, HandleObject obj, MutableHandleValue rval);
extern JS_PUBLIC_API(bool)
MapForEach(JSContext *cx, HandleObject obj, HandleValue callbackFn, HandleValue thisVal);
/*
* Set
*/
extern JS_PUBLIC_API(JSObject *)
NewSetObject(JSContext *cx);
extern JS_PUBLIC_API(uint32_t)
SetSize(JSContext *cx, HandleObject obj);
extern JS_PUBLIC_API(bool)
SetHas(JSContext *cx, HandleObject obj, HandleValue key, bool *rval);
extern JS_PUBLIC_API(bool)
SetDelete(JSContext *cx, HandleObject obj, HandleValue key, bool *rval);
extern JS_PUBLIC_API(bool)
SetAdd(JSContext *cx, HandleObject obj, HandleValue key);
extern JS_PUBLIC_API(bool)
SetClear(JSContext *cx, HandleObject obj);
extern JS_PUBLIC_API(bool)
SetKeys(JSContext *cx, HandleObject obj, MutableHandleValue rval);
extern JS_PUBLIC_API(bool)
SetValues(JSContext *cx, HandleObject obj, MutableHandleValue rval);
extern JS_PUBLIC_API(bool)
SetEntries(JSContext *cx, HandleObject obj, MutableHandleValue rval);
extern JS_PUBLIC_API(bool)
SetForEach(JSContext *cx, HandleObject obj, HandleValue callbackFn, HandleValue thisVal);
} /* namespace JS */
/*
* Dates.
*/
extern JS_PUBLIC_API(JSObject*)
JS_NewDateObject(JSContext* cx, int year, int mon, int mday, int hour, int min, int sec);
/**
* Returns true and sets |*isDate| indicating whether |obj| is a Date object or
* a wrapper around one, otherwise returns false on failure.
*
* This method returns true with |*isDate == false| when passed a proxy whose
* target is a Date, or when passed a revoked proxy.
*/
extern JS_PUBLIC_API(bool)
JS_ObjectIsDate(JSContext* cx, JS::HandleObject obj, bool* isDate);
/************************************************************************/
/*
* Regular Expressions.
*/
#define JSREG_FOLD 0x01u /* fold uppercase to lowercase */
#define JSREG_GLOB 0x02u /* global exec, creates array of matches */
#define JSREG_MULTILINE 0x04u /* treat ^ and $ as begin and end of line */
#define JSREG_STICKY 0x08u /* only match starting at lastIndex */
extern JS_PUBLIC_API(JSObject*)
JS_NewRegExpObject(JSContext* cx, JS::HandleObject obj, const char* bytes, size_t length,
unsigned flags);
extern JS_PUBLIC_API(JSObject*)
JS_NewUCRegExpObject(JSContext* cx, JS::HandleObject obj, const char16_t* chars, size_t length,
unsigned flags);
extern JS_PUBLIC_API(bool)
JS_SetRegExpInput(JSContext* cx, JS::HandleObject obj, JS::HandleString input,
bool multiline);
extern JS_PUBLIC_API(bool)
JS_ClearRegExpStatics(JSContext* cx, JS::HandleObject obj);
extern JS_PUBLIC_API(bool)
JS_ExecuteRegExp(JSContext* cx, JS::HandleObject obj, JS::HandleObject reobj,
char16_t* chars, size_t length, size_t* indexp, bool test,
JS::MutableHandleValue rval);
/* RegExp interface for clients without a global object. */
extern JS_PUBLIC_API(JSObject*)
JS_NewRegExpObjectNoStatics(JSContext* cx, char* bytes, size_t length, unsigned flags);
extern JS_PUBLIC_API(JSObject*)
JS_NewUCRegExpObjectNoStatics(JSContext* cx, char16_t* chars, size_t length, unsigned flags);
extern JS_PUBLIC_API(bool)
JS_ExecuteRegExpNoStatics(JSContext* cx, JS::HandleObject reobj, char16_t* chars, size_t length,
size_t* indexp, bool test, JS::MutableHandleValue rval);
/**
* Returns true and sets |*isRegExp| indicating whether |obj| is a RegExp
* object or a wrapper around one, otherwise returns false on failure.
*
* This method returns true with |*isRegExp == false| when passed a proxy whose
* target is a RegExp, or when passed a revoked proxy.
*/
extern JS_PUBLIC_API(bool)
JS_ObjectIsRegExp(JSContext* cx, JS::HandleObject obj, bool* isRegExp);
extern JS_PUBLIC_API(unsigned)
JS_GetRegExpFlags(JSContext* cx, JS::HandleObject obj);
extern JS_PUBLIC_API(JSString*)
JS_GetRegExpSource(JSContext* cx, JS::HandleObject obj);
/************************************************************************/
extern JS_PUBLIC_API(bool)
JS_IsExceptionPending(JSContext* cx);
extern JS_PUBLIC_API(bool)
JS_GetPendingException(JSContext* cx, JS::MutableHandleValue vp);
extern JS_PUBLIC_API(void)
JS_SetPendingException(JSContext* cx, JS::HandleValue v);
extern JS_PUBLIC_API(void)
JS_ClearPendingException(JSContext* cx);
extern JS_PUBLIC_API(bool)
JS_ReportPendingException(JSContext* cx);
namespace JS {
/**
* Save and later restore the current exception state of a given JSContext.
* This is useful for implementing behavior in C++ that's like try/catch
* or try/finally in JS.
*
* Typical usage:
*
* bool ok = JS::Evaluate(cx, ...);
* AutoSaveExceptionState savedExc(cx);
* ... cleanup that might re-enter JS ...
* return ok;
*/
class JS_PUBLIC_API(AutoSaveExceptionState)
{
private:
JSContext* context;
bool wasPropagatingForcedReturn;
bool wasOverRecursed;
bool wasThrowing;
RootedValue exceptionValue;
public:
/*
* Take a snapshot of cx's current exception state. Then clear any current
* pending exception in cx.
*/
explicit AutoSaveExceptionState(JSContext* cx);
/*
* If neither drop() nor restore() was called, restore the exception
* state only if no exception is currently pending on cx.
*/
~AutoSaveExceptionState();
/*
* Discard any stored exception state.
* If this is called, the destructor is a no-op.
*/
void drop() {
wasPropagatingForcedReturn = false;
wasOverRecursed = false;
wasThrowing = false;
exceptionValue.setUndefined();
}
/*
* Replace cx's exception state with the stored exception state. Then
* discard the stored exception state. If this is called, the
* destructor is a no-op.
*/
void restore();
};
} /* namespace JS */
/* Deprecated API. Use AutoSaveExceptionState instead. */
extern JS_PUBLIC_API(JSExceptionState*)
JS_SaveExceptionState(JSContext* cx);
extern JS_PUBLIC_API(void)
JS_RestoreExceptionState(JSContext* cx, JSExceptionState* state);
extern JS_PUBLIC_API(void)
JS_DropExceptionState(JSContext* cx, JSExceptionState* state);
/**
* If the given object is an exception object, the exception will have (or be
* able to lazily create) an error report struct, and this function will return
* the address of that struct. Otherwise, it returns nullptr. The lifetime
* of the error report struct that might be returned is the same as the
* lifetime of the exception object.
*/
extern JS_PUBLIC_API(JSErrorReport*)
JS_ErrorFromException(JSContext* cx, JS::HandleObject obj);
extern JS_PUBLIC_API(JSObject*)
ExceptionStackOrNull(JSContext* cx, JS::HandleObject obj);
/*
* Throws a StopIteration exception on cx.
*/
extern JS_PUBLIC_API(bool)
JS_ThrowStopIteration(JSContext* cx);
extern JS_PUBLIC_API(bool)
JS_IsStopIteration(JS::Value v);
extern JS_PUBLIC_API(intptr_t)
JS_GetCurrentThread();
/**
* A JS runtime always has an "owner thread". The owner thread is set when the
* runtime is created (to the current thread) and practically all entry points
* into the JS engine check that a runtime (or anything contained in the
* runtime: context, compartment, object, etc) is only touched by its owner
* thread. Embeddings may check this invariant outside the JS engine by calling
* JS_AbortIfWrongThread (which will abort if not on the owner thread, even for
* non-debug builds).
*/
extern JS_PUBLIC_API(void)
JS_AbortIfWrongThread(JSRuntime* rt);
/************************************************************************/
/**
* A constructor can request that the JS engine create a default new 'this'
* object of the given class, using the callee to determine parentage and
* [[Prototype]].
*/
extern JS_PUBLIC_API(JSObject*)
JS_NewObjectForConstructor(JSContext* cx, const JSClass* clasp, const JS::CallArgs& args);
/************************************************************************/
#define JS_DEFAULT_ZEAL_FREQ 100
extern JS_PUBLIC_API(void)
JS_GetGCZeal(JSContext* cx, uint8_t* zeal, uint32_t* frequency, uint32_t* nextScheduled);
extern JS_PUBLIC_API(void)
JS_SetGCZeal(JSContext* cx, uint8_t zeal, uint32_t frequency);
extern JS_PUBLIC_API(void)
JS_ScheduleGC(JSContext* cx, uint32_t count);
extern JS_PUBLIC_API(void)
JS_SetParallelParsingEnabled(JSRuntime* rt, bool enabled);
extern JS_PUBLIC_API(void)
JS_SetOffthreadIonCompilationEnabled(JSRuntime* rt, bool enabled);
#define JIT_COMPILER_OPTIONS(Register) \
Register(BASELINE_WARMUP_TRIGGER, "baseline.warmup.trigger") \
Register(ION_WARMUP_TRIGGER, "ion.warmup.trigger") \
Register(ION_GVN_ENABLE, "ion.gvn.enable") \
Register(ION_FORCE_IC, "ion.forceinlineCaches") \
Register(ION_ENABLE, "ion.enable") \
Register(BASELINE_ENABLE, "baseline.enable") \
Register(OFFTHREAD_COMPILATION_ENABLE, "offthread-compilation.enable") \
Register(SIGNALS_ENABLE, "signals.enable")
typedef enum JSJitCompilerOption {
#define JIT_COMPILER_DECLARE(key, str) \
JSJITCOMPILER_ ## key,
JIT_COMPILER_OPTIONS(JIT_COMPILER_DECLARE)
#undef JIT_COMPILER_DECLARE
JSJITCOMPILER_NOT_AN_OPTION
} JSJitCompilerOption;
extern JS_PUBLIC_API(void)
JS_SetGlobalJitCompilerOption(JSRuntime* rt, JSJitCompilerOption opt, uint32_t value);
extern JS_PUBLIC_API(int)
JS_GetGlobalJitCompilerOption(JSRuntime* rt, JSJitCompilerOption opt);
/**
* Convert a uint32_t index into a jsid.
*/
extern JS_PUBLIC_API(bool)
JS_IndexToId(JSContext* cx, uint32_t index, JS::MutableHandleId);
/**
* Convert chars into a jsid.
*
* |chars| may not be an index.
*/
extern JS_PUBLIC_API(bool)
JS_CharsToId(JSContext* cx, JS::TwoByteChars chars, JS::MutableHandleId);
/**
* Test if the given string is a valid ECMAScript identifier
*/
extern JS_PUBLIC_API(bool)
JS_IsIdentifier(JSContext* cx, JS::HandleString str, bool* isIdentifier);
/**
* Test whether the given chars + length are a valid ECMAScript identifier.
* This version is infallible, so just returns whether the chars are an
* identifier.
*/
extern JS_PUBLIC_API(bool)
JS_IsIdentifier(const char16_t* chars, size_t length);
namespace JS {
/**
* AutoFilename encapsulates a pointer to a C-string and keeps the C-string
* alive for as long as the associated AutoFilename object is alive.
*/
class MOZ_STACK_CLASS JS_PUBLIC_API(AutoFilename)
{
void* scriptSource_;
AutoFilename(const AutoFilename&) = delete;
void operator=(const AutoFilename&) = delete;
public:
AutoFilename() : scriptSource_(nullptr) {}
~AutoFilename() { reset(nullptr); }
const char* get() const;
void reset(void* newScriptSource);
};
/**
* Return the current filename, line number and column number of the most
* currently running frame. Returns true if a scripted frame was found, false
* otherwise.
*
* If a the embedding has hidden the scripted caller for the topmost activation
* record, this will also return false.
*/
extern JS_PUBLIC_API(bool)
DescribeScriptedCaller(JSContext* cx, AutoFilename* filename = nullptr,
unsigned* lineno = nullptr, unsigned* column = nullptr);
extern JS_PUBLIC_API(JSObject*)
GetScriptedCallerGlobal(JSContext* cx);
/**
* Informs the JS engine that the scripted caller should be hidden. This can be
* used by the embedding to maintain an override of the scripted caller in its
* calculations, by hiding the scripted caller in the JS engine and pushing data
* onto a separate stack, which it inspects when DescribeScriptedCaller returns
* null.
*
* We maintain a counter on each activation record. Add() increments the counter
* of the topmost activation, and Remove() decrements it. The count may never
* drop below zero, and must always be exactly zero when the activation is
* popped from the stack.
*/
extern JS_PUBLIC_API(void)
HideScriptedCaller(JSContext* cx);
extern JS_PUBLIC_API(void)
UnhideScriptedCaller(JSContext* cx);
class MOZ_RAII AutoHideScriptedCaller
{
public:
explicit AutoHideScriptedCaller(JSContext* cx
MOZ_GUARD_OBJECT_NOTIFIER_PARAM)
: mContext(cx)
{
MOZ_GUARD_OBJECT_NOTIFIER_INIT;
HideScriptedCaller(mContext);
}
~AutoHideScriptedCaller() {
UnhideScriptedCaller(mContext);
}
protected:
JSContext* mContext;
MOZ_DECL_USE_GUARD_OBJECT_NOTIFIER
};
} /* namespace JS */
/*
* Encode/Decode interpreted scripts and functions to/from memory.
*/
extern JS_PUBLIC_API(void*)
JS_EncodeScript(JSContext* cx, JS::HandleScript script, uint32_t* lengthp);
extern JS_PUBLIC_API(void*)
JS_EncodeInterpretedFunction(JSContext* cx, JS::HandleObject funobj, uint32_t* lengthp);
extern JS_PUBLIC_API(JSScript*)
JS_DecodeScript(JSContext* cx, const void* data, uint32_t length);
extern JS_PUBLIC_API(JSObject*)
JS_DecodeInterpretedFunction(JSContext* cx, const void* data, uint32_t length);
namespace JS {
/*
* This callback represents a request by the JS engine to open for reading the
* existing cache entry for the given global and char range that may contain a
* module. If a cache entry exists, the callback shall return 'true' and return
* the size, base address and an opaque file handle as outparams. If the
* callback returns 'true', the JS engine guarantees a call to
* CloseAsmJSCacheEntryForReadOp, passing the same base address, size and
* handle.
*/
typedef bool
(* OpenAsmJSCacheEntryForReadOp)(HandleObject global, const char16_t* begin, const char16_t* limit,
size_t* size, const uint8_t** memory, intptr_t* handle);
typedef void
(* CloseAsmJSCacheEntryForReadOp)(size_t size, const uint8_t* memory, intptr_t handle);
/** The list of reasons why an asm.js module may not be stored in the cache. */
enum AsmJSCacheResult
{
AsmJSCache_MIN,
AsmJSCache_Success = AsmJSCache_MIN,
AsmJSCache_ModuleTooSmall,
AsmJSCache_SynchronousScript,
AsmJSCache_QuotaExceeded,
AsmJSCache_StorageInitFailure,
AsmJSCache_Disabled_Internal,
AsmJSCache_Disabled_ShellFlags,
AsmJSCache_Disabled_JitInspector,
AsmJSCache_InternalError,
AsmJSCache_LIMIT
};
/*
* This callback represents a request by the JS engine to open for writing a
* cache entry of the given size for the given global and char range containing
* the just-compiled module. If cache entry space is available, the callback
* shall return 'true' and return the base address and an opaque file handle as
* outparams. If the callback returns 'true', the JS engine guarantees a call
* to CloseAsmJSCacheEntryForWriteOp passing the same base address, size and
* handle.
*
* If 'installed' is true, then the cache entry is associated with a permanently
* installed JS file (e.g., in a packaged webapp). This information allows the
* embedding to store the cache entry in a installed location associated with
* the principal of 'global' where it will not be evicted until the associated
* installed JS file is removed.
*/
typedef AsmJSCacheResult
(* OpenAsmJSCacheEntryForWriteOp)(HandleObject global, bool installed,
const char16_t* begin, const char16_t* end,
size_t size, uint8_t** memory, intptr_t* handle);
typedef void
(* CloseAsmJSCacheEntryForWriteOp)(size_t size, uint8_t* memory, intptr_t handle);
typedef js::Vector<char, 0, js::SystemAllocPolicy> BuildIdCharVector;
/**
* Return the buildId (represented as a sequence of characters) associated with
* the currently-executing build. If the JS engine is embedded such that a
* single cache entry can be observed by different compiled versions of the JS
* engine, it is critical that the buildId shall change for each new build of
* the JS engine.
*/
typedef bool
(* BuildIdOp)(BuildIdCharVector* buildId);
struct AsmJSCacheOps
{
OpenAsmJSCacheEntryForReadOp openEntryForRead;
CloseAsmJSCacheEntryForReadOp closeEntryForRead;
OpenAsmJSCacheEntryForWriteOp openEntryForWrite;
CloseAsmJSCacheEntryForWriteOp closeEntryForWrite;
BuildIdOp buildId;
};
extern JS_PUBLIC_API(void)
SetAsmJSCacheOps(JSRuntime* rt, const AsmJSCacheOps* callbacks);
/**
* Convenience class for imitating a JS level for-of loop. Typical usage:
*
* ForOfIterator it(cx);
* if (!it.init(iterable))
* return false;
* RootedValue val(cx);
* while (true) {
* bool done;
* if (!it.next(&val, &done))
* return false;
* if (done)
* break;
* if (!DoStuff(cx, val))
* return false;
* }
*/
class MOZ_STACK_CLASS JS_PUBLIC_API(ForOfIterator) {
protected:
JSContext* cx_;
/*
* Use the ForOfPIC on the global object (see vm/GlobalObject.h) to try
* to optimize iteration across arrays.
*
* Case 1: Regular Iteration
* iterator - pointer to the iterator object.
* index - fixed to NOT_ARRAY (== UINT32_MAX)
*
* Case 2: Optimized Array Iteration
* iterator - pointer to the array object.
* index - current position in array.
*
* The cases are distinguished by whether or not |index| is equal to NOT_ARRAY.
*/
JS::RootedObject iterator;
uint32_t index;
static const uint32_t NOT_ARRAY = UINT32_MAX;
ForOfIterator(const ForOfIterator&) = delete;
ForOfIterator& operator=(const ForOfIterator&) = delete;
public:
explicit ForOfIterator(JSContext* cx) : cx_(cx), iterator(cx_), index(NOT_ARRAY) { }
enum NonIterableBehavior {
ThrowOnNonIterable,
AllowNonIterable
};
/**
* Initialize the iterator. If AllowNonIterable is passed then if getting
* the @@iterator property from iterable returns undefined init() will just
* return true instead of throwing. Callers must then check
* valueIsIterable() before continuing with the iteration.
*/
bool init(JS::HandleValue iterable,
NonIterableBehavior nonIterableBehavior = ThrowOnNonIterable);
/**
* Get the next value from the iterator. If false *done is true
* after this call, do not examine val.
*/
bool next(JS::MutableHandleValue val, bool* done);
/**
* If initialized with throwOnNonCallable = false, check whether
* the value is iterable.
*/
bool valueIsIterable() const {
return iterator;
}
private:
inline bool nextFromOptimizedArray(MutableHandleValue val, bool* done);
bool materializeArrayIterator();
};
/**
* If a large allocation fails when calling pod_{calloc,realloc}CanGC, the JS
* engine may call the large-allocation- failure callback, if set, to allow the
* embedding to flush caches, possibly perform shrinking GCs, etc. to make some
* room. The allocation will then be retried (and may still fail.)
*/
typedef void
(* LargeAllocationFailureCallback)(void* data);
extern JS_PUBLIC_API(void)
SetLargeAllocationFailureCallback(JSRuntime* rt, LargeAllocationFailureCallback afc, void* data);
/**
* Unlike the error reporter, which is only called if the exception for an OOM
* bubbles up and is not caught, the OutOfMemoryCallback is called immediately
* at the OOM site to allow the embedding to capture the current state of heap
* allocation before anything is freed. If the large-allocation-failure callback
* is called at all (not all allocation sites call the large-allocation-failure
* callback on failure), it is called before the out-of-memory callback; the
* out-of-memory callback is only called if the allocation still fails after the
* large-allocation-failure callback has returned.
*/
typedef void
(* OutOfMemoryCallback)(JSContext* cx, void* data);
extern JS_PUBLIC_API(void)
SetOutOfMemoryCallback(JSRuntime* rt, OutOfMemoryCallback cb, void* data);
/**
* Capture the current call stack as a chain of SavedFrame JSObjects, and set
* |stackp| to the SavedFrame for the youngest stack frame, or nullptr if there
* are no JS frames on the stack. If |maxFrameCount| is non-zero, capture at
* most the youngest |maxFrameCount| frames.
*/
extern JS_PUBLIC_API(bool)
CaptureCurrentStack(JSContext* cx, MutableHandleObject stackp, unsigned maxFrameCount = 0);
/*
* This is a utility function for preparing an async stack to be used
* by some other object. This may be used when you need to treat a
* given stack trace as an async parent. If you just need to capture
* the current stack, async parents and all, use CaptureCurrentStack
* instead.
*
* Here |asyncStack| is the async stack to prepare. It is copied into
* |cx|'s current compartment, and the newest frame is given
* |asyncCause| as its asynchronous cause. If |maxFrameCount| is
* non-zero, capture at most the youngest |maxFrameCount| frames. The
* new stack object is written to |stackp|. Returns true on success,
* or sets an exception and returns |false| on error.
*/
extern JS_PUBLIC_API(bool)
CopyAsyncStack(JSContext* cx, HandleObject asyncStack,
HandleString asyncCause, MutableHandleObject stackp,
unsigned maxFrameCount);
/*
* Accessors for working with SavedFrame JSObjects
*
* Each of these functions assert that if their `HandleObject savedFrame`
* argument is non-null, its JSClass is the SavedFrame class (or it is a
* cross-compartment or Xray wrapper around an object with the SavedFrame class)
* and the object is not the SavedFrame.prototype object.
*
* Each of these functions will find the first SavedFrame object in the chain
* whose underlying stack frame principals are subsumed by the cx's current
* compartment's principals, and operate on that SavedFrame object. This
* prevents leaking information about privileged frames to un-privileged
* callers. As a result, the SavedFrame in parameters do _NOT_ need to be in the
* same compartment as the cx, and the various out parameters are _NOT_
* guaranteed to be in the same compartment as cx.
*
* You may consider or skip over self-hosted frames by passing
* `SavedFrameSelfHosted::Include` or `SavedFrameSelfHosted::Exclude`
* respectively.
*
* Additionally, it may be the case that there is no such SavedFrame object
* whose captured frame's principals are subsumed by the caller's compartment's
* principals! If the `HandleObject savedFrame` argument is null, or the
* caller's principals do not subsume any of the chained SavedFrame object's
* principals, `SavedFrameResult::AccessDenied` is returned and a (hopefully)
* sane default value is chosen for the out param.
*
* See also `js/src/doc/SavedFrame/SavedFrame.md`.
*/
enum class SavedFrameResult {
Ok,
AccessDenied
};
enum class SavedFrameSelfHosted {
Include,
Exclude
};
/**
* Given a SavedFrame JSObject, get its source property. Defaults to the empty
* string.
*/
extern JS_PUBLIC_API(SavedFrameResult)
GetSavedFrameSource(JSContext* cx, HandleObject savedFrame, MutableHandleString sourcep,
SavedFrameSelfHosted selfHosted = SavedFrameSelfHosted::Include);
/**
* Given a SavedFrame JSObject, get its line property. Defaults to 0.
*/
extern JS_PUBLIC_API(SavedFrameResult)
GetSavedFrameLine(JSContext* cx, HandleObject savedFrame, uint32_t* linep,
SavedFrameSelfHosted selfHosted = SavedFrameSelfHosted::Include);
/**
* Given a SavedFrame JSObject, get its column property. Defaults to 0.
*/
extern JS_PUBLIC_API(SavedFrameResult)
GetSavedFrameColumn(JSContext* cx, HandleObject savedFrame, uint32_t* columnp,
SavedFrameSelfHosted selfHosted = SavedFrameSelfHosted::Include);
/**
* Given a SavedFrame JSObject, get its functionDisplayName string, or nullptr
* if SpiderMonkey was unable to infer a name for the captured frame's
* function. Defaults to nullptr.
*/
extern JS_PUBLIC_API(SavedFrameResult)
GetSavedFrameFunctionDisplayName(JSContext* cx, HandleObject savedFrame, MutableHandleString namep,
SavedFrameSelfHosted selfHosted = SavedFrameSelfHosted::Include);
/**
* Given a SavedFrame JSObject, get its asyncCause string. Defaults to nullptr.
*/
extern JS_PUBLIC_API(SavedFrameResult)
GetSavedFrameAsyncCause(JSContext* cx, HandleObject savedFrame, MutableHandleString asyncCausep,
SavedFrameSelfHosted selfHosted = SavedFrameSelfHosted::Include);
/**
* Given a SavedFrame JSObject, get its asyncParent SavedFrame object or nullptr
* if there is no asyncParent. The `asyncParentp` out parameter is _NOT_
* guaranteed to be in the cx's compartment. Defaults to nullptr.
*/
extern JS_PUBLIC_API(SavedFrameResult)
GetSavedFrameAsyncParent(JSContext* cx, HandleObject savedFrame, MutableHandleObject asyncParentp,
SavedFrameSelfHosted selfHosted = SavedFrameSelfHosted::Include);
/**
* Given a SavedFrame JSObject, get its parent SavedFrame object or nullptr if
* it is the oldest frame in the stack. The `parentp` out parameter is _NOT_
* guaranteed to be in the cx's compartment. Defaults to nullptr.
*/
extern JS_PUBLIC_API(SavedFrameResult)
GetSavedFrameParent(JSContext* cx, HandleObject savedFrame, MutableHandleObject parentp,
SavedFrameSelfHosted selfHosted = SavedFrameSelfHosted::Include);
/**
* Given a SavedFrame JSObject stack, stringify it in the same format as
* Error.prototype.stack. The stringified stack out parameter is placed in the
* cx's compartment. Defaults to the empty string.
*
* The same notes above about SavedFrame accessors applies here as well: cx
* doesn't need to be in stack's compartment, and stack can be null, a
* SavedFrame object, or a wrapper (CCW or Xray) around a SavedFrame object.
*
* Optional indent parameter specifies the number of white spaces to indent
* each line.
*/
extern JS_PUBLIC_API(bool)
BuildStackString(JSContext* cx, HandleObject stack, MutableHandleString stringp, size_t indent = 0);
} /* namespace JS */
/* Stopwatch-based performance monitoring. */
namespace js {
class AutoStopwatch;
/**
* Abstract base class for a representation of the performance of a
* component. Embeddings interested in performance monitoring should
* provide a concrete implementation of this class, as well as the
* relevant callbacks (see below).
*/
struct PerformanceGroup {
PerformanceGroup();
// The current iteration of the event loop.
uint64_t iteration() const;
// `true` if an instance of `AutoStopwatch` is already monitoring
// the performance of this performance group for this iteration
// of the event loop, `false` otherwise.
bool isAcquired(uint64_t it) const;
// `true` if a specific instance of `AutoStopwatch` is already monitoring
// the performance of this performance group for this iteration
// of the event loop, `false` otherwise.
bool isAcquired(uint64_t it, const AutoStopwatch* owner) const;
// Mark that an instance of `AutoStopwatch` is monitoring
// the performance of this group for a given iteration.
void acquire(uint64_t it, const AutoStopwatch* owner);
// Mark that no `AutoStopwatch` is monitoring the
// performance of this group for the iteration.
void release(uint64_t it, const AutoStopwatch* owner);
// The number of cycles spent in this group during this iteration
// of the event loop. Note that cycles are not a reliable measure,
// especially over short intervals. See Stopwatch.* for a more
// complete discussion on the imprecision of cycle measurement.
uint64_t recentCycles(uint64_t iteration) const;
void addRecentCycles(uint64_t iteration, uint64_t cycles);
// The number of times this group has been activated during this
// iteration of the event loop.
uint64_t recentTicks(uint64_t iteration) const;
void addRecentTicks(uint64_t iteration, uint64_t ticks);
// The number of microseconds spent doing CPOW during this
// iteration of the event loop.
uint64_t recentCPOW(uint64_t iteration) const;
void addRecentCPOW(uint64_t iteration, uint64_t CPOW);
// Get rid of any data that pretends to be recent.
void resetRecentData();
// `true` if new measures should be added to this group, `false`
// otherwise.
bool isActive() const;
void setIsActive(bool);
// `true` if this group has been used in the current iteration,
// `false` otherwise.
bool isUsedInThisIteration() const;
void setIsUsedInThisIteration(bool);
protected:
// An implementation of `delete` for this object. Must be provided
// by the embedding.
virtual void Delete() = 0;
private:
// The number of cycles spent in this group during this iteration
// of the event loop. Note that cycles are not a reliable measure,
// especially over short intervals. See Runtime.cpp for a more
// complete discussion on the imprecision of cycle measurement.
uint64_t recentCycles_;
// The number of times this group has been activated during this
// iteration of the event loop.
uint64_t recentTicks_;
// The number of microseconds spent doing CPOW during this
// iteration of the event loop.
uint64_t recentCPOW_;
// The current iteration of the event loop. If necessary,
// may safely overflow.
uint64_t iteration_;
// `true` if new measures should be added to this group, `false`
// otherwise.
bool isActive_;
// `true` if this group has been used in the current iteration,
// `false` otherwise.
bool isUsedInThisIteration_;
// The stopwatch currently monitoring the group,
// or `nullptr` if none. Used ony for comparison.
const AutoStopwatch* owner_;
public:
// Compatibility with RefPtr<>
void AddRef();
void Release();
uint64_t refCount_;
};
/**
* Commit any Performance Monitoring data.
*
* Until `FlushMonitoring` has been called, all PerformanceMonitoring data is invisible
* to the outside world and can cancelled with a call to `ResetMonitoring`.
*/
extern JS_PUBLIC_API(bool)
FlushPerformanceMonitoring(JSRuntime*);
/**
* Cancel any measurement that hasn't been committed.
*/
extern JS_PUBLIC_API(void)
ResetPerformanceMonitoring(JSRuntime*);
/**
* Cleanup any memory used by performance monitoring.
*/
extern JS_PUBLIC_API(void)
DisposePerformanceMonitoring(JSRuntime*);
/**
* Turn on/off stopwatch-based CPU monitoring.
*
* `SetStopwatchIsMonitoringCPOW` or `SetStopwatchIsMonitoringJank`
* may return `false` if monitoring could not be activated, which may
* happen if we are out of memory.
*/
extern JS_PUBLIC_API(bool)
SetStopwatchIsMonitoringCPOW(JSRuntime*, bool);
extern JS_PUBLIC_API(bool)
GetStopwatchIsMonitoringCPOW(JSRuntime*);
extern JS_PUBLIC_API(bool)
SetStopwatchIsMonitoringJank(JSRuntime*, bool);
extern JS_PUBLIC_API(bool)
GetStopwatchIsMonitoringJank(JSRuntime*);
extern JS_PUBLIC_API(bool)
IsStopwatchActive(JSRuntime*);
// Extract the CPU rescheduling data.
extern JS_PUBLIC_API(void)
GetPerfMonitoringTestCpuRescheduling(JSRuntime*, uint64_t* stayed, uint64_t* moved);
/**
* Add a number of microseconds to the time spent waiting on CPOWs
* since process start.
*/
extern JS_PUBLIC_API(void)
AddCPOWPerformanceDelta(JSRuntime*, uint64_t delta);
typedef bool
(*StopwatchStartCallback)(uint64_t, void*);
extern JS_PUBLIC_API(bool)
SetStopwatchStartCallback(JSRuntime*, StopwatchStartCallback, void*);
typedef bool
(*StopwatchCommitCallback)(uint64_t, mozilla::Vector<RefPtr<PerformanceGroup>>&, void*);
extern JS_PUBLIC_API(bool)
SetStopwatchCommitCallback(JSRuntime*, StopwatchCommitCallback, void*);
typedef bool
(*GetGroupsCallback)(JSContext*, mozilla::Vector<RefPtr<PerformanceGroup>>&, void*);
extern JS_PUBLIC_API(bool)
SetGetPerformanceGroupsCallback(JSRuntime*, GetGroupsCallback, void*);
} /* namespace js */
#endif /* jsapi_h */