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/* -*- Mode: C++; tab-width: 8; indent-tabs-mode: nil; c-basic-offset: 4 -*-
* This Source Code Form is subject to the terms of the Mozilla Public
* License, v. 2.0. If a copy of the MPL was not distributed with this
* file, You can obtain one at http://mozilla.org/MPL/2.0/. */
#ifndef jit_VMFunctions_h
#define jit_VMFunctions_h
#include "mozilla/Attributes.h"
#include "jspubtd.h"
#include "jit/CompileInfo.h"
#include "jit/JitFrames.h"
#include "vm/Interpreter.h"
namespace js {
class NamedLambdaObject;
class WithScope;
class InlineTypedObject;
class GeneratorObject;
class TypedArrayObject;
namespace jit {
enum DataType {
Type_Void,
Type_Bool,
Type_Int32,
Type_Double,
Type_Pointer,
Type_Object,
Type_Value,
Type_Handle
};
struct PopValues
{
uint32_t numValues;
explicit PopValues(uint32_t numValues)
: numValues(numValues)
{ }
};
enum MaybeTailCall {
TailCall,
NonTailCall
};
// Contains information about a virtual machine function that can be called
// from JIT code. Functions described in this manner must conform to a simple
// protocol: the return type must have a special "failure" value (for example,
// false for bool, or nullptr for Objects). If the function is designed to
// return a value that does not meet this requirement - such as
// object-or-nullptr, or an integer, an optional, final outParam can be
// specified. In this case, the return type must be boolean to indicate
// failure.
//
// All functions described by VMFunction take a JSContext * as a first
// argument, and are treated as re-entrant into the VM and therefore fallible.
struct VMFunction
{
// Global linked list of all VMFunctions.
static VMFunction* functions;
VMFunction* next;
// Address of the C function.
void* wrapped;
const char* name_;
// Number of arguments expected, excluding JSContext * as an implicit
// first argument and an outparam as a possible implicit final argument.
uint32_t explicitArgs;
enum ArgProperties {
WordByValue = 0,
DoubleByValue = 1,
WordByRef = 2,
DoubleByRef = 3,
// BitMask version.
Word = 0,
Double = 1,
ByRef = 2
};
// Contains properties about the first 16 arguments.
uint32_t argumentProperties;
// Which arguments should be passed in float register on platforms that
// have them.
uint32_t argumentPassedInFloatRegs;
// The outparam may be any Type_*, and must be the final argument to the
// function, if not Void. outParam != Void implies that the return type
// has a boolean failure mode.
DataType outParam;
// Type returned by the C function and used by the VMFunction wrapper to
// check for failures of the C function. Valid failure/return types are
// boolean and object pointers which are asserted inside the VMFunction
// constructor. If the C function use an outparam (!= Type_Void), then
// the only valid failure/return type is boolean -- object pointers are
// pointless because the wrapper will only use it to compare it against
// nullptr before discarding its value.
DataType returnType;
// Note: a maximum of seven root types is supported.
enum RootType {
RootNone = 0,
RootObject,
RootString,
RootPropertyName,
RootFunction,
RootValue,
RootCell
};
// Contains an combination of enumerated types used by the gc for marking
// arguments of the VM wrapper.
uint64_t argumentRootTypes;
// The root type of the out param if outParam == Type_Handle.
RootType outParamRootType;
// Number of Values the VM wrapper should pop from the stack when it returns.
// Used by baseline IC stubs so that they can use tail calls to call the VM
// wrapper.
uint32_t extraValuesToPop;
// On some architectures, called functions need to explicitly push their
// return address, for a tail call, there is nothing to push, so tail-callness
// needs to be known at compile time.
MaybeTailCall expectTailCall;
uint32_t argc() const {
// JSContext * + args + (OutParam? *)
return 1 + explicitArgc() + ((outParam == Type_Void) ? 0 : 1);
}
DataType failType() const {
return returnType;
}
ArgProperties argProperties(uint32_t explicitArg) const {
return ArgProperties((argumentProperties >> (2 * explicitArg)) & 3);
}
RootType argRootType(uint32_t explicitArg) const {
return RootType((argumentRootTypes >> (3 * explicitArg)) & 7);
}
bool argPassedInFloatReg(uint32_t explicitArg) const {
return ((argumentPassedInFloatRegs >> explicitArg) & 1) == 1;
}
const char* name() const {
return name_;
}
// Return the stack size consumed by explicit arguments.
size_t explicitStackSlots() const {
size_t stackSlots = explicitArgs;
// Fetch all double-word flags of explicit arguments.
uint32_t n =
((1 << (explicitArgs * 2)) - 1) // = Explicit argument mask.
& 0x55555555 // = Mask double-size args.
& argumentProperties;
// Add the number of double-word flags. (expect a few loop
// iteration)
while (n) {
stackSlots++;
n &= n - 1;
}
return stackSlots;
}
// Double-size argument which are passed by value are taking the space
// of 2 C arguments. This function is used to compute the number of
// argument expected by the C function. This is not the same as
// explicitStackSlots because reference to stack slots may take one less
// register in the total count.
size_t explicitArgc() const {
size_t stackSlots = explicitArgs;
// Fetch all explicit arguments.
uint32_t n =
((1 << (explicitArgs * 2)) - 1) // = Explicit argument mask.
& argumentProperties;
// Filter double-size arguments (0x5 = 0b0101) and remove (& ~)
// arguments passed by reference (0b1010 >> 1 == 0b0101).
n = (n & 0x55555555) & ~(n >> 1);
// Add the number of double-word transfered by value. (expect a few
// loop iteration)
while (n) {
stackSlots++;
n &= n - 1;
}
return stackSlots;
}
size_t doubleByRefArgs() const {
size_t count = 0;
// Fetch all explicit arguments.
uint32_t n =
((1 << (explicitArgs * 2)) - 1) // = Explicit argument mask.
& argumentProperties;
// Filter double-size arguments (0x5 = 0b0101) and take (&) only
// arguments passed by reference (0b1010 >> 1 == 0b0101).
n = (n & 0x55555555) & (n >> 1);
// Add the number of double-word transfered by refference. (expect a
// few loop iterations)
while (n) {
count++;
n &= n - 1;
}
return count;
}
VMFunction(void* wrapped, const char* name, uint32_t explicitArgs, uint32_t argumentProperties,
uint32_t argumentPassedInFloatRegs, uint64_t argRootTypes,
DataType outParam, RootType outParamRootType, DataType returnType,
uint32_t extraValuesToPop = 0, MaybeTailCall expectTailCall = NonTailCall)
: wrapped(wrapped),
name_(name),
explicitArgs(explicitArgs),
argumentProperties(argumentProperties),
argumentPassedInFloatRegs(argumentPassedInFloatRegs),
outParam(outParam),
returnType(returnType),
argumentRootTypes(argRootTypes),
outParamRootType(outParamRootType),
extraValuesToPop(extraValuesToPop),
expectTailCall(expectTailCall)
{
// Check for valid failure/return type.
MOZ_ASSERT_IF(outParam != Type_Void, returnType == Type_Bool);
MOZ_ASSERT(returnType == Type_Bool ||
returnType == Type_Object);
}
VMFunction(const VMFunction& o) {
*this = o;
addToFunctions();
}
private:
// Add this to the global list of VMFunctions.
void addToFunctions();
};
template <class> struct TypeToDataType { /* Unexpected return type for a VMFunction. */ };
template <> struct TypeToDataType<bool> { static const DataType result = Type_Bool; };
template <> struct TypeToDataType<JSObject*> { static const DataType result = Type_Object; };
template <> struct TypeToDataType<NativeObject*> { static const DataType result = Type_Object; };
template <> struct TypeToDataType<PlainObject*> { static const DataType result = Type_Object; };
template <> struct TypeToDataType<InlineTypedObject*> { static const DataType result = Type_Object; };
template <> struct TypeToDataType<NamedLambdaObject*> { static const DataType result = Type_Object; };
template <> struct TypeToDataType<ArrayObject*> { static const DataType result = Type_Object; };
template <> struct TypeToDataType<TypedArrayObject*> { static const DataType result = Type_Object; };
template <> struct TypeToDataType<JSString*> { static const DataType result = Type_Object; };
template <> struct TypeToDataType<JSFlatString*> { static const DataType result = Type_Object; };
template <> struct TypeToDataType<HandleObject> { static const DataType result = Type_Handle; };
template <> struct TypeToDataType<HandleString> { static const DataType result = Type_Handle; };
template <> struct TypeToDataType<HandlePropertyName> { static const DataType result = Type_Handle; };
template <> struct TypeToDataType<HandleFunction> { static const DataType result = Type_Handle; };
template <> struct TypeToDataType<Handle<NativeObject*> > { static const DataType result = Type_Handle; };
template <> struct TypeToDataType<Handle<InlineTypedObject*> > { static const DataType result = Type_Handle; };
template <> struct TypeToDataType<Handle<ArrayObject*> > { static const DataType result = Type_Handle; };
template <> struct TypeToDataType<Handle<GeneratorObject*> > { static const DataType result = Type_Handle; };
template <> struct TypeToDataType<Handle<PlainObject*> > { static const DataType result = Type_Handle; };
template <> struct TypeToDataType<Handle<WithScope*> > { static const DataType result = Type_Handle; };
template <> struct TypeToDataType<Handle<LexicalScope*> > { static const DataType result = Type_Handle; };
template <> struct TypeToDataType<Handle<Scope*> > { static const DataType result = Type_Handle; };
template <> struct TypeToDataType<HandleScript> { static const DataType result = Type_Handle; };
template <> struct TypeToDataType<HandleValue> { static const DataType result = Type_Handle; };
template <> struct TypeToDataType<MutableHandleValue> { static const DataType result = Type_Handle; };
// Convert argument types to properties of the argument known by the jit.
template <class T> struct TypeToArgProperties {
static const uint32_t result =
(sizeof(T) <= sizeof(void*) ? VMFunction::Word : VMFunction::Double);
};
template <> struct TypeToArgProperties<const Value&> {
static const uint32_t result = TypeToArgProperties<Value>::result | VMFunction::ByRef;
};
template <> struct TypeToArgProperties<HandleObject> {
static const uint32_t result = TypeToArgProperties<JSObject*>::result | VMFunction::ByRef;
};
template <> struct TypeToArgProperties<HandleString> {
static const uint32_t result = TypeToArgProperties<JSString*>::result | VMFunction::ByRef;
};
template <> struct TypeToArgProperties<HandlePropertyName> {
static const uint32_t result = TypeToArgProperties<PropertyName*>::result | VMFunction::ByRef;
};
template <> struct TypeToArgProperties<HandleFunction> {
static const uint32_t result = TypeToArgProperties<JSFunction*>::result | VMFunction::ByRef;
};
template <> struct TypeToArgProperties<Handle<NativeObject*> > {
static const uint32_t result = TypeToArgProperties<NativeObject*>::result | VMFunction::ByRef;
};
template <> struct TypeToArgProperties<Handle<InlineTypedObject*> > {
static const uint32_t result = TypeToArgProperties<InlineTypedObject*>::result | VMFunction::ByRef;
};
template <> struct TypeToArgProperties<Handle<ArrayObject*> > {
static const uint32_t result = TypeToArgProperties<ArrayObject*>::result | VMFunction::ByRef;
};
template <> struct TypeToArgProperties<Handle<GeneratorObject*> > {
static const uint32_t result = TypeToArgProperties<GeneratorObject*>::result | VMFunction::ByRef;
};
template <> struct TypeToArgProperties<Handle<PlainObject*> > {
static const uint32_t result = TypeToArgProperties<PlainObject*>::result | VMFunction::ByRef;
};
template <> struct TypeToArgProperties<Handle<WithScope*> > {
static const uint32_t result = TypeToArgProperties<WithScope*>::result | VMFunction::ByRef;
};
template <> struct TypeToArgProperties<Handle<LexicalScope*> > {
static const uint32_t result = TypeToArgProperties<LexicalScope*>::result | VMFunction::ByRef;
};
template <> struct TypeToArgProperties<Handle<Scope*> > {
static const uint32_t result = TypeToArgProperties<Scope*>::result | VMFunction::ByRef;
};
template <> struct TypeToArgProperties<HandleScript> {
static const uint32_t result = TypeToArgProperties<JSScript*>::result | VMFunction::ByRef;
};
template <> struct TypeToArgProperties<HandleValue> {
static const uint32_t result = TypeToArgProperties<Value>::result | VMFunction::ByRef;
};
template <> struct TypeToArgProperties<MutableHandleValue> {
static const uint32_t result = TypeToArgProperties<Value>::result | VMFunction::ByRef;
};
template <> struct TypeToArgProperties<HandleShape> {
static const uint32_t result = TypeToArgProperties<Shape*>::result | VMFunction::ByRef;
};
template <> struct TypeToArgProperties<HandleObjectGroup> {
static const uint32_t result = TypeToArgProperties<ObjectGroup*>::result | VMFunction::ByRef;
};
// Convert argument type to whether or not it should be passed in a float
// register on platforms that have them, like x64.
template <class T> struct TypeToPassInFloatReg {
static const uint32_t result = 0;
};
template <> struct TypeToPassInFloatReg<double> {
static const uint32_t result = 1;
};
// Convert argument types to root types used by the gc, see MarkJitExitFrame.
template <class T> struct TypeToRootType {
static const uint32_t result = VMFunction::RootNone;
};
template <> struct TypeToRootType<HandleObject> {
static const uint32_t result = VMFunction::RootObject;
};
template <> struct TypeToRootType<HandleString> {
static const uint32_t result = VMFunction::RootString;
};
template <> struct TypeToRootType<HandlePropertyName> {
static const uint32_t result = VMFunction::RootPropertyName;
};
template <> struct TypeToRootType<HandleFunction> {
static const uint32_t result = VMFunction::RootFunction;
};
template <> struct TypeToRootType<HandleValue> {
static const uint32_t result = VMFunction::RootValue;
};
template <> struct TypeToRootType<MutableHandleValue> {
static const uint32_t result = VMFunction::RootValue;
};
template <> struct TypeToRootType<HandleShape> {
static const uint32_t result = VMFunction::RootCell;
};
template <> struct TypeToRootType<HandleObjectGroup> {
static const uint32_t result = VMFunction::RootCell;
};
template <> struct TypeToRootType<HandleScript> {
static const uint32_t result = VMFunction::RootCell;
};
template <> struct TypeToRootType<Handle<NativeObject*> > {
static const uint32_t result = VMFunction::RootObject;
};
template <> struct TypeToRootType<Handle<InlineTypedObject*> > {
static const uint32_t result = VMFunction::RootObject;
};
template <> struct TypeToRootType<Handle<ArrayObject*> > {
static const uint32_t result = VMFunction::RootObject;
};
template <> struct TypeToRootType<Handle<GeneratorObject*> > {
static const uint32_t result = VMFunction::RootObject;
};
template <> struct TypeToRootType<Handle<PlainObject*> > {
static const uint32_t result = VMFunction::RootObject;
};
template <> struct TypeToRootType<Handle<LexicalScope*> > {
static const uint32_t result = VMFunction::RootCell;
};
template <> struct TypeToRootType<Handle<WithScope*> > {
static const uint32_t result = VMFunction::RootCell;
};
template <> struct TypeToRootType<Handle<Scope*> > {
static const uint32_t result = VMFunction::RootCell;
};
template <class T> struct TypeToRootType<Handle<T> > {
// Fail for Handle types that aren't specialized above.
};
template <class> struct OutParamToDataType { static const DataType result = Type_Void; };
template <> struct OutParamToDataType<Value*> { static const DataType result = Type_Value; };
template <> struct OutParamToDataType<int*> { static const DataType result = Type_Int32; };
template <> struct OutParamToDataType<uint32_t*> { static const DataType result = Type_Int32; };
template <> struct OutParamToDataType<uint8_t**> { static const DataType result = Type_Pointer; };
template <> struct OutParamToDataType<bool*> { static const DataType result = Type_Bool; };
template <> struct OutParamToDataType<double*> { static const DataType result = Type_Double; };
template <> struct OutParamToDataType<MutableHandleValue> { static const DataType result = Type_Handle; };
template <> struct OutParamToDataType<MutableHandleObject> { static const DataType result = Type_Handle; };
template <> struct OutParamToDataType<MutableHandleString> { static const DataType result = Type_Handle; };
template <class> struct OutParamToRootType {
static const VMFunction::RootType result = VMFunction::RootNone;
};
template <> struct OutParamToRootType<MutableHandleValue> {
static const VMFunction::RootType result = VMFunction::RootValue;
};
template <> struct OutParamToRootType<MutableHandleObject> {
static const VMFunction::RootType result = VMFunction::RootObject;
};
template <> struct OutParamToRootType<MutableHandleString> {
static const VMFunction::RootType result = VMFunction::RootString;
};
template <class> struct MatchContext { };
template <> struct MatchContext<JSContext*> {
static const bool valid = true;
};
template <> struct MatchContext<ExclusiveContext*> {
static const bool valid = true;
};
// Extract the last element of a list of types.
template <typename... ArgTypes>
struct LastArg;
template <>
struct LastArg<>
{
typedef void Type;
static constexpr size_t nbArgs = 0;
};
template <typename HeadType>
struct LastArg<HeadType>
{
typedef HeadType Type;
static constexpr size_t nbArgs = 1;
};
template <typename HeadType, typename... TailTypes>
struct LastArg<HeadType, TailTypes...>
{
typedef typename LastArg<TailTypes...>::Type Type;
static constexpr size_t nbArgs = LastArg<TailTypes...>::nbArgs + 1;
};
// Construct a bit mask from a list of types. The mask is constructed as an OR
// of the mask produced for each argument. The result of each argument is
// shifted by its index, such that the result of the first argument is on the
// low bits of the mask, and the result of the last argument in part of the
// high bits of the mask.
template <template<typename> class Each, typename ResultType, size_t Shift,
typename... Args>
struct BitMask;
template <template<typename> class Each, typename ResultType, size_t Shift>
struct BitMask<Each, ResultType, Shift>
{
static constexpr ResultType result = ResultType();
};
template <template<typename> class Each, typename ResultType, size_t Shift,
typename HeadType, typename... TailTypes>
struct BitMask<Each, ResultType, Shift, HeadType, TailTypes...>
{
static_assert(ResultType(Each<HeadType>::result) < (1 << Shift),
"not enough bits reserved by the shift for individual results");
static_assert(LastArg<TailTypes...>::nbArgs < (8 * sizeof(ResultType) / Shift),
"not enough bits in the result type to store all bit masks");
static constexpr ResultType result =
ResultType(Each<HeadType>::result) |
(BitMask<Each, ResultType, Shift, TailTypes...>::result << Shift);
};
// Extract VMFunction properties based on the signature of the function. The
// properties are used to generate the logic for calling the VM function, and
// also for marking the stack during GCs.
template <typename... Args>
struct FunctionInfo;
template <class R, class Context, typename... Args>
struct FunctionInfo<R (*)(Context, Args...)> : public VMFunction
{
typedef R (*pf)(Context, Args...);
static DataType returnType() {
return TypeToDataType<R>::result;
}
static DataType outParam() {
return OutParamToDataType<typename LastArg<Args...>::Type>::result;
}
static RootType outParamRootType() {
return OutParamToRootType<typename LastArg<Args...>::Type>::result;
}
static size_t NbArgs() {
return LastArg<Args...>::nbArgs;
}
static size_t explicitArgs() {
return NbArgs() - (outParam() != Type_Void ? 1 : 0);
}
static uint32_t argumentProperties() {
return BitMask<TypeToArgProperties, uint32_t, 2, Args...>::result;
}
static uint32_t argumentPassedInFloatRegs() {
return BitMask<TypeToPassInFloatReg, uint32_t, 2, Args...>::result;
}
static uint64_t argumentRootTypes() {
return BitMask<TypeToRootType, uint64_t, 3, Args...>::result;
}
explicit FunctionInfo(pf fun, const char* name, PopValues extraValuesToPop = PopValues(0))
: VMFunction(JS_FUNC_TO_DATA_PTR(void*, fun), name, explicitArgs(),
argumentProperties(), argumentPassedInFloatRegs(),
argumentRootTypes(), outParam(), outParamRootType(),
returnType(), extraValuesToPop.numValues, NonTailCall)
{
static_assert(MatchContext<Context>::valid, "Invalid cx type in VMFunction");
}
explicit FunctionInfo(pf fun, const char* name, MaybeTailCall expectTailCall,
PopValues extraValuesToPop = PopValues(0))
: VMFunction(JS_FUNC_TO_DATA_PTR(void*, fun), name, explicitArgs(),
argumentProperties(), argumentPassedInFloatRegs(),
argumentRootTypes(), outParam(), outParamRootType(),
returnType(), extraValuesToPop.numValues, expectTailCall)
{
static_assert(MatchContext<Context>::valid, "Invalid cx type in VMFunction");
}
};
class AutoDetectInvalidation
{
JSContext* cx_;
IonScript* ionScript_;
MutableHandleValue rval_;
bool disabled_;
void setReturnOverride();
public:
AutoDetectInvalidation(JSContext* cx, MutableHandleValue rval, IonScript* ionScript)
: cx_(cx), ionScript_(ionScript), rval_(rval), disabled_(false)
{
MOZ_ASSERT(ionScript);
}
AutoDetectInvalidation(JSContext* cx, MutableHandleValue rval);
void disable() {
MOZ_ASSERT(!disabled_);
disabled_ = true;
}
~AutoDetectInvalidation() {
if (!disabled_ && ionScript_->invalidated())
setReturnOverride();
}
};
MOZ_MUST_USE bool
InvokeFunction(JSContext* cx, HandleObject obj0, bool constructing, bool ignoresReturnValue,
uint32_t argc, Value* argv, MutableHandleValue rval);
MOZ_MUST_USE bool
InvokeFunctionShuffleNewTarget(JSContext* cx, HandleObject obj, uint32_t numActualArgs,
uint32_t numFormalArgs, Value* argv, MutableHandleValue rval);
bool CheckOverRecursed(JSContext* cx);
bool CheckOverRecursedWithExtra(JSContext* cx, BaselineFrame* frame,
uint32_t extra, uint32_t earlyCheck);
JSObject* BindVar(JSContext* cx, HandleObject scopeChain);
MOZ_MUST_USE bool
DefVar(JSContext* cx, HandlePropertyName dn, unsigned attrs, HandleObject scopeChain);
MOZ_MUST_USE bool
DefLexical(JSContext* cx, HandlePropertyName dn, unsigned attrs, HandleObject scopeChain);
MOZ_MUST_USE bool
DefGlobalLexical(JSContext* cx, HandlePropertyName dn, unsigned attrs);
MOZ_MUST_USE bool
MutatePrototype(JSContext* cx, HandlePlainObject obj, HandleValue value);
MOZ_MUST_USE bool
InitProp(JSContext* cx, HandleObject obj, HandlePropertyName name, HandleValue value,
jsbytecode* pc);
template<bool Equal>
bool LooselyEqual(JSContext* cx, MutableHandleValue lhs, MutableHandleValue rhs, bool* res);
template<bool Equal>
bool StrictlyEqual(JSContext* cx, MutableHandleValue lhs, MutableHandleValue rhs, bool* res);
bool LessThan(JSContext* cx, MutableHandleValue lhs, MutableHandleValue rhs, bool* res);
bool LessThanOrEqual(JSContext* cx, MutableHandleValue lhs, MutableHandleValue rhs, bool* res);
bool GreaterThan(JSContext* cx, MutableHandleValue lhs, MutableHandleValue rhs, bool* res);
bool GreaterThanOrEqual(JSContext* cx, MutableHandleValue lhs, MutableHandleValue rhs, bool* res);
template<bool Equal>
bool StringsEqual(JSContext* cx, HandleString left, HandleString right, bool* res);
MOZ_MUST_USE bool ArrayPopDense(JSContext* cx, HandleObject obj, MutableHandleValue rval);
MOZ_MUST_USE bool ArrayPushDense(JSContext* cx, HandleObject obj, HandleValue v, uint32_t* length);
MOZ_MUST_USE bool ArrayShiftDense(JSContext* cx, HandleObject obj, MutableHandleValue rval);
JSString* ArrayJoin(JSContext* cx, HandleObject array, HandleString sep);
MOZ_MUST_USE bool
CharCodeAt(JSContext* cx, HandleString str, int32_t index, uint32_t* code);
JSFlatString* StringFromCharCode(JSContext* cx, int32_t code);
JSString* StringFromCodePoint(JSContext* cx, int32_t codePoint);
MOZ_MUST_USE bool
SetProperty(JSContext* cx, HandleObject obj, HandlePropertyName name, HandleValue value,
bool strict, jsbytecode* pc);
MOZ_MUST_USE bool
InterruptCheck(JSContext* cx);
void* MallocWrapper(JSRuntime* rt, size_t nbytes);
JSObject* NewCallObject(JSContext* cx, HandleShape shape, HandleObjectGroup group);
JSObject* NewSingletonCallObject(JSContext* cx, HandleShape shape);
JSObject* NewStringObject(JSContext* cx, HandleString str);
bool OperatorIn(JSContext* cx, HandleValue key, HandleObject obj, bool* out);
bool OperatorInI(JSContext* cx, uint32_t index, HandleObject obj, bool* out);
MOZ_MUST_USE bool
GetIntrinsicValue(JSContext* cx, HandlePropertyName name, MutableHandleValue rval);
MOZ_MUST_USE bool
CreateThis(JSContext* cx, HandleObject callee, HandleObject newTarget, MutableHandleValue rval);
void GetDynamicName(JSContext* cx, JSObject* scopeChain, JSString* str, Value* vp);
void PostWriteBarrier(JSRuntime* rt, JSObject* obj);
void PostWriteElementBarrier(JSRuntime* rt, JSObject* obj, int32_t index);
void PostGlobalWriteBarrier(JSRuntime* rt, JSObject* obj);
uint32_t GetIndexFromString(JSString* str);
MOZ_MUST_USE bool
DebugPrologue(JSContext* cx, BaselineFrame* frame, jsbytecode* pc, bool* mustReturn);
MOZ_MUST_USE bool
DebugEpilogue(JSContext* cx, BaselineFrame* frame, jsbytecode* pc, bool ok);
MOZ_MUST_USE bool
DebugEpilogueOnBaselineReturn(JSContext* cx, BaselineFrame* frame, jsbytecode* pc);
void FrameIsDebuggeeCheck(BaselineFrame* frame);
JSObject* CreateGenerator(JSContext* cx, BaselineFrame* frame);
MOZ_MUST_USE bool
NormalSuspend(JSContext* cx, HandleObject obj, BaselineFrame* frame, jsbytecode* pc,
uint32_t stackDepth);
MOZ_MUST_USE bool
FinalSuspend(JSContext* cx, HandleObject obj, BaselineFrame* frame, jsbytecode* pc);
MOZ_MUST_USE bool
InterpretResume(JSContext* cx, HandleObject obj, HandleValue val, HandlePropertyName kind,
MutableHandleValue rval);
MOZ_MUST_USE bool
DebugAfterYield(JSContext* cx, BaselineFrame* frame);
MOZ_MUST_USE bool
GeneratorThrowOrClose(JSContext* cx, BaselineFrame* frame, Handle<GeneratorObject*> genObj,
HandleValue arg, uint32_t resumeKind);
MOZ_MUST_USE bool
GlobalNameConflictsCheckFromIon(JSContext* cx, HandleScript script);
MOZ_MUST_USE bool
CheckGlobalOrEvalDeclarationConflicts(JSContext* cx, BaselineFrame* frame);
MOZ_MUST_USE bool
InitFunctionEnvironmentObjects(JSContext* cx, BaselineFrame* frame);
MOZ_MUST_USE bool
NewArgumentsObject(JSContext* cx, BaselineFrame* frame, MutableHandleValue res);
JSObject* InitRestParameter(JSContext* cx, uint32_t length, Value* rest, HandleObject templateObj,
HandleObject res);
MOZ_MUST_USE bool
HandleDebugTrap(JSContext* cx, BaselineFrame* frame, uint8_t* retAddr, bool* mustReturn);
MOZ_MUST_USE bool
OnDebuggerStatement(JSContext* cx, BaselineFrame* frame, jsbytecode* pc, bool* mustReturn);
MOZ_MUST_USE bool
GlobalHasLiveOnDebuggerStatement(JSContext* cx);
MOZ_MUST_USE bool
EnterWith(JSContext* cx, BaselineFrame* frame, HandleValue val, Handle<WithScope*> templ);
MOZ_MUST_USE bool
LeaveWith(JSContext* cx, BaselineFrame* frame);
MOZ_MUST_USE bool
PushLexicalEnv(JSContext* cx, BaselineFrame* frame, Handle<LexicalScope*> scope);
MOZ_MUST_USE bool
PopLexicalEnv(JSContext* cx, BaselineFrame* frame);
MOZ_MUST_USE bool
DebugLeaveThenPopLexicalEnv(JSContext* cx, BaselineFrame* frame, jsbytecode* pc);
MOZ_MUST_USE bool
FreshenLexicalEnv(JSContext* cx, BaselineFrame* frame);
MOZ_MUST_USE bool
DebugLeaveThenFreshenLexicalEnv(JSContext* cx, BaselineFrame* frame, jsbytecode* pc);
MOZ_MUST_USE bool
RecreateLexicalEnv(JSContext* cx, BaselineFrame* frame);
MOZ_MUST_USE bool
DebugLeaveThenRecreateLexicalEnv(JSContext* cx, BaselineFrame* frame, jsbytecode* pc);
MOZ_MUST_USE bool
DebugLeaveLexicalEnv(JSContext* cx, BaselineFrame* frame, jsbytecode* pc);
MOZ_MUST_USE bool
PushVarEnv(JSContext* cx, BaselineFrame* frame, HandleScope scope);
MOZ_MUST_USE bool
PopVarEnv(JSContext* cx, BaselineFrame* frame);
MOZ_MUST_USE bool
InitBaselineFrameForOsr(BaselineFrame* frame, InterpreterFrame* interpFrame,
uint32_t numStackValues);
JSObject* CreateDerivedTypedObj(JSContext* cx, HandleObject descr,
HandleObject owner, int32_t offset);
MOZ_MUST_USE bool
Recompile(JSContext* cx);
MOZ_MUST_USE bool
ForcedRecompile(JSContext* cx);
JSString* StringReplace(JSContext* cx, HandleString string, HandleString pattern,
HandleString repl);
MOZ_MUST_USE bool SetDenseOrUnboxedArrayElement(JSContext* cx, HandleObject obj, int32_t index,
HandleValue value, bool strict);
void AssertValidObjectPtr(JSContext* cx, JSObject* obj);
void AssertValidObjectOrNullPtr(JSContext* cx, JSObject* obj);
void AssertValidStringPtr(JSContext* cx, JSString* str);
void AssertValidSymbolPtr(JSContext* cx, JS::Symbol* sym);
void AssertValidValue(JSContext* cx, Value* v);
void MarkValueFromIon(JSRuntime* rt, Value* vp);
void MarkStringFromIon(JSRuntime* rt, JSString** stringp);
void MarkObjectFromIon(JSRuntime* rt, JSObject** objp);
void MarkShapeFromIon(JSRuntime* rt, Shape** shapep);
void MarkObjectGroupFromIon(JSRuntime* rt, ObjectGroup** groupp);
// Helper for generatePreBarrier.
inline void*
IonMarkFunction(MIRType type)
{
switch (type) {
case MIRType::Value:
return JS_FUNC_TO_DATA_PTR(void*, MarkValueFromIon);
case MIRType::String:
return JS_FUNC_TO_DATA_PTR(void*, MarkStringFromIon);
case MIRType::Object:
return JS_FUNC_TO_DATA_PTR(void*, MarkObjectFromIon);
case MIRType::Shape:
return JS_FUNC_TO_DATA_PTR(void*, MarkShapeFromIon);
case MIRType::ObjectGroup:
return JS_FUNC_TO_DATA_PTR(void*, MarkObjectGroupFromIon);
default: MOZ_CRASH();
}
}
bool ObjectIsCallable(JSObject* obj);
bool ObjectIsConstructor(JSObject* obj);
MOZ_MUST_USE bool
ThrowRuntimeLexicalError(JSContext* cx, unsigned errorNumber);
MOZ_MUST_USE bool
ThrowReadOnlyError(JSContext* cx, int32_t index);
MOZ_MUST_USE bool
BaselineThrowUninitializedThis(JSContext* cx, BaselineFrame* frame);
MOZ_MUST_USE bool
ThrowBadDerivedReturn(JSContext* cx, HandleValue v);
MOZ_MUST_USE bool
ThrowObjectCoercible(JSContext* cx, HandleValue v);
MOZ_MUST_USE bool
BaselineGetFunctionThis(JSContext* cx, BaselineFrame* frame, MutableHandleValue res);
MOZ_MUST_USE bool
CheckIsCallable(JSContext* cx, HandleValue v, CheckIsCallableKind kind);
} // namespace jit
} // namespace js
#endif /* jit_VMFunctions_h */
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