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/* -*- Mode: C++; tab-width: 8; indent-tabs-mode: nil; c-basic-offset: 2 -*-
* vim: set ts=8 sts=2 et sw=2 tw=80:
* 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
#include "ctypes/CTypes.h"
#include "js/experimental/CTypes.h" // JS::CTypesActivity{Callback,Type}, JS::InitCTypesClass, JS::SetCTypesActivityCallback, JS::SetCTypesCallbacks
#include "mozilla/CheckedInt.h"
#include "mozilla/MemoryReporting.h"
#include "mozilla/Sprintf.h"
#include "mozilla/TextUtils.h"
#include "mozilla/Vector.h"
#include "mozilla/WrappingOperations.h"
#if defined(XP_UNIX)
# include <errno.h>
#endif
#if defined(XP_WIN)
# include <float.h>
#endif
#if defined(SOLARIS)
# include <ieeefp.h>
#endif
#include <iterator>
#include <limits>
#include <stdint.h>
#include <sys/types.h>
#include <type_traits>
#include "jsapi.h"
#include "jsexn.h"
#include "jsnum.h"
#include "ctypes/Library.h"
#include "gc/GCContext.h"
#include "jit/AtomicOperations.h"
#include "js/Array.h" // JS::GetArrayLength, JS::IsArrayObject, JS::NewArrayObject
#include "js/ArrayBuffer.h" // JS::{IsArrayBufferObject,GetArrayBufferData,GetArrayBuffer{ByteLength,Data}}
#include "js/CallAndConstruct.h" // JS::IsCallable, JS_CallFunctionValue
#include "js/CharacterEncoding.h"
#include "js/experimental/TypedData.h" // JS_GetArrayBufferView{Type,Data}, JS_GetTypedArrayByteLength, JS_IsArrayBufferViewObject, JS_IsTypedArrayObject
#include "js/friend/ErrorMessages.h" // js::GetErrorMessage, JSMSG_*
#include "js/GlobalObject.h" // JS::CurrentGlobalOrNull
#include "js/Object.h" // JS::GetMaybePtrFromReservedSlot, JS::GetReservedSlot, JS::SetReservedSlot
#include "js/PropertyAndElement.h" // JS_DefineFunction, JS_DefineFunctions, JS_DefineProperties, JS_DefineProperty, JS_DefinePropertyById, JS_DefineUCProperty, JS_Enumerate, JS_GetElement, JS_GetProperty, JS_GetPropertyById
#include "js/PropertySpec.h"
#include "js/SharedArrayBuffer.h" // JS::{GetSharedArrayBuffer{ByteLength,Data},IsSharedArrayBufferObject}
#include "js/StableStringChars.h"
#include "js/UniquePtr.h"
#include "js/Utility.h"
#include "js/Vector.h"
#include "util/Text.h"
#include "util/Unicode.h"
#include "util/WindowsWrapper.h"
#include "vm/JSContext.h"
#include "vm/JSFunction.h"
#include "vm/JSObject.h"
#include "gc/GCContext-inl.h"
#include "vm/JSObject-inl.h"
using std::numeric_limits;
using mozilla::CheckedInt;
using mozilla::IsAsciiAlpha;
using mozilla::IsAsciiDigit;
using JS::AutoCheckCannotGC;
using JS::AutoCTypesActivityCallback;
using JS::AutoStableStringChars;
using JS::CTypesActivityType;
namespace js::ctypes {
static bool HasUnpairedSurrogate(const char16_t* chars, size_t nchars,
char16_t* unpaired) {
for (const char16_t* end = chars + nchars; chars != end; chars++) {
char16_t c = *chars;
if (unicode::IsSurrogate(c)) {
chars++;
if (unicode::IsTrailSurrogate(c) || chars == end) {
*unpaired = c;
return true;
}
char16_t c2 = *chars;
if (!unicode::IsTrailSurrogate(c2)) {
*unpaired = c;
return true;
}
}
}
return false;
}
bool ReportErrorIfUnpairedSurrogatePresent(JSContext* cx, JSLinearString* str) {
if (str->hasLatin1Chars()) {
return true;
}
char16_t unpaired;
{
JS::AutoCheckCannotGC nogc;
if (!HasUnpairedSurrogate(str->twoByteChars(nogc), str->length(),
&unpaired)) {
return true;
}
}
char buffer[10];
SprintfLiteral(buffer, "0x%x", unpaired);
JS_ReportErrorNumberASCII(cx, GetErrorMessage, nullptr,
JSMSG_BAD_SURROGATE_CHAR, buffer);
return false;
}
/*******************************************************************************
** JSAPI function prototypes
*******************************************************************************/
// We use an enclosing struct here out of paranoia about the ability of gcc 4.4
// (and maybe 4.5) to correctly compile this if it were a template function.
// See also the comments in dom/workers/Events.cpp (and other adjacent files) by
// the |struct Property| there.
template <JS::IsAcceptableThis Test, JS::NativeImpl Impl>
struct Property {
static bool Fun(JSContext* cx, unsigned argc, JS::Value* vp) {
JS::CallArgs args = JS::CallArgsFromVp(argc, vp);
return JS::CallNonGenericMethod<Test, Impl>(cx, args);
}
};
static bool ConstructAbstract(JSContext* cx, unsigned argc, Value* vp);
namespace CType {
static bool ConstructData(JSContext* cx, unsigned argc, Value* vp);
static bool ConstructBasic(JSContext* cx, HandleObject obj,
const CallArgs& args);
static void Trace(JSTracer* trc, JSObject* obj);
static void Finalize(JS::GCContext* gcx, JSObject* obj);
bool IsCType(HandleValue v);
bool IsCTypeOrProto(HandleValue v);
bool PrototypeGetter(JSContext* cx, const JS::CallArgs& args);
bool NameGetter(JSContext* cx, const JS::CallArgs& args);
bool SizeGetter(JSContext* cx, const JS::CallArgs& args);
bool PtrGetter(JSContext* cx, const JS::CallArgs& args);
static bool CreateArray(JSContext* cx, unsigned argc, Value* vp);
static bool ToString(JSContext* cx, unsigned argc, Value* vp);
static bool ToSource(JSContext* cx, unsigned argc, Value* vp);
/*
* Get the global "ctypes" object.
*
* |obj| must be a CType object.
*
* This function never returns nullptr.
*/
static JSObject* GetGlobalCTypes(JSContext* cx, JSObject* obj);
} // namespace CType
namespace ABI {
bool IsABI(JSObject* obj);
static bool ToSource(JSContext* cx, unsigned argc, Value* vp);
} // namespace ABI
namespace PointerType {
static bool Create(JSContext* cx, unsigned argc, Value* vp);
static bool ConstructData(JSContext* cx, HandleObject obj,
const CallArgs& args);
bool IsPointerType(HandleValue v);
bool IsPointer(HandleValue v);
bool TargetTypeGetter(JSContext* cx, const JS::CallArgs& args);
bool ContentsGetter(JSContext* cx, const JS::CallArgs& args);
bool ContentsSetter(JSContext* cx, const JS::CallArgs& args);
static bool IsNull(JSContext* cx, unsigned argc, Value* vp);
static bool Increment(JSContext* cx, unsigned argc, Value* vp);
static bool Decrement(JSContext* cx, unsigned argc, Value* vp);
// The following is not an instance function, since we don't want to expose
// arbitrary pointer arithmetic at this moment.
static bool OffsetBy(JSContext* cx, const CallArgs& args, int offset,
const char* name);
} // namespace PointerType
namespace ArrayType {
bool IsArrayType(HandleValue v);
bool IsArrayOrArrayType(HandleValue v);
static bool Create(JSContext* cx, unsigned argc, Value* vp);
static bool ConstructData(JSContext* cx, HandleObject obj,
const CallArgs& args);
bool ElementTypeGetter(JSContext* cx, const JS::CallArgs& args);
bool LengthGetter(JSContext* cx, const JS::CallArgs& args);
static bool Getter(JSContext* cx, HandleObject obj, HandleId idval,
MutableHandleValue vp, bool* handled);
static bool Setter(JSContext* cx, HandleObject obj, HandleId idval,
HandleValue v, ObjectOpResult& result, bool* handled);
static bool AddressOfElement(JSContext* cx, unsigned argc, Value* vp);
} // namespace ArrayType
namespace StructType {
bool IsStruct(HandleValue v);
static bool Create(JSContext* cx, unsigned argc, Value* vp);
static bool ConstructData(JSContext* cx, HandleObject obj,
const CallArgs& args);
bool FieldsArrayGetter(JSContext* cx, const JS::CallArgs& args);
enum { SLOT_FIELDNAME };
static bool FieldGetter(JSContext* cx, unsigned argc, Value* vp);
static bool FieldSetter(JSContext* cx, unsigned argc, Value* vp);
static bool AddressOfField(JSContext* cx, unsigned argc, Value* vp);
static bool Define(JSContext* cx, unsigned argc, Value* vp);
} // namespace StructType
namespace FunctionType {
static bool Create(JSContext* cx, unsigned argc, Value* vp);
static bool ConstructData(JSContext* cx, HandleObject typeObj,
HandleObject dataObj, HandleObject fnObj,
HandleObject thisObj, HandleValue errVal);
static bool Call(JSContext* cx, unsigned argc, Value* vp);
bool IsFunctionType(HandleValue v);
bool ArgTypesGetter(JSContext* cx, const JS::CallArgs& args);
bool ReturnTypeGetter(JSContext* cx, const JS::CallArgs& args);
bool ABIGetter(JSContext* cx, const JS::CallArgs& args);
bool IsVariadicGetter(JSContext* cx, const JS::CallArgs& args);
} // namespace FunctionType
namespace CClosure {
static void Trace(JSTracer* trc, JSObject* obj);
static void Finalize(JS::GCContext* gcx, JSObject* obj);
// libffi callback
static void ClosureStub(ffi_cif* cif, void* result, void** args,
void* userData);
struct ArgClosure : public ScriptEnvironmentPreparer::Closure {
ArgClosure(ffi_cif* cifArg, void* resultArg, void** argsArg,
ClosureInfo* cinfoArg)
: cif(cifArg), result(resultArg), args(argsArg), cinfo(cinfoArg) {}
bool operator()(JSContext* cx) override;
ffi_cif* cif;
void* result;
void** args;
ClosureInfo* cinfo;
};
} // namespace CClosure
namespace CData {
static void Finalize(JS::GCContext* gcx, JSObject* obj);
bool ValueGetter(JSContext* cx, const JS::CallArgs& args);
bool ValueSetter(JSContext* cx, const JS::CallArgs& args);
static bool Address(JSContext* cx, unsigned argc, Value* vp);
static bool ReadString(JSContext* cx, unsigned argc, Value* vp);
static bool ReadStringReplaceMalformed(JSContext* cx, unsigned argc, Value* vp);
static bool ReadTypedArray(JSContext* cx, unsigned argc, Value* vp);
static bool ToSource(JSContext* cx, unsigned argc, Value* vp);
static JSString* GetSourceString(JSContext* cx, HandleObject typeObj,
void* data);
bool ErrnoGetter(JSContext* cx, const JS::CallArgs& args);
#if defined(XP_WIN)
bool LastErrorGetter(JSContext* cx, const JS::CallArgs& args);
#endif // defined(XP_WIN)
} // namespace CData
namespace CDataFinalizer {
/*
* Attach a C function as a finalizer to a JS object.
*
* This function is available from JS as |ctypes.withFinalizer|.
*
* JavaScript signature:
* function(CData, CData): CDataFinalizer
* value finalizer finalizable
*
* Where |finalizer| is a one-argument function taking a value
* with the same type as |value|.
*/
static bool Construct(JSContext* cx, unsigned argc, Value* vp);
/*
* Private data held by |CDataFinalizer|.
*
* See also |enum CDataFinalizerSlot| for the slots of
* |CDataFinalizer|.
*
* Note: the private data may be nullptr, if |dispose|, |forget| or the
* finalizer has already been called.
*/
struct Private {
/*
* The C data to pass to the code.
* Finalization/|dispose|/|forget| release this memory.
*/
void* cargs;
/*
* The total size of the buffer pointed by |cargs|
*/
size_t cargs_size;
/*
* Low-level signature information.
* Finalization/|dispose|/|forget| release this memory.
*/
ffi_cif CIF;
/*
* The C function to invoke during finalization.
* Do not deallocate this.
*/
uintptr_t code;
/*
* A buffer for holding the return value.
* Finalization/|dispose|/|forget| release this memory.
*/
void* rvalue;
};
/*
* Methods of instances of |CDataFinalizer|
*/
namespace Methods {
static bool Dispose(JSContext* cx, unsigned argc, Value* vp);
static bool Forget(JSContext* cx, unsigned argc, Value* vp);
static bool ReadString(JSContext* cx, unsigned argc, Value* vp);
static bool ReadTypedArray(JSContext* cx, unsigned argc, Value* vp);
static bool ToSource(JSContext* cx, unsigned argc, Value* vp);
static bool ToString(JSContext* cx, unsigned argc, Value* vp);
} // namespace Methods
/*
* Utility functions
*
* @return true if |obj| is a CDataFinalizer, false otherwise.
*/
static bool IsCDataFinalizer(JSObject* obj);
/*
* Clean up the finalization information of a CDataFinalizer.
*
* Used by |Finalize|, |Dispose| and |Forget|.
*
* @param p The private information of the CDataFinalizer. If nullptr,
* this function does nothing.
* @param obj Either nullptr, if the object should not be cleaned up (i.e.
* during finalization) or a CDataFinalizer JSObject. Always use nullptr
* if you are calling from a finalizer.
*/
static void Cleanup(Private* p, JSObject* obj);
/*
* Perform the actual call to the finalizer code.
*/
static void CallFinalizer(CDataFinalizer::Private* p, int* errnoStatus,
int32_t* lastErrorStatus);
/*
* Return the CType of a CDataFinalizer object, or nullptr if the object
* has been cleaned-up already.
*/
static JSObject* GetCType(JSContext* cx, JSObject* obj);
/*
* Perform finalization of a |CDataFinalizer|
*/
static void Finalize(JS::GCContext* gcx, JSObject* obj);
/*
* Return the Value contained by this finalizer.
*
* Note that the Value is actually not recorded, but converted back from C.
*/
static bool GetValue(JSContext* cx, JSObject* obj, MutableHandleValue result);
} // namespace CDataFinalizer
// Int64Base provides functions common to Int64 and UInt64.
namespace Int64Base {
JSObject* Construct(JSContext* cx, HandleObject proto, uint64_t data,
bool isUnsigned);
uint64_t GetInt(JSObject* obj);
bool ToString(JSContext* cx, JSObject* obj, const CallArgs& args,
bool isUnsigned);
bool ToSource(JSContext* cx, JSObject* obj, const CallArgs& args,
bool isUnsigned);
static void Finalize(JS::GCContext* gcx, JSObject* obj);
} // namespace Int64Base
namespace Int64 {
static bool Construct(JSContext* cx, unsigned argc, Value* vp);
static bool ToString(JSContext* cx, unsigned argc, Value* vp);
static bool ToSource(JSContext* cx, unsigned argc, Value* vp);
static bool Compare(JSContext* cx, unsigned argc, Value* vp);
static bool Lo(JSContext* cx, unsigned argc, Value* vp);
static bool Hi(JSContext* cx, unsigned argc, Value* vp);
static bool Join(JSContext* cx, unsigned argc, Value* vp);
} // namespace Int64
namespace UInt64 {
static bool Construct(JSContext* cx, unsigned argc, Value* vp);
static bool ToString(JSContext* cx, unsigned argc, Value* vp);
static bool ToSource(JSContext* cx, unsigned argc, Value* vp);
static bool Compare(JSContext* cx, unsigned argc, Value* vp);
static bool Lo(JSContext* cx, unsigned argc, Value* vp);
static bool Hi(JSContext* cx, unsigned argc, Value* vp);
static bool Join(JSContext* cx, unsigned argc, Value* vp);
} // namespace UInt64
/*******************************************************************************
** JSClass definitions and initialization functions
*******************************************************************************/
// Class representing the 'ctypes' object itself. This exists to contain the
// JS::CTypesCallbacks set of function pointers.
static const JSClass sCTypesGlobalClass = {
"ctypes", JSCLASS_HAS_RESERVED_SLOTS(CTYPESGLOBAL_SLOTS)};
static const JSClass sCABIClass = {"CABI",
JSCLASS_HAS_RESERVED_SLOTS(CABI_SLOTS)};
// Class representing ctypes.{C,Pointer,Array,Struct,Function}Type.prototype.
// This exists to give said prototypes a class of "CType", and to provide
// reserved slots for stashing various other prototype objects.
static const JSClassOps sCTypeProtoClassOps = {
nullptr, // addProperty
nullptr, // delProperty
nullptr, // enumerate
nullptr, // newEnumerate
nullptr, // resolve
nullptr, // mayResolve
nullptr, // finalize
ConstructAbstract, // call
ConstructAbstract, // construct
nullptr, // trace
};
static const JSClass sCTypeProtoClass = {
"CType", JSCLASS_HAS_RESERVED_SLOTS(CTYPEPROTO_SLOTS),
&sCTypeProtoClassOps};
// Class representing ctypes.CData.prototype and the 'prototype' properties
// of CTypes. This exists to give said prototypes a class of "CData".
static const JSClass sCDataProtoClass = {"CData", 0};
static const JSClassOps sCTypeClassOps = {
nullptr, // addProperty
nullptr, // delProperty
nullptr, // enumerate
nullptr, // newEnumerate
nullptr, // resolve
nullptr, // mayResolve
CType::Finalize, // finalize
CType::ConstructData, // call
CType::ConstructData, // construct
CType::Trace, // trace
};
static const JSClass sCTypeClass = {
"CType",
JSCLASS_HAS_RESERVED_SLOTS(CTYPE_SLOTS) | JSCLASS_FOREGROUND_FINALIZE,
&sCTypeClassOps};
static const JSClassOps sCDataClassOps = {
nullptr, // addProperty
nullptr, // delProperty
nullptr, // enumerate
nullptr, // newEnumerate
nullptr, // resolve
nullptr, // mayResolve
CData::Finalize, // finalize
FunctionType::Call, // call
FunctionType::Call, // construct
nullptr, // trace
};
static const JSClass sCDataClass = {
"CData",
JSCLASS_HAS_RESERVED_SLOTS(CDATA_SLOTS) | JSCLASS_FOREGROUND_FINALIZE,
&sCDataClassOps};
static const JSClassOps sCClosureClassOps = {
nullptr, // addProperty
nullptr, // delProperty
nullptr, // enumerate
nullptr, // newEnumerate
nullptr, // resolve
nullptr, // mayResolve
CClosure::Finalize, // finalize
nullptr, // call
nullptr, // construct
CClosure::Trace, // trace
};
static const JSClass sCClosureClass = {
"CClosure",
JSCLASS_HAS_RESERVED_SLOTS(CCLOSURE_SLOTS) | JSCLASS_FOREGROUND_FINALIZE,
&sCClosureClassOps};
/*
* Class representing the prototype of CDataFinalizer.
*/
static const JSClass sCDataFinalizerProtoClass = {"CDataFinalizer", 0};
/*
* Class representing instances of CDataFinalizer.
*
* Instances of CDataFinalizer have both private data (with type
* |CDataFinalizer::Private|) and slots (see |CDataFinalizerSlots|).
*/
static const JSClassOps sCDataFinalizerClassOps = {
nullptr, // addProperty
nullptr, // delProperty
nullptr, // enumerate
nullptr, // newEnumerate
nullptr, // resolve
nullptr, // mayResolve
CDataFinalizer::Finalize, // finalize
nullptr, // call
nullptr, // construct
nullptr, // trace
};
static const JSClass sCDataFinalizerClass = {
"CDataFinalizer",
JSCLASS_HAS_RESERVED_SLOTS(CDATAFINALIZER_SLOTS) |
JSCLASS_FOREGROUND_FINALIZE,
&sCDataFinalizerClassOps};
#define CTYPESFN_FLAGS (JSPROP_ENUMERATE | JSPROP_READONLY | JSPROP_PERMANENT)
#define CTYPESCTOR_FLAGS (CTYPESFN_FLAGS | JSFUN_CONSTRUCTOR)
#define CTYPESACC_FLAGS (JSPROP_ENUMERATE | JSPROP_PERMANENT)
#define CABIFN_FLAGS (JSPROP_READONLY | JSPROP_PERMANENT)
#define CDATAFN_FLAGS (JSPROP_READONLY | JSPROP_PERMANENT)
#define CDATAFINALIZERFN_FLAGS (JSPROP_READONLY | JSPROP_PERMANENT)
static const JSPropertySpec sCTypeProps[] = {
JS_PSG("name", (Property<CType::IsCType, CType::NameGetter>::Fun),
CTYPESACC_FLAGS),
JS_PSG("size", (Property<CType::IsCType, CType::SizeGetter>::Fun),
CTYPESACC_FLAGS),
JS_PSG("ptr", (Property<CType::IsCType, CType::PtrGetter>::Fun),
CTYPESACC_FLAGS),
JS_PSG("prototype",
(Property<CType::IsCTypeOrProto, CType::PrototypeGetter>::Fun),
CTYPESACC_FLAGS),
JS_PS_END};
static const JSFunctionSpec sCTypeFunctions[] = {
JS_FN("array", CType::CreateArray, 0, CTYPESFN_FLAGS),
JS_FN("toString", CType::ToString, 0, CTYPESFN_FLAGS),
JS_FN("toSource", CType::ToSource, 0, CTYPESFN_FLAGS), JS_FS_END};
static const JSFunctionSpec sCABIFunctions[] = {
JS_FN("toSource", ABI::ToSource, 0, CABIFN_FLAGS),
JS_FN("toString", ABI::ToSource, 0, CABIFN_FLAGS), JS_FS_END};
static const JSPropertySpec sCDataProps[] = {
JS_PSGS("value", (Property<CData::IsCData, CData::ValueGetter>::Fun),
(Property<CData::IsCData, CData::ValueSetter>::Fun),
JSPROP_PERMANENT),
JS_PS_END};
static const JSFunctionSpec sCDataFunctions[] = {
JS_FN("address", CData::Address, 0, CDATAFN_FLAGS),
JS_FN("readString", CData::ReadString, 0, CDATAFN_FLAGS),
JS_FN("readStringReplaceMalformed", CData::ReadStringReplaceMalformed, 0,
CDATAFN_FLAGS),
JS_FN("readTypedArray", CData::ReadTypedArray, 0, CDATAFN_FLAGS),
JS_FN("toSource", CData::ToSource, 0, CDATAFN_FLAGS),
JS_FN("toString", CData::ToSource, 0, CDATAFN_FLAGS),
JS_FS_END};
static const JSFunctionSpec sCDataFinalizerFunctions[] = {
JS_FN("dispose", CDataFinalizer::Methods::Dispose, 0,
CDATAFINALIZERFN_FLAGS),
JS_FN("forget", CDataFinalizer::Methods::Forget, 0, CDATAFINALIZERFN_FLAGS),
JS_FN("readString", CDataFinalizer::Methods::ReadString, 0,
CDATAFINALIZERFN_FLAGS),
JS_FN("readTypedArray", CDataFinalizer::Methods::ReadTypedArray, 0,
CDATAFINALIZERFN_FLAGS),
JS_FN("toString", CDataFinalizer::Methods::ToString, 0,
CDATAFINALIZERFN_FLAGS),
JS_FN("toSource", CDataFinalizer::Methods::ToSource, 0,
CDATAFINALIZERFN_FLAGS),
JS_FS_END};
static const JSFunctionSpec sPointerFunction =
JS_FN("PointerType", PointerType::Create, 1, CTYPESCTOR_FLAGS);
static const JSPropertySpec sPointerProps[] = {
JS_PSG("targetType",
(Property<PointerType::IsPointerType,
PointerType::TargetTypeGetter>::Fun),
CTYPESACC_FLAGS),
JS_PS_END};
static const JSFunctionSpec sPointerInstanceFunctions[] = {
JS_FN("isNull", PointerType::IsNull, 0, CTYPESFN_FLAGS),
JS_FN("increment", PointerType::Increment, 0, CTYPESFN_FLAGS),
JS_FN("decrement", PointerType::Decrement, 0, CTYPESFN_FLAGS), JS_FS_END};
static const JSPropertySpec sPointerInstanceProps[] = {
JS_PSGS(
"contents",
(Property<PointerType::IsPointer, PointerType::ContentsGetter>::Fun),
(Property<PointerType::IsPointer, PointerType::ContentsSetter>::Fun),
JSPROP_PERMANENT),
JS_PS_END};
static const JSFunctionSpec sArrayFunction =
JS_FN("ArrayType", ArrayType::Create, 1, CTYPESCTOR_FLAGS);
static const JSPropertySpec sArrayProps[] = {
JS_PSG(
"elementType",
(Property<ArrayType::IsArrayType, ArrayType::ElementTypeGetter>::Fun),
CTYPESACC_FLAGS),
JS_PSG(
"length",
(Property<ArrayType::IsArrayOrArrayType, ArrayType::LengthGetter>::Fun),
CTYPESACC_FLAGS),
JS_PS_END};
static const JSFunctionSpec sArrayInstanceFunctions[] = {
JS_FN("addressOfElement", ArrayType::AddressOfElement, 1, CDATAFN_FLAGS),
JS_FS_END};
static const JSPropertySpec sArrayInstanceProps[] = {
JS_PSG(
"length",
(Property<ArrayType::IsArrayOrArrayType, ArrayType::LengthGetter>::Fun),
JSPROP_PERMANENT),
JS_PS_END};
static const JSFunctionSpec sStructFunction =
JS_FN("StructType", StructType::Create, 2, CTYPESCTOR_FLAGS);
static const JSPropertySpec sStructProps[] = {
JS_PSG("fields",
(Property<StructType::IsStruct, StructType::FieldsArrayGetter>::Fun),
CTYPESACC_FLAGS),
JS_PS_END};
static const JSFunctionSpec sStructFunctions[] = {
JS_FN("define", StructType::Define, 1, CDATAFN_FLAGS), JS_FS_END};
static const JSFunctionSpec sStructInstanceFunctions[] = {
JS_FN("addressOfField", StructType::AddressOfField, 1, CDATAFN_FLAGS),
JS_FS_END};
static const JSFunctionSpec sFunctionFunction =
JS_FN("FunctionType", FunctionType::Create, 2, CTYPESCTOR_FLAGS);
static const JSPropertySpec sFunctionProps[] = {
JS_PSG("argTypes",
(Property<FunctionType::IsFunctionType,
FunctionType::ArgTypesGetter>::Fun),
CTYPESACC_FLAGS),
JS_PSG("returnType",
(Property<FunctionType::IsFunctionType,
FunctionType::ReturnTypeGetter>::Fun),
CTYPESACC_FLAGS),
JS_PSG(
"abi",
(Property<FunctionType::IsFunctionType, FunctionType::ABIGetter>::Fun),
CTYPESACC_FLAGS),
JS_PSG("isVariadic",
(Property<FunctionType::IsFunctionType,
FunctionType::IsVariadicGetter>::Fun),
CTYPESACC_FLAGS),
JS_PS_END};
static const JSFunctionSpec sFunctionInstanceFunctions[] = {
JS_FN("call", js::fun_call, 1, CDATAFN_FLAGS),
JS_FN("apply", js::fun_apply, 2, CDATAFN_FLAGS), JS_FS_END};
static const JSClass sInt64ProtoClass = {"Int64", 0};
static const JSClass sUInt64ProtoClass = {"UInt64", 0};
static const JSClassOps sInt64ClassOps = {
nullptr, // addProperty
nullptr, // delProperty
nullptr, // enumerate
nullptr, // newEnumerate
nullptr, // resolve
nullptr, // mayResolve
Int64Base::Finalize, // finalize
nullptr, // call
nullptr, // construct
nullptr, // trace
};
static const JSClass sInt64Class = {
"Int64",
JSCLASS_HAS_RESERVED_SLOTS(INT64_SLOTS) | JSCLASS_FOREGROUND_FINALIZE,
&sInt64ClassOps};
static const JSClass sUInt64Class = {
"UInt64",
JSCLASS_HAS_RESERVED_SLOTS(INT64_SLOTS) | JSCLASS_FOREGROUND_FINALIZE,
&sInt64ClassOps};
static const JSFunctionSpec sInt64StaticFunctions[] = {
JS_FN("compare", Int64::Compare, 2, CTYPESFN_FLAGS),
JS_FN("lo", Int64::Lo, 1, CTYPESFN_FLAGS),
JS_FN("hi", Int64::Hi, 1, CTYPESFN_FLAGS),
// "join" is defined specially; see InitInt64Class.
JS_FS_END};
static const JSFunctionSpec sUInt64StaticFunctions[] = {
JS_FN("compare", UInt64::Compare, 2, CTYPESFN_FLAGS),
JS_FN("lo", UInt64::Lo, 1, CTYPESFN_FLAGS),
JS_FN("hi", UInt64::Hi, 1, CTYPESFN_FLAGS),
// "join" is defined specially; see InitInt64Class.
JS_FS_END};
static const JSFunctionSpec sInt64Functions[] = {
JS_FN("toString", Int64::ToString, 0, CTYPESFN_FLAGS),
JS_FN("toSource", Int64::ToSource, 0, CTYPESFN_FLAGS), JS_FS_END};
static const JSFunctionSpec sUInt64Functions[] = {
JS_FN("toString", UInt64::ToString, 0, CTYPESFN_FLAGS),
JS_FN("toSource", UInt64::ToSource, 0, CTYPESFN_FLAGS), JS_FS_END};
static const JSPropertySpec sModuleProps[] = {
JS_PSG("errno", (Property<IsCTypesGlobal, CData::ErrnoGetter>::Fun),
JSPROP_PERMANENT),
#if defined(XP_WIN)
JS_PSG("winLastError",
(Property<IsCTypesGlobal, CData::LastErrorGetter>::Fun),
JSPROP_PERMANENT),
#endif // defined(XP_WIN)
JS_PS_END};
static const JSFunctionSpec sModuleFunctions[] = {
JS_FN("CDataFinalizer", CDataFinalizer::Construct, 2, CTYPESFN_FLAGS),
JS_FN("open", Library::Open, 1, CTYPESFN_FLAGS),
JS_FN("cast", CData::Cast, 2, CTYPESFN_FLAGS),
JS_FN("getRuntime", CData::GetRuntime, 1, CTYPESFN_FLAGS),
JS_FN("libraryName", Library::Name, 1, CTYPESFN_FLAGS),
JS_FS_END};
// Wrapper for arrays, to intercept indexed gets/sets.
class CDataArrayProxyHandler : public ForwardingProxyHandler {
public:
static const CDataArrayProxyHandler singleton;
static const char family;
constexpr CDataArrayProxyHandler() : ForwardingProxyHandler(&family) {}
bool get(JSContext* cx, HandleObject proxy, HandleValue receiver, HandleId id,
MutableHandleValue vp) const override;
bool set(JSContext* cx, HandleObject proxy, HandleId id, HandleValue v,
HandleValue receiver, ObjectOpResult& result) const override;
};
const CDataArrayProxyHandler CDataArrayProxyHandler::singleton;
const char CDataArrayProxyHandler::family = 0;
bool CDataArrayProxyHandler::get(JSContext* cx, HandleObject proxy,
HandleValue receiver, HandleId id,
MutableHandleValue vp) const {
RootedObject target(cx, proxy->as<ProxyObject>().target());
bool handled = false;
if (!ArrayType::Getter(cx, target, id, vp, &handled)) {
return false;
}
if (handled) {
return true;
}
return ForwardingProxyHandler::get(cx, proxy, receiver, id, vp);
}
bool CDataArrayProxyHandler::set(JSContext* cx, HandleObject proxy, HandleId id,
HandleValue v, HandleValue receiver,
ObjectOpResult& result) const {
RootedObject target(cx, proxy->as<ProxyObject>().target());
bool handled = false;
if (!ArrayType::Setter(cx, target, id, v, result, &handled)) {
return false;
}
if (handled) {
return true;
}
return ForwardingProxyHandler::set(cx, proxy, id, v, receiver, result);
}
static JSObject* MaybeUnwrapArrayWrapper(JSObject* obj) {
if (obj->is<ProxyObject>() &&
obj->as<ProxyObject>().handler() == &CDataArrayProxyHandler::singleton) {
return obj->as<ProxyObject>().target();
}
return obj;
}
static MOZ_ALWAYS_INLINE JSString* NewUCString(JSContext* cx,
const AutoStringChars&& from) {
return JS_NewUCStringCopyN(cx, from.begin(), from.length());
}
/*
* Return a size rounded up to a multiple of a power of two.
*
* Note: |align| must be a power of 2.
*/
static MOZ_ALWAYS_INLINE size_t Align(size_t val, size_t align) {
// Ensure that align is a power of two.
MOZ_ASSERT(align != 0 && (align & (align - 1)) == 0);
return ((val - 1) | (align - 1)) + 1;
}
static ABICode GetABICode(JSObject* obj) {
// make sure we have an object representing a CABI class,
// and extract the enumerated class type from the reserved slot.
if (!obj->hasClass(&sCABIClass)) {
return INVALID_ABI;
}
Value result = JS::GetReservedSlot(obj, SLOT_ABICODE);
return ABICode(result.toInt32());
}
static const JSErrorFormatString ErrorFormatString[CTYPESERR_LIMIT] = {
#define MSG_DEF(name, count, exception, format) \
{#name, format, count, exception},
#include "ctypes/ctypes.msg"
#undef MSG_DEF
};
static const JSErrorFormatString* GetErrorMessage(void* userRef,
const unsigned errorNumber) {
if (0 < errorNumber && errorNumber < CTYPESERR_LIMIT) {
return &ErrorFormatString[errorNumber];
}
return nullptr;
}
static JS::UniqueChars EncodeUTF8(JSContext* cx, AutoString& str) {
RootedString string(cx, NewUCString(cx, str.finish()));
if (!string) {
return nullptr;
}
return JS_EncodeStringToUTF8(cx, string);
}
static const char* CTypesToSourceForError(JSContext* cx, HandleValue val,
JS::UniqueChars& bytes) {
if (val.isObject()) {
RootedObject obj(cx, &val.toObject());
if (CType::IsCType(obj) || CData::IsCDataMaybeUnwrap(&obj)) {
RootedValue v(cx, ObjectValue(*obj));
RootedString str(cx, JS_ValueToSource(cx, v));
bytes = JS_EncodeStringToUTF8(cx, str);
return bytes.get();
}
}
return ValueToSourceForError(cx, val, bytes);
}
static void BuildCStyleFunctionTypeSource(JSContext* cx, HandleObject typeObj,
HandleString nameStr,
unsigned ptrCount,
AutoString& source);
static void BuildCStyleTypeSource(JSContext* cx, JSObject* typeObj_,
AutoString& source) {
RootedObject typeObj(cx, typeObj_);
MOZ_ASSERT(CType::IsCType(typeObj));
switch (CType::GetTypeCode(typeObj)) {
#define BUILD_SOURCE(name, fromType, ffiType) \
case TYPE_##name: \
AppendString(cx, source, #name); \
break;
CTYPES_FOR_EACH_TYPE(BUILD_SOURCE)
#undef BUILD_SOURCE
case TYPE_void_t:
AppendString(cx, source, "void");
break;
case TYPE_pointer: {
unsigned ptrCount = 0;
TypeCode type;
RootedObject baseTypeObj(cx, typeObj);
do {
baseTypeObj = PointerType::GetBaseType(baseTypeObj);
ptrCount++;
type = CType::GetTypeCode(baseTypeObj);
} while (type == TYPE_pointer || type == TYPE_array);
if (type == TYPE_function) {
BuildCStyleFunctionTypeSource(cx, baseTypeObj, nullptr, ptrCount,
source);
break;
}
BuildCStyleTypeSource(cx, baseTypeObj, source);
AppendChars(source, '*', ptrCount);
break;
}
case TYPE_struct: {
RootedString name(cx, CType::GetName(cx, typeObj));
AppendString(cx, source, "struct ");
AppendString(cx, source, name);
break;
}
case TYPE_function:
BuildCStyleFunctionTypeSource(cx, typeObj, nullptr, 0, source);
break;
case TYPE_array:
MOZ_CRASH("TYPE_array shouldn't appear in function type");
}
}
static void BuildCStyleFunctionTypeSource(JSContext* cx, HandleObject typeObj,
HandleString nameStr,
unsigned ptrCount,
AutoString& source) {
MOZ_ASSERT(CType::IsCType(typeObj));
FunctionInfo* fninfo = FunctionType::GetFunctionInfo(typeObj);
BuildCStyleTypeSource(cx, fninfo->mReturnType, source);
AppendString(cx, source, " ");
if (nameStr) {
MOZ_ASSERT(ptrCount == 0);
AppendString(cx, source, nameStr);
} else if (ptrCount) {
AppendString(cx, source, "(");
AppendChars(source, '*', ptrCount);
AppendString(cx, source, ")");
}
AppendString(cx, source, "(");
if (fninfo->mArgTypes.length() > 0) {
for (size_t i = 0; i < fninfo->mArgTypes.length(); ++i) {
BuildCStyleTypeSource(cx, fninfo->mArgTypes[i], source);
if (i != fninfo->mArgTypes.length() - 1 || fninfo->mIsVariadic) {
AppendString(cx, source, ", ");
}
}
if (fninfo->mIsVariadic) {
AppendString(cx, source, "...");
}
}
AppendString(cx, source, ")");
}
static void BuildFunctionTypeSource(JSContext* cx, HandleObject funObj,
AutoString& source) {
MOZ_ASSERT(CData::IsCData(funObj) || CType::IsCType(funObj));
if (CData::IsCData(funObj)) {
Value slot = JS::GetReservedSlot(funObj, SLOT_REFERENT);
if (!slot.isUndefined() && Library::IsLibrary(&slot.toObject())) {
slot = JS::GetReservedSlot(funObj, SLOT_FUNNAME);
MOZ_ASSERT(!slot.isUndefined());
RootedObject typeObj(cx, CData::GetCType(funObj));
RootedObject baseTypeObj(cx, PointerType::GetBaseType(typeObj));
RootedString nameStr(cx, slot.toString());
BuildCStyleFunctionTypeSource(cx, baseTypeObj, nameStr, 0, source);
return;
}
}
RootedValue funVal(cx, ObjectValue(*funObj));
RootedString funcStr(cx, JS_ValueToSource(cx, funVal));
if (!funcStr) {
JS_ClearPendingException(cx);
AppendString(cx, source, "<<error converting function to string>>");
return;
}
AppendString(cx, source, funcStr);
}
enum class ConversionType {
Argument = 0,
Construct,
Finalizer,
Return,
Setter
};
static void BuildConversionPosition(JSContext* cx, ConversionType convType,
HandleObject funObj, unsigned argIndex,
AutoString& source) {
switch (convType) {
case ConversionType::Argument: {
MOZ_ASSERT(funObj);
AppendString(cx, source, " at argument ");
AppendUInt(source, argIndex + 1);
AppendString(cx, source, " of ");
BuildFunctionTypeSource(cx, funObj, source);
break;
}
case ConversionType::Finalizer:
MOZ_ASSERT(funObj);
AppendString(cx, source, " at argument 1 of ");
BuildFunctionTypeSource(cx, funObj, source);
break;
case ConversionType::Return:
MOZ_ASSERT(funObj);
AppendString(cx, source, " at the return value of ");
BuildFunctionTypeSource(cx, funObj, source);
break;
default:
MOZ_ASSERT(!funObj);
break;
}
}
static JSLinearString* GetFieldName(HandleObject structObj,
unsigned fieldIndex) {
const FieldInfoHash* fields = StructType::GetFieldInfo(structObj);
for (FieldInfoHash::Range r = fields->all(); !r.empty(); r.popFront()) {
if (r.front().value().mIndex == fieldIndex) {
return (&r.front())->key();
}
}
return nullptr;
}
static void BuildTypeSource(JSContext* cx, JSObject* typeObj_, bool makeShort,
AutoString& result);
static JS::UniqueChars TypeSourceForError(JSContext* cx, JSObject* typeObj) {
AutoString source;
BuildTypeSource(cx, typeObj, true, source);
if (!source) {
return nullptr;
}
return EncodeUTF8(cx, source);
}
static JS::UniqueChars FunctionTypeSourceForError(JSContext* cx,
HandleObject funObj) {
AutoString funSource;
BuildFunctionTypeSource(cx, funObj, funSource);
if (!funSource) {
return nullptr;
}
return EncodeUTF8(cx, funSource);
}
static JS::UniqueChars ConversionPositionForError(JSContext* cx,
ConversionType convType,
HandleObject funObj,
unsigned argIndex) {
AutoString posSource;
BuildConversionPosition(cx, convType, funObj, argIndex, posSource);
if (!posSource) {
return nullptr;
}
return EncodeUTF8(cx, posSource);
}
class IndexCString final {
char indexStr[21]; // space for UINT64_MAX plus terminating null
static_assert(sizeof(size_t) <= 8, "index array too small");
public:
explicit IndexCString(size_t index) {
SprintfLiteral(indexStr, "%zu", index);
}
const char* get() const { return indexStr; }
};
static bool ConvError(JSContext* cx, const char* expectedStr,
HandleValue actual, ConversionType convType,
HandleObject funObj = nullptr, unsigned argIndex = 0,
HandleObject arrObj = nullptr, unsigned arrIndex = 0) {
JS::UniqueChars valBytes;
const char* valStr = CTypesToSourceForError(cx, actual, valBytes);
if (!valStr) {
return false;
}
if (arrObj) {
MOZ_ASSERT(CType::IsCType(arrObj));
switch (CType::GetTypeCode(arrObj)) {
case TYPE_array: {
MOZ_ASSERT(!funObj);
IndexCString indexStr(arrIndex);
JS::UniqueChars arrStr = TypeSourceForError(cx, arrObj);
if (!arrStr) {
return false;
}
JS_ReportErrorNumberUTF8(cx, GetErrorMessage, nullptr,
CTYPESMSG_CONV_ERROR_ARRAY, valStr,
indexStr.get(), arrStr.get());
break;
}
case TYPE_struct: {
RootedString name(cx, GetFieldName(arrObj, arrIndex));
MOZ_ASSERT(name);
JS::UniqueChars nameStr = JS_EncodeStringToUTF8(cx, name);
if (!nameStr) {
return false;
}
JS::UniqueChars structStr = TypeSourceForError(cx, arrObj);
if (!structStr) {
return false;
}
JS::UniqueChars posStr;
if (funObj) {
posStr = ConversionPositionForError(cx, convType, funObj, argIndex);
if (!posStr) {
return false;
}
}
JS_ReportErrorNumberUTF8(cx, GetErrorMessage, nullptr,
CTYPESMSG_CONV_ERROR_STRUCT, valStr,
nameStr.get(), expectedStr, structStr.get(),
(posStr ? posStr.get() : ""));
break;
}
default:
MOZ_CRASH("invalid arrObj value");
}
return false;
}
switch (convType) {
case ConversionType::Argument: {
MOZ_ASSERT(funObj);
IndexCString indexStr(argIndex + 1);
JS::UniqueChars funStr = FunctionTypeSourceForError(cx, funObj);
if (!funStr) {
return false;
}
JS_ReportErrorNumberUTF8(cx, GetErrorMessage, nullptr,
CTYPESMSG_CONV_ERROR_ARG, valStr, indexStr.get(),
funStr.get());
break;
}
case ConversionType::Finalizer: {
MOZ_ASSERT(funObj);
JS::UniqueChars funStr = FunctionTypeSourceForError(cx, funObj);
if (!funStr) {
return false;
}
JS_ReportErrorNumberUTF8(cx, GetErrorMessage, nullptr,
CTYPESMSG_CONV_ERROR_FIN, valStr, funStr.get());
break;
}
case ConversionType::Return: {
MOZ_ASSERT(funObj);
JS::UniqueChars funStr = FunctionTypeSourceForError(cx, funObj);
if (!funStr) {
return false;
}
JS_ReportErrorNumberUTF8(cx, GetErrorMessage, nullptr,
CTYPESMSG_CONV_ERROR_RET, valStr, funStr.get());
break;
}
case ConversionType::Setter:
case ConversionType::Construct:
MOZ_ASSERT(!funObj);
JS_ReportErrorNumberUTF8(cx, GetErrorMessage, nullptr,
CTYPESMSG_CONV_ERROR_SET, valStr, expectedStr);
break;
}
return false;
}
static bool ConvError(JSContext* cx, HandleObject expectedType,
HandleValue actual, ConversionType convType,
HandleObject funObj = nullptr, unsigned argIndex = 0,
HandleObject arrObj = nullptr, unsigned arrIndex = 0) {
MOZ_ASSERT(CType::IsCType(expectedType));
JS::UniqueChars expectedStr = TypeSourceForError(cx, expectedType);
if (!expectedStr) {
return false;
}
return ConvError(cx, expectedStr.get(), actual, convType, funObj, argIndex,
arrObj, arrIndex);
}
static bool ArgumentConvError(JSContext* cx, HandleValue actual,
const char* funStr, unsigned argIndex) {
MOZ_ASSERT(JS::StringIsASCII(funStr));
JS::UniqueChars valBytes;
const char* valStr = CTypesToSourceForError(cx, actual, valBytes);
if (!valStr) {
return false;
}
IndexCString indexStr(argIndex + 1);
JS_ReportErrorNumberUTF8(cx, GetErrorMessage, nullptr,
CTYPESMSG_CONV_ERROR_ARG, valStr, indexStr.get(),
funStr);
return false;
}
static bool ArgumentLengthError(JSContext* cx, const char* fun,
const char* count, const char* s) {
JS_ReportErrorNumberUTF8(cx, GetErrorMessage, nullptr,
CTYPESMSG_WRONG_ARG_LENGTH, fun, count, s);
return false;
}
static bool ArrayLengthMismatch(JSContext* cx, size_t expectedLength,
HandleObject arrObj, size_t actualLength,
HandleValue actual, ConversionType convType) {
MOZ_ASSERT(arrObj && CType::IsCType(arrObj));
JS::UniqueChars valBytes;
const char* valStr = CTypesToSourceForError(cx, actual, valBytes);
if (!valStr) {
return false;
}
IndexCString expectedLengthStr(expectedLength);
IndexCString actualLengthStr(actualLength);
JS::UniqueChars arrStr = TypeSourceForError(cx, arrObj);
if (!arrStr) {
return false;
}
JS_ReportErrorNumberUTF8(cx, GetErrorMessage, nullptr,
CTYPESMSG_ARRAY_MISMATCH, valStr, arrStr.get(),
expectedLengthStr.get(), actualLengthStr.get());
return false;
}
static bool ArrayLengthOverflow(JSContext* cx, unsigned expectedLength,
HandleObject arrObj, unsigned actualLength,
HandleValue actual, ConversionType convType) {
MOZ_ASSERT(arrObj && CType::IsCType(arrObj));
JS::UniqueChars valBytes;
const char* valStr = CTypesToSourceForError(cx, actual, valBytes);
if (!valStr) {
return false;
}
IndexCString expectedLengthStr(expectedLength);
IndexCString actualLengthStr(actualLength);
JS::UniqueChars arrStr = TypeSourceForError(cx, arrObj);
if (!arrStr) {
return false;
}
JS_ReportErrorNumberUTF8(cx, GetErrorMessage, nullptr,
CTYPESMSG_ARRAY_OVERFLOW, valStr, arrStr.get(),
expectedLengthStr.get(), actualLengthStr.get());
return false;
}
static bool ArgumentRangeMismatch(JSContext* cx, const char* func,
const char* range) {
JS_ReportErrorNumberASCII(cx, GetErrorMessage, nullptr,
CTYPESMSG_ARG_RANGE_MISMATCH, func, range);
return false;
}
static bool ArgumentTypeMismatch(JSContext* cx, const char* arg,
const char* func, const char* type) {
JS_ReportErrorNumberASCII(cx, GetErrorMessage, nullptr,
CTYPESMSG_ARG_TYPE_MISMATCH, arg, func, type);
return false;
}
static bool CannotConstructError(JSContext* cx, const char* type) {
JS_ReportErrorNumberASCII(cx, GetErrorMessage, nullptr,
CTYPESMSG_CANNOT_CONSTRUCT, type);
return false;
}
static bool DuplicateFieldError(JSContext* cx, Handle<JSLinearString*> name) {
JS::UniqueChars nameStr = JS_EncodeStringToUTF8(cx, name);
if (!nameStr) {
return false;
}
JS_ReportErrorNumberUTF8(cx, GetErrorMessage, nullptr,
CTYPESMSG_DUPLICATE_FIELD, nameStr.get());
return false;
}
static bool EmptyFinalizerCallError(JSContext* cx, const char* funName) {
JS_ReportErrorNumberASCII(cx, GetErrorMessage, nullptr,
CTYPESMSG_EMPTY_FIN_CALL, funName);
return false;
}
static bool EmptyFinalizerError(JSContext* cx, ConversionType convType,
HandleObject funObj = nullptr,
unsigned argIndex = 0) {
JS::UniqueChars posStr;
if (funObj) {
posStr = ConversionPositionForError(cx, convType, funObj, argIndex);
if (!posStr) {
return false;
}
}
JS_ReportErrorNumberUTF8(cx, GetErrorMessage, nullptr, CTYPESMSG_EMPTY_FIN,
(posStr ? posStr.get() : ""));
return false;
}
static bool FieldCountMismatch(JSContext* cx, unsigned expectedCount,
HandleObject structObj, unsigned actualCount,
HandleValue actual, ConversionType convType,
HandleObject funObj = nullptr,
unsigned argIndex = 0) {
MOZ_ASSERT(structObj && CType::IsCType(structObj));
JS::UniqueChars valBytes;
const char* valStr = CTypesToSourceForError(cx, actual, valBytes);
if (!valStr) {
return false;
}
JS::UniqueChars structStr = TypeSourceForError(cx, structObj);
if (!structStr) {
return false;
}
IndexCString expectedCountStr(expectedCount);
IndexCString actualCountStr(actualCount);
JS::UniqueChars posStr;
if (funObj) {
posStr = ConversionPositionForError(cx, convType, funObj, argIndex);
if (!posStr) {
return false;
}
}
JS_ReportErrorNumberUTF8(cx, GetErrorMessage, nullptr,
CTYPESMSG_FIELD_MISMATCH, valStr, structStr.get(),
expectedCountStr.get(), actualCountStr.get(),
(posStr ? posStr.get() : ""));
return false;
}
static bool FieldDescriptorCountError(JSContext* cx, HandleValue typeVal,
size_t length) {
JS::UniqueChars valBytes;
const char* valStr = CTypesToSourceForError(cx, typeVal, valBytes);
if (!valStr) {
return false;
}
IndexCString lengthStr(length);
JS_ReportErrorNumberUTF8(cx, GetErrorMessage, nullptr,
CTYPESMSG_FIELD_DESC_COUNT, valStr, lengthStr.get());
return false;
}
static bool FieldDescriptorNameError(JSContext* cx, HandleId id) {
JS::UniqueChars idBytes;
RootedValue idVal(cx, IdToValue(id));
const char* propStr = CTypesToSourceForError(cx, idVal, idBytes);
if (!propStr) {
return false;
}
JS_ReportErrorNumberUTF8(cx, GetErrorMessage, nullptr,
CTYPESMSG_FIELD_DESC_NAME, propStr);
return false;
}
static bool FieldDescriptorSizeError(JSContext* cx, HandleObject typeObj,
HandleId id) {
RootedValue typeVal(cx, ObjectValue(*typeObj));
JS::UniqueChars typeBytes;
const char* typeStr = CTypesToSourceForError(cx, typeVal, typeBytes);
if (!typeStr) {
return false;
}
RootedString idStr(cx, IdToString(cx, id));
JS::UniqueChars propStr = JS_EncodeStringToUTF8(cx, idStr);
if (!propStr) {
return false;
}
JS_ReportErrorNumberUTF8(cx, GetErrorMessage, nullptr,
CTYPESMSG_FIELD_DESC_SIZE, typeStr, propStr.get());
return false;
}
static bool FieldDescriptorNameTypeError(JSContext* cx, HandleValue typeVal) {
JS::UniqueChars valBytes;
const char* valStr = CTypesToSourceForError(cx, typeVal, valBytes);
if (!valStr) {
return false;
}
JS_ReportErrorNumberUTF8(cx, GetErrorMessage, nullptr,
CTYPESMSG_FIELD_DESC_NAMETYPE, valStr);
return false;
}
static bool FieldDescriptorTypeError(JSContext* cx, HandleValue poroVal,
HandleId id) {
JS::UniqueChars typeBytes;
const char* typeStr = CTypesToSourceForError(cx, poroVal, typeBytes);
if (!typeStr) {
return false;
}
RootedString idStr(cx, IdToString(cx, id));
JS::UniqueChars propStr = JS_EncodeStringToUTF8(cx, idStr);
if (!propStr) {
return false;
}
JS_ReportErrorNumberUTF8(cx, GetErrorMessage, nullptr,
CTYPESMSG_FIELD_DESC_TYPE, typeStr, propStr.get());
return false;
}
static bool FieldMissingError(JSContext* cx, JSObject* typeObj,
JSLinearString* name_) {
JS::UniqueChars typeBytes;
RootedString name(cx, name_);
RootedValue typeVal(cx, ObjectValue(*typeObj));
const char* typeStr = CTypesToSourceForError(cx, typeVal, typeBytes);
if (!typeStr) {
return false;
}
JS::UniqueChars nameStr = JS_EncodeStringToUTF8(cx, name);
if (!nameStr) {
return false;
}
JS_ReportErrorNumberUTF8(cx, GetErrorMessage, nullptr,
CTYPESMSG_FIELD_MISSING, typeStr, nameStr.get());
return false;
}
static bool FinalizerSizeError(JSContext* cx, HandleObject funObj,
HandleValue actual) {
MOZ_ASSERT(CType::IsCType(funObj));
JS::UniqueChars valBytes;
const char* valStr = CTypesToSourceForError(cx, actual, valBytes);
if (!valStr) {
return false;
}
JS::UniqueChars funStr = FunctionTypeSourceForError(cx, funObj);
if (!funStr) {
return false;
}
JS_ReportErrorNumberUTF8(cx, GetErrorMessage, nullptr,
CTYPESMSG_FIN_SIZE_ERROR, funStr.get(), valStr);
return false;
}
static bool FunctionArgumentLengthMismatch(
JSContext* cx, unsigned expectedCount, unsigned actualCount,
HandleObject funObj, HandleObject typeObj, bool isVariadic) {
JS::UniqueChars funStr;
Value slot = JS::GetReservedSlot(funObj, SLOT_REFERENT);
if (!slot.isUndefined() && Library::IsLibrary(&slot.toObject())) {
funStr = FunctionTypeSourceForError(cx, funObj);
} else {
funStr = FunctionTypeSourceForError(cx, typeObj);
}
if (!funStr) {
return false;
}
IndexCString expectedCountStr(expectedCount);
IndexCString actualCountStr(actualCount);
const char* variadicStr = isVariadic ? " or more" : "";
JS_ReportErrorNumberUTF8(
cx, GetErrorMessage, nullptr, CTYPESMSG_ARG_COUNT_MISMATCH, funStr.get(),
expectedCountStr.get(), variadicStr, actualCountStr.get());
return false;
}
static bool FunctionArgumentTypeError(JSContext* cx, uint32_t index,
HandleValue typeVal, const char* reason) {
MOZ_ASSERT(JS::StringIsASCII(reason));
JS::UniqueChars valBytes;
const char* valStr = CTypesToSourceForError(cx, typeVal, valBytes);
if (!valStr) {
return false;
}
IndexCString indexStr(index + 1);
JS_ReportErrorNumberUTF8(cx, GetErrorMessage, nullptr,
CTYPESMSG_ARG_TYPE_ERROR, indexStr.get(), reason,
valStr);
return false;
}
static bool FunctionReturnTypeError(JSContext* cx, HandleValue type,
const char* reason) {
MOZ_ASSERT(JS::StringIsASCII(reason));
JS::UniqueChars valBytes;
const char* valStr = CTypesToSourceForError(cx, type, valBytes);
if (!valStr) {
return false;
}
JS_ReportErrorNumberUTF8(cx, GetErrorMessage, nullptr,
CTYPESMSG_RET_TYPE_ERROR, reason, valStr);
return false;
}
static bool IncompatibleCallee(JSContext* cx, const char* funName,
HandleObject actualObj) {
MOZ_ASSERT(JS::StringIsASCII(funName));
JS::UniqueChars valBytes;
RootedValue val(cx, ObjectValue(*actualObj));
const char* valStr = CTypesToSourceForError(cx, val, valBytes);
if (!valStr) {
return false;
}
JS_ReportErrorNumberUTF8(cx, GetErrorMessage, nullptr,
CTYPESMSG_INCOMPATIBLE_CALLEE, funName, valStr);
return false;
}
static bool IncompatibleThisProto(JSContext* cx, const char* funName,
const char* actualType) {
JS_ReportErrorNumberASCII(cx, GetErrorMessage, nullptr,
CTYPESMSG_INCOMPATIBLE_THIS, funName, actualType);
return false;
}
static bool IncompatibleThisProto(JSContext* cx, const char* funName,
HandleValue actualVal) {
MOZ_ASSERT(JS::StringIsASCII(funName));
JS::UniqueChars valBytes;
const char* valStr = CTypesToSourceForError(cx, actualVal, valBytes);
if (!valStr) {
return false;
}
JS_ReportErrorNumberUTF8(cx, GetErrorMessage, nullptr,
CTYPESMSG_INCOMPATIBLE_THIS_VAL, funName,
"incompatible object", valStr);
return false;
}
static bool IncompatibleThisType(JSContext* cx, const char* funName,
const char* actualType) {
JS_ReportErrorNumberASCII(cx, GetErrorMessage, nullptr,
CTYPESMSG_INCOMPATIBLE_THIS_TYPE, funName,
actualType);
return false;
}
static bool IncompatibleThisType(JSContext* cx, const char* funName,
const char* actualType,
HandleValue actualVal) {
MOZ_ASSERT(JS::StringIsASCII(funName));
MOZ_ASSERT(JS::StringIsASCII(actualType));
JS::UniqueChars valBytes;
const char* valStr = CTypesToSourceForError(cx, actualVal, valBytes);
if (!valStr) {
return false;
}
JS_ReportErrorNumberUTF8(cx, GetErrorMessage, nullptr,
CTYPESMSG_INCOMPATIBLE_THIS_VAL, funName, actualType,
valStr);
return false;
}
static bool InvalidIndexError(JSContext* cx, HandleValue val) {
JS::UniqueChars idBytes;
const char* indexStr = CTypesToSourceForError(cx, val, idBytes);
if (!indexStr) {
return false;
}
JS_ReportErrorNumberUTF8(cx, GetErrorMessage, nullptr,
CTYPESMSG_INVALID_INDEX, indexStr);
return false;
}
static bool InvalidIndexError(JSContext* cx, HandleId id) {
RootedValue idVal(cx, IdToValue(id));
return InvalidIndexError(cx, idVal);
}
static bool InvalidIndexRangeError(JSContext* cx, size_t index, size_t length) {
IndexCString indexStr(index);
IndexCString lengthStr(length);
JS_ReportErrorNumberASCII(cx, GetErrorMessage, nullptr,
CTYPESMSG_INVALID_RANGE, indexStr.get(),
lengthStr.get());
return false;
}
static bool NonPrimitiveError(JSContext* cx, HandleObject typeObj) {
MOZ_ASSERT(CType::IsCType(typeObj));
JS::UniqueChars typeStr = TypeSourceForError(cx, typeObj);
if (!typeStr) {
return false;
}
JS_ReportErrorNumberUTF8(cx, GetErrorMessage, nullptr,
CTYPESMSG_NON_PRIMITIVE, typeStr.get());
return false;
}
static bool NonStringBaseError(JSContext* cx, HandleValue thisVal) {
JS::UniqueChars valBytes;
const char* valStr = CTypesToSourceForError(cx, thisVal, valBytes);
if (!valStr) {
return false;
}
JS_ReportErrorNumberUTF8(cx, GetErrorMessage, nullptr,
CTYPESMSG_NON_STRING_BASE, valStr);
return false;
}
static bool NonTypedArrayBaseError(JSContext* cx, HandleValue thisVal) {
JS::UniqueChars valBytes;
const char* valStr = CTypesToSourceForError(cx, thisVal, valBytes);
if (!valStr) {
return false;
}
JS_ReportErrorNumberUTF8(cx, GetErrorMessage, nullptr,
CTYPESMSG_NON_TYPEDARRAY_BASE, valStr);
return false;
}
static bool NullPointerError(JSContext* cx, const char* action,
HandleObject obj) {
MOZ_ASSERT(JS::StringIsASCII(action));
JS::UniqueChars valBytes;
RootedValue val(cx, ObjectValue(*obj));
const char* valStr = CTypesToSourceForError(cx, val, valBytes);
if (!valStr) {
return false;
}
JS_ReportErrorNumberUTF8(cx, GetErrorMessage, nullptr, CTYPESMSG_NULL_POINTER,
action, valStr);
return false;
}
static bool PropNameNonStringError(JSContext* cx, HandleId id,
HandleValue actual, ConversionType convType,
HandleObject funObj = nullptr,
unsigned argIndex = 0) {
JS::UniqueChars valBytes;
const char* valStr = CTypesToSourceForError(cx, actual, valBytes);
if (!valStr) {
return false;
}
JS::UniqueChars idBytes;
RootedValue idVal(cx, IdToValue(id));
const char* propStr = CTypesToSourceForError(cx, idVal, idBytes);
if (!propStr) {
return false;
}
JS::UniqueChars posStr;
if (funObj) {
posStr = ConversionPositionForError(cx, convType, funObj, argIndex);
if (!posStr) {
return false;
}
}
JS_ReportErrorNumberUTF8(cx, GetErrorMessage, nullptr,
CTYPESMSG_PROP_NONSTRING, propStr, valStr,
(posStr ? posStr.get() : ""));
return false;
}
static bool SizeOverflow(JSContext* cx, const char* name, const char* limit) {
JS_ReportErrorNumberASCII(cx, GetErrorMessage, nullptr,
CTYPESMSG_SIZE_OVERFLOW, name, limit);
return false;
}
static bool TypeError(JSContext* cx, const char* expected, HandleValue actual) {
MOZ_ASSERT(JS::StringIsASCII(expected));
JS::UniqueChars bytes;
const char* src = CTypesToSourceForError(cx, actual, bytes);
if (!src) {
return false;
}
JS_ReportErrorNumberUTF8(cx, GetErrorMessage, nullptr, CTYPESMSG_TYPE_ERROR,
expected, src);
return false;
}
static bool TypeOverflow(JSContext* cx, const char* expected,
HandleValue actual) {
MOZ_ASSERT(JS::StringIsASCII(expected));
JS::UniqueChars valBytes;
const char* valStr = CTypesToSourceForError(cx, actual, valBytes);
if (!valStr) {
return false;
}
JS_ReportErrorNumberUTF8(cx, GetErrorMessage, nullptr,
CTYPESMSG_TYPE_OVERFLOW, valStr, expected);
return false;
}
static bool UndefinedSizeCastError(JSContext* cx, HandleObject targetTypeObj) {
JS::UniqueChars targetTypeStr = TypeSourceForError(cx, targetTypeObj);
if (!targetTypeStr) {
return false;
}
JS_ReportErrorNumberUTF8(cx, GetErrorMessage, nullptr,
CTYPESMSG_UNDEFINED_SIZE_CAST, targetTypeStr.get());
return false;
}
static bool SizeMismatchCastError(JSContext* cx, HandleObject sourceTypeObj,
HandleObject targetTypeObj, size_t sourceSize,
size_t targetSize) {
JS::UniqueChars sourceTypeStr = TypeSourceForError(cx, sourceTypeObj);
if (!sourceTypeStr) {
return false;
}
JS::UniqueChars targetTypeStr = TypeSourceForError(cx, targetTypeObj);
if (!targetTypeStr) {
return false;
}
IndexCString sourceSizeStr(sourceSize);
IndexCString targetSizeStr(targetSize);
JS_ReportErrorNumberUTF8(cx, GetErrorMessage, nullptr,
CTYPESMSG_SIZE_MISMATCH_CAST, targetTypeStr.get(),
sourceTypeStr.get(), targetSizeStr.get(),
sourceSizeStr.get());
return false;
}
static bool UndefinedSizePointerError(JSContext* cx, const char* action,
HandleObject obj) {
MOZ_ASSERT(JS::StringIsASCII(action));
JS::UniqueChars valBytes;
RootedValue val(cx, ObjectValue(*obj));
const char* valStr = CTypesToSourceForError(cx, val, valBytes);
if (!valStr) {
return false;
}
JS_ReportErrorNumberUTF8(cx, GetErrorMessage, nullptr,
CTYPESMSG_UNDEFINED_SIZE, action, valStr);
return false;
}
static bool VariadicArgumentTypeError(JSContext* cx, uint32_t index,
HandleValue actual) {
JS::UniqueChars valBytes;
const char* valStr = CTypesToSourceForError(cx, actual, valBytes);
if (!valStr) {
return false;
}
IndexCString indexStr(index + 1);
JS_ReportErrorNumberUTF8(cx, GetErrorMessage, nullptr,
CTYPESMSG_VARG_TYPE_ERROR, indexStr.get(), valStr);
return false;
}
[[nodiscard]] JSObject* GetThisObject(JSContext* cx, const CallArgs& args,
const char* msg) {
if (!args.thisv().isObject()) {
IncompatibleThisProto(cx, msg, args.thisv());
return nullptr;
}
return &args.thisv().toObject();
}
static bool DefineToStringTag(JSContext* cx, HandleObject obj,
const char* toStringTag) {
RootedString toStringTagStr(cx, JS_NewStringCopyZ(cx, toStringTag));
if (!toStringTagStr) {
return false;
}
RootedId toStringTagId(
cx, JS::GetWellKnownSymbolKey(cx, JS::SymbolCode::toStringTag));
return JS_DefinePropertyById(cx, obj, toStringTagId, toStringTagStr,
JSPROP_READONLY);
}
static JSObject* InitCTypeClass(JSContext* cx, HandleObject ctypesObj) {
JSFunction* fun = JS_DefineFunction(cx, ctypesObj, "CType", ConstructAbstract,
0, CTYPESCTOR_FLAGS);
if (!fun) {
return nullptr;
}
RootedObject ctor(cx, JS_GetFunctionObject(fun));
RootedObject fnproto(cx);
if (!JS_GetPrototype(cx, ctor, &fnproto)) {
return nullptr;
}
MOZ_ASSERT(ctor);
MOZ_ASSERT(fnproto);
// Set up ctypes.CType.prototype.
RootedObject prototype(
cx, JS_NewObjectWithGivenProto(cx, &sCTypeProtoClass, fnproto));
if (!prototype) {
return nullptr;
}
if (!JS_DefineProperty(cx, ctor, "prototype", prototype,
JSPROP_ENUMERATE | JSPROP_READONLY | JSPROP_PERMANENT))
return nullptr;
if (!JS_DefineProperty(cx, prototype, "constructor", ctor,
JSPROP_ENUMERATE | JSPROP_READONLY | JSPROP_PERMANENT))
return nullptr;
// Define properties and functions common to all CTypes.
if (!JS_DefineProperties(cx, prototype, sCTypeProps) ||
!JS_DefineFunctions(cx, prototype, sCTypeFunctions))
return nullptr;
if (!DefineToStringTag(cx, prototype, "CType")) {
return nullptr;
}
if (!JS_FreezeObject(cx, ctor) || !JS_FreezeObject(cx, prototype)) {
return nullptr;
}
return prototype;
}
static JSObject* InitABIClass(JSContext* cx) {
RootedObject obj(cx, JS_NewPlainObject(cx));
if (!obj) {
return nullptr;
}
if (!JS_DefineFunctions(cx, obj, sCABIFunctions)) {
return nullptr;
}
if (!DefineToStringTag(cx, obj, "CABI")) {
return nullptr;
}
return obj;
}
static JSObject* InitCDataClass(JSContext* cx, HandleObject parent,
HandleObject CTypeProto) {
JSFunction* fun = JS_DefineFunction(cx, parent, "CData", ConstructAbstract, 0,
CTYPESCTOR_FLAGS);
if (!fun) {
return nullptr;
}
RootedObject ctor(cx, JS_GetFunctionObject(fun));
MOZ_ASSERT(ctor);
// Set up ctypes.CData.__proto__ === ctypes.CType.prototype.
// (Note that 'ctypes.CData instanceof Function' is still true, thanks to the
// prototype chain.)
if (!JS_SetPrototype(cx, ctor, CTypeProto)) {
return nullptr;
}
// Set up ctypes.CData.prototype.
RootedObject prototype(cx, JS_NewObject(cx, &sCDataProtoClass));
if (!prototype) {
return nullptr;
}
if (!JS_DefineProperty(cx, ctor, "prototype", prototype,
JSPROP_ENUMERATE | JSPROP_READONLY | JSPROP_PERMANENT))
return nullptr;
if (!JS_DefineProperty(cx, prototype, "constructor", ctor,
JSPROP_ENUMERATE | JSPROP_READONLY | JSPROP_PERMANENT))
return nullptr;
// Define properties and functions common to all CDatas.
if (!JS_DefineProperties(cx, prototype, sCDataProps) ||
!JS_DefineFunctions(cx, prototype, sCDataFunctions))
return nullptr;
if (!DefineToStringTag(cx, prototype, "CData")) {
return nullptr;
}
!JS_FreezeObject(cx, ctor))
return nullptr;
return prototype;
}
static bool DefineABIConstant(JSContext* cx, HandleObject ctypesObj,
const char* name, ABICode code,
HandleObject prototype) {
RootedObject obj(cx, JS_NewObjectWithGivenProto(cx, &sCABIClass, prototype));
if (!obj) {
return false;
}
JS_SetReservedSlot(obj, SLOT_ABICODE, Int32Value(code));
if (!JS_FreezeObject(cx, obj)) {
return false;
}
return JS_DefineProperty(
cx, ctypesObj, name, obj,
JSPROP_ENUMERATE | JSPROP_READONLY | JSPROP_PERMANENT);
}
// Set up a single type constructor for
// ctypes.{Pointer,Array,Struct,Function}Type.
static bool InitTypeConstructor(
JSContext* cx, HandleObject parent, HandleObject CTypeProto,
HandleObject CDataProto, const JSFunctionSpec spec,
const JSFunctionSpec* fns, const JSPropertySpec* props,
const JSFunctionSpec* instanceFns, const JSPropertySpec* instanceProps,
MutableHandleObject typeProto, MutableHandleObject dataProto) {
JSFunction* fun = js::DefineFunctionWithReserved(
cx, parent, spec.name.string(), spec.call.op, spec.nargs, spec.flags);
if (!fun) {
return false;
}
RootedObject obj(cx, JS_GetFunctionObject(fun));
if (!obj) {
return false;
}
// Set up the .prototype and .prototype.constructor properties.
typeProto.set(JS_NewObjectWithGivenProto(cx, &sCTypeProtoClass, CTypeProto));
if (!typeProto) {
return false;
}
// Define property before proceeding, for GC safety.
if (!JS_DefineProperty(cx, obj, "prototype", typeProto,
JSPROP_ENUMERATE | JSPROP_READONLY | JSPROP_PERMANENT))
return false;
if (fns && !JS_DefineFunctions(cx, typeProto, fns)) {
return false;
}
if (!JS_DefineProperties(cx, typeProto, props)) {
return false;
}
if (!JS_DefineProperty(cx, typeProto, "constructor", obj,
JSPROP_ENUMERATE | JSPROP_READONLY | JSPROP_PERMANENT))
return false;
// Stash ctypes.{Pointer,Array,Struct}Type.prototype on a reserved slot of
// the type constructor, for faster lookup.
js::SetFunctionNativeReserved(obj, SLOT_FN_CTORPROTO,
ObjectValue(*typeProto));
// Create an object to serve as the common ancestor for all CData objects
// created from the given type constructor. This has ctypes.CData.prototype
// as its prototype, such that it inherits the properties and functions
// common to all CDatas.
dataProto.set(JS_NewObjectWithGivenProto(cx, &sCDataProtoClass, CDataProto));
if (!dataProto) {
return false;
}
// Define functions and properties on the 'dataProto' object that are common
// to all CData objects created from this type constructor. (These will
// become functions and properties on CData objects created from this type.)
if (instanceFns && !JS_DefineFunctions(cx, dataProto, instanceFns)) {
return false;
}
if (instanceProps && !JS_DefineProperties(cx, dataProto, instanceProps)) {
return false;
}
// Link the type prototype to the data prototype.
JS_SetReservedSlot(typeProto, SLOT_OURDATAPROTO, ObjectValue(*dataProto));
if (!JS_FreezeObject(cx, obj) ||
!JS_FreezeObject(cx, typeProto))
return false;
return true;
}
static JSObject* InitInt64Class(JSContext* cx, HandleObject parent,
const JSClass* clasp, JSNative construct,
const JSFunctionSpec* fs,
const JSFunctionSpec* static_fs) {
// Init type class and constructor
RootedObject prototype(
cx, JS_InitClass(cx, parent, clasp, nullptr, clasp->name, construct, 0,
nullptr, fs, nullptr, static_fs));
if (!prototype) {
return nullptr;
}
if (clasp == &sInt64ProtoClass) {
if (!DefineToStringTag(cx, prototype, "Int64")) {
return nullptr;
}
} else {
MOZ_ASSERT(clasp == &sUInt64ProtoClass);
if (!DefineToStringTag(cx, prototype, "UInt64")) {
return nullptr;
}
}
RootedObject ctor(cx, JS_GetConstructor(cx, prototype));
if (!ctor) {
return nullptr;
}
// Define the 'join' function as an extended native and stash
// ctypes.{Int64,UInt64}.prototype in a reserved slot of the new function.
JSNative native = (clasp == &sInt64ProtoClass) ? Int64::Join : UInt64::Join;
JSFunction* fun = js::DefineFunctionWithReserved(cx, ctor, "join", native, 2,
CTYPESFN_FLAGS);
if (!fun) {
return nullptr;
}
js::SetFunctionNativeReserved(fun, SLOT_FN_INT64PROTO,
ObjectValue(*prototype));
if (!JS_FreezeObject(cx, ctor)) {
return nullptr;
}
if (!JS_FreezeObject(cx, prototype)) {
return nullptr;
}
return prototype;
}
static void AttachProtos(JSObject* proto, HandleObjectVector protos) {
// For a given 'proto' of [[Class]] "CTypeProto", attach each of the 'protos'
// to the appropriate CTypeProtoSlot. (SLOT_CTYPES is the last slot
// of [[Class]] "CTypeProto" that we fill in this automated manner.)
for (uint32_t i = 0; i <= SLOT_CTYPES; ++i) {
JS_SetReservedSlot(proto, i, ObjectOrNullValue(protos[i]));
}
}
static bool InitTypeClasses(JSContext* cx, HandleObject ctypesObj) {
// Initialize the ctypes.CType class. This acts as an abstract base class for
// the various types, and provides the common API functions. It has:
// * [[Class]] "Function"
// * __proto__ === Function.prototype
// * A constructor that throws a TypeError. (You can't construct an
// abstract type!)
// * 'prototype' property:
// * [[Class]] "CTypeProto"
// * __proto__ === Function.prototype
// * A constructor that throws a TypeError. (You can't construct an
// abstract type instance!)
// * 'constructor' property === ctypes.CType
// * Provides properties and functions common to all CTypes.
RootedObject CTypeProto(cx, InitCTypeClass(cx, ctypesObj));
if (!CTypeProto) {
return false;
}
// Initialize the ctypes.CData class. This acts as an abstract base class for
// instances of the various types, and provides the common API functions.
// It has:
// * [[Class]] "Function"
// * __proto__ === Function.prototype
// * A constructor that throws a TypeError. (You can't construct an
// abstract type instance!)
// * 'prototype' property:
// * [[Class]] "CDataProto"
// * 'constructor' property === ctypes.CData
// * Provides properties and functions common to all CDatas.
RootedObject CDataProto(cx, InitCDataClass(cx, ctypesObj, CTypeProto));
if (!CDataProto) {
return false;
}
// Link CTypeProto to CDataProto.
JS_SetReservedSlot(CTypeProto, SLOT_OURDATAPROTO, ObjectValue(*CDataProto));
// Create and attach the special class constructors: ctypes.PointerType,
// ctypes.ArrayType, ctypes.StructType, and ctypes.FunctionType.
// Each of these constructors 'c' has, respectively:
// * [[Class]] "Function"
// * __proto__ === Function.prototype
// * A constructor that creates a user-defined type.
// * 'prototype' property:
// * [[Class]] "CTypeProto"
// * __proto__ === ctypes.CType.prototype
// * 'constructor' property === 'c'
// We also construct an object 'p' to serve, given a type object 't'
// constructed from one of these type constructors, as
// 't.prototype.__proto__'. This object has:
// * [[Class]] "CDataProto"
// * __proto__ === ctypes.CData.prototype
// * Properties and functions common to all CDatas.
// Therefore an instance 't' of ctypes.{Pointer,Array,Struct,Function}Type
// will have, resp.:
// * [[Class]] "CType"
// * __proto__ === ctypes.{Pointer,Array,Struct,Function}Type.prototype
// * A constructor which creates and returns a CData object, containing
// binary data of the given type.
// * 'prototype' property:
// * [[Class]] "CDataProto"
// * __proto__ === 'p', the prototype object from above
// * 'constructor' property === 't'
RootedObjectVector protos(cx);
if (!protos.resize(CTYPEPROTO_SLOTS)) {
return false;
}
if (!InitTypeConstructor(
cx, ctypesObj, CTypeProto, CDataProto, sPointerFunction, nullptr,
sPointerProps, sPointerInstanceFunctions, sPointerInstanceProps,
protos[SLOT_POINTERPROTO], protos[SLOT_POINTERDATAPROTO]))
return false;
if (!InitTypeConstructor(
cx, ctypesObj, CTypeProto, CDataProto, sArrayFunction, nullptr,
sArrayProps, sArrayInstanceFunctions, sArrayInstanceProps,
protos[SLOT_ARRAYPROTO], protos[SLOT_ARRAYDATAPROTO]))
return false;
if (!InitTypeConstructor(
cx, ctypesObj, CTypeProto, CDataProto, sStructFunction,
sStructFunctions, sStructProps, sStructInstanceFunctions, nullptr,
protos[SLOT_STRUCTPROTO], protos[SLOT_STRUCTDATAPROTO]))
return false;
if (!InitTypeConstructor(cx, ctypesObj, CTypeProto,
protos[SLOT_POINTERDATAPROTO], sFunctionFunction,
nullptr, sFunctionProps, sFunctionInstanceFunctions,
nullptr, protos[SLOT_FUNCTIONPROTO],
protos[SLOT_FUNCTIONDATAPROTO]))
return false;
protos[SLOT_CDATAPROTO].set(CDataProto);
// Create and attach the ctypes.{Int64,UInt64} constructors.
// Each of these has, respectively:
// * [[Class]] "Function"
// * __proto__ === Function.prototype
// * A constructor that creates a ctypes.{Int64,UInt64} object,
// respectively.
// * 'prototype' property:
// * [[Class]] {"Int64Proto","UInt64Proto"}
// * 'constructor' property === ctypes.{Int64,UInt64}
protos[SLOT_INT64PROTO].set(InitInt64Class(cx, ctypesObj, &sInt64ProtoClass,
Int64::Construct, sInt64Functions,
sInt64StaticFunctions));
if (!protos[SLOT_INT64PROTO]) {
return false;
}
protos[SLOT_UINT64PROTO].set(
InitInt64Class(cx, ctypesObj, &sUInt64ProtoClass, UInt64::Construct,
sUInt64Functions, sUInt64StaticFunctions));
if (!protos[SLOT_UINT64PROTO]) {
return false;
}
// Finally, store a pointer to the global ctypes object.
// Note that there is no other reliable manner of locating this object.
protos[SLOT_CTYPES].set(ctypesObj);
// Attach the prototypes just created to each of ctypes.CType.prototype,
// and the special type constructors, so we can access them when constructing
// instances of those types.
AttachProtos(CTypeProto, protos);
AttachProtos(protos[SLOT_POINTERPROTO], protos);
AttachProtos(protos[SLOT_ARRAYPROTO], protos);
AttachProtos(protos[SLOT_STRUCTPROTO], protos);
AttachProtos(protos[SLOT_FUNCTIONPROTO], protos);
RootedObject ABIProto(cx, InitABIClass(cx));
if (!ABIProto) {
return false;
}
// Attach objects representing ABI constants.
if (!DefineABIConstant(cx, ctypesObj, "default_abi", ABI_DEFAULT, ABIProto) ||
!DefineABIConstant(cx, ctypesObj, "stdcall_abi", ABI_STDCALL, ABIProto) ||
!DefineABIConstant(cx, ctypesObj, "thiscall_abi", ABI_THISCALL,
ABIProto) ||
!DefineABIConstant(cx, ctypesObj, "winapi_abi", ABI_WINAPI, ABIProto))
return false;
// Create objects representing the builtin types, and attach them to the
// ctypes object. Each type object 't' has:
// * [[Class]] "CType"
// * __proto__ === ctypes.CType.prototype
// * A constructor which creates and returns a CData object, containing
// binary data of the given type.
// * 'prototype' property:
// * [[Class]] "CDataProto"
// * __proto__ === ctypes.CData.prototype
// * 'constructor' property === 't'
#define DEFINE_TYPE(name, type, ffiType) \
RootedObject typeObj_##name(cx); \
{ \
RootedValue typeVal(cx, Int32Value(sizeof(type))); \
RootedValue alignVal(cx, Int32Value(ffiType.alignment)); \
typeObj_##name = \
CType::DefineBuiltin(cx, ctypesObj, #name, CTypeProto, CDataProto, \
#name, TYPE_##name, typeVal, alignVal, &ffiType); \
if (!typeObj_##name) return false; \
}
CTYPES_FOR_EACH_TYPE(DEFINE_TYPE)
#undef DEFINE_TYPE
// Alias 'ctypes.unsigned' as 'ctypes.unsigned_int', since they represent
// the same type in C.
if (!JS_DefineProperty(cx, ctypesObj, "unsigned", typeObj_unsigned_int,
JSPROP_ENUMERATE | JSPROP_READONLY | JSPROP_PERMANENT))
return false;
// Alias 'ctypes.jschar' as 'ctypes.char16_t' to prevent breaking addons
if (!JS_DefineProperty(cx, ctypesObj, "jschar", typeObj_char16_t,
JSPROP_ENUMERATE | JSPROP_READONLY | JSPROP_PERMANENT))
return false;
// Create objects representing the special types void_t and voidptr_t.
RootedObject typeObj(
cx, CType::DefineBuiltin(cx, ctypesObj, "void_t", CTypeProto, CDataProto,
"void", TYPE_void_t, JS::UndefinedHandleValue,
JS::UndefinedHandleValue, &ffi_type_void));
if (!typeObj) {
return false;
}
typeObj = PointerType::CreateInternal(cx, typeObj);
if (!typeObj) {
return false;
}
if (!JS_DefineProperty(cx, ctypesObj, "voidptr_t", typeObj,
JSPROP_ENUMERATE | JSPROP_READONLY | JSPROP_PERMANENT))
return false;
return true;
}
bool IsCTypesGlobal(JSObject* obj) {
return obj->hasClass(&sCTypesGlobalClass);
}
bool IsCTypesGlobal(HandleValue v) {
return v.isObject() && IsCTypesGlobal(&v.toObject());
}
// Get the JS::CTypesCallbacks struct from the 'ctypes' object 'obj'.
const JS::CTypesCallbacks* GetCallbacks(JSObject* obj) {
MOZ_ASSERT(IsCTypesGlobal(obj));
Value result = JS::GetReservedSlot(obj, SLOT_CALLBACKS);
if (result.isUndefined()) {
return nullptr;
}
return static_cast<const JS::CTypesCallbacks*>(result.toPrivate());
}
// Utility function to access a property of an object as an object
// returns false and sets the error if the property does not exist
// or is not an object
static bool GetObjectProperty(JSContext* cx, HandleObject obj,
const char* property,
MutableHandleObject result) {
RootedValue val(cx);
if (!JS_GetProperty(cx, obj, property, &val)) {
return false;
}
if (val.isPrimitive()) {
JS_ReportErrorASCII(cx, "missing or non-object field");
return false;
}
result.set(val.toObjectOrNull());
return true;
}
} // namespace js::ctypes
using namespace js;
using namespace js::ctypes;
JS_PUBLIC_API bool JS::InitCTypesClass(JSContext* cx,
Handle<JSObject*> global) {
// attach ctypes property to global object
RootedObject ctypes(cx, JS_NewObject(cx, &sCTypesGlobalClass));
if (!ctypes) {
return false;
}
if (!JS_DefineProperty(cx, global, "ctypes", ctypes,
JSPROP_READONLY | JSPROP_PERMANENT)) {
return false;
}
if (!InitTypeClasses(cx, ctypes)) {
return false;
}
// attach API functions and properties
if (!JS_DefineFunctions(cx, ctypes, sModuleFunctions) ||
!JS_DefineProperties(cx, ctypes, sModuleProps))
return false;
if (!DefineToStringTag(cx, ctypes, "ctypes")) {
return false;
}
// Set up ctypes.CDataFinalizer.prototype.
RootedObject ctor(cx);
if (!GetObjectProperty(cx, ctypes, "CDataFinalizer", &ctor)) {
return false;
}
RootedObject prototype(cx, JS_NewObject(cx, &sCDataFinalizerProtoClass));
if (!prototype) {
return false;
}
if (!JS_DefineFunctions(cx, prototype, sCDataFinalizerFunctions)) {
return false;
}
if (!DefineToStringTag(cx, prototype, "CDataFinalizer")) {
return false;
}
if (!JS_DefineProperty(cx, ctor, "prototype", prototype,
JSPROP_ENUMERATE | JSPROP_READONLY | JSPROP_PERMANENT))
return false;
if (!JS_DefineProperty(cx, prototype, "constructor", ctor,
JSPROP_ENUMERATE | JSPROP_READONLY | JSPROP_PERMANENT))
return false;
// Seal the ctypes object, to prevent modification.
return JS_FreezeObject(cx, ctypes);
}
JS_PUBLIC_API void JS::SetCTypesCallbacks(JSObject* ctypesObj,
const CTypesCallbacks* callbacks) {
MOZ_ASSERT(callbacks);
MOZ_ASSERT(IsCTypesGlobal(ctypesObj));
// Set the callbacks on a reserved slot.
JS_SetReservedSlot(ctypesObj, SLOT_CALLBACKS,
PrivateValue(const_cast<CTypesCallbacks*>(callbacks)));
}
namespace js {
namespace ctypes {
size_t SizeOfDataIfCDataObject(mozilla::MallocSizeOf mallocSizeOf,
JSObject* obj) {
if (!CData::IsCData(obj)) {
return 0;
}
size_t n = 0;
Value slot = JS::GetReservedSlot(obj, ctypes::SLOT_OWNS);
if (!slot.isUndefined()) {
bool owns = slot.toBoolean();
slot = JS::GetReservedSlot(obj, ctypes::SLOT_DATA);
if (!slot.isUndefined()) {
char** buffer = static_cast<char**>(slot.toPrivate());
n += mallocSizeOf(buffer);
if (owns) {
n += mallocSizeOf(*buffer);
}
}
}
return n;
}
/*******************************************************************************
** Type conversion functions
*******************************************************************************/
// Enforce some sanity checks on type widths and properties.
// Where the architecture is 64-bit, make sure it's LP64 or LLP64. (ctypes.int
// autoconverts to a primitive JS number; to support ILP64 architectures, it
// would need to autoconvert to an Int64 object instead. Therefore we enforce
// this invariant here.)
static_assert(sizeof(bool) == 1 || sizeof(bool) == 4);
static_assert(sizeof(char) == 1);
static_assert(sizeof(short) == 2);
static_assert(sizeof(int) == 4);
static_assert(sizeof(unsigned) == 4);
static_assert(sizeof(long) == 4 || sizeof(long) == 8);
static_assert(sizeof(long long) == 8);
static_assert(sizeof(size_t) == sizeof(uintptr_t));
static_assert(sizeof(float) == 4);
static_assert(sizeof(PRFuncPtr) == sizeof(void*));
static_assert(numeric_limits<double>::is_signed);
template <typename TargetType, typename FromType,
bool FromIsIntegral = std::is_integral_v<FromType>>
struct ConvertImpl;
template <typename TargetType, typename FromType>
struct ConvertImpl<TargetType, FromType, false> {
static MOZ_ALWAYS_INLINE TargetType Convert(FromType input) {
return JS::ToSignedOrUnsignedInteger<TargetType>(input);
}
};
template <typename TargetType>
struct ConvertUnsignedTargetTo {
static TargetType convert(std::make_unsigned_t<TargetType> input) {
return std::is_signed_v<TargetType> ? mozilla::WrapToSigned(input) : input;
}
};
template <>
struct ConvertUnsignedTargetTo<char16_t> {
static char16_t convert(char16_t input) {
// mozilla::WrapToSigned can't be used on char16_t.
return input;
}
};
template <typename TargetType, typename FromType>
struct ConvertImpl<TargetType, FromType, true> {
static MOZ_ALWAYS_INLINE TargetType Convert(FromType input) {
using UnsignedTargetType = std::make_unsigned_t<TargetType>;
auto resultUnsigned = static_cast<UnsignedTargetType>(input);
return ConvertUnsignedTargetTo<TargetType>::convert(resultUnsigned);
}
};
template <class TargetType, class FromType>
static MOZ_ALWAYS_INLINE TargetType Convert(FromType d) {
static_assert(
std::is_integral_v<FromType> != std::is_floating_point_v<FromType>,
"should only be converting from floating/integral type");
return ConvertImpl<TargetType, FromType>::Convert(d);
}
template <class TargetType, class FromType>
static MOZ_ALWAYS_INLINE bool IsAlwaysExact() {
// Return 'true' if TargetType can always exactly represent FromType.
// This means that:
// 1) TargetType must be the same or more bits wide as FromType. For integers
// represented in 'n' bits, unsigned variants will have 'n' digits while
// signed will have 'n - 1'. For floating point types, 'digits' is the
// mantissa width.
// 2) If FromType is signed, TargetType must also be signed. (Floating point
// types are always signed.)
// 3) If TargetType is an exact integral type, FromType must be also.
if (numeric_limits<TargetType>::digits < numeric_limits<FromType>::digits) {
return false;
}
if (numeric_limits<FromType>::is_signed &&
!numeric_limits<TargetType>::is_signed)
return false;
if (!numeric_limits<FromType>::is_exact &&
numeric_limits<TargetType>::is_exact)
return false;
return true;
}
// Templated helper to determine if FromType 'i' converts losslessly to
// TargetType 'j'. Default case where both types are the same signedness.
template <class TargetType, class FromType, bool TargetSigned, bool FromSigned>
struct IsExactImpl {
static MOZ_ALWAYS_INLINE bool Test(FromType i, TargetType j) {
static_assert(numeric_limits<TargetType>::is_exact);
return FromType(j) == i;
}
};
// Specialization where TargetType is unsigned, FromType is signed.
template <class TargetType, class FromType>
struct IsExactImpl<TargetType, FromType, false, true> {
static MOZ_ALWAYS_INLINE bool Test(FromType i, TargetType j) {
static_assert(numeric_limits<TargetType>::is_exact);
return i >= 0 && FromType(j) == i;
}
};
// Specialization where TargetType is signed, FromType is unsigned.
template <class TargetType, class FromType>
struct IsExactImpl<TargetType, FromType, true, false> {
static MOZ_ALWAYS_INLINE bool Test(FromType i, TargetType j) {
static_assert(numeric_limits<TargetType>::is_exact);
return TargetType(i) >= 0 && FromType(j) == i;
}
};
// Convert FromType 'i' to TargetType 'result', returning true iff 'result'
// is an exact representation of 'i'.
template <class TargetType, class FromType>
static MOZ_ALWAYS_INLINE bool ConvertExact(FromType i, TargetType* result) {
static_assert(std::numeric_limits<TargetType>::is_exact,
"TargetType must be exact to simplify conversion");
*result = Convert<TargetType>(i);
// See if we can avoid a dynamic check.
if (IsAlwaysExact<TargetType, FromType>()) {
return true;
}
// Return 'true' if 'i' is exactly representable in 'TargetType'.
return IsExactImpl<TargetType, FromType,
numeric_limits<TargetType>::is_signed,
numeric_limits<FromType>::is_signed>::Test(i, *result);
}
// Templated helper to determine if Type 'i' is negative. Default case
// where IntegerType is unsigned.
template <class Type, bool IsSigned>
struct IsNegativeImpl {
static MOZ_ALWAYS_INLINE bool Test(Type i) { return false; }
};
// Specialization where Type is signed.
template <class Type>
struct IsNegativeImpl<Type, true> {
static MOZ_ALWAYS_INLINE bool Test(Type i) { return i < 0; }
};
// Determine whether Type 'i' is negative.
template <class Type>
static MOZ_ALWAYS_INLINE bool IsNegative(Type i) {
return IsNegativeImpl<Type, numeric_limits<Type>::is_signed>::Test(i);
}
// Implicitly convert val to bool, allowing bool, int, and double
// arguments numerically equal to 0 or 1.
static bool jsvalToBool(JSContext* cx, HandleValue val, bool* result) {
if (val.isBoolean()) {
*result = val.toBoolean();
return true;
}
if (val.isInt32()) {
int32_t i = val.toInt32();
*result = i != 0;
return i == 0 || i == 1;
}
if (val.isDouble()) {
double d = val.toDouble();
*result = d != 0;
// Allow -0.
return d == 1 || d == 0;
}
// Don't silently convert null to bool. It's probably a mistake.
return false;
}
// Implicitly convert val to IntegerType, allowing bool, int, double,
// Int64, UInt64, and CData integer types 't' where all values of 't' are
// representable by IntegerType.
template <class IntegerType>
static bool jsvalToInteger(JSContext* cx, HandleValue val,
IntegerType* result) {
static_assert(numeric_limits<IntegerType>::is_exact);
if (val.isInt32()) {
// Make sure the integer fits in the alotted precision, and has the right
// sign.
int32_t i = val.toInt32();
return ConvertExact(i, result);
}
if (val.isDouble()) {
// Don't silently lose bits here -- check that val really is an
// integer value, and has the right sign.
double d = val.toDouble();
return ConvertExact(d, result);
}
if (val.isObject()) {
RootedObject obj(cx, &val.toObject());
if (CData::IsCDataMaybeUnwrap(&obj)) {
JSObject* typeObj = CData::GetCType(obj);
void* data = CData::GetData(obj);
// Check whether the source type is always representable, with exact
// precision, by the target type. If it is, convert the value.
switch (CType::GetTypeCode(typeObj)) {
#define INTEGER_CASE(name, fromType, ffiType) \
case TYPE_##name: \
if (!IsAlwaysExact<IntegerType, fromType>()) return false; \
*result = IntegerType(*static_cast<fromType*>(data)); \
return true;
CTYPES_FOR_EACH_INT_TYPE(INTEGER_CASE)
CTYPES_FOR_EACH_WRAPPED_INT_TYPE(INTEGER_CASE)
#undef INTEGER_CASE
case TYPE_void_t:
case TYPE_bool:
case TYPE_float:
case TYPE_double:
case TYPE_float32_t:
case TYPE_float64_t:
case TYPE_char:
case TYPE_signed_char:
case TYPE_unsigned_char:
case TYPE_char16_t:
case TYPE_pointer:
case TYPE_function:
case TYPE_array:
case TYPE_struct:
// Not a compatible number type.
return false;
}
}
if (Int64::IsInt64(obj)) {
// Make sure the integer fits in IntegerType.
int64_t i = Int64Base::GetInt(obj);
return ConvertExact(i, result);
}
if (UInt64::IsUInt64(obj)) {
// Make sure the integer fits in IntegerType.
uint64_t i = Int64Base::GetInt(obj);
return ConvertExact(i, result);
}
if (CDataFinalizer::IsCDataFinalizer(obj)) {
RootedValue innerData(cx);
if (!CDataFinalizer::GetValue(cx, obj, &innerData)) {
return false; // Nothing to convert
}
return jsvalToInteger(cx, innerData, result);
}
return false;
}
if (val.isBoolean()) {
// Implicitly promote boolean values to 0 or 1, like C.
*result = val.toBoolean();
MOZ_ASSERT(*result == 0 || *result == 1);
return true;
}
// Don't silently convert null to an integer. It's probably a mistake.
return false;
}
// Implicitly convert val to FloatType, allowing int, double,
// Int64, UInt64, and CData numeric types 't' where all values of 't' are
// representable by FloatType.
template <class FloatType>
static bool jsvalToFloat(JSContext* cx, HandleValue val, FloatType* result) {
static_assert(!numeric_limits<FloatType>::is_exact);
// The following casts may silently throw away some bits, but there's
// no good way around it. Sternly requiring that the 64-bit double
// argument be exactly representable as a 32-bit float is
// unrealistic: it would allow 1/2 to pass but not 1/3.
if (val.isInt32()) {
*result = FloatType(val.toInt32());
return true;
}
if (val.isDouble()) {
*result = FloatType(val.toDouble());
return true;
}
if (val.isObject()) {
RootedObject obj(cx, &val.toObject());
if (CData::IsCDataMaybeUnwrap(&obj)) {
JSObject* typeObj = CData::GetCType(obj);
void* data = CData::GetData(obj);
// Check whether the source type is always representable, with exact
// precision, by the target type. If it is, convert the value.
switch (CType::GetTypeCode(typeObj)) {
#define NUMERIC_CASE(name, fromType, ffiType) \
case TYPE_##name: \
if (!IsAlwaysExact<FloatType, fromType>()) return false; \
*result = FloatType(*static_cast<fromType*>(data)); \
return true;
CTYPES_FOR_EACH_FLOAT_TYPE(NUMERIC_CASE)
CTYPES_FOR_EACH_INT_TYPE(NUMERIC_CASE)
CTYPES_FOR_EACH_WRAPPED_INT_TYPE(NUMERIC_CASE)
#undef NUMERIC_CASE
case TYPE_void_t:
case TYPE_bool:
case TYPE_char:
case TYPE_signed_char:
case TYPE_unsigned_char:
case TYPE_char16_t:
case TYPE_pointer:
case TYPE_function:
case TYPE_array:
case TYPE_struct:
// Not a compatible number type.
return false;
}
}
}
// Don't silently convert true to 1.0 or false to 0.0, even though C/C++
// does it. It's likely to be a mistake.
return false;
}
template <class IntegerType, class CharT>
static bool StringToInteger(JSContext* cx, CharT* cp, size_t length,
IntegerType* result, bool* overflow) {
static_assert(numeric_limits<IntegerType>::is_exact);
const CharT* end = cp + length;
if (cp == end) {
return false;
}
IntegerType sign = 1;
if (cp[0] == '-') {
if (!numeric_limits<IntegerType>::is_signed) {
return false;
}
sign = -1;
++cp;
}
// Assume base-10, unless the string begins with '0x' or '0X'.
IntegerType base = 10;
if (end - cp > 2 && cp[0] == '0' && (cp[1] == 'x' || cp[1] == 'X')) {
cp += 2;
base = 16;
}
// Scan the string left to right and build the number,
// checking for valid characters 0 - 9, a - f, A - F and overflow.
IntegerType i = 0;
while (cp != end) {
char16_t c = *cp++;
uint8_t digit;
if (IsAsciiDigit(c)) {
digit = c - '0';
} else if (base == 16 && c >= 'a' && c <= 'f') {
digit = c - 'a' + 10;
} else if (base == 16 && c >= 'A' && c <= 'F') {
digit = c - 'A' + 10;
} else {
return false;
}
IntegerType ii = i;
i = ii * base + sign * digit;
if (i / base != ii) {
*overflow = true;
return false;
}
}
*result = i;
return true;
}
template <class IntegerType>
static bool StringToInteger(JSContext* cx, JSString* string,
IntegerType* result, bool* overflow) {
JSLinearString* linear = string->ensureLinear(cx);
if (!linear) {
return false;
}
AutoCheckCannotGC nogc;
size_t length = linear->length();
return string->hasLatin1Chars()
? StringToInteger<IntegerType>(cx, linear->latin1Chars(nogc),
length, result, overflow)
: StringToInteger<IntegerType>(cx, linear->twoByteChars(nogc),
length, result, overflow);
}
// Implicitly convert val to IntegerType, allowing int, double,
// Int64, UInt64, and optionally a decimal or hexadecimal string argument.
// (This is common code shared by jsvalToSize and the Int64/UInt64
// constructors.)
template <class IntegerType>
static bool jsvalToBigInteger(JSContext* cx, HandleValue val, bool allowString,
IntegerType* result, bool* overflow) {
static_assert(numeric_limits<IntegerType>::is_exact);
if (val.isInt32()) {
// Make sure the integer fits in the alotted precision, and has the right
// sign.
int32_t i = val.toInt32();
return ConvertExact(i, result);
}
if (val.isDouble()) {
// Don't silently lose bits here -- check that val really is an
// integer value, and has the right sign.
double d = val.toDouble();
return ConvertExact(d, result);
}
if (allowString && val.isString()) {
// Allow conversion from base-10 or base-16 strings, provided the result
// fits in IntegerType. (This allows an Int64 or UInt64 object to be passed
// to the JS array element operator, which will automatically call
// toString() on the object for us.)
return StringToInteger(cx, val.toString(), result, overflow);
}
if (val.isObject()) {
// Allow conversion from an Int64 or UInt64 object directly.
JSObject* obj = &val.toObject();
if (UInt64::IsUInt64(obj)) {
// Make sure the integer fits in IntegerType.
uint64_t i = Int64Base::GetInt(obj);
return ConvertExact(i, result);
}
if (Int64::IsInt64(obj)) {
// Make sure the integer fits in IntegerType.
int64_t i = Int64Base::GetInt(obj);
return ConvertExact(i, result);
}
if (CDataFinalizer::IsCDataFinalizer(obj)) {
RootedValue innerData(cx);
if (!CDataFinalizer::GetValue(cx, obj, &innerData)) {
return false; // Nothing to convert
}
return jsvalToBigInteger(cx, innerData, allowString, result, overflow);
}
}
return false;
}
// Implicitly convert val to a size value, where the size value is represented
// by size_t but must also fit in a double.
static bool jsvalToSize(JSContext* cx, HandleValue val, bool allowString,
size_t* result) {
bool dummy;
if (!jsvalToBigInteger(cx, val, allowString, result, &dummy)) {
return false;
}
// Also check that the result fits in a double.
return Convert<size_t>(double(*result)) == *result;
}
// Implicitly convert val to IntegerType, allowing int, double,
// Int64, UInt64, and optionally a decimal or hexadecimal string argument.
// (This is common code shared by jsvalToSize and the Int64/UInt64
// constructors.)
template <class IntegerType>
static bool jsidToBigInteger(JSContext* cx, jsid val, bool allowString,
IntegerType* result) {
static_assert(numeric_limits<IntegerType>::is_exact);
if (val.isInt()) {
// Make sure the integer fits in the alotted precision, and has the right
// sign.
int32_t i = val.toInt();
return ConvertExact(i, result);
}
if (allowString && val.isString()) {
// Allow conversion from base-10 or base-16 strings, provided the result
// fits in IntegerType. (This allows an Int64 or UInt64 object to be passed
// to the JS array element operator, which will automatically call
// toString() on the object for us.)
bool dummy;
return StringToInteger(cx, val.toString(), result, &dummy);
}
return false;
}
// Implicitly convert val to a size value, where the size value is represented
// by size_t but must also fit in a double.
static bool jsidToSize(JSContext* cx, jsid val, bool allowString,
size_t* result) {
if (!jsidToBigInteger(cx, val, allowString, result)) {
return false;
}
// Also check that the result fits in a double.
return Convert<size_t>(double(*result)) == *result;
}
// Implicitly convert a size value to a Value, ensuring that the size_t value
// fits in a double.
static bool SizeTojsval(JSContext* cx, size_t size, MutableHandleValue result) {
if (Convert<size_t>(double(size)) != size) {
return false;
}
result.setNumber(double(size));
return true;
}
// Forcefully convert val to IntegerType when explicitly requested.
template <class IntegerType>
static bool jsvalToIntegerExplicit(HandleValue val, IntegerType* result) {
static_assert(numeric_limits<IntegerType>::is_exact);
if (val.isDouble()) {
// Convert using ToInt32-style semantics: non-finite numbers become 0, and
// everything else rounds toward zero then maps into |IntegerType| with
// wraparound semantics.
double d = val.toDouble();
*result = JS::ToSignedOrUnsignedInteger<IntegerType>(d);
return true;
}
if (val.isObject()) {
// Convert Int64 and UInt64 values by C-style cast.
JSObject* obj = &val.toObject();
if (Int64::IsInt64(obj)) {
int64_t i = Int64Base::GetInt(obj);
*result = IntegerType(i);
return true;
}
if (UInt64::IsUInt64(obj)) {
uint64_t i = Int64Base::GetInt(obj);
*result = IntegerType(i);
return true;
}
}
return false;
}
// Forcefully convert val to a pointer value when explicitly requested.
static bool jsvalToPtrExplicit(JSContext* cx, HandleValue val,
uintptr_t* result) {
if (val.isInt32()) {
// int32_t always fits in intptr_t. If the integer is negative, cast through
// an intptr_t intermediate to sign-extend.
int32_t i = val.toInt32();
*result = i < 0 ? uintptr_t(intptr_t(i)) : uintptr_t(i);
return true;
}
if (val.isDouble()) {
double d = val.toDouble();
if (d < 0) {
// Cast through an intptr_t intermediate to sign-extend.
intptr_t i = Convert<intptr_t>(d);
if (double(i) != d) {
return false;
}
*result = uintptr_t(i);
return true;
}
// Don't silently lose bits here -- check that val really is an
// integer value, and has the right sign.
*result = Convert<uintptr_t>(d);
return double(*result) == d;
}
if (val.isObject()) {
JSObject* obj = &val.toObject();
if (Int64::IsInt64(obj)) {
int64_t i = Int64Base::GetInt(obj);
intptr_t p = intptr_t(i);
// Make sure the integer fits in the alotted precision.
if (int64_t(p) != i) {
return false;
}
*result = uintptr_t(p);
return true;
}
if (UInt64::IsUInt64(obj)) {
uint64_t i = Int64Base::GetInt(obj);
// Make sure the integer fits in the alotted precision.
*result = uintptr_t(i);
return uint64_t(*result) == i;
}
}
return false;
}
template <class IntegerType, class CharType, size_t N>
void IntegerToString(IntegerType i, int radix,
StringBuilder<CharType, N>& result) {
static_assert(numeric_limits<IntegerType>::is_exact);
// The buffer must be big enough for all the bits of IntegerType to fit,
// in base-2, including '-'.
CharType buffer[sizeof(IntegerType) * 8 + 1];
CharType* end = std::end(buffer);
CharType* cp = end;
// Build the string in reverse. We use multiplication and subtraction
// instead of modulus because that's much faster.
const bool isNegative = IsNegative(i);
size_t sign = isNegative ? -1 : 1;
do {
IntegerType ii = i / IntegerType(radix);
size_t index = sign * size_t(i - ii * IntegerType(radix));
*--cp = "0123456789abcdefghijklmnopqrstuvwxyz"[index];
i = ii;
} while (i != 0);
if (isNegative) {
*--cp = '-';
}
MOZ_ASSERT(cp >= buffer);
if (!result.append(cp, end)) {
return;
}
}
// Convert C binary value 'data' of CType 'typeObj' to a JS primitive, where
// possible; otherwise, construct and return a CData object. The following
// semantics apply when constructing a CData object for return:
// * If 'wantPrimitive' is true, the caller indicates that 'result' must be
// a JS primitive, and ConvertToJS will fail if 'result' would be a CData
// object. Otherwise:
// * If a CData object 'parentObj' is supplied, the new CData object is
// dependent on the given parent and its buffer refers to a slice of the
// parent's buffer.
// * If 'parentObj' is null, the new CData object may or may not own its
// resulting buffer depending on the 'ownResult' argument.
static bool ConvertToJS(JSContext* cx, HandleObject typeObj,
HandleObject parentObj, void* data, bool wantPrimitive,
bool ownResult, MutableHandleValue result) {
MOZ_ASSERT(!parentObj || CData::IsCData(parentObj));
MOZ_ASSERT(!parentObj || !ownResult);
MOZ_ASSERT(!wantPrimitive || !ownResult);
TypeCode typeCode = CType::GetTypeCode(typeObj);
switch (typeCode) {
case TYPE_void_t:
result.setUndefined();
break;
case TYPE_bool:
result.setBoolean(*static_cast<bool*>(data));
break;
#define INT_CASE(name, type, ffiType) \
case TYPE_##name: { \
type value = *static_cast<type*>(data); \
if (sizeof(type) < 4) \
result.setInt32(int32_t(value)); \
else \
result.setDouble(double(value)); \
break; \
}
CTYPES_FOR_EACH_INT_TYPE(INT_CASE)
#undef INT_CASE
#define WRAPPED_INT_CASE(name, type, ffiType) \
case TYPE_##name: { \
/* Return an Int64 or UInt64 object - do not convert to a JS number. */ \
uint64_t value; \
RootedObject proto(cx); \
if (!numeric_limits<type>::is_signed) { \
value = *static_cast<type*>(data); \
/* Get ctypes.UInt64.prototype from ctypes.CType.prototype. */ \
proto = CType::GetProtoFromType(cx, typeObj, SLOT_UINT64PROTO); \
if (!proto) return false; \
} else { \
value = int64_t(*static_cast<type*>(data)); \
/* Get ctypes.Int64.prototype from ctypes.CType.prototype. */ \
proto = CType::GetProtoFromType(cx, typeObj, SLOT_INT64PROTO); \
if (!proto) return false; \
} \
\
JSObject* obj = Int64Base::Construct(cx, proto, value, \
!numeric_limits<type>::is_signed); \
if (!obj) return false; \
result.setObject(*obj); \
break; \
}
CTYPES_FOR_EACH_WRAPPED_INT_TYPE(WRAPPED_INT_CASE)
#undef WRAPPED_INT_CASE
#define FLOAT_CASE(name, type, ffiType) \
case TYPE_##name: { \
type value = *static_cast<type*>(data); \
result.setDouble(double(value)); \
break; \
}
CTYPES_FOR_EACH_FLOAT_TYPE(FLOAT_CASE)
#undef FLOAT_CASE
#define CHAR_CASE(name, type, ffiType) \
case TYPE_##name: \
/* Convert to an integer. We have no idea what character encoding to */ \
/* use, if any. */ \
result.setInt32(*static_cast<type*>(data)); \
break;
CTYPES_FOR_EACH_CHAR_TYPE(CHAR_CASE)
#undef CHAR_CASE
case TYPE_char16_t: {
// Convert the char16_t to a 1-character string.
JSString* str = JS_NewUCStringCopyN(cx, static_cast<char16_t*>(data), 1);
if (!str) {
return false;
}
result.setString(str);
break;
}
case TYPE_pointer:
case TYPE_array:
case TYPE_struct: {
// We're about to create a new CData object to return. If the caller
// doesn't want this, return early.
if (wantPrimitive) {
return NonPrimitiveError(cx, typeObj);
}
JSObject* obj = CData::Create(cx, typeObj, parentObj, data, ownResult);
if (!obj) {
return false;
}
result.setObject(*obj);
break;
}
case TYPE_function:
MOZ_CRASH("cannot return a FunctionType");
}
return true;
}
// Determine if the contents of a typed array can be converted without
// ambiguity to a C type. Elements of a Int8Array are converted to
// ctypes.int8_t, UInt8Array to ctypes.uint8_t, etc.
bool CanConvertTypedArrayItemTo(JSObject* baseType, JSObject* valObj,
JSContext* cx) {
TypeCode baseTypeCode = CType::GetTypeCode(baseType);
if (baseTypeCode == TYPE_void_t || baseTypeCode == TYPE_char) {
return true;
}
TypeCode elementTypeCode;
switch (JS_GetArrayBufferViewType(valObj)) {
case Scalar::Int8:
elementTypeCode = TYPE_int8_t;
break;
case Scalar::Uint8:
case Scalar::Uint8Clamped:
elementTypeCode = TYPE_uint8_t;
break;
case Scalar::Int16:
elementTypeCode = TYPE_int16_t;
break;
case Scalar::Uint16:
elementTypeCode = TYPE_uint16_t;
break;
case Scalar::Int32:
elementTypeCode = TYPE_int32_t;
break;
case Scalar::Uint32:
elementTypeCode = TYPE_uint32_t;
break;
case Scalar::Float32:
elementTypeCode = TYPE_float32_t;
break;
case Scalar::Float64:
elementTypeCode = TYPE_float64_t;
break;
default:
return false;
}
return elementTypeCode == baseTypeCode;
}
static CDataFinalizer::Private* GetFinalizerPrivate(JSObject* obj) {
MOZ_ASSERT(CDataFinalizer::IsCDataFinalizer(obj));
using T = CDataFinalizer::Private;
return JS::GetMaybePtrFromReservedSlot<T>(obj, SLOT_DATAFINALIZER_PRIVATE);
}
// Implicitly convert Value 'val' to a C binary representation of CType
// 'targetType', storing the result in 'buffer'. Adequate space must be
// provided in 'buffer' by the caller. This function generally does minimal
// coercion between types. There are two cases in which this function is used:
// 1) The target buffer is internal to a CData object; we simply write data
// into it.
// 2) We are converting an argument for an ffi call, in which case 'convType'
// will be 'ConversionType::Argument'. This allows us to handle a special
// case: if necessary, we can autoconvert a JS string primitive to a
// pointer-to-character type. In this case, ownership of the allocated string
// is handed off to the caller; 'freePointer' will be set to indicate this.
static bool ImplicitConvert(JSContext* cx, HandleValue val,
JSObject* targetType_, void* buffer,
ConversionType convType, bool* freePointer,
HandleObject funObj = nullptr,
unsigned argIndex = 0,
HandleObject arrObj = nullptr,
unsigned arrIndex = 0) {
RootedObject targetType(cx, targetType_);
MOZ_ASSERT(CType::IsSizeDefined(targetType));
// First, check if val is either a CData object or a CDataFinalizer
// of type targetType.
JSObject* sourceData = nullptr;
JSObject* sourceType = nullptr;
RootedObject valObj(cx, nullptr);
if (val.isObject()) {
valObj = &val.toObject();
if (CData::IsCDataMaybeUnwrap(&valObj)) {
sourceData = valObj;
sourceType = CData::GetCType(sourceData);
// If the types are equal, copy the buffer contained within the CData.
// (Note that the buffers may overlap partially or completely.)
if (CType::TypesEqual(sourceType, targetType)) {
size_t size = CType::GetSize(sourceType);
memmove(buffer, CData::GetData(sourceData), size);
return true;
}
} else if (CDataFinalizer::IsCDataFinalizer(valObj)) {
sourceData = valObj;
sourceType = CDataFinalizer::GetCType(cx, sourceData);
CDataFinalizer::Private* p = GetFinalizerPrivate(sourceData);
if (!p) {
// We have called |dispose| or |forget| already.
return EmptyFinalizerError(cx, convType, funObj, argIndex);
}
// If the types are equal, copy the buffer contained within the CData.
if (CType::TypesEqual(sourceType, targetType)) {
memmove(buffer, p->cargs, p->cargs_size);
return true;
}
}
}
TypeCode targetCode = CType::GetTypeCode(targetType);
switch (targetCode) {
case TYPE_bool: {
// Do not implicitly lose bits, but allow the values 0, 1, and -0.
// Programs can convert explicitly, if needed, using `Boolean(v)` or
// `!!v`.
bool result;
if (!jsvalToBool(cx, val, &result)) {
return ConvError(cx, "boolean", val, convType, funObj, argIndex, arrObj,
arrIndex);
}
*static_cast<bool*>(buffer) = result;
break;
}
#define CHAR16_CASE(name, type, ffiType) \
case TYPE_##name: { \
/* Convert from a 1-character string, regardless of encoding, */ \
/* or from an integer, provided the result fits in 'type'. */ \
type result = 0; \
if (val.isString()) { \
JSString* str = val.toString(); \
if (str->length() != 1) \
return ConvError(cx, #name, val, convType, funObj, argIndex, arrObj, \
arrIndex); \
JSLinearString* linear = str->ensureLinear(cx); \
if (!linear) return false; \
result = linear->latin1OrTwoByteChar(0); \
} else if (!jsvalToInteger(cx, val, &result)) { \
return ConvError(cx, #name, val, convType, funObj, argIndex, arrObj, \
arrIndex); \
} \
*static_cast<type*>(buffer) = result; \
break; \
}
CTYPES_FOR_EACH_CHAR16_TYPE(CHAR16_CASE)
#undef CHAR16_CASE
#define INTEGRAL_CASE(name, type, ffiType) \
case TYPE_##name: { \
/* Do not implicitly lose bits. */ \
type result; \
if (!jsvalToInteger(cx, val, &result)) \
return ConvError(cx, #name, val, convType, funObj, argIndex, arrObj, \
arrIndex); \
*static_cast<type*>(buffer) = result; \
break; \
}
CTYPES_FOR_EACH_INT_TYPE(INTEGRAL_CASE)
CTYPES_FOR_EACH_WRAPPED_INT_TYPE(INTEGRAL_CASE)
// It's hard to believe ctypes.char16_t("f") should work yet
// ctypes.char("f") should not. Ditto for ctypes.{un,}signed_char. But
// this is how ctypes has always worked, so preserve these semantics, and
// don't switch to an algorithm similar to that in DEFINE_CHAR16_TYPE
// above, just yet.
CTYPES_FOR_EACH_CHAR_TYPE(INTEGRAL_CASE)
#undef INTEGRAL_CASE
#define FLOAT_CASE(name, type, ffiType) \
case TYPE_##name: { \
type result; \
if (!jsvalToFloat(cx, val, &result)) \
return ConvError(cx, #name, val, convType, funObj, argIndex, arrObj, \
arrIndex); \
*static_cast<type*>(buffer) = result; \
break; \
}
CTYPES_FOR_EACH_FLOAT_TYPE(FLOAT_CASE)
#undef FLOAT_CASE
case TYPE_pointer: {
if (val.isNull()) {
// Convert to a null pointer.
*static_cast<void**>(buffer) = nullptr;
break;
}
JS::Rooted<JSObject*> baseType(cx, PointerType::GetBaseType(targetType));
if (sourceData) {
// First, determine if the targetType is ctypes.void_t.ptr.
TypeCode sourceCode = CType::GetTypeCode(sourceType);
void* sourceBuffer = CData::GetData(sourceData);
bool voidptrTarget = CType::GetTypeCode(baseType) == TYPE_void_t;
if (sourceCode == TYPE_pointer && voidptrTarget) {
// Autoconvert if targetType is ctypes.voidptr_t.
*static_cast<void**>(buffer) = *static_cast<void**>(sourceBuffer);
break;
}
if (sourceCode == TYPE_array) {
// Autoconvert an array to a ctypes.void_t.ptr or to
// sourceType.elementType.ptr, just like C.
JSObject* elementType = ArrayType::GetBaseType(sourceType);
if (voidptrTarget || CType::TypesEqual(baseType, elementType)) {
*static_cast<void**>(buffer) = sourceBuffer;
break;
}
}
} else if (convType == ConversionType::Argument && val.isString()) {
// Convert the string for the ffi call. This requires allocating space
// which the caller assumes ownership of.
// TODO: Extend this so we can safely convert strings at other times
// also.
JSString* sourceString = val.toString();
size_t sourceLength = sourceString->length();
Rooted<JSLinearString*> sourceLinear(cx,
sourceString->ensureLinear(cx));
if (!sourceLinear) {
return false;
}
switch (CType::GetTypeCode(baseType)) {
case TYPE_char:
case TYPE_signed_char:
case TYPE_unsigned_char: {
// Reject if unpaired surrogate characters are present.
if (!ReportErrorIfUnpairedSurrogatePresent(cx, sourceLinear)) {
return false;
}
// Convert from UTF-16 to UTF-8.
size_t nbytes = JS::GetDeflatedUTF8StringLength(sourceLinear);
char** charBuffer = static_cast<char**>(buffer);
*charBuffer = cx->pod_malloc<char>(nbytes + 1);
if (!*charBuffer) {
return false;
}
nbytes = JS::DeflateStringToUTF8Buffer(
sourceLinear, mozilla::Span(*charBuffer, nbytes));
(*charBuffer)[nbytes] = '\0';
*freePointer = true;
break;
}
case TYPE_char16_t: {
// Copy the char16_t string data. (We could provide direct access to
// the JSString's buffer, but this approach is safer if the caller
// happens to modify the string.)
char16_t** char16Buffer = static_cast<char16_t**>(buffer);
*char16Buffer = cx->pod_malloc<char16_t>(sourceLength + 1);
if (!*char16Buffer) {
return false;
}
*freePointer = true;
CopyChars(*char16Buffer, *sourceLinear);
(*char16Buffer)[sourceLength] = '\0';
break;
}
default:
return ConvError(cx, targetType, val, convType, funObj, argIndex,
arrObj, arrIndex);
}
break;
} else if (val.isObject() && JS::IsArrayBufferObject(valObj)) {
// Convert ArrayBuffer to pointer without any copy. This is only valid
// when converting an argument to a function call, as it is possible for
// the pointer to be invalidated by anything that runs JS code. (It is
// invalid to invoke JS code from a ctypes function call.)
if (convType != ConversionType::Argument) {
return ConvError(cx, targetType, val, convType, funObj, argIndex,
arrObj, arrIndex);
}
void* ptr;
{
JS::AutoCheckCannotGC nogc;
bool isShared;
ptr = JS::GetArrayBufferData(valObj, &isShared, nogc);
MOZ_ASSERT(!isShared); // Because ArrayBuffer
}
if (!ptr) {
return ConvError(cx, targetType, val, convType, funObj, argIndex,
arrObj, arrIndex);
}
*static_cast<void**>(buffer) = ptr;
break;
} else if (val.isObject() && JS::IsSharedArrayBufferObject(valObj)) {
// CTypes has not yet opted in to allowing shared memory pointers
// to escape. Exporting a pointer to the shared buffer without
// indicating sharedness would expose client code to races.
return ConvError(cx, targetType, val, convType, funObj, argIndex,
arrObj, arrIndex);
} else if (val.isObject() && JS_IsArrayBufferViewObject(valObj)) {
// Same as ArrayBuffer, above, though note that this will take the
// offset of the view into account.
if (!CanConvertTypedArrayItemTo(baseType, valObj, cx)) {
return ConvError(cx, targetType, val, convType, funObj, argIndex,
arrObj, arrIndex);
}
if (convType != ConversionType::Argument) {
return ConvError(cx, targetType, val, convType, funObj, argIndex,
arrObj, arrIndex);
}
void* ptr;
{
JS::AutoCheckCannotGC nogc;
bool isShared;
ptr = JS_GetArrayBufferViewData(valObj, &isShared, nogc);
if (isShared) {
// Opt out of shared memory, for now. Exporting a
// pointer to the shared buffer without indicating
// sharedness would expose client code to races.
ptr = nullptr;
}
}
if (!ptr) {
return ConvError(cx, targetType, val, convType, funObj, argIndex,
arrObj, arrIndex);
}
*static_cast<void**>(buffer) = ptr;
break;
}
return ConvError(cx, targetType, val, convType, funObj, argIndex, arrObj,
arrIndex);
}
case TYPE_array: {
MOZ_ASSERT(!funObj);
RootedObject baseType(cx, ArrayType::GetBaseType(targetType));
size_t targetLength = ArrayType::GetLength(targetType);
if (val.isString()) {
JSString* sourceString = val.toString();
size_t sourceLength = sourceString->length();
Rooted<JSLinearString*> sourceLinear(cx,
sourceString->ensureLinear(cx));
if (!sourceLinear) {
return false;
}
switch (CType::GetTypeCode(baseType)) {
case TYPE_char:
case TYPE_signed_char:
case TYPE_unsigned_char: {
// Reject if unpaired surrogate characters are present.
if (!ReportErrorIfUnpairedSurrogatePresent(cx, sourceLinear)) {
return false;
}
// Convert from UTF-16 or Latin1 to UTF-8.
size_t nbytes = JS::GetDeflatedUTF8StringLength(sourceLinear);
if (targetLength < nbytes) {
MOZ_ASSERT(!funObj);
return ArrayLengthOverflow(cx, targetLength, targetType, nbytes,
val, convType);
}
char* charBuffer = static_cast<char*>(buffer);
nbytes = JS::DeflateStringToUTF8Buffer(
sourceLinear, mozilla::Span(charBuffer, nbytes));
if (targetLength > nbytes) {
charBuffer[nbytes] = '\0';
}
break;
}
case TYPE_char16_t: {
// Copy the string data, char16_t for char16_t, including the
// terminator if there's space.
if (targetLength < sourceLength) {
MOZ_ASSERT(!funObj);
return ArrayLengthOverflow(cx, targetLength, targetType,
sourceLength, val, convType);
}
char16_t* dest = static_cast<char16_t*>(buffer);
CopyChars(dest, *sourceLinear);
if (targetLength > sourceLength) {
dest[sourceLength] = '\0';
}
break;
}
default:
return ConvError(cx, targetType, val, convType, funObj, argIndex,
arrObj, arrIndex);
}
} else {
ESClass cls;
if (!GetClassOfValue(cx, val, &cls)) {
return false;
}
if (cls == ESClass::Array) {
// Convert each element of the array by calling ImplicitConvert.
uint32_t sourceLength;
if (!JS::GetArrayLength(cx, valObj, &sourceLength) ||
targetLength != size_t(sourceLength)) {
MOZ_ASSERT(!funObj);
return ArrayLengthMismatch(cx, targetLength, targetType,
size_t(sourceLength), val, convType);
}
// Convert into an intermediate, in case of failure.
size_t elementSize = CType::GetSize(baseType);
size_t arraySize = elementSize * targetLength;
auto intermediate = cx->make_pod_array<char>(arraySize);
if (!intermediate) {
return false;
}
RootedValue item(cx);
for (uint32_t i = 0; i < sourceLength; ++i) {
if (!JS_GetElement(cx, valObj, i, &item)) {
return false;
}
char* data = intermediate.get() + elementSize * i;
if (!ImplicitConvert(cx, item, baseType, data, convType, nullptr,
funObj, argIndex, targetType, i))
return false;
}
memcpy(buffer, intermediate.get(), arraySize);
} else if (cls == ESClass::ArrayBuffer ||
cls == ESClass::SharedArrayBuffer) {
// Check that array is consistent with type, then
// copy the array.
const bool bufferShared = cls == ESClass::SharedArrayBuffer;
size_t sourceLength = bufferShared
? JS::GetSharedArrayBufferByteLength(valObj)
: JS::GetArrayBufferByteLength(valObj);
size_t elementSize = CType::GetSize(baseType);
size_t arraySize = elementSize * targetLength;
if (arraySize != sourceLength) {
MOZ_ASSERT(!funObj);
return ArrayLengthMismatch(cx, arraySize, targetType, sourceLength,
val, convType);
}
SharedMem<void*> target = SharedMem<void*>::unshared(buffer);
JS::AutoCheckCannotGC nogc;
bool isShared;
SharedMem<void*> src =
(bufferShared
? SharedMem<void*>::shared(
JS::GetSharedArrayBufferData(valObj, &isShared, nogc))
: SharedMem<void*>::unshared(
JS::GetArrayBufferData(valObj, &isShared, nogc)));
MOZ_ASSERT(isShared == bufferShared);
jit::AtomicOperations::memcpySafeWhenRacy(target, src, sourceLength);
break;
} else if (JS_IsTypedArrayObject(valObj)) {
// Check that array is consistent with type, then
// copy the array. It is OK to copy from shared to unshared
// or vice versa.
if (!CanConvertTypedArrayItemTo(baseType, valObj, cx)) {
return ConvError(cx, targetType, val, convType, funObj, argIndex,
arrObj, arrIndex);
}
size_t sourceLength = JS_GetTypedArrayByteLength(valObj);
size_t elementSize = CType::GetSize(baseType);
size_t arraySize = elementSize * targetLength;
if (arraySize != sourceLength) {
MOZ_ASSERT(!funObj);
return ArrayLengthMismatch(cx, arraySize, targetType, sourceLength,
val, convType);
}
SharedMem<void*> target = SharedMem<void*>::unshared(buffer);
JS::AutoCheckCannotGC nogc;
bool isShared;
SharedMem<void*> src = SharedMem<void*>::shared(
JS_GetArrayBufferViewData(valObj, &isShared, nogc));
jit::AtomicOperations::memcpySafeWhenRacy(target, src, sourceLength);
break;
} else {
// Don't implicitly convert to string. Users can implicitly convert
// with `String(x)` or `""+x`.
return ConvError(cx, targetType, val, convType, funObj, argIndex,
arrObj, arrIndex);
}
}
break;
}
case TYPE_struct: {
if (val.isObject() && !sourceData) {
// Enumerate the properties of the object; if they match the struct
// specification, convert the fields.
Rooted<IdVector> props(cx, IdVector(cx));
if (!JS_Enumerate(cx, valObj, &props)) {
return false;
}
// Convert into an intermediate, in case of failure.
size_t structSize = CType::GetSize(targetType);
auto intermediate = cx->make_pod_array<char>(structSize);
if (!intermediate) {
return false;
}
const FieldInfoHash* fields = StructType::GetFieldInfo(targetType);
if (props.length() != fields->count()) {
return FieldCountMismatch(cx, fields->count(), targetType,
props.length(), val, convType, funObj,
argIndex);
}
RootedId id(cx);
for (size_t i = 0; i < props.length(); ++i) {
id = props[i];
if (!id.isString()) {
return PropNameNonStringError(cx, id, val, convType, funObj,
argIndex);
}
JSLinearString* name = id.toLinearString();
const FieldInfo* field =
StructType::LookupField(cx, targetType, name);
if (!field) {
return false;
}
RootedValue prop(cx);
if (!JS_GetPropertyById(cx, valObj, id, &prop)) {
return false;
}
// Convert the field via ImplicitConvert().
char* fieldData = intermediate.get() + field->mOffset;
if (!ImplicitConvert(cx, prop, field->mType, fieldData, convType,
nullptr, funObj, argIndex, targetType, i))
return false;
}
memcpy(buffer, intermediate.get(), structSize);
break;
}
return ConvError(cx, targetType, val, convType, funObj, argIndex, arrObj,
arrIndex);
}
case TYPE_void_t:
case TYPE_function:
MOZ_CRASH("invalid type");
}
return true;
}
// Convert Value 'val' to a C binary representation of CType 'targetType',
// storing the result in 'buffer'. This function is more forceful than
// ImplicitConvert.
static bool ExplicitConvert(JSContext* cx, HandleValue val,
HandleObject targetType, void* buffer,
ConversionType convType) {
// If ImplicitConvert succeeds, use that result.
if (ImplicitConvert(cx, val, targetType, buffer, convType, nullptr)) {
return true;
}
// If ImplicitConvert failed, and there is no pending exception, then assume
// hard failure (out of memory, or some other similarly serious condition).
// We store any pending exception in case we need to re-throw it.
RootedValue ex(cx);
if (!JS_GetPendingException(cx, &ex)) {
return false;
}
// Otherwise, assume soft failure. Clear the pending exception so that we
// can throw a different one as required.
JS_ClearPendingException(cx);
TypeCode type = CType::GetTypeCode(targetType);
switch (type) {
case TYPE_bool: {
*static_cast<bool*>(buffer) = ToBoolean(val);
break;
}
#define INTEGRAL_CASE(name, type, ffiType) \
case TYPE_##name: { \
/* Convert numeric values with a C-style cast, and */ \
/* allow conversion from a base-10 or base-16 string. */ \
type result; \
bool overflow = false; \
if (!jsvalToIntegerExplicit(val, &result) && \
(!val.isString() || \
!StringToInteger(cx, val.toString(), &result, &overflow))) { \
if (overflow) { \
return TypeOverflow(cx, #name, val); \
} \
return ConvError(cx, #name, val, convType); \
} \
*static_cast<type*>(buffer) = result; \
break; \
}
CTYPES_FOR_EACH_INT_TYPE(INTEGRAL_CASE)
CTYPES_FOR_EACH_WRAPPED_INT_TYPE(INTEGRAL_CASE)
CTYPES_FOR_EACH_CHAR_TYPE(INTEGRAL_CASE)
CTYPES_FOR_EACH_CHAR16_TYPE(INTEGRAL_CASE)
#undef INTEGRAL_CASE
case TYPE_pointer: {
// Convert a number, Int64 object, or UInt64 object to a pointer.
uintptr_t result;
if (!jsvalToPtrExplicit(cx, val, &result)) {
return ConvError(cx, targetType, val, convType);
}
*static_cast<uintptr_t*>(buffer) = result;
break;
}
case TYPE_float32_t:
case TYPE_float64_t:
case TYPE_float:
case TYPE_double:
case TYPE_array:
case TYPE_struct:
// ImplicitConvert is sufficient. Re-throw the exception it generated.
JS_SetPendingException(cx, ex);
return false;
case TYPE_void_t:
case TYPE_function:
MOZ_CRASH("invalid type");
}
return true;
}
// Given a CType 'typeObj', generate a string describing the C type declaration
// corresponding to 'typeObj'. For instance, the CType constructed from
// 'ctypes.int32_t.ptr.array(4).ptr.ptr' will result in the type string
// 'int32_t*(**)[4]'.
static JSString* BuildTypeName(JSContext* cx, JSObject* typeObj_) {
AutoString result;
RootedObject typeObj(cx, typeObj_);
// Walk the hierarchy of types, outermost to innermost, building up the type
// string. This consists of the base type, which goes on the left.
// Derived type modifiers (* and []) build from the inside outward, with
// pointers on the left and arrays on the right. An excellent description
// of the rules for building C type declarations can be found at:
TypeCode prevGrouping = CType::GetTypeCode(typeObj), currentGrouping;
while (true) {
currentGrouping = CType::GetTypeCode(typeObj);
switch (currentGrouping) {
case TYPE_pointer: {
// Pointer types go on the left.
PrependString(cx, result, "*");
typeObj = PointerType::GetBaseType(typeObj);
prevGrouping = currentGrouping;
continue;
}
case TYPE_array: {
if (prevGrouping == TYPE_pointer) {
// Outer type is pointer, inner type is array. Grouping is required.
PrependString(cx, result, "(");
AppendString(cx, result, ")");
}
// Array types go on the right.
AppendString(cx, result, "[");
size_t length;
if (ArrayType::GetSafeLength(typeObj, &length)) {
IntegerToString(length, 10, result);
}
AppendString(cx, result, "]");
typeObj = ArrayType::GetBaseType(typeObj);
prevGrouping = currentGrouping;
continue;
}
case TYPE_function: {
FunctionInfo* fninfo = FunctionType::GetFunctionInfo(typeObj);
// Add in the calling convention, if it's not cdecl.
// There's no trailing or leading space needed here, as none of the
// modifiers can produce a string beginning with an identifier ---
// except for TYPE_function itself, which is fine because functions
// can't return functions.
ABICode abi = GetABICode(fninfo->mABI);
if (abi == ABI_STDCALL) {
PrependString(cx, result, "__stdcall");
} else if (abi == ABI_THISCALL) {
PrependString(cx, result, "__thiscall");
} else if (abi == ABI_WINAPI) {
PrependString(cx, result, "WINAPI");
}
// Function application binds more tightly than dereferencing, so
// wrap pointer types in parens. Functions can't return functions
// (only pointers to them), and arrays can't hold functions
// (similarly), so we don't need to address those cases.
if (prevGrouping == TYPE_pointer) {
PrependString(cx, result, "(");
AppendString(cx, result, ")");
}
// Argument list goes on the right.
AppendString(cx, result, "(");
for (size_t i = 0; i < fninfo->mArgTypes.length(); ++i) {
RootedObject argType(cx, fninfo->mArgTypes[i]);
JSString* argName = CType::GetName(cx, argType);
AppendString(cx, result, argName);
if (i != fninfo->mArgTypes.length() - 1 || fninfo->mIsVariadic)
AppendString(cx, result, ", ");
}
if (fninfo->mIsVariadic) {
AppendString(cx, result, "...");
}
AppendString(cx, result, ")");
// Set 'typeObj' to the return type, and let the loop process it.
// 'prevGrouping' doesn't matter here, because functions cannot return
// arrays -- thus the parenthetical rules don't get tickled.
typeObj = fninfo->mReturnType;
continue;
}
default:
// Either a basic or struct type. Use the type's name as the base type.
break;
}
break;
}
// If prepending the base type name directly would splice two
// identifiers, insert a space.
if (IsAsciiAlpha(result[0]) || result[0] == '_') {
PrependString(cx, result, " ");
}
// Stick the base type and derived type parts together.
JSString* baseName = CType::GetName(cx, typeObj);
PrependString(cx, result, baseName);
if (!result) {
return nullptr;
}
return NewUCString(cx, result.finish());
}
// Given a CType 'typeObj', generate a string 'result' such that 'eval(result)'
// would construct the same CType. If 'makeShort' is true, assume that any
// StructType 't' is bound to an in-scope variable of name 't.name', and use
// that variable in place of generating a string to construct the type 't'.
// (This means the type comparison function CType::TypesEqual will return true
// when comparing the input and output of AppendTypeSource, since struct
// equality is determined by strict JSObject pointer equality.)
static void BuildTypeSource(JSContext* cx, JSObject* typeObj_, bool makeShort,
AutoString& result) {
RootedObject typeObj(cx, typeObj_);
// Walk the types, building up the toSource() string.
switch (CType::GetTypeCode(typeObj)) {
case TYPE_void_t:
#define CASE_FOR_TYPE(name, type, ffiType) case TYPE_##name:
CTYPES_FOR_EACH_TYPE(CASE_FOR_TYPE)
#undef CASE_FOR_TYPE
{
AppendString(cx, result, "ctypes.");
JSString* nameStr = CType::GetName(cx, typeObj);
AppendString(cx, result, nameStr);
break;
}
case TYPE_pointer: {
RootedObject baseType(cx, PointerType::GetBaseType(typeObj));
// Specialcase ctypes.voidptr_t.
if (CType::GetTypeCode(baseType) == TYPE_void_t) {
AppendString(cx, result, "ctypes.voidptr_t");
break;
}
// Recursively build the source string, and append '.ptr'.
BuildTypeSource(cx, baseType, makeShort, result);
AppendString(cx, result, ".ptr");
break;
}
case TYPE_function: {
FunctionInfo* fninfo = FunctionType::GetFunctionInfo(typeObj);
AppendString(cx, result, "ctypes.FunctionType(");
switch (GetABICode(fninfo->mABI)) {
case ABI_DEFAULT:
AppendString(cx, result, "ctypes.default_abi, ");
break;
case ABI_STDCALL:
AppendString(cx, result, "ctypes.stdcall_abi, ");
break;
case ABI_THISCALL:
AppendString(cx, result, "ctypes.thiscall_abi, ");
break;
case ABI_WINAPI:
AppendString(cx, result, "ctypes.winapi_abi, ");
break;
case INVALID_ABI:
MOZ_CRASH("invalid abi");
}
// Recursively build the source string describing the function return and
// argument types.
BuildTypeSource(cx, fninfo->mReturnType, true, result);
if (fninfo->mArgTypes.length() > 0) {
AppendString(cx, result, ", [");
for (size_t i = 0; i < fninfo->mArgTypes.length(); ++i) {
BuildTypeSource(cx, fninfo->mArgTypes[i], true, result);
if (i != fninfo->mArgTypes.length() - 1 || fninfo->mIsVariadic)
AppendString(cx, result, ", ");
}
if (fninfo->mIsVariadic) {
AppendString(cx, result, "\"...\"");
}
AppendString(cx, result, "]");
}
AppendString(cx, result, ")");
break;
}
case TYPE_array: {
// Recursively build the source string, and append '.array(n)',
// where n is the array length, or the empty string if the array length
// is undefined.
JSObject* baseType = ArrayType::GetBaseType(typeObj);
BuildTypeSource(cx, baseType, makeShort, result);
AppendString(cx, result, ".array(");
size_t length;
if (ArrayType::GetSafeLength(typeObj, &length)) {
IntegerToString(length, 10, result);
}
AppendString(cx, result, ")");
break;
}
case TYPE_struct: {
JSString* name = CType::GetName(cx, typeObj);
if (makeShort) {
// Shorten the type declaration by assuming that StructType 't' is bound
// to an in-scope variable of name 't.name'.
AppendString(cx, result, name);
break;
}
// Write the full struct declaration.
AppendString(cx, result, "ctypes.StructType(\"");
AppendString(cx, result, name);
AppendString(cx, result, "\"");
// If it's an opaque struct, we're done.
if (!CType::IsSizeDefined(typeObj)) {
AppendString(cx, result, ")");
break;
}
AppendString(cx, result, ", [");
const FieldInfoHash* fields = StructType::GetFieldInfo(typeObj);
size_t length = fields->count();
Vector<const FieldInfoHash::Entry*, 64, SystemAllocPolicy> fieldsArray;
if (!fieldsArray.resize(length)) {
break;
}
for (FieldInfoHash::Range r = fields->all(); !r.empty(); r.popFront()) {
fieldsArray[r.front().value().mIndex] = &r.front();
}
for (size_t i = 0; i < length; ++i) {
const FieldInfoHash::Entry* entry = fieldsArray[i];
AppendString(cx, result, "{ \"");
AppendString(cx, result, entry->key());
AppendString(cx, result, "\": ");
BuildTypeSource(cx, entry->value().mType, true, result);
AppendString(cx, result, " }");
if (i != length - 1) {
AppendString(cx, result, ", ");
}
}
AppendString(cx, result, "])");
break;
}
}
}
// Given a CData object of CType 'typeObj' with binary value 'data', generate a
// string 'result' such that 'eval(result)' would construct a CData object with
// the same CType and containing the same binary value. This assumes that any
// StructType 't' is bound to an in-scope variable of name 't.name'. (This means
// the type comparison function CType::TypesEqual will return true when
// comparing the types, since struct equality is determined by strict JSObject
// pointer equality.) Further, if 'isImplicit' is true, ensure that the
// resulting string can ImplicitConvert successfully if passed to another data
// constructor. (This is important when called recursively, since fields of
// structs and arrays are converted with ImplicitConvert.)
[[nodiscard]] static bool BuildDataSource(JSContext* cx, HandleObject typeObj,
void* data, bool isImplicit,
AutoString& result) {
TypeCode type = CType::GetTypeCode(typeObj);
switch (type) {
case TYPE_bool:
if (*static_cast<bool*>(data)) {
AppendString(cx, result, "true");
} else {
AppendString(cx, result, "false");
}
break;
#define INTEGRAL_CASE(name, type, ffiType) \
case TYPE_##name: \
/* Serialize as a primitive decimal integer. */ \
IntegerToString(*static_cast<type*>(data), 10, result); \
break;
CTYPES_FOR_EACH_INT_TYPE(INTEGRAL_CASE)
#undef INTEGRAL_CASE
#define WRAPPED_INT_CASE(name, type, ffiType) \
case TYPE_##name: \
/* Serialize as a wrapped decimal integer. */ \
if (!numeric_limits<type>::is_signed) \
AppendString(cx, result, "ctypes.UInt64(\""); \
else \
AppendString(cx, result, "ctypes.Int64(\""); \
\
IntegerToString(*static_cast<type*>(data), 10, result); \
AppendString(cx, result, "\")"); \
break;
CTYPES_FOR_EACH_WRAPPED_INT_TYPE(WRAPPED_INT_CASE)
#undef WRAPPED_INT_CASE
#define FLOAT_CASE(name, type, ffiType) \
case TYPE_##name: { \
/* Serialize as a primitive double. */ \
double fp = *static_cast<type*>(data); \
ToCStringBuf cbuf; \
size_t strLength; \
char* str = NumberToCString(&cbuf, fp, &strLength); \
MOZ_ASSERT(str); \
if (!result.append(str, strLength)) { \
JS_ReportOutOfMemory(cx); \
return false; \
} \
break; \
}
CTYPES_FOR_EACH_FLOAT_TYPE(FLOAT_CASE)
#undef FLOAT_CASE
#define CHAR_CASE(name, type, ffiType) \
case TYPE_##name: \
/* Serialize as an integer. */ \
IntegerToString(*static_cast<type*>(data), 10, result); \
break;
CTYPES_FOR_EACH_CHAR_TYPE(CHAR_CASE)
#undef CHAR_CASE
case TYPE_char16_t: {
// Serialize as a 1-character JS string.
JSString* str = JS_NewUCStringCopyN(cx, static_cast<char16_t*>(data), 1);
if (!str) {
return false;
}
// Escape characters, and quote as necessary.
RootedValue valStr(cx, StringValue(str));
JSString* src = JS_ValueToSource(cx, valStr);
if (!src) {
return false;
}
AppendString(cx, result, src);
break;
}
case TYPE_pointer:
case TYPE_function: {
if (isImplicit) {
// The result must be able to ImplicitConvert successfully.
// Wrap in a type constructor, then serialize for ExplicitConvert.
BuildTypeSource(cx, typeObj, true, result);
AppendString(cx, result, "(");
}
// Serialize the pointer value as a wrapped hexadecimal integer.
uintptr_t ptr = *static_cast<uintptr_t*>(data);
AppendString(cx, result, "ctypes.UInt64(\"0x");
IntegerToString(ptr, 16, result);
AppendString(cx, result, "\")");
if (isImplicit) {
AppendString(cx, result, ")");
}
break;
}
case TYPE_array: {
// Serialize each element of the array recursively. Each element must
// be able to ImplicitConvert successfully.
RootedObject baseType(cx, ArrayType::GetBaseType(typeObj));
AppendString(cx, result, "[");
size_t length = ArrayType::GetLength(typeObj);
size_t elementSize = CType::GetSize(baseType);
for (size_t i = 0; i < length; ++i) {
char* element = static_cast<char*>(data) + elementSize * i;
if (!BuildDataSource(cx, baseType, element, true, result)) {
return false;
}
if (i + 1 < length) {
AppendString(cx, result, ", ");
}
}
AppendString(cx, result, "]");
break;
}
case TYPE_struct: {
if (isImplicit) {
// The result must be able to ImplicitConvert successfully.
// Serialize the data as an object with properties, rather than
// a sequence of arguments to the StructType constructor.
AppendString(cx, result, "{");
}
// Serialize each field of the struct recursively. Each field must
// be able to ImplicitConvert successfully.
const FieldInfoHash* fields = StructType::GetFieldInfo(typeObj);
size_t length = fields->count();
Vector<const FieldInfoHash::Entry*, 64, SystemAllocPolicy> fieldsArray;
if (!fieldsArray.resize(length)) {
return false;
}
for (FieldInfoHash::Range r = fields->all(); !r.empty(); r.popFront()) {
fieldsArray[r.front().value().mIndex] = &r.front();
}
for (size_t i = 0; i < length; ++i) {
const FieldInfoHash::Entry* entry = fieldsArray[i];
if (isImplicit) {
AppendString(cx, result, "\"");
AppendString(cx, result, entry->key());
AppendString(cx, result, "\": ");
}
char* fieldData = static_cast<char*>(data) + entry->value().mOffset;
RootedObject entryType(cx, entry->value().mType);
if (!BuildDataSource(cx, entryType, fieldData, true, result)) {
return false;
}
if (i + 1 != length) {
AppendString(cx, result, ", ");
}
}
if (isImplicit) {
AppendString(cx, result, "}");
}
break;
}
case TYPE_void_t:
MOZ_CRASH("invalid type");
}
return true;
}
/*******************************************************************************
** JSAPI callback function implementations
*******************************************************************************/
bool ConstructAbstract(JSContext* cx, unsigned argc, Value* vp) {
// Calling an abstract base class constructor is disallowed.
return CannotConstructError(cx, "abstract type");
}
/*******************************************************************************
** CType implementation
*******************************************************************************/
bool CType::ConstructData(JSContext* cx, unsigned argc, Value* vp) {
CallArgs args = CallArgsFromVp(argc, vp);
// get the callee object...
RootedObject obj(cx, &args.callee());
if (!CType::IsCType(obj)) {
return IncompatibleCallee(cx, "CType constructor", obj);
}
// How we construct the CData object depends on what type we represent.
// An instance 'd' of a CData object of type 't' has:
// * [[Class]] "CData"
// * __proto__ === t.prototype
switch (GetTypeCode(obj)) {
case TYPE_void_t:
return CannotConstructError(cx, "void_t");
case TYPE_function:
JS_ReportErrorNumberASCII(cx, GetErrorMessage, nullptr,
CTYPESMSG_FUNCTION_CONSTRUCT);
return false;
case TYPE_pointer:
return PointerType::ConstructData(cx, obj, args);
case TYPE_array:
return ArrayType::ConstructData(cx, obj, args);
case TYPE_struct:
return StructType::ConstructData(cx, obj, args);
default:
return ConstructBasic(cx, obj, args);
}
}
bool CType::ConstructBasic(JSContext* cx, HandleObject obj,
const CallArgs& args) {
if (args.length() > 1) {
return ArgumentLengthError(cx, "CType constructor", "at most one", "");
}
// construct a CData object
RootedObject result(cx, CData::Create(cx, obj, nullptr, nullptr, true));
if (!result) {
return false;
}
if (args.length() == 1) {
if (!ExplicitConvert(cx, args[0], obj, CData::GetData(result),
ConversionType::Construct))
return false;
}
args.rval().setObject(*result);
return true;
}
JSObject* CType::Create(JSContext* cx, HandleObject typeProto,
HandleObject dataProto, TypeCode type, JSString* name_,
HandleValue size, HandleValue align,
ffi_type* ffiType) {
RootedString name(cx, name_);
// Create a CType object with the properties and slots common to all CTypes.
// Each type object 't' has:
// * [[Class]] "CType"
// * __proto__ === 'typeProto'; one of ctypes.{CType,PointerType,ArrayType,
// StructType}.prototype
// * A constructor which creates and returns a CData object, containing
// binary data of the given type.
// * 'prototype' property:
// * [[Class]] "CDataProto"
// * __proto__ === 'dataProto'; an object containing properties and
// functions common to all CData objects of types derived from
// 'typeProto'. (For instance, this could be ctypes.CData.prototype
// for simple types, or something representing structs for StructTypes.)
// * 'constructor' property === 't'
// * Additional properties specified by 'ps', as appropriate for the
// specific type instance 't'.
RootedObject typeObj(cx,
JS_NewObjectWithGivenProto(cx, &sCTypeClass, typeProto));
if (!typeObj) {
return nullptr;
}
// Set up the reserved slots.
JS_SetReservedSlot(typeObj, SLOT_TYPECODE, Int32Value(type));
if (ffiType) {
JS_SetReservedSlot(typeObj, SLOT_FFITYPE, PrivateValue(ffiType));
if (type == TYPE_struct || type == TYPE_array) {
AddCellMemory(typeObj, sizeof(ffi_type), MemoryUse::CTypeFFIType);
}
}
if (name) {
JS_SetReservedSlot(typeObj, SLOT_NAME, StringValue(name));
}
JS_SetReservedSlot(typeObj, SLOT_SIZE, size);
JS_SetReservedSlot(typeObj, SLOT_ALIGN, align);
if (dataProto) {
// Set up the 'prototype' and 'prototype.constructor' properties.
RootedObject prototype(
cx, JS_NewObjectWithGivenProto(cx, &sCDataProtoClass, dataProto));
if (!prototype) {
return nullptr;
}
if (!JS_DefineProperty(cx, prototype, "constructor", typeObj,
JSPROP_READONLY | JSPROP_PERMANENT))
return nullptr;
// Set the 'prototype' object.
// return nullptr;
JS_SetReservedSlot(typeObj, SLOT_PROTO, ObjectValue(*prototype));
}
if (!JS_FreezeObject(cx, typeObj)) {
return nullptr;
}
// Assert a sanity check on size and alignment: size % alignment should always
// be zero.
MOZ_ASSERT_IF(IsSizeDefined(typeObj),
GetSize(typeObj) % GetAlignment(typeObj) == 0);
return typeObj;
}
JSObject* CType::DefineBuiltin(JSContext* cx, HandleObject ctypesObj,
const char* propName, JSObject* typeProto_,
JSObject* dataProto_, const char* name,
TypeCode type, HandleValue size,
HandleValue align, ffi_type* ffiType) {
RootedObject typeProto(cx, typeProto_);
RootedObject dataProto(cx, dataProto_);
RootedString nameStr(cx, JS_NewStringCopyZ(cx, name));
if (!nameStr) {
return nullptr;
}
// Create a new CType object with the common properties and slots.
RootedObject typeObj(cx, Create(cx, typeProto, dataProto, type, nameStr, size,
align, ffiType));
if (!typeObj) {
return nullptr;
}
// Define the CType as a 'propName' property on 'ctypesObj'.
if (!JS_DefineProperty(cx, ctypesObj, propName, typeObj,
JSPROP_ENUMERATE | JSPROP_READONLY | JSPROP_PERMANENT))
return nullptr;
return typeObj;
}
static void FinalizeFFIType(JS::GCContext* gcx, JSObject* obj,
const Value& slot, size_t elementCount) {
ffi_type* ffiType = static_cast<ffi_type*>(slot.toPrivate());
size_t size = elementCount * sizeof(ffi_type*);
gcx->free_(obj, ffiType->elements, size, MemoryUse::CTypeFFITypeElements);
gcx->delete_(obj, ffiType, MemoryUse::CTypeFFIType);
}
void CType::Finalize(JS::GCContext* gcx, JSObject* obj) {
// Make sure our TypeCode slot is legit. If it's not, bail.
Value slot = JS::GetReservedSlot(obj, SLOT_TYPECODE);
if (slot.isUndefined()) {
return;
}
// The contents of our slots depends on what kind of type we are.
switch (TypeCode(slot.toInt32())) {
case TYPE_function: {
// Free the FunctionInfo.
slot = JS::GetReservedSlot(obj, SLOT_FNINFO);
if (!slot.isUndefined()) {
auto fninfo = static_cast<FunctionInfo*>(slot.toPrivate());
gcx->delete_(obj, fninfo, MemoryUse::CTypeFunctionInfo);
}
break;
}
case TYPE_struct: {
size_t fieldCount = 0;
// Free the FieldInfoHash table.
slot = JS::GetReservedSlot(obj, SLOT_FIELDINFO);
if (!slot.isUndefined()) {
auto info = static_cast<FieldInfoHash*>(slot.toPrivate());
fieldCount = info->count();
gcx->delete_(obj, info, MemoryUse::CTypeFieldInfo);
}
// Free the ffi_type info.
Value slot = JS::GetReservedSlot(obj, SLOT_FFITYPE);
if (!slot.isUndefined()) {
size_t elementCount = fieldCount != 0 ? fieldCount + 1 : 2;
FinalizeFFIType(gcx, obj, slot, elementCount);
}
// Free the ffi_type info.
break;
}
case TYPE_array: {
// Free the ffi_type info.
Value slot = JS::GetReservedSlot(obj, SLOT_FFITYPE);
if (!slot.isUndefined()) {
size_t elementCount = ArrayType::GetLength(obj);
FinalizeFFIType(gcx, obj, slot, elementCount);
}
break;
}
default:
// Nothing to do here.
break;
}
}
void CType::Trace(JSTracer* trc, JSObject* obj) {
// Make sure our TypeCode slot is legit. If it's not, bail.
Value slot = obj->as<NativeObject>().getReservedSlot(SLOT_TYPECODE);
if (slot.isUndefined()) {
return;
}
// The contents of our slots depends on what kind of type we are.
switch (TypeCode(slot.toInt32())) {
case TYPE_struct: {
slot = obj->as<NativeObject>().getReservedSlot(SLOT_FIELDINFO);
if (slot.isUndefined()) {
return;
}
FieldInfoHash* fields = static_cast<FieldInfoHash*>(slot.toPrivate());
fields->trace(trc);
break;
}
case TYPE_function: {
// Check if we have a FunctionInfo.
slot = obj->as<NativeObject>().getReservedSlot(SLOT_FNINFO);
if (slot.isUndefined()) {
return;
}
FunctionInfo* fninfo = static_cast<FunctionInfo*>(slot.toPrivate());
MOZ_ASSERT(fninfo);
// Identify our objects to the tracer.
TraceEdge(trc, &fninfo->mABI, "abi");
TraceEdge(trc, &fninfo->mReturnType, "returnType");
fninfo->mArgTypes.trace(trc);
break;
}
default:
// Nothing to do here.
break;
}
}
bool CType::IsCType(JSObject* obj) { return obj->hasClass(&sCTypeClass); }
bool CType::IsCTypeProto(JSObject* obj) {
return obj->hasClass(&sCTypeProtoClass);
}
TypeCode CType::GetTypeCode(JSObject* typeObj) {
MOZ_ASSERT(IsCType(typeObj));
Value result = JS::GetReservedSlot(typeObj, SLOT_TYPECODE);
return TypeCode(result.toInt32());
}
bool CType::TypesEqual(JSObject* t1, JSObject* t2) {
MOZ_ASSERT(IsCType(t1) && IsCType(t2));
// Fast path: check for object equality.
if (t1 == t2) {
return true;
}
// First, perform shallow comparison.
TypeCode c1 = GetTypeCode(t1);
TypeCode c2 = GetTypeCode(t2);
if (c1 != c2) {
return false;
}
// Determine whether the types require shallow or deep comparison.
switch (c1) {
case TYPE_pointer: {
// Compare base types.
JSObject* b1 = PointerType::GetBaseType(t1);
JSObject* b2 = PointerType::GetBaseType(t2);
return TypesEqual(b1, b2);
}
case TYPE_function: {
FunctionInfo* f1 = FunctionType::GetFunctionInfo(t1);
FunctionInfo* f2 = FunctionType::GetFunctionInfo(t2);
// Compare abi, return type, and argument types.
if (f1->mABI != f2->mABI) {
return false;
}
if (!TypesEqual(f1->mReturnType, f2->mReturnType)) {
return false;
}
if (f1->mArgTypes.length() != f2->mArgTypes.length()) {
return false;
}
if (f1->mIsVariadic != f2->mIsVariadic) {
return false;
}
for (size_t i = 0; i < f1->mArgTypes.length(); ++i) {
if (!TypesEqual(f1->mArgTypes[i], f2->mArgTypes[i])) {
return false;
}
}
return true;
}
case TYPE_array: {
// Compare length, then base types.
// An undefined length array matches other undefined length arrays.
size_t s1 = 0, s2 = 0;
bool d1 = ArrayType::GetSafeLength(t1, &s1);
bool d2 = ArrayType::GetSafeLength(t2, &s2);
if (d1 != d2 || (d1 && s1 != s2)) {
return false;
}
JSObject* b1 = ArrayType::GetBaseType(t1);
JSObject* b2 = ArrayType::GetBaseType(t2);
return TypesEqual(b1, b2);
}
case TYPE_struct:
// Require exact type object equality.
return false;
default:
// Shallow comparison is sufficient.
return true;
}
}
bool CType::GetSafeSize(JSObject* obj, size_t* result) {
MOZ_ASSERT(CType::IsCType(obj));
Value size = JS::GetReservedSlot(obj, SLOT_SIZE);
// The "size" property can be an int, a double, or JS::UndefinedValue()
// (for arrays of undefined length), and must always fit in a size_t.
if (size.isInt32()) {
*result = size.toInt32();
return true;
}
if (size.isDouble()) {
*result = Convert<size_t>(size.toDouble());
return true;
}
MOZ_ASSERT(size.isUndefined());
return false;
}
size_t CType::GetSize(JSObject* obj) {
MOZ_ASSERT(CType::IsCType(obj));
Value size = JS::GetReservedSlot(obj, SLOT_SIZE);
MOZ_ASSERT(!size.isUndefined());
// The "size" property can be an int, a double, or JS::UndefinedValue()
// (for arrays of undefined length), and must always fit in a size_t.
// For callers who know it can never be JS::UndefinedValue(), return a size_t
// directly.
if (size.isInt32()) {
return size.toInt32();
}
return Convert<size_t>(size.toDouble());
}
bool CType::IsSizeDefined(JSObject* obj) {
MOZ_ASSERT(CType::IsCType(obj));
Value size = JS::GetReservedSlot(obj, SLOT_SIZE);
// The "size" property can be an int, a double, or JS::UndefinedValue()
// (for arrays of undefined length), and must always fit in a size_t.
MOZ_ASSERT(size.isInt32() || size.isDouble() || size.isUndefined());
return !size.isUndefined();
}
size_t CType::GetAlignment(JSObject* obj) {
MOZ_ASSERT(CType::IsCType(obj));
Value slot = JS::GetReservedSlot(obj, SLOT_ALIGN);
return static_cast<size_t>(slot.toInt32());
}
ffi_type* CType::GetFFIType(JSContext* cx, JSObject* obj) {
MOZ_ASSERT(CType::IsCType(obj));
Value slot = JS::GetReservedSlot(obj, SLOT_FFITYPE);
if (!slot.isUndefined()) {
return static_cast<ffi_type*>(slot.toPrivate());
}
UniquePtrFFIType result;
switch (CType::GetTypeCode(obj)) {
case TYPE_array:
result = ArrayType::BuildFFIType(cx, obj);
break;
case TYPE_struct:
result = StructType::BuildFFIType(cx, obj);
break;
default:
MOZ_CRASH("simple types must have an ffi_type");
}
if (!result) {
return nullptr;
}
JS_InitReservedSlot(obj, SLOT_FFITYPE, result.get(),
JS::MemoryUse::CTypeFFIType);
return result.release();
}
JSString* CType::GetName(JSContext* cx, HandleObject obj) {
MOZ_ASSERT(CType::IsCType(obj));
Value string = JS::GetReservedSlot(obj, SLOT_NAME);
if (!string.isUndefined()) {
return string.toString();
}
// Build the type name lazily.
JSString* name = BuildTypeName(cx, obj);
if (!name) {
return nullptr;
}
JS_SetReservedSlot(obj, SLOT_NAME, StringValue(name));
return name;
}
JSObject* CType::GetProtoFromCtor(JSObject* obj, CTypeProtoSlot slot) {
// Get ctypes.{Pointer,Array,Struct}Type.prototype from a reserved slot
// on the type constructor.
Value protoslot = js::GetFunctionNativeReserved(obj, SLOT_FN_CTORPROTO);
JSObject* proto = &protoslot.toObject();
MOZ_ASSERT(proto);
MOZ_ASSERT(CType::IsCTypeProto(proto));
// Get the desired prototype.
Value result = JS::GetReservedSlot(proto, slot);
return &result.toObject();
}
JSObject* CType::GetProtoFromType(JSContext* cx, JSObject* objArg,
CTypeProtoSlot slot) {
MOZ_ASSERT(IsCType(objArg));
RootedObject obj(cx, objArg);
// Get the prototype of the type object.
RootedObject proto(cx);
if (!JS_GetPrototype(cx, obj, &proto)) {
return nullptr;
}
MOZ_ASSERT(proto);
MOZ_ASSERT(CType::IsCTypeProto(proto));
// Get the requested ctypes.{Pointer,Array,Struct,Function}Type.prototype.
Value result = JS::GetReservedSlot(proto, slot);
MOZ_ASSERT(result.isObject());
return &result.toObject();
}
bool CType::IsCTypeOrProto(HandleValue v) {
if (!v.isObject()) {
return false;
}
JSObject* obj = &v.toObject();
return CType::IsCType(obj) || CType::IsCTypeProto(obj);
}
bool CType::PrototypeGetter(JSContext* cx, const JS::CallArgs& args) {
RootedObject obj(cx, &args.thisv().toObject());
unsigned slot = CType::IsCTypeProto(obj) ? (unsigned)SLOT_OURDATAPROTO
: (unsigned)SLOT_PROTO;
args.rval().set(JS::GetReservedSlot(obj, slot));
MOZ_ASSERT(args.rval().isObject() || args.rval().isUndefined());
return true;
}
bool CType::IsCType(HandleValue v) {
return v.isObject() && CType::IsCType(&v.toObject());
}
bool CType::NameGetter(JSContext* cx, const JS::CallArgs& args) {
RootedObject obj(cx, &args.thisv().toObject());
JSString* name = CType::GetName(cx, obj);
if (!name) {
return false;
}
args.rval().setString(name);
return true;
}
bool CType::SizeGetter(JSContext* cx, const JS::CallArgs& args) {
RootedObject obj(cx, &args.thisv().toObject());
args.rval().set(JS::GetReservedSlot(obj, SLOT_SIZE));
MOZ_ASSERT(args.rval().isNumber() || args.rval().isUndefined());
return true;
}
bool CType::PtrGetter(JSContext* cx, const JS::CallArgs& args) {
RootedObject obj(cx, &args.thisv().toObject());
JSObject* pointerType = PointerType::CreateInternal(cx, obj);
if (!pointerType) {
return false;
}
args.rval().setObject(*pointerType);
return true;
}
bool CType::CreateArray(JSContext* cx, unsigned argc, Value* vp) {
CallArgs args = CallArgsFromVp(argc, vp);
RootedObject baseType(cx, GetThisObject(cx, args, "CType.prototype.array"));
if (!baseType) {
return false;
}
if (!CType::IsCType(baseType)) {
return IncompatibleThisProto(cx, "CType.prototype.array", args.thisv());
}
// Construct and return a new ArrayType object.
if (args.length() > 1) {
return ArgumentLengthError(cx, "CType.prototype.array", "at most one", "");
}
// Convert the length argument to a size_t.
size_t length = 0;
if (args.length() == 1 && !jsvalToSize(cx, args[0], false, &length)) {
return ArgumentTypeMismatch(cx, "", "CType.prototype.array",
"a nonnegative integer");
}
JSObject* result =
ArrayType::CreateInternal(cx, baseType, length, args.length() == 1);
if (!result) {
return false;
}
args.rval().setObject(*result);
return true;
}
bool CType::ToString(JSContext* cx, unsigned argc, Value* vp) {
CallArgs args = CallArgsFromVp(argc, vp);
RootedObject obj(cx, GetThisObject(cx, args, "CType.prototype.toString"));
if (!obj) {
return false;
}
if (!CType::IsCType(obj) && !CType::IsCTypeProto(obj)) {
return IncompatibleThisProto(cx, "CType.prototype.toString",
InformalValueTypeName(args.thisv()));
}
// Create the appropriate string depending on whether we're sCTypeClass or
// sCTypeProtoClass.
JSString* result;
if (CType::IsCType(obj)) {
AutoString type;
AppendString(cx, type, "type ");
AppendString(cx, type, GetName(cx, obj));
if (!type) {
return false;
}
result = NewUCString(cx, type.finish());
} else {
result = JS_NewStringCopyZ(cx, "[CType proto object]");
}
if (!result) {
return false;
}
args.rval().setString(result);
return true;
}
bool CType::ToSource(JSContext* cx, unsigned argc, Value* vp) {
CallArgs args = CallArgsFromVp(argc, vp);
JSObject* obj = GetThisObject(cx, args, "CType.prototype.toSource");
if (!obj) {
return false;
}
if (!CType::IsCType(obj) && !CType::IsCTypeProto(obj)) {
return IncompatibleThisProto(cx, "CType.prototype.toSource",
InformalValueTypeName(args.thisv()));
}
// Create the appropriate string depending on whether we're sCTypeClass or
// sCTypeProtoClass.
JSString* result;
if (CType::IsCType(obj)) {
AutoString source;
BuildTypeSource(cx, obj, false, source);
if (!source) {
return false;
}
result = NewUCString(cx, source.finish());
} else {
result = JS_NewStringCopyZ(cx, "[CType proto object]");
}
if (!result) {
return false;
}
args.rval().setString(result);
return true;
}
static JSObject* CType::GetGlobalCTypes(JSContext* cx, JSObject* objArg) {
MOZ_ASSERT(CType::IsCType(objArg));
RootedObject obj(cx, objArg);
RootedObject objTypeProto(cx);
if (!JS_GetPrototype(cx, obj, &objTypeProto)) {
return nullptr;
}
MOZ_ASSERT(objTypeProto);
MOZ_ASSERT(CType::IsCTypeProto(objTypeProto));
Value valCTypes = JS::GetReservedSlot(objTypeProto, SLOT_CTYPES);
MOZ_ASSERT(valCTypes.isObject());
return &valCTypes.toObject();
}
/*******************************************************************************
** ABI implementation
*******************************************************************************/
bool ABI::IsABI(JSObject* obj) { return obj->hasClass(&sCABIClass); }
bool ABI::ToSource(JSContext* cx, unsigned argc, Value* vp) {
CallArgs args = CallArgsFromVp(argc, vp);
if (args.length() != 0) {
return ArgumentLengthError(cx, "ABI.prototype.toSource", "no", "s");
}
JSObject* obj = GetThisObject(cx, args, "ABI.prototype.toSource");
if (!obj) {
return false;
}
if (!ABI::IsABI(obj)) {
return IncompatibleThisProto(cx, "ABI.prototype.toSource",
InformalValueTypeName(args.thisv()));
}
JSString* result;
switch (GetABICode(obj)) {
case ABI_DEFAULT:
result = JS_NewStringCopyZ(cx, "ctypes.default_abi");
break;
case ABI_STDCALL:
result = JS_NewStringCopyZ(cx, "ctypes.stdcall_abi");
break;
case ABI_THISCALL:
result = JS_NewStringCopyZ(cx, "ctypes.thiscall_abi");
break;
case ABI_WINAPI:
result = JS_NewStringCopyZ(cx, "ctypes.winapi_abi");
break;
default:
JS_ReportErrorASCII(cx, "not a valid ABICode");
return false;
}
if (!result) {
return false;
}
args.rval().setString(result);
return true;
}
/*******************************************************************************
** PointerType implementation
*******************************************************************************/
bool PointerType::Create(JSContext* cx, unsigned argc, Value* vp) {
CallArgs args = CallArgsFromVp(argc, vp);
// Construct and return a new PointerType object.
if (args.length() != 1) {
return ArgumentLengthError(cx, "PointerType", "one", "");
}
Value arg = args[0];
RootedObject obj(cx);
if (arg.isPrimitive() || !CType::IsCType(obj = &arg.toObject())) {
return ArgumentTypeMismatch(cx, "", "PointerType", "a CType");
}
JSObject* result = CreateInternal(cx, obj);
if (!result) {
return false;
}
args.rval().setObject(*result);
return true;
}
JSObject* PointerType::CreateInternal(JSContext* cx, HandleObject baseType) {
// check if we have a cached PointerType on our base CType.
Value slot = JS::GetReservedSlot(baseType, SLOT_PTR);
if (!slot.isUndefined()) {
return &slot.toObject();
}
// Get ctypes.PointerType.prototype and the common prototype for CData objects
// of this type, or ctypes.FunctionType.prototype for function pointers.
CTypeProtoSlot slotId = CType::GetTypeCode(baseType) == TYPE_function
? SLOT_FUNCTIONDATAPROTO
: SLOT_POINTERDATAPROTO;
RootedObject dataProto(cx, CType::GetProtoFromType(cx, baseType, slotId));
if (!dataProto) {
return nullptr;
}
RootedObject typeProto(
cx, CType::GetProtoFromType(cx, baseType, SLOT_POINTERPROTO));
if (!typeProto) {
return nullptr;
}
// Create a new CType object with the common properties and slots.
RootedValue sizeVal(cx, Int32Value(sizeof(void*)));
RootedValue alignVal(cx, Int32Value(ffi_type_pointer.alignment));
JSObject* typeObj =
CType::Create(cx, typeProto, dataProto, TYPE_pointer, nullptr, sizeVal,
alignVal, &ffi_type_pointer);
if (!typeObj) {
return nullptr;
}
// Set the target type. (This will be 'null' for an opaque pointer type.)
JS_SetReservedSlot(typeObj, SLOT_TARGET_T, ObjectValue(*baseType));
// Finally, cache our newly-created PointerType on our pointed-to CType.
JS_SetReservedSlot(baseType, SLOT_PTR, ObjectValue(*typeObj));
return typeObj;
}
bool PointerType::ConstructData(JSContext* cx, HandleObject obj,
const CallArgs& args) {
if (!CType::IsCType(obj) || CType::GetTypeCode(obj) != TYPE_pointer) {
return IncompatibleCallee(cx, "PointerType constructor", obj);
}
if (args.length() > 3) {
return ArgumentLengthError(cx, "PointerType constructor", "0, 1, 2, or 3",
"s");
}
RootedObject result(cx, CData::Create(cx, obj, nullptr, nullptr, true));
if (!result) {
return false;
}
// Set return value early, must not observe *vp after
args.rval().setObject(*result);
// There are 3 things that we might be creating here:
// 1 - A null pointer (no arguments)
// 2 - An initialized pointer (1 argument)
// 3 - A closure (1-3 arguments)
//
// The API doesn't give us a perfect way to distinguish 2 and 3, but the
// heuristics we use should be fine.
//
// Case 1 - Null pointer
//
if (args.length() == 0) {
return true;
}
// Analyze the arguments a bit to decide what to do next.
RootedObject baseObj(cx, PointerType::GetBaseType(obj));
bool looksLikeClosure = CType::GetTypeCode(baseObj) == TYPE_function &&
args[0].isObject() &&
JS::IsCallable(&args[0].toObject());
//
// Case 2 - Initialized pointer
//
if (!looksLikeClosure) {
if (args.length() != 1) {
return ArgumentLengthError(cx, "FunctionType constructor", "one", "");
}
return ExplicitConvert(cx, args[0], obj, CData::GetData(result),
ConversionType::Construct);
}
//
// Case 3 - Closure
//
// The second argument is an optional 'this' parameter with which to invoke
// the given js function. Callers may leave this blank, or pass null if they
// wish to pass the third argument.
RootedObject thisObj(cx, nullptr);
if (args.length() >= 2) {
if (args[1].isNull()) {
thisObj = nullptr;
} else if (args[1].isObject()) {
thisObj = &args[1].toObject();
} else if (!JS_ValueToObject(cx, args[1], &thisObj)) {
return false;
}
}
// The third argument is an optional error sentinel that js-ctypes will return
// if an exception is raised while executing the closure. The type must match
// the return type of the callback.
RootedValue errVal(cx);
if (args.length() == 3) {
errVal = args[2];
}
RootedObject fnObj(cx, &args[0].toObject());
return FunctionType::ConstructData(cx, baseObj, result, fnObj, thisObj,
errVal);
}
JSObject* PointerType::GetBaseType(JSObject* obj) {
MOZ_ASSERT(CType::GetTypeCode(obj) == TYPE_pointer);
Value type = JS::GetReservedSlot(obj, SLOT_TARGET_T);
MOZ_ASSERT(!type.isNull());
return &type.toObject();
}
bool PointerType::IsPointerType(HandleValue v) {
if (!v.isObject()) {
return false;
}
JSObject* obj = &v.toObject();
return CType::IsCType(obj) && CType::GetTypeCode(obj) == TYPE_pointer;
}
bool PointerType::IsPointer(HandleValue v) {
if (!v.isObject()) {
return false;
}
JSObject* obj = MaybeUnwrapArrayWrapper(&v.toObject());
return CData::IsCData(obj) &&
CType::GetTypeCode(CData::GetCType(obj)) == TYPE_pointer;
}
bool PointerType::TargetTypeGetter(JSContext* cx, const JS::CallArgs& args) {
RootedObject obj(cx, &args.thisv().toObject());
args.rval().set(JS::GetReservedSlot(obj, SLOT_TARGET_T));
MOZ_ASSERT(args.rval().isObject());
return true;
}
bool PointerType::IsNull(JSContext* cx, unsigned argc, Value* vp) {
CallArgs args = CallArgsFromVp(argc, vp);
RootedObject obj(cx, GetThisObject(cx, args, "PointerType.prototype.isNull"));
if (!obj) {
return false;
}
if (!CData::IsCDataMaybeUnwrap(&obj)) {
return IncompatibleThisProto(cx, "PointerType.prototype.isNull",
args.thisv());
}
// Get pointer type and base type.
JSObject* typeObj = CData::GetCType(obj);
if (CType::GetTypeCode(typeObj) != TYPE_pointer) {
return IncompatibleThisType(cx, "PointerType.prototype.isNull",
"non-PointerType CData", args.thisv());
}
void* data = *static_cast<void**>(CData::GetData(obj));
args.rval().setBoolean(data == nullptr);
return true;
}
bool PointerType::OffsetBy(JSContext* cx, const CallArgs& args, int offset,
const char* name) {
RootedObject obj(cx, GetThisObject(cx, args, name));
if (!obj) {
return false;
}
if (!CData::IsCDataMaybeUnwrap(&obj)) {
return IncompatibleThisProto(cx, name, args.thisv());
}
RootedObject typeObj(cx, CData::GetCType(obj));
if (CType::GetTypeCode(typeObj) != TYPE_pointer) {
return IncompatibleThisType(cx, name, "non-PointerType CData",
args.thisv());
}
RootedObject baseType(cx, PointerType::GetBaseType(typeObj));
if (!CType::IsSizeDefined(baseType)) {
return UndefinedSizePointerError(cx, "modify", obj);
}
size_t elementSize = CType::GetSize(baseType);
char* data = static_cast<char*>(*static_cast<void**>(CData::GetData(obj)));
void* address = data + offset * ptrdiff_t(elementSize);
// Create a PointerType CData object containing the new address.
JSObject* result = CData::Create(cx, typeObj, nullptr, &address, true);
if (!result) {
return false;
}
args.rval().setObject(*result);
return true;
}
bool PointerType::Increment(JSContext* cx, unsigned argc, Value* vp) {
CallArgs args = CallArgsFromVp(argc, vp);
return OffsetBy(cx, args, 1, "PointerType.prototype.increment");
}
bool PointerType::Decrement(JSContext* cx, unsigned argc, Value* vp) {
CallArgs args = CallArgsFromVp(argc, vp);
return OffsetBy(cx, args, -1, "PointerType.prototype.decrement");
}
bool PointerType::ContentsGetter(JSContext* cx, const JS::CallArgs& args) {
RootedObject obj(cx, &args.thisv().toObject());
RootedObject baseType(cx, GetBaseType(CData::GetCType(obj)));
if (!CType::IsSizeDefined(baseType)) {
return UndefinedSizePointerError(cx, "get contents of", obj);
}
void* data = *static_cast<void**>(CData::GetData(obj));
if (data == nullptr) {
return NullPointerError(cx, "read contents of", obj);
}
RootedValue result(cx);
if (!ConvertToJS(cx, baseType, nullptr, data, false, false, &result)) {
return false;
}
args.rval().set(result);
return true;
}
bool PointerType::ContentsSetter(JSContext* cx, const JS::CallArgs& args) {
RootedObject obj(cx, &args.thisv().toObject());
RootedObject baseType(cx, GetBaseType(CData::GetCType(obj)));
if (!CType::IsSizeDefined(baseType)) {
return UndefinedSizePointerError(cx, "set contents of", obj);
}
void* data = *static_cast<void**>(CData::GetData(obj));
if (data == nullptr) {
return NullPointerError(cx, "write contents to", obj);
}
args.rval().setUndefined();
return ImplicitConvert(cx, args.get(0), baseType, data,
ConversionType::Setter, nullptr);
}
/*******************************************************************************
** ArrayType implementation
*******************************************************************************/
bool ArrayType::Create(JSContext* cx, unsigned argc, Value* vp) {
CallArgs args = CallArgsFromVp(argc, vp);
// Construct and return a new ArrayType object.
if (args.length() < 1 || args.length() > 2) {
return ArgumentLengthError(cx, "ArrayType", "one or two", "s");
}
if (args[0].isPrimitive() || !CType::IsCType(&args[0].toObject())) {
return ArgumentTypeMismatch(cx, "first ", "ArrayType", "a CType");
}
// Convert the length argument to a size_t.
size_t length = 0;
if (args.length() == 2 && !jsvalToSize(cx, args[1], false, &length)) {
return ArgumentTypeMismatch(cx, "second ", "ArrayType",
"a nonnegative integer");
}
RootedObject baseType(cx, &args[0].toObject());
JSObject* result = CreateInternal(cx, baseType, length, args.length() == 2);
if (!result) {
return false;
}
args.rval().setObject(*result);
return true;
}
JSObject* ArrayType::CreateInternal(JSContext* cx, HandleObject baseType,
size_t length, bool lengthDefined) {
// Get ctypes.ArrayType.prototype and the common prototype for CData objects
// of this type, from ctypes.CType.prototype.
RootedObject typeProto(
cx, CType::GetProtoFromType(cx, baseType, SLOT_ARRAYPROTO));
if (!typeProto) {
return nullptr;
}
RootedObject dataProto(
cx, CType::GetProtoFromType(cx, baseType, SLOT_ARRAYDATAPROTO));
if (!dataProto) {
return nullptr;
}
// Determine the size of the array from the base type, if possible.
// The size of the base type must be defined.
// If our length is undefined, both our size and length will be undefined.
size_t baseSize;
if (!CType::GetSafeSize(baseType, &baseSize)) {
JS_ReportErrorASCII(cx, "base size must be defined");
return nullptr;
}
RootedValue sizeVal(cx);
RootedValue lengthVal(cx);
if (lengthDefined) {
// Check for overflow, and convert to an int or double as required.
size_t size = length * baseSize;
if (length > 0 && size / length != baseSize) {
SizeOverflow(cx, "array size", "size_t");
return nullptr;
}
if (!SizeTojsval(cx, size, &sizeVal)) {
SizeOverflow(cx, "array size", "JavaScript number");
return nullptr;
}
if (!SizeTojsval(cx, length, &lengthVal)) {
SizeOverflow(cx, "array length", "JavaScript number");
return nullptr;
}
}
RootedValue alignVal(cx, Int32Value(CType::GetAlignment(baseType)));
// Create a new CType object with the common properties and slots.
JSObject* typeObj = CType::Create(cx, typeProto, dataProto, TYPE_array,
nullptr, sizeVal, alignVal, nullptr);
if (!typeObj) {
return nullptr;
}
// Set the element type.
JS_SetReservedSlot(typeObj, SLOT_ELEMENT_T, ObjectValue(*baseType));
// Set the length.
JS_SetReservedSlot(typeObj, SLOT_LENGTH, lengthVal);
return typeObj;
}
bool ArrayType::ConstructData(JSContext* cx, HandleObject obj_,
const CallArgs& args) {
RootedObject obj(cx, obj_); // Make a mutable version
if (!CType::IsCType(obj) || CType::GetTypeCode(obj) != TYPE_array) {
return IncompatibleCallee(cx, "ArrayType constructor", obj);
}
// Decide whether we have an object to initialize from. We'll override this
// if we get a length argument instead.
bool convertObject = args.length() == 1;
// Check if we're an array of undefined length. If we are, allow construction
// with a length argument, or with an actual JS array.
if (CType::IsSizeDefined(obj)) {
if (args.length() > 1) {
return ArgumentLengthError(cx, "size defined ArrayType constructor",
"at most one", "");
}
} else {
if (args.length() != 1) {
return ArgumentLengthError(cx, "size undefined ArrayType constructor",
"one", "");
}
RootedObject baseType(cx, GetBaseType(obj));
size_t length;
if (jsvalToSize(cx, args[0], false, &length)) {
// Have a length, rather than an object to initialize from.
convertObject = false;
} else if (args[0].isObject()) {
// We were given an object with a .length property.
// This could be a JS array, or a CData array.
RootedObject arg(cx, &args[0].toObject());
RootedValue lengthVal(cx);
if (!JS_GetProperty(cx, arg, "length", &lengthVal) ||
!jsvalToSize(cx, lengthVal, false, &length)) {
return ArgumentTypeMismatch(cx, "",
"size undefined ArrayType constructor",
"an array object or integer");
}
} else if (args[0].isString()) {
// We were given a string. Size the array to the appropriate length,
// including space for the terminator.
JSString* sourceString = args[0].toString();
size_t sourceLength = sourceString->length();
Rooted<JSLinearString*> sourceLinear(cx, sourceString->ensureLinear(cx));
if (!sourceLinear) {
return false;
}
switch (CType::GetTypeCode(baseType)) {
case TYPE_char:
case TYPE_signed_char:
case TYPE_unsigned_char: {
// Reject if unpaired surrogate characters are present.
if (!ReportErrorIfUnpairedSurrogatePresent(cx, sourceLinear)) {
return false;
}
// Determine the UTF-8 length.
length = JS::GetDeflatedUTF8StringLength(sourceLinear);
++length;
break;
}
case TYPE_char16_t:
length = sourceLength + 1;
break;
default:
return ConvError(cx, obj, args[0], ConversionType::Construct);
}
} else {
return ArgumentTypeMismatch(cx, "",
"size undefined ArrayType constructor",
"an array object or integer");
}
// Construct a new ArrayType of defined length, for the new CData object.
obj = CreateInternal(cx, baseType, length, true);
if (!obj) {
return false;
}
}
JSObject* result = CData::Create(cx, obj, nullptr, nullptr, true);
if (!result) {
return false;
}
args.rval().setObject(*result);
if (convertObject) {
if (!ExplicitConvert(cx, args[0], obj, CData::GetData(result),
ConversionType::Construct))
return false;
}
return true;
}
JSObject* ArrayType::GetBaseType(JSObject* obj) {
MOZ_ASSERT(CType::IsCType(obj));
MOZ_ASSERT(CType::GetTypeCode(obj) == TYPE_array);
Value type = JS::GetReservedSlot(obj, SLOT_ELEMENT_T);
MOZ_ASSERT(!type.isNull());
return &type.toObject();
}
bool ArrayType::GetSafeLength(JSObject* obj, size_t* result) {
MOZ_ASSERT(CType::IsCType(obj));
MOZ_ASSERT(CType::GetTypeCode(obj) == TYPE_array);
Value length = JS::GetReservedSlot(obj, SLOT_LENGTH);
// The "length" property can be an int, a double, or JS::UndefinedValue()
// (for arrays of undefined length), and must always fit in a size_t.
if (length.isInt32()) {
*result = length.toInt32();
return true;
}
if (length.isDouble()) {
*result = Convert<size_t>(length.toDouble());
return true;
}
MOZ_ASSERT(length.isUndefined());
return false;
}
size_t ArrayType::GetLength(JSObject* obj) {
MOZ_ASSERT(CType::IsCType(obj));
MOZ_ASSERT(CType::GetTypeCode(obj) == TYPE_array);
Value length = JS::GetReservedSlot(obj, SLOT_LENGTH);
MOZ_ASSERT(!length.isUndefined());
// The "length" property can be an int, a double, or JS::UndefinedValue()
// (for arrays of undefined length), and must always fit in a size_t.
// For callers who know it can never be JS::UndefinedValue(), return a size_t
// directly.
if (length.isInt32()) {
return length.toInt32();
}
return Convert<size_t>(length.toDouble());
}
UniquePtrFFIType ArrayType::BuildFFIType(JSContext* cx, JSObject* obj) {
MOZ_ASSERT(CType::IsCType(obj));
MOZ_ASSERT(CType::GetTypeCode(obj) == TYPE_array);
MOZ_ASSERT(CType::IsSizeDefined(obj));
JSObject* baseType = ArrayType::GetBaseType(obj);
ffi_type* ffiBaseType = CType::GetFFIType(cx, baseType);
if (!ffiBaseType) {
return nullptr;
}
size_t length = ArrayType::GetLength(obj);
// Create an ffi_type to represent the array. This is necessary for the case
// where the array is part of a struct. Since libffi has no intrinsic
// support for array types, we approximate it by creating a struct type
// with elements of type 'baseType' and with appropriate size and alignment
// values. It would be nice to not do all the work of setting up 'elements',
// but some libffi platforms currently require that it be meaningful. I'm
// looking at you, x86_64.
auto ffiType = cx->make_unique<ffi_type>();
if (!ffiType) {
return nullptr;
}
ffiType->type = FFI_TYPE_STRUCT;
ffiType->size = CType::GetSize(obj);
ffiType->alignment = CType::GetAlignment(obj);
ffiType->elements = cx->pod_malloc<ffi_type*>(length + 1);
if (!ffiType->elements) {
return nullptr;
}
for (size_t i = 0; i < length; ++i) {
ffiType->elements[i] = ffiBaseType;
}
ffiType->elements[length] = nullptr;
return ffiType;
}
bool ArrayType::IsArrayType(HandleValue v) {
if (!v.isObject()) {
return false;
}
JSObject* obj = &v.toObject();
return CType::IsCType(obj) && CType::GetTypeCode(obj) == TYPE_array;
}
bool ArrayType::IsArrayOrArrayType(HandleValue v) {
if (!v.isObject()) {
return false;
}
JSObject* obj = MaybeUnwrapArrayWrapper(&v.toObject());
// Allow both CTypes and CDatas of the ArrayType persuasion by extracting the
// CType if we're dealing with a CData.
if (CData::IsCData(obj)) {
obj = CData::GetCType(obj);
}
return CType::IsCType(obj) && CType::GetTypeCode(obj) == TYPE_array;
}
bool ArrayType::ElementTypeGetter(JSContext* cx, const JS::CallArgs& args) {
RootedObject obj(cx, &args.thisv().toObject());
args.rval().set(JS::GetReservedSlot(obj, SLOT_ELEMENT_T));
MOZ_ASSERT(args.rval().isObject());
return true;
}
bool ArrayType::LengthGetter(JSContext* cx, const JS::CallArgs& args) {
RootedObject obj(cx, &args.thisv().toObject());
// This getter exists for both CTypes and CDatas of the ArrayType persuasion.
// If we're dealing with a CData, get the CType from it.
if (CData::IsCDataMaybeUnwrap(&obj)) {
obj = CData::GetCType(obj);
}
args.rval().set(JS::GetReservedSlot(obj, SLOT_LENGTH));
MOZ_ASSERT(args.rval().isNumber() || args.rval().isUndefined());
return true;
}
bool ArrayType::Getter(JSContext* cx, HandleObject obj, HandleId idval,
MutableHandleValue vp, bool* handled) {
*handled = false;
// This should never happen, but we'll check to be safe.
if (!CData::IsCData(obj)) {
RootedValue objVal(cx, ObjectValue(*obj));
return IncompatibleThisProto(cx, "ArrayType property getter", objVal);
}
// Bail early if we're not an ArrayType. (This setter is present for all
// CData, regardless of CType.)
JSObject* typeObj = CData::GetCType(obj);
if (CType::GetTypeCode(typeObj) != TYPE_array) {
return true;
}
// Convert the index to a size_t and bounds-check it.
size_t index;
size_t length = GetLength(typeObj);
bool ok = jsidToSize(cx, idval, true, &index);
int32_t dummy;
if (!ok && idval.isSymbol()) {
return true;
}
bool dummy2;
if (!ok && idval.isString() &&
!StringToInteger(cx, idval.toString(), &dummy, &dummy2)) {
// String either isn't a number, or doesn't fit in size_t.
// Chances are it's a regular property lookup, so return.
return true;
}
if (!ok) {
return InvalidIndexError(cx, idval);
}
if (index >= length) {
return InvalidIndexRangeError(cx, index, length);
}
*handled = true;
RootedObject baseType(cx, GetBaseType(typeObj));
size_t elementSize = CType::GetSize(baseType);
char* data = static_cast<char*>(CData::GetData(obj)) + elementSize * index;
return ConvertToJS(cx, baseType, obj, data, false, false, vp);
}
bool ArrayType::Setter(JSContext* cx, HandleObject obj, HandleId idval,
HandleValue vp, ObjectOpResult& result, bool* handled) {
*handled = false;
// This should never happen, but we'll check to be safe.
if (!CData::IsCData(obj)) {
RootedValue objVal(cx, ObjectValue(*obj));
return IncompatibleThisProto(cx, "ArrayType property setter", objVal);
}
// Bail early if we're not an ArrayType. (This setter is present for all
// CData, regardless of CType.)
RootedObject typeObj(cx, CData::GetCType(obj));
if (CType::GetTypeCode(typeObj) != TYPE_array) {
return result.succeed();
}
// Convert the index to a size_t and bounds-check it.
size_t index;
size_t length = GetLength(typeObj);
bool ok = jsidToSize(cx, idval, true, &index);
int32_t dummy;
if (!ok && idval.isSymbol()) {
return true;
}
bool dummy2;
if (!ok && idval.isString() &&
!StringToInteger(cx, idval.toString(), &dummy, &dummy2)) {
// String either isn't a number, or doesn't fit in size_t.
// Chances are it's a regular property lookup, so return.
return result.succeed();
}
if (!ok) {
return InvalidIndexError(cx, idval);
}
if (index >= length) {
return InvalidIndexRangeError(cx, index, length);
}
*handled = true;
RootedObject baseType(cx, GetBaseType(typeObj));
size_t elementSize = CType::GetSize(baseType);
char* data = static_cast<char*>(CData::GetData(obj)) + elementSize * index;
if (!ImplicitConvert(cx, vp, baseType, data, ConversionType::Setter, nullptr,
nullptr, 0, typeObj, index))
return false;
return result.succeed();
}
bool ArrayType::AddressOfElement(JSContext* cx, unsigned argc, Value* vp) {
CallArgs args = CallArgsFromVp(argc, vp);
RootedObject obj(
cx, GetThisObject(cx, args, "ArrayType.prototype.addressOfElement"));
if (!obj) {
return false;
}
if (!CData::IsCDataMaybeUnwrap(&obj)) {
return IncompatibleThisProto(cx, "ArrayType.prototype.addressOfElement",
args.thisv());
}
RootedObject typeObj(cx, CData::GetCType(obj));
if (CType::GetTypeCode(typeObj) != TYPE_array) {
return IncompatibleThisType(cx, "ArrayType.prototype.addressOfElement",
"non-ArrayType CData", args.thisv());
}
if (args.length() != 1) {
return ArgumentLengthError(cx, "ArrayType.prototype.addressOfElement",
"one", "");
}
RootedObject baseType(cx, GetBaseType(typeObj));
RootedObject pointerType(cx, PointerType::CreateInternal(cx, baseType));
if (!pointerType) {
return false;
}
// Create a PointerType CData object containing null.
RootedObject result(cx,
CData::Create(cx, pointerType, nullptr, nullptr, true));
if (!result) {
return false;
}
args.rval().setObject(*result);
// Convert the index to a size_t and bounds-check it.
size_t index;
size_t length = GetLength(typeObj);
if (!jsvalToSize(cx, args[0], false, &index)) {
return InvalidIndexError(cx, args[0]);
}
if (index >= length) {
return InvalidIndexRangeError(cx, index, length);
}
// Manually set the pointer inside the object, so we skip the conversion step.
void** data = static_cast<void**>(CData::GetData(result));
size_t elementSize = CType::GetSize(baseType);
*data = static_cast<char*>(CData::GetData(obj)) + elementSize * index;
return true;
}
/*******************************************************************************
** StructType implementation
*******************************************************************************/
// For a struct field descriptor 'val' of the form { name : type }, extract
// 'name' and 'type'.
static JSLinearString* ExtractStructField(JSContext* cx, HandleValue val,
MutableHandleObject typeObj) {
if (val.isPrimitive()) {
FieldDescriptorNameTypeError(cx, val);
return nullptr;
}
RootedObject obj(cx, &val.toObject());
Rooted<IdVector> props(cx, IdVector(cx));
if (!JS_Enumerate(cx, obj, &props)) {
return nullptr;
}
// make sure we have one, and only one, property
if (props.length() != 1) {
FieldDescriptorCountError(cx, val, props.length());
return nullptr;
}
RootedId nameid(cx, props[0]);
if (!nameid.isString()) {
FieldDescriptorNameError(cx, nameid);
return nullptr;
}
RootedValue propVal(cx);
if (!JS_GetPropertyById(cx, obj, nameid, &propVal)) {
return nullptr;
}
if (propVal.isPrimitive() || !CType::IsCType(&propVal.toObject())) {
FieldDescriptorTypeError(cx, propVal, nameid);
return nullptr;
}
// Undefined size or zero size struct members are illegal.
// (Zero-size arrays are legal as struct members in C++, but libffi will
// choke on a zero-size struct, so we disallow them.)
typeObj.set(&propVal.toObject());
size_t size;
if (!CType::GetSafeSize(typeObj, &size) || size == 0) {
FieldDescriptorSizeError(cx, typeObj, nameid);
return nullptr;
}
return nameid.toLinearString();
}
// For a struct field with 'name' and 'type', add an element of the form
// { name : type }.
static bool AddFieldToArray(JSContext* cx, MutableHandleValue element,
JSLinearString* name_, JSObject* typeObj_) {
RootedObject typeObj(cx, typeObj_);
Rooted<JSLinearString*> name(cx, name_);
RootedObject fieldObj(cx, JS_NewPlainObject(cx));
if (!fieldObj) {
return false;
}
element.setObject(*fieldObj);
AutoStableStringChars nameChars(cx);
if (!nameChars.initTwoByte(cx, name)) {
return false;
}
if (!JS_DefineUCProperty(
cx, fieldObj, nameChars.twoByteChars(), name->length(), typeObj,
JSPROP_ENUMERATE | JSPROP_READONLY | JSPROP_PERMANENT))
return false;
return JS_FreezeObject(cx, fieldObj);
}
bool StructType::Create(JSContext* cx, unsigned argc, Value* vp) {
CallArgs args = CallArgsFromVp(argc, vp);
// Construct and return a new StructType object.
if (args.length() < 1 || args.length() > 2) {
return ArgumentLengthError(cx, "StructType", "one or two", "s");
}
Value name = args[0];
if (!name.isString()) {
return ArgumentTypeMismatch(cx, "first ", "StructType", "a string");
}
// Get ctypes.StructType.prototype from the ctypes.StructType constructor.
RootedObject typeProto(
cx, CType::GetProtoFromCtor(&args.callee(), SLOT_STRUCTPROTO));
// Create a simple StructType with no defined fields. The result will be
// non-instantiable as CData, will have no 'prototype' property, and will
// have undefined size and alignment and no ffi_type.
RootedObject result(
cx, CType::Create(cx, typeProto, nullptr, TYPE_struct, name.toString(),
JS::UndefinedHandleValue, JS::UndefinedHandleValue,
nullptr));
if (!result) {
return false;
}
if (args.length() == 2) {
RootedObject arr(cx, args[1].isObject() ? &args[1].toObject() : nullptr);
bool isArray;
if (!arr) {
isArray = false;
} else {
if (!JS::IsArrayObject(cx, arr, &isArray)) {
return false;
}
}
if (!isArray) {
return ArgumentTypeMismatch(cx, "second ", "StructType", "an array");
}
// Define the struct fields.
if (!DefineInternal(cx, result, arr)) {
return false;
}
}
args.rval().setObject(*result);
return true;
}
bool StructType::DefineInternal(JSContext* cx, JSObject* typeObj_,
JSObject* fieldsObj_) {
RootedObject typeObj(cx, typeObj_);
RootedObject fieldsObj(cx, fieldsObj_);
uint32_t len;
MOZ_ALWAYS_TRUE(JS::GetArrayLength(cx, fieldsObj, &len));
// Get the common prototype for CData objects of this type from
// ctypes.CType.prototype.
RootedObject dataProto(
cx, CType::GetProtoFromType(cx, typeObj, SLOT_STRUCTDATAPROTO));
if (!dataProto) {
return false;
}
// Set up the 'prototype' and 'prototype.constructor' properties.
// The prototype will reflect the struct fields as properties on CData objects
// created from this type.
RootedObject prototype(
cx, JS_NewObjectWithGivenProto(cx, &sCDataProtoClass, dataProto));
if (!prototype) {
return false;
}
if (!JS_DefineProperty(cx, prototype, "constructor", typeObj,
JSPROP_READONLY | JSPROP_PERMANENT))
return false;
// Create a FieldInfoHash to stash on the type object.
Rooted<FieldInfoHash> fields(cx, FieldInfoHash(cx->zone(), len));
// Process the field types.
size_t structSize, structAlign;
if (len != 0) {
structSize = 0;
structAlign = 0;
for (uint32_t i = 0; i < len; ++i) {
RootedValue item(cx);
if (!JS_GetElement(cx, fieldsObj, i, &item)) {
return false;
}
RootedObject fieldType(cx, nullptr);
Rooted<JSLinearString*> name(cx,
ExtractStructField(cx, item, &fieldType));
if (!name) {
return false;
}
// Make sure each field name is unique
FieldInfoHash::AddPtr entryPtr = fields.lookupForAdd(name);
if (entryPtr) {
return DuplicateFieldError(cx, name);
}
// Add the field to the StructType's 'prototype' property.
AutoStableStringChars nameChars(cx);
if (!nameChars.initTwoByte(cx, name)) {
return false;
}
RootedFunction getter(
cx,
NewFunctionWithReserved(cx, StructType::FieldGetter, 0, 0, nullptr));
if (!getter) {
return false;
}
SetFunctionNativeReserved(getter, StructType::SLOT_FIELDNAME,
StringValue(JS_FORGET_STRING_LINEARNESS(name)));
RootedObject getterObj(cx, JS_GetFunctionObject(getter));
RootedFunction setter(
cx,
NewFunctionWithReserved(cx, StructType::FieldSetter, 1, 0, nullptr));
if (!setter) {
return false;
}
SetFunctionNativeReserved(setter, StructType::SLOT_FIELDNAME,
StringValue(JS_FORGET_STRING_LINEARNESS(name)));
RootedObject setterObj(cx, JS_GetFunctionObject(setter));
if (!JS_DefineUCProperty(cx, prototype, nameChars.twoByteChars(),
name->length(), getterObj, setterObj,
JSPROP_ENUMERATE | JSPROP_PERMANENT)) {
return false;
}
size_t fieldSize = CType::GetSize(fieldType);
size_t fieldAlign = CType::GetAlignment(fieldType);
size_t fieldOffset = Align(structSize, fieldAlign);
// Check for overflow. Since we hold invariant that fieldSize % fieldAlign
// be zero, we can safely check fieldOffset + fieldSize without first
// checking fieldOffset for overflow.
if (fieldOffset + fieldSize < structSize) {
SizeOverflow(cx, "struct size", "size_t");
return false;
}
// Add field name to the hash
FieldInfo info;
info.mType = fieldType;
info.mIndex = i;
info.mOffset = fieldOffset;
if (!fields.add(entryPtr, name, info)) {
JS_ReportOutOfMemory(cx);
return false;
}
structSize = fieldOffset + fieldSize;
if (fieldAlign > structAlign) {
structAlign = fieldAlign;
}
}
// Pad the struct tail according to struct alignment.
size_t structTail = Align(structSize, structAlign);
if (structTail < structSize) {
SizeOverflow(cx, "struct size", "size_t");
return false;
}
structSize = structTail;
} else {
// Empty structs are illegal in C, but are legal and have a size of
// 1 byte in C++. We're going to allow them, and trick libffi into
// believing this by adding a char member. The resulting struct will have
// no getters or setters, and will be initialized to zero.
structSize = 1;
structAlign = 1;
}
RootedValue sizeVal(cx);
if (!SizeTojsval(cx, structSize, &sizeVal)) {
SizeOverflow(cx, "struct size", "double");
return false;
}
// Move the field hash to the heap and store it in the typeObj.
FieldInfoHash* heapHash = cx->new_<FieldInfoHash>(std::move(fields.get()));
if (!heapHash) {
JS_ReportOutOfMemory(cx);
return false;
}
JS_InitReservedSlot(typeObj, SLOT_FIELDINFO, heapHash,
JS::MemoryUse::CTypeFieldInfo);
JS_SetReservedSlot(typeObj, SLOT_SIZE, sizeVal);
JS_SetReservedSlot(typeObj, SLOT_ALIGN, Int32Value(structAlign));
// return false;
JS_SetReservedSlot(typeObj, SLOT_PROTO, ObjectValue(*prototype));
return true;
}
UniquePtrFFIType StructType::BuildFFIType(JSContext* cx, JSObject* obj) {
MOZ_ASSERT(CType::IsCType(obj));
MOZ_ASSERT(CType::GetTypeCode(obj) == TYPE_struct);
MOZ_ASSERT(CType::IsSizeDefined(obj));
const FieldInfoHash* fields = GetFieldInfo(obj);
size_t len = fields->count();
size_t structSize = CType::GetSize(obj);
size_t structAlign = CType::GetAlignment(obj);
auto ffiType = cx->make_unique<ffi_type>();
if (!ffiType) {
return nullptr;
}
ffiType->type = FFI_TYPE_STRUCT;
size_t count = len != 0 ? len + 1 : 2;
auto elements = cx->make_pod_array<ffi_type*>(count);
if (!elements) {
return nullptr;
}
if (len != 0) {
elements[len] = nullptr;
for (FieldInfoHash::Range r = fields->all(); !r.empty(); r.popFront()) {
const FieldInfoHash::Entry& entry = r.front();
ffi_type* fieldType = CType::GetFFIType(cx, entry.value().mType);
if (!fieldType) {
return nullptr;
}
elements[entry.value().mIndex] = fieldType;
}
} else {
// Represent an empty struct as having a size of 1 byte, just like C++.
MOZ_ASSERT(structSize == 1);
MOZ_ASSERT(structAlign == 1);
elements[0] = &ffi_type_uint8;
elements[1] = nullptr;
}
ffiType->elements = elements.release();
AddCellMemory(obj, count * sizeof(ffi_type*),
MemoryUse::CTypeFFITypeElements);
#ifdef DEBUG
// Perform a sanity check: the result of our struct size and alignment
// calculations should match libffi's. We force it to do this calculation
// by calling ffi_prep_cif.
ffi_cif cif;
ffiType->size = 0;
ffiType->alignment = 0;
ffi_status status =
ffi_prep_cif(&cif, FFI_DEFAULT_ABI, 0, ffiType.get(), nullptr);
MOZ_ASSERT(status == FFI_OK);
MOZ_ASSERT(structSize == ffiType->size);
MOZ_ASSERT(structAlign == ffiType->alignment);
#else
// Fill in the ffi_type's size and align fields. This makes libffi treat the
// type as initialized; it will not recompute the values. (We assume
// everything agrees; if it doesn't, we really want to know about it, which
// is the purpose of the above debug-only check.)
ffiType->size = structSize;
ffiType->alignment = structAlign;
#endif
return ffiType;
}
bool StructType::Define(JSContext* cx, unsigned argc, Value* vp) {
CallArgs args = CallArgsFromVp(argc, vp);
RootedObject obj(cx, GetThisObject(cx, args, "StructType.prototype.define"));
if (!obj) {
return false;
}
if (!CType::IsCType(obj)) {
return IncompatibleThisProto(cx, "StructType.prototype.define",
args.thisv());
}
if (CType::GetTypeCode(obj) != TYPE_struct) {
return IncompatibleThisType(cx, "StructType.prototype.define",
"non-StructType", args.thisv());
}
if (CType::IsSizeDefined(obj)) {
JS_ReportErrorASCII(cx, "StructType has already been defined");
return false;
}
if (args.length() != 1) {
return ArgumentLengthError(cx, "StructType.prototype.define", "one", "");
}
HandleValue arg = args[0];
if (arg.isPrimitive()) {
return ArgumentTypeMismatch(cx, "", "StructType.prototype.define",
"an array");
}
bool isArray;
if (!arg.isObject()) {
isArray = false;
} else {
if (!JS::IsArrayObject(cx, arg, &isArray)) {
return false;
}
}
if (!isArray) {
return ArgumentTypeMismatch(cx, "", "StructType.prototype.define",
"an array");
}
RootedObject arr(cx, &arg.toObject());
return DefineInternal(cx, obj, arr);
}
bool StructType::ConstructData(JSContext* cx, HandleObject obj,
const CallArgs& args) {
if (!CType::IsCType(obj) || CType::GetTypeCode(obj) != TYPE_struct) {
return IncompatibleCallee(cx, "StructType constructor", obj);
}
if (!CType::IsSizeDefined(obj)) {
JS_ReportErrorASCII(cx, "cannot construct an opaque StructType");
return false;
}
JSObject* result = CData::Create(cx, obj, nullptr, nullptr, true);
if (!result) {
return false;
}
args.rval().setObject(*result);
if (args.length() == 0) {
return true;
}
char* buffer = static_cast<char*>(CData::GetData(result));
const FieldInfoHash* fields = GetFieldInfo(obj);
if (args.length() == 1) {
// There are two possible interpretations of the argument:
// 1) It may be an object '{ ... }' with properties representing the
// struct fields intended to ExplicitConvert wholesale to our StructType.
// 2) If the struct contains one field, the arg may be intended to
// ImplicitConvert directly to that arg's CType.
// Thankfully, the conditions for these two possibilities to succeed
// are mutually exclusive, so we can pick the right one.
// Try option 1) first.
if (ExplicitConvert(cx, args[0], obj, buffer, ConversionType::Construct)) {
return true;
}
if (fields->count() != 1) {
return false;
}
// If ExplicitConvert failed, and there is no pending exception, then assume
// hard failure (out of memory, or some other similarly serious condition).
if (!JS_IsExceptionPending(cx)) {
return false;
}
// Otherwise, assume soft failure, and clear the pending exception so that
// we can throw a different one as required.
JS_ClearPendingException(cx);
// Fall through to try option 2).
}
// We have a type constructor of the form 'ctypes.StructType(a, b, c, ...)'.
// ImplicitConvert each field.
if (args.length() == fields->count()) {
for (FieldInfoHash::Range r = fields->all(); !r.empty(); r.popFront()) {
const FieldInfo& field = r.front().value();
MOZ_ASSERT(field.mIndex < fields->count()); /* Quantified invariant */
if (!ImplicitConvert(cx, args[field.mIndex], field.mType,
buffer + field.mOffset, ConversionType::Construct,
nullptr, nullptr, 0, obj, field.mIndex))
return false;
}
return true;
}
size_t count = fields->count();
if (count >= 2) {
char fieldLengthStr[32];
SprintfLiteral(fieldLengthStr, "0, 1, or %zu", count);
return ArgumentLengthError(cx, "StructType constructor", fieldLengthStr,
"s");
}
return ArgumentLengthError(cx, "StructType constructor", "at most one", "");
}
const FieldInfoHash* StructType::GetFieldInfo(JSObject* obj) {
MOZ_ASSERT(CType::IsCType(obj));
MOZ_ASSERT(CType::GetTypeCode(obj) == TYPE_struct);
Value slot = JS::GetReservedSlot(obj, SLOT_FIELDINFO);
MOZ_ASSERT(!slot.isUndefined() && slot.toPrivate());
return static_cast<const FieldInfoHash*>(slot.toPrivate());
}
const FieldInfo* StructType::LookupField(JSContext* cx, JSObject* obj,
JSLinearString* name) {
MOZ_ASSERT(CType::IsCType(obj));
MOZ_ASSERT(CType::GetTypeCode(obj) == TYPE_struct);
FieldInfoHash::Ptr ptr = GetFieldInfo(obj)->lookup(name);
if (ptr) {
return &ptr->value();
}
FieldMissingError(cx, obj, name);
return nullptr;
}
JSObject* StructType::BuildFieldsArray(JSContext* cx, JSObject* obj) {
MOZ_ASSERT(CType::IsCType(obj));
MOZ_ASSERT(CType::GetTypeCode(obj) == TYPE_struct);
MOZ_ASSERT(CType::IsSizeDefined(obj));
const FieldInfoHash* fields = GetFieldInfo(obj);
size_t len = fields->count();
// Prepare a new array for the 'fields' property of the StructType.
JS::RootedValueVector fieldsVec(cx);
if (!fieldsVec.resize(len)) {
return nullptr;
}
for (FieldInfoHash::Range r = fields->all(); !r.empty(); r.popFront()) {
const FieldInfoHash::Entry& entry = r.front();
// Add the field descriptor to the array.
if (!AddFieldToArray(cx, fieldsVec[entry.value().mIndex], entry.key(),
entry.value().mType))
return nullptr;
}
RootedObject fieldsProp(cx, JS::NewArrayObject(cx, fieldsVec));
if (!fieldsProp) {
return nullptr;
}
// Seal the fields array.
if (!JS_FreezeObject(cx, fieldsProp)) {
return nullptr;
}
return fieldsProp;
}
/* static */
bool StructType::IsStruct(HandleValue v) {
if (!v.isObject()) {
return false;
}
JSObject* obj = &v.toObject();
return CType::IsCType(obj) && CType::GetTypeCode(obj) == TYPE_struct;
}
bool StructType::FieldsArrayGetter(JSContext* cx, const JS::CallArgs& args) {
RootedObject obj(cx, &args.thisv().toObject());
args.rval().set(JS::GetReservedSlot(obj, SLOT_FIELDS));
if (!CType::IsSizeDefined(obj)) {
MOZ_ASSERT(args.rval().isUndefined());
return true;
}
if (args.rval().isUndefined()) {
// Build the 'fields' array lazily.
JSObject* fields = BuildFieldsArray(cx, obj);
if (!fields) {
return false;
}
JS_SetReservedSlot(obj, SLOT_FIELDS, ObjectValue(*fields));
args.rval().setObject(*fields);
}
MOZ_ASSERT(args.rval().isObject());
return true;
}
bool StructType::FieldGetter(JSContext* cx, unsigned argc, Value* vp) {
CallArgs args = CallArgsFromVp(argc, vp);
if (!args.thisv().isObject()) {
return IncompatibleThisProto(cx, "StructType property getter",
args.thisv());
}
RootedObject obj(cx, &args.thisv().toObject());
if (!CData::IsCDataMaybeUnwrap(&obj)) {
return IncompatibleThisProto(cx, "StructType property getter",
args.thisv());
}
JSObject* typeObj = CData::GetCType(obj);
if (CType::GetTypeCode(typeObj) != TYPE_struct) {
return IncompatibleThisType(cx, "StructType property getter",
"non-StructType CData", args.thisv());
}
RootedValue nameVal(
cx, GetFunctionNativeReserved(&args.callee(), SLOT_FIELDNAME));
Rooted<JSLinearString*> name(cx,
JS_EnsureLinearString(cx, nameVal.toString()));
if (!name) {
return false;
}
const FieldInfo* field = LookupField(cx, typeObj, name);
if (!field) {
return false;
}
char* data = static_cast<char*>(CData::GetData(obj)) + field->mOffset;
RootedObject fieldType(cx, field->mType);
return ConvertToJS(cx, fieldType, obj, data, false, false, args.rval());
}
bool StructType::FieldSetter(JSContext* cx, unsigned argc, Value* vp) {
CallArgs args = CallArgsFromVp(argc, vp);
if (!args.thisv().isObject()) {
return IncompatibleThisProto(cx, "StructType property setter",
args.thisv());
}
RootedObject obj(cx, &args.thisv().toObject());
if (!CData::IsCDataMaybeUnwrap(&obj)) {
return IncompatibleThisProto(cx, "StructType property setter",
args.thisv());
}
RootedObject typeObj(cx, CData::GetCType(obj));
if (CType::GetTypeCode(typeObj) != TYPE_struct) {
return IncompatibleThisType(cx, "StructType property setter",
"non-StructType CData", args.thisv());
}
RootedValue nameVal(
cx, GetFunctionNativeReserved(&args.callee(), SLOT_FIELDNAME));
Rooted<JSLinearString*> name(cx,
JS_EnsureLinearString(cx, nameVal.toString()));
if (!name) {
return false;
}
const FieldInfo* field = LookupField(cx, typeObj, name);
if (!field) {
return false;
}
args.rval().setUndefined();
char* data = static_cast<char*>(CData::GetData(obj)) + field->mOffset;
return ImplicitConvert(cx, args.get(0), field->mType, data,
ConversionType::Setter, nullptr, nullptr, 0, typeObj,
field->mIndex);
}
bool StructType::AddressOfField(JSContext* cx, unsigned argc, Value* vp) {
CallArgs args = CallArgsFromVp(argc, vp);
RootedObject obj(
cx, GetThisObject(cx, args, "StructType.prototype.addressOfField"));
if (!obj) {
return false;
}
if (!CData::IsCDataMaybeUnwrap(&obj)) {
return IncompatibleThisProto(cx, "StructType.prototype.addressOfField",
args.thisv());
}
JSObject* typeObj = CData::GetCType(obj);
if (CType::GetTypeCode(typeObj) != TYPE_struct) {
return IncompatibleThisType(cx, "StructType.prototype.addressOfField",
"non-StructType CData", args.thisv());
}
if (args.length() != 1) {
return ArgumentLengthError(cx, "StructType.prototype.addressOfField", "one",
"");
}
if (!args[0].isString()) {
return ArgumentTypeMismatch(cx, "", "StructType.prototype.addressOfField",
"a string");
}
JSLinearString* str = JS_EnsureLinearString(cx, args[0].toString());
if (!str) {
return false;
}
const FieldInfo* field = LookupField(cx, typeObj, str);
if (!field) {
return false;
}
RootedObject baseType(cx, field->mType);
RootedObject pointerType(cx, PointerType::CreateInternal(cx, baseType));
if (!pointerType) {
return false;
}
// Create a PointerType CData object containing null.
JSObject* result = CData::Create(cx, pointerType, nullptr, nullptr, true);
if (!result) {
return false;
}
args.rval().setObject(*result);
// Manually set the pointer inside the object, so we skip the conversion step.
void** data = static_cast<void**>(CData::GetData(result));
*data = static_cast<char*>(CData::GetData(obj)) + field->mOffset;
return true;
}
/*******************************************************************************
** FunctionType implementation
*******************************************************************************/
// Helper class for handling allocation of function arguments.
struct AutoValue {
AutoValue() : mData(nullptr) {}
~AutoValue() { js_free(mData); }
bool SizeToType(JSContext* cx, JSObject* type) {
// Allocate a minimum of sizeof(ffi_arg) to handle small integers.
size_t size = Align(CType::GetSize(type), sizeof(ffi_arg));
mData = js_calloc(size);
return mData != nullptr;
}
void* mData;
};
static bool GetABI(JSContext* cx, HandleValue abiType, ffi_abi* result) {
if (abiType.isPrimitive()) {
return false;
}
ABICode abi = GetABICode(abiType.toObjectOrNull());
// determine the ABI from the subset of those available on the
// given platform. ABI_DEFAULT specifies the default
// C calling convention (cdecl) on each platform.
switch (abi) {
case ABI_DEFAULT:
*result = FFI_DEFAULT_ABI;
return true;
case ABI_THISCALL:
#if defined(_WIN64)
# if defined(_M_X64)
*result = FFI_WIN64;
# elif defined(_M_ARM64)
*result = FFI_SYSV;
# else
# error unknown 64-bit Windows platform
# endif
return true;
#elif defined(_WIN32)
*result = FFI_THISCALL;
return true;
#else
break;
#endif
case ABI_STDCALL:
case ABI_WINAPI:
#if (defined(_WIN32) && !defined(_WIN64)) || defined(_OS2)
*result = FFI_STDCALL;
return true;
#elif (defined(_WIN64))
// We'd like the same code to work across Win32 and Win64, so stdcall_api
// and winapi_abi become aliases to the lone Win64 ABI.
# if defined(_M_X64)
*result = FFI_WIN64;
# elif defined(_M_ARM64)
*result = FFI_SYSV;
# else
# error unknown 64-bit Windows platform
# endif
return true;
#endif
case INVALID_ABI:
break;
}
return false;
}
static JSObject* PrepareType(JSContext* cx, uint32_t index, HandleValue type) {
if (type.isPrimitive() || !CType::IsCType(type.toObjectOrNull())) {
FunctionArgumentTypeError(cx, index, type, "is not a ctypes type");
return nullptr;
}
JSObject* result = type.toObjectOrNull();
TypeCode typeCode = CType::GetTypeCode(result);
if (typeCode == TYPE_array) {
// convert array argument types to pointers, just like C.
// ImplicitConvert will do the same, when passing an array as data.
RootedObject baseType(cx, ArrayType::GetBaseType(result));
result = PointerType::CreateInternal(cx, baseType);
if (!result) {
return nullptr;
}
} else if (typeCode == TYPE_void_t || typeCode == TYPE_function) {
// disallow void or function argument types
FunctionArgumentTypeError(cx, index, type, "cannot be void or function");
return nullptr;
}
if (!CType::IsSizeDefined(result)) {
FunctionArgumentTypeError(cx, index, type, "must have defined size");
return nullptr;
}
// libffi cannot pass types of zero size by value.
MOZ_ASSERT(CType::GetSize(result) != 0);
return result;
}
static JSObject* PrepareReturnType(JSContext* cx, HandleValue type) {
if (type.isPrimitive() || !CType::IsCType(type.toObjectOrNull())) {
FunctionReturnTypeError(cx, type, "is not a ctypes type");
return nullptr;
}
JSObject* result = type.toObjectOrNull();
TypeCode typeCode = CType::GetTypeCode(result);
// Arrays and functions can never be return types.
if (typeCode == TYPE_array || typeCode == TYPE_function) {
FunctionReturnTypeError(cx, type, "cannot be an array or function");
return nullptr;
}
if (typeCode != TYPE_void_t && !CType::IsSizeDefined(result)) {
FunctionReturnTypeError(cx, type, "must have defined size");
return nullptr;
}
// libffi cannot pass types of zero size by value.
MOZ_ASSERT(typeCode == TYPE_void_t || CType::GetSize(result) != 0);
return result;
}
static MOZ_ALWAYS_INLINE bool IsEllipsis(JSContext* cx, HandleValue v,
bool* isEllipsis) {
*isEllipsis = false;
if (!v.isString()) {
return true;
}
JSString* str = v.toString();
if (str->length() != 3) {
return true;
}
JSLinearString* linear = str->ensureLinear(cx);
if (!linear) {
return false;
}
char16_t dot = '.';
*isEllipsis = (linear->latin1OrTwoByteChar(0) == dot &&
linear->latin1OrTwoByteChar(1) == dot &&
linear->latin1OrTwoByteChar(2) == dot);
return true;
}
static bool PrepareCIF(JSContext* cx, FunctionInfo* fninfo) {
ffi_abi abi;
RootedValue abiType(cx, ObjectOrNullValue(fninfo->mABI));
if (!GetABI(cx, abiType, &abi)) {
JS_ReportErrorASCII(cx, "Invalid ABI specification");
return false;
}
ffi_type* rtype = CType::GetFFIType(cx, fninfo->mReturnType);
if (!rtype) {
return false;
}
ffi_status status;
if (fninfo->mIsVariadic) {
status = ffi_prep_cif_var(&fninfo->mCIF, abi, fninfo->mArgTypes.length(),
fninfo->mFFITypes.length(), rtype,
fninfo->mFFITypes.begin());
} else {
status = ffi_prep_cif(&fninfo->mCIF, abi, fninfo->mFFITypes.length(), rtype,
fninfo->mFFITypes.begin());
}
switch (status) {
case FFI_OK:
return true;
case FFI_BAD_ABI:
JS_ReportErrorASCII(cx, "Invalid ABI specification");
return false;
case FFI_BAD_TYPEDEF:
JS_ReportErrorASCII(cx, "Invalid type specification");
return false;
default:
JS_ReportErrorASCII(cx, "Unknown libffi error");
return false;
}
}
void FunctionType::BuildSymbolName(JSContext* cx, JSString* name,
JSObject* typeObj, AutoCString& result) {
FunctionInfo* fninfo = GetFunctionInfo(typeObj);
switch (GetABICode(fninfo->mABI)) {
case ABI_DEFAULT:
case ABI_THISCALL:
case ABI_WINAPI:
// For cdecl or WINAPI functions, no mangling is necessary.
AppendString(cx, result, name);
break;
case ABI_STDCALL: {
#if (defined(_WIN32) && !defined(_WIN64)) || defined(_OS2)
// On WIN32, stdcall functions look like:
// _foo@40
// where 'foo' is the function name, and '40' is the aligned size of the
// arguments.
AppendString(cx, result, "_");
AppendString(cx, result, name);
AppendString(cx, result, "@");
// Compute the suffix by aligning each argument to sizeof(ffi_arg).
size_t size = 0;
for (size_t i = 0; i < fninfo->mArgTypes.length(); ++i) {
JSObject* argType = fninfo->mArgTypes[i];
size += Align(CType::GetSize(argType), sizeof(ffi_arg));
}
IntegerToString(size, 10, result);
#elif defined(_WIN64)
// On Win64, stdcall is an alias to the default ABI for compatibility, so
// no mangling is done.
AppendString(cx, result, name);
#endif
break;
}
case INVALID_ABI:
MOZ_CRASH("invalid abi");
}
}
static bool CreateFunctionInfo(JSContext* cx, HandleObject typeObj,
HandleValue abiType, HandleObject returnType,
const HandleValueArray& args) {
FunctionInfo* fninfo(cx->new_<FunctionInfo>(cx->zone()));
if (!fninfo) {
return false;
}
// Stash the FunctionInfo in a reserved slot.
JS_InitReservedSlot(typeObj, SLOT_FNINFO, fninfo,
JS::MemoryUse::CTypeFunctionInfo);
ffi_abi abi;
if (!GetABI(cx, abiType, &abi)) {
JS_ReportErrorASCII(cx, "Invalid ABI specification");
return false;
}
fninfo->mABI = abiType.toObjectOrNull();
fninfo->mReturnType = returnType;
// prepare the argument types
if (!fninfo->mArgTypes.reserve(args.length()) ||
!fninfo->mFFITypes.reserve(args.length())) {
JS_ReportOutOfMemory(cx);
return false;
}
fninfo->mIsVariadic = false;
for (uint32_t i = 0; i < args.length(); ++i) {
bool isEllipsis;
if (!IsEllipsis(cx, args[i], &isEllipsis)) {
return false;
}
if (isEllipsis) {
fninfo->mIsVariadic = true;
if (i < 1) {
JS_ReportErrorASCII(cx,
"\"...\" may not be the first and only parameter "
"type of a variadic function declaration");
return false;
}
if (i < args.length() - 1) {
JS_ReportErrorASCII(cx,
"\"...\" must be the last parameter type of a "
"variadic function declaration");
return false;
}
if (GetABICode(fninfo->mABI) != ABI_DEFAULT) {
JS_ReportErrorASCII(cx,
"Variadic functions must use the __cdecl calling "
"convention");
return false;
}
break;
}
JSObject* argType = PrepareType(cx, i, args[i]);
if (!argType) {
return false;
}
ffi_type* ffiType = CType::GetFFIType(cx, argType);
if (!ffiType) {
return false;
}
fninfo->mArgTypes.infallibleAppend(argType);
fninfo->mFFITypes.infallibleAppend(ffiType);
}
if (fninfo->mIsVariadic) {
// wait to PrepareCIF until function is called
return true;
}
if (!PrepareCIF(cx, fninfo)) {
return false;
}
return true;
}
bool FunctionType::Create(JSContext* cx, unsigned argc, Value* vp) {
// Construct and return a new FunctionType object.
CallArgs args = CallArgsFromVp(argc, vp);
if (args.length() < 2 || args.length() > 3) {
return ArgumentLengthError(cx, "FunctionType", "two or three", "s");
}
JS::RootedValueVector argTypes(cx);
RootedObject arrayObj(cx, nullptr);
if (args.length() == 3) {
// Prepare an array of Values for the arguments.
bool isArray;
if (!args[2].isObject()) {
isArray = false;
} else {
if (!JS::IsArrayObject(cx, args[2], &isArray)) {
return false;
}
}
if (!isArray) {
return ArgumentTypeMismatch(cx, "third ", "FunctionType", "an array");
}
arrayObj = &args[2].toObject();
uint32_t len;
MOZ_ALWAYS_TRUE(JS::GetArrayLength(cx, arrayObj, &len));
if (!argTypes.resize(len)) {
JS_ReportOutOfMemory(cx);
return false;
}
}
// Pull out the argument types from the array, if any.
MOZ_ASSERT_IF(argTypes.length(), arrayObj);
for (uint32_t i = 0; i < argTypes.length(); ++i) {
if (!JS_GetElement(cx, arrayObj, i, argTypes[i])) {
return false;
}
}
JSObject* result = CreateInternal(cx, args[0], args[1], argTypes);
if (!result) {
return false;
}
args.rval().setObject(*result);
return true;
}
JSObject* FunctionType::CreateInternal(JSContext* cx, HandleValue abi,
HandleValue rtype,
const HandleValueArray& args) {
// Prepare the result type
RootedObject returnType(cx, PrepareReturnType(cx, rtype));
if (!returnType) {
return nullptr;
}
// Get ctypes.FunctionType.prototype and the common prototype for CData
// objects of this type, from ctypes.CType.prototype.
RootedObject typeProto(
cx, CType::GetProtoFromType(cx, returnType, SLOT_FUNCTIONPROTO));
if (!typeProto) {
return nullptr;
}
RootedObject dataProto(
cx, CType::GetProtoFromType(cx, returnType, SLOT_FUNCTIONDATAPROTO));
if (!dataProto) {
return nullptr;
}
// Create a new CType object with the common properties and slots.
RootedObject typeObj(
cx, CType::Create(cx, typeProto, dataProto, TYPE_function, nullptr,
JS::UndefinedHandleValue, JS::UndefinedHandleValue,
nullptr));
if (!typeObj) {
return nullptr;
}
// Determine and check the types, and prepare the function CIF.
if (!CreateFunctionInfo(cx, typeObj, abi, returnType, args)) {
return nullptr;
}
return typeObj;
}
// Construct a function pointer to a JS function (see CClosure::Create()).
// Regular function pointers are constructed directly in
// PointerType::ConstructData().
bool FunctionType::ConstructData(JSContext* cx, HandleObject typeObj,
HandleObject dataObj, HandleObject fnObj,
HandleObject thisObj, HandleValue errVal) {
MOZ_ASSERT(CType::GetTypeCode(typeObj) == TYPE_function);
PRFuncPtr* data = static_cast<PRFuncPtr*>(CData::GetData(dataObj));
FunctionInfo* fninfo = FunctionType::GetFunctionInfo(typeObj);
if (fninfo->mIsVariadic) {
JS_ReportErrorASCII(cx, "Can't declare a variadic callback function");
return false;
}
if (GetABICode(fninfo->mABI) == ABI_WINAPI) {
JS_ReportErrorASCII(cx,
"Can't declare a ctypes.winapi_abi callback function, "
"use ctypes.stdcall_abi instead");
return false;
}
RootedObject closureObj(
cx, CClosure::Create(cx, typeObj, fnObj, thisObj, errVal, data));
if (!closureObj) {
return false;
}
// Set the closure object as the referent of the new CData object.
JS_SetReservedSlot(dataObj, SLOT_REFERENT, ObjectValue(*closureObj));
// Seal the CData object, to prevent modification of the function pointer.
// This permanently associates this object with the closure, and avoids
// having to do things like reset SLOT_REFERENT when someone tries to
// change the pointer value.
// could be called on a frozen object.
return JS_FreezeObject(cx, dataObj);
}
typedef Vector<AutoValue, 16, SystemAllocPolicy> AutoValueAutoArray;
static bool ConvertArgument(JSContext* cx, HandleObject funObj,
unsigned argIndex, HandleValue arg, JSObject* type,
AutoValue* value, AutoValueAutoArray* strings) {
if (!value->SizeToType(cx, type)) {
JS_ReportAllocationOverflow(cx);
return false;
}
bool freePointer = false;
if (!ImplicitConvert(cx, arg, type, value->mData, ConversionType::Argument,
&freePointer, funObj, argIndex))
return false;
if (freePointer) {
// ImplicitConvert converted a string for us, which we have to free.
// Keep track of it.
if (!strings->growBy(1)) {
JS_ReportOutOfMemory(cx);
return false;
}
strings->back().mData = *static_cast<char**>(value->mData);
}
return true;
}
bool FunctionType::Call(JSContext* cx, unsigned argc, Value* vp) {
CallArgs args = CallArgsFromVp(argc, vp);
// get the callee object...
RootedObject obj(cx, &args.callee());
if (!CData::IsCDataMaybeUnwrap(&obj)) {
return IncompatibleThisProto(cx, "FunctionType.prototype.call",
args.calleev());
}
RootedObject typeObj(cx, CData::GetCType(obj));
if (CType::GetTypeCode(typeObj) != TYPE_pointer) {
return IncompatibleThisType(cx, "FunctionType.prototype.call",
"non-PointerType CData", args.calleev());
}
typeObj = PointerType::GetBaseType(typeObj);
if (CType::GetTypeCode(typeObj) != TYPE_function) {
return IncompatibleThisType(cx, "FunctionType.prototype.call",
"non-FunctionType pointer", args.calleev());
}
FunctionInfo* fninfo = GetFunctionInfo(typeObj);
uint32_t argcFixed = fninfo->mArgTypes.length();
if ((!fninfo->mIsVariadic && args.length() != argcFixed) ||
(fninfo->mIsVariadic && args.length() < argcFixed)) {
return FunctionArgumentLengthMismatch(cx, argcFixed, args.length(), obj,
typeObj, fninfo->mIsVariadic);
}
// Check if we have a Library object. If we do, make sure it's open.
Value slot = JS::GetReservedSlot(obj, SLOT_REFERENT);
if (!slot.isUndefined() && Library::IsLibrary(&slot.toObject())) {
PRLibrary* library = Library::GetLibrary(&slot.toObject());
if (!library) {
JS_ReportErrorASCII(cx, "library is not open");
return false;
}
}
// prepare the values for each argument
AutoValueAutoArray values;
AutoValueAutoArray strings;
if (!values.resize(args.length())) {
JS_ReportOutOfMemory(cx);
return false;
}
for (unsigned i = 0; i < argcFixed; ++i) {
if (!ConvertArgument(cx, obj, i, args[i], fninfo->mArgTypes[i], &values[i],
&strings)) {
return false;
}
}
if (fninfo->mIsVariadic) {
if (!fninfo->mFFITypes.resize(args.length())) {
JS_ReportOutOfMemory(cx);
return false;
}
RootedObject obj(cx); // Could reuse obj instead of declaring a second
RootedObject type(cx); // RootedObject, but readability would suffer.
RootedValue arg(cx);
for (uint32_t i = argcFixed; i < args.length(); ++i) {
obj = args[i].isObject() ? &args[i].toObject() : nullptr;
if (!obj || !CData::IsCDataMaybeUnwrap(&obj)) {
// Since we know nothing about the CTypes of the ... arguments,
// they absolutely must be CData objects already.
return VariadicArgumentTypeError(cx, i, args[i]);
}
type = CData::GetCType(obj);
if (!type) {
// These functions report their own errors.
return false;
}
RootedValue typeVal(cx, ObjectValue(*type));
type = PrepareType(cx, i, typeVal);
if (!type) {
return false;
}
// Relying on ImplicitConvert only for the limited purpose of
// converting one CType to another (e.g., T[] to T*).
arg = ObjectValue(*obj);
if (!ConvertArgument(cx, obj, i, arg, type, &values[i], &strings)) {
return false;
}
fninfo->mFFITypes[i] = CType::GetFFIType(cx, type);
if (!fninfo->mFFITypes[i]) {
return false;
}
}
if (!PrepareCIF(cx, fninfo)) {
return false;
}
}
// initialize a pointer to an appropriate location, for storing the result
AutoValue returnValue;
TypeCode typeCode = CType::GetTypeCode(fninfo->mReturnType);
if (typeCode != TYPE_void_t &&
!returnValue.SizeToType(cx, fninfo->mReturnType)) {
JS_ReportAllocationOverflow(cx);
return false;
}
// Let the runtime callback know that we are about to call into C.
AutoCTypesActivityCallback autoCallback(cx, CTypesActivityType::BeginCall,
CTypesActivityType::EndCall);
uintptr_t fn = *reinterpret_cast<uintptr_t*>(CData::GetData(obj));
#if defined(XP_WIN)
int32_t lastErrorStatus; // The status as defined by |GetLastError|
int32_t savedLastError = GetLastError();
SetLastError(0);
#endif // defined(XP_WIN)
int errnoStatus; // The status as defined by |errno|
int savedErrno = errno;
errno = 0;
ffi_call(&fninfo->mCIF, FFI_FN(fn), returnValue.mData,
reinterpret_cast<void**>(values.begin()));
// Save error value.
// We need to save it before leaving the scope of |suspend| as destructing
// |suspend| has the side-effect of clearing |GetLastError|
errnoStatus = errno;
#if defined(XP_WIN)
lastErrorStatus = GetLastError();
SetLastError(savedLastError);
#endif // defined(XP_WIN)
errno = savedErrno;
// We're no longer calling into C.
autoCallback.DoEndCallback();
// Store the error value for later consultation with |ctypes.getStatus|
JSObject* objCTypes = CType::GetGlobalCTypes(cx, typeObj);
if (!objCTypes) {
return false;
}
JS_SetReservedSlot(objCTypes, SLOT_ERRNO, Int32Value(errnoStatus));
#if defined(XP_WIN)
JS_SetReservedSlot(objCTypes, SLOT_LASTERROR, Int32Value(lastErrorStatus));
#endif // defined(XP_WIN)
// Small integer types get returned as a word-sized ffi_arg. Coerce it back
// into the correct size for ConvertToJS.
switch (typeCode) {
#define INTEGRAL_CASE(name, type, ffiType) \
case TYPE_##name: \
if (sizeof(type) < sizeof(ffi_arg)) { \
ffi_arg data = *static_cast<ffi_arg*>(returnValue.mData); \
*static_cast<type*>(returnValue.mData) = static_cast<type>(data); \
} \
break;
CTYPES_FOR_EACH_INT_TYPE(INTEGRAL_CASE)
CTYPES_FOR_EACH_WRAPPED_INT_TYPE(INTEGRAL_CASE)
CTYPES_FOR_EACH_BOOL_TYPE(INTEGRAL_CASE)
CTYPES_FOR_EACH_CHAR_TYPE(INTEGRAL_CASE)
CTYPES_FOR_EACH_CHAR16_TYPE(INTEGRAL_CASE)
#undef INTEGRAL_CASE
default:
break;
}
// prepare a JS object from the result
RootedObject returnType(cx, fninfo->mReturnType);
return ConvertToJS(cx, returnType, nullptr, returnValue.mData, false, true,
args.rval());
}
FunctionInfo* FunctionType::GetFunctionInfo(JSObject* obj) {
MOZ_ASSERT(CType::IsCType(obj));
MOZ_ASSERT(CType::GetTypeCode(obj) == TYPE_function);
Value slot = JS::GetReservedSlot(obj, SLOT_FNINFO);
MOZ_ASSERT(!slot.isUndefined() && slot.toPrivate());
return static_cast<FunctionInfo*>(slot.toPrivate());
}
bool FunctionType::IsFunctionType(HandleValue v) {
if (!v.isObject()) {
return false;
}
JSObject* obj = &v.toObject();
return CType::IsCType(obj) && CType::GetTypeCode(obj) == TYPE_function;
}
bool FunctionType::ArgTypesGetter(JSContext* cx, const JS::CallArgs& args) {
JS::Rooted<JSObject*> obj(cx, &args.thisv().toObject());
args.rval().set(JS::GetReservedSlot(obj, SLOT_ARGS_T));
if (!args.rval().isUndefined()) {
return true;
}
FunctionInfo* fninfo = GetFunctionInfo(obj);
size_t len = fninfo->mArgTypes.length();
// Prepare a new array.
JS::Rooted<JSObject*> argTypes(cx);
{
JS::RootedValueVector vec(cx);
if (!vec.resize(len)) {
return false;
}
for (size_t i = 0; i < len; ++i) {
vec[i].setObject(*fninfo->mArgTypes[i]);
}
argTypes = JS::NewArrayObject(cx, vec);
if (!argTypes) {
return false;
}
}
// Seal and cache it.
if (!JS_FreezeObject(cx, argTypes)) {
return false;
}
JS_SetReservedSlot(obj, SLOT_ARGS_T, JS::ObjectValue(*argTypes));
args.rval().setObject(*argTypes);
return true;
}
bool FunctionType::ReturnTypeGetter(JSContext* cx, const JS::CallArgs& args) {
// Get the returnType object from the FunctionInfo.
args.rval().setObject(
*GetFunctionInfo(&args.thisv().toObject())->mReturnType);
return true;
}
bool FunctionType::ABIGetter(JSContext* cx, const JS::CallArgs& args) {
// Get the abi object from the FunctionInfo.
args.rval().setObject(*GetFunctionInfo(&args.thisv().toObject())->mABI);
return true;
}
bool FunctionType::IsVariadicGetter(JSContext* cx, const JS::CallArgs& args) {
args.rval().setBoolean(
GetFunctionInfo(&args.thisv().toObject())->mIsVariadic);
return true;
}
/*******************************************************************************
** CClosure implementation
*******************************************************************************/
JSObject* CClosure::Create(JSContext* cx, HandleObject typeObj,
HandleObject fnObj, HandleObject thisObj,
HandleValue errVal, PRFuncPtr* fnptr) {
MOZ_ASSERT(fnObj);
RootedObject result(cx, JS_NewObject(cx, &sCClosureClass));
if (!result) {
return nullptr;
}
// Get the FunctionInfo from the FunctionType.
FunctionInfo* fninfo = FunctionType::GetFunctionInfo(typeObj);
MOZ_ASSERT(!fninfo->mIsVariadic);
MOZ_ASSERT(GetABICode(fninfo->mABI) != ABI_WINAPI);
// Get the prototype of the FunctionType object, of class CTypeProto,
// which stores our JSContext for use with the closure.
RootedObject proto(cx);
if (!JS_GetPrototype(cx, typeObj, &proto)) {
return nullptr;
}
MOZ_ASSERT(proto);
MOZ_ASSERT(CType::IsCTypeProto(proto));
// Prepare the error sentinel value. It's important to do this now, because
// we might be unable to convert the value to the proper type. If so, we want
// the caller to know about it _now_, rather than some uncertain time in the
// future when the error sentinel is actually needed.
UniquePtr<uint8_t[], JS::FreePolicy> errResult;
if (!errVal.isUndefined()) {
// Make sure the callback returns something.
if (CType::GetTypeCode(fninfo->mReturnType) == TYPE_void_t) {
JS_ReportErrorASCII(cx, "A void callback can't pass an error sentinel");
return nullptr;
}
// With the exception of void, the FunctionType constructor ensures that
// the return type has a defined size.
MOZ_ASSERT(CType::IsSizeDefined(fninfo->mReturnType));
// Allocate a buffer for the return value.
size_t rvSize = CType::GetSize(fninfo->mReturnType);
errResult = cx->make_pod_array<uint8_t>(rvSize);
if (!errResult) {
return nullptr;
}
// Do the value conversion. This might fail, in which case we throw.
if (!ImplicitConvert(cx, errVal, fninfo->mReturnType, errResult.get(),
ConversionType::Return, nullptr, typeObj))
return nullptr;
}
ClosureInfo* cinfo = cx->new_<ClosureInfo>(cx);
if (!cinfo) {
JS_ReportOutOfMemory(cx);
return nullptr;
}
// Copy the important bits of context into cinfo.
cinfo->errResult = errResult.release();
cinfo->closureObj = result;
cinfo->typeObj = typeObj;
cinfo->thisObj = thisObj;
cinfo->jsfnObj = fnObj;
// Stash the ClosureInfo struct on our new object.
JS_InitReservedSlot(result, SLOT_CLOSUREINFO, cinfo,
JS::MemoryUse::CClosureInfo);
// Create an ffi_closure object and initialize it.
void* code;
cinfo->closure =
static_cast<ffi_closure*>(ffi_closure_alloc(sizeof(ffi_closure), &code));
if (!cinfo->closure || !code) {
JS_ReportErrorASCII(cx, "couldn't create closure - libffi error");
return nullptr;
}
ffi_status status = ffi_prep_closure_loc(cinfo->closure, &fninfo->mCIF,
CClosure::ClosureStub, cinfo, code);
if (status != FFI_OK) {
JS_ReportErrorASCII(cx, "couldn't create closure - libffi error");
return nullptr;
}
// Casting between void* and a function pointer is forbidden in C and C++.
// Do it via an integral type.
*fnptr = reinterpret_cast<PRFuncPtr>(reinterpret_cast<uintptr_t>(code));
return result;
}
void CClosure::Trace(JSTracer* trc, JSObject* obj) {
// Make sure our ClosureInfo slot is legit. If it's not, bail.
Value slot = JS::GetReservedSlot(obj, SLOT_CLOSUREINFO);
if (slot.isUndefined()) {
return;
}
ClosureInfo* cinfo = static_cast<ClosureInfo*>(slot.toPrivate());
TraceEdge(trc, &cinfo->closureObj, "closureObj");
TraceEdge(trc, &cinfo->typeObj, "typeObj");
TraceEdge(trc, &cinfo->jsfnObj, "jsfnObj");
TraceNullableEdge(trc, &cinfo->thisObj, "thisObj");
}
void CClosure::Finalize(JS::GCContext* gcx, JSObject* obj) {
// Make sure our ClosureInfo slot is legit. If it's not, bail.
Value slot = JS::GetReservedSlot(obj, SLOT_CLOSUREINFO);
if (slot.isUndefined()) {
return;
}
ClosureInfo* cinfo = static_cast<ClosureInfo*>(slot.toPrivate());
gcx->delete_(obj, cinfo, MemoryUse::CClosureInfo);
}
void CClosure::ClosureStub(ffi_cif* cif, void* result, void** args,
void* userData) {
MOZ_ASSERT(cif);
MOZ_ASSERT(result);
MOZ_ASSERT(args);
MOZ_ASSERT(userData);
// Retrieve the essentials from our closure object.
ArgClosure argClosure(cif, result, args, static_cast<ClosureInfo*>(userData));
JSContext* cx = argClosure.cinfo->cx;
js::AssertSameCompartment(cx, argClosure.cinfo->jsfnObj);
RootedObject global(cx, JS::CurrentGlobalOrNull(cx));
MOZ_ASSERT(global);
js::PrepareScriptEnvironmentAndInvoke(cx, global, argClosure);
}
bool CClosure::ArgClosure::operator()(JSContext* cx) {
// Let the runtime callback know that we are about to call into JS again. The
// end callback will fire automatically when we exit this function.
AutoCTypesActivityCallback autoCallback(cx, CTypesActivityType::BeginCallback,
CTypesActivityType::EndCallback);
RootedObject typeObj(cx, cinfo->typeObj);
RootedObject thisObj(cx, cinfo->thisObj);
RootedValue jsfnVal(cx, ObjectValue(*cinfo->jsfnObj));
AssertSameCompartment(cx, cinfo->jsfnObj);
JS_AbortIfWrongThread(cx);
// Assert that our CIFs agree.
FunctionInfo* fninfo = FunctionType::GetFunctionInfo(typeObj);
MOZ_ASSERT(cif == &fninfo->mCIF);
TypeCode typeCode = CType::GetTypeCode(fninfo->mReturnType);
// Initialize the result to zero, in case something fails. Small integer types
// are promoted to a word-sized ffi_arg, so we must be careful to zero the
// whole word.
size_t rvSize = 0;
if (cif->rtype != &ffi_type_void) {
rvSize = cif->rtype->size;
switch (typeCode) {
#define INTEGRAL_CASE(name, type, ffiType) case TYPE_##name:
CTYPES_FOR_EACH_INT_TYPE(INTEGRAL_CASE)
CTYPES_FOR_EACH_WRAPPED_INT_TYPE(INTEGRAL_CASE)
CTYPES_FOR_EACH_BOOL_TYPE(INTEGRAL_CASE)
CTYPES_FOR_EACH_CHAR_TYPE(INTEGRAL_CASE)
CTYPES_FOR_EACH_CHAR16_TYPE(INTEGRAL_CASE)
#undef INTEGRAL_CASE
rvSize = Align(rvSize, sizeof(ffi_arg));
break;
default:
break;
}
memset(result, 0, rvSize);
}
// Set up an array for converted arguments.
JS::RootedValueVector argv(cx);
if (!argv.resize(cif->nargs)) {
JS_ReportOutOfMemory(cx);
return false;
}
for (uint32_t i = 0; i < cif->nargs; ++i) {
// Convert each argument, and have any CData objects created depend on
// the existing buffers.
RootedObject argType(cx, fninfo->mArgTypes[i]);
if (!ConvertToJS(cx, argType, nullptr, args[i], false, false, argv[i])) {
return false;
}
}
// Call the JS function. 'thisObj' may be nullptr, in which case the JS
// engine will find an appropriate object to use.
RootedValue rval(cx);
bool success = JS_CallFunctionValue(cx, thisObj, jsfnVal, argv, &rval);
// Convert the result. Note that we pass 'ConversionType::Return', such that
// ImplicitConvert will *not* autoconvert a JS string into a pointer-to-char
// type, which would require an allocation that we can't track. The JS
// function must perform this conversion itself and return a PointerType
// CData; thusly, the burden of freeing the data is left to the user.
if (success && cif->rtype != &ffi_type_void) {
success = ImplicitConvert(cx, rval, fninfo->mReturnType, result,
ConversionType::Return, nullptr, typeObj);
}
if (!success) {
// Something failed. The callee may have thrown, or it may not have
// returned a value that ImplicitConvert() was happy with. Depending on how
// prudent the consumer has been, we may or may not have a recovery plan.
//
// Note that PrepareScriptEnvironmentAndInvoke should take care of reporting
// the exception.
if (cinfo->errResult) {
// Good case: we have a sentinel that we can return. Copy it in place of
// the actual return value, and then proceed.
// The buffer we're returning might be larger than the size of the return
// type, due to libffi alignment issues (see above). But it should never
// be smaller.
size_t copySize = CType::GetSize(fninfo->mReturnType);
MOZ_ASSERT(copySize <= rvSize);
memcpy(result, cinfo->errResult, copySize);
// We still want to return false here, so that
// PrepareScriptEnvironmentAndInvoke will report the exception.
} else {
// Bad case: not much we can do here. The rv is already zeroed out, so we
// just return and hope for the best.
}
return false;
}
// Small integer types must be returned as a word-sized ffi_arg. Coerce it
// back into the size libffi expects.
switch (typeCode) {
#define INTEGRAL_CASE(name, type, ffiType) \
case TYPE_##name: \
if (sizeof(type) < sizeof(ffi_arg)) { \
ffi_arg data = *static_cast<type*>(result); \
*static_cast<ffi_arg*>(result) = data; \
} \
break;
CTYPES_FOR_EACH_INT_TYPE(INTEGRAL_CASE)
CTYPES_FOR_EACH_WRAPPED_INT_TYPE(INTEGRAL_CASE)
CTYPES_FOR_EACH_BOOL_TYPE(INTEGRAL_CASE)
CTYPES_FOR_EACH_CHAR_TYPE(INTEGRAL_CASE)
CTYPES_FOR_EACH_CHAR16_TYPE(INTEGRAL_CASE)
#undef INTEGRAL_CASE
default:
break;
}
return true;
}
/*******************************************************************************
** CData implementation
*******************************************************************************/
// Create a new CData object of type 'typeObj' containing binary data supplied
// in 'source', optionally with a referent object 'refObj'.
//
// * 'typeObj' must be a CType of defined (but possibly zero) size.
//
// * If an object 'refObj' is supplied, the new CData object stores the
// referent object in a reserved slot for GC safety, such that 'refObj' will
// be held alive by the resulting CData object. 'refObj' may or may not be
// a CData object; merely an object we want to keep alive.
// * If 'refObj' is a CData object, 'ownResult' must be false.
// * Otherwise, 'refObj' is a Library or CClosure object, and 'ownResult'
// may be true or false.
// * Otherwise 'refObj' is nullptr. In this case, 'ownResult' may be true or
// false.
//
// * If 'ownResult' is true, the CData object will allocate an appropriately
// sized buffer, and free it upon finalization. If 'source' data is
// supplied, the data will be copied from 'source' into the buffer;
// otherwise, the entirety of the new buffer will be initialized to zero.
// * If 'ownResult' is false, the new CData's buffer refers to a slice of
// another buffer kept alive by 'refObj'. 'source' data must be provided,
// and the new CData's buffer will refer to 'source'.
JSObject* CData::Create(JSContext* cx, HandleObject typeObj,
HandleObject refObj, void* source, bool ownResult) {
MOZ_ASSERT(typeObj);
MOZ_ASSERT(CType::IsCType(typeObj));
MOZ_ASSERT(CType::IsSizeDefined(typeObj));
MOZ_ASSERT(ownResult || source);
MOZ_ASSERT_IF(refObj && CData::IsCData(refObj), !ownResult);
// Get the 'prototype' property from the type.
Value slot = JS::GetReservedSlot(typeObj, SLOT_PROTO);
MOZ_ASSERT(slot.isObject());
RootedObject proto(cx, &slot.toObject());
RootedObject dataObj(cx, JS_NewObjectWithGivenProto(cx, &sCDataClass, proto));
if (!dataObj) {
return nullptr;
}
// set the CData's associated type
JS_SetReservedSlot(dataObj, SLOT_CTYPE, ObjectValue(*typeObj));
// Stash the referent object, if any, for GC safety.
if (refObj) {
JS_SetReservedSlot(dataObj, SLOT_REFERENT, ObjectValue(*refObj));
}
// Set our ownership flag.
JS_SetReservedSlot(dataObj, SLOT_OWNS, BooleanValue(ownResult));
// attach the buffer. since it might not be 2-byte aligned, we need to
// allocate an aligned space for it and store it there. :(
UniquePtr<char*, JS::FreePolicy> buffer(cx->new_<char*>());
if (!buffer) {
return nullptr;
}
char* data;
if (!ownResult) {
data = static_cast<char*>(source);
} else {
// Initialize our own buffer.
size_t size = CType::GetSize(typeObj);
data = cx->pod_malloc<char>(size);
if (!data) {
return nullptr;
}
if (!source) {
memset(data, 0, size);
} else {
memcpy(data, source, size);
}
AddCellMemory(dataObj, size, MemoryUse::CDataBuffer);
}
*buffer.get() = data;
JS_InitReservedSlot(dataObj, SLOT_DATA, buffer.release(),
JS::MemoryUse::CDataBufferPtr);
// If this is an array, wrap it in a proxy so we can intercept element
// gets/sets.
if (CType::GetTypeCode(typeObj) != TYPE_array) {
return dataObj;
}
RootedValue priv(cx, ObjectValue(*dataObj));
ProxyOptions options;
options.setLazyProto(true);
return NewProxyObject(cx, &CDataArrayProxyHandler::singleton, priv, nullptr,
options);
}
void CData::Finalize(JS::GCContext* gcx, JSObject* obj) {
// Delete our buffer, and the data it contains if we own it.
Value slot = JS::GetReservedSlot(obj, SLOT_OWNS);
if (slot.isUndefined()) {
return;
}
bool owns = slot.toBoolean();
slot = JS::GetReservedSlot(obj, SLOT_DATA);
if (slot.isUndefined()) {
return;
}
char** buffer = static_cast<char**>(slot.toPrivate());
if (owns) {
JSObject* typeObj = &JS::GetReservedSlot(obj, SLOT_CTYPE).toObject();
size_t size = CType::GetSize(typeObj);
gcx->free_(obj, *buffer, size, MemoryUse::CDataBuffer);
}
gcx->delete_(obj, buffer, MemoryUse::CDataBufferPtr);
}
JSObject* CData::GetCType(JSObject* dataObj) {
dataObj = MaybeUnwrapArrayWrapper(dataObj);
MOZ_ASSERT(CData::IsCData(dataObj));
Value slot = JS::GetReservedSlot(dataObj, SLOT_CTYPE);
JSObject* typeObj = slot.toObjectOrNull();
MOZ_ASSERT(CType::IsCType(typeObj));
return typeObj;
}
void* CData::GetData(JSObject* dataObj) {
dataObj = MaybeUnwrapArrayWrapper(dataObj);
MOZ_ASSERT(CData::IsCData(dataObj));
Value slot = JS::GetReservedSlot(dataObj, SLOT_DATA);
void** buffer = static_cast<void**>(slot.toPrivate());
MOZ_ASSERT(buffer);
MOZ_ASSERT(*buffer);
return *buffer;
}
bool CData::IsCData(JSObject* obj) {
// Assert we don't have an array wrapper.
MOZ_ASSERT(MaybeUnwrapArrayWrapper(obj) == obj);
return obj->hasClass(&sCDataClass);
}
bool CData::IsCDataMaybeUnwrap(MutableHandleObject obj) {
obj.set(MaybeUnwrapArrayWrapper(obj));
return IsCData(obj);
}
bool CData::IsCData(HandleValue v) {
return v.isObject() && CData::IsCData(MaybeUnwrapArrayWrapper(&v.toObject()));
}
bool CData::IsCDataProto(JSObject* obj) {
return obj->hasClass(&sCDataProtoClass);
}
bool CData::ValueGetter(JSContext* cx, const JS::CallArgs& args) {
RootedObject obj(cx, &args.thisv().toObject());
// Convert the value to a primitive; do not create a new CData object.
RootedObject ctype(cx, GetCType(obj));
return ConvertToJS(cx, ctype, nullptr, GetData(obj), true, false,
args.rval());
}
bool CData::ValueSetter(JSContext* cx, const JS::CallArgs& args) {
RootedObject obj(cx, &args.thisv().toObject());
args.rval().setUndefined();
return ImplicitConvert(cx, args.get(0), GetCType(obj), GetData(obj),
ConversionType::Setter, nullptr);
}
bool CData::Address(JSContext* cx, unsigned argc, Value* vp) {
CallArgs args = CallArgsFromVp(argc, vp);
if (args.length() != 0) {
return ArgumentLengthError(cx, "CData.prototype.address", "no", "s");
}
RootedObject obj(cx, GetThisObject(cx, args, "CData.prototype.address"));
if (!obj) {
return false;
}
if (!IsCDataMaybeUnwrap(&obj)) {
return IncompatibleThisProto(cx, "CData.prototype.address", args.thisv());
}
RootedObject typeObj(cx, CData::GetCType(obj));
RootedObject pointerType(cx, PointerType::CreateInternal(cx, typeObj));
if (!pointerType) {
return false;
}
// Create a PointerType CData object containing null.
JSObject* result = CData::Create(cx, pointerType, nullptr, nullptr, true);
if (!result) {
return false;
}
args.rval().setObject(*result);
// Manually set the pointer inside the object, so we skip the conversion step.
void** data = static_cast<void**>(GetData(result));
*data = GetData(obj);
return true;
}
bool CData::Cast(JSContext* cx, unsigned argc, Value* vp) {
CallArgs args = CallArgsFromVp(argc, vp);
if (args.length() != 2) {
return ArgumentLengthError(cx, "ctypes.cast", "two", "s");
}
RootedObject sourceData(cx);
if (args[0].isObject()) {
sourceData = &args[0].toObject();
}
if (!sourceData || !CData::IsCDataMaybeUnwrap(&sourceData)) {
return ArgumentTypeMismatch(cx, "first ", "ctypes.cast", "a CData");
}
RootedObject sourceType(cx, CData::GetCType(sourceData));
if (args[1].isPrimitive() || !CType::IsCType(&args[1].toObject())) {
return ArgumentTypeMismatch(cx, "second ", "ctypes.cast", "a CType");
}
RootedObject targetType(cx, &args[1].toObject());
size_t targetSize;
if (!CType::GetSafeSize(targetType, &targetSize)) {
return UndefinedSizeCastError(cx, targetType);
}
if (targetSize > CType::GetSize(sourceType)) {
return SizeMismatchCastError(cx, sourceType, targetType,
CType::GetSize(sourceType), targetSize);
}
// Construct a new CData object with a type of 'targetType' and a referent
// of 'sourceData'.
void* data = CData::GetData(sourceData);
JSObject* result = CData::Create(cx, targetType, sourceData, data, false);
if (!result) {
return false;
}
args.rval().setObject(*result);
return true;
}
bool CData::GetRuntime(JSContext* cx, unsigned argc, Value* vp) {
CallArgs args = CallArgsFromVp(argc, vp);
if (args.length() != 1) {
return ArgumentLengthError(cx, "ctypes.getRuntime", "one", "");
}
if (args[0].isPrimitive() || !CType::IsCType(&args[0].toObject())) {
return ArgumentTypeMismatch(cx, "", "ctypes.getRuntime", "a CType");
}
RootedObject targetType(cx, &args[0].toObject());
size_t targetSize;
if (!CType::GetSafeSize(targetType, &targetSize) ||
targetSize != sizeof(void*)) {
JS_ReportErrorASCII(cx, "target CType has non-pointer size");
return false;
}
void* data = static_cast<void*>(cx->runtime());
JSObject* result = CData::Create(cx, targetType, nullptr, &data, true);
if (!result) {
return false;
}
args.rval().setObject(*result);
return true;
}
// Unwrap the `this` object to a CData object, or extract a CData object from a
// CDataFinalizer.
static bool GetThisDataObject(JSContext* cx, const CallArgs& args,
const char* funName, MutableHandleObject obj) {
obj.set(GetThisObject(cx, args, funName));
if (!obj) {
return IncompatibleThisProto(cx, funName, args.thisv());
}
if (!CData::IsCDataMaybeUnwrap(obj)) {
if (!CDataFinalizer::IsCDataFinalizer(obj)) {
return IncompatibleThisProto(cx, funName, args.thisv());
}
CDataFinalizer::Private* p = GetFinalizerPrivate(obj);
if (!p) {
return EmptyFinalizerCallError(cx, funName);
}
RootedValue dataVal(cx);
if (!CDataFinalizer::GetValue(cx, obj, &dataVal)) {
return IncompatibleThisProto(cx, funName, args.thisv());
}
if (dataVal.isPrimitive()) {
return IncompatibleThisProto(cx, funName, args.thisv());
}
obj.set(dataVal.toObjectOrNull());
if (!obj || !CData::IsCDataMaybeUnwrap(obj)) {
return IncompatibleThisProto(cx, funName, args.thisv());
}
}
return true;
}
typedef JS::TwoByteCharsZ (*InflateUTF8Method)(JSContext*, const JS::UTF8Chars&,
size_t*, arena_id_t);
static bool ReadStringCommon(JSContext* cx, InflateUTF8Method inflateUTF8,
unsigned argc, Value* vp, const char* funName,
arena_id_t destArenaId) {
CallArgs args = CallArgsFromVp(argc, vp);
if (args.length() != 0) {
return ArgumentLengthError(cx, funName, "no", "s");
}
RootedObject obj(cx);
if (!GetThisDataObject(cx, args, funName, &obj)) {
return false;
}
// Make sure we are a pointer to, or an array of, an 8-bit or 16-bit
// character or integer type.
JSObject* baseType;
JSObject* typeObj = CData::GetCType(obj);
TypeCode typeCode = CType::GetTypeCode(typeObj);
void* data;
size_t maxLength = -1;
switch (typeCode) {
case TYPE_pointer:
baseType = PointerType::GetBaseType(typeObj);
data = *static_cast<void**>(CData::GetData(obj));
if (data == nullptr) {
return NullPointerError(cx, "read contents of", obj);
}
break;
case TYPE_array:
baseType = ArrayType::GetBaseType(typeObj);
data = CData::GetData(obj);
maxLength = ArrayType::GetLength(typeObj);
break;
default:
return TypeError(cx, "PointerType or ArrayType", args.thisv());
}
// Convert the string buffer, taking care to determine the correct string
// length in the case of arrays (which may contain embedded nulls).
JSString* result;
switch (CType::GetTypeCode(baseType)) {
case TYPE_int8_t:
case TYPE_uint8_t:
case TYPE_char:
case TYPE_signed_char:
case TYPE_unsigned_char: {
char* bytes = static_cast<char*>(data);
size_t length = js_strnlen(bytes, maxLength);
// Determine the length.
UniqueTwoByteChars dst(
inflateUTF8(cx, JS::UTF8Chars(bytes, length), &length, destArenaId)
.get());
if (!dst) {
return false;
}
result = JS_NewUCString(cx, std::move(dst), length);
if (!result) {
return false;
}
break;
}
case TYPE_int16_t:
case TYPE_uint16_t:
case TYPE_short:
case TYPE_unsigned_short:
case TYPE_char16_t: {
char16_t* chars = static_cast<char16_t*>(data);
size_t length = js_strnlen(chars, maxLength);
result = JS_NewUCStringCopyN(cx, chars, length);
break;
}
default:
return NonStringBaseError(cx, args.thisv());
}
if (!result) {
return false;
}
args.rval().setString(result);
return true;
}
bool CData::ReadString(JSContext* cx, unsigned argc, Value* vp) {
return ReadStringCommon(cx, JS::UTF8CharsToNewTwoByteCharsZ, argc, vp,
"CData.prototype.readString", js::StringBufferArena);
}
bool CDataFinalizer::Methods::ReadString(JSContext* cx, unsigned argc,
Value* vp) {
return ReadStringCommon(cx, JS::UTF8CharsToNewTwoByteCharsZ, argc, vp,
"CDataFinalizer.prototype.readString",
js::StringBufferArena);
}
bool CData::ReadStringReplaceMalformed(JSContext* cx, unsigned argc,
Value* vp) {
return ReadStringCommon(cx, JS::LossyUTF8CharsToNewTwoByteCharsZ, argc, vp,
"CData.prototype.readStringReplaceMalformed",
js::StringBufferArena);
}
using TypedArrayConstructor = JSObject* (*)(JSContext*, size_t);
template <typename Type>
TypedArrayConstructor GetTypedArrayConstructorImpl() {
if (std::is_floating_point_v<Type>) {
switch (sizeof(Type)) {
case 4:
return JS_NewFloat32Array;
case 8:
return JS_NewFloat64Array;
default:
return nullptr;
}
}
constexpr bool isSigned = std::is_signed_v<Type>;
switch (sizeof(Type)) {
case 1:
return isSigned ? JS_NewInt8Array : JS_NewUint8Array;
case 2:
return isSigned ? JS_NewInt16Array : JS_NewUint16Array;
case 4:
return isSigned ? JS_NewInt32Array : JS_NewUint32Array;
default:
return nullptr;
}
}
static TypedArrayConstructor GetTypedArrayConstructor(TypeCode baseType) {
switch (baseType) {
#define MACRO(name, ctype, _) \
case TYPE_##name: \
return GetTypedArrayConstructorImpl<ctype>();
CTYPES_FOR_EACH_TYPE(MACRO)
#undef MACRO
default:
return nullptr;
}
}
static bool ReadTypedArrayCommon(JSContext* cx, unsigned argc, Value* vp,
const char* funName) {
CallArgs args = CallArgsFromVp(argc, vp);
if (args.length() != 0) {
return ArgumentLengthError(cx, funName, "no", "s");
}
RootedObject obj(cx);
if (!GetThisDataObject(cx, args, funName, &obj)) {
return false;
}
// Make sure we are a pointer to, or an array of, a type that is compatible
// with a typed array base type.
JSObject* baseType;
JSObject* typeObj = CData::GetCType(obj);
TypeCode typeCode = CType::GetTypeCode(typeObj);
void* data;
mozilla::Maybe<size_t> length;
switch (typeCode) {
case TYPE_pointer:
baseType = PointerType::GetBaseType(typeObj);
data = *static_cast<void**>(CData::GetData(obj));
if (data == nullptr) {
return NullPointerError(cx, "read contents of", obj);
}
break;
case TYPE_array:
baseType = ArrayType::GetBaseType(typeObj);
data = CData::GetData(obj);
length.emplace(ArrayType::GetLength(typeObj));
break;
default:
return TypeError(cx, "PointerType or ArrayType", args.thisv());
}
TypeCode baseTypeCode = CType::GetTypeCode(baseType);
// For string inputs only, use strlen to determine the length.
switch (baseTypeCode) {
case TYPE_char:
case TYPE_signed_char:
case TYPE_unsigned_char:
if (!length) {
length.emplace(js_strnlen(static_cast<char*>(data), INT32_MAX));
}
break;
case TYPE_char16_t:
if (!length) {
length.emplace(js_strlen(static_cast<char16_t*>(data)));
}
break;
default:
break;
}
if (!length) {
return NonStringBaseError(cx, args.thisv());
}
auto makeTypedArray = GetTypedArrayConstructor(baseTypeCode);
if (!makeTypedArray) {
return NonTypedArrayBaseError(cx, args.thisv());
}
CheckedInt<size_t> size = *length;
size *= CType::GetSize(baseType);
if (!size.isValid() || size.value() > ArrayBufferObject::ByteLengthLimit) {
return SizeOverflow(cx, "data", "typed array");
}
JSObject* result = makeTypedArray(cx, *length);
if (!result) {
return false;
}
AutoCheckCannotGC nogc(cx);
bool isShared;
void* buffer = JS_GetArrayBufferViewData(&result->as<ArrayBufferViewObject>(),
&isShared, nogc);
MOZ_ASSERT(!isShared);
memcpy(buffer, data, size.value());
args.rval().setObject(*result);
return true;
}
bool CData::ReadTypedArray(JSContext* cx, unsigned argc, Value* vp) {
return ReadTypedArrayCommon(cx, argc, vp, "CData.prototype.readTypedArray");
}
bool CDataFinalizer::Methods::ReadTypedArray(JSContext* cx, unsigned argc,
Value* vp) {
return ReadTypedArrayCommon(cx, argc, vp,
"CDataFinalizer.prototype.readTypedArray");
}
JSString* CData::GetSourceString(JSContext* cx, HandleObject typeObj,
void* data) {
// Walk the types, building up the toSource() string.
// First, we build up the type expression:
// 't.ptr' for pointers;
// 't.array([n])' for arrays;
// 'n' for structs, where n = t.name, the struct's name. (We assume this is
// bound to a variable in the current scope.)
AutoString source;
BuildTypeSource(cx, typeObj, true, source);
AppendString(cx, source, "(");
if (!BuildDataSource(cx, typeObj, data, false, source)) {
source.handle(false);
}
AppendString(cx, source, ")");
if (!source) {
return nullptr;
}
return NewUCString(cx, source.finish());
}
bool CData::ToSource(JSContext* cx, unsigned argc, Value* vp) {
CallArgs args = CallArgsFromVp(argc, vp);
if (args.length() != 0) {
return ArgumentLengthError(cx, "CData.prototype.toSource", "no", "s");
}
RootedObject obj(cx, GetThisObject(cx, args, "CData.prototype.toSource"));
if (!obj) {
return false;
}
if (!CData::IsCDataMaybeUnwrap(&obj) && !CData::IsCDataProto(obj)) {
return IncompatibleThisProto(cx, "CData.prototype.toSource",
InformalValueTypeName(args.thisv()));
}
JSString* result;
if (CData::IsCData(obj)) {
RootedObject typeObj(cx, CData::GetCType(obj));
void* data = CData::GetData(obj);
result = CData::GetSourceString(cx, typeObj, data);
} else {
result = JS_NewStringCopyZ(cx, "[CData proto object]");
}
if (!result) {
return false;
}
args.rval().setString(result);
return true;
}
bool CData::ErrnoGetter(JSContext* cx, const JS::CallArgs& args) {
args.rval().set(JS::GetReservedSlot(&args.thisv().toObject(), SLOT_ERRNO));
return true;
}
#if defined(XP_WIN)
bool CData::LastErrorGetter(JSContext* cx, const JS::CallArgs& args) {
args.rval().set(
JS::GetReservedSlot(&args.thisv().toObject(), SLOT_LASTERROR));
return true;
}
#endif // defined(XP_WIN)
bool CDataFinalizer::Methods::ToSource(JSContext* cx, unsigned argc,
Value* vp) {
CallArgs args = CallArgsFromVp(argc, vp);
RootedObject objThis(
cx, GetThisObject(cx, args, "CDataFinalizer.prototype.toSource"));
if (!objThis) {
return false;
}
if (!CDataFinalizer::IsCDataFinalizer(objThis)) {
return IncompatibleThisProto(cx, "CDataFinalizer.prototype.toSource",
InformalValueTypeName(args.thisv()));
}
CDataFinalizer::Private* p = GetFinalizerPrivate(objThis);
JSString* strMessage;
if (!p) {
strMessage = JS_NewStringCopyZ(cx, "ctypes.CDataFinalizer()");
} else {
RootedObject objType(cx, CDataFinalizer::GetCType(cx, objThis));
if (!objType) {
JS_ReportErrorASCII(cx, "CDataFinalizer has no type");
return false;
}
AutoString source;
AppendString(cx, source, "ctypes.CDataFinalizer(");
JSString* srcValue = CData::GetSourceString(cx, objType, p->cargs);
if (!srcValue) {
return false;
}
AppendString(cx, source, srcValue);
AppendString(cx, source, ", ");
Value valCodePtrType =
JS::GetReservedSlot(objThis, SLOT_DATAFINALIZER_CODETYPE);
if (valCodePtrType.isPrimitive()) {
return false;
}
RootedObject typeObj(cx, valCodePtrType.toObjectOrNull());
JSString* srcDispose = CData::GetSourceString(cx, typeObj, &(p->code));
if (!srcDispose) {
return false;
}
AppendString(cx, source, srcDispose);
AppendString(cx, source, ")");
if (!source) {
return false;
}
strMessage = NewUCString(cx, source.finish());
}
if (!strMessage) {
// This is a memory issue, no error message
return false;
}
args.rval().setString(strMessage);
return true;
}
bool CDataFinalizer::Methods::ToString(JSContext* cx, unsigned argc,
Value* vp) {
CallArgs args = CallArgsFromVp(argc, vp);
JSObject* objThis =
GetThisObject(cx, args, "CDataFinalizer.prototype.toString");
if (!objThis) {
return false;
}
if (!CDataFinalizer::IsCDataFinalizer(objThis)) {
return IncompatibleThisProto(cx, "CDataFinalizer.prototype.toString",
InformalValueTypeName(args.thisv()));
}
JSString* strMessage;
RootedValue value(cx);
if (!GetFinalizerPrivate(objThis)) {
// Pre-check whether CDataFinalizer::GetValue can fail
// to avoid reporting an error when not appropriate.
strMessage = JS_NewStringCopyZ(cx, "[CDataFinalizer - empty]");
if (!strMessage) {
return false;
}
} else if (!CDataFinalizer::GetValue(cx, objThis, &value)) {
MOZ_CRASH("Could not convert an empty CDataFinalizer");
} else {
strMessage = ToString(cx, value);
if (!strMessage) {
return false;
}
}
args.rval().setString(strMessage);
return true;
}
bool CDataFinalizer::IsCDataFinalizer(JSObject* obj) {
return obj->hasClass(&sCDataFinalizerClass);
}
JSObject* CDataFinalizer::GetCType(JSContext* cx, JSObject* obj) {
MOZ_ASSERT(IsCDataFinalizer(obj));
Value valData = JS::GetReservedSlot(obj, SLOT_DATAFINALIZER_VALTYPE);
if (valData.isUndefined()) {
return nullptr;
}
return valData.toObjectOrNull();
}
bool CDataFinalizer::GetValue(JSContext* cx, JSObject* obj,
MutableHandleValue aResult) {
MOZ_ASSERT(IsCDataFinalizer(obj));
CDataFinalizer::Private* p = GetFinalizerPrivate(obj);
if (!p) {
// We have called |dispose| or |forget| already.
JS_ReportErrorASCII(
cx, "Attempting to get the value of an empty CDataFinalizer");
return false;
}
RootedObject ctype(cx, GetCType(cx, obj));
return ConvertToJS(cx, ctype, /*parent*/ nullptr, p->cargs, false, true,
aResult);
}
/*
* Attach a C function as a finalizer to a JS object.
*
* Pseudo-JS signature:
* function(CData<T>, CData<T -> U>): CDataFinalizer<T>
* value, finalizer
*
* This function attaches strong references to the following values:
* - the CType of |value|
*
* Note: This function takes advantage of the fact that non-variadic
* CData functions are initialized during creation.
*/
bool CDataFinalizer::Construct(JSContext* cx, unsigned argc, Value* vp) {
CallArgs args = CallArgsFromVp(argc, vp);
RootedObject objSelf(cx, &args.callee());
RootedObject objProto(cx);
if (!GetObjectProperty(cx, objSelf, "prototype", &objProto)) {
JS_ReportErrorASCII(cx, "CDataFinalizer.prototype does not exist");
return false;
}
// Get arguments
if (args.length() ==
0) { // Special case: the empty (already finalized) object
JSObject* objResult =
JS_NewObjectWithGivenProto(cx, &sCDataFinalizerClass, objProto);
args.rval().setObject(*objResult);
return true;
}
if (args.length() != 2) {
return ArgumentLengthError(cx, "CDataFinalizer constructor", "two", "s");
}
JS::HandleValue valCodePtr = args[1];
if (!valCodePtr.isObject()) {
return TypeError(cx, "_a CData object_ of a function pointer type",
valCodePtr);
}
RootedObject objCodePtr(cx, &valCodePtr.toObject());
// Note: Using a custom argument formatter here would be awkward (requires
// a destructor just to uninstall the formatter).
// 2. Extract argument type of |objCodePtr|
if (!CData::IsCDataMaybeUnwrap(&objCodePtr)) {
return TypeError(cx, "a _CData_ object of a function pointer type",
valCodePtr);
}
RootedObject objCodePtrType(cx, CData::GetCType(objCodePtr));
RootedValue valCodePtrType(cx, ObjectValue(*objCodePtrType));
MOZ_ASSERT(objCodePtrType);
TypeCode typCodePtr = CType::GetTypeCode(objCodePtrType);
if (typCodePtr != TYPE_pointer) {
return TypeError(cx, "a CData object of a function _pointer_ type",
valCodePtr);
}
JSObject* objCodeType = PointerType::GetBaseType(objCodePtrType);
MOZ_ASSERT(objCodeType);
TypeCode typCode = CType::GetTypeCode(objCodeType);
if (typCode != TYPE_function) {
return TypeError(cx, "a CData object of a _function_ pointer type",
valCodePtr);
}
uintptr_t code = *reinterpret_cast<uintptr_t*>(CData::GetData(objCodePtr));
if (!code) {
return TypeError(cx, "a CData object of a _non-NULL_ function pointer type",
valCodePtr);
}
FunctionInfo* funInfoFinalizer = FunctionType::GetFunctionInfo(objCodeType);
MOZ_ASSERT(funInfoFinalizer);
if ((funInfoFinalizer->mArgTypes.length() != 1) ||
(funInfoFinalizer->mIsVariadic)) {
RootedValue valCodeType(cx, ObjectValue(*objCodeType));
return TypeError(cx, "a function accepting exactly one argument",
valCodeType);
}
RootedObject objArgType(cx, funInfoFinalizer->mArgTypes[0]);
RootedObject returnType(cx, funInfoFinalizer->mReturnType);
// Invariant: At this stage, we know that funInfoFinalizer->mIsVariadic
// is |false|. Therefore, funInfoFinalizer->mCIF has already been initialized.
bool freePointer = false;
// 3. Perform dynamic cast of |args[0]| into |objType|, store it in |cargs|
size_t sizeArg;
RootedValue valData(cx, args[0]);
if (!CType::GetSafeSize(objArgType, &sizeArg)) {
RootedValue valCodeType(cx, ObjectValue(*objCodeType));
return TypeError(cx, "a function with one known size argument",
valCodeType);
}
UniquePtr<void, JS::FreePolicy> cargs(malloc(sizeArg));
if (!ImplicitConvert(cx, valData, objArgType, cargs.get(),
ConversionType::Finalizer, &freePointer, objCodePtrType,
0)) {
return false;
}
if (freePointer) {
// Note: We could handle that case, if necessary.
JS_ReportErrorASCII(
cx,
"Internal Error during CDataFinalizer. Object cannot be represented");
return false;
}
// 4. Prepare buffer for holding return value
UniquePtr<void, JS::FreePolicy> rvalue;
if (CType::GetTypeCode(returnType) != TYPE_void_t) {
rvalue.reset(malloc(Align(CType::GetSize(returnType), sizeof(ffi_arg))));
} // Otherwise, simply do not allocate
// 5. Create |objResult|
JSObject* objResult =
JS_NewObjectWithGivenProto(cx, &sCDataFinalizerClass, objProto);
if (!objResult) {
return false;
}
// If our argument is a CData, it holds a type.
// This is the type that we should capture, not that
// of the function, which may be less precise.
JSObject* objBestArgType = objArgType;
if (valData.isObject()) {
RootedObject objData(cx, &valData.toObject());
if (CData::IsCDataMaybeUnwrap(&objData)) {
objBestArgType = CData::GetCType(objData);
size_t sizeBestArg;
if (!CType::GetSafeSize(objBestArgType, &sizeBestArg)) {
MOZ_CRASH("object with unknown size");
}
if (sizeBestArg != sizeArg) {
return FinalizerSizeError(cx, objCodePtrType, valData);
}
}
}
// Used by GetCType
JS_SetReservedSlot(objResult, SLOT_DATAFINALIZER_VALTYPE,
ObjectOrNullValue(objBestArgType));
// Used by ToSource
JS_SetReservedSlot(objResult, SLOT_DATAFINALIZER_CODETYPE,
ObjectValue(*objCodePtrType));
RootedValue abiType(cx, ObjectOrNullValue(funInfoFinalizer->mABI));
ffi_abi abi;
if (!GetABI(cx, abiType, &abi)) {
JS_ReportErrorASCII(cx,
"Internal Error: "
"Invalid ABI specification in CDataFinalizer");
return false;
}
ffi_type* rtype = CType::GetFFIType(cx, funInfoFinalizer->mReturnType);
if (!rtype) {
JS_ReportErrorASCII(cx,
"Internal Error: "
"Could not access ffi type of CDataFinalizer");
return false;
}
// 7. Store C information as private
UniquePtr<CDataFinalizer::Private, JS::FreePolicy> p(
(CDataFinalizer::Private*)malloc(sizeof(CDataFinalizer::Private)));
memmove(&p->CIF, &funInfoFinalizer->mCIF, sizeof(ffi_cif));
p->cargs = cargs.release();
p->rvalue = rvalue.release();
p->cargs_size = sizeArg;
p->code = code;
JS::SetReservedSlot(objResult, SLOT_DATAFINALIZER_PRIVATE,
JS::PrivateValue(p.release()));
args.rval().setObject(*objResult);
return true;
}
/*
* Actually call the finalizer. Does not perform any cleanup on the object.
*
* Preconditions: |this| must be a |CDataFinalizer|, |p| must be non-null.
* The function fails if |this| has gone through |Forget|/|Dispose|
* or |Finalize|.
*
* This function does not alter the value of |errno|/|GetLastError|.
*
* If argument |errnoStatus| is non-nullptr, it receives the value of |errno|
* immediately after the call. Under Windows, if argument |lastErrorStatus|
* is non-nullptr, it receives the value of |GetLastError| immediately after
* the call. On other platforms, |lastErrorStatus| is ignored.
*/
void CDataFinalizer::CallFinalizer(CDataFinalizer::Private* p, int* errnoStatus,
int32_t* lastErrorStatus) {
int savedErrno = errno;
errno = 0;
#if defined(XP_WIN)
int32_t savedLastError = GetLastError();
SetLastError(0);
#endif // defined(XP_WIN)
void* args[1] = {p->cargs};
ffi_call(&p->CIF, FFI_FN(p->code), p->rvalue, args);
if (errnoStatus) {
*errnoStatus = errno;
}
errno = savedErrno;
#if defined(XP_WIN)
if (lastErrorStatus) {
*lastErrorStatus = GetLastError();
}
SetLastError(savedLastError);
#endif // defined(XP_WIN)
}
/*
* Forget the value.
*
* Preconditions: |this| must be a |CDataFinalizer|.
* The function fails if |this| has gone through |Forget|/|Dispose|
* or |Finalize|.
*
* Does not call the finalizer. Cleans up the Private memory and releases all
* strong references.
*/
bool CDataFinalizer::Methods::Forget(JSContext* cx, unsigned argc, Value* vp) {
CallArgs args = CallArgsFromVp(argc, vp);
if (args.length() != 0) {
return ArgumentLengthError(cx, "CDataFinalizer.prototype.forget", "no",
"s");
}
RootedObject obj(cx,
GetThisObject(cx, args, "CDataFinalizer.prototype.forget"));
if (!obj) {
return false;
}
if (!CDataFinalizer::IsCDataFinalizer(obj)) {
return IncompatibleThisProto(cx, "CDataFinalizer.prototype.forget",
args.thisv());
}
CDataFinalizer::Private* p = GetFinalizerPrivate(obj);
if (!p) {
return EmptyFinalizerCallError(cx, "CDataFinalizer.prototype.forget");
}
RootedValue valJSData(cx);
RootedObject ctype(cx, GetCType(cx, obj));
if (!ConvertToJS(cx, ctype, nullptr, p->cargs, false, true, &valJSData)) {
JS_ReportErrorASCII(cx, "CDataFinalizer value cannot be represented");
return false;
}
CDataFinalizer::Cleanup(p, obj);
args.rval().set(valJSData);
return true;
}
/*
* Clean up the value.
*
* Preconditions: |this| must be a |CDataFinalizer|.
* The function fails if |this| has gone through |Forget|/|Dispose|
* or |Finalize|.
*
* Calls the finalizer, cleans up the Private memory and releases all
* strong references.
*/
bool CDataFinalizer::Methods::Dispose(JSContext* cx, unsigned argc, Value* vp) {
CallArgs args = CallArgsFromVp(argc, vp);
if (args.length() != 0) {
return ArgumentLengthError(cx, "CDataFinalizer.prototype.dispose", "no",
"s");
}
RootedObject obj(cx,
GetThisObject(cx, args, "CDataFinalizer.prototype.dispose"));
if (!obj) {
return false;
}
if (!CDataFinalizer::IsCDataFinalizer(obj)) {
return IncompatibleThisProto(cx, "CDataFinalizer.prototype.dispose",
args.thisv());
}
CDataFinalizer::Private* p = GetFinalizerPrivate(obj);
if (!p) {
return EmptyFinalizerCallError(cx, "CDataFinalizer.prototype.dispose");
}
Value valType = JS::GetReservedSlot(obj, SLOT_DATAFINALIZER_VALTYPE);
MOZ_ASSERT(valType.isObject());
RootedObject objCTypes(cx, CType::GetGlobalCTypes(cx, &valType.toObject()));
if (!objCTypes) {
return false;
}
Value valCodePtrType = JS::GetReservedSlot(obj, SLOT_DATAFINALIZER_CODETYPE);
MOZ_ASSERT(valCodePtrType.isObject());
JSObject* objCodePtrType = &valCodePtrType.toObject();
JSObject* objCodeType = PointerType::GetBaseType(objCodePtrType);
MOZ_ASSERT(objCodeType);
MOZ_ASSERT(CType::GetTypeCode(objCodeType) == TYPE_function);
RootedObject resultType(
cx, FunctionType::GetFunctionInfo(objCodeType)->mReturnType);
RootedValue result(cx);
int errnoStatus;
#if defined(XP_WIN)
int32_t lastErrorStatus;
CDataFinalizer::CallFinalizer(p, &errnoStatus, &lastErrorStatus);
#else
CDataFinalizer::CallFinalizer(p, &errnoStatus, nullptr);
#endif // defined(XP_WIN)
JS_SetReservedSlot(objCTypes, SLOT_ERRNO, Int32Value(errnoStatus));
#if defined(XP_WIN)
JS_SetReservedSlot(objCTypes, SLOT_LASTERROR, Int32Value(lastErrorStatus));
#endif // defined(XP_WIN)
if (ConvertToJS(cx, resultType, nullptr, p->rvalue, false, true, &result)) {
CDataFinalizer::Cleanup(p, obj);
args.rval().set(result);
return true;
}
CDataFinalizer::Cleanup(p, obj);
return false;
}
/*
* Perform finalization.
*
* Preconditions: |this| must be the result of |CDataFinalizer|.
* It may have gone through |Forget|/|Dispose|.
*
* If |this| has not gone through |Forget|/|Dispose|, calls the
* finalizer, cleans up the Private memory and releases all
* strong references.
*/
void CDataFinalizer::Finalize(JS::GCContext* gcx, JSObject* obj) {
CDataFinalizer::Private* p = GetFinalizerPrivate(obj);
if (!p) {
return;
}
CDataFinalizer::CallFinalizer(p, nullptr, nullptr);
CDataFinalizer::Cleanup(p, nullptr);
}
/*
* Perform cleanup of a CDataFinalizer
*
* Release strong references, cleanup |Private|.
*
* Argument |p| contains the private information of the CDataFinalizer. If
* nullptr, this function does nothing.
* Argument |obj| should contain |nullptr| during finalization (or in any
* context in which the object itself should not be cleaned up), or a
* CDataFinalizer object otherwise.
*/
void CDataFinalizer::Cleanup(CDataFinalizer::Private* p, JSObject* obj) {
if (!p) {
return; // We have already cleaned up
}
free(p->cargs);
free(p->rvalue);
free(p);
if (!obj) {
return; // No slots to clean up
}
MOZ_ASSERT(CDataFinalizer::IsCDataFinalizer(obj));
static_assert(CDATAFINALIZER_SLOTS == 3, "Code below must clear all slots");
JS::SetReservedSlot(obj, SLOT_DATAFINALIZER_PRIVATE, JS::UndefinedValue());
JS::SetReservedSlot(obj, SLOT_DATAFINALIZER_VALTYPE, JS::NullValue());
JS::SetReservedSlot(obj, SLOT_DATAFINALIZER_CODETYPE, JS::NullValue());
}
/*******************************************************************************
** Int64 and UInt64 implementation
*******************************************************************************/
JSObject* Int64Base::Construct(JSContext* cx, HandleObject proto, uint64_t data,
bool isUnsigned) {
const JSClass* clasp = isUnsigned ? &sUInt64Class : &sInt64Class;
RootedObject result(cx, JS_NewObjectWithGivenProto(cx, clasp, proto));
if (!result) {
return nullptr;
}
// attach the Int64's data
uint64_t* buffer = cx->new_<uint64_t>(data);
if (!buffer) {
return nullptr;
}
JS_InitReservedSlot(result, SLOT_INT64, buffer, JS::MemoryUse::CTypesInt64);
if (!JS_FreezeObject(cx, result)) {
return nullptr;
}
return result;
}
void Int64Base::Finalize(JS::GCContext* gcx, JSObject* obj) {
Value slot = JS::GetReservedSlot(obj, SLOT_INT64);
if (slot.isUndefined()) {
return;
}
uint64_t* buffer = static_cast<uint64_t*>(slot.toPrivate());
gcx->delete_(obj, buffer, MemoryUse::CTypesInt64);
}
uint64_t Int64Base::GetInt(JSObject* obj) {
MOZ_ASSERT(Int64::IsInt64(obj) || UInt64::IsUInt64(obj));
Value slot = JS::GetReservedSlot(obj, SLOT_INT64);
return *static_cast<uint64_t*>(slot.toPrivate());
}
bool Int64Base::ToString(JSContext* cx, JSObject* obj, const CallArgs& args,
bool isUnsigned) {
if (args.length() > 1) {
if (isUnsigned) {
return ArgumentLengthError(cx, "UInt64.prototype.toString", "at most one",
"");
}
return ArgumentLengthError(cx, "Int64.prototype.toString", "at most one",
"");
}
int radix = 10;
if (args.length() == 1) {
Value arg = args[0];
if (arg.isInt32()) {
radix = arg.toInt32();
}
if (!arg.isInt32() || radix < 2 || radix > 36) {
if (isUnsigned) {
return ArgumentRangeMismatch(
cx, "UInt64.prototype.toString",
"an integer at least 2 and no greater than 36");
}
return ArgumentRangeMismatch(
cx, "Int64.prototype.toString",
"an integer at least 2 and no greater than 36");
}
}
AutoString intString;
if (isUnsigned) {
IntegerToString(GetInt(obj), radix, intString);
} else {
IntegerToString(static_cast<int64_t>(GetInt(obj)), radix, intString);
}
if (!intString) {
return false;
}
JSString* result = NewUCString(cx, intString.finish());
if (!result) {
return false;
}
args.rval().setString(result);
return true;
}
bool Int64Base::ToSource(JSContext* cx, JSObject* obj, const CallArgs& args,
bool isUnsigned) {
if (args.length() != 0) {
if (isUnsigned) {
return ArgumentLengthError(cx, "UInt64.prototype.toSource", "no", "s");
}
return ArgumentLengthError(cx, "Int64.prototype.toSource", "no", "s");
}
// Return a decimal string suitable for constructing the number.
AutoString source;
if (isUnsigned) {
AppendString(cx, source, "ctypes.UInt64(\"");
IntegerToString(GetInt(obj), 10, source);
} else {
AppendString(cx, source, "ctypes.Int64(\"");
IntegerToString(static_cast<int64_t>(GetInt(obj)), 10, source);
}
AppendString(cx, source, "\")");
if (!source) {
return false;
}
JSString* result = NewUCString(cx, source.finish());
if (!result) {
return false;
}
args.rval().setString(result);
return true;
}
bool Int64::Construct(JSContext* cx, unsigned argc, Value* vp) {
CallArgs args = CallArgsFromVp(argc, vp);
// Construct and return a new Int64 object.
if (args.length() != 1) {
return ArgumentLengthError(cx, "Int64 constructor", "one", "");
}
int64_t i = 0;
bool overflow = false;
if (!jsvalToBigInteger(cx, args[0], true, &i, &overflow)) {
if (overflow) {
return TypeOverflow(cx, "int64", args[0]);
}
return ArgumentConvError(cx, args[0], "Int64", 0);
}
// Get ctypes.Int64.prototype from the 'prototype' property of the ctor.
RootedValue slot(cx);
RootedObject callee(cx, &args.callee());
MOZ_ALWAYS_TRUE(JS_GetProperty(cx, callee, "prototype", &slot));
RootedObject proto(cx, slot.toObjectOrNull());
MOZ_ASSERT(proto->hasClass(&sInt64ProtoClass));
JSObject* result = Int64Base::Construct(cx, proto, i, false);
if (!result) {
return false;
}
args.rval().setObject(*result);
return true;
}
bool Int64::IsInt64(JSObject* obj) { return obj->hasClass(&sInt64Class); }
bool Int64::ToString(JSContext* cx, unsigned argc, Value* vp) {
CallArgs args = CallArgsFromVp(argc, vp);
RootedObject obj(cx, GetThisObject(cx, args, "Int64.prototype.toString"));
if (!obj) {
return false;
}
if (!Int64::IsInt64(obj)) {
if (!CData::IsCDataMaybeUnwrap(&obj)) {
return IncompatibleThisProto(cx, "Int64.prototype.toString",
InformalValueTypeName(args.thisv()));
}
return IncompatibleThisType(cx, "Int64.prototype.toString",
"non-Int64 CData");
}
return Int64Base::ToString(cx, obj, args, false);
}
bool Int64::ToSource(JSContext* cx, unsigned argc, Value* vp) {
CallArgs args = CallArgsFromVp(argc, vp);
RootedObject obj(cx, GetThisObject(cx, args, "Int64.prototype.toSource"));
if (!obj) {
return false;
}
if (!Int64::IsInt64(obj)) {
if (!CData::IsCDataMaybeUnwrap(&obj)) {
return IncompatibleThisProto(cx, "Int64.prototype.toSource",
InformalValueTypeName(args.thisv()));
}
return IncompatibleThisType(cx, "Int64.prototype.toSource",
"non-Int64 CData");
}
return Int64Base::ToSource(cx, obj, args, false);
}
bool Int64::Compare(JSContext* cx, unsigned argc, Value* vp) {
CallArgs args = CallArgsFromVp(argc, vp);
if (args.length() != 2) {
return ArgumentLengthError(cx, "Int64.compare", "two", "s");
}
if (args[0].isPrimitive() || !Int64::IsInt64(&args[0].toObject())) {
return ArgumentTypeMismatch(cx, "first ", "Int64.compare", "a Int64");
}
if (args[1].isPrimitive() || !Int64::IsInt64(&args[1].toObject())) {
return ArgumentTypeMismatch(cx, "second ", "Int64.compare", "a Int64");
}
JSObject* obj1 = &args[0].toObject();
JSObject* obj2 = &args[1].toObject();
int64_t i1 = Int64Base::GetInt(obj1);
int64_t i2 = Int64Base::GetInt(obj2);
if (i1 == i2) {
args.rval().setInt32(0);
} else if (i1 < i2) {
args.rval().setInt32(-1);
} else {
args.rval().setInt32(1);
}
return true;
}
#define LO_MASK ((uint64_t(1) << 32) - 1)
#define INT64_LO(i) ((i) & LO_MASK)
#define INT64_HI(i) ((i) >> 32)
bool Int64::Lo(JSContext* cx, unsigned argc, Value* vp) {
CallArgs args = CallArgsFromVp(argc, vp);
if (args.length() != 1) {
return ArgumentLengthError(cx, "Int64.lo", "one", "");
}
if (args[0].isPrimitive() || !Int64::IsInt64(&args[0].toObject())) {
return ArgumentTypeMismatch(cx, "", "Int64.lo", "a Int64");
}
JSObject* obj = &args[0].toObject();
int64_t u = Int64Base::GetInt(obj);
double d = uint32_t(INT64_LO(u));
args.rval().setNumber(d);
return true;
}
bool Int64::Hi(JSContext* cx, unsigned argc, Value* vp) {
CallArgs args = CallArgsFromVp(argc, vp);
if (args.length() != 1) {
return ArgumentLengthError(cx, "Int64.hi", "one", "");
}
if (args[0].isPrimitive() || !Int64::IsInt64(&args[0].toObject())) {
return ArgumentTypeMismatch(cx, "", "Int64.hi", "a Int64");
}
JSObject* obj = &args[0].toObject();
int64_t u = Int64Base::GetInt(obj);
double d = int32_t(INT64_HI(u));
args.rval().setDouble(d);
return true;
}
bool Int64::Join(JSContext* cx, unsigned argc, Value* vp) {
CallArgs args = CallArgsFromVp(argc, vp);
if (args.length() != 2) {
return ArgumentLengthError(cx, "Int64.join", "two", "s");
}
int32_t hi;
uint32_t lo;
if (!jsvalToInteger(cx, args[0], &hi)) {
return ArgumentConvError(cx, args[0], "Int64.join", 0);
}
if (!jsvalToInteger(cx, args[1], &lo)) {
return ArgumentConvError(cx, args[1], "Int64.join", 1);
}
int64_t i = mozilla::WrapToSigned((uint64_t(hi) << 32) + lo);
// Get Int64.prototype from the function's reserved slot.
JSObject* callee = &args.callee();
Value slot = js::GetFunctionNativeReserved(callee, SLOT_FN_INT64PROTO);
RootedObject proto(cx, &slot.toObject());
MOZ_ASSERT(proto->hasClass(&sInt64ProtoClass));
JSObject* result = Int64Base::Construct(cx, proto, i, false);
if (!result) {
return false;
}
args.rval().setObject(*result);
return true;
}
bool UInt64::Construct(JSContext* cx, unsigned argc, Value* vp) {
CallArgs args = CallArgsFromVp(argc, vp);
// Construct and return a new UInt64 object.
if (args.length() != 1) {
return ArgumentLengthError(cx, "UInt64 constructor", "one", "");
}
uint64_t u = 0;
bool overflow = false;
if (!jsvalToBigInteger(cx, args[0], true, &u, &overflow)) {
if (overflow) {
return TypeOverflow(cx, "uint64", args[0]);
}
return ArgumentConvError(cx, args[0], "UInt64", 0);
}
// Get ctypes.UInt64.prototype from the 'prototype' property of the ctor.
RootedValue slot(cx);
RootedObject callee(cx, &args.callee());
MOZ_ALWAYS_TRUE(JS_GetProperty(cx, callee, "prototype", &slot));
RootedObject proto(cx, &slot.toObject());
MOZ_ASSERT(proto->hasClass(&sUInt64ProtoClass));
JSObject* result = Int64Base::Construct(cx, proto, u, true);
if (!result) {
return false;
}
args.rval().setObject(*result);
return true;
}
bool UInt64::IsUInt64(JSObject* obj) { return obj->hasClass(&sUInt64Class); }
bool UInt64::ToString(JSContext* cx, unsigned argc, Value* vp) {
CallArgs args = CallArgsFromVp(argc, vp);
RootedObject obj(cx, GetThisObject(cx, args, "UInt64.prototype.toString"));
if (!obj) {
return false;
}
if (!UInt64::IsUInt64(obj)) {
if (!CData::IsCDataMaybeUnwrap(&obj)) {
return IncompatibleThisProto(cx, "UInt64.prototype.toString",
InformalValueTypeName(args.thisv()));
}
return IncompatibleThisType(cx, "UInt64.prototype.toString",
"non-UInt64 CData");
}
return Int64Base::ToString(cx, obj, args, true);
}
bool UInt64::ToSource(JSContext* cx, unsigned argc, Value* vp) {
CallArgs args = CallArgsFromVp(argc, vp);
RootedObject obj(cx, GetThisObject(cx, args, "UInt64.prototype.toSource"));
if (!obj) {
return false;
}
if (!UInt64::IsUInt64(obj)) {
if (!CData::IsCDataMaybeUnwrap(&obj)) {
return IncompatibleThisProto(cx, "UInt64.prototype.toSource",
InformalValueTypeName(args.thisv()));
}
return IncompatibleThisType(cx, "UInt64.prototype.toSource",
"non-UInt64 CData");
}
return Int64Base::ToSource(cx, obj, args, true);
}
bool UInt64::Compare(JSContext* cx, unsigned argc, Value* vp) {
CallArgs args = CallArgsFromVp(argc, vp);
if (args.length() != 2) {
return ArgumentLengthError(cx, "UInt64.compare", "two", "s");
}
if (args[0].isPrimitive() || !UInt64::IsUInt64(&args[0].toObject())) {
return ArgumentTypeMismatch(cx, "first ", "UInt64.compare", "a UInt64");
}
if (args[1].isPrimitive() || !UInt64::IsUInt64(&args[1].toObject())) {
return ArgumentTypeMismatch(cx, "second ", "UInt64.compare", "a UInt64");
}
JSObject* obj1 = &args[0].toObject();
JSObject* obj2 = &args[1].toObject();
uint64_t u1 = Int64Base::GetInt(obj1);
uint64_t u2 = Int64Base::GetInt(obj2);
if (u1 == u2) {
args.rval().setInt32(0);
} else if (u1 < u2) {
args.rval().setInt32(-1);
} else {
args.rval().setInt32(1);
}
return true;
}
bool UInt64::Lo(JSContext* cx, unsigned argc, Value* vp) {
CallArgs args = CallArgsFromVp(argc, vp);
if (args.length() != 1) {
return ArgumentLengthError(cx, "UInt64.lo", "one", "");
}
if (args[0].isPrimitive() || !UInt64::IsUInt64(&args[0].toObject())) {
return ArgumentTypeMismatch(cx, "", "UInt64.lo", "a UInt64");
}
JSObject* obj = &args[0].toObject();
uint64_t u = Int64Base::GetInt(obj);
double d = uint32_t(INT64_LO(u));
args.rval().setDouble(d);
return true;
}
bool UInt64::Hi(JSContext* cx, unsigned argc, Value* vp) {
CallArgs args = CallArgsFromVp(argc, vp);
if (args.length() != 1) {
return ArgumentLengthError(cx, "UInt64.hi", "one", "");
}
if (args[0].isPrimitive() || !UInt64::IsUInt64(&args[0].toObject())) {
return ArgumentTypeMismatch(cx, "", "UInt64.hi", "a UInt64");
}
JSObject* obj = &args[0].toObject();
uint64_t u = Int64Base::GetInt(obj);
double d = uint32_t(INT64_HI(u));
args.rval().setDouble(d);
return true;
}
bool UInt64::Join(JSContext* cx, unsigned argc, Value* vp) {
CallArgs args = CallArgsFromVp(argc, vp);
if (args.length() != 2) {
return ArgumentLengthError(cx, "UInt64.join", "two", "s");
}
uint32_t hi;
uint32_t lo;
if (!jsvalToInteger(cx, args[0], &hi)) {
return ArgumentConvError(cx, args[0], "UInt64.join", 0);
}
if (!jsvalToInteger(cx, args[1], &lo)) {
return ArgumentConvError(cx, args[1], "UInt64.join", 1);
}
uint64_t u = (uint64_t(hi) << 32) + uint64_t(lo);
// Get UInt64.prototype from the function's reserved slot.
JSObject* callee = &args.callee();
Value slot = js::GetFunctionNativeReserved(callee, SLOT_FN_INT64PROTO);
RootedObject proto(cx, &slot.toObject());
MOZ_ASSERT(proto->hasClass(&sUInt64ProtoClass));
JSObject* result = Int64Base::Construct(cx, proto, u, true);
if (!result) {
return false;
}
args.rval().setObject(*result);
return true;
}
} // namespace ctypes
} // namespace js