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// Copyright (c) 2013, the Dart project authors. Please see the AUTHORS file
// for details. All rights reserved. Use of this source code is governed by a
// BSD-style license that can be found in the LICENSE file.
#include "vm/bootstrap_natives.h"
#include "vm/exceptions.h"
#include "vm/native_entry.h"
#include "vm/object.h"
#include "vm/symbols.h"
namespace dart {
static void ThrowMaskRangeException(int64_t m) {
if ((m < 0) || (m > 255)) {
Exceptions::ThrowRangeError("mask", Integer::Handle(Integer::New(m)), 0,
255);
}
}
DEFINE_NATIVE_ENTRY(Float32x4_fromDoubles, 0, 4) {
GET_NON_NULL_NATIVE_ARGUMENT(Double, x, arguments->NativeArgAt(0));
GET_NON_NULL_NATIVE_ARGUMENT(Double, y, arguments->NativeArgAt(1));
GET_NON_NULL_NATIVE_ARGUMENT(Double, z, arguments->NativeArgAt(2));
GET_NON_NULL_NATIVE_ARGUMENT(Double, w, arguments->NativeArgAt(3));
float _x = static_cast<float>(x.value());
float _y = static_cast<float>(y.value());
float _z = static_cast<float>(z.value());
float _w = static_cast<float>(w.value());
return Float32x4::New(_x, _y, _z, _w);
}
DEFINE_NATIVE_ENTRY(Float32x4_splat, 0, 1) {
GET_NON_NULL_NATIVE_ARGUMENT(Double, v, arguments->NativeArgAt(0));
float _v = v.value();
return Float32x4::New(_v, _v, _v, _v);
}
DEFINE_NATIVE_ENTRY(Float32x4_zero, 0, 1) {
ASSERT(
TypeArguments::CheckedHandle(zone, arguments->NativeArgAt(0)).IsNull());
return Float32x4::New(0.0f, 0.0f, 0.0f, 0.0f);
}
DEFINE_NATIVE_ENTRY(Float32x4_fromInt32x4Bits, 0, 2) {
GET_NON_NULL_NATIVE_ARGUMENT(Int32x4, v, arguments->NativeArgAt(1));
return Float32x4::New(v.value());
}
DEFINE_NATIVE_ENTRY(Float32x4_fromFloat64x2, 0, 2) {
GET_NON_NULL_NATIVE_ARGUMENT(Float64x2, v, arguments->NativeArgAt(1));
float _x = static_cast<float>(v.x());
float _y = static_cast<float>(v.y());
return Float32x4::New(_x, _y, 0.0f, 0.0f);
}
DEFINE_NATIVE_ENTRY(Float32x4_add, 0, 2) {
GET_NON_NULL_NATIVE_ARGUMENT(Float32x4, self, arguments->NativeArgAt(0));
GET_NON_NULL_NATIVE_ARGUMENT(Float32x4, other, arguments->NativeArgAt(1));
float _x = self.x() + other.x();
float _y = self.y() + other.y();
float _z = self.z() + other.z();
float _w = self.w() + other.w();
return Float32x4::New(_x, _y, _z, _w);
}
DEFINE_NATIVE_ENTRY(Float32x4_negate, 0, 1) {
GET_NON_NULL_NATIVE_ARGUMENT(Float32x4, self, arguments->NativeArgAt(0));
float _x = -self.x();
float _y = -self.y();
float _z = -self.z();
float _w = -self.w();
return Float32x4::New(_x, _y, _z, _w);
}
DEFINE_NATIVE_ENTRY(Float32x4_sub, 0, 2) {
GET_NON_NULL_NATIVE_ARGUMENT(Float32x4, self, arguments->NativeArgAt(0));
GET_NON_NULL_NATIVE_ARGUMENT(Float32x4, other, arguments->NativeArgAt(1));
float _x = self.x() - other.x();
float _y = self.y() - other.y();
float _z = self.z() - other.z();
float _w = self.w() - other.w();
return Float32x4::New(_x, _y, _z, _w);
}
DEFINE_NATIVE_ENTRY(Float32x4_mul, 0, 2) {
GET_NON_NULL_NATIVE_ARGUMENT(Float32x4, self, arguments->NativeArgAt(0));
GET_NON_NULL_NATIVE_ARGUMENT(Float32x4, other, arguments->NativeArgAt(1));
float _x = self.x() * other.x();
float _y = self.y() * other.y();
float _z = self.z() * other.z();
float _w = self.w() * other.w();
return Float32x4::New(_x, _y, _z, _w);
}
DEFINE_NATIVE_ENTRY(Float32x4_div, 0, 2) {
GET_NON_NULL_NATIVE_ARGUMENT(Float32x4, self, arguments->NativeArgAt(0));
GET_NON_NULL_NATIVE_ARGUMENT(Float32x4, other, arguments->NativeArgAt(1));
float _x = Utils::DivideAllowZero(self.x(), other.x());
float _y = Utils::DivideAllowZero(self.y(), other.y());
float _z = Utils::DivideAllowZero(self.z(), other.z());
float _w = Utils::DivideAllowZero(self.w(), other.w());
return Float32x4::New(_x, _y, _z, _w);
}
DEFINE_NATIVE_ENTRY(Float32x4_cmplt, 0, 2) {
GET_NON_NULL_NATIVE_ARGUMENT(Float32x4, a, arguments->NativeArgAt(0));
GET_NON_NULL_NATIVE_ARGUMENT(Float32x4, b, arguments->NativeArgAt(1));
uint32_t _x = a.x() < b.x() ? 0xFFFFFFFF : 0x0;
uint32_t _y = a.y() < b.y() ? 0xFFFFFFFF : 0x0;
uint32_t _z = a.z() < b.z() ? 0xFFFFFFFF : 0x0;
uint32_t _w = a.w() < b.w() ? 0xFFFFFFFF : 0x0;
return Int32x4::New(_x, _y, _z, _w);
}
DEFINE_NATIVE_ENTRY(Float32x4_cmplte, 0, 2) {
GET_NON_NULL_NATIVE_ARGUMENT(Float32x4, a, arguments->NativeArgAt(0));
GET_NON_NULL_NATIVE_ARGUMENT(Float32x4, b, arguments->NativeArgAt(1));
uint32_t _x = a.x() <= b.x() ? 0xFFFFFFFF : 0x0;
uint32_t _y = a.y() <= b.y() ? 0xFFFFFFFF : 0x0;
uint32_t _z = a.z() <= b.z() ? 0xFFFFFFFF : 0x0;
uint32_t _w = a.w() <= b.w() ? 0xFFFFFFFF : 0x0;
return Int32x4::New(_x, _y, _z, _w);
}
DEFINE_NATIVE_ENTRY(Float32x4_cmpgt, 0, 2) {
GET_NON_NULL_NATIVE_ARGUMENT(Float32x4, a, arguments->NativeArgAt(0));
GET_NON_NULL_NATIVE_ARGUMENT(Float32x4, b, arguments->NativeArgAt(1));
uint32_t _x = a.x() > b.x() ? 0xFFFFFFFF : 0x0;
uint32_t _y = a.y() > b.y() ? 0xFFFFFFFF : 0x0;
uint32_t _z = a.z() > b.z() ? 0xFFFFFFFF : 0x0;
uint32_t _w = a.w() > b.w() ? 0xFFFFFFFF : 0x0;
return Int32x4::New(_x, _y, _z, _w);
}
DEFINE_NATIVE_ENTRY(Float32x4_cmpgte, 0, 2) {
GET_NON_NULL_NATIVE_ARGUMENT(Float32x4, a, arguments->NativeArgAt(0));
GET_NON_NULL_NATIVE_ARGUMENT(Float32x4, b, arguments->NativeArgAt(1));
uint32_t _x = a.x() >= b.x() ? 0xFFFFFFFF : 0x0;
uint32_t _y = a.y() >= b.y() ? 0xFFFFFFFF : 0x0;
uint32_t _z = a.z() >= b.z() ? 0xFFFFFFFF : 0x0;
uint32_t _w = a.w() >= b.w() ? 0xFFFFFFFF : 0x0;
return Int32x4::New(_x, _y, _z, _w);
}
DEFINE_NATIVE_ENTRY(Float32x4_cmpequal, 0, 2) {
GET_NON_NULL_NATIVE_ARGUMENT(Float32x4, a, arguments->NativeArgAt(0));
GET_NON_NULL_NATIVE_ARGUMENT(Float32x4, b, arguments->NativeArgAt(1));
uint32_t _x = a.x() == b.x() ? 0xFFFFFFFF : 0x0;
uint32_t _y = a.y() == b.y() ? 0xFFFFFFFF : 0x0;
uint32_t _z = a.z() == b.z() ? 0xFFFFFFFF : 0x0;
uint32_t _w = a.w() == b.w() ? 0xFFFFFFFF : 0x0;
return Int32x4::New(_x, _y, _z, _w);
}
DEFINE_NATIVE_ENTRY(Float32x4_cmpnequal, 0, 2) {
GET_NON_NULL_NATIVE_ARGUMENT(Float32x4, a, arguments->NativeArgAt(0));
GET_NON_NULL_NATIVE_ARGUMENT(Float32x4, b, arguments->NativeArgAt(1));
uint32_t _x = a.x() != b.x() ? 0xFFFFFFFF : 0x0;
uint32_t _y = a.y() != b.y() ? 0xFFFFFFFF : 0x0;
uint32_t _z = a.z() != b.z() ? 0xFFFFFFFF : 0x0;
uint32_t _w = a.w() != b.w() ? 0xFFFFFFFF : 0x0;
return Int32x4::New(_x, _y, _z, _w);
}
DEFINE_NATIVE_ENTRY(Float32x4_scale, 0, 2) {
GET_NON_NULL_NATIVE_ARGUMENT(Float32x4, self, arguments->NativeArgAt(0));
GET_NON_NULL_NATIVE_ARGUMENT(Double, scale, arguments->NativeArgAt(1));
float _s = static_cast<float>(scale.value());
float _x = self.x() * _s;
float _y = self.y() * _s;
float _z = self.z() * _s;
float _w = self.w() * _s;
return Float32x4::New(_x, _y, _z, _w);
}
DEFINE_NATIVE_ENTRY(Float32x4_abs, 0, 1) {
GET_NON_NULL_NATIVE_ARGUMENT(Float32x4, self, arguments->NativeArgAt(0));
float _x = fabsf(self.x());
float _y = fabsf(self.y());
float _z = fabsf(self.z());
float _w = fabsf(self.w());
return Float32x4::New(_x, _y, _z, _w);
}
#if defined(TARGET_ARCH_ARM64) || defined(TARGET_ARCH_ARM)
static float vminf(float f1, float f2) {
if (f1 == f2) {
// take care of (-0.0) < 0.0, (they are equal according to minss)
auto result = signbit(f1) ? f1 : f2;
return result;
}
auto result = f1 > f2 ? f2 : f1;
return result;
}
static float vmaxf(float f1, float f2) {
if (f1 == f2) {
// take care of (-0.0) < 0.0, (they are equal according to minss)
auto result = signbit(f1) ? f2 : f1;
return result;
}
auto result = f1 < f2 ? f2 : f1;
return result;
}
#endif
DEFINE_NATIVE_ENTRY(Float32x4_clamp, 0, 3) {
GET_NON_NULL_NATIVE_ARGUMENT(Float32x4, self, arguments->NativeArgAt(0));
GET_NON_NULL_NATIVE_ARGUMENT(Float32x4, lo, arguments->NativeArgAt(1));
GET_NON_NULL_NATIVE_ARGUMENT(Float32x4, hi, arguments->NativeArgAt(2));
// The order of the clamping must match the order of the optimized code:
// MAX(MIN(self, hi), lo).
float _x;
float _y;
float _z;
float _w;
// ARM semantics are different from X86/X64 at an instruction level. Ensure
// that we match the semantics of the architecture in the C version.
#if defined(TARGET_ARCH_IA32) || defined(TARGET_ARCH_X64)
_x = self.x() < hi.x() ? self.x() : hi.x();
_y = self.y() < hi.y() ? self.y() : hi.y();
_z = self.z() < hi.z() ? self.z() : hi.z();
_w = self.w() < hi.w() ? self.w() : hi.w();
_x = lo.x() < _x ? _x : lo.x();
_y = lo.y() < _y ? _y : lo.y();
_z = lo.z() < _z ? _z : lo.z();
_w = lo.w() < _w ? _w : lo.w();
#elif defined(TARGET_ARCH_ARM64) || defined(TARGET_ARCH_ARM)
_x = vminf(self.x(), hi.x());
_y = vminf(self.y(), hi.y());
_z = vminf(self.z(), hi.z());
_w = vminf(self.w(), hi.w());
_x = vmaxf(_x, lo.x());
_y = vmaxf(_y, lo.y());
_z = vmaxf(_z, lo.z());
_w = vmaxf(_w, lo.w());
#elif defined(TARGET_ARCH_RISCV32) || defined(TARGET_ARCH_RISCV64)
_x = fminf(self.x(), hi.x());
_y = fminf(self.y(), hi.y());
_z = fminf(self.z(), hi.z());
_w = fminf(self.w(), hi.w());
_x = fmaxf(_x, lo.x());
_y = fmaxf(_y, lo.y());
_z = fmaxf(_z, lo.z());
_w = fmaxf(_w, lo.w());
#else
#error Unknown architecture.
#endif
return Float32x4::New(_x, _y, _z, _w);
}
DEFINE_NATIVE_ENTRY(Float32x4_getX, 0, 1) {
GET_NON_NULL_NATIVE_ARGUMENT(Float32x4, self, arguments->NativeArgAt(0));
double value = static_cast<double>(self.x());
return Double::New(value);
}
DEFINE_NATIVE_ENTRY(Float32x4_getY, 0, 1) {
GET_NON_NULL_NATIVE_ARGUMENT(Float32x4, self, arguments->NativeArgAt(0));
double value = static_cast<double>(self.y());
return Double::New(value);
}
DEFINE_NATIVE_ENTRY(Float32x4_getZ, 0, 1) {
GET_NON_NULL_NATIVE_ARGUMENT(Float32x4, self, arguments->NativeArgAt(0));
double value = static_cast<double>(self.z());
return Double::New(value);
}
DEFINE_NATIVE_ENTRY(Float32x4_getW, 0, 1) {
GET_NON_NULL_NATIVE_ARGUMENT(Float32x4, self, arguments->NativeArgAt(0));
double value = static_cast<double>(self.w());
return Double::New(value);
}
DEFINE_NATIVE_ENTRY(Float32x4_getSignMask, 0, 1) {
GET_NON_NULL_NATIVE_ARGUMENT(Float32x4, self, arguments->NativeArgAt(0));
uint32_t mx = (bit_cast<uint32_t>(self.x()) & 0x80000000) >> 31;
uint32_t my = (bit_cast<uint32_t>(self.y()) & 0x80000000) >> 31;
uint32_t mz = (bit_cast<uint32_t>(self.z()) & 0x80000000) >> 31;
uint32_t mw = (bit_cast<uint32_t>(self.w()) & 0x80000000) >> 31;
uint32_t value = mx | (my << 1) | (mz << 2) | (mw << 3);
return Integer::New(value);
}
DEFINE_NATIVE_ENTRY(Int32x4_getSignMask, 0, 1) {
GET_NON_NULL_NATIVE_ARGUMENT(Int32x4, self, arguments->NativeArgAt(0));
uint32_t mx = (self.x() & 0x80000000) >> 31;
uint32_t my = (self.y() & 0x80000000) >> 31;
uint32_t mz = (self.z() & 0x80000000) >> 31;
uint32_t mw = (self.w() & 0x80000000) >> 31;
uint32_t value = mx | (my << 1) | (mz << 2) | (mw << 3);
return Integer::New(value);
}
DEFINE_NATIVE_ENTRY(Float32x4_shuffle, 0, 2) {
GET_NON_NULL_NATIVE_ARGUMENT(Float32x4, self, arguments->NativeArgAt(0));
GET_NON_NULL_NATIVE_ARGUMENT(Integer, mask, arguments->NativeArgAt(1));
int64_t m = mask.Value();
ThrowMaskRangeException(m);
float data[4] = {self.x(), self.y(), self.z(), self.w()};
float _x = data[m & 0x3];
float _y = data[(m >> 2) & 0x3];
float _z = data[(m >> 4) & 0x3];
float _w = data[(m >> 6) & 0x3];
return Float32x4::New(_x, _y, _z, _w);
}
DEFINE_NATIVE_ENTRY(Float32x4_shuffleMix, 0, 3) {
GET_NON_NULL_NATIVE_ARGUMENT(Float32x4, self, arguments->NativeArgAt(0));
GET_NON_NULL_NATIVE_ARGUMENT(Float32x4, other, arguments->NativeArgAt(1));
GET_NON_NULL_NATIVE_ARGUMENT(Integer, mask, arguments->NativeArgAt(2));
int64_t m = mask.Value();
ThrowMaskRangeException(m);
float data[4] = {self.x(), self.y(), self.z(), self.w()};
float other_data[4] = {other.x(), other.y(), other.z(), other.w()};
float _x = data[m & 0x3];
float _y = data[(m >> 2) & 0x3];
float _z = other_data[(m >> 4) & 0x3];
float _w = other_data[(m >> 6) & 0x3];
return Float32x4::New(_x, _y, _z, _w);
}
DEFINE_NATIVE_ENTRY(Float32x4_setX, 0, 2) {
GET_NON_NULL_NATIVE_ARGUMENT(Float32x4, self, arguments->NativeArgAt(0));
GET_NON_NULL_NATIVE_ARGUMENT(Double, x, arguments->NativeArgAt(1));
float _x = static_cast<float>(x.value());
float _y = self.y();
float _z = self.z();
float _w = self.w();
return Float32x4::New(_x, _y, _z, _w);
}
DEFINE_NATIVE_ENTRY(Float32x4_setY, 0, 2) {
GET_NON_NULL_NATIVE_ARGUMENT(Float32x4, self, arguments->NativeArgAt(0));
GET_NON_NULL_NATIVE_ARGUMENT(Double, y, arguments->NativeArgAt(1));
float _x = self.x();
float _y = static_cast<float>(y.value());
float _z = self.z();
float _w = self.w();
return Float32x4::New(_x, _y, _z, _w);
}
DEFINE_NATIVE_ENTRY(Float32x4_setZ, 0, 2) {
GET_NON_NULL_NATIVE_ARGUMENT(Float32x4, self, arguments->NativeArgAt(0));
GET_NON_NULL_NATIVE_ARGUMENT(Double, z, arguments->NativeArgAt(1));
float _x = self.x();
float _y = self.y();
float _z = static_cast<float>(z.value());
float _w = self.w();
return Float32x4::New(_x, _y, _z, _w);
}
DEFINE_NATIVE_ENTRY(Float32x4_setW, 0, 2) {
GET_NON_NULL_NATIVE_ARGUMENT(Float32x4, self, arguments->NativeArgAt(0));
GET_NON_NULL_NATIVE_ARGUMENT(Double, w, arguments->NativeArgAt(1));
float _x = self.x();
float _y = self.y();
float _z = self.z();
float _w = static_cast<float>(w.value());
return Float32x4::New(_x, _y, _z, _w);
}
DEFINE_NATIVE_ENTRY(Float32x4_min, 0, 2) {
GET_NON_NULL_NATIVE_ARGUMENT(Float32x4, self, arguments->NativeArgAt(0));
GET_NON_NULL_NATIVE_ARGUMENT(Float32x4, other, arguments->NativeArgAt(1));
float _x = self.x() < other.x() ? self.x() : other.x();
float _y = self.y() < other.y() ? self.y() : other.y();
float _z = self.z() < other.z() ? self.z() : other.z();
float _w = self.w() < other.w() ? self.w() : other.w();
return Float32x4::New(_x, _y, _z, _w);
}
DEFINE_NATIVE_ENTRY(Float32x4_max, 0, 2) {
GET_NON_NULL_NATIVE_ARGUMENT(Float32x4, self, arguments->NativeArgAt(0));
GET_NON_NULL_NATIVE_ARGUMENT(Float32x4, other, arguments->NativeArgAt(1));
float _x = self.x() > other.x() ? self.x() : other.x();
float _y = self.y() > other.y() ? self.y() : other.y();
float _z = self.z() > other.z() ? self.z() : other.z();
float _w = self.w() > other.w() ? self.w() : other.w();
return Float32x4::New(_x, _y, _z, _w);
}
DEFINE_NATIVE_ENTRY(Float32x4_sqrt, 0, 1) {
GET_NON_NULL_NATIVE_ARGUMENT(Float32x4, self, arguments->NativeArgAt(0));
float _x = sqrtf(self.x());
float _y = sqrtf(self.y());
float _z = sqrtf(self.z());
float _w = sqrtf(self.w());
return Float32x4::New(_x, _y, _z, _w);
}
DEFINE_NATIVE_ENTRY(Float32x4_reciprocal, 0, 1) {
GET_NON_NULL_NATIVE_ARGUMENT(Float32x4, self, arguments->NativeArgAt(0));
float _x = Utils::DivideAllowZero(1.0f, self.x());
float _y = Utils::DivideAllowZero(1.0f, self.y());
float _z = Utils::DivideAllowZero(1.0f, self.z());
float _w = Utils::DivideAllowZero(1.0f, self.w());
return Float32x4::New(_x, _y, _z, _w);
}
DEFINE_NATIVE_ENTRY(Float32x4_reciprocalSqrt, 0, 1) {
GET_NON_NULL_NATIVE_ARGUMENT(Float32x4, self, arguments->NativeArgAt(0));
float _x = sqrtf(Utils::DivideAllowZero(1.0f, self.x()));
float _y = sqrtf(Utils::DivideAllowZero(1.0f, self.y()));
float _z = sqrtf(Utils::DivideAllowZero(1.0f, self.z()));
float _w = sqrtf(Utils::DivideAllowZero(1.0f, self.w()));
return Float32x4::New(_x, _y, _z, _w);
}
DEFINE_NATIVE_ENTRY(Int32x4_fromInts, 0, 4) {
GET_NON_NULL_NATIVE_ARGUMENT(Integer, x, arguments->NativeArgAt(0));
GET_NON_NULL_NATIVE_ARGUMENT(Integer, y, arguments->NativeArgAt(1));
GET_NON_NULL_NATIVE_ARGUMENT(Integer, z, arguments->NativeArgAt(2));
GET_NON_NULL_NATIVE_ARGUMENT(Integer, w, arguments->NativeArgAt(3));
int32_t _x = static_cast<int32_t>(x.Value() & 0xFFFFFFFF);
int32_t _y = static_cast<int32_t>(y.Value() & 0xFFFFFFFF);
int32_t _z = static_cast<int32_t>(z.Value() & 0xFFFFFFFF);
int32_t _w = static_cast<int32_t>(w.Value() & 0xFFFFFFFF);
return Int32x4::New(_x, _y, _z, _w);
}
DEFINE_NATIVE_ENTRY(Int32x4_fromBools, 0, 4) {
GET_NON_NULL_NATIVE_ARGUMENT(Bool, x, arguments->NativeArgAt(0));
GET_NON_NULL_NATIVE_ARGUMENT(Bool, y, arguments->NativeArgAt(1));
GET_NON_NULL_NATIVE_ARGUMENT(Bool, z, arguments->NativeArgAt(2));
GET_NON_NULL_NATIVE_ARGUMENT(Bool, w, arguments->NativeArgAt(3));
int32_t _x = x.value() ? 0xFFFFFFFF : 0x0;
int32_t _y = y.value() ? 0xFFFFFFFF : 0x0;
int32_t _z = z.value() ? 0xFFFFFFFF : 0x0;
int32_t _w = w.value() ? 0xFFFFFFFF : 0x0;
return Int32x4::New(_x, _y, _z, _w);
}
DEFINE_NATIVE_ENTRY(Int32x4_fromFloat32x4Bits, 0, 2) {
GET_NON_NULL_NATIVE_ARGUMENT(Float32x4, v, arguments->NativeArgAt(1));
return Int32x4::New(v.value());
}
DEFINE_NATIVE_ENTRY(Int32x4_or, 0, 2) {
GET_NON_NULL_NATIVE_ARGUMENT(Int32x4, self, arguments->NativeArgAt(0));
GET_NON_NULL_NATIVE_ARGUMENT(Int32x4, other, arguments->NativeArgAt(1));
int32_t _x = self.x() | other.x();
int32_t _y = self.y() | other.y();
int32_t _z = self.z() | other.z();
int32_t _w = self.w() | other.w();
return Int32x4::New(_x, _y, _z, _w);
}
DEFINE_NATIVE_ENTRY(Int32x4_and, 0, 2) {
GET_NON_NULL_NATIVE_ARGUMENT(Int32x4, self, arguments->NativeArgAt(0));
GET_NON_NULL_NATIVE_ARGUMENT(Int32x4, other, arguments->NativeArgAt(1));
int32_t _x = self.x() & other.x();
int32_t _y = self.y() & other.y();
int32_t _z = self.z() & other.z();
int32_t _w = self.w() & other.w();
return Int32x4::New(_x, _y, _z, _w);
}
DEFINE_NATIVE_ENTRY(Int32x4_xor, 0, 2) {
GET_NON_NULL_NATIVE_ARGUMENT(Int32x4, self, arguments->NativeArgAt(0));
GET_NON_NULL_NATIVE_ARGUMENT(Int32x4, other, arguments->NativeArgAt(1));
int32_t _x = self.x() ^ other.x();
int32_t _y = self.y() ^ other.y();
int32_t _z = self.z() ^ other.z();
int32_t _w = self.w() ^ other.w();
return Int32x4::New(_x, _y, _z, _w);
}
DEFINE_NATIVE_ENTRY(Int32x4_add, 0, 2) {
GET_NON_NULL_NATIVE_ARGUMENT(Int32x4, self, arguments->NativeArgAt(0));
GET_NON_NULL_NATIVE_ARGUMENT(Int32x4, other, arguments->NativeArgAt(1));
int32_t _x = self.x() + other.x();
int32_t _y = self.y() + other.y();
int32_t _z = self.z() + other.z();
int32_t _w = self.w() + other.w();
return Int32x4::New(_x, _y, _z, _w);
}
DEFINE_NATIVE_ENTRY(Int32x4_sub, 0, 2) {
GET_NON_NULL_NATIVE_ARGUMENT(Int32x4, self, arguments->NativeArgAt(0));
GET_NON_NULL_NATIVE_ARGUMENT(Int32x4, other, arguments->NativeArgAt(1));
int32_t _x = self.x() - other.x();
int32_t _y = self.y() - other.y();
int32_t _z = self.z() - other.z();
int32_t _w = self.w() - other.w();
return Int32x4::New(_x, _y, _z, _w);
}
DEFINE_NATIVE_ENTRY(Int32x4_getX, 0, 1) {
GET_NON_NULL_NATIVE_ARGUMENT(Int32x4, self, arguments->NativeArgAt(0));
int32_t value = self.x();
return Integer::New(value);
}
DEFINE_NATIVE_ENTRY(Int32x4_getY, 0, 1) {
GET_NON_NULL_NATIVE_ARGUMENT(Int32x4, self, arguments->NativeArgAt(0));
int32_t value = self.y();
return Integer::New(value);
}
DEFINE_NATIVE_ENTRY(Int32x4_getZ, 0, 1) {
GET_NON_NULL_NATIVE_ARGUMENT(Int32x4, self, arguments->NativeArgAt(0));
int32_t value = self.z();
return Integer::New(value);
}
DEFINE_NATIVE_ENTRY(Int32x4_getW, 0, 1) {
GET_NON_NULL_NATIVE_ARGUMENT(Int32x4, self, arguments->NativeArgAt(0));
int32_t value = self.w();
return Integer::New(value);
}
DEFINE_NATIVE_ENTRY(Int32x4_shuffle, 0, 2) {
GET_NON_NULL_NATIVE_ARGUMENT(Int32x4, self, arguments->NativeArgAt(0));
GET_NON_NULL_NATIVE_ARGUMENT(Integer, mask, arguments->NativeArgAt(1));
int64_t m = mask.Value();
ThrowMaskRangeException(m);
int32_t data[4] = {self.x(), self.y(), self.z(), self.w()};
int32_t _x = data[m & 0x3];
int32_t _y = data[(m >> 2) & 0x3];
int32_t _z = data[(m >> 4) & 0x3];
int32_t _w = data[(m >> 6) & 0x3];
return Int32x4::New(_x, _y, _z, _w);
}
DEFINE_NATIVE_ENTRY(Int32x4_shuffleMix, 0, 3) {
GET_NON_NULL_NATIVE_ARGUMENT(Int32x4, self, arguments->NativeArgAt(0));
GET_NON_NULL_NATIVE_ARGUMENT(Int32x4, zw, arguments->NativeArgAt(1));
GET_NON_NULL_NATIVE_ARGUMENT(Integer, mask, arguments->NativeArgAt(2));
int64_t m = mask.Value();
ThrowMaskRangeException(m);
int32_t data[4] = {self.x(), self.y(), self.z(), self.w()};
int32_t zw_data[4] = {zw.x(), zw.y(), zw.z(), zw.w()};
int32_t _x = data[m & 0x3];
int32_t _y = data[(m >> 2) & 0x3];
int32_t _z = zw_data[(m >> 4) & 0x3];
int32_t _w = zw_data[(m >> 6) & 0x3];
return Int32x4::New(_x, _y, _z, _w);
}
DEFINE_NATIVE_ENTRY(Int32x4_setX, 0, 2) {
GET_NON_NULL_NATIVE_ARGUMENT(Int32x4, self, arguments->NativeArgAt(0));
GET_NON_NULL_NATIVE_ARGUMENT(Integer, x, arguments->NativeArgAt(1));
int32_t _x = static_cast<int32_t>(x.Value() & 0xFFFFFFFF);
int32_t _y = self.y();
int32_t _z = self.z();
int32_t _w = self.w();
return Int32x4::New(_x, _y, _z, _w);
}
DEFINE_NATIVE_ENTRY(Int32x4_setY, 0, 2) {
GET_NON_NULL_NATIVE_ARGUMENT(Int32x4, self, arguments->NativeArgAt(0));
GET_NON_NULL_NATIVE_ARGUMENT(Integer, y, arguments->NativeArgAt(1));
int32_t _x = self.x();
int32_t _y = static_cast<int32_t>(y.Value() & 0xFFFFFFFF);
int32_t _z = self.z();
int32_t _w = self.w();
return Int32x4::New(_x, _y, _z, _w);
}
DEFINE_NATIVE_ENTRY(Int32x4_setZ, 0, 2) {
GET_NON_NULL_NATIVE_ARGUMENT(Int32x4, self, arguments->NativeArgAt(0));
GET_NON_NULL_NATIVE_ARGUMENT(Integer, z, arguments->NativeArgAt(1));
int32_t _x = self.x();
int32_t _y = self.y();
int32_t _z = static_cast<int32_t>(z.Value() & 0xFFFFFFFF);
int32_t _w = self.w();
return Int32x4::New(_x, _y, _z, _w);
}
DEFINE_NATIVE_ENTRY(Int32x4_setW, 0, 2) {
GET_NON_NULL_NATIVE_ARGUMENT(Int32x4, self, arguments->NativeArgAt(0));
GET_NON_NULL_NATIVE_ARGUMENT(Integer, w, arguments->NativeArgAt(1));
int32_t _x = self.x();
int32_t _y = self.y();
int32_t _z = self.z();
int32_t _w = static_cast<int32_t>(w.Value() & 0xFFFFFFFF);
return Int32x4::New(_x, _y, _z, _w);
}
DEFINE_NATIVE_ENTRY(Int32x4_getFlagX, 0, 1) {
GET_NON_NULL_NATIVE_ARGUMENT(Int32x4, self, arguments->NativeArgAt(0));
int32_t value = self.x();
return Bool::Get(value != 0).ptr();
}
DEFINE_NATIVE_ENTRY(Int32x4_getFlagY, 0, 1) {
GET_NON_NULL_NATIVE_ARGUMENT(Int32x4, self, arguments->NativeArgAt(0));
int32_t value = self.y();
return Bool::Get(value != 0).ptr();
}
DEFINE_NATIVE_ENTRY(Int32x4_getFlagZ, 0, 1) {
GET_NON_NULL_NATIVE_ARGUMENT(Int32x4, self, arguments->NativeArgAt(0));
int32_t value = self.z();
return Bool::Get(value != 0).ptr();
}
DEFINE_NATIVE_ENTRY(Int32x4_getFlagW, 0, 1) {
GET_NON_NULL_NATIVE_ARGUMENT(Int32x4, self, arguments->NativeArgAt(0));
int32_t value = self.w();
return Bool::Get(value != 0).ptr();
}
DEFINE_NATIVE_ENTRY(Int32x4_setFlagX, 0, 2) {
GET_NON_NULL_NATIVE_ARGUMENT(Int32x4, self, arguments->NativeArgAt(0));
GET_NON_NULL_NATIVE_ARGUMENT(Bool, flagX, arguments->NativeArgAt(1));
int32_t _x = self.x();
int32_t _y = self.y();
int32_t _z = self.z();
int32_t _w = self.w();
_x = flagX.ptr() == Bool::True().ptr() ? 0xFFFFFFFF : 0x0;
return Int32x4::New(_x, _y, _z, _w);
}
DEFINE_NATIVE_ENTRY(Int32x4_setFlagY, 0, 2) {
GET_NON_NULL_NATIVE_ARGUMENT(Int32x4, self, arguments->NativeArgAt(0));
GET_NON_NULL_NATIVE_ARGUMENT(Bool, flagY, arguments->NativeArgAt(1));
int32_t _x = self.x();
int32_t _y = self.y();
int32_t _z = self.z();
int32_t _w = self.w();
_y = flagY.ptr() == Bool::True().ptr() ? 0xFFFFFFFF : 0x0;
return Int32x4::New(_x, _y, _z, _w);
}
DEFINE_NATIVE_ENTRY(Int32x4_setFlagZ, 0, 2) {
GET_NON_NULL_NATIVE_ARGUMENT(Int32x4, self, arguments->NativeArgAt(0));
GET_NON_NULL_NATIVE_ARGUMENT(Bool, flagZ, arguments->NativeArgAt(1));
int32_t _x = self.x();
int32_t _y = self.y();
int32_t _z = self.z();
int32_t _w = self.w();
_z = flagZ.ptr() == Bool::True().ptr() ? 0xFFFFFFFF : 0x0;
return Int32x4::New(_x, _y, _z, _w);
}
DEFINE_NATIVE_ENTRY(Int32x4_setFlagW, 0, 2) {
GET_NON_NULL_NATIVE_ARGUMENT(Int32x4, self, arguments->NativeArgAt(0));
GET_NON_NULL_NATIVE_ARGUMENT(Bool, flagW, arguments->NativeArgAt(1));
int32_t _x = self.x();
int32_t _y = self.y();
int32_t _z = self.z();
int32_t _w = self.w();
_w = flagW.ptr() == Bool::True().ptr() ? 0xFFFFFFFF : 0x0;
return Int32x4::New(_x, _y, _z, _w);
}
// Used to convert between int32_t and float32 without breaking strict
// aliasing rules.
union float32_int32 {
float f;
int32_t u;
float32_int32(float v) { f = v; }
float32_int32(int32_t v) { u = v; }
};
DEFINE_NATIVE_ENTRY(Int32x4_select, 0, 3) {
GET_NON_NULL_NATIVE_ARGUMENT(Int32x4, self, arguments->NativeArgAt(0));
GET_NON_NULL_NATIVE_ARGUMENT(Float32x4, tv, arguments->NativeArgAt(1));
GET_NON_NULL_NATIVE_ARGUMENT(Float32x4, fv, arguments->NativeArgAt(2));
int32_t _maskX = self.x();
int32_t _maskY = self.y();
int32_t _maskZ = self.z();
int32_t _maskW = self.w();
// Extract floats and interpret them as masks.
float32_int32 tvx(tv.x());
float32_int32 tvy(tv.y());
float32_int32 tvz(tv.z());
float32_int32 tvw(tv.w());
float32_int32 fvx(fv.x());
float32_int32 fvy(fv.y());
float32_int32 fvz(fv.z());
float32_int32 fvw(fv.w());
// Perform select.
float32_int32 tempX((_maskX & tvx.u) | (~_maskX & fvx.u));
float32_int32 tempY((_maskY & tvy.u) | (~_maskY & fvy.u));
float32_int32 tempZ((_maskZ & tvz.u) | (~_maskZ & fvz.u));
float32_int32 tempW((_maskW & tvw.u) | (~_maskW & fvw.u));
return Float32x4::New(tempX.f, tempY.f, tempZ.f, tempW.f);
}
DEFINE_NATIVE_ENTRY(Float64x2_fromDoubles, 0, 2) {
GET_NON_NULL_NATIVE_ARGUMENT(Double, x, arguments->NativeArgAt(0));
GET_NON_NULL_NATIVE_ARGUMENT(Double, y, arguments->NativeArgAt(1));
return Float64x2::New(x.value(), y.value());
}
DEFINE_NATIVE_ENTRY(Float64x2_splat, 0, 1) {
GET_NON_NULL_NATIVE_ARGUMENT(Double, v, arguments->NativeArgAt(0));
return Float64x2::New(v.value(), v.value());
}
DEFINE_NATIVE_ENTRY(Float64x2_zero, 0, 1) {
ASSERT(
TypeArguments::CheckedHandle(zone, arguments->NativeArgAt(0)).IsNull());
return Float64x2::New(0.0, 0.0);
}
DEFINE_NATIVE_ENTRY(Float64x2_fromFloat32x4, 0, 2) {
ASSERT(
TypeArguments::CheckedHandle(zone, arguments->NativeArgAt(0)).IsNull());
GET_NON_NULL_NATIVE_ARGUMENT(Float32x4, v, arguments->NativeArgAt(1));
double _x = v.x();
double _y = v.y();
return Float64x2::New(_x, _y);
}
DEFINE_NATIVE_ENTRY(Float64x2_add, 0, 2) {
GET_NON_NULL_NATIVE_ARGUMENT(Float64x2, self, arguments->NativeArgAt(0));
GET_NON_NULL_NATIVE_ARGUMENT(Float64x2, other, arguments->NativeArgAt(1));
double _x = self.x() + other.x();
double _y = self.y() + other.y();
return Float64x2::New(_x, _y);
}
DEFINE_NATIVE_ENTRY(Float64x2_negate, 0, 1) {
GET_NON_NULL_NATIVE_ARGUMENT(Float64x2, self, arguments->NativeArgAt(0));
double _x = -self.x();
double _y = -self.y();
return Float64x2::New(_x, _y);
}
DEFINE_NATIVE_ENTRY(Float64x2_sub, 0, 2) {
GET_NON_NULL_NATIVE_ARGUMENT(Float64x2, self, arguments->NativeArgAt(0));
GET_NON_NULL_NATIVE_ARGUMENT(Float64x2, other, arguments->NativeArgAt(1));
double _x = self.x() - other.x();
double _y = self.y() - other.y();
return Float64x2::New(_x, _y);
}
DEFINE_NATIVE_ENTRY(Float64x2_mul, 0, 2) {
GET_NON_NULL_NATIVE_ARGUMENT(Float64x2, self, arguments->NativeArgAt(0));
GET_NON_NULL_NATIVE_ARGUMENT(Float64x2, other, arguments->NativeArgAt(1));
double _x = self.x() * other.x();
double _y = self.y() * other.y();
return Float64x2::New(_x, _y);
}
DEFINE_NATIVE_ENTRY(Float64x2_div, 0, 2) {
GET_NON_NULL_NATIVE_ARGUMENT(Float64x2, self, arguments->NativeArgAt(0));
GET_NON_NULL_NATIVE_ARGUMENT(Float64x2, other, arguments->NativeArgAt(1));
double _x = Utils::DivideAllowZero(self.x(), other.x());
double _y = Utils::DivideAllowZero(self.y(), other.y());
return Float64x2::New(_x, _y);
}
DEFINE_NATIVE_ENTRY(Float64x2_scale, 0, 2) {
GET_NON_NULL_NATIVE_ARGUMENT(Float64x2, self, arguments->NativeArgAt(0));
GET_NON_NULL_NATIVE_ARGUMENT(Double, scale, arguments->NativeArgAt(1));
double _s = scale.value();
double _x = self.x() * _s;
double _y = self.y() * _s;
return Float64x2::New(_x, _y);
}
DEFINE_NATIVE_ENTRY(Float64x2_abs, 0, 1) {
GET_NON_NULL_NATIVE_ARGUMENT(Float64x2, self, arguments->NativeArgAt(0));
double _x = fabs(self.x());
double _y = fabs(self.y());
return Float64x2::New(_x, _y);
}
#if defined(TARGET_ARCH_ARM64) || defined(TARGET_ARCH_ARM)
static double vmind(double f1, double f2) {
if (f1 == f2) {
// take care of (-0.0) < 0.0, (they are equal according to minss)
return signbit(f1) ? f1 : f2;
}
return f1 > f2 ? f2 : f1;
}
static double vmaxd(double f1, double f2) {
if (f1 == f2) {
// take care of (-0.0) < 0.0, (they are equal according to minss)
return signbit(f1) ? f2 : f1;
}
return f1 < f2 ? f2 : f1;
}
#endif
DEFINE_NATIVE_ENTRY(Float64x2_clamp, 0, 3) {
GET_NON_NULL_NATIVE_ARGUMENT(Float64x2, self, arguments->NativeArgAt(0));
GET_NON_NULL_NATIVE_ARGUMENT(Float64x2, lo, arguments->NativeArgAt(1));
GET_NON_NULL_NATIVE_ARGUMENT(Float64x2, hi, arguments->NativeArgAt(2));
// The order of the clamping must match the order of the optimized code:
// MAX(MIN(self, hi), lo).
double _x;
double _y;
// ARM semantics are different from X86/X64 at an instruction level. Ensure
// that we match the semantics of the architecture in the C version.
#if defined(TARGET_ARCH_IA32) || defined(TARGET_ARCH_X64)
_x = self.x() < hi.x() ? self.x() : hi.x();
_y = self.y() < hi.y() ? self.y() : hi.y();
_x = lo.x() < _x ? _x : lo.x();
_y = lo.y() < _y ? _y : lo.y();
#elif defined(TARGET_ARCH_ARM64) || defined(TARGET_ARCH_ARM)
_x = vmind(self.x(), hi.x());
_y = vmind(self.y(), hi.y());
_x = vmaxd(_x, lo.x());
_y = vmaxd(_y, lo.y());
#elif defined(TARGET_ARCH_RISCV32) || defined(TARGET_ARCH_RISCV64)
_x = fmin(self.x(), hi.x());
_y = fmin(self.y(), hi.y());
_x = fmax(_x, lo.x());
_y = fmax(_y, lo.y());
#else
#error Unknown architecture.
#endif
return Float64x2::New(_x, _y);
}
DEFINE_NATIVE_ENTRY(Float64x2_getX, 0, 1) {
GET_NON_NULL_NATIVE_ARGUMENT(Float64x2, self, arguments->NativeArgAt(0));
return Double::New(self.x());
}
DEFINE_NATIVE_ENTRY(Float64x2_getY, 0, 1) {
GET_NON_NULL_NATIVE_ARGUMENT(Float64x2, self, arguments->NativeArgAt(0));
return Double::New(self.y());
}
DEFINE_NATIVE_ENTRY(Float64x2_getSignMask, 0, 1) {
GET_NON_NULL_NATIVE_ARGUMENT(Float64x2, self, arguments->NativeArgAt(0));
uint32_t mx = (bit_cast<uint64_t>(self.x()) & 0x8000000000000000LL) >> 63;
uint32_t my = (bit_cast<uint64_t>(self.y()) & 0x8000000000000000LL) >> 63;
uint32_t value = mx | (my << 1);
return Integer::New(value);
}
DEFINE_NATIVE_ENTRY(Float64x2_setX, 0, 2) {
GET_NON_NULL_NATIVE_ARGUMENT(Float64x2, self, arguments->NativeArgAt(0));
GET_NON_NULL_NATIVE_ARGUMENT(Double, x, arguments->NativeArgAt(1));
double _x = x.value();
double _y = self.y();
return Float64x2::New(_x, _y);
}
DEFINE_NATIVE_ENTRY(Float64x2_setY, 0, 2) {
GET_NON_NULL_NATIVE_ARGUMENT(Float64x2, self, arguments->NativeArgAt(0));
GET_NON_NULL_NATIVE_ARGUMENT(Double, y, arguments->NativeArgAt(1));
double _x = self.x();
double _y = y.value();
return Float64x2::New(_x, _y);
}
DEFINE_NATIVE_ENTRY(Float64x2_min, 0, 2) {
GET_NON_NULL_NATIVE_ARGUMENT(Float64x2, self, arguments->NativeArgAt(0));
GET_NON_NULL_NATIVE_ARGUMENT(Float64x2, other, arguments->NativeArgAt(1));
double _x = self.x() < other.x() ? self.x() : other.x();
double _y = self.y() < other.y() ? self.y() : other.y();
return Float64x2::New(_x, _y);
}
DEFINE_NATIVE_ENTRY(Float64x2_max, 0, 2) {
GET_NON_NULL_NATIVE_ARGUMENT(Float64x2, self, arguments->NativeArgAt(0));
GET_NON_NULL_NATIVE_ARGUMENT(Float64x2, other, arguments->NativeArgAt(1));
double _x = self.x() > other.x() ? self.x() : other.x();
double _y = self.y() > other.y() ? self.y() : other.y();
return Float64x2::New(_x, _y);
}
DEFINE_NATIVE_ENTRY(Float64x2_sqrt, 0, 1) {
GET_NON_NULL_NATIVE_ARGUMENT(Float64x2, self, arguments->NativeArgAt(0));
double _x = sqrt(self.x());
double _y = sqrt(self.y());
return Float64x2::New(_x, _y);
}
} // namespace dart