src/third_party/skia/include/private/SkNx.h - cobalt - Git at Google

 /*
  * Copyright 2015 Google Inc.
  *
  * Use of this source code is governed by a BSD-style license that can be
  * found in the LICENSE file.
  */

 #ifndef SkNx_DEFINED
 #define SkNx_DEFINED

 #include "include/core/SkScalar.h"
 #include "include/core/SkTypes.h"
 #include "include/private/SkSafe_math.h"

 #include <algorithm>
 #include <limits>
 #include <type_traits>

 // Every single SkNx method wants to be fully inlined.  (We know better than MSVC).
 #define AI SK_ALWAYS_INLINE

 namespace {  // NOLINT(google-build-namespaces)

 // The default SkNx<N,T> just proxies down to a pair of SkNx<N/2, T>.
 template <int N, typename T>
 struct SkNx {
     typedef SkNx<N/2, T> Half;

     Half fLo, fHi;

     AI SkNx() = default;
     AI SkNx(const Half& lo, const Half& hi) : fLo(lo), fHi(hi) {}

     AI SkNx(T v) : fLo(v), fHi(v) {}

     AI SkNx(T a, T b)           : fLo(a)  , fHi(b)   { static_assert(N==2, ""); }
     AI SkNx(T a, T b, T c, T d) : fLo(a,b), fHi(c,d) { static_assert(N==4, ""); }
     AI SkNx(T a, T b, T c, T d,  T e, T f, T g, T h) : fLo(a,b,c,d), fHi(e,f,g,h) {
         static_assert(N==8, "");
     }
     AI SkNx(T a, T b, T c, T d,  T e, T f, T g, T h,
             T i, T j, T k, T l,  T m, T n, T o, T p)
         : fLo(a,b,c,d, e,f,g,h), fHi(i,j,k,l, m,n,o,p) {
         static_assert(N==16, "");
     }

     AI T operator[](int k) const {
         SkASSERT(0 <= k && k < N);
         return k < N/2 ? fLo[k] : fHi[k-N/2];
     }

     AI static SkNx Load(const void* vptr) {
         auto ptr = (const char*)vptr;
         return { Half::Load(ptr), Half::Load(ptr + N/2*sizeof(T)) };
     }
     AI void store(void* vptr) const {
         auto ptr = (char*)vptr;
         fLo.store(ptr);
         fHi.store(ptr + N/2*sizeof(T));
     }

     AI static void Load4(const void* vptr, SkNx* a, SkNx* b, SkNx* c, SkNx* d) {
         auto ptr = (const char*)vptr;
         Half al, bl, cl, dl,
              ah, bh, ch, dh;
         Half::Load4(ptr                  , &al, &bl, &cl, &dl);
         Half::Load4(ptr + 4*N/2*sizeof(T), &ah, &bh, &ch, &dh);
         *a = SkNx{al, ah};
         *b = SkNx{bl, bh};
         *c = SkNx{cl, ch};
         *d = SkNx{dl, dh};
     }
     AI static void Load3(const void* vptr, SkNx* a, SkNx* b, SkNx* c) {
         auto ptr = (const char*)vptr;
         Half al, bl, cl,
              ah, bh, ch;
         Half::Load3(ptr                  , &al, &bl, &cl);
         Half::Load3(ptr + 3*N/2*sizeof(T), &ah, &bh, &ch);
         *a = SkNx{al, ah};
         *b = SkNx{bl, bh};
         *c = SkNx{cl, ch};
     }
     AI static void Load2(const void* vptr, SkNx* a, SkNx* b) {
         auto ptr = (const char*)vptr;
         Half al, bl,
              ah, bh;
         Half::Load2(ptr                  , &al, &bl);
         Half::Load2(ptr + 2*N/2*sizeof(T), &ah, &bh);
         *a = SkNx{al, ah};
         *b = SkNx{bl, bh};
     }
     AI static void Store4(void* vptr, const SkNx& a, const SkNx& b, const SkNx& c, const SkNx& d) {
         auto ptr = (char*)vptr;
         Half::Store4(ptr,                   a.fLo, b.fLo, c.fLo, d.fLo);
         Half::Store4(ptr + 4*N/2*sizeof(T), a.fHi, b.fHi, c.fHi, d.fHi);
     }
     AI static void Store3(void* vptr, const SkNx& a, const SkNx& b, const SkNx& c) {
         auto ptr = (char*)vptr;
         Half::Store3(ptr,                   a.fLo, b.fLo, c.fLo);
         Half::Store3(ptr + 3*N/2*sizeof(T), a.fHi, b.fHi, c.fHi);
     }
     AI static void Store2(void* vptr, const SkNx& a, const SkNx& b) {
         auto ptr = (char*)vptr;
         Half::Store2(ptr,                   a.fLo, b.fLo);
         Half::Store2(ptr + 2*N/2*sizeof(T), a.fHi, b.fHi);
     }

     AI T min() const { return SkTMin(fLo.min(), fHi.min()); }
     AI T max() const { return SkTMax(fLo.max(), fHi.max()); }
     AI bool anyTrue() const { return fLo.anyTrue() || fHi.anyTrue(); }
     AI bool allTrue() const { return fLo.allTrue() && fHi.allTrue(); }

     AI SkNx    abs() const { return { fLo.   abs(), fHi.   abs() }; }
     AI SkNx   sqrt() const { return { fLo.  sqrt(), fHi.  sqrt() }; }
     AI SkNx  rsqrt() const { return { fLo. rsqrt(), fHi. rsqrt() }; }
     AI SkNx  floor() const { return { fLo. floor(), fHi. floor() }; }
     AI SkNx invert() const { return { fLo.invert(), fHi.invert() }; }

     AI SkNx operator!() const { return { !fLo, !fHi }; }
     AI SkNx operator-() const { return { -fLo, -fHi }; }
     AI SkNx operator~() const { return { ~fLo, ~fHi }; }

     AI SkNx operator<<(int bits) const { return { fLo << bits, fHi << bits }; }
     AI SkNx operator>>(int bits) const { return { fLo >> bits, fHi >> bits }; }

     AI SkNx operator+(const SkNx& y) const { return { fLo + y.fLo, fHi + y.fHi }; }
     AI SkNx operator-(const SkNx& y) const { return { fLo - y.fLo, fHi - y.fHi }; }
     AI SkNx operator*(const SkNx& y) const { return { fLo * y.fLo, fHi * y.fHi }; }
     AI SkNx operator/(const SkNx& y) const { return { fLo / y.fLo, fHi / y.fHi }; }

     AI SkNx operator&(const SkNx& y) const { return { fLo & y.fLo, fHi & y.fHi }; }
     AI SkNx operator|(const SkNx& y) const { return { fLo | y.fLo, fHi | y.fHi }; }
     AI SkNx operator^(const SkNx& y) const { return { fLo ^ y.fLo, fHi ^ y.fHi }; }

     AI SkNx operator==(const SkNx& y) const { return { fLo == y.fLo, fHi == y.fHi }; }
     AI SkNx operator!=(const SkNx& y) const { return { fLo != y.fLo, fHi != y.fHi }; }
     AI SkNx operator<=(const SkNx& y) const { return { fLo <= y.fLo, fHi <= y.fHi }; }
     AI SkNx operator>=(const SkNx& y) const { return { fLo >= y.fLo, fHi >= y.fHi }; }
     AI SkNx operator< (const SkNx& y) const { return { fLo <  y.fLo, fHi <  y.fHi }; }
     AI SkNx operator> (const SkNx& y) const { return { fLo >  y.fLo, fHi >  y.fHi }; }

     AI SkNx saturatedAdd(const SkNx& y) const {
         return { fLo.saturatedAdd(y.fLo), fHi.saturatedAdd(y.fHi) };
     }

     AI SkNx mulHi(const SkNx& m) const {
         return { fLo.mulHi(m.fLo), fHi.mulHi(m.fHi) };
     }
     AI SkNx thenElse(const SkNx& t, const SkNx& e) const {
         return { fLo.thenElse(t.fLo, e.fLo), fHi.thenElse(t.fHi, e.fHi) };
     }
     AI static SkNx Min(const SkNx& x, const SkNx& y) {
         return { Half::Min(x.fLo, y.fLo), Half::Min(x.fHi, y.fHi) };
     }
     AI static SkNx Max(const SkNx& x, const SkNx& y) {
         return { Half::Max(x.fLo, y.fLo), Half::Max(x.fHi, y.fHi) };
     }
 };

 // The N -> N/2 recursion bottoms out at N == 1, a scalar value.
 template <typename T>
 struct SkNx<1,T> {
     T fVal;

     AI SkNx() = default;
     AI SkNx(T v) : fVal(v) {}

     // Android complains against unused parameters, so we guard it
     AI T operator[](int SkDEBUGCODE(k)) const {
         SkASSERT(k == 0);
         return fVal;
     }

     AI static SkNx Load(const void* ptr) {
         SkNx v;
         memcpy(&v, ptr, sizeof(T));
         return v;
     }
     AI void store(void* ptr) const { memcpy(ptr, &fVal, sizeof(T)); }

     AI static void Load4(const void* vptr, SkNx* a, SkNx* b, SkNx* c, SkNx* d) {
         auto ptr = (const char*)vptr;
         *a = Load(ptr + 0*sizeof(T));
         *b = Load(ptr + 1*sizeof(T));
         *c = Load(ptr + 2*sizeof(T));
         *d = Load(ptr + 3*sizeof(T));
     }
     AI static void Load3(const void* vptr, SkNx* a, SkNx* b, SkNx* c) {
         auto ptr = (const char*)vptr;
         *a = Load(ptr + 0*sizeof(T));
         *b = Load(ptr + 1*sizeof(T));
         *c = Load(ptr + 2*sizeof(T));
     }
     AI static void Load2(const void* vptr, SkNx* a, SkNx* b) {
         auto ptr = (const char*)vptr;
         *a = Load(ptr + 0*sizeof(T));
         *b = Load(ptr + 1*sizeof(T));
     }
     AI static void Store4(void* vptr, const SkNx& a, const SkNx& b, const SkNx& c, const SkNx& d) {
         auto ptr = (char*)vptr;
         a.store(ptr + 0*sizeof(T));
         b.store(ptr + 1*sizeof(T));
         c.store(ptr + 2*sizeof(T));
         d.store(ptr + 3*sizeof(T));
     }
     AI static void Store3(void* vptr, const SkNx& a, const SkNx& b, const SkNx& c) {
         auto ptr = (char*)vptr;
         a.store(ptr + 0*sizeof(T));
         b.store(ptr + 1*sizeof(T));
         c.store(ptr + 2*sizeof(T));
     }
     AI static void Store2(void* vptr, const SkNx& a, const SkNx& b) {
         auto ptr = (char*)vptr;
         a.store(ptr + 0*sizeof(T));
         b.store(ptr + 1*sizeof(T));
     }

     AI T min() const { return fVal; }
     AI T max() const { return fVal; }
     AI bool anyTrue() const { return fVal != 0; }
     AI bool allTrue() const { return fVal != 0; }

     AI SkNx    abs() const { return Abs(fVal); }
     AI SkNx   sqrt() const { return Sqrt(fVal); }
     AI SkNx  rsqrt() const { return T(1) / this->sqrt(); }
     AI SkNx  floor() const { return Floor(fVal); }
     AI SkNx invert() const { return T(1) / *this; }

     AI SkNx operator!() const { return !fVal; }
     AI SkNx operator-() const { return -fVal; }
     AI SkNx operator~() const { return FromBits(~ToBits(fVal)); }

     AI SkNx operator<<(int bits) const { return fVal << bits; }
     AI SkNx operator>>(int bits) const { return fVal >> bits; }

     AI SkNx operator+(const SkNx& y) const { return fVal + y.fVal; }
     AI SkNx operator-(const SkNx& y) const { return fVal - y.fVal; }
     AI SkNx operator*(const SkNx& y) const { return fVal * y.fVal; }
     AI SkNx operator/(const SkNx& y) const { return fVal / y.fVal; }

     AI SkNx operator&(const SkNx& y) const { return FromBits(ToBits(fVal) & ToBits(y.fVal)); }
     AI SkNx operator|(const SkNx& y) const { return FromBits(ToBits(fVal) | ToBits(y.fVal)); }
     AI SkNx operator^(const SkNx& y) const { return FromBits(ToBits(fVal) ^ ToBits(y.fVal)); }

     AI SkNx operator==(const SkNx& y) const { return FromBits(fVal == y.fVal ? ~0 : 0); }
     AI SkNx operator!=(const SkNx& y) const { return FromBits(fVal != y.fVal ? ~0 : 0); }
     AI SkNx operator<=(const SkNx& y) const { return FromBits(fVal <= y.fVal ? ~0 : 0); }
     AI SkNx operator>=(const SkNx& y) const { return FromBits(fVal >= y.fVal ? ~0 : 0); }
     AI SkNx operator< (const SkNx& y) const { return FromBits(fVal <  y.fVal ? ~0 : 0); }
     AI SkNx operator> (const SkNx& y) const { return FromBits(fVal >  y.fVal ? ~0 : 0); }

     AI static SkNx Min(const SkNx& x, const SkNx& y) { return x.fVal < y.fVal ? x : y; }
     AI static SkNx Max(const SkNx& x, const SkNx& y) { return x.fVal > y.fVal ? x : y; }

     AI SkNx saturatedAdd(const SkNx& y) const {
         static_assert(std::is_unsigned<T>::value, "");
         T sum = fVal + y.fVal;
         return sum < fVal ? std::numeric_limits<T>::max() : sum;
     }

     AI SkNx mulHi(const SkNx& m) const {
         static_assert(std::is_unsigned<T>::value, "");
         static_assert(sizeof(T) <= 4, "");
         return static_cast<T>((static_cast<uint64_t>(fVal) * m.fVal) >> (sizeof(T)*8));
     }

     AI SkNx thenElse(const SkNx& t, const SkNx& e) const { return fVal != 0 ? t : e; }

 private:
     // Helper functions to choose the right float/double methods.  (In <cmath> madness lies...)
     AI static int     Abs(int val) { return  val < 0 ? -val : val; }

     AI static float   Abs(float val) { return  ::fabsf(val); }
     AI static float  Sqrt(float val) { return  ::sqrtf(val); }
     AI static float Floor(float val) { return ::floorf(val); }

     AI static double   Abs(double val) { return  ::fabs(val); }
     AI static double  Sqrt(double val) { return  ::sqrt(val); }
     AI static double Floor(double val) { return ::floor(val); }

     // Helper functions for working with floats/doubles as bit patterns.
     template <typename U>
     AI static U ToBits(U v) { return v; }
     AI static int32_t ToBits(float  v) { int32_t bits; memcpy(&bits, &v, sizeof(v)); return bits; }
     AI static int64_t ToBits(double v) { int64_t bits; memcpy(&bits, &v, sizeof(v)); return bits; }

     template <typename Bits>
     AI static T FromBits(Bits bits) {
         static_assert(std::is_pod<T   >::value &&
                       std::is_pod<Bits>::value &&
                       sizeof(T) <= sizeof(Bits), "");
         T val;
         memcpy(&val, &bits, sizeof(T));
         return val;
     }
 };

 // Allow scalars on the left or right of binary operators, and things like +=, &=, etc.
 #define V template <int N, typename T> AI static SkNx<N,T>
     V operator+ (T x, const SkNx<N,T>& y) { return SkNx<N,T>(x) +  y; }
     V operator- (T x, const SkNx<N,T>& y) { return SkNx<N,T>(x) -  y; }
     V operator* (T x, const SkNx<N,T>& y) { return SkNx<N,T>(x) *  y; }
     V operator/ (T x, const SkNx<N,T>& y) { return SkNx<N,T>(x) /  y; }
     V operator& (T x, const SkNx<N,T>& y) { return SkNx<N,T>(x) &  y; }
     V operator| (T x, const SkNx<N,T>& y) { return SkNx<N,T>(x) |  y; }
     V operator^ (T x, const SkNx<N,T>& y) { return SkNx<N,T>(x) ^  y; }
     V operator==(T x, const SkNx<N,T>& y) { return SkNx<N,T>(x) == y; }
     V operator!=(T x, const SkNx<N,T>& y) { return SkNx<N,T>(x) != y; }
     V operator<=(T x, const SkNx<N,T>& y) { return SkNx<N,T>(x) <= y; }
     V operator>=(T x, const SkNx<N,T>& y) { return SkNx<N,T>(x) >= y; }
     V operator< (T x, const SkNx<N,T>& y) { return SkNx<N,T>(x) <  y; }
     V operator> (T x, const SkNx<N,T>& y) { return SkNx<N,T>(x) >  y; }

     V operator+ (const SkNx<N,T>& x, T y) { return x +  SkNx<N,T>(y); }
     V operator- (const SkNx<N,T>& x, T y) { return x -  SkNx<N,T>(y); }
     V operator* (const SkNx<N,T>& x, T y) { return x *  SkNx<N,T>(y); }
     V operator/ (const SkNx<N,T>& x, T y) { return x /  SkNx<N,T>(y); }
     V operator& (const SkNx<N,T>& x, T y) { return x &  SkNx<N,T>(y); }
     V operator| (const SkNx<N,T>& x, T y) { return x |  SkNx<N,T>(y); }
     V operator^ (const SkNx<N,T>& x, T y) { return x ^  SkNx<N,T>(y); }
     V operator==(const SkNx<N,T>& x, T y) { return x == SkNx<N,T>(y); }
     V operator!=(const SkNx<N,T>& x, T y) { return x != SkNx<N,T>(y); }
     V operator<=(const SkNx<N,T>& x, T y) { return x <= SkNx<N,T>(y); }
     V operator>=(const SkNx<N,T>& x, T y) { return x >= SkNx<N,T>(y); }
     V operator< (const SkNx<N,T>& x, T y) { return x <  SkNx<N,T>(y); }
     V operator> (const SkNx<N,T>& x, T y) { return x >  SkNx<N,T>(y); }

     V& operator<<=(SkNx<N,T>& x, int bits) { return (x = x << bits); }
     V& operator>>=(SkNx<N,T>& x, int bits) { return (x = x >> bits); }

     V& operator +=(SkNx<N,T>& x, const SkNx<N,T>& y) { return (x = x + y); }
     V& operator -=(SkNx<N,T>& x, const SkNx<N,T>& y) { return (x = x - y); }
     V& operator *=(SkNx<N,T>& x, const SkNx<N,T>& y) { return (x = x * y); }
     V& operator /=(SkNx<N,T>& x, const SkNx<N,T>& y) { return (x = x / y); }
     V& operator &=(SkNx<N,T>& x, const SkNx<N,T>& y) { return (x = x & y); }
     V& operator |=(SkNx<N,T>& x, const SkNx<N,T>& y) { return (x = x | y); }
     V& operator ^=(SkNx<N,T>& x, const SkNx<N,T>& y) { return (x = x ^ y); }

     V& operator +=(SkNx<N,T>& x, T y) { return (x = x + SkNx<N,T>(y)); }
     V& operator -=(SkNx<N,T>& x, T y) { return (x = x - SkNx<N,T>(y)); }
     V& operator *=(SkNx<N,T>& x, T y) { return (x = x * SkNx<N,T>(y)); }
     V& operator /=(SkNx<N,T>& x, T y) { return (x = x / SkNx<N,T>(y)); }
     V& operator &=(SkNx<N,T>& x, T y) { return (x = x & SkNx<N,T>(y)); }
     V& operator |=(SkNx<N,T>& x, T y) { return (x = x | SkNx<N,T>(y)); }
     V& operator ^=(SkNx<N,T>& x, T y) { return (x = x ^ SkNx<N,T>(y)); }
 #undef V

 // SkNx<N,T> ~~> SkNx<N/2,T> + SkNx<N/2,T>
 template <int N, typename T>
 AI static void SkNx_split(const SkNx<N,T>& v, SkNx<N/2,T>* lo, SkNx<N/2,T>* hi) {
     *lo = v.fLo;
     *hi = v.fHi;
 }

 // SkNx<N/2,T> + SkNx<N/2,T> ~~> SkNx<N,T>
 template <int N, typename T>
 AI static SkNx<N*2,T> SkNx_join(const SkNx<N,T>& lo, const SkNx<N,T>& hi) {
     return { lo, hi };
 }

 // A very generic shuffle.  Can reorder, duplicate, contract, expand...
 //    Sk4f v = { R,G,B,A };
 //    SkNx_shuffle<2,1,0,3>(v)         ~~> {B,G,R,A}
 //    SkNx_shuffle<2,1>(v)             ~~> {B,G}
 //    SkNx_shuffle<2,1,2,1,2,1,2,1>(v) ~~> {B,G,B,G,B,G,B,G}
 //    SkNx_shuffle<3,3,3,3>(v)         ~~> {A,A,A,A}
 template <int... Ix, int N, typename T>
 AI static SkNx<sizeof...(Ix),T> SkNx_shuffle(const SkNx<N,T>& v) {
     return { v[Ix]... };
 }

 // Cast from SkNx<N, Src> to SkNx<N, Dst>, as if you called static_cast<Dst>(Src).
 template <typename Dst, typename Src, int N>
 AI static SkNx<N,Dst> SkNx_cast(const SkNx<N,Src>& v) {
     return { SkNx_cast<Dst>(v.fLo), SkNx_cast<Dst>(v.fHi) };
 }
 template <typename Dst, typename Src>
 AI static SkNx<1,Dst> SkNx_cast(const SkNx<1,Src>& v) {
     return static_cast<Dst>(v.fVal);
 }

 template <int N, typename T>
 AI static SkNx<N,T> SkNx_fma(const SkNx<N,T>& f, const SkNx<N,T>& m, const SkNx<N,T>& a) {
     return f*m+a;
 }

 }  // namespace

 typedef SkNx<2,     float> Sk2f;
 typedef SkNx<4,     float> Sk4f;
 typedef SkNx<8,     float> Sk8f;
 typedef SkNx<16,    float> Sk16f;

 typedef SkNx<2,  SkScalar> Sk2s;
 typedef SkNx<4,  SkScalar> Sk4s;
 typedef SkNx<8,  SkScalar> Sk8s;
 typedef SkNx<16, SkScalar> Sk16s;

 typedef SkNx<4,   uint8_t> Sk4b;
 typedef SkNx<8,   uint8_t> Sk8b;
 typedef SkNx<16,  uint8_t> Sk16b;

 typedef SkNx<4,  uint16_t> Sk4h;
 typedef SkNx<8,  uint16_t> Sk8h;
 typedef SkNx<16, uint16_t> Sk16h;

 typedef SkNx<4,  int32_t> Sk4i;
 typedef SkNx<8,  int32_t> Sk8i;
 typedef SkNx<4, uint32_t> Sk4u;

 // Include platform specific specializations if available.
 #if !defined(SKNX_NO_SIMD) && SK_CPU_SSE_LEVEL >= SK_CPU_SSE_LEVEL_SSE2
     #include "include/private/SkNx_sse.h"
 #elif !defined(SKNX_NO_SIMD) && defined(SK_ARM_HAS_NEON)
     #include "include/private/SkNx_neon.h"
 #else

 AI static Sk4i Sk4f_round(const Sk4f& x) {
     return { (int) lrintf (x[0]),
              (int) lrintf (x[1]),
              (int) lrintf (x[2]),
              (int) lrintf (x[3]), };
 }

 #endif

 AI static void Sk4f_ToBytes(uint8_t p[16],
                             const Sk4f& a, const Sk4f& b, const Sk4f& c, const Sk4f& d) {
     SkNx_cast<uint8_t>(SkNx_join(SkNx_join(a,b), SkNx_join(c,d))).store(p);
 }

 #undef AI

 #endif//SkNx_DEFINED
	/*
	* Copyright 2015 Google Inc.
	*
	* Use of this source code is governed by a BSD-style license that can be
	* found in the LICENSE file.
	*/

	#ifndef SkNx_DEFINED
	#define SkNx_DEFINED

	#include "include/core/SkScalar.h"
	#include "include/core/SkTypes.h"
	#include "include/private/SkSafe_math.h"

	#include <algorithm>
	#include <limits>
	#include <type_traits>

	// Every single SkNx method wants to be fully inlined. (We know better than MSVC).
	#define AI SK_ALWAYS_INLINE

	namespace { // NOLINT(google-build-namespaces)

	// The default SkNx<N,T> just proxies down to a pair of SkNx<N/2, T>.
	template <int N, typename T>
	struct SkNx {
	typedef SkNx<N/2, T> Half;

	Half fLo, fHi;

	AI SkNx() = default;
	AI SkNx(const Half& lo, const Half& hi) : fLo(lo), fHi(hi) {}

	AI SkNx(T v) : fLo(v), fHi(v) {}

	AI SkNx(T a, T b) : fLo(a) , fHi(b) { static_assert(N==2, ""); }
	AI SkNx(T a, T b, T c, T d) : fLo(a,b), fHi(c,d) { static_assert(N==4, ""); }
	AI SkNx(T a, T b, T c, T d, T e, T f, T g, T h) : fLo(a,b,c,d), fHi(e,f,g,h) {
	static_assert(N==8, "");
	}
	AI SkNx(T a, T b, T c, T d, T e, T f, T g, T h,
	T i, T j, T k, T l, T m, T n, T o, T p)
	: fLo(a,b,c,d, e,f,g,h), fHi(i,j,k,l, m,n,o,p) {
	static_assert(N==16, "");
	}

	AI T operator[](int k) const {
	SkASSERT(0 <= k && k < N);
	return k < N/2 ? fLo[k] : fHi[k-N/2];
	}

	AI static SkNx Load(const void* vptr) {
	auto ptr = (const char*)vptr;
	return { Half::Load(ptr), Half::Load(ptr + N/2*sizeof(T)) };
	}
	AI void store(void* vptr) const {
	auto ptr = (char*)vptr;
	fLo.store(ptr);
	fHi.store(ptr + N/2*sizeof(T));
	}

	AI static void Load4(const void* vptr, SkNx* a, SkNx* b, SkNx* c, SkNx* d) {
	auto ptr = (const char*)vptr;
	Half al, bl, cl, dl,
	ah, bh, ch, dh;
	Half::Load4(ptr , &al, &bl, &cl, &dl);
	Half::Load4(ptr + 4N/2sizeof(T), &ah, &bh, &ch, &dh);
	*a = SkNx{al, ah};
	*b = SkNx{bl, bh};
	*c = SkNx{cl, ch};
	*d = SkNx{dl, dh};
	}
	AI static void Load3(const void* vptr, SkNx* a, SkNx* b, SkNx* c) {
	auto ptr = (const char*)vptr;
	Half al, bl, cl,
	ah, bh, ch;
	Half::Load3(ptr , &al, &bl, &cl);
	Half::Load3(ptr + 3N/2sizeof(T), &ah, &bh, &ch);
	*a = SkNx{al, ah};
	*b = SkNx{bl, bh};
	*c = SkNx{cl, ch};
	}
	AI static void Load2(const void* vptr, SkNx* a, SkNx* b) {
	auto ptr = (const char*)vptr;
	Half al, bl,
	ah, bh;
	Half::Load2(ptr , &al, &bl);
	Half::Load2(ptr + 2N/2sizeof(T), &ah, &bh);
	*a = SkNx{al, ah};
	*b = SkNx{bl, bh};
	}
	AI static void Store4(void* vptr, const SkNx& a, const SkNx& b, const SkNx& c, const SkNx& d) {
	auto ptr = (char*)vptr;
	Half::Store4(ptr, a.fLo, b.fLo, c.fLo, d.fLo);
	Half::Store4(ptr + 4N/2sizeof(T), a.fHi, b.fHi, c.fHi, d.fHi);
	}
	AI static void Store3(void* vptr, const SkNx& a, const SkNx& b, const SkNx& c) {
	auto ptr = (char*)vptr;
	Half::Store3(ptr, a.fLo, b.fLo, c.fLo);
	Half::Store3(ptr + 3N/2sizeof(T), a.fHi, b.fHi, c.fHi);
	}
	AI static void Store2(void* vptr, const SkNx& a, const SkNx& b) {
	auto ptr = (char*)vptr;
	Half::Store2(ptr, a.fLo, b.fLo);
	Half::Store2(ptr + 2N/2sizeof(T), a.fHi, b.fHi);
	}

	AI T min() const { return SkTMin(fLo.min(), fHi.min()); }
	AI T max() const { return SkTMax(fLo.max(), fHi.max()); }
	AI bool anyTrue() const { return fLo.anyTrue() \|\| fHi.anyTrue(); }
	AI bool allTrue() const { return fLo.allTrue() && fHi.allTrue(); }

	AI SkNx abs() const { return { fLo. abs(), fHi. abs() }; }
	AI SkNx sqrt() const { return { fLo. sqrt(), fHi. sqrt() }; }
	AI SkNx rsqrt() const { return { fLo. rsqrt(), fHi. rsqrt() }; }
	AI SkNx floor() const { return { fLo. floor(), fHi. floor() }; }
	AI SkNx invert() const { return { fLo.invert(), fHi.invert() }; }

	AI SkNx operator!() const { return { !fLo, !fHi }; }
	AI SkNx operator-() const { return { -fLo, -fHi }; }
	AI SkNx operator~() const { return { ~fLo, ~fHi }; }

	AI SkNx operator<<(int bits) const { return { fLo << bits, fHi << bits }; }
	AI SkNx operator>>(int bits) const { return { fLo >> bits, fHi >> bits }; }

	AI SkNx operator+(const SkNx& y) const { return { fLo + y.fLo, fHi + y.fHi }; }
	AI SkNx operator-(const SkNx& y) const { return { fLo - y.fLo, fHi - y.fHi }; }
	AI SkNx operator(const SkNx& y) const { return { fLo y.fLo, fHi * y.fHi }; }
	AI SkNx operator/(const SkNx& y) const { return { fLo / y.fLo, fHi / y.fHi }; }

	AI SkNx operator&(const SkNx& y) const { return { fLo & y.fLo, fHi & y.fHi }; }
	AI SkNx operator\|(const SkNx& y) const { return { fLo \| y.fLo, fHi \| y.fHi }; }
	AI SkNx operator^(const SkNx& y) const { return { fLo ^ y.fLo, fHi ^ y.fHi }; }

	AI SkNx operator==(const SkNx& y) const { return { fLo == y.fLo, fHi == y.fHi }; }
	AI SkNx operator!=(const SkNx& y) const { return { fLo != y.fLo, fHi != y.fHi }; }
	AI SkNx operator<=(const SkNx& y) const { return { fLo <= y.fLo, fHi <= y.fHi }; }
	AI SkNx operator>=(const SkNx& y) const { return { fLo >= y.fLo, fHi >= y.fHi }; }
	AI SkNx operator< (const SkNx& y) const { return { fLo < y.fLo, fHi < y.fHi }; }
	AI SkNx operator> (const SkNx& y) const { return { fLo > y.fLo, fHi > y.fHi }; }

	AI SkNx saturatedAdd(const SkNx& y) const {
	return { fLo.saturatedAdd(y.fLo), fHi.saturatedAdd(y.fHi) };
	}

	AI SkNx mulHi(const SkNx& m) const {
	return { fLo.mulHi(m.fLo), fHi.mulHi(m.fHi) };
	}
	AI SkNx thenElse(const SkNx& t, const SkNx& e) const {
	return { fLo.thenElse(t.fLo, e.fLo), fHi.thenElse(t.fHi, e.fHi) };
	}
	AI static SkNx Min(const SkNx& x, const SkNx& y) {
	return { Half::Min(x.fLo, y.fLo), Half::Min(x.fHi, y.fHi) };
	}
	AI static SkNx Max(const SkNx& x, const SkNx& y) {
	return { Half::Max(x.fLo, y.fLo), Half::Max(x.fHi, y.fHi) };
	}
	};

	// The N -> N/2 recursion bottoms out at N == 1, a scalar value.
	template <typename T>
	struct SkNx<1,T> {
	T fVal;

	AI SkNx() = default;
	AI SkNx(T v) : fVal(v) {}

	// Android complains against unused parameters, so we guard it
	AI T operator[](int SkDEBUGCODE(k)) const {
	SkASSERT(k == 0);
	return fVal;
	}

	AI static SkNx Load(const void* ptr) {
	SkNx v;
	memcpy(&v, ptr, sizeof(T));
	return v;
	}
	AI void store(void* ptr) const { memcpy(ptr, &fVal, sizeof(T)); }

	AI static void Load4(const void* vptr, SkNx* a, SkNx* b, SkNx* c, SkNx* d) {
	auto ptr = (const char*)vptr;
	a = Load(ptr + 0sizeof(T));
	b = Load(ptr + 1sizeof(T));
	c = Load(ptr + 2sizeof(T));
	d = Load(ptr + 3sizeof(T));
	}
	AI static void Load3(const void* vptr, SkNx* a, SkNx* b, SkNx* c) {
	auto ptr = (const char*)vptr;
	a = Load(ptr + 0sizeof(T));
	b = Load(ptr + 1sizeof(T));
	c = Load(ptr + 2sizeof(T));
	}
	AI static void Load2(const void* vptr, SkNx* a, SkNx* b) {
	auto ptr = (const char*)vptr;
	a = Load(ptr + 0sizeof(T));
	b = Load(ptr + 1sizeof(T));
	}
	AI static void Store4(void* vptr, const SkNx& a, const SkNx& b, const SkNx& c, const SkNx& d) {
	auto ptr = (char*)vptr;
	a.store(ptr + 0*sizeof(T));
	b.store(ptr + 1*sizeof(T));
	c.store(ptr + 2*sizeof(T));
	d.store(ptr + 3*sizeof(T));
	}
	AI static void Store3(void* vptr, const SkNx& a, const SkNx& b, const SkNx& c) {
	auto ptr = (char*)vptr;
	a.store(ptr + 0*sizeof(T));
	b.store(ptr + 1*sizeof(T));
	c.store(ptr + 2*sizeof(T));
	}
	AI static void Store2(void* vptr, const SkNx& a, const SkNx& b) {
	auto ptr = (char*)vptr;
	a.store(ptr + 0*sizeof(T));
	b.store(ptr + 1*sizeof(T));
	}

	AI T min() const { return fVal; }
	AI T max() const { return fVal; }
	AI bool anyTrue() const { return fVal != 0; }
	AI bool allTrue() const { return fVal != 0; }

	AI SkNx abs() const { return Abs(fVal); }
	AI SkNx sqrt() const { return Sqrt(fVal); }
	AI SkNx rsqrt() const { return T(1) / this->sqrt(); }
	AI SkNx floor() const { return Floor(fVal); }
	AI SkNx invert() const { return T(1) / *this; }

	AI SkNx operator!() const { return !fVal; }
	AI SkNx operator-() const { return -fVal; }
	AI SkNx operator~() const { return FromBits(~ToBits(fVal)); }

	AI SkNx operator<<(int bits) const { return fVal << bits; }
	AI SkNx operator>>(int bits) const { return fVal >> bits; }

	AI SkNx operator+(const SkNx& y) const { return fVal + y.fVal; }
	AI SkNx operator-(const SkNx& y) const { return fVal - y.fVal; }
	AI SkNx operator(const SkNx& y) const { return fVal y.fVal; }
	AI SkNx operator/(const SkNx& y) const { return fVal / y.fVal; }

	AI SkNx operator&(const SkNx& y) const { return FromBits(ToBits(fVal) & ToBits(y.fVal)); }
	AI SkNx operator\|(const SkNx& y) const { return FromBits(ToBits(fVal) \| ToBits(y.fVal)); }
	AI SkNx operator^(const SkNx& y) const { return FromBits(ToBits(fVal) ^ ToBits(y.fVal)); }

	AI SkNx operator==(const SkNx& y) const { return FromBits(fVal == y.fVal ? ~0 : 0); }
	AI SkNx operator!=(const SkNx& y) const { return FromBits(fVal != y.fVal ? ~0 : 0); }
	AI SkNx operator<=(const SkNx& y) const { return FromBits(fVal <= y.fVal ? ~0 : 0); }
	AI SkNx operator>=(const SkNx& y) const { return FromBits(fVal >= y.fVal ? ~0 : 0); }
	AI SkNx operator< (const SkNx& y) const { return FromBits(fVal < y.fVal ? ~0 : 0); }
	AI SkNx operator> (const SkNx& y) const { return FromBits(fVal > y.fVal ? ~0 : 0); }

	AI static SkNx Min(const SkNx& x, const SkNx& y) { return x.fVal < y.fVal ? x : y; }
	AI static SkNx Max(const SkNx& x, const SkNx& y) { return x.fVal > y.fVal ? x : y; }

	AI SkNx saturatedAdd(const SkNx& y) const {
	static_assert(std::is_unsigned<T>::value, "");
	T sum = fVal + y.fVal;
	return sum < fVal ? std::numeric_limits<T>::max() : sum;
	}

	AI SkNx mulHi(const SkNx& m) const {
	static_assert(std::is_unsigned<T>::value, "");
	static_assert(sizeof(T) <= 4, "");
	return static_cast<T>((static_cast<uint64_t>(fVal) * m.fVal) >> (sizeof(T)*8));
	}

	AI SkNx thenElse(const SkNx& t, const SkNx& e) const { return fVal != 0 ? t : e; }

	private:
	// Helper functions to choose the right float/double methods. (In <cmath> madness lies...)
	AI static int Abs(int val) { return val < 0 ? -val : val; }

	AI static float Abs(float val) { return ::fabsf(val); }
	AI static float Sqrt(float val) { return ::sqrtf(val); }
	AI static float Floor(float val) { return ::floorf(val); }

	AI static double Abs(double val) { return ::fabs(val); }
	AI static double Sqrt(double val) { return ::sqrt(val); }
	AI static double Floor(double val) { return ::floor(val); }

	// Helper functions for working with floats/doubles as bit patterns.
	template <typename U>
	AI static U ToBits(U v) { return v; }
	AI static int32_t ToBits(float v) { int32_t bits; memcpy(&bits, &v, sizeof(v)); return bits; }
	AI static int64_t ToBits(double v) { int64_t bits; memcpy(&bits, &v, sizeof(v)); return bits; }

	template <typename Bits>
	AI static T FromBits(Bits bits) {
	static_assert(std::is_pod<T >::value &&
	std::is_pod<Bits>::value &&
	sizeof(T) <= sizeof(Bits), "");
	T val;
	memcpy(&val, &bits, sizeof(T));
	return val;
	}
	};

	// Allow scalars on the left or right of binary operators, and things like +=, &=, etc.
	#define V template <int N, typename T> AI static SkNx<N,T>
	V operator+ (T x, const SkNx<N,T>& y) { return SkNx<N,T>(x) + y; }
	V operator- (T x, const SkNx<N,T>& y) { return SkNx<N,T>(x) - y; }
	V operator* (T x, const SkNx<N,T>& y) { return SkNx<N,T>(x) * y; }
	V operator/ (T x, const SkNx<N,T>& y) { return SkNx<N,T>(x) / y; }
	V operator& (T x, const SkNx<N,T>& y) { return SkNx<N,T>(x) & y; }
	V operator\| (T x, const SkNx<N,T>& y) { return SkNx<N,T>(x) \| y; }
	V operator^ (T x, const SkNx<N,T>& y) { return SkNx<N,T>(x) ^ y; }
	V operator==(T x, const SkNx<N,T>& y) { return SkNx<N,T>(x) == y; }
	V operator!=(T x, const SkNx<N,T>& y) { return SkNx<N,T>(x) != y; }
	V operator<=(T x, const SkNx<N,T>& y) { return SkNx<N,T>(x) <= y; }
	V operator>=(T x, const SkNx<N,T>& y) { return SkNx<N,T>(x) >= y; }
	V operator< (T x, const SkNx<N,T>& y) { return SkNx<N,T>(x) < y; }
	V operator> (T x, const SkNx<N,T>& y) { return SkNx<N,T>(x) > y; }

	V operator+ (const SkNx<N,T>& x, T y) { return x + SkNx<N,T>(y); }
	V operator- (const SkNx<N,T>& x, T y) { return x - SkNx<N,T>(y); }
	V operator* (const SkNx<N,T>& x, T y) { return x * SkNx<N,T>(y); }
	V operator/ (const SkNx<N,T>& x, T y) { return x / SkNx<N,T>(y); }
	V operator& (const SkNx<N,T>& x, T y) { return x & SkNx<N,T>(y); }
	V operator\| (const SkNx<N,T>& x, T y) { return x \| SkNx<N,T>(y); }
	V operator^ (const SkNx<N,T>& x, T y) { return x ^ SkNx<N,T>(y); }
	V operator==(const SkNx<N,T>& x, T y) { return x == SkNx<N,T>(y); }
	V operator!=(const SkNx<N,T>& x, T y) { return x != SkNx<N,T>(y); }
	V operator<=(const SkNx<N,T>& x, T y) { return x <= SkNx<N,T>(y); }
	V operator>=(const SkNx<N,T>& x, T y) { return x >= SkNx<N,T>(y); }
	V operator< (const SkNx<N,T>& x, T y) { return x < SkNx<N,T>(y); }
	V operator> (const SkNx<N,T>& x, T y) { return x > SkNx<N,T>(y); }

	V& operator<<=(SkNx<N,T>& x, int bits) { return (x = x << bits); }
	V& operator>>=(SkNx<N,T>& x, int bits) { return (x = x >> bits); }

	V& operator +=(SkNx<N,T>& x, const SkNx<N,T>& y) { return (x = x + y); }
	V& operator -=(SkNx<N,T>& x, const SkNx<N,T>& y) { return (x = x - y); }
	V& operator =(SkNx<N,T>& x, const SkNx<N,T>& y) { return (x = x y); }
	V& operator /=(SkNx<N,T>& x, const SkNx<N,T>& y) { return (x = x / y); }
	V& operator &=(SkNx<N,T>& x, const SkNx<N,T>& y) { return (x = x & y); }
	V& operator \|=(SkNx<N,T>& x, const SkNx<N,T>& y) { return (x = x \| y); }
	V& operator ^=(SkNx<N,T>& x, const SkNx<N,T>& y) { return (x = x ^ y); }

	V& operator +=(SkNx<N,T>& x, T y) { return (x = x + SkNx<N,T>(y)); }
	V& operator -=(SkNx<N,T>& x, T y) { return (x = x - SkNx<N,T>(y)); }
	V& operator =(SkNx<N,T>& x, T y) { return (x = x SkNx<N,T>(y)); }
	V& operator /=(SkNx<N,T>& x, T y) { return (x = x / SkNx<N,T>(y)); }
	V& operator &=(SkNx<N,T>& x, T y) { return (x = x & SkNx<N,T>(y)); }
	V& operator \|=(SkNx<N,T>& x, T y) { return (x = x \| SkNx<N,T>(y)); }
	V& operator ^=(SkNx<N,T>& x, T y) { return (x = x ^ SkNx<N,T>(y)); }
	#undef V

	// SkNx<N,T> ~~> SkNx<N/2,T> + SkNx<N/2,T>
	template <int N, typename T>
	AI static void SkNx_split(const SkNx<N,T>& v, SkNx<N/2,T>* lo, SkNx<N/2,T>* hi) {
	*lo = v.fLo;
	*hi = v.fHi;
	}

	// SkNx<N/2,T> + SkNx<N/2,T> ~~> SkNx<N,T>
	template <int N, typename T>
	AI static SkNx<N*2,T> SkNx_join(const SkNx<N,T>& lo, const SkNx<N,T>& hi) {
	return { lo, hi };
	}

	// A very generic shuffle. Can reorder, duplicate, contract, expand...
	// Sk4f v = { R,G,B,A };
	// SkNx_shuffle<2,1,0,3>(v) ~~> {B,G,R,A}
	// SkNx_shuffle<2,1>(v) ~~> {B,G}
	// SkNx_shuffle<2,1,2,1,2,1,2,1>(v) ~~> {B,G,B,G,B,G,B,G}
	// SkNx_shuffle<3,3,3,3>(v) ~~> {A,A,A,A}
	template <int... Ix, int N, typename T>
	AI static SkNx<sizeof...(Ix),T> SkNx_shuffle(const SkNx<N,T>& v) {
	return { v[Ix]... };
	}

	// Cast from SkNx<N, Src> to SkNx<N, Dst>, as if you called static_cast<Dst>(Src).
	template <typename Dst, typename Src, int N>
	AI static SkNx<N,Dst> SkNx_cast(const SkNx<N,Src>& v) {
	return { SkNx_cast<Dst>(v.fLo), SkNx_cast<Dst>(v.fHi) };
	}
	template <typename Dst, typename Src>
	AI static SkNx<1,Dst> SkNx_cast(const SkNx<1,Src>& v) {
	return static_cast<Dst>(v.fVal);
	}

	template <int N, typename T>
	AI static SkNx<N,T> SkNx_fma(const SkNx<N,T>& f, const SkNx<N,T>& m, const SkNx<N,T>& a) {
	return f*m+a;
	}

	} // namespace

	typedef SkNx<2, float> Sk2f;
	typedef SkNx<4, float> Sk4f;
	typedef SkNx<8, float> Sk8f;
	typedef SkNx<16, float> Sk16f;

	typedef SkNx<2, SkScalar> Sk2s;
	typedef SkNx<4, SkScalar> Sk4s;
	typedef SkNx<8, SkScalar> Sk8s;
	typedef SkNx<16, SkScalar> Sk16s;

	typedef SkNx<4, uint8_t> Sk4b;
	typedef SkNx<8, uint8_t> Sk8b;
	typedef SkNx<16, uint8_t> Sk16b;

	typedef SkNx<4, uint16_t> Sk4h;
	typedef SkNx<8, uint16_t> Sk8h;
	typedef SkNx<16, uint16_t> Sk16h;

	typedef SkNx<4, int32_t> Sk4i;
	typedef SkNx<8, int32_t> Sk8i;
	typedef SkNx<4, uint32_t> Sk4u;

	// Include platform specific specializations if available.
	#if !defined(SKNX_NO_SIMD) && SK_CPU_SSE_LEVEL >= SK_CPU_SSE_LEVEL_SSE2
	#include "include/private/SkNx_sse.h"
	#elif !defined(SKNX_NO_SIMD) && defined(SK_ARM_HAS_NEON)
	#include "include/private/SkNx_neon.h"
	#else

	AI static Sk4i Sk4f_round(const Sk4f& x) {
	return { (int) lrintf (x[0]),
	(int) lrintf (x[1]),
	(int) lrintf (x[2]),
	(int) lrintf (x[3]), };
	}

	#endif

	AI static void Sk4f_ToBytes(uint8_t p[16],
	const Sk4f& a, const Sk4f& b, const Sk4f& c, const Sk4f& d) {
	SkNx_cast<uint8_t>(SkNx_join(SkNx_join(a,b), SkNx_join(c,d))).store(p);
	}

	#undef AI

	#endif//SkNx_DEFINED