src/core/SkNx.h - skia - 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

 //#define SKNX_NO_SIMD

 #include "SkScalar.h"
 #include "SkTypes.h"
 #include <math.h>

 // The default implementations just fall back on a pair of size N/2.
 // These support the union of operations we might do to ints and floats, but
 // platform specializations might support fewer (e.g. no float <<, no int /).
 template <int N, typename T>
 class SkNx {
 public:
     SkNx() {}
     SkNx(T val) : fLo(val), fHi(val) {}

     typedef SkNx<N/2, T> Half;
     SkNx(const Half& lo, const Half& hi) : fLo(lo), fHi(hi) {}

     SkNx(T a, T b)                                : fLo(a),       fHi(b)       {}
     SkNx(T a, T b, T c, T d)                      : fLo(a,b),     fHi(c,d)     {}
     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) {}
     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 SkNx Load(const void* ptr) {
         auto vals = (const T*)ptr;
         return SkNx(Half::Load(vals), Half::Load(vals+N/2));
     }

     void store(void* ptr) const {
         auto vals = (T*)ptr;
         fLo.store(vals);
         fHi.store(vals+N/2);
     }

 #define OP(op) SkNx operator op(const SkNx& o) const { return {fLo op o.fLo, fHi op o.fHi}; }
     OP(+) OP(-) OP(*) OP(/)
     OP(&) OP(|) OP(^)
     OP(==) OP(!=) OP(<) OP(>) OP(<=) OP(>=)
 #undef OP

 #define OP(op) SkNx op() const { return {fLo.op(), fHi.op()}; }
     OP(abs) OP(floor)
     OP(sqrt) OP(rsqrt0) OP(rsqrt1) OP(rsqrt2)
     OP(invert) OP(approxInvert)
 #undef OP

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

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

     static SkNx Min(const SkNx& a, const SkNx& b) {
         return {Half::Min(a.fLo, b.fLo), Half::Min(a.fHi, b.fHi)};
     }
     static SkNx Max(const SkNx& a, const SkNx& b) {
         return {Half::Max(a.fLo, b.fLo), Half::Max(a.fHi, b.fHi)};
     }

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

     template <int k> T kth() const { return (*this)[k]; }

     bool allTrue() const { return fLo.allTrue() && fHi.allTrue(); }
     bool anyTrue() const { return fLo.anyTrue() || fHi.anyTrue(); }
     SkNx thenElse(const SkNx& t, const SkNx& e) const {
         return SkNx(fLo.thenElse(t.fLo, e.fLo), fHi.thenElse(t.fHi, e.fHi));
     }

 protected:
     static_assert(0 == (N & (N-1)), "N must be a power of 2.");

     Half fLo, fHi;
 };

 // Bottom out the default implementations with scalars when nothing's been specialized.
 template <typename T>
 class SkNx<1, T> {
 public:
     SkNx() {}
     SkNx(T val) : fVal(val) {}

     static SkNx Load(const void* ptr) {
         auto vals = (const T*)ptr;
         return SkNx(vals[0]);
     }

     void store(void* ptr) const {
         auto vals = (T*) ptr;
         vals[0] = fVal;
     }

 #define OP(op) SkNx operator op(const SkNx& o) const { return fVal op o.fVal; }
     OP(+) OP(-) OP(*) OP(/)
     OP(&) OP(|) OP(^)
     OP(==) OP(!=) OP(<) OP(>) OP(<=) OP(>=)
 #undef OP

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

     SkNx saturatedAdd(const SkNx& o) const {
         SkASSERT((T)(~0) > 0); // TODO: support signed T?
         T sum = fVal + o.fVal;
         return sum < fVal ? (T)(~0) : sum;
     }

     static SkNx Min(const SkNx& a, const SkNx& b) { return SkTMin(a.fVal, b.fVal); }
     static SkNx Max(const SkNx& a, const SkNx& b) { return SkTMax(a.fVal, b.fVal); }

     SkNx abs() const { return SkTAbs(fVal); }
     SkNx floor() const { return Floor(fVal); }

     SkNx  sqrt () const { return Sqrt(fVal); }
     SkNx rsqrt0() const { return this->sqrt().invert(); }
     SkNx rsqrt1() const { return this->rsqrt0(); }
     SkNx rsqrt2() const { return this->rsqrt1(); }

     SkNx       invert() const { return 1 / fVal; }
     SkNx approxInvert() const { return this->invert(); }

     T operator[](int k) const {
         SkASSERT(0 == k);
         return fVal;
     }

     template <int k> T kth() const { return (*this)[k]; }

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

 protected:
     static double Floor(double val) { return ::floor (val); }
     static float  Floor(float  val) { return ::floorf(val); }
     static double Sqrt(double val) { return ::sqrt (val); }
     static float  Sqrt(float  val) { return ::sqrtf(val); }

     T fVal;
 };

 // This generic shuffle can be called to create any valid SkNx<N,T>.
 //     Sk4f f(a,b,c,d);
 //     Sk2f t = SkNx_shuffle<2,1>(f);  // ~~~> Sk2f(c,b)
 //     f = SkNx_shuffle<0,1,1,0>(t);   // ~~~> Sk4f(c,b,b,c)
 template <int... Ix, int N, typename T>
 static inline SkNx<sizeof...(Ix), T> SkNx_shuffle(const SkNx<N,T>& src) { return { src[Ix]... }; }

 // This is a generic cast between two SkNx with the same number of elements N.  E.g.
 //   Sk4b bs = ...;                     // Load 4 bytes.
 //   Sk4f fs = SkNx_cast<float>(bs);    // Cast each byte to a float.
 //   Sk4h hs = SkNx_cast<uint16_t>(fs); // Cast each float to uint16_t.
 template <typename D, typename S>
 static inline SkNx<2,D> SkNx_cast(const SkNx<2,S>& src) {
     return { (D)src[0], (D)src[1] };
 }

 template <typename D, typename S>
 static inline SkNx<4,D> SkNx_cast(const SkNx<4,S>& src) {
     return { (D)src[0], (D)src[1], (D)src[2], (D)src[3] };
 }

 template <typename D, typename S>
 static inline SkNx<8,D> SkNx_cast(const SkNx<8,S>& src) {
     return { (D)src[0], (D)src[1], (D)src[2], (D)src[3],
              (D)src[4], (D)src[5], (D)src[6], (D)src[7] };
 }

 template <typename D, typename S>
 static inline SkNx<16,D> SkNx_cast(const SkNx<16,S>& src) {
     return { (D)src[ 0], (D)src[ 1], (D)src[ 2], (D)src[ 3],
              (D)src[ 4], (D)src[ 5], (D)src[ 6], (D)src[ 7],
              (D)src[ 8], (D)src[ 9], (D)src[10], (D)src[11],
              (D)src[12], (D)src[13], (D)src[14], (D)src[15] };
 }

 typedef SkNx<2,     float> Sk2f;
 typedef SkNx<4,     float> Sk4f;
 typedef SkNx<2,  SkScalar> Sk2s;
 typedef SkNx<4,  SkScalar> Sk4s;

 typedef SkNx<4,   uint8_t> Sk4b;
 typedef SkNx<16,  uint8_t> Sk16b;
 typedef SkNx<4,  uint16_t> Sk4h;
 typedef SkNx<16, uint16_t> Sk16h;

 // Include platform specific specializations if available.
 #if !defined(SKNX_NO_SIMD) && SK_CPU_SSE_LEVEL >= SK_CPU_SSE_LEVEL_SSE2
     #include "../opts/SkNx_sse.h"
 #elif !defined(SKNX_NO_SIMD) && defined(SK_ARM_HAS_NEON)
     #include "../opts/SkNx_neon.h"
 #else
     static inline
     void Sk4f_ToBytes(uint8_t p[16], const Sk4f& a, const Sk4f& b, const Sk4f& c, const Sk4f& d) {
         SkNx_cast<uint8_t>(a).store(p+ 0);
         SkNx_cast<uint8_t>(b).store(p+ 4);
         SkNx_cast<uint8_t>(c).store(p+ 8);
         SkNx_cast<uint8_t>(d).store(p+12);
     }
 #endif

 #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

	//#define SKNX_NO_SIMD

	#include "SkScalar.h"
	#include "SkTypes.h"
	#include <math.h>

	// The default implementations just fall back on a pair of size N/2.
	// These support the union of operations we might do to ints and floats, but
	// platform specializations might support fewer (e.g. no float <<, no int /).
	template <int N, typename T>
	class SkNx {
	public:
	SkNx() {}
	SkNx(T val) : fLo(val), fHi(val) {}

	typedef SkNx<N/2, T> Half;
	SkNx(const Half& lo, const Half& hi) : fLo(lo), fHi(hi) {}

	SkNx(T a, T b) : fLo(a), fHi(b) {}
	SkNx(T a, T b, T c, T d) : fLo(a,b), fHi(c,d) {}
	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) {}
	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 SkNx Load(const void* ptr) {
	auto vals = (const T*)ptr;
	return SkNx(Half::Load(vals), Half::Load(vals+N/2));
	}

	void store(void* ptr) const {
	auto vals = (T*)ptr;
	fLo.store(vals);
	fHi.store(vals+N/2);
	}

	#define OP(op) SkNx operator op(const SkNx& o) const { return {fLo op o.fLo, fHi op o.fHi}; }
	OP(+) OP(-) OP(*) OP(/)
	OP(&) OP(\|) OP(^)
	OP(==) OP(!=) OP(<) OP(>) OP(<=) OP(>=)
	#undef OP

	#define OP(op) SkNx op() const { return {fLo.op(), fHi.op()}; }
	OP(abs) OP(floor)
	OP(sqrt) OP(rsqrt0) OP(rsqrt1) OP(rsqrt2)
	OP(invert) OP(approxInvert)
	#undef OP

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

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

	static SkNx Min(const SkNx& a, const SkNx& b) {
	return {Half::Min(a.fLo, b.fLo), Half::Min(a.fHi, b.fHi)};
	}
	static SkNx Max(const SkNx& a, const SkNx& b) {
	return {Half::Max(a.fLo, b.fLo), Half::Max(a.fHi, b.fHi)};
	}

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

	template <int k> T kth() const { return (*this)[k]; }

	bool allTrue() const { return fLo.allTrue() && fHi.allTrue(); }
	bool anyTrue() const { return fLo.anyTrue() \|\| fHi.anyTrue(); }
	SkNx thenElse(const SkNx& t, const SkNx& e) const {
	return SkNx(fLo.thenElse(t.fLo, e.fLo), fHi.thenElse(t.fHi, e.fHi));
	}

	protected:
	static_assert(0 == (N & (N-1)), "N must be a power of 2.");

	Half fLo, fHi;
	};

	// Bottom out the default implementations with scalars when nothing's been specialized.
	template <typename T>
	class SkNx<1, T> {
	public:
	SkNx() {}
	SkNx(T val) : fVal(val) {}

	static SkNx Load(const void* ptr) {
	auto vals = (const T*)ptr;
	return SkNx(vals[0]);
	}

	void store(void* ptr) const {
	auto vals = (T*) ptr;
	vals[0] = fVal;
	}

	#define OP(op) SkNx operator op(const SkNx& o) const { return fVal op o.fVal; }
	OP(+) OP(-) OP(*) OP(/)
	OP(&) OP(\|) OP(^)
	OP(==) OP(!=) OP(<) OP(>) OP(<=) OP(>=)
	#undef OP

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

	SkNx saturatedAdd(const SkNx& o) const {
	SkASSERT((T)(~0) > 0); // TODO: support signed T?
	T sum = fVal + o.fVal;
	return sum < fVal ? (T)(~0) : sum;
	}

	static SkNx Min(const SkNx& a, const SkNx& b) { return SkTMin(a.fVal, b.fVal); }
	static SkNx Max(const SkNx& a, const SkNx& b) { return SkTMax(a.fVal, b.fVal); }

	SkNx abs() const { return SkTAbs(fVal); }
	SkNx floor() const { return Floor(fVal); }

	SkNx sqrt () const { return Sqrt(fVal); }
	SkNx rsqrt0() const { return this->sqrt().invert(); }
	SkNx rsqrt1() const { return this->rsqrt0(); }
	SkNx rsqrt2() const { return this->rsqrt1(); }

	SkNx invert() const { return 1 / fVal; }
	SkNx approxInvert() const { return this->invert(); }

	T operator[](int k) const {
	SkASSERT(0 == k);
	return fVal;
	}

	template <int k> T kth() const { return (*this)[k]; }

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

	protected:
	static double Floor(double val) { return ::floor (val); }
	static float Floor(float val) { return ::floorf(val); }
	static double Sqrt(double val) { return ::sqrt (val); }
	static float Sqrt(float val) { return ::sqrtf(val); }

	T fVal;
	};

	// This generic shuffle can be called to create any valid SkNx<N,T>.
	// Sk4f f(a,b,c,d);
	// Sk2f t = SkNx_shuffle<2,1>(f); // ~~~> Sk2f(c,b)
	// f = SkNx_shuffle<0,1,1,0>(t); // ~~~> Sk4f(c,b,b,c)
	template <int... Ix, int N, typename T>
	static inline SkNx<sizeof...(Ix), T> SkNx_shuffle(const SkNx<N,T>& src) { return { src[Ix]... }; }

	// This is a generic cast between two SkNx with the same number of elements N. E.g.
	// Sk4b bs = ...; // Load 4 bytes.
	// Sk4f fs = SkNx_cast<float>(bs); // Cast each byte to a float.
	// Sk4h hs = SkNx_cast<uint16_t>(fs); // Cast each float to uint16_t.
	template <typename D, typename S>
	static inline SkNx<2,D> SkNx_cast(const SkNx<2,S>& src) {
	return { (D)src[0], (D)src[1] };
	}

	template <typename D, typename S>
	static inline SkNx<4,D> SkNx_cast(const SkNx<4,S>& src) {
	return { (D)src[0], (D)src[1], (D)src[2], (D)src[3] };
	}

	template <typename D, typename S>
	static inline SkNx<8,D> SkNx_cast(const SkNx<8,S>& src) {
	return { (D)src[0], (D)src[1], (D)src[2], (D)src[3],
	(D)src[4], (D)src[5], (D)src[6], (D)src[7] };
	}

	template <typename D, typename S>
	static inline SkNx<16,D> SkNx_cast(const SkNx<16,S>& src) {
	return { (D)src[ 0], (D)src[ 1], (D)src[ 2], (D)src[ 3],
	(D)src[ 4], (D)src[ 5], (D)src[ 6], (D)src[ 7],
	(D)src[ 8], (D)src[ 9], (D)src[10], (D)src[11],
	(D)src[12], (D)src[13], (D)src[14], (D)src[15] };
	}

	typedef SkNx<2, float> Sk2f;
	typedef SkNx<4, float> Sk4f;
	typedef SkNx<2, SkScalar> Sk2s;
	typedef SkNx<4, SkScalar> Sk4s;

	typedef SkNx<4, uint8_t> Sk4b;
	typedef SkNx<16, uint8_t> Sk16b;
	typedef SkNx<4, uint16_t> Sk4h;
	typedef SkNx<16, uint16_t> Sk16h;

	// Include platform specific specializations if available.
	#if !defined(SKNX_NO_SIMD) && SK_CPU_SSE_LEVEL >= SK_CPU_SSE_LEVEL_SSE2
	#include "../opts/SkNx_sse.h"
	#elif !defined(SKNX_NO_SIMD) && defined(SK_ARM_HAS_NEON)
	#include "../opts/SkNx_neon.h"
	#else
	static inline
	void Sk4f_ToBytes(uint8_t p[16], const Sk4f& a, const Sk4f& b, const Sk4f& c, const Sk4f& d) {
	SkNx_cast<uint8_t>(a).store(p+ 0);
	SkNx_cast<uint8_t>(b).store(p+ 4);
	SkNx_cast<uint8_t>(c).store(p+ 8);
	SkNx_cast<uint8_t>(d).store(p+12);
	}
	#endif

	#endif//SkNx_DEFINED