Eigen/src/Core/arch/NEON/PacketMath.h - fp2-dev/platform/external/eigen - Gitiles

 // This file is part of Eigen, a lightweight C++ template library
 // for linear algebra.
 //
 // Copyright (C) 2008-2009 Gael Guennebaud <gael.guennebaud@inria.fr>
 // Copyright (C) 2010 Konstantinos Margaritis <markos@codex.gr>
 // Heavily based on Gael's SSE version.
 //
 // This Source Code Form is subject to the terms of the Mozilla
 // Public License v. 2.0. If a copy of the MPL was not distributed
 // with this file, You can obtain one at http://mozilla.org/MPL/2.0/.

 #ifndef EIGEN_PACKET_MATH_NEON_H
 #define EIGEN_PACKET_MATH_NEON_H

 namespace Eigen {

 namespace internal {

 #ifndef EIGEN_CACHEFRIENDLY_PRODUCT_THRESHOLD
 #define EIGEN_CACHEFRIENDLY_PRODUCT_THRESHOLD 8
 #endif

 // FIXME NEON has 16 quad registers, but since the current register allocator
 // is so bad, it is much better to reduce it to 8
 #ifndef EIGEN_ARCH_DEFAULT_NUMBER_OF_REGISTERS
 #define EIGEN_ARCH_DEFAULT_NUMBER_OF_REGISTERS 8
 #endif

 typedef float32x4_t Packet4f;
 typedef int32x4_t   Packet4i;
 typedef uint32x4_t  Packet4ui;

 #define _EIGEN_DECLARE_CONST_Packet4f(NAME,X) \
   const Packet4f p4f_##NAME = pset1<Packet4f>(X)

 #define _EIGEN_DECLARE_CONST_Packet4f_FROM_INT(NAME,X) \
   const Packet4f p4f_##NAME = vreinterpretq_f32_u32(pset1<int>(X))

 #define _EIGEN_DECLARE_CONST_Packet4i(NAME,X) \
   const Packet4i p4i_##NAME = pset1<Packet4i>(X)

 #if defined(__llvm__) && !defined(__clang__)
   //Special treatment for Apple's llvm-gcc, its NEON packet types are unions
   #define EIGEN_INIT_NEON_PACKET2(X, Y)       {{X, Y}}
   #define EIGEN_INIT_NEON_PACKET4(X, Y, Z, W) {{X, Y, Z, W}}
 #else
   //Default initializer for packets
   #define EIGEN_INIT_NEON_PACKET2(X, Y)       {X, Y}
   #define EIGEN_INIT_NEON_PACKET4(X, Y, Z, W) {X, Y, Z, W}
 #endif

 #ifndef __pld
 #define __pld(x) asm volatile ( "   pld [%[addr]]\n" :: [addr] "r" (x) : "cc" );
 #endif

 template<> struct packet_traits<float>  : default_packet_traits
 {
   typedef Packet4f type;
   enum {
     Vectorizable = 1,
     AlignedOnScalar = 1,
     size = 4,

     HasDiv  = 1,
     // FIXME check the Has*
     HasSin  = 0,
     HasCos  = 0,
     HasLog  = 0,
     HasExp  = 0,
     HasSqrt = 0
   };
 };
 template<> struct packet_traits<int>    : default_packet_traits
 {
   typedef Packet4i type;
   enum {
     Vectorizable = 1,
     AlignedOnScalar = 1,
     size=4
     // FIXME check the Has*
   };
 };

 #if EIGEN_GNUC_AT_MOST(4,4) && !defined(__llvm__)
 // workaround gcc 4.2, 4.3 and 4.4 compilatin issue
 EIGEN_STRONG_INLINE float32x4_t vld1q_f32(const float* x) { return ::vld1q_f32((const float32_t*)x); }
 EIGEN_STRONG_INLINE float32x2_t vld1_f32 (const float* x) { return ::vld1_f32 ((const float32_t*)x); }
 EIGEN_STRONG_INLINE void        vst1q_f32(float* to, float32x4_t from) { ::vst1q_f32((float32_t*)to,from); }
 EIGEN_STRONG_INLINE void        vst1_f32 (float* to, float32x2_t from) { ::vst1_f32 ((float32_t*)to,from); }
 #endif

 template<> struct unpacket_traits<Packet4f> { typedef float  type; enum {size=4}; };
 template<> struct unpacket_traits<Packet4i> { typedef int    type; enum {size=4}; };

 template<> EIGEN_STRONG_INLINE Packet4f pset1<Packet4f>(const float&  from) { return vdupq_n_f32(from); }
 template<> EIGEN_STRONG_INLINE Packet4i pset1<Packet4i>(const int&    from)   { return vdupq_n_s32(from); }

 template<> EIGEN_STRONG_INLINE Packet4f plset<float>(const float& a)
 {
   Packet4f countdown = EIGEN_INIT_NEON_PACKET4(0, 1, 2, 3);
   return vaddq_f32(pset1<Packet4f>(a), countdown);
 }
 template<> EIGEN_STRONG_INLINE Packet4i plset<int>(const int& a)
 {
   Packet4i countdown = EIGEN_INIT_NEON_PACKET4(0, 1, 2, 3);
   return vaddq_s32(pset1<Packet4i>(a), countdown);
 }

 template<> EIGEN_STRONG_INLINE Packet4f padd<Packet4f>(const Packet4f& a, const Packet4f& b) { return vaddq_f32(a,b); }
 template<> EIGEN_STRONG_INLINE Packet4i padd<Packet4i>(const Packet4i& a, const Packet4i& b) { return vaddq_s32(a,b); }

 template<> EIGEN_STRONG_INLINE Packet4f psub<Packet4f>(const Packet4f& a, const Packet4f& b) { return vsubq_f32(a,b); }
 template<> EIGEN_STRONG_INLINE Packet4i psub<Packet4i>(const Packet4i& a, const Packet4i& b) { return vsubq_s32(a,b); }

 template<> EIGEN_STRONG_INLINE Packet4f pnegate(const Packet4f& a) { return vnegq_f32(a); }
 template<> EIGEN_STRONG_INLINE Packet4i pnegate(const Packet4i& a) { return vnegq_s32(a); }

 template<> EIGEN_STRONG_INLINE Packet4f pconj(const Packet4f& a) { return a; }
 template<> EIGEN_STRONG_INLINE Packet4i pconj(const Packet4i& a) { return a; }

 template<> EIGEN_STRONG_INLINE Packet4f pmul<Packet4f>(const Packet4f& a, const Packet4f& b) { return vmulq_f32(a,b); }
 template<> EIGEN_STRONG_INLINE Packet4i pmul<Packet4i>(const Packet4i& a, const Packet4i& b) { return vmulq_s32(a,b); }

 template<> EIGEN_STRONG_INLINE Packet4f pdiv<Packet4f>(const Packet4f& a, const Packet4f& b)
 {
   Packet4f inv, restep, div;

   // NEON does not offer a divide instruction, we have to do a reciprocal approximation
   // However NEON in contrast to other SIMD engines (AltiVec/SSE), offers
   // a reciprocal estimate AND a reciprocal step -which saves a few instructions
   // vrecpeq_f32() returns an estimate to 1/b, which we will finetune with
   // Newton-Raphson and vrecpsq_f32()
   inv = vrecpeq_f32(b);

   // This returns a differential, by which we will have to multiply inv to get a better
   // approximation of 1/b.
   restep = vrecpsq_f32(b, inv);
   inv = vmulq_f32(restep, inv);

   // Finally, multiply a by 1/b and get the wanted result of the division.
   div = vmulq_f32(a, inv);

   return div;
 }
 template<> EIGEN_STRONG_INLINE Packet4i pdiv<Packet4i>(const Packet4i& /*a*/, const Packet4i& /*b*/)
 { eigen_assert(false && "packet integer division are not supported by NEON");
   return pset1<Packet4i>(0);
 }

 // for some weird raisons, it has to be overloaded for packet of integers
 template<> EIGEN_STRONG_INLINE Packet4f pmadd(const Packet4f& a, const Packet4f& b, const Packet4f& c) { return vmlaq_f32(c,a,b); }
 template<> EIGEN_STRONG_INLINE Packet4i pmadd(const Packet4i& a, const Packet4i& b, const Packet4i& c) { return vmlaq_s32(c,a,b); }

 template<> EIGEN_STRONG_INLINE Packet4f pmin<Packet4f>(const Packet4f& a, const Packet4f& b) { return vminq_f32(a,b); }
 template<> EIGEN_STRONG_INLINE Packet4i pmin<Packet4i>(const Packet4i& a, const Packet4i& b) { return vminq_s32(a,b); }

 template<> EIGEN_STRONG_INLINE Packet4f pmax<Packet4f>(const Packet4f& a, const Packet4f& b) { return vmaxq_f32(a,b); }
 template<> EIGEN_STRONG_INLINE Packet4i pmax<Packet4i>(const Packet4i& a, const Packet4i& b) { return vmaxq_s32(a,b); }

 // Logical Operations are not supported for float, so we have to reinterpret casts using NEON intrinsics
 template<> EIGEN_STRONG_INLINE Packet4f pand<Packet4f>(const Packet4f& a, const Packet4f& b)
 {
   return vreinterpretq_f32_u32(vandq_u32(vreinterpretq_u32_f32(a),vreinterpretq_u32_f32(b)));
 }
 template<> EIGEN_STRONG_INLINE Packet4i pand<Packet4i>(const Packet4i& a, const Packet4i& b) { return vandq_s32(a,b); }

 template<> EIGEN_STRONG_INLINE Packet4f por<Packet4f>(const Packet4f& a, const Packet4f& b)
 {
   return vreinterpretq_f32_u32(vorrq_u32(vreinterpretq_u32_f32(a),vreinterpretq_u32_f32(b)));
 }
 template<> EIGEN_STRONG_INLINE Packet4i por<Packet4i>(const Packet4i& a, const Packet4i& b) { return vorrq_s32(a,b); }

 template<> EIGEN_STRONG_INLINE Packet4f pxor<Packet4f>(const Packet4f& a, const Packet4f& b)
 {
   return vreinterpretq_f32_u32(veorq_u32(vreinterpretq_u32_f32(a),vreinterpretq_u32_f32(b)));
 }
 template<> EIGEN_STRONG_INLINE Packet4i pxor<Packet4i>(const Packet4i& a, const Packet4i& b) { return veorq_s32(a,b); }

 template<> EIGEN_STRONG_INLINE Packet4f pandnot<Packet4f>(const Packet4f& a, const Packet4f& b)
 {
   return vreinterpretq_f32_u32(vbicq_u32(vreinterpretq_u32_f32(a),vreinterpretq_u32_f32(b)));
 }
 template<> EIGEN_STRONG_INLINE Packet4i pandnot<Packet4i>(const Packet4i& a, const Packet4i& b) { return vbicq_s32(a,b); }

 template<> EIGEN_STRONG_INLINE Packet4f pload<Packet4f>(const float* from) { EIGEN_DEBUG_ALIGNED_LOAD return vld1q_f32(from); }
 template<> EIGEN_STRONG_INLINE Packet4i pload<Packet4i>(const int*   from) { EIGEN_DEBUG_ALIGNED_LOAD return vld1q_s32(from); }

 template<> EIGEN_STRONG_INLINE Packet4f ploadu<Packet4f>(const float* from) { EIGEN_DEBUG_UNALIGNED_LOAD return vld1q_f32(from); }
 template<> EIGEN_STRONG_INLINE Packet4i ploadu<Packet4i>(const int* from)   { EIGEN_DEBUG_UNALIGNED_LOAD return vld1q_s32(from); }

 template<> EIGEN_STRONG_INLINE Packet4f ploaddup<Packet4f>(const float*   from)
 {
   float32x2_t lo, hi;
   lo = vld1_dup_f32(from);
   hi = vld1_dup_f32(from+1);
   return vcombine_f32(lo, hi);
 }
 template<> EIGEN_STRONG_INLINE Packet4i ploaddup<Packet4i>(const int*     from)
 {
   int32x2_t lo, hi;
   lo = vld1_dup_s32(from);
   hi = vld1_dup_s32(from+1);
   return vcombine_s32(lo, hi);
 }

 template<> EIGEN_STRONG_INLINE void pstore<float>(float*   to, const Packet4f& from) { EIGEN_DEBUG_ALIGNED_STORE vst1q_f32(to, from); }
 template<> EIGEN_STRONG_INLINE void pstore<int>(int*       to, const Packet4i& from) { EIGEN_DEBUG_ALIGNED_STORE vst1q_s32(to, from); }

 template<> EIGEN_STRONG_INLINE void pstoreu<float>(float*  to, const Packet4f& from) { EIGEN_DEBUG_UNALIGNED_STORE vst1q_f32(to, from); }
 template<> EIGEN_STRONG_INLINE void pstoreu<int>(int*      to, const Packet4i& from) { EIGEN_DEBUG_UNALIGNED_STORE vst1q_s32(to, from); }

 template<> EIGEN_STRONG_INLINE void prefetch<float>(const float* addr) { __pld(addr); }
 template<> EIGEN_STRONG_INLINE void prefetch<int>(const int*     addr) { __pld(addr); }

 // FIXME only store the 2 first elements ?
 template<> EIGEN_STRONG_INLINE float  pfirst<Packet4f>(const Packet4f& a) { float EIGEN_ALIGN16 x[4]; vst1q_f32(x, a); return x[0]; }
 template<> EIGEN_STRONG_INLINE int    pfirst<Packet4i>(const Packet4i& a) { int   EIGEN_ALIGN16 x[4]; vst1q_s32(x, a); return x[0]; }

 template<> EIGEN_STRONG_INLINE Packet4f preverse(const Packet4f& a) {
   float32x2_t a_lo, a_hi;
   Packet4f a_r64;

   a_r64 = vrev64q_f32(a);
   a_lo = vget_low_f32(a_r64);
   a_hi = vget_high_f32(a_r64);
   return vcombine_f32(a_hi, a_lo);
 }
 template<> EIGEN_STRONG_INLINE Packet4i preverse(const Packet4i& a) {
   int32x2_t a_lo, a_hi;
   Packet4i a_r64;

   a_r64 = vrev64q_s32(a);
   a_lo = vget_low_s32(a_r64);
   a_hi = vget_high_s32(a_r64);
   return vcombine_s32(a_hi, a_lo);
 }
 template<> EIGEN_STRONG_INLINE Packet4f pabs(const Packet4f& a) { return vabsq_f32(a); }
 template<> EIGEN_STRONG_INLINE Packet4i pabs(const Packet4i& a) { return vabsq_s32(a); }

 template<> EIGEN_STRONG_INLINE float predux<Packet4f>(const Packet4f& a)
 {
   float32x2_t a_lo, a_hi, sum;

   a_lo = vget_low_f32(a);
   a_hi = vget_high_f32(a);
   sum = vpadd_f32(a_lo, a_hi);
   sum = vpadd_f32(sum, sum);
   return vget_lane_f32(sum, 0);
 }

 template<> EIGEN_STRONG_INLINE Packet4f preduxp<Packet4f>(const Packet4f* vecs)
 {
   float32x4x2_t vtrn1, vtrn2, res1, res2;
   Packet4f sum1, sum2, sum;

   // NEON zip performs interleaving of the supplied vectors.
   // We perform two interleaves in a row to acquire the transposed vector
   vtrn1 = vzipq_f32(vecs[0], vecs[2]);
   vtrn2 = vzipq_f32(vecs[1], vecs[3]);
   res1 = vzipq_f32(vtrn1.val[0], vtrn2.val[0]);
   res2 = vzipq_f32(vtrn1.val[1], vtrn2.val[1]);

   // Do the addition of the resulting vectors
   sum1 = vaddq_f32(res1.val[0], res1.val[1]);
   sum2 = vaddq_f32(res2.val[0], res2.val[1]);
   sum = vaddq_f32(sum1, sum2);

   return sum;
 }

 template<> EIGEN_STRONG_INLINE int predux<Packet4i>(const Packet4i& a)
 {
   int32x2_t a_lo, a_hi, sum;

   a_lo = vget_low_s32(a);
   a_hi = vget_high_s32(a);
   sum = vpadd_s32(a_lo, a_hi);
   sum = vpadd_s32(sum, sum);
   return vget_lane_s32(sum, 0);
 }

 template<> EIGEN_STRONG_INLINE Packet4i preduxp<Packet4i>(const Packet4i* vecs)
 {
   int32x4x2_t vtrn1, vtrn2, res1, res2;
   Packet4i sum1, sum2, sum;

   // NEON zip performs interleaving of the supplied vectors.
   // We perform two interleaves in a row to acquire the transposed vector
   vtrn1 = vzipq_s32(vecs[0], vecs[2]);
   vtrn2 = vzipq_s32(vecs[1], vecs[3]);
   res1 = vzipq_s32(vtrn1.val[0], vtrn2.val[0]);
   res2 = vzipq_s32(vtrn1.val[1], vtrn2.val[1]);

   // Do the addition of the resulting vectors
   sum1 = vaddq_s32(res1.val[0], res1.val[1]);
   sum2 = vaddq_s32(res2.val[0], res2.val[1]);
   sum = vaddq_s32(sum1, sum2);

   return sum;
 }

 // Other reduction functions:
 // mul
 template<> EIGEN_STRONG_INLINE float predux_mul<Packet4f>(const Packet4f& a)
 {
   float32x2_t a_lo, a_hi, prod;

   // Get a_lo = |a1|a2| and a_hi = |a3|a4|
   a_lo = vget_low_f32(a);
   a_hi = vget_high_f32(a);
   // Get the product of a_lo * a_hi -> |a1*a3|a2*a4|
   prod = vmul_f32(a_lo, a_hi);
   // Multiply prod with its swapped value |a2*a4|a1*a3|
   prod = vmul_f32(prod, vrev64_f32(prod));

   return vget_lane_f32(prod, 0);
 }
 template<> EIGEN_STRONG_INLINE int predux_mul<Packet4i>(const Packet4i& a)
 {
   int32x2_t a_lo, a_hi, prod;

   // Get a_lo = |a1|a2| and a_hi = |a3|a4|
   a_lo = vget_low_s32(a);
   a_hi = vget_high_s32(a);
   // Get the product of a_lo * a_hi -> |a1*a3|a2*a4|
   prod = vmul_s32(a_lo, a_hi);
   // Multiply prod with its swapped value |a2*a4|a1*a3|
   prod = vmul_s32(prod, vrev64_s32(prod));

   return vget_lane_s32(prod, 0);
 }

 // min
 template<> EIGEN_STRONG_INLINE float predux_min<Packet4f>(const Packet4f& a)
 {
   float32x2_t a_lo, a_hi, min;

   a_lo = vget_low_f32(a);
   a_hi = vget_high_f32(a);
   min = vpmin_f32(a_lo, a_hi);
   min = vpmin_f32(min, min);

   return vget_lane_f32(min, 0);
 }

 template<> EIGEN_STRONG_INLINE int predux_min<Packet4i>(const Packet4i& a)
 {
   int32x2_t a_lo, a_hi, min;

   a_lo = vget_low_s32(a);
   a_hi = vget_high_s32(a);
   min = vpmin_s32(a_lo, a_hi);
   min = vpmin_s32(min, min);

   return vget_lane_s32(min, 0);
 }

 // max
 template<> EIGEN_STRONG_INLINE float predux_max<Packet4f>(const Packet4f& a)
 {
   float32x2_t a_lo, a_hi, max;

   a_lo = vget_low_f32(a);
   a_hi = vget_high_f32(a);
   max = vpmax_f32(a_lo, a_hi);
   max = vpmax_f32(max, max);

   return vget_lane_f32(max, 0);
 }

 template<> EIGEN_STRONG_INLINE int predux_max<Packet4i>(const Packet4i& a)
 {
   int32x2_t a_lo, a_hi, max;

   a_lo = vget_low_s32(a);
   a_hi = vget_high_s32(a);
   max = vpmax_s32(a_lo, a_hi);

   return vget_lane_s32(max, 0);
 }

 // this PALIGN_NEON business is to work around a bug in LLVM Clang 3.0 causing incorrect compilation errors,
 // see bug 347 and this LLVM bug: http://llvm.org/bugs/show_bug.cgi?id=11074
 #define PALIGN_NEON(Offset,Type,Command) \
 template<>\
 struct palign_impl<Offset,Type>\
 {\
     EIGEN_STRONG_INLINE static void run(Type& first, const Type& second)\
     {\
         if (Offset!=0)\
             first = Command(first, second, Offset);\
     }\
 };\

 PALIGN_NEON(0,Packet4f,vextq_f32)
 PALIGN_NEON(1,Packet4f,vextq_f32)
 PALIGN_NEON(2,Packet4f,vextq_f32)
 PALIGN_NEON(3,Packet4f,vextq_f32)
 PALIGN_NEON(0,Packet4i,vextq_s32)
 PALIGN_NEON(1,Packet4i,vextq_s32)
 PALIGN_NEON(2,Packet4i,vextq_s32)
 PALIGN_NEON(3,Packet4i,vextq_s32)

 #undef PALIGN_NEON

 } // end namespace internal

 } // end namespace Eigen

 #endif // EIGEN_PACKET_MATH_NEON_H
	// This file is part of Eigen, a lightweight C++ template library
	// for linear algebra.
	//
	// Copyright (C) 2008-2009 Gael Guennebaud <gael.guennebaud@inria.fr>
	// Copyright (C) 2010 Konstantinos Margaritis <markos@codex.gr>
	// Heavily based on Gael's SSE version.
	//
	// This Source Code Form is subject to the terms of the Mozilla
	// Public License v. 2.0. If a copy of the MPL was not distributed
	// with this file, You can obtain one at http://mozilla.org/MPL/2.0/.

	#ifndef EIGEN_PACKET_MATH_NEON_H
	#define EIGEN_PACKET_MATH_NEON_H

	namespace Eigen {

	namespace internal {

	#ifndef EIGEN_CACHEFRIENDLY_PRODUCT_THRESHOLD
	#define EIGEN_CACHEFRIENDLY_PRODUCT_THRESHOLD 8
	#endif

	// FIXME NEON has 16 quad registers, but since the current register allocator
	// is so bad, it is much better to reduce it to 8
	#ifndef EIGEN_ARCH_DEFAULT_NUMBER_OF_REGISTERS
	#define EIGEN_ARCH_DEFAULT_NUMBER_OF_REGISTERS 8
	#endif

	typedef float32x4_t Packet4f;
	typedef int32x4_t Packet4i;
	typedef uint32x4_t Packet4ui;

	#define _EIGEN_DECLARE_CONST_Packet4f(NAME,X) \
	const Packet4f p4f_##NAME = pset1<Packet4f>(X)

	#define _EIGEN_DECLARE_CONST_Packet4f_FROM_INT(NAME,X) \
	const Packet4f p4f_##NAME = vreinterpretq_f32_u32(pset1<int>(X))

	#define _EIGEN_DECLARE_CONST_Packet4i(NAME,X) \
	const Packet4i p4i_##NAME = pset1<Packet4i>(X)

	#if defined(__llvm__) && !defined(__clang__)
	//Special treatment for Apple's llvm-gcc, its NEON packet types are unions
	#define EIGEN_INIT_NEON_PACKET2(X, Y) {{X, Y}}
	#define EIGEN_INIT_NEON_PACKET4(X, Y, Z, W) {{X, Y, Z, W}}
	#else
	//Default initializer for packets
	#define EIGEN_INIT_NEON_PACKET2(X, Y) {X, Y}
	#define EIGEN_INIT_NEON_PACKET4(X, Y, Z, W) {X, Y, Z, W}
	#endif

	#ifndef __pld
	#define __pld(x) asm volatile ( " pld [%[addr]]\n" :: [addr] "r" (x) : "cc" );
	#endif

	template<> struct packet_traits<float> : default_packet_traits
	{
	typedef Packet4f type;
	enum {
	Vectorizable = 1,
	AlignedOnScalar = 1,
	size = 4,

	HasDiv = 1,
	// FIXME check the Has*
	HasSin = 0,
	HasCos = 0,
	HasLog = 0,
	HasExp = 0,
	HasSqrt = 0
	};
	};
	template<> struct packet_traits<int> : default_packet_traits
	{
	typedef Packet4i type;
	enum {
	Vectorizable = 1,
	AlignedOnScalar = 1,
	size=4
	// FIXME check the Has*
	};
	};

	#if EIGEN_GNUC_AT_MOST(4,4) && !defined(__llvm__)
	// workaround gcc 4.2, 4.3 and 4.4 compilatin issue
	EIGEN_STRONG_INLINE float32x4_t vld1q_f32(const float* x) { return ::vld1q_f32((const float32_t*)x); }
	EIGEN_STRONG_INLINE float32x2_t vld1_f32 (const float* x) { return ::vld1_f32 ((const float32_t*)x); }
	EIGEN_STRONG_INLINE void vst1q_f32(float* to, float32x4_t from) { ::vst1q_f32((float32_t*)to,from); }
	EIGEN_STRONG_INLINE void vst1_f32 (float* to, float32x2_t from) { ::vst1_f32 ((float32_t*)to,from); }
	#endif

	template<> struct unpacket_traits<Packet4f> { typedef float type; enum {size=4}; };
	template<> struct unpacket_traits<Packet4i> { typedef int type; enum {size=4}; };

	template<> EIGEN_STRONG_INLINE Packet4f pset1<Packet4f>(const float& from) { return vdupq_n_f32(from); }
	template<> EIGEN_STRONG_INLINE Packet4i pset1<Packet4i>(const int& from) { return vdupq_n_s32(from); }

	template<> EIGEN_STRONG_INLINE Packet4f plset<float>(const float& a)
	{
	Packet4f countdown = EIGEN_INIT_NEON_PACKET4(0, 1, 2, 3);
	return vaddq_f32(pset1<Packet4f>(a), countdown);
	}
	template<> EIGEN_STRONG_INLINE Packet4i plset<int>(const int& a)
	{
	Packet4i countdown = EIGEN_INIT_NEON_PACKET4(0, 1, 2, 3);
	return vaddq_s32(pset1<Packet4i>(a), countdown);
	}

	template<> EIGEN_STRONG_INLINE Packet4f padd<Packet4f>(const Packet4f& a, const Packet4f& b) { return vaddq_f32(a,b); }
	template<> EIGEN_STRONG_INLINE Packet4i padd<Packet4i>(const Packet4i& a, const Packet4i& b) { return vaddq_s32(a,b); }

	template<> EIGEN_STRONG_INLINE Packet4f psub<Packet4f>(const Packet4f& a, const Packet4f& b) { return vsubq_f32(a,b); }
	template<> EIGEN_STRONG_INLINE Packet4i psub<Packet4i>(const Packet4i& a, const Packet4i& b) { return vsubq_s32(a,b); }

	template<> EIGEN_STRONG_INLINE Packet4f pnegate(const Packet4f& a) { return vnegq_f32(a); }
	template<> EIGEN_STRONG_INLINE Packet4i pnegate(const Packet4i& a) { return vnegq_s32(a); }

	template<> EIGEN_STRONG_INLINE Packet4f pconj(const Packet4f& a) { return a; }
	template<> EIGEN_STRONG_INLINE Packet4i pconj(const Packet4i& a) { return a; }

	template<> EIGEN_STRONG_INLINE Packet4f pmul<Packet4f>(const Packet4f& a, const Packet4f& b) { return vmulq_f32(a,b); }
	template<> EIGEN_STRONG_INLINE Packet4i pmul<Packet4i>(const Packet4i& a, const Packet4i& b) { return vmulq_s32(a,b); }

	template<> EIGEN_STRONG_INLINE Packet4f pdiv<Packet4f>(const Packet4f& a, const Packet4f& b)
	{
	Packet4f inv, restep, div;

	// NEON does not offer a divide instruction, we have to do a reciprocal approximation
	// However NEON in contrast to other SIMD engines (AltiVec/SSE), offers
	// a reciprocal estimate AND a reciprocal step -which saves a few instructions
	// vrecpeq_f32() returns an estimate to 1/b, which we will finetune with
	// Newton-Raphson and vrecpsq_f32()
	inv = vrecpeq_f32(b);

	// This returns a differential, by which we will have to multiply inv to get a better
	// approximation of 1/b.
	restep = vrecpsq_f32(b, inv);
	inv = vmulq_f32(restep, inv);

	// Finally, multiply a by 1/b and get the wanted result of the division.
	div = vmulq_f32(a, inv);

	return div;
	}
	template<> EIGEN_STRONG_INLINE Packet4i pdiv<Packet4i>(const Packet4i& /a/, const Packet4i& /b/)
	{ eigen_assert(false && "packet integer division are not supported by NEON");
	return pset1<Packet4i>(0);
	}

	// for some weird raisons, it has to be overloaded for packet of integers
	template<> EIGEN_STRONG_INLINE Packet4f pmadd(const Packet4f& a, const Packet4f& b, const Packet4f& c) { return vmlaq_f32(c,a,b); }
	template<> EIGEN_STRONG_INLINE Packet4i pmadd(const Packet4i& a, const Packet4i& b, const Packet4i& c) { return vmlaq_s32(c,a,b); }

	template<> EIGEN_STRONG_INLINE Packet4f pmin<Packet4f>(const Packet4f& a, const Packet4f& b) { return vminq_f32(a,b); }
	template<> EIGEN_STRONG_INLINE Packet4i pmin<Packet4i>(const Packet4i& a, const Packet4i& b) { return vminq_s32(a,b); }

	template<> EIGEN_STRONG_INLINE Packet4f pmax<Packet4f>(const Packet4f& a, const Packet4f& b) { return vmaxq_f32(a,b); }
	template<> EIGEN_STRONG_INLINE Packet4i pmax<Packet4i>(const Packet4i& a, const Packet4i& b) { return vmaxq_s32(a,b); }

	// Logical Operations are not supported for float, so we have to reinterpret casts using NEON intrinsics
	template<> EIGEN_STRONG_INLINE Packet4f pand<Packet4f>(const Packet4f& a, const Packet4f& b)
	{
	return vreinterpretq_f32_u32(vandq_u32(vreinterpretq_u32_f32(a),vreinterpretq_u32_f32(b)));
	}
	template<> EIGEN_STRONG_INLINE Packet4i pand<Packet4i>(const Packet4i& a, const Packet4i& b) { return vandq_s32(a,b); }

	template<> EIGEN_STRONG_INLINE Packet4f por<Packet4f>(const Packet4f& a, const Packet4f& b)
	{
	return vreinterpretq_f32_u32(vorrq_u32(vreinterpretq_u32_f32(a),vreinterpretq_u32_f32(b)));
	}
	template<> EIGEN_STRONG_INLINE Packet4i por<Packet4i>(const Packet4i& a, const Packet4i& b) { return vorrq_s32(a,b); }

	template<> EIGEN_STRONG_INLINE Packet4f pxor<Packet4f>(const Packet4f& a, const Packet4f& b)
	{
	return vreinterpretq_f32_u32(veorq_u32(vreinterpretq_u32_f32(a),vreinterpretq_u32_f32(b)));
	}
	template<> EIGEN_STRONG_INLINE Packet4i pxor<Packet4i>(const Packet4i& a, const Packet4i& b) { return veorq_s32(a,b); }

	template<> EIGEN_STRONG_INLINE Packet4f pandnot<Packet4f>(const Packet4f& a, const Packet4f& b)
	{
	return vreinterpretq_f32_u32(vbicq_u32(vreinterpretq_u32_f32(a),vreinterpretq_u32_f32(b)));
	}
	template<> EIGEN_STRONG_INLINE Packet4i pandnot<Packet4i>(const Packet4i& a, const Packet4i& b) { return vbicq_s32(a,b); }

	template<> EIGEN_STRONG_INLINE Packet4f pload<Packet4f>(const float* from) { EIGEN_DEBUG_ALIGNED_LOAD return vld1q_f32(from); }
	template<> EIGEN_STRONG_INLINE Packet4i pload<Packet4i>(const int* from) { EIGEN_DEBUG_ALIGNED_LOAD return vld1q_s32(from); }

	template<> EIGEN_STRONG_INLINE Packet4f ploadu<Packet4f>(const float* from) { EIGEN_DEBUG_UNALIGNED_LOAD return vld1q_f32(from); }
	template<> EIGEN_STRONG_INLINE Packet4i ploadu<Packet4i>(const int* from) { EIGEN_DEBUG_UNALIGNED_LOAD return vld1q_s32(from); }

	template<> EIGEN_STRONG_INLINE Packet4f ploaddup<Packet4f>(const float* from)
	{
	float32x2_t lo, hi;
	lo = vld1_dup_f32(from);
	hi = vld1_dup_f32(from+1);
	return vcombine_f32(lo, hi);
	}
	template<> EIGEN_STRONG_INLINE Packet4i ploaddup<Packet4i>(const int* from)
	{
	int32x2_t lo, hi;
	lo = vld1_dup_s32(from);
	hi = vld1_dup_s32(from+1);
	return vcombine_s32(lo, hi);
	}

	template<> EIGEN_STRONG_INLINE void pstore<float>(float* to, const Packet4f& from) { EIGEN_DEBUG_ALIGNED_STORE vst1q_f32(to, from); }
	template<> EIGEN_STRONG_INLINE void pstore<int>(int* to, const Packet4i& from) { EIGEN_DEBUG_ALIGNED_STORE vst1q_s32(to, from); }

	template<> EIGEN_STRONG_INLINE void pstoreu<float>(float* to, const Packet4f& from) { EIGEN_DEBUG_UNALIGNED_STORE vst1q_f32(to, from); }
	template<> EIGEN_STRONG_INLINE void pstoreu<int>(int* to, const Packet4i& from) { EIGEN_DEBUG_UNALIGNED_STORE vst1q_s32(to, from); }

	template<> EIGEN_STRONG_INLINE void prefetch<float>(const float* addr) { __pld(addr); }
	template<> EIGEN_STRONG_INLINE void prefetch<int>(const int* addr) { __pld(addr); }

	// FIXME only store the 2 first elements ?
	template<> EIGEN_STRONG_INLINE float pfirst<Packet4f>(const Packet4f& a) { float EIGEN_ALIGN16 x[4]; vst1q_f32(x, a); return x[0]; }
	template<> EIGEN_STRONG_INLINE int pfirst<Packet4i>(const Packet4i& a) { int EIGEN_ALIGN16 x[4]; vst1q_s32(x, a); return x[0]; }

	template<> EIGEN_STRONG_INLINE Packet4f preverse(const Packet4f& a) {
	float32x2_t a_lo, a_hi;
	Packet4f a_r64;

	a_r64 = vrev64q_f32(a);
	a_lo = vget_low_f32(a_r64);
	a_hi = vget_high_f32(a_r64);
	return vcombine_f32(a_hi, a_lo);
	}
	template<> EIGEN_STRONG_INLINE Packet4i preverse(const Packet4i& a) {
	int32x2_t a_lo, a_hi;
	Packet4i a_r64;

	a_r64 = vrev64q_s32(a);
	a_lo = vget_low_s32(a_r64);
	a_hi = vget_high_s32(a_r64);
	return vcombine_s32(a_hi, a_lo);
	}
	template<> EIGEN_STRONG_INLINE Packet4f pabs(const Packet4f& a) { return vabsq_f32(a); }
	template<> EIGEN_STRONG_INLINE Packet4i pabs(const Packet4i& a) { return vabsq_s32(a); }

	template<> EIGEN_STRONG_INLINE float predux<Packet4f>(const Packet4f& a)
	{
	float32x2_t a_lo, a_hi, sum;

	a_lo = vget_low_f32(a);
	a_hi = vget_high_f32(a);
	sum = vpadd_f32(a_lo, a_hi);
	sum = vpadd_f32(sum, sum);
	return vget_lane_f32(sum, 0);
	}

	template<> EIGEN_STRONG_INLINE Packet4f preduxp<Packet4f>(const Packet4f* vecs)
	{
	float32x4x2_t vtrn1, vtrn2, res1, res2;
	Packet4f sum1, sum2, sum;

	// NEON zip performs interleaving of the supplied vectors.
	// We perform two interleaves in a row to acquire the transposed vector
	vtrn1 = vzipq_f32(vecs[0], vecs[2]);
	vtrn2 = vzipq_f32(vecs[1], vecs[3]);
	res1 = vzipq_f32(vtrn1.val[0], vtrn2.val[0]);
	res2 = vzipq_f32(vtrn1.val[1], vtrn2.val[1]);

	// Do the addition of the resulting vectors
	sum1 = vaddq_f32(res1.val[0], res1.val[1]);
	sum2 = vaddq_f32(res2.val[0], res2.val[1]);
	sum = vaddq_f32(sum1, sum2);

	return sum;
	}

	template<> EIGEN_STRONG_INLINE int predux<Packet4i>(const Packet4i& a)
	{
	int32x2_t a_lo, a_hi, sum;

	a_lo = vget_low_s32(a);
	a_hi = vget_high_s32(a);
	sum = vpadd_s32(a_lo, a_hi);
	sum = vpadd_s32(sum, sum);
	return vget_lane_s32(sum, 0);
	}

	template<> EIGEN_STRONG_INLINE Packet4i preduxp<Packet4i>(const Packet4i* vecs)
	{
	int32x4x2_t vtrn1, vtrn2, res1, res2;
	Packet4i sum1, sum2, sum;

	// NEON zip performs interleaving of the supplied vectors.
	// We perform two interleaves in a row to acquire the transposed vector
	vtrn1 = vzipq_s32(vecs[0], vecs[2]);
	vtrn2 = vzipq_s32(vecs[1], vecs[3]);
	res1 = vzipq_s32(vtrn1.val[0], vtrn2.val[0]);
	res2 = vzipq_s32(vtrn1.val[1], vtrn2.val[1]);

	// Do the addition of the resulting vectors
	sum1 = vaddq_s32(res1.val[0], res1.val[1]);
	sum2 = vaddq_s32(res2.val[0], res2.val[1]);
	sum = vaddq_s32(sum1, sum2);

	return sum;
	}

	// Other reduction functions:
	// mul
	template<> EIGEN_STRONG_INLINE float predux_mul<Packet4f>(const Packet4f& a)
	{
	float32x2_t a_lo, a_hi, prod;

	// Get a_lo = \|a1\|a2\| and a_hi = \|a3\|a4\|
	a_lo = vget_low_f32(a);
	a_hi = vget_high_f32(a);
	// Get the product of a_lo * a_hi -> \|a1a3\|a2a4\|
	prod = vmul_f32(a_lo, a_hi);
	// Multiply prod with its swapped value \|a2a4\|a1a3\|
	prod = vmul_f32(prod, vrev64_f32(prod));

	return vget_lane_f32(prod, 0);
	}
	template<> EIGEN_STRONG_INLINE int predux_mul<Packet4i>(const Packet4i& a)
	{
	int32x2_t a_lo, a_hi, prod;

	// Get a_lo = \|a1\|a2\| and a_hi = \|a3\|a4\|
	a_lo = vget_low_s32(a);
	a_hi = vget_high_s32(a);
	// Get the product of a_lo * a_hi -> \|a1a3\|a2a4\|
	prod = vmul_s32(a_lo, a_hi);
	// Multiply prod with its swapped value \|a2a4\|a1a3\|
	prod = vmul_s32(prod, vrev64_s32(prod));

	return vget_lane_s32(prod, 0);
	}

	// min
	template<> EIGEN_STRONG_INLINE float predux_min<Packet4f>(const Packet4f& a)
	{
	float32x2_t a_lo, a_hi, min;

	a_lo = vget_low_f32(a);
	a_hi = vget_high_f32(a);
	min = vpmin_f32(a_lo, a_hi);
	min = vpmin_f32(min, min);

	return vget_lane_f32(min, 0);
	}

	template<> EIGEN_STRONG_INLINE int predux_min<Packet4i>(const Packet4i& a)
	{
	int32x2_t a_lo, a_hi, min;

	a_lo = vget_low_s32(a);
	a_hi = vget_high_s32(a);
	min = vpmin_s32(a_lo, a_hi);
	min = vpmin_s32(min, min);

	return vget_lane_s32(min, 0);
	}

	// max
	template<> EIGEN_STRONG_INLINE float predux_max<Packet4f>(const Packet4f& a)
	{
	float32x2_t a_lo, a_hi, max;

	a_lo = vget_low_f32(a);
	a_hi = vget_high_f32(a);
	max = vpmax_f32(a_lo, a_hi);
	max = vpmax_f32(max, max);

	return vget_lane_f32(max, 0);
	}

	template<> EIGEN_STRONG_INLINE int predux_max<Packet4i>(const Packet4i& a)
	{
	int32x2_t a_lo, a_hi, max;

	a_lo = vget_low_s32(a);
	a_hi = vget_high_s32(a);
	max = vpmax_s32(a_lo, a_hi);

	return vget_lane_s32(max, 0);
	}

	// this PALIGN_NEON business is to work around a bug in LLVM Clang 3.0 causing incorrect compilation errors,
	// see bug 347 and this LLVM bug: http://llvm.org/bugs/show_bug.cgi?id=11074
	#define PALIGN_NEON(Offset,Type,Command) \
	template<>\
	struct palign_impl<Offset,Type>\
	{\
	EIGEN_STRONG_INLINE static void run(Type& first, const Type& second)\
	{\
	if (Offset!=0)\
	first = Command(first, second, Offset);\
	}\
	};\

	PALIGN_NEON(0,Packet4f,vextq_f32)
	PALIGN_NEON(1,Packet4f,vextq_f32)
	PALIGN_NEON(2,Packet4f,vextq_f32)
	PALIGN_NEON(3,Packet4f,vextq_f32)
	PALIGN_NEON(0,Packet4i,vextq_s32)
	PALIGN_NEON(1,Packet4i,vextq_s32)
	PALIGN_NEON(2,Packet4i,vextq_s32)
	PALIGN_NEON(3,Packet4i,vextq_s32)

	#undef PALIGN_NEON

	} // end namespace internal

	} // end namespace Eigen

	#endif // EIGEN_PACKET_MATH_NEON_H