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Grid/Grid_vRealD.h
2015-03-04 03:12:19 +00:00

263 lines
7.8 KiB
C++
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#ifndef VREALD_H
#define VREALD_H
#include "Grid.h"
namespace dpo{
class vRealD {
protected:
dvec v; // dvec is double precision vector
public:
vRealD(){};
friend inline void mult(vRealD * __restrict__ y,const vRealD * __restrict__ l,const vRealD *__restrict__ r) {*y = (*l) * (*r);}
friend inline void sub (vRealD * __restrict__ y,const vRealD * __restrict__ l,const vRealD *__restrict__ r) {*y = (*l) - (*r);}
friend inline void add (vRealD * __restrict__ y,const vRealD * __restrict__ l,const vRealD *__restrict__ r) {*y = (*l) + (*r);}
friend inline vRealD adj(const vRealD &in) { return in; }
friend inline vRealD conj(const vRealD &in){ return in; }
friend inline void mac (vRealD &y,const vRealD a,const vRealD x){
#if defined (AVX1) || defined (SSE2)
y = a*x+y;
#endif
#ifdef AVX2 // AVX 2 introduced FMA support. FMA4 eliminates a copy, but AVX only has FMA3
// accelerates multiply accumulate, but not general multiply add
y.v = _mm256_fmadd_pd(a.v,x.v,y.v);
#endif
#ifdef AVX512
// here precision of vector are still single
y.v = _mm512_fmadd_pd(a.v,x.v,y.v);
#endif
#ifdef QPX
y.v = vec_madd(a.v,x.v,y.v);
#endif
}
//////////////////////////////////
// Initialise to 1,0
//////////////////////////////////
friend inline void vone (vRealD &ret){ vsplat(ret,1.0);}
friend inline void vzero(vRealD &ret){ vsplat(ret,0.0);}
////////////////////////////////////
// Arithmetic operator overloads +,-,*
////////////////////////////////////
friend inline vRealD operator + (vRealD a, vRealD b)
{
vRealD ret;
#if defined (AVX1)|| defined (AVX2)
ret.v = _mm256_add_pd(a.v,b.v);
#endif
#ifdef SSE2
ret.v = _mm_add_pd(a.v,b.v);
#endif
#ifdef AVX512
ret.v = _mm512_add_pd(a.v,b.v);
#endif
#ifdef QPX
ret.v = vec_add(a.v,b.v);
#endif
return ret;
};
friend inline vRealD operator - (vRealD a, vRealD b)
{
vRealD ret;
#if defined (AVX1)|| defined (AVX2)
ret.v = _mm256_sub_pd(a.v,b.v);
#endif
#ifdef SSE2
ret.v = _mm_sub_pd(a.v,b.v);
#endif
#ifdef AVX512
ret.v = _mm512_sub_pd(a.v,b.v);
#endif
#ifdef QPX
ret.v = vec_sub(a.v,b.v);
#endif
return ret;
};
friend inline vRealD operator * (vRealD a, vRealD b)
{
vRealD ret;
#if defined (AVX1)|| defined (AVX2)
ret.v = _mm256_mul_pd(a.v,b.v);
#endif
#ifdef SSE2
ret.v = _mm_mul_pd(a.v,b.v);
#endif
#ifdef AVX512
ret.v = _mm512_mul_pd(a.v,b.v);
#endif
#ifdef QPX
ret.v = vec_mul(a.v,b.v);
#endif
return ret;
};
// Permute plans
// Permute 0 every ABCDEFGH -> BA DC FE HG
// Permute 1 every ABCDEFGH -> CD AB GH EF
// Permute 2 every ABCDEFGH -> EFGH ABCD
// Permute 3 possible on longer iVector lengths (512bit = 8 double = 16 single)
// Permute 4 possible on half precision @512bit vectors.
friend inline void permute(vRealD &y,vRealD b,int perm){
switch (perm){
// 4 doubles=>2 permutes
#if defined(AVX1)||defined(AVX2)
case 0: y.v = _mm256_shuffle_pd(b.v,b.v,0x5); break;
case 1: y.v = _mm256_permute2f128_pd(b.v,b.v,0x01); break;
#endif
#ifdef SSE2
case 0: y.v = _mm_shuffle_pd(b.v,b.v,0x1); break;
#endif
#ifdef AVX512
// 8 double => 3 permutes
// Permute 0 every abcd efgh -> badc fehg
// Permute 1 every abcd efgh -> cdab ghef
// Permute 2 every abcd efgh -> efgh abcd
// NOTE: mm_512_permutex_pd not implemented
// NOTE: ignore warning
case 0: y.v = _mm512_swizzle_pd(b.v,_MM_SWIZ_REG_CDAB); break;
case 1: y.v = _mm512_swizzle_pd(b.v,_MM_SWIZ_REG_BADC); break;
case 2: y.v = _mm512_permute4f128_ps(b.v,(_MM_PERM_ENUM)_MM_SHUFFLE(1,0,3,2)); break;
#endif
#ifdef QPX
#error
#endif
default: exit(EXIT_FAILURE); break;
}
};
// gona be bye bye
void vload(dvec& a){
this->v = a;
}
dvec vget(){
return this->v ;
}
friend inline void vsplat(vRealD &ret,double a){
#if defined (AVX1)|| defined (AVX2)
ret.v = _mm256_set_pd(a,a,a,a);
#endif
#ifdef SSE2
ret.v = _mm_set_pd(a,a);
#endif
#ifdef AVX512
ret.v = _mm512_set1_pd(a);
#endif
#ifdef QPX
ret.v = {a,a,a,a};
#endif
}
friend inline void vset(vRealD &ret, double *a){
#if defined (AVX1)|| defined (AVX2)
ret.v = _mm256_set_pd(a[3],a[2],a[1],a[0]);
#endif
#ifdef SSE2
ret.v = _mm_set_pd(a[0],a[1]);
#endif
#ifdef AVX512
ret.v = _mm512_set_pd(a[7],a[6],a[5],a[4],a[3],a[2],a[1],a[0]);
// Note v has a0 a1 a2 a3 a4 a5 a6 a7
#endif
#ifdef QPX
ret.v = {a[0],a[1],a[2],a[3]};
#endif
}
friend inline void vstore(vRealD &ret, double *a){
#if defined (AVX1)|| defined (AVX2)
_mm256_store_pd(a,ret.v);
#endif
#ifdef SSE2
_mm_store_pd(a,ret.v);
#endif
#ifdef AVX512
_mm512_store_pd(a,ret.v);
// Note v has a7 a6 a5ba4 a3 a2 a1 a0
#endif
#ifdef QPX
printf("%s Not implemented\n",__func__);
exit(-1);
#endif
}
friend inline void vprefetch(const vRealD &v)
{
_mm_prefetch((const char*)&v.v,_MM_HINT_T0);
}
// Unary negation
friend inline vRealD operator -(const vRealD &r) {
vRealD ret;
vzero(ret);
ret = ret - r;
return ret;
}
friend inline RealD Reduce(const vRealD & in)
{
#if defined (AVX1) || defined(AVX2)
typedef union {
uint64_t l;
double d;
} my_conv_t;
my_conv_t converter;
// more reduce_add
/*
__attribute__ ((aligned(32))) double c_[16];
__m256d tmp = _mm256_permute2f128_pd(in.v,in.v,0x01); // tmp 1032; in= 3210
__m256d hadd = _mm256_hadd_pd(in.v,tmp); // hadd = 1+0,3+2,3+2,1+0
tmp = _mm256_permute2f128_pd(hadd,hadd,0x01);// tmp = 3+2,1+0,1+0,3+2
hadd = _mm256_hadd_pd(tmp,tmp); // tmp = 3+2+1+0,3+2+1+0,1+0+3+2,1+0+3+2
_mm256_store_pd(c_,hadd);<3B>
return c[0]
*/
__m256d tmp = _mm256_permute2f128_pd(in.v,in.v,0x01); // tmp 1032; in= 3210
__m256d hadd = _mm256_hadd_pd(in.v,tmp); // hadd = 1+0,3+2,3+2,1+0
hadd = _mm256_hadd_pd(hadd,hadd); // hadd = 1+0+3+2...
converter.l = _mm256_extract_epi64(hadd,0);
return converter.d;
#endif
#ifdef AVX512
return _mm512_reduce_add_pd(in.v);
/*
__attribute__ ((aligned(32))) double c_[8];
_mm512_store_pd(c_,in.v);
return c_[0]+c_[1]+c_[2]+c_[3]+c_[4]+c_[5]+c_[6]+c_[7];
*/
#endif
#ifdef QPX
#endif
}
// *=,+=,-= operators
inline vRealD &operator *=(const vRealD &r) {
*this = (*this)*r;
return *this;
}
inline vRealD &operator +=(const vRealD &r) {
*this = *this+r;
return *this;
}
inline vRealD &operator -=(const vRealD &r) {
*this = *this-r;
return *this;
}
public:
static int Nsimd(void) { return sizeof(dvec)/sizeof(double);}
};
inline vRealD localInnerProduct(const vRealD & l, const vRealD & r) { return conj(l)*r; }
inline void zeroit(vRealD &z){ vzero(z);}
inline vRealD outerProduct(const vRealD &l, const vRealD& r)
{
return l*r;
}
}
#endif