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Adding support for iMatrix exponentiation

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neo 2015-06-09 18:59:45 +09:00
parent 6b8fe04054
commit d60cfe31a7
9 changed files with 83 additions and 1747 deletions
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430
lib/simd/Old/Grid_vComplexD.h
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#ifndef GRID_VCOMPLEXD_H
#define GRID_VCOMPLEXD_H
namespace Grid {
class vComplexD {
public:
zvec v;
public:
typedef zvec vector_type;
typedef ComplexD scalar_type;
vComplexD & operator = ( Zero & z){
vzero(*this);
return (*this);
}
vComplexD( Zero & z){
vzero(*this);
}
vComplexD()=default;
vComplexD(ComplexD a){
vsplat(*this,a);
};
vComplexD(double a){
vsplat(*this,ComplexD(a));
};
///////////////////////////////////////////////
// mac, mult, sub, add, adj
// Should do an AVX2 version with mac.
///////////////////////////////////////////////
friend inline void mac (vComplexD * __restrict__ y,const vComplexD * __restrict__ a,const vComplexD *__restrict__ x) {*y = (*a)*(*x)+(*y);};
friend inline void mult(vComplexD * __restrict__ y,const vComplexD * __restrict__ l,const vComplexD *__restrict__ r) {*y = (*l) * (*r);}
friend inline void sub (vComplexD * __restrict__ y,const vComplexD * __restrict__ l,const vComplexD *__restrict__ r) {*y = (*l) - (*r);}
friend inline void add (vComplexD * __restrict__ y,const vComplexD * __restrict__ l,const vComplexD *__restrict__ r) {*y = (*l) + (*r);}
friend inline vComplexD adj(const vComplexD &in){ return conjugate(in); }
//////////////////////////////////
// Initialise to 1,0,i
//////////////////////////////////
friend inline void vone (vComplexD &ret){ vsplat(ret,1.0,0.0);}
friend inline void vzero (vComplexD &ret){ vsplat(ret,0.0,0.0);}
friend inline void vcomplex_i(vComplexD &ret){ vsplat(ret,0.0,1.0);}
////////////////////////////////////
// Arithmetic operator overloads +,-,*
////////////////////////////////////
friend inline vComplexD operator + (vComplexD a, vComplexD b)
{
vComplexD ret;
#if defined (AVX1)|| defined (AVX2)
ret.v = _mm256_add_pd(a.v,b.v);
#endif
#ifdef SSE4
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 vComplexD operator - (vComplexD a, vComplexD b)
{
vComplexD ret;
#if defined (AVX1)|| defined (AVX2)
ret.v = _mm256_sub_pd(a.v,b.v);
#endif
#ifdef SSE4
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 vComplexD operator * (vComplexD a, vComplexD b)
{
vComplexD ret;
//Multiplicationof (ak+ibk)*(ck+idk)
// a + i b can be stored as a data structure
//From intel optimisation reference guide
/*
movsldup xmm0, Src1; load real parts into the destination,
; a1, a1, a0, a0
movaps xmm1, src2; load the 2nd pair of complex values, ; i.e. d1, c1, d0, c0
mulps xmm0, xmm1; temporary results, a1d1, a1c1, a0d0, ; a0c0
shufps xmm1, xmm1, b1; reorder the real and imaginary ; parts, c1, d1, c0, d0
movshdup xmm2, Src1; load the imaginary parts into the ; destination, b1, b1, b0, b0
mulps xmm2, xmm1; temporary results, b1c1, b1d1, b0c0, ; b0d0
addsubps xmm0, xmm2; b1c1+a1d1, a1c1 -b1d1, b0c0+a0d
VSHUFPD (VEX.256 encoded version)
IF IMM0[0] = 0
THEN DEST[63:0]=SRC1[63:0] ELSE DEST[63:0]=SRC1[127:64] FI;
IF IMM0[1] = 0
THEN DEST[127:64]=SRC2[63:0] ELSE DEST[127:64]=SRC2[127:64] FI;
IF IMM0[2] = 0
THEN DEST[191:128]=SRC1[191:128] ELSE DEST[191:128]=SRC1[255:192] FI;
IF IMM0[3] = 0
THEN DEST[255:192]=SRC2[191:128] ELSE DEST[255:192]=SRC2[255:192] FI; // Ox5 r<->i ; 0xC unchanged
*/
#if defined (AVX1)|| defined (AVX2)
zvec ymm0,ymm1,ymm2;
ymm0 = _mm256_shuffle_pd(a.v,a.v,0x0); // ymm0 <- ar ar, ar,ar b'00,00
ymm0 = _mm256_mul_pd(ymm0,b.v); // ymm0 <- ar bi, ar br
ymm1 = _mm256_shuffle_pd(b.v,b.v,0x5); // ymm1 <- br,bi b'01,01
ymm2 = _mm256_shuffle_pd(a.v,a.v,0xF); // ymm2 <- ai,ai b'11,11
ymm1 = _mm256_mul_pd(ymm1,ymm2); // ymm1 <- br ai, ai bi
ret.v= _mm256_addsub_pd(ymm0,ymm1);
#endif
#ifdef SSE4
zvec ymm0,ymm1,ymm2;
ymm0 = _mm_shuffle_pd(a.v,a.v,0x0); // ymm0 <- ar ar,
ymm0 = _mm_mul_pd(ymm0,b.v); // ymm0 <- ar bi, ar br
ymm1 = _mm_shuffle_pd(b.v,b.v,0x1); // ymm1 <- br,bi b01
ymm2 = _mm_shuffle_pd(a.v,a.v,0x3); // ymm2 <- ai,ai b11
ymm1 = _mm_mul_pd(ymm1,ymm2); // ymm1 <- br ai, ai bi
ret.v= _mm_addsub_pd(ymm0,ymm1);
#endif
#ifdef AVX512
/* This is from
* Automatic SIMD Vectorization of Fast Fourier Transforms for the Larrabee and AVX Instruction Sets
* @inproceedings{McFarlin:2011:ASV:1995896.1995938,
* author = {McFarlin, Daniel S. and Arbatov, Volodymyr and Franchetti, Franz and P\"{u}schel, Markus},
* title = {Automatic SIMD Vectorization of Fast Fourier Transforms for the Larrabee and AVX Instruction Sets},
* booktitle = {Proceedings of the International Conference on Supercomputing},
* series = {ICS '11},
* year = {2011},
* isbn = {978-1-4503-0102-2},
* location = {Tucson, Arizona, USA},
* pages = {265--274},
* numpages = {10},
* url = {http://doi.acm.org/10.1145/1995896.1995938},
* doi = {10.1145/1995896.1995938},
* acmid = {1995938},
* publisher = {ACM},
* address = {New York, NY, USA},
* keywords = {autovectorization, fourier transform, program generation, simd, super-optimization},
* }
*/
zvec vzero,ymm0,ymm1,real,imag;
vzero =(zvec)_mm512_setzero();
ymm0 = _mm512_swizzle_pd(a.v, _MM_SWIZ_REG_CDAB); //
real =(zvec)_mm512_mask_or_epi64((__m512i)a.v, 0xAA,(__m512i)vzero,(__m512i) ymm0);
imag = _mm512_mask_sub_pd(a.v, 0x55,vzero, ymm0);
ymm1 = _mm512_mul_pd(real, b.v);
ymm0 = _mm512_swizzle_pd(b.v, _MM_SWIZ_REG_CDAB); // OK
ret.v= _mm512_fmadd_pd(ymm0,imag,ymm1);
/* Imag OK */
#endif
#ifdef QPX
ret.v = vec_mul(a.v,b.v);
#endif
return ret;
};
////////////////////////////////////////////////////////////////////
// General permute; assumes vector length is same across
// all subtypes; may not be a good assumption, but could
// add the vector width as a template param for BG/Q for example
////////////////////////////////////////////////////////////////////
friend inline void permute(vComplexD &y,vComplexD b,int perm)
{
Gpermute<vComplexD>(y,b,perm);
}
/*
friend inline void merge(vComplexD &y,std::vector<ComplexD *> &extracted)
{
Gmerge<vComplexD,ComplexD >(y,extracted);
}
friend inline void extract(const vComplexD &y,std::vector<ComplexD *> &extracted)
{
Gextract<vComplexD,ComplexD>(y,extracted);
}
friend inline void merge(vComplexD &y,std::vector<ComplexD > &extracted)
{
Gmerge<vComplexD,ComplexD >(y,extracted);
}
friend inline void extract(const vComplexD &y,std::vector<ComplexD > &extracted)
{
Gextract<vComplexD,ComplexD>(y,extracted);
}
*/
///////////////////////
// Splat
///////////////////////
friend inline void vsplat(vComplexD &ret,ComplexD c){
float a= real(c);
float b= imag(c);
vsplat(ret,a,b);
}
friend inline void vsplat(vComplexD &ret,double rl,double ig){
#if defined (AVX1)|| defined (AVX2)
ret.v = _mm256_set_pd(ig,rl,ig,rl);
#endif
#ifdef SSE4
ret.v = _mm_set_pd(ig,rl);
#endif
#ifdef AVX512
ret.v = _mm512_set_pd(ig,rl,ig,rl,ig,rl,ig,rl);
#endif
#ifdef QPX
ret.v = {ig,rl,ig,rl};
#endif
}
friend inline void vset(vComplexD &ret,ComplexD *a){
#if defined (AVX1)|| defined (AVX2)
ret.v = _mm256_set_pd(a[1].imag(),a[1].real(),a[0].imag(),a[0].real());
#endif
#ifdef SSE4
ret.v = _mm_set_pd(a[0].imag(),a[0].real());
#endif
#ifdef AVX512
ret.v = _mm512_set_pd(a[3].imag(),a[3].real(),a[2].imag(),a[2].real(),a[1].imag(),a[1].real(),a[0].imag(),a[0].real());
// Note v has a0 a1 a2 a3
#endif
#ifdef QPX
ret.v = {a[0].real(),a[0].imag(),a[1].real(),a[3].imag()};
#endif
}
friend inline void vstore(const vComplexD &ret, ComplexD *a){
#if defined (AVX1)|| defined (AVX2)
_mm256_store_pd((double *)a,ret.v);
#endif
#ifdef SSE4
_mm_store_pd((double *)a,ret.v);
#endif
#ifdef AVX512
_mm512_store_pd((double *)a,ret.v);
//Note v has a3 a2 a1 a0
#endif
#ifdef QPX
assert(0);
#endif
}
friend inline void vstream(vComplexD &out,const vComplexD &in){
#if defined (AVX1)|| defined (AVX2)
_mm256_stream_pd((double *)&out.v,in.v);
#endif
#ifdef SSE4
_mm_stream_pd((double *)&out.v,in.v);
#endif
#ifdef AVX512
_mm512_storenrngo_pd((double *)&out.v,in.v);
// _mm512_stream_pd((double *)&out.v,in.v);
//Note v has a3 a2 a1 a0
#endif
#ifdef QPX
assert(0);
#endif
}
friend inline void prefetch(const vComplexD &v)
{
_mm_prefetch((const char*)&v.v,_MM_HINT_T0);
}
////////////////////////
// Conjugate
////////////////////////
friend inline vComplexD conjugate(const vComplexD &in){
vComplexD ret ; vzero(ret);
#if defined (AVX1)|| defined (AVX2)
// addsubps 0, inv=>0+in.v[3] 0-in.v[2], 0+in.v[1], 0-in.v[0], ...
zvec tmp = _mm256_addsub_pd(ret.v,_mm256_shuffle_pd(in.v,in.v,0x5));
ret.v =_mm256_shuffle_pd(tmp,tmp,0x5);
#endif
#ifdef SSE4
zvec tmp = _mm_addsub_pd(ret.v,_mm_shuffle_pd(in.v,in.v,0x1));
ret.v = _mm_shuffle_pd(tmp,tmp,0x1);
#endif
#ifdef AVX512
ret.v = _mm512_mask_sub_pd(in.v, 0xaa,ret.v, in.v);
#endif
#ifdef QPX
assert(0);
#endif
return ret;
}
friend inline void timesMinusI(vComplexD &ret,const vComplexD &in){
vzero(ret);
vComplexD tmp;
#if defined (AVX1)|| defined (AVX2)
tmp.v =_mm256_addsub_pd(ret.v,in.v); // r,-i
ret.v =_mm256_shuffle_pd(tmp.v,tmp.v,0x5);
#endif
#ifdef SSE4
tmp.v =_mm_addsub_pd(ret.v,in.v); // r,-i
ret.v =_mm_shuffle_pd(tmp.v,tmp.v,0x1);
#endif
#ifdef AVX512
ret.v = _mm512_mask_sub_pd(in.v,0xaa,ret.v,in.v); // real -imag
ret.v = _mm512_swizzle_pd(ret.v, _MM_SWIZ_REG_CDAB);// OK
#endif
#ifdef QPX
assert(0);
#endif
}
friend inline void timesI(vComplexD &ret, const vComplexD &in){
vzero(ret);
vComplexD tmp;
#if defined (AVX1)|| defined (AVX2)
tmp.v =_mm256_shuffle_pd(in.v,in.v,0x5);
ret.v =_mm256_addsub_pd(ret.v,tmp.v); // i,-r
#endif
#ifdef SSE4
tmp.v =_mm_shuffle_pd(in.v,in.v,0x1);
ret.v =_mm_addsub_pd(ret.v,tmp.v); // r,-i
#endif
#ifdef AVX512
tmp.v = _mm512_swizzle_pd(in.v, _MM_SWIZ_REG_CDAB);// OK
ret.v = _mm512_mask_sub_pd(tmp.v,0xaa,ret.v,tmp.v); // real -imag
#endif
#ifdef QPX
assert(0);
#endif
}
friend inline vComplexD timesMinusI(const vComplexD &in){
vComplexD ret;
timesMinusI(ret,in);
return ret;
}
friend inline vComplexD timesI(const vComplexD &in){
vComplexD ret;
timesI(ret,in);
return ret;
}
// REDUCE FIXME must be a cleaner implementation
friend inline ComplexD Reduce(const vComplexD & in)
{
vComplexD v1,v2;
union {
zvec v;
double f[sizeof(zvec)/sizeof(double)];
} conv;
#ifdef SSE4
v1=in;
#endif
#if defined(AVX1) || defined (AVX2)
permute(v1,in,0); // sse 128; paired complex single
v1=v1+in;
#endif
#ifdef AVX512
permute(v1,in,0); // sse 128; paired complex single
v1=v1+in;
permute(v2,v1,1); // avx 256; quad complex single
v1=v1+v2;
#endif
#ifdef QPX
#error
#endif
conv.v = v1.v;
return ComplexD(conv.f[0],conv.f[1]);
}
// Unary negation
friend inline vComplexD operator -(const vComplexD &r) {
vComplexD ret;
vzero(ret);
ret = ret - r;
return ret;
}
// *=,+=,-= operators
inline vComplexD &operator *=(const vComplexD &r) {
*this = (*this)*r;
return *this;
}
inline vComplexD &operator +=(const vComplexD &r) {
*this = *this+r;
return *this;
}
inline vComplexD &operator -=(const vComplexD &r) {
*this = *this-r;
return *this;
}
public:
static int Nsimd(void) { return sizeof(zvec)/sizeof(double)/2;}
};
inline vComplexD innerProduct(const vComplexD & l, const vComplexD & r) { return conjugate(l)*r; }
typedef vComplexD vDComplex;
inline void zeroit(vComplexD &z){ vzero(z);}
inline vComplexD outerProduct(const vComplexD &l, const vComplexD& r)
{
return l*r;
}
inline vComplexD trace(const vComplexD &arg){
return arg;
}
/////////////////////////////////////////////////////////////////////////
//// Generic routine to promote object<complex> -> object<vcomplex>
//// Supports the array reordering transformation that gives me SIMD utilisation
///////////////////////////////////////////////////////////////////////////
/*
template<template<class> class object>
inline object<vComplex> splat(object<Complex >s){
object<vComplex> ret;
vComplex * v_ptr = (vComplex *)& ret;
Complex * s_ptr = (Complex *) &s;
for(int i=0;i<sizeof(ret);i+=sizeof(vComplex)){
vsplat(*(v_ptr++),*(s_ptr++));
}
return ret;
}
*/
}
#endif

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lib/simd/Old/Grid_vComplexF.h
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#ifndef GRID_VCOMPLEXF
#define GRID_VCOMPLEXF
namespace Grid {
/*
inline void Print(const char *A,cvec c) {
float *fp=(float *)&c;
printf(A);
printf(" %le %le %le %le %le %le %le %le\n",
fp[0],fp[1],fp[2],fp[3],fp[4],fp[5],fp[6],fp[7]);
}
*/
class vComplexF {
// protected:
public:
cvec v;
public:
static inline int Nsimd(void) { return sizeof(cvec)/sizeof(float)/2;}
public:
typedef cvec vector_type;
typedef ComplexF scalar_type;
vComplexF & operator = ( Zero & z){
vzero(*this);
return (*this);
}
// vComplexF( Zero & z){
// vzero(*this);
// }
vComplexF()=default;
vComplexF(ComplexF a){
vsplat(*this,a);
};
vComplexF(double a){
vsplat(*this,ComplexF(a));
};
///////////////////////////////////////////////
// mac, mult, sub, add, adj
// Should do an AVX2 version with mac.
///////////////////////////////////////////////
friend inline void mac (vComplexF * __restrict__ y,const vComplexF * __restrict__ a,const vComplexF *__restrict__ x){ *y = (*a)*(*x)+(*y); };
friend inline void mult(vComplexF * __restrict__ y,const vComplexF * __restrict__ l,const vComplexF *__restrict__ r){ *y = (*l) * (*r); }
friend inline void sub (vComplexF * __restrict__ y,const vComplexF * __restrict__ l,const vComplexF *__restrict__ r){ *y = (*l) - (*r); }
friend inline void add (vComplexF * __restrict__ y,const vComplexF * __restrict__ l,const vComplexF *__restrict__ r){ *y = (*l) + (*r); }
friend inline vComplexF adj(const vComplexF &in){ return conjugate(in); }
//////////////////////////////////
// Initialise to 1,0,i
//////////////////////////////////
friend inline void vone(vComplexF &ret) { vsplat(ret,1.0,0.0); }
friend inline void vzero(vComplexF &ret) { vsplat(ret,0.0,0.0); }
friend inline void vcomplex_i(vComplexF &ret){ vsplat(ret,0.0,1.0); }
////////////////////////////////////
// Arithmetic operator overloads +,-,*
////////////////////////////////////
friend inline vComplexF operator + (vComplexF a, vComplexF b)
{
vComplexF ret;
#if defined (AVX1)|| defined (AVX2)
ret.v = _mm256_add_ps(a.v,b.v);
#endif
#ifdef SSE4
ret.v = _mm_add_ps(a.v,b.v);
#endif
#ifdef AVX512
ret.v = _mm512_add_ps(a.v,b.v);
#endif
#ifdef QPX
#error
#endif
return ret;
};
friend inline vComplexF operator - (vComplexF a, vComplexF b)
{
vComplexF ret;
#if defined (AVX1)|| defined (AVX2)
ret.v = _mm256_sub_ps(a.v,b.v);
#endif
#ifdef SSE4
ret.v = _mm_sub_ps(a.v,b.v);
#endif
#ifdef AVX512
ret.v = _mm512_sub_ps(a.v,b.v);
#endif
#ifdef QPX
#error
#endif
return ret;
};
friend inline vComplexF operator * (vComplexF a, vComplexF b)
{
vComplexF ret;
//Multiplicationof (ak+ibk)*(ck+idk)
// a + i b can be stored as a data structure
//From intel optimisation reference
/*
movsldup xmm0, Src1; load real parts into the destination,
; a1, a1, a0, a0
movaps xmm1, src2; load the 2nd pair of complex values, ; i.e. d1, c1, d0, c0
mulps xmm0, xmm1; temporary results, a1d1, a1c1, a0d0, ; a0c0
shufps xmm1, xmm1, b1; reorder the real and imaginary ; parts, c1, d1, c0, d0
movshdup xmm2, Src1; load the imaginary parts into the ; destination, b1, b1, b0, b0
mulps xmm2, xmm1; temporary results, b1c1, b1d1, b0c0, ; b0d0
addsubps xmm0, xmm2; b1c1+a1d1, a1c1 -b1d1, b0c0+a0d
*/
#if defined (AVX1)|| defined (AVX2)
cvec ymm0,ymm1,ymm2;
ymm0 = _mm256_shuffle_ps(a.v,a.v,_MM_SHUFFLE(2,2,0,0)); // ymm0 <- ar ar,
ymm0 = _mm256_mul_ps(ymm0,b.v); // ymm0 <- ar bi, ar br
// FIXME AVX2 could MAC
ymm1 = _mm256_shuffle_ps(b.v,b.v,_MM_SHUFFLE(2,3,0,1)); // ymm1 <- br,bi
ymm2 = _mm256_shuffle_ps(a.v,a.v,_MM_SHUFFLE(3,3,1,1)); // ymm2 <- ai,ai
ymm1 = _mm256_mul_ps(ymm1,ymm2); // ymm1 <- br ai, ai bi
ret.v= _mm256_addsub_ps(ymm0,ymm1);
#endif
#ifdef SSE4
cvec ymm0,ymm1,ymm2;
ymm0 = _mm_shuffle_ps(a.v,a.v,_MM_SHUFFLE(2,2,0,0)); // ymm0 <- ar ar,
ymm0 = _mm_mul_ps(ymm0,b.v); // ymm0 <- ar bi, ar br
ymm1 = _mm_shuffle_ps(b.v,b.v,_MM_SHUFFLE(2,3,0,1)); // ymm1 <- br,bi
ymm2 = _mm_shuffle_ps(a.v,a.v,_MM_SHUFFLE(3,3,1,1)); // ymm2 <- ai,ai
ymm1 = _mm_mul_ps(ymm1,ymm2); // ymm1 <- br ai, ai bi
ret.v= _mm_addsub_ps(ymm0,ymm1);
#endif
#ifdef AVX512
//
cvec vzero,ymm0,ymm1,real, imag;
vzero = _mm512_setzero();
ymm0 = _mm512_swizzle_ps(a.v, _MM_SWIZ_REG_CDAB); //
real = (__m512)_mm512_mask_or_epi32((__m512i)a.v, 0xAAAA,(__m512i)vzero,(__m512i)ymm0);
imag = _mm512_mask_sub_ps(a.v, 0x5555,vzero, ymm0);
ymm1 = _mm512_mul_ps(real, b.v);
ymm0 = _mm512_swizzle_ps(b.v, _MM_SWIZ_REG_CDAB); // OK
ret.v = _mm512_fmadd_ps(ymm0,imag,ymm1);
#endif
#ifdef QPX
ret.v = vec_mul(a.v,b.v);
#endif
return ret;
};
////////////////////////////////////////////////////////////////////////
// FIXME: gonna remove these load/store, get, set, prefetch
////////////////////////////////////////////////////////////////////////
friend inline void vset(vComplexF &ret, ComplexF *a){
#if defined (AVX1)|| defined (AVX2)
ret.v = _mm256_set_ps(a[3].imag(),a[3].real(),a[2].imag(),a[2].real(),a[1].imag(),a[1].real(),a[0].imag(),a[0].real());
#endif
#ifdef SSE4
ret.v = _mm_set_ps(a[1].imag(), a[1].real(),a[0].imag(),a[0].real());
#endif
#ifdef AVX512
ret.v = _mm512_set_ps(a[7].imag(),a[7].real(),a[6].imag(),a[6].real(),a[5].imag(),a[5].real(),a[4].imag(),a[4].real(),a[3].imag(),a[3].real(),a[2].imag(),a[2].real(),a[1].imag(),a[1].real(),a[0].imag(),a[0].real());
// Note v has a0 a1 a2 a3 a4 a5 a6 a7
#endif
#ifdef QPX
ret.v = {a[0].real(),a[0].imag(),a[1].real(),a[1].imag(),a[2].real(),a[2].imag(),a[3].real(),a[3].imag()};
#endif
}
///////////////////////
// Splat
///////////////////////
friend inline void vsplat(vComplexF &ret,ComplexF c){
float a= real(c);
float b= imag(c);
vsplat(ret,a,b);
}
friend inline void vstore(const vComplexF &ret, ComplexF *a){
#if defined (AVX1)|| defined (AVX2)
_mm256_store_ps((float *)a,ret.v);
#endif
#ifdef SSE4
_mm_store_ps((float *)a,ret.v);
#endif
#ifdef AVX512
_mm512_store_ps((float *)a,ret.v);
//Note v has a3 a2 a1 a0
#endif
#ifdef QPX
assert(0);
#endif
}
friend inline void vstream(vComplexF &out,const vComplexF &in){
#if defined (AVX1)|| defined (AVX2)
_mm256_stream_ps((float *)&out.v,in.v);
#endif
#ifdef SSE4
_mm_stream_ps((float *)&out.v,in.v);
#endif
#ifdef AVX512
_mm512_storenrngo_ps((float *)&out.v,in.v);
//Note v has a3 a2 a1 a0
#endif
#ifdef QPX
assert(0);
#endif
}
friend inline void prefetch(const vComplexF &v)
{
_mm_prefetch((const char*)&v.v,_MM_HINT_T0);
}
friend inline void vsplat(vComplexF &ret,float a,float b){
#if defined (AVX1)|| defined (AVX2)
ret.v = _mm256_set_ps(b,a,b,a,b,a,b,a);
#endif
#ifdef SSE4
ret.v = _mm_set_ps(b,a,b,a);
#endif
#ifdef AVX512
ret.v = _mm512_set_ps(b,a,b,a,b,a,b,a,b,a,b,a,b,a,b,a);
#endif
#ifdef QPX
ret.v = {a,b,a,b};
#endif
}
friend inline void permute(vComplexF &y,vComplexF b,int perm)
{
Gpermute<vComplexF>(y,b,perm);
}
friend inline ComplexF Reduce(const vComplexF & in)
{
vComplexF v1,v2;
union {
cvec v;
float f[sizeof(cvec)/sizeof(float)];
} conv;
#ifdef SSE4
permute(v1,in,0); // sse 128; paired complex single
v1=v1+in;
#endif
#if defined(AVX1) || defined (AVX2)
permute(v1,in,0); // sse 128; paired complex single
v1=v1+in;
permute(v2,v1,1); // avx 256; quad complex single
v1=v1+v2;
#endif
#ifdef AVX512
permute(v1,in,0); // avx512 octo-complex single
v1=v1+in;
permute(v2,v1,1);
v1=v1+v2;
permute(v2,v1,2);
v1=v1+v2;
#endif
#ifdef QPX
#error
#endif
conv.v = v1.v;
return ComplexF(conv.f[0],conv.f[1]);
}
friend inline vComplexF operator * (const ComplexF &a, vComplexF b){
vComplexF va;
vsplat(va,a);
return va*b;
}
friend inline vComplexF operator * (vComplexF b,const ComplexF &a){
return a*b;
}
/*
template<class real>
friend inline vComplexF operator * (vComplexF b,const real &a){
vComplexF va;
Complex ca(a,0);
vsplat(va,ca);
return va*b;
}
template<class real>
friend inline vComplexF operator * (const real &a,vComplexF b){
return a*b;
}
friend inline vComplexF operator + (const Complex &a, vComplexF b){
vComplexF va;
vsplat(va,a);
return va+b;
}
friend inline vComplexF operator + (vComplexF b,const Complex &a){
return a+b;
}
template<class real>
friend inline vComplexF operator + (vComplexF b,const real &a){
vComplexF va;
Complex ca(a,0);
vsplat(va,ca);
return va+b;
}
template<class real>
friend inline vComplexF operator + (const real &a,vComplexF b){
return a+b;
}
friend inline vComplexF operator - (const Complex &a, vComplexF b){
vComplexF va;
vsplat(va,a);
return va-b;
}
friend inline vComplexF operator - (vComplexF b,const Complex &a){
vComplexF va;
vsplat(va,a);
return b-va;
}
template<class real>
friend inline vComplexF operator - (vComplexF b,const real &a){
vComplexF va;
Complex ca(a,0);
vsplat(va,ca);
return b-va;
}
template<class real>
friend inline vComplexF operator - (const real &a,vComplexF b){
vComplexF va;
Complex ca(a,0);
vsplat(va,ca);
return va-b;
}
*/
///////////////////////
// Conjugate
///////////////////////
friend inline vComplexF conjugate(const vComplexF &in){
vComplexF ret ; vzero(ret);
#if defined (AVX1)|| defined (AVX2)
ret.v = _mm256_xor_ps(_mm256_addsub_ps(ret.v,in.v), _mm256_set1_ps(-0.f));
#endif
#ifdef SSE4
ret.v = _mm_xor_ps(_mm_addsub_ps(ret.v,in.v), _mm_set1_ps(-0.f));
#endif
#ifdef AVX512
ret.v = _mm512_mask_sub_ps(in.v,0xaaaa,ret.v,in.v); // Zero out 0+real 0-imag
#endif
#ifdef QPX
assert(0);
#endif
return ret;
}
friend inline void timesMinusI( vComplexF &ret,const vComplexF &in){
vzero(ret);
#if defined (AVX1)|| defined (AVX2)
cvec tmp =_mm256_addsub_ps(ret.v,in.v); // r,-i
ret.v = _mm256_shuffle_ps(tmp,tmp,_MM_SHUFFLE(2,3,0,1)); //-i,r
#endif
#ifdef SSE4
cvec tmp =_mm_addsub_ps(ret.v,in.v); // r,-i
ret.v = _mm_shuffle_ps(tmp,tmp,_MM_SHUFFLE(2,3,0,1));
#endif
#ifdef AVX512
ret.v = _mm512_mask_sub_ps(in.v,0xaaaa,ret.v,in.v); // real -imag
ret.v = _mm512_swizzle_ps(ret.v, _MM_SWIZ_REG_CDAB);// OK
#endif
#ifdef QPX
assert(0);
#endif
}
friend inline void timesI(vComplexF &ret,const vComplexF &in){
vzero(ret);
#if defined (AVX1)|| defined (AVX2)
cvec tmp =_mm256_shuffle_ps(in.v,in.v,_MM_SHUFFLE(2,3,0,1));//i,r
ret.v =_mm256_addsub_ps(ret.v,tmp); //i,-r
#endif
#ifdef SSE4
cvec tmp =_mm_shuffle_ps(in.v,in.v,_MM_SHUFFLE(2,3,0,1));
ret.v = _mm_addsub_ps(ret.v,tmp); // r,-i
#endif
#ifdef AVX512
cvec tmp = _mm512_swizzle_ps(in.v, _MM_SWIZ_REG_CDAB);// OK
ret.v = _mm512_mask_sub_ps(tmp,0xaaaa,ret.v,tmp); // real -imag
#endif
#ifdef QPX
assert(0);
#endif
}
friend inline vComplexF timesMinusI(const vComplexF &in){
vComplexF ret;
timesMinusI(ret,in);
return ret;
}
friend inline vComplexF timesI(const vComplexF &in){
vComplexF ret;
timesI(ret,in);
return ret;
}
// Unary negation
friend inline vComplexF operator -(const vComplexF &r) {
vComplexF ret;
vzero(ret);
ret = ret - r;
return ret;
}
// *=,+=,-= operators
inline vComplexF &operator *=(const vComplexF &r) {
*this = (*this)*r;
return *this;
}
inline vComplexF &operator +=(const vComplexF &r) {
*this = *this+r;
return *this;
}
inline vComplexF &operator -=(const vComplexF &r) {
*this = *this-r;
return *this;
}
/*
friend inline void merge(vComplexF &y,std::vector<ComplexF *> &extracted)
{
Gmerge<vComplexF,ComplexF >(y,extracted);
}
friend inline void extract(const vComplexF &y,std::vector<ComplexF *> &extracted)
{
Gextract<vComplexF,ComplexF>(y,extracted);
}
friend inline void merge(vComplexF &y,std::vector<ComplexF > &extracted)
{
Gmerge<vComplexF,ComplexF >(y,extracted);
}
friend inline void extract(const vComplexF &y,std::vector<ComplexF > &extracted)
{
Gextract<vComplexF,ComplexF>(y,extracted);
}
*/
};
inline vComplexF innerProduct(const vComplexF & l, const vComplexF & r)
{
return conjugate(l)*r;
}
inline void zeroit(vComplexF &z){ vzero(z);}
inline vComplexF outerProduct(const vComplexF &l, const vComplexF& r)
{
return l*r;
}
inline vComplexF trace(const vComplexF &arg){
return arg;
}
}
#endif

259
lib/simd/Old/Grid_vInteger.h
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@ -1,259 +0,0 @@
#ifndef GRID_VINTEGER_H
#define GRID_VINTEGER_H
namespace Grid {
class vInteger {
protected:
public:
ivec v;
typedef ivec vector_type;
typedef Integer scalar_type;
vInteger(){};
vInteger & operator = (const Zero & z){
vzero(*this);
return (*this);
}
vInteger(Integer a){
vsplat(*this,a);
};
////////////////////////////////////
// Arithmetic operator overloads +,-,*
////////////////////////////////////
friend inline vInteger operator + ( vInteger a, vInteger b)
{
vInteger ret;
#if defined (AVX1)
__m128i a0,a1;
__m128i b0,b1;
a0 = _mm256_extractf128_si256(a.v,0);
b0 = _mm256_extractf128_si256(b.v,0);
a1 = _mm256_extractf128_si256(a.v,1);
b1 = _mm256_extractf128_si256(b.v,1);
a0 = _mm_add_epi32(a0,b0);
a1 = _mm_add_epi32(a1,b1);
ret.v = _mm256_set_m128i(a1,a0);
#endif
#if defined (AVX2)
ret.v = _mm256_add_epi32(a.v,b.v);
#endif
#ifdef SSE4
ret.v = _mm_add_epi32(a.v,b.v);
#endif
#ifdef AVX512
ret.v = _mm512_add_epi32(a.v,b.v);
#endif
#ifdef QPX
// Implement as array of ints is only option
#error
#endif
return ret;
};
friend inline vInteger operator - ( vInteger a, vInteger b)
{
vInteger ret;
#if defined (AVX1)
__m128i a0,a1;
__m128i b0,b1;
a0 = _mm256_extractf128_si256(a.v,0);
b0 = _mm256_extractf128_si256(b.v,0);
a1 = _mm256_extractf128_si256(a.v,1);
b1 = _mm256_extractf128_si256(b.v,1);
a0 = _mm_sub_epi32(a0,b0);
a1 = _mm_sub_epi32(a1,b1);
ret.v = _mm256_set_m128i(a1,a0);
#endif
#if defined (AVX2)
ret.v = _mm256_sub_epi32(a.v,b.v);
#endif
#ifdef SSE4
ret.v = _mm_sub_epi32(a.v,b.v);
#endif
#ifdef AVX512
ret.v = _mm512_sub_epi32(a.v,b.v);
#endif
#ifdef QPX
// Implement as array of ints is only option
#error
#endif
return ret;
};
friend inline vInteger operator * ( vInteger a, vInteger b)
{
vInteger ret;
#if defined (AVX1)
__m128i a0,a1;
__m128i b0,b1;
a0 = _mm256_extractf128_si256(a.v,0);
b0 = _mm256_extractf128_si256(b.v,0);
a1 = _mm256_extractf128_si256(a.v,1);
b1 = _mm256_extractf128_si256(b.v,1);
a0 = _mm_mul_epi32(a0,b0);
a1 = _mm_mul_epi32(a1,b1);
ret.v = _mm256_set_m128i(a1,a0);
#endif
#if defined (AVX2)
ret.v = _mm256_mul_epi32(a.v,b.v);
#endif
#ifdef SSE4
ret.v = _mm_mul_epi32(a.v,b.v);
#endif
#ifdef AVX512
// ret.v = _mm512_mul_epi32(a.v,b.v);
ret.v = _mm512_mullo_epi32(a.v,b.v);
#endif
#ifdef QPX
// Implement as array of ints is only option
#error
#endif
return ret;
};
///////////////////////////////////////////////
// mult, sub, add, adj,conjugate, mac functions
///////////////////////////////////////////////
friend inline void mult(vInteger * __restrict__ y,const vInteger * __restrict__ l,const vInteger *__restrict__ r) {*y = (*l) * (*r);}
friend inline void sub (vInteger * __restrict__ y,const vInteger * __restrict__ l,const vInteger *__restrict__ r) {*y = (*l) - (*r);}
friend inline void add (vInteger * __restrict__ y,const vInteger * __restrict__ l,const vInteger *__restrict__ r) {*y = (*l) + (*r);}
friend inline void mac (vInteger &y,const vInteger a,const vInteger x){
y = a*x+y;
}
//////////////////////////////////
// Initialise to 1,0,i
//////////////////////////////////
friend inline void vone (vInteger &ret){vsplat(ret,1);}
friend inline void vzero(vInteger &ret){vsplat(ret,0);}
friend inline void vtrue (vInteger &ret){vsplat(ret,0xFFFFFFFF);}
friend inline void vfalse(vInteger &ret){vsplat(ret,0);}
/////////////////////////////////////////////////////
// Broadcast a value across Nsimd copies.
/////////////////////////////////////////////////////
friend inline void vsplat(vInteger &ret,scalar_type a){
#if defined (AVX1)|| defined (AVX2)
ret.v = _mm256_set1_epi32(a);
#endif
#ifdef SSE4
ret.v = _mm_set1_epi32(a);
#endif
#ifdef AVX512
ret.v = _mm512_set1_epi32(a);
#endif
#ifdef QPX
#error
#endif
}
friend inline void vset(vInteger &ret,scalar_type *a){
#if defined (AVX1)|| defined (AVX2)
ret.v = _mm256_set_epi32(a[7],a[6],a[5],a[4],a[3],a[2],a[1],a[0]);
#endif
#ifdef SSE4
ret.v = _mm_set_epi32(a[0],a[1],a[2],a[3]);
#endif
#ifdef AVX512
ret.v = _mm512_set_epi32( a[15],a[14],a[13],a[12],a[11],a[10],a[9],a[8],
a[7],a[6],a[5],a[4],a[3],a[2],a[1],a[0]);
#endif
#ifdef QPX
#error
#endif
}
friend inline void vstore(const vInteger &ret, Integer *a){
#if defined (AVX1)|| defined (AVX2)
_mm256_store_si256((__m256i*)a,ret.v);
#endif
#ifdef SSE4
_mm_store_si128((__m128i *)a,ret.v);
#endif
#ifdef AVX512
_mm512_store_si512(a,ret.v);
#endif
#ifdef QPX
assert(0);
#endif
}
friend inline void vstream(vInteger & out,const vInteger &in){
out=in;
}
friend inline void prefetch(const vInteger &v)
{
_mm_prefetch((const char*)&v.v,_MM_HINT_T0);
}
// Unary negation
friend inline vInteger operator -(const vInteger &r) {
vInteger ret;
vzero(ret);
ret = ret - r;
return ret;
}
friend inline Integer Reduce(const vInteger & in)
{
// unimplemented
assert(0);
}
// *=,+=,-= operators
inline vInteger &operator *=(const vInteger &r) {
*this = (*this)*r;
return *this;
}
inline vInteger &operator +=(const vInteger &r) {
*this = *this+r;
return *this;
}
inline vInteger &operator -=(const vInteger &r) {
*this = *this-r;
return *this;
}
friend inline void permute(vInteger &y,const vInteger b,int perm)
{
Gpermute<vInteger>(y,b,perm);
}
/*
friend inline void merge(vInteger &y,std::vector<Integer *> &extracted)
{
Gmerge<vInteger,Integer>(y,extracted);
}
friend inline void extract(const vInteger &y,std::vector<Integer *> &extracted)
{
Gextract<vInteger,Integer>(y,extracted);
}
friend inline void merge(vInteger &y,std::vector<Integer> &extracted)
{
Gmerge<vInteger,Integer>(y,extracted);
}
friend inline void extract(const vInteger &y,std::vector<Integer> &extracted)
{
Gextract<vInteger,Integer>(y,extracted);
}
*/
public:
static inline int Nsimd(void) { return sizeof(ivec)/sizeof(Integer);}
};
inline vInteger localInnerProduct(const vInteger & l, const vInteger & r) { return l*r; }
inline void zeroit(vInteger &z){ vzero(z);}
inline vInteger outerProduct(const vInteger &l, const vInteger& r)
{
return l*r;
}
}
#endif

276
lib/simd/Old/Grid_vRealD.h
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@ -1,276 +0,0 @@
#ifndef GRID_VREALD_H
#define GRID_VREALD_H
namespace Grid {
class vRealD {
public:
dvec v; // dvec is double precision vector
public:
typedef dvec vector_type;
typedef RealD scalar_type;
vRealD()=default;
vRealD(RealD a){
vsplat(*this,a);
};
vRealD(Zero &zero){
zeroit(*this);
}
vRealD & operator = ( Zero & z){
vzero(*this);
return (*this);
}
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 conjugate(const vRealD &in){ return in; }
friend inline void mac (vRealD &y,const vRealD a,const vRealD x){
#if defined (AVX1) || defined (SSE4)
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 SSE4
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 SSE4
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 SSE4
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;
};
////////////////////////////////////////////////////////////////////
// General permute; assumes vector length is same across
// all subtypes; may not be a good assumption, but could
// add the vector width as a template param for BG/Q for example
////////////////////////////////////////////////////////////////////
friend inline void permute(vRealD &y,vRealD b,int perm)
{
Gpermute<vRealD>(y,b,perm);
}
/*
friend inline void merge(vRealD &y,std::vector<RealD *> &extracted)
{
Gmerge<vRealD,RealD >(y,extracted);
}
friend inline void extract(const vRealD &y,std::vector<RealD *> &extracted)
{
Gextract<vRealD,RealD>(y,extracted);
}
friend inline void merge(vRealD &y,std::vector<RealD > &extracted)
{
Gmerge<vRealD,RealD >(y,extracted);
}
friend inline void extract(const vRealD &y,std::vector<RealD > &extracted)
{
Gextract<vRealD,RealD>(y,extracted);
}
*/
friend inline void vsplat(vRealD &ret,double a){
#if defined (AVX1)|| defined (AVX2)
ret.v = _mm256_set_pd(a,a,a,a);
#endif
#ifdef SSE4
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 SSE4
ret.v = _mm_set_pd(a[1],a[0]);
#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(const vRealD &ret, double *a){
#if defined (AVX1)|| defined (AVX2)
_mm256_store_pd(a,ret.v);
#endif
#ifdef SSE4
_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
assert(0);
#endif
}
friend inline void vstream(vRealD &out,const vRealD &in){
#if defined (AVX1)|| defined (AVX2)
_mm256_stream_pd((double *)&out.v,in.v);
#endif
#ifdef SSE4
_mm_stream_pd((double *)&out.v,in.v);
#endif
#ifdef AVX512
_mm512_storenrngo_pd((double *)&out.v,in.v);
//Note v has a3 a2 a1 a0
#endif
#ifdef QPX
assert(0);
#endif
}
friend inline void prefetch(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)
{
vRealD v1,v2;
union {
dvec v;
double f[sizeof(dvec)/sizeof(double)];
} conv;
#ifdef SSE4
permute(v1,in,0); // sse 128; paired real double
v1=v1+in;
#endif
#if defined(AVX1) || defined (AVX2)
permute(v1,in,0); // avx 256; quad double
v1=v1+in;
permute(v2,v1,1);
v1=v1+v2;
#endif
#ifdef AVX512
permute(v1,in,0); // avx 512; octo-double
v1=v1+in;
permute(v2,v1,1);
v1=v1+v2;
permute(v2,v1,2);
v1=v1+v2;
#endif
#ifdef QPX
#endif
conv.v=v1.v;
return conv.f[0];
}
// *=,+=,-= 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 innerProduct(const vRealD & l, const vRealD & r) { return conjugate(l)*r; }
inline void zeroit(vRealD &z){ vzero(z);}
inline vRealD outerProduct(const vRealD &l, const vRealD& r)
{
return l*r;
}
inline vRealD trace(const vRealD &arg){
return arg;
}
inline vRealD real(const vRealD &arg){
return arg;
}
}
#endif

313
lib/simd/Old/Grid_vRealF.h
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@ -1,313 +0,0 @@
#ifndef GRID_VREALF_H
#define GRID_VREALF_H
namespace Grid {
class vRealF {
public:
fvec v;
public:
typedef fvec vector_type;
typedef RealF scalar_type;
vRealF()=default;
vRealF(RealF a){
vsplat(*this,a);
};
vRealF(Zero &zero){
zeroit(*this);
}
vRealF & operator = ( Zero & z){
vzero(*this);
return (*this);
}
////////////////////////////////////
// Arithmetic operator overloads +,-,*
////////////////////////////////////
friend inline vRealF operator + ( vRealF a, vRealF b)
{
vRealF ret;
#if defined (AVX1)|| defined (AVX2)
ret.v = _mm256_add_ps(a.v,b.v);
#endif
#ifdef SSE4
ret.v = _mm_add_ps(a.v,b.v);
#endif
#ifdef AVX512
ret.v = _mm512_add_ps(a.v,b.v);
#endif
#ifdef QPX
vector4double aa,bb,cc;
aa = vec_lda(0,(float *)&a);
bb = vec_lda(0,(float *)&b);
cc = vec_add(aa,bb);
vec_sta(cc,0,(float *)&ret.v);
#endif
return ret;
};
friend inline vRealF operator - ( vRealF a, vRealF b)
{
vRealF ret;
#if defined (AVX1)|| defined (AVX2)
ret.v = _mm256_sub_ps(a.v,b.v);
#endif
#ifdef SSE4
ret.v = _mm_sub_ps(a.v,b.v);
#endif
#ifdef AVX512
ret.v = _mm512_sub_ps(a.v,b.v);
#endif
#ifdef QPX
vector4double aa,bb,cc;
aa = vec_lda(0,(float *)&a);
bb = vec_lda(0,(float *)&b);
cc = vec_sub(aa,bb);
vec_sta(cc,0,(float *)&ret.v);
#endif
return ret;
};
friend inline vRealF operator * ( vRealF a, vRealF b)
{
vRealF ret;
#if defined (AVX1)|| defined (AVX2)
ret.v = _mm256_mul_ps(a.v,b.v);
#endif
#ifdef SSE4
ret.v = _mm_mul_ps(a.v,b.v);
#endif
#ifdef AVX512
ret.v = _mm512_mul_ps(a.v,b.v);
#endif
#ifdef QPX
vector4double aa,bb,cc; // QPX single we are forced to load as this promotes single mem->double regs.
aa = vec_lda(0,(float *)&a);
bb = vec_lda(0,(float *)&b);
cc = vec_mul(aa,bb);
vec_sta(cc,0,(float *)&ret.v);
#endif
return ret;
};
///////////////////////////////////////////////
// mult, sub, add, adj,conjugate, mac functions
///////////////////////////////////////////////
friend inline void mult(vRealF * __restrict__ y,const vRealF * __restrict__ l,const vRealF *__restrict__ r) {*y = (*l) * (*r);}
friend inline void sub (vRealF * __restrict__ y,const vRealF * __restrict__ l,const vRealF *__restrict__ r) {*y = (*l) - (*r);}
friend inline void add (vRealF * __restrict__ y,const vRealF * __restrict__ l,const vRealF *__restrict__ r) {*y = (*l) + (*r);}
friend inline vRealF adj(const vRealF &in) { return in; }
friend inline vRealF conjugate(const vRealF &in){ return in; }
friend inline void mac (vRealF &y,const vRealF a,const vRealF x){
#if defined (AVX1) || defined (SSE4)
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_ps(a.v,x.v,y.v);
#endif
#ifdef AVX512
y.v = _mm512_fmadd_ps(a.v,x.v,y.v);
#endif
#ifdef QPX
vector4double aa,xx,yy; // QPX single we are forced to load as this promotes single mem->double regs.
aa = vec_lda(0,(float *)&a.v);
xx = vec_lda(0,(float *)&x.v);
yy = vec_lda(0,(float *)&y.v);
yy = vec_madd(aa,xx,yy);
vec_sta(yy,0,(float *)&y.v);
#endif
}
//////////////////////////////////
// Initialise to 1,0,i
//////////////////////////////////
friend inline void vone (vRealF &ret){vsplat(ret,1.0);}
friend inline void vzero(vRealF &ret){vsplat(ret,0.0);}
////////////////////////////////////////////////////////////////////
// General permute; assumes vector length is same across
// all subtypes; may not be a good assumption, but could
// add the vector width as a template param for BG/Q for example
////////////////////////////////////////////////////////////////////
friend inline void permute(vRealF &y,vRealF b,int perm)
{
Gpermute<vRealF>(y,b,perm);
}
/*
friend inline void merge(vRealF &y,std::vector<RealF *> &extracted)
{
Gmerge<vRealF,RealF >(y,extracted);
}
friend inline void extract(const vRealF &y,std::vector<RealF *> &extracted)
{
Gextract<vRealF,RealF>(y,extracted);
}
friend inline void merge(vRealF &y,std::vector<RealF> &extracted)
{
Gmerge<vRealF,RealF >(y,extracted);
}
friend inline void extract(const vRealF &y,std::vector<RealF> &extracted)
{
Gextract<vRealF,RealF>(y,extracted);
}
*/
/////////////////////////////////////////////////////
// Broadcast a value across Nsimd copies.
/////////////////////////////////////////////////////
friend inline void vsplat(vRealF &ret,float a){
#if defined (AVX1)|| defined (AVX2)
ret.v = _mm256_set_ps(a,a,a,a,a,a,a,a);
#endif
#ifdef SSE4
ret.v = _mm_set_ps(a,a,a,a);
#endif
#ifdef AVX512
//ret.v = _mm512_set_ps(a,a,a,a,a,a,a,a,a,a,a,a,a,a,a,a);
ret.v = _mm512_set1_ps(a);
#endif
#ifdef QPX
ret.v = {a,a,a,a};
#endif
}
friend inline void vset(vRealF &ret, float *a){
#if defined (AVX1)|| defined (AVX2)
ret.v = _mm256_set_ps(a[7],a[6],a[5],a[4],a[3],a[2],a[1],a[0]);
#endif
#ifdef SSE4
ret.v = _mm_set_ps(a[3],a[2],a[1],a[0]);
#endif
#ifdef AVX512
ret.v = _mm512_set_ps( a[15],a[14],a[13],a[12],a[11],a[10],a[9],a[8],
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],a[4],a[5],a[6],a[7]};
#endif
}
////////////////////////////////////////////////////////////////////////
// FIXME: gonna remove these load/store, get, set, prefetch
////////////////////////////////////////////////////////////////////////
friend inline void vstore(const vRealF &ret, float *a){
#if defined (AVX1)|| defined (AVX2)
_mm256_store_ps(a,ret.v);
#endif
#ifdef SSE4
_mm_store_ps(a,ret.v);
#endif
#ifdef AVX512
_mm512_store_ps(a,ret.v);
// Note v has a7 a6 a5ba4 a3 a2 a1 a0
#endif
#ifdef QPX
assert(0);
#endif
}
friend inline void vstream(vRealF &out,const vRealF &in){
#if defined (AVX1)|| defined (AVX2)
_mm256_stream_ps((float *)&out.v,in.v);
#endif
#ifdef SSE4
_mm_stream_ps((float *)&out.v,in.v);
#endif
#ifdef AVX512
_mm512_storenrngo_ps((float *)&out.v,in.v);
// _mm512_stream_ps((float *)&out.v,in.v);
//Note v has a3 a2 a1 a0
#endif
#ifdef QPX
assert(0);
#endif
}
friend inline void prefetch(const vRealF &v)
{
_mm_prefetch((const char*)&v.v,_MM_HINT_T0);
}
// Unary negation
friend inline vRealF operator -(const vRealF &r) {
vRealF ret;
vzero(ret);
ret = ret - r;
return ret;
}
friend inline RealF Reduce(const vRealF & in)
{
vRealF v1,v2;
union {
fvec v;
float f[sizeof(fvec)/sizeof(double)];
} conv;
#ifdef SSE4
permute(v1,in,0); // sse 128; quad single
v1=v1+in;
permute(v2,v1,1);
v1=v1+v2;
#endif
#if defined(AVX1) || defined (AVX2)
permute(v1,in,0); // avx 256; octo-double
v1=v1+in;
permute(v2,v1,1);
v1=v1+v2;
permute(v2,v1,2);
v1=v1+v2;
#endif
#ifdef AVX512
permute(v1,in,0); // avx 256; octo-double
v1=v1+in;
permute(v2,v1,1);
v1=v1+v2;
permute(v2,v1,2);
v1=v1+v2;
permute(v2,v1,3);
v1=v1+v2;
#endif
#ifdef QPX
#endif
conv.v=v1.v;
return conv.f[0];
}
// *=,+=,-= operators
inline vRealF &operator *=(const vRealF &r) {
*this = (*this)*r;
return *this;
}
inline vRealF &operator +=(const vRealF &r) {
*this = *this+r;
return *this;
}
inline vRealF &operator -=(const vRealF &r) {
*this = *this-r;
return *this;
}
public:
static inline int Nsimd(void) { return sizeof(fvec)/sizeof(float);}
};
inline vRealF innerProduct(const vRealF & l, const vRealF & r) { return conjugate(l)*r; }
inline void zeroit(vRealF &z){ vzero(z);}
inline vRealF outerProduct(const vRealF &l, const vRealF& r)
{
return l*r;
}
inline vRealF trace(const vRealF &arg){
return arg;
}
inline vRealF real(const vRealF &arg){
return arg;
}
}
#endif

84
lib/tensors/Tensor_Ta.h
View File

@ -29,15 +29,87 @@ namespace Grid {
{ {
iMatrix<vtype,N> ret(arg); iMatrix<vtype,N> ret(arg);
double factor = (1/(double)N); double factor = (1/(double)N);
for(int c1=0;c1<N;c1++){ ret = (ret - adj(arg))*0.5;
for(int c2=0;c2<N;c2++){
ret._internal[c1][c2]= (ret._internal[c1][c2] - adj(arg._internal[c2][c1]));
ret._internal[c1][c2] *= 0.5;
}}
//ret = (ret - adj(arg))*0.5;
ret -= trace(ret)*factor; ret -= trace(ret)*factor;
return ret; return ret;
} }
///////////////////////////////////////////////
// ProjectOnGroup function for scalar, vector, matrix
///////////////////////////////////////////////
template<class vtype> inline iScalar<vtype> ProjectOnGroup(const iScalar<vtype>&r)
{
iScalar<vtype> ret;
ret._internal = ProjectOnGroup(r._internal);
return ret;
}
template<class vtype,int N> inline iVector<vtype,N> ProjectOnGroup(const iVector<vtype,N>&r)
{
iVector<vtype,N> ret;
for(int i=0;i<N;i++){
ret._internal[i] = ProjectOnGroup(r._internal[i]);
}
return ret;
}
template<class vtype,int N, typename std::enable_if< GridTypeMapper<vtype>::TensorLevel == 0 >::type * =nullptr>
inline iMatrix<vtype,N> ProjectOnGroup(const iMatrix<vtype,N> &arg)
{
// need a check for the group type?
iMatrix<vtype,N> ret(arg);
double nrm;
for(int c1=0;c1<N;c1++){
nrm = 0.0;
for(int c2=0;c2<N;c2++)
nrm = real(innerProduct(ret._internal[c1][c2],ret._internal[c1][c2]));
nrm = 1.0/sqrt(nrm);
for(int c2=0;c2<N;c2++)
ret._internal[c1][c2]*= nrm;
for (int b=c1+1; b<N; ++b){
decltype(ret._internal[b][b]*ret._internal[b][b]) pr = 0.0;
for(int c=0; c<N; ++c)
pr += ret._internal[c1][c]*ret._internal[b][c];
for(int c=0; c<N; ++c){
ret._internal[b][c] -= pr * ret._internal[c1][c];
}
}
}
return ret;
}
///////////////////////////////////////////////
// Exponentiate function for scalar, vector, matrix
///////////////////////////////////////////////
template<class vtype> inline iScalar<vtype> Exponentiate(const iScalar<vtype>&r, double alpha, int Nexp)
{
iScalar<vtype> ret;
ret._internal = Exponentiate(r._internal, alpha, Nexp);
return ret;
}
template<class vtype,int N, typename std::enable_if< GridTypeMapper<vtype>::TensorLevel == 0 >::type * =nullptr>
inline iMatrix<vtype,N> Exponentiate(const iMatrix<vtype,N> &arg, double alpha, int Nexp)
{
iMatrix<vtype,N> unit(1.0);
iMatrix<vtype,N> temp(unit);
for(int i=Nexp; i>=1;--i){
temp *= alpha/double(i);
temp = unit + temp*arg;
}
return ProjectOnGroup(temp);
}
} }
#endif #endif

0
tests/InvSqrt.gnu Normal file
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2
tests/Sqrt.gnu Normal file
View File

@ -0,0 +1,2 @@
f(x) = 6.81384+(-2.34645e-06/(x+0.000228091))+(-1.51593e-05/(x+0.00112084))+(-6.89254e-05/(x+0.003496))+(-0.000288983/(x+0.00954309))+(-0.00119277/(x+0.024928))+(-0.0050183/(x+0.0646627))+(-0.0226449/(x+0.171576))+(-0.123767/(x+0.491792))+(-1.1705/(x+1.78667))+(-102.992/(x+18.4866));
f(x) = 0.14676+(0.00952992/(x+5.40933e-05))+(0.0115952/(x+0.000559699))+(0.0161824/(x+0.00203338))+(0.0243252/(x+0.00582831))+(0.0379533/(x+0.0154649))+(0.060699/(x+0.0401156))+(0.100345/(x+0.104788))+(0.178335/(x+0.286042))+(0.381586/(x+0.892189))+(1.42625/(x+4.38422));

3
tests/Test_main.cc
View File

@ -223,6 +223,9 @@ int main (int argc, char ** argv)
//TComplex tracecm= trace(cm); //TComplex tracecm= trace(cm);
//std::cout << cm << " "<< tracecm << std::endl; //std::cout << cm << " "<< tracecm << std::endl;
cm = ProjectOnGroup(cm);
cm = Exponentiate(cm, 1.0, 10);
// Foo = Foo+scalar; // LatticeColourMatrix+Scalar // Foo = Foo+scalar; // LatticeColourMatrix+Scalar
// Foo = Foo*scalar; // LatticeColourMatrix*Scalar // Foo = Foo*scalar; // LatticeColourMatrix*Scalar