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24087ff3cc08c9ef050165566d25257067744e10
ispc/examples/intrinsics/knc.h
Jean-Luc Duprat 24087ff3cc Expose none() in the ISPC standard library. 
On KNC: all(), any() and none() do not generate a redundant movmsk instruction.
2012-11-27 13:38:28 -08:00

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/*
Copyright (c) 2012, Intel Corporation
All rights reserved.
Redistribution and use in source and binary forms, with or without
modification, are permitted provided that the following conditions are
met:
* Redistributions of source code must retain the above copyright
notice, this list of conditions and the following disclaimer.
* Redistributions in binary form must reproduce the above copyright
notice, this list of conditions and the following disclaimer in the
documentation and/or other materials provided with the distribution.
* Neither the name of Intel Corporation nor the names of its
contributors may be used to endorse or promote products derived from
this software without specific prior written permission.
THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS
IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED
TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A
PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER
OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL,
EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO,
PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR
PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF
LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING
NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS
SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
*/
#include <stdint.h>
#include <math.h>
#include <assert.h>
#include <unistd.h>
#include <algorithm>
#include <immintrin.h>
#include <zmmintrin.h>
#include <iostream> // for operator<<(m512[i])
#include <iomanip> // for operator<<(m512[i])
#ifdef _MSC_VER
#define FORCEINLINE __forceinline
#define PRE_ALIGN(x) /*__declspec(align(x))*/
#define POST_ALIGN(x)
#define roundf(x) (floorf(x + .5f))
#define round(x) (floor(x + .5))
#else
#define FORCEINLINE __attribute__((always_inline))
#define PRE_ALIGN(x)
#define POST_ALIGN(x) __attribute__ ((aligned(x)))
#endif
#define KNC 1
extern "C" {
int printf(const unsigned char *, ...);
int puts(unsigned char *);
unsigned int putchar(unsigned int);
int fflush(void *);
uint8_t *memcpy(uint8_t *, uint8_t *, uint64_t);
uint8_t *memset(uint8_t *, uint8_t, uint64_t);
void memset_pattern16(void *, const void *, uint64_t);
}
typedef float __vec1_f;
typedef double __vec1_d;
typedef int8_t __vec1_i8;
typedef int16_t __vec1_i16;
typedef int32_t __vec1_i32;
typedef int64_t __vec1_i64;
struct __vec16_i32;
typedef struct PRE_ALIGN(2) __vec16_i1 {
FORCEINLINE operator __mmask16() const { return m; }
FORCEINLINE __vec16_i1() { /* FIXME? __mm512_undef_mask(); */ }
FORCEINLINE __vec16_i1(const __mmask16 &in) : m(in) {}
FORCEINLINE __vec16_i1(const __vec16_i32 &in);
FORCEINLINE __vec16_i1(const __vec16_i1 &o) : m(o.m) {}
FORCEINLINE __vec16_i1& operator=(const __vec16_i1 &o) { m = o.m; return *this; }
FORCEINLINE __vec16_i1(uint32_t v00, uint32_t v01, uint32_t v02, uint32_t v03,
uint32_t v04, uint32_t v05, uint32_t v06, uint32_t v07,
uint32_t v08, uint32_t v09, uint32_t v10, uint32_t v11,
uint32_t v12, uint32_t v13, uint32_t v14, uint32_t v15) {
m = (v00) |
((v01) << 1) |
((v02) << 2) |
((v03) << 3) |
((v04) << 4) |
((v05) << 5) |
((v06) << 6) |
((v07) << 7) |
((v08) << 8) |
((v09) << 9) |
((v10) << 10) |
((v11) << 11) |
((v12) << 12) |
((v13) << 13) |
((v14) << 14) |
((v15) << 15);
}
union {
__mmask16 m;
struct {
__mmask8 m1;
__mmask8 m2;
} m8;
};
} POST_ALIGN(2) __vec16_i1;
typedef struct PRE_ALIGN(64) __vec16_f {
FORCEINLINE operator __m512() const { return v; }
FORCEINLINE __vec16_f() : v(_mm512_undefined_ps()) { }
FORCEINLINE __vec16_f(const __m512 &in) : v(in) {}
FORCEINLINE __vec16_f(const __vec16_f &o) : v(o.v) {}
FORCEINLINE __vec16_f& operator =(const __vec16_f &o) { v=o.v; return *this; }
FORCEINLINE __vec16_f(float v00, float v01, float v02, float v03,
float v04, float v05, float v06, float v07,
float v08, float v09, float v10, float v11,
float v12, float v13, float v14, float v15) {
v = _mm512_set_16to16_ps(v15, v14, v13, v12, v11, v10, v09, v08, v07, v06, v05, v04, v03, v02, v01, v00);
}
__m512 v;
} POST_ALIGN(64) __vec16_f;
typedef struct PRE_ALIGN(64) __vec16_d {
FORCEINLINE __vec16_d() : v1(_mm512_undefined_pd()), v2(_mm512_undefined_pd()) {}
FORCEINLINE __vec16_d(const __vec16_d &o) : v1(o.v1), v2(o.v2) {}
FORCEINLINE __vec16_d& operator =(const __vec16_d &o) { v1=o.v1; v2=o.v2; return *this; }
FORCEINLINE __vec16_d(double v00, double v01, double v02, double v03,
double v04, double v05, double v06, double v07,
double v08, double v09, double v10, double v11,
double v12, double v13, double v14, double v15) {
v1 = _mm512_set_8to8_pd(v15, v14, v13, v12, v11, v10, v09, v08);
v2 = _mm512_set_8to8_pd(v07, v06, v05, v04, v03, v02, v01, v00);
}
__m512d v1;
__m512d v2;
} POST_ALIGN(64) __vec16_d;
typedef struct PRE_ALIGN(64) __vec16_i32 {
FORCEINLINE operator __m512i() const { return v; }
FORCEINLINE __vec16_i32() : v(_mm512_undefined_epi32()) {}
FORCEINLINE __vec16_i32(const int32_t &in) : v(_mm512_set1_epi32(in)) {}
FORCEINLINE __vec16_i32(const __m512i &in) : v(in) {}
FORCEINLINE __vec16_i32(const __vec16_i32 &o) : v(o.v) {}
FORCEINLINE __vec16_i32& operator =(const __vec16_i32 &o) { v=o.v; return *this; }
FORCEINLINE __vec16_i32(int32_t v00, int32_t v01, int32_t v02, int32_t v03,
int32_t v04, int32_t v05, int32_t v06, int32_t v07,
int32_t v08, int32_t v09, int32_t v10, int32_t v11,
int32_t v12, int32_t v13, int32_t v14, int32_t v15) {
v = _mm512_set_16to16_pi(v15, v14, v13, v12, v11, v10, v09, v08, v07, v06, v05, v04, v03, v02, v01, v00);
}
__m512i v;
} POST_ALIGN(64) __vec16_i32;
FORCEINLINE __vec16_i1::__vec16_i1(const __vec16_i32 &in) {
m = _mm512_test_epi32_mask(in, in);
}
typedef struct PRE_ALIGN(64) __vec16_i64 {
FORCEINLINE __vec16_i64() : v_lo(_mm512_undefined_epi32()), v_hi(_mm512_undefined_epi32()) {}
FORCEINLINE __vec16_i64(const __vec16_i64 &o) : v_lo(o.v_lo), v_hi(o.v_hi) {}
FORCEINLINE __vec16_i64(__m512i l, __m512i h) : v_lo(l), v_hi(h) {}
FORCEINLINE __vec16_i64& operator =(const __vec16_i64 &o) { v_lo=o.v_lo; v_hi=o.v_hi; return *this; }
FORCEINLINE __vec16_i64(int64_t v00, int64_t v01, int64_t v02, int64_t v03,
int64_t v04, int64_t v05, int64_t v06, int64_t v07,
int64_t v08, int64_t v09, int64_t v10, int64_t v11,
int64_t v12, int64_t v13, int64_t v14, int64_t v15) {
__m512i v1 = _mm512_set_8to8_epi64(v15, v14, v13, v12, v11, v10, v09, v08);
__m512i v2 = _mm512_set_8to8_epi64(v07, v06, v05, v04, v03, v02, v01, v00);
v_hi = _mm512_mask_permutevar_epi32(v_hi, 0xFF00,
_mm512_set_16to16_pi(15,13,11,9,7,5,3,1,14,12,10,8,6,4,2,0),
v1);
v_hi = _mm512_mask_permutevar_epi32(v_hi, 0x00FF,
_mm512_set_16to16_pi(14,12,10,8,6,4,2,0,15,13,11,9,7,5,3,1),
v2);
v_lo = _mm512_mask_permutevar_epi32(v_lo, 0xFF00,
_mm512_set_16to16_pi(14,12,10,8,6,4,2,0,15,13,11,9,7,5,3,1),
v1);
v_lo = _mm512_mask_permutevar_epi32(v_lo, 0x00FF,
_mm512_set_16to16_pi(15,13,11,9,7,5,3,1,14,12,10,8,6,4,2,0),
v2);
}
__m512i v_hi;
__m512i v_lo;
} POST_ALIGN(64) __vec16_i64;
template <typename T>
struct vec16 {
FORCEINLINE vec16() { }
FORCEINLINE vec16(T v0, T v1, T v2, T v3, T v4, T v5, T v6, T v7,
T v8, T v9, T v10, T v11, T v12, T v13, T v14, T v15) {
v[0] = v0; v[1] = v1; v[2] = v2; v[3] = v3;
v[4] = v4; v[5] = v5; v[6] = v6; v[7] = v7;
v[8] = v8; v[9] = v9; v[10] = v10; v[11] = v11;
v[12] = v12; v[13] = v13; v[14] = v14; v[15] = v15;
}
T v[16];
};
PRE_ALIGN(16) struct __vec16_i8 : public vec16<int8_t> {
FORCEINLINE __vec16_i8() { }
FORCEINLINE __vec16_i8(const __vec16_i8 &o);
FORCEINLINE __vec16_i8& operator =(const __vec16_i8 &o);
FORCEINLINE __vec16_i8(int8_t v0, int8_t v1, int8_t v2, int8_t v3,
int8_t v4, int8_t v5, int8_t v6, int8_t v7,
int8_t v8, int8_t v9, int8_t v10, int8_t v11,
int8_t v12, int8_t v13, int8_t v14, int8_t v15)
: vec16<int8_t>(v0, v1, v2, v3, v4, v5, v6, v7,
v8, v9, v10, v11, v12, v13, v14, v15) { }
} POST_ALIGN(16);
PRE_ALIGN(32) struct __vec16_i16 : public vec16<int16_t> {
FORCEINLINE __vec16_i16() { }
FORCEINLINE __vec16_i16(const __vec16_i16 &o);
FORCEINLINE __vec16_i16& operator =(const __vec16_i16 &o);
FORCEINLINE __vec16_i16(int16_t v0, int16_t v1, int16_t v2, int16_t v3,
int16_t v4, int16_t v5, int16_t v6, int16_t v7,
int16_t v8, int16_t v9, int16_t v10, int16_t v11,
int16_t v12, int16_t v13, int16_t v14, int16_t v15)
: vec16<int16_t>(v0, v1, v2, v3, v4, v5, v6, v7,
v8, v9, v10, v11, v12, v13, v14, v15) { }
} POST_ALIGN(32);
///////////////////////////////////////////////////////////////////////////
// debugging helpers
//
inline std::ostream &operator<<(std::ostream &out, const __m512i &v)
{
out << "[";
for (int i=0;i<16;i++)
out << (i?",":"") << std::dec << std::setw(8) << ((int*)&v)[i] << std::dec;
// out << (i?",":"") << std::hex << std::setw(8) << ((int*)&v)[i] << std::dec;
out << "]" << std::flush;
return out;
}
inline std::ostream &operator<<(std::ostream &out, const __m512 &v)
{
out << "[";
for (int i=0;i<16;i++)
out << (i?",":"") << ((float*)&v)[i];
out << "]" << std::flush;
return out;
}
///////////////////////////////////////////////////////////////////////////
// macros...
FORCEINLINE __vec16_i8::__vec16_i8(const __vec16_i8 &o)
{
for (int i=0;i<16;i++)
v[i] = o.v[i];
}
FORCEINLINE __vec16_i8& __vec16_i8::operator=(const __vec16_i8 &o)
{
for (int i=0;i<16;i++)
v[i] = o.v[i];
return *this;
}
///////////////////////////////////////////////////////////////////////////
// macros...
#define UNARY_OP(TYPE, NAME, OP)
/*
static FORCEINLINE TYPE NAME(TYPE v) { \
TYPE ret; \
for (int i = 0; i < 16; ++i) \
ret.v[i] = OP(v.v[i]); \
return ret; \
}
*/
#define BINARY_OP(TYPE, NAME, OP)
/*
static FORCEINLINE TYPE NAME(TYPE a, TYPE b) { \
TYPE ret; \
for (int i = 0; i < 16; ++i) \
ret.v[i] = a.v[i] OP b.v[i]; \
return ret; \
}
*/
#define BINARY_OP_CAST(TYPE, CAST, NAME, OP)
/*
static FORCEINLINE TYPE NAME(TYPE a, TYPE b) { \
TYPE ret; \
for (int i = 0; i < 16; ++i) \
ret.v[i] = (CAST)(a.v[i]) OP (CAST)(b.v[i]); \
return ret; \
}
*/
#define BINARY_OP_FUNC(TYPE, NAME, FUNC)
/*
static FORCEINLINE TYPE NAME(TYPE a, TYPE b) { \
TYPE ret; \
for (int i = 0; i < 16; ++i) \
ret.v[i] = FUNC(a.v[i], b.v[i]); \
return ret; \
}
*/
#define CMP_OP(TYPE, SUFFIX, CAST, NAME, OP)
/*
static FORCEINLINE __vec16_i1 NAME##_##SUFFIX(TYPE a, TYPE b) { \
__vec16_i1 ret; \
ret.v = 0; \
for (int i = 0; i < 16; ++i) \
ret.v |= ((CAST)(a.v[i]) OP (CAST)(b.v[i])) << i; \
return ret; \
}
*/
#define INSERT_EXTRACT(VTYPE, STYPE)
/*
static FORCEINLINE STYPE __extract_element(VTYPE v, int index) { \
return ((STYPE *)&v)[index]; \
} \
static FORCEINLINE void __insert_element(VTYPE *v, int index, STYPE val) { \
((STYPE *)v)[index] = val; \
}
*/
#define LOAD_STORE(VTYPE, STYPE)
/*
static FORCEINLINE VTYPE __load(VTYPE *p, int align) { \
STYPE *ptr = (STYPE *)p; \
VTYPE ret; \
for (int i = 0; i < 16; ++i) \
ret.v[i] = ptr[i]; \
return ret; \
} \
static FORCEINLINE void __store(VTYPE *p, VTYPE v, int align) { \
STYPE *ptr = (STYPE *)p; \
for (int i = 0; i < 16; ++i) \
ptr[i] = v.v[i]; \
}
*/
#define REDUCE_ADD(TYPE, VTYPE, NAME)
/*
static FORCEINLINE TYPE NAME(VTYPE v) { \
TYPE ret = v.v[0]; \
for (int i = 1; i < 16; ++i) \
ret = ret + v.v[i]; \
return ret; \
}
*/
#define REDUCE_MINMAX(TYPE, VTYPE, NAME, OP)
/*
static FORCEINLINE TYPE NAME(VTYPE v) { \
TYPE ret = v.v[0]; \
for (int i = 1; i < 16; ++i) \
ret = (ret OP (TYPE)v.v[i]) ? ret : (TYPE)v.v[i]; \
return ret; \
}
*/
#define SELECT(TYPE)
/*
static FORCEINLINE TYPE __select(__vec16_i1 mask, TYPE a, TYPE b) { \
TYPE ret; \
for (int i = 0; i < 16; ++i) \
ret.v[i] = (mask.v & (1<<i)) ? a.v[i] : b.v[i]; \
return ret; \
} \
static FORCEINLINE TYPE __select(bool cond, TYPE a, TYPE b) { \
return cond ? a : b; \
}
*/
#define SHIFT_UNIFORM(TYPE, CAST, NAME, OP)
/*
static FORCEINLINE TYPE NAME(TYPE a, int32_t b) { \
TYPE ret; \
for (int i = 0; i < 16; ++i) \
ret.v[i] = (CAST)(a.v[i]) OP b; \
return ret; \
}
*/
#define SMEAR(VTYPE, NAME, STYPE)
/*
static FORCEINLINE VTYPE __smear_##NAME(STYPE v) { \
VTYPE ret; \
for (int i = 0; i < 16; ++i) \
ret.v[i] = v; \
return ret; \
} \
*/
#define BROADCAST(VTYPE, NAME, STYPE)
/*
static FORCEINLINE VTYPE __broadcast_##NAME(VTYPE v, int index) { \
VTYPE ret; \
for (int i = 0; i < 16; ++i) \
ret.v[i] = v.v[index & 0xf]; \
return ret; \
} \
*/
#define ROTATE(VTYPE, NAME, STYPE)
/*
static FORCEINLINE VTYPE __rotate_##NAME(VTYPE v, int index) { \
VTYPE ret; \
for (int i = 0; i < 16; ++i) \
ret.v[i] = v.v[(i+index) & 0xf]; \
return ret; \
} \
*/
#define SHUFFLES(VTYPE, NAME, STYPE)
/*
static FORCEINLINE VTYPE __shuffle_##NAME(VTYPE v, __vec16_i32 index) { \
VTYPE ret; \
for (int i = 0; i < 16; ++i) \
ret.v[i] = v.v[__extract_element(index, i) & 0xf]; \
return ret; \
} \
static FORCEINLINE VTYPE __shuffle2_##NAME(VTYPE v0, VTYPE v1, __vec16_i32 index) { \
VTYPE ret; \
for (int i = 0; i < 16; ++i) { \
int ii = __extract_element(index, i) & 0x1f; \
ret.v[i] = (ii < 16) ? v0.v[ii] : v1.v[ii-16]; \
} \
return ret; \
}
*/
///////////////////////////////////////////////////////////////////////////
static FORCEINLINE int8_t __extract_element(__vec1_i8 v, int index) { return ((int8_t *)&v)[index]; }
static FORCEINLINE void __insert_element(__vec1_i8 *v, int index, int8_t val) { ((int8_t *)v)[index] = val; }
static FORCEINLINE int16_t __extract_element(__vec1_i16 v, int index) { return ((int16_t *)&v)[index]; }
static FORCEINLINE void __insert_element(__vec1_i16 *v, int index, int16_t val) { ((int16_t *)v)[index] = val; }
static FORCEINLINE int32_t __extract_element(__vec1_i32 v, int index) { return ((int32_t *)&v)[index]; }
static FORCEINLINE void __insert_element(__vec1_i32 *v, int index, int32_t val) { ((int32_t *)v)[index] = val; }
static FORCEINLINE int64_t __extract_element(__vec1_i64 v, int index) { return ((int64_t *)&v)[index]; }
static FORCEINLINE void __insert_element(__vec1_i64 *v, int index, int64_t val) { ((int64_t *)v)[index] = val; }
static FORCEINLINE float __extract_element(__vec1_f v, int index) { return ((float *)&v)[index]; }
static FORCEINLINE void __insert_element(__vec1_f *v, int index, float val) { ((float *)v)[index] = val; }
static FORCEINLINE double __extract_element(__vec1_d v, int index) { return ((double *)&v)[index]; }
static FORCEINLINE void __insert_element(__vec1_d *v, int index, double val) { ((double *)v)[index] = val; }
///////////////////////////////////////////////////////////////////////////
// mask ops
static FORCEINLINE __vec16_i1 __movmsk(__vec16_i1 mask) {
return _mm512_kmov(mask);
}
static FORCEINLINE bool __any(__vec16_i1 mask) {
return !_mm512_kortestz(mask, mask);
}
static FORCEINLINE bool __all(__vec16_i1 mask) {
return _mm512_kortestc(mask, mask);
}
static FORCEINLINE bool __none(__vec16_i1 mask) {
return _mm512_kortestz(mask, mask);
}
static FORCEINLINE __vec16_i1 __equal_i1(__vec16_i1 a, __vec16_i1 b) {
return _mm512_knot( _mm512_kandn(a, b));
}
static FORCEINLINE __vec16_i1 __and(__vec16_i1 a, __vec16_i1 b) {
return _mm512_kand(a, b);
}
static FORCEINLINE __vec16_i1 __not(__vec16_i1 a) {
return _mm512_knot(a);
}
static FORCEINLINE __vec16_i1 __and_not1(__vec16_i1 a, __vec16_i1 b) {
return _mm512_kandn(a, b);
}
static FORCEINLINE __vec16_i1 __and_not2(__vec16_i1 a, __vec16_i1 b) {
return _mm512_kandnr(a, b);
}
static FORCEINLINE __vec16_i1 __xor(__vec16_i1 a, __vec16_i1 b) {
return _mm512_kxor(a, b);
}
static FORCEINLINE __vec16_i1 __xnor(__vec16_i1 a, __vec16_i1 b) {
return _mm512_kxnor(a, b);
}
static FORCEINLINE __vec16_i1 __or(__vec16_i1 a, __vec16_i1 b) {
return _mm512_kor(a, b);
}
static FORCEINLINE __vec16_i1 __select(__vec16_i1 mask, __vec16_i1 a,
__vec16_i1 b) {
return ((a.m & mask.m) | (b.m & ~mask.m));
//return __or(__and(a, mask), __andnr(b, mask));
}
static FORCEINLINE __vec16_i1 __select(bool cond, __vec16_i1 a, __vec16_i1 b) {
return cond ? a : b;
}
/*
static FORCEINLINE bool __extract_element(__vec16_i1 vec, int index) {
return (vec.v & (1 << index)) ? true : false;
}
static FORCEINLINE void __insert_element(__vec16_i1 *vec, int index,
bool val) {
if (val == false)
vec->v &= ~(1 << index);
else
vec->v |= (1 << index);
}
*/
template <int ALIGN> static FORCEINLINE __vec16_i1 __load(const __vec16_i1 *p) {
const uint16_t *ptr = (const uint16_t *)p;
__vec16_i1 r;
r.m = *ptr;
return r;
}
template <int ALIGN> static FORCEINLINE void __store(__vec16_i1 *p, __vec16_i1 v) {
uint16_t *ptr = (uint16_t *)p;
*ptr = v.m;
}
template <class RetVecType> RetVecType __smear_i1(int i);
template <> static FORCEINLINE __vec16_i1 __smear_i1<__vec16_i1>(int i) {
return i?0xFFFF:0x0;
}
template <class RetVecType> RetVecType __setzero_i1();
template <> static FORCEINLINE __vec16_i1 __setzero_i1<__vec16_i1>() {
return 0;
}
template <class RetVecType> RetVecType __undef_i1();
template <> static FORCEINLINE __vec16_i1 __undef_i1<__vec16_i1>() {
return __vec16_i1();
}
///////////////////////////////////////////////////////////////////////////
// int8
BINARY_OP(__vec16_i8, __add, +)
BINARY_OP(__vec16_i8, __sub, -)
BINARY_OP(__vec16_i8, __mul, *)
BINARY_OP(__vec16_i8, __or, |)
BINARY_OP(__vec16_i8, __and, &)
BINARY_OP(__vec16_i8, __xor, ^)
BINARY_OP(__vec16_i8, __shl, <<)
BINARY_OP_CAST(__vec16_i8, uint8_t, __udiv, /)
BINARY_OP_CAST(__vec16_i8, int8_t, __sdiv, /)
BINARY_OP_CAST(__vec16_i8, uint8_t, __urem, %)
BINARY_OP_CAST(__vec16_i8, int8_t, __srem, %)
BINARY_OP_CAST(__vec16_i8, uint8_t, __lshr, >>)
BINARY_OP_CAST(__vec16_i8, int8_t, __ashr, >>)
SHIFT_UNIFORM(__vec16_i8, uint8_t, __lshr, >>)
SHIFT_UNIFORM(__vec16_i8, int8_t, __ashr, >>)
SHIFT_UNIFORM(__vec16_i8, int8_t, __shl, <<)
CMP_OP(__vec16_i8, i8, int8_t, __equal, ==)
CMP_OP(__vec16_i8, i8, int8_t, __not_equal, !=)
CMP_OP(__vec16_i8, i8, uint8_t, __unsigned_less_equal, <=)
CMP_OP(__vec16_i8, i8, int8_t, __signed_less_equal, <=)
CMP_OP(__vec16_i8, i8, uint8_t, __unsigned_greater_equal, >=)
CMP_OP(__vec16_i8, i8, int8_t, __signed_greater_equal, >=)
CMP_OP(__vec16_i8, i8, uint8_t, __unsigned_less_than, <)
CMP_OP(__vec16_i8, i8, int8_t, __signed_less_than, <)
CMP_OP(__vec16_i8, i8, uint8_t, __unsigned_greater_than, >)
CMP_OP(__vec16_i8, i8, int8_t, __signed_greater_than, >)
SELECT(__vec16_i8)
INSERT_EXTRACT(__vec16_i8, int8_t)
SMEAR(__vec16_i8, i8, int8_t)
BROADCAST(__vec16_i8, i8, int8_t)
ROTATE(__vec16_i8, i8, int8_t)
SHUFFLES(__vec16_i8, i8, int8_t)
LOAD_STORE(__vec16_i8, int8_t)
///////////////////////////////////////////////////////////////////////////
// int16
BINARY_OP(__vec16_i16, __add, +)
BINARY_OP(__vec16_i16, __sub, -)
BINARY_OP(__vec16_i16, __mul, *)
BINARY_OP(__vec16_i16, __or, |)
BINARY_OP(__vec16_i16, __and, &)
BINARY_OP(__vec16_i16, __xor, ^)
BINARY_OP(__vec16_i16, __shl, <<)
BINARY_OP_CAST(__vec16_i16, uint16_t, __udiv, /)
BINARY_OP_CAST(__vec16_i16, int16_t, __sdiv, /)
BINARY_OP_CAST(__vec16_i16, uint16_t, __urem, %)
BINARY_OP_CAST(__vec16_i16, int16_t, __srem, %)
BINARY_OP_CAST(__vec16_i16, uint16_t, __lshr, >>)
BINARY_OP_CAST(__vec16_i16, int16_t, __ashr, >>)
SHIFT_UNIFORM(__vec16_i16, uint16_t, __lshr, >>)
SHIFT_UNIFORM(__vec16_i16, int16_t, __ashr, >>)
SHIFT_UNIFORM(__vec16_i16, int16_t, __shl, <<)
CMP_OP(__vec16_i16, i16, int16_t, __equal, ==)
CMP_OP(__vec16_i16, i16, int16_t, __not_equal, !=)
CMP_OP(__vec16_i16, i16, uint16_t, __unsigned_less_equal, <=)
CMP_OP(__vec16_i16, i16, int16_t, __signed_less_equal, <=)
CMP_OP(__vec16_i16, i16, uint16_t, __unsigned_greater_equal, >=)
CMP_OP(__vec16_i16, i16, int16_t, __signed_greater_equal, >=)
CMP_OP(__vec16_i16, i16, uint16_t, __unsigned_less_than, <)
CMP_OP(__vec16_i16, i16, int16_t, __signed_less_than, <)
CMP_OP(__vec16_i16, i16, uint16_t, __unsigned_greater_than, >)
CMP_OP(__vec16_i16, i16, int16_t, __signed_greater_than, >)
SELECT(__vec16_i16)
INSERT_EXTRACT(__vec16_i16, int16_t)
SMEAR(__vec16_i16, i16, int16_t)
BROADCAST(__vec16_i16, i16, int16_t)
ROTATE(__vec16_i16, i16, int16_t)
SHUFFLES(__vec16_i16, i16, int16_t)
LOAD_STORE(__vec16_i16, int16_t)
///////////////////////////////////////////////////////////////////////////
// int32
static FORCEINLINE __vec16_i32 __add(__vec16_i32 a, __vec16_i32 b) {
return _mm512_add_epi32(a, b);
}
static FORCEINLINE __vec16_i32 __sub(__vec16_i32 a, __vec16_i32 b) {
return _mm512_sub_epi32(a, b);
}
static FORCEINLINE __vec16_i32 __mul(__vec16_i32 a, __vec16_i32 b) {
return _mm512_mullo_epi32(a, b);
}
static FORCEINLINE __vec16_i32 __udiv(__vec16_i32 a, __vec16_i32 b) {
return _mm512_div_epu32(a, b);
}
static FORCEINLINE __vec16_i32 __sdiv(__vec16_i32 a, __vec16_i32 b) {
return _mm512_div_epi32(a, b);
}
static FORCEINLINE __vec16_i32 __urem(__vec16_i32 a, __vec16_i32 b) {
return _mm512_rem_epu32(a, b);
}
static FORCEINLINE __vec16_i32 __srem(__vec16_i32 a, __vec16_i32 b) {
return _mm512_rem_epi32(a, b);
}
static FORCEINLINE __vec16_i32 __or(__vec16_i32 a, __vec16_i32 b) {
return _mm512_or_epi32(a, b);
}
static FORCEINLINE __vec16_i32 __and(__vec16_i32 a, __vec16_i32 b) {
return _mm512_and_epi32(a, b);
}
static FORCEINLINE __vec16_i32 __xor(__vec16_i32 a, __vec16_i32 b) {
return _mm512_xor_epi32(a, b);
}
static FORCEINLINE __vec16_i32 __shl(__vec16_i32 a, __vec16_i32 b) {
return _mm512_sllv_epi32(a, b);
}
static FORCEINLINE __vec16_i32 __lshr(__vec16_i32 a, __vec16_i32 b) {
return _mm512_srlv_epi32(a, b);
}
static FORCEINLINE __vec16_i32 __ashr(__vec16_i32 a, __vec16_i32 b) {
return _mm512_srav_epi32(a, b);
}
static FORCEINLINE __vec16_i32 __shl(__vec16_i32 a, int32_t n) {
return _mm512_slli_epi32(a, n);
}
static FORCEINLINE __vec16_i32 __lshr(__vec16_i32 a, int32_t n) {
return _mm512_srli_epi32(a, n);
}
static FORCEINLINE __vec16_i32 __ashr(__vec16_i32 a, int32_t n) {
return _mm512_srai_epi32(a, n);
}
static FORCEINLINE __vec16_i1 __equal_i32(const __vec16_i32 &a, const __vec16_i32 &b) {
return _mm512_cmpeq_epi32_mask(a, b);
}
static FORCEINLINE __vec16_i1 __equal_i32_and_mask(const __vec16_i32 &a, const __vec16_i32 &b,
__vec16_i1 m) {
return _mm512_mask_cmpeq_epi32_mask(m, a, b);
}
static FORCEINLINE __vec16_i1 __not_equal_i32(__vec16_i32 a, __vec16_i32 b) {
return _mm512_cmpneq_epi32_mask(a, b);
}
static FORCEINLINE __vec16_i1 __not_equal_i32_and_mask(__vec16_i32 a, __vec16_i32 b,
__vec16_i1 m) {
return _mm512_mask_cmpneq_epi32_mask(m, a, b);
}
static FORCEINLINE __vec16_i1 __unsigned_less_equal_i32(__vec16_i32 a, __vec16_i32 b) {
return _mm512_cmple_epu32_mask(a, b);
}
static FORCEINLINE __vec16_i1 __unsigned_less_equal_i32_and_mask(__vec16_i32 a, __vec16_i32 b,
__vec16_i1 m) {
return _mm512_mask_cmple_epu32_mask(m, a, b);
}
static FORCEINLINE __vec16_i1 __signed_less_equal_i32(__vec16_i32 a, __vec16_i32 b) {
return _mm512_cmple_epi32_mask(a, b);
}
static FORCEINLINE __vec16_i1 __signed_less_equal_i32_and_mask(__vec16_i32 a, __vec16_i32 b,
__vec16_i1 m) {
return _mm512_mask_cmple_epi32_mask(m, a, b);
}
static FORCEINLINE __vec16_i1 __unsigned_greater_equal_i32(__vec16_i32 a, __vec16_i32 b) {
return _mm512_cmpge_epu32_mask(a, b);
}
static FORCEINLINE __vec16_i1 __unsigned_greater_equal_i32_and_mask(__vec16_i32 a, __vec16_i32 b,
__vec16_i1 m) {
return _mm512_mask_cmpge_epu32_mask(m, a, b);
}
static FORCEINLINE __vec16_i1 __signed_greater_equal_i32(__vec16_i32 a, __vec16_i32 b) {
return _mm512_cmpge_epi32_mask(a, b);
}
static FORCEINLINE __vec16_i1 __signed_greater_equal_i32_and_mask(__vec16_i32 a, __vec16_i32 b,
__vec16_i1 m) {
return _mm512_mask_cmpge_epi32_mask(m, a, b);
}
static FORCEINLINE __vec16_i1 __unsigned_less_than_i32(__vec16_i32 a, __vec16_i32 b) {
return _mm512_cmplt_epu32_mask(a, b);
}
static FORCEINLINE __vec16_i1 __unsigned_less_than_i32_and_mask(__vec16_i32 a, __vec16_i32 b,
__vec16_i1 m) {
return _mm512_mask_cmplt_epu32_mask(m, a, b);
}
static FORCEINLINE __vec16_i1 __signed_less_than_i32(__vec16_i32 a, __vec16_i32 b) {
return _mm512_cmplt_epi32_mask(a, b);
}
static FORCEINLINE __vec16_i1 __signed_less_than_i32_and_mask(__vec16_i32 a, __vec16_i32 b,
__vec16_i1 m) {
return _mm512_mask_cmplt_epi32_mask(m, a, b);
}
static FORCEINLINE __vec16_i1 __unsigned_greater_than_i32(__vec16_i32 a, __vec16_i32 b) {
return _mm512_cmpgt_epu32_mask(a, b);
}
static FORCEINLINE __vec16_i1 __unsigned_greater_than_i32_and_mask(__vec16_i32 a, __vec16_i32 b,
__vec16_i1 m) {
return _mm512_mask_cmpgt_epu32_mask(m, a, b);
}
static FORCEINLINE __vec16_i1 __signed_greater_than_i32(__vec16_i32 a, __vec16_i32 b) {
return _mm512_cmpgt_epi32_mask(a, b);
}
static FORCEINLINE __vec16_i1 __signed_greater_than_i32_and_mask(__vec16_i32 a, __vec16_i32 b,
__vec16_i1 m) {
return _mm512_mask_cmpgt_epi32_mask(m, a, b);
}
static FORCEINLINE __vec16_i32 __select(__vec16_i1 mask,
__vec16_i32 a, __vec16_i32 b) {
return _mm512_mask_mov_epi32(b.v, mask.m, a.v);
}
static FORCEINLINE __vec16_i32 __select(bool cond, __vec16_i32 a, __vec16_i32 b) {
return cond ? a : b;
}
static FORCEINLINE int32_t __extract_element(__vec16_i32 v, unsigned int index) {
return ((int32_t *)&v)[index];
}
static FORCEINLINE void __insert_element(__vec16_i32 *v, unsigned int index, int32_t val) {
((int32_t *)v)[index] = val;
}
template <class RetVecType> RetVecType __smear_i32(int32_t i);
template <> static FORCEINLINE __vec16_i32 __smear_i32<__vec16_i32>(int32_t i) {
return _mm512_set1_epi32(i);
}
static const __vec16_i32 __ispc_one = __smear_i32<__vec16_i32>(1);
static const __vec16_i32 __ispc_thirty_two = __smear_i32<__vec16_i32>(32);
static const __vec16_i32 __ispc_ffffffff = __smear_i32<__vec16_i32>(-1);
static const __vec16_i32 __ispc_stride1(0, 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15);
template <class RetVecType> RetVecType __setzero_i32();
template <> static FORCEINLINE __vec16_i32 __setzero_i32<__vec16_i32>() {
return _mm512_setzero_epi32();
}
template <class RetVecType> RetVecType __undef_i32();
template <> static FORCEINLINE __vec16_i32 __undef_i32<__vec16_i32>() {
return __vec16_i32();
}
static FORCEINLINE __vec16_i32 __broadcast_i32(__vec16_i32 v, int index) {
int32_t val = __extract_element(v, index & 0xf);
return _mm512_set1_epi32(val);
}
static FORCEINLINE __vec16_i32 __rotate_i32(__vec16_i32 v, int index) {
__vec16_i32 idx = __smear_i32<__vec16_i32>(index);
__vec16_i32 shuffle = _mm512_and_epi32(_mm512_add_epi32(__ispc_stride1, idx), __smear_i32<__vec16_i32>(0x7));
return _mm512_mask_permutevar_epi32(v, 0xffff, shuffle, v);
}
static FORCEINLINE __vec16_i32 __shuffle_i32(__vec16_i32 v, __vec16_i32 index) {
return _mm512_mask_permutevar_epi32(v, 0xffff, index, v);
}
/*
static FORCEINLINE __vec16_i32 __shuffle2_i32(__vec16_i32 v0, __vec16_i32 v1, __vec16_i32 index) {
__vec16_i32 ret; for (int i = 0; i < 16; ++i) { int ii = __extract_element(index, i) & 0x1f; ret.v[i] = (ii < 16) ? v0.v[ii] : v1.v[ii-16]; } return ret;
}
*/
template <int ALIGN> static FORCEINLINE __vec16_i32 __load(const __vec16_i32 *p) {
#ifdef ISPC_FORCE_ALIGNED_MEMORY
return _mm512_load_epi32(p);
#else
__vec16_i32 v;
v = _mm512_extloadunpacklo_epi32(v, p, _MM_UPCONV_EPI32_NONE, _MM_HINT_NONE);
v = _mm512_extloadunpackhi_epi32(v, (uint8_t*)p+64, _MM_UPCONV_EPI32_NONE, _MM_HINT_NONE);
return v;
#endif
}
template <> static FORCEINLINE __vec16_i32 __load<64>(const __vec16_i32 *p) {
return _mm512_load_epi32(p);
}
template <int ALIGN> static FORCEINLINE void __store(__vec16_i32 *p, __vec16_i32 v) {
#ifdef ISPC_FORCE_ALIGNED_MEMORY
_mm512_store_epi32(p, v);
#else
_mm512_extpackstorelo_epi32(p, v, _MM_DOWNCONV_EPI32_NONE, _MM_HINT_NONE);
_mm512_extpackstorehi_epi32((uint8_t*)p+64, v, _MM_DOWNCONV_EPI32_NONE, _MM_HINT_NONE);
#endif
}
template <> static FORCEINLINE void __store<64>(__vec16_i32 *p, __vec16_i32 v) {
_mm512_store_epi32(p, v);
}
///////////////////////////////////////////////////////////////////////////
// int64
static FORCEINLINE int64_t __extract_element(__vec16_i64 v, unsigned int index) {
return (uint64_t(((int32_t *)&v.v_hi)[index])<<32) | (uint64_t(((int32_t *)&v.v_lo)[index]));
}
static FORCEINLINE void __insert_element(__vec16_i64 *v, unsigned int index, int64_t val) {
((int32_t *)&v->v_hi)[index] = val>>32;
((int32_t *)&v->v_lo)[index] = val;
}
template <class RetVecType> RetVecType __setzero_i64();
template <> static FORCEINLINE __vec16_i64 __setzero_i64<__vec16_i64>() {
__vec16_i64 ret;
ret.v_lo = _mm512_setzero_epi32();
ret.v_hi = _mm512_setzero_epi32();
return ret;
}
template <class RetVecType> RetVecType __undef_i64();
template <> static FORCEINLINE __vec16_i64 __undef_i64<__vec16_i64>() {
return __vec16_i64();
}
static FORCEINLINE __vec16_i64 __add(const __vec16_i64 &a, const __vec16_i64 &b)
{
__mmask16 carry = 0;
__m512i lo = _mm512_addsetc_epi32(a.v_lo, b.v_lo, &carry);
__m512i hi = _mm512_adc_epi32(a.v_hi, carry, b.v_hi, &carry);
return __vec16_i64(lo, hi);
}
static FORCEINLINE __vec16_i64 __sub(const __vec16_i64 &a, const __vec16_i64 &b)
{
__mmask16 borrow = 0;
__m512i lo = _mm512_subsetb_epi32(a.v_lo, b.v_lo, &borrow);
__m512i hi = _mm512_sbb_epi32(a.v_hi, borrow, b.v_hi, &borrow);
return __vec16_i64(lo, hi);
}
/*! 64x32 bit mul -- address computations often use a scale that we
know is 32 bits; and 32x64 is faster than 64x64 */
static FORCEINLINE __vec16_i64 __mul(const __vec16_i32 &a, const __vec16_i64 &b)
{
return __vec16_i64(_mm512_mullo_epi32(a.v,b.v_lo),
_mm512_add_epi32(_mm512_mullo_epi32(a.v, b.v_hi),
_mm512_mulhi_epi32(a.v, b.v_lo)));
}
static FORCEINLINE __vec16_i64 __mul(const __vec16_i64 &a, const __vec16_i64 &b)
{
__vec16_i32 lo = _mm512_mullo_epi32(a.v_lo,b.v_lo);
__vec16_i32 hi_m1 = _mm512_mulhi_epi32(a.v_lo, b.v_lo);
__vec16_i32 hi_m2 = _mm512_mullo_epi32(a.v_hi, b.v_lo);
__vec16_i32 hi_m3 = _mm512_mullo_epi32(a.v_lo, b.v_hi);
__mmask16 carry = 0;
__vec16_i32 hi_p23 = _mm512_addsetc_epi32(hi_m2, hi_m1, &carry);
__vec16_i32 hi = _mm512_adc_epi32(hi_m3, carry, hi_p23, &carry);
return __vec16_i64(lo, hi);
}
static FORCEINLINE __vec16_i64 __sdiv(const __vec16_i64 &a, const __vec16_i64 &b)
{
__vec16_i64 ret;
for(int i=0; i<16; i++) {
int64_t dividend = __extract_element(a, i);
int64_t divisor = __extract_element(b, i);
int64_t quotient = dividend / divisor; // SVML
__insert_element(&ret, i, quotient);
}
return ret;
}
static FORCEINLINE __vec16_i64 __udiv(const __vec16_i64 &a, const __vec16_i64 &b)
{
__vec16_i64 ret;
for(int i=0; i<16; i++) {
uint64_t dividend = __extract_element(a, i);
uint64_t divisor = __extract_element(b, i);
uint64_t quotient = dividend / divisor; // SVML
__insert_element(&ret, i, quotient);
}
return ret;
}
static FORCEINLINE __vec16_i64 __or(__vec16_i64 a, __vec16_i64 b) {
return __vec16_i64(_mm512_or_epi32(a.v_lo, b.v_lo), _mm512_or_epi32(a.v_hi, b.v_hi));
}
static FORCEINLINE __vec16_i64 __and(__vec16_i64 a, __vec16_i64 b) {
return __vec16_i64(_mm512_and_epi32(a.v_lo, b.v_lo), _mm512_and_epi32(a.v_hi, b.v_hi));
}
static FORCEINLINE __vec16_i64 __xor(__vec16_i64 a, __vec16_i64 b) {
return __vec16_i64(_mm512_xor_epi32(a.v_lo, b.v_lo), _mm512_xor_epi32(a.v_hi, b.v_hi));
}
static FORCEINLINE __vec16_i64 __shl(__vec16_i64 a, __vec16_i64 b) {
__vec16_i32 xfer = _mm512_srlv_epi32(a.v_lo, _mm512_sub_epi32(__ispc_thirty_two, b.v_lo));
__vec16_i32 hi = _mm512_or_epi32(_mm512_sllv_epi32(a.v_hi, b.v_lo), xfer);
__vec16_i32 lo = _mm512_sllv_epi32(a.v_lo, b.v_lo);
return __vec16_i64(lo, hi);
}
static FORCEINLINE __vec16_i64 __lshr(__vec16_i64 a, __vec16_i64 b) {
__vec16_i32 shift = _mm512_sub_epi32(__ispc_thirty_two, b.v_lo);
__vec16_i32 xfer = _mm512_and_epi32(_mm512_sllv_epi32(__ispc_ffffffff, shift), _mm512_sllv_epi32(a.v_hi, shift));
//__vec16_i32 xfer = _mm512_sllv_epi32(_mm512_and_epi32(a.v_hi,
// _mm512_sub_epi32(_mm512_sllv_epi32(__ispc_one, b.v_lo), __ispc_one)),
// _mm512_sub_epi32(__ispc_thirty_two, b.v_lo));
__vec16_i32 hi = _mm512_srlv_epi32(a.v_hi, b.v_lo);
__vec16_i32 lo = _mm512_or_epi32(xfer, _mm512_srlv_epi32(a.v_lo, b.v_lo));
return __vec16_i64(lo, hi);
}
static FORCEINLINE __vec16_i64 __ashr(__vec16_i64 a, __vec16_i64 b) {
__vec16_i32 xfer = _mm512_sllv_epi32(_mm512_and_epi32(a.v_hi,
_mm512_sub_epi32(_mm512_sllv_epi32(__ispc_one, b.v_lo), __ispc_one)),
_mm512_sub_epi32(__ispc_thirty_two, b.v_lo));
__vec16_i32 hi = _mm512_srav_epi32(a.v_hi, b.v_lo);
__vec16_i32 lo = _mm512_or_epi32(xfer, _mm512_srlv_epi32(a.v_lo, b.v_lo));
return __vec16_i64(lo, hi);
}
BINARY_OP_CAST(__vec16_i64, uint64_t, __udiv, /)
BINARY_OP_CAST(__vec16_i64, int64_t, __sdiv, /)
BINARY_OP_CAST(__vec16_i64, uint64_t, __urem, %)
BINARY_OP_CAST(__vec16_i64, int64_t, __srem, %)
SHIFT_UNIFORM(__vec16_i64, uint64_t, __lshr, >>)
SHIFT_UNIFORM(__vec16_i64, int64_t, __ashr, >>)
SHIFT_UNIFORM(__vec16_i64, int64_t, __shl, <<)
static FORCEINLINE __vec16_i1 __equal_i64(const __vec16_i64 &a, const __vec16_i64 &b) {
const __mmask16 lo_match = _mm512_cmpeq_epi32_mask(a.v_lo,b.v_lo);
return _mm512_mask_cmpeq_epi32_mask(lo_match,a.v_hi,b.v_hi);
}
static FORCEINLINE __vec16_i1 __equal_i64_and_mask(const __vec16_i64 &a, const __vec16_i64 &b,
__vec16_i1 mask) {
__mmask16 lo_match = _mm512_cmpeq_epi32_mask(a.v_lo,b.v_lo);
__mmask16 full_match = _mm512_mask_cmpeq_epi32_mask(lo_match,a.v_hi,b.v_hi);
return _mm512_kand(full_match, (__mmask16)mask);
}
static FORCEINLINE __vec16_i1 __not_equal_i64(const __vec16_i64 &a, const __vec16_i64 &b) {
return __not(__equal_i64(a,b));
}
static FORCEINLINE __vec16_i1 __not_equal_i64_and_mask(const __vec16_i64 &a, const __vec16_i64 &b,
__vec16_i1 mask) {
return __and(__not(__equal_i64(a,b)), mask);
}
CMP_OP(__vec16_i64, i64, uint64_t, __unsigned_less_equal, <=)
CMP_OP(__vec16_i64, i64, int64_t, __signed_less_equal, <=)
CMP_OP(__vec16_i64, i64, uint64_t, __unsigned_greater_equal, >=)
CMP_OP(__vec16_i64, i64, int64_t, __signed_greater_equal, >=)
CMP_OP(__vec16_i64, i64, uint64_t, __unsigned_less_than, <)
CMP_OP(__vec16_i64, i64, int64_t, __signed_less_than, <)
CMP_OP(__vec16_i64, i64, uint64_t, __unsigned_greater_than, >)
CMP_OP(__vec16_i64, i64, int64_t, __signed_greater_than, >)
static FORCEINLINE __vec16_i64 __select(__vec16_i1 mask,
__vec16_i64 a, __vec16_i64 b) {
__vec16_i64 ret;
ret.v_hi = _mm512_mask_mov_epi32(b.v_hi, mask.m, a.v_hi);
ret.v_lo = _mm512_mask_mov_epi32(b.v_lo, mask.m, a.v_lo);
return ret;
}
INSERT_EXTRACT(__vec16_i64, int64_t)
static FORCEINLINE int64_t __extract_element(const __vec16_i64 &v, int index)
{
uint *src = (uint *)&v;
return src[index+16] | (int64_t(src[index]) << 32);
}
template <class RetVecType> RetVecType __smear_i64(const int64_t &l);
template <> FORCEINLINE __vec16_i64 __smear_i64<__vec16_i64>(const int64_t &l) {
const int *i = (const int*)&l;
return __vec16_i64(_mm512_set1_epi32(i[0]), _mm512_set1_epi32(i[1]));
}
BROADCAST(__vec16_i64, i64, int64_t)
ROTATE(__vec16_i64, i64, int64_t)
SHUFFLES(__vec16_i64, i64, int64_t)
LOAD_STORE(__vec16_i64, int64_t)
template <int ALIGN> static FORCEINLINE __vec16_i64 __load(const __vec16_i64 *p) {
__vec16_i32 v1;
__vec16_i32 v2;
v2 = _mm512_extloadunpacklo_epi32(v2, p, _MM_UPCONV_EPI32_NONE, _MM_HINT_NONE);
v2 = _mm512_extloadunpackhi_epi32(v2, (uint8_t*)p+64, _MM_UPCONV_EPI32_NONE, _MM_HINT_NONE);
v1 = _mm512_extloadunpacklo_epi32(v1, (uint8_t*)p+64, _MM_UPCONV_EPI32_NONE, _MM_HINT_NONE);
v1 = _mm512_extloadunpackhi_epi32(v1, (uint8_t*)p+128, _MM_UPCONV_EPI32_NONE, _MM_HINT_NONE);
__vec16_i64 ret;
ret.v_hi = _mm512_mask_permutevar_epi32(ret.v_hi, 0xFF00,
_mm512_set_16to16_pi(15,13,11,9,7,5,3,1,14,12,10,8,6,4,2,0),
v1);
ret.v_hi = _mm512_mask_permutevar_epi32(ret.v_hi, 0x00FF,
_mm512_set_16to16_pi(14,12,10,8,6,4,2,0,15,13,11,9,7,5,3,1),
v2);
ret.v_lo = _mm512_mask_permutevar_epi32(ret.v_lo, 0xFF00,
_mm512_set_16to16_pi(14,12,10,8,6,4,2,0,15,13,11,9,7,5,3,1),
v1);
ret.v_lo = _mm512_mask_permutevar_epi32(ret.v_lo, 0x00FF,
_mm512_set_16to16_pi(15,13,11,9,7,5,3,1,14,12,10,8,6,4,2,0),
v2);
return ret;
}
template <> static FORCEINLINE __vec16_i64 __load<64>(const __vec16_i64 *p) {
__m512i v2 = _mm512_load_epi32(p);
__m512i v1 = _mm512_load_epi32(((uint8_t*)p)+64);
__vec16_i64 ret;
ret.v_hi = _mm512_mask_permutevar_epi32(ret.v_hi, 0xFF00,
_mm512_set_16to16_pi(15,13,11,9,7,5,3,1,14,12,10,8,6,4,2,0),
v1);
ret.v_hi = _mm512_mask_permutevar_epi32(ret.v_hi, 0x00FF,
_mm512_set_16to16_pi(14,12,10,8,6,4,2,0,15,13,11,9,7,5,3,1),
v2);
ret.v_lo = _mm512_mask_permutevar_epi32(ret.v_lo, 0xFF00,
_mm512_set_16to16_pi(14,12,10,8,6,4,2,0,15,13,11,9,7,5,3,1),
v1);
ret.v_lo = _mm512_mask_permutevar_epi32(ret.v_lo, 0x00FF,
_mm512_set_16to16_pi(15,13,11,9,7,5,3,1,14,12,10,8,6,4,2,0),
v2);
return ret;
}
template <> static FORCEINLINE __vec16_i64 __load<128>(const __vec16_i64 *p) {
return __load<64>(p);
}
template <int ALIGN> static FORCEINLINE void __store(__vec16_i64 *p, __vec16_i64 v) {
__m512i v1;
__m512i v2;
v1 = _mm512_mask_permutevar_epi32(_mm512_undefined_epi32(), 0xAAAA,
_mm512_set_16to16_pi(15,15,14,14,13,13,12,12,11,11,10,10,9,9,8,8),
v.v_hi);
v1 = _mm512_mask_permutevar_epi32(v1, 0x5555,
_mm512_set_16to16_pi(15,15,14,14,13,13,12,12,11,11,10,10,9,9,8,8),
v.v_lo);
v2 = _mm512_mask_permutevar_epi32(_mm512_undefined_epi32(), 0xAAAA,
_mm512_set_16to16_pi(7,7,6,6,5,5,4,4,3,3,2,2,1,1,0,0),
v.v_hi);
v2 = _mm512_mask_permutevar_epi32(v2, 0x5555,
_mm512_set_16to16_pi(7,7,6,6,5,5,4,4,3,3,2,2,1,1,0,0),
v.v_lo);
_mm512_extpackstorelo_epi32(p, v2, _MM_DOWNCONV_EPI32_NONE, _MM_HINT_NONE);
_mm512_extpackstorehi_epi32((uint8_t*)p+64, v2, _MM_DOWNCONV_EPI32_NONE, _MM_HINT_NONE);
_mm512_extpackstorelo_epi32((uint8_t*)p+64, v1, _MM_DOWNCONV_EPI32_NONE, _MM_HINT_NONE);
_mm512_extpackstorehi_epi32((uint8_t*)p+128, v1, _MM_DOWNCONV_EPI32_NONE, _MM_HINT_NONE);
}
template <> static FORCEINLINE void __store<64>(__vec16_i64 *p, __vec16_i64 v) {
__m512i v1;
__m512i v2;
v1 = _mm512_mask_permutevar_epi32(_mm512_undefined_epi32(), 0xAAAA,
_mm512_set_16to16_pi(15,15,14,14,13,13,12,12,11,11,10,10,9,9,8,8),
v.v_hi);
v1 = _mm512_mask_permutevar_epi32(v1, 0x5555,
_mm512_set_16to16_pi(15,15,14,14,13,13,12,12,11,11,10,10,9,9,8,8),
v.v_lo);
v2 = _mm512_mask_permutevar_epi32(_mm512_undefined_epi32(), 0xAAAA,
_mm512_set_16to16_pi(7,7,6,6,5,5,4,4,3,3,2,2,1,1,0,0),
v.v_hi);
v2 = _mm512_mask_permutevar_epi32(v2, 0x5555,
_mm512_set_16to16_pi(7,7,6,6,5,5,4,4,3,3,2,2,1,1,0,0),
v.v_lo);
_mm512_store_epi64(p, v2);
_mm512_store_epi64(((uint8_t*)p)+64, v1);
}
template <> static FORCEINLINE void __store<128>(__vec16_i64 *p, __vec16_i64 v) {
__store<64>(p, v);
}
///////////////////////////////////////////////////////////////////////////
// float
static FORCEINLINE __vec16_f __add(__vec16_f a, __vec16_f b) {
return _mm512_add_ps(a, b);
}
static FORCEINLINE __vec16_f __sub(__vec16_f a, __vec16_f b) {
return _mm512_sub_ps(a, b);
}
static FORCEINLINE __vec16_f __mul(__vec16_f a, __vec16_f b) {
return _mm512_mul_ps(a, b);
}
static FORCEINLINE __vec16_f __div(__vec16_f a, __vec16_f b) {
return _mm512_div_ps(a, b);
}
static FORCEINLINE __vec16_i1 __equal_float(__vec16_f a, __vec16_f b) {
return _mm512_cmpeq_ps_mask(a, b);
}
static FORCEINLINE __vec16_i1 __equal_float_and_mask(__vec16_f a, __vec16_f b,
__vec16_i1 m) {
return _mm512_mask_cmpeq_ps_mask(m, a, b);
}
static FORCEINLINE __vec16_i1 __not_equal_float(__vec16_f a, __vec16_f b) {
return _mm512_cmpneq_ps_mask(a, b);
}
static FORCEINLINE __vec16_i1 __not_equal_float_and_mask(__vec16_f a, __vec16_f b,
__vec16_i1 m) {
return _mm512_mask_cmpneq_ps_mask(m, a, b);
}
static FORCEINLINE __vec16_i1 __less_than_float(__vec16_f a, __vec16_f b) {
return _mm512_cmplt_ps_mask(a, b);
}
static FORCEINLINE __vec16_i1 __less_than_float_and_mask(__vec16_f a, __vec16_f b,
__vec16_i1 m) {
return _mm512_mask_cmplt_ps_mask(m, a, b);
}
static FORCEINLINE __vec16_i1 __less_equal_float(__vec16_f a, __vec16_f b) {
return _mm512_cmple_ps_mask(a, b);
}
static FORCEINLINE __vec16_i1 __less_equal_float_and_mask(__vec16_f a, __vec16_f b,
__vec16_i1 m) {
return _mm512_mask_cmple_ps_mask(m, a, b);
}
static FORCEINLINE __vec16_i1 __greater_than_float(__vec16_f a, __vec16_f b) {
return _mm512_cmpnle_ps_mask(a, b);
}
static FORCEINLINE __vec16_i1 __greater_than_float_and_mask(__vec16_f a, __vec16_f b,
__vec16_i1 m) {
return _mm512_mask_cmpnle_ps_mask(m, a, b);
}
static FORCEINLINE __vec16_i1 __greater_equal_float(__vec16_f a, __vec16_f b) {
return _mm512_cmpnlt_ps_mask(a, b);
}
static FORCEINLINE __vec16_i1 __greater_equal_float_and_mask(__vec16_f a, __vec16_f b,
__vec16_i1 m) {
return _mm512_mask_cmpnlt_ps_mask(m, a, b);
}
static FORCEINLINE __vec16_i1 __ordered_float(__vec16_f a, __vec16_f b) {
return _mm512_cmpord_ps_mask(a, b);
}
static FORCEINLINE __vec16_i1 __unordered_float(__vec16_f a, __vec16_f b) {
return _mm512_cmpunord_ps_mask(a, b);
}
static FORCEINLINE __vec16_f __select(__vec16_i1 mask, __vec16_f a, __vec16_f b) {
return _mm512_mask_mov_ps(b, mask, a);
}
static FORCEINLINE __vec16_f __select(bool cond, __vec16_f a, __vec16_f b) {
return cond ? a : b;
}
static FORCEINLINE float __extract_element(__vec16_f v, int index) {
return ((float *)&v)[index];
}
static FORCEINLINE void __insert_element(__vec16_f *v, int index, float val) {
((float *)v)[index] = val;
}
template <class RetVecType> RetVecType __smear_float(float f);
template <> static FORCEINLINE __vec16_f __smear_float<__vec16_f>(float f) {
return _mm512_set_1to16_ps(f);
}
template <class RetVecType> RetVecType __setzero_float();
template <> static FORCEINLINE __vec16_f __setzero_float<__vec16_f>() {
return _mm512_setzero_ps();
}
template <class RetVecType> RetVecType __undef_float();
template <> static FORCEINLINE __vec16_f __undef_float<__vec16_f>() {
return __vec16_f();
}
static FORCEINLINE __vec16_f __broadcast_float(__vec16_f v, int index) {
int32_t val = __extract_element(v, index & 0xf);
return _mm512_set1_ps(val);
}
/*
static FORCEINLINE __vec16_f __rotate_float(__vec16_f v, int index) {
__vec16_f ret; for (int i = 0; i < 16; ++i) ret.v[i] = v.v[(i+index) & 0xf]; return ret;
}
*/
static FORCEINLINE __vec16_f __shuffle_float(__vec16_f v, __vec16_i32 index) {
return _mm512_castsi512_ps(_mm512_mask_permutevar_epi32(_mm512_castps_si512(v), 0xffff, index, _mm512_castps_si512(v)));
}
/*
static FORCEINLINE __vec16_f __shuffle2_float(__vec16_f v0, __vec16_f v1, __vec16_i32 index) {
__vec16_f ret; for (int i = 0; i < 16; ++i) { int ii = __extract_element(index, i) & 0x1f; ret.v[i] = (ii < 16) ? v0.v[ii] : v1.v[ii-16]; } return ret;
}
*/
template <int ALIGN> static FORCEINLINE __vec16_f __load(const __vec16_f *p) {
#ifdef ISPC_FORCE_ALIGNED_MEMORY
return _mm512_load_ps(p);
#else
__vec16_f v;
v = _mm512_extloadunpacklo_ps(v, p, _MM_UPCONV_PS_NONE, _MM_HINT_NONE);
v = _mm512_extloadunpackhi_ps(v, (uint8_t*)p+64, _MM_UPCONV_PS_NONE, _MM_HINT_NONE);
return v;
#endif
}
template <> static FORCEINLINE __vec16_f __load<64>(const __vec16_f *p) {
return _mm512_load_ps(p);
}
template <int ALIGN> static FORCEINLINE void __store(__vec16_f *p, __vec16_f v) {
#ifdef ISPC_FORCE_ALIGNED_MEMORY
_mm512_store_ps(p, v);
#else
_mm512_extpackstorelo_ps(p, v, _MM_DOWNCONV_PS_NONE, _MM_HINT_NONE);
_mm512_extpackstorehi_ps((uint8_t*)p+64, v, _MM_DOWNCONV_PS_NONE, _MM_HINT_NONE);
#endif
}
template <> static FORCEINLINE void __store<64>(__vec16_f *p, __vec16_f v) {
_mm512_store_ps(p, v);
}
///////////////////////////////////////////////////////////////////////////
// double
static FORCEINLINE __vec16_d __add(__vec16_d a, __vec16_d b) {
__vec16_d ret;
ret.v1 = _mm512_add_pd(a.v1, b.v1);
ret.v2 = _mm512_add_pd(a.v2, b.v2);
return ret;
}
static FORCEINLINE __vec16_d __sub(__vec16_d a, __vec16_d b) {
__vec16_d ret;
ret.v1 = _mm512_sub_pd(a.v1, b.v1);
ret.v2 = _mm512_sub_pd(a.v2, b.v2);
return ret;
}
static FORCEINLINE __vec16_d __mul(__vec16_d a, __vec16_d b) {
__vec16_d ret;
ret.v1 = _mm512_mul_pd(a.v1, b.v1);
ret.v2 = _mm512_mul_pd(a.v2, b.v2);
return ret;
}
static FORCEINLINE __vec16_d __div(__vec16_d a, __vec16_d b) {
__vec16_d ret;
ret.v1 = _mm512_div_pd(a.v1, b.v1);
ret.v2 = _mm512_div_pd(a.v2, b.v2);
return ret;
}
static FORCEINLINE __vec16_i1 __equal_double(__vec16_d a, __vec16_d b) {
__vec16_i1 ret;
ret.m8.m1 = _mm512_cmpeq_pd_mask(a.v1, b.v1);
ret.m8.m2 = _mm512_cmpeq_pd_mask(a.v2, b.v2);
return ret;
}
static FORCEINLINE __vec16_i1 __equal_double_and_mask(__vec16_d a, __vec16_d b,
__vec16_i1 m) {
__vec16_i1 ret;
ret.m8.m1 = _mm512_mask_cmpeq_pd_mask(m.m8.m1, a.v1, b.v1);
ret.m8.m2 = _mm512_mask_cmpeq_pd_mask(m.m8.m2, a.v2, b.v2);
return ret;
}
static FORCEINLINE __vec16_i1 __not_equal_double(__vec16_d a, __vec16_d b) {
__vec16_i1 ret;
ret.m8.m1 = _mm512_cmpneq_pd_mask(a.v1, b.v1);
ret.m8.m2 = _mm512_cmpneq_pd_mask(a.v2, b.v2);
return ret;
}
static FORCEINLINE __vec16_i1 __not_equal_double_and_mask(__vec16_d a, __vec16_d b,
__vec16_i1 m) {
__vec16_i1 ret;
ret.m8.m1 = _mm512_mask_cmpneq_pd_mask(m.m8.m1, a.v1, b.v1);
ret.m8.m2 = _mm512_mask_cmpneq_pd_mask(m.m8.m2, a.v2, b.v2);
return ret;
}
static FORCEINLINE __vec16_i1 __less_than_double(__vec16_d a, __vec16_d b) {
__vec16_i1 ret;
ret.m8.m1 = _mm512_cmplt_pd_mask(a.v1, b.v1);
ret.m8.m2 = _mm512_cmplt_pd_mask(a.v2, b.v2);
return ret;
}
static FORCEINLINE __vec16_i1 __less_than_double_and_mask(__vec16_d a, __vec16_d b,
__vec16_i1 m) {
__vec16_i1 ret;
ret.m8.m1 = _mm512_mask_cmplt_pd_mask(m.m8.m1, a.v1, b.v1);
ret.m8.m2 = _mm512_mask_cmplt_pd_mask(m.m8.m2, a.v2, b.v2);
return ret;
}
static FORCEINLINE __vec16_i1 __less_equal_double(__vec16_d a, __vec16_d b) {
__vec16_i1 ret;
ret.m8.m1 = _mm512_cmple_pd_mask(a.v1, b.v1);
ret.m8.m2 = _mm512_cmple_pd_mask(a.v2, b.v2);
return ret;
}
static FORCEINLINE __vec16_i1 __less_equal_double_and_mask(__vec16_d a, __vec16_d b,
__vec16_i1 m) {
__vec16_i1 ret;
ret.m8.m1 = _mm512_mask_cmple_pd_mask(m.m8.m1, a.v1, b.v1);
ret.m8.m2 = _mm512_mask_cmple_pd_mask(m.m8.m2, a.v2, b.v2);
return ret;
}
static FORCEINLINE __vec16_i1 __greater_than_double(__vec16_d a, __vec16_d b) {
__vec16_i1 ret;
ret.m8.m1 = _mm512_cmpnle_pd_mask(a.v1, b.v1);
ret.m8.m2 = _mm512_cmpnle_pd_mask(a.v2, b.v2);
return ret;
}
static FORCEINLINE __vec16_i1 __greater_than_double_and_mask(__vec16_d a, __vec16_d b,
__vec16_i1 m) {
__vec16_i1 ret;
ret.m8.m1 = _mm512_mask_cmpnle_pd_mask(m.m8.m1, a.v1, b.v1);
ret.m8.m2 = _mm512_mask_cmpnle_pd_mask(m.m8.m2, a.v2, b.v2);
return ret;
}
static FORCEINLINE __vec16_i1 __greater_equal_double(__vec16_d a, __vec16_d b) {
__vec16_i1 ret;
ret.m8.m1 = _mm512_cmpnlt_pd_mask(a.v1, b.v1);
ret.m8.m2 = _mm512_cmpnlt_pd_mask(a.v2, b.v2);
return ret;
}
static FORCEINLINE __vec16_i1 __greater_equal_double_and_mask(__vec16_d a, __vec16_d b,
__vec16_i1 m) {
__vec16_i1 ret;
ret.m8.m1 = _mm512_mask_cmpnlt_pd_mask(m.m8.m1, a.v1, b.v1);
ret.m8.m2 = _mm512_mask_cmpnlt_pd_mask(m.m8.m2, a.v2, b.v2);
return ret;
}
static FORCEINLINE __vec16_i1 __ordered_double(__vec16_d a, __vec16_d b) {
__vec16_i1 ret;
ret.m8.m1 = _mm512_cmpord_pd_mask(a.v1, b.v1);
ret.m8.m2 = _mm512_cmpord_pd_mask(a.v2, b.v2);
return ret;
}
static FORCEINLINE __vec16_i1 __unordered_double(__vec16_d a, __vec16_d b) {
__vec16_i1 ret;
ret.m8.m1 = _mm512_cmpunord_pd_mask(a.v1, b.v1);
ret.m8.m2 = _mm512_cmpunord_pd_mask(a.v2, b.v2);
return ret;
}
static FORCEINLINE __vec16_d __select(__vec16_i1 mask, __vec16_d a, __vec16_d b) {
__vec16_d ret;
ret.v1 = _mm512_mask_mov_pd(b.v1, mask.m8.m1, a.v1);
ret.v2 = _mm512_mask_mov_pd(b.v2, mask.m8.m2, a.v2);
return ret;
}
static FORCEINLINE __vec16_d __select(bool cond, __vec16_d a, __vec16_d b) {
return cond ? a : b;
}
static FORCEINLINE double __extract_element(__vec16_d v, int index) {
return ((double *)&v)[index];
}
static FORCEINLINE void __insert_element(__vec16_d *v, int index, double val) {
((double *)v)[index] = val;
}
template <class RetVecType> RetVecType __smear_double(double d);
template <> static FORCEINLINE __vec16_d __smear_double<__vec16_d>(double d) {
__vec16_d ret;
ret.v1 = _mm512_set1_pd(d);
ret.v2 = _mm512_set1_pd(d);
return ret;
}
template <class RetVecType> RetVecType __setzero_double();
template <> static FORCEINLINE __vec16_d __setzero_double<__vec16_d>() {
__vec16_d ret;
ret.v1 = _mm512_setzero_pd();
ret.v2 = _mm512_setzero_pd();
return ret;
}
template <class RetVecType> RetVecType __undef_double();
template <> static FORCEINLINE __vec16_d __undef_double<__vec16_d>() {
return __vec16_d();
}
static FORCEINLINE __vec16_d __broadcast_double(__vec16_d v, int index) {
__vec16_d ret;
double val = __extract_element(v, index & 0xf);
ret.v1 = _mm512_set1_pd(val);
ret.v2 = _mm512_set1_pd(val);
return ret;
}
/*
static FORCEINLINE __vec16_d __rotate_double(__vec16_d v, int index) {
__vec16_d ret; for (int i = 0; i < 16; ++i) ret.v[i] = v.v[(i+index) & 0xf]; return ret;
}
static FORCEINLINE __vec16_d __shuffle_double(__vec16_d v, __vec16_i32 index) {
return _mm512_castsi512_ps(
_mm512_mask_permutevar_epi32(_mm512_castps_si512(v), 0xffff, index, _mm512_castps_si512(v)));
}
static FORCEINLINE __vec16_f __shuffle2_float(__vec16_d v0, __vec16_d v1, __vec16_i32 index) {
__vec16_f ret; for (int i = 0; i < 16; ++i) { int ii = __extract_element(index, i) & 0x1f; ret.v[i] = (ii < 16) ? v0.v[ii] : v1.v[ii-16]; } return ret;
}
*/
template <int ALIGN> static FORCEINLINE __vec16_d __load(const __vec16_d *p) {
__vec16_d ret;
ret.v1 = _mm512_extloadunpacklo_pd(ret.v1, p, _MM_UPCONV_PD_NONE, _MM_HINT_NONE);
ret.v1 = _mm512_extloadunpackhi_pd(ret.v1, (uint8_t*)p+64, _MM_UPCONV_PD_NONE, _MM_HINT_NONE);
ret.v2 = _mm512_extloadunpacklo_pd(ret.v2, (uint8_t*)p+64, _MM_UPCONV_PD_NONE, _MM_HINT_NONE);
ret.v2 = _mm512_extloadunpackhi_pd(ret.v2, (uint8_t*)p+128, _MM_UPCONV_PD_NONE, _MM_HINT_NONE);
return ret;
}
template <> static FORCEINLINE __vec16_d __load<64>(const __vec16_d *p) {
__vec16_d ret;
ret.v1 = _mm512_load_pd(p);
ret.v2 = _mm512_load_pd(((uint8_t*)p)+64);
return ret;
}
template <> static FORCEINLINE __vec16_d __load<128>(const __vec16_d *p) {
return __load<64>(p);
}
template <int ALIGN> static FORCEINLINE void __store(__vec16_d *p, __vec16_d v) {
_mm512_extpackstorelo_pd(p, v.v1, _MM_DOWNCONV_PD_NONE, _MM_HINT_NONE);
_mm512_extpackstorehi_pd((uint8_t*)p+64, v.v1, _MM_DOWNCONV_PD_NONE, _MM_HINT_NONE);
_mm512_extpackstorelo_pd((uint8_t*)p+64, v.v2, _MM_DOWNCONV_PD_NONE, _MM_HINT_NONE);
_mm512_extpackstorehi_pd((uint8_t*)p+128, v.v2, _MM_DOWNCONV_PD_NONE, _MM_HINT_NONE);
}
template <> static FORCEINLINE void __store<64>(__vec16_d *p, __vec16_d v) {
_mm512_store_pd(p, v.v1);
_mm512_store_pd(((uint8_t*)p)+64, v.v2);
}
template <> static FORCEINLINE void __store<128>(__vec16_d *p, __vec16_d v) {
__store<64>(p, v);
}
///////////////////////////////////////////////////////////////////////////
// casts
#define CAST(TO, STO, FROM, SFROM, FUNC)
/*
static FORCEINLINE TO FUNC(TO, FROM val) { \
TO ret; \
for (int i = 0; i < 16; ++i) \
ret.v[i] = (STO)((SFROM)(val.v[i])); \
return ret; \
}
*/
// sign extension conversions
CAST(__vec16_i64, int64_t, __vec16_i32, int32_t, __cast_sext)
CAST(__vec16_i64, int64_t, __vec16_i16, int16_t, __cast_sext)
CAST(__vec16_i64, int64_t, __vec16_i8, int8_t, __cast_sext)
CAST(__vec16_i32, int32_t, __vec16_i16, int16_t, __cast_sext)
CAST(__vec16_i32, int32_t, __vec16_i8, int8_t, __cast_sext)
CAST(__vec16_i16, int16_t, __vec16_i8, int8_t, __cast_sext)
static FORCEINLINE __vec16_i64 __cast_sext(const __vec16_i64 &, const __vec16_i32 &val)
{
return __vec16_i64(val.v,_mm512_srai_epi32(val.v,31));
}
#define CAST_SEXT_I1(TYPE)
/*
static FORCEINLINE TYPE __cast_sext(TYPE, __vec16_i1 v) { \
TYPE ret; \
for (int i = 0; i < 16; ++i) { \
ret.v[i] = 0; \
if (v.v & (1 << i)) \
ret.v[i] = ~ret.v[i]; \
} \
return ret; \
}
*/
CAST_SEXT_I1(__vec16_i8)
CAST_SEXT_I1(__vec16_i16)
CAST_SEXT_I1(__vec16_i32)
// zero extension
CAST(__vec16_i64, uint64_t, __vec16_i32, uint32_t, __cast_zext)
CAST(__vec16_i64, uint64_t, __vec16_i16, uint16_t, __cast_zext)
CAST(__vec16_i64, uint64_t, __vec16_i8, uint8_t, __cast_zext)
CAST(__vec16_i32, uint32_t, __vec16_i16, uint16_t, __cast_zext)
CAST(__vec16_i32, uint32_t, __vec16_i8, uint8_t, __cast_zext)
CAST(__vec16_i16, uint16_t, __vec16_i8, uint8_t, __cast_zext)
static FORCEINLINE __vec16_i64 __cast_zext(const __vec16_i64 &, const __vec16_i32 &val)
{
return __vec16_i64(val.v, _mm512_setzero_epi32());
}
#define CAST_ZEXT_I1(TYPE)
/*
static FORCEINLINE TYPE __cast_zext(TYPE, __vec16_i1 v) { \
TYPE ret; \
for (int i = 0; i < 16; ++i) \
ret.v[i] = (v.v & (1 << i)) ? 1 : 0; \
return ret; \
}
*/
CAST_ZEXT_I1(__vec16_i8)
CAST_ZEXT_I1(__vec16_i16)
CAST_ZEXT_I1(__vec16_i32)
CAST_ZEXT_I1(__vec16_i64)
static FORCEINLINE __vec16_i32 __cast_zext(const __vec16_i32 &, const __vec16_i1 &val)
{
__vec16_i32 ret = _mm512_setzero_epi32();
__vec16_i32 one = _mm512_set1_epi32(1);
return _mm512_mask_mov_epi32(ret, val.m, one);
}
// truncations
CAST(__vec16_i32, int32_t, __vec16_i64, int64_t, __cast_trunc)
CAST(__vec16_i16, int16_t, __vec16_i64, int64_t, __cast_trunc)
CAST(__vec16_i8, int8_t, __vec16_i64, int64_t, __cast_trunc)
CAST(__vec16_i16, int16_t, __vec16_i32, int32_t, __cast_trunc)
CAST(__vec16_i8, int8_t, __vec16_i32, int32_t, __cast_trunc)
CAST(__vec16_i8, int8_t, __vec16_i16, int16_t, __cast_trunc)
// signed int to float/double
CAST(__vec16_f, float, __vec16_i64, int64_t, __cast_sitofp)
CAST(__vec16_d, double, __vec16_i64, int64_t, __cast_sitofp)
static FORCEINLINE __vec16_f __cast_sitofp(__vec16_f, __vec16_i8 val) {
return _mm512_extload_ps(&val, _MM_UPCONV_PS_SINT8, _MM_BROADCAST_16X16, _MM_HINT_NONE);
}
static FORCEINLINE __vec16_f __cast_sitofp(__vec16_f, __vec16_i16 val) {
return _mm512_extload_ps(&val, _MM_UPCONV_PS_SINT16, _MM_BROADCAST_16X16, _MM_HINT_NONE);
}
static FORCEINLINE __vec16_f __cast_sitofp(__vec16_f, __vec16_i32 val) {
return _mm512_cvtfxpnt_round_adjustepi32_ps(val, _MM_ROUND_MODE_NEAREST, _MM_EXPADJ_NONE);
}
static FORCEINLINE __vec16_d __cast_sitofp(__vec16_d, __vec16_i8 val) {
__vec16_i32 vi = _mm512_extload_epi32(&val, _MM_UPCONV_EPI32_SINT8, _MM_BROADCAST_16X16, _MM_HINT_NONE);
__vec16_d ret;
ret.v1 = _mm512_cvtepi32lo_pd(vi);
__vec16_i32 other8 = _mm512_permute4f128_epi32(vi, _MM_PERM_DCDC);
ret.v2 = _mm512_cvtepi32lo_pd(other8);
return ret;
}
static FORCEINLINE __vec16_d __cast_sitofp(__vec16_d, __vec16_i16 val) {
__vec16_i32 vi = _mm512_extload_epi32(&val, _MM_UPCONV_EPI32_SINT16, _MM_BROADCAST_16X16, _MM_HINT_NONE);
__vec16_d ret;
ret.v1 = _mm512_cvtepi32lo_pd(vi);
__vec16_i32 other8 = _mm512_permute4f128_epi32(vi, _MM_PERM_DCDC);
ret.v2 = _mm512_cvtepi32lo_pd(other8);
return ret;
}
static FORCEINLINE __vec16_d __cast_sitofp(__vec16_d, __vec16_i32 val) {
__vec16_d ret;
ret.v1 = _mm512_cvtepi32lo_pd(val);
__vec16_i32 other8 = _mm512_permute4f128_epi32(val, _MM_PERM_DCDC);
ret.v2 = _mm512_cvtepi32lo_pd(other8);
return ret;
}
/*
static FORCEINLINE __vec16_f __cast_sitofp(__vec16_f, __vec16_i64 val) {
__vec16_f ret; for (int i = 0; i < 16; ++i) ret.v[i] = (float)((int64_t)(val.v[i])); return ret;
}
static FORCEINLINE __vec16_d __cast_sitofp(__vec16_d, __vec16_i64 val) {
__vec16_d ret; for (int i = 0; i < 16; ++i) ret.v[i] = (double)((int64_t)(val.v[i])); return ret;
}
*/
// unsigned int to float/double
CAST(__vec16_f, float, __vec16_i16, uint16_t, __cast_uitofp)
CAST(__vec16_f, float, __vec16_i64, uint64_t, __cast_uitofp)
CAST(__vec16_d, double, __vec16_i8, uint8_t, __cast_uitofp)
CAST(__vec16_d, double, __vec16_i16, uint16_t, __cast_uitofp)
CAST(__vec16_d, double, __vec16_i32, uint32_t, __cast_uitofp)
CAST(__vec16_d, double, __vec16_i64, uint64_t, __cast_uitofp)
/*
static FORCEINLINE __vec16_f __cast_uitofp(__vec16_f, __vec16_i1 v) {
__vec16_f ret;
for (int i = 0; i < 16; ++i)
ret.v[i] = (v.v & (1 << i)) ? 1. : 0.;
return ret;
}
*/
static FORCEINLINE __vec16_f __cast_uitofp(__vec16_f, const __vec16_i8 &v) {
return _mm512_extload_ps(v.v,_MM_UPCONV_PS_UINT8,_MM_BROADCAST32_NONE,_MM_HINT_NONE);
}
static FORCEINLINE __vec16_f __cast_uitofp(__vec16_f, __vec16_i32 v) {
return _mm512_cvtfxpnt_round_adjustepu32_ps(v, _MM_FROUND_NO_EXC,_MM_EXPADJ_NONE);
}
// float/double to signed int
static FORCEINLINE __vec16_i32 __cast_fptosi(__vec16_i32, __vec16_f val) {
return _mm512_cvtfxpnt_round_adjustps_epi32(val, _MM_ROUND_MODE_TOWARD_ZERO, _MM_EXPADJ_NONE);
}
static FORCEINLINE __vec16_i32 __cast_fptoui(__vec16_i32, __vec16_f val) {
return _mm512_cvtfxpnt_round_adjustps_epu32(val, _MM_ROUND_MODE_TOWARD_ZERO, _MM_EXPADJ_NONE);
}
CAST(__vec16_i8, int8_t, __vec16_f, float, __cast_fptosi)
CAST(__vec16_i16, int16_t, __vec16_f, float, __cast_fptosi)
CAST(__vec16_i64, int64_t, __vec16_f, float, __cast_fptosi)
CAST(__vec16_i8, int8_t, __vec16_d, double, __cast_fptosi)
CAST(__vec16_i16, int16_t, __vec16_d, double, __cast_fptosi)
CAST(__vec16_i32, int32_t, __vec16_d, double, __cast_fptosi)
CAST(__vec16_i64, int64_t, __vec16_d, double, __cast_fptosi)
// float/double to unsigned int
CAST(__vec16_i8, uint8_t, __vec16_f, float, __cast_fptoui)
CAST(__vec16_i16, uint16_t, __vec16_f, float, __cast_fptoui)
CAST(__vec16_i64, uint64_t, __vec16_f, float, __cast_fptoui)
CAST(__vec16_i8, uint8_t, __vec16_d, double, __cast_fptoui)
CAST(__vec16_i16, uint16_t, __vec16_d, double, __cast_fptoui)
CAST(__vec16_i32, uint32_t, __vec16_d, double, __cast_fptoui)
CAST(__vec16_i64, uint64_t, __vec16_d, double, __cast_fptoui)
// float/double conversions
CAST(__vec16_f, float, __vec16_d, double, __cast_fptrunc)
CAST(__vec16_d, double, __vec16_f, float, __cast_fpext)
/*
typedef union {
int32_t i32;
float f;
int64_t i64;
double d;
} BitcastUnion;
*/
#define CAST_BITS(TO, TO_TYPE, TO_ELT, FROM, FROM_ELT)
/*
static FORCEINLINE TO __cast_bits(TO, FROM val) { \
BitcastUnion u; \
u.FROM_ELT = val; \
return u.TO_ELT; \
}
*/
static FORCEINLINE __vec16_f __cast_bits(__vec16_f, __vec16_i32 val) {
return _mm512_castsi512_ps(val);
}
static FORCEINLINE __vec16_i32 __cast_bits(__vec16_i32, __vec16_f val) {
return _mm512_castps_si512(val);
}
static FORCEINLINE __vec16_i64 __cast_bits(__vec16_i64, __vec16_d val) {
return *(__vec16_i64*)&val;
}
static FORCEINLINE __vec16_d __cast_bits(__vec16_d, __vec16_i64 val) {
return *(__vec16_d*)&val;
}
#define CAST_BITS_SCALAR(TO, FROM)
/*
static FORCEINLINE TO __cast_bits(TO, FROM v) { \
union { \
TO to; \
FROM from; \
} u; \
u.from = v; \
return u.to; \
}
*/
CAST_BITS_SCALAR(uint32_t, float)
CAST_BITS_SCALAR(int32_t, float)
CAST_BITS_SCALAR(float, uint32_t)
CAST_BITS_SCALAR(float, int32_t)
CAST_BITS_SCALAR(uint64_t, double)
CAST_BITS_SCALAR(int64_t, double)
CAST_BITS_SCALAR(double, uint64_t)
CAST_BITS_SCALAR(double, int64_t)
///////////////////////////////////////////////////////////////////////////
// various math functions
static FORCEINLINE float __round_uniform_float(float v) {
return roundf(v);
}
static FORCEINLINE float __floor_uniform_float(float v) {
return floorf(v);
}
static FORCEINLINE float __ceil_uniform_float(float v) {
return ceilf(v);
}
static FORCEINLINE double __round_uniform_double(double v) {
return round(v);
}
static FORCEINLINE double __floor_uniform_double(double v) {
return floor(v);
}
static FORCEINLINE double __ceil_uniform_double(double v) {
return ceil(v);
}
static FORCEINLINE __vec16_f __round_varying_float(__vec16_f v) {
return _mm512_round_ps(v, _MM_ROUND_MODE_NEAREST, _MM_EXPADJ_NONE);
}
static FORCEINLINE __vec16_f __floor_varying_float(__vec16_f v) {
return _mm512_floor_ps(v);
}
static FORCEINLINE __vec16_f __ceil_varying_float(__vec16_f v) {
return _mm512_ceil_ps(v);
}
UNARY_OP(__vec16_d, __round_varying_double, round)
UNARY_OP(__vec16_d, __floor_varying_double, floor)
UNARY_OP(__vec16_d, __ceil_varying_double, ceil)
// min/max
static FORCEINLINE float __min_uniform_float(float a, float b) { return (a<b) ? a : b; }
static FORCEINLINE float __max_uniform_float(float a, float b) { return (a>b) ? a : b; }
static FORCEINLINE double __min_uniform_double(double a, double b) { return (a<b) ? a : b; }
static FORCEINLINE double __max_uniform_double(double a, double b) { return (a>b) ? a : b; }
static FORCEINLINE int32_t __min_uniform_int32(int32_t a, int32_t b) { return (a<b) ? a : b; }
static FORCEINLINE int32_t __max_uniform_int32(int32_t a, int32_t b) { return (a>b) ? a : b; }
static FORCEINLINE int32_t __min_uniform_uint32(uint32_t a, uint32_t b) { return (a<b) ? a : b; }
static FORCEINLINE int32_t __max_uniform_uint32(uint32_t a, uint32_t b) { return (a>b) ? a : b; }
static FORCEINLINE int64_t __min_uniform_int64(int64_t a, int64_t b) { return (a<b) ? a : b; }
static FORCEINLINE int64_t __max_uniform_int64(int64_t a, int64_t b) { return (a>b) ? a : b; }
static FORCEINLINE int64_t __min_uniform_uint64(uint64_t a, uint64_t b) { return (a<b) ? a : b; }
static FORCEINLINE int64_t __max_uniform_uint64(uint64_t a, uint64_t b) { return (a>b) ? a : b; }
static FORCEINLINE __vec16_f __max_varying_float(__vec16_f v1, __vec16_f v2) {
return _mm512_gmax_ps(v1, v2);
}
static FORCEINLINE __vec16_f __min_varying_float(__vec16_f v1, __vec16_f v2) {
return _mm512_gmin_ps(v1, v2);
}
static FORCEINLINE __vec16_i32 __max_varying_int32(__vec16_i32 v1, __vec16_i32 v2) {
return _mm512_max_epi32(v1, v2);
}
static FORCEINLINE __vec16_i32 __min_varying_int32(__vec16_i32 v1, __vec16_i32 v2) {
return _mm512_min_epi32(v1, v2);
}
static FORCEINLINE __vec16_i32 __max_varying_uint32(__vec16_i32 v1, __vec16_i32 v2) {
return _mm512_max_epu32(v1, v2);
}
static FORCEINLINE __vec16_i32 __min_varying_uint32(__vec16_i32 v1, __vec16_i32 v2) {
return _mm512_min_epu32(v1, v2);
}
BINARY_OP_FUNC(__vec16_d, __max_varying_double, __max_uniform_double)
BINARY_OP_FUNC(__vec16_d, __min_varying_double, __min_uniform_double)
BINARY_OP_FUNC(__vec16_i64, __max_varying_int64, __max_uniform_int64)
BINARY_OP_FUNC(__vec16_i64, __min_varying_int64, __min_uniform_int64)
BINARY_OP_FUNC(__vec16_i64, __max_varying_uint64, __max_uniform_uint64)
BINARY_OP_FUNC(__vec16_i64, __min_varying_uint64, __min_uniform_uint64)
// sqrt/rsqrt/rcp
static FORCEINLINE float __rsqrt_uniform_float(float v) {
return 1.f / sqrtf(v);
}
static FORCEINLINE float __rcp_uniform_float(float v) {
return 1.f / v;
}
static FORCEINLINE float __sqrt_uniform_float(float v) {
return sqrtf(v);
}
static FORCEINLINE double __sqrt_uniform_double(double v) {
return sqrt(v);
}
static FORCEINLINE __vec16_f __sqrt_varying_float(__vec16_f v) {
return _mm512_sqrt_ps(v);
}
static FORCEINLINE __vec16_f __rcp_varying_float(__vec16_f v) {
#ifdef ISPC_FAST_MATH
return _mm512_rcp23_ps(v); // Approximation with 23 bits of accuracy.
#else
return _mm512_recip_ps(v);
#endif
}
static FORCEINLINE __vec16_f __rsqrt_varying_float(__vec16_f v) {
#ifdef ISPC_FAST_MATH
return _mm512_rsqrt23_ps(v); // Approximation with 0.775ULP accuracy
#else
return _mm512_invsqrt_ps(v);
#endif
}
static FORCEINLINE __vec16_f __exp_varying_float(__vec16_f v) {
return _mm512_exp_ps(v);
}
static FORCEINLINE __vec16_f __log_varying_float(__vec16_f v) {
return _mm512_log_ps(v);
}
static FORCEINLINE __vec16_f __pow_varying_float(__vec16_f a, __vec16_f b) {
return _mm512_pow_ps(a, b);
}
UNARY_OP(__vec16_d, __sqrt_varying_double, __sqrt_uniform_double)
///////////////////////////////////////////////////////////////////////////
// bit ops
static FORCEINLINE int32_t __popcnt_int32(const __vec1_i32 mask) {
return _mm_countbits_32(mask);
}
static FORCEINLINE int32_t __popcnt_int64(const __vec1_i64 mask) {
return _mm_countbits_64(mask);
}
static FORCEINLINE int32_t __count_trailing_zeros_i32(const __vec1_i32 mask) {
return _mm_tzcnt_32(mask);
}
static FORCEINLINE int64_t __count_trailing_zeros_i64(const __vec1_i64 mask) {
return _mm_tzcnt_64(mask);
}
/*
static FORCEINLINE int32_t __count_leading_zeros_i32(uint32_t v) {
if (v == 0)
return 32;
int count = 0;
while ((v & (1<<31)) == 0) {
++count;
v <<= 1;
}
return count;
}
static FORCEINLINE int64_t __count_leading_zeros_i64(uint64_t v) {
if (v == 0)
return 64;
int count = 0;
while ((v & (1ull<<63)) == 0) {
++count;
v <<= 1;
}
return count;
}
*/
///////////////////////////////////////////////////////////////////////////
// reductions
static const __vec16_i32 __ispc_s1(8, 9, 10, 11, 12, 13, 14, 15, 0, 1, 2, 3, 4, 5, 6, 7);
static const __vec16_i32 __ispc_s2(4, 5, 6, 7, 0, 1, 2, 3, 12, 13, 14, 15, 8, 9, 10, 11);
static const __vec16_i32 __ispc_s3(2, 3, 0, 1, 6, 7, 4, 5, 10, 11, 8, 9, 14, 15, 12, 13);
static const __vec16_i32 __ispc_s4(1, 0, 3, 2, 5, 4, 7, 6, 9, 8, 11, 10, 13, 12, 15, 14);
static FORCEINLINE uint32_t __reduce_add_i32(__vec16_i32 v) {
return _mm512_reduce_add_epi32(v);
}
static FORCEINLINE uint32_t __reduce_min_i32(__vec16_i32 v) {
return _mm512_reduce_min_epi32(v);
}
static FORCEINLINE uint32_t __reduce_max_i32(__vec16_i32 v) {
return _mm512_reduce_max_epi32(v);
}
static FORCEINLINE float __reduce_add_float(__vec16_f v) {
return _mm512_reduce_add_ps(v);
}
static FORCEINLINE float __reduce_min_float(__vec16_f v) {
return _mm512_reduce_min_ps(v);
}
static FORCEINLINE float __reduce_max_float(__vec16_f v) {
return _mm512_reduce_max_ps(v);
}
static FORCEINLINE float __reduce_add_double(__vec16_d v) {
return _mm512_reduce_add_pd(v.v1) + _mm512_reduce_add_pd(v.v2);
}
static FORCEINLINE float __reduce_min_double(__vec16_d v) {
return std::min(_mm512_reduce_min_pd(v.v1), _mm512_reduce_min_pd(v.v2));
}
static FORCEINLINE float __reduce_max_double(__vec16_d v) {
return std::max(_mm512_reduce_max_pd(v.v1), _mm512_reduce_max_pd(v.v2));
}
REDUCE_ADD(uint64_t, __vec16_i64, __reduce_add_int64)
REDUCE_MINMAX(int64_t, __vec16_i64, __reduce_min_int64, <)
REDUCE_MINMAX(int64_t, __vec16_i64, __reduce_max_int64, >)
///////////////////////////////////////////////////////////////////////////
// masked load/store
/*
static FORCEINLINE __vec16_i8 __masked_load_i8(void *p,
__vec16_i1 mask) {
__vec16_i8 ret;
int8_t *ptr = (int8_t *)p;
for (int i = 0; i < 16; ++i)
if ((mask.v & (1 << i)) != 0)
ret.v[i] = ptr[i];
return ret;
}
static FORCEINLINE __vec16_i16 __masked_load_i16(void *p,
__vec16_i1 mask) {
__vec16_i16 ret;
int16_t *ptr = (int16_t *)p;
for (int i = 0; i < 16; ++i)
if ((mask.v & (1 << i)) != 0)
ret.v[i] = ptr[i];
return ret;
}
*/
// Currently, when a pseudo_gather is converted into a masked load, it has to be unaligned
static FORCEINLINE __vec16_i32 __masked_load_i32(void *p, __vec16_i1 mask) {
#ifdef ISPC_FORCE_ALIGNED_MEMORY
return _mm512_mask_load_epi32(__vec16_i32(), mask.m, p);
#else
__vec16_i32 tmp;
tmp.v = _mm512_mask_extloadunpacklo_epi32(tmp.v, 0xFFFF, p, _MM_UPCONV_EPI32_NONE, _MM_HINT_NONE);
tmp.v = _mm512_mask_extloadunpackhi_epi32(tmp.v, 0xFFFF, (uint8_t*)p+64, _MM_UPCONV_EPI32_NONE, _MM_HINT_NONE);
__vec16_i32 ret;
return _mm512_mask_mov_epi32(ret.v, mask.m, tmp.v);
#endif
}
/*
static FORCEINLINE __vec16_i64 __masked_load_i64(void *p,
__vec16_i1 mask) {
union {
__vec16_i64 v64;
__vec16_i32 v32[2];
} ret;
ret.v32[0] = _mm512_mask_loadq(ret, mask, p, _MM_FULLUPC64_NONE, _MM_BROADCAST_8X8, _MM_HINT_NONE);
ret.v32[1] = _mm512_mask_loadq(ret, mask, p, _MM_FULLUPC64_NONE, _MM_BROADCAST_8X8, _MM_HINT_NONE);
return ret.v64;
}
*/
static FORCEINLINE __vec16_f __masked_load_float(void *p, __vec16_i1 mask) {
#ifdef ISPC_FORCE_ALIGNED_MEMORY
return _mm512_mask_load_ps(_mm512_undefined_ps(), mask.m,p);
#else
__vec16_f tmp;
tmp.v = _mm512_mask_extloadunpacklo_ps(tmp.v, 0xFFFF, p, _MM_UPCONV_PS_NONE, _MM_HINT_NONE);
tmp.v = _mm512_mask_extloadunpackhi_ps(tmp.v, 0xFFFF, (uint8_t*)p+64, _MM_UPCONV_PS_NONE, _MM_HINT_NONE);
__vec16_f ret;
return _mm512_mask_mov_ps(ret.v, mask.m, tmp.v);
#endif
}
static FORCEINLINE __vec16_d __masked_load_double(void *p, __vec16_i1 mask) {
#ifdef ISPC_FORCE_ALIGNED_MEMORY
__vec16_d ret;
ret.v1 = _mm512_mask_load_pd(ret.v1, mask.m8.m1, p);
ret.v2 = _mm512_mask_load_pd(ret.v2, mask.m8.m2, (uint8_t*)p+64);
return ret;
#else
__vec16_d tmp;
tmp.v1 = _mm512_mask_extloadunpacklo_pd(tmp.v1, 0xFF, p, _MM_UPCONV_PD_NONE, _MM_HINT_NONE);
tmp.v1 = _mm512_mask_extloadunpackhi_pd(tmp.v1, 0xFF, (uint8_t*)p+64, _MM_UPCONV_PD_NONE, _MM_HINT_NONE);
tmp.v2 = _mm512_mask_extloadunpacklo_pd(tmp.v2, 0xFF, (uint8_t*)p+64, _MM_UPCONV_PD_NONE, _MM_HINT_NONE);
tmp.v2 = _mm512_mask_extloadunpackhi_pd(tmp.v2, 0xFF, (uint8_t*)p+128, _MM_UPCONV_PD_NONE, _MM_HINT_NONE);
__vec16_d ret;
ret.v1 = _mm512_mask_mov_pd(ret.v1, mask.m8.m1, tmp.v1);
ret.v2 = _mm512_mask_mov_pd(ret.v2, mask.m8.m2, tmp.v2);
return ret;
#endif
}
/*
static FORCEINLINE void __masked_store_i8(void *p, __vec16_i8 val,
__vec16_i1 mask) {
int8_t *ptr = (int8_t *)p;
for (int i = 0; i < 16; ++i)
if ((mask.v & (1 << i)) != 0)
ptr[i] = val.v[i];
}
static FORCEINLINE void __masked_store_i16(void *p, __vec16_i16 val,
__vec16_i1 mask) {
int16_t *ptr = (int16_t *)p;
for (int i = 0; i < 16; ++i)
if ((mask.v & (1 << i)) != 0)
ptr[i] = val.v[i];
}
*/
static FORCEINLINE void __masked_store_i32(void *p, __vec16_i32 val, __vec16_i1 mask) {
#ifdef ISPC_FORCE_ALIGNED_MEMORY
_mm512_mask_store_epi32(p, mask.m, val.v);
#else
__vec16_i32 tmp;
tmp.v = _mm512_extloadunpacklo_epi32(tmp.v, p, _MM_UPCONV_EPI32_NONE, _MM_HINT_NONE);
tmp.v = _mm512_extloadunpackhi_epi32(tmp.v, (uint8_t*)p+64, _MM_UPCONV_EPI32_NONE, _MM_HINT_NONE);
tmp.v = _mm512_mask_mov_epi32(tmp.v, mask.m, val.v);
_mm512_extpackstorelo_epi32(p, tmp.v, _MM_DOWNCONV_EPI32_NONE, _MM_HINT_NONE);
_mm512_extpackstorehi_epi32((uint8_t*)p+64, tmp.v, _MM_DOWNCONV_EPI32_NONE, _MM_HINT_NONE);
#endif
}
/*
static FORCEINLINE void __masked_store_i64(void *p, __vec16_i64 val,
__vec16_i1 mask) {
// TODO: this needs to change
_mm512_mask_store_epi64(p, mask, val.v1);
_mm512_mask_store_epi64((uint8_t*)p+64, mask, val.v2);
}
*/
static FORCEINLINE void __masked_store_float(void *p, __vec16_f val,
__vec16_i1 mask) {
#ifdef ISPC_FORCE_ALIGNED_MEMORY
_mm512_mask_store_ps(p, mask.m, val.v);
#else
__vec16_f tmp;
tmp.v = _mm512_extloadunpacklo_ps(tmp.v, p, _MM_UPCONV_PS_NONE, _MM_HINT_NONE);
tmp.v = _mm512_extloadunpackhi_ps(tmp.v, (uint8_t*)p+64, _MM_UPCONV_PS_NONE, _MM_HINT_NONE);
tmp.v = _mm512_mask_mov_ps(tmp.v, mask.m, val.v);
_mm512_extpackstorelo_ps(p, tmp.v, _MM_DOWNCONV_PS_NONE, _MM_HINT_NONE);
_mm512_extpackstorehi_ps((uint8_t*)p+64, tmp.v, _MM_DOWNCONV_PS_NONE, _MM_HINT_NONE);
#endif
}
static FORCEINLINE void __masked_store_double(void *p, __vec16_d val,
__vec16_i1 mask) {
#ifdef ISPC_FORCE_ALIGNED_MEMORY
_mm512_mask_store_pd(p, mask.m8.m1, val.v1);
_mm512_mask_store_pd((uint8_t*)p+64, mask.m8.m2, val.v2);
#else
__vec16_d tmp;
tmp.v1 = _mm512_extloadunpacklo_pd(tmp.v1, p, _MM_UPCONV_PD_NONE, _MM_HINT_NONE);
tmp.v1 = _mm512_extloadunpackhi_pd(tmp.v1, (uint8_t*)p+64, _MM_UPCONV_PD_NONE, _MM_HINT_NONE);
tmp.v2 = _mm512_extloadunpacklo_pd(tmp.v2, (uint8_t*)p+64, _MM_UPCONV_PD_NONE, _MM_HINT_NONE);
tmp.v2 = _mm512_extloadunpackhi_pd(tmp.v2, (uint8_t*)p+128, _MM_UPCONV_PD_NONE, _MM_HINT_NONE);
tmp.v1 = _mm512_mask_mov_pd(tmp.v1, mask.m8.m1, val.v1);
tmp.v2 = _mm512_mask_mov_pd(tmp.v2, mask.m8.m2, val.v2);
_mm512_extpackstorelo_pd(p, tmp.v1, _MM_DOWNCONV_PD_NONE, _MM_HINT_NONE);
_mm512_extpackstorehi_pd((uint8_t*)p+64, tmp.v1, _MM_DOWNCONV_PD_NONE, _MM_HINT_NONE);
_mm512_extpackstorelo_pd((uint8_t*)p+64, tmp.v2, _MM_DOWNCONV_PD_NONE, _MM_HINT_NONE);
_mm512_extpackstorehi_pd((uint8_t*)p+128, tmp.v2, _MM_DOWNCONV_PD_NONE, _MM_HINT_NONE);
#endif
}
/*
static FORCEINLINE void __masked_store_blend_i8(void *p, __vec16_i8 val,
__vec16_i1 mask) {
__masked_store_i8(p, val, mask);
}
static FORCEINLINE void __masked_store_blend_i16(void *p, __vec16_i16 val,
__vec16_i1 mask) {
__masked_store_i16(p, val, mask);
}
*/
static FORCEINLINE void __masked_store_blend_i32(void *p, __vec16_i32 val,
__vec16_i1 mask) {
__masked_store_i32(p, val, mask);
}
/*
static FORCEINLINE void __masked_store_blend_i64(void *p, __vec16_i64 val,
__vec16_i1 mask) {
__masked_store_i64(p, val, mask);
}
*/
static FORCEINLINE void __masked_store_blend_float(void *p, __vec16_f val,
__vec16_i1 mask) {
__masked_store_float(p, val, mask);
}
///////////////////////////////////////////////////////////////////////////
// gather/scatter
// offsets * offsetScale is in bytes (for all of these)
static FORCEINLINE __vec16_i8
__gather_base_offsets32_i8(uint8_t *base, uint32_t scale, __vec16_i32 offsets,
__vec16_i1 mask) {
// (iw): need to temporarily store as int because gathers can only return ints.
__vec16_i32 tmp = _mm512_mask_i32extgather_epi32(_mm512_undefined_epi32(), mask, offsets, base,
_MM_UPCONV_EPI32_SINT8, scale,
_MM_HINT_NONE);
// now, downconverting to chars into temporary char vector
__vec16_i8 ret;
_mm512_extstore_epi32(ret.v,tmp,_MM_DOWNCONV_EPI32_SINT8,_MM_HINT_NONE);
return ret;
}
static FORCEINLINE __vec16_i32
__gather_base_offsets32_i32(uint8_t *base, uint32_t scale, __vec16_i32 offsets,
__vec16_i1 mask) {
return _mm512_mask_i32extgather_epi32(_mm512_undefined_epi32(), mask, offsets,
base, _MM_UPCONV_EPI32_NONE, scale,
_MM_HINT_NONE);
}
static FORCEINLINE __vec16_f
__gather_base_offsets32_float(uint8_t *base, uint32_t scale, __vec16_i32 offsets,
__vec16_i1 mask) {
return _mm512_mask_i32extgather_ps(_mm512_undefined_ps(), mask, offsets,
base, _MM_UPCONV_PS_NONE, scale,
_MM_HINT_NONE);
}
/*! gather with 64-bit offsets.
\todo add optimization that falls back to 32-bit offset gather if
upper 32 bits are all 0es (in practice, offsets are usually array
indices, and _usually_ <4G even if the compiler cannot statically
figure out that this is the case */
static FORCEINLINE __vec16_f
__gather_base_offsets64_float(uint8_t *_base, uint32_t scale, __vec16_i64 offsets,
__vec16_i1 mask) {
// There is no gather instruction with 64-bit offsets in KNC.
// We have to manually iterate over the upper 32 bits ;-)
__vec16_i1 still_to_do = mask;
__vec16_f ret;
while (still_to_do) {
int first_active_lane = _mm_tzcnt_32((int)still_to_do);
const uint &hi32 = ((uint*)&offsets.v_hi)[first_active_lane];
__vec16_i1 match = _mm512_mask_cmp_epi32_mask(mask,offsets.v_hi,
__smear_i32<__vec16_i32>((int32_t)hi32),
_MM_CMPINT_EQ);
void * base = (void*)((unsigned long)_base +
((scale*(unsigned long)hi32) << 32));
ret = _mm512_mask_i32extgather_ps(ret, match, offsets.v_lo, base,
_MM_UPCONV_PS_NONE, scale,
_MM_HINT_NONE);
still_to_do = _mm512_kxor(match, still_to_do);
}
return ret;
}
static FORCEINLINE __vec16_i8
__gather_base_offsets64_i8(uint8_t *_base, uint32_t scale, __vec16_i64 offsets,
__vec16_i1 mask)
{
__vec16_i1 still_to_do = mask;
__vec16_i32 tmp;
while (still_to_do) {
int first_active_lane = _mm_tzcnt_32((int)still_to_do);
const uint &hi32 = ((uint*)&offsets.v_hi)[first_active_lane];
__vec16_i1 match = _mm512_mask_cmp_epi32_mask(mask,offsets.v_hi,
__smear_i32<__vec16_i32>((int32_t)hi32),
_MM_CMPINT_EQ);
void * base = (void*)((unsigned long)_base +
((scale*(unsigned long)hi32) << 32));
tmp = _mm512_mask_i32extgather_epi32(tmp, match, offsets.v_lo, base,
_MM_UPCONV_EPI32_SINT8, scale,
_MM_HINT_NONE);
still_to_do = _mm512_kxor(match,still_to_do);
}
__vec16_i8 ret;
_mm512_extstore_epi32(ret.v,tmp,_MM_DOWNCONV_EPI32_SINT8,_MM_HINT_NONE);
return ret;
}
static FORCEINLINE void
__scatter_base_offsets64_float(uint8_t *_base, uint32_t scale, __vec16_i64 offsets,
__vec16_f value,
__vec16_i1 mask) {
__vec16_i1 still_to_do = mask;
while (still_to_do) {
int first_active_lane = _mm_tzcnt_32((int)still_to_do);
const uint &hi32 = ((uint*)&offsets.v_hi)[first_active_lane];
__vec16_i1 match = _mm512_mask_cmp_epi32_mask(mask,offsets.v_hi,
__smear_i32<__vec16_i32>((int32_t)hi32),
_MM_CMPINT_EQ);
void * base = (void*)((unsigned long)_base +
((scale*(unsigned long)hi32) << 32));
_mm512_mask_i32extscatter_ps(base, match, offsets.v_lo,
value,
_MM_DOWNCONV_PS_NONE, scale,
_MM_HINT_NONE);
still_to_do = _mm512_kxor(match,still_to_do);
}
}
static FORCEINLINE void
__scatter_base_offsets64_i32(uint8_t *_base, uint32_t scale, __vec16_i64 offsets,
__vec16_i32 value,
__vec16_i1 mask) {
__vec16_i1 still_to_do = mask;
while (still_to_do) {
int first_active_lane = _mm_tzcnt_32((int)still_to_do);
const uint &hi32 = ((uint*)&offsets.v_hi)[first_active_lane];
__vec16_i1 match = _mm512_mask_cmp_epi32_mask(mask,offsets.v_hi,
__smear_i32<__vec16_i32>((int32_t)hi32),
_MM_CMPINT_EQ);
void * base = (void*)((unsigned long)_base +
((scale*(unsigned long)hi32) << 32));
_mm512_mask_i32extscatter_epi32(base, match, offsets.v_lo,
value,
_MM_DOWNCONV_EPI32_NONE, scale,
_MM_HINT_NONE);
still_to_do = _mm512_kxor(match,still_to_do);
}
}
static FORCEINLINE __vec16_i32
__gather_base_offsets64_i32(uint8_t *_base, uint32_t scale, __vec16_i64 offsets,
__vec16_i1 mask)
{
__vec16_f r = __gather_base_offsets64_float(_base,scale,offsets,mask);
return (__vec16_i32&)r;
}
//GATHER_BASE_OFFSETS(__vec16_i8, int8_t, __vec16_i32, __gather_base_offsets32_i8)
//GATHER_BASE_OFFSETS(__vec16_i16, int16_t, __vec16_i32, __gather_base_offsets32_i16)
//GATHER_BASE_OFFSETS(__vec16_i64, int64_t, __vec16_i32, __gather_base_offsets32_i64)
#define GATHER_GENERAL(VTYPE, STYPE, PTRTYPE, FUNC)
/*
static FORCEINLINE VTYPE FUNC(PTRTYPE ptrs, __vec16_i1 mask) { \
VTYPE ret; \
for (int i = 0; i < 16; ++i) \
if ((mask.v & (1 << i)) != 0) { \
STYPE *ptr = (STYPE *)ptrs.v[i]; \
ret.v[i] = *ptr; \
} \
return ret; \
}
*/
GATHER_GENERAL(__vec16_i8, int8_t, __vec16_i32, __gather32_i8)
GATHER_GENERAL(__vec16_i8, int8_t, __vec16_i64, __gather64_i8)
GATHER_GENERAL(__vec16_i16, int16_t, __vec16_i32, __gather32_i16)
GATHER_GENERAL(__vec16_i16, int16_t, __vec16_i64, __gather64_i16)
GATHER_GENERAL(__vec16_i32, int32_t, __vec16_i32, __gather32_i32)
GATHER_GENERAL(__vec16_i32, int32_t, __vec16_i64, __gather64_i32)
GATHER_GENERAL(__vec16_i64, int64_t, __vec16_i32, __gather32_i64)
GATHER_GENERAL(__vec16_i64, int64_t, __vec16_i64, __gather64_i64)
// scatter
//SCATTER_BASE_OFFSETS(__vec16_i8, int8_t, __vec16_i32, __scatter_base_offsets32_i8)
//SCATTER_BASE_OFFSETS(__vec16_i8, int8_t, __vec16_i64, __scatter_base_offsets64_i8)
//SCATTER_BASE_OFFSETS(__vec16_i16, int16_t, __vec16_i32, __scatter_base_offsets32_i16)
//SCATTER_BASE_OFFSETS(__vec16_i16, int16_t, __vec16_i64, __scatter_base_offsets64_i16)
//SCATTER_BASE_OFFSETS(__vec16_i32, int32_t, __vec16_i64, __scatter_base_offsets64_i32)
//SCATTER_BASE_OFFSETS(__vec16_i64, int64_t, __vec16_i32, __scatter_base_offsets32_i64)
//SCATTER_BASE_OFFSETS(__vec16_i64, int64_t, __vec16_i64, __scatter_base_offsets64_i64)
static FORCEINLINE void
__scatter_base_offsets32_i32(uint8_t *b, uint32_t scale, __vec16_i32 offsets,
__vec16_i32 val, __vec16_i1 mask)
{
_mm512_mask_i32extscatter_epi32(b, mask, offsets, val,
_MM_DOWNCONV_EPI32_NONE, scale,
_MM_HINT_NONE);
}
static FORCEINLINE void
__scatter_base_offsets32_float(void *base, uint32_t scale, __vec16_i32 offsets,
__vec16_f val, __vec16_i1 mask)
{
_mm512_mask_i32extscatter_ps(base, mask, offsets, val,
_MM_DOWNCONV_PS_NONE, scale,
_MM_HINT_NONE);
}
/*
static FORCEINLINE void
__scatter_base_offsets64_float(void *base, const __vec16_i64 &varyingOffset,
uint32_t scale, const __vec16_i64 &constOffset,
const __vec16_f &val, const __vec16_i1 mask)
{
__vec16_i64 offsets = __add(__mul(varyingOffset,__vec16_i64(scale)), constOffset);
_mm512_mask_i64extscatter_ps(base, mask, offsets, val, _MM_DOWNCONV_PS_NONE, _MM_SCALE_1, _MM_HINT_NONE);
}
*/
#define SCATTER_GENERAL(VTYPE, STYPE, PTRTYPE, FUNC)
/*
static FORCEINLINE void FUNC(PTRTYPE ptrs, VTYPE val, __vec16_i1 mask) { \
VTYPE ret; \
for (int i = 0; i < 16; ++i) \
if ((mask.v & (1 << i)) != 0) { \
STYPE *ptr = (STYPE *)ptrs.v[i]; \
*ptr = val.v[i]; \
} \
}
*/ SCATTER_GENERAL(__vec16_i8, int8_t, __vec16_i32, __scatter32_i8)
SCATTER_GENERAL(__vec16_i8, int8_t, __vec16_i64, __scatter64_i8)
SCATTER_GENERAL(__vec16_i16, int16_t, __vec16_i32, __scatter32_i16)
SCATTER_GENERAL(__vec16_i16, int16_t, __vec16_i64, __scatter64_i16)
SCATTER_GENERAL(__vec16_i32, int32_t, __vec16_i32, __scatter32_i32)
SCATTER_GENERAL(__vec16_i32, int32_t, __vec16_i64, __scatter64_i32)
SCATTER_GENERAL(__vec16_i64, int64_t, __vec16_i32, __scatter32_i64)
SCATTER_GENERAL(__vec16_i64, int64_t, __vec16_i64, __scatter64_i64)
///////////////////////////////////////////////////////////////////////////
// packed load/store
static FORCEINLINE int32_t __packed_load_active(uint32_t *p, __vec16_i32 *val,
__vec16_i1 mask) {
__vec16_i32 v;
v = _mm512_mask_extloadunpacklo_epi32(v, mask, p, _MM_UPCONV_EPI32_NONE, _MM_HINT_NONE);
v = _mm512_mask_extloadunpackhi_epi32(_mm512_undefined_epi32(), mask, (uint8_t*)p+64, _MM_UPCONV_EPI32_NONE, _MM_HINT_NONE);
__store<64>(val, v);
return _mm_countbits_32(uint32_t(mask));
}
static FORCEINLINE int32_t __packed_store_active(uint32_t *p, __vec16_i32 val,
__vec16_i1 mask) {
_mm512_mask_extpackstorelo_epi32(p, mask, val, _MM_DOWNCONV_EPI32_NONE, _MM_HINT_NONE);
_mm512_mask_extpackstorehi_epi32((uint8_t*)p+64, mask, val, _MM_DOWNCONV_EPI32_NONE, _MM_HINT_NONE);
return _mm_countbits_32(uint32_t(mask.m));
}
///////////////////////////////////////////////////////////////////////////
// aos/soa
/*
static FORCEINLINE void __soa_to_aos3_float(__vec16_f v0, __vec16_f v1, __vec16_f v2,
float *ptr) {
for (int i = 0; i < 16; ++i) {
*ptr++ = __extract_element(v0, i);
*ptr++ = __extract_element(v1, i);
*ptr++ = __extract_element(v2, i);
}
}
static FORCEINLINE void __aos_to_soa3_float(float *ptr, __vec16_f *out0, __vec16_f *out1,
__vec16_f *out2) {
for (int i = 0; i < 16; ++i) {
__insert_element(out0, i, *ptr++);
__insert_element(out1, i, *ptr++);
__insert_element(out2, i, *ptr++);
}
}
static FORCEINLINE void __soa_to_aos4_float(__vec16_f v0, __vec16_f v1, __vec16_f v2,
__vec16_f v3, float *ptr) {
for (int i = 0; i < 16; ++i) {
*ptr++ = __extract_element(v0, i);
*ptr++ = __extract_element(v1, i);
*ptr++ = __extract_element(v2, i);
*ptr++ = __extract_element(v3, i);
}
}
static FORCEINLINE void __aos_to_soa4_float(float *ptr, __vec16_f *out0, __vec16_f *out1,
__vec16_f *out2, __vec16_f *out3) {
for (int i = 0; i < 16; ++i) {
__insert_element(out0, i, *ptr++);
__insert_element(out1, i, *ptr++);
__insert_element(out2, i, *ptr++);
__insert_element(out3, i, *ptr++);
}
}
*/
///////////////////////////////////////////////////////////////////////////
// prefetch
static FORCEINLINE void __prefetch_read_uniform_1(const char *p) {
_mm_prefetch(p, _MM_HINT_T0); // prefetch into L1$
}
static FORCEINLINE void __prefetch_read_uniform_2(const char *p) {
_mm_prefetch(p, _MM_HINT_T1); // prefetch into L2$
}
static FORCEINLINE void __prefetch_read_uniform_3(const char *p) {
// There is no L3$ on KNC, don't want to pollute L2$ unecessarily
}
static FORCEINLINE void __prefetch_read_uniform_nt(const char *p) {
_mm_prefetch(p, _MM_HINT_T2); // prefetch into L2$ with non-temporal hint
// _mm_prefetch(p, _MM_HINT_NTA); // prefetch into L1$ with non-temporal hint
}
///////////////////////////////////////////////////////////////////////////
// atomics
static FORCEINLINE uint32_t __atomic_add(uint32_t *p, uint32_t v) {
#ifdef _MSC_VER
return InterlockedAdd((LONG volatile *)p, v) - v;
#else
return __sync_fetch_and_add(p, v);
#endif
}
static FORCEINLINE uint32_t __atomic_sub(uint32_t *p, uint32_t v) {
#ifdef _MSC_VER
return InterlockedAdd((LONG volatile *)p, -v) + v;
#else
return __sync_fetch_and_sub(p, v);
#endif
}
static FORCEINLINE uint32_t __atomic_and(uint32_t *p, uint32_t v) {
#ifdef _MSC_VER
return _InterlockedAnd((LONG volatile *)p, v);
#else
return __sync_fetch_and_and(p, v);
#endif
}
static FORCEINLINE uint32_t __atomic_or(uint32_t *p, uint32_t v) {
#ifdef _MSC_VER
return _InterlockedOr((LONG volatile *)p, v);
#else
return __sync_fetch_and_or(p, v);
#endif
}
static FORCEINLINE uint32_t __atomic_xor(uint32_t *p, uint32_t v) {
#ifdef _MSC_VER
return _InterlockedXor((LONG volatile *)p, v);
#else
return __sync_fetch_and_xor(p, v);
#endif
}
static FORCEINLINE uint32_t __atomic_min(uint32_t *p, uint32_t v) {
int32_t old, min;
do {
old = *((volatile int32_t *)p);
min = (old < (int32_t)v) ? old : (int32_t)v;
#ifdef _MSC_VER
} while (InterlockedCompareExchange((LONG volatile *)p, min, old) != old);
#else
} while (__sync_bool_compare_and_swap(p, old, min) == false);
#endif
return old;
}
static FORCEINLINE uint32_t __atomic_max(uint32_t *p, uint32_t v) {
int32_t old, max;
do {
old = *((volatile int32_t *)p);
max = (old > (int32_t)v) ? old : (int32_t)v;
#ifdef _MSC_VER
} while (InterlockedCompareExchange((LONG volatile *)p, max, old) != old);
#else
} while (__sync_bool_compare_and_swap(p, old, max) == false);
#endif
return old;
}
static FORCEINLINE uint32_t __atomic_umin(uint32_t *p, uint32_t v) {
uint32_t old, min;
do {
old = *((volatile uint32_t *)p);
min = (old < v) ? old : v;
#ifdef _MSC_VER
} while (InterlockedCompareExchange((LONG volatile *)p, min, old) != old);
#else
} while (__sync_bool_compare_and_swap(p, old, min) == false);
#endif
return old;
}
static FORCEINLINE uint32_t __atomic_umax(uint32_t *p, uint32_t v) {
uint32_t old, max;
do {
old = *((volatile uint32_t *)p);
max = (old > v) ? old : v;
#ifdef _MSC_VER
} while (InterlockedCompareExchange((LONG volatile *)p, max, old) != old);
#else
} while (__sync_bool_compare_and_swap(p, old, max) == false);
#endif
return old;
}
static FORCEINLINE uint32_t __atomic_xchg(uint32_t *p, uint32_t v) {
#ifdef _MSC_VER
return InterlockedExchange((LONG volatile *)p, v);
#else
return __sync_lock_test_and_set(p, v);
#endif
}
static FORCEINLINE uint32_t __atomic_cmpxchg(uint32_t *p, uint32_t cmpval,
uint32_t newval) {
#ifdef _MSC_VER
return InterlockedCompareExchange((LONG volatile *)p, newval, cmpval);
#else
return __sync_val_compare_and_swap(p, cmpval, newval);
#endif
}
static FORCEINLINE uint64_t __atomic_add(uint64_t *p, uint64_t v) {
#ifdef _MSC_VER
return InterlockedAdd64((LONGLONG volatile *)p, v) - v;
#else
return __sync_fetch_and_add(p, v);
#endif
}
static FORCEINLINE uint64_t __atomic_sub(uint64_t *p, uint64_t v) {
#ifdef _MSC_VER
return InterlockedAdd64((LONGLONG volatile *)p, -v) + v;
#else
return __sync_fetch_and_sub(p, v);
#endif
}
static FORCEINLINE uint64_t __atomic_and(uint64_t *p, uint64_t v) {
#ifdef _MSC_VER
return InterlockedAnd64((LONGLONG volatile *)p, v) - v;
#else
return __sync_fetch_and_and(p, v);
#endif
}
static FORCEINLINE uint64_t __atomic_or(uint64_t *p, uint64_t v) {
#ifdef _MSC_VER
return InterlockedOr64((LONGLONG volatile *)p, v) - v;
#else
return __sync_fetch_and_or(p, v);
#endif
}
static FORCEINLINE uint64_t __atomic_xor(uint64_t *p, uint64_t v) {
#ifdef _MSC_VER
return InterlockedXor64((LONGLONG volatile *)p, v) - v;
#else
return __sync_fetch_and_xor(p, v);
#endif
}
static FORCEINLINE uint64_t __atomic_min(uint64_t *p, uint64_t v) {
int64_t old, min;
do {
old = *((volatile int64_t *)p);
min = (old < (int64_t)v) ? old : (int64_t)v;
#ifdef _MSC_VER
} while (InterlockedCompareExchange64((LONGLONG volatile *)p, min, old) != old);
#else
} while (__sync_bool_compare_and_swap(p, old, min) == false);
#endif
return old;
}
static FORCEINLINE uint64_t __atomic_max(uint64_t *p, uint64_t v) {
int64_t old, max;
do {
old = *((volatile int64_t *)p);
max = (old > (int64_t)v) ? old : (int64_t)v;
#ifdef _MSC_VER
} while (InterlockedCompareExchange64((LONGLONG volatile *)p, max, old) != old);
#else
} while (__sync_bool_compare_and_swap(p, old, max) == false);
#endif
return old;
}
static FORCEINLINE uint64_t __atomic_umin(uint64_t *p, uint64_t v) {
uint64_t old, min;
do {
old = *((volatile uint64_t *)p);
min = (old < v) ? old : v;
#ifdef _MSC_VER
} while (InterlockedCompareExchange64((LONGLONG volatile *)p, min, old) != old);
#else
} while (__sync_bool_compare_and_swap(p, old, min) == false);
#endif
return old;
}
static FORCEINLINE uint64_t __atomic_umax(uint64_t *p, uint64_t v) {
uint64_t old, max;
do {
old = *((volatile uint64_t *)p);
max = (old > v) ? old : v;
#ifdef _MSC_VER
} while (InterlockedCompareExchange64((LONGLONG volatile *)p, max, old) != old);
#else
} while (__sync_bool_compare_and_swap(p, old, max) == false);
#endif
return old;
}
static FORCEINLINE uint64_t __atomic_xchg(uint64_t *p, uint64_t v) {
#ifdef _MSC_VER
return InterlockedExchange64((LONGLONG volatile *)p, v);
#else
return __sync_lock_test_and_set(p, v);
#endif
}
static FORCEINLINE uint64_t __atomic_cmpxchg(uint64_t *p, uint64_t cmpval,
uint64_t newval) {
#ifdef _MSC_VER
return InterlockedCompareExchange64((LONGLONG volatile *)p, newval, cmpval);
#else
return __sync_val_compare_and_swap(p, cmpval, newval);
#endif
}
#undef FORCEINLINE
#undef PRE_ALIGN
#undef POST_ALIGN
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