1
0
mirror of https://github.com/f4exb/sdrangel.git synced 2024-11-14 12:22:00 -05:00
sdrangel/plugins/channelrx/demoddatv/ldpctool/avx2.h

996 lines
20 KiB
C++

///////////////////////////////////////////////////////////////////////////////////////
// Copyright (C) 2021 Edouard Griffiths, F4EXB <f4exb06@gmail.com> //
// //
// This program is free software; you can redistribute it and/or modify //
// it under the terms of the GNU General Public License as published by //
// the Free Software Foundation as version 3 of the License, or //
// (at your option) any later version. //
// //
// This program is distributed in the hope that it will be useful, //
// but WITHOUT ANY WARRANTY; without even the implied warranty of //
// MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the //
// GNU General Public License V3 for more details. //
// //
// You should have received a copy of the GNU General Public License //
// along with this program. If not, see <http://www.gnu.org/licenses/>. //
///////////////////////////////////////////////////////////////////////////////////////
/*
Intel AVX2 acceleration
Copyright 2018 Ahmet Inan <inan@aicodix.de>
*/
#ifndef AVX2_HH
#define AVX2_HH
#include <immintrin.h>
#include "simd.h"
namespace ldpctool {
template <>
union SIMD<float, 8>
{
static const int SIZE = 8;
typedef float value_type;
typedef uint32_t uint_type;
__m256 m;
value_type v[SIZE];
uint_type u[SIZE];
};
template <>
union SIMD<double, 4>
{
static const int SIZE = 4;
typedef double value_type;
typedef uint64_t uint_type;
__m256d m;
value_type v[SIZE];
uint_type u[SIZE];
};
template <>
union SIMD<int8_t, 32>
{
static const int SIZE = 32;
typedef int8_t value_type;
typedef uint8_t uint_type;
__m256i m;
value_type v[SIZE];
uint_type u[SIZE];
};
template <>
union SIMD<int16_t, 16>
{
static const int SIZE = 16;
typedef int16_t value_type;
typedef uint16_t uint_type;
__m256i m;
value_type v[SIZE];
uint_type u[SIZE];
};
template <>
union SIMD<int32_t, 8>
{
static const int SIZE = 8;
typedef int32_t value_type;
typedef uint32_t uint_type;
__m256i m;
value_type v[SIZE];
uint_type u[SIZE];
};
template <>
union SIMD<int64_t, 4>
{
static const int SIZE = 4;
typedef int64_t value_type;
typedef uint64_t uint_type;
__m256i m;
value_type v[SIZE];
uint_type u[SIZE];
};
template <>
union SIMD<uint8_t, 32>
{
static const int SIZE = 32;
typedef uint8_t value_type;
typedef uint8_t uint_type;
__m256i m;
value_type v[SIZE];
uint_type u[SIZE];
};
template <>
union SIMD<uint16_t, 16>
{
static const int SIZE = 16;
typedef uint16_t value_type;
typedef uint16_t uint_type;
__m256i m;
value_type v[SIZE];
uint_type u[SIZE];
};
template <>
union SIMD<uint32_t, 8>
{
static const int SIZE = 8;
typedef uint32_t value_type;
typedef uint32_t uint_type;
__m256i m;
value_type v[SIZE];
uint_type u[SIZE];
};
template <>
union SIMD<uint64_t, 4>
{
static const int SIZE = 4;
typedef uint64_t value_type;
typedef uint64_t uint_type;
__m256i m;
value_type v[SIZE];
uint_type u[SIZE];
};
template <>
inline SIMD<float, 8> vreinterpret(SIMD<uint32_t, 8> a)
{
SIMD<float, 8> tmp;
tmp.m = (__m256)a.m;
return tmp;
}
template <>
inline SIMD<uint32_t, 8> vreinterpret(SIMD<float, 8> a)
{
SIMD<uint32_t, 8> tmp;
tmp.m = (__m256i)a.m;
return tmp;
}
template <>
inline SIMD<double, 4> vreinterpret(SIMD<uint64_t, 4> a)
{
SIMD<double, 4> tmp;
tmp.m = (__m256d)a.m;
return tmp;
}
template <>
inline SIMD<uint64_t, 4> vreinterpret(SIMD<double, 4> a)
{
SIMD<uint64_t, 4> tmp;
tmp.m = (__m256i)a.m;
return tmp;
}
template <>
inline SIMD<uint8_t, 32> vreinterpret(SIMD<int8_t, 32> a)
{
SIMD<uint8_t, 32> tmp;
tmp.m = (__m256i)a.m;
return tmp;
}
template <>
inline SIMD<int8_t, 32> vreinterpret(SIMD<uint8_t, 32> a)
{
SIMD<int8_t, 32> tmp;
tmp.m = (__m256i)a.m;
return tmp;
}
template <>
inline SIMD<uint16_t, 16> vreinterpret(SIMD<int16_t, 16> a)
{
SIMD<uint16_t, 16> tmp;
tmp.m = (__m256i)a.m;
return tmp;
}
template <>
inline SIMD<int16_t, 16> vreinterpret(SIMD<uint16_t, 16> a)
{
SIMD<int16_t, 16> tmp;
tmp.m = (__m256i)a.m;
return tmp;
}
template <>
inline SIMD<uint32_t, 8> vreinterpret(SIMD<int32_t, 8> a)
{
SIMD<uint32_t, 8> tmp;
tmp.m = (__m256i)a.m;
return tmp;
}
template <>
inline SIMD<int32_t, 8> vreinterpret(SIMD<uint32_t, 8> a)
{
SIMD<int32_t, 8> tmp;
tmp.m = (__m256i)a.m;
return tmp;
}
template <>
inline SIMD<uint64_t, 4> vreinterpret(SIMD<int64_t, 4> a)
{
SIMD<uint64_t, 4> tmp;
tmp.m = (__m256i)a.m;
return tmp;
}
template <>
inline SIMD<int64_t, 4> vreinterpret(SIMD<uint64_t, 4> a)
{
SIMD<int64_t, 4> tmp;
tmp.m = (__m256i)a.m;
return tmp;
}
template <>
inline SIMD<float, 8> vdup<SIMD<float, 8>>(float a)
{
SIMD<float, 8> tmp;
tmp.m = _mm256_set1_ps(a);
return tmp;
}
template <>
inline SIMD<double, 4> vdup<SIMD<double, 4>>(double a)
{
SIMD<double, 4> tmp;
tmp.m = _mm256_set1_pd(a);
return tmp;
}
template <>
inline SIMD<int8_t, 32> vdup<SIMD<int8_t, 32>>(int8_t a)
{
SIMD<int8_t, 32> tmp;
tmp.m = _mm256_set1_epi8(a);
return tmp;
}
template <>
inline SIMD<int16_t, 16> vdup<SIMD<int16_t, 16>>(int16_t a)
{
SIMD<int16_t, 16> tmp;
tmp.m = _mm256_set1_epi16(a);
return tmp;
}
template <>
inline SIMD<int32_t, 8> vdup<SIMD<int32_t, 8>>(int32_t a)
{
SIMD<int32_t, 8> tmp;
tmp.m = _mm256_set1_epi32(a);
return tmp;
}
template <>
inline SIMD<int64_t, 4> vdup<SIMD<int64_t, 4>>(int64_t a)
{
SIMD<int64_t, 4> tmp;
tmp.m = _mm256_set1_epi64x(a);
return tmp;
}
template <>
inline SIMD<float, 8> vzero()
{
SIMD<float, 8> tmp;
tmp.m = _mm256_setzero_ps();
return tmp;
}
template <>
inline SIMD<double, 4> vzero()
{
SIMD<double, 4> tmp;
tmp.m = _mm256_setzero_pd();
return tmp;
}
template <>
inline SIMD<int8_t, 32> vzero()
{
SIMD<int8_t, 32> tmp;
tmp.m = _mm256_setzero_si256();
return tmp;
}
template <>
inline SIMD<int16_t, 16> vzero()
{
SIMD<int16_t, 16> tmp;
tmp.m = _mm256_setzero_si256();
return tmp;
}
template <>
inline SIMD<int32_t, 8> vzero()
{
SIMD<int32_t, 8> tmp;
tmp.m = _mm256_setzero_si256();
return tmp;
}
template <>
inline SIMD<int64_t, 4> vzero()
{
SIMD<int64_t, 4> tmp;
tmp.m = _mm256_setzero_si256();
return tmp;
}
template <>
inline SIMD<float, 8> vadd(SIMD<float, 8> a, SIMD<float, 8> b)
{
SIMD<float, 8> tmp;
tmp.m = _mm256_add_ps(a.m, b.m);
return tmp;
}
template <>
inline SIMD<double, 4> vadd(SIMD<double, 4> a, SIMD<double, 4> b)
{
SIMD<double, 4> tmp;
tmp.m = _mm256_add_pd(a.m, b.m);
return tmp;
}
template <>
inline SIMD<int8_t, 32> vadd(SIMD<int8_t, 32> a, SIMD<int8_t, 32> b)
{
SIMD<int8_t, 32> tmp;
tmp.m = _mm256_add_epi8(a.m, b.m);
return tmp;
}
template <>
inline SIMD<int16_t, 16> vadd(SIMD<int16_t, 16> a, SIMD<int16_t, 16> b)
{
SIMD<int16_t, 16> tmp;
tmp.m = _mm256_add_epi16(a.m, b.m);
return tmp;
}
template <>
inline SIMD<int32_t, 8> vadd(SIMD<int32_t, 8> a, SIMD<int32_t, 8> b)
{
SIMD<int32_t, 8> tmp;
tmp.m = _mm256_add_epi32(a.m, b.m);
return tmp;
}
template <>
inline SIMD<int64_t, 4> vadd(SIMD<int64_t, 4> a, SIMD<int64_t, 4> b)
{
SIMD<int64_t, 4> tmp;
tmp.m = _mm256_add_epi64(a.m, b.m);
return tmp;
}
template <>
inline SIMD<int8_t, 32> vqadd(SIMD<int8_t, 32> a, SIMD<int8_t, 32> b)
{
SIMD<int8_t, 32> tmp;
tmp.m = _mm256_adds_epi8(a.m, b.m);
return tmp;
}
template <>
inline SIMD<int16_t, 16> vqadd(SIMD<int16_t, 16> a, SIMD<int16_t, 16> b)
{
SIMD<int16_t, 16> tmp;
tmp.m = _mm256_adds_epi16(a.m, b.m);
return tmp;
}
template <>
inline SIMD<float, 8> vsub(SIMD<float, 8> a, SIMD<float, 8> b)
{
SIMD<float, 8> tmp;
tmp.m = _mm256_sub_ps(a.m, b.m);
return tmp;
}
template <>
inline SIMD<double, 4> vsub(SIMD<double, 4> a, SIMD<double, 4> b)
{
SIMD<double, 4> tmp;
tmp.m = _mm256_sub_pd(a.m, b.m);
return tmp;
}
template <>
inline SIMD<int8_t, 32> vsub(SIMD<int8_t, 32> a, SIMD<int8_t, 32> b)
{
SIMD<int8_t, 32> tmp;
tmp.m = _mm256_sub_epi8(a.m, b.m);
return tmp;
}
template <>
inline SIMD<int16_t, 16> vsub(SIMD<int16_t, 16> a, SIMD<int16_t, 16> b)
{
SIMD<int16_t, 16> tmp;
tmp.m = _mm256_sub_epi16(a.m, b.m);
return tmp;
}
template <>
inline SIMD<int32_t, 8> vsub(SIMD<int32_t, 8> a, SIMD<int32_t, 8> b)
{
SIMD<int32_t, 8> tmp;
tmp.m = _mm256_sub_epi32(a.m, b.m);
return tmp;
}
template <>
inline SIMD<int64_t, 4> vsub(SIMD<int64_t, 4> a, SIMD<int64_t, 4> b)
{
SIMD<int64_t, 4> tmp;
tmp.m = _mm256_sub_epi64(a.m, b.m);
return tmp;
}
template <>
inline SIMD<int8_t, 32> vqsub(SIMD<int8_t, 32> a, SIMD<int8_t, 32> b)
{
SIMD<int8_t, 32> tmp;
tmp.m = _mm256_subs_epi8(a.m, b.m);
return tmp;
}
template <>
inline SIMD<int16_t, 16> vqsub(SIMD<int16_t, 16> a, SIMD<int16_t, 16> b)
{
SIMD<int16_t, 16> tmp;
tmp.m = _mm256_subs_epi16(a.m, b.m);
return tmp;
}
template <>
inline SIMD<uint8_t, 32> vqsub(SIMD<uint8_t, 32> a, SIMD<uint8_t, 32> b)
{
SIMD<uint8_t, 32> tmp;
tmp.m = _mm256_subs_epu8(a.m, b.m);
return tmp;
}
template <>
inline SIMD<uint16_t, 16> vqsub(SIMD<uint16_t, 16> a, SIMD<uint16_t, 16> b)
{
SIMD<uint16_t, 16> tmp;
tmp.m = _mm256_subs_epu16(a.m, b.m);
return tmp;
}
template <>
inline SIMD<float, 8> vabs(SIMD<float, 8> a)
{
SIMD<float, 8> tmp;
tmp.m = _mm256_andnot_ps(_mm256_set1_ps(-0.f), a.m);
return tmp;
}
template <>
inline SIMD<double, 4> vabs(SIMD<double, 4> a)
{
SIMD<double, 4> tmp;
tmp.m = _mm256_andnot_pd(_mm256_set1_pd(-0.), a.m);
return tmp;
}
template <>
inline SIMD<int8_t, 32> vqabs(SIMD<int8_t, 32> a)
{
SIMD<int8_t, 32> tmp;
tmp.m = _mm256_abs_epi8(_mm256_max_epi8(a.m, _mm256_set1_epi8(-INT8_MAX)));
return tmp;
}
template <>
inline SIMD<int16_t, 16> vqabs(SIMD<int16_t, 16> a)
{
SIMD<int16_t, 16> tmp;
tmp.m = _mm256_abs_epi16(_mm256_max_epi16(a.m, _mm256_set1_epi16(-INT16_MAX)));
return tmp;
}
template <>
inline SIMD<int32_t, 8> vqabs(SIMD<int32_t, 8> a)
{
SIMD<int32_t, 8> tmp;
tmp.m = _mm256_abs_epi32(_mm256_max_epi32(a.m, _mm256_set1_epi32(-INT32_MAX)));
return tmp;
}
template <>
inline SIMD<float, 8> vsign(SIMD<float, 8> a, SIMD<float, 8> b)
{
SIMD<float, 8> tmp;
tmp.m = _mm256_andnot_ps(
_mm256_cmp_ps(b.m, _mm256_setzero_ps(), _CMP_EQ_OQ),
_mm256_xor_ps(a.m, _mm256_and_ps(_mm256_set1_ps(-0.f), b.m)));
return tmp;
}
template <>
inline SIMD<double, 4> vsign(SIMD<double, 4> a, SIMD<double, 4> b)
{
SIMD<double, 4> tmp;
tmp.m = _mm256_andnot_pd(
_mm256_cmp_pd(b.m, _mm256_setzero_pd(), _CMP_EQ_OQ),
_mm256_xor_pd(a.m, _mm256_and_pd(_mm256_set1_pd(-0.), b.m)));
return tmp;
}
template <>
inline SIMD<int8_t, 32> vsign(SIMD<int8_t, 32> a, SIMD<int8_t, 32> b)
{
SIMD<int8_t, 32> tmp;
tmp.m = _mm256_sign_epi8(a.m, b.m);
return tmp;
}
template <>
inline SIMD<int16_t, 16> vsign(SIMD<int16_t, 16> a, SIMD<int16_t, 16> b)
{
SIMD<int16_t, 16> tmp;
tmp.m = _mm256_sign_epi16(a.m, b.m);
return tmp;
}
template <>
inline SIMD<int32_t, 8> vsign(SIMD<int32_t, 8> a, SIMD<int32_t, 8> b)
{
SIMD<int32_t, 8> tmp;
tmp.m = _mm256_sign_epi32(a.m, b.m);
return tmp;
}
template <>
inline SIMD<uint8_t, 32> vorr(SIMD<uint8_t, 32> a, SIMD<uint8_t, 32> b)
{
SIMD<uint8_t, 32> tmp;
tmp.m = _mm256_or_si256(a.m, b.m);
return tmp;
}
template <>
inline SIMD<uint16_t, 16> vorr(SIMD<uint16_t, 16> a, SIMD<uint16_t, 16> b)
{
SIMD<uint16_t, 16> tmp;
tmp.m = _mm256_or_si256(a.m, b.m);
return tmp;
}
template <>
inline SIMD<uint32_t, 8> vorr(SIMD<uint32_t, 8> a, SIMD<uint32_t, 8> b)
{
SIMD<uint32_t, 8> tmp;
tmp.m = _mm256_or_si256(a.m, b.m);
return tmp;
}
template <>
inline SIMD<uint64_t, 4> vorr(SIMD<uint64_t, 4> a, SIMD<uint64_t, 4> b)
{
SIMD<uint64_t, 4> tmp;
tmp.m = _mm256_or_si256(a.m, b.m);
return tmp;
}
template <>
inline SIMD<uint8_t, 32> vand(SIMD<uint8_t, 32> a, SIMD<uint8_t, 32> b)
{
SIMD<uint8_t, 32> tmp;
tmp.m = _mm256_and_si256(a.m, b.m);
return tmp;
}
template <>
inline SIMD<uint16_t, 16> vand(SIMD<uint16_t, 16> a, SIMD<uint16_t, 16> b)
{
SIMD<uint16_t, 16> tmp;
tmp.m = _mm256_and_si256(a.m, b.m);
return tmp;
}
template <>
inline SIMD<uint32_t, 8> vand(SIMD<uint32_t, 8> a, SIMD<uint32_t, 8> b)
{
SIMD<uint32_t, 8> tmp;
tmp.m = _mm256_and_si256(a.m, b.m);
return tmp;
}
template <>
inline SIMD<uint64_t, 4> vand(SIMD<uint64_t, 4> a, SIMD<uint64_t, 4> b)
{
SIMD<uint64_t, 4> tmp;
tmp.m = _mm256_and_si256(a.m, b.m);
return tmp;
}
template <>
inline SIMD<uint8_t, 32> veor(SIMD<uint8_t, 32> a, SIMD<uint8_t, 32> b)
{
SIMD<uint8_t, 32> tmp;
tmp.m = _mm256_xor_si256(a.m, b.m);
return tmp;
}
template <>
inline SIMD<uint16_t, 16> veor(SIMD<uint16_t, 16> a, SIMD<uint16_t, 16> b)
{
SIMD<uint16_t, 16> tmp;
tmp.m = _mm256_xor_si256(a.m, b.m);
return tmp;
}
template <>
inline SIMD<uint32_t, 8> veor(SIMD<uint32_t, 8> a, SIMD<uint32_t, 8> b)
{
SIMD<uint32_t, 8> tmp;
tmp.m = _mm256_xor_si256(a.m, b.m);
return tmp;
}
template <>
inline SIMD<uint64_t, 4> veor(SIMD<uint64_t, 4> a, SIMD<uint64_t, 4> b)
{
SIMD<uint64_t, 4> tmp;
tmp.m = _mm256_xor_si256(a.m, b.m);
return tmp;
}
template <>
inline SIMD<uint8_t, 32> vbic(SIMD<uint8_t, 32> a, SIMD<uint8_t, 32> b)
{
SIMD<uint8_t, 32> tmp;
tmp.m = _mm256_andnot_si256(b.m, a.m);
return tmp;
}
template <>
inline SIMD<uint16_t, 16> vbic(SIMD<uint16_t, 16> a, SIMD<uint16_t, 16> b)
{
SIMD<uint16_t, 16> tmp;
tmp.m = _mm256_andnot_si256(b.m, a.m);
return tmp;
}
template <>
inline SIMD<uint32_t, 8> vbic(SIMD<uint32_t, 8> a, SIMD<uint32_t, 8> b)
{
SIMD<uint32_t, 8> tmp;
tmp.m = _mm256_andnot_si256(b.m, a.m);
return tmp;
}
template <>
inline SIMD<uint64_t, 4> vbic(SIMD<uint64_t, 4> a, SIMD<uint64_t, 4> b)
{
SIMD<uint64_t, 4> tmp;
tmp.m = _mm256_andnot_si256(b.m, a.m);
return tmp;
}
template <>
inline SIMD<uint8_t, 32> vbsl(SIMD<uint8_t, 32> a, SIMD<uint8_t, 32> b, SIMD<uint8_t, 32> c)
{
SIMD<uint8_t, 32> tmp;
tmp.m = _mm256_or_si256(_mm256_and_si256(a.m, b.m), _mm256_andnot_si256(a.m, c.m));
return tmp;
}
template <>
inline SIMD<uint16_t, 16> vbsl(SIMD<uint16_t, 16> a, SIMD<uint16_t, 16> b, SIMD<uint16_t, 16> c)
{
SIMD<uint16_t, 16> tmp;
tmp.m = _mm256_or_si256(_mm256_and_si256(a.m, b.m), _mm256_andnot_si256(a.m, c.m));
return tmp;
}
template <>
inline SIMD<uint32_t, 8> vbsl(SIMD<uint32_t, 8> a, SIMD<uint32_t, 8> b, SIMD<uint32_t, 8> c)
{
SIMD<uint32_t, 8> tmp;
tmp.m = _mm256_or_si256(_mm256_and_si256(a.m, b.m), _mm256_andnot_si256(a.m, c.m));
return tmp;
}
template <>
inline SIMD<uint64_t, 4> vbsl(SIMD<uint64_t, 4> a, SIMD<uint64_t, 4> b, SIMD<uint64_t, 4> c)
{
SIMD<uint64_t, 4> tmp;
tmp.m = _mm256_or_si256(_mm256_and_si256(a.m, b.m), _mm256_andnot_si256(a.m, c.m));
return tmp;
}
template <>
inline SIMD<uint32_t, 8> vceqz(SIMD<float, 8> a)
{
SIMD<uint32_t, 8> tmp;
tmp.m = (__m256i)_mm256_cmp_ps(a.m, _mm256_setzero_ps(), _CMP_EQ_OQ);
return tmp;
}
template <>
inline SIMD<uint64_t, 4> vceqz(SIMD<double, 4> a)
{
SIMD<uint64_t, 4> tmp;
tmp.m = (__m256i)_mm256_cmp_pd(a.m, _mm256_setzero_pd(), _CMP_EQ_OQ);
return tmp;
}
template <>
inline SIMD<uint8_t, 32> vceqz(SIMD<int8_t, 32> a)
{
SIMD<uint8_t, 32> tmp;
tmp.m = _mm256_cmpeq_epi8(a.m, _mm256_setzero_si256());
return tmp;
}
template <>
inline SIMD<uint16_t, 16> vceqz(SIMD<int16_t, 16> a)
{
SIMD<uint16_t, 16> tmp;
tmp.m = _mm256_cmpeq_epi16(a.m, _mm256_setzero_si256());
return tmp;
}
template <>
inline SIMD<uint32_t, 8> vceqz(SIMD<int32_t, 8> a)
{
SIMD<uint32_t, 8> tmp;
tmp.m = _mm256_cmpeq_epi32(a.m, _mm256_setzero_si256());
return tmp;
}
template <>
inline SIMD<uint64_t, 4> vceqz(SIMD<int64_t, 4> a)
{
SIMD<uint64_t, 4> tmp;
tmp.m = _mm256_cmpeq_epi64(a.m, _mm256_setzero_si256());
return tmp;
}
template <>
inline SIMD<uint32_t, 8> vceq(SIMD<float, 8> a, SIMD<float, 8> b)
{
SIMD<uint32_t, 8> tmp;
tmp.m = (__m256i)_mm256_cmp_ps(a.m, b.m, _CMP_EQ_OQ);
return tmp;
}
template <>
inline SIMD<uint64_t, 4> vceq(SIMD<double, 4> a, SIMD<double, 4> b)
{
SIMD<uint64_t, 4> tmp;
tmp.m = (__m256i)_mm256_cmp_pd(a.m, b.m, _CMP_EQ_OQ);
return tmp;
}
template <>
inline SIMD<uint8_t, 32> vceq(SIMD<int8_t, 32> a, SIMD<int8_t, 32> b)
{
SIMD<uint8_t, 32> tmp;
tmp.m = _mm256_cmpeq_epi8(a.m, b.m);
return tmp;
}
template <>
inline SIMD<uint16_t, 16> vceq(SIMD<int16_t, 16> a, SIMD<int16_t, 16> b)
{
SIMD<uint16_t, 16> tmp;
tmp.m = _mm256_cmpeq_epi16(a.m, b.m);
return tmp;
}
template <>
inline SIMD<uint32_t, 8> vceq(SIMD<int32_t, 8> a, SIMD<int32_t, 8> b)
{
SIMD<uint32_t, 8> tmp;
tmp.m = _mm256_cmpeq_epi32(a.m, b.m);
return tmp;
}
template <>
inline SIMD<uint64_t, 4> vceq(SIMD<int64_t, 4> a, SIMD<int64_t, 4> b)
{
SIMD<uint64_t, 4> tmp;
tmp.m = _mm256_cmpeq_epi64(a.m, b.m);
return tmp;
}
template <>
inline SIMD<uint32_t, 8> vcgtz(SIMD<float, 8> a)
{
SIMD<uint32_t, 8> tmp;
tmp.m = (__m256i)_mm256_cmp_ps(a.m, _mm256_setzero_ps(), _CMP_GT_OQ);
return tmp;
}
template <>
inline SIMD<uint64_t, 4> vcgtz(SIMD<double, 4> a)
{
SIMD<uint64_t, 4> tmp;
tmp.m = (__m256i)_mm256_cmp_pd(a.m, _mm256_setzero_pd(), _CMP_GT_OQ);
return tmp;
}
template <>
inline SIMD<uint8_t, 32> vcgtz(SIMD<int8_t, 32> a)
{
SIMD<uint8_t, 32> tmp;
tmp.m = _mm256_cmpgt_epi8(a.m, _mm256_setzero_si256());
return tmp;
}
template <>
inline SIMD<uint16_t, 16> vcgtz(SIMD<int16_t, 16> a)
{
SIMD<uint16_t, 16> tmp;
tmp.m = _mm256_cmpgt_epi16(a.m, _mm256_setzero_si256());
return tmp;
}
template <>
inline SIMD<uint32_t, 8> vcgtz(SIMD<int32_t, 8> a)
{
SIMD<uint32_t, 8> tmp;
tmp.m = _mm256_cmpgt_epi32(a.m, _mm256_setzero_si256());
return tmp;
}
template <>
inline SIMD<uint64_t, 4> vcgtz(SIMD<int64_t, 4> a)
{
SIMD<uint64_t, 4> tmp;
tmp.m = _mm256_cmpgt_epi64(a.m, _mm256_setzero_si256());
return tmp;
}
template <>
inline SIMD<uint32_t, 8> vcltz(SIMD<float, 8> a)
{
SIMD<uint32_t, 8> tmp;
tmp.m = (__m256i)_mm256_cmp_ps(a.m, _mm256_setzero_ps(), _CMP_LT_OQ);
return tmp;
}
template <>
inline SIMD<uint64_t, 4> vcltz(SIMD<double, 4> a)
{
SIMD<uint64_t, 4> tmp;
tmp.m = (__m256i)_mm256_cmp_pd(a.m, _mm256_setzero_pd(), _CMP_LT_OQ);
return tmp;
}
template <>
inline SIMD<uint8_t, 32> vcltz(SIMD<int8_t, 32> a)
{
SIMD<uint8_t, 32> tmp;
tmp.m = _mm256_cmpgt_epi8(_mm256_setzero_si256(), a.m);
return tmp;
}
template <>
inline SIMD<uint16_t, 16> vcltz(SIMD<int16_t, 16> a)
{
SIMD<uint16_t, 16> tmp;
tmp.m = _mm256_cmpgt_epi16(_mm256_setzero_si256(), a.m);
return tmp;
}
template <>
inline SIMD<uint32_t, 8> vcltz(SIMD<int32_t, 8> a)
{
SIMD<uint32_t, 8> tmp;
tmp.m = _mm256_cmpgt_epi32(_mm256_setzero_si256(), a.m);
return tmp;
}
template <>
inline SIMD<uint64_t, 4> vcltz(SIMD<int64_t, 4> a)
{
SIMD<uint64_t, 4> tmp;
tmp.m = _mm256_cmpgt_epi64(_mm256_setzero_si256(), a.m);
return tmp;
}
template <>
inline SIMD<float, 8> vmin(SIMD<float, 8> a, SIMD<float, 8> b)
{
SIMD<float, 8> tmp;
tmp.m = _mm256_min_ps(a.m, b.m);
return tmp;
}
template <>
inline SIMD<double, 4> vmin(SIMD<double, 4> a, SIMD<double, 4> b)
{
SIMD<double, 4> tmp;
tmp.m = _mm256_min_pd(a.m, b.m);
return tmp;
}
template <>
inline SIMD<int8_t, 32> vmin(SIMD<int8_t, 32> a, SIMD<int8_t, 32> b)
{
SIMD<int8_t, 32> tmp;
tmp.m = _mm256_min_epi8(a.m, b.m);
return tmp;
}
template <>
inline SIMD<int16_t, 16> vmin(SIMD<int16_t, 16> a, SIMD<int16_t, 16> b)
{
SIMD<int16_t, 16> tmp;
tmp.m = _mm256_min_epi16(a.m, b.m);
return tmp;
}
template <>
inline SIMD<int32_t, 8> vmin(SIMD<int32_t, 8> a, SIMD<int32_t, 8> b)
{
SIMD<int32_t, 8> tmp;
tmp.m = _mm256_min_epi32(a.m, b.m);
return tmp;
}
template <>
inline SIMD<float, 8> vmax(SIMD<float, 8> a, SIMD<float, 8> b)
{
SIMD<float, 8> tmp;
tmp.m = _mm256_max_ps(a.m, b.m);
return tmp;
}
template <>
inline SIMD<double, 4> vmax(SIMD<double, 4> a, SIMD<double, 4> b)
{
SIMD<double, 4> tmp;
tmp.m = _mm256_max_pd(a.m, b.m);
return tmp;
}
template <>
inline SIMD<int8_t, 32> vmax(SIMD<int8_t, 32> a, SIMD<int8_t, 32> b)
{
SIMD<int8_t, 32> tmp;
tmp.m = _mm256_max_epi8(a.m, b.m);
return tmp;
}
template <>
inline SIMD<int16_t, 16> vmax(SIMD<int16_t, 16> a, SIMD<int16_t, 16> b)
{
SIMD<int16_t, 16> tmp;
tmp.m = _mm256_max_epi16(a.m, b.m);
return tmp;
}
template <>
inline SIMD<int32_t, 8> vmax(SIMD<int32_t, 8> a, SIMD<int32_t, 8> b)
{
SIMD<int32_t, 8> tmp;
tmp.m = _mm256_max_epi32(a.m, b.m);
return tmp;
}
} // namespace ldpctool
#endif