/* * Copyright (C) NHR@FAU, University Erlangen-Nuremberg. * All rights reserved. This file is part of MD-Bench. * Use of this source code is governed by a LGPL-3.0 * license that can be found in the LICENSE file. */ #include #include #include #define MD_SIMD_FLOAT __m256d #define MD_SIMD_INT __m128i #define MD_SIMD_MASK __m256d static inline MD_SIMD_FLOAT simd_broadcast(MD_FLOAT scalar) { return _mm256_set1_pd(scalar); } static inline MD_SIMD_FLOAT simd_zero() { return _mm256_set1_pd(0.0); } static inline MD_SIMD_FLOAT simd_add(MD_SIMD_FLOAT a, MD_SIMD_FLOAT b) { return _mm256_add_pd(a, b); } static inline MD_SIMD_FLOAT simd_sub(MD_SIMD_FLOAT a, MD_SIMD_FLOAT b) { return _mm256_sub_pd(a, b); } static inline MD_SIMD_FLOAT simd_mul(MD_SIMD_FLOAT a, MD_SIMD_FLOAT b) { return _mm256_mul_pd(a, b); } static inline MD_SIMD_FLOAT simd_load(MD_FLOAT *p) { return _mm256_load_pd(p); } static inline void simd_store(MD_FLOAT *p, MD_SIMD_FLOAT a) { _mm256_store_pd(p, a); } static inline MD_SIMD_FLOAT simd_load_h_duplicate(const MD_FLOAT *m) { MD_SIMD_FLOAT ret; fprintf(stderr, "simd_load_h_duplicate(): Not implemented for AVX with double precision!"); exit(-1); return ret; } static inline MD_SIMD_FLOAT simd_load_h_dual(const MD_FLOAT *m) { MD_SIMD_FLOAT ret; fprintf(stderr, "simd_load_h_dual(): Not implemented for AVX with double precision!"); exit(-1); return ret; } static inline MD_FLOAT simd_h_dual_incr_reduced_sum(MD_FLOAT *m, MD_SIMD_FLOAT v0, MD_SIMD_FLOAT v1) { fprintf(stderr, "simd_h_dual_incr_reduced_sum(): Not implemented for AVX with double precision!"); exit(-1); return 0.0; } static inline MD_FLOAT simd_incr_reduced_sum(MD_FLOAT *m, MD_SIMD_FLOAT v0, MD_SIMD_FLOAT v1, MD_SIMD_FLOAT v2, MD_SIMD_FLOAT v3) { __m256d t0, t1, t2; __m128d a0, a1; t0 = _mm256_hadd_pd(v0, v1); t1 = _mm256_hadd_pd(v2, v3); t2 = _mm256_permute2f128_pd(t0, t1, 0x21); t0 = _mm256_add_pd(t0, t2); t1 = _mm256_add_pd(t1, t2); t0 = _mm256_blend_pd(t0, t1, 0b1100); t1 = _mm256_add_pd(t0, _mm256_load_pd(m)); _mm256_store_pd(m, t1); t0 = _mm256_add_pd(t0, _mm256_permute_pd(t0, 0b0101)); a0 = _mm256_castpd256_pd128(t0); a1 = _mm256_extractf128_pd(t0, 0x1); a0 = _mm_add_sd(a0, a1); return *((MD_FLOAT *) &a0); } static inline MD_SIMD_FLOAT select_by_mask(MD_SIMD_FLOAT a, MD_SIMD_MASK m) { return _mm256_and_pd(a, m); } static inline MD_SIMD_FLOAT simd_reciprocal(MD_SIMD_FLOAT a) { return _mm256_cvtps_pd(_mm_rcp_ps(_mm256_cvtpd_ps(a))); } #ifdef __ISA_AVX_FMA__ static inline MD_SIMD_FLOAT simd_fma(MD_SIMD_FLOAT a, MD_SIMD_FLOAT b, MD_SIMD_FLOAT c) { return _mm256_fmadd_pd(a, b, c); } #else static inline MD_SIMD_FLOAT simd_fma(MD_SIMD_FLOAT a, MD_SIMD_FLOAT b, MD_SIMD_FLOAT c) { return simd_add(simd_mul(a, b), c); } #endif static inline MD_SIMD_FLOAT simd_masked_add(MD_SIMD_FLOAT a, MD_SIMD_FLOAT b, MD_SIMD_MASK m) { return simd_add(a, _mm256_and_pd(b, m)); } static inline MD_SIMD_MASK simd_mask_cond_lt(MD_SIMD_FLOAT a, MD_SIMD_FLOAT b) { return _mm256_cmp_pd(a, b, _CMP_LT_OQ); } static inline MD_SIMD_MASK simd_mask_int_cond_lt(MD_SIMD_INT a, MD_SIMD_INT b) { return _mm256_cvtepi32_pd(_mm_cmplt_epi32(a, b)); } static inline MD_SIMD_MASK simd_mask_and(MD_SIMD_MASK a, MD_SIMD_MASK b) { return _mm256_and_pd(a, b); } // TODO: Initialize all diagonal cases and just select the proper one (all bits set or diagonal) based on cond0 static inline MD_SIMD_MASK simd_mask_from_u32(unsigned int a) { const unsigned long long int all = 0xFFFFFFFFFFFFFFFF; const unsigned long long int none = 0x0; return _mm256_castsi256_pd(_mm256_set_epi64x((a & 0x8) ? all : none, (a & 0x4) ? all : none, (a & 0x2) ? all : none, (a & 0x1) ? all : none)); } // TODO: Implement this, althrough it is just required for debugging static inline int simd_mask_to_u32(MD_SIMD_MASK a) { return 0; } static inline MD_FLOAT simd_h_reduce_sum(MD_SIMD_FLOAT a) { __m128d a0, a1; a = _mm256_add_pd(a, _mm256_permute_pd(a, 0b0101)); a0 = _mm256_castpd256_pd128(a); a1 = _mm256_extractf128_pd(a, 0x1); a0 = _mm_add_sd(a0, a1); return *((MD_FLOAT *) &a0); } static inline void simd_h_decr3(MD_FLOAT *m, MD_SIMD_FLOAT a0, MD_SIMD_FLOAT a1, MD_SIMD_FLOAT a2) { fprintf(stderr, "simd_h_decr3(): Not implemented for AVX with double precision!"); exit(-1); } // Functions used in LAMMPS kernel static inline MD_SIMD_FLOAT simd_gather(MD_SIMD_INT vidx, const MD_FLOAT *m, int s) { return _mm256_i32gather_pd(m, vidx, s); } static inline MD_SIMD_INT simd_int_broadcast(int scalar) { return _mm_set1_epi32(scalar); } static inline MD_SIMD_INT simd_int_zero() { return _mm_setzero_si128(); } static inline MD_SIMD_INT simd_int_seq() { return _mm_set_epi32(3, 2, 1, 0); } static inline MD_SIMD_INT simd_int_load(const int *m) { return _mm_load_si128((__m128i const *) m); } static inline MD_SIMD_INT simd_int_add(MD_SIMD_INT a, MD_SIMD_INT b) { return _mm_add_epi32(a, b); } static inline MD_SIMD_INT simd_int_mul(MD_SIMD_INT a, MD_SIMD_INT b) { return _mm_mul_epi32(a, b); } static inline MD_SIMD_INT simd_int_mask_load(const int *m, MD_SIMD_MASK k) { return simd_int_load(m) & _mm256_cvtpd_epi32(k); }