/* * Copyright (c) 2016, Alliance for Open Media. All rights reserved * * This source code is subject to the terms of the BSD 2 Clause License and * the Alliance for Open Media Patent License 1.0. If the BSD 2 Clause License * was not distributed with this source code in the LICENSE file, you can * obtain it at www.aomedia.org/license/software. If the Alliance for Open * Media Patent License 1.0 was not distributed with this source code in the * PATENTS file, you can obtain it at www.aomedia.org/license/patent. */ #include #include #include "config/aom_dsp_rtcd.h" #include "test/acm_random.h" // Inlining not forced for the compiler due to some tests calling // SIMD_INLINE functions via function pointers #undef SIMD_INLINE #define SIMD_INLINE static inline #include "aom_dsp/aom_simd.h" #include "aom_dsp/simd/v256_intrinsics_c.h" // Machine tuned code goes into this file. This file is included from // simd_cmp_sse2.cc, simd_cmp_ssse3.cc etc which define the macros // ARCH (=neon, sse2, ssse3, etc), SIMD_NAMESPACE and ARCH_POSTFIX(). #ifdef _MSC_VER // Disable "value of intrinsic immediate argument 'value' is out of range // 'lowerbound - upperbound'" warning. Visual Studio emits this warning though // the parameters are conditionally checked in e.g., v256_shr_n_byte. Adding a // mask doesn't always appear to be sufficient. #pragma warning(disable : 4556) #endif using libaom_test::ACMRandom; namespace SIMD_NAMESPACE { // Wrap templates around intrinsics using immediate values template v64 imm_v64_shl_n_byte(v64 a) { return v64_shl_n_byte(a, shift); } template v64 imm_v64_shr_n_byte(v64 a) { return v64_shr_n_byte(a, shift); } template v64 imm_v64_shl_n_8(v64 a) { return v64_shl_n_8(a, shift); } template v64 imm_v64_shr_n_u8(v64 a) { return v64_shr_n_u8(a, shift); } template v64 imm_v64_shr_n_s8(v64 a) { return v64_shr_n_s8(a, shift); } template v64 imm_v64_shl_n_16(v64 a) { return v64_shl_n_16(a, shift); } template v64 imm_v64_shr_n_u16(v64 a) { return v64_shr_n_u16(a, shift); } template v64 imm_v64_shr_n_s16(v64 a) { return v64_shr_n_s16(a, shift); } template v64 imm_v64_shl_n_32(v64 a) { return v64_shl_n_32(a, shift); } template v64 imm_v64_shr_n_u32(v64 a) { return v64_shr_n_u32(a, shift); } template v64 imm_v64_shr_n_s32(v64 a) { return v64_shr_n_s32(a, shift); } template v64 imm_v64_align(v64 a, v64 b) { return v64_align(a, b, shift); } // Wrap templates around corresponding C implementations of the above template c_v64 c_imm_v64_shl_n_byte(c_v64 a) { return c_v64_shl_n_byte(a, shift); } template c_v64 c_imm_v64_shr_n_byte(c_v64 a) { return c_v64_shr_n_byte(a, shift); } template c_v64 c_imm_v64_shl_n_8(c_v64 a) { return c_v64_shl_n_8(a, shift); } template c_v64 c_imm_v64_shr_n_u8(c_v64 a) { return c_v64_shr_n_u8(a, shift); } template c_v64 c_imm_v64_shr_n_s8(c_v64 a) { return c_v64_shr_n_s8(a, shift); } template c_v64 c_imm_v64_shl_n_16(c_v64 a) { return c_v64_shl_n_16(a, shift); } template c_v64 c_imm_v64_shr_n_u16(c_v64 a) { return c_v64_shr_n_u16(a, shift); } template c_v64 c_imm_v64_shr_n_s16(c_v64 a) { return c_v64_shr_n_s16(a, shift); } template c_v64 c_imm_v64_shl_n_32(c_v64 a) { return c_v64_shl_n_32(a, shift); } template c_v64 c_imm_v64_shr_n_u32(c_v64 a) { return c_v64_shr_n_u32(a, shift); } template c_v64 c_imm_v64_shr_n_s32(c_v64 a) { return c_v64_shr_n_s32(a, shift); } template c_v64 c_imm_v64_align(c_v64 a, c_v64 b) { return c_v64_align(a, b, shift); } template v128 imm_v128_shl_n_byte(v128 a) { return v128_shl_n_byte(a, shift); } template v128 imm_v128_shr_n_byte(v128 a) { return v128_shr_n_byte(a, shift); } template v128 imm_v128_shl_n_8(v128 a) { return v128_shl_n_8(a, shift); } template v128 imm_v128_shr_n_u8(v128 a) { return v128_shr_n_u8(a, shift); } template v128 imm_v128_shr_n_s8(v128 a) { return v128_shr_n_s8(a, shift); } template v128 imm_v128_shl_n_16(v128 a) { return v128_shl_n_16(a, shift); } template v128 imm_v128_shr_n_u16(v128 a) { return v128_shr_n_u16(a, shift); } template v128 imm_v128_shr_n_s16(v128 a) { return v128_shr_n_s16(a, shift); } template v128 imm_v128_shl_n_32(v128 a) { return v128_shl_n_32(a, shift); } template v128 imm_v128_shr_n_u32(v128 a) { return v128_shr_n_u32(a, shift); } template v128 imm_v128_shr_n_s32(v128 a) { return v128_shr_n_s32(a, shift); } template v128 imm_v128_shl_n_64(v128 a) { return v128_shl_n_64(a, shift); } template v128 imm_v128_shr_n_u64(v128 a) { return v128_shr_n_u64(a, shift); } template v128 imm_v128_shr_n_s64(v128 a) { return v128_shr_n_s64(a, shift); } template v128 imm_v128_align(v128 a, v128 b) { return v128_align(a, b, shift); } template c_v128 c_imm_v128_shl_n_byte(c_v128 a) { return c_v128_shl_n_byte(a, shift); } template c_v128 c_imm_v128_shr_n_byte(c_v128 a) { return c_v128_shr_n_byte(a, shift); } template c_v128 c_imm_v128_shl_n_8(c_v128 a) { return c_v128_shl_n_8(a, shift); } template c_v128 c_imm_v128_shr_n_u8(c_v128 a) { return c_v128_shr_n_u8(a, shift); } template c_v128 c_imm_v128_shr_n_s8(c_v128 a) { return c_v128_shr_n_s8(a, shift); } template c_v128 c_imm_v128_shl_n_16(c_v128 a) { return c_v128_shl_n_16(a, shift); } template c_v128 c_imm_v128_shr_n_u16(c_v128 a) { return c_v128_shr_n_u16(a, shift); } template c_v128 c_imm_v128_shr_n_s16(c_v128 a) { return c_v128_shr_n_s16(a, shift); } template c_v128 c_imm_v128_shl_n_32(c_v128 a) { return c_v128_shl_n_32(a, shift); } template c_v128 c_imm_v128_shr_n_u32(c_v128 a) { return c_v128_shr_n_u32(a, shift); } template c_v128 c_imm_v128_shr_n_s32(c_v128 a) { return c_v128_shr_n_s32(a, shift); } template c_v128 c_imm_v128_shl_n_64(c_v128 a) { return c_v128_shl_n_64(a, shift); } template c_v128 c_imm_v128_shr_n_u64(c_v128 a) { return c_v128_shr_n_u64(a, shift); } template c_v128 c_imm_v128_shr_n_s64(c_v128 a) { return c_v128_shr_n_s64(a, shift); } template c_v128 c_imm_v128_align(c_v128 a, c_v128 b) { return c_v128_align(a, b, shift); } template v256 imm_v256_shl_n_word(v256 a) { return v256_shl_n_word(a, shift); } template v256 imm_v256_shr_n_word(v256 a) { return v256_shr_n_word(a, shift); } template v256 imm_v256_shl_n_byte(v256 a) { return v256_shl_n_byte(a, shift); } template v256 imm_v256_shr_n_byte(v256 a) { return v256_shr_n_byte(a, shift); } template v256 imm_v256_shl_n_8(v256 a) { return v256_shl_n_8(a, shift); } template v256 imm_v256_shr_n_u8(v256 a) { return v256_shr_n_u8(a, shift); } template v256 imm_v256_shr_n_s8(v256 a) { return v256_shr_n_s8(a, shift); } template v256 imm_v256_shl_n_16(v256 a) { return v256_shl_n_16(a, shift); } template v256 imm_v256_shr_n_u16(v256 a) { return v256_shr_n_u16(a, shift); } template v256 imm_v256_shr_n_s16(v256 a) { return v256_shr_n_s16(a, shift); } template v256 imm_v256_shl_n_32(v256 a) { return v256_shl_n_32(a, shift); } template v256 imm_v256_shr_n_u32(v256 a) { return v256_shr_n_u32(a, shift); } template v256 imm_v256_shr_n_s32(v256 a) { return v256_shr_n_s32(a, shift); } template v256 imm_v256_shl_n_64(v256 a) { return v256_shl_n_64(a, shift); } template v256 imm_v256_shr_n_u64(v256 a) { return v256_shr_n_u64(a, shift); } template v256 imm_v256_shr_n_s64(v256 a) { return v256_shr_n_s64(a, shift); } template v256 imm_v256_align(v256 a, v256 b) { return v256_align(a, b, shift); } template c_v256 c_imm_v256_shl_n_word(c_v256 a) { return c_v256_shl_n_word(a, shift); } template c_v256 c_imm_v256_shr_n_word(c_v256 a) { return c_v256_shr_n_word(a, shift); } template c_v256 c_imm_v256_shl_n_byte(c_v256 a) { return c_v256_shl_n_byte(a, shift); } template c_v256 c_imm_v256_shr_n_byte(c_v256 a) { return c_v256_shr_n_byte(a, shift); } template c_v256 c_imm_v256_shl_n_8(c_v256 a) { return c_v256_shl_n_8(a, shift); } template c_v256 c_imm_v256_shr_n_u8(c_v256 a) { return c_v256_shr_n_u8(a, shift); } template c_v256 c_imm_v256_shr_n_s8(c_v256 a) { return c_v256_shr_n_s8(a, shift); } template c_v256 c_imm_v256_shl_n_16(c_v256 a) { return c_v256_shl_n_16(a, shift); } template c_v256 c_imm_v256_shr_n_u16(c_v256 a) { return c_v256_shr_n_u16(a, shift); } template c_v256 c_imm_v256_shr_n_s16(c_v256 a) { return c_v256_shr_n_s16(a, shift); } template c_v256 c_imm_v256_shl_n_32(c_v256 a) { return c_v256_shl_n_32(a, shift); } template c_v256 c_imm_v256_shr_n_u32(c_v256 a) { return c_v256_shr_n_u32(a, shift); } template c_v256 c_imm_v256_shr_n_s32(c_v256 a) { return c_v256_shr_n_s32(a, shift); } template c_v256 c_imm_v256_shl_n_64(c_v256 a) { return c_v256_shl_n_64(a, shift); } template c_v256 c_imm_v256_shr_n_u64(c_v256 a) { return c_v256_shr_n_u64(a, shift); } template c_v256 c_imm_v256_shr_n_s64(c_v256 a) { return c_v256_shr_n_s64(a, shift); } template c_v256 c_imm_v256_align(c_v256 a, c_v256 b) { return c_v256_align(a, b, shift); } // Wrappers around the the SAD and SSD functions uint32_t v64_sad_u8(v64 a, v64 b) { return v64_sad_u8_sum(::v64_sad_u8(v64_sad_u8_init(), a, b)); } uint32_t v64_ssd_u8(v64 a, v64 b) { return v64_ssd_u8_sum(::v64_ssd_u8(v64_ssd_u8_init(), a, b)); } uint32_t c_v64_sad_u8(c_v64 a, c_v64 b) { return c_v64_sad_u8_sum(::c_v64_sad_u8(c_v64_sad_u8_init(), a, b)); } uint32_t c_v64_ssd_u8(c_v64 a, c_v64 b) { return c_v64_ssd_u8_sum(::c_v64_ssd_u8(c_v64_ssd_u8_init(), a, b)); } uint32_t v128_sad_u8(v128 a, v128 b) { return v128_sad_u8_sum(::v128_sad_u8(v128_sad_u8_init(), a, b)); } uint32_t v128_ssd_u8(v128 a, v128 b) { return v128_ssd_u8_sum(::v128_ssd_u8(v128_ssd_u8_init(), a, b)); } uint32_t c_v128_sad_u8(c_v128 a, c_v128 b) { return c_v128_sad_u8_sum(::c_v128_sad_u8(c_v128_sad_u8_init(), a, b)); } uint32_t c_v128_ssd_u8(c_v128 a, c_v128 b) { return c_v128_ssd_u8_sum(::c_v128_ssd_u8(c_v128_ssd_u8_init(), a, b)); } uint32_t v128_sad_u16(v128 a, v128 b) { return v128_sad_u16_sum(::v128_sad_u16(v128_sad_u16_init(), a, b)); } uint64_t v128_ssd_s16(v128 a, v128 b) { return v128_ssd_s16_sum(::v128_ssd_s16(v128_ssd_s16_init(), a, b)); } uint32_t c_v128_sad_u16(c_v128 a, c_v128 b) { return c_v128_sad_u16_sum(::c_v128_sad_u16(c_v128_sad_u16_init(), a, b)); } uint64_t c_v128_ssd_s16(c_v128 a, c_v128 b) { return c_v128_ssd_s16_sum(::c_v128_ssd_s16(c_v128_ssd_s16_init(), a, b)); } uint32_t v256_sad_u8(v256 a, v256 b) { return v256_sad_u8_sum(::v256_sad_u8(v256_sad_u8_init(), a, b)); } uint32_t v256_ssd_u8(v256 a, v256 b) { return v256_ssd_u8_sum(::v256_ssd_u8(v256_ssd_u8_init(), a, b)); } uint32_t c_v256_sad_u8(c_v256 a, c_v256 b) { return c_v256_sad_u8_sum(::c_v256_sad_u8(c_v256_sad_u8_init(), a, b)); } uint32_t c_v256_ssd_u8(c_v256 a, c_v256 b) { return c_v256_ssd_u8_sum(::c_v256_ssd_u8(c_v256_ssd_u8_init(), a, b)); } uint32_t v256_sad_u16(v256 a, v256 b) { return v256_sad_u16_sum(::v256_sad_u16(v256_sad_u16_init(), a, b)); } uint64_t v256_ssd_s16(v256 a, v256 b) { return v256_ssd_s16_sum(::v256_ssd_s16(v256_ssd_s16_init(), a, b)); } uint32_t c_v256_sad_u16(c_v256 a, c_v256 b) { return c_v256_sad_u16_sum(::c_v256_sad_u16(c_v256_sad_u16_init(), a, b)); } uint64_t c_v256_ssd_s16(c_v256 a, c_v256 b) { return c_v256_ssd_s16_sum(::c_v256_ssd_s16(c_v256_ssd_s16_init(), a, b)); } namespace { typedef void (*fptr)(); typedef struct { const char *name; fptr ref; fptr simd; } mapping; #define MAP(name) \ { #name, reinterpret_cast < fptr>(c_##name), reinterpret_cast < fptr>(name) } const mapping m[] = { MAP(v64_sad_u8), MAP(v64_ssd_u8), MAP(v64_add_8), MAP(v64_add_16), MAP(v64_sadd_s8), MAP(v64_sadd_u8), MAP(v64_sadd_s16), MAP(v64_add_32), MAP(v64_sub_8), MAP(v64_ssub_u8), MAP(v64_ssub_s8), MAP(v64_sub_16), MAP(v64_ssub_s16), MAP(v64_ssub_u16), MAP(v64_sub_32), MAP(v64_ziplo_8), MAP(v64_ziphi_8), MAP(v64_ziplo_16), MAP(v64_ziphi_16), MAP(v64_ziplo_32), MAP(v64_ziphi_32), MAP(v64_pack_s32_u16), MAP(v64_pack_s32_s16), MAP(v64_pack_s16_u8), MAP(v64_pack_s16_s8), MAP(v64_unziphi_8), MAP(v64_unziplo_8), MAP(v64_unziphi_16), MAP(v64_unziplo_16), MAP(v64_or), MAP(v64_xor), MAP(v64_and), MAP(v64_andn), MAP(v64_mullo_s16), MAP(v64_mulhi_s16), MAP(v64_mullo_s32), MAP(v64_madd_s16), MAP(v64_madd_us8), MAP(v64_avg_u8), MAP(v64_rdavg_u8), MAP(v64_rdavg_u16), MAP(v64_avg_u16), MAP(v64_min_u8), MAP(v64_max_u8), MAP(v64_min_s8), MAP(v64_max_s8), MAP(v64_min_s16), MAP(v64_max_s16), MAP(v64_cmpgt_s8), MAP(v64_cmplt_s8), MAP(v64_cmpeq_8), MAP(v64_cmpgt_s16), MAP(v64_cmplt_s16), MAP(v64_cmpeq_16), MAP(v64_shuffle_8), MAP(imm_v64_align<1>), MAP(imm_v64_align<2>), MAP(imm_v64_align<3>), MAP(imm_v64_align<4>), MAP(imm_v64_align<5>), MAP(imm_v64_align<6>), MAP(imm_v64_align<7>), MAP(v64_abs_s8), MAP(v64_abs_s16), MAP(v64_unpacklo_u8_s16), MAP(v64_unpackhi_u8_s16), MAP(v64_unpacklo_s8_s16), MAP(v64_unpackhi_s8_s16), MAP(v64_unpacklo_u16_s32), MAP(v64_unpacklo_s16_s32), MAP(v64_unpackhi_u16_s32), MAP(v64_unpackhi_s16_s32), MAP(imm_v64_shr_n_byte<1>), MAP(imm_v64_shr_n_byte<2>), MAP(imm_v64_shr_n_byte<3>), MAP(imm_v64_shr_n_byte<4>), MAP(imm_v64_shr_n_byte<5>), MAP(imm_v64_shr_n_byte<6>), MAP(imm_v64_shr_n_byte<7>), MAP(imm_v64_shl_n_byte<1>), MAP(imm_v64_shl_n_byte<2>), MAP(imm_v64_shl_n_byte<3>), MAP(imm_v64_shl_n_byte<4>), MAP(imm_v64_shl_n_byte<5>), MAP(imm_v64_shl_n_byte<6>), MAP(imm_v64_shl_n_byte<7>), MAP(imm_v64_shl_n_8<1>), MAP(imm_v64_shl_n_8<2>), MAP(imm_v64_shl_n_8<3>), MAP(imm_v64_shl_n_8<4>), MAP(imm_v64_shl_n_8<5>), MAP(imm_v64_shl_n_8<6>), MAP(imm_v64_shl_n_8<7>), MAP(imm_v64_shr_n_u8<1>), MAP(imm_v64_shr_n_u8<2>), MAP(imm_v64_shr_n_u8<3>), MAP(imm_v64_shr_n_u8<4>), MAP(imm_v64_shr_n_u8<5>), MAP(imm_v64_shr_n_u8<6>), MAP(imm_v64_shr_n_u8<7>), MAP(imm_v64_shr_n_s8<1>), MAP(imm_v64_shr_n_s8<2>), MAP(imm_v64_shr_n_s8<3>), MAP(imm_v64_shr_n_s8<4>), MAP(imm_v64_shr_n_s8<5>), MAP(imm_v64_shr_n_s8<6>), MAP(imm_v64_shr_n_s8<7>), MAP(imm_v64_shl_n_16<1>), MAP(imm_v64_shl_n_16<2>), MAP(imm_v64_shl_n_16<4>), MAP(imm_v64_shl_n_16<6>), MAP(imm_v64_shl_n_16<8>), MAP(imm_v64_shl_n_16<10>), MAP(imm_v64_shl_n_16<12>), MAP(imm_v64_shl_n_16<14>), MAP(imm_v64_shr_n_u16<1>), MAP(imm_v64_shr_n_u16<2>), MAP(imm_v64_shr_n_u16<4>), MAP(imm_v64_shr_n_u16<6>), MAP(imm_v64_shr_n_u16<8>), MAP(imm_v64_shr_n_u16<10>), MAP(imm_v64_shr_n_u16<12>), MAP(imm_v64_shr_n_u16<14>), MAP(imm_v64_shr_n_s16<1>), MAP(imm_v64_shr_n_s16<2>), MAP(imm_v64_shr_n_s16<4>), MAP(imm_v64_shr_n_s16<6>), MAP(imm_v64_shr_n_s16<8>), MAP(imm_v64_shr_n_s16<10>), MAP(imm_v64_shr_n_s16<12>), MAP(imm_v64_shr_n_s16<14>), MAP(imm_v64_shl_n_32<1>), MAP(imm_v64_shl_n_32<4>), MAP(imm_v64_shl_n_32<8>), MAP(imm_v64_shl_n_32<12>), MAP(imm_v64_shl_n_32<16>), MAP(imm_v64_shl_n_32<20>), MAP(imm_v64_shl_n_32<24>), MAP(imm_v64_shl_n_32<28>), MAP(imm_v64_shr_n_u32<1>), MAP(imm_v64_shr_n_u32<4>), MAP(imm_v64_shr_n_u32<8>), MAP(imm_v64_shr_n_u32<12>), MAP(imm_v64_shr_n_u32<16>), MAP(imm_v64_shr_n_u32<20>), MAP(imm_v64_shr_n_u32<24>), MAP(imm_v64_shr_n_u32<28>), MAP(imm_v64_shr_n_s32<1>), MAP(imm_v64_shr_n_s32<4>), MAP(imm_v64_shr_n_s32<8>), MAP(imm_v64_shr_n_s32<12>), MAP(imm_v64_shr_n_s32<16>), MAP(imm_v64_shr_n_s32<20>), MAP(imm_v64_shr_n_s32<24>), MAP(imm_v64_shr_n_s32<28>), MAP(v64_shl_8), MAP(v64_shr_u8), MAP(v64_shr_s8), MAP(v64_shl_16), MAP(v64_shr_u16), MAP(v64_shr_s16), MAP(v64_shl_32), MAP(v64_shr_u32), MAP(v64_shr_s32), MAP(v64_hadd_u8), MAP(v64_hadd_s16), MAP(v64_dotp_s16), MAP(v64_dotp_su8), MAP(v64_u64), MAP(v64_low_u32), MAP(v64_high_u32), MAP(v64_low_s32), MAP(v64_high_s32), MAP(v64_dup_8), MAP(v64_dup_16), MAP(v64_dup_32), MAP(v64_from_32), MAP(v64_zero), MAP(v64_from_16), MAP(v128_sad_u8), MAP(v128_ssd_u8), MAP(v128_sad_u16), MAP(v128_ssd_s16), MAP(v128_add_8), MAP(v128_add_16), MAP(v128_sadd_s8), MAP(v128_sadd_u8), MAP(v128_sadd_s16), MAP(v128_add_32), MAP(v128_add_64), MAP(v128_sub_8), MAP(v128_ssub_u8), MAP(v128_ssub_s8), MAP(v128_sub_16), MAP(v128_ssub_s16), MAP(v128_ssub_u16), MAP(v128_sub_32), MAP(v128_sub_64), MAP(v128_ziplo_8), MAP(v128_ziphi_8), MAP(v128_ziplo_16), MAP(v128_ziphi_16), MAP(v128_ziplo_32), MAP(v128_ziphi_32), MAP(v128_ziplo_64), MAP(v128_ziphi_64), MAP(v128_unziphi_8), MAP(v128_unziplo_8), MAP(v128_unziphi_16), MAP(v128_unziplo_16), MAP(v128_unziphi_32), MAP(v128_unziplo_32), MAP(v128_pack_s32_u16), MAP(v128_pack_s32_s16), MAP(v128_pack_s16_u8), MAP(v128_pack_s16_s8), MAP(v128_or), MAP(v128_xor), MAP(v128_and), MAP(v128_andn), MAP(v128_mullo_s16), MAP(v128_mulhi_s16), MAP(v128_mullo_s32), MAP(v128_madd_s16), MAP(v128_madd_us8), MAP(v128_avg_u8), MAP(v128_rdavg_u8), MAP(v128_rdavg_u16), MAP(v128_avg_u16), MAP(v128_min_u8), MAP(v128_max_u8), MAP(v128_min_s8), MAP(v128_max_s8), MAP(v128_min_s16), MAP(v128_max_s16), MAP(v128_min_s32), MAP(v128_max_s32), MAP(v128_cmpgt_s8), MAP(v128_cmplt_s8), MAP(v128_cmpeq_8), MAP(v128_cmpgt_s16), MAP(v128_cmpeq_16), MAP(v128_cmplt_s16), MAP(v128_cmpgt_s32), MAP(v128_cmpeq_32), MAP(v128_cmplt_s32), MAP(v128_shuffle_8), MAP(imm_v128_align<1>), MAP(imm_v128_align<2>), MAP(imm_v128_align<3>), MAP(imm_v128_align<4>), MAP(imm_v128_align<5>), MAP(imm_v128_align<6>), MAP(imm_v128_align<7>), MAP(imm_v128_align<8>), MAP(imm_v128_align<9>), MAP(imm_v128_align<10>), MAP(imm_v128_align<11>), MAP(imm_v128_align<12>), MAP(imm_v128_align<13>), MAP(imm_v128_align<14>), MAP(imm_v128_align<15>), MAP(v128_abs_s8), MAP(v128_abs_s16), MAP(v128_padd_u8), MAP(v128_padd_s16), MAP(v128_unpacklo_u16_s32), MAP(v128_unpacklo_s16_s32), MAP(v128_unpackhi_u16_s32), MAP(v128_unpackhi_s16_s32), MAP(imm_v128_shr_n_byte<1>), MAP(imm_v128_shr_n_byte<2>), MAP(imm_v128_shr_n_byte<3>), MAP(imm_v128_shr_n_byte<4>), MAP(imm_v128_shr_n_byte<5>), MAP(imm_v128_shr_n_byte<6>), MAP(imm_v128_shr_n_byte<7>), MAP(imm_v128_shr_n_byte<8>), MAP(imm_v128_shr_n_byte<9>), MAP(imm_v128_shr_n_byte<10>), MAP(imm_v128_shr_n_byte<11>), MAP(imm_v128_shr_n_byte<12>), MAP(imm_v128_shr_n_byte<13>), MAP(imm_v128_shr_n_byte<14>), MAP(imm_v128_shr_n_byte<15>), MAP(imm_v128_shl_n_byte<1>), MAP(imm_v128_shl_n_byte<2>), MAP(imm_v128_shl_n_byte<3>), MAP(imm_v128_shl_n_byte<4>), MAP(imm_v128_shl_n_byte<5>), MAP(imm_v128_shl_n_byte<6>), MAP(imm_v128_shl_n_byte<7>), MAP(imm_v128_shl_n_byte<8>), MAP(imm_v128_shl_n_byte<9>), MAP(imm_v128_shl_n_byte<10>), MAP(imm_v128_shl_n_byte<11>), MAP(imm_v128_shl_n_byte<12>), MAP(imm_v128_shl_n_byte<13>), MAP(imm_v128_shl_n_byte<14>), MAP(imm_v128_shl_n_byte<15>), MAP(imm_v128_shl_n_8<1>), MAP(imm_v128_shl_n_8<2>), MAP(imm_v128_shl_n_8<3>), MAP(imm_v128_shl_n_8<4>), MAP(imm_v128_shl_n_8<5>), MAP(imm_v128_shl_n_8<6>), MAP(imm_v128_shl_n_8<7>), MAP(imm_v128_shr_n_u8<1>), MAP(imm_v128_shr_n_u8<2>), MAP(imm_v128_shr_n_u8<3>), MAP(imm_v128_shr_n_u8<4>), MAP(imm_v128_shr_n_u8<5>), MAP(imm_v128_shr_n_u8<6>), MAP(imm_v128_shr_n_u8<7>), MAP(imm_v128_shr_n_s8<1>), MAP(imm_v128_shr_n_s8<2>), MAP(imm_v128_shr_n_s8<3>), MAP(imm_v128_shr_n_s8<4>), MAP(imm_v128_shr_n_s8<5>), MAP(imm_v128_shr_n_s8<6>), MAP(imm_v128_shr_n_s8<7>), MAP(imm_v128_shl_n_16<1>), MAP(imm_v128_shl_n_16<2>), MAP(imm_v128_shl_n_16<4>), MAP(imm_v128_shl_n_16<6>), MAP(imm_v128_shl_n_16<8>), MAP(imm_v128_shl_n_16<10>), MAP(imm_v128_shl_n_16<12>), MAP(imm_v128_shl_n_16<14>), MAP(imm_v128_shr_n_u16<1>), MAP(imm_v128_shr_n_u16<2>), MAP(imm_v128_shr_n_u16<4>), MAP(imm_v128_shr_n_u16<6>), MAP(imm_v128_shr_n_u16<8>), MAP(imm_v128_shr_n_u16<10>), MAP(imm_v128_shr_n_u16<12>), MAP(imm_v128_shr_n_u16<14>), MAP(imm_v128_shr_n_s16<1>), MAP(imm_v128_shr_n_s16<2>), MAP(imm_v128_shr_n_s16<4>), MAP(imm_v128_shr_n_s16<6>), MAP(imm_v128_shr_n_s16<8>), MAP(imm_v128_shr_n_s16<10>), MAP(imm_v128_shr_n_s16<12>), MAP(imm_v128_shr_n_s16<14>), MAP(imm_v128_shl_n_32<1>), MAP(imm_v128_shl_n_32<4>), MAP(imm_v128_shl_n_32<8>), MAP(imm_v128_shl_n_32<12>), MAP(imm_v128_shl_n_32<16>), MAP(imm_v128_shl_n_32<20>), MAP(imm_v128_shl_n_32<24>), MAP(imm_v128_shl_n_32<28>), MAP(imm_v128_shr_n_u32<1>), MAP(imm_v128_shr_n_u32<4>), MAP(imm_v128_shr_n_u32<8>), MAP(imm_v128_shr_n_u32<12>), MAP(imm_v128_shr_n_u32<16>), MAP(imm_v128_shr_n_u32<20>), MAP(imm_v128_shr_n_u32<24>), MAP(imm_v128_shr_n_u32<28>), MAP(imm_v128_shr_n_s32<1>), MAP(imm_v128_shr_n_s32<4>), MAP(imm_v128_shr_n_s32<8>), MAP(imm_v128_shr_n_s32<12>), MAP(imm_v128_shr_n_s32<16>), MAP(imm_v128_shr_n_s32<20>), MAP(imm_v128_shr_n_s32<24>), MAP(imm_v128_shr_n_s32<28>), MAP(imm_v128_shl_n_64<1>), MAP(imm_v128_shl_n_64<4>), MAP(imm_v128_shl_n_64<8>), MAP(imm_v128_shl_n_64<12>), MAP(imm_v128_shl_n_64<16>), MAP(imm_v128_shl_n_64<20>), MAP(imm_v128_shl_n_64<24>), MAP(imm_v128_shl_n_64<28>), MAP(imm_v128_shl_n_64<32>), MAP(imm_v128_shl_n_64<36>), MAP(imm_v128_shl_n_64<40>), MAP(imm_v128_shl_n_64<44>), MAP(imm_v128_shl_n_64<48>), MAP(imm_v128_shl_n_64<52>), MAP(imm_v128_shl_n_64<56>), MAP(imm_v128_shl_n_64<60>), MAP(imm_v128_shr_n_u64<1>), MAP(imm_v128_shr_n_u64<4>), MAP(imm_v128_shr_n_u64<8>), MAP(imm_v128_shr_n_u64<12>), MAP(imm_v128_shr_n_u64<16>), MAP(imm_v128_shr_n_u64<20>), MAP(imm_v128_shr_n_u64<24>), MAP(imm_v128_shr_n_u64<28>), MAP(imm_v128_shr_n_u64<32>), MAP(imm_v128_shr_n_u64<36>), MAP(imm_v128_shr_n_u64<40>), MAP(imm_v128_shr_n_u64<44>), MAP(imm_v128_shr_n_u64<48>), MAP(imm_v128_shr_n_u64<52>), MAP(imm_v128_shr_n_u64<56>), MAP(imm_v128_shr_n_u64<60>), MAP(imm_v128_shr_n_s64<1>), MAP(imm_v128_shr_n_s64<4>), MAP(imm_v128_shr_n_s64<8>), MAP(imm_v128_shr_n_s64<12>), MAP(imm_v128_shr_n_s64<16>), MAP(imm_v128_shr_n_s64<20>), MAP(imm_v128_shr_n_s64<24>), MAP(imm_v128_shr_n_s64<28>), MAP(imm_v128_shr_n_s64<32>), MAP(imm_v128_shr_n_s64<36>), MAP(imm_v128_shr_n_s64<40>), MAP(imm_v128_shr_n_s64<44>), MAP(imm_v128_shr_n_s64<48>), MAP(imm_v128_shr_n_s64<52>), MAP(imm_v128_shr_n_s64<56>), MAP(imm_v128_shr_n_s64<60>), MAP(v128_from_v64), MAP(v128_zip_8), MAP(v128_zip_16), MAP(v128_zip_32), MAP(v128_mul_s16), MAP(v128_unpack_u8_s16), MAP(v128_unpack_s8_s16), MAP(v128_unpack_u16_s32), MAP(v128_unpack_s16_s32), MAP(v128_shl_8), MAP(v128_shr_u8), MAP(v128_shr_s8), MAP(v128_shl_16), MAP(v128_shr_u16), MAP(v128_shr_s16), MAP(v128_shl_32), MAP(v128_shr_u32), MAP(v128_shr_s32), MAP(v128_shl_64), MAP(v128_shr_u64), MAP(v128_shr_s64), MAP(v128_hadd_u8), MAP(v128_dotp_su8), MAP(v128_dotp_s16), MAP(v128_dotp_s32), MAP(v128_low_u32), MAP(v128_low_v64), MAP(v128_high_v64), MAP(v128_from_64), MAP(v128_from_32), MAP(v128_movemask_8), MAP(v128_zero), MAP(v128_dup_8), MAP(v128_dup_16), MAP(v128_dup_32), MAP(v128_dup_64), MAP(v128_unpacklo_u8_s16), MAP(v128_unpackhi_u8_s16), MAP(v128_unpacklo_s8_s16), MAP(v128_unpackhi_s8_s16), MAP(v128_blend_8), MAP(u32_load_unaligned), MAP(u32_store_unaligned), MAP(v64_load_unaligned), MAP(v64_store_unaligned), MAP(v128_load_unaligned), MAP(v128_store_unaligned), MAP(v256_sad_u8), MAP(v256_ssd_u8), MAP(v256_sad_u16), MAP(v256_ssd_s16), MAP(v256_hadd_u8), MAP(v256_low_u64), MAP(v256_dotp_su8), MAP(v256_dotp_s16), MAP(v256_dotp_s32), MAP(v256_add_8), MAP(v256_add_16), MAP(v256_sadd_s8), MAP(v256_sadd_u8), MAP(v256_sadd_s16), MAP(v256_add_32), MAP(v256_add_64), MAP(v256_sub_8), MAP(v256_ssub_u8), MAP(v256_ssub_s8), MAP(v256_sub_16), MAP(v256_ssub_u16), MAP(v256_ssub_s16), MAP(v256_sub_32), MAP(v256_sub_64), MAP(v256_ziplo_8), MAP(v256_ziphi_8), MAP(v256_ziplo_16), MAP(v256_ziphi_16), MAP(v256_ziplo_32), MAP(v256_ziphi_32), MAP(v256_ziplo_64), MAP(v256_ziphi_64), MAP(v256_unziphi_8), MAP(v256_unziplo_8), MAP(v256_unziphi_16), MAP(v256_unziplo_16), MAP(v256_unziphi_32), MAP(v256_unziplo_32), MAP(v256_unziphi_64), MAP(v256_unziplo_64), MAP(v256_pack_s32_u16), MAP(v256_pack_s32_s16), MAP(v256_pack_s16_u8), MAP(v256_pack_s16_s8), MAP(v256_or), MAP(v256_xor), MAP(v256_and), MAP(v256_andn), MAP(v256_mullo_s16), MAP(v256_mulhi_s16), MAP(v256_mullo_s32), MAP(v256_madd_s16), MAP(v256_madd_us8), MAP(v256_avg_u8), MAP(v256_rdavg_u8), MAP(v256_rdavg_u16), MAP(v256_avg_u16), MAP(v256_min_u8), MAP(v256_max_u8), MAP(v256_min_s8), MAP(v256_max_s8), MAP(v256_min_s16), MAP(v256_max_s16), MAP(v256_min_s32), MAP(v256_max_s32), MAP(v256_cmpgt_s8), MAP(v256_cmplt_s8), MAP(v256_cmpeq_8), MAP(v256_cmpgt_s16), MAP(v256_cmplt_s16), MAP(v256_cmpeq_16), MAP(v256_cmpgt_s32), MAP(v256_cmplt_s32), MAP(v256_cmpeq_32), MAP(v256_shuffle_8), MAP(v256_pshuffle_8), MAP(v256_wideshuffle_8), MAP(imm_v256_align<1>), MAP(imm_v256_align<2>), MAP(imm_v256_align<3>), MAP(imm_v256_align<4>), MAP(imm_v256_align<5>), MAP(imm_v256_align<6>), MAP(imm_v256_align<7>), MAP(imm_v256_align<8>), MAP(imm_v256_align<9>), MAP(imm_v256_align<10>), MAP(imm_v256_align<11>), MAP(imm_v256_align<12>), MAP(imm_v256_align<13>), MAP(imm_v256_align<14>), MAP(imm_v256_align<15>), MAP(imm_v256_align<16>), MAP(imm_v256_align<17>), MAP(imm_v256_align<18>), MAP(imm_v256_align<19>), MAP(imm_v256_align<20>), MAP(imm_v256_align<21>), MAP(imm_v256_align<22>), MAP(imm_v256_align<23>), MAP(imm_v256_align<24>), MAP(imm_v256_align<25>), MAP(imm_v256_align<26>), MAP(imm_v256_align<27>), MAP(imm_v256_align<28>), MAP(imm_v256_align<29>), MAP(imm_v256_align<30>), MAP(imm_v256_align<31>), MAP(v256_from_v128), MAP(v256_zip_8), MAP(v256_zip_16), MAP(v256_zip_32), MAP(v256_mul_s16), MAP(v256_unpack_u8_s16), MAP(v256_unpack_s8_s16), MAP(v256_unpack_u16_s32), MAP(v256_unpack_s16_s32), MAP(v256_shl_8), MAP(v256_shr_u8), MAP(v256_shr_s8), MAP(v256_shl_16), MAP(v256_shr_u16), MAP(v256_shr_s16), MAP(v256_shl_32), MAP(v256_shr_u32), MAP(v256_shr_s32), MAP(v256_shl_64), MAP(v256_shr_u64), MAP(v256_shr_s64), MAP(v256_abs_s8), MAP(v256_abs_s16), MAP(v256_padd_u8), MAP(v256_padd_s16), MAP(v256_unpacklo_u16_s32), MAP(v256_unpacklo_s16_s32), MAP(v256_unpackhi_u16_s32), MAP(v256_unpackhi_s16_s32), MAP(imm_v256_shr_n_word<1>), MAP(imm_v256_shr_n_word<2>), MAP(imm_v256_shr_n_word<3>), MAP(imm_v256_shr_n_word<4>), MAP(imm_v256_shr_n_word<5>), MAP(imm_v256_shr_n_word<6>), MAP(imm_v256_shr_n_word<7>), MAP(imm_v256_shr_n_word<8>), MAP(imm_v256_shr_n_word<9>), MAP(imm_v256_shr_n_word<10>), MAP(imm_v256_shr_n_word<11>), MAP(imm_v256_shr_n_word<12>), MAP(imm_v256_shr_n_word<13>), MAP(imm_v256_shr_n_word<14>), MAP(imm_v256_shr_n_word<15>), MAP(imm_v256_shl_n_word<1>), MAP(imm_v256_shl_n_word<2>), MAP(imm_v256_shl_n_word<3>), MAP(imm_v256_shl_n_word<4>), MAP(imm_v256_shl_n_word<5>), MAP(imm_v256_shl_n_word<6>), MAP(imm_v256_shl_n_word<7>), MAP(imm_v256_shl_n_word<8>), MAP(imm_v256_shl_n_word<9>), MAP(imm_v256_shl_n_word<10>), MAP(imm_v256_shl_n_word<11>), MAP(imm_v256_shl_n_word<12>), MAP(imm_v256_shl_n_word<13>), MAP(imm_v256_shl_n_word<14>), MAP(imm_v256_shl_n_word<15>), MAP(imm_v256_shr_n_byte<1>), MAP(imm_v256_shr_n_byte<2>), MAP(imm_v256_shr_n_byte<3>), MAP(imm_v256_shr_n_byte<4>), MAP(imm_v256_shr_n_byte<5>), MAP(imm_v256_shr_n_byte<6>), MAP(imm_v256_shr_n_byte<7>), MAP(imm_v256_shr_n_byte<8>), MAP(imm_v256_shr_n_byte<9>), MAP(imm_v256_shr_n_byte<10>), MAP(imm_v256_shr_n_byte<11>), MAP(imm_v256_shr_n_byte<12>), MAP(imm_v256_shr_n_byte<13>), MAP(imm_v256_shr_n_byte<14>), MAP(imm_v256_shr_n_byte<15>), MAP(imm_v256_shr_n_byte<16>), MAP(imm_v256_shr_n_byte<17>), MAP(imm_v256_shr_n_byte<18>), MAP(imm_v256_shr_n_byte<19>), MAP(imm_v256_shr_n_byte<20>), MAP(imm_v256_shr_n_byte<21>), MAP(imm_v256_shr_n_byte<22>), MAP(imm_v256_shr_n_byte<23>), MAP(imm_v256_shr_n_byte<24>), MAP(imm_v256_shr_n_byte<25>), MAP(imm_v256_shr_n_byte<26>), MAP(imm_v256_shr_n_byte<27>), MAP(imm_v256_shr_n_byte<28>), MAP(imm_v256_shr_n_byte<29>), MAP(imm_v256_shr_n_byte<30>), MAP(imm_v256_shr_n_byte<31>), MAP(imm_v256_shl_n_byte<1>), MAP(imm_v256_shl_n_byte<2>), MAP(imm_v256_shl_n_byte<3>), MAP(imm_v256_shl_n_byte<4>), MAP(imm_v256_shl_n_byte<5>), MAP(imm_v256_shl_n_byte<6>), MAP(imm_v256_shl_n_byte<7>), MAP(imm_v256_shl_n_byte<8>), MAP(imm_v256_shl_n_byte<9>), MAP(imm_v256_shl_n_byte<10>), MAP(imm_v256_shl_n_byte<11>), MAP(imm_v256_shl_n_byte<12>), MAP(imm_v256_shl_n_byte<13>), MAP(imm_v256_shl_n_byte<14>), MAP(imm_v256_shl_n_byte<15>), MAP(imm_v256_shl_n_byte<16>), MAP(imm_v256_shl_n_byte<17>), MAP(imm_v256_shl_n_byte<18>), MAP(imm_v256_shl_n_byte<19>), MAP(imm_v256_shl_n_byte<20>), MAP(imm_v256_shl_n_byte<21>), MAP(imm_v256_shl_n_byte<22>), MAP(imm_v256_shl_n_byte<23>), MAP(imm_v256_shl_n_byte<24>), MAP(imm_v256_shl_n_byte<25>), MAP(imm_v256_shl_n_byte<26>), MAP(imm_v256_shl_n_byte<27>), MAP(imm_v256_shl_n_byte<28>), MAP(imm_v256_shl_n_byte<29>), MAP(imm_v256_shl_n_byte<30>), MAP(imm_v256_shl_n_byte<31>), MAP(imm_v256_shl_n_8<1>), MAP(imm_v256_shl_n_8<2>), MAP(imm_v256_shl_n_8<3>), MAP(imm_v256_shl_n_8<4>), MAP(imm_v256_shl_n_8<5>), MAP(imm_v256_shl_n_8<6>), MAP(imm_v256_shl_n_8<7>), MAP(imm_v256_shr_n_u8<1>), MAP(imm_v256_shr_n_u8<2>), MAP(imm_v256_shr_n_u8<3>), MAP(imm_v256_shr_n_u8<4>), MAP(imm_v256_shr_n_u8<5>), MAP(imm_v256_shr_n_u8<6>), MAP(imm_v256_shr_n_u8<7>), MAP(imm_v256_shr_n_s8<1>), MAP(imm_v256_shr_n_s8<2>), MAP(imm_v256_shr_n_s8<3>), MAP(imm_v256_shr_n_s8<4>), MAP(imm_v256_shr_n_s8<5>), MAP(imm_v256_shr_n_s8<6>), MAP(imm_v256_shr_n_s8<7>), MAP(imm_v256_shl_n_16<1>), MAP(imm_v256_shl_n_16<2>), MAP(imm_v256_shl_n_16<4>), MAP(imm_v256_shl_n_16<6>), MAP(imm_v256_shl_n_16<8>), MAP(imm_v256_shl_n_16<10>), MAP(imm_v256_shl_n_16<12>), MAP(imm_v256_shl_n_16<14>), MAP(imm_v256_shr_n_u16<1>), MAP(imm_v256_shr_n_u16<2>), MAP(imm_v256_shr_n_u16<4>), MAP(imm_v256_shr_n_u16<6>), MAP(imm_v256_shr_n_u16<8>), MAP(imm_v256_shr_n_u16<10>), MAP(imm_v256_shr_n_u16<12>), MAP(imm_v256_shr_n_u16<14>), MAP(imm_v256_shr_n_s16<1>), MAP(imm_v256_shr_n_s16<2>), MAP(imm_v256_shr_n_s16<4>), MAP(imm_v256_shr_n_s16<6>), MAP(imm_v256_shr_n_s16<8>), MAP(imm_v256_shr_n_s16<10>), MAP(imm_v256_shr_n_s16<12>), MAP(imm_v256_shr_n_s16<14>), MAP(imm_v256_shl_n_32<1>), MAP(imm_v256_shl_n_32<4>), MAP(imm_v256_shl_n_32<8>), MAP(imm_v256_shl_n_32<12>), MAP(imm_v256_shl_n_32<16>), MAP(imm_v256_shl_n_32<20>), MAP(imm_v256_shl_n_32<24>), MAP(imm_v256_shl_n_32<28>), MAP(imm_v256_shr_n_u32<1>), MAP(imm_v256_shr_n_u32<4>), MAP(imm_v256_shr_n_u32<8>), MAP(imm_v256_shr_n_u32<12>), MAP(imm_v256_shr_n_u32<16>), MAP(imm_v256_shr_n_u32<20>), MAP(imm_v256_shr_n_u32<24>), MAP(imm_v256_shr_n_u32<28>), MAP(imm_v256_shr_n_s32<1>), MAP(imm_v256_shr_n_s32<4>), MAP(imm_v256_shr_n_s32<8>), MAP(imm_v256_shr_n_s32<12>), MAP(imm_v256_shr_n_s32<16>), MAP(imm_v256_shr_n_s32<20>), MAP(imm_v256_shr_n_s32<24>), MAP(imm_v256_shr_n_s32<28>), MAP(imm_v256_shl_n_64<1>), MAP(imm_v256_shl_n_64<4>), MAP(imm_v256_shl_n_64<8>), MAP(imm_v256_shl_n_64<12>), MAP(imm_v256_shl_n_64<16>), MAP(imm_v256_shl_n_64<20>), MAP(imm_v256_shl_n_64<24>), MAP(imm_v256_shl_n_64<28>), MAP(imm_v256_shl_n_64<32>), MAP(imm_v256_shl_n_64<36>), MAP(imm_v256_shl_n_64<40>), MAP(imm_v256_shl_n_64<44>), MAP(imm_v256_shl_n_64<48>), MAP(imm_v256_shl_n_64<52>), MAP(imm_v256_shl_n_64<56>), MAP(imm_v256_shl_n_64<60>), MAP(imm_v256_shr_n_u64<1>), MAP(imm_v256_shr_n_u64<4>), MAP(imm_v256_shr_n_u64<8>), MAP(imm_v256_shr_n_u64<12>), MAP(imm_v256_shr_n_u64<16>), MAP(imm_v256_shr_n_u64<20>), MAP(imm_v256_shr_n_u64<24>), MAP(imm_v256_shr_n_u64<28>), MAP(imm_v256_shr_n_u64<32>), MAP(imm_v256_shr_n_u64<36>), MAP(imm_v256_shr_n_u64<40>), MAP(imm_v256_shr_n_u64<44>), MAP(imm_v256_shr_n_u64<48>), MAP(imm_v256_shr_n_u64<52>), MAP(imm_v256_shr_n_u64<56>), MAP(imm_v256_shr_n_u64<60>), MAP(imm_v256_shr_n_s64<1>), MAP(imm_v256_shr_n_s64<4>), MAP(imm_v256_shr_n_s64<8>), MAP(imm_v256_shr_n_s64<12>), MAP(imm_v256_shr_n_s64<16>), MAP(imm_v256_shr_n_s64<20>), MAP(imm_v256_shr_n_s64<24>), MAP(imm_v256_shr_n_s64<28>), MAP(imm_v256_shr_n_s64<32>), MAP(imm_v256_shr_n_s64<36>), MAP(imm_v256_shr_n_s64<40>), MAP(imm_v256_shr_n_s64<44>), MAP(imm_v256_shr_n_s64<48>), MAP(imm_v256_shr_n_s64<52>), MAP(imm_v256_shr_n_s64<56>), MAP(imm_v256_shr_n_s64<60>), MAP(v256_movemask_8), MAP(v256_zero), MAP(v256_dup_8), MAP(v256_dup_16), MAP(v256_dup_32), MAP(v256_dup_64), MAP(v256_low_u32), MAP(v256_low_v64), MAP(v256_from_64), MAP(v256_from_v64), MAP(v256_ziplo_128), MAP(v256_ziphi_128), MAP(v256_unpacklo_u8_s16), MAP(v256_unpackhi_u8_s16), MAP(v256_unpacklo_s8_s16), MAP(v256_unpackhi_s8_s16), MAP(v256_blend_8), { nullptr, nullptr, nullptr } }; #undef MAP // Map reference functions to machine tuned functions. Since the // functions depend on machine tuned types, the non-machine tuned // instantiations of the test can't refer to these functions directly, // so we refer to them by name and do the mapping here. void Map(const char *name, fptr *ref, fptr *simd) { unsigned int i; for (i = 0; m[i].name && strcmp(name, m[i].name); i++) { } *ref = m[i].ref; *simd = m[i].simd; } // Used for printing errors in TestSimd1Arg, TestSimd2Args and TestSimd3Args std::string Print(const uint8_t *a, int size) { std::string text = "0x"; for (int i = 0; i < size; i++) { const uint8_t c = a[!CONFIG_BIG_ENDIAN ? size - 1 - i : i]; // Same as snprintf(..., ..., "%02x", c) text += (c >> 4) + '0' + ((c >> 4) > 9) * ('a' - '0' - 10); text += (c & 15) + '0' + ((c & 15) > 9) * ('a' - '0' - 10); } return text; } // Used in TestSimd1Arg, TestSimd2Args and TestSimd3Args to restrict argument // ranges void SetMask(uint8_t *s, int size, uint32_t mask, uint32_t maskwidth) { switch (maskwidth) { case 0: { break; } case 8: { for (int i = 0; i < size; i++) s[i] &= mask; break; } case 16: { uint16_t *t = reinterpret_cast(s); assert(!(reinterpret_cast(s) & 1)); for (int i = 0; i < size / 2; i++) t[i] &= mask; break; } case 32: { uint32_t *t = reinterpret_cast(s); assert(!(reinterpret_cast(s) & 3)); for (int i = 0; i < size / 4; i++) t[i] &= mask; break; } case 64: { uint64_t *t = reinterpret_cast(s); assert(!(reinterpret_cast(s) & 7)); for (int i = 0; i < size / 8; i++) t[i] &= mask; break; } default: { FAIL() << "Unsupported mask width"; break; } } } // We need some extra load/store functions void u64_store_aligned(void *p, uint64_t a) { v64_store_aligned(p, v64_from_64(a)); } void s32_store_aligned(void *p, int32_t a) { u32_store_aligned(p, static_cast(a)); } void s64_store_aligned(void *p, int64_t a) { v64_store_aligned(p, v64_from_64(static_cast(a))); } void c_u64_store_aligned(void *p, uint64_t a) { c_v64_store_aligned(p, c_v64_from_64(a)); } void c_s32_store_aligned(void *p, int32_t a) { c_u32_store_aligned(p, static_cast(a)); } void c_s64_store_aligned(void *p, int64_t a) { c_v64_store_aligned(p, c_v64_from_64(static_cast(a))); } uint64_t u64_load_aligned(const void *p) { return v64_u64(v64_load_aligned(p)); } uint16_t u16_load_aligned(const void *p) { return *(reinterpret_cast(p)); } uint8_t u8_load_aligned(const void *p) { return *(reinterpret_cast(p)); } uint64_t c_u64_load_aligned(const void *p) { return c_v64_u64(c_v64_load_aligned(p)); } uint16_t c_u16_load_aligned(const void *p) { return *(reinterpret_cast(p)); } uint8_t c_u8_load_aligned(const void *p) { return *(reinterpret_cast(p)); } // CompareSimd1Arg, CompareSimd2Args and CompareSimd3Args compare // intrinsics taking 1, 2 or 3 arguments respectively with their // corresponding C reference. Ideally, the loads and stores should // have gone into the template parameter list, but v64 and v128 could // be typedef'ed to the same type (which is the case on x86) and then // we can't instantiate both v64 and v128, so the function return and // argument types, including the always differing types in the C // equivalent are used instead. The function arguments must be void // pointers and then go through a cast to avoid matching errors in the // branches eliminated by the typeid tests in the calling function. template int CompareSimd1Arg(fptr store, fptr load, fptr simd, void *d, fptr c_store, fptr c_load, fptr c_simd, void *ref_d, const void *a) { void (*const my_store)(void *, Ret) = (void (*const)(void *, Ret))store; Arg (*const my_load)(const void *) = (Arg(*const)(const void *))load; Ret (*const my_simd)(Arg) = (Ret(*const)(Arg))simd; void (*const my_c_store)(void *, CRet) = (void (*const)(void *, CRet))c_store; CArg (*const my_c_load)(const void *) = (CArg(*const)(const void *))c_load; CRet (*const my_c_simd)(CArg) = (CRet(*const)(CArg))c_simd; // Call reference and intrinsic my_c_store(ref_d, my_c_simd(my_c_load(a))); my_store(d, my_simd(my_load(a))); // Compare results return memcmp(ref_d, d, sizeof(CRet)); } template int CompareSimd2Args(fptr store, fptr load1, fptr load2, fptr simd, void *d, fptr c_store, fptr c_load1, fptr c_load2, fptr c_simd, void *ref_d, const void *a, const void *b) { void (*const my_store)(void *, Ret) = (void (*const)(void *, Ret))store; Arg1 (*const my_load1)(const void *) = (Arg1(*const)(const void *))load1; Arg2 (*const my_load2)(const void *) = (Arg2(*const)(const void *))load2; Ret (*const my_simd)(Arg1, Arg2) = (Ret(*const)(Arg1, Arg2))simd; void (*const my_c_store)(void *, CRet) = (void (*const)(void *, CRet))c_store; CArg1 (*const my_c_load1)(const void *) = (CArg1(*const)(const void *))c_load1; CArg2 (*const my_c_load2)(const void *) = (CArg2(*const)(const void *))c_load2; CRet (*const my_c_simd)(CArg1, CArg2) = (CRet(*const)(CArg1, CArg2))c_simd; // Call reference and intrinsic my_c_store(ref_d, my_c_simd(my_c_load1(a), my_c_load2(b))); my_store(d, my_simd(my_load1(a), my_load2(b))); // Compare results return memcmp(ref_d, d, sizeof(CRet)); } template int CompareSimd3Args(fptr store, fptr load1, fptr load2, fptr load3, fptr simd, void *d, fptr c_store, fptr c_load1, fptr c_load2, fptr c_load3, fptr c_simd, void *ref_d, const void *a, const void *b, const void *c) { void (*const my_store)(void *, Ret) = (void (*const)(void *, Ret))store; Arg1 (*const my_load1)(const void *) = (Arg1(*const)(const void *))load1; Arg2 (*const my_load2)(const void *) = (Arg2(*const)(const void *))load2; Arg3 (*const my_load3)(const void *) = (Arg3(*const)(const void *))load3; Ret (*const my_simd)(Arg1, Arg2, Arg3) = (Ret(*const)(Arg1, Arg2, Arg3))simd; void (*const my_c_store)(void *, CRet) = (void (*const)(void *, CRet))c_store; CArg1 (*const my_c_load1)(const void *) = (CArg1(*const)(const void *))c_load1; CArg2 (*const my_c_load2)(const void *) = (CArg2(*const)(const void *))c_load2; CArg3 (*const my_c_load3)(const void *) = (CArg3(*const)(const void *))c_load3; CRet (*const my_c_simd)(CArg1, CArg2, CArg3) = (CRet(*const)(CArg1, CArg2, CArg3))c_simd; // Call reference and intrinsic my_c_store(ref_d, my_c_simd(my_c_load1(a), my_c_load2(b), my_c_load3(c))); my_store(d, my_simd(my_load1(a), my_load2(b), my_load3(c))); // Compare results return memcmp(ref_d, d, sizeof(CRet)); } } // namespace template void TestSimd1Arg(uint32_t iterations, uint32_t mask, uint32_t maskwidth, const char *name) { ACMRandom rnd(ACMRandom::DeterministicSeed()); fptr ref_simd; fptr simd; int error = 0; DECLARE_ALIGNED(32, uint8_t, s[32]); DECLARE_ALIGNED(32, uint8_t, d[32]); DECLARE_ALIGNED(32, uint8_t, ref_d[32]); assert(sizeof(CArg) <= 32 && sizeof(CRet) <= 32); memset(ref_d, 0, sizeof(ref_d)); memset(d, 0, sizeof(d)); Map(name, &ref_simd, &simd); if (simd == nullptr || ref_simd == nullptr) { FAIL() << "Internal error: Unknown intrinsic function " << name; } for (unsigned int count = 0; count < iterations && !error && !testing::Test::HasFailure(); count++) { for (unsigned int c = 0; c < sizeof(CArg); c++) s[c] = rnd.Rand8(); if (maskwidth) { SetMask(s, sizeof(CArg), mask, maskwidth); } if (typeid(CRet) == typeid(c_v64) && typeid(CArg) == typeid(c_v64)) { // V64_V64 error = CompareSimd1Arg( reinterpret_cast(v64_store_aligned), reinterpret_cast(v64_load_aligned), simd, d, reinterpret_cast(c_v64_store_aligned), reinterpret_cast(c_v64_load_aligned), ref_simd, ref_d, s); } else if (typeid(CRet) == typeid(c_v64) && typeid(CArg) == typeid(uint8_t)) { // V64_U8 error = CompareSimd1Arg( reinterpret_cast(v64_store_aligned), reinterpret_cast(u8_load_aligned), simd, d, reinterpret_cast(c_v64_store_aligned), reinterpret_cast(c_u8_load_aligned), ref_simd, ref_d, s); } else if (typeid(CRet) == typeid(c_v64) && typeid(CArg) == typeid(uint16_t)) { // V64_U16 error = CompareSimd1Arg( reinterpret_cast(v64_store_aligned), reinterpret_cast(u16_load_aligned), simd, d, reinterpret_cast(c_v64_store_aligned), reinterpret_cast(c_u16_load_aligned), ref_simd, ref_d, s); } else if (typeid(CRet) == typeid(c_v64) && typeid(CArg) == typeid(uint32_t)) { // V64_U32 error = CompareSimd1Arg( reinterpret_cast(v64_store_aligned), reinterpret_cast(u32_load_aligned), simd, d, reinterpret_cast(c_v64_store_aligned), reinterpret_cast(c_u32_load_aligned), ref_simd, ref_d, s); } else if (typeid(CRet) == typeid(uint64_t) && typeid(CArg) == typeid(c_v64)) { // U64_V64 error = CompareSimd1Arg( reinterpret_cast(u64_store_aligned), reinterpret_cast(v64_load_aligned), simd, d, reinterpret_cast(c_u64_store_aligned), reinterpret_cast(c_v64_load_aligned), ref_simd, ref_d, s); } else if (typeid(CRet) == typeid(int64_t) && typeid(CArg) == typeid(c_v64)) { // S64_V64 error = CompareSimd1Arg( reinterpret_cast(s64_store_aligned), reinterpret_cast(v64_load_aligned), simd, d, reinterpret_cast(c_s64_store_aligned), reinterpret_cast(c_v64_load_aligned), ref_simd, ref_d, s); } else if (typeid(CRet) == typeid(uint32_t) && typeid(CArg) == typeid(c_v64)) { // U32_V64 error = CompareSimd1Arg( reinterpret_cast(u32_store_aligned), reinterpret_cast(v64_load_aligned), simd, d, reinterpret_cast(c_u32_store_aligned), reinterpret_cast(c_v64_load_aligned), ref_simd, ref_d, s); } else if (typeid(CRet) == typeid(int32_t) && typeid(CArg) == typeid(c_v64)) { // S32_V64 error = CompareSimd1Arg( reinterpret_cast(s32_store_aligned), reinterpret_cast(v64_load_aligned), simd, d, reinterpret_cast(c_s32_store_aligned), reinterpret_cast(c_v64_load_aligned), ref_simd, ref_d, s); } else if (typeid(CRet) == typeid(uint32_t) && typeid(CArg) == typeid(c_v128)) { // U32_V128 error = CompareSimd1Arg( reinterpret_cast(u32_store_aligned), reinterpret_cast(v128_load_aligned), simd, d, reinterpret_cast(c_u32_store_aligned), reinterpret_cast(c_v128_load_aligned), ref_simd, ref_d, s); } else if (typeid(CRet) == typeid(uint64_t) && typeid(CArg) == typeid(c_v128)) { // U64_V128 error = CompareSimd1Arg( reinterpret_cast(u64_store_aligned), reinterpret_cast(v128_load_aligned), simd, d, reinterpret_cast(c_u64_store_aligned), reinterpret_cast(c_v128_load_aligned), ref_simd, ref_d, s); } else if (typeid(CRet) == typeid(uint64_t) && typeid(CArg) == typeid(c_v256)) { // U64_V256 error = CompareSimd1Arg( reinterpret_cast(u64_store_aligned), reinterpret_cast(v256_load_aligned), simd, d, reinterpret_cast(c_u64_store_aligned), reinterpret_cast(c_v256_load_aligned), ref_simd, ref_d, s); } else if (typeid(CRet) == typeid(c_v64) && typeid(CArg) == typeid(c_v128)) { // V64_V128 error = CompareSimd1Arg( reinterpret_cast(v64_store_aligned), reinterpret_cast(v128_load_aligned), simd, d, reinterpret_cast(c_v64_store_aligned), reinterpret_cast(c_v128_load_aligned), ref_simd, ref_d, s); } else if (typeid(CRet) == typeid(c_v128) && typeid(CArg) == typeid(c_v128)) { // V128_V128 error = CompareSimd1Arg( reinterpret_cast(v128_store_aligned), reinterpret_cast(v128_load_aligned), simd, d, reinterpret_cast(c_v128_store_aligned), reinterpret_cast(c_v128_load_aligned), ref_simd, ref_d, s); } else if (typeid(CRet) == typeid(c_v128) && typeid(CArg) == typeid(c_v64)) { // V128_V64 error = CompareSimd1Arg( reinterpret_cast(v128_store_aligned), reinterpret_cast(v64_load_aligned), simd, d, reinterpret_cast(c_v128_store_aligned), reinterpret_cast(c_v64_load_aligned), ref_simd, ref_d, s); } else if (typeid(CRet) == typeid(c_v128) && typeid(CArg) == typeid(uint8_t)) { // V128_U8 error = CompareSimd1Arg( reinterpret_cast(v128_store_aligned), reinterpret_cast(u8_load_aligned), simd, d, reinterpret_cast(c_v128_store_aligned), reinterpret_cast(c_u8_load_aligned), ref_simd, ref_d, s); } else if (typeid(CRet) == typeid(c_v128) && typeid(CArg) == typeid(uint16_t)) { // V128_U16 error = CompareSimd1Arg( reinterpret_cast(v128_store_aligned), reinterpret_cast(u16_load_aligned), simd, d, reinterpret_cast(c_v128_store_aligned), reinterpret_cast(c_u16_load_aligned), ref_simd, ref_d, s); } else if (typeid(CRet) == typeid(c_v128) && typeid(CArg) == typeid(uint32_t)) { // V128_U32 error = CompareSimd1Arg( reinterpret_cast(v128_store_aligned), reinterpret_cast(u32_load_aligned), simd, d, reinterpret_cast(c_v128_store_aligned), reinterpret_cast(c_u32_load_aligned), ref_simd, ref_d, s); } else if (typeid(CRet) == typeid(c_v128) && typeid(CArg) == typeid(uint64_t)) { // V128_U64 error = CompareSimd1Arg( reinterpret_cast(v128_store_aligned), reinterpret_cast(u64_load_aligned), simd, d, reinterpret_cast(c_v128_store_aligned), reinterpret_cast(c_u64_load_aligned), ref_simd, ref_d, s); } else if (typeid(CRet) == typeid(c_v256) && typeid(CArg) == typeid(c_v256)) { // V256_V256 error = CompareSimd1Arg( reinterpret_cast(v256_store_aligned), reinterpret_cast(v256_load_aligned), simd, d, reinterpret_cast(c_v256_store_aligned), reinterpret_cast(c_v256_load_aligned), ref_simd, ref_d, s); } else if (typeid(CRet) == typeid(c_v256) && typeid(CArg) == typeid(c_v128)) { // V256_V128 error = CompareSimd1Arg( reinterpret_cast(v256_store_aligned), reinterpret_cast(v128_load_aligned), simd, d, reinterpret_cast(c_v256_store_aligned), reinterpret_cast(c_v128_load_aligned), ref_simd, ref_d, s); } else if (typeid(CRet) == typeid(c_v256) && typeid(CArg) == typeid(uint8_t)) { // V256_U8 error = CompareSimd1Arg( reinterpret_cast(v256_store_aligned), reinterpret_cast(u8_load_aligned), simd, d, reinterpret_cast(c_v256_store_aligned), reinterpret_cast(c_u8_load_aligned), ref_simd, ref_d, s); } else if (typeid(CRet) == typeid(c_v256) && typeid(CArg) == typeid(uint16_t)) { // V256_U16 error = CompareSimd1Arg( reinterpret_cast(v256_store_aligned), reinterpret_cast(u16_load_aligned), simd, d, reinterpret_cast(c_v256_store_aligned), reinterpret_cast(c_u16_load_aligned), ref_simd, ref_d, s); } else if (typeid(CRet) == typeid(c_v256) && typeid(CArg) == typeid(uint32_t)) { // V256_U32 error = CompareSimd1Arg( reinterpret_cast(v256_store_aligned), reinterpret_cast(u32_load_aligned), simd, d, reinterpret_cast(c_v256_store_aligned), reinterpret_cast(c_u32_load_aligned), ref_simd, ref_d, s); } else if (typeid(CRet) == typeid(c_v256) && typeid(CArg) == typeid(uint64_t)) { // V256_U64 error = CompareSimd1Arg( reinterpret_cast(v256_store_aligned), reinterpret_cast(u64_load_aligned), simd, d, reinterpret_cast(c_v256_store_aligned), reinterpret_cast(c_u64_load_aligned), ref_simd, ref_d, s); } else if (typeid(CRet) == typeid(uint32_t) && typeid(CArg) == typeid(c_v256)) { // U32_V256 error = CompareSimd1Arg( reinterpret_cast(u32_store_aligned), reinterpret_cast(v256_load_aligned), simd, d, reinterpret_cast(c_u32_store_aligned), reinterpret_cast(c_v256_load_aligned), ref_simd, ref_d, s); } else if (typeid(CRet) == typeid(c_v64) && typeid(CArg) == typeid(c_v256)) { // V64_V256 error = CompareSimd1Arg( reinterpret_cast(v64_store_aligned), reinterpret_cast(v256_load_aligned), simd, d, reinterpret_cast(c_v64_store_aligned), reinterpret_cast(c_v256_load_aligned), ref_simd, ref_d, s); } else { FAIL() << "Internal error: Unknown intrinsic function " << typeid(CRet).name() << " " << name << "(" << typeid(CArg).name() << ")"; } } EXPECT_EQ(0, error) << "Error: mismatch for " << name << "(" << Print(s, sizeof(CArg)) << ") -> " << Print(d, sizeof(CRet)) << " (simd), " << Print(ref_d, sizeof(CRet)) << " (ref)"; } template void TestSimd2Args(uint32_t iterations, uint32_t mask, uint32_t maskwidth, const char *name) { ACMRandom rnd(ACMRandom::DeterministicSeed()); fptr ref_simd; fptr simd; int error = 0; DECLARE_ALIGNED(32, uint8_t, s1[32]); DECLARE_ALIGNED(32, uint8_t, s2[32]); DECLARE_ALIGNED(32, uint8_t, d[32]); DECLARE_ALIGNED(32, uint8_t, ref_d[32]); assert(sizeof(CArg1) <= 32 && sizeof(CArg2) <= 32 && sizeof(CRet) <= 32); memset(ref_d, 0, sizeof(ref_d)); memset(d, 0, sizeof(d)); Map(name, &ref_simd, &simd); if (simd == nullptr || ref_simd == nullptr) { FAIL() << "Internal error: Unknown intrinsic function " << name; } for (unsigned int count = 0; count < iterations && !error && !testing::Test::HasFailure(); count++) { for (unsigned int c = 0; c < sizeof(CArg1); c++) s1[c] = rnd.Rand8(); for (unsigned int c = 0; c < sizeof(CArg2); c++) s2[c] = rnd.Rand8(); if (maskwidth) SetMask(s2, sizeof(CArg2), mask, maskwidth); if (typeid(CRet) == typeid(c_v64) && typeid(CArg1) == typeid(c_v64) && typeid(CArg2) == typeid(c_v64)) { // V64_V64V64 error = CompareSimd2Args( reinterpret_cast(v64_store_aligned), reinterpret_cast(v64_load_aligned), reinterpret_cast(v64_load_aligned), simd, d, reinterpret_cast(c_v64_store_aligned), reinterpret_cast(c_v64_load_aligned), reinterpret_cast(c_v64_load_aligned), reinterpret_cast(ref_simd), ref_d, s1, s2); } else if (typeid(CRet) == typeid(c_v64) && typeid(CArg1) == typeid(uint32_t) && typeid(CArg2) == typeid(uint32_t)) { // V64_U32U32 error = CompareSimd2Args( reinterpret_cast(v64_store_aligned), reinterpret_cast(u32_load_aligned), reinterpret_cast(u32_load_aligned), simd, d, reinterpret_cast(c_v64_store_aligned), reinterpret_cast(c_u32_load_aligned), reinterpret_cast(c_u32_load_aligned), reinterpret_cast(ref_simd), ref_d, s1, s2); } else if (typeid(CRet) == typeid(uint32_t) && typeid(CArg1) == typeid(c_v64) && typeid(CArg2) == typeid(c_v64)) { // U32_V64V64 error = CompareSimd2Args( reinterpret_cast(u32_store_aligned), reinterpret_cast(v64_load_aligned), reinterpret_cast(v64_load_aligned), simd, d, reinterpret_cast(c_u32_store_aligned), reinterpret_cast(c_v64_load_aligned), reinterpret_cast(c_v64_load_aligned), reinterpret_cast(ref_simd), ref_d, s1, s2); } else if (typeid(CRet) == typeid(int64_t) && typeid(CArg1) == typeid(c_v64) && typeid(CArg2) == typeid(c_v64)) { // S64_V64V64 error = CompareSimd2Args( reinterpret_cast(s64_store_aligned), reinterpret_cast(v64_load_aligned), reinterpret_cast(v64_load_aligned), simd, d, reinterpret_cast(c_s64_store_aligned), reinterpret_cast(c_v64_load_aligned), reinterpret_cast(c_v64_load_aligned), reinterpret_cast(ref_simd), ref_d, s1, s2); } else if (typeid(CRet) == typeid(c_v64) && typeid(CArg1) == typeid(c_v64) && typeid(CArg2) == typeid(uint32_t)) { // V64_V64U32 error = CompareSimd2Args( reinterpret_cast(v64_store_aligned), reinterpret_cast(v64_load_aligned), reinterpret_cast(u32_load_aligned), simd, d, reinterpret_cast(c_v64_store_aligned), reinterpret_cast(c_v64_load_aligned), reinterpret_cast(c_u32_load_aligned), reinterpret_cast(ref_simd), ref_d, s1, s2); } else if (typeid(CRet) == typeid(c_v128) && typeid(CArg1) == typeid(c_v128) && typeid(CArg2) == typeid(c_v128)) { // V128_V128V128 error = CompareSimd2Args( reinterpret_cast(v128_store_aligned), reinterpret_cast(v128_load_aligned), reinterpret_cast(v128_load_aligned), simd, d, reinterpret_cast(c_v128_store_aligned), reinterpret_cast(c_v128_load_aligned), reinterpret_cast(c_v128_load_aligned), reinterpret_cast(ref_simd), ref_d, s1, s2); } else if (typeid(CRet) == typeid(uint32_t) && typeid(CArg1) == typeid(c_v128) && typeid(CArg2) == typeid(c_v128)) { // U32_V128V128 error = CompareSimd2Args( reinterpret_cast(u32_store_aligned), reinterpret_cast(v128_load_aligned), reinterpret_cast(v128_load_aligned), simd, d, reinterpret_cast(c_u32_store_aligned), reinterpret_cast(c_v128_load_aligned), reinterpret_cast(c_v128_load_aligned), reinterpret_cast(ref_simd), ref_d, s1, s2); } else if (typeid(CRet) == typeid(uint64_t) && typeid(CArg1) == typeid(c_v128) && typeid(CArg2) == typeid(c_v128)) { // U64_V128V128 error = CompareSimd2Args( reinterpret_cast(u64_store_aligned), reinterpret_cast(v128_load_aligned), reinterpret_cast(v128_load_aligned), simd, d, reinterpret_cast(c_u64_store_aligned), reinterpret_cast(c_v128_load_aligned), reinterpret_cast(c_v128_load_aligned), reinterpret_cast(ref_simd), ref_d, s1, s2); } else if (typeid(CRet) == typeid(int64_t) && typeid(CArg1) == typeid(c_v128) && typeid(CArg2) == typeid(c_v128)) { // S64_V128V128 error = CompareSimd2Args( reinterpret_cast(s64_store_aligned), reinterpret_cast(v128_load_aligned), reinterpret_cast(v128_load_aligned), simd, d, reinterpret_cast(c_s64_store_aligned), reinterpret_cast(c_v128_load_aligned), reinterpret_cast(c_v128_load_aligned), reinterpret_cast(ref_simd), ref_d, s1, s2); } else if (typeid(CRet) == typeid(c_v128) && typeid(CArg1) == typeid(uint64_t) && typeid(CArg2) == typeid(uint64_t)) { // V128_U64U64 error = CompareSimd2Args( reinterpret_cast(v128_store_aligned), reinterpret_cast(u64_load_aligned), reinterpret_cast(u64_load_aligned), simd, d, reinterpret_cast(c_v128_store_aligned), reinterpret_cast(c_u64_load_aligned), reinterpret_cast(c_u64_load_aligned), reinterpret_cast(ref_simd), ref_d, s1, s2); } else if (typeid(CRet) == typeid(c_v128) && typeid(CArg1) == typeid(c_v64) && typeid(CArg2) == typeid(c_v64)) { // V128_V64V64 error = CompareSimd2Args( reinterpret_cast(v128_store_aligned), reinterpret_cast(v64_load_aligned), reinterpret_cast(v64_load_aligned), simd, d, reinterpret_cast(c_v128_store_aligned), reinterpret_cast(c_v64_load_aligned), reinterpret_cast(c_v64_load_aligned), reinterpret_cast(ref_simd), ref_d, s1, s2); } else if (typeid(CRet) == typeid(c_v128) && typeid(CArg1) == typeid(c_v128) && typeid(CArg2) == typeid(uint32_t)) { // V128_V128U32 error = CompareSimd2Args( reinterpret_cast(v128_store_aligned), reinterpret_cast(v128_load_aligned), reinterpret_cast(u32_load_aligned), simd, d, reinterpret_cast(c_v128_store_aligned), reinterpret_cast(c_v128_load_aligned), reinterpret_cast(c_u32_load_aligned), reinterpret_cast(ref_simd), ref_d, s1, s2); } else if (typeid(CRet) == typeid(c_v256) && typeid(CArg1) == typeid(c_v256) && typeid(CArg2) == typeid(c_v256)) { // V256_V256V256 error = CompareSimd2Args( reinterpret_cast(v256_store_aligned), reinterpret_cast(v256_load_aligned), reinterpret_cast(v256_load_aligned), simd, d, reinterpret_cast(c_v256_store_aligned), reinterpret_cast(c_v256_load_aligned), reinterpret_cast(c_v256_load_aligned), reinterpret_cast(ref_simd), ref_d, s1, s2); } else if (typeid(CRet) == typeid(uint64_t) && typeid(CArg1) == typeid(c_v256) && typeid(CArg2) == typeid(c_v256)) { // U64_V256V256 error = CompareSimd2Args( reinterpret_cast(u64_store_aligned), reinterpret_cast(v256_load_aligned), reinterpret_cast(v256_load_aligned), simd, d, reinterpret_cast(c_u64_store_aligned), reinterpret_cast(c_v256_load_aligned), reinterpret_cast(c_v256_load_aligned), reinterpret_cast(ref_simd), ref_d, s1, s2); } else if (typeid(CRet) == typeid(int64_t) && typeid(CArg1) == typeid(c_v256) && typeid(CArg2) == typeid(c_v256)) { // S64_V256V256 error = CompareSimd2Args( reinterpret_cast(s64_store_aligned), reinterpret_cast(v256_load_aligned), reinterpret_cast(v256_load_aligned), simd, d, reinterpret_cast(c_s64_store_aligned), reinterpret_cast(c_v256_load_aligned), reinterpret_cast(c_v256_load_aligned), reinterpret_cast(ref_simd), ref_d, s1, s2); } else if (typeid(CRet) == typeid(uint32_t) && typeid(CArg1) == typeid(c_v256) && typeid(CArg2) == typeid(c_v256)) { // U32_V256V256 error = CompareSimd2Args( reinterpret_cast(u32_store_aligned), reinterpret_cast(v256_load_aligned), reinterpret_cast(v256_load_aligned), simd, d, reinterpret_cast(c_u32_store_aligned), reinterpret_cast(c_v256_load_aligned), reinterpret_cast(c_v256_load_aligned), reinterpret_cast(ref_simd), ref_d, s1, s2); } else if (typeid(CRet) == typeid(c_v256) && typeid(CArg1) == typeid(c_v128) && typeid(CArg2) == typeid(c_v128)) { // V256_V128V128 error = CompareSimd2Args( reinterpret_cast(v256_store_aligned), reinterpret_cast(v128_load_aligned), reinterpret_cast(v128_load_aligned), simd, d, reinterpret_cast(c_v256_store_aligned), reinterpret_cast(c_v128_load_aligned), reinterpret_cast(c_v128_load_aligned), reinterpret_cast(ref_simd), ref_d, s1, s2); } else if (typeid(CRet) == typeid(c_v256) && typeid(CArg1) == typeid(c_v256) && typeid(CArg2) == typeid(uint32_t)) { // V256_V256U32 error = CompareSimd2Args( reinterpret_cast(v256_store_aligned), reinterpret_cast(v256_load_aligned), reinterpret_cast(u32_load_aligned), simd, d, reinterpret_cast(c_v256_store_aligned), reinterpret_cast(c_v256_load_aligned), reinterpret_cast(c_u32_load_aligned), reinterpret_cast(ref_simd), ref_d, s1, s2); } else { FAIL() << "Internal error: Unknown intrinsic function " << typeid(CRet).name() << " " << name << "(" << typeid(CArg1).name() << ", " << typeid(CArg2).name() << ")"; } } EXPECT_EQ(0, error) << "Error: mismatch for " << name << "(" << Print(s1, sizeof(CArg1)) << ", " << Print(s2, sizeof(CArg2)) << ") -> " << Print(d, sizeof(CRet)) << " (simd), " << Print(ref_d, sizeof(CRet)) << " (ref)"; } template void TestSimd3Args(uint32_t iterations, uint32_t mask, uint32_t maskwidth, const char *name) { ACMRandom rnd(ACMRandom::DeterministicSeed()); fptr ref_simd; fptr simd; int error = 0; DECLARE_ALIGNED(32, uint8_t, s1[32]); DECLARE_ALIGNED(32, uint8_t, s2[32]); DECLARE_ALIGNED(32, uint8_t, s3[32]); DECLARE_ALIGNED(32, uint8_t, d[32]); DECLARE_ALIGNED(32, uint8_t, ref_d[32]); assert(sizeof(CArg1) <= 32 && sizeof(CArg2) <= 32 && sizeof(CArg3) <= 32 && sizeof(CRet) <= 32); memset(ref_d, 0, sizeof(ref_d)); memset(d, 0, sizeof(d)); Map(name, &ref_simd, &simd); if (simd == nullptr || ref_simd == nullptr) { FAIL() << "Internal error: Unknown intrinsic function " << name; } for (unsigned int count = 0; count < iterations && !error && !testing::Test::HasFailure(); count++) { for (unsigned int c = 0; c < sizeof(CArg1); c++) s1[c] = rnd.Rand8(); for (unsigned int c = 0; c < sizeof(CArg2); c++) s2[c] = rnd.Rand8(); for (unsigned int c = 0; c < sizeof(CArg3); c++) s3[c] = rnd.Rand8(); if (maskwidth) SetMask(s3, sizeof(CArg3), mask, maskwidth); if (typeid(CRet) == typeid(c_v128) && typeid(CArg1) == typeid(c_v128) && typeid(CArg2) == typeid(c_v128) && typeid(CArg3) == typeid(c_v128)) { // V128_V128V128V128 error = CompareSimd3Args( reinterpret_cast(v128_store_aligned), reinterpret_cast(v128_load_aligned), reinterpret_cast(v128_load_aligned), reinterpret_cast(v128_load_aligned), simd, d, reinterpret_cast(c_v128_store_aligned), reinterpret_cast(c_v128_load_aligned), reinterpret_cast(c_v128_load_aligned), reinterpret_cast(c_v128_load_aligned), reinterpret_cast(ref_simd), ref_d, s1, s2, s3); } else if (typeid(CRet) == typeid(c_v256) && typeid(CArg1) == typeid(c_v256) && typeid(CArg2) == typeid(c_v256) && typeid(CArg3) == typeid(c_v256)) { // V256_V256V256V256 error = CompareSimd3Args( reinterpret_cast(v256_store_aligned), reinterpret_cast(v256_load_aligned), reinterpret_cast(v256_load_aligned), reinterpret_cast(v256_load_aligned), simd, d, reinterpret_cast(c_v256_store_aligned), reinterpret_cast(c_v256_load_aligned), reinterpret_cast(c_v256_load_aligned), reinterpret_cast(c_v256_load_aligned), reinterpret_cast(ref_simd), ref_d, s1, s2, s3); } else { FAIL() << "Internal error: Unknown intrinsic function " << typeid(CRet).name() << " " << name << "(" << typeid(CArg1).name() << ", " << typeid(CArg2).name() << ", " << typeid(CArg3).name() << ")"; } } EXPECT_EQ(0, error) << "Error: mismatch for " << name << "(" << Print(s1, sizeof(CArg1)) << ", " << Print(s2, sizeof(CArg2)) << ", " << Print(s3, sizeof(CArg3)) << ") -> " << Print(d, sizeof(CRet)) << " (simd), " << Print(ref_d, sizeof(CRet)) << " (ref)"; } // Instantiations to make the functions callable from another files template void TestSimd1Arg(uint32_t, uint32_t, uint32_t, const char *); template void TestSimd1Arg(uint32_t, uint32_t, uint32_t, const char *); template void TestSimd1Arg(uint32_t, uint32_t, uint32_t, const char *); template void TestSimd1Arg(uint32_t, uint32_t, uint32_t, const char *); template void TestSimd1Arg(uint32_t, uint32_t, uint32_t, const char *); template void TestSimd1Arg(uint32_t, uint32_t, uint32_t, const char *); template void TestSimd1Arg(uint32_t, uint32_t, uint32_t, const char *); template void TestSimd1Arg(uint32_t, uint32_t, uint32_t, const char *); template void TestSimd2Args(uint32_t, uint32_t, uint32_t, const char *); template void TestSimd2Args(uint32_t, uint32_t, uint32_t, const char *); template void TestSimd2Args(uint32_t, uint32_t, uint32_t, const char *); template void TestSimd2Args(uint32_t, uint32_t, uint32_t, const char *); template void TestSimd2Args(uint32_t, uint32_t, uint32_t, const char *); template void TestSimd1Arg(uint32_t, uint32_t, uint32_t, const char *); template void TestSimd1Arg(uint32_t, uint32_t, uint32_t, const char *); template void TestSimd1Arg(uint32_t, uint32_t, uint32_t, const char *); template void TestSimd1Arg(uint32_t, uint32_t, uint32_t, const char *); template void TestSimd1Arg(uint32_t, uint32_t, uint32_t, const char *); template void TestSimd1Arg(uint32_t, uint32_t, uint32_t, const char *); template void TestSimd1Arg(uint32_t, uint32_t, uint32_t, const char *); template void TestSimd1Arg(uint32_t, uint32_t, uint32_t, const char *); template void TestSimd1Arg(uint32_t, uint32_t, uint32_t, const char *); template void TestSimd2Args(uint32_t, uint32_t, uint32_t, const char *); template void TestSimd2Args(uint32_t, uint32_t, uint32_t, const char *); template void TestSimd2Args(uint32_t, uint32_t, uint32_t, const char *); template void TestSimd2Args(uint32_t, uint32_t, uint32_t, const char *); template void TestSimd2Args(uint32_t, uint32_t, uint32_t, const char *); template void TestSimd2Args(uint32_t, uint32_t, uint32_t, const char *); template void TestSimd2Args(uint32_t, uint32_t, uint32_t, const char *); template void TestSimd3Args(uint32_t, uint32_t, uint32_t, const char *); template void TestSimd1Arg(uint32_t, uint32_t, uint32_t, const char *); template void TestSimd1Arg(uint32_t, uint32_t, uint32_t, const char *); template void TestSimd1Arg(uint32_t, uint32_t, uint32_t, const char *); template void TestSimd1Arg(uint32_t, uint32_t, uint32_t, const char *); template void TestSimd1Arg(uint32_t, uint32_t, uint32_t, const char *); template void TestSimd1Arg(uint32_t, uint32_t, uint32_t, const char *); template void TestSimd1Arg(uint32_t, uint32_t, uint32_t, const char *); template void TestSimd1Arg(uint32_t, uint32_t, uint32_t, const char *); template void TestSimd1Arg(uint32_t, uint32_t, uint32_t, const char *); template void TestSimd2Args(uint32_t, uint32_t, uint32_t, const char *); template void TestSimd2Args(uint32_t, uint32_t, uint32_t, const char *); template void TestSimd2Args(uint32_t, uint32_t, uint32_t, const char *); template void TestSimd2Args(uint32_t, uint32_t, uint32_t, const char *); template void TestSimd2Args(uint32_t, uint32_t, uint32_t, const char *); template void TestSimd2Args(uint32_t, uint32_t, uint32_t, const char *); template void TestSimd3Args(uint32_t, uint32_t, uint32_t, const char *); } // namespace SIMD_NAMESPACE