/* SPDX-License-Identifier: MIT * * Permission is hereby granted, free of charge, to any person * obtaining a copy of this software and associated documentation * files (the "Software"), to deal in the Software without * restriction, including without limitation the rights to use, copy, * modify, merge, publish, distribute, sublicense, and/or sell copies * of the Software, and to permit persons to whom the Software is * furnished to do so, subject to the following conditions: * * The above copyright notice and this permission notice shall be * included in all copies or substantial portions of the Software. * * THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, * EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF * MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND * NONINFRINGEMENT. IN NO EVENT SHALL THE AUTHORS OR COPYRIGHT HOLDERS * BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER IN AN * ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN * CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE * SOFTWARE. * * Copyright: * 2021 Evan Nemerson */ #if !defined(SIMDE_MIPS_MSA_ADDS_H) #define SIMDE_MIPS_MSA_ADDS_H #include "types.h" HEDLEY_DIAGNOSTIC_PUSH SIMDE_DISABLE_UNWANTED_DIAGNOSTICS SIMDE_BEGIN_DECLS_ SIMDE_FUNCTION_ATTRIBUTES simde_v16i8 simde_msa_adds_s_b(simde_v16i8 a, simde_v16i8 b) { #if defined(SIMDE_MIPS_MSA_NATIVE) return __msa_adds_s_b(a, b); #elif defined(SIMDE_ARM_NEON_A32V7_NATIVE) return vqaddq_s8(a, b); #elif defined(SIMDE_POWER_ALTIVEC_P6) return vec_adds(a, b); #else simde_v16i8_private a_ = simde_v16i8_to_private(a), b_ = simde_v16i8_to_private(b), r_; #if defined(SIMDE_WASM_SIMD128_NATIVE) r_.v128 = wasm_i8x16_add_sat(a_.v128, b_.v128); #elif defined(SIMDE_X86_SSE2_NATIVE) r_.m128i = _mm_adds_epi8(a_.m128i, b_.m128i); #elif defined(SIMDE_VECTOR_SCALAR) uint8_t au SIMDE_VECTOR(16) = HEDLEY_REINTERPRET_CAST(__typeof__(au), a_.values); uint8_t bu SIMDE_VECTOR(16) = HEDLEY_REINTERPRET_CAST(__typeof__(bu), b_.values); uint8_t ru SIMDE_VECTOR(16) = au + bu; au = (au >> 7) + INT8_MAX; uint8_t m SIMDE_VECTOR(16) = HEDLEY_REINTERPRET_CAST(__typeof__(m), HEDLEY_REINTERPRET_CAST(__typeof__(r_.values), (au ^ bu) | ~(bu ^ ru)) < 0); r_.values = HEDLEY_REINTERPRET_CAST(__typeof__(r_.values), (au & ~m) | (ru & m)); #else SIMDE_VECTORIZE for (size_t i = 0 ; i < (sizeof(r_.values) / sizeof(r_.values[0])) ; i++) { r_.values[i] = simde_math_adds_i8(a_.values[i], b_.values[i]); } #endif return simde_v16i8_from_private(r_); #endif } #if defined(SIMDE_MIPS_MSA_ENABLE_NATIVE_ALIASES) #undef __msa_adds_s_b #define __msa_adds_s_b(a, b) simde_msa_adds_s_b((a), (b)) #endif SIMDE_FUNCTION_ATTRIBUTES simde_v8i16 simde_msa_adds_s_h(simde_v8i16 a, simde_v8i16 b) { #if defined(SIMDE_MIPS_MSA_NATIVE) return __msa_adds_s_h(a, b); #elif defined(SIMDE_ARM_NEON_A32V7_NATIVE) return vqaddq_s16(a, b); #elif defined(SIMDE_POWER_ALTIVEC_P6) return vec_adds(a, b); #else simde_v8i16_private a_ = simde_v8i16_to_private(a), b_ = simde_v8i16_to_private(b), r_; #if defined(SIMDE_WASM_SIMD128_NATIVE) r_.v128 = wasm_i16x8_add_sat(a_.v128, b_.v128); #elif defined(SIMDE_X86_SSE2_NATIVE) r_.m128i = _mm_adds_epi16(a_.m128i, b_.m128i); #elif defined(SIMDE_VECTOR_SCALAR) uint16_t au SIMDE_VECTOR(16) = HEDLEY_REINTERPRET_CAST(__typeof__(au), a_.values); uint16_t bu SIMDE_VECTOR(16) = HEDLEY_REINTERPRET_CAST(__typeof__(bu), b_.values); uint16_t ru SIMDE_VECTOR(16) = au + bu; au = (au >> 15) + INT16_MAX; uint16_t m SIMDE_VECTOR(16) = HEDLEY_REINTERPRET_CAST(__typeof__(m), HEDLEY_REINTERPRET_CAST(__typeof__(r_.values), (au ^ bu) | ~(bu ^ ru)) < 0); r_.values = HEDLEY_REINTERPRET_CAST(__typeof__(r_.values), (au & ~m) | (ru & m)); #else SIMDE_VECTORIZE for (size_t i = 0 ; i < (sizeof(r_.values) / sizeof(r_.values[0])) ; i++) { r_.values[i] = simde_math_adds_i16(a_.values[i], b_.values[i]); } #endif return simde_v8i16_from_private(r_); #endif } #if defined(SIMDE_MIPS_MSA_ENABLE_NATIVE_ALIASES) #undef __msa_adds_s_h #define __msa_adds_s_h(a, b) simde_msa_adds_s_h((a), (b)) #endif SIMDE_FUNCTION_ATTRIBUTES simde_v4i32 simde_msa_adds_s_w(simde_v4i32 a, simde_v4i32 b) { #if defined(SIMDE_MIPS_MSA_NATIVE) return __msa_adds_s_w(a, b); #elif defined(SIMDE_ARM_NEON_A32V7_NATIVE) return vqaddq_s32(a, b); #elif defined(SIMDE_POWER_ALTIVEC_P6) return vec_adds(a, b); #else simde_v4i32_private a_ = simde_v4i32_to_private(a), b_ = simde_v4i32_to_private(b), r_; #if defined(SIMDE_X86_SSE2_NATIVE) /* https://stackoverflow.com/a/56544654/501126 */ const __m128i int_max = _mm_set1_epi32(INT32_MAX); /* normal result (possibly wraps around) */ const __m128i sum = _mm_add_epi32(a_.m128i, b_.m128i); /* If result saturates, it has the same sign as both a and b */ const __m128i sign_bit = _mm_srli_epi32(a_.m128i, 31); /* shift sign to lowest bit */ #if defined(SIMDE_X86_AVX512VL_NATIVE) const __m128i overflow = _mm_ternarylogic_epi32(a_.m128i, b_.m128i, sum, 0x42); #else const __m128i sign_xor = _mm_xor_si128(a_.m128i, b_.m128i); const __m128i overflow = _mm_andnot_si128(sign_xor, _mm_xor_si128(a_.m128i, sum)); #endif #if defined(SIMDE_X86_AVX512DQ_NATIVE) && defined(SIMDE_X86_AVX512VL_NATIVE) r_.m128i = _mm_mask_add_epi32(sum, _mm_movepi32_mask(overflow), int_max, sign_bit); #else const __m128i saturated = _mm_add_epi32(int_max, sign_bit); #if defined(SIMDE_X86_SSE4_1_NATIVE) r_.m128i = _mm_castps_si128( _mm_blendv_ps( _mm_castsi128_ps(sum), _mm_castsi128_ps(saturated), _mm_castsi128_ps(overflow) ) ); #else const __m128i overflow_mask = _mm_srai_epi32(overflow, 31); r_.m128i = _mm_or_si128( _mm_and_si128(overflow_mask, saturated), _mm_andnot_si128(overflow_mask, sum) ); #endif #endif #elif defined(SIMDE_VECTOR_SCALAR) uint32_t au SIMDE_VECTOR(16) = HEDLEY_REINTERPRET_CAST(__typeof__(au), a_.values); uint32_t bu SIMDE_VECTOR(16) = HEDLEY_REINTERPRET_CAST(__typeof__(bu), b_.values); uint32_t ru SIMDE_VECTOR(16) = au + bu; au = (au >> 31) + INT32_MAX; uint32_t m SIMDE_VECTOR(16) = HEDLEY_REINTERPRET_CAST(__typeof__(m), HEDLEY_REINTERPRET_CAST(__typeof__(r_.values), (au ^ bu) | ~(bu ^ ru)) < 0); r_.values = HEDLEY_REINTERPRET_CAST(__typeof__(r_.values), (au & ~m) | (ru & m)); #else SIMDE_VECTORIZE for (size_t i = 0 ; i < (sizeof(r_.values) / sizeof(r_.values[0])) ; i++) { r_.values[i] = simde_math_adds_i32(a_.values[i], b_.values[i]); } #endif return simde_v4i32_from_private(r_); #endif } #if defined(SIMDE_MIPS_MSA_ENABLE_NATIVE_ALIASES) #undef __msa_adds_s_w #define __msa_adds_s_w(a, b) simde_msa_adds_s_w((a), (b)) #endif SIMDE_FUNCTION_ATTRIBUTES simde_v2i64 simde_msa_adds_s_d(simde_v2i64 a, simde_v2i64 b) { #if defined(SIMDE_MIPS_MSA_NATIVE) return __msa_adds_s_d(a, b); #elif defined(SIMDE_ARM_NEON_A32V7_NATIVE) return vqaddq_s64(a, b); #else simde_v2i64_private a_ = simde_v2i64_to_private(a), b_ = simde_v2i64_to_private(b), r_; #if defined(SIMDE_X86_SSE4_1_NATIVE) /* https://stackoverflow.com/a/56544654/501126 */ const __m128i int_max = _mm_set1_epi64x(INT64_MAX); /* normal result (possibly wraps around) */ const __m128i sum = _mm_add_epi64(a_.m128i, b_.m128i); /* If result saturates, it has the same sign as both a and b */ const __m128i sign_bit = _mm_srli_epi64(a_.m128i, 63); /* shift sign to lowest bit */ #if defined(SIMDE_X86_AVX512VL_NATIVE) const __m128i overflow = _mm_ternarylogic_epi64(a_.m128i, b_.m128i, sum, 0x42); #else const __m128i sign_xor = _mm_xor_si128(a_.m128i, b_.m128i); const __m128i overflow = _mm_andnot_si128(sign_xor, _mm_xor_si128(a_.m128i, sum)); #endif #if defined(SIMDE_X86_AVX512VL_NATIVE) && defined(SIMDE_X86_AVX512DQ_NATIVE) r_.m128i = _mm_mask_add_epi64(sum, _mm_movepi64_mask(overflow), int_max, sign_bit); #else const __m128i saturated = _mm_add_epi64(int_max, sign_bit); r_.m128i = _mm_castpd_si128( _mm_blendv_pd( _mm_castsi128_pd(sum), _mm_castsi128_pd(saturated), _mm_castsi128_pd(overflow) ) ); #endif #elif defined(SIMDE_VECTOR_SCALAR) uint64_t au SIMDE_VECTOR(16) = HEDLEY_REINTERPRET_CAST(__typeof__(au), a_.values); uint64_t bu SIMDE_VECTOR(16) = HEDLEY_REINTERPRET_CAST(__typeof__(bu), b_.values); uint64_t ru SIMDE_VECTOR(16) = au + bu; au = (au >> 63) + INT64_MAX; uint64_t m SIMDE_VECTOR(16) = HEDLEY_REINTERPRET_CAST(__typeof__(m), HEDLEY_REINTERPRET_CAST(__typeof__(r_.values), (au ^ bu) | ~(bu ^ ru)) < 0); r_.values = HEDLEY_REINTERPRET_CAST(__typeof__(r_.values), (au & ~m) | (ru & m)); #else SIMDE_VECTORIZE for (size_t i = 0 ; i < (sizeof(r_.values) / sizeof(r_.values[0])) ; i++) { r_.values[i] = simde_math_adds_i64(a_.values[i], b_.values[i]); } #endif return simde_v2i64_from_private(r_); #endif } #if defined(SIMDE_MIPS_MSA_ENABLE_NATIVE_ALIASES) #undef __msa_adds_s_d #define __msa_adds_s_d(a, b) simde_msa_adds_s_d((a), (b)) #endif SIMDE_FUNCTION_ATTRIBUTES simde_v16u8 simde_msa_adds_u_b(simde_v16u8 a, simde_v16u8 b) { #if defined(SIMDE_MIPS_MSA_NATIVE) return __msa_adds_u_b(a, b); #elif defined(SIMDE_ARM_NEON_A32V7_NATIVE) return vqaddq_u8(a, b); #elif defined(SIMDE_POWER_ALTIVEC_P6) return vec_adds(a, b); #else simde_v16u8_private a_ = simde_v16u8_to_private(a), b_ = simde_v16u8_to_private(b), r_; #if defined(SIMDE_WASM_SIMD128_NATIVE) r_.v128 = wasm_u8x16_add_sat(a_.v128, b_.v128); #elif defined(SIMDE_X86_SSE2_NATIVE) r_.m128i = _mm_adds_epu8(a_.m128i, b_.m128i); #elif defined(SIMDE_VECTOR_SUBSCRIPT) r_.values = a_.values + b_.values; r_.values |= HEDLEY_REINTERPRET_CAST(__typeof__(r_.values), r_.values < a_.values); #else SIMDE_VECTORIZE for (size_t i = 0 ; i < (sizeof(r_.values) / sizeof(r_.values[0])) ; i++) { r_.values[i] = simde_math_adds_u8(a_.values[i], b_.values[i]); } #endif return simde_v16u8_from_private(r_); #endif } #if defined(SIMDE_MIPS_MSA_ENABLE_NATIVE_ALIASES) #undef __msa_adds_u_b #define __msa_adds_u_b(a, b) simde_msa_adds_u_b((a), (b)) #endif SIMDE_FUNCTION_ATTRIBUTES simde_v8u16 simde_msa_adds_u_h(simde_v8u16 a, simde_v8u16 b) { #if defined(SIMDE_MIPS_MSA_NATIVE) return __msa_adds_u_h(a, b); #elif defined(SIMDE_ARM_NEON_A32V7_NATIVE) return vqaddq_u16(a, b); #elif defined(SIMDE_POWER_ALTIVEC_P6) return vec_adds(a, b); #else simde_v8u16_private a_ = simde_v8u16_to_private(a), b_ = simde_v8u16_to_private(b), r_; #if defined(SIMDE_WASM_SIMD128_NATIVE) r_.v128 = wasm_u16x8_add_sat(a_.v128, b_.v128); #elif defined(SIMDE_X86_SSE2_NATIVE) r_.m128i = _mm_adds_epu16(a_.m128i, b_.m128i); #elif defined(SIMDE_VECTOR_SUBSCRIPT) r_.values = a_.values + b_.values; r_.values |= HEDLEY_REINTERPRET_CAST(__typeof__(r_.values), r_.values < a_.values); #else SIMDE_VECTORIZE for (size_t i = 0 ; i < (sizeof(r_.values) / sizeof(r_.values[0])) ; i++) { r_.values[i] = simde_math_adds_u16(a_.values[i], b_.values[i]); } #endif return simde_v8u16_from_private(r_); #endif } #if defined(SIMDE_MIPS_MSA_ENABLE_NATIVE_ALIASES) #undef __msa_adds_u_h #define __msa_adds_u_h(a, b) simde_msa_adds_u_h((a), (b)) #endif SIMDE_FUNCTION_ATTRIBUTES simde_v4u32 simde_msa_adds_u_w(simde_v4u32 a, simde_v4u32 b) { #if defined(SIMDE_MIPS_MSA_NATIVE) return __msa_adds_u_w(a, b); #elif defined(SIMDE_ARM_NEON_A32V7_NATIVE) return vqaddq_u32(a, b); #elif defined(SIMDE_POWER_ALTIVEC_P6) return vec_adds(a, b); #else simde_v4u32_private a_ = simde_v4u32_to_private(a), b_ = simde_v4u32_to_private(b), r_; #if defined(SIMDE_X86_SSE4_1_NATIVE) #if defined(__AVX512VL__) __m128i notb = _mm_ternarylogic_epi32(b, b, b, 0x0f); #else __m128i notb = _mm_xor_si128(b_.m128i, _mm_set1_epi32(~INT32_C(0))); #endif r_.m128i = _mm_add_epi32( b_.m128i, _mm_min_epu32( a_.m128i, notb ) ); #elif defined(SIMDE_X86_SSE2_NATIVE) const __m128i sum = _mm_add_epi32(a_.m128i, b_.m128i); const __m128i i32min = _mm_set1_epi32(INT32_MIN); a_.m128i = _mm_xor_si128(a_.m128i, i32min); r_.m128i = _mm_or_si128(_mm_cmpgt_epi32(a_.m128i, _mm_xor_si128(i32min, sum)), sum); #elif defined(SIMDE_VECTOR_SUBSCRIPT) r_.values = a_.values + b_.values; r_.values |= HEDLEY_REINTERPRET_CAST(__typeof__(r_.values), r_.values < a_.values); #else SIMDE_VECTORIZE for (size_t i = 0 ; i < (sizeof(r_.values) / sizeof(r_.values[0])) ; i++) { r_.values[i] = simde_math_adds_u32(a_.values[i], b_.values[i]); } #endif return simde_v4u32_from_private(r_); #endif } #if defined(SIMDE_MIPS_MSA_ENABLE_NATIVE_ALIASES) #undef __msa_adds_u_w #define __msa_adds_u_w(a, b) simde_msa_adds_u_w((a), (b)) #endif SIMDE_FUNCTION_ATTRIBUTES simde_v2u64 simde_msa_adds_u_d(simde_v2u64 a, simde_v2u64 b) { #if defined(SIMDE_MIPS_MSA_NATIVE) return __msa_adds_u_d(a, b); #elif defined(SIMDE_ARM_NEON_A32V7_NATIVE) return vqaddq_u64(a, b); #else simde_v2u64_private a_ = simde_v2u64_to_private(a), b_ = simde_v2u64_to_private(b), r_; #if defined(SIMDE_VECTOR_SUBSCRIPT) r_.values = a_.values + b_.values; r_.values |= HEDLEY_REINTERPRET_CAST(__typeof__(r_.values), r_.values < a_.values); #else SIMDE_VECTORIZE for (size_t i = 0 ; i < (sizeof(r_.values) / sizeof(r_.values[0])) ; i++) { r_.values[i] = simde_math_adds_u64(a_.values[i], b_.values[i]); } #endif return simde_v2u64_from_private(r_); #endif } #if defined(SIMDE_MIPS_MSA_ENABLE_NATIVE_ALIASES) #undef __msa_adds_u_d #define __msa_adds_u_d(a, b) simde_msa_adds_u_d((a), (b)) #endif SIMDE_END_DECLS_ HEDLEY_DIAGNOSTIC_POP #endif /* !defined(SIMDE_MIPS_MSA_ADDS_H) */