#if !defined(INTERLEAVE_H__) #define INTERLEAVE_H__ 1 ////////////////////////////////////////////////////////////////////////// // // Utilities to interleave and deinterleave multiple data for parallel // processing using SIMD. Utilities are grouped by data size. // //////////////////////////////// // // 32 bit data // Transpose 1 block consisting of 4x4x32 bit integers. #define MM128_ILEAVE32( d0, d1, d2, d3, s0, s1, s2, s3 ) \ { \ __m128i t0 = mm128_shuffle2_32( s0, s1, 0x44 ); \ __m128i t1 = mm128_shuffle2_32( s0, s1, 0xee ); \ __m128i t2 = mm128_shuffle2_32( s2, s3, 0x44 ); \ __m128i t3 = mm128_shuffle2_32( s2, s3, 0xee ); \ d0 = mm128_shuffle2_32( t0, t2, 0x88 ); \ d1 = mm128_shuffle2_32( t0, t2, 0xdd ); \ d2 = mm128_shuffle2_32( t1, t3, 0x88 ); \ d3 = mm128_shuffle2_32( t1, t3, 0xdd ); \ } #if defined(__AVX2__) // Transpose 2 contiguous blocks #define MM256_ILEAVE32( d0, d1, d2, d3, s0, s1, s2, s3 ) \ { \ __m256i t0 = mm256_shuffle2_32( s0, s1, 0x44 ); \ __m256i t1 = mm256_shuffle2_32( s0, s1, 0xee ); \ __m256i t2 = mm256_shuffle2_32( s2, s3, 0x44 ); \ __m256i t3 = mm256_shuffle2_32( s2, s3, 0xee ); \ d0 = mm256_shuffle2_32( t0, t2, 0x88 ); \ d1 = mm256_shuffle2_32( t0, t2, 0xdd ); \ d2 = mm256_shuffle2_32( t1, t3, 0x88 ); \ d3 = mm256_shuffle2_32( t1, t3, 0xdd ); \ } #endif #if defined(__AVX512F__) // Transpose 4 contiguous blocks. #define MM512_ILEAVE32( d0, d1, d2, d3, s0, s1, s2, s3 ) \ { \ __m512i t0 = mm512_shuffle2_32( s0, s1, 0x44 ); \ __m512i t1 = mm512_shuffle2_32( s0, s1, 0xee ); \ __m512i t2 = mm512_shuffle2_32( s2, s3, 0x44 ); \ __m512i t3 = mm512_shuffle2_32( s2, s3, 0xee ); \ d0 = mm512_shuffle2_32( t0, t2, 0x88 ); \ d1 = mm512_shuffle2_32( t0, t2, 0xdd ); \ d2 = mm512_shuffle2_32( t1, t3, 0x88 ); \ d3 = mm512_shuffle2_32( t1, t3, 0xdd ); \ } #endif // 2x32 static inline void intrlv_2x32( void *dst, const void *src0, const void *src1, const int bit_len ) { uint32_t *d = (uint32_t*)dst;; const uint32_t *s0 = (const uint32_t*)src0; const uint32_t *s1 = (const uint32_t*)src1; d[ 0] = s0[ 0]; d[ 1] = s1[ 0]; d[ 2] = s0[ 1]; d[ 3] = s1[ 1]; d[ 4] = s0[ 2]; d[ 5] = s1[ 2]; d[ 6] = s0[ 3]; d[ 7] = s1[ 3]; d[ 8] = s0[ 4]; d[ 9] = s1[ 4]; d[10] = s0[ 5]; d[11] = s1[ 5]; d[12] = s0[ 6]; d[13] = s1[ 6]; d[14] = s0[ 7]; d[15] = s1[ 7]; if ( bit_len <= 256 ) return; d[16] = s0[ 8]; d[17] = s1[ 8]; d[18] = s0[ 9]; d[19] = s1[ 9]; d[20] = s0[10]; d[21] = s1[10]; d[22] = s0[11]; d[23] = s1[11]; d[24] = s0[12]; d[25] = s1[12]; d[26] = s0[13]; d[27] = s1[13]; d[28] = s0[14]; d[29] = s1[14]; d[30] = s0[15]; d[31] = s1[15]; if ( bit_len <= 512 ) return; d[32] = s0[16]; d[33] = s1[16]; d[34] = s0[17]; d[35] = s1[17]; d[36] = s0[18]; d[37] = s1[18]; d[38] = s0[19]; d[39] = s1[19]; if ( bit_len <= 640 ) return; d[40] = s0[20]; d[41] = s1[20]; d[42] = s0[21]; d[43] = s1[21]; d[44] = s0[22]; d[45] = s1[22]; d[46] = s0[23]; d[47] = s1[23]; d[48] = s0[24]; d[49] = s1[24]; d[50] = s0[25]; d[51] = s1[25]; d[52] = s0[26]; d[53] = s1[26]; d[54] = s0[27]; d[55] = s1[27]; d[56] = s0[28]; d[57] = s1[28]; d[58] = s0[29]; d[59] = s1[29]; d[60] = s0[30]; d[61] = s1[30]; d[62] = s0[31]; d[63] = s1[31]; } static inline void dintrlv_2x32( void *dst0, void *dst1, const void *src, const int bit_len ) { uint32_t *d0 = (uint32_t*)dst0; uint32_t *d1 = (uint32_t*)dst1; const uint32_t *s = (const uint32_t*)src; d0[ 0] = s[ 0]; d1[ 0] = s[ 1]; d0[ 1] = s[ 2]; d1[ 1] = s[ 3]; d0[ 2] = s[ 4]; d1[ 2] = s[ 5]; d0[ 3] = s[ 6]; d1[ 3] = s[ 7]; d0[ 4] = s[ 8]; d1[ 4] = s[ 9]; d0[ 5] = s[10]; d1[ 5] = s[11]; d0[ 6] = s[12]; d1[ 6] = s[13]; d0[ 7] = s[14]; d1[ 7] = s[15]; if ( bit_len <= 256 ) return; d0[ 8] = s[16]; d1[ 8] = s[17]; d0[ 9] = s[18]; d1[ 9] = s[19]; d0[10] = s[20]; d1[10] = s[21]; d0[11] = s[22]; d1[11] = s[23]; d0[12] = s[24]; d1[12] = s[25]; d0[13] = s[26]; d1[13] = s[27]; d0[14] = s[28]; d1[14] = s[29]; d0[15] = s[30]; d1[15] = s[31]; if ( bit_len <= 512 ) return; d0[16] = s[32]; d1[16] = s[33]; d0[17] = s[34]; d1[17] = s[35]; d0[18] = s[36]; d1[18] = s[37]; d0[19] = s[38]; d1[19] = s[39]; if ( bit_len <= 640 ) return; d0[20] = s[40]; d1[20] = s[41]; d0[21] = s[42]; d1[21] = s[43]; d0[22] = s[44]; d1[22] = s[45]; d0[23] = s[46]; d1[23] = s[47]; d0[24] = s[48]; d1[24] = s[49]; d0[25] = s[50]; d1[25] = s[51]; d0[26] = s[52]; d1[26] = s[53]; d0[27] = s[54]; d1[27] = s[55]; d0[28] = s[56]; d1[28] = s[57]; d0[29] = s[58]; d1[29] = s[59]; d0[30] = s[60]; d1[30] = s[61]; d0[31] = s[62]; d1[31] = s[63]; } static inline void extr_lane_2x32( void *dst, const void *src, const int lane, const int bit_len ) { uint32_t *d = (uint32_t*)dst; const uint32_t *s = (const uint32_t*)src; d[ 0] = s[ lane ]; d[ 1] = s[ lane+ 2 ]; d[ 2] = s[ lane+ 4 ]; d[ 3] = s[ lane+ 6 ]; d[ 4] = s[ lane+ 8 ]; d[ 5] = s[ lane+10 ]; d[ 6] = s[ lane+12 ]; d[ 7] = s[ lane+14 ]; if ( bit_len <= 256 ) return; d[ 8] = s[ lane+16 ]; d[ 9] = s[ lane+18 ]; d[10] = s[ lane+20 ]; d[11] = s[ lane+22 ]; d[12] = s[ lane+24 ]; d[13] = s[ lane+26 ]; d[14] = s[ lane+28 ]; d[15] = s[ lane+30 ]; } // 4x32 /* static inline void intrlv_4x32( void *dst, const void *src0, const void *src1, const void *src2, const void *src3, const int bit_len ) { __m128i *d = (__m128i*)dst; const __m128i *s0 = (const __m128i*)src0; const __m128i *s1 = (const __m128i*)src1; const __m128i *s2 = (const __m128i*)src2; const __m128i *s3 = (const __m128i*)src3; MM128_ILEAVE32( d[ 0], d[ 1], d[ 2], d[ 3], s0[0], s1[0], s2[0], s3[0] ); MM128_ILEAVE32( d[ 4], d[ 5], d[ 6], d[ 7], s0[1], s1[1], s2[1], s3[1] ); if ( bit_len <= 256 ) return; MM128_ILEAVE32( d[ 8], d[ 9], d[10], d[11], s0[2], s1[2], s2[2], s3[2] ); MM128_ILEAVE32( d[12], d[13], d[14], d[15], s0[3], s1[3], s2[3], s3[3] ); if ( bit_len <= 512 ) return; MM128_ILEAVE32( d[16], d[17], d[18], d[19], s0[4], s1[4], s2[4], s3[4] ); if ( bit_len <= 640 ) return; MM128_ILEAVE32( d[20], d[21], d[22], d[23], s0[5], s1[5], s2[5], s3[5] ); MM128_ILEAVE32( d[24], d[25], d[26], d[27], s0[6], s1[6], s2[6], s3[6] ); MM128_ILEAVE32( d[28], d[29], d[30], d[31], s0[4], s1[4], s2[4], s3[4] ); } */ static inline void intrlv_4x32( void * dst, const void *src0, const void *src1, const void *src2, const void *src3, const int bit_len ) { uint32_t *d = (uint32_t*)dst; const uint32_t *s0 = (const uint32_t*)src0; const uint32_t *s1 = (const uint32_t*)src1; const uint32_t *s2 = (const uint32_t*)src2; const uint32_t *s3 = (const uint32_t*)src3; d[ 0] = s0[ 0]; d[ 1] = s1[ 0]; d[ 2] = s2[ 0]; d[ 3] = s3[ 0]; d[ 4] = s0[ 1]; d[ 5] = s1[ 1]; d[ 6] = s2[ 1]; d[ 7] = s3[ 1]; d[ 8] = s0[ 2]; d[ 9] = s1[ 2]; d[ 10] = s2[ 2]; d[ 11] = s3[ 2]; d[ 12] = s0[ 3]; d[ 13] = s1[ 3]; d[ 14] = s2[ 3]; d[ 15] = s3[ 3]; d[ 16] = s0[ 4]; d[ 17] = s1[ 4]; d[ 18] = s2[ 4]; d[ 19] = s3[ 4]; d[ 20] = s0[ 5]; d[ 21] = s1[ 5]; d[ 22] = s2[ 5]; d[ 23] = s3[ 5]; d[ 24] = s0[ 6]; d[ 25] = s1[ 6]; d[ 26] = s2[ 6]; d[ 27] = s3[ 6]; d[ 28] = s0[ 7]; d[ 29] = s1[ 7]; d[ 30] = s2[ 7]; d[ 31] = s3[ 7]; if ( bit_len <= 256 ) return; d[ 32] = s0[ 8]; d[ 33] = s1[ 8]; d[ 34] = s2[ 8]; d[ 35] = s3[ 8]; d[ 36] = s0[ 9]; d[ 37] = s1[ 9]; d[ 38] = s2[ 9]; d[ 39] = s3[ 9]; d[ 40] = s0[10]; d[ 41] = s1[10]; d[ 42] = s2[10]; d[ 43] = s3[10]; d[ 44] = s0[11]; d[ 45] = s1[11]; d[ 46] = s2[11]; d[ 47] = s3[11]; d[ 48] = s0[12]; d[ 49] = s1[12]; d[ 50] = s2[12]; d[ 51] = s3[12]; d[ 52] = s0[13]; d[ 53] = s1[13]; d[ 54] = s2[13]; d[ 55] = s3[13]; d[ 56] = s0[14]; d[ 57] = s1[14]; d[ 58] = s2[14]; d[ 59] = s3[14]; d[ 60] = s0[15]; d[ 61] = s1[15]; d[ 62] = s2[15]; d[ 63] = s3[15]; if ( bit_len <= 512 ) return; d[ 64] = s0[16]; d[ 65] = s1[16]; d[ 66] = s2[16]; d[ 67] = s3[16]; d[ 68] = s0[17]; d[ 69] = s1[17]; d[ 70] = s2[17]; d[ 71] = s3[17]; d[ 72] = s0[18]; d[ 73] = s1[18]; d[ 74] = s2[18]; d[ 75] = s3[18]; d[ 76] = s0[19]; d[ 77] = s1[19]; d[ 78] = s2[19]; d[ 79] = s3[19]; if ( bit_len <= 640 ) return; d[ 80] = s0[20]; d[ 81] = s1[20]; d[ 82] = s2[20]; d[ 83] = s3[20]; d[ 84] = s0[21]; d[ 85] = s1[21]; d[ 86] = s2[21]; d[ 87] = s3[21]; d[ 88] = s0[22]; d[ 89] = s1[22]; d[ 90] = s2[22]; d[ 91] = s3[22]; d[ 92] = s0[23]; d[ 93] = s1[23]; d[ 94] = s2[23]; d[ 95] = s3[23]; d[ 96] = s0[24]; d[ 97] = s1[24]; d[ 98] = s2[24]; d[ 99] = s3[24]; d[100] = s0[25]; d[101] = s1[25]; d[102] = s2[25]; d[103] = s3[25]; d[104] = s0[26]; d[105] = s1[26]; d[106] = s2[26]; d[107] = s3[26]; d[108] = s0[27]; d[109] = s1[27]; d[110] = s2[27]; d[111] = s3[27]; d[112] = s0[28]; d[113] = s1[28]; d[114] = s2[28]; d[115] = s3[28]; d[116] = s0[29]; d[117] = s1[29]; d[118] = s2[29]; d[119] = s3[29]; d[120] = s0[30]; d[121] = s1[30]; d[122] = s2[30]; d[123] = s3[30]; d[124] = s0[31]; d[125] = s1[31]; d[126] = s2[31]; d[127] = s3[31]; } /* static inline void intrlv_4x32_512( void *dst, const void *src0, const void *src1, const void *src2, const void *src3 ) { #if defined(__AVX2__) __m256i *d = (__m256i*)dst; const __m256i *s0 = (const __m256i*)src0; const __m256i *s1 = (const __m256i*)src1; const __m256i *s2 = (const __m256i*)src2; const __m256i *s3 = (const __m256i*)src3; __m256i dt0, dt1, dt2, dt3; MM256_ILEAVE32( dt0, dt1, dt2, dt3, s0[0], s1[0], s2[0], s3[0] ); d[0] = _mm256_permute2x128_si256( dt0, dt1, 0x20 ); d[1] = _mm256_permute2x128_si256( dt2, dt3, 0x20 ); d[2] = _mm256_permute2x128_si256( dt0, dt1, 0x31 ); d[3] = _mm256_permute2x128_si256( dt2, dt3, 0x31 ); MM256_ILEAVE32( dt0, dt1, dt2, dt3, s0[1], s1[1], s2[1], s3[1] ); d[4] = _mm256_permute2x128_si256( dt0, dt1, 0x20 ); d[5] = _mm256_permute2x128_si256( dt2, dt3, 0x20 ); d[6] = _mm256_permute2x128_si256( dt0, dt1, 0x31 ); d[7] = _mm256_permute2x128_si256( dt2, dt3, 0x31 ); #else __m128i *d = (__m128i*)dst; const __m128i *s0 = (const __m128i*)src0; const __m128i *s1 = (const __m128i*)src1; const __m128i *s2 = (const __m128i*)src2; const __m128i *s3 = (const __m128i*)src3; MM128_ILEAVE32( d[ 0], d[ 1], d[ 2], d[ 3], s0[0], s1[0], s2[0], s3[0] ); MM128_ILEAVE32( d[ 4], d[ 5], d[ 6], d[ 7], s0[1], s1[1], s2[1], s3[1] ); MM128_ILEAVE32( d[ 8], d[ 9], d[10], d[11], s0[2], s1[2], s2[2], s3[2] ); MM128_ILEAVE32( d[12], d[13], d[14], d[15], s0[3], s1[3], s2[3], s3[3] ); #endif } */ static inline void intrlv_4x32_512( void *dst, const void *src0, const void *src1, const void *src2, const void *src3 ) { uint32_t *d = (uint32_t*)dst; const uint32_t *s0 = (const uint32_t*)src0; const uint32_t *s1 = (const uint32_t*)src1; const uint32_t *s2 = (const uint32_t*)src2; const uint32_t *s3 = (const uint32_t*)src3; d[ 0] = s0[ 0]; d[ 1] = s1[ 0]; d[ 2] = s2[ 0]; d[ 3] = s3[ 0]; d[ 4] = s0[ 1]; d[ 5] = s1[ 1]; d[ 6] = s2[ 1]; d[ 7] = s3[ 1]; d[ 8] = s0[ 2]; d[ 9] = s1[ 2]; d[ 10] = s2[ 2]; d[ 11] = s3[ 2]; d[ 12] = s0[ 3]; d[ 13] = s1[ 3]; d[ 14] = s2[ 3]; d[ 15] = s3[ 3]; d[ 16] = s0[ 4]; d[ 17] = s1[ 4]; d[ 18] = s2[ 4]; d[ 19] = s3[ 4]; d[ 20] = s0[ 5]; d[ 21] = s1[ 5]; d[ 22] = s2[ 5]; d[ 23] = s3[ 5]; d[ 24] = s0[ 6]; d[ 25] = s1[ 6]; d[ 26] = s2[ 6]; d[ 27] = s3[ 6]; d[ 28] = s0[ 7]; d[ 29] = s1[ 7]; d[ 30] = s2[ 7]; d[ 31] = s3[ 7]; d[ 32] = s0[ 8]; d[ 33] = s1[ 8]; d[ 34] = s2[ 8]; d[ 35] = s3[ 8]; d[ 36] = s0[ 9]; d[ 37] = s1[ 9]; d[ 38] = s2[ 9]; d[ 39] = s3[ 9]; d[ 40] = s0[10]; d[ 41] = s1[10]; d[ 42] = s2[10]; d[ 43] = s3[10]; d[ 44] = s0[11]; d[ 45] = s1[11]; d[ 46] = s2[11]; d[ 47] = s3[11]; d[ 48] = s0[12]; d[ 49] = s1[12]; d[ 50] = s2[12]; d[ 51] = s3[12]; d[ 52] = s0[13]; d[ 53] = s1[13]; d[ 54] = s2[13]; d[ 55] = s3[13]; d[ 56] = s0[14]; d[ 57] = s1[14]; d[ 58] = s2[14]; d[ 59] = s3[14]; d[ 60] = s0[15]; d[ 61] = s1[15]; d[ 62] = s2[15]; d[ 63] = s3[15]; } /* static inline void dintrlv_4x32( void *dst0, void *dst1, void *dst2, void *dst3, const void *src, const int bit_len ) { __m128i *d0 = (__m128i*)dst0; __m128i *d1 = (__m128i*)dst1; __m128i *d2 = (__m128i*)dst2; __m128i *d3 = (__m128i*)dst3; const __m128i *s = (const __m128i*)src; MM128_ILEAVE32( d0[0], d1[0], d2[0], d3[0], s[ 0], s[ 1], s[ 2], s[ 3] ); MM128_ILEAVE32( d0[1], d1[1], d2[1], d3[1], s[ 4], s[ 5], s[ 6], s[ 7] ); if ( bit_len <= 256 ) return; MM128_ILEAVE32( d0[2], d1[2], d2[2], d3[2], s[ 8], s[ 9], s[10], s[11] ); MM128_ILEAVE32( d0[3], d1[3], d2[3], d3[3], s[12], s[13], s[14], s[15] ); if ( bit_len <= 512 ) return; MM128_ILEAVE32( d0[4], d1[4], d2[4], d3[4], s[16], s[17], s[18], s[19] ); if ( bit_len <= 640 ) return; MM128_ILEAVE32( d0[5], d1[5], d2[5], d3[5], s[20], s[21], s[22], s[23] ); MM128_ILEAVE32( d0[6], d1[6], d2[6], d3[6], s[24], s[25], s[26], s[27] ); MM128_ILEAVE32( d0[7], d1[7], d2[7], d3[7], s[28], s[29], s[30], s[31] ); } */ static inline void dintrlv_4x32( void *dst0, void *dst1, void *dst2, void *dst3, const void *src, const int bit_len ) { uint32_t *d0 = (uint32_t*)dst0; uint32_t *d1 = (uint32_t*)dst1; uint32_t *d2 = (uint32_t*)dst2; uint32_t *d3 = (uint32_t*)dst3; const uint32_t *s = (const uint32_t*)src; d0[ 0] = s[ 0]; d1[ 0] = s[ 1]; d2[ 0] = s[ 2]; d3[ 0] = s[ 3]; d0[ 1] = s[ 4]; d1[ 1] = s[ 5]; d2[ 1] = s[ 6]; d3[ 1] = s[ 7]; d0[ 2] = s[ 8]; d1[ 2] = s[ 9]; d2[ 2] = s[ 10]; d3[ 2] = s[ 11]; d0[ 3] = s[ 12]; d1[ 3] = s[ 13]; d2[ 3] = s[ 14]; d3[ 3] = s[ 15]; d0[ 4] = s[ 16]; d1[ 4] = s[ 17]; d2[ 4] = s[ 18]; d3[ 4] = s[ 19]; d0[ 5] = s[ 20]; d1[ 5] = s[ 21]; d2[ 5] = s[ 22]; d3[ 5] = s[ 23]; d0[ 6] = s[ 24]; d1[ 6] = s[ 25]; d2[ 6] = s[ 26]; d3[ 6] = s[ 27]; d0[ 7] = s[ 28]; d1[ 7] = s[ 29]; d2[ 7] = s[ 30]; d3[ 7] = s[ 31]; if ( bit_len <= 256 ) return; d0[ 8] = s[ 32]; d1[ 8] = s[ 33]; d2[ 8] = s[ 34]; d3[ 8] = s[ 35]; d0[ 9] = s[ 36]; d1[ 9] = s[ 37]; d2[ 9] = s[ 38]; d3[ 9] = s[ 39]; d0[10] = s[ 40]; d1[10] = s[ 41]; d2[10] = s[ 42]; d3[10] = s[ 43]; d0[11] = s[ 44]; d1[11] = s[ 45]; d2[11] = s[ 46]; d3[11] = s[ 47]; d0[12] = s[ 48]; d1[12] = s[ 49]; d2[12] = s[ 50]; d3[12] = s[ 51]; d0[13] = s[ 52]; d1[13] = s[ 53]; d2[13] = s[ 54]; d3[13] = s[ 55]; d0[14] = s[ 56]; d1[14] = s[ 57]; d2[14] = s[ 58]; d3[14] = s[ 59]; d0[15] = s[ 60]; d1[15] = s[ 61]; d2[15] = s[ 62]; d3[15] = s[ 63]; if ( bit_len <= 512 ) return; d0[16] = s[ 64]; d1[16] = s[ 65]; d2[16] = s[ 66]; d3[16] = s[ 67]; d0[17] = s[ 68]; d1[17] = s[ 69]; d2[17] = s[ 70]; d3[17] = s[ 71]; d0[18] = s[ 72]; d1[18] = s[ 73]; d2[18] = s[ 74]; d3[18] = s[ 75]; d0[19] = s[ 76]; d1[19] = s[ 77]; d2[19] = s[ 78]; d3[19] = s[ 79]; if ( bit_len <= 640 ) return; d0[20] = s[ 80]; d1[20] = s[ 81]; d2[20] = s[ 82]; d3[20] = s[ 83]; d0[21] = s[ 84]; d1[21] = s[ 85]; d2[21] = s[ 86]; d3[21] = s[ 87]; d0[22] = s[ 88]; d1[22] = s[ 89]; d2[22] = s[ 90]; d3[22] = s[ 91]; d0[23] = s[ 92]; d1[23] = s[ 93]; d2[23] = s[ 94]; d3[23] = s[ 95]; d0[24] = s[ 96]; d1[24] = s[ 97]; d2[24] = s[ 98]; d3[24] = s[ 99]; d0[25] = s[100]; d1[25] = s[101]; d2[25] = s[102]; d3[25] = s[103]; d0[26] = s[104]; d1[26] = s[105]; d2[26] = s[106]; d3[26] = s[107]; d0[27] = s[108]; d1[27] = s[109]; d2[27] = s[110]; d3[27] = s[111]; d0[28] = s[112]; d1[28] = s[113]; d2[28] = s[114]; d3[28] = s[115]; d0[29] = s[116]; d1[29] = s[117]; d2[29] = s[118]; d3[29] = s[119]; d0[30] = s[120]; d1[30] = s[121]; d2[30] = s[122]; d3[30] = s[123]; d0[31] = s[124]; d1[31] = s[125]; d2[31] = s[126]; d3[31] = s[127]; } /* static inline void dintrlv_4x32_512( void *dst0, void *dst1, void *dst2, void *dst3, const void *src ) { #if defined(__AVX2__) __m256i *d0 = (__m256i*)dst0; __m256i *d1 = (__m256i*)dst1; __m256i *d2 = (__m256i*)dst2; __m256i *d3 = (__m256i*)dst3; const __m256i *s = (const __m256i*)src; __m256i st0 = _mm256_permute2x128_si256( s[0], s[2], 0x20 ); __m256i st2 = _mm256_permute2x128_si256( s[1], s[3], 0x20 ); __m256i st1 = _mm256_permute2x128_si256( s[0], s[2], 0x31 ); __m256i st3 = _mm256_permute2x128_si256( s[1], s[3], 0x31 ); MM256_ILEAVE32( d0[0], d1[0], d2[0], d3[0], st0, st1, st2, st3 ); st0 = _mm256_permute2x128_si256( s[4], s[6], 0x20 ); st2 = _mm256_permute2x128_si256( s[5], s[7], 0x20 ); st1 = _mm256_permute2x128_si256( s[4], s[6], 0x31 ); st3 = _mm256_permute2x128_si256( s[5], s[7], 0x31 ); MM256_ILEAVE32( d0[1], d1[1], d2[1], d3[1], st0, st1, st2, st3 ); #else __m128i *d0 = (__m128i*)dst0; __m128i *d1 = (__m128i*)dst1; __m128i *d2 = (__m128i*)dst2; __m128i *d3 = (__m128i*)dst3; const __m128i *s = (const __m128i*)src; MM128_ILEAVE32( d0[0], d1[0], d2[0], d3[0], s[ 0], s[ 1], s[ 2], s[ 3] ); MM128_ILEAVE32( d0[1], d1[1], d2[1], d3[1], s[ 4], s[ 5], s[ 6], s[ 7] ); MM128_ILEAVE32( d0[2], d1[2], d2[2], d3[2], s[ 8], s[ 9], s[10], s[11] ); MM128_ILEAVE32( d0[3], d1[3], d2[3], d3[3], s[12], s[13], s[14], s[15] ); #endif } */ static inline void dintrlv_4x32_512( void *dst0, void *dst1, void *dst2, void *dst3, const void *src ) { uint32_t *d0 = (uint32_t*)dst0; uint32_t *d1 = (uint32_t*)dst1; uint32_t *d2 = (uint32_t*)dst2; uint32_t *d3 = (uint32_t*)dst3; const uint32_t *s = (const uint32_t*)src; d0[ 0] = s[ 0]; d1[ 0] = s[ 1]; d2[ 0] = s[ 2]; d3[ 0] = s[ 3]; d0[ 1] = s[ 4]; d1[ 1] = s[ 5]; d2[ 1] = s[ 6]; d3[ 1] = s[ 7]; d0[ 2] = s[ 8]; d1[ 2] = s[ 9]; d2[ 2] = s[ 10]; d3[ 2] = s[ 11]; d0[ 3] = s[ 12]; d1[ 3] = s[ 13]; d2[ 3] = s[ 14]; d3[ 3] = s[ 15]; d0[ 4] = s[ 16]; d1[ 4] = s[ 17]; d2[ 4] = s[ 18]; d3[ 4] = s[ 19]; d0[ 5] = s[ 20]; d1[ 5] = s[ 21]; d2[ 5] = s[ 22]; d3[ 5] = s[ 23]; d0[ 6] = s[ 24]; d1[ 6] = s[ 25]; d2[ 6] = s[ 26]; d3[ 6] = s[ 27]; d0[ 7] = s[ 28]; d1[ 7] = s[ 29]; d2[ 7] = s[ 30]; d3[ 7] = s[ 31]; d0[ 8] = s[ 32]; d1[ 8] = s[ 33]; d2[ 8] = s[ 34]; d3[ 8] = s[ 35]; d0[ 9] = s[ 36]; d1[ 9] = s[ 37]; d2[ 9] = s[ 38]; d3[ 9] = s[ 39]; d0[10] = s[ 40]; d1[10] = s[ 41]; d2[10] = s[ 42]; d3[10] = s[ 43]; d0[11] = s[ 44]; d1[11] = s[ 45]; d2[11] = s[ 46]; d3[11] = s[ 47]; d0[12] = s[ 48]; d1[12] = s[ 49]; d2[12] = s[ 50]; d3[12] = s[ 51]; d0[13] = s[ 52]; d1[13] = s[ 53]; d2[13] = s[ 54]; d3[13] = s[ 55]; d0[14] = s[ 56]; d1[14] = s[ 57]; d2[14] = s[ 58]; d3[14] = s[ 59]; d0[15] = s[ 60]; d1[15] = s[ 61]; d2[15] = s[ 62]; d3[15] = s[ 63]; } static inline void extr_lane_4x32( void *d, const void *s, const int lane, const int bit_len ) { ((uint32_t*)d)[ 0] = ((const uint32_t*)s)[ lane ]; ((uint32_t*)d)[ 1] = ((const uint32_t*)s)[ lane+ 4 ]; ((uint32_t*)d)[ 2] = ((const uint32_t*)s)[ lane+ 8 ]; ((uint32_t*)d)[ 3] = ((const uint32_t*)s)[ lane+12 ]; ((uint32_t*)d)[ 4] = ((const uint32_t*)s)[ lane+16 ]; ((uint32_t*)d)[ 5] = ((const uint32_t*)s)[ lane+20 ]; ((uint32_t*)d)[ 6] = ((const uint32_t*)s)[ lane+24 ]; ((uint32_t*)d)[ 7] = ((const uint32_t*)s)[ lane+28 ]; if ( bit_len <= 256 ) return; ((uint32_t*)d)[ 8] = ((const uint32_t*)s)[ lane+32 ]; ((uint32_t*)d)[ 9] = ((const uint32_t*)s)[ lane+36 ]; ((uint32_t*)d)[10] = ((const uint32_t*)s)[ lane+40 ]; ((uint32_t*)d)[11] = ((const uint32_t*)s)[ lane+44 ]; ((uint32_t*)d)[12] = ((const uint32_t*)s)[ lane+48 ]; ((uint32_t*)d)[13] = ((const uint32_t*)s)[ lane+52 ]; ((uint32_t*)d)[14] = ((const uint32_t*)s)[ lane+56 ]; ((uint32_t*)d)[15] = ((const uint32_t*)s)[ lane+60 ]; } // Still used by decred due to odd data size: 180 bytes // bit_len must be multiple of 32 static inline void mm128_intrlv_4x32x( void *dst, void *src0, void *src1, void *src2, void *src3, const int bit_len ) { uint32_t *d = (uint32_t*)dst; uint32_t *s0 = (uint32_t*)src0; uint32_t *s1 = (uint32_t*)src1; uint32_t *s2 = (uint32_t*)src2; uint32_t *s3 = (uint32_t*)src3; for ( int i = 0; i < bit_len >> 5; i++, d += 4 ) { *d = *(s0+i); *(d+1) = *(s1+i); *(d+2) = *(s2+i); *(d+3) = *(s3+i); } } #if defined(__SSSE3__) static inline void mm128_bswap32_80( void *d, void *s ) { __m128i bswap_shuf = m128_const_64( 0x0c0d0e0f08090a0b, 0x0405060700010203 ); casti_m128i( d, 0 ) = _mm_shuffle_epi8( casti_m128i( s, 0 ), bswap_shuf ); casti_m128i( d, 1 ) = _mm_shuffle_epi8( casti_m128i( s, 1 ), bswap_shuf ); casti_m128i( d, 2 ) = _mm_shuffle_epi8( casti_m128i( s, 2 ), bswap_shuf ); casti_m128i( d, 3 ) = _mm_shuffle_epi8( casti_m128i( s, 3 ), bswap_shuf ); casti_m128i( d, 4 ) = _mm_shuffle_epi8( casti_m128i( s, 4 ), bswap_shuf ); } #else static inline void mm128_bswap32_80( void *d, void *s ) { ( (uint32_t*)d )[ 0] = bswap_32( ( (uint32_t*)s )[ 0] ); ( (uint32_t*)d )[ 1] = bswap_32( ( (uint32_t*)s )[ 1] ); ( (uint32_t*)d )[ 2] = bswap_32( ( (uint32_t*)s )[ 2] ); ( (uint32_t*)d )[ 3] = bswap_32( ( (uint32_t*)s )[ 3] ); ( (uint32_t*)d )[ 4] = bswap_32( ( (uint32_t*)s )[ 4] ); ( (uint32_t*)d )[ 5] = bswap_32( ( (uint32_t*)s )[ 5] ); ( (uint32_t*)d )[ 6] = bswap_32( ( (uint32_t*)s )[ 6] ); ( (uint32_t*)d )[ 7] = bswap_32( ( (uint32_t*)s )[ 7] ); ( (uint32_t*)d )[ 8] = bswap_32( ( (uint32_t*)s )[ 8] ); ( (uint32_t*)d )[ 9] = bswap_32( ( (uint32_t*)s )[ 9] ); ( (uint32_t*)d )[10] = bswap_32( ( (uint32_t*)s )[10] ); ( (uint32_t*)d )[11] = bswap_32( ( (uint32_t*)s )[11] ); ( (uint32_t*)d )[12] = bswap_32( ( (uint32_t*)s )[12] ); ( (uint32_t*)d )[13] = bswap_32( ( (uint32_t*)s )[13] ); ( (uint32_t*)d )[14] = bswap_32( ( (uint32_t*)s )[14] ); ( (uint32_t*)d )[15] = bswap_32( ( (uint32_t*)s )[15] ); ( (uint32_t*)d )[16] = bswap_32( ( (uint32_t*)s )[16] ); ( (uint32_t*)d )[17] = bswap_32( ( (uint32_t*)s )[17] ); ( (uint32_t*)d )[18] = bswap_32( ( (uint32_t*)s )[18] ); ( (uint32_t*)d )[19] = bswap_32( ( (uint32_t*)s )[19] ); } #endif static inline void mm128_bswap32_intrlv80_4x32( void *d, const void *src ) { uint32_t *s = (uint32_t*)src; casti_m128i( d, 0 ) = _mm_set1_epi32( bswap_32( s[ 0] ) ); casti_m128i( d, 1 ) = _mm_set1_epi32( bswap_32( s[ 1] ) ); casti_m128i( d, 2 ) = _mm_set1_epi32( bswap_32( s[ 2] ) ); casti_m128i( d, 3 ) = _mm_set1_epi32( bswap_32( s[ 3] ) ); casti_m128i( d, 4 ) = _mm_set1_epi32( bswap_32( s[ 4] ) ); casti_m128i( d, 5 ) = _mm_set1_epi32( bswap_32( s[ 5] ) ); casti_m128i( d, 6 ) = _mm_set1_epi32( bswap_32( s[ 6] ) ); casti_m128i( d, 7 ) = _mm_set1_epi32( bswap_32( s[ 7] ) ); casti_m128i( d, 8 ) = _mm_set1_epi32( bswap_32( s[ 8] ) ); casti_m128i( d, 9 ) = _mm_set1_epi32( bswap_32( s[ 9] ) ); casti_m128i( d,10 ) = _mm_set1_epi32( bswap_32( s[10] ) ); casti_m128i( d,11 ) = _mm_set1_epi32( bswap_32( s[11] ) ); casti_m128i( d,12 ) = _mm_set1_epi32( bswap_32( s[12] ) ); casti_m128i( d,13 ) = _mm_set1_epi32( bswap_32( s[13] ) ); casti_m128i( d,14 ) = _mm_set1_epi32( bswap_32( s[14] ) ); casti_m128i( d,15 ) = _mm_set1_epi32( bswap_32( s[15] ) ); casti_m128i( d,16 ) = _mm_set1_epi32( bswap_32( s[16] ) ); casti_m128i( d,17 ) = _mm_set1_epi32( bswap_32( s[17] ) ); casti_m128i( d,18 ) = _mm_set1_epi32( bswap_32( s[18] ) ); casti_m128i( d,19 ) = _mm_set1_epi32( bswap_32( s[19] ) ); } /* static inline void mm128_bswap32_intrlv80_4x32( void *d, const void *src ) { __m128i s0 = casti_m128i( src,0 ); __m128i s1 = casti_m128i( src,1 ); __m128i s2 = casti_m128i( src,2 ); __m128i s3 = casti_m128i( src,3 ); __m128i s4 = casti_m128i( src,4 ); #if defined(__SSSE3__) __m128i bswap_shuf = m128_const_64( 0x0c0d0e0f08090a0b, 0x0405060700010203 ); s0 = _mm_shuffle_epi8( s0, bswap_shuf ); s1 = _mm_shuffle_epi8( s1, bswap_shuf ); s2 = _mm_shuffle_epi8( s2, bswap_shuf ); s3 = _mm_shuffle_epi8( s3, bswap_shuf ); s4 = _mm_shuffle_epi8( s4, bswap_shuf ); #else s0 = mm128_bswap_32( s0 ); s1 = mm128_bswap_32( s1 ); s2 = mm128_bswap_32( s2 ); s3 = mm128_bswap_32( s3 ); s4 = mm128_bswap_32( s4 ); #endif casti_m128i( d, 0 ) = _mm_shuffle_epi32( s0, 0x00 ); casti_m128i( d, 1 ) = _mm_shuffle_epi32( s0, 0x55 ); casti_m128i( d, 2 ) = _mm_shuffle_epi32( s0, 0xaa ); casti_m128i( d, 3 ) = _mm_shuffle_epi32( s0, 0xff ); casti_m128i( d, 4 ) = _mm_shuffle_epi32( s1, 0x00 ); casti_m128i( d, 5 ) = _mm_shuffle_epi32( s1, 0x55 ); casti_m128i( d, 6 ) = _mm_shuffle_epi32( s1, 0xaa ); casti_m128i( d, 7 ) = _mm_shuffle_epi32( s1, 0xff ); casti_m128i( d, 8 ) = _mm_shuffle_epi32( s2, 0x00 ); casti_m128i( d, 9 ) = _mm_shuffle_epi32( s2, 0x55 ); casti_m128i( d,10 ) = _mm_shuffle_epi32( s2, 0xaa ); casti_m128i( d,11 ) = _mm_shuffle_epi32( s2, 0xff ); casti_m128i( d,12 ) = _mm_shuffle_epi32( s3, 0x00 ); casti_m128i( d,13 ) = _mm_shuffle_epi32( s3, 0x55 ); casti_m128i( d,14 ) = _mm_shuffle_epi32( s3, 0xaa ); casti_m128i( d,15 ) = _mm_shuffle_epi32( s3, 0xff ); casti_m128i( d,16 ) = _mm_shuffle_epi32( s4, 0x00 ); casti_m128i( d,17 ) = _mm_shuffle_epi32( s4, 0x55 ); casti_m128i( d,18 ) = _mm_shuffle_epi32( s4, 0xaa ); casti_m128i( d,19 ) = _mm_shuffle_epi32( s4, 0xff ); } */ // 8x32 /* static inline void intrlv_8x32( void *dst, const void *src0, const void *src1, const void *src2, const void *src3, const void *src4, const void *src5, const void *src6, const void *src7, const int bit_len ) { __m128i *d = (__m128i*)dst; const __m128i *s0 = (const __m128i*)src0; const __m128i *s1 = (const __m128i*)src1; const __m128i *s2 = (const __m128i*)src2; const __m128i *s3 = (const __m128i*)src3; const __m128i *s4 = (const __m128i*)src4; const __m128i *s5 = (const __m128i*)src5; const __m128i *s6 = (const __m128i*)src6; const __m128i *s7 = (const __m128i*)src7; MM128_ILEAVE32( d[ 0], d[ 2], d[ 4], d[ 6], s0[0], s1[0], s2[0], s3[0] ); MM128_ILEAVE32( d[ 1], d[ 3], d[ 5], d[ 7], s4[0], s5[0], s6[0], s7[0] ); MM128_ILEAVE32( d[ 8], d[10], d[12], d[14], s0[1], s1[1], s2[1], s3[1] ); MM128_ILEAVE32( d[ 9], d[11], d[13], d[15], s4[1], s5[1], s6[1], s7[1] ); if ( bit_len <= 256 ) return; MM128_ILEAVE32( d[16], d[18], d[20], d[22], s0[2], s1[2], s2[2], s3[2] ); MM128_ILEAVE32( d[17], d[19], d[21], d[23], s4[2], s5[2], s6[2], s7[2] ); MM128_ILEAVE32( d[24], d[26], d[28], d[30], s0[3], s1[3], s2[3], s3[3] ); MM128_ILEAVE32( d[25], d[27], d[29], d[31], s4[3], s5[3], s6[3], s7[3] ); if ( bit_len <= 512 ) return; MM128_ILEAVE32( d[32], d[34], d[36], d[38], s0[4], s1[4], s2[4], s3[4] ); MM128_ILEAVE32( d[33], d[35], d[37], d[39], s4[4], s5[4], s6[4], s7[4] ); if ( bit_len <= 640 ) return; MM128_ILEAVE32( d[40], d[42], d[44], d[46], s0[5], s1[5], s2[5], s3[5] ); MM128_ILEAVE32( d[41], d[43], d[45], d[47], s4[5], s5[5], s6[5], s7[5] ); MM128_ILEAVE32( d[48], d[50], d[52], d[54], s0[6], s1[6], s2[6], s3[6] ); MM128_ILEAVE32( d[49], d[51], d[53], d[55], s4[6], s5[6], s6[6], s7[6] ); MM128_ILEAVE32( d[56], d[58], d[60], d[62], s0[7], s1[7], s2[7], s3[7] ); MM128_ILEAVE32( d[57], d[59], d[61], d[63], s4[7], s5[7], s6[7], s7[7] ); } // Not used static inline void intrlv_8x32_256( void *dst, const void *src0, const void *src1, const void *src2, const void *src3, const void *src4, const void *src5, const void *src6, const void *src7 ) { #if defined(__AVX2__) __m256i *d = (__m256i*)dst; const __m256i *s0 = (const __m256i*)src0; const __m256i *s1 = (const __m256i*)src1; const __m256i *s2 = (const __m256i*)src2; const __m256i *s3 = (const __m256i*)src3; const __m256i *s4 = (const __m256i*)src4; const __m256i *s5 = (const __m256i*)src5; const __m256i *s6 = (const __m256i*)src6; const __m256i *s7 = (const __m256i*)src7; __m256i dt0, dt1, dt2, dt3, dt4, dt5, dt6, dt7; MM256_ILEAVE32( dt0, dt1, dt2, dt3, s0[0], s1[0], s2[0], s3[0] ); MM256_ILEAVE32( dt4, dt5, dt6, dt7, s4[0], s5[0], s6[0], s7[0] ); d[0] = _mm256_permute2x128_si256( dt0, dt4, 0x20 ); d[4] = _mm256_permute2x128_si256( dt0, dt4, 0x31 ); d[1] = _mm256_permute2x128_si256( dt1, dt5, 0x20 ); d[5] = _mm256_permute2x128_si256( dt1, dt5, 0x31 ); d[2] = _mm256_permute2x128_si256( dt2, dt6, 0x20 ); d[6] = _mm256_permute2x128_si256( dt2, dt6, 0x31 ); d[3] = _mm256_permute2x128_si256( dt3, dt7, 0x20 ); d[7] = _mm256_permute2x128_si256( dt3, dt7, 0x31 ); #else // Shouldn't get here, 8x32 used only with AVX2 __m128i *d = (__m128i*)dst; const __m128i *s0 = (const __m128i*)src0; const __m128i *s1 = (const __m128i*)src1; const __m128i *s2 = (const __m128i*)src2; const __m128i *s3 = (const __m128i*)src3; const __m128i *s4 = (const __m128i*)src4; const __m128i *s5 = (const __m128i*)src5; const __m128i *s6 = (const __m128i*)src6; const __m128i *s7 = (const __m128i*)src7; MM128_ILEAVE32( d[ 0], d[ 2], d[ 4], d[ 6], s0[0], s1[0], s2[0], s3[0] ); MM128_ILEAVE32( d[ 1], d[ 3], d[ 5], d[ 7], s4[0], s5[0], s6[0], s7[0] ); MM128_ILEAVE32( d[ 8], d[10], d[12], d[14], s0[1], s1[1], s2[1], s3[1] ); MM128_ILEAVE32( d[ 9], d[11], d[13], d[15], s4[1], s5[1], s6[1], s7[1] ); #endif } static inline void intrlv_8x32_512( void *dst, const void *src0, const void *src1, const void *src2, const void *src3, const void *src4, const void *src5, const void *src6, const void *src7 ) { #if 0 //defined(__AVX512F__) __m512i *d = (__m512i*)dst; const __m512i *s0 = (const __m512i*)src0; const __m512i *s1 = (const __m512i*)src1; const __m512i *s2 = (const __m512i*)src2; const __m512i *s3 = (const __m512i*)src3; const __m512i *s4 = (const __m512i*)src4; const __m512i *s5 = (const __m512i*)src5; const __m512i *s6 = (const __m512i*)src6; const __m512i *s7 = (const __m512i*)src7; __m512i dt0, dt1, dt2, dt3, dt4, dt5, dt6, dt7, t0, t1, t2, t3; MM512_ILEAVE32( dt0, dt1, dt2, dt3, s0[0], s1[0], s2[0], s3[0] ); MM512_ILEAVE32( dt4, dt5, dt6, dt7, s4[0], s5[0], s6[0], s7[0] ); t0 = _mm512_shuffle_i32x4( dt0, dt4, 0x44 ); t2 = _mm512_shuffle_i32x4( dt1, dt5, 0x44 ); t1 = _mm512_shuffle_i32x4( dt0, dt4, 0xee ); t3 = _mm512_shuffle_i32x4( dt1, dt5, 0xee ); d[0] = _mm512_shuffle_i32x4( t0, t2, 0x88 ); d[2] = _mm512_shuffle_i32x4( t0, t2, 0xdd ); d[4] = _mm512_shuffle_i32x4( t1, t3, 0x88 ); d[6] = _mm512_shuffle_i32x4( t1, t3, 0xdd ); t0 = _mm512_shuffle_i32x4( dt2, dt6, 0x44 ); t2 = _mm512_shuffle_i32x4( dt3, dt7, 0x44 ); t1 = _mm512_shuffle_i32x4( dt2, dt6, 0xee ); t3 = _mm512_shuffle_i32x4( dt3, dt7, 0xee ); d[1] = _mm512_shuffle_i32x4( t0, t2, 0x88 ); d[3] = _mm512_shuffle_i32x4( t0, t2, 0xdd ); d[5] = _mm512_shuffle_i32x4( t1, t3, 0x88 ); d[7] = _mm512_shuffle_i32x4( t1, t3, 0xdd ); #elif defined(__AVX2__) __m256i *d = (__m256i*)dst; const __m256i *s0 = (const __m256i*)src0; const __m256i *s1 = (const __m256i*)src1; const __m256i *s2 = (const __m256i*)src2; const __m256i *s3 = (const __m256i*)src3; const __m256i *s4 = (const __m256i*)src4; const __m256i *s5 = (const __m256i*)src5; const __m256i *s6 = (const __m256i*)src6; const __m256i *s7 = (const __m256i*)src7; __m256i dt0, dt1, dt2, dt3, dt4, dt5, dt6, dt7; MM256_ILEAVE32( dt0, dt1, dt2, dt3, s0[0], s1[0], s2[0], s3[0] ); MM256_ILEAVE32( dt4, dt5, dt6, dt7, s4[0], s5[0], s6[0], s7[0] ); d[0] = _mm256_permute2x128_si256( dt0, dt4, 0x20 ); d[1] = _mm256_permute2x128_si256( dt1, dt5, 0x20 ); d[4] = _mm256_permute2x128_si256( dt0, dt4, 0x31 ); d[5] = _mm256_permute2x128_si256( dt1, dt5, 0x31 ); d[2] = _mm256_permute2x128_si256( dt2, dt6, 0x20 ); d[3] = _mm256_permute2x128_si256( dt3, dt7, 0x20 ); d[6] = _mm256_permute2x128_si256( dt2, dt6, 0x31 ); d[7] = _mm256_permute2x128_si256( dt3, dt7, 0x31 ); MM256_ILEAVE32( dt0, dt1, dt2, dt3, s0[1], s1[1], s2[1], s3[1] ); MM256_ILEAVE32( dt4, dt5, dt6, dt7, s4[1], s5[1], s6[1], s7[1] ); d[ 8] = _mm256_permute2x128_si256( dt0, dt4, 0x20 ); d[ 9] = _mm256_permute2x128_si256( dt1, dt5, 0x20 ); d[12] = _mm256_permute2x128_si256( dt0, dt4, 0x31 ); d[13] = _mm256_permute2x128_si256( dt1, dt5, 0x31 ); d[10] = _mm256_permute2x128_si256( dt2, dt6, 0x20 ); d[11] = _mm256_permute2x128_si256( dt3, dt7, 0x20 ); d[14] = _mm256_permute2x128_si256( dt2, dt6, 0x31 ); d[15] = _mm256_permute2x128_si256( dt3, dt7, 0x31 ); #else // Shouldn't get here, 8x32 only used with AVX2 or AVX512 __m128i *d = (__m128i*)dst; const __m128i *s0 = (const __m128i*)src0; const __m128i *s1 = (const __m128i*)src1; const __m128i *s2 = (const __m128i*)src2; const __m128i *s3 = (const __m128i*)src3; const __m128i *s4 = (const __m128i*)src4; const __m128i *s5 = (const __m128i*)src5; const __m128i *s6 = (const __m128i*)src6; const __m128i *s7 = (const __m128i*)src7; MM128_ILEAVE32( d[ 0], d[ 2], d[ 4], d[ 6], s0[0], s1[0], s2[0], s3[0] ); MM128_ILEAVE32( d[ 1], d[ 3], d[ 5], d[ 7], s4[0], s5[0], s6[0], s7[0] ); MM128_ILEAVE32( d[ 8], d[10], d[12], d[14], s0[1], s1[1], s2[1], s3[1] ); MM128_ILEAVE32( d[ 9], d[11], d[13], d[15], s4[1], s5[1], s6[1], s7[1] ); MM128_ILEAVE32( d[16], d[18], d[20], d[22], s0[2], s1[2], s2[2], s3[2] ); MM128_ILEAVE32( d[17], d[19], d[21], d[23], s4[2], s5[2], s6[2], s7[2] ); MM128_ILEAVE32( d[24], d[26], d[28], d[30], s0[3], s1[3], s2[3], s3[3] ); MM128_ILEAVE32( d[25], d[27], d[29], d[31], s4[3], s5[3], s6[3], s7[3] ); #endif } */ #define ILEAVE_8x32( i ) do \ { \ uint32_t *d = (uint32_t*)(dst) + ( (i) << 3 ); \ d[0] = *( (const uint32_t*)(s0) +(i) ); \ d[1] = *( (const uint32_t*)(s1) +(i) ); \ d[2] = *( (const uint32_t*)(s2) +(i) ); \ d[3] = *( (const uint32_t*)(s3) +(i) ); \ d[4] = *( (const uint32_t*)(s4) +(i) ); \ d[5] = *( (const uint32_t*)(s5) +(i) ); \ d[6] = *( (const uint32_t*)(s6) +(i) ); \ d[7] = *( (const uint32_t*)(s7) +(i) ); \ } while(0) static inline void intrlv_8x32b( void *dst, const void *s0, const void *s1, const void *s2, const void *s3, const void *s4, const void *s5, const void *s6, const void *s7, const int bit_len ) { for ( int i = 0; i < bit_len/32; i++ ) ILEAVE_8x32( i ); } static inline void intrlv_8x32( void *dst, const void *s0, const void *s1, const void *s2, const void *s3, const void *s4, const void *s5, const void *s6, const void *s7, const int bit_len ) { ILEAVE_8x32( 0 ); ILEAVE_8x32( 1 ); ILEAVE_8x32( 2 ); ILEAVE_8x32( 3 ); ILEAVE_8x32( 4 ); ILEAVE_8x32( 5 ); ILEAVE_8x32( 6 ); ILEAVE_8x32( 7 ); if ( bit_len <= 256 ) return; ILEAVE_8x32( 8 ); ILEAVE_8x32( 9 ); ILEAVE_8x32( 10 ); ILEAVE_8x32( 11 ); ILEAVE_8x32( 12 ); ILEAVE_8x32( 13 ); ILEAVE_8x32( 14 ); ILEAVE_8x32( 15 ); if ( bit_len <= 512 ) return; ILEAVE_8x32( 16 ); ILEAVE_8x32( 17 ); ILEAVE_8x32( 18 ); ILEAVE_8x32( 19 ); if ( bit_len <= 640 ) return; ILEAVE_8x32( 20 ); ILEAVE_8x32( 21 ); ILEAVE_8x32( 22 ); ILEAVE_8x32( 23 ); ILEAVE_8x32( 24 ); ILEAVE_8x32( 25 ); ILEAVE_8x32( 26 ); ILEAVE_8x32( 27 ); ILEAVE_8x32( 28 ); ILEAVE_8x32( 29 ); ILEAVE_8x32( 30 ); ILEAVE_8x32( 31 ); } static inline void intrlv_8x32_512( void *dst, const void *s0, const void *s1, const void *s2, const void *s3, const void *s4, const void *s5, const void *s6, const void *s7 ) { ILEAVE_8x32( 0 ); ILEAVE_8x32( 1 ); ILEAVE_8x32( 2 ); ILEAVE_8x32( 3 ); ILEAVE_8x32( 4 ); ILEAVE_8x32( 5 ); ILEAVE_8x32( 6 ); ILEAVE_8x32( 7 ); ILEAVE_8x32( 8 ); ILEAVE_8x32( 9 ); ILEAVE_8x32( 10 ); ILEAVE_8x32( 11 ); ILEAVE_8x32( 12 ); ILEAVE_8x32( 13 ); ILEAVE_8x32( 14 ); ILEAVE_8x32( 15 ); } #undef ILEAVE_8x32 /* static inline void dintrlv_8x32( void *dst0, void *dst1, void *dst2, void *dst3, void *dst4, void *dst5, void *dst6, void *dst7, const void *src, const int bit_len ) { __m128i *d0 = (__m128i*)dst0; __m128i *d1 = (__m128i*)dst1; __m128i *d2 = (__m128i*)dst2; __m128i *d3 = (__m128i*)dst3; __m128i *d4 = (__m128i*)dst4; __m128i *d5 = (__m128i*)dst5; __m128i *d6 = (__m128i*)dst6; __m128i *d7 = (__m128i*)dst7; const __m128i *s = (const __m128i*)src; MM128_ILEAVE32( d0[0], d1[0], d2[0], d3[0], s[ 0], s[ 2], s[ 4], s[ 6] ); MM128_ILEAVE32( d4[0], d5[0], d6[0], d7[0], s[ 1], s[ 3], s[ 5], s[ 7] ); MM128_ILEAVE32( d0[1], d1[1], d2[1], d3[1], s[ 8], s[10], s[12], s[14] ); MM128_ILEAVE32( d4[1], d5[1], d6[1], d7[1], s[ 9], s[11], s[13], s[15] ); if ( bit_len <= 256 ) return; MM128_ILEAVE32( d0[2], d1[2], d2[2], d3[2], s[16], s[18], s[20], s[22] ); MM128_ILEAVE32( d4[2], d5[2], d6[2], d7[2], s[17], s[19], s[21], s[23] ); MM128_ILEAVE32( d0[3], d1[3], d2[3], d3[3], s[24], s[26], s[28], s[30] ); MM128_ILEAVE32( d4[3], d5[3], d6[3], d7[3], s[25], s[27], s[29], s[31] ); if ( bit_len <= 512 ) return; MM128_ILEAVE32( d0[4], d1[4], d2[4], d3[4], s[32], s[34], s[36], s[38] ); MM128_ILEAVE32( d4[4], d5[4], d6[4], d7[4], s[33], s[35], s[37], s[39] ); if ( bit_len <= 640 ) return; MM128_ILEAVE32( d0[5], d1[5], d2[5], d3[5], s[40], s[42], s[44], s[46] ); MM128_ILEAVE32( d4[5], d5[5], d6[5], d7[5], s[41], s[43], s[45], s[47] ); MM128_ILEAVE32( d0[6], d1[6], d2[6], d3[6], s[48], s[50], s[52], s[54] ); MM128_ILEAVE32( d4[6], d5[6], d6[6], d7[6], s[49], s[51], s[53], s[55] ); MM128_ILEAVE32( d0[7], d1[7], d2[7], d3[7], s[56], s[58], s[60], s[62] ); MM128_ILEAVE32( d4[7], d5[7], d6[7], d7[7], s[57], s[59], s[61], s[63] ); } static inline void dintrlv_8x32_256( void *dst0, void *dst1, void *dst2, void *dst3, void *dst4, void *dst5, void *dst6, void *dst7, const void *src ) { #if defined(__AVX2__) __m256i *d0 = (__m256i*)dst0; __m256i *d1 = (__m256i*)dst1; __m256i *d2 = (__m256i*)dst2; __m256i *d3 = (__m256i*)dst3; __m256i *d4 = (__m256i*)dst4; __m256i *d5 = (__m256i*)dst5; __m256i *d6 = (__m256i*)dst6; __m256i *d7 = (__m256i*)dst7; const __m256i *s = (const __m256i*)src; __m256i st0 = _mm256_permute2x128_si256( s[0], s[4], 0x20 ); __m256i st1 = _mm256_permute2x128_si256( s[0], s[4], 0x31 ); __m256i st2 = _mm256_permute2x128_si256( s[1], s[5], 0x20 ); __m256i st3 = _mm256_permute2x128_si256( s[1], s[5], 0x31 ); __m256i st4 = _mm256_permute2x128_si256( s[2], s[6], 0x20 ); __m256i st5 = _mm256_permute2x128_si256( s[2], s[6], 0x31 ); __m256i st6 = _mm256_permute2x128_si256( s[3], s[7], 0x20 ); __m256i st7 = _mm256_permute2x128_si256( s[3], s[7], 0x31 ); MM256_ILEAVE32( d0[0], d1[0], d2[0], d3[0], st0, st2, st4, st6 ); MM256_ILEAVE32( d4[0], d5[0], d6[0], d7[0], st1, st3, st5, st7 ); #else // Not needed, 8x32 used only with AVX2, AVX512 __m128i *d0 = (__m128i*)dst0; __m128i *d1 = (__m128i*)dst1; __m128i *d2 = (__m128i*)dst2; __m128i *d3 = (__m128i*)dst3; __m128i *d4 = (__m128i*)dst4; __m128i *d5 = (__m128i*)dst5; __m128i *d6 = (__m128i*)dst6; __m128i *d7 = (__m128i*)dst7; const __m128i *s = (const __m128i*)src; MM128_ILEAVE32( d0[0], d1[0], d2[0], d3[0], s[ 0], s[ 2], s[ 4], s[ 6] ); MM128_ILEAVE32( d4[0], d5[0], d6[0], d7[0], s[ 1], s[ 3], s[ 5], s[ 7] ); MM128_ILEAVE32( d0[1], d1[1], d2[1], d3[1], s[ 8], s[10], s[12], s[14] ); MM128_ILEAVE32( d4[1], d5[1], d6[1], d7[1], s[ 9], s[11], s[13], s[15] ); #endif } static inline void dintrlv_8x32_512( void *dst0, void *dst1, void *dst2, void *dst3, void *dst4, void *dst5, void *dst6, void *dst7, const void *src ) { #if 0 // defined(__AVX512F__) __m512i *d0 = (__m512i*)dst0; __m512i *d1 = (__m512i*)dst1; __m512i *d2 = (__m512i*)dst2; __m512i *d3 = (__m512i*)dst3; __m512i *d4 = (__m512i*)dst4; __m512i *d5 = (__m512i*)dst5; __m512i *d6 = (__m512i*)dst6; __m512i *d7 = (__m512i*)dst7; const __m512i *s = (const __m512i*)src; __m512i st0, st1, st2, st3, st4, st5, st6, st7, t0, t1, t2, t3; t0 = _mm512_shuffle_i32x4( s[0], s[2], 0x44 ); t2 = _mm512_shuffle_i32x4( s[4], s[6], 0x44 ); t1 = _mm512_shuffle_i32x4( s[0], s[2], 0xee ); t3 = _mm512_shuffle_i32x4( s[4], s[6], 0xee ); st0 = _mm512_shuffle_i32x4( t0, t2, 0x88 ); st4 = _mm512_shuffle_i32x4( t0, t2, 0xdd ); st1 = _mm512_shuffle_i32x4( t1, t3, 0x88 ); st5 = _mm512_shuffle_i32x4( t1, t3, 0xdd ); t0 = _mm512_shuffle_i32x4( s[1], s[3], 0x44 ); t2 = _mm512_shuffle_i32x4( s[5], s[7], 0x44 ); t1 = _mm512_shuffle_i32x4( s[1], s[3], 0xee ); t3 = _mm512_shuffle_i32x4( s[5], s[7], 0xee ); st2 = _mm512_shuffle_i32x4( t0, t2, 0x88 ); st6 = _mm512_shuffle_i32x4( t0, t2, 0xdd ); st3 = _mm512_shuffle_i32x4( t1, t3, 0x88 ); st7 = _mm512_shuffle_i32x4( t1, t3, 0xdd ); MM512_ILEAVE32( d0[0], d1[0], d2[0], d3[0], st0, st1, st2, st3 ); MM512_ILEAVE32( d4[0], d5[0], d6[0], d7[0], st4, st5, st6, st7 ); #elif defined(__AVX2__) __m256i *d0 = (__m256i*)dst0; __m256i *d1 = (__m256i*)dst1; __m256i *d2 = (__m256i*)dst2; __m256i *d3 = (__m256i*)dst3; __m256i *d4 = (__m256i*)dst4; __m256i *d5 = (__m256i*)dst5; __m256i *d6 = (__m256i*)dst6; __m256i *d7 = (__m256i*)dst7; const __m256i *s = (const __m256i*)src; __m256i st0 = _mm256_permute2x128_si256( s[0], s[4], 0x20 ); __m256i st2 = _mm256_permute2x128_si256( s[1], s[5], 0x20 ); __m256i st1 = _mm256_permute2x128_si256( s[0], s[4], 0x31 ); __m256i st3 = _mm256_permute2x128_si256( s[1], s[5], 0x31 ); __m256i st4 = _mm256_permute2x128_si256( s[2], s[6], 0x20 ); __m256i st6 = _mm256_permute2x128_si256( s[3], s[7], 0x20 ); __m256i st5 = _mm256_permute2x128_si256( s[2], s[6], 0x31 ); __m256i st7 = _mm256_permute2x128_si256( s[3], s[7], 0x31 ); MM256_ILEAVE32( d0[0], d1[0], d2[0], d3[0], st0, st2, st4, st6 ); MM256_ILEAVE32( d4[0], d5[0], d6[0], d7[0], st1, st3, st5, st7 ); st0 = _mm256_permute2x128_si256( s[ 8], s[12], 0x20 ); st2 = _mm256_permute2x128_si256( s[ 9], s[13], 0x20 ); st1 = _mm256_permute2x128_si256( s[ 8], s[12], 0x31 ); st3 = _mm256_permute2x128_si256( s[ 9], s[13], 0x31 ); st4 = _mm256_permute2x128_si256( s[10], s[14], 0x20 ); st6 = _mm256_permute2x128_si256( s[11], s[15], 0x20 ); st5 = _mm256_permute2x128_si256( s[10], s[14], 0x31 ); st7 = _mm256_permute2x128_si256( s[11], s[15], 0x31 ); MM256_ILEAVE32( d0[1], d1[1], d2[1], d3[1], st0, st2, st4, st6 ); MM256_ILEAVE32( d4[1], d5[1], d6[1], d7[1], st1, st3, st5, st7 ); #else __m128i *d0 = (__m128i*)dst0; __m128i *d1 = (__m128i*)dst1; __m128i *d2 = (__m128i*)dst2; __m128i *d3 = (__m128i*)dst3; __m128i *d4 = (__m128i*)dst4; __m128i *d5 = (__m128i*)dst5; __m128i *d6 = (__m128i*)dst6; __m128i *d7 = (__m128i*)dst7; const __m128i *s = (const __m128i*)src; MM128_ILEAVE32( d0[0], d1[0], d2[0], d3[0], s[ 0], s[ 2], s[ 4], s[ 6] ); MM128_ILEAVE32( d4[0], d5[0], d6[0], d7[0], s[ 1], s[ 3], s[ 5], s[ 7] ); MM128_ILEAVE32( d0[1], d1[1], d2[1], d3[1], s[ 8], s[10], s[12], s[14] ); MM128_ILEAVE32( d4[1], d5[1], d6[1], d7[1], s[ 9], s[11], s[13], s[15] ); MM128_ILEAVE32( d0[2], d1[2], d2[2], d3[2], s[16], s[18], s[20], s[22] ); MM128_ILEAVE32( d4[2], d5[2], d6[2], d7[2], s[17], s[19], s[21], s[23] ); MM128_ILEAVE32( d0[3], d1[3], d2[3], d3[3], s[24], s[26], s[28], s[30] ); MM128_ILEAVE32( d4[3], d5[3], d6[3], d7[3], s[25], s[27], s[29], s[31] ); #endif } */ #define DLEAVE_8x32( i ) do \ { \ const uint32_t *s = (const uint32_t*)(src) + ( (i) << 3 ); \ *( (uint32_t*)(d0) +(i) ) = s[0]; \ *( (uint32_t*)(d1) +(i) ) = s[1]; \ *( (uint32_t*)(d2) +(i) ) = s[2]; \ *( (uint32_t*)(d3) +(i) ) = s[3]; \ *( (uint32_t*)(d4) +(i) ) = s[4]; \ *( (uint32_t*)(d5) +(i) ) = s[5]; \ *( (uint32_t*)(d6) +(i) ) = s[6]; \ *( (uint32_t*)(d7) +(i) ) = s[7]; \ } while(0) static inline void dintrlv_8x32b( void *d0, void *d1, void *d2, void *d3, void *d4, void *d5, void *d6, void *d7, const void *src, const int bit_len ) { for ( int i = 0; i < bit_len/32; i++ ) DLEAVE_8x32( i ); } static inline void dintrlv_8x32( void *d0, void *d1, void *d2, void *d3, void *d4, void *d5, void *d6, void *d7, const void *src, const int bit_len ) { DLEAVE_8x32( 0 ); DLEAVE_8x32( 1 ); DLEAVE_8x32( 2 ); DLEAVE_8x32( 3 ); DLEAVE_8x32( 4 ); DLEAVE_8x32( 5 ); DLEAVE_8x32( 6 ); DLEAVE_8x32( 7 ); if ( bit_len <= 256 ) return; DLEAVE_8x32( 8 ); DLEAVE_8x32( 9 ); DLEAVE_8x32( 10 ); DLEAVE_8x32( 11 ); DLEAVE_8x32( 12 ); DLEAVE_8x32( 13 ); DLEAVE_8x32( 14 ); DLEAVE_8x32( 15 ); if ( bit_len <= 512 ) return; DLEAVE_8x32( 16 ); DLEAVE_8x32( 17 ); DLEAVE_8x32( 18 ); DLEAVE_8x32( 19 ); if ( bit_len <= 640 ) return; DLEAVE_8x32( 20 ); DLEAVE_8x32( 21 ); DLEAVE_8x32( 22 ); DLEAVE_8x32( 23 ); DLEAVE_8x32( 24 ); DLEAVE_8x32( 25 ); DLEAVE_8x32( 26 ); DLEAVE_8x32( 27 ); DLEAVE_8x32( 28 ); DLEAVE_8x32( 29 ); DLEAVE_8x32( 30 ); DLEAVE_8x32( 31 ); } static inline void dintrlv_8x32_512( void *d0, void *d1, void *d2, void *d3, void *d4, void *d5, void *d6, void *d7, const void *src ) { DLEAVE_8x32( 0 ); DLEAVE_8x32( 1 ); DLEAVE_8x32( 2 ); DLEAVE_8x32( 3 ); DLEAVE_8x32( 4 ); DLEAVE_8x32( 5 ); DLEAVE_8x32( 6 ); DLEAVE_8x32( 7 ); DLEAVE_8x32( 8 ); DLEAVE_8x32( 9 ); DLEAVE_8x32( 10 ); DLEAVE_8x32( 11 ); DLEAVE_8x32( 12 ); DLEAVE_8x32( 13 ); DLEAVE_8x32( 14 ); DLEAVE_8x32( 15 ); } #undef DLEAVE_8x32 static inline void extr_lane_8x32( void *d, const void *s, const int lane, const int bit_len ) { ((uint32_t*)d)[ 0] = ((const uint32_t*)s)[ lane ]; ((uint32_t*)d)[ 1] = ((const uint32_t*)s)[ lane+ 8 ]; ((uint32_t*)d)[ 2] = ((const uint32_t*)s)[ lane+ 16 ]; ((uint32_t*)d)[ 3] = ((const uint32_t*)s)[ lane+ 24 ]; ((uint32_t*)d)[ 4] = ((const uint32_t*)s)[ lane+ 32 ]; ((uint32_t*)d)[ 5] = ((const uint32_t*)s)[ lane+ 40 ]; ((uint32_t*)d)[ 6] = ((const uint32_t*)s)[ lane+ 48 ]; ((uint32_t*)d)[ 7] = ((const uint32_t*)s)[ lane+ 56 ]; if ( bit_len <= 256 ) return; ((uint32_t*)d)[ 8] = ((const uint32_t*)s)[ lane+ 64 ]; ((uint32_t*)d)[ 9] = ((const uint32_t*)s)[ lane+ 72 ]; ((uint32_t*)d)[10] = ((const uint32_t*)s)[ lane+ 80 ]; ((uint32_t*)d)[11] = ((const uint32_t*)s)[ lane+ 88 ]; ((uint32_t*)d)[12] = ((const uint32_t*)s)[ lane+ 96 ]; ((uint32_t*)d)[13] = ((const uint32_t*)s)[ lane+104 ]; ((uint32_t*)d)[14] = ((const uint32_t*)s)[ lane+112 ]; ((uint32_t*)d)[15] = ((const uint32_t*)s)[ lane+120 ]; } #if defined(__AVX2__) static inline void mm256_bswap32_intrlv80_8x32( void *d, const void *src ) { uint32_t *s = (uint32_t*)src; casti_m256i( d, 0 ) = _mm256_set1_epi32( bswap_32( s[ 0] ) ); casti_m256i( d, 1 ) = _mm256_set1_epi32( bswap_32( s[ 1] ) ); casti_m256i( d, 2 ) = _mm256_set1_epi32( bswap_32( s[ 2] ) ); casti_m256i( d, 3 ) = _mm256_set1_epi32( bswap_32( s[ 3] ) ); casti_m256i( d, 4 ) = _mm256_set1_epi32( bswap_32( s[ 4] ) ); casti_m256i( d, 5 ) = _mm256_set1_epi32( bswap_32( s[ 5] ) ); casti_m256i( d, 6 ) = _mm256_set1_epi32( bswap_32( s[ 6] ) ); casti_m256i( d, 7 ) = _mm256_set1_epi32( bswap_32( s[ 7] ) ); casti_m256i( d, 8 ) = _mm256_set1_epi32( bswap_32( s[ 8] ) ); casti_m256i( d, 9 ) = _mm256_set1_epi32( bswap_32( s[ 9] ) ); casti_m256i( d,10 ) = _mm256_set1_epi32( bswap_32( s[10] ) ); casti_m256i( d,11 ) = _mm256_set1_epi32( bswap_32( s[11] ) ); casti_m256i( d,12 ) = _mm256_set1_epi32( bswap_32( s[12] ) ); casti_m256i( d,13 ) = _mm256_set1_epi32( bswap_32( s[13] ) ); casti_m256i( d,14 ) = _mm256_set1_epi32( bswap_32( s[14] ) ); casti_m256i( d,15 ) = _mm256_set1_epi32( bswap_32( s[15] ) ); casti_m256i( d,16 ) = _mm256_set1_epi32( bswap_32( s[16] ) ); casti_m256i( d,17 ) = _mm256_set1_epi32( bswap_32( s[17] ) ); casti_m256i( d,18 ) = _mm256_set1_epi32( bswap_32( s[18] ) ); casti_m256i( d,19 ) = _mm256_set1_epi32( bswap_32( s[19] ) ); } /* static inline void mm256_bswap32_intrlv80_8x32( void *d, const void *src ) { __m128i bswap_shuf = m128_const_64( 0x0c0d0e0f08090a0b, 0x0405060700010203 ); __m128i s0 = casti_m128i( src,0 ); __m128i s1 = casti_m128i( src,1 ); __m128i s2 = casti_m128i( src,2 ); __m128i s3 = casti_m128i( src,3 ); __m128i s4 = casti_m128i( src,4 ); s0 = _mm_shuffle_epi8( s0, bswap_shuf ); s1 = _mm_shuffle_epi8( s1, bswap_shuf ); s2 = _mm_shuffle_epi8( s2, bswap_shuf ); s3 = _mm_shuffle_epi8( s3, bswap_shuf ); s4 = _mm_shuffle_epi8( s4, bswap_shuf ); casti_m128i( d, 0 ) = casti_m128i( d, 1 ) = _mm_shuffle_epi32( s0 , 0x00 ); casti_m128i( d, 2 ) = casti_m128i( d, 3 ) = _mm_shuffle_epi32( s0 , 0x55 ); casti_m128i( d, 4 ) = casti_m128i( d, 5 ) = _mm_shuffle_epi32( s0 , 0xaa ); casti_m128i( d, 6 ) = casti_m128i( d, 7 ) = _mm_shuffle_epi32( s0 , 0xff ); casti_m128i( d, 8 ) = casti_m128i( d, 9 ) = _mm_shuffle_epi32( s1 , 0x00 ); casti_m128i( d,10 ) = casti_m128i( d,11 ) = _mm_shuffle_epi32( s1 , 0x55 ); casti_m128i( d,12 ) = casti_m128i( d,13 ) = _mm_shuffle_epi32( s1 , 0xaa ); casti_m128i( d,14 ) = casti_m128i( d,15 ) = _mm_shuffle_epi32( s1 , 0xff ); casti_m128i( d,16 ) = casti_m128i( d,17 ) = _mm_shuffle_epi32( s2 , 0x00 ); casti_m128i( d,18 ) = casti_m128i( d,19 ) = _mm_shuffle_epi32( s2 , 0x55 ); casti_m128i( d,20 ) = casti_m128i( d,21 ) = _mm_shuffle_epi32( s2 , 0xaa ); casti_m128i( d,22 ) = casti_m128i( d,23 ) = _mm_shuffle_epi32( s2 , 0xff ); casti_m128i( d,24 ) = casti_m128i( d,25 ) = _mm_shuffle_epi32( s3 , 0x00 ); casti_m128i( d,26 ) = casti_m128i( d,27 ) = _mm_shuffle_epi32( s3 , 0x55 ); casti_m128i( d,28 ) = casti_m128i( d,29 ) = _mm_shuffle_epi32( s3 , 0xaa ); casti_m128i( d,30 ) = casti_m128i( d,31 ) = _mm_shuffle_epi32( s3 , 0xff ); casti_m128i( d,32 ) = casti_m128i( d,33 ) = _mm_shuffle_epi32( s4 , 0x00 ); casti_m128i( d,34 ) = casti_m128i( d,35 ) = _mm_shuffle_epi32( s4 , 0x55 ); casti_m128i( d,36 ) = casti_m128i( d,37 ) = _mm_shuffle_epi32( s4 , 0xaa ); casti_m128i( d,38 ) = casti_m128i( d,39 ) = _mm_shuffle_epi32( s4 , 0xff ); } */ #endif // AVX2 // 16x32 /* static inline void intrlv_16x32( void *dst, const void *src00, const void *src01, const void *src02, const void *src03, const void *src04, const void *src05, const void *src06, const void *src07, const void *src08, const void *src09, const void *src10, const void *src11, const void *src12, const void *src13, const void *src14, const void *src15, const int bit_len ) { __m128i *d = (__m128i*)dst; const __m128i *s00 = (const __m128i*)src00; const __m128i *s01 = (const __m128i*)src01; const __m128i *s02 = (const __m128i*)src02; const __m128i *s03 = (const __m128i*)src03; const __m128i *s04 = (const __m128i*)src04; const __m128i *s05 = (const __m128i*)src05; const __m128i *s06 = (const __m128i*)src06; const __m128i *s07 = (const __m128i*)src07; const __m128i *s08 = (const __m128i*)src08; const __m128i *s09 = (const __m128i*)src09; const __m128i *s10 = (const __m128i*)src10; const __m128i *s11 = (const __m128i*)src11; const __m128i *s12 = (const __m128i*)src12; const __m128i *s13 = (const __m128i*)src13; const __m128i *s14 = (const __m128i*)src14; const __m128i *s15 = (const __m128i*)src15; MM128_ILEAVE32( d[ 0], d[ 4], d[ 8], d[12], s00[0], s01[0], s02[0], s03[0] ); MM128_ILEAVE32( d[ 1], d[ 5], d[ 9], d[13], s04[0], s05[0], s06[0], s07[0] ); MM128_ILEAVE32( d[ 2], d[ 6], d[10], d[14], s08[0], s09[0], s10[0], s11[0] ); MM128_ILEAVE32( d[ 3], d[ 7], d[11], d[15], s12[0], s13[0], s14[0], s15[0] ); MM128_ILEAVE32( d[16], d[20], d[24], d[28], s00[1], s01[1], s02[1], s03[1] ); MM128_ILEAVE32( d[17], d[21], d[25], d[29], s04[1], s05[1], s06[1], s07[1] ); MM128_ILEAVE32( d[18], d[22], d[26], d[30], s08[1], s09[1], s10[1], s11[1] ); MM128_ILEAVE32( d[19], d[23], d[27], d[31], s12[1], s13[1], s14[1], s15[1] ); if ( bit_len <= 256 ) return; MM128_ILEAVE32( d[32], d[36], d[40], d[44], s00[2], s01[2], s02[2], s03[2] ); MM128_ILEAVE32( d[33], d[37], d[41], d[45], s04[2], s05[2], s06[2], s07[2] ); MM128_ILEAVE32( d[34], d[38], d[42], d[46], s08[2], s09[2], s10[2], s11[2] ); MM128_ILEAVE32( d[35], d[39], d[43], d[47], s12[2], s13[2], s14[2], s15[2] ); MM128_ILEAVE32( d[48], d[52], d[56], d[60], s00[3], s01[3], s02[3], s03[3] ); MM128_ILEAVE32( d[49], d[53], d[57], d[61], s04[3], s05[3], s06[3], s07[3] ); MM128_ILEAVE32( d[50], d[54], d[58], d[62], s08[3], s09[3], s10[3], s11[3] ); MM128_ILEAVE32( d[51], d[55], d[59], d[63], s12[3], s13[3], s14[3], s15[3] ); if ( bit_len <= 512 ) return; MM128_ILEAVE32( d[64], d[68], d[72], d[76], s00[4], s01[4], s02[4], s03[4] ); MM128_ILEAVE32( d[65], d[69], d[73], d[77], s04[4], s05[4], s06[4], s07[4] ); MM128_ILEAVE32( d[66], d[70], d[74], d[78], s08[4], s09[4], s10[4], s11[4] ); MM128_ILEAVE32( d[67], d[71], d[75], d[79], s12[4], s13[4], s14[4], s15[4] ); if ( bit_len <= 640 ) return; MM128_ILEAVE32( d[80], d[84], d[88], d[92], s00[5], s01[5], s02[5], s03[5] ); MM128_ILEAVE32( d[81], d[85], d[89], d[93], s04[5], s05[5], s06[5], s07[5] ); MM128_ILEAVE32( d[82], d[86], d[90], d[94], s08[5], s09[5], s10[5], s11[5] ); MM128_ILEAVE32( d[83], d[87], d[91], d[95], s12[5], s13[5], s14[5], s15[5] ); MM128_ILEAVE32( d[ 96], d[100], d[104], d[108], s00[6], s01[6], s02[6], s03[6] ); MM128_ILEAVE32( d[ 97], d[101], d[105], d[109], s04[6], s05[6], s06[6], s07[6] ); MM128_ILEAVE32( d[ 98], d[102], d[106], d[110], s08[6], s09[6], s10[6], s11[6] ); MM128_ILEAVE32( d[ 99], d[103], d[107], d[111], s12[6], s13[6], s14[6], s15[6] ); MM128_ILEAVE32( d[112], d[116], d[120], d[124], s00[7], s01[7], s02[7], s03[7] ); MM128_ILEAVE32( d[113], d[117], d[121], d[125], s04[7], s05[7], s06[7], s07[7] ); MM128_ILEAVE32( d[114], d[118], d[122], d[126], s08[7], s09[7], s10[7], s11[7] ); MM128_ILEAVE32( d[115], d[119], d[123], d[127], s12[7], s13[7], s14[7], s15[7] ); } // Not used, only potential use is with AVX512 #if defined(__AVX2__) static inline void intrlv_16x32_256( void *dst, const void *src00, const void *src01, const void *src02, const void *src03, const void *src04, const void *src05, const void *src06, const void *src07, const void *src08, const void *src09, const void *src10, const void *src11, const void *src12, const void *src13, const void *src14, const void *src15 ) { __m256i *d = (__m256i*)dst; const __m256i *s00 = (const __m256i*)src00; const __m256i *s01 = (const __m256i*)src01; const __m256i *s02 = (const __m256i*)src02; const __m256i *s03 = (const __m256i*)src03; const __m256i *s04 = (const __m256i*)src04; const __m256i *s05 = (const __m256i*)src05; const __m256i *s06 = (const __m256i*)src06; const __m256i *s07 = (const __m256i*)src07; const __m256i *s08 = (const __m256i*)src08; const __m256i *s09 = (const __m256i*)src09; const __m256i *s10 = (const __m256i*)src10; const __m256i *s11 = (const __m256i*)src11; const __m256i *s12 = (const __m256i*)src12; const __m256i *s13 = (const __m256i*)src13; const __m256i *s14 = (const __m256i*)src14; const __m256i *s15 = (const __m256i*)src15; __m256i dt0, dt1, dt2, dt3, dt4, dt5, dt6, dt7; MM256_ILEAVE32( dt0, dt1, dt2, dt3, s00[0], s01[0], s02[0], s03[0] ); MM256_ILEAVE32( dt4, dt5, dt6, dt7, s04[0], s05[0], s06[0], s07[0] ); d[ 0] = _mm256_permute2x128_si256( dt0, dt4, 0x20 ); d[ 8] = _mm256_permute2x128_si256( dt0, dt4, 0x31 ); d[ 2] = _mm256_permute2x128_si256( dt1, dt5, 0x20 ); d[10] = _mm256_permute2x128_si256( dt1, dt5, 0x31 ); d[ 4] = _mm256_permute2x128_si256( dt2, dt6, 0x20 ); d[12] = _mm256_permute2x128_si256( dt2, dt6, 0x31 ); d[ 6] = _mm256_permute2x128_si256( dt3, dt7, 0x20 ); d[14] = _mm256_permute2x128_si256( dt3, dt7, 0x31 ); MM256_ILEAVE32( dt0, dt1, dt1, dt3, s08[0], s09[0], s10[0], s11[0] ); MM256_ILEAVE32( dt4, dt5, dt6, dt7, s12[0], s13[0], s14[0], s15[0] ); d[ 1] = _mm256_permute2x128_si256( dt0, dt4, 0x20 ); d[ 9] = _mm256_permute2x128_si256( dt0, dt4, 0x31 ); d[ 3] = _mm256_permute2x128_si256( dt1, dt5, 0x20 ); d[11] = _mm256_permute2x128_si256( dt1, dt5, 0x31 ); d[ 5] = _mm256_permute2x128_si256( dt2, dt6, 0x20 ); d[13] = _mm256_permute2x128_si256( dt2, dt6, 0x31 ); d[ 7] = _mm256_permute2x128_si256( dt3, dt7, 0x20 ); d[15] = _mm256_permute2x128_si256( dt3, dt7, 0x31 ); } #endif // Not used static inline void intrlv_16x32_512( void *dst, const void *src00, const void *src01, const void *src02, const void *src03, const void *src04, const void *src05, const void *src06, const void *src07, const void *src08, const void *src09, const void *src10, const void *src11, const void *src12, const void *src13, const void *src14, const void *src15 ) { #if defined(__AVX512F__) __m512i *d = (__m512i*)dst; const __m512i *s00 = (const __m512i*)src00; const __m512i *s01 = (const __m512i*)src01; const __m512i *s02 = (const __m512i*)src02; const __m512i *s03 = (const __m512i*)src03; const __m512i *s04 = (const __m512i*)src04; const __m512i *s05 = (const __m512i*)src05; const __m512i *s06 = (const __m512i*)src06; const __m512i *s07 = (const __m512i*)src07; const __m512i *s08 = (const __m512i*)src08; const __m512i *s09 = (const __m512i*)src09; const __m512i *s10 = (const __m512i*)src10; const __m512i *s11 = (const __m512i*)src11; const __m512i *s12 = (const __m512i*)src12; const __m512i *s13 = (const __m512i*)src13; const __m512i *s14 = (const __m512i*)src14; const __m512i *s15 = (const __m512i*)src15; __m512i st00, st01, st02, st03, st04, st05, st06, st07, st08, st09, st10, st11, st12, st13, st14, st15, t0, t1, t2, t3; MM512_ILEAVE32( st00, st01, st02, st03, s00[0], s01[0], s02[0], s03[0] ); MM512_ILEAVE32( st04, st05, st06, st07, s04[0], s05[0], s06[0], s07[0] ); MM512_ILEAVE32( st08, st09, st10, st11, s08[0], s09[0], s10[0], s11[0] ); MM512_ILEAVE32( st12, st13, st14, st15, s12[0], s13[0], s14[0], s15[0] ); t0 = _mm512_shuffle_i32x4( st00, st04, 0x88 ); t1 = _mm512_shuffle_i32x4( st00, st04, 0xdd ); t2 = _mm512_shuffle_i32x4( st08, st12, 0x88 ); t3 = _mm512_shuffle_i32x4( st08, st12, 0xdd ); d[ 0] = _mm512_shuffle_i32x4( t0, t2, 0x88 ); d[ 8] = _mm512_shuffle_i32x4( t0, t2, 0xdd ); d[ 4] = _mm512_shuffle_i32x4( t1, t3, 0x88 ); d[12] = _mm512_shuffle_i32x4( t1, t3, 0xdd ); t0 = _mm512_shuffle_i32x4( st01, st05, 0x88 ); t1 = _mm512_shuffle_i32x4( st01, st05, 0xdd ); t2 = _mm512_shuffle_i32x4( st09, st13, 0x88 ); t3 = _mm512_shuffle_i32x4( st09, st13, 0xdd ); d[ 1] = _mm512_shuffle_i32x4( t0, t2, 0x88 ); d[ 9] = _mm512_shuffle_i32x4( t0, t2, 0xdd ); d[ 5] = _mm512_shuffle_i32x4( t1, t3, 0x88 ); d[13] = _mm512_shuffle_i32x4( t1, t3, 0xdd ); t0 = _mm512_shuffle_i32x4( st02, st06, 0x88 ); t1 = _mm512_shuffle_i32x4( st02, st06, 0xdd ); t2 = _mm512_shuffle_i32x4( st10, st14, 0x88 ); t3 = _mm512_shuffle_i32x4( st10, st14, 0xdd ); d[ 2] = _mm512_shuffle_i32x4( t0, t2, 0x88 ); d[10] = _mm512_shuffle_i32x4( t0, t2, 0xdd ); d[ 6] = _mm512_shuffle_i32x4( t1, t3, 0x88 ); d[14] = _mm512_shuffle_i32x4( t1, t3, 0xdd ); t0 = _mm512_shuffle_i32x4( st03, st07, 0x88 ); t1 = _mm512_shuffle_i32x4( st03, st07, 0xdd ); t2 = _mm512_shuffle_i32x4( st11, st15, 0x88 ); t3 = _mm512_shuffle_i32x4( st11, st15, 0xdd ); d[ 3] = _mm512_shuffle_i32x4( t0, t2, 0x88 ); d[11] = _mm512_shuffle_i32x4( t0, t2, 0xdd ); d[ 7] = _mm512_shuffle_i32x4( t1, t3, 0x88 ); d[15] = _mm512_shuffle_i32x4( t1, t3, 0xdd ); #endif } */ #define ILEAVE_16x32( i ) do \ { \ uint32_t *d = (uint32_t*)(dst) + ( (i) << 4 ); \ d[ 0] = *( (const uint32_t*)(s00) +(i) ); \ d[ 1] = *( (const uint32_t*)(s01) +(i) ); \ d[ 2] = *( (const uint32_t*)(s02) +(i) ); \ d[ 3] = *( (const uint32_t*)(s03) +(i) ); \ d[ 4] = *( (const uint32_t*)(s04) +(i) ); \ d[ 5] = *( (const uint32_t*)(s05) +(i) ); \ d[ 6] = *( (const uint32_t*)(s06) +(i) ); \ d[ 7] = *( (const uint32_t*)(s07) +(i) ); \ d[ 8] = *( (const uint32_t*)(s08) +(i) ); \ d[ 9] = *( (const uint32_t*)(s09) +(i) ); \ d[10] = *( (const uint32_t*)(s10) +(i) ); \ d[11] = *( (const uint32_t*)(s11) +(i) ); \ d[12] = *( (const uint32_t*)(s12) +(i) ); \ d[13] = *( (const uint32_t*)(s13) +(i) ); \ d[14] = *( (const uint32_t*)(s14) +(i) ); \ d[15] = *( (const uint32_t*)(s15) +(i) ); \ } while(0) static inline void intrlv_16x32( void *dst, const void *s00, const void *s01, const void *s02, const void *s03, const void *s04, const void *s05, const void *s06, const void *s07, const void *s08, const void *s09, const void *s10, const void *s11, const void *s12, const void *s13, const void *s14, const void *s15, const int bit_len ) { ILEAVE_16x32( 0 ); ILEAVE_16x32( 1 ); ILEAVE_16x32( 2 ); ILEAVE_16x32( 3 ); ILEAVE_16x32( 4 ); ILEAVE_16x32( 5 ); ILEAVE_16x32( 6 ); ILEAVE_16x32( 7 ); if ( bit_len <= 256 ) return; ILEAVE_16x32( 8 ); ILEAVE_16x32( 9 ); ILEAVE_16x32( 10 ); ILEAVE_16x32( 11 ); ILEAVE_16x32( 12 ); ILEAVE_16x32( 13 ); ILEAVE_16x32( 14 ); ILEAVE_16x32( 15 ); if ( bit_len <= 512 ) return; ILEAVE_16x32( 16 ); ILEAVE_16x32( 17 ); ILEAVE_16x32( 18 ); ILEAVE_16x32( 19 ); if ( bit_len <= 640 ) return; ILEAVE_16x32( 20 ); ILEAVE_16x32( 21 ); ILEAVE_16x32( 22 ); ILEAVE_16x32( 23 ); ILEAVE_16x32( 24 ); ILEAVE_16x32( 25 ); ILEAVE_16x32( 26 ); ILEAVE_16x32( 27 ); ILEAVE_16x32( 28 ); ILEAVE_16x32( 29 ); ILEAVE_16x32( 30 ); ILEAVE_16x32( 31 ); } static inline void intrlv_16x32_512( void *dst, const void *s00, const void *s01, const void *s02, const void *s03, const void *s04, const void *s05, const void *s06, const void *s07, const void *s08, const void *s09, const void *s10, const void *s11, const void *s12, const void *s13, const void *s14, const void *s15 ) { ILEAVE_16x32( 0 ); ILEAVE_16x32( 1 ); ILEAVE_16x32( 2 ); ILEAVE_16x32( 3 ); ILEAVE_16x32( 4 ); ILEAVE_16x32( 5 ); ILEAVE_16x32( 6 ); ILEAVE_16x32( 7 ); ILEAVE_16x32( 8 ); ILEAVE_16x32( 9 ); ILEAVE_16x32( 10 ); ILEAVE_16x32( 11 ); ILEAVE_16x32( 12 ); ILEAVE_16x32( 13 ); ILEAVE_16x32( 14 ); ILEAVE_16x32( 15 ); } #undef ILEAVE_16x32 /* static inline void dintrlv_16x32( void *dst00, void *dst01, void *dst02, void *dst03, void *dst04, void *dst05, void *dst06, void *dst07, void *dst08, void *dst09, void *dst10, void *dst11, void *dst12, void *dst13, void *dst14, void *dst15, const void *src, const int bit_len ) { __m128i *d00 = (__m128i*)dst00; __m128i *d01 = (__m128i*)dst01; __m128i *d02 = (__m128i*)dst02; __m128i *d03 = (__m128i*)dst03; __m128i *d04 = (__m128i*)dst04; __m128i *d05 = (__m128i*)dst05; __m128i *d06 = (__m128i*)dst06; __m128i *d07 = (__m128i*)dst07; __m128i *d08 = (__m128i*)dst08; __m128i *d09 = (__m128i*)dst09; __m128i *d10 = (__m128i*)dst10; __m128i *d11 = (__m128i*)dst11; __m128i *d12 = (__m128i*)dst12; __m128i *d13 = (__m128i*)dst13; __m128i *d14 = (__m128i*)dst14; __m128i *d15 = (__m128i*)dst15; const __m128i *s = (const __m128i*)src; MM128_ILEAVE32( d00[0], d01[0], d02[0], d03[0], s[ 0], s[ 4], s[ 8], s[12] ); MM128_ILEAVE32( d04[0], d05[0], d06[0], d07[0], s[ 1], s[ 5], s[ 9], s[13] ); MM128_ILEAVE32( d08[0], d09[0], d10[0], d11[0], s[ 2], s[ 6], s[10], s[14] ); MM128_ILEAVE32( d12[0], d13[0], d14[0], d15[0], s[ 3], s[ 7], s[11], s[15] ); MM128_ILEAVE32( d00[1], d01[1], d02[1], d03[1], s[16], s[20], s[24], s[28] ); MM128_ILEAVE32( d04[1], d05[1], d06[1], d07[1], s[17], s[21], s[25], s[29] ); MM128_ILEAVE32( d08[1], d09[1], d10[1], d11[1], s[18], s[22], s[26], s[30] ); MM128_ILEAVE32( d12[1], d13[1], d14[1], d15[1], s[19], s[23], s[27], s[31] ); if ( bit_len <= 256 ) return; MM128_ILEAVE32( d00[2], d01[2], d02[2], d03[2], s[32], s[36], s[40], s[44] ); MM128_ILEAVE32( d04[2], d05[2], d06[2], d07[2], s[33], s[37], s[41], s[45] ); MM128_ILEAVE32( d08[2], d09[2], d10[2], d11[2], s[34], s[38], s[42], s[46] ); MM128_ILEAVE32( d12[2], d13[2], d14[2], d15[2], s[35], s[39], s[43], s[47] ); MM128_ILEAVE32( d00[3], d01[3], d02[3], d03[3], s[48], s[52], s[56], s[60] ); MM128_ILEAVE32( d04[3], d05[3], d06[3], d07[3], s[49], s[53], s[57], s[61] ); MM128_ILEAVE32( d08[3], d09[3], d10[3], d11[3], s[50], s[54], s[58], s[62] ); MM128_ILEAVE32( d12[3], d13[3], d14[3], d15[3], s[51], s[55], s[59], s[63] ); if ( bit_len <= 512 ) return; MM128_ILEAVE32( d00[4], d01[4], d02[4], d03[4], s[64], s[68], s[72], s[76] ); MM128_ILEAVE32( d04[4], d05[4], d06[4], d07[4], s[65], s[69], s[73], s[77] ); MM128_ILEAVE32( d08[4], d09[4], d10[4], d11[4], s[66], s[70], s[74], s[78] ); MM128_ILEAVE32( d12[4], d13[4], d14[4], d15[4], s[67], s[71], s[75], s[79] ); if ( bit_len <= 640 ) return; MM128_ILEAVE32( d00[5], d01[5], d02[5], d03[5], s[80], s[84], s[88], s[92] ); MM128_ILEAVE32( d04[5], d05[5], d06[5], d07[5], s[81], s[85], s[89], s[93] ); MM128_ILEAVE32( d08[5], d09[5], d10[5], d11[5], s[82], s[86], s[90], s[94] ); MM128_ILEAVE32( d12[5], d13[5], d14[5], d15[5], s[83], s[87], s[91], s[95] ); MM128_ILEAVE32( d00[6], d01[6], d02[6], d03[6], s[ 96], s[100], s[104], s[108] ); MM128_ILEAVE32( d04[6], d05[6], d06[6], d07[6], s[ 97], s[101], s[105], s[109] ); MM128_ILEAVE32( d08[6], d09[6], d10[6], d11[6], s[ 98], s[102], s[106], s[110] ); MM128_ILEAVE32( d12[6], d13[6], d14[6], d15[6], s[ 99], s[103], s[107], s[111] ); MM128_ILEAVE32( d00[7], d01[7], d02[7], d03[7], s[112], s[116], s[120], s[124] ); MM128_ILEAVE32( d04[7], d05[7], d06[7], d07[7], s[113], s[117], s[121], s[125] ); MM128_ILEAVE32( d08[7], d09[7], d10[7], d11[7], s[114], s[118], s[122], s[126] ); MM128_ILEAVE32( d12[7], d13[7], d14[7], d15[7], s[115], s[119], s[123], s[127] ); } // 4 interleave algorithms same memory footprint: // // 1. 32 bit integer move // // Most instructions, all 32 bit loads & stores, use general purpose regs // // 2. SSE2 128 bit shuffle // // 128 bit loads and stores + fast shuffles, fewer total instructions: .75, // uses 128 bit simd regs // // 3. AVX2 2x128 bit shuffle with 256 bit permute // // 256 bit loads and stores + slow 256 bit permutes, even fewer instructions: // additional .5, uses 256 bit simd regs // // 4. AVX2 2x128 bit shuffle with union // // 128 bit loads, 256 bit stores + 128 bit moves using union + overhead // converting from mm128 to mm256, compiler may choose mem ovly or static inline void dintrlv_16x32_256( void *dst00, void *dst01, void *dst02, void *dst03, void *dst04, void *dst05, void *dst06, void *dst07, void *dst08, void *dst09, void *dst10, void *dst11, void *dst12, void *dst13, void *dst14, void *dst15, const void *src ) { #if defined(__AVX2__) // Can't use AVX512, min bit_len is 512 unless a single contiguous // output buffer is used. const __m256i *s = (const __m256i*)src; __m256i *d00 = (__m256i*)dst00; __m256i *d01 = (__m256i*)dst01; __m256i *d02 = (__m256i*)dst02; __m256i *d03 = (__m256i*)dst03; __m256i *d04 = (__m256i*)dst04; __m256i *d05 = (__m256i*)dst05; __m256i *d06 = (__m256i*)dst06; __m256i *d07 = (__m256i*)dst07; __m256i *d08 = (__m256i*)dst08; __m256i *d09 = (__m256i*)dst09; __m256i *d10 = (__m256i*)dst10; __m256i *d11 = (__m256i*)dst11; __m256i *d12 = (__m256i*)dst12; __m256i *d13 = (__m256i*)dst13; __m256i *d14 = (__m256i*)dst14; __m256i *d15 = (__m256i*)dst15; __m256i st0, st1, st2, st3, st4, st5, st6, st7; st0 = _mm256_permute2x128_si256( s[ 0], s[ 8], 0x20 ); st4 = _mm256_permute2x128_si256( s[ 0], s[ 8], 0x31 ); st1 = _mm256_permute2x128_si256( s[ 2], s[10], 0x20 ); st5 = _mm256_permute2x128_si256( s[ 2], s[10], 0x31 ); st2 = _mm256_permute2x128_si256( s[ 4], s[12], 0x20 ); st6 = _mm256_permute2x128_si256( s[ 4], s[12], 0x31 ); st3 = _mm256_permute2x128_si256( s[ 6], s[14], 0x20 ); st7 = _mm256_permute2x128_si256( s[ 6], s[14], 0x31 ); MM256_ILEAVE32( d00[0], d01[0], d02[0], d03[0], st0, st1, st2, st3 ); MM256_ILEAVE32( d04[0], d05[0], d06[0], d07[0], st4, st5, st6, st7 ); st0 = _mm256_permute2x128_si256( s[ 1], s[ 9], 0x20 ); st4 = _mm256_permute2x128_si256( s[ 1], s[ 9], 0x31 ); st1 = _mm256_permute2x128_si256( s[ 3], s[11], 0x20 ); st5 = _mm256_permute2x128_si256( s[ 3], s[11], 0x31 ); st2 = _mm256_permute2x128_si256( s[ 5], s[13], 0x20 ); st6 = _mm256_permute2x128_si256( s[ 5], s[13], 0x31 ); st3 = _mm256_permute2x128_si256( s[ 7], s[15], 0x20 ); st7 = _mm256_permute2x128_si256( s[ 7], s[15], 0x31 ); MM256_ILEAVE32( d08[0], d09[0], d10[0], d11[0], st0, st1, st2, st3 ); MM256_ILEAVE32( d12[0], d13[0], d14[0], d15[0], st4, st5, st6, st7 ); #else // not needed, 16x32 is only used with AVX512 __m128i *d00 = (__m128i*)dst00; __m128i *d01 = (__m128i*)dst01; __m128i *d02 = (__m128i*)dst02; __m128i *d03 = (__m128i*)dst03; __m128i *d04 = (__m128i*)dst04; __m128i *d05 = (__m128i*)dst05; __m128i *d06 = (__m128i*)dst06; __m128i *d07 = (__m128i*)dst07; __m128i *d08 = (__m128i*)dst08; __m128i *d09 = (__m128i*)dst09; __m128i *d10 = (__m128i*)dst10; __m128i *d11 = (__m128i*)dst11; __m128i *d12 = (__m128i*)dst12; __m128i *d13 = (__m128i*)dst13; __m128i *d14 = (__m128i*)dst14; __m128i *d15 = (__m128i*)dst15; const __m128i *s = (const __m128i*)src; MM128_ILEAVE32( d00[0], d01[0], d02[0], d03[0], s[ 0], s[ 4], s[ 8], s[12] ); MM128_ILEAVE32( d04[0], d05[0], d06[0], d07[0], s[ 1], s[ 5], s[ 9], s[13] ); MM128_ILEAVE32( d08[0], d09[0], d10[0], d11[0], s[ 2], s[ 6], s[10], s[14] ); MM128_ILEAVE32( d12[0], d13[0], d14[0], d15[0], s[ 3], s[ 7], s[11], s[15] ); MM128_ILEAVE32( d00[1], d01[1], d02[1], d03[1], s[16], s[20], s[24], s[28] ); MM128_ILEAVE32( d04[1], d05[1], d06[1], d07[1], s[17], s[21], s[25], s[29] ); MM128_ILEAVE32( d08[1], d09[1], d10[1], d11[1], s[18], s[22], s[26], s[30] ); MM128_ILEAVE32( d12[1], d13[1], d14[1], d15[1], s[19], s[23], s[27], s[31] ); #endif } */ #define DLEAVE_16x32( i ) do \ { \ const uint32_t *s = (const uint32_t*)(src) + ( (i) << 4 ); \ *( (uint32_t*)(d00) +(i) ) = s[ 0]; \ *( (uint32_t*)(d01) +(i) ) = s[ 1]; \ *( (uint32_t*)(d02) +(i) ) = s[ 2]; \ *( (uint32_t*)(d03) +(i) ) = s[ 3]; \ *( (uint32_t*)(d04) +(i) ) = s[ 4]; \ *( (uint32_t*)(d05) +(i) ) = s[ 5]; \ *( (uint32_t*)(d06) +(i) ) = s[ 6]; \ *( (uint32_t*)(d07) +(i) ) = s[ 7]; \ *( (uint32_t*)(d08) +(i) ) = s[ 8]; \ *( (uint32_t*)(d09) +(i) ) = s[ 9]; \ *( (uint32_t*)(d10) +(i) ) = s[10]; \ *( (uint32_t*)(d11) +(i) ) = s[11]; \ *( (uint32_t*)(d12) +(i) ) = s[12]; \ *( (uint32_t*)(d13) +(i) ) = s[13]; \ *( (uint32_t*)(d14) +(i) ) = s[14]; \ *( (uint32_t*)(d15) +(i) ) = s[15]; \ } while(0) static inline void dintrlv_16x32( void *d00, void *d01, void *d02, void *d03, void *d04, void *d05, void *d06, void *d07, void *d08, void *d09, void *d10, void *d11, void *d12, void *d13, void *d14, void *d15, const void *src, const int bit_len ) { DLEAVE_16x32( 0 ); DLEAVE_16x32( 1 ); DLEAVE_16x32( 2 ); DLEAVE_16x32( 3 ); DLEAVE_16x32( 4 ); DLEAVE_16x32( 5 ); DLEAVE_16x32( 6 ); DLEAVE_16x32( 7 ); if ( bit_len <= 256 ) return; DLEAVE_16x32( 8 ); DLEAVE_16x32( 9 ); DLEAVE_16x32( 10 ); DLEAVE_16x32( 11 ); DLEAVE_16x32( 12 ); DLEAVE_16x32( 13 ); DLEAVE_16x32( 14 ); DLEAVE_16x32( 15 ); if ( bit_len <= 512 ) return; DLEAVE_16x32( 16 ); DLEAVE_16x32( 17 ); DLEAVE_16x32( 18 ); DLEAVE_16x32( 19 ); if ( bit_len <= 640 ) return; DLEAVE_16x32( 20 ); DLEAVE_16x32( 21 ); DLEAVE_16x32( 22 ); DLEAVE_16x32( 23 ); DLEAVE_16x32( 24 ); DLEAVE_16x32( 25 ); DLEAVE_16x32( 26 ); DLEAVE_16x32( 27 ); DLEAVE_16x32( 28 ); DLEAVE_16x32( 29 ); DLEAVE_16x32( 30 ); DLEAVE_16x32( 31 ); } static inline void dintrlv_16x32_512( void *d00, void *d01, void *d02, void *d03, void *d04, void *d05, void *d06, void *d07, void *d08, void *d09, void *d10, void *d11, void *d12, void *d13, void *d14, void *d15, const void *src ) { DLEAVE_16x32( 0 ); DLEAVE_16x32( 1 ); DLEAVE_16x32( 2 ); DLEAVE_16x32( 3 ); DLEAVE_16x32( 4 ); DLEAVE_16x32( 5 ); DLEAVE_16x32( 6 ); DLEAVE_16x32( 7 ); DLEAVE_16x32( 8 ); DLEAVE_16x32( 9 ); DLEAVE_16x32( 10 ); DLEAVE_16x32( 11 ); DLEAVE_16x32( 12 ); DLEAVE_16x32( 13 ); DLEAVE_16x32( 14 ); DLEAVE_16x32( 15 ); } #undef DLEAVE_16x32 static inline void extr_lane_16x32( void *d, const void *s, const int lane, const int bit_len ) { ((uint32_t*)d)[ 0] = ((const uint32_t*)s)[ lane ]; ((uint32_t*)d)[ 1] = ((const uint32_t*)s)[ lane+16 ]; ((uint32_t*)d)[ 2] = ((const uint32_t*)s)[ lane+32 ]; ((uint32_t*)d)[ 3] = ((const uint32_t*)s)[ lane+48 ]; ((uint32_t*)d)[ 4] = ((const uint32_t*)s)[ lane+64 ]; ((uint32_t*)d)[ 5] = ((const uint32_t*)s)[ lane+80 ]; ((uint32_t*)d)[ 6] = ((const uint32_t*)s)[ lane+96 ]; ((uint32_t*)d)[ 7] = ((const uint32_t*)s)[ lane+112 ]; if ( bit_len <= 256 ) return; ((uint32_t*)d)[ 8] = ((const uint32_t*)s)[ lane+128 ]; ((uint32_t*)d)[ 9] = ((const uint32_t*)s)[ lane+144 ]; ((uint32_t*)d)[10] = ((const uint32_t*)s)[ lane+160 ]; ((uint32_t*)d)[11] = ((const uint32_t*)s)[ lane+176 ]; ((uint32_t*)d)[12] = ((const uint32_t*)s)[ lane+192 ]; ((uint32_t*)d)[13] = ((const uint32_t*)s)[ lane+208 ]; ((uint32_t*)d)[14] = ((const uint32_t*)s)[ lane+224 ]; ((uint32_t*)d)[15] = ((const uint32_t*)s)[ lane+240 ]; } #if defined(__AVX512F__) && defined(__AVX512VL__) static inline void mm512_bswap32_intrlv80_16x32( void *d, const void *src ) { uint32_t *s = (uint32_t*)src; casti_m512i( d, 0 ) = _mm512_set1_epi32( bswap_32( s[ 0] ) ); casti_m512i( d, 1 ) = _mm512_set1_epi32( bswap_32( s[ 1] ) ); casti_m512i( d, 2 ) = _mm512_set1_epi32( bswap_32( s[ 2] ) ); casti_m512i( d, 3 ) = _mm512_set1_epi32( bswap_32( s[ 3] ) ); casti_m512i( d, 4 ) = _mm512_set1_epi32( bswap_32( s[ 4] ) ); casti_m512i( d, 5 ) = _mm512_set1_epi32( bswap_32( s[ 5] ) ); casti_m512i( d, 6 ) = _mm512_set1_epi32( bswap_32( s[ 6] ) ); casti_m512i( d, 7 ) = _mm512_set1_epi32( bswap_32( s[ 7] ) ); casti_m512i( d, 8 ) = _mm512_set1_epi32( bswap_32( s[ 8] ) ); casti_m512i( d, 9 ) = _mm512_set1_epi32( bswap_32( s[ 9] ) ); casti_m512i( d,10 ) = _mm512_set1_epi32( bswap_32( s[10] ) ); casti_m512i( d,11 ) = _mm512_set1_epi32( bswap_32( s[11] ) ); casti_m512i( d,12 ) = _mm512_set1_epi32( bswap_32( s[12] ) ); casti_m512i( d,13 ) = _mm512_set1_epi32( bswap_32( s[13] ) ); casti_m512i( d,14 ) = _mm512_set1_epi32( bswap_32( s[14] ) ); casti_m512i( d,15 ) = _mm512_set1_epi32( bswap_32( s[15] ) ); casti_m512i( d,16 ) = _mm512_set1_epi32( bswap_32( s[16] ) ); casti_m512i( d,17 ) = _mm512_set1_epi32( bswap_32( s[17] ) ); casti_m512i( d,18 ) = _mm512_set1_epi32( bswap_32( s[18] ) ); casti_m512i( d,19 ) = _mm512_set1_epi32( bswap_32( s[19] ) ); } /* static inline void mm512_bswap32_intrlv80_16x32( void *d, const void *src ) { __m128i bswap_shuf = m128_const_64( 0x0c0d0e0f08090a0b, 0x0405060700010203 ); __m128i s0 = casti_m128i( src,0 ); __m128i s1 = casti_m128i( src,1 ); __m128i s2 = casti_m128i( src,2 ); __m128i s3 = casti_m128i( src,3 ); __m128i s4 = casti_m128i( src,4 ); s0 = _mm_shuffle_epi8( s0, bswap_shuf ); s1 = _mm_shuffle_epi8( s1, bswap_shuf ); s2 = _mm_shuffle_epi8( s2, bswap_shuf ); s3 = _mm_shuffle_epi8( s3, bswap_shuf ); s4 = _mm_shuffle_epi8( s4, bswap_shuf ); casti_m128i( d, 0 ) = casti_m128i( d, 1 ) = casti_m128i( d, 2 ) = casti_m128i( d, 3 ) = _mm_shuffle_epi32( s0 , 0x00 ); casti_m128i( d, 4 ) = casti_m128i( d, 5 ) = casti_m128i( d, 6 ) = casti_m128i( d, 7 ) = _mm_shuffle_epi32( s0 , 0x55 ); casti_m128i( d, 8 ) = casti_m128i( d, 9 ) = casti_m128i( d,10 ) = casti_m128i( d,11 ) = _mm_shuffle_epi32( s0 , 0xaa ); casti_m128i( d,12 ) = casti_m128i( d,13 ) = casti_m128i( d,14 ) = casti_m128i( d,15 ) = _mm_shuffle_epi32( s0 , 0xff ); casti_m128i( d,16 ) = casti_m128i( d,17 ) = casti_m128i( d,18 ) = casti_m128i( d,19 ) = _mm_shuffle_epi32( s1 , 0x00 ); casti_m128i( d,20 ) = casti_m128i( d,21 ) = casti_m128i( d,22 ) = casti_m128i( d,23 ) = _mm_shuffle_epi32( s1 , 0x55 ); casti_m128i( d,24 ) = casti_m128i( d,25 ) = casti_m128i( d,26 ) = casti_m128i( d,27 ) = _mm_shuffle_epi32( s1 , 0xaa ); casti_m128i( d,28 ) = casti_m128i( d,29 ) = casti_m128i( d,30 ) = casti_m128i( d,31 ) = _mm_shuffle_epi32( s1 , 0xff ); casti_m128i( d,32 ) = casti_m128i( d,33 ) = casti_m128i( d,34 ) = casti_m128i( d,35 ) = _mm_shuffle_epi32( s2 , 0x00 ); casti_m128i( d,36 ) = casti_m128i( d,37 ) = casti_m128i( d,38 ) = casti_m128i( d,39 ) = _mm_shuffle_epi32( s2 , 0x55 ); casti_m128i( d,40 ) = casti_m128i( d,41 ) = casti_m128i( d,42 ) = casti_m128i( d,43 ) = _mm_shuffle_epi32( s2 , 0xaa ); casti_m128i( d,44 ) = casti_m128i( d,45 ) = casti_m128i( d,46 ) = casti_m128i( d,47 ) = _mm_shuffle_epi32( s2 , 0xff ); casti_m128i( d,48 ) = casti_m128i( d,49 ) = casti_m128i( d,50 ) = casti_m128i( d,51 ) = _mm_shuffle_epi32( s3 , 0x00 ); casti_m128i( d,52 ) = casti_m128i( d,53 ) = casti_m128i( d,54 ) = casti_m128i( d,55 ) = _mm_shuffle_epi32( s3 , 0x55 ); casti_m128i( d,56 ) = casti_m128i( d,57 ) = casti_m128i( d,58 ) = casti_m128i( d,59 ) = _mm_shuffle_epi32( s3 , 0xaa ); casti_m128i( d,60 ) = casti_m128i( d,61 ) = casti_m128i( d,62 ) = casti_m128i( d,63 ) = _mm_shuffle_epi32( s3 , 0xff ); casti_m128i( d,64 ) = casti_m128i( d,65 ) = casti_m128i( d,66 ) = casti_m128i( d,67 ) = _mm_shuffle_epi32( s4 , 0x00 ); casti_m128i( d,68 ) = casti_m128i( d,69 ) = casti_m128i( d,70 ) = casti_m128i( d,71 ) = _mm_shuffle_epi32( s4 , 0x55 ); casti_m128i( d,72 ) = casti_m128i( d,73 ) = casti_m128i( d,74 ) = casti_m128i( d,75 ) = _mm_shuffle_epi32( s4 , 0xaa ); casti_m128i( d,76 ) = casti_m128i( d,77 ) = casti_m128i( d,78 ) = casti_m128i( d,79 ) = _mm_shuffle_epi32( s4 , 0xff ); } */ #endif // AVX512 /////////////////////////// // // 64 bit data // 2x64 (SSE2) static inline void intrlv_2x64( void *dst, const void *src0, const void *src1, const int bit_len ) { uint64_t *d = (uint64_t*)dst;; const uint64_t *s0 = (const uint64_t*)src0; const uint64_t *s1 = (const uint64_t*)src1; d[ 0] = s0[ 0]; d[ 1] = s1[ 0]; d[ 2] = s0[ 1]; d[ 3] = s1[ 1]; d[ 4] = s0[ 2]; d[ 5] = s1[ 2]; d[ 6] = s0[ 3]; d[ 7] = s1[ 3]; if ( bit_len <= 256 ) return; d[ 8] = s0[ 4]; d[ 9] = s1[ 4]; d[10] = s0[ 5]; d[11] = s1[ 5]; d[12] = s0[ 6]; d[13] = s1[ 6]; d[14] = s0[ 7]; d[15] = s1[ 7]; if ( bit_len <= 512 ) return; d[16] = s0[ 8]; d[17] = s1[ 8]; d[18] = s0[ 9]; d[19] = s1[ 9]; if ( bit_len <= 640 ) return; d[20] = s0[10]; d[21] = s1[10]; d[22] = s0[11]; d[23] = s1[11]; d[24] = s0[12]; d[25] = s1[12]; d[26] = s0[13]; d[27] = s1[13]; d[28] = s0[14]; d[29] = s1[14]; d[30] = s0[15]; d[31] = s1[15]; } static inline void dintrlv_2x64( void *dst0, void *dst1, const void *src, const int bit_len ) { uint64_t *d0 = (uint64_t*)dst0; uint64_t *d1 = (uint64_t*)dst1; const uint64_t *s = (const uint64_t*)src; d0[ 0] = s[ 0]; d1[ 0] = s[ 1]; d0[ 1] = s[ 2]; d1[ 1] = s[ 3]; d0[ 2] = s[ 4]; d1[ 2] = s[ 5]; d0[ 3] = s[ 6]; d1[ 3] = s[ 7]; if ( bit_len <= 256 ) return; d0[ 4] = s[ 8]; d1[ 4] = s[ 9]; d0[ 5] = s[10]; d1[ 5] = s[11]; d0[ 6] = s[12]; d1[ 6] = s[13]; d0[ 7] = s[14]; d1[ 7] = s[15]; if ( bit_len <= 512 ) return; d0[ 8] = s[16]; d1[ 8] = s[17]; d0[ 9] = s[18]; d1[ 9] = s[19]; if ( bit_len <= 640 ) return; d0[10] = s[20]; d1[10] = s[21]; d0[11] = s[22]; d1[11] = s[23]; d0[12] = s[24]; d1[12] = s[25]; d0[13] = s[26]; d1[13] = s[27]; d0[14] = s[28]; d1[14] = s[29]; d0[15] = s[30]; d1[15] = s[31]; } // 4x64 (AVX2) static inline void intrlv_4x64( void *dst, const void *src0, const void *src1, const void *src2, const void *src3, const int bit_len ) { __m128i *d = (__m128i*)dst; const __m128i *s0 = (const __m128i*)src0; const __m128i *s1 = (const __m128i*)src1; const __m128i *s2 = (const __m128i*)src2; const __m128i *s3 = (const __m128i*)src3; d[ 0] = _mm_unpacklo_epi64( s0[0], s1[0] ); d[ 1] = _mm_unpacklo_epi64( s2[0], s3[0] ); d[ 2] = _mm_unpackhi_epi64( s0[0], s1[0] ); d[ 3] = _mm_unpackhi_epi64( s2[0], s3[0] ); d[ 4] = _mm_unpacklo_epi64( s0[1], s1[1] ); d[ 5] = _mm_unpacklo_epi64( s2[1], s3[1] ); d[ 6] = _mm_unpackhi_epi64( s0[1], s1[1] ); d[ 7] = _mm_unpackhi_epi64( s2[1], s3[1] ); if ( bit_len <= 256 ) return; d[ 8] = _mm_unpacklo_epi64( s0[2], s1[2] ); d[ 9] = _mm_unpacklo_epi64( s2[2], s3[2] ); d[10] = _mm_unpackhi_epi64( s0[2], s1[2] ); d[11] = _mm_unpackhi_epi64( s2[2], s3[2] ); d[12] = _mm_unpacklo_epi64( s0[3], s1[3] ); d[13] = _mm_unpacklo_epi64( s2[3], s3[3] ); d[14] = _mm_unpackhi_epi64( s0[3], s1[3] ); d[15] = _mm_unpackhi_epi64( s2[3], s3[3] ); if ( bit_len <= 512 ) return; d[16] = _mm_unpacklo_epi64( s0[4], s1[4] ); d[17] = _mm_unpacklo_epi64( s2[4], s3[4] ); d[18] = _mm_unpackhi_epi64( s0[4], s1[4] ); d[19] = _mm_unpackhi_epi64( s2[4], s3[4] ); if ( bit_len <= 640 ) return; d[20] = _mm_unpacklo_epi64( s0[5], s1[5] ); d[21] = _mm_unpacklo_epi64( s2[5], s3[5] ); d[22] = _mm_unpackhi_epi64( s0[5], s1[5] ); d[23] = _mm_unpackhi_epi64( s2[5], s3[5] ); d[24] = _mm_unpacklo_epi64( s0[6], s1[6] ); d[25] = _mm_unpacklo_epi64( s2[6], s3[6] ); d[26] = _mm_unpackhi_epi64( s0[6], s1[6] ); d[27] = _mm_unpackhi_epi64( s2[6], s3[6] ); d[28] = _mm_unpacklo_epi64( s0[7], s1[7] ); d[29] = _mm_unpacklo_epi64( s2[7], s3[7] ); d[30] = _mm_unpackhi_epi64( s0[7], s1[7] ); d[31] = _mm_unpackhi_epi64( s2[7], s3[7] ); } static inline void intrlv_4x64_512( void *dst, const void *src0, const void *src1, const void *src2, const void *src3 ) { __m128i *d = (__m128i*)dst; const __m128i *s0 = (const __m128i*)src0; const __m128i *s1 = (const __m128i*)src1; const __m128i *s2 = (const __m128i*)src2; const __m128i *s3 = (const __m128i*)src3; d[ 0] = _mm_unpacklo_epi64( s0[0], s1[0] ); d[ 1] = _mm_unpacklo_epi64( s2[0], s3[0] ); d[ 2] = _mm_unpackhi_epi64( s0[0], s1[0] ); d[ 3] = _mm_unpackhi_epi64( s2[0], s3[0] ); d[ 4] = _mm_unpacklo_epi64( s0[1], s1[1] ); d[ 5] = _mm_unpacklo_epi64( s2[1], s3[1] ); d[ 6] = _mm_unpackhi_epi64( s0[1], s1[1] ); d[ 7] = _mm_unpackhi_epi64( s2[1], s3[1] ); d[ 8] = _mm_unpacklo_epi64( s0[2], s1[2] ); d[ 9] = _mm_unpacklo_epi64( s2[2], s3[2] ); d[10] = _mm_unpackhi_epi64( s0[2], s1[2] ); d[11] = _mm_unpackhi_epi64( s2[2], s3[2] ); d[12] = _mm_unpacklo_epi64( s0[3], s1[3] ); d[13] = _mm_unpacklo_epi64( s2[3], s3[3] ); d[14] = _mm_unpackhi_epi64( s0[3], s1[3] ); d[15] = _mm_unpackhi_epi64( s2[3], s3[3] ); } static inline void dintrlv_4x64( void *dst0, void *dst1, void *dst2, void *dst3, const void *src, const int bit_len ) { __m128i *d0 = (__m128i*)dst0; __m128i *d1 = (__m128i*)dst1; __m128i *d2 = (__m128i*)dst2; __m128i *d3 = (__m128i*)dst3; const __m128i *s = (const __m128i*)src; d0[0] = _mm_unpacklo_epi64( s[ 0], s[ 2] ); d1[0] = _mm_unpackhi_epi64( s[ 0], s[ 2] ); d2[0] = _mm_unpacklo_epi64( s[ 1], s[ 3] ); d3[0] = _mm_unpackhi_epi64( s[ 1], s[ 3] ); d0[1] = _mm_unpacklo_epi64( s[ 4], s[ 6] ); d1[1] = _mm_unpackhi_epi64( s[ 4], s[ 6] ); d2[1] = _mm_unpacklo_epi64( s[ 5], s[ 7] ); d3[1] = _mm_unpackhi_epi64( s[ 5], s[ 7] ); if ( bit_len <= 256 ) return; d0[2] = _mm_unpacklo_epi64( s[ 8], s[10] ); d1[2] = _mm_unpackhi_epi64( s[ 8], s[10] ); d2[2] = _mm_unpacklo_epi64( s[ 9], s[11] ); d3[2] = _mm_unpackhi_epi64( s[ 9], s[11] ); d0[3] = _mm_unpacklo_epi64( s[12], s[14] ); d1[3] = _mm_unpackhi_epi64( s[12], s[14] ); d2[3] = _mm_unpacklo_epi64( s[13], s[15] ); d3[3] = _mm_unpackhi_epi64( s[13], s[15] ); if ( bit_len <= 512 ) return; d0[4] = _mm_unpacklo_epi64( s[16], s[18] ); d1[4] = _mm_unpackhi_epi64( s[16], s[18] ); d2[4] = _mm_unpacklo_epi64( s[17], s[19] ); d3[4] = _mm_unpackhi_epi64( s[17], s[19] ); if ( bit_len <= 640 ) return; d0[5] = _mm_unpacklo_epi64( s[20], s[22] ); d1[5] = _mm_unpackhi_epi64( s[20], s[22] ); d2[5] = _mm_unpacklo_epi64( s[21], s[23] ); d3[5] = _mm_unpackhi_epi64( s[21], s[23] ); d0[6] = _mm_unpacklo_epi64( s[24], s[26] ); d1[6] = _mm_unpackhi_epi64( s[24], s[26] ); d2[6] = _mm_unpacklo_epi64( s[25], s[27] ); d3[6] = _mm_unpackhi_epi64( s[25], s[27] ); d0[7] = _mm_unpacklo_epi64( s[28], s[30] ); d1[7] = _mm_unpackhi_epi64( s[28], s[30] ); d2[7] = _mm_unpacklo_epi64( s[29], s[31] ); d3[7] = _mm_unpackhi_epi64( s[29], s[31] ); } static inline void dintrlv_4x64_512( void *dst0, void *dst1, void *dst2, void *dst3, const void *src ) { __m128i *d0 = (__m128i*)dst0; __m128i *d1 = (__m128i*)dst1; __m128i *d2 = (__m128i*)dst2; __m128i *d3 = (__m128i*)dst3; const __m128i *s = (const __m128i*)src; d0[0] = _mm_unpacklo_epi64( s[ 0], s[ 2] ); d1[0] = _mm_unpackhi_epi64( s[ 0], s[ 2] ); d2[0] = _mm_unpacklo_epi64( s[ 1], s[ 3] ); d3[0] = _mm_unpackhi_epi64( s[ 1], s[ 3] ); d0[1] = _mm_unpacklo_epi64( s[ 4], s[ 6] ); d1[1] = _mm_unpackhi_epi64( s[ 4], s[ 6] ); d2[1] = _mm_unpacklo_epi64( s[ 5], s[ 7] ); d3[1] = _mm_unpackhi_epi64( s[ 5], s[ 7] ); d0[2] = _mm_unpacklo_epi64( s[ 8], s[10] ); d1[2] = _mm_unpackhi_epi64( s[ 8], s[10] ); d2[2] = _mm_unpacklo_epi64( s[ 9], s[11] ); d3[2] = _mm_unpackhi_epi64( s[ 9], s[11] ); d0[3] = _mm_unpacklo_epi64( s[12], s[14] ); d1[3] = _mm_unpackhi_epi64( s[12], s[14] ); d2[3] = _mm_unpacklo_epi64( s[13], s[15] ); d3[3] = _mm_unpackhi_epi64( s[13], s[15] ); } static inline void extr_lane_4x64( void *dst, const void *src, const int lane, const int bit_len ) { __m128i *d = (__m128i*)dst; const __m128i *s = (const __m128i*)src; int i = lane / 2; if ( lane % 2 ) // odd lanes { d[0] = _mm_unpackhi_epi64( s[ i+ 0 ], s[ i+ 2 ] ); d[1] = _mm_unpackhi_epi64( s[ i+ 4 ], s[ i+ 6 ] ); if ( bit_len <= 256 ) return; d[2] = _mm_unpackhi_epi64( s[ i+ 8 ], s[ i+10 ] ); d[3] = _mm_unpackhi_epi64( s[ i+12 ], s[ i+14 ] ); } else // even lanes { d[0] = _mm_unpacklo_epi64( s[ i+ 0 ], s[ i+ 2 ] ); d[1] = _mm_unpacklo_epi64( s[ i+ 4 ], s[ i+ 6 ] ); if ( bit_len <= 256 ) return; d[2] = _mm_unpacklo_epi64( s[ i+ 8 ], s[ i+10 ] ); d[3] = _mm_unpacklo_epi64( s[ i+12 ], s[ i+14 ] ); } return; // bit_len == 512 } /* static inline void extr_lane_4x64( void *d, const void *s, const int lane, const int bit_len ) { ((uint64_t*)d)[ 0] = ((const uint64_t*)s)[ lane ]; ((uint64_t*)d)[ 1] = ((const uint64_t*)s)[ lane+ 4 ]; ((uint64_t*)d)[ 2] = ((const uint64_t*)s)[ lane+ 8 ]; ((uint64_t*)d)[ 3] = ((const uint64_t*)s)[ lane+12 ]; if ( bit_len <= 256 ) return; ((uint64_t*)d)[ 4] = ((const uint64_t*)s)[ lane+16 ]; ((uint64_t*)d)[ 5] = ((const uint64_t*)s)[ lane+20 ]; ((uint64_t*)d)[ 6] = ((const uint64_t*)s)[ lane+24 ]; ((uint64_t*)d)[ 7] = ((const uint64_t*)s)[ lane+28 ]; } */ #if defined(__AVX2__) // Doesn't really need AVX2, just SSSE3, but is only used with AVX2 code. static inline void mm256_intrlv80_4x64( void *d, const void *src ) { __m128i s0 = casti_m128i( src,0 ); __m128i s1 = casti_m128i( src,1 ); __m128i s2 = casti_m128i( src,2 ); __m128i s3 = casti_m128i( src,3 ); __m128i s4 = casti_m128i( src,4 ); casti_m128i( d, 0 ) = casti_m128i( d, 1 ) = _mm_shuffle_epi32( s0, 0x44 ); casti_m128i( d, 2 ) = casti_m128i( d, 3 ) = _mm_shuffle_epi32( s0, 0xee ); casti_m128i( d, 4 ) = casti_m128i( d, 5 ) = _mm_shuffle_epi32( s1, 0x44 ); casti_m128i( d, 6 ) = casti_m128i( d, 7 ) = _mm_shuffle_epi32( s1, 0xee ); casti_m128i( d, 8 ) = casti_m128i( d, 9 ) = _mm_shuffle_epi32( s2, 0x44 ); casti_m128i( d, 10 ) = casti_m128i( d, 11 ) = _mm_shuffle_epi32( s2, 0xee ); casti_m128i( d, 12 ) = casti_m128i( d, 13 ) = _mm_shuffle_epi32( s3, 0x44 ); casti_m128i( d, 14 ) = casti_m128i( d, 15 ) = _mm_shuffle_epi32( s3, 0xee ); casti_m128i( d, 16 ) = casti_m128i( d, 17 ) = _mm_shuffle_epi32( s4, 0x44 ); casti_m128i( d, 18 ) = casti_m128i( d, 19 ) = _mm_shuffle_epi32( s4, 0xee ); } static inline void mm256_bswap32_intrlv80_4x64( void *d, const void *src ) { __m128i bswap_shuf = m128_const_64( 0x0c0d0e0f08090a0b, 0x0405060700010203 ); __m128i s0 = casti_m128i( src,0 ); __m128i s1 = casti_m128i( src,1 ); __m128i s2 = casti_m128i( src,2 ); __m128i s3 = casti_m128i( src,3 ); __m128i s4 = casti_m128i( src,4 ); s0 = _mm_shuffle_epi8( s0, bswap_shuf ); s1 = _mm_shuffle_epi8( s1, bswap_shuf ); s2 = _mm_shuffle_epi8( s2, bswap_shuf ); s3 = _mm_shuffle_epi8( s3, bswap_shuf ); s4 = _mm_shuffle_epi8( s4, bswap_shuf ); casti_m128i( d, 0 ) = casti_m128i( d, 1 ) = _mm_shuffle_epi32( s0, 0x44 ); casti_m128i( d, 2 ) = casti_m128i( d, 3 ) = _mm_shuffle_epi32( s0, 0xee ); casti_m128i( d, 4 ) = casti_m128i( d, 5 ) = _mm_shuffle_epi32( s1, 0x44 ); casti_m128i( d, 6 ) = casti_m128i( d, 7 ) = _mm_shuffle_epi32( s1, 0xee ); casti_m128i( d, 8 ) = casti_m128i( d, 9 ) = _mm_shuffle_epi32( s2, 0x44 ); casti_m128i( d, 10 ) = casti_m128i( d, 11 ) = _mm_shuffle_epi32( s2, 0xee ); casti_m128i( d, 12 ) = casti_m128i( d, 13 ) = _mm_shuffle_epi32( s3, 0x44 ); casti_m128i( d, 14 ) = casti_m128i( d, 15 ) = _mm_shuffle_epi32( s3, 0xee ); casti_m128i( d, 16 ) = casti_m128i( d, 17 ) = _mm_shuffle_epi32( s4, 0x44 ); casti_m128i( d, 18 ) = casti_m128i( d, 19 ) = _mm_shuffle_epi32( s4, 0xee ); } #endif // AVX2 // 8x64 (AVX512) static inline void intrlv_8x64( void *dst, const void *src0, const void *src1, const void *src2, const void *src3, const void *src4, const void *src5, const void *src6, const void *src7, const int bit_len ) { __m128i *d = (__m128i*)dst; const __m128i *s0 = (const __m128i*)src0; const __m128i *s1 = (const __m128i*)src1; const __m128i *s2 = (const __m128i*)src2; const __m128i *s3 = (const __m128i*)src3; const __m128i *s4 = (const __m128i*)src4; const __m128i *s5 = (const __m128i*)src5; const __m128i *s6 = (const __m128i*)src6; const __m128i *s7 = (const __m128i*)src7; d[ 0] = _mm_unpacklo_epi64( s0[0], s1[0] ); d[ 1] = _mm_unpacklo_epi64( s2[0], s3[0] ); d[ 2] = _mm_unpacklo_epi64( s4[0], s5[0] ); d[ 3] = _mm_unpacklo_epi64( s6[0], s7[0] ); d[ 4] = _mm_unpackhi_epi64( s0[0], s1[0] ); d[ 5] = _mm_unpackhi_epi64( s2[0], s3[0] ); d[ 6] = _mm_unpackhi_epi64( s4[0], s5[0] ); d[ 7] = _mm_unpackhi_epi64( s6[0], s7[0] ); d[ 8] = _mm_unpacklo_epi64( s0[1], s1[1] ); d[ 9] = _mm_unpacklo_epi64( s2[1], s3[1] ); d[10] = _mm_unpacklo_epi64( s4[1], s5[1] ); d[11] = _mm_unpacklo_epi64( s6[1], s7[1] ); d[12] = _mm_unpackhi_epi64( s0[1], s1[1] ); d[13] = _mm_unpackhi_epi64( s2[1], s3[1] ); d[14] = _mm_unpackhi_epi64( s4[1], s5[1] ); d[15] = _mm_unpackhi_epi64( s6[1], s7[1] ); if ( bit_len <= 256 ) return; d[16] = _mm_unpacklo_epi64( s0[2], s1[2] ); d[17] = _mm_unpacklo_epi64( s2[2], s3[2] ); d[18] = _mm_unpacklo_epi64( s4[2], s5[2] ); d[19] = _mm_unpacklo_epi64( s6[2], s7[2] ); d[20] = _mm_unpackhi_epi64( s0[2], s1[2] ); d[21] = _mm_unpackhi_epi64( s2[2], s3[2] ); d[22] = _mm_unpackhi_epi64( s4[2], s5[2] ); d[23] = _mm_unpackhi_epi64( s6[2], s7[2] ); d[24] = _mm_unpacklo_epi64( s0[3], s1[3] ); d[25] = _mm_unpacklo_epi64( s2[3], s3[3] ); d[26] = _mm_unpacklo_epi64( s4[3], s5[3] ); d[27] = _mm_unpacklo_epi64( s6[3], s7[3] ); d[28] = _mm_unpackhi_epi64( s0[3], s1[3] ); d[29] = _mm_unpackhi_epi64( s2[3], s3[3] ); d[30] = _mm_unpackhi_epi64( s4[3], s5[3] ); d[31] = _mm_unpackhi_epi64( s6[3], s7[3] ); if ( bit_len <= 512 ) return; d[32] = _mm_unpacklo_epi64( s0[4], s1[4] ); d[33] = _mm_unpacklo_epi64( s2[4], s3[4] ); d[34] = _mm_unpacklo_epi64( s4[4], s5[4] ); d[35] = _mm_unpacklo_epi64( s6[4], s7[4] ); d[36] = _mm_unpackhi_epi64( s0[4], s1[4] ); d[37] = _mm_unpackhi_epi64( s2[4], s3[4] ); d[38] = _mm_unpackhi_epi64( s4[4], s5[4] ); d[39] = _mm_unpackhi_epi64( s6[4], s7[4] ); if ( bit_len <= 640 ) return; d[40] = _mm_unpacklo_epi64( s0[5], s1[5] ); d[41] = _mm_unpacklo_epi64( s2[5], s3[5] ); d[42] = _mm_unpacklo_epi64( s4[5], s5[5] ); d[43] = _mm_unpacklo_epi64( s6[5], s7[5] ); d[44] = _mm_unpackhi_epi64( s0[5], s1[5] ); d[45] = _mm_unpackhi_epi64( s2[5], s3[5] ); d[46] = _mm_unpackhi_epi64( s4[5], s5[5] ); d[47] = _mm_unpackhi_epi64( s6[5], s7[5] ); d[48] = _mm_unpacklo_epi64( s0[6], s1[6] ); d[49] = _mm_unpacklo_epi64( s2[6], s3[6] ); d[50] = _mm_unpacklo_epi64( s4[6], s5[6] ); d[51] = _mm_unpacklo_epi64( s6[6], s7[6] ); d[52] = _mm_unpackhi_epi64( s0[6], s1[6] ); d[53] = _mm_unpackhi_epi64( s2[6], s3[6] ); d[54] = _mm_unpackhi_epi64( s4[6], s5[6] ); d[55] = _mm_unpackhi_epi64( s6[6], s7[6] ); d[56] = _mm_unpacklo_epi64( s0[7], s1[7] ); d[57] = _mm_unpacklo_epi64( s2[7], s3[7] ); d[58] = _mm_unpacklo_epi64( s4[7], s5[7] ); d[59] = _mm_unpacklo_epi64( s6[7], s7[7] ); d[60] = _mm_unpackhi_epi64( s0[7], s1[7] ); d[61] = _mm_unpackhi_epi64( s2[7], s3[7] ); d[62] = _mm_unpackhi_epi64( s4[7], s5[7] ); d[63] = _mm_unpackhi_epi64( s6[7], s7[7] ); } static inline void intrlv_8x64_512( void *dst, const void *src0, const void *src1, const void *src2, const void *src3, const void *src4, const void *src5, const void *src6, const void *src7 ) { __m128i *d = (__m128i*)dst; const __m128i *s0 = (const __m128i*)src0; const __m128i *s1 = (const __m128i*)src1; const __m128i *s2 = (const __m128i*)src2; const __m128i *s3 = (const __m128i*)src3; const __m128i *s4 = (const __m128i*)src4; const __m128i *s5 = (const __m128i*)src5; const __m128i *s6 = (const __m128i*)src6; const __m128i *s7 = (const __m128i*)src7; d[ 0] = _mm_unpacklo_epi64( s0[0], s1[0] ); d[ 1] = _mm_unpacklo_epi64( s2[0], s3[0] ); d[ 2] = _mm_unpacklo_epi64( s4[0], s5[0] ); d[ 3] = _mm_unpacklo_epi64( s6[0], s7[0] ); d[ 4] = _mm_unpackhi_epi64( s0[0], s1[0] ); d[ 5] = _mm_unpackhi_epi64( s2[0], s3[0] ); d[ 6] = _mm_unpackhi_epi64( s4[0], s5[0] ); d[ 7] = _mm_unpackhi_epi64( s6[0], s7[0] ); d[ 8] = _mm_unpacklo_epi64( s0[1], s1[1] ); d[ 9] = _mm_unpacklo_epi64( s2[1], s3[1] ); d[10] = _mm_unpacklo_epi64( s4[1], s5[1] ); d[11] = _mm_unpacklo_epi64( s6[1], s7[1] ); d[12] = _mm_unpackhi_epi64( s0[1], s1[1] ); d[13] = _mm_unpackhi_epi64( s2[1], s3[1] ); d[14] = _mm_unpackhi_epi64( s4[1], s5[1] ); d[15] = _mm_unpackhi_epi64( s6[1], s7[1] ); d[16] = _mm_unpacklo_epi64( s0[2], s1[2] ); d[17] = _mm_unpacklo_epi64( s2[2], s3[2] ); d[18] = _mm_unpacklo_epi64( s4[2], s5[2] ); d[19] = _mm_unpacklo_epi64( s6[2], s7[2] ); d[20] = _mm_unpackhi_epi64( s0[2], s1[2] ); d[21] = _mm_unpackhi_epi64( s2[2], s3[2] ); d[22] = _mm_unpackhi_epi64( s4[2], s5[2] ); d[23] = _mm_unpackhi_epi64( s6[2], s7[2] ); d[24] = _mm_unpacklo_epi64( s0[3], s1[3] ); d[25] = _mm_unpacklo_epi64( s2[3], s3[3] ); d[26] = _mm_unpacklo_epi64( s4[3], s5[3] ); d[27] = _mm_unpacklo_epi64( s6[3], s7[3] ); d[28] = _mm_unpackhi_epi64( s0[3], s1[3] ); d[29] = _mm_unpackhi_epi64( s2[3], s3[3] ); d[30] = _mm_unpackhi_epi64( s4[3], s5[3] ); d[31] = _mm_unpackhi_epi64( s6[3], s7[3] ); } static inline void dintrlv_8x64( void *dst0, void *dst1, void *dst2, void *dst3, void *dst4, void *dst5, void *dst6, void *dst7, const void *src, const int bit_len ) { __m128i *d0 = (__m128i*)dst0; __m128i *d1 = (__m128i*)dst1; __m128i *d2 = (__m128i*)dst2; __m128i *d3 = (__m128i*)dst3; __m128i *d4 = (__m128i*)dst4; __m128i *d5 = (__m128i*)dst5; __m128i *d6 = (__m128i*)dst6; __m128i *d7 = (__m128i*)dst7; const __m128i* s = (const __m128i*)src; d0[0] = _mm_unpacklo_epi64( s[ 0], s[ 4] ); d1[0] = _mm_unpackhi_epi64( s[ 0], s[ 4] ); d2[0] = _mm_unpacklo_epi64( s[ 1], s[ 5] ); d3[0] = _mm_unpackhi_epi64( s[ 1], s[ 5] ); d4[0] = _mm_unpacklo_epi64( s[ 2], s[ 6] ); d5[0] = _mm_unpackhi_epi64( s[ 2], s[ 6] ); d6[0] = _mm_unpacklo_epi64( s[ 3], s[ 7] ); d7[0] = _mm_unpackhi_epi64( s[ 3], s[ 7] ); d0[1] = _mm_unpacklo_epi64( s[ 8], s[12] ); d1[1] = _mm_unpackhi_epi64( s[ 8], s[12] ); d2[1] = _mm_unpacklo_epi64( s[ 9], s[13] ); d3[1] = _mm_unpackhi_epi64( s[ 9], s[13] ); d4[1] = _mm_unpacklo_epi64( s[10], s[14] ); d5[1] = _mm_unpackhi_epi64( s[10], s[14] ); d6[1] = _mm_unpacklo_epi64( s[11], s[15] ); d7[1] = _mm_unpackhi_epi64( s[11], s[15] ); if ( bit_len <= 256 ) return; d0[2] = _mm_unpacklo_epi64( s[16], s[20] ); d1[2] = _mm_unpackhi_epi64( s[16], s[20] ); d2[2] = _mm_unpacklo_epi64( s[17], s[21] ); d3[2] = _mm_unpackhi_epi64( s[17], s[21] ); d4[2] = _mm_unpacklo_epi64( s[18], s[22] ); d5[2] = _mm_unpackhi_epi64( s[18], s[22] ); d6[2] = _mm_unpacklo_epi64( s[19], s[23] ); d7[2] = _mm_unpackhi_epi64( s[19], s[23] ); d0[3] = _mm_unpacklo_epi64( s[24], s[28] ); d1[3] = _mm_unpackhi_epi64( s[24], s[28] ); d2[3] = _mm_unpacklo_epi64( s[25], s[29] ); d3[3] = _mm_unpackhi_epi64( s[25], s[29] ); d4[3] = _mm_unpacklo_epi64( s[26], s[30] ); d5[3] = _mm_unpackhi_epi64( s[26], s[30] ); d6[3] = _mm_unpacklo_epi64( s[27], s[31] ); d7[3] = _mm_unpackhi_epi64( s[27], s[31] ); if ( bit_len <= 512 ) return; d0[4] = _mm_unpacklo_epi64( s[32], s[36] ); d1[4] = _mm_unpackhi_epi64( s[32], s[36] ); d2[4] = _mm_unpacklo_epi64( s[33], s[37] ); d3[4] = _mm_unpackhi_epi64( s[33], s[37] ); d4[4] = _mm_unpacklo_epi64( s[34], s[38] ); d5[4] = _mm_unpackhi_epi64( s[34], s[38] ); d6[4] = _mm_unpacklo_epi64( s[35], s[39] ); d7[4] = _mm_unpackhi_epi64( s[35], s[39] ); if ( bit_len <= 640 ) return; d0[5] = _mm_unpacklo_epi64( s[40], s[44] ); d1[5] = _mm_unpackhi_epi64( s[40], s[44] ); d2[5] = _mm_unpacklo_epi64( s[41], s[45] ); d3[5] = _mm_unpackhi_epi64( s[41], s[45] ); d4[5] = _mm_unpacklo_epi64( s[42], s[46] ); d5[5] = _mm_unpackhi_epi64( s[42], s[46] ); d6[5] = _mm_unpacklo_epi64( s[43], s[47] ); d7[5] = _mm_unpackhi_epi64( s[43], s[47] ); d0[6] = _mm_unpacklo_epi64( s[48], s[52] ); d1[6] = _mm_unpackhi_epi64( s[48], s[52] ); d2[6] = _mm_unpacklo_epi64( s[49], s[53] ); d3[6] = _mm_unpackhi_epi64( s[49], s[53] ); d4[6] = _mm_unpacklo_epi64( s[50], s[54] ); d5[6] = _mm_unpackhi_epi64( s[50], s[54] ); d6[6] = _mm_unpacklo_epi64( s[51], s[55] ); d7[6] = _mm_unpackhi_epi64( s[51], s[55] ); d0[7] = _mm_unpacklo_epi64( s[56], s[60] ); d1[7] = _mm_unpackhi_epi64( s[56], s[60] ); d2[7] = _mm_unpacklo_epi64( s[57], s[61] ); d3[7] = _mm_unpackhi_epi64( s[57], s[61] ); d4[7] = _mm_unpacklo_epi64( s[58], s[62] ); d5[7] = _mm_unpackhi_epi64( s[58], s[62] ); d6[7] = _mm_unpacklo_epi64( s[59], s[63] ); d7[7] = _mm_unpackhi_epi64( s[59], s[63] ); } static inline void dintrlv_8x64_512( void *dst0, void *dst1, void *dst2, void *dst3, void *dst4, void *dst5, void *dst6, void *dst7, const void *src ) { __m128i *d0 = (__m128i*)dst0; __m128i *d1 = (__m128i*)dst1; __m128i *d2 = (__m128i*)dst2; __m128i *d3 = (__m128i*)dst3; __m128i *d4 = (__m128i*)dst4; __m128i *d5 = (__m128i*)dst5; __m128i *d6 = (__m128i*)dst6; __m128i *d7 = (__m128i*)dst7; const __m128i* s = (const __m128i*)src; d0[0] = _mm_unpacklo_epi64( s[ 0], s[ 4] ); d1[0] = _mm_unpackhi_epi64( s[ 0], s[ 4] ); d2[0] = _mm_unpacklo_epi64( s[ 1], s[ 5] ); d3[0] = _mm_unpackhi_epi64( s[ 1], s[ 5] ); d4[0] = _mm_unpacklo_epi64( s[ 2], s[ 6] ); d5[0] = _mm_unpackhi_epi64( s[ 2], s[ 6] ); d6[0] = _mm_unpacklo_epi64( s[ 3], s[ 7] ); d7[0] = _mm_unpackhi_epi64( s[ 3], s[ 7] ); d0[1] = _mm_unpacklo_epi64( s[ 8], s[12] ); d1[1] = _mm_unpackhi_epi64( s[ 8], s[12] ); d2[1] = _mm_unpacklo_epi64( s[ 9], s[13] ); d3[1] = _mm_unpackhi_epi64( s[ 9], s[13] ); d4[1] = _mm_unpacklo_epi64( s[10], s[14] ); d5[1] = _mm_unpackhi_epi64( s[10], s[14] ); d6[1] = _mm_unpacklo_epi64( s[11], s[15] ); d7[1] = _mm_unpackhi_epi64( s[11], s[15] ); d0[2] = _mm_unpacklo_epi64( s[16], s[20] ); d1[2] = _mm_unpackhi_epi64( s[16], s[20] ); d2[2] = _mm_unpacklo_epi64( s[17], s[21] ); d3[2] = _mm_unpackhi_epi64( s[17], s[21] ); d4[2] = _mm_unpacklo_epi64( s[18], s[22] ); d5[2] = _mm_unpackhi_epi64( s[18], s[22] ); d6[2] = _mm_unpacklo_epi64( s[19], s[23] ); d7[2] = _mm_unpackhi_epi64( s[19], s[23] ); d0[3] = _mm_unpacklo_epi64( s[24], s[28] ); d1[3] = _mm_unpackhi_epi64( s[24], s[28] ); d2[3] = _mm_unpacklo_epi64( s[25], s[29] ); d3[3] = _mm_unpackhi_epi64( s[25], s[29] ); d4[3] = _mm_unpacklo_epi64( s[26], s[30] ); d5[3] = _mm_unpackhi_epi64( s[26], s[30] ); d6[3] = _mm_unpacklo_epi64( s[27], s[31] ); d7[3] = _mm_unpackhi_epi64( s[27], s[31] ); } static inline void extr_lane_8x64( void *dst, const void *src, const int lane, const int bit_len ) { __m128i *d = (__m128i*)dst; const __m128i *s = (const __m128i*)src; int i = lane / 2; if ( lane % 2 ) // odd lanes { d[0] = _mm_unpackhi_epi64( s[ i+ 0], s[ i+ 4] ); d[1] = _mm_unpackhi_epi64( s[ i+ 8], s[ i+12] ); if ( bit_len <= 256 ) return; d[2] = _mm_unpackhi_epi64( s[ i+16], s[ i+20] ); d[3] = _mm_unpackhi_epi64( s[ i+24], s[ i+28] ); } else // even lanes { d[0] = _mm_unpacklo_epi64( s[ i+ 0], s[ i+ 4] ); d[1] = _mm_unpacklo_epi64( s[ i+ 8], s[ i+12] ); if ( bit_len <= 256 ) return; d[2] = _mm_unpacklo_epi64( s[ i+16], s[ i+20] ); d[3] = _mm_unpacklo_epi64( s[ i+24], s[ i+28] ); } return; } /* static inline void extr_lane_8x64( void *d, const void *s, const int lane, const int bit_len ) { ((uint64_t*)d)[ 0] = ((const uint64_t*)s)[ lane ]; ((uint64_t*)d)[ 1] = ((const uint64_t*)s)[ lane+ 8 ]; ((uint64_t*)d)[ 2] = ((const uint64_t*)s)[ lane+ 16 ]; ((uint64_t*)d)[ 3] = ((const uint64_t*)s)[ lane+ 24 ]; if ( bit_len <= 256 ) return; ((uint64_t*)d)[ 4] = ((const uint64_t*)s)[ lane+ 32 ]; ((uint64_t*)d)[ 5] = ((const uint64_t*)s)[ lane+ 40 ]; ((uint64_t*)d)[ 6] = ((const uint64_t*)s)[ lane+ 48 ]; ((uint64_t*)d)[ 7] = ((const uint64_t*)s)[ lane+ 56 ]; } */ #if defined(__AVX512F__) && defined(__AVX512VL__) // broadcast to all lanes static inline void mm512_intrlv80_8x64( void *dst, const void *src ) { __m128i *d = (__m128i*)dst; const __m128i *s = (const __m128i*)src; d[ 0] = d[ 1] = d[ 2] = d[ 3] = _mm_shuffle_epi32( s[0], 0x44 ); d[ 4] = d[ 5] = d[ 6] = d[ 7] = _mm_shuffle_epi32( s[0], 0xee ); d[ 8] = d[ 9] = d[10] = d[11] = _mm_shuffle_epi32( s[1], 0x44 ); d[12] = d[13] = d[14] = d[15] = _mm_shuffle_epi32( s[1], 0xee ); d[16] = d[17] = d[18] = d[19] = _mm_shuffle_epi32( s[2], 0x44 ); d[20] = d[21] = d[22] = d[23] = _mm_shuffle_epi32( s[2], 0xee ); d[24] = d[25] = d[26] = d[27] = _mm_shuffle_epi32( s[3], 0x44 ); d[28] = d[29] = d[30] = d[31] = _mm_shuffle_epi32( s[3], 0xee ); d[32] = d[33] = d[34] = d[35] = _mm_shuffle_epi32( s[4], 0x44 ); d[36] = d[37] = d[38] = d[39] = _mm_shuffle_epi32( s[4], 0xee ); } // byte swap and broadcast to al lanes static inline void mm512_bswap32_intrlv80_8x64( void *d, const void *src ) { __m128i bswap_shuf = m128_const_64( 0x0c0d0e0f08090a0b, 0x0405060700010203 ); __m128i s0 = casti_m128i( src,0 ); __m128i s1 = casti_m128i( src,1 ); __m128i s2 = casti_m128i( src,2 ); __m128i s3 = casti_m128i( src,3 ); __m128i s4 = casti_m128i( src,4 ); s0 = _mm_shuffle_epi8( s0, bswap_shuf ); s1 = _mm_shuffle_epi8( s1, bswap_shuf ); s2 = _mm_shuffle_epi8( s2, bswap_shuf ); s3 = _mm_shuffle_epi8( s3, bswap_shuf ); s4 = _mm_shuffle_epi8( s4, bswap_shuf ); casti_m128i( d, 0 ) = casti_m128i( d, 1 ) = casti_m128i( d, 2 ) = casti_m128i( d, 3 ) = _mm_shuffle_epi32( s0, 0x44 ); casti_m128i( d, 4 ) = casti_m128i( d, 5 ) = casti_m128i( d, 6 ) = casti_m128i( d, 7 ) = _mm_shuffle_epi32( s0, 0xee ); casti_m128i( d, 8 ) = casti_m128i( d, 9 ) = casti_m128i( d, 10 ) = casti_m128i( d, 11 ) = _mm_shuffle_epi32( s1, 0x44 ); casti_m128i( d, 12 ) = casti_m128i( d, 13 ) = casti_m128i( d, 14 ) = casti_m128i( d, 15 ) = _mm_shuffle_epi32( s1, 0xee ); casti_m128i( d, 16 ) = casti_m128i( d, 17 ) = casti_m128i( d, 18 ) = casti_m128i( d, 19 ) = _mm_shuffle_epi32( s2, 0x44 ); casti_m128i( d, 20 ) = casti_m128i( d, 21 ) = casti_m128i( d, 22 ) = casti_m128i( d, 23 ) = _mm_shuffle_epi32( s2, 0xee ); casti_m128i( d, 24 ) = casti_m128i( d, 25 ) = casti_m128i( d, 26 ) = casti_m128i( d, 27 ) = _mm_shuffle_epi32( s3, 0x44 ); casti_m128i( d, 28 ) = casti_m128i( d, 29 ) = casti_m128i( d, 30 ) = casti_m128i( d, 31 ) = _mm_shuffle_epi32( s3, 0xee ); casti_m128i( d, 32 ) = casti_m128i( d, 33 ) = casti_m128i( d, 34 ) = casti_m128i( d, 35 ) = _mm_shuffle_epi32( s4, 0x44 ); casti_m128i( d, 36 ) = casti_m128i( d, 37 ) = casti_m128i( d, 38 ) = casti_m128i( d, 39 ) = _mm_shuffle_epi32( s4, 0xee ); } #endif // AVX512 ////////////////////////// // // 128 bit data // 2x128 (AVX2) static inline void intrlv_2x128( void *dst, const void *src0, const void *src1, const int bit_len ) { __m128i *d = (__m128i*)dst; const __m128i *s0 = (const __m128i*)src0; const __m128i *s1 = (const __m128i*)src1; d[ 0] = s0[0]; d[ 1] = s1[0]; d[ 2] = s0[1]; d[ 3] = s1[1]; if ( bit_len <= 256 ) return; d[ 4] = s0[2]; d[ 5] = s1[2]; d[ 6] = s0[3]; d[ 7] = s1[3]; if ( bit_len <= 512 ) return; d[ 8] = s0[4]; d[ 9] = s1[4]; if ( bit_len <= 640 ) return; d[10] = s0[5]; d[11] = s1[5]; d[12] = s0[6]; d[13] = s1[6]; d[14] = s0[7]; d[15] = s1[7]; if ( bit_len <= 1024 ) return; d[16] = s0[8]; d[17] = s1[8]; d[18] = s0[9]; d[19] = s1[9]; // if ( bit_len <= 1280 ) return; } static inline void intrlv_2x128_512( void *dst, const void *src0, const void *src1 ) { __m128i *d = (__m128i*)dst; const __m128i *s0 = (const __m128i*)src0; const __m128i *s1 = (const __m128i*)src1; d[0] = s0[0]; d[1] = s1[0]; d[2] = s0[1]; d[3] = s1[1]; d[4] = s0[2]; d[5] = s1[2]; d[6] = s0[3]; d[7] = s1[3]; } static inline void dintrlv_2x128( void *dst0, void *dst1, const void *src, int bit_len ) { __m128i *d0 = (__m128i*)dst0; __m128i *d1 = (__m128i*)dst1; const __m128i *s = (const __m128i*)src; d0[0] = s[ 0]; d1[0] = s[ 1]; d0[1] = s[ 2]; d1[1] = s[ 3]; if ( bit_len <= 256 ) return; d0[2] = s[ 4]; d1[2] = s[ 5]; d0[3] = s[ 6]; d1[3] = s[ 7]; if ( bit_len <= 512 ) return; d0[4] = s[ 8]; d1[4] = s[ 9]; if ( bit_len <= 640 ) return; d0[5] = s[10]; d1[5] = s[11]; d0[6] = s[12]; d1[6] = s[13]; d0[7] = s[14]; d1[7] = s[15]; } static inline void dintrlv_2x128_512( void *dst0, void *dst1, const void *src ) { __m128i *d0 = (__m128i*)dst0; __m128i *d1 = (__m128i*)dst1; const __m128i *s = (const __m128i*)src; d0[0] = s[0]; d1[0] = s[1]; d0[1] = s[2]; d1[1] = s[3]; d0[2] = s[4]; d1[2] = s[5]; d0[3] = s[6]; d1[3] = s[7]; } // 4x128 (AVX512) static inline void intrlv_4x128( void *dst, const void *src0, const void *src1, const void *src2, const void *src3, const int bit_len ) { __m128i *d = (__m128i*)dst; const __m128i *s0 = (const __m128i*)src0; const __m128i *s1 = (const __m128i*)src1; const __m128i *s2 = (const __m128i*)src2; const __m128i *s3 = (const __m128i*)src3; d[ 0] = s0[0]; d[ 1] = s1[0]; d[ 2] = s2[0]; d[ 3] = s3[0]; d[ 4] = s0[1]; d[ 5] = s1[1]; d[ 6] = s2[1]; d[ 7] = s3[1]; if ( bit_len <= 256 ) return; d[ 8] = s0[2]; d[ 9] = s1[2]; d[10] = s2[2]; d[11] = s3[2]; d[12] = s0[3]; d[13] = s1[3]; d[14] = s2[3]; d[15] = s3[3]; if ( bit_len <= 512 ) return; d[16] = s0[4]; d[17] = s1[4]; d[18] = s2[4]; d[19] = s3[4]; if ( bit_len <= 640 ) return; d[20] = s0[5]; d[21] = s1[5]; d[22] = s2[5]; d[23] = s3[5]; d[24] = s0[6]; d[25] = s1[6]; d[26] = s2[6]; d[27] = s3[6]; d[28] = s0[7]; d[29] = s1[7]; d[30] = s2[7]; d[31] = s3[7]; if ( bit_len <= 1024 ) return; d[32] = s0[8]; d[33] = s1[8]; d[34] = s2[8]; d[35] = s3[8]; d[36] = s0[9]; d[37] = s1[9]; d[38] = s2[9]; d[39] = s3[9]; // if ( bit_len <= 1280 ) return; } static inline void intrlv_4x128_512( void *dst, const void *src0, const void *src1, const void *src2, const void *src3 ) { __m128i *d = (__m128i*)dst; const __m128i *s0 = (const __m128i*)src0; const __m128i *s1 = (const __m128i*)src1; const __m128i *s2 = (const __m128i*)src2; const __m128i *s3 = (const __m128i*)src3; d[ 0] = s0[0]; d[ 1] = s1[0]; d[ 2] = s2[0]; d[ 3] = s3[0]; d[ 4] = s0[1]; d[ 5] = s1[1]; d[ 6] = s2[1]; d[ 7] = s3[1]; d[ 8] = s0[2]; d[ 9] = s1[2]; d[10] = s2[2]; d[11] = s3[2]; d[12] = s0[3]; d[13] = s1[3]; d[14] = s2[3]; d[15] = s3[3]; } static inline void dintrlv_4x128( void *dst0, void *dst1, void *dst2, void *dst3, const void *src, const int bit_len ) { __m128i *d0 = (__m128i*)dst0; __m128i *d1 = (__m128i*)dst1; __m128i *d2 = (__m128i*)dst2; __m128i *d3 = (__m128i*)dst3; const __m128i *s = (const __m128i*)src; d0[0] = s[ 0]; d1[0] = s[ 1]; d2[0] = s[ 2]; d3[0] = s[ 3]; d0[1] = s[ 4]; d1[1] = s[ 5]; d2[1] = s[ 6]; d3[1] = s[ 7]; if ( bit_len <= 256 ) return; d0[2] = s[ 8]; d1[2] = s[ 9]; d2[2] = s[10]; d3[2] = s[11]; d0[3] = s[12]; d1[3] = s[13]; d2[3] = s[14]; d3[3] = s[15]; if ( bit_len <= 512 ) return; d0[4] = s[16]; d1[4] = s[17]; d2[4] = s[18]; d3[4] = s[19]; if ( bit_len <= 640 ) return; d0[5] = s[20]; d1[5] = s[21]; d2[5] = s[22]; d3[5] = s[23]; d0[6] = s[24]; d1[6] = s[25]; d2[6] = s[26]; d3[6] = s[27]; d0[7] = s[28]; d1[7] = s[29]; d2[7] = s[30]; d3[7] = s[31]; } static inline void dintrlv_4x128_512( void *dst0, void *dst1, void *dst2, void *dst3, const void *src ) { __m128i *d0 = (__m128i*)dst0; __m128i *d1 = (__m128i*)dst1; __m128i *d2 = (__m128i*)dst2; __m128i *d3 = (__m128i*)dst3; const __m128i *s = (const __m128i*)src; d0[0] = s[ 0]; d1[0] = s[ 1]; d2[0] = s[ 2]; d3[0] = s[ 3]; d0[1] = s[ 4]; d1[1] = s[ 5]; d2[1] = s[ 6]; d3[1] = s[ 7]; d0[2] = s[ 8]; d1[2] = s[ 9]; d2[2] = s[10]; d3[2] = s[11]; d0[3] = s[12]; d1[3] = s[13]; d2[3] = s[14]; d3[3] = s[15]; } #if defined(__AVX512F__) && defined(__AVX512VL__) && defined(__AVX512DQ__) && defined(__AVX512BW__) static inline void mm512_bswap32_intrlv80_4x128( void *d, void *src ) { __m128i bswap_shuf = m128_const_64( 0x0c0d0e0f08090a0b, 0x0405060700010203 ); __m128i s0 = casti_m128i( src,0 ); __m128i s1 = casti_m128i( src,1 ); __m128i s2 = casti_m128i( src,2 ); __m128i s3 = casti_m128i( src,3 ); __m128i s4 = casti_m128i( src,4 ); s0 = _mm_shuffle_epi8( s0, bswap_shuf ); s1 = _mm_shuffle_epi8( s1, bswap_shuf ); s2 = _mm_shuffle_epi8( s2, bswap_shuf ); s3 = _mm_shuffle_epi8( s3, bswap_shuf ); s4 = _mm_shuffle_epi8( s4, bswap_shuf ); casti_m512i( d, 0 ) = _mm512_broadcast_i64x2( s0 ); casti_m512i( d, 1 ) = _mm512_broadcast_i64x2( s1 ); casti_m512i( d, 2 ) = _mm512_broadcast_i64x2( s2 ); casti_m512i( d, 3 ) = _mm512_broadcast_i64x2( s3 ); casti_m512i( d, 4 ) = _mm512_broadcast_i64x2( s4 ); } #endif // 2x256 (AVX512) #if defined (__AVX__) static inline void intrlv_2x256( void *dst, const void *src0, const void *src1, const int bit_len ) { __m256i *d = (__m256i*)dst; const __m256i *s0 = (const __m256i*)src0; const __m256i *s1 = (const __m256i*)src1; d[0] = s0[0]; d[1] = s1[0]; if ( bit_len <= 256 ) return; d[2] = s0[1]; d[3] = s1[1]; if ( bit_len <= 512 ) return; d[4] = s0[2]; if ( bit_len <= 640 ) return; d[5] = s1[2]; d[6] = s0[3]; d[7] = s1[3]; } // No 80 byte dintrlv static inline void dintrlv_2x256( void *dst0, void *dst1, const void *src, int bit_len ) { __m256i *d0 = (__m256i*)dst0; __m256i *d1 = (__m256i*)dst1; const __m256i *s = (const __m256i*)src; d0[0] = s[0]; d1[0] = s[1]; if ( bit_len <= 256 ) return; d0[1] = s[2]; d1[1] = s[3]; if ( bit_len <= 512 ) return; d0[2] = s[4]; d1[2] = s[5]; d0[3] = s[6]; d1[3] = s[7]; } #endif // AVX /////////////////////////// // // Re-intereleaving // 4x64 -> 4x32 #define RLEAVE_4x64_4x32( i ) do \ { \ uint32_t *d = (uint32_t*)dst + (i); \ const uint32_t *s = (const uint32_t*)src + (i); \ d[0] = s[0]; d[1] = s[2]; \ d[2] = s[4]; d[3] = s[6]; \ d[4] = s[1]; d[5] = s[3]; \ d[6] = s[5]; d[7] = s[7]; \ } while(0) // Convert 4x64 byte (256 bit) vectors to 4x32 (128 bit) vectors for AVX // bit_len must be multiple of 64 static inline void rintrlv_4x64_4x32( void *dst, const void *src, const int bit_len ) { RLEAVE_4x64_4x32( 0 ); RLEAVE_4x64_4x32( 8 ); RLEAVE_4x64_4x32( 16 ); RLEAVE_4x64_4x32( 24 ); if ( bit_len <= 256 ) return; RLEAVE_4x64_4x32( 32 ); RLEAVE_4x64_4x32( 40 ); RLEAVE_4x64_4x32( 48 ); RLEAVE_4x64_4x32( 56 ); if ( bit_len <= 512 ) return; RLEAVE_4x64_4x32( 64 ); RLEAVE_4x64_4x32( 72 ); if ( bit_len <= 640 ) return; RLEAVE_4x64_4x32( 80 ); RLEAVE_4x64_4x32( 88 ); RLEAVE_4x64_4x32( 96 ); RLEAVE_4x64_4x32( 104 ); RLEAVE_4x64_4x32( 112 ); RLEAVE_4x64_4x32( 120 ); } #undef RLEAVE_4x64_4x32 #define RLEAVE_8x64_8x32( i ) do \ { \ uint32_t *d = (uint32_t*)dst + (i); \ const uint32_t *s = (const uint32_t*)src + (i); \ d[ 0] = s[ 0]; d[ 1] = s[ 2]; d[ 2] = s[ 4]; d[ 3] = s[ 6]; \ d[ 4] = s[ 8]; d[ 5] = s[10]; d[ 6] = s[12]; d[ 7] = s[14]; \ d[ 8] = s[ 1]; d[ 9] = s[ 3]; d[10] = s[ 5]; d[11] = s[ 7]; \ d[12] = s[ 9]; d[13] = s[11]; d[14] = s[13]; d[15] = s[15]; \ } while(0) // 8x64 -> 8x32 static inline void rintrlv_8x64_8x32( void *dst, const void *src, const int bit_len ) { RLEAVE_8x64_8x32( 0 ); RLEAVE_8x64_8x32( 16 ); RLEAVE_8x64_8x32( 32 ); RLEAVE_8x64_8x32( 48 ); if ( bit_len <= 256 ) return; RLEAVE_8x64_8x32( 64 ); RLEAVE_8x64_8x32( 80 ); RLEAVE_8x64_8x32( 96 ); RLEAVE_8x64_8x32( 112 ); if ( bit_len <= 512 ) return; RLEAVE_8x64_8x32( 128 ); RLEAVE_8x64_8x32( 144 ); if ( bit_len <= 640 ) return; RLEAVE_8x64_8x32( 160 ); RLEAVE_8x64_8x32( 176 ); RLEAVE_8x64_8x32( 192 ); RLEAVE_8x64_8x32( 208 ); RLEAVE_8x64_8x32( 224 ); RLEAVE_8x64_8x32( 240 ); } #undef RLEAVE_8x64_8x32 // 4x32 -> 4x64 static inline void rintrlv_4x32_4x64( void *dst, const void *src, const int bit_len ) { __m128i *d = (__m128i*)dst; const __m128i *s = (const __m128i*)src; d[ 0] = _mm_unpacklo_epi32( s[ 0], s[ 1] ); d[ 1] = _mm_unpackhi_epi32( s[ 0], s[ 1] ); d[ 2] = _mm_unpacklo_epi32( s[ 2], s[ 3] ); d[ 3] = _mm_unpackhi_epi32( s[ 2], s[ 3] ); d[ 4] = _mm_unpacklo_epi32( s[ 4], s[ 5] ); d[ 5] = _mm_unpackhi_epi32( s[ 4], s[ 5] ); d[ 6] = _mm_unpacklo_epi32( s[ 6], s[ 7] ); d[ 7] = _mm_unpackhi_epi32( s[ 6], s[ 7] ); if ( bit_len <= 256 ) return; d[ 8] = _mm_unpacklo_epi32( s[ 8], s[ 9] ); d[ 9] = _mm_unpackhi_epi32( s[ 8], s[ 9] ); d[10] = _mm_unpacklo_epi32( s[10], s[11] ); d[11] = _mm_unpackhi_epi32( s[10], s[11] ); d[12] = _mm_unpacklo_epi32( s[12], s[13] ); d[13] = _mm_unpackhi_epi32( s[12], s[13] ); d[14] = _mm_unpacklo_epi32( s[14], s[15] ); d[15] = _mm_unpackhi_epi32( s[14], s[15] ); if ( bit_len <= 512 ) return; d[16] = _mm_unpacklo_epi32( s[16], s[17] ); d[17] = _mm_unpackhi_epi32( s[16], s[17] ); d[18] = _mm_unpacklo_epi32( s[18], s[19] ); d[19] = _mm_unpackhi_epi32( s[18], s[19] ); if ( bit_len <= 640 ) return; d[20] = _mm_unpacklo_epi32( s[20], s[21] ); d[21] = _mm_unpackhi_epi32( s[20], s[21] ); d[22] = _mm_unpacklo_epi32( s[22], s[23] ); d[23] = _mm_unpackhi_epi32( s[22], s[23] ); d[24] = _mm_unpacklo_epi32( s[24], s[25] ); d[25] = _mm_unpackhi_epi32( s[24], s[25] ); d[26] = _mm_unpacklo_epi32( s[26], s[27] ); d[27] = _mm_unpackhi_epi32( s[26], s[27] ); d[28] = _mm_unpacklo_epi32( s[28], s[29] ); d[29] = _mm_unpackhi_epi32( s[28], s[29] ); d[30] = _mm_unpacklo_epi32( s[30], s[31] ); d[31] = _mm_unpackhi_epi32( s[30], s[31] ); } // 8x32 -> 8x64 static inline void rintrlv_8x32_8x64( void *dst, const void *src, const int bit_len ) { __m128i *d = (__m128i*)dst; const __m128i *s = (const __m128i*)src; d[ 0] = _mm_unpacklo_epi32( s[ 0], s[ 2] ); d[ 1] = _mm_unpackhi_epi32( s[ 0], s[ 2] ); d[ 2] = _mm_unpacklo_epi32( s[ 1], s[ 3] ); d[ 3] = _mm_unpackhi_epi32( s[ 1], s[ 3] ); d[ 4] = _mm_unpacklo_epi32( s[ 4], s[ 6] ); d[ 5] = _mm_unpackhi_epi32( s[ 4], s[ 6] ); d[ 6] = _mm_unpacklo_epi32( s[ 5], s[ 7] ); d[ 7] = _mm_unpackhi_epi32( s[ 5], s[ 7] ); d[ 8] = _mm_unpacklo_epi32( s[ 8], s[10] ); d[ 9] = _mm_unpackhi_epi32( s[ 8], s[10] ); d[10] = _mm_unpacklo_epi32( s[ 9], s[11] ); d[11] = _mm_unpackhi_epi32( s[ 9], s[11] ); d[12] = _mm_unpacklo_epi32( s[12], s[14] ); d[13] = _mm_unpackhi_epi32( s[12], s[14] ); d[14] = _mm_unpacklo_epi32( s[13], s[15] ); d[15] = _mm_unpackhi_epi32( s[13], s[15] ); if ( bit_len <= 256 ) return; d[16] = _mm_unpacklo_epi32( s[16], s[18] ); d[17] = _mm_unpackhi_epi32( s[16], s[18] ); d[18] = _mm_unpacklo_epi32( s[17], s[19] ); d[19] = _mm_unpackhi_epi32( s[17], s[19] ); d[20] = _mm_unpacklo_epi32( s[20], s[22] ); d[21] = _mm_unpackhi_epi32( s[20], s[22] ); d[22] = _mm_unpacklo_epi32( s[21], s[23] ); d[23] = _mm_unpackhi_epi32( s[21], s[23] ); d[24] = _mm_unpacklo_epi32( s[24], s[26] ); d[25] = _mm_unpackhi_epi32( s[24], s[26] ); d[26] = _mm_unpacklo_epi32( s[25], s[27] ); d[27] = _mm_unpackhi_epi32( s[25], s[27] ); d[28] = _mm_unpacklo_epi32( s[28], s[30] ); d[29] = _mm_unpackhi_epi32( s[28], s[30] ); d[30] = _mm_unpacklo_epi32( s[29], s[31] ); d[31] = _mm_unpackhi_epi32( s[29], s[31] ); if ( bit_len <= 512 ) return; d[32] = _mm_unpacklo_epi32( s[32], s[34] ); d[33] = _mm_unpackhi_epi32( s[32], s[34] ); d[34] = _mm_unpacklo_epi32( s[33], s[35] ); d[35] = _mm_unpackhi_epi32( s[33], s[35] ); d[36] = _mm_unpacklo_epi32( s[36], s[38] ); d[37] = _mm_unpackhi_epi32( s[36], s[38] ); d[38] = _mm_unpacklo_epi32( s[37], s[39] ); d[39] = _mm_unpackhi_epi32( s[37], s[39] ); if ( bit_len <= 640 ) return; d[40] = _mm_unpacklo_epi32( s[40], s[42] ); d[41] = _mm_unpackhi_epi32( s[40], s[42] ); d[42] = _mm_unpacklo_epi32( s[41], s[43] ); d[43] = _mm_unpackhi_epi32( s[41], s[43] ); d[44] = _mm_unpacklo_epi32( s[44], s[46] ); d[45] = _mm_unpackhi_epi32( s[44], s[46] ); d[46] = _mm_unpacklo_epi32( s[45], s[47] ); d[47] = _mm_unpackhi_epi32( s[45], s[47] ); d[48] = _mm_unpacklo_epi32( s[48], s[50] ); d[49] = _mm_unpackhi_epi32( s[48], s[50] ); d[50] = _mm_unpacklo_epi32( s[49], s[51] ); d[51] = _mm_unpackhi_epi32( s[49], s[51] ); d[52] = _mm_unpacklo_epi32( s[52], s[54] ); d[53] = _mm_unpackhi_epi32( s[52], s[54] ); d[54] = _mm_unpacklo_epi32( s[53], s[55] ); d[55] = _mm_unpackhi_epi32( s[53], s[55] ); d[56] = _mm_unpacklo_epi32( s[56], s[58] ); d[57] = _mm_unpackhi_epi32( s[56], s[58] ); d[58] = _mm_unpacklo_epi32( s[57], s[59] ); d[59] = _mm_unpackhi_epi32( s[57], s[59] ); d[60] = _mm_unpacklo_epi32( s[60], s[62] ); d[61] = _mm_unpackhi_epi32( s[60], s[62] ); d[62] = _mm_unpacklo_epi32( s[61], s[63] ); d[63] = _mm_unpackhi_epi32( s[61], s[63] ); } // 8x32 -> 4x128 // 16 bytes per lane #define RLEAVE_8X32_4X128( i ) \ do { \ uint32_t *d0 = (uint32_t*)dst0 + (i); \ uint32_t *d1 = (uint32_t*)dst1 + (i); \ const uint32_t *s = (const uint32_t*)src + ((i)<<1); \ d0[ 0] = s[ 0]; d1[ 0] = s[ 4]; \ d0[ 1] = s[ 8]; d1[ 1] = s[12]; \ d0[ 2] = s[16]; d1[ 2] = s[20]; \ d0[ 3] = s[24]; d1[ 3] = s[28]; \ \ d0[ 4] = s[ 1]; d1[ 4] = s[ 5]; \ d0[ 5] = s[ 9]; d1[ 5] = s[13]; \ d0[ 6] = s[17]; d1[ 6] = s[21]; \ d0[ 7] = s[25]; d1[ 7] = s[29]; \ \ d0[ 8] = s[ 2]; d1[ 8] = s[ 6]; \ d0[ 9] = s[10]; d1[ 9] = s[14]; \ d0[10] = s[18]; d1[10] = s[22]; \ d0[11] = s[26]; d1[11] = s[30]; \ \ d0[12] = s[ 3]; d1[12] = s[ 7]; \ d0[13] = s[11]; d1[13] = s[15]; \ d0[14] = s[19]; d1[14] = s[23]; \ d0[15] = s[27]; d1[15] = s[31]; \ } while(0) static inline void rintrlv_8x32_4x128( void *dst0, void *dst1, const void *src, const int bit_len ) { RLEAVE_8X32_4X128( 0 ); RLEAVE_8X32_4X128( 16 ); if ( bit_len <= 256 ) return; RLEAVE_8X32_4X128( 32 ); RLEAVE_8X32_4X128( 48 ); if ( bit_len <= 512 ) return; RLEAVE_8X32_4X128( 64 ); if ( bit_len <= 640 ) return; RLEAVE_8X32_4X128( 80 ); RLEAVE_8X32_4X128( 96 ); RLEAVE_8X32_4X128( 112 ); } #undef RLEAVE_8X32_4X128 /* #define RLEAVE_4x32_4x64(i) do \ { \ uint32_t *d = (uint32_t*)dst + (i); \ const uint32_t *s = (const uint32_t*)src + (i); \ d[0] = s[0]; d[1] = s[4]; \ d[2] = s[1]; d[3] = s[5]; \ d[4] = s[2]; d[5] = s[6]; \ d[6] = s[3]; d[7] = s[7]; \ } while(0) static inline void rintrlv_4x32_4x64( void *dst, const void *src, int bit_len ) { RLEAVE_4x32_4x64( 0 ); RLEAVE_4x32_4x64( 8 ); RLEAVE_4x32_4x64( 16 ); RLEAVE_4x32_4x64( 24 ); if ( bit_len <= 256 ) return; RLEAVE_4x32_4x64( 32 ); RLEAVE_4x32_4x64( 40 ); RLEAVE_4x32_4x64( 48 ); RLEAVE_4x32_4x64( 56 ); if ( bit_len <= 512 ) return; RLEAVE_4x32_4x64( 64 ); RLEAVE_4x32_4x64( 72 ); RLEAVE_4x32_4x64( 80 ); RLEAVE_4x32_4x64( 88 ); RLEAVE_4x32_4x64( 96 ); RLEAVE_4x32_4x64( 104 ); RLEAVE_4x32_4x64( 112 ); RLEAVE_4x32_4x64( 120 ); } #undef RLEAVE_4x32_4x64 */ // 2x128 -> 4x64 static inline void rintrlv_2x128_4x64( void *dst, const void *src0, const void *src1, const int bit_len ) { __m128i *d = (__m128i*)dst; const __m128i *s0 = (const __m128i*)src0; const __m128i *s1 = (const __m128i*)src1; d[ 0] = _mm_unpacklo_epi64( s0[ 0], s0[ 1] ); d[ 1] = _mm_unpacklo_epi64( s1[ 0], s1[ 1] ); d[ 2] = _mm_unpackhi_epi64( s0[ 0], s0[ 1] ); d[ 3] = _mm_unpackhi_epi64( s1[ 0], s1[ 1] ); d[ 4] = _mm_unpacklo_epi64( s0[ 2], s0[ 3] ); d[ 5] = _mm_unpacklo_epi64( s1[ 2], s1[ 3] ); d[ 6] = _mm_unpackhi_epi64( s0[ 2], s0[ 3] ); d[ 7] = _mm_unpackhi_epi64( s1[ 2], s1[ 3] ); if ( bit_len <= 256 ) return; d[ 8] = _mm_unpacklo_epi64( s0[ 4], s0[ 5] ); d[ 9] = _mm_unpacklo_epi64( s1[ 4], s1[ 5] ); d[10] = _mm_unpackhi_epi64( s0[ 4], s0[ 5] ); d[11] = _mm_unpackhi_epi64( s1[ 4], s1[ 5] ); d[12] = _mm_unpacklo_epi64( s0[ 6], s0[ 7] ); d[13] = _mm_unpacklo_epi64( s1[ 6], s1[ 7] ); d[14] = _mm_unpackhi_epi64( s0[ 6], s0[ 7] ); d[15] = _mm_unpackhi_epi64( s1[ 6], s1[ 7] ); if ( bit_len <= 512 ) return; d[16] = _mm_unpacklo_epi64( s0[ 8], s0[ 9] ); d[17] = _mm_unpacklo_epi64( s1[ 8], s1[ 9] ); d[18] = _mm_unpackhi_epi64( s0[ 8], s0[ 9] ); d[19] = _mm_unpackhi_epi64( s1[ 8], s1[ 9] ); if ( bit_len <= 640 ) return; d[20] = _mm_unpacklo_epi64( s0[10], s0[11] ); d[21] = _mm_unpacklo_epi64( s1[10], s1[11] ); d[22] = _mm_unpackhi_epi64( s0[10], s0[11] ); d[23] = _mm_unpackhi_epi64( s1[10], s1[11] ); d[24] = _mm_unpacklo_epi64( s0[12], s0[13] ); d[25] = _mm_unpacklo_epi64( s1[12], s1[13] ); d[26] = _mm_unpackhi_epi64( s0[12], s0[13] ); d[27] = _mm_unpackhi_epi64( s1[12], s1[13] ); d[28] = _mm_unpacklo_epi64( s0[14], s0[15] ); d[29] = _mm_unpacklo_epi64( s1[14], s1[15] ); d[30] = _mm_unpackhi_epi64( s0[14], s0[15] ); d[31] = _mm_unpackhi_epi64( s1[14], s1[15] ); } /* #define RLEAVE_2x128_4x64( i ) do \ { \ uint64_t *d = (uint64_t*)dst + ((i)<<1); \ const uint64_t *s0 = (const uint64_t*)src0 + (i); \ const uint64_t *s1 = (const uint64_t*)src1 + (i); \ d[0] = s0[0]; d[1] = s0[2]; \ d[2] = s1[0]; d[3] = s1[2]; \ d[4] = s0[1]; d[5] = s0[3]; \ d[6] = s1[1]; d[7] = s1[3]; \ } while(0) static inline void rintrlv_2x128_4x64( void *dst, const void *src0, const void *src1, int bit_len ) { RLEAVE_2x128_4x64( 0 ); RLEAVE_2x128_4x64( 4 ); if ( bit_len <= 256 ) return; RLEAVE_2x128_4x64( 8 ); RLEAVE_2x128_4x64( 12 ); if ( bit_len <= 512 ) return; RLEAVE_2x128_4x64( 16 ); RLEAVE_2x128_4x64( 20 ); RLEAVE_2x128_4x64( 24 ); RLEAVE_2x128_4x64( 28 ); } #undef RLEAVE_2x128_4x64 */ // 4x64 -> 2x128 static inline void rintrlv_4x64_2x128( void *dst0, void *dst1, const void *src, const int bit_len ) { __m128i *d0 = (__m128i*)dst0; __m128i *d1 = (__m128i*)dst1; const __m128i* s = (const __m128i*)src; d0[ 0] = _mm_unpacklo_epi64( s[ 0], s[ 2] ); d0[ 1] = _mm_unpackhi_epi64( s[ 0], s[ 2] ); d1[ 0] = _mm_unpacklo_epi64( s[ 1], s[ 3] ); d1[ 1] = _mm_unpackhi_epi64( s[ 1], s[ 3] ); d0[ 2] = _mm_unpacklo_epi64( s[ 4], s[ 6] ); d0[ 3] = _mm_unpackhi_epi64( s[ 4], s[ 6] ); d1[ 2] = _mm_unpacklo_epi64( s[ 5], s[ 7] ); d1[ 3] = _mm_unpackhi_epi64( s[ 5], s[ 7] ); if ( bit_len <= 256 ) return; d0[ 4] = _mm_unpacklo_epi64( s[ 8], s[10] ); d0[ 5] = _mm_unpackhi_epi64( s[ 8], s[10] ); d1[ 4] = _mm_unpacklo_epi64( s[ 9], s[11] ); d1[ 5] = _mm_unpackhi_epi64( s[ 9], s[11] ); d0[ 6] = _mm_unpacklo_epi64( s[12], s[14] ); d0[ 7] = _mm_unpackhi_epi64( s[12], s[14] ); d1[ 6] = _mm_unpacklo_epi64( s[13], s[15] ); d1[ 7] = _mm_unpackhi_epi64( s[13], s[15] ); if ( bit_len <= 512 ) return; d0[ 8] = _mm_unpacklo_epi64( s[16], s[18] ); d0[ 9] = _mm_unpackhi_epi64( s[16], s[18] ); d1[ 8] = _mm_unpacklo_epi64( s[17], s[19] ); d1[ 9] = _mm_unpackhi_epi64( s[17], s[19] ); if ( bit_len <= 640 ) return; d0[10] = _mm_unpacklo_epi64( s[20], s[22] ); d0[11] = _mm_unpackhi_epi64( s[20], s[22] ); d1[10] = _mm_unpacklo_epi64( s[21], s[23] ); d1[11] = _mm_unpackhi_epi64( s[21], s[23] ); d0[12] = _mm_unpacklo_epi64( s[24], s[26] ); d0[13] = _mm_unpackhi_epi64( s[24], s[26] ); d1[12] = _mm_unpacklo_epi64( s[25], s[27] ); d1[13] = _mm_unpackhi_epi64( s[25], s[27] ); d0[14] = _mm_unpacklo_epi64( s[28], s[30] ); d0[15] = _mm_unpackhi_epi64( s[28], s[30] ); d1[14] = _mm_unpacklo_epi64( s[29], s[31] ); d1[15] = _mm_unpackhi_epi64( s[29], s[31] ); } /* #define RLEAVE_4x64_2x128( i ) do \ { \ uint64_t *d0 = (uint64_t*)dst0 + (i); \ uint64_t *d1 = (uint64_t*)dst1 + (i); \ const uint64_t *s = (const uint64_t*)src + ((i)<<1); \ d0[0] = s[0]; d0[1] = s[4]; \ d0[2] = s[1]; d0[3] = s[5]; \ d1[0] = s[2]; d1[1] = s[6]; \ d1[2] = s[3]; d1[3] = s[7]; \ } while(0) static inline void rintrlv_4x64_2x128( void *dst0, void *dst1, const void *src, int bit_len ) { RLEAVE_4x64_2x128( 0 ); RLEAVE_4x64_2x128( 4 ); if ( bit_len <= 256 ) return; RLEAVE_4x64_2x128( 8 ); RLEAVE_4x64_2x128( 12 ); if ( bit_len <= 512 ) return; RLEAVE_4x64_2x128( 16 ); RLEAVE_4x64_2x128( 20 ); RLEAVE_4x64_2x128( 24 ); RLEAVE_4x64_2x128( 28 ); } */ // 2x128 -> 8x64 static inline void rintrlv_4x128_8x64( void *dst, const void *src0, const void *src1, const int bit_len ) { __m128i *d = (__m128i*)dst; const __m128i *s0 = (const __m128i*)src0; const __m128i *s1 = (const __m128i*)src1; d[ 0] = _mm_unpacklo_epi64( s0[ 0], s0[ 1] ); d[ 1] = _mm_unpacklo_epi64( s0[ 2], s0[ 3] ); d[ 2] = _mm_unpacklo_epi64( s1[ 0], s1[ 1] ); d[ 3] = _mm_unpacklo_epi64( s1[ 2], s1[ 3] ); d[ 4] = _mm_unpackhi_epi64( s0[ 0], s0[ 1] ); d[ 5] = _mm_unpackhi_epi64( s0[ 2], s0[ 3] ); d[ 6] = _mm_unpackhi_epi64( s1[ 0], s1[ 1] ); d[ 7] = _mm_unpackhi_epi64( s1[ 2], s1[ 3] ); d[ 8] = _mm_unpacklo_epi64( s0[ 4], s0[ 5] ); d[ 9] = _mm_unpacklo_epi64( s0[ 6], s0[ 7] ); d[10] = _mm_unpacklo_epi64( s1[ 4], s1[ 5] ); d[11] = _mm_unpacklo_epi64( s1[ 6], s1[ 7] ); d[12] = _mm_unpackhi_epi64( s0[ 4], s0[ 5] ); d[13] = _mm_unpackhi_epi64( s0[ 6], s0[ 7] ); d[14] = _mm_unpackhi_epi64( s1[ 4], s1[ 5] ); d[15] = _mm_unpackhi_epi64( s1[ 6], s1[ 7] ); if ( bit_len <= 256 ) return; d[16] = _mm_unpacklo_epi64( s0[ 8], s0[ 9] ); d[17] = _mm_unpacklo_epi64( s0[10], s0[11] ); d[18] = _mm_unpacklo_epi64( s1[ 8], s1[ 9] ); d[19] = _mm_unpacklo_epi64( s1[10], s1[11] ); d[20] = _mm_unpackhi_epi64( s0[ 8], s0[ 9] ); d[21] = _mm_unpackhi_epi64( s0[10], s0[11] ); d[22] = _mm_unpackhi_epi64( s1[ 8], s1[ 9] ); d[23] = _mm_unpackhi_epi64( s1[10], s1[11] ); d[24] = _mm_unpacklo_epi64( s0[12], s0[13] ); d[25] = _mm_unpacklo_epi64( s0[14], s0[15] ); d[26] = _mm_unpacklo_epi64( s1[12], s1[13] ); d[27] = _mm_unpacklo_epi64( s1[14], s1[15] ); d[28] = _mm_unpackhi_epi64( s0[12], s0[13] ); d[29] = _mm_unpackhi_epi64( s0[14], s0[15] ); d[30] = _mm_unpackhi_epi64( s1[12], s1[13] ); d[31] = _mm_unpackhi_epi64( s1[14], s1[15] ); if ( bit_len <= 512 ) return; d[32] = _mm_unpacklo_epi64( s0[16], s0[17] ); d[33] = _mm_unpacklo_epi64( s0[18], s0[19] ); d[34] = _mm_unpacklo_epi64( s1[16], s1[17] ); d[35] = _mm_unpacklo_epi64( s1[18], s1[19] ); d[36] = _mm_unpackhi_epi64( s0[16], s0[17] ); d[37] = _mm_unpackhi_epi64( s0[18], s0[19] ); d[38] = _mm_unpackhi_epi64( s1[16], s1[17] ); d[39] = _mm_unpackhi_epi64( s1[18], s1[19] ); if ( bit_len <= 640 ) return; d[40] = _mm_unpacklo_epi64( s0[20], s0[21] ); d[41] = _mm_unpacklo_epi64( s0[22], s0[23] ); d[42] = _mm_unpacklo_epi64( s1[20], s1[21] ); d[43] = _mm_unpacklo_epi64( s1[22], s1[23] ); d[44] = _mm_unpackhi_epi64( s0[20], s0[21] ); d[45] = _mm_unpackhi_epi64( s0[22], s0[23] ); d[46] = _mm_unpackhi_epi64( s1[20], s1[21] ); d[47] = _mm_unpackhi_epi64( s1[22], s1[23] ); d[48] = _mm_unpacklo_epi64( s0[24], s0[25] ); d[49] = _mm_unpacklo_epi64( s0[26], s0[27] ); d[50] = _mm_unpacklo_epi64( s1[24], s1[25] ); d[51] = _mm_unpacklo_epi64( s1[26], s1[27] ); d[52] = _mm_unpackhi_epi64( s0[24], s0[25] ); d[53] = _mm_unpackhi_epi64( s0[26], s0[27] ); d[54] = _mm_unpackhi_epi64( s1[24], s1[25] ); d[55] = _mm_unpackhi_epi64( s1[26], s1[27] ); d[56] = _mm_unpacklo_epi64( s0[28], s0[29] ); d[57] = _mm_unpacklo_epi64( s0[30], s0[31] ); d[58] = _mm_unpacklo_epi64( s1[28], s1[29] ); d[59] = _mm_unpacklo_epi64( s1[30], s1[31] ); d[60] = _mm_unpackhi_epi64( s0[28], s0[29] ); d[61] = _mm_unpackhi_epi64( s0[30], s0[31] ); d[62] = _mm_unpackhi_epi64( s1[28], s1[29] ); d[63] = _mm_unpackhi_epi64( s1[30], s1[31] ); } // 8x64 -> 4x128 static inline void rintrlv_8x64_4x128( void *dst0, void *dst1, const void *src, const int bit_len ) { __m128i *d0 = (__m128i*)dst0; __m128i *d1 = (__m128i*)dst1; const __m128i* s = (const __m128i*)src; d0[ 0] = _mm_unpacklo_epi64( s[ 0], s[ 4] ); d0[ 1] = _mm_unpackhi_epi64( s[ 0], s[ 4] ); d1[ 0] = _mm_unpacklo_epi64( s[ 2], s[ 6] ); d1[ 1] = _mm_unpackhi_epi64( s[ 2], s[ 6] ); d0[ 2] = _mm_unpacklo_epi64( s[ 1], s[ 5] ); d0[ 3] = _mm_unpackhi_epi64( s[ 1], s[ 5] ); d1[ 2] = _mm_unpacklo_epi64( s[ 3], s[ 7] ); d1[ 3] = _mm_unpackhi_epi64( s[ 3], s[ 7] ); d0[ 4] = _mm_unpacklo_epi64( s[ 8], s[12] ); d0[ 5] = _mm_unpackhi_epi64( s[ 8], s[12] ); d1[ 4] = _mm_unpacklo_epi64( s[10], s[14] ); d1[ 5] = _mm_unpackhi_epi64( s[10], s[14] ); d0[ 6] = _mm_unpacklo_epi64( s[ 9], s[13] ); d0[ 7] = _mm_unpackhi_epi64( s[ 9], s[13] ); d1[ 6] = _mm_unpacklo_epi64( s[11], s[15] ); d1[ 7] = _mm_unpackhi_epi64( s[11], s[15] ); if ( bit_len <= 256 ) return; d0[ 8] = _mm_unpacklo_epi64( s[16], s[20] ); d0[ 9] = _mm_unpackhi_epi64( s[16], s[20] ); d1[ 8] = _mm_unpacklo_epi64( s[18], s[22] ); d1[ 9] = _mm_unpackhi_epi64( s[18], s[22] ); d0[10] = _mm_unpacklo_epi64( s[17], s[21] ); d0[11] = _mm_unpackhi_epi64( s[17], s[21] ); d1[10] = _mm_unpacklo_epi64( s[19], s[23] ); d1[11] = _mm_unpackhi_epi64( s[19], s[23] ); d0[12] = _mm_unpacklo_epi64( s[24], s[28] ); d0[13] = _mm_unpackhi_epi64( s[24], s[28] ); d1[12] = _mm_unpacklo_epi64( s[26], s[30] ); d1[13] = _mm_unpackhi_epi64( s[26], s[30] ); d0[14] = _mm_unpacklo_epi64( s[25], s[29] ); d0[15] = _mm_unpackhi_epi64( s[25], s[29] ); d1[14] = _mm_unpacklo_epi64( s[27], s[31] ); d1[15] = _mm_unpackhi_epi64( s[27], s[31] ); if ( bit_len <= 512 ) return; d0[16] = _mm_unpacklo_epi64( s[32], s[36] ); d0[17] = _mm_unpackhi_epi64( s[32], s[36] ); d1[16] = _mm_unpacklo_epi64( s[34], s[38] ); d1[17] = _mm_unpackhi_epi64( s[34], s[38] ); d0[18] = _mm_unpacklo_epi64( s[33], s[37] ); d0[19] = _mm_unpackhi_epi64( s[33], s[37] ); d1[18] = _mm_unpacklo_epi64( s[35], s[39] ); d1[19] = _mm_unpackhi_epi64( s[35], s[39] ); if ( bit_len <= 640 ) return; d0[20] = _mm_unpacklo_epi64( s[40], s[44] ); d0[21] = _mm_unpackhi_epi64( s[40], s[44] ); d1[20] = _mm_unpacklo_epi64( s[42], s[46] ); d1[21] = _mm_unpackhi_epi64( s[42], s[46] ); d0[22] = _mm_unpacklo_epi64( s[41], s[45] ); d0[23] = _mm_unpackhi_epi64( s[41], s[45] ); d1[22] = _mm_unpacklo_epi64( s[43], s[47] ); d1[23] = _mm_unpackhi_epi64( s[43], s[47] ); d0[24] = _mm_unpacklo_epi64( s[48], s[52] ); d0[25] = _mm_unpackhi_epi64( s[48], s[52] ); d1[24] = _mm_unpacklo_epi64( s[50], s[54] ); d1[25] = _mm_unpackhi_epi64( s[50], s[54] ); d0[26] = _mm_unpacklo_epi64( s[49], s[53] ); d0[27] = _mm_unpackhi_epi64( s[49], s[53] ); d1[26] = _mm_unpacklo_epi64( s[51], s[55] ); d1[27] = _mm_unpackhi_epi64( s[51], s[55] ); d0[28] = _mm_unpacklo_epi64( s[56], s[60] ); d0[29] = _mm_unpackhi_epi64( s[56], s[60] ); d1[28] = _mm_unpacklo_epi64( s[58], s[62] ); d1[29] = _mm_unpackhi_epi64( s[58], s[62] ); d0[30] = _mm_unpacklo_epi64( s[57], s[61] ); d0[31] = _mm_unpackhi_epi64( s[57], s[61] ); d1[30] = _mm_unpacklo_epi64( s[59], s[63] ); d1[31] = _mm_unpackhi_epi64( s[59], s[63] ); } // 8x64 -> 2x256 static inline void rintrlv_8x64_2x256( void *dst0, void *dst1, void *dst2, void *dst3, const void *src, const int bit_len ) { __m128i *d0 = (__m128i*)dst0; __m128i *d1 = (__m128i*)dst1; __m128i *d2 = (__m128i*)dst2; __m128i *d3 = (__m128i*)dst3; const __m128i* s = (const __m128i*)src; d0[ 0] = _mm_unpacklo_epi64( s[ 0], s[ 4] ); d1[ 0] = _mm_unpackhi_epi64( s[ 0], s[ 4] ); d2[ 0] = _mm_unpacklo_epi64( s[ 1], s[ 5] ); d3[ 0] = _mm_unpackhi_epi64( s[ 1], s[ 5] ); d0[ 1] = _mm_unpacklo_epi64( s[ 2], s[ 6] ); d1[ 1] = _mm_unpackhi_epi64( s[ 2], s[ 6] ); d2[ 1] = _mm_unpacklo_epi64( s[ 3], s[ 7] ); d3[ 1] = _mm_unpackhi_epi64( s[ 3], s[ 7] ); d0[ 2] = _mm_unpacklo_epi64( s[ 8], s[12] ); d1[ 2] = _mm_unpackhi_epi64( s[ 8], s[12] ); d2[ 2] = _mm_unpacklo_epi64( s[ 9], s[13] ); d3[ 2] = _mm_unpackhi_epi64( s[ 9], s[13] ); d0[ 3] = _mm_unpacklo_epi64( s[10], s[14] ); d1[ 3] = _mm_unpackhi_epi64( s[10], s[14] ); d2[ 3] = _mm_unpacklo_epi64( s[11], s[15] ); d3[ 3] = _mm_unpackhi_epi64( s[11], s[15] ); if ( bit_len <= 256 ) return; d0[ 4] = _mm_unpacklo_epi64( s[16], s[20] ); d1[ 4] = _mm_unpackhi_epi64( s[16], s[20] ); d2[ 4] = _mm_unpacklo_epi64( s[17], s[21] ); d3[ 4] = _mm_unpackhi_epi64( s[17], s[21] ); d0[ 5] = _mm_unpacklo_epi64( s[18], s[22] ); d1[ 5] = _mm_unpackhi_epi64( s[18], s[22] ); d2[ 5] = _mm_unpacklo_epi64( s[19], s[23] ); d3[ 5] = _mm_unpackhi_epi64( s[19], s[23] ); d0[ 6] = _mm_unpacklo_epi64( s[24], s[28] ); d1[ 6] = _mm_unpackhi_epi64( s[24], s[28] ); d2[ 6] = _mm_unpacklo_epi64( s[25], s[29] ); d3[ 6] = _mm_unpackhi_epi64( s[25], s[29] ); d0[ 7] = _mm_unpacklo_epi64( s[26], s[30] ); d1[ 7] = _mm_unpackhi_epi64( s[26], s[30] ); d2[ 7] = _mm_unpacklo_epi64( s[27], s[31] ); d3[ 7] = _mm_unpackhi_epi64( s[27], s[31] ); if ( bit_len <= 512 ) return; d0[ 8] = _mm_unpacklo_epi64( s[32], s[36] ); d1[ 8] = _mm_unpackhi_epi64( s[32], s[36] ); d2[ 8] = _mm_unpacklo_epi64( s[33], s[37] ); d3[ 8] = _mm_unpackhi_epi64( s[33], s[37] ); d0[ 9] = _mm_unpacklo_epi64( s[34], s[38] ); d1[ 9] = _mm_unpackhi_epi64( s[34], s[38] ); d2[ 9] = _mm_unpacklo_epi64( s[35], s[39] ); d3[ 9] = _mm_unpackhi_epi64( s[35], s[39] ); if ( bit_len <= 640 ) return; d0[10] = _mm_unpacklo_epi64( s[40], s[44] ); d1[10] = _mm_unpackhi_epi64( s[40], s[44] ); d2[10] = _mm_unpacklo_epi64( s[41], s[45] ); d3[10] = _mm_unpackhi_epi64( s[41], s[45] ); d0[11] = _mm_unpacklo_epi64( s[42], s[46] ); d1[11] = _mm_unpackhi_epi64( s[42], s[46] ); d2[11] = _mm_unpacklo_epi64( s[43], s[47] ); d3[11] = _mm_unpackhi_epi64( s[43], s[47] ); d0[12] = _mm_unpacklo_epi64( s[48], s[52] ); d1[12] = _mm_unpackhi_epi64( s[48], s[52] ); d2[12] = _mm_unpacklo_epi64( s[49], s[53] ); d3[12] = _mm_unpackhi_epi64( s[49], s[53] ); d0[13] = _mm_unpacklo_epi64( s[50], s[54] ); d1[13] = _mm_unpackhi_epi64( s[50], s[54] ); d2[13] = _mm_unpacklo_epi64( s[51], s[55] ); d3[13] = _mm_unpackhi_epi64( s[51], s[55] ); d0[14] = _mm_unpacklo_epi64( s[56], s[60] ); d1[14] = _mm_unpackhi_epi64( s[56], s[60] ); d2[14] = _mm_unpacklo_epi64( s[57], s[61] ); d3[14] = _mm_unpackhi_epi64( s[57], s[61] ); d0[15] = _mm_unpacklo_epi64( s[58], s[62] ); d1[15] = _mm_unpackhi_epi64( s[58], s[62] ); d2[15] = _mm_unpacklo_epi64( s[59], s[63] ); d3[15] = _mm_unpackhi_epi64( s[59], s[63] ); } // 4x128 -> 8x64 static inline void rintrlv_2x256_8x64( void *dst, const void *src0, const void *src1, const void *src2, const void *src3, const int bit_len ) { __m128i *d = (__m128i*)dst; __m128i *s0 = (__m128i*)src0; __m128i *s1 = (__m128i*)src1; __m128i *s2 = (__m128i*)src2; __m128i *s3 = (__m128i*)src3; d[ 0] = _mm_unpacklo_epi64( s0[0], s0[2] ); d[ 1] = _mm_unpacklo_epi64( s1[0], s1[2] ); d[ 2] = _mm_unpacklo_epi64( s2[0], s2[2] ); d[ 3] = _mm_unpacklo_epi64( s3[0], s3[2] ); d[ 4] = _mm_unpackhi_epi64( s0[0], s0[2] ); d[ 5] = _mm_unpackhi_epi64( s1[0], s1[2] ); d[ 6] = _mm_unpackhi_epi64( s2[0], s2[2] ); d[ 7] = _mm_unpackhi_epi64( s3[0], s3[2] ); d[ 8] = _mm_unpacklo_epi64( s0[1], s0[3] ); d[ 9] = _mm_unpacklo_epi64( s1[1], s1[3] ); d[10] = _mm_unpacklo_epi64( s2[1], s2[3] ); d[11] = _mm_unpacklo_epi64( s3[1], s3[3] ); d[12] = _mm_unpackhi_epi64( s0[1], s0[3] ); d[13] = _mm_unpackhi_epi64( s1[1], s1[3] ); d[14] = _mm_unpackhi_epi64( s2[1], s2[3] ); d[15] = _mm_unpackhi_epi64( s3[1], s3[3] ); if ( bit_len <= 256 ) return; d[16] = _mm_unpacklo_epi64( s0[4], s0[6] ); d[17] = _mm_unpacklo_epi64( s1[4], s1[6] ); d[18] = _mm_unpacklo_epi64( s2[4], s2[6] ); d[19] = _mm_unpacklo_epi64( s3[4], s3[6] ); d[20] = _mm_unpackhi_epi64( s0[4], s0[6] ); d[21] = _mm_unpackhi_epi64( s1[4], s1[6] ); d[22] = _mm_unpackhi_epi64( s2[4], s2[6] ); d[23] = _mm_unpackhi_epi64( s3[4], s3[6] ); d[24] = _mm_unpacklo_epi64( s0[5], s0[7] ); d[25] = _mm_unpacklo_epi64( s1[5], s1[7] ); d[26] = _mm_unpacklo_epi64( s2[5], s2[7] ); d[27] = _mm_unpacklo_epi64( s3[5], s3[7] ); d[28] = _mm_unpackhi_epi64( s0[5], s0[7] ); d[29] = _mm_unpackhi_epi64( s1[5], s1[7] ); d[30] = _mm_unpackhi_epi64( s2[5], s2[7] ); d[31] = _mm_unpackhi_epi64( s3[5], s3[7] ); if ( bit_len <= 512 ) return; d[32] = _mm_unpacklo_epi64( s0[8], s0[10] ); d[33] = _mm_unpacklo_epi64( s1[8], s1[10] ); d[34] = _mm_unpacklo_epi64( s2[8], s2[10] ); d[35] = _mm_unpacklo_epi64( s3[8], s3[10] ); d[36] = _mm_unpackhi_epi64( s0[8], s0[10] ); d[37] = _mm_unpackhi_epi64( s1[8], s1[10] ); d[38] = _mm_unpackhi_epi64( s2[8], s2[10] ); d[39] = _mm_unpackhi_epi64( s3[8], s3[10] ); if ( bit_len <= 640 ) return; d[40] = _mm_unpacklo_epi64( s0[9], s0[11] ); d[41] = _mm_unpacklo_epi64( s1[9], s1[11] ); d[42] = _mm_unpacklo_epi64( s2[9], s2[11] ); d[43] = _mm_unpacklo_epi64( s3[9], s3[11] ); d[44] = _mm_unpackhi_epi64( s0[9], s0[11] ); d[45] = _mm_unpackhi_epi64( s1[9], s1[11] ); d[46] = _mm_unpackhi_epi64( s2[9], s2[11] ); d[47] = _mm_unpackhi_epi64( s3[9], s3[11] ); d[48] = _mm_unpacklo_epi64( s0[12], s0[14] ); d[49] = _mm_unpacklo_epi64( s1[12], s1[14] ); d[50] = _mm_unpacklo_epi64( s2[12], s2[14] ); d[51] = _mm_unpacklo_epi64( s3[12], s3[14] ); d[52] = _mm_unpackhi_epi64( s0[12], s0[14] ); d[53] = _mm_unpackhi_epi64( s1[12], s1[14] ); d[54] = _mm_unpackhi_epi64( s2[12], s2[14] ); d[55] = _mm_unpackhi_epi64( s3[12], s3[14] ); d[56] = _mm_unpacklo_epi64( s0[13], s0[15] ); d[57] = _mm_unpacklo_epi64( s1[13], s1[15] ); d[58] = _mm_unpacklo_epi64( s2[13], s2[15] ); d[59] = _mm_unpacklo_epi64( s3[13], s3[15] ); d[60] = _mm_unpackhi_epi64( s0[13], s0[15] ); d[61] = _mm_unpackhi_epi64( s1[13], s1[15] ); d[62] = _mm_unpackhi_epi64( s2[13], s2[15] ); d[63] = _mm_unpackhi_epi64( s3[13], s3[15] ); } // // Some functions customized for mining. // blend 2 vectors while interleaving: { hi[n], lo[n-1], ... hi[1], lo[0] } #if defined(__SSE4_1__) // No SSE2 implementation. //#define mm128_intrlv_blend_64( hi, lo ) _mm_blend_epi16( hi, lo, 0x0f ) //#define mm128_intrlv_blend_32( hi, lo ) _mm_blend_epi16( hi, lo, 0x33 ) #endif // SSE4_1 #if defined(__AVX2__) //#define mm256_intrlv_blend_128( hi, lo ) _mm256_blend_epi32( hi, lo, 0x0f ) //#define mm256_intrlv_blend_64( hi, lo ) _mm256_blend_epi32( hi, lo, 0x33 ) #define mm256_intrlv_blend_32( hi, lo ) _mm256_blend_epi32( hi, lo, 0x55 ) // change to _mm256_blend_epi32 // // Select lanes of 32 byte hash from 2 sources according to control mask. // macro due to 256 bit value arg. #define mm256_blend_hash_4x64( dst, a, b, mask ) \ do { \ dst[0] = _mm256_blendv_epi8( a[0], b[0], mask ); \ dst[1] = _mm256_blendv_epi8( a[1], b[1], mask ); \ dst[2] = _mm256_blendv_epi8( a[2], b[2], mask ); \ dst[3] = _mm256_blendv_epi8( a[3], b[3], mask ); \ dst[4] = _mm256_blendv_epi8( a[4], b[4], mask ); \ dst[5] = _mm256_blendv_epi8( a[5], b[5], mask ); \ dst[6] = _mm256_blendv_epi8( a[6], b[6], mask ); \ dst[7] = _mm256_blendv_epi8( a[7], b[7], mask ); \ } while(0) #endif // AVX2 #if defined(__AVX512F__) && defined(__AVX512VL__) && defined(__AVX512DQ__) && defined(__AVX512BW__) /* #define mm512_intrlv_blend_128( hi, lo ) \ _mm512_mask_blend_epi32( 0x0f0f, hi, lo ) #define mm512_intrlv_blend_64( hi, lo ) \ _mm512_mask_blend_epi32( 0x3333, hi, lo ) */ #define mm512_intrlv_blend_32( hi, lo ) \ _mm512_mask_blend_epi32( 0x5555, hi, lo ) #define mm512_blend_hash_8x64( dst, a, b, mask ) \ do { \ dst[0] = _mm512_mask_blend_epi64( mask, a[0], b[0] ); \ dst[1] = _mm512_mask_blend_epi64( mask, a[1], b[1] ); \ dst[2] = _mm512_mask_blend_epi64( mask, a[2], b[2] ); \ dst[3] = _mm512_mask_blend_epi64( mask, a[3], b[3] ); \ dst[4] = _mm512_mask_blend_epi64( mask, a[4], b[4] ); \ dst[5] = _mm512_mask_blend_epi64( mask, a[5], b[5] ); \ dst[6] = _mm512_mask_blend_epi64( mask, a[6], b[6] ); \ dst[7] = _mm512_mask_blend_epi64( mask, a[7], b[7] ); \ } while(0) #endif // AVX512 #endif // INTERLEAVE_H__