/***************************************************************************** * This file is part of Kvazaar HEVC encoder. * * Copyright (C) 2013-2015 Tampere University of Technology and others (see * COPYING file). * * Kvazaar is free software: you can redistribute it and/or modify it under * the terms of the GNU Lesser General Public License as published by the * Free Software Foundation; either version 2.1 of the License, or (at your * option) any later version. * * Kvazaar is distributed in the hope that it will be useful, but WITHOUT ANY * WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS * FOR A PARTICULAR PURPOSE. See the GNU Lesser General Public License for * more details. * * You should have received a copy of the GNU General Public License along * with Kvazaar. If not, see . ****************************************************************************/ /* * \file */ #include "strategies/avx2/quant-avx2.h" #if COMPILE_INTEL_AVX2 && defined X86_64 #include #include #include "avx2_common_functions.h" #include "cu.h" #include "encoder.h" #include "encoderstate.h" #include "kvazaar.h" #include "rdo.h" #include "scalinglist.h" #include "strategies/generic/quant-generic.h" #include "strategies/strategies-quant.h" #include "strategyselector.h" #include "tables.h" #include "transform.h" static INLINE int32_t hsum32_8x32i(__m256i src) { __m128i a = _mm256_extracti128_si256(src, 0); __m128i b = _mm256_extracti128_si256(src, 1); a = _mm_add_epi32(a, b); b = _mm_shuffle_epi32(a, _MM_SHUFFLE(0, 1, 2, 3)); a = _mm_add_epi32(a, b); b = _mm_shuffle_epi32(a, _MM_SHUFFLE(2, 3, 0, 1)); a = _mm_add_epi32(a, b); return _mm_cvtsi128_si32(a); } static INLINE int32_t hsum32_16x16i(__m256i src) { __m128i a = _mm256_extracti128_si256(src, 0); __m128i b = _mm256_extracti128_si256(src, 1); __m256i c = _mm256_cvtepi16_epi32(a); __m256i d = _mm256_cvtepi16_epi32(b); c = _mm256_add_epi32(c, d); return hsum32_8x32i(c); } // Rearranges a 16x32b double vector into a format suitable for a stable SIMD // max algorithm: // (abcd|efgh) (ijkl|mnop) => (aceg|ikmo) (bdfh|jlnp) static INLINE void rearrange_512(__m256i *hi, __m256i *lo) { const __m256i perm8x32mask = _mm256_setr_epi32(0, 2, 4, 6, 1, 3, 5, 7); __m256i tmphi = _mm256_permutevar8x32_epi32(*hi, perm8x32mask); __m256i tmplo = _mm256_permutevar8x32_epi32(*lo, perm8x32mask); *hi = _mm256_permute2x128_si256(tmplo, tmphi, 0x31); *lo = _mm256_permute2x128_si256(tmplo, tmphi, 0x20); } static INLINE void get_cheapest_alternative(__m256i costs_hi, __m256i costs_lo, __m256i ns, __m256i changes, int16_t *final_change, int32_t *min_pos) { // Interleave ns and lo into 32-bit variables and to two 256-bit wide vecs, // to have the same data layout as in costs. Zero extend to 32b width, shift // changes 16 bits to the left, and store them into the same vectors. __m256i tmp1hi = _mm256_unpackhi_epi16(ns, changes); __m256i tmp1lo = _mm256_unpacklo_epi16(ns, changes); __m256i pl1hi = _mm256_permute2x128_si256(tmp1lo, tmp1hi, 0x31); __m256i pl1lo = _mm256_permute2x128_si256(tmp1lo, tmp1hi, 0x20); // Reorder to afford result stability (if multiple atoms tie for cheapest, // rightmost ie. the highest is the wanted one) rearrange_512(&costs_hi, &costs_lo); rearrange_512(&pl1hi, &pl1lo); // 0: pick hi, 1: pick lo (equality evaluates as 0) __m256i cmpmask1 = _mm256_cmpgt_epi32(costs_hi, costs_lo); __m256i cost1 = _mm256_blendv_epi8(costs_hi, costs_lo, cmpmask1); __m256i pl1_1 = _mm256_blendv_epi8(pl1hi, pl1lo, cmpmask1); __m256i cost2 = _mm256_shuffle_epi32(cost1, _MM_SHUFFLE(2, 3, 0, 1)); __m256i pl1_2 = _mm256_shuffle_epi32(pl1_1, _MM_SHUFFLE(2, 3, 0, 1)); __m256i cmpmask2 = _mm256_cmpgt_epi32(cost2, cost1); __m256i cost3 = _mm256_blendv_epi8(cost2, cost1, cmpmask2); __m256i pl1_3 = _mm256_blendv_epi8(pl1_2, pl1_1, cmpmask2); __m256i cost4 = _mm256_shuffle_epi32(cost3, _MM_SHUFFLE(1, 0, 3, 2)); __m256i pl1_4 = _mm256_shuffle_epi32(pl1_3, _MM_SHUFFLE(1, 0, 3, 2)); __m256i cmpmask3 = _mm256_cmpgt_epi32(cost4, cost3); __m256i cost5 = _mm256_blendv_epi8(cost4, cost3, cmpmask3); __m256i pl1_5 = _mm256_blendv_epi8(pl1_4, pl1_3, cmpmask3); __m256i cost6 = _mm256_permute4x64_epi64(cost5, _MM_SHUFFLE(1, 0, 3, 2)); __m256i pl1_6 = _mm256_permute4x64_epi64(pl1_5, _MM_SHUFFLE(1, 0, 3, 2)); __m256i cmpmask4 = _mm256_cmpgt_epi32(cost6, cost5); __m256i pl1_7 = _mm256_blendv_epi8(pl1_6, pl1_5, cmpmask4); __m128i res1_128 = _mm256_castsi256_si128(pl1_7); uint32_t tmp1 = (uint32_t)_mm_extract_epi32(res1_128, 0); uint16_t n = (uint16_t)(tmp1 & 0xffff); uint16_t chng = (uint16_t)(tmp1 >> 16); *final_change = (int16_t)chng; *min_pos = (int32_t)n; } static INLINE __m256i concatenate_2x128i(__m128i lo, __m128i hi) { __m256i v = _mm256_castsi128_si256(lo); return _mm256_inserti128_si256(v, hi, 1); } static INLINE void scanord_read_vector_32(const int32_t *__restrict quant_coeff, const uint32_t *__restrict scan, int8_t scan_mode, int32_t subpos, int32_t width, __m256i *__restrict v_quant_coeffs) { const size_t row_offsets[4] = { scan[subpos] + width * 0, scan[subpos] + width * 1, scan[subpos] + width * 2, scan[subpos] + width * 3, }; const __m256i shufmasks[3] = { _mm256_setr_epi32(5, 2, 6, 0, 3, 7, 4, 1), _mm256_setr_epi32(0, 1, 2, 3, 4, 5, 6, 7), _mm256_setr_epi32(2, 3, 0, 1, 6, 7, 4, 5), }; const __m256i blend_masks[3] = { _mm256_setr_epi32( 0, 0, 0, -1, 0, 0, -1, -1), _mm256_setr_epi32( 0, 0, 0, 0, 0, 0, 0, 0), _mm256_setr_epi32( 0, 0, -1, -1, 0, 0, -1, -1), }; const __m256i rearr_masks_lo[3] = { _mm256_setr_epi32(0, 4, 1, 3, 5, 2, 6, 7), _mm256_setr_epi32(0, 1, 2, 3, 4, 5, 6, 7), _mm256_setr_epi32(0, 4, 2, 6, 1, 5, 3, 7), }; const __m256i rearr_masks_hi[3] = { _mm256_setr_epi32(6, 3, 0, 1, 7, 2, 4, 5), _mm256_setr_epi32(0, 1, 2, 3, 4, 5, 6, 7), _mm256_setr_epi32(2, 6, 0, 4, 3, 7, 1, 5), }; __m128i coeffs[4] = { _mm_loadu_si128((__m128i *)(quant_coeff + row_offsets[0])), _mm_loadu_si128((__m128i *)(quant_coeff + row_offsets[1])), _mm_loadu_si128((__m128i *)(quant_coeff + row_offsets[2])), _mm_loadu_si128((__m128i *)(quant_coeff + row_offsets[3])), }; __m256i coeffs_upper = concatenate_2x128i(coeffs[0], coeffs[1]); __m256i coeffs_lower = concatenate_2x128i(coeffs[2], coeffs[3]); __m256i lower_shuffled = _mm256_permutevar8x32_epi32(coeffs_lower, shufmasks[scan_mode]); __m256i upper_blended = _mm256_blendv_epi8(coeffs_upper, lower_shuffled, blend_masks[scan_mode]); __m256i lower_blended = _mm256_blendv_epi8(lower_shuffled, coeffs_upper, blend_masks[scan_mode]); __m256i result_lo = _mm256_permutevar8x32_epi32(upper_blended, rearr_masks_lo[scan_mode]); __m256i result_hi = _mm256_permutevar8x32_epi32(lower_blended, rearr_masks_hi[scan_mode]); v_quant_coeffs[0] = result_lo; v_quant_coeffs[1] = result_hi; } #define VEC_WIDTH 16 #define SCAN_SET_SIZE 16 #define LOG2_SCAN_SET_SIZE 4 static INLINE int32_t hide_block_sign(__m256i coefs, __m256i q_coefs, __m256i deltas_h, __m256i deltas_l, coeff_t * __restrict q_coef, const uint32_t * __restrict scan, int32_t subpos, int32_t last_cg) { assert(SCAN_SET_SIZE == 16); int32_t first_nz_pos_in_cg, last_nz_pos_in_cg; int32_t abssum = 0; // Find first and last nonzero coeffs get_first_last_nz_int16(q_coefs, &first_nz_pos_in_cg, &last_nz_pos_in_cg); // Sum all kvz_quant coeffs between first and last abssum = hsum32_16x16i(q_coefs); if (last_nz_pos_in_cg >= 0 && last_cg == -1) { last_cg = 1; } if (last_nz_pos_in_cg - first_nz_pos_in_cg >= 4) { uint32_t q_coef_signbits = _mm256_movemask_epi8(q_coefs); int32_t signbit = (q_coef_signbits >> (2 * first_nz_pos_in_cg + 1)) & 0x1; if (signbit != (abssum & 0x1)) { // compare signbit with sum_parity int32_t min_pos; int16_t final_change; int16_t cheapest_q; const int32_t mask_max = (last_cg == 1) ? last_nz_pos_in_cg : SCAN_SET_SIZE - 1; const __m256i zero = _mm256_setzero_si256(); const __m256i ones = _mm256_set1_epi16(1); const __m256i maxiters = _mm256_set1_epi16(mask_max); const __m256i ff = _mm256_set1_epi8(0xff); const __m256i fnpics = _mm256_set1_epi16((int16_t)first_nz_pos_in_cg); const __m256i ns = _mm256_setr_epi16(0, 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15); __m256i block_signbit = _mm256_set1_epi16(((int16_t)signbit) * -1); __m256i coef_signbits = _mm256_cmpgt_epi16(zero, coefs); __m256i signbits_equal_block = _mm256_cmpeq_epi16(coef_signbits, block_signbit); __m256i q_coefs_zero = _mm256_cmpeq_epi16(q_coefs, zero); __m256i dus_packed = _mm256_packs_epi32(deltas_l, deltas_h); __m256i dus_ordered = _mm256_permute4x64_epi64(dus_packed, _MM_SHUFFLE(3, 1, 2, 0)); __m256i dus_positive = _mm256_cmpgt_epi16(dus_ordered, zero); __m256i q_coef_abss = _mm256_abs_epi16(q_coefs); __m256i q_coefs_plusminus_one = _mm256_cmpeq_epi16(q_coef_abss, ones); __m256i eq_fnpics = _mm256_cmpeq_epi16(fnpics, ns); __m256i lt_fnpics = _mm256_cmpgt_epi16(fnpics, ns); __m256i maxcost_subcond1s = _mm256_and_si256(eq_fnpics, q_coefs_plusminus_one); __m256i maxcost_subcond2s = _mm256_andnot_si256(signbits_equal_block, lt_fnpics); __m256i elsecond1s_inv = _mm256_or_si256(dus_positive, maxcost_subcond1s); __m256i elsecond1s = _mm256_andnot_si256(elsecond1s_inv, ff); __m256i outside_maxiters = _mm256_cmpgt_epi16(ns, maxiters); __m256i negdelta_cond1s = _mm256_andnot_si256(q_coefs_zero, dus_positive); __m256i negdelta_cond2s = _mm256_andnot_si256(maxcost_subcond2s, q_coefs_zero); __m256i negdelta_mask16s_part1 = _mm256_or_si256(negdelta_cond1s, negdelta_cond2s); __m256i negdelta_mask16s = _mm256_andnot_si256(outside_maxiters, negdelta_mask16s_part1); __m256i posdelta_mask16s_part1 = _mm256_andnot_si256(q_coefs_zero, elsecond1s); __m256i posdelta_mask16s = _mm256_andnot_si256(outside_maxiters, posdelta_mask16s_part1); __m256i maxcost_cond1_parts = _mm256_andnot_si256(dus_positive, maxcost_subcond1s); __m256i maxcost_cond1s = _mm256_andnot_si256(q_coefs_zero, maxcost_cond1_parts); __m256i maxcost_cond2s = _mm256_and_si256(q_coefs_zero, maxcost_subcond2s); __m256i maxcost_mask16s_parts = _mm256_or_si256(maxcost_cond1s, maxcost_cond2s); __m256i maxcost_mask16s = _mm256_or_si256(maxcost_mask16s_parts, outside_maxiters); __m128i tmp_l, tmp_h; tmp_l = _mm256_extracti128_si256(negdelta_mask16s, 0); tmp_h = _mm256_extracti128_si256(negdelta_mask16s, 1); __m256i negdelta_mask32s_l = _mm256_cvtepi16_epi32(tmp_l); __m256i negdelta_mask32s_h = _mm256_cvtepi16_epi32(tmp_h); tmp_l = _mm256_extracti128_si256(posdelta_mask16s, 0); tmp_h = _mm256_extracti128_si256(posdelta_mask16s, 1); __m256i posdelta_mask32s_l = _mm256_cvtepi16_epi32(tmp_l); __m256i posdelta_mask32s_h = _mm256_cvtepi16_epi32(tmp_h); tmp_l = _mm256_extracti128_si256(maxcost_mask16s, 0); tmp_h = _mm256_extracti128_si256(maxcost_mask16s, 1); __m256i maxcost_mask32s_l = _mm256_cvtepi16_epi32(tmp_l); __m256i maxcost_mask32s_h = _mm256_cvtepi16_epi32(tmp_h); // Output value generation // cur_change_max: zero // cur_change_negdelta: ff // cur_change_posdelta: ones __m256i costs_negdelta_h = _mm256_sub_epi32(zero, deltas_h); __m256i costs_negdelta_l = _mm256_sub_epi32(zero, deltas_l); // costs_posdelta_l and _h: deltas_l and _h __m256i costs_max_lh = _mm256_set1_epi32(0x7fffffff); __m256i change_neg = _mm256_and_si256(negdelta_mask16s, ones); __m256i change_pos = _mm256_and_si256(posdelta_mask16s, ff); __m256i change_max = _mm256_and_si256(maxcost_mask16s, zero); __m256i cost_neg_l = _mm256_and_si256(negdelta_mask32s_l, costs_negdelta_l); __m256i cost_neg_h = _mm256_and_si256(negdelta_mask32s_h, costs_negdelta_h); __m256i cost_pos_l = _mm256_and_si256(posdelta_mask32s_l, deltas_l); __m256i cost_pos_h = _mm256_and_si256(posdelta_mask32s_h, deltas_h); __m256i cost_max_l = _mm256_and_si256(maxcost_mask32s_l, costs_max_lh); __m256i cost_max_h = _mm256_and_si256(maxcost_mask32s_h, costs_max_lh); __m256i changes = _mm256_or_si256(change_neg, _mm256_or_si256(change_pos, change_max)); __m256i costs_l = _mm256_or_si256(cost_neg_l, _mm256_or_si256(cost_pos_l, cost_max_l)); __m256i costs_h = _mm256_or_si256(cost_neg_h, _mm256_or_si256(cost_pos_h, cost_max_h)); get_cheapest_alternative(costs_h, costs_l, ns, changes, &final_change, &min_pos); const int32_t best_id = scan[min_pos + subpos]; cheapest_q = q_coef[best_id]; if (cheapest_q == 32767 || cheapest_q == -32768) final_change = -1; uint32_t coef_signs = _mm256_movemask_epi8(coef_signbits); uint32_t cheapest_coef_sign_mask = (uint32_t)(1 << (2 * min_pos)); if (!(coef_signs & cheapest_coef_sign_mask)) cheapest_q += final_change; else cheapest_q -= final_change; q_coef[best_id] = cheapest_q; } // Hide } if (last_cg == 1) last_cg = 0; return last_cg; } /** * \brief quantize transformed coefficents * */ void kvz_quant_avx2(const encoder_state_t * const state, const coeff_t * __restrict coef, coeff_t * __restrict q_coef, int32_t width, int32_t height, int8_t type, int8_t scan_idx, int8_t block_type) { const encoder_control_t * const encoder = state->encoder_control; //const uint32_t log2_block_size = kvz_g_convert_to_bit[width] + 2; //const uint32_t * const scan = kvz_g_sig_last_scan[scan_idx][log2_block_size - 1]; int32_t qp_scaled = kvz_get_scaled_qp(type, state->qp, (encoder->bitdepth - 8) * 6); const uint32_t log2_tr_size = kvz_g_convert_to_bit[width] + 2; const int32_t scalinglist_type = (block_type == CU_INTRA ? 0 : 3) + (int8_t)("\0\3\1\2"[type]); const int32_t *quant_coeff = encoder->scaling_list.quant_coeff[log2_tr_size - 2][scalinglist_type][qp_scaled % 6]; const int32_t transform_shift = MAX_TR_DYNAMIC_RANGE - encoder->bitdepth - log2_tr_size; //!< Represents scaling through forward transform const int32_t q_bits = QUANT_SHIFT + qp_scaled / 6 + transform_shift; const int32_t add = ((state->frame->slicetype == KVZ_SLICE_I) ? 171 : 85) << (q_bits - 9); //const int32_t q_bits8 = q_bits - 8; uint32_t ac_sum = 0; int32_t last_cg = -1; __m256i v_ac_sum = _mm256_setzero_si256(); // Loading once is enough if scaling lists are not off __m256i low_b = _mm256_setzero_si256(), high_b = _mm256_setzero_si256(); if (!(state->encoder_control->scaling_list.enable)) { low_b = _mm256_set1_epi32(quant_coeff[0]); high_b = low_b; } for (int32_t n = 0; n < width * height; n += VEC_WIDTH) { __m256i v_level = _mm256_loadu_si256((__m256i *)(coef + n)); __m256i v_sign = _mm256_cmpgt_epi16(_mm256_setzero_si256(), v_level); v_sign = _mm256_or_si256(v_sign, _mm256_set1_epi16(1)); if (state->encoder_control->scaling_list.enable) { __m256i v_quant_coeff_lo = _mm256_loadu_si256(((__m256i *)(quant_coeff + n)) + 0); __m256i v_quant_coeff_hi = _mm256_loadu_si256(((__m256i *)(quant_coeff + n)) + 1); low_b = _mm256_permute2x128_si256(v_quant_coeff_lo, v_quant_coeff_hi, 0x20); high_b = _mm256_permute2x128_si256(v_quant_coeff_lo, v_quant_coeff_hi, 0x31); } // TODO: do we need to have this? // #define CHECK_QUANT_COEFFS #ifdef CHECK_QUANT_COEFFS __m256i abs_vq_lo = _mm256_abs_epi32(v_quant_coeff_lo); __m256i abs_vq_hi = _mm256_abs_epi32(v_quant_coeff_hi); __m256i vq_over_16b_lo = _mm256_cmpgt_epi32(abs_vq_lo, _mm256_set1_epi32(0x7fff)); __m256i vq_over_16b_hi = _mm256_cmpgt_epi32(abs_vq_hi, _mm256_set1_epi32(0x7fff)); uint32_t over_16b_mask_lo = _mm256_movemask_epi8(vq_over_16b_lo); uint32_t over_16b_mask_hi = _mm256_movemask_epi8(vq_over_16b_hi); assert(!(over_16b_mask_lo || over_16b_mask_hi)); #endif v_level = _mm256_abs_epi16(v_level); __m256i low_a = _mm256_unpacklo_epi16(v_level, _mm256_setzero_si256()); __m256i high_a = _mm256_unpackhi_epi16(v_level, _mm256_setzero_si256()); __m256i v_level32_a = _mm256_mullo_epi32(low_a, low_b); __m256i v_level32_b = _mm256_mullo_epi32(high_a, high_b); v_level32_a = _mm256_add_epi32(v_level32_a, _mm256_set1_epi32(add)); v_level32_b = _mm256_add_epi32(v_level32_b, _mm256_set1_epi32(add)); v_level32_a = _mm256_srai_epi32(v_level32_a, q_bits); v_level32_b = _mm256_srai_epi32(v_level32_b, q_bits); v_level = _mm256_packs_epi32(v_level32_a, v_level32_b); v_level = _mm256_sign_epi16(v_level, v_sign); _mm256_storeu_si256((__m256i *)(q_coef + n), v_level); v_ac_sum = _mm256_add_epi32(v_ac_sum, v_level32_a); v_ac_sum = _mm256_add_epi32(v_ac_sum, v_level32_b); } __m128i temp = _mm_add_epi32(_mm256_castsi256_si128(v_ac_sum), _mm256_extracti128_si256(v_ac_sum, 1)); temp = _mm_add_epi32(temp, _mm_shuffle_epi32(temp, _MM_SHUFFLE(1, 0, 3, 2))); temp = _mm_add_epi32(temp, _mm_shuffle_epi32(temp, _MM_SHUFFLE(0, 1, 0, 1))); ac_sum += _mm_cvtsi128_si32(temp); /* // Signhiding disabled in VVC if (!encoder->cfg.signhide_enable || ac_sum < 2) return; assert(VEC_WIDTH == SCAN_SET_SIZE); for (int32_t subpos = (width * height - 1) & (~(VEC_WIDTH - 1)); subpos >= 0; subpos -= VEC_WIDTH) { const int16_t *coeffs[2] = {coef, q_coef}; __m256i result_coeffs[2]; __m256i v_quant_coeffs[2]; __m256i v_coef, q_coefs; __m256i v_quant_coeff_lo, v_quant_coeff_hi; scanord_read_vector(coeffs, scan, scan_idx, subpos, width, result_coeffs, 2); v_coef = result_coeffs[0]; q_coefs = result_coeffs[1]; if (state->encoder_control->scaling_list.enable) { scanord_read_vector_32(quant_coeff, scan, scan_idx, subpos, width, v_quant_coeffs); v_quant_coeff_lo = v_quant_coeffs[0]; v_quant_coeff_hi = v_quant_coeffs[1]; low_b = _mm256_permute2x128_si256(v_quant_coeff_lo, v_quant_coeff_hi, 0x20); high_b = _mm256_permute2x128_si256(v_quant_coeff_lo, v_quant_coeff_hi, 0x31); } __m256i v_level = _mm256_abs_epi16(v_coef); __m256i low_a = _mm256_unpacklo_epi16(v_level, _mm256_setzero_si256()); __m256i high_a = _mm256_unpackhi_epi16(v_level, _mm256_setzero_si256()); __m256i v_quant_coeff_a = _mm256_or_si256(low_b, _mm256_setzero_si256()); __m256i v_quant_coeff_b = _mm256_or_si256(high_b, _mm256_setzero_si256()); __m256i v_level32_a = _mm256_mullo_epi32(low_a, low_b); __m256i v_level32_b = _mm256_mullo_epi32(high_a, high_b); v_level32_a = _mm256_add_epi32(v_level32_a, _mm256_set1_epi32(add)); v_level32_b = _mm256_add_epi32(v_level32_b, _mm256_set1_epi32(add)); v_level32_a = _mm256_srai_epi32(v_level32_a, q_bits); v_level32_b = _mm256_srai_epi32(v_level32_b, q_bits); v_level = _mm256_packs_epi32(v_level32_a, v_level32_b); __m256i v_coef_a = _mm256_unpacklo_epi16(_mm256_abs_epi16(v_coef), _mm256_set1_epi16(0)); __m256i v_coef_b = _mm256_unpackhi_epi16(_mm256_abs_epi16(v_coef), _mm256_set1_epi16(0)); v_coef_a = _mm256_mullo_epi32(v_coef_a, v_quant_coeff_a); v_coef_b = _mm256_mullo_epi32(v_coef_b, v_quant_coeff_b); v_coef_a = _mm256_sub_epi32(v_coef_a, _mm256_slli_epi32(_mm256_unpacklo_epi16(v_level, _mm256_set1_epi16(0)), q_bits) ); v_coef_b = _mm256_sub_epi32(v_coef_b, _mm256_slli_epi32(_mm256_unpackhi_epi16(v_level, _mm256_set1_epi16(0)), q_bits) ); v_coef_a = _mm256_srai_epi32(v_coef_a, q_bits8); v_coef_b = _mm256_srai_epi32(v_coef_b, q_bits8); __m256i deltas_h = _mm256_permute2x128_si256(v_coef_a, v_coef_b, 0x31); __m256i deltas_l = _mm256_permute2x128_si256(v_coef_a, v_coef_b, 0x20); last_cg = hide_block_sign(v_coef, q_coefs, deltas_h, deltas_l, q_coef, scan, subpos, last_cg); } #undef VEC_WIDTH #undef SCAN_SET_SIZE #undef LOG2_SCAN_SET_SIZE */ } #if KVZ_BIT_DEPTH == 8 static INLINE __m128i get_residual_4x1_avx2(const uint8_t *a_in, const uint8_t *b_in){ __m128i a = _mm_cvtsi32_si128(*(int32_t*)a_in); __m128i b = _mm_cvtsi32_si128(*(int32_t*)b_in); __m128i diff = _mm_sub_epi16(_mm_cvtepu8_epi16(a), _mm_cvtepu8_epi16(b) ); return diff; } static INLINE __m128i get_residual_8x1_avx2(const uint8_t *a_in, const uint8_t *b_in){ __m128i a = _mm_cvtsi64_si128(*(int64_t*)a_in); __m128i b = _mm_cvtsi64_si128(*(int64_t*)b_in); __m128i diff = _mm_sub_epi16(_mm_cvtepu8_epi16(a), _mm_cvtepu8_epi16(b) ); return diff; } static INLINE int32_t get_quantized_recon_4x1_avx2(int16_t *residual, const uint8_t *pred_in){ __m128i res = _mm_loadl_epi64((__m128i*)residual); __m128i pred = _mm_cvtsi32_si128(*(int32_t*)pred_in); __m128i rec = _mm_add_epi16(res, _mm_cvtepu8_epi16(pred)); return _mm_cvtsi128_si32(_mm_packus_epi16(rec, rec)); } static INLINE int64_t get_quantized_recon_8x1_avx2(int16_t *residual, const uint8_t *pred_in){ __m128i res = _mm_loadu_si128((__m128i*)residual); __m128i pred = _mm_cvtsi64_si128(*(int64_t*)pred_in); __m128i rec = _mm_add_epi16(res, _mm_cvtepu8_epi16(pred)); return _mm_cvtsi128_si64(_mm_packus_epi16(rec, rec)); } static void get_residual_avx2(const uint8_t *ref_in, const uint8_t *pred_in, int16_t *residual, int width, int in_stride){ __m128i diff = _mm_setzero_si128(); switch (width) { case 4: diff = get_residual_4x1_avx2(ref_in + 0 * in_stride, pred_in + 0 * in_stride); _mm_storel_epi64((__m128i*)&(residual[0]), diff); diff = get_residual_4x1_avx2(ref_in + 1 * in_stride, pred_in + 1 * in_stride); _mm_storel_epi64((__m128i*)&(residual[4]), diff); diff = get_residual_4x1_avx2(ref_in + 2 * in_stride, pred_in + 2 * in_stride); _mm_storel_epi64((__m128i*)&(residual[8]), diff); diff = get_residual_4x1_avx2(ref_in + 3 * in_stride, pred_in + 3 * in_stride); _mm_storel_epi64((__m128i*)&(residual[12]), diff); break; case 8: diff = get_residual_8x1_avx2(&ref_in[0 * in_stride], &pred_in[0 * in_stride]); _mm_storeu_si128((__m128i*)&(residual[0]), diff); diff = get_residual_8x1_avx2(&ref_in[1 * in_stride], &pred_in[1 * in_stride]); _mm_storeu_si128((__m128i*)&(residual[8]), diff); diff = get_residual_8x1_avx2(&ref_in[2 * in_stride], &pred_in[2 * in_stride]); _mm_storeu_si128((__m128i*)&(residual[16]), diff); diff = get_residual_8x1_avx2(&ref_in[3 * in_stride], &pred_in[3 * in_stride]); _mm_storeu_si128((__m128i*)&(residual[24]), diff); diff = get_residual_8x1_avx2(&ref_in[4 * in_stride], &pred_in[4 * in_stride]); _mm_storeu_si128((__m128i*)&(residual[32]), diff); diff = get_residual_8x1_avx2(&ref_in[5 * in_stride], &pred_in[5 * in_stride]); _mm_storeu_si128((__m128i*)&(residual[40]), diff); diff = get_residual_8x1_avx2(&ref_in[6 * in_stride], &pred_in[6 * in_stride]); _mm_storeu_si128((__m128i*)&(residual[48]), diff); diff = get_residual_8x1_avx2(&ref_in[7 * in_stride], &pred_in[7 * in_stride]); _mm_storeu_si128((__m128i*)&(residual[56]), diff); break; default: for (int y = 0; y < width; ++y) { for (int x = 0; x < width; x+=16) { diff = get_residual_8x1_avx2(&ref_in[x + y * in_stride], &pred_in[x + y * in_stride]); _mm_storeu_si128((__m128i*)&residual[x + y * width], diff); diff = get_residual_8x1_avx2(&ref_in[(x+8) + y * in_stride], &pred_in[(x+8) + y * in_stride]); _mm_storeu_si128((__m128i*)&residual[(x+8) + y * width], diff); } } break; } } static void get_quantized_recon_avx2(int16_t *residual, const uint8_t *pred_in, int in_stride, uint8_t *rec_out, int out_stride, int width){ switch (width) { case 4: *(int32_t*)&(rec_out[0 * out_stride]) = get_quantized_recon_4x1_avx2(residual + 0 * width, pred_in + 0 * in_stride); *(int32_t*)&(rec_out[1 * out_stride]) = get_quantized_recon_4x1_avx2(residual + 1 * width, pred_in + 1 * in_stride); *(int32_t*)&(rec_out[2 * out_stride]) = get_quantized_recon_4x1_avx2(residual + 2 * width, pred_in + 2 * in_stride); *(int32_t*)&(rec_out[3 * out_stride]) = get_quantized_recon_4x1_avx2(residual + 3 * width, pred_in + 3 * in_stride); break; case 8: *(int64_t*)&(rec_out[0 * out_stride]) = get_quantized_recon_8x1_avx2(residual + 0 * width, pred_in + 0 * in_stride); *(int64_t*)&(rec_out[1 * out_stride]) = get_quantized_recon_8x1_avx2(residual + 1 * width, pred_in + 1 * in_stride); *(int64_t*)&(rec_out[2 * out_stride]) = get_quantized_recon_8x1_avx2(residual + 2 * width, pred_in + 2 * in_stride); *(int64_t*)&(rec_out[3 * out_stride]) = get_quantized_recon_8x1_avx2(residual + 3 * width, pred_in + 3 * in_stride); *(int64_t*)&(rec_out[4 * out_stride]) = get_quantized_recon_8x1_avx2(residual + 4 * width, pred_in + 4 * in_stride); *(int64_t*)&(rec_out[5 * out_stride]) = get_quantized_recon_8x1_avx2(residual + 5 * width, pred_in + 5 * in_stride); *(int64_t*)&(rec_out[6 * out_stride]) = get_quantized_recon_8x1_avx2(residual + 6 * width, pred_in + 6 * in_stride); *(int64_t*)&(rec_out[7 * out_stride]) = get_quantized_recon_8x1_avx2(residual + 7 * width, pred_in + 7 * in_stride); break; default: for (int y = 0; y < width; ++y) { for (int x = 0; x < width; x += 16) { *(int64_t*)&(rec_out[x + y * out_stride]) = get_quantized_recon_8x1_avx2(residual + x + y * width, pred_in + x + y * in_stride); *(int64_t*)&(rec_out[(x + 8) + y * out_stride]) = get_quantized_recon_8x1_avx2(residual + (x + 8) + y * width, pred_in + (x + 8) + y * in_stride); } } break; } } /** * \brief Quantize residual and get both the reconstruction and coeffs. * * \param width Transform width. * \param color Color. * \param scan_order Coefficient scan order. * \param use_trskip Whether transform skip is used. * \param stride Stride for ref_in, pred_in and rec_out. * \param ref_in Reference pixels. * \param pred_in Predicted pixels. * \param rec_out Reconstructed pixels. * \param coeff_out Coefficients used for reconstruction of rec_out. * \param early_skip if this is used for early skip, bypass IT and IQ * * \returns Whether coeff_out contains any non-zero coefficients. */ int kvz_quantize_residual_avx2(encoder_state_t *const state, const cu_info_t *const cur_cu, const int width, const color_t color, const coeff_scan_order_t scan_order, const int use_trskip, const int in_stride, const int out_stride, const uint8_t *const ref_in, const uint8_t *const pred_in, uint8_t *rec_out, coeff_t *coeff_out, bool early_skip) { // Temporary arrays to pass data to and from kvz_quant and transform functions. ALIGNED(64) int16_t residual[TR_MAX_WIDTH * TR_MAX_WIDTH]; ALIGNED(64) coeff_t coeff[TR_MAX_WIDTH * TR_MAX_WIDTH]; int has_coeffs = 0; assert(width <= TR_MAX_WIDTH); assert(width >= TR_MIN_WIDTH); // Get residual. (ref_in - pred_in -> residual) get_residual_avx2(ref_in, pred_in, residual, width, in_stride); // Transform residual. (residual -> coeff) if (use_trskip) { kvz_transformskip(state->encoder_control, residual, coeff, width); } else { kvz_transform2d(state->encoder_control, residual, coeff, width, color, cur_cu); } // Quantize coeffs. (coeff -> coeff_out) if (state->encoder_control->cfg.rdoq_enable && (width > 4 || !state->encoder_control->cfg.rdoq_skip)) { int8_t tr_depth = cur_cu->tr_depth - cur_cu->depth; tr_depth += (cur_cu->part_size == SIZE_NxN ? 1 : 0); kvz_rdoq(state, coeff, coeff_out, width, width, (color == COLOR_Y ? 0 : 2), scan_order, cur_cu->type, tr_depth); } else { kvz_quant(state, coeff, coeff_out, width, width, (color == COLOR_Y ? 0 : 2), scan_order, cur_cu->type); } // Check if there are any non-zero coefficients. for (int i = 0; i < width * width; i += 8) { __m128i v_quant_coeff = _mm_loadu_si128((__m128i*)&(coeff_out[i])); has_coeffs = !_mm_testz_si128(_mm_set1_epi8(0xFF), v_quant_coeff); if(has_coeffs) break; } // Do the inverse quantization and transformation and the reconstruction to // rec_out. if (has_coeffs && !early_skip) { // Get quantized residual. (coeff_out -> coeff -> residual) kvz_dequant(state, coeff_out, coeff, width, width, (color == COLOR_Y ? 0 : (color == COLOR_U ? 2 : 3)), cur_cu->type); if (use_trskip) { kvz_itransformskip(state->encoder_control, residual, coeff, width); } else { kvz_itransform2d(state->encoder_control, residual, coeff, width, color, cur_cu); } // Get quantized reconstruction. (residual + pred_in -> rec_out) get_quantized_recon_avx2(residual, pred_in, in_stride, rec_out, out_stride, width); } else if (rec_out != pred_in) { // With no coeffs and rec_out == pred_int we skip copying the coefficients // because the reconstruction is just the prediction. int y, x; for (y = 0; y < width; ++y) { for (x = 0; x < width; ++x) { rec_out[x + y * out_stride] = pred_in[x + y * in_stride]; } } } return has_coeffs; } /** * \brief inverse quantize transformed and quantized coefficents * */ void kvz_dequant_avx2(const encoder_state_t * const state, coeff_t *q_coef, coeff_t *coef, int32_t width, int32_t height,int8_t type, int8_t block_type) { const encoder_control_t * const encoder = state->encoder_control; int32_t shift,add,coeff_q; int32_t n; int32_t transform_shift = 15 - encoder->bitdepth - (kvz_g_convert_to_bit[ width ] + 2); int32_t qp_scaled = kvz_get_scaled_qp(type, state->qp, (encoder->bitdepth-8)*6); shift = 20 - QUANT_SHIFT - transform_shift; if (encoder->scaling_list.enable) { uint32_t log2_tr_size = kvz_g_convert_to_bit[ width ] + 2; int32_t scalinglist_type = (block_type == CU_INTRA ? 0 : 3) + (int8_t)("\0\3\1\2"[type]); const int32_t *dequant_coef = encoder->scaling_list.de_quant_coeff[log2_tr_size-2][scalinglist_type][qp_scaled%6]; shift += 4; if (shift >qp_scaled / 6) { add = 1 << (shift - qp_scaled/6 - 1); for (n = 0; n < width * height; n++) { coeff_q = ((q_coef[n] * dequant_coef[n]) + add ) >> (shift - qp_scaled/6); coef[n] = (coeff_t)CLIP(-32768,32767,coeff_q); } } else { for (n = 0; n < width * height; n++) { // Clip to avoid possible overflow in following shift left operation coeff_q = CLIP(-32768, 32767, q_coef[n] * dequant_coef[n]); coef[n] = (coeff_t)CLIP(-32768, 32767, coeff_q << (qp_scaled/6 - shift)); } } } else { int32_t scale = kvz_g_inv_quant_scales[qp_scaled%6] << (qp_scaled/6); add = 1 << (shift-1); __m256i v_scale = _mm256_set1_epi32(scale); __m256i v_add = _mm256_set1_epi32(add); for (n = 0; n < width*height; n+=16) { __m128i temp0 = _mm_loadu_si128((__m128i*)&(q_coef[n])); __m128i temp1 = _mm_loadu_si128((__m128i*)&(q_coef[n + 8])); __m256i v_coeff_q_lo = _mm256_cvtepi16_epi32(_mm_unpacklo_epi64(temp0, temp1)); __m256i v_coeff_q_hi = _mm256_cvtepi16_epi32(_mm_unpackhi_epi64(temp0, temp1)); v_coeff_q_lo = _mm256_mullo_epi32(v_coeff_q_lo, v_scale); v_coeff_q_hi = _mm256_mullo_epi32(v_coeff_q_hi, v_scale); v_coeff_q_lo = _mm256_add_epi32(v_coeff_q_lo, v_add); v_coeff_q_hi = _mm256_add_epi32(v_coeff_q_hi, v_add); v_coeff_q_lo = _mm256_srai_epi32(v_coeff_q_lo, shift); v_coeff_q_hi = _mm256_srai_epi32(v_coeff_q_hi, shift); v_coeff_q_lo = _mm256_packs_epi32(v_coeff_q_lo, v_coeff_q_hi); _mm_storeu_si128((__m128i*)&(coef[n]), _mm256_castsi256_si128(v_coeff_q_lo) ); _mm_storeu_si128((__m128i*)&(coef[n + 8]), _mm256_extracti128_si256(v_coeff_q_lo, 1) ); } } } #endif // KVZ_BIT_DEPTH == 8 static uint32_t coeff_abs_sum_avx2(const coeff_t *coeffs, const size_t length) { assert(length % 8 == 0); __m256i total = _mm256_abs_epi32(_mm256_cvtepi16_epi32(_mm_loadu_si128((__m128i*) coeffs))); for (int i = 8; i < length; i += 8) { __m256i temp = _mm256_abs_epi32(_mm256_cvtepi16_epi32(_mm_loadu_si128((__m128i*) &coeffs[i]))); total = _mm256_add_epi32(total, temp); } __m128i result128 = _mm_add_epi32( _mm256_castsi256_si128(total), _mm256_extractf128_si256(total, 1) ); uint32_t parts[4]; _mm_storeu_si128((__m128i*) parts, result128); return parts[0] + parts[1] + parts[2] + parts[3]; } #define TO_Q88(f) ((int16_t)((f) * 256.0f)) static uint32_t fast_coeff_cost_avx2(const coeff_t *coeff, int32_t width, int32_t qp) { #define NUM_BUCKETS 5 static const int16_t wt_m[NUM_BUCKETS] = { TO_Q88(-0.004916), TO_Q88( 0.010806), TO_Q88( 0.055562), TO_Q88( 0.033436), TO_Q88(-0.007690), }; static const int16_t wt_c[NUM_BUCKETS] = { TO_Q88( 0.172024), TO_Q88( 3.421462), TO_Q88( 2.879506), TO_Q88( 5.585471), TO_Q88( 0.256772), }; const __m256i zero = _mm256_setzero_si256(); const __m256i threes = _mm256_set1_epi16(3); const __m256i ones = _mm256_srli_epi16(threes, 1); const __m256i twos = _mm256_slli_epi16(ones, 1); __m256i wt[NUM_BUCKETS - 1]; for (int32_t i = 0; i < NUM_BUCKETS - 1; i++) wt[i] = _mm256_set1_epi16(wt_m[i] * qp + wt_c[i]); uint32_t wid_wt = width * (wt_m[NUM_BUCKETS - 1] * qp + wt_c[NUM_BUCKETS - 1]); __m256i avx_inc = _mm256_setzero_si256(); for (int32_t i = 0; i < width * width; i += 16) { __m256i curr = _mm256_loadu_si256((__m256i *)(coeff + i)); __m256i curr_abs = _mm256_abs_epi16 (curr); __m256i curr_max3 = _mm256_min_epi16 (curr_abs, threes); __m256i curr_eq_0 = _mm256_cmpeq_epi16(curr_max3, zero); __m256i curr_eq_1 = _mm256_cmpeq_epi16(curr_max3, ones); __m256i curr_eq_2 = _mm256_cmpeq_epi16(curr_max3, twos); __m256i curr_eq_3 = _mm256_cmpeq_epi16(curr_max3, threes); __m256i curr_0_wt = _mm256_and_si256 (curr_eq_0, wt[0]); __m256i curr_1_wt = _mm256_and_si256 (curr_eq_1, wt[1]); __m256i curr_2_wt = _mm256_and_si256 (curr_eq_2, wt[2]); __m256i curr_3_wt = _mm256_and_si256 (curr_eq_3, wt[3]); // Use madd to horizontally sum 16-bit weights into 32-bit atoms __m256i wt_0_32b = _mm256_madd_epi16(curr_0_wt, ones); __m256i wt_1_32b = _mm256_madd_epi16(curr_1_wt, ones); __m256i wt_2_32b = _mm256_madd_epi16(curr_2_wt, ones); __m256i wt_3_32b = _mm256_madd_epi16(curr_3_wt, ones); __m256i wt_01 = _mm256_add_epi32(wt_0_32b, wt_1_32b); __m256i wt_23 = _mm256_add_epi32(wt_2_32b, wt_3_32b); __m256i curr_wts = _mm256_add_epi32(wt_01, wt_23); avx_inc = _mm256_add_epi32(avx_inc, curr_wts); } __m128i inchi = _mm256_extracti128_si256(avx_inc, 1); __m128i inclo = _mm256_castsi256_si128 (avx_inc); __m128i sum_1 = _mm_add_epi32 (inclo, inchi); __m128i sum_2 = _mm_shuffle_epi32(sum_1, _MM_SHUFFLE(1, 0, 3, 2)); __m128i sum_3 = _mm_add_epi32 (sum_1, sum_2); __m128i sum_4 = _mm_shuffle_epi32(sum_3, _MM_SHUFFLE(2, 3, 0, 1)); __m128i sum = _mm_add_epi32 (sum_3, sum_4); uint32_t sum_u32 = _mm_cvtsi128_si32(sum); uint32_t sum_total = sum_u32 + wid_wt; return sum_total >> 8; #undef NUM_BUCKETS } #undef TO_Q88 #endif //COMPILE_INTEL_AVX2 && defined X86_64 int kvz_strategy_register_quant_avx2(void* opaque, uint8_t bitdepth) { bool success = true; #if COMPILE_INTEL_AVX2 && defined X86_64 #if KVZ_BIT_DEPTH == 8 if (bitdepth == 8) { success &= kvz_strategyselector_register(opaque, "quantize_residual", "avx2", 40, &kvz_quantize_residual_avx2); success &= kvz_strategyselector_register(opaque, "dequant", "avx2", 40, &kvz_dequant_avx2); } #endif // KVZ_BIT_DEPTH == 8 success &= kvz_strategyselector_register(opaque, "quant", "avx2", 40, &kvz_quant_avx2); success &= kvz_strategyselector_register(opaque, "coeff_abs_sum", "avx2", 0, &coeff_abs_sum_avx2); success &= kvz_strategyselector_register(opaque, "fast_coeff_cost", "avx2", 40, &fast_coeff_cost_avx2); #endif //COMPILE_INTEL_AVX2 && defined X86_64 return success; }