/***************************************************************************** * 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/picture-avx2.h" #if COMPILE_INTEL_AVX2 #include #include #include "kvazaar.h" #include "strategies/strategies-picture.h" #include "strategyselector.h" #include "strategies/strategies-common.h" #include "strategies/generic/picture-generic.h" /** * \brief Calculate SAD for 8x8 bytes in continuous memory. */ static INLINE __m256i inline_8bit_sad_8x8_avx2(const __m256i *const a, const __m256i *const b) { __m256i sum0, sum1; sum0 = _mm256_sad_epu8(_mm256_load_si256(a + 0), _mm256_load_si256(b + 0)); sum1 = _mm256_sad_epu8(_mm256_load_si256(a + 1), _mm256_load_si256(b + 1)); return _mm256_add_epi32(sum0, sum1); } /** * \brief Calculate SAD for 16x16 bytes in continuous memory. */ static INLINE __m256i inline_8bit_sad_16x16_avx2(const __m256i *const a, const __m256i *const b) { const unsigned size_of_8x8 = 8 * 8 / sizeof(__m256i); // Calculate in 4 chunks of 16x4. __m256i sum0, sum1, sum2, sum3; sum0 = inline_8bit_sad_8x8_avx2(a + 0 * size_of_8x8, b + 0 * size_of_8x8); sum1 = inline_8bit_sad_8x8_avx2(a + 1 * size_of_8x8, b + 1 * size_of_8x8); sum2 = inline_8bit_sad_8x8_avx2(a + 2 * size_of_8x8, b + 2 * size_of_8x8); sum3 = inline_8bit_sad_8x8_avx2(a + 3 * size_of_8x8, b + 3 * size_of_8x8); sum0 = _mm256_add_epi32(sum0, sum1); sum2 = _mm256_add_epi32(sum2, sum3); return _mm256_add_epi32(sum0, sum2); } /** * \brief Get sum of the low 32 bits of four 64 bit numbers from __m256i as uint32_t. */ static INLINE uint32_t m256i_horizontal_sum(const __m256i sum) { // Add the high 128 bits to low 128 bits. __m128i mm128_result = _mm_add_epi32(_mm256_castsi256_si128(sum), _mm256_extractf128_si256(sum, 1)); // Add the high 64 bits to low 64 bits. uint32_t result[4]; _mm_storeu_si128((__m128i*)result, mm128_result); return result[0] + result[2]; } static unsigned sad_8bit_8x8_avx2(const kvz_pixel *buf1, const kvz_pixel *buf2) { const __m256i *const a = (const __m256i *)buf1; const __m256i *const b = (const __m256i *)buf2; __m256i sum = inline_8bit_sad_8x8_avx2(a, b); return m256i_horizontal_sum(sum); } static unsigned sad_8bit_16x16_avx2(const kvz_pixel *buf1, const kvz_pixel *buf2) { const __m256i *const a = (const __m256i *)buf1; const __m256i *const b = (const __m256i *)buf2; __m256i sum = inline_8bit_sad_16x16_avx2(a, b); return m256i_horizontal_sum(sum); } static unsigned sad_8bit_32x32_avx2(const kvz_pixel *buf1, const kvz_pixel *buf2) { const __m256i *const a = (const __m256i *)buf1; const __m256i *const b = (const __m256i *)buf2; const unsigned size_of_8x8 = 8 * 8 / sizeof(__m256i); const unsigned size_of_32x32 = 32 * 32 / sizeof(__m256i); // Looping 512 bytes at a time seems faster than letting VC figure it out // through inlining, like inline_8bit_sad_16x16_avx2 does. __m256i sum0 = inline_8bit_sad_8x8_avx2(a, b); for (unsigned i = size_of_8x8; i < size_of_32x32; i += size_of_8x8) { __m256i sum1 = inline_8bit_sad_8x8_avx2(a + i, b + i); sum0 = _mm256_add_epi32(sum0, sum1); } return m256i_horizontal_sum(sum0); } static unsigned sad_8bit_64x64_avx2(const kvz_pixel * buf1, const kvz_pixel * buf2) { const __m256i *const a = (const __m256i *)buf1; const __m256i *const b = (const __m256i *)buf2; const unsigned size_of_8x8 = 8 * 8 / sizeof(__m256i); const unsigned size_of_64x64 = 64 * 64 / sizeof(__m256i); // Looping 512 bytes at a time seems faster than letting VC figure it out // through inlining, like inline_8bit_sad_16x16_avx2 does. __m256i sum0 = inline_8bit_sad_8x8_avx2(a, b); for (unsigned i = size_of_8x8; i < size_of_64x64; i += size_of_8x8) { __m256i sum1 = inline_8bit_sad_8x8_avx2(a + i, b + i); sum0 = _mm256_add_epi32(sum0, sum1); } return m256i_horizontal_sum(sum0); } static unsigned satd_4x4_8bit_avx2(const kvz_pixel *org, const kvz_pixel *cur) { __m128i original = _mm_cvtepu8_epi16(_mm_loadl_epi64((__m128i*)org)); __m128i current = _mm_cvtepu8_epi16(_mm_loadl_epi64((__m128i*)cur)); __m128i diff_lo = _mm_sub_epi16(current, original); original = _mm_cvtepu8_epi16(_mm_loadl_epi64((__m128i*)(org + 8))); current = _mm_cvtepu8_epi16(_mm_loadl_epi64((__m128i*)(cur + 8))); __m128i diff_hi = _mm_sub_epi16(current, original); //Hor __m128i row0 = _mm_hadd_epi16(diff_lo, diff_hi); __m128i row1 = _mm_hsub_epi16(diff_lo, diff_hi); __m128i row2 = _mm_hadd_epi16(row0, row1); __m128i row3 = _mm_hsub_epi16(row0, row1); //Ver row0 = _mm_hadd_epi16(row2, row3); row1 = _mm_hsub_epi16(row2, row3); row2 = _mm_hadd_epi16(row0, row1); row3 = _mm_hsub_epi16(row0, row1); //Abs and sum row2 = _mm_abs_epi16(row2); row3 = _mm_abs_epi16(row3); row3 = _mm_add_epi16(row2, row3); row3 = _mm_add_epi16(row3, _mm_shuffle_epi32(row3, KVZ_PERMUTE(2, 3, 0, 1) )); row3 = _mm_add_epi16(row3, _mm_shuffle_epi32(row3, KVZ_PERMUTE(1, 0, 1, 0) )); row3 = _mm_add_epi16(row3, _mm_shufflelo_epi16(row3, KVZ_PERMUTE(1, 0, 1, 0) )); unsigned sum = _mm_extract_epi16(row3, 0); unsigned satd = (sum + 1) >> 1; return satd; } static void satd_8bit_4x4_dual_avx2( const pred_buffer preds, const kvz_pixel * const orig, unsigned num_modes, unsigned *satds_out) { __m256i original = _mm256_broadcastsi128_si256(_mm_cvtepu8_epi16(_mm_loadl_epi64((__m128i*)orig))); __m256i pred = _mm256_cvtepu8_epi16(_mm_loadl_epi64((__m128i*)preds[0])); pred = _mm256_inserti128_si256(pred, _mm_cvtepu8_epi16(_mm_loadl_epi64((__m128i*)preds[1])), 1); __m256i diff_lo = _mm256_sub_epi16(pred, original); original = _mm256_broadcastsi128_si256(_mm_cvtepu8_epi16(_mm_loadl_epi64((__m128i*)(orig + 8)))); pred = _mm256_cvtepu8_epi16(_mm_loadl_epi64((__m128i*)(preds[0] + 8))); pred = _mm256_inserti128_si256(pred, _mm_cvtepu8_epi16(_mm_loadl_epi64((__m128i*)(preds[1] + 8))), 1); __m256i diff_hi = _mm256_sub_epi16(pred, original); //Hor __m256i row0 = _mm256_hadd_epi16(diff_lo, diff_hi); __m256i row1 = _mm256_hsub_epi16(diff_lo, diff_hi); __m256i row2 = _mm256_hadd_epi16(row0, row1); __m256i row3 = _mm256_hsub_epi16(row0, row1); //Ver row0 = _mm256_hadd_epi16(row2, row3); row1 = _mm256_hsub_epi16(row2, row3); row2 = _mm256_hadd_epi16(row0, row1); row3 = _mm256_hsub_epi16(row0, row1); //Abs and sum row2 = _mm256_abs_epi16(row2); row3 = _mm256_abs_epi16(row3); row3 = _mm256_add_epi16(row2, row3); row3 = _mm256_add_epi16(row3, _mm256_shuffle_epi32(row3, KVZ_PERMUTE(2, 3, 0, 1) )); row3 = _mm256_add_epi16(row3, _mm256_shuffle_epi32(row3, KVZ_PERMUTE(1, 0, 1, 0) )); row3 = _mm256_add_epi16(row3, _mm256_shufflelo_epi16(row3, KVZ_PERMUTE(1, 0, 1, 0) )); unsigned sum1 = _mm_extract_epi16(_mm256_castsi256_si128(row3), 0); sum1 = (sum1 + 1) >> 1; unsigned sum2 = _mm_extract_epi16(_mm256_extracti128_si256(row3, 1), 0); sum2 = (sum2 + 1) >> 1; satds_out[0] = sum1; satds_out[1] = sum2; } static INLINE void hor_transform_row_avx2(__m128i* row){ __m128i mask_pos = _mm_set1_epi16(1); __m128i mask_neg = _mm_set1_epi16(-1); __m128i sign_mask = _mm_unpacklo_epi64(mask_pos, mask_neg); __m128i temp = _mm_shuffle_epi32(*row, KVZ_PERMUTE(2, 3, 0, 1)); *row = _mm_sign_epi16(*row, sign_mask); *row = _mm_add_epi16(*row, temp); sign_mask = _mm_unpacklo_epi32(mask_pos, mask_neg); temp = _mm_shuffle_epi32(*row, KVZ_PERMUTE(1, 0, 3, 2)); *row = _mm_sign_epi16(*row, sign_mask); *row = _mm_add_epi16(*row, temp); sign_mask = _mm_unpacklo_epi16(mask_pos, mask_neg); temp = _mm_shufflelo_epi16(*row, KVZ_PERMUTE(1,0,3,2)); temp = _mm_shufflehi_epi16(temp, KVZ_PERMUTE(1,0,3,2)); *row = _mm_sign_epi16(*row, sign_mask); *row = _mm_add_epi16(*row, temp); } static INLINE void hor_transform_row_dual_avx2(__m256i* row){ __m256i mask_pos = _mm256_set1_epi16(1); __m256i mask_neg = _mm256_set1_epi16(-1); __m256i sign_mask = _mm256_unpacklo_epi64(mask_pos, mask_neg); __m256i temp = _mm256_shuffle_epi32(*row, KVZ_PERMUTE(2, 3, 0, 1)); *row = _mm256_sign_epi16(*row, sign_mask); *row = _mm256_add_epi16(*row, temp); sign_mask = _mm256_unpacklo_epi32(mask_pos, mask_neg); temp = _mm256_shuffle_epi32(*row, KVZ_PERMUTE(1, 0, 3, 2)); *row = _mm256_sign_epi16(*row, sign_mask); *row = _mm256_add_epi16(*row, temp); sign_mask = _mm256_unpacklo_epi16(mask_pos, mask_neg); temp = _mm256_shufflelo_epi16(*row, KVZ_PERMUTE(1,0,3,2)); temp = _mm256_shufflehi_epi16(temp, KVZ_PERMUTE(1,0,3,2)); *row = _mm256_sign_epi16(*row, sign_mask); *row = _mm256_add_epi16(*row, temp); } static INLINE void add_sub_avx2(__m128i *out, __m128i *in, unsigned out_idx0, unsigned out_idx1, unsigned in_idx0, unsigned in_idx1) { out[out_idx0] = _mm_add_epi16(in[in_idx0], in[in_idx1]); out[out_idx1] = _mm_sub_epi16(in[in_idx0], in[in_idx1]); } static INLINE void ver_transform_block_avx2(__m128i (*rows)[8]){ __m128i temp0[8]; add_sub_avx2(temp0, (*rows), 0, 1, 0, 1); add_sub_avx2(temp0, (*rows), 2, 3, 2, 3); add_sub_avx2(temp0, (*rows), 4, 5, 4, 5); add_sub_avx2(temp0, (*rows), 6, 7, 6, 7); __m128i temp1[8]; add_sub_avx2(temp1, temp0, 0, 1, 0, 2); add_sub_avx2(temp1, temp0, 2, 3, 1, 3); add_sub_avx2(temp1, temp0, 4, 5, 4, 6); add_sub_avx2(temp1, temp0, 6, 7, 5, 7); add_sub_avx2((*rows), temp1, 0, 1, 0, 4); add_sub_avx2((*rows), temp1, 2, 3, 1, 5); add_sub_avx2((*rows), temp1, 4, 5, 2, 6); add_sub_avx2((*rows), temp1, 6, 7, 3, 7); } static INLINE void add_sub_dual_avx2(__m256i *out, __m256i *in, unsigned out_idx0, unsigned out_idx1, unsigned in_idx0, unsigned in_idx1) { out[out_idx0] = _mm256_add_epi16(in[in_idx0], in[in_idx1]); out[out_idx1] = _mm256_sub_epi16(in[in_idx0], in[in_idx1]); } static INLINE void ver_transform_block_dual_avx2(__m256i (*rows)[8]){ __m256i temp0[8]; add_sub_dual_avx2(temp0, (*rows), 0, 1, 0, 1); add_sub_dual_avx2(temp0, (*rows), 2, 3, 2, 3); add_sub_dual_avx2(temp0, (*rows), 4, 5, 4, 5); add_sub_dual_avx2(temp0, (*rows), 6, 7, 6, 7); __m256i temp1[8]; add_sub_dual_avx2(temp1, temp0, 0, 1, 0, 2); add_sub_dual_avx2(temp1, temp0, 2, 3, 1, 3); add_sub_dual_avx2(temp1, temp0, 4, 5, 4, 6); add_sub_dual_avx2(temp1, temp0, 6, 7, 5, 7); add_sub_dual_avx2((*rows), temp1, 0, 1, 0, 4); add_sub_dual_avx2((*rows), temp1, 2, 3, 1, 5); add_sub_dual_avx2((*rows), temp1, 4, 5, 2, 6); add_sub_dual_avx2((*rows), temp1, 6, 7, 3, 7); } INLINE static void haddwd_accumulate_avx2(__m128i *accumulate, __m128i *ver_row) { __m128i abs_value = _mm_abs_epi16(*ver_row); *accumulate = _mm_add_epi32(*accumulate, _mm_madd_epi16(abs_value, _mm_set1_epi16(1))); } INLINE static void haddwd_accumulate_dual_avx2(__m256i *accumulate, __m256i *ver_row) { __m256i abs_value = _mm256_abs_epi16(*ver_row); *accumulate = _mm256_add_epi32(*accumulate, _mm256_madd_epi16(abs_value, _mm256_set1_epi16(1))); } INLINE static unsigned sum_block_avx2(__m128i *ver_row) { __m128i sad = _mm_setzero_si128(); haddwd_accumulate_avx2(&sad, ver_row + 0); haddwd_accumulate_avx2(&sad, ver_row + 1); haddwd_accumulate_avx2(&sad, ver_row + 2); haddwd_accumulate_avx2(&sad, ver_row + 3); haddwd_accumulate_avx2(&sad, ver_row + 4); haddwd_accumulate_avx2(&sad, ver_row + 5); haddwd_accumulate_avx2(&sad, ver_row + 6); haddwd_accumulate_avx2(&sad, ver_row + 7); sad = _mm_add_epi32(sad, _mm_shuffle_epi32(sad, KVZ_PERMUTE(2, 3, 0, 1))); sad = _mm_add_epi32(sad, _mm_shuffle_epi32(sad, KVZ_PERMUTE(1, 0, 1, 0))); return _mm_cvtsi128_si32(sad); } INLINE static void sum_block_dual_avx2(__m256i *ver_row, unsigned *sum0, unsigned *sum1) { __m256i sad = _mm256_setzero_si256(); haddwd_accumulate_dual_avx2(&sad, ver_row + 0); haddwd_accumulate_dual_avx2(&sad, ver_row + 1); haddwd_accumulate_dual_avx2(&sad, ver_row + 2); haddwd_accumulate_dual_avx2(&sad, ver_row + 3); haddwd_accumulate_dual_avx2(&sad, ver_row + 4); haddwd_accumulate_dual_avx2(&sad, ver_row + 5); haddwd_accumulate_dual_avx2(&sad, ver_row + 6); haddwd_accumulate_dual_avx2(&sad, ver_row + 7); sad = _mm256_add_epi32(sad, _mm256_shuffle_epi32(sad, KVZ_PERMUTE(2, 3, 0, 1))); sad = _mm256_add_epi32(sad, _mm256_shuffle_epi32(sad, KVZ_PERMUTE(1, 0, 1, 0))); *sum0 = _mm_cvtsi128_si32(_mm256_extracti128_si256(sad, 0)); *sum1 = _mm_cvtsi128_si32(_mm256_extracti128_si256(sad, 1)); } INLINE static __m128i diff_row_avx2(const kvz_pixel *buf1, const kvz_pixel *buf2) { __m128i buf1_row = _mm_cvtepu8_epi16(_mm_loadl_epi64((__m128i*)buf1)); __m128i buf2_row = _mm_cvtepu8_epi16(_mm_loadl_epi64((__m128i*)buf2)); return _mm_sub_epi16(buf1_row, buf2_row); } INLINE static __m256i diff_row_dual_avx2(const kvz_pixel *buf1, const kvz_pixel *buf2, const kvz_pixel *orig) { __m128i temp1 = _mm_loadl_epi64((__m128i*)buf1); __m128i temp2 = _mm_loadl_epi64((__m128i*)buf2); __m128i temp3 = _mm_loadl_epi64((__m128i*)orig); __m256i buf1_row = _mm256_cvtepu8_epi16(_mm_unpacklo_epi64(temp1, temp2)); __m256i buf2_row = _mm256_cvtepu8_epi16(_mm_broadcastq_epi64(temp3)); return _mm256_sub_epi16(buf1_row, buf2_row); } INLINE static void diff_blocks_avx2(__m128i (*row_diff)[8], const kvz_pixel * buf1, unsigned stride1, const kvz_pixel * orig, unsigned stride_orig) { (*row_diff)[0] = diff_row_avx2(buf1 + 0 * stride1, orig + 0 * stride_orig); (*row_diff)[1] = diff_row_avx2(buf1 + 1 * stride1, orig + 1 * stride_orig); (*row_diff)[2] = diff_row_avx2(buf1 + 2 * stride1, orig + 2 * stride_orig); (*row_diff)[3] = diff_row_avx2(buf1 + 3 * stride1, orig + 3 * stride_orig); (*row_diff)[4] = diff_row_avx2(buf1 + 4 * stride1, orig + 4 * stride_orig); (*row_diff)[5] = diff_row_avx2(buf1 + 5 * stride1, orig + 5 * stride_orig); (*row_diff)[6] = diff_row_avx2(buf1 + 6 * stride1, orig + 6 * stride_orig); (*row_diff)[7] = diff_row_avx2(buf1 + 7 * stride1, orig + 7 * stride_orig); } INLINE static void diff_blocks_dual_avx2(__m256i (*row_diff)[8], const kvz_pixel * buf1, unsigned stride1, const kvz_pixel * buf2, unsigned stride2, const kvz_pixel * orig, unsigned stride_orig) { (*row_diff)[0] = diff_row_dual_avx2(buf1 + 0 * stride1, buf2 + 0 * stride2, orig + 0 * stride_orig); (*row_diff)[1] = diff_row_dual_avx2(buf1 + 1 * stride1, buf2 + 1 * stride2, orig + 1 * stride_orig); (*row_diff)[2] = diff_row_dual_avx2(buf1 + 2 * stride1, buf2 + 2 * stride2, orig + 2 * stride_orig); (*row_diff)[3] = diff_row_dual_avx2(buf1 + 3 * stride1, buf2 + 3 * stride2, orig + 3 * stride_orig); (*row_diff)[4] = diff_row_dual_avx2(buf1 + 4 * stride1, buf2 + 4 * stride2, orig + 4 * stride_orig); (*row_diff)[5] = diff_row_dual_avx2(buf1 + 5 * stride1, buf2 + 5 * stride2, orig + 5 * stride_orig); (*row_diff)[6] = diff_row_dual_avx2(buf1 + 6 * stride1, buf2 + 6 * stride2, orig + 6 * stride_orig); (*row_diff)[7] = diff_row_dual_avx2(buf1 + 7 * stride1, buf2 + 7 * stride2, orig + 7 * stride_orig); } INLINE static void hor_transform_block_avx2(__m128i (*row_diff)[8]) { hor_transform_row_avx2((*row_diff) + 0); hor_transform_row_avx2((*row_diff) + 1); hor_transform_row_avx2((*row_diff) + 2); hor_transform_row_avx2((*row_diff) + 3); hor_transform_row_avx2((*row_diff) + 4); hor_transform_row_avx2((*row_diff) + 5); hor_transform_row_avx2((*row_diff) + 6); hor_transform_row_avx2((*row_diff) + 7); } INLINE static void hor_transform_block_dual_avx2(__m256i (*row_diff)[8]) { hor_transform_row_dual_avx2((*row_diff) + 0); hor_transform_row_dual_avx2((*row_diff) + 1); hor_transform_row_dual_avx2((*row_diff) + 2); hor_transform_row_dual_avx2((*row_diff) + 3); hor_transform_row_dual_avx2((*row_diff) + 4); hor_transform_row_dual_avx2((*row_diff) + 5); hor_transform_row_dual_avx2((*row_diff) + 6); hor_transform_row_dual_avx2((*row_diff) + 7); } static void kvz_satd_8bit_8x8_general_dual_avx2(const kvz_pixel * buf1, unsigned stride1, const kvz_pixel * buf2, unsigned stride2, const kvz_pixel * orig, unsigned stride_orig, unsigned *sum0, unsigned *sum1) { __m256i temp[8]; diff_blocks_dual_avx2(&temp, buf1, stride1, buf2, stride2, orig, stride_orig); hor_transform_block_dual_avx2(&temp); ver_transform_block_dual_avx2(&temp); sum_block_dual_avx2(temp, sum0, sum1); *sum0 = (*sum0 + 2) >> 2; *sum1 = (*sum1 + 2) >> 2; } /** * \brief Calculate SATD between two 4x4 blocks inside bigger arrays. */ static unsigned kvz_satd_4x4_subblock_8bit_avx2(const kvz_pixel * buf1, const int32_t stride1, const kvz_pixel * buf2, const int32_t stride2) { // TODO: AVX2 implementation return kvz_satd_4x4_subblock_generic(buf1, stride1, buf2, stride2); } static void kvz_satd_4x4_subblock_quad_avx2(const kvz_pixel *preds[4], const int strides[4], const kvz_pixel *orig, const int orig_stride, unsigned costs[4]) { // TODO: AVX2 implementation kvz_satd_4x4_subblock_quad_generic(preds, strides, orig, orig_stride, costs); } static unsigned satd_8x8_subblock_8bit_avx2(const kvz_pixel * buf1, unsigned stride1, const kvz_pixel * buf2, unsigned stride2) { __m128i temp[8]; diff_blocks_avx2(&temp, buf1, stride1, buf2, stride2); hor_transform_block_avx2(&temp); ver_transform_block_avx2(&temp); unsigned sad = sum_block_avx2(temp); unsigned result = (sad + 2) >> 2; return result; } static void satd_8x8_subblock_quad_avx2(const kvz_pixel **preds, const int *strides, const kvz_pixel *orig, const int orig_stride, unsigned *costs) { kvz_satd_8bit_8x8_general_dual_avx2(preds[0], strides[0], preds[1], strides[1], orig, orig_stride, &costs[0], &costs[1]); kvz_satd_8bit_8x8_general_dual_avx2(preds[2], strides[2], preds[3], strides[3], orig, orig_stride, &costs[2], &costs[3]); } SATD_NxN(8bit_avx2, 8) SATD_NxN(8bit_avx2, 16) SATD_NxN(8bit_avx2, 32) SATD_NxN(8bit_avx2, 64) SATD_ANY_SIZE(8bit_avx2) // Function macro for defining hadamard calculating functions // for fixed size blocks. They calculate hadamard for integer // multiples of 8x8 with the 8x8 hadamard function. #define SATD_NXN_DUAL_AVX2(n) \ static void satd_8bit_ ## n ## x ## n ## _dual_avx2( \ const pred_buffer preds, const kvz_pixel * const orig, unsigned num_modes, unsigned *satds_out) \ { \ unsigned x, y; \ satds_out[0] = 0; \ satds_out[1] = 0; \ unsigned sum1 = 0; \ unsigned sum2 = 0; \ for (y = 0; y < (n); y += 8) { \ unsigned row = y * (n); \ for (x = 0; x < (n); x += 8) { \ kvz_satd_8bit_8x8_general_dual_avx2(&preds[0][row + x], (n), &preds[1][row + x], (n), &orig[row + x], (n), &sum1, &sum2); \ satds_out[0] += sum1; \ satds_out[1] += sum2; \ } \ } \ satds_out[0] >>= (KVZ_BIT_DEPTH-8); \ satds_out[1] >>= (KVZ_BIT_DEPTH-8); \ } static void satd_8bit_8x8_dual_avx2( const pred_buffer preds, const kvz_pixel * const orig, unsigned num_modes, unsigned *satds_out) { unsigned x, y; satds_out[0] = 0; satds_out[1] = 0; unsigned sum1 = 0; unsigned sum2 = 0; for (y = 0; y < (8); y += 8) { unsigned row = y * (8); for (x = 0; x < (8); x += 8) { kvz_satd_8bit_8x8_general_dual_avx2(&preds[0][row + x], (8), &preds[1][row + x], (8), &orig[row + x], (8), &sum1, &sum2); satds_out[0] += sum1; satds_out[1] += sum2; } } satds_out[0] >>= (KVZ_BIT_DEPTH-8); satds_out[1] >>= (KVZ_BIT_DEPTH-8); } //SATD_NXN_DUAL_AVX2(8) //Use the non-macro version SATD_NXN_DUAL_AVX2(16) SATD_NXN_DUAL_AVX2(32) SATD_NXN_DUAL_AVX2(64) #define SATD_ANY_SIZE_MULTI_AVX2(suffix, num_parallel_blocks) \ static cost_pixel_any_size_multi_func satd_any_size_## suffix; \ static void satd_any_size_ ## suffix ( \ int width, int height, \ const kvz_pixel **preds, \ const int *strides, \ const kvz_pixel *orig, \ const int orig_stride, \ unsigned num_modes, \ unsigned *costs_out, \ int8_t *valid) \ { \ unsigned sums[num_parallel_blocks] = { 0 }; \ const kvz_pixel *pred_ptrs[4] = { preds[0], preds[1], preds[2], preds[3] };\ const kvz_pixel *orig_ptr = orig; \ costs_out[0] = 0; costs_out[1] = 0; costs_out[2] = 0; costs_out[3] = 0; \ if (width % 8 != 0) { \ /* Process the first column using 4x4 blocks. */ \ for (int y = 0; y < height; y += 4) { \ kvz_satd_4x4_subblock_ ## suffix(preds, strides, orig, orig_stride, sums); \ } \ orig_ptr += 4; \ for(int blk = 0; blk < num_parallel_blocks; ++blk){\ pred_ptrs[blk] += 4; \ }\ width -= 4; \ } \ if (height % 8 != 0) { \ /* Process the first row using 4x4 blocks. */ \ for (int x = 0; x < width; x += 4 ) { \ kvz_satd_4x4_subblock_ ## suffix(pred_ptrs, strides, orig_ptr, orig_stride, sums); \ } \ orig_ptr += 4 * orig_stride; \ for(int blk = 0; blk < num_parallel_blocks; ++blk){\ pred_ptrs[blk] += 4 * strides[blk]; \ }\ height -= 4; \ } \ /* The rest can now be processed with 8x8 blocks. */ \ for (int y = 0; y < height; y += 8) { \ orig_ptr = &orig[y * orig_stride]; \ pred_ptrs[0] = &preds[0][y * strides[0]]; \ pred_ptrs[1] = &preds[1][y * strides[1]]; \ pred_ptrs[2] = &preds[2][y * strides[2]]; \ pred_ptrs[3] = &preds[3][y * strides[3]]; \ for (int x = 0; x < width; x += 8) { \ satd_8x8_subblock_ ## suffix(pred_ptrs, strides, orig_ptr, orig_stride, sums); \ orig_ptr += 8; \ pred_ptrs[0] += 8; \ pred_ptrs[1] += 8; \ pred_ptrs[2] += 8; \ pred_ptrs[3] += 8; \ costs_out[0] += sums[0]; \ costs_out[1] += sums[1]; \ costs_out[2] += sums[2]; \ costs_out[3] += sums[3]; \ } \ } \ for(int i = 0; i < num_parallel_blocks; ++i){\ costs_out[i] = costs_out[i] >> (KVZ_BIT_DEPTH - 8);\ } \ return; \ } SATD_ANY_SIZE_MULTI_AVX2(quad_avx2, 4) #endif //COMPILE_INTEL_AVX2 int kvz_strategy_register_picture_avx2(void* opaque, uint8_t bitdepth) { bool success = true; #if COMPILE_INTEL_AVX2 // We don't actually use SAD for intra right now, other than 4x4 for // transform skip, but we might again one day and this is some of the // simplest code to look at for anyone interested in doing more // optimizations, so it's worth it to keep this maintained. if (bitdepth == 8){ success &= kvz_strategyselector_register(opaque, "sad_8x8", "avx2", 40, &sad_8bit_8x8_avx2); success &= kvz_strategyselector_register(opaque, "sad_16x16", "avx2", 40, &sad_8bit_16x16_avx2); success &= kvz_strategyselector_register(opaque, "sad_32x32", "avx2", 40, &sad_8bit_32x32_avx2); success &= kvz_strategyselector_register(opaque, "sad_64x64", "avx2", 40, &sad_8bit_64x64_avx2); success &= kvz_strategyselector_register(opaque, "satd_4x4", "avx2", 40, &satd_4x4_8bit_avx2); success &= kvz_strategyselector_register(opaque, "satd_8x8", "avx2", 40, &satd_8x8_8bit_avx2); success &= kvz_strategyselector_register(opaque, "satd_16x16", "avx2", 40, &satd_16x16_8bit_avx2); success &= kvz_strategyselector_register(opaque, "satd_32x32", "avx2", 40, &satd_32x32_8bit_avx2); success &= kvz_strategyselector_register(opaque, "satd_64x64", "avx2", 40, &satd_64x64_8bit_avx2); success &= kvz_strategyselector_register(opaque, "satd_4x4_dual", "avx2", 40, &satd_8bit_4x4_dual_avx2); success &= kvz_strategyselector_register(opaque, "satd_8x8_dual", "avx2", 40, &satd_8bit_8x8_dual_avx2); success &= kvz_strategyselector_register(opaque, "satd_16x16_dual", "avx2", 40, &satd_8bit_16x16_dual_avx2); success &= kvz_strategyselector_register(opaque, "satd_32x32_dual", "avx2", 40, &satd_8bit_32x32_dual_avx2); success &= kvz_strategyselector_register(opaque, "satd_64x64_dual", "avx2", 40, &satd_8bit_64x64_dual_avx2); success &= kvz_strategyselector_register(opaque, "satd_any_size", "avx2", 40, &satd_any_size_8bit_avx2); success &= kvz_strategyselector_register(opaque, "satd_any_size_quad", "generic", 40, &satd_any_size_quad_avx2); } #endif return success; }