/* * Copyright (c) 2018, Alliance for Open Media. All rights reserved * * This source code is subject to the terms of the BSD 2 Clause License and * the Alliance for Open Media Patent License 1.0. If the BSD 2 Clause License * was not distributed with this source code in the LICENSE file, you can * obtain it at www.aomedia.org/license/software. If the Alliance for Open * Media Patent License 1.0 was not distributed with this source code in the * PATENTS file, you can obtain it at www.aomedia.org/license/patent. */ #include #include "config/av1_rtcd.h" #include "av1/encoder/block.h" #include "av1/encoder/hash.h" #include "av1/encoder/hash_motion.h" static const int crc_bits = 16; static const int block_size_bits = 3; static void hash_table_clear_all(hash_table *p_hash_table) { if (p_hash_table->p_lookup_table == NULL) { return; } int max_addr = 1 << (crc_bits + block_size_bits); for (int i = 0; i < max_addr; i++) { if (p_hash_table->p_lookup_table[i] != NULL) { aom_vector_destroy(p_hash_table->p_lookup_table[i]); aom_free(p_hash_table->p_lookup_table[i]); p_hash_table->p_lookup_table[i] = NULL; } } } // TODO(youzhou@microsoft.com): is higher than 8 bits screen content supported? // If yes, fix this function static void get_pixels_in_1D_char_array_by_block_2x2(uint8_t *y_src, int stride, uint8_t *p_pixels_in1D) { uint8_t *p_pel = y_src; int index = 0; for (int i = 0; i < 2; i++) { for (int j = 0; j < 2; j++) { p_pixels_in1D[index++] = p_pel[j]; } p_pel += stride; } } static void get_pixels_in_1D_short_array_by_block_2x2(uint16_t *y_src, int stride, uint16_t *p_pixels_in1D) { uint16_t *p_pel = y_src; int index = 0; for (int i = 0; i < 2; i++) { for (int j = 0; j < 2; j++) { p_pixels_in1D[index++] = p_pel[j]; } p_pel += stride; } } static int is_block_2x2_row_same_value(uint8_t *p) { if (p[0] != p[1] || p[2] != p[3]) { return 0; } return 1; } static int is_block16_2x2_row_same_value(uint16_t *p) { if (p[0] != p[1] || p[2] != p[3]) { return 0; } return 1; } static int is_block_2x2_col_same_value(uint8_t *p) { if ((p[0] != p[2]) || (p[1] != p[3])) { return 0; } return 1; } static int is_block16_2x2_col_same_value(uint16_t *p) { if ((p[0] != p[2]) || (p[1] != p[3])) { return 0; } return 1; } // the hash value (hash_value1 consists two parts, the first 3 bits relate to // the block size and the remaining 16 bits are the crc values. This fuction // is used to get the first 3 bits. static int hash_block_size_to_index(int block_size) { switch (block_size) { case 4: return 0; case 8: return 1; case 16: return 2; case 32: return 3; case 64: return 4; case 128: return 5; default: return -1; } } void av1_hash_table_init(hash_table *p_hash_table, MACROBLOCK *x) { if (x->g_crc_initialized == 0) { av1_crc_calculator_init(&x->crc_calculator1, 24, 0x5D6DCB); av1_crc_calculator_init(&x->crc_calculator2, 24, 0x864CFB); x->g_crc_initialized = 1; } p_hash_table->p_lookup_table = NULL; } void av1_hash_table_destroy(hash_table *p_hash_table) { hash_table_clear_all(p_hash_table); aom_free(p_hash_table->p_lookup_table); p_hash_table->p_lookup_table = NULL; } void av1_hash_table_create(hash_table *p_hash_table) { if (p_hash_table->p_lookup_table != NULL) { hash_table_clear_all(p_hash_table); return; } const int max_addr = 1 << (crc_bits + block_size_bits); p_hash_table->p_lookup_table = (Vector **)aom_malloc(sizeof(p_hash_table->p_lookup_table[0]) * max_addr); memset(p_hash_table->p_lookup_table, 0, sizeof(p_hash_table->p_lookup_table[0]) * max_addr); } static void hash_table_add_to_table(hash_table *p_hash_table, uint32_t hash_value, block_hash *curr_block_hash) { if (p_hash_table->p_lookup_table[hash_value] == NULL) { p_hash_table->p_lookup_table[hash_value] = aom_malloc(sizeof(p_hash_table->p_lookup_table[0][0])); aom_vector_setup(p_hash_table->p_lookup_table[hash_value], 10, sizeof(curr_block_hash[0])); aom_vector_push_back(p_hash_table->p_lookup_table[hash_value], curr_block_hash); } else { aom_vector_push_back(p_hash_table->p_lookup_table[hash_value], curr_block_hash); } } int32_t av1_hash_table_count(hash_table *p_hash_table, uint32_t hash_value) { if (p_hash_table->p_lookup_table[hash_value] == NULL) { return 0; } else { return (int32_t)(p_hash_table->p_lookup_table[hash_value]->size); } } Iterator av1_hash_get_first_iterator(hash_table *p_hash_table, uint32_t hash_value) { assert(av1_hash_table_count(p_hash_table, hash_value) > 0); return aom_vector_begin(p_hash_table->p_lookup_table[hash_value]); } int32_t av1_has_exact_match(hash_table *p_hash_table, uint32_t hash_value1, uint32_t hash_value2) { if (p_hash_table->p_lookup_table[hash_value1] == NULL) { return 0; } Iterator iterator = aom_vector_begin(p_hash_table->p_lookup_table[hash_value1]); Iterator last = aom_vector_end(p_hash_table->p_lookup_table[hash_value1]); for (; !iterator_equals(&iterator, &last); iterator_increment(&iterator)) { if ((*(block_hash *)iterator_get(&iterator)).hash_value2 == hash_value2) { return 1; } } return 0; } void av1_generate_block_2x2_hash_value(const YV12_BUFFER_CONFIG *picture, uint32_t *pic_block_hash[2], int8_t *pic_block_same_info[3], MACROBLOCK *x) { const int width = 2; const int height = 2; const int x_end = picture->y_crop_width - width + 1; const int y_end = picture->y_crop_height - height + 1; const int length = width * 2; if (picture->flags & YV12_FLAG_HIGHBITDEPTH) { uint16_t p[4]; int pos = 0; for (int y_pos = 0; y_pos < y_end; y_pos++) { for (int x_pos = 0; x_pos < x_end; x_pos++) { get_pixels_in_1D_short_array_by_block_2x2( CONVERT_TO_SHORTPTR(picture->y_buffer) + y_pos * picture->y_stride + x_pos, picture->y_stride, p); pic_block_same_info[0][pos] = is_block16_2x2_row_same_value(p); pic_block_same_info[1][pos] = is_block16_2x2_col_same_value(p); pic_block_hash[0][pos] = av1_get_crc_value( &x->crc_calculator1, (uint8_t *)p, length * sizeof(p[0])); pic_block_hash[1][pos] = av1_get_crc_value( &x->crc_calculator2, (uint8_t *)p, length * sizeof(p[0])); pos++; } pos += width - 1; } } else { uint8_t p[4]; int pos = 0; for (int y_pos = 0; y_pos < y_end; y_pos++) { for (int x_pos = 0; x_pos < x_end; x_pos++) { get_pixels_in_1D_char_array_by_block_2x2( picture->y_buffer + y_pos * picture->y_stride + x_pos, picture->y_stride, p); pic_block_same_info[0][pos] = is_block_2x2_row_same_value(p); pic_block_same_info[1][pos] = is_block_2x2_col_same_value(p); pic_block_hash[0][pos] = av1_get_crc_value(&x->crc_calculator1, p, length * sizeof(p[0])); pic_block_hash[1][pos] = av1_get_crc_value(&x->crc_calculator2, p, length * sizeof(p[0])); pos++; } pos += width - 1; } } } void av1_generate_block_hash_value(const YV12_BUFFER_CONFIG *picture, int block_size, uint32_t *src_pic_block_hash[2], uint32_t *dst_pic_block_hash[2], int8_t *src_pic_block_same_info[3], int8_t *dst_pic_block_same_info[3], MACROBLOCK *x) { const int pic_width = picture->y_crop_width; const int x_end = picture->y_crop_width - block_size + 1; const int y_end = picture->y_crop_height - block_size + 1; const int src_size = block_size >> 1; const int quad_size = block_size >> 2; uint32_t p[4]; const int length = sizeof(p); int pos = 0; for (int y_pos = 0; y_pos < y_end; y_pos++) { for (int x_pos = 0; x_pos < x_end; x_pos++) { p[0] = src_pic_block_hash[0][pos]; p[1] = src_pic_block_hash[0][pos + src_size]; p[2] = src_pic_block_hash[0][pos + src_size * pic_width]; p[3] = src_pic_block_hash[0][pos + src_size * pic_width + src_size]; dst_pic_block_hash[0][pos] = av1_get_crc_value(&x->crc_calculator1, (uint8_t *)p, length); p[0] = src_pic_block_hash[1][pos]; p[1] = src_pic_block_hash[1][pos + src_size]; p[2] = src_pic_block_hash[1][pos + src_size * pic_width]; p[3] = src_pic_block_hash[1][pos + src_size * pic_width + src_size]; dst_pic_block_hash[1][pos] = av1_get_crc_value(&x->crc_calculator2, (uint8_t *)p, length); dst_pic_block_same_info[0][pos] = src_pic_block_same_info[0][pos] && src_pic_block_same_info[0][pos + quad_size] && src_pic_block_same_info[0][pos + src_size] && src_pic_block_same_info[0][pos + src_size * pic_width] && src_pic_block_same_info[0][pos + src_size * pic_width + quad_size] && src_pic_block_same_info[0][pos + src_size * pic_width + src_size]; dst_pic_block_same_info[1][pos] = src_pic_block_same_info[1][pos] && src_pic_block_same_info[1][pos + src_size] && src_pic_block_same_info[1][pos + quad_size * pic_width] && src_pic_block_same_info[1][pos + quad_size * pic_width + src_size] && src_pic_block_same_info[1][pos + src_size * pic_width] && src_pic_block_same_info[1][pos + src_size * pic_width + src_size]; pos++; } pos += block_size - 1; } if (block_size >= 4) { const int size_minus_1 = block_size - 1; pos = 0; for (int y_pos = 0; y_pos < y_end; y_pos++) { for (int x_pos = 0; x_pos < x_end; x_pos++) { dst_pic_block_same_info[2][pos] = (!dst_pic_block_same_info[0][pos] && !dst_pic_block_same_info[1][pos]) || (((x_pos & size_minus_1) == 0) && ((y_pos & size_minus_1) == 0)); pos++; } pos += block_size - 1; } } } void av1_add_to_hash_map_by_row_with_precal_data(hash_table *p_hash_table, uint32_t *pic_hash[2], int8_t *pic_is_same, int pic_width, int pic_height, int block_size) { const int x_end = pic_width - block_size + 1; const int y_end = pic_height - block_size + 1; const int8_t *src_is_added = pic_is_same; const uint32_t *src_hash[2] = { pic_hash[0], pic_hash[1] }; int add_value = hash_block_size_to_index(block_size); assert(add_value >= 0); add_value <<= crc_bits; const int crc_mask = (1 << crc_bits) - 1; for (int x_pos = 0; x_pos < x_end; x_pos++) { for (int y_pos = 0; y_pos < y_end; y_pos++) { const int pos = y_pos * pic_width + x_pos; // valid data if (src_is_added[pos]) { block_hash curr_block_hash; curr_block_hash.x = x_pos; curr_block_hash.y = y_pos; const uint32_t hash_value1 = (src_hash[0][pos] & crc_mask) + add_value; curr_block_hash.hash_value2 = src_hash[1][pos]; hash_table_add_to_table(p_hash_table, hash_value1, &curr_block_hash); } } } } int av1_hash_is_horizontal_perfect(const YV12_BUFFER_CONFIG *picture, int block_size, int x_start, int y_start) { const int stride = picture->y_stride; const uint8_t *p = picture->y_buffer + y_start * stride + x_start; if (picture->flags & YV12_FLAG_HIGHBITDEPTH) { const uint16_t *p16 = CONVERT_TO_SHORTPTR(p); for (int i = 0; i < block_size; i++) { for (int j = 1; j < block_size; j++) { if (p16[j] != p16[0]) { return 0; } } p16 += stride; } } else { for (int i = 0; i < block_size; i++) { for (int j = 1; j < block_size; j++) { if (p[j] != p[0]) { return 0; } } p += stride; } } return 1; } int av1_hash_is_vertical_perfect(const YV12_BUFFER_CONFIG *picture, int block_size, int x_start, int y_start) { const int stride = picture->y_stride; const uint8_t *p = picture->y_buffer + y_start * stride + x_start; if (picture->flags & YV12_FLAG_HIGHBITDEPTH) { const uint16_t *p16 = CONVERT_TO_SHORTPTR(p); for (int i = 0; i < block_size; i++) { for (int j = 1; j < block_size; j++) { if (p16[j * stride + i] != p16[i]) { return 0; } } } } else { for (int i = 0; i < block_size; i++) { for (int j = 1; j < block_size; j++) { if (p[j * stride + i] != p[i]) { return 0; } } } } return 1; } void av1_get_block_hash_value(uint8_t *y_src, int stride, int block_size, uint32_t *hash_value1, uint32_t *hash_value2, int use_highbitdepth, MACROBLOCK *x) { uint32_t to_hash[4]; const int add_value = hash_block_size_to_index(block_size) << crc_bits; assert(add_value >= 0); const int crc_mask = (1 << crc_bits) - 1; // 2x2 subblock hash values in current CU int sub_block_in_width = (block_size >> 1); if (use_highbitdepth) { uint16_t pixel_to_hash[4]; uint16_t *y16_src = CONVERT_TO_SHORTPTR(y_src); for (int y_pos = 0; y_pos < block_size; y_pos += 2) { for (int x_pos = 0; x_pos < block_size; x_pos += 2) { int pos = (y_pos >> 1) * sub_block_in_width + (x_pos >> 1); get_pixels_in_1D_short_array_by_block_2x2( y16_src + y_pos * stride + x_pos, stride, pixel_to_hash); assert(pos < AOM_BUFFER_SIZE_FOR_BLOCK_HASH); x->hash_value_buffer[0][0][pos] = av1_get_crc_value(&x->crc_calculator1, (uint8_t *)pixel_to_hash, sizeof(pixel_to_hash)); x->hash_value_buffer[1][0][pos] = av1_get_crc_value(&x->crc_calculator2, (uint8_t *)pixel_to_hash, sizeof(pixel_to_hash)); } } } else { uint8_t pixel_to_hash[4]; for (int y_pos = 0; y_pos < block_size; y_pos += 2) { for (int x_pos = 0; x_pos < block_size; x_pos += 2) { int pos = (y_pos >> 1) * sub_block_in_width + (x_pos >> 1); get_pixels_in_1D_char_array_by_block_2x2(y_src + y_pos * stride + x_pos, stride, pixel_to_hash); assert(pos < AOM_BUFFER_SIZE_FOR_BLOCK_HASH); x->hash_value_buffer[0][0][pos] = av1_get_crc_value( &x->crc_calculator1, pixel_to_hash, sizeof(pixel_to_hash)); x->hash_value_buffer[1][0][pos] = av1_get_crc_value( &x->crc_calculator2, pixel_to_hash, sizeof(pixel_to_hash)); } } } int src_sub_block_in_width = sub_block_in_width; sub_block_in_width >>= 1; int src_idx = 1; int dst_idx = 0; // 4x4 subblock hash values to current block hash values for (int sub_width = 4; sub_width <= block_size; sub_width *= 2) { src_idx = 1 - src_idx; dst_idx = 1 - dst_idx; int dst_pos = 0; for (int y_pos = 0; y_pos < sub_block_in_width; y_pos++) { for (int x_pos = 0; x_pos < sub_block_in_width; x_pos++) { int srcPos = (y_pos << 1) * src_sub_block_in_width + (x_pos << 1); assert(srcPos + 1 < AOM_BUFFER_SIZE_FOR_BLOCK_HASH); assert(srcPos + src_sub_block_in_width + 1 < AOM_BUFFER_SIZE_FOR_BLOCK_HASH); assert(dst_pos < AOM_BUFFER_SIZE_FOR_BLOCK_HASH); to_hash[0] = x->hash_value_buffer[0][src_idx][srcPos]; to_hash[1] = x->hash_value_buffer[0][src_idx][srcPos + 1]; to_hash[2] = x->hash_value_buffer[0][src_idx][srcPos + src_sub_block_in_width]; to_hash[3] = x->hash_value_buffer[0][src_idx] [srcPos + src_sub_block_in_width + 1]; x->hash_value_buffer[0][dst_idx][dst_pos] = av1_get_crc_value( &x->crc_calculator1, (uint8_t *)to_hash, sizeof(to_hash)); to_hash[0] = x->hash_value_buffer[1][src_idx][srcPos]; to_hash[1] = x->hash_value_buffer[1][src_idx][srcPos + 1]; to_hash[2] = x->hash_value_buffer[1][src_idx][srcPos + src_sub_block_in_width]; to_hash[3] = x->hash_value_buffer[1][src_idx] [srcPos + src_sub_block_in_width + 1]; x->hash_value_buffer[1][dst_idx][dst_pos] = av1_get_crc_value( &x->crc_calculator2, (uint8_t *)to_hash, sizeof(to_hash)); dst_pos++; } } src_sub_block_in_width = sub_block_in_width; sub_block_in_width >>= 1; } *hash_value1 = (x->hash_value_buffer[0][dst_idx][0] & crc_mask) + add_value; *hash_value2 = x->hash_value_buffer[1][dst_idx][0]; }