#ifndef PICTURE_H_ #define PICTURE_H_ /***************************************************************************** * This file is part of Kvazaar HEVC encoder. * * Copyright (C) 2013-2014 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 General Public License version 2 as published * by the Free Software Foundation. * * 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 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 * \brief Coding Unit (CU) and picture data related functions. */ #include "global.h" //#include "sao.h" struct sao_info_struct; ////////////////////////////////////////////////////////////////////////// // CONSTANTS enum { CU_NOTSET = 0, CU_PCM, CU_SKIP, CU_SPLIT, CU_INTRA, CU_INTER }; enum { SLICE_B = 0, SLICE_P = 1, SLICE_I = 2 }; enum { REF_PIC_LIST_0 = 0, REF_PIC_LIST_1 = 1, REF_PIC_LIST_X = 100 }; typedef enum { COLOR_Y = 0, COLOR_U, COLOR_V, NUM_COLORS } color_index; ////////////////////////////////////////////////////////////////////////// // TYPES typedef struct { int x; int y; } vector2d; /** * \brief Struct for CU intra info */ typedef struct { uint32_t cost; uint32_t bitcost; int8_t mode; int8_t mode_chroma; int8_t tr_skip; //!< \brief transform skip flag } cu_info_intra; /** * \brief Struct for CU inter info */ typedef struct { uint32_t cost; uint32_t bitcost; int16_t mv[2]; int16_t mvd[2]; uint8_t mv_cand; // \brief selected MV candidate uint8_t mv_ref; // \brief Index of the encoder_control.ref array. uint8_t mv_dir; // \brief Probably describes if mv_ref is forward, backward or both. Might not be needed? int8_t mode; } cu_info_inter; /** * \brief Struct for CU info */ typedef struct { int8_t type; //!< \brief block type, CU_INTER / CU_INTRA int8_t depth; //!< \brief depth / size of this block int8_t part_size; //!< \brief Currently only 2Nx2N, TODO: AMP/SMP/NxN parts int8_t tr_depth; //!< \brief transform depth int8_t coded; //!< \brief flag to indicate this block is coded and reconstructed int8_t skipped; //!< \brief flag to indicate this block is skipped int8_t merged; //!< \brief flag to indicate this block is merged int8_t merge_idx; //!< \brief merge index // MAX_DEPTH+4 for the 4 PUs at the last level. int8_t coeff_top_y[MAX_DEPTH+5]; //!< \brief is there coded coeffs Y in top level int8_t coeff_top_u[MAX_DEPTH+5]; //!< \brief is there coded coeffs U in top level int8_t coeff_top_v[MAX_DEPTH+5]; //!< \brief is there coded coeffs V in top level cu_info_intra intra[4]; cu_info_inter inter; } cu_info; /** * \brief Struct which contains all picture data */ typedef struct picture_struct { pixel* y_data; //!< \brief Pointer to luma pixel array. pixel* u_data; //!< \brief Pointer to chroma U pixel array. pixel* v_data; //!< \brief Pointer to chroma V pixel array. pixel *data[NUM_COLORS]; // \brief Alternate access method to same data. pixel* y_recdata; //!< \brief Pointer to reconstructed Y-data. pixel* u_recdata; //!< \brief Pointer to reconstructed U-data. pixel* v_recdata; //!< \brief Pointer to reconstructed V-data. pixel *recdata[NUM_COLORS]; // \brief Alternate access method to same data. pixel* pred_y; //!< \brief Pointer to predicted Y pixel* pred_u; //!< \brief Pointer to predicted U pixel* pred_v; //!< \brief Pointer to predicted V coefficient* coeff_y; //!< \brief coefficient pointer Y coefficient* coeff_u; //!< \brief coefficient pointer U coefficient* coeff_v; //!< \brief coefficient pointer V int32_t width; //!< \brief Luma pixel array width. int32_t height; //!< \brief Luma pixel array height. int32_t height_in_lcu; //!< \brief Picture width in number of LCU's. int32_t width_in_lcu; //!< \brief Picture height in number of LCU's. uint8_t referenced; //!< \brief Whether this picture is referenced. cu_info** cu_array; //!< \brief Info for each CU at each depth. uint8_t type; uint8_t slicetype; uint8_t slice_sao_luma_flag; uint8_t slice_sao_chroma_flag; struct sao_info_struct *sao_luma; //!< \brief Array of sao parameters for every LCU. struct sao_info_struct *sao_chroma; //!< \brief Array of sao parameters for every LCU. int32_t poc; //!< \brief Picture order count } picture; /** * \brief Struct which contains array of picture structs */ typedef struct { picture** pics; //!< \brief Pointer to array of picture pointers. int32_t size; //!< \brief Array size. int32_t used_size; } picture_list; #define SUB_SCU_BIT_MASK (64 - 1) #define SUB_SCU(xy) (xy & SUB_SCU_BIT_MASK) #define LCU_CU_WIDTH 8 #define LCU_T_CU_WIDTH 9 #define LCU_CU_OFFSET 10 // Width from top left of the LCU, so +1 for ref buffer size. #define LCU_REF_PX_WIDTH (LCU_WIDTH + LCU_WIDTH / 2) /** * Top and left intra reference pixels for LCU. * - Intra needs maximum of 32 to the right and down from LCU border. * - First pixel is the top-left pixel. */ typedef struct { pixel y[LCU_REF_PX_WIDTH + 1]; pixel u[LCU_REF_PX_WIDTH / 2 + 1]; pixel v[LCU_REF_PX_WIDTH / 2 + 1]; } lcu_ref_px_t; typedef struct { coefficient y[LCU_LUMA_SIZE]; coefficient u[LCU_CHROMA_SIZE]; coefficient v[LCU_CHROMA_SIZE]; } lcu_coeff_t; typedef struct { pixel y[LCU_LUMA_SIZE]; pixel u[LCU_CHROMA_SIZE]; pixel v[LCU_CHROMA_SIZE]; } lcu_yuv_t; typedef struct { int size; pixel *y; pixel *u; pixel *v; } yuv_t; typedef struct { lcu_ref_px_t top_ref; //!< Reference pixels from adjacent LCUs. lcu_ref_px_t left_ref; //!< Reference pixels from adjacent LCUs. lcu_yuv_t ref; //!< LCU reference pixels lcu_yuv_t rec; //!< LCU reconstructed pixels /** * We get the coefficients as a byproduct of doing reconstruction during the * search. It might be more efficient to recalculate the final coefficients * once we know the final modes rather than copying them. */ lcu_coeff_t coeff; //!< LCU coefficients /** * A 9x9 CU array for the LCU, +1 CU. * - Top reference CUs on row 0. * - Left reference CUs on column 0. * - All of LCUs CUs on 1:9, 1:9. * - Top right reference CU on the last slot. */ cu_info cu[9*9+1]; } lcu_t; ////////////////////////////////////////////////////////////////////////// // FUNCTIONS yuv_t * alloc_yuv_t(int luma_size); void dealloc_yuv_t(yuv_t * yuv); picture * picture_init(int32_t width, int32_t height, int32_t width_in_lcu, int32_t height_in_lcu); int picture_destroy(picture *pic); void picture_blit_pixels(const pixel* orig, pixel *dst, unsigned width, unsigned height, unsigned orig_stride, unsigned dst_stride); void picture_blit_coeffs(const coefficient *orig, coefficient *dst, unsigned width, unsigned height, unsigned orig_stride, unsigned dst_stride); picture_list * picture_list_init(int size); int picture_list_resize(picture_list *list, unsigned size); int picture_list_destroy(picture_list *list); int picture_list_add(picture_list *list, picture *pic); int picture_list_rem(picture_list *list, unsigned n, int8_t destroy); typedef unsigned (*cost_16bit_nxn_func)(pixel *block1, pixel *block2); cost_16bit_nxn_func get_satd_16bit_nxn_func(unsigned n); cost_16bit_nxn_func get_sad_16bit_nxn_func(unsigned n); unsigned satd_16bit_nxn(pixel *block1, pixel *block2, unsigned n); unsigned sad_16bit_nxn(pixel *block1, pixel *block2, unsigned n); unsigned calc_sad(const picture *pic, const picture *ref, int pic_x, int pic_y, int ref_x, int ref_y, int block_width, int block_height); double image_psnr(pixel *frame1, pixel *frame2, int32_t x, int32_t y); ////////////////////////////////////////////////////////////////////////// // MACROS #define GET_SPLITDATA(CU,curDepth) ((CU)->depth > curDepth) #define SET_SPLITDATA(CU,flag) { (CU)->split=(flag); } #endif