#ifndef CU_H_ #define CU_H_ /***************************************************************************** * This file is part of uvg266 VVC encoder. * * Copyright (c) 2021, Tampere University, ITU/ISO/IEC, project contributors * All rights reserved. * * Redistribution and use in source and binary forms, with or without modification, * are permitted provided that the following conditions are met: * * * Redistributions of source code must retain the above copyright notice, this * list of conditions and the following disclaimer. * * * Redistributions in binary form must reproduce the above copyright notice, this * list of conditions and the following disclaimer in the documentation and/or * other materials provided with the distribution. * * * Neither the name of the Tampere University or ITU/ISO/IEC nor the names of its * contributors may be used to endorse or promote products derived from * this software without specific prior written permission. * * THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" AND * ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED * WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE * DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT HOLDER OR CONTRIBUTORS BE LIABLE FOR * ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES * INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; * LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION HOWEVER CAUSED AND ON * ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT * SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. * INCLUDING NEGLIGENCE OR OTHERWISE ARISING IN ANY WAY OUT OF THE USE OF THIS ****************************************************************************/ /** * \ingroup DataStructures * \file * Coding Unit data structure and related functions. */ #include "global.h" // IWYU pragma: keep #include "image.h" #include "uvg266.h" //Cu stuff ////////////////////////////////////////////////////////////////////////// // CONSTANTS typedef enum { CU_NOTSET = 0, CU_INTRA = 1, CU_INTER = 2, CU_PCM = 3, } cu_type_t; typedef enum { SIZE_2Nx2N = 0, SIZE_2NxN = 1, SIZE_Nx2N = 2, SIZE_NxN = 3, SIZE_2NxnU = 4, SIZE_2NxnD = 5, SIZE_nLx2N = 6, SIZE_nRx2N = 7, } part_mode_t; //MTS transform combinations typedef enum { MTS_DCT2_DCT2 = 0, MTS_SKIP = 1, MTS_DST7_DST7 = 2, MTS_DCT8_DST7 = 3, MTS_DST7_DCT8 = 4, MTS_DCT8_DCT8 = 5, MTS_TR_NUM = 6, } mts_idx; ////////////////////////////////////////////////////////////////////////// // TYPES typedef struct { int x; int y; } vector2d_t; enum uvg_tree_type { UVG_BOTH_T = 0, UVG_LUMA_T = 1, UVG_CHROMA_T = 2 }; enum split_type { NO_SPLIT = 0, QT_SPLIT = 1, BT_HOR_SPLIT = 2, BT_VER_SPLIT = 3, TT_HOR_SPLIT = 4, TT_VER_SPLIT = 5, }; typedef struct { uint32_t split_tree; uint8_t current_depth; uint8_t mtt_depth; uint8_t implicit_mtt_depth; uint8_t part_index; } split_tree_t; // Split for each depth takes three bits like xxy where if either x bit is set // it is a MTT split, and if there are any MTT split QT split is not allowed #define CAN_QT_SPLIT(x) (((x) & 6DB6DB6) == 0) /** * \brief Struct for CU info */ typedef struct { uint8_t type : 2; //!< \brief block type, one of cu_type_t values uint8_t skipped : 1; //!< \brief flag to indicate this block is skipped uint8_t merged : 1; //!< \brief flag to indicate this block is merged uint8_t merge_idx : 3; //!< \brief merge index uint8_t tr_skip : 3; //!< \brief transform skip flag uint8_t tr_idx : 3; //!< \brief transform index uint8_t joint_cb_cr : 2; //!< \brief joint chroma residual coding uint8_t log2_width : 3; uint8_t log2_height : 3; uint8_t log2_chroma_width : 3; uint8_t log2_chroma_height : 3; uint16_t cbf; uint8_t root_cbf; uint32_t split_tree : 3 * 9; /** * \brief QP used for the CU. * * This is required for deblocking when per-LCU QPs are enabled. */ uint8_t qp; uint8_t bdpcmMode : 1; uint8_t violates_mts_coeff_constraint : 1; uint8_t mts_last_scan_pos : 1; uint8_t violates_lfnst_constrained_luma : 1; uint8_t violates_lfnst_constrained_chroma : 1; uint8_t lfnst_last_scan_pos : 1; uint8_t lfnst_idx : 2; uint8_t cr_lfnst_idx : 2; uint8_t luma_deblocking : 2; uint8_t chroma_deblocking : 2; union { struct { int8_t mode; int8_t mode_chroma; uint8_t multi_ref_idx; int8_t mip_flag; int8_t mip_is_transposed; int8_t isp_mode; } intra; struct { mv_t mv[2][2]; // \brief Motion vectors for L0 and L1 uint8_t mv_ref[2]; // \brief Index of the L0 and L1 array. uint8_t mv_cand0 : 1; // \brief selected MV candidate uint8_t mv_cand1 : 1; // \brief selected MV candidate uint8_t mv_dir : 2; // \brief Probably describes if mv_ref is L0, L1 or both (bi-pred) uint8_t imv : 2; // \brief Adaptive motion vector resolution for this block } inter; }; } cu_info_t; typedef struct { int16_t x; int16_t y; uint8_t local_x; uint8_t local_y; int8_t width; int8_t height; int8_t chroma_width; int8_t chroma_height; } cu_loc_t; void uvg_cu_loc_ctor(cu_loc_t *loc, int x, int y, int width, int height); typedef struct encoder_state_t encoder_state_t; int uvg_get_split_locs( const cu_loc_t* const origin, enum split_type split, cu_loc_t out[4], uint8_t* separate_chroma); int uvg_get_possible_splits(const encoder_state_t* const state, const cu_loc_t* const cu_loc, split_tree_t split_tree, enum uvg_tree_type tree_type, bool splits[6]); #define CU_GET_MV_CAND(cu_info_ptr, reflist) \ (((reflist) == 0) ? (cu_info_ptr)->inter.mv_cand0 : (cu_info_ptr)->inter.mv_cand1) #define CU_SET_MV_CAND(cu_info_ptr, reflist, value) \ do { \ if ((reflist) == 0) { \ (cu_info_ptr)->inter.mv_cand0 = (value); \ } else { \ (cu_info_ptr)->inter.mv_cand1 = (value); \ } \ } while (0) #define CHECKPOINT_CU(prefix_str, cu) CHECKPOINT(prefix_str " type=%d part_size=%d coded=%d " \ "skipped=%d merged=%d merge_idx=%d cbf.y=%d cbf.u=%d cbf.v=%d " \ "intra[0].cost=%u intra[0].bitcost=%u intra[0].mode=%d intra[0].mode_chroma=%d intra[0].tr_skip=%d " \ "intra[1].cost=%u intra[1].bitcost=%u intra[1].mode=%d intra[1].mode_chroma=%d intra[1].tr_skip=%d " \ "intra[2].cost=%u intra[2].bitcost=%u intra[2].mode=%d intra[2].mode_chroma=%d intra[2].tr_skip=%d " \ "intra[3].cost=%u intra[3].bitcost=%u intra[3].mode=%d intra[3].mode_chroma=%d intra[3].tr_skip=%d " \ "inter.cost=%u inter.bitcost=%u inter.mv[0]=%d inter.mv[1]=%d inter.mvd[0]=%d inter.mvd[1]=%d " \ "inter.mv_cand=%d inter.mv_ref=%d inter.mv_dir=%d inter.mode=%d" \ , (cu).type, (cu).part_size, (cu).coded, \ (cu).skipped, (cu).merged, (cu).merge_idx, (cu).cbf.y, (cu).cbf.u, (cu).cbf.v, \ (cu).intra[0].cost, (cu).intra[0].bitcost, (cu).intra[0].mode, (cu).intra[0].mode_chroma, (cu).intra[0].tr_skip, \ (cu).intra[1].cost, (cu).intra[1].bitcost, (cu).intra[1].mode, (cu).intra[1].mode_chroma, (cu).intra[1].tr_skip, \ (cu).intra[2].cost, (cu).intra[2].bitcost, (cu).intra[2].mode, (cu).intra[2].mode_chroma, (cu).intra[2].tr_skip, \ (cu).intra[3].cost, (cu).intra[3].bitcost, (cu).intra[3].mode, (cu).intra[3].mode_chroma, (cu).intra[3].tr_skip, \ (cu).inter.cost, (cu).inter.bitcost, (cu).inter.mv[0], (cu).inter.mv[1], (cu).inter.mvd[0], (cu).inter.mvd[1], \ (cu).inter.mv_cand, (cu).inter.mv_ref, (cu).inter.mv_dir, (cu).inter.mode) typedef struct cu_array_t { struct cu_array_t *base; //!< \brief base cu array or NULL cu_info_t *data; //!< \brief cu array uint32_t width; //!< \brief width of the array in pixels uint32_t height; //!< \brief height of the array in pixels uint32_t stride; //!< \brief stride of the array in pixels uint32_t refcount; //!< \brief number of references to this cu_array } cu_array_t; cu_info_t* uvg_cu_array_at(cu_array_t *cua, unsigned x_px, unsigned y_px); void uvg_get_isp_cu_arr_coords(int* x, int* y); const cu_info_t* uvg_cu_array_at_const(const cu_array_t *cua, unsigned x_px, unsigned y_px); cu_array_t * uvg_cu_array_alloc(const int width, const int height); cu_array_t* uvg_cu_array_chroma_alloc(const int width, const int height, enum uvg_chroma_format chroma); cu_array_t * uvg_cu_subarray(cu_array_t *base, const unsigned x_offset, const unsigned y_offset, const unsigned width, const unsigned height); void uvg_cu_array_free(cu_array_t **cua_ptr); cu_array_t * uvg_cu_array_copy_ref(cu_array_t* cua); /** * \brief Return the 7 lowest-order bits of the pixel coordinate. * * The 7 lower-order bits correspond to the distance from the left or top edge * of the containing LCU. */ #define SUB_SCU(xy) ((xy) & (LCU_WIDTH - 1)) #define SUB_SCU_TREE(xy, t) ((xy) & (((t) != KVZ_CHROMA_T ? LCU_WIDTH : LCU_WIDTH_C) - 1)) #define LCU_CU_WIDTH 16 #define LCU_T_CU_WIDTH (LCU_CU_WIDTH + 1) #define LCU_CU_OFFSET (LCU_T_CU_WIDTH + 1) #define SCU_WIDTH (LCU_WIDTH / LCU_CU_WIDTH) // 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 { uvg_pixel y[LCU_REF_PX_WIDTH + 1]; uvg_pixel u[LCU_REF_PX_WIDTH / 2 + 1]; uvg_pixel v[LCU_REF_PX_WIDTH / 2 + 1]; } lcu_ref_px_t; /** * \brief Coefficients of an LCU * * Coefficients inside a single TU are stored in row-major order. TUs * themselves are stored in a zig-zag order, so that the coefficients of * a TU are contiguous in memory. * * Example storage order for a 32x32 pixel TU tree * \verbatim +------+------+------+------+---------------------------+ | 0 | 16 | 64 | 80 | | | - | - | - | - | | | 15 | 31 | 79 | 95 | | +------+------+------+------+ | | 32 | 48 | 96 | 112 | | | - | - | - | - | | | 47 | 63 | 111 | 127 | | +------+------+------+------+ 256 - 511 | | 128 | 144 | 192 | 208 | | | - | - | - | - | | | 143 | 159 | 207 | 223 | | +------+------+------+------+ | | 160 | 176 | 224 | 240 | | | - | - | - | - | | | 175 | 191 | 239 | 255 | | +------+------+------+------+-------------+------+------+ | 512 | 528 | | | 832 | 848 | | - | - | | | - | - | | 527 | 543 | | | 847 | 863 | +------+------+ 576 - 639 | 768 - 831 +------+------+ | 544 | 560 | | | 864 | 880 | | - | - | | | - | - | | 559 | 575 | | | 879 | 895 | +------+------+-------------+-------------+------+------+ | | | | | | | | | | | | | | | | 640 - 703 | 704 - 767 | 896 - 959 | 960 - 1023 | | | | | | | | | | | | | | | | +-------------+-------------+-------------+-------------+ \endverbatim */ typedef ALIGNED(8) struct { coeff_t y[LCU_LUMA_SIZE]; coeff_t u[LCU_CHROMA_SIZE]; coeff_t v[LCU_CHROMA_SIZE]; coeff_t joint_uv[LCU_CHROMA_SIZE]; } lcu_coeff_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 17x17 CU array, plus the top right reference CU. * - Top reference CUs at indices [0,16] (row 0). * - Left reference CUs at indices 17*n where n is in [0,16] (column 0). * - All CUs of this LCU at indices 17*y + x where x,y are in [1,16]. * - Top right reference CU at the last index. * * The figure below shows how the indices map to CU locations. * \verbatim .-- left reference CUs v 0 | 1 2 . . . 16 | 289 <-- top reference CUs -----+--------------------+---- 17 | 18 19 . . . 33 | 34 | 35 36 . . . 50 <-- this LCU . | . . . . | . | . . . . | . | . . . . | 272 | 273 274 . . . 288 | -----+--------------------+---- \endverbatim */ cu_info_t cu[LCU_T_CU_WIDTH * LCU_T_CU_WIDTH + 1]; } lcu_t; void uvg_cu_array_copy_from_lcu(cu_array_t* dst, int dst_x, int dst_y, const lcu_t *src, enum uvg_tree_type tree_type); int uvg_count_available_edge_cus(const cu_loc_t* const cu_loc, const lcu_t* const lcu, bool left); int uvg_count_chroma_tree_available_edge_cus(int x, int y, int width, int height, const lcu_t* const lcu, bool left); /** * \brief Return pointer to the top right reference CU. */ #define LCU_GET_TOP_RIGHT_CU(lcu) \ (&(lcu)->cu[LCU_T_CU_WIDTH * LCU_T_CU_WIDTH]) /** * \brief Return pointer to the CU containing a given pixel. * * \param lcu pointer to the containing LCU * \param x_px x-coordinate relative to the upper left corner of the LCU * \param y_px y-coordinate relative to the upper left corner of the LCU * \return pointer to the CU at coordinates (x_px, y_px) */ #define LCU_GET_CU_AT_PX(lcu, x_px, y_px) \ (&(lcu)->cu[LCU_CU_OFFSET + ((x_px) >> 2) + ((y_px) >> 2) * LCU_T_CU_WIDTH]) /** * \brief Copy a part of a coeff_t array to another. * * \param width Size of the block to be copied in pixels. * \param src Pointer to the source array. * \param dest Pointer to the destination array. */ static INLINE void copy_coeffs(const coeff_t *__restrict src, coeff_t *__restrict dest, size_t width, size_t height, const int lcu_width) { for (int j = 0; j < height; ++j) { memcpy(dest + j * lcu_width, src + j * lcu_width, width * sizeof(coeff_t)); } } /** * \brief Convert (x, y) coordinates to z-order index. * * Only works for widths and coordinates divisible by four. Width must be * a power of two in range [4..64]. * * \param width size of the containing block * \param x x-coordinate * \param y y-coordinate * \return index in z-order */ static INLINE unsigned xy_to_zorder(unsigned width, unsigned x, unsigned y) { assert(width % 4 == 0 && width >= 4 && width <= 64); assert(x % 4 == 0 && x < width); assert(y % 4 == 0 && y < width); unsigned result = 0; switch (width) { case 64: result += x / 32 * (32*32); result += y / 32 * (64*32); x %= 32; y %= 32; // fallthrough case 32: result += x / 16 * (16*16); result += y / 16 * (32*16); x %= 16; y %= 16; // fallthrough case 16: result += x / 8 * ( 8*8); result += y / 8 * (16*8); x %= 8; y %= 8; // fallthrough case 8: result += x / 4 * (4*4); result += y / 4 * (8*4); // fallthrough case 4: break; } return result; } #define CHECKPOINT_LCU(prefix_str, lcu) do { \ CHECKPOINT_CU(prefix_str " cu[0]", (lcu).cu[0]); \ CHECKPOINT_CU(prefix_str " cu[1]", (lcu).cu[1]); \ CHECKPOINT_CU(prefix_str " cu[2]", (lcu).cu[2]); \ CHECKPOINT_CU(prefix_str " cu[3]", (lcu).cu[3]); \ CHECKPOINT_CU(prefix_str " cu[4]", (lcu).cu[4]); \ CHECKPOINT_CU(prefix_str " cu[5]", (lcu).cu[5]); \ CHECKPOINT_CU(prefix_str " cu[6]", (lcu).cu[6]); \ CHECKPOINT_CU(prefix_str " cu[7]", (lcu).cu[7]); \ CHECKPOINT_CU(prefix_str " cu[8]", (lcu).cu[8]); \ CHECKPOINT_CU(prefix_str " cu[9]", (lcu).cu[9]); \ CHECKPOINT_CU(prefix_str " cu[10]", (lcu).cu[10]); \ CHECKPOINT_CU(prefix_str " cu[11]", (lcu).cu[11]); \ CHECKPOINT_CU(prefix_str " cu[12]", (lcu).cu[12]); \ CHECKPOINT_CU(prefix_str " cu[13]", (lcu).cu[13]); \ CHECKPOINT_CU(prefix_str " cu[14]", (lcu).cu[14]); \ CHECKPOINT_CU(prefix_str " cu[15]", (lcu).cu[15]); \ CHECKPOINT_CU(prefix_str " cu[16]", (lcu).cu[16]); \ CHECKPOINT_CU(prefix_str " cu[17]", (lcu).cu[17]); \ CHECKPOINT_CU(prefix_str " cu[18]", (lcu).cu[18]); \ CHECKPOINT_CU(prefix_str " cu[19]", (lcu).cu[19]); \ CHECKPOINT_CU(prefix_str " cu[20]", (lcu).cu[20]); \ CHECKPOINT_CU(prefix_str " cu[21]", (lcu).cu[21]); \ CHECKPOINT_CU(prefix_str " cu[22]", (lcu).cu[22]); \ CHECKPOINT_CU(prefix_str " cu[23]", (lcu).cu[23]); \ CHECKPOINT_CU(prefix_str " cu[24]", (lcu).cu[24]); \ CHECKPOINT_CU(prefix_str " cu[25]", (lcu).cu[25]); \ CHECKPOINT_CU(prefix_str " cu[26]", (lcu).cu[26]); \ CHECKPOINT_CU(prefix_str " cu[27]", (lcu).cu[27]); \ CHECKPOINT_CU(prefix_str " cu[28]", (lcu).cu[28]); \ CHECKPOINT_CU(prefix_str " cu[29]", (lcu).cu[29]); \ CHECKPOINT_CU(prefix_str " cu[30]", (lcu).cu[30]); \ CHECKPOINT_CU(prefix_str " cu[31]", (lcu).cu[31]); \ CHECKPOINT_CU(prefix_str " cu[32]", (lcu).cu[32]); \ CHECKPOINT_CU(prefix_str " cu[33]", (lcu).cu[33]); \ CHECKPOINT_CU(prefix_str " cu[34]", (lcu).cu[34]); \ CHECKPOINT_CU(prefix_str " cu[35]", (lcu).cu[35]); \ CHECKPOINT_CU(prefix_str " cu[36]", (lcu).cu[36]); \ CHECKPOINT_CU(prefix_str " cu[37]", (lcu).cu[37]); \ CHECKPOINT_CU(prefix_str " cu[38]", (lcu).cu[38]); \ CHECKPOINT_CU(prefix_str " cu[39]", (lcu).cu[39]); \ CHECKPOINT_CU(prefix_str " cu[40]", (lcu).cu[40]); \ CHECKPOINT_CU(prefix_str " cu[41]", (lcu).cu[41]); \ CHECKPOINT_CU(prefix_str " cu[42]", (lcu).cu[42]); \ CHECKPOINT_CU(prefix_str " cu[43]", (lcu).cu[43]); \ CHECKPOINT_CU(prefix_str " cu[44]", (lcu).cu[44]); \ CHECKPOINT_CU(prefix_str " cu[45]", (lcu).cu[45]); \ CHECKPOINT_CU(prefix_str " cu[46]", (lcu).cu[46]); \ CHECKPOINT_CU(prefix_str " cu[47]", (lcu).cu[47]); \ CHECKPOINT_CU(prefix_str " cu[48]", (lcu).cu[48]); \ CHECKPOINT_CU(prefix_str " cu[49]", (lcu).cu[49]); \ CHECKPOINT_CU(prefix_str " cu[50]", (lcu).cu[50]); \ CHECKPOINT_CU(prefix_str " cu[51]", (lcu).cu[51]); \ CHECKPOINT_CU(prefix_str " cu[52]", (lcu).cu[52]); \ CHECKPOINT_CU(prefix_str " cu[53]", (lcu).cu[53]); \ CHECKPOINT_CU(prefix_str " cu[54]", (lcu).cu[54]); \ CHECKPOINT_CU(prefix_str " cu[55]", (lcu).cu[55]); \ CHECKPOINT_CU(prefix_str " cu[56]", (lcu).cu[56]); \ CHECKPOINT_CU(prefix_str " cu[57]", (lcu).cu[57]); \ CHECKPOINT_CU(prefix_str " cu[58]", (lcu).cu[58]); \ CHECKPOINT_CU(prefix_str " cu[59]", (lcu).cu[59]); \ CHECKPOINT_CU(prefix_str " cu[60]", (lcu).cu[60]); \ CHECKPOINT_CU(prefix_str " cu[61]", (lcu).cu[61]); \ CHECKPOINT_CU(prefix_str " cu[62]", (lcu).cu[62]); \ CHECKPOINT_CU(prefix_str " cu[63]", (lcu).cu[63]); \ CHECKPOINT_CU(prefix_str " cu[64]", (lcu).cu[64]); \ CHECKPOINT_CU(prefix_str " cu[65]", (lcu).cu[65]); \ CHECKPOINT_CU(prefix_str " cu[66]", (lcu).cu[66]); \ CHECKPOINT_CU(prefix_str " cu[67]", (lcu).cu[67]); \ CHECKPOINT_CU(prefix_str " cu[68]", (lcu).cu[68]); \ CHECKPOINT_CU(prefix_str " cu[69]", (lcu).cu[69]); \ CHECKPOINT_CU(prefix_str " cu[70]", (lcu).cu[70]); \ CHECKPOINT_CU(prefix_str " cu[71]", (lcu).cu[71]); \ CHECKPOINT_CU(prefix_str " cu[72]", (lcu).cu[72]); \ CHECKPOINT_CU(prefix_str " cu[73]", (lcu).cu[73]); \ CHECKPOINT_CU(prefix_str " cu[74]", (lcu).cu[74]); \ CHECKPOINT_CU(prefix_str " cu[75]", (lcu).cu[75]); \ CHECKPOINT_CU(prefix_str " cu[76]", (lcu).cu[76]); \ CHECKPOINT_CU(prefix_str " cu[77]", (lcu).cu[77]); \ CHECKPOINT_CU(prefix_str " cu[78]", (lcu).cu[78]); \ CHECKPOINT_CU(prefix_str " cu[79]", (lcu).cu[79]); \ CHECKPOINT_CU(prefix_str " cu[80]", (lcu).cu[80]); \ CHECKPOINT_CU(prefix_str " cu[81]", (lcu).cu[81]); \ } while(0) /** * Check if CBF in a given level >= depth is true. */ static INLINE int cbf_is_set(uint16_t cbf, color_t plane) { return (cbf & (1 << (plane))) != 0; } /** * Check if CBF in a given level >= depth is true. */ static INLINE int cbf_is_set_any(uint16_t cbf) { return cbf_is_set(cbf, COLOR_Y) || cbf_is_set(cbf, COLOR_U) || cbf_is_set(cbf, COLOR_V); } /** * Set CBF in a level to true. */ static INLINE void cbf_set(uint16_t *cbf, color_t plane) { // Return value of the bit corresponding to the level. *cbf |= (1) << (plane); } /** * Set CBF in a level to true if it is set at a lower level in any of * the child_cbfs. */ static INLINE void cbf_set_conditionally(uint16_t *cbf, uint16_t child_cbfs[3], color_t plane) { bool child_cbf_set = cbf_is_set(child_cbfs[0], plane) || cbf_is_set(child_cbfs[1], plane) || cbf_is_set(child_cbfs[2], plane); if (child_cbf_set) { cbf_set(cbf, plane); } } /** */ static INLINE void cbf_clear(uint16_t *cbf, color_t plane) { *cbf &= ~(1 << (plane)); } /** * Copy cbf flags. */ static INLINE void cbf_copy(uint16_t *cbf, uint16_t src, color_t plane) { cbf_clear(cbf, plane); *cbf |= src & (1 << plane); } #define GET_SPLITDATA(CU,curDepth) (((CU)->split_tree >> ((curDepth) * 3)) & 7) #define PU_IS_TU(cu) ((cu)->log2_width <= TR_MAX_LOG2_SIZE && (cu)->log2_height <= TR_MAX_LOG2_SIZE) #endif