| /****************************************************************************** |
| * |
| * Copyright (C) 2015 The Android Open Source Project |
| * |
| * Licensed under the Apache License, Version 2.0 (the "License"); |
| * you may not use this file except in compliance with the License. |
| * You may obtain a copy of the License at: |
| * |
| * http://www.apache.org/licenses/LICENSE-2.0 |
| * |
| * Unless required by applicable law or agreed to in writing, software |
| * distributed under the License is distributed on an "AS IS" BASIS, |
| * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. |
| * See the License for the specific language governing permissions and |
| * limitations under the License. |
| * |
| ***************************************************************************** |
| * Originally developed and contributed by Ittiam Systems Pvt. Ltd, Bangalore |
| */ |
| |
| /** |
| ******************************************************************************* |
| * @file |
| * ih264e_intra_modes_eval.c |
| * |
| * @brief |
| * This file contains definitions of routines that perform rate distortion |
| * analysis on a macroblock if they are to be coded as intra. |
| * |
| * @author |
| * ittiam |
| * |
| * @par List of Functions: |
| * - ih264e_derive_neighbor_availability_of_mbs() |
| * - ih264e_derive_ngbr_avbl_of_mb_partitions() |
| * - ih264e_evaluate_intra16x16_modes_for_least_cost_rdoptoff() |
| * - ih264e_evaluate_intra8x8_modes_for_least_cost_rdoptoff() |
| * - ih264e_evaluate_intra4x4_modes_for_least_cost_rdoptoff() |
| * - ih264e_evaluate_intra4x4_modes_for_least_cost_rdopton() |
| * - ih264e_evaluate_chroma_intra8x8_modes_for_least_cost_rdoptoff() |
| * - ih264e_evaluate_intra16x16_modes() |
| * - ih264e_evaluate_intra4x4_modes() |
| * - ih264e_evaluate_intra_chroma_modes() |
| * |
| * @remarks |
| * None |
| * |
| ******************************************************************************* |
| */ |
| |
| /*****************************************************************************/ |
| /* File Includes */ |
| /*****************************************************************************/ |
| |
| /* System include files */ |
| #include <stdio.h> |
| #include <string.h> |
| #include <limits.h> |
| #include <assert.h> |
| |
| /* User include files */ |
| #include "ih264e_config.h" |
| #include "ih264_typedefs.h" |
| #include "ih264e_defs.h" |
| #include "iv2.h" |
| #include "ive2.h" |
| #include "ih264_debug.h" |
| #include "ih264_defs.h" |
| #include "ih264_macros.h" |
| #include "ih264_intra_pred_filters.h" |
| #include "ih264_structs.h" |
| #include "ih264_common_tables.h" |
| #include "ih264_trans_quant_itrans_iquant.h" |
| #include "ih264_inter_pred_filters.h" |
| #include "ih264_mem_fns.h" |
| #include "ih264_padding.h" |
| #include "ih264_deblk_edge_filters.h" |
| #include "ih264_cabac_tables.h" |
| #include "ime_distortion_metrics.h" |
| #include "ih264e_error.h" |
| #include "ih264e_bitstream.h" |
| #include "ime_defs.h" |
| #include "ime_structs.h" |
| #include "irc_cntrl_param.h" |
| #include "irc_frame_info_collector.h" |
| #include "ih264e_rate_control.h" |
| #include "ih264e_cabac_structs.h" |
| #include "ih264e_structs.h" |
| #include "ih264e_intra_modes_eval.h" |
| #include "ih264e_globals.h" |
| #include "ime_platform_macros.h" |
| |
| |
| /*****************************************************************************/ |
| /* Function Definitions */ |
| /*****************************************************************************/ |
| |
| /** |
| ****************************************************************************** |
| * |
| * @brief |
| * derivation process for macroblock availability |
| * |
| * @par Description |
| * Calculates the availability of the left, top, topright and topleft macroblocks. |
| * |
| * @param[in] ps_proc_ctxt |
| * pointer to proc context (handle) |
| * |
| * @remarks Based on section 6.4.5 in H264 spec |
| * |
| * @return none |
| * |
| ****************************************************************************** |
| */ |
| void ih264e_derive_nghbr_avbl_of_mbs(process_ctxt_t *ps_proc) |
| { |
| UWORD8 *pu1_slice_idx_curr = ps_proc->pu1_slice_idx; |
| UWORD8 *pu1_slice_idx_b; |
| UWORD8 *pu1_slice_idx_a; |
| UWORD8 *pu1_slice_idx_c; |
| UWORD8 *pu1_slice_idx_d; |
| block_neighbors_t *ps_ngbr_avbl; |
| WORD32 i4_mb_x, i4_mb_y; |
| WORD32 i4_wd_mbs; |
| |
| i4_mb_x = ps_proc->i4_mb_x; |
| i4_mb_y = ps_proc->i4_mb_y; |
| |
| i4_wd_mbs = ps_proc->i4_wd_mbs; |
| |
| pu1_slice_idx_curr += (i4_mb_y * i4_wd_mbs) + i4_mb_x; |
| pu1_slice_idx_a = pu1_slice_idx_curr - 1; |
| pu1_slice_idx_b = pu1_slice_idx_curr - i4_wd_mbs; |
| pu1_slice_idx_c = pu1_slice_idx_b + 1; |
| pu1_slice_idx_d = pu1_slice_idx_b - 1; |
| ps_ngbr_avbl = ps_proc->ps_ngbr_avbl; |
| |
| /**********************************************************************/ |
| /* The macroblock is marked as available, unless one of the following */ |
| /* conditions is true in which case the macroblock shall be marked as */ |
| /* not available. */ |
| /* 1. mbAddr < 0 */ |
| /* 2 mbAddr > CurrMbAddr */ |
| /* 3. the macroblock with address mbAddr belongs to a different slice */ |
| /* than the macroblock with address CurrMbAddr */ |
| /**********************************************************************/ |
| |
| /* left macroblock availability */ |
| if (i4_mb_x == 0) |
| { /* macroblocks along first column */ |
| ps_ngbr_avbl->u1_mb_a = 0; |
| } |
| else |
| { /* macroblocks belong to same slice? */ |
| if (*pu1_slice_idx_a != *pu1_slice_idx_curr) |
| ps_ngbr_avbl->u1_mb_a = 0; |
| else |
| ps_ngbr_avbl->u1_mb_a = 1; |
| } |
| |
| /* top macroblock availability */ |
| if (i4_mb_y == 0) |
| { /* macroblocks along first row */ |
| ps_ngbr_avbl->u1_mb_b = 0; |
| } |
| else |
| { /* macroblocks belong to same slice? */ |
| if (*pu1_slice_idx_b != *pu1_slice_idx_curr) |
| ps_ngbr_avbl->u1_mb_b = 0; |
| else |
| ps_ngbr_avbl->u1_mb_b = 1; |
| } |
| |
| /* top right macroblock availability */ |
| if (i4_mb_x == i4_wd_mbs-1 || i4_mb_y == 0) |
| { /* macroblocks along last column */ |
| ps_ngbr_avbl->u1_mb_c = 0; |
| } |
| else |
| { /* macroblocks belong to same slice? */ |
| if (*pu1_slice_idx_c != *pu1_slice_idx_curr) |
| ps_ngbr_avbl->u1_mb_c = 0; |
| else |
| ps_ngbr_avbl->u1_mb_c = 1; |
| } |
| |
| /* top left macroblock availability */ |
| if (i4_mb_x == 0 || i4_mb_y == 0) |
| { /* macroblocks along first column */ |
| ps_ngbr_avbl->u1_mb_d = 0; |
| } |
| else |
| { /* macroblocks belong to same slice? */ |
| if (*pu1_slice_idx_d != *pu1_slice_idx_curr) |
| ps_ngbr_avbl->u1_mb_d = 0; |
| else |
| ps_ngbr_avbl->u1_mb_d = 1; |
| } |
| } |
| |
| /** |
| ****************************************************************************** |
| * |
| * @brief |
| * derivation process for subblock/partition availability |
| * |
| * @par Description |
| * Calculates the availability of the left, top, topright and topleft subblock |
| * or partitions. |
| * |
| * @param[in] ps_proc_ctxt |
| * pointer to macroblock context (handle) |
| * |
| * @param[in] i1_pel_pos_x |
| * column position of the pel wrt the current block |
| * |
| * @param[in] i1_pel_pos_y |
| * row position of the pel in wrt current block |
| * |
| * @remarks Assumptions: before calling this function it is assumed that |
| * the neighbor availability of the current macroblock is already derived. |
| * Based on table 6-3 of H264 specification |
| * |
| * @return availability status (yes or no) |
| * |
| ****************************************************************************** |
| */ |
| UWORD8 ih264e_derive_ngbr_avbl_of_mb_partitions(block_neighbors_t *ps_ngbr_avbl, |
| WORD8 i1_pel_pos_x, |
| WORD8 i1_pel_pos_y) |
| { |
| UWORD8 u1_neighbor_avail=0; |
| |
| /**********************************************************************/ |
| /* values of i1_pel_pos_x in the range 0-15 inclusive correspond to */ |
| /* various columns of a macroblock */ |
| /* */ |
| /* values of i1_pel_pos_y in the range 0-15 inclusive correspond to */ |
| /* various rows of a macroblock */ |
| /* */ |
| /* other values of i1_pel_pos_x & i1_pel_pos_y represents elements */ |
| /* outside the bound of an mb ie., represents its neighbors. */ |
| /**********************************************************************/ |
| if (i1_pel_pos_x < 0) |
| { /* column(-1) */ |
| if (i1_pel_pos_y < 0) |
| { /* row(-1) */ |
| u1_neighbor_avail = ps_ngbr_avbl->u1_mb_d; /* current mb topleft availability */ |
| } |
| else if (i1_pel_pos_y >= 0 && i1_pel_pos_y < 16) |
| { /* all rows of a macroblock */ |
| u1_neighbor_avail = ps_ngbr_avbl->u1_mb_a; /* current mb left availability */ |
| } |
| else /* if (i1_pel_pos_y >= 16) */ |
| { /* rows(+16) */ |
| u1_neighbor_avail = 0; /* current mb bottom left availability */ |
| } |
| } |
| else if (i1_pel_pos_x >= 0 && i1_pel_pos_x < 16) |
| { /* all columns of a macroblock */ |
| if (i1_pel_pos_y < 0) |
| { /* row(-1) */ |
| u1_neighbor_avail = ps_ngbr_avbl->u1_mb_b; /* current mb top availability */ |
| } |
| else if (i1_pel_pos_y >= 0 && i1_pel_pos_y < 16) |
| { /* all rows of a macroblock */ |
| u1_neighbor_avail = 1; /* current mb availability */ |
| /* availability of the partition is dependent on the position of the partition inside the mb */ |
| /* although the availability is declared as 1 in all cases these needs to be corrected somewhere else and this is not done in here */ |
| } |
| else /* if (i1_pel_pos_y >= 16) */ |
| { /* rows(+16) */ |
| u1_neighbor_avail = 0; /* current mb bottom availability */ |
| } |
| } |
| else if (i1_pel_pos_x >= 16) |
| { /* column(+16) */ |
| if (i1_pel_pos_y < 0) |
| { /* row(-1) */ |
| u1_neighbor_avail = ps_ngbr_avbl->u1_mb_c; /* current mb top right availability */ |
| } |
| else /* if (i1_pel_pos_y >= 0) */ |
| { /* all other rows */ |
| u1_neighbor_avail = 0; /* current mb right & bottom right availability */ |
| } |
| } |
| |
| return u1_neighbor_avail; |
| } |
| |
| /** |
| ****************************************************************************** |
| * |
| * @brief |
| * evaluate best intra 16x16 mode (rate distortion opt off) |
| * |
| * @par Description |
| * This function evaluates all the possible intra 16x16 modes and finds the mode |
| * that best represents the macro-block (least distortion) and occupies fewer |
| * bits in the bit-stream. |
| * |
| * @param[in] ps_proc_ctxt |
| * pointer to process context (handle) |
| * |
| * @remarks |
| * Ideally the cost of encoding a macroblock is calculated as |
| * (distortion + lambda*rate). Where distortion is SAD/SATD,... between the |
| * input block and the reconstructed block and rate is the number of bits taken |
| * to place the macroblock in the bit-stream. In this routine the rate does not |
| * exactly point to the total number of bits it takes, rather it points to header |
| * bits necessary for encoding the macroblock. Assuming the deltaQP, cbp bits |
| * and residual bits fall in to texture bits the number of bits taken to encoding |
| * mbtype is considered as rate, we compute cost. Further we will approximate |
| * the distortion as the deviation b/w input and the predicted block as opposed |
| * to input and reconstructed block. |
| * |
| * NOTE: As per the Document JVT-O079, for intra 16x16 macroblock, |
| * the SAD and cost are one and the same. |
| * |
| * @return none |
| * |
| ****************************************************************************** |
| */ |
| |
| void ih264e_evaluate_intra16x16_modes_for_least_cost_rdoptoff(process_ctxt_t *ps_proc) |
| { |
| /* Codec Context */ |
| codec_t *ps_codec = ps_proc->ps_codec; |
| |
| /* SAD(distortion metric) of an 8x8 block */ |
| WORD32 i4_mb_distortion = INT_MAX, i4_mb_distortion_least = INT_MAX; |
| |
| /* lambda */ |
| UWORD32 u4_lambda = ps_proc->u4_lambda; |
| |
| /* cost = distortion + lambda*rate */ |
| WORD32 i4_mb_cost= INT_MAX, i4_mb_cost_least = INT_MAX; |
| |
| /* intra mode */ |
| UWORD32 u4_intra_mode, u4_best_intra_16x16_mode = DC_I16x16; |
| |
| /* neighbor pels for intra prediction */ |
| UWORD8 *pu1_ngbr_pels_i16 = ps_proc->au1_ngbr_pels; |
| |
| /* neighbor availability */ |
| WORD32 i4_ngbr_avbl; |
| |
| /* pointer to src macro block */ |
| UWORD8 *pu1_curr_mb = ps_proc->pu1_src_buf_luma; |
| UWORD8 *pu1_ref_mb = ps_proc->pu1_rec_buf_luma; |
| |
| /* pointer to prediction macro block */ |
| UWORD8 *pu1_pred_mb_intra_16x16 = ps_proc->pu1_pred_mb_intra_16x16; |
| UWORD8 *pu1_pred_mb_intra_16x16_plane = ps_proc->pu1_pred_mb_intra_16x16_plane; |
| |
| /* strides */ |
| WORD32 i4_src_strd = ps_proc->i4_src_strd; |
| WORD32 i4_pred_strd = ps_proc->i4_pred_strd; |
| WORD32 i4_rec_strd = ps_proc->i4_rec_strd; |
| |
| /* pointer to neighbors left, top, topleft */ |
| UWORD8 *pu1_mb_a = pu1_ref_mb - 1; |
| UWORD8 *pu1_mb_b = pu1_ref_mb - i4_rec_strd; |
| UWORD8 *pu1_mb_d = pu1_mb_b - 1; |
| UWORD8 u1_mb_a, u1_mb_b, u1_mb_d; |
| /* valid intra modes map */ |
| UWORD32 u4_valid_intra_modes; |
| |
| /* lut for valid intra modes */ |
| const UWORD8 u1_valid_intra_modes[8] = {4, 6, 4, 6, 5, 7, 5, 15}; |
| |
| /* temp var */ |
| UWORD32 i, u4_enable_fast_sad = 0, offset = 0; |
| mb_info_t *ps_top_mb_syn_ele = ps_proc->ps_top_row_mb_syntax_ele + ps_proc->i4_mb_x; |
| UWORD32 u4_constrained_intra_pred = ps_proc->ps_codec->s_cfg.u4_constrained_intra_pred; |
| |
| /* init temp var */ |
| if (ps_proc->i4_slice_type != ISLICE) |
| { |
| /* Offset for MBtype */ |
| offset = (ps_proc->i4_slice_type == PSLICE) ? 5 : 23; |
| u4_enable_fast_sad = ps_proc->s_me_ctxt.u4_enable_fast_sad; |
| } |
| |
| /* locating neighbors that are available for prediction */ |
| |
| /* gather prediction pels from the neighbors, if particular set is not available |
| * it is set to zero*/ |
| /* left pels */ |
| u1_mb_a = ((ps_proc->ps_ngbr_avbl->u1_mb_a) |
| && (u4_constrained_intra_pred ? ps_proc->s_left_mb_syntax_ele.u2_is_intra : 1)); |
| if (u1_mb_a) |
| { |
| for(i = 0; i < 16; i++) |
| pu1_ngbr_pels_i16[16-1-i] = pu1_mb_a[i * i4_rec_strd]; |
| } |
| else |
| { |
| ps_codec->pf_mem_set_mul8(pu1_ngbr_pels_i16,0,MB_SIZE); |
| } |
| /* top pels */ |
| u1_mb_b = ((ps_proc->ps_ngbr_avbl->u1_mb_b) |
| && (u4_constrained_intra_pred ? ps_top_mb_syn_ele->u2_is_intra : 1)); |
| if (u1_mb_b) |
| { |
| ps_codec->pf_mem_cpy_mul8(pu1_ngbr_pels_i16+16+1,pu1_mb_b,16); |
| } |
| else |
| { |
| ps_codec->pf_mem_set_mul8(pu1_ngbr_pels_i16+16+1,0,MB_SIZE); |
| } |
| /* topleft pels */ |
| u1_mb_d = ((ps_proc->ps_ngbr_avbl->u1_mb_d) |
| && (u4_constrained_intra_pred ? ps_proc->s_top_left_mb_syntax_ele.u2_is_intra : 1)); |
| if (u1_mb_d) |
| { |
| pu1_ngbr_pels_i16[16] = *pu1_mb_d; |
| } |
| else |
| { |
| pu1_ngbr_pels_i16[16] = 0; |
| } |
| |
| i4_ngbr_avbl = (u1_mb_a) + (u1_mb_b << 2) + (u1_mb_d << 1); |
| ps_proc->i4_ngbr_avbl_16x16_mb = i4_ngbr_avbl; |
| |
| /* set valid intra modes for evaluation */ |
| u4_valid_intra_modes = u1_valid_intra_modes[i4_ngbr_avbl]; |
| |
| if (ps_codec->s_cfg.u4_enc_speed_preset == IVE_FAST) |
| u4_valid_intra_modes &= ~(1 << PLANE_I16x16); |
| |
| /* evaluate b/w HORZ_I16x16, VERT_I16x16 & DC_I16x16 */ |
| ps_codec->pf_ih264e_evaluate_intra16x16_modes(pu1_curr_mb, pu1_ngbr_pels_i16, pu1_pred_mb_intra_16x16, |
| i4_src_strd, i4_pred_strd, |
| i4_ngbr_avbl, &u4_intra_mode, &i4_mb_distortion_least, |
| u4_valid_intra_modes); |
| |
| /* cost = distortion + lambda*rate */ |
| i4_mb_cost_least = i4_mb_distortion_least; |
| |
| if ((( (u4_valid_intra_modes >> 3) & 1) != 0) && (ps_codec->s_cfg.u4_enc_speed_preset != IVE_FASTEST || |
| ps_proc->i4_slice_type == ISLICE)) |
| { |
| /* intra prediction for PLANE mode*/ |
| (ps_codec->apf_intra_pred_16_l)[PLANE_I16x16](pu1_ngbr_pels_i16, pu1_pred_mb_intra_16x16_plane, 0, i4_pred_strd, i4_ngbr_avbl); |
| |
| /* evaluate distortion between the actual blk and the estimated blk for the given mode */ |
| ps_codec->apf_compute_sad_16x16[u4_enable_fast_sad](pu1_curr_mb, pu1_pred_mb_intra_16x16_plane, i4_src_strd, i4_pred_strd, i4_mb_cost_least, &i4_mb_distortion); |
| |
| /* cost = distortion + lambda*rate */ |
| i4_mb_cost = i4_mb_distortion; |
| |
| /* update the least cost information if necessary */ |
| if(i4_mb_cost < i4_mb_distortion_least) |
| { |
| u4_intra_mode = PLANE_I16x16; |
| |
| i4_mb_cost_least = i4_mb_cost; |
| i4_mb_distortion_least = i4_mb_distortion; |
| } |
| } |
| |
| u4_best_intra_16x16_mode = u4_intra_mode; |
| |
| DEBUG("%d partition cost, %d intra mode\n", i4_mb_cost_least * 32, u4_best_intra_16x16_mode); |
| |
| ps_proc->u1_l_i16_mode = u4_best_intra_16x16_mode; |
| |
| /* cost = distortion + lambda*rate */ |
| i4_mb_cost_least = i4_mb_distortion_least + u4_lambda*u1_uev_codelength[offset + u4_best_intra_16x16_mode]; |
| |
| |
| /* update the type of the mb if necessary */ |
| if (i4_mb_cost_least < ps_proc->i4_mb_cost) |
| { |
| ps_proc->i4_mb_cost = i4_mb_cost_least; |
| ps_proc->i4_mb_distortion = i4_mb_distortion_least; |
| ps_proc->u4_mb_type = I16x16; |
| } |
| |
| return ; |
| } |
| |
| |
| /** |
| ****************************************************************************** |
| * |
| * @brief |
| * evaluate best intra 8x8 mode (rate distortion opt on) |
| * |
| * @par Description |
| * This function evaluates all the possible intra 8x8 modes and finds the mode |
| * that best represents the macro-block (least distortion) and occupies fewer |
| * bits in the bit-stream. |
| * |
| * @param[in] ps_proc_ctxt |
| * pointer to proc ctxt |
| * |
| * @remarks Ideally the cost of encoding a macroblock is calculated as |
| * (distortion + lambda*rate). Where distortion is SAD/SATD,... between the |
| * input block and the reconstructed block and rate is the number of bits taken |
| * to place the macroblock in the bit-stream. In this routine the rate does not |
| * exactly point to the total number of bits it takes, rather it points to header |
| * bits necessary for encoding the macroblock. Assuming the deltaQP, cbp bits |
| * and residual bits fall in to texture bits the number of bits taken to encoding |
| * mbtype is considered as rate, we compute cost. Further we will approximate |
| * the distortion as the deviation b/w input and the predicted block as opposed |
| * to input and reconstructed block. |
| * |
| * NOTE: TODO: This function needs to be tested |
| * |
| * @return none |
| * |
| ****************************************************************************** |
| */ |
| void ih264e_evaluate_intra8x8_modes_for_least_cost_rdoptoff(process_ctxt_t *ps_proc) |
| { |
| /* Codec Context */ |
| codec_t *ps_codec = ps_proc->ps_codec; |
| |
| /* SAD(distortion metric) of an 4x4 block */ |
| WORD32 i4_partition_distortion, i4_partition_distortion_least = INT_MAX, i4_total_distortion = 0; |
| |
| /* lambda */ |
| UWORD32 u4_lambda = ps_proc->u4_lambda; |
| |
| /* cost = distortion + lambda*rate */ |
| WORD32 i4_partition_cost, i4_partition_cost_least, i4_total_cost = u4_lambda; |
| |
| /* cost due to mbtype */ |
| UWORD32 u4_cost_one_bit = u4_lambda, u4_cost_four_bits = 4 * u4_lambda; |
| |
| /* intra mode */ |
| UWORD32 u4_intra_mode, u4_best_intra_8x8_mode = DC_I8x8, u4_estimated_intra_8x8_mode; |
| |
| /* neighbor pels for intra prediction */ |
| UWORD8 *pu1_ngbr_pels_i8 = ps_proc->au1_ngbr_pels; |
| |
| /* pointer to curr partition */ |
| UWORD8 *pu1_mb_curr; |
| |
| /* pointer to prediction macro block */ |
| UWORD8 *pu1_pred_mb = ps_proc->pu1_pred_mb; |
| |
| /* strides */ |
| WORD32 i4_src_strd = ps_proc->i4_src_strd; |
| WORD32 i4_pred_strd = ps_proc->i4_pred_strd; |
| |
| /* neighbors left, top, top right, top left */ |
| UWORD8 *pu1_mb_a; |
| UWORD8 *pu1_mb_b; |
| UWORD8 *pu1_mb_d; |
| |
| /* neighbor availability */ |
| WORD32 i4_ngbr_avbl; |
| block_neighbors_t s_ngbr_avbl; |
| |
| /* temp vars */ |
| UWORD32 b8, u4_pix_x, u4_pix_y; |
| UWORD32 u4_constrained_intra_pred = ps_proc->ps_codec->s_cfg.u4_constrained_intra_pred; |
| block_neighbors_t s_ngbr_avbl_MB; |
| |
| /* ngbr mb syntax information */ |
| UWORD8 *pu1_top_mb_intra_modes = ps_proc->pu1_top_mb_intra_modes + (ps_proc->i4_mb_x << 4); |
| mb_info_t *ps_top_mb_syn_ele = ps_proc->ps_top_row_mb_syntax_ele + ps_proc->i4_mb_x; |
| mb_info_t *ps_top_right_mb_syn_ele = ps_proc->ps_top_row_mb_syntax_ele + ps_proc->i4_mb_x; |
| /* valid intra modes map */ |
| UWORD32 u4_valid_intra_modes; |
| |
| if (ps_proc->ps_ngbr_avbl->u1_mb_c) |
| { |
| ps_top_right_mb_syn_ele = ps_proc->ps_top_row_mb_syntax_ele + (ps_proc->i4_mb_x + 1); |
| } |
| /* left pels */ |
| s_ngbr_avbl_MB.u1_mb_a = ((ps_proc->ps_ngbr_avbl->u1_mb_a) |
| && (u4_constrained_intra_pred ? ps_proc->s_left_mb_syntax_ele.u2_is_intra : 1)); |
| |
| /* top pels */ |
| s_ngbr_avbl_MB.u1_mb_b = ((ps_proc->ps_ngbr_avbl->u1_mb_b) |
| && (u4_constrained_intra_pred ? ps_top_mb_syn_ele->u2_is_intra : 1)); |
| |
| /* topleft pels */ |
| s_ngbr_avbl_MB.u1_mb_d = ((ps_proc->ps_ngbr_avbl->u1_mb_d) |
| && (u4_constrained_intra_pred ? ps_proc->s_top_left_mb_syntax_ele.u2_is_intra : 1)); |
| |
| /* top right */ |
| s_ngbr_avbl_MB.u1_mb_c = ((ps_proc->ps_ngbr_avbl->u1_mb_c) |
| && (u4_constrained_intra_pred ? ps_top_right_mb_syn_ele->u2_is_intra : 1)); |
| |
| |
| for(b8 = 0; b8 < 4; b8++) |
| { |
| u4_pix_x = (b8 & 0x01) << 3; |
| u4_pix_y = (b8 >> 1) << 3; |
| |
| pu1_mb_curr = ps_proc->pu1_src_buf_luma + u4_pix_x + (u4_pix_y * i4_src_strd); |
| /* when rdopt is off, we use the input as reference for constructing prediction buffer */ |
| /* as opposed to using the recon pels. (open loop intra prediction) */ |
| pu1_mb_a = pu1_mb_curr - 1; /* pointer to left macro block */ |
| pu1_mb_b = pu1_mb_curr - i4_src_strd; /* pointer to top macro block */ |
| pu1_mb_d = pu1_mb_b - 1; /* pointer to top left macro block */ |
| |
| /* locating neighbors that are available for prediction */ |
| /* TODO : update the neighbor availability information basing on constrained intra pred information */ |
| /* TODO : i4_ngbr_avbl is only being used in DC mode. Can the DC mode be split in to distinct routines */ |
| /* basing on neighbors available and hence evade the computation of neighbor availability totally. */ |
| s_ngbr_avbl.u1_mb_a = ih264e_derive_ngbr_avbl_of_mb_partitions(&s_ngbr_avbl_MB, u4_pix_x - 1, u4_pix_y); /* xD = -1, yD = 0 */ |
| s_ngbr_avbl.u1_mb_b = ih264e_derive_ngbr_avbl_of_mb_partitions(&s_ngbr_avbl_MB, u4_pix_x, u4_pix_y - 1); /* xD = 0, yD = -1 */ |
| s_ngbr_avbl.u1_mb_c = ih264e_derive_ngbr_avbl_of_mb_partitions(&s_ngbr_avbl_MB, u4_pix_x + 8, u4_pix_y - 1); /* xD = BLK_8x8_SIZE, yD = -1 */ |
| s_ngbr_avbl.u1_mb_d = ih264e_derive_ngbr_avbl_of_mb_partitions(&s_ngbr_avbl_MB, u4_pix_x - 1, u4_pix_y - 1); /* xD = -1, yD = -1 */ |
| |
| /* i4_ngbr_avbl = blk_a * LEFT_MB_AVAILABLE_MASK + blk_b * TOP_MB_AVAILABLE_MASK + blk_c * TOP_RIGHT_MB_AVAILABLE_MASK + blk_d * TOP_LEFT_MB_AVAILABLE_MASK */ |
| i4_ngbr_avbl = (s_ngbr_avbl.u1_mb_a) + (s_ngbr_avbl.u1_mb_d << 1) + (s_ngbr_avbl.u1_mb_b << 2) + (s_ngbr_avbl.u1_mb_c << 3) + |
| (s_ngbr_avbl.u1_mb_a << 4); |
| /* if top partition is available and top right is not available for intra prediction, then */ |
| /* padd top right samples using top sample and make top right also available */ |
| /* i4_ngbr_avbl = (s_ngbr_avbl.u1_mb_a) + (s_ngbr_avbl.u1_mb_d << 1) + (s_ngbr_avbl.u1_mb_b << 2) + ((s_ngbr_avbl.u1_mb_b | s_ngbr_avbl.u1_mb_c) << 3); */ |
| ps_proc->ai4_neighbor_avail_8x8_subblks[b8] = i4_ngbr_avbl; |
| |
| |
| ih264_intra_pred_luma_8x8_mode_ref_filtering(pu1_mb_a, pu1_mb_b, pu1_mb_d, pu1_ngbr_pels_i8, |
| i4_src_strd, i4_ngbr_avbl); |
| |
| i4_partition_cost_least = INT_MAX; |
| /* set valid intra modes for evaluation */ |
| u4_valid_intra_modes = 0x1ff; |
| |
| if (!s_ngbr_avbl.u1_mb_b) |
| { |
| u4_valid_intra_modes &= ~(1 << VERT_I4x4); |
| u4_valid_intra_modes &= ~(1 << DIAG_DL_I4x4); |
| u4_valid_intra_modes &= ~(1 << VERT_L_I4x4); |
| } |
| if (!s_ngbr_avbl.u1_mb_a) |
| { |
| u4_valid_intra_modes &= ~(1 << HORZ_I4x4); |
| u4_valid_intra_modes &= ~(1 << HORZ_U_I4x4); |
| } |
| if (!s_ngbr_avbl.u1_mb_a || !s_ngbr_avbl.u1_mb_b || !s_ngbr_avbl.u1_mb_d) |
| { |
| u4_valid_intra_modes &= ~(1 << DIAG_DR_I4x4); |
| u4_valid_intra_modes &= ~(1 << VERT_R_I4x4); |
| u4_valid_intra_modes &= ~(1 << HORZ_D_I4x4); |
| } |
| |
| /* estimate the intra 8x8 mode for the current partition (for evaluating cost) */ |
| if (!s_ngbr_avbl.u1_mb_a || !s_ngbr_avbl.u1_mb_b) |
| { |
| u4_estimated_intra_8x8_mode = DC_I8x8; |
| } |
| else |
| { |
| UWORD32 u4_left_intra_8x8_mode = DC_I8x8; |
| UWORD32 u4_top_intra_8x8_mode = DC_I8x8; |
| |
| if (u4_pix_x == 0) |
| { |
| if (ps_proc->s_left_mb_syntax_ele.u2_mb_type == I8x8) |
| { |
| u4_left_intra_8x8_mode = ps_proc->au1_left_mb_intra_modes[b8+1]; |
| } |
| else if (ps_proc->s_left_mb_syntax_ele.u2_mb_type == I4x4) |
| { |
| u4_left_intra_8x8_mode = ps_proc->au1_left_mb_intra_modes[(b8+1)*4+2]; |
| } |
| } |
| else |
| { |
| u4_left_intra_8x8_mode = ps_proc->au1_intra_luma_mb_8x8_modes[b8-1]; |
| } |
| |
| if (u4_pix_y == 0) |
| { |
| if (ps_top_mb_syn_ele->u2_mb_type == I8x8) |
| { |
| u4_top_intra_8x8_mode = pu1_top_mb_intra_modes[b8+2]; |
| } |
| else if (ps_top_mb_syn_ele->u2_mb_type == I4x4) |
| { |
| u4_top_intra_8x8_mode = pu1_top_mb_intra_modes[(b8+2)*4+2]; |
| } |
| } |
| else |
| { |
| u4_top_intra_8x8_mode = ps_proc->au1_intra_luma_mb_8x8_modes[b8-2]; |
| } |
| |
| u4_estimated_intra_8x8_mode = MIN(u4_left_intra_8x8_mode, u4_top_intra_8x8_mode); |
| } |
| |
| /* perform intra mode 8x8 evaluation */ |
| for (u4_intra_mode = VERT_I8x8; u4_valid_intra_modes != 0; u4_intra_mode++, u4_valid_intra_modes >>= 1) |
| { |
| if ( (u4_valid_intra_modes & 1) == 0) |
| continue; |
| |
| /* intra prediction */ |
| (ps_codec->apf_intra_pred_8_l)[u4_intra_mode](pu1_ngbr_pels_i8, pu1_pred_mb, 0, i4_pred_strd, i4_ngbr_avbl); |
| |
| /* evaluate distortion between the actual blk and the estimated blk for the given mode */ |
| ime_compute_sad_8x8(pu1_mb_curr, pu1_pred_mb, i4_src_strd, i4_pred_strd, i4_partition_cost_least, &i4_partition_distortion); |
| |
| i4_partition_cost = i4_partition_distortion + ((u4_estimated_intra_8x8_mode == u4_intra_mode)?u4_cost_one_bit:u4_cost_four_bits); |
| |
| /* update the least cost information if necessary */ |
| if (i4_partition_cost < i4_partition_cost_least) |
| { |
| i4_partition_cost_least = i4_partition_cost; |
| i4_partition_distortion_least = i4_partition_distortion; |
| u4_best_intra_8x8_mode = u4_intra_mode; |
| } |
| } |
| /* macroblock distortion */ |
| i4_total_cost += i4_partition_cost_least; |
| i4_total_distortion += i4_partition_distortion_least; |
| /* mb partition mode */ |
| ps_proc->au1_intra_luma_mb_8x8_modes[b8] = u4_best_intra_8x8_mode; |
| |
| } |
| |
| /* update the type of the mb if necessary */ |
| if (i4_total_cost < ps_proc->i4_mb_cost) |
| { |
| ps_proc->i4_mb_cost = i4_total_cost; |
| ps_proc->i4_mb_distortion = i4_total_distortion; |
| ps_proc->u4_mb_type = I8x8; |
| } |
| |
| return ; |
| } |
| |
| |
| /** |
| ****************************************************************************** |
| * |
| * @brief |
| * evaluate best intra 4x4 mode (rate distortion opt off) |
| * |
| * @par Description |
| * This function evaluates all the possible intra 4x4 modes and finds the mode |
| * that best represents the macro-block (least distortion) and occupies fewer |
| * bits in the bit-stream. |
| * |
| * @param[in] ps_proc_ctxt |
| * pointer to proc ctxt |
| * |
| * @remarks |
| * Ideally the cost of encoding a macroblock is calculated as |
| * (distortion + lambda*rate). Where distortion is SAD/SATD,... between the |
| * input block and the reconstructed block and rate is the number of bits taken |
| * to place the macroblock in the bit-stream. In this routine the rate does not |
| * exactly point to the total number of bits it takes, rather it points to header |
| * bits necessary for encoding the macroblock. Assuming the deltaQP, cbp bits |
| * and residual bits fall in to texture bits the number of bits taken to encoding |
| * mbtype is considered as rate, we compute cost. Further we will approximate |
| * the distortion as the deviation b/w input and the predicted block as opposed |
| * to input and reconstructed block. |
| * |
| * NOTE: As per the Document JVT-O079, for the whole intra 4x4 macroblock, |
| * 24*lambda is added to the SAD before comparison with the best SAD for |
| * inter prediction. This is an empirical value to prevent using too many intra |
| * blocks. |
| * |
| * @return none |
| * |
| ****************************************************************************** |
| */ |
| void ih264e_evaluate_intra4x4_modes_for_least_cost_rdoptoff(process_ctxt_t *ps_proc) |
| { |
| /* Codec Context */ |
| codec_t *ps_codec = ps_proc->ps_codec; |
| |
| /* SAD(distortion metric) of an 4x4 block */ |
| WORD32 i4_partition_distortion_least = INT_MAX, i4_total_distortion = 0; |
| |
| /* lambda */ |
| UWORD32 u4_lambda = ps_proc->u4_lambda; |
| |
| /* cost = distortion + lambda*rate */ |
| WORD32 i4_partition_cost_least, i4_total_cost = (24 + 1) * u4_lambda; |
| |
| /* cost due to mbtype */ |
| UWORD32 u4_cost_one_bit = u4_lambda, u4_cost_four_bits = 4 * u4_lambda; |
| |
| /* intra mode */ |
| UWORD32 u4_best_intra_4x4_mode = DC_I4x4, u4_estimated_intra_4x4_mode; |
| |
| /* neighbor pels for intra prediction */ |
| UWORD8 *pu1_ngbr_pels_i4 = ps_proc->au1_ngbr_pels; |
| |
| /* pointer to curr partition */ |
| UWORD8 *pu1_mb_curr; |
| |
| /* pointer to prediction macro block */ |
| UWORD8 *pu1_pred_mb = ps_proc->pu1_pred_mb; |
| |
| /* strides */ |
| WORD32 i4_src_strd = ps_proc->i4_src_strd; |
| WORD32 i4_pred_strd = ps_proc->i4_pred_strd; |
| |
| /* neighbors left, top, top right, top left */ |
| UWORD8 *pu1_mb_a; |
| UWORD8 *pu1_mb_b; |
| UWORD8 *pu1_mb_c; |
| UWORD8 *pu1_mb_d; |
| |
| /* neighbor availability */ |
| WORD32 i4_ngbr_avbl; |
| block_neighbors_t s_ngbr_avbl; |
| |
| /* temp vars */ |
| UWORD32 i, b8, b4, u4_blk_x, u4_blk_y, u4_pix_x, u4_pix_y; |
| |
| /* scan order inside 4x4 block */ |
| const UWORD8 u1_scan_order[16] = {0, 1, 4, 5, 2, 3, 6, 7, 8, 9, 12, 13, 10, 11, 14, 15}; |
| |
| /* ngbr sub mb modes */ |
| UWORD8 *pu1_top_mb_intra_modes = ps_proc->pu1_top_mb_intra_modes + (ps_proc->i4_mb_x << 4); |
| mb_info_t *ps_top_mb_syn_ele = ps_proc->ps_top_row_mb_syntax_ele + ps_proc->i4_mb_x; |
| mb_info_t *ps_top_right_mb_syn_ele = ps_proc->ps_top_row_mb_syntax_ele + ps_proc->i4_mb_x; |
| |
| /* valid intra modes map */ |
| UWORD32 u4_valid_intra_modes; |
| UWORD16 u2_valid_modes[8] = {4, 262, 4, 262, 141, 399, 141, 511}; |
| |
| UWORD32 u4_constrained_intra_pred = ps_proc->ps_codec->s_cfg.u4_constrained_intra_pred; |
| UWORD8 u1_mb_a, u1_mb_b, u1_mb_c, u1_mb_d; |
| if (ps_proc->ps_ngbr_avbl->u1_mb_c) |
| { |
| ps_top_right_mb_syn_ele = ps_proc->ps_top_row_mb_syntax_ele + ps_proc->i4_mb_x + 1; |
| } |
| /* left pels */ |
| u1_mb_a = ((ps_proc->ps_ngbr_avbl->u1_mb_a) |
| && (u4_constrained_intra_pred ? ps_proc->s_left_mb_syntax_ele.u2_is_intra : 1)); |
| |
| /* top pels */ |
| u1_mb_b = ((ps_proc->ps_ngbr_avbl->u1_mb_b) |
| && (u4_constrained_intra_pred ? ps_top_mb_syn_ele->u2_is_intra : 1)); |
| |
| /* topleft pels */ |
| u1_mb_d = ((ps_proc->ps_ngbr_avbl->u1_mb_d) |
| && (u4_constrained_intra_pred ? ps_proc->s_top_left_mb_syntax_ele.u2_is_intra : 1)); |
| |
| /* top right */ |
| u1_mb_c = ((ps_proc->ps_ngbr_avbl->u1_mb_c) |
| && (u4_constrained_intra_pred ? ps_top_right_mb_syn_ele->u2_is_intra : 1)); |
| |
| i4_ngbr_avbl = (u1_mb_a) + (u1_mb_d << 1) + (u1_mb_b << 2) + (u1_mb_c << 3); |
| memcpy(ps_proc->au1_ngbr_avbl_4x4_subblks, gau1_ih264_4x4_ngbr_avbl[i4_ngbr_avbl], 16); |
| |
| for (b8 = 0; b8 < 4; b8++) |
| { |
| u4_blk_x = (b8 & 0x01) << 3; |
| u4_blk_y = (b8 >> 1) << 3; |
| for (b4 = 0; b4 < 4; b4++) |
| { |
| u4_pix_x = u4_blk_x + ((b4 & 0x01) << 2); |
| u4_pix_y = u4_blk_y + ((b4 >> 1) << 2); |
| |
| pu1_mb_curr = ps_proc->pu1_src_buf_luma + u4_pix_x + (u4_pix_y * i4_src_strd); |
| /* when rdopt is off, we use the input as reference for constructing prediction buffer */ |
| /* as opposed to using the recon pels. (open loop intra prediction) */ |
| pu1_mb_a = pu1_mb_curr - 1; /* pointer to left macro block */ |
| pu1_mb_b = pu1_mb_curr - i4_src_strd; /* pointer to top macro block */ |
| pu1_mb_c = pu1_mb_b + 4; /* pointer to top macro block */ |
| pu1_mb_d = pu1_mb_b - 1; /* pointer to top left macro block */ |
| |
| /* locating neighbors that are available for prediction */ |
| /* TODO : update the neighbor availability information basing on constrained intra pred information */ |
| /* TODO : i4_ngbr_avbl is only being used in DC mode. Can the DC mode be split in to distinct routines */ |
| /* basing on neighbors available and hence evade the computation of neighbor availability totally. */ |
| |
| i4_ngbr_avbl = ps_proc->au1_ngbr_avbl_4x4_subblks[(b8 << 2) + b4]; |
| s_ngbr_avbl.u1_mb_a = (i4_ngbr_avbl & 0x1); |
| s_ngbr_avbl.u1_mb_d = (i4_ngbr_avbl & 0x2) >> 1; |
| s_ngbr_avbl.u1_mb_b = (i4_ngbr_avbl & 0x4) >> 2; |
| s_ngbr_avbl.u1_mb_c = (i4_ngbr_avbl & 0x8) >> 3; |
| /* set valid intra modes for evaluation */ |
| u4_valid_intra_modes = u2_valid_modes[i4_ngbr_avbl & 0x7]; |
| |
| /* if top partition is available and top right is not available for intra prediction, then */ |
| /* padd top right samples using top sample and make top right also available */ |
| /* i4_ngbr_avbl = (s_ngbr_avbl.u1_mb_a) + (s_ngbr_avbl.u1_mb_d << 1) + (s_ngbr_avbl.u1_mb_b << 2) + ((s_ngbr_avbl.u1_mb_b | s_ngbr_avbl.u1_mb_c) << 3); */ |
| |
| /* gather prediction pels from the neighbors */ |
| if (s_ngbr_avbl.u1_mb_a) |
| { |
| for(i = 0; i < 4; i++) |
| pu1_ngbr_pels_i4[4 - 1 -i] = pu1_mb_a[i * i4_src_strd]; |
| } |
| else |
| { |
| memset(pu1_ngbr_pels_i4, 0, 4); |
| } |
| |
| if (s_ngbr_avbl.u1_mb_b) |
| { |
| memcpy(pu1_ngbr_pels_i4 + 4 + 1, pu1_mb_b, 4); |
| } |
| else |
| { |
| memset(pu1_ngbr_pels_i4 + 5, 0, 4); |
| } |
| |
| if (s_ngbr_avbl.u1_mb_d) |
| pu1_ngbr_pels_i4[4] = *pu1_mb_d; |
| else |
| pu1_ngbr_pels_i4[4] = 0; |
| |
| if (s_ngbr_avbl.u1_mb_c) |
| { |
| memcpy(pu1_ngbr_pels_i4 + 8 + 1, pu1_mb_c, 4); |
| } |
| else if (s_ngbr_avbl.u1_mb_b) |
| { |
| memset(pu1_ngbr_pels_i4 + 8 + 1, pu1_ngbr_pels_i4[8], 4); |
| s_ngbr_avbl.u1_mb_c = s_ngbr_avbl.u1_mb_b; |
| } |
| |
| i4_partition_cost_least = INT_MAX; |
| |
| /* predict the intra 4x4 mode for the current partition (for evaluating cost) */ |
| if (!s_ngbr_avbl.u1_mb_a || !s_ngbr_avbl.u1_mb_b) |
| { |
| u4_estimated_intra_4x4_mode = DC_I4x4; |
| } |
| else |
| { |
| UWORD32 u4_left_intra_4x4_mode = DC_I4x4; |
| UWORD32 u4_top_intra_4x4_mode = DC_I4x4; |
| |
| if (u4_pix_x == 0) |
| { |
| if (ps_proc->s_left_mb_syntax_ele.u2_mb_type == I4x4) |
| { |
| u4_left_intra_4x4_mode = ps_proc->au1_left_mb_intra_modes[u1_scan_order[3 + u4_pix_y]]; |
| } |
| else if (ps_proc->s_left_mb_syntax_ele.u2_mb_type == I8x8) |
| { |
| u4_left_intra_4x4_mode = ps_proc->au1_left_mb_intra_modes[b8 + 1]; |
| } |
| } |
| else |
| { |
| u4_left_intra_4x4_mode = ps_proc->au1_intra_luma_mb_4x4_modes[u1_scan_order[(u4_pix_x >> 2) + u4_pix_y - 1]]; |
| } |
| |
| if (u4_pix_y == 0) |
| { |
| if (ps_top_mb_syn_ele->u2_mb_type == I4x4) |
| { |
| u4_top_intra_4x4_mode = pu1_top_mb_intra_modes[u1_scan_order[12 + (u4_pix_x >> 2)]]; |
| } |
| else if (ps_top_mb_syn_ele->u2_mb_type == I8x8) |
| { |
| u4_top_intra_4x4_mode = pu1_top_mb_intra_modes[b8 + 2]; |
| } |
| } |
| else |
| { |
| u4_top_intra_4x4_mode = ps_proc->au1_intra_luma_mb_4x4_modes[u1_scan_order[(u4_pix_x >> 2) + u4_pix_y - 4]]; |
| } |
| |
| u4_estimated_intra_4x4_mode = MIN(u4_left_intra_4x4_mode, u4_top_intra_4x4_mode); |
| } |
| |
| ps_proc->au1_predicted_intra_luma_mb_4x4_modes[(b8 << 2) + b4] = u4_estimated_intra_4x4_mode; |
| |
| /* mode evaluation and prediction */ |
| ps_codec->pf_ih264e_evaluate_intra_4x4_modes(pu1_mb_curr, |
| pu1_ngbr_pels_i4, |
| pu1_pred_mb, i4_src_strd, |
| i4_pred_strd, i4_ngbr_avbl, |
| &u4_best_intra_4x4_mode, |
| &i4_partition_cost_least, |
| u4_valid_intra_modes, |
| u4_lambda, |
| u4_estimated_intra_4x4_mode); |
| |
| |
| i4_partition_distortion_least = i4_partition_cost_least - ((u4_estimated_intra_4x4_mode == u4_best_intra_4x4_mode) ? u4_cost_one_bit : u4_cost_four_bits); |
| |
| DEBUG("%d partition cost, %d intra mode\n", i4_partition_cost_least, u4_best_intra_4x4_mode); |
| /* macroblock distortion */ |
| i4_total_distortion += i4_partition_distortion_least; |
| i4_total_cost += i4_partition_cost_least; |
| /* mb partition mode */ |
| ps_proc->au1_intra_luma_mb_4x4_modes[(b8 << 2) + b4] = u4_best_intra_4x4_mode; |
| } |
| } |
| |
| /* update the type of the mb if necessary */ |
| if (i4_total_cost < ps_proc->i4_mb_cost) |
| { |
| ps_proc->i4_mb_cost = i4_total_cost; |
| ps_proc->i4_mb_distortion = i4_total_distortion; |
| ps_proc->u4_mb_type = I4x4; |
| } |
| |
| return ; |
| } |
| |
| /** |
| ****************************************************************************** |
| * |
| * @brief evaluate best intra 4x4 mode (rate distortion opt on) |
| * |
| * @par Description |
| * This function evaluates all the possible intra 4x4 modes and finds the mode |
| * that best represents the macro-block (least distortion) and occupies fewer |
| * bits in the bit-stream. |
| * |
| * @param[in] ps_proc_ctxt |
| * pointer to proc ctxt |
| * |
| * @remarks |
| * Ideally the cost of encoding a macroblock is calculated as |
| * (distortion + lambda*rate). Where distortion is SAD/SATD,... between the |
| * input block and the reconstructed block and rate is the number of bits taken |
| * to place the macroblock in the bit-stream. In this routine the rate does not |
| * exactly point to the total number of bits it takes, rather it points to header |
| * bits necessary for encoding the macroblock. Assuming the deltaQP, cbp bits |
| * and residual bits fall in to texture bits the number of bits taken to encoding |
| * mbtype is considered as rate, we compute cost. Further we will approximate |
| * the distortion as the deviation b/w input and the predicted block as opposed |
| * to input and reconstructed block. |
| * |
| * NOTE: As per the Document JVT-O079, for the whole intra 4x4 macroblock, |
| * 24*lambda is added to the SAD before comparison with the best SAD for |
| * inter prediction. This is an empirical value to prevent using too many intra |
| * blocks. |
| * |
| * @return none |
| * |
| ****************************************************************************** |
| */ |
| void ih264e_evaluate_intra4x4_modes_for_least_cost_rdopton(process_ctxt_t *ps_proc) |
| { |
| /* Codec Context */ |
| codec_t *ps_codec = ps_proc->ps_codec; |
| |
| /* SAD(distortion metric) of an 4x4 block */ |
| WORD32 i4_partition_distortion_least = INT_MAX, i4_total_distortion = 0; |
| |
| /* lambda */ |
| UWORD32 u4_lambda = ps_proc->u4_lambda; |
| |
| /* cost = distortion + lambda*rate */ |
| WORD32 i4_partition_cost_least, i4_total_cost = (24 + 1) * u4_lambda; |
| |
| /* cost due to mbtype */ |
| UWORD32 u4_cost_one_bit = u4_lambda, u4_cost_four_bits = 4 * u4_lambda; |
| |
| /* intra mode */ |
| UWORD32 u4_best_intra_4x4_mode = DC_I4x4, u4_estimated_intra_4x4_mode; |
| |
| /* neighbor pels for intra prediction */ |
| UWORD8 *pu1_ngbr_pels_i4 = ps_proc->au1_ngbr_pels; |
| |
| /* pointer to curr partition */ |
| UWORD8 *pu1_mb_curr; |
| UWORD8 *pu1_mb_ref_left, *pu1_mb_ref_top; |
| UWORD8 *pu1_ref_mb_intra_4x4; |
| |
| /* pointer to residual macro block */ |
| WORD16 *pi2_res_mb = ps_proc->pi2_res_buf_intra_4x4; |
| |
| /* pointer to prediction macro block */ |
| UWORD8 *pu1_pred_mb = ps_proc->pu1_pred_mb; |
| |
| /* strides */ |
| WORD32 i4_src_strd = ps_proc->i4_src_strd; |
| WORD32 i4_pred_strd = ps_proc->i4_pred_strd; |
| WORD32 i4_ref_strd_left, i4_ref_strd_top; |
| |
| /* neighbors left, top, top right, top left */ |
| UWORD8 *pu1_mb_a; |
| UWORD8 *pu1_mb_b; |
| UWORD8 *pu1_mb_c; |
| UWORD8 *pu1_mb_d; |
| |
| /* number of non zero coeffs*/ |
| UWORD8 *pu1_nnz = (UWORD8 *)ps_proc->au4_nnz_intra_4x4; |
| |
| /* quantization parameters */ |
| quant_params_t *ps_qp_params = ps_proc->ps_qp_params[0]; |
| |
| /* neighbor availability */ |
| WORD32 i4_ngbr_avbl; |
| block_neighbors_t s_ngbr_avbl; |
| |
| /* temp vars */ |
| UWORD32 i, b8, b4, u4_blk_x, u4_blk_y, u4_pix_x, u4_pix_y; |
| |
| /* scan order inside 4x4 block */ |
| const UWORD8 u1_scan_order[16] = {0, 1, 4, 5, 2, 3, 6, 7, 8, 9, 12, 13, 10, 11, 14, 15}; |
| |
| /* ngbr sub mb modes */ |
| UWORD8 *pu1_top_mb_intra_modes = ps_proc->pu1_top_mb_intra_modes + (ps_proc->i4_mb_x << 4); |
| mb_info_t *ps_top_mb_syn_ele = ps_proc->ps_top_row_mb_syntax_ele + ps_proc->i4_mb_x; |
| mb_info_t *ps_top_right_mb_syn_ele = ps_proc->ps_top_row_mb_syntax_ele + ps_proc->i4_mb_x; |
| |
| /* valid intra modes map */ |
| UWORD32 u4_valid_intra_modes; |
| UWORD16 u2_valid_modes[8] = {4, 262, 4, 262, 141, 399, 141, 511}; |
| |
| /* Dummy variable for 4x4 trans function */ |
| WORD16 i2_dc_dummy; |
| UWORD8 u1_mb_a, u1_mb_b, u1_mb_c, u1_mb_d; |
| UWORD32 u4_constrained_intra_pred = ps_proc->ps_codec->s_cfg.u4_constrained_intra_pred; |
| |
| /* compute ngbr availability for sub blks */ |
| if (ps_proc->ps_ngbr_avbl->u1_mb_c) |
| { |
| ps_top_right_mb_syn_ele = ps_proc->ps_top_row_mb_syntax_ele + (ps_proc->i4_mb_x + 1); |
| } |
| |
| /* left pels */ |
| u1_mb_a = ((ps_proc->ps_ngbr_avbl->u1_mb_a) |
| && (u4_constrained_intra_pred ? ps_proc->s_left_mb_syntax_ele.u2_is_intra : 1)); |
| |
| /* top pels */ |
| u1_mb_b = ((ps_proc->ps_ngbr_avbl->u1_mb_b) |
| && (u4_constrained_intra_pred ? ps_top_mb_syn_ele->u2_is_intra : 1)); |
| |
| /* topleft pels */ |
| u1_mb_d = ((ps_proc->ps_ngbr_avbl->u1_mb_d) |
| && (u4_constrained_intra_pred ? ps_proc->s_top_left_mb_syntax_ele.u2_is_intra : 1)); |
| |
| /* top right pels */ |
| u1_mb_c = ((ps_proc->ps_ngbr_avbl->u1_mb_c) |
| && (u4_constrained_intra_pred ? ps_top_right_mb_syn_ele->u2_is_intra : 1)); |
| |
| i4_ngbr_avbl = (u1_mb_a) + (u1_mb_d << 1) + (u1_mb_b << 2) + (u1_mb_c << 3); |
| memcpy(ps_proc->au1_ngbr_avbl_4x4_subblks, gau1_ih264_4x4_ngbr_avbl[i4_ngbr_avbl], 16); |
| |
| for(b8 = 0; b8 < 4; b8++) |
| { |
| u4_blk_x = (b8 & 0x01) << 3; |
| u4_blk_y = (b8 >> 1) << 3; |
| for(b4 = 0; b4 < 4; b4++, pu1_nnz++, pi2_res_mb += MB_SIZE) |
| { |
| u4_pix_x = u4_blk_x + ((b4 & 0x01) << 2); |
| u4_pix_y = u4_blk_y + ((b4 >> 1) << 2); |
| |
| pu1_ref_mb_intra_4x4 = ps_proc->pu1_ref_mb_intra_4x4 + u4_pix_x + (u4_pix_y * i4_pred_strd); |
| pu1_mb_curr = ps_proc->pu1_src_buf_luma + u4_pix_x + (u4_pix_y * i4_src_strd); |
| if (u4_pix_x == 0) |
| { |
| i4_ref_strd_left = ps_proc->i4_rec_strd; |
| pu1_mb_ref_left = ps_proc->pu1_rec_buf_luma + u4_pix_x + (u4_pix_y * i4_ref_strd_left); |
| } |
| else |
| { |
| i4_ref_strd_left = i4_pred_strd; |
| pu1_mb_ref_left = pu1_ref_mb_intra_4x4; |
| } |
| if (u4_pix_y == 0) |
| { |
| i4_ref_strd_top = ps_proc->i4_rec_strd; |
| pu1_mb_ref_top = ps_proc->pu1_rec_buf_luma + u4_pix_x + (u4_pix_y * i4_ref_strd_top); |
| } |
| else |
| { |
| i4_ref_strd_top = i4_pred_strd; |
| pu1_mb_ref_top = pu1_ref_mb_intra_4x4; |
| } |
| |
| pu1_mb_a = pu1_mb_ref_left - 1; /* pointer to left macro block */ |
| pu1_mb_b = pu1_mb_ref_top - i4_ref_strd_top; /* pointer to top macro block */ |
| pu1_mb_c = pu1_mb_b + 4; /* pointer to top right macro block */ |
| if (u4_pix_y == 0) |
| pu1_mb_d = pu1_mb_b - 1; |
| else |
| pu1_mb_d = pu1_mb_a - i4_ref_strd_left; /* pointer to top left macro block */ |
| |
| /* locating neighbors that are available for prediction */ |
| /* TODO : update the neighbor availability information basing on constrained intra pred information */ |
| /* TODO : i4_ngbr_avbl is only being used in DC mode. Can the DC mode be split in to distinct routines */ |
| /* basing on neighbors available and hence evade the computation of neighbor availability totally. */ |
| |
| i4_ngbr_avbl = ps_proc->au1_ngbr_avbl_4x4_subblks[(b8 << 2) + b4]; |
| s_ngbr_avbl.u1_mb_a = (i4_ngbr_avbl & 0x1); |
| s_ngbr_avbl.u1_mb_d = (i4_ngbr_avbl & 0x2) >> 1; |
| s_ngbr_avbl.u1_mb_b = (i4_ngbr_avbl & 0x4) >> 2; |
| s_ngbr_avbl.u1_mb_c = (i4_ngbr_avbl & 0x8) >> 3; |
| /* set valid intra modes for evaluation */ |
| u4_valid_intra_modes = u2_valid_modes[i4_ngbr_avbl & 0x7]; |
| |
| /* if top partition is available and top right is not available for intra prediction, then */ |
| /* padd top right samples using top sample and make top right also available */ |
| /* i4_ngbr_avbl = (s_ngbr_avbl.u1_mb_a) + (s_ngbr_avbl.u1_mb_d << 1) + (s_ngbr_avbl.u1_mb_b << 2) + ((s_ngbr_avbl.u1_mb_b | s_ngbr_avbl.u1_mb_c) << 3); */ |
| |
| /* gather prediction pels from the neighbors */ |
| if (s_ngbr_avbl.u1_mb_a) |
| { |
| for(i = 0; i < 4; i++) |
| pu1_ngbr_pels_i4[4 - 1 -i] = pu1_mb_a[i * i4_ref_strd_left]; |
| } |
| else |
| { |
| memset(pu1_ngbr_pels_i4,0,4); |
| } |
| if(s_ngbr_avbl.u1_mb_b) |
| { |
| memcpy(pu1_ngbr_pels_i4 + 4 + 1, pu1_mb_b, 4); |
| } |
| else |
| { |
| memset(pu1_ngbr_pels_i4 + 4 + 1, 0, 4); |
| } |
| if (s_ngbr_avbl.u1_mb_d) |
| pu1_ngbr_pels_i4[4] = *pu1_mb_d; |
| else |
| pu1_ngbr_pels_i4[4] = 0; |
| if (s_ngbr_avbl.u1_mb_c) |
| { |
| memcpy(pu1_ngbr_pels_i4 + 8 + 1, pu1_mb_c, 4); |
| } |
| else if (s_ngbr_avbl.u1_mb_b) |
| { |
| memset(pu1_ngbr_pels_i4 + 8 + 1, pu1_ngbr_pels_i4[8], 4); |
| s_ngbr_avbl.u1_mb_c = s_ngbr_avbl.u1_mb_b; |
| } |
| |
| i4_partition_cost_least = INT_MAX; |
| |
| /* predict the intra 4x4 mode for the current partition (for evaluating cost) */ |
| if (!s_ngbr_avbl.u1_mb_a || !s_ngbr_avbl.u1_mb_b) |
| { |
| u4_estimated_intra_4x4_mode = DC_I4x4; |
| } |
| else |
| { |
| UWORD32 u4_left_intra_4x4_mode = DC_I4x4; |
| UWORD32 u4_top_intra_4x4_mode = DC_I4x4; |
| |
| if (u4_pix_x == 0) |
| { |
| if (ps_proc->s_left_mb_syntax_ele.u2_mb_type == I4x4) |
| { |
| u4_left_intra_4x4_mode = ps_proc->au1_left_mb_intra_modes[u1_scan_order[3 + u4_pix_y]]; |
| } |
| else if (ps_proc->s_left_mb_syntax_ele.u2_mb_type == I8x8) |
| { |
| u4_left_intra_4x4_mode = ps_proc->au1_left_mb_intra_modes[b8 + 1]; |
| } |
| } |
| else |
| { |
| u4_left_intra_4x4_mode = ps_proc->au1_intra_luma_mb_4x4_modes[u1_scan_order[(u4_pix_x >> 2) + u4_pix_y - 1]]; |
| } |
| |
| if (u4_pix_y == 0) |
| { |
| if (ps_top_mb_syn_ele->u2_mb_type == I4x4) |
| { |
| u4_top_intra_4x4_mode = pu1_top_mb_intra_modes[u1_scan_order[12 + (u4_pix_x >> 2)]]; |
| } |
| else if (ps_top_mb_syn_ele->u2_mb_type == I8x8) |
| { |
| u4_top_intra_4x4_mode = pu1_top_mb_intra_modes[b8 + 2]; |
| } |
| } |
| else |
| { |
| u4_top_intra_4x4_mode = ps_proc->au1_intra_luma_mb_4x4_modes[u1_scan_order[(u4_pix_x >> 2) + u4_pix_y - 4]]; |
| } |
| |
| u4_estimated_intra_4x4_mode = MIN(u4_left_intra_4x4_mode, u4_top_intra_4x4_mode); |
| } |
| |
| ps_proc->au1_predicted_intra_luma_mb_4x4_modes[(b8 << 2) + b4] = u4_estimated_intra_4x4_mode; |
| |
| /*mode evaluation and prediction*/ |
| ps_codec->pf_ih264e_evaluate_intra_4x4_modes(pu1_mb_curr, |
| pu1_ngbr_pels_i4, |
| pu1_pred_mb, i4_src_strd, |
| i4_pred_strd, i4_ngbr_avbl, |
| &u4_best_intra_4x4_mode, |
| &i4_partition_cost_least, |
| u4_valid_intra_modes, |
| u4_lambda, |
| u4_estimated_intra_4x4_mode); |
| |
| |
| i4_partition_distortion_least = i4_partition_cost_least - ((u4_estimated_intra_4x4_mode == u4_best_intra_4x4_mode)?u4_cost_one_bit:u4_cost_four_bits); |
| |
| DEBUG("%d partition cost, %d intra mode\n", i4_partition_cost_least, u4_best_intra_4x4_mode); |
| |
| /* macroblock distortion */ |
| i4_total_distortion += i4_partition_distortion_least; |
| i4_total_cost += i4_partition_cost_least; |
| |
| /* mb partition mode */ |
| ps_proc->au1_intra_luma_mb_4x4_modes[(b8 << 2) + b4] = u4_best_intra_4x4_mode; |
| |
| |
| /********************************************************/ |
| /* error estimation, */ |
| /* transform */ |
| /* quantization */ |
| /********************************************************/ |
| ps_codec->pf_resi_trans_quant_4x4(pu1_mb_curr, pu1_pred_mb, |
| pi2_res_mb, i4_src_strd, |
| i4_pred_strd, |
| /* No op stride, this implies a buff of lenght 1x16 */ |
| ps_qp_params->pu2_scale_mat, |
| ps_qp_params->pu2_thres_mat, |
| ps_qp_params->u1_qbits, |
| ps_qp_params->u4_dead_zone, |
| pu1_nnz, &i2_dc_dummy); |
| |
| /********************************************************/ |
| /* ierror estimation, */ |
| /* itransform */ |
| /* iquantization */ |
| /********************************************************/ |
| ps_codec->pf_iquant_itrans_recon_4x4(pi2_res_mb, pu1_pred_mb, |
| pu1_ref_mb_intra_4x4, |
| i4_pred_strd, i4_pred_strd, |
| ps_qp_params->pu2_iscale_mat, |
| ps_qp_params->pu2_weigh_mat, |
| ps_qp_params->u1_qp_div, |
| ps_proc->pv_scratch_buff, 0, |
| NULL); |
| } |
| } |
| |
| /* update the type of the mb if necessary */ |
| if (i4_total_cost < ps_proc->i4_mb_cost) |
| { |
| ps_proc->i4_mb_cost = i4_total_cost; |
| ps_proc->i4_mb_distortion = i4_total_distortion; |
| ps_proc->u4_mb_type = I4x4; |
| } |
| |
| return ; |
| } |
| |
| /** |
| ****************************************************************************** |
| * |
| * @brief |
| * evaluate best chroma intra 8x8 mode (rate distortion opt off) |
| * |
| * @par Description |
| * This function evaluates all the possible chroma intra 8x8 modes and finds |
| * the mode that best represents the macroblock (least distortion) and occupies |
| * fewer bits in the bitstream. |
| * |
| * @param[in] ps_proc_ctxt |
| * pointer to macroblock context (handle) |
| * |
| * @remarks |
| * For chroma best intra pred mode is calculated based only on SAD |
| * |
| * @returns none |
| * |
| ****************************************************************************** |
| */ |
| |
| void ih264e_evaluate_chroma_intra8x8_modes_for_least_cost_rdoptoff(process_ctxt_t *ps_proc) |
| { |
| /* Codec Context */ |
| codec_t *ps_codec = ps_proc->ps_codec; |
| |
| /* SAD(distortion metric) of an 8x8 block */ |
| WORD32 i4_mb_distortion, i4_chroma_mb_distortion; |
| |
| /* intra mode */ |
| UWORD32 u4_best_chroma_intra_8x8_mode = DC_CH_I8x8; |
| |
| /* neighbor pels for intra prediction */ |
| UWORD8 *pu1_ngbr_pels_c_i8x8 = ps_proc->au1_ngbr_pels; |
| |
| /* pointer to curr macro block */ |
| UWORD8 *pu1_curr_mb = ps_proc->pu1_src_buf_chroma; |
| UWORD8 *pu1_ref_mb = ps_proc->pu1_rec_buf_chroma; |
| |
| /* pointer to prediction macro block */ |
| UWORD8 *pu1_pred_mb = ps_proc->pu1_pred_mb_intra_chroma; |
| UWORD8 *pu1_pred_mb_plane = ps_proc->pu1_pred_mb_intra_chroma_plane; |
| |
| /* strides */ |
| WORD32 i4_src_strd_c = ps_proc->i4_src_chroma_strd; |
| WORD32 i4_pred_strd = ps_proc->i4_pred_strd; |
| WORD32 i4_rec_strd_c = ps_proc->i4_rec_strd; |
| |
| /* neighbors left, top, top left */ |
| UWORD8 *pu1_mb_a = pu1_ref_mb - 2; |
| UWORD8 *pu1_mb_b = pu1_ref_mb - i4_rec_strd_c; |
| UWORD8 *pu1_mb_d = pu1_mb_b - 2; |
| |
| /* neighbor availability */ |
| const UWORD8 u1_valid_intra_modes[8] = {1, 3, 1, 3, 5, 7, 5, 15}; |
| WORD32 i4_ngbr_avbl; |
| |
| /* valid intra modes map */ |
| UWORD32 u4_valid_intra_modes; |
| mb_info_t *ps_top_mb_syn_ele = ps_proc->ps_top_row_mb_syntax_ele + ps_proc->i4_mb_x; |
| |
| /* temp var */ |
| UWORD8 i; |
| UWORD32 u4_constrained_intra_pred = ps_proc->ps_codec->s_cfg.u4_constrained_intra_pred; |
| UWORD8 u1_mb_a, u1_mb_b, u1_mb_d; |
| /* locating neighbors that are available for prediction */ |
| |
| /* gather prediction pels from the neighbors */ |
| /* left pels */ |
| u1_mb_a = ((ps_proc->ps_ngbr_avbl->u1_mb_a) |
| && (u4_constrained_intra_pred ? ps_proc->s_left_mb_syntax_ele.u2_is_intra : 1)); |
| if (u1_mb_a) |
| { |
| for (i = 0; i < 16; i += 2) |
| { |
| pu1_ngbr_pels_c_i8x8[16 - 2 - i] = pu1_mb_a[(i / 2) * i4_rec_strd_c]; |
| pu1_ngbr_pels_c_i8x8[16 - 1 - i] = pu1_mb_a[(i / 2) * i4_rec_strd_c + 1]; |
| } |
| } |
| else |
| { |
| ps_codec->pf_mem_set_mul8(pu1_ngbr_pels_c_i8x8, 0, MB_SIZE); |
| } |
| |
| /* top pels */ |
| u1_mb_b = ((ps_proc->ps_ngbr_avbl->u1_mb_b) |
| && (u4_constrained_intra_pred ? ps_top_mb_syn_ele->u2_is_intra : 1)); |
| if (u1_mb_b) |
| { |
| ps_codec->pf_mem_cpy_mul8(&pu1_ngbr_pels_c_i8x8[18], pu1_mb_b, 16); |
| } |
| else |
| { |
| ps_codec->pf_mem_set_mul8((pu1_ngbr_pels_c_i8x8 + 18), 0, MB_SIZE); |
| } |
| |
| /* top left pels */ |
| u1_mb_d = ((ps_proc->ps_ngbr_avbl->u1_mb_d) |
| && (u4_constrained_intra_pred ? ps_proc->s_top_left_mb_syntax_ele.u2_is_intra : 1)); |
| if (u1_mb_d) |
| { |
| pu1_ngbr_pels_c_i8x8[16] = *pu1_mb_d; |
| pu1_ngbr_pels_c_i8x8[17] = *(pu1_mb_d + 1); |
| } |
| i4_ngbr_avbl = (u1_mb_a) + (u1_mb_b << 2) + (u1_mb_d << 1); |
| ps_proc->i4_chroma_neighbor_avail_8x8_mb = i4_ngbr_avbl; |
| |
| u4_valid_intra_modes = u1_valid_intra_modes[i4_ngbr_avbl]; |
| |
| if (ps_codec->s_cfg.u4_enc_speed_preset == IVE_FAST) |
| u4_valid_intra_modes &= ~(1 << PLANE_CH_I8x8); |
| |
| i4_chroma_mb_distortion = INT_MAX; |
| |
| /* perform intra mode chroma 8x8 evaluation */ |
| /* intra prediction */ |
| ps_codec->pf_ih264e_evaluate_intra_chroma_modes(pu1_curr_mb, |
| pu1_ngbr_pels_c_i8x8, |
| pu1_pred_mb, |
| i4_src_strd_c, |
| i4_pred_strd, |
| i4_ngbr_avbl, |
| &u4_best_chroma_intra_8x8_mode, |
| &i4_chroma_mb_distortion, |
| u4_valid_intra_modes); |
| |
| if (u4_valid_intra_modes & 8)/* if Chroma PLANE is valid*/ |
| { |
| (ps_codec->apf_intra_pred_c)[PLANE_CH_I8x8](pu1_ngbr_pels_c_i8x8, pu1_pred_mb_plane, 0, i4_pred_strd, i4_ngbr_avbl); |
| |
| /* evaluate distortion(sad) */ |
| ps_codec->pf_compute_sad_16x8(pu1_curr_mb, pu1_pred_mb_plane, i4_src_strd_c, i4_pred_strd, i4_chroma_mb_distortion, &i4_mb_distortion); |
| |
| /* update the least distortion information if necessary */ |
| if(i4_mb_distortion < i4_chroma_mb_distortion) |
| { |
| i4_chroma_mb_distortion = i4_mb_distortion; |
| u4_best_chroma_intra_8x8_mode = PLANE_CH_I8x8; |
| } |
| } |
| |
| DEBUG("%d partition cost, %d intra mode\n", i4_chroma_mb_distortion, u4_best_chroma_intra_8x8_mode); |
| |
| ps_proc->u1_c_i8_mode = u4_best_chroma_intra_8x8_mode; |
| |
| return ; |
| } |
| |
| |
| /** |
| ****************************************************************************** |
| * |
| * @brief |
| * Evaluate best intra 16x16 mode (among VERT, HORZ and DC) and do the |
| * prediction. |
| * |
| * @par Description |
| * This function evaluates first three 16x16 modes and compute corresponding sad |
| * and return the buffer predicted with best mode. |
| * |
| * @param[in] pu1_src |
| * UWORD8 pointer to the source |
| * |
| * @param[in] pu1_ngbr_pels_i16 |
| * UWORD8 pointer to neighbouring pels |
| * |
| * @param[out] pu1_dst |
| * UWORD8 pointer to the destination |
| * |
| * @param[in] src_strd |
| * integer source stride |
| * |
| * @param[in] dst_strd |
| * integer destination stride |
| * |
| * @param[in] u4_n_avblty |
| * availability of neighbouring pixels |
| * |
| * @param[in] u4_intra_mode |
| * Pointer to the variable in which best mode is returned |
| * |
| * @param[in] pu4_sadmin |
| * Pointer to the variable in which minimum sad is returned |
| * |
| * @param[in] u4_valid_intra_modes |
| * Says what all modes are valid |
| * |
| * @returns none |
| * |
| ****************************************************************************** |
| */ |
| void ih264e_evaluate_intra16x16_modes(UWORD8 *pu1_src, |
| UWORD8 *pu1_ngbr_pels_i16, |
| UWORD8 *pu1_dst, |
| UWORD32 src_strd, |
| UWORD32 dst_strd, |
| WORD32 u4_n_avblty, |
| UWORD32 *u4_intra_mode, |
| WORD32 *pu4_sadmin, |
| UWORD32 u4_valid_intra_modes) |
| { |
| UWORD8 *pu1_neighbour; |
| UWORD8 *pu1_src_temp = pu1_src; |
| UWORD8 left = 0, top = 0; |
| WORD32 u4_dcval = 0; |
| WORD32 i, j; |
| WORD32 i4_sad_vert = INT_MAX, i4_sad_horz = INT_MAX, i4_sad_dc = INT_MAX, |
| i4_min_sad = INT_MAX; |
| UWORD8 val; |
| |
| left = (u4_n_avblty & LEFT_MB_AVAILABLE_MASK); |
| top = (u4_n_avblty & TOP_MB_AVAILABLE_MASK) >> 2; |
| |
| /* left available */ |
| if (left) |
| { |
| i4_sad_horz = 0; |
| |
| for (i = 0; i < 16; i++) |
| { |
| val = pu1_ngbr_pels_i16[15 - i]; |
| |
| u4_dcval += val; |
| |
| for (j = 0; j < 16; j++) |
| { |
| i4_sad_horz += ABS(val - pu1_src_temp[j]); |
| } |
| |
| pu1_src_temp += src_strd; |
| } |
| u4_dcval += 8; |
| } |
| |
| pu1_src_temp = pu1_src; |
| /* top available */ |
| if (top) |
| { |
| i4_sad_vert = 0; |
| |
| for (i = 0; i < 16; i++) |
| { |
| u4_dcval += pu1_ngbr_pels_i16[17 + i]; |
| |
| for (j = 0; j < 16; j++) |
| { |
| i4_sad_vert += ABS(pu1_ngbr_pels_i16[17 + j] - pu1_src_temp[j]); |
| } |
| pu1_src_temp += src_strd; |
| |
| } |
| u4_dcval += 8; |
| } |
| |
| u4_dcval = (u4_dcval) >> (3 + left + top); |
| |
| pu1_src_temp = pu1_src; |
| |
| /* none available */ |
| u4_dcval += (left == 0) * (top == 0) * 128; |
| |
| i4_sad_dc = 0; |
| |
| for (i = 0; i < 16; i++) |
| { |
| for (j = 0; j < 16; j++) |
| { |
| i4_sad_dc += ABS(u4_dcval - pu1_src_temp[j]); |
| } |
| pu1_src_temp += src_strd; |
| } |
| |
| if ((u4_valid_intra_modes & 04) == 0)/* If DC is disabled */ |
| i4_sad_dc = INT_MAX; |
| |
| if ((u4_valid_intra_modes & 01) == 0)/* If VERT is disabled */ |
| i4_sad_vert = INT_MAX; |
| |
| if ((u4_valid_intra_modes & 02) == 0)/* If HORZ is disabled */ |
| i4_sad_horz = INT_MAX; |
| |
| i4_min_sad = MIN3(i4_sad_horz, i4_sad_dc, i4_sad_vert); |
| |
| /* Finding Minimum sad and doing corresponding prediction */ |
| if (i4_min_sad < *pu4_sadmin) |
| { |
| *pu4_sadmin = i4_min_sad; |
| if (i4_min_sad == i4_sad_vert) |
| { |
| *u4_intra_mode = VERT_I16x16; |
| pu1_neighbour = pu1_ngbr_pels_i16 + 17; |
| for (j = 0; j < 16; j++) |
| { |
| memcpy(pu1_dst, pu1_neighbour, MB_SIZE); |
| pu1_dst += dst_strd; |
| } |
| } |
| else if (i4_min_sad == i4_sad_horz) |
| { |
| *u4_intra_mode = HORZ_I16x16; |
| for (j = 0; j < 16; j++) |
| { |
| val = pu1_ngbr_pels_i16[15 - j]; |
| memset(pu1_dst, val, MB_SIZE); |
| pu1_dst += dst_strd; |
| } |
| } |
| else |
| { |
| *u4_intra_mode = DC_I16x16; |
| for (j = 0; j < 16; j++) |
| { |
| memset(pu1_dst, u4_dcval, MB_SIZE); |
| pu1_dst += dst_strd; |
| } |
| } |
| } |
| return; |
| } |
| |
| /** |
| ****************************************************************************** |
| * |
| * @brief |
| * Evaluate best intra 4x4 mode and perform prediction. |
| * |
| * @par Description |
| * This function evaluates 4x4 modes and compute corresponding sad |
| * and return the buffer predicted with best mode. |
| * |
| * @param[in] pu1_src |
| * UWORD8 pointer to the source |
| * |
| * @param[in] pu1_ngbr_pels |
| * UWORD8 pointer to neighbouring pels |
| * |
| * @param[out] pu1_dst |
| * UWORD8 pointer to the destination |
| * |
| * @param[in] src_strd |
| * integer source stride |
| * |
| * @param[in] dst_strd |
| * integer destination stride |
| * |
| * @param[in] u4_n_avblty |
| * availability of neighbouring pixels |
| * |
| * @param[in] u4_intra_mode |
| * Pointer to the variable in which best mode is returned |
| * |
| * @param[in] pu4_sadmin |
| * Pointer to the variable in which minimum cost is returned |
| * |
| * @param[in] u4_valid_intra_modes |
| * Says what all modes are valid |
| * |
| * @param[in] u4_lambda |
| * Lamda value for computing cost from SAD |
| * |
| * @param[in] u4_predictd_mode |
| * Predicted mode for cost computation |
| * |
| * @returns none |
| * |
| ****************************************************************************** |
| */ |
| void ih264e_evaluate_intra_4x4_modes(UWORD8 *pu1_src, |
| UWORD8 *pu1_ngbr_pels, |
| UWORD8 *pu1_dst, |
| UWORD32 src_strd, |
| UWORD32 dst_strd, |
| WORD32 u4_n_avblty, |
| UWORD32 *u4_intra_mode, |
| WORD32 *pu4_sadmin, |
| UWORD32 u4_valid_intra_modes, |
| UWORD32 u4_lambda, |
| UWORD32 u4_predictd_mode) |
| { |
| UWORD8 *pu1_src_temp = pu1_src; |
| UWORD8 *pu1_pred = pu1_ngbr_pels; |
| UWORD8 left = 0, top = 0; |
| UWORD8 u1_pred_val = 0; |
| UWORD8 u1_pred_vals[4] = {0}; |
| UWORD8 *pu1_pred_val = NULL; |
| /* To store FILT121 operated values*/ |
| UWORD8 u1_pred_vals_diag_121[15] = {0}; |
| /* To store FILT11 operated values*/ |
| UWORD8 u1_pred_vals_diag_11[15] = {0}; |
| UWORD8 u1_pred_vals_vert_r[8] = {0}; |
| UWORD8 u1_pred_vals_horz_d[10] = {0}; |
| UWORD8 u1_pred_vals_horz_u[10] = {0}; |
| WORD32 u4_dcval = 0; |
| WORD32 i4_sad[MAX_I4x4] = {INT_MAX, INT_MAX, INT_MAX, INT_MAX, INT_MAX, |
| INT_MAX, INT_MAX, INT_MAX, INT_MAX}; |
| |
| WORD32 i4_cost[MAX_I4x4] = {INT_MAX, INT_MAX, INT_MAX, INT_MAX, INT_MAX, |
| INT_MAX, INT_MAX, INT_MAX, INT_MAX}; |
| WORD32 i, i4_min_cost = INT_MAX; |
| |
| left = (u4_n_avblty & LEFT_MB_AVAILABLE_MASK); |
| top = (u4_n_avblty & TOP_MB_AVAILABLE_MASK) >> 2; |
| |
| /* Computing SAD */ |
| |
| /* VERT mode valid */ |
| if (u4_valid_intra_modes & 1) |
| { |
| pu1_pred = pu1_ngbr_pels + 5; |
| i4_sad[VERT_I4x4] = 0; |
| i4_cost[VERT_I4x4] = 0; |
| |
| USADA8(pu1_src_temp, pu1_pred, i4_sad[VERT_I4x4]); |
| pu1_src_temp += src_strd; |
| USADA8(pu1_src_temp, pu1_pred, i4_sad[VERT_I4x4]); |
| pu1_src_temp += src_strd; |
| USADA8(pu1_src_temp, pu1_pred, i4_sad[VERT_I4x4]); |
| pu1_src_temp += src_strd; |
| USADA8(pu1_src_temp, pu1_pred, i4_sad[VERT_I4x4]); |
| |
| i4_cost[VERT_I4x4] = i4_sad[VERT_I4x4] + ((u4_predictd_mode == VERT_I4x4) ? |
| u4_lambda : 4 * u4_lambda); |
| } |
| |
| /* HORZ mode valid */ |
| if (u4_valid_intra_modes & 2) |
| { |
| i4_sad[HORZ_I4x4] = 0; |
| i4_cost[HORZ_I4x4] =0; |
| pu1_src_temp = pu1_src; |
| |
| u1_pred_val = pu1_ngbr_pels[3]; |
| |
| i4_sad[HORZ_I4x4] += ABS(pu1_src_temp[0] - u1_pred_val) |
| + ABS(pu1_src_temp[1] - u1_pred_val) |
| + ABS(pu1_src_temp[2] - u1_pred_val) |
| + ABS(pu1_src_temp[3] - u1_pred_val); |
| pu1_src_temp += src_strd; |
| |
| u1_pred_val = pu1_ngbr_pels[2]; |
| |
| i4_sad[HORZ_I4x4] += ABS(pu1_src_temp[0] - u1_pred_val) |
| + ABS(pu1_src_temp[1] - u1_pred_val) |
| + ABS(pu1_src_temp[2] - u1_pred_val) |
| + ABS(pu1_src_temp[3] - u1_pred_val); |
| pu1_src_temp += src_strd; |
| |
| u1_pred_val = pu1_ngbr_pels[1]; |
| |
| i4_sad[HORZ_I4x4] += ABS(pu1_src_temp[0] - u1_pred_val) |
| + ABS(pu1_src_temp[1] - u1_pred_val) |
| + ABS(pu1_src_temp[2] - u1_pred_val) |
| + ABS(pu1_src_temp[3] - u1_pred_val); |
| pu1_src_temp += src_strd; |
| |
| u1_pred_val = pu1_ngbr_pels[0]; |
| |
| i4_sad[HORZ_I4x4] += ABS(pu1_src_temp[0] - u1_pred_val) |
| + ABS(pu1_src_temp[1] - u1_pred_val) |
| + ABS(pu1_src_temp[2] - u1_pred_val) |
| + ABS(pu1_src_temp[3] - u1_pred_val); |
| |
| i4_cost[HORZ_I4x4] = i4_sad[HORZ_I4x4] + ((u4_predictd_mode == HORZ_I4x4) ? |
| u4_lambda : 4 * u4_lambda); |
| } |
| |
| /* DC mode valid */ |
| if (u4_valid_intra_modes & 4) |
| { |
| i4_sad[DC_I4x4] = 0; |
| i4_cost[DC_I4x4] = 0; |
| pu1_src_temp = pu1_src; |
| |
| if (left) |
| u4_dcval = pu1_ngbr_pels[0] + pu1_ngbr_pels[1] + pu1_ngbr_pels[2] |
| + pu1_ngbr_pels[3] + 2; |
| if (top) |
| u4_dcval += pu1_ngbr_pels[5] + pu1_ngbr_pels[6] + pu1_ngbr_pels[7] |
| + pu1_ngbr_pels[8] + 2; |
| |
| u4_dcval = (u4_dcval) ? (u4_dcval >> (1 + left + top)) : 128; |
| |
| /* none available */ |
| memset(u1_pred_vals, u4_dcval, 4); |
| USADA8(pu1_src_temp, u1_pred_vals, i4_sad[DC_I4x4]); |
| pu1_src_temp += src_strd; |
| USADA8(pu1_src_temp, u1_pred_vals, i4_sad[DC_I4x4]); |
| pu1_src_temp += src_strd; |
| USADA8(pu1_src_temp, u1_pred_vals, i4_sad[DC_I4x4]); |
| pu1_src_temp += src_strd; |
| USADA8(pu1_src_temp, u1_pred_vals, i4_sad[DC_I4x4]); |
| pu1_src_temp += src_strd; |
| |
| i4_cost[DC_I4x4] = i4_sad[DC_I4x4] + ((u4_predictd_mode == DC_I4x4) ? |
| u4_lambda : 4 * u4_lambda); |
| } |
| |
| /* if modes other than VERT, HORZ and DC are valid */ |
| if (u4_valid_intra_modes > 7) |
| { |
| pu1_pred = pu1_ngbr_pels; |
| pu1_pred[13] = pu1_pred[14] = pu1_pred[12]; |
| |
| /* Performing FILT121 and FILT11 operation for all neighbour values*/ |
| for (i = 0; i < 13; i++) |
| { |
| u1_pred_vals_diag_121[i] = FILT121(pu1_pred[0], pu1_pred[1], pu1_pred[2]); |
| u1_pred_vals_diag_11[i] = FILT11(pu1_pred[0], pu1_pred[1]); |
| |
| pu1_pred++; |
| } |
| |
| if (u4_valid_intra_modes & 8)/* DIAG_DL */ |
| { |
| i4_sad[DIAG_DL_I4x4] = 0; |
| i4_cost[DIAG_DL_I4x4] = 0; |
| pu1_src_temp = pu1_src; |
| pu1_pred_val = u1_pred_vals_diag_121 + 5; |
| |
| USADA8(pu1_src_temp, pu1_pred_val, i4_sad[DIAG_DL_I4x4]); |
| pu1_src_temp += src_strd; |
| USADA8(pu1_src_temp, (pu1_pred_val + 1), i4_sad[DIAG_DL_I4x4]); |
| pu1_src_temp += src_strd; |
| USADA8(pu1_src_temp, (pu1_pred_val + 2), i4_sad[DIAG_DL_I4x4]); |
| pu1_src_temp += src_strd; |
| USADA8(pu1_src_temp, (pu1_pred_val + 3), i4_sad[DIAG_DL_I4x4]); |
| pu1_src_temp += src_strd; |
| i4_cost[DIAG_DL_I4x4] = i4_sad[DIAG_DL_I4x4] + ((u4_predictd_mode == DIAG_DL_I4x4) ? |
| u4_lambda : 4 * u4_lambda); |
| } |
| |
| if (u4_valid_intra_modes & 16)/* DIAG_DR */ |
| { |
| i4_sad[DIAG_DR_I4x4] = 0; |
| i4_cost[DIAG_DR_I4x4] = 0; |
| pu1_src_temp = pu1_src; |
| pu1_pred_val = u1_pred_vals_diag_121 + 3; |
| |
| USADA8(pu1_src_temp, pu1_pred_val, i4_sad[DIAG_DR_I4x4]); |
| pu1_src_temp += src_strd; |
| USADA8(pu1_src_temp, (pu1_pred_val - 1), i4_sad[DIAG_DR_I4x4]); |
| pu1_src_temp += src_strd; |
| USADA8(pu1_src_temp, (pu1_pred_val - 2), i4_sad[DIAG_DR_I4x4]); |
| pu1_src_temp += src_strd; |
| USADA8(pu1_src_temp, (pu1_pred_val - 3), i4_sad[DIAG_DR_I4x4]); |
| pu1_src_temp += src_strd; |
| i4_cost[DIAG_DR_I4x4] = i4_sad[DIAG_DR_I4x4] + ((u4_predictd_mode == DIAG_DR_I4x4) ? |
| u4_lambda : 4 * u4_lambda); |
| |
| } |
| |
| if (u4_valid_intra_modes & 32)/* VERT_R mode valid ????*/ |
| { |
| i4_sad[VERT_R_I4x4] = 0; |
| |
| pu1_src_temp = pu1_src; |
| u1_pred_vals_vert_r[0] = u1_pred_vals_diag_121[2]; |
| memcpy((u1_pred_vals_vert_r + 1), (u1_pred_vals_diag_11 + 4), 3); |
| u1_pred_vals_vert_r[4] = u1_pred_vals_diag_121[1]; |
| memcpy((u1_pred_vals_vert_r + 5), (u1_pred_vals_diag_121 + 3), 3); |
| |
| pu1_pred_val = u1_pred_vals_diag_11 + 4; |
| USADA8(pu1_src_temp, pu1_pred_val, i4_sad[VERT_R_I4x4]); |
| pu1_pred_val = u1_pred_vals_diag_121 + 3; |
| pu1_src_temp += src_strd; |
| USADA8(pu1_src_temp, pu1_pred_val, i4_sad[VERT_R_I4x4]); |
| pu1_src_temp += src_strd; |
| USADA8(pu1_src_temp, (u1_pred_vals_vert_r), i4_sad[VERT_R_I4x4]); |
| pu1_src_temp += src_strd; |
| USADA8(pu1_src_temp, (u1_pred_vals_vert_r + 4), |
| i4_sad[VERT_R_I4x4]); |
| |
| i4_cost[VERT_R_I4x4] = i4_sad[VERT_R_I4x4] + ((u4_predictd_mode == VERT_R_I4x4) ? |
| u4_lambda : 4 * u4_lambda); |
| } |
| |
| if (u4_valid_intra_modes & 64)/* HORZ_D mode valid ????*/ |
| { |
| i4_sad[HORZ_D_I4x4] = 0; |
| |
| pu1_src_temp = pu1_src; |
| u1_pred_vals_horz_d[6] = u1_pred_vals_diag_11[3]; |
| memcpy((u1_pred_vals_horz_d + 7), (u1_pred_vals_diag_121 + 3), 3); |
| u1_pred_vals_horz_d[0] = u1_pred_vals_diag_11[0]; |
| u1_pred_vals_horz_d[1] = u1_pred_vals_diag_121[0]; |
| u1_pred_vals_horz_d[2] = u1_pred_vals_diag_11[1]; |
| u1_pred_vals_horz_d[3] = u1_pred_vals_diag_121[1]; |
| u1_pred_vals_horz_d[4] = u1_pred_vals_diag_11[2]; |
| u1_pred_vals_horz_d[5] = u1_pred_vals_diag_121[2]; |
| |
| pu1_pred_val = u1_pred_vals_horz_d; |
| USADA8(pu1_src_temp, (pu1_pred_val + 6), i4_sad[HORZ_D_I4x4]); |
| pu1_src_temp += src_strd; |
| USADA8(pu1_src_temp, (pu1_pred_val + 4), i4_sad[HORZ_D_I4x4]); |
| pu1_src_temp += src_strd; |
| USADA8(pu1_src_temp, (pu1_pred_val + 2), i4_sad[HORZ_D_I4x4]); |
| pu1_src_temp += src_strd; |
| USADA8(pu1_src_temp, (pu1_pred_val), i4_sad[HORZ_D_I4x4]); |
| |
| i4_cost[HORZ_D_I4x4] = i4_sad[HORZ_D_I4x4] + ((u4_predictd_mode == HORZ_D_I4x4) ? |
| u4_lambda : 4 * u4_lambda); |
| } |
| |
| if (u4_valid_intra_modes & 128)/* VERT_L mode valid ????*/ |
| { |
| i4_sad[VERT_L_I4x4] = 0; |
| pu1_src_temp = pu1_src; |
| pu1_pred_val = u1_pred_vals_diag_11 + 5; |
| USADA8(pu1_src_temp, (pu1_pred_val), i4_sad[VERT_L_I4x4]); |
| pu1_src_temp += src_strd; |
| pu1_pred_val = u1_pred_vals_diag_121 + 5; |
| USADA8(pu1_src_temp, (pu1_pred_val), i4_sad[VERT_L_I4x4]); |
| pu1_src_temp += src_strd; |
| pu1_pred_val = u1_pred_vals_diag_11 + 6; |
| USADA8(pu1_src_temp, (pu1_pred_val), i4_sad[VERT_L_I4x4]); |
| pu1_src_temp += src_strd; |
| pu1_pred_val = u1_pred_vals_diag_121 + 6; |
| USADA8(pu1_src_temp, (pu1_pred_val), i4_sad[VERT_L_I4x4]); |
| |
| i4_cost[VERT_L_I4x4] = i4_sad[VERT_L_I4x4] + ((u4_predictd_mode == VERT_L_I4x4) ? |
| u4_lambda : 4 * u4_lambda); |
| } |
| |
| if (u4_valid_intra_modes & 256)/* HORZ_U mode valid ????*/ |
| { |
| i4_sad[HORZ_U_I4x4] = 0; |
| pu1_src_temp = pu1_src; |
| u1_pred_vals_horz_u[0] = u1_pred_vals_diag_11[2]; |
| u1_pred_vals_horz_u[1] = u1_pred_vals_diag_121[1]; |
| u1_pred_vals_horz_u[2] = u1_pred_vals_diag_11[1]; |
| u1_pred_vals_horz_u[3] = u1_pred_vals_diag_121[0]; |
| u1_pred_vals_horz_u[4] = u1_pred_vals_diag_11[0]; |
| u1_pred_vals_horz_u[5] = FILT121(pu1_ngbr_pels[0], pu1_ngbr_pels[0], pu1_ngbr_pels[1]); |
| |
| memset((u1_pred_vals_horz_u + 6), pu1_ngbr_pels[0], 4); |
| |
| pu1_pred_val = u1_pred_vals_horz_u; |
| USADA8(pu1_src_temp, (pu1_pred_val), i4_sad[HORZ_U_I4x4]); |
| pu1_src_temp += src_strd; |
| USADA8(pu1_src_temp, (pu1_pred_val + 2), i4_sad[HORZ_U_I4x4]); |
| pu1_src_temp += src_strd; |
| USADA8(pu1_src_temp, (pu1_pred_val + 4), i4_sad[HORZ_U_I4x4]); |
| pu1_src_temp += src_strd; |
| USADA8(pu1_src_temp, (pu1_pred_val + 6), i4_sad[HORZ_U_I4x4]); |
| |
| i4_cost[HORZ_U_I4x4] = i4_sad[HORZ_U_I4x4] + ((u4_predictd_mode == HORZ_U_I4x4) ? |
| u4_lambda : 4 * u4_lambda); |
| } |
| |
| i4_min_cost = MIN3(MIN3(i4_cost[0], i4_cost[1], i4_cost[2]), |
| MIN3(i4_cost[3], i4_cost[4], i4_cost[5]), |
| MIN3(i4_cost[6], i4_cost[7], i4_cost[8])); |
| |
| } |
| else |
| { |
| /* Only first three modes valid */ |
| i4_min_cost = MIN3(i4_cost[0], i4_cost[1], i4_cost[2]); |
| } |
| |
| *pu4_sadmin = i4_min_cost; |
| |
| if (i4_min_cost == i4_cost[0]) |
| { |
| *u4_intra_mode = VERT_I4x4; |
| pu1_pred_val = pu1_ngbr_pels + 5; |
| memcpy(pu1_dst, (pu1_pred_val), 4); |
| pu1_dst += dst_strd; |
| memcpy(pu1_dst, (pu1_pred_val), 4); |
| pu1_dst += dst_strd; |
| memcpy(pu1_dst, (pu1_pred_val), 4); |
| pu1_dst += dst_strd; |
| memcpy(pu1_dst, (pu1_pred_val), 4); |
| } |
| else if (i4_min_cost == i4_cost[1]) |
| { |
| *u4_intra_mode = HORZ_I4x4; |
| memset(pu1_dst, pu1_ngbr_pels[3], 4); |
| pu1_dst += dst_strd; |
| memset(pu1_dst, pu1_ngbr_pels[2], 4); |
| pu1_dst += dst_strd; |
| memset(pu1_dst, pu1_ngbr_pels[1], 4); |
| pu1_dst += dst_strd; |
| memset(pu1_dst, pu1_ngbr_pels[0], 4); |
| } |
| else if (i4_min_cost == i4_cost[2]) |
| { |
| *u4_intra_mode = DC_I4x4; |
| memset(pu1_dst, u4_dcval, 4); |
| pu1_dst += dst_strd; |
| memset(pu1_dst, u4_dcval, 4); |
| pu1_dst += dst_strd; |
| memset(pu1_dst, u4_dcval, 4); |
| pu1_dst += dst_strd; |
| memset(pu1_dst, u4_dcval, 4); |
| } |
| |
| else if (i4_min_cost == i4_cost[3]) |
| { |
| *u4_intra_mode = DIAG_DL_I4x4; |
| pu1_pred_val = u1_pred_vals_diag_121 + 5; |
| memcpy(pu1_dst, (pu1_pred_val), 4); |
| pu1_dst += dst_strd; |
| memcpy(pu1_dst, (pu1_pred_val + 1), 4); |
| pu1_dst += dst_strd; |
| memcpy(pu1_dst, (pu1_pred_val + 2), 4); |
| pu1_dst += dst_strd; |
| memcpy(pu1_dst, (pu1_pred_val + 3), 4); |
| } |
| else if (i4_min_cost == i4_cost[4]) |
| { |
| *u4_intra_mode = DIAG_DR_I4x4; |
| pu1_pred_val = u1_pred_vals_diag_121 + 3; |
| |
| memcpy(pu1_dst, (pu1_pred_val), 4); |
| pu1_dst += dst_strd; |
| memcpy(pu1_dst, (pu1_pred_val - 1), 4); |
| pu1_dst += dst_strd; |
| memcpy(pu1_dst, (pu1_pred_val - 2), 4); |
| pu1_dst += dst_strd; |
| memcpy(pu1_dst, (pu1_pred_val - 3), 4); |
| } |
| |
| else if (i4_min_cost == i4_cost[5]) |
| { |
| *u4_intra_mode = VERT_R_I4x4; |
| pu1_pred_val = u1_pred_vals_diag_11 + 4; |
| memcpy(pu1_dst, (pu1_pred_val), 4); |
| pu1_dst += dst_strd; |
| pu1_pred_val = u1_pred_vals_diag_121 + 3; |
| memcpy(pu1_dst, (pu1_pred_val), 4); |
| pu1_dst += dst_strd; |
| memcpy(pu1_dst, (u1_pred_vals_vert_r), 4); |
| pu1_dst += dst_strd; |
| memcpy(pu1_dst, (u1_pred_vals_vert_r + 4), 4); |
| } |
| else if (i4_min_cost == i4_cost[6]) |
| { |
| *u4_intra_mode = HORZ_D_I4x4; |
| pu1_pred_val = u1_pred_vals_horz_d; |
| memcpy(pu1_dst, (pu1_pred_val + 6), 4); |
| pu1_dst += dst_strd; |
| memcpy(pu1_dst, (pu1_pred_val + 4), 4); |
| pu1_dst += dst_strd; |
| memcpy(pu1_dst, (pu1_pred_val + 2), 4); |
| pu1_dst += dst_strd; |
| memcpy(pu1_dst, (pu1_pred_val), 4); |
| pu1_dst += dst_strd; |
| } |
| else if (i4_min_cost == i4_cost[7]) |
| { |
| *u4_intra_mode = VERT_L_I4x4; |
| pu1_pred_val = u1_pred_vals_diag_11 + 5; |
| memcpy(pu1_dst, (pu1_pred_val), 4); |
| pu1_dst += dst_strd; |
| pu1_pred_val = u1_pred_vals_diag_121 + 5; |
| memcpy(pu1_dst, (pu1_pred_val), 4); |
| pu1_dst += dst_strd; |
| pu1_pred_val = u1_pred_vals_diag_11 + 6; |
| memcpy(pu1_dst, (pu1_pred_val), 4); |
| pu1_dst += dst_strd; |
| pu1_pred_val = u1_pred_vals_diag_121 + 6; |
| memcpy(pu1_dst, (pu1_pred_val), 4); |
| } |
| else if (i4_min_cost == i4_cost[8]) |
| { |
| *u4_intra_mode = HORZ_U_I4x4; |
| pu1_pred_val = u1_pred_vals_horz_u; |
| memcpy(pu1_dst, (pu1_pred_val), 4); |
| pu1_dst += dst_strd; |
| memcpy(pu1_dst, (pu1_pred_val + 2), 4); |
| pu1_dst += dst_strd; |
| memcpy(pu1_dst, (pu1_pred_val + 4), 4); |
| pu1_dst += dst_strd; |
| memcpy(pu1_dst, (pu1_pred_val + 6), 4); |
| pu1_dst += dst_strd; |
| } |
| |
| return; |
| } |
| |
| /** |
| ****************************************************************************** |
| * |
| * @brief: |
| * Evaluate best intr chroma mode (among VERT, HORZ and DC ) and do the prediction. |
| * |
| * @par Description |
| * This function evaluates first three intra chroma modes and compute corresponding sad |
| * and return the buffer predicted with best mode. |
| * |
| * @param[in] pu1_src |
| * UWORD8 pointer to the source |
| * |
| * @param[in] pu1_ngbr_pels |
| * UWORD8 pointer to neighbouring pels |
| * |
| * @param[out] pu1_dst |
| * UWORD8 pointer to the destination |
| * |
| * @param[in] src_strd |
| * integer source stride |
| * |
| * @param[in] dst_strd |
| * integer destination stride |
| * |
| * @param[in] u4_n_avblty |
| * availability of neighbouring pixels |
| * |
| * @param[in] u4_intra_mode |
| * Pointer to the variable in which best mode is returned |
| * |
| * @param[in] pu4_sadmin |
| * Pointer to the variable in which minimum sad is returned |
| * |
| * @param[in] u4_valid_intra_modes |
| * Says what all modes are valid |
| * |
| * @return none |
| * |
| ****************************************************************************** |
| */ |
| void ih264e_evaluate_intra_chroma_modes(UWORD8 *pu1_src, |
| UWORD8 *pu1_ngbr_pels, |
| UWORD8 *pu1_dst, |
| UWORD32 src_strd, |
| UWORD32 dst_strd, |
| WORD32 u4_n_avblty, |
| UWORD32 *u4_intra_mode, |
| WORD32 *pu4_sadmin, |
| UWORD32 u4_valid_intra_modes) |
| { |
| UWORD8 *pu1_neighbour; |
| UWORD8 *pu1_src_temp = pu1_src; |
| UWORD8 left = 0, top = 0; |
| WORD32 u4_dcval_u_l[2] = { 0, 0 }, /*sum left neighbours for 'U' ,two separate sets - sum of first four from top,and sum of four values from bottom */ |
| u4_dcval_u_t[2] = { 0, 0 }; /*sum top neighbours for 'U'*/ |
| |
| WORD32 u4_dcval_v_l[2] = { 0, 0 }, /*sum left neighbours for 'V'*/ |
| u4_dcval_v_t[2] = { 0, 0 }; /*sum top neighbours for 'V'*/ |
| |
| WORD32 i, j, row, col, i4_sad_vert = INT_MAX, i4_sad_horz = INT_MAX, |
| i4_sad_dc = INT_MAX, i4_min_sad = INT_MAX; |
| UWORD8 val_u, val_v; |
| |
| WORD32 u4_dc_val[2][2][2];/* ----------- |
| | | | Chroma can have four |
| | 00 | 01 | separate dc value... |
| ----------- u4_dc_val corresponds to this dc values |
| | | | with u4_dc_val[2][2][U] and u4_dc_val[2][2][V] |
| | 10 | 11 | |
| ----------- */ |
| left = (u4_n_avblty & LEFT_MB_AVAILABLE_MASK); |
| top = (u4_n_avblty & TOP_MB_AVAILABLE_MASK) >> 2; |
| |
| /*Evaluating HORZ*/ |
| if (left)/* Ifleft available*/ |
| { |
| i4_sad_horz = 0; |
| |
| for (i = 0; i < 8; i++) |
| { |
| val_v = pu1_ngbr_pels[15 - 2 * i]; |
| val_u = pu1_ngbr_pels[15 - 2 * i - 1]; |
| row = i / 4; |
| u4_dcval_u_l[row] += val_u; |
| u4_dcval_v_l[row] += val_v; |
| for (j = 0; j < 8; j++) |
| { |
| i4_sad_horz += ABS(val_u - pu1_src_temp[2 * j]);/* Finding SAD for HORZ mode*/ |
| i4_sad_horz += ABS(val_v - pu1_src_temp[2 * j + 1]); |
| } |
| |
| pu1_src_temp += src_strd; |
| } |
| u4_dcval_u_l[0] += 2; |
| u4_dcval_u_l[1] += 2; |
| u4_dcval_v_l[0] += 2; |
| u4_dcval_v_l[1] += 2; |
| } |
| |
| /*Evaluating VERT**/ |
| pu1_src_temp = pu1_src; |
| if (top) /* top available*/ |
| { |
| i4_sad_vert = 0; |
| |
| for (i = 0; i < 8; i++) |
| { |
| col = i / 4; |
| |
| val_u = pu1_ngbr_pels[18 + i * 2]; |
| val_v = pu1_ngbr_pels[18 + i * 2 + 1]; |
| u4_dcval_u_t[col] += val_u; |
| u4_dcval_v_t[col] += val_v; |
| |
| for (j = 0; j < 16; j++) |
| { |
| i4_sad_vert += ABS(pu1_ngbr_pels[18 + j] - pu1_src_temp[j]);/* Finding SAD for VERT mode*/ |
| } |
| pu1_src_temp += src_strd; |
| |
| } |
| u4_dcval_u_t[0] += 2; |
| u4_dcval_u_t[1] += 2; |
| u4_dcval_v_t[0] += 2; |
| u4_dcval_v_t[1] += 2; |
| } |
| |
| /* computing DC value*/ |
| /* Equation 8-128 in spec*/ |
| u4_dc_val[0][0][0] = (u4_dcval_u_l[0] + u4_dcval_u_t[0]) >> (1 + left + top); |
| u4_dc_val[0][0][1] = (u4_dcval_v_l[0] + u4_dcval_v_t[0]) >> (1 + left + top); |
| u4_dc_val[1][1][0] = (u4_dcval_u_l[1] + u4_dcval_u_t[1]) >> (1 + left + top); |
| u4_dc_val[1][1][1] = (u4_dcval_v_l[1] + u4_dcval_v_t[1]) >> (1 + left + top); |
| |
| if (top) |
| { |
| /* Equation 8-132 in spec*/ |
| u4_dc_val[0][1][0] = (u4_dcval_u_t[1]) >> (1 + top); |
| u4_dc_val[0][1][1] = (u4_dcval_v_t[1]) >> (1 + top); |
| } |
| else |
| { |
| u4_dc_val[0][1][0] = (u4_dcval_u_l[0]) >> (1 + left); |
| u4_dc_val[0][1][1] = (u4_dcval_v_l[0]) >> (1 + left); |
| } |
| |
| if (left) |
| { |
| u4_dc_val[1][0][0] = (u4_dcval_u_l[1]) >> (1 + left); |
| u4_dc_val[1][0][1] = (u4_dcval_v_l[1]) >> (1 + left); |
| } |
| else |
| { |
| u4_dc_val[1][0][0] = (u4_dcval_u_t[0]) >> (1 + top); |
| u4_dc_val[1][0][1] = (u4_dcval_v_t[0]) >> (1 + top); |
| } |
| |
| if (!(left || top)) |
| { |
| /*none available*/ |
| u4_dc_val[0][0][0] = u4_dc_val[0][0][1] = |
| u4_dc_val[0][1][0] = u4_dc_val[0][1][1] = |
| u4_dc_val[1][0][0] = u4_dc_val[1][0][1] = |
| u4_dc_val[1][1][0] = u4_dc_val[1][1][1] = 128; |
| } |
| |
| /* Evaluating DC */ |
| pu1_src_temp = pu1_src; |
| i4_sad_dc = 0; |
| for (i = 0; i < 8; i++) |
| { |
| for (j = 0; j < 8; j++) |
| { |
| col = j / 4; |
| row = i / 4; |
| val_u = u4_dc_val[row][col][0]; |
| val_v = u4_dc_val[row][col][1]; |
| |
| i4_sad_dc += ABS(val_u - pu1_src_temp[2 * j]);/* Finding SAD for DC mode*/ |
| i4_sad_dc += ABS(val_v - pu1_src_temp[2 * j + 1]); |
| } |
| pu1_src_temp += src_strd; |
| } |
| |
| if ((u4_valid_intra_modes & 01) == 0)/* If DC is disabled*/ |
| i4_sad_dc = INT_MAX; |
| if ((u4_valid_intra_modes & 02) == 0)/* If HORZ is disabled*/ |
| i4_sad_horz = INT_MAX; |
| if ((u4_valid_intra_modes & 04) == 0)/* If VERT is disabled*/ |
| i4_sad_vert = INT_MAX; |
| |
| i4_min_sad = MIN3(i4_sad_horz, i4_sad_dc, i4_sad_vert); |
| |
| /* Finding Minimum sad and doing corresponding prediction*/ |
| if (i4_min_sad < *pu4_sadmin) |
| { |
| *pu4_sadmin = i4_min_sad; |
| |
| if (i4_min_sad == i4_sad_dc) |
| { |
| *u4_intra_mode = DC_CH_I8x8; |
| for (i = 0; i < 8; i++) |
| { |
| for (j = 0; j < 8; j++) |
| { |
| col = j / 4; |
| row = i / 4; |
| |
| pu1_dst[2 * j] = u4_dc_val[row][col][0]; |
| pu1_dst[2 * j + 1] = u4_dc_val[row][col][1]; |
| } |
| pu1_dst += dst_strd; |
| } |
| } |
| else if (i4_min_sad == i4_sad_horz) |
| { |
| *u4_intra_mode = HORZ_CH_I8x8; |
| for (j = 0; j < 8; j++) |
| { |
| val_v = pu1_ngbr_pels[15 - 2 * j]; |
| val_u = pu1_ngbr_pels[15 - 2 * j - 1]; |
| |
| for (i = 0; i < 8; i++) |
| { |
| pu1_dst[2 * i] = val_u; |
| pu1_dst[2 * i + 1] = val_v; |
| |
| } |
| pu1_dst += dst_strd; |
| } |
| } |
| else |
| { |
| *u4_intra_mode = VERT_CH_I8x8; |
| pu1_neighbour = pu1_ngbr_pels + 18; |
| for (j = 0; j < 8; j++) |
| { |
| memcpy(pu1_dst, pu1_neighbour, MB_SIZE); |
| pu1_dst += dst_strd; |
| } |
| } |
| } |
| |
| return; |
| } |