#include "alf.h" #include #include #include #include #include "cabac.h" #include "rdo.h" #include "strategies/strategies-sao.h" #include "kvz_math.h" void kvz_alf_init(encoder_state_t *const state, encoder_state_config_slice_t *slice) //alf_info_t *alf) { if (g_slice_count == state->slice->id) { return; } g_slice_count = state->slice->id; reset_alf_param(&alf_param); if (false/*cs.slice->getPendingRasInit()*/ || (state->frame->pictype == KVZ_NAL_IDR_W_RADL || state->frame->pictype == KVZ_NAL_IDR_N_LP)) { for (int i = 0; i < ALF_CTB_MAX_NUM_APS; i++) { //state->slice->apss[i].aps_id = 0; //state->slice->apss[i].aps_type = 0; reset_alf_param(&state->slice->apss[i]); state->slice->apss[i].num_luma_filters = 0; } g_aps_id_start = ALF_CTB_MAX_NUM_APS; } enum kvz_chroma_format chroma_fmt = state->encoder_control->chroma_format; chroma_scale_x = (chroma_fmt == KVZ_CSP_444) ? 0 : 1; chroma_scale_y = (chroma_fmt != KVZ_CSP_420) ? 0 : 1; //Default clp_rng for a slice g_clp_rngs.comp[COMPONENT_Y].min = g_clp_rngs.comp[COMPONENT_Cb].min = g_clp_rngs.comp[COMPONENT_Cr].min = 0; g_clp_rngs.comp[COMPONENT_Y].max = (1<< ALF_NUM_BITS)-1; g_clp_rngs.comp[COMPONENT_Y].bd = ALF_NUM_BITS; g_clp_rngs.comp[COMPONENT_Y].n = 0; g_clp_rngs.comp[COMPONENT_Cb].max = g_clp_rngs.comp[COMPONENT_Cr].max = (1<< ALF_NUM_BITS)-1; g_clp_rngs.comp[COMPONENT_Cb].bd = g_clp_rngs.comp[COMPONENT_Cr].bd = ALF_NUM_BITS; g_clp_rngs.comp[COMPONENT_Cb].n = g_clp_rngs.comp[COMPONENT_Cr].n = 0; g_clp_rngs.used = g_clp_rngs.chroma = false; //int shiftLuma = 2 * 0;// DISTORTION_PRECISION_ADJUSTMENT(g_input_bit_depth[CHANNEL_TYPE_LUMA]); //int shiftChroma = 2 * 0;// DISTORTION_PRECISION_ADJUSTMENT(m_inputBitDepth[CHANNEL_TYPE_CHROMA]); g_lambda[COMPONENT_Y] = state->frame->lambda;// *double(1 << shiftLuma); g_lambda[COMPONENT_Cb] = state->frame->lambda;// *double(1 << shiftChroma); g_lambda[COMPONENT_Cr] = state->frame->lambda;// *double(1 << shiftChroma); } //-------------------------help functions--------------------------- bool is_crossed_by_virtual_boundaries(const int x_pos, const int y_pos, const int width, const int height, bool* clip_top, bool* clip_bottom, bool* clip_left, bool* clip_right, int* num_hor_vir_bndry, int* num_ver_vir_bndry, int hor_vir_bndry_pos[], int ver_vir_bndry_pos[], encoder_state_t *const state) { *clip_top = false; *clip_bottom = false; *clip_left = false; *clip_right = false; *num_hor_vir_bndry = 0; *num_ver_vir_bndry = 0; if (state->encoder_control->cfg.loop_filter_across_virtual_boundaries_disabled_flag) { for (int i = 0; i < state->slice->num_hor_virtual_boundaries; i++) { if (state->slice->virtual_boundaries_pos_y[i] == y_pos) { *clip_top = true; } else if (state->slice->virtual_boundaries_pos_y[i] == y_pos + height) { *clip_bottom = true; } else if (y_pos < state->slice->virtual_boundaries_pos_y[i] && state->slice->virtual_boundaries_pos_y[i] < y_pos + height) { hor_vir_bndry_pos[*num_hor_vir_bndry++] = state->slice->virtual_boundaries_pos_y[i]; } } for (int i = 0; i < state->slice->num_ver_virtual_boundaries; i++) { if (state->slice->virtual_boundaries_pos_x[i] == x_pos) { *clip_left = true; } else if (state->slice->virtual_boundaries_pos_x[i] == x_pos + width) { *clip_right = true; } else if (x_pos < state->slice->virtual_boundaries_pos_x[i] && state->slice->virtual_boundaries_pos_x[i] < x_pos + width) { ver_vir_bndry_pos[*num_ver_vir_bndry++] = state->slice->virtual_boundaries_pos_x[i]; } } } return *num_hor_vir_bndry > 0 || *num_ver_vir_bndry > 0 || *clip_top || *clip_bottom || *clip_left || *clip_right; } void init_ctu_alternative_chroma(uint8_t* ctu_alts[MAX_NUM_COMPONENT]) { uint8_t alt_idx = 0; for (int ctu_idx = 0; ctu_idx < g_num_ctus_in_pic; ++ctu_idx) { ctu_alts[COMPONENT_Cb][ctu_idx] = alt_idx; ctu_alts[COMPONENT_Cr][ctu_idx] = alt_idx; if ((ctu_idx + 1) * g_alf_aps_temp.num_alternatives_chroma >= (alt_idx + 1)*g_num_ctus_in_pic) ++alt_idx; } } int clip_alf(const int clip, const short ref, const short val0, const short val1) { return alf_clip3(-clip, +clip, val0 - ref) + alf_clip3(-clip, +clip, val1 - ref); } int alf_clip_pixel(const int a, const clp_rng clp_rng) { return MIN(MAX(clp_rng.min, a), clp_rng.max); } int alf_clip3(const int minVal, const int maxVal, const int a) { return MIN(MAX(minVal, a), maxVal); } void get_clip_max(alf_covariance *cov, int *clip_max) { const int num_coeff = cov->num_coeff; for (int k = 0; k < num_coeff - 1; ++k) { clip_max[k] = 0; bool inc = true; while (inc && clip_max[k] + 1 < cov->num_bins && cov->y[clip_max[k] + 1][k] == cov->y[clip_max[k]][k]) { for (int l = 0; inc && l < num_coeff; ++l) if (cov->ee[clip_max[k]][0][k][l] != cov->ee[clip_max[k] + 1][0][k][l]) { inc = false; } if (inc) { ++clip_max[k]; } } } clip_max[num_coeff - 1] = 0; } void reduce_clip_cost(alf_covariance *cov, int *clip) { for (int k = 0; k < cov->num_coeff - 1; ++k) { bool dec = true; while (dec && clip[k] > 0 && cov->y[clip[k] - 1][k] == cov->y[clip[k]][k]) { for (int l = 0; dec && l < cov->num_coeff; ++l) if (cov->ee[clip[k]][clip[l]][k][l] != cov->ee[clip[k] - 1][clip[l]][k][l]) { dec = false; } if (dec) { --clip[k]; } } } } void set_ey_from_clip(alf_covariance *cov,const int* clip, double ee[MAX_NUM_ALF_LUMA_COEFF][MAX_NUM_ALF_LUMA_COEFF], double y[MAX_NUM_ALF_LUMA_COEFF], int size) { for (int k = 0; ky[clip[k]][k]; for (int l = 0; lee[clip[k]][clip[l]][k][l]; } } } double optimize_filter(alf_covariance *cov, int* clip, double *f, bool optimize_clip) { const int size = cov->num_coeff; int clip_max[MAX_NUM_ALF_LUMA_COEFF]; double err_best, err_last; double ke[MAX_NUM_ALF_LUMA_COEFF][MAX_NUM_ALF_LUMA_COEFF]; double ky[MAX_NUM_ALF_LUMA_COEFF]; if (optimize_clip) { // Start by looking for min clipping that has no impact => max_clipping get_clip_max(cov, clip_max); for (int k = 0; knum_bins - 1); } } set_ey_from_clip(cov, clip, ke, ky, size); gns_solve_by_chol(ke, ky, f, size); err_best = calculate_error(cov, clip, f); int step = optimize_clip ? (cov->num_bins + 1) / 2 : 0; while (step > 0) { double err_min = err_best; int idx_min = -1; int inc_min = 0; for (int k = 0; k < size - 1; ++k) { if (clip[k] - step >= clip_max[k]) { clip[k] -= step; ky[k] = cov->y[clip[k]][k]; for (int l = 0; l < size; l++) { ke[k][l] = cov->ee[clip[k]][clip[l]][k][l]; ke[l][k] = cov->ee[clip[l]][clip[k]][l][k]; } gns_solve_by_chol(ke, ky, f, size); err_last = calculate_error(cov, clip, f); if (err_last < err_min) { err_min = err_last; idx_min = k; inc_min = -step; } clip[k] += step; } if (clip[k] + step < cov->num_bins) { clip[k] += step; ky[k] = cov->y[clip[k]][k]; for (int l = 0; l < size; l++) { ke[k][l] = cov->ee[clip[k]][clip[l]][k][l]; ke[l][k] = cov->ee[clip[l]][clip[k]][l][k]; } gns_solve_by_chol(ke, ky, f, size); err_last = calculate_error(cov, clip, f); if (err_last < err_min) { err_min = err_last; idx_min = k; inc_min = step; } clip[k] -= step; } ky[k] = cov->y[clip[k]][k]; for (int l = 0; l < size; l++) { ke[k][l] = cov->ee[clip[k]][clip[l]][k][l]; ke[l][k] = cov->ee[clip[l]][clip[k]][l][k]; } } if (idx_min >= 0) { err_best = err_min; clip[idx_min] += inc_min; ky[idx_min] = cov->y[clip[idx_min]][idx_min]; for (int l = 0; l < size; l++) { ke[idx_min][l] = cov->ee[clip[idx_min]][clip[l]][idx_min][l]; ke[l][idx_min] = cov->ee[clip[l]][clip[idx_min]][l][idx_min]; } } else { --step; } } if (optimize_clip) { // test all max for (int k = 0; k < size - 1; ++k) { clip_max[k] = 0; } double ke_max[MAX_NUM_ALF_LUMA_COEFF][MAX_NUM_ALF_LUMA_COEFF]; double ky_max[MAX_NUM_ALF_LUMA_COEFF]; set_ey_from_clip(cov, clip_max, ke_max, ky_max, size); gns_solve_by_chol(ke_max, ky_max, f, size); err_last = calculate_error(cov, clip_max, f); if (err_last < err_best) { err_best = err_last; for (int k = 0; k= 0; i--) { double sum = 0; for (int j = i + 1; j <= size; j++) { sum += r[i][j] * a[j]; } a[i] = (z[i] - sum) / r[i][i]; } } void gns_transpose_backsubstitution(double u[MAX_NUM_ALF_LUMA_COEFF][MAX_NUM_ALF_LUMA_COEFF], double* rhs, double* x, int order) { /* Backsubstitution starts */ x[0] = rhs[0] / u[0][0]; /* First row of U' */ for (int i = 1; i < order; i++) { /* For the rows 1..order-1 */ double sum = 0; //Holds backsubstitution from already handled rows for (int j = 0; j < i; j++) /* Backsubst already solved unknowns */ { sum += x[j] * u[j][i]; } x[i] = (rhs[i] - sum) / u[i][i]; /* i'th component of solution vect. */ } } int gns_cholesky_dec(double inp_matr[MAX_NUM_ALF_LUMA_COEFF][MAX_NUM_ALF_LUMA_COEFF], double out_matr[MAX_NUM_ALF_LUMA_COEFF][MAX_NUM_ALF_LUMA_COEFF], int num_eq) { static double inv_diag[MAX_NUM_ALF_LUMA_COEFF]; /* Vector of the inverse of diagonal entries of outMatr */ for (int i = 0; i < num_eq; i++) { for (int j = i; j < num_eq; j++) { /* Compute the scaling factor */ double scale = inp_matr[i][j]; if (i > 0) { for (int k = i - 1; k >= 0; k--) { scale -= out_matr[k][j] * out_matr[k][i]; } } /* Compute i'th row of outMatr */ if (i == j) { if (scale <= REG_SQR) // if(scale <= 0 ) /* If inpMatr is singular */ { return 0; } else /* Normal operation */ inv_diag[i] = 1.0 / (out_matr[i][i] = sqrt(scale)); } else { out_matr[i][j] = scale * inv_diag[i]; /* Upper triangular part */ out_matr[j][i] = 0.0; /* Lower triangular part set to 0 */ } } } return 1; /* Signal that Cholesky factorization is successfully performed */ } int gns_solve_by_chol(double lhs[MAX_NUM_ALF_LUMA_COEFF][MAX_NUM_ALF_LUMA_COEFF], double rhs[MAX_NUM_ALF_LUMA_COEFF], double *x, int num_eq) { static double aux[MAX_NUM_ALF_LUMA_COEFF]; /* Auxiliary vector */ static double u[MAX_NUM_ALF_LUMA_COEFF][MAX_NUM_ALF_LUMA_COEFF]; /* Upper triangular Cholesky factor of lhs */ int res = 1; // Signal that Cholesky factorization is successfully performed /* The equation to be solved is LHSx = rhs */ /* Compute upper triangular U such that U'*U = lhs */ if (gns_cholesky_dec(lhs, u, num_eq)) /* If Cholesky decomposition has been successful */ { /* Now, the equation is U'*U*x = rhs, where U is upper triangular * Solve U'*aux = rhs for aux */ gns_transpose_backsubstitution(u, rhs, aux, num_eq); /* The equation is now U*x = aux, solve it for x (new motion coefficients) */ gns_backsubstitution(u, aux, num_eq, x); } else /* lhs was singular */ { res = 0; /* Regularize lhs */ for (int i = 0; i < num_eq; i++) { lhs[i][i] += REG; } /* Compute upper triangular U such that U'*U = regularized lhs */ res = gns_cholesky_dec(lhs, u, num_eq); if (!res) { memset(x, 0, sizeof(double)*num_eq); return 0; } /* Solve U'*aux = rhs for aux */ gns_transpose_backsubstitution(u, rhs, aux, num_eq); /* Solve U*x = aux for x */ gns_backsubstitution(u, aux, num_eq, x); } return res; } int gns_solve_by_chol_clip_gns(alf_covariance *cov, const int *clip, double *x, int num_eq) { double lhs[MAX_NUM_ALF_LUMA_COEFF][MAX_NUM_ALF_LUMA_COEFF]; double rhs[MAX_NUM_ALF_LUMA_COEFF]; set_ey_from_clip(cov, clip, lhs, rhs, num_eq); return gns_solve_by_chol(lhs, rhs, x, num_eq); } double calc_error_for_coeffs(alf_covariance *cov, const int *clip, const int *coeff, const int num_coeff, const int bit_depth) { double factor = 1 << (bit_depth - 1); double error = 0; for (int i = 0; i < num_coeff; i++) //diagonal { double sum = 0; for (int j = i + 1; j < num_coeff; j++) { sum += cov->ee[clip[i]][clip[j]][i][j] * coeff[j]; } error += ((cov->ee[clip[i]][clip[i]][i][i] * coeff[i] + sum * 2) / factor - 2 * cov->y[clip[i]][i]) * coeff[i]; } return error / factor; } /*#if !JVET_O0216_ALF_COEFF_EG3 || !JVET_O0064_SIMP_ALF_CLIP_CODING int get_golomb_k_min(channel_type channel, const int num_filters, int k_min_tab[MAX_NUM_ALF_LUMA_COEFF], int bits_coeff_scan[m_MAX_SCAN_VAL][m_MAX_EXP_GOLOMB]) { int k_start; const int max_golomb_idx = channel == CHANNEL_TYPE_LUMA ? 3 : 2; int min_bits_k_start = MAX_INT; int min_k_start = -1; for (int k = 1; k < 8; k++) { int bits_k_start = 0; k_start = k; for (int scan_pos = 0; scan_pos < max_golomb_idx; scan_pos++) { int k_min = k_start; int min_bits = bits_coeff_scan[scan_pos][k_min]; if (bits_coeff_scan[scan_pos][k_start + 1] < min_bits) { k_min = k_start + 1; min_bits = bits_coeff_scan[scan_pos][k_min]; } k_start = k_min; bits_k_start += min_bits; } if (bits_k_start < min_bits_k_start) { min_bits_k_start = bits_k_start; min_k_start = k; } } k_start = min_k_start; for (int scan_pos = 0; scan_pos < max_golomb_idx; scan_pos++) { int k_min = k_start; int min_bits = bits_coeff_scan[scan_pos][k_min]; if (bits_coeff_scan[scan_pos][k_start + 1] < min_bits) { k_min = k_start + 1; min_bits = bits_coeff_scan[scan_pos][k_min]; } k_min_tab[scan_pos] = k_min; k_start = k_min; } return min_k_start; }*/ int length_golomb(int coeff_val, int k, bool signed_coeff) { int num_bins = 0; unsigned int symbol = abs(coeff_val); while (symbol >= (unsigned int)(1 << k)) { num_bins++; symbol -= 1 << k; k++; } num_bins += (k + 1); if (signed_coeff && coeff_val != 0) { num_bins++; } return num_bins; } int length_uvlc(int ui_code) { int ui_length = 1; int ui_temp = ++ui_code; assert(ui_temp); // "Integer overflow" while (1 != ui_temp) { ui_temp >>= 1; ui_length += 2; } // Take care of cases where ui_length > 32 return (ui_length >> 1) + ((ui_length + 1) >> 1); } double get_dist_coeff_force_0(bool* coded_var_bins, double error_force_0_coeff_tab[MAX_NUM_ALF_CLASSES][2], int* bits_var_bin, const int num_filters) { double dist_force_0 = 0; memset(coded_var_bins, 0, sizeof(*coded_var_bins) * MAX_NUM_ALF_CLASSES); for (int filt_idx = 0; filt_idx < num_filters; filt_idx++) { double cost_diff = error_force_0_coeff_tab[filt_idx][0] - (error_force_0_coeff_tab[filt_idx][1] + g_lambda[COMPONENT_Y] * bits_var_bin[filt_idx]); coded_var_bins[filt_idx] = cost_diff > 0 ? true : false; dist_force_0 += error_force_0_coeff_tab[filt_idx][coded_var_bins[filt_idx] ? 1 : 0]; } return dist_force_0; } double get_dist_force_0(channel_type channel, const int num_filters, double error_tab_force_0_coeff[MAX_NUM_ALF_CLASSES][2], bool* coded_var_bins) { int num_coeff = channel == CHANNEL_TYPE_LUMA ? 13 : 7; static int bits_var_bin[MAX_NUM_ALF_CLASSES]; for (int ind = 0; ind < num_filters; ++ind) { bits_var_bin[ind] = 0; for (int i = 0; i < num_coeff - 1; i++) { bits_var_bin[ind] += length_golomb(abs(g_filter_coeff_set[ind][i]), 3, true); } } //#if JVET_O0090_ALF_CHROMA_FILTER_ALTERNATIVES_CTB if (g_alf_aps_temp.non_linear_flag[CHANNEL_TYPE_LUMA][0]) /*#else if (g_alf_aps_temp.non_linear_flag[CHANNEL_TYPE_LUMA]) #endif*/ { for (int ind = 0; ind < num_filters; ++ind) { for (int i = 0; i < num_coeff - 1; i++) { if (!abs(g_filter_coeff_set[ind][i])) { g_filter_clipp_set[ind][i] = 0; } } } } double dist_force_0 = get_dist_coeff_force_0(coded_var_bins, error_tab_force_0_coeff, bits_var_bin, num_filters); return dist_force_0; } int get_cost_filter_coeff_force_0(channel_type channel, int **p_diff_q_filter_coeff_int_pp, const int num_filters, bool* coded_var_bins) { const int num_coeff = channel == CHANNEL_TYPE_LUMA ? 13 : 7; int len = num_filters; //filter_coefficient_flag[i] // Filter coefficients for (int ind = 0; ind < num_filters; ++ind) { if (coded_var_bins[ind]) { for (int i = 0; i < num_coeff - 1; i++) { len += length_golomb(abs(p_diff_q_filter_coeff_int_pp[ind][i]), 3, true); // alf_coeff_luma_delta[i][j] } } } //#if JVET_O0090_ALF_CHROMA_FILTER_ALTERNATIVES_CTB if (g_alf_aps_temp.non_linear_flag[CHANNEL_TYPE_LUMA][0]) /*#else if (g_alf_aps_temp.non_linear_flag[CHANNEL_TYPE_LUMA]) #endif*/ { for (int ind = 0; ind < num_filters; ++ind) { for (int i = 0; i < num_coeff - 1; i++) { if (!abs(p_diff_q_filter_coeff_int_pp[ind][i])) { g_filter_clipp_set[ind][i] = 0; } len += 2; } } } return len; } int get_cost_filter_coeff(channel_type channel, int **p_diff_q_filter_coeff_int_pp, const int num_filters) { // #if JVET_O0216_ALF_COEFF_EG3 return length_filter_coeffs(channel, num_filters, p_diff_q_filter_coeff_int_pp); // alf_coeff_luma_delta[i][j]; /* #else const int num_coeff = channel == CHANNEL_TYPE_LUMA ? 13 : 7; const int max_golomb_idx = channel == CHANNEL_TYPE_LUMA ? 3 : 2; const int *golomb_idx = channel == CHANNEL_TYPE_LUMA ? alf_golomb_idx_7 : alf_golomb_idx_5; memset(g_bits_coeff_scan, 0, sizeof(g_bits_coeff_scan)); for (int ind = 0; ind < num_filters; ++ind) { for (int i = 0; i < num_coeff - 1; i++) { int coeff_val = abs(p_diff_q_filter_coeff_int_pp[ind][i]); for (int k = 1; k < 15; k++) { g_bits_coeff_scan[golomb_idx[i]][k] += length_golomb(coeff_val, k); } } } int k_min = get_golomb_k_min(channel, num_filters, g_k_min_tab, g_bits_coeff_scan); // Coding parameters int len = k_min //min_golomb_order + max_golomb_idx; //golomb_order_increase_flag // Filter coefficients //len += lengthFilterCoeffs( alfShape, num_filters, p_diff_q_filter_coeff_int_pp, m_kMinTab ); // alf_coeff_luma_delta[i][j] for (int ind = 0; ind < num_filters; ++ind) { for (int i = 0; i < num_coeff - 1; i++) { len += length_golomb(abs(p_diff_q_filter_coeff_int_pp[ind][i]), g_k_min_tab[golomb_idx[i]]); } } return len; */ } int get_cost_filter_clipp(channel_type channel, int **p_diff_q_filter_coeff_int_pp, const int num_filters) { int num_coeff = channel == CHANNEL_TYPE_LUMA ? 13 : 7; for (int filter_idx = 0; filter_idx < num_filters; ++filter_idx) { for (int i = 0; i < num_coeff - 1; i++) { if (!abs(p_diff_q_filter_coeff_int_pp[filter_idx][i])) { g_filter_clipp_set[filter_idx][i] = 0; } } } return (num_filters * (num_coeff - 1)) << 1; } /*#if !JVET_O0491_HLS_CLEANUP int get_tb_length(int ui_symbol, const int ui_max_symbol) { int ui_thresh; if (ui_max_symbol > 256) { int ui_thresh_val = 1 << 8; ui_thresh = 8; while (ui_thresh_val <= ui_max_symbol) { ui_thresh++; ui_thresh_val <<= 1; } ui_thresh--; } else { ui_thresh = kvz_tb_max[ui_max_symbol]; } int ui_val = 1 << ui_thresh; assert(ui_val <= ui_max_symbol); assert((ui_val << 1) > ui_max_symbol); assert(ui_symbol < ui_max_symbol); int b = ui_max_symbol - ui_val; assert(b < ui_val); if (ui_symbol < ui_val - b) { return ui_thresh; } else { return ui_thresh + 1; } }*/ int get_non_filter_coeff_rate(alf_aps *aps) { //short* filter_coeff_delta_idx = aps->filter_coeff_delta_idx; //int fixed_filter_pattern = aps->fixed_filter_pattern; //int fixed_filter_set_index = aps->fixed_filter_set_index; int len = 1 // alf_coefficients_delta_flag /*#if !JVET_O0491_HLS_CLEANUP + length_truncated_unary(0, 3) // chroma_idc = 0, it is signalled when ALF is enabled for luma + get_tb_length(num_luma_filters - 1, MAX_NUM_ALF_CLASSES); //numLumaFilters*/ + 2 // slice_alf_chroma_idc u(2) + length_uvlc(aps->num_luma_filters - 1); // alf_luma_num_filters_signalled_minus1 ue(v) if (aps->num_luma_filters > 1) { const int coeff_length = kvz_math_ceil_log2(aps->num_luma_filters); //#if JVET_O0491_HLS_CLEANUP for (int i = 0; i < MAX_NUM_ALF_CLASSES; i++) { //len += get_tb_length((int)filter_coeff_delta_idx[i], num_luma_filters); //#if !JVET_O0491_HLS_CLEANUP len += coeff_length; } } /*#if !JVET_O0669_REMOVE_ALF_COEFF_PRED len++; //fixed filter set flag if (*fixed_filter_set_index > 0) { len += get_tb_length(*fixed_filter_set_index - 1, ALF_NUM_FIXED_FILTER_SETS); len += 1; //fixed filter flag pattern if (*fixed_filter_pattern > 0) len += MAX_NUM_ALF_CLASSES; //"fixed_filter_flag" for each class }*/ return len; } int length_filter_coeffs(channel_type channel, const int num_filters, int **filter_coeff) { int num_coeff = channel == CHANNEL_TYPE_LUMA ? 13 : 7; int bit_cnt = 0; for (int ind = 0; ind < num_filters; ++ind) { for (int i = 0; i < num_coeff - 1; i++) { bit_cnt += length_golomb(abs(filter_coeff[ind][i]), 3, true); } } return bit_cnt; } double calculate_error(alf_covariance *cov, const int *clip, const double *coeff) { double sum = 0; for (int i = 0; i < cov->num_coeff; i++) { sum += coeff[i] * cov->y[clip[i]][i]; } return cov->pix_acc - sum; } double calculate_error_opt_filt(alf_covariance *cov, const int *clip) { double c[MAX_NUM_ALF_LUMA_COEFF]; return optimize_filter_gns_calc(cov, clip, c, cov->num_coeff); } /*#if !JVET_O0090_ALF_CHROMA_FILTER_ALTERNATIVES_CTB int get_coeff_rate(alf_aps* alf_aps, bool is_chroma) { int iBits = 0; assert(is_chroma); int num_coeff = is_chroma ? 7 : 13; // Filter coefficients for (int i = 0; i < num_coeff - 1; i++) { iBits += length_golomb(alf_aps->chroma_coeff[i], 3, true); // alf_coeff_chroma[i], alf_coeff_luma_delta[i][j] } if (g_alf_aps_temp.non_linear_flag[is_chroma]) { for (int i = 0; i < num_coeff - 1; i++) { if (!abs(alf_aps->chroma_coeff[i])) { alf_aps->chroma_clipp[i] = 0; } } iBits += ((num_coeff - 1) << 1); } return iBits; }#endif*/ int get_chroma_coeff_rate(alf_aps* aps, int alt_idx) { int i_bits = 0; //AlfFilterShape alfShape(5); const int num_coeff = 7; // Filter coefficients for (int i = 0; i < num_coeff - 1; i++) { i_bits += length_golomb(aps->chroma_coeff[alt_idx][i], 3, true); // alf_coeff_chroma[alt_idx][i] } if (g_alf_aps_temp.non_linear_flag[CHANNEL_TYPE_CHROMA][alt_idx]) { for (int i = 0; i < num_coeff - 1; i++) { if (!abs(aps->chroma_coeff[alt_idx][i])) { aps->chroma_clipp[alt_idx][i] = 0; } } i_bits += ((num_coeff - 1) << 1); } return i_bits; } /*#if !JVET_O0491_HLS_CLEANUP int length_truncated_unary(int symbol, int max_symbol) { if (max_symbol == 0) { return 0; } bool code_last = (max_symbol > symbol); int num_bins = 0; while (symbol--) { num_bins++; } if (code_last) { num_bins++; } return num_bins; }*/ double get_filtered_distortion(alf_covariance* cov, const int num_classes, const int num_filters_minus1, const int num_coeff) { double dist = 0; for (int class_idx = 0; class_idx < num_classes; class_idx++) { dist += calc_error_for_coeffs(&cov[class_idx], g_filter_clipp_set[class_idx], g_filter_coeff_set[class_idx], num_coeff, ALF_NUM_BITS); } return dist; } double get_unfiltered_distortion_cov_channel(alf_covariance* cov, channel_type channel) { double dist = 0; if (channel == CHANNEL_TYPE_LUMA) { dist = get_unfiltered_distortion_cov_classes(cov, MAX_NUM_ALF_CLASSES); } else { /*#if !JVET_O0491_HLS_CLEANUP dist = get_unfiltered_distortion_cov_classes(cov, 1) + length_truncated_unary(0, 3) * g_lambda[COMPONENT_Cb];*/ dist = get_unfiltered_distortion_cov_classes(cov, 1); } return dist; } double get_unfiltered_distortion_cov_classes(alf_covariance* cov, const int num_classes) { double dist = 0; for (int class_idx = 0; class_idx < num_classes; class_idx++) { dist += cov[class_idx].pix_acc; } return dist; } void get_frame_stats(channel_type channel, int i_shape_idx, int ctu_idx) { bool is_luma = channel == CHANNEL_TYPE_LUMA ? true : false; int num_classes = is_luma ? MAX_NUM_ALF_CLASSES : 1; //#if JVET_O0090_ALF_CHROMA_FILTER_ALTERNATIVES_CTB int num_alternatives = is_luma ? 1 : g_alf_aps_temp.num_alternatives_chroma; // When calling this function m_ctuEnableFlag shall be set to 0 for CTUs using alternative APS // Here we compute frame stats for building new alternative filters for (int alt_idx = 0; alt_idx < num_alternatives; ++alt_idx) { for (int i = 0; i < num_classes; i++) { reset_alf_covariance(&g_alf_covariance_frame[channel][i_shape_idx][is_luma ? i : alt_idx], g_alf_num_clipping_values[channel]); } if (is_luma) { get_frame_stat(g_alf_covariance_frame[CHANNEL_TYPE_LUMA][i_shape_idx], g_alf_covariance[COMPONENT_Y][i_shape_idx], g_ctu_enable_flag[COMPONENT_Y], NULL, num_classes, alt_idx, ctu_idx); } else { get_frame_stat(g_alf_covariance_frame[CHANNEL_TYPE_CHROMA][i_shape_idx], g_alf_covariance[COMPONENT_Cb][i_shape_idx], g_ctu_enable_flag[COMPONENT_Cb], g_ctu_alternative[COMPONENT_Cb], num_classes, alt_idx, ctu_idx); get_frame_stat(g_alf_covariance_frame[CHANNEL_TYPE_CHROMA][i_shape_idx], g_alf_covariance[COMPONENT_Cr][i_shape_idx], g_ctu_enable_flag[COMPONENT_Cr], g_ctu_alternative[COMPONENT_Cr], num_classes, alt_idx, ctu_idx); } } /*#else for (int i = 0; i < num_classes; i++) { reset_alf_covariance(&g_alf_covariance_frame[channel][i_shape_idx][i], g_alf_num_clipping_values[channel]); } if (channel == CHANNEL_TYPE_LUMA) { get_frame_stat(g_alf_covariance_frame[CHANNEL_TYPE_LUMA][i_shape_idx], g_alf_covariance[COMPONENT_Y][i_shape_idx], g_ctu_enable_flag[COMPONENT_Y], num_classes); } else { get_frame_stat(g_alf_covariance_frame[CHANNEL_TYPE_CHROMA][i_shape_idx], g_alf_covariance[COMPONENT_Cb][i_shape_idx], g_ctu_enable_flag[COMPONENT_Cb], num_classes); get_frame_stat(g_alf_covariance_frame[CHANNEL_TYPE_CHROMA][i_shape_idx], g_alf_covariance[COMPONENT_Cr][i_shape_idx], g_ctu_enable_flag[COMPONENT_Cr], num_classes); } #endif*/ } //#if JVET_O0090_ALF_CHROMA_FILTER_ALTERNATIVES_CTB void get_frame_stat(alf_covariance* frame_cov, alf_covariance** ctb_cov, uint8_t* ctb_enable_flags, uint8_t* ctb_alt_idx, const int num_classes, int alt_idx, int ctu_idx) /*#else void get_frame_stat(alf_covariance* frame_cov, alf_covariance** ctb_cov, uint8_t* ctb_enable_flags, const int num_classes) #endif*/ { //#if JVET_O0090_ALF_CHROMA_FILTER_ALTERNATIVES_CTB const channel_type channel = (!ctb_alt_idx ? CHANNEL_TYPE_LUMA : CHANNEL_TYPE_CHROMA); bool is_luma = channel == CHANNEL_TYPE_LUMA ? true : false; //for (int ctu_idx = 0; ctu_idx < g_num_ctus_in_pic; ctu_idx++) { if (ctb_enable_flags[ctu_idx]) { for (int class_idx = 0; class_idx < num_classes; class_idx++) { if (is_luma || alt_idx == ctb_alt_idx[ctu_idx]) { add_alf_cov(&frame_cov[is_luma ? class_idx : alt_idx], &ctb_cov[ctu_idx][class_idx]); } } } } /*#else for (int i = 0; i < g_num_ctus_in_pic; i++) { if (ctb_enable_flags[i]) { for (int j = 0; j < num_classes; j++) { add_alf_cov(&frame_cov[j], &ctb_cov[i][j]); } } } #endif*/ } void copy_cov(alf_covariance *dst, alf_covariance *src) { dst->num_coeff = src->num_coeff; dst->num_bins = src->num_bins; memcpy(&dst->ee, &src->ee, sizeof(dst->ee)); memcpy(&dst->y, &src->y, sizeof(dst->y)); dst->pix_acc = src->pix_acc; } void copy_alf_param(alf_aps *dst, alf_aps *src) { memcpy(dst->enabled_flag, src->enabled_flag, sizeof(dst->enabled_flag)); memcpy(dst->non_linear_flag, src->non_linear_flag, sizeof(dst->non_linear_flag)); memcpy(dst->luma_coeff, src->luma_coeff, sizeof(dst->luma_coeff)); memcpy(dst->luma_clipp, src->luma_clipp, sizeof(dst->luma_clipp)); //#if JVET_O0090_ALF_CHROMA_FILTER_ALTERNATIVES_CTB dst->num_alternatives_chroma = src->num_alternatives_chroma; //#endif memcpy(dst->chroma_coeff, src->chroma_coeff, sizeof(dst->chroma_coeff)); memcpy(dst->chroma_clipp, src->chroma_clipp, sizeof(dst->chroma_clipp)); memcpy(dst->filter_coeff_delta_idx, src->filter_coeff_delta_idx, sizeof(dst->filter_coeff_delta_idx)); memcpy(dst->alf_luma_coeff_flag, src->alf_luma_coeff_flag, sizeof(dst->alf_luma_coeff_flag)); dst->num_luma_filters = src->num_luma_filters; dst->alf_luma_coeff_delta_flag = src->alf_luma_coeff_delta_flag; //#if !JVET_O0669_REMOVE_ALF_COEFF_PRED //dst->alf_luma_coeff_delta_prediction_flag = src->alf_luma_coeff_delta_prediction_flag; //#endif dst->t_layer = src->t_layer; memcpy(dst->new_filter_flag, src->new_filter_flag, sizeof(dst->new_filter_flag)); //#if !JVET_O0669_REMOVE_ALF_COEFF_PRED //dst->fixed_filter_pattern = src->fixed_filter_pattern; //memcpy(dst->fixed_filter_idx, src->fixed_filter_idx, sizeof(dst->fixed_filter_idx)); //dst->fixed_filter_set_index = src->fixed_filter_set_index; //#endif } void copy_alf_param_w_channel(alf_aps* dst, alf_aps* src, channel_type channel) { if (channel == CHANNEL_TYPE_LUMA) { copy_alf_param(dst, src); } else { /*#if !JVET_O0090_ALF_CHROMA_FILTER_ALTERNATIVES_CTB alfParamDst.nonLinearFlag[channel] = alfParamSrc.nonLinearFlag[channel]; #endif*/ dst->enabled_flag[COMPONENT_Cb] = src->enabled_flag[COMPONENT_Cb]; dst->enabled_flag[COMPONENT_Cr] = src->enabled_flag[COMPONENT_Cr]; //#if JVET_O0090_ALF_CHROMA_FILTER_ALTERNATIVES_CTB dst->num_alternatives_chroma = src->num_alternatives_chroma; memcpy(dst->non_linear_flag[CHANNEL_TYPE_CHROMA], src->non_linear_flag[CHANNEL_TYPE_CHROMA], sizeof(dst->non_linear_flag[CHANNEL_TYPE_CHROMA])); //#endif memcpy(dst->chroma_coeff, src->chroma_coeff, sizeof(dst->chroma_coeff)); memcpy(dst->chroma_clipp, src->chroma_clipp, sizeof(dst->chroma_clipp)); } } void reset_alf_param(alf_aps *src) { memset(src->enabled_flag, false, sizeof(src->enabled_flag)); memset(src->non_linear_flag, false, sizeof(src->non_linear_flag)); memset(src->luma_coeff, 0, sizeof(src->luma_coeff)); memset(src->luma_clipp, 0, sizeof(src->luma_clipp)); //#if JVET_O0090_ALF_CHROMA_FILTER_ALTERNATIVES_CTB src->num_alternatives_chroma = 1; //#endif memset(src->chroma_coeff, 0, sizeof(src->chroma_coeff)); memset(src->chroma_clipp, 0, sizeof(src->chroma_clipp)); memset(src->filter_coeff_delta_idx, 0, sizeof(src->filter_coeff_delta_idx)); memset(src->alf_luma_coeff_flag, true, sizeof(src->alf_luma_coeff_flag)); src->num_luma_filters = 1; src->alf_luma_coeff_delta_flag = false; /*#if !JVET_O0669_REMOVE_ALF_COEFF_PRED alfLumaCoeffDeltaPredictionFlag = false; #endif*/ src->t_layer = 0; memset(src->new_filter_flag, 0, sizeof(src->new_filter_flag)); /*#if !JVET_O0669_REMOVE_ALF_COEFF_PRED fixedFilterPattern = 0; std::memset(fixedFilterIdx, 0, sizeof(fixedFilterIdx)); fixedFilterSetIndex = 0; #endif*/ } void add_alf_cov(alf_covariance *dst, alf_covariance *src) { int num_bins = dst->num_bins; int num_coeff = dst->num_coeff; for (int b0 = 0; b0 < num_bins; b0++) { for (int b1 = 0; b1 < num_bins; b1++) { for (int j = 0; j < num_coeff; j++) { for (int i = 0; i < num_coeff; i++) { dst->ee[b0][b1][j][i] += src->ee[b0][b1][j][i]; } } } } for (int b = 0; b < num_bins; b++) { for (int j = 0; j < num_coeff; j++) { dst->y[b][j] += src->y[b][j]; } } dst->pix_acc += src->pix_acc; } void add_alf_cov_lhs_rhs(alf_covariance *dst, alf_covariance *lhs, alf_covariance *rhs) { int num_coeff = lhs->num_coeff; int num_bins = lhs->num_bins; for (int b0 = 0; b0 < num_bins; b0++) { for (int b1 = 0; b1 < num_bins; b1++) { for (int j = 0; j < num_coeff; j++) { for (int i = 0; i < num_coeff; i++) { dst->ee[b0][b1][j][i] = lhs->ee[b0][b1][j][i] + rhs->ee[b0][b1][j][i]; } } } } for (int b = 0; b < num_bins; b++) { for (int j = 0; j < num_coeff; j++) { dst->y[b][j] = lhs->y[b][j] + rhs->y[b][j]; } } dst->pix_acc = lhs->pix_acc + rhs->pix_acc; } void reset_alf_covariance(alf_covariance *alf, int num_bins) { if (num_bins > 0) { alf->num_bins = num_bins; } alf->pix_acc = 0; memset(&alf->y, 0, sizeof(alf->y)); memset(&alf->ee, 0, sizeof(alf->ee)); } void adjust_pixels(kvz_pixel *src, int x_start, int x_end, int y_start, int y_end, int stride, int pic_width, int pic_height) { assert(x_start <= x_end); assert(y_start <= y_end); assert(x_end <= pic_width); assert(y_end <= pic_height); //not on any edge if (x_start != 0 && y_start != 0 && x_end != pic_width && y_end != pic_height) { return; } bool top_left = (x_start == 0 && y_start == 0); bool top_right = (x_end == pic_width && y_start == 0); bool bottom_left = (x_start == 0 && y_end == pic_height); bool bottom_right = (x_end == pic_width && y_end == pic_height); //left side if (x_start == 0) { for (int y = y_start; y < y_end; y++) { src[y * stride - 4] = src[y * stride - 3] = src[y * stride - 2] = src[y * stride - 1] = src[y * stride]; } } //right side if (x_end == pic_width) { const int x_px = x_end - 1; for (int y = y_start; y < y_end; y++) { src[y * stride + x_px + 4] = src[y * stride + x_px + 3] = src[y * stride + x_px + 2] = src[y * stride + x_px + 1] = src[y * stride + x_px]; } } //top if (y_start == 0) { for (int x = x_start; x < x_end; x++) { src[-4 * stride + x] = src[-3 * stride + x] = src[-2 * stride + x] = src[-1 * stride + x] = src[x]; } } //bottom if (y_end == pic_height) { const int y_px = y_end - 1; for (int x = x_start; x < x_end; x++) { src[x + stride * (4 + y_px)] = src[x + stride * (3 + y_px)] = src[x + stride * (2 + y_px)] = src[x + stride * (1 + y_px)] = src[x + stride * y_px]; } } //left top corner if (top_left) { for (int x = -4; x < 0; x++) { src[-4 * stride + x] = src[-3 * stride + x] = src[-2 * stride + x] = src[-1 * stride + x] = src[0]; } } //right top corner if (top_right) { const int x_px = x_end - 1; for (int x = pic_width; x < pic_width + 4; x++) { src[-4 * stride + x] = src[-3 * stride + x] = src[-2 * stride + x] = src[-1 * stride + x] = src[x_px]; } } //left or right bottom corner if (bottom_left) { const int y_px = y_end - 1; for (int x = -4; x < 0; x++) { src[(4 + y_px) * stride + x] = src[(3 + y_px) * stride + x] = src[(2 + y_px) * stride + x] = src[(1 + y_px) * stride + x] = src[stride * y_px]; } } if (bottom_right) { const int x_px = x_end - 1; const int y_px = y_end - 1; for (int x = x_end; x < x_end + 4; x++) { src[(4 + y_px) * stride + x] = src[(3 + y_px) * stride + x] = src[(2 + y_px) * stride + x] = src[(1 + y_px) * stride + x] = src[stride * y_px + x_px]; } } } void adjust_pixels_chroma(kvz_pixel *src, int x_start, int x_end, int y_start, int y_end, int stride, int pic_width, int pic_height) { assert(x_start <= x_end); assert(y_start <= y_end); assert(x_end <= pic_width); assert(y_end <= pic_height); //not on any edge if (x_start != 0 && y_start != 0 && x_end != pic_width && y_end != pic_height) { return; } bool top_left = (x_start == 0 && y_start == 0); bool top_right = (x_end == pic_width && y_start == 0); bool bottom_left = (x_start == 0 && y_end == pic_height); bool bottom_right = (x_end == pic_width && y_end == pic_height); //left side if (x_start == 0) { for (int y = y_start; y < y_end; y++) { src[y * stride - 2] = src[y * stride - 1] = src[y * stride]; } } //right side if (x_end == pic_width) { const int x_px = x_end - 1; for (int y = y_start; y < y_end; y++) { src[y * stride + x_px + 2] = src[y * stride + x_px + 1] = src[y * stride + x_px]; } } //top if (y_start == 0) { for (int x = x_start; x < x_end; x++) { src[-2 * stride + x] = src[-1 * stride + x] = src[x]; } } //bottom if (y_end == pic_height) { const int y_px = y_end - 1; for (int x = x_start; x < x_end; x++) { src[x + stride * (2 + y_px)] = src[x + stride * (1 + y_px)] = src[x + stride * y_px]; } } //left top corner if (top_left) { for (int x = -2; x < 0; x++) { src[-2 * stride + x] = src[-1 * stride + x] = src[0]; } } //right top corner if (top_right) { const int x_px = x_end - 1; for (int x = pic_width; x < pic_width + 2; x++) { src[-2 * stride + x] = src[-1 * stride + x] = src[x_px]; } } //left or right bottom corner if (bottom_left) { const int y_px = y_end - 1; for (int x = -2; x < 0; x++) { src[(2 + y_px) * stride + x] = src[(1 + y_px) * stride + x] = src[stride * y_px]; } } if (bottom_right) { const int x_px = x_end - 1; const int y_px = y_end - 1; for (int x = x_end; x < x_end + 2; x++) { src[(2 + y_px) * stride + x] = src[(1 + y_px) * stride + x] = src[stride * y_px + x_px]; } } } void set_ctu_enable_flag(uint8_t **flags, channel_type channel, int ctu_idx, uint8_t value) { if (channel == CHANNEL_TYPE_LUMA) { flags[COMPONENT_Y][ctu_idx] = value; } else { flags[COMPONENT_Cr][ctu_idx] = value; flags[COMPONENT_Cb][ctu_idx] = value; } } void copy_ctu_enable_flag(uint8_t **flags_dst, uint8_t **flags_src, channel_type channel, int ctu_idx) { if (channel == CHANNEL_TYPE_LUMA) { flags_dst[COMPONENT_Y][ctu_idx] = flags_src[COMPONENT_Y][ctu_idx]; } else { flags_dst[COMPONENT_Cr][ctu_idx] = flags_src[COMPONENT_Cr][ctu_idx]; flags_dst[COMPONENT_Cb][ctu_idx] = flags_src[COMPONENT_Cb][ctu_idx]; } } //------------------------------------------------------------------- //-------------------------encoding functions------------------------ void kvz_alf_enc_process(encoder_state_t *const state, const lcu_order_element_t *const lcu //#if ENABLE_QPA //const double lambdaChromaWeight //#endif ) { //const TempCtx ctxStart(m_CtxCache, AlfCtx(m_CABACEstimator->getCtx())); memcpy(&cabac_estimator, &state->cabac, sizeof(cabac_estimator)); memcpy(&ctx_start, &state->cabac, sizeof(ctx_start)); cabac_estimator.only_count = 1; ctx_start.only_count = 1; // derive classification //const kvz_pixel rec_luma = state->tile->frame->rec->y; //const PreCalcValues& pcv = *cs.pcv; const int lumaHeight = state->tile->frame->height; const int lumaWidth = state->tile->frame->width; /*const int maxCUHeight = LCU_WIDTH; const int maxCUWidth = LCU_WIDTH;*/ bool clip_top = false, clip_bottom = false, clip_left = false, clip_right = false; int num_hor_vir_bndry = 0, num_ver_vir_bndry = 0; int hor_vir_bndry_pos[] = { 0, 0, 0 }; int ver_vir_bndry_pos[] = { 0, 0, 0 }; //turha /*for (int y_pos = 0; y_pos < lumaHeight; y_pos += maxCUHeight) { for (int x_pos = 0; x_pos < lumaWidth; x_pos += maxCUWidth) {*/ const int y_pos = lcu->position_px.y; const int x_pos = lcu->position_px.x; const int width = lcu->size.x; //(x_pos + maxCUWidth > lumaWidth) ? (lumaWidth - x_pos) : maxCUWidth; const int height = lcu->size.y; //(y_pos + maxCUHeight > lumaHeight) ? (lumaHeight - y_pos) : maxCUHeight; //Tätä if-lauseen sisällä olevaa algoritmia pitää vielä viilata if (is_crossed_by_virtual_boundaries(x_pos, y_pos, width, height, &clip_top, &clip_bottom, &clip_left, &clip_right, &num_hor_vir_bndry, &num_ver_vir_bndry, hor_vir_bndry_pos, ver_vir_bndry_pos, state)) { int y_start = y_pos; for (int i = 0; i <= num_hor_vir_bndry; i++) { const int y_end = i == num_hor_vir_bndry ? y_pos + height : hor_vir_bndry_pos[i]; const int h = y_end - y_start; const bool clip_t = (i == 0 && clip_top) || (i > 0) || (y_start == 0); const bool clip_b = (i == num_hor_vir_bndry && clip_bottom) || (i < num_hor_vir_bndry) || (y_end == lumaHeight); int x_start = x_pos; for (int j = 0; j <= num_ver_vir_bndry; j++) { const int x_end = j == num_ver_vir_bndry ? x_pos + width : ver_vir_bndry_pos[j]; const int w = x_end - x_start; const bool clip_l = (j == 0 && clip_left) || (j > 0) || (x_start == 0); const bool clip_r = (j == num_ver_vir_bndry && clip_right) || (j < num_ver_vir_bndry) || (x_end == lumaWidth); //const int w_buf = w + (clip_l ? 0 : MAX_ALF_PADDING_SIZE) + (clip_r ? 0 : MAX_ALF_PADDING_SIZE); //const int h_buf = h + (clip_t ? 0 : MAX_ALF_PADDING_SIZE) + (clip_b ? 0 : MAX_ALF_PADDING_SIZE); //PelUnitBuf buf = m_tempBuf2.subBuf(UnitArea(cs.area.chromaFormat, Area(0, 0, w_buf, h_buf))); //buf.copyFrom(recYuv.subBuf(UnitArea(cs.area.chromaFormat, Area(x_start - (clip_l ? 0 : MAX_ALF_PADDING_SIZE), y_start - (clip_t ? 0 : MAX_ALF_PADDING_SIZE), w_buf, h_buf)))); //buf.extendBorderPel(MAX_ALF_PADDING_SIZE); //buf = buf.subBuf(UnitArea(cs.area.chromaFormat, Area(clip_l ? 0 : MAX_ALF_PADDING_SIZE, clip_t ? 0 : MAX_ALF_PADDING_SIZE, w, h))); //const Area blkSrc(0, 0, w, h); //const Area blkDst(xStart, yStart, w, h); kvz_alf_derive_classification(state, w, h, x_start, y_start, x_start, y_start); /*#if !JVET_O0525_REMOVE_PCM //Area blkPCM(xStart, yStart, w, h); kvz_alf_reset_pcm_blk_class_info(state, lcu, w, h, x_start, y_start);*/ x_start = x_end; } y_start = y_end; } } else { //Area blk(x_pos, y_pos, width, height); kvz_alf_derive_classification(state, width, height, x_pos, y_pos, x_pos, y_pos); /*#if !JVET_O0525_REMOVE_PCM //Area blkPCM(x_pos, y_pos, width, height); kvz_alf_reset_pcm_blk_class_info(state, lcu, width, height, x_pos, y_pos);*/ } // } //} // get CTB stats for filtering kvz_alf_derive_stats_for_filtering(state, lcu); //checked //#if JVET_O0090_ALF_CHROMA_FILTER_ALTERNATIVES_CTB /*for (int ctbIdx = 0; ctbIdx < m_numCTUsInPic; ctbIdx++) { cs.slice->getPic()->getAlfCtbFilterIndex()[ctbIdx] = NUM_FIXED_FILTER_SETS; }*/ g_alf_ctb_filter_index[lcu->index] = ALF_NUM_FIXED_FILTER_SETS; //g_classifier //g_alf_covariance //g_alf_ctb_filter kvz_alf_derive_filter__encode__reconstruct(state, lcu, 0.0); } void kvz_alf_derive_filter__encode__reconstruct(encoder_state_t *const state, const lcu_order_element_t *lcu //#if ENABLE_QPA , const double lambda_chroma_weight //#endif ) { int lcu_index = lcu->index; // consider using new filter (only) alf_param.new_filter_flag[CHANNEL_TYPE_LUMA] = true; alf_param.new_filter_flag[CHANNEL_TYPE_CHROMA] = true; state->slice->tile_group_num_aps = 1; // Only new filter for RD cost optimization //#endif // derive filter (luma) kvz_alf_encoder(state, lcu, &alf_param, CHANNEL_TYPE_LUMA //#if ENABLE_QPA , lambda_chroma_weight //#endif ); //ulkopuolelle // derive filter (chroma) kvz_alf_encoder(state, lcu, &alf_param, CHANNEL_TYPE_CHROMA //#if ENABLE_QPA , lambda_chroma_weight //#endif ); //ulkopuolelle //#if JVET_O0090_ALF_CHROMA_FILTER_ALTERNATIVES_CTB // let alfEncoderCtb decide now alf_param.new_filter_flag[CHANNEL_TYPE_LUMA] = false; alf_param.new_filter_flag[CHANNEL_TYPE_CHROMA] = false; state->slice->tile_group_num_aps = 0; //#endif //m_CABACEstimator->getCtx() = AlfCtx(ctxStart); memcpy(&cabac_estimator, &ctx_start, sizeof(cabac_estimator)); kvz_alf_encoder_ctb(state, &alf_param, lcu_index //#if ENABLE_QPA , lambda_chroma_weight //#endif ); //memcpy(&state->cabac, &cabac_estimator, sizeof(state->cabac)); //state->cabac.only_count = 0; //kvz_encode_alf(state, lcu->index, &alf_param); kvz_encode_alf_bits(state, lcu_index); kvz_alf_reconstructor(state, lcu_index); } double kvz_alf_derive_ctb_alf_enable_flags(encoder_state_t * const state, channel_type channel, const int i_shape_idx, double *dist_unfilter, const int num_classes, int ctu_idx, //#if ENABLE_QPA const double chroma_weight //#endif ) { /* TempCtx ctxTempStart(m_CtxCache); TempCtx ctxTempBest(m_CtxCache);*/ cabac_data_t ctx_temp_start; cabac_data_t ctx_temp_best; /*#if JVET_O0090_ALF_CHROMA_FILTER_ALTERNATIVES_CTB TempCtx ctxTempAltStart(m_CtxCache); TempCtx ctxTempAltBest(m_CtxCache);*/ cabac_data_t ctx_temp_alt_start; cabac_data_t ctx_temp_alt_best; //#endif kvz_config cfg = state->encoder_control->cfg; bool is_luma = channel == CHANNEL_TYPE_LUMA ? 1 : 0; const kvz_pixel comp_id_first = is_luma ? COMPONENT_Y : COMPONENT_Cb; const kvz_pixel comp_id_last = is_luma ? COMPONENT_Y : COMPONENT_Cr; //#if JVET_O0090_ALF_CHROMA_FILTER_ALTERNATIVES_CTB const int num_alts = is_luma ? 1 : g_alf_aps_temp.num_alternatives_chroma; //#endif int num_coeff = is_luma ? 13 : 7; double cost = 0; *dist_unfilter = 0; if (is_luma) { g_alf_aps_temp.enabled_flag[COMPONENT_Y] = 1; } else { g_alf_aps_temp.enabled_flag[COMPONENT_Cb] = 1; g_alf_aps_temp.enabled_flag[COMPONENT_Cr] = 1; } //#if ENABLE_QPA assert((chroma_weight <= 0.0) && (state->slice->start_in_ts == 0)); //"incompatible start CTU address, must be 0" //#endif kvz_alf_reconstruct_coeff(state, &g_alf_aps_temp, channel, true, is_luma); //#if JVET_O0090_ALF_CHROMA_FILTER_ALTERNATIVES_CTB for (int alt_idx = 0; alt_idx < (is_luma ? 1 : MAX_NUM_ALF_ALTERNATIVES_CHROMA); alt_idx++) { for (int class_idx = 0; class_idx < (is_luma ? MAX_NUM_ALF_CLASSES : 1); class_idx++) { for (int i = 0; i < (is_luma ? MAX_NUM_ALF_LUMA_COEFF : MAX_NUM_ALF_CHROMA_COEFF); i++) { g_filter_coeff_set[is_luma ? class_idx : alt_idx][i] = is_luma ? g_coeff_final[class_idx * MAX_NUM_ALF_LUMA_COEFF + i] : g_chroma_coeff_final[alt_idx][i]; g_filter_clipp_set[is_luma ? class_idx : alt_idx][i] = is_luma ? g_clipp_final[class_idx * MAX_NUM_ALF_LUMA_COEFF + i] : g_chroma_clipp_final[alt_idx][i]; } } } /*#else for (int class_idx = 0; class_idx < (is_luma ? MAX_NUM_ALF_CLASSES : 1); class_idx++) { for (int i = 0; i < (is_luma ? MAX_NUM_ALF_LUMA_COEFF : MAX_NUM_ALF_CHROMA_COEFF); i++) { g_filter_coeff_set[class_idx][i] = is_luma ? g_coeff_final[class_idx * MAX_NUM_ALF_LUMA_COEFF + i] : g_chroma_coeff_final[i]; g_filter_clipp_set[class_idx][i] = is_luma ? g_clipp_final[class_idx * MAX_NUM_ALF_LUMA_COEFF + i] : g_chroma_clipp_final[i]; } } #endif*/ //for (int ctu_idx = 0; ctu_idx < g_num_ctus_in_pic; ctu_idx++) { for (int comp_id = comp_id_first; comp_id <= comp_id_last; comp_id++) { //#if JVET_O0090_ALF_CHROMA_FILTER_ALTERNATIVES_CTB //#if ENABLE_QPA const double ctu_lambda = chroma_weight > 0.0 ? (is_luma ? 0/*cs.picture->m_uEnerHpCtu[ctuIdx]*/ : 0/*cs.picture->m_uEnerHpCtu[ctuIdx]*/ / chroma_weight) : g_lambda[comp_id]; /*#else const double ctu_lambda = m_lambda[compID]; #endif #endif*/ double dist_unfilter_ctu = get_unfiltered_distortion_cov_classes(g_alf_covariance[comp_id][i_shape_idx][ctu_idx], num_classes); //ctxTempStart = AlfCtx(m_CABACEstimator->getCtx()); memcpy(&ctx_temp_start, &cabac_estimator, sizeof(ctx_temp_start)); //m_CABACEstimator->resetBits(); kvz_cabac_reset_bits(&cabac_estimator); cabac_estimator.only_count = 1; g_ctu_enable_flag[comp_id][ctu_idx] = 1; code_alf_ctu_enable_flag(state, &cabac_estimator, ctu_idx, comp_id, &g_alf_aps_temp); //#if JVET_O0090_ALF_CHROMA_FILTER_ALTERNATIVES_CTB if (is_luma) { // Evaluate cost of signaling filter set index for convergence of filters enabled flag / filter derivation assert(g_alf_ctb_filter_index[ctu_idx] == ALF_NUM_FIXED_FILTER_SETS); assert(state->slice->tile_group_num_aps == 1); code_alf_ctu_filter_index(state, &cabac_estimator, ctu_idx, g_alf_aps_temp.enabled_flag[COMPONENT_Y]); } double cost_on = dist_unfilter_ctu + ctu_lambda * (23 - cabac_estimator.bits_left) + (cabac_estimator.num_buffered_bytes << 3); //frac_bits_scale * 0 /*m_CABACEstimator->getEstFracBits()*/; /*#else double costOn = distUnfilterCtu + getFilteredDistortion(m_alfCovariance[compID][iShapeIdx][ctuIdx], numClasses, m_alfParamTemp.numLumaFilters - 1, numCoeff); #if ENABLE_QPA const double ctu_lambda = chromaWeight > 0.0 ? (isLuma(channel) ? cs.picture->m_uEnerHpCtu[ctuIdx] : cs.picture->m_uEnerHpCtu[ctuIdx] / chromaWeight) : m_lambda[compID]; #else const double ctu_lambda = m_lambda[compID]; #endif costOn += ctu_lambda * FRAC_BITS_SCALE * m_CABACEstimator->getEstFracBits(); #endif*/ //ctxTempBest = AlfCtx(m_CABACEstimator->getCtx()); memcpy(&ctx_temp_best, &cabac_estimator, sizeof(ctx_temp_best)); //#if JVET_O0090_ALF_CHROMA_FILTER_ALTERNATIVES_CTB if (is_luma) { cost_on += get_filtered_distortion(g_alf_covariance[comp_id][i_shape_idx][ctu_idx], num_classes, g_alf_aps_temp.num_luma_filters - 1, num_coeff); } else { double best_alt_cost = MAX_DOUBLE; int best_alt_idx = -1; //ctxTempAltStart = AlfCtx(ctxTempBest); memcpy(&ctx_temp_alt_start, &ctx_temp_best, sizeof(ctx_temp_alt_start)); for (int alt_idx = 0; alt_idx < num_alts; ++alt_idx) { if (alt_idx) { //m_CABACEstimator->getCtx() = AlfCtx(ctxTempAltStart); memcpy(&cabac_estimator, &ctx_temp_alt_start, sizeof(cabac_estimator)); } //m_CABACEstimator->resetBits(); kvz_cabac_reset_bits(&cabac_estimator); cabac_estimator.only_count = 1; g_ctu_alternative[comp_id][ctu_idx] = alt_idx; code_alf_ctu_alternative_ctu(state, &cabac_estimator, ctu_idx, comp_id, &g_alf_aps_temp); double r_altCost = ctu_lambda * (23 - cabac_estimator.bits_left) + (cabac_estimator.num_buffered_bytes << 3); //frac_bits_scale * 0/*m_CABACEstimator->getEstFracBits()*/; double alt_dist = 0.; alt_dist += calc_error_for_coeffs(&g_alf_covariance[comp_id][i_shape_idx][ctu_idx][0], g_filter_clipp_set[alt_idx], g_filter_coeff_set[alt_idx], num_coeff, ALF_NUM_BITS); double alt_cost = alt_dist + r_altCost; if (alt_cost < best_alt_cost) { best_alt_cost = alt_cost; best_alt_idx = alt_idx; //ctxTempBest = AlfCtx(m_CABACEstimator->getCtx()); memcpy(&ctx_temp_best, &cabac_estimator, sizeof(ctx_temp_best)); } } g_ctu_alternative[comp_id][ctu_idx] = best_alt_idx; cost_on += best_alt_cost; } //#endif //m_CABACEstimator->getCtx() = AlfCtx(ctxTempStart); memcpy(&cabac_estimator, &ctx_temp_start, sizeof(cabac_estimator)); //m_CABACEstimator->resetBits(); kvz_cabac_reset_bits(&cabac_estimator); cabac_estimator.only_count = 1; g_ctu_enable_flag[comp_id][ctu_idx] = 0; code_alf_ctu_enable_flag(state, &cabac_estimator, ctu_idx, comp_id, &g_alf_aps_temp); double cost_off = dist_unfilter_ctu + ctu_lambda * (23 - cabac_estimator.bits_left) + (cabac_estimator.num_buffered_bytes << 3); //frac_bits_scale * 0;// m_CABACEstimator->getEstFracBits(); if (cost_on < cost_off) { cost += cost_on; //m_CABACEstimator->getCtx() = AlfCtx(ctxTempBest); memcpy(&cabac_estimator, &ctx_temp_best, sizeof(cabac_estimator)); g_ctu_enable_flag[comp_id][ctu_idx] = 1; } else { cost += cost_off; g_ctu_enable_flag[comp_id][ctu_idx] = 0; *dist_unfilter += dist_unfilter_ctu; } } } if (!is_luma) { const alf_component_id compIDFirst = COMPONENT_Cb; const alf_component_id compIDLast = COMPONENT_Cr; for (int compId = compIDFirst; compId <= compIDLast; compId++) { g_alf_aps_temp.enabled_flag[compId] = false; for (int i = 0; i < g_num_ctus_in_pic; i++) { if (g_ctu_enable_flag[compId][i]) { g_alf_aps_temp.enabled_flag[compId] = true; break; } } } /*#if !JVET_O0491_HLS_CLEANUP const int alf_chroma_idc = g_alf_aps_temp.enabled_flag[COMPONENT_Cb] * 2 + g_alf_aps_temp.enabled_flag[COMPONENT_Cr]; cost += length_truncated_unary(alf_chroma_idc, 3) * g_lambda[channel];*/ } return cost; } void kvz_alf_enc_create(encoder_state_t const *state, const lcu_order_element_t *lcu) { if (g_curr_frame == g_old_frame) { return; } g_curr_frame = g_old_frame; kvz_alf_create(state, lcu); for (int channel_idx = 0; channel_idx < MAX_NUM_CHANNEL_TYPE; channel_idx++) { channel_type ch_type = (channel_type)channel_idx; //#if JVET_O0090_ALF_CHROMA_FILTER_ALTERNATIVES_CTB int num_classes = channel_idx ? MAX_NUM_ALF_ALTERNATIVES_CHROMA : MAX_NUM_ALF_CLASSES; /*#else int num_classes = channel_idx ? 1 : MAX_NUM_ALF_CLASSES; #endif*/ int num_coeffs = channel_idx ? 7 : 13; //m_alfCovarianceFrame[ch_type] = new AlfCovariance*[m_filterShapes[ch_type].size()]; g_alf_covariance_frame[ch_type] = malloc(sizeof(**g_alf_covariance_frame[ch_type])); for (int i = 0; i != 1/*m_filterShapes[ch_type].size()*/; i++) { g_alf_covariance_frame[ch_type][i] = malloc(num_classes * sizeof(alf_covariance)); for (int k = 0; k < num_classes; k++) { g_alf_covariance_frame[ch_type][i][k].num_coeff = num_coeffs; g_alf_covariance_frame[ch_type][i][k].num_bins = g_max_alf_num_clipping_values; memset(g_alf_covariance_frame[ch_type][i][k].y, 0, sizeof(g_alf_covariance_frame[ch_type][i][k].y)); memset(g_alf_covariance_frame[ch_type][i][k].ee, 0, sizeof(g_alf_covariance_frame[ch_type][i][k].ee)); } } } for (int comp_idx = 0; comp_idx < MAX_NUM_COMPONENT; comp_idx++) { g_ctu_enable_flag[comp_idx] = malloc(g_num_ctus_in_pic * sizeof(*g_ctu_enable_flag[comp_idx])); g_ctu_enable_flag_tmp[comp_idx] = malloc(g_num_ctus_in_pic * sizeof(*g_ctu_enable_flag_tmp[comp_idx])); //#if JVET_O0090_ALF_CHROMA_FILTER_ALTERNATIVES_CTB // g_ctu_enable_flag_tmp2[comp_idx] = malloc(g_num_ctus_in_pic * sizeof(*g_ctu_enable_flag_tmp2[comp_idx])); if (comp_idx == COMPONENT_Y) { g_ctu_alternative_tmp[comp_idx] = NULL; g_ctu_alternative[comp_idx] = NULL; } else { g_ctu_alternative_tmp[comp_idx] = malloc(g_num_ctus_in_pic * sizeof(*g_ctu_alternative_tmp[comp_idx])); g_ctu_alternative[comp_idx] = malloc(g_num_ctus_in_pic * sizeof(*g_ctu_alternative[comp_idx])); //std::fill_n(m_ctuAlternativeTmp[compIdx], m_numCTUsInPic, 0); for (int ctu_idx = 0; ctu_idx < g_num_ctus_in_pic; ctu_idx++) { g_ctu_alternative_tmp[comp_idx][ctu_idx] = 0; g_ctu_alternative[comp_idx][ctu_idx] = 0; } } //#endif int num_classes = comp_idx ? 1 : MAX_NUM_ALF_CLASSES; int num_coeffs = comp_idx ? 7 : 13; g_alf_covariance[comp_idx] = malloc(sizeof(***g_alf_covariance[comp_idx])); for (int i = 0; i != 1/*m_filterShapes[ch_type].size()*/; i++) { g_alf_covariance[comp_idx][i] = malloc(g_num_ctus_in_pic * sizeof(**g_alf_covariance[comp_idx][i])); for (int j = 0; j < g_num_ctus_in_pic; j++) { g_alf_covariance[comp_idx][i][j] = malloc(num_classes * sizeof(alf_covariance)); for (int k = 0; k < num_classes; k++) { g_alf_covariance[comp_idx][i][j][k].num_coeff = num_coeffs; g_alf_covariance[comp_idx][i][j][k].num_bins = g_max_alf_num_clipping_values; memset(g_alf_covariance[comp_idx][i][j][k].y, 0, sizeof(g_alf_covariance[comp_idx][i][j][k].y)); memset(g_alf_covariance[comp_idx][i][j][k].ee, 0, sizeof(g_alf_covariance[comp_idx][i][j][k].ee)); } } } } for (int i = 0; i != 1/*m_filterShapes[COMPONENT_Y].size()*/; i++) { for (int j = 0; j <= MAX_NUM_ALF_CLASSES + 1; j++) { g_alf_covariance_merged[i][j].num_coeff = 13; g_alf_covariance_merged[i][j].num_bins = g_max_alf_num_clipping_values; memset(g_alf_covariance_merged[i][j].y, 0, sizeof(g_alf_covariance_merged[i][j].y)); memset(g_alf_covariance_merged[i][j].ee, 0, sizeof(g_alf_covariance_merged[i][j].ee)); } } //#if JVET_O0090_ALF_CHROMA_FILTER_ALTERNATIVES_CTB g_filter_coeff_set = malloc(/*MAX(*/MAX_NUM_ALF_CLASSES/*, MAX_NUM_ALF_ALTERNATIVES_CHROMA)*/ * sizeof(int*)); g_filter_clipp_set = malloc(/*MAX(*/MAX_NUM_ALF_CLASSES/*, MAX_NUM_ALF_ALTERNATIVES_CHROMA)*/ * sizeof(int*)); /*#else g_filter_coeff_set = malloc(MAX_NUM_ALF_CLASSES * sizeof(int*)); g_filter_clipp_set = malloc(MAX_NUM_ALF_CLASSES * sizeof(int*)); #endif*/ g_diff_filter_coeff = malloc(MAX_NUM_ALF_CLASSES * sizeof(int*)); for (int i = 0; i < MAX_NUM_ALF_CLASSES; i++) { g_filter_coeff_set[i] = malloc(MAX_NUM_ALF_LUMA_COEFF * sizeof(int)); g_filter_clipp_set[i] = malloc(MAX_NUM_ALF_LUMA_COEFF * sizeof(int)); g_diff_filter_coeff[i] = malloc(MAX_NUM_ALF_LUMA_COEFF * sizeof(int)); } g_aps_id_start = ALF_CTB_MAX_NUM_APS; //g_ctb_distortion_fixed_filter = malloc(g_num_ctus_in_pic * sizeof(double)); for (int comp = 0; comp < MAX_NUM_COMPONENT; comp++) { g_ctb_distortion_unfilter[comp] = malloc(g_num_ctus_in_pic * sizeof(double)); } g_alf_ctb_filter_index = malloc(g_num_ctus_in_pic * sizeof(*g_alf_ctb_filter_index)); g_alf_ctb_filter_set_index_tmp = malloc(g_num_ctus_in_pic * sizeof(*g_alf_ctb_filter_set_index_tmp)); memset(g_clip_default_enc, 0, sizeof(g_clip_default_enc)); enum kvz_chroma_format chroma_fmt = state->encoder_control->chroma_format; const int number_of_components = (chroma_fmt == KVZ_CSP_400) ? 1 : MAX_NUM_COMPONENT; // init CTU stats buffers for (int comp_idx = 0; comp_idx < number_of_components; comp_idx++) { bool is_luma = comp_idx == 0 ? 1 : 0; const int num_classes = is_luma ? MAX_NUM_ALF_CLASSES : 1; for (int shape = 0; shape != 1 /*m_filterShapes[toChannelType(comp_id)].size()*/; shape++) { for (int class_idx = 0; class_idx < num_classes; class_idx++) { for (int ctu_idx = 0; ctu_idx < g_num_ctus_in_pic; ctu_idx++) { reset_alf_covariance(&g_alf_covariance[comp_idx][shape][ctu_idx][class_idx], g_alf_num_clipping_values[comp_idx == COMPONENT_Y ? CHANNEL_TYPE_LUMA : CHANNEL_TYPE_CHROMA]); } } } } // init Frame stats buffers const int number_of_channels = (chroma_fmt == KVZ_CSP_400) ? 1 : MAX_NUM_CHANNEL_TYPE; for (int channel_idx = 0; channel_idx < number_of_channels; channel_idx++) { const channel_type channel_id = channel_idx; bool is_luma = channel_id == CHANNEL_TYPE_LUMA ? true : false; //#if JVET_O0090_ALF_CHROMA_FILTER_ALTERNATIVES_CTB const int num_alts = is_luma ? 1 : MAX_NUM_ALF_ALTERNATIVES_CHROMA; //#endif const int num_classes = is_luma ? MAX_NUM_ALF_CLASSES : 1; //#if JVET_O0090_ALF_CHROMA_FILTER_ALTERNATIVES_CTB for (int alt_idx = 0; alt_idx < num_alts; ++alt_idx) { //#endif for (int shape = 0; shape != 1/*m_filterShapes[channel_idx].size()*/; shape++) { for (int class_idx = 0; class_idx < num_classes; class_idx++) { //#if JVET_O0090_ALF_CHROMA_FILTER_ALTERNATIVES_CTB reset_alf_covariance(&g_alf_covariance_frame[channel_idx][shape][is_luma ? class_idx : alt_idx], g_alf_num_clipping_values[channel_id]); /*#else reset_alf_covariance(&g_alf_covariance_frame[channel_idx][shape][class_idx], g_alf_num_clipping_values[channel_id]); #endif*/ } } } } // init alf enable flags for (int comp_idx = 0; comp_idx < MAX_NUM_COMPONENT; comp_idx++) { for (int ctu_idx = 0; ctu_idx < g_num_ctus_in_pic; ctu_idx++) { g_ctu_enable_flag[comp_idx][ctu_idx] = 0; //cs.picture->getAlfCtuEnableFlag( compIdx ); //#if JVET_O0090_ALF_CHROMA_FILTER_ALTERNATIVES_CTB if (comp_idx != 0) { g_ctu_alternative[comp_idx][ctu_idx] = 0; //cs.picture->getAlfCtuAlternativeData(compIdx); } //#endif } } const size_t simd_padding_width = 64; int width = state->tile->frame->width; int height = state->tile->frame->height; int stride = state->tile->frame->source->stride; unsigned int luma_size = (width + 8) * (height + 8); unsigned chroma_sizes[] = { 0, luma_size / 4, luma_size / 2, luma_size }; unsigned chroma_size = chroma_sizes[chroma_fmt]; alf_fulldata = MALLOC_SIMD_PADDED(kvz_pixel, (luma_size + 2 * chroma_size), simd_padding_width * 2); alf_fulldata = &alf_fulldata[4 * (width + 8) + 4] + simd_padding_width / sizeof(kvz_pixel); alf_tmp_y = &alf_fulldata[0]; alf_ctb_tmp_y = malloc((64 + 8)*(64 + 8) * sizeof(kvz_pixel)); alf_ctb_tmp_y = &alf_ctb_tmp_y[(64 + 8) * 4 + 4]; if (chroma_fmt == KVZ_CSP_400) { alf_tmp_u = NULL; alf_tmp_v = NULL; alf_ctb_tmp_u = NULL; alf_ctb_tmp_v = NULL; } else { alf_tmp_u = &alf_fulldata[luma_size - (4 * (width + 8) + 4) + (2 * (stride / 2) + 2)]; alf_tmp_v = &alf_fulldata[luma_size - (4 * (width + 8) + 4) + chroma_size + (2 * (stride / 2) + 2)]; alf_ctb_tmp_u = malloc((32 + 4)*(32 + 4) * sizeof(kvz_pixel)); alf_ctb_tmp_u = &alf_ctb_tmp_u[(32 + 4) * 2 + 2]; alf_ctb_tmp_v = malloc((32 + 4)*(32 + 4) * sizeof(kvz_pixel)); alf_ctb_tmp_v = &alf_ctb_tmp_v[(32 + 4) * 2 + 2]; } //kvz_alf_encoder_ctb for (int i = 0; i < ALF_CTB_MAX_NUM_APS; i++) { best_aps_ids[i] = -1; aps_ids[i] = -1; } size_of_aps_ids = 0; } void kvz_frame_end(encoder_state_t const *state, videoframe_t * const frame, const lcu_order_element_t *const lcu) { if (lcu->index != g_num_ctus_in_pic - 1) { return; } if (!g_created) { return; } g_curr_frame += 1; const int width = frame->width; const int height = frame->height; int height_in_lcu = frame->height_in_lcu; int width_in_lcu = frame->width_in_lcu; int luma_stride = frame->rec->stride; int chroma_stride = luma_stride >> chroma_scale_x; int h_end = 0; int h_start = 0; int h_end_chroma = 0; int h_start_chroma = 0; int w_end = 0; int w_start = 0; int w_end_chroma = 0; int w_start_chroma = 0; int cur_ctb = 0; { if (state->slice->tile_group_alf_enabled_flag[COMPONENT_Y]) { for (int h_lcu = 0; h_lcu < height_in_lcu; h_lcu++) { h_end = MIN(h_end + LCU_WIDTH, height); h_end_chroma = h_end >> chroma_scale_y; for (int w_lcu = 0; w_lcu < width_in_lcu; w_lcu++) { w_end = MIN(w_end + LCU_WIDTH, width); w_end_chroma = w_end >> chroma_scale_x; if (g_ctu_enable_flag[COMPONENT_Y][cur_ctb]) { for (int h = h_start; h < h_end; h++) { for (int w = w_start; w < w_end; w++) { frame->rec->y[h * luma_stride + w] = alf_tmp_y[h * luma_stride + w]; } } } if (state->slice->tile_group_alf_enabled_flag[COMPONENT_Cb] || state->slice->tile_group_alf_enabled_flag[COMPONENT_Cr]) { if (g_ctu_enable_flag[COMPONENT_Cb][cur_ctb] && g_ctu_enable_flag[COMPONENT_Cr][cur_ctb]) { for (int h = h_start_chroma; h < h_end_chroma; h++) { for (int w = w_start_chroma; w < w_end_chroma; w++) { frame->rec->u[h * chroma_stride + w] = alf_tmp_u[h * chroma_stride + w]; frame->rec->v[h * chroma_stride + w] = alf_tmp_v[h * chroma_stride + w]; } } } } cur_ctb += 1; w_start = w_end; w_start_chroma = w_end_chroma; } w_start = w_end = 0; w_start_chroma = w_end_chroma = 0; h_start = h_end; h_start_chroma = h_end_chroma; } } } } void kvz_alf_enc_destroy(videoframe_t * const frame) { /*if (lcu->index != g_num_ctus_in_pic - 1) { return; } if (!g_created) { return; } g_curr_frame += 1;*/ /*const int width = frame->width; const int height = frame->height; int height_in_lcu = frame->height_in_lcu; int width_in_lcu = frame->width_in_lcu; int luma_stride = frame->rec->stride; int chroma_stride = luma_stride >> chroma_scale_x; int h_end = 0; int h_start = 0; int h_end_chroma = 0; int h_start_chroma = 0; int w_end = 0; int w_start = 0; int w_end_chroma = 0; int w_start_chroma = 0; int cur_ctb = 0; { if (state->slice->tile_group_alf_enabled_flag[COMPONENT_Y]) { for (int h_lcu = 0; h_lcu < height_in_lcu; h_lcu++) { h_end = MIN(h_end + LCU_WIDTH, height); h_end_chroma = h_end >> chroma_scale_y; for (int w_lcu = 0; w_lcu < width_in_lcu; w_lcu++) { w_end = MIN(w_end + LCU_WIDTH, width); w_end_chroma = w_end >> chroma_scale_x; if (g_ctu_enable_flag[COMPONENT_Y][cur_ctb]) { for (int h = h_start; h < h_end; h++) { for (int w = w_start; w < w_end; w++) { frame->rec->y[h * luma_stride + w] = alf_tmp_y[h * luma_stride + w]; } } } if (state->slice->tile_group_alf_enabled_flag[COMPONENT_Cb] || state->slice->tile_group_alf_enabled_flag[COMPONENT_Cr]) { if (g_ctu_enable_flag[COMPONENT_Cb][cur_ctb] && g_ctu_enable_flag[COMPONENT_Cr][cur_ctb]) { for (int h = h_start_chroma; h < h_end_chroma; h++) { for (int w = w_start_chroma; w < w_end_chroma; w++) { frame->rec->u[h * chroma_stride + w] = alf_tmp_u[h * chroma_stride + w]; frame->rec->v[h * chroma_stride + w] = alf_tmp_v[h * chroma_stride + w]; } } } } cur_ctb += 1; w_start = w_end; w_start_chroma = w_end_chroma; } w_start = w_end = 0; w_start_chroma = w_end_chroma = 0; h_start = h_end; h_start_chroma = h_end_chroma; } } }*/ for (int channel_idx = 0; channel_idx < MAX_NUM_CHANNEL_TYPE; channel_idx++) { if (g_alf_covariance_frame[channel_idx]) { channel_type chType = channel_idx ? CHANNEL_TYPE_CHROMA : CHANNEL_TYPE_LUMA; int numClasses = channel_idx ? 1 : MAX_NUM_ALF_CLASSES; int num_coeff = channel_idx ? 7 : 13; for (int i = 0; i != 1/*m_filterShapes[ch_type].size()*/; i++) { FREE_POINTER(g_alf_covariance_frame[channel_idx][i]); } FREE_POINTER(g_alf_covariance_frame[channel_idx]); } } for (int comp_idx = 0; comp_idx < MAX_NUM_COMPONENT; comp_idx++) { if (g_ctu_enable_flag[comp_idx]) { FREE_POINTER(g_ctu_enable_flag[comp_idx]); } if (g_ctu_enable_flag_tmp[comp_idx]) { FREE_POINTER(g_ctu_enable_flag_tmp[comp_idx]); } //#if JVET_O0090_ALF_CHROMA_FILTER_ALTERNATIVES_CTB /*if (g_ctu_enable_flag_tmp2[comp_idx]) { FREE_POINTER(g_ctu_enable_flag_tmp2[comp_idx]); }*/ if (g_ctu_alternative_tmp[comp_idx]) { FREE_POINTER(g_ctu_alternative_tmp[comp_idx]); } if (g_ctu_alternative[comp_idx]) { FREE_POINTER(g_ctu_alternative[comp_idx]); } //#endif if (g_alf_covariance[comp_idx]) { channel_type chType = comp_idx ? CHANNEL_TYPE_CHROMA : CHANNEL_TYPE_LUMA; int numClasses = comp_idx ? 1 : MAX_NUM_ALF_CLASSES; for (int i = 0; i != 1/*m_filterShapes[ch_type].size()*/; i++) { for (int j = 0; j < g_num_ctus_in_pic; j++) { FREE_POINTER(g_alf_covariance[comp_idx][i][j]); } FREE_POINTER(g_alf_covariance[comp_idx][i]); } FREE_POINTER(g_alf_covariance[comp_idx]); } } if (g_filter_coeff_set) { for (int i = 0; i < MAX_NUM_ALF_CLASSES; i++) { FREE_POINTER(g_filter_coeff_set[i]); } FREE_POINTER(g_filter_coeff_set); } if (g_filter_clipp_set) { for (int i = 0; i < MAX_NUM_ALF_CLASSES; i++) { FREE_POINTER(g_filter_clipp_set[i]); } FREE_POINTER(g_filter_clipp_set); } if (g_diff_filter_coeff) { for (int i = 0; i < MAX_NUM_ALF_CLASSES; i++) { FREE_POINTER(g_diff_filter_coeff[i]); } FREE_POINTER(g_diff_filter_coeff); } /*if (g_ctb_distortion_fixed_filter != NULL) { FREE_POINTER(g_ctb_distortion_fixed_filter); }*/ for (int comp = 0; comp < MAX_NUM_COMPONENT; comp++) { if (g_ctb_distortion_unfilter[comp] != NULL) { FREE_POINTER(g_ctb_distortion_unfilter[comp]); } } if (g_alf_ctb_filter_index) { FREE_POINTER(g_alf_ctb_filter_index); } if (g_alf_ctb_filter_set_index_tmp) { FREE_POINTER(g_alf_ctb_filter_set_index_tmp); } //if (tmp_rec_pic) /*{ memcpy(&frame->rec->y, &tmp_rec_pic->y, sizeof(frame->rec->y)); memcpy(&frame->rec->u, &tmp_rec_pic->u, sizeof(frame->rec->u)); memcpy(&frame->rec->v, &tmp_rec_pic->v, sizeof(frame->rec->v)); memcpy(&frame->rec->data[0], &tmp_rec_pic->data[0], sizeof(frame->rec->data[0])); memcpy(&frame->rec->data[1], &tmp_rec_pic->data[1], sizeof(frame->rec->data[1])); memcpy(&frame->rec->data[2], &tmp_rec_pic->data[2], sizeof(frame->rec->data[2])); tmp_rec_pic = NULL; }*/ /* for (int h = 0; h < height; h++) { for (int w = 0; w < width; w++) { frame->rec->y[h * stride + w] = alf_tmp_y[h * stride + w]; } } stride = stride >> 1; for (int h = 0; h < height >> 1; h++) { for (int w = 0; w < width >> 1; w++) { frame->rec->u[h * stride + w] = alf_tmp_u[h * stride + w]; frame->rec->v[h * stride + w] = alf_tmp_v[h * stride + w]; } } } }*/ //memcpy(&frame->rec->y, &alf_tmp_y, sizeof(frame->rec->y)); //memcpy(&frame->rec->u, &alf_tmp_u, sizeof(frame->rec->u)); //memcpy(&frame->rec->v, &alf_tmp_v, sizeof(frame->rec->v)); kvz_alf_destroy(frame); } void kvz_alf_encoder(encoder_state_t *const state, const lcu_order_element_t *lcu, alf_aps *aps, channel_type channel, //#if ENABLE_QPA const double lambda_chroma_weight // = 0.0 //#endif ) { int ctu_idx = lcu->index; //const TempCtx ctxStart(m_CtxCache, AlfCtx(m_CABACEstimator->getCtx())); const cabac_data_t ctx_start; memcpy(&ctx_start, &cabac_estimator, sizeof(ctx_start)); //TempCtx ctxBest(m_CtxCache); cabac_data_t ctx_best; bool is_luma = channel == CHANNEL_TYPE_LUMA ? 1 : 0; kvz_config cfg = state->encoder_control->cfg; double cost_min = MAX_DOUBLE; g_bits_new_filter[channel] = 0; const int num_classes = is_luma ? MAX_NUM_ALF_CLASSES : 1; int ui_coeff_bits = 0; for (int i_shape_idx = 0; i_shape_idx < 1/*alfFilterShape.size()*/; i_shape_idx++) { //m_alfSliceParamTemp = alfSliceParam; copy_alf_param(&g_alf_aps_temp, aps); //1. get unfiltered distortion //#if JVET_O0090_ALF_CHROMA_FILTER_ALTERNATIVES_CTB if (!is_luma) g_alf_aps_temp.num_alternatives_chroma = 1; //#endif double cost = get_unfiltered_distortion_cov_channel(g_alf_covariance_frame[channel][i_shape_idx], channel); cost /= 1.001; // slight preference for unfiltered choice if (cost < cost_min) { cost_min = cost; if (is_luma) { aps->enabled_flag[COMPONENT_Y] = 0; } else { aps->enabled_flag[COMPONENT_Cb] = 0; aps->enabled_flag[COMPONENT_Cr] = 0; } // no CABAC signalling //ctxBest = AlfCtx(ctxStart); memcpy(&ctx_best, &ctx_start, sizeof(ctx_best)); //setCtuEnableFlag(m_ctuEnableFlagTmp, channel, 0); /*if (is_luma) { memset(g_ctu_enable_flag_tmp[COMPONENT_Y], 0, sizeof(uint8_t) * g_num_ctus_in_pic); } else { memset(g_ctu_enable_flag_tmp[COMPONENT_Cb], 0, sizeof(uint8_t) * g_num_ctus_in_pic); memset(g_ctu_enable_flag_tmp[COMPONENT_Cr], 0, sizeof(uint8_t) * g_num_ctus_in_pic); }*/ set_ctu_enable_flag(g_ctu_enable_flag_tmp, channel, ctu_idx, 0); //#if JVET_O0090_ALF_CHROMA_FILTER_ALTERNATIVES_CTB if (!is_luma) { //for (int ctu_idx = 0; ctu_idx < g_num_ctus_in_pic; ctu_idx++) { g_ctu_alternative_tmp[COMPONENT_Cb][ctu_idx] = 0; g_ctu_alternative_tmp[COMPONENT_Cr][ctu_idx] = 0; //} } //#endif } const int non_linear_flag_max = //#if JVET_O0090_ALF_CHROMA_FILTER_ALTERNATIVES_CTB (is_luma ? cfg.alf_non_linear_luma : 0) // For Chroma non linear flag is check for each alternative filter /*#else (isLuma(channel) ? m_encCfg->getUseNonLinearAlfLuma() : m_encCfg->getUseNonLinearAlfChroma()) #endif*/ ? 2 : 1; for (int non_linear_flag = 0; non_linear_flag < non_linear_flag_max; non_linear_flag++) { //#if JVET_O0090_ALF_CHROMA_FILTER_ALTERNATIVES_CTB for (int num_alternatives = is_luma ? 1 : MIN(g_num_ctus_in_pic * 2, MAX_NUM_ALF_ALTERNATIVES_CHROMA); num_alternatives > 0; num_alternatives--) { if (!is_luma) g_alf_aps_temp.num_alternatives_chroma = num_alternatives; //#endif //2. all CTUs are on //setEnableFlag(m_alfSliceParamTemp, channel, true); if (is_luma) { g_alf_aps_temp.enabled_flag[COMPONENT_Y] = 1; } else { g_alf_aps_temp.enabled_flag[COMPONENT_Cb] = 1; g_alf_aps_temp.enabled_flag[COMPONENT_Cr] = 1; } //#if JVET_O0090_ALF_CHROMA_FILTER_ALTERNATIVES_CTB if (is_luma) g_alf_aps_temp.non_linear_flag[channel][0] = non_linear_flag; /*#else m_alfParamTemp.nonLinearFlag[channel] = nonLinearFlag; #endif*/ //m_CABACEstimator->getCtx() = AlfCtx(ctxStart); memcpy(&cabac_estimator, &ctx_start, sizeof(cabac_estimator)); //setCtuEnableFlag(m_ctuEnableFlag, channel, 1); /*if (is_luma) { memset(g_ctu_enable_flag[COMPONENT_Y], 1, sizeof(uint8_t) * g_num_ctus_in_pic); } else { memset(g_ctu_enable_flag[COMPONENT_Cb], 1, sizeof(uint8_t) * g_num_ctus_in_pic); memset(g_ctu_enable_flag[COMPONENT_Cr], 1, sizeof(uint8_t) * g_num_ctus_in_pic); }*/ set_ctu_enable_flag(g_ctu_enable_flag, channel, ctu_idx, 1); //#if JVET_O0090_ALF_CHROMA_FILTER_ALTERNATIVES_CTB // all alternatives are on if (!is_luma) init_ctu_alternative_chroma(g_ctu_alternative); cost = kvz_alf_get_filter_coeff_and_cost(state, channel, 0, &ui_coeff_bits, i_shape_idx, true, false, ctu_idx); /*#else cost = kvz_alf_get_filter_coeff_and_cost(state, channel, 0, &ui_coeff_bits, i_shape_idx, non_linear_flag != 0, false); #endif*/ if (cost < cost_min) { g_bits_new_filter[channel] = ui_coeff_bits; cost_min = cost; copy_alf_param_w_channel(aps, &g_alf_aps_temp, channel); //ctxBest = AlfCtx(m_CABACEstimator->getCtx()); memcpy(&ctx_best, &cabac_estimator, sizeof(ctx_best)); //setCtuEnableFlag(m_ctuEnableFlagTmp, channel, 1); /*if (is_luma) { memset(g_ctu_enable_flag_tmp[COMPONENT_Y], 1, sizeof(uint8_t) * g_num_ctus_in_pic); } else { memset(g_ctu_enable_flag_tmp[COMPONENT_Cb], 1, sizeof(uint8_t) * g_num_ctus_in_pic); memset(g_ctu_enable_flag_tmp[COMPONENT_Cr], 1, sizeof(uint8_t) * g_num_ctus_in_pic); }*/ set_ctu_enable_flag(g_ctu_enable_flag_tmp, channel, ctu_idx, 1); //#if JVET_O0090_ALF_CHROMA_FILTER_ALTERNATIVES_CTB if (!is_luma) { //memcpy(g_ctu_alternative_tmp[COMPONENT_Cb], g_ctu_alternative[COMPONENT_Cb], sizeof(uint8_t) * g_num_ctus_in_pic); //memcpy(g_ctu_alternative_tmp[COMPONENT_Cr], g_ctu_alternative[COMPONENT_Cr], sizeof(uint8_t) * g_num_ctus_in_pic); g_ctu_alternative_tmp[COMPONENT_Cb][ctu_idx] = g_ctu_alternative[COMPONENT_Cb][ctu_idx]; g_ctu_alternative_tmp[COMPONENT_Cr][ctu_idx] = g_ctu_alternative[COMPONENT_Cr][ctu_idx]; } //#endif } //3. CTU decision double dist_unfilter = 0; //#if JVET_O0090_ALF_CHROMA_FILTER_ALTERNATIVES_CTB double prev_it_cost = MAX_DOUBLE; //#endif //#if JVET_O0090_ALF_CHROMA_FILTER_ALTERNATIVES_CTB const int iter_num = is_luma ? (2 * 4 + 1) : (2 * (2 + g_alf_aps_temp.num_alternatives_chroma - 1) + 1); /*#else const int iterNum = isLuma(channel) ? (2 * 4 + 1) : (2 * 2 + 1); #endif*/ for (int iter = 0; iter < iter_num; iter++) { if ((iter & 0x01) == 0) { //m_CABACEstimator->getCtx() = AlfCtx(ctxStart); memcpy(&cabac_estimator, &ctx_start, sizeof(cabac_estimator)); cost = g_lambda[channel] * ui_coeff_bits; cost += kvz_alf_derive_ctb_alf_enable_flags(state, channel, i_shape_idx, &dist_unfilter, num_classes, ctu_idx, //#if ENABLE_QPA lambda_chroma_weight //#endif ); if (cost < cost_min) { g_bits_new_filter[channel] = ui_coeff_bits; cost_min = cost; //ctxBest = AlfCtx(m_CABACEstimator->getCtx()); memcpy(&ctx_best, &cabac_estimator, sizeof(ctx_best)); //copyCtuEnableFlag(m_ctuEnableFlagTmp, m_ctuEnableFlag, channel); /*if (is_luma) { memcpy(g_ctu_enable_flag_tmp[COMPONENT_Y], g_ctu_enable_flag[COMPONENT_Y], sizeof(uint8_t) * g_num_ctus_in_pic); } else { memcpy(g_ctu_enable_flag_tmp[COMPONENT_Cr], g_ctu_enable_flag[COMPONENT_Cr], sizeof(uint8_t) * g_num_ctus_in_pic); memcpy(g_ctu_enable_flag_tmp[COMPONENT_Cb], g_ctu_enable_flag[COMPONENT_Cb], sizeof(uint8_t) * g_num_ctus_in_pic); }*/ copy_ctu_enable_flag(g_ctu_enable_flag_tmp, g_ctu_enable_flag, channel, ctu_idx); //#if JVET_O0090_ALF_CHROMA_FILTER_ALTERNATIVES_CTB if (!is_luma) { //for (int idx_ctu = 0; idx_ctu < g_num_ctus_in_pic; idx_ctu++) { g_ctu_alternative_tmp[COMPONENT_Cb][ctu_idx] = g_ctu_alternative[COMPONENT_Cb][ctu_idx]; g_ctu_alternative_tmp[COMPONENT_Cr][ctu_idx] = g_ctu_alternative[COMPONENT_Cr][ctu_idx]; //} } //#endif copy_alf_param_w_channel(aps, &g_alf_aps_temp, channel); } //#if JVET_O0090_ALF_CHROMA_FILTER_ALTERNATIVES_CTB else if (cost >= prev_it_cost) { // High probability that we have converged or we are diverging break; } prev_it_cost = cost; //#endif } else { //#if JVET_O0090_ALF_CHROMA_FILTER_ALTERNATIVES_CTB // no need to reset CABAC here, since uiCoeffBits is not affected /*cost = */kvz_alf_get_filter_coeff_and_cost(state, channel, dist_unfilter, &ui_coeff_bits, i_shape_idx, true, false, ctu_idx); /*#else cost = kvz_alf_get_filter_coeff_and_cost(state, channel, dist_unfilter, &ui_coeff_bits, i_shape_idx, true, false); #endif*/ } }//for iter // Decrease number of alternatives and reset ctu params and filters //#if JVET_O0090_ALF_CHROMA_FILTER_ALTERNATIVES_CTB } //#endif }//for non_linea_flag }//for shape_idx //m_CABACEstimator->getCtx() = AlfCtx(ctxBest); memcpy(&cabac_estimator, &ctx_best, sizeof(cabac_estimator)); //#if JVET_O0090_ALF_CHROMA_FILTER_ALTERNATIVES_CTB if (!is_luma) { //memcpy(g_ctu_alternative[COMPONENT_Cb], g_ctu_alternative_tmp[COMPONENT_Cb], sizeof(uint8_t) * g_num_ctus_in_pic); //memcpy(g_ctu_alternative[COMPONENT_Cr], g_ctu_alternative_tmp[COMPONENT_Cr], sizeof(uint8_t) * g_num_ctus_in_pic); g_ctu_alternative[COMPONENT_Cb][ctu_idx] = g_ctu_alternative_tmp[COMPONENT_Cb][ctu_idx]; g_ctu_alternative[COMPONENT_Cr][ctu_idx] = g_ctu_alternative_tmp[COMPONENT_Cr][ctu_idx]; } /*if (is_luma) { memcpy(g_ctu_enable_flag[COMPONENT_Y], g_ctu_enable_flag_tmp[COMPONENT_Y], sizeof(uint8_t) * g_num_ctus_in_pic); } else { memcpy(g_ctu_enable_flag[COMPONENT_Cb], g_ctu_enable_flag_tmp[COMPONENT_Cb], sizeof(uint8_t) * g_num_ctus_in_pic); memcpy(g_ctu_enable_flag[COMPONENT_Cr], g_ctu_enable_flag_tmp[COMPONENT_Cr], sizeof(uint8_t) * g_num_ctus_in_pic); }*/ copy_ctu_enable_flag(g_ctu_enable_flag, g_ctu_enable_flag_tmp, channel, ctu_idx); //#endif } void kvz_alf_get_avai_aps_ids_luma(encoder_state_t *const state, int *new_aps_id, int *aps_ids, int *size_of_aps_ids) { param_set_map *aps_set = state->slice->param_set_map; for (int i = 0; i < ALF_CTB_MAX_NUM_APS; i++) { state->slice->apss[i] = aps_set[i + NUM_APS_TYPE_LEN + T_ALF_APS].parameter_set; } //std::vector result; int aps_id_checked = 0, cur_aps_id = g_aps_id_start; if (cur_aps_id < ALF_CTB_MAX_NUM_APS) { while (aps_id_checked < ALF_CTB_MAX_NUM_APS && (state->frame->slicetype == KVZ_SLICE_I) && *size_of_aps_ids < ALF_CTB_MAX_NUM_APS /*&& /*!cs.slice->getPendingRasInit()*/ && (state->frame->pictype == KVZ_NAL_IDR_W_RADL || state->frame->pictype == KVZ_NAL_IDR_N_LP)) { alf_aps *cur_aps = &state->slice->apss[cur_aps_id]; bool aps_found = aps_set[cur_aps_id + NUM_APS_TYPE_LEN + T_ALF_APS].b_changed; if (aps_found/*cur_aps*/ && cur_aps->t_layer/*cur_aps->getTemporalId()*/ <= state->slice->id/*cs.slice->getTLayer()*/ && cur_aps->new_filter_flag[CHANNEL_TYPE_LUMA]) { //result.push_back(cur_aps_id); bool add_aps = true; for (int aps_idx = 0; aps_idx < (*size_of_aps_ids); aps_idx++) { if (aps_ids[aps_idx] == cur_aps_id) { add_aps = false; continue; } } if (add_aps) { aps_ids[*size_of_aps_ids] = cur_aps_id; (*size_of_aps_ids)++; } } aps_id_checked++; cur_aps_id = (cur_aps_id + 1) % ALF_CTB_MAX_NUM_APS; } } state->slice->tile_group_num_aps = *size_of_aps_ids; for (int i = 0; i < state->slice->tile_group_num_aps; i++) { state->slice->tile_group_luma_aps_id[i] = aps_ids[i]; } *new_aps_id = g_aps_id_start - 1; if (*new_aps_id < 0) { *new_aps_id = (int)ALF_CTB_MAX_NUM_APS - 1; } assert(*new_aps_id < (int)MAX_NUM_APS); //Wrong APS index assignment in getAvaiApsIdsLuma } void kvz_alf_derive_stats_for_filtering(encoder_state_t *const state, const lcu_order_element_t *const lcu) { enum kvz_chroma_format chroma_fmt = state->encoder_control->chroma_format; //alf_classifier **g_classifier = state->tile->frame->alf_info->g_classifier; int32_t pic_width = state->tile->frame->rec->width; int32_t pic_height = state->tile->frame->rec->height; //int ctu_rs_addr = 0; const int number_of_components = (chroma_fmt == KVZ_CSP_400) ? 1 : MAX_NUM_COMPONENT; /*// init CTU stats buffers for (int comp_idx = 0; comp_idx < number_of_components; comp_idx++) { bool is_luma = comp_idx == 0 ? 1 : 0; const int num_classes = is_luma ? MAX_NUM_ALF_CLASSES : 1; for (int shape = 0; shape != 1 /*m_filterShapes[toChannelType(comp_id)].size()*//*; shape++) { for (int class_idx = 0; class_idx < num_classes; class_idx++) { //tämä luup pois /*for (int ctu_idx = 0; ctu_idx < g_num_ctus_in_pic; ctu_idx++) {*//* reset_alf_covariance(&g_alf_covariance[comp_idx][shape][lcu->index][class_idx], g_alf_num_clipping_values[comp_idx == COMPONENT_Y ? CHANNEL_TYPE_LUMA : CHANNEL_TYPE_CHROMA]); //} } } } //kerran jossain muualla (kai?) // init Frame stats buffers const int number_of_channels = (chroma_fmt == KVZ_CSP_400) ? 1 : MAX_NUM_CHANNEL_TYPE; for (int channel_idx = 0; channel_idx < number_of_channels; channel_idx++) { const channel_type channel_id = channel_idx; const int num_classes = channel_id == CHANNEL_TYPE_LUMA ? MAX_NUM_ALF_CLASSES : 1; for (int shape = 0; shape != 1/*m_filterShapes[channel_idx].size()*//*; shape++) { for (int class_idx = 0; class_idx < num_classes; class_idx++) { reset_alf_covariance(&g_alf_covariance_frame[channel_idx][shape][class_idx], g_alf_num_clipping_values[channel_id]); } } }*/ bool clip_top = false, clip_bottom = false, clip_left = false, clip_right = false; int num_hor_vir_bndry = 0, num_ver_vir_bndry = 0; int hor_vir_bndry_pos[] = { 0, 0, 0 }; int ver_vir_bndry_pos[] = { 0, 0, 0 }; int max_cu_height = LCU_WIDTH; //turhat /*for (int y_pos = 0; y_pos < pic_height; y_pos += max_cu_height) { for (int x_pos = 0; x_pos < pic_width; x_pos += max_cu_width) {*/ //lcu->size const int x_pos = lcu->position_px.x; const int y_pos = lcu->position_px.y; const int width = lcu->size.x; //(x_pos + max_cu_width > pic_width) ? (pic_width - x_pos) : max_cu_width; const int height = lcu->size.y; //(y_pos + max_cu_height > pic_height) ? (pic_height - y_pos) : max_cu_height; if (is_crossed_by_virtual_boundaries(x_pos, y_pos, width, height, &clip_top, &clip_bottom, &clip_left, &clip_right, &num_hor_vir_bndry, &num_ver_vir_bndry, hor_vir_bndry_pos, ver_vir_bndry_pos, state)) { int y_start = y_pos; for (int i = 0; i <= num_hor_vir_bndry; i++) { const int y_end = i == num_hor_vir_bndry ? y_pos + height : hor_vir_bndry_pos[i]; const int h = y_end - y_start; const bool clip_t = (i == 0 && clip_top) || (i > 0) || (y_start == 0); const bool clip_b = (i == num_hor_vir_bndry && clip_bottom) || (i < num_hor_vir_bndry) || (y_end == pic_height); int x_start = x_pos; for (int j = 0; j <= num_ver_vir_bndry; j++) { const int x_end = j == num_ver_vir_bndry ? x_pos + width : ver_vir_bndry_pos[j]; const int w = x_end - x_start; const bool clip_l = (j == 0 && clip_left) || (j > 0) || (x_start == 0); const bool clip_r = (j == num_ver_vir_bndry && clip_right) || (j < num_ver_vir_bndry) || (x_end == pic_width); const int w_buf = w + (clip_l ? 0 : MAX_ALF_PADDING_SIZE) + (clip_r ? 0 : MAX_ALF_PADDING_SIZE); const int h_buf = h + (clip_t ? 0 : MAX_ALF_PADDING_SIZE) + (clip_b ? 0 : MAX_ALF_PADDING_SIZE); //PelUnitBuf recBuf = m_tempBuf2.subBuf(UnitArea(cs.area.chromaFormat, Area(0, 0, w_buf, h_buf))); //recBuf.copyFrom(recYuv.subBuf(UnitArea(cs.area.chromaFormat, Area(x_start - (clip_l ? 0 : MAX_ALF_PADDING_SIZE), y_start - (clip_t ? 0 : MAX_ALF_PADDING_SIZE), w_buf, h_buf)))); //recBuf.extendBorderPel(MAX_ALF_PADDING_SIZE); //recBuf = recBuf.subBuf(UnitArea(cs.area.chromaFormat, Area(clip_l ? 0 : MAX_ALF_PADDING_SIZE, clip_t ? 0 : MAX_ALF_PADDING_SIZE, w, h))); //const UnitArea area(m_chromaFormat, Area(0, 0, w, h)); //const UnitArea areaDst(m_chromaFormat, Area(x_start, y_start, w, h)); for (int comp_idx = 0; comp_idx < number_of_components; comp_idx++) { const bool is_luma = comp_idx == COMPONENT_Y ? 1 : 0; channel_type ch_type = is_luma ? CHANNEL_TYPE_LUMA : CHANNEL_TYPE_CHROMA; int blk_w = is_luma ? w : w >> chroma_scale_x; int blk_h = is_luma ? h : h >> chroma_scale_y; int pos_x = is_luma ? x_start : x_start >> chroma_scale_x; int pos_y = is_luma ? y_start : y_start >> chroma_scale_y; int32_t org_stride = is_luma ? state->tile->frame->source->stride : state->tile->frame->source->stride >> chroma_scale_x; int32_t rec_stride = is_luma ? state->tile->frame->rec->stride : state->tile->frame->rec->stride >> chroma_scale_x; kvz_pixel *org = comp_idx ? (comp_idx - 1 ? &state->tile->frame->source->v[pos_x + pos_y * org_stride] : &state->tile->frame->source->u[pos_x + pos_y * org_stride]) : &state->tile->frame->source->y[pos_x + pos_y * org_stride]; kvz_pixel *rec = comp_idx ? (comp_idx - 1 ? &state->tile->frame->rec->v[pos_x + pos_y * org_stride] : &state->tile->frame->rec->u[pos_x + pos_y * org_stride]) : &state->tile->frame->rec->y[pos_x + pos_y * org_stride]; for (int shape = 0; shape !=1/*m_filterShapes[ch_type].size()*/; shape++) { kvz_alf_get_blk_stats(state, lcu, ch_type, &g_alf_covariance[comp_idx][shape][lcu->index], comp_idx ? NULL : g_classifier, org, org_stride, rec, rec_stride, pos_x, pos_y, pos_x, pos_y, blk_w, blk_h, ((comp_idx == 0) ? g_alf_vb_luma_ctu_height : g_alf_vb_chma_ctu_height), ((y_pos + max_cu_height >= pic_height) ? pic_height : ((comp_idx == 0) ? g_alf_vb_luma_pos : g_alf_vb_chma_pos)) ); } } x_start = x_end; } y_start = y_end; } for (int comp_idx = 0; comp_idx < number_of_components; comp_idx++) { const bool is_luma = comp_idx == COMPONENT_Y ? 1 : 0; channel_type ch_type = is_luma ? CHANNEL_TYPE_LUMA : CHANNEL_TYPE_CHROMA; for (int shape = 0; shape != 1/*m_filterShapes[chType].size()*/; shape++) { const int num_classes = is_luma ? MAX_NUM_ALF_CLASSES : 1; for (int class_idx = 0; class_idx < num_classes; class_idx++) { //#if JVET_O0090_ALF_CHROMA_FILTER_ALTERNATIVES_CTB add_alf_cov(&g_alf_covariance_frame[ch_type][shape][is_luma ? class_idx : 0], &g_alf_covariance[comp_idx][shape][lcu->index][class_idx]); /*#else add_alf_cov(&g_alf_covariance_frame[ch_type][shape][class_idx], &g_alf_covariance[comp_idx][shape][lcu->index][class_idx]); #endif*/ } } } } else { for (int comp_idx = 0; comp_idx < number_of_components; comp_idx++) { const bool is_luma = comp_idx == COMPONENT_Y ? 1 : 0; channel_type ch_type = is_luma ? CHANNEL_TYPE_LUMA : CHANNEL_TYPE_CHROMA; int blk_w = is_luma ? width : width >> chroma_scale_x; int blk_h = is_luma ? height : height >> chroma_scale_y; int pos_x = is_luma ? x_pos : x_pos >> chroma_scale_x; int pos_y = is_luma ? y_pos : y_pos >> chroma_scale_y; int32_t org_stride = is_luma ? state->tile->frame->source->stride : state->tile->frame->source->stride >> chroma_scale_x; int32_t rec_stride = is_luma ? state->tile->frame->rec->stride : state->tile->frame->rec->stride >> chroma_scale_x; kvz_pixel *org = comp_idx ? (comp_idx - 1 ? &state->tile->frame->source->v[pos_x + pos_y * org_stride] : &state->tile->frame->source->u[pos_x + pos_y * org_stride]) : &state->tile->frame->source->y[pos_x + pos_y * org_stride]; kvz_pixel *rec = comp_idx ? (comp_idx - 1 ? &state->tile->frame->rec->v[pos_x + pos_y * rec_stride] : &state->tile->frame->rec->u[pos_x + pos_y * rec_stride]) : &state->tile->frame->rec->y[pos_x + pos_y * rec_stride]; for (int shape = 0; shape != 1/*m_filterShapes[ch_type].size()*/; shape++) { kvz_alf_get_blk_stats(state, lcu, ch_type, &g_alf_covariance[comp_idx][shape][lcu->index], comp_idx ? NULL : g_classifier, org, org_stride, rec, rec_stride, pos_x, pos_y, pos_x, pos_y, blk_w, blk_h , (is_luma ? g_alf_vb_luma_ctu_height : g_alf_vb_chma_ctu_height) , ((y_pos + max_cu_height >= pic_height) ? pic_height : ((is_luma) ? g_alf_vb_luma_pos : g_alf_vb_chma_pos))); const int num_classes = is_luma ? MAX_NUM_ALF_CLASSES : 1; for (int class_idx = 0; class_idx < num_classes; class_idx++) { //#if JVET_O0090_ALF_CHROMA_FILTER_ALTERNATIVES_CTB add_alf_cov(&g_alf_covariance_frame[ch_type][shape][is_luma ? class_idx : 0], &g_alf_covariance[comp_idx][shape][lcu->index][class_idx]); /*#else add_alf_cov(&g_alf_covariance_frame[ch_type][shape][class_idx], &g_alf_covariance[comp_idx][shape][lcu->index][class_idx]); #endif*/ } } } } //turhat /*ctu_rs_addr++; } }*/ } void kvz_alf_get_blk_stats(encoder_state_t *const state, const lcu_order_element_t *const lcu, channel_type channel, alf_covariance **alf_covariance, alf_classifier **g_classifier, kvz_pixel *org, int32_t org_stride, kvz_pixel *rec, int32_t rec_stride, const int x_pos, const int y_pos, const int x_dst, const int y_dst, const int width, const int height, int vb_ctu_height, int vb_pos) { static int e_local[MAX_NUM_ALF_LUMA_COEFF][MAX_ALF_NUM_CLIPPING_VALUES]; const int num_bins = g_alf_num_clipping_values[channel]; int num_coeff = channel == CHANNEL_TYPE_LUMA ? 13 : 7; int transpose_idx = 0; int class_idx = 0; for (int i = 0; i < height; i++) { int vb_distance = ((y_dst + i) % vb_ctu_height) - vb_pos; for (int j = 0; j < width; j++) { if (g_classifier && g_classifier[y_dst + i][x_dst + j].class_idx == ALF_UNUSED_CLASS_IDX && g_classifier[y_dst + i][x_dst + j].transpose_idx == ALF_UNUSED_TRANSPOSE_IDX) { continue; } memset(e_local, 0, sizeof(e_local)); if (g_classifier) { alf_classifier* cl = &g_classifier[y_dst + i][x_dst + j]; transpose_idx = cl->transpose_idx; class_idx = cl->class_idx; } double weight = 1.0; if (0/*m_alfWSSD*/) { weight = g_luma_level_to_weight_plut[org[j]]; } int y_local = org[j] - rec[j]; kvz_alf_calc_covariance(e_local, rec + j, rec_stride, channel, transpose_idx, vb_distance); for (int k = 0; k < num_coeff; k++) { for (int l = k; l < num_coeff; l++) { for (int b0 = 0; b0 < num_bins; b0++) { for (int b1 = 0; b1 < num_bins; b1++) { if (0/*m_alfWSSD*/) { (*alf_covariance)[class_idx].ee[b0][b1][k][l] += weight * (double)(e_local[k][b0] * e_local[l][b1]); } else { (*alf_covariance)[class_idx].ee[b0][b1][k][l] += e_local[k][b0] * e_local[l][b1]; } } } } for (int b = 0; b < num_bins; b++) { if (0/*m_alfWSSD*/) { (*alf_covariance)[class_idx].y[b][k] += weight * (double)(e_local[k][b] * y_local); } else { (*alf_covariance)[class_idx].y[b][k] += e_local[k][b] * y_local; } } } if (0/*m_alfWSSD*/) { (*alf_covariance)[class_idx].pix_acc += weight * (double)(y_local * y_local); } else { (*alf_covariance)[class_idx].pix_acc += y_local * y_local; } } org += org_stride; rec += rec_stride; } int num_classes = g_classifier ? MAX_NUM_ALF_CLASSES : 1; for (class_idx = 0; class_idx < num_classes; class_idx++) { for (int k = 1; k < num_coeff; k++) { for (int l = 0; l < k; l++) { for (int b0 = 0; b0 < num_bins; b0++) { for (int b1 = 0; b1 < num_bins; b1++) { (*alf_covariance)[class_idx].ee[b0][b1][k][l] = (*alf_covariance)[class_idx].ee[b1][b0][l][k]; } } } } } } void kvz_alf_calc_covariance(int e_local[MAX_NUM_ALF_LUMA_COEFF][MAX_ALF_NUM_CLIPPING_VALUES], const kvz_pixel *rec, const int stride, const channel_type channel, const int transpose_idx, int vb_distance) { int clip_top_row = -4; int clip_bot_row = 4; if (vb_distance >= -3 && vb_distance < 0) { clip_bot_row = -vb_distance - 1; clip_top_row = -clip_bot_row; // symmetric } else if (vb_distance >= 0 && vb_distance < 3) { clip_top_row = -vb_distance; clip_bot_row = -clip_top_row; // symmetric } const bool is_luma = channel == CHANNEL_TYPE_LUMA; const int *filter_pattern = is_luma ? alf_pattern_7 : alf_pattern_5; const int half_filter_length = (is_luma ? 7 : 5) >> 1; const short* clip = g_alf_clipping_values[channel]; const int num_bins = g_alf_num_clipping_values[channel]; int k = 0; const short curr = rec[0]; if (transpose_idx == 0) { for (int i = -half_filter_length; i < 0; i++) { const kvz_pixel* rec0 = rec + MAX(i, clip_top_row) * stride; const kvz_pixel* rec1 = rec - MAX(i, -clip_bot_row) * stride; for (int j = -half_filter_length - i; j <= half_filter_length + i; j++, k++) { for (int b = 0; b < num_bins; b++) { e_local[filter_pattern[k]][b] += clip_alf(clip[b], curr, rec0[j], rec1[-j]); } } } for (int j = -half_filter_length; j < 0; j++, k++) { for (int b = 0; b < num_bins; b++) { e_local[filter_pattern[k]][b] += clip_alf(clip[b], curr, rec[j], rec[-j]); } } } else if (transpose_idx == 1) { for (int j = -half_filter_length; j < 0; j++) { const kvz_pixel* rec0 = rec + j; const kvz_pixel* rec1 = rec - j; for (int i = -half_filter_length - j; i <= half_filter_length + j; i++, k++) { for (int b = 0; b < num_bins; b++) { e_local[filter_pattern[k]][b] += clip_alf(clip[b], curr, rec0[MAX(i, clip_top_row) * stride], rec1[-MAX(i, -clip_bot_row) * stride]); } } } for (int i = -half_filter_length; i < 0; i++, k++) { for (int b = 0; b < num_bins; b++) { e_local[filter_pattern[k]][b] += clip_alf(clip[b], curr, rec[MAX(i, clip_top_row) * stride], rec[-MAX(i, -clip_bot_row) * stride]); } } } else if (transpose_idx == 2) { for (int i = -half_filter_length; i < 0; i++) { const kvz_pixel* rec0 = rec + MAX(i, clip_top_row) * stride; const kvz_pixel* rec1 = rec - MAX(i, -clip_bot_row) * stride; for (int j = half_filter_length + i; j >= -half_filter_length - i; j--, k++) { for (int b = 0; b < num_bins; b++) { e_local[filter_pattern[k]][b] += clip_alf(clip[b], curr, rec0[j], rec1[-j]); } } } for (int j = -half_filter_length; j < 0; j++, k++) { for (int b = 0; b < num_bins; b++) { e_local[filter_pattern[k]][b] += clip_alf(clip[b], curr, rec[j], rec[-j]); } } } else { for (int j = -half_filter_length; j < 0; j++) { const kvz_pixel* rec0 = rec + j; const kvz_pixel* rec1 = rec - j; for (int i = half_filter_length + j; i >= -half_filter_length - j; i--, k++) { for (int b = 0; b < num_bins; b++) { e_local[filter_pattern[k]][b] += clip_alf(clip[b], curr, rec0[MAX(i, clip_top_row) * stride], rec1[-MAX(i, -clip_bot_row) * stride]); } } } for (int i = -half_filter_length; i < 0; i++, k++) { for (int b = 0; b < num_bins; b++) { e_local[filter_pattern[k]][b] += clip_alf(clip[b], curr, rec[MAX(i, clip_top_row) * stride], rec[-MAX(i, -clip_bot_row) * stride]); } } } for (int b = 0; b < num_bins; b++) { e_local[filter_pattern[k]][b] += curr; } } double kvz_alf_get_filter_coeff_and_cost(encoder_state_t *const state, channel_type channel, double dist_unfilter, int *ui_coeff_bits, int i_shape_idx, bool b_re_collect_stat, bool only_filter_cost, int ctu_idx) { bool is_luma = channel == CHANNEL_TYPE_LUMA ? 1 : 0; const int num_coeff = channel == CHANNEL_TYPE_LUMA ? 13 : 7; //collect stat based on CTU decision if (b_re_collect_stat) { get_frame_stats(channel, i_shape_idx, ctu_idx); } double dist = dist_unfilter; *ui_coeff_bits = 0; /*#if !JVET_O0491_HLS_CLEANUP int ui_slice_flag = 0;*/ //AlfFilterShape& alfFilterShape = m_alfSliceParamTemp.filterShapes[channel][iShapeIdx]; //get filter coeff if (is_luma) { //#if JVET_O0090_ALF_CHROMA_FILTER_ALTERNATIVES_CTB //Tarvitaanko tätä alustusta ollenkaan? const int fill_val = g_alf_aps_temp.non_linear_flag[channel][0] ? g_alf_num_clipping_values[CHANNEL_TYPE_LUMA] / 2 : 0; for (int i = 0; i < MAX_NUM_ALF_CLASSES; i++) { for (int j = 0; j < MAX_NUM_ALF_CLASSES; j++) { for (int k = 0; k < MAX_NUM_ALF_LUMA_COEFF; k++) { g_alf_clip_merged[i_shape_idx][i][j][k] = fill_val; } } } /*#else std::fill_n(m_alfClipMerged[iShapeIdx][0][0], MAX_NUM_ALF_LUMA_COEFF*MAX_NUM_ALF_CLASSES*MAX_NUM_ALF_CLASSES, m_alfParamTemp.nonLinearFlag[channel] ? AlfNumClippingValues[CHANNEL_TYPE_LUMA] / 2 : 0); #endif*/ // Reset Merge Tmp Cov reset_alf_covariance(&g_alf_covariance_merged[i_shape_idx][MAX_NUM_ALF_CLASSES], g_alf_num_clipping_values[channel]); reset_alf_covariance(&g_alf_covariance_merged[i_shape_idx][MAX_NUM_ALF_CLASSES + 1], g_alf_num_clipping_values[channel]); //distortion //clip_merged:iä ei tarvitse nollata ennen dist += kvz_alf_merge_filters_and_cost(state, &g_alf_aps_temp, channel, ui_coeff_bits, g_alf_covariance_frame[channel][i_shape_idx], g_alf_covariance_merged[i_shape_idx], g_alf_clip_merged[i_shape_idx]); } else { //distortion /*#if !JVET_O0090_ALF_CHROMA_FILTER_ALTERNATIVES_CTB assert(num_coeff == g_alf_covariance_frame[channel][i_shape_idx][0].num_coeff); //std::fill_n(m_filterClippSet[0], MAX_NUM_ALF_CHROMA_COEFF, m_alfParamTemp.non_linear_flag[channel] ? AlfNumClippingValues[CHANNEL_TYPE_CHROMA] / 2 : 0); const int fill_val = g_alf_aps_temp.non_linear_flag[channel] ? g_alf_num_clipping_values[CHANNEL_TYPE_CHROMA] / 2 : 0; for (int i = 0; i < MAX_NUM_ALF_CHROMA_COEFF; i++) { g_filter_clipp_set[0][i] = fill_val; } dist += g_alf_covariance_frame[channel][i_shape_idx][0].pix_acc + kvz_alf_derive_coeff_quant(channel, g_filter_clipp_set[0], g_filter_coeff_set[0], &g_alf_covariance_frame[channel][i_shape_idx][0], ALF_NUM_BITS, g_alf_aps_temp.non_linear_flag[channel]); #endif*/ /*#if !JVET_O0491_HLS_CLEANUP //setEnableFlag( m_alfSliceParamTemp, channel, m_ctuEnableFlag ); const int alf_chroma_idc = g_alf_aps_temp.enabled_flag[COMPONENT_Cb] * 2 + g_alf_aps_temp.enabled_flag[COMPONENT_Cr]; #endif*/ for (int alt_idx = 0; alt_idx < g_alf_aps_temp.num_alternatives_chroma; ++alt_idx) { assert(num_coeff == g_alf_covariance_frame[channel][i_shape_idx][alt_idx].num_coeff); alf_aps best_slice_param; double best_cost = MAX_DOUBLE; double best_dist = MAX_DOUBLE; int best_coeff_bits = 0; const int non_linear_flag_max = state->encoder_control->cfg.alf_non_linear_chroma ? 2 : 1; for (int non_linear_flag = 0; non_linear_flag < non_linear_flag_max; non_linear_flag++) { g_alf_aps_temp.non_linear_flag[channel][alt_idx] = non_linear_flag; //std::fill_n(m_filterClippSet[alt_idx], MAX_NUM_ALF_CHROMA_COEFF, non_linear_flag ? AlfNumClippingValues[CHANNEL_TYPE_CHROMA] / 2 : 0); int fill_val = non_linear_flag ? g_alf_num_clipping_values[CHANNEL_TYPE_CHROMA] / 2 : 0; for (int i = 0; i < MAX_NUM_ALF_CHROMA_COEFF; i++) { g_filter_clipp_set[alt_idx][i] = fill_val; } double dist = g_alf_covariance_frame[channel][i_shape_idx][alt_idx].pix_acc + kvz_alf_derive_coeff_quant(channel, g_filter_clipp_set[alt_idx], g_filter_coeff_set[alt_idx], &g_alf_covariance_frame[channel][i_shape_idx][alt_idx], ALF_NUM_BITS, non_linear_flag); for (int i = 0; i < MAX_NUM_ALF_CHROMA_COEFF; i++) { g_alf_aps_temp.chroma_coeff[alt_idx][i] = g_filter_coeff_set[alt_idx][i]; g_alf_aps_temp.chroma_clipp[alt_idx][i] = g_filter_clipp_set[alt_idx][i]; } int coeff_bits = get_chroma_coeff_rate(&g_alf_aps_temp, alt_idx); double cost = dist + g_lambda[channel] * coeff_bits; if (cost < best_cost) { best_cost = cost; best_dist = dist; best_coeff_bits = coeff_bits; copy_alf_param(&best_slice_param, &g_alf_aps_temp); } } *ui_coeff_bits += best_coeff_bits; dist += best_dist; copy_alf_param(&g_alf_aps_temp, &best_slice_param); } *ui_coeff_bits += length_uvlc(g_alf_aps_temp.num_alternatives_chroma - 1); *ui_coeff_bits += g_alf_aps_temp.num_alternatives_chroma; // non-linear flags /*#if !JVET_O0491_HLS_CLEANUP uiSliceFlag = lengthTruncatedUnary(alfChromaIdc, 3) - lengthTruncatedUnary(0, 3); // rate already put on Luma #endif*/ /*#else for (int i = 0; i < MAX_NUM_ALF_CHROMA_COEFF; i++) { g_alf_aps_temp.chroma_coeff[i] = g_filter_coeff_set[0][i]; g_alf_aps_temp.chroma_clipp[i] = g_filter_clipp_set[0][i]; } #endif*/ } if (only_filter_cost) { return dist + g_lambda[channel] * *ui_coeff_bits; } /*#if !JVET_O0491_HLS_CLEANUP double rate = *ui_coeff_bits + ui_slice_flag;*/ double rate = *ui_coeff_bits; //m_CABACEstimator->resetBits(); kvz_cabac_reset_bits(&cabac_estimator); //m_CABACEstimator->codeAlfCtuEnableFlags(cs, channel, &m_alfParamTemp); code_alf_ctu_enable_flags_channel(state, &cabac_estimator, channel, &g_alf_aps_temp); //#if JVET_O0090_ALF_CHROMA_FILTER_ALTERNATIVES_CTB //for (int ctu_idx = 0; ctu_idx < g_num_ctus_in_pic; ctu_idx++) { if (is_luma) { // Evaluate cost of signaling filter set index for convergence of filters enabled flag / filter derivation assert(g_alf_ctb_filter_index[ctu_idx] == ALF_NUM_FIXED_FILTER_SETS); assert(state->slice->tile_group_num_aps == 1); //m_CABACEstimator->codeAlfCtuFilterIndex(cs, ctu_idx, &m_alfParamTemp.enabledFlag[COMPONENT_Y]); code_alf_ctu_filter_index(state, &cabac_estimator, ctu_idx, g_alf_aps_temp.enabled_flag[COMPONENT_Y]); } } //m_CABACEstimator->codeAlfCtuAlternatives(cs, channel, &m_alfParamTemp); code_alf_ctu_alternatives_channel(state, &cabac_estimator, channel, &g_alf_aps_temp, ctu_idx); //#endif rate += (23 - cabac_estimator.bits_left) + (cabac_estimator.num_buffered_bytes << 3); //frac_bits_scale * 0;/*(double)m_CABACEstimator->getEstFracBits();*/ return dist + g_lambda[channel] * rate; } //#if JVET_O0669_REMOVE_ALF_COEFF_PRED int kvz_alf_derive_filter_coefficients_prediction_mode(channel_type channel, int **filter_set, int **filter_coeff_diff, const int num_filters) { return (g_alf_aps_temp.non_linear_flag[CHANNEL_TYPE_LUMA] ? get_cost_filter_clipp(channel, filter_set, num_filters) : 0) + get_cost_filter_coeff(channel, filter_set, num_filters); /* #else int kvz_alf_derive_filter_coefficients_prediction_mode(channel_type channel, int **filter_set, int** filter_coeff_diff, const int num_filters) { int num_coeff = channel == CHANNEL_TYPE_LUMA ? 13 : 7; int rate_pred_mode0 = get_cost_filter_coeff(channel, filter_set, num_filters); for (int ind = 0; ind < num_filters; ++ind) { if (ind == 0) { memcpy(filter_coeff_diff[ind], filter_set[ind], sizeof(int) * num_coeff); } else { for (int i = 0; i < num_coeff; i++) { filter_coeff_diff[ind][i] = filter_set[ind][i] - filter_set[ind - 1][i]; } } } int rate_pred_mode1 = get_cost_filter_coeff(channel, filter_coeff_diff, num_filters); *pred_mode = (rate_pred_mode1 < rate_pred_mode0 && num_filters > 1) ? 1 : 0; return (num_filters > 1 ? 1 : 0) // coeff_delta_pred_mode_flag + (pred_mode ? rate_pred_mode1 : rate_pred_mode0); // min_golomb_order, golomb_order_increase_flag, alf_coeff_luma_delta */ } void kvz_alf_merge_classes(channel_type channel, alf_covariance* cov, alf_covariance* cov_merged, int clip_merged[MAX_NUM_ALF_CLASSES][MAX_NUM_ALF_CLASSES][MAX_NUM_ALF_LUMA_COEFF], const int num_classes, short filter_indices[MAX_NUM_ALF_CLASSES][MAX_NUM_ALF_CLASSES]) { const int num_coeff = channel == CHANNEL_TYPE_LUMA ? 13 : 7; static int tmp_clip[MAX_NUM_ALF_LUMA_COEFF]; static int best_merge_clip[MAX_NUM_ALF_LUMA_COEFF]; static double err[MAX_NUM_ALF_CLASSES]; static double best_merge_err; static bool available_class[MAX_NUM_ALF_CLASSES]; static uint8_t index_list[MAX_NUM_ALF_CLASSES]; static uint8_t index_list_temp[MAX_NUM_ALF_CLASSES]; int num_remaining = num_classes; memset(filter_indices, 0, sizeof(short) * MAX_NUM_ALF_CLASSES * MAX_NUM_ALF_CLASSES); for (int i = 0; i < num_classes; i++) { filter_indices[num_remaining - 1][i] = i; index_list[i] = i; available_class[i] = true; //cov_merged[i] = cov[i]; copy_cov(&cov_merged[i], &cov[i]); //#if JVET_O0090_ALF_CHROMA_FILTER_ALTERNATIVES_CTB cov_merged[i].num_bins = g_alf_aps_temp.non_linear_flag[CHANNEL_TYPE_LUMA][0] ? g_alf_num_clipping_values[COMPONENT_Y] : 1; /*#else cov_merged[i].num_bins = g_alf_aps_temp.non_linear_flag[CHANNEL_TYPE_LUMA] ? g_alf_num_clipping_values[COMPONENT_Y] : 1; #endif*/ } // Try merging different covariance matrices // temporal AlfCovariance structure is allocated as the last element in covMerged array, the size of covMerged is MAX_NUM_ALF_CLASSES + 1 alf_covariance* tmp_cov = &cov_merged[MAX_NUM_ALF_CLASSES]; //#if JVET_O0090_ALF_CHROMA_FILTER_ALTERNATIVES_CTB tmp_cov->num_bins = g_alf_aps_temp.non_linear_flag[CHANNEL_TYPE_LUMA][0] ? g_alf_num_clipping_values[COMPONENT_Y] : 1; /*#else tmp_cov->num_bins = g_alf_aps_temp.non_linear_flag[CHANNEL_TYPE_LUMA] ? g_alf_num_clipping_values[COMPONENT_Y] : 1; #endif*/ // init Clip for (int i = 0; i < num_classes; i++) { //#if JVET_O0090_ALF_CHROMA_FILTER_ALTERNATIVES_CTB for (int val = 0; val < MAX_NUM_ALF_LUMA_COEFF; val++) { clip_merged[num_remaining - 1][i][val] = g_alf_aps_temp.non_linear_flag[CHANNEL_TYPE_LUMA][0] ? g_alf_num_clipping_values[CHANNEL_TYPE_LUMA] / 2 : 0; } if (g_alf_aps_temp.non_linear_flag[CHANNEL_TYPE_LUMA][0]) /*#else for (int val = 0; val < MAX_NUM_ALF_LUMA_COEFF; val++) { clip_merged[num_remaining - 1][i][val] = g_alf_aps_temp.non_linear_flag[CHANNEL_TYPE_LUMA] ? g_alf_num_clipping_values[CHANNEL_TYPE_LUMA] / 2 : 0; } if (g_alf_aps_temp.non_linear_flag[CHANNEL_TYPE_LUMA]) #endif*/ { err[i] = optimize_filter_clip(&cov_merged[i], clip_merged[num_remaining - 1][i]); } else { err[i] = calculate_error_opt_filt(&cov_merged[i], clip_merged[num_remaining - 1][i]); } } while (num_remaining > 2) { double error_min = MAX_DOUBLE; //std::numeric_limits::max(); int best_to_merge_idx1 = 0, best_to_merge_idx2 = 1; for (int i = 0; i < num_classes - 1; i++) { if (available_class[i]) { for (int j = i + 1; j < num_classes; j++) { if (available_class[j]) { double error1 = err[i]; double error2 = err[j]; add_alf_cov_lhs_rhs(tmp_cov, &cov_merged[i], &cov_merged[j]); for (int l = 0; l < MAX_NUM_ALF_LUMA_COEFF; ++l) { tmp_clip[l] = (clip_merged[num_remaining - 1][i][l] + clip_merged[num_remaining - 1][j][l] + 1) >> 1; } //#if JVET_O0090_ALF_CHROMA_FILTER_ALTERNATIVES_CTB double error_merged = g_alf_aps_temp.non_linear_flag[CHANNEL_TYPE_LUMA][0] ? optimize_filter_clip(tmp_cov, tmp_clip) : calculate_error_opt_filt(tmp_cov, tmp_clip); /*#else double error_merged = g_alf_aps_temp.non_linear_flag[CHANNEL_TYPE_LUMA] ? optimize_filter_clip(tmp_cov, tmp_clip) : calculate_error_opt_filt(tmp_cov, tmp_clip); #endif*/ double error = error_merged - error1 - error2; if (error < error_min) { best_merge_err = error_merged; memcpy(best_merge_clip, tmp_clip, sizeof(best_merge_clip)); error_min = error; best_to_merge_idx1 = i; best_to_merge_idx2 = j; } } } } } add_alf_cov(&cov_merged[best_to_merge_idx1], &cov_merged[best_to_merge_idx2]); memcpy(clip_merged[num_remaining - 2], clip_merged[num_remaining - 1], sizeof(int[MAX_NUM_ALF_CLASSES][MAX_NUM_ALF_LUMA_COEFF])); memcpy(clip_merged[num_remaining - 2][best_to_merge_idx1], best_merge_clip, sizeof(best_merge_clip)); err[best_to_merge_idx1] = best_merge_err; available_class[best_to_merge_idx2] = false; for (int i = 0; i < num_classes; i++) { if (index_list[i] == best_to_merge_idx2) { index_list[i] = best_to_merge_idx1; } } num_remaining--; if (num_remaining <= num_classes) { memcpy(index_list_temp, index_list, sizeof(uint8_t) * num_classes); bool exist = false; int ind = 0; for (int j = 0; j < num_classes; j++) { exist = false; for (int i = 0; i < num_classes; i++) { if (index_list_temp[i] == j) { exist = true; break; } } if (exist) { for (int i = 0; i < num_classes; i++) { if (index_list_temp[i] == j) { filter_indices[num_remaining - 1][i] = ind; index_list_temp[i] = -1; } } ind++; } } } } } double kvz_alf_merge_filters_and_cost(encoder_state_t *const state, alf_aps *alf_aps, channel_type channel, int *ui_coeff_bits, alf_covariance *cov_frame, alf_covariance *cov_merged, int clip_merged[MAX_NUM_ALF_CLASSES][MAX_NUM_ALF_CLASSES][MAX_NUM_ALF_LUMA_COEFF]) { const int num_coeff = channel == CHANNEL_TYPE_LUMA ? 13 : 7; int num_filters_best = 0; int num_filters = MAX_NUM_ALF_CLASSES; static bool coded_var_bins[MAX_NUM_ALF_CLASSES]; static double error_force_0_coeff_tab[MAX_NUM_ALF_CLASSES][2]; double cost, cost0, dist, dist_force0, cost_min = MAX_DOUBLE; int coeff_bits, coeff_bits_force0; //clip_merged:iä ei tarvitse nollata ennen kvz_alf_merge_classes(channel, cov_frame, cov_merged, clip_merged, MAX_NUM_ALF_CLASSES, g_filter_indices); while (num_filters >= 1) { dist = kvz_alf_derive_filter_coeffs(alf_aps, channel, cov_frame, cov_merged, g_filter_indices[num_filters-1], num_filters, error_force_0_coeff_tab, clip_merged); // filter coeffs are stored in m_filterCoeffSet dist_force0 = get_dist_force_0(channel, num_filters, error_force_0_coeff_tab, coded_var_bins); coeff_bits = kvz_alf_derive_filter_coefficients_prediction_mode(channel, g_filter_coeff_set, g_diff_filter_coeff, num_filters); coeff_bits_force0 = get_cost_filter_coeff_force_0(channel, g_filter_coeff_set, num_filters, coded_var_bins); cost = dist + g_lambda[COMPONENT_Y] * coeff_bits; cost0 = dist_force0 + g_lambda[COMPONENT_Y] * coeff_bits_force0; if (cost0 < cost) { cost = cost0; } /* #if !JVET_O0669_REMOVE_ALF_COEFF_PRED if (*fixed_filter_set_index > 0) { int len = 0; len += get_tb_length(*fixed_filter_set_index - 1, ALF_NUM_FIXED_FILTER_SETS); len += 1; //fixed filter flag pattern if (*fixed_filter_pattern > 0) { len += MAX_NUM_ALF_CLASSES; //"fixed_filter_flag" for each class } cost += g_lambda[COMPONENT_Y] * len; }*/ if (cost <= cost_min) { cost_min = cost; num_filters_best = num_filters; //best_pred_mode = pred_mode; #if !JVET_O0669_REMOVE_ALF_COEFF_PRED } num_filters--; } dist = kvz_alf_derive_filter_coeffs(alf_aps, channel, cov_frame, cov_merged, g_filter_indices[num_filters_best - 1], num_filters_best, error_force_0_coeff_tab, clip_merged); coeff_bits = kvz_alf_derive_filter_coefficients_prediction_mode(channel, g_filter_coeff_set, g_diff_filter_coeff, num_filters_best); dist_force0 = get_dist_force_0(channel, num_filters_best, error_force_0_coeff_tab, coded_var_bins); coeff_bits_force0 = get_cost_filter_coeff_force_0(channel, g_filter_coeff_set, num_filters_best, coded_var_bins); cost = dist + g_lambda[COMPONENT_Y] * coeff_bits; cost0 = dist_force0 + g_lambda[COMPONENT_Y] * coeff_bits_force0; alf_aps->num_luma_filters = num_filters_best; double dist_return; if (cost <= cost0) { dist_return = dist; alf_aps->alf_luma_coeff_delta_flag = 0; *ui_coeff_bits = coeff_bits; //alf_aps->alf_luma_coeff_delta_prediction_flag = best_pred_mode; #if !JVET_O0669_REMOVE_ALF_COEFF_PRED } else { dist_return = dist_force0; alf_aps->alf_luma_coeff_delta_flag = 1; *ui_coeff_bits = coeff_bits_force0; memcpy(alf_aps->alf_luma_coeff_flag, coded_var_bins, sizeof(coded_var_bins)); //*alf_luma_coeff_delta_prediction_flag = 0; #if !JVET_O0669_REMOVE_ALF_COEFF_PRED for (int var_ind = 0; var_ind < num_filters_best; var_ind++) { if (coded_var_bins[var_ind] == 0) { memset(g_filter_coeff_set[var_ind], 0, sizeof(int) * MAX_NUM_ALF_LUMA_COEFF); memset(g_filter_clipp_set[var_ind], 0, sizeof(int) * MAX_NUM_ALF_LUMA_COEFF); } } } for (int ind = 0; ind < alf_aps->num_luma_filters; ++ind) { for (int i = 0; i < num_coeff; i++) { // #if JVET_O0669_REMOVE_ALF_COEFF_PRED alf_aps->luma_coeff[ind * MAX_NUM_ALF_LUMA_COEFF + i] = g_filter_coeff_set[ind][i]; /* #else if (alf_aps->alf_luma_coeff_delta_prediction_flag) { alf_aps->luma_coeff[ind * MAX_NUM_ALF_LUMA_COEFF + i] = g_diff_filter_coeff[ind][i]; } else { alf_aps->luma_coeff[ind * MAX_NUM_ALF_LUMA_COEFF + i] = g_filter_coeff_set[ind][i]; }*/ alf_aps->luma_clipp[ind * MAX_NUM_ALF_LUMA_COEFF + i] = g_filter_clipp_set[ind][i]; } } memcpy(alf_aps->filter_coeff_delta_idx, g_filter_indices[num_filters_best - 1], sizeof(short) * MAX_NUM_ALF_CLASSES); *ui_coeff_bits += get_non_filter_coeff_rate(alf_aps); return dist_return; } double kvz_alf_derive_filter_coeffs(alf_aps *aps, channel_type channel, alf_covariance *cov, alf_covariance *covMerged, short* filter_indices, int num_filters, double error_tab_force_0_coeff[MAX_NUM_ALF_CLASSES][2], int clip_merged[MAX_NUM_ALF_CLASSES][MAX_NUM_ALF_CLASSES][MAX_NUM_ALF_LUMA_COEFF]) { // #if !JVET_O0669_REMOVE_ALF_COEFF_PRED //int *fixed_filter_pattern = &aps->fixed_filter_pattern; //int *fixed_filter_idx = aps->fixed_filter_idx; //int *fixed_filter_set_index = &aps->fixed_filter_set_index; int num_coeff = channel == CHANNEL_TYPE_LUMA ? 13 : 7; int *weights = channel == CHANNEL_TYPE_LUMA ? alf_weights_7 : alf_weights_5; double error = 0.0; alf_covariance *tmp_cov = &covMerged[MAX_NUM_ALF_CLASSES]; /* #if !JVET_O0669_REMOVE_ALF_COEFF_PRED *fixed_filter_set_index = 0; alf_covariance tmp_cov_ff = covMerged[MAX_NUM_ALF_CLASSES + 1]; double factor = 1 << (ALF_NUM_BITS - 1); double error_min = 0; double error_min_per_class[MAX_NUM_ALF_CLASSES] = { 0 }; double error_cur_set_per_class[MAX_NUM_ALF_CLASSES] = { 0 }; int fixed_filter_flag_per_class[MAX_NUM_ALF_CLASSES] = { 0 }; for (int filter_set_idx = 0; filter_set_idx < ALF_NUM_FIXED_FILTER_SETS; filter_set_idx++) { double error_cur = 0; for (int class_idx = 0; class_idx < MAX_NUM_ALF_CLASSES; class_idx++) { int fixed_filter_idx = g_class_to_filter_mapping[filter_set_idx][class_idx]; error_cur_set_per_class[class_idx] = calc_error_for_coeffs(cov[class_idx].ee, cov[class_idx].y, g_fixed_filter_set_coeff[fixed_filter_idx], MAX_NUM_ALF_LUMA_COEFF, ALF_NUM_BITS); if (error_cur_set_per_class[class_idx] >= 0) { error_cur_set_per_class[class_idx] = 0; fixed_filter_flag_per_class[class_idx] = 0; } else { error_cur += error_cur_set_per_class[class_idx]; fixed_filter_flag_per_class[class_idx] = 1; } } if (error_cur < error_min) { memcpy(fixed_filter_idx, fixed_filter_flag_per_class, sizeof(fixed_filter_flag_per_class)); *fixed_filter_set_index = filter_set_idx + 1; error_min = error_cur; memcpy(error_min_per_class, error_cur_set_per_class, sizeof(error_min_per_class)); } } *fixed_filter_pattern = 0; if (*fixed_filter_set_index > 0) { for (int class_idx = 0; class_idx < MAX_NUM_ALF_CLASSES; class_idx++) { if (fixed_filter_idx[class_idx] == 0) { *fixed_filter_pattern = 1; break; } } }*/ for( int filt_idx = 0; filt_idx < num_filters; filt_idx++ ) { reset_alf_covariance(tmp_cov, -1); bool found_clip = false; for( int class_idx = 0; class_idx < MAX_NUM_ALF_CLASSES; class_idx++ ) { if( filter_indices[class_idx] == filt_idx ) { //tmp_cov += cov[class_idx]; add_alf_cov(tmp_cov, &cov[class_idx]); /* #if !JVET_O0669_REMOVE_ALF_COEFF_PRED //adjust stat tmp_cov_ff = cov[class_idx]; if (*fixed_filter_set_index > 0 && fixed_filter_idx[class_idx] > 0) { int fixed_filter_idx = g_class_to_filter_mapping[*fixed_filter_set_index - 1][class_idx]; tmp_cov_ff.pix_acc += error_min_per_class[class_idx]; for (int i = 0; i < MAX_NUM_ALF_LUMA_COEFF; i++) { double sum = 0; for (int j = 0; j < MAX_NUM_ALF_LUMA_COEFF; j++) { sum += tmp_cov_ff.ee[i][j] * g_fixed_filter_set_coeff[fixed_filter_idx][j]; } sum /= factor; tmp_cov_ff.y[i] -= sum; } } //tmp_cov += tmp_cov_ff; for (int j = 0; j < tmp_cov.num_coeff; j++) { for (int i = 0; i < tmp_cov.num_coeff; i++) { tmp_cov.ee[j][i] += tmp_cov_ff.ee[j][i]; } tmp_cov.y[j] += tmp_cov_ff.y[j]; } tmp_cov.pix_acc += tmp_cov_ff.pix_acc; */ if (!found_clip) { found_clip = true; // clip should be at the adress of shortest one memcpy(g_filter_clipp_set[filt_idx], clip_merged[num_filters - 1][class_idx], sizeof(int[MAX_NUM_ALF_LUMA_COEFF])); } } } // Find coeffcients assert(num_coeff == tmp_cov->num_coeff); error_tab_force_0_coeff[filt_idx][1] = tmp_cov->pix_acc + kvz_alf_derive_coeff_quant(channel, g_filter_clipp_set[filt_idx], g_filter_coeff_set[filt_idx], tmp_cov, ALF_NUM_BITS, false); error_tab_force_0_coeff[filt_idx][0] = tmp_cov->pix_acc; error += error_tab_force_0_coeff[filt_idx][1]; } return error; } double kvz_alf_derive_coeff_quant(channel_type channel, int *filter_clipp, int *filter_coeff_quant, const alf_covariance* cov, const int bit_depth, const bool optimize_clip) { const bool is_luma = channel == CHANNEL_TYPE_LUMA ? true : false; const int num_coeff = is_luma ? 13 : 7; int *weights = is_luma ? alf_weights_7 : alf_weights_5; const int factor = 1 << (ALF_NUM_BITS - 1); const int max_value = factor - 1; const int min_value = -factor + 1; static double filter_coeff[MAX_NUM_ALF_LUMA_COEFF]; optimize_filter(cov, filter_clipp, filter_coeff, optimize_clip); //roundFiltCoeff(filterCoeffQuant, filter_coeff, num_coeff, factor); for (int i = 0; i < num_coeff; i++) { int sign = filter_coeff[i] > 0 ? 1 : -1; filter_coeff_quant[i] = (int)(filter_coeff[i] * sign * factor + 0.5) * sign; } for (int i = 0; i < num_coeff - 1; i++) { filter_coeff_quant[i] = MIN(max_value, MAX(min_value, filter_coeff_quant[i])); } filter_coeff_quant[num_coeff - 1] = 0; int modified = 1; double err_ref = calc_error_for_coeffs(cov, filter_clipp, filter_coeff_quant, num_coeff, bit_depth); int sign; while (modified) { modified = 0; for (int sign_count = 0; sign_count <= 1; sign_count++) { sign = sign_count == 0 ? 1 : -1; double err_min = MAX_DOUBLE; int min_ind = -1; for (int k = 0; k < num_coeff - 1; k++) { if (filter_coeff_quant[k] - sign > max_value || filter_coeff_quant[k] - sign < min_value) continue; filter_coeff_quant[k] -= sign; double error = calc_error_for_coeffs(cov, filter_clipp, filter_coeff_quant, num_coeff, bit_depth); if (error < err_min) { err_min = error; min_ind = k; } filter_coeff_quant[k] += sign; } if (err_min < err_ref) { filter_coeff_quant[min_ind] -= sign; modified++; err_ref = err_min; } } } return err_ref; } void kvz_alf_encoder_ctb(encoder_state_t *const state, alf_aps *aps, int ctu_idx, //#if ENABLE_QPA const double lambda_chroma_weight //#endif ) { //TempCtx ctxStart(m_CtxCache, AlfCtx(m_CABACEstimator->getCtx())); cabac_data_t ctx_start; memcpy(&ctx_start, &cabac_estimator, sizeof(ctx_start)); //TempCtx ctxBest(m_CtxCache); cabac_data_t ctx_best; //TempCtx ctxTempStart(m_CtxCache); cabac_data_t ctx_temp_start; //TempCtx ctxTempBest(m_CtxCache);*/ cabac_data_t ctx_temp_best; //#if JVET_O0090_ALF_CHROMA_FILTER_ALTERNATIVES_CTB /*TempCtx ctxTempAltStart(m_CtxCache); TempCtx ctxTempAltBest(m_CtxCache);*/ cabac_data_t ctx_temp_alt_start; cabac_data_t ctx_temp_alt_best; //#endif //AlfSliceParam alfSliceParamNewFiltersBest = alfSliceParamNewFilters; alf_aps alf_aps_new_filters_best; copy_alf_param(&alf_aps_new_filters_best, aps); alf_aps* apss = state->slice->apss; bool has_new_filters[2] = { aps->enabled_flag[COMPONENT_Y] , aps->enabled_flag[COMPONENT_Cb] || aps->enabled_flag[COMPONENT_Cr] }; //initDistortion(); for (int comp = 0; comp < MAX_NUM_COMPONENT; comp++) { //for (int ctb_idx = 0; ctb_idx < g_num_ctus_in_pic; ctb_idx++) { g_ctb_distortion_unfilter[comp][ctu_idx] = get_unfiltered_distortion_cov_classes(g_alf_covariance[comp][0][ctu_idx], comp == 0 ? MAX_NUM_ALF_CLASSES : 1); } } //luma //#if JVET_O0090_ALF_CHROMA_FILTER_ALTERNATIVES_CTB copy_alf_param(&g_alf_aps_temp, aps); //#endif //memset(g_ctu_enable_flag[COMPONENT_Y], 1, sizeof(uint8_t) * g_num_ctus_in_pic); g_ctu_enable_flag[COMPONENT_Y][ctu_idx] = 1; get_frame_stats(CHANNEL_TYPE_LUMA, 0, ctu_idx); //memset(g_ctu_enable_flag[COMPONENT_Y], 0, sizeof(uint8_t) * g_num_ctus_in_pic); g_ctu_enable_flag[COMPONENT_Y][ctu_idx] = 0; double cost_off = get_unfiltered_distortion_cov_channel(g_alf_covariance_frame[CHANNEL_TYPE_LUMA][0], CHANNEL_TYPE_LUMA); kvz_alf_get_avai_aps_ids_luma(state, &new_aps_id, aps_ids, &size_of_aps_ids); double cost_min = MAX_DOUBLE; kvz_alf_reconstruct_coeff_aps(state, true, false, true); int num_loops = has_new_filters[CHANNEL_TYPE_LUMA] ? 2 : 1; for (int use_new_filter = 0; use_new_filter < num_loops; use_new_filter++) { int bits_new_filter = 0; if (use_new_filter == 1) { if (!has_new_filters[CHANNEL_TYPE_LUMA]) { continue; } else { bits_new_filter = g_bits_new_filter[CHANNEL_TYPE_LUMA]; kvz_alf_reconstruct_coeff(state, aps, CHANNEL_TYPE_LUMA, true, true); } } int num_iter = use_new_filter ? 2 : 1; for (int num_temporal_aps = 0; num_temporal_aps <= size_of_aps_ids/*apsIds.size()*/; num_temporal_aps++) { if (num_temporal_aps + use_new_filter >= ALF_CTB_MAX_NUM_APS) { continue; } //cs.slice->setTileGroupNumAps(numTemporalAps + useNewFilter); state->slice->tile_group_num_aps = num_temporal_aps + use_new_filter; int num_filter_set = ALF_NUM_FIXED_FILTER_SETS + num_temporal_aps + use_new_filter; if (num_temporal_aps == size_of_aps_ids && num_temporal_aps > 0 && use_new_filter && new_aps_id == aps_ids[size_of_aps_ids - 1] /*apsIds.back()*/) //last temporalAPS is occupied by new filter set and this temporal APS becomes unavailable { continue; } for (int iter = 0; iter < num_iter; iter++) { //g_alf_aps_temp = aps; copy_alf_param(&g_alf_aps_temp, aps); g_alf_aps_temp.enabled_flag[CHANNEL_TYPE_LUMA] = true; double cur_cost = 3 * g_lambda[CHANNEL_TYPE_LUMA]; if (iter > 0) //re-derive new filter-set { double d_dist_org_new_filter = 0; int blocks_using_new_filter = 0; //for (int ctb_idx = 0; ctb_idx < g_num_ctus_in_pic; ctb_idx++) { if (g_ctu_enable_flag[COMPONENT_Y][ctu_idx] && g_alf_ctb_filter_index[ctu_idx] != ALF_NUM_FIXED_FILTER_SETS) { g_ctu_enable_flag[COMPONENT_Y][ctu_idx] = 0; } else if (g_ctu_enable_flag[COMPONENT_Y][ctu_idx] && g_alf_ctb_filter_index[ctu_idx] == ALF_NUM_FIXED_FILTER_SETS) { blocks_using_new_filter++; d_dist_org_new_filter += g_ctb_distortion_unfilter[COMPONENT_Y][ctu_idx]; for (int class_idx = 0; class_idx < MAX_NUM_ALF_CLASSES; class_idx++) { short* p_coeff = g_coeff_final; short* p_clipp = g_clipp_final; for (int i = 0; i < MAX_NUM_ALF_LUMA_COEFF; i++) { g_filter_tmp[i] = p_coeff[class_idx * MAX_NUM_ALF_LUMA_COEFF + i]; g_clip_tmp[i] = p_clipp[class_idx * MAX_NUM_ALF_LUMA_COEFF + i]; } d_dist_org_new_filter += calc_error_for_coeffs(&g_alf_covariance[COMPONENT_Y][0][ctu_idx][class_idx], g_clip_tmp, g_filter_tmp, MAX_NUM_ALF_LUMA_COEFF, ALF_NUM_BITS); } } } if (blocks_using_new_filter > 0 && blocks_using_new_filter < g_num_ctus_in_pic) { int bit_nl[2] = { 0, 0 }; double err_nl[2] = { 0.0, 0.0 }; err_nl[1] = MAX_DOUBLE; //#if JVET_O0090_ALF_CHROMA_FILTER_ALTERNATIVES_CTB g_alf_aps_temp.non_linear_flag[CHANNEL_TYPE_LUMA][0] = 1; /*#else g_alf_aps_temp.non_linear_flag[CHANNEL_TYPE_LUMA] = 1; #endif*/ if (state->encoder_control->cfg.alf_non_linear_luma) { err_nl[1] = kvz_alf_get_filter_coeff_and_cost(state, CHANNEL_TYPE_LUMA, 0, &bit_nl[1], 0, true, true, ctu_idx); copy_alf_param(&g_alf_aps_temp_nl, &g_alf_aps_temp); } else { err_nl[1] = MAX_DOUBLE; } //#if JVET_O0090_ALF_CHROMA_FILTER_ALTERNATIVES_CTB g_alf_aps_temp.non_linear_flag[CHANNEL_TYPE_LUMA][0] = 0; /*#else g_alf_aps_temp.non_linear_flag[CHANNEL_TYPE_LUMA] = 0; #endif*/ //errNL[0] = getFilterCoeffAndCost(cs, 0, CHANNEL_TYPE_LUMA, true, 0, bitNL[0], true); err_nl[0] = kvz_alf_get_filter_coeff_and_cost(state, CHANNEL_TYPE_LUMA, 0, &bit_nl[0], 0, true, true, ctu_idx); int bitsNewFilterTempLuma = bit_nl[0]; int bits_new_filter_temp_luma = bit_nl[0]; double err = err_nl[0]; if (err_nl[1] < err_nl[0]) { err = err_nl[1]; bits_new_filter_temp_luma = bit_nl[1]; copy_alf_param(&g_alf_aps_temp, &g_alf_aps_temp_nl); } if (d_dist_org_new_filter + g_lambda[CHANNEL_TYPE_LUMA] * g_bits_new_filter[CHANNEL_TYPE_LUMA] < err) //re-derived filter is not good, skip { continue; } kvz_alf_reconstruct_coeff(state, &g_alf_aps_temp, CHANNEL_TYPE_LUMA, true, true); bits_new_filter = bits_new_filter_temp_luma; } else //no blocks using new filter, skip { continue; } } //m_CABACEstimator->getCtx() = ctxStart; memcpy(&cabac_estimator, &ctx_start, sizeof(cabac_estimator)); //for (int ctb_idx = 0; ctb_idx < g_num_ctus_in_pic; ctb_idx++) { double dist_unfilter_ctb = g_ctb_distortion_unfilter[COMPONENT_Y][ctu_idx]; //ctb on g_ctu_enable_flag[COMPONENT_Y][ctu_idx] = 1; double cost_on = MAX_DOUBLE; //ctxTempStart = AlfCtx(m_CABACEstimator->getCtx()); memcpy(&ctx_temp_start, &cabac_estimator, sizeof(ctx_temp_start)); ctx_temp_start.only_count = 1; int i_best_filter_set_idx = 0; for (int filter_set_idx = 0; filter_set_idx < num_filter_set; filter_set_idx++) { //rate //m_CABACEstimator->getCtx() = AlfCtx(ctxTempStart); memcpy(&cabac_estimator, &ctx_temp_start, sizeof(cabac_estimator)); //m_CABACEstimator->resetBits(); kvz_cabac_reset_bits(&cabac_estimator); //m_CABACEstimator->codeAlfCtuEnableFlag(cs, ctbIdx, COMPONENT_Y, &m_alfSliceParamTemp); code_alf_ctu_enable_flag(state, &cabac_estimator, ctu_idx, COMPONENT_Y, &g_alf_aps_temp); g_alf_ctb_filter_index[ctu_idx] = filter_set_idx; code_alf_ctu_filter_index(state, &cabac_estimator, ctu_idx, g_alf_aps_temp.enabled_flag[COMPONENT_Y]); double rate_on = (23 - cabac_estimator.bits_left) + (cabac_estimator.num_buffered_bytes << 3); //frac_bits_scale * 0; /*(double)m_CABACEstimator->getEstFracBits()*/ ; //distortion double dist = dist_unfilter_ctb; for (int class_idx = 0; class_idx < MAX_NUM_ALF_CLASSES; class_idx++) { if (filter_set_idx < ALF_NUM_FIXED_FILTER_SETS) { int filter_idx = g_class_to_filter_mapping[filter_set_idx][class_idx]; dist += calc_error_for_coeffs(&g_alf_covariance[COMPONENT_Y][0][ctu_idx][class_idx], g_clip_default_enc, g_fixed_filter_set_coeff[filter_idx], MAX_NUM_ALF_LUMA_COEFF, ALF_NUM_BITS); } else { short *p_coeff; short *p_clipp; if (use_new_filter && filter_set_idx == ALF_NUM_FIXED_FILTER_SETS) { p_coeff = g_coeff_final; p_clipp = g_clipp_final; } else if (use_new_filter) { p_coeff = g_coeff_aps_luma[filter_set_idx - 1 - ALF_NUM_FIXED_FILTER_SETS]; p_clipp = g_clipp_aps_luma[filter_set_idx - 1 - ALF_NUM_FIXED_FILTER_SETS]; } else { p_coeff = g_coeff_aps_luma[filter_set_idx - ALF_NUM_FIXED_FILTER_SETS]; p_clipp = g_clipp_aps_luma[filter_set_idx - ALF_NUM_FIXED_FILTER_SETS]; } for (int i = 0; i < MAX_NUM_ALF_LUMA_COEFF; i++) { g_filter_tmp[i] = p_coeff[class_idx * MAX_NUM_ALF_LUMA_COEFF + i]; g_clip_tmp[i] = p_clipp[class_idx * MAX_NUM_ALF_LUMA_COEFF + i]; } dist += calc_error_for_coeffs(&g_alf_covariance[COMPONENT_Y][0][ctu_idx][class_idx], g_clip_tmp, g_filter_tmp, MAX_NUM_ALF_LUMA_COEFF, ALF_NUM_BITS); } } //cost double cost_on_tmp = dist + g_lambda[COMPONENT_Y] * rate_on; if (cost_on_tmp < cost_on) { //ctxTempBest = AlfCtx(m_CABACEstimator->getCtx()); memcpy(&ctx_temp_best, &cabac_estimator, sizeof(ctx_temp_best)); ctx_temp_best.only_count = 1; cost_on = cost_on_tmp; i_best_filter_set_idx = filter_set_idx; } } //ctb off g_ctu_enable_flag[COMPONENT_Y][ctu_idx] = 0; //rate //m_CABACEstimator->getCtx() = AlfCtx(ctxTempStart); memcpy(&cabac_estimator, &ctx_temp_start, sizeof(cabac_estimator)); //m_CABACEstimator->resetBits(); kvz_cabac_reset_bits(&cabac_estimator); //m_CABACEstimator->codeAlfCtuEnableFlag(cs, ctbIdx, COMPONENT_Y, &m_alfSliceParamTemp); code_alf_ctu_enable_flag(state, &cabac_estimator, ctu_idx, COMPONENT_Y, &g_alf_aps_temp); //cost double cost_off = dist_unfilter_ctb + g_lambda[COMPONENT_Y] * (23 - cabac_estimator.bits_left) + (cabac_estimator.num_buffered_bytes << 3);// frac_bits_scale * 0; /* (double)m_CABACEstimator->getEstFracBits()*/ ; if (cost_on < cost_off) { //m_CABACEstimator->getCtx() = AlfCtx(ctxTempBest); memcpy(&cabac_estimator, &ctx_temp_best, sizeof(cabac_estimator)); g_ctu_enable_flag[COMPONENT_Y][ctu_idx] = 1; g_alf_ctb_filter_index[ctu_idx] = i_best_filter_set_idx; cur_cost += cost_on; } else { g_ctu_enable_flag[COMPONENT_Y][ctu_idx] = 0; cur_cost += cost_off; } } //for(ctbIdx) int tmp_bits = bits_new_filter + 3 * (num_filter_set - ALF_NUM_FIXED_FILTER_SETS); cur_cost += tmp_bits * g_lambda[COMPONENT_Y]; if (cur_cost < cost_min) { cost_min = cur_cost; //bestApsIds.resize(numFilterSet - alf_num_fixed_filter_sets); for (int i = 0; i < num_filter_set - ALF_NUM_FIXED_FILTER_SETS/*bestApsIds.size()*/; i++) { if (i == 0 && use_new_filter) { best_aps_ids[i] = new_aps_id; } else { best_aps_ids[i] = aps_ids[i - use_new_filter]; } } //alfSliceParamNewFiltersBest = m_alfSliceParamTemp; copy_alf_param(&alf_aps_new_filters_best, &g_alf_aps_temp); //ctxBest = AlfCtx(m_CABACEstimator->getCtx()); memcpy(&ctx_best, &cabac_estimator, sizeof(ctx_best)); //copyCtuEnableFlag(m_ctuEnableFlagTmp, m_ctuEnableFlag, CHANNEL_TYPE_LUMA); //memcpy(g_ctu_enable_flag_tmp[COMPONENT_Y], g_ctu_enable_flag[COMPONENT_Y], sizeof(uint8_t) * g_num_ctus_in_pic); copy_ctu_enable_flag(g_ctu_enable_flag_tmp, g_ctu_enable_flag, COMPONENT_Y, ctu_idx); //for (int ctu_idx = 0; ctu_idx < g_num_ctus_in_pic; ctu_idx++) { g_alf_ctb_filter_set_index_tmp[ctu_idx] = g_alf_ctb_filter_index[ctu_idx]; } alf_aps_new_filters_best.new_filter_flag[CHANNEL_TYPE_LUMA] = use_new_filter; } }//for (int iter = 0; iter < numIter; iter++) }// for (int numTemporalAps = 0; numTemporalAps < apsIds.size(); numTemporalAps++) }//for (int useNewFilter = 0; useNewFilter <= 1; useNewFilter++) if (cost_off <= cost_min) { memset(state->slice->tile_group_alf_enabled_flag, 0, sizeof(state->slice->tile_group_alf_enabled_flag)); state->slice->tile_group_num_aps = 0; for (int i = 0; i < MAX_NUM_COMPONENT; i++) { //memset(g_ctu_enable_flag[i], 0, sizeof(uint8_t) * g_num_ctus_in_pic); g_ctu_enable_flag[i][ctu_idx] = 0; } return; } else { //alfSliceParamNewFiltersBest.tLayer = cs.slice->getTLayer(); alf_aps_new_filters_best.t_layer = state->slice->id; //cs.slice->setTileGroupAlfEnabledFlag(COMPONENT_Y, true); state->slice->tile_group_alf_enabled_flag[COMPONENT_Y] = true; //cs.slice->setTileGroupNumAps((int)bestApsIds.size()); int size_of_best_aps_ids = 0; for (int i = 0; i < 8; i++) { if (best_aps_ids[i] != -1) { size_of_best_aps_ids++; } } state->slice->tile_group_num_aps = size_of_best_aps_ids; //cs.slice->setAPSs(bestApsIds); for (int i = 0; i < size_of_best_aps_ids; i++) { state->slice->tile_group_luma_aps_id[i] = best_aps_ids[i]; } //copyCtuEnableFlag(m_ctuEnableFlag, m_ctuEnableFlagTmp, CHANNEL_TYPE_LUMA); //memcpy(g_ctu_enable_flag[COMPONENT_Y], g_ctu_enable_flag_tmp[COMPONENT_Y], sizeof(uint8_t) * g_num_ctus_in_pic); copy_ctu_enable_flag(g_ctu_enable_flag, g_ctu_enable_flag_tmp, CHANNEL_TYPE_LUMA, ctu_idx); //for (int ctu_idx = 0; ctu_idx < g_num_ctus_in_pic; ctu_idx++) { g_alf_ctb_filter_index[ctu_idx] = g_alf_ctb_filter_set_index_tmp[ctu_idx]; } if (alf_aps_new_filters_best.new_filter_flag[CHANNEL_TYPE_LUMA]) { //APS* newAPS = m_apsMap->getPS((new_aps_id << NUM_APS_TYPE_LEN) + T_ALF_APS); alf_aps* new_aps = &state->slice->param_set_map[new_aps_id + NUM_APS_TYPE_LEN + T_ALF_APS].parameter_set; if (new_aps->aps_id < 0 || new_aps->aps_id >= ALF_CTB_MAX_NUM_APS) // new_aps == NULL { //newAPS = m_apsMap->allocatePS(new_aps_id); assert(new_aps_id + NUM_APS_TYPE_LEN + T_ALF_APS < MAX_NUM_APS); //Invalid PS id bool found = false; for (int i = 0; i < ALF_CTB_MAX_NUM_APS; i++) { if (state->slice->param_set_map[i].parameter_set.aps_id == new_aps_id + NUM_APS_TYPE_LEN + T_ALF_APS) { found = true; } } if (!found) { state->slice->param_set_map[new_aps_id + NUM_APS_TYPE_LEN + T_ALF_APS].b_changed = true; //state->slice->param_set_map[new_aps_id + NUM_APS_TYPE_LEN+ T_ALF_APS].p_nalu_data = 0; //state->slice->param_set_map[new_aps_id + NUM_APS_TYPE_LEN + T_ALF_APS].parameter_set = malloc(sizeof(alf_aps)); state->slice->param_set_map[new_aps_id + NUM_APS_TYPE_LEN + T_ALF_APS].parameter_set.aps_id = new_aps_id + NUM_APS_TYPE_LEN + T_ALF_APS; } copy_alf_param(new_aps, &state->slice->param_set_map[new_aps_id + NUM_APS_TYPE_LEN + T_ALF_APS].parameter_set); new_aps->aps_id = new_aps_id; new_aps->aps_type = T_ALF_APS; } copy_alf_param(new_aps, &alf_aps_new_filters_best); new_aps->new_filter_flag[CHANNEL_TYPE_CHROMA] = false; state->slice->param_set_map[new_aps_id + NUM_APS_TYPE_LEN + T_ALF_APS].b_changed = true; g_aps_id_start = new_aps_id; } //std::vector apsIds = cs.slice->getTileGroupApsIdLuma(); int* aps_ids = state->slice->tile_group_luma_aps_id; for (int i = 0; i < state->slice->tile_group_num_aps; i++) { //apss[apsIds[i]] = m_apsMap->getPS((apsIds[i] << NUM_APS_TYPE_LEN) + T_ALF_APS); state->slice->apss[aps_ids[i]].aps_id = state->slice->param_set_map[aps_ids[i + NUM_APS_TYPE_LEN + T_ALF_APS]].parameter_set.aps_id; state->slice->apss[aps_ids[i]].aps_type = state->slice->param_set_map[aps_ids[i + NUM_APS_TYPE_LEN + T_ALF_APS]].parameter_set.aps_type; copy_alf_param(&state->slice->apss[aps_ids[i]], &state->slice->param_set_map[aps_ids[i + NUM_APS_TYPE_LEN + T_ALF_APS]].parameter_set); } } //chroma //#if JVET_O0090_ALF_CHROMA_FILTER_ALTERNATIVES_CTB copy_alf_param(&g_alf_aps_temp, &alf_aps_new_filters_best); if (g_alf_aps_temp.num_alternatives_chroma < 1) { g_alf_aps_temp.num_alternatives_chroma = 1; } //set_ctu_alternative_chroma(m_ctuAlternative, 0); //for (int ctu_idx = 0; ctu_idx < g_num_ctus_in_pic; ctu_idx++) { g_ctu_alternative[COMPONENT_Cb][ctu_idx] = 0; g_ctu_alternative[COMPONENT_Cr][ctu_idx] = 0; } //#endif //memset(g_ctu_enable_flag[COMPONENT_Cb], 1, sizeof(uint8_t) * g_num_ctus_in_pic); //memset(g_ctu_enable_flag[COMPONENT_Cr], 1, sizeof(uint8_t) * g_num_ctus_in_pic); set_ctu_enable_flag(g_ctu_enable_flag, CHANNEL_TYPE_CHROMA, ctu_idx, 1); get_frame_stats(CHANNEL_TYPE_CHROMA, 0, ctu_idx); cost_off = get_unfiltered_distortion_cov_channel(g_alf_covariance_frame[CHANNEL_TYPE_CHROMA][0], CHANNEL_TYPE_CHROMA); cost_min = MAX_DOUBLE; //m_CABACEstimator->getCtx() = AlfCtx(ctxBest); memcpy(&cabac_estimator, &ctx_best, sizeof(cabac_estimator)); //ctxStart = AlfCtx(m_CABACEstimator->getCtx()); memcpy(&ctx_start, &cabac_estimator, sizeof(ctx_start)); ctx_start.only_count = 1; int new_aps_id_chroma = -1; if (alf_aps_new_filters_best.new_filter_flag[CHANNEL_TYPE_LUMA] && (alf_aps_new_filters_best.enabled_flag[COMPONENT_Cb] || alf_aps_new_filters_best.enabled_flag[COMPONENT_Cr])) { new_aps_id_chroma = new_aps_id; } else if (alf_aps_new_filters_best.enabled_flag[COMPONENT_Cb] || alf_aps_new_filters_best.enabled_flag[COMPONENT_Cr]) { int cur_id = g_aps_id_start; while (new_aps_id_chroma < 0) { cur_id--; if (cur_id < 0) { cur_id = ALF_CTB_MAX_NUM_APS - 1; } bool found = false; for (int i = 0; i < 8; i++) { if (cur_id == best_aps_ids[i]) { found = true; } } if (!found) { new_aps_id_chroma = cur_id; } } } for (int cur_aps_id = 0; cur_aps_id < ALF_CTB_MAX_NUM_APS; cur_aps_id++) { if ((/*(cs.slice->getPendingRasInit() ||*/ (state->frame->pictype == KVZ_NAL_IDR_W_RADL || state->frame->pictype == KVZ_NAL_IDR_N_LP) || (state->frame->slicetype == KVZ_SLICE_I)) && cur_aps_id != new_aps_id_chroma) { continue; } //APS* cur_aps = m_apsMap->getPS(cur_aps_id); alf_aps* cur_aps = &state->slice->param_set_map[cur_aps_id + NUM_APS_TYPE_LEN + T_ALF_APS].parameter_set; double cur_cost = g_lambda[CHANNEL_TYPE_CHROMA]/*981.62883931057581*/ * 3; if (cur_aps_id == new_aps_id_chroma) { copy_alf_param(&g_alf_aps_temp, aps); cur_cost += g_lambda[CHANNEL_TYPE_CHROMA] * g_bits_new_filter[CHANNEL_TYPE_CHROMA]; } else if (cur_aps && cur_aps->t_layer <= state->slice->id && cur_aps->new_filter_flag[CHANNEL_TYPE_CHROMA]) { //g_alf_slice_aps_temp = cur_aps; copy_alf_param(&g_alf_aps_temp, cur_aps); } else { continue; } kvz_alf_reconstruct_coeff(state, &g_alf_aps_temp, CHANNEL_TYPE_CHROMA, true, true); //m_CABACEstimator->getCtx() = AlfCtx(ctxStart); memcpy(&cabac_estimator, &ctx_start, sizeof(cabac_estimator)); for (int comp_id = 1; comp_id < MAX_NUM_COMPONENT; comp_id++) { g_alf_aps_temp.enabled_flag[comp_id] = true; //for (int ctb_idx = 0; ctb_idx < g_num_ctus_in_pic; ctb_idx++) { double dist_unfilter_ctu = g_ctb_distortion_unfilter[comp_id][ctu_idx]; //cost on g_ctu_enable_flag[comp_id][ctu_idx] = 1; //ctxTempStart = AlfCtx(m_CABACEstimator->getCtx()); memcpy(&ctx_temp_start, &cabac_estimator, sizeof(ctx_temp_start)); ctx_temp_start.only_count = 1; //rate //m_CABACEstimator->getCtx() = AlfCtx(ctxTempStart); memcpy(&cabac_estimator, &ctx_temp_start, sizeof(cabac_estimator)); //m_CABACEstimator->resetBits(); kvz_cabac_reset_bits(&cabac_estimator); //ctb flag code_alf_ctu_enable_flag(state, &cabac_estimator, ctu_idx, comp_id, &g_alf_aps_temp); double rate_on = (23 - cabac_estimator.bits_left) + (cabac_estimator.num_buffered_bytes << 3); //frac_bits_scale*(double)838/*m_CABACEstimator->getEstFracBits()*/; //#if JVET_O0090_ALF_CHROMA_FILTER_ALTERNATIVES_CTB //#if ENABLE_QPA const double ctu_lambda = lambda_chroma_weight > 0.0 ? 0/*cs.picture->m_uEnerHpCtu[ctbIdx]*/ / lambda_chroma_weight : g_lambda[comp_id]; /*#else const double ctu_lambda = m_lambda[compId]; #endif*/ double dist = MAX_DOUBLE; int num_alts = g_alf_aps_temp.num_alternatives_chroma; //ctxTempBest = AlfCtx(m_CABACEstimator->getCtx()); memcpy(&ctx_temp_best, &cabac_estimator, sizeof(ctx_temp_best)); ctx_temp_best.only_count = 1; double best_alt_rate = 0; double best_alt_cost = MAX_DOUBLE; int best_alt_idx = -1; //ctxTempAltStart = AlfCtx(ctxTempBest); memcpy(&ctx_temp_alt_start, &ctx_temp_best, sizeof(ctx_temp_alt_start)); for (int alt_idx = 0; alt_idx < num_alts; ++alt_idx) { if (alt_idx) { //m_CABACEstimator->getCtx() = AlfCtx(ctxTempAltStart); memcpy(&cabac_estimator, &ctx_temp_alt_start, sizeof(cabac_estimator)); } //m_CABACEstimator->resetBits(); kvz_cabac_reset_bits(&cabac_estimator); g_ctu_alternative[comp_id][ctu_idx] = alt_idx; //m_CABACEstimator->codeAlfCtuAlternative(cs, ctbIdx, compId, &m_alfParamTemp); code_alf_ctu_alternative_ctu(state, &cabac_estimator, ctu_idx, comp_id, &g_alf_aps_temp); double alt_rate = (23 - cabac_estimator.bits_left) + (cabac_estimator.num_buffered_bytes << 3); //frac_bits_scale * 0/*m_CABACEstimator->getEstFracBits()*/; double r_alt_cost = ctu_lambda * alt_rate; //distortion for (int i = 0; i < MAX_NUM_ALF_CHROMA_COEFF; i++) { g_filter_tmp[i] = g_chroma_coeff_final[alt_idx][i]; g_clip_tmp[i] = g_chroma_clipp_final[alt_idx][i]; } double alt_dist = calc_error_for_coeffs(&g_alf_covariance[comp_id][0][ctu_idx][0], g_clip_tmp, g_filter_tmp, MAX_NUM_ALF_CHROMA_COEFF, ALF_NUM_BITS); double alt_cost = alt_dist + r_alt_cost; if (alt_cost < best_alt_cost) { best_alt_cost = alt_cost; best_alt_idx = alt_idx; best_alt_rate = alt_rate; //ctxTempBest = AlfCtx(m_CABACEstimator->getCtx()); memcpy(&ctx_temp_best, &cabac_estimator, sizeof(ctx_temp_best)); ctx_temp_best.only_count = 1; dist = alt_dist; } } g_ctu_alternative[comp_id][ctu_idx] = best_alt_idx; rate_on += best_alt_rate; dist += dist_unfilter_ctu; //cost double cost_on = dist + ctu_lambda * rate_on; /*#else //distortion for (int i = 0; i < MAX_NUM_ALF_CHROMA_COEFF; i++) { g_filter_tmp[i] = g_chroma_coeff_final[i]; g_clip_tmp[i] = g_chroma_clipp_final[i]; } double dist = dist_unfilter_ctu + calc_error_for_coeffs(&g_alf_covariance[comp_id][0][ctb_idx][0], g_clip_tmp, g_filter_tmp, MAX_NUM_ALF_CHROMA_COEFF, ALF_NUM_BITS); double cost_on = dist + g_lambda[comp_id] * rate_on; //ctxTempBest = AlfCtx(m_CABACEstimator->getCtx()); memcpy(&ctx_temp_best, &cabac_estimator, sizeof(ctx_temp_best)); #endif*/ //cost off g_ctu_enable_flag[comp_id][ctu_idx] = 0; //rate //m_CABACEstimator->getCtx() = AlfCtx(ctxTempStart); memcpy(&cabac_estimator, &ctx_temp_start, sizeof(cabac_estimator)); //m_CABACEstimator->resetBits(); kvz_cabac_reset_bits(&cabac_estimator); code_alf_ctu_enable_flag(state, &cabac_estimator, ctu_idx, comp_id, &g_alf_aps_temp); //cost double cost_off = dist_unfilter_ctu + g_lambda[comp_id] * (23 - cabac_estimator.bits_left) + (cabac_estimator.num_buffered_bytes << 3); //frac_bits_scale*(double)838/*m_CABACEstimator->getEstFracBits()*/; if (cost_on < cost_off) { //m_CABACEstimator->getCtx() = AlfCtx(ctxTempBest); memcpy(&cabac_estimator, &ctx_temp_best, sizeof(cabac_estimator)); g_ctu_enable_flag[comp_id][ctu_idx] = 1; cur_cost += cost_on; } else { g_ctu_enable_flag[comp_id][ctu_idx] = 0; cur_cost += cost_off; } }//ctb_idx }//comp_id //chroma idc //setEnableFlag(m_alfSliceParamTemp, CHANNEL_TYPE_CHROMA, m_ctuEnableFlag); for (int comp_id = COMPONENT_Cb; comp_id <= COMPONENT_Cr; comp_id++) { g_alf_aps_temp.enabled_flag[comp_id] = false; //for (int i = 0; i < g_num_ctus_in_pic; i++) { if (g_ctu_enable_flag[comp_id][ctu_idx]) { g_alf_aps_temp.enabled_flag[comp_id] = true; break; } } } //#if JVET_O0090_ALF_CHROMA_FILTER_ALTERNATIVES_CTB /*#if !JVET_O0491_HLS_CLEANUP curCost += (lengthTruncatedUnary(alfChromaIdc, 3) - lengthTruncatedUnary(0, 3)) * m_lambda[CHANNEL_TYPE_CHROMA]; #endif #else cur_cost += length_truncated_unary(alf_chroma_idc, 3) * g_lambda[CHANNEL_TYPE_CHROMA]; #endif*/ if (cur_cost < cost_min) { cost_min = cur_cost; state->slice->tile_group_chroma_aps_id = cur_aps_id; state->slice->tile_group_alf_enabled_flag[COMPONENT_Cb] = g_alf_aps_temp.enabled_flag[COMPONENT_Cb]; state->slice->tile_group_alf_enabled_flag[COMPONENT_Cr] = g_alf_aps_temp.enabled_flag[COMPONENT_Cr]; //memcpy(g_ctu_enable_flag_tmp[COMPONENT_Cb], g_ctu_enable_flag[COMPONENT_Cb], sizeof(uint8_t) * g_num_ctus_in_pic); //memcpy(g_ctu_enable_flag_tmp[COMPONENT_Cr], g_ctu_enable_flag[COMPONENT_Cr], sizeof(uint8_t) * g_num_ctus_in_pic); copy_ctu_enable_flag(g_ctu_enable_flag_tmp, g_ctu_enable_flag, CHANNEL_TYPE_CHROMA, ctu_idx); //#if JVET_O0090_ALF_CHROMA_FILTER_ALTERNATIVES_CTB //for (int idx = 0; idx < g_num_ctus_in_pic; idx++) { g_ctu_alternative_tmp[COMPONENT_Cb][ctu_idx] = g_ctu_alternative[COMPONENT_Cb][ctu_idx]; g_ctu_alternative_tmp[COMPONENT_Cr][ctu_idx] = g_ctu_alternative[COMPONENT_Cr][ctu_idx]; } //#endif } } if (cost_off < cost_min) { state->slice->tile_group_alf_enabled_flag[COMPONENT_Cb] = false; state->slice->tile_group_alf_enabled_flag[COMPONENT_Cr] = false; //memset(g_ctu_enable_flag[COMPONENT_Cb], 0, sizeof(uint8_t) * g_num_ctus_in_pic); //memset(g_ctu_enable_flag[COMPONENT_Cr], 0, sizeof(uint8_t) * g_num_ctus_in_pic); set_ctu_enable_flag(g_ctu_enable_flag, CHANNEL_TYPE_CHROMA, ctu_idx, 0); } else { //memcpy(g_ctu_enable_flag[COMPONENT_Cb], g_ctu_enable_flag_tmp[COMPONENT_Cb], sizeof(uint8_t) * g_num_ctus_in_pic); //memcpy(g_ctu_enable_flag[COMPONENT_Cr], g_ctu_enable_flag_tmp[COMPONENT_Cr], sizeof(uint8_t) * g_num_ctus_in_pic); copy_ctu_enable_flag(g_ctu_enable_flag, g_ctu_enable_flag_tmp, CHANNEL_TYPE_CHROMA, ctu_idx); //#if JVET_O0090_ALF_CHROMA_FILTER_ALTERNATIVES_CTB //for (int idx = 0; idx < g_num_ctus_in_pic; idx++) { g_ctu_alternative[COMPONENT_Cb][ctu_idx] = g_ctu_alternative_tmp[COMPONENT_Cb][ctu_idx]; g_ctu_alternative[COMPONENT_Cr][ctu_idx] = g_ctu_alternative_tmp[COMPONENT_Cr][ctu_idx]; } //#endif if (state->slice->tile_group_chroma_aps_id == new_aps_id_chroma) //new filter { //APS* newAPS = m_apsMap->getPS(new_aps_id_chroma); alf_aps* new_aps = &state->slice->param_set_map[new_aps_id_chroma + NUM_APS_TYPE_LEN + T_ALF_APS].parameter_set; if (new_aps->aps_id < 0 || new_aps->aps_id >= ALF_CTB_MAX_NUM_APS) //new_aps == NULL { //newAPS = m_apsMap->allocatePS(new_aps_id); assert(new_aps_id + NUM_APS_TYPE_LEN + T_ALF_APS < MAX_NUM_APS); //Invalid PS id bool found = false; for (int i = 0; i < (sizeof(state->slice->param_set_map) / sizeof(state->slice->param_set_map[0])); i++) { if (state->slice->param_set_map[i].parameter_set.aps_id == new_aps_id + NUM_APS_TYPE_LEN + T_ALF_APS) { found = true; } } if (!found) { state->slice->param_set_map[new_aps_id + NUM_APS_TYPE_LEN + T_ALF_APS].b_changed = true; //state->slice->param_set_map[new_aps_id + NUM_APS_TYPE_LEN + T_ALF_APS].p_nalu_data = 0; //state->slice->param_set_map[new_aps_id + NUM_APS_TYPE_LEN + T_ALF_APS].parameter_set = malloc(sizeof(alf_aps)); state->slice->param_set_map[new_aps_id + NUM_APS_TYPE_LEN + T_ALF_APS].parameter_set.aps_id = new_aps_id + T_ALF_APS; } copy_alf_param(new_aps, &state->slice->param_set_map[new_aps_id + NUM_APS_TYPE_LEN + T_ALF_APS].parameter_set); new_aps->aps_id = new_aps_id; new_aps->aps_type = T_ALF_APS; reset_alf_param(new_aps); } new_aps->new_filter_flag[CHANNEL_TYPE_CHROMA] = true; if (!alf_aps_new_filters_best.new_filter_flag[CHANNEL_TYPE_LUMA]) { new_aps->new_filter_flag[CHANNEL_TYPE_LUMA] = false; } //#if JVET_O0090_ALF_CHROMA_FILTER_ALTERNATIVES_CTB new_aps->num_alternatives_chroma = aps->num_alternatives_chroma; for (int alt_idx = 0; alt_idx < MAX_NUM_ALF_ALTERNATIVES_CHROMA; ++alt_idx) new_aps->non_linear_flag[CHANNEL_TYPE_CHROMA][alt_idx] = aps->non_linear_flag[CHANNEL_TYPE_CHROMA][alt_idx]; /*#else new_aps->non_linear_flag[CHANNEL_TYPE_CHROMA] = aps->non_linear_flag[CHANNEL_TYPE_CHROMA]; #endif*/ new_aps->t_layer = state->slice->id; //#if JVET_O0090_ALF_CHROMA_FILTER_ALTERNATIVES_CTB for (int alt_idx = 0; alt_idx < MAX_NUM_ALF_ALTERNATIVES_CHROMA; ++alt_idx) { for (int i = 0; i < MAX_NUM_ALF_CHROMA_COEFF; i++) { new_aps->chroma_coeff[alt_idx][i] = aps->chroma_coeff[alt_idx][i]; new_aps->chroma_clipp[alt_idx][i] = aps->chroma_clipp[alt_idx][i]; } } /*#else for (int i = 0; i < MAX_NUM_ALF_CHROMA_COEFF; i++) { new_aps->chroma_coeff[i] = aps->chroma_coeff[i]; new_aps->chroma_clipp[i] = aps->chroma_clipp[i]; } #endif*/ state->slice->param_set_map[new_aps_id_chroma + NUM_APS_TYPE_LEN + T_ALF_APS].b_changed = true; g_aps_id_start = new_aps_id_chroma; } apss[state->slice->tile_group_chroma_aps_id].aps_id = state->slice->param_set_map[state->slice->tile_group_chroma_aps_id + NUM_APS_TYPE_LEN + T_ALF_APS].parameter_set.aps_id; apss[state->slice->tile_group_chroma_aps_id].aps_type = state->slice->param_set_map[state->slice->tile_group_chroma_aps_id + NUM_APS_TYPE_LEN + T_ALF_APS].parameter_set.aps_type; copy_alf_param(&apss[state->slice->tile_group_chroma_aps_id], &state->slice->param_set_map[state->slice->tile_group_chroma_aps_id + NUM_APS_TYPE_LEN + T_ALF_APS].parameter_set); } } void kvz_alf_reconstructor(encoder_state_t const *state, int ctu_idx) { enum kvz_chroma_format chroma_fmt = state->encoder_control->chroma_format; if (!state->slice->tile_group_alf_enabled_flag[COMPONENT_Y]) { return; } kvz_alf_reconstruct_coeff_aps(state, true, state->slice->tile_group_alf_enabled_flag[COMPONENT_Cb] || state->slice->tile_group_alf_enabled_flag[COMPONENT_Cr], false); int luma_height = state->tile->frame->height; int luma_width = state->tile->frame->width; const int max_cu_width = LCU_WIDTH; const int max_cu_height = LCU_WIDTH; //int ctu_idx = 0; bool clip_top = false, clip_bottom = false, clip_left = false, clip_right = false; int num_hor_vir_bndry = 0, num_ver_vir_bndry = 0; int hor_vir_bndry_pos[] = { 0, 0, 0 }; int ver_vir_bndry_pos[] = { 0, 0, 0 }; /*for (int y_pos = 0; y_pos < luma_height; y_pos += max_cu_height) { for (int x_pos = 0; x_pos < luma_width; x_pos += max_cu_width) {*/ //for (int ctu_idx = 0; ctu_idx < g_num_ctus_in_pic; ctu_idx++) { const lcu_order_element_t lcu = state->lcu_order[ctu_idx]; const int width = lcu.size.x; //(x_pos + max_cu_width > luma_width) ? (luma_width - x_pos) : max_cu_width; const int height = lcu.size.y; //(y_pos + max_cu_height > luma_height) ? (luma_height - y_pos) : max_cu_height; const int x_pos = lcu.position_px.x; const int y_pos = lcu.position_px.y; bool ctu_enable_flag = g_ctu_enable_flag[COMPONENT_Y][ctu_idx]; for (int comp_idx = 1; comp_idx < MAX_NUM_COMPONENT; comp_idx++) { ctu_enable_flag |= g_ctu_enable_flag[comp_idx][ctu_idx] > 0; } if (ctu_enable_flag && is_crossed_by_virtual_boundaries(x_pos, y_pos, width, height, &clip_top, &clip_bottom, &clip_left, &clip_right, &num_hor_vir_bndry, &num_ver_vir_bndry, hor_vir_bndry_pos, ver_vir_bndry_pos, state)) { int y_start = y_pos; for (int i = 0; i <= num_hor_vir_bndry; i++) { const int y_end = i == num_hor_vir_bndry ? y_pos + height : hor_vir_bndry_pos[i]; const int h = y_end - y_start; const bool clip_t = (i == 0 && clip_top) || (i > 0) || (y_start == 0); const bool clip_b = (i == num_hor_vir_bndry && clip_bottom) || (i < num_hor_vir_bndry) || (y_end == luma_height); int x_start = x_pos; for (int j = 0; j <= num_ver_vir_bndry; j++) { const int x_end = j == num_ver_vir_bndry ? x_pos + width : ver_vir_bndry_pos[j]; const int w = x_end - x_start; const bool clip_l = (j == 0 && clip_left) || (j > 0) || (x_start == 0); const bool clip_r = (j == num_ver_vir_bndry && clip_right) || (j < num_ver_vir_bndry) || (x_end == luma_width); const int w_buf = w + (clip_l ? 0 : MAX_ALF_PADDING_SIZE) + (clip_r ? 0 : MAX_ALF_PADDING_SIZE); const int h_buf = h + (clip_t ? 0 : MAX_ALF_PADDING_SIZE) + (clip_b ? 0 : MAX_ALF_PADDING_SIZE); //PelUnitBuf buf = m_tempBuf2.subBuf(UnitArea(cs.area.chromaFormat, Area(0, 0, w_buf, h_buf))); //buf.copyFrom(recExtBuf.subBuf(UnitArea(cs.area.chromaFormat, Area(x_start - (clip_l ? 0 : MAX_ALF_PADDING_SIZE), y_start - (clip_t ? 0 : MAX_ALF_PADDING_SIZE), w_buf, h_buf)))); //buf.extendBorderPel(MAX_ALF_PADDING_SIZE); //buf = buf.subBuf(UnitArea(cs.area.chromaFormat, Area(clip_l ? 0 : MAX_ALF_PADDING_SIZE, clip_t ? 0 : MAX_ALF_PADDING_SIZE, w, h))); if (g_ctu_enable_flag[COMPONENT_Y][ctu_idx]) { //const Area blkSrc(0, 0, w, h); //const Area blkDst(x_start, y_start, w, h); short filter_set_index = g_alf_ctb_filter_index[ctu_idx]; short *coeff; short *clip; if (filter_set_index >= ALF_NUM_FIXED_FILTER_SETS) { coeff = g_coeff_aps_luma[filter_set_index - ALF_NUM_FIXED_FILTER_SETS]; clip = g_clipp_aps_luma[filter_set_index - ALF_NUM_FIXED_FILTER_SETS]; } else { coeff = g_fixed_filter_set_coeff_dec[filter_set_index]; clip = g_clip_default; } kvz_alf_filter_block(state, state->tile->frame->rec->y, alf_tmp_y, state->tile->frame->rec->stride, state->tile->frame->rec->stride, coeff, clip, g_clp_rngs.comp[COMPONENT_Y], COMPONENT_Y, w, h, x_start, y_start, x_start, y_start, ((y_pos + max_cu_height >= luma_height) ? luma_height : g_alf_vb_luma_pos), g_alf_vb_luma_ctu_height); } for (int comp_idx = 1; comp_idx < MAX_NUM_COMPONENT; comp_idx++) { alf_component_id comp_id = comp_idx; if (g_ctu_enable_flag[comp_idx][ctu_idx]) { //const Area blkSrc(0, 0, w >> chromaScaleX, h >> chromaScaleY); //const Area blkDst(x_start >> chromaScaleX, y_start >> chromaScaleY, w >> chromaScaleX, h >> chromaScaleY); //#if JVET_O0090_ALF_CHROMA_FILTER_ALTERNATIVES_CTB const kvz_pixel *src_pixels = comp_id - 1 ? state->tile->frame->rec->v : state->tile->frame->rec->u; kvz_pixel *dst_pixels = comp_id - 1 ? alf_tmp_v : alf_tmp_u; const int src_stride = state->tile->frame->rec->stride >> 1; const int dst_stride = state->tile->frame->rec->stride >> 1; const int alt_num = g_ctu_alternative[comp_id][ctu_idx]; kvz_alf_filter_block(state, src_pixels, dst_pixels, src_stride, dst_stride, g_chroma_coeff_final[alt_num], g_chroma_clipp_final[alt_num], g_clp_rngs.comp[comp_idx], comp_id, w >> chroma_scale_x, h >> chroma_scale_y, x_start >> chroma_scale_x, y_start >> chroma_scale_y, x_start >> chroma_scale_x, y_start >> chroma_scale_y, ((y_pos + max_cu_height >= luma_height) ? luma_height : g_alf_vb_chma_pos), g_alf_vb_chma_ctu_height); /*#else kvz_alf_filter_block(state, g_chroma_coeff_final, g_chroma_clipp_final, g_clp_rngs.comp[comp_idx], comp_id, w >> chroma_scale_x, h >> chroma_scale_y, x_start >> chroma_scale_x, y_start >> chroma_scale_y, x_start >> chroma_scale_x, y_start >> chroma_scale_y, ((y_pos + max_cu_height >= luma_height) ? luma_height : g_alf_vb_chma_pos), g_alf_vb_chma_ctu_height); #endif*/ } } x_start = x_end; } y_start = y_end; } } else { if (g_ctu_enable_flag[COMPONENT_Y][ctu_idx]) { //Area blk(x_pos, y_pos, width, height); short filter_set_index = g_alf_ctb_filter_index[ctu_idx]; short *coeff; short *clip; if (filter_set_index >= ALF_NUM_FIXED_FILTER_SETS) { coeff = g_coeff_aps_luma[filter_set_index - ALF_NUM_FIXED_FILTER_SETS]; clip = g_clipp_aps_luma[filter_set_index - ALF_NUM_FIXED_FILTER_SETS]; } else { coeff = g_fixed_filter_set_coeff_dec[filter_set_index]; clip = g_clip_default; } kvz_alf_filter_block(state, state->tile->frame->rec->y, alf_tmp_y, state->tile->frame->rec->stride, state->tile->frame->rec->stride, coeff, clip, g_clp_rngs.comp[COMPONENT_Y], COMPONENT_Y, width, height, x_pos, y_pos, x_pos, y_pos, ((y_pos + max_cu_height >= luma_height) ? luma_height : g_alf_vb_luma_pos), g_alf_vb_luma_ctu_height); } /*else { int stride = state->tile->frame->rec->stride; for (int h = y_pos; h < y_pos + height; h++) { for (int w = x_pos; w < x_pos + width; w++) { alf_tmp_y[h * stride + w] = state->tile->frame->rec->y[h * stride + w]; } } }*/ for (int comp_idx = 1; comp_idx < MAX_NUM_COMPONENT; comp_idx++) { alf_component_id comp_id = comp_idx; if (g_ctu_enable_flag[comp_idx][ctu_idx]) { //Area blk(x_pos >> chroma_scale_x, y_pos >> chroma_scale_y, width >> chroma_scale_x, height >> chroma_scale_y); //m_filter5x5Blk(m_classifier, recYuv, tmpYuv, blk, comp_id, m_chromaCoeffFinal, clp_rngs.comp[comp_idx], cs); //#if JVET_O0090_ALF_CHROMA_FILTER_ALTERNATIVES_CTB const kvz_pixel *src_pixels = comp_id - 1 ? state->tile->frame->rec->v : state->tile->frame->rec->u; kvz_pixel *dst_pixels = comp_id - 1 ? alf_tmp_v : alf_tmp_u; const int src_stride = state->tile->frame->rec->stride >> 1; const int dst_stride = state->tile->frame->rec->stride >> 1; const int alt_num = g_ctu_alternative[comp_id][ctu_idx]; kvz_alf_filter_block(state, src_pixels, dst_pixels, src_stride, dst_stride, g_chroma_coeff_final[alt_num], g_chroma_clipp_final[alt_num], g_clp_rngs.comp[comp_idx], comp_idx, width >> chroma_scale_x, height >> chroma_scale_y, x_pos >> chroma_scale_x, y_pos >> chroma_scale_y, x_pos >> chroma_scale_x, y_pos >> chroma_scale_y, ((y_pos + max_cu_height >= luma_height) ? luma_height : g_alf_vb_chma_pos), g_alf_vb_chma_ctu_height); /*#else kvz_alf_filter_block(state, g_chroma_coeff_final, g_chroma_clipp_final, g_clp_rngs.comp[comp_idx], comp_idx, width >> chroma_scale_x, height >> chroma_scale_y, x_pos >> chroma_scale_x, y_pos >> chroma_scale_y, x_pos >> chroma_scale_x, y_pos >> chroma_scale_y, ((y_pos + max_cu_height >= luma_height) ? luma_height : g_alf_vb_chma_pos), g_alf_vb_chma_ctu_height); #endif*/ } /*else { int stride = state->tile->frame->rec->stride >> chroma_scale_y; int h_start = y_pos >> chroma_scale_y; int w_start = x_pos >> chroma_scale_x; int c_width = width >> chroma_scale_x; int c_height = height >> chroma_scale_y; if (comp_idx == COMPONENT_Cb) { for (int h = h_start; h < h_start + c_height; h++) { for (int w = w_start; w < w_start + c_width; w++) { alf_tmp_u[h * stride + w] = state->tile->frame->rec->u[h * stride + w]; } } } if (comp_idx == COMPONENT_Cr) { for (int h = h_start; h < h_start + c_height; h++) { for (int w = w_start; w < w_start + c_width; w++) { alf_tmp_v[h * stride + w] = state->tile->frame->rec->v[h * stride + w]; } } } }*/ } } } //ctu_idx++; //} //} } //---------------------------------------------------------------------- //-------------------------cabac writer functions------------------------ void kvz_cabac_reset_bits(cabac_data_t * const data) { data->low = 0; data->bits_left = 23; data->num_buffered_bytes = 0; data->buffered_byte = 0xff; } void code_alf_ctu_enable_flags_channel(encoder_state_t * const state, cabac_data_t * const cabac, channel_type channel, alf_aps *aps) { if (channel == CHANNEL_TYPE_LUMA) { if (aps->enabled_flag[COMPONENT_Y]) code_alf_ctu_enable_flags_component(state, cabac, COMPONENT_Y, aps); } else { if (aps->enabled_flag[COMPONENT_Cb]) code_alf_ctu_enable_flags_component(state, cabac, COMPONENT_Cb, aps); if (aps->enabled_flag[COMPONENT_Cr]) code_alf_ctu_enable_flags_component(state, cabac, COMPONENT_Cr, aps); } } void code_alf_ctu_enable_flags_component(encoder_state_t * const state, cabac_data_t * const cabac, alf_component_id component_id, alf_aps *aps) { for (int ctu_idx = 0; ctu_idx < g_num_ctus_in_pic; ctu_idx++) { code_alf_ctu_enable_flag(state, cabac, ctu_idx, component_id, aps); } } void code_alf_ctu_enable_flag(encoder_state_t * const state, cabac_data_t * const cabac, uint32_t ctu_rs_addr, alf_component_id component_id, alf_aps *aps) { const encoder_control_t * const encoder = state->encoder_control; const bool alf_component_enabled = (aps != NULL) ? aps->enabled_flag[component_id] : state->slice->tile_group_alf_enabled_flag[component_id]; if (encoder->cfg.alf_enable && alf_component_enabled) { int frame_width_in_ctus = state->tile->frame->width_in_lcu; //int ry = ctu_rs_addr / frame_width_in_ctus; //int rx = ctu_rs_addr - ry * frame_width_in_ctus; const uint32_t curSliceIdx = state->slice->id; //const Position pos(rx * cs.pcv->maxCUWidth, ry * cs.pcv->maxCUHeight); //const uint32_t curSliceIdx = cs.slice->getIndependentSliceIdx(); //const uint32_t curTileIdx = cs.picture->brickMap->getBrickIdxRsMap(pos); //bool leftAvail = cs.getCURestricted(pos.offset(-(int)pcv.maxCUWidth, 0), curSliceIdx, curTileIdx, CH_L) ? true : false; //bool aboveAvail = cs.getCURestricted(pos.offset(0, -(int)pcv.maxCUHeight), curSliceIdx, curTileIdx, CH_L) ? true : false; bool left_avail = state->lcu_order[ctu_rs_addr].left ? 1 : 0; bool above_avail = state->lcu_order[ctu_rs_addr].above ? 1 : 0; int left_ctu_addr = left_avail ? ctu_rs_addr - 1 : -1; int above_ctu_addr = above_avail ? ctu_rs_addr - frame_width_in_ctus : -1; uint8_t* ctb_alf_flag = g_ctu_enable_flag[component_id]; int ctx = 0; ctx += left_ctu_addr > -1 ? (ctb_alf_flag[left_ctu_addr] ? 1 : 0) : 0; ctx += above_ctu_addr > -1 ? (ctb_alf_flag[above_ctu_addr] ? 1 : 0) : 0; //m_BinEncoder.encodeBin(ctbAlfFlag[ctuRsAddr], Ctx::ctbAlfFlag(comp_idx * 3 + ctx)); cabac->cur_ctx = &(cabac->ctx.alf_ctb_flag_model[component_id * 3 + ctx]); CABAC_BIN(cabac, ctb_alf_flag[ctu_rs_addr], "alf_ctb_flag"); } } void code_alf_ctu_filter_index(encoder_state_t * const state, cabac_data_t * const cabac, uint32_t ctu_rs_addr, bool alf_enable_luma) { bitstream_t *stream = &state->stream; const encoder_control_t * const encoder = state->encoder_control; if (!encoder->cfg.alf_enable || !alf_enable_luma)//(!cs.sps->getALFEnabledFlag()) || (!alfEnableLuma)) { return; } if (!g_ctu_enable_flag[COMPONENT_Y][ctu_rs_addr]) { return; } const unsigned filter_set_idx = g_alf_ctb_filter_index[ctu_rs_addr]; unsigned num_aps = state->slice->tile_group_num_aps; unsigned num_available_filt_sets = num_aps + ALF_NUM_FIXED_FILTER_SETS; if (num_available_filt_sets > ALF_NUM_FIXED_FILTER_SETS) { int use_latest_filt = (filter_set_idx == ALF_NUM_FIXED_FILTER_SETS) ? 1 : 0; /*if (num_aps == 0) { use_latest_filt = 1; }*/ cabac->cur_ctx = &(cabac->ctx.alf_latest_filt); CABAC_BIN(cabac, use_latest_filt, "use_latest_filt"); if (!use_latest_filt) { if (num_aps == 1) { assert(filter_set_idx < ALF_NUM_FIXED_FILTER_SETS); //Fixed set numavail kvz_cabac_encode_trunc_bin(cabac, filter_set_idx, ALF_NUM_FIXED_FILTER_SETS); } else { int use_temporal_filt = (filter_set_idx > ALF_NUM_FIXED_FILTER_SETS) ? 1 : 0; cabac->cur_ctx = &(cabac->ctx.alf_temporal_filt); CABAC_BIN(cabac, use_temporal_filt, "use_temporal_filt"); if (use_temporal_filt) { assert((filter_set_idx - (ALF_NUM_FIXED_FILTER_SETS + 1)) < (num_aps - 1)); //Temporal non-latest set if (num_aps > 2) { kvz_cabac_encode_trunc_bin(cabac, filter_set_idx - (ALF_NUM_FIXED_FILTER_SETS + 1), num_available_filt_sets - (ALF_NUM_FIXED_FILTER_SETS + 1)); } } else { assert(filter_set_idx < ALF_NUM_FIXED_FILTER_SETS); //Fixed set larger than temporal kvz_cabac_encode_trunc_bin(cabac, filter_set_idx, ALF_NUM_FIXED_FILTER_SETS); } } } } else { assert(filter_set_idx < ALF_NUM_FIXED_FILTER_SETS); //Fixed set numavail < num_fixed kvz_cabac_encode_trunc_bin(cabac, filter_set_idx, ALF_NUM_FIXED_FILTER_SETS); } } //#if JVET_O0090_ALF_CHROMA_FILTER_ALTERNATIVES_CTB void code_alf_ctu_alternatives_channel(encoder_state_t * const state, cabac_data_t * const cabac, channel_type channel, alf_aps* aps, int ctu_idx) { if (channel == CHANNEL_TYPE_CHROMA) { if (aps->enabled_flag[COMPONENT_Cb]) code_alf_ctu_alternatives_component(state, cabac, COMPONENT_Cb, aps, ctu_idx); if (aps->enabled_flag[COMPONENT_Cr]) code_alf_ctu_alternatives_component(state, cabac, COMPONENT_Cr, aps, ctu_idx); } } void code_alf_ctu_alternatives_component(encoder_state_t * const state, cabac_data_t * const cabac, alf_component_id comp_id, alf_aps* aps, int ctu_idx) { if (comp_id == COMPONENT_Y) return; uint32_t num_ctus = g_num_ctus_in_pic; uint8_t* ctb_alf_flag = g_ctu_enable_flag[comp_id]; //for (int ctu_idx = 0; ctu_idx < num_ctus; ctu_idx++) { if (ctb_alf_flag[ctu_idx]) { code_alf_ctu_alternative_ctu(state, cabac, ctu_idx, comp_id, aps); } } } void code_alf_ctu_alternative_ctu(encoder_state_t * const state, cabac_data_t * const cabac, uint32_t ctu_rs_addr, const alf_component_id comp_idx, const alf_aps* aps) { if (comp_idx == COMPONENT_Y) return; int aps_idx = aps ? 0 : state->slice->tile_group_chroma_aps_id; const alf_aps* alf_param_ref = aps ? (aps) : &state->slice->apss[aps_idx]; if (aps || (state->encoder_control->cfg.alf_enable && state->slice->tile_group_alf_enabled_flag[comp_idx])) { uint8_t* ctb_alf_flag = g_ctu_enable_flag[comp_idx]; if (ctb_alf_flag[ctu_rs_addr]) { const int num_alts = alf_param_ref->num_alternatives_chroma; uint8_t* ctb_alf_alternative = g_ctu_alternative[comp_idx]; unsigned num_ones = ctb_alf_alternative[ctu_rs_addr]; assert(ctb_alf_alternative[ctu_rs_addr] < num_alts); for (int i = 0; i < num_ones; ++i) { cabac->cur_ctx = &cabac->ctx.alf_ctb_alternatives[comp_idx - 1]; CABAC_BIN(cabac, 1, "alf_ctb_alternatives"); } if (num_ones < num_alts - 1) { cabac->cur_ctx = &cabac->ctx.alf_ctb_alternatives[comp_idx - 1]; CABAC_BIN(cabac, 0, "alf_ctb_alternatives"); } } } } //#endif void kvz_encode_alf_bits(encoder_state_t * const state, const int ctu_idx) { for (int comp_idx = 0; comp_idx < MAX_NUM_COMPONENT; comp_idx++) { bool is_luma = comp_idx == COMPONENT_Y ? true : false; if (!is_luma) { state->slice->tile_group_alf_enabled_flag[comp_idx] = 0; } code_alf_ctu_enable_flag(state, &state->cabac, ctu_idx, comp_idx, NULL); if (is_luma) { if (g_ctu_enable_flag[comp_idx][ctu_idx]) { /*if (state->slice->tile_group_num_aps < 1) { state->slice->tile_group_num_aps = 1; code_alf_ctu_filter_index(state, &state->cabac, ctu_idx, state->slice->tile_group_alf_enabled_flag[COMPONENT_Y]); state->slice->tile_group_num_aps = 0; } else { code_alf_ctu_filter_index(state, &state->cabac, ctu_idx, state->slice->tile_group_alf_enabled_flag[COMPONENT_Y]); }*/ int num_aps = state->slice->tile_group_num_aps; state->slice->tile_group_num_aps = 2; code_alf_ctu_filter_index(state, &state->cabac, ctu_idx, state->slice->tile_group_alf_enabled_flag[COMPONENT_Y]); state->slice->tile_group_num_aps = num_aps; } } if (!is_luma) { uint8_t* ctb_alf_flag = state->slice->tile_group_alf_enabled_flag[comp_idx] ? g_ctu_enable_flag[comp_idx] : NULL; if (ctb_alf_flag && ctb_alf_flag[ctu_idx]) { code_alf_ctu_alternative_ctu(state, &state->cabac, ctu_idx, comp_idx, NULL); } } } } void encoder_state_write_adaptation_parameter_set(encoder_state_t * const state, alf_aps *aps) { #ifdef KVZ_DEBUG printf("=========== Adaptation Parameter Set ===========\n"); #endif bitstream_t * const stream = &state->stream; //WRITE_CODE(pcAPS->getAPSId(), 5, "adaptation_parameter_set_id"); WRITE_U(stream, aps->aps_id, 5, "adaptation_parameter_set_id"); //WRITE_CODE(pcAPS->getAPSType(), 3, "aps_params_type"); WRITE_U(stream, aps->aps_type, 3, "aps_params_type"); if (aps->aps_type == T_ALF_APS) { code_alf_aps(state, aps); } /*else if (aps->aps_type == T_LMCS_APS) { codeLmcsAps(pcAPS); }*/ //WRITE_FLAG(0, "aps_extension_flag"); //Implementation when this flag is equal to 1 should be added when it is needed. Currently in the spec we don't have case when this flag is equal to 1 WRITE_U(stream, 0, 1, "aps_extension_flag"); //Implementation when this flag is equal to 1 should be added when it is needed. Currently in the spec we don't have case when this flag is equal to 1 kvz_bitstream_add_rbsp_trailing_bits(stream); } void code_alf_aps(encoder_state_t * const state, alf_aps* aps) { bitstream_t * const stream = &state->stream; //WRITE_FLAG(param.newFilterFlag[CHANNEL_TYPE_LUMA], "alf_luma_new_filter"); WRITE_U(stream, aps->new_filter_flag[CHANNEL_TYPE_LUMA], 1, "alf_luma_new_filter"); //WRITE_FLAG(param.newFilterFlag[CHANNEL_TYPE_CHROMA], "alf_chroma_new_filter"); WRITE_U(stream, aps->new_filter_flag[CHANNEL_TYPE_CHROMA], 1, "alf_chroma_new_filter") if (aps->new_filter_flag[CHANNEL_TYPE_LUMA]) { //#if JVET_O0090_ALF_CHROMA_FILTER_ALTERNATIVES_CTB //WRITE_FLAG(param.nonLinearFlag[CHANNEL_TYPE_LUMA][0], "alf_luma_clip"); WRITE_U(stream, aps->non_linear_flag[CHANNEL_TYPE_LUMA][0], 1, "alf_luma_clip"); /*#else WRITE_FLAG(param.nonLinearFlag[CHANNEL_TYPE_LUMA], "alf_luma_clip"); #endif*/ //#if JVET_O0491_HLS_CLEANUP //WRITE_UVLC(param.numLumaFilters - 1, "alf_luma_num_filters_signalled_minus1"); WRITE_UE(stream, aps->num_luma_filters - 1, "alf_luma_num_filters_signalled_minus1"); /*#else xWriteTruncBinCode(param.numLumaFilters - 1, MAX_NUM_ALF_CLASSES); //number_of_filters_minus1 #endif*/ if (aps->num_luma_filters > 1) { //#if JVET_O0491_HLS_CLEANUP //const int length = ceilLog2(param.numLumaFilters); const int length = kvz_math_ceil_log2(aps->num_luma_filters); //#endif for (int i = 0; i < MAX_NUM_ALF_CLASSES; i++) { //#if JVET_O0491_HLS_CLEANUP //WRITE_CODE(param.filterCoeffDeltaIdx[i], length, "alf_luma_coeff_delta_idx"); WRITE_U(stream, aps->filter_coeff_delta_idx[i], length, "alf_luma_coeff_delta_idx"); /*#else xWriteTruncBinCode((uint32_t)param.filterCoeffDeltaIdx[i], param.numLumaFilters); //filter_coeff_delta[i] #endif*/ } } /*#if !JVET_O0669_REMOVE_ALF_COEFF_PRED WRITE_FLAG(param.fixedFilterSetIndex > 0 ? 1 : 0, "fixed_filter_set_flag"); if (param.fixedFilterSetIndex > 0) { xWriteTruncBinCode(param.fixedFilterSetIndex - 1, NUM_FIXED_FILTER_SETS); WRITE_FLAG(param.fixedFilterPattern, "fixed_filter_flag_pattern"); for (int classIdx = 0; classIdx < MAX_NUM_ALF_CLASSES; classIdx++) { if (param.fixedFilterPattern > 0) { WRITE_FLAG(param.fixedFilterIdx[classIdx], "fixed_filter_flag"); } else { CHECK(param.fixedFilterIdx[classIdx] != 1, "Disabled fixed filter"); } } } #endif*/ //#if JVET_O0090_ALF_CHROMA_FILTER_ALTERNATIVES_CTB alf_filter(state, aps, false, 0); /*#else alfFilter(param, false); #endif*/ } if (aps->new_filter_flag[CHANNEL_TYPE_CHROMA]) { //#if JVET_O0090_ALF_CHROMA_FILTER_ALTERNATIVES_CTB if (MAX_NUM_ALF_ALTERNATIVES_CHROMA > 1) { //WRITE_UVLC(param.numAlternativesChroma - 1, "alf_chroma_num_alts_minus1"); WRITE_UE(stream, aps->num_alternatives_chroma - 1, "alf_chroma_num_alts_minus1"); } for (int alt_idx = 0; alt_idx < aps->num_alternatives_chroma; ++alt_idx) { //WRITE_FLAG(param.nonLinearFlag[CHANNEL_TYPE_CHROMA][alt_idx], "alf_nonlinear_enable_flag_chroma"); WRITE_U(stream, aps->non_linear_flag[CHANNEL_TYPE_CHROMA][alt_idx], 1, "alf_nonlinear_enable_flag_chroma"); alf_filter(state, aps, true, alt_idx); } /*#else WRITE_FLAG(param.nonLinearFlag[CHANNEL_TYPE_CHROMA], "alf_chroma_clip"); alfFilter(param, true); #endif*/ } } //#if JVET_O0090_ALF_CHROMA_FILTER_ALTERNATIVES_CTB void alf_filter(encoder_state_t * const state, alf_aps* aps, const bool is_chroma, const int alt_idx) /*#else void HLSWriter::alfFilter(const AlfParam& alfParam, const bool is_chroma) #endif*/ { bitstream_t * const stream = &state->stream; if (!is_chroma) { //WRITE_FLAG(alfParam.alfLumaCoeffDeltaFlag, "alf_luma_coeff_delta_flag"); WRITE_U(stream, aps->alf_luma_coeff_delta_flag, 1, "alf_luma_coeff_delta_flag"); /*#if !JVET_O0669_REMOVE_ALF_COEFF_PRED if (!alfParam.alfLumaCoeffDeltaFlag) { if (alfParam.numLumaFilters > 1) { WRITE_FLAG(alfParam.alfLumaCoeffDeltaPredictionFlag, "alf_luma_coeff_delta_prediction_flag"); } } #endif*/ } //AlfFilterShape alfShape(is_chroma ? 5 : 7); const int num_coeff = is_chroma ? 7 : 13; /*#if !JVET_O0216_ALF_COEFF_EG3 || !JVET_O0064_SIMP_ALF_CLIP_CODING static int bitsCoeffScan[EncAdaptiveLoopFilter::m_MAX_SCAN_VAL][EncAdaptiveLoopFilter::m_MAX_EXP_GOLOMB]; memset(bitsCoeffScan, 0, sizeof(bitsCoeffScan)); const int maxGolombIdx = AdaptiveLoopFilter::getMaxGolombIdx(alfShape.filterType); #endif*/ //#if JVET_O0090_ALF_CHROMA_FILTER_ALTERNATIVES_CTB const short* coeff = is_chroma ? aps->chroma_coeff[alt_idx] : aps->luma_coeff; const short* clipp = is_chroma ? aps->chroma_clipp[alt_idx] : aps->luma_clipp; /*#else const short* coeff = is_chroma ? alfParam.chromaCoeff : alfParam.lumaCoeff; const short* clipp = is_chroma ? alfParam.chromaClipp : alfParam.lumaClipp; #endif*/ const int num_filters = is_chroma ? 1 : aps->num_luma_filters; // vlc for all /*#if !JVET_O0216_ALF_COEFF_EG3 for (int ind = 0; ind < num_filters; ++ind) { if (is_chroma || !alfParam.alfLumaCoeffDeltaFlag || alfParam.alfLumaCoeffFlag[ind]) { for (int i = 0; i < alfShape.numCoeff - 1; i++) { int coeffVal = abs(coeff[ind * MAX_NUM_ALF_LUMA_COEFF + i]); for (int k = 1; k < 15; k++) { bitsCoeffScan[alfShape.golombIdx[i]][k] += EncAdaptiveLoopFilter::lengthGolomb(coeffVal, k); } } } } #endif*/ /*#if !JVET_O0216_ALF_COEFF_EG3 || !JVET_O0064_SIMP_ALF_CLIP_CODING static int kMinTab[MAX_NUM_ALF_COEFF]; #endif*/ /*#if !JVET_O0216_ALF_COEFF_EG3 int kMin = EncAdaptiveLoopFilter::getGolombKMin(alfShape, num_filters, kMinTab, bitsCoeffScan); // Golomb parameters WRITE_UVLC(kMin - 1, is_chroma ? "alf_chroma_min_eg_order_minus1" : "alf_luma_min_eg_order_minus1"); for (int idx = 0; idx < maxGolombIdx; idx++) { bool golombOrderIncreaseFlag = (kMinTab[idx] != kMin) ? true : false; CHECK(!(kMinTab[idx] <= kMin + 1), "ALF Golomb parameter not consistent"); WRITE_FLAG(golombOrderIncreaseFlag, is_chroma ? "alf_chroma_eg_order_increase_flag" : "alf_luma_eg_order_increase_flag"); kMin = kMinTab[idx]; } #endif*/ if (!is_chroma) { if (aps->alf_luma_coeff_delta_flag) { for (int ind = 0; ind < num_filters; ++ind) { //WRITE_FLAG(alfParam.alfLumaCoeffFlag[ind], "alf_luma_coeff_flag[i]"); WRITE_U(stream, aps->alf_luma_coeff_flag[ind], 1, "alf_luma_coeff_flag[i]"); } } } // Filter coefficients for (int ind = 0; ind < num_filters; ++ind) { if (!is_chroma && !aps->alf_luma_coeff_flag[ind] && aps->alf_luma_coeff_delta_flag) { continue; } for (int i = 0; i < num_coeff - 1; i++) { //#if JVET_O0216_ALF_COEFF_EG3 alf_golomb_encode(state, coeff[ind * MAX_NUM_ALF_LUMA_COEFF + i], 3, true); // alf_coeff_chroma[i], alf_coeff_luma_delta[i][j] /*#else alfGolombEncode(coeff[ind* MAX_NUM_ALF_LUMA_COEFF + i], kMinTab[alfShape.golombIdx[i]]); // alf_coeff_chroma[i], alf_coeff_luma_delta[i][j] #endif*/ } } // Clipping values coding //#if JVET_O0090_ALF_CHROMA_FILTER_ALTERNATIVES_CTB if (aps->non_linear_flag[is_chroma][alt_idx]) /*#else if (alfParam.nonLinearFlag[is_chroma]) #endif*/ { //#if JVET_O0064_SIMP_ALF_CLIP_CODING for (int ind = 0; ind < num_filters; ++ind) { for (int i = 0; i < num_coeff - 1; i++) { //WRITE_CODE(clipp[ind* MAX_NUM_ALF_LUMA_COEFF + i], 2, "alf_clipping_index"); WRITE_U(stream, clipp[ind * MAX_NUM_ALF_LUMA_COEFF + i], 2, "alf_clipping_index"); } } /*#else memset(bitsCoeffScan, 0, sizeof(bitsCoeffScan)); short recCoeff[MAX_NUM_ALF_CLASSES * MAX_NUM_ALF_LUMA_COEFF]; if (is_chroma) { memcpy(recCoeff, coeff, sizeof(short) * MAX_NUM_ALF_CHROMA_COEFF); } else { memcpy(recCoeff, coeff, sizeof(short) * num_filters * MAX_NUM_ALF_LUMA_COEFF); #if !JVET_O0669_REMOVE_ALF_COEFF_PRED if (alfParam.alfLumaCoeffDeltaPredictionFlag) { for (int i = 1; i < num_filters; i++) { for (int j = 0; j < alfShape.numCoeff - 1; j++) { recCoeff[i * MAX_NUM_ALF_LUMA_COEFF + j] += recCoeff[(i - 1) * MAX_NUM_ALF_LUMA_COEFF + j]; } } } #endif } // vlc for all for (int ind = 0; ind < num_filters; ++ind) { if (is_chroma || !alfParam.alfLumaCoeffDeltaFlag || alfParam.alfLumaCoeffFlag[ind]) { for (int i = 0; i < alfShape.numCoeff - 1; i++) { if (!abs(recCoeff[ind * MAX_NUM_ALF_LUMA_COEFF + i])) continue; int coeffVal = abs(clipp[ind * MAX_NUM_ALF_LUMA_COEFF + i]); for (int k = 1; k < 15; k++) { bitsCoeffScan[alfShape.golombIdx[i]][k] += EncAdaptiveLoopFilter::lengthGolomb(coeffVal, k, false); } } } } #if JVET_O0216_ALF_COEFF_EG3 int kMin = EncAdaptiveLoopFilter::getGolombKMin(alfShape, num_filters, kMinTab, bitsCoeffScan); #else kMin = EncAdaptiveLoopFilter::getGolombKMin(alfShape, num_filters, kMinTab, bitsCoeffScan); #endif // Golomb parameters WRITE_UVLC(kMin - 1, "clip_min_golomb_order"); for (int idx = 0; idx < maxGolombIdx; idx++) { bool golombOrderIncreaseFlag = (kMinTab[idx] != kMin) ? true : false; CHECK(!(kMinTab[idx] <= kMin + 1), "ALF Golomb parameter not consistent"); WRITE_FLAG(golombOrderIncreaseFlag, "clip_golomb_order_increase_flag"); kMin = kMinTab[idx]; } // Filter coefficients for (int ind = 0; ind < num_filters; ++ind) { if (!is_chroma && !alfParam.alfLumaCoeffFlag[ind] && alfParam.alfLumaCoeffDeltaFlag) { continue; } for (int i = 0; i < alfShape.numCoeff - 1; i++) { if (!abs(recCoeff[ind * MAX_NUM_ALF_LUMA_COEFF + i])) continue; alfGolombEncode(clipp[ind* MAX_NUM_ALF_LUMA_COEFF + i], kMinTab[alfShape.golombIdx[i]], false); // alf_coeff_chroma[i], alf_coeff_luma_delta[i][j] } } #endif*/ } } void alf_golomb_encode(encoder_state_t * const state, int coeff, int k, const bool signed_coeff) { bitstream_t * const stream = &state->stream; unsigned int symbol = abs(coeff); while (symbol >= (unsigned int)(1 << k)) { symbol -= 1 << k; k++; //WRITE_FLAG(0, "alf_coeff_abs_prefix"); WRITE_U(stream, 0, 1, "alf_coeff_abs_prefix"); } //WRITE_FLAG(1, "alf_coeff_abs_prefix"); WRITE_U(stream, 1, 1, "alf_coeff_abs_prefix"); if (k > 0) { //WRITE_CODE(symbol, k, "alf_coeff_abs_suffix"); WRITE_U(stream, symbol, k, "alf_coeff_abs_suffix"); } if (signed_coeff && coeff != 0) { //WRITE_FLAG((coeff < 0) ? 1 : 0, "alf_coeff_sign"); WRITE_U(stream, (coeff < 0) ? 1 : 0, 1, "alf_coeff_sign"); } } //--------------------------------------------------------------------- //-------------------------CTU functions-------------------------------- void kvz_alf_process(encoder_state_t const *state, const lcu_order_element_t const *lcu) { //if (!cs.slice->getTileGroupAlfEnabledFlag(COMPONENT_Y) && !cs.slice->getTileGroupAlfEnabledFlag(COMPONENT_Cb) && !cs.slice->getTileGroupAlfEnabledFlag(COMPONENT_Cr)) if (!state->slice->tile_group_alf_enabled_flag[COMPONENT_Y] && !state->slice->tile_group_alf_enabled_flag[COMPONENT_Cb] && !state->slice->tile_group_alf_enabled_flag[COMPONENT_Cr]) { return; } enum kvz_chroma_format chroma_fmt = state->encoder_control->chroma_format; bool alf_ctb_flag = &state->cabac.ctx.alf_ctb_flag_model[COMPONENT_Y]; // set clipping range // done in INIT //m_clp_rngs = cs.slice->getClpRngs(); // set CTU enable flags for (int comp_idx = 0; comp_idx < MAX_NUM_COMPONENT; comp_idx++) { for (int ctu_idx = 0; ctu_idx < g_num_ctus_in_pic; ctu_idx++) { g_ctu_enable_flag[comp_idx][ctu_idx] = g_alf_ctu_enable_flag[comp_idx][ctu_idx]; //#if JVET_O0090_ALF_CHROMA_FILTER_ALTERNATIVES_CTB g_ctu_alternative[comp_idx][ctu_idx] = g_alf_ctu_alternative[comp_idx][ctu_idx]; //#endif } } kvz_alf_reconstruct_coeff_aps(state, true, state->slice->tile_group_alf_enabled_flag[COMPONENT_Cb] || state->slice->tile_group_alf_enabled_flag[COMPONENT_Cr], false); //PelUnitBuf recYuv = cs.getRecoBuf(); kvz_picture *rec_yuv = state->tile->frame->rec; //m_tempBuf.copyFrom(recYuv); //PelUnitBuf tmpYuv = m_tempBuf.getBuf(cs.area); //tmpYuv.extendBorderPel(MAX_ALF_FILTER_LENGTH >> 1); int luma_height = state->tile->frame->height; int luma_width = state->tile->frame->width; int ctu_idx = 0; int max_cu_width = LCU_WIDTH; int max_cu_height = LCU_WIDTH; bool clip_top = false, clip_bottom = false, clip_left = false, clip_right = false; int num_hor_vir_bndry = 0, num_ver_vir_bndry = 0; int hor_vir_bndry_pos[] = { 0, 0, 0 }; int ver_vir_bndry_pos[] = { 0, 0, 0 }; for (int y_pos = 0; y_pos < luma_height; y_pos += max_cu_width) { for (int x_pos = 0; x_pos < luma_width; x_pos += max_cu_width) { const int width = (x_pos + max_cu_width > luma_width) ? (luma_width - x_pos) : max_cu_width; const int height = (y_pos + max_cu_width > luma_height) ? (luma_height - y_pos) : max_cu_width; bool ctuEnableFlag = g_ctu_enable_flag[COMPONENT_Y][ctu_idx]; for (int comp_idx = 1; comp_idx < MAX_NUM_COMPONENT; comp_idx++) { ctuEnableFlag |= g_ctu_enable_flag[comp_idx][ctu_idx] > 0; } if(ctuEnableFlag && is_crossed_by_virtual_boundaries(x_pos, y_pos, width, height, &clip_top, &clip_bottom, &clip_left, &clip_right, &num_hor_vir_bndry, &num_ver_vir_bndry, hor_vir_bndry_pos, ver_vir_bndry_pos, state)) { int y_start = y_pos; for (int i = 0; i <= num_hor_vir_bndry; i++) { const int y_end = i == num_hor_vir_bndry ? y_pos + height : hor_vir_bndry_pos[i]; const int h = y_end - y_start; const bool clipT = (i == 0 && clip_top) || (i > 0) || (y_start == 0); const bool clipB = (i == num_hor_vir_bndry && clip_bottom) || (i < num_hor_vir_bndry) || (y_end == luma_height); int x_start = x_pos; for (int j = 0; j <= num_ver_vir_bndry; j++) { const int x_end = j == num_ver_vir_bndry ? x_pos + width : ver_vir_bndry_pos[j]; const int w = x_end - x_start; const bool clipL = (j == 0 && clip_left) || (j > 0) || (x_start == 0); const bool clipR = (j == num_ver_vir_bndry && clip_right) || (j < num_ver_vir_bndry) || (x_end == luma_width); const int wBuf = w + (clipL ? 0 : MAX_ALF_PADDING_SIZE) + (clipR ? 0 : MAX_ALF_PADDING_SIZE); const int hBuf = h + (clipT ? 0 : MAX_ALF_PADDING_SIZE) + (clipB ? 0 : MAX_ALF_PADDING_SIZE); /* PelUnitBuf buf = m_tempBuf2.subBuf(UnitArea(cs.area.chromaFormat, Area(0, 0, w_buf, h_buf))); buf.copyFrom(tmpYuv.subBuf(UnitArea(cs.area.chromaFormat, Area(x_start - (clip_l ? 0 : MAX_ALF_PADDING_SIZE), y_start - (clip_t ? 0 : MAX_ALF_PADDING_SIZE), w_buf, h_buf)))); buf.extendBorderPel(MAX_ALF_PADDING_SIZE); buf = buf.subBuf(UnitArea(cs.area.chromaFormat, Area(clip_l ? 0 : MAX_ALF_PADDING_SIZE, clip_t ? 0 : MAX_ALF_PADDING_SIZE, w, h))); */ if (g_ctu_enable_flag[COMPONENT_Y][ctu_idx]) { //const Area blkSrc(0, 0, w, h); //const Area blkDst(x_start, y_start, w, h); //deriveClassification(m_classifier, buf.get(COMPONENT_Y), blkDst, blkSrc); kvz_alf_derive_classification(state, w, h, x_start, y_start, x_start, y_start); //const Area blkPCM(x_start, y_start, w, h); //#if !JVET_O0525_REMOVE_PCM //resetPCMBlkClassInfo(cs, m_classifier, buf.get(COMPONENT_Y), blkPCM); //kvz_alf_reset_pcm_blk_class_info(state, lcu, w, h, x_start, y_start); short filter_set_index = g_alf_ctb_filter_index[ctu_idx]; short *coeff; short *clip; if (filter_set_index >= ALF_NUM_FIXED_FILTER_SETS) { coeff = g_coeff_aps_luma[filter_set_index - ALF_NUM_FIXED_FILTER_SETS]; clip = g_clipp_aps_luma[filter_set_index - ALF_NUM_FIXED_FILTER_SETS]; } else { coeff = g_fixed_filter_set_coeff_dec[filter_set_index]; clip = g_clip_default; } kvz_alf_filter_block(state, state->tile->frame->rec->y, alf_tmp_y, state->tile->frame->rec->stride, state->tile->frame->rec->stride, coeff, clip, g_clp_rngs.comp[COMPONENT_Y], COMPONENT_Y, w, h, x_start, y_start, x_start, y_start, ((y_pos + max_cu_height >= luma_height) ? luma_height : g_alf_vb_luma_pos), g_alf_vb_luma_ctu_height); } for (int comp_idx = 1; comp_idx < MAX_NUM_COMPONENT; comp_idx++) { alf_component_id comp_id = comp_idx; if (g_ctu_enable_flag[comp_idx][ctu_idx]) { //const Area blkSrc(0, 0, w >> chromaScaleX, h >> chromaScaleY); //const Area blkDst(x_start >> chromaScaleX, y_start >> chromaScaleY, w >> chromaScaleX, h >> chromaScaleY); //#if JVET_O0090_ALF_CHROMA_FILTER_ALTERNATIVES_CTB const kvz_pixel *src_pixels = comp_id - 1 ? state->tile->frame->rec->v : state->tile->frame->rec->u; kvz_pixel *dst_pixels = comp_id - 1 ? alf_tmp_v : alf_tmp_u; const int src_stride = state->tile->frame->rec->stride >> 1; const int dst_stride = state->tile->frame->rec->stride >> 1; uint8_t alt_num = g_ctu_alternative[comp_idx][ctu_idx]; kvz_alf_filter_block(state, src_pixels, dst_pixels, src_stride, dst_stride, g_chroma_coeff_final[alt_num], g_chroma_clipp_final[alt_num], g_clp_rngs.comp[comp_idx], comp_id, w >> chroma_scale_x, h >> chroma_scale_y, x_start >> chroma_scale_x, y_start >> chroma_scale_y, x_start >> chroma_scale_x, y_start >> chroma_scale_y, ((y_pos + max_cu_height >= luma_height) ? luma_height : g_alf_vb_chma_pos), g_alf_vb_chma_ctu_height); /*#else kvz_alf_filter_block(state, g_chroma_coeff_final, g_chroma_clipp_final, g_clp_rngs.comp[comp_idx], comp_id, w >> chroma_scale_x, h >> chroma_scale_y, x_start >> chroma_scale_x, y_start >> chroma_scale_y, x_start >> chroma_scale_x, y_start >> chroma_scale_y, ((y_pos + max_cu_height >= luma_height) ? luma_height : g_alf_vb_chma_pos), g_alf_vb_chma_ctu_height); #endif*/ } } x_start = x_end; } y_start = y_end; } } else { //const UnitArea area(cs.area.chromaFormat, Area(x_pos, y_pos, width, height)); if (g_ctu_enable_flag[COMPONENT_Y][ctu_idx]) { //Area blk(x_pos, y_pos, width, height); //deriveClassification(m_classifier, tmpYuv.get(COMPONENT_Y), blk, blk); kvz_alf_derive_classification(state, width, height, x_pos, y_pos, x_pos, y_pos); //Area blkPCM(x_pos, y_pos, width, height); //#if !JVET_O0525_REMOVE_PCM //resetPCMBlkClassInfo(cs, m_classifier, tmpYuv.get(COMPONENT_Y), blkPCM); //kvz_alf_reset_pcm_blk_class_info(state, lcu, width, height, x_pos, y_pos); short filter_set_index = g_alf_ctb_filter_index[ctu_idx]; short *coeff; short *clip; if (filter_set_index >= ALF_NUM_FIXED_FILTER_SETS) { coeff = g_coeff_aps_luma[filter_set_index - ALF_NUM_FIXED_FILTER_SETS]; clip = g_clipp_aps_luma[filter_set_index - ALF_NUM_FIXED_FILTER_SETS]; } else { coeff = g_fixed_filter_set_coeff_dec[filter_set_index]; clip = g_clip_default; } kvz_alf_filter_block(state, state->tile->frame->rec->y, alf_tmp_y, state->tile->frame->rec->stride, state->tile->frame->rec->stride, coeff, clip, g_clp_rngs.comp[COMPONENT_Y], COMPONENT_Y, width, height, x_pos, y_pos, x_pos, y_pos, ((y_pos + max_cu_height >= luma_height) ? luma_height : g_alf_vb_luma_pos), g_alf_vb_luma_ctu_height); } for (int comp_idx = 1; comp_idx < MAX_NUM_COMPONENT; comp_idx++) { alf_component_id comp_id = comp_idx; if (g_ctu_enable_flag[comp_idx][ctu_idx]) { //Area blk(x_pos >> chroma_scale_x, y_pos >> chroma_scale_y, width >> chroma_scale_x, height >> chroma_scale_y); //m_filter5x5Blk(m_classifier, recYuv, tmpYuv, blk, comp_id, m_chromaCoeffFinal, clp_rngs.comp[comp_idx], cs); //#if JVET_O0090_ALF_CHROMA_FILTER_ALTERNATIVES_CTB const kvz_pixel *src_pixels = comp_id - 1 ? state->tile->frame->rec->v : state->tile->frame->rec->u; kvz_pixel *dst_pixels = comp_id - 1 ? alf_tmp_v : alf_tmp_u; const int src_stride = state->tile->frame->rec->stride >> 1; const int dst_stride = state->tile->frame->rec->stride >> 1; uint8_t alt_num = g_ctu_alternative[comp_idx][ctu_idx]; kvz_alf_filter_block(state, src_pixels, dst_pixels, src_stride, dst_stride, g_chroma_coeff_final[alt_num], g_chroma_clipp_final[alt_num], g_clp_rngs.comp[comp_idx], comp_idx, width >> chroma_scale_x, height >> chroma_scale_y, x_pos >> chroma_scale_x, y_pos >> chroma_scale_y, x_pos >> chroma_scale_x, y_pos >> chroma_scale_y, ((y_pos + max_cu_height >= luma_height) ? luma_height : g_alf_vb_chma_pos), g_alf_vb_chma_ctu_height); /*#else kvz_alf_filter_block(state, g_chroma_coeff_final, g_chroma_clipp_final, g_clp_rngs.comp[comp_idx], comp_idx, width >> chroma_scale_x, height >> chroma_scale_y, x_pos >> chroma_scale_x, y_pos >> chroma_scale_y, x_pos >> chroma_scale_x, y_pos >> chroma_scale_y, ((y_pos + max_cu_height >= luma_height) ? luma_height : g_alf_vb_chma_pos), g_alf_vb_chma_ctu_height); #endif*/ } } } ctu_idx++; } } } void kvz_alf_reconstruct_coeff_aps(encoder_state_t *const state, bool luma, bool chroma, bool is_rdo) { //luma alf_aps* apss = state->slice->apss; //AlfSliceParam alfSliceParamTmp; alf_aps alf_param_tmp; //APS* cur_aps; alf_aps* cur_aps; if (luma) { for (int i = 0; i < state->slice->tile_group_num_aps /* 1, cs.slice->getTileGroupNumAps()*/; i++) { int aps_idx = state->slice->tile_group_luma_aps_id[i]; cur_aps = &apss[aps_idx]; assert(cur_aps != NULL); // "invalid APS" alf_param_tmp = *cur_aps; kvz_alf_reconstruct_coeff(state, &alf_param_tmp, CHANNEL_TYPE_LUMA, is_rdo, true); memcpy(g_coeff_aps_luma[i], g_coeff_final, sizeof(g_coeff_final)); memcpy(g_clipp_aps_luma[i], g_clipp_final, sizeof(g_clipp_final)); } } //chroma if (chroma) { int aps_idx_chroma = state->slice->tile_group_chroma_aps_id; cur_aps = &apss[aps_idx_chroma]; //#if JVET_O0090_ALF_CHROMA_FILTER_ALTERNATIVES_CTB /* g_alf_aps_chroma turha välikäsi (?) copy_alf_param(g_alf_aps_chroma, cur_aps); copy_alf_param(alf_param_tmp, g_alf_aps_chroma);*/ copy_alf_param(&alf_param_tmp, cur_aps); /*#else copy_alf_param(alf_param_tmp, cur_aps); #endif*/ kvz_alf_reconstruct_coeff(state, &alf_param_tmp, CHANNEL_TYPE_CHROMA, is_rdo, true); } } //void reconstructCoeff(AlfSliceParam& alfSliceParam, ChannelType channel, const bool isRdo, const bool isRedo) void kvz_alf_reconstruct_coeff(encoder_state_t *const state, alf_aps *aps, channel_type channel, const bool is_rdo, const bool is_redo) { int factor = is_rdo ? 0 : (1 << (ALF_NUM_BITS - 1)); bool is_luma = channel == CHANNEL_TYPE_LUMA ? 1 : 0; alf_filter_type filter_type = is_luma ? ALF_FILTER_7X7 : ALF_FILTER_5X5; int num_classes = is_luma ? MAX_NUM_ALF_CLASSES : 1; int num_coeff = filter_type == ALF_FILTER_5X5 ? 7 : 13; int num_coeff_minus1 = num_coeff - 1; /*#if !JVET_O0090_ALF_CHROMA_FILTER_ALTERNATIVES_CTB int num_filters = is_luma ? num_luma_filters : 1; short* coeff = is_luma ? luma_coeff : chroma_coeff; short* clipp = is_luma ? luma_clipp : chroma_clipp; #endif*/ //#if JVET_O0090_ALF_CHROMA_FILTER_ALTERNATIVES_CTB const int num_alts = is_luma ? 1 : aps->num_alternatives_chroma; for (int alt_idx = 0; alt_idx < num_alts; ++alt_idx) { int num_filters = is_luma ? aps->num_luma_filters : 1; short* coeff = is_luma ? aps->luma_coeff : aps->chroma_coeff[alt_idx]; short* clipp = is_luma ? aps->luma_clipp : aps->chroma_clipp[alt_idx]; /*#if !JVET_O0669_REMOVE_ALF_COEFF_PRED if (alfParam.alfLumaCoeffDeltaPredictionFlag && isLuma(channel)) { for (int i = 1; i < num_filters; i++) { for (int j = 0; j < numCoeffMinus1; j++) { coeff[i * MAX_NUM_ALF_LUMA_COEFF + j] += coeff[(i - 1) * MAX_NUM_ALF_LUMA_COEFF + j]; } } } #endif*/ for (int filter_idx = 0; filter_idx < num_filters; filter_idx++) { coeff[filter_idx * MAX_NUM_ALF_LUMA_COEFF + num_coeff_minus1] = factor; } if (!is_luma) { for (int coeff_idx = 0; coeff_idx < num_coeff_minus1; ++coeff_idx) { g_chroma_coeff_final[alt_idx][coeff_idx] = coeff[coeff_idx]; int clip_idx = aps->non_linear_flag[channel][alt_idx] ? clipp[coeff_idx] : 0; g_chroma_clipp_final[alt_idx][coeff_idx] = is_rdo ? clip_idx : g_alf_clipping_values[channel][clip_idx]; } g_chroma_coeff_final[alt_idx][num_coeff_minus1] = factor; g_chroma_clipp_final[alt_idx][num_coeff_minus1] = is_rdo ? 0 : g_alf_clipping_values[channel][0]; continue; } for (int class_idx = 0; class_idx < num_classes; class_idx++) { int filterIdx = aps->filter_coeff_delta_idx[class_idx]; /*#if !JVET_O0669_REMOVE_ALF_COEFF_PRED int fixedFilterIdx = alfParam.fixedFilterSetIndex; if (fixedFilterIdx > 0 && alfParam.fixedFilterIdx[class_idx] > 0) { fixedFilterIdx = m_classToFilterMapping[fixedFilterIdx - 1][class_idx]; } else { fixedFilterIdx = -1; } #endif*/ for (int coeff_idx = 0; coeff_idx < num_coeff_minus1; ++coeff_idx) { g_coeff_final[class_idx * MAX_NUM_ALF_LUMA_COEFF + coeff_idx] = coeff[filterIdx * MAX_NUM_ALF_LUMA_COEFF + coeff_idx]; /*#if !JVET_O0669_REMOVE_ALF_COEFF_PRED //fixed filter if (fixedFilterIdx >= 0) { m_coeffFinal[class_idx * MAX_NUM_ALF_LUMA_COEFF + coeff_idx] += m_fixedFilterSetCoeff[fixedFilterIdx][coeff_idx]; } #endif*/ } g_coeff_final[class_idx* MAX_NUM_ALF_LUMA_COEFF + num_coeff_minus1] = factor; g_clipp_final[class_idx* MAX_NUM_ALF_LUMA_COEFF + num_coeff_minus1] = is_rdo ? 0 : g_alf_clipping_values[channel][0]; for (int coeff_idx = 0; coeff_idx < num_coeff_minus1; ++coeff_idx) { int clipIdx = aps->non_linear_flag[channel][alt_idx] ? (clipp + filterIdx * MAX_NUM_ALF_LUMA_COEFF)[coeff_idx] : 0; (g_clipp_final + class_idx * MAX_NUM_ALF_LUMA_COEFF)[coeff_idx] = is_rdo ? clipIdx : g_alf_clipping_values[channel][clipIdx]; } g_clipp_final[class_idx* MAX_NUM_ALF_LUMA_COEFF + num_coeff_minus1] = is_rdo ? 0 : g_alf_clipping_values[channel][0]; } } /*#if !JVET_O0669_REMOVE_ALF_COEFF_PRED if (is_chroma(channel)) return; if (isRedo && alfParam.alfLumaCoeffDeltaPredictionFlag) { int num_filters = alfParam.numLumaFilters; short* coeff = alfParam.lumaCoeff; for (int i = num_filters - 1; i > 0; i--) { for (int j = 0; j < numCoeffMinus1; j++) { coeff[i * MAX_NUM_ALF_LUMA_COEFF + j] = coeff[i * MAX_NUM_ALF_LUMA_COEFF + j] - coeff[(i - 1) * MAX_NUM_ALF_LUMA_COEFF + j]; } } } #endif*/ /*#else /*#if !JVET_O0669_REMOVE_ALF_COEFF_PRED if (*alf_luma_coeff_delta_prediction_flag && is_luma) { for (int i = 1; i < num_filters; i++) { for (int j = 0; j < num_coeff_minus1; j++) { coeff[i * MAX_NUM_ALF_LUMA_COEFF + j] += coeff[(i - 1) * MAX_NUM_ALF_LUMA_COEFF + j]; } } }*//* for (int filter_idx = 0; filter_idx < num_filters; filter_idx++) { coeff[filter_idx* MAX_NUM_ALF_LUMA_COEFF + num_coeff_minus1] = factor; } if ( !is_luma ) { for (int coeff_idx = 0; coeff_idx < num_coeff_minus1; ++coeff_idx) { g_chroma_coeff_final[coeff_idx] = chroma_coeff[coeff_idx]; g_chroma_coeff_final[coeff_idx] = chroma_coeff[coeff_idx]; int clip_idx = aps->non_linear_flag[channel] ? clipp[coeff_idx] : 0; g_chroma_clipp_final[coeff_idx] = is_rdo ? clip_idx : g_alf_clipping_values[channel][clip_idx]; } g_chroma_coeff_final[num_coeff_minus1] = factor; g_chroma_clipp_final[num_coeff_minus1] = is_rdo ? 0 : g_alf_clipping_values[channel][0]; return; } for (int class_idx = 0; class_idx < num_classes; class_idx++) { int filter_idx = filter_coeff_delta_idx[class_idx]; /*#if !JVET_O0669_REMOVE_ALF_COEFF_PRED int fixed_filter_idx = *fixed_filter_set_index; //13 if (fixed_filter_idx > 0 && aps->fixed_filter_idx[class_idx] > 0) { fixed_filter_idx = g_class_to_filter_mapping[fixed_filter_idx - 1][class_idx]; } else { fixed_filter_idx = -1; }*//* for (int coeff_idx = 0; coeff_idx < num_coeff_minus1; ++coeff_idx) { g_coeff_final[class_idx * MAX_NUM_ALF_LUMA_COEFF + coeff_idx] = coeff[filter_idx * MAX_NUM_ALF_LUMA_COEFF + coeff_idx]; /*#if !JVET_O0669_REMOVE_ALF_COEFF_PRED //fixed filter if (fixed_filter_idx >= 0) { g_coeff_final[class_idx * MAX_NUM_ALF_LUMA_COEFF + coeff_idx] += g_fixed_filter_set_coeff[fixed_filter_idx][coeff_idx]; }*//* } g_coeff_final[class_idx * MAX_NUM_ALF_LUMA_COEFF + num_coeff_minus1] = factor; g_clipp_final[class_idx* MAX_NUM_ALF_LUMA_COEFF + num_coeff_minus1] = is_rdo ? 0 : g_alf_clipping_values[channel][0]; for (int coeff_idx = 0; coeff_idx < num_coeff_minus1; ++coeff_idx) { int clip_idx = aps->non_linear_flag[channel] ? (clipp + filter_idx * MAX_NUM_ALF_LUMA_COEFF)[coeff_idx] : 0; g_clipp_final[class_idx * MAX_NUM_ALF_LUMA_COEFF + coeff_idx] = is_rdo ? clip_idx : g_alf_clipping_values[channel][clip_idx]; } } /*#if !JVET_O0669_REMOVE_ALF_COEFF_PRED if (is_redo && state->cabac.ctx.alf_luma_coeff_delta_prediction_flag.state[0]) { for (int i = num_filters - 1; i > 0; i--) { for (int j = 0; j < num_coeff_minus1; j++) { coeff[i * MAX_NUM_ALF_LUMA_COEFF + j] = coeff[i * MAX_NUM_ALF_LUMA_COEFF + j] - coeff[(i - 1) * MAX_NUM_ALF_LUMA_COEFF + j]; } } }*/ } void kvz_alf_create(encoder_state_t const *state, const lcu_order_element_t const *lcu) { if (g_created) { return; } const int pic_width = state->tile->frame->width; const int pic_height = state->tile->frame->height; const int max_cu_width = LCU_WIDTH; //128 const int max_cu_height = LCU_WIDTH; //128 enum kvz_chroma_format chroma_fmt = state->encoder_control->chroma_format; const int num_ctus_in_width = (pic_width / max_cu_width) + ((pic_width % max_cu_width) ? 1 : 0); const int num_ctus_in_height = (pic_height / max_cu_height) + ((pic_height % max_cu_height) ? 1 : 0); g_num_ctus_in_pic = num_ctus_in_width * num_ctus_in_height; g_alf_vb_luma_pos = max_cu_height - ALF_VB_POS_ABOVE_CTUROW_LUMA; g_alf_vb_chma_pos = (max_cu_height >> ((chroma_fmt == KVZ_CSP_420) ? 1 : 0)) - ALF_VB_POS_ABOVE_CTUROW_CHMA; g_alf_vb_luma_ctu_height = max_cu_height; g_alf_vb_chma_ctu_height = (max_cu_height >> ((chroma_fmt == KVZ_CSP_420) ? 1 : 0)); assert(g_alf_num_clipping_values[CHANNEL_TYPE_LUMA] > 0); //"g_alf_num_clipping_values[CHANNEL_TYPE_LUMA] must be at least one" for (int i = 0; i < g_alf_num_clipping_values[CHANNEL_TYPE_LUMA]; ++i) { g_alf_clipping_values[CHANNEL_TYPE_LUMA][i] = (short)round(pow(2., g_input_bit_depth[CHANNEL_TYPE_LUMA] * (g_alf_num_clipping_values[CHANNEL_TYPE_LUMA] - i) / g_alf_num_clipping_values[CHANNEL_TYPE_LUMA])); } assert(g_alf_num_clipping_values[CHANNEL_TYPE_CHROMA] > 0); //"g_alf_num_clipping_values[CHANNEL_TYPE_CHROMA] must be at least one" g_alf_clipping_values[CHANNEL_TYPE_CHROMA][0] = 1 << g_input_bit_depth[CHANNEL_TYPE_CHROMA]; for (int i = 1; i < g_alf_num_clipping_values[CHANNEL_TYPE_CHROMA]; ++i) { g_alf_clipping_values[CHANNEL_TYPE_CHROMA][i] = (short)round(pow(2., g_input_bit_depth[CHANNEL_TYPE_CHROMA] - 8 + 8. * (g_alf_num_clipping_values[CHANNEL_TYPE_CHROMA] - i - 1) / (g_alf_num_clipping_values[CHANNEL_TYPE_CHROMA] - 1))); } // Classification g_classifier = malloc(pic_height * sizeof(**g_classifier)); g_classifier[0] = malloc(pic_height * pic_width * sizeof(*g_classifier)); for (int i = 1; i < pic_height; i++) { g_classifier[i] = g_classifier[0] + i * pic_width; } for (int filter_set_index = 0; filter_set_index < ALF_NUM_FIXED_FILTER_SETS; filter_set_index++) { for (int class_idx = 0; class_idx < MAX_NUM_ALF_CLASSES; class_idx++) { int fixed_filter_idx = g_class_to_filter_mapping[filter_set_index][class_idx]; for (int i = 0; i < MAX_NUM_ALF_LUMA_COEFF - 1; i++) { g_fixed_filter_set_coeff_dec[filter_set_index][class_idx * MAX_NUM_ALF_LUMA_COEFF + i] = g_fixed_filter_set_coeff[fixed_filter_idx][i]; } g_fixed_filter_set_coeff_dec[filter_set_index][class_idx * MAX_NUM_ALF_LUMA_COEFF + MAX_NUM_ALF_LUMA_COEFF - 1] = (1 << (ALF_NUM_BITS - 1)); } } for (int i = 0; i < MAX_NUM_ALF_LUMA_COEFF * MAX_NUM_ALF_CLASSES; i++) { g_clip_default[i] = g_alf_clipping_values[CHANNEL_TYPE_LUMA][0]; } g_created = true; } void kvz_alf_destroy(videoframe_t * const frame) { if (!g_created) { return; } if (g_classifier) { FREE_POINTER(g_classifier[0]); FREE_POINTER(g_classifier); } g_created = false; } void kvz_alf_derive_classification(encoder_state_t *const state, const int width, const int height, int x_pos, int y_pos, const int blk_dst_x, const int blk_dst_y)//, //alf_classifier** g_classifier) { int32_t pic_height = state->tile->frame->rec->height; int max_height = y_pos + height; int max_width = x_pos + width; adjust_pixels(state->tile->frame->rec->y, x_pos, max_width, y_pos, max_height, state->tile->frame->rec->stride, max_width, max_height); adjust_pixels_chroma(state->tile->frame->rec->u, x_pos >> chroma_scale_x, max_width >> chroma_scale_x, y_pos >> chroma_scale_y, max_height >> chroma_scale_y, state->tile->frame->rec->stride >> chroma_scale_x, max_width >> chroma_scale_x, max_height >> chroma_scale_y); adjust_pixels_chroma(state->tile->frame->rec->v, x_pos >> chroma_scale_x, max_width >> chroma_scale_x, y_pos >> chroma_scale_y, max_height >> chroma_scale_y, state->tile->frame->rec->stride >> chroma_scale_x, max_width >> chroma_scale_x, max_height >> chroma_scale_y); for (int i = y_pos; i < max_height; i += CLASSIFICATION_BLK_SIZE) { int n_height = MIN(i + CLASSIFICATION_BLK_SIZE, max_height) - i; for (int j = x_pos; j < max_width; j += CLASSIFICATION_BLK_SIZE) { int n_width = MIN(j + CLASSIFICATION_BLK_SIZE, max_width) - j; kvz_alf_derive_classification_blk(state, g_input_bit_depth[CHANNEL_TYPE_LUMA] + 4, n_height, n_width, j, i, j - x_pos + blk_dst_x, i - y_pos + blk_dst_y, g_alf_vb_luma_ctu_height, ((i - y_pos + blk_dst_y + n_height >= pic_height) ? pic_height : g_alf_vb_luma_pos)); } } } /*kvz_alf_reset_pcm_blk_class_info //Turha jos PCM on pois päältä. void kvz_alf_reset_pcm_blk_class_info(encoder_state_t *const state, const lcu_order_element_t *const lcu, const int width, const int height, int x_pos, int y_pos) { if (!ENABLE_PCM) //!cs.sps->getPCMFilterDisableFlag() { return; } //alf_classifier **g_classifier = state->tile->frame->alf_info->g_classifier; int max_height = y_pos + height; int max_width = x_pos + width; const int cls_size_y = 4; const int cls_size_x = 4; int class_idx = ALF_UNUSED_CLASS_IDX; int transpose_idx = ALF_UNUSED_TRANSPOSE_IDX; for (int i = y_pos; i < max_height; i += CLASSIFICATION_BLK_SIZE) { int n_height = MIN(i + CLASSIFICATION_BLK_SIZE, max_height) - i; for (int j = x_pos; j < max_width; j += CLASSIFICATION_BLK_SIZE) { int n_width = MIN(j + CLASSIFICATION_BLK_SIZE, max_width) - j; int pos_x = j; int pos_y = i; for (int subi = 0; subi < n_height; subi += cls_size_y) { for (int subj = 0; subj < n_width; subj += cls_size_x) { int y_offset = subi + pos_y; int x_offset = subj + pos_x; //Position pos(xOffset, yOffset); //const CodingUnit* cu = cs.getCU(pos, CH_L); if (1) //cu->ipcm ///ipcm_flag = 0 { alf_classifier *cl0 = g_classifier[y_offset] + x_offset; alf_classifier *cl1 = g_classifier[y_offset + 1] + x_offset; alf_classifier *cl2 = g_classifier[y_offset + 2] + x_offset; alf_classifier *cl3 = g_classifier[y_offset + 3] + x_offset; cl0[0].class_idx = cl0[1].class_idx = cl0[2].class_idx = cl0[3].class_idx = cl1[0].class_idx = cl1[1].class_idx = cl1[2].class_idx = cl1[3].class_idx = cl2[0].class_idx = cl2[1].class_idx = cl2[2].class_idx = cl2[3].class_idx = cl3[0].class_idx = cl3[1].class_idx = cl3[2].class_idx = cl3[3].class_idx = class_idx; cl0[0].transpose_idx = cl0[1].transpose_idx = cl0[2].transpose_idx = cl0[3].transpose_idx = cl1[0].transpose_idx = cl1[1].transpose_idx = cl1[2].transpose_idx = cl1[3].transpose_idx = cl2[0].transpose_idx = cl2[1].transpose_idx = cl2[2].transpose_idx = cl2[3].transpose_idx = cl3[0].transpose_idx = cl3[1].transpose_idx = cl3[2].transpose_idx = cl3[3].transpose_idx = transpose_idx; } } } } } }*/ void kvz_alf_derive_classification_blk(encoder_state_t * const state, const int shift, const int n_height, const int n_width, const int blk_pos_x, const int blk_pos_y, const int blk_dst_x, const int blk_dst_y, const int vb_ctu_height, int vb_pos) { videoframe_t* const frame = state->tile->frame; //int ***g_laplacian = state->tile->frame->alf_info->g_laplacian; //alf_classifier **g_classifier = state->tile->frame->alf_info->g_classifier; //CHECK((vb_ctu_height & (vb_ctu_height - 1)) != 0, "vb_ctu_height must be a power of 2"); static const int th[16] = { 0, 1, 2, 2, 2, 2, 2, 3, 3, 3, 3, 3, 3, 3, 3, 4 }; const int stride = frame->rec->stride; kvz_pixel *src = state->tile->frame->rec->y; const int max_activity = 15; int fl = 2; int fl_p1 = fl + 1; int fl2 = 2 * fl; int main_direction, secondary_direction, dir_temp_hv, dir_temp_d; int pix_y; int height = n_height + fl2; int width = n_width + fl2; int pos_x = blk_pos_x; int pos_y = blk_pos_y; int start_height = pos_y - fl_p1; for (int i = 0; i < height; i += 2) { int yoffset = (i + 1 + start_height) * stride - fl_p1; const kvz_pixel *src0 = &src[yoffset - stride]; const kvz_pixel *src1 = &src[yoffset]; const kvz_pixel *src2 = &src[yoffset + stride]; const kvz_pixel *src3 = &src[yoffset + stride * 2]; const int y = blk_dst_y - 2 + i; if (y > 0 && (y & (vb_ctu_height - 1)) == vb_pos - 2) { src3 = &src[yoffset + stride]; } else if (y > 0 && (y & (vb_ctu_height - 1)) == vb_pos) { src0 = &src[yoffset]; } int *p_y_ver = g_laplacian[ALF_VER][i]; int *p_y_hor = g_laplacian[ALF_HOR][i]; int *p_y_dig0 = g_laplacian[ALF_DIAG0][i]; int *p_y_dig1 = g_laplacian[ALF_DIAG1][i]; for (int j = 0; j < width; j += 2) { pix_y = j + 1 + pos_x; const kvz_pixel *p_y = src1 + pix_y; const kvz_pixel *p_y_down = src0 + pix_y; const kvz_pixel *p_y_up = src2 + pix_y; const kvz_pixel *p_y_up2 = src3 + pix_y; const int16_t y0 = p_y[0] << 1; const int16_t y_up1 = p_y_up[1] << 1; p_y_ver[j] = abs(y0 - p_y_down[0] - p_y_up[0]) + abs(y_up1 - p_y[1] - p_y_up2[1]); p_y_hor[j] = abs(y0 - p_y[1] - p_y[-1]) + abs(y_up1 - p_y_up[2] - p_y_up[0]); p_y_dig0[j] = abs(y0 - p_y_down[-1] - p_y_up[1]) + abs(y_up1 - p_y[0] - p_y_up2[2]); p_y_dig1[j] = abs(y0 - p_y_up[-1] - p_y_down[1]) + abs(y_up1 - p_y_up2[0] - p_y[2]); if (j > 4 && (j - 6) % 4 == 0) { int j_m6 = j - 6; int j_m4 = j - 4; int j_m2 = j - 2; p_y_ver[j_m6] += p_y_ver[j_m4] + p_y_ver[j_m2] + p_y_ver[j]; p_y_hor[j_m6] += p_y_hor[j_m4] + p_y_hor[j_m2] + p_y_hor[j]; p_y_dig0[j_m6] += p_y_dig0[j_m4] + p_y_dig0[j_m2] + p_y_dig0[j]; p_y_dig1[j_m6] += p_y_dig1[j_m4] + p_y_dig1[j_m2] + p_y_dig1[j]; } } } // classification block size const int cls_size_y = 4; const int cls_size_x = 4; //for (int i = 0; i < blk.height; i += cls_size_y) for (int i = 0; i < n_height; i += cls_size_y) { int* p_y_ver = g_laplacian[ALF_VER][i]; int* p_y_ver2 = g_laplacian[ALF_VER][i + 2]; int* p_y_ver4 = g_laplacian[ALF_VER][i + 4]; int* p_y_ver6 = g_laplacian[ALF_VER][i + 6]; int* p_y_hor = g_laplacian[ALF_HOR][i]; int* p_y_hor2 = g_laplacian[ALF_HOR][i + 2]; int* p_y_hor4 = g_laplacian[ALF_HOR][i + 4]; int* p_y_hor6 = g_laplacian[ALF_HOR][i + 6]; int* p_y_dig0 = g_laplacian[ALF_DIAG0][i]; int* p_y_dig02 = g_laplacian[ALF_DIAG0][i + 2]; int* p_y_dig04 = g_laplacian[ALF_DIAG0][i + 4]; int* p_y_dig06 = g_laplacian[ALF_DIAG0][i + 6]; int* p_y_dig1 = g_laplacian[ALF_DIAG1][i]; int* p_y_dig12 = g_laplacian[ALF_DIAG1][i + 2]; int* p_y_dig14 = g_laplacian[ALF_DIAG1][i + 4]; int* p_y_dig16 = g_laplacian[ALF_DIAG1][i + 6]; //for (int j = 0; j < blk.width; j += cls_size_x) for (int j = 0; j < n_width; j += cls_size_x) { int sum_v = 0; int sum_h = 0; int sum_d0 = 0; int sum_d1 = 0; if (((i + blk_dst_y) % vb_ctu_height) == (vb_pos - 4)) { sum_v = p_y_ver[j] + p_y_ver2[j] + p_y_ver4[j]; sum_h = p_y_hor[j] + p_y_hor2[j] + p_y_hor4[j]; sum_d0 = p_y_dig0[j] + p_y_dig02[j] + p_y_dig04[j]; sum_d1 = p_y_dig1[j] + p_y_dig12[j] + p_y_dig14[j]; } else if (((i + blk_dst_y) % vb_ctu_height) == vb_pos) { sum_v = p_y_ver2[j] + p_y_ver4[j] + p_y_ver6[j]; sum_h = p_y_hor2[j] + p_y_hor4[j] + p_y_hor6[j]; sum_d0 = p_y_dig02[j] + p_y_dig04[j] + p_y_dig06[j]; sum_d1 = p_y_dig12[j] + p_y_dig14[j] + p_y_dig16[j]; } else { sum_v = p_y_ver[j] + p_y_ver2[j] + p_y_ver4[j] + p_y_ver6[j]; sum_h = p_y_hor[j] + p_y_hor2[j] + p_y_hor4[j] + p_y_hor6[j]; sum_d0 = p_y_dig0[j] + p_y_dig02[j] + p_y_dig04[j] + p_y_dig06[j]; sum_d1 = p_y_dig1[j] + p_y_dig12[j] + p_y_dig14[j] + p_y_dig16[j]; } int temp_act = sum_v + sum_h; int activity = 0; const int y = (i + blk_dst_y) & (vb_ctu_height - 1); if (y == vb_pos - 4 || y == vb_pos) { activity = alf_clip3(0, max_activity, (temp_act * 96) >> shift); } else { activity = alf_clip3(0, max_activity, (temp_act * 64) >> shift); } int class_idx = th[activity]; int hv1, hv0, d1, d0, hvd1, hvd0; if (sum_v > sum_h) { hv1 = sum_v; hv0 = sum_h; dir_temp_hv = 1; } else { hv1 = sum_h; hv0 = sum_v; dir_temp_hv = 3; } if (sum_d0 > sum_d1) { d1 = sum_d0; d0 = sum_d1; dir_temp_d = 0; } else { d1 = sum_d1; d0 = sum_d0; dir_temp_d = 2; } if((uint32_t)d1 * (uint32_t)hv0 > (uint32_t)hv1 * (uint32_t)d0) { hvd1 = d1; hvd0 = d0; main_direction = dir_temp_d; secondary_direction = dir_temp_hv; } else { hvd1 = hv1; hvd0 = hv0; main_direction = dir_temp_hv; secondary_direction = dir_temp_d; } int direction_strength = 0; if (hvd1 > 2 * hvd0) { direction_strength = 1; } if (hvd1 * 2 > 9 * hvd0) { direction_strength = 2; } if (direction_strength) { class_idx += (((main_direction & 0x1) << 1) + direction_strength) * 5; } static const int transpose_table[8] = { 0, 1, 0, 2, 2, 3, 1, 3 }; int transpose_idx = transpose_table[main_direction * 2 + (secondary_direction >> 1)]; int y_offset = i + blk_dst_y; int x_offset = j + blk_dst_x; alf_classifier *cl0 = g_classifier[y_offset] + x_offset; alf_classifier *cl1 = g_classifier[y_offset + 1] + x_offset; alf_classifier *cl2 = g_classifier[y_offset + 2] + x_offset; alf_classifier *cl3 = g_classifier[y_offset + 3] + x_offset; cl0[0].class_idx = cl0[1].class_idx = cl0[2].class_idx = cl0[3].class_idx = cl1[0].class_idx = cl1[1].class_idx = cl1[2].class_idx = cl1[3].class_idx = cl2[0].class_idx = cl2[1].class_idx = cl2[2].class_idx = cl2[3].class_idx = cl3[0].class_idx = cl3[1].class_idx = cl3[2].class_idx = cl3[3].class_idx = class_idx; cl0[0].transpose_idx = cl0[1].transpose_idx = cl0[2].transpose_idx = cl0[3].transpose_idx = cl1[0].transpose_idx = cl1[1].transpose_idx = cl1[2].transpose_idx = cl1[3].transpose_idx = cl2[0].transpose_idx = cl2[1].transpose_idx = cl2[2].transpose_idx = cl2[3].transpose_idx = cl3[0].transpose_idx = cl3[1].transpose_idx = cl3[2].transpose_idx = cl3[3].transpose_idx = transpose_idx; } } } void kvz_alf_filter_block(encoder_state_t * const state, const kvz_pixel *src_pixels, kvz_pixel *dst_pixels, const int src_stride, const int dst_stride, const short* filter_set, const short *fClipSet, clp_rng clp_rng, alf_component_id component_id, const int width, const int height, int x_pos, int y_pos, int blk_dst_x, int blk_dst_y, int vb_pos, const int vb_ctu_height) { videoframe_t* const frame = state->tile->frame; alf_filter_type const filter_type = component_id == COMPONENT_Y ? ALF_FILTER_7X7 : ALF_FILTER_5X5; const bool chroma = component_id == COMPONENT_Y ? 0 : 1; //alf_classifier **g_classifier = state->tile->frame->alf_info->g_classifier; //CHECK((vb_ctu_height & (vb_ctu_height - 1)) != 0, "vb_ctu_height must be a power of 2"); if (chroma) { assert((int)filter_type == 0); //Chroma needs to have filtType == 0 } /*#if !JVET_O0525_REMOVE_PCM //bool isDualTree = CS::isDualITree(cs); bool is_dual_tree = false; bool is_pcm_filter_enabled = ENABLE_PCM; enum kvz_chroma_format chroma_fmt = state->encoder_control->chroma_format; */ //const int srcStride = srcLuma.stride; //const int src_stride = frame->rec->stride; //const int dstStride = dstLuma.stride; //const int dst_stride = frame->rec->stride; const int start_height = y_pos; const int end_height = start_height + height; const int start_width = x_pos; const int end_width = start_width + width; const kvz_pixel *src = src_pixels; kvz_pixel *dst = dst_pixels + blk_dst_y * dst_stride; const kvz_pixel *p_img_y_pad_0, *p_img_y_pad_1, *p_img_y_pad_2, *p_img_y_pad_3, *p_img_y_pad_4, *p_img_y_pad_5, *p_img_y_pad_6; const kvz_pixel *p_img_0, *p_img_1, *p_img_2, *p_img_3, *p_img_4, *p_img_5, *p_img_6; const short *coef = filter_set; const short *clip = fClipSet; const int shift = ALF_NUM_BITS - 1; const int offset = 1 << (shift - 1); int transpose_idx = 0; const int cls_size_y = 4; const int cls_size_x = 4; /*#if !JVET_O0525_REMOVE_PCM bool pcm_flags_2x2[4] = { 0,0,0,0 };*/ assert((start_height % cls_size_y) == 0); //Wrong startHeight in filtering assert((start_width % cls_size_x) == 0); //Wrong startWidth in filtering assert(((end_height - start_height) % cls_size_y) == 0); //Wrong endHeight in filtering assert(((end_width - start_width) % cls_size_x) == 0); //Wrong endWidth in filtering alf_classifier *p_class = NULL; int dst_stride2 = dst_stride * cls_size_y; int src_stride2 = src_stride * cls_size_y; //std::vector filterCoeff(MAX_NUM_ALF_LUMA_COEFF); int filter_coeff[MAX_NUM_ALF_LUMA_COEFF]; //std::array filterClipp; int filter_clipp[MAX_NUM_ALF_LUMA_COEFF]; p_img_y_pad_0 = src + start_height * src_stride + start_width; p_img_y_pad_1 = p_img_y_pad_0 + src_stride; p_img_y_pad_2 = p_img_y_pad_0 - src_stride; p_img_y_pad_3 = p_img_y_pad_1 + src_stride; p_img_y_pad_4 = p_img_y_pad_2 - src_stride; p_img_y_pad_5 = p_img_y_pad_3 + src_stride; p_img_y_pad_6 = p_img_y_pad_4 - src_stride; kvz_pixel* p_rec_0 = dst + blk_dst_x;//start_width; kvz_pixel* p_rec_1 = p_rec_0 + dst_stride; for (int i = 0; i < end_height - start_height; i += cls_size_y) { if (!chroma) { p_class = g_classifier[blk_dst_y + i] + blk_dst_x; } for (int j = 0; j < end_width - start_width; j += cls_size_x) { if (!chroma) { alf_classifier cl = p_class[j]; transpose_idx = cl.transpose_idx; /*#if !JVET_O0525_REMOVE_PCM if (is_pcm_filter_enabled && cl.class_idx == ALF_UNUSED_CLASS_IDX && transpose_idx == ALF_UNUSED_TRANSPOSE_IDX) { continue; }*/ coef = filter_set + cl.class_idx * MAX_NUM_ALF_LUMA_COEFF; clip = fClipSet + cl.class_idx * MAX_NUM_ALF_LUMA_COEFF; } /*#if !JVET_O0525_REMOVE_PCM else if (is_pcm_filter_enabled) { int blk_x, blk_y; bool *flags = pcm_flags_2x2; // check which chroma 2x2 blocks use PCM // chroma PCM may not be aligned with 4x4 ALF processing grid for (blk_y = 0; blk_y < 4; blk_y += 2) { for (blk_x = 0; blk_x < 4; blk_x += 2) { //Position pos(j + blkDst.x + blkX, i + blkDst.y + blkY); //CodingUnit* cu = is_dual_tree ? cs.getCU(pos, CH_C) : cs.getCU(recalcPosition(nChromaFormat, CH_C, CH_L, pos), CH_L); *flags++ = 1; //cu->ipcm ? 1 : 0; } } // skip entire 4x4 if all chroma 2x2 blocks use PCM if (pcm_flags_2x2[0] && pcm_flags_2x2[1] && pcm_flags_2x2[2] && pcm_flags_2x2[3]) { continue; } }*/ if (filter_type == ALF_FILTER_7X7) { if (transpose_idx == 1) { filter_coeff[0] = coef[9]; filter_coeff[1] = coef[4]; filter_coeff[2] = coef[10]; filter_coeff[3] = coef[8]; filter_coeff[4] = coef[1]; filter_coeff[5] = coef[5]; filter_coeff[6] = coef[11]; filter_coeff[7] = coef[7]; filter_coeff[8] = coef[3]; filter_coeff[9] = coef[0]; filter_coeff[10] = coef[2]; filter_coeff[11] = coef[6]; filter_coeff[12] = coef[12]; filter_clipp[0] = clip[9]; filter_clipp[1] = clip[4]; filter_clipp[2] = clip[10]; filter_clipp[3] = clip[8]; filter_clipp[4] = clip[1]; filter_clipp[5] = clip[5]; filter_clipp[6] = clip[11]; filter_clipp[7] = clip[7]; filter_clipp[8] = clip[3]; filter_clipp[9] = clip[0]; filter_clipp[10] = clip[2]; filter_clipp[11] = clip[6]; filter_clipp[12] = clip[12]; } else if (transpose_idx == 2) { filter_coeff[0] = coef[0]; filter_coeff[1] = coef[3]; filter_coeff[2] = coef[2]; filter_coeff[3] = coef[1]; filter_coeff[4] = coef[8]; filter_coeff[5] = coef[7]; filter_coeff[6] = coef[6]; filter_coeff[7] = coef[5]; filter_coeff[8] = coef[4]; filter_coeff[9] = coef[9]; filter_coeff[10] = coef[10]; filter_coeff[11] = coef[11]; filter_coeff[12] = coef[12]; filter_clipp[0] = clip[0]; filter_clipp[1] = clip[3]; filter_clipp[2] = clip[2]; filter_clipp[3] = clip[1]; filter_clipp[4] = clip[8]; filter_clipp[5] = clip[7]; filter_clipp[6] = clip[6]; filter_clipp[7] = clip[5]; filter_clipp[8] = clip[4]; filter_clipp[9] = clip[9]; filter_clipp[10] = clip[10]; filter_clipp[11] = clip[11]; filter_clipp[12] = clip[12]; } else if (transpose_idx == 3) { filter_coeff[0] = coef[9]; filter_coeff[1] = coef[8]; filter_coeff[2] = coef[10]; filter_coeff[3] = coef[4]; filter_coeff[4] = coef[3]; filter_coeff[5] = coef[7]; filter_coeff[6] = coef[11]; filter_coeff[7] = coef[5]; filter_coeff[8] = coef[1]; filter_coeff[9] = coef[0]; filter_coeff[10] = coef[2]; filter_coeff[11] = coef[6]; filter_coeff[12] = coef[12]; filter_clipp[0] = clip[9]; filter_clipp[1] = clip[8]; filter_clipp[2] = clip[10]; filter_clipp[3] = clip[4]; filter_clipp[4] = clip[3]; filter_clipp[5] = clip[7]; filter_clipp[6] = clip[11]; filter_clipp[7] = clip[5]; filter_clipp[8] = clip[1]; filter_clipp[9] = clip[0]; filter_clipp[10] = clip[2]; filter_clipp[11] = clip[6]; filter_clipp[12] = clip[12]; } else { filter_coeff[0] = coef[0]; filter_coeff[1] = coef[1]; filter_coeff[2] = coef[2]; filter_coeff[3] = coef[3]; filter_coeff[4] = coef[4]; filter_coeff[5] = coef[5]; filter_coeff[6] = coef[6]; filter_coeff[7] = coef[7]; filter_coeff[8] = coef[8]; filter_coeff[9] = coef[9]; filter_coeff[10] = coef[10]; filter_coeff[11] = coef[11]; filter_coeff[12] = coef[12]; filter_clipp[0] = clip[0]; filter_clipp[1] = clip[1]; filter_clipp[2] = clip[2]; filter_clipp[3] = clip[3]; filter_clipp[4] = clip[4]; filter_clipp[5] = clip[5]; filter_clipp[6] = clip[6]; filter_clipp[7] = clip[7]; filter_clipp[8] = clip[8]; filter_clipp[9] = clip[9]; filter_clipp[10] = clip[10]; filter_clipp[11] = clip[11]; filter_clipp[12] = clip[12]; } } else { if (transpose_idx == 1) { filter_coeff[0] = coef[4]; filter_coeff[1] = coef[1]; filter_coeff[2] = coef[5]; filter_coeff[3] = coef[3]; filter_coeff[4] = coef[0]; filter_coeff[5] = coef[2]; filter_coeff[6] = coef[6]; filter_clipp[0] = clip[4]; filter_clipp[1] = clip[1]; filter_clipp[2] = clip[5]; filter_clipp[3] = clip[3]; filter_clipp[4] = clip[0]; filter_clipp[5] = clip[2]; filter_clipp[6] = clip[6]; } else if (transpose_idx == 2) { filter_coeff[0] = coef[0]; filter_coeff[1] = coef[3]; filter_coeff[2] = coef[2]; filter_coeff[3] = coef[1]; filter_coeff[4] = coef[4]; filter_coeff[5] = coef[5]; filter_coeff[6] = coef[6]; filter_clipp[0] = clip[0]; filter_clipp[1] = clip[3]; filter_clipp[2] = clip[2]; filter_clipp[3] = clip[1]; filter_clipp[4] = clip[4]; filter_clipp[5] = clip[5]; filter_clipp[6] = clip[6]; } else if (transpose_idx == 3) { filter_coeff[0] = coef[4]; filter_coeff[1] = coef[3]; filter_coeff[2] = coef[5]; filter_coeff[3] = coef[1]; filter_coeff[4] = coef[0]; filter_coeff[5] = coef[2]; filter_coeff[6] = coef[6]; filter_clipp[0] = clip[4]; filter_clipp[1] = clip[3]; filter_clipp[2] = clip[5]; filter_clipp[3] = clip[1]; filter_clipp[4] = clip[0]; filter_clipp[5] = clip[2]; filter_clipp[6] = clip[6]; } else { filter_coeff[0] = coef[0]; filter_coeff[1] = coef[1]; filter_coeff[2] = coef[2]; filter_coeff[3] = coef[3]; filter_coeff[4] = coef[4]; filter_coeff[5] = coef[5]; filter_coeff[6] = coef[6]; filter_clipp[0] = clip[0]; filter_clipp[1] = clip[1]; filter_clipp[2] = clip[2]; filter_clipp[3] = clip[3]; filter_clipp[4] = clip[4]; filter_clipp[5] = clip[5]; filter_clipp[6] = clip[6]; } } for (int ii = 0; ii < cls_size_y; ii++) { p_img_0 = p_img_y_pad_0 + j + ii * src_stride; p_img_1 = p_img_y_pad_1 + j + ii * src_stride; p_img_2 = p_img_y_pad_2 + j + ii * src_stride; p_img_3 = p_img_y_pad_3 + j + ii * src_stride; p_img_4 = p_img_y_pad_4 + j + ii * src_stride; p_img_5 = p_img_y_pad_5 + j + ii * src_stride; p_img_6 = p_img_y_pad_6 + j + ii * src_stride; p_rec_1 = p_rec_0 + j + ii * dst_stride; const int yVb = (blk_dst_y + i + ii) & (vb_ctu_height - 1); if (yVb < vb_pos && (yVb >= vb_pos - (chroma ? 2 : 4))) // above { p_img_1 = (yVb == vb_pos - 1) ? p_img_0 : p_img_1; p_img_3 = (yVb >= vb_pos - 2) ? p_img_1 : p_img_3; p_img_5 = (yVb >= vb_pos - 3) ? p_img_3 : p_img_5; p_img_2 = (yVb == vb_pos - 1) ? p_img_0 : p_img_2; p_img_4 = (yVb >= vb_pos - 2) ? p_img_2 : p_img_4; p_img_6 = (yVb >= vb_pos - 3) ? p_img_4 : p_img_6; } else if (yVb >= vb_pos && (yVb <= vb_pos + (chroma ? 1 : 3))) // bottom { p_img_2 = (yVb == vb_pos) ? p_img_0 : p_img_2; p_img_4 = (yVb <= vb_pos + 1) ? p_img_2 : p_img_4; p_img_6 = (yVb <= vb_pos + 2) ? p_img_4 : p_img_6; p_img_1 = (yVb == vb_pos) ? p_img_0 : p_img_1; p_img_3 = (yVb <= vb_pos + 1) ? p_img_1 : p_img_3; p_img_5 = (yVb <= vb_pos + 2) ? p_img_3 : p_img_5; } for (int jj = 0; jj < cls_size_x; jj++) { /*#if !JVET_O0525_REMOVE_PCM // skip 2x2 PCM chroma blocks if (chroma && is_pcm_filter_enabled) { if (pcm_flags_2x2[2 * (ii >> 1) + (jj >> 1)]) { p_img_0++; p_img_1++; p_img_2++; p_img_3++; p_img_4++; p_img_5++; p_img_6++; continue; } }*/ int sum = 0; const kvz_pixel curr = p_img_0[+0]; if (filter_type == ALF_FILTER_7X7) { sum += filter_coeff[0] * (clip_alf(filter_clipp[0], curr, p_img_5[+0], p_img_6[+0])); sum += filter_coeff[1] * (clip_alf(filter_clipp[1], curr, p_img_3[+1], p_img_4[-1])); sum += filter_coeff[2] * (clip_alf(filter_clipp[2], curr, p_img_3[+0], p_img_4[+0])); sum += filter_coeff[3] * (clip_alf(filter_clipp[3], curr, p_img_3[-1], p_img_4[+1])); sum += filter_coeff[4] * (clip_alf(filter_clipp[4], curr, p_img_1[+2], p_img_2[-2])); sum += filter_coeff[5] * (clip_alf(filter_clipp[5], curr, p_img_1[+1], p_img_2[-1])); sum += filter_coeff[6] * (clip_alf(filter_clipp[6], curr, p_img_1[+0], p_img_2[+0])); sum += filter_coeff[7] * (clip_alf(filter_clipp[7], curr, p_img_1[-1], p_img_2[+1])); sum += filter_coeff[8] * (clip_alf(filter_clipp[8], curr, p_img_1[-2], p_img_2[+2])); sum += filter_coeff[9] * (clip_alf(filter_clipp[9], curr, p_img_0[+3], p_img_0[-3])); sum += filter_coeff[10] * (clip_alf(filter_clipp[10], curr, p_img_0[+2], p_img_0[-2])); sum += filter_coeff[11] * (clip_alf(filter_clipp[11], curr, p_img_0[+1], p_img_0[-1])); } else { sum += filter_coeff[0] * (clip_alf(filter_clipp[0], curr, p_img_3[+0], p_img_4[+0])); sum += filter_coeff[1] * (clip_alf(filter_clipp[1], curr, p_img_1[+1], p_img_2[-1])); sum += filter_coeff[2] * (clip_alf(filter_clipp[2], curr, p_img_1[+0], p_img_2[+0])); sum += filter_coeff[3] * (clip_alf(filter_clipp[3], curr, p_img_1[-1], p_img_2[+1])); sum += filter_coeff[4] * (clip_alf(filter_clipp[4], curr, p_img_0[+2], p_img_0[-2])); sum += filter_coeff[5] * (clip_alf(filter_clipp[5], curr, p_img_0[+1], p_img_0[-1])); } sum = (sum + offset) >> shift; sum += curr; p_rec_1[jj] = alf_clip_pixel(sum, clp_rng); p_img_0++; p_img_1++; p_img_2++; p_img_3++; p_img_4++; p_img_5++; p_img_6++; } } } p_rec_0 += dst_stride2; p_rec_1 += dst_stride2; p_img_y_pad_0 += src_stride2; p_img_y_pad_1 += src_stride2; p_img_y_pad_2 += src_stride2; p_img_y_pad_3 += src_stride2; p_img_y_pad_4 += src_stride2; p_img_y_pad_5 += src_stride2; p_img_y_pad_6 += src_stride2; } }