/****************************************************************************** * * * Copyright (C) 2018 The Android Open Source Project * * Licensed under the Apache License, Version 2.0 (the "License"); * you may not use this file except in compliance with the License. * You may obtain a copy of the License at: * * http://www.apache.org/licenses/LICENSE-2.0 * * Unless required by applicable law or agreed to in writing, software * distributed under the License is distributed on an "AS IS" BASIS, * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. * See the License for the specific language governing permissions and * limitations under the License. * ***************************************************************************** * Originally developed and contributed by Ittiam Systems Pvt. Ltd, Bangalore */ #include #include "ixheaacd_bitbuffer.h" #include "ixheaacd_config.h" #include "ixheaacd_mps_polyphase.h" #include "ixheaacd_mps_dec.h" #include "ixheaacd_mps_interface.h" #include "ixheaacd_mps_process.h" #include #include #include #include #include "ixheaacd_common_rom.h" #include "ixheaacd_defines.h" #include "ixheaacd_pns.h" #include #include "ixheaacd_pulsedata.h" #include "ixheaacd_sbrdecsettings.h" #include "ixheaacd_sbr_scale.h" #include "ixheaacd_lpp_tran.h" #include "ixheaacd_env_extr_part.h" #include #include "ixheaacd_hybrid.h" #include "ixheaacd_ps_dec.h" #include "ixheaacd_env_extr.h" #include "ixheaacd_qmf_dec.h" #include "ixheaacd_env_calc.h" #include "ixheaacd_sbr_const.h" #include "ixheaacd_pvc_dec.h" #include "ixheaacd_sbr_dec.h" #define HP_SIZE (9) #define STP_LPF_COEFF1 (0.950f) #define STP_LPF_COEFF2 (0.450f) #define STP_UPDATE_ENERGY_RATE (32) #define STP_SCALE_LIMIT (2.82f) #define STP_DAMP (0.1f) #define max(a, b) ((a > b) ? (a) : (b)) #define min(a, b) ((a < b) ? (a) : (b)) static FLOAT32 ixheaacd_bp[BP_SIZE] = { 0.0000f, 0.0005f, 0.0092f, 0.0587f, 0.2580f, 0.7392f, 0.9791f, 0.9993f, 1.0000f, 1.0000f, 1.0000f, 1.0000f, 0.9999f, 0.9984f, 0.9908f, 0.9639f, 0.8952f, 0.7711f, 0.6127f, 0.4609f, 0.3391f, 0.2493f, 0.1848f, 0.1387f, 0.1053f}; static FLOAT32 ixheaacd_gf[BP_SIZE] = { 0.f, 0.f, 0.f, 0.f, 0.f, 0.f, 1e-008f, 8.1e-007f, 3.61e-006f, 8.41e-006f, 1.6e-005f, 2.704e-005f, 3.969e-005f, 5.625e-005f, 7.396e-005f, 9.801e-005f, 0.00012321f, 0.00015625f, 0.00019881f, 0.00024964f, 0.00032041f, 0.00041209f, 0.00053824f, 0.00070756f, 0.00094249f}; static VOID ixheaacd_mps_temp_process_scale_calc(ia_mps_dec_state_struct* self, WORD32 ts, FLOAT32* scale) { FLOAT32 dir_energy; FLOAT32 diff_energy[2]; FLOAT32 temp; WORD32 ch, n; WORD32 left_ch = 0, right_ch = 1; if (self->subband_var.init_flag == 0) { for (ch = 0; ch < 2; ch++) { self->subband_var.tp_scale_last[ch] = 1.0f; self->subband_var.nrg_diff_prev[ch] = 32768 * 32768; } self->subband_var.nrg_dir_prev = 32768 * 32768; self->subband_var.init_flag = 1; } if (self->subband_var.update_old_ener == STP_UPDATE_ENERGY_RATE) { self->subband_var.update_old_ener = 1; self->subband_var.nrg_dir_prev = self->subband_var.nrg_dir; for (ch = 0; ch < self->out_ch_count; ch++) self->subband_var.nrg_diff_prev[ch] = self->subband_var.nrg_diff[ch]; } else self->subband_var.update_old_ener++; dir_energy = 0; for (n = 6; n < BP_SIZE; n++) { FLOAT32 dir_left_re = self->hyb_dir_out[left_ch][ts][n + 7].re; FLOAT32 dir_right_re = self->hyb_dir_out[right_ch][ts][n + 7].re; FLOAT32 dir_left_im = self->hyb_dir_out[left_ch][ts][n + 7].im; FLOAT32 dir_right_im = self->hyb_dir_out[right_ch][ts][n + 7].im; temp = ((dir_left_re + dir_right_re) * (dir_left_re + dir_right_re)) + ((dir_left_im + dir_right_im) * (dir_left_im + dir_right_im)); dir_energy += temp * ixheaacd_bp[n] * ixheaacd_bp[n] * ixheaacd_gf[n] * ixheaacd_gf[n]; } self->subband_var.nrg_dir = (FLOAT32)(STP_LPF_COEFF1 * self->subband_var.nrg_dir + (1.0 - STP_LPF_COEFF1) * dir_energy); dir_energy /= (self->subband_var.nrg_dir_prev + ABS_THR); for (ch = 0; ch < self->out_ch_count; ch++) { diff_energy[ch] = 0; for (n = 6; n < BP_SIZE; n++) { FLOAT32 diff_re = self->hyb_diff_out[ch][ts][n + 7].re; FLOAT32 diff_im = self->hyb_diff_out[ch][ts][n + 7].im; temp = (diff_re * diff_re) + (diff_im * diff_im); diff_energy[ch] += temp * ixheaacd_bp[n] * ixheaacd_bp[n] * ixheaacd_gf[n] * ixheaacd_gf[n]; } self->subband_var.nrg_diff[ch] = (FLOAT32)(STP_LPF_COEFF1 * self->subband_var.nrg_diff[ch] + (1.0 - STP_LPF_COEFF1) * diff_energy[ch]); diff_energy[ch] /= (self->subband_var.nrg_diff_prev[ch] + ABS_THR); } scale[left_ch] = (FLOAT32)sqrt((dir_energy) / (diff_energy[left_ch] + 1e-9)); scale[right_ch] = (FLOAT32)sqrt((dir_energy) / (diff_energy[right_ch] + 1e-9)); for (ch = 0; ch < self->out_ch_count; ch++) { scale[ch] = STP_DAMP + (1 - STP_DAMP) * scale[ch]; } for (ch = 0; ch < self->out_ch_count; ch++) { scale[ch] = min(max(scale[ch], (FLOAT32)(1.0 / STP_SCALE_LIMIT)), STP_SCALE_LIMIT); } for (ch = 0; ch < self->out_ch_count; ch++) { scale[ch] = (FLOAT32)(STP_LPF_COEFF2 * scale[ch] + (1.0 - STP_LPF_COEFF2) * self->subband_var.tp_scale_last[ch]); self->subband_var.tp_scale_last[ch] = scale[ch]; } } static VOID ixheaacd_mps_subbandtp(ia_mps_dec_state_struct* self, WORD32 ts) { FLOAT32 scale[2]; WORD32 ch, n; WORD32 no_scaling; FLOAT32 temp; const WORD32 ixheaacd_hybrid_to_qmf_map[] = {0, 0, 0, 0, 0, 0, 1, 1, 2, 2}; ixheaacd_mps_temp_process_scale_calc(self, ts, scale); for (ch = 0; ch < self->out_ch_count; ch++) { no_scaling = 1; if ((self->config->bs_temp_shape_config == 1) || (self->config->bs_temp_shape_config == 2)) no_scaling = !self->temp_shape_enable_ch_stp[ch]; if (no_scaling == 1) { for (n = 0; n < self->hyb_band_count; n++) { self->hyb_dir_out[ch][ts][n].re += self->hyb_diff_out[ch][ts][n].re; self->hyb_dir_out[ch][ts][n].im += self->hyb_diff_out[ch][ts][n].im; } } else { for (n = 0; n < 10; n++) { temp = (FLOAT32)(scale[ch] * ixheaacd_bp[ixheaacd_hybrid_to_qmf_map[n]]); self->hyb_dir_out[ch][ts][n].re += (self->hyb_diff_out[ch][ts][n].re * temp); self->hyb_dir_out[ch][ts][n].im += (self->hyb_diff_out[ch][ts][n].im * temp); } for (; n < HP_SIZE - 3 + 10; n++) { temp = (FLOAT32)(scale[ch] * ixheaacd_bp[n + 3 - 10]); self->hyb_dir_out[ch][ts][n].re += (self->hyb_diff_out[ch][ts][n].re * temp); self->hyb_dir_out[ch][ts][n].im += (self->hyb_diff_out[ch][ts][n].im * temp); } for (; n < self->hyb_band_count; n++) { temp = (FLOAT32)(scale[ch]); self->hyb_dir_out[ch][ts][n].re += (self->hyb_diff_out[ch][ts][n].re * temp); self->hyb_dir_out[ch][ts][n].im += (self->hyb_diff_out[ch][ts][n].im * temp); } } } } WORD32 ixheaacd_mps_temp_process(ia_mps_dec_state_struct* self) { WORD32 ch, ts, hyb; WORD32 err = 0; for (ch = 0; ch < self->out_ch_count; ch++) { for (ts = 0; ts < self->time_slots; ts++) { for (hyb = 0; hyb < HYBRID_BAND_BORDER; hyb++) { self->hyb_dir_out[ch][ts][hyb].re += self->hyb_diff_out[ch][ts][hyb].re; self->hyb_dir_out[ch][ts][hyb].im += self->hyb_diff_out[ch][ts][hyb].im; self->hyb_diff_out[ch][ts][hyb].re = 0; self->hyb_diff_out[ch][ts][hyb].im = 0; } } } for (ts = 0; ts < self->time_slots; ts++) ixheaacd_mps_subbandtp(self, ts); ixheaacd_mps_qmf_hyb_synthesis(self); for (ch = 0; ch < self->out_ch_count; ch++) { err = ixheaacd_sbr_dec_from_mps(&self->qmf_out_dir[ch][0][0].re, self->p_sbr_dec[ch], self->p_sbr_frame[ch], self->p_sbr_header[ch]); if (err) return err; } ixheaacd_mps_synt_calc(self); return err; }