/****************************************************************************** * * * 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 "ixheaac_type_def.h" #include "ixheaac_constants.h" #include "ixheaacd_bitbuffer.h" #include "ixheaacd_interface.h" #include "ixheaacd_common_rom.h" #include "ixheaacd_sbrdecsettings.h" #include "ixheaacd_sbr_scale.h" #include "ixheaacd_env_extr_part.h" #include "ixheaacd_sbr_rom.h" #include "ixheaacd_hybrid.h" #include "ixheaacd_ps_dec.h" #include "ixheaacd_config.h" #include "ixheaacd_qmf_dec.h" #include "ixheaacd_mps_polyphase.h" #include "ixheaacd_mps_struct_def.h" #include "ixheaacd_mps_res_rom.h" #include "ixheaacd_mps_aac_struct.h" #include "ixheaacd_mps_dec.h" #include "ixheaacd_function_selector.h" extern const FLOAT32 ixheaacd_mps_polyphase_filter_coeff[10 * MAX_NUM_QMF_BANDS_SAC / 2]; extern const FLOAT32 ixheaacd_mps_post_twid[30]; extern const FLOAT32 ixheaacd_mps_pre_twid[64]; extern const FLOAT32 ixheaacd_ldmps_polyphase_filter_coeff[1280]; extern const FLOAT32 ixheaacd_ldmps_pre_twid[32]; extern const FLOAT32 ixheaacd_mps_post_re_32[64]; extern const FLOAT32 ixheaacd_mps_post_im_32[64]; VOID ixheaacd_mps_synt_init(FLOAT32 state[POLY_PHASE_SYNTH_SIZE]) { memset(state, 0, sizeof(FLOAT32) * POLY_PHASE_SYNTH_SIZE); } VOID ixheaacd_mps_synt_post_fft_twiddle_dec(WORD32 resolution, FLOAT32 *fin_re, FLOAT32 *fin_im, const FLOAT32 *table_re, const FLOAT32 *table_im, FLOAT32 *state) { WORD32 l; for (l = 0; l < 2 * resolution; l++) { state[2 * resolution - l - 1] = ((fin_re[l] * table_re[l]) + (fin_im[l] * table_im[l])); } } VOID ixheaacd_mps_synt_out_calc_dec(WORD32 resolution, FLOAT32 *out, FLOAT32 *state, const FLOAT32 *filter_coeff) { WORD32 l, k; FLOAT32 *out1, *out2, *state1, *state2; out1 = out; out2 = out + resolution; state1 = state; state2 = state + (3 * resolution); for (k = 0; k < 5; k++) { for (l = 0; l < resolution; l++) { *out1++ = (*state1++) * (*filter_coeff++); *out2++ = (*state2++) * (*filter_coeff++); } out1 += resolution; out2 += resolution; state1 += (3 * resolution); state2 += (3 * resolution); } } VOID ixheaacd_mps_synt_out_calc_dec_ldmps(WORD32 resolution, FLOAT32 *out, FLOAT32 *state, const FLOAT32 *filter_coeff) { WORD32 l, k; FLOAT32 *out1, *out2, *state1, *state2; const FLOAT32 *filter1, *filter2; filter1 = filter_coeff; filter2 = filter_coeff + resolution; out1 = out; out2 = out + resolution; state1 = state; state2 = state + (3 * resolution); for (k = 0; k < 5; k++) { for (l = 0; l < resolution; l++) { *out1++ = (*state1++) * (*filter1++); *out2++ = (*state2++) * (*filter2++); } filter1 += resolution; filter2 += resolution; out1 += resolution; out2 += resolution; state1 += (3 * resolution); state2 += (3 * resolution); } } VOID ixheaacd_mps_synt_out_calc_dec_ldmps_32(WORD32 resolution, FLOAT32 *out, FLOAT32 *state, const FLOAT32 *filter_coeff) { WORD32 l, k; FLOAT32 *out1, *out2, *state1, *state2; const FLOAT32 *filter1, *filter2; filter1 = filter_coeff; filter2 = filter_coeff + 2 * resolution; out1 = out; out2 = out + resolution; state1 = state; state2 = state + (3 * resolution); for (k = 0; k < 5; k++) { for (l = 0; l < resolution; l++) { *out1++ = ((*state1++) * (filter1[2*l] + filter1[2*l+1])/2); *out2++ = ((*state2++) * (filter2[2 * l] + filter2[2 * l + 1])/2); } filter1 += 4 * resolution; filter2 += 4 * resolution; out1 += resolution; out2 += resolution; state1 += (3 * resolution); state2 += (3 * resolution); } } VOID ixheaacd_mps_synth_pre_twidle(FLOAT32 *out_re, FLOAT32 *out_im, FLOAT32 *c_in, WORD32 len) { WORD32 i; FLOAT32 *c_s = c_in; FLOAT32 *p_re_s = out_re; FLOAT32 *p_im_s = out_im; FLOAT32 *c_e = c_in + (len << 1) - 1; FLOAT32 *p_im_e = out_im + len - 1; FLOAT32 *p_re_e = out_re + len - 1; const FLOAT32 *prtw = ixheaacd_mps_pre_twid; for (i = 0; i < len; i += 4) { *p_re_s = ((*c_s++) * (*prtw)); p_re_s++; *p_im_s = -((*c_s--) * (*prtw)); p_im_s++; *p_im_s = ((*c_e--) * (*prtw)); p_im_s--; *p_re_s = ((*c_e++) * (*prtw++)); p_re_s--; *p_im_s += ((*c_e--) * (*prtw)); p_im_s++; *p_re_s += ((*c_e--) * (*prtw)); p_re_s++; *p_re_s -= ((*c_s++) * (*prtw)); p_re_s++; *p_im_s += ((*c_s++) * (*prtw++)); p_im_s++; *p_im_e = ((*c_e--) * (*prtw)); p_im_e--; *p_re_e = -((*c_e++) * (*prtw)); p_re_e--; *p_re_e = ((*c_s++) * (*prtw)); p_re_e++; *p_im_e = ((*c_s--) * (*prtw++)); p_im_e++; *p_re_e += ((*c_s++) * (*prtw)); p_re_e--; *p_im_e += ((*c_s++) * (*prtw)); p_im_e--; *p_im_e -= ((*c_e--) * (*prtw)); p_im_e--; *p_re_e += ((*c_e--) * (*prtw++)); p_re_e--; } } VOID ixheaacd_mps_synth_post_twidle(FLOAT32 *state, FLOAT32 *out_re, FLOAT32 *out_im, WORD32 len) { WORD32 i; { FLOAT32 x_0, x_1, x_2, x_3; FLOAT32 *p_re_e, *p_im_e; const FLOAT32 *potw = ixheaacd_mps_post_twid; FLOAT32 *p_re_s = out_re; FLOAT32 *p_im_s = out_im; p_re_e = p_re_s + (len - 2); p_im_e = p_im_s + (len - 2); x_0 = *p_re_e; x_1 = *(p_re_e + 1); x_2 = *p_im_e; x_3 = *(p_im_e + 1); *(p_re_e + 1) = -*(p_re_s + 1); *(p_im_e + 1) = -*p_im_s; *p_im_s = *(p_im_s + 1); for (i = 5; i < len; i += 4) { FLOAT32 twdr = *potw++; FLOAT32 twdi = *potw++; FLOAT32 tmp; *p_re_e = (x_0 * twdi); *p_re_e += (x_1 * twdr); p_re_e--; p_re_s++; *p_re_s = (x_0 * twdr); *p_re_s -= (x_1 * twdi); p_re_s++; x_1 = *p_re_e--; x_0 = *p_re_e++; *p_re_e = (*p_re_s++ * twdi); *p_re_e += -(*p_re_s * twdr); p_re_e--; tmp = (*p_re_s-- * twdi); *p_re_s = tmp + (*p_re_s * twdr); *p_im_e = -(x_2 * twdr); *p_im_e += (x_3 * twdi); p_im_e--; p_im_s++; *p_im_s = -(x_2 * twdi); *p_im_s -= (x_3 * twdr); p_im_s++; x_3 = *p_im_e--; x_2 = *p_im_e++; *p_im_e = -(*p_im_s++ * twdr); *p_im_e -= (*p_im_s * twdi); p_im_e--; tmp = (*p_im_s-- * twdr); *p_im_s = tmp - (*p_im_s * twdi); } *p_re_e = 0.7071067f * (x_1 + x_0); *p_im_e = 0.7071067f * (x_3 - x_2); *(p_re_s + 1) = -0.7071067f * (x_1 - x_0); *(p_im_s + 1) = -0.7071067f * (x_3 + x_2); } for (i = 0; i < len; i++) { state[i] = out_im[i] - out_re[i]; state[len + i] = out_im[len - i - 1] + out_re[len - i - 1]; state[len - i - 1] = out_im[len - i - 1] - out_re[len - i - 1]; state[2 * len - i - 1] = out_im[i] + out_re[i]; } } VOID ixheaacd_mps_synt_pre_twiddle_dec(FLOAT32 *ptr_in, const FLOAT32 *table, FLOAT32 *fin_re, FLOAT32 *fin_im, WORD32 resolution) { WORD32 k; FLOAT32 *c_s = ptr_in; FLOAT32 *p_re_s = fin_re; FLOAT32 *p_im_s = fin_im; FLOAT32 *c_e = ptr_in + (resolution << 1) - 1; FLOAT32 *p_im_e = fin_im + resolution - 1; FLOAT32 *p_re_e = fin_re + resolution - 1; for (k = 0; k < resolution; k += 2) { *p_re_s = (*c_s++) * (*table); *p_im_s = (*c_s) * (*table); *p_re_e = (*c_e--) * (*table); *p_im_e = -(*c_e) * (*table++); *p_re_s += (*c_s--) * (*table); *p_im_s += -(*c_s++) * (*table); p_re_s++; p_im_s++; c_s++; *p_re_e += (*c_e++) * (*table); *p_im_e += (*c_e--) * (*table++); p_re_e--; p_im_e--; c_e--; } } VOID ixheaacd_mps_synt_calc(ia_mps_dec_state_struct *self) { WORD32 k, l, ts, ch; FLOAT32 *state, *tmp_state, *out; const FLOAT32 *filt_coeff; FLOAT32 *tmp_buf = self->tmp_buf; FLOAT32 fin_re[64] = {0}; FLOAT32 fin_im[64] = {0}; WORD32 resolution = self->resolution; WORD32 m_resolution = resolution >> 1; const FLOAT32 *ixheaacd_mps_post_re, *ixheaacd_mps_post_im; VOID(*ixheaacd_mps_synt_out_calc_pointer) (WORD32 resolution, FLOAT32 *out, FLOAT32 *state, const FLOAT32 *filter_coeff); if (self->ldmps_config.ldmps_present_flag) { ixheaacd_mps_synt_out_calc_pointer = &ixheaacd_mps_synt_out_calc_dec_ldmps; filt_coeff = ixheaacd_ldmps_polyphase_filter_coeff; } else { ixheaacd_mps_synt_out_calc_pointer = ixheaacd_mps_synt_out_calc; filt_coeff = ixheaacd_mps_polyphase_filter_coeff; } if (self->qmf_band_count == 32) { for (ch = 0; ch < self->out_ch_count; ch++) { tmp_state = self->qmf_filt_state[ch]; state = &tmp_buf[self->time_slots * 2 * resolution]; memcpy(state, tmp_state, sizeof(FLOAT32) * 18 * resolution); out = &tmp_buf[74 * MAX_NUM_QMF_BANDS_SAC]; ixheaacd_mps_post_re = ixheaacd_mps_post_re_32; ixheaacd_mps_post_im = ixheaacd_mps_post_im_32; for (ts = 0; ts < self->time_slots; ts++) { state -= (2 * resolution); ixheaacd_mps_synt_pre_twiddle_dec(&self->qmf_out_dir[ch][ts][0].re, ixheaacd_ldmps_pre_twid, fin_re, fin_im, resolution); for (k = resolution; k < 2 * resolution; k++) { fin_re[k] = 0; fin_im[k] = 0; } ixheaacd_mps_complex_fft(fin_re, fin_im, 2 * resolution); ixheaacd_mps_synt_post_fft_twiddle_dec(resolution, fin_re, fin_im, ixheaacd_mps_post_re, ixheaacd_mps_post_im, state); ixheaacd_mps_synt_out_calc_dec_ldmps_32(resolution, out, state, filt_coeff); for (k = 0; k < resolution; k++) { FLOAT32 acc = out[k]; for (l = 1; l < 10; l++) { acc += out[resolution * l + k]; } self->output_buffer[ch][self->qmf_band_count * ts + k] = acc; } } memcpy(tmp_state, state, sizeof(FLOAT32) * 18 * resolution); } } else { for (ch = 0; ch < self->out_ch_count; ch++) { tmp_state = self->qmf_filt_state[ch]; state = &tmp_buf[self->time_slots * 2 * resolution]; memcpy(state, tmp_state, sizeof(FLOAT32) * 18 * resolution); out = &tmp_buf[74 * MAX_NUM_QMF_BANDS_SAC]; for (ts = 0; ts < self->time_slots; ts++) { state -= (2 * resolution); ixheaacd_mps_synth_pre_twidle( fin_re, fin_im, &self->qmf_out_dir[ch][ts][0].re, resolution); ixheaacd_mps_synth_calc_fft(fin_re, fin_im, m_resolution); ixheaacd_mps_synth_post_twidle(state, fin_re, fin_im, resolution); (*ixheaacd_mps_synt_out_calc_pointer)(resolution, out, state, filt_coeff); for (k = 0; k < resolution; k++) { FLOAT32 acc = out[k]; for (l = 1; l < 10; l++) { acc += out[resolution * l + k]; } self->output_buffer[ch][self->qmf_band_count * ts + k] = acc; } } memcpy(tmp_state, state, sizeof(FLOAT32) * 18 * resolution); } } }