/* *=================================================================== * 3GPP AMR Wideband Floating-point Speech Codec *=================================================================== */ #include #include #include #include #include "typedef.h" #include "dec_main.h" #include "dec_dtx.h" #include "dec_acelp.h" #include "dec_gain.h" #include "dec_lpc.h" #include "dec_util.h" #define MAX_16 (Word16)0x7fff #define MIN_16 (Word16)0x8000 #define L_FRAME 256 /* Frame size */ #define NB_SUBFR 4 /* Number of subframe per frame */ #define L_SUBFR 64 /* Subframe size */ #define MODE_7k 0 /* modes */ #define MODE_9k 1 #define MODE_12k 2 #define MODE_14k 3 #define MODE_16k 4 #define MODE_18k 5 #define MODE_20k 6 #define MODE_23k 7 #define MODE_24k 8 #define RX_SPEECH_PROBABLY_DEGRADED 1 /* rx types */ #define RX_SPEECH_LOST 2 #define RX_SPEECH_BAD 3 #define RX_NO_DATA 7 #define Q_MAX 8 /* scaling max for signal */ #define PIT_SHARP 27853 /* pitch sharpening factor = 0.85 Q15 */ #define PIT_MIN 34 /* Minimum pitch lag with resolution 1/4 */ #define PIT_FR2 128 /* Minimum pitch lag with resolution 1/2 */ #define PIT_FR1_9b 160 /* Minimum pitch lag with resolution 1 */ #define PIT_FR1_8b 92 /* Minimum pitch lag with resolution 1 */ extern const Word16 D_ROM_isp[]; extern const Word16 D_ROM_isf[]; extern const Word16 D_ROM_interpol_frac[]; #ifdef WIN32 #pragma warning( disable : 4310) #endif /* * Decoder_reset * * Parameters: * st I/O: pointer to state structure * reset_all I: perform full reset * * Function: * Initialisation of variables for the decoder section. * * * Returns: * void */ void D_MAIN_reset(void *st, Word16 reset_all) { Word32 i; Decoder_State *dec_state; dec_state = (Decoder_State*)st; memset(dec_state->mem_exc, 0, (PIT_MAX + L_INTERPOL) * sizeof(Word16)); memset(dec_state->mem_isf_q, 0, M * sizeof(Word16)); dec_state->mem_T0_frac = 0; /* old pitch value = 64.0 */ dec_state->mem_T0 = 64; dec_state->mem_first_frame = 1; dec_state->mem_gc_thres = 0; dec_state->mem_tilt_code = 0; memset(dec_state->mem_ph_disp, 0, 8 * sizeof(Word16)); /* scaling memories for excitation */ dec_state->mem_q = Q_MAX; dec_state->mem_subfr_q[3] = Q_MAX; dec_state->mem_subfr_q[2] = Q_MAX; dec_state->mem_subfr_q[1] = Q_MAX; dec_state->mem_subfr_q[0] = Q_MAX; if(reset_all != 0) { /* routines initialization */ D_GAIN_init(dec_state->mem_gain); memset(dec_state->mem_oversamp, 0, (2 * 12) * sizeof(Word16)); memset(dec_state->mem_sig_out, 0, 6 * sizeof(Word16)); memset(dec_state->mem_hf, 0, (31 - 1) * sizeof(Word16)); memset(dec_state->mem_hf3, 0, (31 - 1) * sizeof(Word16)); memset(dec_state->mem_hp400, 0, 6 * sizeof(Word16)); D_GAIN_lag_concealment_init(dec_state->mem_lag); /* isp initialization */ memcpy(dec_state->mem_isp, D_ROM_isp, M * sizeof(Word16)); memcpy(dec_state->mem_isf, D_ROM_isf, M * sizeof(Word16)); for(i = 0; i < L_MEANBUF; i++) { memcpy(&dec_state->mem_isf_buf[i * M], D_ROM_isf, M * sizeof(Word16)); } /* variable initialization */ dec_state->mem_deemph = 0; dec_state->mem_seed = 21845; /* init random with 21845 */ dec_state->mem_seed2 = 21845; dec_state->mem_seed3 = 21845; dec_state->mem_state = 0; dec_state->mem_bfi = 0; /* Static vectors to zero */ memset(dec_state->mem_syn_hf, 0, M16k * sizeof(Word16)); memset(dec_state->mem_syn_hi, 0, M * sizeof(Word16)); memset(dec_state->mem_syn_lo, 0, M * sizeof(Word16)); D_DTX_reset(dec_state->dtx_decSt, D_ROM_isf); dec_state->mem_vad_hist = 0; } return; } /* * Decoder_init * * Parameters: * spd_state O: pointer to state structure * * Function: * Initialization of variables for the decoder section. * Memory allocation. * * Returns: * return zero if succesful */ Word32 D_MAIN_init(void **spd_state) { /* Decoder states */ Decoder_State *st; *spd_state = NULL; /* * Memory allocation for coder state. */ if((st = (Decoder_State*)malloc(sizeof(Decoder_State))) == NULL) { return(-1); } st->dtx_decSt = NULL; D_DTX_init(&st->dtx_decSt, D_ROM_isf); D_MAIN_reset((void *)st, 1); *spd_state = (void *)st; return(0); } /* * Decoder_close * * Parameters: * spd_state I: pointer to state structure * * Function: * Free coder memory. * * Returns: * void */ void D_MAIN_close(void **spd_state) { D_DTX_exit(&(((Decoder_State *)(*spd_state))->dtx_decSt)); free(*spd_state); return; } /* * Decoder_exe * * Parameters: * mode I: used mode * prms I: parameter vector * synth_out O: synthesis speech * spe_state B: state structure * frame_type I: received frame type * * Function: * Main decoder routine. * * Returns: * 0 if successful */ Word32 D_MAIN_decode(Word16 mode, Word16 prms[], Word16 synth16k[], void *spd_state, UWord8 frame_type) { Word32 code2[L_SUBFR]; /* algebraic codevector */ Word32 L_tmp, L_tmp2, L_gain_code, L_stab_fac; Word32 i, j, i_subfr, pit_flag; Word32 T0, T0_frac, T0_max, select, T0_min = 0; Word16 exc2[L_FRAME]; /* excitation vector */ Word16 Aq[NB_SUBFR * (M + 1)]; /* A(z) quantized for the 4 subframes */ Word16 code[L_SUBFR]; /* algebraic codevector */ Word16 excp[L_SUBFR]; /* excitation vector */ Word16 HfIsf[M16k]; Word16 ispnew[M]; /* immittance spectral pairs at 4nd sfr*/ Word16 isf[M]; /* ISF (frequency domain) at 4nd sfr */ Word16 isf_tmp[M]; /* ISF tmp */ Word16 ind[8]; /* quantization indices */ Word16 index, fac, voice_fac, max, Q_new = 0; Word16 gain_pit, gain_code, gain_code_lo, tmp; Word16 corr_gain = 0; UWord16 pit_sharp = 0; Word16 *exc; /* Excitation vector */ Word16 *p_Aq; /* ptr to A(z) for the 4 subframes */ Word16 *p_isf; /* prt to isf */ Decoder_State *st; /* Decoder states */ UWord8 newDTXState, bfi, unusable_frame; UWord8 vad_flag; st = (Decoder_State*)spd_state; /* find the new DTX state SPEECH OR DTX */ newDTXState = D_DTX_rx_handler(st->dtx_decSt, frame_type); if(newDTXState != SPEECH) { D_DTX_exe(st->dtx_decSt, exc2, newDTXState, isf, &prms); } /* SPEECH action state machine */ if((frame_type == RX_SPEECH_BAD) | (frame_type == RX_SPEECH_PROBABLY_DEGRADED)) { /* bfi for all index, bits are not usable */ bfi = 1; unusable_frame = 0; } else if((frame_type == RX_NO_DATA) | (frame_type == RX_SPEECH_LOST)) { /* bfi only for lsf, gains and pitch period */ bfi = 1; unusable_frame = 1; } else { bfi = 0; unusable_frame = 0; } if(bfi != 0) { st->mem_state = (UWord8)(st->mem_state + 1); if(st->mem_state > 6) { st->mem_state = 6; } } else { st->mem_state = (UWord8)(st->mem_state >> 1); } /* * If this frame is the first speech frame after CNI period, * set the BFH state machine to an appropriate state depending * on whether there was DTX muting before start of speech or not * If there was DTX muting, the first speech frame is muted. * If there was no DTX muting, the first speech frame is not * muted. The BFH state machine starts from state 5, however, to * keep the audible noise resulting from a SID frame which is * erroneously interpreted as a good speech frame as small as * possible (the decoder output in this case is quickly muted) */ if(st->dtx_decSt->mem_dtx_global_state == DTX) { st->mem_state = 5; st->mem_bfi = 0; } else if(st->dtx_decSt->mem_dtx_global_state == D_DTX_MUTE) { st->mem_state = 5; st->mem_bfi = 1; } if(newDTXState == SPEECH) { vad_flag = (UWord8)(*prms++); if(bfi == 0) { if(vad_flag == 0) { st->mem_vad_hist = (Word16)(st->mem_vad_hist + 1); if(st->mem_vad_hist > 32767) { st->mem_vad_hist = 32767; } } else { st->mem_vad_hist = 0; } } } /* * DTX-CNG */ if(newDTXState != SPEECH) /* CNG mode */ { /* * increase slightly energy of noise below 200 Hz * Convert ISFs to the cosine domain */ D_LPC_isf_isp_conversion(isf, ispnew, M); D_LPC_isp_a_conversion(ispnew, Aq, 1, M); memcpy(isf_tmp, st->mem_isf, M * sizeof(Word16)); for(i_subfr = 0; i_subfr < L_FRAME; i_subfr += L_SUBFR) { j = (i_subfr >> 6); for(i = 0; i < M; i++) { L_tmp = (isf_tmp[i] * (32767 - D_ROM_interpol_frac[j])) << 1; L_tmp = L_tmp + ((isf[i] * D_ROM_interpol_frac[j]) << 1); HfIsf[i] = (Word16)((L_tmp + 0x8000) >> 16); } D_UTIL_dec_synthesis(Aq, &exc2[i_subfr], 0, &synth16k[i_subfr * 5 /4], (Word16) 1, HfIsf, mode, newDTXState, bfi, st); } /* reset speech coder memories */ D_MAIN_reset(st, 0); memcpy(st->mem_isf, isf, M * sizeof(Word16)); st->mem_bfi = bfi; st->dtx_decSt->mem_dtx_global_state = (UWord8)newDTXState; return(0); } /* * ACELP */ exc = st->mem_exc + PIT_MAX + L_INTERPOL; /* Decode the ISFs */ if(mode <= MODE_7k) { ind[0] = *prms++; ind[1] = *prms++; ind[2] = *prms++; ind[3] = *prms++; ind[4] = *prms++; D_LPC_isf_2s3s_decode(ind, isf, st->mem_isf_q, st->mem_isf, st->mem_isf_buf, bfi); } else { ind[0] = *prms++; ind[1] = *prms++; ind[2] = *prms++; ind[3] = *prms++; ind[4] = *prms++; ind[5] = *prms++; ind[6] = *prms++; D_LPC_isf_2s5s_decode(ind, isf, st->mem_isf_q, st->mem_isf, st->mem_isf_buf, bfi); } /* Convert ISFs to the cosine domain */ D_LPC_isf_isp_conversion(isf, ispnew, M); if(st->mem_first_frame != 0) { st->mem_first_frame = 0; memcpy(st->mem_isp, ispnew, M * sizeof(Word16)); } /* Find the interpolated ISPs and convert to a[] for all subframes */ D_LPC_int_isp_find(st->mem_isp, ispnew, D_ROM_interpol_frac, Aq); /* update isp memory for the next frame */ memcpy(st->mem_isp, ispnew, M * sizeof(Word16)); /* Check stability on isf : distance between old isf and current isf */ L_tmp = 0; p_isf = st->mem_isf; for(i = 0; i < M - 1; i++) { tmp = (Word16)((isf[i] - p_isf[i])); L_tmp = L_tmp + (tmp * tmp); } if(L_tmp < 3276928) { L_tmp = L_tmp >> 7; L_tmp = (L_tmp * 26214) >> 15; /* tmp = L_tmp*0.8/256 */ L_tmp = 20480 - L_tmp; /* 1.25 - tmp */ L_stab_fac = L_tmp << 1; /* Q14 -> Q15 with saturation */ if(L_stab_fac > 0x7FFF) { L_stab_fac = 0x7FFF; } } else { L_stab_fac = 0x0; } memcpy(isf_tmp, st->mem_isf, M * sizeof(Word16)); memcpy(st->mem_isf, isf, M * sizeof(Word16)); /* * Loop for every subframe in the analysis frame * * The subframe size is L_SUBFR and the loop is repeated L_FRAME/L_SUBFR * times * - decode the pitch delay and filter mode * - decode algebraic code * - decode pitch and codebook gains * - find voicing factor and tilt of code for next subframe * - find the excitation and compute synthesis speech */ p_Aq = Aq; /* pointer to interpolated LPC parameters */ for(i_subfr = 0; i_subfr < L_FRAME; i_subfr += L_SUBFR) { pit_flag = i_subfr; if((i_subfr == (2 * L_SUBFR)) & (mode > MODE_7k)) { pit_flag = 0; } /* * - Decode pitch lag * Lag indeces received also in case of BFI, * so that the parameter pointer stays in sync. */ if(pit_flag == 0) { if(mode <= MODE_9k) { index = *prms++; if(index < ((PIT_FR1_8b - PIT_MIN) * 2)) { T0 = (PIT_MIN + (index >> 1)); T0_frac = (index - ((T0 - PIT_MIN) << 1)); T0_frac = (T0_frac << 1); } else { T0 = index + (PIT_FR1_8b - ((PIT_FR1_8b - PIT_MIN) * 2)); T0_frac = 0; } } else { index = *prms++; if(index < ((PIT_FR2 - PIT_MIN) * 4)) { T0 = PIT_MIN + (index >> 2); T0_frac = index - ((T0 - PIT_MIN) << 2); } else if(index < ((((PIT_FR2 - PIT_MIN) * 4) + ((PIT_FR1_9b - PIT_FR2) * 2)))) { index = (Word16)((index - ((PIT_FR2 - PIT_MIN) * 4))); T0 = PIT_FR2 + (index >> 1); T0_frac = index - ((T0 - PIT_FR2) << 1); T0_frac = T0_frac << 1; } else { T0 = index + (PIT_FR1_9b - ((PIT_FR2 - PIT_MIN) * 4) - ((PIT_FR1_9b - PIT_FR2) * 2)); T0_frac = 0; } } /* find T0_min and T0_max for subframe 2 and 4 */ T0_min = T0 - 8; if(T0_min < PIT_MIN) { T0_min = PIT_MIN; } T0_max = T0_min + 15; if(T0_max > PIT_MAX) { T0_max = PIT_MAX; T0_min = T0_max - 15; } } else { /* if subframe 2 or 4 */ if(mode <= MODE_9k) { index = *prms++; T0 = T0_min + (index >> 1); T0_frac = index - ((T0 - T0_min) << 1); T0_frac = T0_frac << 1; } else { index = *prms++; T0 = T0_min + (index >> 2); T0_frac = index - ((T0 - T0_min) << 2); } } /* check BFI after pitch lag decoding */ if(bfi != 0) /* if frame erasure */ { D_GAIN_lag_concealment(&(st->mem_gain[17]), st->mem_lag, &T0, &(st->mem_T0), &(st->mem_seed3), unusable_frame); T0_frac = 0; } /* * Find the pitch gain, the interpolation filter * and the adaptive codebook vector. */ D_GAIN_adaptive_codebook_excitation(&exc[i_subfr], T0, T0_frac); if(unusable_frame) { select = 1; } else { if(mode <= MODE_9k) { select = 0; } else { select = *prms++; } } if(select == 0) { /* find pitch excitation with lp filter */ for(i = 0; i < L_SUBFR; i++) { L_tmp = 2949 * exc[i - 1 + i_subfr]; L_tmp = L_tmp + (10486 * exc[i + i_subfr]); L_tmp = L_tmp + (2949 * exc[i + 1 + i_subfr]); code[i] = (Word16)((L_tmp + 0x2000) >> 14); } memcpy(&exc[i_subfr], code, L_SUBFR * sizeof(Word16)); } /* * Decode innovative codebook. * Add the fixed-gain pitch contribution to code[]. */ if(unusable_frame != 0) { /* the innovative code doesn't need to be scaled (see Q_gain2) */ for(i = 0; i < L_SUBFR; i++) { code[i] = (Word16)(D_UTIL_random(&(st->mem_seed)) >> 3); } } else if(mode <= MODE_7k) { ind[0] = *prms++; D_ACELP_decode_2t(ind[0], code); } else if(mode <= MODE_9k) { memcpy(ind, prms, 4 * sizeof(Word16)); prms += 4; D_ACELP_decode_4t(ind, 20, code); } else if(mode <= MODE_12k) { memcpy(ind, prms, 4 * sizeof(Word16)); prms += 4; D_ACELP_decode_4t(ind, 36, code); } else if(mode <= MODE_14k) { memcpy(ind, prms, 4 * sizeof(Word16)); prms += 4; D_ACELP_decode_4t(ind, 44, code); } else if(mode <= MODE_16k) { memcpy(ind, prms, 4 * sizeof(Word16)); prms += 4; D_ACELP_decode_4t(ind, 52, code); } else if(mode <= MODE_18k) { memcpy(ind, prms, 8 * sizeof(Word16)); prms += 8; D_ACELP_decode_4t(ind, 64, code); } else if(mode <= MODE_20k) { memcpy(ind, prms, 8 * sizeof(Word16)); prms += 8; D_ACELP_decode_4t(ind, 72, code); } else { memcpy(ind, prms, 8 * sizeof(Word16)); prms += 8; D_ACELP_decode_4t(ind, 88, code); } tmp = 0; D_UTIL_preemph(code, st->mem_tilt_code, L_SUBFR, &tmp); L_tmp = T0; if(T0_frac > 2) { L_tmp = L_tmp + 1; } D_GAIN_pitch_sharpening(code, L_tmp, PIT_SHARP); /* * Decode codebooks gains. */ index = *prms++; /* codebook gain index */ if(mode <= MODE_9k) { D_GAIN_decode(index, 6, code, &gain_pit, &L_gain_code, bfi, st->mem_bfi, st->mem_state, unusable_frame, st->mem_vad_hist, st->mem_gain); } else { D_GAIN_decode(index, 7, code, &gain_pit, &L_gain_code, bfi, st->mem_bfi, st->mem_state, unusable_frame, st->mem_vad_hist, st->mem_gain); } /* find best scaling to perform on excitation (Q_new) */ tmp = st->mem_subfr_q[0]; for(i = 1; i < 4; i++) { if(st->mem_subfr_q[i] < tmp) { tmp = st->mem_subfr_q[i]; } } /* limit scaling (Q_new) to Q_MAX */ if(tmp > Q_MAX) { tmp = Q_MAX; } Q_new = 0; L_tmp = L_gain_code; /* L_gain_code in Q16 */ while((L_tmp < 0x08000000L) && (Q_new < tmp)) { L_tmp = (L_tmp << 1); Q_new = (Word16)((Q_new + 1)); } if(L_tmp < 0x7FFF7FFF) { gain_code = (Word16)((L_tmp + 0x8000) >> 16); /* scaled gain_code with Qnew */ } else { gain_code = 32767; } if(Q_new > st->mem_q) { D_UTIL_signal_up_scale(exc + i_subfr - (PIT_MAX + L_INTERPOL), PIT_MAX + L_INTERPOL + L_SUBFR, (Word16)(Q_new - st->mem_q)); } else { D_UTIL_signal_down_scale(exc + i_subfr - (PIT_MAX + L_INTERPOL), PIT_MAX + L_INTERPOL + L_SUBFR, (Word16)(st->mem_q - Q_new)); } st->mem_q = Q_new; /* * Update parameters for the next subframe. * - tilt of code: 0.0 (unvoiced) to 0.5 (voiced) */ if(bfi == 0) { /* LTP-Lag history update */ for(i = 4; i > 0; i--) { st->mem_lag[i] = st->mem_lag[i - 1]; } st->mem_lag[0] = (Word16)T0; st->mem_T0 = (Word16)T0; st->mem_T0_frac = 0; /* Remove fraction in case of BFI */ } /* find voice factor in Q15 (1=voiced, -1=unvoiced) */ memcpy(exc2, &exc[i_subfr], L_SUBFR * sizeof(Word16)); D_UTIL_signal_down_scale(exc2, L_SUBFR, 3); /* post processing of excitation elements */ if(mode <= MODE_9k) { pit_sharp = (Word16)(gain_pit << 1); if(pit_sharp > 16384) { if(pit_sharp > 32767) { pit_sharp = 32767; } for(i = 0; i < L_SUBFR; i++) { L_tmp = (exc2[i] * pit_sharp) >> 15; L_tmp = L_tmp * gain_pit; excp[i] = (Word16)((L_tmp + 0x8000) >> 16); } } } voice_fac = D_GAIN_find_voice_factor(exc2, -3, gain_pit, code, gain_code, L_SUBFR); /* tilt of code for next subframe: 0.5=voiced, 0=unvoiced */ st->mem_tilt_code = (Word16)((voice_fac >> 2) + 8192); /* * Find the total excitation. * Find synthesis speech corresponding to exc[]. * Find maximum value of excitation for next scaling */ memcpy(exc2, &exc[i_subfr], L_SUBFR * sizeof(Word16)); max = 1; for(i = 0; i < L_SUBFR; i++) { L_tmp = (code[i] * gain_code) << 5; L_tmp = L_tmp + (exc[i + i_subfr] * gain_pit); L_tmp = (L_tmp + 0x2000) >> 14; if((L_tmp > MIN_16) & (L_tmp < 32768)) { exc[i + i_subfr] = (Word16)L_tmp; tmp = (Word16)(abs(L_tmp)); if(tmp > max) { max = tmp; } } else if(L_tmp > MAX_16) { exc[i + i_subfr] = MAX_16; max = MAX_16; } else { exc[i + i_subfr] = MIN_16; max = MAX_16; } } /* tmp = scaling possible according to max value of excitation */ tmp = (Word16)((D_UTIL_norm_s(max) + Q_new) - 1); st->mem_subfr_q[3] = st->mem_subfr_q[2]; st->mem_subfr_q[2] = st->mem_subfr_q[1]; st->mem_subfr_q[1] = st->mem_subfr_q[0]; st->mem_subfr_q[0] = tmp; /* * phase dispersion to enhance noise in low bit rate */ /* L_gain_code in Q16 */ D_UTIL_l_extract(L_gain_code, &gain_code, &gain_code_lo); if(mode <= MODE_7k) { j = 0; /* high dispersion for rate <= 7.5 kbit/s */ } else if(mode <= MODE_9k) { j = 1; /* low dispersion for rate <= 9.6 kbit/s */ } else { j = 2; /* no dispersion for rate > 9.6 kbit/s */ } D_ACELP_phase_dispersion(gain_code, gain_pit, code, (Word16)j, st->mem_ph_disp); /* * noise enhancer * - Enhance excitation on noise. (modify gain of code) * If signal is noisy and LPC filter is stable, move gain * of code 1.5 dB toward gain of code threshold. * This decrease by 3 dB noise energy variation. */ L_tmp = 16384 - (voice_fac >> 1); /* 1=unvoiced, 0=voiced */ fac = (Word16)((L_stab_fac * L_tmp) >> 15); L_tmp = L_gain_code; if(L_tmp < st->mem_gc_thres) { L_tmp = (L_tmp + D_UTIL_mpy_32_16(gain_code, gain_code_lo, 6226)); if(L_tmp > st->mem_gc_thres) { L_tmp = st->mem_gc_thres; } } else { L_tmp = D_UTIL_mpy_32_16(gain_code, gain_code_lo, 27536); if(L_tmp < st->mem_gc_thres) { L_tmp = st->mem_gc_thres; } } st->mem_gc_thres = L_tmp; L_gain_code = D_UTIL_mpy_32_16(gain_code, gain_code_lo, (Word16)(32767 - fac)); D_UTIL_l_extract(L_tmp, &gain_code, &gain_code_lo); L_gain_code = L_gain_code + D_UTIL_mpy_32_16(gain_code, gain_code_lo, fac); /* * pitch enhancer * - Enhance excitation on voice. (HP filtering of code) * On voiced signal, filtering of code by a smooth fir HP * filter to decrease energy of code in low frequency. */ L_tmp2 = (voice_fac >> 3) + 4096; /* 0.25=voiced, 0=unvoiced */ L_tmp = (code[0] << 15) - (code[1] * L_tmp2); code2[0] = (L_tmp + 0x4000) >> 15; for(i = 1; i < L_SUBFR - 1; i++) { L_tmp = code[i] << 15; L_tmp = L_tmp - (code[i + 1] * L_tmp2); L_tmp = L_tmp - (code[i - 1] * L_tmp2); code2[i] = (L_tmp + 0x4000) >> 15; } L_tmp = code[L_SUBFR - 1] << 15; L_tmp = L_tmp - (code[L_SUBFR - 2] * L_tmp2); code2[L_SUBFR - 1] = (L_tmp + 0x4000) >> 15; /* build excitation */ gain_code = (Word16)(((L_gain_code << Q_new) + 0x8000) >> 16); for(i = 0; i < L_SUBFR; i++) { L_tmp = (code2[i] * gain_code) << 5; L_tmp = L_tmp + (exc2[i] * gain_pit); L_tmp = (L_tmp + 0x2000) >> 14; exc2[i] = D_UTIL_saturate(L_tmp); } if(mode <= MODE_9k) { if(pit_sharp > 16384) { for(i = 0; i < L_SUBFR; i++) { L_tmp = (excp[i] + exc2[i]); excp[i] = D_UTIL_saturate(L_tmp); } D_GAIN_adaptive_control(exc2, excp, L_SUBFR); memcpy(exc2, excp, L_SUBFR * sizeof(Word16)); } } if(mode <= MODE_7k) { j = (i_subfr >> 6); for(i = 0; i < M; i++) { L_tmp = isf_tmp[i] * (32767 - D_ROM_interpol_frac[j]); L_tmp = L_tmp + (isf[i] * D_ROM_interpol_frac[j]); HfIsf[i] = (Word16)((L_tmp + 0x4000) >> 15); } } else { memset(st->mem_syn_hf, 0, (M16k - M) * sizeof(Word16)); } if(mode >= MODE_24k) { corr_gain = *prms++; D_UTIL_dec_synthesis(p_Aq, exc2, Q_new, &synth16k[i_subfr * 5 / 4], corr_gain, HfIsf, mode, newDTXState, bfi, st); } else { D_UTIL_dec_synthesis(p_Aq, exc2, Q_new, &synth16k[i_subfr * 5 / 4], 0, HfIsf, mode, newDTXState, bfi, st); } p_Aq += (M + 1); /* interpolated LPC parameters for next subframe */ } /* * Update signal for next frame * -> save past of exc[] * -> save pitch parameters. */ memmove(st->mem_exc, &st->mem_exc[L_FRAME], (PIT_MAX + L_INTERPOL) * sizeof(Word16)); D_UTIL_signal_down_scale(exc, L_FRAME, Q_new); D_DTX_activity_update(st->dtx_decSt, isf, exc); st->dtx_decSt->mem_dtx_global_state = (UWord8)newDTXState; st->mem_bfi = bfi; return(0); }