FreeCalypso > hg > gsm-codec-lib
view libtwamr/vad1.c @ 543:53d3f48af107
libgsmefr is now at version 1.2.0
author | Mychaela Falconia <falcon@freecalypso.org> |
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date | Sun, 29 Sep 2024 02:41:28 +0000 |
parents | 8847c1740e78 |
children |
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/* ***************************************************************************** **-------------------------------------------------------------------------** ** ** ** GSM AMR-NB speech codec R98 Version 7.6.0 December 12, 2001 ** ** R99 Version 3.3.0 ** ** REL-4 Version 4.1.0 ** ** ** **-------------------------------------------------------------------------** ***************************************************************************** * * File : vad1.c * Purpose : Voice Activity Detection (VAD) for AMR (option 1) * ***************************************************************************** */ /* ***************************************************************************** * MODULE INCLUDE FILE AND VERSION ID ***************************************************************************** */ #include "namespace.h" #include "vad1.h" /* ***************************************************************************** * INCLUDE FILES ***************************************************************************** */ #include "typedef.h" #include "basic_op.h" #include "no_count.h" #include "oper_32b.h" #include "cnst_vad.h" /* ***************************************************************************** * LOCAL VARIABLES AND TABLES ***************************************************************************** */ /* ******************************************************************************** * PRIVATE PROGRAM CODE ******************************************************************************** */ /**************************************************************************** * * Function : first_filter_stage * Purpose : Scale input down by one bit. Calculate 5th order * half-band lowpass/highpass filter pair with * decimation. * ***************************************************************************/ static void first_filter_stage(Word16 in[], /* i : input signal */ Word16 out[], /* o : output values, every other */ /* output is low-pass part and */ /* other is high-pass part every */ Word16 data[] /* i/o : filter memory */ ) { Word16 temp0, temp1, temp2, temp3, i; Word16 data0, data1; data0 = data[0]; move16 (); data1 = data[1]; move16 (); for (i = 0; i < FRAME_LEN/4; i++) { temp0 = sub(shr(in[4*i+0], 2), mult(COEFF5_1, data0)); temp1 = add(data0, mult(COEFF5_1, temp0)); temp3 = sub(shr(in[4*i+1], 2), mult(COEFF5_2, data1)); temp2 = add(data1, mult(COEFF5_2, temp3)); out[4*i+0] = add(temp1, temp2); move16 (); out[4*i+1] = sub(temp1, temp2); move16 (); data0 = sub(shr(in[4*i+2], 2), mult(COEFF5_1, temp0)); temp1 = add(temp0, mult(COEFF5_1, data0)); data1 = sub(shr(in[4*i+3], 2), mult(COEFF5_2, temp3)); temp2 = add(temp3, mult(COEFF5_2, data1)); out[4*i+2] = add(temp1, temp2); move16 (); out[4*i+3] = sub(temp1, temp2); move16 (); } data[0] = data0; move16 (); data[1] = data1; move16 (); } /**************************************************************************** * * Function : filter5 * Purpose : Fifth-order half-band lowpass/highpass filter pair with * decimation. * ***************************************************************************/ static void filter5(Word16 *in0, /* i/o : input values; output low-pass part */ Word16 *in1, /* i/o : input values; output high-pass part */ Word16 data[] /* i/o : updated filter memory */ ) { Word16 temp0, temp1, temp2; temp0 = sub(*in0, mult(COEFF5_1, data[0])); temp1 = add(data[0], mult(COEFF5_1, temp0)); data[0] = temp0; move16 (); temp0 = sub(*in1, mult(COEFF5_2, data[1])); temp2 = add(data[1], mult(COEFF5_2, temp0)); data[1] = temp0; move16 (); *in0 = shr(add(temp1, temp2), 1); move16 (); *in1 = shr(sub(temp1, temp2), 1); move16 (); } /**************************************************************************** * * Function : filter3 * Purpose : Third-order half-band lowpass/highpass filter pair with * decimation. * Return value : * ***************************************************************************/ static void filter3(Word16 *in0, /* i/o : input values; output low-pass part */ Word16 *in1, /* i/o : input values; output high-pass part */ Word16 *data /* i/o : updated filter memory */ ) { Word16 temp1, temp2; temp1 = sub(*in1, mult(COEFF3, *data)); temp2 = add(*data, mult(COEFF3, temp1)); *data = temp1; move16 (); *in1 = shr(sub(*in0, temp2), 1); move16 (); *in0 = shr(add(*in0, temp2), 1); move16 (); } /**************************************************************************** * * Function : level_calculation * Purpose : Calculate signal level in a sub-band. Level is calculated * by summing absolute values of the input data. * Return value : signal level * ***************************************************************************/ static Word16 level_calculation( Word16 data[], /* i : signal buffer */ Word16 *sub_level, /* i : level calculate at the end of the previous frame */ /* o : level of signal calculated from the last */ /* (count2 - count1) samples */ Word16 count1, /* i : number of samples to be counted */ Word16 count2, /* i : number of samples to be counted */ Word16 ind_m, /* i : step size for the index of the data buffer */ Word16 ind_a, /* i : starting index of the data buffer */ Word16 scale /* i : scaling for the level calculation */ ) { Word32 l_temp1, l_temp2; Word16 level, i; l_temp1 = 0L; move32 (); for (i = count1; i < count2; i++) { l_temp1 = L_mac(l_temp1, 1, abs_s(data[ind_m*i+ind_a])); } l_temp2 = L_add(l_temp1, L_shl(*sub_level, sub(16, scale))); *sub_level = extract_h(L_shl(l_temp1, scale)); for (i = 0; i < count1; i++) { l_temp2 = L_mac(l_temp2, 1, abs_s(data[ind_m*i+ind_a])); } level = extract_h(L_shl(l_temp2, scale)); return level; } /**************************************************************************** * * Function : filter_bank * Purpose : Divides input signal into 9-bands and calculas level of * the signal in each band * ***************************************************************************/ static void filter_bank(vadState1 *st, /* i/o : State struct */ Word16 in[], /* i : input frame */ Word16 level[] /* 0 : signal levels at each band */ ) { Word16 i; Word16 tmp_buf[FRAME_LEN]; /* calculate the filter bank */ first_filter_stage(in, tmp_buf, st->a_data5[0]); for (i = 0; i < FRAME_LEN/4; i++) { filter5(&tmp_buf[4*i], &tmp_buf[4*i+2], st->a_data5[1]); filter5(&tmp_buf[4*i+1], &tmp_buf[4*i+3], st->a_data5[2]); } for (i = 0; i < FRAME_LEN/8; i++) { filter3(&tmp_buf[8*i+0], &tmp_buf[8*i+4], &st->a_data3[0]); filter3(&tmp_buf[8*i+2], &tmp_buf[8*i+6], &st->a_data3[1]); filter3(&tmp_buf[8*i+3], &tmp_buf[8*i+7], &st->a_data3[4]); } for (i = 0; i < FRAME_LEN/16; i++) { filter3(&tmp_buf[16*i+0], &tmp_buf[16*i+8], &st->a_data3[2]); filter3(&tmp_buf[16*i+4], &tmp_buf[16*i+12], &st->a_data3[3]); } /* calculate levels in each frequency band */ /* 3000 - 4000 Hz*/ level[8] = level_calculation(tmp_buf, &st->sub_level[8], FRAME_LEN/4-8, FRAME_LEN/4, 4, 1, 15); move16 (); /* 2500 - 3000 Hz*/ level[7] = level_calculation(tmp_buf, &st->sub_level[7], FRAME_LEN/8-4, FRAME_LEN/8, 8, 7, 16); move16 (); /* 2000 - 2500 Hz*/ level[6] = level_calculation(tmp_buf, &st->sub_level[6], FRAME_LEN/8-4, FRAME_LEN/8, 8, 3, 16); move16 (); /* 1500 - 2000 Hz*/ level[5] = level_calculation(tmp_buf, &st->sub_level[5], FRAME_LEN/8-4, FRAME_LEN/8, 8, 2, 16); move16 (); /* 1000 - 1500 Hz*/ level[4] = level_calculation(tmp_buf, &st->sub_level[4], FRAME_LEN/8-4, FRAME_LEN/8, 8, 6, 16); move16 (); /* 750 - 1000 Hz*/ level[3] = level_calculation(tmp_buf, &st->sub_level[3], FRAME_LEN/16-2, FRAME_LEN/16, 16, 4, 16); move16 (); /* 500 - 750 Hz*/ level[2] = level_calculation(tmp_buf, &st->sub_level[2], FRAME_LEN/16-2, FRAME_LEN/16, 16, 12, 16); move16 (); /* 250 - 500 Hz*/ level[1] = level_calculation(tmp_buf, &st->sub_level[1], FRAME_LEN/16-2, FRAME_LEN/16, 16, 8, 16); move16 (); /* 0 - 250 Hz*/ level[0] = level_calculation(tmp_buf, &st->sub_level[0], FRAME_LEN/16-2, FRAME_LEN/16, 16, 0, 16); move16 (); } /**************************************************************************** * * Function : update_cntrl * Purpose : Control update of the background noise estimate. * Inputs : pitch: flags for pitch detection * stat_count: stationary counter * tone: flags indicating presence of a tone * complex: flags for complex detection * vadreg: intermediate VAD flags * Output : stat_count: stationary counter * ***************************************************************************/ static void update_cntrl(vadState1 *st, /* i/o : State struct */ Word16 level[] /* i : sub-band levels of the input frame */ ) { Word16 i, temp, stat_rat, exp; Word16 num, denom; Word16 alpha; /* handle highband complex signal input separately */ /* if ther has been highband correlation for some time */ /* make sure that the VAD update speed is low for a while */ test (); if (st->complex_warning != 0) { test (); if (sub(st->stat_count, CAD_MIN_STAT_COUNT) < 0) { st->stat_count = CAD_MIN_STAT_COUNT; move16 (); } } /* NB stat_count is allowed to be decreased by one below again */ /* deadlock in speech is not possible unless the signal is very */ /* complex and need a high rate */ /* if fullband pitch or tone have been detected for a while, initialize stat_count */ logic16 (); test (); logic16 (); test (); if ((sub((st->pitch & 0x6000), 0x6000) == 0) || (sub((st->tone & 0x7c00), 0x7c00) == 0)) { st->stat_count = STAT_COUNT; move16 (); } else { /* if 8 last vad-decisions have been "0", reinitialize stat_count */ logic16 (); test (); if ((st->vadreg & 0x7f80) == 0) { st->stat_count = STAT_COUNT; move16 (); } else { stat_rat = 0; move16 (); for (i = 0; i < COMPLEN; i++) { test (); if (sub(level[i], st->ave_level[i]) > 0) { num = level[i]; move16 (); denom = st->ave_level[i]; move16 (); } else { num = st->ave_level[i]; move16 (); denom = level[i]; move16 (); } /* Limit nimimum value of num and denom to STAT_THR_LEVEL */ test (); if (sub(num, STAT_THR_LEVEL) < 0) { num = STAT_THR_LEVEL; move16 (); } test (); if (sub(denom, STAT_THR_LEVEL) < 0) { denom = STAT_THR_LEVEL; move16 (); } exp = norm_s(denom); denom = shl(denom, exp); /* stat_rat = num/denom * 64 */ temp = div_s(shr(num, 1), denom); stat_rat = add(stat_rat, shr(temp, sub(8, exp))); } /* compare stat_rat with a threshold and update stat_count */ test (); if (sub(stat_rat, STAT_THR) > 0) { st->stat_count = STAT_COUNT; move16 (); } else { logic16 ();test (); if ((st->vadreg & 0x4000) != 0) { test (); if (st->stat_count != 0) { st->stat_count = sub(st->stat_count, 1); move16 (); } } } } } /* Update average amplitude estimate for stationarity estimation */ alpha = ALPHA4; move16 (); test (); if (sub(st->stat_count, STAT_COUNT) == 0) { alpha = 32767; move16 (); } else if ((st->vadreg & 0x4000) == 0) { logic16 (); test (); alpha = ALPHA5; move16 (); } for (i = 0; i < COMPLEN; i++) { st->ave_level[i] = add(st->ave_level[i], mult_r(alpha, sub(level[i], st->ave_level[i]))); move16 (); } } /**************************************************************************** * * Function : hangover_addition * Purpose : Add hangover for complex signal or after speech bursts * Inputs : burst_count: counter for the length of speech bursts * hang_count: hangover counter * vadreg: intermediate VAD decision * Outputs : burst_count: counter for the length of speech bursts * hang_count: hangover counter * Return value : VAD_flag indicating final VAD decision * ***************************************************************************/ static Word16 hangover_addition( vadState1 *st, /* i/o : State struct */ Word16 noise_level, /* i : average level of the noise */ /* estimates */ Word16 low_power /* i : flag power of the input frame */ ) { Word16 hang_len, burst_len; /* Calculate burst_len and hang_len burst_len: number of consecutive intermediate vad flags with "1"-decision required for hangover addition hang_len: length of the hangover */ test (); if (sub(noise_level, HANG_NOISE_THR) > 0) { burst_len = BURST_LEN_HIGH_NOISE; move16 (); hang_len = HANG_LEN_HIGH_NOISE; move16 (); } else { burst_len = BURST_LEN_LOW_NOISE; move16 (); hang_len = HANG_LEN_LOW_NOISE; move16 (); } /* if the input power (pow_sum) is lower than a threshold, clear counters and set VAD_flag to "0" "fast exit" */ test (); if (low_power != 0) { st->burst_count = 0; move16 (); st->hang_count = 0; move16 (); st->complex_hang_count = 0; move16 (); st->complex_hang_timer = 0; move16 (); return 0; } test (); if (sub(st->complex_hang_timer, CVAD_HANG_LIMIT) > 0) { test (); if (sub(st->complex_hang_count, CVAD_HANG_LENGTH) < 0) { st->complex_hang_count = CVAD_HANG_LENGTH; move16 (); } } /* long time very complex signal override VAD output function */ test (); if (st->complex_hang_count != 0) { st->burst_count = BURST_LEN_HIGH_NOISE; move16 (); st->complex_hang_count = sub(st->complex_hang_count, 1); move16 (); return 1; } else { /* let hp_corr work in from a noise_period indicated by the VAD */ test (); test (); logic16 (); if (((st->vadreg & 0x3ff0) == 0) && (sub(st->corr_hp_fast, CVAD_THRESH_IN_NOISE) > 0)) { return 1; } } /* update the counters (hang_count, burst_count) */ logic16 (); test (); if ((st->vadreg & 0x4000) != 0) { st->burst_count = add(st->burst_count, 1); move16 (); test (); if (sub(st->burst_count, burst_len) >= 0) { st->hang_count = hang_len; move16 (); } return 1; } else { st->burst_count = 0; move16 (); test (); if (st->hang_count > 0) { st->hang_count = sub(st->hang_count, 1); move16 (); return 1; } } return 0; } /**************************************************************************** * * Function : noise_estimate_update * Purpose : Update of background noise estimate * Inputs : bckr_est: background noise estimate * pitch: flags for pitch detection * stat_count: stationary counter * Outputs : bckr_est: background noise estimate * ***************************************************************************/ static void noise_estimate_update( vadState1 *st, /* i/o : State struct */ Word16 level[] /* i : sub-band levels of the input frame */ ) { Word16 i, alpha_up, alpha_down, bckr_add; /* Control update of bckr_est[] */ update_cntrl(st, level); /* Choose update speed */ bckr_add = 2; move16 (); logic16 (); test (); logic16 (); test (); test (); if (((0x7800 & st->vadreg) == 0) && ((st->pitch & 0x7800) == 0) && (st->complex_hang_count == 0)) { alpha_up = ALPHA_UP1; move16 (); alpha_down = ALPHA_DOWN1; move16 (); } else { test (); test (); if ((st->stat_count == 0) && (st->complex_hang_count == 0)) { alpha_up = ALPHA_UP2; move16 (); alpha_down = ALPHA_DOWN2; move16 (); } else { alpha_up = 0; move16 (); alpha_down = ALPHA3; move16 (); bckr_add = 0; move16 (); } } /* Update noise estimate (bckr_est) */ for (i = 0; i < COMPLEN; i++) { Word16 temp; temp = sub(st->old_level[i], st->bckr_est[i]); test (); if (temp < 0) { /* update downwards*/ st->bckr_est[i] = add(-2, add(st->bckr_est[i], mult_r(alpha_down, temp))); move16 (); /* limit minimum value of the noise estimate to NOISE_MIN */ test (); if (sub(st->bckr_est[i], NOISE_MIN) < 0) { st->bckr_est[i] = NOISE_MIN; move16 (); } } else { /* update upwards */ st->bckr_est[i] = add(bckr_add, add(st->bckr_est[i], mult_r(alpha_up, temp))); move16 (); /* limit maximum value of the noise estimate to NOISE_MAX */ test (); if (sub(st->bckr_est[i], NOISE_MAX) > 0) { st->bckr_est[i] = NOISE_MAX; move16 (); } } } /* Update signal levels of the previous frame (old_level) */ for(i = 0; i < COMPLEN; i++) { st->old_level[i] = level[i]; move16 (); } } /**************************************************************************** * * Function : complex_estimate_adapt * Purpose : Update/adapt of complex signal estimate * Inputs : low_power: low signal power flag * Outputs : st->corr_hp_fast: long term complex signal estimate * ***************************************************************************/ static void complex_estimate_adapt( vadState1 *st, /* i/o : VAD state struct */ Word16 low_power /* i : very low level flag of the input frame */ ) { Word16 alpha; /* Q15 */ Word32 L_tmp; /* Q31 */ /* adapt speed on own state */ test (); if (sub(st->best_corr_hp, st->corr_hp_fast) < 0) /* decrease */ { test (); if (sub(st->corr_hp_fast, CVAD_THRESH_ADAPT_HIGH) < 0) { /* low state */ alpha = CVAD_ADAPT_FAST; move16(); } else { /* high state */ alpha = CVAD_ADAPT_REALLY_FAST; move16(); } } else /* increase */ { test (); if (sub(st->corr_hp_fast, CVAD_THRESH_ADAPT_HIGH) < 0) { alpha = CVAD_ADAPT_FAST; move16(); } else { alpha = CVAD_ADAPT_SLOW; move16(); } } L_tmp = L_deposit_h(st->corr_hp_fast); L_tmp = L_msu(L_tmp, alpha, st->corr_hp_fast); L_tmp = L_mac(L_tmp, alpha, st->best_corr_hp); st->corr_hp_fast = round(L_tmp); /* Q15 */ move16(); test (); if (sub(st->corr_hp_fast, CVAD_MIN_CORR) < 0) { st->corr_hp_fast = CVAD_MIN_CORR; move16(); } test (); if (low_power != 0) { st->corr_hp_fast = CVAD_MIN_CORR; move16(); } } /**************************************************************************** * * Function : complex_vad * Purpose : complex background decision * Return value : the complex background decision * ***************************************************************************/ static Word16 complex_vad(vadState1 *st, /* i/o : VAD state struct */ Word16 low_power /* i : flag power of the input frame */ ) { st->complex_high = shr(st->complex_high, 1); move16 (); st->complex_low = shr(st->complex_low, 1); move16 (); test (); if (low_power == 0) { test (); if (sub(st->corr_hp_fast, CVAD_THRESH_ADAPT_HIGH) > 0) { st->complex_high = st->complex_high | 0x4000; logic16 (); move16 (); } test (); if (sub(st->corr_hp_fast, CVAD_THRESH_ADAPT_LOW) > 0 ) { st->complex_low = st->complex_low | 0x4000; logic16 (); move16 (); } } test (); if (sub(st->corr_hp_fast, CVAD_THRESH_HANG) > 0) { st->complex_hang_timer = add(st->complex_hang_timer, 1); move16 (); } else { st->complex_hang_timer = 0; move16 (); } test (); logic16 (); test (); logic16 (); return ((sub((st->complex_high & 0x7f80), 0x7f80) == 0) || (sub((st->complex_low & 0x7fff), 0x7fff) == 0)); } /**************************************************************************** * * Function : vad_decision * Purpose : Calculates VAD_flag * Inputs : bckr_est: background noise estimate * vadreg: intermediate VAD flags * Outputs : noise_level: average level of the noise estimates * vadreg: intermediate VAD flags * Return value : VAD_flag * ***************************************************************************/ static Word16 vad_decision( vadState1 *st, /* i/o : State struct */ Word16 level[COMPLEN], /* i : sub-band levels of the input frame */ Word32 pow_sum /* i : power of the input frame */ ) { Word16 i; Word16 snr_sum; Word32 L_temp; Word16 vad_thr, temp, noise_level; Word16 low_power_flag; /* Calculate squared sum of the input levels (level) divided by the background noise components (bckr_est). */ L_temp = 0; move32(); for (i = 0; i < COMPLEN; i++) { Word16 exp; exp = norm_s(st->bckr_est[i]); temp = shl(st->bckr_est[i], exp); temp = div_s(shr(level[i], 1), temp); temp = shl(temp, sub(exp, UNIRSHFT-1)); L_temp = L_mac(L_temp, temp, temp); } snr_sum = extract_h(L_shl(L_temp, 6)); snr_sum = mult(snr_sum, INV_COMPLEN); /* Calculate average level of estimated background noise */ L_temp = 0; move32(); for (i = 0; i < COMPLEN; i++) { L_temp = L_add(L_temp, st->bckr_est[i]); } noise_level = extract_h(L_shl(L_temp, 13)); /* Calculate VAD threshold */ vad_thr = add(mult(VAD_SLOPE, sub(noise_level, VAD_P1)), VAD_THR_HIGH); test (); if (sub(vad_thr, VAD_THR_LOW) < 0) { vad_thr = VAD_THR_LOW; move16 (); } /* Shift VAD decision register */ st->vadreg = shr(st->vadreg, 1); move16 (); /* Make intermediate VAD decision */ test (); if (sub(snr_sum, vad_thr) > 0) { st->vadreg = st->vadreg | 0x4000; logic16 (); move16 (); } /* primary vad decsion made */ /* check if the input power (pow_sum) is lower than a threshold" */ test (); if (L_sub(pow_sum, VAD_POW_LOW) < 0) { low_power_flag = 1; move16 (); } else { low_power_flag = 0; move16 (); } /* update complex signal estimate st->corr_hp_fast and hangover reset timer using */ /* low_power_flag and corr_hp_fast and various adaptation speeds */ complex_estimate_adapt(st, low_power_flag); /* check multiple thresholds of the st->corr_hp_fast value */ st->complex_warning = complex_vad(st, low_power_flag); move16(); /* Update speech subband vad background noise estimates */ noise_estimate_update(st, level); /* Add speech and complex hangover and return speech VAD_flag */ /* long term complex hangover may be added */ st->speech_vad_decision = hangover_addition(st, noise_level, low_power_flag); move16 (); return (st->speech_vad_decision); } /* ***************************************************************************** * PUBLIC PROGRAM CODE ***************************************************************************** */ /************************************************************************* * * Function: vad1_reset * Purpose: Initializes state memory to zero * ************************************************************************** */ void vad1_reset (vadState1 *state) { Word16 i, j; /* Initialize pitch detection variables */ state->oldlag_count = 0; state->oldlag = 0; state->pitch = 0; state->tone = 0; state->complex_high = 0; state->complex_low = 0; state->complex_hang_timer = 0; state->vadreg = 0; state->stat_count = 0; state->burst_count = 0; state->hang_count = 0; state->complex_hang_count = 0; /* initialize memory used by the filter bank */ for (i = 0; i < 3; i++) { for (j = 0; j < 2; j++) { state->a_data5[i][j] = 0; } } for (i = 0; i < 5; i++) { state->a_data3[i] = 0; } /* initialize the rest of the memory */ for (i = 0; i < COMPLEN; i++) { state->bckr_est[i] = NOISE_INIT; state->old_level[i] = NOISE_INIT; state->ave_level[i] = NOISE_INIT; state->sub_level[i] = 0; } state->best_corr_hp = CVAD_LOWPOW_RESET; state->speech_vad_decision = 0; state->complex_warning = 0; state->sp_burst_count = 0; state->corr_hp_fast = CVAD_LOWPOW_RESET; } /**************************************************************************** * * Function : vad_complex_detection_update * Purpose : update vad->bestCorr_hp complex signal feature state * ***************************************************************************/ void vad_complex_detection_update (vadState1 *st, /* i/o : State struct */ Word16 best_corr_hp /* i : best Corr */ ) { st->best_corr_hp = best_corr_hp; move16(); } /**************************************************************************** * * Function : vad_tone_detection * Purpose : Set tone flag if pitch gain is high. This is used to detect * signaling tones and other signals with high pitch gain. * Inputs : tone: flags indicating presence of a tone * Outputs : tone: flags indicating presence of a tone * ***************************************************************************/ void vad_tone_detection (vadState1 *st, /* i/o : State struct */ Word32 t0, /* i : autocorrelation maxima */ Word32 t1 /* i : energy */ ) { Word16 temp; /* if (t0 > TONE_THR * t1) set tone flag */ temp = round(t1); test (); test (); if ((temp > 0) && (L_msu(t0, temp, TONE_THR) > 0)) { st->tone = st->tone | 0x4000; logic16 (); move16 (); } } /**************************************************************************** * * Function : vad_tone_detection_update * Purpose : Update the tone flag register. Tone flags are shifted right * by one bit. This function should be called from the speech * encoder before call to Vad_tone_detection() function. * ***************************************************************************/ void vad_tone_detection_update ( vadState1 *st, /* i/o : State struct */ Word16 one_lag_per_frame /* i : 1 if one open-loop lag is calculated per each frame, otherwise 0 */ ) { /* Shift tone flags right by one bit */ st->tone = shr(st->tone, 1); move16 (); /* If open-loop lag is calculated only once in each frame, do extra update and assume that the other tone flag of the frame is one. */ if (one_lag_per_frame != 0) { st->tone = shr(st->tone, 1); st->tone = st->tone | 0x2000; logic16 (); move16 (); } } /**************************************************************************** * * Function : vad_pitch_detection * Purpose : Test whether signal contains pitch or other periodic * component. * Return value : Boolean voiced / unvoiced decision in state variable * ***************************************************************************/ void vad_pitch_detection (vadState1 *st, /* i/o : State struct */ Word16 T_op[] /* i : speech encoder open loop lags */ ) { Word16 lagcount, i; lagcount = 0; move16 (); for (i = 0; i < 2; i++) { test (); if (sub (abs_s (sub (st->oldlag, T_op[i])), LTHRESH) < 0) { lagcount = add (lagcount, 1); } /* Save the current LTP lag */ st->oldlag = T_op[i]; move16 (); } /* Make pitch decision. Save flag of the pitch detection to the variable pitch. */ st->pitch = shr(st->pitch, 1); move16(); test (); if (sub ( add (st->oldlag_count, lagcount), NTHRESH) >= 0) { st->pitch = st->pitch | 0x4000; logic16(); move16(); } /* Update oldlagcount */ st->oldlag_count = lagcount; move16 (); } /**************************************************************************** * * Function : vad * Purpose : Main program for Voice Activity Detection (VAD) for AMR * Return value : VAD Decision, 1 = speech, 0 = noise * ***************************************************************************/ Word16 vad1(vadState1 *st, /* i/o : State struct */ Word16 in_buf[] /* i : samples of the input frame */ ) { Word16 level[COMPLEN]; Word32 pow_sum; Word16 i; /* Calculate power of the input frame. */ pow_sum = 0L; move32 (); for (i = 0; i < FRAME_LEN; i++) { pow_sum = L_mac(pow_sum, in_buf[i-LOOKAHEAD], in_buf[i-LOOKAHEAD]); } /* If input power is very low, clear pitch flag of the current frame */ test (); if (L_sub(pow_sum, POW_PITCH_THR) < 0) { st->pitch = st->pitch & 0x3fff; logic16 (); move16 (); } /* If input power is very low, clear complex flag of the "current" frame */ test (); if (L_sub(pow_sum, POW_COMPLEX_THR) < 0) { st->complex_low = st->complex_low & 0x3fff; logic16 (); move16 (); } /* Run the filter bank which calculates signal levels at each band */ filter_bank(st, in_buf, level); return (vad_decision(st, level, pow_sum)); }