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Diffstat (limited to 'media/libstagefright/codecs/amrwbenc/src/c4t64fx.c')
-rw-r--r-- | media/libstagefright/codecs/amrwbenc/src/c4t64fx.c | 1043 |
1 files changed, 0 insertions, 1043 deletions
diff --git a/media/libstagefright/codecs/amrwbenc/src/c4t64fx.c b/media/libstagefright/codecs/amrwbenc/src/c4t64fx.c deleted file mode 100644 index 1ecc11f..0000000 --- a/media/libstagefright/codecs/amrwbenc/src/c4t64fx.c +++ /dev/null @@ -1,1043 +0,0 @@ -/* - ** Copyright 2003-2010, VisualOn, Inc. - ** - ** 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. - */ - -/*********************************************************************** -* File: c4t64fx.c * -* * -* Description:Performs algebraic codebook search for higher modes * -* * -************************************************************************/ - -/************************************************************************ -* Function: ACELP_4t64_fx() * -* * -* 20, 36, 44, 52, 64, 72, 88 bits algebraic codebook. * -* 4 tracks x 16 positions per track = 64 samples. * -* * -* 20 bits --> 4 pulses in a frame of 64 samples. * -* 36 bits --> 8 pulses in a frame of 64 samples. * -* 44 bits --> 10 pulses in a frame of 64 samples. * -* 52 bits --> 12 pulses in a frame of 64 samples. * -* 64 bits --> 16 pulses in a frame of 64 samples. * -* 72 bits --> 18 pulses in a frame of 64 samples. * -* 88 bits --> 24 pulses in a frame of 64 samples. * -* * -* All pulses can have two (2) possible amplitudes: +1 or -1. * -* Each pulse can have sixteen (16) possible positions. * -*************************************************************************/ - -#include "typedef.h" -#include "basic_op.h" -#include "math_op.h" -#include "acelp.h" -#include "cnst.h" - -#include "q_pulse.h" - -static Word16 tipos[36] = { - 0, 1, 2, 3, /* starting point &ipos[0], 1st iter */ - 1, 2, 3, 0, /* starting point &ipos[4], 2nd iter */ - 2, 3, 0, 1, /* starting point &ipos[8], 3rd iter */ - 3, 0, 1, 2, /* starting point &ipos[12], 4th iter */ - 0, 1, 2, 3, - 1, 2, 3, 0, - 2, 3, 0, 1, - 3, 0, 1, 2, - 0, 1, 2, 3}; /* end point for 24 pulses &ipos[35], 4th iter */ - -#define NB_PULSE_MAX 24 - -#define L_SUBFR 64 -#define NB_TRACK 4 -#define STEP 4 -#define NB_POS 16 -#define MSIZE 256 -#define NB_MAX 8 -#define NPMAXPT ((NB_PULSE_MAX+NB_TRACK-1)/NB_TRACK) - -/* Private functions */ -void cor_h_vec_012( - Word16 h[], /* (i) scaled impulse response */ - Word16 vec[], /* (i) scaled vector (/8) to correlate with h[] */ - Word16 track, /* (i) track to use */ - Word16 sign[], /* (i) sign vector */ - Word16 rrixix[][NB_POS], /* (i) correlation of h[x] with h[x] */ - Word16 cor_1[], /* (o) result of correlation (NB_POS elements) */ - Word16 cor_2[] /* (o) result of correlation (NB_POS elements) */ - ); - -void cor_h_vec_012_asm( - Word16 h[], /* (i) scaled impulse response */ - Word16 vec[], /* (i) scaled vector (/8) to correlate with h[] */ - Word16 track, /* (i) track to use */ - Word16 sign[], /* (i) sign vector */ - Word16 rrixix[][NB_POS], /* (i) correlation of h[x] with h[x] */ - Word16 cor_1[], /* (o) result of correlation (NB_POS elements) */ - Word16 cor_2[] /* (o) result of correlation (NB_POS elements) */ - ); - -void cor_h_vec_30( - Word16 h[], /* (i) scaled impulse response */ - Word16 vec[], /* (i) scaled vector (/8) to correlate with h[] */ - Word16 track, /* (i) track to use */ - Word16 sign[], /* (i) sign vector */ - Word16 rrixix[][NB_POS], /* (i) correlation of h[x] with h[x] */ - Word16 cor_1[], /* (o) result of correlation (NB_POS elements) */ - Word16 cor_2[] /* (o) result of correlation (NB_POS elements) */ - ); - -void search_ixiy( - Word16 nb_pos_ix, /* (i) nb of pos for pulse 1 (1..8) */ - Word16 track_x, /* (i) track of pulse 1 */ - Word16 track_y, /* (i) track of pulse 2 */ - Word16 * ps, /* (i/o) correlation of all fixed pulses */ - Word16 * alp, /* (i/o) energy of all fixed pulses */ - Word16 * ix, /* (o) position of pulse 1 */ - Word16 * iy, /* (o) position of pulse 2 */ - Word16 dn[], /* (i) corr. between target and h[] */ - Word16 dn2[], /* (i) vector of selected positions */ - Word16 cor_x[], /* (i) corr. of pulse 1 with fixed pulses */ - Word16 cor_y[], /* (i) corr. of pulse 2 with fixed pulses */ - Word16 rrixiy[][MSIZE] /* (i) corr. of pulse 1 with pulse 2 */ - ); - - -void ACELP_4t64_fx( - Word16 dn[], /* (i) <12b : correlation between target x[] and H[] */ - Word16 cn[], /* (i) <12b : residual after long term prediction */ - Word16 H[], /* (i) Q12: impulse response of weighted synthesis filter */ - Word16 code[], /* (o) Q9 : algebraic (fixed) codebook excitation */ - Word16 y[], /* (o) Q9 : filtered fixed codebook excitation */ - Word16 nbbits, /* (i) : 20, 36, 44, 52, 64, 72 or 88 bits */ - Word16 ser_size, /* (i) : bit rate */ - Word16 _index[] /* (o) : index (20): 5+5+5+5 = 20 bits. */ - /* (o) : index (36): 9+9+9+9 = 36 bits. */ - /* (o) : index (44): 13+9+13+9 = 44 bits. */ - /* (o) : index (52): 13+13+13+13 = 52 bits. */ - /* (o) : index (64): 2+2+2+2+14+14+14+14 = 64 bits. */ - /* (o) : index (72): 10+2+10+2+10+14+10+14 = 72 bits. */ - /* (o) : index (88): 11+11+11+11+11+11+11+11 = 88 bits. */ - ) -{ - Word32 i, j, k; - Word16 st, ix, iy, pos, index, track, nb_pulse, nbiter, j_temp; - Word16 psk, ps, alpk, alp, val, k_cn, k_dn, exp; - Word16 *p0, *p1, *p2, *p3, *psign; - Word16 *h, *h_inv, *ptr_h1, *ptr_h2, *ptr_hf, h_shift; - Word32 s, cor, L_tmp, L_index; - Word16 dn2[L_SUBFR], sign[L_SUBFR], vec[L_SUBFR]; - Word16 ind[NPMAXPT * NB_TRACK]; - Word16 codvec[NB_PULSE_MAX], nbpos[10]; - Word16 cor_x[NB_POS], cor_y[NB_POS], pos_max[NB_TRACK]; - Word16 h_buf[4 * L_SUBFR]; - Word16 rrixix[NB_TRACK][NB_POS], rrixiy[NB_TRACK][MSIZE]; - Word16 ipos[NB_PULSE_MAX]; - - switch (nbbits) - { - case 20: /* 20 bits, 4 pulses, 4 tracks */ - nbiter = 4; /* 4x16x16=1024 loop */ - alp = 8192; /* alp = 2.0 (Q12) */ - nb_pulse = 4; - nbpos[0] = 4; - nbpos[1] = 8; - break; - case 36: /* 36 bits, 8 pulses, 4 tracks */ - nbiter = 4; /* 4x20x16=1280 loop */ - alp = 4096; /* alp = 1.0 (Q12) */ - nb_pulse = 8; - nbpos[0] = 4; - nbpos[1] = 8; - nbpos[2] = 8; - break; - case 44: /* 44 bits, 10 pulses, 4 tracks */ - nbiter = 4; /* 4x26x16=1664 loop */ - alp = 4096; /* alp = 1.0 (Q12) */ - nb_pulse = 10; - nbpos[0] = 4; - nbpos[1] = 6; - nbpos[2] = 8; - nbpos[3] = 8; - break; - case 52: /* 52 bits, 12 pulses, 4 tracks */ - nbiter = 4; /* 4x26x16=1664 loop */ - alp = 4096; /* alp = 1.0 (Q12) */ - nb_pulse = 12; - nbpos[0] = 4; - nbpos[1] = 6; - nbpos[2] = 8; - nbpos[3] = 8; - break; - case 64: /* 64 bits, 16 pulses, 4 tracks */ - nbiter = 3; /* 3x36x16=1728 loop */ - alp = 3277; /* alp = 0.8 (Q12) */ - nb_pulse = 16; - nbpos[0] = 4; - nbpos[1] = 4; - nbpos[2] = 6; - nbpos[3] = 6; - nbpos[4] = 8; - nbpos[5] = 8; - break; - case 72: /* 72 bits, 18 pulses, 4 tracks */ - nbiter = 3; /* 3x35x16=1680 loop */ - alp = 3072; /* alp = 0.75 (Q12) */ - nb_pulse = 18; - nbpos[0] = 2; - nbpos[1] = 3; - nbpos[2] = 4; - nbpos[3] = 5; - nbpos[4] = 6; - nbpos[5] = 7; - nbpos[6] = 8; - break; - case 88: /* 88 bits, 24 pulses, 4 tracks */ - if(ser_size > 462) - nbiter = 1; - else - nbiter = 2; /* 2x53x16=1696 loop */ - - alp = 2048; /* alp = 0.5 (Q12) */ - nb_pulse = 24; - nbpos[0] = 2; - nbpos[1] = 2; - nbpos[2] = 3; - nbpos[3] = 4; - nbpos[4] = 5; - nbpos[5] = 6; - nbpos[6] = 7; - nbpos[7] = 8; - nbpos[8] = 8; - nbpos[9] = 8; - break; - default: - nbiter = 0; - alp = 0; - nb_pulse = 0; - } - - for (i = 0; i < nb_pulse; i++) - { - codvec[i] = i; - } - - /*----------------------------------------------------------------* - * Find sign for each pulse position. * - *----------------------------------------------------------------*/ - /* calculate energy for normalization of cn[] and dn[] */ - /* set k_cn = 32..32767 (ener_cn = 2^30..256-0) */ -#ifdef ASM_OPT /* asm optimization branch */ - s = Dot_product12_asm(cn, cn, L_SUBFR, &exp); -#else - s = Dot_product12(cn, cn, L_SUBFR, &exp); -#endif - - Isqrt_n(&s, &exp); - s = L_shl(s, (exp + 5)); - k_cn = extract_h(L_add(s, 0x8000)); - - /* set k_dn = 32..512 (ener_dn = 2^30..2^22) */ -#ifdef ASM_OPT /* asm optimization branch */ - s = Dot_product12_asm(dn, dn, L_SUBFR, &exp); -#else - s = Dot_product12(dn, dn, L_SUBFR, &exp); -#endif - - Isqrt_n(&s, &exp); - k_dn = (L_shl(s, (exp + 5 + 3)) + 0x8000) >> 16; /* k_dn = 256..4096 */ - k_dn = vo_mult_r(alp, k_dn); /* alp in Q12 */ - - /* mix normalized cn[] and dn[] */ - p0 = cn; - p1 = dn; - p2 = dn2; - - for (i = 0; i < L_SUBFR/4; i++) - { - s = (k_cn* (*p0++))+(k_dn * (*p1++)); - *p2++ = s >> 7; - s = (k_cn* (*p0++))+(k_dn * (*p1++)); - *p2++ = s >> 7; - s = (k_cn* (*p0++))+(k_dn * (*p1++)); - *p2++ = s >> 7; - s = (k_cn* (*p0++))+(k_dn * (*p1++)); - *p2++ = s >> 7; - } - - /* set sign according to dn2[] = k_cn*cn[] + k_dn*dn[] */ - for(i = 0; i < L_SUBFR; i++) - { - val = dn[i]; - ps = dn2[i]; - if (ps >= 0) - { - sign[i] = 32767; /* sign = +1 (Q12) */ - vec[i] = -32768; - } else - { - sign[i] = -32768; /* sign = -1 (Q12) */ - vec[i] = 32767; - dn[i] = -val; - dn2[i] = -ps; - } - } - /*----------------------------------------------------------------* - * Select NB_MAX position per track according to max of dn2[]. * - *----------------------------------------------------------------*/ - pos = 0; - for (i = 0; i < NB_TRACK; i++) - { - for (k = 0; k < NB_MAX; k++) - { - ps = -1; - for (j = i; j < L_SUBFR; j += STEP) - { - if(dn2[j] > ps) - { - ps = dn2[j]; - pos = j; - } - } - dn2[pos] = (k - NB_MAX); /* dn2 < 0 when position is selected */ - if (k == 0) - { - pos_max[i] = pos; - } - } - } - - /*--------------------------------------------------------------* - * Scale h[] to avoid overflow and to get maximum of precision * - * on correlation. * - * * - * Maximum of h[] (h[0]) is fixed to 2048 (MAX16 / 16). * - * ==> This allow addition of 16 pulses without saturation. * - * * - * Energy worst case (on resonant impulse response), * - * - energy of h[] is approximately MAX/16. * - * - During search, the energy is divided by 8 to avoid * - * overflow on "alp". (energy of h[] = MAX/128). * - * ==> "alp" worst case detected is 22854 on sinusoidal wave. * - *--------------------------------------------------------------*/ - - /* impulse response buffer for fast computation */ - - h = h_buf; - h_inv = h_buf + (2 * L_SUBFR); - L_tmp = 0; - for (i = 0; i < L_SUBFR; i++) - { - *h++ = 0; - *h_inv++ = 0; - L_tmp += (H[i] * H[i]) << 1; - } - /* scale h[] down (/2) when energy of h[] is high with many pulses used */ - val = extract_h(L_tmp); - h_shift = 0; - - if ((nb_pulse >= 12) && (val > 1024)) - { - h_shift = 1; - } - p0 = H; - p1 = h; - p2 = h_inv; - - for (i = 0; i < L_SUBFR/4; i++) - { - *p1 = *p0++ >> h_shift; - *p2++ = -(*p1++); - *p1 = *p0++ >> h_shift; - *p2++ = -(*p1++); - *p1 = *p0++ >> h_shift; - *p2++ = -(*p1++); - *p1 = *p0++ >> h_shift; - *p2++ = -(*p1++); - } - - /*------------------------------------------------------------* - * Compute rrixix[][] needed for the codebook search. * - * This algorithm compute impulse response energy of all * - * positions (16) in each track (4). Total = 4x16 = 64. * - *------------------------------------------------------------*/ - - /* storage order --> i3i3, i2i2, i1i1, i0i0 */ - - /* Init pointers to last position of rrixix[] */ - p0 = &rrixix[0][NB_POS - 1]; - p1 = &rrixix[1][NB_POS - 1]; - p2 = &rrixix[2][NB_POS - 1]; - p3 = &rrixix[3][NB_POS - 1]; - - ptr_h1 = h; - cor = 0x00008000L; /* for rounding */ - for (i = 0; i < NB_POS; i++) - { - cor += vo_L_mult((*ptr_h1), (*ptr_h1)); - ptr_h1++; - *p3-- = extract_h(cor); - cor += vo_L_mult((*ptr_h1), (*ptr_h1)); - ptr_h1++; - *p2-- = extract_h(cor); - cor += vo_L_mult((*ptr_h1), (*ptr_h1)); - ptr_h1++; - *p1-- = extract_h(cor); - cor += vo_L_mult((*ptr_h1), (*ptr_h1)); - ptr_h1++; - *p0-- = extract_h(cor); - } - - /*------------------------------------------------------------* - * Compute rrixiy[][] needed for the codebook search. * - * This algorithm compute correlation between 2 pulses * - * (2 impulses responses) in 4 possible adjacents tracks. * - * (track 0-1, 1-2, 2-3 and 3-0). Total = 4x16x16 = 1024. * - *------------------------------------------------------------*/ - - /* storage order --> i2i3, i1i2, i0i1, i3i0 */ - - pos = MSIZE - 1; - ptr_hf = h + 1; - - for (k = 0; k < NB_POS; k++) - { - p3 = &rrixiy[2][pos]; - p2 = &rrixiy[1][pos]; - p1 = &rrixiy[0][pos]; - p0 = &rrixiy[3][pos - NB_POS]; - - cor = 0x00008000L; /* for rounding */ - ptr_h1 = h; - ptr_h2 = ptr_hf; - - for (i = k + 1; i < NB_POS; i++) - { - cor += vo_L_mult((*ptr_h1), (*ptr_h2)); - ptr_h1++; - ptr_h2++; - *p3 = extract_h(cor); - cor += vo_L_mult((*ptr_h1), (*ptr_h2)); - ptr_h1++; - ptr_h2++; - *p2 = extract_h(cor); - cor += vo_L_mult((*ptr_h1), (*ptr_h2)); - ptr_h1++; - ptr_h2++; - *p1 = extract_h(cor); - cor += vo_L_mult((*ptr_h1), (*ptr_h2)); - ptr_h1++; - ptr_h2++; - *p0 = extract_h(cor); - - p3 -= (NB_POS + 1); - p2 -= (NB_POS + 1); - p1 -= (NB_POS + 1); - p0 -= (NB_POS + 1); - } - cor += vo_L_mult((*ptr_h1), (*ptr_h2)); - ptr_h1++; - ptr_h2++; - *p3 = extract_h(cor); - cor += vo_L_mult((*ptr_h1), (*ptr_h2)); - ptr_h1++; - ptr_h2++; - *p2 = extract_h(cor); - cor += vo_L_mult((*ptr_h1), (*ptr_h2)); - ptr_h1++; - ptr_h2++; - *p1 = extract_h(cor); - - pos -= NB_POS; - ptr_hf += STEP; - } - - /* storage order --> i3i0, i2i3, i1i2, i0i1 */ - - pos = MSIZE - 1; - ptr_hf = h + 3; - - for (k = 0; k < NB_POS; k++) - { - p3 = &rrixiy[3][pos]; - p2 = &rrixiy[2][pos - 1]; - p1 = &rrixiy[1][pos - 1]; - p0 = &rrixiy[0][pos - 1]; - - cor = 0x00008000L; /* for rounding */ - ptr_h1 = h; - ptr_h2 = ptr_hf; - - for (i = k + 1; i < NB_POS; i++) - { - cor += vo_L_mult((*ptr_h1), (*ptr_h2)); - ptr_h1++; - ptr_h2++; - *p3 = extract_h(cor); - cor += vo_L_mult((*ptr_h1), (*ptr_h2)); - ptr_h1++; - ptr_h2++; - *p2 = extract_h(cor); - cor += vo_L_mult((*ptr_h1), (*ptr_h2)); - ptr_h1++; - ptr_h2++; - *p1 = extract_h(cor); - cor += vo_L_mult((*ptr_h1), (*ptr_h2)); - ptr_h1++; - ptr_h2++; - *p0 = extract_h(cor); - - p3 -= (NB_POS + 1); - p2 -= (NB_POS + 1); - p1 -= (NB_POS + 1); - p0 -= (NB_POS + 1); - } - cor += vo_L_mult((*ptr_h1), (*ptr_h2)); - ptr_h1++; - ptr_h2++; - *p3 = extract_h(cor); - - pos--; - ptr_hf += STEP; - } - - /*------------------------------------------------------------* - * Modification of rrixiy[][] to take signs into account. * - *------------------------------------------------------------*/ - - p0 = &rrixiy[0][0]; - - for (k = 0; k < NB_TRACK; k++) - { - j_temp = (k + 1)&0x03; - for (i = k; i < L_SUBFR; i += STEP) - { - psign = sign; - if (psign[i] < 0) - { - psign = vec; - } - j = j_temp; - for (; j < L_SUBFR; j += STEP) - { - *p0 = vo_mult(*p0, psign[j]); - p0++; - } - } - } - - /*-------------------------------------------------------------------* - * Deep first search * - *-------------------------------------------------------------------*/ - - psk = -1; - alpk = 1; - - for (k = 0; k < nbiter; k++) - { - j_temp = k<<2; - for (i = 0; i < nb_pulse; i++) - ipos[i] = tipos[j_temp + i]; - - if(nbbits == 20) - { - pos = 0; - ps = 0; - alp = 0; - for (i = 0; i < L_SUBFR; i++) - { - vec[i] = 0; - } - } else if ((nbbits == 36) || (nbbits == 44)) - { - /* first stage: fix 2 pulses */ - pos = 2; - - ix = ind[0] = pos_max[ipos[0]]; - iy = ind[1] = pos_max[ipos[1]]; - ps = dn[ix] + dn[iy]; - i = ix >> 2; /* ix / STEP */ - j = iy >> 2; /* iy / STEP */ - s = rrixix[ipos[0]][i] << 13; - s += rrixix[ipos[1]][j] << 13; - i = (i << 4) + j; /* (ix/STEP)*NB_POS + (iy/STEP) */ - s += rrixiy[ipos[0]][i] << 14; - alp = (s + 0x8000) >> 16; - if (sign[ix] < 0) - p0 = h_inv - ix; - else - p0 = h - ix; - if (sign[iy] < 0) - p1 = h_inv - iy; - else - p1 = h - iy; - - for (i = 0; i < L_SUBFR; i++) - { - vec[i] = (*p0++) + (*p1++); - } - - if(nbbits == 44) - { - ipos[8] = 0; - ipos[9] = 1; - } - } else - { - /* first stage: fix 4 pulses */ - pos = 4; - - ix = ind[0] = pos_max[ipos[0]]; - iy = ind[1] = pos_max[ipos[1]]; - i = ind[2] = pos_max[ipos[2]]; - j = ind[3] = pos_max[ipos[3]]; - ps = add1(add1(add1(dn[ix], dn[iy]), dn[i]), dn[j]); - - if (sign[ix] < 0) - p0 = h_inv - ix; - else - p0 = h - ix; - - if (sign[iy] < 0) - p1 = h_inv - iy; - else - p1 = h - iy; - - if (sign[i] < 0) - p2 = h_inv - i; - else - p2 = h - i; - - if (sign[j] < 0) - p3 = h_inv - j; - else - p3 = h - j; - - L_tmp = 0L; - for(i = 0; i < L_SUBFR; i++) - { - vec[i] = add1(add1(add1(*p0++, *p1++), *p2++), *p3++); - L_tmp += (vec[i] * vec[i]) << 1; - } - - alp = ((L_tmp >> 3) + 0x8000) >> 16; - - if(nbbits == 72) - { - ipos[16] = 0; - ipos[17] = 1; - } - } - - /* other stages of 2 pulses */ - - for (j = pos, st = 0; j < nb_pulse; j += 2, st++) - { - /*--------------------------------------------------* - * Calculate correlation of all possible positions * - * of the next 2 pulses with previous fixed pulses. * - * Each pulse can have 16 possible positions. * - *--------------------------------------------------*/ - if(ipos[j] == 3) - { - cor_h_vec_30(h, vec, ipos[j], sign, rrixix, cor_x, cor_y); - } - else - { -#ifdef ASM_OPT /* asm optimization branch */ - cor_h_vec_012_asm(h, vec, ipos[j], sign, rrixix, cor_x, cor_y); -#else - cor_h_vec_012(h, vec, ipos[j], sign, rrixix, cor_x, cor_y); -#endif - } - /*--------------------------------------------------* - * Find best positions of 2 pulses. * - *--------------------------------------------------*/ - search_ixiy(nbpos[st], ipos[j], ipos[j + 1], &ps, &alp, - &ix, &iy, dn, dn2, cor_x, cor_y, rrixiy); - - ind[j] = ix; - ind[j + 1] = iy; - - if (sign[ix] < 0) - p0 = h_inv - ix; - else - p0 = h - ix; - if (sign[iy] < 0) - p1 = h_inv - iy; - else - p1 = h - iy; - - for (i = 0; i < L_SUBFR; i+=4) - { - vec[i] += add1((*p0++), (*p1++)); - vec[i+1] += add1((*p0++), (*p1++)); - vec[i+2] += add1((*p0++), (*p1++)); - vec[i+3] += add1((*p0++), (*p1++)); - } - } - /* memorise the best codevector */ - ps = vo_mult(ps, ps); - s = vo_L_msu(vo_L_mult(alpk, ps), psk, alp); - if (s > 0) - { - psk = ps; - alpk = alp; - for (i = 0; i < nb_pulse; i++) - { - codvec[i] = ind[i]; - } - for (i = 0; i < L_SUBFR; i++) - { - y[i] = vec[i]; - } - } - } - /*-------------------------------------------------------------------* - * Build the codeword, the filtered codeword and index of codevector.* - *-------------------------------------------------------------------*/ - for (i = 0; i < NPMAXPT * NB_TRACK; i++) - { - ind[i] = -1; - } - for (i = 0; i < L_SUBFR; i++) - { - code[i] = 0; - y[i] = vo_shr_r(y[i], 3); /* Q12 to Q9 */ - } - val = (512 >> h_shift); /* codeword in Q9 format */ - for (k = 0; k < nb_pulse; k++) - { - i = codvec[k]; /* read pulse position */ - j = sign[i]; /* read sign */ - index = i >> 2; /* index = pos of pulse (0..15) */ - track = (Word16) (i & 0x03); /* track = i % NB_TRACK (0..3) */ - - if (j > 0) - { - code[i] += val; - codvec[k] += 128; - } else - { - code[i] -= val; - index += NB_POS; - } - - i = (Word16)((vo_L_mult(track, NPMAXPT) >> 1)); - - while (ind[i] >= 0) - { - i += 1; - } - ind[i] = index; - } - - k = 0; - /* Build index of codevector */ - if(nbbits == 20) - { - for (track = 0; track < NB_TRACK; track++) - { - _index[track] = (Word16)(quant_1p_N1(ind[k], 4)); - k += NPMAXPT; - } - } else if(nbbits == 36) - { - for (track = 0; track < NB_TRACK; track++) - { - _index[track] = (Word16)(quant_2p_2N1(ind[k], ind[k + 1], 4)); - k += NPMAXPT; - } - } else if(nbbits == 44) - { - for (track = 0; track < NB_TRACK - 2; track++) - { - _index[track] = (Word16)(quant_3p_3N1(ind[k], ind[k + 1], ind[k + 2], 4)); - k += NPMAXPT; - } - for (track = 2; track < NB_TRACK; track++) - { - _index[track] = (Word16)(quant_2p_2N1(ind[k], ind[k + 1], 4)); - k += NPMAXPT; - } - } else if(nbbits == 52) - { - for (track = 0; track < NB_TRACK; track++) - { - _index[track] = (Word16)(quant_3p_3N1(ind[k], ind[k + 1], ind[k + 2], 4)); - k += NPMAXPT; - } - } else if(nbbits == 64) - { - for (track = 0; track < NB_TRACK; track++) - { - L_index = quant_4p_4N(&ind[k], 4); - _index[track] = (Word16)((L_index >> 14) & 3); - _index[track + NB_TRACK] = (Word16)(L_index & 0x3FFF); - k += NPMAXPT; - } - } else if(nbbits == 72) - { - for (track = 0; track < NB_TRACK - 2; track++) - { - L_index = quant_5p_5N(&ind[k], 4); - _index[track] = (Word16)((L_index >> 10) & 0x03FF); - _index[track + NB_TRACK] = (Word16)(L_index & 0x03FF); - k += NPMAXPT; - } - for (track = 2; track < NB_TRACK; track++) - { - L_index = quant_4p_4N(&ind[k], 4); - _index[track] = (Word16)((L_index >> 14) & 3); - _index[track + NB_TRACK] = (Word16)(L_index & 0x3FFF); - k += NPMAXPT; - } - } else if(nbbits == 88) - { - for (track = 0; track < NB_TRACK; track++) - { - L_index = quant_6p_6N_2(&ind[k], 4); - _index[track] = (Word16)((L_index >> 11) & 0x07FF); - _index[track + NB_TRACK] = (Word16)(L_index & 0x07FF); - k += NPMAXPT; - } - } - return; -} - - -/*-------------------------------------------------------------------* - * Function cor_h_vec() * - * ~~~~~~~~~~~~~~~~~~~~~ * - * Compute correlations of h[] with vec[] for the specified track. * - *-------------------------------------------------------------------*/ -void cor_h_vec_30( - Word16 h[], /* (i) scaled impulse response */ - Word16 vec[], /* (i) scaled vector (/8) to correlate with h[] */ - Word16 track, /* (i) track to use */ - Word16 sign[], /* (i) sign vector */ - Word16 rrixix[][NB_POS], /* (i) correlation of h[x] with h[x] */ - Word16 cor_1[], /* (o) result of correlation (NB_POS elements) */ - Word16 cor_2[] /* (o) result of correlation (NB_POS elements) */ - ) -{ - Word32 i, j, pos, corr; - Word16 *p0, *p1, *p2,*p3,*cor_x,*cor_y; - Word32 L_sum1,L_sum2; - cor_x = cor_1; - cor_y = cor_2; - p0 = rrixix[track]; - p3 = rrixix[0]; - pos = track; - - for (i = 0; i < NB_POS; i+=2) - { - L_sum1 = L_sum2 = 0L; - p1 = h; - p2 = &vec[pos]; - for (j=pos;j < L_SUBFR; j++) - { - L_sum1 += *p1 * *p2; - p2-=3; - L_sum2 += *p1++ * *p2; - p2+=4; - } - p2-=3; - L_sum2 += *p1++ * *p2++; - L_sum2 += *p1++ * *p2++; - L_sum2 += *p1++ * *p2++; - - L_sum1 = (L_sum1 << 2); - L_sum2 = (L_sum2 << 2); - - corr = vo_round(L_sum1); - *cor_x++ = vo_mult(corr, sign[pos]) + (*p0++); - corr = vo_round(L_sum2); - *cor_y++ = vo_mult(corr, sign[pos-3]) + (*p3++); - pos += STEP; - - L_sum1 = L_sum2 = 0L; - p1 = h; - p2 = &vec[pos]; - for (j=pos;j < L_SUBFR; j++) - { - L_sum1 += *p1 * *p2; - p2-=3; - L_sum2 += *p1++ * *p2; - p2+=4; - } - p2-=3; - L_sum2 += *p1++ * *p2++; - L_sum2 += *p1++ * *p2++; - L_sum2 += *p1++ * *p2++; - - L_sum1 = (L_sum1 << 2); - L_sum2 = (L_sum2 << 2); - - corr = vo_round(L_sum1); - *cor_x++ = vo_mult(corr, sign[pos]) + (*p0++); - corr = vo_round(L_sum2); - *cor_y++ = vo_mult(corr, sign[pos-3]) + (*p3++); - pos += STEP; - } - return; -} - -void cor_h_vec_012( - Word16 h[], /* (i) scaled impulse response */ - Word16 vec[], /* (i) scaled vector (/8) to correlate with h[] */ - Word16 track, /* (i) track to use */ - Word16 sign[], /* (i) sign vector */ - Word16 rrixix[][NB_POS], /* (i) correlation of h[x] with h[x] */ - Word16 cor_1[], /* (o) result of correlation (NB_POS elements) */ - Word16 cor_2[] /* (o) result of correlation (NB_POS elements) */ - ) -{ - Word32 i, j, pos, corr; - Word16 *p0, *p1, *p2,*p3,*cor_x,*cor_y; - Word32 L_sum1,L_sum2; - cor_x = cor_1; - cor_y = cor_2; - p0 = rrixix[track]; - p3 = rrixix[track+1]; - pos = track; - - for (i = 0; i < NB_POS; i+=2) - { - L_sum1 = L_sum2 = 0L; - p1 = h; - p2 = &vec[pos]; - for (j=62-pos ;j >= 0; j--) - { - L_sum1 += *p1 * *p2++; - L_sum2 += *p1++ * *p2; - } - L_sum1 += *p1 * *p2; - L_sum1 = (L_sum1 << 2); - L_sum2 = (L_sum2 << 2); - - corr = (L_sum1 + 0x8000) >> 16; - cor_x[i] = vo_mult(corr, sign[pos]) + (*p0++); - corr = (L_sum2 + 0x8000) >> 16; - cor_y[i] = vo_mult(corr, sign[pos + 1]) + (*p3++); - pos += STEP; - - L_sum1 = L_sum2 = 0L; - p1 = h; - p2 = &vec[pos]; - for (j= 62-pos;j >= 0; j--) - { - L_sum1 += *p1 * *p2++; - L_sum2 += *p1++ * *p2; - } - L_sum1 += *p1 * *p2; - L_sum1 = (L_sum1 << 2); - L_sum2 = (L_sum2 << 2); - - corr = (L_sum1 + 0x8000) >> 16; - cor_x[i+1] = vo_mult(corr, sign[pos]) + (*p0++); - corr = (L_sum2 + 0x8000) >> 16; - cor_y[i+1] = vo_mult(corr, sign[pos + 1]) + (*p3++); - pos += STEP; - } - return; -} - -/*-------------------------------------------------------------------* - * Function search_ixiy() * - * ~~~~~~~~~~~~~~~~~~~~~~~ * - * Find the best positions of 2 pulses in a subframe. * - *-------------------------------------------------------------------*/ - -void search_ixiy( - Word16 nb_pos_ix, /* (i) nb of pos for pulse 1 (1..8) */ - Word16 track_x, /* (i) track of pulse 1 */ - Word16 track_y, /* (i) track of pulse 2 */ - Word16 * ps, /* (i/o) correlation of all fixed pulses */ - Word16 * alp, /* (i/o) energy of all fixed pulses */ - Word16 * ix, /* (o) position of pulse 1 */ - Word16 * iy, /* (o) position of pulse 2 */ - Word16 dn[], /* (i) corr. between target and h[] */ - Word16 dn2[], /* (i) vector of selected positions */ - Word16 cor_x[], /* (i) corr. of pulse 1 with fixed pulses */ - Word16 cor_y[], /* (i) corr. of pulse 2 with fixed pulses */ - Word16 rrixiy[][MSIZE] /* (i) corr. of pulse 1 with pulse 2 */ - ) -{ - Word32 x, y, pos, thres_ix; - Word16 ps1, ps2, sq, sqk; - Word16 alp_16, alpk; - Word16 *p0, *p1, *p2; - Word32 s, alp0, alp1, alp2; - - p0 = cor_x; - p1 = cor_y; - p2 = rrixiy[track_x]; - - thres_ix = nb_pos_ix - NB_MAX; - - alp0 = L_deposit_h(*alp); - alp0 = (alp0 + 0x00008000L); /* for rounding */ - - sqk = -1; - alpk = 1; - - for (x = track_x; x < L_SUBFR; x += STEP) - { - ps1 = *ps + dn[x]; - alp1 = alp0 + ((*p0++)<<13); - - if (dn2[x] < thres_ix) - { - pos = -1; - for (y = track_y; y < L_SUBFR; y += STEP) - { - ps2 = add1(ps1, dn[y]); - - alp2 = alp1 + ((*p1++)<<13); - alp2 = alp2 + ((*p2++)<<14); - alp_16 = extract_h(alp2); - sq = vo_mult(ps2, ps2); - s = vo_L_mult(alpk, sq) - ((sqk * alp_16)<<1); - - if (s > 0) - { - sqk = sq; - alpk = alp_16; - pos = y; - } - } - p1 -= NB_POS; - - if (pos >= 0) - { - *ix = x; - *iy = pos; - } - } else - { - p2 += NB_POS; - } - } - - *ps = add1(*ps, add1(dn[*ix], dn[*iy])); - *alp = alpk; - - return; -} - - - - |