/* *=================================================================== * 3GPP AMR Wideband Floating-point Speech Codec *=================================================================== */ #include #include "typedef.h" #include "dec_util.h" #define M 16 /* Order of LP filter */ #define MP1 (M + 1) #define M16k 20 #define NC16k (M16k / 2) #define MU 10923 /* Prediction factor (1.0/3.0) in Q15 */ #define L_MEANBUF 3 #define ALPHA 29491 /* 0. 9 in Q15 */ #define ONE_ALPHA (32768-ALPHA) /* (1.0 - ALPHA) in Q15 */ #define ORDER 16 /* order of linear prediction filter */ #define ISF_GAP 128 /* 50 Hz */ #define INV_LENGTH 2731 /* 1/12 */ extern const Word16 D_ROM_dico1_isf[]; extern const Word16 D_ROM_dico2_isf[]; extern const Word16 D_ROM_dico21_isf_36b[]; extern const Word16 D_ROM_dico22_isf_36b[]; extern const Word16 D_ROM_dico23_isf_36b[]; extern const Word16 D_ROM_dico21_isf[]; extern const Word16 D_ROM_dico22_isf[]; extern const Word16 D_ROM_dico23_isf[]; extern const Word16 D_ROM_dico24_isf[]; extern const Word16 D_ROM_dico25_isf[]; extern const Word16 D_ROM_dico1_isf_noise[]; extern const Word16 D_ROM_dico2_isf_noise[]; extern const Word16 D_ROM_dico3_isf_noise[]; extern const Word16 D_ROM_dico4_isf_noise[]; extern const Word16 D_ROM_dico5_isf_noise[]; extern const Word16 D_ROM_mean_isf[]; extern const Word16 D_ROM_mean_isf_noise[]; extern const Word16 D_ROM_cos[]; /* * D_LPC_isf_reorder * * Parameters: * isf I/O: vector of isfs * min_dist I: quantized ISFs (in frequency domain) * n I: LPC order * * Function: * To make sure that the isfs are properly order and to keep a certain * minimum distance between consecutive isfs. * * Returns: * void */ static void D_LPC_isf_reorder(Word16 *isf, Word16 min_dist, Word16 n) { Word32 i, isf_min; isf_min = min_dist; for(i = 0; i < n - 1; i++) { if(isf[i] < isf_min) { isf[i] = (Word16)isf_min; } isf_min = isf[i] + min_dist; } return; } /* * D_LPC_isf_noise_d * * Parameters: * indice I: indices of the selected codebook entries * isf_q O: quantized ISFs (in frequency domain) * * Function: * Decoding of ISF parameters * * Returns: * void */ void D_LPC_isf_noise_d(Word16 *indice, Word16 *isf_q) { Word32 i; for(i = 0; i < 2; i++) { isf_q[i] = D_ROM_dico1_isf_noise[indice[0] * 2 + i]; } for(i = 0; i < 3; i++) { isf_q[i + 2] = D_ROM_dico2_isf_noise[indice[1] * 3 + i]; } for(i = 0; i < 3; i++) { isf_q[i + 5] = D_ROM_dico3_isf_noise[indice[2] * 3 + i]; } for(i = 0; i < 4; i++) { isf_q[i + 8] = D_ROM_dico4_isf_noise[indice[3] * 4 + i]; } for(i = 0; i < 4; i++) { isf_q[i + 12] = D_ROM_dico5_isf_noise[indice[4] * 4 + i]; } for(i = 0; i < ORDER; i++) { isf_q[i] = (Word16)(isf_q[i]+ D_ROM_mean_isf_noise[i]); } D_LPC_isf_reorder(isf_q, ISF_GAP, ORDER); return; } /* * D_LPC_isf_isp_conversion * * Parameters: * isp O: (Q15) isp[m] (range: -1<=val<1) * isf I: (Q15) isf[m] normalized (range: 0.0 <= val <= 0.5) * m I: LPC order * * Function: * Transformation isf to isp * * ISP are immitance spectral pair in cosine domain (-1 to 1). * ISF are immitance spectral pair in frequency domain (0 to 6400). * Returns: * void */ void D_LPC_isf_isp_conversion(Word16 isf[], Word16 isp[], Word16 m) { Word32 i, ind, offset, tmp; for(i = 0; i < m - 1; i++) { isp[i] = isf[i]; } isp[m - 1] = (Word16)(isf[m - 1] << 1); for(i = 0; i < m; i++) { ind = isp[i] >> 7; /* ind = b7-b15 of isf[i] */ offset = isp[i] & 0x007f; /* offset = b0-b6 of isf[i] */ /* isp[i] = table[ind]+ ((table[ind+1]-table[ind])*offset) / 128 */ tmp = (D_ROM_cos[ind + 1] - D_ROM_cos[ind]) * offset; isp[i] = (Word16)(D_ROM_cos[ind] + (tmp >> 7)); } return; } /* * D_LPC_isp_pol_get * * Parameters: * isp I: Immitance spectral pairs (cosine domaine) * f O: the coefficients of F1 or F2 * n I: no of coefficients (m/2) * k16 I: 16k flag * * Function: * Find the polynomial F1(z) or F2(z) from the ISPs. * This is performed by expanding the product polynomials: * * F1(z) = product ( 1 - 2 isp_i z^-1 + z^-2 ) * i=0,2,4,6,8 * F2(z) = product ( 1 - 2 isp_i z^-1 + z^-2 ) * i=1,3,5,7 * * where isp_i are the ISPs in the cosine domain. * * Returns: * void */ static void D_LPC_isp_pol_get(Word16 *isp, Word32 *f, Word32 n, Word16 k16) { Word32 i, j, t0, s1, s2; Word16 hi, lo; s1 = 8388608; s2 = 512; if(k16) { s1 >>= 2; s2 >>= 2; } /* All computation in Q23 */ f[0] = s1; /* f[0] = 1.0; in Q23 */ f[1] = isp[0] * (-s2); /* f[1] = -2.0*isp[0] in Q23 */ f += 2; /* Advance f pointer */ isp += 2; /* Advance isp pointer */ for(i = 2; i <= n; i++) { *f = f[ - 2]; for(j = 1; j < i; j++, f--) { D_UTIL_l_extract(f[- 1], &hi, &lo); t0 = D_UTIL_mpy_32_16(hi, lo, *isp); /* t0 = f[-1] * isp */ t0 = (t0 << 1); *f = (*f - t0); /* *f -= t0 */ *f = (*f + f[ - 2]); /* *f += f[-2] */ } *f = *f - (*isp * s2); /* *f -= isp << 8 */ f += i; /* Advance f pointer */ isp += 2; /* Advance isp pointer */ } return; } /* * D_LPC_isp_a_conversion * * Parameters: * isp I: (Q15) Immittance spectral pairs * a O: (Q12) Predictor coefficients (order = M) * m I: order of LP filter * * Function: * Convert ISPs to predictor coefficients a[] * * Returns: * void */ void D_LPC_isp_a_conversion(Word16 isp[], Word16 a[], Word32 adaptive_scaling, Word16 m) { Word32 j, i, nc, tmax, q, q_sug, r; Word32 f1[NC16k + 1], f2[NC16k]; Word32 t0; Word16 hi, lo; nc = m >> 1; if(nc > 8) { D_LPC_isp_pol_get(&isp[0], f1, nc, 1); for(i = 0; i <= nc; i++) { f1[i] = (f1[i] << 2); } } else { D_LPC_isp_pol_get(&isp[0], f1, nc, 0); } if(nc > 8) { D_LPC_isp_pol_get(&isp[1], f2, nc - 1, 1); for(i = 0; i <= nc - 1; i++) { f2[i] = (f2[i] << 2); } } else { D_LPC_isp_pol_get(&isp[1], f2, nc - 1, 0); } /* * Multiply F2(z) by (1 - z^-2) */ for(i = nc - 1; i > 1; i--) { f2[i] = f2[i] - f2[i - 2]; /* f2[i] -= f2[i-2]; */ } /* * Scale F1(z) by (1+isp[m-1]) and F2(z) by (1-isp[m-1]) */ for(i = 0; i < nc; i++) { /* f1[i] *= (1.0 + isp[M-1]); */ D_UTIL_l_extract(f1[i], &hi, &lo); t0 = D_UTIL_mpy_32_16(hi, lo, isp[m - 1]); f1[i] = f1[i] + t0; /* f2[i] *= (1.0 - isp[M-1]); */ D_UTIL_l_extract(f2[i], &hi, &lo); t0 = D_UTIL_mpy_32_16(hi, lo, isp[m - 1]); f2[i] = f2[i] - t0; } /* * A(z) = (F1(z)+F2(z))/2 * F1(z) is symmetric and F2(z) is antisymmetric */ /* a[0] = 1.0; */ a[0] = 4096; tmax = 1; for(i = 1, j = m - 1; i < nc; i++, j--) { /* a[i] = 0.5*(f1[i] + f2[i]); */ t0 = f1[i] + f2[i]; /* f1[i] + f2[i] */ tmax |= labs(t0); a[i] = (Word16)((t0 + 0x800) >> 12); /* from Q23 to Q12 and * 0.5 */ /* a[j] = 0.5*(f1[i] - f2[i]); */ t0 = (f1[i] - f2[i]); /* f1[i] - f2[i] */ tmax |= labs(t0); a[j] = (Word16)((t0 + 0x800) >> 12); /* from Q23 to Q12 and * 0.5 */ } /* rescale data if overflow has occured and reprocess the loop */ if (adaptive_scaling) { q = 4 - D_UTIL_norm_l(tmax); /* adaptive scaling enabled */ } else { q = 0; /* adaptive scaling disabled */ } if (q > 0) { q_sug = 12 + q; r = 1 << (q_sug - 1); for (i = 1, j = m - 1; i < nc; i++, j--) { /* a[i] = 0.5*(f1[i] + f2[i]); */ t0 = f1[i] + f2[i]; /* f1[i] + f2[i] */ a[i] = (Word16)((t0 + r) >> q_sug); /* from Q23 to Q12 and * 0.5 */ /* a[j] = 0.5*(f1[i] - f2[i]); */ t0 = f1[i] - f2[i]; /* f1[i] - f2[i] */ a[j] = (Word16)((t0 + r) >> q_sug); /* from Q23 to Q12 and * 0.5 */ } a[0] = (Word16)(a[0] >> q); } else { q_sug = 12; r = 1 << (q_sug - 1); q = 0; } /* a[NC] = 0.5*f1[NC]*(1.0 + isp[M-1]); */ D_UTIL_l_extract(f1[nc], &hi, &lo); t0 = D_UTIL_mpy_32_16(hi, lo, isp[m - 1]); t0 = f1[nc] + t0; a[nc] = (Word16)((t0 + r) >> q_sug); /* from Q23 to Q12 and * 0.5 */ /* a[m] = isp[m-1]; */ a[m] = (Word16)((isp[m - 1] >> (2 + q)) + 1); /* from Q15 to Q12 */ a[m] = (Word16)(a[m] >> 1); return; } /* * D_LPC_a_weight * * Parameters: * a I: LP filter coefficients * ap O: weighted LP filter coefficients * gamma I: weighting factor * m I: order of LP filter * * Function: * Weighting of LP filter coefficients, ap[i] = a[i] * (gamma^i). * * Returns: * void */ void D_LPC_a_weight(Word16 a[], Word16 ap[], Word16 gamma, Word16 m) { Word32 i, fac; ap[0] = a[0]; fac = gamma; for(i = 1; i < m; i++) { ap[i] = (Word16)(((a[i] * fac) + 0x4000) >> 15); fac = ((fac * gamma) + 0x4000) >> 15; } ap[m] = (Word16)(((a[m] * fac) + 0x4000) >> 15); return; } /* * D_LPC_isf_2s3s_decode * * Parameters: * indice I: quantisation indices * isf_q O: quantised ISFs in the cosine domain * past_isfq I/O: past ISF quantizer * isfold I: past quantised ISF * isf_buf O: isf buffer * bfi I: Bad frame indicator * * Function: * Decoding of ISF parameters. * * Returns: * void */ void D_LPC_isf_2s3s_decode(Word16 *indice, Word16 *isf_q, Word16 *past_isfq, Word16 *isfold, Word16 *isf_buf, Word16 bfi) { Word32 ref_isf[M]; Word32 L_tmp, i, j; Word16 tmp; if(bfi == 0) /* Good frame */ { for(i = 0; i < 9; i++) { isf_q[i] = D_ROM_dico1_isf[indice[0] * 9 + i]; } for(i = 0; i < 7; i++) { isf_q[i + 9] = D_ROM_dico2_isf[indice[1] * 7 + i]; } for(i = 0; i < 5; i++) { isf_q[i] = (Word16)(isf_q[i] + D_ROM_dico21_isf_36b[indice[2] * 5 + i]); } for(i = 0; i < 4; i++) { isf_q[i + 5] = (Word16)(isf_q[i + 5] + D_ROM_dico22_isf_36b[indice[3] * 4 + i]); } for(i = 0; i < 7; i++) { isf_q[i + 9] = (Word16)(isf_q[i + 9] + D_ROM_dico23_isf_36b[indice[4] * 7 + i]); } for(i = 0; i < ORDER; i++) { tmp = isf_q[i]; isf_q[i] = (Word16)((tmp + D_ROM_mean_isf[i]) + ((MU * past_isfq[i]) >> 15)); past_isfq[i] = tmp; } for(i = 0; i < M; i++) { for(j = (L_MEANBUF - 1); j > 0; j--) { isf_buf[j * M + i] = isf_buf[(j - 1) * M + i]; } isf_buf[i] = isf_q[i]; } } else { /* bad frame */ for(i = 0; i < M; i++) { L_tmp = D_ROM_mean_isf[i]; for(j = 0; j < L_MEANBUF; j++) { L_tmp = L_tmp + isf_buf[j * M + i]; } ref_isf[i] = (L_tmp + 0x1) >> 2; } /* use the past ISFs slightly shifted towards their mean */ for(i = 0; i < ORDER; i++) { isf_q[i] = (Word16)((((ALPHA * isfold[i]) >> 15) + ((ONE_ALPHA * ref_isf[i]) >> 15))); } /* estimate past quantized residual to be used in next frame */ for(i = 0; i < ORDER; i++) { /* predicted ISF */ L_tmp = ref_isf[i] + ((past_isfq[i] * MU) >> 15); /* past_isfq[i] *= 0.5 */ past_isfq[i] = (Word16)((isf_q[i] - L_tmp) >> 1); } } D_LPC_isf_reorder(isf_q, ISF_GAP, ORDER); return; } /* * D_LPC_isf_2s5s_decode * * Parameters: * indice I: quantization indices * isf_q O: quantized ISFs in the cosine domain * past_isfq I/O: past ISF quantizer * isfold I: past quantized ISF * isf_buf O: isf buffer * bfi I: Bad frame indicator * * Function: * Decoding of ISF parameters. * * Returns: * void */ void D_LPC_isf_2s5s_decode(Word16 *indice, Word16 *isf_q, Word16 *past_isfq, Word16 *isfold, Word16 *isf_buf, Word16 bfi) { Word32 ref_isf[M]; Word32 i, j, L_tmp; Word16 tmp; if(bfi == 0) /* Good frame */ { for(i = 0; i < 9; i++) { isf_q[i] = D_ROM_dico1_isf[indice[0] * 9 + i]; } for(i = 0; i < 7; i++) { isf_q[i + 9] = D_ROM_dico2_isf[indice[1] * 7 + i]; } for(i = 0; i < 3; i++) { isf_q[i] = (Word16)(isf_q[i] + D_ROM_dico21_isf[indice[2] * 3 + i]); } for(i = 0; i < 3; i++) { isf_q[i + 3] = (Word16)(isf_q[i + 3] + D_ROM_dico22_isf[indice[3] * 3 + i]); } for(i = 0; i < 3; i++) { isf_q[i + 6] = (Word16)(isf_q[i + 6] + D_ROM_dico23_isf[indice[4] * 3 + i]); } for(i = 0; i < 3; i++) { isf_q[i + 9] = (Word16)(isf_q[i + 9] + D_ROM_dico24_isf[indice[5] * 3 + i]); } for(i = 0; i < 4; i++) { isf_q[i + 12] = (Word16)(isf_q[i + 12] + D_ROM_dico25_isf[indice[6] * 4 + i]); } for(i = 0; i < ORDER; i++) { tmp = isf_q[i]; isf_q[i] = (Word16)((tmp + D_ROM_mean_isf[i]) + ((MU * past_isfq[i]) >> 15)); past_isfq[i] = tmp; } for(i = 0; i < M; i++) { for(j = (L_MEANBUF - 1); j > 0; j--) { isf_buf[j * M + i] = isf_buf[(j - 1) * M + i]; } isf_buf[i] = isf_q[i]; } } else { /* bad frame */ for(i = 0; i < M; i++) { L_tmp = D_ROM_mean_isf[i]; for(j = 0; j < L_MEANBUF; j++) { L_tmp = L_tmp + isf_buf[j * M + i]; } ref_isf[i] = (L_tmp + 0x1) >> 2; } /* use the past ISFs slightly shifted towards their mean */ for(i = 0; i < ORDER; i++) { isf_q[i] = (Word16)(((ALPHA * isfold[i]) >> 15) + ((ONE_ALPHA * ref_isf[i]) >> 15)); } /* estimate past quantized residual to be used in next frame */ for(i = 0; i < ORDER; i++) { /* predicted ISF */ L_tmp = ref_isf[i] + ((past_isfq[i] * MU) >> 15); /* past_isfq[i] *= 0.5 */ past_isfq[i] = (Word16)((isf_q[i] - L_tmp) >> 1); } } D_LPC_isf_reorder(isf_q, ISF_GAP, ORDER); return; } /* * D_LPC_int_isp_find * * Parameters: * isp_old I: isps from past frame * isp_new I: isps from present frame * frac I: (Q15) fraction for 3 first subfr * Az O: LP coefficients in 4 subframes * * Function: * Find the interpolated ISP parameters for all subframes. * * Returns: * void */ void D_LPC_int_isp_find(Word16 isp_old[], Word16 isp_new[], const Word16 frac[], Word16 Az[]) { Word32 tmp, i, k, fac_old, fac_new; Word16 isp[M]; for(k = 0; k < 3; k++) { fac_new = frac[k]; fac_old = (32767 - fac_new) + 1; /* 1.0 - fac_new */ for(i = 0; i < M; i++) { tmp = isp_old[i] * fac_old; tmp += isp_new[i] * fac_new; isp[i] = (Word16)((tmp + 0x4000) >> 15); } D_LPC_isp_a_conversion(isp, Az, 0, M); Az += MP1; } /* 4th subframe: isp_new (frac=1.0) */ D_LPC_isp_a_conversion(isp_new, Az, 0, M); return; } /* * D_LPC_isf_extrapolation * * Parameters: * HfIsf I/O: ISF vector * * Function: * Conversion of 16th-order 12.8kHz ISF vector * into 20th-order 16kHz ISF vector * * Returns: * void */ void D_LPC_isf_extrapolation(Word16 HfIsf[]) { Word32 IsfDiff[M - 2]; Word32 IsfCorr[3]; Word32 tmp, tmp2, tmp3, mean, i; Word32 MaxCorr, exp, exp2, coeff; Word16 hi, lo; HfIsf[M16k - 1] = HfIsf[M - 1]; /* Difference vector */ for(i = 1; i < M - 1; i++) { IsfDiff[i - 1] = HfIsf[i] - HfIsf[i - 1]; } tmp = 0; /* Mean of difference vector */ for(i = 3; i < (M - 1); i++) { tmp = tmp + (IsfDiff[i - 1] * INV_LENGTH); } mean = (tmp + 0x4000) >> 15; IsfCorr[0] = 0; IsfCorr[1] = 0; IsfCorr[2] = 0; tmp = 0; for(i = 0; i < M - 2; i++) { if(IsfDiff[i] > tmp) { tmp = IsfDiff[i]; } } exp = D_UTIL_norm_s((Word16)tmp); for(i = 0; i < M - 2; i++) { IsfDiff[i] = IsfDiff[i] << exp; } mean = mean << exp; for(i = 7; i < M - 2; i++) { tmp2 = IsfDiff[i] - mean; tmp3 = IsfDiff[i - 2] - mean; tmp = (tmp2 * tmp3) << 1; D_UTIL_l_extract(tmp, &hi, &lo); tmp = D_UTIL_mpy_32(hi, lo, hi, lo); IsfCorr[0] = (IsfCorr[0] + tmp); } for(i = 7; i < M - 2; i++) { tmp2 = IsfDiff[i] - mean; tmp3 = IsfDiff[i - 3] - mean; tmp = (tmp2 * tmp3) << 1; D_UTIL_l_extract(tmp, &hi, &lo); tmp = D_UTIL_mpy_32(hi, lo, hi, lo); IsfCorr[1] = (IsfCorr[1] + tmp); } for(i = 7; i < M - 2; i++) { tmp2 = IsfDiff[i] - mean; tmp3 = IsfDiff[i - 4] - mean; tmp = (tmp2 * tmp3) << 1; D_UTIL_l_extract(tmp, &hi, &lo); tmp = D_UTIL_mpy_32(hi, lo, hi, lo); IsfCorr[2] = (IsfCorr[2] + tmp); } if(IsfCorr[0] > IsfCorr[1]) { MaxCorr = 0; } else { MaxCorr = 1; } if(IsfCorr[2] > IsfCorr[MaxCorr]) { MaxCorr = 2; } MaxCorr = MaxCorr + 1; /* Maximum correlation of difference vector */ for(i = M - 1; i < (M16k - 1); i++) { tmp = (HfIsf[i - 1 - MaxCorr] - HfIsf[i - 2 - MaxCorr]); HfIsf[i] = (Word16)(HfIsf[i - 1] + tmp); } /* tmp=7965+(HfIsf[2]-HfIsf[3]-HfIsf[4])/6; */ tmp = HfIsf[4] + HfIsf[3]; tmp = HfIsf[2] - tmp; tmp = (tmp * 5461) >> 15; tmp = tmp + 20390; if(tmp > 19456) { /* Maximum value of ISF should be at most 7600 Hz */ tmp = 19456; } tmp = tmp - HfIsf[M - 2]; tmp2 = HfIsf[M16k - 2] - HfIsf[M - 2]; exp2 = D_UTIL_norm_s((Word16)tmp2); exp = D_UTIL_norm_s((Word16)tmp); exp = exp - 1; tmp = tmp << exp; tmp2 = tmp2 << exp2; coeff = (tmp << 15) / tmp2; /* Coefficient for stretching the ISF vector */ exp = exp2 - exp; if(exp >= 0) { for(i = M - 1; i < M16k - 1; i++) { tmp = ((HfIsf[i] - HfIsf[i - 1]) * coeff) >> 15; IsfDiff[i - (M - 1)] = tmp << exp; } } else { exp = 15 - exp; for(i = M - 1; i < M16k - 1; i++) { IsfDiff[i - (M - 1)] = ((HfIsf[i] - HfIsf[i - 1]) * coeff) >> exp; } } for(i = M; i < (M16k - 1); i++) { /* The difference between ISF(n) and ISF(n-2) should be at least 500 Hz */ tmp = ((IsfDiff[i - (M - 1)] + IsfDiff[i - M]) - 1280); if(tmp < 0) { if(IsfDiff[i - (M - 1)] > IsfDiff[i - M]) { IsfDiff[i - M] = (1280 - IsfDiff[i - (M - 1)]); } else { IsfDiff[i - (M - 1)] = (1280 - IsfDiff[i - M]); } } } for(i = M - 1; i < M16k - 1; i++) { HfIsf[i] = (Word16)(HfIsf[i - 1] + IsfDiff[i - (M - 1)]); } for(i = 0; i < M16k - 1; i++) { HfIsf[i] = (Word16)((HfIsf[i] * 13107) >> 14); /* Scale the ISF vector correctly for 16000 kHz */ } D_LPC_isf_isp_conversion(HfIsf, HfIsf, M16k); return; }