/* ** 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: q_gain2.c * * * * Description: * * Quantization of pitch and codebook gains. * * MA prediction is performed on the innovation energy (in dB with mean * * removed). * * An initial predicted gain, g_0, is first determined and the correction * * factor alpha = gain / g_0 is quantized. * * The pitch gain and the correction factor are vector quantized and the * * mean-squared weighted error criterion is used in the quantizer search. * ****************************************************************************/ #include "typedef.h" #include "basic_op.h" #include "oper_32b.h" #include "math_op.h" #include "log2.h" #include "acelp.h" #include "q_gain2.tab" #define MEAN_ENER 30 #define RANGE 64 #define PRED_ORDER 4 /* MA prediction coeff ={0.5, 0.4, 0.3, 0.2} in Q13 */ static Word16 pred[PRED_ORDER] = {4096, 3277, 2458, 1638}; void Init_Q_gain2( Word16 * mem /* output :static memory (2 words) */ ) { Word32 i; /* 4nd order quantizer energy predictor (init to -14.0 in Q10) */ for (i = 0; i < PRED_ORDER; i++) { mem[i] = -14336; /* past_qua_en[i] */ } return; } Word16 Q_gain2( /* Return index of quantization. */ Word16 xn[], /* (i) Q_xn: Target vector. */ Word16 y1[], /* (i) Q_xn: Adaptive codebook. */ Word16 Q_xn, /* (i) : xn and y1 format */ Word16 y2[], /* (i) Q9 : Filtered innovative vector. */ Word16 code[], /* (i) Q9 : Innovative vector. */ Word16 g_coeff[], /* (i) : Correlations */ /* Compute in G_pitch(). */ Word16 L_subfr, /* (i) : Subframe lenght. */ Word16 nbits, /* (i) : number of bits (6 or 7) */ Word16 * gain_pit, /* (i/o)Q14: Pitch gain. */ Word32 * gain_cod, /* (o) Q16 : Code gain. */ Word16 gp_clip, /* (i) : Gp Clipping flag */ Word16 * mem /* (i/o) : static memory (2 words) */ ) { Word16 index, *p, min_ind, size; Word16 exp, frac, gcode0, exp_gcode0, e_max, exp_code, qua_ener; Word16 g_pitch, g2_pitch, g_code, g_pit_cod, g2_code, g2_code_lo; Word16 coeff[5], coeff_lo[5], exp_coeff[5]; Word16 exp_max[5]; Word32 i, j, L_tmp, dist_min; Word16 *past_qua_en, *t_qua_gain; past_qua_en = mem; /*-----------------------------------------------------------------* * - Find the initial quantization pitch index * * - Set gains search range * *-----------------------------------------------------------------*/ if (nbits == 6) { t_qua_gain = t_qua_gain6b; min_ind = 0; size = RANGE; if(gp_clip == 1) { size = size - 16; /* limit gain pitch to 1.0 */ } } else { t_qua_gain = t_qua_gain7b; p = t_qua_gain7b + RANGE; /* pt at 1/4th of table */ j = nb_qua_gain7b - RANGE; if (gp_clip == 1) { j = j - 27; /* limit gain pitch to 1.0 */ } min_ind = 0; g_pitch = *gain_pit; for (i = 0; i < j; i++, p += 2) { if (g_pitch > *p) { min_ind = min_ind + 1; } } size = RANGE; } /*------------------------------------------------------------------* * Compute coefficient need for the quantization. * * * * coeff[0] = y1 y1 * * coeff[1] = -2 xn y1 * * coeff[2] = y2 y2 * * coeff[3] = -2 xn y2 * * coeff[4] = 2 y1 y2 * * * * Product and have been compute in G_pitch() and * * are in vector g_coeff[]. * *------------------------------------------------------------------*/ coeff[0] = g_coeff[0]; exp_coeff[0] = g_coeff[1]; coeff[1] = negate(g_coeff[2]); /* coeff[1] = -2 xn y1 */ exp_coeff[1] = g_coeff[3] + 1; /* Compute scalar product */ #ifdef ASM_OPT /* asm optimization branch */ coeff[2] = extract_h(Dot_product12_asm(y2, y2, L_subfr, &exp)); #else coeff[2] = extract_h(Dot_product12(y2, y2, L_subfr, &exp)); #endif exp_coeff[2] = (exp - 18) + (Q_xn << 1); /* -18 (y2 Q9) */ /* Compute scalar product -2* */ #ifdef ASM_OPT /* asm optimization branch */ coeff[3] = extract_h(L_negate(Dot_product12_asm(xn, y2, L_subfr, &exp))); #else coeff[3] = extract_h(L_negate(Dot_product12(xn, y2, L_subfr, &exp))); #endif exp_coeff[3] = (exp - 8) + Q_xn; /* -9 (y2 Q9), +1 (2 xn y2) */ /* Compute scalar product 2* */ #ifdef ASM_OPT /* asm optimization branch */ coeff[4] = extract_h(Dot_product12_asm(y1, y2, L_subfr, &exp)); #else coeff[4] = extract_h(Dot_product12(y1, y2, L_subfr, &exp)); #endif exp_coeff[4] = (exp - 8) + Q_xn; /* -9 (y2 Q9), +1 (2 y1 y2) */ /*-----------------------------------------------------------------* * Find energy of code and compute: * * * * L_tmp = MEAN_ENER - 10log10(energy of code/ L_subfr) * * = MEAN_ENER - 3.0103*log2(energy of code/ L_subfr) * *-----------------------------------------------------------------*/ #ifdef ASM_OPT /* asm optimization branch */ L_tmp = Dot_product12_asm(code, code, L_subfr, &exp_code); #else L_tmp = Dot_product12(code, code, L_subfr, &exp_code); #endif /* exp_code: -18 (code in Q9), -6 (/L_subfr), -31 (L_tmp Q31->Q0) */ exp_code = (exp_code - (18 + 6 + 31)); Log2(L_tmp, &exp, &frac); exp += exp_code; L_tmp = Mpy_32_16(exp, frac, -24660); /* x -3.0103(Q13) -> Q14 */ L_tmp += (MEAN_ENER * 8192)<<1; /* + MEAN_ENER in Q14 */ /*-----------------------------------------------------------------* * Compute gcode0. * * = Sum(i=0,1) pred[i]*past_qua_en[i] + mean_ener - ener_code * *-----------------------------------------------------------------*/ L_tmp = (L_tmp << 10); /* From Q14 to Q24 */ L_tmp += (pred[0] * past_qua_en[0])<<1; /* Q13*Q10 -> Q24 */ L_tmp += (pred[1] * past_qua_en[1])<<1; /* Q13*Q10 -> Q24 */ L_tmp += (pred[2] * past_qua_en[2])<<1; /* Q13*Q10 -> Q24 */ L_tmp += (pred[3] * past_qua_en[3])<<1; /* Q13*Q10 -> Q24 */ gcode0 = extract_h(L_tmp); /* From Q24 to Q8 */ /*-----------------------------------------------------------------* * gcode0 = pow(10.0, gcode0/20) * * = pow(2, 3.321928*gcode0/20) * * = pow(2, 0.166096*gcode0) * *-----------------------------------------------------------------*/ L_tmp = vo_L_mult(gcode0, 5443); /* *0.166096 in Q15 -> Q24 */ L_tmp = L_tmp >> 8; /* From Q24 to Q16 */ VO_L_Extract(L_tmp, &exp_gcode0, &frac); /* Extract exponent of gcode0 */ gcode0 = (Word16)(Pow2(14, frac)); /* Put 14 as exponent so that */ /* output of Pow2() will be: */ /* 16384 < Pow2() <= 32767 */ exp_gcode0 -= 14; /*-------------------------------------------------------------------------* * Find the best quantizer * * ~~~~~~~~~~~~~~~~~~~~~~~ * * Before doing the computation we need to aling exponents of coeff[] * * to be sure to have the maximum precision. * * * * In the table the pitch gains are in Q14, the code gains are in Q11 and * * are multiply by gcode0 which have been multiply by 2^exp_gcode0. * * Also when we compute g_pitch*g_pitch, g_code*g_code and g_pitch*g_code * * we divide by 2^15. * * Considering all the scaling above we have: * * * * exp_code = exp_gcode0-11+15 = exp_gcode0+4 * * * * g_pitch*g_pitch = -14-14+15 * * g_pitch = -14 * * g_code*g_code = (2*exp_code)+15 * * g_code = exp_code * * g_pitch*g_code = -14 + exp_code +15 * * * * g_pitch*g_pitch * coeff[0] ;exp_max0 = exp_coeff[0] - 13 * * g_pitch * coeff[1] ;exp_max1 = exp_coeff[1] - 14 * * g_code*g_code * coeff[2] ;exp_max2 = exp_coeff[2] +15+(2*exp_code) * * g_code * coeff[3] ;exp_max3 = exp_coeff[3] + exp_code * * g_pitch*g_code * coeff[4] ;exp_max4 = exp_coeff[4] + 1 + exp_code * *-------------------------------------------------------------------------*/ exp_code = (exp_gcode0 + 4); exp_max[0] = (exp_coeff[0] - 13); exp_max[1] = (exp_coeff[1] - 14); exp_max[2] = (exp_coeff[2] + (15 + (exp_code << 1))); exp_max[3] = (exp_coeff[3] + exp_code); exp_max[4] = (exp_coeff[4] + (1 + exp_code)); /* Find maximum exponant */ e_max = exp_max[0]; for (i = 1; i < 5; i++) { if(exp_max[i] > e_max) { e_max = exp_max[i]; } } /* align coeff[] and save in special 32 bit double precision */ for (i = 0; i < 5; i++) { j = add1(vo_sub(e_max, exp_max[i]), 2);/* /4 to avoid overflow */ L_tmp = L_deposit_h(coeff[i]); L_tmp = L_shr(L_tmp, j); VO_L_Extract(L_tmp, &coeff[i], &coeff_lo[i]); coeff_lo[i] = (coeff_lo[i] >> 3); /* lo >> 3 */ } /* Codebook search */ dist_min = MAX_32; p = &t_qua_gain[min_ind << 1]; index = 0; for (i = 0; i < size; i++) { g_pitch = *p++; g_code = *p++; g_code = ((g_code * gcode0) + 0x4000)>>15; g2_pitch = ((g_pitch * g_pitch) + 0x4000)>>15; g_pit_cod = ((g_code * g_pitch) + 0x4000)>>15; L_tmp = (g_code * g_code)<<1; VO_L_Extract(L_tmp, &g2_code, &g2_code_lo); L_tmp = (coeff[2] * g2_code_lo)<<1; L_tmp = (L_tmp >> 3); L_tmp += (coeff_lo[0] * g2_pitch)<<1; L_tmp += (coeff_lo[1] * g_pitch)<<1; L_tmp += (coeff_lo[2] * g2_code)<<1; L_tmp += (coeff_lo[3] * g_code)<<1; L_tmp += (coeff_lo[4] * g_pit_cod)<<1; L_tmp = (L_tmp >> 12); L_tmp += (coeff[0] * g2_pitch)<<1; L_tmp += (coeff[1] * g_pitch)<<1; L_tmp += (coeff[2] * g2_code)<<1; L_tmp += (coeff[3] * g_code)<<1; L_tmp += (coeff[4] * g_pit_cod)<<1; if(L_tmp < dist_min) { dist_min = L_tmp; index = i; } } /* Read the quantized gains */ index = index + min_ind; p = &t_qua_gain[(index + index)]; *gain_pit = *p++; /* selected pitch gain in Q14 */ g_code = *p++; /* selected code gain in Q11 */ L_tmp = vo_L_mult(g_code, gcode0); /* Q11*Q0 -> Q12 */ L_tmp = L_shl(L_tmp, (exp_gcode0 + 4)); /* Q12 -> Q16 */ *gain_cod = L_tmp; /* gain of code in Q16 */ /*---------------------------------------------------* * qua_ener = 20*log10(g_code) * * = 6.0206*log2(g_code) * * = 6.0206*(log2(g_codeQ11) - 11) * *---------------------------------------------------*/ L_tmp = L_deposit_l(g_code); Log2(L_tmp, &exp, &frac); exp -= 11; L_tmp = Mpy_32_16(exp, frac, 24660); /* x 6.0206 in Q12 */ qua_ener = (Word16)(L_tmp >> 3); /* result in Q10 */ /* update table of past quantized energies */ past_qua_en[3] = past_qua_en[2]; past_qua_en[2] = past_qua_en[1]; past_qua_en[1] = past_qua_en[0]; past_qua_en[0] = qua_ener; return (index); }