/*---------------------------------------------------------------------------*\ Original copyright FILE........: AKSLSPD.C TYPE........: Turbo C COMPANY.....: Voicetronix AUTHOR......: David Rowe DATE CREATED: 24/2/93 Heavily modified by Jean-Marc Valin (fixed-point, optimizations, additional functions, ...) This file contains functions for converting Linear Prediction Coefficients (LPC) to Line Spectral Pair (LSP) and back. Note that the LSP coefficients are not in radians format but in the x domain of the unit circle. Speex License: Redistribution and use in source and binary forms, with or without modification, are permitted provided that the following conditions are met: - Redistributions of source code must retain the above copyright notice, this list of conditions and the following disclaimer. - Redistributions in binary form must reproduce the above copyright notice, this list of conditions and the following disclaimer in the documentation and/or other materials provided with the distribution. - Neither the name of the Xiph.org Foundation nor the names of its contributors may be used to endorse or promote products derived from this software without specific prior written permission. THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS ``AS IS'' AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE FOUNDATION OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. */ #ifdef HAVE_CONFIG_H #include "config.h" #endif #ifdef _MSC_VER #include "winpoop.h" #endif #include #include "lsp.h" #include "stack_alloc.h" #include "math_approx.h" #ifndef M_PI #define M_PI 3.14159265358979323846 /* pi */ #endif #ifndef NULL #define NULL 0 #endif #ifdef FIXED_POINT #define C1 8192 #define C2 -4096 #define C3 340 #define C4 -10 static spx_word16_t spx_cos(spx_word16_t x) { spx_word16_t x2; if (x<12868) { x2 = MULT16_16_P13(x,x); return ADD32(C1, MULT16_16_P13(x2, ADD32(C2, MULT16_16_P13(x2, ADD32(C3, MULT16_16_P13(C4, x2)))))); } else { x = SUB16(25736,x); x2 = MULT16_16_P13(x,x); return SUB32(-C1, MULT16_16_P13(x2, ADD32(C2, MULT16_16_P13(x2, ADD32(C3, MULT16_16_P13(C4, x2)))))); /*return SUB32(-C1, MULT16_16_Q13(x2, ADD32(C2, MULT16_16_Q13(C3, x2))));*/ } } #define FREQ_SCALE 16384 /*#define ANGLE2X(a) (32768*cos(((a)/8192.)))*/ #define ANGLE2X(a) (SHL16(spx_cos(a),2)) /*#define X2ANGLE(x) (acos(.00006103515625*(x))*LSP_SCALING)*/ #define X2ANGLE(x) (spx_acos(x)) #else /*#define C1 0.99940307 #define C2 -0.49558072 #define C3 0.03679168*/ #define C1 0.9999932946f #define C2 -0.4999124376f #define C3 0.0414877472f #define C4 -0.0012712095f #define SPX_PI_2 1.5707963268 static inline spx_word16_t spx_cos(spx_word16_t x) { if (x>1; VARDECL(spx_word16_t *coefn); /*Prevents overflows*/ if (x>16383) x = 16383; if (x<-16383) x = -16383; /* Allocate memory for Chebyshev series formulation */ ALLOC(T, m2+1, spx_word16_t); ALLOC(coefn, m2+1, spx_word16_t); for (i=0;i>1; /* Allocate memory for Chebyshev series formulation */ ALLOC(T, m2+1, float); /* Initialise values */ T[0]=1; T[1]=x; /* Evaluate Chebyshev series formulation using iterative approach */ /* Evaluate polynomial and return value also free memory space */ sum = coef[m2] + coef[m2-1]*x; x *= 2; for(i=2;i<=m2;i++) { T[i] = x*T[i-1] - T[i-2]; sum += coef[m2-i] * T[i]; } return sum; } #endif /*---------------------------------------------------------------------------*\ FUNCTION....: lpc_to_lsp() AUTHOR......: David Rowe DATE CREATED: 24/2/93 This function converts LPC coefficients to LSP coefficients. \*---------------------------------------------------------------------------*/ #ifdef FIXED_POINT #define SIGN_CHANGE(a,b) (((a)&0x70000000)^((b)&0x70000000)||(b==0)) #else #define SIGN_CHANGE(a,b) (((a)*(b))<0.0) #endif int lpc_to_lsp (spx_coef_t *a,int lpcrdr,spx_lsp_t *freq,int nb,spx_word16_t delta, char *stack) /* float *a lpc coefficients */ /* int lpcrdr order of LPC coefficients (10) */ /* float *freq LSP frequencies in the x domain */ /* int nb number of sub-intervals (4) */ /* float delta grid spacing interval (0.02) */ { spx_word16_t temp_xr,xl,xr,xm=0; spx_word32_t psuml,psumr,psumm,temp_psumr/*,temp_qsumr*/; int i,j,m,flag,k; VARDECL(spx_word32_t *Q); /* ptrs for memory allocation */ VARDECL(spx_word32_t *P); spx_word32_t *px; /* ptrs of respective P'(z) & Q'(z) */ spx_word32_t *qx; spx_word32_t *p; spx_word32_t *q; spx_word32_t *pt; /* ptr used for cheb_poly_eval() whether P' or Q' */ int roots=0; /* DR 8/2/94: number of roots found */ flag = 1; /* program is searching for a root when, 1 else has found one */ m = lpcrdr/2; /* order of P'(z) & Q'(z) polynomials */ /* Allocate memory space for polynomials */ ALLOC(Q, (m+1), spx_word32_t); ALLOC(P, (m+1), spx_word32_t); /* determine P'(z)'s and Q'(z)'s coefficients where P'(z) = P(z)/(1 + z^(-1)) and Q'(z) = Q(z)/(1-z^(-1)) */ px = P; /* initialise ptrs */ qx = Q; p = px; q = qx; #ifdef FIXED_POINT *px++ = LPC_SCALING; *qx++ = LPC_SCALING; for(i=1;i<=m;i++){ *px++ = SUB32(ADD32(EXTEND32(a[i]),EXTEND32(a[lpcrdr+1-i])), *p++); *qx++ = ADD32(SUB32(EXTEND32(a[i]),EXTEND32(a[lpcrdr+1-i])), *q++); } px = P; qx = Q; for(i=0;i=32768) speex_warning_int("px", *px); if (fabs(*qx)>=32768) speex_warning_int("qx", *qx);*/ *px = PSHR32(*px,2); *qx = PSHR32(*qx,2); px++; qx++; } /* The reason for this lies in the way cheb_poly_eva() is implemented for fixed-point */ P[m] = PSHR32(P[m],3); Q[m] = PSHR32(Q[m],3); #else *px++ = LPC_SCALING; *qx++ = LPC_SCALING; for(i=1;i<=m;i++){ *px++ = (a[i]+a[lpcrdr+1-i]) - *p++; *qx++ = (a[i]-a[lpcrdr+1-i]) + *q++; } px = P; qx = Q; for(i=0;i= -FREQ_SCALE)){ spx_word16_t dd; /* Modified by JMV to provide smaller steps around x=+-1 */ #ifdef FIXED_POINT dd = MULT16_16_Q15(delta,SUB16(FREQ_SCALE, MULT16_16_Q14(MULT16_16_Q14(xl,xl),14000))); if (psuml<512 && psuml>-512) dd = PSHR16(dd,1); #else dd=delta*(1-.9*xl*xl); if (fabs(psuml)<.2) dd *= .5; #endif xr = SUB16(xl, dd); /* interval spacing */ psumr = cheb_poly_eva(pt,xr,lpcrdr,stack);/* poly(xl-delta_x) */ temp_psumr = psumr; temp_xr = xr; /* if no sign change increment xr and re-evaluate poly(xr). Repeat til sign change. if a sign change has occurred the interval is bisected and then checked again for a sign change which determines in which interval the zero lies in. If there is no sign change between poly(xm) and poly(xl) set interval between xm and xr else set interval between xl and xr and repeat till root is located within the specified limits */ if(SIGN_CHANGE(psumr,psuml)) { roots++; psumm=psuml; for(k=0;k<=nb;k++){ #ifdef FIXED_POINT xm = ADD16(PSHR16(xl,1),PSHR16(xr,1)); /* bisect the interval */ #else xm = .5*(xl+xr); /* bisect the interval */ #endif psumm=cheb_poly_eva(pt,xm,lpcrdr,stack); /*if(psumm*psuml>0.)*/ if(!SIGN_CHANGE(psumm,psuml)) { psuml=psumm; xl=xm; } else { psumr=psumm; xr=xm; } } /* once zero is found, reset initial interval to xr */ freq[j] = X2ANGLE(xm); xl = xm; flag = 0; /* reset flag for next search */ } else{ psuml=temp_psumr; xl=temp_xr; } } } return(roots); } /*---------------------------------------------------------------------------*\ FUNCTION....: lsp_to_lpc() AUTHOR......: David Rowe DATE CREATED: 24/2/93 lsp_to_lpc: This function converts LSP coefficients to LPC coefficients. \*---------------------------------------------------------------------------*/ #ifdef FIXED_POINT void lsp_to_lpc(spx_lsp_t *freq,spx_coef_t *ak,int lpcrdr, char *stack) /* float *freq array of LSP frequencies in the x domain */ /* float *ak array of LPC coefficients */ /* int lpcrdr order of LPC coefficients */ { int i,j; spx_word32_t xout1,xout2,xin1,xin2; VARDECL(spx_word32_t *Wp); spx_word32_t *pw,*n1,*n2,*n3,*n4=NULL; VARDECL(spx_word16_t *freqn); int m = lpcrdr>>1; ALLOC(freqn, lpcrdr, spx_word16_t); for (i=0;iSHL(32766,8)) ak[j] = 32767; else if (xout1 + xout2 < -SHL(32766,8)) ak[j] = -32767; else ak[j] = EXTRACT16(PSHR32(ADD32(xout1,xout2),8)); *(n4+1) = xin1; *(n4+2) = xin2; xin1 = 0; xin2 = 0; } } #else void lsp_to_lpc(spx_lsp_t *freq,spx_coef_t *ak,int lpcrdr, char *stack) /* float *freq array of LSP frequencies in the x domain */ /* float *ak array of LPC coefficients */ /* int lpcrdr order of LPC coefficients */ { int i,j; float xout1,xout2,xin1,xin2; VARDECL(float *Wp); float *pw,*n1,*n2,*n3,*n4=NULL; VARDECL(float *x_freq); int m = lpcrdr>>1; ALLOC(Wp, 4*m+2, float); pw = Wp; /* initialise contents of array */ for(i=0;i<=4*m+1;i++){ /* set contents of buffer to 0 */ *pw++ = 0.0; } /* Set pointers up */ pw = Wp; xin1 = 1.0; xin2 = 1.0; ALLOC(x_freq, lpcrdr, float); for (i=0;im2) lsp[len-1]=m2; for (i=1;ilsp[i+1]-m) lsp[i]= SHR16(lsp[i],1) + SHR16(lsp[i+1]-m,1); } } void lsp_interpolate(spx_lsp_t *old_lsp, spx_lsp_t *new_lsp, spx_lsp_t *interp_lsp, int len, int subframe, int nb_subframes) { int i; spx_word16_t tmp = DIV32_16(SHL32(1 + subframe,14),nb_subframes); spx_word16_t tmp2 = 16384-tmp; for (i=0;iLSP_SCALING*(M_PI-margin)) lsp[len-1]=LSP_SCALING*(M_PI-margin); for (i=1;ilsp[i+1]-LSP_SCALING*margin) lsp[i]= .5f* (lsp[i] + lsp[i+1]-LSP_SCALING*margin); } } void lsp_interpolate(spx_lsp_t *old_lsp, spx_lsp_t *new_lsp, spx_lsp_t *interp_lsp, int len, int subframe, int nb_subframes) { int i; float tmp = (1.0f + subframe)/nb_subframes; for (i=0;i