ref: 8f56b0d4535e9b6d46fb22f5b52e26b25e8d46a2
dir: /lpc10/bsynz.c/
/* * Revision 1.2 1996/08/20 20:18:55 jaf * Removed all static local variables that were SAVE'd in the Fortran * code, and put them in struct lpc10_decoder_state that is passed as an * argument. * * Removed init function, since all initialization is now done in * init_lpc10_decoder_state(). * * Revision 1.1 1996/08/19 22:32:58 jaf * Initial revision * */ /* -- translated by f2c (version 19951025). You must link the resulting object file with the libraries: -lf2c -lm (in that order) */ #include "f2c.h" int bsynz_(real *coef, integer *ip, integer *iv, real *sout, real *rms, real *ratio, real *g2pass, struct lpc10_decoder_state *st); /* Common Block Declarations */ extern struct { integer order, lframe; logical corrp; } contrl_; #define contrl_1 contrl_ /* ***************************************************************** */ /* BSYNZ Version 54 */ /* * Revision 1.2 1996/08/20 20:18:55 jaf * Removed all static local variables that were SAVE'd in the Fortran * code, and put them in struct lpc10_decoder_state that is passed as an * argument. * * Removed init function, since all initialization is now done in * init_lpc10_decoder_state(). * * Revision 1.1 1996/08/19 22:32:58 jaf * Initial revision * */ /* Revision 1.4 1996/03/27 18:11:22 jaf */ /* Changed the range of NOISE printed out in the debugging statements, */ /* even though they are commented out. I didn't discover this until I */ /* tried comparing two different versions of the LPC-10 coder, each with */ /* full tracing enabled. */ /* Revision 1.3 1996/03/26 19:33:23 jaf */ /* Commented out trace statements. */ /* Revision 1.2 1996/03/20 17:12:54 jaf */ /* Added comments about which indices of array arguments are read or */ /* written. */ /* Rearranged local variable declarations to indicate which need to be */ /* saved from one invocation to the next. Added entry INITBSYNZ to */ /* reinitialize the local state variables, if desired. */ /* Revision 1.1 1996/02/07 14:43:15 jaf */ /* Initial revision */ /* ***************************************************************** */ /* Synthesize One Pitch Epoch */ /* Input: */ /* COEF - Predictor coefficients */ /* Indices 1 through ORDER read. */ /* IP - Pitch period (number of samples to synthesize) */ /* IV - Voicing for the current epoch */ /* RMS - Energy for the current epoch */ /* RATIO - Energy slope for plosives */ /* G2PASS- Sharpening factor for 2 pass synthesis */ /* Output: */ /* SOUT - Synthesized speech */ /* Indices 1 through IP written. */ /* This subroutine maintains local state from one call to the next. If */ /* you want to switch to using a new audio stream for this filter, or */ /* reinitialize its state for any other reason, call the ENTRY */ /* INITBSYNZ. */ /* Subroutine */ int bsynz_(real *coef, integer *ip, integer *iv, real *sout, real *rms, real *ratio, real *g2pass, struct lpc10_decoder_state *st) { /* Initialized data */ integer *ipo; real *rmso; static integer kexc[25] = { 8,-16,26,-48,86,-162,294,-502,718,-728,184, 672,-610,-672,184,728,718,502,294,162,86,48,26,16,8 }; real *exc; real *exc2; real *lpi1; real *lpi2; real *lpi3; real *hpi1; real *hpi2; real *hpi3; /* System generated locals */ integer i__1, i__2; real r__1, r__2; /* Builtin functions */ double sqrt(doublereal); /* Local variables */ real gain, xssq; integer i__, j, k; real noise[166], pulse; integer px; real sscale; extern integer random_(struct lpc10_decoder_state *); real xy, sum, ssq; real lpi0, hpi0; /* LPC Processing control variables: */ /* *** Read-only: initialized in setup */ /* Files for Speech, Parameter, and Bitstream Input & Output, */ /* and message and debug outputs. */ /* Here are the only files which use these variables: */ /* lpcsim.f setup.f trans.f error.f vqsetup.f */ /* Many files which use fdebug are not listed, since it is only used in */ /* those other files conditionally, to print trace statements. */ /* integer fsi, fso, fpi, fpo, fbi, fbo, pbin, fmsg, fdebug */ /* LPC order, Frame size, Quantization rate, Bits per frame, */ /* Error correction */ /* Subroutine SETUP is the only place where order is assigned a value, */ /* and that value is 10. It could increase efficiency 1% or so to */ /* declare order as a constant (i.e., a Fortran PARAMETER) instead of as */ /* a variable in a COMMON block, since it is used in many places in the */ /* core of the coding and decoding routines. Actually, I take that back. */ /* At least when compiling with f2c, the upper bound of DO loops is */ /* stored in a local variable before the DO loop begins, and then that is */ /* compared against on each iteration. */ /* Similarly for lframe, which is given a value of MAXFRM in SETUP. */ /* Similarly for quant, which is given a value of 2400 in SETUP. quant */ /* is used in only a few places, and never in the core coding and */ /* decoding routines, so it could be eliminated entirely. */ /* nbits is similar to quant, and is given a value of 54 in SETUP. */ /* corrp is given a value of .TRUE. in SETUP, and is only used in the */ /* subroutines ENCODE and DECODE. It doesn't affect the speed of the */ /* coder significantly whether it is .TRUE. or .FALSE., or whether it is */ /* a constant or a variable, since it is only examined once per frame. */ /* Leaving it as a variable that is set to .TRUE. seems like a good */ /* idea, since it does enable some error-correction capability for */ /* unvoiced frames, with no change in the coding rate, and no noticeable */ /* quality difference in the decoded speech. */ /* integer quant, nbits */ /* *** Read/write: variables for debugging, not needed for LPC algorithm */ /* Current frame, Unstable frames, Output clip count, Max onset buffer, */ /* Debug listing detail level, Line count on listing page */ /* nframe is not needed for an embedded LPC10 at all. */ /* nunsfm is initialized to 0 in SETUP, and incremented in subroutine */ /* ERROR, which is only called from RCCHK. When LPC10 is embedded into */ /* an application, I would recommend removing the call to ERROR in RCCHK, */ /* and remove ERROR and nunsfm completely. */ /* iclip is initialized to 0 in SETUP, and incremented in entry SWRITE in */ /* sread.f. When LPC10 is embedded into an application, one might want */ /* to cause it to be incremented in a routine that takes the output of */ /* SYNTHS and sends it to an audio device. It could be optionally */ /* displayed, for those that might want to know what it is. */ /* maxosp is never initialized to 0 in SETUP, although it probably should */ /* be, and it is updated in subroutine ANALYS. I doubt that its value */ /* would be of much interest to an application in which LPC10 is */ /* embedded. */ /* listl and lincnt are not needed for an embedded LPC10 at all. */ /* integer nframe, nunsfm, iclip, maxosp, listl, lincnt */ /* common /contrl/ fsi, fso, fpi, fpo, fbi, fbo, pbin, fmsg, fdebug */ /* common /contrl/ quant, nbits */ /* common /contrl/ nframe, nunsfm, iclip, maxosp, listl, lincnt */ /* Function return value definitions */ /* Parameters/constants */ /* KEXC is not a Fortran PARAMETER, but it is an array initialized */ /* with a DATA statement that is never modified. */ /* Local variables that need not be saved */ /* NOISE is declared with range (1:MAXPIT+MAXORD), but only indices */ /* ORDER+1 through ORDER+IP are ever used, and I think that IP */ /* .LE. MAXPIT. Why not declare it to be in the range (1:MAXPIT) */ /* and use that range? */ /* Local state */ /* I believe that only indices 1 through ORDER of EXC need to be */ /* saved from one invocation to the next, but we may as well save */ /* the whole array. */ /* None of these local variables were given initial values in the */ /* original code. I'm guessing that 0 is a reasonable initial */ /* value for all of them. */ /* Parameter adjustments */ if (coef) { --coef; } if (sout) { --sout; } /* Function Body */ ipo = &(st->ipo); exc = &(st->exc[0]); exc2 = &(st->exc2[0]); lpi1 = &(st->lpi1); lpi2 = &(st->lpi2); lpi3 = &(st->lpi3); hpi1 = &(st->hpi1); hpi2 = &(st->hpi2); hpi3 = &(st->hpi3); rmso = &(st->rmso_bsynz); /* MAXPIT+MAXORD=166 */ /* Calculate history scale factor XY and scale filter state */ /* Computing MIN */ r__1 = *rmso / (*rms + 1e-6f); xy = min(r__1,8.f); *rmso = *rms; i__1 = contrl_1.order; for (i__ = 1; i__ <= i__1; ++i__) { exc2[i__ - 1] = exc2[*ipo + i__ - 1] * xy; } *ipo = *ip; if (*iv == 0) { /* Generate white noise for unvoiced */ i__1 = *ip; for (i__ = 1; i__ <= i__1; ++i__) { exc[contrl_1.order + i__ - 1] = (real) (random_(st) / 64); } /* Impulse doublet excitation for plosives */ /* (RANDOM()+32768) is in the range 0 to 2**16-1. Therefore the */ /* following expression should be evaluated using integers with at */ /* least 32 bits (16 isn't enough), and PX should be in the rang e */ /* ORDER+1+0 through ORDER+1+(IP-2) .EQ. ORDER+IP-1. */ px = (random_(st) + 32768) * (*ip - 1) / 65536 + contrl_1.order + 1; r__1 = *ratio / 4 * 1.f; pulse = r__1 * 342; if (pulse > 2e3f) { pulse = 2e3f; } exc[px - 1] += pulse; exc[px] -= pulse; /* Load voiced excitation */ } else { sscale = sqrt((real) (*ip)) / 6.928f; i__1 = *ip; for (i__ = 1; i__ <= i__1; ++i__) { exc[contrl_1.order + i__ - 1] = 0.f; if (i__ <= 25) { exc[contrl_1.order + i__ - 1] = sscale * kexc[i__ - 1]; } lpi0 = exc[contrl_1.order + i__ - 1]; r__2 = exc[contrl_1.order + i__ - 1] * .125f + *lpi1 * .75f; r__1 = r__2 + *lpi2 * .125f; exc[contrl_1.order + i__ - 1] = r__1 + *lpi3 * 0.f; *lpi3 = *lpi2; *lpi2 = *lpi1; *lpi1 = lpi0; } i__1 = *ip; for (i__ = 1; i__ <= i__1; ++i__) { noise[contrl_1.order + i__ - 1] = random_(st) * 1.f / 64; hpi0 = noise[contrl_1.order + i__ - 1]; r__2 = noise[contrl_1.order + i__ - 1] * -.125f + *hpi1 * .25f; r__1 = r__2 + *hpi2 * -.125f; noise[contrl_1.order + i__ - 1] = r__1 + *hpi3 * 0.f; *hpi3 = *hpi2; *hpi2 = *hpi1; *hpi1 = hpi0; } i__1 = *ip; for (i__ = 1; i__ <= i__1; ++i__) { exc[contrl_1.order + i__ - 1] += noise[contrl_1.order + i__ - 1]; } } /* Synthesis filters: */ /* Modify the excitation with all-zero filter 1 + G*SUM */ xssq = 0.f; i__1 = *ip; for (i__ = 1; i__ <= i__1; ++i__) { k = contrl_1.order + i__; sum = 0.f; i__2 = contrl_1.order; for (j = 1; j <= i__2; ++j) { sum += coef[j] * exc[k - j - 1]; } sum *= *g2pass; exc2[k - 1] = sum + exc[k - 1]; } /* Synthesize using the all pole filter 1 / (1 - SUM) */ i__1 = *ip; for (i__ = 1; i__ <= i__1; ++i__) { k = contrl_1.order + i__; sum = 0.f; i__2 = contrl_1.order; for (j = 1; j <= i__2; ++j) { sum += coef[j] * exc2[k - j - 1]; } exc2[k - 1] = sum + exc2[k - 1]; xssq += exc2[k - 1] * exc2[k - 1]; } /* Save filter history for next epoch */ i__1 = contrl_1.order; for (i__ = 1; i__ <= i__1; ++i__) { exc[i__ - 1] = exc[*ip + i__ - 1]; exc2[i__ - 1] = exc2[*ip + i__ - 1]; } /* Apply gain to match RMS */ r__1 = *rms * *rms; ssq = r__1 * *ip; gain = sqrt(ssq / xssq); i__1 = *ip; for (i__ = 1; i__ <= i__1; ++i__) { sout[i__] = gain * exc2[contrl_1.order + i__ - 1]; } return 0; } /* bsynz_ */