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bfea71b0c4
svn-id: r12110
959 lines
31 KiB
C++
959 lines
31 KiB
C++
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#include "stdafx.h"
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#include <math.h>
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#include "sound/resample.h"
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#include "sound/audiostream.h"
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#pragma mark -
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/**
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* Calculates the filter coeffs for a Kaiser-windowed low-pass filter with a
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* given roll-off frequency. These coeffs are stored into a array of doubles.
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*
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* reference: "Digital Filters, 2nd edition"
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* R.W. Hamming, pp. 178-179
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*
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* LpFilter() computes the coeffs of a Kaiser-windowed low pass filter with
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* the following characteristics:
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*
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* c[] = array in which to store computed coeffs
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* frq = roll-off frequency of filter
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* N = Half the window length in number of coeffs
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* Beta = parameter of Kaiser window
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* Num = number of coeffs before 1/frq
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*
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* Beta trades the rejection of the lowpass filter against the transition
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* width from passband to stopband. Larger Beta means a slower
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* transition and greater stopband rejection. See Rabiner and Gold
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* (Theory and Application of DSP) under Kaiser windows for more about
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* Beta. The following table from Rabiner and Gold gives some feel
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* for the effect of Beta:
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*
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* All ripples in dB, width of transition band = D*N where N = window length
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*
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* BETA D PB RIP SB RIP
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* 2.120 1.50 +-0.27 -30
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* 3.384 2.23 0.0864 -40
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* 4.538 2.93 0.0274 -50
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* 5.658 3.62 0.00868 -60
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* 6.764 4.32 0.00275 -70
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* 7.865 5.0 0.000868 -80
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* 8.960 5.7 0.000275 -90
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* 10.056 6.4 0.000087 -100
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*/
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static void LpFilter(double c[], int N, double frq, double Beta, int Num);
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/**
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* Calls LpFilter() to create a filter, then scales the double coeffs into an
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* array of half words.
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* ERROR return codes:
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* 0 - no error
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* 1 - Nwing too large (Nwing is > MAXNWING)
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* 2 - Froll is not in interval [0:1)
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* 3 - Beta is < 1.0
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* 4 - LpScl will not fit in 16-bits
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*/
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static int makeFilter(HWORD Imp[], HWORD ImpD[], UHWORD *LpScl, UHWORD Nwing,
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double Froll, double Beta);
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static WORD FilterUp(HWORD Imp[], HWORD ImpD[], UHWORD Nwing, bool Interp,
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HWORD *Xp, HWORD Inc, HWORD Ph);
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static WORD FilterUD(HWORD Imp[], HWORD ImpD[], UHWORD Nwing, bool Interp,
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HWORD *Xp, HWORD Ph, HWORD Inc, UHWORD dhb);
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#pragma mark -
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/*
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*
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* The configuration constants below govern
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* the number of bits in the input sample and filter coefficients, the
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* number of bits to the right of the binary-point for fixed-point math, etc.
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*
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*/
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/* Conversion constants */
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#define Nhc 8
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#define Na 7
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#define Np (Nhc+Na)
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#define Npc (1<<Nhc)
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#define Amask ((1<<Na)-1)
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#define Pmask ((1<<Np)-1)
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#define Nh 16
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#define Nb 16
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#define Nhxn 14
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#define Nhg (Nh-Nhxn)
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#define NLpScl 13
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/* Description of constants:
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*
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* Npc - is the number of look-up values available for the lowpass filter
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* between the beginning of its impulse response and the "cutoff time"
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* of the filter. The cutoff time is defined as the reciprocal of the
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* lowpass-filter cut off frequence in Hz. For example, if the
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* lowpass filter were a sinc function, Npc would be the index of the
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* impulse-response lookup-table corresponding to the first zero-
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* crossing of the sinc function. (The inverse first zero-crossing
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* time of a sinc function equals its nominal cutoff frequency in Hz.)
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* Npc must be a power of 2 due to the details of the current
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* implementation. The default value of 512 is sufficiently high that
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* using linear interpolation to fill in between the table entries
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* gives approximately 16-bit accuracy in filter coefficients.
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*
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* Nhc - is log base 2 of Npc.
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*
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* Na - is the number of bits devoted to linear interpolation of the
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* filter coefficients.
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*
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* Np - is Na + Nhc, the number of bits to the right of the binary point
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* in the integer "time" variable. To the left of the point, it indexes
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* the input array (X), and to the right, it is interpreted as a number
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* between 0 and 1 sample of the input X. Np must be less than 16 in
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* this implementation.
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*
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* Nh - is the number of bits in the filter coefficients. The sum of Nh and
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* the number of bits in the input data (typically 16) cannot exceed 32.
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* Thus Nh should be 16. The largest filter coefficient should nearly
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* fill 16 bits (32767).
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*
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* Nb - is the number of bits in the input data. The sum of Nb and Nh cannot
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* exceed 32.
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*
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* Nhxn - is the number of bits to right shift after multiplying each input
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* sample times a filter coefficient. It can be as great as Nh and as
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* small as 0. Nhxn = Nh-2 gives 2 guard bits in the multiply-add
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* accumulation. If Nhxn=0, the accumulation will soon overflow 32 bits.
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*
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* Nhg - is the number of guard bits in mpy-add accumulation (equal to Nh-Nhxn)
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*
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* NLpScl - is the number of bits allocated to the unity-gain normalization
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* factor. The output of the lowpass filter is multiplied by LpScl and
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* then right-shifted NLpScl bits. To avoid overflow, we must have
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* Nb+Nhg+NLpScl < 32.
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*/
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#pragma mark -
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#define IBUFFSIZE 4096 /* Input buffer size */
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static inline HWORD WordToHword(WORD v, int scl)
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{
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HWORD out;
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v = (v + (1 << (NLpScl-1))) >> NLpScl; // Round & scale
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if (v>MAX_HWORD) {
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v = MAX_HWORD;
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} else if (v < MIN_HWORD) {
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v = MIN_HWORD;
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}
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out = (HWORD) v;
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return out;
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}
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/* Sampling rate up-conversion only subroutine;
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* Slightly faster than down-conversion;
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*/
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static int SrcUp(HWORD X[], HWORD Y[], double factor, UWORD *Time,
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UHWORD Nx, UHWORD Nwing, UHWORD LpScl,
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HWORD Imp[], HWORD ImpD[], bool Interp)
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{
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HWORD *Xp, *Ystart;
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WORD v;
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double dt; /* Step through input signal */
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UWORD dtb; /* Fixed-point version of Dt */
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UWORD endTime; /* When Time reaches EndTime, return to user */
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dt = 1.0/factor; /* Output sampling period */
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dtb = (UWORD)(dt*(1<<Np) + 0.5); /* Fixed-point representation */
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Ystart = Y;
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endTime = *Time + (1<<Np)*(WORD)Nx;
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while (*Time < endTime)
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{
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Xp = &X[*Time>>Np]; /* Ptr to current input sample */
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/* Perform left-wing inner product */
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v = FilterUp(Imp, ImpD, Nwing, Interp, Xp, (HWORD)(*Time&Pmask),-1);
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/* Perform right-wing inner product */
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v += FilterUp(Imp, ImpD, Nwing, Interp, Xp+1,
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/* previous (triggers warning): (HWORD)((-*Time)&Pmask),1); */
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(HWORD)((((*Time)^Pmask)+1)&Pmask),1);
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v >>= Nhg; /* Make guard bits */
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v *= LpScl; /* Normalize for unity filter gain */
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*Y++ = WordToHword(v,NLpScl); /* strip guard bits, deposit output */
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*Time += dtb; /* Move to next sample by time increment */
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}
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return (Y - Ystart); /* Return the number of output samples */
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}
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/* Sampling rate conversion subroutine */
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static int SrcUD(HWORD X[], HWORD Y[], double factor, UWORD *Time,
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UHWORD Nx, UHWORD Nwing, UHWORD LpScl,
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HWORD Imp[], HWORD ImpD[], bool Interp)
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{
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HWORD *Xp, *Ystart;
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WORD v;
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double dh; /* Step through filter impulse response */
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double dt; /* Step through input signal */
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UWORD endTime; /* When Time reaches EndTime, return to user */
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UWORD dhb, dtb; /* Fixed-point versions of Dh,Dt */
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dt = 1.0/factor; /* Output sampling period */
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dtb = (UWORD)(dt*(1<<Np) + 0.5); /* Fixed-point representation */
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dh = MIN((double)Npc, factor*Npc); /* Filter sampling period */
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dhb = (UWORD)(dh*(1<<Na) + 0.5); /* Fixed-point representation */
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Ystart = Y;
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endTime = *Time + (1<<Np)*(WORD)Nx;
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while (*Time < endTime)
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{
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Xp = &X[*Time>>Np]; /* Ptr to current input sample */
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v = FilterUD(Imp, ImpD, Nwing, Interp, Xp, (HWORD)(*Time&Pmask),
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-1, dhb); /* Perform left-wing inner product */
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v += FilterUD(Imp, ImpD, Nwing, Interp, Xp+1,
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/* previous (triggers warning): (HWORD)((-*Time)&Pmask), */
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(HWORD)((((*Time)^Pmask)+1)&Pmask),
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1, dhb); /* Perform right-wing inner product */
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v >>= Nhg; /* Make guard bits */
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v *= LpScl; /* Normalize for unity filter gain */
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*Y++ = WordToHword(v,NLpScl); /* strip guard bits, deposit output */
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*Time += dtb; /* Move to next sample by time increment */
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}
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return (Y - Ystart); /* Return the number of output samples */
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}
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#pragma mark -
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#define IzeroEPSILON 1E-21 /* Max error acceptable in Izero */
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static double Izero(double x)
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{
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double sum, u, halfx, temp;
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int n;
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sum = u = n = 1;
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halfx = x/2.0;
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do {
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temp = halfx/(double)n;
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n += 1;
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temp *= temp;
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u *= temp;
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sum += u;
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} while (u >= IzeroEPSILON*sum);
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return(sum);
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}
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void LpFilter(double c[], int N, double frq, double Beta, int Num)
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{
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double IBeta, temp, inm1;
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int i;
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/* Calculate ideal lowpass filter impulse response coefficients: */
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c[0] = 2.0*frq;
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for (i=1; i<N; i++) {
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temp = M_PI*(double)i/(double)Num;
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c[i] = sin(2.0*temp*frq)/temp; /* Analog sinc function, cutoff = frq */
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}
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/*
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* Calculate and Apply Kaiser window to ideal lowpass filter.
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* Note: last window value is IBeta which is NOT zero.
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* You're supposed to really truncate the window here, not ramp
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* it to zero. This helps reduce the first sidelobe.
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*/
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IBeta = 1.0/Izero(Beta);
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inm1 = 1.0/((double)(N-1));
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for (i=1; i<N; i++) {
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temp = (double)i * inm1;
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c[i] *= Izero(Beta*sqrt(1.0-temp*temp)) * IBeta;
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}
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}
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static double ImpR[MAXNWING];
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int makeFilter(HWORD Imp[], HWORD ImpD[], UHWORD *LpScl, UHWORD Nwing,
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double Froll, double Beta)
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{
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double DCgain, Scl, Maxh;
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HWORD Dh;
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int i, temp;
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if (Nwing > MAXNWING) /* Check for valid parameters */
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return(1);
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if ((Froll<=0) || (Froll>1))
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return(2);
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if (Beta < 1)
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return(3);
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/*
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* Design Kaiser-windowed sinc-function low-pass filter
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*/
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LpFilter(ImpR, (int)Nwing, 0.5*Froll, Beta, Npc);
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/* Compute the DC gain of the lowpass filter, and its maximum coefficient
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* magnitude. Scale the coefficients so that the maximum coeffiecient just
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* fits in Nh-bit fixed-point, and compute LpScl as the NLpScl-bit (signed)
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* scale factor which when multiplied by the output of the lowpass filter
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* gives unity gain. */
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DCgain = 0;
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Dh = Npc; /* Filter sampling period for factors>=1 */
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for (i=Dh; i<Nwing; i+=Dh)
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DCgain += ImpR[i];
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DCgain = 2*DCgain + ImpR[0]; /* DC gain of real coefficients */
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for (Maxh=i=0; i<Nwing; i++)
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Maxh = MAX(Maxh, fabs(ImpR[i]));
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Scl = ((1<<(Nh-1))-1)/Maxh; /* Map largest coeff to 16-bit maximum */
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temp = (int)fabs((1<<(NLpScl+Nh))/(DCgain*Scl));
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if (temp >= 1<<16)
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return(4); /* Filter scale factor overflows UHWORD */
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*LpScl = temp;
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/* Scale filter coefficients for Nh bits and convert to integer */
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if (ImpR[0] < 0) /* Need pos 1st value for LpScl storage */
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Scl = -Scl;
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for (i=0; i<Nwing; i++) /* Scale them */
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ImpR[i] *= Scl;
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for (i=0; i<Nwing; i++) /* Round them */
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Imp[i] = (HWORD)(ImpR[i] + 0.5);
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/* ImpD makes linear interpolation of the filter coefficients faster */
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for (i=0; i<Nwing-1; i++)
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ImpD[i] = Imp[i+1] - Imp[i];
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ImpD[Nwing-1] = - Imp[Nwing-1]; /* Last coeff. not interpolated */
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return(0);
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}
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#pragma mark -
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WORD FilterUp(HWORD Imp[], HWORD ImpD[],
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UHWORD Nwing, bool Interp,
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HWORD *Xp, HWORD Ph, HWORD Inc)
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{
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HWORD *Hp, *Hdp = NULL, *End;
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HWORD a = 0;
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WORD v, t;
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v=0;
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Hp = &Imp[Ph>>Na];
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End = &Imp[Nwing];
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if (Interp) {
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Hdp = &ImpD[Ph>>Na];
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a = Ph & Amask;
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}
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if (Inc == 1) /* If doing right wing... */
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{ /* ...drop extra coeff, so when Ph is */
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End--; /* 0.5, we don't do too many mult's */
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if (Ph == 0) /* If the phase is zero... */
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{ /* ...then we've already skipped the */
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Hp += Npc; /* first sample, so we must also */
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Hdp += Npc; /* skip ahead in Imp[] and ImpD[] */
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}
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}
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if (Interp)
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while (Hp < End) {
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t = *Hp; /* Get filter coeff */
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t += (((WORD)*Hdp)*a)>>Na; /* t is now interp'd filter coeff */
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Hdp += Npc; /* Filter coeff differences step */
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t *= *Xp; /* Mult coeff by input sample */
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if (t & (1<<(Nhxn-1))) /* Round, if needed */
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t += (1<<(Nhxn-1));
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t >>= Nhxn; /* Leave some guard bits, but come back some */
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v += t; /* The filter output */
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Hp += Npc; /* Filter coeff step */
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Xp += Inc; /* Input signal step. NO CHECK ON BOUNDS */
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}
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else
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while (Hp < End) {
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t = *Hp; /* Get filter coeff */
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t *= *Xp; /* Mult coeff by input sample */
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if (t & (1<<(Nhxn-1))) /* Round, if needed */
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t += (1<<(Nhxn-1));
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t >>= Nhxn; /* Leave some guard bits, but come back some */
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v += t; /* The filter output */
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Hp += Npc; /* Filter coeff step */
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Xp += Inc; /* Input signal step. NO CHECK ON BOUNDS */
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}
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return(v);
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}
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WORD FilterUD( HWORD Imp[], HWORD ImpD[],
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UHWORD Nwing, bool Interp,
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HWORD *Xp, HWORD Ph, HWORD Inc, UHWORD dhb)
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{
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HWORD a;
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HWORD *Hp, *Hdp, *End;
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WORD v, t;
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UWORD Ho;
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v=0;
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Ho = (Ph*(UWORD)dhb)>>Np;
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End = &Imp[Nwing];
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if (Inc == 1) /* If doing right wing... */
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{ /* ...drop extra coeff, so when Ph is */
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End--; /* 0.5, we don't do too many mult's */
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if (Ph == 0) /* If the phase is zero... */
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Ho += dhb; /* ...then we've already skipped the */
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} /* first sample, so we must also */
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/* skip ahead in Imp[] and ImpD[] */
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if (Interp)
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while ((Hp = &Imp[Ho>>Na]) < End) {
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t = *Hp; /* Get IR sample */
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Hdp = &ImpD[Ho>>Na]; /* get interp (lower Na) bits from diff table*/
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a = Ho & Amask; /* a is logically between 0 and 1 */
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t += (((WORD)*Hdp)*a)>>Na; /* t is now interp'd filter coeff */
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t *= *Xp; /* Mult coeff by input sample */
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if (t & 1<<(Nhxn-1)) /* Round, if needed */
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t += 1<<(Nhxn-1);
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t >>= Nhxn; /* Leave some guard bits, but come back some */
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v += t; /* The filter output */
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Ho += dhb; /* IR step */
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Xp += Inc; /* Input signal step. NO CHECK ON BOUNDS */
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}
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else
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while ((Hp = &Imp[Ho>>Na]) < End) {
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t = *Hp; /* Get IR sample */
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t *= *Xp; /* Mult coeff by input sample */
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if (t & 1<<(Nhxn-1)) /* Round, if needed */
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t += 1<<(Nhxn-1);
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t >>= Nhxn; /* Leave some guard bits, but come back some */
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v += t; /* The filter output */
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Ho += dhb; /* IR step */
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Xp += Inc; /* Input signal step. NO CHECK ON BOUNDS */
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}
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return(v);
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}
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#pragma mark -
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#if 0
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static int resampleWithFilter( /* number of output samples returned */
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double factor, /* factor = outSampleRate/inSampleRate */
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int infd, /* input and output file descriptors */
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int outfd,
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int inCount, /* number of input samples to convert */
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int outCount, /* number of output samples to compute */
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int nChans, /* number of sound channels (1 or 2) */
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bool interpFilt, /* TRUE means interpolate filter coeffs */
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HWORD Imp[], HWORD ImpD[],
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UHWORD LpScl, UHWORD Nmult, UHWORD Nwing)
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{
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UWORD Time, Time2; /* Current time/pos in input sample */
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UHWORD Xp, Ncreep, Xoff, Xread;
|
||
int OBUFFSIZE = (int)(((double)IBUFFSIZE)*factor+2.0);
|
||
HWORD X1[IBUFFSIZE], Y1[OBUFFSIZE]; /* I/O buffers */
|
||
HWORD X2[IBUFFSIZE], Y2[OBUFFSIZE]; /* I/O buffers */
|
||
UHWORD Nout, Nx;
|
||
int i, Ycount, last;
|
||
|
||
MUS_SAMPLE_TYPE **obufs = sndlib_allocate_buffers(nChans, OBUFFSIZE);
|
||
if (obufs == NULL)
|
||
return err_ret("Can't allocate output buffers");
|
||
|
||
/* Account for increased filter gain when using factors less than 1 */
|
||
if (factor < 1)
|
||
LpScl = LpScl*factor + 0.5;
|
||
|
||
/* Calc reach of LP filter wing & give some creeping room */
|
||
Xoff = ((Nmult+1)/2.0) * MAX(1.0,1.0/factor) + 10;
|
||
|
||
if (IBUFFSIZE < 2*Xoff) /* Check input buffer size */
|
||
return err_ret("IBUFFSIZE (or factor) is too small");
|
||
|
||
Nx = IBUFFSIZE - 2*Xoff; /* # of samples to process each iteration */
|
||
|
||
last = 0; /* Have not read last input sample yet */
|
||
Ycount = 0; /* Current sample and length of output file */
|
||
Xp = Xoff; /* Current "now"-sample pointer for input */
|
||
Xread = Xoff; /* Position in input array to read into */
|
||
Time = (Xoff<<Np); /* Current-time pointer for converter */
|
||
|
||
for (i=0; i<Xoff; X1[i++]=0); /* Need Xoff zeros at begining of sample */
|
||
for (i=0; i<Xoff; X2[i++]=0); /* Need Xoff zeros at begining of sample */
|
||
|
||
do {
|
||
if (!last) /* If haven't read last sample yet */
|
||
{
|
||
last = readData(infd, inCount, X1, X2, IBUFFSIZE,
|
||
nChans, (int)Xread);
|
||
if (last && (last-Xoff<Nx)) { /* If last sample has been read... */
|
||
Nx = last-Xoff; /* ...calc last sample affected by filter */
|
||
if (Nx <= 0)
|
||
break;
|
||
}
|
||
}
|
||
/* Resample stuff in input buffer */
|
||
Time2 = Time;
|
||
if (factor >= 1) { /* SrcUp() is faster if we can use it */
|
||
Nout=SrcUp(X1,Y1,factor,&Time,Nx,Nwing,LpScl,Imp,ImpD,interpFilt);
|
||
if (nChans==2)
|
||
Nout=SrcUp(X2,Y2,factor,&Time2,Nx,Nwing,LpScl,Imp,ImpD,
|
||
interpFilt);
|
||
}
|
||
else {
|
||
Nout=SrcUD(X1,Y1,factor,&Time,Nx,Nwing,LpScl,Imp,ImpD,interpFilt);
|
||
if (nChans==2)
|
||
Nout=SrcUD(X2,Y2,factor,&Time2,Nx,Nwing,LpScl,Imp,ImpD,
|
||
interpFilt);
|
||
}
|
||
|
||
Time -= (Nx<<Np); /* Move converter Nx samples back in time */
|
||
Xp += Nx; /* Advance by number of samples processed */
|
||
Ncreep = (Time>>Np) - Xoff; /* Calc time accumulation in Time */
|
||
if (Ncreep) {
|
||
Time -= (Ncreep<<Np); /* Remove time accumulation */
|
||
Xp += Ncreep; /* and add it to read pointer */
|
||
}
|
||
for (i=0; i<IBUFFSIZE-Xp+Xoff; i++) { /* Copy part of input signal */
|
||
X1[i] = X1[i+Xp-Xoff]; /* that must be re-used */
|
||
if (nChans==2)
|
||
X2[i] = X2[i+Xp-Xoff]; /* that must be re-used */
|
||
}
|
||
if (last) { /* If near end of sample... */
|
||
last -= Xp; /* ...keep track were it ends */
|
||
if (!last) /* Lengthen input by 1 sample if... */
|
||
last++; /* ...needed to keep flag TRUE */
|
||
}
|
||
Xread = i; /* Pos in input buff to read new data into */
|
||
Xp = Xoff;
|
||
|
||
Ycount += Nout;
|
||
if (Ycount>outCount) {
|
||
Nout -= (Ycount-outCount);
|
||
Ycount = outCount;
|
||
}
|
||
|
||
if (Nout > OBUFFSIZE) /* Check to see if output buff overflowed */
|
||
return err_ret("Output array overflow");
|
||
|
||
if (nChans==1) {
|
||
for (i = 0; i < Nout; i++)
|
||
obufs[0][i] = HWORD_TO_MUS_SAMPLE_TYPE(Y1[i]);
|
||
} else {
|
||
for (i = 0; i < Nout; i++) {
|
||
obufs[0][i] = HWORD_TO_MUS_SAMPLE_TYPE(Y1[i]);
|
||
obufs[1][i] = HWORD_TO_MUS_SAMPLE_TYPE(Y2[i]);
|
||
}
|
||
}
|
||
/* NB: errors reported within sndlib */
|
||
mus_file_write(outfd, 0, Nout - 1, nChans, obufs);
|
||
|
||
printf("."); fflush(stdout);
|
||
|
||
} while (Ycount<outCount); /* Continue until done */
|
||
|
||
return(Ycount); /* Return # of samples in output file */
|
||
}
|
||
#endif
|
||
|
||
|
||
#pragma mark -
|
||
|
||
|
||
#if 0
|
||
/* here for linear interp. might be useful for other things */
|
||
static st_rate_t st_gcd(st_rate_t a, st_rate_t b)
|
||
{
|
||
if (b == 0)
|
||
return a;
|
||
else
|
||
return st_gcd(b, a % b);
|
||
}
|
||
|
||
|
||
/*
|
||
* Prepare processing.
|
||
*/
|
||
int st_resample_start(resample_t r, st_rate_t inrate, st_rate_t outrate) {
|
||
long Xoff, gcdrate;
|
||
int i;
|
||
|
||
if (inrate == outrate) {
|
||
st_fail("Input and Output rates must be different to use resample effect");
|
||
return (ST_EOF);
|
||
}
|
||
|
||
r->Factor = (double)outrate / (double)inrate;
|
||
|
||
gcdrate = st_gcd(inrate, outrate);
|
||
r->a = inrate / gcdrate;
|
||
r->b = outrate / gcdrate;
|
||
|
||
if (r->a <= r->b && r->b <= NQMAX) {
|
||
r->quadr = -1; /* exact coeff's */
|
||
r->Nq = r->b; /* MAX(r->a,r->b); */
|
||
} else {
|
||
r->Nq = Nc; /* for now */
|
||
}
|
||
|
||
/* Check for illegal constants */
|
||
# if 0
|
||
if (Lp >= 16)
|
||
st_fail("Error: Lp>=16");
|
||
if (Nb + Nhg + NLpScl >= 32)
|
||
st_fail("Error: Nb+Nhg+NLpScl>=32");
|
||
if (Nh + Nb > 32)
|
||
st_fail("Error: Nh+Nb>32");
|
||
# endif
|
||
|
||
/* Nwing: # of filter coeffs in right wing */
|
||
r->Nwing = r->Nq * (r->Nmult / 2 + 1) + 1;
|
||
|
||
r->Imp = (Float *)malloc(sizeof(Float) * (r->Nwing + 2)) + 1;
|
||
/* need Imp[-1] and Imp[Nwing] for quadratic interpolation */
|
||
/* returns error # <=0, or adjusted wing-len > 0 */
|
||
i = makeFilter(r->Imp, r->Nwing, r->rolloff, r->beta, r->Nq);
|
||
if (i <= 0) {
|
||
st_fail("resample: Unable to make filter\n");
|
||
return (ST_EOF);
|
||
}
|
||
|
||
st_report("Nmult: %ld, Nwing: %ld, Nq: %ld\n",r->Nmult,r->Nwing,r->Nq); // FIXME
|
||
|
||
if (r->quadr < 0) { /* exact coeff's method */
|
||
r->Xh = r->Nwing / r->b;
|
||
st_report("resample: rate ratio %ld:%ld, coeff interpolation not needed\n", r->a, r->b);
|
||
} else {
|
||
r->dhb = Np; /* Fixed-point Filter sampling-time-increment */
|
||
if (r->Factor < 1.0)
|
||
r->dhb = (long)(r->Factor * Np + 0.5);
|
||
r->Xh = (r->Nwing << La) / r->dhb;
|
||
/* (Xh * dhb)>>La is max index into Imp[] */
|
||
}
|
||
|
||
/* reach of LP filter wings + some creeping room */
|
||
Xoff = r->Xh + 10;
|
||
r->Xoff = Xoff;
|
||
|
||
/* Current "now"-sample pointer for input to filter */
|
||
r->Xp = Xoff;
|
||
/* Position in input array to read into */
|
||
r->Xread = Xoff;
|
||
/* Current-time pointer for converter */
|
||
r->Time = Xoff;
|
||
if (r->quadr < 0) { /* exact coeff's method */
|
||
r->t = Xoff * r->Nq;
|
||
}
|
||
i = BUFFSIZE - 2 * Xoff;
|
||
if (i < r->Factor + 1.0 / r->Factor) /* Check input buffer size */
|
||
{
|
||
st_fail("Factor is too small or large for BUFFSIZE");
|
||
return (ST_EOF);
|
||
}
|
||
|
||
r->Xsize = (long)(2 * Xoff + i / (1.0 + r->Factor));
|
||
r->Ysize = BUFFSIZE - r->Xsize;
|
||
st_report("Xsize %ld, Ysize %ld, Xoff %ld",r->Xsize,r->Ysize,r->Xoff); // FIXME
|
||
|
||
r->X = (Float *) malloc(sizeof(Float) * (BUFFSIZE));
|
||
r->Y = r->X + r->Xsize;
|
||
r->Yposition = 0;
|
||
|
||
/* Need Xoff zeros at beginning of sample */
|
||
for (i = 0; i < Xoff; i++)
|
||
r->X[i] = 0;
|
||
return (ST_SUCCESS);
|
||
}
|
||
|
||
/*
|
||
* Processed signed long samples from ibuf to obuf.
|
||
* Return number of samples processed.
|
||
*/
|
||
int st_resample_flow(resample_t r, AudioStream &input, st_sample_t *obuf, st_size_t *osamp, st_volume_t vol) {
|
||
long i, k, last;
|
||
long Nout = 0; // The number of bytes we effectively output
|
||
long Nx; // The number of bytes we will read from input
|
||
long Nproc; // The number of bytes we process to generate Nout output bytes
|
||
const long obufSize = *osamp;
|
||
|
||
/*
|
||
TODO: adjust for the changes made to AudioStream; add support for stereo
|
||
initially, could just average the left/right channel -> bad for quality of course,
|
||
but easiest to implement and would get this going again.
|
||
Next step is to duplicate the X/Y buffers... a lot of computations don't care about
|
||
how many channels there are anyway, they could just be ran twice, e.g. SrcEX and SrcUD.
|
||
But better for efficiency would be to rewrite those to deal with 2 channels, too.
|
||
Because esp in SrcEX/SrcUD, only very few computations depend on the input data,
|
||
and dealing with both channels in parallel should only be a little slower than dealing
|
||
with them alone
|
||
*/
|
||
|
||
// Constrain amount we actually process
|
||
//fprintf(stderr,"Xp %d, Xread %d\n",r->Xp, r->Xread);
|
||
|
||
// Initially assume we process the full X buffer starting at the filter
|
||
// start position.
|
||
Nproc = r->Xsize - r->Xp;
|
||
|
||
// Nproc is bounded indirectly by the size of output buffer, and also by
|
||
// the remaining size of the Y buffer (whichever is smaller).
|
||
// We round up for the output buffer, because we want to generate enough
|
||
// bytes to fill it.
|
||
i = MIN((long)((r->Ysize - r->Yposition) / r->Factor), (long)ceil((obufSize - r->Yposition) / r->Factor));
|
||
if (Nproc > i)
|
||
Nproc = i;
|
||
|
||
// Now that we know how many bytes we want to process, we determine
|
||
// how many bytes to read. We already have Xread bytes in our input
|
||
// buffer, so we need Nproc - r->Xread more bytes.
|
||
Nx = Nproc - r->Xread + r->Xoff + r->Xp; // FIXME: Fingolfin thinks this is the correct thing, not what's in the next line!
|
||
// Nx = Nproc - r->Xread; /* space for right-wing future-data */
|
||
if (Nx <= 0) {
|
||
st_fail("resample: Can not handle this sample rate change. Nx not positive: %d", Nx);
|
||
return (ST_EOF);
|
||
}
|
||
|
||
// Read in up to Nx bytes
|
||
for (i = r->Xread; i < Nx + r->Xread && !input.eos(); i++) {
|
||
r->X[i] = (Float)input.read();
|
||
}
|
||
Nx = i - r->Xread; // Compute how many samples we actually read
|
||
|
||
fprintf(stderr,"Nx %d\n",Nx);
|
||
|
||
|
||
last = Nx + r->Xread; // 'last' is the idx after the last valid byte in X (i.e. number of bytes are in buffer X right now)
|
||
|
||
// Finally compute the effective number of bytes to process
|
||
Nproc = last - r->Xoff - r->Xp;
|
||
|
||
if (Nproc <= 0) {
|
||
/* fill in starting here next time */
|
||
r->Xread = last;
|
||
/* leave *isamp alone, we consumed it */
|
||
*osamp = 0;
|
||
return (ST_SUCCESS);
|
||
}
|
||
if (r->quadr < 0) { /* exact coeff's method */
|
||
long creep;
|
||
Nout = SrcEX(r, Nproc) + r->Yposition;
|
||
fprintf(stderr,"Nproc %d --> %d\n",Nproc,Nout);
|
||
/* Move converter Nproc samples back in time */
|
||
r->t -= Nproc * r->b;
|
||
/* Advance by number of samples processed */
|
||
r->Xp += Nproc;
|
||
/* Calc time accumulation in Time */
|
||
creep = r->t / r->b - r->Xoff;
|
||
if (creep) {
|
||
r->t -= creep * r->b; /* Remove time accumulation */
|
||
r->Xp += creep; /* and add it to read pointer */
|
||
fprintf(stderr,"Nproc %ld, creep %ld\n",Nproc,creep);
|
||
}
|
||
} else { /* approx coeff's method */
|
||
long creep;
|
||
Nout = SrcUD(r, Nproc) + r->Yposition;
|
||
fprintf(stderr,"Nproc %d --> %d\n",Nproc,Nout);
|
||
/* Move converter Nproc samples back in time */
|
||
r->Time -= Nproc;
|
||
/* Advance by number of samples processed */
|
||
r->Xp += Nproc;
|
||
/* Calc time accumulation in Time */
|
||
creep = (long)(r->Time - r->Xoff);
|
||
if (creep) {
|
||
r->Time -= creep; /* Remove time accumulation */
|
||
r->Xp += creep; /* and add it to read pointer */
|
||
fprintf(stderr,"Nproc %ld, creep %ld\n",Nproc,creep);
|
||
}
|
||
}
|
||
|
||
/* Copy back portion of input signal that must be re-used */
|
||
k = r->Xp - r->Xoff;
|
||
//fprintf(stderr,"k %d, last %d\n",k,last);
|
||
for (i = 0; i < last - k; i++)
|
||
r->X[i] = r->X[i + k];
|
||
|
||
/* Pos in input buff to read new data into */
|
||
r->Xread = i;
|
||
r->Xp = r->Xoff;
|
||
|
||
printf("osamp = %ld, Nout = %ld\n", obufSize, Nout);
|
||
long numOutSamples = MIN(obufSize, Nout);
|
||
for (i = 0; i < numOutSamples; i++) {
|
||
int sample = (int)(r->Y[i] * vol / 256);
|
||
clampedAdd(*obuf++, sample);
|
||
#if 1 // FIXME: Hack to generate stereo output
|
||
// clampedAdd(*obuf++, sample);
|
||
*obuf++;
|
||
#endif
|
||
}
|
||
|
||
// Move down the remaining Y bytes
|
||
for (i = numOutSamples; i < Nout; i++) {
|
||
r->Y[i-numOutSamples] = r->Y[i];
|
||
}
|
||
if (Nout > numOutSamples)
|
||
r->Yposition = Nout - numOutSamples;
|
||
else
|
||
r->Yposition = 0;
|
||
|
||
// Finally set *osamp to the number of samples we put into the output buffer
|
||
*osamp = numOutSamples;
|
||
|
||
return (ST_SUCCESS);
|
||
}
|
||
|
||
/*
|
||
* Process tail of input samples.
|
||
*/
|
||
int st_resample_drain(resample_t r, st_sample_t *obuf, st_size_t *osamp, st_volume_t vol) {
|
||
long osamp_res;
|
||
st_sample_t *Obuf;
|
||
int rc;
|
||
|
||
/*fprintf(stderr,"Xoff %d, Xt %d <--- DRAIN\n",r->Xoff, r->Xt);*/
|
||
|
||
/* stuff end with Xoff zeros */
|
||
ZeroInputStream zero(r->Xoff);
|
||
osamp_res = *osamp;
|
||
Obuf = obuf;
|
||
while (!zero.eos() && osamp_res > 0) {
|
||
st_sample_t Osamp;
|
||
Osamp = osamp_res;
|
||
rc = st_resample_flow(r, zero, Obuf, (st_size_t *) & Osamp, vol);
|
||
if (rc)
|
||
return rc;
|
||
/*fprintf(stderr,"DRAIN isamp,osamp (%d,%d) -> (%d,%d)\n",
|
||
isamp_res,osamp_res,Isamp,Osamp);*/
|
||
Obuf += Osamp;
|
||
osamp_res -= Osamp;
|
||
}
|
||
*osamp -= osamp_res;
|
||
fprintf(stderr,"DRAIN osamp %d\n", *osamp);
|
||
if (!zero.eos())
|
||
st_warn("drain overran obuf\n");
|
||
fflush(stderr);
|
||
return (ST_SUCCESS);
|
||
}
|
||
|
||
/*
|
||
* Do anything required when you stop reading samples.
|
||
* Don't close input file!
|
||
*/
|
||
int st_resample_stop(resample_t r) {
|
||
free(r->Imp - 1);
|
||
free(r->X);
|
||
/* free(r->Y); Y is in same block starting at X */
|
||
return (ST_SUCCESS);
|
||
}
|
||
|
||
#endif
|
||
|
||
#pragma mark -
|
||
|
||
|
||
ResampleRateConverter::ResampleRateConverter(st_rate_t inrate, st_rate_t outrate, int quality) {
|
||
// FIXME: quality is for now a nasty hack. Valid values are 0,1,2,3
|
||
|
||
double rolloff; /* roll-off frequency */
|
||
double beta; /* passband/stopband tuning magic */
|
||
|
||
switch (quality) {
|
||
case 0:
|
||
/* These defaults are conservative with respect to aliasing. */
|
||
rolloff = 0.80;
|
||
beta = 16;
|
||
quadr = 0;
|
||
Nmult = 45;
|
||
break;
|
||
case 1:
|
||
rolloff = 0.80;
|
||
beta = 16;
|
||
quadr = 1;
|
||
Nmult = 45;
|
||
break;
|
||
case 2:
|
||
rolloff = 0.875;
|
||
beta = 16;
|
||
quadr = 1;
|
||
Nmult = 75;
|
||
break;
|
||
case 3:
|
||
rolloff = 0.94;
|
||
beta = 16;
|
||
quadr = 1;
|
||
Nmult = 149;
|
||
break;
|
||
default:
|
||
error("Illegal quality level %d\n", quality);
|
||
break;
|
||
}
|
||
|
||
makeFilter(Imp, ImpD, &LpScl, Nmult, rolloff, beta);
|
||
|
||
int OBUFFSIZE = (IBUFFSIZE * outrate / inrate + 2);
|
||
X1 = (HWORD *)malloc(IBUFFSIZE);
|
||
X2 = (HWORD *)malloc(IBUFFSIZE);
|
||
Y1 = (HWORD *)malloc(OBUFFSIZE);
|
||
Y2 = (HWORD *)malloc(OBUFFSIZE);
|
||
|
||
// HACK this is invalid code but "fixes" a compiler warning for now
|
||
double factor = outrate / (double)inrate;
|
||
UHWORD Xp, /*Ncreep,*/ Xoff, Xread;
|
||
UHWORD Nout, Nx;
|
||
int Ycount, last;
|
||
|
||
/* Account for increased filter gain when using factors less than 1 */
|
||
if (factor < 1)
|
||
LpScl = (UHWORD)(LpScl*factor + 0.5);
|
||
|
||
/* Calc reach of LP filter wing & give some creeping room */
|
||
Xoff = (UHWORD)(((Nmult+1)/2.0) * MAX(1.0,1.0/factor) + 10);
|
||
|
||
if (IBUFFSIZE < 2*Xoff) /* Check input buffer size */
|
||
error("IBUFFSIZE (or factor) is too small");
|
||
|
||
Nx = IBUFFSIZE - 2*Xoff; /* # of samples to process each iteration */
|
||
|
||
last = 0; /* Have not read last input sample yet */
|
||
Ycount = 0; /* Current sample and length of output file */
|
||
Xp = Xoff; /* Current "now"-sample pointer for input */
|
||
Xread = Xoff; /* Position in input array to read into */
|
||
Time = (Xoff<<Np); /* Current-time pointer for converter */
|
||
|
||
Nout = SrcUp(X1, Y1, factor, &Time, Nx, Nwing, LpScl, Imp, ImpD, quadr);
|
||
Nout = SrcUD(X1, Y1, factor, &Time, Nx, Nwing, LpScl, Imp, ImpD, quadr);
|
||
|
||
// st_resample_start(&rstuff, inrate, outrate);
|
||
}
|
||
|
||
ResampleRateConverter::~ResampleRateConverter() {
|
||
// st_resample_stop(&rstuff);
|
||
free(X1);
|
||
free(X2);
|
||
free(Y1);
|
||
free(Y2);
|
||
}
|
||
|
||
int ResampleRateConverter::flow(AudioStream &input, st_sample_t *obuf, st_size_t osamp, st_volume_t vol) {
|
||
// return st_resample_flow(&rstuff, input, obuf, &osamp, vol);
|
||
return 0;
|
||
}
|
||
|
||
int ResampleRateConverter::drain(st_sample_t *obuf, st_size_t osamp, st_volume_t vol) {
|
||
// return st_resample_drain(&rstuff, obuf, &osamp, vol);
|
||
return 0;
|
||
}
|
||
|