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filter_code.cpp
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filter_code.cpp
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/*
Copyright (C) 2019 BrerDawg
This program is free software; you can redistribute it and/or
modify it under the terms of the GNU General Public License
as published by the Free Software Foundation; either version 2
of the License, or (at your option) any later version.
This program is distributed in the hope that it will be useful,
but WITHOUT ANY WARRANTY; without even the implied warranty of
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
GNU General Public License for more details.
You should have received a copy of the GNU General Public License
along with this program; if not, write to the Free Software
Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301, USA.
*/
//filter_code.cpp
//v1.01 01-sep-2018
//v1.02 07-nov-2020 //changed 'twopi' to a constant, commented out some iir code
//v1.03 09-oct-2022 //added function: 'iir_process(..)' which is similar to: 'filter_iir_2nd_order(..)' and 'filter_iir_2nd_order_2ch(..)'
//added function prototypes to: 'filter_code.h' ---> 'bool create_iir_filter_from_coeffs( st_iir &iir, vector<double> &vcoeff );'
//added function prototypes to: 'filter_code.h' ---> 'void iir_delete_filter( st_iir &iir );' and 'void iir_init( st_iir &iir );'
//added extra filter types to 'en_filter_window_type_tag' and 'filter_fir_windowed()': 'fwt_lanczos1', 'fwt_lanczos1_5', 'fwt_lanczos2', 'fwt_lanczos3'
//added 'filter_fir_sinc(..)'
//v1.04 22-jul-2023 //added namespace 'filter_code::'
//v1.05 18-sep-2023 //added 'create_filter_iir_using_q()'
//v1.06 26-feb-2024 //remove include(s) of 'globals.h' 'mgraph.h'
//changed 'delete' to 'delete[]'
//added 'st_fir.verb' 'st_fir.suser0' 'st_fir.suser1' 'st_fir.user_id0' 'st_fir.user_id1'
#include "filter_code.h"
namespace filter_code
{
float iir2nd_coeffs[5]; //second order iir
#define twopi (2.0*M_PI)
//reads an iowa hills coeffients text file and get filter coeffs for one specified section,
//only parses the 2'nd Order Sections that have headings: 'Sect xx',
//specify required section starting at index 0,
//returns 1 on success, else 0
bool read_iowa_hills_coeffs( string fname, int section, double &a1, double &a2, double &b0, double &b1, double &b2 )
{
string s1, ssection;
mystr m1;
if( !m1.readfile( fname, 20000 ) ) //saftey margin
{
printf("read_iowa_hills_coeffs() - failed to read file: '%s'\n", fname.c_str() );
return 0;
}
printf("read_iowa_hills_coeffs() ---------------------------------\n" );
strpf( ssection, "Sect %d", section );
bool in_section = 0;
int section_line = 0;
int check_count = 0;
char c0, c1;
double dd;
int ii = 0;
for( ii = 0; ii < 20000; ii++ ) //saftey margin
{
if( !m1.gets( s1 ) ) break;
if( s1.compare( ssection ) == 0 ) in_section = 1;
if( in_section )
{
printf("got %03d: line: %03d, '%s'\n", ii, section_line, s1.c_str() );
if( section_line == 2 ) { sscanf( s1.c_str(), "%c%c %lf", &c0, &c1, &dd ); a1 = dd; printf("check %c%c %.17f\n", c0, c1, a1 ); check_count++; }
if( section_line == 3 ) { sscanf( s1.c_str(), "%c%c %lf", &c0, &c1, &dd ); a2 = dd; printf("check %c%c %.17f\n", c0, c1, a2 ); check_count++; }
if( section_line == 4 ) { sscanf( s1.c_str(), "%c%c %lf", &c0, &c1, &dd ); b0 = dd; printf("check %c%c %.17f\n", c0, c1, b0 ); check_count++; }
if( section_line == 5 ) { sscanf( s1.c_str(), "%c%c %lf", &c0, &c1, &dd ); b1 = dd; printf("check %c%c %.17f\n", c0, c1, b1 ); check_count++; }
if( section_line == 6 ) { sscanf( s1.c_str(), "%c%c %lf", &c0, &c1, &dd ); b2 = dd; printf("check %c%c %.17f\n", c0, c1, b2 ); check_count++; }
section_line++;
if( section_line >= 7 ) break;
}
}
//printf("read_iowa_hills_coeffs() - done - section_line %d, check_count: %d\n", section_line, check_count );
if( section_line != 7 )
{
printf("read_iowa_hills_coeffs() - 'section_line' expected to reach 7, only reached: %d, check coeffs read correctly\n", section_line );
return 0;
}
if( check_count != 5 )
{
printf("read_iowa_hills_coeffs() - 'check_count' expected to reach 5, only reached: %d, check coeffs read correctly\n", check_count );
return 0;
}
printf("read_iowa_hills_coeffs() ---------------------------------\n" );
return 1;
}
//note a0 is not used (it would be one), the other coeffs should be divided by the a0 you calc'd
// -- X --> add ------->------+-----> b0 ----> add --- Y ---->
// ^ | ^
// | v |
// | | |
// ^ xn0 ^
// | | |
// | | |
// | v |
// add <...-a1 <... xn0 ....> b1 ...> add
// ^ | ^
// | v |
// | | |
// | xn1 |
// ^ | ^
// | | |
// | v |
// |<....-a2 <... add ....> b2 ....> |
//NOTE this is SIMILAR to 'iir_process()'
//2nd order direct form 2 iir filter
bool filter_iir_2nd_order( vector <st_cplex_tag> &viq, double a1, double a2, double b0, double b1, double b2, double &d0r, double &d1r, double &d0i, double &d1i )
{
for ( int i = 0; i < viq.size(); i++ ) //for every sample
{
double sum_rev = viq[ i ].real - a1 * d0r - a2 * d1r;
double sum_fwd = sum_rev * b0 + b1 * d0r + b2 * d1r;
viq[ i ].real = sum_fwd;
d1r = d0r;
d0r = sum_rev;
}
for ( int i = 0; i < viq.size(); i++ ) //for every sample
{
double sum_rev = viq[ i ].imag - a1 * d0i - a2 * d1i;
double sum_fwd = sum_rev * b0 + b1 * d0i + b2 * d1i;
viq[ i ].imag = sum_fwd;
d1i = d0i;
d0i = sum_rev;
}
}
void filter_iir_2nd_order( float &fsignal, st_iir_2nd_order_tag &of )
{
//a1 = coeff[0]
//a1 = coeff[1]
//b0 = coeff[2]
//b1 = coeff[3]
//b2 = coeff[4]
float sum_rev = fsignal - of.coeff[0] * of.delay0[0] - of.coeff[1] * of.delay0[1];
float sum_fwd = sum_rev * of.coeff[2] + of.coeff[3] * of.delay0[0] + of.coeff[4] * of.delay0[1];
fsignal = sum_fwd;
of.delay0[1] = of.delay0[0];
of.delay0[0] = sum_rev;
}
void filter_iir_2nd_order_2ch( float &fsig0, float &fsig1, st_iir_2nd_order_tag &of )
{
//a1 = coeff[0]
//a1 = coeff[1]
//b0 = coeff[2]
//b1 = coeff[3]
//b2 = coeff[4]
float sum_rev0 = fsig0 - of.coeff[0] * of.delay0[0] - of.coeff[1] * of.delay0[1];
float sum_rev1 = fsig1 - of.coeff[0] * of.delay1[0] - of.coeff[1] * of.delay1[1]; //ch1
float sum_fwd0 = sum_rev0 * of.coeff[2] + of.coeff[3] * of.delay0[0] + of.coeff[4] * of.delay0[1];
float sum_fwd1 = sum_rev1 * of.coeff[2] + of.coeff[3] * of.delay1[0] + of.coeff[4] * of.delay1[1]; //ch1
fsig0 = sum_fwd0;
fsig1 = sum_fwd1; //ch1
of.delay0[1] = of.delay0[0];
of.delay0[0] = sum_rev0;
of.delay1[1] = of.delay1[0];
of.delay1[0] = sum_rev1; //ch1
}
//----------------------------------------------------------------------
void iir_init( st_iir &iir )
{
if( iir.created == 0 ) return;
iir.dly0 = 0;
iir.dly1 = 0;
}
//delete filter
void iir_delete_filter( st_iir &iir )
{
if ( iir.created == 0 ) return;
iir.created = 0;
}
//note a0 is not used (it would be one), the other coeffs should be divided by the a0 you calc'd
// -- X --> add ------->------+-----> b0 ----> add --- Y ---->
// ^ | ^
// | v |
// | | |
// ^ xn0 ^
// | | |
// | | |
// | v |
// add <...-a1 <... xn0 ....> b1 ...> add
// ^ | ^
// | v |
// | | |
// | xn1 |
// ^ | ^
// | | |
// | v |
// |<....-a2 <... add ....> b2 ....> |
//NOTE this is SIMILAR to 'filter_iir_2nd_order()'
//2nd order direct form 2 iir filter
double iir_process( st_iir &iir, double in )
{
if( iir.created == 0 ) return 0;
if ( iir.bypass )
{
return in;
}
double sum_rev = in - iir.a1 * iir.dly0 - iir.a2 * iir.dly1;
double sum_fwd = sum_rev * iir.b0 + iir.b1 * iir.dly0 + iir.b2 * iir.dly1;
iir.dly1 = iir.dly0;
iir.dly0 = sum_rev;
return sum_fwd;
}
//build a filter from a vector loaded with coeffs
bool create_iir_filter_from_coeffs( st_iir &iir, vector<double> &vcoeff )
{
if( iir.created ) iir_delete_filter( iir );
//if( vcoeff.size() == 0 ) return 0;
if( vcoeff.size() < 5 ) return 0;
iir.a1 = vcoeff[0]; //load coeffs
iir.a2 = vcoeff[1];
iir.b0 = vcoeff[2];
iir.b1 = vcoeff[3];
iir.b2 = vcoeff[4];
iir.coeff_cnt = vcoeff.size();
iir.bypass = 0;
iir_init( iir ); //clear iir delays
iir.created = 1;
return 1;
}
//----------------------------------------------------------------------
void create_filter_iir_using_q( filter_code::en_filter_pass_type_tag filt_type, float filt_freq_in, float filt_q_in, int srate_in, filter_code::st_iir_2nd_order_tag &iir )
{
vector<double> vfilt_coeff;
float db_gain = 0;
if( !calc_filter_iir_2nd_order( filt_type, filt_freq_in, filt_q_in, db_gain, srate_in, vfilt_coeff ) )
{
printf( "create_filter_iir_using_q() - failed to calc filter coeffs, freq %f, q %f\n", filt_freq_in, filt_q_in );
return;
}
//printf( "create_filter0() - iir freq %f, q %f %f %f %f %f %f\n", filt_freq0, filt_q0, iir0.coeff[0], iir0.coeff[1], iir0.coeff[2], iir0.coeff[3], iir0.coeff[4] );
iir.bypass = 0;
iir.coeff[0] = vfilt_coeff[0]; //a1
iir.coeff[1] = vfilt_coeff[1]; //a2
iir.coeff[2] = vfilt_coeff[2]; //b0
iir.coeff[3] = vfilt_coeff[3]; //b1
iir.coeff[4] = vfilt_coeff[4]; //b2
iir.delay0[0] = 0;
iir.delay0[1] = 0;
iir.delay1[0] = 0;
iir.delay1[1] = 0;
iir.bypass = 1;
}
/*
void filter_iir_2nd_order_slow( double &dsignal, double a1, double a2, double b0, double b1, double b2, double &d0, double &d1 )
{
double sum_rev = dsignal - a1 * d0 - a2 * d1;
double sum_fwd = sum_rev * b0 + b1 * d0 + b2 * d1;
dsignal = sum_fwd;
d1 = d0;
d0 = sum_rev;
}
*/
//calc spec filter coeffs suitable for a Direct Form 1 - IIR, 2nd Order
//see ...
// http://www.musicdsp.org/files/Audio-EQ-Cookbook.txt
//Direct Form 1 - IIR, 2nd Order
// -X-----+---> b0 ----> add --------------+----Y---->
// | ^ |
// xn0 | yn0
// | | |
// |...> b1 ....> add <.... -a1 <...|
// | ^ |
// xn1 | yn1
// | | |
// |...> b2 ....> add <.... -a2 <...|
//can be used with 'st_iir' or 'st_iir_2nd_order_tag' and associated functions: iir_process()' or 'filter_iir_2nd_order()'
bool calc_filter_iir_2nd_order( en_filter_pass_type_tag filt_type, double fc1, double in_Q, double db_gain, double srate, vector<double> &vcoeff )
{
printf( "filter_iir_2nd_order() - type: %u, fc1: %f, q: %f, db_gain: %f\n", filt_type, fc1, in_Q, db_gain );
if( fc1 >= srate / 2.0 )
{
printf( "filter_iir_2nd_order() - fc1: %f violates Nyquist, limiting to: %f\n", fc1, srate / 2.0 - 1 );
fc1 = srate / 2.0 - 1;
}
double Fs = srate;
double f0 = fc1;
double w0 = twopi * f0 / Fs;
double Q = in_Q;
//double BW = in_bw / fc1;
double dBgain = db_gain;
double A = pow ( 10.0 , ( dBgain / 40.0 ) ); // A = sqrt( 10.0 ^( dBgain / 20.0 ) ) (for peaking and shelving EQ filters only)
double gain = pow ( 10.0 , ( db_gain / 20.0 ) );
double alpha = sin( w0 ) / ( 2.0 * Q ); //(case: Q)
//double alpha = sin( w0 ) * sinh( log( 2.0 ) / 2.0 * BW * w0 / sin( w0 ) ); //(case: BW)
//double alpha = sin( w0 ) / 2.0 * sqrt( ( A + 1.0 / A ) * ( 1.0 / S - 1 ) + 2.0 ); //(case: S)
double a0, a1, a2;
double b0, b1, b2;
bool ok = 0;
printf( "filter_iir_2nd_order() - w0: %f, alpha: %f, A: %f\n", w0, alpha, A );
if( filt_type == fpt_lowpass )
{
b0 = ( 1.0 - cos( w0 ) ) / 2.0;
b1 = 1.0 - cos( w0 );
b2 = ( 1.0 - cos( w0 ) ) / 2.0;
a0 = 1.0 + alpha;
a1 = -2.0 * cos( w0 );
a2 = 1.0 - alpha;
ok = 1;
}
if( filt_type == fpt_highpass )
{
b0 = ( 1.0 + cos( w0 ) ) / 2.0;
b1 = - ( 1.0 + cos( w0 ) );
b2 = ( 1.0 + cos( w0 ) ) / 2.0;
a0 = 1.0 + alpha;
a1 = -2.0 * cos( w0 );
a2 = 1.0 - alpha;
ok = 1;
}
if( filt_type == fpt_bandpass ) //constant skirt gain, peak gain = Q
{
b0 = sin(w0)/2.0; //Q*alpha;
b1 = 0.0;
b2 = -sin(w0)/2.0; //-Q*alpha;
a0 = 1.0 + alpha;
a1 = -2.0*cos(w0);
a2 = 1.0 - alpha;
ok = 1;
}
if( filt_type == fpt_bandpass2 ) //constant 0 dB peak gain
{
b0 = alpha;
b1 = 0.0;
b2 = -alpha;
a0 = 1.0 + alpha;
a1 = -2.0*cos(w0);
a2 = 1.0 - alpha;
ok = 1;
}
if( filt_type == fpt_notch )
{
b0 = 1.0;
b1 = -2.0*cos(w0);
b2 = 1.0;
a0 = 1.0 + alpha;
a1 = -2.0*cos(w0);
a2 = 1.0 - alpha;
ok = 1;
}
if( filt_type == fpt_apf )
{
b0 = 1.0 - alpha;
b1 = -2.0*cos(w0);
b2 = 1.0 + alpha;
a0 = 1.0 + alpha;
a1 = -2.0*cos(w0);
a2 = 1 - alpha;
ok = 1;
}
if( filt_type == fpt_peakeq )
{
b0 = 1.0 + alpha*A;
b1 = -2.0*cos(w0);
b2 = 1.0 - alpha*A;
a0 = 1.0 + alpha/A;
a1 = -2.0*cos(w0);
a2 = 1.0 - alpha/A;
ok = 1;
}
if( filt_type == fpt_lowshelf )
{
b0 = A*( (A+1.0) - (A-1.0)*cos(w0) + 2.0*sqrt(A)*alpha );
b1 = 2.0*A*( (A-1.0) - (A+1.0)*cos(w0) );
b2 = A*( (A+1.0) - (A-1.0)*cos(w0) - 2.0*sqrt(A)*alpha );
a0 = (A+1.0) + (A-1.0)*cos(w0) + 2.0*sqrt(A)*alpha;
a1 = -2.0*( (A-1.0) + (A+1.0)*cos(w0) );
a2 = (A+1.0) + (A-1.0)*cos(w0) - 2.0*sqrt(A)*alpha;
ok = 1;
}
if( filt_type == fpt_highshelf )
{
b0 = A*( (A+1.0) + (A-1.0)*cos(w0) + 2.0*sqrt(A)*alpha );
b1 = -2.0*A*( (A-1.0) + (A+1.0)*cos(w0) );
b2 = A*( (A+1.0) + (A-1.0)*cos(w0) - 2.0*sqrt(A)*alpha );
a0 = (A+1.0) - (A-1.0)*cos(w0) + 2.0*sqrt(A)*alpha;
a1 = 2.0*( (A-1.0) - (A+1.0)*cos(w0) );
a2 = (A+1.0) - (A-1.0)*cos(w0) - 2.0*sqrt(A)*alpha;
ok = 1;
}
if( !ok )
{
printf( "filter_iir_2nd_order() - type: %u, is not supported\n", filt_type );
return 0;
}
vcoeff.clear();
vcoeff.push_back( a1 / a0 );
vcoeff.push_back( a2 / a0 );
vcoeff.push_back( b0 / a0 );
vcoeff.push_back( b1 / a0 );
vcoeff.push_back( b2 / a0 );
printf( "filter_iir_2nd_order():\n" );
printf( "a1: %f, a2: %f\n", a1 / a0, a2 / a0 );
printf( "b0: %f, b1: %f, b2: %f\n", b0 / a0, b1 / a0, b2 / a0 );
//conv_vcoeff_to_scoeff( vcoeff, scoeff );
return 1;
}
//v1.03
double filter_fir_sinc(double x)
{
if (x != 0)
{
x *= M_PI;
return ( sin(x)/x);
}
return 1;
}
//calc spec filter coeffs using spec window type(e.g. blackman) and spec filter type(e.g: hpf, notch)
//refer http://www.mikroe.com/chapters/view/72/chapter-2-fir-filters/
bool filter_fir_windowed( en_filter_window_type_tag wnd_type, en_filter_pass_type_tag filt_type, unsigned int taps, double fc1, double fc2, double srate, vector<double> &vcoeff )
{
int ilow;
float x;
if( ( taps & 0x1 ) == 1 )
{
taps++;
printf( "filter_fir_windowed() - to keep window impulse response symetrical, taps count will be slighlty increased\n" );
}
if( taps >= cn_filter_tap_limit )
{
printf( "filter_fir_windowed() - tap count is too large: %u, limit is: %u\n", taps, cn_filter_tap_limit - 1 );
return 0;
}
printf( "filter_fir_windowed() - srate: %f, fc1: %f, fc2: %f\n", srate, fc1, fc2 );
//printf( "filter_fir_windowed() - wnd_type: %d, filt_type: %d\n", wnd_type, filt_type );
double fs = srate;
// fs = 20000;
// fc1 = 2500;
double *w = new double[ taps + 10 ]; //add some extra space, even though only one extra space is required (as N = taps + 1)
double *hd = new double[ taps + 10 ];
double *hcoeff = new double[ taps + 10 ];
//filt_type = fpt_highpass;
vcoeff.clear();
//double twopi = 2.0 * M_PI;
double wc1, wc2;
wc1 = twopi * fc1 / fs;
wc2 = twopi * fc2 / fs;
int Nf = taps;
double N = Nf + 1;
printf( "filter_fir_windowed() - coeff count will be: %u\n", (unsigned int)N );
double M = (double)Nf / 2.0;
//cslpf( 0, "filter_fir_windowed() - wnd_type: %d, filt_type: %d, taps: %d, wc1: %g, wc2: %g\n", wnd_type, filt_type, taps, wc1, wc2 );
//!! fix this
if( wnd_type == fwt_kaiser )
{
wnd_type = fwt_undefined;
printf( "filter_fir_windowed() - wnd=kaiser not yet supported\n" );
}
for( double n = 0; n < N; n++ )
{
int i = (int)n;
switch( wnd_type )
{
case fwt_rect:
w[ i ] = 1.0; //rect window impulse resp
break;
case fwt_bartlett:
ilow = ( N - 1.0 ) / 2.0 ; //work out which formula to use (what side of the triangle peak we are in)
if( i <= ilow ) w[ i ] = 2.0 * n / ( N - 1.0 ) ; //bartlett/triangle window impulse resp
else w[ i ] = 2.0 - 2.0 * n / ( N - 1.0 ) ;
break;
case fwt_hann:
w[ i ] = 0.5 * ( 1.0 - cos( ( twopi * n / ( N - 1.0 ) ) ) ); //hann window impulse resp
break;
case fwt_bartlett_hanning:
w[ i ] = 0.62 - 0.48 * fabs( n / ( N - 1.0 ) - 0.5 ) + 0.38 * cos( ( twopi * ( n / ( N - 1.0 ) - 0.5 ) ) ); //bartlett-hanning window impulse resp
break;
case fwt_hamming:
w[ i ] = 0.54 - 0.46 * cos( twopi * n / ( N - 1.0 ) ); //hamming window impulse resp, note the text in http://www.mikroe.com.. listed above is slightly incorrect, used wikipedia version
break;
case fwt_blackman:
w[ i ] = 0.42 - 0.5 * cos( twopi * n / ( N - 1.0 ) ) + 0.08 * cos( 2.0 * twopi * n / ( N - 1.0 ) ); //blackman window impulse resp
break;
case fwt_blackman_harris:
w[ i ] = 0.35875 - 0.48829 * cos( twopi * n / ( N - 1.0 ) ) + 0.14128 * cos( 2.0 * twopi * n / ( N - 1.0 ) ) - 0.01168 * cos( 3.0 * twopi * n / ( N - 1.0 ) ); //blackman-harris window impulse resp
break;
case fwt_lanczos1: //v1.03
x = 2.0f * (float)n/(N-1);
x -= 1;
if (x < 0) x = - x;
if (x < 1) w[ i ] = ( filter_fir_sinc( x ) * filter_fir_sinc( x / 1.0 ) );
else w[ i ] = 0;
break;
case fwt_lanczos1_5: //v1.03
x = 3.0f * (float)n/(N-1);
x -= 1.5f;
if (x < 0) x = - x;
if (x < 1.5) w[ i ] = ( filter_fir_sinc( x ) * filter_fir_sinc( x / 1.5 ) );
else w[ i ] = 0;
break;
case fwt_lanczos2: //v1.03
x = 4.0f * (float)n/(N-1);
x -= 2;
if (x < 0) x = - x;
if (x < 2) w[ i ] = ( filter_fir_sinc( x ) * filter_fir_sinc( x / 2.0 ) );
else w[ i ] = 0;
break;
case fwt_lanczos3: //v1.03
x = 6.0f * (float)n/(N-1);
x -= 3;
if (x < 0) x = - x;
if (x < 3) w[ i ] = ( filter_fir_sinc( x ) * filter_fir_sinc( x / 3.0 ) );
else w[ i ] = 0;
break;
default:
printf( "filter_fir_windowed() - unknown filter window type(wnd): %u\n", wnd_type );
return 0;
break;
}
switch( filt_type )
{
case fpt_lowpass:
//ideal lowpass impulse response
if( (int)n != (int)M ) hd[ i ] = ( ( sin( wc1 * ( n - M ) ) ) / ( M_PI * ( n - M ) ) );
else hd[ i ] = wc1 / M_PI;
break;
case fpt_highpass:
//ideal highpass impulse response
if( (int)n != (int)M ) hd[ i ] = -( ( sin( wc1 * ( n - M ) ) ) / ( M_PI * ( n - M ) ) );
else hd[ i ] = 1.0 - wc1 / M_PI;
break;
case fpt_bandpass:
//ideal bandpass impulse response
if( (int)n != (int)M ) hd[ i ] = ( sin( wc2 * ( n - M ) ) / ( M_PI * ( n - M ) ) ) - ( sin( wc1 * ( n - M ) ) / ( M_PI * ( n - M ) ) );
else hd[ i ] = ( wc2 - wc1 ) / M_PI;
break;
case fpt_notch:
//ideal notch impulse response
if( (int)n != (int)M ) hd[ i ] = ( sin( wc1 * ( n - M ) ) / ( M_PI * ( n - M ) ) ) - ( sin( wc2 * ( n - M ) ) / ( M_PI * ( n - M ) ) );
else hd[ i ] = 1.0 - ( wc1 - wc2 ) / M_PI;
break;
default:
printf( "filter_fir_windowed() - unknown filter type: %u\n", filt_type );
return 0;
break;
}
hcoeff[ i ] = w[ i ] * hd[ i ]; //window * impulse response
// printf( "filter_fir_windowed() - w[%d]: %g, hd[]: %g, h[]: %g\n", (int)n, w[ i ], hd[ i ], hcoeff[ i ] );
//printf( "filter_fir_windowed() - w[%d]: %g, hd[]: %g, h[]: %g\n", (int)n, w[ i ], hd[ i ], hcoeff[ i ] );
vcoeff.push_back( hcoeff[ i ] );
}
delete w;
delete hd;
delete hcoeff;
return 1;
}
//just clears a created filter's bufs, make sure you set various 'st_fir' elements manually, this function does not alter 'st_fir'
//MAKE SURE you set 'fir.bypass = 0', see 'create_filter_from_coeffs()' for example
void fir_init( st_fir &fir )
{
if( fir.created == 0 ) return;
fir.prev_idx = 0;
for( int i = 0; i < fir.coeff_cnt; i++ ) fir.prev[ i ] = 0;
}
//not for user use
void fir_init_internal_use( st_fir &fir )
{
if( fir.created == 0 ) return;
fir.prev_idx = 0;
for( int i = 0; i < fir.coeff_cnt; i++ ) fir.prev[ i ] = 0;
}
//EXAMPLE of HOW to set up 'st_fir' before 'filter_code::create_filter_from_coeffs()'
//filter_code::st_fir fir00;
//fir00.verb = 1;
//fir00.suser0 = "fir00";
//fir00.suser1 = "in function xxxx";
//fir00.user_id0 = 0;
//fir00.user_id1 = 0;
//fir00.bypass = 0;
//fir00.created = 0;
//build an fir filter from a string loaded with coeffs, allocates memory so it must be deleted
//see ABOVE for example usage
bool create_filter_from_coeffs( st_fir &fir, vector<double> &vcoeff )
{
bool vb = fir.verb; //v1.06
if( fir.created ) delete_filter( fir );
if( vcoeff.size() == 0 )
{
if(vb)printf( "create_filter_from_coeffs() - filter not created, size requested was zero, '%s' '%s'\n", fir.suser0.c_str(), fir.suser1.c_str() );
return 0;
}
if(vb) printf( "create_filter_from_coeffs() - alloc 2 filter bufs, size each %d, '%s' '%s'\n", (int)vcoeff.size(), fir.suser0.c_str(), fir.suser1.c_str() );
fir.coeff_ptr = new double [ vcoeff.size() ]; //alloc space
fir.prev = new double [ vcoeff.size() ];
if(vb) printf( "create_filter_from_coeffs() - about to load filter coeffs, '%s' '%s'\n", fir.suser0.c_str(), fir.suser1.c_str() );
for( int i = 0; i < vcoeff.size(); i++ ) //load coeffs
{
fir.coeff_ptr[ i ] = vcoeff[ i ];
}
fir.coeff_cnt = vcoeff.size();
fir.created = 1;
//fir.bypass = 0;
fir_init_internal_use( fir ); //clear fir buf
if(vb) printf( "create_filter_from_coeffs() - filter created, '%s' '%s'\n", fir.suser0.c_str(), fir.suser1.c_str() );
if(vb) if( fir.bypass ) printf( "create_filter_from_coeffs() - filter is in BYPASS, '%s' '%s'\n", fir.suser0.c_str(), fir.suser1.c_str() );
return 1;
}
//delete filter and free any memory allocated
void delete_filter( st_fir &fir )
{
bool vb = fir.verb; //v1.06
if ( fir.created == 0 )
{
if(vb)printf( "delete_filter() - can't delete filter, it's not created, '%s' '%s'\n", fir.suser0.c_str(), fir.suser1.c_str() );
return;
}
if(vb)printf( "delete_filter() - about to delete filter, '%s' '%s'\n", fir.suser0.c_str(), fir.suser1.c_str() );
fir.created = 0;
if(vb)printf( "delete_filter() - deleted filter, '%s' '%s'\n", fir.suser0.c_str(), fir.suser1.c_str() );
delete[] fir.coeff_ptr; //v1.06
delete[] fir.prev;
fir.coeff_ptr = 0;
fir.prev = 0;
}
void fir_in( st_fir &fir, double in )
{
if( fir.created == 0 ) return;
fir.prev[ fir.prev_idx++ ] = in;