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/************************************************************************
IMPORTANT NOTE : this file contains two clearly delimited sections :
the ARCHITECTURE section (in two parts) and the USER section. Each section
is governed by its own copyright and license. Please check individually
each section for license and copyright information.
*************************************************************************/
/*******************BEGIN ARCHITECTURE SECTION (part 1/2)****************/
/************************************************************************
FAUST Architecture File
Copyright (C) 2003-2019 GRAME, Centre National de Creation Musicale
---------------------------------------------------------------------
This Architecture section 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 3 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, see <http://www.gnu.org/licenses/>.
EXCEPTION : As a special exception, you may create a larger work
that contains this FAUST architecture section and distribute
that work under terms of your choice, so long as this FAUST
architecture section is not modified.
************************************************************************
************************************************************************/
#include <stdlib.h>
#include <stdio.h>
#include <string.h>
#include <limits.h>
#include <math.h>
#include <errno.h>
#include <time.h>
#include <unistd.h>
#include <string>
#include <iostream>
#include <iomanip>
#include "faust/gui/UI.h"
#include "faust/gui/console.h"
#include "faust/gui/meta.h"
#include "faust/audio/channels.h"
#include "faust/dsp/dsp-adapter.h"
#include "faust/dsp/dsp-combiner.h"
using namespace std;
/******************************************************************************
*******************************************************************************
VECTOR INTRINSICS
*******************************************************************************
*******************************************************************************/
<<includeIntrinsic>>
/********************END ARCHITECTURE SECTION (part 1/2)****************/
/**************************BEGIN USER SECTION **************************/
<<includeclass>>
/***************************END USER SECTION ***************************/
/*******************BEGIN ARCHITECTURE SECTION (part 2/2)***************/
dsp* DSP;
std::list<GUI*> GUI::fGuiList;
ztimedmap GUI::gTimedZoneMap;
#define kFrames 512
int main(int argc, char* argv[])
{
FAUSTFLOAT start_at_sample, nb_samples, sample_rate, down_sample, up_sample, filter_type;
DSP = new mydsp();
CMDUI* interface = new CMDUI(argc, argv);
DSP->buildUserInterface(interface);
interface->addOption("-s", &start_at_sample, 0, 0.0, 100000000.0);
interface->addOption("-n", &nb_samples, 16, 0.0, 100000000.0);
interface->addOption("-r", &sample_rate, 44100.0, 1.0, 192000.0);
// For up/down sampling
interface->addOption("-ds", &down_sample, 1.0, 1.0, 16.0);
interface->addOption("-us", &up_sample, 1.0, 1.0, 16.0);
interface->addOption("-filter", &filter_type, 1.0, 1.0, 4.0);
if ((down_sample != 1.0) && (up_sample != 1.0)) {
cerr << "ERROR : -ds '" << down_sample << "' and -us '" << up_sample << "' cannot be used at the same time !\n";
exit(1);
}
// Setup up/down sampling, FC factor is expressed as a Double<INT,DENOM> to allow template specialization
int filter = int(filter_type);
if (down_sample != 1.0) {
int ds = int(down_sample);
dsp* busN = new dsp_bus(DSP->getNumOutputs());
switch (filter) {
case 1:
if (ds == 2) DSP = new dsp_sequencer(DSP, new dsp_down_sampler<LowPass3<Double<45,100>, 2, float> >(busN));
else if (ds == 4) DSP = new dsp_sequencer(DSP, new dsp_down_sampler<LowPass3<Double<45,100>, 4, float> >(busN));
else if (ds == 8) DSP = new dsp_sequencer(DSP, new dsp_down_sampler<LowPass3<Double<45,100>, 8, float> >(busN));
else if (ds == 16) DSP = new dsp_sequencer(DSP, new dsp_down_sampler<LowPass3<Double<45,100>, 16, float> >(busN));
else cerr << "Downsampling factor must be a power of two and <= 16\n";
break;
case 2:
if (ds == 2) DSP = new dsp_sequencer(DSP, new dsp_down_sampler<LowPass4<Double<45,100>, 2, float> >(busN));
else if (ds == 4) DSP = new dsp_sequencer(DSP, new dsp_down_sampler<LowPass4<Double<45,100>, 4, float> >(busN));
else if (ds == 8) DSP = new dsp_sequencer(DSP, new dsp_down_sampler<LowPass4<Double<45,100>, 8, float> >(busN));
else if (ds == 16) DSP = new dsp_sequencer(DSP, new dsp_down_sampler<LowPass4<Double<45,100>, 16, float> >(busN));
else cerr << "Downsampling factor must be a power of two and <= 16\n";
break;
case 3:
if (ds == 2) DSP = new dsp_sequencer(DSP, new dsp_down_sampler<LowPass3e<Double<45,100>, 2, float> >(busN));
else if (ds == 4) DSP = new dsp_sequencer(DSP, new dsp_down_sampler<LowPass3e<Double<45,100>, 4, float> >(busN));
else if (ds == 8) DSP = new dsp_sequencer(DSP, new dsp_down_sampler<LowPass3e<Double<45,100>, 8, float> >(busN));
else if (ds == 16) DSP = new dsp_sequencer(DSP, new dsp_down_sampler<LowPass3e<Double<45,100>, 16, float> >(busN));
else cerr << "Downsampling factor must be a power of two and <= 16\n";
break;
case 4:
if (ds == 2) DSP = new dsp_sequencer(DSP, new dsp_down_sampler<LowPass6e<Double<45,100>, 2, float> >(busN));
else if (ds == 4) DSP = new dsp_sequencer(DSP, new dsp_down_sampler<LowPass6e<Double<45,100>, 4, float> >(busN));
else if (ds == 8) DSP = new dsp_sequencer(DSP, new dsp_down_sampler<LowPass6e<Double<45,100>, 8, float> >(busN));
else if (ds == 16) DSP = new dsp_sequencer(DSP, new dsp_down_sampler<LowPass6e<Double<45,100>, 16, float> >(busN));
break;
default:
cerr << "Incorrect filter type : " << filter << endl;
break;
}
} else if (up_sample != 1.0) {
int up = int(up_sample);
dsp* busN = new dsp_bus(DSP->getNumOutputs());
switch (filter) {
case 1:
if (up == 2) DSP = new dsp_sequencer(DSP, new dsp_up_sampler<LowPass3<Double<45,100>, 2, float> >(busN));
else if (up == 4) DSP = new dsp_sequencer(DSP, new dsp_up_sampler<LowPass3<Double<45,100>, 4, float> >(busN));
else if (up == 8) DSP = new dsp_sequencer(DSP, new dsp_up_sampler<LowPass3<Double<45,100>, 8, float> >(busN));
else if (up == 16) DSP = new dsp_sequencer(DSP, new dsp_up_sampler<LowPass3<Double<45,100>, 16, float> >(busN));
else cerr << "Upsampling factor must be a power of two and <= 16\n";
break;
case 2:
if (up == 2) DSP = new dsp_sequencer(DSP, new dsp_up_sampler<LowPass4<Double<45,100>, 2, float> >(busN));
else if (up == 4) DSP = new dsp_sequencer(DSP, new dsp_up_sampler<LowPass4<Double<45,100>, 4, float> >(busN));
else if (up == 8) DSP = new dsp_sequencer(DSP, new dsp_up_sampler<LowPass4<Double<45,100>, 8, float> >(busN));
else if (up == 16) DSP = new dsp_sequencer(DSP, new dsp_up_sampler<LowPass4<Double<45,100>, 16, float> >(busN));
else cerr << "Upsampling factor must be a power of two and <= 16\n";
break;
case 3:
if (up == 2) DSP = new dsp_sequencer(DSP, new dsp_up_sampler<LowPass3e<Double<45,100>, 2, float> >(busN));
else if (up == 4) DSP = new dsp_sequencer(DSP, new dsp_up_sampler<LowPass3e<Double<45,100>, 4, float> >(busN));
else if (up == 8) DSP = new dsp_sequencer(DSP, new dsp_up_sampler<LowPass3e<Double<45,100>, 8, float> >(busN));
else if (up == 16) DSP = new dsp_sequencer(DSP, new dsp_up_sampler<LowPass3e<Double<45,100>, 16, float> >(busN));
else cerr << "Upsampling factor must be a power of two and <= 16\n";
break;
case 4:
if (up == 2) DSP = new dsp_sequencer(DSP, new dsp_up_sampler<LowPass6e<Double<45,100>, 2, float> >(busN));
else if (up == 4) DSP = new dsp_sequencer(DSP, new dsp_up_sampler<LowPass6e<Double<45,100>, 4, float> >(busN));
else if (up == 8) DSP = new dsp_sequencer(DSP, new dsp_up_sampler<LowPass6e<Double<45,100>, 8, float> >(busN));
else if (up == 16) DSP = new dsp_sequencer(DSP, new dsp_up_sampler<LowPass6e<Double<45,100>, 16, float> >(busN));
break;
default:
cerr << "Incorrect filter type : " << filter << endl;
break;
}
}
// init signal processor and the user interface values:
DSP->init(int(sample_rate));
// modify the UI values according to the command line options, after init
interface->process_command();
// prepare input channels (if any) with an impulse
int nins = DSP->getNumInputs();
channels inchan(kFrames, nins);
inchan.impulse(); // after each compute we will zero them
// prepare output channels
int nouts = DSP->getNumOutputs();
channels outchan(kFrames, nouts);
// print usage info:
printf("%% Usage: octave --persist thisfile.m\n\n");
// print matlab-compatible matrix syntax followed by a plot command:
printf("faustout = [ ...\n");
// skip <start> samples
int start = int(start_at_sample);
while (start > kFrames) {
DSP->compute(kFrames, inchan.buffers(), outchan.buffers());
inchan.zero();
start -= kFrames;
}
if (start > 0) {
DSP->compute(start, inchan.buffers(), outchan.buffers());
}
// end skip
int nbsamples = int(nb_samples);
cout << setprecision(numeric_limits<FAUSTFLOAT>::max_digits10);
// Print by buffer
while (nbsamples > kFrames) {
DSP->compute(kFrames, inchan.buffers(), outchan.buffers());
inchan.zero();
for (int i = 0; i < kFrames; i++) {
for (int c = 0; c < nouts; c++) {
cout << " " << outchan.buffers()[c][i];
}
if (i < kFrames-1) {
printf("; ...\n");
} else {
printf("; ...\n%%---- Chunk Boundary ----\n");
}
}
nbsamples -= kFrames;
}
// Print remaining frames
if (nbsamples) {
DSP->compute(nbsamples, inchan.buffers(), outchan.buffers());
inchan.zero();
for (int i = 0; i < nbsamples; i++) {
for (int c = 0; c < nouts; c++) {
cout << " " << outchan.buffers()[c][i];
}
printf("; ...\n");
}
}
printf("];\n\n");
printf("plot(faustout);\n");
printf("title('Plot generated by %s made using ''faust -a matlabplot.cpp ...''');\n", argv[0]);
printf("xlabel('Time (samples)');\n");
printf("ylabel('Amplitude');\n");
if (nouts > 0) {
printf("legend(");
for (int c = 0; c < nouts; c++) {
printf("'channel %d'", c+1);
if (c < nouts-1) { printf(","); }
}
printf(");\n");
printf("print -dpdf %s.pdf;\n", argv[0]);
}
delete DSP;
return 0;
}
/********************END ARCHITECTURE SECTION (part 2/2)****************/
|
