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gnu: alsa-modular-synth: Add patch to fix vocoder build error. 

* gnu/packages/patches/alsa-modular-synth-fix-vocoder.patch: New file.
* gnu/local.mk (dist_patch_DATA): Add it.
* gnu/packages/audio.scm (alsa-modular-synth)[source]: Add it.
This commit is contained in:
Ricardo Wurmus 2020-06-13 23:47:14 +02:00
parent 29961439aa
commit 401e6ccb12
No known key found for this signature in database
GPG Key ID: 197A5888235FACAC
3 changed files with 526 additions and 1 deletions
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1
gnu/local.mk
View File

@ -751,6 +751,7 @@ dist_patch_DATA = \
%D%/packages/patches/akonadi-not-relocatable.patch \
%D%/packages/patches/akonadi-timestamps.patch \
%D%/packages/patches/allegro-mesa-18.2.5-and-later.patch \
%D%/packages/patches/alsa-modular-synth-fix-vocoder.patch \
%D%/packages/patches/amule-crypto-6.patch \
%D%/packages/patches/anki-mpv-args.patch \
%D%/packages/patches/antiword-CVE-2014-8123.patch \

4
gnu/packages/audio.scm
View File

@ -175,7 +175,9 @@ implementation of Adaptive Multi Rate Narrowband and Wideband
"/" version "/ams-" version ".tar.bz2"))
(sha256
(base32
"1azbrhpfk4nnybr7kgmc7w6al6xnzppg853vas8gmkh185kk11l0"))))
"1azbrhpfk4nnybr7kgmc7w6al6xnzppg853vas8gmkh185kk11l0"))
(patches
(search-patches "alsa-modular-synth-fix-vocoder.patch"))))
(build-system gnu-build-system)
(arguments
`(#:configure-flags

522
gnu/packages/patches/alsa-modular-synth-fix-vocoder.patch Normal file
View File

@ -0,0 +1,522 @@
This patch was taken from Debian.
https://salsa.debian.org/multimedia-team/ams/-/raw/master/debian/patches/0007-Make-vocoder-module-compatible-to-C-11.patch
From: Guido Scholz <gscholz@users.sourceforge.net>
Date: Tue, 6 Nov 2018 21:55:38 +0100
Subject: Make vocoder module compatible to C++11
---
src/m_vocoder.cpp | 218 +++++++++++++++++++++++++++---------------------------
src/m_vocoder.h | 31 ++++----
2 files changed, 124 insertions(+), 125 deletions(-)
diff --git a/src/m_vocoder.cpp b/src/m_vocoder.cpp
index 572cf65..371e2cf 100644
--- a/src/m_vocoder.cpp
+++ b/src/m_vocoder.cpp
@@ -18,10 +18,6 @@
along with ams. If not, see <http://www.gnu.org/licenses/>.
*/
-#include <stdio.h>
-#include <stdlib.h>
-#include <unistd.h>
-#include <math.h>
#include <qwidget.h>
#include <qstring.h>
#include <qslider.h>
@@ -36,16 +32,13 @@
#include "synthdata.h"
#include "midicheckbox.h"
#include "midislider.h"
-// For FFTW to be happy we must include complex.h before fftw3.h
-#include <complex.h>
-#include <fftw3.h>
#include "port.h"
#include "m_vocoder.h"
// Window function - One way to make the FFT behave
// and give more continuous results over edge steps.
-float M_vocoder::windowcurve (int windowfunc, int len, int elem, float alpha)
+float M_vocoder::windowcurve (int windowfunc, unsigned int len, int elem, float alpha)
{
float out;
out = 1.0;
@@ -98,6 +91,7 @@ float M_vocoder::windowcurve (int windowfunc, int len, int elem, float alpha)
return (out);
}
+
M_vocoder::M_vocoder(QWidget* parent, int id)
: Module(M_type_vocoder, id, 5, parent, tr("FFT Vocoder"))
{
@@ -160,6 +154,7 @@ M_vocoder::M_vocoder(QWidget* parent, int id)
modbuf[l1] = (float *)malloc( fftsize * sizeof(float));
memset( modbuf[l1], 0, fftsize * sizeof(float));
}
+
carrbuf = (float **)malloc(synthdata->poly * sizeof(float *));
for (l1 = 0; l1 < synthdata->poly; l1++) {
carrbuf[l1] = (float *)malloc( fftsize * sizeof(float));
@@ -175,38 +170,48 @@ M_vocoder::M_vocoder(QWidget* parent, int id)
window[l2] = windowcurve (whichwin, fftsize, l2, 0.25);
// FFTW setup stuff
- carrinforward = (fftw_complex *) fftw_malloc (sizeof (fftw_complex)
- * fftsize);
- carrinbackward = (fftw_complex *) fftw_malloc (sizeof (fftw_complex)
- * fftsize);
- carroutforward = (fftw_complex *) fftw_malloc (sizeof (fftw_complex)
- * fftsize);
- carroutbackward = (fftw_complex *) fftw_malloc (sizeof (fftw_complex)
- * fftsize);
- modinforward = (fftw_complex *) fftw_malloc (sizeof (fftw_complex)
- * fftsize);
- modinbackward = (fftw_complex *) fftw_malloc (sizeof (fftw_complex)
- * fftsize);
- modoutforward = (fftw_complex *) fftw_malloc (sizeof (fftw_complex)
- * fftsize);
- modoutbackward = (fftw_complex *) fftw_malloc (sizeof (fftw_complex)
- * fftsize);
- fftw_set_timelimit (5.0);
- planmodforward = fftw_plan_dft_1d (fftsize, modinforward,
- modoutforward, FFTW_FORWARD, FFTW_MEASURE);
- planmodbackward = fftw_plan_dft_1d (fftsize, modinbackward,
- modoutbackward, FFTW_BACKWARD, FFTW_MEASURE);
- plancarrforward = fftw_plan_dft_1d (fftsize, carrinforward,
- carroutforward, FFTW_FORWARD, FFTW_MEASURE);
- plancarrbackward = fftw_plan_dft_1d (fftsize, carrinbackward,
- carroutbackward, FFTW_BACKWARD, FFTW_MEASURE);
+ carrinforward.reserve(fftsize);
+ carrinbackward.reserve(fftsize);
+ carroutforward.reserve(fftsize);
+ carroutbackward.reserve(fftsize);
+ modinforward.reserve(fftsize);
+ modinbackward.reserve(fftsize);
+ modoutforward.reserve(fftsize);
+ modoutbackward.reserve(fftsize);
+
+ fftw_set_timelimit(5.0);
+
+ planmodforward = fftw_plan_dft_1d(fftsize,
+ reinterpret_cast<fftw_complex*> (modinforward.data()),
+ reinterpret_cast<fftw_complex*> (modoutforward.data()),
+ FFTW_FORWARD, FFTW_MEASURE);
+
+ planmodbackward = fftw_plan_dft_1d(fftsize,
+ reinterpret_cast<fftw_complex*> (modinbackward.data()),
+ reinterpret_cast<fftw_complex*> (modoutbackward.data()),
+ FFTW_BACKWARD, FFTW_MEASURE);
+
+ plancarrforward = fftw_plan_dft_1d(fftsize,
+ reinterpret_cast<fftw_complex*> (carrinforward.data()),
+ reinterpret_cast<fftw_complex*> (carroutforward.data()),
+ FFTW_FORWARD, FFTW_MEASURE);
+
+ plancarrbackward = fftw_plan_dft_1d(fftsize,
+ reinterpret_cast<fftw_complex*> (carrinbackward.data()),
+ reinterpret_cast<fftw_complex*> (carroutbackward.data()),
+ FFTW_BACKWARD, FFTW_MEASURE);
}
+
M_vocoder::~M_vocoder() {
- int l1;
+ // Clean up FFTW stuff.
+ fftw_destroy_plan (plancarrforward);
+ fftw_destroy_plan (plancarrbackward);
+ fftw_destroy_plan (planmodforward);
+ fftw_destroy_plan (planmodbackward);
- for (l1 = 0; l1 < synthdata->poly; l1++) {
+ for (int l1 = 0; l1 < synthdata->poly; l1++) {
free(modbuf[l1]);
free(carrbuf[l1]);
}
@@ -215,29 +220,14 @@ M_vocoder::~M_vocoder() {
free (window);
free (modmap);
free (armodmap);
-
- //#define FFTW_CLEANUP
-#ifdef FFTW_CLEANUP
- // Clean up FFTW stuff.
- fftw_destroy_plan (plancarrforward);
- fftw_destroy_plan (plancarrbackward);
- fftw_destroy_plan (planmodforward);
- fftw_destroy_plan (planmodbackward);
- fftw_free (carrinforward);
- fftw_free (carrinbackward);
- fftw_free (carroutforward);
- fftw_free (carroutbackward);
- fftw_free (modinforward);
- fftw_free (modinbackward);
- fftw_free (modoutforward);
- fftw_free (modoutbackward);
-#endif
}
+
void M_vocoder::generateCycle() {
int l1; // l1 indexes along polyphony.
unsigned int l2; // l2 indexes along the cycle
+ const std::complex<double> I(0.0, 1.0);
inModulator = port_M_modulator->getinputdata();
inPitchShift = port_M_pitchshift->getinputdata();
@@ -272,7 +262,7 @@ void M_vocoder::generateCycle() {
// Did the user change the FFT windowing function?
if (myFFTWindowFunc != whichwin) {
whichwin = myFFTWindowFunc;
- for (l2 = 0; l2 < (unsigned int) fftsize; l2++)
+ for (l2 = 0; l2 < fftsize; l2++)
window[l2] = windowcurve (whichwin, fftsize, l2, 0.25);
}
@@ -294,7 +284,7 @@ void M_vocoder::generateCycle() {
}
// window the input buffer to modinforward
- for (l2 = 0; l2 < (unsigned int)fftsize ; l2++) {
+ for (l2 = 0; l2 < fftsize ; l2++) {
modinforward[l2] = modbuf[l1][l2] * window[l2];
}
@@ -310,17 +300,18 @@ void M_vocoder::generateCycle() {
fftw_execute (planmodforward);
// copy the FFT of the modulator to modinbackward.
- for (l2 = 0; l2 < (unsigned int)fftsize; l2++)
- modinbackward[l2] = modoutforward[l2];
+ //for (l2 = 0; l2 < fftsize; l2++)
+ // modinbackward[l2] = modoutforward[l2];
+ modinbackward = modoutforward;
// Send the FFT of the modulator to the output for giggles
// and get an approximation of the first harmonic too.
float firstharmonicval;
int firstharmonicindex;
firstharmonicval = 0.0;
- firstharmonicindex = 1.0;
+ firstharmonicindex = 1;
for (l2 = 1; l2 < (unsigned int) synthdata->cyclesize; l2++) {
- data[2][l1][l2] = logf(fabs (creal (modoutforward[l2])) + 1.0);
+ data[2][l1][l2] = logf(fabs(modoutforward[l2].real()) + 1.0);
if (data[2][l1][l2] > firstharmonicval) {
firstharmonicindex = l2;
firstharmonicval = data[2][l1][l2] ;
@@ -333,35 +324,38 @@ void M_vocoder::generateCycle() {
// intermediate frequency-domain munging of modulator
// Frequency (additive, Bode-style) shifting first
- for (l2 = 0; l2 < (unsigned int)fftsize; l2++)
- modinbackward[l2] = 0;
+ for (l2 = 0; l2 < fftsize; l2++)
+ modinbackward[l2] = 0.0;
+
int lclfrq;
- for (l2 = 0; l2 < (unsigned int)fftsize/2; l2++) {
+ for (l2 = 0; l2 < fftsize/2; l2++) {
// positive frequencies (first half) of the FFT result
lclfrq = l2 + (int)freqshift + vcfreqshift * inFreqShift[l1][0];
lclfrq = lclfrq > 0 ? lclfrq : 0;
- lclfrq = lclfrq < ((fftsize/2)-1) ? lclfrq : (fftsize/2)-1;
+ lclfrq = lclfrq < (int)((fftsize/2)-1) ? lclfrq : (fftsize/2)-1;
modinbackward [lclfrq] = modoutforward [l2];
// Negative frequencies (second half of the fft result)
- modinbackward [fftsize - lclfrq] = modoutforward [ fftsize - l2];
+ modinbackward [fftsize - lclfrq] = modoutforward [fftsize - l2];
}
- // Pitchshifting (multiplicative, harmonic-retaining) shifting.
- // Note that we reuse the modoutforward as working space
- for (l2 = 0; l2 < (unsigned int) fftsize; l2++) {
- modoutforward[l2] = modinbackward[l2];
- };
- for (l2 = 0; l2 < (unsigned int)fftsize; l2++)
- modinbackward[l2] = 0;
+ // Pitchshifting (multiplicative, harmonic-retaining) shifting.
+ // Note that we reuse the modoutforward as working space
+ //for (l2 = 0; l2 < fftsize; l2++) {
+ // modoutforward[l2] = modinbackward[l2];
+ //};
+ modoutforward = modinbackward;
+
+ for (l2 = 0; l2 < fftsize; l2++)
+ modinbackward[l2] = 0.0;
float psmod, psfactor;
psmod = (pitchshift + vcpitch * inPitchShift[l1][0]);
psfactor = pow (2.0, psmod);
- for (l2 = 0; l2 < (unsigned int)fftsize/2; l2++) {
+ for (l2 = 0; l2 < fftsize/2; l2++) {
// positive frequencies (first half) of the FFT result
lclfrq = l2 * psfactor;
lclfrq = lclfrq > 0 ? lclfrq : 0;
- lclfrq = lclfrq < ((fftsize/2)-1) ? lclfrq : (fftsize/2)-1;
+ lclfrq = lclfrq < (int)((fftsize/2)-1) ? lclfrq : (fftsize/2)-1;
// Old way to pitch shift: just move the bucket. But this puts
// nulls wherever the energy is split between two buckets with
// a 180 degree phase difference.
@@ -375,12 +369,12 @@ void M_vocoder::generateCycle() {
// Better way: move freq. bin, multiply angle by octave motion.
//
modinbackward[lclfrq] +=
- cabs (modoutforward [l2])
- * cexp (I * ( carg (modoutforward [l2])
+ std::abs(modoutforward[l2])
+ * std::exp (I * ( std::arg (modoutforward [l2])
+ (l2 * phaseshift * psfactor)));
modinbackward[fftsize - lclfrq] +=
- cabs (modoutforward [ fftsize - l2])
- * cexp (I * ( carg (modoutforward [ fftsize - l2])
+ std::abs (modoutforward [ fftsize - l2])
+ * std::exp (I * ( std::arg (modoutforward [ fftsize - l2])
+ (l2 * phaseshift * psfactor)));
};
}
@@ -389,9 +383,9 @@ void M_vocoder::generateCycle() {
fftw_execute (planmodbackward);
// renormalize the time-domain modulator output
- for (l2 = 0; l2 < (unsigned)fftsize; l2++) {
- modoutbackward [l2] = modoutbackward[l2] / float (fftsize) ;
- modoutbackward [l2] = modoutbackward[l2] / window[l2];
+ for (l2 = 0; l2 < fftsize; l2++) {
+ modoutbackward [l2] = modoutbackward[l2] / (double) fftsize;
+ modoutbackward [l2] = modoutbackward[l2] / (double) window[l2];
}
unsigned int i;
@@ -400,13 +394,11 @@ void M_vocoder::generateCycle() {
// Splicing the new output to the results
- if (dynsplice == 0.0)
- {
+ if (dynsplice == 0.0) {
// output it as the altered modulator.
for (l2 = 0; l2 < synthdata->cyclesize; l2++) {
- data[0][l1][l2] = creal ( modoutbackward [l2 +
- fftsize/2 -
- synthdata->cyclesize/2 ]);
+ data[0][l1][l2] =
+ modoutbackward[l2 + fftsize/2 - synthdata->cyclesize/2].real();
}
clomatch_index = fftsize - synthdata->cyclesize;
}
@@ -421,18 +413,21 @@ void M_vocoder::generateCycle() {
float tval, dtval;
int searchstart;
float spliceval, dspliceval;
- searchstart = fftsize/2 - synthdata->cyclesize;
- if (searchstart < 1) searchstart = 1;
- clomatch_index = searchstart;
+
+ searchstart = fftsize/2 - synthdata->cyclesize;
+ if (searchstart < 1)
+ searchstart = 1;
+
+ clomatch_index = searchstart;
spliceval = data[0][l1][synthdata->cyclesize - 1];
dspliceval = spliceval - data[0][l1][synthdata->cyclesize - 2];
- clov_sofar= fabs(creal(modoutbackward[clomatch_index])-spliceval );
+ clov_sofar= fabs(modoutbackward[clomatch_index].real()-spliceval);
for (l2 = searchstart;
l2 < (searchstart + synthdata->cyclesize);
l2++)
{
- tval = creal (modoutbackward[l2]);
- dtval = tval - creal (modoutbackward [l2-1]);
+ tval = modoutbackward[l2].real();
+ dtval = tval - modoutbackward [l2-1].real();
if (
((fabs (tval - spliceval )) < clov_sofar )
&& ((dtval * dspliceval ) >= 0)
@@ -445,15 +440,15 @@ void M_vocoder::generateCycle() {
};
// fprintf (stderr, "%d %f %f ",
// clomatch_index, clov_sofar, clodv_sofar);
-
+
// What's our residual error, so that we can splice this
// with minimal "click"?
- residual = + spliceval - creal( modoutbackward[clomatch_index]);
+ residual = + spliceval - modoutbackward[clomatch_index].real();
// Move our wave, with the best match so far established, to
// the output buffer area.
for (l2 = 0; l2 < synthdata->cyclesize; l2++) {
- data[0][l1][l2] = creal ( modoutbackward [ clomatch_index + l2])
+ data[0][l1][l2] = modoutbackward[clomatch_index + l2].real()
+ ((1.0 - (float(l2) / float(synthdata->cyclesize))) * residual);
};
@@ -466,17 +461,18 @@ void M_vocoder::generateCycle() {
for (l2 = 0; l2 < fftsize - synthdata->cyclesize; l2++) {
carrbuf [l1][l2] = carrbuf [l1][l2 + synthdata->cyclesize];
}
+
for (l2 = 0; l2 < synthdata->cyclesize; l2++) {
carrbuf [l1][l2 + fftsize - synthdata->cyclesize] = inCarrier[l1][l2];
}
- for (l2 = 0; l2 < unsigned (fftsize); l2++) {
+ for (l2 = 0; l2 < fftsize; l2++) {
carrinforward [l2] = carrbuf [l1][l2] * window[l2];
}
fftw_execute (plancarrforward);
- for (l2 = 0; l2 < (unsigned) fftsize; l2++) {
+ for (l2 = 0; l2 < fftsize; l2++) {
carrinbackward[l2] = carroutforward[l2];
};
@@ -486,34 +482,37 @@ void M_vocoder::generateCycle() {
// Group the modulator into channels, and multipy the channels
// over the carrier.
- int localchannels;
- localchannels = channels + vcchannels * inChannels[l1][0];
- if (localchannels < 1) localchannels = 1;
- if (localchannels > fftsize - 1) localchannels = fftsize - 1;
- for (l2 = 0; l2 < (unsigned) fftsize; l2++) {
+ unsigned int localchannels = channels + vcchannels * inChannels[l1][0];
+ if (localchannels < 1)
+ localchannels = 1;
+
+ if (localchannels > fftsize - 1)
+ localchannels = fftsize - 1;
+
+ for (l2 = 0; l2 < fftsize; l2++) {
modmap[l2] = 0;
// initial conditions...
if (l2 == 0)
for (i = 0; i < channels; i++)
- modmap[l2] += cabs (modoutforward[l2 + i]);
+ modmap[l2] += std::abs(modoutforward[l2 + i]);
else
modmap [l2] = modmap[l2 - 1];
// add the heads, subtract the tails
i = l2 + channels;
- if (l2 < (unsigned)fftsize - 2)
- modmap[l2] += cabs( modoutforward [i] );
+ if (l2 < fftsize - 2)
+ modmap[l2] += std::abs(modoutforward[i]);
i = l2 - channels;
if (l2 >= channels)
- modmap[l2] -= cabs( modoutforward [i] );
+ modmap[l2] -= std::abs(modoutforward[i]);
}
// Normalize the modmap
- for (l2 = 0; l2 < (unsigned) fftsize; l2++)
+ for (l2 = 0; l2 < fftsize; l2++)
modmap[l2] = modmap[l2] / localchannels;
// Do attack/release
- for (l2 = 0; l2 < (unsigned) fftsize; l2++) {
+ for (l2 = 0; l2 < fftsize; l2++) {
if (modmap [l2] > armodmap[l2])
armodmap [l2] += (1 - attack) * (modmap[l2] - armodmap[l2]);
if (modmap [l2] < armodmap[l2])
@@ -521,8 +520,8 @@ void M_vocoder::generateCycle() {
}
// multiply the carrier by the modulation map.
- for (l2 = 0; l2 < (unsigned) fftsize; l2++) {
- carrinbackward[l2] = carroutforward[l2] * armodmap[l2];
+ for (l2 = 0; l2 < fftsize; l2++) {
+ carrinbackward[l2] = carroutforward[l2] * (double) armodmap[l2];
}
// reverse transform to final output, and renormalize by 1/fftsize.
@@ -532,8 +531,7 @@ void M_vocoder::generateCycle() {
for (l2 = 0; l2 < synthdata->cyclesize; l2++) {
offset = l2 + (fftsize/2) - (synthdata->cyclesize / 2);
data[1][l1][l2]=
- (creal(carroutbackward[offset]/window[offset])) / (fftsize * 100);
+ (carroutbackward[offset].real()/window[offset]) / (fftsize * 100);
};
};
}
-
diff --git a/src/m_vocoder.h b/src/m_vocoder.h
index 38eac58..32c8521 100644
--- a/src/m_vocoder.h
+++ b/src/m_vocoder.h
@@ -1,4 +1,4 @@
-/*
+/*
Vocoder - derived from m_delay.cpp
Copyright (C) 2011 Bill Yerazunis <yerazunis@yahoo.com>
@@ -22,7 +22,9 @@
#define M_VOCODER_H
#include "module.h"
-#include <complex.h>
+
+#include <vector>
+#include <ccomplex>
#include <fftw3.h>
#define MODULE_VOCODER_WIDTH 105
@@ -30,7 +32,7 @@
class M_vocoder : public Module
{
- Q_OBJECT
+ Q_OBJECT
float channels, vcchannels;
float attack, release;
@@ -42,21 +44,20 @@ class M_vocoder : public Module
Port *port_M_modulator, *port_M_pitchshift, *port_M_freqshift,
*port_M_channels, *port_M_carrier;
+
Port *port_modfft_out, *port_firstharmonic_out,
- *port_altmodulator_out,
- *port_vocoder_out;
+ *port_altmodulator_out, *port_vocoder_out;
- fftw_plan planmodforward, planmodbackward,
+ fftw_plan planmodforward, planmodbackward,
plancarrforward, plancarrbackward;
- fftw_complex *carrinforward, *carroutforward,
- *carrinbackward, *carroutbackward,
- *modinforward, *modoutforward,
- *modinbackward, *modoutbackward;
+ std::vector<std::complex<double>> carrinforward, carroutforward,
+ carrinbackward, carroutbackward,
+ modinforward, modoutforward,
+ modinbackward, modoutbackward;
- public:
- int fftsize;
- float **inModulator, **inPitchShift, **inFreqShift,
+ unsigned int fftsize;
+ float **inModulator, **inPitchShift, **inFreqShift,
**inChannels, **inCarrier;
// the previous time-based samples, for overlapping
float **modbuf, **carrbuf;
@@ -68,10 +69,10 @@ class M_vocoder : public Module
float *armodmap;
public:
- float windowcurve (int windowfunc, int len, int elem, float alpha );
+ float windowcurve (int windowfunc, unsigned int len, int elem, float alpha );
M_vocoder(QWidget* parent=0, int id = 0);
~M_vocoder();
void generateCycle();
};
-
+
#endif