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livetrax/libs/ardour/amp.cc

451 lines
12 KiB
C++

/*
Copyright (C) 2006 Paul Davis
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.,
675 Mass Ave, Cambridge, MA 02139, USA.
*/
#include <iostream>
#include <cstring>
#include <cmath>
#include <algorithm>
#include "evoral/Curve.hpp"
#include "ardour/amp.h"
#include "ardour/audio_buffer.h"
#include "ardour/buffer_set.h"
#include "ardour/gain_control.h"
#include "ardour/midi_buffer.h"
#include "ardour/rc_configuration.h"
#include "ardour/session.h"
#include "pbd/i18n.h"
using namespace ARDOUR;
using namespace PBD;
// used for low-pass filter denormal protection
#define GAIN_COEFF_TINY (1e-10) // -200dB
Amp::Amp (Session& s, const std::string& name, boost::shared_ptr<GainControl> gc, bool control_midi_also)
: Processor(s, "Amp")
, _apply_gain(true)
, _apply_gain_automation(false)
, _current_gain(GAIN_COEFF_ZERO)
, _current_automation_frame (INT64_MAX)
, _gain_control (gc)
, _gain_automation_buffer(0)
, _midi_amp (control_midi_also)
{
set_display_name (name);
add_control (_gain_control);
}
bool
Amp::can_support_io_configuration (const ChanCount& in, ChanCount& out)
{
out = in;
return true;
}
bool
Amp::configure_io (ChanCount in, ChanCount out)
{
if (out != in) { // always 1:1
return false;
}
return Processor::configure_io (in, out);
}
static void
scale_midi_velocity(Evoral::Event<MidiBuffer::TimeType>& ev, float factor)
{
factor = std::max(factor, 0.0f);
ev.set_velocity(std::min(127L, lrintf(ev.velocity() * factor)));
}
void
Amp::run (BufferSet& bufs, framepos_t /*start_frame*/, framepos_t /*end_frame*/, double /*speed*/, pframes_t nframes, bool)
{
if (!_active && !_pending_active) {
return;
}
if (_apply_gain) {
if (_apply_gain_automation) {
gain_t* gab = _gain_automation_buffer;
assert (gab);
if (_midi_amp) {
for (BufferSet::midi_iterator i = bufs.midi_begin(); i != bufs.midi_end(); ++i) {
MidiBuffer& mb (*i);
for (MidiBuffer::iterator m = mb.begin(); m != mb.end(); ++m) {
Evoral::Event<MidiBuffer::TimeType> ev = *m;
if (ev.is_note_on()) {
assert(ev.time() >= 0 && ev.time() < nframes);
scale_midi_velocity (ev, fabsf (gab[ev.time()]));
}
}
}
}
const double a = 156.825 / _session.nominal_frame_rate(); // 25 Hz LPF; see Amp::apply_gain for details
double lpf = _current_gain;
for (BufferSet::audio_iterator i = bufs.audio_begin(); i != bufs.audio_end(); ++i) {
Sample* const sp = i->data();
lpf = _current_gain;
for (pframes_t nx = 0; nx < nframes; ++nx) {
sp[nx] *= lpf;
lpf += a * (gab[nx] - lpf);
}
}
if (fabs (lpf) < GAIN_COEFF_TINY) {
_current_gain = GAIN_COEFF_ZERO;
} else {
_current_gain = lpf;
}
} else { /* manual (scalar) gain */
gain_t const dg = _gain_control->get_value();
if (_current_gain != dg) {
_current_gain = Amp::apply_gain (bufs, _session.nominal_frame_rate(), nframes, _current_gain, dg, _midi_amp);
} else if (_current_gain != GAIN_COEFF_UNITY) {
/* gain has not changed, but its non-unity */
if (_midi_amp) {
/* don't Trim midi velocity -- only relevant for Midi on Audio tracks */
for (BufferSet::midi_iterator i = bufs.midi_begin(); i != bufs.midi_end(); ++i) {
MidiBuffer& mb (*i);
for (MidiBuffer::iterator m = mb.begin(); m != mb.end(); ++m) {
Evoral::Event<MidiBuffer::TimeType> ev = *m;
if (ev.is_note_on()) {
scale_midi_velocity (ev, fabsf (_current_gain));
}
}
}
}
for (BufferSet::audio_iterator i = bufs.audio_begin(); i != bufs.audio_end(); ++i) {
apply_gain_to_buffer (i->data(), nframes, _current_gain);
}
}
}
}
_active = _pending_active;
}
gain_t
Amp::apply_gain (BufferSet& bufs, framecnt_t sample_rate, framecnt_t nframes, gain_t initial, gain_t target, bool midi_amp)
{
/** Apply a (potentially) declicked gain to the buffers of @a bufs */
gain_t rv = target;
if (nframes == 0 || bufs.count().n_total() == 0) {
return initial;
}
// if we don't need to declick, defer to apply_simple_gain
if (initial == target) {
apply_simple_gain (bufs, nframes, target);
return target;
}
/* MIDI Gain */
if (midi_amp) {
/* don't Trim midi velocity -- only relevant for Midi on Audio tracks */
for (BufferSet::midi_iterator i = bufs.midi_begin(); i != bufs.midi_end(); ++i) {
gain_t delta;
if (target < initial) {
/* fade out: remove more and more of delta from initial */
delta = -(initial - target);
} else {
/* fade in: add more and more of delta from initial */
delta = target - initial;
}
MidiBuffer& mb (*i);
for (MidiBuffer::iterator m = mb.begin(); m != mb.end(); ++m) {
Evoral::Event<MidiBuffer::TimeType> ev = *m;
if (ev.is_note_on()) {
const gain_t scale = delta * (ev.time()/(double) nframes);
scale_midi_velocity (ev, fabsf (initial + scale));
}
}
}
}
/* Audio Gain */
/* Low pass filter coefficient: 1.0 - e^(-2.0 * π * f / 48000) f in Hz.
* for f << SR, approx a ~= 6.2 * f / SR;
*/
const double a = 156.825 / sample_rate; // 25 Hz LPF
for (BufferSet::audio_iterator i = bufs.audio_begin(); i != bufs.audio_end(); ++i) {
Sample* const buffer = i->data();
double lpf = initial;
for (pframes_t nx = 0; nx < nframes; ++nx) {
buffer[nx] *= lpf;
lpf += a * (target - lpf);
}
if (i == bufs.audio_begin()) {
rv = lpf;
}
}
if (fabsf (rv - target) < GAIN_COEFF_TINY) return target;
if (fabsf (rv) < GAIN_COEFF_TINY) return GAIN_COEFF_ZERO;
return rv;
}
void
Amp::declick (BufferSet& bufs, framecnt_t nframes, int dir)
{
if (nframes == 0 || bufs.count().n_total() == 0) {
return;
}
const framecnt_t declick = std::min ((framecnt_t) 512, nframes);
const double fractional_shift = 1.0 / declick ;
gain_t delta, initial;
if (dir < 0) {
/* fade out: remove more and more of delta from initial */
delta = -1.0;
initial = GAIN_COEFF_UNITY;
} else {
/* fade in: add more and more of delta from initial */
delta = 1.0;
initial = GAIN_COEFF_ZERO;
}
/* Audio Gain */
for (BufferSet::audio_iterator i = bufs.audio_begin(); i != bufs.audio_end(); ++i) {
Sample* const buffer = i->data();
double fractional_pos = 0.0;
for (pframes_t nx = 0; nx < declick; ++nx) {
buffer[nx] *= initial + (delta * fractional_pos);
fractional_pos += fractional_shift;
}
/* now ensure the rest of the buffer has the target value applied, if necessary. */
if (declick != nframes) {
if (dir < 0) {
memset (&buffer[declick], 0, sizeof (Sample) * (nframes - declick));
}
}
}
}
gain_t
Amp::apply_gain (AudioBuffer& buf, framecnt_t sample_rate, framecnt_t nframes, gain_t initial, gain_t target)
{
/* Apply a (potentially) declicked gain to the contents of @a buf
* -- used by MonitorProcessor::run()
*/
if (nframes == 0) {
return initial;
}
// if we don't need to declick, defer to apply_simple_gain
if (initial == target) {
apply_simple_gain (buf, nframes, target);
return target;
}
Sample* const buffer = buf.data();
const double a = 156.825 / sample_rate; // 25 Hz LPF, see [other] Amp::apply_gain() above for details
double lpf = initial;
for (pframes_t nx = 0; nx < nframes; ++nx) {
buffer[nx] *= lpf;
lpf += a * (target - lpf);
}
if (fabs (lpf - target) < GAIN_COEFF_TINY) return target;
if (fabs (lpf) < GAIN_COEFF_TINY) return GAIN_COEFF_ZERO;
return lpf;
}
void
Amp::apply_simple_gain (BufferSet& bufs, framecnt_t nframes, gain_t target, bool midi_amp)
{
if (fabsf (target) < GAIN_COEFF_SMALL) {
if (midi_amp) {
/* don't Trim midi velocity -- only relevant for Midi on Audio tracks */
for (BufferSet::midi_iterator i = bufs.midi_begin(); i != bufs.midi_end(); ++i) {
MidiBuffer& mb (*i);
for (MidiBuffer::iterator m = mb.begin(); m != mb.end(); ++m) {
Evoral::Event<MidiBuffer::TimeType> ev = *m;
if (ev.is_note_on()) {
ev.set_velocity (0);
}
}
}
}
for (BufferSet::audio_iterator i = bufs.audio_begin(); i != bufs.audio_end(); ++i) {
memset (i->data(), 0, sizeof (Sample) * nframes);
}
} else if (target != GAIN_COEFF_UNITY) {
if (midi_amp) {
/* don't Trim midi velocity -- only relevant for Midi on Audio tracks */
for (BufferSet::midi_iterator i = bufs.midi_begin(); i != bufs.midi_end(); ++i) {
MidiBuffer& mb (*i);
for (MidiBuffer::iterator m = mb.begin(); m != mb.end(); ++m) {
Evoral::Event<MidiBuffer::TimeType> ev = *m;
if (ev.is_note_on()) {
scale_midi_velocity(ev, fabsf (target));
}
}
}
}
for (BufferSet::audio_iterator i = bufs.audio_begin(); i != bufs.audio_end(); ++i) {
apply_gain_to_buffer (i->data(), nframes, target);
}
}
}
void
Amp::apply_simple_gain (AudioBuffer& buf, framecnt_t nframes, gain_t target)
{
if (fabsf (target) < GAIN_COEFF_SMALL) {
memset (buf.data(), 0, sizeof (Sample) * nframes);
} else if (target != GAIN_COEFF_UNITY) {
apply_gain_to_buffer (buf.data(), nframes, target);
}
}
XMLNode&
Amp::state (bool full_state)
{
XMLNode& node (Processor::state (full_state));
node.add_property("type", _gain_control->parameter().type() == GainAutomation ? "amp" : "trim");
node.add_child_nocopy (_gain_control->get_state());
return node;
}
int
Amp::set_state (const XMLNode& node, int version)
{
XMLNode* gain_node;
Processor::set_state (node, version);
if ((gain_node = node.child (Controllable::xml_node_name.c_str())) != 0) {
_gain_control->set_state (*gain_node, version);
}
return 0;
}
/** Write gain automation for this cycle into the buffer previously passed in to
* set_gain_automation_buffer (if we are in automation playback mode and the
* transport is rolling).
*/
void
Amp::setup_gain_automation (framepos_t start_frame, framepos_t end_frame, framecnt_t nframes)
{
Glib::Threads::Mutex::Lock am (control_lock(), Glib::Threads::TRY_LOCK);
if (am.locked()
&& (_session.transport_rolling() || _session.bounce_processing())
&& _gain_control->automation_playback())
{
assert (_gain_automation_buffer);
_apply_gain_automation = _gain_control->list()->curve().rt_safe_get_vector (
start_frame, end_frame, _gain_automation_buffer, nframes);
/* XXX the future requires a way to automate the control master
* and merge its own automation vector/curve with this one. We
* don't have a way to do that just yet, so for now, just get
* the master's current gain and scale our own automation
* vector/curve by this value.
*/
if (_gain_control->slaved()) {
const double master_gain = _gain_control->get_masters_value ();
if (master_gain != 1.0) {
apply_gain_to_buffer (_gain_automation_buffer, nframes, master_gain);
}
}
if (start_frame != _current_automation_frame && _session.bounce_processing ()) {
_current_gain = _gain_automation_buffer[0];
}
_current_automation_frame = end_frame;
} else {
_apply_gain_automation = false;
_current_automation_frame = INT64_MAX;
}
}
bool
Amp::visible() const
{
return true;
}
std::string
Amp::value_as_string (boost::shared_ptr<const AutomationControl> ac) const
{
if (ac == _gain_control) {
char buffer[32];
snprintf (buffer, sizeof (buffer), _("%.2fdB"), ac->internal_to_user (ac->get_value ()));
return buffer;
}
return Automatable::value_as_string (ac);
}
/** Sets up the buffer that setup_gain_automation and ::run will use for
* gain automationc curves. Must be called before setup_gain_automation,
* and must be called with process lock held.
*/
void
Amp::set_gain_automation_buffer (gain_t* g)
{
_gain_automation_buffer = g;
}