/*
This file is part of Ingen.
Copyright 2007-2012 David Robillard
Ingen is free software: you can redistribute it and/or modify it under the
terms of the GNU Affero General Public License as published by the Free
Software Foundation, either version 3 of the License, or any later version.
Ingen 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 Affero General Public License for details.
You should have received a copy of the GNU Affero General Public License
along with Ingen. If not, see .
*/
#include
#include "ingen/shared/LV2URIMap.hpp"
#include "ingen/shared/URIs.hpp"
#include "internals/Controller.hpp"
#include "lv2/lv2plug.in/ns/ext/atom/util.h"
#include "raul/midi_events.h"
#include "AudioBuffer.hpp"
#include "InputPort.hpp"
#include "InternalPlugin.hpp"
#include "Notification.hpp"
#include "OutputPort.hpp"
#include "PostProcessor.hpp"
#include "ProcessContext.hpp"
#include "util.hpp"
using namespace std;
namespace Ingen {
namespace Server {
namespace Internals {
InternalPlugin* ControllerNode::internal_plugin(Shared::URIs& uris) {
return new InternalPlugin(uris, NS_INTERNALS "Controller", "controller");
}
ControllerNode::ControllerNode(InternalPlugin* plugin,
BufferFactory& bufs,
const string& path,
bool polyphonic,
PatchImpl* parent,
SampleRate srate)
: NodeImpl(plugin, path, false, parent, srate)
, _learning(false)
{
const Ingen::Shared::URIs& uris = bufs.uris();
_ports = new Raul::Array(6);
_midi_in_port = new InputPort(bufs, this, "input", 0, 1,
PortType::ATOM, uris.atom_Sequence, Raul::Atom());
_midi_in_port->set_property(uris.lv2_name, bufs.forge().alloc("Input"));
_ports->at(0) = _midi_in_port;
_param_port = new InputPort(bufs, this, "controller", 1, 1,
PortType::CONTROL, 0, bufs.forge().make(0.0f));
_param_port->set_property(uris.lv2_minimum, bufs.forge().make(0.0f));
_param_port->set_property(uris.lv2_maximum, bufs.forge().make(127.0f));
_param_port->set_property(uris.lv2_integer, bufs.forge().make(true));
_param_port->set_property(uris.lv2_name, bufs.forge().alloc("Controller"));
_ports->at(1) = _param_port;
_log_port = new InputPort(bufs, this, "logarithmic", 2, 1,
PortType::CONTROL, 0, bufs.forge().make(0.0f));
_log_port->set_property(uris.lv2_portProperty, uris.lv2_toggled);
_log_port->set_property(uris.lv2_name, bufs.forge().alloc("Logarithmic"));
_ports->at(2) = _log_port;
_min_port = new InputPort(bufs, this, "minimum", 3, 1,
PortType::CONTROL, 0, bufs.forge().make(0.0f));
_min_port->set_property(uris.lv2_name, bufs.forge().alloc("Minimum"));
_ports->at(3) = _min_port;
_max_port = new InputPort(bufs, this, "maximum", 4, 1,
PortType::CONTROL, 0, bufs.forge().make(1.0f));
_max_port->set_property(uris.lv2_name, bufs.forge().alloc("Maximum"));
_ports->at(4) = _max_port;
_audio_port = new OutputPort(bufs, this, "ar_output", 5, 1,
PortType::AUDIO, 0, bufs.forge().make(0.0f));
_audio_port->set_property(uris.lv2_name, bufs.forge().alloc("Output"));
_ports->at(5) = _audio_port;
}
void
ControllerNode::process(ProcessContext& context)
{
NodeImpl::pre_process(context);
Buffer* const midi_in = _midi_in_port->buffer(0).get();
LV2_Atom_Sequence* seq = (LV2_Atom_Sequence*)midi_in->atom();
LV2_ATOM_SEQUENCE_FOREACH(seq, ev) {
const uint8_t* buf = (const uint8_t*)LV2_ATOM_BODY(&ev->body);
if (ev->body.type == _midi_in_port->bufs().uris().midi_MidiEvent &&
ev->body.size >= 3 && (buf[0] & 0xF0) == MIDI_CMD_CONTROL) {
control(context, buf[1], buf[2], ev->time.frames + context.start());
}
}
NodeImpl::post_process(context);
}
void
ControllerNode::control(ProcessContext& context, uint8_t control_num, uint8_t val, FrameTime time)
{
Sample scaled_value;
const Sample nval = (val / 127.0f); // normalized [0, 1]
if (_learning) {
// FIXME: not thread safe
_param_port->set_value(context.engine().world()->forge().make(control_num));
((AudioBuffer*)_param_port->buffer(0).get())->set_value(
(float)control_num, context.start(), context.end());
_param_port->broadcast_value(context, true);
_learning = false;
}
const Sample min_port_val = ((AudioBuffer*)_min_port->buffer(0).get())->value_at(0);
const Sample max_port_val = ((AudioBuffer*)_max_port->buffer(0).get())->value_at(0);
const Sample log_port_val = ((AudioBuffer*)_log_port->buffer(0).get())->value_at(0);
if (log_port_val > 0.0f) {
// haaaaack, stupid negatives and logarithms
Sample log_offset = 0;
if (min_port_val < 0)
log_offset = fabs(min_port_val);
const Sample min = log(min_port_val + 1 + log_offset);
const Sample max = log(max_port_val + 1 + log_offset);
scaled_value = expf(nval * (max - min) + min) - 1 - log_offset;
} else {
scaled_value = ((nval) * (max_port_val - min_port_val)) + min_port_val;
}
if (control_num == ((AudioBuffer*)_param_port->buffer(0).get())->value_at(0))
((AudioBuffer*)_audio_port->buffer(0).get())->set_value(scaled_value, context.start(), time);
}
} // namespace Internals
} // namespace Server
} // namespace Ingen