ardour/livetrax
13
0
Fork 0
Code
7cbf35a3d6
livetrax/libs/surfaces/generic_midi/midicontrollable.cc
Paul Davis 9e3299f97d change Controllable::set_value() API to include grouped control consideration. 
This also removes Route::group_gain_control() and associated machinery.
Not yet tested with Mackie or other surfaces. More work to done to
start using the group capabilities, and also potentially to add
or derive more controls as RouteAutomationControls
2016-01-02 04:58:30 -05:00

776 lines
21 KiB
C++
Raw Blame History

/*
Copyright (C) 1998-2006 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 <stdint.h>
#include <cmath>
#include <climits>
#include <iostream>
#include "pbd/error.h"
#include "pbd/controllable_descriptor.h"
#include "pbd/xml++.h"
#include "pbd/stacktrace.h"
#include "pbd/compose.h"
#include "midi++/types.h" // Added by JE - 06-01-2009. All instances of 'byte' changed to 'MIDI::byte' (for clarification)
#include "midi++/port.h"
#include "midi++/channel.h"
#include "ardour/async_midi_port.h"
#include "ardour/automation_control.h"
#include "ardour/midi_ui.h"
#include "ardour/utils.h"
#include "ardour/debug.h"
#include "midicontrollable.h"
#include "generic_midi_control_protocol.h"
using namespace std;
using namespace MIDI;
using namespace PBD;
using namespace ARDOUR;
MIDIControllable::MIDIControllable (GenericMidiControlProtocol* s, MIDI::Parser& p, bool m)
: _surface (s)
, controllable (0)
, _descriptor (0)
, _parser (p)
, _momentary (m)
{
_learned = false; /* from URI */
_encoder = No_enc;
setting = false;
last_value = 0; // got a better idea ?
last_controllable_value = 0.0f;
control_type = none;
control_rpn = -1;
control_nrpn = -1;
_control_description = "MIDI Control: none";
control_additional = (MIDI::byte) -1;
feedback = true; // for now
}
MIDIControllable::MIDIControllable (GenericMidiControlProtocol* s, MIDI::Parser& p, Controllable& c, bool m)
: _surface (s)
, _descriptor (0)
, _parser (p)
, _momentary (m)
{
set_controllable (&c);
_learned = true; /* from controllable */
_encoder = No_enc;
setting = false;
last_value = 0; // got a better idea ?
last_controllable_value = 0.0f;
control_type = none;
control_rpn = -1;
control_nrpn = -1;
_control_description = "MIDI Control: none";
control_additional = (MIDI::byte) -1;
feedback = true; // for now
}
MIDIControllable::~MIDIControllable ()
{
drop_external_control ();
}
int
MIDIControllable::init (const std::string& s)
{
_current_uri = s;
delete _descriptor;
_descriptor = new ControllableDescriptor;
return _descriptor->set (s);
}
void
MIDIControllable::midi_forget ()
{
/* stop listening for incoming messages, but retain
our existing event + type information.
*/
midi_sense_connection[0].disconnect ();
midi_sense_connection[1].disconnect ();
midi_learn_connection.disconnect ();
}
void
MIDIControllable::drop_external_control ()
{
midi_forget ();
control_rpn = -1;
control_nrpn = -1;
control_type = none;
control_additional = (MIDI::byte) -1;
}
void
MIDIControllable::set_controllable (Controllable* c)
{
if (c == controllable) {
return;
}
controllable_death_connection.disconnect ();
controllable = c;
if (controllable) {
last_controllable_value = controllable->get_value();
} else {
last_controllable_value = 0.0f; // is there a better value?
}
if (controllable) {
controllable->Destroyed.connect (controllable_death_connection, MISSING_INVALIDATOR,
boost::bind (&MIDIControllable::drop_controllable, this),
MidiControlUI::instance());
}
}
void
MIDIControllable::midi_rebind (channel_t c)
{
if (c >= 0) {
bind_midi (c, control_type, control_additional);
} else {
midi_forget ();
}
}
void
MIDIControllable::learn_about_external_control ()
{
drop_external_control ();
_parser.any.connect_same_thread (midi_learn_connection, boost::bind (&MIDIControllable::midi_receiver, this, _1, _2, _3));
}
void
MIDIControllable::stop_learning ()
{
midi_learn_connection.disconnect ();
}
int
MIDIControllable::control_to_midi (float val)
{
if (controllable->is_gain_like()) {
return gain_to_slider_position (val) * max_value_for_type ();
}
float control_min = controllable->lower ();
float control_max = controllable->upper ();
float control_range = control_max - control_min;
if (controllable->is_toggle()) {
if (val >= (control_min + (control_range/2.0f))) {
return max_value_for_type();
} else {
return 0;
}
} else {
AutomationControl *actl = dynamic_cast<AutomationControl*> (controllable);
if (actl) {
control_min = actl->internal_to_interface(control_min);
control_max = actl->internal_to_interface(control_max);
control_range = control_max - control_min;
val = actl->internal_to_interface(val);
}
}
// fiddle value of max so value doesn't jump from 125 to 127 for 1.0
// otherwise decrement won't work.
return (val - control_min) / control_range * (max_value_for_type () - 1);
}
float
MIDIControllable::midi_to_control (int val)
{
/* fiddle with MIDI value so that we get an odd number of integer steps
and can thus represent "middle" precisely as 0.5. this maps to
the range 0..+1.0 (0 to 126)
*/
float fv = (val == 0 ? 0 : float (val - 1) / (max_value_for_type() - 1));
if (controllable->is_gain_like()) {
return controllable->interface_to_internal (fv);
}
DEBUG_TRACE (DEBUG::GenericMidi, string_compose ("Raw value %1 float %2\n", val, fv));
float control_min = controllable->lower ();
float control_max = controllable->upper ();
float control_range = control_max - control_min;
DEBUG_TRACE (DEBUG::GenericMidi, string_compose ("Min %1 Max %2 Range %3\n", control_min, control_max, control_range));
AutomationControl *actl = dynamic_cast<AutomationControl*> (controllable);
if (actl) {
if (fv == 0.f) return control_min;
if (fv == 1.f) return control_max;
control_min = actl->internal_to_interface(control_min);
control_max = actl->internal_to_interface(control_max);
control_range = control_max - control_min;
return actl->interface_to_internal((fv * control_range) + control_min);
}
return (fv * control_range) + control_min;
}
void
MIDIControllable::midi_sense_note_on (Parser &p, EventTwoBytes *tb)
{
midi_sense_note (p, tb, true);
}
void
MIDIControllable::midi_sense_note_off (Parser &p, EventTwoBytes *tb)
{
midi_sense_note (p, tb, false);
}
int
MIDIControllable::lookup_controllable()
{
if (!_descriptor) {
return -1;
}
boost::shared_ptr<Controllable> c = _surface->lookup_controllable (*_descriptor);
if (!c) {
return -1;
}
set_controllable (c.get ());
return 0;
}
void
MIDIControllable::drop_controllable ()
{
set_controllable (0);
}
void
MIDIControllable::midi_sense_note (Parser &, EventTwoBytes *msg, bool /*is_on*/)
{
if (!controllable) {
if (lookup_controllable()) {
return;
}
}
if (!controllable->is_toggle()) {
if (control_additional == msg->note_number) {
controllable->set_value (midi_to_control (msg->velocity), Controllable::NoGroup);
DEBUG_TRACE (DEBUG::GenericMidi, string_compose ("Note %1 value %2 %3\n", (int) msg->note_number, (float) midi_to_control (msg->velocity), current_uri() ));
}
} else {
if (control_additional == msg->note_number) {
float new_value = controllable->get_value() > 0.5f ? 0.0f : 1.0f;
controllable->set_value (new_value, Controllable::NoGroup);
DEBUG_TRACE (DEBUG::GenericMidi, string_compose ("Note %1 Value %2 %3\n", (int) msg->note_number, (float) new_value, current_uri()));
}
}
last_value = (MIDI::byte) (controllable->get_value() * 127.0); // to prevent feedback fights
}
void
MIDIControllable::midi_sense_controller (Parser &, EventTwoBytes *msg)
{
if (!controllable) {
if (lookup_controllable ()) {
return;
}
}
assert (controllable);
if (controllable->touching()) {
return; // to prevent feedback fights when e.g. dragging a UI slider
}
if (control_additional == msg->controller_number) {
if (!controllable->is_toggle()) {
if (get_encoder() == No_enc) {
float new_value = msg->value;
float max_value = max(last_controllable_value, new_value);
float min_value = min(last_controllable_value, new_value);
float range = max_value - min_value;
float threshold = (float) _surface->threshold ();
bool const in_sync = (
range < threshold &&
controllable->get_value() <= midi_to_control(max_value) &&
controllable->get_value() >= midi_to_control(min_value)
);
/* If the surface is not motorised, we try to prevent jumps when
the MIDI controller and controllable are out of sync.
There might be a better way of doing this.
*/
if (in_sync || _surface->motorised ()) {
controllable->set_value (midi_to_control (new_value), Controllable::NoGroup);
}
DEBUG_TRACE (DEBUG::GenericMidi, string_compose ("MIDI CC %1 value %2 %3\n", (int) msg->controller_number, (float) midi_to_control(new_value), current_uri() ));
last_controllable_value = new_value;
} else {
int offset = (msg->value & 0x3f);
switch (get_encoder()) {
case Enc_L:
if (msg->value > 0x40) {
controllable->set_value (midi_to_control (last_value - offset + 1), Controllable::NoGroup);
} else {
controllable->set_value (midi_to_control (last_value + offset + 1), Controllable::NoGroup);
}
break;
case Enc_R:
if (msg->value > 0x40) {
controllable->set_value (midi_to_control (last_value + offset + 1), Controllable::NoGroup);
} else {
controllable->set_value (midi_to_control (last_value - offset + 1), Controllable::NoGroup);
}
break;
case Enc_2:
if (msg->value > 0x40) {
controllable->set_value (midi_to_control (last_value - (0x7f - msg->value) + 1), Controllable::NoGroup);
} else {
controllable->set_value (midi_to_control (last_value + offset + 1), Controllable::NoGroup);
}
break;
case Enc_B:
if (msg->value > 0x40) {
controllable->set_value (midi_to_control (last_value + offset + 1), Controllable::NoGroup);
} else {
controllable->set_value (midi_to_control (last_value - (0x40 - offset)), Controllable::NoGroup);
}
break;
default:
break;
}
DEBUG_TRACE (DEBUG::GenericMidi, string_compose ("MIDI CC %1 value %2 %3\n", (int) msg->controller_number, (int) last_value, current_uri() ));
}
} else {
if (msg->value > 64.0f) {
controllable->set_value (1, Controllable::NoGroup);
DEBUG_TRACE (DEBUG::GenericMidi, string_compose ("Midi CC %1 value 1 %2\n", (int) msg->controller_number, current_uri()));
} else {
controllable->set_value (0, Controllable::NoGroup);
DEBUG_TRACE (DEBUG::GenericMidi, string_compose ("Midi CC %1 value 0 %2\n", (int) msg->controller_number, current_uri()));
}
}
last_value = (MIDI::byte) (control_to_midi(controllable->get_value())); // to prevent feedback fights
}
}
void
MIDIControllable::midi_sense_program_change (Parser &, MIDI::byte msg)
{
if (!controllable) {
if (lookup_controllable ()) {
return;
}
}
if (msg == control_additional) {
if (!controllable->is_toggle()) {
controllable->set_value (1.0, Controllable::NoGroup);
DEBUG_TRACE (DEBUG::GenericMidi, string_compose ("MIDI program %1 value 1.0 %3\n", (int) msg, current_uri() ));
} else {
float new_value = controllable->get_value() > 0.5f ? 0.0f : 1.0f;
controllable->set_value (new_value, Controllable::NoGroup);
DEBUG_TRACE (DEBUG::GenericMidi, string_compose ("MIDI program %1 value %2 %3\n", (int) msg, (float) new_value, current_uri()));
}
}
last_value = (MIDI::byte) (controllable->get_value() * 127.0); // to prevent feedback fights
}
void
MIDIControllable::midi_sense_pitchbend (Parser &, pitchbend_t pb)
{
if (!controllable) {
if (lookup_controllable ()) {
return;
}
}
if (!controllable->is_toggle()) {
controllable->set_value (midi_to_control (pb), Controllable::NoGroup);
DEBUG_TRACE (DEBUG::GenericMidi, string_compose ("MIDI pitchbend %1 value %2 %3\n", (int) control_channel, (float) midi_to_control (pb), current_uri() ));
} else {
if (pb > 8065.0f) {
controllable->set_value (1, Controllable::NoGroup);
DEBUG_TRACE (DEBUG::GenericMidi, string_compose ("Midi pitchbend %1 value 1 %2\n", (int) control_channel, current_uri()));
} else {
controllable->set_value (0, Controllable::NoGroup);
DEBUG_TRACE (DEBUG::GenericMidi, string_compose ("Midi pitchbend %1 value 0 %2\n", (int) control_channel, current_uri()));
}
}
last_value = control_to_midi (controllable->get_value ());
}
void
MIDIControllable::midi_receiver (Parser &, MIDI::byte *msg, size_t /*len*/)
{
/* we only respond to channel messages */
if ((msg[0] & 0xF0) < 0x80 || (msg[0] & 0xF0) > 0xE0) {
return;
}
_surface->check_used_event(msg[0], msg[1]);
bind_midi ((channel_t) (msg[0] & 0xf), eventType (msg[0] & 0xF0), msg[1]);
if (controllable) {
controllable->LearningFinished ();
}
}
void
MIDIControllable::rpn_value_change (Parser&, uint16_t rpn, float val)
{
if (control_rpn == rpn) {
if (controllable) {
controllable->set_value (val, Controllable::NoGroup);
}
}
}
void
MIDIControllable::nrpn_value_change (Parser&, uint16_t nrpn, float val)
{
if (control_nrpn == nrpn) {
if (controllable) {
controllable->set_value (val, Controllable::NoGroup);
}
}
}
void
MIDIControllable::rpn_change (Parser&, uint16_t rpn, int dir)
{
if (control_rpn == rpn) {
if (controllable) {
/* XXX how to increment/decrement ? */
// controllable->set_value (val);
}
}
}
void
MIDIControllable::nrpn_change (Parser&, uint16_t nrpn, int dir)
{
if (control_nrpn == nrpn) {
if (controllable) {
/* XXX how to increment/decrement ? */
// controllable->set_value (val);
}
}
}
void
MIDIControllable::bind_rpn_value (channel_t chn, uint16_t rpn)
{
int chn_i = chn;
drop_external_control ();
control_rpn = rpn;
control_channel = chn;
_parser.channel_rpn[chn_i].connect_same_thread (midi_sense_connection[0], boost::bind (&MIDIControllable::rpn_value_change, this, _1, _2, _3));
}
void
MIDIControllable::bind_nrpn_value (channel_t chn, uint16_t nrpn)
{
int chn_i = chn;
drop_external_control ();
control_nrpn = nrpn;
control_channel = chn;
_parser.channel_nrpn[chn_i].connect_same_thread (midi_sense_connection[0], boost::bind (&MIDIControllable::rpn_value_change, this, _1, _2, _3));
}
void
MIDIControllable::bind_nrpn_change (channel_t chn, uint16_t nrpn)
{
int chn_i = chn;
drop_external_control ();
control_nrpn = nrpn;
control_channel = chn;
_parser.channel_nrpn_change[chn_i].connect_same_thread (midi_sense_connection[0], boost::bind (&MIDIControllable::rpn_change, this, _1, _2, _3));
}
void
MIDIControllable::bind_rpn_change (channel_t chn, uint16_t rpn)
{
int chn_i = chn;
drop_external_control ();
control_rpn = rpn;
control_channel = chn;
_parser.channel_rpn_change[chn_i].connect_same_thread (midi_sense_connection[0], boost::bind (&MIDIControllable::nrpn_change, this, _1, _2, _3));
}
void
MIDIControllable::bind_midi (channel_t chn, eventType ev, MIDI::byte additional)
{
char buf[64];
drop_external_control ();
control_type = ev;
control_channel = chn;
control_additional = additional;
int chn_i = chn;
switch (ev) {
case MIDI::off:
_parser.channel_note_off[chn_i].connect_same_thread (midi_sense_connection[0], boost::bind (&MIDIControllable::midi_sense_note_off, this, _1, _2));
/* if this is a togglee, connect to noteOn as well,
and we'll toggle back and forth between the two.
*/
if (_momentary) {
_parser.channel_note_on[chn_i].connect_same_thread (midi_sense_connection[1], boost::bind (&MIDIControllable::midi_sense_note_on, this, _1, _2));
}
_control_description = "MIDI control: NoteOff";
break;
case MIDI::on:
_parser.channel_note_on[chn_i].connect_same_thread (midi_sense_connection[0], boost::bind (&MIDIControllable::midi_sense_note_on, this, _1, _2));
if (_momentary) {
_parser.channel_note_off[chn_i].connect_same_thread (midi_sense_connection[1], boost::bind (&MIDIControllable::midi_sense_note_off, this, _1, _2));
}
_control_description = "MIDI control: NoteOn";
break;
case MIDI::controller:
_parser.channel_controller[chn_i].connect_same_thread (midi_sense_connection[0], boost::bind (&MIDIControllable::midi_sense_controller, this, _1, _2));
snprintf (buf, sizeof (buf), "MIDI control: Controller %d", control_additional);
_control_description = buf;
break;
case MIDI::program:
_parser.channel_program_change[chn_i].connect_same_thread (midi_sense_connection[0], boost::bind (&MIDIControllable::midi_sense_program_change, this, _1, _2));
_control_description = "MIDI control: ProgramChange";
break;
case MIDI::pitchbend:
_parser.channel_pitchbend[chn_i].connect_same_thread (midi_sense_connection[0], boost::bind (&MIDIControllable::midi_sense_pitchbend, this, _1, _2));
_control_description = "MIDI control: Pitchbend";
break;
default:
break;
}
DEBUG_TRACE (DEBUG::GenericMidi, string_compose ("Controlable: bind_midi: %1 on Channel %2 value %3 \n", _control_description, chn_i + 1, (int) additional));
}
MIDI::byte*
MIDIControllable::write_feedback (MIDI::byte* buf, int32_t& bufsize, bool /*force*/)
{
if (!controllable || !feedback) {
return buf;
}
float val = controllable->get_value ();
/* Note that when sending RPN/NPRN we do two things:
*
* always send MSB first, then LSB
* null/reset the parameter ID after sending.
*
* this follows recommendations found online, eg. http://www.philrees.co.uk/nrpnq.htm
*/
if (control_rpn >= 0) {
if (bufsize < 13) {
return buf;
}
int rpn_val = (int) lrintf (val * 16384.0);
if (last_value == rpn_val) {
return buf;
}
*buf++ = (0xb0) | control_channel;
*buf++ = 0x62;
*buf++ = (int) ((control_rpn) >> 7);
*buf++ = 0x63;
*buf++ = (int) (control_rpn & 0x7f);
*buf++ = 0x06;
*buf++ = (int) (rpn_val >> 7);
*buf++ = 0x26;
*buf++ = (int) (rpn_val & 0x7f);
*buf++ = 0x62;
*buf++ = 0x7f;
*buf++ = 0x63;
*buf++ = 0x7f;
bufsize -= 13;
last_value = rpn_val;
DEBUG_TRACE (DEBUG::GenericMidi, string_compose ("MIDI out: RPN %1 Channel %2 Value %3\n", control_rpn, (int) control_channel, val));
return buf;
}
if (control_nrpn >= 0) {
int rpn_val = (int) lrintf (val * 16384.0);
if (last_value == rpn_val) {
return buf;
}
*buf++ = (0xb0) | control_channel;
*buf++ = 0x64;
*buf++ = (int) ((control_rpn) >> 7);
*buf++ = 0x65;
*buf++ = (int) (control_rpn & 0x7f);
*buf++ = 0x06;
*buf++ = (int) (rpn_val >> 7);
*buf++ = 0x26;
*buf++ = (int) (rpn_val & 0x7f);
*buf++ = 0x64;
*buf++ = 0x7f;
*buf++ = 0x65;
*buf++ = 0x7f;
last_value = rpn_val;
bufsize -= 13;
DEBUG_TRACE (DEBUG::GenericMidi, string_compose ("MIDI out: NRPN %1 Channel %2 Value %3\n", control_nrpn, (int) control_channel, val));
return buf;
}
if (control_type == none || bufsize <= 2) {
return buf;
}
int const gm = control_to_midi (val);
if (gm == last_value) {
return buf;
}
DEBUG_TRACE (DEBUG::GenericMidi, string_compose ("Feedback: %1 %2\n", control_description(), current_uri()));
*buf++ = (0xF0 & control_type) | (0xF & control_channel);
int ev_size = 3;
switch (control_type) {
case MIDI::pitchbend:
*buf++ = int (gm) & 127;
*buf++ = (int (gm) >> 7) & 127;
break;
case MIDI::program:
*buf++ = control_additional; /* program number */
ev_size = 2;
break;
default:
*buf++ = control_additional; /* controller number */
*buf++ = gm;
break;
}
DEBUG_TRACE (DEBUG::GenericMidi, string_compose ("MIDI out: Type %1 Channel %2 Bytes %3 %4\n", (int) control_type, (int) control_channel , (int) *(buf - 2), (int) *(buf - 1)));
last_value = gm;
bufsize -= ev_size;
return buf;
}
int
MIDIControllable::set_state (const XMLNode& node, int /*version*/)
{
const XMLProperty* prop;
int xx;
if ((prop = node.property ("event")) != 0) {
sscanf (prop->value().c_str(), "0x%x", &xx);
control_type = (MIDI::eventType) xx;
} else {
return -1;
}
if ((prop = node.property ("channel")) != 0) {
sscanf (prop->value().c_str(), "%d", &xx);
control_channel = (MIDI::channel_t) xx;
} else {
return -1;
}
if ((prop = node.property ("additional")) != 0) {
sscanf (prop->value().c_str(), "0x%x", &xx);
control_additional = (MIDI::byte) xx;
} else {
return -1;
}
if ((prop = node.property ("feedback")) != 0) {
feedback = (prop->value() == "yes");
} else {
feedback = true; // default
}
bind_midi (control_channel, control_type, control_additional);
return 0;
}
XMLNode&
MIDIControllable::get_state ()
{
char buf[32];
XMLNode* node = new XMLNode ("MIDIControllable");
if (_current_uri.empty()) {
node->add_property ("id", controllable->id().to_s());
} else {
node->add_property ("uri", _current_uri);
}
if (controllable) {
snprintf (buf, sizeof(buf), "0x%x", (int) control_type);
node->add_property ("event", buf);
snprintf (buf, sizeof(buf), "%d", (int) control_channel);
node->add_property ("channel", buf);
snprintf (buf, sizeof(buf), "0x%x", (int) control_additional);
node->add_property ("additional", buf);
node->add_property ("feedback", (feedback ? "yes" : "no"));
}
return *node;
}
/** @return the maximum value for a control value transmitted
* using a given MIDI::eventType.
*/
int
MIDIControllable::max_value_for_type () const
{
/* XXX: this is not complete */
if (control_type == MIDI::pitchbend) {
return 16383;
}
return 127;
}
View Git Blame Copy Permalink