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livetrax/libs/surfaces/generic_midi/generic_midi_control_protocol.cc

1038 lines
24 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 <stdint.h>
#include <sstream>
#include <algorithm>
#include <glibmm/fileutils.h>
#include <glibmm/miscutils.h>
#include "pbd/controllable_descriptor.h"
#include "pbd/error.h"
#include "pbd/failed_constructor.h"
#include "pbd/pathscanner.h"
#include "pbd/xml++.h"
#include "midi++/port.h"
#include "ardour/audioengine.h"
#include "ardour/filesystem_paths.h"
#include "ardour/session.h"
#include "ardour/route.h"
#include "ardour/midi_ui.h"
#include "ardour/rc_configuration.h"
#include "ardour/midiport_manager.h"
#include "generic_midi_control_protocol.h"
#include "midicontrollable.h"
#include "midifunction.h"
#include "midiaction.h"
using namespace ARDOUR;
using namespace PBD;
using namespace std;
#include "i18n.h"
#define midi_ui_context() MidiControlUI::instance() /* a UICallback-derived object that specifies the event loop for signal handling */
GenericMidiControlProtocol::GenericMidiControlProtocol (Session& s)
: ControlProtocol (s, _("Generic MIDI"))
, _motorised (false)
, _threshold (10)
, gui (0)
{
_input_port = AudioEngine::instance()->midi_input_port ();
_output_port = AudioEngine::instance()->midi_output_port ();
do_feedback = false;
_feedback_interval = 10000; // microseconds
last_feedback_time = 0;
_current_bank = 0;
_bank_size = 0;
/* these signals are emitted by the MidiControlUI's event loop thread
* and we may as well handle them right there in the same the same
* thread
*/
Controllable::StartLearning.connect_same_thread (*this, boost::bind (&GenericMidiControlProtocol::start_learning, this, _1));
Controllable::StopLearning.connect_same_thread (*this, boost::bind (&GenericMidiControlProtocol::stop_learning, this, _1));
Controllable::CreateBinding.connect_same_thread (*this, boost::bind (&GenericMidiControlProtocol::create_binding, this, _1, _2, _3));
Controllable::DeleteBinding.connect_same_thread (*this, boost::bind (&GenericMidiControlProtocol::delete_binding, this, _1));
Session::SendFeedback.connect (*this, MISSING_INVALIDATOR, boost::bind (&GenericMidiControlProtocol::send_feedback, this), midi_ui_context());;
#if 0
/* XXXX SOMETHING GOES WRONG HERE (april 2012) - STILL DEBUGGING */
/* this signal is emitted by the process() callback, and if
* send_feedback() is going to do anything, it should do it in the
* context of the process() callback itself.
*/
Session::SendFeedback.connect_same_thread (*this, boost::bind (&GenericMidiControlProtocol::send_feedback, this));
#endif
/* this one is cross-thread */
Route::RemoteControlIDChange.connect (*this, MISSING_INVALIDATOR, boost::bind (&GenericMidiControlProtocol::reset_controllables, this), midi_ui_context());
reload_maps ();
}
GenericMidiControlProtocol::~GenericMidiControlProtocol ()
{
drop_all ();
tear_down_gui ();
}
static const char * const midimap_env_variable_name = "ARDOUR_MIDIMAPS_PATH";
static const char* const midi_map_dir_name = "midi_maps";
static const char* const midi_map_suffix = ".map";
SearchPath
system_midi_map_search_path ()
{
bool midimap_path_defined = false;
std::string spath_env (Glib::getenv (midimap_env_variable_name, midimap_path_defined));
if (midimap_path_defined) {
return spath_env;
}
SearchPath spath (ardour_data_search_path());
spath.add_subdirectory_to_paths(midi_map_dir_name);
return spath;
}
static std::string
user_midi_map_directory ()
{
return Glib::build_filename (user_config_directory(), midi_map_dir_name);
}
static bool
midi_map_filter (const string &str, void */*arg*/)
{
return (str.length() > strlen(midi_map_suffix) &&
str.find (midi_map_suffix) == (str.length() - strlen (midi_map_suffix)));
}
void
GenericMidiControlProtocol::reload_maps ()
{
vector<string *> *midi_maps;
PathScanner scanner;
SearchPath spath (system_midi_map_search_path());
spath += user_midi_map_directory ();
midi_maps = scanner (spath.to_string(), midi_map_filter, 0, false, true);
if (!midi_maps) {
cerr << "No MIDI maps found using " << spath.to_string() << endl;
return;
}
for (vector<string*>::iterator i = midi_maps->begin(); i != midi_maps->end(); ++i) {
string fullpath = *(*i);
XMLTree tree;
if (!tree.read (fullpath.c_str())) {
continue;
}
MapInfo mi;
XMLProperty* prop = tree.root()->property ("name");
if (!prop) {
continue;
}
mi.name = prop->value ();
mi.path = fullpath;
map_info.push_back (mi);
}
delete midi_maps;
}
void
GenericMidiControlProtocol::drop_all ()
{
Glib::Threads::Mutex::Lock lm (pending_lock);
Glib::Threads::Mutex::Lock lm2 (controllables_lock);
for (MIDIControllables::iterator i = controllables.begin(); i != controllables.end(); ++i) {
delete *i;
}
controllables.clear ();
for (MIDIPendingControllables::iterator i = pending_controllables.begin(); i != pending_controllables.end(); ++i) {
delete *i;
}
pending_controllables.clear ();
for (MIDIFunctions::iterator i = functions.begin(); i != functions.end(); ++i) {
delete *i;
}
functions.clear ();
for (MIDIActions::iterator i = actions.begin(); i != actions.end(); ++i) {
delete *i;
}
actions.clear ();
}
void
GenericMidiControlProtocol::drop_bindings ()
{
Glib::Threads::Mutex::Lock lm2 (controllables_lock);
for (MIDIControllables::iterator i = controllables.begin(); i != controllables.end(); ) {
if (!(*i)->learned()) {
delete *i;
i = controllables.erase (i);
} else {
++i;
}
}
for (MIDIFunctions::iterator i = functions.begin(); i != functions.end(); ++i) {
delete *i;
}
functions.clear ();
_current_binding = "";
_bank_size = 0;
_current_bank = 0;
}
int
GenericMidiControlProtocol::set_active (bool /*yn*/)
{
/* start/stop delivery/outbound thread */
return 0;
}
void
GenericMidiControlProtocol::set_feedback_interval (microseconds_t ms)
{
_feedback_interval = ms;
}
void
GenericMidiControlProtocol::send_feedback ()
{
/* This is executed in RT "process" context", so no blocking calls
*/
if (!do_feedback) {
return;
}
microseconds_t now = get_microseconds ();
if (last_feedback_time != 0) {
if ((now - last_feedback_time) < _feedback_interval) {
return;
}
}
_send_feedback ();
last_feedback_time = now;
}
void
GenericMidiControlProtocol::_send_feedback ()
{
/* This is executed in RT "process" context", so no blocking calls
*/
const int32_t bufsize = 16 * 1024; /* XXX too big */
MIDI::byte buf[bufsize];
int32_t bsize = bufsize;
/* XXX: due to bugs in some ALSA / JACK MIDI bridges, we have to do separate
writes for each controllable here; if we send more than one MIDI message
in a single jack_midi_event_write then some bridges will only pass the
first on to ALSA.
*/
Glib::Threads::Mutex::Lock lm (controllables_lock, Glib::Threads::TRY_LOCK);
if (!lm.locked ()) {
return;
}
for (MIDIControllables::iterator r = controllables.begin(); r != controllables.end(); ++r) {
MIDI::byte* end = (*r)->write_feedback (buf, bsize);
if (end != buf) {
_output_port->write (buf, (int32_t) (end - buf), 0);
}
}
}
bool
GenericMidiControlProtocol::start_learning (Controllable* c)
{
if (c == 0) {
return false;
}
Glib::Threads::Mutex::Lock lm2 (controllables_lock);
MIDIControllables::iterator tmp;
for (MIDIControllables::iterator i = controllables.begin(); i != controllables.end(); ) {
tmp = i;
++tmp;
if ((*i)->get_controllable() == c) {
delete (*i);
controllables.erase (i);
}
i = tmp;
}
{
Glib::Threads::Mutex::Lock lm (pending_lock);
MIDIPendingControllables::iterator ptmp;
for (MIDIPendingControllables::iterator i = pending_controllables.begin(); i != pending_controllables.end(); ) {
ptmp = i;
++ptmp;
if (((*i)->first)->get_controllable() == c) {
(*i)->second.disconnect();
delete (*i)->first;
delete *i;
pending_controllables.erase (i);
}
i = ptmp;
}
}
MIDIControllable* mc = 0;
for (MIDIControllables::iterator i = controllables.begin(); i != controllables.end(); ++i) {
if ((*i)->get_controllable() && ((*i)->get_controllable()->id() == c->id())) {
mc = *i;
break;
}
}
if (!mc) {
mc = new MIDIControllable (this, *_input_port->parser(), *c, false);
}
{
Glib::Threads::Mutex::Lock lm (pending_lock);
MIDIPendingControllable* element = new MIDIPendingControllable;
element->first = mc;
c->LearningFinished.connect_same_thread (element->second, boost::bind (&GenericMidiControlProtocol::learning_stopped, this, mc));
pending_controllables.push_back (element);
}
mc->learn_about_external_control ();
return true;
}
void
GenericMidiControlProtocol::learning_stopped (MIDIControllable* mc)
{
Glib::Threads::Mutex::Lock lm (pending_lock);
Glib::Threads::Mutex::Lock lm2 (controllables_lock);
MIDIPendingControllables::iterator tmp;
for (MIDIPendingControllables::iterator i = pending_controllables.begin(); i != pending_controllables.end(); ) {
tmp = i;
++tmp;
if ( (*i)->first == mc) {
(*i)->second.disconnect();
delete *i;
pending_controllables.erase(i);
}
i = tmp;
}
controllables.push_back (mc);
}
void
GenericMidiControlProtocol::stop_learning (Controllable* c)
{
Glib::Threads::Mutex::Lock lm (pending_lock);
Glib::Threads::Mutex::Lock lm2 (controllables_lock);
MIDIControllable* dptr = 0;
/* learning timed out, and we've been told to consider this attempt to learn to be cancelled. find the
relevant MIDIControllable and remove it from the pending list.
*/
for (MIDIPendingControllables::iterator i = pending_controllables.begin(); i != pending_controllables.end(); ++i) {
if (((*i)->first)->get_controllable() == c) {
(*i)->first->stop_learning ();
dptr = (*i)->first;
(*i)->second.disconnect();
delete *i;
pending_controllables.erase (i);
break;
}
}
delete dptr;
}
void
GenericMidiControlProtocol::delete_binding (PBD::Controllable* control)
{
if (control != 0) {
Glib::Threads::Mutex::Lock lm2 (controllables_lock);
for (MIDIControllables::iterator iter = controllables.begin(); iter != controllables.end();) {
MIDIControllable* existingBinding = (*iter);
if (control == (existingBinding->get_controllable())) {
delete existingBinding;
iter = controllables.erase (iter);
} else {
++iter;
}
}
}
}
void
GenericMidiControlProtocol::create_binding (PBD::Controllable* control, int pos, int control_number)
{
if (control != NULL) {
Glib::Threads::Mutex::Lock lm2 (controllables_lock);
MIDI::channel_t channel = (pos & 0xf);
MIDI::byte value = control_number;
// Create a MIDIControllable
MIDIControllable* mc = new MIDIControllable (this, *_input_port->parser(), *control, false);
// Remove any old binding for this midi channel/type/value pair
// Note: can't use delete_binding() here because we don't know the specific controllable we want to remove, only the midi information
for (MIDIControllables::iterator iter = controllables.begin(); iter != controllables.end();) {
MIDIControllable* existingBinding = (*iter);
if ((existingBinding->get_control_channel() & 0xf ) == channel &&
existingBinding->get_control_additional() == value &&
(existingBinding->get_control_type() & 0xf0 ) == MIDI::controller) {
delete existingBinding;
iter = controllables.erase (iter);
} else {
++iter;
}
}
// Update the MIDI Controllable based on the the pos param
// Here is where a table lookup for user mappings could go; for now we'll just wing it...
mc->bind_midi(channel, MIDI::controller, value);
controllables.push_back (mc);
}
}
XMLNode&
GenericMidiControlProtocol::get_state ()
{
XMLNode* node = new XMLNode ("Protocol");
char buf[32];
node->add_property (X_("name"), _name);
node->add_property (X_("feedback"), do_feedback ? "1" : "0");
snprintf (buf, sizeof (buf), "%" PRIu64, _feedback_interval);
node->add_property (X_("feedback_interval"), buf);
snprintf (buf, sizeof (buf), "%d", _threshold);
node->add_property (X_("threshold"), buf);
if (!_current_binding.empty()) {
node->add_property ("binding", _current_binding);
}
XMLNode* children = new XMLNode (X_("Controls"));
node->add_child_nocopy (*children);
Glib::Threads::Mutex::Lock lm2 (controllables_lock);
for (MIDIControllables::iterator i = controllables.begin(); i != controllables.end(); ++i) {
/* we don't care about bindings that come from a bindings map, because
they will all be reset/recreated when we load the relevant bindings
file.
*/
if ((*i)->get_controllable() && (*i)->learned()) {
children->add_child_nocopy ((*i)->get_state());
}
}
return *node;
}
int
GenericMidiControlProtocol::set_state (const XMLNode& node, int version)
{
XMLNodeList nlist;
XMLNodeConstIterator niter;
const XMLProperty* prop;
if ((prop = node.property ("feedback")) != 0) {
do_feedback = (bool) atoi (prop->value().c_str());
} else {
do_feedback = false;
}
if ((prop = node.property ("feedback_interval")) != 0) {
if (sscanf (prop->value().c_str(), "%" PRIu64, &_feedback_interval) != 1) {
_feedback_interval = 10000;
}
} else {
_feedback_interval = 10000;
}
if ((prop = node.property ("threshold")) != 0) {
if (sscanf (prop->value().c_str(), "%d", &_threshold) != 1) {
_threshold = 10;
}
} else {
_threshold = 10;
}
boost::shared_ptr<Controllable> c;
{
Glib::Threads::Mutex::Lock lm (pending_lock);
for (MIDIPendingControllables::iterator i = pending_controllables.begin(); i != pending_controllables.end(); ++i) {
delete *i;
}
pending_controllables.clear ();
}
/* Load up specific bindings from the
* <Controls><MidiControllable>...</MidiControllable><Controls> section
*/
{
Glib::Threads::Mutex::Lock lm2 (controllables_lock);
controllables.clear ();
nlist = node.children(); // "Controls"
if (!nlist.empty()) {
nlist = nlist.front()->children(); // "MIDIControllable" ...
if (!nlist.empty()) {
for (niter = nlist.begin(); niter != nlist.end(); ++niter) {
if ((prop = (*niter)->property ("id")) != 0) {
ID id = prop->value ();
Controllable* c = Controllable::by_id (id);
if (c) {
MIDIControllable* mc = new MIDIControllable (this, *_input_port->parser(), *c, false);
if (mc->set_state (**niter, version) == 0) {
controllables.push_back (mc);
}
} else {
warning << string_compose (
_("Generic MIDI control: controllable %1 not found in session (ignored)"),
id) << endmsg;
}
}
}
}
}
}
if ((prop = node.property ("binding")) != 0) {
for (list<MapInfo>::iterator x = map_info.begin(); x != map_info.end(); ++x) {
if (prop->value() == (*x).name) {
load_bindings ((*x).path);
break;
}
}
}
return 0;
}
int
GenericMidiControlProtocol::set_feedback (bool yn)
{
do_feedback = yn;
last_feedback_time = 0;
return 0;
}
bool
GenericMidiControlProtocol::get_feedback () const
{
return do_feedback;
}
int
GenericMidiControlProtocol::load_bindings (const string& xmlpath)
{
XMLTree state_tree;
if (!state_tree.read (xmlpath.c_str())) {
error << string_compose(_("Could not understand MIDI bindings file %1"), xmlpath) << endmsg;
return -1;
}
XMLNode* root = state_tree.root();
if (root->name() != X_("ArdourMIDIBindings")) {
error << string_compose (_("MIDI Bindings file %1 is not really a MIDI bindings file"), xmlpath) << endmsg;
return -1;
}
const XMLProperty* prop;
if ((prop = root->property ("version")) == 0) {
return -1;
} else {
int major;
int minor;
int micro;
sscanf (prop->value().c_str(), "%d.%d.%d", &major, &minor, &micro);
Stateful::loading_state_version = (major * 1000) + minor;
}
const XMLNodeList& children (root->children());
XMLNodeConstIterator citer;
XMLNodeConstIterator gciter;
MIDIControllable* mc;
drop_all ();
for (citer = children.begin(); citer != children.end(); ++citer) {
if ((*citer)->name() == "DeviceInfo") {
const XMLProperty* prop;
if ((prop = (*citer)->property ("bank-size")) != 0) {
_bank_size = atoi (prop->value());
_current_bank = 0;
}
if ((prop = (*citer)->property ("motorised")) != 0 || ((prop = (*citer)->property ("motorized")) != 0)) {
_motorised = string_is_affirmative (prop->value ());
} else {
_motorised = false;
}
if ((prop = (*citer)->property ("threshold")) != 0) {
_threshold = atoi (prop->value ());
} else {
_threshold = 10;
}
}
if ((*citer)->name() == "Binding") {
const XMLNode* child = *citer;
if (child->property ("uri")) {
/* controllable */
if ((mc = create_binding (*child)) != 0) {
Glib::Threads::Mutex::Lock lm2 (controllables_lock);
controllables.push_back (mc);
}
} else if (child->property ("function")) {
/* function */
MIDIFunction* mf;
if ((mf = create_function (*child)) != 0) {
functions.push_back (mf);
}
} else if (child->property ("action")) {
MIDIAction* ma;
if ((ma = create_action (*child)) != 0) {
actions.push_back (ma);
}
}
}
}
if ((prop = root->property ("name")) != 0) {
_current_binding = prop->value ();
}
reset_controllables ();
return 0;
}
MIDIControllable*
GenericMidiControlProtocol::create_binding (const XMLNode& node)
{
const XMLProperty* prop;
MIDI::byte detail;
MIDI::channel_t channel;
string uri;
MIDI::eventType ev;
int intval;
bool momentary;
if ((prop = node.property (X_("ctl"))) != 0) {
ev = MIDI::controller;
} else if ((prop = node.property (X_("note"))) != 0) {
ev = MIDI::on;
} else if ((prop = node.property (X_("pgm"))) != 0) {
ev = MIDI::program;
} else if ((prop = node.property (X_("pb"))) != 0) {
ev = MIDI::pitchbend;
} else {
return 0;
}
if (sscanf (prop->value().c_str(), "%d", &intval) != 1) {
return 0;
}
detail = (MIDI::byte) intval;
if ((prop = node.property (X_("channel"))) == 0) {
return 0;
}
if (sscanf (prop->value().c_str(), "%d", &intval) != 1) {
return 0;
}
channel = (MIDI::channel_t) intval;
/* adjust channel to zero-based counting */
if (channel > 0) {
channel -= 1;
}
if ((prop = node.property (X_("momentary"))) != 0) {
momentary = string_is_affirmative (prop->value());
} else {
momentary = false;
}
prop = node.property (X_("uri"));
uri = prop->value();
MIDIControllable* mc = new MIDIControllable (this, *_input_port->parser(), momentary);
if (mc->init (uri)) {
delete mc;
return 0;
}
mc->bind_midi (channel, ev, detail);
return mc;
}
void
GenericMidiControlProtocol::reset_controllables ()
{
Glib::Threads::Mutex::Lock lm2 (controllables_lock);
for (MIDIControllables::iterator iter = controllables.begin(); iter != controllables.end(); ) {
MIDIControllable* existingBinding = (*iter);
MIDIControllables::iterator next = iter;
++next;
if (!existingBinding->learned()) {
ControllableDescriptor& desc (existingBinding->descriptor());
if (desc.banked()) {
desc.set_bank_offset (_current_bank * _bank_size);
}
/* its entirely possible that the session doesn't have
* the specified controllable (e.g. it has too few
* tracks). if we find this to be the case, we just leave
* the binding around, unbound, and it will do "late
* binding" (or "lazy binding") if/when any data arrives.
*/
existingBinding->lookup_controllable ();
}
iter = next;
}
}
boost::shared_ptr<Controllable>
GenericMidiControlProtocol::lookup_controllable (const ControllableDescriptor& desc) const
{
return session->controllable_by_descriptor (desc);
}
MIDIFunction*
GenericMidiControlProtocol::create_function (const XMLNode& node)
{
const XMLProperty* prop;
int intval;
MIDI::byte detail = 0;
MIDI::channel_t channel = 0;
string uri;
MIDI::eventType ev;
MIDI::byte* data = 0;
uint32_t data_size = 0;
string argument;
if ((prop = node.property (X_("ctl"))) != 0) {
ev = MIDI::controller;
} else if ((prop = node.property (X_("note"))) != 0) {
ev = MIDI::on;
} else if ((prop = node.property (X_("pgm"))) != 0) {
ev = MIDI::program;
} else if ((prop = node.property (X_("sysex"))) != 0 || (prop = node.property (X_("msg"))) != 0) {
if (prop->name() == X_("sysex")) {
ev = MIDI::sysex;
} else {
ev = MIDI::any;
}
int val;
uint32_t cnt;
{
cnt = 0;
stringstream ss (prop->value());
ss << hex;
while (ss >> val) {
cnt++;
}
}
if (cnt == 0) {
return 0;
}
data = new MIDI::byte[cnt];
data_size = cnt;
{
stringstream ss (prop->value());
ss << hex;
cnt = 0;
while (ss >> val) {
data[cnt++] = (MIDI::byte) val;
}
}
} else {
warning << "Binding ignored - unknown type" << endmsg;
return 0;
}
if (data_size == 0) {
if (sscanf (prop->value().c_str(), "%d", &intval) != 1) {
return 0;
}
detail = (MIDI::byte) intval;
if ((prop = node.property (X_("channel"))) == 0) {
return 0;
}
if (sscanf (prop->value().c_str(), "%d", &intval) != 1) {
return 0;
}
channel = (MIDI::channel_t) intval;
/* adjust channel to zero-based counting */
if (channel > 0) {
channel -= 1;
}
}
if ((prop = node.property (X_("arg"))) != 0 || (prop = node.property (X_("argument"))) != 0 || (prop = node.property (X_("arguments"))) != 0) {
argument = prop->value ();
}
prop = node.property (X_("function"));
MIDIFunction* mf = new MIDIFunction (*_input_port->parser());
if (mf->setup (*this, prop->value(), argument, data, data_size)) {
delete mf;
return 0;
}
mf->bind_midi (channel, ev, detail);
return mf;
}
MIDIAction*
GenericMidiControlProtocol::create_action (const XMLNode& node)
{
const XMLProperty* prop;
int intval;
MIDI::byte detail = 0;
MIDI::channel_t channel = 0;
string uri;
MIDI::eventType ev;
MIDI::byte* data = 0;
uint32_t data_size = 0;
if ((prop = node.property (X_("ctl"))) != 0) {
ev = MIDI::controller;
} else if ((prop = node.property (X_("note"))) != 0) {
ev = MIDI::on;
} else if ((prop = node.property (X_("pgm"))) != 0) {
ev = MIDI::program;
} else if ((prop = node.property (X_("sysex"))) != 0 || (prop = node.property (X_("msg"))) != 0) {
if (prop->name() == X_("sysex")) {
ev = MIDI::sysex;
} else {
ev = MIDI::any;
}
int val;
uint32_t cnt;
{
cnt = 0;
stringstream ss (prop->value());
ss << hex;
while (ss >> val) {
cnt++;
}
}
if (cnt == 0) {
return 0;
}
data = new MIDI::byte[cnt];
data_size = cnt;
{
stringstream ss (prop->value());
ss << hex;
cnt = 0;
while (ss >> val) {
data[cnt++] = (MIDI::byte) val;
}
}
} else {
warning << "Binding ignored - unknown type" << endmsg;
return 0;
}
if (data_size == 0) {
if (sscanf (prop->value().c_str(), "%d", &intval) != 1) {
return 0;
}
detail = (MIDI::byte) intval;
if ((prop = node.property (X_("channel"))) == 0) {
return 0;
}
if (sscanf (prop->value().c_str(), "%d", &intval) != 1) {
return 0;
}
channel = (MIDI::channel_t) intval;
/* adjust channel to zero-based counting */
if (channel > 0) {
channel -= 1;
}
}
prop = node.property (X_("action"));
MIDIAction* ma = new MIDIAction (*_input_port->parser());
if (ma->init (*this, prop->value(), data, data_size)) {
delete ma;
return 0;
}
ma->bind_midi (channel, ev, detail);
return ma;
}
void
GenericMidiControlProtocol::set_current_bank (uint32_t b)
{
_current_bank = b;
reset_controllables ();
}
void
GenericMidiControlProtocol::next_bank ()
{
_current_bank++;
reset_controllables ();
}
void
GenericMidiControlProtocol::prev_bank()
{
if (_current_bank) {
_current_bank--;
reset_controllables ();
}
}
void
GenericMidiControlProtocol::set_motorised (bool m)
{
_motorised = m;
}
void
GenericMidiControlProtocol::set_threshold (int t)
{
_threshold = t;
}