/* * Copyright (C) 2006-2007 John Anderson * Copyright (C) 2008-2016 Paul Davis * Copyright (C) 2008 Doug McLain * Copyright (C) 2010-2012 Carl Hetherington * Copyright (C) 2015-2016 Len Ovens * Copyright (C) 2015-2016 Robin Gareus * Copyright (C) 2016-2018 Ben Loftis * * 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., * 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA. */ #include #include #include #include #include #include #include "pbd/debug.h" #include "midi++/port.h" #include "ardour/audioengine.h" #include "ardour/automation_control.h" #include "ardour/chan_count.h" #include "ardour/debug.h" #include "ardour/route.h" #include "ardour/meter.h" #include "ardour/panner.h" #include "ardour/panner_shell.h" #include "ardour/profile.h" #include "ardour/rc_configuration.h" #include "ardour/session.h" #include "ardour/types.h" #include "ardour/utils.h" #include #include "control_group.h" #include "surface_port.h" #include "surface.h" #include "strip.h" #include "mackie_control_protocol.h" #include "jog_wheel.h" #include "strip.h" #include "button.h" #include "led.h" #include "pot.h" #include "fader.h" #include "jog.h" #include "meter.h" #include "pbd/i18n.h" #ifdef PLATFORM_WINDOWS #define random() rand() #endif using namespace std; using namespace PBD; using ARDOUR::Stripable; using ARDOUR::Panner; using ARDOUR::Profile; using ARDOUR::AutomationControl; using ARDOUR::ChanCount; using namespace ArdourSurface; using namespace ArdourSurface::MACKIE_NAMESPACE; #define ui_context() MackieControlProtocol::instance() /* a UICallback-derived object that specifies the event loop for signal handling */ // The MCU sysex header.4th byte Will be overwritten // when we get an incoming sysex that identifies // the device type static MidiByteArray mackie_sysex_hdr (5, MIDI::sysex, 0x0, 0x0, 0x66, 0x14); // The MCU extender sysex header.4th byte Will be overwritten // when we get an incoming sysex that identifies // the device type static MidiByteArray mackie_sysex_hdr_xt (5, MIDI::sysex, 0x0, 0x0, 0x66, 0x15); //QCON // The MCU sysex header for QCon Control surface static MidiByteArray mackie_sysex_hdr_qcon (5, MIDI::sysex, 0x0, 0x0, 0x66, 0x14); // The MCU sysex header for QCon Control - extender // The extender differs from Mackie by 4th bit - it's same like for main control surface (for display) static MidiByteArray mackie_sysex_hdr_xt_qcon (5, MIDI::sysex, 0x0, 0x0, 0x66, 0x14); static MidiByteArray empty_midi_byte_array; Surface::Surface (MackieControlProtocol& mcp, const std::string& device_name, uint32_t number, surface_type_t stype) : _mcp (mcp) , _stype (stype) , _number (number) , _name (device_name) , _active (false) , _connected (false) , _jog_wheel (0) , _master_fader (0) , _last_master_gain_written (-0.0f) , _has_master_display (false) , _has_master_meter (false) , connection_state (0) , is_qcon (false) , input_source (0) { DEBUG_TRACE (DEBUG::MackieControl, "Surface::Surface init\n"); try { _port = new SurfacePort (*this); } catch (...) { throw failed_constructor (); } //Store Qcon flag is_qcon = mcp.device_info().is_qcon(); /* only the first Surface object has global controls */ /* lets use master_position instead */ uint32_t mp = _mcp.device_info().master_position(); if (_number == mp) { DEBUG_TRACE (DEBUG::MackieControl, "Surface matches MasterPosition. Might have global controls.\n"); if ( is_qcon ) { _has_master_display = (mcp.device_info().has_master_fader() && mcp.device_info().has_qcon_second_lcd()); _has_master_meter = mcp.device_info().has_qcon_master_meters(); } if (_mcp.device_info().has_global_controls()) { init_controls (); DEBUG_TRACE (DEBUG::MackieControl, "init_controls done\n"); } if (_mcp.device_info().has_master_fader()) { setup_master (); DEBUG_TRACE (DEBUG::MackieControl, "setup_master done\n"); } } uint32_t n = _mcp.device_info().strip_cnt(); if (n) { init_strips (n); DEBUG_TRACE (DEBUG::MackieControl, "init_strips done\n"); } if (_mcp.device_info().uses_ipmidi()) { /* ipMIDI port already exists, we can just assume that we're * connected. * * If the user still hasn't connected the ipMIDI surface and/or * turned it on, then they have to press "Discover Mackie * Devices" in the GUI at the right time. */ connection_state |= (InputConnected|OutputConnected); connected (); } connect_to_signals (); DEBUG_TRACE (DEBUG::MackieControl, "Surface::Surface done\n"); } Surface::~Surface () { DEBUG_TRACE (DEBUG::MackieControl, "Surface::~Surface init\n"); if (input_source) { g_source_destroy (input_source); input_source = 0; } // delete groups (strips) for (Groups::iterator it = groups.begin(); it != groups.end(); ++it) { delete it->second; } // delete controls (global buttons, master fader etc) for (Controls::iterator it = controls.begin(); it != controls.end(); ++it) { delete *it; } delete _jog_wheel; delete _port; // the ports take time to release and we may be rebuilding right away // in the case of changing devices. g_usleep (10000); DEBUG_TRACE (DEBUG::MackieControl, "Surface::~Surface done\n"); } bool Surface::connection_handler (std::weak_ptr, std::string name1, std::weak_ptr, std::string name2, bool yn) { if (!_port) { return false; } string ni = ARDOUR::AudioEngine::instance()->make_port_name_non_relative (_port->input_name()); string no = ARDOUR::AudioEngine::instance()->make_port_name_non_relative (_port->output_name()); if (ni == name1 || ni == name2) { if (yn) { connection_state |= InputConnected; } else { connection_state &= ~InputConnected; } } else if (no == name1 || no == name2) { if (yn) { connection_state |= OutputConnected; } else { connection_state &= ~OutputConnected; } } else { /* not our ports */ return false; } if ((connection_state & (InputConnected|OutputConnected)) == (InputConnected|OutputConnected)) { /* this will send a device query message, which should result in a response that will kick off device type discovery and activation of the surface(s). The intended order of events is: - each surface sends a device query message - devices respond with either MCP or LCP response (sysex in both cases) - sysex message causes Surface::turn_it_on() which tells the MCP object that the surface is ready, and sets up strip displays and binds faders and buttons for that surface In the case of LCP, where this is a handshake process that could fail, the response process to the initial sysex after a device query will mark the surface inactive, which won't shut anything down but will stop any writes to the device. Note: there are no known cases of the handshake process failing. We actually can't initiate this in this callback, so we have to queue it with the MCP event loop. */ /* XXX this is a horrible hack. Without a short sleep here, something prevents the device wakeup messages from being sent and/or the responses from being received. */ g_usleep (100000); connected (); } else { DEBUG_TRACE (DEBUG::MackieControl, string_compose ("Surface %1 disconnected (input or output or both)\n", _name)); _active = false; } return true; /* connection status changed */ } XMLNode& Surface::get_state() const { XMLNode* node = new XMLNode (X_("Surface")); node->set_property (X_("name"), _name); node->add_child_nocopy (_port->get_state()); return *node; } int Surface::set_state (const XMLNode& node, int version) { /* Look for a node named after the device we're part of */ XMLNodeList const& children = node.children(); XMLNode* mynode = 0; for (XMLNodeList::const_iterator c = children.begin(); c != children.end(); ++c) { std::string name; if ((*c)->get_property (X_("name"), name) && name == _name) { mynode = *c; break; } } if (!mynode) { return 0; } XMLNode* portnode = mynode->child (X_("Port")); if (portnode) { if (_port->set_state (*portnode, version)) { return -1; } } return 0; } const MidiByteArray& Surface::sysex_hdr() const { switch (_stype) { case mcu: if (_mcp.device_info().is_qcon()) { return mackie_sysex_hdr_qcon; } else { return mackie_sysex_hdr; } case ext: if(_mcp.device_info().is_qcon()) { return mackie_sysex_hdr_xt_qcon; } else { return mackie_sysex_hdr_xt; } } cout << "SurfacePort::sysex_hdr _port_type not known" << endl; return mackie_sysex_hdr; } static GlobalControlDefinition mackie_global_controls[] = { { "external", Pot::External, Pot::factory, "none" }, { "fader_touch", Led::FaderTouch, Led::factory, "master" }, { "timecode", Led::Timecode, Led::factory, "none" }, { "beats", Led::Beats, Led::factory, "none" }, { "solo", Led::RudeSolo, Led::factory, "none" }, { "relay_click", Led::RelayClick, Led::factory, "none" }, { "", 0, Led::factory, "" } }; void Surface::init_controls() { Group* group; DEBUG_TRACE (DEBUG::MackieControl, "Surface::init_controls: creating groups\n"); groups["assignment"] = new Group ("assignment"); groups["automation"] = new Group ("automation"); groups["bank"] = new Group ("bank"); groups["cursor"] = new Group ("cursor"); groups["display"] = new Group ("display"); groups["function select"] = new Group ("function select"); groups["global view"] = new Group ("global view"); groups["master"] = new Group ("master"); groups["modifiers"] = new Group ("modifiers"); groups["none"] = new Group ("none"); groups["transport"] = new Group ("transport"); groups["user"] = new Group ("user"); groups["utilities"] = new Group ("utilities"); DEBUG_TRACE (DEBUG::MackieControl, "Surface::init_controls: creating jog wheel\n"); if (_mcp.device_info().has_jog_wheel()) { _jog_wheel = new MACKIE_NAMESPACE::JogWheel (_mcp); } DEBUG_TRACE (DEBUG::MackieControl, "Surface::init_controls: creating global controls\n"); for (uint32_t n = 0; mackie_global_controls[n].name[0]; ++n) { group = groups[mackie_global_controls[n].group_name]; Control* control = mackie_global_controls[n].factory (*this, mackie_global_controls[n].id, mackie_global_controls[n].name, *group); controls_by_device_independent_id[mackie_global_controls[n].id] = control; } /* add global buttons */ DEBUG_TRACE (DEBUG::MackieControl, "Surface::init_controls: adding global buttons\n"); const map& global_buttons (_mcp.device_info().global_buttons()); for (map::const_iterator b = global_buttons.begin(); b != global_buttons.end(); ++b){ group = groups[b->second.group]; controls_by_device_independent_id[b->first] = Button::factory (*this, b->first, b->second.id, b->second.label, *group); } } void Surface::init_strips (uint32_t n) { const map& strip_buttons (_mcp.device_info().strip_buttons()); for (uint32_t i = 0; i < n; ++i) { char name[32]; snprintf (name, sizeof (name), "strip_%d", (8* _number) + i); Strip* strip = new Strip (*this, name, i, strip_buttons); groups[name] = strip; strips.push_back (strip); } } void Surface::master_monitor_may_have_changed () { if (_number == _mcp.device_info().master_position()) { setup_master (); } } bool Surface::master_stripable_is_master_monitor () { if (_master_stripable == _mcp.get_session().monitor_out()) { return true; } return false; } void Surface::toggle_master_monitor () { if(master_stripable_is_master_monitor()) { _master_stripable = _mcp.get_session().master_out(); } else if (_mcp.get_session().monitor_out() != 0) { _master_stripable = _mcp.get_session().monitor_out(); } else { return; } _master_fader->set_control (_master_stripable->gain_control()); _master_stripable->gain_control()->Changed.connect (master_connection, MISSING_INVALIDATOR, std::bind (&Surface::master_gain_changed, this), ui_context()); _last_master_gain_written = FLT_MAX; master_gain_changed (); } void Surface::setup_master () { if ((_master_stripable = _mcp.get_session().monitor_out()) == 0) { _master_stripable = _mcp.get_session().master_out(); } if (!_master_stripable) { if (_master_fader) { _master_fader->set_control (std::shared_ptr()); } master_connection.disconnect (); return; } if (!_master_fader) { Groups::iterator group_it; Group* master_group; group_it = groups.find("master"); DeviceInfo device_info = _mcp.device_info(); if (group_it == groups.end()) { groups["master"] = master_group = new Group ("master"); } else { master_group = group_it->second; } _master_fader = dynamic_cast (Fader::factory (*this, device_info.strip_cnt(), "master", *master_group)); GlobalButtonInfo master_button = device_info.get_global_button(Button::MasterFaderTouch); DEBUG_RESULT_CAST (Button*, bb, dynamic_cast, (Button::factory ( *this, Button::MasterFaderTouch, master_button.id, master_button.label, *(group_it->second) ))); DEBUG_TRACE (DEBUG::MackieControl, string_compose ("surface %1 Master Fader new button BID %2 id %3\n", number(), Button::MasterFaderTouch, bb->id())); } else { master_connection.disconnect (); } _master_fader->set_control (_master_stripable->gain_control()); _master_stripable->gain_control()->Changed.connect (master_connection, MISSING_INVALIDATOR, std::bind (&Surface::master_gain_changed, this), ui_context()); _last_master_gain_written = FLT_MAX; /* some essentially impossible value */ master_gain_changed (); if (_has_master_display) { _master_stripable->PropertyChanged.connect (master_connection, MISSING_INVALIDATOR, std::bind (&Surface::master_property_changed, this, _1), ui_context()); show_master_name(); } } void Surface::master_gain_changed () { if (!_master_fader) { return; } std::shared_ptr ac = _master_fader->control(); if (!ac) { return; } float normalized_position = ac->internal_to_interface (ac->get_value()); if (normalized_position == _last_master_gain_written) { return; } DEBUG_TRACE (DEBUG::MackieControl, string_compose("Surface::master_gain_changed: val %1, pos %2\n", ac->get_value(), normalized_position)); write (_master_fader->set_position (normalized_position)); _last_master_gain_written = normalized_position; } void Surface::master_property_changed (const PropertyChange& what_changed) { if (what_changed.contains (ARDOUR::Properties::name)) { DEBUG_TRACE (DEBUG::MackieControl, "master_property_changed\n"); string fullname = string(); if (!_master_stripable) { fullname = string(); } else { fullname = _master_stripable->name(); } if (fullname.length() <= 6) { pending_display[0] = fullname; } else { pending_display[0] = PBD::short_version (fullname, 6); } } } void Surface::master_meter_changed () { if (!_has_master_meter) { return; } if (!_master_stripable) { return; } ChanCount count = _master_stripable->peak_meter()->output_streams(); for (unsigned i = 0; i < 2 && i < count.n_audio(); ++i) { int segment; float dB = _master_stripable->peak_meter()->meter_level (i, ARDOUR::MeterPeak); std::pair result = Meter::calculate_meter_over_and_deflection(dB); MidiByteArray msg; /* we can use up to 13 segments */ segment = lrintf ((result.second/115.0) * 13.0); write (MidiByteArray (2, 0xd1, (i<<4) | segment)); } } void Surface::show_master_name () { string fullname = string(); if (!_master_stripable) { fullname = string(); } else { fullname = _master_stripable->name(); } DEBUG_TRACE (DEBUG::MackieControl, string_compose ("show_master_name: name %1\n", fullname)); if (fullname.length() <= 6) { pending_display[0] = fullname; } else { pending_display[0] = PBD::short_version (fullname, 6); } } MidiByteArray Surface::master_display (uint32_t line_number, const std::string& line) { /* The second lcd on the Qcon Pro X master unit uses a 6 character label instead of 7. * That allows a 9th label for the master fader and since there is a space at the end * use all 6 characters for text. * * Format: _6Char#1_6Char#2_6Char#3_6Char#4_6Char#5_6Char#6_6Char#7_6Char#8_6Char#9_ * * The _ in the format is a space that is inserted as label display seperators * * The second LCD is an extention to the MCP with a different sys ex header. */ MidiByteArray retval; DEBUG_TRACE (DEBUG::MackieControl, string_compose ("master display: line %1 = %2\n", line_number, line)); retval << MidiByteArray (5, MIDI::sysex, 0x0, 0x0, 0x67, 0x15); // code for display retval << 0x13; // offset (0 to 0x37 first line, 0x38 to 0x6f for second line) retval << (49 + (line_number * 0x38)); // 9th position // ascii data to display. `line` is UTF-8 string ascii = Glib::convert_with_fallback (line, "UTF-8", "ISO-8859-1", "_"); string::size_type len = ascii.length(); if (len > 6) { ascii = ascii.substr (0, 6); len = 5; } retval << ascii; // pad with " " out to N chars for (unsigned i = len; i < 6; ++i) { retval << ' '; } // Space as the last character retval << ' '; // sysex trailer retval << MIDI::eox; return retval; } MidiByteArray Surface::blank_master_display (uint32_t line_number) { if (line_number == 0) { return MidiByteArray (15, MIDI::sysex, 0x0, 0x0, 0x67, 0x15, 0x13, 0x31 , 0x20, 0x20, 0x20, 0x20, 0x20, 0x20, 0x20, MIDI::eox); } else { return MidiByteArray (15, MIDI::sysex, 0x0, 0x0, 0x67, 0x15, 0x13, 0x69 , 0x20, 0x20, 0x20, 0x20, 0x20, 0x20, 0x20, MIDI::eox); } } float Surface::scaled_delta (float delta, float current_speed) { /* XXX needs work before use */ const float sign = delta < 0.0 ? -1.0 : 1.0; return ((sign * std::pow (delta + 1.0, 2.0)) + current_speed) / 100.0; } void Surface::display_bank_start (uint32_t current_bank) { if (current_bank == 0) { // send Ar. to 2-char display on the master show_two_char_display ("Ar", ".."); } else { // write the current first remote_id to the 2-char display show_two_char_display (current_bank); } } void Surface::blank_jog_ring () { Control* control = controls_by_device_independent_id[Jog::ID]; if (control) { Pot* pot = dynamic_cast (control); if (pot) { _port->write (pot->set (0.0, false, Pot::spread)); } } } float Surface::scrub_scaling_factor () const { return 100.0; } void Surface::connect_to_signals () { if (!_connected) { DEBUG_TRACE (DEBUG::MackieControl, string_compose ("Surface %1 connecting to signals on port %2\n", number(), _port->input_port().name())); MIDI::Parser* p = _port->input_port().parser(); /* Incoming sysex */ p->sysex.connect_same_thread (*this, std::bind (&Surface::handle_midi_sysex, this, _1, _2, _3)); /* V-Pot messages are Controller */ p->controller.connect_same_thread (*this, std::bind (&Surface::handle_midi_controller_message, this, _1, _2)); /* Button messages are NoteOn */ p->note_on.connect_same_thread (*this, std::bind (&Surface::handle_midi_note_on_message, this, _1, _2)); /* Button messages are NoteOn but libmidi++ sends note-on w/velocity = 0 as note-off so catch them too */ p->note_off.connect_same_thread (*this, std::bind (&Surface::handle_midi_note_on_message, this, _1, _2)); /* Fader messages are Pitchbend */ uint32_t i; for (i = 0; i < _mcp.device_info().strip_cnt(); i++) { p->channel_pitchbend[i].connect_same_thread (*this, std::bind (&Surface::handle_midi_pitchbend_message, this, _1, _2, i)); } // Master fader p->channel_pitchbend[_mcp.device_info().strip_cnt()].connect_same_thread (*this, std::bind (&Surface::handle_midi_pitchbend_message, this, _1, _2, _mcp.device_info().strip_cnt())); _connected = true; } } void Surface::handle_midi_pitchbend_message (MIDI::Parser&, MIDI::pitchbend_t pb, uint32_t fader_id) { /* Pitchbend messages are fader position messages. Nothing in the data we get * from the MIDI::Parser conveys the fader ID, which was given by the * channel ID in the status byte. * * Instead, we have used bind() to supply the fader-within-strip ID * when we connected to the per-channel pitchbend events. */ DEBUG_TRACE (DEBUG::MackieControl, string_compose ("Surface::handle_midi_pitchbend_message on port %3, fader = %1 value = %2 (%4)\n", fader_id, pb, _number, pb/16383.0)); if (_mcp.device_info().no_handshake()) { turn_it_on (); } Fader* fader = faders[fader_id]; if (fader) { Strip* strip = dynamic_cast (&fader->group()); float pos = pb / 16383.0; if (strip) { strip->handle_fader (*fader, pos); } else { DEBUG_TRACE (DEBUG::MackieControl, "Handling master fader\n"); /* master fader */ fader->set_value (pos); // alter master gain write (fader->set_position (pos)); // write back value (required for servo) } } else { DEBUG_TRACE (DEBUG::MackieControl, "fader not found\n"); } } void Surface::handle_midi_note_on_message (MIDI::Parser &, MIDI::EventTwoBytes* ev) { DEBUG_TRACE (DEBUG::MackieControl, string_compose ("Surface::handle_midi_note_on_message %1 = %2\n", (int) ev->note_number, (int) ev->velocity)); if (_mcp.device_info().no_handshake()) { turn_it_on (); } if (_mcp.device_info().device_type() == DeviceInfo::HUI && ev->note_number == 0 && ev->velocity == 127) { turn_it_on (); } /* fader touch sense is given by "buttons" 0xe..0xe7 and 0xe8 for the * master. */ if (ev->note_number >= 0xE0 && ev->note_number <= 0xE8) { Fader* fader = faders[ev->note_number]; DEBUG_TRACE (DEBUG::MackieControl, string_compose ("Surface: fader touch message, fader = %1\n", fader)); if (fader) { Strip* strip = dynamic_cast (&fader->group()); if (ev->velocity > 64) { strip->handle_fader_touch (*fader, true); } else { strip->handle_fader_touch (*fader, false); } } return; } Button* button = buttons[ev->note_number]; if (button) { if (ev->velocity > 64) { button->pressed (); } Strip* strip = dynamic_cast (&button->group()); if (strip) { DEBUG_TRACE (DEBUG::MackieControl, string_compose ("strip %1 button %2 pressed ? %3\n", strip->index(), button->name(), (ev->velocity > 64))); strip->handle_button (*button, ev->velocity > 64 ? press : release); } else { /* global button */ DEBUG_TRACE (DEBUG::MackieControl, string_compose ("global button %1\n", button->id())); _mcp.handle_button_event (*this, *button, ev->velocity > 64 ? press : release); } if (ev->velocity <= 64) { button->released (); } } else { DEBUG_TRACE (DEBUG::MackieControl, string_compose ("no button found for %1\n", (int) ev->note_number)); } /* button release should reset timer AFTER handler(s) have run */ } void Surface::handle_midi_controller_message (MIDI::Parser &, MIDI::EventTwoBytes* ev) { DEBUG_TRACE (DEBUG::MackieControl, string_compose ("SurfacePort::handle_midi_controller %1 = %2\n", (int) ev->controller_number, (int) ev->value)); if (_mcp.device_info().no_handshake()) { turn_it_on (); } Pot* pot = pots[ev->controller_number]; // bit 6 gives the sign float sign = (ev->value & 0x40) == 0 ? 1.0 : -1.0; // bits 0..5 give the velocity. we interpret this as "ticks // moved before this message was sent" float ticks = (ev->value & 0x3f); if (ticks == 0) { /* euphonix and perhaps other devices send zero when they mean 1, we think. */ ticks = 1; } float delta = 0; if (mcp().main_modifier_state() == MackieControlProtocol::MODIFIER_SHIFT) { delta = sign * (ticks / (float) 0xff); } else { delta = sign * (ticks / (float) 0x3f); } if (!pot) { if (ev->controller_number == Jog::ID && _jog_wheel) { DEBUG_TRACE (DEBUG::MackieControl, string_compose ("Jog wheel moved %1\n", ticks)); _jog_wheel->jog_event (delta); return; } // add external (pedal?) control here return; } Strip* strip = dynamic_cast (&pot->group()); if (strip) { strip->handle_pot (*pot, delta); } } void Surface::handle_midi_sysex (MIDI::Parser &, MIDI::byte * raw_bytes, size_t count) { MidiByteArray bytes (count, raw_bytes); if (_mcp.device_info().no_handshake()) { turn_it_on (); } /* always save the device type ID so that our outgoing sysex messages * are correct */ if (_stype == mcu) { if (_mcp.device_info().is_qcon()) { mackie_sysex_hdr_qcon[4] = bytes[4]; } else { mackie_sysex_hdr[4] = bytes[4]; } } else { if (_mcp.device_info().is_qcon()) { mackie_sysex_hdr_xt_qcon[4] = bytes[4]; } else { mackie_sysex_hdr_xt[4] = bytes[4]; } } switch (bytes[5]) { case 0x01: if (!_active) { DEBUG_TRACE (DEBUG::MackieControl, string_compose ("handle_midi_sysex: %1\n", bytes)); } /* MCP: Device Ready LCP: Connection Challenge */ if (bytes[4] == 0x10 || bytes[4] == 0x11) { DEBUG_TRACE (DEBUG::MackieControl, "Logic Control Device connection challenge\n"); write_sysex (host_connection_query (bytes)); } else { if (!_active) { DEBUG_TRACE (DEBUG::MackieControl, string_compose ("Mackie Control Device ready, current status = %1\n", _active)); } turn_it_on (); } break; case 0x06: if (!_active) { DEBUG_TRACE (DEBUG::MackieControl, string_compose ("handle_midi_sysex: %1\n", bytes)); } /* Behringer X-Touch Compact: Device Ready */ DEBUG_TRACE (DEBUG::MackieControl, string_compose ("Behringer X-Touch Compact ready, current status = %1\n", _active)); turn_it_on (); break; case 0x03: /* LCP Connection Confirmation */ DEBUG_TRACE (DEBUG::MackieControl, string_compose ("handle_midi_sysex: %1\n", bytes)); DEBUG_TRACE (DEBUG::MackieControl, "Logic Control Device confirms connection, ardour replies\n"); if (bytes[4] == 0x10 || bytes[4] == 0x11) { write_sysex (host_connection_confirmation (bytes)); turn_it_on (); } break; case 0x04: /* LCP: Confirmation Denied */ DEBUG_TRACE (DEBUG::MackieControl, string_compose ("handle_midi_sysex: %1\n", bytes)); DEBUG_TRACE (DEBUG::MackieControl, "Logic Control Device denies connection\n"); _active = false; break; default: DEBUG_TRACE (DEBUG::MackieControl, string_compose ("handle_midi_sysex: %1\n", bytes)); DEBUG_TRACE (DEBUG::MackieControl, string_compose ("unknown device ID byte %1", (int) bytes[5])); error << "MCP: unknown sysex: " << bytes << endmsg; } } static MidiByteArray calculate_challenge_response (MidiByteArray::iterator begin, MidiByteArray::iterator end) { MidiByteArray l; back_insert_iterator back (l); copy (begin, end, back); MidiByteArray retval; // this is how to calculate the response to the challenge. // from the Logic docs. retval << (0x7f & (l[0] + (l[1] ^ 0xa) - l[3])); retval << (0x7f & ( (l[2] >> l[3]) ^ (l[0] + l[3]))); retval << (0x7f & ((l[3] - (l[2] << 2)) ^ (l[0] | l[1]))); retval << (0x7f & (l[1] - l[2] + (0xf0 ^ (l[3] << 4)))); return retval; } MidiByteArray Surface::host_connection_query (MidiByteArray & bytes) { MidiByteArray response; if (bytes[4] != 0x10 && bytes[4] != 0x11) { /* not a Logic Control device - no response required */ return response; } // handle host connection query DEBUG_TRACE (DEBUG::MackieControl, string_compose ("host connection query: %1\n", bytes)); if (bytes.size() != 18) { cerr << "expecting 18 bytes, read " << bytes << " from " << _port->input_port().name() << endl; return response; } // build and send host connection reply response << 0x02; copy (bytes.begin() + 6, bytes.begin() + 6 + 7, back_inserter (response)); response << calculate_challenge_response (bytes.begin() + 6 + 7, bytes.begin() + 6 + 7 + 4); return response; } MidiByteArray Surface::host_connection_confirmation (const MidiByteArray & bytes) { DEBUG_TRACE (DEBUG::MackieControl, string_compose ("host_connection_confirmation: %1\n", bytes)); // decode host connection confirmation if (bytes.size() != 14) { ostringstream os; os << "expecting 14 bytes, read " << bytes << " from " << _port->input_port().name(); throw MackieControlException (os.str()); } // send version request return MidiByteArray (2, 0x13, 0x00); } void Surface::turn_it_on () { if (_active) { return; } _active = true; _mcp.device_ready (); for (Strips::iterator s = strips.begin(); s != strips.end(); ++s) { (*s)->notify_all (); } update_view_mode_display (false); // if (_mcp.device_info ().has_global_controls ()) { // _mcp.update_global_button (Button::Read, _mcp.metering_active ()); // } } void Surface::write_sysex (const MidiByteArray & mba) { if (mba.empty()) { return; } MidiByteArray buf; buf << sysex_hdr() << mba << MIDI::eox; _port->write (buf); } void Surface::write_sysex (MIDI::byte msg) { MidiByteArray buf; buf << sysex_hdr() << msg << MIDI::eox; _port->write (buf); } uint32_t Surface::n_strips (bool with_locked_strips) const { if (with_locked_strips) { return strips.size(); } uint32_t n = 0; for (Strips::const_iterator it = strips.begin(); it != strips.end(); ++it) { if (!(*it)->locked()) { ++n; } } return n; } Strip* Surface::nth_strip (uint32_t n) const { if (n > n_strips()) { return 0; } return strips[n]; } void Surface::zero_all () { if (_mcp.device_info().has_timecode_display ()) { display_timecode (string (10, '0'), string (10, ' ')); } if (_mcp.device_info().has_two_character_display()) { show_two_char_display (string (2, '0'), string (2, ' ')); } if (_mcp.device_info().has_master_fader () && _master_fader) { _port->write (_master_fader->zero ()); if (_has_master_display) { DEBUG_TRACE (DEBUG::MackieControl, "Surface::zero_all: Clearing Master display\n"); _port->write (blank_master_display(0)); _port->write (blank_master_display(1)); pending_display[0] = string(); pending_display[1] = string(); current_display[0] = string(); current_display[1] = string(); } if (_has_master_meter) { _port->write (MidiByteArray (2, 0xd1, 0x00)); _port->write (MidiByteArray (2, 0xd1, 0x10)); } } // zero all strips for (Strips::iterator it = strips.begin(); it != strips.end(); ++it) { (*it)->zero(); } zero_controls (); } void Surface::zero_controls () { if (!_mcp.device_info().has_global_controls()) { return; } // turn off global buttons and leds for (Controls::iterator it = controls.begin(); it != controls.end(); ++it) { Control & control = **it; if (!control.group().is_strip()) { _port->write (control.zero()); } } // and the led ring for the master strip blank_jog_ring (); _last_master_gain_written = 0.0f; } void Surface::periodic (PBD::microseconds_t now_usecs) { master_gain_changed(); master_meter_changed(); for (Strips::iterator s = strips.begin(); s != strips.end(); ++s) { (*s)->periodic (now_usecs); } } void Surface::redisplay (PBD::microseconds_t now, bool force) { if (_has_master_display) { if (force || (current_display[0] != pending_display[0])) { DEBUG_TRACE (DEBUG::MackieControl, "Surface::redisplay: Updating master display line 0\n"); write (master_display (0, pending_display[0])); current_display[0] = pending_display[0]; } if (force || (current_display[1] != pending_display[1])) { DEBUG_TRACE (DEBUG::MackieControl, "Surface::redisplay: Updating master display line 1\n"); write (master_display (1, pending_display[1])); current_display[1] = pending_display[1]; } } for (Strips::iterator s = strips.begin(); s != strips.end(); ++s) { (*s)->redisplay (now, force); } } void Surface::write (const MidiByteArray& data) { if (_active) { _port->write (data); } else { DEBUG_TRACE (DEBUG::MackieControl, "surface not active, write ignored\n"); } } void Surface::update_strip_selection () { Strips::iterator s = strips.begin(); for ( ; s != strips.end(); ++s) { (*s)->update_selection_state(); } } void Surface::map_stripables (const vector >& stripables) { vector >::const_iterator r; Strips::iterator s = strips.begin(); DEBUG_TRACE (DEBUG::MackieControl, string_compose ("Mapping %1 stripables to %2 strips\n", stripables.size(), strips.size())); bool xtouch = _mcp.device_info().is_xtouch(); XTouchColors colors[] { Off, Off, Off, Off, Off, Off, Off, Off }; uint8_t i = 0; for (r = stripables.begin(); r != stripables.end() && s != strips.end(); ++s) { /* don't try to assign stripables to a locked strip. it won't use it anyway, but if we do, then we get out of sync with the proposed mapping. */ if (!(*s)->locked()) { if(xtouch){ colors[i] = static_cast (convert_color_to_xtouch_value((*r)->presentation_info().color())); ++i; } (*s)->set_stripable (*r); ++r; } } for (; s != strips.end(); ++s) { DEBUG_TRACE (DEBUG::MackieControl, string_compose ("strip %1 being set to null stripable\n", (*s)->index())); (*s)->set_stripable (std::shared_ptr()); } if(xtouch){ _port->write (display_colors_on_xtouch(colors)); //write colors to strips for xtouch } } static char translate_seven_segment (char achar) { achar = toupper (achar); if (achar >= 0x40 && achar <= 0x5f) { return achar - 0x40; } else if (achar >= 0x20 && achar <= 0x3f) { return achar; } else { return 0x20; } } void Surface::show_two_char_display (const std::string & msg, const std::string & dots) { if (_stype != mcu || !_mcp.device_info().has_two_character_display() || msg.length() != 2 || dots.length() != 2) { return; } MidiByteArray right (3, 0xb0, 0x4b, 0x00); MidiByteArray left (3, 0xb0, 0x4a, 0x00); right[2] = translate_seven_segment (msg[0]) + (dots[0] == '.' ? 0x40 : 0x00); left[2] = translate_seven_segment (msg[1]) + (dots[1] == '.' ? 0x40 : 0x00); _port->write (right); _port->write (left); } void Surface::show_two_char_display (unsigned int value, const std::string & /*dots*/) { ostringstream os; os << setfill('0') << setw(2) << value % 100; show_two_char_display (os.str()); } void Surface::display_timecode (const std::string & timecode, const std::string & last_timecode) { //TODO: Fix for Qcon to correct timecode value if is over 1000 bars if (!_active || !_mcp.device_info().has_timecode_display()) { return; } // if there's no change, send nothing, not even sysex header if (timecode == last_timecode) return; // length sanity checking string local_timecode = timecode; // truncate to 10 characters if (local_timecode.length() > 10) { local_timecode = local_timecode.substr (0, 10); } // pad to 10 characters while (local_timecode.length() < 10) { local_timecode += " "; } // translate characters. // Only the characters that actually changed are sent. int position = 0x3f; int i; for (i = local_timecode.length () - 1; i >= 0; i--) { position++; if (local_timecode[i] == last_timecode[i]) { continue; } MidiByteArray retval (2, 0xb0, position); retval << translate_seven_segment (local_timecode[i]); _port->write (retval); } } void Surface::update_flip_mode_display () { for (Strips::iterator s = strips.begin(); s != strips.end(); ++s) { (*s)->flip_mode_changed (); } } void Surface::subview_mode_changed () { show_master_name(); for (Strips::iterator s = strips.begin(); s != strips.end(); ++s) { (*s)->subview_mode_changed (); } } void Surface::update_view_mode_display (bool with_helpful_text) { string text; int id = -1; if (!_active) { return; } switch (_mcp.view_mode()) { case MackieControlProtocol::Mixer: show_two_char_display ("Mx"); id = Button::View; text = _("Mixer View"); break; case MackieControlProtocol::AudioTracks: show_two_char_display ("AT"); id = Button::AudioTracks; text = _("Audio Tracks"); break; case MackieControlProtocol::MidiTracks: show_two_char_display ("MT"); id = Button::MidiTracks; text = _("MIDI Tracks"); break; case MackieControlProtocol::Busses: show_two_char_display ("BS"); id = Button::Busses; if (Profile->get_mixbus()) { text = _("Mixbusses"); } else { text = _("Busses"); } break; case MackieControlProtocol::Auxes: show_two_char_display ("Au"); id = Button::Aux; text = _("Auxes"); break; case MackieControlProtocol::Outputs: show_two_char_display ("Fb"); id = Button::Outputs; text = _("Foldback Busses"); break; case MackieControlProtocol::Selected: show_two_char_display ("SE"); id = Button::User; text = _("Selected Tracks"); break; case MackieControlProtocol::AudioInstr: show_two_char_display ("IS"); id = Button::AudioInstruments; text = _("VCAs"); break; case MackieControlProtocol::Inputs: show_two_char_display ("CU"); id = Button::Inputs; text = _("Cue Tracks"); break; default: break; } vector view_mode_buttons; view_mode_buttons.push_back (Button::View); view_mode_buttons.push_back (Button::Busses); view_mode_buttons.push_back (Button::Plugin); view_mode_buttons.push_back (Button::AudioTracks); view_mode_buttons.push_back (Button::MidiTracks); view_mode_buttons.push_back (Button::Aux); view_mode_buttons.push_back (Button::Outputs); view_mode_buttons.push_back (Button::User); view_mode_buttons.push_back (Button::Inputs); view_mode_buttons.push_back (Button::AudioInstruments); view_mode_buttons.push_back (Button::Outputs); if (id >= 0) { for (vector::iterator i = view_mode_buttons.begin(); i != view_mode_buttons.end(); ++i) { map::iterator x = controls_by_device_independent_id.find (*i); if (x != controls_by_device_independent_id.end()) { Button* button = dynamic_cast (x->second); if (button) { bool onoff; onoff = (*i) == id; _port->write (button->set_state (onoff)); } } } } if (with_helpful_text && !text.empty()) { display_message_for (text, 1000); } } void Surface::say_hello () { /* wakeup for Mackie Control */ MidiByteArray wakeup (7, MIDI::sysex, 0x00, 0x00, 0x66, 0x14, 0x00, MIDI::eox); _port->write (wakeup); wakeup[4] = 0x15; /* wakup Mackie XT */ _port->write (wakeup); wakeup[4] = 0x10; /* wakeup Logic Control */ _port->write (wakeup); wakeup[4] = 0x11; /* wakeup Logic Control XT */ _port->write (wakeup); } void Surface::next_jog_mode () { if (_jog_wheel) { if (_jog_wheel->mode() == JogWheel::scroll) { _jog_wheel->set_mode (JogWheel::shuttle); } else { _jog_wheel->set_mode (JogWheel::scroll); } } } void Surface::set_jog_mode (JogWheel::Mode m) { if (_jog_wheel) { _jog_wheel->set_mode (m); } } bool Surface::stripable_is_locked_to_strip (std::shared_ptr stripable) const { for (Strips::const_iterator s = strips.begin(); s != strips.end(); ++s) { if ((*s)->stripable() == stripable && (*s)->locked()) { return true; } } return false; } bool Surface::stripable_is_mapped (std::shared_ptr stripable) const { for (Strips::const_iterator s = strips.begin(); s != strips.end(); ++s) { if ((*s)->stripable() == stripable) { return true; } } return false; } void Surface::notify_metering_state_changed() { for (Strips::const_iterator s = strips.begin(); s != strips.end(); ++s) { (*s)->notify_metering_state_changed (); } } void Surface::reset () { if (_port) { /* reset msg for Mackie Control */ MidiByteArray msg; msg << sysex_hdr(); msg << 0x08; msg << 0x00; msg << MIDI::eox; _port->write (msg); } } void Surface::toggle_backlight () { if (_port) { int onoff = random() %2; MidiByteArray msg; msg << sysex_hdr (); msg << 0xa; msg << (onoff ? 0x1 : 0x0); msg << MIDI::eox; _port->write (msg); } } void Surface::recalibrate_faders () { if (_port) { MidiByteArray msg; msg << sysex_hdr (); msg << 0x09; msg << 0x00; msg << MIDI::eox; _port->write (msg); } } void Surface::set_touch_sensitivity (int sensitivity) { /* NOTE: assumed called from GUI code, hence sleep() */ /* sensitivity already clamped by caller */ if( !is_qcon ) { // Qcon doesn't support fader sensitivity if (_port) { MidiByteArray msg; msg << sysex_hdr (); msg << 0x0e; msg << 0xff; /* overwritten for each fader below */ msg << (sensitivity & 0x7f); msg << MIDI::eox; for (int fader = 0; fader < 9; ++fader) { msg[6] = fader; _port->write (msg); } } } } void Surface::hui_heartbeat () { if (!_port) { return; } MidiByteArray msg (3, MIDI::on, 0x0, 0x0); _port->write (msg); } void Surface::connected () { DEBUG_TRACE (DEBUG::MackieControl, string_compose ("Surface %1 now connected, trying to ping device...\n", _name)); say_hello (); if (_mcp.device_info().no_handshake()) { turn_it_on (); } } MidiByteArray Surface::display_line (string const& msg, int line_num) { MidiByteArray midi_msg; midi_msg << sysex_hdr (); midi_msg << 0x12; midi_msg << (line_num ? 0x38 : 0x0); /* offsets into char array * on device that * correspond to line * starts */ if (msg.empty()) { midi_msg.insert (midi_msg.end(), 55, ' '); } else { /* ascii data to display. @p msg is UTF-8 which is not legal. */ string ascii = Glib::convert_with_fallback (msg, "UTF-8", "ISO-8859-1", "_"); string::size_type len = ascii.length(); if (len > 55) { midi_msg << ascii.substr (0, 55); } else { midi_msg << ascii; for (string::size_type i = len; i < 55; ++i) { midi_msg << ' '; } } } midi_msg << MIDI::eox; return midi_msg; } /** display @p msg on the 55x2 screen for @p msecs milliseconds * * @param msg is assumed to be UTF-8 encoded, and will be converted * to ASCII with an underscore as fallback character before being * sent to the device. */ void Surface::display_message_for (string const& msg, uint64_t msecs) { string::size_type newline; if ((newline = msg.find ('\n')) == string::npos) { _port->write (display_line (msg, 0)); _port->write (display_line (string(), 1)); } else if (newline == 0) { _port->write (display_line (string(), 0)); _port->write (display_line (msg.substr (1), 1)); } else { string first_line = msg.substr (0, newline-1); string second_line = msg.substr (newline+1); _port->write (display_line (first_line, 0)); _port->write (display_line (second_line.substr (0, second_line.find_first_of ('\n')), 1)); } for (Strips::const_iterator s = strips.begin(); s != strips.end(); ++s) { (*s)->block_screen_display_for (msecs); } } /** display @p color_values on the 8 scribble strips of the X-Touch * * @param color_values is assumed to be an array with a color value for each of the 8 scribble strips */ MidiByteArray Surface::display_colors_on_xtouch (const XTouchColors color_values[]) const { MidiByteArray midi_msg; midi_msg << sysex_hdr (); midi_msg << 0x72; uint8_t displaycount = 8; for (uint8_t i = 0; i < displaycount; ++i) { midi_msg << color_values[i]; } midi_msg << MIDI::eox; return midi_msg; } /** takes trackcolor in 0xRRGGBBAA (Red, Green, Blue, Alpha) and converts it to suitable xtouch colors * return value can be casted to enum XTouchColor */ uint8_t Surface::convert_color_to_xtouch_value (uint32_t color) const { uint8_t red = color >> 24; uint8_t green = (color >> 16) & 0xff; uint8_t blue = (color >> 8) & 0xff; uint8_t max = red; if (max < green) { max = green; } if (max < blue) { max = blue; } if (max != 0) { //set the highest value to 0xFF to be brightness independent float norm = 255.0/max; red = static_cast (red*norm); green = static_cast (green*norm); blue = static_cast (blue*norm); uint8_t xcolor = 0; if (red > 0x7f) { xcolor = xcolor | 0b001; //lowest bit is red } if (green > 0x7f) { xcolor = xcolor | 0b010; //second bit is green } if (blue > 0x7f) { xcolor = xcolor | 0b100; //third bit is blue } return xcolor; } else { return White; //if it would be black (color = 0x000000) return white, because black means off } }