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ardour/libs/ardour/route.cc
Robin Gareus bb090c0012 add self-removing Sends (remove on disconnect) 
The idea is to dynamically add/remove sends for feeding a sidechain
and re-use all existing "External Send" infrastructure in particular
latency compensation.
2016-04-17 14:01:09 +02:00

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/*
Copyright (C) 2000 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.
*/
#ifdef WAF_BUILD
#include "libardour-config.h"
#endif
#include <cmath>
#include <cassert>
#include <algorithm>
#include <glibmm.h>
#include <boost/algorithm/string.hpp>
#include "pbd/xml++.h"
#include "pbd/enumwriter.h"
#include "pbd/memento_command.h"
#include "pbd/stacktrace.h"
#include "pbd/convert.h"
#include "pbd/boost_debug.h"
#include "pbd/unwind.h"
#include "ardour/amp.h"
#include "ardour/audio_buffer.h"
#include "ardour/audio_track.h"
#include "ardour/audio_port.h"
#include "ardour/audioengine.h"
#include "ardour/buffer.h"
#include "ardour/buffer_set.h"
#include "ardour/capturing_processor.h"
#include "ardour/debug.h"
#include "ardour/delivery.h"
#include "ardour/gain_control.h"
#include "ardour/internal_return.h"
#include "ardour/internal_send.h"
#include "ardour/meter.h"
#include "ardour/delayline.h"
#include "ardour/midi_buffer.h"
#include "ardour/midi_port.h"
#include "ardour/monitor_processor.h"
#include "ardour/pannable.h"
#include "ardour/panner.h"
#include "ardour/panner_shell.h"
#include "ardour/parameter_descriptor.h"
#include "ardour/plugin_insert.h"
#include "ardour/port.h"
#include "ardour/port_insert.h"
#include "ardour/processor.h"
#include "ardour/profile.h"
#include "ardour/route.h"
#include "ardour/route_group.h"
#include "ardour/send.h"
#include "ardour/session.h"
#include "ardour/unknown_processor.h"
#include "ardour/utils.h"
#include "i18n.h"
using namespace std;
using namespace ARDOUR;
using namespace PBD;
PBD::Signal0<void> Route::SyncOrderKeys;
PBD::Signal0<void> Route::RemoteControlIDChange;
/** Base class for all routable/mixable objects (tracks and busses) */
Route::Route (Session& sess, string name, Flag flg, DataType default_type)
: SessionObject (sess, name)
, Automatable (sess)
, GraphNode (sess._process_graph)
, _active (true)
, _signal_latency (0)
, _signal_latency_at_amp_position (0)
, _signal_latency_at_trim_position (0)
, _initial_delay (0)
, _roll_delay (0)
, _pending_process_reorder (0)
, _pending_signals (0)
, _flags (flg)
, _pending_declick (true)
, _meter_point (MeterPostFader)
, _pending_meter_point (MeterPostFader)
, _meter_type (MeterPeak)
, _self_solo (false)
, _soloed_by_others_upstream (0)
, _soloed_by_others_downstream (0)
, _solo_isolated (false)
, _solo_isolated_by_upstream (0)
, _denormal_protection (false)
, _recordable (true)
, _silent (false)
, _declickable (false)
, _mute_master (new MuteMaster (sess, name))
, _have_internal_generator (false)
, _solo_safe (false)
, _default_type (default_type)
, _order_key (0)
, _has_order_key (false)
, _remote_control_id (0)
, _track_number (0)
, _in_configure_processors (false)
, _initial_io_setup (false)
, _in_sidechain_setup (false)
, _strict_io (false)
, _custom_meter_position_noted (false)
{
processor_max_streams.reset();
}
int
Route::init ()
{
/* set default meter type */
if (is_master()) {
_meter_type = Config->get_meter_type_master ();
}
else if (dynamic_cast<Track*>(this)) {
_meter_type = Config->get_meter_type_track ();
} else {
_meter_type = Config->get_meter_type_bus ();
}
/* add standard controls */
_solo_control.reset (new SoloControllable (X_("solo"), shared_from_this ()));
_mute_control.reset (new MuteControllable (X_("mute"), shared_from_this ()));
_phase_control.reset (new PhaseControllable (X_("phase"), shared_from_this ()));
_solo_isolate_control.reset (new SoloIsolateControllable (X_("solo-iso"), shared_from_this ()));
_solo_safe_control.reset (new SoloSafeControllable (X_("solo-safe"), shared_from_this ()));
_solo_control->set_flags (Controllable::Flag (_solo_control->flags() | Controllable::Toggle));
_mute_control->set_flags (Controllable::Flag (_mute_control->flags() | Controllable::Toggle));
_phase_control->set_flags (Controllable::Flag (_phase_control->flags() | Controllable::Toggle));
add_control (_solo_control);
add_control (_mute_control);
add_control (_phase_control);
/* panning */
if (!(_flags & Route::MonitorOut)) {
_pannable.reset (new Pannable (_session));
}
/* input and output objects */
_input.reset (new IO (_session, _name, IO::Input, _default_type));
_output.reset (new IO (_session, _name, IO::Output, _default_type));
_input->changed.connect_same_thread (*this, boost::bind (&Route::input_change_handler, this, _1, _2));
_input->PortCountChanging.connect_same_thread (*this, boost::bind (&Route::input_port_count_changing, this, _1));
_output->changed.connect_same_thread (*this, boost::bind (&Route::output_change_handler, this, _1, _2));
_output->PortCountChanging.connect_same_thread (*this, boost::bind (&Route::output_port_count_changing, this, _1));
#if 0 // not used - just yet
if (!is_master() && !is_monitor() && !is_auditioner()) {
_delayline.reset (new DelayLine (_session, _name));
add_processor (_delayline, PreFader);
}
#endif
/* add amp processor */
_gain_control = boost::shared_ptr<GainControllable> (new GainControllable (_session, GainAutomation, shared_from_this ()));
add_control (_gain_control);
_amp.reset (new Amp (_session, X_("Fader"), _gain_control, true));
add_processor (_amp, PostFader);
if (is_monitor ()) {
_amp->set_display_name (_("Monitor"));
}
/* and input trim */
_trim_control = boost::shared_ptr<GainControllable> (new GainControllable (_session, TrimAutomation, shared_from_this ()));
add_control (_trim_control);
_trim.reset (new Amp (_session, X_("Trim"), _trim_control, false));
_trim->set_display_to_user (false);
if (dynamic_cast<AudioTrack*>(this)) {
/* we can't do this in the AudioTrack's constructor
* because _trim does not exit then
*/
_trim->activate();
}
else if (!dynamic_cast<Track*>(this) && ! ( is_monitor() || is_auditioner() )) {
/* regular bus */
_trim->activate();
}
/* create standard processors: meter, main outs, monitor out;
they will be added to _processors by setup_invisible_processors ()
*/
_meter.reset (new PeakMeter (_session, _name));
_meter->set_owner (this);
_meter->set_display_to_user (false);
_meter->activate ();
_main_outs.reset (new Delivery (_session, _output, _pannable, _mute_master, _name, Delivery::Main));
_main_outs->activate ();
if (is_monitor()) {
/* where we listen to tracks */
_intreturn.reset (new InternalReturn (_session));
_intreturn->activate ();
/* the thing that provides proper control over a control/monitor/listen bus
(such as per-channel cut, dim, solo, invert, etc).
*/
_monitor_control.reset (new MonitorProcessor (_session));
_monitor_control->activate ();
}
if (is_master() || is_monitor() || is_auditioner()) {
_mute_master->set_solo_ignore (true);
}
/* now that we have _meter, its safe to connect to this */
{
Glib::Threads::Mutex::Lock lx (AudioEngine::instance()->process_lock ());
configure_processors (0);
}
return 0;
}
Route::~Route ()
{
DEBUG_TRACE (DEBUG::Destruction, string_compose ("route %1 destructor\n", _name));
/* do this early so that we don't get incoming signals as we are going through destruction
*/
drop_connections ();
/* don't use clear_processors here, as it depends on the session which may
be half-destroyed by now
*/
Glib::Threads::RWLock::WriterLock lm (_processor_lock);
for (ProcessorList::iterator i = _processors.begin(); i != _processors.end(); ++i) {
(*i)->drop_references ();
}
_processors.clear ();
}
void
Route::set_remote_control_id (uint32_t id, bool notify_class_listeners)
{
if (Config->get_remote_model() != UserOrdered) {
return;
}
set_remote_control_id_internal (id, notify_class_listeners);
}
void
Route::set_remote_control_id_internal (uint32_t id, bool notify_class_listeners)
{
/* force IDs for master/monitor busses and prevent
any other route from accidentally getting these IDs
(i.e. legacy sessions)
*/
if (is_master() && id != MasterBusRemoteControlID) {
id = MasterBusRemoteControlID;
}
if (is_monitor() && id != MonitorBusRemoteControlID) {
id = MonitorBusRemoteControlID;
}
if (id < 1) {
return;
}
/* don't allow it to collide */
if (!is_master () && !is_monitor() &&
(id == MasterBusRemoteControlID || id == MonitorBusRemoteControlID)) {
id += MonitorBusRemoteControlID;
}
if (id != remote_control_id()) {
_remote_control_id = id;
RemoteControlIDChanged ();
if (notify_class_listeners) {
RemoteControlIDChange ();
}
}
}
uint32_t
Route::remote_control_id() const
{
if (is_master()) {
return MasterBusRemoteControlID;
}
if (is_monitor()) {
return MonitorBusRemoteControlID;
}
return _remote_control_id;
}
bool
Route::has_order_key () const
{
return _has_order_key;
}
uint32_t
Route::order_key () const
{
return _order_key;
}
void
Route::set_remote_control_id_explicit (uint32_t rid)
{
if (is_master() || is_monitor() || is_auditioner()) {
/* hard-coded remote IDs, or no remote ID */
return;
}
if (_remote_control_id != rid) {
DEBUG_TRACE (DEBUG::OrderKeys, string_compose ("%1: set edit-based RID to %2\n", name(), rid));
_remote_control_id = rid;
RemoteControlIDChanged (); /* EMIT SIGNAL (per-route) */
}
/* don't emit the class-level RID signal RemoteControlIDChange here,
leave that to the entity that changed the order key, so that we
don't get lots of emissions for no good reasons (e.g. when changing
all route order keys).
See Session::sync_remote_id_from_order_keys() for the (primary|only)
spot where that is emitted.
*/
}
void
Route::set_order_key (uint32_t n)
{
_has_order_key = true;
if (_order_key == n) {
return;
}
_order_key = n;
DEBUG_TRACE (DEBUG::OrderKeys, string_compose ("%1 order key set to %2\n",
name(), order_key ()));
_session.set_dirty ();
}
string
Route::ensure_track_or_route_name(string name, Session &session)
{
string newname = name;
while (!session.io_name_is_legal (newname)) {
newname = bump_name_once (newname, ' ');
}
return newname;
}
void
Route::inc_gain (gain_t factor)
{
/* To be used ONLY when doing group-relative gain adjustment, from
* ::set_gain()
*/
float desired_gain = _gain_control->user_double();
if (fabsf (desired_gain) < GAIN_COEFF_SMALL) {
// really?! what's the idea here?
_gain_control->route_set_value (0.000001f + (0.000001f * factor));
} else {
_gain_control->route_set_value (desired_gain + (desired_gain * factor));
}
}
void
Route::set_gain (gain_t val, Controllable::GroupControlDisposition group_override)
{
if (use_group (group_override, &RouteGroup::is_gain)) {
if (_route_group->is_relative()) {
gain_t usable_gain = _gain_control->get_value();
if (usable_gain < 0.000001f) {
usable_gain = 0.000001f;
}
gain_t delta = val;
if (delta < 0.000001f) {
delta = 0.000001f;
}
delta -= usable_gain;
if (delta == 0.0f)
return;
gain_t factor = delta / usable_gain;
if (factor > 0.0f) {
factor = _route_group->get_max_factor(factor);
if (factor == 0.0f) {
_amp->gain_control()->Changed(); /* EMIT SIGNAL */
return;
}
} else {
factor = _route_group->get_min_factor(factor);
if (factor == 0.0f) {
_amp->gain_control()->Changed(); /* EMIT SIGNAL */
return;
}
}
_route_group->foreach_route (boost::bind (&Route::inc_gain, _1, factor));
} else {
_route_group->foreach_route (boost::bind (&Route::set_gain, _1, val, Controllable::NoGroup));
}
return;
}
if (val == _gain_control->get_value()) {
return;
}
_gain_control->route_set_value (val);
}
void
Route::set_trim (gain_t val, Controllable::GroupControlDisposition /* group override */)
{
// TODO route group, see set_gain()
_trim_control->route_set_value (val);
}
void
Route::maybe_declick (BufferSet&, framecnt_t, int)
{
/* this is the "bus" implementation and they never declick.
*/
return;
}
/** Process this route for one (sub) cycle (process thread)
*
* @param bufs Scratch buffers to use for the signal path
* @param start_frame Initial transport frame
* @param end_frame Final transport frame
* @param nframes Number of frames to output (to ports)
*
* Note that (end_frame - start_frame) may not be equal to nframes when the
* transport speed isn't 1.0 (eg varispeed).
*/
void
Route::process_output_buffers (BufferSet& bufs,
framepos_t start_frame, framepos_t end_frame, pframes_t nframes,
int declick, bool gain_automation_ok)
{
/* Caller must hold process lock */
assert (!AudioEngine::instance()->process_lock().trylock());
Glib::Threads::RWLock::ReaderLock lm (_processor_lock, Glib::Threads::TRY_LOCK);
if (!lm.locked()) {
// can this actually happen? functions calling process_output_buffers()
// already take a reader-lock.
bufs.silence (nframes, 0);
return;
}
/* figure out if we're going to use gain automation */
if (gain_automation_ok) {
_amp->set_gain_automation_buffer (_session.gain_automation_buffer ());
_amp->setup_gain_automation (
start_frame + _signal_latency_at_amp_position,
end_frame + _signal_latency_at_amp_position,
nframes);
_trim->set_gain_automation_buffer (_session.trim_automation_buffer ());
_trim->setup_gain_automation (
start_frame + _signal_latency_at_trim_position,
end_frame + _signal_latency_at_trim_position,
nframes);
} else {
_amp->apply_gain_automation (false);
_trim->apply_gain_automation (false);
}
/* Tell main outs what to do about monitoring. We do this so that
on a transition between monitoring states we get a de-clicking gain
change in the _main_outs delivery, if config.get_use_monitor_fades()
is true.
We override this in the case where we have an internal generator.
*/
bool silence = _have_internal_generator ? false : (monitoring_state () == MonitoringSilence);
_main_outs->no_outs_cuz_we_no_monitor (silence);
/* -------------------------------------------------------------------------------------------
GLOBAL DECLICK (for transport changes etc.)
----------------------------------------------------------------------------------------- */
maybe_declick (bufs, nframes, declick);
_pending_declick = 0;
/* -------------------------------------------------------------------------------------------
DENORMAL CONTROL/PHASE INVERT
----------------------------------------------------------------------------------------- */
if (_phase_invert.any ()) {
int chn = 0;
if (_denormal_protection || Config->get_denormal_protection()) {
for (BufferSet::audio_iterator i = bufs.audio_begin(); i != bufs.audio_end(); ++i, ++chn) {
Sample* const sp = i->data();
if (_phase_invert[chn]) {
for (pframes_t nx = 0; nx < nframes; ++nx) {
sp[nx] = -sp[nx];
sp[nx] += 1.0e-27f;
}
} else {
for (pframes_t nx = 0; nx < nframes; ++nx) {
sp[nx] += 1.0e-27f;
}
}
}
} else {
for (BufferSet::audio_iterator i = bufs.audio_begin(); i != bufs.audio_end(); ++i, ++chn) {
Sample* const sp = i->data();
if (_phase_invert[chn]) {
for (pframes_t nx = 0; nx < nframes; ++nx) {
sp[nx] = -sp[nx];
}
}
}
}
} else {
if (_denormal_protection || Config->get_denormal_protection()) {
for (BufferSet::audio_iterator i = bufs.audio_begin(); i != bufs.audio_end(); ++i) {
Sample* const sp = i->data();
for (pframes_t nx = 0; nx < nframes; ++nx) {
sp[nx] += 1.0e-27f;
}
}
}
}
/* -------------------------------------------------------------------------------------------
and go ....
----------------------------------------------------------------------------------------- */
/* set this to be true if the meter will already have been ::run() earlier */
bool const meter_already_run = metering_state() == MeteringInput;
framecnt_t latency = 0;
for (ProcessorList::const_iterator i = _processors.begin(); i != _processors.end(); ++i) {
if (meter_already_run && boost::dynamic_pointer_cast<PeakMeter> (*i)) {
/* don't ::run() the meter, otherwise it will have its previous peak corrupted */
continue;
}
#ifndef NDEBUG
/* if it has any inputs, make sure they match */
if (boost::dynamic_pointer_cast<UnknownProcessor> (*i) == 0 && (*i)->input_streams() != ChanCount::ZERO) {
if (bufs.count() != (*i)->input_streams()) {
DEBUG_TRACE (
DEBUG::Processors, string_compose (
"input port mismatch %1 bufs = %2 input for %3 = %4\n",
_name, bufs.count(), (*i)->name(), (*i)->input_streams()
)
);
}
}
#endif
/* should we NOT run plugins here if the route is inactive?
do we catch route != active somewhere higher?
*/
if (boost::dynamic_pointer_cast<Send>(*i) != 0) {
boost::dynamic_pointer_cast<Send>(*i)->set_delay_in(_signal_latency - latency);
}
(*i)->run (bufs, start_frame - latency, end_frame - latency, nframes, *i != _processors.back());
bufs.set_count ((*i)->output_streams());
if ((*i)->active ()) {
latency += (*i)->signal_latency ();
}
}
}
void
Route::bounce_process (BufferSet& buffers, framepos_t start, framecnt_t nframes,
boost::shared_ptr<Processor> endpoint,
bool include_endpoint, bool for_export, bool for_freeze)
{
/* If no processing is required, there's no need to go any further. */
if (!endpoint && !include_endpoint) {
return;
}
framecnt_t latency = bounce_get_latency(_amp, false, for_export, for_freeze);
_amp->set_gain_automation_buffer (_session.gain_automation_buffer ());
_amp->setup_gain_automation (start - latency, start - latency + nframes, nframes);
/* trim is always at the top, for bounce no latency compensation is needed */
_trim->set_gain_automation_buffer (_session.trim_automation_buffer ());
_trim->setup_gain_automation (start, start + nframes, nframes);
latency = 0;
for (ProcessorList::iterator i = _processors.begin(); i != _processors.end(); ++i) {
if (!include_endpoint && (*i) == endpoint) {
break;
}
/* if we're *not* exporting, stop processing if we come across a routing processor. */
if (!for_export && boost::dynamic_pointer_cast<PortInsert>(*i)) {
break;
}
if (!for_export && for_freeze && (*i)->does_routing() && (*i)->active()) {
break;
}
/* special case the panner (export outputs)
* Ideally we'd only run the panner, not the delivery itself...
* but panners need separate input/output buffers and some context
* (panshell, panner type, etc). AFAICT there is no ill side effect
* of re-using the main delivery when freewheeling/exporting a region.
*/
if ((*i) == _main_outs) {
assert ((*i)->does_routing());
(*i)->run (buffers, start - latency, start - latency + nframes, nframes, true);
buffers.set_count ((*i)->output_streams());
}
/* don't run any processors that do routing.
* Also don't bother with metering.
*/
if (!(*i)->does_routing() && !boost::dynamic_pointer_cast<PeakMeter>(*i)) {
(*i)->run (buffers, start - latency, start - latency + nframes, nframes, true);
buffers.set_count ((*i)->output_streams());
latency += (*i)->signal_latency ();
}
if ((*i) == endpoint) {
break;
}
}
}
framecnt_t
Route::bounce_get_latency (boost::shared_ptr<Processor> endpoint,
bool include_endpoint, bool for_export, bool for_freeze) const
{
framecnt_t latency = 0;
if (!endpoint && !include_endpoint) {
return latency;
}
for (ProcessorList::const_iterator i = _processors.begin(); i != _processors.end(); ++i) {
if (!include_endpoint && (*i) == endpoint) {
break;
}
if (!for_export && boost::dynamic_pointer_cast<PortInsert>(*i)) {
break;
}
if (!for_export && for_freeze && (*i)->does_routing() && (*i)->active()) {
break;
}
if (!(*i)->does_routing() && !boost::dynamic_pointer_cast<PeakMeter>(*i)) {
latency += (*i)->signal_latency ();
}
if ((*i) == endpoint) {
break;
}
}
return latency;
}
ChanCount
Route::bounce_get_output_streams (ChanCount &cc, boost::shared_ptr<Processor> endpoint,
bool include_endpoint, bool for_export, bool for_freeze) const
{
if (!endpoint && !include_endpoint) {
return cc;
}
for (ProcessorList::const_iterator i = _processors.begin(); i != _processors.end(); ++i) {
if (!include_endpoint && (*i) == endpoint) {
break;
}
if (!for_export && boost::dynamic_pointer_cast<PortInsert>(*i)) {
break;
}
if (!for_export && for_freeze && (*i)->does_routing() && (*i)->active()) {
break;
}
if (!(*i)->does_routing() && !boost::dynamic_pointer_cast<PeakMeter>(*i)) {
cc = (*i)->output_streams();
}
if ((*i) == endpoint) {
break;
}
}
return cc;
}
ChanCount
Route::n_process_buffers ()
{
return max (_input->n_ports(), processor_max_streams);
}
void
Route::monitor_run (framepos_t start_frame, framepos_t end_frame, pframes_t nframes, int declick)
{
assert (is_monitor());
BufferSet& bufs (_session.get_route_buffers (n_process_buffers()));
fill_buffers_with_input (bufs, _input, nframes);
passthru (bufs, start_frame, end_frame, nframes, declick);
}
void
Route::passthru (BufferSet& bufs, framepos_t start_frame, framepos_t end_frame, pframes_t nframes, int declick)
{
_silent = false;
if (is_monitor() && _session.listening() && !_session.is_auditioning()) {
/* control/monitor bus ignores input ports when something is
feeding the listen "stream". data will "arrive" into the
route from the intreturn processor element.
*/
bufs.silence (nframes, 0);
}
write_out_of_band_data (bufs, start_frame, end_frame, nframes);
process_output_buffers (bufs, start_frame, end_frame, nframes, declick, true);
}
void
Route::passthru_silence (framepos_t start_frame, framepos_t end_frame, pframes_t nframes, int declick)
{
BufferSet& bufs (_session.get_route_buffers (n_process_buffers(), true));
bufs.set_count (_input->n_ports());
write_out_of_band_data (bufs, start_frame, end_frame, nframes);
process_output_buffers (bufs, start_frame, end_frame, nframes, declick, false);
}
void
Route::set_listen (bool yn, Controllable::GroupControlDisposition group_override)
{
if (_solo_safe) {
return;
}
if (use_group (group_override, &RouteGroup::is_solo)) {
_route_group->foreach_route (boost::bind (&Route::set_listen, _1, yn, Controllable::ForGroup));
return;
}
if (_monitor_send) {
if (yn != _monitor_send->active()) {
if (yn) {
_monitor_send->activate ();
_mute_master->set_soloed_by_self (true);
} else {
_monitor_send->deactivate ();
_mute_master->set_soloed_by_self (false);
}
_mute_master->set_soloed_by_others (false);
listen_changed (group_override); /* EMIT SIGNAL */
}
}
}
bool
Route::listening_via_monitor () const
{
if (_monitor_send) {
return _monitor_send->active ();
} else {
return false;
}
}
void
Route::set_solo_safe (bool yn, Controllable::GroupControlDisposition /* group_override */)
{
if (_solo_safe != yn) {
_solo_safe = yn;
solo_safe_changed (); /* EMIT SIGNAL */
_solo_safe_control->Changed(); /* EMIT SIGNAL */
}
}
bool
Route::solo_safe() const
{
return _solo_safe;
}
void
Route::clear_all_solo_state ()
{
// ideally this function will never do anything, it only exists to forestall Murphy
bool emit_changed = false;
#ifndef NDEBUG
// these are really debug messages, but of possible interest.
if (_self_solo) {
PBD::info << string_compose (_("Cleared Explicit solo: %1\n"), name());
}
if (_soloed_by_others_upstream || _soloed_by_others_downstream) {
PBD::info << string_compose (_("Cleared Implicit solo: %1 up:%2 down:%3\n"),
name(), _soloed_by_others_upstream, _soloed_by_others_downstream);
}
#endif
if (!_self_solo && (_soloed_by_others_upstream || _soloed_by_others_downstream)) {
// if self-soled, set_solo() will do signal emission
emit_changed = true;
}
_soloed_by_others_upstream = 0;
_soloed_by_others_downstream = 0;
{
PBD::Unwinder<bool> uw (_solo_safe, false);
set_solo (false, Controllable::NoGroup);
}
if (emit_changed) {
set_mute_master_solo ();
solo_changed (false, Controllable::UseGroup); /* EMIT SIGNAL */
}
}
void
Route::set_solo (bool yn, Controllable::GroupControlDisposition group_override)
{
DEBUG_TRACE (DEBUG::Solo, string_compose ("%1: set solo => %2, grp ? %3 currently self-soloed ? %4\n",
name(), yn, enum_2_string(group_override), self_soloed()));
if (_solo_safe) {
DEBUG_TRACE (DEBUG::Solo, string_compose ("%1 ignore solo change due to solo-safe\n", name()));
return;
}
if (is_master() || is_monitor() || is_auditioner()) {
DEBUG_TRACE (DEBUG::Solo, string_compose ("%1 ignore solo change (master, monitor or auditioner)\n", name()));
return;
}
if (use_group (group_override, &RouteGroup::is_solo)) {
_route_group->foreach_route (boost::bind (&Route::set_solo, _1, yn, Controllable::ForGroup));
return;
}
if (self_soloed() != yn) {
set_self_solo (yn);
solo_changed (true, group_override); /* EMIT SIGNAL */
_solo_control->Changed (); /* EMIT SIGNAL */
}
assert (Config->get_solo_control_is_listen_control() || !_monitor_send || !_monitor_send->active());
/* XXX TRACKS DEVELOPERS: THIS LOGIC SUGGESTS THAT YOU ARE NOT AWARE OF
Config->get_solo_mute_overrride().
*/
if (yn && Profile->get_trx()) {
set_mute (false, Controllable::UseGroup);
}
}
void
Route::set_self_solo (bool yn)
{
DEBUG_TRACE (DEBUG::Solo, string_compose ("%1: set SELF solo => %2\n", name(), yn));
_self_solo = yn;
set_mute_master_solo ();
}
void
Route::mod_solo_by_others_upstream (int32_t delta)
{
DEBUG_TRACE (DEBUG::Solo, string_compose ("%1 mod solo-by-upstream by %2, current up = %3 down = %4\n",
name(), delta, _soloed_by_others_upstream, _soloed_by_others_downstream));
uint32_t old_sbu = _soloed_by_others_upstream;
if (delta < 0) {
if (_soloed_by_others_upstream >= (uint32_t) abs (delta)) {
_soloed_by_others_upstream += delta;
} else {
_soloed_by_others_upstream = 0;
}
} else {
_soloed_by_others_upstream += delta;
}
DEBUG_TRACE (DEBUG::Solo, string_compose (
"%1 SbU delta %2 = %3 old = %4 sbd %5 ss %6 exclusive %7\n",
name(), delta, _soloed_by_others_upstream, old_sbu,
_soloed_by_others_downstream, _self_solo, Config->get_exclusive_solo()));
/* push the inverse solo change to everything that feeds us.
This is important for solo-within-group. When we solo 1 track out of N that
feed a bus, that track will cause mod_solo_by_upstream (+1) to be called
on the bus. The bus then needs to call mod_solo_by_downstream (-1) on all
tracks that feed it. This will silence them if they were audible because
of a bus solo, but the newly soloed track will still be audible (because
it is self-soloed).
but .. do this only when we are being told to solo-by-upstream (i.e delta = +1),
not in reverse.
*/
if ((_self_solo || _soloed_by_others_downstream) &&
((old_sbu == 0 && _soloed_by_others_upstream > 0) ||
(old_sbu > 0 && _soloed_by_others_upstream == 0))) {
if (delta > 0 || !Config->get_exclusive_solo()) {
DEBUG_TRACE (DEBUG::Solo, string_compose("\t ... INVERT push from %1\n", _name));
for (FedBy::iterator i = _fed_by.begin(); i != _fed_by.end(); ++i) {
if (i->sends_only) {
continue;
}
boost::shared_ptr<Route> sr = i->r.lock();
if (sr) {
sr->mod_solo_by_others_downstream (-delta);
}
}
}
}
set_mute_master_solo ();
solo_changed (false, Controllable::UseGroup); /* EMIT SIGNAL */
}
void
Route::mod_solo_by_others_downstream (int32_t delta)
{
DEBUG_TRACE (DEBUG::Solo, string_compose ("%1 mod solo-by-downstream by %2, current up = %3 down = %4\n",
name(), delta, _soloed_by_others_upstream, _soloed_by_others_downstream));
if (delta < 0) {
if (_soloed_by_others_downstream >= (uint32_t) abs (delta)) {
_soloed_by_others_downstream += delta;
} else {
_soloed_by_others_downstream = 0;
}
} else {
_soloed_by_others_downstream += delta;
}
DEBUG_TRACE (DEBUG::Solo, string_compose ("%1 SbD delta %2 = %3\n", name(), delta, _soloed_by_others_downstream));
set_mute_master_solo ();
solo_changed (false, Controllable::UseGroup); /* EMIT SIGNAL */
}
void
Route::set_mute_master_solo ()
{
_mute_master->set_soloed_by_self (self_soloed());
_mute_master->set_soloed_by_others (soloed_by_others_downstream() || soloed_by_others_upstream());
}
void
Route::mod_solo_isolated_by_upstream (bool yn)
{
bool old = solo_isolated ();
DEBUG_TRACE (DEBUG::Solo, string_compose ("%1 mod_solo_isolated_by_upstream cur: %2 d: %3\n",
name(), _solo_isolated_by_upstream, yn ? "+1" : "-1"));
if (!yn) {
if (_solo_isolated_by_upstream >= 1) {
_solo_isolated_by_upstream--;
} else {
_solo_isolated_by_upstream = 0;
}
} else {
_solo_isolated_by_upstream++;
}
if (solo_isolated() != old) {
/* solo isolated status changed */
_mute_master->set_solo_ignore (solo_isolated());
solo_isolated_changed (); /* EMIT SIGNAL */
}
}
void
Route::set_solo_isolated (bool yn, Controllable::GroupControlDisposition group_override)
{
if (is_master() || is_monitor() || is_auditioner()) {
return;
}
if (use_group (group_override, &RouteGroup::is_solo)) {
_route_group->foreach_route (boost::bind (&Route::set_solo_isolated, _1, yn, Controllable::ForGroup));
return;
}
bool changed = false;
if (yn) {
if (_solo_isolated == false) {
_mute_master->set_solo_ignore (true);
changed = true;
}
_solo_isolated = true;
} else {
if (_solo_isolated == true) {
_solo_isolated = false;
_mute_master->set_solo_ignore (false);
changed = true;
}
}
if (!changed) {
return;
}
/* forward propagate solo-isolate status to everything fed by this route, but not those via sends only */
boost::shared_ptr<RouteList> routes = _session.get_routes ();
for (RouteList::iterator i = routes->begin(); i != routes->end(); ++i) {
if ((*i).get() == this || (*i)->is_master() || (*i)->is_monitor() || (*i)->is_auditioner()) {
continue;
}
bool sends_only;
bool does_feed = feeds (*i, &sends_only);
if (does_feed && !sends_only) {
(*i)->mod_solo_isolated_by_upstream (yn);
}
}
/* XXX should we back-propagate as well? (April 2010: myself and chris goddard think not) */
solo_isolated_changed (); /* EMIT SIGNAL */
_solo_isolate_control->Changed(); /* EMIT SIGNAL */
}
bool
Route::solo_isolated () const
{
return (_solo_isolated == true) || (_solo_isolated_by_upstream > 0);
}
void
Route::set_mute_points (MuteMaster::MutePoint mp)
{
_mute_master->set_mute_points (mp);
mute_points_changed (); /* EMIT SIGNAL */
if (_mute_master->muted_by_self()) {
mute_changed (); /* EMIT SIGNAL */
_mute_control->Changed (); /* EMIT SIGNAL */
}
}
void
Route::set_mute (bool yn, Controllable::GroupControlDisposition group_override)
{
if (use_group (group_override, &RouteGroup::is_mute)) {
_route_group->foreach_route (boost::bind (&Route::set_mute, _1, yn, Controllable::ForGroup));
return;
}
if (muted() != yn) {
_mute_master->set_muted_by_self (yn);
/* allow any derived classes to respond to the mute change
before anybody else knows about it.
*/
act_on_mute ();
/* tell everyone else */
mute_changed (); /* EMIT SIGNAL */
_mute_control->Changed (); /* EMIT SIGNAL */
}
}
bool
Route::muted () const
{
return _mute_master->muted_by_self();
}
bool
Route::muted_by_others () const
{
// This method is only used by route_ui for display state.
// The real thing is MuteMaster::muted_by_others_at()
//master is never muted by others
if (is_master())
return false;
//now check to see if something is soloed (and I am not)
//see also MuteMaster::mute_gain_at()
return (_session.soloing() && !soloed() && !solo_isolated());
}
#if 0
static void
dump_processors(const string& name, const list<boost::shared_ptr<Processor> >& procs)
{
cerr << name << " {" << endl;
for (list<boost::shared_ptr<Processor> >::const_iterator p = procs.begin();
p != procs.end(); ++p) {
cerr << "\t" << (*p)->name() << " ID = " << (*p)->id() << " @ " << (*p) << endl;
}
cerr << "}" << endl;
}
#endif
/** Supposing that we want to insert a Processor at a given Placement, return
* the processor to add the new one before (or 0 to add at the end).
*/
boost::shared_ptr<Processor>
Route::before_processor_for_placement (Placement p)
{
Glib::Threads::RWLock::ReaderLock lm (_processor_lock);
ProcessorList::iterator loc;
if (p == PreFader) {
/* generic pre-fader: insert immediately before the amp */
loc = find (_processors.begin(), _processors.end(), _amp);
} else {
/* generic post-fader: insert right before the main outs */
loc = find (_processors.begin(), _processors.end(), _main_outs);
}
return loc != _processors.end() ? *loc : boost::shared_ptr<Processor> ();
}
/** Supposing that we want to insert a Processor at a given index, return
* the processor to add the new one before (or 0 to add at the end).
*/
boost::shared_ptr<Processor>
Route::before_processor_for_index (int index)
{
if (index == -1) {
return boost::shared_ptr<Processor> ();
}
Glib::Threads::RWLock::ReaderLock lm (_processor_lock);
ProcessorList::iterator i = _processors.begin ();
int j = 0;
while (i != _processors.end() && j < index) {
if ((*i)->display_to_user()) {
++j;
}
++i;
}
return (i != _processors.end() ? *i : boost::shared_ptr<Processor> ());
}
/** Add a processor either pre- or post-fader
* @return 0 on success, non-0 on failure.
*/
int
Route::add_processor (boost::shared_ptr<Processor> processor, Placement placement, ProcessorStreams* err, bool activation_allowed)
{
return add_processor (processor, before_processor_for_placement (placement), err, activation_allowed);
}
/** Add a processor to a route such that it ends up with a given index into the visible processors.
* @param index Index to add the processor at, or -1 to add at the end of the list.
* @return 0 on success, non-0 on failure.
*/
int
Route::add_processor_by_index (boost::shared_ptr<Processor> processor, int index, ProcessorStreams* err, bool activation_allowed)
{
return add_processor (processor, before_processor_for_index (index), err, activation_allowed);
}
/** Add a processor to the route.
* @param before An existing processor in the list, or 0; the new processor will be inserted immediately before it (or at the end).
* @return 0 on success, non-0 on failure.
*/
int
Route::add_processor (boost::shared_ptr<Processor> processor, boost::shared_ptr<Processor> before, ProcessorStreams* err, bool activation_allowed)
{
assert (processor != _meter);
assert (processor != _main_outs);
DEBUG_TRACE (DEBUG::Processors, string_compose (
"%1 adding processor %2\n", name(), processor->name()));
if (!AudioEngine::instance()->connected() || !processor) {
return 1;
}
if (_strict_io) {
boost::shared_ptr<PluginInsert> pi;
if ((pi = boost::dynamic_pointer_cast<PluginInsert>(processor)) != 0) {
pi->set_strict_io (true);
}
}
{
Glib::Threads::Mutex::Lock lx (AudioEngine::instance()->process_lock ());
Glib::Threads::RWLock::WriterLock lm (_processor_lock);
ProcessorState pstate (this);
boost::shared_ptr<PluginInsert> pi;
boost::shared_ptr<PortInsert> porti;
if (processor == _amp) {
/* Ensure that only one amp is in the list at any time */
ProcessorList::iterator check = find (_processors.begin(), _processors.end(), processor);
if (check != _processors.end()) {
if (before == _amp) {
/* Already in position; all is well */
return 0;
} else {
_processors.erase (check);
}
}
}
assert (find (_processors.begin(), _processors.end(), processor) == _processors.end ());
ProcessorList::iterator loc;
if (before) {
/* inserting before a processor; find it */
loc = find (_processors.begin(), _processors.end(), before);
if (loc == _processors.end ()) {
/* Not found */
return 1;
}
} else {
/* inserting at end */
loc = _processors.end ();
}
_processors.insert (loc, processor);
processor->set_owner (this);
// Set up processor list channels. This will set processor->[input|output]_streams(),
// configure redirect ports properly, etc.
{
if (configure_processors_unlocked (err)) {
pstate.restore ();
configure_processors_unlocked (0); // it worked before we tried to add it ...
return -1;
}
}
if ((pi = boost::dynamic_pointer_cast<PluginInsert>(processor)) != 0) {
if (pi->has_no_inputs ()) {
/* generator plugin */
_have_internal_generator = true;
}
}
if (activation_allowed && (!_session.get_bypass_all_loaded_plugins () || !processor->display_to_user ())) {
processor->activate ();
}
processor->ActiveChanged.connect_same_thread (*this, boost::bind (&Session::update_latency_compensation, &_session, false));
_output->set_user_latency (0);
}
reset_instrument_info ();
processors_changed (RouteProcessorChange ()); /* EMIT SIGNAL */
set_processor_positions ();
boost::shared_ptr<Send> send;
if ((send = boost::dynamic_pointer_cast<Send> (processor))) {
send->SelfDestruct.connect_same_thread (*this,
boost::bind (&Route::processor_selfdestruct, this, boost::weak_ptr<Processor> (processor)));
}
return 0;
}
void
Route::processor_selfdestruct (boost::weak_ptr<Processor> wp)
{
/* We cannot destruct the processor here (usually RT-thread
* with various locks held - in case of sends also io_locks).
* Queue for deletion in low-priority thread.
*/
Glib::Threads::Mutex::Lock lx (selfdestruct_lock);
selfdestruct_sequence.push_back (wp);
}
bool
Route::add_processor_from_xml_2X (const XMLNode& node, int version)
{
const XMLProperty *prop;
try {
boost::shared_ptr<Processor> processor;
/* bit of a hack: get the `placement' property from the <Redirect> tag here
so that we can add the processor in the right place (pre/post-fader)
*/
XMLNodeList const & children = node.children ();
XMLNodeList::const_iterator i = children.begin ();
while (i != children.end() && (*i)->name() != X_("Redirect")) {
++i;
}
Placement placement = PreFader;
if (i != children.end()) {
if ((prop = (*i)->property (X_("placement"))) != 0) {
placement = Placement (string_2_enum (prop->value(), placement));
}
}
if (node.name() == "Insert") {
if ((prop = node.property ("type")) != 0) {
if (prop->value() == "ladspa" || prop->value() == "Ladspa" ||
prop->value() == "lv2" ||
prop->value() == "windows-vst" ||
prop->value() == "lxvst" ||
prop->value() == "audiounit") {
if (_session.get_disable_all_loaded_plugins ()) {
processor.reset (new UnknownProcessor (_session, node));
} else {
processor.reset (new PluginInsert (_session));
processor->set_owner (this);
}
} else {
processor.reset (new PortInsert (_session, _pannable, _mute_master));
}
}
} else if (node.name() == "Send") {
boost::shared_ptr<Pannable> sendpan (new Pannable (_session));
processor.reset (new Send (_session, sendpan, _mute_master));
} else {
error << string_compose(_("unknown Processor type \"%1\"; ignored"), node.name()) << endmsg;
return false;
}
if (processor->set_state (node, version)) {
return false;
}
//A2 uses the "active" flag in the toplevel redirect node, not in the child plugin/IO
if (i != children.end()) {
if ((prop = (*i)->property (X_("active"))) != 0) {
if ( string_is_affirmative (prop->value()) && (!_session.get_bypass_all_loaded_plugins () || !processor->display_to_user () ) )
processor->activate();
else
processor->deactivate();
}
}
return (add_processor (processor, placement, 0, false) == 0);
}
catch (failed_constructor &err) {
warning << _("processor could not be created. Ignored.") << endmsg;
return false;
}
}
int
Route::add_processors (const ProcessorList& others, boost::shared_ptr<Processor> before, ProcessorStreams* err)
{
/* NOTE: this is intended to be used ONLY when copying
processors from another Route. Hence the subtle
differences between this and ::add_processor()
*/
ProcessorList::iterator loc;
if (before) {
loc = find(_processors.begin(), _processors.end(), before);
} else {
/* nothing specified - at end */
loc = _processors.end ();
}
if (!_session.engine().connected()) {
return 1;
}
if (others.empty()) {
return 0;
}
{
Glib::Threads::Mutex::Lock lx (AudioEngine::instance()->process_lock ());
Glib::Threads::RWLock::WriterLock lm (_processor_lock);
ProcessorState pstate (this);
for (ProcessorList::const_iterator i = others.begin(); i != others.end(); ++i) {
if (*i == _meter) {
continue;
}
boost::shared_ptr<PluginInsert> pi;
if ((pi = boost::dynamic_pointer_cast<PluginInsert>(*i)) != 0) {
pi->set_strict_io (_strict_io);
}
_processors.insert (loc, *i);
(*i)->set_owner (this);
if ((*i)->active()) {
(*i)->activate ();
}
/* Think: does this really need to be called for every processor in the loop? */
{
if (configure_processors_unlocked (err)) {
pstate.restore ();
configure_processors_unlocked (0); // it worked before we tried to add it ...
return -1;
}
}
(*i)->ActiveChanged.connect_same_thread (*this, boost::bind (&Session::update_latency_compensation, &_session, false));
}
for (ProcessorList::const_iterator i = _processors.begin(); i != _processors.end(); ++i) {
boost::shared_ptr<PluginInsert> pi;
if ((pi = boost::dynamic_pointer_cast<PluginInsert>(*i)) != 0) {
if (pi->has_no_inputs ()) {
_have_internal_generator = true;
break;
}
}
}
_output->set_user_latency (0);
}
reset_instrument_info ();
processors_changed (RouteProcessorChange ()); /* EMIT SIGNAL */
set_processor_positions ();
return 0;
}
void
Route::placement_range(Placement p, ProcessorList::iterator& start, ProcessorList::iterator& end)
{
if (p == PreFader) {
start = _processors.begin();
end = find(_processors.begin(), _processors.end(), _amp);
} else {
start = find(_processors.begin(), _processors.end(), _amp);
++start;
end = _processors.end();
}
}
/** Turn off all processors with a given placement
* @param p Placement of processors to disable
*/
void
Route::disable_processors (Placement p)
{
Glib::Threads::RWLock::ReaderLock lm (_processor_lock);
ProcessorList::iterator start, end;
placement_range(p, start, end);
for (ProcessorList::iterator i = start; i != end; ++i) {
(*i)->deactivate ();
}
_session.set_dirty ();
}
/** Turn off all redirects
*/
void
Route::disable_processors ()
{
Glib::Threads::RWLock::ReaderLock lm (_processor_lock);
for (ProcessorList::iterator i = _processors.begin(); i != _processors.end(); ++i) {
(*i)->deactivate ();
}
_session.set_dirty ();
}
/** Turn off all redirects with a given placement
* @param p Placement of redirects to disable
*/
void
Route::disable_plugins (Placement p)
{
Glib::Threads::RWLock::ReaderLock lm (_processor_lock);
ProcessorList::iterator start, end;
placement_range(p, start, end);
for (ProcessorList::iterator i = start; i != end; ++i) {
if (boost::dynamic_pointer_cast<PluginInsert> (*i)) {
(*i)->deactivate ();
}
}
_session.set_dirty ();
}
/** Turn off all plugins
*/
void
Route::disable_plugins ()
{
Glib::Threads::RWLock::ReaderLock lm (_processor_lock);
for (ProcessorList::iterator i = _processors.begin(); i != _processors.end(); ++i) {
if (boost::dynamic_pointer_cast<PluginInsert> (*i)) {
(*i)->deactivate ();
}
}
_session.set_dirty ();
}
void
Route::ab_plugins (bool forward)
{
Glib::Threads::RWLock::ReaderLock lm (_processor_lock);
if (forward) {
/* forward = turn off all active redirects, and mark them so that the next time
we go the other way, we will revert them
*/
for (ProcessorList::iterator i = _processors.begin(); i != _processors.end(); ++i) {
if (!boost::dynamic_pointer_cast<PluginInsert> (*i)) {
continue;
}
if ((*i)->active()) {
(*i)->deactivate ();
(*i)->set_next_ab_is_active (true);
} else {
(*i)->set_next_ab_is_active (false);
}
}
} else {
/* backward = if the redirect was marked to go active on the next ab, do so */
for (ProcessorList::iterator i = _processors.begin(); i != _processors.end(); ++i) {
if (!boost::dynamic_pointer_cast<PluginInsert> (*i)) {
continue;
}
if ((*i)->get_next_ab_is_active()) {
(*i)->activate ();
} else {
(*i)->deactivate ();
}
}
}
_session.set_dirty ();
}
/** Remove processors with a given placement.
* @param p Placement of processors to remove.
*/
void
Route::clear_processors (Placement p)
{
if (!_session.engine().connected()) {
return;
}
bool already_deleting = _session.deletion_in_progress();
if (!already_deleting) {
_session.set_deletion_in_progress();
}
{
Glib::Threads::Mutex::Lock lx (AudioEngine::instance()->process_lock ());
Glib::Threads::RWLock::WriterLock lm (_processor_lock);
ProcessorList new_list;
ProcessorStreams err;
bool seen_amp = false;
for (ProcessorList::iterator i = _processors.begin(); i != _processors.end(); ++i) {
if (*i == _amp) {
seen_amp = true;
}
if ((*i) == _amp || (*i) == _meter || (*i) == _main_outs || (*i) == _delayline || (*i) == _trim) {
/* you can't remove these */
new_list.push_back (*i);
} else {
if (seen_amp) {
switch (p) {
case PreFader:
new_list.push_back (*i);
break;
case PostFader:
(*i)->drop_references ();
break;
}
} else {
switch (p) {
case PreFader:
(*i)->drop_references ();
break;
case PostFader:
new_list.push_back (*i);
break;
}
}
}
}
_processors = new_list;
configure_processors_unlocked (&err); // this can't fail
}
processor_max_streams.reset();
_have_internal_generator = false;
processors_changed (RouteProcessorChange ()); /* EMIT SIGNAL */
set_processor_positions ();
reset_instrument_info ();
if (!already_deleting) {
_session.clear_deletion_in_progress();
}
}
int
Route::remove_processor (boost::shared_ptr<Processor> processor, ProcessorStreams* err, bool need_process_lock)
{
// TODO once the export point can be configured properly, do something smarter here
if (processor == _capturing_processor) {
Glib::Threads::Mutex::Lock lx (AudioEngine::instance()->process_lock (), Glib::Threads::NOT_LOCK);
if (need_process_lock) {
lx.acquire();
}
_capturing_processor.reset();
if (need_process_lock) {
lx.release();
}
}
/* these can never be removed */
if (processor == _amp || processor == _meter || processor == _main_outs || processor == _delayline || processor == _trim) {
return 0;
}
if (!_session.engine().connected()) {
return 1;
}
processor_max_streams.reset();
{
Glib::Threads::Mutex::Lock lx (AudioEngine::instance()->process_lock (), Glib::Threads::NOT_LOCK);
if (need_process_lock) {
lx.acquire();
}
/* Caller must hold process lock */
assert (!AudioEngine::instance()->process_lock().trylock());
Glib::Threads::RWLock::WriterLock lm (_processor_lock); // XXX deadlock after export
ProcessorState pstate (this);
ProcessorList::iterator i;
bool removed = false;
for (i = _processors.begin(); i != _processors.end(); ) {
if (*i == processor) {
/* move along, see failure case for configure_processors()
where we may need to reconfigure the processor.
*/
/* stop redirects that send signals to JACK ports
from causing noise as a result of no longer being
run.
*/
boost::shared_ptr<IOProcessor> iop = boost::dynamic_pointer_cast<IOProcessor> (*i);
boost::shared_ptr<PluginInsert> pi = boost::dynamic_pointer_cast<PluginInsert>(*i);
if (pi != 0) {
assert (iop == 0);
iop = pi->sidechain();
}
if (iop != 0) {
iop->disconnect ();
}
i = _processors.erase (i);
removed = true;
break;
} else {
++i;
}
_output->set_user_latency (0);
}
if (!removed) {
/* what? */
return 1;
}
if (configure_processors_unlocked (err)) {
pstate.restore ();
/* we know this will work, because it worked before :) */
configure_processors_unlocked (0);
return -1;
}
_have_internal_generator = false;
for (i = _processors.begin(); i != _processors.end(); ++i) {
boost::shared_ptr<PluginInsert> pi;
if ((pi = boost::dynamic_pointer_cast<PluginInsert>(*i)) != 0) {
if (pi->has_no_inputs ()) {
_have_internal_generator = true;
break;
}
}
}
if (need_process_lock) {
lx.release();
}
}
reset_instrument_info ();
processor->drop_references ();
processors_changed (RouteProcessorChange ()); /* EMIT SIGNAL */
set_processor_positions ();
return 0;
}
int
Route::replace_processor (boost::shared_ptr<Processor> old, boost::shared_ptr<Processor> sub, ProcessorStreams* err)
{
/* these can never be removed */
if (old == _amp || old == _meter || old == _main_outs || old == _delayline || old == _trim) {
return 1;
}
/* and can't be used as substitute, either */
if (sub == _amp || sub == _meter || sub == _main_outs || sub == _delayline || sub == _trim) {
return 1;
}
/* I/Os are out, too */
if (boost::dynamic_pointer_cast<IOProcessor> (old) || boost::dynamic_pointer_cast<IOProcessor> (sub)) {
return 1;
}
/* this function cannot be used to swap/reorder processors */
if (find (_processors.begin(), _processors.end(), sub) != _processors.end ()) {
return 1;
}
if (!AudioEngine::instance()->connected() || !old || !sub) {
return 1;
}
/* ensure that sub is not owned by another route */
if (sub->owner ()) {
return 1;
}
{
Glib::Threads::Mutex::Lock lx (AudioEngine::instance()->process_lock ());
Glib::Threads::RWLock::WriterLock lm (_processor_lock);
ProcessorState pstate (this);
assert (find (_processors.begin(), _processors.end(), sub) == _processors.end ());
ProcessorList::iterator i;
bool replaced = false;
bool enable = old->active ();
for (i = _processors.begin(); i != _processors.end(); ) {
if (*i == old) {
i = _processors.erase (i);
_processors.insert (i, sub);
sub->set_owner (this);
replaced = true;
break;
} else {
++i;
}
}
if (!replaced) {
return 1;
}
if (_strict_io) {
boost::shared_ptr<PluginInsert> pi;
if ((pi = boost::dynamic_pointer_cast<PluginInsert>(sub)) != 0) {
pi->set_strict_io (true);
}
}
if (configure_processors_unlocked (err)) {
pstate.restore ();
configure_processors_unlocked (0);
return -1;
}
_have_internal_generator = false;
for (i = _processors.begin(); i != _processors.end(); ++i) {
boost::shared_ptr<PluginInsert> pi;
if ((pi = boost::dynamic_pointer_cast<PluginInsert>(*i)) != 0) {
if (pi->has_no_inputs ()) {
_have_internal_generator = true;
break;
}
}
}
if (enable) {
sub->activate ();
}
sub->ActiveChanged.connect_same_thread (*this, boost::bind (&Session::update_latency_compensation, &_session, false));
_output->set_user_latency (0);
}
reset_instrument_info ();
old->drop_references ();
processors_changed (RouteProcessorChange ()); /* EMIT SIGNAL */
set_processor_positions ();
return 0;
}
int
Route::remove_processors (const ProcessorList& to_be_deleted, ProcessorStreams* err)
{
ProcessorList deleted;
if (!_session.engine().connected()) {
return 1;
}
processor_max_streams.reset();
{
Glib::Threads::Mutex::Lock lx (AudioEngine::instance()->process_lock ());
Glib::Threads::RWLock::WriterLock lm (_processor_lock);
ProcessorState pstate (this);
ProcessorList::iterator i;
boost::shared_ptr<Processor> processor;
for (i = _processors.begin(); i != _processors.end(); ) {
processor = *i;
/* these can never be removed */
if (processor == _amp || processor == _meter || processor == _main_outs || processor == _delayline || processor == _trim) {
++i;
continue;
}
/* see if its in the list of processors to delete */
if (find (to_be_deleted.begin(), to_be_deleted.end(), processor) == to_be_deleted.end()) {
++i;
continue;
}
/* stop IOProcessors that send to JACK ports
from causing noise as a result of no longer being
run.
*/
boost::shared_ptr<IOProcessor> iop = boost::dynamic_pointer_cast<IOProcessor>(processor);
boost::shared_ptr<PluginInsert> pi = boost::dynamic_pointer_cast<PluginInsert>(processor);
if (pi != 0) {
assert (iop == 0);
iop = pi->sidechain();
}
if (iop != 0) {
iop->disconnect ();
}
deleted.push_back (processor);
i = _processors.erase (i);
}
if (deleted.empty()) {
/* none of those in the requested list were found */
return 0;
}
_output->set_user_latency (0);
if (configure_processors_unlocked (err)) {
pstate.restore ();
/* we know this will work, because it worked before :) */
configure_processors_unlocked (0);
return -1;
}
//lx.unlock();
_have_internal_generator = false;
for (i = _processors.begin(); i != _processors.end(); ++i) {
boost::shared_ptr<PluginInsert> pi;
if ((pi = boost::dynamic_pointer_cast<PluginInsert>(*i)) != 0) {
if (pi->has_no_inputs ()) {
_have_internal_generator = true;
break;
}
}
}
}
/* now try to do what we need to so that those that were removed will be deleted */
for (ProcessorList::iterator i = deleted.begin(); i != deleted.end(); ++i) {
(*i)->drop_references ();
}
reset_instrument_info ();
processors_changed (RouteProcessorChange ()); /* EMIT SIGNAL */
set_processor_positions ();
return 0;
}
void
Route::reset_instrument_info ()
{
boost::shared_ptr<Processor> instr = the_instrument();
if (instr) {
_instrument_info.set_internal_instrument (instr);
}
}
/** Caller must hold process lock */
int
Route::configure_processors (ProcessorStreams* err)
{
#ifndef PLATFORM_WINDOWS
assert (!AudioEngine::instance()->process_lock().trylock());
#endif
if (!_in_configure_processors) {
Glib::Threads::RWLock::WriterLock lm (_processor_lock);
return configure_processors_unlocked (err);
}
return 0;
}
ChanCount
Route::input_streams () const
{
return _input->n_ports ();
}
list<pair<ChanCount, ChanCount> >
Route::try_configure_processors (ChanCount in, ProcessorStreams* err)
{
Glib::Threads::RWLock::ReaderLock lm (_processor_lock);
return try_configure_processors_unlocked (in, err);
}
list<pair<ChanCount, ChanCount> >
Route::try_configure_processors_unlocked (ChanCount in, ProcessorStreams* err)
{
// Check each processor in order to see if we can configure as requested
ChanCount out;
list<pair<ChanCount, ChanCount> > configuration;
uint32_t index = 0;
DEBUG_TRACE (DEBUG::Processors, string_compose ("%1: configure processors\n", _name));
DEBUG_TRACE (DEBUG::Processors, "{\n");
for (ProcessorList::iterator p = _processors.begin(); p != _processors.end(); ++p, ++index) {
if ((*p)->can_support_io_configuration(in, out)) {
if (boost::dynamic_pointer_cast<Delivery> (*p)
&& boost::dynamic_pointer_cast<Delivery> (*p)->role() == Delivery::Main
&& !(is_monitor() || is_auditioner())
&& ( _strict_io || Profile->get_mixbus ())) {
/* with strict I/O the panner + output are forced to
* follow the last processor's output.
*
* Delivery::can_support_io_configuration() will only add ports,
* but not remove excess ports.
*
* This works because the delivery only requires
* as many outputs as there are inputs.
* Delivery::configure_io() will do the actual removal
* by calling _output->ensure_io()
*/
if (!is_master() && _session.master_out ()) {
/* ..but at least as many as there are master-inputs */
// XXX this may need special-casing for mixbus (master-outputs)
// and should maybe be a preference anyway ?!
out = ChanCount::max (in, _session.master_out ()->n_inputs ());
} else {
out = in;
}
}
DEBUG_TRACE (DEBUG::Processors, string_compose ("\t%1 ID=%2 in=%3 out=%4\n",(*p)->name(), (*p)->id(), in, out));
configuration.push_back(make_pair(in, out));
if (is_monitor()) {
// restriction for Monitor Section Processors
if (in.n_audio() != out.n_audio() || out.n_midi() > 0) {
/* do not allow to add/remove channels (for now)
* The Monitor follows the master-bus and has no panner (unpan)
* but do allow processors with midi-in to be added (e.g VSTs with control that
* will remain unconnected)
*/
DEBUG_TRACE (DEBUG::Processors, "Monitor: Channel configuration not allowed.\n");
return list<pair<ChanCount, ChanCount> > ();
}
if (boost::dynamic_pointer_cast<InternalSend> (*p)) {
// internal sends make no sense, only feedback
DEBUG_TRACE (DEBUG::Processors, "Monitor: No Sends allowed.\n");
return list<pair<ChanCount, ChanCount> > ();
}
if (boost::dynamic_pointer_cast<PortInsert> (*p)) {
/* External Sends can be problematic. one can add/remove ports
* there signal leaves the DAW to external monitors anyway, so there's
* no real use for allowing them here anyway.
*/
DEBUG_TRACE (DEBUG::Processors, "Monitor: No External Sends allowed.\n");
return list<pair<ChanCount, ChanCount> > ();
}
if (boost::dynamic_pointer_cast<Send> (*p)) {
// ditto
DEBUG_TRACE (DEBUG::Processors, "Monitor: No Sends allowed.\n");
return list<pair<ChanCount, ChanCount> > ();
}
}
in = out;
} else {
if (err) {
err->index = index;
err->count = in;
}
DEBUG_TRACE (DEBUG::Processors, "---- CONFIGURATION FAILED.\n");
DEBUG_TRACE (DEBUG::Processors, string_compose ("---- %1 cannot support in=%2 out=%3\n", (*p)->name(), in, out));
DEBUG_TRACE (DEBUG::Processors, "}\n");
return list<pair<ChanCount, ChanCount> > ();
}
}
DEBUG_TRACE (DEBUG::Processors, "}\n");
return configuration;
}
/** Set the input/output configuration of each processor in the processors list.
* Caller must hold process lock.
* Return 0 on success, otherwise configuration is impossible.
*/
int
Route::configure_processors_unlocked (ProcessorStreams* err)
{
#ifndef PLATFORM_WINDOWS
assert (!AudioEngine::instance()->process_lock().trylock());
#endif
if (_in_configure_processors) {
return 0;
}
/* put invisible processors where they should be */
setup_invisible_processors ();
_in_configure_processors = true;
list<pair<ChanCount, ChanCount> > configuration = try_configure_processors_unlocked (input_streams (), err);
if (configuration.empty ()) {
_in_configure_processors = false;
return -1;
}
ChanCount out;
bool seen_mains_out = false;
processor_out_streams = _input->n_ports();
processor_max_streams.reset();
list< pair<ChanCount,ChanCount> >::iterator c = configuration.begin();
for (ProcessorList::iterator p = _processors.begin(); p != _processors.end(); ++p, ++c) {
if (!(*p)->configure_io(c->first, c->second)) {
DEBUG_TRACE (DEBUG::Processors, string_compose ("%1: configuration failed\n", _name));
_in_configure_processors = false;
return -1;
}
processor_max_streams = ChanCount::max(processor_max_streams, c->first);
processor_max_streams = ChanCount::max(processor_max_streams, c->second);
boost::shared_ptr<IOProcessor> iop;
boost::shared_ptr<PluginInsert> pi;
if ((pi = boost::dynamic_pointer_cast<PluginInsert>(*p)) != 0) {
/* plugins connected via Split or Hide Match may have more channels.
* route/scratch buffers are needed for all of them
* The configuration may only be a subset (both input and output)
*/
processor_max_streams = ChanCount::max(processor_max_streams, pi->required_buffers());
}
else if ((iop = boost::dynamic_pointer_cast<IOProcessor>(*p)) != 0) {
processor_max_streams = ChanCount::max(processor_max_streams, iop->natural_input_streams());
processor_max_streams = ChanCount::max(processor_max_streams, iop->natural_output_streams());
}
out = c->second;
if (boost::dynamic_pointer_cast<Delivery> (*p)
&& boost::dynamic_pointer_cast<Delivery> (*p)->role() == Delivery::Main) {
/* main delivery will increase port count to match input.
* the Delivery::Main is usually the last processor - followed only by
* 'MeterOutput'.
*/
seen_mains_out = true;
}
if (!seen_mains_out) {
processor_out_streams = out;
}
}
if (_meter) {
_meter->set_max_channels (processor_max_streams);
}
/* make sure we have sufficient scratch buffers to cope with the new processor
configuration
*/
_session.ensure_buffers (n_process_buffers ());
DEBUG_TRACE (DEBUG::Processors, string_compose ("%1: configuration complete\n", _name));
_in_configure_processors = false;
return 0;
}
/** Set all visible processors to a given active state (except Fader, whose state is not changed)
* @param state New active state for those processors.
*/
void
Route::all_visible_processors_active (bool state)
{
Glib::Threads::RWLock::ReaderLock lm (_processor_lock);
if (_processors.empty()) {
return;
}
for (ProcessorList::iterator i = _processors.begin(); i != _processors.end(); ++i) {
if (!(*i)->display_to_user() || boost::dynamic_pointer_cast<Amp> (*i)) {
continue;
}
if (state) {
(*i)->activate ();
} else {
(*i)->deactivate ();
}
}
_session.set_dirty ();
}
bool
Route::processors_reorder_needs_configure (const ProcessorList& new_order)
{
/* check if re-order requires re-configuration of any processors
* -> compare channel configuration for all processors
*/
Glib::Threads::RWLock::ReaderLock lm (_processor_lock);
ChanCount c = input_streams ();
for (ProcessorList::const_iterator j = new_order.begin(); j != new_order.end(); ++j) {
bool found = false;
if (c != (*j)->input_streams()) {
return true;
}
for (ProcessorList::const_iterator i = _processors.begin(); i != _processors.end(); ++i) {
if (*i == *j) {
found = true;
if ((*i)->input_streams() != c) {
return true;
}
c = (*i)->output_streams();
break;
}
}
if (!found) {
return true;
}
}
return false;
}
#ifdef __clang__
__attribute__((annotate("realtime")))
#endif
void
Route::apply_processor_order (const ProcessorList& new_order)
{
/* need to hold processor_lock; either read or write lock
* and the engine process_lock.
* Due to r/w lock ambiguity we can only assert the latter
*/
assert (!AudioEngine::instance()->process_lock().trylock());
/* "new_order" is an ordered list of processors to be positioned according to "placement".
* NOTE: all processors in "new_order" MUST be marked as display_to_user(). There maybe additional
* processors in the current actual processor list that are hidden. Any visible processors
* in the current list but not in "new_order" will be assumed to be deleted.
*/
/* "as_it_will_be" and "_processors" are lists of shared pointers.
* actual memory usage is small, but insert/erase is not actually rt-safe :(
* (note though that ::processors_reorder_needs_configure() ensured that
* this function will only ever be called from the rt-thread if no processor were removed)
*
* either way, I can't proove it, but an x-run due to re-order here is less likley
* than an x-run-less 'ardour-silent cycle' both of which effectively "click".
*/
ProcessorList as_it_will_be;
ProcessorList::iterator oiter;
ProcessorList::const_iterator niter;
oiter = _processors.begin();
niter = new_order.begin();
while (niter != new_order.end()) {
/* if the next processor in the old list is invisible (i.e. should not be in the new order)
then append it to the temp list.
Otherwise, see if the next processor in the old list is in the new list. if not,
its been deleted. If its there, append it to the temp list.
*/
if (oiter == _processors.end()) {
/* no more elements in the old list, so just stick the rest of
the new order onto the temp list.
*/
as_it_will_be.insert (as_it_will_be.end(), niter, new_order.end());
while (niter != new_order.end()) {
++niter;
}
break;
} else {
if (!(*oiter)->display_to_user()) {
as_it_will_be.push_back (*oiter);
} else {
/* visible processor: check that its in the new order */
if (find (new_order.begin(), new_order.end(), (*oiter)) == new_order.end()) {
/* deleted: do nothing, shared_ptr<> will clean up */
} else {
/* ignore this one, and add the next item from the new order instead */
as_it_will_be.push_back (*niter);
++niter;
}
}
/* now remove from old order - its taken care of no matter what */
oiter = _processors.erase (oiter);
}
}
_processors.insert (oiter, as_it_will_be.begin(), as_it_will_be.end());
/* If the meter is in a custom position, find it and make a rough note of its position */
maybe_note_meter_position ();
}
int
Route::reorder_processors (const ProcessorList& new_order, ProcessorStreams* err)
{
// it a change is already queued, wait for it
// (unless engine is stopped. apply immediately and proceed
while (g_atomic_int_get (&_pending_process_reorder)) {
if (!AudioEngine::instance()->running()) {
DEBUG_TRACE (DEBUG::Processors, "offline apply queued processor re-order.\n");
Glib::Threads::RWLock::WriterLock lm (_processor_lock);
apply_processor_order(_pending_processor_order);
setup_invisible_processors ();
g_atomic_int_set (&_pending_process_reorder, 0);
processors_changed (RouteProcessorChange ()); /* EMIT SIGNAL */
set_processor_positions ();
} else {
// TODO rather use a semaphore or something.
// but since ::reorder_processors() is called
// from the GUI thread, this is fine..
Glib::usleep(500);
}
}
if (processors_reorder_needs_configure (new_order) || !AudioEngine::instance()->running()) {
Glib::Threads::Mutex::Lock lx (AudioEngine::instance()->process_lock ());
Glib::Threads::RWLock::WriterLock lm (_processor_lock);
ProcessorState pstate (this);
apply_processor_order (new_order);
if (configure_processors_unlocked (err)) {
pstate.restore ();
return -1;
}
lm.release();
lx.release();
processors_changed (RouteProcessorChange ()); /* EMIT SIGNAL */
set_processor_positions ();
} else {
DEBUG_TRACE (DEBUG::Processors, "Queue clickless processor re-order.\n");
Glib::Threads::RWLock::ReaderLock lm (_processor_lock);
// _pending_processor_order is protected by _processor_lock
_pending_processor_order = new_order;
g_atomic_int_set (&_pending_process_reorder, 1);
}
return 0;
}
bool
Route::add_remove_sidechain (boost::shared_ptr<Processor> proc, bool add)
{
boost::shared_ptr<PluginInsert> pi;
if ((pi = boost::dynamic_pointer_cast<PluginInsert>(proc)) == 0) {
return false;
}
if (pi->has_sidechain () == add) {
return true; // ?? call failed, but result is as expected.
}
{
Glib::Threads::RWLock::ReaderLock lm (_processor_lock);
ProcessorList::iterator i = find (_processors.begin(), _processors.end(), proc);
if (i == _processors.end ()) {
return false;
}
}
{
Glib::Threads::Mutex::Lock lx (AudioEngine::instance()->process_lock ()); // take before Writerlock to avoid deadlock
Glib::Threads::RWLock::WriterLock lm (_processor_lock);
PBD::Unwinder<bool> uw (_in_sidechain_setup, true);
lx.release (); // IO::add_port() and ~IO takes process lock - XXX check if this is safe
if (add) {
if (!pi->add_sidechain ()) {
return false;
}
} else {
if (!pi->del_sidechain ()) {
return false;
}
}
lx.acquire ();
list<pair<ChanCount, ChanCount> > c = try_configure_processors_unlocked (n_inputs (), 0);
lx.release ();
if (c.empty()) {
if (add) {
pi->del_sidechain ();
} else {
pi->add_sidechain ();
// TODO restore side-chain's state.
}
return false;
}
lx.acquire ();
configure_processors_unlocked (0);
}
if (pi->has_sidechain ()) {
pi->sidechain_input ()->changed.connect_same_thread (*this, boost::bind (&Route::sidechain_change_handler, this, _1, _2));
}
processors_changed (RouteProcessorChange ()); /* EMIT SIGNAL */
_session.set_dirty ();
return true;
}
bool
Route::plugin_preset_output (boost::shared_ptr<Processor> proc, ChanCount outs)
{
boost::shared_ptr<PluginInsert> pi;
if ((pi = boost::dynamic_pointer_cast<PluginInsert>(proc)) == 0) {
return false;
}
{
Glib::Threads::RWLock::ReaderLock lm (_processor_lock);
ProcessorList::iterator i = find (_processors.begin(), _processors.end(), proc);
if (i == _processors.end ()) {
return false;
}
}
{
Glib::Threads::Mutex::Lock lx (AudioEngine::instance()->process_lock ());
Glib::Threads::RWLock::WriterLock lm (_processor_lock);
const ChanCount& old (pi->preset_out ());
if (!pi->set_preset_out (outs)) {
return true; // no change, OK
}
list<pair<ChanCount, ChanCount> > c = try_configure_processors_unlocked (n_inputs (), 0);
if (c.empty()) {
/* not possible */
pi->set_preset_out (old);
return false;
}
configure_processors_unlocked (0);
}
processors_changed (RouteProcessorChange ()); /* EMIT SIGNAL */
_session.set_dirty ();
return true;
}
bool
Route::reset_plugin_insert (boost::shared_ptr<Processor> proc)
{
ChanCount unused;
return customize_plugin_insert (proc, 0, unused);
}
bool
Route::customize_plugin_insert (boost::shared_ptr<Processor> proc, uint32_t count, ChanCount outs)
{
boost::shared_ptr<PluginInsert> pi;
if ((pi = boost::dynamic_pointer_cast<PluginInsert>(proc)) == 0) {
return false;
}
{
Glib::Threads::RWLock::ReaderLock lm (_processor_lock);
ProcessorList::iterator i = find (_processors.begin(), _processors.end(), proc);
if (i == _processors.end ()) {
return false;
}
}
{
Glib::Threads::Mutex::Lock lx (AudioEngine::instance()->process_lock ());
Glib::Threads::RWLock::WriterLock lm (_processor_lock);
bool old_cust = pi->custom_cfg ();
uint32_t old_cnt = pi->get_count ();
ChanCount old_chan = pi->output_streams ();
if (count == 0) {
pi->set_custom_cfg (false);
} else {
pi->set_custom_cfg (true);
pi->set_count (count);
pi->set_outputs (outs);
}
list<pair<ChanCount, ChanCount> > c = try_configure_processors_unlocked (n_inputs (), 0);
if (c.empty()) {
/* not possible */
pi->set_count (old_cnt);
pi->set_outputs (old_chan);
pi->set_custom_cfg (old_cust);
return false;
}
configure_processors_unlocked (0);
}
processors_changed (RouteProcessorChange ()); /* EMIT SIGNAL */
_session.set_dirty ();
return true;
}
bool
Route::set_strict_io (const bool enable)
{
Glib::Threads::Mutex::Lock lx (AudioEngine::instance()->process_lock ());
if (_strict_io != enable) {
_strict_io = enable;
Glib::Threads::RWLock::ReaderLock lm (_processor_lock);
for (ProcessorList::iterator p = _processors.begin(); p != _processors.end(); ++p) {
boost::shared_ptr<PluginInsert> pi;
if ((pi = boost::dynamic_pointer_cast<PluginInsert>(*p)) != 0) {
pi->set_strict_io (_strict_io);
}
}
list<pair<ChanCount, ChanCount> > c = try_configure_processors_unlocked (n_inputs (), 0);
if (c.empty()) {
// not possible
_strict_io = !enable; // restore old value
for (ProcessorList::iterator p = _processors.begin(); p != _processors.end(); ++p) {
boost::shared_ptr<PluginInsert> pi;
if ((pi = boost::dynamic_pointer_cast<PluginInsert>(*p)) != 0) {
pi->set_strict_io (_strict_io);
}
}
return false;
}
lm.release ();
configure_processors (0);
lx.release ();
processors_changed (RouteProcessorChange ()); /* EMIT SIGNAL */
_session.set_dirty ();
}
return true;
}
XMLNode&
Route::get_state()
{
return state(true);
}
XMLNode&
Route::get_template()
{
return state(false);
}
XMLNode&
Route::state(bool full_state)
{
if (!_session._template_state_dir.empty()) {
assert (!full_state); // only for templates
foreach_processor (sigc::bind (sigc::mem_fun (*this, &Route::set_plugin_state_dir), _session._template_state_dir));
}
XMLNode *node = new XMLNode("Route");
ProcessorList::iterator i;
char buf[32];
id().print (buf, sizeof (buf));
node->add_property("id", buf);
node->add_property ("name", _name);
node->add_property("default-type", _default_type.to_string());
node->add_property ("strict-io", _strict_io);
if (_flags) {
node->add_property("flags", enum_2_string (_flags));
}
node->add_property("active", _active?"yes":"no");
string p;
boost::to_string (_phase_invert, p);
node->add_property("phase-invert", p);
node->add_property("denormal-protection", _denormal_protection?"yes":"no");
node->add_property("meter-point", enum_2_string (_meter_point));
node->add_property("meter-type", enum_2_string (_meter_type));
if (_route_group) {
node->add_property("route-group", _route_group->name());
}
snprintf (buf, sizeof (buf), "%d", _order_key);
node->add_property ("order-key", buf);
node->add_property ("self-solo", (_self_solo ? "yes" : "no"));
snprintf (buf, sizeof (buf), "%d", _soloed_by_others_upstream);
node->add_property ("soloed-by-upstream", buf);
snprintf (buf, sizeof (buf), "%d", _soloed_by_others_downstream);
node->add_property ("soloed-by-downstream", buf);
node->add_property ("solo-isolated", solo_isolated() ? "yes" : "no");
node->add_property ("solo-safe", _solo_safe ? "yes" : "no");
node->add_child_nocopy (_input->state (full_state));
node->add_child_nocopy (_output->state (full_state));
node->add_child_nocopy (_solo_control->get_state ());
node->add_child_nocopy (_mute_control->get_state ());
node->add_child_nocopy (_mute_master->get_state ());
if (full_state) {
node->add_child_nocopy (Automatable::get_automation_xml_state ());
}
XMLNode* remote_control_node = new XMLNode (X_("RemoteControl"));
snprintf (buf, sizeof (buf), "%d", _remote_control_id);
remote_control_node->add_property (X_("id"), buf);
node->add_child_nocopy (*remote_control_node);
if (_comment.length()) {
XMLNode *cmt = node->add_child ("Comment");
cmt->add_content (_comment);
}
if (_pannable) {
node->add_child_nocopy (_pannable->state (full_state));
}
for (i = _processors.begin(); i != _processors.end(); ++i) {
if (!full_state) {
/* template save: do not include internal sends functioning as
aux sends because the chance of the target ID
in the session where this template is used
is not very likely.
similarly, do not save listen sends which connect to
the monitor section, because these will always be
added if necessary.
*/
boost::shared_ptr<InternalSend> is;
if ((is = boost::dynamic_pointer_cast<InternalSend> (*i)) != 0) {
if (is->role() == Delivery::Listen) {
continue;
}
}
}
node->add_child_nocopy((*i)->state (full_state));
}
if (_extra_xml) {
node->add_child_copy (*_extra_xml);
}
if (_custom_meter_position_noted) {
boost::shared_ptr<Processor> after = _processor_after_last_custom_meter.lock ();
if (after) {
after->id().print (buf, sizeof (buf));
node->add_property (X_("processor-after-last-custom-meter"), buf);
}
}
if (!_session._template_state_dir.empty()) {
foreach_processor (sigc::bind (sigc::mem_fun (*this, &Route::set_plugin_state_dir), ""));
}
return *node;
}
int
Route::set_state (const XMLNode& node, int version)
{
if (version < 3000) {
return set_state_2X (node, version);
}
XMLNodeList nlist;
XMLNodeConstIterator niter;
XMLNode *child;
const XMLProperty *prop;
if (node.name() != "Route"){
error << string_compose(_("Bad node sent to Route::set_state() [%1]"), node.name()) << endmsg;
return -1;
}
if ((prop = node.property (X_("name"))) != 0) {
Route::set_name (prop->value());
}
set_id (node);
_initial_io_setup = true;
if ((prop = node.property (X_("flags"))) != 0) {
_flags = Flag (string_2_enum (prop->value(), _flags));
} else {
_flags = Flag (0);
}
if ((prop = node.property (X_("strict-io"))) != 0) {
_strict_io = string_is_affirmative (prop->value());
}
if (is_master() || is_monitor() || is_auditioner()) {
_mute_master->set_solo_ignore (true);
}
if (is_monitor()) {
/* monitor bus does not get a panner, but if (re)created
via XML, it will already have one by the time we
call ::set_state(). so ... remove it.
*/
unpan ();
}
/* add all processors (except amp, which is always present) */
nlist = node.children();
XMLNode processor_state (X_("processor_state"));
Stateful::save_extra_xml (node);
for (niter = nlist.begin(); niter != nlist.end(); ++niter){
child = *niter;
if (child->name() == IO::state_node_name) {
if ((prop = child->property (X_("direction"))) == 0) {
continue;
}
if (prop->value() == "Input") {
_input->set_state (*child, version);
} else if (prop->value() == "Output") {
_output->set_state (*child, version);
}
}
if (child->name() == X_("Processor")) {
processor_state.add_child_copy (*child);
}
if (child->name() == X_("Pannable")) {
if (_pannable) {
_pannable->set_state (*child, version);
} else {
warning << string_compose (_("Pannable state found for route (%1) without a panner!"), name()) << endmsg;
}
}
}
if ((prop = node.property (X_("meter-point"))) != 0) {
MeterPoint mp = MeterPoint (string_2_enum (prop->value (), _meter_point));
set_meter_point (mp, true);
if (_meter) {
_meter->set_display_to_user (_meter_point == MeterCustom);
}
}
if ((prop = node.property (X_("meter-type"))) != 0) {
_meter_type = MeterType (string_2_enum (prop->value (), _meter_type));
}
_initial_io_setup = false;
set_processor_state (processor_state);
// this looks up the internal instrument in processors
reset_instrument_info();
if ((prop = node.property ("self-solo")) != 0) {
set_self_solo (string_is_affirmative (prop->value()));
}
if ((prop = node.property ("soloed-by-upstream")) != 0) {
_soloed_by_others_upstream = 0; // needed for mod_.... () to work
mod_solo_by_others_upstream (atoi (prop->value()));
}
if ((prop = node.property ("soloed-by-downstream")) != 0) {
_soloed_by_others_downstream = 0; // needed for mod_.... () to work
mod_solo_by_others_downstream (atoi (prop->value()));
}
if ((prop = node.property ("solo-isolated")) != 0) {
set_solo_isolated (string_is_affirmative (prop->value()), Controllable::NoGroup);
}
if ((prop = node.property ("solo-safe")) != 0) {
set_solo_safe (string_is_affirmative (prop->value()), Controllable::NoGroup);
}
if ((prop = node.property (X_("phase-invert"))) != 0) {
set_phase_invert (boost::dynamic_bitset<> (prop->value ()));
}
if ((prop = node.property (X_("denormal-protection"))) != 0) {
set_denormal_protection (string_is_affirmative (prop->value()));
}
if ((prop = node.property (X_("active"))) != 0) {
bool yn = string_is_affirmative (prop->value());
_active = !yn; // force switch
set_active (yn, this);
}
if ((prop = node.property (X_("order-key"))) != 0) { // New order key (no separate mixer/editor ordering)
set_order_key (atoi(prop->value()));
}
if ((prop = node.property (X_("order-keys"))) != 0) { // Deprecated order keys
int32_t n;
string::size_type colon, equal;
string remaining = prop->value();
while (remaining.length()) {
if ((equal = remaining.find_first_of ('=')) == string::npos || equal == remaining.length()) {
error << string_compose (_("badly formed order key string in state file! [%1] ... ignored."), remaining)
<< endmsg;
} else {
if (sscanf (remaining.substr (equal+1).c_str(), "%d", &n) != 1) {
error << string_compose (_("badly formed order key string in state file! [%1] ... ignored."), remaining)
<< endmsg;
} else {
string keyname = remaining.substr (0, equal);
if ((keyname == "EditorSort") || (keyname == "editor")) {
cerr << "Setting " << name() << " order key to " << n << " using saved Editor order." << endl;
set_order_key (n);
}
}
}
colon = remaining.find_first_of (':');
if (colon != string::npos) {
remaining = remaining.substr (colon+1);
} else {
break;
}
}
}
if ((prop = node.property (X_("processor-after-last-custom-meter"))) != 0) {
PBD::ID id (prop->value ());
Glib::Threads::RWLock::ReaderLock lm (_processor_lock);
ProcessorList::const_iterator i = _processors.begin ();
while (i != _processors.end() && (*i)->id() != id) {
++i;
}
if (i != _processors.end ()) {
_processor_after_last_custom_meter = *i;
_custom_meter_position_noted = true;
}
}
for (niter = nlist.begin(); niter != nlist.end(); ++niter){
child = *niter;
if (child->name() == X_("Comment")) {
/* XXX this is a terrible API design in libxml++ */
XMLNode *cmt = *(child->children().begin());
_comment = cmt->content();
} else if (child->name() == Controllable::xml_node_name && (prop = child->property("name")) != 0) {
if (prop->value() == "solo") {
_solo_control->set_state (*child, version);
} else if (prop->value() == "mute") {
_mute_control->set_state (*child, version);
}
} else if (child->name() == X_("RemoteControl")) {
if ((prop = child->property (X_("id"))) != 0) {
int32_t x;
sscanf (prop->value().c_str(), "%d", &x);
set_remote_control_id_internal (x);
}
} else if (child->name() == X_("MuteMaster")) {
_mute_master->set_state (*child, version);
} else if (child->name() == Automatable::xml_node_name) {
set_automation_xml_state (*child, Evoral::Parameter(NullAutomation));
}
}
return 0;
}
int
Route::set_state_2X (const XMLNode& node, int version)
{
LocaleGuard lg (X_("C"));
XMLNodeList nlist;
XMLNodeConstIterator niter;
XMLNode *child;
const XMLProperty *prop;
/* 2X things which still remain to be handled:
* default-type
* automation
* controlouts
*/
if (node.name() != "Route") {
error << string_compose(_("Bad node sent to Route::set_state() [%1]"), node.name()) << endmsg;
return -1;
}
if ((prop = node.property (X_("flags"))) != 0) {
string f = prop->value ();
boost::replace_all (f, "ControlOut", "MonitorOut");
_flags = Flag (string_2_enum (f, _flags));
} else {
_flags = Flag (0);
}
if (is_master() || is_monitor() || is_auditioner()) {
_mute_master->set_solo_ignore (true);
}
if ((prop = node.property (X_("phase-invert"))) != 0) {
boost::dynamic_bitset<> p (_input->n_ports().n_audio ());
if (string_is_affirmative (prop->value ())) {
p.set ();
}
set_phase_invert (p);
}
if ((prop = node.property (X_("denormal-protection"))) != 0) {
set_denormal_protection (string_is_affirmative (prop->value()));
}
if ((prop = node.property (X_("soloed"))) != 0) {
bool yn = string_is_affirmative (prop->value());
/* XXX force reset of solo status */
set_solo (yn);
}
if ((prop = node.property (X_("muted"))) != 0) {
bool first = true;
bool muted = string_is_affirmative (prop->value());
if (muted) {
string mute_point;
if ((prop = node.property (X_("mute-affects-pre-fader"))) != 0) {
if (string_is_affirmative (prop->value())){
mute_point = mute_point + "PreFader";
first = false;
}
}
if ((prop = node.property (X_("mute-affects-post-fader"))) != 0) {
if (string_is_affirmative (prop->value())){
if (!first) {
mute_point = mute_point + ",";
}
mute_point = mute_point + "PostFader";
first = false;
}
}
if ((prop = node.property (X_("mute-affects-control-outs"))) != 0) {
if (string_is_affirmative (prop->value())){
if (!first) {
mute_point = mute_point + ",";
}
mute_point = mute_point + "Listen";
first = false;
}
}
if ((prop = node.property (X_("mute-affects-main-outs"))) != 0) {
if (string_is_affirmative (prop->value())){
if (!first) {
mute_point = mute_point + ",";
}
mute_point = mute_point + "Main";
}
}
_mute_master->set_mute_points (mute_point);
_mute_master->set_muted_by_self (true);
}
}
if ((prop = node.property (X_("meter-point"))) != 0) {
_meter_point = MeterPoint (string_2_enum (prop->value (), _meter_point));
}
/* do not carry over edit/mix groups from 2.X because (a) its hard (b) they
don't mean the same thing.
*/
if ((prop = node.property (X_("order-keys"))) != 0) {
int32_t n;
string::size_type colon, equal;
string remaining = prop->value();
while (remaining.length()) {
if ((equal = remaining.find_first_of ('=')) == string::npos || equal == remaining.length()) {
error << string_compose (_("badly formed order key string in state file! [%1] ... ignored."), remaining)
<< endmsg;
} else {
if (sscanf (remaining.substr (equal+1).c_str(), "%d", &n) != 1) {
error << string_compose (_("badly formed order key string in state file! [%1] ... ignored."), remaining)
<< endmsg;
} else {
string keyname = remaining.substr (0, equal);
if (keyname == "EditorSort" || keyname == "editor") {
info << string_compose(_("Converting deprecated order key for %1 using Editor order %2"), name (), n) << endmsg;
set_order_key (n);
}
}
}
colon = remaining.find_first_of (':');
if (colon != string::npos) {
remaining = remaining.substr (colon+1);
} else {
break;
}
}
}
/* IOs */
nlist = node.children ();
for (niter = nlist.begin(); niter != nlist.end(); ++niter) {
child = *niter;
if (child->name() == IO::state_node_name) {
/* there is a note in IO::set_state_2X() about why we have to call
this directly.
*/
_input->set_state_2X (*child, version, true);
_output->set_state_2X (*child, version, false);
if ((prop = child->property (X_("name"))) != 0) {
Route::set_name (prop->value ());
}
set_id (*child);
if ((prop = child->property (X_("active"))) != 0) {
bool yn = string_is_affirmative (prop->value());
_active = !yn; // force switch
set_active (yn, this);
}
if ((prop = child->property (X_("gain"))) != 0) {
gain_t val;
if (sscanf (prop->value().c_str(), "%f", &val) == 1) {
_amp->gain_control()->set_value (val, Controllable::NoGroup);
}
}
/* Set up Panners in the IO */
XMLNodeList io_nlist = child->children ();
XMLNodeConstIterator io_niter;
XMLNode *io_child;
for (io_niter = io_nlist.begin(); io_niter != io_nlist.end(); ++io_niter) {
io_child = *io_niter;
if (io_child->name() == X_("Panner")) {
_main_outs->panner_shell()->set_state(*io_child, version);
} else if (io_child->name() == X_("Automation")) {
/* IO's automation is for the fader */
_amp->set_automation_xml_state (*io_child, Evoral::Parameter (GainAutomation));
}
}
}
}
XMLNodeList redirect_nodes;
for (niter = nlist.begin(); niter != nlist.end(); ++niter){
child = *niter;
if (child->name() == X_("Send") || child->name() == X_("Insert")) {
redirect_nodes.push_back(child);
}
}
set_processor_state_2X (redirect_nodes, version);
Stateful::save_extra_xml (node);
for (niter = nlist.begin(); niter != nlist.end(); ++niter){
child = *niter;
if (child->name() == X_("Comment")) {
/* XXX this is a terrible API design in libxml++ */
XMLNode *cmt = *(child->children().begin());
_comment = cmt->content();
} else if (child->name() == Controllable::xml_node_name && (prop = child->property("name")) != 0) {
if (prop->value() == X_("solo")) {
_solo_control->set_state (*child, version);
} else if (prop->value() == X_("mute")) {
_mute_control->set_state (*child, version);
}
} else if (child->name() == X_("RemoteControl")) {
if ((prop = child->property (X_("id"))) != 0) {
int32_t x;
sscanf (prop->value().c_str(), "%d", &x);
set_remote_control_id_internal (x);
}
}
}
return 0;
}
XMLNode&
Route::get_processor_state ()
{
XMLNode* root = new XMLNode (X_("redirects"));
for (ProcessorList::iterator i = _processors.begin(); i != _processors.end(); ++i) {
root->add_child_nocopy ((*i)->state (true));
}
return *root;
}
void
Route::set_processor_state_2X (XMLNodeList const & nList, int version)
{
/* We don't bother removing existing processors not in nList, as this
method will only be called when creating a Route from scratch, not
for undo purposes. Just put processors in at the appropriate place
in the list.
*/
for (XMLNodeConstIterator i = nList.begin(); i != nList.end(); ++i) {
add_processor_from_xml_2X (**i, version);
}
}
void
Route::set_processor_state (const XMLNode& node)
{
const XMLNodeList &nlist = node.children();
XMLNodeConstIterator niter;
ProcessorList new_order;
bool must_configure = false;
for (niter = nlist.begin(); niter != nlist.end(); ++niter) {
XMLProperty* prop = (*niter)->property ("type");
if (prop->value() == "amp") {
_amp->set_state (**niter, Stateful::current_state_version);
new_order.push_back (_amp);
} else if (prop->value() == "trim") {
_trim->set_state (**niter, Stateful::current_state_version);
new_order.push_back (_trim);
} else if (prop->value() == "meter") {
_meter->set_state (**niter, Stateful::current_state_version);
new_order.push_back (_meter);
} else if (prop->value() == "delay") {
if (_delayline) {
_delayline->set_state (**niter, Stateful::current_state_version);
new_order.push_back (_delayline);
}
} else if (prop->value() == "main-outs") {
_main_outs->set_state (**niter, Stateful::current_state_version);
} else if (prop->value() == "intreturn") {
if (!_intreturn) {
_intreturn.reset (new InternalReturn (_session));
must_configure = true;
}
_intreturn->set_state (**niter, Stateful::current_state_version);
} else if (is_monitor() && prop->value() == "monitor") {
if (!_monitor_control) {
_monitor_control.reset (new MonitorProcessor (_session));
must_configure = true;
}
_monitor_control->set_state (**niter, Stateful::current_state_version);
} else if (prop->value() == "capture") {
/* CapturingProcessor should never be restored, it's always
added explicitly when needed */
} else {
ProcessorList::iterator o;
for (o = _processors.begin(); o != _processors.end(); ++o) {
XMLProperty* id_prop = (*niter)->property(X_("id"));
if (id_prop && (*o)->id() == id_prop->value()) {
(*o)->set_state (**niter, Stateful::current_state_version);
new_order.push_back (*o);
break;
}
}
// If the processor (*niter) is not on the route then create it
if (o == _processors.end()) {
boost::shared_ptr<Processor> processor;
if (prop->value() == "intsend") {
processor.reset (new InternalSend (_session, _pannable, _mute_master, boost::dynamic_pointer_cast<ARDOUR::Route>(shared_from_this()), boost::shared_ptr<Route>(), Delivery::Aux, true));
} else if (prop->value() == "ladspa" || prop->value() == "Ladspa" ||
prop->value() == "lv2" ||
prop->value() == "windows-vst" ||
prop->value() == "lxvst" ||
prop->value() == "luaproc" ||
prop->value() == "audiounit") {
if (_session.get_disable_all_loaded_plugins ()) {
processor.reset (new UnknownProcessor (_session, **niter));
} else {
processor.reset (new PluginInsert (_session));
processor->set_owner (this);
if (_strict_io) {
boost::shared_ptr<PluginInsert> pi = boost::dynamic_pointer_cast<PluginInsert>(processor);
pi->set_strict_io (true);
}
}
} else if (prop->value() == "port") {
processor.reset (new PortInsert (_session, _pannable, _mute_master));
} else if (prop->value() == "send") {
processor.reset (new Send (_session, _pannable, _mute_master, Delivery::Send, true));
boost::shared_ptr<Send> send = boost::dynamic_pointer_cast<Send> (processor);
send->SelfDestruct.connect_same_thread (*this,
boost::bind (&Route::processor_selfdestruct, this, boost::weak_ptr<Processor> (processor)));
} else {
error << string_compose(_("unknown Processor type \"%1\"; ignored"), prop->value()) << endmsg;
continue;
}
if (processor->set_state (**niter, Stateful::current_state_version) != 0) {
/* This processor could not be configured. Turn it into a UnknownProcessor */
processor.reset (new UnknownProcessor (_session, **niter));
}
/* subscribe to Sidechain IO changes */
boost::shared_ptr<PluginInsert> pi = boost::dynamic_pointer_cast<PluginInsert> (processor);
if (pi && pi->has_sidechain ()) {
pi->sidechain_input ()->changed.connect_same_thread (*this, boost::bind (&Route::sidechain_change_handler, this, _1, _2));
}
/* we have to note the monitor send here, otherwise a new one will be created
and the state of this one will be lost.
*/
boost::shared_ptr<InternalSend> isend = boost::dynamic_pointer_cast<InternalSend> (processor);
if (isend && isend->role() == Delivery::Listen) {
_monitor_send = isend;
}
/* it doesn't matter if invisible processors are added here, as they
will be sorted out by setup_invisible_processors () shortly.
*/
new_order.push_back (processor);
must_configure = true;
}
}
}
{
Glib::Threads::Mutex::Lock lx (AudioEngine::instance()->process_lock ());
Glib::Threads::RWLock::WriterLock lm (_processor_lock);
_processors = new_order;
if (must_configure) {
configure_processors_unlocked (0);
}
for (ProcessorList::const_iterator i = _processors.begin(); i != _processors.end(); ++i) {
(*i)->set_owner (this);
(*i)->ActiveChanged.connect_same_thread (*this, boost::bind (&Session::update_latency_compensation, &_session, false));
boost::shared_ptr<PluginInsert> pi;
if ((pi = boost::dynamic_pointer_cast<PluginInsert>(*i)) != 0) {
if (pi->has_no_inputs ()) {
_have_internal_generator = true;
break;
}
}
}
}
reset_instrument_info ();
processors_changed (RouteProcessorChange ()); /* EMIT SIGNAL */
set_processor_positions ();
}
void
Route::curve_reallocate ()
{
// _gain_automation_curve.finish_resize ();
// _pan_automation_curve.finish_resize ();
}
void
Route::silence (framecnt_t nframes)
{
Glib::Threads::RWLock::ReaderLock lm (_processor_lock, Glib::Threads::TRY_LOCK);
if (!lm.locked()) {
return;
}
silence_unlocked (nframes);
}
void
Route::silence_unlocked (framecnt_t nframes)
{
/* Must be called with the processor lock held */
if (!_silent) {
_output->silence (nframes);
for (ProcessorList::iterator i = _processors.begin(); i != _processors.end(); ++i) {
boost::shared_ptr<PluginInsert> pi;
if (!_active && (pi = boost::dynamic_pointer_cast<PluginInsert> (*i)) != 0) {
// skip plugins, they don't need anything when we're not active
continue;
}
(*i)->silence (nframes);
}
if (nframes == _session.get_block_size()) {
// _silent = true;
}
}
}
void
Route::add_internal_return ()
{
if (!_intreturn) {
_intreturn.reset (new InternalReturn (_session));
add_processor (_intreturn, PreFader);
}
}
void
Route::add_send_to_internal_return (InternalSend* send)
{
Glib::Threads::RWLock::ReaderLock rm (_processor_lock);
for (ProcessorList::const_iterator x = _processors.begin(); x != _processors.end(); ++x) {
boost::shared_ptr<InternalReturn> d = boost::dynamic_pointer_cast<InternalReturn>(*x);
if (d) {
return d->add_send (send);
}
}
}
void
Route::remove_send_from_internal_return (InternalSend* send)
{
Glib::Threads::RWLock::ReaderLock rm (_processor_lock);
for (ProcessorList::const_iterator x = _processors.begin(); x != _processors.end(); ++x) {
boost::shared_ptr<InternalReturn> d = boost::dynamic_pointer_cast<InternalReturn>(*x);
if (d) {
return d->remove_send (send);
}
}
}
void
Route::enable_monitor_send ()
{
/* Caller must hold process lock */
assert (!AudioEngine::instance()->process_lock().trylock());
/* master never sends to monitor section via the normal mechanism */
assert (!is_master ());
assert (!is_monitor ());
/* make sure we have one */
if (!_monitor_send) {
_monitor_send.reset (new InternalSend (_session, _pannable, _mute_master, boost::dynamic_pointer_cast<ARDOUR::Route>(shared_from_this()), _session.monitor_out(), Delivery::Listen));
_monitor_send->set_display_to_user (false);
}
/* set it up */
configure_processors (0);
}
/** Add an aux send to a route.
* @param route route to send to.
* @param before Processor to insert before, or 0 to insert at the end.
*/
int
Route::add_aux_send (boost::shared_ptr<Route> route, boost::shared_ptr<Processor> before)
{
assert (route != _session.monitor_out ());
{
Glib::Threads::RWLock::ReaderLock rm (_processor_lock);
for (ProcessorList::iterator x = _processors.begin(); x != _processors.end(); ++x) {
boost::shared_ptr<InternalSend> d = boost::dynamic_pointer_cast<InternalSend> (*x);
if (d && d->target_route() == route) {
/* already listening via the specified IO: do nothing */
return 0;
}
}
}
try {
boost::shared_ptr<InternalSend> listener;
{
Glib::Threads::Mutex::Lock lm (AudioEngine::instance()->process_lock ());
boost::shared_ptr<Pannable> sendpan (new Pannable (_session));
listener.reset (new InternalSend (_session, sendpan, _mute_master, boost::dynamic_pointer_cast<ARDOUR::Route>(shared_from_this()), route, Delivery::Aux));
}
add_processor (listener, before);
} catch (failed_constructor& err) {
return -1;
}
return 0;
}
void
Route::remove_aux_or_listen (boost::shared_ptr<Route> route)
{
ProcessorStreams err;
ProcessorList::iterator tmp;
{
Glib::Threads::RWLock::ReaderLock rl(_processor_lock);
/* have to do this early because otherwise processor reconfig
* will put _monitor_send back in the list
*/
if (route == _session.monitor_out()) {
_monitor_send.reset ();
}
again:
for (ProcessorList::iterator x = _processors.begin(); x != _processors.end(); ++x) {
boost::shared_ptr<InternalSend> d = boost::dynamic_pointer_cast<InternalSend>(*x);
if (d && d->target_route() == route) {
rl.release ();
if (remove_processor (*x, &err, false) > 0) {
rl.acquire ();
continue;
}
rl.acquire ();
/* list could have been demolished while we dropped the lock
so start over.
*/
if (_session.engine().connected()) {
/* i/o processors cannot be removed if the engine is not running
* so don't live-loop in case the engine is N/A or dies
*/
goto again;
}
}
}
}
}
void
Route::set_comment (string cmt, void *src)
{
_comment = cmt;
comment_changed ();
_session.set_dirty ();
}
bool
Route::add_fed_by (boost::shared_ptr<Route> other, bool via_sends_only)
{
FeedRecord fr (other, via_sends_only);
pair<FedBy::iterator,bool> result = _fed_by.insert (fr);
if (!result.second) {
/* already a record for "other" - make sure sends-only information is correct */
if (!via_sends_only && result.first->sends_only) {
FeedRecord* frp = const_cast<FeedRecord*>(&(*result.first));
frp->sends_only = false;
}
}
return result.second;
}
void
Route::clear_fed_by ()
{
_fed_by.clear ();
}
bool
Route::feeds (boost::shared_ptr<Route> other, bool* via_sends_only)
{
const FedBy& fed_by (other->fed_by());
for (FedBy::const_iterator f = fed_by.begin(); f != fed_by.end(); ++f) {
boost::shared_ptr<Route> sr = f->r.lock();
if (sr && (sr.get() == this)) {
if (via_sends_only) {
*via_sends_only = f->sends_only;
}
return true;
}
}
return false;
}
IOVector
Route::all_inputs () const
{
/* TODO, if this works as expected,
* cache the IOVector and maintain it via
* input_change_handler(), sidechain_change_handler() etc
*/
IOVector ios;
ios.push_back (_input);
Glib::Threads::RWLock::ReaderLock lm (_processor_lock);
for (ProcessorList::const_iterator r = _processors.begin(); r != _processors.end(); ++r) {
boost::shared_ptr<IOProcessor> iop = boost::dynamic_pointer_cast<IOProcessor>(*r);
boost::shared_ptr<PluginInsert> pi = boost::dynamic_pointer_cast<PluginInsert>(*r);
if (pi != 0) {
assert (iop == 0);
iop = pi->sidechain();
}
if (iop != 0 && iop->input()) {
ios.push_back (iop->input());
}
}
return ios;
}
IOVector
Route::all_outputs () const
{
IOVector ios;
// _output is included via Delivery
Glib::Threads::RWLock::ReaderLock lm (_processor_lock);
for (ProcessorList::const_iterator r = _processors.begin(); r != _processors.end(); ++r) {
boost::shared_ptr<IOProcessor> iop = boost::dynamic_pointer_cast<IOProcessor>(*r);
if (iop != 0 && iop->output()) {
ios.push_back (iop->output());
}
}
return ios;
}
bool
Route::direct_feeds_according_to_reality (boost::shared_ptr<Route> other, bool* via_send_only)
{
DEBUG_TRACE (DEBUG::Graph, string_compose ("Feeds? %1\n", _name));
if (other->all_inputs().fed_by (_output)) {
DEBUG_TRACE (DEBUG::Graph, string_compose ("\tdirect FEEDS %2\n", other->name()));
if (via_send_only) {
*via_send_only = false;
}
return true;
}
Glib::Threads::RWLock::ReaderLock lm (_processor_lock); // XXX
for (ProcessorList::iterator r = _processors.begin(); r != _processors.end(); ++r) {
boost::shared_ptr<IOProcessor> iop = boost::dynamic_pointer_cast<IOProcessor>(*r);
boost::shared_ptr<PluginInsert> pi = boost::dynamic_pointer_cast<PluginInsert>(*r);
if (pi != 0) {
assert (iop == 0);
iop = pi->sidechain();
}
if (iop != 0) {
boost::shared_ptr<const IO> iop_out = iop->output();
if ((iop_out && other->all_inputs().fed_by (iop_out)) || iop->feeds (other)) {
DEBUG_TRACE (DEBUG::Graph, string_compose ("\tIOP %1 does feed %2\n", iop->name(), other->name()));
if (via_send_only) {
*via_send_only = true;
}
return true;
} else {
DEBUG_TRACE (DEBUG::Graph, string_compose ("\tIOP %1 does NOT feed %2\n", iop->name(), other->name()));
}
} else {
DEBUG_TRACE (DEBUG::Graph, string_compose ("\tPROC %1 is not an IOP\n", (*r)->name()));
}
}
DEBUG_TRACE (DEBUG::Graph, string_compose ("\tdoes NOT feed %1\n", other->name()));
return false;
}
bool
Route::direct_feeds_according_to_graph (boost::shared_ptr<Route> other, bool* via_send_only)
{
return _session._current_route_graph.has (shared_from_this (), other, via_send_only);
}
bool
Route::feeds_according_to_graph (boost::shared_ptr<Route> other)
{
return _session._current_route_graph.feeds (shared_from_this (), other);
}
/** Called from the (non-realtime) butler thread when the transport is stopped */
void
Route::nonrealtime_handle_transport_stopped (bool /*abort_ignored*/, bool /*did_locate*/, bool can_flush_processors)
{
framepos_t now = _session.transport_frame();
{
Glib::Threads::RWLock::ReaderLock lm (_processor_lock);
Automatable::transport_stopped (now);
for (ProcessorList::iterator i = _processors.begin(); i != _processors.end(); ++i) {
if (!_have_internal_generator && (Config->get_plugins_stop_with_transport() && can_flush_processors)) {
(*i)->flush ();
}
(*i)->transport_stopped (now);
}
}
_roll_delay = _initial_delay;
}
void
Route::input_change_handler (IOChange change, void * /*src*/)
{
if ((change.type & IOChange::ConfigurationChanged)) {
/* This is called with the process lock held if change
contains ConfigurationChanged
*/
configure_processors (0);
_phase_invert.resize (_input->n_ports().n_audio ());
io_changed (); /* EMIT SIGNAL */
}
if (_soloed_by_others_upstream || _solo_isolated_by_upstream) {
int sbou = 0;
int ibou = 0;
boost::shared_ptr<RouteList> routes = _session.get_routes ();
if (_input->connected()) {
for (RouteList::iterator i = routes->begin(); i != routes->end(); ++i) {
if ((*i).get() == this || (*i)->is_master() || (*i)->is_monitor() || (*i)->is_auditioner()) {
continue;
}
bool sends_only;
bool does_feed = (*i)->direct_feeds_according_to_reality (shared_from_this(), &sends_only);
if (does_feed && !sends_only) {
if ((*i)->soloed()) {
++sbou;
}
if ((*i)->solo_isolated()) {
++ibou;
}
}
}
}
int delta = sbou - _soloed_by_others_upstream;
int idelta = ibou - _solo_isolated_by_upstream;
if (idelta < -1) {
PBD::warning << string_compose (
_("Invalid Solo-Isolate propagation: from:%1 new:%2 - old:%3 = delta:%4"),
_name, ibou, _solo_isolated_by_upstream, idelta)
<< endmsg;
}
if (_soloed_by_others_upstream) {
// ignore new connections (they're not propagated)
if (delta <= 0) {
mod_solo_by_others_upstream (delta);
}
}
if (_solo_isolated_by_upstream) {
// solo-isolate currently only propagates downstream
if (idelta < 0) {
mod_solo_isolated_by_upstream (false);
}
// TODO think: mod_solo_isolated_by_upstream() does not take delta arg,
// but idelta can't be smaller than -1, can it?
//_solo_isolated_by_upstream = ibou;
}
// Session::route_solo_changed does not propagate indirect solo-changes
// propagate downstream to tracks
for (RouteList::iterator i = routes->begin(); i != routes->end(); ++i) {
if ((*i).get() == this || (*i)->is_master() || (*i)->is_monitor() || (*i)->is_auditioner()) {
continue;
}
bool sends_only;
bool does_feed = feeds (*i, &sends_only);
if (delta <= 0 && does_feed && !sends_only) {
(*i)->mod_solo_by_others_upstream (delta);
}
if (idelta < 0 && does_feed && !sends_only) {
(*i)->mod_solo_isolated_by_upstream (false);
}
}
}
}
void
Route::output_change_handler (IOChange change, void * /*src*/)
{
if (_initial_io_setup) {
return;
}
if ((change.type & IOChange::ConfigurationChanged)) {
/* This is called with the process lock held if change
contains ConfigurationChanged
*/
configure_processors (0);
if (is_master()) {
_session.reset_monitor_section();
}
io_changed (); /* EMIT SIGNAL */
}
if (_soloed_by_others_downstream) {
int sbod = 0;
/* checking all all downstream routes for
* explicit of implict solo is a rather drastic measure,
* ideally the input_change_handler() of the other route
* would propagate the change to us.
*/
boost::shared_ptr<RouteList> routes = _session.get_routes ();
if (_output->connected()) {
for (RouteList::iterator i = routes->begin(); i != routes->end(); ++i) {
if ((*i).get() == this || (*i)->is_master() || (*i)->is_monitor() || (*i)->is_auditioner()) {
continue;
}
bool sends_only;
bool does_feed = direct_feeds_according_to_reality (*i, &sends_only);
if (does_feed && !sends_only) {
if ((*i)->soloed()) {
++sbod;
break;
}
}
}
}
int delta = sbod - _soloed_by_others_downstream;
if (delta <= 0) {
// do not allow new connections to change implicit solo (no propagation)
mod_solo_by_others_downstream (delta);
// Session::route_solo_changed() does not propagate indirect solo-changes
// propagate upstream to tracks
for (RouteList::iterator i = routes->begin(); i != routes->end(); ++i) {
if ((*i).get() == this || (*i)->is_master() || (*i)->is_monitor() || (*i)->is_auditioner()) {
continue;
}
bool sends_only;
bool does_feed = (*i)->feeds (shared_from_this(), &sends_only);
if (delta != 0 && does_feed && !sends_only) {
(*i)->mod_solo_by_others_downstream (delta);
}
}
}
}
}
void
Route::sidechain_change_handler (IOChange change, void * /*src*/)
{
if (_initial_io_setup || _in_sidechain_setup) {
return;
}
if ((change.type & IOChange::ConfigurationChanged)) {
/* This is called with the process lock held if change
contains ConfigurationChanged
*/
configure_processors (0);
}
}
uint32_t
Route::pans_required () const
{
if (n_outputs().n_audio() < 2) {
return 0;
}
return max (n_inputs ().n_audio(), processor_max_streams.n_audio());
}
int
Route::no_roll (pframes_t nframes, framepos_t start_frame, framepos_t end_frame, bool session_state_changing)
{
Glib::Threads::RWLock::ReaderLock lm (_processor_lock, Glib::Threads::TRY_LOCK);
if (!lm.locked()) {
return 0;
}
if (n_outputs().n_total() == 0) {
return 0;
}
if (!_active || n_inputs() == ChanCount::ZERO) {
silence_unlocked (nframes);
return 0;
}
if (session_state_changing) {
if (_session.transport_speed() != 0.0f) {
/* we're rolling but some state is changing (e.g. our diskstream contents)
so we cannot use them. Be silent till this is over.
XXX note the absurdity of ::no_roll() being called when we ARE rolling!
*/
silence_unlocked (nframes);
return 0;
}
/* we're really not rolling, so we're either delivery silence or actually
monitoring, both of which are safe to do while session_state_changing is true.
*/
}
BufferSet& bufs = _session.get_route_buffers (n_process_buffers());
fill_buffers_with_input (bufs, _input, nframes);
if (_meter_point == MeterInput) {
_meter->run (bufs, start_frame, end_frame, nframes, true);
}
_amp->apply_gain_automation (false);
_trim->apply_gain_automation (false);
passthru (bufs, start_frame, end_frame, nframes, 0);
return 0;
}
int
Route::roll (pframes_t nframes, framepos_t start_frame, framepos_t end_frame, int declick, bool& /* need_butler */)
{
Glib::Threads::RWLock::ReaderLock lm (_processor_lock, Glib::Threads::TRY_LOCK);
if (!lm.locked()) {
return 0;
}
if (n_outputs().n_total() == 0) {
return 0;
}
if (!_active || n_inputs().n_total() == 0) {
silence_unlocked (nframes);
return 0;
}
framepos_t unused = 0;
if ((nframes = check_initial_delay (nframes, unused)) == 0) {
return 0;
}
_silent = false;
BufferSet& bufs = _session.get_route_buffers (n_process_buffers());
fill_buffers_with_input (bufs, _input, nframes);
if (_meter_point == MeterInput) {
_meter->run (bufs, start_frame, end_frame, nframes, true);
}
passthru (bufs, start_frame, end_frame, nframes, declick);
return 0;
}
int
Route::silent_roll (pframes_t nframes, framepos_t /*start_frame*/, framepos_t /*end_frame*/, bool& /* need_butler */)
{
silence (nframes);
return 0;
}
void
Route::flush_processors ()
{
/* XXX shouldn't really try to take this lock, since
this is called from the RT audio thread.
*/
Glib::Threads::RWLock::ReaderLock lm (_processor_lock);
for (ProcessorList::iterator i = _processors.begin(); i != _processors.end(); ++i) {
(*i)->flush ();
}
}
#ifdef __clang__
__attribute__((annotate("realtime")))
#endif
bool
Route::apply_processor_changes_rt ()
{
int emissions = EmitNone;
if (_pending_meter_point != _meter_point) {
Glib::Threads::RWLock::WriterLock pwl (_processor_lock, Glib::Threads::TRY_LOCK);
if (pwl.locked()) {
/* meters always have buffers for 'processor_max_streams'
* they can be re-positioned without re-allocation */
if (set_meter_point_unlocked()) {
emissions |= EmitMeterChanged | EmitMeterVisibilityChange;;
} else {
emissions |= EmitMeterChanged;
}
}
}
bool changed = false;
if (g_atomic_int_get (&_pending_process_reorder)) {
Glib::Threads::RWLock::WriterLock pwl (_processor_lock, Glib::Threads::TRY_LOCK);
if (pwl.locked()) {
apply_processor_order (_pending_processor_order);
setup_invisible_processors ();
changed = true;
g_atomic_int_set (&_pending_process_reorder, 0);
emissions |= EmitRtProcessorChange;
}
}
if (changed) {
set_processor_positions ();
}
if (emissions != 0) {
g_atomic_int_set (&_pending_signals, emissions);
return true;
}
return (!selfdestruct_sequence.empty ());
}
void
Route::emit_pending_signals ()
{
int sig = g_atomic_int_and (&_pending_signals, 0);
if (sig & EmitMeterChanged) {
_meter->emit_configuration_changed();
meter_change (); /* EMIT SIGNAL */
if (sig & EmitMeterVisibilityChange) {
processors_changed (RouteProcessorChange (RouteProcessorChange::MeterPointChange, true)); /* EMIT SIGNAL */
} else {
processors_changed (RouteProcessorChange (RouteProcessorChange::MeterPointChange, false)); /* EMIT SIGNAL */
}
}
if (sig & EmitRtProcessorChange) {
processors_changed (RouteProcessorChange (RouteProcessorChange::RealTimeChange)); /* EMIT SIGNAL */
}
/* this would be a job for the butler.
* Conceptually we should not take processe/processor locks here.
* OTOH its more efficient (less overhead for summoning the butler and
* telling her what do do) and signal emission is called
* directly after the process callback, which decreases the chance
* of x-runs when taking the locks.
*/
while (!selfdestruct_sequence.empty ()) {
Glib::Threads::Mutex::Lock lx (selfdestruct_lock);
if (selfdestruct_sequence.empty ()) { break; } // re-check with lock
boost::shared_ptr<Processor> proc = selfdestruct_sequence.back ().lock ();
selfdestruct_sequence.pop_back ();
lx.release ();
if (proc) {
remove_processor (proc);
}
}
}
void
Route::set_meter_point (MeterPoint p, bool force)
{
if (_pending_meter_point == p && !force) {
return;
}
if (force || !AudioEngine::instance()->running()) {
Glib::Threads::Mutex::Lock lx (AudioEngine::instance()->process_lock ());
Glib::Threads::RWLock::WriterLock lm (_processor_lock);
_pending_meter_point = p;
_meter->emit_configuration_changed();
meter_change (); /* EMIT SIGNAL */
if (set_meter_point_unlocked()) {
processors_changed (RouteProcessorChange (RouteProcessorChange::MeterPointChange, true)); /* EMIT SIGNAL */
} else {
processors_changed (RouteProcessorChange (RouteProcessorChange::MeterPointChange, false)); /* EMIT SIGNAL */
}
} else {
_pending_meter_point = p;
}
}
#ifdef __clang__
__attribute__((annotate("realtime")))
#endif
bool
Route::set_meter_point_unlocked ()
{
#ifndef NDEBUG
/* Caller must hold process and processor write lock */
assert (!AudioEngine::instance()->process_lock().trylock());
Glib::Threads::RWLock::WriterLock lm (_processor_lock, Glib::Threads::TRY_LOCK);
assert (!lm.locked ());
#endif
_meter_point = _pending_meter_point;
bool meter_was_visible_to_user = _meter->display_to_user ();
if (!_custom_meter_position_noted) {
maybe_note_meter_position ();
}
if (_meter_point != MeterCustom) {
_meter->set_display_to_user (false);
setup_invisible_processors ();
} else {
_meter->set_display_to_user (true);
/* If we have a previous position for the custom meter, try to put it there */
boost::shared_ptr<Processor> after = _processor_after_last_custom_meter.lock ();
if (after) {
ProcessorList::iterator i = find (_processors.begin(), _processors.end(), after);
if (i != _processors.end ()) {
_processors.remove (_meter);
_processors.insert (i, _meter);
}
} else {// at end, right before the mains_out/panner
_processors.remove (_meter);
ProcessorList::iterator main = _processors.end();
_processors.insert (--main, _meter);
}
}
/* Set up the meter for its new position */
ProcessorList::iterator loc = find (_processors.begin(), _processors.end(), _meter);
ChanCount m_in;
if (loc == _processors.begin()) {
m_in = _input->n_ports();
} else {
ProcessorList::iterator before = loc;
--before;
m_in = (*before)->output_streams ();
}
_meter->reflect_inputs (m_in);
/* we do not need to reconfigure the processors, because the meter
(a) is always ready to handle processor_max_streams
(b) is always an N-in/N-out processor, and thus moving
it doesn't require any changes to the other processors.
*/
/* these should really be done after releasing the lock
* but all those signals are subscribed to with gui_thread()
* so we're safe.
*/
return (_meter->display_to_user() != meter_was_visible_to_user);
}
void
Route::listen_position_changed ()
{
{
Glib::Threads::Mutex::Lock lx (AudioEngine::instance()->process_lock ());
Glib::Threads::RWLock::WriterLock lm (_processor_lock);
ProcessorState pstate (this);
if (configure_processors_unlocked (0)) {
DEBUG_TRACE (DEBUG::Processors, "---- CONFIGURATION FAILED.\n");
pstate.restore ();
configure_processors_unlocked (0); // it worked before we tried to add it ...
return;
}
}
processors_changed (RouteProcessorChange ()); /* EMIT SIGNAL */
_session.set_dirty ();
}
boost::shared_ptr<CapturingProcessor>
Route::add_export_point()
{
Glib::Threads::RWLock::ReaderLock lm (_processor_lock);
if (!_capturing_processor) {
lm.release();
Glib::Threads::Mutex::Lock lx (AudioEngine::instance()->process_lock ());
Glib::Threads::RWLock::WriterLock lw (_processor_lock);
_capturing_processor.reset (new CapturingProcessor (_session));
_capturing_processor->activate ();
configure_processors_unlocked (0);
}
return _capturing_processor;
}
framecnt_t
Route::update_signal_latency ()
{
framecnt_t l = _output->user_latency();
framecnt_t lamp = 0;
bool before_amp = true;
framecnt_t ltrim = 0;
bool before_trim = true;
for (ProcessorList::iterator i = _processors.begin(); i != _processors.end(); ++i) {
if ((*i)->active ()) {
l += (*i)->signal_latency ();
}
if ((*i) == _amp) {
before_amp = false;
}
if ((*i) == _trim) {
before_amp = false;
}
if (before_amp) {
lamp = l;
}
if (before_trim) {
lamp = l;
}
}
DEBUG_TRACE (DEBUG::Latency, string_compose ("%1: internal signal latency = %2\n", _name, l));
// TODO: (lamp - _signal_latency) to sync to output (read-ahed), currently _roll_delay shifts this around
_signal_latency_at_amp_position = lamp;
_signal_latency_at_trim_position = ltrim;
if (_signal_latency != l) {
_signal_latency = l;
signal_latency_changed (); /* EMIT SIGNAL */
}
return _signal_latency;
}
void
Route::set_user_latency (framecnt_t nframes)
{
_output->set_user_latency (nframes);
_session.update_latency_compensation ();
}
void
Route::set_latency_compensation (framecnt_t longest_session_latency)
{
framecnt_t old = _initial_delay;
if (_signal_latency < longest_session_latency) {
_initial_delay = longest_session_latency - _signal_latency;
} else {
_initial_delay = 0;
}
DEBUG_TRACE (DEBUG::Latency, string_compose (
"%1: compensate for maximum latency of %2,"
"given own latency of %3, using initial delay of %4\n",
name(), longest_session_latency, _signal_latency, _initial_delay));
if (_initial_delay != old) {
initial_delay_changed (); /* EMIT SIGNAL */
}
if (_session.transport_stopped()) {
_roll_delay = _initial_delay;
}
}
void
Route::set_block_size (pframes_t nframes)
{
for (ProcessorList::iterator i = _processors.begin(); i != _processors.end(); ++i) {
(*i)->set_block_size (nframes);
}
_session.ensure_buffers (n_process_buffers ());
}
void
Route::protect_automation ()
{
for (ProcessorList::iterator i = _processors.begin(); i != _processors.end(); ++i)
(*i)->protect_automation();
}
/** @param declick 1 to set a pending declick fade-in,
* -1 to set a pending declick fade-out
*/
void
Route::set_pending_declick (int declick)
{
if (_declickable) {
/* this call is not allowed to turn off a pending declick */
if (declick) {
_pending_declick = declick;
}
} else {
_pending_declick = 0;
}
}
/** Shift automation forwards from a particular place, thereby inserting time.
* Adds undo commands for any shifts that are performed.
*
* @param pos Position to start shifting from.
* @param frames Amount to shift forwards by.
*/
void
Route::shift (framepos_t pos, framecnt_t frames)
{
/* gain automation */
{
boost::shared_ptr<AutomationControl> gc = _amp->gain_control();
XMLNode &before = gc->alist()->get_state ();
gc->alist()->shift (pos, frames);
XMLNode &after = gc->alist()->get_state ();
_session.add_command (new MementoCommand<AutomationList> (*gc->alist().get(), &before, &after));
}
/* gain automation */
{
boost::shared_ptr<AutomationControl> gc = _trim->gain_control();
XMLNode &before = gc->alist()->get_state ();
gc->alist()->shift (pos, frames);
XMLNode &after = gc->alist()->get_state ();
_session.add_command (new MementoCommand<AutomationList> (*gc->alist().get(), &before, &after));
}
// TODO mute automation ??
/* pan automation */
if (_pannable) {
ControlSet::Controls& c (_pannable->controls());
for (ControlSet::Controls::const_iterator ci = c.begin(); ci != c.end(); ++ci) {
boost::shared_ptr<AutomationControl> pc = boost::dynamic_pointer_cast<AutomationControl> (ci->second);
if (pc) {
boost::shared_ptr<AutomationList> al = pc->alist();
XMLNode& before = al->get_state ();
al->shift (pos, frames);
XMLNode& after = al->get_state ();
_session.add_command (new MementoCommand<AutomationList> (*al.get(), &before, &after));
}
}
}
/* redirect automation */
{
Glib::Threads::RWLock::ReaderLock lm (_processor_lock);
for (ProcessorList::iterator i = _processors.begin (); i != _processors.end (); ++i) {
set<Evoral::Parameter> parameters = (*i)->what_can_be_automated();
for (set<Evoral::Parameter>::const_iterator p = parameters.begin (); p != parameters.end (); ++p) {
boost::shared_ptr<AutomationControl> ac = (*i)->automation_control (*p);
if (ac) {
boost::shared_ptr<AutomationList> al = ac->alist();
XMLNode &before = al->get_state ();
al->shift (pos, frames);
XMLNode &after = al->get_state ();
_session.add_command (new MementoCommand<AutomationList> (*al.get(), &before, &after));
}
}
}
}
}
void
Route::set_plugin_state_dir (boost::weak_ptr<Processor> p, const std::string& d)
{
boost::shared_ptr<Processor> processor (p.lock ());
boost::shared_ptr<PluginInsert> pi = boost::dynamic_pointer_cast<PluginInsert> (processor);
if (!pi) {
return;
}
pi->set_state_dir (d);
}
int
Route::save_as_template (const string& path, const string& name)
{
std::string state_dir = path.substr (0, path.find_last_of ('.')); // strip template_suffix
PBD::Unwinder<std::string> uw (_session._template_state_dir, state_dir);
XMLNode& node (state (false));
XMLTree tree;
IO::set_name_in_state (*node.children().front(), name);
tree.set_root (&node);
/* return zero on success, non-zero otherwise */
return !tree.write (path.c_str());
}
bool
Route::set_name (const string& str)
{
if (str == name()) {
return true;
}
string name = Route::ensure_track_or_route_name (str, _session);
SessionObject::set_name (name);
bool ret = (_input->set_name(name) && _output->set_name(name));
if (ret) {
/* rename the main outs. Leave other IO processors
* with whatever name they already have, because its
* just fine as it is (it will not contain the route
* name if its a port insert, port send or port return).
*/
if (_main_outs) {
if (_main_outs->set_name (name)) {
/* XXX returning false here is stupid because
we already changed the route name.
*/
return false;
}
}
}
return ret;
}
/** Set the name of a route in an XML description.
* @param node XML <Route> node to set the name in.
* @param name New name.
*/
void
Route::set_name_in_state (XMLNode& node, string const & name, bool rename_playlist)
{
node.add_property (X_("name"), name);
XMLNodeList children = node.children();
for (XMLNodeIterator i = children.begin(); i != children.end(); ++i) {
if ((*i)->name() == X_("IO")) {
IO::set_name_in_state (**i, name);
} else if ((*i)->name() == X_("Processor")) {
XMLProperty* role = (*i)->property (X_("role"));
if (role && role->value() == X_("Main")) {
(*i)->add_property (X_("name"), name);
}
} else if ((*i)->name() == X_("Diskstream")) {
if (rename_playlist) {
(*i)->add_property (X_("playlist"), string_compose ("%1.1", name).c_str());
}
(*i)->add_property (X_("name"), name);
}
}
}
boost::shared_ptr<Send>
Route::internal_send_for (boost::shared_ptr<const Route> target) const
{
Glib::Threads::RWLock::ReaderLock lm (_processor_lock);
for (ProcessorList::const_iterator i = _processors.begin(); i != _processors.end(); ++i) {
boost::shared_ptr<InternalSend> send;
if ((send = boost::dynamic_pointer_cast<InternalSend>(*i)) != 0) {
if (send->target_route() == target) {
return send;
}
}
}
return boost::shared_ptr<Send>();
}
/** @param c Audio channel index.
* @param yn true to invert phase, otherwise false.
*/
void
Route::set_phase_invert (uint32_t c, bool yn)
{
if (_phase_invert[c] != yn) {
_phase_invert[c] = yn;
phase_invert_changed (); /* EMIT SIGNAL */
_phase_control->Changed(); /* EMIT SIGNAL */
_session.set_dirty ();
}
}
void
Route::set_phase_invert (boost::dynamic_bitset<> p)
{
if (_phase_invert != p) {
_phase_invert = p;
phase_invert_changed (); /* EMIT SIGNAL */
_session.set_dirty ();
}
}
bool
Route::phase_invert (uint32_t c) const
{
return _phase_invert[c];
}
boost::dynamic_bitset<>
Route::phase_invert () const
{
return _phase_invert;
}
void
Route::set_denormal_protection (bool yn)
{
if (_denormal_protection != yn) {
_denormal_protection = yn;
denormal_protection_changed (); /* EMIT SIGNAL */
}
}
bool
Route::denormal_protection () const
{
return _denormal_protection;
}
void
Route::set_active (bool yn, void* src)
{
if (_session.transport_rolling()) {
return;
}
if (_route_group && src != _route_group && _route_group->is_active() && _route_group->is_route_active()) {
_route_group->foreach_route (boost::bind (&Route::set_active, _1, yn, _route_group));
return;
}
if (_active != yn) {
_active = yn;
_input->set_active (yn);
_output->set_active (yn);
active_changed (); // EMIT SIGNAL
_session.set_dirty ();
}
}
boost::shared_ptr<Pannable>
Route::pannable() const
{
return _pannable;
}
boost::shared_ptr<Panner>
Route::panner() const
{
/* may be null ! */
return _main_outs->panner_shell()->panner();
}
boost::shared_ptr<PannerShell>
Route::panner_shell() const
{
return _main_outs->panner_shell();
}
boost::shared_ptr<GainControl>
Route::gain_control() const
{
return _gain_control;
}
boost::shared_ptr<GainControl>
Route::trim_control() const
{
return _trim_control;
}
boost::shared_ptr<Route::PhaseControllable>
Route::phase_control() const
{
if (phase_invert().size()) {
return _phase_control;
} else {
return boost::shared_ptr<PhaseControllable>();
}
}
boost::shared_ptr<AutomationControl>
Route::get_control (const Evoral::Parameter& param)
{
/* either we own the control or .... */
boost::shared_ptr<AutomationControl> c = boost::dynamic_pointer_cast<AutomationControl>(control (param));
if (!c) {
/* maybe one of our processors does or ... */
Glib::Threads::RWLock::ReaderLock rm (_processor_lock);
for (ProcessorList::iterator i = _processors.begin(); i != _processors.end(); ++i) {
if ((c = boost::dynamic_pointer_cast<AutomationControl>((*i)->control (param))) != 0) {
break;
}
}
}
if (!c) {
/* nobody does so we'll make a new one */
c = boost::dynamic_pointer_cast<AutomationControl>(control_factory(param));
add_control(c);
}
return c;
}
boost::shared_ptr<Processor>
Route::nth_plugin (uint32_t n) const
{
Glib::Threads::RWLock::ReaderLock lm (_processor_lock);
ProcessorList::const_iterator i;
for (i = _processors.begin(); i != _processors.end(); ++i) {
if (boost::dynamic_pointer_cast<PluginInsert> (*i)) {
if (n-- == 0) {
return *i;
}
}
}
return boost::shared_ptr<Processor> ();
}
boost::shared_ptr<Processor>
Route::nth_send (uint32_t n) const
{
Glib::Threads::RWLock::ReaderLock lm (_processor_lock);
ProcessorList::const_iterator i;
for (i = _processors.begin(); i != _processors.end(); ++i) {
if (boost::dynamic_pointer_cast<Send> (*i)) {
if ((*i)->name().find (_("Monitor")) == 0) {
/* send to monitor section is not considered
to be an accessible send.
*/
continue;
}
if (n-- == 0) {
return *i;
}
}
}
return boost::shared_ptr<Processor> ();
}
bool
Route::has_io_processor_named (const string& name)
{
Glib::Threads::RWLock::ReaderLock lm (_processor_lock);
ProcessorList::iterator i;
for (i = _processors.begin(); i != _processors.end(); ++i) {
if (boost::dynamic_pointer_cast<Send> (*i) ||
boost::dynamic_pointer_cast<PortInsert> (*i)) {
if ((*i)->name() == name) {
return true;
}
}
}
return false;
}
MuteMaster::MutePoint
Route::mute_points () const
{
return _mute_master->mute_points ();
}
void
Route::set_processor_positions ()
{
Glib::Threads::RWLock::ReaderLock lm (_processor_lock);
bool had_amp = false;
for (ProcessorList::const_iterator i = _processors.begin(); i != _processors.end(); ++i) {
(*i)->set_pre_fader (!had_amp);
if (*i == _amp) {
had_amp = true;
}
}
}
/** Called when there is a proposed change to the input port count */
bool
Route::input_port_count_changing (ChanCount to)
{
list<pair<ChanCount, ChanCount> > c = try_configure_processors (to, 0);
if (c.empty()) {
/* The processors cannot be configured with the new input arrangement, so
block the change.
*/
return true;
}
/* The change is ok */
return false;
}
/** Called when there is a proposed change to the output port count */
bool
Route::output_port_count_changing (ChanCount to)
{
if (_strict_io && !_in_configure_processors) {
return true;
}
for (DataType::iterator t = DataType::begin(); t != DataType::end(); ++t) {
if (processor_out_streams.get(*t) > to.get(*t)) {
return true;
}
}
/* The change is ok */
return false;
}
list<string>
Route::unknown_processors () const
{
list<string> p;
if (_session.get_disable_all_loaded_plugins ()) {
// Do not list "missing plugins" if they are explicitly disabled
return p;
}
Glib::Threads::RWLock::ReaderLock lm (_processor_lock);
for (ProcessorList::const_iterator i = _processors.begin(); i != _processors.end(); ++i) {
if (boost::dynamic_pointer_cast<UnknownProcessor const> (*i)) {
p.push_back ((*i)->name ());
}
}
return p;
}
framecnt_t
Route::update_port_latencies (PortSet& from, PortSet& to, bool playback, framecnt_t our_latency) const
{
/* we assume that all our input ports feed all our output ports. its not
universally true, but the alternative is way too corner-case to worry about.
*/
LatencyRange all_connections;
if (from.empty()) {
all_connections.min = 0;
all_connections.max = 0;
} else {
all_connections.min = ~((pframes_t) 0);
all_connections.max = 0;
/* iterate over all "from" ports and determine the latency range for all of their
connections to the "outside" (outside of this Route).
*/
for (PortSet::iterator p = from.begin(); p != from.end(); ++p) {
LatencyRange range;
p->get_connected_latency_range (range, playback);
all_connections.min = min (all_connections.min, range.min);
all_connections.max = max (all_connections.max, range.max);
}
}
/* set the "from" port latencies to the max/min range of all their connections */
for (PortSet::iterator p = from.begin(); p != from.end(); ++p) {
p->set_private_latency_range (all_connections, playback);
}
/* set the ports "in the direction of the flow" to the same value as above plus our own signal latency */
all_connections.min += our_latency;
all_connections.max += our_latency;
for (PortSet::iterator p = to.begin(); p != to.end(); ++p) {
p->set_private_latency_range (all_connections, playback);
}
return all_connections.max;
}
framecnt_t
Route::set_private_port_latencies (bool playback) const
{
framecnt_t own_latency = 0;
/* Processor list not protected by lock: MUST BE CALLED FROM PROCESS THREAD
OR LATENCY CALLBACK.
This is called (early) from the latency callback. It computes the REAL
latency associated with each port and stores the result as the "private"
latency of the port. A later call to Route::set_public_port_latencies()
sets all ports to the same value to reflect the fact that we do latency
compensation and so all signals are delayed by the same amount as they
flow through ardour.
*/
for (ProcessorList::const_iterator i = _processors.begin(); i != _processors.end(); ++i) {
if ((*i)->active ()) {
own_latency += (*i)->signal_latency ();
}
}
if (playback) {
/* playback: propagate latency from "outside the route" to outputs to inputs */
return update_port_latencies (_output->ports (), _input->ports (), true, own_latency);
} else {
/* capture: propagate latency from "outside the route" to inputs to outputs */
return update_port_latencies (_input->ports (), _output->ports (), false, own_latency);
}
}
void
Route::set_public_port_latencies (framecnt_t value, bool playback) const
{
/* this is called to set the JACK-visible port latencies, which take
latency compensation into account.
*/
LatencyRange range;
range.min = value;
range.max = value;
{
const PortSet& ports (_input->ports());
for (PortSet::const_iterator p = ports.begin(); p != ports.end(); ++p) {
p->set_public_latency_range (range, playback);
}
}
{
const PortSet& ports (_output->ports());
for (PortSet::const_iterator p = ports.begin(); p != ports.end(); ++p) {
p->set_public_latency_range (range, playback);
}
}
}
/** Put the invisible processors in the right place in _processors.
* Must be called with a writer lock on _processor_lock held.
*/
#ifdef __clang__
__attribute__((annotate("realtime")))
#endif
void
Route::setup_invisible_processors ()
{
#ifndef NDEBUG
Glib::Threads::RWLock::WriterLock lm (_processor_lock, Glib::Threads::TRY_LOCK);
assert (!lm.locked ());
#endif
if (!_main_outs) {
/* too early to be doing this stuff */
return;
}
/* we'll build this new list here and then use it
*
* TODO put the ProcessorList is on the stack for RT-safety.
*/
ProcessorList new_processors;
/* find visible processors */
for (ProcessorList::iterator i = _processors.begin(); i != _processors.end(); ++i) {
if ((*i)->display_to_user ()) {
new_processors.push_back (*i);
}
}
/* find the amp */
ProcessorList::iterator amp = new_processors.begin ();
while (amp != new_processors.end() && *amp != _amp) {
++amp;
}
assert (amp != new_processors.end ());
/* and the processor after the amp */
ProcessorList::iterator after_amp = amp;
++after_amp;
/* METER */
if (_meter) {
switch (_meter_point) {
case MeterInput:
assert (!_meter->display_to_user ());
new_processors.push_front (_meter);
break;
case MeterPreFader:
assert (!_meter->display_to_user ());
new_processors.insert (amp, _meter);
break;
case MeterPostFader:
/* do nothing here */
break;
case MeterOutput:
/* do nothing here */
break;
case MeterCustom:
/* the meter is visible, so we don't touch it here */
break;
}
}
/* MAIN OUTS */
assert (_main_outs);
assert (!_main_outs->display_to_user ());
new_processors.push_back (_main_outs);
/* iterator for the main outs */
ProcessorList::iterator main = new_processors.end();
--main;
/* OUTPUT METERING */
if (_meter && (_meter_point == MeterOutput || _meter_point == MeterPostFader)) {
assert (!_meter->display_to_user ());
/* add the processor just before or just after the main outs */
ProcessorList::iterator meter_point = main;
if (_meter_point == MeterOutput) {
++meter_point;
}
new_processors.insert (meter_point, _meter);
}
/* MONITOR SEND */
if (_monitor_send && !is_monitor ()) {
assert (!_monitor_send->display_to_user ());
switch (Config->get_listen_position ()) {
case PreFaderListen:
switch (Config->get_pfl_position ()) {
case PFLFromBeforeProcessors:
new_processors.push_front (_monitor_send);
break;
case PFLFromAfterProcessors:
new_processors.insert (amp, _monitor_send);
break;
}
_monitor_send->set_can_pan (false);
break;
case AfterFaderListen:
switch (Config->get_afl_position ()) {
case AFLFromBeforeProcessors:
new_processors.insert (after_amp, _monitor_send);
break;
case AFLFromAfterProcessors:
new_processors.insert (new_processors.end(), _monitor_send);
break;
}
_monitor_send->set_can_pan (true);
break;
}
}
#if 0 // not used - just yet
if (!is_master() && !is_monitor() && !is_auditioner()) {
new_processors.push_front (_delayline);
}
#endif
/* MONITOR CONTROL */
if (_monitor_control && is_monitor ()) {
assert (!_monitor_control->display_to_user ());
new_processors.insert (amp, _monitor_control);
}
/* INTERNAL RETURN */
/* doing this here means that any monitor control will come just after
the return.
*/
if (_intreturn) {
assert (!_intreturn->display_to_user ());
new_processors.push_front (_intreturn);
}
if (_trim && _trim->active()) {
assert (!_trim->display_to_user ());
new_processors.push_front (_trim);
}
/* EXPORT PROCESSOR */
if (_capturing_processor) {
assert (!_capturing_processor->display_to_user ());
new_processors.push_front (_capturing_processor);
}
_processors = new_processors;
for (ProcessorList::iterator i = _processors.begin(); i != _processors.end(); ++i) {
if (!(*i)->display_to_user () && !(*i)->active () && (*i) != _monitor_send) {
(*i)->activate ();
}
}
DEBUG_TRACE (DEBUG::Processors, string_compose ("%1: setup_invisible_processors\n", _name));
for (ProcessorList::iterator i = _processors.begin(); i != _processors.end(); ++i) {
DEBUG_TRACE (DEBUG::Processors, string_compose ("\t%1\n", (*i)->name ()));
}
}
void
Route::unpan ()
{
Glib::Threads::Mutex::Lock lm (AudioEngine::instance()->process_lock ());
Glib::Threads::RWLock::ReaderLock lp (_processor_lock);
_pannable.reset ();
for (ProcessorList::iterator i = _processors.begin(); i != _processors.end(); ++i) {
boost::shared_ptr<Delivery> d = boost::dynamic_pointer_cast<Delivery>(*i);
if (d) {
d->unpan ();
}
}
}
/** If the meter point is `Custom', make a note of where the meter is.
* This is so that if the meter point is subsequently set to something else,
* and then back to custom, we can put the meter back where it was last time
* custom was enabled.
*
* Must be called with the _processor_lock held.
*/
void
Route::maybe_note_meter_position ()
{
if (_meter_point != MeterCustom) {
return;
}
_custom_meter_position_noted = true;
/* custom meter points range from after trim to before panner/main_outs
* this is a limitation by the current processor UI
*/
bool seen_trim = false;
_processor_after_last_custom_meter.reset();
for (ProcessorList::iterator i = _processors.begin(); i != _processors.end(); ++i) {
if ((*i) == _trim) {
seen_trim = true;
}
if ((*i) == _main_outs) {
_processor_after_last_custom_meter = *i;
break;
}
if (boost::dynamic_pointer_cast<PeakMeter> (*i)) {
if (!seen_trim) {
_processor_after_last_custom_meter = _trim;
} else {
ProcessorList::iterator j = i;
++j;
assert(j != _processors.end ()); // main_outs should be before
_processor_after_last_custom_meter = *j;
}
break;
}
}
assert(_processor_after_last_custom_meter.lock());
}
boost::shared_ptr<Processor>
Route::processor_by_id (PBD::ID id) const
{
Glib::Threads::RWLock::ReaderLock lm (_processor_lock);
for (ProcessorList::const_iterator i = _processors.begin(); i != _processors.end(); ++i) {
if ((*i)->id() == id) {
return *i;
}
}
return boost::shared_ptr<Processor> ();
}
/** @return the monitoring state, or in other words what data we are pushing
* into the route (data from the inputs, data from disk or silence)
*/
MonitorState
Route::monitoring_state () const
{
return MonitoringInput;
}
/** @return what we should be metering; either the data coming from the input
* IO or the data that is flowing through the route.
*/
MeterState
Route::metering_state () const
{
return MeteringRoute;
}
bool
Route::has_external_redirects () const
{
for (ProcessorList::const_iterator i = _processors.begin(); i != _processors.end(); ++i) {
/* ignore inactive processors and obviously ignore the main
* outs since everything has them and we don't care.
*/
if ((*i)->active() && (*i) != _main_outs && (*i)->does_routing()) {
return true;;
}
}
return false;
}
boost::shared_ptr<Processor>
Route::the_instrument () const
{
Glib::Threads::RWLock::ReaderLock lm (_processor_lock);
return the_instrument_unlocked ();
}
boost::shared_ptr<Processor>
Route::the_instrument_unlocked () const
{
for (ProcessorList::const_iterator i = _processors.begin(); i != _processors.end(); ++i) {
if (boost::dynamic_pointer_cast<PluginInsert>(*i)) {
if ((*i)->input_streams().n_midi() > 0 &&
(*i)->output_streams().n_audio() > 0) {
return (*i);
}
}
}
return boost::shared_ptr<Processor>();
}
void
Route::non_realtime_locate (framepos_t pos)
{
if (_pannable) {
_pannable->transport_located (pos);
}
if (_delayline.get()) {
_delayline.get()->flush();
}
{
//Glib::Threads::Mutex::Lock lx (AudioEngine::instance()->process_lock ());
Glib::Threads::RWLock::ReaderLock lm (_processor_lock);
for (ProcessorList::iterator i = _processors.begin(); i != _processors.end(); ++i) {
(*i)->transport_located (pos);
}
}
_roll_delay = _initial_delay;
}
void
Route::fill_buffers_with_input (BufferSet& bufs, boost::shared_ptr<IO> io, pframes_t nframes)
{
size_t n_buffers;
size_t i;
/* MIDI
*
* We don't currently mix MIDI input together, so we don't need the
* complex logic of the audio case.
*/
n_buffers = bufs.count().n_midi ();
for (i = 0; i < n_buffers; ++i) {
boost::shared_ptr<MidiPort> source_port = io->midi (i);
MidiBuffer& buf (bufs.get_midi (i));
if (source_port) {
buf.copy (source_port->get_midi_buffer(nframes));
} else {
buf.silence (nframes);
}
}
/* AUDIO */
n_buffers = bufs.count().n_audio();
size_t n_ports = io->n_ports().n_audio();
float scaling = 1.0f;
if (n_ports > n_buffers) {
scaling = ((float) n_buffers) / n_ports;
}
for (i = 0; i < n_ports; ++i) {
/* if there are more ports than buffers, map them onto buffers
* in a round-robin fashion
*/
boost::shared_ptr<AudioPort> source_port = io->audio (i);
AudioBuffer& buf (bufs.get_audio (i%n_buffers));
if (i < n_buffers) {
/* first time through just copy a channel into
the output buffer.
*/
buf.read_from (source_port->get_audio_buffer (nframes), nframes);
if (scaling != 1.0f) {
buf.apply_gain (scaling, nframes);
}
} else {
/* on subsequent times around, merge data from
* the port with what is already there
*/
if (scaling != 1.0f) {
buf.accumulate_with_gain_from (source_port->get_audio_buffer (nframes), nframes, 0, scaling);
} else {
buf.accumulate_from (source_port->get_audio_buffer (nframes), nframes);
}
}
}
/* silence any remaining buffers */
for (; i < n_buffers; ++i) {
AudioBuffer& buf (bufs.get_audio (i));
buf.silence (nframes);
}
/* establish the initial setup of the buffer set, reflecting what was
copied into it. unless, of course, we are the auditioner, in which
case nothing was fed into it from the inputs at all.
*/
if (!is_auditioner()) {
bufs.set_count (io->n_ports());
}
}
boost::shared_ptr<AutomationControl>
Route::pan_azimuth_control() const
{
#ifdef MIXBUS
boost::shared_ptr<ARDOUR::PluginInsert> plug = ch_post();
if (!plug) {
return boost::shared_ptr<AutomationControl>();
}
const uint32_t port_channel_post_pan = 2; // gtk2_ardour/mixbus_ports.h
return boost::dynamic_pointer_cast<ARDOUR::AutomationControl> (plug->control (Evoral::Parameter (ARDOUR::PluginAutomation, 0, port_channel_post_pan)));
#else
if (!_pannable || !panner()) {
return boost::shared_ptr<AutomationControl>();
}
return _pannable->pan_azimuth_control;
#endif
}
boost::shared_ptr<AutomationControl>
Route::pan_elevation_control() const
{
if (Profile->get_mixbus() || !_pannable || !panner()) {
return boost::shared_ptr<AutomationControl>();
}
set<Evoral::Parameter> c = panner()->what_can_be_automated ();
if (c.find (PanElevationAutomation) != c.end()) {
return _pannable->pan_elevation_control;
} else {
return boost::shared_ptr<AutomationControl>();
}
}
boost::shared_ptr<AutomationControl>
Route::pan_width_control() const
{
if (Profile->get_mixbus() || !_pannable || !panner()) {
return boost::shared_ptr<AutomationControl>();
}
set<Evoral::Parameter> c = panner()->what_can_be_automated ();
if (c.find (PanWidthAutomation) != c.end()) {
return _pannable->pan_width_control;
} else {
return boost::shared_ptr<AutomationControl>();
}
}
boost::shared_ptr<AutomationControl>
Route::pan_frontback_control() const
{
if (Profile->get_mixbus() || !_pannable || !panner()) {
return boost::shared_ptr<AutomationControl>();
}
set<Evoral::Parameter> c = panner()->what_can_be_automated ();
if (c.find (PanFrontBackAutomation) != c.end()) {
return _pannable->pan_frontback_control;
} else {
return boost::shared_ptr<AutomationControl>();
}
}
boost::shared_ptr<AutomationControl>
Route::pan_lfe_control() const
{
if (Profile->get_mixbus() || !_pannable || !panner()) {
return boost::shared_ptr<AutomationControl>();
}
set<Evoral::Parameter> c = panner()->what_can_be_automated ();
if (c.find (PanLFEAutomation) != c.end()) {
return _pannable->pan_lfe_control;
} else {
return boost::shared_ptr<AutomationControl>();
}
}
uint32_t
Route::eq_band_cnt () const
{
if (Profile->get_mixbus()) {
return 3;
} else {
/* Ardour has no well-known EQ object */
return 0;
}
}
boost::shared_ptr<AutomationControl>
Route::eq_gain_controllable (uint32_t band) const
{
#ifdef MIXBUS
boost::shared_ptr<PluginInsert> eq = ch_eq();
if (!eq) {
return boost::shared_ptr<AutomationControl>();
}
uint32_t port_number;
switch (band) {
case 0:
if (is_master() || mixbus()) {
port_number = 4;
} else {
port_number = 8;
}
break;
case 1:
if (is_master() || mixbus()) {
port_number = 3;
} else {
port_number = 6;
}
break;
case 2:
if (is_master() || mixbus()) {
port_number = 2;
} else {
port_number = 4;
}
break;
default:
return boost::shared_ptr<AutomationControl>();
}
return boost::dynamic_pointer_cast<ARDOUR::AutomationControl> (eq->control (Evoral::Parameter (ARDOUR::PluginAutomation, 0, port_number)));
#else
return boost::shared_ptr<AutomationControl>();
#endif
}
boost::shared_ptr<AutomationControl>
Route::eq_freq_controllable (uint32_t band) const
{
#ifdef MIXBUS
if (mixbus() || is_master()) {
/* no frequency controls for mixbusses or master */
return boost::shared_ptr<AutomationControl>();
}
boost::shared_ptr<PluginInsert> eq = ch_eq();
if (!eq) {
return boost::shared_ptr<AutomationControl>();
}
uint32_t port_number;
switch (band) {
case 0:
port_number = 7;
break;
case 1:
port_number = 5;
break;
case 2:
port_number = 3;
break;
default:
return boost::shared_ptr<AutomationControl>();
}
return boost::dynamic_pointer_cast<ARDOUR::AutomationControl> (eq->control (Evoral::Parameter (ARDOUR::PluginAutomation, 0, port_number)));
#else
return boost::shared_ptr<AutomationControl>();
#endif
}
boost::shared_ptr<AutomationControl>
Route::eq_q_controllable (uint32_t band) const
{
return boost::shared_ptr<AutomationControl>();
}
boost::shared_ptr<AutomationControl>
Route::eq_shape_controllable (uint32_t band) const
{
return boost::shared_ptr<AutomationControl>();
}
boost::shared_ptr<AutomationControl>
Route::eq_enable_controllable () const
{
#ifdef MIXBUS
boost::shared_ptr<PluginInsert> eq = ch_eq();
if (!eq) {
return boost::shared_ptr<AutomationControl>();
}
return boost::dynamic_pointer_cast<ARDOUR::AutomationControl> (eq->control (Evoral::Parameter (ARDOUR::PluginAutomation, 0, 1)));
#else
return boost::shared_ptr<AutomationControl>();
#endif
}
boost::shared_ptr<AutomationControl>
Route::eq_hpf_controllable () const
{
#ifdef MIXBUS
boost::shared_ptr<PluginInsert> eq = ch_eq();
if (!eq) {
return boost::shared_ptr<AutomationControl>();
}
return boost::dynamic_pointer_cast<ARDOUR::AutomationControl> (eq->control (Evoral::Parameter (ARDOUR::PluginAutomation, 0, 2)));
#else
return boost::shared_ptr<AutomationControl>();
#endif
}
string
Route::eq_band_name (uint32_t band) const
{
if (Profile->get_mixbus()) {
switch (band) {
case 0:
return _("lo");
case 1:
return _("mid");
case 2:
return _("hi");
default:
return string();
}
} else {
return string ();
}
}
boost::shared_ptr<AutomationControl>
Route::comp_enable_controllable () const
{
#ifdef MIXBUS
boost::shared_ptr<PluginInsert> comp = ch_comp();
if (!comp) {
return boost::shared_ptr<AutomationControl>();
}
return boost::dynamic_pointer_cast<ARDOUR::AutomationControl> (comp->control (Evoral::Parameter (ARDOUR::PluginAutomation, 0, 1)));
#else
return boost::shared_ptr<AutomationControl>();
#endif
}
boost::shared_ptr<AutomationControl>
Route::comp_threshold_controllable () const
{
#ifdef MIXBUS
boost::shared_ptr<PluginInsert> comp = ch_comp();
if (!comp) {
return boost::shared_ptr<AutomationControl>();
}
return boost::dynamic_pointer_cast<ARDOUR::AutomationControl> (comp->control (Evoral::Parameter (ARDOUR::PluginAutomation, 0, 2)));
#else
return boost::shared_ptr<AutomationControl>();
#endif
}
boost::shared_ptr<AutomationControl>
Route::comp_speed_controllable () const
{
#ifdef MIXBUS
boost::shared_ptr<PluginInsert> comp = ch_comp();
if (!comp) {
return boost::shared_ptr<AutomationControl>();
}
return boost::dynamic_pointer_cast<ARDOUR::AutomationControl> (comp->control (Evoral::Parameter (ARDOUR::PluginAutomation, 0, 3)));
#else
return boost::shared_ptr<AutomationControl>();
#endif
}
boost::shared_ptr<AutomationControl>
Route::comp_mode_controllable () const
{
#ifdef MIXBUS
boost::shared_ptr<PluginInsert> comp = ch_comp();
if (!comp) {
return boost::shared_ptr<AutomationControl>();
}
return boost::dynamic_pointer_cast<ARDOUR::AutomationControl> (comp->control (Evoral::Parameter (ARDOUR::PluginAutomation, 0, 4)));
#else
return boost::shared_ptr<AutomationControl>();
#endif
}
boost::shared_ptr<AutomationControl>
Route::comp_makeup_controllable () const
{
#ifdef MIXBUS
boost::shared_ptr<PluginInsert> comp = ch_comp();
if (!comp) {
return boost::shared_ptr<AutomationControl>();
}
return boost::dynamic_pointer_cast<ARDOUR::AutomationControl> (comp->control (Evoral::Parameter (ARDOUR::PluginAutomation, 0, 5)));
#else
return boost::shared_ptr<AutomationControl>();
#endif
}
boost::shared_ptr<AutomationControl>
Route::comp_redux_controllable () const
{
#ifdef MIXBUS
boost::shared_ptr<PluginInsert> comp = ch_comp();
if (!comp) {
return boost::shared_ptr<AutomationControl>();
}
return boost::dynamic_pointer_cast<ARDOUR::AutomationControl> (comp->control (Evoral::Parameter (ARDOUR::PluginAutomation, 0, 6)));
#else
return boost::shared_ptr<AutomationControl>();
#endif
}
string
Route::comp_mode_name (uint32_t mode) const
{
#ifdef MIXBUS
switch (mode) {
case 0:
return _("Leveler");
case 1:
return _("Compressor");
case 2:
return _("Limiter");
case 3:
return mixbus() ? _("Sidechain") : _("Limiter");
}
return _("???");
#else
return _("???");
#endif
}
string
Route::comp_speed_name (uint32_t mode) const
{
#ifdef MIXBUS
switch (mode) {
case 0:
return _("Attk");
case 1:
return _("Ratio");
case 2:
case 3:
return _("Rels");
}
return _("???");
#else
return _("???");
#endif
}
boost::shared_ptr<AutomationControl>
Route::send_level_controllable (uint32_t n) const
{
#ifdef MIXBUS
boost::shared_ptr<ARDOUR::PluginInsert> plug = ch_post();
if (!plug) {
return boost::shared_ptr<AutomationControl>();
}
if (n >= 8) {
/* no such bus */
return boost::shared_ptr<AutomationControl>();
}
const uint32_t port_id = port_channel_post_aux1_level + (2*n); // gtk2_ardour/mixbus_ports.h
return boost::dynamic_pointer_cast<ARDOUR::AutomationControl> (plug->control (Evoral::Parameter (ARDOUR::PluginAutomation, 0, port_id)));
#else
boost::shared_ptr<Send> s = boost::dynamic_pointer_cast<Send>(nth_send (n));
if (!s) {
return boost::shared_ptr<AutomationControl>();
}
return s->gain_control ();
#endif
}
boost::shared_ptr<AutomationControl>
Route::send_enable_controllable (uint32_t n) const
{
#ifdef MIXBUS
boost::shared_ptr<ARDOUR::PluginInsert> plug = ch_post();
if (!plug) {
return boost::shared_ptr<AutomationControl>();
}
if (n >= 8) {
/* no such bus */
return boost::shared_ptr<AutomationControl>();
}
const uint32_t port_id = port_channel_post_aux1_asgn + (2*n); // gtk2_ardour/mixbus_ports.h
return boost::dynamic_pointer_cast<ARDOUR::AutomationControl> (plug->control (Evoral::Parameter (ARDOUR::PluginAutomation, 0, port_id)));
#else
/* although Ardour sends have enable/disable as part of the Processor
API, it is not exposed as a controllable.
XXX: we should fix this.
*/
return boost::shared_ptr<AutomationControl>();
#endif
}
string
Route::send_name (uint32_t n) const
{
#ifdef MIXBUS
if (n >= 8) {
return string();
}
boost::shared_ptr<Route> r = _session.get_mixbus (n);
assert (r);
return r->name();
#else
boost::shared_ptr<Processor> p = nth_send (n);
if (p) {
return p->name();
} else {
return string();
}
#endif
}
boost::shared_ptr<AutomationControl>
Route::master_send_enable_controllable () const
{
#ifdef MIXBUS
boost::shared_ptr<ARDOUR::PluginInsert> plug = ch_post();
if (!plug) {
return boost::shared_ptr<AutomationControl>();
}
return boost::dynamic_pointer_cast<ARDOUR::AutomationControl> (plug->control (Evoral::Parameter (ARDOUR::PluginAutomation, 0, port_channel_post_mstr_assign)));
#else
return boost::shared_ptr<AutomationControl>();
#endif
}
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