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livetrax/gtk2_ardour/automation_line.cc
Robin Gareus 4050ca5633
Update GPL boilerplate and (C)
Copyright-holder and year information is extracted from git log.

git history begins in 2005. So (C) from 1998..2005 is lost. Also some
(C) assignment of commits where the committer didn't use --author.
2019-08-03 15:53:15 +02:00

1374 lines
35 KiB
C++

/*
* Copyright (C) 2005-2017 Paul Davis <paul@linuxaudiosystems.com>
* Copyright (C) 2005 Karsten Wiese <fzuuzf@googlemail.com>
* Copyright (C) 2005 Taybin Rutkin <taybin@taybin.com>
* Copyright (C) 2006 Hans Fugal <hans@fugal.net>
* Copyright (C) 2007-2012 Carl Hetherington <carl@carlh.net>
* Copyright (C) 2007-2015 David Robillard <d@drobilla.net>
* Copyright (C) 2007 Doug McLain <doug@nostar.net>
* Copyright (C) 2013-2017 Robin Gareus <robin@gareus.org>
* Copyright (C) 2014-2016 Nick Mainsbridge <mainsbridge@gmail.com>
*
* This program is free software; you can redistribute it and/or modify
* it under the terms of the GNU General Public License as published by
* the Free Software Foundation; either version 2 of the License, or
* (at your option) any later version.
*
* This program is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
* GNU General Public License for more details.
*
* You should have received a copy of the GNU General Public License along
* with this program; if not, write to the Free Software Foundation, Inc.,
* 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA.
*/
#include <cmath>
#ifdef COMPILER_MSVC
#include <float.h>
// 'std::isnan()' is not available in MSVC.
#define isnan_local(val) (bool)_isnan((double)val)
#else
#define isnan_local std::isnan
#endif
#include <climits>
#include <vector>
#include "boost/shared_ptr.hpp"
#include "pbd/floating.h"
#include "pbd/memento_command.h"
#include "pbd/stl_delete.h"
#include "pbd/stacktrace.h"
#include "ardour/automation_list.h"
#include "ardour/dB.h"
#include "ardour/debug.h"
#include "ardour/parameter_types.h"
#include "ardour/tempo.h"
#include "evoral/Curve.hpp"
#include "canvas/debug.h"
#include "automation_line.h"
#include "control_point.h"
#include "gui_thread.h"
#include "rgb_macros.h"
#include "public_editor.h"
#include "selection.h"
#include "time_axis_view.h"
#include "point_selection.h"
#include "automation_time_axis.h"
#include "ui_config.h"
#include "ardour/event_type_map.h"
#include "ardour/session.h"
#include "ardour/value_as_string.h"
#include "pbd/i18n.h"
using namespace std;
using namespace ARDOUR;
using namespace PBD;
using namespace Editing;
/** @param converter A TimeConverter whose origin_b is the start time of the AutomationList in session samples.
* This will not be deleted by AutomationLine.
*/
AutomationLine::AutomationLine (const string& name,
TimeAxisView& tv,
ArdourCanvas::Item& parent,
boost::shared_ptr<AutomationList> al,
const ParameterDescriptor& desc,
Evoral::TimeConverter<double, samplepos_t>* converter)
: trackview (tv)
, _name (name)
, alist (al)
, _time_converter (converter ? converter : new Evoral::IdentityConverter<double, samplepos_t>)
, _parent_group (parent)
, _offset (0)
, _maximum_time (max_samplepos)
, _fill (false)
, _desc (desc)
{
if (converter) {
_our_time_converter = false;
} else {
_our_time_converter = true;
}
_visible = Line;
update_pending = false;
have_timeout = false;
no_draw = false;
_is_boolean = false;
terminal_points_can_slide = true;
_height = 0;
group = new ArdourCanvas::Container (&parent, ArdourCanvas::Duple(0, 1.5));
CANVAS_DEBUG_NAME (group, "region gain envelope group");
line = new ArdourCanvas::PolyLine (group);
CANVAS_DEBUG_NAME (line, "region gain envelope line");
line->set_data ("line", this);
line->set_outline_width (2.0);
line->set_covers_threshold (4.0);
line->Event.connect (sigc::mem_fun (*this, &AutomationLine::event_handler));
trackview.session()->register_with_memento_command_factory(alist->id(), this);
interpolation_changed (alist->interpolation ());
connect_to_list ();
}
AutomationLine::~AutomationLine ()
{
vector_delete (&control_points);
delete group;
if (_our_time_converter) {
delete _time_converter;
}
}
bool
AutomationLine::event_handler (GdkEvent* event)
{
return PublicEditor::instance().canvas_line_event (event, line, this);
}
bool
AutomationLine::is_stepped() const
{
return (_desc.toggled ||
(alist && alist->interpolation() == AutomationList::Discrete));
}
void
AutomationLine::update_visibility ()
{
if (_visible & Line) {
/* Only show the line when there are some points, otherwise we may show an out-of-date line
when automation points have been removed (the line will still follow the shape of the
old points).
*/
if (control_points.size() >= 2) {
line->show();
} else {
line->hide ();
}
if (_visible & ControlPoints) {
for (vector<ControlPoint*>::iterator i = control_points.begin(); i != control_points.end(); ++i) {
(*i)->show ();
}
} else if (_visible & SelectedControlPoints) {
for (vector<ControlPoint*>::iterator i = control_points.begin(); i != control_points.end(); ++i) {
if ((*i)->selected()) {
(*i)->show ();
} else {
(*i)->hide ();
}
}
} else {
for (vector<ControlPoint*>::iterator i = control_points.begin(); i != control_points.end(); ++i) {
(*i)->hide ();
}
}
} else {
line->hide ();
for (vector<ControlPoint*>::iterator i = control_points.begin(); i != control_points.end(); ++i) {
if (_visible & ControlPoints) {
(*i)->show ();
} else {
(*i)->hide ();
}
}
}
}
bool
AutomationLine::get_uses_gain_mapping () const
{
switch (_desc.type) {
case GainAutomation:
case EnvelopeAutomation:
case TrimAutomation:
return true;
default:
return false;
}
}
void
AutomationLine::hide ()
{
/* leave control points setting unchanged, we are just hiding the
overall line
*/
set_visibility (AutomationLine::VisibleAspects (_visible & ~Line));
}
double
AutomationLine::control_point_box_size ()
{
if (_height > TimeAxisView::preset_height (HeightLarger)) {
return 8.0;
} else if (_height > (guint32) TimeAxisView::preset_height (HeightNormal)) {
return 6.0;
}
return 4.0;
}
void
AutomationLine::set_height (guint32 h)
{
if (h != _height) {
_height = h;
double bsz = control_point_box_size();
for (vector<ControlPoint*>::iterator i = control_points.begin(); i != control_points.end(); ++i) {
(*i)->set_size (bsz);
}
if (_fill) {
line->set_fill_y1 (_height);
} else {
line->set_fill_y1 (0);
}
reset ();
}
}
void
AutomationLine::set_line_color (uint32_t color)
{
_line_color = color;
line->set_outline_color (color);
Gtkmm2ext::SVAModifier mod = UIConfiguration::instance().modifier ("automation line fill");
line->set_fill_color ((color & 0xffffff00) + mod.a()*255);
}
ControlPoint*
AutomationLine::nth (uint32_t n)
{
if (n < control_points.size()) {
return control_points[n];
} else {
return 0;
}
}
ControlPoint const *
AutomationLine::nth (uint32_t n) const
{
if (n < control_points.size()) {
return control_points[n];
} else {
return 0;
}
}
void
AutomationLine::modify_point_y (ControlPoint& cp, double y)
{
/* clamp y-coord appropriately. y is supposed to be a normalized fraction (0.0-1.0),
and needs to be converted to a canvas unit distance.
*/
y = max (0.0, y);
y = min (1.0, y);
y = _height - (y * _height);
double const x = trackview.editor().sample_to_pixel_unrounded (_time_converter->to((*cp.model())->when) - _offset);
trackview.editor().begin_reversible_command (_("automation event move"));
trackview.editor().session()->add_command (
new MementoCommand<AutomationList> (memento_command_binder(), &get_state(), 0));
cp.move_to (x, y, ControlPoint::Full);
alist->freeze ();
sync_model_with_view_point (cp);
alist->thaw ();
reset_line_coords (cp);
if (line_points.size() > 1) {
line->set_steps (line_points, is_stepped());
}
update_pending = false;
trackview.editor().session()->add_command (
new MementoCommand<AutomationList> (memento_command_binder(), 0, &alist->get_state()));
trackview.editor().commit_reversible_command ();
trackview.editor().session()->set_dirty ();
}
void
AutomationLine::reset_line_coords (ControlPoint& cp)
{
if (cp.view_index() < line_points.size()) {
line_points[cp.view_index()].x = cp.get_x ();
line_points[cp.view_index()].y = cp.get_y ();
}
}
bool
AutomationLine::sync_model_with_view_points (list<ControlPoint*> cp)
{
update_pending = true;
bool moved = false;
for (list<ControlPoint*>::iterator i = cp.begin(); i != cp.end(); ++i) {
moved = sync_model_with_view_point (**i) || moved;
}
return moved;
}
string
AutomationLine::get_verbose_cursor_string (double fraction) const
{
return fraction_to_string (fraction);
}
string
AutomationLine::get_verbose_cursor_relative_string (double fraction, double delta) const
{
std::string s = fraction_to_string (fraction);
std::string d = delta_to_string (delta);
return s + " (" + d + ")";
}
/**
* @param fraction y fraction
* @return string representation of this value, using dB if appropriate.
*/
string
AutomationLine::fraction_to_string (double fraction) const
{
view_to_model_coord_y (fraction);
return ARDOUR::value_as_string (_desc, fraction);
}
string
AutomationLine::delta_to_string (double delta) const
{
if (!get_uses_gain_mapping () && _desc.logarithmic) {
return "x " + ARDOUR::value_as_string (_desc, delta);
} else {
return "\u0394 " + ARDOUR::value_as_string (_desc, delta);
}
}
/**
* @param s Value string in the form as returned by fraction_to_string.
* @return Corresponding y fraction.
*/
double
AutomationLine::string_to_fraction (string const & s) const
{
double v;
sscanf (s.c_str(), "%lf", &v);
switch (_desc.type) {
case GainAutomation:
case EnvelopeAutomation:
case TrimAutomation:
if (s == "-inf") { /* translation */
v = 0;
} else {
v = dB_to_coefficient (v);
}
break;
default:
break;
}
model_to_view_coord_y (v);
return v;
}
/** Start dragging a single point, possibly adding others if the supplied point is selected and there
* are other selected points.
*
* @param cp Point to drag.
* @param x Initial x position (units).
* @param fraction Initial y position (as a fraction of the track height, where 0 is the bottom and 1 the top)
*/
void
AutomationLine::start_drag_single (ControlPoint* cp, double x, float fraction)
{
trackview.editor().session()->add_command (
new MementoCommand<AutomationList> (memento_command_binder(), &get_state(), 0));
_drag_points.clear ();
_drag_points.push_back (cp);
if (cp->selected ()) {
for (vector<ControlPoint*>::iterator i = control_points.begin(); i != control_points.end(); ++i) {
if (*i != cp && (*i)->selected()) {
_drag_points.push_back (*i);
}
}
}
start_drag_common (x, fraction);
}
/** Start dragging a line vertically (with no change in x)
* @param i1 Control point index of the `left' point on the line.
* @param i2 Control point index of the `right' point on the line.
* @param fraction Initial y position (as a fraction of the track height, where 0 is the bottom and 1 the top)
*/
void
AutomationLine::start_drag_line (uint32_t i1, uint32_t i2, float fraction)
{
trackview.editor().session()->add_command (
new MementoCommand<AutomationList> (memento_command_binder (), &get_state(), 0));
_drag_points.clear ();
for (uint32_t i = i1; i <= i2; i++) {
_drag_points.push_back (nth (i));
}
start_drag_common (0, fraction);
}
/** Start dragging multiple points (with no change in x)
* @param cp Points to drag.
* @param fraction Initial y position (as a fraction of the track height, where 0 is the bottom and 1 the top)
*/
void
AutomationLine::start_drag_multiple (list<ControlPoint*> cp, float fraction, XMLNode* state)
{
trackview.editor().session()->add_command (
new MementoCommand<AutomationList> (memento_command_binder(), state, 0));
_drag_points = cp;
start_drag_common (0, fraction);
}
struct ControlPointSorter
{
bool operator() (ControlPoint const * a, ControlPoint const * b) const {
if (floateq (a->get_x(), b->get_x(), 1)) {
return a->view_index() < b->view_index();
}
return a->get_x() < b->get_x();
}
};
AutomationLine::ContiguousControlPoints::ContiguousControlPoints (AutomationLine& al)
: line (al), before_x (0), after_x (DBL_MAX)
{
}
void
AutomationLine::ContiguousControlPoints::compute_x_bounds (PublicEditor& e)
{
uint32_t sz = size();
if (sz > 0 && sz < line.npoints()) {
const TempoMap& map (e.session()->tempo_map());
/* determine the limits on x-axis motion for this
contiguous range of control points
*/
if (front()->view_index() > 0) {
before_x = line.nth (front()->view_index() - 1)->get_x();
const samplepos_t pos = e.pixel_to_sample(before_x);
const Meter& meter = map.meter_at_sample (pos);
const samplecnt_t len = ceil (meter.samples_per_bar (map.tempo_at_sample (pos), e.session()->sample_rate())
/ (Timecode::BBT_Time::ticks_per_beat * meter.divisions_per_bar()) );
const double one_tick_in_pixels = e.sample_to_pixel_unrounded (len);
before_x += one_tick_in_pixels;
}
/* if our last point has a point after it in the line,
we have an "after" bound
*/
if (back()->view_index() < (line.npoints() - 1)) {
after_x = line.nth (back()->view_index() + 1)->get_x();
const samplepos_t pos = e.pixel_to_sample(after_x);
const Meter& meter = map.meter_at_sample (pos);
const samplecnt_t len = ceil (meter.samples_per_bar (map.tempo_at_sample (pos), e.session()->sample_rate())
/ (Timecode::BBT_Time::ticks_per_beat * meter.divisions_per_bar()));
const double one_tick_in_pixels = e.sample_to_pixel_unrounded (len);
after_x -= one_tick_in_pixels;
}
}
}
double
AutomationLine::ContiguousControlPoints::clamp_dx (double dx)
{
if (empty()) {
return dx;
}
/* get the maximum distance we can move any of these points along the x-axis
*/
double tx; /* possible position a point would move to, given dx */
ControlPoint* cp;
if (dx > 0) {
/* check the last point, since we're moving later in time */
cp = back();
} else {
/* check the first point, since we're moving earlier in time */
cp = front();
}
tx = cp->get_x() + dx; // new possible position if we just add the motion
tx = max (tx, before_x); // can't move later than following point
tx = min (tx, after_x); // can't move earlier than preceeding point
return tx - cp->get_x ();
}
void
AutomationLine::ContiguousControlPoints::move (double dx, double dvalue)
{
for (std::list<ControlPoint*>::iterator i = begin(); i != end(); ++i) {
// compute y-axis delta
double view_y = 1.0 - (*i)->get_y() / line.height();
line.view_to_model_coord_y (view_y);
line.apply_delta (view_y, dvalue);
line.model_to_view_coord_y (view_y);
view_y = (1.0 - view_y) * line.height();
(*i)->move_to ((*i)->get_x() + dx, view_y, ControlPoint::Full);
line.reset_line_coords (**i);
}
}
/** Common parts of starting a drag.
* @param x Starting x position in units, or 0 if x is being ignored.
* @param fraction Starting y position (as a fraction of the track height, where 0 is the bottom and 1 the top)
*/
void
AutomationLine::start_drag_common (double x, float fraction)
{
_drag_x = x;
_drag_distance = 0;
_last_drag_fraction = fraction;
_drag_had_movement = false;
did_push = false;
/* they are probably ordered already, but we have to make sure */
_drag_points.sort (ControlPointSorter());
}
/** Should be called to indicate motion during a drag.
* @param x New x position of the drag in canvas units, or undefined if ignore_x == true.
* @param fraction New y fraction.
* @return x position and y fraction that were actually used (once clamped).
*/
pair<float, float>
AutomationLine::drag_motion (double const x, float fraction, bool ignore_x, bool with_push, uint32_t& final_index)
{
if (_drag_points.empty()) {
return pair<double,float> (fraction, _desc.is_linear () ? 0 : 1);
}
double dx = ignore_x ? 0 : (x - _drag_x);
double dy = fraction - _last_drag_fraction;
if (!_drag_had_movement) {
/* "first move" ... do some stuff that we don't want to do if
no motion ever took place, but need to do before we handle
motion.
*/
/* partition the points we are dragging into (potentially several)
* set(s) of contiguous points. this will not happen with a normal
* drag, but if the user does a discontiguous selection, it can.
*/
uint32_t expected_view_index = 0;
CCP contig;
for (list<ControlPoint*>::iterator i = _drag_points.begin(); i != _drag_points.end(); ++i) {
if (i == _drag_points.begin() || (*i)->view_index() != expected_view_index) {
contig.reset (new ContiguousControlPoints (*this));
contiguous_points.push_back (contig);
}
contig->push_back (*i);
expected_view_index = (*i)->view_index() + 1;
}
if (contiguous_points.back()->empty()) {
contiguous_points.pop_back ();
}
for (vector<CCP>::iterator ccp = contiguous_points.begin(); ccp != contiguous_points.end(); ++ccp) {
(*ccp)->compute_x_bounds (trackview.editor());
}
_drag_had_movement = true;
}
/* OK, now on to the stuff related to *this* motion event. First, for
* each contiguous range, figure out the maximum x-axis motion we are
* allowed (because of neighbouring points that are not moving.
*
* if we are moving forwards with push, we don't need to do this,
* since all later points will move too.
*/
if (dx < 0 || ((dx > 0) && !with_push)) {
for (vector<CCP>::iterator ccp = contiguous_points.begin(); ccp != contiguous_points.end(); ++ccp) {
double dxt = (*ccp)->clamp_dx (dx);
if (fabs (dxt) < fabs (dx)) {
dx = dxt;
}
}
}
/* compute deflection */
double delta_value;
{
double value0 = _last_drag_fraction;
double value1 = _last_drag_fraction + dy;
view_to_model_coord_y (value0);
view_to_model_coord_y (value1);
delta_value = compute_delta (value0, value1);
}
/* special case -inf */
if (delta_value == 0 && dy > 0 && !_desc.is_linear ()) {
assert (_desc.lower == 0);
delta_value = 1.0;
}
/* clamp y */
for (list<ControlPoint*>::iterator i = _drag_points.begin(); i != _drag_points.end(); ++i) {
double vy = 1.0 - (*i)->get_y() / _height;
view_to_model_coord_y (vy);
const double orig = vy;
apply_delta (vy, delta_value);
if (vy < _desc.lower) {
delta_value = compute_delta (orig, _desc.lower);
}
if (vy > _desc.upper) {
delta_value = compute_delta (orig, _desc.upper);
}
}
if (dx || dy) {
/* and now move each section */
for (vector<CCP>::iterator ccp = contiguous_points.begin(); ccp != contiguous_points.end(); ++ccp) {
(*ccp)->move (dx, delta_value);
}
if (with_push) {
final_index = contiguous_points.back()->back()->view_index () + 1;
ControlPoint* p;
uint32_t i = final_index;
while ((p = nth (i)) != 0 && p->can_slide()) {
p->move_to (p->get_x() + dx, p->get_y(), ControlPoint::Full);
reset_line_coords (*p);
++i;
}
}
/* update actual line coordinates (will queue a redraw) */
if (line_points.size() > 1) {
line->set_steps (line_points, is_stepped());
}
}
/* calculate effective delta */
ControlPoint* cp = _drag_points.front();
double vy = 1.0 - cp->get_y() / (double)_height;
view_to_model_coord_y (vy);
float val = (*(cp->model ()))->value;
float effective_delta = _desc.compute_delta (val, vy);
/* special case recovery from -inf */
if (val == 0 && effective_delta == 0 && vy > 0) {
assert (!_desc.is_linear ());
effective_delta = HUGE_VAL; // +Infinity
}
double const result_frac = _last_drag_fraction + dy;
_drag_distance += dx;
_drag_x += dx;
_last_drag_fraction = result_frac;
did_push = with_push;
return pair<float, float> (result_frac, effective_delta);
}
/** Should be called to indicate the end of a drag */
void
AutomationLine::end_drag (bool with_push, uint32_t final_index)
{
if (!_drag_had_movement) {
return;
}
alist->freeze ();
bool moved = sync_model_with_view_points (_drag_points);
if (with_push) {
ControlPoint* p;
uint32_t i = final_index;
while ((p = nth (i)) != 0 && p->can_slide()) {
moved = sync_model_with_view_point (*p) || moved;
++i;
}
}
alist->thaw ();
update_pending = false;
if (moved) {
/* A point has moved as a result of sync (clamped to integer or boolean
value), update line accordingly. */
line->set_steps (line_points, is_stepped());
}
trackview.editor().session()->add_command (
new MementoCommand<AutomationList>(memento_command_binder (), 0, &alist->get_state()));
trackview.editor().session()->set_dirty ();
did_push = false;
contiguous_points.clear ();
}
bool
AutomationLine::sync_model_with_view_point (ControlPoint& cp)
{
/* find out where the visual control point is.
initial results are in canvas units. ask the
line to convert them to something relevant.
*/
double view_x = cp.get_x();
double view_y = 1.0 - cp.get_y() / (double)_height;
/* if xval has not changed, set it directly from the model to avoid rounding errors */
if (view_x == trackview.editor().sample_to_pixel_unrounded (_time_converter->to ((*cp.model())->when)) - _offset) {
view_x = (*cp.model())->when - _offset;
} else {
view_x = trackview.editor().pixel_to_sample (view_x);
view_x = _time_converter->from (view_x + _offset);
}
update_pending = true;
view_to_model_coord_y (view_y);
alist->modify (cp.model(), view_x, view_y);
/* convert back from model to view y for clamping position (for integer/boolean/etc) */
model_to_view_coord_y (view_y);
const double point_y = _height - (view_y * _height);
if (point_y != cp.get_y()) {
cp.move_to (cp.get_x(), point_y, ControlPoint::Full);
reset_line_coords (cp);
return true;
}
return false;
}
bool
AutomationLine::control_points_adjacent (double xval, uint32_t & before, uint32_t& after)
{
ControlPoint *bcp = 0;
ControlPoint *acp = 0;
double unit_xval;
unit_xval = trackview.editor().sample_to_pixel_unrounded (xval);
for (vector<ControlPoint*>::iterator i = control_points.begin(); i != control_points.end(); ++i) {
if ((*i)->get_x() <= unit_xval) {
if (!bcp || (*i)->get_x() > bcp->get_x()) {
bcp = *i;
before = bcp->view_index();
}
} else if ((*i)->get_x() > unit_xval) {
acp = *i;
after = acp->view_index();
break;
}
}
return bcp && acp;
}
bool
AutomationLine::is_last_point (ControlPoint& cp)
{
// If the list is not empty, and the point is the last point in the list
if (alist->empty()) {
return false;
}
AutomationList::const_iterator i = alist->end();
--i;
if (cp.model() == i) {
return true;
}
return false;
}
bool
AutomationLine::is_first_point (ControlPoint& cp)
{
// If the list is not empty, and the point is the first point in the list
if (!alist->empty() && cp.model() == alist->begin()) {
return true;
}
return false;
}
// This is copied into AudioRegionGainLine
void
AutomationLine::remove_point (ControlPoint& cp)
{
trackview.editor().begin_reversible_command (_("remove control point"));
XMLNode &before = alist->get_state();
trackview.editor ().get_selection ().clear_points ();
alist->erase (cp.model());
trackview.editor().session()->add_command(
new MementoCommand<AutomationList> (memento_command_binder (), &before, &alist->get_state()));
trackview.editor().commit_reversible_command ();
trackview.editor().session()->set_dirty ();
}
/** Get selectable points within an area.
* @param start Start position in session samples.
* @param end End position in session samples.
* @param bot Bottom y range, as a fraction of line height, where 0 is the bottom of the line.
* @param top Top y range, as a fraction of line height, where 0 is the bottom of the line.
* @param result Filled in with selectable things; in this case, ControlPoints.
*/
void
AutomationLine::get_selectables (samplepos_t start, samplepos_t end, double botfrac, double topfrac, list<Selectable*>& results)
{
/* convert fractions to display coordinates with 0 at the top of the track */
double const bot_track = (1 - topfrac) * trackview.current_height ();
double const top_track = (1 - botfrac) * trackview.current_height ();
for (vector<ControlPoint*>::iterator i = control_points.begin(); i != control_points.end(); ++i) {
double const model_when = (*(*i)->model())->when;
/* model_when is relative to the start of the source, so we just need to add on the origin_b here
(as it is the session sample position of the start of the source)
*/
samplepos_t const session_samples_when = _time_converter->to (model_when) + _time_converter->origin_b ();
if (session_samples_when >= start && session_samples_when <= end && (*i)->get_y() >= bot_track && (*i)->get_y() <= top_track) {
results.push_back (*i);
}
}
}
void
AutomationLine::get_inverted_selectables (Selection&, list<Selectable*>& /*results*/)
{
// hmmm ....
}
void
AutomationLine::set_selected_points (PointSelection const & points)
{
for (vector<ControlPoint*>::iterator i = control_points.begin(); i != control_points.end(); ++i) {
(*i)->set_selected (false);
}
for (PointSelection::const_iterator i = points.begin(); i != points.end(); ++i) {
(*i)->set_selected (true);
}
if (points.empty()) {
remove_visibility (SelectedControlPoints);
} else {
add_visibility (SelectedControlPoints);
}
set_colors ();
}
void
AutomationLine::set_colors ()
{
set_line_color (UIConfiguration::instance().color ("automation line"));
for (vector<ControlPoint*>::iterator i = control_points.begin(); i != control_points.end(); ++i) {
(*i)->set_color ();
}
}
void
AutomationLine::list_changed ()
{
DEBUG_TRACE (DEBUG::Automation, string_compose ("\tline changed, existing update pending? %1\n", update_pending));
if (!update_pending) {
update_pending = true;
Gtkmm2ext::UI::instance()->call_slot (invalidator (*this), boost::bind (&AutomationLine::queue_reset, this));
}
}
void
AutomationLine::reset_callback (const Evoral::ControlList& events)
{
uint32_t vp = 0;
uint32_t pi = 0;
uint32_t np;
if (events.empty()) {
for (vector<ControlPoint*>::iterator i = control_points.begin(); i != control_points.end(); ++i) {
delete *i;
}
control_points.clear ();
line->hide();
return;
}
/* hide all existing points, and the line */
for (vector<ControlPoint*>::iterator i = control_points.begin(); i != control_points.end(); ++i) {
(*i)->hide();
}
line->hide ();
np = events.size();
Evoral::ControlList& e = const_cast<Evoral::ControlList&> (events);
for (AutomationList::iterator ai = e.begin(); ai != e.end(); ++ai, ++pi) {
double tx = (*ai)->when;
double ty = (*ai)->value;
/* convert from model coordinates to canonical view coordinates */
model_to_view_coord (tx, ty);
if (isnan_local (tx) || isnan_local (ty)) {
warning << string_compose (_("Ignoring illegal points on AutomationLine \"%1\""),
_name) << endmsg;
continue;
}
if (tx >= max_samplepos || tx < 0 || tx >= _maximum_time) {
continue;
}
/* convert x-coordinate to a canvas unit coordinate (this takes
* zoom and scroll into account).
*/
tx = trackview.editor().sample_to_pixel_unrounded (tx);
/* convert from canonical view height (0..1.0) to actual
* height coordinates (using X11's top-left rooted system)
*/
ty = _height - (ty * _height);
add_visible_control_point (vp, pi, tx, ty, ai, np);
vp++;
}
/* discard extra CP's to avoid confusing ourselves */
while (control_points.size() > vp) {
ControlPoint* cp = control_points.back();
control_points.pop_back ();
delete cp;
}
if (!terminal_points_can_slide) {
control_points.back()->set_can_slide(false);
}
if (vp > 1) {
/* reset the line coordinates given to the CanvasLine */
while (line_points.size() < vp) {
line_points.push_back (ArdourCanvas::Duple (0,0));
}
while (line_points.size() > vp) {
line_points.pop_back ();
}
for (uint32_t n = 0; n < vp; ++n) {
line_points[n].x = control_points[n]->get_x();
line_points[n].y = control_points[n]->get_y();
}
line->set_steps (line_points, is_stepped());
update_visibility ();
}
set_selected_points (trackview.editor().get_selection().points);
}
void
AutomationLine::reset ()
{
DEBUG_TRACE (DEBUG::Automation, "\t\tLINE RESET\n");
update_pending = false;
have_timeout = false;
if (no_draw) {
return;
}
/* TODO: abort any drags in progress, e.g. draging points while writing automation
* (the control-point model, used by AutomationLine::drag_motion, will be invalid).
*
* Note: reset() may also be called from an aborted drag (LineDrag::aborted)
* maybe abort in list_changed(), interpolation_changed() and ... ?
* XXX
*/
alist->apply_to_points (*this, &AutomationLine::reset_callback);
}
void
AutomationLine::queue_reset ()
{
/* this must be called from the GUI thread */
if (trackview.editor().session()->transport_rolling() && alist->automation_write()) {
/* automation write pass ... defer to a timeout */
/* redraw in 1/4 second */
if (!have_timeout) {
DEBUG_TRACE (DEBUG::Automation, "\tqueue timeout\n");
Glib::signal_timeout().connect (sigc::bind_return (sigc::mem_fun (*this, &AutomationLine::reset), false), 250);
have_timeout = true;
} else {
DEBUG_TRACE (DEBUG::Automation, "\ttimeout already queued, change ignored\n");
}
} else {
reset ();
}
}
void
AutomationLine::clear ()
{
/* parent must create and commit command */
XMLNode &before = alist->get_state();
alist->clear();
trackview.editor().session()->add_command (
new MementoCommand<AutomationList> (memento_command_binder (), &before, &alist->get_state()));
}
void
AutomationLine::set_list (boost::shared_ptr<ARDOUR::AutomationList> list)
{
alist = list;
queue_reset ();
connect_to_list ();
}
void
AutomationLine::add_visibility (VisibleAspects va)
{
VisibleAspects old = _visible;
_visible = VisibleAspects (_visible | va);
if (old != _visible) {
update_visibility ();
}
}
void
AutomationLine::set_visibility (VisibleAspects va)
{
if (_visible != va) {
_visible = va;
update_visibility ();
}
}
void
AutomationLine::remove_visibility (VisibleAspects va)
{
VisibleAspects old = _visible;
_visible = VisibleAspects (_visible & ~va);
if (old != _visible) {
update_visibility ();
}
}
void
AutomationLine::track_entered()
{
add_visibility (ControlPoints);
}
void
AutomationLine::track_exited()
{
remove_visibility (ControlPoints);
}
XMLNode &
AutomationLine::get_state (void)
{
/* function as a proxy for the model */
return alist->get_state();
}
int
AutomationLine::set_state (const XMLNode &node, int version)
{
/* function as a proxy for the model */
return alist->set_state (node, version);
}
void
AutomationLine::view_to_model_coord (double& x, double& y) const
{
x = _time_converter->from (x);
view_to_model_coord_y (y);
}
void
AutomationLine::view_to_model_coord_y (double& y) const
{
if (alist->default_interpolation () != alist->interpolation()) {
switch (alist->interpolation()) {
case AutomationList::Discrete:
/* toggles and MIDI only -- see is_stepped() */
assert (alist->default_interpolation () == AutomationList::Linear);
break;
case AutomationList::Linear:
y = y * (_desc.upper - _desc.lower) + _desc.lower;
return;
default:
/* types that default to linear, can't be use
* Logarithmic or Exponential interpolation.
* "Curved" is invalid for automation (only x-fads)
*/
assert (0);
break;
}
}
y = _desc.from_interface (y);
}
double
AutomationLine::compute_delta (double from, double to) const
{
return _desc.compute_delta (from, to);
}
void
AutomationLine::apply_delta (double& val, double delta) const
{
if (val == 0 && !_desc.is_linear () && delta >= 1.0) {
/* recover from -inf */
val = 1.0 / _height;
view_to_model_coord_y (val);
return;
}
val = _desc.apply_delta (val, delta);
}
void
AutomationLine::model_to_view_coord_y (double& y) const
{
if (alist->default_interpolation () != alist->interpolation()) {
switch (alist->interpolation()) {
case AutomationList::Discrete:
/* toggles and MIDI only -- see is_stepped */
assert (alist->default_interpolation () == AutomationList::Linear);
break;
case AutomationList::Linear:
y = (y - _desc.lower) / (_desc.upper - _desc.lower);
return;
default:
/* types that default to linear, can't be use
* Logarithmic or Exponential interpolation.
* "Curved" is invalid for automation (only x-fads)
*/
assert (0);
break;
}
}
y = _desc.to_interface (y);
}
void
AutomationLine::model_to_view_coord (double& x, double& y) const
{
model_to_view_coord_y (y);
x = _time_converter->to (x) - _offset;
}
/** Called when our list has announced that its interpolation style has changed */
void
AutomationLine::interpolation_changed (AutomationList::InterpolationStyle style)
{
if (line_points.size() > 1) {
reset ();
line->set_steps(line_points, is_stepped());
}
}
void
AutomationLine::add_visible_control_point (uint32_t view_index, uint32_t pi, double tx, double ty,
AutomationList::iterator model, uint32_t npoints)
{
ControlPoint::ShapeType shape;
if (view_index >= control_points.size()) {
/* make sure we have enough control points */
ControlPoint* ncp = new ControlPoint (*this);
ncp->set_size (control_point_box_size ());
control_points.push_back (ncp);
}
if (!terminal_points_can_slide) {
if (pi == 0) {
control_points[view_index]->set_can_slide (false);
if (tx == 0) {
shape = ControlPoint::Start;
} else {
shape = ControlPoint::Full;
}
} else if (pi == npoints - 1) {
control_points[view_index]->set_can_slide (false);
shape = ControlPoint::End;
} else {
control_points[view_index]->set_can_slide (true);
shape = ControlPoint::Full;
}
} else {
control_points[view_index]->set_can_slide (true);
shape = ControlPoint::Full;
}
control_points[view_index]->reset (tx, ty, model, view_index, shape);
/* finally, control visibility */
if (_visible & ControlPoints) {
control_points[view_index]->show ();
} else {
control_points[view_index]->hide ();
}
}
void
AutomationLine::connect_to_list ()
{
_list_connections.drop_connections ();
alist->StateChanged.connect (_list_connections, invalidator (*this), boost::bind (&AutomationLine::list_changed, this), gui_context());
alist->InterpolationChanged.connect (
_list_connections, invalidator (*this), boost::bind (&AutomationLine::interpolation_changed, this, _1), gui_context());
}
MementoCommandBinder<AutomationList>*
AutomationLine::memento_command_binder ()
{
return new SimpleMementoCommandBinder<AutomationList> (*alist.get());
}
/** Set the maximum time that points on this line can be at, relative
* to the start of the track or region that it is on.
*/
void
AutomationLine::set_maximum_time (samplecnt_t t)
{
if (_maximum_time == t) {
return;
}
_maximum_time = t;
reset ();
}
/** @return min and max x positions of points that are in the list, in session samples */
pair<samplepos_t, samplepos_t>
AutomationLine::get_point_x_range () const
{
pair<samplepos_t, samplepos_t> r (max_samplepos, 0);
for (AutomationList::const_iterator i = the_list()->begin(); i != the_list()->end(); ++i) {
r.first = min (r.first, session_position (i));
r.second = max (r.second, session_position (i));
}
return r;
}
samplepos_t
AutomationLine::session_position (AutomationList::const_iterator p) const
{
return _time_converter->to ((*p)->when) + _offset + _time_converter->origin_b ();
}
void
AutomationLine::set_offset (samplepos_t off)
{
if (_offset == off) {
return;
}
_offset = off;
reset ();
}