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livetrax/libs/canvas/item.cc
Paul Davis 4fa4b9a135 remove use of boost::optional to define "undefined" Canvas::Rect, and use Rect::empty instead.
This commit includes Rect::operator bool() which might be a candidate for removal in a future commit, in an attempt
to make the meaning clearer
2017-01-19 20:54:54 +01:00

1139 lines
19 KiB
C++

/*
Copyright (C) 2011-2013 Paul Davis
Author: Carl Hetherington <cth@carlh.net>
This program is free software; you can redistribute it and/or modify
it under the terms of the GNU General Public License as published by
the Free Software Foundation; either version 2 of the License, or
(at your option) any later version.
This program is distributed in the hope that it will be useful,
but WITHOUT ANY WARRANTY; without even the implied warranty of
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
GNU General Public License for more details.
You should have received a copy of the GNU General Public License
along with this program; if not, write to the Free Software
Foundation, Inc., 675 Mass Ave, Cambridge, MA 02139, USA.
*/
#include "pbd/compose.h"
#include "pbd/demangle.h"
#include "pbd/convert.h"
#include "ardour/utils.h"
#include "canvas/canvas.h"
#include "canvas/debug.h"
#include "canvas/item.h"
#include "canvas/scroll_group.h"
using namespace std;
using namespace PBD;
using namespace ArdourCanvas;
int Item::default_items_per_cell = 64;
Item::Item (Canvas* canvas)
: Fill (*this)
, Outline (*this)
, _canvas (canvas)
, _parent (0)
, _scroll_parent (0)
, _visible (true)
, _bounding_box_dirty (true)
, _lut (0)
, _ignore_events (false)
{
DEBUG_TRACE (DEBUG::CanvasItems, string_compose ("new canvas item %1\n", this));
}
Item::Item (Item* parent)
: Fill (*this)
, Outline (*this)
, _canvas (parent->canvas())
, _parent (parent)
, _scroll_parent (0)
, _visible (true)
, _bounding_box_dirty (true)
, _lut (0)
, _ignore_events (false)
{
DEBUG_TRACE (DEBUG::CanvasItems, string_compose ("new canvas item %1\n", this));
if (parent) {
_parent->add (this);
}
find_scroll_parent ();
}
Item::Item (Item* parent, Duple const& p)
: Fill (*this)
, Outline (*this)
, _canvas (parent->canvas())
, _parent (parent)
, _scroll_parent (0)
, _position (p)
, _visible (true)
, _bounding_box_dirty (true)
, _lut (0)
, _ignore_events (false)
{
DEBUG_TRACE (DEBUG::CanvasItems, string_compose ("new canvas item %1\n", this));
if (parent) {
_parent->add (this);
}
find_scroll_parent ();
}
Item::~Item ()
{
if (_parent) {
_parent->remove (this);
}
if (_canvas) {
_canvas->item_going_away (this, _bounding_box);
}
clear_items (true);
delete _lut;
}
bool
Item::visible() const
{
Item const * i = this;
while (i) {
if (!i->self_visible()) {
return false;
}
i = i->parent();
}
return true;
}
Duple
Item::canvas_origin () const
{
return item_to_canvas (Duple (0,0));
}
Duple
Item::window_origin () const
{
/* This is slightly subtle. Our _position is in the coordinate space of
our parent. So to find out where that is in window coordinates, we
have to ask our parent.
*/
if (_parent) {
return _parent->item_to_window (_position);
} else {
return _position;
}
}
ArdourCanvas::Rect
Item::item_to_parent (ArdourCanvas::Rect const & r) const
{
return r.translate (_position);
}
Duple
Item::scroll_offset () const
{
if (_scroll_parent) {
return _scroll_parent->scroll_offset();
}
return Duple (0,0);
}
Duple
Item::position_offset() const
{
Item const * i = this;
Duple offset;
while (i) {
offset = offset.translate (i->position());
i = i->parent();
}
return offset;
}
ArdourCanvas::Rect
Item::item_to_canvas (ArdourCanvas::Rect const & r) const
{
return r.translate (position_offset());
}
ArdourCanvas::Duple
Item::item_to_canvas (ArdourCanvas::Duple const & d) const
{
return d.translate (position_offset());
}
ArdourCanvas::Duple
Item::canvas_to_item (ArdourCanvas::Duple const & r) const
{
return r.translate (-position_offset());
}
ArdourCanvas::Rect
Item::canvas_to_item (ArdourCanvas::Rect const & r) const
{
return r.translate (-position_offset());
}
void
Item::item_to_canvas (Coord& x, Coord& y) const
{
Duple d = item_to_canvas (Duple (x, y));
x = d.x;
y = d.y;
}
void
Item::canvas_to_item (Coord& x, Coord& y) const
{
Duple d = canvas_to_item (Duple (x, y));
x = d.x;
y = d.y;
}
Duple
Item::item_to_window (ArdourCanvas::Duple const & d, bool rounded) const
{
Duple ret = item_to_canvas (d).translate (-scroll_offset());
if (rounded) {
ret.x = round (ret.x);
ret.y = round (ret.y);
}
return ret;
}
Duple
Item::window_to_item (ArdourCanvas::Duple const & d) const
{
return canvas_to_item (d.translate (scroll_offset()));
}
ArdourCanvas::Rect
Item::item_to_window (ArdourCanvas::Rect const & r, bool rounded) const
{
Rect ret = item_to_canvas (r).translate (-scroll_offset());
if (rounded) {
ret.x0 = round (ret.x0);
ret.x1 = round (ret.x1);
ret.y0 = round (ret.y0);
ret.y1 = round (ret.y1);
}
return ret;
}
ArdourCanvas::Rect
Item::window_to_item (ArdourCanvas::Rect const & r) const
{
return canvas_to_item (r.translate (scroll_offset()));
}
/** Set the position of this item in the parent's coordinates */
void
Item::set_position (Duple p)
{
if (p == _position) {
return;
}
ArdourCanvas::Rect bbox = bounding_box ();
ArdourCanvas::Rect pre_change_parent_bounding_box;
if (bbox) {
/* see the comment in Canvas::item_moved() to understand
* why we use the parent's bounding box here.
*/
pre_change_parent_bounding_box = item_to_parent (bbox);
}
_position = p;
/* only update canvas and parent if visible. Otherwise, this
will be done when ::show() is called.
*/
if (visible()) {
_canvas->item_moved (this, pre_change_parent_bounding_box);
if (_parent) {
_parent->child_changed ();
}
}
}
void
Item::set_x_position (Coord x)
{
set_position (Duple (x, _position.y));
}
void
Item::set_y_position (Coord y)
{
set_position (Duple (_position.x, y));
}
void
Item::raise_to_top ()
{
if (_parent) {
_parent->raise_child_to_top (this);
}
}
void
Item::raise (int levels)
{
if (_parent) {
_parent->raise_child (this, levels);
}
}
void
Item::lower_to_bottom ()
{
if (_parent) {
_parent->lower_child_to_bottom (this);
}
}
void
Item::hide ()
{
if (_visible) {
_visible = false;
/* children are all hidden because we are hidden, no need
to propagate change because our bounding box necessarily
includes them all already. thus our being hidden results
in (a) a redraw of the entire bounding box (b) no children
will be drawn.
BUT ... current item in canvas might be one of our children,
which is now hidden. So propagate away.
*/
for (list<Item*>::iterator i = _items.begin(); i != _items.end(); ++i) {
if ((*i)->self_visible()) {
/* item was visible but is now hidden because
we (its parent) are hidden
*/
(*i)->propagate_show_hide ();
}
}
propagate_show_hide ();
}
}
void
Item::show ()
{
if (!_visible) {
_visible = true;
for (list<Item*>::iterator i = _items.begin(); i != _items.end(); ++i) {
if ((*i)->self_visible()) {
/* item used to be hidden by us (its parent),
but is now visible
*/
(*i)->propagate_show_hide ();
}
}
propagate_show_hide ();
}
}
void
Item::propagate_show_hide ()
{
/* bounding box may have changed while we were hidden */
if (_parent) {
_parent->child_changed ();
}
_canvas->item_shown_or_hidden (this);
}
Duple
Item::item_to_parent (Duple const & d) const
{
return d.translate (_position);
}
Duple
Item::parent_to_item (Duple const & d) const
{
return d.translate (- _position);
}
ArdourCanvas::Rect
Item::parent_to_item (ArdourCanvas::Rect const & d) const
{
return d.translate (- _position);
}
void
Item::unparent ()
{
_parent = 0;
_scroll_parent = 0;
}
void
Item::reparent (Item* new_parent, bool already_added)
{
if (new_parent == _parent) {
return;
}
assert (_canvas == new_parent->canvas());
if (_parent) {
_parent->remove (this);
}
assert (new_parent);
_parent = new_parent;
_canvas = _parent->canvas ();
find_scroll_parent ();
if (!already_added) {
_parent->add (this);
}
}
void
Item::find_scroll_parent ()
{
Item const * i = this;
ScrollGroup const * last_scroll_group = 0;
/* Don't allow a scroll group to find itself as its own scroll parent
*/
i = i->parent ();
while (i) {
ScrollGroup const * sg = dynamic_cast<ScrollGroup const *> (i);
if (sg) {
last_scroll_group = sg;
}
i = i->parent();
}
_scroll_parent = const_cast<ScrollGroup*> (last_scroll_group);
}
bool
Item::common_ancestor_within (uint32_t limit, const Item& other) const
{
uint32_t d1 = depth();
uint32_t d2 = other.depth();
const Item* i1 = this;
const Item* i2 = &other;
/* move towards root until we are at the same level
for both items
*/
while (d1 != d2) {
if (d1 > d2) {
if (!i1) {
return false;
}
i1 = i1->parent();
d1--;
limit--;
} else {
if (!i2) {
return false;
}
i2 = i2->parent();
d2--;
limit--;
}
if (limit == 0) {
return false;
}
}
/* now see if there is a common parent */
while (i1 != i2) {
if (i1) {
i1 = i1->parent();
}
if (i2) {
i2 = i2->parent ();
}
limit--;
if (limit == 0) {
return false;
}
}
return true;
}
const Item*
Item::closest_ancestor_with (const Item& other) const
{
uint32_t d1 = depth();
uint32_t d2 = other.depth();
const Item* i1 = this;
const Item* i2 = &other;
/* move towards root until we are at the same level
for both items
*/
while (d1 != d2) {
if (d1 > d2) {
if (!i1) {
return 0;
}
i1 = i1->parent();
d1--;
} else {
if (!i2) {
return 0;
}
i2 = i2->parent();
d2--;
}
}
/* now see if there is a common parent */
while (i1 != i2) {
if (i1) {
i1 = i1->parent();
}
if (i2) {
i2 = i2->parent ();
}
}
return i1;
}
bool
Item::is_descendant_of (const Item& candidate) const
{
Item const * i = _parent;
while (i) {
if (i == &candidate) {
return true;
}
i = i->parent();
}
return false;
}
void
Item::grab_focus ()
{
/* XXX */
}
/** @return Bounding box in this item's coordinates */
ArdourCanvas::Rect
Item::bounding_box () const
{
if (_bounding_box_dirty) {
compute_bounding_box ();
assert (!_bounding_box_dirty);
add_child_bounding_boxes ();
}
return _bounding_box;
}
Coord
Item::height () const
{
ArdourCanvas::Rect bb = bounding_box();
if (bb) {
return bb.height ();
}
return 0;
}
Coord
Item::width () const
{
ArdourCanvas::Rect bb = bounding_box();
if (bb) {
return bb.width ();
}
return 0;
}
void
Item::redraw () const
{
if (visible() && _bounding_box && _canvas) {
_canvas->request_redraw (item_to_window (_bounding_box));
}
}
void
Item::begin_change ()
{
_pre_change_bounding_box = bounding_box ();
}
void
Item::end_change ()
{
if (visible()) {
_canvas->item_changed (this, _pre_change_bounding_box);
if (_parent) {
_parent->child_changed ();
}
}
}
void
Item::begin_visual_change ()
{
}
void
Item::end_visual_change ()
{
if (visible()) {
_canvas->item_visual_property_changed (this);
}
}
void
Item::move (Duple movement)
{
set_position (position() + movement);
}
void
Item::grab ()
{
assert (_canvas);
_canvas->grab (this);
}
void
Item::ungrab ()
{
assert (_canvas);
_canvas->ungrab ();
}
void
Item::set_data (string const & key, void* data)
{
_data[key] = data;
}
void *
Item::get_data (string const & key) const
{
map<string, void*>::const_iterator i = _data.find (key);
if (i == _data.end ()) {
return 0;
}
return i->second;
}
void
Item::set_ignore_events (bool ignore)
{
_ignore_events = ignore;
}
std::string
Item::whatami () const
{
std::string type = demangle (typeid (*this).name());
return type.substr (type.find_last_of (':') + 1);
}
uint32_t
Item::depth () const
{
Item* i = _parent;
int d = 0;
while (i) {
++d;
i = i->parent();
}
return d;
}
bool
Item::covers (Duple const & point) const
{
Duple p = window_to_item (point);
if (_bounding_box_dirty) {
compute_bounding_box ();
}
Rect r = bounding_box();
if (!r) {
return false;
}
return r.contains (p);
}
/* nesting/grouping API */
void
Item::render_children (Rect const & area, Cairo::RefPtr<Cairo::Context> context) const
{
if (_items.empty()) {
return;
}
ensure_lut ();
std::vector<Item*> items = _lut->get (area);
#ifdef CANVAS_DEBUG
if (DEBUG_ENABLED(PBD::DEBUG::CanvasRender)) {
cerr << string_compose ("%1%7 %2 @ %7 render %5 @ %6 %3 items out of %4\n",
_canvas->render_indent(), (name.empty() ? string ("[unnamed]") : name), items.size(), _items.size(), area, _position, this,
whatami());
}
#endif
++render_depth;
for (std::vector<Item*>::const_iterator i = items.begin(); i != items.end(); ++i) {
if (!(*i)->visible ()) {
#ifdef CANVAS_DEBUG
if (DEBUG_ENABLED(PBD::DEBUG::CanvasRender)) {
cerr << _canvas->render_indent() << "Item " << (*i)->whatami() << " [" << (*i)->name << "] invisible - skipped\n";
}
#endif
continue;
}
Rect item_bbox = (*i)->bounding_box ();
if (!item_bbox) {
#ifdef CANVAS_DEBUG
if (DEBUG_ENABLED(PBD::DEBUG::CanvasRender)) {
cerr << _canvas->render_indent() << "Item " << (*i)->whatami() << " [" << (*i)->name << "] empty - skipped\n";
}
#endif
continue;
}
Rect item = (*i)->item_to_window (item_bbox, false);
Rect d = item.intersection (area);
if (d) {
Rect draw = d;
if (draw.width() && draw.height()) {
#ifdef CANVAS_DEBUG
if (DEBUG_ENABLED(PBD::DEBUG::CanvasRender)) {
if (dynamic_cast<Container*>(*i) == 0) {
cerr << _canvas->render_indent() << "render "
<< ' '
<< (*i)
<< ' '
<< (*i)->whatami()
<< ' '
<< (*i)->name
<< " item "
<< item_bbox
<< " window = "
<< item
<< " intersect = "
<< draw
<< " @ "
<< _position
<< endl;
}
}
#endif
(*i)->render (area, context);
++render_count;
}
} else {
#ifdef CANVAS_DEBUG
if (DEBUG_ENABLED(PBD::DEBUG::CanvasRender)) {
cerr << string_compose ("%1skip render of %2 %3, no intersection between %4 and %5\n", _canvas->render_indent(), (*i)->whatami(),
(*i)->name, item, area);
}
#endif
}
}
--render_depth;
}
void
Item::add_child_bounding_boxes (bool include_hidden) const
{
Rect self;
Rect bbox;
bool have_one = false;
if (_bounding_box) {
bbox = _bounding_box;
have_one = true;
}
for (list<Item*>::const_iterator i = _items.begin(); i != _items.end(); ++i) {
if (!(*i)->visible() && !include_hidden) {
continue;
}
Rect item_bbox = (*i)->bounding_box ();
if (!item_bbox) {
continue;
}
Rect group_bbox = (*i)->item_to_parent (item_bbox);
if (have_one) {
bbox = bbox.extend (group_bbox);
} else {
bbox = group_bbox;
have_one = true;
}
}
if (!have_one) {
_bounding_box = Rect ();
} else {
_bounding_box = bbox;
}
}
void
Item::add (Item* i)
{
/* XXX should really notify canvas about this */
_items.push_back (i);
i->reparent (this, true);
invalidate_lut ();
_bounding_box_dirty = true;
}
void
Item::add_front (Item* i)
{
/* XXX should really notify canvas about this */
_items.push_front (i);
i->reparent (this, true);
invalidate_lut ();
_bounding_box_dirty = true;
}
void
Item::remove (Item* i)
{
if (i->parent() != this) {
return;
}
/* we cannot call bounding_box() here because that will iterate over
_items, one of which (the argument, i) may be in the middle of
deletion, making it impossible to call compute_bounding_box()
on it.
*/
if (_bounding_box) {
_pre_change_bounding_box = _bounding_box;
} else {
_pre_change_bounding_box = Rect();
}
i->unparent ();
_items.remove (i);
invalidate_lut ();
_bounding_box_dirty = true;
end_change ();
}
void
Item::clear (bool with_delete)
{
begin_change ();
clear_items (with_delete);
invalidate_lut ();
_bounding_box_dirty = true;
end_change ();
}
void
Item::clear_items (bool with_delete)
{
for (list<Item*>::iterator i = _items.begin(); i != _items.end(); ) {
list<Item*>::iterator tmp = i;
Item *item = *i;
++tmp;
/* remove from list before doing anything else, because we
* don't want to find the item in _items during any activity
* driven by unparent-ing or deletion.
*/
_items.erase (i);
item->unparent ();
if (with_delete) {
delete item;
}
i = tmp;
}
}
void
Item::raise_child_to_top (Item* i)
{
if (!_items.empty()) {
if (_items.back() == i) {
return;
}
}
_items.remove (i);
_items.push_back (i);
invalidate_lut ();
redraw ();
}
void
Item::raise_child (Item* i, int levels)
{
list<Item*>::iterator j = find (_items.begin(), _items.end(), i);
assert (j != _items.end ());
++j;
_items.remove (i);
while (levels > 0 && j != _items.end ()) {
++j;
--levels;
}
_items.insert (j, i);
invalidate_lut ();
redraw ();
}
void
Item::lower_child_to_bottom (Item* i)
{
if (!_items.empty()) {
if (_items.front() == i) {
return;
}
}
_items.remove (i);
_items.push_front (i);
invalidate_lut ();
redraw ();
}
void
Item::ensure_lut () const
{
if (!_lut) {
_lut = new DumbLookupTable (*this);
}
}
void
Item::invalidate_lut () const
{
delete _lut;
_lut = 0;
}
void
Item::child_changed ()
{
invalidate_lut ();
_bounding_box_dirty = true;
if (_parent) {
_parent->child_changed ();
}
}
void
Item::add_items_at_point (Duple const point, vector<Item const *>& items) const
{
Rect const bbox = bounding_box ();
/* Point is in window coordinate system */
if (!bbox || !item_to_window (bbox).contains (point)) {
return;
}
/* recurse and add any items within our group that contain point.
Our children are only considered visible if we are, and similarly
only if we do not ignore events.
*/
vector<Item*> our_items;
if (!_items.empty() && visible() && !_ignore_events) {
ensure_lut ();
our_items = _lut->items_at_point (point);
}
if (!our_items.empty() || covers (point)) {
/* this adds this item itself to the list of items at point */
items.push_back (this);
}
for (vector<Item*>::iterator i = our_items.begin(); i != our_items.end(); ++i) {
(*i)->add_items_at_point (point, items);
}
}
void
Item::set_tooltip (const std::string& s)
{
_tooltip = s;
}
void
Item::start_tooltip_timeout ()
{
if (!_tooltip.empty()) {
_canvas->start_tooltip_timeout (this);
}
}
void
Item::stop_tooltip_timeout ()
{
_canvas->stop_tooltip_timeout ();
}
void
Item::dump (ostream& o) const
{
ArdourCanvas::Rect bb = bounding_box();
o << _canvas->indent() << whatami() << ' ' << this << " self-Visible ? " << self_visible() << " visible ? " << visible();
o << " @ " << position();
#ifdef CANVAS_DEBUG
if (!name.empty()) {
o << ' ' << name;
}
#endif
if (bb) {
o << endl << _canvas->indent() << "\tbbox: " << bb;
o << endl << _canvas->indent() << "\tCANVAS bbox: " << item_to_canvas (bb);
} else {
o << " bbox unset";
}
o << endl;
if (!_items.empty()) {
#ifdef CANVAS_DEBUG
o << _canvas->indent();
o << " @ " << position();
o << " Items: " << _items.size();
o << " Self-Visible ? " << self_visible();
o << " Visible ? " << visible();
Rect bb = bounding_box();
if (bb) {
o << endl << _canvas->indent() << " bbox: " << bb;
o << endl << _canvas->indent() << " CANVAS bbox: " << item_to_canvas (bb);
} else {
o << " bbox unset";
}
o << endl;
#endif
ArdourCanvas::dump_depth++;
for (list<Item*>::const_iterator i = _items.begin(); i != _items.end(); ++i) {
o << **i;
}
ArdourCanvas::dump_depth--;
}
}
ostream&
ArdourCanvas::operator<< (ostream& o, const Item& i)
{
i.dump (o);
return o;
}