/* * Copyright (C) 2020 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., * 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA. */ #include #include "pbd/i18n.h" #include "pbd/unwind.h" #include "pbd/stacktrace.h" #include "kiwi/kiwi.h" #include "canvas/constraint_packer.h" #include "canvas/constrained_item.h" #include "canvas/item.h" #include "canvas/rectangle.h" using namespace ArdourCanvas; using std::cerr; using std::endl; using std::vector; using kiwi::Constraint; using namespace kiwi; ConstraintPacker::ConstraintPacker (Canvas* canvas) : Container (canvas) , width (X_("packer width")) , height (X_("packer height")) , in_alloc (false) { set_fill (false); set_outline (false); } ConstraintPacker::ConstraintPacker (Item* parent) : Container (parent) , width (X_("packer width")) , height (X_("packer height")) , in_alloc (false) { set_fill (false); set_outline (false); } void ConstraintPacker::compute_bounding_box () const { _bounding_box = _allocation; _bounding_box_dirty = false; } void ConstraintPacker::child_changed (bool bbox_changed) { Item::child_changed (bbox_changed); if (in_alloc || !bbox_changed) { return; } #if 0 cerr << "CP, child bbox changed\n"; for (ConstrainedItemMap::iterator x = constrained_map.begin(); x != constrained_map.end(); ++x) { Duple i = x->first->intrinsic_size(); if (r) { // cerr << x->first->whatami() << '/' << x->first->name << " has instrinsic size " << r << endl; kiwi::Variable& w (x->second->intrinsic_width()); if (!r.width()) { if (_solver.hasEditVariable (w)) { _solver.removeEditVariable (w); cerr << "\tremoved inttrinsic-width edit var\n"; } } else { if (!_solver.hasEditVariable (w)) { cerr << "\tadding intrinsic width constraints\n"; _solver.addEditVariable (w, kiwi::strength::strong); _solver.addConstraint (Constraint {x->second->width() >= w } | kiwi::strength::strong); _solver.addConstraint (Constraint (x->second->width() <= w) | kiwi::strength::weak); } } kiwi::Variable& h (x->second->intrinsic_height()); if (!r.height()) { if (_solver.hasEditVariable (h)) { _solver.removeEditVariable (h); cerr << "\tremoved inttrinsic-height edit var\n"; } } else { if (!_solver.hasEditVariable (h)) { cerr << "\tadding intrinsic height constraints\n"; _solver.addEditVariable (h, kiwi::strength::strong); _solver.addConstraint (Constraint {x->second->height() >= h } | kiwi::strength::strong); _solver.addConstraint (Constraint (x->second->height() <= h) | kiwi::strength::weak); } } } } #endif } void ConstraintPacker::constrain (kiwi::Constraint const &c) { constraint_list.push_back (c); } void ConstraintPacker::preferred_size (Duple& minimum, Duple& natural) const { /* our parent wants to know how big we are. We may have some intrinsic size (i.e. "everything in this constraint layout should fit into WxH". Just up two constraints on our width and height, and solve. We may have one intrinsic dimension (i.e. "everything in this constraint layout should fit into this (width|height). Ask all of our children for the size-given-(W|H). Add constraints to represent those values, and solve. We may have no intrinsic dimensions at all. This is the tricky one. */ kiwi::Solver s; if (_intrinsic_width > 0) { s.addEditVariable (width, kiwi::strength::strong); s.suggestValue (width, _intrinsic_width); } else if (_intrinsic_height > 0) { s.addEditVariable (height, kiwi::strength::strong); s.suggestValue (height, _intrinsic_height); } for (ConstrainedItemMap::const_iterator x = constrained_map.begin(); x != constrained_map.end(); ++x) { Duple min, natural; ConstrainedItem* ci = x->second; x->first->preferred_size (min, natural); s.addConstraint (ci->width() >= min.width() | kiwi::strength::required); s.addConstraint (ci->height() >= min.height() | kiwi::strength::required); s.addConstraint (ci->width() == natural.width() | kiwi::strength::medium); s.addConstraint (ci->height() == natural.width() | kiwi::strength::medium); add_constraints (s, ci); } for (ConstraintList::const_iterator c = constraint_list.begin(); c != constraint_list.end(); ++c) { s.addConstraint (*c); } s.updateVariables (); Duple ret; natural.x = width.value (); natural.y = height.value (); minimum = natural; cerr << "CP::sr returns " << natural<< endl; } void ConstraintPacker::size_allocate (Rect const & r) { PBD::Unwinder uw (in_alloc, true); Item::size_allocate (r); kiwi::Solver s; s.addConstraint (width == r.width()); s.addConstraint (height == r.height()); // s.addEditVariable (width, kiwi::strength::strong); // s.addEditVariable (height, kiwi::strength::strong); // s.suggestValue (width, r.width()); // s.suggestValue (height, r.height()); for (ConstrainedItemMap::iterator x = constrained_map.begin(); x != constrained_map.end(); ++x) { Duple min, natural; ConstrainedItem* ci = x->second; x->first->preferred_size (min, natural); s.addConstraint (ci->width() >= min.width() | kiwi::strength::required); s.addConstraint (ci->height() >= min.height() | kiwi::strength::required); s.addConstraint (ci->width() == natural.width() | kiwi::strength::medium); s.addConstraint (ci->height() == natural.width() | kiwi::strength::medium); add_constraints (s, ci); } for (ConstraintList::const_iterator c = constraint_list.begin(); c != constraint_list.end(); ++c) { s.addConstraint (*c); } s.updateVariables (); apply (0); _bounding_box_dirty = true; } void ConstraintPacker::add (Item* item) { (void) add_constrained (item); } void ConstraintPacker::add_front (Item* item) { (void) add_constrained (item); } void ConstraintPacker::add_constraints (Solver& s, ConstrainedItem* ci) const { /* add any constraints inherent to this item */ vector const & vc (ci->constraints()); for (vector::const_iterator x = vc.begin(); x != vc.end(); ++x) { s.addConstraint (*x); } } ConstrainedItem* ConstraintPacker::add_constrained (Item* item) { ConstrainedItem* ci = new ConstrainedItem (*item); add_constrained_internal (item, ci); return ci; } void ConstraintPacker::add_constrained_internal (Item* item, ConstrainedItem* ci) { Item::add (item); item->set_layout_sensitive (true); constrained_map.insert (std::make_pair (item, ci)); child_changed (true); } void ConstraintPacker::remove (Item* item) { Item::remove (item); for (ConstrainedItemMap::iterator x = constrained_map.begin(); x != constrained_map.end(); ++x) { if (x->first == item) { /* remove any non-builtin constraints for this item */ for (ConstraintList::iterator c = constraint_list.begin(); c != constraint_list.end(); ++c) { if (x->second->involved (*c)) { constraint_list.erase (c); } } item->set_layout_sensitive (false); /* clean up */ delete x->second; constrained_map.erase (x); break; } } } void ConstraintPacker::apply (Solver* s) { for (ConstrainedItemMap::iterator x = constrained_map.begin(); x != constrained_map.end(); ++x) { x->second->constrained (*this); } }