static void sp_canvas_bpath_update(SPCanvasItem *item, Geom::Affine const &affine, unsigned int flags)
{
SPCanvasBPath *cbp = SP_CANVAS_BPATH(item);
item->canvas->requestRedraw((int)item->x1, (int)item->y1, (int)item->x2, (int)item->y2);
if (reinterpret_cast<SPCanvasItemClass *>(sp_canvas_bpath_parent_class)->update) {
reinterpret_cast<SPCanvasItemClass *>(sp_canvas_bpath_parent_class)->update(item, affine, flags);
}
sp_canvas_item_reset_bounds (item);
if (!cbp->curve) return;
cbp->affine = affine;
Geom::OptRect bbox = bounds_exact_transformed(cbp->curve->get_pathvector(), affine);
if (bbox) {
item->x1 = (int)bbox->min()[Geom::X] - 1;
item->y1 = (int)bbox->min()[Geom::Y] - 1;
item->x2 = (int)bbox->max()[Geom::X] + 1;
item->y2 = (int)bbox->max()[Geom::Y] + 1;
} else {
item->x1 = 0;
item->y1 = 0;
item->x2 = 0;
item->y2 = 0;
}
item->canvas->requestRedraw((int)item->x1, (int)item->y1, (int)item->x2, (int)item->y2);
}
/**
* Takes a list of inkscape items, extracts the graph defined by
* connectors between them, and uses graph layout techniques to find
* a nice layout
*/
void graphlayout(std::vector<SPItem*> const &items) {
if(items.empty()) {
return;
}
list<SPItem *> selected;
filterConnectors(items,selected);
if (selected.empty()) return;
const unsigned n=selected.size();
//Check 2 or more selected objects
if (n < 2) return;
// add the connector spacing to the size of node bounding boxes
// so that connectors can always be routed between shapes
SPDesktop* desktop = SP_ACTIVE_DESKTOP;
double spacing = 0;
if(desktop) spacing = desktop->namedview->connector_spacing+0.1;
map<string,unsigned> nodelookup;
vector<Rectangle*> rs;
vector<Edge> es;
for (list<SPItem *>::iterator i(selected.begin());
i != selected.end();
++i)
{
SPItem *u=*i;
Geom::OptRect const item_box = u->desktopVisualBounds();
if(item_box) {
Geom::Point ll(item_box->min());
Geom::Point ur(item_box->max());
nodelookup[u->getId()]=rs.size();
rs.push_back(new Rectangle(ll[0]-spacing,ur[0]+spacing,
ll[1]-spacing,ur[1]+spacing));
} else {
// I'm not actually sure if it's possible for something with a
// NULL item-box to be attached to a connector in which case we
// should never get to here... but if such a null box can occur it's
// probably pretty safe to simply ignore
//fprintf(stderr,"NULL item_box found in graphlayout, ignoring!\n");
}
}
Inkscape::Preferences *prefs = Inkscape::Preferences::get();
SimpleConstraints scx,scy;
double ideal_connector_length = prefs->getDouble("/tools/connector/length", 100.0);
double directed_edge_height_modifier = 1.0;
bool directed = prefs->getBool("/tools/connector/directedlayout");
bool avoid_overlaps = prefs->getBool("/tools/connector/avoidoverlaplayout");
for (list<SPItem *>::iterator i(selected.begin());
i != selected.end();
++i)
{
SPItem *iu=*i;
map<string,unsigned>::iterator i_iter=nodelookup.find(iu->getId());
map<string,unsigned>::iterator i_iter_end=nodelookup.end();
if(i_iter==i_iter_end) {
continue;
}
unsigned u=i_iter->second;
std::vector<SPItem *> nlist=iu->avoidRef->getAttachedConnectors(Avoid::runningFrom);
list<SPItem *> connectors;
connectors.insert(connectors.end(), nlist.begin(), nlist.end());
for (list<SPItem *>::iterator j(connectors.begin());
j != connectors.end();
++j) {
SPItem *conn=*j;
SPItem *iv;
SPItem *items[2];
assert(isConnector(conn));
SP_PATH(conn)->connEndPair.getAttachedItems(items);
if(items[0]==iu) {
iv=items[1];
} else {
iv=items[0];
}
if (iv == NULL) {
// The connector is not attached to anything at the
// other end so we should just ignore it.
continue;
}
// If iv not in nodelookup we again treat the connector
// as disconnected and continue
map<string,unsigned>::iterator v_pair=nodelookup.find(iv->getId());
if(v_pair!=nodelookup.end()) {
unsigned v=v_pair->second;
//cout << "Edge: (" << u <<","<<v<<")"<<endl;
es.push_back(make_pair(u,v));
if(conn->style->marker_end.set) {
if(directed && strcmp(conn->style->marker_end.value,"none")) {
scy.push_back(new SimpleConstraint(v, u,
(ideal_connector_length * directed_edge_height_modifier)));
}
}
}
}
}
const unsigned E = es.size();
double eweights[E];
fill(eweights,eweights+E,1);
vector<Component*> cs;
connectedComponents(rs,es,scx,scy,cs);
for(unsigned i=0;i<cs.size();i++) {
Component* c=cs[i];
if(c->edges.size()<2) continue;
CheckProgress test(0.0001,100,selected,rs,nodelookup);
ConstrainedMajorizationLayout alg(c->rects,c->edges,eweights,ideal_connector_length,test);
alg.setupConstraints(NULL,NULL,avoid_overlaps,
NULL,NULL,&c->scx,&c->scy,NULL,NULL);
alg.run();
}
separateComponents(cs);
for (list<SPItem *>::iterator it(selected.begin());
it != selected.end();
++it)
{
SPItem *u=*it;
if(!isConnector(u)) {
map<string,unsigned>::iterator i=nodelookup.find(u->getId());
if(i!=nodelookup.end()) {
Rectangle* r=rs[i->second];
Geom::OptRect item_box = u->desktopVisualBounds();
if (item_box) {
Geom::Point const curr(item_box->midpoint());
Geom::Point const dest(r->getCentreX(),r->getCentreY());
sp_item_move_rel(u, Geom::Translate(dest - curr));
}
}
}
}
for(unsigned i=0;i<scx.size();i++) {
delete scx[i];
}
for(unsigned i=0;i<scy.size();i++) {
delete scy[i];
}
for(unsigned i=0;i<rs.size();i++) {
delete rs[i];
}
}
