/* * This program source code file is part of KiCad, a free EDA CAD application. * * Copyright (C) 2004-2018 Jean-Pierre Charras, jp.charras at wanadoo.fr * Copyright (C) 2011 Wayne Stambaugh * Copyright (C) 1992-2020 KiCad Developers, see AUTHORS.txt for contributors. * * 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, you may find one here: * http://www.gnu.org/licenses/old-licenses/gpl-2.0.html * or you may search the http://www.gnu.org website for the version 2 license, * or you may write to the Free Software Foundation, Inc., * 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301, USA */ #include #include #include #include #include #include #include #include #include #include TRACKS_CLEANER::TRACKS_CLEANER( BOARD* aPcb, BOARD_COMMIT& aCommit ) : m_brd( aPcb ), m_commit( aCommit ), m_dryRun( true ), m_itemsList( nullptr ) { } /* Main cleaning function. * Delete * - Redundant points on tracks (merge aligned segments) * - vias on pad * - null length segments */ void TRACKS_CLEANER::CleanupBoard( bool aDryRun, std::vector >* aItemsList, bool aRemoveMisConnected, bool aCleanVias, bool aMergeSegments, bool aDeleteUnconnected, bool aDeleteTracksinPad, bool aDeleteDanglingVias ) { bool has_deleted = false; m_dryRun = aDryRun; m_itemsList = aItemsList; cleanup( aCleanVias, aMergeSegments || aRemoveMisConnected, aMergeSegments, aMergeSegments ); if( aRemoveMisConnected ) removeShortingTrackSegments(); if( aDeleteTracksinPad ) deleteTracksInPads(); has_deleted = deleteDanglingTracks( aDeleteUnconnected, aDeleteDanglingVias ); if( has_deleted && aMergeSegments ) cleanup( false, false, false, true ); } void TRACKS_CLEANER::removeShortingTrackSegments() { std::shared_ptr connectivity = m_brd->GetConnectivity(); std::set toRemove; for( PCB_TRACK* segment : m_brd->Tracks() ) { // Assume that the user knows what they are doing if( segment->IsLocked() ) continue; for( PAD* testedPad : connectivity->GetConnectedPads( segment ) ) { if( segment->GetNetCode() != testedPad->GetNetCode() ) { std::shared_ptr item; if( segment->Type() == PCB_VIA_T ) item = std::make_shared( CLEANUP_SHORTING_VIA ); else item = std::make_shared( CLEANUP_SHORTING_TRACK ); item->SetItems( segment ); m_itemsList->push_back( item ); toRemove.insert( segment ); } } for( PCB_TRACK* testedTrack : connectivity->GetConnectedTracks( segment ) ) { if( segment->GetNetCode() != testedTrack->GetNetCode() ) { std::shared_ptr item; if( segment->Type() == PCB_VIA_T ) item = std::make_shared( CLEANUP_SHORTING_VIA ); else item = std::make_shared( CLEANUP_SHORTING_TRACK ); item->SetItems( segment ); m_itemsList->push_back( item ); toRemove.insert( segment ); } } } if( !m_dryRun ) removeItems( toRemove ); } bool TRACKS_CLEANER::testTrackEndpointIsNode( PCB_TRACK* aTrack, bool aTstStart ) { // A node is a point where more than 2 items are connected. auto connectivity = m_brd->GetConnectivity(); auto items = connectivity->GetConnectivityAlgo()->ItemEntry( aTrack ).GetItems(); if( items.empty() ) return false; auto citem = items.front(); if( !citem->Valid() ) return false; auto anchors = citem->Anchors(); VECTOR2I refpoint = aTstStart ? aTrack->GetStart() : aTrack->GetEnd(); for( const auto& anchor : anchors ) { if( anchor->Pos() != refpoint ) continue; // The right anchor point is found: if more than one other item // (pad, via, track...) is connected, it is a node: return anchor->ConnectedItemsCount() > 1; } return false; } bool TRACKS_CLEANER::deleteDanglingTracks( bool aTrack, bool aVia ) { bool item_erased = false; bool modified = false; if( !aTrack && !aVia ) return false; do // Iterate when at least one track is deleted { item_erased = false; // Ensure the connectivity is up to date, especially after removing a dangling segment m_brd->BuildConnectivity(); // Keep a duplicate deque to all deleting in the primary std::deque temp_tracks( m_brd->Tracks() ); for( PCB_TRACK* track : temp_tracks ) { if( track->IsLocked() || ( track->GetFlags() & IS_DELETED ) > 0 ) continue; if( !aVia && track->Type() == PCB_VIA_T ) continue; if( !aTrack && ( track->Type() == PCB_TRACE_T || track->Type() == PCB_ARC_T ) ) continue; // Test if a track (or a via) endpoint is not connected to another track or zone. if( m_brd->GetConnectivity()->TestTrackEndpointDangling( track ) ) { std::shared_ptr item; if( track->Type() == PCB_VIA_T ) item = std::make_shared( CLEANUP_DANGLING_VIA ); else item = std::make_shared( CLEANUP_DANGLING_TRACK ); item->SetItems( track ); m_itemsList->push_back( item ); track->SetFlags( IS_DELETED ); // keep iterating, because a track connected to the deleted track // now perhaps is not connected and should be deleted item_erased = true; if( !m_dryRun ) { m_brd->Remove( track ); m_commit.Removed( track ); modified = true; } } } } while( item_erased ); // A segment was erased: test for some new dangling segments return modified; } void TRACKS_CLEANER::deleteTracksInPads() { std::set toRemove; // Delete tracks that start and end on the same pad std::shared_ptr connectivity = m_brd->GetConnectivity(); for( PCB_TRACK* track : m_brd->Tracks() ) { if( track->IsLocked() ) continue; if( track->Type() == PCB_VIA_T ) continue; // Mark track if connected to pads for( PAD* pad : connectivity->GetConnectedPads( track ) ) { if( pad->HitTest( track->GetStart() ) && pad->HitTest( track->GetEnd() ) ) { SHAPE_POLY_SET poly; track->TransformShapeWithClearanceToPolygon( poly, track->GetLayer(), 0, ARC_HIGH_DEF, ERROR_INSIDE ); poly.BooleanSubtract( *pad->GetEffectivePolygon(), SHAPE_POLY_SET::PM_FAST ); if( poly.IsEmpty() ) { auto item = std::make_shared( CLEANUP_TRACK_IN_PAD ); item->SetItems( track ); m_itemsList->push_back( item ); toRemove.insert( track ); track->SetFlags( IS_DELETED ); } } } } if( !m_dryRun ) removeItems( toRemove ); } /** * Geometry-based cleanup: duplicate items, null items, colinear items. */ void TRACKS_CLEANER::cleanup( bool aDeleteDuplicateVias, bool aDeleteNullSegments, bool aDeleteDuplicateSegments, bool aMergeSegments ) { DRC_RTREE rtree; for( PCB_TRACK* track : m_brd->Tracks() ) { track->ClearFlags( IS_DELETED | SKIP_STRUCT ); rtree.Insert( track, track->GetLayer() ); } std::set toRemove; for( PCB_TRACK* track : m_brd->Tracks() ) { if( track->HasFlag( IS_DELETED ) || track->IsLocked() ) continue; if( aDeleteDuplicateVias && track->Type() == PCB_VIA_T ) { PCB_VIA* via = static_cast( track ); if( via->GetStart() != via->GetEnd() ) via->SetEnd( via->GetStart() ); rtree.QueryColliding( via, via->GetLayer(), via->GetLayer(), // Filter: [&]( BOARD_ITEM* aItem ) -> bool { return aItem->Type() == PCB_VIA_T && !aItem->HasFlag( SKIP_STRUCT ) && !aItem->HasFlag( IS_DELETED ); }, // Visitor: [&]( BOARD_ITEM* aItem ) -> bool { PCB_VIA* other = static_cast( aItem ); if( via->GetPosition() == other->GetPosition() && via->GetViaType() == other->GetViaType() && via->GetLayerSet() == other->GetLayerSet() ) { auto item = std::make_shared( CLEANUP_REDUNDANT_VIA ); item->SetItems( via ); m_itemsList->push_back( item ); via->SetFlags( IS_DELETED ); toRemove.insert( via ); } return true; } ); // To delete through Via on THT pads at same location // Examine the list of connected pads: if a through pad is found, the via is redundant for( PAD* pad : m_brd->GetConnectivity()->GetConnectedPads( via ) ) { const LSET all_cu = LSET::AllCuMask(); if( ( pad->GetLayerSet() & all_cu ) == all_cu ) { auto item = std::make_shared( CLEANUP_REDUNDANT_VIA ); item->SetItems( via, pad ); m_itemsList->push_back( item ); via->SetFlags( IS_DELETED ); toRemove.insert( via ); break; } } via->SetFlags( SKIP_STRUCT ); } if( aDeleteNullSegments && track->Type() != PCB_VIA_T ) { if( track->IsNull() ) { auto item = std::make_shared( CLEANUP_ZERO_LENGTH_TRACK ); item->SetItems( track ); m_itemsList->push_back( item ); track->SetFlags( IS_DELETED ); toRemove.insert( track ); } } if( aDeleteDuplicateSegments && track->Type() == PCB_TRACE_T && !track->IsNull() ) { rtree.QueryColliding( track, track->GetLayer(), track->GetLayer(), // Filter: [&]( BOARD_ITEM* aItem ) -> bool { return aItem->Type() == PCB_TRACE_T && !aItem->HasFlag( SKIP_STRUCT ) && !aItem->HasFlag( IS_DELETED ) && !static_cast( aItem )->IsNull(); }, // Visitor: [&]( BOARD_ITEM* aItem ) -> bool { PCB_TRACK* other = static_cast( aItem ); if( track->IsPointOnEnds( other->GetStart() ) && track->IsPointOnEnds( other->GetEnd() ) && track->GetWidth() == other->GetWidth() && track->GetLayer() == other->GetLayer() ) { auto item = std::make_shared( CLEANUP_DUPLICATE_TRACK ); item->SetItems( track ); m_itemsList->push_back( item ); track->SetFlags( IS_DELETED ); toRemove.insert( track ); } return true; } ); track->SetFlags( SKIP_STRUCT ); } } if( !m_dryRun ) removeItems( toRemove ); if( aMergeSegments ) { bool merged; do { merged = false; m_brd->BuildConnectivity(); auto connectivity = m_brd->GetConnectivity()->GetConnectivityAlgo(); // Keep a duplicate deque to all deleting in the primary std::deque temp_segments( m_brd->Tracks() ); // merge collinear segments: for( PCB_TRACK* segment : temp_segments ) { if( segment->Type() != PCB_TRACE_T ) // one can merge only track collinear segments, not vias. continue; if( segment->HasFlag( IS_DELETED ) ) // already taken in account continue; for( CN_ITEM* citem : connectivity->ItemEntry( segment ).GetItems() ) { // Do not merge an end which has different width tracks attached -- it's a // common use-case for necking-down a track between pads. std::vector sameWidthCandidates; std::vector differentWidthCandidates; for( CN_ITEM* connected : citem->ConnectedItems() ) { if( !connected->Valid() ) continue; BOARD_CONNECTED_ITEM* candidateItem = connected->Parent(); if( candidateItem->Type() == PCB_TRACE_T && !candidateItem->HasFlag( IS_DELETED ) ) { PCB_TRACK* candidateSegment = static_cast( candidateItem ); if( candidateSegment->GetWidth() == segment->GetWidth() ) sameWidthCandidates.push_back( candidateSegment ); else differentWidthCandidates.push_back( candidateSegment ); } } if( differentWidthCandidates.size() == 0 ) { for( PCB_TRACK* candidate : sameWidthCandidates ) { if( segment->ApproxCollinear( *candidate ) ) merged |= mergeCollinearSegments( segment, candidate ); } } } } } while( merged ); } for( PCB_TRACK* track : m_brd->Tracks() ) track->ClearFlags( IS_DELETED | SKIP_STRUCT ); } bool TRACKS_CLEANER::mergeCollinearSegments( PCB_TRACK* aSeg1, PCB_TRACK* aSeg2 ) { KICAD_T items[] = { PCB_TRACE_T, PCB_ARC_T, PCB_VIA_T, PCB_PAD_T, PCB_ZONE_T }; if( aSeg1->IsLocked() || aSeg2->IsLocked() ) return false; std::shared_ptr connectivity = m_brd->GetConnectivity(); std::vector tracks = connectivity->GetConnectedItems( aSeg1, items ); std::vector tracks2 = connectivity->GetConnectedItems( aSeg2, items ); std::move( tracks2.begin(), tracks2.end(), std::back_inserter( tracks ) ); std::sort( tracks.begin(), tracks.end() ); tracks.erase( std::unique( tracks.begin(), tracks.end() ), tracks.end() ); tracks.erase( std::remove_if( tracks.begin(), tracks.end(), [ aSeg1, aSeg2 ]( BOARD_CONNECTED_ITEM* aTest ) { return ( aTest == aSeg1 ) || ( aTest == aSeg2 ); } ), tracks.end() ); std::set pts; // Collect the unique points where the two tracks are connected to other items for( BOARD_CONNECTED_ITEM* citem : tracks ) { if( PCB_TRACK* track = dyn_cast( citem ) ) { if( track->IsPointOnEnds( aSeg1->GetStart() ) ) pts.emplace( aSeg1->GetStart() ); if( track->IsPointOnEnds( aSeg1->GetEnd() ) ) pts.emplace( aSeg1->GetEnd() ); if( track->IsPointOnEnds( aSeg2->GetStart() ) ) pts.emplace( aSeg2->GetStart() ); if( track->IsPointOnEnds( aSeg2->GetEnd() ) ) pts.emplace( aSeg2->GetEnd() ); } else { if( citem->HitTest( aSeg1->GetStart(), ( aSeg1->GetWidth() + 1 ) / 2 ) ) pts.emplace( aSeg1->GetStart() ); if( citem->HitTest( aSeg1->GetEnd(), ( aSeg1->GetWidth() + 1 ) / 2 ) ) pts.emplace( aSeg1->GetEnd() ); if( citem->HitTest( aSeg2->GetStart(), ( aSeg2->GetWidth() + 1 ) / 2 ) ) pts.emplace( aSeg2->GetStart() ); if( citem->HitTest( aSeg2->GetEnd(), ( aSeg2->GetWidth() + 1 ) / 2 ) ) pts.emplace( aSeg2->GetEnd() ); } } // This means there is a node in the center if( pts.size() > 2 ) return false; // Verify the removed point after merging is not a node. // If it is a node (i.e. if more than one other item is connected, the segments cannot be merged PCB_TRACK dummy_seg( *aSeg1 ); // Calculate the new ends of the segment to merge, and store them to dummy_seg: int min_x = std::min( aSeg1->GetStart().x, std::min( aSeg1->GetEnd().x, std::min( aSeg2->GetStart().x, aSeg2->GetEnd().x ) ) ); int min_y = std::min( aSeg1->GetStart().y, std::min( aSeg1->GetEnd().y, std::min( aSeg2->GetStart().y, aSeg2->GetEnd().y ) ) ); int max_x = std::max( aSeg1->GetStart().x, std::max( aSeg1->GetEnd().x, std::max( aSeg2->GetStart().x, aSeg2->GetEnd().x ) ) ); int max_y = std::max( aSeg1->GetStart().y, std::max( aSeg1->GetEnd().y, std::max( aSeg2->GetStart().y, aSeg2->GetEnd().y ) ) ); if( ( aSeg1->GetStart().x > aSeg1->GetEnd().x ) == ( aSeg1->GetStart().y > aSeg1->GetEnd().y ) ) { dummy_seg.SetStart( wxPoint( min_x, min_y ) ); dummy_seg.SetEnd( wxPoint( max_x, max_y ) ); } else { dummy_seg.SetStart( wxPoint( min_x, max_y ) ); dummy_seg.SetEnd( wxPoint( max_x, min_y ) ); } // If the existing connected points are not the same as the points generated by our // min/max alg, then assign the missing points to the end closest. This ensures that // our replacment track is still connected for( auto pt : pts ) { if( !dummy_seg.IsPointOnEnds( wxPoint( pt.x, pt.y ) ) ) { if( ( VECTOR2I( dummy_seg.GetStart() ) - pt ).SquaredEuclideanNorm() < ( VECTOR2I( dummy_seg.GetEnd() ) - pt ).SquaredEuclideanNorm() ) dummy_seg.SetStart( wxPoint( pt.x, pt.y ) ); else dummy_seg.SetEnd( wxPoint( pt.x, pt.y ) ); } } // Now find the removed end(s) and stop merging if it is a node: if( aSeg1->GetStart() != dummy_seg.GetStart() && aSeg1->GetStart() != dummy_seg.GetEnd() ) { if( testTrackEndpointIsNode( aSeg1, true ) ) return false; } if( aSeg1->GetEnd() != dummy_seg.GetStart() && aSeg1->GetEnd() != dummy_seg.GetEnd() ) { if( testTrackEndpointIsNode( aSeg1, false ) ) return false; } std::shared_ptr item = std::make_shared( CLEANUP_MERGE_TRACKS ); item->SetItems( aSeg1, aSeg2 ); m_itemsList->push_back( item ); aSeg2->SetFlags( IS_DELETED ); if( !m_dryRun ) { m_commit.Modify( aSeg1 ); *aSeg1 = dummy_seg; connectivity->Update( aSeg1 ); // Clear the status flags here after update. for( auto pad : connectivity->GetConnectedPads( aSeg1 ) ) { aSeg1->SetState( BEGIN_ONPAD, pad->HitTest( aSeg1->GetStart() ) ); aSeg1->SetState( END_ONPAD, pad->HitTest( aSeg1->GetEnd() ) ); } // Merge successful, seg2 has to go away m_brd->Remove( aSeg2 ); m_commit.Removed( aSeg2 ); } return true; } void TRACKS_CLEANER::removeItems( std::set& aItems ) { for( auto item : aItems ) { m_brd->Remove( item ); m_commit.Removed( item ); } }