/* * 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) 1992-2023 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 #include #include GRAPHICS_CLEANER::GRAPHICS_CLEANER( const DRAWINGS& aDrawings, FOOTPRINT* aParentFootprint, BOARD_COMMIT& aCommit, TOOL_MANAGER* aToolMgr ) : m_drawings( aDrawings ), m_parentFootprint( aParentFootprint ), m_commit( aCommit ), m_toolMgr( aToolMgr ), m_dryRun( true ), m_epsilon( 0 ), m_outlinesTolerance( 0 ), m_itemsList( nullptr ) { } void GRAPHICS_CLEANER::CleanupBoard( bool aDryRun, std::vector>* aItemsList, bool aMergeRects, bool aDeleteRedundant, bool aMergePads, bool aFixBoardOutlines, int aTolerance ) { m_dryRun = aDryRun; m_itemsList = aItemsList; m_outlinesTolerance = aTolerance; m_epsilon = m_commit.GetBoard()->GetDesignSettings().m_MaxError; // Clear the flag used to mark some shapes as deleted, in dry run: for( BOARD_ITEM* drawing : m_drawings ) drawing->ClearFlags( IS_DELETED ); if( aDeleteRedundant ) cleanupShapes(); if( aFixBoardOutlines ) fixBoardOutlines(); if( aMergeRects ) mergeRects(); if( aMergePads ) mergePads(); // Clear the flag used to mark some shapes: for( BOARD_ITEM* drawing : m_drawings ) drawing->ClearFlags( IS_DELETED ); } bool equivalent( const VECTOR2I& a, const VECTOR2I& b, int epsilon ) { return abs( a.x - b.x ) < epsilon && abs( a.y - b.y ) < epsilon; }; bool GRAPHICS_CLEANER::isNullShape( PCB_SHAPE* aShape ) { switch( aShape->GetShape() ) { case SHAPE_T::SEGMENT: case SHAPE_T::RECTANGLE: case SHAPE_T::ARC: return equivalent( aShape->GetStart(), aShape->GetEnd(), m_epsilon ); case SHAPE_T::CIRCLE: return aShape->GetRadius() == 0; case SHAPE_T::POLY: return aShape->GetPointCount() == 0; case SHAPE_T::BEZIER: aShape->RebuildBezierToSegmentsPointsList( ARC_HIGH_DEF ); // If the Bezier points list contains 2 points, it is equivalent to a segment if( aShape->GetBezierPoints().size() == 2 ) return equivalent( aShape->GetStart(), aShape->GetEnd(), m_epsilon ); // If the Bezier points list contains 1 points, it is equivalent to a point return aShape->GetBezierPoints().size() < 2; default: UNIMPLEMENTED_FOR( aShape->SHAPE_T_asString() ); return false; } } bool GRAPHICS_CLEANER::areEquivalent( PCB_SHAPE* aShape1, PCB_SHAPE* aShape2 ) { if( aShape1->GetShape() != aShape2->GetShape() || aShape1->GetLayer() != aShape2->GetLayer() || aShape1->GetWidth() != aShape2->GetWidth() ) { return false; } switch( aShape1->GetShape() ) { case SHAPE_T::SEGMENT: case SHAPE_T::RECTANGLE: case SHAPE_T::CIRCLE: return equivalent( aShape1->GetStart(), aShape2->GetStart(), m_epsilon ) && equivalent( aShape1->GetEnd(), aShape2->GetEnd(), m_epsilon ); case SHAPE_T::ARC: return equivalent( aShape1->GetCenter(), aShape2->GetCenter(), m_epsilon ) && equivalent( aShape1->GetStart(), aShape2->GetStart(), m_epsilon ) && equivalent( aShape1->GetEnd(), aShape2->GetEnd(), m_epsilon ); case SHAPE_T::POLY: // TODO return false; case SHAPE_T::BEZIER: return equivalent( aShape1->GetStart(), aShape2->GetStart(), m_epsilon ) && equivalent( aShape1->GetEnd(), aShape2->GetEnd(), m_epsilon ) && equivalent( aShape1->GetBezierC1(), aShape2->GetBezierC1(), m_epsilon ) && equivalent( aShape1->GetBezierC2(), aShape2->GetBezierC2(), m_epsilon ); default: wxFAIL_MSG( wxT( "GRAPHICS_CLEANER::areEquivalent unimplemented for " ) + aShape1->SHAPE_T_asString() ); return false; } } void GRAPHICS_CLEANER::cleanupShapes() { // Remove duplicate shapes (2 superimposed identical shapes): for( auto it = m_drawings.begin(); it != m_drawings.end(); it++ ) { PCB_SHAPE* shape = dynamic_cast( *it ); if( !shape || shape->HasFlag( IS_DELETED ) ) continue; if( isNullShape( shape ) ) { std::shared_ptr item = std::make_shared( CLEANUP_NULL_GRAPHIC ); item->SetItems( shape ); m_itemsList->push_back( item ); if( !m_dryRun ) m_commit.Remove( shape ); continue; } for( auto it2 = it + 1; it2 != m_drawings.end(); it2++ ) { PCB_SHAPE* shape2 = dynamic_cast( *it2 ); if( !shape2 || shape2->HasFlag( IS_DELETED ) ) continue; if( areEquivalent( shape, shape2 ) ) { std::shared_ptr item = std::make_shared( CLEANUP_DUPLICATE_GRAPHIC ); item->SetItems( shape2 ); m_itemsList->push_back( item ); shape2->SetFlags(IS_DELETED ); if( !m_dryRun ) m_commit.Remove( shape2 ); } } } } void GRAPHICS_CLEANER::fixBoardOutlines() { if( m_dryRun ) return; std::vector shapeList; std::vector> newShapes; for( BOARD_ITEM* item : m_drawings ) { PCB_SHAPE* shape = dynamic_cast( item ); if( !shape || !shape->IsOnLayer( Edge_Cuts ) ) continue; shapeList.push_back( shape ); if( !m_dryRun ) m_commit.Modify( shape ); } ConnectBoardShapes( shapeList, newShapes, m_outlinesTolerance ); std::vector items_to_select; for( std::unique_ptr& ptr : newShapes ) m_commit.Add( ptr.release() ); } void GRAPHICS_CLEANER::mergeRects() { struct SIDE_CANDIDATE { SIDE_CANDIDATE( PCB_SHAPE* aShape ) : start( aShape->GetStart() ), end( aShape->GetEnd() ), shape( aShape ) { if( start.x > end.x || start.y > end.y ) std::swap( start, end ); } VECTOR2I start; VECTOR2I end; PCB_SHAPE* shape; }; std::vector sides; std::map> ptMap; // First load all the candidates into the side vector and layer maps for( BOARD_ITEM* item : m_drawings ) { PCB_SHAPE* shape = dynamic_cast( item ); if( !shape || isNullShape( shape ) || shape->GetShape() != SHAPE_T::SEGMENT ) continue; if( shape->GetStart().x == shape->GetEnd().x || shape->GetStart().y == shape->GetEnd().y ) { sides.emplace_back( new SIDE_CANDIDATE( shape ) ); ptMap[ sides.back()->start ].push_back( sides.back() ); } } // Now go through the sides and try and match lines into rectangles for( SIDE_CANDIDATE* side : sides ) { if( side->shape->HasFlag( IS_DELETED ) ) continue; SIDE_CANDIDATE* left = nullptr; SIDE_CANDIDATE* top = nullptr; SIDE_CANDIDATE* right = nullptr; SIDE_CANDIDATE* bottom = nullptr; auto viable = [&]( SIDE_CANDIDATE* aCandidate ) -> bool { return aCandidate->shape->GetLayer() == side->shape->GetLayer() && aCandidate->shape->GetWidth() == side->shape->GetWidth() && !aCandidate->shape->HasFlag( IS_DELETED ); }; if( side->start.x == side->end.x ) { // We've found a possible left; see if we have a top // left = side; for( SIDE_CANDIDATE* candidate : ptMap[ left->start ] ) { if( candidate != left && viable( candidate ) ) { top = candidate; break; } } } else if( side->start.y == side->end.y ) { // We've found a possible top; see if we have a left // top = side; for( SIDE_CANDIDATE* candidate : ptMap[ top->start ] ) { if( candidate != top && viable( candidate ) ) { left = candidate; break; } } } if( top && left ) { // See if we can fill in the other two sides // for( SIDE_CANDIDATE* candidate : ptMap[ top->end ] ) { if( candidate != top && candidate != left && viable( candidate ) ) { right = candidate; break; } } for( SIDE_CANDIDATE* candidate : ptMap[ left->end ] ) { if( candidate != top && candidate != left && viable( candidate ) ) { bottom = candidate; break; } } if( right && bottom && right->end == bottom->end ) { left->shape->SetFlags( IS_DELETED ); top->shape->SetFlags( IS_DELETED ); right->shape->SetFlags( IS_DELETED ); bottom->shape->SetFlags( IS_DELETED ); std::shared_ptr item = std::make_shared( CLEANUP_LINES_TO_RECT ); item->SetItems( left->shape, top->shape, right->shape, bottom->shape ); m_itemsList->push_back( item ); if( !m_dryRun ) { PCB_SHAPE* rect = new PCB_SHAPE( m_parentFootprint ); rect->SetShape( SHAPE_T::RECTANGLE ); rect->SetFilled( false ); rect->SetStart( top->start ); rect->SetEnd( bottom->end ); rect->SetLayer( top->shape->GetLayer() ); rect->SetStroke( top->shape->GetStroke() ); m_commit.Add( rect ); m_commit.Remove( left->shape ); m_commit.Remove( top->shape ); m_commit.Remove( right->shape ); m_commit.Remove( bottom->shape ); } } } } for( SIDE_CANDIDATE* side : sides ) delete side; } void GRAPHICS_CLEANER::mergePads() { wxCHECK_MSG( m_parentFootprint, /*void*/, wxT( "mergePads() is FootprintEditor only" ) ); PAD_TOOL* padTool = m_toolMgr->GetTool(); std::map padToNetTieGroupMap = m_parentFootprint->MapPadNumbersToNetTieGroups(); for( PAD* pad : m_parentFootprint->Pads() ) { // Don't merge a pad that's in a net-tie pad group. (We don't care which group.) if( padToNetTieGroupMap[ pad->GetNumber() ] >= 0 ) continue; if( m_commit.GetStatus( m_parentFootprint ) == 0 ) m_commit.Modify( m_parentFootprint ); std::vector shapes = padTool->RecombinePad( pad, m_dryRun ); if( !shapes.empty() ) { std::shared_ptr item = std::make_shared( CLEANUP_MERGE_PAD ); for( PCB_SHAPE* shape : shapes ) item->AddItem( shape ); item->AddItem( pad ); m_itemsList->push_back( item ); } } }