convert_shape_list_to_polygon.cpp

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/*
 * This program source code file is part of KiCad, a free EDA CAD application.
 *
 * Copyright (C) 2017 Jean-Pierre Charras, jp.charras at wanadoo.fr
 * Copyright (C) 2015 SoftPLC Corporation, Dick Hollenbeck <[email protected]>
 * Copyright The 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 <unordered_set>
 
#include <trigo.h>
#include <macros.h>
 
#include <math/vector2d.h>
#include <pcb_shape.h>
#include <footprint.h>
#include <pad.h>
#include <base_units.h>
#include <convert_basic_shapes_to_polygon.h>
#include <geometry/shape_poly_set.h>
#include <geometry/geometry_utils.h>
#include <convert_shape_list_to_polygon.h>
#include <board.h>
#include <collectors.h>
 
#include <nanoflann.hpp>
 
#include <wx/log.h>
 
 
const wxChar* traceBoardOutline = wxT( "KICAD_BOARD_OUTLINE" );
 
 
class SCOPED_FLAGS_CLEANER : public std::unordered_set<EDA_ITEM*>
{
    EDA_ITEM_FLAGS m_flagsToClear;
 
public:
    SCOPED_FLAGS_CLEANER( const EDA_ITEM_FLAGS& aFlagsToClear ) : m_flagsToClear( aFlagsToClear ) {}
 
    ~SCOPED_FLAGS_CLEANER()
    {
        for( EDA_ITEM* item : *this )
            item->ClearFlags( m_flagsToClear );
    }
};
 
 
static bool close_enough( VECTOR2I aLeft, VECTOR2I aRight, unsigned aLimit )
{
    return ( aLeft - aRight ).SquaredEuclideanNorm() <= SEG::Square( aLimit );
}
 
 
static bool closer_to_first( VECTOR2I aRef, VECTOR2I aFirst, VECTOR2I aSecond )
{
    return ( aRef - aFirst ).SquaredEuclideanNorm() < ( aRef - aSecond ).SquaredEuclideanNorm();
}
 
 
static bool isCopperOutside( const FOOTPRINT* aFootprint, SHAPE_POLY_SET& aShape )
{
    bool padOutside = false;
 
    for( PAD* pad : aFootprint->Pads() )
    {
        pad->Padstack().ForEachUniqueLayer(
            [&]( PCB_LAYER_ID aLayer )
            {
                SHAPE_POLY_SET poly = aShape.CloneDropTriangulation();
 
                poly.ClearArcs();
 
                poly.BooleanIntersection( *pad->GetEffectivePolygon( aLayer, ERROR_INSIDE ) );
 
                if( poly.OutlineCount() == 0 )
                {
                    VECTOR2I padPos = pad->GetPosition();
                    wxLogTrace( traceBoardOutline, wxT( "Tested pad (%d, %d): outside" ),
                                padPos.x, padPos.y );
                    padOutside = true;
                }
            } );
 
        if( padOutside )
            break;
 
        VECTOR2I padPos = pad->GetPosition();
        wxLogTrace( traceBoardOutline, wxT( "Tested pad (%d, %d): not outside" ),
                    padPos.x, padPos.y );
    }
 
    return padOutside;
}
 
 
struct PCB_SHAPE_ENDPOINTS_ADAPTOR
{
    std::vector<std::pair<VECTOR2I, PCB_SHAPE*>> endpoints;
 
    PCB_SHAPE_ENDPOINTS_ADAPTOR( const std::vector<PCB_SHAPE*>& shapes )
    {
        endpoints.reserve( shapes.size() * 2 );
 
        for( PCB_SHAPE* shape : shapes )
        {
            endpoints.emplace_back( shape->GetStart(), shape );
            endpoints.emplace_back( shape->GetEnd(), shape );
        }
    }
 
    // Required by nanoflann
    size_t kdtree_get_point_count() const { return endpoints.size(); }
 
    // Returns the dim'th component of the idx'th point
    double kdtree_get_pt( const size_t idx, const size_t dim ) const
    {
        if( dim == 0 )
            return static_cast<double>( endpoints[idx].first.x );
        else
            return static_cast<double>( endpoints[idx].first.y );
    }
 
    template <class BBOX>
    bool kdtree_get_bbox( BBOX& ) const
    {
        return false;
    }
};
 
using KDTree = nanoflann::KDTreeSingleIndexAdaptor<nanoflann::L2_Simple_Adaptor<double, PCB_SHAPE_ENDPOINTS_ADAPTOR>,
                                                   PCB_SHAPE_ENDPOINTS_ADAPTOR,
                                                   2 /* dim */ >;
 
// Helper function to find next shape using KD-tree
static PCB_SHAPE* findNext( PCB_SHAPE* aShape, const VECTOR2I& aPoint, const KDTree& kdTree,
                            const PCB_SHAPE_ENDPOINTS_ADAPTOR& adaptor, unsigned aLimit )
{
    const double query_pt[2] = { static_cast<double>( aPoint.x ), static_cast<double>( aPoint.y ) };
 
    // Search for points within a very small radius for exact matches
    std::vector<nanoflann::ResultItem<size_t, double>> matches;
    double                                             search_radius_sq = static_cast<double>( aLimit * aLimit );
    nanoflann::RadiusResultSet<double, size_t>         radiusResultSet( search_radius_sq, matches );
 
    kdTree.findNeighbors( radiusResultSet, query_pt );
 
    if( matches.empty() )
        return nullptr;
 
    // Find the closest valid candidate
    PCB_SHAPE* closest_graphic = nullptr;
    double     closest_dist_sq = search_radius_sq;
 
    for( const auto& match : matches )
    {
        PCB_SHAPE* candidate = adaptor.endpoints[match.first].second;
 
        if( candidate == aShape )
            continue;
 
        if( match.second < closest_dist_sq && !candidate->HasFlag( SKIP_STRUCT ) )
        {
            closest_dist_sq = match.second;
            closest_graphic = candidate;
        }
    }
 
    return closest_graphic;
}
 
bool doConvertOutlineToPolygon( std::vector<PCB_SHAPE*>& aShapeList, SHAPE_POLY_SET& aPolygons,
                                int aErrorMax, int aChainingEpsilon, bool aAllowDisjoint,
                                OUTLINE_ERROR_HANDLER* aErrorHandler, bool aAllowUseArcsInPolygons,
                                SCOPED_FLAGS_CLEANER& aCleaner )
{
    if( aShapeList.size() == 0 )
        return true;
 
    bool       selfIntersecting = false;
    PCB_SHAPE* graphic = nullptr;
 
    std::set<PCB_SHAPE*> startCandidates( aShapeList.begin(), aShapeList.end() );
 
    // Pre-build KD-tree
    PCB_SHAPE_ENDPOINTS_ADAPTOR adaptor( aShapeList );
    KDTree                      kdTree( 2, adaptor, nanoflann::KDTreeSingleIndexAdaptorParams( 10 ) );
 
    // Keep a list of where the various shapes came from so after doing our combined-polygon
    // tests we can still report errors against the individual graphic items.
    std::map<std::pair<VECTOR2I, VECTOR2I>, PCB_SHAPE*> shapeOwners;
 
    auto fetchOwner =
            [&]( const SEG& seg ) -> PCB_SHAPE*
            {
                auto it = shapeOwners.find( std::make_pair( seg.A, seg.B ) );
                return it == shapeOwners.end() ? nullptr : it->second;
            };
 
    PCB_SHAPE* prevGraphic = nullptr;
    VECTOR2I   prevPt;
 
    std::vector<SHAPE_LINE_CHAIN> contours;
    contours.reserve( startCandidates.size() );
 
    for( PCB_SHAPE* shape : startCandidates )
        shape->ClearFlags( SKIP_STRUCT );
 
    while( startCandidates.size() )
    {
        graphic = (PCB_SHAPE*) *startCandidates.begin();
        graphic->SetFlags( SKIP_STRUCT );
        aCleaner.insert( graphic );
        startCandidates.erase( startCandidates.begin() );
 
        contours.emplace_back();
 
        SHAPE_LINE_CHAIN& currContour = contours.back();
        currContour.SetWidth( graphic->GetWidth() );
        bool firstPt = true;
 
        // Circles, rects and polygons are closed shapes unto themselves (and do not combine
        // with other shapes), so process them separately.
        if( graphic->GetShape() == SHAPE_T::POLY )
        {
            for( auto it = graphic->GetPolyShape().CIterate(); it; it++ )
            {
                VECTOR2I pt = *it;
 
                currContour.Append( pt );
 
                if( firstPt )
                    firstPt = false;
                else
                    shapeOwners[ std::make_pair( prevPt, pt ) ] = graphic;
 
                prevPt = pt;
            }
 
            currContour.SetClosed( true );
        }
        else if( graphic->GetShape() == SHAPE_T::CIRCLE )
        {
            VECTOR2I center = graphic->GetCenter();
            int      radius  = graphic->GetRadius();
            VECTOR2I start = center;
            start.x += radius;
 
            // Add 360 deg Arc in currContour
            SHAPE_ARC arc360( center, start, ANGLE_360, 0 );
            currContour.Append( arc360, aErrorMax );
            currContour.SetClosed( true );
 
            // set shapeOwners for currContour points created by appending the arc360:
            for( int ii = 1; ii < currContour.PointCount(); ++ii )
            {
                shapeOwners[ std::make_pair( currContour.CPoint( ii-1 ),
                                             currContour.CPoint( ii ) ) ] = graphic;
            }
 
            if( !aAllowUseArcsInPolygons )
                currContour.ClearArcs();
        }
        else if( graphic->GetShape() == SHAPE_T::RECTANGLE )
        {
            std::vector<VECTOR2I> pts = graphic->GetRectCorners();
 
            for( const VECTOR2I& pt : pts )
            {
                currContour.Append( pt );
 
                if( firstPt )
                    firstPt = false;
                else
                    shapeOwners[ std::make_pair( prevPt, pt ) ] = graphic;
 
                prevPt = pt;
            }
 
            currContour.SetClosed( true );
        }
        else
        {
            // Polygon start point. Arbitrarily chosen end of the segment and build the poly
            // from here.
            VECTOR2I startPt = graphic->GetEnd();
            prevPt = startPt;
            currContour.Append( prevPt );
 
            // do not append the other end point yet, this first 'graphic' might be an arc
            for(;;)
            {
                switch( graphic->GetShape() )
                {
                case SHAPE_T::RECTANGLE:
                case SHAPE_T::CIRCLE:
                {
                    // As a non-first item, closed shapes can't be anything but self-intersecting
                    if( aErrorHandler )
                    {
                        wxASSERT( prevGraphic );
                        (*aErrorHandler)( _( "(self-intersecting)" ), prevGraphic, graphic,
                                          prevPt );
                    }
 
                    selfIntersecting = true;
 
                    // A closed shape will finish where it started, so no point in updating prevPt
                    break;
                }
 
                case SHAPE_T::SEGMENT:
                {
                    VECTOR2I nextPt;
 
                    // Use the line segment end point furthest away from prevPt as we assume
                    // the other end to be ON prevPt or very close to it.
                    if( closer_to_first( prevPt, graphic->GetStart(), graphic->GetEnd()) )
                        nextPt = graphic->GetEnd();
                    else
                        nextPt = graphic->GetStart();
 
                    currContour.Append( nextPt );
                    shapeOwners[ std::make_pair( prevPt, nextPt ) ] = graphic;
                    prevPt = nextPt;
                }
                break;
 
                case SHAPE_T::ARC:
                {
                    VECTOR2I  pstart = graphic->GetStart();
                    VECTOR2I  pmid = graphic->GetArcMid();
                    VECTOR2I  pend = graphic->GetEnd();
 
                    if( !close_enough( prevPt, pstart, aChainingEpsilon ) )
                    {
                        wxASSERT( close_enough( prevPt, graphic->GetEnd(), aChainingEpsilon ) );
 
                        std::swap( pstart, pend );
                    }
 
                    // Snap the arc start point to avoid potential self-intersections
                    pstart = prevPt;
 
                    SHAPE_ARC sarc( pstart, pmid, pend, 0 );
 
                    SHAPE_LINE_CHAIN arcChain;
                    arcChain.Append( sarc, aErrorMax );
 
                    if( !aAllowUseArcsInPolygons )
                        arcChain.ClearArcs();
 
                    // set shapeOwners for arcChain points created by appending the sarc:
                    for( int ii = 1; ii < arcChain.PointCount(); ++ii )
                    {
                        shapeOwners[std::make_pair( arcChain.CPoint( ii - 1 ),
                                                    arcChain.CPoint( ii ) )] = graphic;
                    }
 
                    currContour.Append( arcChain );
 
                    prevPt = pend;
                }
                break;
 
                case SHAPE_T::BEZIER:
                {
                    // We do not support Bezier curves in polygons, so approximate with a series
                    // of short lines and put those line segments into the !same! PATH.
                    VECTOR2I nextPt;
                    bool    reverse = false;
 
                    // Use the end point furthest away from  prevPt as we assume the other
                    // end to be ON prevPt or very close to it.
                    if( closer_to_first( prevPt, graphic->GetStart(), graphic->GetEnd()) )
                    {
                        nextPt = graphic->GetEnd();
                    }
                    else
                    {
                        nextPt = graphic->GetStart();
                        reverse = true;
                    }
 
                    // Ensure the approximated Bezier shape is built
                    graphic->RebuildBezierToSegmentsPointsList( aErrorMax );
 
                    if( reverse )
                    {
                        for( int jj = graphic->GetBezierPoints().size()-1; jj >= 0; jj-- )
                        {
                            const VECTOR2I& pt = graphic->GetBezierPoints()[jj];
 
                            if( prevPt == pt )
                                continue;
 
                            currContour.Append( pt );
                            shapeOwners[ std::make_pair( prevPt, pt ) ] = graphic;
                            prevPt = pt;
                        }
                    }
                    else
                    {
                        for( const VECTOR2I& pt : graphic->GetBezierPoints() )
                        {
                            if( prevPt == pt )
                                continue;
 
                            currContour.Append( pt );
                            shapeOwners[ std::make_pair( prevPt, pt ) ] = graphic;
                            prevPt = pt;
                        }
                    }
 
                    prevPt = nextPt;
                }
                break;
 
                default:
                    UNIMPLEMENTED_FOR( graphic->SHAPE_T_asString() );
                    return false;
                }
 
                PCB_SHAPE* nextGraphic = findNext( graphic, prevPt, kdTree, adaptor, aChainingEpsilon );
 
                if( nextGraphic && !( nextGraphic->GetFlags() & SKIP_STRUCT ) )
                {
                    prevGraphic = graphic;
                    graphic = nextGraphic;
                    graphic->SetFlags( SKIP_STRUCT );
                    aCleaner.insert( graphic );
                    startCandidates.erase( graphic );
                    continue;
                }
 
                // Finished, or ran into trouble...
                if( close_enough( startPt, prevPt, aChainingEpsilon ) )
                {
                    if( startPt != prevPt && currContour.PointCount() > 2 )
                    {
                        // Snap the last shape's endpoint to the outline startpoint
                        PCB_SHAPE* owner = fetchOwner( currContour.CSegment( -1 ) );
 
                        if( currContour.IsArcEnd( currContour.PointCount() - 1 ) )
                        {
                            SHAPE_ARC arc = currContour.Arc(
                                    currContour.ArcIndex( currContour.PointCount() - 1 ) );
 
                            // Snap the arc endpoint
                            SHAPE_ARC sarc( arc.GetP0(), arc.GetArcMid(), startPt, 0 );
 
                            SHAPE_LINE_CHAIN arcChain;
                            arcChain.Append( sarc, aErrorMax );
 
                            if( !aAllowUseArcsInPolygons )
                                arcChain.ClearArcs();
 
                            // Set shapeOwners for arcChain points created by appending the sarc:
                            for( int ii = 1; ii < arcChain.PointCount(); ++ii )
                            {
                                shapeOwners[std::make_pair( arcChain.CPoint( ii - 1 ),
                                                            arcChain.CPoint( ii ) )] = owner;
                            }
 
                            currContour.RemoveShape( currContour.PointCount() - 1 );
                            currContour.Append( arcChain );
                        }
                        else
                        {
                            // Snap the segment endpoint
                            currContour.SetPoint( -1, startPt );
 
                            shapeOwners[std::make_pair( currContour.CPoints()[currContour.PointCount() - 2 ],
                                                        currContour.CLastPoint() )] = owner;
                        }
 
                        prevPt = startPt;
                    }
 
                    currContour.SetClosed( true );
                    break;
                }
                else if( nextGraphic )  // encountered already-used segment, but not at the start
                {
                    if( aErrorHandler )
                        (*aErrorHandler)( _( "(self-intersecting)" ), graphic, nextGraphic,
                                          prevPt );
 
                    break;
                }
                else                    // encountered discontinuity
                {
                    if( aErrorHandler )
                        (*aErrorHandler)( _( "(not a closed shape)" ), graphic, nullptr, prevPt );
 
                    break;
                }
            }
        }
    }
 
    for( const SHAPE_LINE_CHAIN& contour : contours )
    {
        if( !contour.IsClosed() )
            return false;
    }
 
    std::map<int, std::vector<int>> contourToParentIndexesMap;
 
    for( size_t ii = 0; ii < contours.size(); ++ii )
    {
        SHAPE_LINE_CHAIN& contour = contours[ii];
 
        if( !contour.GetCachedBBox()->IsValid() )
            contour.GenerateBBoxCache();
    }
 
    for( size_t ii = 0; ii < contours.size(); ++ii )
    {
        VECTOR2I         firstPt = contours[ii].GetPoint( 0 );
        std::vector<int> parents;
 
        for( size_t jj = 0; jj < contours.size(); ++jj )
        {
            if( jj == ii )
                continue;
 
            const SHAPE_LINE_CHAIN& parentCandidate = contours[jj];
 
            if( parentCandidate.PointInside( firstPt, 0, true ) )
                parents.push_back( jj );
        }
 
        contourToParentIndexesMap[ii] = std::move( parents );
    }
 
    // Next add those that are top-level outlines to the SHAPE_POLY_SET
    std::map<int, int> contourToOutlineIdxMap;
 
    for( const auto& [ contourIndex, parentIndexes ] : contourToParentIndexesMap )
    {
        if( parentIndexes.size() %2 == 0 )
        {
            // Even number of parents; top-level outline
            if( !aAllowDisjoint && !aPolygons.IsEmpty() )
            {
                if( aErrorHandler )
                {
                    BOARD_ITEM* a = fetchOwner( aPolygons.Outline( 0 ).GetSegment( 0 ) );
                    BOARD_ITEM* b = fetchOwner( contours[ contourIndex ].GetSegment( 0 ) );
 
                    if( a && b )
                    {
                        (*aErrorHandler)( _( "(multiple board outlines not supported)" ), a, b,
                                          contours[ contourIndex ].GetPoint( 0 ) );
 
                        return false;
                    }
                }
            }
 
            aPolygons.AddOutline( contours[ contourIndex ] );
            contourToOutlineIdxMap[ contourIndex ] = aPolygons.OutlineCount() - 1;
        }
    }
 
    // And finally add the holes
    for( const auto& [ contourIndex, parentIndexes ] : contourToParentIndexesMap )
    {
        if( parentIndexes.size() %2 == 1 )
        {
            // Odd number of parents; we're a hole in the parent which has one fewer parents
            // than we have.
            const SHAPE_LINE_CHAIN& hole = contours[ contourIndex ];
 
            for( int parentContourIdx : parentIndexes )
            {
                if( contourToParentIndexesMap[ parentContourIdx ].size() == parentIndexes.size() - 1 )
                {
                    int outlineIdx = contourToOutlineIdxMap[ parentContourIdx ];
                    aPolygons.AddHole( hole, outlineIdx );
                    break;
                }
            }
        }
    }
 
    // All of the silliness that follows is to work around the segment iterator while checking
    // for collisions.
    // TODO: Implement proper segment and point iterators that follow std
    std::vector<SEG> segments;
    size_t total = 0;
 
    for( int ii = 0; ii < aPolygons.OutlineCount(); ++ii )
    {
        const SHAPE_LINE_CHAIN& contour = aPolygons.Outline( ii );
        total += contour.SegmentCount();
 
        for( int jj = 0; jj < aPolygons.HoleCount( ii ); ++jj )
        {
            const SHAPE_LINE_CHAIN& hole = aPolygons.Hole( ii, jj );
            total += hole.SegmentCount();
        }
    }
 
    segments.reserve( total );
 
    for( auto seg = aPolygons.IterateSegmentsWithHoles(); seg; seg++ )
    {
        SEG segment = *seg;
 
        // Ensure segments are always ordered A < B
        if( LexicographicalCompare( segment.A, segment.B ) > 0 )
        {
            std::swap( segment.A, segment.B );
        }
 
        segments.push_back( segment );
    }
 
    std::sort( segments.begin(), segments.end(),
               []( const SEG& a, const SEG& b )
               {
                   if( a.A != b.A )
                       return LexicographicalCompare( a.A, b.A ) < 0;
 
                   return LexicographicalCompare( a.B, b.B ) < 0;
               } );
 
    for( size_t i = 0; i < segments.size(); ++i )
    {
        const SEG& seg1 = segments[i];
 
        for( size_t j = i + 1; j < segments.size(); ++j )
        {
            const SEG& seg2 = segments[j];
 
            if( seg2.A > seg1.B )
            {
                // No more segments to check, as they are sorted by A and B.
                break;
            }
 
            // Check for exact overlapping segments.
            if( seg1 == seg2 || ( seg1.A == seg2.B && seg1.B == seg2.A ) )
            {
                if( aErrorHandler )
                {
                    BOARD_ITEM* a = fetchOwner( seg1 );
                    BOARD_ITEM* b = fetchOwner( seg2 );
                    (*aErrorHandler)( _( "(self-intersecting)" ), a, b, seg1.A );
                }
 
                selfIntersecting = true;
            }
            else if( OPT_VECTOR2I pt = seg1.Intersect( seg2, true ) )
            {
                if( aErrorHandler )
                {
                    BOARD_ITEM* a = fetchOwner( seg1 );
                    BOARD_ITEM* b = fetchOwner( seg2 );
                    (*aErrorHandler)( _( "(self-intersecting)" ), a, b, *pt );
                }
 
                selfIntersecting = true;
            }
        }
    }
 
    return !selfIntersecting;
}
 
 
bool ConvertOutlineToPolygon( std::vector<PCB_SHAPE*>& aShapeList, SHAPE_POLY_SET& aPolygons,
                              int aErrorMax, int aChainingEpsilon, bool aAllowDisjoint,
                              OUTLINE_ERROR_HANDLER* aErrorHandler, bool aAllowUseArcsInPolygons )
{
    SCOPED_FLAGS_CLEANER cleaner( SKIP_STRUCT );
 
    return doConvertOutlineToPolygon( aShapeList, aPolygons, aErrorMax, aChainingEpsilon,
                                      aAllowDisjoint, aErrorHandler, aAllowUseArcsInPolygons,
                                      cleaner );
}
 
 
bool TestBoardOutlinesGraphicItems( BOARD* aBoard, int aMinDist,
                                    OUTLINE_ERROR_HANDLER* aErrorHandler )
{
    bool                success = true;
    PCB_TYPE_COLLECTOR  items;
    int                 min_dist = std::max( 0, aMinDist );
 
    // Get all the shapes into 'items', then keep only those on layer == Edge_Cuts.
    items.Collect( aBoard, { PCB_SHAPE_T } );
 
    std::vector<PCB_SHAPE*> shapeList;
 
    for( int ii = 0; ii < items.GetCount(); ii++ )
    {
        PCB_SHAPE* seg = static_cast<PCB_SHAPE*>( items[ii] );
 
        if( seg->GetLayer() == Edge_Cuts )
            shapeList.push_back( seg );
    }
 
    // Now Test validity of collected items
    for( PCB_SHAPE* shape : shapeList )
    {
        switch( shape->GetShape() )
        {
        case SHAPE_T::RECTANGLE:
        {
            VECTOR2I seg = shape->GetEnd() - shape->GetStart();
            int dim = seg.EuclideanNorm();
 
            if( dim <= min_dist )
            {
                success = false;
 
                if( aErrorHandler )
                {
                    (*aErrorHandler)( wxString::Format( _( "(rectangle has null or very small "
                                                           "size: %d nm)" ), dim ),
                                      shape, nullptr, shape->GetStart() );
                }
            }
            break;
        }
 
        case SHAPE_T::CIRCLE:
        {
            int r = shape->GetRadius();
 
            if( r <= min_dist )
            {
                success = false;
 
                if( aErrorHandler )
                {
                    (*aErrorHandler)( wxString::Format( _( "(circle has null or very small "
                                                           "radius: %d nm)" ), r ),
                                      shape, nullptr, shape->GetStart() );
                }
            }
            break;
        }
 
        case SHAPE_T::SEGMENT:
        {
            VECTOR2I seg = shape->GetEnd() - shape->GetStart();
            int dim = seg.EuclideanNorm();
 
            if( dim <= min_dist )
            {
                success = false;
 
                if( aErrorHandler )
                {
                    (*aErrorHandler)( wxString::Format( _( "(segment has null or very small "
                                                           "length: %d nm)" ), dim ),
                                      shape, nullptr, shape->GetStart() );
                }
            }
            break;
            }
 
        case SHAPE_T::ARC:
        {
            // Arc size can be evaluated from the distance between arc middle point and arc ends
            // We do not need a precise value, just an idea of its size
            VECTOR2I arcMiddle = shape->GetArcMid();
            VECTOR2I seg1 = arcMiddle - shape->GetStart();
            VECTOR2I seg2 = shape->GetEnd() - arcMiddle;
            int dim = seg1.EuclideanNorm() + seg2.EuclideanNorm();
 
            if( dim <= min_dist )
            {
                success = false;
 
                if( aErrorHandler )
                {
                    (*aErrorHandler)( wxString::Format( _( "(arc has null or very small size: "
                                                           "%d nm)" ), dim ),
                                      shape, nullptr, shape->GetStart() );
                }
            }
            break;
            }
 
        case SHAPE_T::POLY:
            break;
 
        case SHAPE_T::BEZIER:
            break;
 
        default:
            UNIMPLEMENTED_FOR( shape->SHAPE_T_asString() );
            return false;
        }
    }
 
    return success;
}
 
 
bool BuildBoardPolygonOutlines( BOARD* aBoard, SHAPE_POLY_SET& aOutlines, int aErrorMax,
                                int aChainingEpsilon, OUTLINE_ERROR_HANDLER* aErrorHandler,
                                bool aAllowUseArcsInPolygons )
{
    PCB_TYPE_COLLECTOR items;
    SHAPE_POLY_SET     fpHoles;
    bool               success = false;
 
    SCOPED_FLAGS_CLEANER cleaner( SKIP_STRUCT );
 
    // Get all the shapes into 'items', then keep only those on layer == Edge_Cuts.
    items.Collect( aBoard, { PCB_SHAPE_T } );
 
    for( int ii = 0; ii < items.GetCount(); ++ii )
        items[ii]->ClearFlags( SKIP_STRUCT );
 
    for( FOOTPRINT* fp : aBoard->Footprints() )
    {
        PCB_TYPE_COLLECTOR fpItems;
        fpItems.Collect( fp, { PCB_SHAPE_T } );
 
        std::vector<PCB_SHAPE*> fpSegList;
 
        for( int ii = 0; ii < fpItems.GetCount(); ii++ )
        {
            PCB_SHAPE* fpSeg = static_cast<PCB_SHAPE*>( fpItems[ii] );
 
            if( fpSeg->GetLayer() == Edge_Cuts )
                fpSegList.push_back( fpSeg );
        }
 
        if( !fpSegList.empty() )
        {
            SHAPE_POLY_SET fpOutlines;
            success = doConvertOutlineToPolygon( fpSegList, fpOutlines, aErrorMax, aChainingEpsilon,
                                                 false,
                                                 // don't report errors here; the second pass also
                                                 // gets an opportunity to use these segments
                                                 nullptr, aAllowUseArcsInPolygons, cleaner );
 
            // Test to see if we should make holes or outlines.  Holes are made if the footprint
            // has copper outside of a single, closed outline.  If there are multiple outlines,
            // we assume that the footprint edges represent holes as we do not support multiple
            // boards.  Similarly, if any of the footprint pads are located outside of the edges,
            // then the edges are holes
            if( success && ( isCopperOutside( fp, fpOutlines ) || fpOutlines.OutlineCount() > 1 ) )
            {
                fpHoles.Append( fpOutlines );
            }
            else
            {
                // If it wasn't a closed area, or wasn't a hole, the we want to keep the fpSegs
                // in contention for the board outline builds.
                for( int ii = 0; ii < fpItems.GetCount(); ++ii )
                    fpItems[ii]->ClearFlags( SKIP_STRUCT );
            }
        }
    }
 
    // Make a working copy of aSegList, because the list is modified during calculations
    std::vector<PCB_SHAPE*> segList;
 
    for( int ii = 0; ii < items.GetCount(); ii++ )
    {
        PCB_SHAPE* seg = static_cast<PCB_SHAPE*>( items[ii] );
 
        // Skip anything already used to generate footprint holes (above)
        if( seg->GetFlags() & SKIP_STRUCT )
            continue;
 
        if( seg->GetLayer() == Edge_Cuts )
            segList.push_back( seg );
    }
 
    if( segList.size() )
    {
        success = doConvertOutlineToPolygon( segList, aOutlines, aErrorMax, aChainingEpsilon, true,
                                             aErrorHandler, aAllowUseArcsInPolygons, cleaner );
    }
 
    if( !success || !aOutlines.OutlineCount() )
    {
        // Couldn't create a valid polygon outline.  Use the board edge cuts bounding box to
        // create a rectangular outline, or, failing that, the bounding box of the items on
        // the board.
        BOX2I bbbox = aBoard->GetBoardEdgesBoundingBox();
 
        // If null area, uses the global bounding box.
        if( ( bbbox.GetWidth() ) == 0 || ( bbbox.GetHeight() == 0 ) )
            bbbox = aBoard->ComputeBoundingBox( false );
 
        // Ensure non null area. If happen, gives a minimal size.
        if( ( bbbox.GetWidth() ) == 0 || ( bbbox.GetHeight() == 0 ) )
            bbbox.Inflate( pcbIUScale.mmToIU( 1.0 ) );
 
        aOutlines.RemoveAllContours();
        aOutlines.NewOutline();
 
        VECTOR2I corner;
        aOutlines.Append( bbbox.GetOrigin() );
 
        corner.x = bbbox.GetOrigin().x;
        corner.y = bbbox.GetEnd().y;
        aOutlines.Append( corner );
 
        aOutlines.Append( bbbox.GetEnd() );
 
        corner.x = bbbox.GetEnd().x;
        corner.y = bbbox.GetOrigin().y;
        aOutlines.Append( corner );
    }
 
    for( int ii = 0; ii < fpHoles.OutlineCount(); ++ii )
    {
        const VECTOR2I holePt = fpHoles.Outline( ii ).CPoint( 0 );
 
        for( int jj = 0; jj < aOutlines.OutlineCount(); ++jj )
        {
            if( aOutlines.Outline( jj ).PointInside( holePt ) )
            {
                aOutlines.AddHole( fpHoles.Outline( ii ), jj );
                break;
            }
        }
    }
 
    return success;
}
 
 
void buildBoardBoundingBoxPoly( const BOARD* aBoard, SHAPE_POLY_SET& aOutline )
{
    BOX2I            bbbox = aBoard->GetBoundingBox();
    SHAPE_LINE_CHAIN chain;
 
    // If null area, uses the global bounding box.
    if( ( bbbox.GetWidth() ) == 0 || ( bbbox.GetHeight() == 0 ) )
        bbbox = aBoard->ComputeBoundingBox( false );
 
    // Ensure non null area. If happen, gives a minimal size.
    if( ( bbbox.GetWidth() ) == 0 || ( bbbox.GetHeight() == 0 ) )
        bbbox.Inflate( pcbIUScale.mmToIU( 1.0 ) );
 
    // Inflate slightly (by 1/10th the size of the box)
    bbbox.Inflate( bbbox.GetWidth() / 10, bbbox.GetHeight() / 10 );
 
    chain.Append( bbbox.GetOrigin() );
    chain.Append( bbbox.GetOrigin().x, bbbox.GetEnd().y );
    chain.Append( bbbox.GetEnd() );
    chain.Append( bbbox.GetEnd().x, bbbox.GetOrigin().y );
    chain.SetClosed( true );
 
    aOutline.RemoveAllContours();
    aOutline.AddOutline( chain );
}
 
 
VECTOR2I projectPointOnSegment( const VECTOR2I& aEndPoint, const SHAPE_POLY_SET& aOutline,
        int aOutlineNum = 0 )
{
    int      minDistance = -1;
    VECTOR2I projPoint;
 
    for( auto it = aOutline.CIterateSegments( aOutlineNum ); it; it++ )
    {
        auto seg = it.Get();
        int dis = seg.Distance( aEndPoint );
 
        if( minDistance < 0 || ( dis < minDistance ) )
        {
            minDistance = dis;
            projPoint   = seg.NearestPoint( aEndPoint );
        }
    }
 
    return projPoint;
}
 
 
int findEndSegments( SHAPE_LINE_CHAIN& aChain, SEG& aStartSeg, SEG& aEndSeg )
{
    int foundSegs = 0;
 
    for( int i = 0; i < aChain.SegmentCount(); i++ )
    {
        SEG seg = aChain.Segment( i );
 
        bool foundA = false;
        bool foundB = false;
 
        for( int j = 0; j < aChain.SegmentCount(); j++ )
        {
            // Don't test the segment against itself
            if( i == j )
                continue;
 
            SEG testSeg = aChain.Segment( j );
 
            if( testSeg.Contains( seg.A ) )
                foundA = true;
 
            if( testSeg.Contains( seg.B ) )
                foundB = true;
        }
 
        // This segment isn't a start or end
        if( foundA && foundB )
            continue;
 
        if( foundSegs == 0 )
        {
            // The first segment we encounter is the "start" segment
            wxLogTrace( traceBoardOutline, wxT( "Found start segment: (%d, %d)-(%d, %d)" ),
                        seg.A.x, seg.A.y, seg.B.x, seg.B.y );
            aStartSeg = seg;
            foundSegs++;
        }
        else
        {
            // Once we find both start and end, we can stop
            wxLogTrace( traceBoardOutline, wxT( "Found end segment: (%d, %d)-(%d, %d)" ),
                        seg.A.x, seg.A.y, seg.B.x, seg.B.y );
            aEndSeg = seg;
            foundSegs++;
            break;
        }
    }
 
    return foundSegs;
}
 
 
bool BuildFootprintPolygonOutlines( BOARD* aBoard, SHAPE_POLY_SET& aOutlines, int aErrorMax,
                                    int aChainingEpsilon, OUTLINE_ERROR_HANDLER* aErrorHandler )
 
{
    FOOTPRINT* footprint = aBoard->GetFirstFootprint();
 
    // No footprint loaded
    if( !footprint )
    {
        wxLogTrace( traceBoardOutline, wxT( "No footprint found on board" ) );
        return false;
    }
 
    PCB_TYPE_COLLECTOR items;
    SHAPE_POLY_SET     outlines;
    bool               success = false;
 
    SCOPED_FLAGS_CLEANER cleaner( SKIP_STRUCT );
 
    // Get all the SHAPEs into 'items', then keep only those on layer == Edge_Cuts.
    items.Collect( aBoard, { PCB_SHAPE_T } );
 
    // Make a working copy of aSegList, because the list is modified during calculations
    std::vector<PCB_SHAPE*> segList;
 
    for( int ii = 0; ii < items.GetCount(); ii++ )
    {
        if( items[ii]->GetLayer() == Edge_Cuts )
            segList.push_back( static_cast<PCB_SHAPE*>( items[ii] ) );
    }
 
    if( !segList.empty() )
    {
        success = doConvertOutlineToPolygon( segList, outlines, aErrorMax, aChainingEpsilon, true,
                                             aErrorHandler, false, cleaner );
    }
 
    // A closed outline was found on Edge_Cuts
    if( success )
    {
        wxLogTrace( traceBoardOutline, wxT( "Closed outline found" ) );
 
        // If copper is outside a closed polygon, treat it as a hole
        // If there are multiple outlines in the footprint, they are also holes
        if( isCopperOutside( footprint, outlines ) || outlines.OutlineCount() > 1 )
        {
            wxLogTrace( traceBoardOutline, wxT( "Treating outline as a hole" ) );
 
            buildBoardBoundingBoxPoly( aBoard, aOutlines );
 
            // Copy all outlines from the conversion as holes into the new outline
            for( int i = 0; i < outlines.OutlineCount(); i++ )
            {
                SHAPE_LINE_CHAIN& out = outlines.Outline( i );
 
                if( out.IsClosed() )
                    aOutlines.AddHole( out, -1 );
 
                for( int j = 0; j < outlines.HoleCount( i ); j++ )
                {
                    SHAPE_LINE_CHAIN& hole = outlines.Hole( i, j );
 
                    if( hole.IsClosed() )
                        aOutlines.AddHole( hole, -1 );
                }
            }
        }
        // If all copper is inside, then the computed outline is the board outline
        else
        {
            wxLogTrace( traceBoardOutline, wxT( "Treating outline as board edge" ) );
            aOutlines = std::move( outlines );
        }
 
        return true;
    }
    // No board outlines were found, so use the bounding box
    else if( outlines.OutlineCount() == 0 )
    {
        wxLogTrace( traceBoardOutline, wxT( "Using footprint bounding box" ) );
        buildBoardBoundingBoxPoly( aBoard, aOutlines );
 
        return true;
    }
    // There is an outline present, but it is not closed
    else
    {
        wxLogTrace( traceBoardOutline, wxT( "Trying to build outline" ) );
 
        std::vector<SHAPE_LINE_CHAIN> closedChains;
        std::vector<SHAPE_LINE_CHAIN> openChains;
 
        // The ConvertOutlineToPolygon function returns only one main outline and the rest as
        // holes, so we promote the holes and process them
        openChains.push_back( outlines.Outline( 0 ) );
 
        for( int j = 0; j < outlines.HoleCount( 0 ); j++ )
        {
            SHAPE_LINE_CHAIN hole = outlines.Hole( 0, j );
 
            if( hole.IsClosed() )
            {
                wxLogTrace( traceBoardOutline, wxT( "Found closed hole" ) );
                closedChains.push_back( hole );
            }
            else
            {
                wxLogTrace( traceBoardOutline, wxT( "Found open hole" ) );
                openChains.push_back( hole );
            }
        }
 
        SHAPE_POLY_SET bbox;
        buildBoardBoundingBoxPoly( aBoard, bbox );
 
        // Treat the open polys as the board edge
        SHAPE_LINE_CHAIN chain = openChains[0];
        SHAPE_LINE_CHAIN rect  = bbox.Outline( 0 );
 
        // We know the outline chain is open, so set to non-closed to get better segment count
        chain.SetClosed( false );
 
        SEG startSeg;
        SEG endSeg;
 
        // The two possible board outlines
        SHAPE_LINE_CHAIN upper;
        SHAPE_LINE_CHAIN lower;
 
        findEndSegments( chain, startSeg, endSeg );
 
        if( chain.SegmentCount() == 0 )
        {
            // Something is wrong, bail out with the overall footprint bounding box
            wxLogTrace( traceBoardOutline, wxT( "No line segments in provided outline" ) );
            aOutlines = std::move( bbox );
            return true;
        }
        else if( chain.SegmentCount() == 1 )
        {
            // This case means there is only 1 line segment making up the edge cuts of the
            // footprint, so we just need to use it to cut the bounding box in half.
            wxLogTrace( traceBoardOutline, wxT( "Only 1 line segment in provided outline" ) );
 
            startSeg = chain.Segment( 0 );
 
            // Intersect with all the sides of the rectangle
            OPT_VECTOR2I inter0 = startSeg.IntersectLines( rect.Segment( 0 ) );
            OPT_VECTOR2I inter1 = startSeg.IntersectLines( rect.Segment( 1 ) );
            OPT_VECTOR2I inter2 = startSeg.IntersectLines( rect.Segment( 2 ) );
            OPT_VECTOR2I inter3 = startSeg.IntersectLines( rect.Segment( 3 ) );
 
            if( inter0 && inter2 && !inter1 && !inter3 )
            {
                // Intersects the vertical rectangle sides only
                wxLogTrace( traceBoardOutline, wxT( "Segment intersects only vertical bbox sides" ) );
 
                // The upper half
                upper.Append( *inter0 );
                upper.Append( rect.GetPoint( 1 ) );
                upper.Append( rect.GetPoint( 2 ) );
                upper.Append( *inter2 );
                upper.SetClosed( true );
 
                // The lower half
                lower.Append( *inter0 );
                lower.Append( rect.GetPoint( 0 ) );
                lower.Append( rect.GetPoint( 3 ) );
                lower.Append( *inter2 );
                lower.SetClosed( true );
            }
            else if( inter1 && inter3 && !inter0 && !inter2 )
            {
                // Intersects the horizontal rectangle sides only
                wxLogTrace( traceBoardOutline, wxT( "Segment intersects only horizontal bbox sides" ) );
 
                // The left half
                upper.Append( *inter1 );
                upper.Append( rect.GetPoint( 1 ) );
                upper.Append( rect.GetPoint( 0 ) );
                upper.Append( *inter3 );
                upper.SetClosed( true );
 
                // The right half
                lower.Append( *inter1 );
                lower.Append( rect.GetPoint( 2 ) );
                lower.Append( rect.GetPoint( 3 ) );
                lower.Append( *inter3 );
                lower.SetClosed( true );
            }
            else
            {
                // Angled line segment that cuts across a corner
                wxLogTrace( traceBoardOutline, wxT( "Segment intersects two perpendicular bbox sides" ) );
 
                // Figure out which actual lines are intersected, since IntersectLines assumes
                // an infinite line
                bool hit0 = rect.Segment( 0 ).Contains( *inter0 );
                bool hit1 = rect.Segment( 1 ).Contains( *inter1 );
                bool hit2 = rect.Segment( 2 ).Contains( *inter2 );
                bool hit3 = rect.Segment( 3 ).Contains( *inter3 );
 
                if( hit0 && hit1 )
                {
                    // Cut across the upper left corner
                    wxLogTrace( traceBoardOutline, wxT( "Segment cuts upper left corner" ) );
 
                    // The upper half
                    upper.Append( *inter0 );
                    upper.Append( rect.GetPoint( 1 ) );
                    upper.Append( *inter1 );
                    upper.SetClosed( true );
 
                    // The lower half
                    lower.Append( *inter0 );
                    lower.Append( rect.GetPoint( 0 ) );
                    lower.Append( rect.GetPoint( 3 ) );
                    lower.Append( rect.GetPoint( 2 ) );
                    lower.Append( *inter1 );
                    lower.SetClosed( true );
                }
                else if( hit1 && hit2 )
                {
                    // Cut across the upper right corner
                    wxLogTrace( traceBoardOutline, wxT( "Segment cuts upper right corner" ) );
 
                    // The upper half
                    upper.Append( *inter1 );
                    upper.Append( rect.GetPoint( 2 ) );
                    upper.Append( *inter2 );
                    upper.SetClosed( true );
 
                    // The lower half
                    lower.Append( *inter1 );
                    lower.Append( rect.GetPoint( 1 ) );
                    lower.Append( rect.GetPoint( 0 ) );
                    lower.Append( rect.GetPoint( 3 ) );
                    lower.Append( *inter2 );
                    lower.SetClosed( true );
                }
                else if( hit2 && hit3 )
                {
                    // Cut across the lower right corner
                    wxLogTrace( traceBoardOutline, wxT( "Segment cuts lower right corner" ) );
 
                    // The upper half
                    upper.Append( *inter2 );
                    upper.Append( rect.GetPoint( 2 ) );
                    upper.Append( rect.GetPoint( 1 ) );
                    upper.Append( rect.GetPoint( 0 ) );
                    upper.Append( *inter3 );
                    upper.SetClosed( true );
 
                    // The bottom half
                    lower.Append( *inter2 );
                    lower.Append( rect.GetPoint( 3 ) );
                    lower.Append( *inter3 );
                    lower.SetClosed( true );
                }
                else
                {
                    // Cut across the lower left corner
                    wxLogTrace( traceBoardOutline, wxT( "Segment cuts upper left corner" ) );
 
                    // The upper half
                    upper.Append( *inter0 );
                    upper.Append( rect.GetPoint( 1 ) );
                    upper.Append( rect.GetPoint( 2 ) );
                    upper.Append( rect.GetPoint( 3 ) );
                    upper.Append( *inter3 );
                    upper.SetClosed( true );
 
                    // The bottom half
                    lower.Append( *inter0 );
                    lower.Append( rect.GetPoint( 0 ) );
                    lower.Append( *inter3 );
                    lower.SetClosed( true );
                }
            }
        }
        else
        {
            // More than 1 segment
            wxLogTrace( traceBoardOutline, wxT( "Multiple segments in outline" ) );
 
            // Just a temporary thing
            aOutlines = std::move( bbox );
            return true;
        }
 
        // Figure out which is the correct outline
        SHAPE_POLY_SET poly1;
        SHAPE_POLY_SET poly2;
 
        poly1.NewOutline();
        poly1.Append( upper );
 
        poly2.NewOutline();
        poly2.Append( lower );
 
        if( isCopperOutside( footprint, poly1 ) )
        {
            wxLogTrace( traceBoardOutline, wxT( "Using lower shape" ) );
            aOutlines = std::move( poly2 );
        }
        else
        {
            wxLogTrace( traceBoardOutline, wxT( "Using upper shape" ) );
            aOutlines = std::move( poly1 );
        }
 
        // Add all closed polys as holes to the main outline
        for( SHAPE_LINE_CHAIN& closedChain : closedChains )
        {
            wxLogTrace( traceBoardOutline, wxT( "Adding hole to main outline" ) );
            aOutlines.AddHole( closedChain, -1 );
        }
 
        return true;
    }
 
    // We really shouldn't reach this point
    return false;
}