/* * 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 * 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 */ /** * @file convert_drawsegment_list_to_polygon.cpp * @brief functions to convert a shape built with DRAWSEGMENTS to a polygon. * expecting the shape describes shape similar to a polygon */ #include #include #include #include #include #include #include #include #include #include #include /** * Flag to enable debug tracing for the board outline creation * * Use "KICAD_BOARD_OUTLINE" to enable. * * @ingroup trace_env_vars */ const wxChar* traceBoardOutline = wxT( "KICAD_BOARD_OUTLINE" ); /** * Function close_ness * is a non-exact distance (also called Manhattan distance) used to approximate * the distance between two points. * The distance is very in-exact, but can be helpful when used * to pick between alternative neighboring points. * @param aLeft is the first point * @param aRight is the second point * @return unsigned - a measure of proximity that the caller knows about, in BIU, * but remember it is only an approximation. */ static unsigned close_ness( const wxPoint& aLeft, const wxPoint& aRight ) { // Don't need an accurate distance calculation, just something // approximating it, for relative ordering. return unsigned( std::abs( aLeft.x - aRight.x ) + abs( aLeft.y - aRight.y ) ); } /** * Function close_enough * is a local and tunable method of qualifying the proximity of two points. * * @param aLeft is the first point * @param aRight is the second point * @param aLimit is a measure of proximity that the caller knows about. * @return bool - true if the two points are close enough, else false. */ inline bool close_enough( const wxPoint& aLeft, const wxPoint& aRight, unsigned aLimit ) { // We don't use an accurate distance calculation, just something // approximating it, since aLimit is non-exact anyway except when zero. return close_ness( aLeft, aRight ) <= aLimit; } /** * Function close_st * is a local method of qualifying if either the start of end point of a segment is closest to a point. * * @param aReference is the reference point * @param aFirst is the first point * @param aSecond is the second point * @return bool - true if the the first point is closest to the reference, otherwise false. */ inline bool close_st( const wxPoint& aReference, const wxPoint& aFirst, const wxPoint& aSecond ) { // We don't use an accurate distance calculation, just something // approximating to find the closest to the reference. return close_ness( aReference, aFirst ) <= close_ness( aReference, aSecond ); } /** * Searches for a PCB_SHAPE matching a given end point or start point in a list. * @param aShape The starting shape. * @param aPoint The starting or ending point to search for. * @param aList The list to remove from. * @param aLimit is the distance from \a aPoint that still constitutes a valid find. * @return PCB_SHAPE* - The first PCB_SHAPE that has a start or end point matching * aPoint, otherwise NULL if none. */ static PCB_SHAPE* findNext( PCB_SHAPE* aShape, const wxPoint& aPoint, const std::vector& aList, unsigned aLimit ) { unsigned min_d = INT_MAX; int ndx_min = 0; // find the point closest to aPoint and perhaps exactly matching aPoint. for( size_t i = 0; i < aList.size(); ++i ) { PCB_SHAPE* graphic = aList[i]; if( graphic == aShape ) continue; unsigned d; switch( graphic->GetShape() ) { case S_ARC: if( aPoint == graphic->GetArcStart() || aPoint == graphic->GetArcEnd() ) { return graphic; } d = close_ness( aPoint, graphic->GetArcStart() ); if( d < min_d ) { min_d = d; ndx_min = i; } d = close_ness( aPoint, graphic->GetArcEnd() ); if( d < min_d ) { min_d = d; ndx_min = i; } break; default: if( aPoint == graphic->GetStart() || aPoint == graphic->GetEnd() ) { return graphic; } d = close_ness( aPoint, graphic->GetStart() ); if( d < min_d ) { min_d = d; ndx_min = i; } d = close_ness( aPoint, graphic->GetEnd() ); if( d < min_d ) { min_d = d; ndx_min = i; } } } if( min_d <= aLimit ) { return aList[ndx_min]; } return NULL; } /** * Function ConvertOutlineToPolygon * build a polygon (with holes) from a PCB_SHAPE list, which is expected to be * a outline, therefore a closed main outline with perhaps closed inner outlines. * These closed inner outlines are considered as holes in the main outline * @param aSegList the initial list of drawsegments (only lines, circles and arcs). * @param aPolygons will contain the complex polygon. * @param aTolerance is the max distance between points that is still accepted as connected * (internal units) * @param aErrorText is a wxString to return error message. * @param aDiscontinuities = an optional array of wxPoint giving the locations of * discontinuities in the outline * @param aIntersections = an optional array of wxPoint giving the locations of self- * intersections in the outline */ bool ConvertOutlineToPolygon( std::vector& aSegList, SHAPE_POLY_SET& aPolygons, unsigned int aTolerance, wxString* aErrorText, std::vector* aDiscontinuities, std::vector* aIntersections ) { if( aSegList.size() == 0 ) return true; bool polygonComplete = false; wxString msg; PCB_SHAPE* graphic; wxPoint prevPt; std::set startCandidates( aSegList.begin(), aSegList.end() ); // Find edge point with minimum x, this should be in the outer polygon // which will define the perimeter polygon polygon. wxPoint xmin = wxPoint( INT_MAX, 0 ); int xmini = 0; for( size_t i = 0; i < aSegList.size(); i++ ) { graphic = (PCB_SHAPE*) aSegList[i]; graphic->ClearFlags( SKIP_STRUCT ); switch( graphic->GetShape() ) { case S_RECT: case S_SEGMENT: { if( graphic->GetStart().x < xmin.x ) { xmin = graphic->GetStart(); xmini = i; } if( graphic->GetEnd().x < xmin.x ) { xmin = graphic->GetEnd(); xmini = i; } } break; case S_ARC: { wxPoint pstart = graphic->GetArcStart(); wxPoint center = graphic->GetCenter(); double angle = -graphic->GetAngle(); double radius = graphic->GetRadius(); int steps = GetArcToSegmentCount( radius, aTolerance, angle / 10.0 ); wxPoint pt; for( int step = 1; step<=steps; ++step ) { double rotation = ( angle * step ) / steps; pt = pstart; RotatePoint( &pt, center, rotation ); if( pt.x < xmin.x ) { xmin = pt; xmini = i; } } } break; case S_CIRCLE: { wxPoint pt = graphic->GetCenter(); // pt has minimum x point pt.x -= graphic->GetRadius(); // when the radius <= 0, this is a mal-formed circle. Skip it if( graphic->GetRadius() > 0 && pt.x < xmin.x ) { xmin = pt; xmini = i; } } break; case S_CURVE: { graphic->RebuildBezierToSegmentsPointsList( graphic->GetWidth() ); for( const wxPoint& pt : graphic->GetBezierPoints()) { if( pt.x < xmin.x ) { xmin = pt; xmini = i; } } } break; case S_POLYGON: { const SHAPE_POLY_SET poly = graphic->GetPolyShape(); MODULE* module = aSegList[0]->GetParentModule(); double orientation = module ? module->GetOrientation() : 0.0; VECTOR2I offset = module ? module->GetPosition() : VECTOR2I( 0, 0 ); for( auto iter = poly.CIterate(); iter; iter++ ) { VECTOR2I pt = *iter; RotatePoint( pt, orientation ); pt += offset; if( pt.x < xmin.x ) { xmin.x = pt.x; xmin.y = pt.y; xmini = i; } } } break; default: break; } } // Grab the left most point, assume its on the board's perimeter, and see if we // can put enough graphics together by matching endpoints to formulate a cohesive // polygon. graphic = (PCB_SHAPE*) aSegList[xmini]; graphic->SetFlags( SKIP_STRUCT ); startCandidates.erase( graphic ); // Output the outline perimeter as polygon. if( graphic->GetShape() == S_CIRCLE ) { TransformCircleToPolygon( aPolygons, graphic->GetCenter(), graphic->GetRadius(), ARC_LOW_DEF, ERROR_INSIDE ); polygonComplete = true; } else if( graphic->GetShape() == S_RECT ) { std::vector pts = graphic->GetRectCorners(); aPolygons.NewOutline(); for( const wxPoint& pt : pts ) aPolygons.Append( pt ); polygonComplete = true; } else if( graphic->GetShape() == S_POLYGON ) { MODULE* module = graphic->GetParentModule(); // NULL for items not in footprints double orientation = module ? module->GetOrientation() : 0.0; VECTOR2I offset = module ? module->GetPosition() : VECTOR2I( 0, 0 ); aPolygons.NewOutline(); for( auto it = graphic->GetPolyShape().CIterate( 0 ); it; it++ ) { auto pt = *it; RotatePoint( pt, orientation ); pt += offset; aPolygons.Append( pt ); } } else { // Polygon start point. Arbitrarily chosen end of the // segment and build the poly from here. wxPoint startPt = graphic->GetShape() == S_ARC ? graphic->GetArcEnd() : graphic->GetEnd(); prevPt = startPt; aPolygons.NewOutline(); aPolygons.Append( prevPt ); // Do not append the other end point yet of this 'graphic', this first // 'graphic' might be an arc or a curve. for(;;) { switch( graphic->GetShape() ) { case S_SEGMENT: { wxPoint 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( close_st( prevPt, graphic->GetStart(), graphic->GetEnd() ) ) nextPt = graphic->GetEnd(); else nextPt = graphic->GetStart(); aPolygons.Append( nextPt ); prevPt = nextPt; } break; case S_ARC: // We do not support arcs in polygons, so approximate an arc with a series of // short lines and put those line segments into the !same! PATH. { wxPoint pstart = graphic->GetArcStart(); wxPoint pend = graphic->GetArcEnd(); wxPoint pcenter = graphic->GetCenter(); double angle = -graphic->GetAngle(); double radius = graphic->GetRadius(); int steps = GetArcToSegmentCount( radius, aTolerance, angle / 10.0 ); if( !close_enough( prevPt, pstart, aTolerance ) ) { wxASSERT( close_enough( prevPt, graphic->GetArcEnd(), aTolerance ) ); angle = -angle; std::swap( pstart, pend ); } // Create intermediate points between start and end: for( int step = 1; step < steps; ++step ) { double rotation = ( angle * step ) / steps; wxPoint pt = pstart; RotatePoint( &pt, pcenter, rotation ); aPolygons.Append( pt ); } // Append the last arc end point aPolygons.Append( pend ); prevPt = pend; } break; case S_CURVE: // 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. { wxPoint 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( close_st( prevPt, graphic->GetStart(), graphic->GetEnd() ) ) nextPt = graphic->GetEnd(); else { nextPt = graphic->GetStart(); reverse = true; } if( reverse ) { for( int jj = graphic->GetBezierPoints().size()-1; jj >= 0; jj-- ) aPolygons.Append( graphic->GetBezierPoints()[jj] ); } else { for( size_t jj = 0; jj < graphic->GetBezierPoints().size(); jj++ ) aPolygons.Append( graphic->GetBezierPoints()[jj] ); } prevPt = nextPt; } break; default: wxFAIL_MSG( "Unsupported PCB_SHAPE type " + BOARD_ITEM::ShowShape( graphic->GetShape() ) ); return false; } // Get next closest segment. graphic = findNext( graphic, prevPt, aSegList, aTolerance ); if( graphic && !( graphic->GetFlags() & SKIP_STRUCT ) ) { graphic->SetFlags( SKIP_STRUCT ); startCandidates.erase( graphic ); continue; } // Finished, or ran into trouble... if( close_enough( startPt, prevPt, aTolerance ) ) { polygonComplete = true; break; } else if( graphic ) // encountered already-used segment, but not at the start { polygonComplete = false; break; } else // encountered discontinuity { if( aErrorText ) { msg.Printf( _( "Unable to find edge with an endpoint of (%s, %s)." ), StringFromValue( EDA_UNITS::MILLIMETRES, prevPt.x ), StringFromValue( EDA_UNITS::MILLIMETRES, prevPt.y ) ); *aErrorText << msg << "\n"; } if( aDiscontinuities ) aDiscontinuities->emplace_back( prevPt ); polygonComplete = false; break; } } } int holeNum = -1; while( startCandidates.size() ) { int hole = aPolygons.NewHole(); holeNum++; graphic = (PCB_SHAPE*) *startCandidates.begin(); graphic->SetFlags( SKIP_STRUCT ); startCandidates.erase( startCandidates.begin() ); // Both circles and polygons on the edge cuts layer are closed items that // do not connect to other elements, so we process them independently if( graphic->GetShape() == S_POLYGON ) { MODULE* module = graphic->GetParentModule(); // NULL for items not in footprints double orientation = module ? module->GetOrientation() : 0.0; VECTOR2I offset = module ? module->GetPosition() : VECTOR2I( 0, 0 ); for( auto it = graphic->GetPolyShape().CIterate(); it; it++ ) { auto val = *it; RotatePoint( val, orientation ); val += offset; aPolygons.Append( val, -1, hole ); } } else if( graphic->GetShape() == S_CIRCLE ) { // make a circle by segments; wxPoint center = graphic->GetCenter(); double angle = 3600.0; wxPoint start = center; int radius = graphic->GetRadius(); int steps = GetArcToSegmentCount( radius, aTolerance, 360.0 ); wxPoint nextPt; start.x += radius; for( int step = 0; step < steps; ++step ) { double rotation = ( angle * step ) / steps; nextPt = start; RotatePoint( &nextPt.x, &nextPt.y, center.x, center.y, rotation ); aPolygons.Append( nextPt, -1, hole ); } } else if( graphic->GetShape() == S_RECT ) { std::vector pts = graphic->GetRectCorners(); for( const wxPoint& pt : pts ) aPolygons.Append( pt, -1, hole ); } else { // Polygon start point. Arbitrarily chosen end of the // segment and build the poly from here. wxPoint startPt( graphic->GetEnd() ); prevPt = graphic->GetEnd(); aPolygons.Append( prevPt, -1, hole ); // do not append the other end point yet, this first 'graphic' might be an arc for(;;) { switch( graphic->GetShape() ) { case S_SEGMENT: { wxPoint 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( close_st( prevPt, graphic->GetStart(), graphic->GetEnd() ) ) nextPt = graphic->GetEnd(); else nextPt = graphic->GetStart(); prevPt = nextPt; aPolygons.Append( prevPt, -1, hole ); } break; case S_ARC: // We do not support arcs in polygons, so approximate an arc with a series of // short lines and put those line segments into the !same! PATH. { wxPoint pstart = graphic->GetArcStart(); wxPoint pend = graphic->GetArcEnd(); wxPoint pcenter = graphic->GetCenter(); double angle = -graphic->GetAngle(); int radius = graphic->GetRadius(); int steps = GetArcToSegmentCount( radius, aTolerance, angle / 10.0 ); if( !close_enough( prevPt, pstart, aTolerance ) ) { wxASSERT( close_enough( prevPt, graphic->GetArcEnd(), aTolerance ) ); angle = -angle; std::swap( pstart, pend ); } // Create intermediate points between start and end: for( int step = 1; step < steps; ++step ) { double rotation = ( angle * step ) / steps; wxPoint pt = pstart; RotatePoint( &pt, pcenter, rotation ); aPolygons.Append( pt, -1, hole ); } // Append the last arc end point aPolygons.Append( pend, -1, hole ); prevPt = pend; } break; case S_CURVE: // 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. { wxPoint 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( close_st( prevPt, graphic->GetStart(), graphic->GetEnd() ) ) nextPt = graphic->GetEnd(); else { nextPt = graphic->GetStart(); reverse = true; } if( reverse ) { for( int jj = graphic->GetBezierPoints().size()-1; jj >= 0; jj-- ) aPolygons.Append( graphic->GetBezierPoints()[jj], -1, hole ); } else { for( const wxPoint& pt : graphic->GetBezierPoints()) aPolygons.Append( pt, -1, hole ); } prevPt = nextPt; } break; default: wxFAIL_MSG( "Unsupported PCB_SHAPE type " + BOARD_ITEM::ShowShape( graphic->GetShape() ) ); return false; } // Get next closest segment. graphic = findNext( graphic, prevPt, aSegList, aTolerance ); if( graphic && !( graphic->GetFlags() & SKIP_STRUCT ) ) { graphic->SetFlags( SKIP_STRUCT ); startCandidates.erase( graphic ); continue; } // Finished, or ran into trouble... if( close_enough( startPt, prevPt, aTolerance ) ) { break; } else if( graphic ) // encountered already-used segment, but not at the start { polygonComplete = false; break; } else // encountered discontinuity { if( aErrorText ) { msg.Printf( _( "Unable to find edge with an endpoint of (%s, %s)." ), StringFromValue( EDA_UNITS::MILLIMETRES, prevPt.x ), StringFromValue( EDA_UNITS::MILLIMETRES, prevPt.y ) ); *aErrorText << msg << "\n"; } if( aDiscontinuities ) aDiscontinuities->emplace_back( prevPt ); polygonComplete = false; break; } } } } if( !polygonComplete ) return false; // 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 bool selfIntersecting = false; for( auto seg1 = aPolygons.IterateSegmentsWithHoles(); seg1; seg1++ ) { auto seg2 = seg1; for( ++seg2; seg2; seg2++ ) { // Check for exact overlapping segments. This is not viewed // as an intersection below if( *seg1 == *seg2 || ( ( *seg1 ).A == ( *seg2 ).B && ( *seg1 ).B == ( *seg2 ).A ) ) { if( aIntersections ) aIntersections->emplace_back( ( *seg1 ).A.x, ( *seg1 ).A.y ); selfIntersecting = true; } if( boost::optional pt = seg1.Get().Intersect( seg2.Get(), true ) ) { if( aIntersections ) aIntersections->emplace_back( (wxPoint) pt.get() ); selfIntersecting = true; } } } return !selfIntersecting; } #include #include /* This function is used to extract a board outlines (3D view, automatic zones build ...) * Any closed outline inside the main outline is a hole * All contours should be closed, i.e. valid closed polygon vertices */ bool BuildBoardPolygonOutlines( BOARD* aBoard, SHAPE_POLY_SET& aOutlines, unsigned int aTolerance, wxString* aErrorText, std::vector* aDiscontinuities, std::vector* aIntersections ) { PCB_TYPE_COLLECTOR items; bool success = false; // Get all the DRAWSEGMENTS and module graphics into 'items', // then keep only those on layer == Edge_Cuts. static const KICAD_T scan_graphics[] = { PCB_SHAPE_T, PCB_FP_SHAPE_T, EOT }; items.Collect( aBoard, scan_graphics ); // Make a working copy of aSegList, because the list is modified during calculations std::vector segList; for( int ii = 0; ii < items.GetCount(); ii++ ) { if( items[ii]->GetLayer() == Edge_Cuts ) segList.push_back( static_cast( items[ii] ) ); } if( segList.size() ) { success = ConvertOutlineToPolygon( segList, aOutlines, aTolerance, aErrorText, aDiscontinuities, aIntersections ); } else if( aErrorText ) { *aErrorText = _( "No edges found on Edge.Cuts layer." ); } 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. EDA_RECT bbbox = aBoard->GetBoardEdgesBoundingBox(); // If null area, uses the global bounding box. if( ( bbbox.GetWidth() ) == 0 || ( bbbox.GetHeight() == 0 ) ) bbbox = aBoard->ComputeBoundingBox(); // Ensure non null area. If happen, gives a minimal size. if( ( bbbox.GetWidth() ) == 0 || ( bbbox.GetHeight() == 0 ) ) bbbox.Inflate( Millimeter2iu( 1.0 ) ); aOutlines.RemoveAllContours(); aOutlines.NewOutline(); wxPoint 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 ); } return success; } /** * Get the complete bounding box of the board (including all items). * * The vertex numbers and segment numbers of the rectangle returned. * 1 * *---------------* * |1 2| * 0| |2 * |0 3| * *---------------* * 3 */ void buildBoardBoundingBoxPoly( const BOARD* aBoard, SHAPE_POLY_SET& aOutline ) { EDA_RECT 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(); // Ensure non null area. If happen, gives a minimal size. if( ( bbbox.GetWidth() ) == 0 || ( bbbox.GetHeight() == 0 ) ) bbbox.Inflate( Millimeter2iu( 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 ); } bool isCopperOutside( const MODULE* aMod, SHAPE_POLY_SET& aShape ) { bool padOutside = false; for( D_PAD* pad : aMod->Pads() ) { SHAPE_POLY_SET poly = aShape; poly.BooleanIntersection( *pad->GetEffectivePolygon(), SHAPE_POLY_SET::PM_FAST ); if( poly.OutlineCount() == 0 ) { wxPoint padPos = pad->GetPosition(); wxLogTrace( traceBoardOutline, "Tested pad (%d, %d): outside", padPos.x, padPos.y ); padOutside = true; break; } wxPoint padPos = pad->GetPosition(); wxLogTrace( traceBoardOutline, "Tested pad (%d, %d): not outside", padPos.x, padPos.y ); } return padOutside; } 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, "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, "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; } /** * This function is used to extract a board outline for a footprint view. * * Notes: * * Incomplete outlines will be closed by joining the end of the outline * onto the bounding box (by simply projecting the end points) and then take the * area that contains the copper. * * If all copper lies inside a closed outline, than that outline will be treated * as an external board outline. * * If copper is located outside a closed outline, then that outline will be treated * as a hole, and the outer edge will be formed using the bounding box. */ bool BuildFootprintPolygonOutlines( BOARD* aBoard, SHAPE_POLY_SET& aOutlines, unsigned int aTolerance, wxString* aErrorText, std::vector* aDiscontinuities, std::vector* aIntersections ) { PCB_TYPE_COLLECTOR items; SHAPE_POLY_SET outlines; // Get all the DRAWSEGMENTS and module graphics into 'items', // then keep only those on layer == Edge_Cuts. static const KICAD_T scan_graphics[] = { PCB_SHAPE_T, PCB_FP_SHAPE_T, EOT }; items.Collect( aBoard, scan_graphics ); // Make a working copy of aSegList, because the list is modified during calculations std::vector segList; for( int ii = 0; ii < items.GetCount(); ii++ ) { if( items[ii]->GetLayer() == Edge_Cuts ) segList.push_back( static_cast( items[ii] ) ); } bool success = ConvertOutlineToPolygon( segList, outlines, aTolerance, aErrorText, aDiscontinuities, aIntersections ); MODULE* boardMod = aBoard->GetFirstModule(); // No module loaded if( !boardMod ) { wxLogTrace( traceBoardOutline, "No module found on board" ); if( aErrorText ) *aErrorText = _( "No footprint loaded" ); return false; } // A closed outline was found if( success ) { wxLogTrace( traceBoardOutline, "Closed outline found" ); // If copper is outside a closed polygon, treat it as a hole if( isCopperOutside( boardMod, outlines ) ) { wxLogTrace( traceBoardOutline, "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, "Treating outline as board edge" ); aOutlines = outlines; } return true; } // No board outlines were found, so use the bounding box else if( outlines.OutlineCount() == 0 ) { wxLogTrace( traceBoardOutline, "Using footprint bounding box" ); buildBoardBoundingBoxPoly( aBoard, aOutlines ); return true; } // There is an outline present, but it is not closed else { wxLogTrace( traceBoardOutline, "Trying to build outline" ); std::vector closedChains; std::vector 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, "Found closed hole" ); closedChains.push_back( hole ); } else { wxLogTrace( traceBoardOutline, "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 module bounding box wxLogTrace( traceBoardOutline, "No line segments in provided outline" ); aOutlines = 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, "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, "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, "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, "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, "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, "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, "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, "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, "Multiple segments in outline" ); // Just a temporary thing aOutlines = 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( boardMod, poly1 ) ) { wxLogTrace( traceBoardOutline, "Using lower shape" ); aOutlines = poly2; } else { wxLogTrace( traceBoardOutline, "Using upper shape" ); aOutlines = poly1; } // Add all closed polys as holes to the main outline for( SHAPE_LINE_CHAIN& closedChain : closedChains ) { wxLogTrace( traceBoardOutline, "Adding hole to main outline" ); aOutlines.AddHole( closedChain, -1 ); } return true; } // We really shouldn't reach this point return false; }