/***********************************************/ /* zones_convert_to_polygons_aux_functions.cpp */ /***********************************************/ /* auxiliary functions used to calculare filled copper zones areas */ #include #include "fctsys.h" #include "polygons_defs.h" #include "common.h" #include "pcbnew.h" #include "wxPcbStruct.h" #include "trigo.h" #include "zones.h" #include "PolyLine.h" /** * Function BuildUnconnectedThermalStubsPolygonList * Creates a set of polygons corresponding to stubs created by thermal shapes on pads * which are not connected to a zone (dangling bridges) * @param aCornerBuffer = a std::vector where to store polygons * @param aPcb = the board. * @param aZone = a pointer to the ZONE_CONTAINER to examine. * @param aArcCorrection = a pointer to the ZONE_CONTAINER to examine. * @param aRoundPadThermalRotation = the rotation in 1.0 degree for thermal stubs in round pads */ void BuildUnconnectedThermalStubsPolygonList( std::vector& aCornerBuffer, BOARD* aPcb, ZONE_CONTAINER* aZone, double aArcCorrection, int aRoundPadThermalRotation) { std::vector corners_buffer; // a local polygon buffer to store one stub corners_buffer.reserve( 4 ); wxPoint ptTest[4]; int zone_clearance = aZone->m_ZoneClearance; EDA_RECT item_boundingbox; EDA_RECT zone_boundingbox = aZone->GetBoundingBox(); int biggest_clearance = aPcb->GetBiggestClearanceValue(); biggest_clearance = MAX( biggest_clearance, zone_clearance ); zone_boundingbox.Inflate( biggest_clearance ); // half size of the pen used to draw/plot zones outlines int pen_radius = aZone->m_ZoneMinThickness / 2; // Calculate thermal bridge half width int thermbridgeWidth = aZone->m_ThermalReliefCopperBridgeValue / 2; for( MODULE* module = aPcb->m_Modules; module; module = module->Next() ) { for( D_PAD* pad = module->m_Pads; pad != NULL; pad = pad->Next() ) { // check if( !pad->IsOnLayer( aZone->GetLayer() ) ) continue; if( pad->GetNet() != aZone->GetNet() ) continue; item_boundingbox = pad->GetBoundingBox(); item_boundingbox.Inflate( aZone->m_ThermalReliefGapValue ); if( !( item_boundingbox.Intersects( zone_boundingbox ) ) ) continue; // Thermal bridges are like a segment from a starting point inside the pad // to an ending point outside the pad wxPoint startpoint, endpoint; endpoint.x = ( pad->m_Size.x / 2 ) + aZone->m_ThermalReliefGapValue; endpoint.y = ( pad->m_Size.y / 2 ) + aZone->m_ThermalReliefGapValue; int copperThickness = aZone->m_ThermalReliefCopperBridgeValue - aZone->m_ZoneMinThickness; if( copperThickness < 0 ) copperThickness = 0; startpoint.x = min( pad->m_Size.x, copperThickness ); startpoint.y = min( pad->m_Size.y, copperThickness ); startpoint.x /= 2; startpoint.y /= 2; // This is CIRCLE pad tweak (for circle pads the thermal stubs are at 45 deg) int fAngle = pad->m_Orient; if( pad->m_PadShape == PAD_CIRCLE ) { endpoint.x = (int) ( endpoint.x * aArcCorrection ); endpoint.y = endpoint.x; fAngle = aRoundPadThermalRotation; } // contour line width has to be taken into calculation to avoid "thermal stub bleed" endpoint.x += pen_radius; endpoint.y += pen_radius; // compute north, south, west and east points for zone connection. ptTest[0] = wxPoint( 0, endpoint.y ); // lower point ptTest[1] = wxPoint( 0, -endpoint.y ); // upper point ptTest[2] = wxPoint( endpoint.x, 0 ); // right point ptTest[3] = wxPoint( -endpoint.x, 0 ); // left point // Test all sides for( int i = 0; i < 4; i++ ) { // rotate point RotatePoint( &ptTest[i], fAngle ); // translate point ptTest[i] += pad->ReturnShapePos(); if( aZone->HitTestFilledArea( ptTest[i] ) ) continue; corners_buffer.clear(); // polygons are rectangles with width of copper bridge value switch( i ) { case 0: // lower stub corners_buffer.push_back( wxPoint( -thermbridgeWidth, endpoint.y ) ); corners_buffer.push_back( wxPoint( +thermbridgeWidth, endpoint.y ) ); corners_buffer.push_back( wxPoint( +thermbridgeWidth, startpoint.y ) ); corners_buffer.push_back( wxPoint( -thermbridgeWidth, startpoint.y ) ); break; case 1: // upper stub corners_buffer.push_back( wxPoint( -thermbridgeWidth, -endpoint.y ) ); corners_buffer.push_back( wxPoint( +thermbridgeWidth, -endpoint.y ) ); corners_buffer.push_back( wxPoint( +thermbridgeWidth, -startpoint.y ) ); corners_buffer.push_back( wxPoint( -thermbridgeWidth, -startpoint.y ) ); break; case 2: // right stub corners_buffer.push_back( wxPoint( endpoint.x, -thermbridgeWidth ) ); corners_buffer.push_back( wxPoint( endpoint.x, thermbridgeWidth ) ); corners_buffer.push_back( wxPoint( +startpoint.x, thermbridgeWidth ) ); corners_buffer.push_back( wxPoint( +startpoint.x, -thermbridgeWidth ) ); break; case 3: // left stub corners_buffer.push_back( wxPoint( -endpoint.x, -thermbridgeWidth ) ); corners_buffer.push_back( wxPoint( -endpoint.x, thermbridgeWidth ) ); corners_buffer.push_back( wxPoint( -startpoint.x, thermbridgeWidth ) ); corners_buffer.push_back( wxPoint( -startpoint.x, -thermbridgeWidth ) ); break; } // add computed polygon to list for( unsigned ic = 0; ic < corners_buffer.size(); ic++ ) { wxPoint cpos = corners_buffer[ic]; RotatePoint( &cpos, fAngle ); // Rotate according to module orientation cpos += pad->ReturnShapePos(); // Shift origin to position CPolyPt corner; corner.x = cpos.x; corner.y = cpos.y; corner.end_contour = ( ic < (corners_buffer.size() - 1) ) ? 0 : 1; aCornerBuffer.push_back( corner ); } } } } }