/* * This program source code file is part of KiCad, a free EDA CAD application. * * Copyright (C) 2007, 2008 Lubo Racko * Copyright (C) 2007, 2008, 2012-2013 Alexander Lunev * Copyright (C) 2012-2021 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 #include namespace PCAD2KICAD { PCB_LAYER_ID PCB::GetKiCadLayer( int aPCadLayer ) const { auto it = m_LayersMap.find( aPCadLayer ); if( it == m_LayersMap.end() ) THROW_IO_ERROR( wxString::Format( _( "Unknown PCad layer %u" ), unsigned( aPCadLayer ) ) ); return it->second.KiCadLayer; } LAYER_TYPE_T PCB::GetLayerType( int aPCadLayer ) const { auto it = m_LayersMap.find( aPCadLayer ); if( it == m_LayersMap.end() ) THROW_IO_ERROR( wxString::Format( _( "Unknown PCad layer %u" ), unsigned( aPCadLayer ) ) ); return it->second.layerType; } wxString PCB::GetLayerNetNameRef( int aPCadLayer ) const { auto it = m_LayersMap.find( aPCadLayer ); if( it == m_LayersMap.end() ) THROW_IO_ERROR( wxString::Format( _( "Unknown PCad layer %u" ), unsigned( aPCadLayer ) ) ); return it->second.netNameRef; } PCB::PCB( BOARD* aBoard ) : PCB_FOOTPRINT( this, aBoard ) { m_DefaultMeasurementUnit = wxT( "mil" ); for( size_t i = 0; i < 8; ++i ) { TLAYER layer; layer.KiCadLayer = F_Mask; // default layer.layerType = LAYER_TYPE_NONSIGNAL; // default layer.netNameRef = wxEmptyString; // default m_LayersMap.insert( std::make_pair( i, layer ) ); } m_SizeX = 0; m_SizeY = 0; m_LayersMap[1].KiCadLayer = F_Cu; m_LayersMap[1].layerType = LAYER_TYPE_SIGNAL; m_LayersMap[2].KiCadLayer = B_Cu; m_LayersMap[2].layerType = LAYER_TYPE_SIGNAL; m_LayersMap[3].KiCadLayer = Eco2_User; m_LayersMap[6].KiCadLayer = F_SilkS; m_LayersMap[7].KiCadLayer = B_SilkS; m_mappedBottom = false; m_mappedTop = false; } PCB::~PCB() { int i; for( i = 0; i < (int) m_PcbComponents.GetCount(); i++ ) { delete m_PcbComponents[i]; } for( i = 0; i < (int) m_PcbNetlist.GetCount(); i++ ) { delete m_PcbNetlist[i]; } } int PCB::GetNetCode( const wxString& aNetName ) const { const PCB_NET* net; for( int i = 0; i < (int) m_PcbNetlist.GetCount(); i++ ) { net = m_PcbNetlist[i]; if( net->m_Name == aNetName ) { return net->m_NetCode; } } return 0; } XNODE* PCB::FindCompDefName( XNODE* aNode, const wxString& aName ) const { XNODE* result = nullptr, * lNode; wxString propValue; lNode = FindNode( aNode, wxT( "compDef" ) ); while( lNode ) { if( lNode->GetName().IsSameAs( wxT( "compDef" ), false ) ) { lNode->GetAttribute( wxT( "Name" ), &propValue ); if( propValue == aName ) { result = lNode; lNode = nullptr; } } if( lNode ) lNode = lNode->GetNext(); } return result; } void PCB::SetTextProperty( XNODE* aNode, TTEXTVALUE* aTextValue, const wxString& aPatGraphRefName, const wxString& aXmlName, const wxString& aActualConversion ) { XNODE* tNode, * t1Node; wxString n, nnew, pn, propValue, str; // aNode is pattern now tNode = aNode; t1Node = aNode; n = aXmlName; // new file format version if( FindNode( tNode, wxT( "patternGraphicsNameRef" ) ) ) { FindNode( tNode, wxT( "patternGraphicsNameRef" ) )->GetAttribute( wxT( "Name" ), &pn ); pn.Trim( false ); pn.Trim( true ); tNode = FindNode( tNode, wxT( "patternGraphicsRef" ) ); while( tNode ) { if( tNode->GetName().IsSameAs( wxT( "patternGraphicsRef" ), false ) ) { if( FindNode( tNode, wxT( "patternGraphicsNameRef" ) ) ) { FindNode( tNode, wxT( "patternGraphicsNameRef" ) )->GetAttribute( wxT( "Name" ), &propValue ); if( propValue == pn ) { t1Node = tNode; // find correct section with same name. str = aTextValue->text; str.Trim( false ); str.Trim( true ); nnew = n; // new file version n = n + wxT( ' ' ) + str; // old file version tNode = nullptr; } } } if( tNode ) tNode = tNode->GetNext(); } } // old version and compatible for both from this point tNode = FindNode( t1Node, wxT( "attr" ) ); while( tNode ) { tNode->GetAttribute( wxT( "Name" ), &propValue ); propValue.Trim( false ); propValue.Trim( true ); if( propValue == n || propValue == nnew ) break; tNode = tNode->GetNext(); } if( tNode ) SetTextParameters( tNode, aTextValue, m_DefaultMeasurementUnit, aActualConversion ); } void PCB::DoPCBComponents( XNODE* aNode, wxXmlDocument* aXmlDoc, const wxString& aActualConversion, wxStatusBar* aStatusBar ) { XNODE* lNode, * tNode, * mNode; PCB_FOOTPRINT* fp; PCB_PAD* pad; PCB_VIA* via; PCB_KEEPOUT* keepOut; wxString cn, str, propValue; lNode = aNode->GetChildren(); while( lNode ) { fp = nullptr; if( lNode->GetName().IsSameAs( wxT( "pattern" ), false ) ) { FindNode( lNode, wxT( "patternRef" ) )->GetAttribute( wxT( "Name" ), &cn ); cn = ValidateName( cn ); tNode = FindNode( (XNODE *)aXmlDoc->GetRoot(), wxT( "library" ) ); if( tNode && cn.Len() > 0 ) { tNode = FindModulePatternDefName( tNode, cn ); if( tNode ) { fp = new PCB_FOOTPRINT( this, m_board ); mNode = FindNode( lNode, wxT( "patternGraphicsNameRef" ) ); if( mNode ) mNode->GetAttribute( wxT( "Name" ), &fp->m_patGraphRefName ); fp->Parse( tNode, aStatusBar, m_DefaultMeasurementUnit, aActualConversion ); } } if( fp ) { fp->m_compRef = cn; // default - in new version of file it is updated later.... tNode = FindNode( lNode, wxT( "refDesRef" ) ); if( tNode ) { tNode->GetAttribute( wxT( "Name" ), &fp->m_name.text ); SetTextProperty( lNode, &fp->m_name, fp->m_patGraphRefName, wxT( "RefDes" ), aActualConversion ); SetTextProperty( lNode, &fp->m_Value, fp->m_patGraphRefName, wxT( "Value" ), aActualConversion ); } tNode = FindNode( lNode, wxT( "pt" ) ); if( tNode ) { SetPosition( tNode->GetNodeContent(), m_DefaultMeasurementUnit, &fp->m_positionX, &fp->m_positionY, aActualConversion ); } tNode = FindNode( lNode, wxT( "rotation" ) ); if( tNode ) { str = tNode->GetNodeContent(); str.Trim( false ); fp->m_rotation = StrToInt1Units( str ); } str = FindNodeGetContent( lNode, wxT( "isFlipped" ) ); if( str.IsSameAs( wxT( "True" ), false ) ) fp->m_Mirror = 1; tNode = aNode; while( tNode->GetName() != wxT( "www.lura.sk" ) ) tNode = tNode->GetParent(); tNode = FindNode( tNode, wxT( "netlist" ) ); if( tNode ) { tNode = FindNode( tNode, wxT( "compInst" ) ); while( tNode ) { tNode->GetAttribute( wxT( "Name" ), &propValue ); if( propValue == fp->m_name.text ) { if( FindNode( tNode, wxT( "compValue" ) ) ) { FindNode( tNode, wxT( "compValue" ) )->GetAttribute( wxT( "Name" ), &fp->m_Value.text ); fp->m_Value.text.Trim( false ); fp->m_Value.text.Trim( true ); } if( FindNode( tNode, wxT( "compRef" ) ) ) { FindNode( tNode, wxT( "compRef" ) )->GetAttribute( wxT( "Name" ), &fp->m_compRef ); fp->m_compRef.Trim( false ); fp->m_compRef.Trim( true ); } tNode = nullptr; } else { tNode = tNode->GetNext(); } } } // map pins tNode = FindNode( (XNODE *)aXmlDoc->GetRoot(), wxT( "library" ) ); tNode = FindCompDefName( tNode, fp->m_compRef ); if( tNode ) { tNode = FindPinMap( tNode ); if( tNode ) { mNode = tNode->GetChildren(); while( mNode ) { if( mNode->GetName().IsSameAs( wxT( "padNum" ), false ) ) { str = mNode->GetNodeContent(); mNode = mNode->GetNext(); if( !mNode ) break; mNode->GetAttribute( wxT( "Name" ), &propValue ); fp->SetName( str, propValue ); mNode = mNode->GetNext(); } else { mNode = mNode->GetNext(); if( !mNode ) break; mNode = mNode->GetNext(); } } } } m_PcbComponents.Add( fp ); } } else if( lNode->GetName().IsSameAs( wxT( "pad" ), false ) ) { pad = new PCB_PAD( this, m_board ); pad->Parse( lNode, m_DefaultMeasurementUnit, aActualConversion ); m_PcbComponents.Add( pad ); } else if( lNode->GetName().IsSameAs( wxT( "via" ), false ) ) { via = new PCB_VIA( this, m_board ); via->Parse( lNode, m_DefaultMeasurementUnit, aActualConversion ); m_PcbComponents.Add( via ); } else if( lNode->GetName().IsSameAs( wxT( "polyKeepOut" ), false ) ) { keepOut = new PCB_KEEPOUT( m_callbacks, m_board, 0 ); if( keepOut->Parse( lNode, m_DefaultMeasurementUnit, aActualConversion ) ) m_PcbComponents.Add( keepOut ); else delete keepOut; } lNode = lNode->GetNext(); } } void PCB::ConnectPinToNet( const wxString& aCompRef, const wxString& aPinRef, const wxString& aNetName ) { PCB_FOOTPRINT* footprint; PCB_PAD* cp; int i, j; for( i = 0; i < (int) m_PcbComponents.GetCount(); i++ ) { footprint = (PCB_FOOTPRINT*) m_PcbComponents[i]; if( footprint->m_objType == wxT( 'M' ) && footprint->m_name.text == aCompRef ) { for( j = 0; j < (int) footprint->m_FootprintItems.GetCount(); j++ ) { if( footprint->m_FootprintItems[j]->m_objType == wxT( 'P' ) ) { cp = (PCB_PAD*) footprint->m_FootprintItems[j]; if( cp->m_name.text == aPinRef ) cp->m_net = aNetName; } } } } } int PCB::FindLayer( const wxString& aLayerName ) const { for( LAYER_NUM i = 0; i < (int)m_layersStackup.size(); ++i ) { if( m_layersStackup[i] == aLayerName ) return i; } return -1; } void PCB::MapLayer( XNODE* aNode ) { wxString lName, layerType; PCB_LAYER_ID KiCadLayer; long num = 0; aNode->GetAttribute( wxT( "Name" ), &lName ); lName = lName.MakeUpper(); if( lName == wxT( "TOP ASSY" ) ) { KiCadLayer = F_Fab; } else if( lName == wxT( "TOP SILK" ) ) { KiCadLayer = F_SilkS; } else if( lName == wxT( "TOP PASTE" ) ) { KiCadLayer = F_Paste; } else if( lName == wxT( "TOP MASK" ) ) { KiCadLayer = F_Mask; } else if( lName == wxT( "TOP" ) ) { KiCadLayer = F_Cu; m_mappedTop = true; } else if( lName == wxT( "BOTTOM" ) ) { KiCadLayer = B_Cu; m_mappedBottom = true; } else if( lName == wxT( "BOT MASK" ) ) { KiCadLayer = B_Mask; } else if( lName == wxT( "BOT PASTE" ) ) { KiCadLayer = B_Paste; } else if( lName == wxT( "BOT SILK" ) ) { KiCadLayer = B_SilkS; } else if( lName == wxT( "BOT ASSY" ) ) { KiCadLayer = B_Fab; } else if( lName == wxT( "BOARD" ) ) { KiCadLayer = Edge_Cuts; } else { int layernum = FindLayer( lName ); if( layernum == -1 ) KiCadLayer = Dwgs_User; // default else // Account for ordering (leave room for F.Cu and B.Cu // TODO: Add layer mapping widget if( !m_mappedTop ) ++layernum; if( m_mappedBottom ) --layernum; KiCadLayer = ToLAYER_ID( layernum ); } if( FindNode( aNode, wxT( "layerNum" ) ) ) FindNode( aNode, wxT( "layerNum" ) )->GetNodeContent().ToLong( &num ); if( num < 0 ) THROW_IO_ERROR( wxString::Format( wxT( "layerNum = %ld is out of range" ), num ) ); TLAYER newlayer; newlayer.KiCadLayer = KiCadLayer; if( FindNode( aNode, wxT( "layerType" ) ) ) { layerType = FindNode( aNode, wxT( "layerType" ) )->GetNodeContent().Trim( false ); if( layerType.IsSameAs( wxT( "NonSignal" ), false ) ) newlayer.layerType = LAYER_TYPE_NONSIGNAL; if( layerType.IsSameAs( wxT( "Signal" ), false ) ) newlayer.layerType = LAYER_TYPE_SIGNAL; if( layerType.IsSameAs( wxT( "Plane" ), false ) ) newlayer.layerType = LAYER_TYPE_PLANE; } m_LayersMap.insert( std::make_pair( num, newlayer ) ); if( FindNode( aNode, wxT( "netNameRef" ) ) ) { FindNode( aNode, wxT( "netNameRef" ) )->GetAttribute( wxT( "Name" ), &m_LayersMap[(int) num].netNameRef ); } } int PCB::FindOutlinePoint( const VERTICES_ARRAY* aOutline, wxRealPoint aPoint ) const { int i; for( i = 0; i < (int) aOutline->GetCount(); i++ ) { if( *((*aOutline)[i]) == aPoint ) return i; } return -1; } double PCB::GetDistance( const wxRealPoint* aPoint1, const wxRealPoint* aPoint2 ) const { return sqrt( ( aPoint1->x - aPoint2->x ) * ( aPoint1->x - aPoint2->x ) + ( aPoint1->y - aPoint2->y ) * ( aPoint1->y - aPoint2->y ) ); } void PCB::GetBoardOutline( wxXmlDocument* aXmlDoc, const wxString& aActualConversion ) { XNODE* iNode, *lNode, *pNode; long PCadLayer = 0; int x, y, i, j, targetInd; wxRealPoint* xchgPoint; double minDistance, distance; iNode = FindNode( (XNODE *)aXmlDoc->GetRoot(), wxT( "pcbDesign" ) ); if( iNode ) { // COMPONENTS AND OBJECTS iNode = iNode->GetChildren(); while( iNode ) { // objects if( iNode->GetName().IsSameAs( wxT( "layerContents" ), false ) ) { if( FindNode( iNode, wxT( "layerNumRef" ) ) ) FindNode( iNode, wxT( "layerNumRef" ) )->GetNodeContent().ToLong( &PCadLayer ); if( GetKiCadLayer( PCadLayer ) == Edge_Cuts ) { lNode = iNode->GetChildren(); while( lNode ) { if( lNode->GetName().IsSameAs( wxT( "line" ), false ) ) { pNode = FindNode( lNode, wxT( "pt" ) ); if( pNode ) { SetPosition( pNode->GetNodeContent(), m_DefaultMeasurementUnit, &x, &y, aActualConversion ); if( FindOutlinePoint( &m_BoardOutline, wxRealPoint( x, y) ) == -1 ) m_BoardOutline.Add( new wxRealPoint( x, y ) ); } if( pNode ) pNode = pNode->GetNext(); if( pNode ) { SetPosition( pNode->GetNodeContent(), m_DefaultMeasurementUnit, &x, &y, aActualConversion ); if( FindOutlinePoint( &m_BoardOutline, wxRealPoint( x, y) ) == -1 ) m_BoardOutline.Add( new wxRealPoint( x, y ) ); } } lNode = lNode->GetNext(); } //m_boardOutline.Sort( cmpFunc ); // sort vertices according to the distances between them if( m_BoardOutline.GetCount() > 3 ) { for( i = 0; i < (int) m_BoardOutline.GetCount() - 1; i++ ) { minDistance = GetDistance( m_BoardOutline[i], m_BoardOutline[ i + 1] ); targetInd = i + 1; for( j = i + 2; j < (int) m_BoardOutline.GetCount(); j++ ) { distance = GetDistance( m_BoardOutline[i], m_BoardOutline[j] ); if( distance < minDistance ) { minDistance = distance; targetInd = j; } } xchgPoint = m_BoardOutline[ i + 1]; m_BoardOutline[ i + 1] = m_BoardOutline[targetInd]; m_BoardOutline[targetInd] = xchgPoint; } } break; } } iNode = iNode->GetNext(); } } } void PCB::ParseBoard( wxStatusBar* aStatusBar, wxXmlDocument* aXmlDoc, const wxString& aActualConversion ) { XNODE* aNode;//, *aaNode; PCB_NET* net; PCB_COMPONENT* comp; PCB_FOOTPRINT* footprint; wxString compRef, pinRef, layerName, layerType; int i, j, netCode; // Default measurement units aNode = FindNode( (XNODE *)aXmlDoc->GetRoot(), wxT( "asciiHeader" ) ); if( aNode ) { aNode = FindNode( aNode, wxT( "fileUnits" ) ); if( aNode ) { m_DefaultMeasurementUnit = aNode->GetNodeContent().Lower(); m_DefaultMeasurementUnit.Trim( true ); m_DefaultMeasurementUnit.Trim( false ); } } // Determine layers stackup aNode = FindNode( (XNODE *)aXmlDoc->GetRoot(), wxT( "pcbDesign" ) ); /*if( aNode ) { aNode = FindNode( aNode, wxT( "layersStackup" ) ); if( aNode ) { aNode = FindNode( aNode, wxT( "layerStackupData" ) ); while( aNode ) { if( aNode->GetName() == wxT( "layerStackupData" ) ) { aaNode = FindNode( aNode, wxT( "layerStackupName" ) ); if( aaNode ) { aaNode->GetAttribute( wxT( "Name" ), &layerName ); layerName = layerName.MakeUpper(); m_layersStackup.Add( layerName ); } } aNode = aNode->GetNext(); } } }*/ if( aNode ) { aNode = FindNode( aNode, wxT( "layerDef" ) ); while( aNode ) { if( aNode->GetName().IsSameAs( wxT( "layerDef" ), false ) ) { if( FindNode( aNode, wxT( "layerType" ) ) ) { layerType = FindNode( aNode, wxT( "layerType" ) )->GetNodeContent().Trim( false ); if( layerType.IsSameAs( wxT( "Signal" ), false ) || layerType.IsSameAs( wxT( "Plane" ), false ) ) { aNode->GetAttribute( wxT( "Name" ), &layerName ); layerName = layerName.MakeUpper(); m_layersStackup.emplace_back( layerName ); if( m_layersStackup.size() > 32 ) THROW_IO_ERROR( _( "KiCad only supports 32 signal layers." ) ); } } } aNode = aNode->GetNext(); } } // Layers mapping aNode = FindNode( (XNODE *)aXmlDoc->GetRoot(), wxT( "pcbDesign" ) ); if( aNode ) { aNode = FindNode( aNode, wxT( "layerDef" ) ); while( aNode ) { if( aNode->GetName().IsSameAs( wxT( "layerDef" ), false ) ) MapLayer( aNode ); aNode = aNode->GetNext(); } } GetBoardOutline( aXmlDoc, aActualConversion ); // NETLIST // aStatusBar->SetStatusText( wxT( "Loading NETLIST " ) ); aNode = FindNode( (XNODE *)aXmlDoc->GetRoot(), wxT( "netlist" ) ); if( aNode ) { aNode = FindNode( aNode, wxT( "net" ) ); netCode = 1; while( aNode ) { net = new PCB_NET( netCode++ ); net->Parse( aNode ); m_PcbNetlist.Add( net ); aNode = aNode->GetNext(); } } // BOARD FILE // aStatusBar->SetStatusText( wxT( "Loading BOARD DEFINITION " ) ); aNode = FindNode( (XNODE *)aXmlDoc->GetRoot(), wxT( "pcbDesign" ) ); if( aNode ) { // COMPONENTS AND OBJECTS aNode = aNode->GetChildren(); while( aNode ) { // Components/footprints if( aNode->GetName().IsSameAs( wxT( "multiLayer" ), false ) ) DoPCBComponents( aNode, aXmlDoc, aActualConversion, aStatusBar ); // objects if( aNode->GetName().IsSameAs( wxT( "layerContents" ), false ) ) DoLayerContentsObjects( aNode, nullptr, &m_PcbComponents, aStatusBar, m_DefaultMeasurementUnit, aActualConversion ); aNode = aNode->GetNext(); } // POSTPROCESS -- SET NETLIST REFERENCES // aStatusBar->SetStatusText( wxT( "Processing NETLIST " ) ); for( i = 0; i < (int) m_PcbNetlist.GetCount(); i++ ) { net = m_PcbNetlist[i]; for( j = 0; j < (int) net->m_NetNodes.GetCount(); j++ ) { compRef = net->m_NetNodes[j]->m_CompRef; compRef.Trim( false ); compRef.Trim( true ); pinRef = net->m_NetNodes[j]->m_PinRef; pinRef.Trim( false ); pinRef.Trim( true ); ConnectPinToNet( compRef, pinRef, net->m_Name ); } } // POSTPROCESS -- FLIP COMPONENTS for( i = 0; i < (int) m_PcbComponents.GetCount(); i++ ) { if( m_PcbComponents[i]->m_objType == wxT( 'M' ) ) ( (PCB_FOOTPRINT*) m_PcbComponents[i] )->Flip(); } // POSTPROCESS -- SET/OPTIMIZE NEW PCB POSITION // aStatusBar->SetStatusText( wxT( "Optimizing BOARD POSITION " ) ); m_SizeX = 10000000; m_SizeY = 0; for( i = 0; i < (int) m_PcbComponents.GetCount(); i++ ) { comp = m_PcbComponents[i]; if( comp->m_positionY < m_SizeY ) m_SizeY = comp->m_positionY; // max Y if( comp->m_positionX < m_SizeX && comp->m_positionX > 0 ) m_SizeX = comp->m_positionX; // Min X } m_SizeY -= 10000; m_SizeX -= 10000; // aStatusBar->SetStatusText( wxT( " POSITIONING POSTPROCESS " ) ); for( i = 0; i < (int) m_PcbComponents.GetCount(); i++ ) m_PcbComponents[i]->SetPosOffset( -m_SizeX, -m_SizeY ); m_SizeX = 0; m_SizeY = 0; for( i = 0; i < (int) m_PcbComponents.GetCount(); i++ ) { comp = m_PcbComponents[i]; if( comp->m_positionY < m_SizeY ) m_SizeY = comp->m_positionY; // max Y if( comp->m_positionX > m_SizeX ) m_SizeX = comp->m_positionX; // Min X } // SHEET SIZE CALCULATION m_SizeY = -m_SizeY; // it is in absolute units m_SizeX += 10000; m_SizeY += 10000; // A4 is minimum $Descr A4 11700 8267 if( m_SizeX < 11700 ) m_SizeX = 11700; if( m_SizeY < 8267 ) m_SizeY = 8267; } else { // LIBRARY FILE // aStatusBar->SetStatusText( wxT( "Processing LIBRARY FILE " ) ); aNode = FindNode( (XNODE *)aXmlDoc->GetRoot(), wxT( "library" ) ); if( aNode ) { aNode = FindNode( aNode, wxT( "compDef" ) ); while( aNode ) { // aStatusBar->SetStatusText( wxT( "Processing COMPONENTS " ) ); if( aNode->GetName().IsSameAs( wxT( "compDef" ), false ) ) { footprint = new PCB_FOOTPRINT( this, m_board ); footprint->Parse( aNode, aStatusBar, m_DefaultMeasurementUnit, aActualConversion ); m_PcbComponents.Add( footprint ); } aNode = aNode->GetNext(); } } } } void PCB::AddToBoard() { int i; PCB_NET* net; m_board->SetCopperLayerCount( m_layersStackup.size() ); for( i = 0; i < (int) m_PcbNetlist.GetCount(); i++ ) { net = m_PcbNetlist[i]; m_board->Add( new NETINFO_ITEM( m_board, net->m_Name, net->m_NetCode ) ); } for( i = 0; i < (int) m_PcbComponents.GetCount(); i++ ) { m_PcbComponents[i]->AddToBoard(); } } } // namespace PCAD2KICAD