/* * This program source code file is part of KiCad, a free EDA CAD application. * * Copyright (C) 2013 Cirilo Bernardo * Copyright (C) 2018-2023 KiCad Developers, see AUTHORS.txt for contributors. * * This program is free software; you can redistribute it and/or * modify it under the terms of the GNU General Public License * as published by the Free Software Foundation; either version 2 * of the License, or (at your option) any later version. * * This program is distributed in the hope that it will be useful, * but WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the * GNU General Public License for more details. * * You should have received a copy of the GNU General Public License * along with this program; if not, you may find one here: * http://www.gnu.org/licenses/old-licenses/gpl-2.0.html * or you may search the http://www.gnu.org website for the version 2 license, * or you may write to the Free Software Foundation, Inc., * 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301, USA */ #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include "project.h" #include "kiway.h" #include "3d_cache/3d_cache.h" #include "filename_resolver.h" #include // to define pcbIUScale.FromMillimeter(x) // assumed default graphical line thickness: == 0.1mm #define LINE_WIDTH (pcbIUScale.mmToIU( 0.1 )) static FILENAME_RESOLVER* resolver; /** * Retrieve line segment information from the edge layer and compiles the data into a form * which can be output as an IDFv3 compliant #BOARD_OUTLINE section. */ static void idf_export_outline( BOARD* aPcb, IDF3_BOARD& aIDFBoard ) { double scale = aIDFBoard.GetUserScale(); IDF_POINT sp, ep; // start and end points from KiCad item std::list< IDF_SEGMENT* > lines; // IDF intermediate form of KiCad graphical item IDF_OUTLINE* outline = nullptr; // graphical items forming an outline or cutout // NOTE: IMPLEMENTATION // If/when component cutouts are allowed, we must implement them separately. Cutouts // must be added to the board outline section and not to the Other Outline section. // The footprint cutouts should be handled via the idf_export_footprint() routine. double offX, offY; aIDFBoard.GetUserOffset( offX, offY ); // Retrieve segments and arcs from the board for( BOARD_ITEM* item : aPcb->Drawings() ) { if( item->Type() != PCB_SHAPE_T || item->GetLayer() != Edge_Cuts ) continue; PCB_SHAPE* graphic = static_cast( item ); switch( graphic->GetShape() ) { case SHAPE_T::SEGMENT: { if( graphic->GetStart() == graphic->GetEnd() ) break; sp.x = graphic->GetStart().x * scale + offX; sp.y = -graphic->GetStart().y * scale + offY; ep.x = graphic->GetEnd().x * scale + offX; ep.y = -graphic->GetEnd().y * scale + offY; IDF_SEGMENT* seg = new IDF_SEGMENT( sp, ep ); if( seg ) lines.push_back( seg ); break; } case SHAPE_T::RECTANGLE: { if( graphic->GetStart() == graphic->GetEnd() ) break; double top = graphic->GetStart().y * scale + offY; double left = graphic->GetStart().x * scale + offX; double bottom = graphic->GetEnd().y * scale + offY; double right = graphic->GetEnd().x * scale + offX; IDF_POINT corners[4]; corners[0] = IDF_POINT( left, top ); corners[1] = IDF_POINT( right, top ); corners[2] = IDF_POINT( right, bottom ); corners[3] = IDF_POINT( left, bottom ); lines.push_back( new IDF_SEGMENT( corners[0], corners[1] ) ); lines.push_back( new IDF_SEGMENT( corners[1], corners[2] ) ); lines.push_back( new IDF_SEGMENT( corners[2], corners[3] ) ); lines.push_back( new IDF_SEGMENT( corners[3], corners[0] ) ); break; } case SHAPE_T::ARC: { if( graphic->GetCenter() == graphic->GetStart() ) break; sp.x = graphic->GetCenter().x * scale + offX; sp.y = -graphic->GetCenter().y * scale + offY; ep.x = graphic->GetStart().x * scale + offX; ep.y = -graphic->GetStart().y * scale + offY; IDF_SEGMENT* seg = new IDF_SEGMENT( sp, ep, -graphic->GetArcAngle().AsDegrees(), true ); if( seg ) lines.push_back( seg ); break; } case SHAPE_T::CIRCLE: { if( graphic->GetRadius() == 0 ) break; sp.x = graphic->GetCenter().x * scale + offX; sp.y = -graphic->GetCenter().y * scale + offY; ep.x = sp.x - graphic->GetRadius() * scale; ep.y = sp.y; // Circles must always have an angle of +360 deg. to appease // quirky MCAD implementations of IDF. IDF_SEGMENT* seg = new IDF_SEGMENT( sp, ep, 360.0, true ); if( seg ) lines.push_back( seg ); break; } default: break; } } // if there is no outline then use the bounding box if( lines.empty() ) { goto UseBoundingBox; } // get the board outline and write it out // note: we do not use a try/catch block here since we intend // to simply ignore unclosed loops and continue processing // until we're out of segments to process outline = new IDF_OUTLINE; IDF3::GetOutline( lines, *outline ); if( outline->empty() ) goto UseBoundingBox; aIDFBoard.AddBoardOutline( outline ); outline = nullptr; // get all cutouts and write them out while( !lines.empty() ) { if( !outline ) outline = new IDF_OUTLINE; IDF3::GetOutline( lines, *outline ); if( outline->empty() ) { outline->Clear(); continue; } aIDFBoard.AddBoardOutline( outline ); outline = nullptr; } return; UseBoundingBox: // clean up if necessary while( !lines.empty() ) { delete lines.front(); lines.pop_front(); } if( outline ) outline->Clear(); else outline = new IDF_OUTLINE; // Fetch a rectangular bounding box for the board; there is always some uncertainty in the // board dimensions computed via ComputeBoundingBox() since this depends on the individual // footprint entities. BOX2I bbbox = aPcb->GetBoardEdgesBoundingBox(); // convert to mm and compensate for an assumed LINE_WIDTH line thickness double x = ( bbbox.GetOrigin().x + LINE_WIDTH / 2 ) * scale + offX; double y = ( bbbox.GetOrigin().y + LINE_WIDTH / 2 ) * scale + offY; double dx = ( bbbox.GetSize().x - LINE_WIDTH ) * scale; double dy = ( bbbox.GetSize().y - LINE_WIDTH ) * scale; double px[4], py[4]; px[0] = x; py[0] = y; px[1] = x; py[1] = y + dy; px[2] = x + dx; py[2] = y + dy; px[3] = x + dx; py[3] = y; IDF_POINT p1, p2; p1.x = px[3]; p1.y = py[3]; p2.x = px[0]; p2.y = py[0]; outline->push( new IDF_SEGMENT( p1, p2 ) ); for( int i = 1; i < 4; ++i ) { p1.x = px[i - 1]; p1.y = py[i - 1]; p2.x = px[i]; p2.y = py[i]; outline->push( new IDF_SEGMENT( p1, p2 ) ); } aIDFBoard.AddBoardOutline( outline ); } /** * Retrieve information from all board footprints, adds drill holes to the DRILLED_HOLES or * BOARD_OUTLINE section as appropriate, Compiles data for the PLACEMENT section and compiles * data for the library ELECTRICAL section. */ static void idf_export_footprint( BOARD* aPcb, FOOTPRINT* aFootprint, IDF3_BOARD& aIDFBoard, bool aIncludeUnspecified, bool aIncludeDNP ) { // Reference Designator std::string crefdes = TO_UTF8( aFootprint->Reference().GetShownText( false ) ); wxString libraryName = aFootprint->GetFPID().GetLibNickname(); wxString footprintBasePath = wxEmptyString; if( aPcb->GetProject() ) { const FP_LIB_TABLE_ROW* fpRow = nullptr; try { fpRow = PROJECT_PCB::PcbFootprintLibs( aPcb->GetProject() )->FindRow( libraryName, false ); } catch( ... ) { // Not found: do nothing } if( fpRow ) footprintBasePath = fpRow->GetFullURI( true ); } if( crefdes.empty() || !crefdes.compare( "~" ) ) { std::string cvalue = TO_UTF8( aFootprint->Value().GetShownText( false ) ); // if both the RefDes and Value are empty or set to '~' the board owns the part, // otherwise associated parts of the footprint must be marked NOREFDES. if( cvalue.empty() || !cvalue.compare( "~" ) ) crefdes = "BOARD"; else crefdes = "NOREFDES"; } // TODO: If footprint cutouts are supported we must add code here // for( EDA_ITEM* item = aFootprint->GraphicalItems(); item != NULL; item = item->Next() ) // { // if( item->Type() != PCB_SHAPE_T || item->GetLayer() != Edge_Cuts ) // continue; // code to export cutouts // } // Export pads double drill, x, y; double scale = aIDFBoard.GetUserScale(); IDF3::KEY_PLATING kplate; std::string pintype; std::string tstr; double dx, dy; aIDFBoard.GetUserOffset( dx, dy ); for( auto pad : aFootprint->Pads() ) { drill = (double) pad->GetDrillSize().x * scale; x = pad->GetPosition().x * scale + dx; y = -pad->GetPosition().y * scale + dy; // Export the hole on the edge layer if( drill > 0.0 ) { // plating if( pad->GetAttribute() == PAD_ATTRIB::NPTH ) kplate = IDF3::NPTH; else kplate = IDF3::PTH; // hole type tstr = TO_UTF8( pad->GetNumber() ); if( tstr.empty() || !tstr.compare( "0" ) || !tstr.compare( "~" ) || ( kplate == IDF3::NPTH ) || ( pad->GetDrillShape() == PAD_DRILL_SHAPE::OBLONG ) ) pintype = "MTG"; else pintype = "PIN"; // fields: // 1. hole dia. : float // 2. X coord : float // 3. Y coord : float // 4. plating : PTH | NPTH // 5. Assoc. part : BOARD | NOREFDES | PANEL | {"refdes"} // 6. type : PIN | VIA | MTG | TOOL | { "other" } // 7. owner : MCAD | ECAD | UNOWNED if( ( pad->GetDrillShape() == PAD_DRILL_SHAPE::OBLONG ) && ( pad->GetDrillSize().x != pad->GetDrillSize().y ) ) { // NOTE: IDF does not have direct support for slots; // slots are implemented as a board cutout and we // cannot represent plating or reference designators double dlength = pad->GetDrillSize().y * scale; // NOTE: The orientation of footprints and pads have // the opposite sense due to KiCad drawing on a // screen with a LH coordinate system double angle = pad->GetOrientation().AsDegrees(); // NOTE: Since this code assumes the scenario where // GetDrillSize().y is the length but idf_parser.cpp // assumes a length along the X axis, the orientation // must be shifted +90 deg when GetDrillSize().y is // the major axis. if( dlength < drill ) { std::swap( drill, dlength ); } else { angle += 90.0; } // NOTE: KiCad measures a slot's length from end to end // rather than between the centers of the arcs dlength -= drill; aIDFBoard.AddSlot( drill, dlength, angle, x, y ); } else { IDF_DRILL_DATA *dp = new IDF_DRILL_DATA( drill, x, y, kplate, crefdes, pintype, IDF3::ECAD ); if( !aIDFBoard.AddDrill( dp ) ) { delete dp; std::ostringstream ostr; ostr << __FILE__ << ":" << __LINE__ << ":" << __FUNCTION__; ostr << "(): could not add drill"; throw std::runtime_error( ostr.str() ); } } } } if( ( !(aFootprint->GetAttributes() & (FP_THROUGH_HOLE|FP_SMD)) ) && !aIncludeUnspecified ) return; if( aFootprint->IsDNP() && !aIncludeDNP ) return; // add any valid models to the library item list std::string refdes; IDF3_COMPONENT* comp = nullptr; auto sM = aFootprint->Models().begin(); auto eM = aFootprint->Models().end(); wxFileName idfFile; wxString idfExt; while( sM != eM ) { if( !sM->m_Show ) { ++sM; continue; } idfFile.Assign( resolver->ResolvePath( sM->m_Filename, footprintBasePath ) ); idfExt = idfFile.GetExt(); if( idfExt.Cmp( wxT( "idf" ) ) && idfExt.Cmp( wxT( "IDF" ) ) ) { ++sM; continue; } if( refdes.empty() ) { refdes = TO_UTF8( aFootprint->Reference().GetShownText( false ) ); // NOREFDES cannot be used or else the software gets confused // when writing out the placement data due to conflicting // placement and layer specifications; to work around this we // create a (hopefully) unique refdes for our exported part. if( refdes.empty() || !refdes.compare( "~" ) ) refdes = aIDFBoard.GetNewRefDes(); } IDF3_COMP_OUTLINE* outline; outline = aIDFBoard.GetComponentOutline( idfFile.GetFullPath() ); if( !outline ) throw( std::runtime_error( aIDFBoard.GetError() ) ); double rotz = aFootprint->GetOrientation().AsDegrees(); double locx = sM->m_Offset.x * 25.4; // part offsets are in inches double locy = sM->m_Offset.y * 25.4; double locz = sM->m_Offset.z * 25.4; double lrot = sM->m_Rotation.z; bool top = ( aFootprint->GetLayer() == B_Cu ) ? false : true; if( top ) { locy = -locy; RotatePoint( &locx, &locy, aFootprint->GetOrientation() ); locy = -locy; } if( !top ) { lrot = -lrot; RotatePoint( &locx, &locy, aFootprint->GetOrientation() ); locy = -locy; rotz = 180.0 - rotz; if( rotz >= 360.0 ) while( rotz >= 360.0 ) rotz -= 360.0; if( rotz <= -360.0 ) while( rotz <= -360.0 ) rotz += 360.0; } if( comp == nullptr ) comp = aIDFBoard.FindComponent( refdes ); if( comp == nullptr ) { comp = new IDF3_COMPONENT( &aIDFBoard ); if( comp == nullptr ) throw( std::runtime_error( aIDFBoard.GetError() ) ); comp->SetRefDes( refdes ); if( top ) { comp->SetPosition( aFootprint->GetPosition().x * scale + dx, -aFootprint->GetPosition().y * scale + dy, rotz, IDF3::LYR_TOP ); } else { comp->SetPosition( aFootprint->GetPosition().x * scale + dx, -aFootprint->GetPosition().y * scale + dy, rotz, IDF3::LYR_BOTTOM ); } comp->SetPlacement( IDF3::PS_ECAD ); aIDFBoard.AddComponent( comp ); } else { double refX, refY, refA; IDF3::IDF_LAYER side; if( ! comp->GetPosition( refX, refY, refA, side ) ) { // place the item if( top ) { comp->SetPosition( aFootprint->GetPosition().x * scale + dx, -aFootprint->GetPosition().y * scale + dy, rotz, IDF3::LYR_TOP ); } else { comp->SetPosition( aFootprint->GetPosition().x * scale + dx, -aFootprint->GetPosition().y * scale + dy, rotz, IDF3::LYR_BOTTOM ); } comp->SetPlacement( IDF3::PS_ECAD ); } else { // check that the retrieved component matches this one refX = refX - ( aFootprint->GetPosition().x * scale + dx ); refY = refY - ( -aFootprint->GetPosition().y * scale + dy ); refA = refA - rotz; refA *= refA; refX *= refX; refY *= refY; refX += refY; // conditions: same side, X,Y coordinates within 10 microns, // angle within 0.01 degree if( ( top && side == IDF3::LYR_BOTTOM ) || ( !top && side == IDF3::LYR_TOP ) || ( refA > 0.0001 ) || ( refX > 0.0001 ) ) { comp->GetPosition( refX, refY, refA, side ); std::ostringstream ostr; ostr << "* " << __FILE__ << ":" << __LINE__ << ":" << __FUNCTION__ << "():\n"; ostr << "* conflicting Reference Designator '" << refdes << "'\n"; ostr << "* X loc: " << ( aFootprint->GetPosition().x * scale + dx); ostr << " vs. " << refX << "\n"; ostr << "* Y loc: " << ( -aFootprint->GetPosition().y * scale + dy); ostr << " vs. " << refY << "\n"; ostr << "* angle: " << rotz; ostr << " vs. " << refA << "\n"; if( top ) ostr << "* TOP vs. "; else ostr << "* BOTTOM vs. "; if( side == IDF3::LYR_TOP ) ostr << "TOP"; else ostr << "BOTTOM"; throw( std::runtime_error( ostr.str() ) ); } } } // create the local data ... IDF3_COMP_OUTLINE_DATA* data = new IDF3_COMP_OUTLINE_DATA( comp, outline ); data->SetOffsets( locx, locy, locz, lrot ); comp->AddOutlineData( data ); ++sM; } } /** * Generate IDFv3 compliant board (*.emn) and library (*.emp) files representing the user's * PCB design. */ bool PCB_EDIT_FRAME::Export_IDF3( BOARD* aPcb, const wxString& aFullFileName, bool aUseThou, double aXRef, double aYRef, bool aIncludeUnspecified, bool aIncludeDNP ) { IDF3_BOARD idfBoard( IDF3::CAD_ELEC ); // Switch the locale to standard C (needed to print floating point numbers) LOCALE_IO toggle; resolver = PROJECT_PCB::Get3DCacheManager( &Prj() )->GetResolver(); bool ok = true; double scale = pcbIUScale.MM_PER_IU; // we must scale internal units to mm for IDF IDF3::IDF_UNIT idfUnit; if( aUseThou ) { idfUnit = IDF3::UNIT_THOU; idfBoard.SetUserPrecision( 1 ); } else { idfUnit = IDF3::UNIT_MM; idfBoard.SetUserPrecision( 5 ); } wxFileName brdName = aPcb->GetFileName(); idfBoard.SetUserScale( scale ); idfBoard.SetBoardThickness( aPcb->GetDesignSettings().GetBoardThickness() * scale ); idfBoard.SetBoardName( TO_UTF8( brdName.GetFullName() ) ); idfBoard.SetBoardVersion( 0 ); idfBoard.SetLibraryVersion( 0 ); std::ostringstream ostr; ostr << "KiCad " << TO_UTF8( GetBuildVersion() ); idfBoard.SetIDFSource( ostr.str() ); try { // set up the board reference point idfBoard.SetUserOffset( -aXRef, aYRef ); // Export the board outline idf_export_outline( aPcb, idfBoard ); // Output the drill holes and footprint (library) data. for( FOOTPRINT* footprint : aPcb->Footprints() ) idf_export_footprint( aPcb, footprint, idfBoard, aIncludeUnspecified, aIncludeDNP ); if( !idfBoard.WriteFile( aFullFileName, idfUnit, false ) ) { wxString msg; msg << _( "IDF Export Failed:\n" ) << From_UTF8( idfBoard.GetError().c_str() ); wxMessageBox( msg ); ok = false; } } catch( const IO_ERROR& ioe ) { wxString msg; msg << _( "IDF Export Failed:\n" ) << ioe.What(); wxMessageBox( msg ); ok = false; } catch( const std::exception& e ) { wxString msg; msg << _( "IDF Export Failed:\n" ) << From_UTF8( e.what() ); wxMessageBox( msg ); ok = false; } return ok; }