/* * This program source code file is part of KiCad, a free EDA CAD application. * * Copyright (C) 2007-2015 SoftPLC Corporation, Dick Hollenbeck * Copyright (C) 2015-2016 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 */ /* This source is a complement to specctra.cpp and implements the export to specctra dsn file format. The specification for the grammar of the specctra dsn file used to develop this code is given here: http://tech.groups.yahoo.com/group/kicad-users/files/ then file "specctra.pdf" Also see the comments at the top of the specctra.cpp file itself. */ #include #include // HISTORY_NUMBER #include // DisplayError() #include // EDA_FileSelector() #include // RotatePoint() #include #include // std::set #include // std::map #include // boost::addressof() #include #include #include #include #include #include #include #include #include #include using namespace DSN; // Add .1 mil to the requested clearances as a safety margin. // There has been disagreement about interpretation of clearance in the past // between KiCad and Freerouter, so keep this safetyMargin until the // disagreement is resolved and stable. Freerouter seems to be moving // (protected) traces upon loading the DSN file, and even though it seems to sometimes // add its own 0.1 to the clearances, I believe this is happening after // the load process (and moving traces) so I am of the opinion this is // still needed. static const double safetyMargin = 0.1; /** * Function close_ness * is a non-exact distance calculator 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( 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 ); } // see wxPcbStruct.h void PCB_EDIT_FRAME::ExportToSpecctra( wxCommandEvent& event ) { wxString fullFileName = GetBoard()->GetFileName(); wxString path; wxString name; wxString ext; wxString dsn_ext = wxT( ".dsn" ); wxString mask = wxT( "*" ) + dsn_ext; wxFileName::SplitPath( fullFileName, &path, &name, &ext ); name += dsn_ext; fullFileName = EDA_FILE_SELECTOR( _( "Specctra DSN file:" ), path, name, // name.ext without path! dsn_ext, mask, this, wxFD_SAVE, false ); if( fullFileName == wxEmptyString ) return; ExportSpecctraFile( fullFileName ); } bool PCB_EDIT_FRAME::ExportSpecctraFile( const wxString& aFullFilename ) { SPECCTRA_DB db; bool ok = true; wxString errorText; BASE_SCREEN* screen = GetScreen(); bool wasModified = screen->IsModify(); db.SetPCB( SPECCTRA_DB::MakePCB() ); LOCALE_IO toggle; // Switch the locale to standard C // DSN Images (=KiCad MODULES and pads) must be presented from the // top view. So we temporarily flip any modules which are on the back // side of the board to the front, and record this in the MODULE's flag field. db.FlipMODULEs( GetBoard() ); try { GetBoard()->SynchronizeNetsAndNetClasses(); db.FromBOARD( GetBoard() ); db.ExportPCB( aFullFilename, true ); // if an exception is thrown by FromBOARD or ExportPCB(), then // ~SPECCTRA_DB() will close the file. } catch( const IO_ERROR& ioe ) { ok = false; // copy the error string to safe place, ioe is in this scope only. errorText = ioe.What(); } // done assuredly, even if an exception was thrown and caught. db.RevertMODULEs( GetBoard() ); // The two calls below to MODULE::Flip(), both set the // modified flag, yet their actions cancel each other out, so it should // be ok to clear the modify flag. if( !wasModified ) screen->ClrModify(); if( ok ) { SetStatusText( wxString( _( "BOARD exported OK." ) ) ); } else { errorText += '\n'; errorText += _( "Unable to export, please fix and try again." ); DisplayError( this, errorText ); } return ok; } namespace DSN { const KICAD_T SPECCTRA_DB::scanPADs[] = { PCB_PAD_T, EOT }; // "specctra reported units" are what we tell the external router that our // exported lengths are in. /** * Function scale * converts a distance from PCBNEW internal units to the reported specctra dsn units * in floating point format. */ static inline double scale( int kicadDist ) { // nanometers to um return kicadDist / ( IU_PER_MM / 1000.0 ); } // / Convert integer internal units to float um static inline double IU2um( int kicadDist ) { return kicadDist * (1000.0 / IU_PER_MM); } static inline double mapX( int x ) { return scale( x ); } static inline double mapY( int y ) { return -scale( y ); // make y negative, since it is increasing going down. } /** * Function mapPt * converts a KiCad point into a DSN file point. Kicad's BOARD coordinates * are in nanometers (called Internal Units or IU)and we are exporting in units * of mils, so we have to scale them. */ static POINT mapPt( const wxPoint& pt ) { POINT ret; ret.x = mapX( pt.x ); ret.y = mapY( pt.y ); ret.FixNegativeZero(); return ret; } /** * Function findPoint * searches for a DRAWSEGMENT with an end point or start point of aPoint, and * if found, removes it from the TYPE_COLLECTOR and returns it, else returns NULL. * @param aPoint The starting or ending point to search for. * @param items The list to remove from. * @param aLimit is the distance from \a aPoint that still constitutes a valid find. * @return DRAWSEGMENT* - The first DRAWSEGMENT that has a start or end point matching * aPoint, otherwise NULL if none. */ static DRAWSEGMENT* findPoint( const wxPoint& aPoint, ::PCB_TYPE_COLLECTOR* items, unsigned aLimit ) { unsigned min_d = INT_MAX; int ndx_min = 0; // find the point closest to aPoint and perhaps exactly matching aPoint. for( int i = 0; i < items->GetCount(); ++i ) { DRAWSEGMENT* graphic = (DRAWSEGMENT*) (*items)[i]; unsigned d; wxASSERT( graphic->Type() == PCB_LINE_T || graphic->Type() == PCB_MODULE_EDGE_T ); switch( graphic->GetShape() ) { case S_ARC: if( aPoint == graphic->GetArcStart() || aPoint == graphic->GetArcEnd() ) { items->Remove( i ); 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() ) { items->Remove( i ); 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 ) { DRAWSEGMENT* graphic = (DRAWSEGMENT*) (*items)[ndx_min]; items->Remove( ndx_min ); return graphic; } #if defined(DEBUG) if( items->GetCount() ) { printf( "Unable to find segment matching point (%.6g;%.6g) (seg count %d)\n", IU2um( aPoint.x )/1000, IU2um( aPoint.y )/1000, items->GetCount()); for( int i = 0; i< items->GetCount(); ++i ) { DRAWSEGMENT* graphic = (DRAWSEGMENT*) (*items)[i]; if( graphic->GetShape() == S_ARC ) printf( "item %d, type=%s, start=%.6g;%.6g end=%.6g;%.6g\n", i + 1, TO_UTF8( BOARD_ITEM::ShowShape( graphic->GetShape() ) ), IU2um( graphic->GetArcStart().x )/1000, IU2um( graphic->GetArcStart().y )/1000, IU2um( graphic->GetArcEnd().x )/1000, IU2um( graphic->GetArcEnd().y )/1000 ); else printf( "item %d, type=%s, start=%.6g;%.6g end=%.6g;%.6g\n", i + 1, TO_UTF8( BOARD_ITEM::ShowShape( graphic->GetShape() ) ), IU2um( graphic->GetStart().x )/1000, IU2um( graphic->GetStart().y )/1000, IU2um( graphic->GetEnd().x )/1000, IU2um( graphic->GetEnd().y )/1000 ); } } #endif return NULL; } /** * Function isRoundKeepout * decides if the pad is a copper-less through hole which needs to be made into * a round keepout. */ static bool isRoundKeepout( D_PAD* aPad ) { if( aPad->GetShape()==PAD_SHAPE_CIRCLE ) { if( aPad->GetDrillSize().x >= aPad->GetSize().x ) return true; if( !( aPad->GetLayerSet() & LSET::AllCuMask() ).any() ) return true; } return false; } /** * Function makePath * creates a PATH element with a single straight line, a pair of vertices. */ static PATH* makePath( const POINT& aStart, const POINT& aEnd, const std::string& aLayerName ) { PATH* path = new PATH( 0, T_path ); path->AppendPoint( aStart ); path->AppendPoint( aEnd ); path->SetLayerId( aLayerName.c_str() ); return path; } PADSTACK* SPECCTRA_DB::makePADSTACK( BOARD* aBoard, D_PAD* aPad ) { char name[256]; // padstack name builder std::string uniqifier; // caller must do these checks before calling here. wxASSERT( !isRoundKeepout( aPad ) ); PADSTACK* padstack = new PADSTACK(); int reportedLayers = 0; // how many in reported padstack const char* layerName[MAX_CU_LAYERS]; uniqifier = '['; static const LSET all_cu = LSET::AllCuMask(); bool onAllCopperLayers = ( (aPad->GetLayerSet() & all_cu) == all_cu ); if( onAllCopperLayers ) uniqifier += 'A'; // A for all layers const int copperCount = aBoard->GetCopperLayerCount(); for( int layer=0; layerIsOnLayer( kilayer ) ) { layerName[reportedLayers++] = layerIds[layer].c_str(); if( !onAllCopperLayers ) { if( layer == 0 ) uniqifier += 'T'; else if( layer == copperCount - 1 ) uniqifier += 'B'; else uniqifier += char('0' + layer); // layer index char } } } uniqifier += ']'; POINT dsnOffset; if( aPad->GetOffset().x || aPad->GetOffset().y ) { char offsetTxt[64]; wxPoint offset( aPad->GetOffset().x, aPad->GetOffset().y ); dsnOffset = mapPt( offset ); // using '(' or ')' would cause padstack name to be quote wrapped, // so use other brackets, and {} locks freerouter. sprintf( offsetTxt, "[%.6g,%.6g]", dsnOffset.x, dsnOffset.y ); uniqifier += offsetTxt; } switch( aPad->GetShape() ) { default: case PAD_SHAPE_CIRCLE: { double diameter = scale( aPad->GetSize().x ); for( int ndx=0; ndxAppend( shape ); CIRCLE* circle = new CIRCLE( shape ); shape->SetShape( circle ); circle->SetLayerId( layerName[ndx] ); circle->SetDiameter( diameter ); circle->SetVertex( dsnOffset ); } snprintf( name, sizeof(name), "Round%sPad_%.6g_um", uniqifier.c_str(), IU2um( aPad->GetSize().x ) ); name[ sizeof(name) - 1 ] = 0; padstack->SetPadstackId( name ); } break; case PAD_SHAPE_RECT: { double dx = scale( aPad->GetSize().x ) / 2.0; double dy = scale( aPad->GetSize().y ) / 2.0; POINT lowerLeft( -dx, -dy ); POINT upperRight( dx, dy ); lowerLeft += dsnOffset; upperRight += dsnOffset; for( int ndx=0; ndxAppend( shape ); RECTANGLE* rect = new RECTANGLE( shape ); shape->SetShape( rect ); rect->SetLayerId( layerName[ndx] ); rect->SetCorners( lowerLeft, upperRight ); } snprintf( name, sizeof(name), "Rect%sPad_%.6gx%.6g_um", uniqifier.c_str(), IU2um( aPad->GetSize().x ), IU2um( aPad->GetSize().y ) ); name[ sizeof(name) - 1 ] = 0; padstack->SetPadstackId( name ); } break; case PAD_SHAPE_OVAL: { double dx = scale( aPad->GetSize().x ) / 2.0; double dy = scale( aPad->GetSize().y ) / 2.0; double dr = dx - dy; double radius; POINT pstart; POINT pstop; if( dr >= 0 ) // oval is horizontal { radius = dy; pstart = POINT( -dr, 0.0 ); pstop = POINT( dr, 0.0 ); } else // oval is vertical { radius = dx; dr = -dr; pstart = POINT( 0.0, -dr ); pstop = POINT( 0.0, dr ); } pstart += dsnOffset; pstop += dsnOffset; for( int ndx=0; ndxAppend( shape ); path = makePath( pstart, pstop, layerName[ndx] ); shape->SetShape( path ); path->aperture_width = 2.0 * radius; } snprintf( name, sizeof(name), "Oval%sPad_%.6gx%.6g_um", uniqifier.c_str(), IU2um( aPad->GetSize().x ), IU2um( aPad->GetSize().y ) ); name[ sizeof(name) - 1 ] = 0; padstack->SetPadstackId( name ); } break; case PAD_SHAPE_TRAPEZOID: { double dx = scale( aPad->GetSize().x ) / 2.0; double dy = scale( aPad->GetSize().y ) / 2.0; double ddx = scale( aPad->GetDelta().x ) / 2.0; double ddy = scale( aPad->GetDelta().y ) / 2.0; // see class_pad_draw_functions.cpp which draws the trapezoid pad POINT lowerLeft( -dx - ddy, -dy - ddx ); POINT upperLeft( -dx + ddy, +dy + ddx ); POINT upperRight( +dx - ddy, +dy - ddx ); POINT lowerRight( +dx + ddy, -dy + ddx ); lowerLeft += dsnOffset; upperLeft += dsnOffset; upperRight += dsnOffset; lowerRight += dsnOffset; for( int ndx=0; ndxAppend( shape ); // a T_polygon exists as a PATH PATH* polygon = new PATH( shape, T_polygon ); shape->SetShape( polygon ); polygon->SetLayerId( layerName[ndx] ); polygon->AppendPoint( lowerLeft ); polygon->AppendPoint( upperLeft ); polygon->AppendPoint( upperRight ); polygon->AppendPoint( lowerRight ); } // this string _must_ be unique for a given physical shape snprintf( name, sizeof(name), "Trapz%sPad_%.6gx%.6g_%c%.6gx%c%.6g_um", uniqifier.c_str(), IU2um( aPad->GetSize().x ), IU2um( aPad->GetSize().y ), aPad->GetDelta().x < 0 ? 'n' : 'p', std::abs( IU2um( aPad->GetDelta().x )), aPad->GetDelta().y < 0 ? 'n' : 'p', std::abs( IU2um( aPad->GetDelta().y ) ) ); name[ sizeof(name)-1 ] = 0; padstack->SetPadstackId( name ); } break; } return padstack; } /// data type used to ensure unique-ness of pin names, holding (wxString and int) typedef std::map PINMAP; IMAGE* SPECCTRA_DB::makeIMAGE( BOARD* aBoard, MODULE* aModule ) { PINMAP pinmap; wxString padName; PCB_TYPE_COLLECTOR moduleItems; // get all the MODULE's pads. moduleItems.Collect( aModule, scanPADs ); IMAGE* image = new IMAGE(0); image->image_id = aModule->GetFPID().Format().c_str(); // from the pads, and make an IMAGE using collated padstacks. for( int p=0; pGetDrillSize().x ); POINT vertex = mapPt( pad->GetPos0() ); int layerCount = aBoard->GetCopperLayerCount(); for( int layer=0; layerkeepouts.push_back( keepout ); CIRCLE* circle = new CIRCLE( keepout ); keepout->SetShape( circle ); circle->SetDiameter( diameter ); circle->SetVertex( vertex ); circle->SetLayerId( layerIds[layer].c_str() ); } } // else if() could there be a square keepout here? else { PADSTACK* padstack = makePADSTACK( aBoard, pad ); PADSTACKSET::iterator iter = padstackset.find( *padstack ); if( iter != padstackset.end() ) { // padstack is a duplicate, delete it and use the original delete padstack; padstack = (PADSTACK*) *iter.base(); // folklore, be careful here } else { padstackset.insert( padstack ); } PIN* pin = new PIN( image ); padName = pad->GetPadName(); pin->pin_id = TO_UTF8( padName ); if( padName!=wxEmptyString && pinmap.find( padName )==pinmap.end() ) { pinmap[ padName ] = 0; } else // pad name is a duplicate within this module { char buf[32]; int duplicates = ++pinmap[ padName ]; sprintf( buf, "@%d", duplicates ); pin->pin_id += buf; // append "@1" or "@2", etc. to pin name } pin->kiNetCode = pad->GetNetCode(); image->pins.push_back( pin ); pin->padstack_id = padstack->padstack_id; double angle = pad->GetOrientationDegrees() - aModule->GetOrientationDegrees(); NORMALIZE_ANGLE_DEGREES_POS( angle ); pin->SetRotation( angle ); wxPoint pos( pad->GetPos0() ); pin->SetVertex( mapPt( pos ) ); } } #if 1 // enable image (outline) scopes. static const KICAD_T scanEDGEs[] = { PCB_MODULE_EDGE_T, EOT }; // get all the MODULE's EDGE_MODULEs and convert those to DSN outlines. moduleItems.Collect( aModule, scanEDGEs ); for( int i = 0; iGetShape() ) { case S_SEGMENT: outline = new SHAPE( image, T_outline ); image->Append( outline ); path = new PATH( outline ); outline->SetShape( path ); path->SetAperture( scale( graphic->GetWidth() ) ); path->SetLayerId( "signal" ); path->AppendPoint( mapPt( graphic->GetStart0() ) ); path->AppendPoint( mapPt( graphic->GetEnd0() ) ); break; case S_CIRCLE: { // this is best done by 4 QARC's but freerouter does not yet support QARCs. // for now, support by using line segments. outline = new SHAPE( image, T_outline ); image->Append( outline ); path = new PATH( outline ); outline->SetShape( path ); path->SetAperture( scale( graphic->GetWidth() ) ); path->SetLayerId( "signal" ); // Do the math using KiCad units, that way we stay out of the // scientific notation range of floating point numbers in the // DSN file. We do not parse scientific notation in our own // lexer/beautifier, and the spec is not clear that this is // required. Fixed point floats are all that should be needed. double radius = GetLineLength( graphic->GetStart(), graphic->GetEnd() ); // better if evenly divisible into 360 const int DEGREE_INTERVAL = 18; // 18 means 20 line segments for( double radians = 0.0; radians < 2 * M_PI; radians += DEGREE_INTERVAL * M_PI / 180.0 ) { wxPoint point( KiROUND( radius * cos( radians ) ), KiROUND( radius * sin( radians ) ) ); point += graphic->m_Start0; // an offset path->AppendPoint( mapPt( point ) ); } } break; case S_RECT: case S_ARC: default: DBG( printf( "makeIMAGE(): unsupported shape %s\n", TO_UTF8( BOARD_ITEM::ShowShape( graphic->GetShape() ) ) ); ) continue; } } #endif return image; } PADSTACK* SPECCTRA_DB::makeVia( int aCopperDiameter, int aDrillDiameter, int aTopLayer, int aBotLayer ) { char name[48]; PADSTACK* padstack = new PADSTACK(); double dsnDiameter = scale( aCopperDiameter ); for( int layer=aTopLayer; layer<=aBotLayer; ++layer ) { SHAPE* shape = new SHAPE( padstack ); padstack->Append( shape ); CIRCLE* circle = new CIRCLE( shape ); shape->SetShape( circle ); circle->SetDiameter( dsnDiameter ); circle->SetLayerId( layerIds[layer].c_str() ); } snprintf( name, sizeof(name), "Via[%d-%d]_%.6g:%.6g_um", aTopLayer, aBotLayer, dsnDiameter, // encode the drill value into the name for later import IU2um( aDrillDiameter ) ); name[ sizeof(name) - 1 ] = 0; padstack->SetPadstackId( name ); return padstack; } PADSTACK* SPECCTRA_DB::makeVia( const ::VIA* aVia ) { LAYER_ID topLayerNum; LAYER_ID botLayerNum; aVia->LayerPair( &topLayerNum, &botLayerNum ); int topLayer = kicadLayer2pcb[topLayerNum]; int botLayer = kicadLayer2pcb[botLayerNum]; if( topLayer > botLayer ) std::swap( topLayer, botLayer ); return makeVia( aVia->GetWidth(), aVia->GetDrillValue(), topLayer, botLayer ); } /** * Function makeCircle * does a line segmented circle into aPath. */ static void makeCircle( PATH* aPath, DRAWSEGMENT* aGraphic ) { // do a circle segmentation const int STEPS = 2 * 36; int radius = aGraphic->GetRadius(); if( radius <= 0 ) // Should not occur, but ... return; wxPoint center = aGraphic->GetCenter(); double angle = 3600.0; wxPoint start = center; start.x += radius; wxPoint nextPt; for( int step = 0; stepAppendPoint( mapPt( nextPt ) ); } } void SPECCTRA_DB::fillBOUNDARY( BOARD* aBoard, BOUNDARY* boundary ) throw( IO_ERROR, boost::bad_pointer ) { PCB_TYPE_COLLECTOR items; unsigned prox; // a proximity BIU metric, not an accurate distance const int STEPS = 36; // for a segmentation of an arc of 360 degrees // Get all the DRAWSEGMENTS and module graphics into 'items', // then keep only those on layer == Edge_Cuts. static const KICAD_T scan_graphics[] = { PCB_LINE_T, PCB_MODULE_EDGE_T, EOT }; items.Collect( aBoard, scan_graphics ); for( int i = 0; iGetLayer() != Edge_Cuts ) items.Remove( i ); else // remove graphics not on Edge_Cuts layer ++i; } if( items.GetCount() ) { PATH* path = new PATH( boundary ); boundary->paths.push_back( path ); path->layer_id = "pcb"; wxPoint prevPt; DRAWSEGMENT* graphic; // Find edge point with minimum x, this should be in the outer polygon // which will define the perimeter Edge.Cuts polygon. wxPoint xmin = wxPoint( INT_MAX, 0 ); int xmini = 0; for( int i = 0; i < items.GetCount(); i++ ) { graphic = (DRAWSEGMENT*) items[i]; switch( graphic->GetShape() ) { 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: // Freerouter does not yet understand arcs, so approximate // an arc with a series of short lines and put those // line segments into the !same! PATH. { wxPoint pstart = graphic->GetArcStart(); wxPoint center = graphic->GetCenter(); double angle = -graphic->GetAngle(); int steps = STEPS * fabs(angle) /3600.0; if( steps == 0 ) steps = 1; 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; default: { wxString error = wxString::Format( _( "Unsupported DRAWSEGMENT type %s" ), GetChars( BOARD_ITEM::ShowShape( graphic->GetShape() ) ) ); THROW_IO_ERROR( error ); } 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 = (DRAWSEGMENT*) items[xmini]; // The first DRAWSEGMENT is in 'graphic', ok to remove it from 'items' items.Remove( xmini ); // Set maximum proximity threshold for point to point nearness metric for // board perimeter only, not interior keepouts yet. prox = Millimeter2iu( 0.01 ); // should be enough to fix rounding issues // is arc start and end point calculations // Output the Edge.Cuts perimeter as circle or polygon. if( graphic->GetShape() == S_CIRCLE ) { makeCircle( path, graphic ); } else { // Polygon start point. Arbitrarily chosen end of the // segment and build the poly from here. wxPoint startPt = wxPoint( graphic->GetEnd() ); prevPt = graphic->GetEnd(); path->AppendPoint( mapPt( prevPt ) ); // Do not append the other end point yet of this 'graphic', 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(); } path->AppendPoint( mapPt( nextPt ) ); prevPt = nextPt; } break; case S_ARC: // Freerouter does not yet understand arcs, 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 steps = STEPS * fabs(angle) /3600.0; if( steps == 0 ) steps = 1; if( !close_enough( prevPt, pstart, prox ) ) { wxASSERT( close_enough( prevPt, graphic->GetArcEnd(), prox ) ); angle = -angle; std::swap( pstart, pend ); } wxPoint nextPt; for( int step = 1; step<=steps; ++step ) { double rotation = ( angle * step ) / steps; nextPt = pstart; RotatePoint( &nextPt, pcenter, rotation ); path->AppendPoint( mapPt( nextPt ) ); } prevPt = nextPt; } break; default: { wxString error = wxString::Format( _( "Unsupported DRAWSEGMENT type %s" ), GetChars( BOARD_ITEM::ShowShape( graphic->GetShape() ) ) ); THROW_IO_ERROR( error ); } break; } // Get next closest segment. graphic = findPoint( prevPt, &items, prox ); // If there are no more close segments, check if the board // outline polygon can be closed. if( !graphic ) { if( close_enough( startPt, prevPt, prox ) ) { // Close the polygon back to start point path->AppendPoint( mapPt( startPt ) ); } else { wxString error = wxString::Format( _( "Unable to find the next boundary segment with an endpoint of (%s mm, %s mm). " "Edge.Cuts perimeter graphics must form a contiguous, closed polygon." ), GetChars( FROM_UTF8( BOARD_ITEM::FormatInternalUnits( prevPt.x ).c_str() ) ), GetChars( FROM_UTF8( BOARD_ITEM::FormatInternalUnits( prevPt.y ).c_str() ) ) ); THROW_IO_ERROR( error ); } break; } } } // Output the interior Edge.Cuts graphics as keepouts, using same nearness // metric as the board edge as otherwise we have trouble completing complex // polygons. prox = Millimeter2iu( 0.05 ); while( items.GetCount() ) { // emit a signal layers keepout for every interior polygon left... KEEPOUT* keepout = new KEEPOUT( NULL, T_keepout ); PATH* poly_ko = new PATH( NULL, T_polygon ); keepout->SetShape( poly_ko ); poly_ko->SetLayerId( "signal" ); pcb->structure->keepouts.push_back( keepout ); graphic = (DRAWSEGMENT*) items[0]; items.Remove( 0 ); if( graphic->GetShape() == S_CIRCLE ) { makeCircle( poly_ko, graphic ); } else { // Polygon start point. Arbitrarily chosen end of the // segment and build the poly from here. wxPoint startPt( graphic->GetEnd() ); prevPt = graphic->GetEnd(); poly_ko->AppendPoint( mapPt( prevPt ) ); // 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; poly_ko->AppendPoint( mapPt( prevPt ) ); } break; case S_ARC: // Freerouter does not yet understand arcs, 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 steps = STEPS * fabs(angle) /3600.0; if( steps == 0 ) steps = 1; if( !close_enough( prevPt, pstart, prox ) ) { wxASSERT( close_enough( prevPt, graphic->GetArcEnd(), prox ) ); angle = -angle; std::swap( pstart, pend ); } wxPoint nextPt; for( int step = 1; step<=steps; ++step ) { double rotation = ( angle * step ) / steps; nextPt = pstart; RotatePoint( &nextPt, pcenter, rotation ); poly_ko->AppendPoint( mapPt( nextPt ) ); } prevPt = nextPt; } break; default: { wxString error = wxString::Format( _( "Unsupported DRAWSEGMENT type %s" ), GetChars( BOARD_ITEM::ShowShape( graphic->GetShape() ) ) ); THROW_IO_ERROR( error ); } break; } // Get next closest segment. graphic = findPoint( prevPt, &items, prox ); // If there are no more close segments, check if polygon // can be closed. if( !graphic ) { if( close_enough( startPt, prevPt, prox ) ) { // Close the polygon back to start point poly_ko->AppendPoint( mapPt( startPt ) ); } else { wxString error = wxString::Format( _( "Unable to find the next keepout segment with an endpoint of (%s mm, %s mm).\n" "Edit Edge.Cuts interior graphics, making them contiguous polygons each." ), GetChars( FROM_UTF8( BOARD_ITEM::FormatInternalUnits( prevPt.x ).c_str() ) ), GetChars( FROM_UTF8( BOARD_ITEM::FormatInternalUnits( prevPt.y ).c_str() ) ) ); THROW_IO_ERROR( error ); } break; } } } } } else { // User has not defined a board perimeter yet... EDA_RECT bbbox = aBoard->ComputeBoundingBox(); RECTANGLE* rect = new RECTANGLE( boundary ); boundary->rectangle = rect; rect->layer_id = "pcb"; // opposite corners wxPoint bottomRight( bbbox.GetRight(), bbbox.GetBottom() ); rect->SetCorners( mapPt( bbbox.GetOrigin() ), mapPt( bottomRight ) ); } } /* This function is not used in SPECCTRA export, * but uses a lot of functions from it * and is used to extract a board outlines (3D view, automatic zones build ...) * makes the board perimeter for the DSN file by filling the BOUNDARY element. * Any closed outline inside the main outline is a hole * All contours should be closed, i.e. valid closed polygon vertices */ bool SPECCTRA_DB::GetBoardPolygonOutlines( BOARD* aBoard, SHAPE_POLY_SET& aOutlines, SHAPE_POLY_SET& aHoles, wxString* aErrorText ) { bool success = true; double specctra2UIfactor = IU_PER_MM / 1000.0; // Specctra unite = micron if( ! pcb ) { pcb = new PCB(); pcb->structure = new STRUCTURE( pcb ); } CPolyPt corner; BOUNDARY* boundary = new BOUNDARY( 0 ); pcb->structure->SetBOUNDARY( boundary ); aOutlines.NewOutline(); try { fillBOUNDARY( aBoard, boundary ); std::vector buffer; boundary->GetCorners( buffer ); for( unsigned ii = 0; ii < buffer.size(); ii+=2 ) { corner.x = buffer[ii] * specctra2UIfactor; corner.y = - buffer[ii+1] * specctra2UIfactor; aOutlines.Append( corner.x, corner.y ); } // Export holes, stored as keepouts polygonal shapes. // by fillBOUNDARY() KEEPOUTS& holes = pcb->structure->keepouts; for( KEEPOUTS::iterator i=holes.begin(); i!=holes.end(); ++i ) { KEEPOUT& keepout = *i; PATH* poly_hole = (PATH*)keepout.shape; POINTS& plist = poly_hole->GetPoints(); aHoles.NewOutline(); for( unsigned ii = 0; ii < plist.size(); ii++ ) { corner.x = plist[ii].x * specctra2UIfactor; corner.y = - plist[ii].y * specctra2UIfactor; aHoles.Append( corner.x, corner.y ); } } } catch( const IO_ERROR& ioe ) { // Creates a valid polygon outline is not possible. // So uses the board edge cuts bounding box to create a // rectangular outline // (when no edge cuts items, fillBOUNDARY build a contour // from global bounding box success = false; if( aErrorText ) *aErrorText = ioe.What(); EDA_RECT bbbox = aBoard->ComputeBoundingBox( true ); // 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(); corner.x = bbbox.GetOrigin().x; corner.y = bbbox.GetOrigin().y; aOutlines.Append( corner.x, corner.y ); corner.x = bbbox.GetOrigin().x; corner.y = bbbox.GetEnd().y; aOutlines.Append( corner.x, corner.y ); corner.x = bbbox.GetEnd().x; corner.y = bbbox.GetEnd().y; aOutlines.Append( corner.x, corner.y ); corner.x = bbbox.GetEnd().x; corner.y = bbbox.GetOrigin().y; aOutlines.Append( corner.x, corner.y ); } return success; } typedef std::set STRINGSET; typedef std::pair STRINGSET_PAIR; void SPECCTRA_DB::FromBOARD( BOARD* aBoard ) throw( IO_ERROR, boost::bad_ptr_container_operation ) { PCB_TYPE_COLLECTOR items; static const KICAD_T scanMODULEs[] = { PCB_MODULE_T, EOT }; // Not all boards are exportable. Check that all reference Ids are unique. // Unless they are unique, we cannot import the session file which comes // back to us later from the router. { items.Collect( aBoard, scanMODULEs ); STRINGSET refs; // holds module reference designators for( int i=0; iGetReference() == wxEmptyString ) { THROW_IO_ERROR( wxString::Format( _( "Component with value of '%s' has empty reference id." ), GetChars( module->GetValue() ) ) ); } // if we cannot insert OK, that means the reference has been seen before. STRINGSET_PAIR refpair = refs.insert( TO_UTF8( module->GetReference() ) ); if( !refpair.second ) // insert failed { THROW_IO_ERROR( wxString::Format( _( "Multiple components have identical reference IDs of '%s'." ), GetChars( module->GetReference() ) ) ); } } } if( !pcb ) pcb = SPECCTRA_DB::MakePCB(); //---------------------------------------------------- { // specctra wants top physical layer first, then going down to the // bottom most physical layer in physical sequence. // @question : why does KiCad not display layers in that order? buildLayerMaps( aBoard ); int layerCount = aBoard->GetCopperLayerCount(); for( int pcbNdx=0; pcbNdxstructure ); pcb->structure->layers.push_back( layer ); layer->name = layerIds[pcbNdx]; DSN_T layerType; switch( aBoard->GetLayerType( pcbLayer2kicad[pcbNdx] ) ) { default: case LT_SIGNAL: layerType = T_signal; break; case LT_POWER: layerType = T_power; break; #if 1 // Freerouter does not support type "mixed", only signal and power. // Remap "mixed" to "signal". case LT_MIXED: layerType = T_signal; break; #else case LT_MIXED: layerType = T_mixed; break; #endif case LT_JUMPER: layerType = T_jumper; break; } layer->layer_type = layerType; layer->properties.push_back( PROPERTY() ); PROPERTY* property = &layer->properties.back(); property->name = "index"; char temp[32]; sprintf( temp, "%d", pcbNdx ); property->value = temp; } } // a space in a quoted token is NOT a terminator, true establishes this. pcb->parser->space_in_quoted_tokens = true; //----- & -------------------- { // tell freerouter to use "tenths of micrometers", // which is 100 nm resolution. Possibly more resolution is possible // in freerouter, but it would need testing. pcb->unit->units = T_um; pcb->resolution->units = T_um; pcb->resolution->value = 10; // tenths of a um // pcb->resolution->value = 1000; // "thousandths of a um" (i.e. "nm") } //----------------------------------------------- { // Because fillBOUNDARY() can throw an exception, we link in an // empty boundary so the BOUNDARY does not get lost in the event of // of an exception. BOUNDARY* boundary = new BOUNDARY( 0 ); pcb->structure->SetBOUNDARY( boundary ); fillBOUNDARY( aBoard, boundary ); } //------------------------------------------------------------- { char rule[80]; NETCLASSPTR defaultClass = aBoard->GetDesignSettings().GetDefault(); int defaultTrackWidth = defaultClass->GetTrackWidth(); int defaultClearance = defaultClass->GetClearance(); double clearance = scale( defaultClearance ); STRINGS& rules = pcb->structure->rules->rules; sprintf( rule, "(width %.6g)", scale( defaultTrackWidth ) ); rules.push_back( rule ); sprintf( rule, "(clearance %.6g)", clearance + safetyMargin ); rules.push_back( rule ); // On a high density board (a board with 4 mil tracks, 4 mil spacing) // a typical solder mask clearance will be 2-3 mils. // This exposes 2 to 3 mils of bare board around each pad, and would // leave only 1 to 2 mils of solder mask between the solder mask's boundary // to the edge of any trace within "clearance" of the pad. So we need at least // 2 mils *extra* clearance for traces which would come near a pad on // a different net. So if the baseline trace to trace clearance was say 4 mils, then // the SMD to trace clearance should be at least 6 mils. double default_smd = clearance + safetyMargin; if( default_smd <= 6.0 ) default_smd = 6.0; sprintf( rule, "(clearance %.6g (type default_smd))", default_smd ); rules.push_back( rule ); /* see: http://www.freerouting.net/usren/viewtopic.php?f=5&t=339#p474 sprintf( rule, "(clearance %.6g (type pad_to_turn_gap))", clearance + safetyMargin ); rules.push_back( rule ); sprintf( rule, "(clearance %.6g (type smd_to_turn_gap))", clearance + safetyMargin ); rules.push_back( rule ); sprintf( rule, "(clearance %.6g (type via_via))", clearance + safetyMargin ); rules.push_back( rule ); sprintf( rule, "(clearance %.6g (type via_smd))", clearance + safetyMargin ); rules.push_back( rule ); sprintf( rule, "(clearance %.6g (type via_pin))", clearance + safetyMargin ); rules.push_back( rule ); sprintf( rule, "(clearance %.6g (type pin_pin))", clearance + safetyMargin ); rules.push_back( rule ); sprintf( rule, "(clearance %.6g (type smd_pin))", clearance + safetyMargin ); rules.push_back( rule ); */ // Pad to pad spacing on a single SMT part can be closer than our // clearance, we don't want freerouter complaining about that, so // output a significantly smaller pad to pad clearance to freerouter. clearance = scale( defaultClearance ) / 4; sprintf( rule, "(clearance %.6g (type smd_smd))", clearance ); rules.push_back( rule ); } //------------------------------------- // Note: only zones are output here, keepout areas be be created later { int netlessZones = 0; static const KICAD_T scanZONEs[] = { PCB_ZONE_AREA_T, EOT }; items.Collect( aBoard, scanZONEs ); for( int i = 0; iGetIsKeepout() ) continue; // Currently, we export only copper layers if( ! IsCopperLayer( item->GetLayer() ) ) continue; COPPER_PLANE* plane = new COPPER_PLANE( pcb->structure ); pcb->structure->planes.push_back( plane ); PATH* mainPolygon = new PATH( plane, T_polygon ); plane->SetShape( mainPolygon ); plane->name = TO_UTF8( item->GetNetname() ); if( plane->name.size() == 0 ) { char name[32]; // This is one of those no connection zones, netcode=0, and it has no name. // Create a unique, bogus netname. NET* no_net = new NET( pcb->network ); sprintf( name, "@:no_net_%d", netlessZones++ ); no_net->net_id = name; // add the bogus net name to network->nets. pcb->network->nets.push_back( no_net ); // use the bogus net name in the netless zone. plane->name = no_net->net_id; } mainPolygon->layer_id = layerIds[ kicadLayer2pcb[ item->GetLayer() ] ]; int count = item->Outline()->m_CornersList.GetCornersCount(); int ndx = 0; // used in 2 for() loops below for( ; ndxOutline()->m_CornersList[ndx].x, item->Outline()->m_CornersList[ndx].y ); mainPolygon->AppendPoint( mapPt(point) ); // this was the end of the main polygon if( item->Outline()->m_CornersList[ndx].end_contour ) break; } WINDOW* window = 0; PATH* cutout = 0; // handle the cutouts for( ++ndx; ndxOutline()->m_CornersList[ndx-1].end_contour ) { window = new WINDOW( plane ); plane->AddWindow( window ); cutout = new PATH( window, T_polygon ); window->SetShape( cutout ); cutout->layer_id = layerIds[ kicadLayer2pcb[ item->GetLayer() ] ]; } wxASSERT( window ); wxASSERT( cutout ); wxPoint point(item->Outline()->m_CornersList[ndx].x, item->Outline()->m_CornersList[ndx].y ); cutout->AppendPoint( mapPt(point) ); } } } //------------------------------------- { static const KICAD_T scanZONEs[] = { PCB_ZONE_AREA_T, EOT }; items.Collect( aBoard, scanZONEs ); for( int i=0; iGetIsKeepout() ) continue; // keepout areas have a type. types are // T_place_keepout, T_via_keepout, T_wire_keepout, // T_bend_keepout, T_elongate_keepout, T_keepout. // Pcbnew knows only T_keepout, T_via_keepout and T_wire_keepout DSN_T keepout_type; if( item->GetDoNotAllowVias() && item->GetDoNotAllowTracks() ) keepout_type = T_keepout; else if( item->GetDoNotAllowVias() ) keepout_type = T_via_keepout; else if( item->GetDoNotAllowTracks() ) keepout_type = T_wire_keepout; else keepout_type = T_keepout; KEEPOUT* keepout = new KEEPOUT( pcb->structure, keepout_type ); pcb->structure->keepouts.push_back( keepout ); PATH* mainPolygon = new PATH( keepout, T_polygon ); keepout->SetShape( mainPolygon ); mainPolygon->layer_id = layerIds[ kicadLayer2pcb[ item->GetLayer() ] ]; int count = item->Outline()->m_CornersList.GetCornersCount(); int ndx = 0; // used in 2 for() loops below for( ; ndxOutline()->m_CornersList[ndx].x, item->Outline()->m_CornersList[ndx].y ); mainPolygon->AppendPoint( mapPt(point) ); // this was the end of the main polygon if( item->Outline()->m_CornersList[ndx].end_contour ) break; } WINDOW* window = 0; PATH* cutout = 0; // handle the cutouts for( ++ndx; ndxOutline()->m_CornersList[ndx-1].end_contour ) { window = new WINDOW( keepout ); keepout->AddWindow( window ); cutout = new PATH( window, T_polygon ); window->SetShape( cutout ); cutout->layer_id = layerIds[ kicadLayer2pcb[ item->GetLayer() ] ]; } wxASSERT( window ); wxASSERT( cutout ); wxPoint point(item->Outline()->m_CornersList[ndx].x, item->Outline()->m_CornersList[ndx].y ); cutout->AppendPoint( mapPt(point) ); } } } //---------------------------- { PIN_REF empty( pcb->network ); std::string componentId; // find the highest numbered netCode within the board. int highestNetCode = aBoard->GetNetCount() - 1; deleteNETs(); // expand the net vector to highestNetCode+1, setting empty to NULL nets.resize( highestNetCode + 1, NULL ); // skip netcode = 0 for( unsigned i = 1; inetwork ); for( unsigned ii = 0; ii < aBoard->GetNetCount(); ii++ ) { NETINFO_ITEM* net = aBoard->FindNet( ii ); int netcode = net->GetNet(); if( netcode > 0 ) nets[ netcode ]->net_id = TO_UTF8( net->GetNetname() ); } items.Collect( aBoard, scanMODULEs ); padstackset.clear(); for( int m = 0; mGetReference() ); // create a net list entry for all the actual pins in the image // for the current module. location of this code is critical // because we fabricated some pin names to ensure unique-ness // of pin names within a module, do not move this code because // the life of this 'IMAGE* image' is not necessarily long. The // exported netlist will have some fabricated pin names in it. // If you don't like fabricated pin names, then make sure all pads // within your MODULEs are uniquely named! for( unsigned p = 0; ppins.size(); ++p ) { PIN* pin = &image->pins[p]; int netcode = pin->kiNetCode; if( netcode > 0 ) { NET* net = nets[netcode]; net->pins.push_back( empty ); PIN_REF& pin_ref = net->pins.back(); pin_ref.component_id = componentId; pin_ref.pin_id = pin->pin_id; } } IMAGE* registered = pcb->library->LookupIMAGE( image ); if( registered != image ) { // If our new 'image' is not a unique IMAGE, delete it. // and use the registered one, known as 'image' after this. delete image; image = registered; } COMPONENT* comp = pcb->placement->LookupCOMPONENT( image->GetImageId() ); PLACE* place = new PLACE( comp ); comp->places.push_back( place ); place->SetRotation( module->GetOrientationDegrees() ); place->SetVertex( mapPt( module->GetPosition() ) ); place->component_id = componentId; place->part_number = TO_UTF8( module->GetValue() ); // module is flipped from bottom side, set side to T_back if( module->GetFlag() ) { double angle = 180.0 - module->GetOrientationDegrees(); NORMALIZE_ANGLE_DEGREES_POS( angle ); place->SetRotation( angle ); place->side = T_back; } } // copy the SPECCTRA_DB::padstackset to the LIBRARY. Since we are // removing, do not increment the iterator for( PADSTACKSET::iterator i = padstackset.begin(); i!=padstackset.end(); i = padstackset.begin() ) { PADSTACKSET::auto_type ps = padstackset.release( i ); PADSTACK* padstack = ps.release(); pcb->library->AddPadstack( padstack ); } // copy our SPECCTRA_DB::nets to the pcb->network for( unsigned n = 1; npins.size() ) { // give ownership to pcb->network pcb->network->nets.push_back( net ); nets[n] = 0; } } } //-----< output vias used in netclasses >----------------------------------- { NETCLASSES& nclasses = aBoard->GetDesignSettings().m_NetClasses; // Assume the netclass vias are all the same kind of thru, blind, or buried vias. // This is in lieu of either having each netclass via have its own layer pair in // the netclass dialog, or such control in the specctra export dialog. // if( aBoard->GetDesignSettings().m_CurrentViaType == VIA_THROUGH ) { m_top_via_layer = 0; // first specctra cu layer is number zero. m_bot_via_layer = aBoard->GetCopperLayerCount()-1; } /* else { // again, should be in the BOARD: topLayer = kicadLayer2pcb[ GetScreen()->m_Route_Layer_TOP ]; botLayer = kicadLayer2pcb[ GetScreen()->m_Route_Layer_BOTTOM ]; } */ // Add the via from the Default netclass first. The via container // in pcb->library preserves the sequence of addition. NETCLASSPTR netclass = nclasses.GetDefault(); PADSTACK* via = makeVia( netclass->GetViaDiameter(), netclass->GetViaDrill(), m_top_via_layer, m_bot_via_layer ); // we AppendVia() this first one, there is no way it can be a duplicate, // the pcb->library via container is empty at this point. After this, // we'll have to use LookupVia(). wxASSERT( pcb->library->vias.size() == 0 ); pcb->library->AppendVia( via ); #if 0 // I've seen no way to make stock vias useable by freerouter. Also the // zero based diameter was leading to duplicates in the LookupVia() function. // User should use netclass based vias when going to freerouter. // Output the stock vias, but preserve uniqueness in the via container by // using LookupVia(). for( unsigned i = 0; i < aBoard->m_ViasDimensionsList.size(); ++i ) { int viaSize = aBoard->m_ViasDimensionsList[i].m_Diameter; int viaDrill = aBoard->m_ViasDimensionsList[i].m_Drill; via = makeVia( viaSize, viaDrill, m_top_via_layer, m_bot_via_layer ); // maybe add 'via' to the library, but only if unique. PADSTACK* registered = pcb->library->LookupVia( via ); if( registered != via ) delete via; } #endif // set the "spare via" index at the start of the // pcb->library->spareViaIndex = pcb->library->vias.size(); // output the non-Default netclass vias for( NETCLASSES::iterator nc = nclasses.begin(); nc != nclasses.end(); ++nc ) { netclass = nc->second; via = makeVia( netclass->GetViaDiameter(), netclass->GetViaDrill(), m_top_via_layer, m_bot_via_layer ); // maybe add 'via' to the library, but only if unique. PADSTACK* registered = pcb->library->LookupVia( via ); if( registered != via ) delete via; } } #if 1 // do existing wires and vias //---------------------------------------- { // export all of them for now, later we'll decide what controls we need // on this. static const KICAD_T scanTRACKs[] = { PCB_TRACE_T, EOT }; items.Collect( aBoard, scanTRACKs ); std::string netname; WIRING* wiring = pcb->wiring; PATH* path = 0; int old_netcode = -1; int old_width = -1; LAYER_NUM old_layer = UNDEFINED_LAYER; for( int i=0; iGetNetCode(); if( netcode == 0 ) continue; if( old_netcode != netcode || old_width != track->GetWidth() || old_layer != track->GetLayer() || (path && path->points.back() != mapPt(track->GetStart()) ) ) { old_width = track->GetWidth(); old_layer = track->GetLayer(); if( old_netcode != netcode ) { old_netcode = netcode; NETINFO_ITEM* net = aBoard->FindNet( netcode ); wxASSERT( net ); netname = TO_UTF8( net->GetNetname() ); } WIRE* wire = new WIRE( wiring ); wiring->wires.push_back( wire ); wire->net_id = netname; wire->wire_type = T_protect; // @todo, this should be configurable LAYER_NUM kiLayer = track->GetLayer(); int pcbLayer = kicadLayer2pcb[kiLayer]; path = new PATH( wire ); wire->SetShape( path ); path->layer_id = layerIds[pcbLayer]; path->aperture_width = scale( old_width ); path->AppendPoint( mapPt( track->GetStart() ) ); } if( path ) // Should not occur path->AppendPoint( mapPt( track->GetEnd() ) ); } } //---------------------- { // Export all vias, once per unique size and drill diameter combo. static const KICAD_T scanVIAs[] = { PCB_VIA_T, EOT }; items.Collect( aBoard, scanVIAs ); for( int i = 0; iType() == PCB_VIA_T ); int netcode = via->GetNetCode(); if( netcode == 0 ) continue; PADSTACK* padstack = makeVia( via ); PADSTACK* registered = pcb->library->LookupVia( padstack ); // if the one looked up is not our padstack, then delete our padstack // since it was a duplicate of one already registered. if( padstack != registered ) { delete padstack; } WIRE_VIA* dsnVia = new WIRE_VIA( pcb->wiring ); pcb->wiring->wire_vias.push_back( dsnVia ); dsnVia->padstack_id = registered->padstack_id; dsnVia->vertexes.push_back( mapPt( via->GetPosition() ) ); NETINFO_ITEM* net = aBoard->FindNet( netcode ); wxASSERT( net ); dsnVia->net_id = TO_UTF8( net->GetNetname() ); dsnVia->via_type = T_protect; // @todo, this should be configurable } } #endif // do existing wires and vias //------------------------------------------------------ { // The pcb->library will output which is a combined // list of part padstacks and via padstacks. specctra dsn uses the // to say which of those padstacks are vias. // Output the vias in the padstack list here, by name only. This must // be done after exporting existing vias as WIRE_VIAs. VIA* vias = pcb->structure->via; for( unsigned viaNdx = 0; viaNdx < pcb->library->vias.size(); ++viaNdx ) { vias->AppendVia( pcb->library->vias[viaNdx].padstack_id.c_str() ); } } //--------------------------------------------------------- NETCLASSES& nclasses = aBoard->GetDesignSettings().m_NetClasses; exportNETCLASS( nclasses.GetDefault(), aBoard ); for( NETCLASSES::iterator nc = nclasses.begin(); nc != nclasses.end(); ++nc ) { NETCLASSPTR netclass = nc->second; exportNETCLASS( netclass, aBoard ); } } void SPECCTRA_DB::exportNETCLASS( NETCLASSPTR aNetClass, BOARD* aBoard ) { /* From page 11 of specctra spec: * * Routing and Placement Rule Hierarchies * * Routing and placement rules can be defined at multiple levels of design * specification. When a routing or placement rule is defined for an object at * multiple levels, a predefined routing or placement precedence order * automatically determines which rule to apply to the object. The routing rule * precedence order is * * pcb < layer < class < class layer < group_set < group_set layer < net < * net layer < group < group layer < fromto < fromto layer < class_class < * class_class layer < padstack < region < class region < net region < * class_class region * * A pcb rule (global rule for the PCB design) has the lowest precedence in the * hierarchy. A class-to-class region rule has the highest precedence. Rules * set at one level of the hierarchy override conflicting rules set at lower * levels. The placement rule precedence order is * * pcb < image_set < image < component < super cluster < room < * room_image_set < family_family < image_image * * A pcb rule (global rule for the PCB design) has the lowest precedence in the * hierarchy. An image-to-image rule has the highest precedence. Rules set at * one level of the hierarchy override conflicting rules set at lower levels. */ char text[256]; CLASS* clazz = new CLASS( pcb->network ); pcb->network->classes.push_back( clazz ); // freerouter creates a class named 'default' anyway, and if we // try and use that, we end up with two 'default' via rules so use // something else as the name of our default class. clazz->class_id = TO_UTF8( aNetClass->GetName() ); for( NETCLASS::iterator net = aNetClass->begin(); net != aNetClass->end(); ++net ) clazz->net_ids.push_back( TO_UTF8( *net ) ); clazz->rules = new RULE( clazz, T_rule ); // output the track width. int trackWidth = aNetClass->GetTrackWidth(); sprintf( text, "(width %.6g)", scale( trackWidth ) ); clazz->rules->rules.push_back( text ); // output the clearance. int clearance = aNetClass->GetClearance(); sprintf( text, "(clearance %.6g)", scale( clearance ) + safetyMargin ); clazz->rules->rules.push_back( text ); if( aNetClass->GetName() == NETCLASS::Default ) { clazz->class_id = "kicad_default"; } // the easiest way to get the via name is to create a via (which generates // the name internal to the PADSTACK), and then grab the name and then // delete the via. There are not that many netclasses so // this should never become a performance issue. PADSTACK* via = makeVia( aNetClass->GetViaDiameter(), aNetClass->GetViaDrill(), m_top_via_layer, m_bot_via_layer ); snprintf( text, sizeof(text), "(use_via %s)", via->GetPadstackId().c_str() ); clazz->circuit.push_back( text ); delete via; } void SPECCTRA_DB::FlipMODULEs( BOARD* aBoard ) { for( MODULE* module = aBoard->m_Modules; module; module = module->Next() ) { module->SetFlag( 0 ); if( module->GetLayer() == B_Cu ) { module->Flip( module->GetPosition() ); module->SetFlag( 1 ); } } modulesAreFlipped = true; } void SPECCTRA_DB::RevertMODULEs( BOARD* aBoard ) { if( !modulesAreFlipped ) return; // DSN Images (=KiCad MODULES and pads) must be presented from the // top view. Restore those that were flipped. for( MODULE* module = aBoard->m_Modules; module; module = module->Next() ) { if( module->GetFlag() ) { module->Flip( module->GetPosition() ); module->SetFlag( 0 ); } } modulesAreFlipped = false; } } // namespace DSN