/* * This program source code file is part of KiCad, a free EDA CAD application. * * Copyright (C) 2012 SoftPLC Corporation, Dick Hollenbeck * Copyright (C) 2012-2015 KiCad Developers, see change_log.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 */ /* Pcbnew PLUGIN for Eagle 6.x XML *.brd and footprint format. XML parsing and converting: Getting line numbers and byte offsets from the source XML file is not possible using currently available XML libraries within KiCad project: wxXmlDocument and boost::property_tree. property_tree will give line numbers but no byte offsets, and only during document loading. This means that if we have a problem after the document is successfully loaded, there is no way to correlate back to line number and byte offset of the problem. So a different approach is taken, one which relies on the XML elements themselves using an XPATH type of reporting mechanism. The path to the problem is reported in the error messages. This means keeping track of that path as we traverse the XML document for the sole purpose of accurate error reporting. User can load the source XML file into firefox or other xml browser and follow our error message. Load() TODO's *) verify zone fill clearances are correct */ #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include using namespace boost::property_tree; using namespace std; typedef EAGLE_PLUGIN::BIU BIU; typedef PTREE::const_assoc_iterator CA_ITER; typedef PTREE::const_iterator CITER; typedef std::pair CA_ITER_RANGE; typedef MODULE_MAP::iterator MODULE_ITER; typedef MODULE_MAP::const_iterator MODULE_CITER; typedef boost::optional opt_string; typedef boost::optional opt_int; typedef boost::optional opt_double; typedef boost::optional opt_bool; /// segment (element) of our XPATH into the Eagle XML document tree in PTREE form. struct TRIPLET { const char* element; const char* attribute; const char* value; TRIPLET( const char* aElement, const char* aAttribute = "", const char* aValue = "" ) : element( aElement ), attribute( aAttribute ), value( aValue ) {} }; /** * Class XPATH * keeps track of what we are working on within a PTREE. * Then if an exception is thrown, the place within the tree that gave us * grief can be reported almost accurately. To minimally impact * speed, merely assign const char* pointers during the tree walking * expedition. The const char* pointers must be to C strings residing either in * the data or code segment (i.e. "compiled in") or within the XML document, but * not on the stack, since the stack is unwound during the throwing of the * exception. The XML document will not immediately vanish since we capture * the xpath (using function Contents()) before the XML document tree (PTREE) * is destroyed. */ class XPATH { std::vector p; public: void push( const char* aPathSegment, const char* aAttribute="" ) { p.push_back( TRIPLET( aPathSegment, aAttribute ) ); } void clear() { p.clear(); } void pop() { p.pop_back(); } /// modify the last path node's value void Value( const char* aValue ) { p.back().value = aValue; } /// modify the last path node's attribute void Attribute( const char* aAttribute ) { p.back().attribute = aAttribute; } /// return the contents of the XPATH as a single string string Contents() { typedef std::vector::const_iterator CITER; string ret; for( CITER it = p.begin(); it != p.end(); ++it ) { if( it != p.begin() ) ret += '.'; ret += it->element; if( it->attribute[0] && it->value[0] ) { ret += '['; ret += it->attribute; ret += '='; ret += it->value; ret += ']'; } } return ret; } }; /** * Function parseOptionalBool * returns an opt_bool and sets it true or false according to the presence * and value of an attribute within the CPTREE element. */ static opt_bool parseOptionalBool( CPTREE& attribs, const char* aName ) { opt_bool ret; opt_string stemp = attribs.get_optional( aName ); if( stemp ) ret = !stemp->compare( "yes" ); return ret; } // All of the 'E'STRUCTS below merely hold Eagle XML information verbatim, in binary. // For maintenance and troubleshooting purposes, it was thought that we'd need to // separate the conversion process into distinct steps. There is no intent to have KiCad // forms of information in these 'E'STRUCTS. They are only binary forms // of the Eagle information in the corresponding Eagle XML nodes. /// Eagle rotation struct EROT { bool mirror; bool spin; double degrees; EROT() : mirror( false ), spin( false ), degrees( 0 ) {} EROT( double aDegrees ) : mirror( false ), spin( false ), degrees( aDegrees ) {} }; typedef boost::optional opt_erot; /// parse an Eagle XML "rot" field. Unfortunately the DTD seems not to explain /// this format very well. [S][M]R. Examples: "R90", "MR180", "SR180" static EROT erot( const string& aRot ) { EROT rot; rot.spin = aRot.find( 'S' ) != aRot.npos; rot.mirror = aRot.find( 'M' ) != aRot.npos; rot.degrees = strtod( aRot.c_str() + 1 // skip leading 'R' + int( rot.spin ) // skip optional leading 'S' + int( rot.mirror ), // skip optional leading 'M' NULL ); return rot; } /// Eagle "rot" fields are optional, handle that by returning opt_erot. static opt_erot parseOptionalEROT( CPTREE& attribs ) { opt_erot ret; opt_string stemp = attribs.get_optional( "rot" ); if( stemp ) ret = erot( *stemp ); return ret; } /// Eagle wire struct EWIRE { double x1; double y1; double x2; double y2; double width; LAYER_NUM layer; // for style: (continuous | longdash | shortdash | dashdot) enum { CONTINUOUS, LONGDASH, SHORTDASH, DASHDOT, }; opt_int style; opt_double curve; ///< range is -359.9..359.9 // for cap: (flat | round) enum { FLAT, ROUND, }; opt_int cap; EWIRE( CPTREE& aWire ); }; /** * Constructor EWIRE * converts a "wire"'s xml attributes ( <wire> ) * to binary without additional conversion. * This result is an EWIRE with the <wire> textual data merely converted to binary. */ EWIRE::EWIRE( CPTREE& aWire ) { CPTREE& attribs = aWire.get_child( "" ); /* */ x1 = attribs.get( "x1" ); y1 = attribs.get( "y1" ); x2 = attribs.get( "x2" ); y2 = attribs.get( "y2" ); width = attribs.get( "width" ); layer = attribs.get( "layer" ); curve = attribs.get_optional( "curve" ); opt_string s = attribs.get_optional( "style" ); if( s ) { if( !s->compare( "continuous" ) ) style = EWIRE::CONTINUOUS; else if( !s->compare( "longdash" ) ) style = EWIRE::LONGDASH; else if( !s->compare( "shortdash" ) ) style = EWIRE::SHORTDASH; else if( !s->compare( "dashdot" ) ) style = EWIRE::DASHDOT; } s = attribs.get_optional( "cap" ); if( s ) { if( !s->compare( "round" ) ) cap = EWIRE::ROUND; else if( !s->compare( "flat" ) ) cap = EWIRE::FLAT; } // ignoring extent } /// Eagle via struct EVIA { double x; double y; int layer_front_most; /// < extent int layer_back_most; /// < inclusive double drill; opt_double diam; opt_string shape; EVIA( CPTREE& aVia ); }; EVIA::EVIA( CPTREE& aVia ) { CPTREE& attribs = aVia.get_child( "" ); /* */ x = attribs.get( "x" ); y = attribs.get( "y" ); string ext = attribs.get( "extent" ); sscanf( ext.c_str(), "%d-%d", &layer_front_most, &layer_back_most ); drill = attribs.get( "drill" ); diam = attribs.get_optional( "diameter" ); shape = attribs.get_optional( "shape" ); } /// Eagle circle struct ECIRCLE { double x; double y; double radius; double width; LAYER_NUM layer; ECIRCLE( CPTREE& aCircle ); }; ECIRCLE::ECIRCLE( CPTREE& aCircle ) { CPTREE& attribs = aCircle.get_child( "" ); /* */ x = attribs.get( "x" ); y = attribs.get( "y" ); radius = attribs.get( "radius" ); width = attribs.get( "width" ); layer = attribs.get( "layer" ); } /// Eagle XML rectangle in binary struct ERECT { double x1; double y1; double x2; double y2; int layer; opt_erot rot; ERECT( CPTREE& aRect ); }; ERECT::ERECT( CPTREE& aRect ) { CPTREE& attribs = aRect.get_child( "" ); /* */ x1 = attribs.get( "x1" ); y1 = attribs.get( "y1" ); x2 = attribs.get( "x2" ); y2 = attribs.get( "y2" ); layer = attribs.get( "layer" ); rot = parseOptionalEROT( attribs ); } /// Eagle "attribute" XML element, no foolin'. struct EATTR { string name; opt_string value; opt_double x; opt_double y; opt_double size; opt_int layer; opt_double ratio; opt_erot rot; enum { // for 'display' Off, VALUE, NAME, BOTH, }; opt_int display; EATTR( CPTREE& aTree ); EATTR() {} }; /** * Constructor EATTR * parses an Eagle "attribute" XML element. Note that an attribute element * is different than an XML element attribute. The attribute element is a * full XML node in and of itself, and has attributes of its own. Blame Eagle. */ EATTR::EATTR( CPTREE& aAttribute ) { CPTREE& attribs = aAttribute.get_child( "" ); /* or context -- constant %Bool; "no" -- only in context -- > */ name = attribs.get( "name" ); // #REQUIRED value = attribs.get_optional( "value" ); x = attribs.get_optional( "x" ); y = attribs.get_optional( "y" ); size = attribs.get_optional( "size" ); // KiCad cannot currently put a TEXTE_MODULE on a different layer than the MODULE // Eagle can it seems. layer = attribs.get_optional( "layer" ); ratio = attribs.get_optional( "ratio" ); rot = parseOptionalEROT( attribs ); opt_string stemp = attribs.get_optional( "display" ); if( stemp ) { // (off | value | name | both) if( !stemp->compare( "off" ) ) display = EATTR::Off; else if( !stemp->compare( "value" ) ) display = EATTR::VALUE; else if( !stemp->compare( "name" ) ) display = EATTR::NAME; else if( !stemp->compare( "both" ) ) display = EATTR::BOTH; } } /// Eagle text element struct ETEXT { string text; double x; double y; double size; int layer; opt_string font; opt_double ratio; opt_erot rot; enum { // for align CENTER, CENTER_LEFT, TOP_CENTER, TOP_LEFT, TOP_RIGHT, // opposites are -1 x above, used by code tricks in here CENTER_RIGHT = -CENTER_LEFT, BOTTOM_CENTER = -TOP_CENTER, BOTTOM_LEFT = -TOP_RIGHT, BOTTOM_RIGHT = -TOP_LEFT, }; opt_int align; ETEXT( CPTREE& aText ); }; ETEXT::ETEXT( CPTREE& aText ) { CPTREE& attribs = aText.get_child( "" ); /* */ text = aText.data(); x = attribs.get( "x" ); y = attribs.get( "y" ); size = attribs.get( "size" ); layer = attribs.get( "layer" ); font = attribs.get_optional( "font" ); ratio = attribs.get_optional( "ratio" ); rot = parseOptionalEROT( attribs ); opt_string stemp = attribs.get_optional( "align" ); if( stemp ) { // (bottom-left | bottom-center | bottom-right | center-left | // center | center-right | top-left | top-center | top-right) if( !stemp->compare( "center" ) ) align = ETEXT::CENTER; else if( !stemp->compare( "center-right" ) ) align = ETEXT::CENTER_RIGHT; else if( !stemp->compare( "top-left" ) ) align = ETEXT::TOP_LEFT; else if( !stemp->compare( "top-center" ) ) align = ETEXT::TOP_CENTER; else if( !stemp->compare( "top-right" ) ) align = ETEXT::TOP_RIGHT; else if( !stemp->compare( "bottom-left" ) ) align = ETEXT::BOTTOM_LEFT; else if( !stemp->compare( "bottom-center" ) ) align = ETEXT::BOTTOM_CENTER; else if( !stemp->compare( "bottom-right" ) ) align = ETEXT::BOTTOM_RIGHT; else if( !stemp->compare( "center-left" ) ) align = ETEXT::CENTER_LEFT; } } /// Eagle thru hol pad struct EPAD { string name; double x; double y; double drill; opt_double diameter; // for shape: (square | round | octagon | long | offset) enum { SQUARE, ROUND, OCTAGON, LONG, OFFSET, }; opt_int shape; opt_erot rot; opt_bool stop; opt_bool thermals; opt_bool first; EPAD( CPTREE& aPad ); }; EPAD::EPAD( CPTREE& aPad ) { CPTREE& attribs = aPad.get_child( "" ); /* */ // #REQUIRED says DTD, throw exception if not found name = attribs.get( "name" ); x = attribs.get( "x" ); y = attribs.get( "y" ); drill = attribs.get( "drill" ); diameter = attribs.get_optional( "diameter" ); opt_string s = attribs.get_optional( "shape" ); if( s ) { // (square | round | octagon | long | offset) if( !s->compare( "square" ) ) shape = EPAD::SQUARE; else if( !s->compare( "round" ) ) shape = EPAD::ROUND; else if( !s->compare( "octagon" ) ) shape = EPAD::OCTAGON; else if( !s->compare( "long" ) ) shape = EPAD::LONG; else if( !s->compare( "offset" ) ) shape = EPAD::OFFSET; } rot = parseOptionalEROT( attribs ); stop = parseOptionalBool( attribs, "stop" ); thermals = parseOptionalBool( attribs, "thermals" ); first = parseOptionalBool( attribs, "first" ); } /// Eagle SMD pad struct ESMD { string name; double x; double y; double dx; double dy; int layer; opt_int roundness; opt_erot rot; opt_bool stop; opt_bool thermals; opt_bool cream; ESMD( CPTREE& aSMD ); }; ESMD::ESMD( CPTREE& aSMD ) { CPTREE& attribs = aSMD.get_child( "" ); /* */ // DTD #REQUIRED, throw exception if not found name = attribs.get( "name" ); x = attribs.get( "x" ); y = attribs.get( "y" ); dx = attribs.get( "dx" ); dy = attribs.get( "dy" ); layer = attribs.get( "layer" ); rot = parseOptionalEROT( attribs ); roundness = attribs.get_optional( "roundness" ); thermals = parseOptionalBool( attribs, "thermals" ); stop = parseOptionalBool( attribs, "stop" ); thermals = parseOptionalBool( attribs, "thermals" ); cream = parseOptionalBool( attribs, "cream" ); } struct EVERTEX { double x; double y; EVERTEX( CPTREE& aVertex ); }; EVERTEX::EVERTEX( CPTREE& aVertex ) { CPTREE& attribs = aVertex.get_child( "" ); /* */ x = attribs.get( "x" ); y = attribs.get( "y" ); } /// Eagle polygon, without vertices which are parsed as needed struct EPOLYGON { double width; int layer; opt_double spacing; // KiCad priority is opposite of Eagle rank, that is: // - Eagle Low rank drawn first // - KiCad high priority drawn first // So since Eagle has an upper limit we define this, used for the cases // where no rank is specified. static const int max_priority = 6; enum { // for pour SOLID, HATCH, CUTOUT, }; opt_int pour; opt_double isolate; opt_bool orphans; opt_bool thermals; opt_int rank; EPOLYGON( CPTREE& aPolygon ); }; EPOLYGON::EPOLYGON( CPTREE& aPolygon ) { CPTREE& attribs = aPolygon.get_child( "" ); /* or context -- orphans %Bool; "no" -- only in context -- thermals %Bool; "yes" -- only in context -- rank %Int; "0" -- 1..6 in context, 0 or 7 in context -- > */ width = attribs.get( "width" ); layer = attribs.get( "layer" ); spacing = attribs.get_optional( "spacing" ); isolate = attribs.get_optional( "isolate" ); opt_string s = attribs.get_optional( "pour" ); if( s ) { // (solid | hatch | cutout) if( !s->compare( "hatch" ) ) pour = EPOLYGON::HATCH; else if( !s->compare( "cutout" ) ) pour = EPOLYGON::CUTOUT; else pour = EPOLYGON::SOLID; } orphans = parseOptionalBool( attribs, "orphans" ); thermals = parseOptionalBool( attribs, "thermals" ); rank = attribs.get_optional( "rank" ); } /// Eagle hole element struct EHOLE { double x; double y; double drill; EHOLE( CPTREE& aHole ); }; EHOLE::EHOLE( CPTREE& aHole ) { CPTREE& attribs = aHole.get_child( "" ); /* */ // #REQUIRED: x = attribs.get( "x" ); y = attribs.get( "y" ); drill = attribs.get( "drill" ); } /// Eagle element element struct EELEMENT { string name; string library; string package; string value; double x; double y; opt_bool locked; // opt_bool smashed; opt_erot rot; EELEMENT( CPTREE& aElement ); }; EELEMENT::EELEMENT( CPTREE& aElement ) { CPTREE& attribs = aElement.get_child( "" ); /* */ // #REQUIRED name = attribs.get( "name" ); library = attribs.get( "library" ); value = attribs.get( "value" ); package = attribs.get( "package" ); ReplaceIllegalFileNameChars( &package ); x = attribs.get( "x" ); y = attribs.get( "y" ); // optional locked = parseOptionalBool( attribs, "locked" ); // smashed = pasreOptionalBool( attribs, "smashed" ); rot = parseOptionalEROT( attribs ); } struct ELAYER { int number; string name; int color; int fill; opt_bool visible; opt_bool active; ELAYER( CPTREE& aLayer ); }; ELAYER::ELAYER( CPTREE& aLayer ) { CPTREE& attribs = aLayer.get_child( "" ); /* */ number = attribs.get( "number" ); name = attribs.get( "name" ); color = attribs.get( "color" ); fill = 1; // Temporary value. visible = parseOptionalBool( attribs, "visible" ); active = parseOptionalBool( attribs, "active" ); } /// Parse an eagle distance which is either mm, or mils if there is "mil" suffix. /// Return is in BIU. static double parseEagle( const string& aDistance ) { double ret = strtod( aDistance.c_str(), NULL ); if( aDistance.npos != aDistance.find( "mil" ) ) ret = IU_PER_MILS * ret; else ret = IU_PER_MM * ret; return ret; } /// subset of eagle.drawing.board.designrules in the XML document struct ERULES { int psElongationLong; ///< percent over 100%. 0-> not elongated, 100->twice as wide as is tall ///< Goes into making a scaling factor for "long" pads. int psElongationOffset; ///< the offset of the hole within the "long" pad. double rvPadTop; ///< top pad size as percent of drill size // double rvPadBottom; ///< bottom pad size as percent of drill size double rlMinPadTop; ///< minimum copper annulus on through hole pads double rlMaxPadTop; ///< maximum copper annulus on through hole pads double rvViaOuter; ///< copper annulus is this percent of via hole double rlMinViaOuter; ///< minimum copper annulus on via double rlMaxViaOuter; ///< maximum copper annulus on via double mdWireWire; ///< wire to wire spacing I presume. ERULES() : psElongationLong ( 100 ), psElongationOffset ( 0 ), rvPadTop ( 0.25 ), // rvPadBottom ( 0.25 ), rlMinPadTop ( Mils2iu( 10 ) ), rlMaxPadTop ( Mils2iu( 20 ) ), rvViaOuter ( 0.25 ), rlMinViaOuter ( Mils2iu( 10 ) ), rlMaxViaOuter ( Mils2iu( 20 ) ), mdWireWire ( 0 ) {} void parse( CPTREE& aRules ); }; void ERULES::parse( CPTREE& aRules ) { for( CITER it = aRules.begin(); it != aRules.end(); ++it ) { if( it->first != "param" ) continue; CPTREE& attribs = it->second.get_child( "" ); const string& name = attribs.get( "name" ); if( name == "psElongationLong" ) psElongationLong = attribs.get( "value" ); else if( name == "psElongationOffset" ) psElongationOffset = attribs.get( "value" ); else if( name == "rvPadTop" ) rvPadTop = attribs.get( "value" ); else if( name == "rlMinPadTop" ) rlMinPadTop = parseEagle( attribs.get( "value" ) ); else if( name == "rlMaxPadTop" ) rlMaxPadTop = parseEagle( attribs.get( "value" ) ); else if( name == "rvViaOuter" ) rvViaOuter = attribs.get( "value" ); else if( name == "rlMinViaOuter" ) rlMinViaOuter = parseEagle( attribs.get( "value" ) ); else if( name == "rlMaxViaOuter" ) rlMaxViaOuter = parseEagle( attribs.get( "value" ) ); else if( name == "mdWireWire" ) mdWireWire = parseEagle( attribs.get( "value" ) ); } } /// Assemble a two part key as a simple concatonation of aFirst and aSecond parts, /// using a separator. static inline string makeKey( const string& aFirst, const string& aSecond ) { string key = aFirst + '\x02' + aSecond; return key; } /// Make a unique time stamp static inline unsigned long timeStamp( CPTREE& aTree ) { // in this case from a unique tree memory location return (unsigned long)(void*) &aTree; } /// Convert an Eagle curve end to a KiCad center for S_ARC wxPoint kicad_arc_center( wxPoint start, wxPoint end, double angle ) { // Eagle give us start and end. // S_ARC wants start to give the center, and end to give the start. double dx = end.x - start.x, dy = end.y - start.y; wxPoint mid = (start + end) / 2; double dlen = sqrt( dx*dx + dy*dy ); double dist = dlen / ( 2 * tan( DEG2RAD( angle ) / 2 ) ); wxPoint center( mid.x + dist * ( dy / dlen ), mid.y - dist * ( dx / dlen ) ); return center; } EAGLE_PLUGIN::EAGLE_PLUGIN() : m_rules( new ERULES() ), m_xpath( new XPATH() ), m_mod_time( wxDateTime::Now() ) { init( NULL ); clear_cu_map(); } EAGLE_PLUGIN::~EAGLE_PLUGIN() { delete m_rules; delete m_xpath; } const wxString EAGLE_PLUGIN::PluginName() const { return wxT( "Eagle" ); } const wxString EAGLE_PLUGIN::GetFileExtension() const { return wxT( "brd" ); } int inline EAGLE_PLUGIN::kicad( double d ) const { return KiROUND( biu_per_mm * d ); } wxSize inline EAGLE_PLUGIN::kicad_fontz( double d ) const { // texts seem to better match eagle when scaled down by 0.95 int kz = kicad( d ) * 95 / 100; return wxSize( kz, kz ); } BOARD* EAGLE_PLUGIN::Load( const wxString& aFileName, BOARD* aAppendToMe, const PROPERTIES* aProperties ) { LOCALE_IO toggle; // toggles on, then off, the C locale. PTREE doc; init( aProperties ); m_board = aAppendToMe ? aAppendToMe : new BOARD(); // Give the filename to the board if it's new if( !aAppendToMe ) m_board->SetFileName( aFileName ); // delete on exception, iff I own m_board, according to aAppendToMe auto_ptr deleter( aAppendToMe ? NULL : m_board ); try { // 8 bit "filename" should be encoded according to disk filename encoding, // (maybe this is current locale, maybe not, its a filesystem issue), // and is not necessarily utf8. string filename = (const char*) aFileName.char_str( wxConvFile ); read_xml( filename, doc, xml_parser::no_comments ); m_min_trace = INT_MAX; m_min_via = INT_MAX; m_min_via_hole = INT_MAX; loadAllSections( doc ); BOARD_DESIGN_SETTINGS& designSettings = m_board->GetDesignSettings(); if( m_min_trace < designSettings.m_TrackMinWidth ) designSettings.m_TrackMinWidth = m_min_trace; if( m_min_via < designSettings.m_ViasMinSize ) designSettings.m_ViasMinSize = m_min_via; if( m_min_via_hole < designSettings.m_ViasMinDrill ) designSettings.m_ViasMinDrill = m_min_via_hole; if( m_rules->mdWireWire ) { NETCLASSPTR defaultNetclass = designSettings.GetDefault(); int clearance = KiROUND( m_rules->mdWireWire ); if( clearance < defaultNetclass->GetClearance() ) defaultNetclass->SetClearance( clearance ); } // should be empty, else missing m_xpath->pop() wxASSERT( m_xpath->Contents().size() == 0 ); } catch( file_parser_error fpe ) { // for xml_parser_error, what() has the line number in it, // but no byte offset. That should be an adequate error message. THROW_IO_ERROR( fpe.what() ); } // Class ptree_error is a base class for xml_parser_error & file_parser_error, // so one catch should be OK for all errors. catch( ptree_error pte ) { string errmsg = pte.what(); errmsg += " @\n"; errmsg += m_xpath->Contents(); THROW_IO_ERROR( errmsg ); } // IO_ERROR exceptions are left uncaught, they pass upwards from here. // Ensure the copper layers count is a multiple of 2 // Pcbnew does not like boards with odd layers count // (these boards cannot exist. they actually have a even layers count) int lyrcnt = m_board->GetCopperLayerCount(); if( (lyrcnt % 2) != 0 ) { lyrcnt++; m_board->SetCopperLayerCount( lyrcnt ); } centerBoard(); deleter.release(); return m_board; } void EAGLE_PLUGIN::init( const PROPERTIES* aProperties ) { m_hole_count = 0; m_min_trace = 0; m_min_via = 0; m_min_via_hole = 0; m_xpath->clear(); m_pads_to_nets.clear(); // m_templates.clear(); this is the FOOTPRINT cache too m_board = NULL; m_props = aProperties; mm_per_biu = 1/IU_PER_MM; biu_per_mm = IU_PER_MM; delete m_rules; m_rules = new ERULES(); } void EAGLE_PLUGIN::clear_cu_map() { // All cu layers are invalid until we see them in the section while // loading either a board or library. See loadLayerDefs(). for( unsigned i = 0; i < DIM(m_cu_map); ++i ) m_cu_map[i] = -1; } void EAGLE_PLUGIN::loadAllSections( CPTREE& aDoc ) { CPTREE& drawing = aDoc.get_child( "eagle.drawing" ); CPTREE& board = drawing.get_child( "board" ); m_xpath->push( "eagle.drawing" ); { m_xpath->push( "board" ); CPTREE& designrules = board.get_child( "designrules" ); loadDesignRules( designrules ); m_xpath->pop(); } { m_xpath->push( "layers" ); CPTREE& layers = drawing.get_child( "layers" ); loadLayerDefs( layers ); m_xpath->pop(); } { m_xpath->push( "board" ); CPTREE& plain = board.get_child( "plain" ); loadPlain( plain ); CPTREE& signals = board.get_child( "signals" ); loadSignals( signals ); CPTREE& libs = board.get_child( "libraries" ); loadLibraries( libs ); CPTREE& elems = board.get_child( "elements" ); loadElements( elems ); m_xpath->pop(); // "board" } m_xpath->pop(); // "eagle.drawing" } void EAGLE_PLUGIN::loadDesignRules( CPTREE& aDesignRules ) { m_xpath->push( "designrules" ); m_rules->parse( aDesignRules ); m_xpath->pop(); // "designrules" } void EAGLE_PLUGIN::loadLayerDefs( CPTREE& aLayers ) { typedef std::vector ELAYERS; typedef ELAYERS::const_iterator EITER; ELAYERS cu; // copper layers // find the subset of layers that are copper, and active for( CITER layer = aLayers.begin(); layer != aLayers.end(); ++layer ) { ELAYER elayer( layer->second ); if( elayer.number >= 1 && elayer.number <= 16 && ( !elayer.active || *elayer.active ) ) { cu.push_back( elayer ); } } // establish cu layer map: int ki_layer_count = 0; for( EITER it = cu.begin(); it != cu.end(); ++it, ++ki_layer_count ) { if( ki_layer_count == 0 ) m_cu_map[it->number] = F_Cu; else if( ki_layer_count == int( cu.size()-1 ) ) m_cu_map[it->number] = B_Cu; else { // some eagle boards do not have contiguous layer number sequences. #if 0 // pre LAYER_ID & LSET: m_cu_map[it->number] = cu.size() - 1 - ki_layer_count; #else m_cu_map[it->number] = ki_layer_count; #endif } } #if 0 && defined(DEBUG) printf( "m_cu_map:\n" ); for( unsigned i=0; iSetCopperLayerCount( cu.size() ); for( EITER it = cu.begin(); it != cu.end(); ++it ) { LAYER_ID layer = kicad_layer( it->number ); // these function provide their own protection against UNDEFINED_LAYER: m_board->SetLayerName( layer, FROM_UTF8( it->name.c_str() ) ); m_board->SetLayerType( layer, LT_SIGNAL ); // could map the colors here } } } void EAGLE_PLUGIN::loadPlain( CPTREE& aGraphics ) { m_xpath->push( "plain" ); // (polygon | wire | text | circle | rectangle | frame | hole)* for( CITER gr = aGraphics.begin(); gr != aGraphics.end(); ++gr ) { if( gr->first == "wire" ) { m_xpath->push( "wire" ); EWIRE w( gr->second ); LAYER_ID layer = kicad_layer( w.layer ); wxPoint start( kicad_x( w.x1 ), kicad_y( w.y1 ) ); wxPoint end( kicad_x( w.x2 ), kicad_y( w.y2 ) ); if( layer != UNDEFINED_LAYER ) { DRAWSEGMENT* dseg = new DRAWSEGMENT( m_board ); m_board->Add( dseg, ADD_APPEND ); if( !w.curve ) { dseg->SetStart( start ); dseg->SetEnd( end ); } else { wxPoint center = kicad_arc_center( start, end, *w.curve); dseg->SetShape( S_ARC ); dseg->SetStart( center ); dseg->SetEnd( start ); dseg->SetAngle( *w.curve * -10.0 ); // KiCad rotates the other way } dseg->SetTimeStamp( timeStamp( gr->second ) ); dseg->SetLayer( layer ); dseg->SetWidth( Millimeter2iu( DEFAULT_PCB_EDGE_THICKNESS ) ); } m_xpath->pop(); } else if( gr->first == "text" ) { #if defined(DEBUG) if( gr->second.data() == "ATMEGA328" ) { int breakhere = 1; (void) breakhere; } #endif m_xpath->push( "text" ); ETEXT t( gr->second ); LAYER_ID layer = kicad_layer( t.layer ); if( layer != UNDEFINED_LAYER ) { TEXTE_PCB* pcbtxt = new TEXTE_PCB( m_board ); m_board->Add( pcbtxt, ADD_APPEND ); pcbtxt->SetLayer( layer ); pcbtxt->SetTimeStamp( timeStamp( gr->second ) ); pcbtxt->SetText( FROM_UTF8( t.text.c_str() ) ); pcbtxt->SetTextPosition( wxPoint( kicad_x( t.x ), kicad_y( t.y ) ) ); pcbtxt->SetSize( kicad_fontz( t.size ) ); double ratio = t.ratio ? *t.ratio : 8; // DTD says 8 is default pcbtxt->SetThickness( kicad( t.size * ratio / 100 ) ); int align = t.align ? *t.align : ETEXT::BOTTOM_LEFT; if( t.rot ) { int sign = t.rot->mirror ? -1 : 1; pcbtxt->SetMirrored( t.rot->mirror ); double degrees = t.rot->degrees; if( degrees == 90 || t.rot->spin ) pcbtxt->SetOrientation( sign * t.rot->degrees * 10 ); else if( degrees == 180 ) align = ETEXT::TOP_RIGHT; else if( degrees == 270 ) { pcbtxt->SetOrientation( sign * 90 * 10 ); align = ETEXT::TOP_RIGHT; } } switch( align ) { case ETEXT::CENTER: // this was the default in pcbtxt's constructor break; case ETEXT::CENTER_LEFT: pcbtxt->SetHorizJustify( GR_TEXT_HJUSTIFY_LEFT ); break; case ETEXT::CENTER_RIGHT: pcbtxt->SetHorizJustify( GR_TEXT_HJUSTIFY_RIGHT ); break; case ETEXT::TOP_CENTER: pcbtxt->SetVertJustify( GR_TEXT_VJUSTIFY_TOP ); break; case ETEXT::TOP_LEFT: pcbtxt->SetHorizJustify( GR_TEXT_HJUSTIFY_LEFT ); pcbtxt->SetVertJustify( GR_TEXT_VJUSTIFY_TOP ); break; case ETEXT::TOP_RIGHT: pcbtxt->SetHorizJustify( GR_TEXT_HJUSTIFY_RIGHT ); pcbtxt->SetVertJustify( GR_TEXT_VJUSTIFY_TOP ); break; case ETEXT::BOTTOM_CENTER: pcbtxt->SetVertJustify( GR_TEXT_VJUSTIFY_BOTTOM ); break; case ETEXT::BOTTOM_LEFT: pcbtxt->SetHorizJustify( GR_TEXT_HJUSTIFY_LEFT ); pcbtxt->SetVertJustify( GR_TEXT_VJUSTIFY_BOTTOM ); break; case ETEXT::BOTTOM_RIGHT: pcbtxt->SetHorizJustify( GR_TEXT_HJUSTIFY_RIGHT ); pcbtxt->SetVertJustify( GR_TEXT_VJUSTIFY_BOTTOM ); break; } } m_xpath->pop(); } else if( gr->first == "circle" ) { m_xpath->push( "circle" ); ECIRCLE c( gr->second ); LAYER_ID layer = kicad_layer( c.layer ); if( layer != UNDEFINED_LAYER ) // unsupported layer { DRAWSEGMENT* dseg = new DRAWSEGMENT( m_board ); m_board->Add( dseg, ADD_APPEND ); dseg->SetShape( S_CIRCLE ); dseg->SetTimeStamp( timeStamp( gr->second ) ); dseg->SetLayer( layer ); dseg->SetStart( wxPoint( kicad_x( c.x ), kicad_y( c.y ) ) ); dseg->SetEnd( wxPoint( kicad_x( c.x + c.radius ), kicad_y( c.y ) ) ); dseg->SetWidth( kicad( c.width ) ); } m_xpath->pop(); } else if( gr->first == "rectangle" ) { // This seems to be a simplified rectangular [copper] zone, cannot find any // net related info on it from the DTD. m_xpath->push( "rectangle" ); ERECT r( gr->second ); LAYER_ID layer = kicad_layer( r.layer ); if( IsCopperLayer( layer ) ) { // use a "netcode = 0" type ZONE: ZONE_CONTAINER* zone = new ZONE_CONTAINER( m_board ); m_board->Add( zone, ADD_APPEND ); zone->SetTimeStamp( timeStamp( gr->second ) ); zone->SetLayer( layer ); zone->SetNetCode( NETINFO_LIST::UNCONNECTED ); CPolyLine::HATCH_STYLE outline_hatch = CPolyLine::DIAGONAL_EDGE; zone->Outline()->Start( layer, kicad_x( r.x1 ), kicad_y( r.y1 ), outline_hatch ); zone->AppendCorner( wxPoint( kicad_x( r.x2 ), kicad_y( r.y1 ) ) ); zone->AppendCorner( wxPoint( kicad_x( r.x2 ), kicad_y( r.y2 ) ) ); zone->AppendCorner( wxPoint( kicad_x( r.x1 ), kicad_y( r.y2 ) ) ); zone->Outline()->CloseLastContour(); // this is not my fault: zone->Outline()->SetHatch( outline_hatch, Mils2iu( zone->Outline()->GetDefaultHatchPitchMils() ), true ); } m_xpath->pop(); } else if( gr->first == "hole" ) { m_xpath->push( "hole" ); EHOLE e( gr->second ); // Fabricate a MODULE with a single PAD_ATTRIB_HOLE_NOT_PLATED pad. // Use m_hole_count to gen up a unique name. MODULE* module = new MODULE( m_board ); m_board->Add( module, ADD_APPEND ); char temp[40]; sprintf( temp, "@HOLE%d", m_hole_count++ ); module->SetReference( FROM_UTF8( temp ) ); module->Reference().SetVisible( false ); wxPoint pos( kicad_x( e.x ), kicad_y( e.y ) ); module->SetPosition( pos ); // Add a PAD_ATTRIB_HOLE_NOT_PLATED pad to this module. D_PAD* pad = new D_PAD( module ); module->Pads().PushBack( pad ); pad->SetShape( PAD_SHAPE_CIRCLE ); pad->SetAttribute( PAD_ATTRIB_HOLE_NOT_PLATED ); /* pad's position is already centered on module at relative (0, 0) wxPoint padpos( kicad_x( e.x ), kicad_y( e.y ) ); pad->SetPos0( padpos ); pad->SetPosition( padpos + module->GetPosition() ); */ wxSize sz( kicad( e.drill ), kicad( e.drill ) ); pad->SetDrillSize( sz ); pad->SetSize( sz ); pad->SetLayerSet( LSET::AllCuMask() ); m_xpath->pop(); } else if( gr->first == "frame" ) { // picture this } else if( gr->first == "polygon" ) { // could be on a copper layer, could be on another layer. // copper layer would be done using netCode=0 type of ZONE_CONTAINER. } } m_xpath->pop(); } void EAGLE_PLUGIN::loadLibrary( CPTREE& aLib, const string* aLibName ) { m_xpath->push( "packages" ); // library will have node, skip that and get the single packages node CPTREE& packages = aLib.get_child( "packages" ); // Create a MODULE for all the eagle packages, for use later via a copy constructor // to instantiate needed MODULES in our BOARD. Save the MODULE templates in // a MODULE_MAP using a single lookup key consisting of libname+pkgname. for( CITER package = packages.begin(); package != packages.end(); ++package ) { m_xpath->push( "package", "name" ); const string& pack_ref = package->second.get( ".name" ); string pack_name( pack_ref ); ReplaceIllegalFileNameChars( &pack_name ); #if 0 && defined(DEBUG) if( pack_name == "TO220H" ) { int breakhere = 1; (void) breakhere; } #endif m_xpath->Value( pack_name.c_str() ); string key = aLibName ? makeKey( *aLibName, pack_name ) : pack_name; MODULE* m = makeModule( package->second, pack_name ); // add the templating MODULE to the MODULE template factory "m_templates" std::pair r = m_templates.insert( key, m ); if( !r.second // && !( m_props && m_props->Value( "ignore_duplicates" ) ) ) { wxString lib = aLibName ? FROM_UTF8( aLibName->c_str() ) : m_lib_path; wxString pkg = FROM_UTF8( pack_name.c_str() ); wxString emsg = wxString::Format( _( " name: '%s' duplicated in eagle : '%s'" ), GetChars( pkg ), GetChars( lib ) ); THROW_IO_ERROR( emsg ); } m_xpath->pop(); } m_xpath->pop(); // "packages" } void EAGLE_PLUGIN::loadLibraries( CPTREE& aLibs ) { m_xpath->push( "libraries.library", "name" ); for( CITER library = aLibs.begin(); library != aLibs.end(); ++library ) { const string& lib_name = library->second.get( ".name" ); m_xpath->Value( lib_name.c_str() ); loadLibrary( library->second, &lib_name ); } m_xpath->pop(); } void EAGLE_PLUGIN::loadElements( CPTREE& aElements ) { m_xpath->push( "elements.element", "name" ); EATTR name; EATTR value; for( CITER it = aElements.begin(); it != aElements.end(); ++it ) { if( it->first != "element" ) continue; EELEMENT e( it->second ); // use "NULL-ness" as an indication of presence of the attribute: EATTR* nameAttr = 0; EATTR* valueAttr = 0; m_xpath->Value( e.name.c_str() ); string key = makeKey( e.library, e.package ); MODULE_CITER mi = m_templates.find( key ); if( mi == m_templates.end() ) { wxString emsg = wxString::Format( _( "No '%s' package in library '%s'" ), GetChars( FROM_UTF8( e.package.c_str() ) ), GetChars( FROM_UTF8( e.library.c_str() ) ) ); THROW_IO_ERROR( emsg ); } #if defined(DEBUG) if( e.name == "ARM_C8" ) { int breakhere = 1; (void) breakhere; } #endif // copy constructor to clone the template MODULE* m = new MODULE( *mi->second ); m_board->Add( m, ADD_APPEND ); // update the nets within the pads of the clone for( D_PAD* pad = m->Pads(); pad; pad = pad->Next() ) { string key = makeKey( e.name, TO_UTF8( pad->GetPadName() ) ); NET_MAP_CITER ni = m_pads_to_nets.find( key ); if( ni != m_pads_to_nets.end() ) { const ENET* enet = &ni->second; pad->SetNetCode( enet->netcode ); } } m->SetPosition( wxPoint( kicad_x( e.x ), kicad_y( e.y ) ) ); m->SetReference( FROM_UTF8( e.name.c_str() ) ); m->SetValue( FROM_UTF8( e.value.c_str() ) ); // m->Value().SetVisible( false ); // initalize these to default values incase the elements are not present. m_xpath->push( "attribute", "name" ); // VALUE and NAME can have something like our text "effects" overrides // in SWEET and new schematic. Eagle calls these XML elements "attribute". // There can be one for NAME and/or VALUE both. Features present in the // EATTR override the ones established in the package only if they are // present here (except for rot, which if not present means angle zero). // So the logic is a bit different than in packageText() and in plain text. for( CITER ait = it->second.begin(); ait != it->second.end(); ++ait ) { if( ait->first != "attribute" ) continue; EATTR a( ait->second ); if( a.name == "NAME" ) { name = a; nameAttr = &name; } else if( a.name == "VALUE" ) { value = a; valueAttr = &value; } } m_xpath->pop(); // "attribute" orientModuleAndText( m, e, nameAttr, valueAttr ); } m_xpath->pop(); // "elements.element" } void EAGLE_PLUGIN::orientModuleAndText( MODULE* m, const EELEMENT& e, const EATTR* nameAttr, const EATTR* valueAttr ) { if( e.rot ) { if( e.rot->mirror ) { double orientation = e.rot->degrees + 180.0; m->SetOrientation( orientation * 10 ); m->Flip( m->GetPosition() ); } else m->SetOrientation( e.rot->degrees * 10 ); } orientModuleText( m, e, &m->Reference(), nameAttr ); orientModuleText( m, e, &m->Value(), valueAttr ); } void EAGLE_PLUGIN::orientModuleText( MODULE* m, const EELEMENT& e, TEXTE_MODULE* txt, const EATTR* aAttr ) { if( aAttr ) { const EATTR& a = *aAttr; if( a.value ) { txt->SetText( FROM_UTF8( a.value->c_str() ) ); } if( a.x && a.y ) // boost::optional { wxPoint pos( kicad_x( *a.x ), kicad_y( *a.y ) ); txt->SetTextPosition( pos ); } // Even though size and ratio are both optional, I am not seeing // a case where ratio is present but size is not. double ratio = 8; wxSize fontz = txt->GetSize(); if( a.size ) { fontz = kicad_fontz( *a.size ); txt->SetSize( fontz ); if( a.ratio ) ratio = *a.ratio; } int lw = int( fontz.y * ratio / 100.0 ); txt->SetThickness( lw ); int align = ETEXT::BOTTOM_LEFT; // bottom-left is eagle default // The "rot" in a EATTR seems to be assumed to be zero if it is not // present, and this zero rotation becomes an override to the // package's text field. If they did not want zero, they specify // what they want explicitly. double degrees = a.rot ? a.rot->degrees : 0; double orient; // relative to parent int sign = 1; bool spin = false; if( a.rot ) { spin = a.rot->spin; sign = a.rot->mirror ? -1 : 1; txt->SetMirrored( a.rot->mirror ); } if( degrees == 90 || degrees == 0 || spin ) { orient = degrees - m->GetOrientation() / 10; txt->SetOrientation( sign * orient * 10 ); } else if( degrees == 180 ) { orient = 0 - m->GetOrientation() / 10; txt->SetOrientation( sign * orient * 10 ); align = ETEXT::TOP_RIGHT; } else if( degrees == 270 ) { orient = 90 - m->GetOrientation() / 10; align = ETEXT::TOP_RIGHT; txt->SetOrientation( sign * orient * 10 ); } else { orient = 90 + degrees - m->GetOrientation() / 10; txt->SetOrientation( sign * orient * 10 ); } switch( align ) { case ETEXT::TOP_RIGHT: txt->SetHorizJustify( GR_TEXT_HJUSTIFY_RIGHT ); txt->SetVertJustify( GR_TEXT_VJUSTIFY_TOP ); break; case ETEXT::BOTTOM_LEFT: txt->SetHorizJustify( GR_TEXT_HJUSTIFY_LEFT ); txt->SetVertJustify( GR_TEXT_VJUSTIFY_BOTTOM ); break; default: ; } } else // the text is per the original package, sans { double degrees = ( txt->GetOrientation() + m->GetOrientation() ) / 10; // @todo there are a few more cases than these to contend with: if( (!txt->IsMirrored() && ( abs( degrees ) == 180 || abs( degrees ) == 270 )) || ( txt->IsMirrored() && ( degrees == 360 ) ) ) { // ETEXT::TOP_RIGHT: txt->SetHorizJustify( GR_TEXT_HJUSTIFY_RIGHT ); txt->SetVertJustify( GR_TEXT_VJUSTIFY_TOP ); } } } MODULE* EAGLE_PLUGIN::makeModule( CPTREE& aPackage, const string& aPkgName ) const { std::auto_ptr m( new MODULE( m_board ) ); m->SetFPID( FPID( aPkgName ) ); opt_string description = aPackage.get_optional( "description" ); if( description ) m->SetDescription( FROM_UTF8( description->c_str() ) ); for( CITER it = aPackage.begin(); it != aPackage.end(); ++it ) { CPTREE& t = it->second; if( it->first == "wire" ) packageWire( m.get(), t ); else if( it->first == "pad" ) packagePad( m.get(), t ); else if( it->first == "text" ) packageText( m.get(), t ); else if( it->first == "rectangle" ) packageRectangle( m.get(), t ); else if( it->first == "polygon" ) packagePolygon( m.get(), t ); else if( it->first == "circle" ) packageCircle( m.get(), t ); else if( it->first == "hole" ) packageHole( m.get(), t ); else if( it->first == "smd" ) packageSMD( m.get(), t ); } return m.release(); } void EAGLE_PLUGIN::packageWire( MODULE* aModule, CPTREE& aTree ) const { EWIRE w( aTree ); LAYER_ID layer = kicad_layer( w.layer ); if( IsNonCopperLayer( layer ) ) // only valid non-copper wires, skip copper package wires { wxPoint start( kicad_x( w.x1 ), kicad_y( w.y1 ) ); wxPoint end( kicad_x( w.x2 ), kicad_y( w.y2 ) ); int width = kicad( w.width ); // FIXME: the cap attribute is ignored because kicad can't create lines // with flat ends. EDGE_MODULE* dwg; if( !w.curve ) { dwg = new EDGE_MODULE( aModule, S_SEGMENT ); dwg->SetStart0( start ); dwg->SetEnd0( end ); } else { dwg = new EDGE_MODULE( aModule, S_ARC ); wxPoint center = kicad_arc_center( start, end, *w.curve); dwg->SetStart0( center ); dwg->SetEnd0( start ); dwg->SetAngle( *w.curve * -10.0 ); // KiCad rotates the other way } dwg->SetLayer( layer ); dwg->SetWidth( width ); aModule->GraphicalItems().PushBack( dwg ); } } void EAGLE_PLUGIN::packagePad( MODULE* aModule, CPTREE& aTree ) const { // this is thru hole technology here, no SMDs EPAD e( aTree ); D_PAD* pad = new D_PAD( aModule ); aModule->Pads().PushBack( pad ); pad->SetPadName( FROM_UTF8( e.name.c_str() ) ); // pad's "Position" is not relative to the module's, // whereas Pos0 is relative to the module's but is the unrotated coordinate. wxPoint padpos( kicad_x( e.x ), kicad_y( e.y ) ); pad->SetPos0( padpos ); RotatePoint( &padpos, aModule->GetOrientation() ); pad->SetPosition( padpos + aModule->GetPosition() ); pad->SetDrillSize( wxSize( kicad( e.drill ), kicad( e.drill ) ) ); pad->SetLayerSet( LSET::AllCuMask().set( B_Mask ).set( F_Mask ) ); if( e.shape ) { switch( *e.shape ) { case EPAD::ROUND: wxASSERT( pad->GetShape()==PAD_SHAPE_CIRCLE ); // verify set in D_PAD constructor break; case EPAD::OCTAGON: // no KiCad octagonal pad shape, use PAD_CIRCLE for now. // pad->SetShape( PAD_OCTAGON ); wxASSERT( pad->GetShape()==PAD_SHAPE_CIRCLE ); // verify set in D_PAD constructor break; case EPAD::LONG: pad->SetShape( PAD_SHAPE_OVAL ); break; case EPAD::SQUARE: pad->SetShape( PAD_SHAPE_RECT ); break; case EPAD::OFFSET: ; // don't know what to do here. } } else { // if shape is not present, our default is circle and that matches their default "round" } if( e.diameter ) { int diameter = kicad( *e.diameter ); pad->SetSize( wxSize( diameter, diameter ) ); } else { double drillz = pad->GetDrillSize().x; double annulus = drillz * m_rules->rvPadTop; // copper annulus, eagle "restring" annulus = Clamp( m_rules->rlMinPadTop, annulus, m_rules->rlMaxPadTop ); int diameter = KiROUND( drillz + 2 * annulus ); pad->SetSize( wxSize( KiROUND( diameter ), KiROUND( diameter ) ) ); } if( pad->GetShape() == PAD_SHAPE_OVAL ) { // The Eagle "long" pad is wider than it is tall, // m_elongation is percent elongation wxSize sz = pad->GetSize(); sz.x = ( sz.x * ( 100 + m_rules->psElongationLong ) ) / 100; pad->SetSize( sz ); } if( e.rot ) { pad->SetOrientation( e.rot->degrees * 10 ); } // @todo: handle stop and thermal } void EAGLE_PLUGIN::packageText( MODULE* aModule, CPTREE& aTree ) const { ETEXT t( aTree ); LAYER_ID layer = kicad_layer( t.layer ); if( layer == UNDEFINED_LAYER ) { layer = Cmts_User; } TEXTE_MODULE* txt; if( t.text == ">NAME" || t.text == ">name" ) txt = &aModule->Reference(); else if( t.text == ">VALUE" || t.text == ">value" ) txt = &aModule->Value(); else { // FIXME: graphical text items are rotated for some reason. txt = new TEXTE_MODULE( aModule ); aModule->GraphicalItems().PushBack( txt ); } txt->SetTimeStamp( timeStamp( aTree ) ); txt->SetText( FROM_UTF8( t.text.c_str() ) ); wxPoint pos( kicad_x( t.x ), kicad_y( t.y ) ); txt->SetTextPosition( pos ); txt->SetPos0( pos - aModule->GetPosition() ); txt->SetLayer( layer ); txt->SetSize( kicad_fontz( t.size ) ); double ratio = t.ratio ? *t.ratio : 8; // DTD says 8 is default txt->SetThickness( kicad( t.size * ratio / 100 ) ); int align = t.align ? *t.align : ETEXT::BOTTOM_LEFT; // bottom-left is eagle default // An eagle package is never rotated, the DTD does not allow it. // angle -= aModule->GetOrienation(); if( t.rot ) { int sign = t.rot->mirror ? -1 : 1; txt->SetMirrored( t.rot->mirror ); double degrees = t.rot->degrees; if( degrees == 90 || t.rot->spin ) txt->SetOrientation( sign * degrees * 10 ); else if( degrees == 180 ) align = ETEXT::TOP_RIGHT; else if( degrees == 270 ) { align = ETEXT::TOP_RIGHT; txt->SetOrientation( sign * 90 * 10 ); } } switch( align ) { case ETEXT::CENTER: // this was the default in pcbtxt's constructor break; case ETEXT::CENTER_LEFT: txt->SetHorizJustify( GR_TEXT_HJUSTIFY_LEFT ); break; case ETEXT::CENTER_RIGHT: txt->SetHorizJustify( GR_TEXT_HJUSTIFY_RIGHT ); break; case ETEXT::TOP_CENTER: txt->SetVertJustify( GR_TEXT_VJUSTIFY_TOP ); break; case ETEXT::TOP_LEFT: txt->SetHorizJustify( GR_TEXT_HJUSTIFY_LEFT ); txt->SetVertJustify( GR_TEXT_VJUSTIFY_TOP ); break; case ETEXT::TOP_RIGHT: txt->SetHorizJustify( GR_TEXT_HJUSTIFY_RIGHT ); txt->SetVertJustify( GR_TEXT_VJUSTIFY_TOP ); break; case ETEXT::BOTTOM_CENTER: txt->SetVertJustify( GR_TEXT_VJUSTIFY_BOTTOM ); break; case ETEXT::BOTTOM_LEFT: txt->SetHorizJustify( GR_TEXT_HJUSTIFY_LEFT ); txt->SetVertJustify( GR_TEXT_VJUSTIFY_BOTTOM ); break; case ETEXT::BOTTOM_RIGHT: txt->SetHorizJustify( GR_TEXT_HJUSTIFY_RIGHT ); txt->SetVertJustify( GR_TEXT_VJUSTIFY_BOTTOM ); break; } } void EAGLE_PLUGIN::packageRectangle( MODULE* aModule, CPTREE& aTree ) const { ERECT r( aTree ); LAYER_ID layer = kicad_layer( r.layer ); if( IsNonCopperLayer( layer ) ) // skip copper "package.rectangle"s { EDGE_MODULE* dwg = new EDGE_MODULE( aModule, S_POLYGON ); aModule->GraphicalItems().PushBack( dwg ); dwg->SetLayer( layer ); dwg->SetWidth( 0 ); dwg->SetTimeStamp( timeStamp( aTree ) ); std::vector pts; wxPoint start( wxPoint( kicad_x( r.x1 ), kicad_y( r.y1 ) ) ); wxPoint end( wxPoint( kicad_x( r.x1 ), kicad_y( r.y2 ) ) ); pts.push_back( start ); pts.push_back( wxPoint( kicad_x( r.x2 ), kicad_y( r.y1 ) ) ); pts.push_back( wxPoint( kicad_x( r.x2 ), kicad_y( r.y2 ) ) ); pts.push_back( end ); dwg->SetPolyPoints( pts ); dwg->SetStart0( start ); dwg->SetEnd0( end ); } } void EAGLE_PLUGIN::packagePolygon( MODULE* aModule, CPTREE& aTree ) const { EPOLYGON p( aTree ); LAYER_ID layer = kicad_layer( p.layer ); if( IsNonCopperLayer( layer ) ) // skip copper "package.rectangle"s { EDGE_MODULE* dwg = new EDGE_MODULE( aModule, S_POLYGON ); aModule->GraphicalItems().PushBack( dwg ); dwg->SetWidth( 0 ); // it's filled, no need for boundary width /* switch( layer ) { case Eco1_User: layer = F_SilkS; break; case Eco2_User: layer = B_SilkS; break; // all MODULE templates (created from eagle packages) are on front layer // until cloned. case Cmts_User: layer = F_SilkS; break; } */ dwg->SetLayer( layer ); dwg->SetTimeStamp( timeStamp( aTree ) ); std::vector pts; pts.reserve( aTree.size() ); for( CITER vi = aTree.begin(); vi != aTree.end(); ++vi ) { if( vi->first != "vertex" ) // skip node continue; EVERTEX v( vi->second ); pts.push_back( wxPoint( kicad_x( v.x ), kicad_y( v.y ) ) ); } dwg->SetPolyPoints( pts ); dwg->SetStart0( *pts.begin() ); dwg->SetEnd0( pts.back() ); } } void EAGLE_PLUGIN::packageCircle( MODULE* aModule, CPTREE& aTree ) const { ECIRCLE e( aTree ); LAYER_ID layer = kicad_layer( e.layer ); EDGE_MODULE* gr = new EDGE_MODULE( aModule, S_CIRCLE ); aModule->GraphicalItems().PushBack( gr ); gr->SetWidth( kicad( e.width ) ); switch( (int) layer ) { case UNDEFINED_LAYER: layer = Cmts_User; break; /* case Eco1_User: layer = F_SilkS; break; case Eco2_User: layer = B_SilkS; break; */ default: break; } gr->SetLayer( layer ); gr->SetTimeStamp( timeStamp( aTree ) ); gr->SetStart0( wxPoint( kicad_x( e.x ), kicad_y( e.y ) ) ); gr->SetEnd0( wxPoint( kicad_x( e.x + e.radius ), kicad_y( e.y ) ) ); } void EAGLE_PLUGIN::packageHole( MODULE* aModule, CPTREE& aTree ) const { EHOLE e( aTree ); // we add a PAD_ATTRIB_HOLE_NOT_PLATED pad to this module. D_PAD* pad = new D_PAD( aModule ); aModule->Pads().PushBack( pad ); pad->SetShape( PAD_SHAPE_CIRCLE ); pad->SetAttribute( PAD_ATTRIB_HOLE_NOT_PLATED ); // Mechanical purpose only: // no offset, no net name, no pad name allowed // pad->SetOffset( wxPoint( 0, 0 ) ); // pad->SetPadName( wxEmptyString ); wxPoint padpos( kicad_x( e.x ), kicad_y( e.y ) ); pad->SetPos0( padpos ); pad->SetPosition( padpos + aModule->GetPosition() ); wxSize sz( kicad( e.drill ), kicad( e.drill ) ); pad->SetDrillSize( sz ); pad->SetSize( sz ); pad->SetLayerSet( LSET::AllCuMask() /* | SOLDERMASK_LAYER_BACK | SOLDERMASK_LAYER_FRONT */ ); } void EAGLE_PLUGIN::packageSMD( MODULE* aModule, CPTREE& aTree ) const { ESMD e( aTree ); LAYER_ID layer = kicad_layer( e.layer ); if( !IsCopperLayer( layer ) ) { return; } D_PAD* pad = new D_PAD( aModule ); aModule->Pads().PushBack( pad ); pad->SetPadName( FROM_UTF8( e.name.c_str() ) ); pad->SetShape( PAD_SHAPE_RECT ); pad->SetAttribute( PAD_ATTRIB_SMD ); // pad's "Position" is not relative to the module's, // whereas Pos0 is relative to the module's but is the unrotated coordinate. wxPoint padpos( kicad_x( e.x ), kicad_y( e.y ) ); pad->SetPos0( padpos ); RotatePoint( &padpos, aModule->GetOrientation() ); pad->SetPosition( padpos + aModule->GetPosition() ); pad->SetSize( wxSize( kicad( e.dx ), kicad( e.dy ) ) ); pad->SetLayer( layer ); static const LSET front( 3, F_Cu, F_Paste, F_Mask ); static const LSET back( 3, B_Cu, B_Paste, B_Mask ); if( layer == F_Cu ) pad->SetLayerSet( front ); else if( layer == B_Cu ) pad->SetLayerSet( back ); // Optional according to DTD if( e.roundness ) // set set shape to PAD_SHAPE_RECT above, in case roundness is not present { if( *e.roundness >= 75 ) // roundness goes from 0-100% as integer { if( e.dy == e.dx ) pad->SetShape( PAD_SHAPE_CIRCLE ); else pad->SetShape( PAD_SHAPE_OVAL ); } } if( e.rot ) { pad->SetOrientation( e.rot->degrees * 10 ); } // don't know what stop, thermals, and cream should look like now. } /// non-owning container typedef std::vector ZONES; void EAGLE_PLUGIN::loadSignals( CPTREE& aSignals ) { ZONES zones; // per net m_xpath->push( "signals.signal", "name" ); int netCode = 1; for( CITER net = aSignals.begin(); net != aSignals.end(); ++net ) { bool sawPad = false; zones.clear(); const string& nname = net->second.get( ".name" ); wxString netName = FROM_UTF8( nname.c_str() ); m_board->AppendNet( new NETINFO_ITEM( m_board, netName, netCode ) ); m_xpath->Value( nname.c_str() ); #if defined(DEBUG) if( netName == wxT( "N$8" ) ) { int breakhere = 1; (void) breakhere; } #endif // (contactref | polygon | wire | via)* for( CITER it = net->second.begin(); it != net->second.end(); ++it ) { if( it->first == "wire" ) { m_xpath->push( "wire" ); EWIRE w( it->second ); LAYER_ID layer = kicad_layer( w.layer ); if( IsCopperLayer( layer ) ) { TRACK* t = new TRACK( m_board ); t->SetTimeStamp( timeStamp( it->second ) ); t->SetPosition( wxPoint( kicad_x( w.x1 ), kicad_y( w.y1 ) ) ); t->SetEnd( wxPoint( kicad_x( w.x2 ), kicad_y( w.y2 ) ) ); int width = kicad( w.width ); if( width < m_min_trace ) m_min_trace = width; t->SetWidth( width ); t->SetLayer( layer ); t->SetNetCode( netCode ); m_board->m_Track.Insert( t, NULL ); } else { // put non copper wires where the sun don't shine. } m_xpath->pop(); } else if( it->first == "via" ) { m_xpath->push( "via" ); EVIA v( it->second ); LAYER_ID layer_front_most = kicad_layer( v.layer_front_most ); LAYER_ID layer_back_most = kicad_layer( v.layer_back_most ); if( IsCopperLayer( layer_front_most ) && IsCopperLayer( layer_back_most ) ) { int kidiam; int drillz = kicad( v.drill ); VIA* via = new VIA( m_board ); m_board->m_Track.Insert( via, NULL ); via->SetLayerPair( layer_front_most, layer_back_most ); if( v.diam ) { kidiam = kicad( *v.diam ); via->SetWidth( kidiam ); } else { double annulus = drillz * m_rules->rvViaOuter; // eagle "restring" annulus = Clamp( m_rules->rlMinViaOuter, annulus, m_rules->rlMaxViaOuter ); kidiam = KiROUND( drillz + 2 * annulus ); via->SetWidth( kidiam ); } via->SetDrill( drillz ); if( kidiam < m_min_via ) m_min_via = kidiam; if( drillz < m_min_via_hole ) m_min_via_hole = drillz; if( layer_front_most == F_Cu && layer_back_most == B_Cu ) via->SetViaType( VIA_THROUGH ); else if( layer_front_most == F_Cu || layer_back_most == B_Cu ) via->SetViaType( VIA_MICROVIA ); else via->SetViaType( VIA_BLIND_BURIED ); via->SetTimeStamp( timeStamp( it->second ) ); wxPoint pos( kicad_x( v.x ), kicad_y( v.y ) ); via->SetPosition( pos ); via->SetEnd( pos ); via->SetNetCode( netCode ); } m_xpath->pop(); } else if( it->first == "contactref" ) { m_xpath->push( "contactref" ); // CPTREE& attribs = it->second.get_child( "" ); const string& reference = attribs.get( "element" ); const string& pad = attribs.get( "pad" ); string key = makeKey( reference, pad ) ; // D(printf( "adding refname:'%s' pad:'%s' netcode:%d netname:'%s'\n", reference.c_str(), pad.c_str(), netCode, nname.c_str() );) m_pads_to_nets[ key ] = ENET( netCode, nname ); m_xpath->pop(); sawPad = true; } else if( it->first == "polygon" ) { m_xpath->push( "polygon" ); EPOLYGON p( it->second ); LAYER_ID layer = kicad_layer( p.layer ); if( IsCopperLayer( layer ) ) { // use a "netcode = 0" type ZONE: ZONE_CONTAINER* zone = new ZONE_CONTAINER( m_board ); m_board->Add( zone, ADD_APPEND ); zones.push_back( zone ); zone->SetTimeStamp( timeStamp( it->second ) ); zone->SetLayer( layer ); zone->SetNetCode( netCode ); CPolyLine::HATCH_STYLE outline_hatch = CPolyLine::DIAGONAL_EDGE; bool first = true; for( CITER vi = it->second.begin(); vi != it->second.end(); ++vi ) { if( vi->first != "vertex" ) // skip node continue; EVERTEX v( vi->second ); // the ZONE_CONTAINER API needs work, as you can see: if( first ) { zone->Outline()->Start( layer, kicad_x( v.x ), kicad_y( v.y ), outline_hatch ); first = false; } else zone->AppendCorner( wxPoint( kicad_x( v.x ), kicad_y( v.y ) ) ); } zone->Outline()->CloseLastContour(); // If pour is set the zone should be hatched, // set the hatch size from the spacing variable. if( p.pour ) { zone->Outline()->SetHatch( outline_hatch, *p.spacing, true ); } // clearances, etc. zone->SetArcSegmentCount( 32 ); // @todo: should be a constructor default? zone->SetMinThickness( kicad( p.width ) ); // FIXME: KiCad zones have very rounded corners compared to eagle. // This means that isolation amounts that work well in eagle // tend to make copper intrude in soldermask free areas around pads. if( p.isolate ) { zone->SetZoneClearance( kicad( *p.isolate ) ); } // missing == yes per DTD. bool thermals = !p.thermals || *p.thermals; zone->SetPadConnection( thermals ? PAD_ZONE_CONN_THERMAL : PAD_ZONE_CONN_FULL ); if( thermals ) { // FIXME: eagle calculates dimensions for thermal spokes // based on what the zone is connecting to. // (i.e. width of spoke is half of the smaller side of an smd pad) // This is a basic workaround zone->SetThermalReliefGap( kicad( p.width + 0.05 ) ); zone->SetThermalReliefCopperBridge( kicad( p.width + 0.05 ) ); } int rank = p.rank ? *p.rank : p.max_priority; zone->SetPriority( rank ); } m_xpath->pop(); // "polygon" } } if( zones.size() && !sawPad ) { // KiCad does not support an unconnected zone with its own non-zero netcode, // but only when assigned netcode = 0 w/o a name... for( ZONES::iterator it = zones.begin(); it != zones.end(); ++it ) (*it)->SetNetCode( NETINFO_LIST::UNCONNECTED ); // therefore omit this signal/net. } else netCode++; } m_xpath->pop(); // "signals.signal" } LAYER_ID EAGLE_PLUGIN::kicad_layer( int aEagleLayer ) const { /* will assume this is a valid mapping for all eagle boards until I get paid more: */ int kiLayer; // eagle copper layer: if( aEagleLayer >= 1 && aEagleLayer < int( DIM( m_cu_map ) ) ) { kiLayer = m_cu_map[aEagleLayer]; } else { /* #define FIRST_NON_COPPER_LAYER 16 #define B_Adhes 16 #define F_Adhes 17 #define B_Paste 18 #define F_Paste 19 #define B_SilkS 20 #define F_SilkS 21 #define B_Mask 22 #define F_Mask 23 #define Dwgs_User 24 #define Cmts_User 25 #define Eco1_User 26 #define Eco2_User 27 #define Edge_Cuts 28 #define LAST_NON_COPPER_LAYER 28 #define UNUSED_LAYER_29 29 #define UNUSED_LAYER_30 30 #define UNUSED_LAYER_31 31 */ // translate non-copper eagle layer to pcbnew layer switch( aEagleLayer ) { case 20: kiLayer = Edge_Cuts; break; // eagle says "Dimension" layer, but it's for board perimeter case 21: kiLayer = F_SilkS; break; case 22: kiLayer = B_SilkS; break; case 25: kiLayer = F_SilkS; break; case 26: kiLayer = B_SilkS; break; case 27: kiLayer = F_SilkS; break; case 28: kiLayer = B_SilkS; break; case 29: kiLayer = F_Mask; break; case 30: kiLayer = B_Mask; break; case 31: kiLayer = F_Paste; break; case 32: kiLayer = B_Paste; break; case 33: kiLayer = F_Mask; break; case 34: kiLayer = B_Mask; break; case 35: kiLayer = F_Adhes; break; case 36: kiLayer = B_Adhes; break; case 49: kiLayer = Cmts_User; break; case 50: kiLayer = Cmts_User; break; // Packages show the future chip pins on SMD parts using layer 51. // This is an area slightly smaller than the PAD/SMD copper area. // Carry those visual aids into the MODULE on the drawing layer, not silkscreen. case 51: kiLayer = Dwgs_User; break; case 52: kiLayer = Dwgs_User; break; case 95: kiLayer = Eco1_User; break; case 96: kiLayer = Eco2_User; break; default: // some layers do not map to KiCad // DBG( printf( "unsupported eagle layer: %d\n", aEagleLayer );) kiLayer = UNDEFINED_LAYER; break; } } return LAYER_ID( kiLayer ); } void EAGLE_PLUGIN::centerBoard() { if( m_props ) { UTF8 page_width; UTF8 page_height; if( m_props->Value( "page_width", &page_width ) && m_props->Value( "page_height", &page_height ) ) { EDA_RECT bbbox = m_board->ComputeBoundingBox( true ); int w = atoi( page_width.c_str() ); int h = atoi( page_height.c_str() ); int desired_x = ( w - bbbox.GetWidth() ) / 2; int desired_y = ( h - bbbox.GetHeight() ) / 2; DBG(printf( "bbox.width:%d bbox.height:%d w:%d h:%d desired_x:%d desired_y:%d\n", bbbox.GetWidth(), bbbox.GetHeight(), w, h, desired_x, desired_y );) m_board->Move( wxPoint( desired_x - bbbox.GetX(), desired_y - bbbox.GetY() ) ); } } } wxDateTime EAGLE_PLUGIN::getModificationTime( const wxString& aPath ) { wxFileName fn( aPath ); // Do not call wxFileName::GetModificationTime() on a non-existent file, because // if it fails, wx's implementation calls the crap wxLogSysError() which // eventually infects our UI with an unwanted popup window, so don't let it fail. if( !fn.IsFileReadable() ) { wxString msg = wxString::Format( _( "File '%s' is not readable." ), GetChars( aPath ) ); THROW_IO_ERROR( msg ); } /* // update the writable flag while we have a wxFileName, in a network this // is possibly quite dynamic anyway. m_writable = fn.IsFileWritable(); */ wxDateTime modTime = fn.GetModificationTime(); if( !modTime.IsValid() ) modTime.Now(); return modTime; } void EAGLE_PLUGIN::cacheLib( const wxString& aLibPath ) { try { wxDateTime modtime = getModificationTime( aLibPath ); // Fixes assertions in wxWidgets debug builds for the wxDateTime object. Refresh the // cache if either of the wxDateTime objects are invalid or the last file modification // time differs from the current file modification time. bool load = !m_mod_time.IsValid() || !modtime.IsValid() || m_mod_time != modtime; if( aLibPath != m_lib_path || load ) { PTREE doc; LOCALE_IO toggle; // toggles on, then off, the C locale. m_templates.clear(); // Set this before completion of loading, since we rely on it for // text of an exception. Delay setting m_mod_time until after successful load // however. m_lib_path = aLibPath; // 8 bit "filename" should be encoded according to disk filename encoding, // (maybe this is current locale, maybe not, its a filesystem issue), // and is not necessarily utf8. string filename = (const char*) aLibPath.char_str( wxConvFile ); read_xml( filename, doc, xml_parser::no_comments ); // clear the cu map and then rebuild it. clear_cu_map(); m_xpath->push( "eagle.drawing.layers" ); CPTREE& layers = doc.get_child( "eagle.drawing.layers" ); loadLayerDefs( layers ); m_xpath->pop(); m_xpath->push( "eagle.drawing.library" ); CPTREE& library = doc.get_child( "eagle.drawing.library" ); loadLibrary( library, NULL ); m_xpath->pop(); m_mod_time = modtime; } } catch( file_parser_error fpe ) { // for xml_parser_error, what() has the line number in it, // but no byte offset. That should be an adequate error message. THROW_IO_ERROR( fpe.what() ); } // Class ptree_error is a base class for xml_parser_error & file_parser_error, // so one catch should be OK for all errors. catch( ptree_error pte ) { string errmsg = pte.what(); errmsg += " @\n"; errmsg += m_xpath->Contents(); THROW_IO_ERROR( errmsg ); } } wxArrayString EAGLE_PLUGIN::FootprintEnumerate( const wxString& aLibraryPath, const PROPERTIES* aProperties ) { init( aProperties ); cacheLib( aLibraryPath ); wxArrayString ret; for( MODULE_CITER it = m_templates.begin(); it != m_templates.end(); ++it ) ret.Add( FROM_UTF8( it->first.c_str() ) ); return ret; } MODULE* EAGLE_PLUGIN::FootprintLoad( const wxString& aLibraryPath, const wxString& aFootprintName, const PROPERTIES* aProperties ) { init( aProperties ); cacheLib( aLibraryPath ); string key = TO_UTF8( aFootprintName ); MODULE_CITER mi = m_templates.find( key ); if( mi == m_templates.end() ) return NULL; // copy constructor to clone the template MODULE* ret = new MODULE( *mi->second ); return ret; } void EAGLE_PLUGIN::FootprintLibOptions( PROPERTIES* aListToAppendTo ) const { PLUGIN::FootprintLibOptions( aListToAppendTo ); /* (*aListToAppendTo)["ignore_duplicates"] = UTF8( _( "Ignore duplicately named footprints within the same Eagle library. " "Only the first similarly named footprint will be loaded." )); */ } /* void EAGLE_PLUGIN::Save( const wxString& aFileName, BOARD* aBoard, const PROPERTIES* aProperties ) { // Eagle lovers apply here. } void EAGLE_PLUGIN::FootprintSave( const wxString& aLibraryPath, const MODULE* aFootprint, const PROPERTIES* aProperties ) { } void EAGLE_PLUGIN::FootprintDelete( const wxString& aLibraryPath, const wxString& aFootprintName ) { } void EAGLE_PLUGIN::FootprintLibCreate( const wxString& aLibraryPath, const PROPERTIES* aProperties ) { } bool EAGLE_PLUGIN::FootprintLibDelete( const wxString& aLibraryPath, const PROPERTIES* aProperties ) { } bool EAGLE_PLUGIN::IsFootprintLibWritable( const wxString& aLibraryPath ) { return true; } */