/* * This program source code file is part of KiCad, a free EDA CAD application. * * Copyright (C) 2012 Wayne Stambaugh * Copyright (C) 1992-2023 KiCad Developers, see AUTHORS.txt for contributors. * * This program is free software; you can redistribute it and/or * modify it under the terms of the GNU General Public License * as published by the Free Software Foundation; either version 2 * of the License, or (at your option) any later version. * * This program is distributed in the hope that it will be useful, * but WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the * GNU General Public License for more details. * * You should have received a copy of the GNU General Public License * along with this program; if not, you may find one here: * http://www.gnu.org/licenses/old-licenses/gpl-2.0.html * or you may search the http://www.gnu.org website for the version 2 license, * or you may write to the Free Software Foundation, Inc., * 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301, USA */ /** * @file pcb_io_geda.cpp * @brief Geda PCB file plugin implementation file. */ #include #include #include // for KiROUND #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include static inline long parseInt( const wxString& aValue, double aScalar ) { double value = std::numeric_limits::max(); /* * In 2011 gEDA/pcb introduced values with units, like "10mm" or "200mil". * Unit-less values are still centimils (100000 units per inch), like with * the previous format. * * Distinction between the even older format (mils, 1000 units per inch) * and the pre-2011 format is done in ::parseFOOTPRINT already; the * distinction is by whether an object definition opens with '(' or '['. * All values with explicit unit open with a '[' so there's no need to * consider this distinction when parsing them. * * The solution here is to watch for a unit and, if present, convert the * value to centimils. All unit-less values are read unaltered. This way * the code below can continue to consider all read values to be in mils or * centimils. It also matches the strategy gEDA/pcb uses for backwards * compatibility with its own layouts. * * Fortunately gEDA/pcb allows only units 'mil' and 'mm' in files, see * definition of ALLOW_READABLE in gEDA/pcb's pcb_printf.h. So we don't * have to test for all 11 units gEDA/pcb allows in user dialogs. */ if( aValue.EndsWith( wxT( "mm" ) ) ) { aScalar *= 100000.0 / 25.4; } else if( aValue.EndsWith( wxT( "mil" ) ) ) { aScalar *= 100.; } // This conversion reports failure on strings as simple as "1000", still // it returns the right result in &value. Thus, ignore the return value. aValue.ToCDouble(&value); if( value == std::numeric_limits::max() ) // conversion really failed { THROW_IO_ERROR( wxString::Format( _( "Cannot convert '%s' to an integer." ), aValue.GetData() ) ); } return KiROUND( value * aScalar ); } /** * helper class for creating a footprint library cache. * * The new footprint library design is a file path of individual footprint files * that contain a single footprint per file. This class is a helper only for the * footprint portion of the PLUGIN API, and only for the #PCB_IO_KICAD_SEXPR plugin. It is * private to this implementation file so it is not placed into a header. */ class GPCB_FPL_CACHE_ITEM { public: GPCB_FPL_CACHE_ITEM( FOOTPRINT* aFootprint, const WX_FILENAME& aFileName ); WX_FILENAME GetFileName() const { return m_filename; } FOOTPRINT* GetFootprint() const { return m_footprint.get(); } private: WX_FILENAME m_filename; ///< The full file name and path of the footprint to cache. std::unique_ptr m_footprint; }; GPCB_FPL_CACHE_ITEM::GPCB_FPL_CACHE_ITEM( FOOTPRINT* aFootprint, const WX_FILENAME& aFileName ) : m_filename( aFileName ), m_footprint( aFootprint ) { } typedef boost::ptr_map< std::string, GPCB_FPL_CACHE_ITEM > FOOTPRINT_MAP; class GPCB_FPL_CACHE { public: GPCB_FPL_CACHE( PCB_IO_GEDA* aOwner, const wxString& aLibraryPath ); wxString GetPath() const { return m_lib_path.GetPath(); } bool IsWritable() const { return m_lib_path.IsOk() && m_lib_path.IsDirWritable(); } FOOTPRINT_MAP& GetFootprints() { return m_footprints; } // Most all functions in this class throw IO_ERROR exceptions. There are no // error codes nor user interface calls from here, nor in any PLUGIN. // Catch these exceptions higher up please. /// Save not implemented for the Geda PCB footprint library format. void Load(); void Remove( const wxString& aFootprintName ); /** * Generate a timestamp representing all source files in the cache (including the * parent directory). * * Timestamps should not be considered ordered. They either match or they don't. */ static long long GetTimestamp( const wxString& aLibPath ); /** * Return true if the cache is not up-to-date. */ bool IsModified(); private: FOOTPRINT* parseFOOTPRINT( LINE_READER* aLineReader ); /** * Test \a aFlag for \a aMask or \a aName. * * @param aFlag is a list of flags to test against: can be a bit field flag or a list name flag * a bit field flag is an hexadecimal value: Ox00020000 a list name flag is a * string list of flags, comma separated like square,option1. * @param aMask is the flag list to test. * @param aName is the flag name to find in list. * @return true if found. */ bool testFlags( const wxString& aFlag, long aMask, const wxChar* aName ); /** * Extract parameters and tokens from \a aLineReader and adds them to \a aParameterList. * * Delimiter characters are: * [ ] ( ) Begin and end of parameter list and units indicator * " is a string delimiter * space is the param separator * The first word is the keyword * the second item is one of ( or [ * other are parameters (number or delimited string) * last parameter is ) or ] * * @param aParameterList This list of parameters parsed. * @param aLineReader The line reader object to parse. */ void parseParameters( wxArrayString& aParameterList, LINE_READER* aLineReader ); PCB_IO_GEDA* m_owner; ///< Plugin object that owns the cache. wxFileName m_lib_path; ///< The path of the library. FOOTPRINT_MAP m_footprints; ///< Map of footprint file name to FOOTPRINT*. bool m_cache_dirty; ///< Stored separately because it's expensive to check ///< m_cache_timestamp against all the files. long long m_cache_timestamp; ///< A hash of the timestamps for all the footprint ///< files. }; GPCB_FPL_CACHE::GPCB_FPL_CACHE( PCB_IO_GEDA* aOwner, const wxString& aLibraryPath ) { m_owner = aOwner; m_lib_path.SetPath( aLibraryPath ); m_cache_timestamp = 0; m_cache_dirty = true; } void GPCB_FPL_CACHE::Load() { m_cache_dirty = false; m_cache_timestamp = 0; // Note: like our .pretty footprint libraries, the gpcb footprint libraries are folders, // and the footprints are the .fp files inside this folder. wxDir dir( m_lib_path.GetPath() ); if( !dir.IsOpened() ) { THROW_IO_ERROR( wxString::Format( _( "Footprint library '%s' not found." ), m_lib_path.GetPath().GetData() ) ); } wxString fullName; wxString fileSpec = wxT( "*." ) + wxString( FILEEXT::GedaPcbFootprintLibFileExtension ); // wxFileName construction is egregiously slow. Construct it once and just swap out // the filename thereafter. WX_FILENAME fn( m_lib_path.GetPath(), wxT( "dummyName" ) ); if( !dir.GetFirst( &fullName, fileSpec ) ) return; wxString cacheErrorMsg; do { fn.SetFullName( fullName ); // Queue I/O errors so only files that fail to parse don't get loaded. try { // reader now owns fp, will close on exception or return FILE_LINE_READER reader( fn.GetFullPath() ); std::string name = TO_UTF8( fn.GetName() ); FOOTPRINT* footprint = parseFOOTPRINT( &reader ); // The footprint name is the file name without the extension. footprint->SetFPID( LIB_ID( wxEmptyString, fn.GetName() ) ); m_footprints.insert( name, new GPCB_FPL_CACHE_ITEM( footprint, fn ) ); } catch( const IO_ERROR& ioe ) { if( !cacheErrorMsg.IsEmpty() ) cacheErrorMsg += wxT( "\n\n" ); cacheErrorMsg += ioe.What(); } } while( dir.GetNext( &fullName ) ); if( !cacheErrorMsg.IsEmpty() ) THROW_IO_ERROR( cacheErrorMsg ); } void GPCB_FPL_CACHE::Remove( const wxString& aFootprintName ) { std::string footprintName = TO_UTF8( aFootprintName ); FOOTPRINT_MAP::const_iterator it = m_footprints.find( footprintName ); if( it == m_footprints.end() ) { THROW_IO_ERROR( wxString::Format( _( "Library '%s' has no footprint '%s'." ), m_lib_path.GetPath().GetData(), aFootprintName.GetData() ) ); } // Remove the footprint from the cache and delete the footprint file from the library. wxString fullPath = it->second->GetFileName().GetFullPath(); m_footprints.erase( footprintName ); wxRemoveFile( fullPath ); } bool GPCB_FPL_CACHE::IsModified() { m_cache_dirty = m_cache_dirty || GetTimestamp( m_lib_path.GetFullPath() ) != m_cache_timestamp; return m_cache_dirty; } long long GPCB_FPL_CACHE::GetTimestamp( const wxString& aLibPath ) { wxString fileSpec = wxT( "*." ) + wxString( FILEEXT::GedaPcbFootprintLibFileExtension ); return TimestampDir( aLibPath, fileSpec ); } FOOTPRINT* GPCB_FPL_CACHE::parseFOOTPRINT( LINE_READER* aLineReader ) { #define TEXT_DEFAULT_SIZE ( 40*pcbIUScale.IU_PER_MILS ) #define OLD_GPCB_UNIT_CONV pcbIUScale.IU_PER_MILS // Old version unit = 1 mil, so conv_unit is 10 or 0.1 #define NEW_GPCB_UNIT_CONV ( 0.01*pcbIUScale.IU_PER_MILS ) int paramCnt; // GPCB unit = 0.01 mils and Pcbnew 0.1. double conv_unit = NEW_GPCB_UNIT_CONV; VECTOR2I textPos; wxString msg; wxArrayString parameters; std::unique_ptr footprint = std::make_unique( nullptr ); if( aLineReader->ReadLine() == nullptr ) { msg = aLineReader->GetSource() + wxT( ": empty file" ); THROW_IO_ERROR( msg ); } parameters.Clear(); parseParameters( parameters, aLineReader ); paramCnt = parameters.GetCount(); /* From the Geda PCB documentation, valid Element definitions: * Element [SFlags "Desc" "Name" "Value" MX MY TX TY TDir TScale TSFlags] * Element (NFlags "Desc" "Name" "Value" MX MY TX TY TDir TScale TNFlags) * Element (NFlags "Desc" "Name" "Value" TX TY TDir TScale TNFlags) * Element (NFlags "Desc" "Name" TX TY TDir TScale TNFlags) * Element ("Desc" "Name" TX TY TDir TScale TNFlags) */ if( parameters[0].CmpNoCase( wxT( "Element" ) ) != 0 ) { msg.Printf( _( "Unknown token '%s'" ), parameters[0] ); THROW_PARSE_ERROR( msg, aLineReader->GetSource(), (const char *)aLineReader, aLineReader->LineNumber(), 0 ); } if( paramCnt < 10 || paramCnt > 14 ) { msg.Printf( _( "Element token contains %d parameters." ), paramCnt ); THROW_PARSE_ERROR( msg, aLineReader->GetSource(), (const char *)aLineReader, aLineReader->LineNumber(), 0 ); } // Test symbol after "Element": if [ units = 0.01 mils, and if ( units = 1 mil if( parameters[1] == wxT( "(" ) ) conv_unit = OLD_GPCB_UNIT_CONV; if( paramCnt > 10 ) { footprint->SetLibDescription( parameters[3] ); footprint->SetReference( parameters[4] ); } else { footprint->SetLibDescription( parameters[2] ); footprint->SetReference( parameters[3] ); } // Read value if( paramCnt > 10 ) footprint->SetValue( parameters[5] ); // With gEDA/pcb, value is meaningful after instantiation, only, so it's // often empty in bare footprints. if( footprint->Value().GetText().IsEmpty() ) footprint->Value().SetText( wxT( "VAL**" ) ); if( footprint->Reference().GetText().IsEmpty() ) footprint->Reference().SetText( wxT( "REF**" ) ); while( aLineReader->ReadLine() ) { parameters.Clear(); parseParameters( parameters, aLineReader ); if( parameters.IsEmpty() || parameters[0] == wxT( "(" ) ) continue; if( parameters[0] == wxT( ")" ) ) break; paramCnt = parameters.GetCount(); // Test units value for a string line param (more than 3 parameters : ident [ xx ] ) if( paramCnt > 3 ) { if( parameters[1] == wxT( "(" ) ) conv_unit = OLD_GPCB_UNIT_CONV; else conv_unit = NEW_GPCB_UNIT_CONV; } wxLogTrace( traceGedaPcbPlugin, wxT( "%s parameter count = %d." ), parameters[0], paramCnt ); // Parse a line with format: ElementLine [X1 Y1 X2 Y2 Thickness] if( parameters[0].CmpNoCase( wxT( "ElementLine" ) ) == 0 ) { if( paramCnt != 8 ) { msg.Printf( wxT( "ElementLine token contains %d parameters." ), paramCnt ); THROW_PARSE_ERROR( msg, aLineReader->GetSource(), (const char *)aLineReader, aLineReader->LineNumber(), 0 ); } PCB_SHAPE* shape = new PCB_SHAPE( footprint.get(), SHAPE_T::SEGMENT ); shape->SetLayer( F_SilkS ); shape->SetStart( VECTOR2I( parseInt( parameters[2], conv_unit ), parseInt( parameters[3], conv_unit ) ) ); shape->SetEnd( VECTOR2I( parseInt( parameters[4], conv_unit ), parseInt( parameters[5], conv_unit ) ) ); shape->SetStroke( STROKE_PARAMS( parseInt( parameters[6], conv_unit ), LINE_STYLE::SOLID ) ); shape->Rotate( { 0, 0 }, footprint->GetOrientation() ); shape->Move( footprint->GetPosition() ); footprint->Add( shape ); continue; } // Parse an arc with format: ElementArc [X Y Width Height StartAngle DeltaAngle Thickness] if( parameters[0].CmpNoCase( wxT( "ElementArc" ) ) == 0 ) { if( paramCnt != 10 ) { msg.Printf( wxT( "ElementArc token contains %d parameters." ), paramCnt ); THROW_PARSE_ERROR( msg, aLineReader->GetSource(), (const char *)aLineReader, aLineReader->LineNumber(), 0 ); } // Pcbnew does know ellipse so we must have Width = Height PCB_SHAPE* shape = new PCB_SHAPE( footprint.get(), SHAPE_T::ARC ); shape->SetLayer( F_SilkS ); footprint->Add( shape ); // for and arc: ibuf[3] = ibuf[4]. Pcbnew does not know ellipses int radius = ( parseInt( parameters[4], conv_unit ) + parseInt( parameters[5], conv_unit ) ) / 2; VECTOR2I centre( parseInt( parameters[2], conv_unit ), parseInt( parameters[3], conv_unit ) ); // Pcbnew start angles are inverted and 180 degrees from Geda PCB angles. EDA_ANGLE start_angle( (int) parseInt( parameters[6], -10.0 ), TENTHS_OF_A_DEGREE_T ); start_angle += ANGLE_180; // Pcbnew delta angle direction is the opposite of Geda PCB delta angles. EDA_ANGLE sweep_angle( (int) parseInt( parameters[7], -10.0 ), TENTHS_OF_A_DEGREE_T ); // Geda PCB does not support circles. if( sweep_angle == -ANGLE_360 ) { shape->SetShape( SHAPE_T::CIRCLE ); shape->SetCenter( centre ); shape->SetEnd( centre + VECTOR2I( radius, 0 ) ); } else { // Calculate start point coordinate of arc VECTOR2I arcStart( radius, 0 ); RotatePoint( arcStart, -start_angle ); shape->SetCenter( centre ); shape->SetStart( arcStart + centre ); // Angle value is clockwise in gpcb and Pcbnew. shape->SetArcAngleAndEnd( sweep_angle, true ); } shape->SetStroke( STROKE_PARAMS( parseInt( parameters[8], conv_unit ), LINE_STYLE::SOLID ) ); shape->Rotate( { 0, 0 }, footprint->GetOrientation() ); shape->Move( footprint->GetPosition() ); continue; } // Parse a Pad with no hole with format: // Pad [rX1 rY1 rX2 rY2 Thickness Clearance Mask "Name" "Number" SFlags] // Pad (rX1 rY1 rX2 rY2 Thickness Clearance Mask "Name" "Number" NFlags) // Pad (aX1 aY1 aX2 aY2 Thickness "Name" "Number" NFlags) // Pad (aX1 aY1 aX2 aY2 Thickness "Name" NFlags) if( parameters[0].CmpNoCase( wxT( "Pad" ) ) == 0 ) { if( paramCnt < 10 || paramCnt > 13 ) { msg.Printf( wxT( "Pad token contains %d parameters." ), paramCnt ); THROW_PARSE_ERROR( msg, aLineReader->GetSource(), (const char *)aLineReader, aLineReader->LineNumber(), 0 ); } std::unique_ptr pad = std::make_unique( footprint.get() ); static const LSET pad_front( 3, F_Cu, F_Mask, F_Paste ); static const LSET pad_back( 3, B_Cu, B_Mask, B_Paste ); pad->SetShape( PAD_SHAPE::RECTANGLE ); pad->SetAttribute( PAD_ATTRIB::SMD ); pad->SetLayerSet( pad_front ); if( testFlags( parameters[paramCnt-2], 0x0080, wxT( "onsolder" ) ) ) pad->SetLayerSet( pad_back ); // Set the pad name: // Pcbnew pad name is used for electrical connection calculations. // Accordingly it should be mapped to gEDA's pin/pad number, // which is used for the same purpose. // gEDA also features a pin/pad "name", which is an arbitrary string // and set to the pin name of the netlist on instantiation. Many gEDA // bare footprints use identical strings for name and number, so this // can be a bit confusing. pad->SetNumber( parameters[paramCnt-3] ); int x1 = parseInt( parameters[2], conv_unit ); int x2 = parseInt( parameters[4], conv_unit ); int y1 = parseInt( parameters[3], conv_unit ); int y2 = parseInt( parameters[5], conv_unit ); int width = parseInt( parameters[6], conv_unit ); VECTOR2I delta( x2 - x1, y2 - y1 ); double angle = atan2( (double)delta.y, (double)delta.x ); // Get the pad clearance and the solder mask clearance. if( paramCnt == 13 ) { int clearance = parseInt( parameters[7], conv_unit ); // One of gEDA's oddities is that clearance between pad and polygon // is given as the gap on both sides of the pad together, so for // KiCad it has to halfed. pad->SetLocalClearance( clearance / 2 ); // In GEDA, the mask value is the size of the hole in this // solder mask. In Pcbnew, it is a margin, therefore the distance // between the copper and the mask int maskMargin = parseInt( parameters[8], conv_unit ); maskMargin = ( maskMargin - width ) / 2; pad->SetLocalSolderMaskMargin( maskMargin ); } // Negate angle (due to Y reversed axis) EDA_ANGLE orient( -angle, RADIANS_T ); pad->SetOrientation( orient ); VECTOR2I padPos( ( x1 + x2 ) / 2, ( y1 + y2 ) / 2 ); pad->SetSize( VECTOR2I( KiROUND( EuclideanNorm( delta ) ) + width, width ) ); padPos += footprint->GetPosition(); pad->SetPosition( padPos ); if( !testFlags( parameters[paramCnt-2], 0x0100, wxT( "square" ) ) ) { if( pad->GetSize().x == pad->GetSize().y ) pad->SetShape( PAD_SHAPE::CIRCLE ); else pad->SetShape( PAD_SHAPE::OVAL ); } if( pad->GetSizeX() > 0 && pad->GetSizeY() > 0 ) { footprint->Add( pad.release() ); } else { wxLogError( _( "Invalid zero-sized pad ignored in\nfile: %s" ), aLineReader->GetSource() ); } continue; } // Parse a Pin with through hole with format: // Pin [rX rY Thickness Clearance Mask Drill "Name" "Number" SFlags] // Pin (rX rY Thickness Clearance Mask Drill "Name" "Number" NFlags) // Pin (aX aY Thickness Drill "Name" "Number" NFlags) // Pin (aX aY Thickness Drill "Name" NFlags) // Pin (aX aY Thickness "Name" NFlags) if( parameters[0].CmpNoCase( wxT( "Pin" ) ) == 0 ) { if( paramCnt < 8 || paramCnt > 12 ) { msg.Printf( wxT( "Pin token contains %d parameters." ), paramCnt ); THROW_PARSE_ERROR( msg, aLineReader->GetSource(), (const char *)aLineReader, aLineReader->LineNumber(), 0 ); } PAD* pad = new PAD( footprint.get() ); pad->SetShape( PAD_SHAPE::CIRCLE ); static const LSET pad_set = LSET::AllCuMask() | LSET( 3, F_SilkS, F_Mask, B_Mask ); pad->SetLayerSet( pad_set ); if( testFlags( parameters[paramCnt-2], 0x0100, wxT( "square" ) ) ) pad->SetShape( PAD_SHAPE::RECTANGLE ); // Set the pad name: // Pcbnew pad name is used for electrical connection calculations. // Accordingly it should be mapped to gEDA's pin/pad number, // which is used for the same purpose. pad->SetNumber( parameters[paramCnt-3] ); VECTOR2I padPos( parseInt( parameters[2], conv_unit ), parseInt( parameters[3], conv_unit ) ); int padSize = parseInt( parameters[4], conv_unit ); pad->SetSize( VECTOR2I( padSize, padSize ) ); int drillSize = 0; // Get the pad clearance, solder mask clearance, and drill size. if( paramCnt == 12 ) { int clearance = parseInt( parameters[5], conv_unit ); // One of gEDA's oddities is that clearance between pad and polygon // is given as the gap on both sides of the pad together, so for // KiCad it has to halfed. pad->SetLocalClearance( clearance / 2 ); // In GEDA, the mask value is the size of the hole in this // solder mask. In Pcbnew, it is a margin, therefore the distance // between the copper and the mask int maskMargin = parseInt( parameters[6], conv_unit ); maskMargin = ( maskMargin - padSize ) / 2; pad->SetLocalSolderMaskMargin( maskMargin ); drillSize = parseInt( parameters[7], conv_unit ); } else { drillSize = parseInt( parameters[5], conv_unit ); } pad->SetDrillSize( VECTOR2I( drillSize, drillSize ) ); padPos += footprint->GetPosition(); pad->SetPosition( padPos ); if( pad->GetShape() == PAD_SHAPE::CIRCLE && pad->GetSize().x != pad->GetSize().y ) pad->SetShape( PAD_SHAPE::OVAL ); footprint->Add( pad ); continue; } } footprint->AutoPositionFields(); return footprint.release(); } void GPCB_FPL_CACHE::parseParameters( wxArrayString& aParameterList, LINE_READER* aLineReader ) { char key; wxString tmp; char* line = aLineReader->Line(); // Last line already ready in main parser loop. while( *line != 0 ) { key = *line; line++; switch( key ) { case '[': case '(': if( !tmp.IsEmpty() ) { aParameterList.Add( tmp ); tmp.Clear(); } tmp.Append( key ); aParameterList.Add( tmp ); tmp.Clear(); // Opening delimiter "(" after Element statement. Any other occurrence is part // of a keyword definition. if( aParameterList.GetCount() == 1 ) { wxLogTrace( traceGedaPcbPlugin, dump( aParameterList ) ); return; } break; case ']': case ')': if( !tmp.IsEmpty() ) { aParameterList.Add( tmp ); tmp.Clear(); } tmp.Append( key ); aParameterList.Add( tmp ); wxLogTrace( traceGedaPcbPlugin, dump( aParameterList ) ); return; case '\n': case '\r': // Element descriptions can span multiple lines. line = aLineReader->ReadLine(); KI_FALLTHROUGH; case '\t': case ' ': if( !tmp.IsEmpty() ) { aParameterList.Add( tmp ); tmp.Clear(); } break; case '"': // Handle empty quotes. if( *line == '"' ) { line++; tmp.Clear(); aParameterList.Add( wxEmptyString ); break; } while( *line != 0 ) { key = *line; line++; if( key == '"' ) { aParameterList.Add( tmp ); tmp.Clear(); break; } else { tmp.Append( key ); } } break; case '#': line = aLineReader->ReadLine(); break; default: tmp.Append( key ); break; } } } bool GPCB_FPL_CACHE::testFlags( const wxString& aFlag, long aMask, const wxChar* aName ) { wxString number; if( aFlag.StartsWith( wxT( "0x" ), &number ) || aFlag.StartsWith( wxT( "0X" ), &number ) ) { long lflags; if( number.ToLong( &lflags, 16 ) && ( lflags & aMask ) ) return true; } else if( aFlag.Contains( aName ) ) { return true; } return false; } PCB_IO_GEDA::PCB_IO_GEDA() : PCB_IO( wxS( "gEDA PCB" ) ), m_cache( nullptr ), m_ctl( 0 ) { m_reader = nullptr; init( nullptr ); } PCB_IO_GEDA::PCB_IO_GEDA( int aControlFlags ) : PCB_IO( wxS( "gEDA PCB" ) ), m_cache( nullptr ), m_ctl( aControlFlags ) { m_reader = nullptr; init( nullptr ); } PCB_IO_GEDA::~PCB_IO_GEDA() { delete m_cache; } void PCB_IO_GEDA::init( const STRING_UTF8_MAP* aProperties ) { m_props = aProperties; } void PCB_IO_GEDA::validateCache( const wxString& aLibraryPath, bool checkModified ) { if( !m_cache || ( checkModified && m_cache->IsModified() ) ) { // a spectacular episode in memory management: delete m_cache; m_cache = new GPCB_FPL_CACHE( this, aLibraryPath ); m_cache->Load(); } } FOOTPRINT* PCB_IO_GEDA::ImportFootprint( const wxString& aFootprintPath, wxString& aFootprintNameOut, const STRING_UTF8_MAP* aProperties ) { wxFileName fn( aFootprintPath ); FILE_LINE_READER freader( aFootprintPath ); WHITESPACE_FILTER_READER reader( freader ); reader.ReadLine(); char* line = reader.Line(); if( !line ) return nullptr; if( strncasecmp( line, "Element", strlen( "Element" ) ) != 0 ) return nullptr; aFootprintNameOut = fn.GetName(); return FootprintLoad( fn.GetPath(), aFootprintNameOut ); } void PCB_IO_GEDA::FootprintEnumerate( wxArrayString& aFootprintNames, const wxString& aLibraryPath, bool aBestEfforts, const STRING_UTF8_MAP* aProperties ) { LOCALE_IO toggle; // toggles on, then off, the C locale. wxDir dir( aLibraryPath ); wxString errorMsg; if( !dir.IsOpened() ) { if( aBestEfforts ) return; else { THROW_IO_ERROR( wxString::Format( _( "Footprint library '%s' not found." ), aLibraryPath ) ); } } init( aProperties ); try { validateCache( aLibraryPath ); } catch( const IO_ERROR& ioe ) { errorMsg = ioe.What(); } // Some of the files may have been parsed correctly so we want to add the valid files to // the library. for( const auto& footprint : m_cache->GetFootprints() ) aFootprintNames.Add( From_UTF8( footprint.first.c_str() ) ); if( !errorMsg.IsEmpty() && !aBestEfforts ) THROW_IO_ERROR( errorMsg ); } const FOOTPRINT* PCB_IO_GEDA::getFootprint( const wxString& aLibraryPath, const wxString& aFootprintName, const STRING_UTF8_MAP* aProperties, bool checkModified ) { LOCALE_IO toggle; // toggles on, then off, the C locale. init( aProperties ); validateCache( aLibraryPath, checkModified ); const FOOTPRINT_MAP& mods = m_cache->GetFootprints(); FOOTPRINT_MAP::const_iterator it = mods.find( TO_UTF8( aFootprintName ) ); if( it == mods.end() ) return nullptr; return it->second->GetFootprint(); } const FOOTPRINT* PCB_IO_GEDA::GetEnumeratedFootprint( const wxString& aLibraryPath, const wxString& aFootprintName, const STRING_UTF8_MAP* aProperties ) { return getFootprint( aLibraryPath, aFootprintName, aProperties, false ); } FOOTPRINT* PCB_IO_GEDA::FootprintLoad( const wxString& aLibraryPath, const wxString& aFootprintName, bool aKeepUUID, const STRING_UTF8_MAP* aProperties ) { const FOOTPRINT* footprint = getFootprint( aLibraryPath, aFootprintName, aProperties, true ); if( footprint ) { FOOTPRINT* copy = (FOOTPRINT*) footprint->Duplicate(); copy->SetParent( nullptr ); return copy; } return nullptr; } void PCB_IO_GEDA::FootprintDelete( const wxString& aLibraryPath, const wxString& aFootprintName, const STRING_UTF8_MAP* aProperties ) { LOCALE_IO toggle; // toggles on, then off, the C locale. init( aProperties ); validateCache( aLibraryPath ); if( !m_cache->IsWritable() ) { THROW_IO_ERROR( wxString::Format( _( "Library '%s' is read only." ), aLibraryPath.GetData() ) ); } m_cache->Remove( aFootprintName ); } bool PCB_IO_GEDA::DeleteLibrary( const wxString& aLibraryPath, const STRING_UTF8_MAP* aProperties ) { wxFileName fn; fn.SetPath( aLibraryPath ); // Return if there is no library path to delete. if( !fn.DirExists() ) return false; if( !fn.IsDirWritable() ) { THROW_IO_ERROR( wxString::Format( _( "Insufficient permissions to delete folder '%s'." ), aLibraryPath.GetData() ) ); } wxDir dir( aLibraryPath ); if( dir.HasSubDirs() ) { THROW_IO_ERROR( wxString::Format( _( "Library folder '%s' has unexpected sub-folders." ), aLibraryPath.GetData() ) ); } // All the footprint files must be deleted before the directory can be deleted. if( dir.HasFiles() ) { unsigned i; wxFileName tmp; wxArrayString files; wxDir::GetAllFiles( aLibraryPath, &files ); for( i = 0; i < files.GetCount(); i++ ) { tmp = files[i]; if( tmp.GetExt() != FILEEXT::KiCadFootprintFileExtension ) { THROW_IO_ERROR( wxString::Format( _( "Unexpected file '%s' found in library '%s'." ), files[i].GetData(), aLibraryPath.GetData() ) ); } } for( i = 0; i < files.GetCount(); i++ ) { wxRemoveFile( files[i] ); } } wxLogTrace( traceGedaPcbPlugin, wxT( "Removing footprint library '%s'" ), aLibraryPath.GetData() ); // Some of the more elaborate wxRemoveFile() crap puts up its own wxLog dialog // we don't want that. we want bare metal portability with no UI here. if( !wxRmdir( aLibraryPath ) ) { THROW_IO_ERROR( wxString::Format( _( "Footprint library '%s' cannot be deleted." ), aLibraryPath.GetData() ) ); } // For some reason removing a directory in Windows is not immediately updated. This delay // prevents an error when attempting to immediately recreate the same directory when over // writing an existing library. #ifdef __WINDOWS__ wxMilliSleep( 250L ); #endif if( m_cache && m_cache->GetPath() == aLibraryPath ) { delete m_cache; m_cache = nullptr; } return true; } long long PCB_IO_GEDA::GetLibraryTimestamp( const wxString& aLibraryPath ) const { return GPCB_FPL_CACHE::GetTimestamp( aLibraryPath ); } bool PCB_IO_GEDA::IsLibraryWritable( const wxString& aLibraryPath ) { LOCALE_IO toggle; init( nullptr ); validateCache( aLibraryPath ); return m_cache->IsWritable(); }