/* * This program source code file is part of KiCad, a free EDA CAD application. * * Copyright (C) 2020 BeagleBoard Foundation * Copyright (C) 2020-2021 KiCad Developers, see AUTHORS.txt for contributors. * Author: Seth Hillbrand * * 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 3 * of the License, or (at your option) any later version. * * This program is distributed in the hope that it will be useful, * but WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the * GNU General Public License for more details. * * You should have received a copy of the GNU General Public License * along with this program; if not, you may find one here: * http://www.gnu.org/licenses/old-licenses/gpl-2.0.html * or you may search the http://www.gnu.org website for the version 2 license, * or you may write to the Free Software Foundation, Inc., * 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301, USA */ #include "import_fabmaster.h" #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include void FABMASTER::checkpoint() { const unsigned PROGRESS_DELTA = 250; if( m_progressReporter ) { if( ++m_doneCount > m_lastProgressCount + PROGRESS_DELTA ) { m_progressReporter->SetCurrentProgress( ( (double) m_doneCount ) / std::max( 1U, m_totalCount ) ); if( !m_progressReporter->KeepRefreshing() ) THROW_IO_ERROR( ( "Open cancelled by user." ) ); m_lastProgressCount = m_doneCount; } } } double FABMASTER::readDouble( const std::string& aStr ) const { std::istringstream istr( aStr ); istr.imbue( std::locale::classic() ); double doubleValue; istr >> doubleValue; return doubleValue; } int FABMASTER::readInt( const std::string& aStr ) const { std::istringstream istr( aStr ); istr.imbue( std::locale::classic() ); int intValue; istr >> intValue; return intValue; } bool FABMASTER::Read( const std::string& aFile ) { std::ifstream ifs( aFile, std::ios::in | std::ios::binary ); if( !ifs.is_open() ) return false; m_filename = aFile; // Read/ignore all bytes in the file to find the size and then go back to the beginning ifs.ignore( std::numeric_limits::max() ); std::streamsize length = ifs.gcount(); ifs.clear(); ifs.seekg( 0, std::ios_base::beg ); std::string buffer( std::istreambuf_iterator{ ifs }, {} ); std::vector < std::string > row; // Reserve an estimate of the number of rows to prevent continual re-allocation // crashing (Looking at you MSVC) row.reserve( length / 100 ); std::string cell; cell.reserve( 100 ); bool quoted = false; for( auto ch : buffer ) { switch( ch ) { case '"': if( cell.empty() || cell[0] == '"' ) quoted = !quoted; cell += ch; break; case '!': if( !quoted ) { row.push_back( cell ); cell.clear(); } else cell += ch; break; case '\n': /// Rows end with "!" and we don't want to keep the empty cell if( !cell.empty() ) row.push_back( cell ); cell.clear(); rows.push_back( row ); row.clear(); quoted = false; break; case '\r': break; default: cell += std::toupper( ch ); } } // Handle last line without linebreak if( !cell.empty() || !row.empty() ) { row.push_back( cell ); cell.clear(); rows.push_back( row ); row.clear(); } return true; } FABMASTER::section_type FABMASTER::detectType( size_t aOffset ) { single_row row; try { row = rows.at( aOffset ); } catch( std::out_of_range& ) { return UNKNOWN_EXTRACT; } if( row.size() < 3 ) return UNKNOWN_EXTRACT; if( row[0].back() != 'A' ) return UNKNOWN_EXTRACT; std::string row1 = row[1]; std::string row2 = row[2]; std::string row3{}; /// We strip the underscores from all column names as some export variants use them and some do not row1.erase( std::remove_if( row1.begin(), row1.end(), []( char c ){ return c == '_'; } ), row1.end() ); row2.erase( std::remove_if( row2.begin(), row2.end(), []( char c ){ return c == '_'; } ), row2.end() ); if( row.size() > 3 ) { row3 = row[3]; row3.erase( std::remove_if( row3.begin(), row3.end(), []( char c ){ return c == '_'; } ), row3.end() ); } if( row1 == "REFDES" && row2 == "COMPCLASS" ) return EXTRACT_REFDES; if( row1 == "NETNAME" && row2 == "REFDES" ) return EXTRACT_NETS; if( row1 == "CLASS" && row2 == "SUBCLASS" && row3.empty() ) return EXTRACT_BASIC_LAYERS; if( row1 == "GRAPHICDATANAME" && row2 == "GRAPHICDATANUMBER" ) return EXTRACT_GRAPHICS; if( row1 == "CLASS" && row2 == "SUBCLASS" && row3 == "GRAPHICDATANAME" ) return EXTRACT_TRACES; if( row1 == "SYMNAME" && row2 == "PINNAME" ) return FABMASTER_EXTRACT_PINS; if( row1 == "SYMNAME" && row2 == "SYMMIRROR" && row3 == "PINNAME" ) return EXTRACT_PINS; if( row1 == "VIAX" && row2 == "VIAY" ) return EXTRACT_VIAS; if( row1 == "SUBCLASS" && row2 == "PADSHAPENAME" ) return EXTRACT_PAD_SHAPES; if( row1 == "PADNAME" ) return EXTRACT_PADSTACKS; if( row1 == "LAYERSORT" ) return EXTRACT_FULL_LAYERS; wxLogError( _( "Unknown FABMASTER section %s:%s at row %zu." ), row1.c_str(), row2.c_str(), aOffset ); return UNKNOWN_EXTRACT; } double FABMASTER::processScaleFactor( size_t aRow ) { double retval = 0.0; if( aRow >= rows.size() ) return -1.0; if( rows[aRow].size() < 11 ) { wxLogError( _( "Invalid row size in J row %zu. Expecting 11 elements but found %zu." ), aRow, rows[aRow].size() ); return -1.0; } for( int i = 7; i < 10 && retval < 1.0; ++i ) { auto units = rows[aRow][i]; std::transform(units.begin(), units.end(),units.begin(), ::toupper); if( units == "MILS" ) retval = IU_PER_MILS; else if( units == "MILLIMETERS" ) retval = IU_PER_MM; else if( units == "MICRONS" ) retval = IU_PER_MM * 10.0; else if( units == "INCHES" ) retval = IU_PER_MILS * 1000.0; } if( retval < 1.0 ) { wxLogError( _( "Could not find units value, defaulting to mils." ) ); retval = IU_PER_MILS; } return retval; } int FABMASTER::getColFromName( size_t aRow, const std::string& aStr ) { if( aRow >= rows.size() ) return -1; auto header = rows[aRow]; for( size_t i = 0; i < header.size(); i++ ) { /// Some Fabmaster headers include the underscores while others do not /// so we strip them uniformly before comparing header[i].erase( std::remove_if( header[i].begin(), header[i].end(), []( const char c ){ return c == '_'; } ), header[i].end() ); if( header[i] == aStr ) return i; } THROW_IO_ERROR( wxString::Format( _( "Could not find column label %s." ), aStr.c_str() ) ); return -1; } PCB_LAYER_ID FABMASTER::getLayer( const std::string& aLayerName ) { const auto& kicad_layer = layers.find( aLayerName); if( kicad_layer == layers.end() ) return UNDEFINED_LAYER; else return static_cast( kicad_layer->second.layerid ); } size_t FABMASTER::processPadStackLayers( size_t aRow ) { size_t rownum = aRow + 2; if( rownum >= rows.size() ) return -1; const single_row& header = rows[aRow]; int pad_name_col = getColFromName( aRow, "PADNAME" ); int pad_num_col = getColFromName( aRow, "RECNUMBER" ); int pad_lay_col = getColFromName( aRow, "LAYER" ); int pad_fix_col = getColFromName( aRow, "FIXFLAG" ); int pad_via_col = getColFromName( aRow, "VIAFLAG" ); int pad_shape_col = getColFromName( aRow, "PADSHAPE1" ); int pad_width_col = getColFromName( aRow, "PADWIDTH" ); int pad_height_col = getColFromName( aRow, "PADHGHT" ); int pad_xoff_col = getColFromName( aRow, "PADXOFF" ); int pad_yoff_col = getColFromName( aRow, "PADYOFF" ); int pad_flash_col = getColFromName( aRow, "PADFLASH" ); int pad_shape_name_col = getColFromName( aRow, "PADSHAPENAME" ); for( ; rownum < rows.size() && rows[rownum].size() > 0 && rows[rownum][0] == "S"; ++rownum ) { const single_row& row = rows[rownum]; if( row.size() != header.size() ) { wxLogError( _( "Invalid row size in row %zu. Expecting %zu elements but found %zu." ), rownum, header.size(), row.size() ); continue; } auto pad_name = row[pad_name_col]; auto pad_num = row[pad_num_col]; auto pad_layer = row[pad_lay_col]; auto pad_is_fixed = row[pad_fix_col]; auto pad_is_via = row[pad_via_col]; auto pad_shape = row[pad_shape_col]; auto pad_width = row[pad_width_col]; auto pad_height = row[pad_height_col]; auto pad_xoff = row[pad_xoff_col]; auto pad_yoff = row[pad_yoff_col]; auto pad_flash = row[pad_flash_col]; auto pad_shapename = row[pad_shape_name_col]; // This layer setting seems to be unused if( pad_layer == "INTERNAL_PAD_DEF" || pad_layer == "internal_pad_def" ) continue; // Skip the technical layers if( pad_layer[0] == '~' ) break; auto result = layers.emplace( pad_layer, FABMASTER_LAYER{} ); FABMASTER_LAYER& layer = result.first->second; /// If the layer ids have not yet been assigned if( layer.id == 0 ) { layer.name = pad_layer; layer.id = readInt( pad_num ); layer.conductive = true; } } return 0; } /** * A!PADNAME!RECNUMBER!LAYER!FIXFLAG!VIAFLAG!PADSHAPE1!PADWIDTH!PADHGHT! * PADXOFF!PADYOFF!PADFLASH!PADSHAPENAME!TRELSHAPE1!TRELWIDTH!TRELHGHT! * TRELXOFF!TRELYOFF!TRELFLASH!TRELSHAPENAME!APADSHAPE1!APADWIDTH!APADHGHT! * APADXOFF!APADYOFF!APADFLASH!APADSHAPENAME! */ size_t FABMASTER::processPadStacks( size_t aRow ) { size_t rownum = aRow + 2; if( rownum >= rows.size() ) return -1; const single_row& header = rows[aRow]; double scale_factor = processScaleFactor( aRow + 1 ); if( scale_factor <= 0.0 ) return -1; int pad_name_col = getColFromName( aRow, "PADNAME" ); int pad_num_col = getColFromName( aRow, "RECNUMBER" ); int pad_lay_col = getColFromName( aRow, "LAYER" ); int pad_fix_col = getColFromName( aRow, "FIXFLAG" ); int pad_via_col = getColFromName( aRow, "VIAFLAG" ); int pad_shape_col = getColFromName( aRow, "PADSHAPE1" ); int pad_width_col = getColFromName( aRow, "PADWIDTH" ); int pad_height_col = getColFromName( aRow, "PADHGHT" ); int pad_xoff_col = getColFromName( aRow, "PADXOFF" ); int pad_yoff_col = getColFromName( aRow, "PADYOFF" ); int pad_flash_col = getColFromName( aRow, "PADFLASH" ); int pad_shape_name_col = getColFromName( aRow, "PADSHAPENAME" ); for( ; rownum < rows.size() && rows[rownum].size() > 0 && rows[rownum][0] == "S"; ++rownum ) { const single_row& row = rows[rownum]; FM_PAD* pad; if( row.size() != header.size() ) { wxLogError( _( "Invalid row size in row %zu. Expecting %zu elements but found %zu." ), rownum, header.size(), row.size() ); continue; } auto pad_name = row[pad_name_col]; auto pad_num = row[pad_num_col]; auto pad_layer = row[pad_lay_col]; auto pad_is_fixed = row[pad_fix_col]; auto pad_is_via = row[pad_via_col]; auto pad_shape = row[pad_shape_col]; auto pad_width = row[pad_width_col]; auto pad_height = row[pad_height_col]; auto pad_xoff = row[pad_xoff_col]; auto pad_yoff = row[pad_yoff_col]; auto pad_flash = row[pad_flash_col]; auto pad_shapename = row[pad_shape_name_col]; // This layer setting seems to be unused if( pad_layer == "INTERNAL_PAD_DEF" || pad_layer == "internal_pad_def" ) continue; int recnum = KiROUND( readDouble( pad_num ) ); auto new_pad = pads.find( pad_name ); if( new_pad != pads.end() ) pad = &new_pad->second; else { pads[pad_name] = FM_PAD(); pad = &pads[pad_name]; pad->name = pad_name; } /// Handle the drill layer if( pad_layer == "~DRILL" ) { int drill_hit; int drill_x; int drill_y; try { drill_hit = KiROUND( std::fabs( readDouble( pad_shape ) * scale_factor ) ); drill_x = KiROUND( std::fabs( readDouble( pad_width ) * scale_factor ) ); drill_y = KiROUND( std::fabs( readDouble( pad_height ) * scale_factor ) ); } catch( ... ) { wxLogError( _( "Expecting drill size value but found %s!%s!%s in row %zu." ), pad_shape.c_str(), pad_width.c_str(), pad_height.c_str(), rownum ); continue; } if( drill_hit == 0 ) { pad->drill = false; continue; } pad->drill = true; /// This is to account for broken fabmaster outputs where circle drill hits don't actually get the /// drill hit value. if( drill_x == drill_y ) { pad->drill_size_x = drill_hit; pad->drill_size_y = drill_hit; } else { pad->drill_size_x = drill_x; pad->drill_size_y = drill_y; } if( !pad_shapename.empty() && pad_shapename[0] == 'P' ) pad->plated = true; continue; } if( pad_shape.empty() ) continue; double w; double h; try { w = readDouble( pad_width ) * scale_factor; h = readDouble( pad_height ) * scale_factor; } catch( ... ) { wxLogError( _( "Expecting pad size values but found %s : %s in row %zu." ), pad_width.c_str(), pad_height.c_str(), rownum ); continue; } if( w <= 0.0 ) continue; auto layer = layers.find( pad_layer ); if( layer != layers.end() ) { if( layer->second.layerid == F_Cu ) pad->top = true; else if( layer->second.layerid == B_Cu ) pad->bottom = true; } if( w > std::numeric_limits::max() || h > std::numeric_limits::max() ) { wxLogError( _( "Invalid pad size in row %zu." ), rownum ); continue; } if( pad_layer == "~TSM" || pad_layer == "~BSM" ) { if( w > 0.0 && h > 0.0 ) { pad->mask_width = KiROUND( w ); pad->mask_height = KiROUND( h ); } continue; } if( pad_layer == "~TSP" || pad_layer == "~BSP" ) { if( w > 0.0 && h > 0.0 ) { pad->paste_width = KiROUND( w ); pad->paste_height = KiROUND( h ); } continue; } /// All remaining technical layers are not handled if( pad_layer[0] == '~' ) continue; try { pad->x_offset = KiROUND( readDouble( pad_xoff ) * scale_factor ); pad->y_offset = -KiROUND( readDouble( pad_yoff ) * scale_factor ); } catch( ... ) { wxLogError( _( "Expecting pad offset values but found %s:%s in row %zu." ), pad_xoff.c_str(), pad_yoff.c_str(), rownum ); continue; } if( w > 0.0 && h > 0.0 && recnum == 1 ) { pad->width = KiROUND( w ); pad->height = KiROUND( h ); pad->via = ( std::toupper( pad_is_via[0] ) != 'V' ); if( pad_shape == "CIRCLE" ) { pad->height = pad->width; pad->shape = PAD_SHAPE::CIRCLE; } else if( pad_shape == "RECTANGLE" ) { pad->shape = PAD_SHAPE::RECT; } else if( pad_shape == "ROUNDED_RECT" ) { pad->shape = PAD_SHAPE::ROUNDRECT; } else if( pad_shape == "SQUARE" ) { pad->shape = PAD_SHAPE::RECT; pad->height = pad->width; } else if( pad_shape == "OBLONG" || pad_shape == "OBLONG_X" || pad_shape == "OBLONG_Y" ) pad->shape = PAD_SHAPE::OVAL; else if( pad_shape == "OCTAGON" ) { pad->shape = PAD_SHAPE::RECT; pad->is_octogon = true; } else if( pad_shape == "SHAPE" ) { pad->shape = PAD_SHAPE::CUSTOM; pad->custom_name = pad_shapename; } else { wxLogError( _( "Unknown pad shape name '%s' on layer '%s' in row %zu." ), pad_shape.c_str(), pad_layer.c_str(), rownum ); continue; } } } return rownum - aRow; } size_t FABMASTER::processSimpleLayers( size_t aRow ) { size_t rownum = aRow + 2; if( rownum >= rows.size() ) return -1; auto header = rows[aRow]; double scale_factor = processScaleFactor( aRow + 1 ); if( scale_factor <= 0.0 ) return -1; int layer_class_col = getColFromName( aRow, "CLASS" ); int layer_subclass_col = getColFromName( aRow, "SUBCLASS" ); if( layer_class_col < 0 || layer_subclass_col < 0 ) return -1; for( ; rownum < rows.size() && rows[rownum].size() > 0 && rows[rownum][0] == "S"; ++rownum ) { const single_row& row = rows[rownum]; if( row.size() != header.size() ) { wxLogError( _( "Invalid row size in row %zu. Expecting %zu elements but found %zu." ), rownum, header.size(), row.size() ); continue; } auto result = layers.emplace( row[layer_subclass_col], FABMASTER_LAYER{} ); FABMASTER_LAYER& layer = result.first->second; layer.name = row[layer_subclass_col]; layer.positive = true; layer.conductive = false; if( row[layer_class_col] == "ANTI ETCH" ) { layer.positive = false; layer.conductive = true; } else if( row[layer_class_col] == "ETCH" ) { layer.conductive = true; } } return rownum - aRow; } bool FABMASTER::assignLayers() { bool has_l1 = false; int max_layer = 0; std::string max_layer_name; std::vector> extra_layers { { "ASSEMBLY_TOP", F_Fab }, { "ASSEMBLY_BOTTOM", B_Fab }, { "PLACE_BOUND_TOP", F_CrtYd }, { "PLACE_BOUND_BOTTOM", B_CrtYd }, }; std::vector layer_order; for( auto& el : layers ) { FABMASTER_LAYER& layer = el.second; layer.layerid = UNSELECTED_LAYER; if( layer.conductive ) { layer_order.push_back( &layer ); } else if( layer.name.find( "SILK" ) != std::string::npos && layer.name.find( "AUTOSILK" ) == std::string::npos ) // Skip the autosilk layer { if( layer.name.find( "B" ) != std::string::npos ) layer.layerid = B_SilkS; else layer.layerid = F_SilkS; } else if( layer.name.find( "MASK" ) != std::string::npos || layer.name.find( "MSK" ) != std::string::npos ) { if( layer.name.find( "B" ) != std::string::npos ) layer.layerid = B_Mask; else layer.layerid = F_Mask; } else if( layer.name.find( "PAST" ) != std::string::npos ) { if( layer.name.find( "B" ) != std::string::npos ) layer.layerid = B_Paste; else layer.layerid = F_Paste; } else if( layer.name.find( "NCLEGEND" ) != std::string::npos ) layer.layerid = Dwgs_User; else layer.disable = true; } std::sort( layer_order.begin(), layer_order.end(), FABMASTER_LAYER::BY_ID() ); int layernum = 0; for( auto layer : layer_order ) layer->layerid = layernum++; /// Back copper has a special id number, so assign that to the last copper layer /// in the stackup layer_order.back()->layerid = B_Cu; for( auto& new_pair : extra_layers ) { FABMASTER_LAYER new_layer; new_layer.name = new_pair.first; new_layer.layerid = new_pair.second; new_layer.conductive = false; auto result = layers.emplace( new_pair.first, new_layer ); if( !result.second ) { result.first->second.layerid = new_pair.second; result.first->second.disable = false; } } return true; } /** * A!LAYER_SORT!LAYER_SUBCLASS!LAYER_ARTWORK!LAYER_USE!LAYER_CONDUCTOR!LAYER_DIELECTRIC_CONSTANT! * LAYER_ELECTRICAL_CONDUCTIVITY!LAYER_MATERIAL!LAYER_SHIELD_LAYER!LAYER_THERMAL_CONDUCTIVITY! * LAYER_THICKNESS! */ size_t FABMASTER::processLayers( size_t aRow ) { size_t rownum = aRow + 2; if( rownum >= rows.size() ) return -1; auto header = rows[aRow]; double scale_factor = processScaleFactor( aRow + 1 ); if( scale_factor <= 0.0 ) return -1; int layer_sort_col = getColFromName( aRow, "LAYERSORT" ); int layer_subclass_col = getColFromName( aRow, "LAYERSUBCLASS" ); int layer_art_col = getColFromName( aRow, "LAYERARTWORK" ); int layer_use_col = getColFromName( aRow, "LAYERUSE" ); int layer_cond_col = getColFromName( aRow, "LAYERCONDUCTOR" ); int layer_er_col = getColFromName( aRow, "LAYERDIELECTRICCONSTANT" ); int layer_rho_col = getColFromName( aRow, "LAYERELECTRICALCONDUCTIVITY" ); int layer_mat_col = getColFromName( aRow, "LAYERMATERIAL" ); if( layer_sort_col < 0 || layer_subclass_col < 0 || layer_art_col < 0 || layer_use_col < 0 || layer_cond_col < 0 || layer_er_col < 0 || layer_rho_col < 0 || layer_mat_col < 0 ) return -1; for( ; rownum < rows.size() && rows[rownum].size() > 0 && rows[rownum][0] == "S"; ++rownum ) { const single_row& row = rows[rownum]; if( row.size() != header.size() ) { wxLogError( _( "Invalid row size in row %zu. Expecting %zu elements but found %zu." ), rownum, header.size(), row.size() ); continue; } auto layer_sort = row[layer_sort_col]; auto layer_subclass = row[layer_subclass_col]; auto layer_art = row[layer_art_col]; auto layer_use = row[layer_use_col]; auto layer_cond = row[layer_cond_col]; auto layer_er = row[layer_er_col]; auto layer_rho = row[layer_rho_col]; auto layer_mat = row[layer_mat_col]; if( layer_mat == "AIR" ) continue; FABMASTER_LAYER layer; if( layer_subclass.empty() ) { if( layer_cond != "NO" ) layer.name = "In.Cu" + layer_sort; else layer.name = "Dielectric" + layer_sort; } layer.positive = ( layer_art != "NEGATIVE" ); layers.emplace( layer.name, layer ); } return rownum - aRow; } /** * A!SUBCLASS!PAD_SHAPE_NAME!GRAPHIC_DATA_NAME!GRAPHIC_DATA_NUMBER!RECORD_TAG!GRAPHIC_DATA_1! * GRAPHIC_DATA_2!GRAPHIC_DATA_3!GRAPHIC_DATA_4!GRAPHIC_DATA_5!GRAPHIC_DATA_6!GRAPHIC_DATA_7! * GRAPHIC_DATA_8!GRAPHIC_DATA_9!PAD_STACK_NAME!REFDES!PIN_NUMBER! */ size_t FABMASTER::processCustomPads( size_t aRow ) { size_t rownum = aRow + 2; if( rownum >= rows.size() ) return -1; auto header = rows[aRow]; double scale_factor = processScaleFactor( aRow + 1 ); if( scale_factor <= 0.0 ) return -1; int pad_subclass_col = getColFromName( aRow, "SUBCLASS" ); int pad_shape_name_col = getColFromName( aRow, "PADSHAPENAME" ); int pad_grdata_name_col = getColFromName( aRow, "GRAPHICDATANAME" ); int pad_grdata_num_col = getColFromName( aRow, "GRAPHICDATANUMBER" ); int pad_record_tag_col = getColFromName( aRow, "RECORDTAG" ); int pad_grdata1_col = getColFromName( aRow, "GRAPHICDATA1" ); int pad_grdata2_col = getColFromName( aRow, "GRAPHICDATA2" ); int pad_grdata3_col = getColFromName( aRow, "GRAPHICDATA3" ); int pad_grdata4_col = getColFromName( aRow, "GRAPHICDATA4" ); int pad_grdata5_col = getColFromName( aRow, "GRAPHICDATA5" ); int pad_grdata6_col = getColFromName( aRow, "GRAPHICDATA6" ); int pad_grdata7_col = getColFromName( aRow, "GRAPHICDATA7" ); int pad_grdata8_col = getColFromName( aRow, "GRAPHICDATA8" ); int pad_grdata9_col = getColFromName( aRow, "GRAPHICDATA9" ); int pad_stack_name_col = getColFromName( aRow, "PADSTACKNAME" ); int pad_refdes_col = getColFromName( aRow, "REFDES" ); int pad_pin_num_col = getColFromName( aRow, "PINNUMBER" ); if( pad_subclass_col < 0 || pad_shape_name_col < 0 || pad_grdata1_col < 0 || pad_grdata2_col < 0 || pad_grdata3_col < 0 || pad_grdata4_col < 0 || pad_grdata5_col < 0 || pad_grdata6_col < 0 || pad_grdata7_col < 0 || pad_grdata8_col < 0 || pad_grdata9_col < 0 || pad_stack_name_col < 0 || pad_refdes_col < 0 || pad_pin_num_col < 0 ) return -1; for( ; rownum < rows.size() && rows[rownum].size() > 0 && rows[rownum][0] == "S"; ++rownum ) { const single_row& row = rows[rownum]; if( row.size() != header.size() ) { wxLogError( _( "Invalid row size in row %zu. Expecting %zu elements but found %zu." ), rownum, header.size(), row.size() ); continue; } auto pad_layer = row[pad_subclass_col]; auto pad_shape_name = row[pad_shape_name_col]; auto pad_record_tag = row[pad_record_tag_col]; GRAPHIC_DATA gr_data; gr_data.graphic_dataname = row[pad_grdata_name_col]; gr_data.graphic_datanum = row[pad_grdata_num_col]; gr_data.graphic_data1 = row[pad_grdata1_col]; gr_data.graphic_data2 = row[pad_grdata2_col]; gr_data.graphic_data3 = row[pad_grdata3_col]; gr_data.graphic_data4 = row[pad_grdata4_col]; gr_data.graphic_data5 = row[pad_grdata5_col]; gr_data.graphic_data6 = row[pad_grdata6_col]; gr_data.graphic_data7 = row[pad_grdata7_col]; gr_data.graphic_data8 = row[pad_grdata8_col]; gr_data.graphic_data9 = row[pad_grdata9_col]; auto pad_stack_name = row[pad_stack_name_col]; auto pad_refdes = row[pad_refdes_col]; auto pad_pin_num = row[pad_pin_num_col]; // N.B. We get the FIGSHAPE records as "FIG_SHAPE name". We only want "name" // and we don't process other pad shape records std::string prefix( "FIG_SHAPE " ); if( pad_shape_name.length() <= prefix.length() || !std::equal( prefix.begin(), prefix.end(), pad_shape_name.begin() ) ) { continue; } // Custom pads are a series of records with the same record ID but incrementing // Sequence numbers. int id = -1; int seq = -1; if( std::sscanf( pad_record_tag.c_str(), "%d %d", &id, &seq ) != 2 ) { wxLogError( _( "Invalid format for id string '%s' in custom pad row %zu." ), pad_record_tag.c_str(), rownum ); continue; } auto name = pad_shape_name.substr( prefix.length() ); name += "_" + pad_refdes + "_" + pad_pin_num; auto ret = pad_shapes.emplace( name, FABMASTER_PAD_SHAPE{} ); auto& custom_pad = ret.first->second; // If we were able to insert the pad name, then we need to initialize the // record if( ret.second ) { custom_pad.name = name; custom_pad.padstack = pad_stack_name; custom_pad.pinnum = pad_pin_num; custom_pad.refdes = pad_refdes; } // At this point we extract the individual graphical elements for processing the complex pad. The // coordinates are in board origin format, so we'll need to fix the offset later when we assign them // to the modules. auto gr_item = std::unique_ptr( processGraphic( gr_data, scale_factor ) ); if( gr_item ) { gr_item->layer = pad_layer; gr_item->refdes = pad_refdes; gr_item->seq = seq; gr_item->subseq = 0; /// emplace may fail here, in which case, it returns the correct position to use for the existing map auto pad_it = custom_pad.elements.emplace( id, graphic_element{} ); auto retval = pad_it.first->second.insert( std::move(gr_item ) ); if( !retval.second ) { wxLogError( _( "Could not insert graphical item %d into padstack '%s'." ), seq, pad_stack_name.c_str() ); } } else { wxLogError( _( "Unrecognized pad shape primitive '%s' in row %zu." ), gr_data.graphic_dataname, rownum ); } } return rownum - aRow; } FABMASTER::GRAPHIC_LINE* FABMASTER::processLine( const FABMASTER::GRAPHIC_DATA& aData, double aScale ) { GRAPHIC_LINE* new_line = new GRAPHIC_LINE ; new_line->shape = GR_SHAPE_LINE; new_line->start_x = KiROUND( readDouble( aData.graphic_data1 ) * aScale ); new_line->start_y = -KiROUND( readDouble( aData.graphic_data2 ) * aScale ); new_line->end_x = KiROUND( readDouble( aData.graphic_data3 ) * aScale ); new_line->end_y = -KiROUND( readDouble( aData.graphic_data4 ) * aScale ); new_line->width = KiROUND( readDouble( aData.graphic_data5 ) * aScale ); return new_line; } FABMASTER::GRAPHIC_ARC* FABMASTER::processArc( const FABMASTER::GRAPHIC_DATA& aData, double aScale ) { GRAPHIC_ARC* new_arc = new GRAPHIC_ARC ; new_arc->shape = GR_SHAPE_ARC; new_arc->start_x = KiROUND( readDouble( aData.graphic_data1 ) * aScale ); new_arc->start_y = -KiROUND( readDouble( aData.graphic_data2 ) * aScale ); new_arc->end_x = KiROUND( readDouble( aData.graphic_data3 ) * aScale ); new_arc->end_y = -KiROUND( readDouble( aData.graphic_data4 ) * aScale ); new_arc->center_x = KiROUND( readDouble( aData.graphic_data5 ) * aScale ); new_arc->center_y = -KiROUND( readDouble( aData.graphic_data6 ) * aScale ); new_arc->radius = KiROUND( readDouble( aData.graphic_data7 ) * aScale ); new_arc->width = KiROUND( readDouble( aData.graphic_data8 ) * aScale ); new_arc->clockwise = ( aData.graphic_data9 != "COUNTERCLOCKWISE" ); double startangle = NormalizeAnglePos( RAD2DECIDEG( atan2( new_arc->start_y - new_arc->center_y, new_arc->start_x - new_arc->center_x ) ) ); double endangle = NormalizeAnglePos( RAD2DECIDEG( atan2( new_arc->end_y - new_arc->center_y, new_arc->end_x - new_arc->center_x ) ) ); double angle; VECTOR2I center( new_arc->center_x, new_arc->center_y ); VECTOR2I start( new_arc->start_x, new_arc->start_y ); VECTOR2I mid( new_arc->start_x, new_arc->start_y ); VECTOR2I end( new_arc->end_x, new_arc->end_y ); angle = endangle - startangle; if( new_arc->clockwise && angle < 0.0 ) angle += 3600.0; if( !new_arc->clockwise && angle > 0.0 ) angle -= 3600.0; if( start == end ) angle = -3600.0; RotatePoint( mid, center, -angle / 2.0 ); new_arc->result = SHAPE_ARC( start, mid, end, 0 ); return new_arc; } FABMASTER::GRAPHIC_RECTANGLE* FABMASTER::processRectangle( const FABMASTER::GRAPHIC_DATA& aData, double aScale ) { GRAPHIC_RECTANGLE* new_rect = new GRAPHIC_RECTANGLE; new_rect->shape = GR_SHAPE_RECTANGLE; new_rect->start_x = KiROUND( readDouble( aData.graphic_data1 ) * aScale ); new_rect->start_y = -KiROUND( readDouble( aData.graphic_data2 ) * aScale ); new_rect->end_x = KiROUND( readDouble( aData.graphic_data3 ) * aScale ); new_rect->end_y = -KiROUND( readDouble( aData.graphic_data4 ) * aScale ); new_rect->fill = aData.graphic_data5 == "1"; new_rect->width = 0; return new_rect; } FABMASTER::GRAPHIC_TEXT* FABMASTER::processText( const FABMASTER::GRAPHIC_DATA& aData, double aScale ) { GRAPHIC_TEXT* new_text = new GRAPHIC_TEXT; new_text->shape = GR_SHAPE_TEXT; new_text->start_x = KiROUND( readDouble( aData.graphic_data1 ) * aScale ); new_text->start_y = -KiROUND( readDouble( aData.graphic_data2 ) * aScale ); new_text->rotation = KiROUND( readDouble( aData.graphic_data3 ) ); new_text->mirror = ( aData.graphic_data4 == "YES" ); if( aData.graphic_data5 == "RIGHT" ) new_text->orient = GR_TEXT_HJUSTIFY_RIGHT; else if( aData.graphic_data5 == "CENTER" ) new_text->orient = GR_TEXT_HJUSTIFY_CENTER; else new_text->orient = GR_TEXT_HJUSTIFY_LEFT; std::vector toks = split( aData.graphic_data6, " \t" ); if( toks.size() < 8 ) { // We log the error here but continue in the case of too few tokens wxLogError( _( "Invalid token count. Expected 8 but found %zu." ), toks.size() ); new_text->height = 0; new_text->width = 0; new_text->ital = false; new_text->thickness = 0; } else { // 0 = size // 1 = font new_text->height = KiROUND( readDouble( toks[2] ) * aScale ); new_text->width = KiROUND( readDouble( toks[3] ) * aScale ); new_text->ital = readDouble( toks[4] ) != 0.0; // 5 = character spacing // 6 = line spacing new_text->thickness = KiROUND( readDouble( toks[7] ) * aScale ); } new_text->text = aData.graphic_data7; return new_text; } FABMASTER::GRAPHIC_ITEM* FABMASTER::processGraphic( const GRAPHIC_DATA& aData, double aScale ) { GRAPHIC_ITEM* retval = nullptr; if( aData.graphic_dataname == "LINE" ) retval = processLine( aData, aScale ); else if( aData.graphic_dataname == "ARC" ) retval = processArc( aData, aScale ); else if( aData.graphic_dataname == "RECTANGLE" ) retval = processRectangle( aData, aScale ); else if( aData.graphic_dataname == "TEXT" ) retval = processText( aData, aScale ); if( retval && !aData.graphic_data10.empty() ) { if( aData.graphic_data10 == "CONNECT" ) retval->type = GR_TYPE_CONNECT; else if( aData.graphic_data10 == "NOTCONNECT" ) retval->type = GR_TYPE_NOTCONNECT; else if( aData.graphic_data10 == "SHAPE" ) retval->type = GR_TYPE_NOTCONNECT; else if( aData.graphic_data10 == "VOID" ) retval->type = GR_TYPE_NOTCONNECT; else if( aData.graphic_data10 == "POLYGON" ) retval->type = GR_TYPE_NOTCONNECT; else retval->type = GR_TYPE_NONE; } return retval; } /** * A!GRAPHIC_DATA_NAME!GRAPHIC_DATA_NUMBER!RECORD_TAG!GRAPHIC_DATA_1!GRAPHIC_DATA_2!GRAPHIC_DATA_3! * GRAPHIC_DATA_4!GRAPHIC_DATA_5!GRAPHIC_DATA_6!GRAPHIC_DATA_7!GRAPHIC_DATA_8!GRAPHIC_DATA_9! * SUBCLASS!SYM_NAME!REFDES! */ size_t FABMASTER::processGeometry( size_t aRow ) { size_t rownum = aRow + 2; if( rownum >= rows.size() ) return -1; const single_row& header = rows[aRow]; double scale_factor = processScaleFactor( aRow + 1 ); if( scale_factor <= 0.0 ) return -1; int geo_name_col = getColFromName( aRow, "GRAPHICDATANAME" ); int geo_num_col = getColFromName( aRow, "GRAPHICDATANUMBER" ); int geo_tag_col = getColFromName( aRow, "RECORDTAG" ); int geo_grdata1_col = getColFromName( aRow, "GRAPHICDATA1" ); int geo_grdata2_col = getColFromName( aRow, "GRAPHICDATA2" ); int geo_grdata3_col = getColFromName( aRow, "GRAPHICDATA3" ); int geo_grdata4_col = getColFromName( aRow, "GRAPHICDATA4" ); int geo_grdata5_col = getColFromName( aRow, "GRAPHICDATA5" ); int geo_grdata6_col = getColFromName( aRow, "GRAPHICDATA6" ); int geo_grdata7_col = getColFromName( aRow, "GRAPHICDATA7" ); int geo_grdata8_col = getColFromName( aRow, "GRAPHICDATA8" ); int geo_grdata9_col = getColFromName( aRow, "GRAPHICDATA9" ); int geo_subclass_col = getColFromName( aRow, "SUBCLASS" ); int geo_sym_name_col = getColFromName( aRow, "SYMNAME" ); int geo_refdes_col = getColFromName( aRow, "REFDES" ); if( geo_name_col < 0 || geo_num_col < 0 || geo_grdata1_col < 0 || geo_grdata2_col < 0 || geo_grdata3_col < 0 || geo_grdata4_col < 0 || geo_grdata5_col < 0 || geo_grdata6_col < 0 || geo_grdata7_col < 0 || geo_grdata8_col < 0 || geo_grdata9_col < 0 || geo_subclass_col < 0 || geo_sym_name_col < 0 || geo_refdes_col < 0 ) return -1; for( ; rownum < rows.size() && rows[rownum].size() > 0 && rows[rownum][0] == "S"; ++rownum ) { const single_row& row = rows[rownum]; if( row.size() != header.size() ) { wxLogError( _( "Invalid row size in row %zu. Expecting %zu elements but found %zu." ), rownum, header.size(), row.size() ); continue; } auto geo_tag = row[geo_tag_col]; GRAPHIC_DATA gr_data; gr_data.graphic_dataname = row[geo_name_col]; gr_data.graphic_datanum = row[geo_num_col]; gr_data.graphic_data1 = row[geo_grdata1_col]; gr_data.graphic_data2 = row[geo_grdata2_col]; gr_data.graphic_data3 = row[geo_grdata3_col]; gr_data.graphic_data4 = row[geo_grdata4_col]; gr_data.graphic_data5 = row[geo_grdata5_col]; gr_data.graphic_data6 = row[geo_grdata6_col]; gr_data.graphic_data7 = row[geo_grdata7_col]; gr_data.graphic_data8 = row[geo_grdata8_col]; gr_data.graphic_data9 = row[geo_grdata9_col]; auto geo_refdes = row[geo_refdes_col]; // Grouped graphics are a series of records with the same record ID but incrementing // Sequence numbers. int id = -1; int seq = -1; int subseq = 0; if( std::sscanf( geo_tag.c_str(), "%d %d %d", &id, &seq, &subseq ) < 2 ) { wxLogError( _( "Invalid format for record_tag string '%s' in row %zu." ), geo_tag.c_str(), rownum ); continue; } auto gr_item = std::unique_ptr( processGraphic( gr_data, scale_factor ) ); if( !gr_item ) { wxLogDebug( "Unhandled graphic item '%s' in row %zu.", gr_data.graphic_dataname.c_str(), geo_tag.c_str(), rownum ); continue; } gr_item->layer = row[geo_subclass_col]; gr_item->seq = seq; gr_item->subseq = subseq; if( geo_refdes.empty() ) { if( board_graphics.empty() || board_graphics.back().id != id ) { GEOM_GRAPHIC new_gr; new_gr.subclass = row[geo_subclass_col]; new_gr.refdes = row[geo_refdes_col]; new_gr.name = row[geo_sym_name_col]; new_gr.id = id; new_gr.elements = std::make_unique(); board_graphics.push_back( std::move( new_gr ) ); } GEOM_GRAPHIC& graphic = board_graphics.back(); graphic.elements->emplace( std::move( gr_item ) ); } else { auto sym_gr_it = comp_graphics.emplace( geo_refdes, std::map{} ); auto map_it = sym_gr_it.first->second.emplace( id, GEOM_GRAPHIC{} ); auto& gr = map_it.first; if( map_it.second ) { gr->second.subclass = row[geo_subclass_col]; gr->second.refdes = row[geo_refdes_col]; gr->second.name = row[geo_sym_name_col]; gr->second.id = id; gr->second.elements = std::make_unique(); } auto result = gr->second.elements->emplace( std::move( gr_item ) ); } } return rownum - aRow; } /** * A!VIA_X!VIA_Y!PAD_STACK_NAME!NET_NAME!TEST_POINT! */ size_t FABMASTER::processVias( size_t aRow ) { size_t rownum = aRow + 2; if( rownum >= rows.size() ) return -1; const single_row& header = rows[aRow]; double scale_factor = processScaleFactor( aRow + 1 ); if( scale_factor <= 0.0 ) return -1; int viax_col = getColFromName( aRow, "VIAX" ); int viay_col = getColFromName( aRow, "VIAY" ); int padstack_name_col = getColFromName( aRow, "PADSTACKNAME" ); int net_name_col = getColFromName( aRow, "NETNAME" ); int test_point_col = getColFromName( aRow, "TESTPOINT" ); if( viax_col < 0 || viay_col < 0 || padstack_name_col < 0 || net_name_col < 0 || test_point_col < 0 ) return -1; for( ; rownum < rows.size() && rows[rownum].size() > 0 && rows[rownum][0] == "S"; ++rownum ) { const single_row& row = rows[rownum]; if( row.size() != header.size() ) { wxLogError( _( "Invalid row size in row %zu. Expecting %zu elements but found %zu." ), rownum, header.size(), row.size() ); continue; } vias.emplace_back( std::make_unique() ); auto& via = vias.back(); via->x = KiROUND( readDouble( row[viax_col] ) * scale_factor ); via->y = -KiROUND( readDouble( row[viay_col] ) * scale_factor ); via->padstack = row[padstack_name_col]; via->net = row[net_name_col]; via->test_point = ( row[test_point_col] == "YES" ); } return rownum - aRow; } /** * A!CLASS!SUBCLASS!GRAPHIC_DATA_NAME!GRAPHIC_DATA_NUMBER!RECORD_TAG!GRAPHIC_DATA_1!GRAPHIC_DATA_2! * GRAPHIC_DATA_3!GRAPHIC_DATA_4!GRAPHIC_DATA_5!GRAPHIC_DATA_6!GRAPHIC_DATA_7!GRAPHIC_DATA_8! * GRAPHIC_DATA_9!NET_NAME! */ size_t FABMASTER::processTraces( size_t aRow ) { size_t rownum = aRow + 2; if( rownum >= rows.size() ) return -1; const single_row& header = rows[aRow]; double scale_factor = processScaleFactor( aRow + 1 ); if( scale_factor <= 0.0 ) return -1; int class_col = getColFromName( aRow, "CLASS" ); int layer_col = getColFromName( aRow, "SUBCLASS" ); int grdata_name_col = getColFromName( aRow, "GRAPHICDATANAME" ); int grdata_num_col = getColFromName( aRow, "GRAPHICDATANUMBER" ); int tag_col = getColFromName( aRow, "RECORDTAG" ); int grdata1_col = getColFromName( aRow, "GRAPHICDATA1" ); int grdata2_col = getColFromName( aRow, "GRAPHICDATA2" ); int grdata3_col = getColFromName( aRow, "GRAPHICDATA3" ); int grdata4_col = getColFromName( aRow, "GRAPHICDATA4" ); int grdata5_col = getColFromName( aRow, "GRAPHICDATA5" ); int grdata6_col = getColFromName( aRow, "GRAPHICDATA6" ); int grdata7_col = getColFromName( aRow, "GRAPHICDATA7" ); int grdata8_col = getColFromName( aRow, "GRAPHICDATA8" ); int grdata9_col = getColFromName( aRow, "GRAPHICDATA9" ); int netname_col = getColFromName( aRow, "NETNAME" ); if( class_col < 0 || layer_col < 0 || grdata_name_col < 0 || grdata_num_col < 0 || tag_col < 0 || grdata1_col < 0 || grdata2_col < 0 || grdata3_col < 0 || grdata4_col < 0 || grdata5_col < 0 || grdata6_col < 0 || grdata7_col < 0 || grdata8_col < 0 || grdata9_col < 0 || netname_col < 0 ) return -1; for( ; rownum < rows.size() && rows[rownum].size() > 0 && rows[rownum][0] == "S"; ++rownum ) { const single_row& row = rows[rownum]; if( row.size() != header.size() ) { wxLogError( _( "Invalid row size in row %zu. Expecting %zu elements but found %zu." ), rownum, header.size(), row.size() ); continue; } GRAPHIC_DATA gr_data; gr_data.graphic_dataname = row[grdata_name_col]; gr_data.graphic_datanum = row[grdata_num_col]; gr_data.graphic_data1 = row[grdata1_col]; gr_data.graphic_data2 = row[grdata2_col]; gr_data.graphic_data3 = row[grdata3_col]; gr_data.graphic_data4 = row[grdata4_col]; gr_data.graphic_data5 = row[grdata5_col]; gr_data.graphic_data6 = row[grdata6_col]; gr_data.graphic_data7 = row[grdata7_col]; gr_data.graphic_data8 = row[grdata8_col]; gr_data.graphic_data9 = row[grdata9_col]; const std::string& geo_tag = row[tag_col]; // Grouped graphics are a series of records with the same record ID but incrementing // Sequence numbers. int id = -1; int seq = -1; int subseq = 0; if( std::sscanf( geo_tag.c_str(), "%d %d %d", &id, &seq, &subseq ) < 2 ) { wxLogError( _( "Invalid format for record_tag string '%s' in row %zu." ), geo_tag.c_str(), rownum ); continue; } auto gr_item = std::unique_ptr( processGraphic( gr_data, scale_factor ) ); if( !gr_item ) { wxLogDebug( _( "Unhandled graphic item '%s' in row %zu." ), gr_data.graphic_dataname.c_str(), rownum ); continue; } auto new_trace = std::make_unique(); new_trace->id = id; new_trace->layer = row[layer_col]; new_trace->netname = row[netname_col]; new_trace->lclass = row[class_col]; gr_item->layer = row[layer_col]; gr_item->seq = seq; gr_item->subseq = subseq; // Collect the reference designator positions for the footprints later if( new_trace->lclass == "REF DES" ) { auto result = refdes.emplace( std::move( new_trace ) ); auto& ref = *result.first; ref->segment.emplace( std::move( gr_item ) ); } else if( gr_item->width == 0 ) { auto result = zones.emplace( std::move( new_trace ) ); auto& zone = *result.first; auto gr_result = zone->segment.emplace( std::move( gr_item ) ); if( !gr_result.second ) { wxLogError( _( "Duplicate item for ID %d and sequence %d in row %zu." ), id, seq, rownum ); } } else { auto result = traces.emplace( std::move( new_trace ) ); auto& trace = *result.first; auto gr_result = trace->segment.emplace( std::move( gr_item ) ); if( !gr_result.second ) { wxLogError( _( "Duplicate item for ID %d and sequence %d in row %zu." ), id, seq, rownum ); } } } return rownum - aRow; } FABMASTER::SYMTYPE FABMASTER::parseSymType( const std::string& aSymType ) { if( aSymType == "PACKAGE" ) return SYMTYPE_PACKAGE; else if( aSymType == "DRAFTING") return SYMTYPE_DRAFTING; else if( aSymType == "MECHANICAL" ) return SYMTYPE_MECH; else if( aSymType == "FORMAT" ) return SYMTYPE_FORMAT; return SYMTYPE_NONE; } FABMASTER::COMPCLASS FABMASTER::parseCompClass( const std::string& aCmpClass ) { if( aCmpClass == "IO" ) return COMPCLASS_IO; else if( aCmpClass == "IC" ) return COMPCLASS_IC; else if( aCmpClass == "DISCRETE" ) return COMPCLASS_DISCRETE; return COMPCLASS_NONE; } /** * A!REFDES!COMP_CLASS!COMP_PART_NUMBER!COMP_HEIGHT!COMP_DEVICE_LABEL!COMP_INSERTION_CODE!SYM_TYPE! * SYM_NAME!SYM_MIRROR!SYM_ROTATE!SYM_X!SYM_Y!COMP_VALUE!COMP_TOL!COMP_VOLTAGE! */ size_t FABMASTER::processFootprints( size_t aRow ) { size_t rownum = aRow + 2; if( rownum >= rows.size() ) return -1; const single_row& header = rows[aRow]; double scale_factor = processScaleFactor( aRow + 1 ); if( scale_factor <= 0.0 ) return -1; int refdes_col = getColFromName( aRow, "REFDES" ); int compclass_col = getColFromName( aRow, "COMPCLASS" ); int comppartnum_col = getColFromName( aRow, "COMPPARTNUMBER" ); int compheight_col = getColFromName( aRow, "COMPHEIGHT" ); int compdevlabelcol = getColFromName( aRow, "COMPDEVICELABEL" ); int compinscode_col = getColFromName( aRow, "COMPINSERTIONCODE" ); int symtype_col = getColFromName( aRow, "SYMTYPE" ); int symname_col = getColFromName( aRow, "SYMNAME" ); int symmirror_col = getColFromName( aRow, "SYMMIRROR" ); int symrotate_col = getColFromName( aRow, "SYMROTATE" ); int symx_col = getColFromName( aRow, "SYMX" ); int symy_col = getColFromName( aRow, "SYMY" ); int compvalue_col = getColFromName( aRow, "COMPVALUE" ); int comptol_col = getColFromName( aRow, "COMPTOL" ); int compvolt_col = getColFromName( aRow, "COMPVOLTAGE" ); if( refdes_col < 0 || compclass_col < 0 || comppartnum_col < 0 || compheight_col < 0 || compdevlabelcol < 0 || compinscode_col < 0 || symtype_col < 0 || symname_col < 0 || symmirror_col < 0 || symrotate_col < 0 || symx_col < 0 || symy_col < 0 || compvalue_col < 0 || comptol_col < 0 || compvolt_col < 0 ) return -1; for( ; rownum < rows.size() && rows[rownum].size() > 0 && rows[rownum][0] == "S"; ++rownum ) { const single_row& row = rows[rownum]; if( row.size() != header.size() ) { wxLogError( _( "Invalid row size in row %zu. Expecting %zu elements but found %zu." ), rownum, header.size(), row.size() ); continue; } auto cmp = std::make_unique(); cmp->refdes = row[refdes_col]; cmp->cclass = parseCompClass( row[compclass_col] ); cmp->pn = row[comppartnum_col]; cmp->height = row[compheight_col]; cmp->dev_label = row[compdevlabelcol]; cmp->insert_code = row[compinscode_col]; cmp->type = parseSymType( row[symtype_col] ); cmp->name = row[symname_col]; cmp->mirror = ( row[symmirror_col] == "YES" ); cmp->rotate = readDouble( row[symrotate_col] ); cmp->x = KiROUND( readDouble( row[symx_col] ) * scale_factor ); cmp->y = -KiROUND( readDouble( row[symy_col] ) * scale_factor ); cmp->value = row[compvalue_col]; cmp->tol = row[comptol_col]; cmp->voltage = row[compvolt_col]; auto vec = components.find( cmp->refdes ); if( vec == components.end() ) { auto retval = components.insert( std::make_pair( cmp->refdes, std::vector>{} ) ); vec = retval.first; } vec->second.push_back( std::move( cmp ) ); } return rownum - aRow; } /** * A!SYM_NAME!SYM_MIRROR!PIN_NAME!PIN_NUMBER!PIN_X!PIN_Y!PAD_STACK_NAME!REFDES!PIN_ROTATION!TEST_POINT! */ size_t FABMASTER::processPins( size_t aRow ) { size_t rownum = aRow + 2; if( rownum >= rows.size() ) return -1; const single_row& header = rows[aRow]; double scale_factor = processScaleFactor( aRow + 1 ); if( scale_factor <= 0.0 ) return -1; int symname_col = getColFromName( aRow, "SYMNAME" ); int symmirror_col = getColFromName( aRow, "SYMMIRROR" ); int pinname_col = getColFromName( aRow, "PINNAME" ); int pinnum_col = getColFromName( aRow, "PINNUMBER" ); int pinx_col = getColFromName( aRow, "PINX" ); int piny_col = getColFromName( aRow, "PINY" ); int padstack_col = getColFromName( aRow, "PADSTACKNAME" ); int refdes_col = getColFromName( aRow, "REFDES" ); int pinrot_col = getColFromName( aRow, "PINROTATION" ); int testpoint_col = getColFromName( aRow, "TESTPOINT" ); if( symname_col < 0 ||symmirror_col < 0 || pinname_col < 0 || pinnum_col < 0 || pinx_col < 0 || piny_col < 0 || padstack_col < 0 || refdes_col < 0 || pinrot_col < 0 || testpoint_col < 0 ) return -1; for( ; rownum < rows.size() && rows[rownum].size() > 0 && rows[rownum][0] == "S"; ++rownum ) { const single_row& row = rows[rownum]; if( row.size() != header.size() ) { wxLogError( _( "Invalid row size in row %zu. Expecting %zu elements but found %zu." ), rownum, header.size(), row.size() ); continue; } auto pin = std::make_unique(); pin->name = row[symname_col]; pin->mirror = ( row[symmirror_col] == "YES" ); pin->pin_name = row[pinname_col]; pin->pin_number = row[pinnum_col]; pin->pin_x = KiROUND( readDouble( row[pinx_col] ) * scale_factor ); pin->pin_y = -KiROUND( readDouble( row[piny_col] ) * scale_factor ); pin->padstack = row[padstack_col]; pin->refdes = row[refdes_col]; pin->rotation = readDouble( row[pinrot_col] ); auto map_it = pins.find( pin->refdes ); if( map_it == pins.end() ) { auto retval = pins.insert( std::make_pair( pin->refdes, std::set, PIN::BY_NUM>{} ) ); map_it = retval.first; } map_it->second.insert( std::move( pin ) ); } return rownum - aRow; } /** * A!NET_NAME!REFDES!PIN_NUMBER!PIN_NAME!PIN_GROUND!PIN_POWER! */ size_t FABMASTER::processNets( size_t aRow ) { size_t rownum = aRow + 2; if( rownum >= rows.size() ) return -1; const single_row& header = rows[aRow]; double scale_factor = processScaleFactor( aRow + 1 ); if( scale_factor <= 0.0 ) return -1; int netname_col = getColFromName( aRow, "NETNAME" ); int refdes_col = getColFromName( aRow, "REFDES" ); int pinnum_col = getColFromName( aRow, "PINNUMBER" ); int pinname_col = getColFromName( aRow, "PINNAME" ); int pingnd_col = getColFromName( aRow, "PINGROUND" ); int pinpwr_col = getColFromName( aRow, "PINPOWER" ); if( netname_col < 0 || refdes_col < 0 || pinnum_col < 0 || pinname_col < 0 || pingnd_col < 0 || pinpwr_col < 0 ) return -1; for( ; rownum < rows.size() && rows[rownum].size() > 0 && rows[rownum][0] == "S"; ++rownum ) { const single_row& row = rows[rownum]; if( row.size() != header.size() ) { wxLogError( _( "Invalid row size in row %zu. Expecting %zu elements but found %zu." ), rownum, header.size(), row.size() ); continue; } NETNAME new_net; new_net.name = row[netname_col]; new_net.refdes = row[refdes_col]; new_net.pin_num = row[pinnum_col]; new_net.pin_name = row[pinname_col]; new_net.pin_gnd = ( row[pingnd_col] == "YES" ); new_net.pin_pwr = ( row[pinpwr_col] == "YES" ); pin_nets.emplace( std::make_pair( new_net.refdes, new_net.pin_num ), new_net ); netnames.insert( row[netname_col] ); } return rownum - aRow; } bool FABMASTER::Process() { for( size_t i = 0; i < rows.size(); ) { auto type = detectType( i ); switch( type ) { case EXTRACT_PADSTACKS: { /// We extract the basic layers from the padstacks first as this is the only place /// the stackup is kept in the basic fabmaster export processPadStackLayers( i ); assignLayers(); int retval = processPadStacks( i ); i += std::max( retval, 1 ); break; } case EXTRACT_FULL_LAYERS: { int retval = processLayers( i ); i += std::max( retval, 1 ); break; } case EXTRACT_BASIC_LAYERS: { int retval = processSimpleLayers( i ); i += std::max( retval, 1 ); break; } case EXTRACT_VIAS: { int retval = processVias( i ); i += std::max( retval, 1 ); break; } case EXTRACT_TRACES: { int retval = processTraces( i ); i += std::max( retval, 1 ); break; } case EXTRACT_REFDES: { int retval = processFootprints( i ); i += std::max( retval, 1 ); break; } case EXTRACT_NETS: { int retval = processNets( i ); i += std::max( retval, 1 ); break; } case EXTRACT_GRAPHICS: { int retval = processGeometry( i ); i += std::max( retval, 1 ); break; } case EXTRACT_PINS: { int retval = processPins( i ); i += std::max( retval, 1 ); break; } case EXTRACT_PAD_SHAPES: { int retval = processCustomPads( i ); i += std::max( retval, 1 ); break; } default: ++i; break; } } return true; } bool FABMASTER::loadZones( BOARD* aBoard ) { for( auto& zone : zones ) { checkpoint(); if( IsCopperLayer( getLayer( zone->layer ) ) || zone->layer == "ALL" ) { loadZone( aBoard, zone ); } else { if( zone->layer == "OUTLINE" || zone->layer == "DESIGN_OUTLINE" ) { loadOutline( aBoard, zone ); } else { loadPolygon( aBoard, zone ); } } } /** * Zones in FABMASTER come in two varieties: * - Outlines with no net code attached * - Filled areas with net code attached * * In pcbnew, we want the outline with net code attached. To determine which * outline should have which netcode, we look for overlapping areas. Each unnetted zone * outline will be assigned the netcode that with the most hits on the edge of their * outline. */ std::set zones_to_delete; for( auto zone : aBoard->Zones() ) { /// Remove the filled areas in favor of the outlines if( zone->GetNetCode() > 0 ) { zones_to_delete.insert( zone ); } } for( auto zone1 : aBoard->Zones() ) { /// Zone1 will be the destination zone for the new net if( zone1->GetNetCode() > 0 ) continue; SHAPE_LINE_CHAIN& outline1 = zone1->Outline()->Outline( 0 ); std::vector overlaps( aBoard->GetNetInfo().GetNetCount() + 1, 0 ); std::vector> possible_deletions( overlaps.size() ); for( auto zone2 : aBoard->Zones() ) { if( zone2->GetNetCode() <= 0 ) continue; SHAPE_LINE_CHAIN& outline2 = zone2->Outline()->Outline( 0 ); if( zone1->GetLayer() != zone2->GetLayer() ) continue; if( !outline1.BBox().Intersects( outline2.BBox() ) ) continue; for( auto& pt1 : outline1.CPoints() ) { /// We're looking for the netcode with the most overlaps to the un-netted zone if( outline2.PointOnEdge( pt1, 1 ) ) overlaps[ zone2->GetNetCode() ]++; } for( auto& pt2 : outline2.CPoints() ) { /// The overlap between outline1 and outline2 isn't perfect, so look for overlaps /// in both directions if( outline1.PointOnEdge( pt2, 1 ) ) overlaps[ zone2->GetNetCode() ]++; } } size_t max_net = 0; size_t max_net_id = 0; for( size_t el = 1; el < overlaps.size(); ++el ) { if( overlaps[el] > max_net ) { max_net = overlaps[el]; max_net_id = el; } } if( max_net > 0 ) zone1->SetNetCode( max_net_id ); } for( auto zone : zones_to_delete ) { aBoard->Remove( zone ); delete zone; } return true; } bool FABMASTER::loadFootprints( BOARD* aBoard ) { const NETNAMES_MAP& netinfo = aBoard->GetNetInfo().NetsByName(); const auto& ds = aBoard->GetDesignSettings(); for( auto& mod : components ) { checkpoint(); bool has_multiple = mod.second.size() > 1; for( int i = 0; i < mod.second.size(); ++i ) { auto& src = mod.second[i]; FOOTPRINT* fp = new FOOTPRINT( aBoard ); wxString mod_ref = src->name; wxString lib_ref = m_filename.GetName(); if( has_multiple ) mod_ref.Append( wxString::Format( "_%d", i ) ); ReplaceIllegalFileNameChars( lib_ref, '_' ); ReplaceIllegalFileNameChars( mod_ref, '_' ); wxString key = !lib_ref.empty() ? lib_ref + ":" + mod_ref : mod_ref; LIB_ID fpID; fpID.Parse( key, true ); fp->SetFPID( fpID ); fp->SetPosition( wxPoint( src->x, src->y ) ); fp->SetOrientationDegrees( -src->rotate ); // KiCad netlisting requires parts to have non-digit + digit annotation. // If the reference begins with a number, we prepend 'UNK' (unknown) for the source designator wxString reference = src->refdes; if( !std::isalpha( src->refdes[0] ) ) reference.Prepend( "UNK" ); fp->SetReference( reference ); fp->SetValue( src->value ); fp->Value().SetLayer( F_Fab ); fp->Value().SetVisible( false ); for( auto& ref : refdes ) { const GRAPHIC_TEXT *lsrc = static_cast( ( *( ref->segment.begin() ) ).get() ); if( lsrc->text == src->refdes ) { FP_TEXT* txt = nullptr; PCB_LAYER_ID layer = getLayer( ref->layer ); if( !IsPcbLayer( layer ) ) { printf("The layer %s is not mapped?\n", ref->layer.c_str() ); continue; } if( layer == F_SilkS || layer == B_SilkS ) txt = &( fp->Reference() ); else txt = new FP_TEXT( fp ); if( src->mirror ) { txt->SetLayer( FlipLayer( layer ) ); txt->SetTextPos( wxPoint( lsrc->start_x, 2 * src->y - ( lsrc->start_y - lsrc->height / 2 ) ) ); } else { txt->SetLayer( layer ); txt->SetTextPos( wxPoint( lsrc->start_x, lsrc->start_y - lsrc->height / 2 ) ); } txt->SetText( lsrc->text ); txt->SetItalic( lsrc->ital ); txt->SetTextThickness( lsrc->thickness ); txt->SetTextHeight( lsrc->height ); txt->SetTextWidth( lsrc->width ); txt->SetHorizJustify( lsrc->orient ); txt->SetLocalCoord(); if( txt != &fp->Reference() ) fp->Add( txt, ADD_MODE::APPEND ); } } /// Always set the module to the top and flip later if needed /// When flipping later, we get the full coordinate transform for free fp->SetLayer( F_Cu ); auto gr_it = comp_graphics.find( src->refdes ); if( gr_it == comp_graphics.end() ) { continue; //TODO: Error } for( auto& gr_ref : gr_it->second ) { auto& graphic = gr_ref.second; for( auto& seg : *graphic.elements ) { PCB_LAYER_ID layer = Dwgs_User; if( IsPcbLayer( getLayer( seg->layer ) ) ) layer = getLayer( seg->layer ); switch( seg->shape ) { case GR_SHAPE_LINE: { const GRAPHIC_LINE* lsrc = static_cast( seg.get() ); FP_SHAPE* line = new FP_SHAPE( fp, SHAPE_T::SEGMENT ); if( src->mirror ) { line->SetLayer( FlipLayer( layer ) ); line->SetStart( wxPoint( lsrc->start_x, 2 * src->y - lsrc->start_y ) ); line->SetEnd( wxPoint( lsrc->end_x, 2 * src->y - lsrc->end_y ) ); } else { line->SetLayer( layer ); line->SetStart( wxPoint( lsrc->start_x, lsrc->start_y ) ); line->SetEnd( wxPoint( lsrc->end_x, lsrc->end_y ) ); } line->SetWidth( lsrc->width ); line->SetLocalCoord(); if( lsrc->width == 0 ) line->SetWidth( ds.GetLineThickness( line->GetLayer() ) ); fp->Add( line, ADD_MODE::APPEND ); break; } case GR_SHAPE_ARC: { const GRAPHIC_ARC* lsrc = static_cast( seg.get() ); FP_SHAPE* arc = new FP_SHAPE( fp, SHAPE_T::ARC ); if( src->mirror ) { arc->SetLayer( FlipLayer( layer ) ); arc->SetCenter( wxPoint( lsrc->center_x, 2 * src->y - lsrc->center_y ) ); arc->SetArcStart( wxPoint( lsrc->end_x, 2 * src->y - lsrc->end_y ) ); arc->SetAngle( lsrc->result.GetCentralAngle() * 10.0 ); } else { arc->SetLayer( layer ); arc->SetCenter( wxPoint( lsrc->center_x, lsrc->center_y ) ); arc->SetArcStart( wxPoint( lsrc->end_x, lsrc->end_y ) ); arc->SetAngle( -lsrc->result.GetCentralAngle() * 10.0 ); } arc->SetWidth( lsrc->width ); arc->SetLocalCoord(); if( lsrc->width == 0 ) arc->SetWidth( ds.GetLineThickness( arc->GetLayer() ) ); fp->Add( arc, ADD_MODE::APPEND ); break; } case GR_SHAPE_RECTANGLE: { const GRAPHIC_RECTANGLE *lsrc = static_cast( seg.get() ); FP_SHAPE* rect = new FP_SHAPE( fp, SHAPE_T::RECT ); if( src->mirror ) { rect->SetLayer( FlipLayer( layer ) ); rect->SetStart( wxPoint( lsrc->start_x, 2 * src->y - lsrc->start_y ) ); rect->SetEnd( wxPoint( lsrc->end_x, 2 * src->y - lsrc->end_y ) ); } else { rect->SetLayer( layer ); rect->SetStart( wxPoint( lsrc->start_x, lsrc->start_y ) ); rect->SetEnd( wxPoint( lsrc->end_x, lsrc->end_y ) ); } rect->SetWidth( ds.GetLineThickness( rect->GetLayer() ) ); rect->SetLocalCoord(); fp->Add( rect, ADD_MODE::APPEND ); break; } case GR_SHAPE_TEXT: { const GRAPHIC_TEXT *lsrc = static_cast( seg.get() ); FP_TEXT* txt = new FP_TEXT( fp ); if( src->mirror ) { txt->SetLayer( FlipLayer( layer ) ); txt->SetTextPos( wxPoint( lsrc->start_x, 2 * src->y - ( lsrc->start_y - lsrc->height / 2 ) ) ); } else { txt->SetLayer( layer ); txt->SetTextPos( wxPoint( lsrc->start_x, lsrc->start_y - lsrc->height / 2 ) ); } txt->SetText( lsrc->text ); txt->SetItalic( lsrc->ital ); txt->SetTextThickness( lsrc->thickness ); txt->SetTextHeight( lsrc->height ); txt->SetTextWidth( lsrc->width ); txt->SetHorizJustify( lsrc->orient ); txt->SetLocalCoord(); // FABMASTER doesn't have visibility flags but layers that are not silk should be hidden // by default to prevent clutter. if( txt->GetLayer() != F_SilkS && txt->GetLayer() != B_SilkS ) txt->SetVisible( false ); fp->Add( txt, ADD_MODE::APPEND ); break; } default: continue; } } } auto pin_it = pins.find( src->refdes ); if( pin_it != pins.end() ) { for( auto& pin : pin_it->second ) { auto pin_net_it = pin_nets.find( std::make_pair( pin->refdes, pin->pin_number ) ); auto padstack = pads.find( pin->padstack ); std::string netname = ""; if( pin_net_it != pin_nets.end() ) netname = pin_net_it->second.name; auto net_it = netinfo.find( netname ); PAD* newpad = new PAD( fp ); if( net_it != netinfo.end() ) newpad->SetNet( net_it->second ); else newpad->SetNetCode( 0 ); newpad->SetX( pin->pin_x ); if( src->mirror ) newpad->SetY( 2 * src->y - pin->pin_y ); else newpad->SetY( pin->pin_y ); newpad->SetNumber( pin->pin_number ); if( padstack == pads.end() ) { ///TODO:Warning delete newpad; continue; } else { auto& pad = padstack->second; newpad->SetShape( pad.shape ); if( pad.shape == PAD_SHAPE::CUSTOM ) { // Choose the smaller dimension to ensure the base pad // is fully hidden by the custom pad int pad_size = std::min( pad.width, pad.height ); newpad->SetSize( wxSize( pad_size / 2, pad_size / 2 ) ); std::string custom_name = pad.custom_name + "_" + pin->refdes + "_" + pin->pin_number; auto custom_it = pad_shapes.find( custom_name ); if( custom_it != pad_shapes.end() ) { SHAPE_POLY_SET poly_outline; int last_subseq = 0; int hole_idx = -1; poly_outline.NewOutline(); // Custom pad shapes have a group of elements // that are a list of graphical polygons for( const auto& el : (*custom_it).second.elements ) { // For now, we are only processing the custom pad for the top layer // TODO: Use full padstacks when implementing in KiCad PCB_LAYER_ID primary_layer = src->mirror ? B_Cu : F_Cu; if( getLayer( ( *( el.second.begin() ) )->layer ) != primary_layer ) continue; for( const auto& seg : el.second ) { if( seg->subseq > 0 || seg->subseq != last_subseq ) { poly_outline.Polygon(0).back().SetClosed( true ); hole_idx = poly_outline.AddHole( SHAPE_LINE_CHAIN{} ); } if( seg->shape == GR_SHAPE_LINE ) { const GRAPHIC_LINE* src = static_cast( seg.get() ); if( poly_outline.VertexCount( 0, hole_idx ) == 0 ) poly_outline.Append( src->start_x, src->start_y, 0, hole_idx ); poly_outline.Append( src->end_x, src->end_y, 0, hole_idx ); } else if( seg->shape == GR_SHAPE_ARC ) { const GRAPHIC_ARC* src = static_cast( seg.get() ); SHAPE_LINE_CHAIN& chain = poly_outline.Hole( 0, hole_idx ); chain.Append( src->result ); } } } if( poly_outline.OutlineCount() < 1 || poly_outline.Outline( 0 ).PointCount() < 3 ) { wxLogError( _( "Invalid custom pad '%s'. Replacing with " "circular pad." ), custom_name.c_str() ); newpad->SetShape( PAD_SHAPE::CIRCLE ); } else { poly_outline.Fracture( SHAPE_POLY_SET::POLYGON_MODE::PM_FAST ); poly_outline.Move( -newpad->GetPosition() ); if( src->mirror ) { poly_outline.Mirror( false, true, VECTOR2I( 0, ( pin->pin_y - src->y ) ) ); poly_outline.Rotate( ( -src->rotate + pin->rotation ) * M_PI / 180.0 ); } else { poly_outline.Rotate( ( src->rotate - pin->rotation ) * M_PI / 180.0 ); } newpad->AddPrimitivePoly( poly_outline, 0, true ); } SHAPE_POLY_SET mergedPolygon; newpad->MergePrimitivesAsPolygon( &mergedPolygon ); if( mergedPolygon.OutlineCount() > 1 ) { wxLogError( _( "Invalid custom pad '%s'. Replacing with " "circular pad." ), custom_name.c_str() ); newpad->SetShape( PAD_SHAPE::CIRCLE ); } } else { wxLogError( _( "Could not find custom pad '%s'." ), custom_name.c_str() ); } } else newpad->SetSize( wxSize( pad.width, pad.height ) ); if( pad.drill ) { if( pad.plated ) { newpad->SetAttribute( PAD_ATTRIB::PTH ); newpad->SetLayerSet( PAD::PTHMask() ); } else { newpad->SetAttribute( PAD_ATTRIB::NPTH ); newpad->SetLayerSet( PAD::UnplatedHoleMask() ); } if( pad.drill_size_x == pad.drill_size_y ) newpad->SetDrillShape( PAD_DRILL_SHAPE_CIRCLE ); else newpad->SetDrillShape( PAD_DRILL_SHAPE_OBLONG ); newpad->SetDrillSize( wxSize( pad.drill_size_x, pad.drill_size_y ) ); } else { newpad->SetAttribute( PAD_ATTRIB::SMD ); if( pad.top ) newpad->SetLayerSet( PAD::SMDMask() ); else if( pad.bottom ) newpad->SetLayerSet( FlipLayerMask( PAD::SMDMask() ) ); } } newpad->SetLocalCoord(); if( src->mirror ) newpad->SetOrientation( ( -src->rotate + pin->rotation ) * 10.0 ); else newpad->SetOrientation( ( src->rotate - pin->rotation ) * 10.0 ); fp->Add( newpad, ADD_MODE::APPEND ); } } if( src->mirror ) { fp->SetOrientationDegrees( 180.0 - src->rotate ); fp->Flip( fp->GetPosition(), true ); } aBoard->Add( fp, ADD_MODE::APPEND ); } } return true; } bool FABMASTER::loadLayers( BOARD* aBoard ) { LSET layer_set; /// The basic layers that get enabled for normal boards layer_set |= LSET::AllTechMask() | LSET::UserMask(); for( auto& layer : layers ) { checkpoint(); if( layer.second.layerid >= PCBNEW_LAYER_ID_START ) layer_set.set( layer.second.layerid ); } aBoard->SetEnabledLayers( layer_set ); for( auto& layer : layers ) { if( layer.second.conductive ) { aBoard->SetLayerName( static_cast( layer.second.layerid ), layer.second.name ); } } return true; } bool FABMASTER::loadVias( BOARD* aBoard ) { const NETNAMES_MAP& netinfo = aBoard->GetNetInfo().NetsByName(); const auto& ds = aBoard->GetDesignSettings(); for( auto& via : vias ) { checkpoint(); auto net_it = netinfo.find( via->net ); auto padstack = pads.find( via->padstack ); PCB_VIA* new_via = new PCB_VIA( aBoard ); new_via->SetPosition( wxPoint( via->x, via->y ) ); if( net_it != netinfo.end() ) new_via->SetNet( net_it->second ); if( padstack == pads.end() ) { new_via->SetDrillDefault(); if( !ds.m_ViasDimensionsList.empty() ) { new_via->SetWidth( ds.m_ViasDimensionsList[0].m_Diameter ); new_via->SetDrill( ds.m_ViasDimensionsList[0].m_Drill ); } else { new_via->SetDrillDefault(); new_via->SetWidth( ds.m_ViasMinSize ); } } else { new_via->SetDrill( padstack->second.drill_size_x ); new_via->SetWidth( padstack->second.width ); } aBoard->Add( new_via, ADD_MODE::APPEND ); } return true; } bool FABMASTER::loadNets( BOARD* aBoard ) { for( auto& net : netnames ) { checkpoint(); NETINFO_ITEM *newnet = new NETINFO_ITEM( aBoard, net ); aBoard->Add( newnet, ADD_MODE::APPEND ); } return true; } bool FABMASTER::loadEtch( BOARD* aBoard, const std::unique_ptr& aLine) { const NETNAMES_MAP& netinfo = aBoard->GetNetInfo().NetsByName(); auto net_it = netinfo.find( aLine->netname ); int last_subseq = 0; ZONE* new_zone = nullptr; for( const auto& seg : aLine->segment ) { PCB_LAYER_ID layer = getLayer( seg->layer ); if( IsCopperLayer( layer ) ) { if( seg->shape == GR_SHAPE_LINE ) { const GRAPHIC_LINE* src = static_cast( seg.get() ); PCB_TRACK* trk = new PCB_TRACK( aBoard ); trk->SetLayer( layer ); trk->SetStart( wxPoint( src->start_x, src->start_y ) ); trk->SetEnd( wxPoint( src->end_x, src->end_y ) ); trk->SetWidth( src->width ); if( net_it != netinfo.end() ) trk->SetNet( net_it->second ); aBoard->Add( trk, ADD_MODE::APPEND ); } else if( seg->shape == GR_SHAPE_ARC ) { const GRAPHIC_ARC* src = static_cast( seg.get() ); PCB_ARC* trk = new PCB_ARC( aBoard, &src->result ); trk->SetLayer( layer ); trk->SetWidth( src->width ); if( net_it != netinfo.end() ) trk->SetNet( net_it->second ); aBoard->Add( trk, ADD_MODE::APPEND ); } } else { wxLogError( _( "Expecting etch data to be on copper layer. Row found on layer '%s'" ), seg->layer.c_str() ); } } return true; } SHAPE_POLY_SET FABMASTER::loadShapePolySet( const graphic_element& aElement ) { SHAPE_POLY_SET poly_outline; int last_subseq = 0; int hole_idx = -1; poly_outline.NewOutline(); for( const auto& seg : aElement ) { if( seg->subseq > 0 || seg->subseq != last_subseq ) hole_idx = poly_outline.AddHole( SHAPE_LINE_CHAIN{} ); if( seg->shape == GR_SHAPE_LINE ) { const GRAPHIC_LINE* src = static_cast( seg.get() ); if( poly_outline.VertexCount( 0, hole_idx ) == 0 ) poly_outline.Append( src->start_x, src->start_y, 0, hole_idx ); poly_outline.Append( src->end_x, src->end_y, 0, hole_idx ); } else if( seg->shape == GR_SHAPE_ARC ) { const GRAPHIC_ARC* src = static_cast( seg.get() ); SHAPE_LINE_CHAIN& chain = poly_outline.Hole( 0, hole_idx ); chain.Append( src->result ); } } poly_outline.Fracture( SHAPE_POLY_SET::POLYGON_MODE::PM_FAST ); return poly_outline; } bool FABMASTER::loadPolygon( BOARD* aBoard, const std::unique_ptr& aLine) { if( aLine->segment.size() < 3 ) return false; PCB_LAYER_ID layer = Cmts_User; auto new_layer = getLayer( aLine->layer ); if( IsPcbLayer( new_layer ) ) layer = new_layer; SHAPE_POLY_SET poly_outline = loadShapePolySet( aLine->segment ); if( poly_outline.OutlineCount() < 1 || poly_outline.COutline( 0 ).PointCount() < 3 ) return false; PCB_SHAPE* new_poly = new PCB_SHAPE( aBoard ); new_poly->SetShape( SHAPE_T::POLY ); new_poly->SetLayer( layer ); // Polygons on the silk layer are filled but other layers are not/fill doesn't make sense if( layer == F_SilkS || layer == B_SilkS ) { new_poly->SetFilled( true ); new_poly->SetWidth( 0 ); } else { new_poly->SetWidth( ( *( aLine->segment.begin() ) )->width ); if( new_poly->GetWidth() == 0 ) new_poly->SetWidth( aBoard->GetDesignSettings().GetLineThickness( layer ) ); } new_poly->SetPolyShape( poly_outline ); aBoard->Add( new_poly, ADD_MODE::APPEND ); return true; } bool FABMASTER::loadZone( BOARD* aBoard, const std::unique_ptr& aLine) { if( aLine->segment.size() < 3 ) return false; int last_subseq = 0; int hole_idx = -1; SHAPE_POLY_SET* zone_outline = nullptr; ZONE* zone = nullptr; const NETNAMES_MAP& netinfo = aBoard->GetNetInfo().NetsByName(); auto net_it = netinfo.find( aLine->netname ); PCB_LAYER_ID layer = Cmts_User; auto new_layer = getLayer( aLine->layer ); if( IsPcbLayer( new_layer ) ) layer = new_layer; zone = new ZONE( aBoard ); zone_outline = new SHAPE_POLY_SET; if( net_it != netinfo.end() ) zone->SetNet( net_it->second ); if( aLine->layer == "ALL" ) zone->SetLayerSet( aBoard->GetLayerSet() & LSET::AllCuMask() ); else zone->SetLayer( layer ); zone->SetIsRuleArea( false ); zone->SetDoNotAllowTracks( false ); zone->SetDoNotAllowVias( false ); zone->SetDoNotAllowPads( false ); zone->SetDoNotAllowFootprints( false ); zone->SetDoNotAllowCopperPour( false ); if( aLine->lclass == "ROUTE KEEPOUT") { zone->SetIsRuleArea( true ); zone->SetDoNotAllowTracks( true ); } else if( aLine->lclass == "VIA KEEPOUT") { zone->SetIsRuleArea( true ); zone->SetDoNotAllowVias( true ); } zone->SetPriority( 50 ); zone->SetLocalClearance( 0 ); zone->SetPadConnection( ZONE_CONNECTION::FULL ); zone_outline->NewOutline(); for( const auto& seg : aLine->segment ) { if( seg->subseq > 0 && seg->subseq != last_subseq ) { /// Don't knock holes in the BOUNDARY systems. These are the outer layers for zone fills. if( aLine->lclass == "BOUNDARY" ) break; hole_idx = zone_outline->AddHole( SHAPE_LINE_CHAIN{} ); last_subseq = seg->subseq; last_subseq = seg->subseq; } if( seg->shape == GR_SHAPE_LINE ) { const GRAPHIC_LINE* src = static_cast( seg.get() ); if( zone_outline->VertexCount( 0, hole_idx ) == 0 ) zone_outline->Append( src->start_x, src->start_y, 0, hole_idx ); zone_outline->Append( src->end_x, src->end_y, 0, hole_idx ); } else if( seg->shape == GR_SHAPE_ARC ) { const GRAPHIC_ARC* src = static_cast( seg.get() ); zone_outline->Hole( 0, hole_idx ).Append( src->result ); } } if( zone_outline->Outline( 0 ).PointCount() >= 3 ) { zone->SetOutline( zone_outline ); aBoard->Add( zone, ADD_MODE::APPEND ); } else { delete( zone_outline ); delete( zone ); } return true; } bool FABMASTER::loadOutline( BOARD* aBoard, const std::unique_ptr& aLine) { PCB_LAYER_ID layer; if( aLine->lclass == "BOARD GEOMETRY" ) layer = Edge_Cuts; else if( aLine->lclass == "DRAWING FORMAT" ) layer = Dwgs_User; else layer = Cmts_User; for( auto& seg : aLine->segment ) { switch( seg->shape ) { case GR_SHAPE_LINE: { const GRAPHIC_LINE* src = static_cast( seg.get() ); PCB_SHAPE* line = new PCB_SHAPE( aBoard ); line->SetShape( SHAPE_T::SEGMENT ); line->SetLayer( layer ); line->SetStart( wxPoint( src->start_x, src->start_y ) ); line->SetEnd( wxPoint( src->end_x, src->end_y ) ); line->SetWidth( src->width ); if( line->GetWidth() == 0 ) line->SetWidth( aBoard->GetDesignSettings().GetLineThickness( layer ) ); aBoard->Add( line, ADD_MODE::APPEND ); break; } case GR_SHAPE_ARC: { const GRAPHIC_ARC* src = static_cast( seg.get() ); PCB_SHAPE* arc = new PCB_SHAPE( aBoard ); arc->SetShape( SHAPE_T::ARC ); arc->SetLayer( layer ); arc->SetCenter( wxPoint( src->center_x, src->center_y ) ); arc->SetArcStart( wxPoint( src->start_x, src->start_y ) ); arc->SetAngle( src->result.GetCentralAngle() * 10.0 ); arc->SetWidth( src->width ); if( arc->GetWidth() == 0 ) arc->SetWidth( aBoard->GetDesignSettings().GetLineThickness( layer ) ); aBoard->Add( arc, ADD_MODE::APPEND ); break; } case GR_SHAPE_RECTANGLE: { const GRAPHIC_RECTANGLE *src = static_cast( seg.get() ); PCB_SHAPE* rect = new PCB_SHAPE( aBoard ); rect->SetShape( SHAPE_T::RECT ); rect->SetLayer( layer ); rect->SetStart( wxPoint( src->start_x, src->start_y ) ); rect->SetEnd( wxPoint( src->end_x, src->end_y ) ); rect->SetWidth( aBoard->GetDesignSettings().GetLineThickness( layer ) ); aBoard->Add( rect, ADD_MODE::APPEND ); break; } case GR_SHAPE_TEXT: { const GRAPHIC_TEXT *src = static_cast( seg.get() ); PCB_TEXT* txt = new PCB_TEXT( aBoard ); txt->SetLayer( layer ); txt->SetTextPos( wxPoint( src->start_x, src->start_y - src->height / 2 ) ); txt->SetText( src->text ); txt->SetItalic( src->ital ); txt->SetTextThickness( src->thickness ); txt->SetTextHeight( src->height ); txt->SetTextWidth( src->width ); txt->SetHorizJustify( src->orient ); aBoard->Add( txt, ADD_MODE::APPEND ); break; } default: return false; } } return true; } bool FABMASTER::loadGraphics( BOARD* aBoard ) { for( auto& geom : board_graphics ) { checkpoint(); PCB_LAYER_ID layer; // The pin numbers are not useful for us outside of the footprints if( geom.subclass == "PIN_NUMBER" ) continue; layer = getLayer( geom.subclass ); if( !IsPcbLayer( layer ) ) layer = Cmts_User; if( !geom.elements->empty() ) { /// Zero-width segments/arcs are polygon outlines if( ( *( geom.elements->begin() ) )->width == 0 ) { SHAPE_POLY_SET poly_outline = loadShapePolySet( *( geom.elements ) ); if( poly_outline.OutlineCount() < 1 || poly_outline.COutline( 0 ).PointCount() < 3 ) continue; PCB_SHAPE* new_poly = new PCB_SHAPE( aBoard ); new_poly->SetShape( SHAPE_T::POLY ); new_poly->SetLayer( layer ); new_poly->SetPolyShape( poly_outline ); new_poly->SetWidth( 0 ); if( layer == F_SilkS || layer == B_SilkS ) new_poly->SetFilled( true ); aBoard->Add( new_poly, ADD_MODE::APPEND ); } } for( auto& seg : *geom.elements ) { switch( seg->shape ) { case GR_SHAPE_LINE: { const GRAPHIC_LINE* src = static_cast( seg.get() ); PCB_SHAPE* line = new PCB_SHAPE( aBoard ); line->SetShape( SHAPE_T::SEGMENT ); line->SetLayer( layer ); line->SetStart( wxPoint( src->start_x, src->start_y ) ); line->SetEnd( wxPoint( src->end_x, src->end_y ) ); line->SetWidth( src->width ); aBoard->Add( line, ADD_MODE::APPEND ); break; } case GR_SHAPE_ARC: { const GRAPHIC_ARC* src = static_cast( seg.get() ); PCB_SHAPE* arc = new PCB_SHAPE( aBoard ); arc->SetShape( SHAPE_T::ARC ); arc->SetLayer( layer ); arc->SetCenter( wxPoint( src->center_x, src->center_y ) ); arc->SetArcStart( wxPoint( src->start_x, src->start_y ) ); arc->SetAngle( src->result.GetCentralAngle() * 10.0 ); arc->SetWidth( src->width ); aBoard->Add( arc, ADD_MODE::APPEND ); break; } case GR_SHAPE_RECTANGLE: { const GRAPHIC_RECTANGLE *src = static_cast( seg.get() ); PCB_SHAPE* rect = new PCB_SHAPE( aBoard ); rect->SetShape( SHAPE_T::RECT ); rect->SetLayer( layer ); rect->SetStart( wxPoint( src->start_x, src->start_y ) ); rect->SetEnd( wxPoint( src->end_x, src->end_y ) ); rect->SetWidth( 0 ); aBoard->Add( rect, ADD_MODE::APPEND ); break; } case GR_SHAPE_TEXT: { const GRAPHIC_TEXT *src = static_cast( seg.get() ); PCB_TEXT* txt = new PCB_TEXT( aBoard ); txt->SetLayer( layer ); txt->SetTextPos( wxPoint( src->start_x, src->start_y - src->height / 2 ) ); txt->SetText( src->text ); txt->SetItalic( src->ital ); txt->SetTextThickness( src->thickness ); txt->SetTextHeight( src->height ); txt->SetTextWidth( src->width ); txt->SetHorizJustify( src->orient ); aBoard->Add( txt, ADD_MODE::APPEND ); break; } default: return false; } } } return true; } bool FABMASTER::orderZones( BOARD* aBoard ) { std::vector zones = aBoard->Zones(); std::sort( zones.begin(), zones.end(), [&]( const ZONE* a, const ZONE* b ) { if( a->GetLayer() == b->GetLayer() ) return a->GetBoundingBox().GetArea() > b->GetBoundingBox().GetArea(); return a->GetLayer() < b->GetLayer(); } ); PCB_LAYER_ID layer = UNDEFINED_LAYER; unsigned int priority = 0; for( ZONE* zone : zones ) { if( zone->GetLayer() != layer ) { layer = zone->GetLayer(); priority = 0; } zone->SetPriority( priority ); priority += 10; } return true; } bool FABMASTER::LoadBoard( BOARD* aBoard, PROGRESS_REPORTER* aProgressReporter ) { aBoard->SetFileName( m_filename.GetFullPath() ); m_progressReporter = aProgressReporter; m_totalCount = netnames.size() + layers.size() + vias.size() + components.size() + zones.size() + board_graphics.size() + traces.size(); m_doneCount = 0; loadNets( aBoard ); loadLayers( aBoard ); loadVias( aBoard ); loadFootprints( aBoard ); loadZones( aBoard ); loadGraphics( aBoard ); for( auto& track : traces ) { checkpoint(); if( track->lclass == "ETCH" ) { loadEtch( aBoard, track); } else if( track->layer == "OUTLINE" ) { loadOutline( aBoard, track ); } } orderZones( aBoard ); return true; }