/* * This program source code file is part of KiCad, a free EDA CAD application. * * 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 */ #include #include #include #include #include #include #include #include #include #include #include #include const int bdsSchemaVersion = 2; BOARD_DESIGN_SETTINGS::BOARD_DESIGN_SETTINGS( JSON_SETTINGS* aParent, const std::string& aPath ) : NESTED_SETTINGS( "board_design_settings", bdsSchemaVersion, aParent, aPath ) { // We want to leave alone parameters that aren't found in the project JSON as they may be // initialized by the board file parser before NESTED_SETTINGS::LoadFromFile is called. m_resetParamsIfMissing = false; // Create a default NET_SETTINGS so that things don't break horribly if there's no project // loaded. This also is used during file load for legacy boards that have netclasses stored // in the file. After load, this information will be moved to the project and the pointer // updated. m_NetSettings = std::make_shared( nullptr, "" ); m_HasStackup = false; // no stackup defined by default m_Pad_Master = std::make_unique( nullptr ); LSET all_set = LSET().set(); m_enabledLayers = all_set; // All layers enabled at first. // SetCopperLayerCount() will adjust this. SetCopperLayerCount( 2 ); // Default design is a double sided board m_CurrentViaType = VIATYPE::THROUGH; // if true, when creating a new track starting on an existing track, use this track width m_UseConnectedTrackWidth = false; m_TempOverrideTrackWidth = false; // First is always the reference designator m_DefaultFPTextItems.emplace_back( wxT( "REF**" ), true, F_SilkS ); // Second is always the value m_DefaultFPTextItems.emplace_back( wxT( "" ), true, F_Fab ); // Any following ones are freebies m_DefaultFPTextItems.emplace_back( wxT( "${REFERENCE}" ), true, F_Fab ); m_LineThickness[ LAYER_CLASS_SILK ] = pcbIUScale.mmToIU( DEFAULT_SILK_LINE_WIDTH ); m_TextSize[ LAYER_CLASS_SILK ] = VECTOR2I( pcbIUScale.mmToIU( DEFAULT_SILK_TEXT_SIZE ), pcbIUScale.mmToIU( DEFAULT_SILK_TEXT_SIZE ) ); m_TextThickness[ LAYER_CLASS_SILK ] = pcbIUScale.mmToIU( DEFAULT_SILK_TEXT_WIDTH ); m_TextItalic[ LAYER_CLASS_SILK ] = false; m_TextUpright[ LAYER_CLASS_SILK ] = false; m_LineThickness[ LAYER_CLASS_COPPER ] = pcbIUScale.mmToIU( DEFAULT_COPPER_LINE_WIDTH ); m_TextSize[ LAYER_CLASS_COPPER ] = VECTOR2I( pcbIUScale.mmToIU( DEFAULT_COPPER_TEXT_SIZE ), pcbIUScale.mmToIU( DEFAULT_COPPER_TEXT_SIZE ) ); m_TextThickness[ LAYER_CLASS_COPPER ] = pcbIUScale.mmToIU( DEFAULT_COPPER_TEXT_WIDTH ); m_TextItalic[ LAYER_CLASS_COPPER ] = false; m_TextUpright[ LAYER_CLASS_COPPER ] = false; // Edges & Courtyards; text properties aren't used but better to have them holding // reasonable values than not. m_LineThickness[ LAYER_CLASS_EDGES ] = pcbIUScale.mmToIU( DEFAULT_EDGE_WIDTH ); m_TextSize[ LAYER_CLASS_EDGES ] = VECTOR2I( pcbIUScale.mmToIU( DEFAULT_TEXT_SIZE ), pcbIUScale.mmToIU( DEFAULT_TEXT_SIZE ) ); m_TextThickness[ LAYER_CLASS_EDGES ] = pcbIUScale.mmToIU( DEFAULT_TEXT_WIDTH ); m_TextItalic[ LAYER_CLASS_EDGES ] = false; m_TextUpright[ LAYER_CLASS_EDGES ] = false; m_LineThickness[ LAYER_CLASS_COURTYARD ] = pcbIUScale.mmToIU( DEFAULT_COURTYARD_WIDTH ); m_TextSize[ LAYER_CLASS_COURTYARD ] = VECTOR2I( pcbIUScale.mmToIU( DEFAULT_TEXT_SIZE ), pcbIUScale.mmToIU( DEFAULT_TEXT_SIZE ) ); m_TextThickness[ LAYER_CLASS_COURTYARD ] = pcbIUScale.mmToIU( DEFAULT_TEXT_WIDTH ); m_TextItalic[ LAYER_CLASS_COURTYARD ] = false; m_TextUpright[ LAYER_CLASS_COURTYARD ] = false; m_LineThickness[ LAYER_CLASS_FAB ] = pcbIUScale.mmToIU( DEFAULT_LINE_WIDTH ); m_TextSize[LAYER_CLASS_FAB] = VECTOR2I( pcbIUScale.mmToIU( DEFAULT_TEXT_SIZE ), pcbIUScale.mmToIU( DEFAULT_TEXT_SIZE ) ); m_TextThickness[ LAYER_CLASS_FAB ] = pcbIUScale.mmToIU( DEFAULT_TEXT_WIDTH ); m_TextItalic[ LAYER_CLASS_FAB ] = false; m_TextUpright[ LAYER_CLASS_FAB ] = false; m_LineThickness[ LAYER_CLASS_OTHERS ] = pcbIUScale.mmToIU( DEFAULT_LINE_WIDTH ); m_TextSize[ LAYER_CLASS_OTHERS ] = VECTOR2I( pcbIUScale.mmToIU( DEFAULT_TEXT_SIZE ), pcbIUScale.mmToIU( DEFAULT_TEXT_SIZE ) ); m_TextThickness[ LAYER_CLASS_OTHERS ] = pcbIUScale.mmToIU( DEFAULT_TEXT_WIDTH ); m_TextItalic[ LAYER_CLASS_OTHERS ] = false; m_TextUpright[ LAYER_CLASS_OTHERS ] = false; m_StyleFPFields = false; m_StyleFPText = false; m_StyleFPShapes = false; m_DimensionPrecision = DIM_PRECISION::X_XXXX; m_DimensionUnitsMode = DIM_UNITS_MODE::AUTOMATIC; m_DimensionUnitsFormat = DIM_UNITS_FORMAT::BARE_SUFFIX; m_DimensionSuppressZeroes = false; m_DimensionTextPosition = DIM_TEXT_POSITION::OUTSIDE; m_DimensionKeepTextAligned = true; m_DimensionArrowLength = pcbIUScale.MilsToIU( DEFAULT_DIMENSION_ARROW_LENGTH ); m_DimensionExtensionOffset = pcbIUScale.mmToIU( DEFAULT_DIMENSION_EXTENSION_OFFSET ); m_useCustomTrackVia = false; m_customTrackWidth = pcbIUScale.mmToIU( DEFAULT_CUSTOMTRACKWIDTH ); m_customViaSize.m_Diameter = pcbIUScale.mmToIU( DEFAULT_VIASMINSIZE ); m_customViaSize.m_Drill = pcbIUScale.mmToIU( DEFAULT_MINTHROUGHDRILL ); m_useCustomDiffPair = false; m_customDiffPair.m_Width = pcbIUScale.mmToIU( DEFAULT_CUSTOMDPAIRWIDTH ); m_customDiffPair.m_Gap = pcbIUScale.mmToIU( DEFAULT_CUSTOMDPAIRGAP ); m_customDiffPair.m_ViaGap = pcbIUScale.mmToIU( DEFAULT_CUSTOMDPAIRVIAGAP ); m_MinClearance = pcbIUScale.mmToIU( DEFAULT_MINCLEARANCE ); m_MinConn = pcbIUScale.mmToIU( DEFAULT_MINCONNECTION ); m_TrackMinWidth = pcbIUScale.mmToIU( DEFAULT_TRACKMINWIDTH ); m_ViasMinAnnularWidth = pcbIUScale.mmToIU( DEFAULT_VIASMINSIZE - DEFAULT_MINTHROUGHDRILL ) / 2; m_ViasMinSize = pcbIUScale.mmToIU( DEFAULT_VIASMINSIZE ); m_MinThroughDrill = pcbIUScale.mmToIU( DEFAULT_MINTHROUGHDRILL ); m_MicroViasMinSize = pcbIUScale.mmToIU( DEFAULT_MICROVIASMINSIZE ); m_MicroViasMinDrill = pcbIUScale.mmToIU( DEFAULT_MICROVIASMINDRILL ); m_CopperEdgeClearance = pcbIUScale.mmToIU( DEFAULT_COPPEREDGECLEARANCE ); m_HoleClearance = pcbIUScale.mmToIU( DEFAULT_HOLECLEARANCE ); m_HoleToHoleMin = pcbIUScale.mmToIU( DEFAULT_HOLETOHOLEMIN ); m_SilkClearance = pcbIUScale.mmToIU( DEFAULT_SILKCLEARANCE ); m_MinResolvedSpokes = DEFAULT_MINRESOLVEDSPOKES; m_MinSilkTextHeight = pcbIUScale.mmToIU( DEFAULT_SILK_TEXT_SIZE * 0.8 ); m_MinSilkTextThickness= pcbIUScale.mmToIU( DEFAULT_SILK_TEXT_WIDTH * 0.8 ); for( int errorCode = DRCE_FIRST; errorCode <= DRCE_LAST; ++errorCode ) m_DRCSeverities[ errorCode ] = RPT_SEVERITY_ERROR; m_DRCSeverities[ DRCE_DRILLED_HOLES_COLOCATED ] = RPT_SEVERITY_WARNING; m_DRCSeverities[ DRCE_MISSING_COURTYARD ] = RPT_SEVERITY_IGNORE; m_DRCSeverities[ DRCE_PTH_IN_COURTYARD ] = RPT_SEVERITY_IGNORE; m_DRCSeverities[ DRCE_NPTH_IN_COURTYARD ] = RPT_SEVERITY_IGNORE; m_DRCSeverities[ DRCE_DANGLING_TRACK ] = RPT_SEVERITY_WARNING; m_DRCSeverities[ DRCE_DANGLING_VIA ] = RPT_SEVERITY_WARNING; m_DRCSeverities[ DRCE_COPPER_SLIVER ] = RPT_SEVERITY_WARNING; m_DRCSeverities[ DRCE_ISOLATED_COPPER ] = RPT_SEVERITY_WARNING; m_DRCSeverities[ DRCE_PADSTACK ] = RPT_SEVERITY_WARNING; m_DRCSeverities[ DRCE_MISSING_FOOTPRINT ] = RPT_SEVERITY_WARNING; m_DRCSeverities[ DRCE_DUPLICATE_FOOTPRINT ] = RPT_SEVERITY_WARNING; m_DRCSeverities[ DRCE_EXTRA_FOOTPRINT ] = RPT_SEVERITY_WARNING; m_DRCSeverities[ DRCE_NET_CONFLICT ] = RPT_SEVERITY_WARNING; m_DRCSeverities[ DRCE_OVERLAPPING_SILK ] = RPT_SEVERITY_WARNING; m_DRCSeverities[ DRCE_SILK_CLEARANCE ] = RPT_SEVERITY_WARNING; m_DRCSeverities[ DRCE_SILK_EDGE_CLEARANCE ] = RPT_SEVERITY_WARNING; m_DRCSeverities[ DRCE_TEXT_HEIGHT ] = RPT_SEVERITY_WARNING; m_DRCSeverities[ DRCE_TEXT_THICKNESS ] = RPT_SEVERITY_WARNING; m_DRCSeverities[ DRCE_FOOTPRINT_TYPE_MISMATCH ] = RPT_SEVERITY_IGNORE; m_DRCSeverities[ DRCE_LIB_FOOTPRINT_ISSUES ] = RPT_SEVERITY_WARNING; m_DRCSeverities[ DRCE_LIB_FOOTPRINT_MISMATCH ] = RPT_SEVERITY_WARNING; m_DRCSeverities[ DRCE_CONNECTION_WIDTH ] = RPT_SEVERITY_WARNING; m_MaxError = ARC_HIGH_DEF; m_ZoneKeepExternalFillets = false; m_UseHeightForLengthCalcs = true; // Global mask margins: m_SolderMaskExpansion = pcbIUScale.mmToIU( DEFAULT_SOLDERMASK_EXPANSION ); m_SolderMaskMinWidth = pcbIUScale.mmToIU( DEFAULT_SOLDERMASK_MIN_WIDTH ); m_SolderMaskToCopperClearance = pcbIUScale.mmToIU( DEFAULT_SOLDERMASK_TO_COPPER_CLEARANCE ); // Solder paste margin absolute value m_SolderPasteMargin = pcbIUScale.mmToIU( DEFAULT_SOLDERPASTE_CLEARANCE ); // Solder paste margin as a ratio of pad size // The final margin is the sum of these 2 values // Usually < 0 because the mask is smaller than pad m_SolderPasteMarginRatio = DEFAULT_SOLDERPASTE_RATIO; m_AllowSoldermaskBridgesInFPs = false; // Layer thickness for 3D viewer m_boardThickness = pcbIUScale.mmToIU( DEFAULT_BOARD_THICKNESS_MM ); m_viaSizeIndex = 0; m_trackWidthIndex = 0; m_diffPairIndex = 0; // Parameters stored in JSON in the project file // NOTE: Previously, BOARD_DESIGN_SETTINGS stored the basic board layer information (layer // names and enable/disable state) in the project file even though this information is also // stored in the board file. This was implemented for importing these settings from another // project. Going forward, the import feature will just import from other board files (since // we could have multi-board projects in the future anyway) so this functionality is dropped. m_params.emplace_back( new PARAM( "rules.use_height_for_length_calcs", &m_UseHeightForLengthCalcs, true ) ); m_params.emplace_back( new PARAM_SCALED( "rules.min_clearance", &m_MinClearance, pcbIUScale.mmToIU( DEFAULT_MINCLEARANCE ), pcbIUScale.mmToIU( 0.00 ), pcbIUScale.mmToIU( 25.0 ), pcbIUScale.MM_PER_IU ) ); m_params.emplace_back( new PARAM_SCALED( "rules.min_connection", &m_MinConn, pcbIUScale.mmToIU( DEFAULT_MINCONNECTION ), pcbIUScale.mmToIU( 0.00 ), pcbIUScale.mmToIU( 100.0 ), pcbIUScale.MM_PER_IU ) ); m_params.emplace_back( new PARAM_SCALED( "rules.min_track_width", &m_TrackMinWidth, pcbIUScale.mmToIU( DEFAULT_TRACKMINWIDTH ), pcbIUScale.mmToIU( 0.00 ), pcbIUScale.mmToIU( 25.0 ), pcbIUScale.MM_PER_IU ) ); m_params.emplace_back( new PARAM_SCALED( "rules.min_via_annular_width", &m_ViasMinAnnularWidth, pcbIUScale.mmToIU( DEFAULT_VIASMINSIZE ), pcbIUScale.mmToIU( 0.00 ), pcbIUScale.mmToIU( 25.0 ), pcbIUScale.MM_PER_IU ) ); m_params.emplace_back( new PARAM_SCALED( "rules.min_via_diameter", &m_ViasMinSize, pcbIUScale.mmToIU( DEFAULT_VIASMINSIZE ), pcbIUScale.mmToIU( 0.00 ), pcbIUScale.mmToIU( 25.0 ), pcbIUScale.MM_PER_IU ) ); m_params.emplace_back( new PARAM_SCALED( "rules.min_through_hole_diameter", &m_MinThroughDrill, pcbIUScale.mmToIU( DEFAULT_MINTHROUGHDRILL ), pcbIUScale.mmToIU( 0.00 ), pcbIUScale.mmToIU( 25.0 ), pcbIUScale.MM_PER_IU ) ); m_params.emplace_back( new PARAM_SCALED( "rules.min_microvia_diameter", &m_MicroViasMinSize, pcbIUScale.mmToIU( DEFAULT_MICROVIASMINSIZE ), pcbIUScale.mmToIU( 0.00 ), pcbIUScale.mmToIU( 10.0 ), pcbIUScale.MM_PER_IU ) ); m_params.emplace_back( new PARAM_SCALED( "rules.min_microvia_drill", &m_MicroViasMinDrill, pcbIUScale.mmToIU( DEFAULT_MICROVIASMINDRILL ), pcbIUScale.mmToIU( 0.00 ), pcbIUScale.mmToIU( 10.0 ), pcbIUScale.MM_PER_IU ) ); m_params.emplace_back( new PARAM_SCALED( "rules.min_hole_to_hole", &m_HoleToHoleMin, pcbIUScale.mmToIU( DEFAULT_HOLETOHOLEMIN ), pcbIUScale.mmToIU( 0.00 ), pcbIUScale.mmToIU( 10.0 ), pcbIUScale.MM_PER_IU ) ); m_params.emplace_back( new PARAM_SCALED( "rules.min_hole_clearance", &m_HoleClearance, pcbIUScale.mmToIU( DEFAULT_HOLECLEARANCE ), pcbIUScale.mmToIU( 0.00 ), pcbIUScale.mmToIU( 100.0 ), pcbIUScale.MM_PER_IU ) ); m_params.emplace_back( new PARAM_SCALED( "rules.min_silk_clearance", &m_SilkClearance, pcbIUScale.mmToIU( DEFAULT_SILKCLEARANCE ), pcbIUScale.mmToIU( 0.00 ), pcbIUScale.mmToIU( 100.0 ), pcbIUScale.MM_PER_IU ) ); // While the maximum *effective* value is 4, we've had users interpret this as the count on // all layers, and enter something like 10. They'll figure it out soon enough *unless* we // enforce a max of 4 (and therefore reset it back to the default of 2), at which point it // just looks buggy. m_params.emplace_back( new PARAM( "rules.min_resolved_spokes", &m_MinResolvedSpokes, DEFAULT_MINRESOLVEDSPOKES, 0, 99 ) ); m_params.emplace_back( new PARAM_SCALED( "rules.min_text_height", &m_MinSilkTextHeight, pcbIUScale.mmToIU( DEFAULT_SILK_TEXT_SIZE * 0.8 ), pcbIUScale.mmToIU( 0.00 ), pcbIUScale.mmToIU( 100.0 ), pcbIUScale.MM_PER_IU ) ); m_params.emplace_back( new PARAM_SCALED( "rules.min_text_thickness", &m_MinSilkTextThickness, pcbIUScale.mmToIU( DEFAULT_SILK_TEXT_WIDTH * 0.8 ), pcbIUScale.mmToIU( 0.00 ), pcbIUScale.mmToIU( 25.0 ), pcbIUScale.MM_PER_IU ) ); // Note: a clearance of -0.01 is a flag indicating we should use the legacy (pre-6.0) method // based on the edge cut thicknesses. m_params.emplace_back( new PARAM_SCALED( "rules.min_copper_edge_clearance", &m_CopperEdgeClearance, pcbIUScale.mmToIU( LEGACY_COPPEREDGECLEARANCE ), pcbIUScale.mmToIU( -0.01 ), pcbIUScale.mmToIU( 25.0 ), pcbIUScale.MM_PER_IU ) ); m_params.emplace_back( new PARAM_LAMBDA( "rule_severities", [&]() -> nlohmann::json { nlohmann::json ret = {}; for( const RC_ITEM& item : DRC_ITEM::GetItemsWithSeverities() ) { wxString name = item.GetSettingsKey(); int code = item.GetErrorCode(); if( name.IsEmpty() || m_DRCSeverities.count( code ) == 0 ) continue; ret[std::string( name.ToUTF8() )] = SeverityToString( m_DRCSeverities[code] ); } return ret; }, [&]( const nlohmann::json& aJson ) { if( !aJson.is_object() ) return; for( const RC_ITEM& item : DRC_ITEM::GetItemsWithSeverities() ) { wxString name = item.GetSettingsKey(); std::string key( name.ToUTF8() ); if( aJson.contains( key ) ) m_DRCSeverities[item.GetErrorCode()] = SeverityFromString( aJson[key] ); } }, {} ) ); m_params.emplace_back( new PARAM_LAMBDA( "drc_exclusions", [&]() -> nlohmann::json { nlohmann::json js = nlohmann::json::array(); for( const auto& entry : m_DrcExclusions ) js.push_back( entry ); return js; }, [&]( const nlohmann::json& aObj ) { m_DrcExclusions.clear(); if( !aObj.is_array() ) return; for( const nlohmann::json& entry : aObj ) { if( entry.empty() ) continue; m_DrcExclusions.insert( entry.get() ); } }, {} ) ); m_params.emplace_back( new PARAM_LAMBDA( "track_widths", [&]() -> nlohmann::json { nlohmann::json js = nlohmann::json::array(); for( const int& width : m_TrackWidthList ) js.push_back( pcbIUScale.IUTomm( width ) ); return js; }, [&]( const nlohmann::json& aJson ) { if( !aJson.is_array() ) return; m_TrackWidthList.clear(); for( const nlohmann::json& entry : aJson ) { if( entry.empty() ) continue; m_TrackWidthList.emplace_back( pcbIUScale.mmToIU( entry.get() ) ); } }, {} ) ); m_params.emplace_back( new PARAM_LAMBDA( "via_dimensions", [&]() -> nlohmann::json { nlohmann::json js = nlohmann::json::array(); for( const auto& via : m_ViasDimensionsList ) { nlohmann::json entry = {}; entry["diameter"] = pcbIUScale.IUTomm( via.m_Diameter ); entry["drill"] = pcbIUScale.IUTomm( via.m_Drill ); js.push_back( entry ); } return js; }, [&]( const nlohmann::json& aObj ) { if( !aObj.is_array() ) return; m_ViasDimensionsList.clear(); for( const nlohmann::json& entry : aObj ) { if( entry.empty() || !entry.is_object() ) continue; if( !entry.contains( "diameter" ) || !entry.contains( "drill" ) ) continue; int diameter = pcbIUScale.mmToIU( entry["diameter"].get() ); int drill = pcbIUScale.mmToIU( entry["drill"].get() ); m_ViasDimensionsList.emplace_back( VIA_DIMENSION( diameter, drill ) ); } }, {} ) ); m_params.emplace_back( new PARAM_LAMBDA( "diff_pair_dimensions", [&]() -> nlohmann::json { nlohmann::json js = nlohmann::json::array(); for( const auto& pair : m_DiffPairDimensionsList ) { nlohmann::json entry = {}; entry["width"] = pcbIUScale.IUTomm( pair.m_Width ); entry["gap"] = pcbIUScale.IUTomm( pair.m_Gap ); entry["via_gap"] = pcbIUScale.IUTomm( pair.m_ViaGap ); js.push_back( entry ); } return js; }, [&]( const nlohmann::json& aObj ) { if( !aObj.is_array() ) return; m_DiffPairDimensionsList.clear(); for( const nlohmann::json& entry : aObj ) { if( entry.empty() || !entry.is_object() ) continue; if( !entry.contains( "width" ) || !entry.contains( "gap" ) || !entry.contains( "via_gap" ) ) continue; int width = pcbIUScale.mmToIU( entry["width"].get() ); int gap = pcbIUScale.mmToIU( entry["gap"].get() ); int via_gap = pcbIUScale.mmToIU( entry["via_gap"].get() ); m_DiffPairDimensionsList.emplace_back( DIFF_PAIR_DIMENSION( width, gap, via_gap ) ); } }, {} ) ); // Handle options for teardrops (targets and some others): m_params.emplace_back( new PARAM_LAMBDA( "teardrop_options", [&]() -> nlohmann::json { nlohmann::json js = nlohmann::json::array(); nlohmann::json entry = {}; entry["td_onviapad"] = m_TeardropParamsList.m_TargetViasPads; entry["td_onpadsmd"] = m_TeardropParamsList.m_TargetPadsWithNoHole; entry["td_ontrackend"] = m_TeardropParamsList.m_TargetTrack2Track; entry["td_onroundshapesonly"] = m_TeardropParamsList.m_UseRoundShapesOnly; js.push_back( entry ); return js; }, [&]( const nlohmann::json& aObj ) { if( !aObj.is_array() ) return; for( const nlohmann::json& entry : aObj ) { if( entry.empty() || !entry.is_object() ) continue; if( entry.contains( "td_onviapad" ) ) m_TeardropParamsList.m_TargetViasPads = entry["td_onviapad"].get(); if( entry.contains( "td_onpadsmd" ) ) m_TeardropParamsList.m_TargetPadsWithNoHole = entry["td_onpadsmd"].get(); if( entry.contains( "td_ontrackend" ) ) m_TeardropParamsList.m_TargetTrack2Track = entry["td_ontrackend"].get(); if( entry.contains( "td_onroundshapesonly" ) ) m_TeardropParamsList.m_UseRoundShapesOnly = entry["td_onroundshapesonly"].get(); // Legacy settings for( int ii = 0; ii < 3; ++ii ) { TEARDROP_PARAMETERS* td_prm = m_TeardropParamsList.GetParameters( (TARGET_TD)ii ); if( entry.contains( "td_allow_use_two_tracks" ) ) td_prm->m_AllowUseTwoTracks = entry["td_allow_use_two_tracks"].get(); if( entry.contains( "td_curve_segcount" ) ) td_prm->m_CurveSegCount = entry["td_curve_segcount"].get(); if( entry.contains( "td_on_pad_in_zone" ) ) td_prm->m_TdOnPadsInZones = entry["td_on_pad_in_zone"].get(); } } }, {} ) ); // Handle parameters (sizes, shape) for each type of teardrop: m_params.emplace_back( new PARAM_LAMBDA( "teardrop_parameters", [&]() -> nlohmann::json { nlohmann::json js = nlohmann::json::array(); for( size_t ii = 0; ii < m_TeardropParamsList.GetParametersCount(); ii++ ) { nlohmann::json entry = {}; TEARDROP_PARAMETERS* td_prm = m_TeardropParamsList.GetParameters( (TARGET_TD)ii ); entry["td_target_name"] = GetTeardropTargetCanonicalName( (TARGET_TD)ii ); entry["td_maxlen"] = pcbIUScale.IUTomm( td_prm->m_TdMaxLen ); entry["td_maxheight"] = pcbIUScale.IUTomm( td_prm->m_TdMaxWidth ); entry["td_length_ratio"] = td_prm->m_BestLengthRatio; entry["td_height_ratio"] = td_prm->m_BestWidthRatio; entry["td_curve_segcount"] = td_prm->m_CurveSegCount; entry["td_width_to_size_filter_ratio"] = td_prm->m_WidthtoSizeFilterRatio; entry["td_allow_use_two_tracks"] = td_prm->m_AllowUseTwoTracks; entry["td_curve_segcount"] = td_prm->m_CurveSegCount; entry["td_on_pad_in_zone"] = td_prm->m_TdOnPadsInZones; js.push_back( entry ); } return js; }, [&]( const nlohmann::json& aObj ) { if( !aObj.is_array() ) return; for( const nlohmann::json& entry : aObj ) { if( entry.empty() || !entry.is_object() ) continue; if( !entry.contains( "td_target_name" ) ) continue; int idx = GetTeardropTargetTypeFromCanonicalName( entry["td_target_name"].get() ); if( idx >= 0 && idx < 3 ) { TEARDROP_PARAMETERS* td_prm = m_TeardropParamsList.GetParameters( (TARGET_TD)idx ); if( entry.contains( "td_maxlen" ) ) td_prm->m_TdMaxLen = pcbIUScale.mmToIU( entry["td_maxlen"].get() ); if( entry.contains( "td_maxheight" ) ) td_prm->m_TdMaxWidth = pcbIUScale.mmToIU( entry["td_maxheight"].get() ); if( entry.contains( "td_length_ratio" ) ) td_prm->m_BestLengthRatio = entry["td_length_ratio"].get(); if( entry.contains( "td_height_ratio" ) ) td_prm->m_BestWidthRatio = entry["td_height_ratio"].get(); if( entry.contains( "td_curve_segcount" ) ) td_prm->m_CurveSegCount = entry["td_curve_segcount"].get(); if( entry.contains( "td_width_to_size_filter_ratio" ) ) td_prm->m_WidthtoSizeFilterRatio = entry["td_width_to_size_filter_ratio"].get(); if( entry.contains( "td_allow_use_two_tracks" ) ) td_prm->m_AllowUseTwoTracks = entry["td_allow_use_two_tracks"].get(); if( entry.contains( "td_curve_segcount" ) ) td_prm->m_CurveSegCount = entry["td_curve_segcount"].get(); if( entry.contains( "td_on_pad_in_zone" ) ) td_prm->m_TdOnPadsInZones = entry["td_on_pad_in_zone"].get(); } } }, {} ) ); m_params.emplace_back( new PARAM_LAMBDA( "tuning_pattern_settings", [&]() -> nlohmann::json { nlohmann::json js = {}; auto make_settings = []( const PNS::MEANDER_SETTINGS& aSettings ) { nlohmann::json entry = {}; entry["min_amplitude"] = pcbIUScale.IUTomm( aSettings.m_minAmplitude ); entry["max_amplitude"] = pcbIUScale.IUTomm( aSettings.m_maxAmplitude ); entry["spacing"] = pcbIUScale.IUTomm( aSettings.m_spacing ); entry["corner_style"] = aSettings.m_cornerStyle == PNS::MEANDER_STYLE_CHAMFER ? 0 : 1; entry["corner_radius_percentage"] = aSettings.m_cornerRadiusPercentage; entry["single_sided"] = aSettings.m_singleSided; return entry; }; js["single_track_defaults"] = make_settings( m_singleTrackMeanderSettings ); js["diff_pair_defaults"] = make_settings( m_diffPairMeanderSettings ); js["diff_pair_skew_defaults"] = make_settings( m_skewMeanderSettings ); return js; }, [&]( const nlohmann::json& aObj ) { auto read_settings = []( const nlohmann::json& entry ) -> PNS::MEANDER_SETTINGS { PNS::MEANDER_SETTINGS settings; if( entry.contains( "min_amplitude" ) ) settings.m_minAmplitude = pcbIUScale.mmToIU( entry["min_amplitude"].get() ); if( entry.contains( "max_amplitude" ) ) settings.m_maxAmplitude = pcbIUScale.mmToIU( entry["max_amplitude"].get() ); if( entry.contains( "spacing" ) ) settings.m_spacing = pcbIUScale.mmToIU( entry["spacing"].get() ); if( entry.contains( "corner_style" ) ) { settings.m_cornerStyle = entry["corner_style"] == 0 ? PNS::MEANDER_STYLE_CHAMFER : PNS::MEANDER_STYLE_ROUND; } if( entry.contains( "corner_radius_percentage" ) ) settings.m_cornerRadiusPercentage = entry["corner_radius_percentage"].get(); if( entry.contains( "single_sided" ) ) settings.m_singleSided = entry["single_sided"].get(); return settings; }; if( aObj.contains( "single_track_defaults" ) ) m_singleTrackMeanderSettings = read_settings( aObj["single_track_defaults"] ); if( aObj.contains( "diff_pair_defaults" ) ) m_diffPairMeanderSettings = read_settings( aObj["diff_pair_defaults"] ); if( aObj.contains( "diff_pair_skew_defaults" ) ) m_skewMeanderSettings = read_settings( aObj["diff_pair_skew_defaults"] ); }, {} ) ); int minTextSize = pcbIUScale.MilsToIU( TEXT_MIN_SIZE_MILS ); int maxTextSize = pcbIUScale.MilsToIU( TEXT_MAX_SIZE_MILS ); int minStroke = 1; int maxStroke = pcbIUScale.mmToIU( 100 ); m_params.emplace_back( new PARAM_SCALED( "defaults.silk_line_width", &m_LineThickness[LAYER_CLASS_SILK], pcbIUScale.mmToIU( DEFAULT_SILK_LINE_WIDTH ), minStroke, maxStroke, pcbIUScale.MM_PER_IU ) ); m_params.emplace_back( new PARAM_SCALED( "defaults.silk_text_size_v", &m_TextSize[LAYER_CLASS_SILK].y, pcbIUScale.mmToIU( DEFAULT_SILK_TEXT_SIZE ), minTextSize, maxTextSize, pcbIUScale.MM_PER_IU ) ); m_params.emplace_back( new PARAM_SCALED( "defaults.silk_text_size_h", &m_TextSize[LAYER_CLASS_SILK].x, pcbIUScale.mmToIU( DEFAULT_SILK_TEXT_SIZE ), minTextSize, maxTextSize, pcbIUScale.MM_PER_IU ) ); m_params.emplace_back( new PARAM_SCALED( "defaults.silk_text_thickness", &m_TextThickness[LAYER_CLASS_SILK], pcbIUScale.mmToIU( DEFAULT_SILK_TEXT_WIDTH ), minStroke, maxStroke, pcbIUScale.MM_PER_IU ) ); m_params.emplace_back( new PARAM( "defaults.silk_text_italic", &m_TextItalic[LAYER_CLASS_SILK], false ) ); m_params.emplace_back( new PARAM( "defaults.silk_text_upright", &m_TextUpright[ LAYER_CLASS_SILK ], true ) ); m_params.emplace_back( new PARAM_SCALED( "defaults.copper_line_width", &m_LineThickness[LAYER_CLASS_COPPER], pcbIUScale.mmToIU( DEFAULT_COPPER_LINE_WIDTH ), minStroke, maxStroke, pcbIUScale.MM_PER_IU ) ); m_params.emplace_back( new PARAM_SCALED( "defaults.copper_text_size_v", &m_TextSize[LAYER_CLASS_COPPER].y, pcbIUScale.mmToIU( DEFAULT_COPPER_TEXT_SIZE ), minTextSize, maxTextSize, pcbIUScale.MM_PER_IU ) ); m_params.emplace_back( new PARAM_SCALED( "defaults.copper_text_size_h", &m_TextSize[LAYER_CLASS_COPPER].x, pcbIUScale.mmToIU( DEFAULT_COPPER_TEXT_SIZE ), minTextSize, maxTextSize, pcbIUScale.MM_PER_IU ) ); m_params.emplace_back( new PARAM_SCALED( "defaults.copper_text_thickness", &m_TextThickness[LAYER_CLASS_COPPER], pcbIUScale.mmToIU( DEFAULT_COPPER_TEXT_WIDTH ), minStroke, maxStroke, pcbIUScale.MM_PER_IU ) ); m_params.emplace_back( new PARAM( "defaults.copper_text_italic", &m_TextItalic[LAYER_CLASS_COPPER], false ) ); m_params.emplace_back( new PARAM( "defaults.copper_text_upright", &m_TextUpright[LAYER_CLASS_COPPER], true ) ); m_params.emplace_back( new PARAM_SCALED( "defaults.board_outline_line_width", &m_LineThickness[LAYER_CLASS_EDGES], pcbIUScale.mmToIU( DEFAULT_EDGE_WIDTH ), minStroke, maxStroke, pcbIUScale.MM_PER_IU ) ); m_params.emplace_back( new PARAM_SCALED( "defaults.courtyard_line_width", &m_LineThickness[LAYER_CLASS_COURTYARD], pcbIUScale.mmToIU( DEFAULT_COURTYARD_WIDTH ), minStroke, maxStroke, pcbIUScale.MM_PER_IU ) ); m_params.emplace_back( new PARAM_SCALED( "defaults.fab_line_width", &m_LineThickness[LAYER_CLASS_FAB], pcbIUScale.mmToIU( DEFAULT_LINE_WIDTH ), minStroke, maxStroke, pcbIUScale.MM_PER_IU ) ); m_params.emplace_back( new PARAM_SCALED( "defaults.fab_text_size_v", &m_TextSize[LAYER_CLASS_FAB].y, pcbIUScale.mmToIU( DEFAULT_TEXT_SIZE ), minTextSize, maxTextSize, pcbIUScale.MM_PER_IU ) ); m_params.emplace_back( new PARAM_SCALED( "defaults.fab_text_size_h", &m_TextSize[LAYER_CLASS_FAB].x, pcbIUScale.mmToIU( DEFAULT_TEXT_SIZE ), minTextSize, maxTextSize, pcbIUScale.MM_PER_IU ) ); m_params.emplace_back( new PARAM_SCALED( "defaults.fab_text_thickness", &m_TextThickness[LAYER_CLASS_FAB], pcbIUScale.mmToIU( DEFAULT_TEXT_WIDTH ), minStroke, maxStroke, pcbIUScale.MM_PER_IU ) ); m_params.emplace_back( new PARAM( "defaults.fab_text_italic", &m_TextItalic[LAYER_CLASS_FAB], false ) ); m_params.emplace_back( new PARAM( "defaults.fab_text_upright", &m_TextUpright[LAYER_CLASS_FAB], true ) ); m_params.emplace_back( new PARAM_SCALED( "defaults.other_line_width", &m_LineThickness[LAYER_CLASS_OTHERS], pcbIUScale.mmToIU( DEFAULT_LINE_WIDTH ), minStroke, maxStroke, pcbIUScale.MM_PER_IU ) ); m_params.emplace_back( new PARAM_SCALED( "defaults.other_text_size_v", &m_TextSize[LAYER_CLASS_OTHERS].y, pcbIUScale.mmToIU( DEFAULT_TEXT_SIZE ), minTextSize, maxTextSize, pcbIUScale.MM_PER_IU ) ); m_params.emplace_back( new PARAM_SCALED( "defaults.other_text_size_h", &m_TextSize[LAYER_CLASS_OTHERS].x, pcbIUScale.mmToIU( DEFAULT_TEXT_SIZE ), minTextSize, maxTextSize, pcbIUScale.MM_PER_IU ) ); m_params.emplace_back( new PARAM_SCALED( "defaults.other_text_thickness", &m_TextThickness[LAYER_CLASS_OTHERS], pcbIUScale.mmToIU( DEFAULT_TEXT_WIDTH ), minStroke, maxStroke, pcbIUScale.MM_PER_IU ) ); m_params.emplace_back( new PARAM( "defaults.other_text_italic", &m_TextItalic[LAYER_CLASS_OTHERS], false ) ); m_params.emplace_back( new PARAM( "defaults.other_text_upright", &m_TextUpright[LAYER_CLASS_OTHERS], true ) ); m_params.emplace_back( new PARAM_ENUM( "defaults.dimension_units", &m_DimensionUnitsMode, DIM_UNITS_MODE::AUTOMATIC, DIM_UNITS_MODE::INCHES, DIM_UNITS_MODE::AUTOMATIC ) ); m_params.emplace_back( new PARAM_ENUM( "defaults.dimension_precision", &m_DimensionPrecision, DIM_PRECISION::X_XXXX, DIM_PRECISION::X, DIM_PRECISION::V_VVVVV ) ); m_params.emplace_back( new PARAM_ENUM( "defaults.dimensions.units_format", &m_DimensionUnitsFormat, DIM_UNITS_FORMAT::BARE_SUFFIX, DIM_UNITS_FORMAT::NO_SUFFIX, DIM_UNITS_FORMAT::PAREN_SUFFIX ) ); m_params.emplace_back( new PARAM( "defaults.dimensions.suppress_zeroes", &m_DimensionSuppressZeroes, false ) ); // NOTE: excluding DIM_TEXT_POSITION::MANUAL from the valid range here m_params.emplace_back( new PARAM_ENUM( "defaults.dimensions.text_position", &m_DimensionTextPosition, DIM_TEXT_POSITION::OUTSIDE, DIM_TEXT_POSITION::OUTSIDE, DIM_TEXT_POSITION::INLINE ) ); m_params.emplace_back( new PARAM( "defaults.dimensions.keep_text_aligned", &m_DimensionKeepTextAligned, true ) ); m_params.emplace_back( new PARAM( "defaults.dimensions.arrow_length", &m_DimensionArrowLength, pcbIUScale.MilsToIU( DEFAULT_DIMENSION_ARROW_LENGTH ) ) ); m_params.emplace_back( new PARAM( "defaults.dimensions.extension_offset", &m_DimensionExtensionOffset, pcbIUScale.mmToIU( DEFAULT_DIMENSION_EXTENSION_OFFSET ) ) ); m_params.emplace_back( new PARAM( "defaults.apply_defaults_to_fp_fields", &m_StyleFPFields, false ) ); m_params.emplace_back( new PARAM( "defaults.apply_defaults_to_fp_text", &m_StyleFPText, false ) ); m_params.emplace_back( new PARAM( "defaults.apply_defaults_to_fp_shapes", &m_StyleFPShapes, false ) ); m_params.emplace_back( new PARAM_SCALED( "defaults.zones.min_clearance", &m_defaultZoneSettings.m_ZoneClearance, pcbIUScale.mmToIU( ZONE_CLEARANCE_MM ), pcbIUScale.mmToIU( 0.0 ), pcbIUScale.mmToIU( 25.0 ), pcbIUScale.MM_PER_IU ) ); m_params.emplace_back( new PARAM_LAMBDA( "defaults.pads", [&]() -> nlohmann::json { nlohmann::json ret = { { "width", pcbIUScale.IUTomm( m_Pad_Master->GetSize().x ) }, { "height", pcbIUScale.IUTomm( m_Pad_Master->GetSize().y ) }, { "drill", pcbIUScale.IUTomm( m_Pad_Master->GetDrillSize().x ) } }; return ret; }, [&]( const nlohmann::json& aJson ) { if( aJson.contains( "width" ) && aJson.contains( "height" ) && aJson.contains( "drill" ) ) { VECTOR2I sz; sz.x = pcbIUScale.mmToIU( aJson["width"].get() ); sz.y = pcbIUScale.mmToIU( aJson["height"].get() ); m_Pad_Master->SetSize( sz ); int drill = pcbIUScale.mmToIU( aJson["drill"].get() ); m_Pad_Master->SetDrillSize( VECTOR2I( drill, drill ) ); } }, {} ) ); m_params.emplace_back( new PARAM_SCALED( "rules.max_error", &m_MaxError, ARC_HIGH_DEF, pcbIUScale.mmToIU( 0.0001 ), pcbIUScale.mmToIU( 1.0 ), pcbIUScale.MM_PER_IU ) ); m_params.emplace_back( new PARAM_SCALED( "rules.solder_mask_to_copper_clearance", &m_SolderMaskToCopperClearance, pcbIUScale.mmToIU( DEFAULT_SOLDERMASK_TO_COPPER_CLEARANCE ), pcbIUScale.mmToIU( 0.0 ), pcbIUScale.mmToIU( 25.0 ), pcbIUScale.MM_PER_IU ) ); m_params.emplace_back( new PARAM( "zones_allow_external_fillets", &m_ZoneKeepExternalFillets, false ) ); registerMigration( 0, 1, std::bind( &BOARD_DESIGN_SETTINGS::migrateSchema0to1, this ) ); registerMigration( 1, 2, [&]() -> bool { // Schema 1 to 2: move mask and paste margin settings back to board. // The parameters are removed, so we just have to manually load them here and // they will get saved with the board if( std::optional optval = Get( "rules.solder_mask_clearance" ) ) m_SolderMaskExpansion = static_cast( *optval * pcbIUScale.IU_PER_MM ); if( std::optional optval = Get( "rules.solder_mask_min_width" ) ) m_SolderMaskMinWidth = static_cast( *optval * pcbIUScale.IU_PER_MM ); if( std::optional optval = Get( "rules.solder_paste_clearance" ) ) m_SolderPasteMargin = static_cast( *optval * pcbIUScale.IU_PER_MM ); if( std::optional optval = Get( "rules.solder_paste_margin_ratio" ) ) m_SolderPasteMarginRatio = *optval; try { At( "rules" ).erase( "solder_mask_clearance" ); At( "rules" ).erase( "solder_mask_min_width" ); At( "rules" ).erase( "solder_paste_clearance" ); At( "rules" ).erase( "solder_paste_margin_ratio" ); } catch( ... ) {} return true; } ); } BOARD_DESIGN_SETTINGS::~BOARD_DESIGN_SETTINGS() { if( m_parent ) { m_parent->ReleaseNestedSettings( this ); m_parent = nullptr; } } BOARD_DESIGN_SETTINGS::BOARD_DESIGN_SETTINGS( const BOARD_DESIGN_SETTINGS& aOther ) : NESTED_SETTINGS( "board_design_settings", bdsSchemaVersion, aOther.m_parent, aOther.m_path ), m_Pad_Master( nullptr ) { initFromOther( aOther ); } BOARD_DESIGN_SETTINGS& BOARD_DESIGN_SETTINGS::operator=( const BOARD_DESIGN_SETTINGS& aOther ) { initFromOther( aOther ); return *this; } void BOARD_DESIGN_SETTINGS::initFromOther( const BOARD_DESIGN_SETTINGS& aOther ) { // Copy of NESTED_SETTINGS around is not allowed, so let's just update the params. m_TrackWidthList = aOther.m_TrackWidthList; m_ViasDimensionsList = aOther.m_ViasDimensionsList; m_DiffPairDimensionsList = aOther.m_DiffPairDimensionsList; m_CurrentViaType = aOther.m_CurrentViaType; m_UseConnectedTrackWidth = aOther.m_UseConnectedTrackWidth; m_TempOverrideTrackWidth = aOther.m_TempOverrideTrackWidth; m_MinClearance = aOther.m_MinClearance; m_MinConn = aOther.m_MinConn; m_TrackMinWidth = aOther.m_TrackMinWidth; m_ViasMinAnnularWidth = aOther.m_ViasMinAnnularWidth; m_ViasMinSize = aOther.m_ViasMinSize; m_MinThroughDrill = aOther.m_MinThroughDrill; m_MicroViasMinSize = aOther.m_MicroViasMinSize; m_MicroViasMinDrill = aOther.m_MicroViasMinDrill; m_CopperEdgeClearance = aOther.m_CopperEdgeClearance; m_HoleClearance = aOther.m_HoleClearance; m_HoleToHoleMin = aOther.m_HoleToHoleMin; m_SilkClearance = aOther.m_SilkClearance; m_MinResolvedSpokes = aOther.m_MinResolvedSpokes; m_MinSilkTextHeight = aOther.m_MinSilkTextHeight; m_MinSilkTextThickness = aOther.m_MinSilkTextThickness; m_DRCSeverities = aOther.m_DRCSeverities; m_DrcExclusions = aOther.m_DrcExclusions; m_ZoneKeepExternalFillets = aOther.m_ZoneKeepExternalFillets; m_MaxError = aOther.m_MaxError; m_SolderMaskExpansion = aOther.m_SolderMaskExpansion; m_SolderMaskMinWidth = aOther.m_SolderMaskMinWidth; m_SolderMaskToCopperClearance = aOther.m_SolderMaskToCopperClearance; m_SolderPasteMargin = aOther.m_SolderPasteMargin; m_SolderPasteMarginRatio = aOther.m_SolderPasteMarginRatio; m_AllowSoldermaskBridgesInFPs = aOther.m_AllowSoldermaskBridgesInFPs; m_DefaultFPTextItems = aOther.m_DefaultFPTextItems; std::copy( std::begin( aOther.m_LineThickness ), std::end( aOther.m_LineThickness ), std::begin( m_LineThickness ) ); std::copy( std::begin( aOther.m_TextSize ), std::end( aOther.m_TextSize ), std::begin( m_TextSize ) ); std::copy( std::begin( aOther.m_TextThickness ), std::end( aOther.m_TextThickness ), std::begin( m_TextThickness ) ); std::copy( std::begin( aOther.m_TextItalic ), std::end( aOther.m_TextItalic ), std::begin( m_TextItalic ) ); std::copy( std::begin( aOther.m_TextUpright ), std::end( aOther.m_TextUpright ), std::begin( m_TextUpright ) ); m_DimensionUnitsMode = aOther.m_DimensionUnitsMode; m_DimensionPrecision = aOther.m_DimensionPrecision; m_DimensionUnitsFormat = aOther.m_DimensionUnitsFormat; m_DimensionSuppressZeroes = aOther.m_DimensionSuppressZeroes; m_DimensionTextPosition = aOther.m_DimensionTextPosition; m_DimensionKeepTextAligned = aOther.m_DimensionKeepTextAligned; m_DimensionArrowLength = aOther.m_DimensionArrowLength; m_DimensionExtensionOffset = aOther.m_DimensionExtensionOffset; m_auxOrigin = aOther.m_auxOrigin; m_gridOrigin = aOther.m_gridOrigin; m_HasStackup = aOther.m_HasStackup; m_UseHeightForLengthCalcs= aOther.m_UseHeightForLengthCalcs; m_trackWidthIndex = aOther.m_trackWidthIndex; m_viaSizeIndex = aOther.m_viaSizeIndex; m_diffPairIndex = aOther.m_diffPairIndex; m_useCustomTrackVia = aOther.m_useCustomTrackVia; m_customTrackWidth = aOther.m_customTrackWidth; m_customViaSize = aOther.m_customViaSize; m_useCustomDiffPair = aOther.m_useCustomDiffPair; m_customDiffPair = aOther.m_customDiffPair; m_copperLayerCount = aOther.m_copperLayerCount; m_enabledLayers = aOther.m_enabledLayers; m_boardThickness = aOther.m_boardThickness; m_currentNetClassName = aOther.m_currentNetClassName; m_stackup = aOther.m_stackup; m_NetSettings = aOther.m_NetSettings; m_Pad_Master = std::make_unique( *aOther.m_Pad_Master ); m_defaultZoneSettings = aOther.m_defaultZoneSettings; } bool BOARD_DESIGN_SETTINGS::migrateSchema0to1() { /** * Schema 0 to 1: default dimension precision changed in meaning. * Previously it was an enum with the following meaning: * * 0: 0.01mm / 1 mil / 0.001 in * 1: 0.001mm / 0.1 mil / 0.0001 in * 2: 0.0001mm / 0.01 mil / 0.00001 in * * Now it is independent of display units and is an integer meaning the number of digits * displayed after the decimal point, so we have to migrate based on the default units. * * The units is an integer with the following mapping: * * 0: Inches * 1: Mils * 2: Millimeters */ std::string units_ptr( "defaults.dimension_units" ); std::string precision_ptr( "defaults.dimension_precision" ); if( !( Contains( units_ptr ) && Contains( precision_ptr ) && At( units_ptr ).is_number_integer() && At( precision_ptr ).is_number_integer() ) ) { // if either is missing or invalid, migration doesn't make sense return true; } int units = *Get( units_ptr ); int precision = *Get( precision_ptr ); // The enum maps directly to precision if the units is mils int extraDigits = 0; switch( units ) { case 0: extraDigits = 3; break; case 2: extraDigits = 2; break; default: break; } precision += extraDigits; Set( precision_ptr, precision ); return true; } bool BOARD_DESIGN_SETTINGS::LoadFromFile( const wxString& aDirectory ) { bool ret = NESTED_SETTINGS::LoadFromFile( aDirectory ); // A number of things won't have been translated by the PROJECT_FILE migration because of // descoped objects required to decode this data. So, it will be in the legacy.pcbnew // section and needs to be pulled out here PROJECT_FILE* project = dynamic_cast( GetParent() ); if( !project ) return ret; bool migrated = false; auto drcName = []( int aCode ) -> std::string { std::shared_ptr item = DRC_ITEM::Create( aCode ); wxString name = item->GetSettingsKey(); return std::string( name.ToUTF8() ); }; const std::string rs = "rule_severities."; const std::string no_courtyard_key = "legacy_no_courtyard_defined"; const std::string courtyard_overlap_key = "legacy_courtyards_overlap"; try { nlohmann::json& severities = project->Internals()->at( "/board/design_settings/rule_severities"_json_pointer ); if( severities.contains( no_courtyard_key ) ) { if( severities[no_courtyard_key].get() ) Set( rs + drcName( DRCE_MISSING_COURTYARD ), "error" ); else Set( rs + drcName( DRCE_MISSING_COURTYARD ), "ignore" ); severities.erase( no_courtyard_key ); migrated = true; } if( severities.contains( courtyard_overlap_key ) ) { if( severities[courtyard_overlap_key].get() ) Set( rs + drcName( DRCE_OVERLAPPING_FOOTPRINTS ), "error" ); else Set( rs + drcName( DRCE_OVERLAPPING_FOOTPRINTS ), "ignore" ); severities.erase( courtyard_overlap_key ); migrated = true; } } catch( ... ) { } if( Contains( "legacy" ) ) { // This defaults to false for new boards, but version 5.1.x and prior kept the fillets // so we do the same for legacy boards. m_ZoneKeepExternalFillets = true; project->At( "legacy" ).erase( "pcbnew" ); } // Now that we have everything, we need to load again if( migrated ) Load(); return ret; } SEVERITY BOARD_DESIGN_SETTINGS::GetSeverity( int aDRCErrorCode ) { return m_DRCSeverities[ aDRCErrorCode ]; } bool BOARD_DESIGN_SETTINGS::Ignore( int aDRCErrorCode ) { return m_DRCSeverities[ aDRCErrorCode ] == RPT_SEVERITY_IGNORE; } int BOARD_DESIGN_SETTINGS::GetBiggestClearanceValue() const { int biggest = std::max( m_MinClearance, m_HoleClearance ); DRC_CONSTRAINT constraint; biggest = std::max( biggest, m_HoleToHoleMin ); biggest = std::max( biggest, m_CopperEdgeClearance ); if( m_DRCEngine ) { m_DRCEngine->QueryWorstConstraint( CLEARANCE_CONSTRAINT, constraint ); biggest = std::max( biggest, constraint.Value().Min() ); m_DRCEngine->QueryWorstConstraint( HOLE_CLEARANCE_CONSTRAINT, constraint ); biggest = std::max( biggest, constraint.Value().Min() ); m_DRCEngine->QueryWorstConstraint( EDGE_CLEARANCE_CONSTRAINT, constraint ); biggest = std::max( biggest, constraint.Value().Min() ); m_DRCEngine->QueryWorstConstraint( HOLE_TO_HOLE_CONSTRAINT, constraint ); biggest = std::max( biggest, constraint.Value().Min() ); } return biggest; } int BOARD_DESIGN_SETTINGS::GetSmallestClearanceValue() const { int clearance = m_NetSettings->m_DefaultNetClass->GetClearance(); for( const auto& [ name, netclass ] : m_NetSettings->m_NetClasses ) clearance = std::min( clearance, netclass->GetClearance() ); return clearance; } void BOARD_DESIGN_SETTINGS::SetViaSizeIndex( unsigned aIndex ) { m_viaSizeIndex = std::min( aIndex, (unsigned) m_ViasDimensionsList.size() ); m_useCustomTrackVia = false; } int BOARD_DESIGN_SETTINGS::GetCurrentViaSize() const { if( m_useCustomTrackVia ) return m_customViaSize.m_Diameter; else if( m_viaSizeIndex == 0 ) return m_NetSettings->m_DefaultNetClass->GetViaDiameter(); else return m_ViasDimensionsList[ m_viaSizeIndex ].m_Diameter; } int BOARD_DESIGN_SETTINGS::GetCurrentViaDrill() const { int drill; if( m_useCustomTrackVia ) drill = m_customViaSize.m_Drill; else if( m_viaSizeIndex == 0 ) drill = m_NetSettings->m_DefaultNetClass->GetViaDrill(); else drill = m_ViasDimensionsList[ m_viaSizeIndex ].m_Drill; return drill > 0 ? drill : -1; } void BOARD_DESIGN_SETTINGS::SetTrackWidthIndex( unsigned aIndex ) { m_trackWidthIndex = std::min( aIndex, (unsigned) m_TrackWidthList.size() ); m_useCustomTrackVia = false; } int BOARD_DESIGN_SETTINGS::GetCurrentTrackWidth() const { if( m_useCustomTrackVia ) return m_customTrackWidth; else if( m_trackWidthIndex == 0 ) return m_NetSettings->m_DefaultNetClass->GetTrackWidth(); else return m_TrackWidthList[ m_trackWidthIndex ]; } void BOARD_DESIGN_SETTINGS::SetDiffPairIndex( unsigned aIndex ) { if( !m_DiffPairDimensionsList.empty() ) { m_diffPairIndex = std::min( aIndex, static_cast( m_DiffPairDimensionsList.size() ) - 1 ); } m_useCustomDiffPair = false; } int BOARD_DESIGN_SETTINGS::GetCurrentDiffPairWidth() const { if( m_useCustomDiffPair ) { return m_customDiffPair.m_Width; } else if( m_diffPairIndex == 0 ) { if( m_NetSettings->m_DefaultNetClass->HasDiffPairWidth() ) return m_NetSettings->m_DefaultNetClass->GetDiffPairWidth(); else return m_NetSettings->m_DefaultNetClass->GetTrackWidth(); } else { return m_DiffPairDimensionsList[m_diffPairIndex].m_Width; } } int BOARD_DESIGN_SETTINGS::GetCurrentDiffPairGap() const { if( m_useCustomDiffPair ) { return m_customDiffPair.m_Gap; } else if( m_diffPairIndex == 0 ) { if( m_NetSettings->m_DefaultNetClass->HasDiffPairGap() ) return m_NetSettings->m_DefaultNetClass->GetDiffPairGap(); else return m_NetSettings->m_DefaultNetClass->GetClearance(); } else { return m_DiffPairDimensionsList[m_diffPairIndex].m_Gap; } } int BOARD_DESIGN_SETTINGS::GetCurrentDiffPairViaGap() const { if( m_useCustomDiffPair ) { return m_customDiffPair.m_ViaGap; } else if( m_diffPairIndex == 0 ) { if( m_NetSettings->m_DefaultNetClass->HasDiffPairViaGap() ) return m_NetSettings->m_DefaultNetClass->GetDiffPairViaGap(); else return GetCurrentDiffPairGap(); } else { return m_DiffPairDimensionsList[m_diffPairIndex].m_ViaGap; } } void BOARD_DESIGN_SETTINGS::SetCopperLayerCount( int aNewLayerCount ) { m_copperLayerCount = aNewLayerCount; // Update only enabled copper layers mask m_enabledLayers &= ~LSET::AllCuMask(); if( aNewLayerCount > 0 ) m_enabledLayers |= LSET::AllCuMask( aNewLayerCount ); } void BOARD_DESIGN_SETTINGS::SetEnabledLayers( LSET aMask ) { // Back and front layers are always enabled. aMask.set( B_Cu ).set( F_Cu ); m_enabledLayers = aMask; // update m_CopperLayerCount to ensure its consistency with m_EnabledLayers m_copperLayerCount = ( aMask & LSET::AllCuMask() ).count(); } // Return the layer class index { silk, copper, edges & courtyards, fab, others } of the // given layer. int BOARD_DESIGN_SETTINGS::GetLayerClass( PCB_LAYER_ID aLayer ) const { if( aLayer == F_SilkS || aLayer == B_SilkS ) return LAYER_CLASS_SILK; else if( IsCopperLayer( aLayer ) ) return LAYER_CLASS_COPPER; else if( aLayer == Edge_Cuts ) return LAYER_CLASS_EDGES; else if( aLayer == F_CrtYd || aLayer == B_CrtYd ) return LAYER_CLASS_COURTYARD; else if( aLayer == F_Fab || aLayer == B_Fab ) return LAYER_CLASS_FAB; else return LAYER_CLASS_OTHERS; } int BOARD_DESIGN_SETTINGS::GetDRCEpsilon() const { return pcbIUScale.mmToIU( ADVANCED_CFG::GetCfg().m_DRCEpsilon ); } int BOARD_DESIGN_SETTINGS::GetHolePlatingThickness() const { return pcbIUScale.mmToIU( ADVANCED_CFG::GetCfg().m_HoleWallThickness ); } int BOARD_DESIGN_SETTINGS::GetLineThickness( PCB_LAYER_ID aLayer ) const { return m_LineThickness[ GetLayerClass( aLayer ) ]; } VECTOR2I BOARD_DESIGN_SETTINGS::GetTextSize( PCB_LAYER_ID aLayer ) const { return m_TextSize[ GetLayerClass( aLayer ) ]; } int BOARD_DESIGN_SETTINGS::GetTextThickness( PCB_LAYER_ID aLayer ) const { return m_TextThickness[ GetLayerClass( aLayer ) ]; } bool BOARD_DESIGN_SETTINGS::GetTextItalic( PCB_LAYER_ID aLayer ) const { return m_TextItalic[ GetLayerClass( aLayer ) ]; } bool BOARD_DESIGN_SETTINGS::GetTextUpright( PCB_LAYER_ID aLayer ) const { return m_TextUpright[ GetLayerClass( aLayer ) ]; }