/* * This program source code file is part of KiCad, a free EDA CAD application. * * Copyright (C) 2016 Jean-Pierre Charras, jp.charras at wanadoo.fr * Copyright (C) 2015 Wayne Stambaugh * Copyright (C) 1992-2024 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 #include #include #include #include #include #include #include #include #include #include #include bool IncrementLabelMember( wxString& name, int aIncrement ) { if( name.IsEmpty() ) return true; wxString suffix; wxString digits; wxString outputFormat; wxString outputNumber; int ii = name.Len() - 1; int dCount = 0; while( ii >= 0 && !wxIsdigit( name.GetChar( ii ) ) ) { suffix = name.GetChar( ii ) + suffix; ii--; } while( ii >= 0 && wxIsdigit( name.GetChar( ii ) ) ) { digits = name.GetChar( ii ) + digits; ii--; dCount++; } if( digits.IsEmpty() ) return true; long number = 0; if( digits.ToLong( &number ) ) { number += aIncrement; // Don't let result go below zero if( number > -1 ) { name.Remove( ii + 1 ); //write out a format string with correct number of leading zeroes outputFormat.Printf( wxS( "%%0%dld" ), dCount ); //write out the number using the format string outputNumber.Printf( outputFormat, number ); name << outputNumber << suffix; return true; } } return false; } /* Coding polygons for global symbol graphic shapes. * the first parml is the number of corners * others are the corners coordinates in reduced units * the real coordinate is the reduced coordinate * text half size */ static int TemplateIN_HN[] = { 6, 0, 0, -1, -1, -2, -1, -2, 1, -1, 1, 0, 0 }; static int TemplateIN_HI[] = { 6, 0, 0, 1, 1, 2, 1, 2, -1, 1, -1, 0, 0 }; static int TemplateIN_UP[] = { 6, 0, 0, 1, -1, 1, -2, -1, -2, -1, -1, 0, 0 }; static int TemplateIN_BOTTOM[] = { 6, 0, 0, 1, 1, 1, 2, -1, 2, -1, 1, 0, 0 }; static int TemplateOUT_HN[] = { 6, -2, 0, -1, 1, 0, 1, 0, -1, -1, -1, -2, 0 }; static int TemplateOUT_HI[] = { 6, 2, 0, 1, -1, 0, -1, 0, 1, 1, 1, 2, 0 }; static int TemplateOUT_UP[] = { 6, 0, -2, 1, -1, 1, 0, -1, 0, -1, -1, 0, -2 }; static int TemplateOUT_BOTTOM[] = { 6, 0, 2, 1, 1, 1, 0, -1, 0, -1, 1, 0, 2 }; static int TemplateUNSPC_HN[] = { 5, 0, -1, -2, -1, -2, 1, 0, 1, 0, -1 }; static int TemplateUNSPC_HI[] = { 5, 0, -1, 2, -1, 2, 1, 0, 1, 0, -1 }; static int TemplateUNSPC_UP[] = { 5, 1, 0, 1, -2, -1, -2, -1, 0, 1, 0 }; static int TemplateUNSPC_BOTTOM[] = { 5, 1, 0, 1, 2, -1, 2, -1, 0, 1, 0 }; static int TemplateBIDI_HN[] = { 5, 0, 0, -1, -1, -2, 0, -1, 1, 0, 0 }; static int TemplateBIDI_HI[] = { 5, 0, 0, 1, -1, 2, 0, 1, 1, 0, 0 }; static int TemplateBIDI_UP[] = { 5, 0, 0, -1, -1, 0, -2, 1, -1, 0, 0 }; static int TemplateBIDI_BOTTOM[] = { 5, 0, 0, -1, 1, 0, 2, 1, 1, 0, 0 }; static int Template3STATE_HN[] = { 5, 0, 0, -1, -1, -2, 0, -1, 1, 0, 0 }; static int Template3STATE_HI[] = { 5, 0, 0, 1, -1, 2, 0, 1, 1, 0, 0 }; static int Template3STATE_UP[] = { 5, 0, 0, -1, -1, 0, -2, 1, -1, 0, 0 }; static int Template3STATE_BOTTOM[] = { 5, 0, 0, -1, 1, 0, 2, 1, 1, 0, 0 }; static int* TemplateShape[5][4] = { { TemplateIN_HN, TemplateIN_UP, TemplateIN_HI, TemplateIN_BOTTOM }, { TemplateOUT_HN, TemplateOUT_UP, TemplateOUT_HI, TemplateOUT_BOTTOM }, { TemplateBIDI_HN, TemplateBIDI_UP, TemplateBIDI_HI, TemplateBIDI_BOTTOM }, { Template3STATE_HN, Template3STATE_UP, Template3STATE_HI, Template3STATE_BOTTOM }, { TemplateUNSPC_HN, TemplateUNSPC_UP, TemplateUNSPC_HI, TemplateUNSPC_BOTTOM } }; wxString getElectricalTypeLabel( LABEL_FLAG_SHAPE aType ) { switch( aType ) { case LABEL_FLAG_SHAPE::L_INPUT: return _( "Input" ); case LABEL_FLAG_SHAPE::L_OUTPUT: return _( "Output" ); case LABEL_FLAG_SHAPE::L_BIDI: return _( "Bidirectional" ); case LABEL_FLAG_SHAPE::L_TRISTATE: return _( "Tri-State" ); case LABEL_FLAG_SHAPE::L_UNSPECIFIED: return _( "Passive" ); default: return wxT( "???" ); } } SPIN_STYLE SPIN_STYLE::RotateCCW() { SPIN newSpin = m_spin; switch( m_spin ) { case SPIN_STYLE::LEFT: newSpin = SPIN_STYLE::BOTTOM; break; case SPIN_STYLE::BOTTOM: newSpin = SPIN_STYLE::RIGHT; break; case SPIN_STYLE::RIGHT: newSpin = SPIN_STYLE::UP; break; case SPIN_STYLE::UP: newSpin = SPIN_STYLE::LEFT; break; } return SPIN_STYLE( newSpin ); } SPIN_STYLE SPIN_STYLE::MirrorX() { SPIN newSpin = m_spin; switch( m_spin ) { case SPIN_STYLE::UP: newSpin = SPIN_STYLE::BOTTOM; break; case SPIN_STYLE::BOTTOM: newSpin = SPIN_STYLE::UP; break; case SPIN_STYLE::LEFT: break; case SPIN_STYLE::RIGHT: break; } return SPIN_STYLE( newSpin ); } SPIN_STYLE SPIN_STYLE::MirrorY() { SPIN newSpin = m_spin; switch( m_spin ) { case SPIN_STYLE::LEFT: newSpin = SPIN_STYLE::RIGHT; break; case SPIN_STYLE::RIGHT: newSpin = SPIN_STYLE::LEFT; break; case SPIN_STYLE::UP: break; case SPIN_STYLE::BOTTOM: break; } return SPIN_STYLE( newSpin ); } SCH_LABEL_BASE::SCH_LABEL_BASE( const VECTOR2I& aPos, const wxString& aText, KICAD_T aType ) : SCH_TEXT( aPos, aText, LAYER_NOTES, aType ), m_shape( L_UNSPECIFIED ), m_connectionType( CONNECTION_TYPE::NONE ), m_isDangling( true ), m_lastResolvedColor( COLOR4D::UNSPECIFIED ) { SetMultilineAllowed( false ); ClearFieldsAutoplaced(); // fields are not yet autoplaced. if( !HasTextVars() ) m_cached_driver_name = EscapeString( EDA_TEXT::GetShownText( true, 0 ), CTX_NETNAME ); } SCH_LABEL_BASE::SCH_LABEL_BASE( const SCH_LABEL_BASE& aLabel ) : SCH_TEXT( aLabel ), m_shape( aLabel.m_shape ), m_connectionType( aLabel.m_connectionType ), m_isDangling( aLabel.m_isDangling ), m_lastResolvedColor( aLabel.m_lastResolvedColor ), m_cached_driver_name( aLabel.m_cached_driver_name ) { SetMultilineAllowed( false ); m_fields = aLabel.m_fields; for( SCH_FIELD& field : m_fields ) field.SetParent( this ); } SCH_LABEL_BASE& SCH_LABEL_BASE::operator=( const SCH_LABEL_BASE& aLabel ) { SCH_TEXT::operator=( aLabel ); m_cached_driver_name = aLabel.m_cached_driver_name; return *this; } const wxString SCH_LABEL_BASE::GetDefaultFieldName( const wxString& aName, bool aUseDefaultName ) { if( aName == wxT( "Intersheetrefs" ) ) return _( "Sheet References" ); else if( aName == wxT( "Netclass" ) ) return _( "Net Class" ); else if( aName.IsEmpty() && aUseDefaultName ) return _( "Field" ); else return aName; } bool SCH_LABEL_BASE::IsType( const std::vector& aScanTypes ) const { if( SCH_TEXT::IsType( aScanTypes ) ) return true; for( KICAD_T scanType : aScanTypes ) { if( scanType == SCH_LABEL_LOCATE_ANY_T ) return true; } wxCHECK_MSG( Schematic(), false, wxT( "No parent SCHEMATIC set for SCH_LABEL!" ) ); // Ensure m_connected_items for Schematic()->CurrentSheet() exists. // Can be not the case when "this" is living in clipboard if( m_connected_items.find( Schematic()->CurrentSheet() ) == m_connected_items.end() ) return false; const SCH_ITEM_VEC& item_set = m_connected_items.at( Schematic()->CurrentSheet() ); for( KICAD_T scanType : aScanTypes ) { if( scanType == SCH_LABEL_LOCATE_WIRE_T ) { for( SCH_ITEM* connection : item_set ) { if( connection->IsType( { SCH_ITEM_LOCATE_WIRE_T, SCH_PIN_T } ) ) return true; } } if ( scanType == SCH_LABEL_LOCATE_BUS_T ) { for( SCH_ITEM* connection : item_set ) { if( connection->IsType( { SCH_ITEM_LOCATE_BUS_T } ) ) return true; } } } return false; } void SCH_LABEL_BASE::SwapData( SCH_ITEM* aItem ) { SCH_TEXT::SwapData( aItem ); SCH_LABEL_BASE* label = static_cast( aItem ); m_fields.swap( label->m_fields ); std::swap( m_fieldsAutoplaced, label->m_fieldsAutoplaced ); for( SCH_FIELD& field : m_fields ) field.SetParent( this ); for( SCH_FIELD& field : label->m_fields ) field.SetParent( label ); std::swap( m_shape, label->m_shape ); std::swap( m_connectionType, label->m_connectionType ); std::swap( m_isDangling, label->m_isDangling ); std::swap( m_lastResolvedColor, label->m_lastResolvedColor ); } COLOR4D SCH_LABEL_BASE::GetLabelColor() const { if( GetTextColor() != COLOR4D::UNSPECIFIED ) m_lastResolvedColor = GetTextColor(); else if( !IsConnectivityDirty() ) m_lastResolvedColor = GetEffectiveNetClass()->GetSchematicColor(); return m_lastResolvedColor; } void SCH_LABEL_BASE::SetSpinStyle( SPIN_STYLE aSpinStyle ) { // Assume "Right" and Left" mean which side of the anchor the text will be on // Thus we want to left justify text up against the anchor if we are on the right switch( aSpinStyle ) { default: wxFAIL_MSG( "Bad spin style" ); KI_FALLTHROUGH; case SPIN_STYLE::RIGHT: // Horiz Normal Orientation SetTextAngle( ANGLE_HORIZONTAL ); SetHorizJustify( GR_TEXT_H_ALIGN_LEFT ); break; case SPIN_STYLE::UP: // Vert Orientation UP SetTextAngle( ANGLE_VERTICAL ); SetHorizJustify( GR_TEXT_H_ALIGN_LEFT ); break; case SPIN_STYLE::LEFT: // Horiz Orientation - Right justified SetTextAngle( ANGLE_HORIZONTAL ); SetHorizJustify( GR_TEXT_H_ALIGN_RIGHT ); break; case SPIN_STYLE::BOTTOM: // Vert Orientation BOTTOM SetTextAngle( ANGLE_VERTICAL ); SetHorizJustify( GR_TEXT_H_ALIGN_RIGHT ); break; } SetVertJustify( GR_TEXT_V_ALIGN_BOTTOM ); } SPIN_STYLE SCH_LABEL_BASE::GetSpinStyle() const { if( GetTextAngle() == ANGLE_VERTICAL ) { if( GetHorizJustify() == GR_TEXT_H_ALIGN_RIGHT ) return SPIN_STYLE::BOTTOM; else return SPIN_STYLE::UP; } else { if( GetHorizJustify() == GR_TEXT_H_ALIGN_RIGHT ) return SPIN_STYLE::LEFT; else return SPIN_STYLE::RIGHT; } } VECTOR2I SCH_LABEL_BASE::GetSchematicTextOffset( const RENDER_SETTINGS* aSettings ) const { VECTOR2I text_offset; // add an offset to x (or y) position to aid readability of text on a wire or line int dist = GetTextOffset( aSettings ) + GetPenWidth(); switch( GetSpinStyle() ) { case SPIN_STYLE::UP: case SPIN_STYLE::BOTTOM: text_offset.x = -dist; break; // Vert Orientation default: case SPIN_STYLE::LEFT: case SPIN_STYLE::RIGHT: text_offset.y = -dist; break; // Horiz Orientation } return text_offset; } void SCH_LABEL_BASE::SetPosition( const VECTOR2I& aPosition ) { VECTOR2I offset = aPosition - GetTextPos(); Move( offset ); } void SCH_LABEL_BASE::Move( const VECTOR2I& aMoveVector ) { SCH_TEXT::Move( aMoveVector ); for( SCH_FIELD& field : m_fields ) field.Offset( aMoveVector ); } void SCH_LABEL_BASE::Rotate( const VECTOR2I& aCenter, bool aRotateCCW ) { VECTOR2I pt = GetTextPos(); RotatePoint( pt, aCenter, aRotateCCW ? ANGLE_270 : ANGLE_90 ); VECTOR2I offset = pt - GetTextPos(); Rotate90( aRotateCCW ); SetTextPos( GetTextPos() + offset ); for( SCH_FIELD& field : m_fields ) field.SetTextPos( field.GetTextPos() + offset ); } void SCH_LABEL_BASE::Rotate90( bool aClockwise ) { SCH_TEXT::Rotate90( aClockwise ); if( m_fieldsAutoplaced == FIELDS_AUTOPLACED_AUTO ) { AutoplaceFields( /* aScreen */ nullptr, /* aManual */ false ); } else { for( SCH_FIELD& field : m_fields ) { if( field.GetTextAngle().IsVertical() && field.GetHorizJustify() == GR_TEXT_H_ALIGN_LEFT ) { if( !aClockwise ) field.SetHorizJustify( GR_TEXT_H_ALIGN_RIGHT ); field.SetTextAngle( ANGLE_HORIZONTAL ); } else if( field.GetTextAngle().IsVertical() && field.GetHorizJustify() == GR_TEXT_H_ALIGN_RIGHT ) { if( !aClockwise ) field.SetHorizJustify( GR_TEXT_H_ALIGN_LEFT ); field.SetTextAngle( ANGLE_HORIZONTAL ); } else if( field.GetTextAngle().IsHorizontal() && field.GetHorizJustify() == GR_TEXT_H_ALIGN_LEFT ) { if( aClockwise ) field.SetHorizJustify( GR_TEXT_H_ALIGN_LEFT ); field.SetTextAngle( ANGLE_VERTICAL ); } else if( field.GetTextAngle().IsHorizontal() && field.GetHorizJustify() == GR_TEXT_H_ALIGN_RIGHT ) { if( aClockwise ) field.SetHorizJustify( GR_TEXT_H_ALIGN_LEFT ); field.SetTextAngle( ANGLE_VERTICAL ); } VECTOR2I pos = field.GetTextPos(); RotatePoint( pos, GetPosition(), aClockwise ? -ANGLE_90 : ANGLE_90 ); field.SetTextPos( pos ); } } } void SCH_LABEL_BASE::MirrorSpinStyle( bool aLeftRight ) { SCH_TEXT::MirrorSpinStyle( aLeftRight ); for( SCH_FIELD& field : m_fields ) { if( ( aLeftRight && field.GetTextAngle().IsHorizontal() ) || ( !aLeftRight && field.GetTextAngle().IsVertical() ) ) { if( field.GetHorizJustify() == GR_TEXT_H_ALIGN_LEFT ) field.SetHorizJustify( GR_TEXT_H_ALIGN_RIGHT ); else field.SetHorizJustify( GR_TEXT_H_ALIGN_LEFT ); } VECTOR2I pos = field.GetTextPos(); VECTOR2I delta = (VECTOR2I)GetPosition() - pos; if( aLeftRight ) pos.x = GetPosition().x + delta.x; else pos.y = GetPosition().y + delta.y; field.SetTextPos( pos ); } } void SCH_LABEL_BASE::MirrorHorizontally( int aCenter ) { VECTOR2I old_pos = GetPosition(); SCH_TEXT::MirrorHorizontally( aCenter ); for( SCH_FIELD& field : m_fields ) { if( field.GetTextAngle() == ANGLE_HORIZONTAL ) field.FlipHJustify(); VECTOR2I pos = field.GetTextPos(); VECTOR2I delta = old_pos - pos; pos.x = GetPosition().x + delta.x; field.SetPosition( pos ); } } void SCH_LABEL_BASE::MirrorVertically( int aCenter ) { VECTOR2I old_pos = GetPosition(); SCH_TEXT::MirrorVertically( aCenter ); for( SCH_FIELD& field : m_fields ) { if( field.GetTextAngle() == ANGLE_VERTICAL ) field.FlipHJustify(); VECTOR2I pos = field.GetTextPos(); VECTOR2I delta = old_pos - pos; pos.y = GetPosition().y + delta.y; field.SetPosition( pos ); } } bool SCH_LABEL_BASE::IncrementLabel( int aIncrement ) { wxString text = GetText(); if( IncrementLabelMember( text, aIncrement ) ) { SetText( text ); return true; } return false; } bool SCH_LABEL_BASE::operator==( const SCH_ITEM& aOther ) const { const SCH_LABEL_BASE* other = dynamic_cast( &aOther ); if( !other ) return false; if( m_shape != other->m_shape ) return false; if( m_connectionType != other->m_connectionType ) return false; if( m_fields.size() != other->m_fields.size() ) return false; for( size_t ii = 0; ii < m_fields.size(); ++ii ) { if( !( m_fields[ii] == other->m_fields[ii] ) ) return false; } return SCH_TEXT::operator==( aOther ); } double SCH_LABEL_BASE::Similarity( const SCH_ITEM& aOther ) const { const SCH_LABEL_BASE* other = dynamic_cast( &aOther ); if( !other ) return 0.0; if( m_Uuid == other->m_Uuid ) return 1.0; double similarity = SCH_TEXT::Similarity( aOther ); if( typeid( *this ) != typeid( aOther ) ) similarity *= 0.9; if( m_shape == other->m_shape ) similarity *= 0.9; if( m_connectionType == other->m_connectionType ) similarity *= 0.9; for( size_t ii = 0; ii < m_fields.size(); ++ii ) { if( ii >= other->m_fields.size() ) break; similarity *= m_fields[ii].Similarity( other->m_fields[ii] ); } int diff = std::abs( int( m_fields.size() ) - int( other->m_fields.size() ) ); similarity *= std::pow( 0.9, diff ); return similarity; } void SCH_LABEL_BASE::AutoplaceFields( SCH_SCREEN* aScreen, bool aManual ) { int margin = GetTextOffset() * 2; int labelLen = GetBodyBoundingBox().GetSizeMax(); int accumulated = GetTextHeight() / 2; if( Type() == SCH_GLOBAL_LABEL_T ) accumulated += margin + GetPenWidth() + margin; for( SCH_FIELD& field : m_fields ) { VECTOR2I offset( 0, 0 ); switch( GetSpinStyle() ) { default: case SPIN_STYLE::LEFT: field.SetTextAngle( ANGLE_HORIZONTAL ); field.SetHorizJustify( GR_TEXT_H_ALIGN_RIGHT ); if( field.GetCanonicalName() == wxT( "Intersheetrefs" ) ) offset.x = - ( labelLen + margin ); else offset.y = accumulated + field.GetTextHeight() / 2; break; case SPIN_STYLE::UP: field.SetTextAngle( ANGLE_VERTICAL ); field.SetHorizJustify( GR_TEXT_H_ALIGN_LEFT ); if( field.GetCanonicalName() == wxT( "Intersheetrefs" ) ) offset.y = - ( labelLen + margin ); else offset.x = accumulated + field.GetTextHeight() / 2; break; case SPIN_STYLE::RIGHT: field.SetTextAngle( ANGLE_HORIZONTAL ); field.SetHorizJustify( GR_TEXT_H_ALIGN_LEFT ); if( field.GetCanonicalName() == wxT( "Intersheetrefs" ) ) offset.x = labelLen + margin; else offset.y = accumulated + field.GetTextHeight() / 2; break; case SPIN_STYLE::BOTTOM: field.SetTextAngle( ANGLE_VERTICAL ); field.SetHorizJustify( GR_TEXT_H_ALIGN_RIGHT ); if( field.GetCanonicalName() == wxT( "Intersheetrefs" ) ) offset.y = labelLen + margin; else offset.x = accumulated + field.GetTextHeight() / 2; break; } field.SetTextPos( GetTextPos() + offset ); if( field.GetCanonicalName() != wxT( "Intersheetrefs" ) ) accumulated += field.GetTextHeight() + margin; } m_fieldsAutoplaced = FIELDS_AUTOPLACED_AUTO; } void SCH_LABEL_BASE::GetIntersheetRefs( const SCH_SHEET_PATH* aPath, std::vector>* pages ) { wxCHECK( pages, /* void */ ); if( Schematic() ) { wxString resolvedLabel = GetShownText( &Schematic()->CurrentSheet(), false ); auto it = Schematic()->GetPageRefsMap().find( resolvedLabel ); if( it != Schematic()->GetPageRefsMap().end() ) { std::vector pageListCopy; pageListCopy.insert( pageListCopy.end(), it->second.begin(), it->second.end() ); if( !Schematic()->Settings().m_IntersheetRefsListOwnPage ) { int currentPage = Schematic()->CurrentSheet().GetVirtualPageNumber(); alg::delete_matching( pageListCopy, currentPage ); if( pageListCopy.empty() ) return; } std::sort( pageListCopy.begin(), pageListCopy.end() ); std::map sheetPages = Schematic()->GetVirtualPageToSheetPagesMap(); std::map sheetNames = Schematic()->GetVirtualPageToSheetNamesMap(); for( int pageNum : pageListCopy ) pages->push_back( { sheetPages[ pageNum ], sheetNames[ pageNum ] } ); } } } void SCH_LABEL_BASE::GetContextualTextVars( wxArrayString* aVars ) const { for( const SCH_FIELD& field : m_fields ) aVars->push_back( field.GetCanonicalName().Upper() ); aVars->push_back( wxT( "OP" ) ); aVars->push_back( wxT( "CONNECTION_TYPE" ) ); aVars->push_back( wxT( "SHORT_NET_NAME" ) ); aVars->push_back( wxT( "NET_NAME" ) ); aVars->push_back( wxT( "NET_CLASS" ) ); } bool SCH_LABEL_BASE::ResolveTextVar( const SCH_SHEET_PATH* aPath, wxString* token, int aDepth ) const { static wxRegEx operatingPoint( wxT( "^" "OP" "(.([0-9])?([a-zA-Z]*))?" "$" ) ); wxCHECK( aPath, false ); SCHEMATIC* schematic = Schematic(); if( !schematic ) return false; if( operatingPoint.Matches( *token ) ) { int precision = 3; wxString precisionStr( operatingPoint.GetMatch( *token, 2 ) ); wxString range( operatingPoint.GetMatch( *token, 3 ) ); if( !precisionStr.IsEmpty() ) precision = precisionStr[0] - '0'; if( range.IsEmpty() ) range = wxS( "~V" ); const SCH_CONNECTION* connection = Connection(); *token = wxS( "?" ); if( connection ) *token = schematic->GetOperatingPoint( connection->Name( false ), precision, range ); return true; } if( token->Contains( ':' ) ) { if( schematic->ResolveCrossReference( token, aDepth + 1 ) ) return true; } if( ( Type() == SCH_GLOBAL_LABEL_T || Type() == SCH_HIER_LABEL_T || Type() == SCH_SHEET_PIN_T ) && token->IsSameAs( wxT( "CONNECTION_TYPE" ) ) ) { const SCH_LABEL_BASE* label = static_cast( this ); *token = getElectricalTypeLabel( label->GetShape() ); return true; } else if( token->IsSameAs( wxT( "SHORT_NET_NAME" ) ) ) { const SCH_CONNECTION* connection = Connection(); *token = wxEmptyString; if( connection ) *token = connection->LocalName(); return true; } else if( token->IsSameAs( wxT( "NET_NAME" ) ) ) { const SCH_CONNECTION* connection = Connection(); *token = wxEmptyString; if( connection ) *token = connection->Name(); return true; } else if( token->IsSameAs( wxT( "NET_CLASS" ) ) ) { const SCH_CONNECTION* connection = Connection(); *token = wxEmptyString; if( connection ) *token = GetEffectiveNetClass()->GetName(); return true; } for( const SCH_FIELD& field : m_fields) { if( token->IsSameAs( field.GetName() ) ) { *token = field.GetShownText( false, aDepth + 1 ); return true; } } // See if parent can resolve it (these will recurse to ancestors) if( Type() == SCH_SHEET_PIN_T && m_parent ) { SCH_SHEET* sheet = static_cast( m_parent ); SCH_SHEET_PATH path = *aPath; path.push_back( sheet ); if( sheet->ResolveTextVar( &path, token, aDepth + 1 ) ) return true; } else { if( aPath->Last()->ResolveTextVar( aPath, token, aDepth + 1 ) ) return true; } return false; } bool SCH_LABEL_BASE::HasCachedDriverName() const { return !HasTextVars(); } const wxString& SCH_LABEL_BASE::GetCachedDriverName() const { return m_cached_driver_name; } void SCH_LABEL_BASE::cacheShownText() { EDA_TEXT::cacheShownText(); if( !HasTextVars() ) m_cached_driver_name = EscapeString( EDA_TEXT::GetShownText( true, 0 ), CTX_NETNAME ); } wxString SCH_LABEL_BASE::GetShownText( const SCH_SHEET_PATH* aPath, bool aAllowExtraText, int aDepth ) const { std::function textResolver = [&]( wxString* token ) -> bool { return ResolveTextVar( aPath, token, aDepth ); }; wxString text = EDA_TEXT::GetShownText( aAllowExtraText, aDepth ); if( text == wxS( "~" ) ) // Legacy placeholder for empty string { text = wxS( "" ); } else if( HasTextVars() ) { if( aDepth < 10 ) text = ExpandTextVars( text, &textResolver ); } return text; } void SCH_LABEL_BASE::RunOnChildren( const std::function& aFunction ) { for( SCH_FIELD& field : m_fields ) aFunction( &field ); } bool SCH_LABEL_BASE::Matches( const EDA_SEARCH_DATA& aSearchData, void* aAuxData ) const { return SCH_ITEM::Matches( UnescapeString( GetText() ), aSearchData ); } bool SCH_LABEL_BASE::Replace( const EDA_SEARCH_DATA& aSearchData, void* aAuxData ) { EDA_SEARCH_DATA localSearchData( aSearchData ); localSearchData.findString = EscapeString( aSearchData.findString, CTX_NETNAME ); localSearchData.replaceString = EscapeString( aSearchData.replaceString, CTX_NETNAME ); return EDA_TEXT::Replace( localSearchData ); } INSPECT_RESULT SCH_LABEL_BASE::Visit( INSPECTOR aInspector, void* testData, const std::vector& aScanTypes ) { if( IsType( aScanTypes ) ) { if( INSPECT_RESULT::QUIT == aInspector( this, nullptr ) ) return INSPECT_RESULT::QUIT; } for( KICAD_T scanType : aScanTypes ) { if( scanType == SCH_LOCATE_ANY_T || scanType == SCH_FIELD_T ) { for( SCH_FIELD& field : m_fields ) { if( INSPECT_RESULT::QUIT == aInspector( &field, this ) ) return INSPECT_RESULT::QUIT; } } } return INSPECT_RESULT::CONTINUE; } void SCH_LABEL_BASE::GetEndPoints( std::vector& aItemList ) { DANGLING_END_ITEM item( LABEL_END, this, GetTextPos() ); aItemList.push_back( item ); } std::vector SCH_LABEL_BASE::GetConnectionPoints() const { return { GetTextPos() }; } void SCH_LABEL_BASE::ViewGetLayers( int aLayers[], int& aCount ) const { aCount = 5; aLayers[0] = LAYER_DANGLING; aLayers[1] = LAYER_DEVICE; aLayers[2] = LAYER_NETCLASS_REFS; aLayers[3] = LAYER_FIELDS; aLayers[4] = LAYER_SELECTION_SHADOWS; } int SCH_LABEL_BASE::GetLabelBoxExpansion( const RENDER_SETTINGS* aSettings ) const { double ratio; if( aSettings ) ratio = static_cast( aSettings )->m_LabelSizeRatio; else if( Schematic() ) ratio = Schematic()->Settings().m_LabelSizeRatio; else ratio = DEFAULT_LABEL_SIZE_RATIO; // For previews (such as in Preferences), etc. return KiROUND( ratio * GetTextSize().y ); } const BOX2I SCH_LABEL_BASE::GetBodyBoundingBox() const { // build the bounding box of the label only, without taking into account its fields BOX2I box; std::vector pts; CreateGraphicShape( nullptr, pts, GetTextPos() ); for( const VECTOR2I& pt : pts ) box.Merge( pt ); box.Inflate( GetEffectiveTextPenWidth() / 2 ); box.Normalize(); return box; } const BOX2I SCH_LABEL_BASE::GetBoundingBox() const { // build the bounding box of the entire label, including its fields BOX2I box = GetBodyBoundingBox(); for( const SCH_FIELD& field : m_fields ) { if( field.IsVisible() ) { BOX2I fieldBBox = field.GetBoundingBox(); if( Type() == SCH_LABEL_T || Type() == SCH_GLOBAL_LABEL_T ) fieldBBox.Offset( GetSchematicTextOffset( nullptr ) ); box.Merge( fieldBBox ); } } box.Normalize(); return box; } bool SCH_LABEL_BASE::HitTest( const VECTOR2I& aPosition, int aAccuracy ) const { BOX2I bbox = GetBodyBoundingBox(); bbox.Inflate( aAccuracy ); if( bbox.Contains( aPosition ) ) return true; for( const SCH_FIELD& field : m_fields ) { if( field.IsVisible() ) { BOX2I fieldBBox = field.GetBoundingBox(); fieldBBox.Inflate( aAccuracy ); if( Type() == SCH_LABEL_T || Type() == SCH_GLOBAL_LABEL_T ) fieldBBox.Offset( GetSchematicTextOffset( nullptr ) ); if( fieldBBox.Contains( aPosition ) ) return true; } } return false; } bool SCH_LABEL_BASE::HitTest( const BOX2I& aRect, bool aContained, int aAccuracy ) const { BOX2I rect = aRect; rect.Inflate( aAccuracy ); if( aContained ) { return rect.Contains( GetBoundingBox() ); } else { if( rect.Intersects( GetBodyBoundingBox() ) ) return true; for( const SCH_FIELD& field : m_fields ) { if( field.IsVisible() ) { BOX2I fieldBBox = field.GetBoundingBox(); if( Type() == SCH_LABEL_T || Type() == SCH_GLOBAL_LABEL_T ) fieldBBox.Offset( GetSchematicTextOffset( nullptr ) ); if( rect.Intersects( fieldBBox ) ) return true; } } return false; } } bool SCH_LABEL_BASE::UpdateDanglingState( std::vector& aItemListByType, std::vector& aItemListByPos, const SCH_SHEET_PATH* aPath ) { bool previousState = m_isDangling; VECTOR2I text_pos = GetTextPos(); m_isDangling = true; m_connectionType = CONNECTION_TYPE::NONE; for( auto it = DANGLING_END_ITEM_HELPER::get_lower_pos( aItemListByPos, text_pos ); it < aItemListByPos.end() && it->GetPosition() == text_pos; it++ ) { DANGLING_END_ITEM& item = *it; if( item.GetItem() == this ) continue; switch( item.GetType() ) { case PIN_END: case LABEL_END: case SHEET_LABEL_END: case NO_CONNECT_END: if( text_pos == item.GetPosition() ) { m_isDangling = false; if( aPath && item.GetType() != PIN_END ) AddConnectionTo( *aPath, static_cast( item.GetItem() ) ); } break; default: break; } if( !m_isDangling ) break; } if( m_isDangling ) { for( auto it = DANGLING_END_ITEM_HELPER::get_lower_type( aItemListByType, BUS_END ); it < aItemListByType.end() && it->GetType() == BUS_END; it++ ) { DANGLING_END_ITEM& item = *it; DANGLING_END_ITEM& nextItem = *( ++it ); int accuracy = 1; // We have rounding issues with an accuracy of 0 m_isDangling = !TestSegmentHit( text_pos, item.GetPosition(), nextItem.GetPosition(), accuracy ); if( m_isDangling ) continue; m_connectionType = CONNECTION_TYPE::BUS; // Add the line to the connected items, since it won't be picked // up by a search of intersecting connection points if( aPath ) { auto sch_item = static_cast( item.GetItem() ); AddConnectionTo( *aPath, sch_item ); sch_item->AddConnectionTo( *aPath, this ); } break; } if( m_isDangling ) { for( auto it = DANGLING_END_ITEM_HELPER::get_lower_type( aItemListByType, WIRE_END ); it < aItemListByType.end() && it->GetType() == WIRE_END; it++ ) { DANGLING_END_ITEM& item = *it; DANGLING_END_ITEM& nextItem = *( ++it ); int accuracy = 1; // We have rounding issues with an accuracy of 0 m_isDangling = !TestSegmentHit( text_pos, item.GetPosition(), nextItem.GetPosition(), accuracy ); if( m_isDangling ) continue; m_connectionType = CONNECTION_TYPE::NET; // Add the line to the connected items, since it won't be picked // up by a search of intersecting connection points if( aPath ) { auto sch_item = static_cast( item.GetItem() ); AddConnectionTo( *aPath, sch_item ); sch_item->AddConnectionTo( *aPath, this ); } break; } } } if( m_isDangling ) m_connectionType = CONNECTION_TYPE::NONE; return previousState != m_isDangling; } bool SCH_LABEL_BASE::HasConnectivityChanges( const SCH_ITEM* aItem, const SCH_SHEET_PATH* aInstance ) const { // Do not compare to ourself. if( aItem == this || !IsConnectable() ) return false; const SCH_LABEL_BASE* label = dynamic_cast( aItem ); // Don't compare against a different SCH_ITEM. wxCHECK( label, false ); if( GetPosition() != label->GetPosition() ) return true; if( GetShownText( aInstance ) != label->GetShownText( aInstance ) ) return true; std::vector netclasses; std::vector otherNetclasses; for( const SCH_FIELD& field : m_fields ) { if( field.GetCanonicalName() == wxT( "Netclass" ) ) netclasses.push_back( field.GetText() ); } for( const SCH_FIELD& field : label->m_fields ) { if( field.GetCanonicalName() == wxT( "Netclass" ) ) otherNetclasses.push_back( field.GetText() ); } return netclasses != otherNetclasses; } void SCH_LABEL_BASE::GetMsgPanelInfo( EDA_DRAW_FRAME* aFrame, std::vector& aList ) { wxString msg; switch( Type() ) { case SCH_LABEL_T: msg = _( "Label" ); break; case SCH_DIRECTIVE_LABEL_T: msg = _( "Directive Label" ); break; case SCH_GLOBAL_LABEL_T: msg = _( "Global Label" ); break; case SCH_HIER_LABEL_T: msg = _( "Hierarchical Label" ); break; case SCH_SHEET_PIN_T: msg = _( "Hierarchical Sheet Pin" ); break; default: return; } // Don't use GetShownText() here; we want to show the user the variable references aList.emplace_back( msg, UnescapeString( GetText() ) ); // Display electrical type if it is relevant if( Type() == SCH_GLOBAL_LABEL_T || Type() == SCH_HIER_LABEL_T || Type() == SCH_SHEET_PIN_T ) aList.emplace_back( _( "Type" ), getElectricalTypeLabel( GetShape() ) ); aList.emplace_back( _( "Font" ), GetFont() ? GetFont()->GetName() : _( "Default" ) ); wxString textStyle[] = { _( "Normal" ), _( "Italic" ), _( "Bold" ), _( "Bold Italic" ) }; int style = IsBold() && IsItalic() ? 3 : IsBold() ? 2 : IsItalic() ? 1 : 0; aList.emplace_back( _( "Style" ), textStyle[style] ); aList.emplace_back( _( "Text Size" ), aFrame->MessageTextFromValue( GetTextWidth() ) ); switch( GetSpinStyle() ) { case SPIN_STYLE::LEFT: msg = _( "Align right" ); break; case SPIN_STYLE::UP: msg = _( "Align bottom" ); break; case SPIN_STYLE::RIGHT: msg = _( "Align left" ); break; case SPIN_STYLE::BOTTOM: msg = _( "Align top" ); break; default: msg = wxT( "???" ); break; } aList.emplace_back( _( "Justification" ), msg ); SCH_CONNECTION* conn = nullptr; if( !IsConnectivityDirty() && dynamic_cast( aFrame ) ) conn = Connection(); if( conn ) { conn->AppendInfoToMsgPanel( aList ); if( !conn->IsBus() ) { aList.emplace_back( _( "Resolved Netclass" ), UnescapeString( GetEffectiveNetClass()->GetName() ) ); } } } void SCH_LABEL_BASE::Plot( PLOTTER* aPlotter, bool aBackground, const SCH_PLOT_OPTS& aPlotOpts, int aUnit, int aBodyStyle, const VECTOR2I& aOffset, bool aDimmed ) { static std::vector s_poly; SCH_SHEET_PATH* sheet = &Schematic()->CurrentSheet(); RENDER_SETTINGS* settings = aPlotter->RenderSettings(); SCH_CONNECTION* connection = Connection(); int layer = ( connection && connection->IsBus() ) ? LAYER_BUS : m_layer; COLOR4D color = settings->GetLayerColor( layer ); int penWidth = GetEffectiveTextPenWidth( settings->GetDefaultPenWidth() ); if( aPlotter->GetColorMode() && GetTextColor() != COLOR4D::UNSPECIFIED ) color = GetTextColor(); penWidth = std::max( penWidth, settings->GetMinPenWidth() ); aPlotter->SetCurrentLineWidth( penWidth ); KIFONT::FONT* font = GetFont(); if( !font ) font = KIFONT::FONT::GetFont( settings->GetDefaultFont(), IsBold(), IsItalic() ); VECTOR2I textpos = GetTextPos() + GetSchematicTextOffset( aPlotter->RenderSettings() ); CreateGraphicShape( aPlotter->RenderSettings(), s_poly, GetTextPos() ); TEXT_ATTRIBUTES attrs = GetAttributes(); attrs.m_StrokeWidth = penWidth; attrs.m_Multiline = false; if( aBackground ) { // No filled shapes (yet) } else { aPlotter->PlotText( textpos, color, GetShownText( sheet, true ), attrs, font, GetFontMetrics() ); if( GetShape() == LABEL_FLAG_SHAPE::F_DOT ) { aPlotter->MoveTo( s_poly[0] ); aPlotter->LineTo( s_poly[1] ); aPlotter->PenFinish(); int diameter = ( s_poly[2] - s_poly[1] ).EuclideanNorm() * 2; aPlotter->FilledCircle( s_poly[2], diameter , FILLED, nullptr ); } else if( GetShape() == LABEL_FLAG_SHAPE::F_ROUND ) { aPlotter->MoveTo( s_poly[0] ); aPlotter->LineTo( s_poly[1] ); aPlotter->PenFinish(); int diameter = ( s_poly[2] - s_poly[1] ).EuclideanNorm() * 2; aPlotter->ThickCircle( s_poly[2], diameter, penWidth, FILLED, nullptr ); } else { if( !s_poly.empty() ) aPlotter->PlotPoly( s_poly, FILL_T::NO_FILL, penWidth ); } // Plot attributes to a hypertext menu if( aPlotOpts.m_PDFPropertyPopups ) { std::vector properties; if( connection ) { properties.emplace_back( wxString::Format( wxT( "!%s = %s" ), _( "Net" ), connection->Name() ) ); properties.emplace_back( wxString::Format( wxT( "!%s = %s" ), _( "Resolved netclass" ), GetEffectiveNetClass()->GetName() ) ); } for( const SCH_FIELD& field : GetFields() ) { properties.emplace_back( wxString::Format( wxT( "!%s = %s" ), field.GetName(), field.GetShownText( false ) ) ); } if( !properties.empty() ) aPlotter->HyperlinkMenu( GetBodyBoundingBox(), properties ); } if( Type() == SCH_HIER_LABEL_T ) { aPlotter->Bookmark( GetBodyBoundingBox(), GetShownText( false ), _( "Hierarchical Labels" ) ); } } for( SCH_FIELD& field : m_fields ) field.Plot( aPlotter, aBackground, aPlotOpts, aUnit, aBodyStyle, aOffset, aDimmed ); } void SCH_LABEL_BASE::Print( const SCH_RENDER_SETTINGS* aSettings, int aUnit, int aBodyStyle, const VECTOR2I& aOffset, bool aForceNoFill, bool aDimmed ) { static std::vector s_poly; SCH_CONNECTION* connection = Connection(); int layer = ( connection && connection->IsBus() ) ? LAYER_BUS : m_layer; wxDC* DC = aSettings->GetPrintDC(); COLOR4D color = aSettings->GetLayerColor( layer ); bool blackAndWhiteMode = GetGRForceBlackPenState(); int penWidth = GetEffectivePenWidth( aSettings ); VECTOR2I text_offset = aOffset + GetSchematicTextOffset( aSettings ); if( !blackAndWhiteMode && GetTextColor() != COLOR4D::UNSPECIFIED ) color = GetTextColor(); EDA_TEXT::Print( aSettings, text_offset, color ); CreateGraphicShape( aSettings, s_poly, GetTextPos() + aOffset ); if( GetShape() == LABEL_FLAG_SHAPE::F_DOT ) { GRLine( DC, s_poly[0], s_poly[1], penWidth, color ); int radius = ( s_poly[2] - s_poly[1] ).EuclideanNorm(); GRFilledCircle( DC, s_poly[2], radius, penWidth, color, color ); } else if( GetShape() == LABEL_FLAG_SHAPE::F_ROUND ) { GRLine( DC, s_poly[0], s_poly[1], penWidth, color ); int radius = ( s_poly[2] - s_poly[1] ).EuclideanNorm(); GRCircle( DC, s_poly[2], radius, penWidth, color ); } else { if( !s_poly.empty() ) GRPoly( DC, s_poly.size(), &s_poly[0], false, penWidth, color, color ); } for( SCH_FIELD& field : m_fields ) field.Print( aSettings, aUnit, aBodyStyle, aOffset, aForceNoFill, aDimmed ); } bool SCH_LABEL_BASE::AutoRotateOnPlacement() const { return m_autoRotateOnPlacement; } void SCH_LABEL_BASE::SetAutoRotateOnPlacement( bool autoRotate ) { m_autoRotateOnPlacement = autoRotate; } SCH_LABEL::SCH_LABEL( const VECTOR2I& pos, const wxString& text ) : SCH_LABEL_BASE( pos, text, SCH_LABEL_T ) { m_layer = LAYER_LOCLABEL; m_shape = LABEL_FLAG_SHAPE::L_INPUT; m_isDangling = true; } void SCH_LABEL::Serialize( google::protobuf::Any &aContainer ) const { kiapi::schematic::types::LocalLabel label; label.mutable_id()->set_value( m_Uuid.AsStdString() ); kiapi::common::PackVector2( *label.mutable_position(), GetPosition() ); aContainer.PackFrom( label ); } bool SCH_LABEL::Deserialize( const google::protobuf::Any &aContainer ) { kiapi::schematic::types::LocalLabel label; if( !aContainer.UnpackTo( &label ) ) return false; const_cast( m_Uuid ) = KIID( label.id().value() ); SetPosition( kiapi::common::UnpackVector2( label.position() ) ); return true; } const BOX2I SCH_LABEL::GetBodyBoundingBox() const { BOX2I rect = GetTextBox(); rect.Offset( 0, -GetTextOffset() ); rect.Inflate( GetEffectiveTextPenWidth() ); if( !GetTextAngle().IsZero() ) { // Rotate rect VECTOR2I pos = rect.GetOrigin(); VECTOR2I end = rect.GetEnd(); RotatePoint( pos, GetTextPos(), GetTextAngle() ); RotatePoint( end, GetTextPos(), GetTextAngle() ); rect.SetOrigin( pos ); rect.SetEnd( end ); rect.Normalize(); } // Labels have a position point that is outside of the TextBox rect.Merge( GetPosition() ); return rect; } wxString SCH_LABEL::GetItemDescription( UNITS_PROVIDER* aUnitsProvider ) const { return wxString::Format( _( "Label '%s'" ), KIUI::EllipsizeMenuText( GetShownText( false ) ) ); } BITMAPS SCH_LABEL::GetMenuImage() const { return BITMAPS::add_line_label; } SCH_DIRECTIVE_LABEL::SCH_DIRECTIVE_LABEL( const VECTOR2I& pos ) : SCH_LABEL_BASE( pos, wxEmptyString, SCH_DIRECTIVE_LABEL_T ) { m_layer = LAYER_NETCLASS_REFS; m_shape = LABEL_FLAG_SHAPE::F_ROUND; m_pinLength = schIUScale.MilsToIU( 100 ); m_symbolSize = schIUScale.MilsToIU( 20 ); m_isDangling = true; } void SCH_DIRECTIVE_LABEL::SwapData( SCH_ITEM* aItem ) { SCH_LABEL_BASE::SwapData( aItem ); SCH_DIRECTIVE_LABEL* label = static_cast( aItem ); std::swap( m_pinLength, label->m_pinLength ); std::swap( m_symbolSize, label->m_symbolSize ); } SCH_DIRECTIVE_LABEL::SCH_DIRECTIVE_LABEL( const SCH_DIRECTIVE_LABEL& aClassLabel ) : SCH_LABEL_BASE( aClassLabel ) { m_pinLength = aClassLabel.m_pinLength; m_symbolSize = aClassLabel.m_symbolSize; } void SCH_DIRECTIVE_LABEL::Serialize( google::protobuf::Any &aContainer ) const { // TODO } bool SCH_DIRECTIVE_LABEL::Deserialize( const google::protobuf::Any &aContainer ) { // TODO return false; } int SCH_DIRECTIVE_LABEL::GetPenWidth() const { int pen = 0; if( Schematic() ) pen = Schematic()->Settings().m_DefaultLineWidth; return GetEffectiveTextPenWidth( pen ); } void SCH_DIRECTIVE_LABEL::MirrorSpinStyle( bool aLeftRight ) { // The "text" is in fact a graphic shape. For a horizontal "text", it looks like a // vertical shape (like a text reduced to only "I" letter). // So the mirroring is not exactly similar to a SCH_TEXT item SCH_TEXT::MirrorSpinStyle( !aLeftRight ); for( SCH_FIELD& field : m_fields ) { if( ( aLeftRight && field.GetTextAngle().IsHorizontal() ) || ( !aLeftRight && field.GetTextAngle().IsVertical() ) ) { if( field.GetHorizJustify() == GR_TEXT_H_ALIGN_LEFT ) field.SetHorizJustify( GR_TEXT_H_ALIGN_RIGHT ); else field.SetHorizJustify( GR_TEXT_H_ALIGN_LEFT ); } VECTOR2I pos = field.GetTextPos(); VECTOR2I delta = (VECTOR2I)GetPosition() - pos; if( aLeftRight ) pos.x = GetPosition().x + delta.x; else pos.y = GetPosition().y + delta.y; field.SetTextPos( pos ); } } void SCH_DIRECTIVE_LABEL::MirrorHorizontally( int aCenter ) { VECTOR2I old_pos = GetPosition(); // The "text" is in fact a graphic shape. For a horizontal "text", it looks like a // vertical shape (like a text reduced to only "I" letter). // So the mirroring is not exactly similar to a SCH_TEXT item // Text is NOT really mirrored; it is moved to a suitable horizontal position SetSpinStyle( GetSpinStyle().MirrorX() ); SetTextX( MIRRORVAL( GetTextPos().x, aCenter ) ); for( SCH_FIELD& field : m_fields ) { if( field.GetHorizJustify() == GR_TEXT_H_ALIGN_LEFT ) field.SetHorizJustify( GR_TEXT_H_ALIGN_RIGHT ); else if( field.GetHorizJustify() == GR_TEXT_H_ALIGN_RIGHT ) field.SetHorizJustify( GR_TEXT_H_ALIGN_LEFT ); VECTOR2I pos = field.GetTextPos(); VECTOR2I delta = old_pos - pos; pos.x = GetPosition().x + delta.x; field.SetPosition( pos ); } } void SCH_DIRECTIVE_LABEL::MirrorVertically( int aCenter ) { VECTOR2I old_pos = GetPosition(); // The "text" is in fact a graphic shape. For a horizontal "text", it looks like a // vertical shape (like a text reduced to only "I" letter). // So the mirroring is not exactly similar to a SCH_TEXT item // Text is NOT really mirrored; it is moved to a suitable vertical position SetSpinStyle( GetSpinStyle().MirrorY() ); SetTextY( MIRRORVAL( GetTextPos().y, aCenter ) ); for( SCH_FIELD& field : m_fields ) { VECTOR2I pos = field.GetTextPos(); VECTOR2I delta = old_pos - pos; pos.y = GetPosition().y + delta.y; field.SetPosition( pos ); } } void SCH_DIRECTIVE_LABEL::CreateGraphicShape( const RENDER_SETTINGS* aRenderSettings, std::vector& aPoints, const VECTOR2I& aPos ) const { int symbolSize = m_symbolSize; aPoints.clear(); switch( m_shape ) { case LABEL_FLAG_SHAPE::F_DOT: symbolSize = KiROUND( symbolSize * 0.7 ); KI_FALLTHROUGH; case LABEL_FLAG_SHAPE::F_ROUND: // First 3 points are used for generating shape aPoints.emplace_back( VECTOR2I( 0, 0 ) ); aPoints.emplace_back( VECTOR2I( 0, m_pinLength - symbolSize ) ); aPoints.emplace_back( VECTOR2I( 0, m_pinLength ) ); // These points are just used to bulk out the bounding box aPoints.emplace_back( VECTOR2I( -m_symbolSize, m_pinLength ) ); aPoints.emplace_back( VECTOR2I( 0, m_pinLength ) ); aPoints.emplace_back( VECTOR2I( m_symbolSize, m_pinLength + symbolSize ) ); break; case LABEL_FLAG_SHAPE::F_DIAMOND: aPoints.emplace_back( VECTOR2I( 0, 0 ) ); aPoints.emplace_back( VECTOR2I( 0, m_pinLength - symbolSize ) ); aPoints.emplace_back( VECTOR2I( -2 * m_symbolSize, m_pinLength ) ); aPoints.emplace_back( VECTOR2I( 0, m_pinLength + symbolSize ) ); aPoints.emplace_back( VECTOR2I( 2 * m_symbolSize, m_pinLength ) ); aPoints.emplace_back( VECTOR2I( 0, m_pinLength - symbolSize ) ); aPoints.emplace_back( VECTOR2I( 0, 0 ) ); break; case LABEL_FLAG_SHAPE::F_RECTANGLE: symbolSize = KiROUND( symbolSize * 0.8 ); aPoints.emplace_back( VECTOR2I( 0, 0 ) ); aPoints.emplace_back( VECTOR2I( 0, m_pinLength - symbolSize ) ); aPoints.emplace_back( VECTOR2I( -2 * symbolSize, m_pinLength - symbolSize ) ); aPoints.emplace_back( VECTOR2I( -2 * symbolSize, m_pinLength + symbolSize ) ); aPoints.emplace_back( VECTOR2I( 2 * symbolSize, m_pinLength + symbolSize ) ); aPoints.emplace_back( VECTOR2I( 2 * symbolSize, m_pinLength - symbolSize ) ); aPoints.emplace_back( VECTOR2I( 0, m_pinLength - symbolSize ) ); aPoints.emplace_back( VECTOR2I( 0, 0 ) ); break; default: break; } // Rotate outlines and move corners to real position for( VECTOR2I& aPoint : aPoints ) { switch( GetSpinStyle() ) { default: case SPIN_STYLE::LEFT: break; case SPIN_STYLE::UP: RotatePoint( aPoint, -ANGLE_90 ); break; case SPIN_STYLE::RIGHT: RotatePoint( aPoint, ANGLE_180 ); break; case SPIN_STYLE::BOTTOM: RotatePoint( aPoint, ANGLE_90 ); break; } aPoint += aPos; } } void SCH_DIRECTIVE_LABEL::AutoplaceFields( SCH_SCREEN* aScreen, bool aManual ) { int margin = GetTextOffset(); int symbolWidth = m_symbolSize; int origin = m_pinLength; if( m_shape == LABEL_FLAG_SHAPE::F_DIAMOND || m_shape == LABEL_FLAG_SHAPE::F_RECTANGLE ) symbolWidth *= 2; if( IsItalic() ) margin = KiROUND( margin * 1.5 ); VECTOR2I offset; for( SCH_FIELD& field : m_fields ) { switch( GetSpinStyle() ) { default: case SPIN_STYLE::LEFT: field.SetTextAngle( ANGLE_HORIZONTAL ); offset = { symbolWidth + margin, origin }; break; case SPIN_STYLE::UP: field.SetTextAngle( ANGLE_VERTICAL ); offset = { -origin, -( symbolWidth + margin ) }; break; case SPIN_STYLE::RIGHT: field.SetTextAngle( ANGLE_HORIZONTAL ); offset = { symbolWidth + margin, -origin }; break; case SPIN_STYLE::BOTTOM: field.SetTextAngle( ANGLE_VERTICAL ); offset = { origin, -( symbolWidth + margin ) }; break; } field.SetHorizJustify( GR_TEXT_H_ALIGN_LEFT ); field.SetTextPos( GetPosition() + offset ); origin -= field.GetTextHeight() + margin; } m_fieldsAutoplaced = FIELDS_AUTOPLACED_AUTO; } wxString SCH_DIRECTIVE_LABEL::GetItemDescription( UNITS_PROVIDER* aUnitsProvider ) const { if( m_fields.empty() ) { return _( "Directive Label" ); } else { return wxString::Format( _( "Directive Label [%s %s]" ), UnescapeString( m_fields[0].GetName() ), KIUI::EllipsizeMenuText( m_fields[0].GetShownText( false ) ) ); } } SCH_GLOBALLABEL::SCH_GLOBALLABEL( const VECTOR2I& pos, const wxString& text ) : SCH_LABEL_BASE( pos, text, SCH_GLOBAL_LABEL_T ) { m_layer = LAYER_GLOBLABEL; m_shape = LABEL_FLAG_SHAPE::L_BIDI; m_isDangling = true; SetVertJustify( GR_TEXT_V_ALIGN_CENTER ); m_fields.emplace_back( SCH_FIELD( pos, 0, this, wxT( "Sheet References" ) ) ); m_fields[0].SetText( wxT( "${INTERSHEET_REFS}" ) ); m_fields[0].SetVisible( false ); m_fields[0].SetLayer( LAYER_INTERSHEET_REFS ); m_fields[0].SetVertJustify( GR_TEXT_V_ALIGN_CENTER ); } SCH_GLOBALLABEL::SCH_GLOBALLABEL( const SCH_GLOBALLABEL& aGlobalLabel ) : SCH_LABEL_BASE( aGlobalLabel ) { } void SCH_GLOBALLABEL::Serialize( google::protobuf::Any &aContainer ) const { // TODO } bool SCH_GLOBALLABEL::Deserialize( const google::protobuf::Any &aContainer ) { // TODO return false; } VECTOR2I SCH_GLOBALLABEL::GetSchematicTextOffset( const RENDER_SETTINGS* aSettings ) const { int horiz = GetLabelBoxExpansion( aSettings ); // Center the text on the center line of "E" instead of "R" to make room for an overbar int vert = GetTextHeight() * 0.0715; switch( m_shape ) { case LABEL_FLAG_SHAPE::L_INPUT: case LABEL_FLAG_SHAPE::L_BIDI: case LABEL_FLAG_SHAPE::L_TRISTATE: horiz += GetTextHeight() * 3 / 4; // Use three-quarters-height as proxy for triangle size break; case LABEL_FLAG_SHAPE::L_OUTPUT: case LABEL_FLAG_SHAPE::L_UNSPECIFIED: default: break; } switch( GetSpinStyle() ) { default: case SPIN_STYLE::LEFT: return VECTOR2I( -horiz, vert ); case SPIN_STYLE::UP: return VECTOR2I( vert, -horiz ); case SPIN_STYLE::RIGHT: return VECTOR2I( horiz, vert ); case SPIN_STYLE::BOTTOM: return VECTOR2I( vert, horiz ); } } void SCH_GLOBALLABEL::SetSpinStyle( SPIN_STYLE aSpinStyle ) { SCH_LABEL_BASE::SetSpinStyle( aSpinStyle ); SetVertJustify( GR_TEXT_V_ALIGN_CENTER ); } bool SCH_GLOBALLABEL::ResolveTextVar( const SCH_SHEET_PATH* aPath, wxString* token, int aDepth ) const { wxCHECK( aPath, false ); SCHEMATIC* schematic = Schematic(); if( !schematic ) return false; if( token->IsSameAs( wxT( "INTERSHEET_REFS" ) ) ) { SCHEMATIC_SETTINGS& settings = schematic->Settings(); wxString ref; auto it = schematic->GetPageRefsMap().find( GetShownText( aPath ) ); if( it == schematic->GetPageRefsMap().end() ) { ref = "?"; } else { std::vector pageListCopy; pageListCopy.insert( pageListCopy.end(), it->second.begin(), it->second.end() ); std::sort( pageListCopy.begin(), pageListCopy.end() ); if( !settings.m_IntersheetRefsListOwnPage ) { int currentPage = schematic->CurrentSheet().GetVirtualPageNumber(); alg::delete_matching( pageListCopy, currentPage ); } std::map sheetPages = schematic->GetVirtualPageToSheetPagesMap(); if( ( settings.m_IntersheetRefsFormatShort ) && ( pageListCopy.size() > 2 ) ) { ref.Append( wxString::Format( wxT( "%s..%s" ), sheetPages[pageListCopy.front()], sheetPages[pageListCopy.back()] ) ); } else { for( const int& pageNo : pageListCopy ) ref.Append( wxString::Format( wxT( "%s," ), sheetPages[pageNo] ) ); if( !ref.IsEmpty() && ref.Last() == ',' ) ref.RemoveLast(); } } *token = settings.m_IntersheetRefsPrefix + ref + settings.m_IntersheetRefsSuffix; return true; } return SCH_LABEL_BASE::ResolveTextVar( aPath, token, aDepth ); } void SCH_GLOBALLABEL::ViewGetLayers( int aLayers[], int& aCount ) const { aCount = 6; aLayers[0] = LAYER_DANGLING; aLayers[1] = LAYER_DEVICE; aLayers[2] = LAYER_INTERSHEET_REFS; aLayers[3] = LAYER_NETCLASS_REFS; aLayers[4] = LAYER_FIELDS; aLayers[5] = LAYER_SELECTION_SHADOWS; } void SCH_GLOBALLABEL::CreateGraphicShape( const RENDER_SETTINGS* aRenderSettings, std::vector& aPoints, const VECTOR2I& aPos ) const { int margin = GetLabelBoxExpansion( aRenderSettings ); int halfSize = ( GetTextHeight() / 2 ) + margin; int linewidth = GetPenWidth(); int symb_len = GetTextBox().GetWidth() + 2 * margin; int x = symb_len + linewidth + 3; int y = halfSize + linewidth + 3; aPoints.clear(); // Create outline shape : 6 points aPoints.emplace_back( VECTOR2I( 0, 0 ) ); aPoints.emplace_back( VECTOR2I( 0, -y ) ); // Up aPoints.emplace_back( VECTOR2I( -x, -y ) ); // left aPoints.emplace_back( VECTOR2I( -x, 0 ) ); // Up left aPoints.emplace_back( VECTOR2I( -x, y ) ); // left down aPoints.emplace_back( VECTOR2I( 0, y ) ); // down int x_offset = 0; switch( m_shape ) { case LABEL_FLAG_SHAPE::L_INPUT: x_offset = -halfSize; aPoints[0].x += halfSize; break; case LABEL_FLAG_SHAPE::L_OUTPUT: aPoints[3].x -= halfSize; break; case LABEL_FLAG_SHAPE::L_BIDI: case LABEL_FLAG_SHAPE::L_TRISTATE: x_offset = -halfSize; aPoints[0].x += halfSize; aPoints[3].x -= halfSize; break; case LABEL_FLAG_SHAPE::L_UNSPECIFIED: default: break; } // Rotate outlines and move corners in real position for( VECTOR2I& aPoint : aPoints ) { aPoint.x += x_offset; switch( GetSpinStyle() ) { default: case SPIN_STYLE::LEFT: break; case SPIN_STYLE::UP: RotatePoint( aPoint, -ANGLE_90 ); break; case SPIN_STYLE::RIGHT: RotatePoint( aPoint, ANGLE_180 ); break; case SPIN_STYLE::BOTTOM: RotatePoint( aPoint, ANGLE_90 ); break; } aPoint += aPos; } aPoints.push_back( aPoints[0] ); // closing } wxString SCH_GLOBALLABEL::GetItemDescription( UNITS_PROVIDER* aUnitsProvider ) const { return wxString::Format( _( "Global Label '%s'" ), KIUI::EllipsizeMenuText( GetShownText( false ) ) ); } BITMAPS SCH_GLOBALLABEL::GetMenuImage() const { return BITMAPS::add_glabel; } SCH_HIERLABEL::SCH_HIERLABEL( const VECTOR2I& pos, const wxString& text, KICAD_T aType ) : SCH_LABEL_BASE( pos, text, aType ) { m_layer = LAYER_HIERLABEL; m_shape = LABEL_FLAG_SHAPE::L_INPUT; m_isDangling = true; } void SCH_HIERLABEL::Serialize( google::protobuf::Any &aContainer ) const { // TODO } bool SCH_HIERLABEL::Deserialize( const google::protobuf::Any &aContainer ) { // TODO return false; } void SCH_HIERLABEL::SetSpinStyle( SPIN_STYLE aSpinStyle ) { SCH_LABEL_BASE::SetSpinStyle( aSpinStyle ); SetVertJustify( GR_TEXT_V_ALIGN_CENTER ); } void SCH_HIERLABEL::CreateGraphicShape( const RENDER_SETTINGS* aSettings, std::vector& aPoints, const VECTOR2I& aPos ) const { CreateGraphicShape( aSettings, aPoints, aPos, m_shape ); } void SCH_HIERLABEL::CreateGraphicShape( const RENDER_SETTINGS* aSettings, std::vector& aPoints, const VECTOR2I& aPos, LABEL_FLAG_SHAPE aShape ) const { int* Template = TemplateShape[static_cast( aShape )][static_cast( GetSpinStyle() )]; int halfSize = GetTextHeight() / 2; int imax = *Template; Template++; aPoints.clear(); for( int ii = 0; ii < imax; ii++ ) { VECTOR2I corner; corner.x = ( halfSize * (*Template) ) + aPos.x; Template++; corner.y = ( halfSize * (*Template) ) + aPos.y; Template++; aPoints.push_back( corner ); } } const BOX2I SCH_HIERLABEL::GetBodyBoundingBox() const { int penWidth = GetEffectiveTextPenWidth(); int margin = GetTextOffset(); int x = GetTextPos().x; int y = GetTextPos().y; int height = GetTextHeight() + penWidth + margin; int length = GetTextBox().GetWidth(); length += height; // add height for triangular shapes int dx, dy; switch( GetSpinStyle() ) { default: case SPIN_STYLE::LEFT: dx = -length; dy = height; x += schIUScale.MilsToIU( DANGLING_SYMBOL_SIZE ); y -= height / 2; break; case SPIN_STYLE::UP: dx = height; dy = -length; x -= height / 2; y += schIUScale.MilsToIU( DANGLING_SYMBOL_SIZE ); break; case SPIN_STYLE::RIGHT: dx = length; dy = height; x -= schIUScale.MilsToIU( DANGLING_SYMBOL_SIZE ); y -= height / 2; break; case SPIN_STYLE::BOTTOM: dx = height; dy = length; x -= height / 2; y -= schIUScale.MilsToIU( DANGLING_SYMBOL_SIZE ); break; } BOX2I box( VECTOR2I( x, y ), VECTOR2I( dx, dy ) ); box.Normalize(); return box; } VECTOR2I SCH_HIERLABEL::GetSchematicTextOffset( const RENDER_SETTINGS* aSettings ) const { VECTOR2I text_offset; int dist = GetTextOffset( aSettings ); dist += GetTextWidth(); switch( GetSpinStyle() ) { default: case SPIN_STYLE::LEFT: text_offset.x = -dist; break; // Orientation horiz normale case SPIN_STYLE::UP: text_offset.y = -dist; break; // Orientation vert UP case SPIN_STYLE::RIGHT: text_offset.x = dist; break; // Orientation horiz inverse case SPIN_STYLE::BOTTOM: text_offset.y = dist; break; // Orientation vert BOTTOM } return text_offset; } wxString SCH_HIERLABEL::GetItemDescription( UNITS_PROVIDER* aUnitsProvider ) const { return wxString::Format( _( "Hierarchical Label '%s'" ), KIUI::EllipsizeMenuText( GetShownText( false ) ) ); } BITMAPS SCH_HIERLABEL::GetMenuImage() const { return BITMAPS::add_hierarchical_label; } HTML_MESSAGE_BOX* SCH_TEXT::ShowSyntaxHelp( wxWindow* aParentWindow ) { wxString msg = #include "sch_text_help_md.h" ; HTML_MESSAGE_BOX* dlg = new HTML_MESSAGE_BOX( nullptr, _( "Syntax Help" ) ); wxSize sz( 320, 320 ); dlg->SetMinSize( dlg->ConvertDialogToPixels( sz ) ); dlg->SetDialogSizeInDU( sz.x, sz.y ); wxString html_txt; ConvertMarkdown2Html( wxGetTranslation( msg ), html_txt ); dlg->AddHTML_Text( html_txt ); dlg->ShowModeless(); return dlg; } static struct SCH_LABEL_DESC { SCH_LABEL_DESC() { auto& labelShapeEnum = ENUM_MAP::Instance(); if( labelShapeEnum.Choices().GetCount() == 0 ) { labelShapeEnum.Map( LABEL_SHAPE::LABEL_INPUT, _HKI( "Input" ) ) .Map( LABEL_SHAPE::LABEL_OUTPUT, _HKI( "Output" ) ) .Map( LABEL_SHAPE::LABEL_BIDI, _HKI( "Bidirectional" ) ) .Map( LABEL_SHAPE::LABEL_TRISTATE, _HKI( "Tri-state" ) ) .Map( LABEL_SHAPE::LABEL_PASSIVE, _HKI( "Passive" ) ); } PROPERTY_MANAGER& propMgr = PROPERTY_MANAGER::Instance(); REGISTER_TYPE( SCH_LABEL_BASE ); REGISTER_TYPE( SCH_LABEL ); REGISTER_TYPE( SCH_HIERLABEL ); propMgr.AddTypeCast( new TYPE_CAST ); propMgr.AddTypeCast( new TYPE_CAST ); propMgr.AddTypeCast( new TYPE_CAST ); propMgr.AddTypeCast( new TYPE_CAST ); propMgr.AddTypeCast( new TYPE_CAST ); propMgr.AddTypeCast( new TYPE_CAST ); propMgr.AddTypeCast( new TYPE_CAST ); propMgr.AddTypeCast( new TYPE_CAST ); propMgr.AddTypeCast( new TYPE_CAST ); propMgr.InheritsAfter( TYPE_HASH( SCH_LABEL_BASE ), TYPE_HASH( SCH_TEXT ) ); propMgr.InheritsAfter( TYPE_HASH( SCH_LABEL ), TYPE_HASH( SCH_LABEL_BASE ) ); propMgr.InheritsAfter( TYPE_HASH( SCH_HIERLABEL ), TYPE_HASH( SCH_LABEL_BASE ) ); propMgr.InheritsAfter( TYPE_HASH( SCH_GLOBALLABEL ), TYPE_HASH( SCH_LABEL_BASE ) ); auto hasLabelShape = []( INSPECTABLE* aItem ) -> bool { if( SCH_LABEL_BASE* label = dynamic_cast( aItem ) ) return label->IsType( { SCH_GLOBAL_LABEL_T, SCH_HIER_LABEL_T } ); return false; }; propMgr.AddProperty( new PROPERTY_ENUM( _HKI( "Shape" ), &SCH_LABEL_BASE::SetLabelShape, &SCH_LABEL_BASE::GetLabelShape ) ) .SetAvailableFunc( hasLabelShape ); propMgr.Mask( TYPE_HASH( SCH_LABEL_BASE ), TYPE_HASH( EDA_TEXT ), _HKI( "Hyperlink" ) ); } } _SCH_LABEL_DESC; static struct SCH_DIRECTIVE_LABEL_DESC { SCH_DIRECTIVE_LABEL_DESC() { auto& flagShapeEnum = ENUM_MAP::Instance(); if( flagShapeEnum.Choices().GetCount() == 0 ) { flagShapeEnum.Map( FLAG_SHAPE::FLAG_DOT, _HKI( "Dot" ) ) .Map( FLAG_SHAPE::FLAG_CIRCLE, _HKI( "Circle" ) ) .Map( FLAG_SHAPE::FLAG_DIAMOND, _HKI( "Diamond" ) ) .Map( FLAG_SHAPE::FLAG_RECTANGLE, _HKI( "Rectangle" ) ); } PROPERTY_MANAGER& propMgr = PROPERTY_MANAGER::Instance(); REGISTER_TYPE( SCH_DIRECTIVE_LABEL ); propMgr.AddTypeCast( new TYPE_CAST ); propMgr.AddTypeCast( new TYPE_CAST ); propMgr.AddTypeCast( new TYPE_CAST ); propMgr.InheritsAfter( TYPE_HASH( SCH_DIRECTIVE_LABEL ), TYPE_HASH( SCH_LABEL_BASE ) ); propMgr.AddProperty( new PROPERTY_ENUM( _HKI( "Shape" ), &SCH_DIRECTIVE_LABEL::SetFlagShape, &SCH_DIRECTIVE_LABEL::GetFlagShape ) ); propMgr.AddProperty( new PROPERTY( _HKI( "Pin length" ), &SCH_DIRECTIVE_LABEL::SetPinLength, &SCH_DIRECTIVE_LABEL::GetPinLength, PROPERTY_DISPLAY::PT_SIZE ) ); propMgr.Mask( TYPE_HASH( SCH_DIRECTIVE_LABEL ), TYPE_HASH( EDA_TEXT ), _HKI( "Text" ) ); propMgr.Mask( TYPE_HASH( SCH_DIRECTIVE_LABEL ), TYPE_HASH( EDA_TEXT ), _HKI( "Thickness" ) ); propMgr.Mask( TYPE_HASH( SCH_DIRECTIVE_LABEL ), TYPE_HASH( EDA_TEXT ), _HKI( "Italic" ) ); propMgr.Mask( TYPE_HASH( SCH_DIRECTIVE_LABEL ), TYPE_HASH( EDA_TEXT ), _HKI( "Bold" ) ); propMgr.Mask( TYPE_HASH( SCH_DIRECTIVE_LABEL ), TYPE_HASH( EDA_TEXT ), _HKI( "Horizontal Justification" ) ); propMgr.Mask( TYPE_HASH( SCH_DIRECTIVE_LABEL ), TYPE_HASH( EDA_TEXT ), _HKI( "Vertical Justification" ) ); } } _SCH_DIRECTIVE_LABEL_DESC; ENUM_TO_WXANY( LABEL_SHAPE ) ENUM_TO_WXANY( FLAG_SHAPE )