/* * This program source code file is part of KiCad, a free EDA CAD application. * * Copyright (C) 2013 Jean-Pierre Charras, jp.charras at wanadoo.fr * Copyright (C) 2012 SoftPLC Corporation, Dick Hollenbeck * Copyright (C) 2008 Wayne Stambaugh * Copyright (C) 1992-2020 KiCad Developers, see AUTHORS.txt for contributors. * * This program is free software; you can redistribute it and/or * modify it under the terms of the GNU General Public License * as published by the Free Software Foundation; either version 2 * of the License, or (at your option) any later version. * * This program is distributed in the hope that it will be useful, * but WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the * GNU General Public License for more details. * * You should have received a copy of the GNU General Public License * along with this program; if not, you may find one here: * http://www.gnu.org/licenses/old-licenses/gpl-2.0.html * or you may search the http://www.gnu.org website for the version 2 license, * or you may write to the Free Software Foundation, Inc., * 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301, USA */ /** * @file sch_screen.cpp * @brief Implementation of SCH_SCREEN and SCH_SCREENS classes. */ #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include // TODO(JE) Debugging only #include #define EESCHEMA_FILE_STAMP "EESchema" #define ZOOM_FACTOR( x ) ( x * IU_PER_MILS ) /* Default zoom values. Limited to these values to keep a decent size * to menus */ static double SchematicZoomList[] = { ZOOM_FACTOR( 0.5 ), ZOOM_FACTOR( 0.7 ), ZOOM_FACTOR( 1.0 ), ZOOM_FACTOR( 1.5 ), ZOOM_FACTOR( 2.0 ), ZOOM_FACTOR( 3.0 ), ZOOM_FACTOR( 4.0 ), ZOOM_FACTOR( 6.0 ), ZOOM_FACTOR( 8.0 ), ZOOM_FACTOR( 11.0 ), ZOOM_FACTOR( 13.0 ), ZOOM_FACTOR( 16.0 ), ZOOM_FACTOR( 20.0 ), ZOOM_FACTOR( 26.0 ), ZOOM_FACTOR( 32.0 ), ZOOM_FACTOR( 48.0 ), ZOOM_FACTOR( 64.0 ), ZOOM_FACTOR( 80.0 ), ZOOM_FACTOR( 128.0 ) }; /* Default grid sizes for the schematic editor. * Do NOT add others values (mainly grid values in mm), because they * can break the schematic: Because wires and pins are considered as * connected when the are to the same coordinate we cannot mix * coordinates in mils (internal units) and mm (that cannot exactly * converted in mils in many cases). In fact schematic must only use * 50 and 25 mils to place labels, wires and components others values * are useful only for graphic items (mainly in library editor) so use * integer values in mils only. The 100 mil grid is added to help * conform to the KiCad Library Convention. Which states: "Using a * 100mil grid, pin ends and origin must lie on grid nodes IEC-60617" */ static GRID_TYPE SchematicGridList[] = { { ID_POPUP_GRID_LEVEL_100, wxRealPoint( Mils2iu( 100 ), Mils2iu( 100 ) ) }, { ID_POPUP_GRID_LEVEL_50, wxRealPoint( Mils2iu( 50 ), Mils2iu( 50 ) ) }, { ID_POPUP_GRID_LEVEL_25, wxRealPoint( Mils2iu( 25 ), Mils2iu( 25 ) ) }, { ID_POPUP_GRID_LEVEL_10, wxRealPoint( Mils2iu( 10 ), Mils2iu( 10 ) ) }, { ID_POPUP_GRID_LEVEL_5, wxRealPoint( Mils2iu( 5 ), Mils2iu( 5 ) ) }, { ID_POPUP_GRID_LEVEL_2, wxRealPoint( Mils2iu( 2 ), Mils2iu( 2 ) ) }, { ID_POPUP_GRID_LEVEL_1, wxRealPoint( Mils2iu( 1 ), Mils2iu( 1 ) ) }, }; SCH_SCREEN::SCH_SCREEN( KIWAY* aKiway ) : BASE_SCREEN( SCH_SCREEN_T ), KIWAY_HOLDER( aKiway, KIWAY_HOLDER::HOLDER_TYPE::SCREEN ), m_paper( wxT( "A4" ) ) { m_modification_sync = 0; SetZoom( 32 ); for( unsigned zoom : SchematicZoomList ) m_ZoomList.push_back( zoom ); for( GRID_TYPE grid : SchematicGridList ) AddGrid( grid ); // Set the default grid size, now that the grid list is populated SetGrid( wxRealPoint( Mils2iu( 50 ), Mils2iu( 50 ) ) ); m_refCount = 0; // Suitable for schematic only. For libedit and viewlib, must be set to true m_Center = false; InitDataPoints( m_paper.GetSizeIU() ); } SCH_SCREEN::~SCH_SCREEN() { ClearUndoRedoList(); FreeDrawList(); } void SCH_SCREEN::IncRefCount() { m_refCount++; } void SCH_SCREEN::DecRefCount() { wxCHECK_RET( m_refCount != 0, wxT( "Screen reference count already zero. Bad programmer!" ) ); m_refCount--; } void SCH_SCREEN::Append( SCH_ITEM* aItem ) { if( aItem->Type() != SCH_SHEET_PIN_T && aItem->Type() != SCH_FIELD_T ) { m_rtree.insert( aItem ); --m_modification_sync; } } void SCH_SCREEN::Append( SCH_SCREEN* aScreen ) { wxCHECK_RET( aScreen, "Invalid screen object." ); // No need to descend the hierarchy. Once the top level screen is copied, all of it's // children are copied as well. for( auto aItem : aScreen->m_rtree ) Append( aItem ); aScreen->Clear( false ); } void SCH_SCREEN::Clear( bool aFree ) { if( aFree ) FreeDrawList(); else m_rtree.clear(); // Clear the project settings m_ScreenNumber = m_NumberOfScreens = 1; m_titles.Clear(); } void SCH_SCREEN::FreeDrawList() { // We don't know which order we will encounter dependent items (e.g. pins or fields), so // we store the items to be deleted until we've fully cleared the tree before deleting std::vector delete_list; std::copy_if( m_rtree.begin(), m_rtree.end(), std::back_inserter( delete_list ), []( SCH_ITEM* aItem ) { return ( aItem->Type() != SCH_SHEET_PIN_T && aItem->Type() != SCH_FIELD_T ); } ); m_rtree.clear(); for( auto item : delete_list ) delete item; } void SCH_SCREEN::Update( SCH_ITEM* aItem ) { if( Remove( aItem ) ) Append( aItem ); } bool SCH_SCREEN::Remove( SCH_ITEM* aItem ) { return m_rtree.remove( aItem ); } void SCH_SCREEN::DeleteItem( SCH_ITEM* aItem ) { wxCHECK_RET( aItem, wxT( "Cannot delete invalid item from screen." ) ); SetModify(); Remove( aItem ); if( aItem->Type() == SCH_SHEET_PIN_T ) { // This structure is attached to a sheet, get the parent sheet object. SCH_SHEET_PIN* sheetPin = (SCH_SHEET_PIN*) aItem; SCH_SHEET* sheet = sheetPin->GetParent(); wxCHECK_RET( sheet, wxT( "Sheet label parent not properly set, bad programmer!" ) ); sheet->RemovePin( sheetPin ); return; } else { delete aItem; } } bool SCH_SCREEN::CheckIfOnDrawList( SCH_ITEM* aItem ) { return m_rtree.contains( aItem, true ); } SCH_ITEM* SCH_SCREEN::GetItem( const wxPoint& aPosition, int aAccuracy, KICAD_T aType ) { EDA_RECT bbox; bbox.SetOrigin( aPosition ); bbox.Inflate( aAccuracy ); for( auto item : Items().Overlapping( aType, bbox ) ) { if( item->HitTest( aPosition, aAccuracy ) ) return item; } return nullptr; } std::set SCH_SCREEN::MarkConnections( SCH_LINE* aSegment ) { std::set retval; std::stack to_search; wxCHECK_MSG( ( aSegment ) && ( aSegment->Type() == SCH_LINE_T ), retval, wxT( "Invalid object pointer." ) ); to_search.push( aSegment ); while( !to_search.empty() ) { auto test_item = to_search.top(); to_search.pop(); for( auto item : Items().Overlapping( SCH_JUNCTION_T, test_item->GetBoundingBox() ) ) { if( test_item->IsEndPoint( item->GetPosition() ) ) retval.insert( item ); } for( auto item : Items().Overlapping( SCH_LINE_T, test_item->GetBoundingBox() ) ) { // Skip connecting lines on different layers (e.g. buses) if( test_item->GetLayer() != item->GetLayer() ) continue; auto line = static_cast( item ); if( ( test_item->IsEndPoint( line->GetStartPoint() ) && !GetPin( line->GetStartPoint(), NULL, true ) ) || ( test_item->IsEndPoint( line->GetEndPoint() ) && !GetPin( line->GetEndPoint(), nullptr, true ) ) ) { auto result = retval.insert( line ); if( result.second ) to_search.push( line ); } } } return retval; } bool SCH_SCREEN::IsJunctionNeeded( const wxPoint& aPosition, bool aNew ) { enum { WIRES, BUSES } layers; bool has_nonparallel[ sizeof( layers ) ] = { false }; int end_count[ sizeof( layers ) ] = { 0 }; int pin_count = 0; std::vector lines[ sizeof( layers ) ]; for( auto item : Items().Overlapping( aPosition ) ) { if( item->GetEditFlags() & STRUCT_DELETED ) continue; if( aNew && ( item->Type() == SCH_JUNCTION_T ) && ( item->HitTest( aPosition ) ) ) return false; if( ( item->Type() == SCH_LINE_T ) && ( item->HitTest( aPosition, 0 ) ) ) { if( item->GetLayer() == LAYER_WIRE ) lines[WIRES].push_back( (SCH_LINE*) item ); else if( item->GetLayer() == LAYER_BUS ) lines[BUSES].push_back( (SCH_LINE*) item ); } if( ( ( item->Type() == SCH_COMPONENT_T ) || ( item->Type() == SCH_SHEET_T ) ) && ( item->IsConnected( aPosition ) ) ) pin_count++; } for( int i : { WIRES, BUSES } ) { bool removed_overlapping = false; bool mid_point = false; for( auto line = lines[i].begin(); line < lines[i].end(); line++ ) { if( !(*line)->IsEndPoint( aPosition ) ) mid_point = true; else end_count[i]++; for( auto second_line = lines[i].end() - 1; second_line > line; second_line-- ) { if( !(*line)->IsParallel( *second_line ) ) has_nonparallel[i] = true; else if( !removed_overlapping && (*line)->IsSameQuadrant( *second_line, aPosition ) ) { removed_overlapping = true; } } } /// A line with a midpoint should be counted as two endpoints for this calculation /// because the junction will split the line into two if there is another item /// present at the point. if( mid_point ) end_count[i] += 2; ///Overlapping lines that point in the same direction should not be counted /// as extra end_points. if( removed_overlapping ) end_count[i]--; } // If there are three or more endpoints if( pin_count && pin_count + end_count[WIRES] > 2 ) return true; // If there is at least one segment that ends on a non-parallel line or // junction of two other lines if( has_nonparallel[WIRES] && end_count[WIRES] > 2 ) return true; // Check for bus - bus junction requirements if( has_nonparallel[BUSES] && end_count[BUSES] > 2 ) return true; return false; } bool SCH_SCREEN::IsTerminalPoint( const wxPoint& aPosition, int aLayer ) { wxCHECK_MSG( aLayer == LAYER_NOTES || aLayer == LAYER_BUS || aLayer == LAYER_WIRE, false, wxT( "Invalid layer type passed to SCH_SCREEN::IsTerminalPoint()." ) ); SCH_SHEET_PIN* label; SCH_TEXT* text; SCH_CONNECTION conn; switch( aLayer ) { case LAYER_BUS: if( GetBus( aPosition ) ) return true; label = GetSheetLabel( aPosition ); if( label && conn.IsBusLabel( label->GetText() ) && label->IsConnected( aPosition ) ) return true; text = GetLabel( aPosition ); if( text && conn.IsBusLabel( text->GetText() ) && text->IsConnected( aPosition ) && (text->Type() != SCH_LABEL_T) ) return true; break; case LAYER_NOTES: if( GetLine( aPosition ) ) return true; break; case LAYER_WIRE: if( GetItem( aPosition, std::max( GetDefaultLineThickness(), 3 ), SCH_BUS_WIRE_ENTRY_T) ) return true; if( GetItem( aPosition, std::max( GetDefaultLineThickness(), 3 ), SCH_BUS_BUS_ENTRY_T) ) return true; if( GetItem( aPosition, std::max( GetDefaultLineThickness(), 3 ), SCH_JUNCTION_T ) ) return true; if( GetPin( aPosition, NULL, true ) ) return true; if( GetWire( aPosition ) ) return true; text = GetLabel( aPosition ); if( text && text->IsConnected( aPosition ) && !conn.IsBusLabel( text->GetText() ) ) return true; label = GetSheetLabel( aPosition ); if( label && label->IsConnected( aPosition ) && !conn.IsBusLabel( label->GetText() ) ) return true; break; default: break; } return false; } void SCH_SCREEN::UpdateSymbolLinks( bool aForce ) { // Initialize or reinitialize the pointer to the LIB_PART for each component // found in m_drawList, but only if needed (change in lib or schematic) // therefore the calculation time is usually very low. if( !IsEmpty() ) { std::vector cmps; SYMBOL_LIB_TABLE* libs = Prj().SchSymbolLibTable(); int mod_hash = libs->GetModifyHash(); for( auto aItem : Items().OfType( SCH_COMPONENT_T ) ) cmps.push_back( static_cast( aItem ) ); for( auto cmp : cmps ) Remove( cmp ); // Must we resolve? if( (m_modification_sync != mod_hash) || aForce ) { SCH_COMPONENT::ResolveAll( cmps, *libs, Prj().SchLibs()->GetCacheLibrary() ); m_modification_sync = mod_hash; // note the last mod_hash } // Resolving will update the pin caches but we must ensure that this happens // even if the libraries don't change. else { for( auto cmp : cmps ) cmp->UpdatePins(); } // Changing the symbol may adjust the bbox of the symbol. This re-inserts the // item with the new bbox for( auto cmp : cmps ) Append( cmp ); } } void SCH_SCREEN::Print( wxDC* aDC ) { // Ensure links are up to date, even if a library was reloaded for some reason: std::vector< SCH_ITEM* > junctions; std::vector bitmaps; std::vector other; // Ensure links are up to date, even if a library was reloaded for some reason: UpdateSymbolLinks(); for( auto item : Items() ) { if( item->IsMoving() || item->IsResized() ) continue; if( item->Type() == SCH_JUNCTION_T ) junctions.push_back( item ); else if( item->Type() == SCH_BITMAP_T ) bitmaps.push_back( item ); else other.push_back( item ); } /// Sort to ensure plot-order consistency with screen drawing std::sort( other.begin(), other.end(), []( const SCH_ITEM* a, const SCH_ITEM* b ) { if( a->Type() == b->Type() ) return a->GetLayer() > b->GetLayer(); return a->Type() > b->Type(); } ); for( auto item : bitmaps ) item->Print( aDC, wxPoint( 0, 0 ) ); for( auto item : other ) item->Print( aDC, wxPoint( 0, 0 ) ); for( auto item : junctions ) item->Print( aDC, wxPoint( 0, 0 ) ); } void SCH_SCREEN::Plot( PLOTTER* aPlotter ) { // Ensure links are up to date, even if a library was reloaded for some reason: std::vector< SCH_ITEM* > junctions; std::vector< SCH_ITEM* > bitmaps; std::vector< SCH_ITEM* > other; // Ensure links are up to date, even if a library was reloaded for some reason: UpdateSymbolLinks(); for( auto item : Items() ) { if( item->IsMoving() || item->IsResized() ) continue; if( item->Type() == SCH_JUNCTION_T ) junctions.push_back( item ); else if( item->Type() == SCH_BITMAP_T ) bitmaps.push_back( item ); else other.push_back( item ); } /// Sort to ensure plot-order consistency with screen drawing std::sort( other.begin(), other.end(), []( const SCH_ITEM* a, const SCH_ITEM* b ) { if( a->Type() == b->Type() ) return a->GetLayer() > b->GetLayer(); return a->Type() > b->Type(); } ); // Bitmaps are drawn first to ensure they are in the background // This is particularly important for the wxPostscriptDC (used in *nix printers) as // the bitmap PS command clears the screen for( auto item : bitmaps ) { aPlotter->SetCurrentLineWidth( item->GetPenSize() ); item->Plot( aPlotter ); } for( auto item : other ) { aPlotter->SetCurrentLineWidth( item->GetPenSize() ); item->Plot( aPlotter ); } for( auto item : junctions ) { aPlotter->SetCurrentLineWidth( item->GetPenSize() ); item->Plot( aPlotter ); } } void SCH_SCREEN::ClearUndoORRedoList( UNDO_REDO_CONTAINER& aList, int aItemCount ) { if( aItemCount == 0 ) return; for( auto& command : aList.m_CommandsList ) { command->ClearListAndDeleteItems(); delete command; } aList.m_CommandsList.clear(); } void SCH_SCREEN::ClearDrawingState() { for( auto item : Items() ) item->ClearTempFlags(); } LIB_PIN* SCH_SCREEN::GetPin( const wxPoint& aPosition, SCH_COMPONENT** aComponent, bool aEndPointOnly ) { SCH_COMPONENT* component = NULL; LIB_PIN* pin = NULL; for( SCH_ITEM* item : Items().Overlapping( SCH_COMPONENT_T, aPosition ) ) { component = static_cast( item ); if( aEndPointOnly ) { pin = NULL; if( !component->GetPartRef() ) continue; for( pin = component->GetPartRef()->GetNextPin(); pin; pin = component->GetPartRef()->GetNextPin( pin ) ) { // Skip items not used for this part. if( component->GetUnit() && pin->GetUnit() && ( pin->GetUnit() != component->GetUnit() ) ) continue; if( component->GetConvert() && pin->GetConvert() && ( pin->GetConvert() != component->GetConvert() ) ) continue; if(component->GetPinPhysicalPosition( pin ) == aPosition ) break; } if( pin ) break; } else { pin = (LIB_PIN*) component->GetDrawItem( aPosition, LIB_PIN_T ); if( pin ) break; } } if( pin && aComponent ) *aComponent = component; return pin; } SCH_SHEET_PIN* SCH_SCREEN::GetSheetLabel( const wxPoint& aPosition ) { SCH_SHEET_PIN* sheetPin = nullptr; for( SCH_ITEM* item : Items().OfType( SCH_SHEET_T ) ) { auto sheet = static_cast( item ); sheetPin = sheet->GetPin( aPosition ); if( sheetPin ) break; } return sheetPin; } size_t SCH_SCREEN::CountConnectedItems( const wxPoint& aPos, bool aTestJunctions ) { size_t count = 0; for( SCH_ITEM* item : Items() ) { if( ( item->Type() != SCH_JUNCTION_T || aTestJunctions ) && item->IsConnected( aPos ) ) count++; } return count; } void SCH_SCREEN::ClearAnnotation( SCH_SHEET_PATH* aSheetPath ) { for( SCH_ITEM* item : Items().OfType( SCH_COMPONENT_T ) ) { SCH_COMPONENT* component = static_cast( item ); component->ClearAnnotation( aSheetPath ); // Clear the modified component flag set by component->ClearAnnotation // because we do not use it here and we should not leave this flag set, // when an editing is finished: component->ClearFlags(); } } void SCH_SCREEN::EnsureAlternateReferencesExist() { if( GetClientSheetPathsCount() <= 1 ) // No need for alternate reference return; for( SCH_ITEM* item : Items().OfType( SCH_COMPONENT_T ) ) { auto component = static_cast( item ); // Add (when not existing) all sheet path entries for( unsigned int ii = 0; ii < m_clientSheetPathList.GetCount(); ii++ ) component->AddSheetPathReferenceEntryIfMissing( m_clientSheetPathList[ii] ); } } void SCH_SCREEN::GetHierarchicalItems( EDA_ITEMS& aItems ) { for( SCH_ITEM* item : Items() ) { if( ( item->Type() == SCH_SHEET_T ) || ( item->Type() == SCH_COMPONENT_T ) ) aItems.push_back( item ); } } bool SCH_SCREEN::TestDanglingEnds( const SCH_SHEET_PATH* aPath ) { std::vector< DANGLING_END_ITEM > endPoints; bool hasStateChanged = false; for( SCH_ITEM* item : Items() ) item->GetEndPoints( endPoints ); for( SCH_ITEM* item : Items() ) { if( item->UpdateDanglingState( endPoints, aPath ) ) hasStateChanged = true; } return hasStateChanged; } SCH_LINE* SCH_SCREEN::GetLine( const wxPoint& aPosition, int aAccuracy, int aLayer, SCH_LINE_TEST_T aSearchType ) { for( SCH_ITEM* item : Items() ) { if( item->Type() != SCH_LINE_T ) continue; if( item->GetLayer() != aLayer ) continue; if( !item->HitTest( aPosition, aAccuracy ) ) continue; switch( aSearchType ) { case ENTIRE_LENGTH_T: return (SCH_LINE*) item; case EXCLUDE_END_POINTS_T: if( !( (SCH_LINE*) item )->IsEndPoint( aPosition ) ) return (SCH_LINE*) item; break; case END_POINTS_ONLY_T: if( ( (SCH_LINE*) item )->IsEndPoint( aPosition ) ) return (SCH_LINE*) item; } } return NULL; } SCH_TEXT* SCH_SCREEN::GetLabel( const wxPoint& aPosition, int aAccuracy ) { for( SCH_ITEM* item : Items().Overlapping( aPosition, aAccuracy ) ) { switch( item->Type() ) { case SCH_LABEL_T: case SCH_GLOBAL_LABEL_T: case SCH_HIER_LABEL_T: if( item->HitTest( aPosition, aAccuracy ) ) return (SCH_TEXT*) item; default: ; } } return NULL; } bool SCH_SCREEN::SetComponentFootprint( SCH_SHEET_PATH* aSheetPath, const wxString& aReference, const wxString& aFootPrint, bool aSetVisible ) { SCH_COMPONENT* component; bool found = false; for( SCH_ITEM* item : Items().OfType( SCH_COMPONENT_T ) ) { component = static_cast( item ); if( aReference.CmpNoCase( component->GetRef( aSheetPath ) ) == 0 ) { // Found: Init Footprint Field /* Give a reasonable value to the field position and * orientation, if the text is empty at position 0, because * it is probably not yet initialized */ SCH_FIELD * fpfield = component->GetField( FOOTPRINT ); if( fpfield->GetText().IsEmpty() && ( fpfield->GetTextPos() == component->GetPosition() ) ) { fpfield->SetTextAngle( component->GetField( VALUE )->GetTextAngle() ); fpfield->SetTextPos( component->GetField( VALUE )->GetTextPos() ); fpfield->SetTextSize( component->GetField( VALUE )->GetTextSize() ); if( fpfield->GetTextAngle() == 0.0 ) fpfield->Offset( wxPoint( 0, Mils2iu( 100 ) ) ); else fpfield->Offset( wxPoint( Mils2iu( 100 ), 0 ) ); } fpfield->SetText( aFootPrint ); fpfield->SetVisible( aSetVisible ); found = true; } } return found; } void SCH_SCREEN::AddBusAlias( std::shared_ptr aAlias ) { m_aliases.insert( aAlias ); } bool SCH_SCREEN::IsBusAlias( const wxString& aLabel ) { SCH_SHEET_LIST aSheets( g_RootSheet ); for( unsigned i = 0; i < aSheets.size(); i++ ) { for( const auto& alias : aSheets[i].LastScreen()->GetBusAliases() ) { if( alias->GetName() == aLabel ) { return true; } } } return false; } std::shared_ptr SCH_SCREEN::GetBusAlias( const wxString& aLabel ) { SCH_SHEET_LIST aSheets( g_RootSheet ); for( unsigned i = 0; i < aSheets.size(); i++ ) { for( auto alias : aSheets[i].LastScreen()->GetBusAliases() ) { if( alias->GetName() == aLabel ) { return alias; } } } return NULL; } #if defined(DEBUG) void SCH_SCREEN::Show( int nestLevel, std::ostream& os ) const { // for now, make it look like XML, expand on this later. NestedSpace( nestLevel, os ) << '<' << GetClass().Lower().mb_str() << ">\n"; for( const SCH_ITEM* item : Items() ) item->Show( nestLevel + 1, os ); NestedSpace( nestLevel, os ) << "\n"; } #endif SCH_SCREENS::SCH_SCREENS( SCH_SHEET* aSheet ) { m_index = 0; buildScreenList( ( !aSheet ) ? g_RootSheet : aSheet ); } SCH_SCREENS::~SCH_SCREENS() { } SCH_SCREEN* SCH_SCREENS::GetFirst() { m_index = 0; if( m_screens.size() > 0 ) return m_screens[0]; return NULL; } SCH_SCREEN* SCH_SCREENS::GetNext() { if( m_index < m_screens.size() ) m_index++; return GetScreen( m_index ); } SCH_SCREEN* SCH_SCREENS::GetScreen( unsigned int aIndex ) const { if( aIndex < m_screens.size() ) return m_screens[ aIndex ]; return NULL; } void SCH_SCREENS::addScreenToList( SCH_SCREEN* aScreen ) { if( aScreen == NULL ) return; for( const SCH_SCREEN* screen : m_screens ) { if( screen == aScreen ) return; } m_screens.push_back( aScreen ); } void SCH_SCREENS::buildScreenList( SCH_SHEET* aSheet ) { if( aSheet && aSheet->Type() == SCH_SHEET_T ) { SCH_SCREEN* screen = aSheet->GetScreen(); addScreenToList( screen ); for( SCH_ITEM* item : screen->Items().OfType( SCH_SHEET_T ) ) buildScreenList( static_cast( item ) ); } } void SCH_SCREENS::ClearAnnotation() { for( SCH_SCREEN* screen : m_screens ) screen->ClearAnnotation( NULL ); } void SCH_SCREENS::ClearAnnotationOfNewSheetPaths( SCH_SHEET_LIST& aInitialSheetPathList ) { // Clear the annotation for the components inside new sheetpaths // not already in aInitialSheetList SCH_SCREENS screensList( g_RootSheet ); // The list of screens, shared by sheet paths screensList.BuildClientSheetPathList(); // build the shared by sheet paths, by screen // Search for new sheet paths, not existing in aInitialSheetPathList // and existing in sheetpathList SCH_SHEET_LIST sheetpathList( g_RootSheet ); for( SCH_SHEET_PATH& sheetpath: sheetpathList ) { bool path_exists = false; for( const SCH_SHEET_PATH& existing_sheetpath: aInitialSheetPathList ) { if( existing_sheetpath.Path() == sheetpath.Path() ) { path_exists = true; break; } } if( !path_exists ) { // A new sheet path is found: clear the annotation corresponding to this new path: SCH_SCREEN* curr_screen = sheetpath.LastScreen(); // Clear annotation and create the AR for this path, if not exists, // when the screen is shared by sheet paths. // Otherwise ClearAnnotation do nothing, because the F1 field is used as // reference default value and takes the latest displayed value curr_screen->EnsureAlternateReferencesExist(); curr_screen->ClearAnnotation( &sheetpath ); } } } int SCH_SCREENS::ReplaceDuplicateTimeStamps() { EDA_ITEMS items; int count = 0; auto timestamp_cmp = []( const EDA_ITEM* a, const EDA_ITEM* b ) -> bool { return a->m_Uuid < b->m_Uuid; }; std::set unique_stamps( timestamp_cmp ); for( SCH_SCREEN* screen : m_screens ) screen->GetHierarchicalItems( items ); if( items.size() < 2 ) return 0; for( EDA_ITEM* item : items ) { if( !unique_stamps.insert( item ).second ) { // Reset to fully random UUID. This may lose reference, but better to be // deterministic about it rather than to have duplicate UUIDs with random // side-effects. const_cast( item->m_Uuid ) = KIID(); count++; } } return count; } void SCH_SCREENS::DeleteMarker( SCH_MARKER* aMarker ) { for( SCH_SCREEN* screen = GetFirst(); screen; screen = GetNext() ) { for( SCH_ITEM* item : screen->Items().OfType( SCH_MARKER_T ) ) { if( item == aMarker ) { screen->DeleteItem( item ); return; } } } } void SCH_SCREENS::DeleteMarkers( enum MARKER_BASE::TYPEMARKER aMarkerType, int aErrorCode ) { for( SCH_SCREEN* screen = GetFirst(); screen; screen = GetNext() ) { std::vector markers; for( SCH_ITEM* item : screen->Items().OfType( SCH_MARKER_T ) ) { SCH_MARKER* marker = static_cast( item ); RC_ITEM* rcItem = marker->GetRCItem(); if( marker->GetMarkerType() == aMarkerType && ( aErrorCode == ERCE_UNSPECIFIED || rcItem->GetErrorCode() == aErrorCode ) ) { markers.push_back( item ); } } for( SCH_ITEM* marker : markers ) screen->DeleteItem( marker ); } } void SCH_SCREENS::DeleteAllMarkers( enum MARKER_BASE::TYPEMARKER aMarkerType ) { DeleteMarkers( aMarkerType, ERCE_UNSPECIFIED ); } void SCH_SCREENS::UpdateSymbolLinks( bool aForce ) { for( SCH_SCREEN* screen = GetFirst(); screen; screen = GetNext() ) screen->UpdateSymbolLinks( aForce ); SCH_SHEET_LIST sheets( g_RootSheet ); // All of the library symbols have been replaced with copies so the connection graph // pointer are stale. if( g_ConnectionGraph ) g_ConnectionGraph->Recalculate( sheets, true ); } void SCH_SCREENS::TestDanglingEnds() { std::vector screens; for( SCH_SCREEN* screen = GetFirst(); screen; screen = GetNext() ) screens.push_back( screen ); size_t parallelThreadCount = std::min( std::thread::hardware_concurrency(), screens.size() ); std::atomic nextScreen( 0 ); std::vector> returns( parallelThreadCount ); auto update_lambda = [&screens, &nextScreen]() -> size_t { for( auto i = nextScreen++; i < screens.size(); i = nextScreen++ ) screens[i]->TestDanglingEnds(); return 1; }; if( parallelThreadCount == 1 ) update_lambda(); else { for( size_t ii = 0; ii < parallelThreadCount; ++ii ) returns[ii] = std::async( std::launch::async, update_lambda ); // Finalize the threads for( size_t ii = 0; ii < parallelThreadCount; ++ii ) returns[ii].wait(); } } bool SCH_SCREENS::HasNoFullyDefinedLibIds() { SCH_SCREEN* screen; unsigned cnt = 0; for( screen = GetFirst(); screen; screen = GetNext() ) { for( auto item : screen->Items().OfType( SCH_COMPONENT_T ) ) { cnt++; auto symbol = static_cast( item ); if( !symbol->GetLibId().GetLibNickname().empty() ) return false; } } return cnt != 0; } size_t SCH_SCREENS::GetLibNicknames( wxArrayString& aLibNicknames ) { for( SCH_SCREEN* screen = GetFirst(); screen; screen = GetNext() ) { for( auto item : screen->Items().OfType( SCH_COMPONENT_T ) ) { auto symbol = static_cast( item ); auto& nickname = symbol->GetLibId().GetLibNickname(); if( !nickname.empty() && ( aLibNicknames.Index( nickname ) == wxNOT_FOUND ) ) aLibNicknames.Add( nickname ); } } return aLibNicknames.GetCount(); } int SCH_SCREENS::ChangeSymbolLibNickname( const wxString& aFrom, const wxString& aTo ) { SCH_SCREEN* screen; int cnt = 0; for( screen = GetFirst(); screen; screen = GetNext() ) { for( auto item : screen->Items().OfType( SCH_COMPONENT_T ) ) { auto symbol = static_cast( item ); if( symbol->GetLibId().GetLibNickname() != aFrom ) continue; LIB_ID id = symbol->GetLibId(); id.SetLibNickname( aTo ); symbol->SetLibId( id ); cnt++; } } return cnt; } bool SCH_SCREENS::HasSchematic( const wxString& aSchematicFileName ) { for( const SCH_SCREEN* screen = GetFirst(); screen; screen = GetNext() ) { if( screen->GetFileName() == aSchematicFileName ) return true; } return false; } bool SCH_SCREENS::CanCauseCaseSensitivityIssue( const wxString& aSchematicFileName ) const { wxString lhsLower; wxString rhsLower; wxFileName lhs; wxFileName rhs = aSchematicFileName; wxCHECK( rhs.IsAbsolute(), false ); for( const SCH_SCREEN* screen : m_screens ) { lhs = screen->GetFileName(); if( lhs.GetPath() != rhs.GetPath() ) continue; lhsLower = lhs.GetFullName().Lower(); rhsLower = rhs.GetFullName().Lower(); if( lhsLower == rhsLower && lhs.GetFullName() != rhs.GetFullName() ) return true; } return false; } void SCH_SCREENS::BuildClientSheetPathList() { SCH_SHEET_LIST sheetList( g_RootSheet ); for( SCH_SCREEN* curr_screen = GetFirst(); curr_screen; curr_screen = GetNext() ) curr_screen->GetClientSheetPaths().Clear(); for( SCH_SHEET_PATH& sheetpath: sheetList ) { SCH_SCREEN* used_screen = sheetpath.LastScreen(); // SEarch for the used_screen in list and add this unique sheet path: for( SCH_SCREEN* curr_screen = GetFirst(); curr_screen; curr_screen = GetNext() ) { if( used_screen == curr_screen ) { curr_screen->GetClientSheetPaths().Add( sheetpath.PathAsString() ); break; } } } }