/* * This program source code file is part of KiCad, a free EDA CAD application. * * Copyright (C) 2018 CERN * Copyright (C) 2021-2022 KiCad Developers, see AUTHORS.txt for contributors. * * @author Jon Evans * * 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, see . */ #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 // for realtime connectivity switch in release builds /* * Flag to enable connectivity profiling * @ingroup trace_env_vars */ static const wxChar DanglingProfileMask[] = wxT( "CONN_PROFILE" ); /* * Flag to enable connectivity tracing * @ingroup trace_env_vars */ static const wxChar ConnTrace[] = wxT( "CONN" ); void CONNECTION_SUBGRAPH::RemoveItem( SCH_ITEM* aItem ) { m_items.erase( aItem ); m_drivers.erase( aItem ); if( aItem == m_driver ) { m_driver = nullptr; m_driver_connection = nullptr; } if( aItem->Type() == SCH_SHEET_PIN_T ) m_hier_pins.erase( static_cast( aItem ) ); if( aItem->Type() == SCH_HIER_LABEL_T ) m_hier_ports.erase( static_cast( aItem ) ); } bool CONNECTION_SUBGRAPH::ResolveDrivers( bool aCheckMultipleDrivers ) { auto candidate_cmp = [&]( SCH_ITEM* a, SCH_ITEM* b ) -> bool { // meet irreflexive requirements of std::sort if( a == b ) return false; SCH_CONNECTION* ac = a->Connection( &m_sheet ); SCH_CONNECTION* bc = b->Connection( &m_sheet ); // Ensure we don't pick the subset over the superset if( ac->IsBus() && bc->IsBus() ) return bc->IsSubsetOf( ac ); // Ensure we don't pick a hidden power pin on a regular symbol over // one on a power symbol if( a->Type() == SCH_PIN_T && b->Type() == SCH_PIN_T ) { SCH_PIN* pa = static_cast( a ); SCH_PIN* pb = static_cast( b ); bool aPower = pa->GetLibPin()->GetParent()->IsPower(); bool bPower = pb->GetLibPin()->GetParent()->IsPower(); if( aPower && !bPower ) return true; else if( bPower && !aPower ) return false; } const wxString& a_name = GetNameForDriver( a ); const wxString& b_name = GetNameForDriver( b ); bool a_lowQualityName = a_name.Contains( "-Pad" ); bool b_lowQualityName = b_name.Contains( "-Pad" ); if( a_lowQualityName && !b_lowQualityName ) return false; else if( b_lowQualityName && !a_lowQualityName ) return true; else return a_name < b_name; }; auto strong_cmp = [this]( SCH_ITEM* a, SCH_ITEM* b ) -> bool { const wxString& a_name = GetNameForDriver( a ); const wxString& b_name = GetNameForDriver( b ); return a_name < b_name; }; PRIORITY highest_priority = PRIORITY::INVALID; std::set candidates( candidate_cmp ); std::set strong_drivers( strong_cmp ); m_driver = nullptr; // Hierarchical labels are lower priority than local labels here, // because on the first pass we want local labels to drive subgraphs // so that we can identify same-sheet neighbors and link them together. // Hierarchical labels will end up overriding the final net name if // a higher-level sheet has a different name during the hierarchical // pass. for( SCH_ITEM* item : m_drivers ) { PRIORITY item_priority = GetDriverPriority( item ); if( item_priority == PRIORITY::PIN && !static_cast( item )->GetParentSymbol()->IsInNetlist() ) continue; if( item_priority >= PRIORITY::HIER_LABEL ) strong_drivers.insert( item ); if( item_priority > highest_priority ) { candidates.clear(); candidates.insert( item ); highest_priority = item_priority; } else if( !candidates.empty() && ( item_priority == highest_priority ) ) { candidates.insert( item ); } } if( highest_priority >= PRIORITY::HIER_LABEL ) m_strong_driver = true; // Power pins are 5, global labels are 6 m_local_driver = ( highest_priority < PRIORITY::POWER_PIN ); if( !candidates.empty() ) { if( candidates.size() > 1 ) { if( highest_priority == PRIORITY::SHEET_PIN ) { // We have multiple options, and they are all hierarchical // sheet pins. Let's prefer outputs over inputs. for( SCH_ITEM* c : candidates ) { SCH_SHEET_PIN* p = static_cast( c ); if( p->GetShape() == LABEL_FLAG_SHAPE::L_OUTPUT ) { m_driver = c; break; } } } } if( !m_driver ) m_driver = *candidates.begin(); } if( strong_drivers.size() > 1 ) m_multiple_drivers = true; // Drop weak drivers if( m_strong_driver ) { m_drivers.clear(); m_drivers.insert( strong_drivers.begin(), strong_drivers.end() ); } // Cache driver connection if( m_driver ) { m_driver_connection = m_driver->Connection( &m_sheet ); m_driver_connection->ConfigureFromLabel( GetNameForDriver( m_driver ) ); m_driver_connection->SetDriver( m_driver ); m_driver_connection->ClearDirty(); } else if( !m_is_bus_member ) { m_driver_connection = nullptr; } return ( m_driver != nullptr ); } void CONNECTION_SUBGRAPH::getAllConnectedItems( std::set>& aItems, std::set& aSubgraphs ) { CONNECTION_SUBGRAPH* sg = this; while( sg->m_absorbed_by ) { wxASSERT( sg->m_graph == sg->m_absorbed_by->m_graph ); sg = sg->m_absorbed_by; } // If we are unable to insert the subgraph into the set, then we have already // visited it and don't need to add it again. if( aSubgraphs.insert( sg ).second == false ) return; aSubgraphs.insert( sg->m_absorbed_subgraphs.begin(), sg->m_absorbed_subgraphs.end() ); for( SCH_ITEM* item : sg->m_items ) aItems.emplace( m_sheet, item ); for( CONNECTION_SUBGRAPH* child_sg : sg->m_hier_children ) child_sg->getAllConnectedItems( aItems, aSubgraphs ); } wxString CONNECTION_SUBGRAPH::GetNetName() const { if( !m_driver || m_dirty ) return ""; if( !m_driver->Connection( &m_sheet ) ) { #ifdef CONNECTIVITY_DEBUG wxASSERT_MSG( false, wxS( "Tried to get the net name of an item with no connection" ) ); #endif return ""; } return m_driver->Connection( &m_sheet )->Name(); } std::vector CONNECTION_SUBGRAPH::GetAllBusLabels() const { std::vector labels; for( SCH_ITEM* item : m_drivers ) { switch( item->Type() ) { case SCH_LABEL_T: case SCH_GLOBAL_LABEL_T: { CONNECTION_TYPE type = item->Connection( &m_sheet )->Type(); // Only consider bus vectors if( type == CONNECTION_TYPE::BUS || type == CONNECTION_TYPE::BUS_GROUP ) labels.push_back( item ); break; } default: break; } } return labels; } std::vector CONNECTION_SUBGRAPH::GetVectorBusLabels() const { std::vector labels; for( SCH_ITEM* item : m_drivers ) { switch( item->Type() ) { case SCH_LABEL_T: case SCH_GLOBAL_LABEL_T: { SCH_CONNECTION* label_conn = item->Connection( &m_sheet ); // Only consider bus vectors if( label_conn->Type() == CONNECTION_TYPE::BUS ) labels.push_back( item ); break; } default: break; } } return labels; } wxString CONNECTION_SUBGRAPH::driverName( SCH_ITEM* aItem ) const { switch( aItem->Type() ) { case SCH_PIN_T: { bool forceNoConnect = m_no_connect != nullptr; SCH_PIN* pin = static_cast( aItem ); return pin->GetDefaultNetName( m_sheet, forceNoConnect ); } case SCH_LABEL_T: case SCH_GLOBAL_LABEL_T: case SCH_HIER_LABEL_T: return EscapeString( static_cast( aItem )->GetShownText( &m_sheet, false ), CTX_NETNAME ); case SCH_SHEET_PIN_T: // Sheet pins need to use their parent sheet as their starting sheet or they will // resolve variables on the current sheet first return EscapeString( static_cast( aItem )->GetShownText( nullptr, false ), CTX_NETNAME ); default: wxFAIL_MSG( wxS( "Unhandled item type in GetNameForDriver" ) ); break; } return wxEmptyString; } const wxString& CONNECTION_SUBGRAPH::GetNameForDriver( SCH_ITEM* aItem ) const { auto it = m_driver_name_cache.find( aItem ); if( it != m_driver_name_cache.end() ) return it->second; return m_driver_name_cache.emplace( aItem, driverName( aItem ) ).first->second; } const wxString CONNECTION_SUBGRAPH::GetNetclassForDriver( SCH_ITEM* aItem ) const { wxString netclass; aItem->RunOnChildren( [&]( SCH_ITEM* aChild ) { if( aChild->Type() == SCH_FIELD_T ) { SCH_FIELD* field = static_cast( aChild ); if( field->GetCanonicalName() == wxT( "Netclass" ) ) { netclass = field->GetText(); return false; } } return true; } ); return netclass; } void CONNECTION_SUBGRAPH::Absorb( CONNECTION_SUBGRAPH* aOther ) { wxASSERT( m_sheet == aOther->m_sheet ); for( SCH_ITEM* item : aOther->m_items ) { item->Connection( &m_sheet )->SetSubgraphCode( m_code ); AddItem( item ); } m_absorbed_subgraphs.insert( aOther ); m_absorbed_subgraphs.insert( aOther->m_absorbed_subgraphs.begin(), aOther->m_absorbed_subgraphs.end() ); m_bus_neighbors.insert( aOther->m_bus_neighbors.begin(), aOther->m_bus_neighbors.end() ); m_bus_parents.insert( aOther->m_bus_parents.begin(), aOther->m_bus_parents.end() ); m_multiple_drivers |= aOther->m_multiple_drivers; std::function set_absorbed_by = [ & ]( CONNECTION_SUBGRAPH *child ) { child->m_absorbed_by = this; for( CONNECTION_SUBGRAPH* subchild : child->m_absorbed_subgraphs ) set_absorbed_by( subchild ); }; aOther->m_absorbed = true; aOther->m_dirty = false; aOther->m_driver = nullptr; aOther->m_driver_connection = nullptr; set_absorbed_by( aOther ); } void CONNECTION_SUBGRAPH::AddItem( SCH_ITEM* aItem ) { m_items.insert( aItem ); if( aItem->Connection( &m_sheet )->IsDriver() ) m_drivers.insert( aItem ); if( aItem->Type() == SCH_SHEET_PIN_T ) m_hier_pins.insert( static_cast( aItem ) ); else if( aItem->Type() == SCH_HIER_LABEL_T ) m_hier_ports.insert( static_cast( aItem ) ); } void CONNECTION_SUBGRAPH::UpdateItemConnections() { if( !m_driver_connection ) return; for( SCH_ITEM* item : m_items ) { SCH_CONNECTION* item_conn = item->GetOrInitConnection( m_sheet, m_graph ); if( !item_conn ) continue; if( ( m_driver_connection->IsBus() && item_conn->IsNet() ) || ( m_driver_connection->IsNet() && item_conn->IsBus() ) ) { continue; } if( item != m_driver ) { item_conn->Clone( *m_driver_connection ); item_conn->ClearDirty(); } } } CONNECTION_SUBGRAPH::PRIORITY CONNECTION_SUBGRAPH::GetDriverPriority( SCH_ITEM* aDriver ) { if( !aDriver ) return PRIORITY::NONE; switch( aDriver->Type() ) { case SCH_SHEET_PIN_T: return PRIORITY::SHEET_PIN; case SCH_HIER_LABEL_T: return PRIORITY::HIER_LABEL; case SCH_LABEL_T: return PRIORITY::LOCAL_LABEL; case SCH_GLOBAL_LABEL_T: return PRIORITY::GLOBAL; case SCH_PIN_T: { SCH_PIN* sch_pin = static_cast( aDriver ); SCH_SYMBOL* sym = sch_pin->GetParentSymbol(); if( sch_pin->IsPowerConnection() ) return PRIORITY::POWER_PIN; else if( !sym || !sym->GetIncludeOnBoard() || sym->GetLibSymbolRef()->GetReferenceField().GetText().StartsWith( '#' ) ) return PRIORITY::NONE; else return PRIORITY::PIN; } default: return PRIORITY::NONE; } } void CONNECTION_GRAPH::Merge( CONNECTION_GRAPH& aGraph ) { std::copy( aGraph.m_items.begin(), aGraph.m_items.end(), std::back_inserter( m_items ) ); for( SCH_ITEM* item : aGraph.m_items ) item->SetConnectionGraph( this ); std::copy( aGraph.m_subgraphs.begin(), aGraph.m_subgraphs.end(), std::back_inserter( m_subgraphs ) ); for( CONNECTION_SUBGRAPH* sg : aGraph.m_subgraphs ) { if( sg->m_driver_connection ) sg->m_driver_connection->SetGraph( this ); sg->m_graph = this; } std::copy( aGraph.m_driver_subgraphs.begin(), aGraph.m_driver_subgraphs.end(), std::back_inserter( m_driver_subgraphs ) ); std::copy( aGraph.m_invisible_power_pins.begin(), aGraph.m_invisible_power_pins.end(), std::back_inserter( m_invisible_power_pins ) ); for( auto& [key, value] : aGraph.m_net_name_to_subgraphs_map ) m_net_name_to_subgraphs_map.insert_or_assign( key, value ); for( auto& [key, value] : aGraph.m_sheet_to_subgraphs_map ) m_sheet_to_subgraphs_map.insert_or_assign( key, value ); for( auto& [key, value] : aGraph.m_net_name_to_code_map ) m_net_name_to_code_map.insert_or_assign( key, value ); for( auto& [key, value] : aGraph.m_bus_name_to_code_map ) m_bus_name_to_code_map.insert_or_assign( key, value ); for( auto& [key, value] : aGraph.m_net_code_to_subgraphs_map ) m_net_code_to_subgraphs_map.insert_or_assign( key, value ); for( auto& [key, value] : aGraph.m_item_to_subgraph_map ) m_item_to_subgraph_map.insert_or_assign( key, value ); for( auto& [key, value] : aGraph.m_local_label_cache ) m_local_label_cache.insert_or_assign( key, value ); for( auto& [key, value] : aGraph.m_global_label_cache ) m_global_label_cache.insert_or_assign( key, value ); m_last_bus_code = std::max( m_last_bus_code, aGraph.m_last_bus_code ); m_last_net_code = std::max( m_last_net_code, aGraph.m_last_net_code ); m_last_subgraph_code = std::max( m_last_subgraph_code, aGraph.m_last_subgraph_code ); } void CONNECTION_GRAPH::Reset() { for( auto& subgraph : m_subgraphs ) { /// Only delete subgraphs of which we are the owner if( subgraph->m_graph == this ) delete subgraph; } m_items.clear(); m_subgraphs.clear(); m_driver_subgraphs.clear(); m_sheet_to_subgraphs_map.clear(); m_invisible_power_pins.clear(); m_bus_alias_cache.clear(); m_net_name_to_code_map.clear(); m_bus_name_to_code_map.clear(); m_net_code_to_subgraphs_map.clear(); m_net_name_to_subgraphs_map.clear(); m_item_to_subgraph_map.clear(); m_local_label_cache.clear(); m_global_label_cache.clear(); m_last_net_code = 1; m_last_bus_code = 1; m_last_subgraph_code = 1; } void CONNECTION_GRAPH::Recalculate( const SCH_SHEET_LIST& aSheetList, bool aUnconditional, std::function* aChangedItemHandler ) { PROF_TIMER recalc_time( "CONNECTION_GRAPH::Recalculate" ); if( aUnconditional ) Reset(); PROF_TIMER update_items( "updateItemConnectivity" ); m_sheetList = aSheetList; std::set dirty_items; for( const SCH_SHEET_PATH& sheet : aSheetList ) { std::vector items; // Store current unit value, to regenerate it after calculations // (useful in complex hierarchies) std::vector> symbolsChanged; for( SCH_ITEM* item : sheet.LastScreen()->Items() ) { if( item->IsConnectable() && ( aUnconditional || item->IsConnectivityDirty() ) ) { wxLogTrace( ConnTrace, wxT( "Adding item %s to connectivity graph update" ), item->GetTypeDesc() ); items.push_back( item ); dirty_items.insert( item ); } // Ensure the hierarchy info stored in SCREENS is built and up to date // (multi-unit symbols) if( item->Type() == SCH_SYMBOL_T ) { SCH_SYMBOL* symbol = static_cast( item ); int new_unit = symbol->GetUnitSelection( &sheet ); // Store the initial unit value, to regenerate it after calculations, // if modified if( symbol->GetUnit() != new_unit ) symbolsChanged.push_back( { symbol, symbol->GetUnit() } ); symbol->UpdateUnit( new_unit ); } } m_items.reserve( m_items.size() + items.size() ); updateItemConnectivity( sheet, items ); // UpdateDanglingState() also adds connected items for SCH_TEXT sheet.LastScreen()->TestDanglingEnds( &sheet, aChangedItemHandler ); // Restore the m_unit member, to avoid changes in current active sheet path // after calculations for( auto& item : symbolsChanged ) { item.first->UpdateUnit( item.second ); } } for( SCH_ITEM* item : dirty_items ) item->SetConnectivityDirty( false ); if( wxLog::IsAllowedTraceMask( DanglingProfileMask ) ) update_items.Show(); PROF_TIMER build_graph( "buildConnectionGraph" ); buildConnectionGraph( aChangedItemHandler ); if( wxLog::IsAllowedTraceMask( DanglingProfileMask ) ) build_graph.Show(); recalc_time.Stop(); if( wxLog::IsAllowedTraceMask( DanglingProfileMask ) ) recalc_time.Show(); } std::set> CONNECTION_GRAPH::ExtractAffectedItems( const std::set &aItems ) { std::set> retvals; std::set subgraphs; auto traverse_subgraph = [&retvals, &subgraphs]( CONNECTION_SUBGRAPH* aSubgraph ) { // Find the primary subgraph on this sheet while( aSubgraph->m_absorbed_by ) { wxASSERT( aSubgraph->m_graph == aSubgraph->m_absorbed_by->m_graph ); aSubgraph = aSubgraph->m_absorbed_by; } // Find the top most connected subgraph on all sheets while( aSubgraph->m_hier_parent ) { wxASSERT( aSubgraph->m_graph == aSubgraph->m_hier_parent->m_graph ); aSubgraph = aSubgraph->m_hier_parent; } // Recurse through all subsheets to collect connected items aSubgraph->getAllConnectedItems( retvals, subgraphs ); }; for( SCH_ITEM* item : aItems ) { auto it = m_item_to_subgraph_map.find( item ); if( it == m_item_to_subgraph_map.end() ) continue; CONNECTION_SUBGRAPH* sg = it->second; traverse_subgraph( sg ); for( auto& bus_it : sg->m_bus_neighbors ) { for( CONNECTION_SUBGRAPH* bus_sg : bus_it.second ) traverse_subgraph( bus_sg ); } for( auto& bus_it : sg->m_bus_parents ) { for( CONNECTION_SUBGRAPH* bus_sg : bus_it.second ) traverse_subgraph( bus_sg ); } alg::delete_matching( m_items, item ); } removeSubgraphs( subgraphs ); return retvals; } void CONNECTION_GRAPH::removeSubgraphs( std::set& aSubgraphs ) { std::sort( m_driver_subgraphs.begin(), m_driver_subgraphs.end() ); std::sort( m_subgraphs.begin(), m_subgraphs.end() ); std::set codes_to_remove; for( auto el : m_sheet_to_subgraphs_map ) { std::sort( el.second.begin(), el.second.end() ); } for( CONNECTION_SUBGRAPH* sg : aSubgraphs ) { for( auto it : sg->m_bus_neighbors ) { for( CONNECTION_SUBGRAPH* neighbor : it.second ) { auto& parents = neighbor->m_bus_parents[it.first]; for( auto test = parents.begin(); test != parents.end(); ) { if( *test == sg ) test = parents.erase( test ); else ++test; } if( parents.empty() ) neighbor->m_bus_parents.erase( it.first ); } } for( auto it : sg->m_bus_parents ) { for( CONNECTION_SUBGRAPH* parent : it.second ) { auto& neighbors = parent->m_bus_neighbors[it.first]; for( auto test = neighbors.begin(); test != neighbors.end(); ) { if( *test == sg ) test = neighbors.erase( test ); else ++test; } if( neighbors.empty() ) parent->m_bus_neighbors.erase( it.first ); } } { auto it = std::lower_bound( m_driver_subgraphs.begin(), m_driver_subgraphs.end(), sg ); while( it != m_driver_subgraphs.end() && *it == sg ) it = m_driver_subgraphs.erase( it ); } { auto it = std::lower_bound( m_subgraphs.begin(), m_subgraphs.end(), sg ); while( it != m_subgraphs.end() && *it == sg ) it = m_subgraphs.erase( it ); } for( auto el : m_sheet_to_subgraphs_map ) { auto it = std::lower_bound( el.second.begin(), el.second.end(), sg ); while( it != el.second.end() && *it == sg ) it = el.second.erase( it ); } auto remove_sg = [sg]( auto it ) -> bool { for( const CONNECTION_SUBGRAPH* test_sg : it->second ) { if( sg == test_sg ) return true; } return false; }; for( auto it = m_global_label_cache.begin(); it != m_global_label_cache.end(); ) { if( remove_sg( it ) ) it = m_global_label_cache.erase( it ); else ++it; } for( auto it = m_local_label_cache.begin(); it != m_local_label_cache.end(); ) { if( remove_sg( it ) ) it = m_local_label_cache.erase( it ); else ++it; } for( auto it = m_net_code_to_subgraphs_map.begin(); it != m_net_code_to_subgraphs_map.end(); ) { if( remove_sg( it ) ) { codes_to_remove.insert( it->first.Netcode ); it = m_net_code_to_subgraphs_map.erase( it ); } else ++it; } for( auto it = m_net_name_to_subgraphs_map.begin(); it != m_net_name_to_subgraphs_map.end(); ) { if( remove_sg( it ) ) it = m_net_name_to_subgraphs_map.erase( it ); else ++it; } for( auto it = m_item_to_subgraph_map.begin(); it != m_item_to_subgraph_map.end(); ) { if( it->second == sg ) it = m_item_to_subgraph_map.erase( it ); else ++it; } } for( auto it = m_net_name_to_code_map.begin(); it != m_net_name_to_code_map.end(); ) { if( codes_to_remove.find( it->second ) != codes_to_remove.end() ) it = m_net_name_to_code_map.erase( it ); else ++it; } for( auto it = m_bus_name_to_code_map.begin(); it != m_bus_name_to_code_map.end(); ) { if( codes_to_remove.find( it->second ) != codes_to_remove.end() ) it = m_bus_name_to_code_map.erase( it ); else ++it; } for( CONNECTION_SUBGRAPH* sg : aSubgraphs ) { sg->m_code = -1; sg->m_graph = nullptr; delete sg; } } void CONNECTION_GRAPH::updateItemConnectivity( const SCH_SHEET_PATH& aSheet, const std::vector& aItemList ) { std::map> connection_map; for( SCH_ITEM* item : aItemList ) { std::vector points = item->GetConnectionPoints(); item->ConnectedItems( aSheet ).clear(); if( item->Type() == SCH_SHEET_T ) { for( SCH_SHEET_PIN* pin : static_cast( item )->GetPins() ) { pin->InitializeConnection( aSheet, this ); pin->ConnectedItems( aSheet ).clear(); connection_map[ pin->GetTextPos() ].push_back( pin ); m_items.emplace_back( pin ); } } else if( item->Type() == SCH_SYMBOL_T ) { SCH_SYMBOL* symbol = static_cast( item ); for( SCH_PIN* pin : symbol->GetPins( &aSheet ) ) { pin->InitializeConnection( aSheet, this ); VECTOR2I pos = pin->GetPosition(); // because calling the first time is not thread-safe pin->GetDefaultNetName( aSheet ); pin->ConnectedItems( aSheet ).clear(); // Invisible power pins need to be post-processed later if( pin->IsPowerConnection() && !pin->IsVisible() ) m_invisible_power_pins.emplace_back( std::make_pair( aSheet, pin ) ); connection_map[ pos ].push_back( pin ); m_items.emplace_back( pin ); } } else { m_items.emplace_back( item ); SCH_CONNECTION* conn = item->InitializeConnection( aSheet, this ); // Set bus/net property here so that the propagation code uses it switch( item->Type() ) { case SCH_LINE_T: conn->SetType( item->GetLayer() == LAYER_BUS ? CONNECTION_TYPE::BUS : CONNECTION_TYPE::NET ); break; case SCH_BUS_BUS_ENTRY_T: conn->SetType( CONNECTION_TYPE::BUS ); // clean previous (old) links: static_cast( item )->m_connected_bus_items[0] = nullptr; static_cast( item )->m_connected_bus_items[1] = nullptr; break; case SCH_PIN_T: conn->SetType( CONNECTION_TYPE::NET ); break; case SCH_BUS_WIRE_ENTRY_T: conn->SetType( CONNECTION_TYPE::NET ); // clean previous (old) link: static_cast( item )->m_connected_bus_item = nullptr; break; default: break; } for( const VECTOR2I& point : points ) connection_map[ point ].push_back( item ); } } for( const auto& it : connection_map ) { std::vector connection_vec = it.second; std::sort( connection_vec.begin(), connection_vec.end() ); connection_vec.erase( std::unique( connection_vec.begin(), connection_vec.end() ), connection_vec.end() ); // Pre-scan to see if we have a bus at this location SCH_LINE* busLine = aSheet.LastScreen()->GetBus( it.first ); std::mutex update_mutex; auto update_lambda = [&]( SCH_ITEM* connected_item ) -> size_t { // Bus entries are special: they can have connection points in the // middle of a wire segment, because the junction algo doesn't split // the segment in two where you place a bus entry. This means that // bus entries that don't land on the end of a line segment need to // have "virtual" connection points to the segments they graphically // touch. if( connected_item->Type() == SCH_BUS_WIRE_ENTRY_T ) { // If this location only has the connection point of the bus // entry itself, this means that either the bus entry is not // connected to anything graphically, or that it is connected to // a segment at some point other than at one of the endpoints. if( connection_vec.size() == 1 ) { if( busLine ) { auto bus_entry = static_cast( connected_item ); bus_entry->m_connected_bus_item = busLine; } } } // Bus-to-bus entries are treated just like bus wires else if( connected_item->Type() == SCH_BUS_BUS_ENTRY_T ) { if( connection_vec.size() < 2 ) { if( busLine ) { auto bus_entry = static_cast( connected_item ); if( it.first == bus_entry->GetPosition() ) bus_entry->m_connected_bus_items[0] = busLine; else bus_entry->m_connected_bus_items[1] = busLine; std::lock_guard lock( update_mutex ); bus_entry->AddConnectionTo( aSheet, busLine ); busLine->AddConnectionTo( aSheet, bus_entry ); } } } // Change junctions to be on bus junction layer if they are touching a bus else if( connected_item->Type() == SCH_JUNCTION_T ) { connected_item->SetLayer( busLine ? LAYER_BUS_JUNCTION : LAYER_JUNCTION ); } SCH_ITEM_SET& connected_set = connected_item->ConnectedItems( aSheet ); connected_set.reserve( connection_vec.size() ); for( SCH_ITEM* test_item : connection_vec ) { bool bus_connection_ok = true; if( test_item == connected_item ) continue; // Set up the link between the bus entry net and the bus if( connected_item->Type() == SCH_BUS_WIRE_ENTRY_T ) { if( test_item->GetLayer() == LAYER_BUS ) { auto bus_entry = static_cast( connected_item ); bus_entry->m_connected_bus_item = test_item; } } // Bus entries only connect to bus lines on the end that is touching a bus line. // If the user has overlapped another net line with the endpoint of the bus entry // where the entry connects to a bus, we don't want to short-circuit it. if( connected_item->Type() == SCH_BUS_WIRE_ENTRY_T ) { bus_connection_ok = !busLine || test_item->GetLayer() == LAYER_BUS; } else if( test_item->Type() == SCH_BUS_WIRE_ENTRY_T ) { bus_connection_ok = !busLine || connected_item->GetLayer() == LAYER_BUS; } if( connected_item->ConnectionPropagatesTo( test_item ) && test_item->ConnectionPropagatesTo( connected_item ) && bus_connection_ok ) { connected_set.push_back( test_item ); } } // If we got this far and did not find a connected bus item for a bus entry, // we should do a manual scan in case there is a bus item on this connection // point but we didn't pick it up earlier because there is *also* a net item here. if( connected_item->Type() == SCH_BUS_WIRE_ENTRY_T ) { auto bus_entry = static_cast( connected_item ); if( !bus_entry->m_connected_bus_item ) { SCH_SCREEN* screen = aSheet.LastScreen(); SCH_LINE* bus = screen->GetBus( it.first ); if( bus ) bus_entry->m_connected_bus_item = bus; } } return 1; }; thread_pool& tp = GetKiCadThreadPool(); tp.push_loop( connection_vec.size(), [&]( const int a, const int b) { for( int ii = a; ii < b; ++ii ) update_lambda( connection_vec[ii] ); }); tp.wait_for_tasks(); } } void CONNECTION_GRAPH::buildItemSubGraphs() { // Recache all bus aliases for later use wxCHECK_RET( m_schematic, wxS( "Connection graph cannot be built without schematic pointer" ) ); SCH_SHEET_LIST all_sheets = m_schematic->GetSheets(); for( unsigned i = 0; i < all_sheets.size(); i++ ) { for( const std::shared_ptr& alias : all_sheets[i].LastScreen()->GetBusAliases() ) m_bus_alias_cache[ alias->GetName() ] = alias; } // Build subgraphs from items (on a per-sheet basis) for( SCH_ITEM* item : m_items ) { for( const auto& it : item->m_connection_map ) { const SCH_SHEET_PATH& sheet = it.first; SCH_CONNECTION* connection = it.second; if( connection->SubgraphCode() == 0 ) { CONNECTION_SUBGRAPH* subgraph = new CONNECTION_SUBGRAPH( this ); subgraph->m_code = m_last_subgraph_code++; subgraph->m_sheet = sheet; subgraph->AddItem( item ); connection->SetSubgraphCode( subgraph->m_code ); m_item_to_subgraph_map[item] = subgraph; std::list memberlist; auto get_items = [&]( SCH_ITEM* aItem ) -> bool { SCH_CONNECTION* conn = aItem->GetOrInitConnection( sheet, this ); bool unique = !( aItem->GetFlags() & CANDIDATE ); if( conn && !conn->SubgraphCode() ) aItem->SetFlags( CANDIDATE ); return ( unique && conn && ( conn->SubgraphCode() == 0 ) ); }; std::copy_if( item->ConnectedItems( sheet ).begin(), item->ConnectedItems( sheet ).end(), std::back_inserter( memberlist ), get_items ); for( SCH_ITEM* connected_item : memberlist ) { if( connected_item->Type() == SCH_NO_CONNECT_T ) subgraph->m_no_connect = connected_item; SCH_CONNECTION* connected_conn = connected_item->Connection( &sheet ); wxASSERT( connected_conn ); if( connected_conn->SubgraphCode() == 0 ) { connected_conn->SetSubgraphCode( subgraph->m_code ); m_item_to_subgraph_map[connected_item] = subgraph; subgraph->AddItem( connected_item ); SCH_ITEM_SET& citemset = connected_item->ConnectedItems( sheet ); for( SCH_ITEM* citem : citemset ) { if( citem->HasFlag( CANDIDATE ) ) continue; if( get_items( citem ) ) memberlist.push_back( citem ); } } } for( SCH_ITEM* connected_item : memberlist ) connected_item->ClearFlags( CANDIDATE ); subgraph->m_dirty = true; m_subgraphs.push_back( subgraph ); } } } } void CONNECTION_GRAPH::resolveAllDrivers() { // Resolve drivers for subgraphs and propagate connectivity info std::vector dirty_graphs; std::copy_if( m_subgraphs.begin(), m_subgraphs.end(), std::back_inserter( dirty_graphs ), [&] ( const CONNECTION_SUBGRAPH* candidate ) { return candidate->m_dirty; } ); std::vector> returns( dirty_graphs.size() ); auto update_lambda = []( CONNECTION_SUBGRAPH* subgraph ) -> size_t { if( !subgraph->m_dirty ) return 0; // Special processing for some items for( SCH_ITEM* item : subgraph->m_items ) { switch( item->Type() ) { case SCH_NO_CONNECT_T: subgraph->m_no_connect = item; break; case SCH_BUS_WIRE_ENTRY_T: subgraph->m_bus_entry = item; break; case SCH_PIN_T: { auto pin = static_cast( item ); if( pin->GetType() == ELECTRICAL_PINTYPE::PT_NC ) subgraph->m_no_connect = item; break; } default: break; } } subgraph->ResolveDrivers( true ); subgraph->m_dirty = false; return 1; }; thread_pool& tp = GetKiCadThreadPool(); tp.push_loop( dirty_graphs.size(), [&]( const int a, const int b) { for( int ii = a; ii < b; ++ii ) update_lambda( dirty_graphs[ii] ); }); tp.wait_for_tasks(); // Now discard any non-driven subgraphs from further consideration std::copy_if( m_subgraphs.begin(), m_subgraphs.end(), std::back_inserter( m_driver_subgraphs ), [&] ( const CONNECTION_SUBGRAPH* candidate ) -> bool { return candidate->m_driver; } ); } void CONNECTION_GRAPH::collectAllDriverValues() { // Check for subgraphs with the same net name but only weak drivers. // For example, two wires that are both connected to hierarchical // sheet pins that happen to have the same name, but are not the same. for( auto&& subgraph : m_driver_subgraphs ) { wxString full_name = subgraph->m_driver_connection->Name(); wxString name = subgraph->m_driver_connection->Name( true ); m_net_name_to_subgraphs_map[full_name].emplace_back( subgraph ); // For vector buses, we need to cache the prefix also, as two different instances of the // weakly driven pin may have the same prefix but different vector start and end. We need // to treat those as needing renaming also, because otherwise if they end up on a sheet with // common usage, they will be incorrectly merged. if( subgraph->m_driver_connection->Type() == CONNECTION_TYPE::BUS ) { wxString prefixOnly = full_name.BeforeFirst( '[' ) + wxT( "[]" ); m_net_name_to_subgraphs_map[prefixOnly].emplace_back( subgraph ); } subgraph->m_dirty = true; if( subgraph->m_strong_driver ) { SCH_ITEM* driver = subgraph->m_driver; SCH_SHEET_PATH sheet = subgraph->m_sheet; switch( driver->Type() ) { case SCH_LABEL_T: case SCH_HIER_LABEL_T: { m_local_label_cache[std::make_pair( sheet, name )].push_back( subgraph ); break; } case SCH_GLOBAL_LABEL_T: { m_global_label_cache[name].push_back( subgraph ); break; } case SCH_PIN_T: { SCH_PIN* pin = static_cast( driver ); wxASSERT( pin->IsPowerConnection() ); m_global_label_cache[name].push_back( subgraph ); break; } default: { UNITS_PROVIDER unitsProvider( schIUScale, EDA_UNITS::MILLIMETRES ); wxLogTrace( ConnTrace, wxS( "Unexpected strong driver %s" ), driver->GetItemDescription( &unitsProvider ) ); break; } } } } } void CONNECTION_GRAPH::generateBusAliasMembers() { std::vector new_subgraphs; for( CONNECTION_SUBGRAPH* subgraph : m_driver_subgraphs ) { SCH_ITEM_SET vec = subgraph->GetAllBusLabels(); for( SCH_ITEM* item : vec ) { SCH_LABEL_BASE* label = static_cast( item ); SCH_CONNECTION dummy( item, subgraph->m_sheet ); dummy.SetGraph( this ); dummy.ConfigureFromLabel( label->GetText() ); wxLogTrace( ConnTrace, wxS( "new bus label (%s)" ), label->GetText() ); for( const auto& conn : dummy.Members() ) { wxString name = conn->FullLocalName(); CONNECTION_SUBGRAPH* new_sg = new CONNECTION_SUBGRAPH( this ); // This connection cannot form a part of the item because the item is not, itself // connected to this subgraph. It exists as part of a virtual item that may be connected // to other items but is not in the schematic. SCH_CONNECTION* new_conn = new SCH_CONNECTION( item, subgraph->m_sheet ); new_conn->SetGraph( this ); new_conn->SetName( name ); new_conn->SetType( CONNECTION_TYPE::NET ); subgraph->StoreImplicitConnection( new_conn ); int code = assignNewNetCode( *new_conn ); wxLogTrace( ConnTrace, wxS( "SG(%ld), Adding full local name (%s) with sg (%d) on subsheet %s" ), subgraph->m_code, name, code, subgraph->m_sheet.PathHumanReadable() ); new_sg->m_driver_connection = new_conn; new_sg->m_code = m_last_subgraph_code++; new_sg->m_sheet = subgraph->m_sheet; new_sg->m_is_bus_member = true; new_sg->m_strong_driver = true; /// Need to figure out why these sgs are not getting connected to their bus parents NET_NAME_CODE_CACHE_KEY key = { new_sg->GetNetName(), code }; m_net_code_to_subgraphs_map[ key ].push_back( new_sg ); m_net_name_to_subgraphs_map[ name ].push_back( new_sg ); m_subgraphs.push_back( new_sg ); new_subgraphs.push_back( new_sg ); } } } std::copy( new_subgraphs.begin(), new_subgraphs.end(), std::back_inserter( m_driver_subgraphs ) ); } void CONNECTION_GRAPH::generateInvisiblePinSubGraphs() { // Generate subgraphs for invisible power pins. These will be merged with other subgraphs // on the same sheet in the next loop. std::unordered_map invisible_pin_subgraphs; for( const auto& it : m_invisible_power_pins ) { SCH_SHEET_PATH sheet = it.first; SCH_PIN* pin = it.second; if( !pin->ConnectedItems( sheet ).empty() && !pin->GetLibPin()->GetParent()->IsPower() ) { // ERC will warn about this: user has wired up an invisible pin continue; } SCH_CONNECTION* connection = pin->GetOrInitConnection( sheet, this ); // If this pin already has a subgraph, don't need to process if( !connection || connection->SubgraphCode() > 0 ) continue; connection->SetName( pin->GetShownName() ); int code = assignNewNetCode( *connection ); connection->SetNetCode( code ); CONNECTION_SUBGRAPH* subgraph; auto jj = invisible_pin_subgraphs.find( code ); if( jj != invisible_pin_subgraphs.end() ) { subgraph = jj->second; subgraph->AddItem( pin ); } else { subgraph = new CONNECTION_SUBGRAPH( this ); subgraph->m_code = m_last_subgraph_code++; subgraph->m_sheet = sheet; subgraph->AddItem( pin ); subgraph->ResolveDrivers(); NET_NAME_CODE_CACHE_KEY key = { subgraph->GetNetName(), code }; m_net_code_to_subgraphs_map[ key ].push_back( subgraph ); m_subgraphs.push_back( subgraph ); m_driver_subgraphs.push_back( subgraph ); invisible_pin_subgraphs[code] = subgraph; } connection->SetSubgraphCode( subgraph->m_code ); } } void CONNECTION_GRAPH::processSubGraphs() { // Here we do all the local (sheet) processing of each subgraph, including assigning net // codes, merging subgraphs together that use label connections, etc. // Cache remaining valid subgraphs by sheet path for( CONNECTION_SUBGRAPH* subgraph : m_driver_subgraphs ) m_sheet_to_subgraphs_map[ subgraph->m_sheet ].emplace_back( subgraph ); std::unordered_set invalidated_subgraphs; for( CONNECTION_SUBGRAPH* subgraph : m_driver_subgraphs ) { if( subgraph->m_absorbed ) continue; SCH_CONNECTION* connection = subgraph->m_driver_connection; SCH_SHEET_PATH sheet = subgraph->m_sheet; wxString name = connection->Name(); // Test subgraphs with weak drivers for net name conflicts and fix them unsigned suffix = 1; auto create_new_name = [&suffix]( SCH_CONNECTION* aConn ) -> wxString { wxString newName; wxString suffixStr = std::to_wstring( suffix ); // For group buses with a prefix, we can add the suffix to the prefix. // If they don't have a prefix, we force the creation of a prefix so that // two buses don't get inadvertently shorted together. if( aConn->Type() == CONNECTION_TYPE::BUS_GROUP ) { wxString prefix = aConn->BusPrefix(); if( prefix.empty() ) prefix = wxT( "BUS" ); // So result will be "BUS_1{...}" wxString oldName = aConn->Name().AfterFirst( '{' ); newName << prefix << wxT( "_" ) << suffixStr << wxT( "{" ) << oldName; aConn->ConfigureFromLabel( newName ); } else { newName << aConn->Name() << wxT( "_" ) << suffixStr; aConn->SetSuffix( wxString( wxT( "_" ) ) << suffixStr ); } suffix++; return newName; }; if( !subgraph->m_strong_driver ) { std::vector* vec = &m_net_name_to_subgraphs_map.at( name ); // If we are a unique bus vector, check if we aren't actually unique because of another // subgraph with a similar bus vector if( vec->size() <= 1 && subgraph->m_driver_connection->Type() == CONNECTION_TYPE::BUS ) { wxString prefixOnly = name.BeforeFirst( '[' ) + wxT( "[]" ); vec = &m_net_name_to_subgraphs_map.at( prefixOnly ); } if( vec->size() > 1 ) { wxString new_name = create_new_name( connection ); while( m_net_name_to_subgraphs_map.count( new_name ) ) new_name = create_new_name( connection ); wxLogTrace( ConnTrace, wxS( "%ld (%s) is weakly driven and not unique. Changing to %s." ), subgraph->m_code, name, new_name ); alg::delete_matching( *vec, subgraph ); m_net_name_to_subgraphs_map[new_name].emplace_back( subgraph ); name = new_name; } else if( subgraph->m_driver ) { // If there is no conflict, promote sheet pins to be strong drivers so that they // will be considered below for propagation/merging. // It is possible for this to generate a conflict if the sheet pin has the same // name as a global label on the same sheet, because global merging will then treat // this subgraph as if it had a matching local label. So, for those cases, we // don't apply this promotion if( subgraph->m_driver->Type() == SCH_SHEET_PIN_T ) { bool conflict = false; wxString global_name = connection->Name( true ); auto kk = m_net_name_to_subgraphs_map.find( global_name ); if( kk != m_net_name_to_subgraphs_map.end() ) { // A global will conflict if it is on the same sheet as this subgraph, since // it would be connected by implicit local label linking std::vector& candidates = kk->second; for( const CONNECTION_SUBGRAPH* candidate : candidates ) { if( candidate->m_sheet == sheet ) conflict = true; } } if( conflict ) { wxLogTrace( ConnTrace, wxS( "%ld (%s) skipped for promotion due to potential conflict" ), subgraph->m_code, name ); } else { UNITS_PROVIDER unitsProvider( schIUScale, EDA_UNITS::MILLIMETRES ); wxLogTrace( ConnTrace, wxS( "%ld (%s) weakly driven by unique sheet pin %s, promoting" ), subgraph->m_code, name, subgraph->m_driver->GetItemDescription( &unitsProvider ) ); subgraph->m_strong_driver = true; } } } } // Assign net codes if( connection->IsBus() ) { int code = -1; auto it = m_bus_name_to_code_map.find( name ); if( it != m_bus_name_to_code_map.end() ) { code = it->second; } else { code = m_last_bus_code++; m_bus_name_to_code_map[ name ] = code; } connection->SetBusCode( code ); assignNetCodesToBus( connection ); } else { assignNewNetCode( *connection ); } // Reset the flag for the next loop below subgraph->m_dirty = true; // Next, we merge together subgraphs that have label connections, and create // neighbor links for subgraphs that are part of a bus on the same sheet. // For merging, we consider each possible strong driver. // If this subgraph doesn't have a strong driver, let's skip it, since there is no // way it will be merged with anything. if( !subgraph->m_strong_driver ) continue; // candidate_subgraphs will contain each valid, non-bus subgraph on the same sheet // as the subgraph we are considering that has a strong driver. // Weakly driven subgraphs are not considered since they will never be absorbed or // form neighbor links. std::vector candidate_subgraphs; std::copy_if( m_sheet_to_subgraphs_map[ subgraph->m_sheet ].begin(), m_sheet_to_subgraphs_map[ subgraph->m_sheet ].end(), std::back_inserter( candidate_subgraphs ), [&] ( const CONNECTION_SUBGRAPH* candidate ) { return ( !candidate->m_absorbed && candidate->m_strong_driver && candidate != subgraph ); } ); // This is a list of connections on the current subgraph to compare to the // drivers of each candidate subgraph. If the current subgraph is a bus, // we should consider each bus member. std::vector< std::shared_ptr > connections_to_check; // Also check the main driving connection connections_to_check.push_back( std::make_shared( *connection ) ); auto add_connections_to_check = [&] ( CONNECTION_SUBGRAPH* aSubgraph ) { for( SCH_ITEM* possible_driver : aSubgraph->m_items ) { if( possible_driver == aSubgraph->m_driver ) continue; auto c = getDefaultConnection( possible_driver, aSubgraph ); if( c ) { if( c->Type() != aSubgraph->m_driver_connection->Type() ) continue; if( c->Name( true ) == aSubgraph->m_driver_connection->Name( true ) ) continue; connections_to_check.push_back( c ); wxLogTrace( ConnTrace, wxS( "%lu (%s): Adding secondary driver %s" ), aSubgraph->m_code, aSubgraph->m_driver_connection->Name( true ), c->Name( true ) ); } } }; // Now add other strong drivers // The actual connection attached to these items will have been overwritten // by the chosen driver of the subgraph, so we need to create a dummy connection add_connections_to_check( subgraph ); std::set checked_connections; for( unsigned i = 0; i < connections_to_check.size(); i++ ) { auto member = connections_to_check[i]; // Don't check the same connection twice if( !checked_connections.insert( member.get() ).second ) continue; if( member->IsBus() ) { connections_to_check.insert( connections_to_check.end(), member->Members().begin(), member->Members().end() ); } wxString test_name = member->Name( true ); for( CONNECTION_SUBGRAPH* candidate : candidate_subgraphs ) { if( candidate->m_absorbed || candidate == subgraph ) continue; bool match = false; if( candidate->m_driver_connection->Name( true ) == test_name ) { match = true; } else { if( !candidate->m_multiple_drivers ) continue; for( SCH_ITEM *driver : candidate->m_drivers ) { if( driver == candidate->m_driver ) continue; // Sheet pins are not candidates for merging if( driver->Type() == SCH_SHEET_PIN_T ) continue; if( driver->Type() == SCH_PIN_T ) { auto pin = static_cast( driver ); if( pin->IsPowerConnection() && pin->GetShownName() == test_name ) { match = true; break; } } else { wxASSERT( driver->Type() == SCH_LABEL_T || driver->Type() == SCH_GLOBAL_LABEL_T || driver->Type() == SCH_HIER_LABEL_T ); if( subgraph->GetNameForDriver( driver ) == test_name ) { match = true; break; } } } } if( match ) { if( connection->IsBus() && candidate->m_driver_connection->IsNet() ) { wxLogTrace( ConnTrace, wxS( "%lu (%s) has bus child %lu (%s)" ), subgraph->m_code, connection->Name(), candidate->m_code, member->Name() ); subgraph->m_bus_neighbors[member].insert( candidate ); candidate->m_bus_parents[member].insert( subgraph ); } else { wxLogTrace( ConnTrace, wxS( "%lu (%s) absorbs neighbor %lu (%s)" ), subgraph->m_code, connection->Name(), candidate->m_code, candidate->m_driver_connection->Name() ); // Candidate may have other non-chosen drivers we need to follow add_connections_to_check( candidate ); subgraph->Absorb( candidate ); invalidated_subgraphs.insert( subgraph ); } } } } } // Update any subgraph that was invalidated above for( CONNECTION_SUBGRAPH* subgraph : invalidated_subgraphs ) { if( subgraph->m_absorbed ) continue; if( !subgraph->ResolveDrivers() ) continue; if( subgraph->m_driver_connection->IsBus() ) assignNetCodesToBus( subgraph->m_driver_connection ); else assignNewNetCode( *subgraph->m_driver_connection ); wxLogTrace( ConnTrace, wxS( "Re-resolving drivers for %lu (%s)" ), subgraph->m_code, subgraph->m_driver_connection->Name() ); } } // TODO(JE) This won't give the same subgraph IDs (and eventually net/graph codes) // to the same subgraph necessarily if it runs over and over again on the same // sheet. We need: // // a) a cache of net/bus codes, like used before // b) to persist the CONNECTION_GRAPH globally so the cache is persistent, // c) some way of trying to avoid changing net names. so we should keep track // of the previous driver of a net, and if it comes down to choosing between // equally-prioritized drivers, choose the one that already exists as a driver // on some portion of the items. void CONNECTION_GRAPH::buildConnectionGraph( std::function* aChangedItemHandler ) { // Recache all bus aliases for later use wxCHECK_RET( m_schematic, wxT( "Connection graph cannot be built without schematic pointer" ) ); SCH_SHEET_LIST all_sheets = m_schematic->GetSheets(); for( unsigned i = 0; i < all_sheets.size(); i++ ) { for( const std::shared_ptr& alias : all_sheets[i].LastScreen()->GetBusAliases() ) m_bus_alias_cache[ alias->GetName() ] = alias; } PROF_TIMER sub_graph( "buildItemSubGraphs" ); buildItemSubGraphs(); if( wxLog::IsAllowedTraceMask( DanglingProfileMask ) ) sub_graph.Show(); /** * TODO(JE): Net codes are non-deterministic. Fortunately, they are also not really used for * anything. We should consider removing them entirely and just using net names everywhere. */ resolveAllDrivers(); collectAllDriverValues(); generateInvisiblePinSubGraphs(); generateBusAliasMembers(); PROF_TIMER proc_sub_graph( "ProcessSubGraphs" ); processSubGraphs(); if( wxLog::IsAllowedTraceMask( DanglingProfileMask ) ) proc_sub_graph.Show(); // Absorbed subgraphs should no longer be considered alg::delete_if( m_driver_subgraphs, [&]( const CONNECTION_SUBGRAPH* candidate ) -> bool { return candidate->m_absorbed; } ); // Store global subgraphs for later reference std::vector global_subgraphs; std::copy_if( m_driver_subgraphs.begin(), m_driver_subgraphs.end(), std::back_inserter( global_subgraphs ), [&] ( const CONNECTION_SUBGRAPH* candidate ) -> bool { return !candidate->m_local_driver; } ); // Recache remaining valid subgraphs by sheet path m_sheet_to_subgraphs_map.clear(); for( CONNECTION_SUBGRAPH* subgraph : m_driver_subgraphs ) m_sheet_to_subgraphs_map[ subgraph->m_sheet ].emplace_back( subgraph ); thread_pool& tp = GetKiCadThreadPool(); tp.push_loop( m_driver_subgraphs.size(), [&]( const int a, const int b) { for( int ii = a; ii < b; ++ii ) m_driver_subgraphs[ii]->UpdateItemConnections(); }); tp.wait_for_tasks(); // Next time through the subgraphs, we do some post-processing to handle things like // connecting bus members to their neighboring subgraphs, and then propagate connections // through the hierarchy for( CONNECTION_SUBGRAPH* subgraph : m_driver_subgraphs ) { if( !subgraph->m_dirty ) continue; wxLogTrace( ConnTrace, wxS( "Processing %lu (%s) for propagation" ), subgraph->m_code, subgraph->m_driver_connection->Name() ); // For subgraphs that are driven by a global (power port or label) and have more // than one global driver, we need to seek out other subgraphs driven by the // same name as the non-chosen driver and update them to match the chosen one. if( !subgraph->m_local_driver && subgraph->m_multiple_drivers ) { for( SCH_ITEM* driver : subgraph->m_drivers ) { if( driver == subgraph->m_driver ) continue; const wxString& secondary_name = subgraph->GetNameForDriver( driver ); if( secondary_name == subgraph->m_driver_connection->Name() ) continue; bool secondary_is_global = CONNECTION_SUBGRAPH::GetDriverPriority( driver ) >= CONNECTION_SUBGRAPH::PRIORITY::POWER_PIN; for( CONNECTION_SUBGRAPH* candidate : global_subgraphs ) { if( candidate == subgraph ) continue; if( !secondary_is_global && candidate->m_sheet != subgraph->m_sheet ) continue; SCH_CONNECTION* conn = candidate->m_driver_connection; if( conn->Name() == secondary_name ) { wxLogTrace( ConnTrace, wxS( "Global %lu (%s) promoted to %s" ), candidate->m_code, conn->Name(), subgraph->m_driver_connection->Name() ); conn->Clone( *subgraph->m_driver_connection ); candidate->m_dirty = false; propagateToNeighbors( candidate, false ); } } } } // This call will handle descending the hierarchy and updating child subgraphs propagateToNeighbors( subgraph, false ); } // After processing and allowing some to be skipped if they have hierarchical // pins connecting both up and down the hierarchy, we check to see if any of them // have not been processed. This would indicate that they do not have off-sheet connections // but we still need to handle the subgraph for( CONNECTION_SUBGRAPH* subgraph : m_driver_subgraphs ) { if( subgraph->m_dirty ) propagateToNeighbors( subgraph, true ); } // Handle buses that have been linked together somewhere by member (net) connections. // This feels a bit hacky, perhaps this algorithm should be revisited in the future. // For net subgraphs that have more than one bus parent, we need to ensure that those // buses are linked together in the final netlist. The final name of each bus might not // match the local name that was used to establish the parent-child relationship, because // the bus may have been renamed by a hierarchical connection. So, for each of these cases, // we need to identify the appropriate bus members to link together (and their final names), // and then update all instances of the old name in the hierarchy. for( CONNECTION_SUBGRAPH* subgraph : m_driver_subgraphs ) { // All SGs should have been processed by propagateToNeighbors above wxASSERT_MSG( !subgraph->m_dirty, wxS( "Subgraph not processed by propagateToNeighbors!" ) ); if( subgraph->m_bus_parents.size() < 2 ) continue; SCH_CONNECTION* conn = subgraph->m_driver_connection; wxLogTrace( ConnTrace, wxS( "%lu (%s) has multiple bus parents" ), subgraph->m_code, conn->Name() ); wxASSERT( conn->IsNet() ); for( const auto& ii : subgraph->m_bus_parents ) { SCH_CONNECTION* link_member = ii.first.get(); for( CONNECTION_SUBGRAPH* parent : ii.second ) { while( parent->m_absorbed ) parent = parent->m_absorbed_by; SCH_CONNECTION* match = matchBusMember( parent->m_driver_connection, link_member ); if( !match ) { wxLogTrace( ConnTrace, wxS( "Warning: could not match %s inside %lu (%s)" ), conn->Name(), parent->m_code, parent->m_driver_connection->Name() ); continue; } if( conn->Name() != match->Name() ) { wxString old_name = match->Name(); wxLogTrace( ConnTrace, wxS( "Updating %lu (%s) member %s to %s" ), parent->m_code, parent->m_driver_connection->Name(), old_name, conn->Name() ); match->Clone( *conn ); auto jj = m_net_name_to_subgraphs_map.find( old_name ); if( jj == m_net_name_to_subgraphs_map.end() ) continue; for( CONNECTION_SUBGRAPH* old_sg : jj->second ) { while( old_sg->m_absorbed ) old_sg = old_sg->m_absorbed_by; old_sg->m_driver_connection->Clone( *conn ); } } } } } auto updateItemConnectionsTask = [&]( CONNECTION_SUBGRAPH* subgraph ) -> size_t { // Make sure weakly-driven single-pin nets get the unconnected_ prefix if( !subgraph->m_strong_driver && subgraph->m_drivers.size() == 1 && subgraph->m_driver->Type() == SCH_PIN_T ) { SCH_PIN* pin = static_cast( subgraph->m_driver ); wxString name = pin->GetDefaultNetName( subgraph->m_sheet, true ); subgraph->m_driver_connection->ConfigureFromLabel( name ); } subgraph->m_dirty = false; subgraph->UpdateItemConnections(); // No other processing to do on buses if( subgraph->m_driver_connection->IsBus() ) return 0; // As a visual aid, we can check sheet pins that are driven by themselves to see // if they should be promoted to buses if( subgraph->m_driver && subgraph->m_driver->Type() == SCH_SHEET_PIN_T ) { SCH_SHEET_PIN* pin = static_cast( subgraph->m_driver ); if( SCH_SHEET* sheet = pin->GetParent() ) { wxString pinText = pin->GetText(); SCH_SCREEN* screen = sheet->GetScreen(); for( SCH_ITEM* item : screen->Items().OfType( SCH_HIER_LABEL_T ) ) { SCH_HIERLABEL* label = static_cast( item ); if( label->GetText() == pinText ) { SCH_SHEET_PATH path = subgraph->m_sheet; path.push_back( sheet ); SCH_CONNECTION* parent_conn = label->Connection( &path ); if( parent_conn && parent_conn->IsBus() ) subgraph->m_driver_connection->SetType( CONNECTION_TYPE::BUS ); break; } } if( subgraph->m_driver_connection->IsBus() ) return 0; } } return 1; }; tp.push_loop( m_driver_subgraphs.size(), [&]( const int a, const int b) { for( int ii = a; ii < b; ++ii ) updateItemConnectionsTask( m_driver_subgraphs[ii] ); }); tp.wait_for_tasks(); m_net_code_to_subgraphs_map.clear(); m_net_name_to_subgraphs_map.clear(); for( CONNECTION_SUBGRAPH* subgraph : m_driver_subgraphs ) { NET_NAME_CODE_CACHE_KEY key = { subgraph->GetNetName(), subgraph->m_driver_connection->NetCode() }; m_net_code_to_subgraphs_map[ key ].push_back( subgraph ); m_net_name_to_subgraphs_map[subgraph->m_driver_connection->Name()].push_back( subgraph ); } std::shared_ptr& netSettings = m_schematic->Prj().GetProjectFile().m_NetSettings; std::map oldAssignments = netSettings->m_NetClassLabelAssignments; netSettings->m_NetClassLabelAssignments.clear(); auto dirtySubgraphs = [&]( const std::vector& subgraphs ) { if( aChangedItemHandler ) { for( const CONNECTION_SUBGRAPH* subgraph : subgraphs ) { for( SCH_ITEM* item : subgraph->m_items ) (*aChangedItemHandler)( item ); } } }; auto checkNetclassDrivers = [&]( const std::vector& subgraphs ) { const CONNECTION_SUBGRAPH* driverSubgraph = nullptr; wxString netclass; wxCHECK_RET( !subgraphs.empty(), wxT("Invalid empty subgraph" ) ); for( const CONNECTION_SUBGRAPH* subgraph : subgraphs ) { for( SCH_ITEM* item : subgraph->m_items ) { netclass = subgraph->GetNetclassForDriver( item ); if( !netclass.IsEmpty() ) break; } if( !netclass.IsEmpty() ) { driverSubgraph = subgraph; break; } } if( netclass.IsEmpty() ) return; if( !driverSubgraph ) driverSubgraph = subgraphs.front(); const wxString netname = driverSubgraph->GetNetName(); if( driverSubgraph->m_driver_connection->IsBus() ) { for( const auto& member : driverSubgraph->m_driver_connection->Members() ) { netSettings->m_NetClassLabelAssignments[ member->Name() ] = netclass; auto ii = m_net_name_to_subgraphs_map.find( member->Name() ); if( ii != m_net_name_to_subgraphs_map.end() ) dirtySubgraphs( ii->second ); } } netSettings->m_NetClassLabelAssignments[ netname ] = netclass; if( oldAssignments[ netname ] != netclass ) dirtySubgraphs( subgraphs ); }; for( const auto& [ netname, subgraphs ] : m_net_name_to_subgraphs_map ) checkNetclassDrivers( subgraphs ); } int CONNECTION_GRAPH::getOrCreateNetCode( const wxString& aNetName ) { int code; auto it = m_net_name_to_code_map.find( aNetName ); if( it == m_net_name_to_code_map.end() ) { code = m_last_net_code++; m_net_name_to_code_map[ aNetName ] = code; } else { code = it->second; } return code; } int CONNECTION_GRAPH::assignNewNetCode( SCH_CONNECTION& aConnection ) { int code = getOrCreateNetCode( aConnection.Name() ); aConnection.SetNetCode( code ); return code; } void CONNECTION_GRAPH::assignNetCodesToBus( SCH_CONNECTION* aConnection ) { std::vector> connections_to_check( aConnection->Members() ); for( unsigned i = 0; i < connections_to_check.size(); i++ ) { const std::shared_ptr& member = connections_to_check[i]; if( member->IsBus() ) { connections_to_check.insert( connections_to_check.end(), member->Members().begin(), member->Members().end() ); continue; } assignNewNetCode( *member ); } } void CONNECTION_GRAPH::propagateToNeighbors( CONNECTION_SUBGRAPH* aSubgraph, bool aForce ) { SCH_CONNECTION* conn = aSubgraph->m_driver_connection; std::vector search_list; std::unordered_set visited; std::unordered_set stale_bus_members; auto visit =[&]( CONNECTION_SUBGRAPH* aParent ) { for( SCH_SHEET_PIN* pin : aParent->m_hier_pins ) { SCH_SHEET_PATH path = aParent->m_sheet; path.push_back( pin->GetParent() ); auto it = m_sheet_to_subgraphs_map.find( path ); if( it == m_sheet_to_subgraphs_map.end() ) continue; for( CONNECTION_SUBGRAPH* candidate : it->second ) { if( !candidate->m_strong_driver || candidate->m_hier_ports.empty() || visited.count( candidate ) ) { continue; } for( SCH_HIERLABEL* label : candidate->m_hier_ports ) { if( candidate->GetNameForDriver( label ) == aParent->GetNameForDriver( pin ) ) { wxLogTrace( ConnTrace, wxS( "%lu: found child %lu (%s)" ), aParent->m_code, candidate->m_code, candidate->m_driver_connection->Name() ); candidate->m_hier_parent = aParent; aParent->m_hier_children.insert( candidate ); wxASSERT( candidate->m_graph == aParent->m_graph ); search_list.push_back( candidate ); break; } } } } for( SCH_HIERLABEL* label : aParent->m_hier_ports ) { SCH_SHEET_PATH path = aParent->m_sheet; path.pop_back(); auto it = m_sheet_to_subgraphs_map.find( path ); if( it == m_sheet_to_subgraphs_map.end() ) continue; for( CONNECTION_SUBGRAPH* candidate : it->second ) { if( candidate->m_hier_pins.empty() || visited.count( candidate ) || candidate->m_driver_connection->Type() != aParent->m_driver_connection->Type() ) { continue; } const KIID& last_parent_uuid = aParent->m_sheet.Last()->m_Uuid; for( SCH_SHEET_PIN* pin : candidate->m_hier_pins ) { // If the last sheet UUIDs won't match, no need to check the full path if( pin->GetParent()->m_Uuid != last_parent_uuid ) continue; SCH_SHEET_PATH pin_path = path; pin_path.push_back( pin->GetParent() ); if( pin_path != aParent->m_sheet ) continue; if( aParent->GetNameForDriver( label ) == candidate->GetNameForDriver( pin ) ) { wxLogTrace( ConnTrace, wxS( "%lu: found additional parent %lu (%s)" ), aParent->m_code, candidate->m_code, candidate->m_driver_connection->Name() ); aParent->m_hier_children.insert( candidate ); search_list.push_back( candidate ); break; } } } } }; auto propagate_bus_neighbors = [&]( CONNECTION_SUBGRAPH* aParentGraph ) { for( const auto& kv : aParentGraph->m_bus_neighbors ) { for( CONNECTION_SUBGRAPH* neighbor : kv.second ) { // May have been absorbed but won't have been deleted while( neighbor->m_absorbed ) neighbor = neighbor->m_absorbed_by; SCH_CONNECTION* parent = aParentGraph->m_driver_connection; // Now member may be out of date, since we just cloned the // connection from higher up in the hierarchy. We need to // figure out what the actual new connection is. SCH_CONNECTION* member = matchBusMember( parent, kv.first.get() ); if( !member ) { // Try harder: we might match on a secondary driver for( CONNECTION_SUBGRAPH* sg : kv.second ) { if( sg->m_multiple_drivers ) { SCH_SHEET_PATH sheet = sg->m_sheet; for( SCH_ITEM* driver : sg->m_drivers ) { auto c = getDefaultConnection( driver, sg ); member = matchBusMember( parent, c.get() ); if( member ) break; } } if( member ) break; } } // This is bad, probably an ERC error if( !member ) { wxLogTrace( ConnTrace, wxS( "Could not match bus member %s in %s" ), kv.first->Name(), parent->Name() ); continue; } auto neighbor_conn = neighbor->m_driver_connection; auto neighbor_name = neighbor_conn->Name(); // Matching name: no update needed if( neighbor_name == member->Name() ) continue; // Was this neighbor already updated from a different sheet? Don't rename it again if( neighbor_conn->Sheet() != neighbor->m_sheet ) continue; // Safety check against infinite recursion wxASSERT( neighbor_conn->IsNet() ); wxLogTrace( ConnTrace, wxS( "%lu (%s) connected to bus member %s (local %s)" ), neighbor->m_code, neighbor_name, member->Name(), member->LocalName() ); // Take whichever name is higher priority if( CONNECTION_SUBGRAPH::GetDriverPriority( neighbor->m_driver ) >= CONNECTION_SUBGRAPH::PRIORITY::POWER_PIN ) { member->Clone( *neighbor_conn ); stale_bus_members.insert( member ); } else { neighbor_conn->Clone( *member ); recacheSubgraphName( neighbor, neighbor_name ); // Recurse onto this neighbor in case it needs to re-propagate neighbor->m_dirty = true; propagateToNeighbors( neighbor, aForce ); } } } }; // If we are a bus, we must propagate to local neighbors and then the hierarchy if( conn->IsBus() ) propagate_bus_neighbors( aSubgraph ); // If we have both ports and pins, skip processing as we'll be visited by a parent or child. // If we only have one or the other, process (we can either go bottom-up or top-down depending // on which subgraph comes up first) if( !aForce && !aSubgraph->m_hier_ports.empty() && !aSubgraph->m_hier_pins.empty() ) { wxLogTrace( ConnTrace, wxS( "%lu (%s) has both hier ports and pins; deferring processing" ), aSubgraph->m_code, conn->Name() ); return; } else if( aSubgraph->m_hier_ports.empty() && aSubgraph->m_hier_pins.empty() ) { wxLogTrace( ConnTrace, wxS( "%lu (%s) has no hier pins or ports on sheet %s; marking clean" ), aSubgraph->m_code, conn->Name(), aSubgraph->m_sheet.PathHumanReadable() ); aSubgraph->m_dirty = false; return; } visited.insert( aSubgraph ); wxLogTrace( ConnTrace, wxS( "Propagating %lu (%s) to subsheets" ), aSubgraph->m_code, aSubgraph->m_driver_connection->Name() ); visit( aSubgraph ); for( unsigned i = 0; i < search_list.size(); i++ ) { auto child = search_list[i]; if( visited.insert( child ).second ) visit( child ); child->m_dirty = false; } // Now, find the best driver for this chain of subgraphs CONNECTION_SUBGRAPH* bestDriver = aSubgraph; CONNECTION_SUBGRAPH::PRIORITY highest = CONNECTION_SUBGRAPH::GetDriverPriority( aSubgraph->m_driver ); bool bestIsStrong = ( highest >= CONNECTION_SUBGRAPH::PRIORITY::HIER_LABEL ); wxString bestName = aSubgraph->m_driver_connection->Name(); // Check if a subsheet has a higher-priority connection to the same net if( highest < CONNECTION_SUBGRAPH::PRIORITY::POWER_PIN ) { for( CONNECTION_SUBGRAPH* subgraph : visited ) { if( subgraph == aSubgraph ) continue; CONNECTION_SUBGRAPH::PRIORITY priority = CONNECTION_SUBGRAPH::GetDriverPriority( subgraph->m_driver ); bool candidateStrong = ( priority >= CONNECTION_SUBGRAPH::PRIORITY::HIER_LABEL ); wxString candidateName = subgraph->m_driver_connection->Name(); bool shorterPath = subgraph->m_sheet.size() < bestDriver->m_sheet.size(); bool asGoodPath = subgraph->m_sheet.size() <= bestDriver->m_sheet.size(); // Pick a better driving subgraph if it: // a) has a power pin or global driver // b) is a strong driver and we're a weak driver // c) is a higher priority strong driver // d) matches our priority, is a strong driver, and has a shorter path // e) matches our strength and is at least as short, and is alphabetically lower if( ( priority >= CONNECTION_SUBGRAPH::PRIORITY::POWER_PIN ) || ( !bestIsStrong && candidateStrong ) || ( priority > highest && candidateStrong ) || ( priority == highest && candidateStrong && shorterPath ) || ( ( bestIsStrong == candidateStrong ) && asGoodPath && ( priority == highest ) && ( candidateName < bestName ) ) ) { bestDriver = subgraph; highest = priority; bestIsStrong = candidateStrong; bestName = candidateName; } } } if( bestDriver != aSubgraph ) { wxLogTrace( ConnTrace, wxS( "%lu (%s) overridden by new driver %lu (%s)" ), aSubgraph->m_code, aSubgraph->m_driver_connection->Name(), bestDriver->m_code, bestDriver->m_driver_connection->Name() ); } conn = bestDriver->m_driver_connection; for( CONNECTION_SUBGRAPH* subgraph : visited ) { wxString old_name = subgraph->m_driver_connection->Name(); subgraph->m_driver_connection->Clone( *conn ); if( old_name != conn->Name() ) recacheSubgraphName( subgraph, old_name ); if( conn->IsBus() ) propagate_bus_neighbors( subgraph ); } // Somewhere along the way, a bus member may have been upgraded to a global or power label. // Because this can happen anywhere, we need a second pass to update all instances of that bus // member to have the correct connection info if( conn->IsBus() && !stale_bus_members.empty() ) { std::unordered_set cached_members = stale_bus_members; for( SCH_CONNECTION* stale_member : cached_members ) { for( CONNECTION_SUBGRAPH* subgraph : visited ) { SCH_CONNECTION* member = matchBusMember( subgraph->m_driver_connection, stale_member ); if( !member ) { wxLogTrace( ConnTrace, wxS( "WARNING: failed to match stale member %s in %s." ), stale_member->Name(), subgraph->m_driver_connection->Name() ); continue; } wxLogTrace( ConnTrace, wxS( "Updating %lu (%s) member %s to %s" ), subgraph->m_code, subgraph->m_driver_connection->Name(), member->LocalName(), stale_member->Name() ); member->Clone( *stale_member ); propagate_bus_neighbors( subgraph ); } } } aSubgraph->m_dirty = false; } std::shared_ptr CONNECTION_GRAPH::getDefaultConnection( SCH_ITEM* aItem, CONNECTION_SUBGRAPH* aSubgraph ) { std::shared_ptr c = std::shared_ptr( nullptr ); switch( aItem->Type() ) { case SCH_PIN_T: { SCH_PIN* pin = static_cast( aItem ); if( pin->IsPowerConnection() ) c = std::make_shared( aItem, aSubgraph->m_sheet ); break; } case SCH_GLOBAL_LABEL_T: case SCH_HIER_LABEL_T: case SCH_LABEL_T: { c = std::make_shared( aItem, aSubgraph->m_sheet ); break; } default: break; } if( c ) { c->SetGraph( this ); c->ConfigureFromLabel( aSubgraph->GetNameForDriver( aItem ) ); } return c; } SCH_CONNECTION* CONNECTION_GRAPH::matchBusMember( SCH_CONNECTION* aBusConnection, SCH_CONNECTION* aSearch ) { wxASSERT( aBusConnection->IsBus() ); SCH_CONNECTION* match = nullptr; if( aBusConnection->Type() == CONNECTION_TYPE::BUS ) { // Vector bus: compare against index, because we allow the name // to be different for( const std::shared_ptr& bus_member : aBusConnection->Members() ) { if( bus_member->VectorIndex() == aSearch->VectorIndex() ) { match = bus_member.get(); break; } } } else { // Group bus for( const std::shared_ptr& c : aBusConnection->Members() ) { // Vector inside group: compare names, because for bus groups // we expect the naming to be consistent across all usages // TODO(JE) explain this in the docs if( c->Type() == CONNECTION_TYPE::BUS ) { for( const std::shared_ptr& bus_member : c->Members() ) { if( bus_member->LocalName() == aSearch->LocalName() ) { match = bus_member.get(); break; } } } else if( c->LocalName() == aSearch->LocalName() ) { match = c.get(); break; } } } return match; } void CONNECTION_GRAPH::recacheSubgraphName( CONNECTION_SUBGRAPH* aSubgraph, const wxString& aOldName ) { auto it = m_net_name_to_subgraphs_map.find( aOldName ); if( it != m_net_name_to_subgraphs_map.end() ) { std::vector& vec = it->second; alg::delete_matching( vec, aSubgraph ); } wxLogTrace( ConnTrace, wxS( "recacheSubgraphName: %s => %s" ), aOldName, aSubgraph->m_driver_connection->Name() ); m_net_name_to_subgraphs_map[aSubgraph->m_driver_connection->Name()].push_back( aSubgraph ); } std::shared_ptr CONNECTION_GRAPH::GetBusAlias( const wxString& aName ) { auto it = m_bus_alias_cache.find( aName ); return it != m_bus_alias_cache.end() ? it->second : nullptr; } std::vector CONNECTION_GRAPH::GetBusesNeedingMigration() { std::vector ret; for( CONNECTION_SUBGRAPH* subgraph : m_subgraphs ) { // Graph is supposed to be up-to-date before calling this wxASSERT( !subgraph->m_dirty ); if( !subgraph->m_driver ) continue; SCH_CONNECTION* connection = subgraph->m_driver->Connection( &subgraph->m_sheet ); if( !connection->IsBus() ) continue; auto labels = subgraph->GetVectorBusLabels(); if( labels.size() > 1 ) { bool different = false; wxString first = static_cast( labels.at( 0 ) )->GetShownText( false ); for( unsigned i = 1; i < labels.size(); ++i ) { if( static_cast( labels.at( i ) )->GetShownText( false ) != first ) { different = true; break; } } if( !different ) continue; wxLogTrace( ConnTrace, wxS( "SG %ld (%s) has multiple bus labels" ), subgraph->m_code, connection->Name() ); ret.push_back( subgraph ); } } return ret; } wxString CONNECTION_GRAPH::GetResolvedSubgraphName( const CONNECTION_SUBGRAPH* aSubGraph ) const { wxString retval = aSubGraph->GetNetName(); bool found = false; // This is a hacky way to find the true subgraph net name (why do we not store it?) // TODO: Remove once the actual netname of the subgraph is stored with the subgraph for( auto it = m_net_name_to_subgraphs_map.begin(); it != m_net_name_to_subgraphs_map.end() && !found; ++it ) { for( CONNECTION_SUBGRAPH* graph : it->second ) { if( graph == aSubGraph ) { retval = it->first; found = true; break; } } } return retval; } CONNECTION_SUBGRAPH* CONNECTION_GRAPH::FindSubgraphByName( const wxString& aNetName, const SCH_SHEET_PATH& aPath ) { auto it = m_net_name_to_subgraphs_map.find( aNetName ); if( it == m_net_name_to_subgraphs_map.end() ) return nullptr; for( CONNECTION_SUBGRAPH* sg : it->second ) { // Cache is supposed to be valid by now wxASSERT( sg && !sg->m_absorbed && sg->m_driver_connection ); if( sg->m_sheet == aPath && sg->m_driver_connection->Name() == aNetName ) return sg; } return nullptr; } CONNECTION_SUBGRAPH* CONNECTION_GRAPH::FindFirstSubgraphByName( const wxString& aNetName ) { auto it = m_net_name_to_subgraphs_map.find( aNetName ); if( it == m_net_name_to_subgraphs_map.end() ) return nullptr; wxASSERT( !it->second.empty() ); return it->second[0]; } CONNECTION_SUBGRAPH* CONNECTION_GRAPH::GetSubgraphForItem( SCH_ITEM* aItem ) { auto it = m_item_to_subgraph_map.find( aItem ); CONNECTION_SUBGRAPH* ret = it != m_item_to_subgraph_map.end() ? it->second : nullptr; while( ret && ret->m_absorbed ) ret = ret->m_absorbed_by; return ret; } int CONNECTION_GRAPH::RunERC() { int error_count = 0; wxCHECK_MSG( m_schematic, true, wxS( "Null m_schematic in CONNECTION_GRAPH::RunERC" ) ); ERC_SETTINGS& settings = m_schematic->ErcSettings(); // We don't want to run many ERC checks more than once on a given screen even though it may // represent multiple sheets with multiple subgraphs. We can tell these apart by drivers. std::set seenDriverInstances; for( CONNECTION_SUBGRAPH* subgraph : m_subgraphs ) { // There shouldn't be any null sub-graph pointers. wxCHECK2( subgraph, continue ); // Graph is supposed to be up-to-date before calling RunERC() wxASSERT( !subgraph->m_dirty ); if( subgraph->m_absorbed ) continue; if( seenDriverInstances.count( subgraph->m_driver ) ) continue; if( subgraph->m_driver ) seenDriverInstances.insert( subgraph->m_driver ); /** * NOTE: * * We could check that labels attached to bus subgraphs follow the * proper format (i.e. actually define a bus). * * This check doesn't need to be here right now because labels * won't actually be connected to bus wires if they aren't in the right * format due to their TestDanglingEnds() implementation. */ if( settings.IsTestEnabled( ERCE_DRIVER_CONFLICT ) ) { if( !ercCheckMultipleDrivers( subgraph ) ) error_count++; } subgraph->ResolveDrivers( false ); if( settings.IsTestEnabled( ERCE_BUS_TO_NET_CONFLICT ) ) { if( !ercCheckBusToNetConflicts( subgraph ) ) error_count++; } if( settings.IsTestEnabled( ERCE_BUS_ENTRY_CONFLICT ) ) { if( !ercCheckBusToBusEntryConflicts( subgraph ) ) error_count++; } if( settings.IsTestEnabled( ERCE_BUS_TO_BUS_CONFLICT ) ) { if( !ercCheckBusToBusConflicts( subgraph ) ) error_count++; } if( settings.IsTestEnabled( ERCE_WIRE_DANGLING ) ) { if( !ercCheckFloatingWires( subgraph ) ) error_count++; } if( settings.IsTestEnabled( ERCE_NOCONNECT_CONNECTED ) || settings.IsTestEnabled( ERCE_NOCONNECT_NOT_CONNECTED ) || settings.IsTestEnabled( ERCE_PIN_NOT_CONNECTED ) ) { if( !ercCheckNoConnects( subgraph ) ) error_count++; } if( settings.IsTestEnabled( ERCE_LABEL_NOT_CONNECTED ) || settings.IsTestEnabled( ERCE_GLOBLABEL ) ) { if( !ercCheckLabels( subgraph ) ) error_count++; } } // Hierarchical sheet checking is done at the schematic level if( settings.IsTestEnabled( ERCE_HIERACHICAL_LABEL ) || settings.IsTestEnabled( ERCE_PIN_NOT_CONNECTED ) ) { error_count += ercCheckHierSheets(); } if( settings.IsTestEnabled( ERCE_NETCLASS_CONFLICT ) ) { for( const auto& [ netname, subgraphs ] : m_net_name_to_subgraphs_map ) { if( !ercCheckNetclassConflicts( subgraphs ) ) error_count++; } } return error_count; } bool CONNECTION_GRAPH::ercCheckMultipleDrivers( const CONNECTION_SUBGRAPH* aSubgraph ) { wxCHECK( aSubgraph, false ); if( aSubgraph->m_multiple_drivers ) { for( SCH_ITEM* driver : aSubgraph->m_drivers ) { if( driver == aSubgraph->m_driver ) continue; if( driver->Type() == SCH_GLOBAL_LABEL_T || driver->Type() == SCH_HIER_LABEL_T || driver->Type() == SCH_LABEL_T || ( driver->Type() == SCH_PIN_T && static_cast( driver )->IsPowerConnection() ) ) { const wxString& primaryName = aSubgraph->GetNameForDriver( aSubgraph->m_driver ); const wxString& secondaryName = aSubgraph->GetNameForDriver( driver ); if( primaryName == secondaryName ) continue; wxString msg = wxString::Format( _( "Both %s and %s are attached to the same " "items; %s will be used in the netlist" ), primaryName, secondaryName, primaryName ); std::shared_ptr ercItem = ERC_ITEM::Create( ERCE_DRIVER_CONFLICT ); ercItem->SetItems( aSubgraph->m_driver, driver ); ercItem->SetErrorMessage( msg ); SCH_MARKER* marker = new SCH_MARKER( ercItem, driver->GetPosition() ); aSubgraph->m_sheet.LastScreen()->Append( marker ); return false; } } } return true; } bool CONNECTION_GRAPH::ercCheckNetclassConflicts( const std::vector& subgraphs ) { wxString firstNetclass; SCH_ITEM* firstNetclassDriver = nullptr; for( const CONNECTION_SUBGRAPH* subgraph : subgraphs ) { for( SCH_ITEM* item : subgraph->m_items ) { const wxString netclass = subgraph->GetNetclassForDriver( item ); if( netclass.IsEmpty() ) continue; if( netclass != firstNetclass ) { if( !firstNetclassDriver ) { firstNetclass = netclass; firstNetclassDriver = item; continue; } std::shared_ptr ercItem = ERC_ITEM::Create( ERCE_NETCLASS_CONFLICT ); ercItem->SetItems( firstNetclassDriver, item ); SCH_MARKER* marker = new SCH_MARKER( ercItem, item->GetPosition() ); subgraph->m_sheet.LastScreen()->Append( marker ); return false; } } } return true; } bool CONNECTION_GRAPH::ercCheckBusToNetConflicts( const CONNECTION_SUBGRAPH* aSubgraph ) { const SCH_SHEET_PATH& sheet = aSubgraph->m_sheet; SCH_SCREEN* screen = sheet.LastScreen(); SCH_ITEM* net_item = nullptr; SCH_ITEM* bus_item = nullptr; SCH_CONNECTION conn( this ); for( SCH_ITEM* item : aSubgraph->m_items ) { switch( item->Type() ) { case SCH_LINE_T: { if( item->GetLayer() == LAYER_BUS ) bus_item = ( !bus_item ) ? item : bus_item; else net_item = ( !net_item ) ? item : net_item; break; } case SCH_LABEL_T: case SCH_GLOBAL_LABEL_T: case SCH_SHEET_PIN_T: case SCH_HIER_LABEL_T: { SCH_TEXT* text = static_cast( item ); conn.ConfigureFromLabel( EscapeString( text->GetShownText( false ), CTX_NETNAME ) ); if( conn.IsBus() ) bus_item = ( !bus_item ) ? item : bus_item; else net_item = ( !net_item ) ? item : net_item; break; } default: break; } } if( net_item && bus_item ) { std::shared_ptr ercItem = ERC_ITEM::Create( ERCE_BUS_TO_NET_CONFLICT ); ercItem->SetItems( net_item, bus_item ); SCH_MARKER* marker = new SCH_MARKER( ercItem, net_item->GetPosition() ); screen->Append( marker ); return false; } return true; } bool CONNECTION_GRAPH::ercCheckBusToBusConflicts( const CONNECTION_SUBGRAPH* aSubgraph ) { const SCH_SHEET_PATH& sheet = aSubgraph->m_sheet; SCH_SCREEN* screen = sheet.LastScreen(); SCH_ITEM* label = nullptr; SCH_ITEM* port = nullptr; for( SCH_ITEM* item : aSubgraph->m_items ) { switch( item->Type() ) { case SCH_TEXT_T: case SCH_GLOBAL_LABEL_T: { if( !label && item->Connection( &sheet )->IsBus() ) label = item; break; } case SCH_SHEET_PIN_T: case SCH_HIER_LABEL_T: { if( !port && item->Connection( &sheet )->IsBus() ) port = item; break; } default: break; } } if( label && port ) { bool match = false; for( const auto& member : label->Connection( &sheet )->Members() ) { for( const auto& test : port->Connection( &sheet )->Members() ) { if( test != member && member->Name() == test->Name() ) { match = true; break; } } if( match ) break; } if( !match ) { std::shared_ptr ercItem = ERC_ITEM::Create( ERCE_BUS_TO_BUS_CONFLICT ); ercItem->SetItems( label, port ); SCH_MARKER* marker = new SCH_MARKER( ercItem, label->GetPosition() ); screen->Append( marker ); return false; } } return true; } bool CONNECTION_GRAPH::ercCheckBusToBusEntryConflicts( const CONNECTION_SUBGRAPH* aSubgraph ) { bool conflict = false; const SCH_SHEET_PATH& sheet = aSubgraph->m_sheet; SCH_SCREEN* screen = sheet.LastScreen(); SCH_BUS_WIRE_ENTRY* bus_entry = nullptr; SCH_ITEM* bus_wire = nullptr; wxString bus_name; if( !aSubgraph->m_driver_connection ) { // Incomplete bus entry. Let the unconnected tests handle it. return true; } for( SCH_ITEM* item : aSubgraph->m_items ) { switch( item->Type() ) { case SCH_BUS_WIRE_ENTRY_T: { if( !bus_entry ) bus_entry = static_cast( item ); break; } default: break; } } if( bus_entry && bus_entry->m_connected_bus_item ) { bus_wire = bus_entry->m_connected_bus_item; wxASSERT( bus_wire->Type() == SCH_LINE_T ); // In some cases, the connection list (SCH_CONNECTION*) can be null. // Skip null connections. if( bus_entry->Connection( &sheet ) && bus_wire->Type() == SCH_LINE_T && bus_wire->Connection( &sheet ) ) { conflict = true; // Assume a conflict; we'll reset if we find it's OK bus_name = bus_wire->Connection( &sheet )->Name(); std::set test_names; test_names.insert( bus_entry->Connection( &sheet )->Name() ); wxString baseName = sheet.PathHumanReadable(); for( SCH_ITEM* driver : aSubgraph->m_drivers ) test_names.insert( baseName + aSubgraph->GetNameForDriver( driver ) ); for( const auto& member : bus_wire->Connection( &sheet )->Members() ) { if( member->Type() == CONNECTION_TYPE::BUS ) { for( const auto& sub_member : member->Members() ) { if( test_names.count( sub_member->Name() ) ) conflict = false; } } else if( test_names.count( member->Name() ) ) { conflict = false; } } } } // Don't report warnings if this bus member has been overridden by a higher priority power pin // or global label if( conflict && CONNECTION_SUBGRAPH::GetDriverPriority( aSubgraph->m_driver ) >= CONNECTION_SUBGRAPH::PRIORITY::POWER_PIN ) { conflict = false; } if( conflict ) { wxString netName = aSubgraph->m_driver_connection->Name(); wxString msg = wxString::Format( _( "Net %s is graphically connected to bus %s but is not a" " member of that bus" ), UnescapeString( netName ), UnescapeString( bus_name ) ); std::shared_ptr ercItem = ERC_ITEM::Create( ERCE_BUS_ENTRY_CONFLICT ); ercItem->SetItems( bus_entry, bus_wire ); ercItem->SetErrorMessage( msg ); SCH_MARKER* marker = new SCH_MARKER( ercItem, bus_entry->GetPosition() ); screen->Append( marker ); return false; } return true; } // TODO(JE) Check sheet pins here too? bool CONNECTION_GRAPH::ercCheckNoConnects( const CONNECTION_SUBGRAPH* aSubgraph ) { ERC_SETTINGS& settings = m_schematic->ErcSettings(); const SCH_SHEET_PATH& sheet = aSubgraph->m_sheet; SCH_SCREEN* screen = sheet.LastScreen(); bool ok = true; SCH_PIN* pin = nullptr; std::set unique_pins; std::set unique_labels; wxString netName = GetResolvedSubgraphName( aSubgraph ); auto process_subgraph = [&]( const CONNECTION_SUBGRAPH* aProcessGraph ) { // Any subgraph that contains a no-connect should not // more than one pin (which would indicate it is connected for( SCH_ITEM* item : aProcessGraph->m_items ) { switch( item->Type() ) { case SCH_PIN_T: { SCH_PIN* test_pin = static_cast( item ); // Only link NC to pin on the current subgraph being checked if( aProcessGraph == aSubgraph ) pin = test_pin; if( std::none_of( unique_pins.begin(), unique_pins.end(), [test_pin]( SCH_PIN* aPin ) { return test_pin->IsStacked( aPin ); } )) { unique_pins.insert( test_pin ); } break; } case SCH_LABEL_T: case SCH_GLOBAL_LABEL_T: case SCH_HIER_LABEL_T: unique_labels.insert( static_cast( item ) ); KI_FALLTHROUGH; default: break; } } }; auto it = m_net_name_to_subgraphs_map.find( netName ); if( it != m_net_name_to_subgraphs_map.end() ) { for( const CONNECTION_SUBGRAPH* subgraph : it->second ) { process_subgraph( subgraph ); } } else { process_subgraph( aSubgraph ); } if( aSubgraph->m_no_connect != nullptr ) { if( unique_pins.size() > 1 && settings.IsTestEnabled( ERCE_NOCONNECT_CONNECTED ) ) { std::shared_ptr ercItem = ERC_ITEM::Create( ERCE_NOCONNECT_CONNECTED ); VECTOR2I pos; if( pin ) { ercItem->SetItems( pin, aSubgraph->m_no_connect ); pos = pin->GetTransformedPosition(); } else { ercItem->SetItems( aSubgraph->m_no_connect ); pos = aSubgraph->m_no_connect->GetPosition(); } SCH_MARKER* marker = new SCH_MARKER( ercItem, pos ); screen->Append( marker ); ok = false; } if( unique_pins.empty() && unique_labels.empty() && settings.IsTestEnabled( ERCE_NOCONNECT_NOT_CONNECTED ) ) { std::shared_ptr ercItem = ERC_ITEM::Create( ERCE_NOCONNECT_NOT_CONNECTED ); ercItem->SetItems( aSubgraph->m_no_connect ); SCH_MARKER* marker = new SCH_MARKER( ercItem, aSubgraph->m_no_connect->GetPosition() ); screen->Append( marker ); ok = false; } } else { bool has_other_connections = false; std::vector pins; // Any subgraph that lacks a no-connect and contains a pin should also // contain at least one other potential driver for( SCH_ITEM* item : aSubgraph->m_items ) { switch( item->Type() ) { case SCH_PIN_T: { // Stacked pins do not count as other connections but non-stacked pins do if( !has_other_connections && !pins.empty() ) { SCH_PIN* test_pin = static_cast( item ); for( SCH_PIN* other_pin : pins ) { if( !test_pin->IsStacked( other_pin ) ) { has_other_connections = true; break; } } } pins.emplace_back( static_cast( item ) ); break; } default: if( aSubgraph->GetDriverPriority( item ) != CONNECTION_SUBGRAPH::PRIORITY::NONE ) has_other_connections = true; break; } } // For many checks, we can just use the first pin pin = pins.empty() ? nullptr : pins[0]; // But if there is a power pin, it might be connected elsewhere for( SCH_PIN* test_pin : pins ) { if( test_pin->GetType() == ELECTRICAL_PINTYPE::PT_POWER_IN ) { pin = test_pin; break; } } // Check if invisible power input pins connect to anything else via net name, // but not for power symbols as the ones in the standard library all have invisible pins // and we want to throw unconnected errors for those even if they are connected to other // net items by name, because usually failing to connect them graphically is a mistake if( pin && !has_other_connections && pin->GetType() == ELECTRICAL_PINTYPE::PT_POWER_IN && !pin->IsVisible() && !pin->GetLibPin()->GetParent()->IsPower() ) { wxString name = pin->Connection( &sheet )->Name(); wxString local_name = pin->Connection( &sheet )->Name( true ); if( m_global_label_cache.count( name ) || m_local_label_cache.count( std::make_pair( sheet, local_name ) ) ) { has_other_connections = true; } } // Only one pin, and it's not a no-connect pin if( pin && !has_other_connections && pin->GetType() != ELECTRICAL_PINTYPE::PT_NC && pin->GetType() != ELECTRICAL_PINTYPE::PT_NIC && settings.IsTestEnabled( ERCE_PIN_NOT_CONNECTED ) ) { std::shared_ptr ercItem = ERC_ITEM::Create( ERCE_PIN_NOT_CONNECTED ); ercItem->SetItems( pin ); SCH_MARKER* marker = new SCH_MARKER( ercItem, pin->GetTransformedPosition() ); screen->Append( marker ); ok = false; } // If there are multiple pins in this SG, they might be indirectly connected (by netname) // rather than directly connected (by wires). We want to flag dangling pins even if they // join nets with another pin, as it's often a mistake if( pins.size() > 1 ) { for( SCH_PIN* testPin : pins ) { // We only apply this test to power symbols, because other symbols have invisible // pins that are meant to be dangling, but the KiCad standard library power symbols // have invisible pins that are *not* meant to be dangling. if( testPin->GetLibPin()->GetParent()->IsPower() && testPin->ConnectedItems( sheet ).empty() && settings.IsTestEnabled( ERCE_PIN_NOT_CONNECTED ) ) { std::shared_ptr ercItem = ERC_ITEM::Create( ERCE_PIN_NOT_CONNECTED ); ercItem->SetItems( testPin ); SCH_MARKER* marker = new SCH_MARKER( ercItem, testPin->GetTransformedPosition() ); screen->Append( marker ); ok = false; } } } } return ok; } bool CONNECTION_GRAPH::ercCheckFloatingWires( const CONNECTION_SUBGRAPH* aSubgraph ) { if( aSubgraph->m_driver ) return true; std::vector wires; // We've gotten this far, so we know we have no valid driver. All we need to do is check // for a wire that we can place the error on. for( SCH_ITEM* item : aSubgraph->m_items ) { if( item->Type() == SCH_LINE_T && item->GetLayer() == LAYER_WIRE ) wires.emplace_back( item ); else if( item->Type() == SCH_BUS_WIRE_ENTRY_T ) wires.emplace_back( item ); } if( !wires.empty() ) { SCH_SCREEN* screen = aSubgraph->m_sheet.LastScreen(); std::shared_ptr ercItem = ERC_ITEM::Create( ERCE_WIRE_DANGLING ); ercItem->SetItems( wires[0], wires.size() > 1 ? wires[1] : nullptr, wires.size() > 2 ? wires[2] : nullptr, wires.size() > 3 ? wires[3] : nullptr ); SCH_MARKER* marker = new SCH_MARKER( ercItem, wires[0]->GetPosition() ); screen->Append( marker ); return false; } return true; } bool CONNECTION_GRAPH::ercCheckLabels( const CONNECTION_SUBGRAPH* aSubgraph ) { // Label connection rules: // Any label without a no-connect needs to have at least 2 pins, otherwise it is invalid // Local labels are flagged if they don't connect to any pins and don't have a no-connect // Global labels are flagged if they appear only once, don't connect to any local labels, // and don't have a no-connect marker if( !aSubgraph->m_driver_connection ) return true; // Buses are excluded from this test: many users create buses with only a single instance // and it's not really a problem as long as the nets in the bus pass ERC if( aSubgraph->m_driver_connection->IsBus() ) return true; ERC_SETTINGS& settings = m_schematic->ErcSettings(); bool ok = true; int pinCount = 0; bool has_nc = !!aSubgraph->m_no_connect; std::map> label_map; auto hasPins = []( const CONNECTION_SUBGRAPH* aLocSubgraph ) -> int { return std::count_if( aLocSubgraph->m_items.begin(), aLocSubgraph->m_items.end(), []( const SCH_ITEM* item ) { return item->Type() == SCH_PIN_T; } ); }; auto reportError = [&]( SCH_TEXT* aText, int errCode ) { if( settings.IsTestEnabled( errCode ) ) { std::shared_ptr ercItem = ERC_ITEM::Create( errCode ); ercItem->SetItems( aText ); SCH_MARKER* marker = new SCH_MARKER( ercItem, aText->GetPosition() ); aSubgraph->m_sheet.LastScreen()->Append( marker ); } }; pinCount = hasPins( aSubgraph ); for( SCH_ITEM* item : aSubgraph->m_items ) { switch( item->Type() ) { case SCH_LABEL_T: case SCH_GLOBAL_LABEL_T: case SCH_HIER_LABEL_T: { SCH_TEXT* text = static_cast( item ); label_map[item->Type()].push_back( text ); // Below, we'll create an ERC if the whole subgraph is unconnected. But, additionally, // we want to error if an individual label in the subgraph is floating, even if it's // connected to other valid things by way of another label on the same sheet. if( text->IsDangling() ) { reportError( text, ERCE_LABEL_NOT_CONNECTED ); return false; } break; } default: break; } } if( label_map.empty() ) return true; wxString netName = GetResolvedSubgraphName( aSubgraph ); wxCHECK_MSG( m_schematic, true, wxS( "Null m_schematic in CONNECTION_GRAPH::ercCheckLabels" ) ); // Labels that have multiple pins connected are not dangling (may be used for naming segments) // so leave them without errors here if( pinCount > 1 ) return true; for( auto& [type, label_vec] : label_map ) { switch( type ) { case SCH_GLOBAL_LABEL_T: if( !settings.IsTestEnabled( ERCE_GLOBLABEL ) ) continue; break; default: if( !settings.IsTestEnabled( ERCE_LABEL_NOT_CONNECTED ) ) continue; break; } for( SCH_TEXT* text : label_vec ) { int allPins = pinCount; auto it = m_net_name_to_subgraphs_map.find( netName ); if( it != m_net_name_to_subgraphs_map.end() ) { for( const CONNECTION_SUBGRAPH* neighbor : it->second ) { if( neighbor == aSubgraph ) continue; if( neighbor->m_no_connect ) has_nc = true; allPins += hasPins( neighbor ); } } if( allPins == 1 && !has_nc ) { reportError( text, type == SCH_GLOBAL_LABEL_T ? ERCE_GLOBLABEL : ERCE_LABEL_NOT_CONNECTED ); ok = false; } if( allPins == 0 ) { reportError( text, type == SCH_GLOBAL_LABEL_T ? ERCE_GLOBLABEL : ERCE_LABEL_NOT_CONNECTED ); ok = false; } } } return ok; } int CONNECTION_GRAPH::ercCheckHierSheets() { int errors = 0; ERC_SETTINGS& settings = m_schematic->ErcSettings(); for( const SCH_SHEET_PATH& sheet : m_sheetList ) { for( SCH_ITEM* item : sheet.LastScreen()->Items() ) { if( item->Type() != SCH_SHEET_T ) continue; SCH_SHEET* parentSheet = static_cast( item ); std::map pins; std::map labels; for( SCH_SHEET_PIN* pin : parentSheet->GetPins() ) { if( settings.IsTestEnabled( ERCE_HIERACHICAL_LABEL ) ) pins[pin->GetText()] = pin; if( pin->IsDangling() && settings.IsTestEnabled( ERCE_PIN_NOT_CONNECTED ) ) { std::shared_ptr ercItem = ERC_ITEM::Create( ERCE_PIN_NOT_CONNECTED ); ercItem->SetItems( pin ); SCH_MARKER* marker = new SCH_MARKER( ercItem, pin->GetPosition() ); sheet.LastScreen()->Append( marker ); errors++; } } if( settings.IsTestEnabled( ERCE_HIERACHICAL_LABEL ) ) { std::set matchedPins; for( SCH_ITEM* subItem : parentSheet->GetScreen()->Items() ) { if( subItem->Type() == SCH_HIER_LABEL_T ) { SCH_HIERLABEL* label = static_cast( subItem ); if( !pins.count( label->GetText() ) ) labels[label->GetText()] = label; else matchedPins.insert( label->GetText() ); } } for( const wxString& matched : matchedPins ) pins.erase( matched ); for( const std::pair& unmatched : pins ) { wxString msg = wxString::Format( _( "Sheet pin %s has no matching hierarchical " "label inside the sheet" ), UnescapeString( unmatched.first ) ); std::shared_ptr ercItem = ERC_ITEM::Create( ERCE_HIERACHICAL_LABEL ); ercItem->SetItems( unmatched.second ); ercItem->SetErrorMessage( msg ); ercItem->SetSheetSpecificPath( sheet ); ercItem->SetItemsSheetPaths( sheet ); SCH_MARKER* marker = new SCH_MARKER( ercItem, unmatched.second->GetPosition() ); sheet.LastScreen()->Append( marker ); errors++; } for( const std::pair& unmatched : labels ) { wxString msg = wxString::Format( _( "Hierarchical label %s has no matching " "sheet pin in the parent sheet" ), UnescapeString( unmatched.first ) ); SCH_SHEET_PATH parentSheetPath = sheet; parentSheetPath.push_back( parentSheet ); std::shared_ptr ercItem = ERC_ITEM::Create( ERCE_HIERACHICAL_LABEL ); ercItem->SetItems( unmatched.second ); ercItem->SetErrorMessage( msg ); ercItem->SetSheetSpecificPath( parentSheetPath ); ercItem->SetItemsSheetPaths( parentSheetPath ); SCH_MARKER* marker = new SCH_MARKER( ercItem, unmatched.second->GetPosition() ); parentSheet->GetScreen()->Append( marker ); errors++; } } } } return errors; }