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kicad-source/eeschema/connection_graph.cpp
Seth Hillbrand 938645b29d Add terrible hack to get subgraph netname 
In certain cases, the subgraph does not receive the proper netname,
preventing us from checking for correct pin counts.  This is a backwards
iteration of the net name <-> subgraph map to extract the proper name
and sibling subgraphs

Fixes https://gitlab.com/kicad/code/kicad/issues/12165

Fixes https://gitlab.com/kicad/code/kicad/issues/12814
2022-11-21 15:19:45 -08:00

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/*
* 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 <jon@craftyjon.com>
*
* 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 <http://www.gnu.org/licenses/>.
*/
#include <list>
#include <future>
#include <vector>
#include <unordered_map>
#include <profile.h>
#include <common.h>
#include <core/kicad_algo.h>
#include <erc.h>
#include <pin_type.h>
#include <sch_bus_entry.h>
#include <sch_symbol.h>
#include <sch_edit_frame.h>
#include <sch_line.h>
#include <sch_marker.h>
#include <sch_pin.h>
#include <sch_sheet.h>
#include <sch_sheet_path.h>
#include <sch_sheet_pin.h>
#include <sch_text.h>
#include <schematic.h>
#include <connection_graph.h>
#include <project/project_file.h>
#include <project/net_settings.h>
#include <widgets/ui_common.h>
#include <string_utils.h>
#include <thread_pool.h>
#include <wx/log.h>
#include <advanced_config.h> // for realtime connectivity switch in release builds
/*
* Flag to enable connectivity profiling
* @ingroup trace_env_vars
*/
static const wxChar ConnProfileMask[] = wxT( "CONN_PROFILE" );
/*
* Flag to enable connectivity tracing
* @ingroup trace_env_vars
*/
static const wxChar ConnTrace[] = wxT( "CONN" );
bool CONNECTION_SUBGRAPH::ResolveDrivers( bool aCheckMultipleDrivers )
{
PRIORITY highest_priority = PRIORITY::INVALID;
std::vector<SCH_ITEM*> candidates;
std::vector<SCH_ITEM*> strong_drivers;
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<SCH_PIN*>( item )->GetParentSymbol()->IsInNetlist() )
continue;
if( item_priority >= PRIORITY::HIER_LABEL )
strong_drivers.push_back( item );
if( item_priority > highest_priority )
{
candidates.clear();
candidates.push_back( item );
highest_priority = item_priority;
}
else if( !candidates.empty() && ( item_priority == highest_priority ) )
{
candidates.push_back( 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<SCH_SHEET_PIN*>( c );
if( p->GetShape() == LABEL_FLAG_SHAPE::L_OUTPUT )
{
m_driver = c;
break;
}
}
}
else
{
// For all other driver types, sort by quality of name
std::sort( candidates.begin(), candidates.end(),
[&]( 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<SCH_PIN*>( a );
SCH_PIN* pb = static_cast<SCH_PIN*>( b );
bool aPower = pa->GetLibPin()->GetParent()->IsPower();
bool bPower = pb->GetLibPin()->GetParent()->IsPower();
if( aPower && !bPower )
return true;
else if( bPower && !aPower )
return false;
}
wxString a_name = GetNameForDriver( a );
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;
} );
}
}
if( !m_driver )
m_driver = candidates[0];
}
if( strong_drivers.size() > 1 )
m_multiple_drivers = true;
// Drop weak drivers
if( m_strong_driver )
m_drivers = strong_drivers;
// 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
{
m_driver_connection = nullptr;
}
if( aCheckMultipleDrivers && m_multiple_drivers )
{
// First check if all the candidates are actually the same
bool same = true;
wxString first = GetNameForDriver( candidates[0] );
SCH_ITEM* second_item = nullptr;
for( unsigned i = 1; i < candidates.size(); i++ )
{
if( GetNameForDriver( candidates[i] ) != first )
{
second_item = candidates[i];
same = false;
break;
}
}
if( !same )
{
m_first_driver = m_driver;
m_second_driver = second_item;
}
}
return ( m_driver != nullptr );
}
wxString CONNECTION_SUBGRAPH::GetNetName() const
{
if( !m_driver || m_dirty )
return "";
if( !m_driver->Connection( &m_sheet ) )
{
#ifdef CONNECTIVITY_DEBUG
wxASSERT_MSG( false, "Tried to get the net name of an item with no connection" );
#endif
return "";
}
return m_driver->Connection( &m_sheet )->Name();
}
std::vector<SCH_ITEM*> CONNECTION_SUBGRAPH::GetBusLabels() const
{
std::vector<SCH_ITEM*> 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<SCH_PIN*>( aItem );
return pin->GetDefaultNetName( m_sheet, forceNoConnect );
break;
}
case SCH_LABEL_T:
case SCH_GLOBAL_LABEL_T:
case SCH_HIER_LABEL_T:
case SCH_SHEET_PIN_T:
{
return EscapeString( static_cast<SCH_TEXT*>( aItem )->GetShownText(), CTX_NETNAME );
break;
}
default:
wxFAIL_MSG( "Unhandled item type in GetNameForDriver" );
break;
}
return wxEmptyString;
}
const wxString& CONNECTION_SUBGRAPH::GetNameForDriver( SCH_ITEM* aItem )
{
auto it = m_driver_name_cache.find( aItem );
if( it != m_driver_name_cache.end() )
return it->second;
m_driver_name_cache.emplace( aItem, driverName( aItem ) );
return m_driver_name_cache.at( aItem );
}
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 driverName( aItem );
}
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<SCH_FIELD*>( 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_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;
aOther->m_absorbed = true;
aOther->m_dirty = false;
aOther->m_driver = nullptr;
aOther->m_driver_connection = nullptr;
aOther->m_absorbed_by = this;
}
void CONNECTION_SUBGRAPH::AddItem( SCH_ITEM* aItem )
{
m_items.push_back( aItem );
if( aItem->Connection( &m_sheet )->IsDriver() )
m_drivers.push_back( aItem );
if( aItem->Type() == SCH_SHEET_PIN_T )
m_hier_pins.push_back( static_cast<SCH_SHEET_PIN*>( aItem ) );
else if( aItem->Type() == SCH_HIER_LABEL_T )
m_hier_ports.push_back( static_cast<SCH_HIERLABEL*>( 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<SCH_PIN*>( aDriver );
if( sch_pin->IsPowerConnection() )
return PRIORITY::POWER_PIN;
else
return PRIORITY::PIN;
}
default: return PRIORITY::NONE;
}
}
bool CONNECTION_GRAPH::m_allowRealTime = true;
void CONNECTION_GRAPH::Reset()
{
for( auto& subgraph : m_subgraphs )
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<void( SCH_ITEM* )>* aChangedItemHandler )
{
PROF_TIMER recalc_time( "CONNECTION_GRAPH::Recalculate" );
if( aUnconditional )
Reset();
PROF_TIMER update_items( "updateItemConnectivity" );
m_sheetList = aSheetList;
for( const SCH_SHEET_PATH& sheet : aSheetList )
{
std::vector<SCH_ITEM*> items;
// Store current unit value, to regenerate it after calculations
// (useful in complex hierarchies)
std::vector<std::pair<SCH_SYMBOL*, int>> symbolsChanged;
for( SCH_ITEM* item : sheet.LastScreen()->Items() )
{
if( item->IsConnectable() && ( aUnconditional || item->IsConnectivityDirty() ) )
items.push_back( 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<SCH_SYMBOL*>( 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 );
}
}
if( wxLog::IsAllowedTraceMask( ConnProfileMask ) )
update_items.Show();
PROF_TIMER build_graph( "buildConnectionGraph" );
buildConnectionGraph( aChangedItemHandler );
if( wxLog::IsAllowedTraceMask( ConnProfileMask ) )
build_graph.Show();
recalc_time.Stop();
if( wxLog::IsAllowedTraceMask( ConnProfileMask ) )
recalc_time.Show();
#ifndef DEBUG
// Pressure relief valve for release builds
const double max_recalc_time_msecs = 250.;
if( m_allowRealTime && ADVANCED_CFG::GetCfg().m_RealTimeConnectivity &&
recalc_time.msecs() > max_recalc_time_msecs )
{
m_allowRealTime = false;
}
#endif
}
void CONNECTION_GRAPH::updateItemConnectivity( const SCH_SHEET_PATH& aSheet,
const std::vector<SCH_ITEM*>& aItemList )
{
std::map<VECTOR2I, std::vector<SCH_ITEM*>> connection_map;
for( SCH_ITEM* item : aItemList )
{
std::vector<VECTOR2I> points = item->GetConnectionPoints();
item->ConnectedItems( aSheet ).clear();
if( item->Type() == SCH_SHEET_T )
{
for( SCH_SHEET_PIN* pin : static_cast<SCH_SHEET*>( 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<SCH_SYMBOL*>( 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<SCH_BUS_BUS_ENTRY*>( item )->m_connected_bus_items[0] = nullptr;
static_cast<SCH_BUS_BUS_ENTRY*>( 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<SCH_BUS_WIRE_ENTRY*>( item )->m_connected_bus_item = nullptr;
break;
default:
break;
}
for( const VECTOR2I& point : points )
connection_map[ point ].push_back( item );
}
item->SetConnectivityDirty( false );
}
for( const auto& it : connection_map )
{
std::vector<SCH_ITEM*> 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<SCH_BUS_WIRE_ENTRY*>( 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<SCH_BUS_BUS_ENTRY*>( 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<std::mutex> 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<SCH_BUS_WIRE_ENTRY*>( 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<SCH_BUS_WIRE_ENTRY*>( 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;
};
GetKiCadThreadPool().parallelize_loop( 0, connection_vec.size(),
[&]( const int a, const int b)
{
for( int ii = a; ii < b; ++ii )
update_lambda( connection_vec[ii] );
}).wait();
}
}
void CONNECTION_GRAPH::buildItemSubGraphs()
{
// Recache all bus aliases for later use
wxCHECK_RET( m_schematic, "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<BUS_ALIAS>& 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<SCH_ITEM*> 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<CONNECTION_SUBGRAPH*> 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<std::future<size_t>> 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<SCH_PIN*>( 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;
};
GetKiCadThreadPool().parallelize_loop( 0, dirty_graphs.size(),
[&]( const int a, const int b)
{
for( int ii = a; ii < b; ++ii )
update_lambda( dirty_graphs[ii] );
}).wait();
// 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<SCH_PIN*>( driver );
wxASSERT( pin->IsPowerConnection() );
m_global_label_cache[name].push_back( subgraph );
break;
}
default:
{
UNITS_PROVIDER unitsProvider( schIUScale, EDA_UNITS::MILLIMETRES );
wxLogTrace( ConnTrace, "Unexpected strong driver %s",
driver->GetSelectMenuText( &unitsProvider ) );
break;
}
}
}
}
}
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<int, CONNECTION_SUBGRAPH*> 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<CONNECTION_SUBGRAPH*> 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<CONNECTION_SUBGRAPH*>* 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, "%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 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<CONNECTION_SUBGRAPH*>& candidates = kk->second;
for( const CONNECTION_SUBGRAPH* candidate : candidates )
{
if( candidate->m_sheet == sheet )
conflict = true;
}
}
if( conflict )
{
wxLogTrace( ConnTrace,
"%ld (%s) skipped for promotion due to potential conflict",
subgraph->m_code, name );
}
else
{
UNITS_PROVIDER unitsProvider( schIUScale, EDA_UNITS::MILLIMETRES );
wxLogTrace( ConnTrace,
"%ld (%s) weakly driven by unique sheet pin %s, promoting",
subgraph->m_code, name,
subgraph->m_driver->GetSelectMenuText( &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<CONNECTION_SUBGRAPH*> 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<SCH_CONNECTION> > connections_to_check;
// Also check the main driving connection
connections_to_check.push_back( std::make_shared<SCH_CONNECTION>( *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,
"%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 );
for( unsigned i = 0; i < connections_to_check.size(); i++ )
{
auto member = connections_to_check[i];
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 )
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<SCH_PIN*>( 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, "%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, "%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;
subgraph->ResolveDrivers();
if( subgraph->m_driver_connection->IsBus() )
assignNetCodesToBus( subgraph->m_driver_connection );
else
assignNewNetCode( *subgraph->m_driver_connection );
wxLogTrace( ConnTrace, "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<void( SCH_ITEM* )>* 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<BUS_ALIAS>& alias : all_sheets[i].LastScreen()->GetBusAliases() )
m_bus_alias_cache[ alias->GetName() ] = alias;
}
PROF_TIMER sub_graph( "buildItemSubGraphs" );
buildItemSubGraphs();
if( wxLog::IsAllowedTraceMask( ConnProfileMask ) )
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();
PROF_TIMER proc_sub_graph( "ProcessSubGraphs" );
processSubGraphs();
if( wxLog::IsAllowedTraceMask( ConnProfileMask ) )
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<CONNECTION_SUBGRAPH*> 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 );
GetKiCadThreadPool().parallelize_loop( 0, m_driver_subgraphs.size(),
[&]( const int a, const int b)
{
for( int ii = a; ii < b; ++ii )
m_driver_subgraphs[ii]->UpdateItemConnections();
}).wait();
// 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, "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;
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, "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;
}
}
}
}
// This call will handle descending the hierarchy and updating child subgraphs
propagateToNeighbors( subgraph );
}
// 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, "Subgraph not processed by propagateToNeighbors!" );
if( subgraph->m_bus_parents.size() < 2 )
continue;
SCH_CONNECTION* conn = subgraph->m_driver_connection;
wxLogTrace( ConnTrace, "%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, "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, "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<SCH_PIN*>( 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->Type() == SCH_SHEET_PIN_T )
{
SCH_SHEET_PIN* pin = static_cast<SCH_SHEET_PIN*>( 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<SCH_HIERLABEL*>( 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;
};
GetKiCadThreadPool().parallelize_loop( 0, m_driver_subgraphs.size(),
[&]( const int a, const int b)
{
for( int ii = a; ii < b; ++ii )
updateItemConnectionsTask( m_driver_subgraphs[ii] );
}).wait();
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<NET_SETTINGS>& netSettings = m_schematic->Prj().GetProjectFile().m_NetSettings;
std::map<wxString, wxString> oldAssignments = netSettings->m_NetClassLabelAssignments;
netSettings->m_NetClassLabelAssignments.clear();
auto dirtySubgraphs =
[&]( const std::vector<CONNECTION_SUBGRAPH*>& subgraphs )
{
if( aChangedItemHandler )
{
for( const CONNECTION_SUBGRAPH* subgraph : subgraphs )
{
for( SCH_ITEM* item : subgraph->m_items )
(*aChangedItemHandler)( item );
}
}
};
auto checkNetclassDrivers =
[&]( const std::vector<CONNECTION_SUBGRAPH*>& subgraphs )
{
const CONNECTION_SUBGRAPH* driverSubgraph;
wxString netclass;
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;
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::assignNewNetCode( SCH_CONNECTION& aConnection )
{
int code;
auto it = m_net_name_to_code_map.find( aConnection.Name() );
if( it == m_net_name_to_code_map.end() )
{
code = m_last_net_code++;
m_net_name_to_code_map[ aConnection.Name() ] = code;
}
else
{
code = it->second;
}
aConnection.SetNetCode( code );
return code;
}
void CONNECTION_GRAPH::assignNetCodesToBus( SCH_CONNECTION* aConnection )
{
std::vector< std::shared_ptr<SCH_CONNECTION>>& connections_to_check( aConnection->Members() );
for( unsigned i = 0; i < connections_to_check.size(); i++ )
{
const std::shared_ptr<SCH_CONNECTION>& 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 )
{
SCH_CONNECTION* conn = aSubgraph->m_driver_connection;
std::vector<CONNECTION_SUBGRAPH*> search_list;
std::unordered_set<CONNECTION_SUBGRAPH*> visited;
std::vector<SCH_CONNECTION*> 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, "%lu: found child %lu (%s)", aParent->m_code,
candidate->m_code, candidate->m_driver_connection->Name() );
candidate->m_hier_parent = aParent;
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, "%lu: found additional parent %lu (%s)",
aParent->m_code, candidate->m_code,
candidate->m_driver_connection->Name() );
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, "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, "%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.push_back( 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 );
}
}
}
};
// 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( !aSubgraph->m_hier_ports.empty() && !aSubgraph->m_hier_pins.empty() )
{
wxLogTrace( ConnTrace, "%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, "%lu (%s) has no hier pins or ports; marking clean",
aSubgraph->m_code, conn->Name() );
aSubgraph->m_dirty = false;
return;
}
visited.insert( aSubgraph );
wxLogTrace( ConnTrace, "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];
visited.insert( child );
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, "%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() )
{
for( SCH_CONNECTION* stale_member : stale_bus_members )
{
for( CONNECTION_SUBGRAPH* subgraph : visited )
{
SCH_CONNECTION* member = matchBusMember( subgraph->m_driver_connection,
stale_member );
if( !member )
{
wxLogTrace( ConnTrace, "WARNING: failed to match stale member %s in %s.",
stale_member->Name(), subgraph->m_driver_connection->Name() );
continue;
}
wxLogTrace( ConnTrace, "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<SCH_CONNECTION> CONNECTION_GRAPH::getDefaultConnection( SCH_ITEM* aItem,
CONNECTION_SUBGRAPH* aSubgraph )
{
std::shared_ptr<SCH_CONNECTION> c = std::shared_ptr<SCH_CONNECTION>( nullptr );
switch( aItem->Type() )
{
case SCH_PIN_T:
{
SCH_PIN* pin = static_cast<SCH_PIN*>( aItem );
if( pin->IsPowerConnection() )
c = std::make_shared<SCH_CONNECTION>( aItem, aSubgraph->m_sheet );
break;
}
case SCH_GLOBAL_LABEL_T:
case SCH_HIER_LABEL_T:
case SCH_LABEL_T:
{
c = std::make_shared<SCH_CONNECTION>( 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<SCH_CONNECTION>& bus_member : aBusConnection->Members() )
{
if( bus_member->VectorIndex() == aSearch->VectorIndex() )
{
match = bus_member.get();
break;
}
}
}
else
{
// Group bus
for( const std::shared_ptr<SCH_CONNECTION>& 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<SCH_CONNECTION>& 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<CONNECTION_SUBGRAPH*>& vec = it->second;
// alg::delete_matching( vec, aSubgraph );
// }
//
// wxLogTrace( ConnTrace, "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<BUS_ALIAS> 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<const CONNECTION_SUBGRAPH*> CONNECTION_GRAPH::GetBusesNeedingMigration()
{
std::vector<const CONNECTION_SUBGRAPH*> 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->GetBusLabels();
if( labels.size() > 1 )
{
bool different = false;
wxString first = static_cast<SCH_TEXT*>( labels.at( 0 ) )->GetShownText();
for( unsigned i = 1; i < labels.size(); ++i )
{
if( static_cast<SCH_TEXT*>( labels.at( i ) )->GetShownText() != first )
{
different = true;
break;
}
}
if( !different )
continue;
wxLogTrace( ConnTrace, "SG %ld (%s) has multiple bus labels", subgraph->m_code,
connection->Name() );
ret.push_back( subgraph );
}
}
return ret;
}
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, "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<SCH_ITEM*> 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 );
/*
* This was changed late in 6.0 to fix https://gitlab.com/kicad/code/kicad/-/issues/9367
* so I'm going to leave the original code in for just a little while. If anyone comes
* across this in 7.0 development (or later), feel free to delete.
*/
#if 0
if( aSubgraph->m_second_driver )
{
SCH_ITEM* primary = aSubgraph->m_first_driver;
SCH_ITEM* secondary = aSubgraph->m_second_driver;
wxPoint pos = primary->Type() == SCH_PIN_T ?
static_cast<SCH_PIN*>( primary )->GetTransformedPosition() :
primary->GetPosition();
wxString primaryName = aSubgraph->GetNameForDriver( primary );
wxString secondaryName = aSubgraph->GetNameForDriver( secondary );
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<ERC_ITEM> ercItem = ERC_ITEM::Create( ERCE_DRIVER_CONFLICT );
ercItem->SetItems( primary, secondary );
ercItem->SetErrorMessage( msg );
SCH_MARKER* marker = new SCH_MARKER( ercItem, pos );
aSubgraph->m_sheet.LastScreen()->Append( marker );
return false;
}
#else
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<SCH_PIN*>( driver )->IsPowerConnection() ) )
{
wxString primaryName = aSubgraph->GetNameForDriver( aSubgraph->m_driver );
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<ERC_ITEM> 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;
}
}
}
#endif
return true;
}
bool CONNECTION_GRAPH::ercCheckNetclassConflicts( const std::vector<CONNECTION_SUBGRAPH*>& 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<ERC_ITEM> 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<SCH_TEXT*>( item );
conn.ConfigureFromLabel( EscapeString( text->GetShownText(), 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<ERC_ITEM> 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<ERC_ITEM> 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<SCH_BUS_WIRE_ENTRY*>( 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<wxString> 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<ERC_ITEM> 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;
if( aSubgraph->m_no_connect != nullptr )
{
SCH_PIN* pin = nullptr;
std::set<SCH_ITEM*> unique_items;
// Any subgraph that contains both a pin and a no-connect should not
// contain any other driving items.
for( SCH_ITEM* item : aSubgraph->m_items )
{
switch( item->Type() )
{
case SCH_PIN_T:
{
pin = static_cast<SCH_PIN*>( item );
// Insert the pin's parent so that we don't flag stacked pins
if( auto [existing, success] = unique_items.insert(
static_cast<SCH_ITEM*>( pin->GetParent() ) ); !success )
{
SCH_PIN* ex_pin = static_cast<SCH_PIN*>( *existing );
// Stacked pins don't count as connected
// but if they are not stacked, but still in the same symbol
// flag this for an error
if( !pin->IsStacked( ex_pin ) )
unique_items.insert( ex_pin );
}
break;
}
case SCH_LINE_T:
case SCH_JUNCTION_T:
case SCH_NO_CONNECT_T:
break;
default:
unique_items.insert( item );
}
}
if( unique_items.size() > 1 && pin && settings.IsTestEnabled( ERCE_NOCONNECT_CONNECTED ) )
{
std::shared_ptr<ERC_ITEM> ercItem = ERC_ITEM::Create( ERCE_NOCONNECT_CONNECTED );
ercItem->SetItems( pin );
SCH_MARKER* marker = new SCH_MARKER( ercItem, pin->GetTransformedPosition() );
screen->Append( marker );
ok = false;
}
if( unique_items.empty() && settings.IsTestEnabled( ERCE_NOCONNECT_NOT_CONNECTED ) )
{
std::shared_ptr<ERC_ITEM> 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<SCH_PIN*> 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* pin = static_cast<SCH_PIN*>( item );
for( SCH_PIN* other_pin : pins )
{
if( other_pin->GetParent() != pin->GetParent()
|| other_pin->GetPosition() != pin->GetPosition() )
{
has_other_connections = true;
break;
}
}
}
pins.emplace_back( static_cast<SCH_PIN*>( 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
SCH_PIN* pin = pins.empty() ? nullptr : pins[0];
// 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<ERC_ITEM> 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<ERC_ITEM> 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<SCH_ITEM*> 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<ERC_ITEM> 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;
std::map<KICAD_T, std::vector<SCH_TEXT*>> label_map;
auto hasPins =
[]( const CONNECTION_SUBGRAPH* aLocSubgraph ) -> int
{
int retval = 0;
for( const SCH_ITEM* item : aLocSubgraph->m_items )
{
switch( item->Type() )
{
case SCH_PIN_T:
++retval;
break;
default: break;
}
}
return retval;
};
auto reportError = [&]( SCH_TEXT* aText, int errCode )
{
if( settings.IsTestEnabled( errCode ) )
{
std::shared_ptr<ERC_ITEM> 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<SCH_TEXT*>( 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;
}
// If this subgraph has a no-connect, do not continue processing as we do not
// submit no-connect errors for nets explicitly designated as no-connect
case SCH_NO_CONNECT_T:
return true;
default:
break;
}
}
if( label_map.empty() )
return true;
// 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
wxString netName = aSubgraph->GetNetName();
for( auto it = m_net_name_to_subgraphs_map.begin(); it != m_net_name_to_subgraphs_map.end(); ++it )
{
for( CONNECTION_SUBGRAPH* graph : it->second )
{
if( graph == aSubgraph )
{
netName = it->first;
}
}
}
wxCHECK_MSG( m_schematic, true, "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;
allPins += hasPins( neighbor );
}
}
if( allPins < 2 )
{
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<SCH_SHEET*>( item );
std::map<wxString, SCH_SHEET_PIN*> pins;
std::map<wxString, SCH_HIERLABEL*> 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<ERC_ITEM> 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<wxString> matchedPins;
for( SCH_ITEM* subItem : parentSheet->GetScreen()->Items() )
{
if( subItem->Type() == SCH_HIER_LABEL_T )
{
SCH_HIERLABEL* label = static_cast<SCH_HIERLABEL*>( 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<const wxString, SCH_SHEET_PIN*>& unmatched : pins )
{
wxString msg = wxString::Format( _( "Sheet pin %s has no matching hierarchical "
"label inside the sheet" ),
UnescapeString( unmatched.first ) );
std::shared_ptr<ERC_ITEM> ercItem = ERC_ITEM::Create( ERCE_HIERACHICAL_LABEL );
ercItem->SetItems( unmatched.second );
ercItem->SetErrorMessage( msg );
ercItem->SetIsSheetSpecific();
SCH_MARKER* marker = new SCH_MARKER( ercItem, unmatched.second->GetPosition() );
sheet.LastScreen()->Append( marker );
errors++;
}
for( const std::pair<const wxString, SCH_HIERLABEL*>& unmatched : labels )
{
wxString msg = wxString::Format( _( "Hierarchical label %s has no matching "
"sheet pin in the parent sheet" ),
UnescapeString( unmatched.first ) );
std::shared_ptr<ERC_ITEM> ercItem = ERC_ITEM::Create( ERCE_HIERACHICAL_LABEL );
ercItem->SetItems( unmatched.second );
ercItem->SetErrorMessage( msg );
ercItem->SetIsSheetSpecific();
SCH_MARKER* marker = new SCH_MARKER( ercItem, unmatched.second->GetPosition() );
parentSheet->GetScreen()->Append( marker );
errors++;
}
}
}
}
return errors;
}
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