kicad/pcbnew/board.cpp

3104 lines
86 KiB
C++

/*
* This program source code file is part of KiCad, a free EDA CAD application.
*
* Copyright (C) 2018 Jean-Pierre Charras, jp.charras at wanadoo.fr
* Copyright (C) 2012 SoftPLC Corporation, Dick Hollenbeck <dick@softplc.com>
* Copyright (C) 2011 Wayne Stambaugh <stambaughw@gmail.com>
*
* Copyright (C) 1992-2024 KiCad Developers, see AUTHORS.txt for contributors.
*
* This program is free software; you can redistribute it and/or
* modify it under the terms of the GNU General Public License
* as published by the Free Software Foundation; either version 2
* of the License, or (at your option) any later version.
*
* This program is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
* GNU General Public License for more details.
*
* You should have received a copy of the GNU General Public License
* along with this program; if not, you may find one here:
* http://www.gnu.org/licenses/old-licenses/gpl-2.0.html
* or you may search the http://www.gnu.org website for the version 2 license,
* or you may write to the Free Software Foundation, Inc.,
* 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301, USA
*/
#include <iterator>
#include <wx/log.h>
#include <drc/drc_rtree.h>
#include <board_design_settings.h>
#include <board_commit.h>
#include <board.h>
#include <core/arraydim.h>
#include <core/kicad_algo.h>
#include <connectivity/connectivity_data.h>
#include <convert_shape_list_to_polygon.h>
#include <footprint.h>
#include <font/outline_font.h>
#include <lset.h>
#include <pcb_base_frame.h>
#include <pcb_track.h>
#include <pcb_marker.h>
#include <pcb_group.h>
#include <pcb_generator.h>
#include <pcb_target.h>
#include <pcb_shape.h>
#include <pcb_text.h>
#include <pcb_textbox.h>
#include <pcb_table.h>
#include <pcb_dimension.h>
#include <pgm_base.h>
#include <pcbnew_settings.h>
#include <progress_reporter.h>
#include <project.h>
#include <project/net_settings.h>
#include <project/project_file.h>
#include <project/project_local_settings.h>
#include <ratsnest/ratsnest_data.h>
#include <reporter.h>
#include <tool/tool_manager.h>
#include <tool/selection_conditions.h>
#include <string_utils.h>
#include <core/thread_pool.h>
#include <zone.h>
#include <mutex>
// This is an odd place for this, but CvPcb won't link if it's in board_item.cpp like I first
// tried it.
VECTOR2I BOARD_ITEM::ZeroOffset( 0, 0 );
BOARD::BOARD() :
BOARD_ITEM_CONTAINER( (BOARD_ITEM*) nullptr, PCB_T ),
m_LegacyDesignSettingsLoaded( false ),
m_LegacyCopperEdgeClearanceLoaded( false ),
m_LegacyNetclassesLoaded( false ),
m_boardUse( BOARD_USE::NORMAL ),
m_timeStamp( 1 ),
m_paper( PAGE_INFO::A4 ),
m_project( nullptr ),
m_userUnits( EDA_UNITS::MILLIMETRES ),
m_designSettings( new BOARD_DESIGN_SETTINGS( nullptr, "board.design_settings" ) ),
m_NetInfo( this ),
m_embedFonts( false )
{
// A too small value do not allow connecting 2 shapes (i.e. segments) not exactly connected
// A too large value do not allow safely connecting 2 shapes like very short segments.
m_outlinesChainingEpsilon = pcbIUScale.mmToIU( DEFAULT_CHAINING_EPSILON_MM );
m_DRCMaxClearance = 0;
m_DRCMaxPhysicalClearance = 0;
// we have not loaded a board yet, assume latest until then.
m_fileFormatVersionAtLoad = LEGACY_BOARD_FILE_VERSION;
for( int layer = 0; layer < PCB_LAYER_ID_COUNT; ++layer )
{
m_layers[layer].m_name = GetStandardLayerName( ToLAYER_ID( layer ) );
if( IsCopperLayer( layer ) )
m_layers[layer].m_type = LT_SIGNAL;
else if( layer >= User_1 && layer <= User_9 )
m_layers[layer].m_type = LT_AUX;
else
m_layers[layer].m_type = LT_UNDEFINED;
}
recalcOpposites();
// Creates a zone to show sloder mask bridges created by a min web value
// it it just to show them
m_SolderMaskBridges = new ZONE( this );
m_SolderMaskBridges->SetHatchStyle( ZONE_BORDER_DISPLAY_STYLE::INVISIBLE_BORDER );
m_SolderMaskBridges->SetLayerSet( LSET().set( F_Mask ).set( B_Mask ) );
int infinity = ( std::numeric_limits<int>::max() / 2 ) - pcbIUScale.mmToIU( 1 );
m_SolderMaskBridges->Outline()->NewOutline();
m_SolderMaskBridges->Outline()->Append( VECTOR2I( -infinity, -infinity ) );
m_SolderMaskBridges->Outline()->Append( VECTOR2I( -infinity, +infinity ) );
m_SolderMaskBridges->Outline()->Append( VECTOR2I( +infinity, +infinity ) );
m_SolderMaskBridges->Outline()->Append( VECTOR2I( +infinity, -infinity ) );
m_SolderMaskBridges->SetMinThickness( 0 );
BOARD_DESIGN_SETTINGS& bds = GetDesignSettings();
// Initialize default netclass.
bds.m_NetSettings->SetDefaultNetclass( std::make_shared<NETCLASS>( NETCLASS::Default ) );
bds.m_NetSettings->GetDefaultNetclass()->SetDescription(
_( "This is the default net class." ) );
bds.UseCustomTrackViaSize( false );
// Initialize ratsnest
m_connectivity.reset( new CONNECTIVITY_DATA() );
// Set flag bits on these that will only be cleared if these are loaded from a legacy file
m_LegacyVisibleLayers.reset().set( Rescue );
m_LegacyVisibleItems.reset().set( GAL_LAYER_INDEX( GAL_LAYER_ID_BITMASK_END ) );
}
BOARD::~BOARD()
{
// Untangle group parents before doing any deleting
for( PCB_GROUP* group : m_groups )
{
for( BOARD_ITEM* item : group->GetItems() )
item->SetParentGroup( nullptr );
}
for( PCB_GENERATOR* generator : m_generators )
{
for( BOARD_ITEM* item : generator->GetItems() )
item->SetParentGroup( nullptr );
}
m_itemByIdCache.clear();
// Clean up the owned elements
DeleteMARKERs();
delete m_SolderMaskBridges;
BOARD_ITEM_SET ownedItems = GetItemSet();
m_zones.clear();
m_footprints.clear();
m_tracks.clear();
m_drawings.clear();
m_groups.clear();
// Generators not currently returned by GetItemSet
for( PCB_GENERATOR* g : m_generators )
ownedItems.insert( g );
m_generators.clear();
// Delete the owned items after clearing the containers, because some item dtors
// cause call chains that query the containers
for( BOARD_ITEM* item : ownedItems )
delete item;
}
bool BOARD::BuildConnectivity( PROGRESS_REPORTER* aReporter )
{
if( !GetConnectivity()->Build( this, aReporter ) )
return false;
UpdateRatsnestExclusions();
return true;
}
void BOARD::SetProject( PROJECT* aProject, bool aReferenceOnly )
{
if( m_project )
ClearProject();
m_project = aProject;
if( aProject && !aReferenceOnly )
{
PROJECT_FILE& project = aProject->GetProjectFile();
// Link the design settings object to the project file
project.m_BoardSettings = &GetDesignSettings();
// Set parent, which also will load the values from JSON stored in the project if we don't
// have legacy design settings loaded already
project.m_BoardSettings->SetParent( &project, !m_LegacyDesignSettingsLoaded );
// The DesignSettings' netclasses pointer will be pointing to its internal netclasses
// list at this point. If we loaded anything into it from a legacy board file then we
// want to transfer it over to the project netclasses list.
if( m_LegacyNetclassesLoaded )
{
std::shared_ptr<NET_SETTINGS> legacySettings = GetDesignSettings().m_NetSettings;
std::shared_ptr<NET_SETTINGS>& projectSettings = project.NetSettings();
projectSettings->SetDefaultNetclass( legacySettings->GetDefaultNetclass() );
projectSettings->SetNetclasses( legacySettings->GetNetclasses() );
projectSettings->SetNetclassPatternAssignments(
std::move( legacySettings->GetNetclassPatternAssignments() ) );
}
// Now update the DesignSettings' netclass pointer to point into the project.
GetDesignSettings().m_NetSettings = project.NetSettings();
}
}
void BOARD::ClearProject()
{
if( !m_project )
return;
PROJECT_FILE& project = m_project->GetProjectFile();
// Owned by the BOARD
if( project.m_BoardSettings )
{
project.ReleaseNestedSettings( project.m_BoardSettings );
project.m_BoardSettings = nullptr;
}
GetDesignSettings().m_NetSettings = nullptr;
GetDesignSettings().SetParent( nullptr );
m_project = nullptr;
}
void BOARD::IncrementTimeStamp()
{
m_timeStamp++;
if( !m_IntersectsAreaCache.empty()
|| !m_EnclosedByAreaCache.empty()
|| !m_IntersectsCourtyardCache.empty()
|| !m_IntersectsFCourtyardCache.empty()
|| !m_IntersectsBCourtyardCache.empty()
|| !m_LayerExpressionCache.empty()
|| !m_ZoneBBoxCache.empty()
|| m_CopperItemRTreeCache
|| m_maxClearanceValue.has_value() )
{
std::unique_lock<std::shared_mutex> writeLock( m_CachesMutex );
m_IntersectsAreaCache.clear();
m_EnclosedByAreaCache.clear();
m_IntersectsCourtyardCache.clear();
m_IntersectsFCourtyardCache.clear();
m_IntersectsBCourtyardCache.clear();
m_LayerExpressionCache.clear();
m_ZoneBBoxCache.clear();
m_CopperItemRTreeCache = nullptr;
// These are always regenerated before use, but still probably safer to clear them
// while we're here.
m_DRCMaxClearance = 0;
m_DRCMaxPhysicalClearance = 0;
m_DRCZones.clear();
m_DRCCopperZones.clear();
m_ZoneIsolatedIslandsMap.clear();
m_CopperZoneRTreeCache.clear();
m_maxClearanceValue.reset();
}
}
void BOARD::UpdateRatsnestExclusions()
{
std::set<std::pair<KIID, KIID>> m_ratsnestExclusions;
for( PCB_MARKER* marker : GetBoard()->Markers() )
{
if( marker->GetMarkerType() == MARKER_BASE::MARKER_RATSNEST && marker->IsExcluded() )
{
const std::shared_ptr<RC_ITEM>& rcItem = marker->GetRCItem();
m_ratsnestExclusions.emplace( rcItem->GetMainItemID(), rcItem->GetAuxItemID() );
m_ratsnestExclusions.emplace( rcItem->GetAuxItemID(), rcItem->GetMainItemID() );
}
}
GetConnectivity()->RunOnUnconnectedEdges(
[&]( CN_EDGE& aEdge )
{
if( aEdge.GetSourceNode() && aEdge.GetTargetNode()
&& !aEdge.GetSourceNode()->Dirty() && !aEdge.GetTargetNode()->Dirty() )
{
std::pair<KIID, KIID> ids = { aEdge.GetSourceNode()->Parent()->m_Uuid,
aEdge.GetTargetNode()->Parent()->m_Uuid };
aEdge.SetVisible( m_ratsnestExclusions.count( ids ) == 0 );
}
return true;
} );
}
void BOARD::RecordDRCExclusions()
{
m_designSettings->m_DrcExclusions.clear();
m_designSettings->m_DrcExclusionComments.clear();
for( PCB_MARKER* marker : m_markers )
{
if( marker->IsExcluded() )
{
wxString serialized = marker->SerializeToString();
m_designSettings->m_DrcExclusions.insert( serialized );
m_designSettings->m_DrcExclusionComments[ serialized ] = marker->GetComment();
}
}
}
std::vector<PCB_MARKER*> BOARD::ResolveDRCExclusions( bool aCreateMarkers )
{
std::set<wxString> exclusions = m_designSettings->m_DrcExclusions;
std::map<wxString, wxString> comments = m_designSettings->m_DrcExclusionComments;
m_designSettings->m_DrcExclusions.clear();
m_designSettings->m_DrcExclusionComments.clear();
for( PCB_MARKER* marker : GetBoard()->Markers() )
{
wxString serialized = marker->SerializeToString();
std::set<wxString>::iterator it = exclusions.find( serialized );
if( it != exclusions.end() )
{
marker->SetExcluded( true, comments[ serialized ] );
// Exclusion still valid; store back to BOARD_DESIGN_SETTINGS
m_designSettings->m_DrcExclusions.insert( serialized );
m_designSettings->m_DrcExclusionComments[ serialized ] = comments[ serialized ];
exclusions.erase( it );
}
}
std::vector<PCB_MARKER*> newMarkers;
if( aCreateMarkers )
{
for( const wxString& serialized : exclusions )
{
PCB_MARKER* marker = PCB_MARKER::DeserializeFromString( serialized );
if( !marker )
continue;
// Check to see if items still exist
for( const KIID& guid : marker->GetRCItem()->GetIDs() )
{
if( GetItem( guid ) == DELETED_BOARD_ITEM::GetInstance() )
{
delete marker;
marker = nullptr;
break;
}
}
if( marker )
{
marker->SetExcluded( true, comments[ serialized ] );
newMarkers.push_back( marker );
// Exclusion still valid; store back to BOARD_DESIGN_SETTINGS
m_designSettings->m_DrcExclusions.insert( serialized );
m_designSettings->m_DrcExclusionComments[ serialized ] = comments[ serialized ];
}
}
}
return newMarkers;
}
void BOARD::GetContextualTextVars( wxArrayString* aVars ) const
{
auto add =
[&]( const wxString& aVar )
{
if( !alg::contains( *aVars, aVar ) )
aVars->push_back( aVar );
};
add( wxT( "LAYER" ) );
add( wxT( "FILENAME" ) );
add( wxT( "FILEPATH" ) );
add( wxT( "PROJECTNAME" ) );
GetTitleBlock().GetContextualTextVars( aVars );
if( GetProject() )
{
for( std::pair<wxString, wxString> entry : GetProject()->GetTextVars() )
add( entry.first );
}
}
bool BOARD::ResolveTextVar( wxString* token, int aDepth ) const
{
if( token->Contains( ':' ) )
{
wxString remainder;
wxString ref = token->BeforeFirst( ':', &remainder );
BOARD_ITEM* refItem = GetItem( KIID( ref ) );
if( refItem && refItem->Type() == PCB_FOOTPRINT_T )
{
FOOTPRINT* refFP = static_cast<FOOTPRINT*>( refItem );
if( refFP->ResolveTextVar( &remainder, aDepth + 1 ) )
{
*token = remainder;
return true;
}
}
}
if( token->IsSameAs( wxT( "FILENAME" ) ) )
{
wxFileName fn( GetFileName() );
*token = fn.GetFullName();
return true;
}
else if( token->IsSameAs( wxT( "FILEPATH" ) ) )
{
wxFileName fn( GetFileName() );
*token = fn.GetFullPath();
return true;
}
else if( token->IsSameAs( wxT( "PROJECTNAME" ) ) && GetProject() )
{
*token = GetProject()->GetProjectName();
return true;
}
wxString var = *token;
if( m_properties.count( var ) )
{
*token = m_properties.at( var );
return true;
}
else if( GetTitleBlock().TextVarResolver( token, m_project ) )
{
return true;
}
if( GetProject() && GetProject()->TextVarResolver( token ) )
return true;
return false;
}
VECTOR2I BOARD::GetPosition() const
{
return ZeroOffset;
}
void BOARD::SetPosition( const VECTOR2I& aPos )
{
wxLogWarning( wxT( "This should not be called on the BOARD object") );
}
void BOARD::Move( const VECTOR2I& aMoveVector ) // overload
{
INSPECTOR_FUNC inspector =
[&] ( EDA_ITEM* item, void* testData )
{
if( item->IsBOARD_ITEM() )
{
BOARD_ITEM* board_item = static_cast<BOARD_ITEM*>( item );
// aMoveVector was snapshotted, don't need "data".
// Only move the top level group
if( !board_item->GetParentGroup() && !board_item->GetParentFootprint() )
board_item->Move( aMoveVector );
}
return INSPECT_RESULT::CONTINUE;
};
Visit( inspector, nullptr, GENERAL_COLLECTOR::BoardLevelItems );
}
TRACKS BOARD::TracksInNet( int aNetCode )
{
TRACKS ret;
INSPECTOR_FUNC inspector = [aNetCode, &ret]( EDA_ITEM* item, void* testData )
{
PCB_TRACK* t = static_cast<PCB_TRACK*>( item );
if( t->GetNetCode() == aNetCode )
ret.push_back( t );
return INSPECT_RESULT::CONTINUE;
};
// visit this BOARD's PCB_TRACKs and PCB_VIAs with above TRACK INSPECTOR which
// appends all in aNetCode to ret.
Visit( inspector, nullptr, GENERAL_COLLECTOR::Tracks );
return ret;
}
bool BOARD::SetLayerDescr( PCB_LAYER_ID aIndex, const LAYER& aLayer )
{
if( unsigned( aIndex ) < arrayDim( m_layers ) )
{
m_layers[ aIndex ] = aLayer;
recalcOpposites();
return true;
}
return false;
}
PCB_LAYER_ID BOARD::GetLayerID( const wxString& aLayerName ) const
{
// Check the BOARD physical layer names.
for( int layer = 0; layer < PCB_LAYER_ID_COUNT; ++layer )
{
if ( m_layers[ layer ].m_name == aLayerName || m_layers[ layer ].m_userName == aLayerName )
return ToLAYER_ID( layer );
}
// Otherwise fall back to the system standard layer names for virtual layers.
for( int layer = 0; layer < PCB_LAYER_ID_COUNT; ++layer )
{
if( GetStandardLayerName( ToLAYER_ID( layer ) ) == aLayerName )
return ToLAYER_ID( layer );
}
return UNDEFINED_LAYER;
}
const wxString BOARD::GetLayerName( PCB_LAYER_ID aLayer ) const
{
// All layer names are stored in the BOARD.
if( IsLayerEnabled( aLayer ) )
{
// Standard names were set in BOARD::BOARD() but they may be over-ridden by
// BOARD::SetLayerName(). For copper layers, return the user defined layer name,
// if it was set. Otherwise return the Standard English layer name.
if( !m_layers[aLayer].m_userName.IsEmpty() )
return m_layers[aLayer].m_userName;
}
return GetStandardLayerName( aLayer );
}
bool BOARD::SetLayerName( PCB_LAYER_ID aLayer, const wxString& aLayerName )
{
if( !aLayerName.IsEmpty() )
{
// no quote chars in the name allowed
if( aLayerName.Find( wxChar( '"' ) ) != wxNOT_FOUND )
return false;
if( IsLayerEnabled( aLayer ) )
{
m_layers[aLayer].m_userName = aLayerName;
recalcOpposites();
return true;
}
}
return false;
}
LAYER_T BOARD::GetLayerType( PCB_LAYER_ID aLayer ) const
{
if( IsLayerEnabled( aLayer ) )
return m_layers[aLayer].m_type;
if( aLayer >= User_1 && aLayer <= User_9 )
return LT_AUX;
else if( IsCopperLayer( aLayer ) )
return LT_SIGNAL;
else
return LT_UNDEFINED;
}
bool BOARD::SetLayerType( PCB_LAYER_ID aLayer, LAYER_T aLayerType )
{
if( IsLayerEnabled( aLayer ) )
{
m_layers[aLayer].m_type = aLayerType;
recalcOpposites();
return true;
}
return false;
}
const char* LAYER::ShowType( LAYER_T aType )
{
switch( aType )
{
default:
case LT_SIGNAL: return "signal";
case LT_POWER: return "power";
case LT_MIXED: return "mixed";
case LT_JUMPER: return "jumper";
case LT_AUX: return "auxiliary";
case LT_FRONT: return "front";
case LT_BACK: return "back";
}
}
LAYER_T LAYER::ParseType( const char* aType )
{
if( strcmp( aType, "signal" ) == 0 ) return LT_SIGNAL;
else if( strcmp( aType, "power" ) == 0 ) return LT_POWER;
else if( strcmp( aType, "mixed" ) == 0 ) return LT_MIXED;
else if( strcmp( aType, "jumper" ) == 0 ) return LT_JUMPER;
else if( strcmp( aType, "auxiliary" ) == 0 ) return LT_AUX;
else if( strcmp( aType, "front" ) == 0 ) return LT_FRONT;
else if( strcmp( aType, "back" ) == 0 ) return LT_BACK;
else return LT_UNDEFINED;
}
void BOARD::recalcOpposites()
{
for( int layer = F_Cu; layer < User_9; ++layer )
m_layers[layer].m_opposite = ::FlipLayer( ToLAYER_ID( layer ), GetCopperLayerCount() );
// Match up similary-named front/back user layers
for( int layer = User_1; layer <= User_9; ++layer )
{
if( m_layers[layer].m_opposite != layer ) // already paired
continue;
if( m_layers[layer].m_type != LT_FRONT )
continue;
wxString principalName = m_layers[layer].m_userName.AfterFirst( '.' );
for( int ii = User_1; ii <= User_9; ++ii )
{
if( ii == layer ) // can't pair with self
continue;
if( m_layers[ii].m_opposite != ii ) // already paired
continue;
if( m_layers[ii].m_type != LT_BACK )
continue;
wxString candidate = m_layers[ii].m_userName.AfterFirst( '.' );
if( !candidate.IsEmpty() && candidate == principalName )
{
m_layers[layer].m_opposite = ii;
m_layers[ii].m_opposite = layer;
break;
}
}
}
// Match up non-custom-named consecutive front/back user layer pairs
for( int layer = User_1; layer < User_9; ++layer )
{
int next = layer + 1;
// ignore already-matched layers
if( m_layers[layer].m_opposite != layer || m_layers[next].m_opposite != next )
continue;
// ignore layer pairs that aren't consecutive front/back
if( m_layers[layer].m_type != LT_FRONT || m_layers[next].m_type != LT_BACK )
continue;
if( m_layers[layer].m_userName != m_layers[layer].m_name
&& m_layers[next].m_userName != m_layers[next].m_name )
{
m_layers[layer].m_opposite = next;
m_layers[next].m_opposite = layer;
}
}
}
PCB_LAYER_ID BOARD::FlipLayer( PCB_LAYER_ID aLayer ) const
{
return ToLAYER_ID( m_layers[aLayer].m_opposite );
}
int BOARD::GetCopperLayerCount() const
{
return GetDesignSettings().GetCopperLayerCount();
}
void BOARD::SetCopperLayerCount( int aCount )
{
GetDesignSettings().SetCopperLayerCount( aCount );
}
PCB_LAYER_ID BOARD::GetCopperLayerStackMaxId() const
{
int imax = GetCopperLayerCount();
// layers IDs are F_Cu, B_Cu, and even IDs values (imax values)
if( imax <= 2 ) // at least 2 layers are expected
return B_Cu;
// For a 4 layer, last ID is In2_Cu = 6 (IDs are 0, 2, 4, 6)
return static_cast<PCB_LAYER_ID>( (imax-1) * 2 );
}
int BOARD::LayerDepth( PCB_LAYER_ID aStartLayer, PCB_LAYER_ID aEndLayer ) const
{
if( aStartLayer > aEndLayer )
std::swap( aStartLayer, aEndLayer );
if( aEndLayer == B_Cu )
aEndLayer = ToLAYER_ID( F_Cu + GetCopperLayerCount() - 1 );
return aEndLayer - aStartLayer;
}
LSET BOARD::GetEnabledLayers() const
{
return GetDesignSettings().GetEnabledLayers();
}
bool BOARD::IsLayerVisible( PCB_LAYER_ID aLayer ) const
{
// If there is no project, assume layer is visible always
return GetDesignSettings().IsLayerEnabled( aLayer )
&& ( !m_project || m_project->GetLocalSettings().m_VisibleLayers[aLayer] );
}
LSET BOARD::GetVisibleLayers() const
{
return m_project ? m_project->GetLocalSettings().m_VisibleLayers : LSET::AllLayersMask();
}
void BOARD::SetEnabledLayers( LSET aLayerSet )
{
GetDesignSettings().SetEnabledLayers( aLayerSet );
}
bool BOARD::IsLayerEnabled( PCB_LAYER_ID aLayer ) const
{
return GetDesignSettings().IsLayerEnabled( aLayer );
}
void BOARD::SetVisibleLayers( LSET aLayerSet )
{
if( m_project )
m_project->GetLocalSettings().m_VisibleLayers = aLayerSet;
}
void BOARD::SetVisibleElements( const GAL_SET& aSet )
{
// Call SetElementVisibility for each item
// to ensure specific calculations that can be needed by some items,
// just changing the visibility flags could be not sufficient.
for( size_t i = 0; i < aSet.size(); i++ )
SetElementVisibility( GAL_LAYER_ID_START + static_cast<int>( i ), aSet[i] );
}
void BOARD::SetVisibleAlls()
{
SetVisibleLayers( LSET().set() );
// Call SetElementVisibility for each item,
// to ensure specific calculations that can be needed by some items
for( GAL_LAYER_ID ii = GAL_LAYER_ID_START; ii < GAL_LAYER_ID_BITMASK_END; ++ii )
SetElementVisibility( ii, true );
}
GAL_SET BOARD::GetVisibleElements() const
{
return m_project ? m_project->GetLocalSettings().m_VisibleItems : GAL_SET().set();
}
bool BOARD::IsElementVisible( GAL_LAYER_ID aLayer ) const
{
return !m_project || m_project->GetLocalSettings().m_VisibleItems[aLayer - GAL_LAYER_ID_START];
}
void BOARD::SetElementVisibility( GAL_LAYER_ID aLayer, bool isEnabled )
{
if( m_project )
m_project->GetLocalSettings().m_VisibleItems.set( aLayer - GAL_LAYER_ID_START, isEnabled );
switch( aLayer )
{
case LAYER_RATSNEST:
{
// because we have a tool to show/hide ratsnest relative to a pad or a footprint
// so the hide/show option is a per item selection
for( PCB_TRACK* track : Tracks() )
track->SetLocalRatsnestVisible( isEnabled );
for( FOOTPRINT* footprint : Footprints() )
{
for( PAD* pad : footprint->Pads() )
pad->SetLocalRatsnestVisible( isEnabled );
}
for( ZONE* zone : Zones() )
zone->SetLocalRatsnestVisible( isEnabled );
break;
}
default:
;
}
}
bool BOARD::IsFootprintLayerVisible( PCB_LAYER_ID aLayer ) const
{
switch( aLayer )
{
case F_Cu: return IsElementVisible( LAYER_FOOTPRINTS_FR );
case B_Cu: return IsElementVisible( LAYER_FOOTPRINTS_BK );
default: wxFAIL_MSG( wxT( "BOARD::IsModuleLayerVisible(): bad layer" ) ); return true;
}
}
BOARD_DESIGN_SETTINGS& BOARD::GetDesignSettings() const
{
return *m_designSettings;
}
int BOARD::GetMaxClearanceValue() const
{
if( !m_maxClearanceValue.has_value() )
{
std::unique_lock<std::shared_mutex> writeLock( m_CachesMutex );
int worstClearance = m_designSettings->GetBiggestClearanceValue();
for( ZONE* zone : m_zones )
worstClearance = std::max( worstClearance, zone->GetLocalClearance().value() );
for( FOOTPRINT* footprint : m_footprints )
{
for( PAD* pad : footprint->Pads() )
{
std::optional<int> override = pad->GetClearanceOverrides( nullptr );
if( override.has_value() )
worstClearance = std::max( worstClearance, override.value() );
}
for( ZONE* zone : footprint->Zones() )
worstClearance = std::max( worstClearance, zone->GetLocalClearance().value() );
}
m_maxClearanceValue = worstClearance;
}
return m_maxClearanceValue.value_or( 0 );
};
void BOARD::CacheTriangulation( PROGRESS_REPORTER* aReporter, const std::vector<ZONE*>& aZones )
{
std::vector<ZONE*> zones = aZones;
if( zones.empty() )
zones = m_zones;
if( zones.empty() )
return;
if( aReporter )
aReporter->Report( _( "Tessellating copper zones..." ) );
thread_pool& tp = GetKiCadThreadPool();
std::vector<std::future<size_t>> returns;
returns.reserve( zones.size() );
auto cache_zones = [aReporter]( ZONE* aZone ) -> size_t
{
if( aReporter && aReporter->IsCancelled() )
return 0;
aZone->CacheTriangulation();
if( aReporter )
aReporter->AdvanceProgress();
return 1;
};
for( ZONE* zone : zones )
returns.emplace_back( tp.submit( cache_zones, zone ) );
// Finalize the triangulation threads
for( const std::future<size_t>& ret : returns )
{
std::future_status status = ret.wait_for( std::chrono::milliseconds( 250 ) );
while( status != std::future_status::ready )
{
if( aReporter )
aReporter->KeepRefreshing();
status = ret.wait_for( std::chrono::milliseconds( 250 ) );
}
}
}
void BOARD::FixupEmbeddedData()
{
for( FOOTPRINT* footprint : m_footprints )
{
for( auto& [filename, embeddedFile] : footprint->EmbeddedFileMap() )
{
EMBEDDED_FILES::EMBEDDED_FILE* file = GetEmbeddedFile( filename );
if( file )
{
embeddedFile->compressedEncodedData = file->compressedEncodedData;
embeddedFile->decompressedData = file->decompressedData;
embeddedFile->data_hash = file->data_hash;
embeddedFile->is_valid = file->is_valid;
}
}
}
}
void BOARD::Add( BOARD_ITEM* aBoardItem, ADD_MODE aMode, bool aSkipConnectivity )
{
if( aBoardItem == nullptr )
{
wxFAIL_MSG( wxT( "BOARD::Add() param error: aBoardItem nullptr" ) );
return;
}
m_itemByIdCache.insert( { aBoardItem->m_Uuid, aBoardItem } );
switch( aBoardItem->Type() )
{
case PCB_NETINFO_T:
m_NetInfo.AppendNet( (NETINFO_ITEM*) aBoardItem );
break;
// this one uses a vector
case PCB_MARKER_T:
m_markers.push_back( (PCB_MARKER*) aBoardItem );
break;
// this one uses a vector
case PCB_GROUP_T:
m_groups.push_back( (PCB_GROUP*) aBoardItem );
break;
// this one uses a vector
case PCB_GENERATOR_T:
m_generators.push_back( (PCB_GENERATOR*) aBoardItem );
break;
// this one uses a vector
case PCB_ZONE_T:
m_zones.push_back( (ZONE*) aBoardItem );
break;
case PCB_TRACE_T:
case PCB_VIA_T:
case PCB_ARC_T:
// N.B. This inserts a small memory leak as we lose the
if( !IsCopperLayer( aBoardItem->GetLayer() ) )
{
wxFAIL_MSG( wxT( "BOARD::Add() Cannot place Track on non-copper layer" ) );
return;
}
if( aMode == ADD_MODE::APPEND || aMode == ADD_MODE::BULK_APPEND )
m_tracks.push_back( static_cast<PCB_TRACK*>( aBoardItem ) );
else
m_tracks.push_front( static_cast<PCB_TRACK*>( aBoardItem ) );
break;
case PCB_FOOTPRINT_T:
{
FOOTPRINT* footprint = static_cast<FOOTPRINT*>( aBoardItem );
if( aMode == ADD_MODE::APPEND || aMode == ADD_MODE::BULK_APPEND )
m_footprints.push_back( footprint );
else
m_footprints.push_front( footprint );
footprint->RunOnChildren( [&]( BOARD_ITEM* aChild )
{
m_itemByIdCache.insert( { aChild->m_Uuid, aChild } );
} );
break;
}
case PCB_DIM_ALIGNED_T:
case PCB_DIM_CENTER_T:
case PCB_DIM_RADIAL_T:
case PCB_DIM_ORTHOGONAL_T:
case PCB_DIM_LEADER_T:
case PCB_SHAPE_T:
case PCB_REFERENCE_IMAGE_T:
case PCB_FIELD_T:
case PCB_TEXT_T:
case PCB_TEXTBOX_T:
case PCB_TABLE_T:
case PCB_TARGET_T:
{
if( aMode == ADD_MODE::APPEND || aMode == ADD_MODE::BULK_APPEND )
m_drawings.push_back( aBoardItem );
else
m_drawings.push_front( aBoardItem );
if( aBoardItem->Type() == PCB_TABLE_T )
{
PCB_TABLE* table = static_cast<PCB_TABLE*>( aBoardItem );
table->RunOnChildren( [&]( BOARD_ITEM* aChild )
{
m_itemByIdCache.insert( { aChild->m_Uuid, aChild } );
} );
}
break;
}
// other types may use linked list
default:
{
wxString msg;
msg.Printf( wxT( "BOARD::Add() needs work: BOARD_ITEM type (%d) not handled" ),
aBoardItem->Type() );
wxFAIL_MSG( msg );
return;
}
break;
}
aBoardItem->SetParent( this );
aBoardItem->ClearEditFlags();
if( !aSkipConnectivity )
m_connectivity->Add( aBoardItem );
if( aMode != ADD_MODE::BULK_INSERT && aMode != ADD_MODE::BULK_APPEND )
{
InvokeListeners( &BOARD_LISTENER::OnBoardItemAdded, *this, aBoardItem );
}
}
void BOARD::FinalizeBulkAdd( std::vector<BOARD_ITEM*>& aNewItems )
{
InvokeListeners( &BOARD_LISTENER::OnBoardItemsAdded, *this, aNewItems );
}
void BOARD::FinalizeBulkRemove( std::vector<BOARD_ITEM*>& aRemovedItems )
{
InvokeListeners( &BOARD_LISTENER::OnBoardItemsRemoved, *this, aRemovedItems );
}
void BOARD::Remove( BOARD_ITEM* aBoardItem, REMOVE_MODE aRemoveMode )
{
// find these calls and fix them! Don't send me no stinking' nullptr.
wxASSERT( aBoardItem );
m_itemByIdCache.erase( aBoardItem->m_Uuid );
switch( aBoardItem->Type() )
{
case PCB_NETINFO_T:
{
NETINFO_ITEM* netItem = static_cast<NETINFO_ITEM*>( aBoardItem );
NETINFO_ITEM* unconnected = m_NetInfo.GetNetItem( NETINFO_LIST::UNCONNECTED );
for( BOARD_CONNECTED_ITEM* boardItem : AllConnectedItems() )
{
if( boardItem->GetNet() == netItem )
boardItem->SetNet( unconnected );
}
m_NetInfo.RemoveNet( netItem );
break;
}
case PCB_MARKER_T:
alg::delete_matching( m_markers, aBoardItem );
break;
case PCB_GROUP_T:
alg::delete_matching( m_groups, aBoardItem );
break;
case PCB_ZONE_T:
alg::delete_matching( m_zones, aBoardItem );
break;
case PCB_GENERATOR_T:
alg::delete_matching( m_generators, aBoardItem );
break;
case PCB_FOOTPRINT_T:
{
alg::delete_matching( m_footprints, aBoardItem );
FOOTPRINT* footprint = static_cast<FOOTPRINT*>( aBoardItem );
footprint->RunOnChildren( [&]( BOARD_ITEM* aChild )
{
m_itemByIdCache.erase( aChild->m_Uuid );
} );
break;
}
case PCB_TRACE_T:
case PCB_ARC_T:
case PCB_VIA_T:
alg::delete_matching( m_tracks, aBoardItem );
break;
case PCB_DIM_ALIGNED_T:
case PCB_DIM_CENTER_T:
case PCB_DIM_RADIAL_T:
case PCB_DIM_ORTHOGONAL_T:
case PCB_DIM_LEADER_T:
case PCB_SHAPE_T:
case PCB_REFERENCE_IMAGE_T:
case PCB_FIELD_T:
case PCB_TEXT_T:
case PCB_TEXTBOX_T:
case PCB_TABLE_T:
case PCB_TARGET_T:
{
alg::delete_matching( m_drawings, aBoardItem );
if( aBoardItem->Type() == PCB_TABLE_T )
{
PCB_TABLE* table = static_cast<PCB_TABLE*>( aBoardItem );
table->RunOnChildren( [&]( BOARD_ITEM* aChild )
{
m_itemByIdCache.erase( aChild->m_Uuid );
} );
}
break;
}
// other types may use linked list
default:
wxFAIL_MSG( wxT( "BOARD::Remove() needs more ::Type() support" ) );
}
aBoardItem->SetFlags( STRUCT_DELETED );
PCB_GROUP* parentGroup = aBoardItem->GetParentGroup();
if( parentGroup && !( parentGroup->GetFlags() & STRUCT_DELETED ) )
parentGroup->RemoveItem( aBoardItem );
m_connectivity->Remove( aBoardItem );
if( aRemoveMode != REMOVE_MODE::BULK )
InvokeListeners( &BOARD_LISTENER::OnBoardItemRemoved, *this, aBoardItem );
}
void BOARD::RemoveAll( std::initializer_list<KICAD_T> aTypes )
{
std::vector<BOARD_ITEM*> removed;
for( const KICAD_T& type : aTypes )
{
switch( type )
{
case PCB_NETINFO_T:
for( NETINFO_ITEM* item : m_NetInfo )
removed.emplace_back( item );
m_NetInfo.clear();
break;
case PCB_MARKER_T:
std::copy( m_markers.begin(), m_markers.end(), std::back_inserter( removed ) );
m_markers.clear();
break;
case PCB_GROUP_T:
std::copy( m_groups.begin(), m_groups.end(), std::back_inserter( removed ) );
m_groups.clear();
break;
case PCB_ZONE_T:
std::copy( m_zones.begin(), m_zones.end(), std::back_inserter( removed ) );
m_zones.clear();
break;
case PCB_GENERATOR_T:
std::copy( m_generators.begin(), m_generators.end(), std::back_inserter( removed ) );
m_generators.clear();
break;
case PCB_FOOTPRINT_T:
std::copy( m_footprints.begin(), m_footprints.end(), std::back_inserter( removed ) );
m_footprints.clear();
break;
case PCB_TRACE_T:
std::copy( m_tracks.begin(), m_tracks.end(), std::back_inserter( removed ) );
m_tracks.clear();
break;
case PCB_ARC_T:
case PCB_VIA_T:
wxFAIL_MSG( wxT( "Use PCB_TRACE_T to remove all tracks, arcs, and vias" ) );
break;
case PCB_SHAPE_T:
std::copy( m_drawings.begin(), m_drawings.end(), std::back_inserter( removed ) );
m_drawings.clear();
break;
case PCB_DIM_ALIGNED_T:
case PCB_DIM_CENTER_T:
case PCB_DIM_RADIAL_T:
case PCB_DIM_ORTHOGONAL_T:
case PCB_DIM_LEADER_T:
case PCB_REFERENCE_IMAGE_T:
case PCB_FIELD_T:
case PCB_TEXT_T:
case PCB_TEXTBOX_T:
case PCB_TABLE_T:
case PCB_TARGET_T:
wxFAIL_MSG( wxT( "Use PCB_SHAPE_T to remove all graphics and text" ) );
break;
default:
wxFAIL_MSG( wxT( "BOARD::RemoveAll() needs more ::Type() support" ) );
}
}
for( BOARD_ITEM* item : removed )
m_itemByIdCache.erase( item->m_Uuid );
FinalizeBulkRemove( removed );
}
wxString BOARD::GetItemDescription( UNITS_PROVIDER* aUnitsProvider, bool aFull ) const
{
return wxString::Format( _( "PCB" ) );
}
void BOARD::UpdateUserUnits( BOARD_ITEM* aItem, KIGFX::VIEW* aView )
{
INSPECTOR_FUNC inspector =
[&]( EDA_ITEM* descendant, void* aTestData )
{
PCB_DIMENSION_BASE* dimension = static_cast<PCB_DIMENSION_BASE*>( descendant );
if( dimension->GetUnitsMode() == DIM_UNITS_MODE::AUTOMATIC )
{
dimension->UpdateUnits();
if( aView )
aView->Update( dimension );
}
return INSPECT_RESULT::CONTINUE;
};
aItem->Visit( inspector, nullptr, { PCB_DIM_ALIGNED_T,
PCB_DIM_LEADER_T,
PCB_DIM_ORTHOGONAL_T,
PCB_DIM_CENTER_T,
PCB_DIM_RADIAL_T } );
}
void BOARD::DeleteMARKERs()
{
// the vector does not know how to delete the PCB_MARKER, it holds pointers
for( PCB_MARKER* marker : m_markers )
{
// We also must clear the cache
m_itemByIdCache.erase( marker->m_Uuid );
delete marker;
}
m_markers.clear();
}
void BOARD::DeleteMARKERs( bool aWarningsAndErrors, bool aExclusions )
{
// Deleting lots of items from a vector can be very slow. Copy remaining items instead.
MARKERS remaining;
for( PCB_MARKER* marker : m_markers )
{
if( ( marker->GetSeverity() == RPT_SEVERITY_EXCLUSION && aExclusions )
|| ( marker->GetSeverity() != RPT_SEVERITY_EXCLUSION && aWarningsAndErrors ) )
{
// We also must clear the cache
m_itemByIdCache.erase( marker->m_Uuid );
delete marker;
}
else
{
remaining.push_back( marker );
}
}
m_markers = remaining;
}
void BOARD::DeleteAllFootprints()
{
for( FOOTPRINT* footprint : m_footprints )
{
m_itemByIdCache.erase( footprint->m_Uuid );
delete footprint;
}
m_footprints.clear();
IncrementTimeStamp();
}
BOARD_ITEM* BOARD::GetItem( const KIID& aID ) const
{
if( aID == niluuid )
return nullptr;
if( m_itemByIdCache.count( aID ) )
return m_itemByIdCache.at( aID );
for( PCB_TRACK* track : Tracks() )
{
if( track->m_Uuid == aID )
return track;
}
for( FOOTPRINT* footprint : Footprints() )
{
if( footprint->m_Uuid == aID )
return footprint;
for( PAD* pad : footprint->Pads() )
{
if( pad->m_Uuid == aID )
return pad;
}
for( PCB_FIELD* field : footprint->Fields() )
{
if( field->m_Uuid == aID )
return field;
}
for( BOARD_ITEM* drawing : footprint->GraphicalItems() )
{
if( drawing->m_Uuid == aID )
return drawing;
}
for( BOARD_ITEM* zone : footprint->Zones() )
{
if( zone->m_Uuid == aID )
return zone;
}
for( PCB_GROUP* group : footprint->Groups() )
{
if( group->m_Uuid == aID )
return group;
}
}
for( ZONE* zone : Zones() )
{
if( zone->m_Uuid == aID )
return zone;
}
for( BOARD_ITEM* drawing : Drawings() )
{
if( drawing->Type() == PCB_TABLE_T )
{
for( PCB_TABLECELL* cell : static_cast<PCB_TABLE*>( drawing )->GetCells() )
{
if( cell->m_Uuid == aID )
return drawing;
}
}
if( drawing->m_Uuid == aID )
return drawing;
}
for( PCB_MARKER* marker : m_markers )
{
if( marker->m_Uuid == aID )
return marker;
}
for( PCB_GROUP* group : m_groups )
{
if( group->m_Uuid == aID )
return group;
}
for( PCB_GENERATOR* generator : m_generators )
{
if( generator->m_Uuid == aID )
return generator;
}
for( NETINFO_ITEM* netInfo : m_NetInfo )
{
if( netInfo->m_Uuid == aID )
return netInfo;
}
if( m_Uuid == aID )
return const_cast<BOARD*>( this );
// Not found; weak reference has been deleted.
return DELETED_BOARD_ITEM::GetInstance();
}
void BOARD::FillItemMap( std::map<KIID, EDA_ITEM*>& aMap )
{
// the board itself
aMap[ m_Uuid ] = this;
for( PCB_TRACK* track : Tracks() )
aMap[ track->m_Uuid ] = track;
for( FOOTPRINT* footprint : Footprints() )
{
aMap[ footprint->m_Uuid ] = footprint;
for( PAD* pad : footprint->Pads() )
aMap[ pad->m_Uuid ] = pad;
aMap[ footprint->Reference().m_Uuid ] = &footprint->Reference();
aMap[ footprint->Value().m_Uuid ] = &footprint->Value();
for( BOARD_ITEM* drawing : footprint->GraphicalItems() )
aMap[ drawing->m_Uuid ] = drawing;
}
for( ZONE* zone : Zones() )
aMap[ zone->m_Uuid ] = zone;
for( BOARD_ITEM* drawing : Drawings() )
aMap[ drawing->m_Uuid ] = drawing;
for( PCB_MARKER* marker : m_markers )
aMap[ marker->m_Uuid ] = marker;
for( PCB_GROUP* group : m_groups )
aMap[ group->m_Uuid ] = group;
for( PCB_GENERATOR* generator : m_generators )
aMap[ generator->m_Uuid ] = generator;
}
wxString BOARD::ConvertCrossReferencesToKIIDs( const wxString& aSource ) const
{
wxString newbuf;
size_t sourceLen = aSource.length();
for( size_t i = 0; i < sourceLen; ++i )
{
if( aSource[i] == '$' && i + 1 < sourceLen && aSource[i+1] == '{' )
{
wxString token;
bool isCrossRef = false;
for( i = i + 2; i < sourceLen; ++i )
{
if( aSource[i] == '}' )
break;
if( aSource[i] == ':' )
isCrossRef = true;
token.append( aSource[i] );
}
if( isCrossRef )
{
wxString remainder;
wxString ref = token.BeforeFirst( ':', &remainder );
for( const FOOTPRINT* footprint : Footprints() )
{
if( footprint->GetReference().CmpNoCase( ref ) == 0 )
{
wxString test( remainder );
if( footprint->ResolveTextVar( &test ) )
token = footprint->m_Uuid.AsString() + wxT( ":" ) + remainder;
break;
}
}
}
newbuf.append( wxT( "${" ) + token + wxT( "}" ) );
}
else
{
newbuf.append( aSource[i] );
}
}
return newbuf;
}
wxString BOARD::ConvertKIIDsToCrossReferences( const wxString& aSource ) const
{
wxString newbuf;
size_t sourceLen = aSource.length();
for( size_t i = 0; i < sourceLen; ++i )
{
if( aSource[i] == '$' && i + 1 < sourceLen && aSource[i+1] == '{' )
{
wxString token;
bool isCrossRef = false;
for( i = i + 2; i < sourceLen; ++i )
{
if( aSource[i] == '}' )
break;
if( aSource[i] == ':' )
isCrossRef = true;
token.append( aSource[i] );
}
if( isCrossRef )
{
wxString remainder;
wxString ref = token.BeforeFirst( ':', &remainder );
BOARD_ITEM* refItem = GetItem( KIID( ref ) );
if( refItem && refItem->Type() == PCB_FOOTPRINT_T )
{
token = static_cast<FOOTPRINT*>( refItem )->GetReference() + wxT( ":" )
+ remainder;
}
}
newbuf.append( wxT( "${" ) + token + wxT( "}" ) );
}
else
{
newbuf.append( aSource[i] );
}
}
return newbuf;
}
unsigned BOARD::GetNodesCount( int aNet ) const
{
unsigned retval = 0;
for( FOOTPRINT* footprint : Footprints() )
{
for( PAD* pad : footprint->Pads() )
{
if( ( aNet == -1 && pad->GetNetCode() > 0 ) || aNet == pad->GetNetCode() )
retval++;
}
}
return retval;
}
BOX2I BOARD::ComputeBoundingBox( bool aBoardEdgesOnly ) const
{
BOX2I bbox;
LSET visible = GetVisibleLayers();
// If the board is just showing a footprint, we want all footprint layers included in the
// bounding box
if( IsFootprintHolder() )
visible.set();
if( aBoardEdgesOnly )
visible.set( Edge_Cuts );
// Check shapes, dimensions, texts, and fiducials
for( BOARD_ITEM* item : m_drawings )
{
if( aBoardEdgesOnly && ( item->GetLayer() != Edge_Cuts || item->Type() != PCB_SHAPE_T ) )
continue;
if( ( item->GetLayerSet() & visible ).any() )
bbox.Merge( item->GetBoundingBox() );
}
// Check footprints
for( FOOTPRINT* footprint : m_footprints )
{
if( aBoardEdgesOnly )
{
for( const BOARD_ITEM* edge : footprint->GraphicalItems() )
{
if( edge->GetLayer() == Edge_Cuts && edge->Type() == PCB_SHAPE_T )
bbox.Merge( edge->GetBoundingBox() );
}
}
else if( ( footprint->GetLayerSet() & visible ).any() )
{
bbox.Merge( footprint->GetBoundingBox( true ) );
}
}
if( !aBoardEdgesOnly )
{
// Check tracks
for( PCB_TRACK* track : m_tracks )
{
if( ( track->GetLayerSet() & visible ).any() )
bbox.Merge( track->GetBoundingBox() );
}
// Check zones
for( ZONE* aZone : m_zones )
{
if( ( aZone->GetLayerSet() & visible ).any() )
bbox.Merge( aZone->GetBoundingBox() );
}
}
return bbox;
}
void BOARD::GetMsgPanelInfo( EDA_DRAW_FRAME* aFrame, std::vector<MSG_PANEL_ITEM>& aList )
{
int padCount = 0;
int viaCount = 0;
int trackSegmentCount = 0;
std::set<int> netCodes;
int unconnected = GetConnectivity()->GetUnconnectedCount( true );
for( PCB_TRACK* item : m_tracks )
{
if( item->Type() == PCB_VIA_T )
viaCount++;
else
trackSegmentCount++;
if( item->GetNetCode() > 0 )
netCodes.insert( item->GetNetCode() );
}
for( FOOTPRINT* footprint : Footprints() )
{
for( PAD* pad : footprint->Pads() )
{
padCount++;
if( pad->GetNetCode() > 0 )
netCodes.insert( pad->GetNetCode() );
}
}
aList.emplace_back( _( "Pads" ), wxString::Format( wxT( "%d" ), padCount ) );
aList.emplace_back( _( "Vias" ), wxString::Format( wxT( "%d" ), viaCount ) );
aList.emplace_back( _( "Track Segments" ), wxString::Format( wxT( "%d" ), trackSegmentCount ) );
aList.emplace_back( _( "Nets" ), wxString::Format( wxT( "%d" ), (int) netCodes.size() ) );
aList.emplace_back( _( "Unrouted" ), wxString::Format( wxT( "%d" ), unconnected ) );
}
INSPECT_RESULT BOARD::Visit( INSPECTOR inspector, void* testData,
const std::vector<KICAD_T>& scanTypes )
{
#if 0 && defined(DEBUG)
std::cout << GetClass().mb_str() << ' ';
#endif
bool footprintsScanned = false;
bool drawingsScanned = false;
bool tracksScanned = false;
for( KICAD_T scanType : scanTypes )
{
switch( scanType )
{
case PCB_T:
if( inspector( this, testData ) == INSPECT_RESULT::QUIT )
return INSPECT_RESULT::QUIT;
break;
/*
* Instances of the requested KICAD_T live in a list, either one that I manage, or one
* that my footprints manage. If it's a type managed by class FOOTPRINT, then simply
* pass it on to each footprint's Visit() function via IterateForward( m_footprints, ... ).
*/
case PCB_FOOTPRINT_T:
case PCB_PAD_T:
case PCB_SHAPE_T:
case PCB_REFERENCE_IMAGE_T:
case PCB_FIELD_T:
case PCB_TEXT_T:
case PCB_TEXTBOX_T:
case PCB_TABLE_T:
case PCB_TABLECELL_T:
case PCB_DIM_ALIGNED_T:
case PCB_DIM_CENTER_T:
case PCB_DIM_RADIAL_T:
case PCB_DIM_ORTHOGONAL_T:
case PCB_DIM_LEADER_T:
case PCB_TARGET_T:
if( !footprintsScanned )
{
if( IterateForward<FOOTPRINT*>( m_footprints, inspector, testData, scanTypes )
== INSPECT_RESULT::QUIT )
{
return INSPECT_RESULT::QUIT;
}
footprintsScanned = true;
}
if( !drawingsScanned )
{
if( IterateForward<BOARD_ITEM*>( m_drawings, inspector, testData, scanTypes )
== INSPECT_RESULT::QUIT )
{
return INSPECT_RESULT::QUIT;
}
drawingsScanned = true;
}
break;
case PCB_VIA_T:
case PCB_TRACE_T:
case PCB_ARC_T:
if( !tracksScanned )
{
if( IterateForward<PCB_TRACK*>( m_tracks, inspector, testData, scanTypes )
== INSPECT_RESULT::QUIT )
{
return INSPECT_RESULT::QUIT;
}
tracksScanned = true;
}
break;
case PCB_MARKER_T:
for( PCB_MARKER* marker : m_markers )
{
if( marker->Visit( inspector, testData, { scanType } ) == INSPECT_RESULT::QUIT )
return INSPECT_RESULT::QUIT;
}
break;
case PCB_ZONE_T:
if( !footprintsScanned )
{
if( IterateForward<FOOTPRINT*>( m_footprints, inspector, testData, scanTypes )
== INSPECT_RESULT::QUIT )
{
return INSPECT_RESULT::QUIT;
}
footprintsScanned = true;
}
for( ZONE* zone : m_zones)
{
if( zone->Visit( inspector, testData, { scanType } ) == INSPECT_RESULT::QUIT )
return INSPECT_RESULT::QUIT;
}
break;
case PCB_GENERATOR_T:
if( !footprintsScanned )
{
if( IterateForward<FOOTPRINT*>( m_footprints, inspector, testData, scanTypes )
== INSPECT_RESULT::QUIT )
{
return INSPECT_RESULT::QUIT;
}
footprintsScanned = true;
}
if( IterateForward<PCB_GENERATOR*>( m_generators, inspector, testData, { scanType } )
== INSPECT_RESULT::QUIT )
{
return INSPECT_RESULT::QUIT;
}
break;
case PCB_GROUP_T:
if( IterateForward<PCB_GROUP*>( m_groups, inspector, testData, { scanType } )
== INSPECT_RESULT::QUIT )
{
return INSPECT_RESULT::QUIT;
}
break;
default:
break;
}
}
return INSPECT_RESULT::CONTINUE;
}
NETINFO_ITEM* BOARD::FindNet( int aNetcode ) const
{
// the first valid netcode is 1 and the last is m_NetInfo.GetCount()-1.
// zero is reserved for "no connection" and is not actually a net.
// nullptr is returned for non valid netcodes
wxASSERT( m_NetInfo.GetNetCount() > 0 );
if( aNetcode == NETINFO_LIST::UNCONNECTED && m_NetInfo.GetNetCount() == 0 )
return NETINFO_LIST::OrphanedItem();
else
return m_NetInfo.GetNetItem( aNetcode );
}
NETINFO_ITEM* BOARD::FindNet( const wxString& aNetname ) const
{
return m_NetInfo.GetNetItem( aNetname );
}
int BOARD::MatchDpSuffix( const wxString& aNetName, wxString& aComplementNet )
{
int rv = 0;
int count = 0;
for( auto it = aNetName.rbegin(); it != aNetName.rend() && rv == 0; ++it, ++count )
{
int ch = *it;
if( ( ch >= '0' && ch <= '9' ) || ch == '_' )
{
continue;
}
else if( ch == '+' )
{
aComplementNet = wxT( "-" );
rv = 1;
}
else if( ch == '-' )
{
aComplementNet = wxT( "+" );
rv = -1;
}
else if( ch == 'N' )
{
aComplementNet = wxT( "P" );
rv = -1;
}
else if ( ch == 'P' )
{
aComplementNet = wxT( "N" );
rv = 1;
}
else
{
break;
}
}
if( rv != 0 && count >= 1 )
{
aComplementNet = aNetName.Left( aNetName.length() - count )
+ aComplementNet
+ aNetName.Right( count - 1 );
}
return rv;
}
NETINFO_ITEM* BOARD::DpCoupledNet( const NETINFO_ITEM* aNet )
{
if( aNet )
{
wxString refName = aNet->GetNetname();
wxString coupledNetName;
if( MatchDpSuffix( refName, coupledNetName ) )
return FindNet( coupledNetName );
}
return nullptr;
}
FOOTPRINT* BOARD::FindFootprintByReference( const wxString& aReference ) const
{
for( FOOTPRINT* footprint : m_footprints )
{
if( aReference == footprint->GetReference() )
return footprint;
}
return nullptr;
}
FOOTPRINT* BOARD::FindFootprintByPath( const KIID_PATH& aPath ) const
{
for( FOOTPRINT* footprint : m_footprints )
{
if( footprint->GetPath() == aPath )
return footprint;
}
return nullptr;
}
std::set<wxString> BOARD::GetNetClassAssignmentCandidates() const
{
std::set<wxString> names;
for( const NETINFO_ITEM* net : m_NetInfo )
{
if( !net->GetNetname().IsEmpty() )
names.insert( net->GetNetname() );
}
return names;
}
void BOARD::SynchronizeProperties()
{
wxCHECK( m_project, /*void*/ );
if( !m_project->IsNullProject() )
SetProperties( m_project->GetTextVars() );
}
void BOARD::SynchronizeNetsAndNetClasses( bool aResetTrackAndViaSizes )
{
if( !m_project )
return;
BOARD_DESIGN_SETTINGS& bds = GetDesignSettings();
const std::shared_ptr<NETCLASS>& defaultNetClass = bds.m_NetSettings->GetDefaultNetclass();
bds.m_NetSettings->ClearAllCaches();
for( NETINFO_ITEM* net : m_NetInfo )
net->SetNetClass( bds.m_NetSettings->GetEffectiveNetClass( net->GetNetname() ) );
if( aResetTrackAndViaSizes )
{
// Set initial values for custom track width & via size to match the default
// netclass settings
bds.UseCustomTrackViaSize( false );
bds.SetCustomTrackWidth( defaultNetClass->GetTrackWidth() );
bds.SetCustomViaSize( defaultNetClass->GetViaDiameter() );
bds.SetCustomViaDrill( defaultNetClass->GetViaDrill() );
bds.SetCustomDiffPairWidth( defaultNetClass->GetDiffPairWidth() );
bds.SetCustomDiffPairGap( defaultNetClass->GetDiffPairGap() );
bds.SetCustomDiffPairViaGap( defaultNetClass->GetDiffPairViaGap() );
}
InvokeListeners( &BOARD_LISTENER::OnBoardNetSettingsChanged, *this );
}
int BOARD::SetAreasNetCodesFromNetNames()
{
int error_count = 0;
for( ZONE* zone : Zones() )
{
if( !zone->IsOnCopperLayer() )
{
zone->SetNetCode( NETINFO_LIST::UNCONNECTED );
continue;
}
if( zone->GetNetCode() != 0 ) // i.e. if this zone is connected to a net
{
const NETINFO_ITEM* net = zone->GetNet();
if( net )
{
zone->SetNetCode( net->GetNetCode() );
}
else
{
error_count++;
// keep Net Name and set m_NetCode to -1 : error flag.
zone->SetNetCode( -1 );
}
}
}
return error_count;
}
PAD* BOARD::GetPad( const VECTOR2I& aPosition, LSET aLayerSet ) const
{
if( !aLayerSet.any() )
aLayerSet = LSET::AllCuMask();
for( FOOTPRINT* footprint : m_footprints )
{
PAD* pad = nullptr;
if( footprint->HitTest( aPosition ) )
pad = footprint->GetPad( aPosition, aLayerSet );
if( pad )
return pad;
}
return nullptr;
}
PAD* BOARD::GetPad( const PCB_TRACK* aTrace, ENDPOINT_T aEndPoint ) const
{
const VECTOR2I& aPosition = aTrace->GetEndPoint( aEndPoint );
LSET lset( { aTrace->GetLayer() } );
return GetPad( aPosition, lset );
}
PAD* BOARD::GetPadFast( const VECTOR2I& aPosition, LSET aLayerSet ) const
{
for( FOOTPRINT* footprint : Footprints() )
{
for( PAD* pad : footprint->Pads() )
{
if( pad->GetPosition() != aPosition )
continue;
// Pad found, it must be on the correct layer
if( ( pad->GetLayerSet() & aLayerSet ).any() )
return pad;
}
}
return nullptr;
}
PAD* BOARD::GetPad( std::vector<PAD*>& aPadList, const VECTOR2I& aPosition, LSET aLayerSet ) const
{
// Search aPadList for aPosition
// aPadList is sorted by X then Y values, and a fast binary search is used
int idxmax = aPadList.size() - 1;
int delta = aPadList.size();
int idx = 0; // Starting index is the beginning of list
while( delta )
{
// Calculate half size of remaining interval to test.
// Ensure the computed value is not truncated (too small)
if( (delta & 1) && ( delta > 1 ) )
delta++;
delta /= 2;
PAD* pad = aPadList[idx];
if( pad->GetPosition() == aPosition ) // candidate found
{
// The pad must match the layer mask:
if( ( aLayerSet & pad->GetLayerSet() ).any() )
return pad;
// More than one pad can be at aPosition
// search for a pad at aPosition that matched this mask
// search next
for( int ii = idx+1; ii <= idxmax; ii++ )
{
pad = aPadList[ii];
if( pad->GetPosition() != aPosition )
break;
if( ( aLayerSet & pad->GetLayerSet() ).any() )
return pad;
}
// search previous
for( int ii = idx - 1 ;ii >=0; ii-- )
{
pad = aPadList[ii];
if( pad->GetPosition() != aPosition )
break;
if( ( aLayerSet & pad->GetLayerSet() ).any() )
return pad;
}
// Not found:
return nullptr;
}
if( pad->GetPosition().x == aPosition.x ) // Must search considering Y coordinate
{
if( pad->GetPosition().y < aPosition.y ) // Must search after this item
{
idx += delta;
if( idx > idxmax )
idx = idxmax;
}
else // Must search before this item
{
idx -= delta;
if( idx < 0 )
idx = 0;
}
}
else if( pad->GetPosition().x < aPosition.x ) // Must search after this item
{
idx += delta;
if( idx > idxmax )
idx = idxmax;
}
else // Must search before this item
{
idx -= delta;
if( idx < 0 )
idx = 0;
}
}
return nullptr;
}
/**
* Used by #GetSortedPadListByXCoord to sort a pad list by X coordinate value.
*
* This function is used to build ordered pads lists
*/
bool sortPadsByXthenYCoord( PAD* const & aLH, PAD* const & aRH )
{
if( aLH->GetPosition().x == aRH->GetPosition().x )
return aLH->GetPosition().y < aRH->GetPosition().y;
return aLH->GetPosition().x < aRH->GetPosition().x;
}
void BOARD::GetSortedPadListByXthenYCoord( std::vector<PAD*>& aVector, int aNetCode ) const
{
for( FOOTPRINT* footprint : Footprints() )
{
for( PAD* pad : footprint->Pads( ) )
{
if( aNetCode < 0 || pad->GetNetCode() == aNetCode )
aVector.push_back( pad );
}
}
std::sort( aVector.begin(), aVector.end(), sortPadsByXthenYCoord );
}
BOARD_STACKUP BOARD::GetStackupOrDefault() const
{
if( GetDesignSettings().m_HasStackup )
return GetDesignSettings().GetStackupDescriptor();
BOARD_STACKUP stackup;
stackup.BuildDefaultStackupList( &GetDesignSettings(), GetCopperLayerCount() );
return stackup;
}
std::tuple<int, double, double> BOARD::GetTrackLength( const PCB_TRACK& aTrack ) const
{
int count = 0;
double length = 0.0;
double package_length = 0.0;
auto connectivity = GetBoard()->GetConnectivity();
BOARD_STACKUP& stackup = GetDesignSettings().GetStackupDescriptor();
bool useHeight = GetDesignSettings().m_UseHeightForLengthCalcs;
static const std::vector<KICAD_T> baseConnectedTypes = { PCB_TRACE_T,
PCB_ARC_T,
PCB_VIA_T,
PCB_PAD_T };
for( BOARD_CONNECTED_ITEM* item : connectivity->GetConnectedItems( &aTrack, baseConnectedTypes ) )
{
count++;
if( PCB_TRACK* track = dynamic_cast<PCB_TRACK*>( item ) )
{
if( track->Type() == PCB_VIA_T && useHeight )
{
PCB_VIA* via = static_cast<PCB_VIA*>( track );
length += stackup.GetLayerDistance( via->TopLayer(), via->BottomLayer() );
continue;
}
else if( track->Type() == PCB_ARC_T )
{
// Note: we don't apply the clip-to-pad optimization if an arc ends in a pad
// Room for future improvement.
length += track->GetLength();
continue;
}
bool inPad = false;
SEG trackSeg( track->GetStart(), track->GetEnd() );
double segLen = trackSeg.Length();
double segInPadLen = 0;
for( auto pad_it : connectivity->GetConnectedPads( item ) )
{
PAD* pad = static_cast<PAD*>( pad_it );
bool hitStart = pad->HitTest( track->GetStart(), track->GetWidth() / 2 );
bool hitEnd = pad->HitTest( track->GetEnd(), track->GetWidth() / 2 );
if( hitStart && hitEnd )
{
inPad = true;
break;
}
else if( hitStart || hitEnd )
{
VECTOR2I loc;
// We may not collide even if we passed the bounding-box hit test
if( pad->GetEffectivePolygon( track->GetLayer(), ERROR_INSIDE )->Collide( trackSeg, 0, nullptr, &loc ) )
{
// Part 1: length of the seg to the intersection with the pad poly
if( hitStart )
trackSeg.A = loc;
else
trackSeg.B = loc;
segLen = trackSeg.Length();
// Part 2: length from the intersection to the pad anchor
segInPadLen += ( loc - pad->GetPosition() ).EuclideanNorm();
}
}
}
if( !inPad )
length += segLen + segInPadLen;
}
else if( PAD* pad = dynamic_cast<PAD*>( item ) )
{
package_length += pad->GetPadToDieLength();
}
}
return std::make_tuple( count, length, package_length );
}
FOOTPRINT* BOARD::GetFootprint( const VECTOR2I& aPosition, PCB_LAYER_ID aActiveLayer,
bool aVisibleOnly, bool aIgnoreLocked ) const
{
FOOTPRINT* footprint = nullptr;
FOOTPRINT* alt_footprint = nullptr;
int min_dim = 0x7FFFFFFF;
int alt_min_dim = 0x7FFFFFFF;
bool current_layer_back = IsBackLayer( aActiveLayer );
for( FOOTPRINT* candidate : m_footprints )
{
// is the ref point within the footprint's bounds?
if( !candidate->HitTest( aPosition ) )
continue;
// if caller wants to ignore locked footprints, and this one is locked, skip it.
if( aIgnoreLocked && candidate->IsLocked() )
continue;
PCB_LAYER_ID layer = candidate->GetLayer();
// Filter non visible footprints if requested
if( !aVisibleOnly || IsFootprintLayerVisible( layer ) )
{
BOX2I bb = candidate->GetBoundingBox( false );
int offx = bb.GetX() + bb.GetWidth() / 2;
int offy = bb.GetY() + bb.GetHeight() / 2;
// off x & offy point to the middle of the box.
int dist = ( aPosition.x - offx ) * ( aPosition.x - offx ) +
( aPosition.y - offy ) * ( aPosition.y - offy );
if( current_layer_back == IsBackLayer( layer ) )
{
if( dist <= min_dim )
{
// better footprint shown on the active side
footprint = candidate;
min_dim = dist;
}
}
else if( aVisibleOnly && IsFootprintLayerVisible( layer ) )
{
if( dist <= alt_min_dim )
{
// better footprint shown on the other side
alt_footprint = candidate;
alt_min_dim = dist;
}
}
}
}
if( footprint )
return footprint;
if( alt_footprint)
return alt_footprint;
return nullptr;
}
std::list<ZONE*> BOARD::GetZoneList( bool aIncludeZonesInFootprints ) const
{
std::list<ZONE*> zones;
for( ZONE* zone : Zones() )
zones.push_back( zone );
if( aIncludeZonesInFootprints )
{
for( FOOTPRINT* footprint : m_footprints )
{
for( ZONE* zone : footprint->Zones() )
zones.push_back( zone );
}
}
return zones;
}
ZONE* BOARD::AddArea( PICKED_ITEMS_LIST* aNewZonesList, int aNetcode, PCB_LAYER_ID aLayer,
VECTOR2I aStartPointPosition, ZONE_BORDER_DISPLAY_STYLE aHatch )
{
ZONE* new_area = new ZONE( this );
new_area->SetNetCode( aNetcode );
new_area->SetLayer( aLayer );
m_zones.push_back( new_area );
new_area->SetHatchStyle( (ZONE_BORDER_DISPLAY_STYLE) aHatch );
// Add the first corner to the new zone
new_area->AppendCorner( aStartPointPosition, -1 );
if( aNewZonesList )
{
ITEM_PICKER picker( nullptr, new_area, UNDO_REDO::NEWITEM );
aNewZonesList->PushItem( picker );
}
return new_area;
}
bool BOARD::GetBoardPolygonOutlines( SHAPE_POLY_SET& aOutlines,
OUTLINE_ERROR_HANDLER* aErrorHandler,
bool aAllowUseArcsInPolygons,
bool aIncludeNPTHAsOutlines )
{
// max dist from one endPt to next startPt: use the current value
int chainingEpsilon = GetOutlinesChainingEpsilon();
bool success = BuildBoardPolygonOutlines( this, aOutlines, GetDesignSettings().m_MaxError,
chainingEpsilon, aErrorHandler,
aAllowUseArcsInPolygons );
// Now add NPTH oval holes as holes in outlines if required
if( aIncludeNPTHAsOutlines )
{
for( FOOTPRINT* fp : Footprints() )
{
for( PAD* pad : fp->Pads() )
{
if( pad->GetAttribute () != PAD_ATTRIB::NPTH )
continue;
SHAPE_POLY_SET hole;
pad->TransformHoleToPolygon( hole, 0, GetDesignSettings().m_MaxError, ERROR_INSIDE );
if( hole.OutlineCount() > 0 ) // can be not the case for malformed NPTH holes
{
// Add this pad hole to the main outline
// But we can have more than one main outline (i.e. more than one board), so
// search the right main outline i.e. the outline that contains the pad hole
SHAPE_LINE_CHAIN& pad_hole = hole.Outline( 0 );
const VECTOR2I holePt = pad_hole.CPoint( 0 );
for( int jj = 0; jj < aOutlines.OutlineCount(); ++jj )
{
if( aOutlines.Outline( jj ).PointInside( holePt ) )
{
aOutlines.AddHole( pad_hole, jj );
break;
}
}
}
}
}
}
// Make polygon strictly simple to avoid issues (especially in 3D viewer)
aOutlines.Simplify( SHAPE_POLY_SET::PM_STRICTLY_SIMPLE );
return success;
}
EMBEDDED_FILES* BOARD::GetEmbeddedFiles()
{
if( IsFootprintHolder() )
return static_cast<EMBEDDED_FILES*>( GetFirstFootprint() );
return static_cast<EMBEDDED_FILES*>( this );
}
const EMBEDDED_FILES* BOARD::GetEmbeddedFiles() const
{
if( IsFootprintHolder() )
return static_cast<const EMBEDDED_FILES*>( GetFirstFootprint() );
return static_cast<const EMBEDDED_FILES*>( this );
}
void BOARD::EmbedFonts()
{
std::set<KIFONT::OUTLINE_FONT*> fonts;
for( BOARD_ITEM* item : Drawings() )
{
if( EDA_TEXT* text = dynamic_cast<EDA_TEXT*>( item ) )
{
KIFONT::FONT* font = text->GetFont();
if( !font || font->IsStroke() )
continue;
using EMBEDDING_PERMISSION = KIFONT::OUTLINE_FONT::EMBEDDING_PERMISSION;
auto* outline = static_cast<KIFONT::OUTLINE_FONT*>( font );
if( outline->GetEmbeddingPermission() == EMBEDDING_PERMISSION::EDITABLE
|| outline->GetEmbeddingPermission() == EMBEDDING_PERMISSION::INSTALLABLE )
{
fonts.insert( outline );
}
}
}
for( KIFONT::OUTLINE_FONT* font : fonts )
{
auto file = GetEmbeddedFiles()->AddFile( font->GetFileName(), false );
file->type = EMBEDDED_FILES::EMBEDDED_FILE::FILE_TYPE::FONT;
}
}
const std::vector<PAD*> BOARD::GetPads() const
{
std::vector<PAD*> allPads;
for( FOOTPRINT* footprint : Footprints() )
{
for( PAD* pad : footprint->Pads() )
allPads.push_back( pad );
}
return allPads;
}
const std::vector<BOARD_CONNECTED_ITEM*> BOARD::AllConnectedItems()
{
std::vector<BOARD_CONNECTED_ITEM*> items;
for( PCB_TRACK* track : Tracks() )
items.push_back( track );
for( FOOTPRINT* footprint : Footprints() )
{
for( PAD* pad : footprint->Pads() )
items.push_back( pad );
}
for( ZONE* zone : Zones() )
items.push_back( zone );
for( BOARD_ITEM* item : Drawings() )
{
if( BOARD_CONNECTED_ITEM* bci = dynamic_cast<BOARD_CONNECTED_ITEM*>( item ) )
items.push_back( bci );
}
return items;
}
void BOARD::MapNets( BOARD* aDestBoard )
{
for( BOARD_CONNECTED_ITEM* item : AllConnectedItems() )
{
NETINFO_ITEM* netInfo = aDestBoard->FindNet( item->GetNetname() );
if( netInfo )
item->SetNet( netInfo );
else
{
NETINFO_ITEM* newNet = new NETINFO_ITEM( aDestBoard, item->GetNetname() );
aDestBoard->Add( newNet );
item->SetNet( newNet );
}
}
}
void BOARD::SanitizeNetcodes()
{
for ( BOARD_CONNECTED_ITEM* item : AllConnectedItems() )
{
if( FindNet( item->GetNetCode() ) == nullptr )
item->SetNetCode( NETINFO_LIST::ORPHANED );
}
}
void BOARD::AddListener( BOARD_LISTENER* aListener )
{
if( !alg::contains( m_listeners, aListener ) )
m_listeners.push_back( aListener );
}
void BOARD::RemoveListener( BOARD_LISTENER* aListener )
{
auto i = std::find( m_listeners.begin(), m_listeners.end(), aListener );
if( i != m_listeners.end() )
{
std::iter_swap( i, m_listeners.end() - 1 );
m_listeners.pop_back();
}
}
void BOARD::RemoveAllListeners()
{
m_listeners.clear();
}
void BOARD::OnItemChanged( BOARD_ITEM* aItem )
{
InvokeListeners( &BOARD_LISTENER::OnBoardItemChanged, *this, aItem );
}
void BOARD::OnItemsChanged( std::vector<BOARD_ITEM*>& aItems )
{
InvokeListeners( &BOARD_LISTENER::OnBoardItemsChanged, *this, aItems );
}
void BOARD::OnItemsCompositeUpdate( std::vector<BOARD_ITEM*>& aAddedItems,
std::vector<BOARD_ITEM*>& aRemovedItems,
std::vector<BOARD_ITEM*>& aChangedItems )
{
InvokeListeners( &BOARD_LISTENER::OnBoardCompositeUpdate, *this, aAddedItems, aRemovedItems,
aChangedItems );
}
void BOARD::OnRatsnestChanged()
{
InvokeListeners( &BOARD_LISTENER::OnBoardRatsnestChanged, *this );
}
void BOARD::ResetNetHighLight()
{
m_highLight.Clear();
m_highLightPrevious.Clear();
InvokeListeners( &BOARD_LISTENER::OnBoardHighlightNetChanged, *this );
}
void BOARD::SetHighLightNet( int aNetCode, bool aMulti )
{
if( !m_highLight.m_netCodes.count( aNetCode ) )
{
if( !aMulti )
m_highLight.m_netCodes.clear();
m_highLight.m_netCodes.insert( aNetCode );
InvokeListeners( &BOARD_LISTENER::OnBoardHighlightNetChanged, *this );
}
}
void BOARD::HighLightON( bool aValue )
{
if( m_highLight.m_highLightOn != aValue )
{
m_highLight.m_highLightOn = aValue;
InvokeListeners( &BOARD_LISTENER::OnBoardHighlightNetChanged, *this );
}
}
wxString BOARD::GroupsSanityCheck( bool repair )
{
if( repair )
{
while( GroupsSanityCheckInternal( repair ) != wxEmptyString )
{};
return wxEmptyString;
}
return GroupsSanityCheckInternal( repair );
}
wxString BOARD::GroupsSanityCheckInternal( bool repair )
{
// Cycle detection
//
// Each group has at most one parent group.
// So we start at group 0 and traverse the parent chain, marking groups seen along the way.
// If we ever see a group that we've already marked, that's a cycle.
// If we reach the end of the chain, we know all groups in that chain are not part of any cycle.
//
// Algorithm below is linear in the # of groups because each group is visited only once.
// There may be extra time taken due to the container access calls and iterators.
//
// Groups we know are cycle free
std::unordered_set<PCB_GROUP*> knownCycleFreeGroups;
// Groups in the current chain we're exploring.
std::unordered_set<PCB_GROUP*> currentChainGroups;
// Groups we haven't checked yet.
std::unordered_set<PCB_GROUP*> toCheckGroups;
// Initialize set of groups and generators to check that could participate in a cycle.
for( PCB_GROUP* group : Groups() )
toCheckGroups.insert( group );
for( PCB_GENERATOR* gen : Generators() )
toCheckGroups.insert( gen );
while( !toCheckGroups.empty() )
{
currentChainGroups.clear();
PCB_GROUP* group = *toCheckGroups.begin();
while( true )
{
if( currentChainGroups.find( group ) != currentChainGroups.end() )
{
if( repair )
Remove( group );
return "Cycle detected in group membership";
}
else if( knownCycleFreeGroups.find( group ) != knownCycleFreeGroups.end() )
{
// Parent is a group we know does not lead to a cycle
break;
}
currentChainGroups.insert( group );
// We haven't visited currIdx yet, so it must be in toCheckGroups
toCheckGroups.erase( group );
group = group->GetParentGroup();
if( !group )
{
// end of chain and no cycles found in this chain
break;
}
}
// No cycles found in chain, so add it to set of groups we know don't participate
// in a cycle.
knownCycleFreeGroups.insert( currentChainGroups.begin(), currentChainGroups.end() );
}
// Success
return "";
}
BOARD::GroupLegalOpsField BOARD::GroupLegalOps( const PCB_SELECTION& selection ) const
{
bool hasGroup = false;
bool hasMember = false;
for( EDA_ITEM* item : selection )
{
if( item->IsBOARD_ITEM() )
{
BOARD_ITEM* board_item = static_cast<BOARD_ITEM*>( item );
if( board_item->Type() == PCB_GROUP_T )
hasGroup = true;
if( board_item->GetParentGroup() )
hasMember = true;
}
}
GroupLegalOpsField legalOps;
legalOps.create = true;
legalOps.removeItems = hasMember;
legalOps.ungroup = hasGroup;
return legalOps;
}
bool BOARD::cmp_items::operator() ( const BOARD_ITEM* a, const BOARD_ITEM* b ) const
{
if( a->Type() != b->Type() )
return a->Type() < b->Type();
if( a->GetLayer() != b->GetLayer() )
return a->GetLayer() < b->GetLayer();
if( a->GetPosition().x != b->GetPosition().x )
return a->GetPosition().x < b->GetPosition().x;
if( a->GetPosition().y != b->GetPosition().y )
return a->GetPosition().y < b->GetPosition().y;
if( a->m_Uuid != b->m_Uuid ) // shopuld be always the case foer valid boards
return a->m_Uuid < b->m_Uuid;
return a < b;
}
bool BOARD::cmp_drawings::operator()( const BOARD_ITEM* aFirst,
const BOARD_ITEM* aSecond ) const
{
if( aFirst->Type() != aSecond->Type() )
return aFirst->Type() < aSecond->Type();
if( aFirst->GetLayer() != aSecond->GetLayer() )
return aFirst->GetLayer() < aSecond->GetLayer();
if( aFirst->Type() == PCB_SHAPE_T )
{
const PCB_SHAPE* shape = static_cast<const PCB_SHAPE*>( aFirst );
const PCB_SHAPE* other = static_cast<const PCB_SHAPE*>( aSecond );
return shape->Compare( other );
}
else if( aFirst->Type() == PCB_TEXT_T || aFirst->Type() == PCB_FIELD_T )
{
const PCB_TEXT* text = static_cast<const PCB_TEXT*>( aFirst );
const PCB_TEXT* other = static_cast<const PCB_TEXT*>( aSecond );
return text->Compare( other );
}
else if( aFirst->Type() == PCB_TEXTBOX_T )
{
const PCB_TEXTBOX* textbox = static_cast<const PCB_TEXTBOX*>( aFirst );
const PCB_TEXTBOX* other = static_cast<const PCB_TEXTBOX*>( aSecond );
return textbox->PCB_SHAPE::Compare( other ) && textbox->EDA_TEXT::Compare( other );
}
else if( aFirst->Type() == PCB_TABLE_T )
{
const PCB_TABLE* table = static_cast<const PCB_TABLE*>( aFirst );
const PCB_TABLE* other = static_cast<const PCB_TABLE*>( aSecond );
return PCB_TABLE::Compare( table, other );
}
return aFirst->m_Uuid < aSecond->m_Uuid;
}
void BOARD::ConvertBrdLayerToPolygonalContours( PCB_LAYER_ID aLayer,
SHAPE_POLY_SET& aOutlines ) const
{
int maxError = GetDesignSettings().m_MaxError;
// convert tracks and vias:
for( const PCB_TRACK* track : m_tracks )
{
if( !track->IsOnLayer( aLayer ) )
continue;
track->TransformShapeToPolygon( aOutlines, aLayer, 0, maxError, ERROR_INSIDE );
}
// convert pads and other copper items in footprints
for( const FOOTPRINT* footprint : m_footprints )
{
footprint->TransformPadsToPolySet( aOutlines, aLayer, 0, maxError, ERROR_INSIDE );
footprint->TransformFPShapesToPolySet( aOutlines, aLayer, 0, maxError, ERROR_INSIDE,
true, /* include text */
true, /* include shapes */
false /* include private items */ );
for( const ZONE* zone : footprint->Zones() )
{
if( zone->GetLayerSet().test( aLayer ) )
zone->TransformSolidAreasShapesToPolygon( aLayer, aOutlines );
}
}
// convert copper zones
for( const ZONE* zone : Zones() )
{
if( zone->GetLayerSet().test( aLayer ) )
zone->TransformSolidAreasShapesToPolygon( aLayer, aOutlines );
}
// convert graphic items on copper layers (texts)
for( const BOARD_ITEM* item : m_drawings )
{
if( !item->IsOnLayer( aLayer ) )
continue;
switch( item->Type() )
{
case PCB_SHAPE_T:
{
const PCB_SHAPE* shape = static_cast<const PCB_SHAPE*>( item );
shape->TransformShapeToPolygon( aOutlines, aLayer, 0, maxError, ERROR_INSIDE );
break;
}
case PCB_FIELD_T:
case PCB_TEXT_T:
{
const PCB_TEXT* text = static_cast<const PCB_TEXT*>( item );
text->TransformTextToPolySet( aOutlines, 0, maxError, ERROR_INSIDE );
break;
}
case PCB_TEXTBOX_T:
{
const PCB_TEXTBOX* textbox = static_cast<const PCB_TEXTBOX*>( item );
// border
textbox->PCB_SHAPE::TransformShapeToPolygon( aOutlines, aLayer, 0, maxError,
ERROR_INSIDE );
// text
textbox->TransformTextToPolySet( aOutlines, 0, maxError, ERROR_INSIDE );
break;
}
case PCB_TABLE_T:
{
const PCB_TABLE* table = static_cast<const PCB_TABLE*>( item );
table->TransformShapeToPolygon( aOutlines, aLayer, 0, maxError, ERROR_INSIDE );
break;
}
case PCB_DIM_ALIGNED_T:
case PCB_DIM_CENTER_T:
case PCB_DIM_RADIAL_T:
case PCB_DIM_ORTHOGONAL_T:
case PCB_DIM_LEADER_T:
{
const PCB_DIMENSION_BASE* dim = static_cast<const PCB_DIMENSION_BASE*>( item );
dim->TransformShapeToPolygon( aOutlines, aLayer, 0, maxError, ERROR_INSIDE );
dim->TransformTextToPolySet( aOutlines, 0, maxError, ERROR_INSIDE );
break;
}
default:
break;
}
}
}
const BOARD_ITEM_SET BOARD::GetItemSet()
{
BOARD_ITEM_SET items;
std::copy( m_tracks.begin(), m_tracks.end(), std::inserter( items, items.end() ) );
std::copy( m_zones.begin(), m_zones.end(), std::inserter( items, items.end() ) );
std::copy( m_footprints.begin(), m_footprints.end(), std::inserter( items, items.end() ) );
std::copy( m_drawings.begin(), m_drawings.end(), std::inserter( items, items.end() ) );
std::copy( m_markers.begin(), m_markers.end(), std::inserter( items, items.end() ) );
std::copy( m_groups.begin(), m_groups.end(), std::inserter( items, items.end() ) );
return items;
}
bool BOARD::operator==( const BOARD_ITEM& aItem ) const
{
if( aItem.Type() != Type() )
return false;
const BOARD& other = static_cast<const BOARD&>( aItem );
if( *m_designSettings != *other.m_designSettings )
return false;
if( m_NetInfo.GetNetCount() != other.m_NetInfo.GetNetCount() )
return false;
const NETNAMES_MAP& thisNetNames = m_NetInfo.NetsByName();
const NETNAMES_MAP& otherNetNames = other.m_NetInfo.NetsByName();
for( auto it1 = thisNetNames.begin(), it2 = otherNetNames.begin();
it1 != thisNetNames.end() && it2 != otherNetNames.end(); ++it1, ++it2 )
{
// We only compare the names in order here, not the index values
// as the index values are auto-generated and the names are not.
if( it1->first != it2->first )
return false;
}
if( m_properties.size() != other.m_properties.size() )
return false;
for( auto it1 = m_properties.begin(), it2 = other.m_properties.begin();
it1 != m_properties.end() && it2 != other.m_properties.end(); ++it1, ++it2 )
{
if( *it1 != *it2 )
return false;
}
if( m_paper.GetCustomHeightMils() != other.m_paper.GetCustomHeightMils() )
return false;
if( m_paper.GetCustomWidthMils() != other.m_paper.GetCustomWidthMils() )
return false;
if( m_paper.GetSizeMils() != other.m_paper.GetSizeMils() )
return false;
if( m_paper.GetPaperId() != other.m_paper.GetPaperId() )
return false;
if( m_paper.GetWxOrientation() != other.m_paper.GetWxOrientation() )
return false;
for( int ii = 0; !m_titles.GetComment( ii ).empty(); ++ii )
{
if( m_titles.GetComment( ii ) != other.m_titles.GetComment( ii ) )
return false;
}
wxArrayString ourVars;
m_titles.GetContextualTextVars( &ourVars );
wxArrayString otherVars;
other.m_titles.GetContextualTextVars( &otherVars );
if( ourVars != otherVars )
return false;
return true;
}