/* * This program source code file is part of KiCad, a free EDA CAD application. * * Copyright (C) 2019-2022 KiCad Developers, see AUTHORS.txt for contributors. * * This program is free software; you can redistribute it and/or * modify it under the terms of the GNU General Public License * as published by the Free Software Foundation; either version 2 * of the License, or (at your option) any later version. * * This program is distributed in the hope that it will be useful, * but WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the * GNU General Public License for more details. * * You should have received a copy of the GNU General Public License * along with this program; if not, you may find one here: * http://www.gnu.org/licenses/old-licenses/gpl-2.0.html * or you may search the http://www.gnu.org website for the version 2 license, * or you may write to the Free Software Foundation, Inc., * 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301, USA */ #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include bool exprFromTo( LIBEVAL::CONTEXT* aCtx, void* self ) { PCB_EXPR_VAR_REF* vref = static_cast( self ); BOARD_ITEM* item = vref ? vref->GetObject( aCtx ) : nullptr; LIBEVAL::VALUE* result = aCtx->AllocValue(); LIBEVAL::VALUE* argTo = aCtx->Pop(); LIBEVAL::VALUE* argFrom = aCtx->Pop(); result->Set(0.0); aCtx->Push( result ); if(!item) return false; auto ftCache = item->GetBoard()->GetConnectivity()->GetFromToCache(); if( !ftCache ) { wxLogWarning( wxT( "Attempting to call fromTo() with non-existent from-to cache, " "aborting..." )); return true; } if( ftCache->IsOnFromToPath( static_cast( item ), argFrom->AsString(), argTo->AsString() ) ) { result->Set(1.0); } return true; } static void existsOnLayer( LIBEVAL::CONTEXT* aCtx, void *self ) { PCB_EXPR_VAR_REF* vref = static_cast( self ); BOARD_ITEM* item = vref ? vref->GetObject( aCtx ) : nullptr; LIBEVAL::VALUE* arg = aCtx->Pop(); LIBEVAL::VALUE* result = aCtx->AllocValue(); result->Set( 0.0 ); aCtx->Push( result ); if( !item ) return; if( !arg ) { if( aCtx->HasErrorCallback() ) { aCtx->ReportError( wxString::Format( _( "Missing argument to '%s'" ), wxT( "existsOnLayer()" ) ) ); } return; } result->SetDeferredEval( [item, arg, aCtx]() -> double { const wxString& layerName = arg->AsString(); wxPGChoices& layerMap = ENUM_MAP::Instance().Choices(); if( aCtx->HasErrorCallback()) { /* * Interpreted version */ bool anyMatch = false; for( unsigned ii = 0; ii < layerMap.GetCount(); ++ii ) { wxPGChoiceEntry& entry = layerMap[ ii ]; if( entry.GetText().Matches( layerName )) { anyMatch = true; if( item->IsOnLayer( ToLAYER_ID( entry.GetValue()))) return 1.0; } } if( !anyMatch ) { aCtx->ReportError( wxString::Format( _( "Unrecognized layer '%s'" ), layerName ) ); } } else { /* * Compiled version */ BOARD* board = item->GetBoard(); std::unique_lock cacheLock( board->m_CachesMutex ); auto i = board->m_LayerExpressionCache.find( layerName ); LSET mask; if( i == board->m_LayerExpressionCache.end() ) { for( unsigned ii = 0; ii < layerMap.GetCount(); ++ii ) { wxPGChoiceEntry& entry = layerMap[ ii ]; if( entry.GetText().Matches( layerName ) ) mask.set( ToLAYER_ID( entry.GetValue() ) ); } board->m_LayerExpressionCache[ layerName ] = mask; } else { mask = i->second; } if( ( item->GetLayerSet() & mask ).any() ) return 1.0; } return 0.0; } ); } static void isPlated( LIBEVAL::CONTEXT* aCtx, void* self ) { LIBEVAL::VALUE* result = aCtx->AllocValue(); result->Set( 0.0 ); aCtx->Push( result ); PCB_EXPR_VAR_REF* vref = static_cast( self ); BOARD_ITEM* item = vref ? vref->GetObject( aCtx ) : nullptr; if( !item ) return; if( item->Type() == PCB_PAD_T && static_cast( item )->GetAttribute() == PAD_ATTRIB::PTH ) result->Set( 1.0 ); else if( item->Type() == PCB_VIA_T ) result->Set( 1.0 ); } bool calcIsInsideCourtyard( BOARD_ITEM* aItem, const EDA_RECT& aItemBBox, std::shared_ptr& aItemShape, PCB_EXPR_CONTEXT* aCtx, FOOTPRINT* aFootprint, PCB_LAYER_ID aSide ) { SHAPE_POLY_SET footprintCourtyard; footprintCourtyard = aFootprint->GetCourtyard( aSide ); if( !aFootprint->GetBoundingBox().Intersects( aItemBBox ) ) return false; if( !aItemShape ) aItemShape = aItem->GetEffectiveShape( aCtx->GetLayer() ); return footprintCourtyard.Collide( aItemShape.get() ); }; bool isInsideCourtyard( BOARD_ITEM* aItem, const EDA_RECT& aItemBBox, std::shared_ptr& aItemShape, PCB_EXPR_CONTEXT* aCtx, FOOTPRINT* aFootprint, PCB_LAYER_ID aSide ) { if( !aFootprint ) return false; BOARD* board = aItem->GetBoard(); std::unique_lock cacheLock( board->m_CachesMutex ); std::pair key( aFootprint, aItem ); std::map< std::pair, bool >* cache; switch( aSide ) { case F_Cu: cache = &board->m_InsideFCourtyardCache; break; case B_Cu: cache = &board->m_InsideBCourtyardCache; break; default: cache = &board->m_InsideCourtyardCache; break; } auto i = cache->find( key ); if( i != cache->end() ) return i->second; bool res = calcIsInsideCourtyard( aItem, aItemBBox, aItemShape, aCtx, aFootprint, aSide ); (*cache)[ key ] = res; return res; }; static void insideCourtyard( LIBEVAL::CONTEXT* aCtx, void* self ) { PCB_EXPR_CONTEXT* context = static_cast( aCtx ); LIBEVAL::VALUE* arg = aCtx->Pop(); LIBEVAL::VALUE* result = aCtx->AllocValue(); result->Set( 0.0 ); aCtx->Push( result ); if( !arg ) { if( aCtx->HasErrorCallback() ) { aCtx->ReportError( wxString::Format( _( "Missing argument to '%s'" ), wxT( "insideCourtyard()" ) ) ); } return; } PCB_EXPR_VAR_REF* vref = static_cast( self ); BOARD_ITEM* item = vref ? vref->GetObject( aCtx ) : nullptr; if( !item ) return; result->SetDeferredEval( [item, arg, context]() -> double { BOARD* board = item->GetBoard(); EDA_RECT itemBBox; std::shared_ptr itemShape; if( item->Type() == PCB_ZONE_T || item->Type() == PCB_FP_ZONE_T ) itemBBox = static_cast( item )->GetCachedBoundingBox(); else itemBBox = item->GetBoundingBox(); if( arg->AsString() == wxT( "A" ) ) { FOOTPRINT* fp = dynamic_cast( context->GetItem( 0 ) ); if( isInsideCourtyard( item, itemBBox, itemShape, context, fp, In1_Cu ) ) return 1.0; } else if( arg->AsString() == wxT( "B" ) ) { FOOTPRINT* fp = dynamic_cast( context->GetItem( 1 ) ); if( isInsideCourtyard( item, itemBBox, itemShape, context, fp, In1_Cu ) ) return 1.0; } else for( FOOTPRINT* fp : board->Footprints() ) { if( fp->GetReference().Matches( arg->AsString() ) ) { if( isInsideCourtyard( item, itemBBox, itemShape, context, fp, In1_Cu ) ) return 1.0; } } return 0.0; } ); } static void insideFrontCourtyard( LIBEVAL::CONTEXT* aCtx, void* self ) { PCB_EXPR_CONTEXT* context = static_cast( aCtx ); LIBEVAL::VALUE* arg = aCtx->Pop(); LIBEVAL::VALUE* result = aCtx->AllocValue(); result->Set( 0.0 ); aCtx->Push( result ); if( !arg ) { if( aCtx->HasErrorCallback() ) { aCtx->ReportError( wxString::Format( _( "Missing argument to '%s'" ), wxT( "insideFrontCourtyard()" ) ) ); } return; } PCB_EXPR_VAR_REF* vref = static_cast( self ); BOARD_ITEM* item = vref ? vref->GetObject( aCtx ) : nullptr; if( !item ) return; result->SetDeferredEval( [item, arg, context]() -> double { BOARD* board = item->GetBoard(); EDA_RECT itemBBox; std::shared_ptr itemShape; if( item->Type() == PCB_ZONE_T || item->Type() == PCB_FP_ZONE_T ) itemBBox = static_cast( item )->GetCachedBoundingBox(); else itemBBox = item->GetBoundingBox(); if( arg->AsString() == wxT( "A" ) ) { FOOTPRINT* fp = dynamic_cast( context->GetItem( 0 ) ); if( isInsideCourtyard( item, itemBBox, itemShape, context, fp, F_Cu ) ) return 1.0; } else if( arg->AsString() == wxT( "B" ) ) { FOOTPRINT* fp = dynamic_cast( context->GetItem( 1 ) ); if( isInsideCourtyard( item, itemBBox, itemShape, context, fp, F_Cu ) ) return 1.0; } else for( FOOTPRINT* fp : board->Footprints() ) { if( fp->GetReference().Matches( arg->AsString() ) ) { if( isInsideCourtyard( item, itemBBox, itemShape, context, fp, F_Cu ) ) return 1.0; } } return 0.0; } ); } static void insideBackCourtyard( LIBEVAL::CONTEXT* aCtx, void* self ) { PCB_EXPR_CONTEXT* context = static_cast( aCtx ); LIBEVAL::VALUE* arg = aCtx->Pop(); LIBEVAL::VALUE* result = aCtx->AllocValue(); result->Set( 0.0 ); aCtx->Push( result ); if( !arg ) { if( aCtx->HasErrorCallback() ) { aCtx->ReportError( wxString::Format( _( "Missing argument to '%s'" ), wxT( "insideBackCourtyard()" ) ) ); } return; } PCB_EXPR_VAR_REF* vref = static_cast( self ); BOARD_ITEM* item = vref ? vref->GetObject( aCtx ) : nullptr; if( !item ) return; result->SetDeferredEval( [item, arg, context]() -> double { BOARD* board = item->GetBoard(); EDA_RECT itemBBox; std::shared_ptr itemShape; if( item->Type() == PCB_ZONE_T || item->Type() == PCB_FP_ZONE_T ) itemBBox = static_cast( item )->GetCachedBoundingBox(); else itemBBox = item->GetBoundingBox(); if( arg->AsString() == wxT( "A" ) ) { FOOTPRINT* fp = dynamic_cast( context->GetItem( 0 ) ); if( isInsideCourtyard( item, itemBBox, itemShape, context, fp, B_Cu ) ) return 1.0; } else if( arg->AsString() == wxT( "B" ) ) { FOOTPRINT* fp = dynamic_cast( context->GetItem( 1 ) ); if( isInsideCourtyard( item, itemBBox, itemShape, context, fp, B_Cu ) ) return 1.0; } else for( FOOTPRINT* fp : board->Footprints() ) { if( fp->GetReference().Matches( arg->AsString() ) ) { if( isInsideCourtyard( item, itemBBox, itemShape, context, fp, B_Cu ) ) return 1.0; } } return 0.0; } ); } bool calcIsInsideArea( BOARD_ITEM* aItem, const EDA_RECT& aItemBBox, PCB_EXPR_CONTEXT* aCtx, ZONE* aArea ) { BOARD* board = aArea->GetBoard(); EDA_RECT areaBBox = aArea->GetBoundingBox(); std::shared_ptr shape; if( !areaBBox.Intersects( aItemBBox ) ) return false; // Collisions include touching, so we need to deflate outline by enough to exclude it. // This is particularly important for detecting copper fills as they will be exactly // touching along the entire exclusion border. SHAPE_POLY_SET areaOutline = *aArea->Outline(); areaOutline.Deflate( board->GetDesignSettings().GetDRCEpsilon(), 0, SHAPE_POLY_SET::ALLOW_ACUTE_CORNERS ); if( aItem->GetFlags() & HOLE_PROXY ) { if( aItem->Type() == PCB_PAD_T ) { PAD* pad = static_cast( aItem ); const SHAPE_SEGMENT* holeShape = pad->GetEffectiveHoleShape(); return areaOutline.Collide( holeShape ); } else if( aItem->Type() == PCB_VIA_T ) { PCB_VIA* via = static_cast( aItem ); const SHAPE_CIRCLE holeShape( via->GetPosition(), via->GetDrillValue() ); LSET overlap = via->GetLayerSet() & aArea->GetLayerSet(); /// Avoid buried vias that don't overlap the zone's layers if( overlap.count() > 0 ) { if( aCtx->GetLayer() == UNDEFINED_LAYER || overlap.Contains( aCtx->GetLayer() ) ) return areaOutline.Collide( &holeShape ); } } return false; } if( aItem->Type() == PCB_FOOTPRINT_T ) { FOOTPRINT* footprint = static_cast( aItem ); if( ( footprint->GetFlags() & MALFORMED_COURTYARDS ) != 0 ) { if( aCtx->HasErrorCallback() ) { aCtx->ReportError( _( "Footprint's courtyard is not a single, closed shape." ) ); } return false; } if( ( aArea->GetLayerSet() & LSET::FrontMask() ).any() ) { const SHAPE_POLY_SET& courtyard = footprint->GetCourtyard( F_CrtYd ); if( courtyard.OutlineCount() == 0 ) { if( aCtx->HasErrorCallback() ) aCtx->ReportError( _( "Footprint has no front courtyard." ) ); return false; } else { return areaOutline.Collide( &courtyard.Outline( 0 ) ); } } if( ( aArea->GetLayerSet() & LSET::BackMask() ).any() ) { const SHAPE_POLY_SET& courtyard = footprint->GetCourtyard( B_CrtYd ); if( courtyard.OutlineCount() == 0 ) { if( aCtx->HasErrorCallback() ) aCtx->ReportError( _( "Footprint has no back courtyard." ) ); return false; } else { return areaOutline.Collide( &courtyard.Outline( 0 ) ); } } return false; } if( aItem->Type() == PCB_ZONE_T || aItem->Type() == PCB_FP_ZONE_T ) { ZONE* zone = static_cast( aItem ); if( !zone->IsFilled() ) return false; DRC_RTREE* zoneRTree = board->m_CopperZoneRTrees[ zone ].get(); std::vector shapes; if( zoneRTree ) { for( PCB_LAYER_ID layer : aArea->GetLayerSet().Seq() ) { if( aCtx->GetLayer() == layer || aCtx->GetLayer() == UNDEFINED_LAYER ) { if( zoneRTree->QueryColliding( areaBBox, &areaOutline, layer ) ) return true; } } } return false; } else { PCB_LAYER_ID layer = aCtx->GetLayer(); if( layer != UNDEFINED_LAYER && !( aArea->GetLayerSet().Contains( layer ) ) ) return false; if( !shape ) shape = aItem->GetEffectiveShape( layer ); return areaOutline.Collide( shape.get() ); } } bool isInsideArea( BOARD_ITEM* aItem, const EDA_RECT& aItemBBox, PCB_EXPR_CONTEXT* aCtx, ZONE* aArea ) { if( !aArea || aArea == aItem || aArea->GetParent() == aItem ) return false; if( !( aArea->GetLayerSet() & aItem->GetLayerSet() ).any() ) return false; BOARD* board = aArea->GetBoard(); std::unique_lock cacheLock( board->m_CachesMutex ); PCB_LAYER_ID layer = aCtx->GetLayer(); std::tuple key( aArea, aItem, layer ); auto i = board->m_InsideAreaCache.find( key ); if( i != board->m_InsideAreaCache.end() ) return i->second; bool isInside = calcIsInsideArea( aItem, aItemBBox, aCtx, aArea ); board->m_InsideAreaCache[ key ] = isInside; return isInside; } static void insideArea( LIBEVAL::CONTEXT* aCtx, void* self ) { PCB_EXPR_CONTEXT* context = static_cast( aCtx ); LIBEVAL::VALUE* arg = aCtx->Pop(); LIBEVAL::VALUE* result = aCtx->AllocValue(); result->Set( 0.0 ); aCtx->Push( result ); if( !arg ) { if( aCtx->HasErrorCallback() ) { aCtx->ReportError( wxString::Format( _( "Missing argument to '%s'" ), wxT( "insideArea()" ) ) ); } return; } PCB_EXPR_VAR_REF* vref = static_cast( self ); BOARD_ITEM* item = vref ? vref->GetObject( aCtx ) : nullptr; if( !item ) return; result->SetDeferredEval( [item, arg, context]() -> double { BOARD* board = item->GetBoard(); EDA_RECT itemBBox; if( item->Type() == PCB_ZONE_T || item->Type() == PCB_FP_ZONE_T ) itemBBox = static_cast( item )->GetCachedBoundingBox(); else itemBBox = item->GetBoundingBox(); if( arg->AsString() == wxT( "A" ) ) { ZONE* zone = dynamic_cast( context->GetItem( 0 ) ); return isInsideArea( item, itemBBox, context, zone ) ? 1.0 : 0.0; } else if( arg->AsString() == wxT( "B" ) ) { ZONE* zone = dynamic_cast( context->GetItem( 1 ) ); return isInsideArea( item, itemBBox, context, zone ) ? 1.0 : 0.0; } else if( KIID::SniffTest( arg->AsString() ) ) { KIID target( arg->AsString()); for( ZONE* area : board->Zones() ) { // Only a single zone can match the UUID; exit once we find a match whether // "inside" or not if( area->m_Uuid == target ) return isInsideArea( item, itemBBox, context, area ) ? 1.0 : 0.0; } for( FOOTPRINT* footprint : board->Footprints() ) { for( ZONE* area : footprint->Zones() ) { // Only a single zone can match the UUID; exit once we find a match // whether "inside" or not if( area->m_Uuid == target ) return isInsideArea( item, itemBBox, context, area ) ? 1.0 : 0.0; } } return 0.0; } else // Match on zone name { for( ZONE* area : board->Zones()) { if( area->GetZoneName().Matches( arg->AsString() ) ) { // Many zones can match the name; exit only when we find an "inside" if( isInsideArea( item, itemBBox, context, area ) ) return 1.0; } } for( FOOTPRINT* footprint : board->Footprints() ) { for( ZONE* area : footprint->Zones() ) { // Many zones can match the name; exit only when we find an "inside" if( area->GetZoneName().Matches( arg->AsString() ) ) { if( isInsideArea( item, itemBBox, context, area ) ) return 1.0; } } } return 0.0; } } ); } static void memberOf( LIBEVAL::CONTEXT* aCtx, void* self ) { LIBEVAL::VALUE* arg = aCtx->Pop(); LIBEVAL::VALUE* result = aCtx->AllocValue(); result->Set( 0.0 ); aCtx->Push( result ); if( !arg ) { if( aCtx->HasErrorCallback() ) { aCtx->ReportError( wxString::Format( _( "Missing argument to '%s'" ), wxT( "memberOf()" ) ) ); } return; } PCB_EXPR_VAR_REF* vref = static_cast( self ); BOARD_ITEM* item = vref ? vref->GetObject( aCtx ) : nullptr; if( !item ) return; result->SetDeferredEval( [item, arg]() -> double { PCB_GROUP* group = item->GetParentGroup(); if( !group && item->GetParent() && item->GetParent()->Type() == PCB_FOOTPRINT_T ) group = item->GetParent()->GetParentGroup(); while( group ) { if( group->GetName().Matches( arg->AsString() ) ) return 1.0; group = group->GetParentGroup(); } return 0.0; } ); } static void isMicroVia( LIBEVAL::CONTEXT* aCtx, void* self ) { PCB_EXPR_VAR_REF* vref = static_cast( self ); BOARD_ITEM* item = vref ? vref->GetObject( aCtx ) : nullptr; LIBEVAL::VALUE* result = aCtx->AllocValue(); result->Set( 0.0 ); aCtx->Push( result ); PCB_VIA* via = dyn_cast( item ); if( via && via->GetViaType() == VIATYPE::MICROVIA ) result->Set ( 1.0 ); } static void isBlindBuriedVia( LIBEVAL::CONTEXT* aCtx, void* self ) { PCB_EXPR_VAR_REF* vref = static_cast( self ); BOARD_ITEM* item = vref ? vref->GetObject( aCtx ) : nullptr; LIBEVAL::VALUE* result = aCtx->AllocValue(); result->Set( 0.0 ); aCtx->Push( result ); PCB_VIA* via = dyn_cast( item ); if( via && via->GetViaType() == VIATYPE::BLIND_BURIED ) result->Set ( 1.0 ); } static void isCoupledDiffPair( LIBEVAL::CONTEXT* aCtx, void* self ) { PCB_EXPR_CONTEXT* context = static_cast( aCtx ); BOARD_CONNECTED_ITEM* a = dynamic_cast( context->GetItem( 0 ) ); BOARD_CONNECTED_ITEM* b = dynamic_cast( context->GetItem( 1 ) ); LIBEVAL::VALUE* result = aCtx->AllocValue(); result->Set( 0.0 ); aCtx->Push( result ); result->SetDeferredEval( [a, b, context]() -> double { NETINFO_ITEM* netinfo = a ? a->GetNet() : nullptr; if( !netinfo ) return 0.0; wxString coupledNet; wxString dummy; if( !DRC_ENGINE::MatchDpSuffix( netinfo->GetNetname(), coupledNet, dummy ) ) return 0.0; if( context->GetConstraint() == DRC_CONSTRAINT_T::LENGTH_CONSTRAINT || context->GetConstraint() == DRC_CONSTRAINT_T::SKEW_CONSTRAINT ) { // DRC engine evaluates these singly, so we won't have a B item return 1.0; } return b && b->GetNetname() == coupledNet; } ); } static void inDiffPair( LIBEVAL::CONTEXT* aCtx, void* self ) { LIBEVAL::VALUE* argv = aCtx->Pop(); PCB_EXPR_VAR_REF* vref = static_cast( self ); BOARD_ITEM* item = vref ? vref->GetObject( aCtx ) : nullptr; LIBEVAL::VALUE* result = aCtx->AllocValue(); result->Set( 0.0 ); aCtx->Push( result ); if( !argv ) { if( aCtx->HasErrorCallback() ) { aCtx->ReportError( wxString::Format( _( "Missing argument to '%s'" ), wxT( "inDiffPair()" ) ) ); } return; } if( !item || !item->GetBoard() ) return; result->SetDeferredEval( [item, argv]() -> double { if( item && item->IsConnected() ) { NETINFO_ITEM* netinfo = static_cast( item )->GetNet(); wxString refName = netinfo->GetNetname(); wxString arg = argv->AsString(); wxString baseName, coupledNet; int polarity = DRC_ENGINE::MatchDpSuffix( refName, coupledNet, baseName ); if( polarity != 0 && item->GetBoard()->FindNet( coupledNet ) ) { if( baseName.Matches( arg ) ) return 1.0; if( baseName.EndsWith( "_" ) && baseName.BeforeLast( '_' ).Matches( arg ) ) return 1.0; } } return 0.0; } ); } PCB_EXPR_BUILTIN_FUNCTIONS::PCB_EXPR_BUILTIN_FUNCTIONS() { RegisterAllFunctions(); } void PCB_EXPR_BUILTIN_FUNCTIONS::RegisterAllFunctions() { m_funcs.clear(); RegisterFunc( wxT( "existsOnLayer('x')" ), existsOnLayer ); RegisterFunc( wxT( "isPlated()" ), isPlated ); RegisterFunc( wxT( "insideCourtyard('x')" ), insideCourtyard ); RegisterFunc( wxT( "insideFrontCourtyard('x')" ), insideFrontCourtyard ); RegisterFunc( wxT( "insideBackCourtyard('x')" ), insideBackCourtyard ); RegisterFunc( wxT( "insideArea('x')" ), insideArea ); RegisterFunc( wxT( "isMicroVia()" ), isMicroVia ); RegisterFunc( wxT( "isBlindBuriedVia()" ), isBlindBuriedVia ); RegisterFunc( wxT( "memberOf('x')" ), memberOf ); RegisterFunc( wxT( "fromTo('x','y')" ), exprFromTo ); RegisterFunc( wxT( "isCoupledDiffPair()" ), isCoupledDiffPair ); RegisterFunc( wxT( "inDiffPair('x')" ), inDiffPair ); } BOARD_ITEM* PCB_EXPR_VAR_REF::GetObject( const LIBEVAL::CONTEXT* aCtx ) const { wxASSERT( dynamic_cast( aCtx ) ); const PCB_EXPR_CONTEXT* ctx = static_cast( aCtx ); BOARD_ITEM* item = ctx->GetItem( m_itemIndex ); return item; } class PCB_LAYER_VALUE : public LIBEVAL::VALUE { public: PCB_LAYER_VALUE( PCB_LAYER_ID aLayer ) : LIBEVAL::VALUE( LayerName( aLayer ) ), m_layer( aLayer ) {}; virtual bool EqualTo( LIBEVAL::CONTEXT* aCtx, const VALUE* b ) const override { // For boards with user-defined layer names there will be 2 entries for each layer // in the ENUM_MAP: one for the canonical layer name and one for the user layer name. // We need to check against both. wxPGChoices& layerMap = ENUM_MAP::Instance().Choices(); const wxString& layerName = b->AsString(); BOARD* board = static_cast( aCtx )->GetBoard(); std::unique_lock cacheLock( board->m_CachesMutex ); auto i = board->m_LayerExpressionCache.find( layerName ); LSET mask; if( i == board->m_LayerExpressionCache.end() ) { for( unsigned ii = 0; ii < layerMap.GetCount(); ++ii ) { wxPGChoiceEntry& entry = layerMap[ii]; if( entry.GetText().Matches( layerName ) ) mask.set( ToLAYER_ID( entry.GetValue() ) ); } board->m_LayerExpressionCache[ layerName ] = mask; } else { mask = i->second; } return mask.Contains( m_layer ); } protected: PCB_LAYER_ID m_layer; }; LIBEVAL::VALUE* PCB_EXPR_VAR_REF::GetValue( LIBEVAL::CONTEXT* aCtx ) { PCB_EXPR_CONTEXT* context = static_cast( aCtx ); if( m_itemIndex == 2 ) return new PCB_LAYER_VALUE( context->GetLayer() ); BOARD_ITEM* item = GetObject( aCtx ); if( !item ) return new LIBEVAL::VALUE(); auto it = m_matchingTypes.find( TYPE_HASH( *item ) ); if( it == m_matchingTypes.end() ) { // Don't force user to type "A.Type == 'via' && A.Via_Type == 'buried'" when the // simpler "A.Via_Type == 'buried'" is perfectly clear. Instead, return an undefined // value when the property doesn't appear on a particular object. return new LIBEVAL::VALUE(); } else { if( m_type == LIBEVAL::VT_NUMERIC ) return new LIBEVAL::VALUE( (double) item->Get( it->second ) ); else { wxString str; if( !m_isEnum ) { str = item->Get( it->second ); return new LIBEVAL::VALUE( str ); } else { const wxAny& any = item->Get( it->second ); bool valid = any.GetAs( &str ); if( valid ) { if( it->second->Name() == wxT( "Layer" ) ) return new PCB_LAYER_VALUE( context->GetBoard()->GetLayerID( str ) ); else return new LIBEVAL::VALUE( str ); } } return new LIBEVAL::VALUE(); } } } LIBEVAL::VALUE* PCB_EXPR_NETCLASS_REF::GetValue( LIBEVAL::CONTEXT* aCtx ) { BOARD_ITEM* item = GetObject( aCtx ); if( !item ) return new LIBEVAL::VALUE(); if( item->IsConnected() ) return new LIBEVAL::VALUE( static_cast( item )->GetNetClassName() ); else return new LIBEVAL::VALUE(); } LIBEVAL::VALUE* PCB_EXPR_NETNAME_REF::GetValue( LIBEVAL::CONTEXT* aCtx ) { BOARD_ITEM* item = GetObject( aCtx ); if( !item ) return new LIBEVAL::VALUE(); if( item->IsConnected() ) return new LIBEVAL::VALUE( static_cast( item )->GetNetname() ); else return new LIBEVAL::VALUE(); } LIBEVAL::VALUE* PCB_EXPR_TYPE_REF::GetValue( LIBEVAL::CONTEXT* aCtx ) { BOARD_ITEM* item = GetObject( aCtx ); if( !item ) return new LIBEVAL::VALUE(); return new LIBEVAL::VALUE( ENUM_MAP::Instance().ToString( item->Type() ) ); } LIBEVAL::FUNC_CALL_REF PCB_EXPR_UCODE::CreateFuncCall( const wxString& aName ) { PCB_EXPR_BUILTIN_FUNCTIONS& registry = PCB_EXPR_BUILTIN_FUNCTIONS::Instance(); return registry.Get( aName.Lower() ); } std::unique_ptr PCB_EXPR_UCODE::CreateVarRef( const wxString& aVar, const wxString& aField ) { PROPERTY_MANAGER& propMgr = PROPERTY_MANAGER::Instance(); std::unique_ptr vref; // Check for a couple of very common cases and compile them straight to "object code". if( aField.CmpNoCase( wxT( "NetClass" ) ) == 0 ) { if( aVar == wxT( "A" ) ) return std::make_unique( 0 ); else if( aVar == wxT( "B" ) ) return std::make_unique( 1 ); else return nullptr; } else if( aField.CmpNoCase( wxT( "NetName" ) ) == 0 ) { if( aVar == wxT( "A" ) ) return std::make_unique( 0 ); else if( aVar == wxT( "B" ) ) return std::make_unique( 1 ); else return nullptr; } else if( aField.CmpNoCase( wxT( "Type" ) ) == 0 ) { if( aVar == wxT( "A" ) ) return std::make_unique( 0 ); else if( aVar == wxT( "B" ) ) return std::make_unique( 1 ); else return nullptr; } if( aVar == wxT( "A" ) || aVar == wxT( "AB" ) ) vref = std::make_unique( 0 ); else if( aVar == wxT( "B" ) ) vref = std::make_unique( 1 ); else if( aVar == wxT( "L" ) ) vref = std::make_unique( 2 ); else return nullptr; if( aField.length() == 0 ) // return reference to base object { return std::move( vref ); } wxString field( aField ); field.Replace( wxT( "_" ), wxT( " " ) ); for( const PROPERTY_MANAGER::CLASS_INFO& cls : propMgr.GetAllClasses() ) { if( propMgr.IsOfType( cls.type, TYPE_HASH( BOARD_ITEM ) ) ) { PROPERTY_BASE* prop = propMgr.GetProperty( cls.type, field ); if( prop ) { vref->AddAllowedClass( cls.type, prop ); if( prop->TypeHash() == TYPE_HASH( int ) ) { vref->SetType( LIBEVAL::VT_NUMERIC ); } else if( prop->TypeHash() == TYPE_HASH( wxString ) ) { vref->SetType( LIBEVAL::VT_STRING ); } else if ( prop->HasChoices() ) { // it's an enum, we treat it as string vref->SetType( LIBEVAL::VT_STRING ); vref->SetIsEnum ( true ); } else { wxFAIL_MSG( wxT( "PCB_EXPR_UCODE::createVarRef: Unknown property type." ) ); } } } } if( vref->GetType() == LIBEVAL::VT_UNDEFINED ) vref->SetType( LIBEVAL::VT_PARSE_ERROR ); return std::move( vref ); } BOARD* PCB_EXPR_CONTEXT::GetBoard() const { if( m_items[0] ) return m_items[0]->GetBoard(); return nullptr; } class PCB_UNIT_RESOLVER : public LIBEVAL::UNIT_RESOLVER { public: virtual ~PCB_UNIT_RESOLVER() { } virtual const std::vector& GetSupportedUnits() const override { static const std::vector pcbUnits = { wxT( "mil" ), wxT( "mm" ), wxT( "in" ) }; return pcbUnits; } virtual wxString GetSupportedUnitsMessage() const override { return _( "must be mm, in, or mil" ); } virtual double Convert( const wxString& aString, int unitId ) const override { double v = wxAtof( aString ); switch( unitId ) { case 0: return DoubleValueFromString( EDA_UNITS::MILS, aString ); case 1: return DoubleValueFromString( EDA_UNITS::MILLIMETRES, aString ); case 2: return DoubleValueFromString( EDA_UNITS::INCHES, aString ); default: return v; } }; }; PCB_EXPR_COMPILER::PCB_EXPR_COMPILER() { m_unitResolver = std::make_unique(); } PCB_EXPR_EVALUATOR::PCB_EXPR_EVALUATOR() : m_result( 0 ), m_compiler(), m_ucode(), m_errorStatus() { } PCB_EXPR_EVALUATOR::~PCB_EXPR_EVALUATOR() { } bool PCB_EXPR_EVALUATOR::Evaluate( const wxString& aExpr ) { PCB_EXPR_UCODE ucode; PCB_EXPR_CONTEXT preflightContext( NULL_CONSTRAINT, F_Cu ); if( !m_compiler.Compile( aExpr.ToUTF8().data(), &ucode, &preflightContext ) ) return false; PCB_EXPR_CONTEXT evaluationContext( NULL_CONSTRAINT, F_Cu ); LIBEVAL::VALUE* result = ucode.Run( &evaluationContext ); if( result->GetType() == LIBEVAL::VT_NUMERIC ) m_result = KiROUND( result->AsDouble() ); return true; }