/* * This program source code file is part of KiCad, a free EDA CAD application. * * Copyright (C) 2004-2019 Jean-Pierre Charras, jp.charras at wanadoo.fr * Copyright (C) 2014 Dick Hollenbeck, dick@softplc.com * Copyright (C) 2017-2020 KiCad Developers, see change_log.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 #include #include #include #include #include #include #include #include // for KiROUND #include #include #include #include #include #include #include DRC::DRC() : PCB_TOOL_BASE( "pcbnew.DRCTool" ), m_pcbEditorFrame( nullptr ), m_pcb( nullptr ), m_drcDialog( nullptr ) { // establish initial values for everything: m_doPad2PadTest = true; // enable pad to pad clearance tests m_doUnconnectedTest = true; // enable unconnected tests m_doZonesTest = false; // disable zone to items clearance tests m_doKeepoutTest = true; // enable keepout areas to items clearance tests m_refillZones = false; // Only fill zones if requested by user. m_reportAllTrackErrors = false; m_testFootprints = false; m_drcRun = false; m_footprintsTested = false; } DRC::~DRC() { for( DRC_ITEM* unconnectedItem : m_unconnected ) delete unconnectedItem; for( DRC_ITEM* footprintItem : m_footprints ) delete footprintItem; } void DRC::Reset( RESET_REASON aReason ) { m_pcbEditorFrame = getEditFrame(); if( aReason == MODEL_RELOAD ) { if( m_drcDialog ) DestroyDRCDialog( wxID_OK ); m_pcb = m_pcbEditorFrame->GetBoard(); } } void DRC::ShowDRCDialog( wxWindow* aParent ) { bool show_dlg_modal = true; // the dialog needs a parent frame. if it is not specified, this is // the PCB editor frame specified in DRC class. if( !aParent ) { // if any parent is specified, the dialog is modal. // if this is the default PCB editor frame, it is not modal show_dlg_modal = false; aParent = m_pcbEditorFrame; } Activate(); m_toolMgr->RunAction( PCB_ACTIONS::selectionClear, true ); if( !m_drcDialog ) { m_drcDialog = new DIALOG_DRC( this, m_pcbEditorFrame, aParent ); updatePointers(); if( show_dlg_modal ) m_drcDialog->ShowModal(); else m_drcDialog->Show( true ); } else // The dialog is just not visible (because the user has double clicked on an error item) { updatePointers(); m_drcDialog->Show( true ); } } int DRC::ShowDRCDialog( const TOOL_EVENT& aEvent ) { ShowDRCDialog( nullptr ); return 0; } bool DRC::IsDRCDialogShown() { if( m_drcDialog ) return m_drcDialog->IsShown(); return false; } void DRC::addMarkerToPcb( MARKER_PCB* aMarker ) { if( m_pcb->GetDesignSettings().Ignore( aMarker->GetRCItem()->GetErrorCode() ) ) { delete aMarker; return; } BOARD_COMMIT commit( m_pcbEditorFrame ); commit.Add( aMarker ); commit.Push( wxEmptyString, false, false ); } void DRC::DestroyDRCDialog( int aReason ) { if( m_drcDialog ) { m_drcDialog->Destroy(); m_drcDialog = nullptr; } } int DRC::TestZoneToZoneOutlines() { BOARD* board = m_pcbEditorFrame->GetBoard(); int nerrors = 0; wxString msg; std::vector smoothed_polys; smoothed_polys.resize( board->GetAreaCount() ); for( int ia = 0; ia < board->GetAreaCount(); ia++ ) { ZONE_CONTAINER* zoneRef = board->GetArea( ia ); std::set colinearCorners; zoneRef->GetColinearCorners( board, colinearCorners ); zoneRef->BuildSmoothedPoly( smoothed_polys[ia], &colinearCorners ); } // iterate through all areas for( int ia = 0; ia < board->GetAreaCount(); ia++ ) { ZONE_CONTAINER* zoneRef = board->GetArea( ia ); if( !zoneRef->IsOnCopperLayer() ) continue; // If we are testing a single zone, then iterate through all other zones // Otherwise, we have already tested the zone combination for( int ia2 = ia + 1; ia2 < board->GetAreaCount(); ia2++ ) { ZONE_CONTAINER* zoneToTest = board->GetArea( ia2 ); if( zoneRef == zoneToTest ) continue; // test for same layer if( zoneRef->GetLayer() != zoneToTest->GetLayer() ) continue; // Test for same net if( zoneRef->GetNetCode() == zoneToTest->GetNetCode() && zoneRef->GetNetCode() >= 0 ) continue; // test for different priorities if( zoneRef->GetPriority() != zoneToTest->GetPriority() ) continue; // test for different types if( zoneRef->GetIsKeepout() != zoneToTest->GetIsKeepout() ) continue; // Examine a candidate zone: compare zoneToTest to zoneRef // Get clearance used in zone to zone test. The policy used to // obtain that value is now part of the zone object itself by way of // ZONE_CONTAINER::GetClearance(). wxString clearanceSource; int zone2zoneClearance = zoneRef->GetClearance( zoneToTest, &clearanceSource ); // Keepout areas have no clearance, so set zone2zoneClearance to 1 // ( zone2zoneClearance = 0 can create problems in test functions) if( zoneRef->GetIsKeepout() ) zone2zoneClearance = 1; // test for some corners of zoneRef inside zoneToTest for( auto iterator = smoothed_polys[ia].IterateWithHoles(); iterator; iterator++ ) { VECTOR2I currentVertex = *iterator; wxPoint pt( currentVertex.x, currentVertex.y ); if( smoothed_polys[ia2].Contains( currentVertex ) ) { DRC_ITEM* drcItem = new DRC_ITEM( DRCE_ZONES_INTERSECT ); drcItem->SetItems( zoneRef, zoneToTest ); MARKER_PCB* marker = new MARKER_PCB( drcItem, pt ); addMarkerToPcb( marker ); nerrors++; } } // test for some corners of zoneToTest inside zoneRef for( auto iterator = smoothed_polys[ia2].IterateWithHoles(); iterator; iterator++ ) { VECTOR2I currentVertex = *iterator; wxPoint pt( currentVertex.x, currentVertex.y ); if( smoothed_polys[ia].Contains( currentVertex ) ) { DRC_ITEM* drcItem = new DRC_ITEM( DRCE_ZONES_INTERSECT ); drcItem->SetItems( zoneToTest, zoneRef ); MARKER_PCB* marker = new MARKER_PCB( drcItem, pt ); addMarkerToPcb( marker ); nerrors++; } } // Iterate through all the segments of refSmoothedPoly std::map conflictPoints; for( auto refIt = smoothed_polys[ia].IterateSegmentsWithHoles(); refIt; refIt++ ) { // Build ref segment SEG refSegment = *refIt; // Iterate through all the segments in smoothed_polys[ia2] for( auto testIt = smoothed_polys[ia2].IterateSegmentsWithHoles(); testIt; testIt++ ) { // Build test segment SEG testSegment = *testIt; wxPoint pt; int ax1, ay1, ax2, ay2; ax1 = refSegment.A.x; ay1 = refSegment.A.y; ax2 = refSegment.B.x; ay2 = refSegment.B.y; int bx1, by1, bx2, by2; bx1 = testSegment.A.x; by1 = testSegment.A.y; bx2 = testSegment.B.x; by2 = testSegment.B.y; int d = GetClearanceBetweenSegments( bx1, by1, bx2, by2, 0, ax1, ay1, ax2, ay2, 0, zone2zoneClearance, &pt.x, &pt.y ); if( d < zone2zoneClearance ) { if( conflictPoints.count( pt ) ) conflictPoints[ pt ] = std::min( conflictPoints[ pt ], d ); else conflictPoints[ pt ] = d; } } } for( const std::pair& conflict : conflictPoints ) { int actual = conflict.second; DRC_ITEM* drcItem; if( actual <= 0 ) { drcItem = new DRC_ITEM( DRCE_ZONES_INTERSECT ); } else { drcItem = new DRC_ITEM( DRCE_ZONES_TOO_CLOSE ); msg.Printf( drcItem->GetErrorText() + _( " (%s %s; actual %s)" ), clearanceSource, MessageTextFromValue( userUnits(), zone2zoneClearance, true ), MessageTextFromValue( userUnits(), conflict.second, true ) ); drcItem->SetErrorMessage( msg ); } drcItem->SetItems( zoneRef, zoneToTest ); MARKER_PCB* marker = new MARKER_PCB( drcItem, conflict.first ); addMarkerToPcb( marker ); nerrors++; } } } return nerrors; } void DRC::RunTests( wxTextCtrl* aMessages ) { // be sure m_pcb is the current board, not a old one // ( the board can be reloaded ) m_pcb = m_pcbEditorFrame->GetBoard(); if( aMessages ) { aMessages->AppendText( _( "Board Outline...\n" ) ); wxSafeYield(); } testOutline(); if( aMessages ) { aMessages->AppendText( _( "Netclasses...\n" ) ); wxSafeYield(); } if( !testNetClasses() ) { // testing the netclasses is a special case because if the netclasses // do not pass the BOARD_DESIGN_SETTINGS checks, then every member of a net // class (a NET) will cause its items such as tracks, vias, and pads // to also fail. So quit after *all* netclass errors have been reported. if( aMessages ) aMessages->AppendText( _( "NETCLASS VIOLATIONS: Aborting DRC\n" ) ); // update the m_drcDialog listboxes updatePointers(); return; } // test pad to pad clearances, nothing to do with tracks, vias or zones. if( m_doPad2PadTest ) { if( aMessages ) { aMessages->AppendText( _( "Pad clearances...\n" ) ); wxSafeYield(); } testPad2Pad(); } // test clearances between drilled holes if( aMessages ) { aMessages->AppendText( _( "Drill clearances...\n" ) ); wxSafeYield(); } testDrilledHoles(); // caller (a wxTopLevelFrame) is the wxDialog or the Pcb Editor frame that call DRC: wxWindow* caller = aMessages ? aMessages->GetParent() : m_pcbEditorFrame; if( m_refillZones ) { if( aMessages ) aMessages->AppendText( _( "Refilling all zones...\n" ) ); m_toolMgr->GetTool()->FillAllZones( caller ); } else { if( aMessages ) aMessages->AppendText( _( "Checking zone fills...\n" ) ); m_toolMgr->GetTool()->CheckAllZones( caller ); } // test track and via clearances to other tracks, pads, and vias if( aMessages ) { aMessages->AppendText( _( "Track clearances...\n" ) ); wxSafeYield(); } testTracks( aMessages ? aMessages->GetParent() : m_pcbEditorFrame, true ); // test zone clearances to other zones if( aMessages ) { aMessages->AppendText( _( "Zone to zone clearances...\n" ) ); wxSafeYield(); } testZones(); // find and gather unconnected pads. if( m_doUnconnectedTest && !m_pcb->GetDesignSettings().Ignore( DRCE_UNCONNECTED_ITEMS ) ) { if( aMessages ) { aMessages->AppendText( _( "Unconnected pads...\n" ) ); aMessages->Refresh(); } testUnconnected(); } // find and gather vias, tracks, pads inside keepout areas. if( m_doKeepoutTest ) { if( aMessages ) { aMessages->AppendText( _( "Keepout areas ...\n" ) ); aMessages->Refresh(); } testKeepoutAreas(); } // find and gather vias, tracks, pads inside text boxes. if( aMessages ) { aMessages->AppendText( _( "Text and graphic clearances...\n" ) ); wxSafeYield(); } testCopperTextAndGraphics(); // test courtyards if( !m_pcb->GetDesignSettings().Ignore( DRCE_OVERLAPPING_FOOTPRINTS ) || !m_pcb->GetDesignSettings().Ignore( DRCE_MISSING_COURTYARD ) || !m_pcb->GetDesignSettings().Ignore( DRCE_MALFORMED_COURTYARD ) ) { if( aMessages ) { aMessages->AppendText( _( "Courtyard areas...\n" ) ); aMessages->Refresh(); } doCourtyardsDrc(); } for( DRC_ITEM* footprintItem : m_footprints ) delete footprintItem; m_footprints.clear(); m_footprintsTested = false; if( m_testFootprints && !Kiface().IsSingle() ) { if( aMessages ) { aMessages->AppendText( _( "Checking footprints against schematic...\n" ) ); aMessages->Refresh(); } NETLIST netlist; m_pcbEditorFrame->FetchNetlistFromSchematic( netlist, PCB_EDIT_FRAME::ANNOTATION_DIALOG ); if( m_drcDialog ) m_drcDialog->Raise(); TestFootprints( netlist, m_pcb, m_drcDialog->GetUserUnits(), m_footprints ); m_footprintsTested = true; } // Check if there are items on disabled layers if( !m_pcb->GetDesignSettings().Ignore( DRCE_DISABLED_LAYER_ITEM ) ) testDisabledLayers(); if( aMessages ) { aMessages->AppendText( _( "Items on disabled layers...\n" ) ); aMessages->Refresh(); } if( !m_pcb->GetDesignSettings().Ignore( DRCE_UNRESOLVED_VARIABLE ) ) testTextVars(); m_drcRun = true; // update the m_drcDialog listboxes updatePointers(); if( aMessages ) { // no newline on this one because it is last, don't want the window // to unnecessarily scroll. aMessages->AppendText( _( "Finished" ) ); } } void DRC::updatePointers() { // update my pointers, m_pcbEditorFrame is the only unchangeable one m_pcb = m_pcbEditorFrame->GetBoard(); m_pcbEditorFrame->ResolveDRCExclusions(); if( m_drcDialog ) // Use diag list boxes only in DRC dialog { m_drcDialog->SetMarkersProvider( new BOARD_DRC_ITEMS_PROVIDER( m_pcb ) ); m_drcDialog->SetUnconnectedProvider( new RATSNEST_DRC_ITEMS_PROVIDER( m_pcbEditorFrame, &m_unconnected ) ); m_drcDialog->SetFootprintsProvider( new VECTOR_DRC_ITEMS_PROVIDER( m_pcbEditorFrame, &m_footprints ) ); } } bool DRC::doNetClass( const NETCLASSPTR& nc, wxString& msg ) { bool ret = true; const BOARD_DESIGN_SETTINGS& g = m_pcb->GetDesignSettings(); if( nc->GetClearance() < g.m_MinClearance ) { DRC_ITEM* drcItem = new DRC_ITEM( DRCE_NETCLASS_CLEARANCE ); msg.Printf( drcItem->GetErrorText() + _( " (board minimum %s; %s netclass %s)" ), MessageTextFromValue( userUnits(), g.m_MinClearance, true ), nc->GetName(), MessageTextFromValue( userUnits(), nc->GetClearance(), true ) ); drcItem->SetErrorMessage( msg ); addMarkerToPcb( new MARKER_PCB( drcItem, wxPoint() ) ); ret = false; } if( nc->GetTrackWidth() < g.m_TrackMinWidth ) { DRC_ITEM* drcItem = new DRC_ITEM( DRCE_NETCLASS_TRACKWIDTH ); msg.Printf( drcItem->GetErrorText() + _( " (board minimum %s; %s netclass %s)" ), MessageTextFromValue( userUnits(), g.m_TrackMinWidth, true ), nc->GetName(), MessageTextFromValue( userUnits(), nc->GetTrackWidth(), true ) ); drcItem->SetErrorMessage( msg ); addMarkerToPcb( new MARKER_PCB( drcItem, wxPoint() ) ); ret = false; } if( nc->GetViaDiameter() < g.m_ViasMinSize ) { DRC_ITEM* drcItem = new DRC_ITEM( DRCE_NETCLASS_VIASIZE ); msg.Printf( drcItem->GetErrorText() + _( " (board minimum %s; %s netclass %s)" ), MessageTextFromValue( userUnits(), g.m_ViasMinSize, true ), nc->GetName(), MessageTextFromValue( userUnits(), nc->GetViaDiameter(), true ) ); drcItem->SetErrorMessage( msg ); addMarkerToPcb( new MARKER_PCB( drcItem, wxPoint() ) ); ret = false; } if( nc->GetViaDrill() < g.m_MinThroughDrill ) { DRC_ITEM* drcItem = new DRC_ITEM( DRCE_NETCLASS_VIADRILLSIZE ); msg.Printf( drcItem->GetErrorText() + _( " (board min through hole %s; %s netclass %s)" ), MessageTextFromValue( userUnits(), g.m_MinThroughDrill, true ), nc->GetName(), MessageTextFromValue( userUnits(), nc->GetViaDrill(), true ) ); drcItem->SetErrorMessage( msg ); addMarkerToPcb( new MARKER_PCB( drcItem, wxPoint() ) ); ret = false; } if( nc->GetuViaDiameter() < g.m_MicroViasMinSize ) { DRC_ITEM* drcItem = new DRC_ITEM( DRCE_NETCLASS_uVIASIZE ); msg.Printf( drcItem->GetErrorText() + _( " (board minimum %s; %s netclass %s)" ), MessageTextFromValue( userUnits(), g.m_MicroViasMinSize, true ), nc->GetName(), MessageTextFromValue( userUnits(), nc->GetuViaDiameter(), true ) ); drcItem->SetErrorMessage( msg ); addMarkerToPcb( new MARKER_PCB( drcItem, wxPoint() ) ); ret = false; } if( nc->GetuViaDrill() < g.m_MicroViasMinDrill ) { DRC_ITEM* drcItem = new DRC_ITEM( DRCE_NETCLASS_uVIADRILLSIZE ); msg.Printf( drcItem->GetErrorText() + _( " (board minimum %s; %s netclass %s)" ), MessageTextFromValue( userUnits(), g.m_MicroViasMinDrill, true ), nc->GetName(), MessageTextFromValue( userUnits(), nc->GetuViaDrill(), true ) ); drcItem->SetErrorMessage( msg ); addMarkerToPcb( new MARKER_PCB( drcItem, wxPoint() ) ); ret = false; } return ret; } bool DRC::testNetClasses() { bool ret = true; NETCLASSES& netclasses = m_pcb->GetDesignSettings().m_NetClasses; wxString msg; // construct this only once here, not in a loop, since somewhat expensive. if( !doNetClass( netclasses.GetDefault(), msg ) ) ret = false; for( NETCLASSES::const_iterator i = netclasses.begin(); i != netclasses.end(); ++i ) { NETCLASSPTR nc = i->second; if( !doNetClass( nc, msg ) ) ret = false; } return ret; } void DRC::testPad2Pad() { std::vector sortedPads; m_pcb->GetSortedPadListByXthenYCoord( sortedPads ); if( sortedPads.empty() ) return; // find the max size of the pads (used to stop the test) int max_size = 0; for( D_PAD* pad : sortedPads ) { // GetBoundingRadius() is the radius of the minimum sized circle fully containing the pad int radius = pad->GetBoundingRadius(); if( radius > max_size ) max_size = radius; } // Upper limit of pad list (limit not included) D_PAD** listEnd = &sortedPads[0] + sortedPads.size(); // Test the pads for( auto& pad : sortedPads ) { int x_limit = pad->GetClearance() + pad->GetBoundingRadius() + pad->GetPosition().x; doPadToPadsDrc( pad, &pad, listEnd, max_size + x_limit ); } } void DRC::testDrilledHoles() { BOARD_DESIGN_SETTINGS& dsnSettings = m_pcb->GetDesignSettings(); // Test drilled holes to minimize drill bit breakage. // // Check pad & std. via circular holes for hole-to-hole-min (non-circular holes are milled) // Check pad & std. via holes for via-min-drill (minimum hole classification) // Check uvia holes for uvia-min-drill (laser drill classification) struct DRILLED_HOLE { wxPoint m_location; int m_drillRadius; BOARD_ITEM* m_owner; }; std::vector holes; DRILLED_HOLE hole; wxString msg; for( MODULE* mod : m_pcb->Modules() ) { for( D_PAD* pad : mod->Pads( ) ) { int minDimension = std::min( pad->GetDrillSize().x, pad->GetDrillSize().y ); if( minDimension == 0 ) continue; if( !dsnSettings.Ignore( DRCE_TOO_SMALL_PAD_DRILL ) && minDimension < dsnSettings.m_MinThroughDrill ) { DRC_ITEM* drcItem = new DRC_ITEM( DRCE_TOO_SMALL_PAD_DRILL ); msg.Printf( drcItem->GetErrorText() + _( " (board min through hole %s; actual %s)" ), MessageTextFromValue( userUnits(), dsnSettings.m_MinThroughDrill, true ), MessageTextFromValue( userUnits(), minDimension, true ) ); drcItem->SetErrorMessage( msg ); drcItem->SetItems( pad ); MARKER_PCB* marker = new MARKER_PCB( drcItem, pad->GetPosition() ); addMarkerToPcb( marker ); } if( pad->GetDrillShape() == PAD_DRILL_SHAPE_CIRCLE ) { hole.m_location = pad->GetPosition(); hole.m_drillRadius = pad->GetDrillSize().x / 2; hole.m_owner = pad; holes.push_back( hole ); } } } for( TRACK* track : m_pcb->Tracks() ) { VIA* via = dynamic_cast( track ); if( !via ) continue; if( via->GetViaType() == VIATYPE::MICROVIA ) { if( !dsnSettings.Ignore( DRCE_TOO_SMALL_MICROVIA_DRILL ) && via->GetDrillValue() < dsnSettings.m_MicroViasMinDrill ) { DRC_ITEM* drcItem = new DRC_ITEM( DRCE_TOO_SMALL_MICROVIA_DRILL ); msg.Printf( drcItem->GetErrorText() + _( " (board minimum %s; actual %s)" ), MessageTextFromValue( userUnits(), dsnSettings.m_MicroViasMinDrill, true ), MessageTextFromValue( userUnits(), via->GetDrillValue(), true ) ); drcItem->SetErrorMessage( msg ); drcItem->SetItems( via ); MARKER_PCB* marker = new MARKER_PCB( drcItem, via->GetPosition() ); addMarkerToPcb( marker ); } } else { if( !dsnSettings.Ignore( DRCE_TOO_SMALL_VIA_DRILL ) && via->GetDrillValue() < dsnSettings.m_MinThroughDrill ) { DRC_ITEM* drcItem = new DRC_ITEM( DRCE_TOO_SMALL_VIA_DRILL ); msg.Printf( drcItem->GetErrorText() + _( " (board min through hole %s; actual %s)" ), MessageTextFromValue( userUnits(), dsnSettings.m_MinThroughDrill, true ), MessageTextFromValue( userUnits(), via->GetDrillValue(), true ) ); drcItem->SetErrorMessage( msg ); drcItem->SetItems( via ); MARKER_PCB* marker = new MARKER_PCB( drcItem, via->GetPosition() ); addMarkerToPcb( marker ); } hole.m_location = via->GetPosition(); hole.m_drillRadius = via->GetDrillValue() / 2; hole.m_owner = via; holes.push_back( hole ); } } if( dsnSettings.m_HoleToHoleMin == 0 || dsnSettings.Ignore( DRCE_DRILLED_HOLES_TOO_CLOSE ) ) return; for( size_t ii = 0; ii < holes.size(); ++ii ) { const DRILLED_HOLE& refHole = holes[ ii ]; for( size_t jj = ii + 1; jj < holes.size(); ++jj ) { const DRILLED_HOLE& checkHole = holes[ jj ]; // Holes with identical locations are allowable if( checkHole.m_location == refHole.m_location ) continue; int actual = KiROUND( GetLineLength( checkHole.m_location, refHole.m_location ) ); actual = std::max( 0, actual - checkHole.m_drillRadius - refHole.m_drillRadius ); if( actual < dsnSettings.m_HoleToHoleMin ) { DRC_ITEM* drcItem = new DRC_ITEM( DRCE_DRILLED_HOLES_TOO_CLOSE ); msg.Printf( drcItem->GetErrorText() + _( " (board minimum %s; actual %s)" ), MessageTextFromValue( userUnits(), dsnSettings.m_HoleToHoleMin, true ), MessageTextFromValue( userUnits(), actual, true ) ); drcItem->SetErrorMessage( msg ); drcItem->SetItems( refHole.m_owner, checkHole.m_owner ); MARKER_PCB* marker = new MARKER_PCB( drcItem, refHole.m_location ); addMarkerToPcb( marker ); } } } } void DRC::testTracks( wxWindow *aActiveWindow, bool aShowProgressBar ) { wxProgressDialog * progressDialog = NULL; const int delta = 500; // This is the number of tests between 2 calls to the // progress bar int count = m_pcb->Tracks().size(); int deltamax = count/delta; if( aShowProgressBar && deltamax > 3 ) { // Do not use wxPD_APP_MODAL style here: it is not necessary and create issues // on OSX progressDialog = new wxProgressDialog( _( "Track clearances" ), wxEmptyString, deltamax, aActiveWindow, wxPD_AUTO_HIDE | wxPD_CAN_ABORT | wxPD_ELAPSED_TIME ); progressDialog->Update( 0, wxEmptyString ); } int ii = 0; count = 0; for( auto seg_it = m_pcb->Tracks().begin(); seg_it != m_pcb->Tracks().end(); seg_it++ ) { if( ii++ > delta ) { ii = 0; count++; if( progressDialog ) { if( !progressDialog->Update( count, wxEmptyString ) ) break; // Aborted by user #ifdef __WXMAC__ // Work around a dialog z-order issue on OS X if( count == deltamax ) aActiveWindow->Raise(); #endif } } // Test new segment against tracks and pads, optionally against copper zones doTrackDrc( *seg_it, seg_it + 1, m_pcb->Tracks().end(), m_doZonesTest ); } if( progressDialog ) progressDialog->Destroy(); } void DRC::testUnconnected() { for( DRC_ITEM* unconnectedItem : m_unconnected ) delete unconnectedItem; m_unconnected.clear(); auto connectivity = m_pcb->GetConnectivity(); connectivity->Clear(); connectivity->Build( m_pcb ); // just in case. This really needs to be reliable. connectivity->RecalculateRatsnest(); std::vector edges; connectivity->GetUnconnectedEdges( edges ); for( const auto& edge : edges ) { DRC_ITEM* item = new DRC_ITEM( DRCE_UNCONNECTED_ITEMS ); item->SetItems( edge.GetSourceNode()->Parent(), edge.GetTargetNode()->Parent() ); m_unconnected.push_back( item ); } } void DRC::testZones() { // Test copper areas for valid netcodes // if a netcode is < 0 the netname was not found when reading a netlist // if a netcode is == 0 the netname is void, and the zone is not connected. // This is allowed, but i am not sure this is a good idea // // In recent Pcbnew versions, the netcode is always >= 0, but an internal net name // is stored, and initialized from the file or the zone properties editor. // if it differs from the net name from net code, there is a DRC issue if( !m_pcb->GetDesignSettings().Ignore( DRCE_ZONE_HAS_EMPTY_NET ) ) { for( int ii = 0; ii < m_pcb->GetAreaCount(); ii++ ) { ZONE_CONTAINER* zone = m_pcb->GetArea( ii ); if( !zone->IsOnCopperLayer() ) continue; int netcode = zone->GetNetCode(); // a netcode < 0 or > 0 and no pad in net is a error or strange // perhaps a "dead" net, which happens when all pads in this net were removed // Remark: a netcode < 0 should not happen (this is more a bug somewhere) int pads_in_net = ( netcode > 0 ) ? m_pcb->GetConnectivity()->GetPadCount( netcode ) : 1; if( ( netcode < 0 ) || pads_in_net == 0 ) { DRC_ITEM* drcItem = new DRC_ITEM( DRCE_ZONE_HAS_EMPTY_NET ); drcItem->SetItems( zone ); MARKER_PCB* marker = new MARKER_PCB( drcItem, zone->GetPosition() ); addMarkerToPcb( marker ); } } } // Test copper areas outlines, and create markers when needed TestZoneToZoneOutlines(); } void DRC::testKeepoutAreas() { // Get a list of all zones to inspect, from both board and footprints std::list areasToInspect = m_pcb->GetZoneList( true ); // Test keepout areas for vias, tracks and pads inside keepout areas for( ZONE_CONTAINER* area : areasToInspect ) { if( !area->GetIsKeepout() ) continue; for( TRACK* segm : m_pcb->Tracks() ) { if( segm->Type() == PCB_TRACE_T ) { if( !area->GetDoNotAllowTracks() ) continue; // Ignore if the keepout zone is not on the same layer if( !area->IsOnLayer( segm->GetLayer() ) ) continue; int widths = segm->GetWidth() / 2; SEG trackSeg( segm->GetStart(), segm->GetEnd() ); SEG::ecoord center2center_squared = area->Outline()->SquaredDistance( trackSeg ); if( center2center_squared <= SEG::Square( widths) ) { DRC_ITEM* drcItem = new DRC_ITEM( DRCE_TRACK_INSIDE_KEEPOUT ); drcItem->SetItems( segm, area ); MARKER_PCB* marker = new MARKER_PCB( drcItem, getLocation( segm, area ) ); addMarkerToPcb( marker ); } } else if( segm->Type() == PCB_VIA_T ) { if( ! area->GetDoNotAllowVias() ) continue; if( !area->CommonLayerExists( segm->GetLayerSet() ) ) continue; int widths = segm->GetWidth() / 2; wxPoint viaPos = segm->GetPosition(); SEG::ecoord center2center_squared = area->Outline()->SquaredDistance( viaPos ); if( center2center_squared <= SEG::Square( widths) ) { DRC_ITEM* drcItem = new DRC_ITEM( DRCE_VIA_INSIDE_KEEPOUT ); drcItem->SetItems( segm, area ); MARKER_PCB* marker = new MARKER_PCB( drcItem, getLocation( segm, area ) ); addMarkerToPcb( marker ); } } } if( !area->GetDoNotAllowPads() && !area->GetDoNotAllowFootprints() ) continue; EDA_RECT areaBBox = area->GetBoundingBox(); bool checkFront = area->CommonLayerExists( LSET::FrontMask() ); bool checkBack = area->CommonLayerExists( LSET::BackMask() ); for( MODULE* fp : m_pcb->Modules() ) { if( area->GetDoNotAllowFootprints() && ( fp->IsFlipped() ? checkBack : checkFront ) ) { // Fast test to detect a footprint inside the keepout area bounding box. if( areaBBox.Intersects( fp->GetBoundingBox() ) ) { SHAPE_POLY_SET outline; if( fp->BuildPolyCourtyard() ) { outline = fp->IsFlipped() ? fp->GetPolyCourtyardBack() : fp->GetPolyCourtyardFront(); } if( outline.OutlineCount() == 0 ) outline = fp->GetBoundingPoly(); // Build the common area between footprint and the keepout area: outline.BooleanIntersection( *area->Outline(), SHAPE_POLY_SET::PM_FAST ); // If it's not empty then we have a violation if( outline.OutlineCount() ) { const VECTOR2I& pt = outline.CVertex( 0, 0, -1 ); DRC_ITEM* drcItem = new DRC_ITEM( DRCE_FOOTPRINT_INSIDE_KEEPOUT ); drcItem->SetItems( fp, area ); MARKER_PCB* marker = new MARKER_PCB( drcItem, (wxPoint) pt ); addMarkerToPcb( marker ); } } } if( area->GetDoNotAllowPads() ) { for( D_PAD* pad : fp->Pads() ) { if( !area->CommonLayerExists( pad->GetLayerSet() ) ) continue; // Fast test to detect a pad inside the keepout area bounding box. EDA_RECT padBBox( pad->ShapePos(), wxSize() ); padBBox.Inflate( pad->GetBoundingRadius() ); if( areaBBox.Intersects( padBBox ) ) { SHAPE_POLY_SET outline; pad->TransformShapeWithClearanceToPolygon( outline, 0 ); // Build the common area between pad and the keepout area: outline.BooleanIntersection( *area->Outline(), SHAPE_POLY_SET::PM_FAST ); // If it's not empty then we have a violation if( outline.OutlineCount() ) { const VECTOR2I& pt = outline.CVertex( 0, 0, -1 ); DRC_ITEM* drcItem = new DRC_ITEM( DRCE_PAD_INSIDE_KEEPOUT ); drcItem->SetItems( pad, area ); MARKER_PCB* marker = new MARKER_PCB( drcItem, (wxPoint) pt ); addMarkerToPcb( marker ); } } } } } } } void DRC::testCopperTextAndGraphics() { // Test copper items for clearance violations with vias, tracks and pads for( BOARD_ITEM* brdItem : m_pcb->Drawings() ) { if( IsCopperLayer( brdItem->GetLayer() ) ) { if( brdItem->Type() == PCB_TEXT_T ) testCopperTextItem( brdItem ); else if( brdItem->Type() == PCB_LINE_T ) testCopperDrawItem( static_cast( brdItem )); } } for( MODULE* module : m_pcb->Modules() ) { TEXTE_MODULE& ref = module->Reference(); TEXTE_MODULE& val = module->Value(); if( ref.IsVisible() && IsCopperLayer( ref.GetLayer() ) ) testCopperTextItem( &ref ); if( val.IsVisible() && IsCopperLayer( val.GetLayer() ) ) testCopperTextItem( &val ); if( module->IsNetTie() ) continue; for( BOARD_ITEM* item : module->GraphicalItems() ) { if( IsCopperLayer( item->GetLayer() ) ) { if( item->Type() == PCB_MODULE_TEXT_T && ( (TEXTE_MODULE*) item )->IsVisible() ) testCopperTextItem( item ); else if( item->Type() == PCB_MODULE_EDGE_T ) testCopperDrawItem( static_cast( item )); } } } } void DRC::testCopperDrawItem( DRAWSEGMENT* aItem ) { std::vector itemShape; int itemWidth = aItem->GetWidth(); switch( aItem->GetShape() ) { case S_ARC: { SHAPE_ARC arc( aItem->GetCenter(), aItem->GetArcStart(), (double) aItem->GetAngle() / 10.0 ); auto l = arc.ConvertToPolyline(); for( int i = 0; i < l.SegmentCount(); i++ ) itemShape.push_back( l.Segment( i ) ); break; } case S_SEGMENT: itemShape.emplace_back( SEG( aItem->GetStart(), aItem->GetEnd() ) ); break; case S_CIRCLE: { // SHAPE_CIRCLE has no ConvertToPolyline() method, so use a 360.0 SHAPE_ARC SHAPE_ARC circle( aItem->GetCenter(), aItem->GetEnd(), 360.0 ); auto l = circle.ConvertToPolyline(); for( int i = 0; i < l.SegmentCount(); i++ ) itemShape.push_back( l.Segment( i ) ); break; } case S_CURVE: { aItem->RebuildBezierToSegmentsPointsList( aItem->GetWidth() ); wxPoint start_pt = aItem->GetBezierPoints()[0]; for( unsigned int jj = 1; jj < aItem->GetBezierPoints().size(); jj++ ) { wxPoint end_pt = aItem->GetBezierPoints()[jj]; itemShape.emplace_back( SEG( start_pt, end_pt ) ); start_pt = end_pt; } break; } default: break; } EDA_RECT bbox = aItem->GetBoundingBox(); SHAPE_RECT rect_area( bbox.GetX(), bbox.GetY(), bbox.GetWidth(), bbox.GetHeight() ); wxString msg; // Test tracks and vias for( auto track : m_pcb->Tracks() ) { if( !track->IsOnLayer( aItem->GetLayer() ) ) continue; wxString clearanceSource; int minClearance = track->GetClearance( nullptr, &clearanceSource ); int widths = ( track->GetWidth() + itemWidth ) / 2; int center2centerAllowed = minClearance + widths; SEG trackSeg( track->GetStart(), track->GetEnd() ); // Fast test to detect a track segment candidate inside the text bounding box if( !rect_area.Collide( trackSeg, center2centerAllowed ) ) continue; OPT minSeg; SEG::ecoord center2center_squared = 0; for( const SEG& itemSeg : itemShape ) { SEG::ecoord thisDist_squared = trackSeg.SquaredDistance( itemSeg ); if( !minSeg || thisDist_squared < center2center_squared ) { minSeg = itemSeg; center2center_squared = thisDist_squared; } } if( center2center_squared < SEG::Square( center2centerAllowed ) ) { int actual = std::max( 0.0, sqrt( center2center_squared ) - widths ); int errorCode = ( track->Type() == PCB_VIA_T ) ? DRCE_VIA_NEAR_COPPER : DRCE_TRACK_NEAR_COPPER; DRC_ITEM* drcItem = new DRC_ITEM( errorCode ); msg.Printf( drcItem->GetErrorText() + _( " (%s %s; actual %s)" ), clearanceSource, MessageTextFromValue( userUnits(), minClearance, true ), MessageTextFromValue( userUnits(), actual, true ) ); drcItem->SetErrorMessage( msg ); drcItem->SetItems( track, aItem ); wxPoint pos = getLocation( track, minSeg.get() ); MARKER_PCB* marker = new MARKER_PCB( drcItem, pos ); addMarkerToPcb( marker ); } } // Test pads for( auto pad : m_pcb->GetPads() ) { if( !pad->IsOnLayer( aItem->GetLayer() ) ) continue; // Graphic items are allowed to act as net-ties within their own footprint if( pad->GetParent() == aItem->GetParent() ) continue; // Fast test to detect a pad candidate inside the text bounding box // Finer test (time consumming) is made only for pads near the text. int bb_radius = pad->GetBoundingRadius() + pad->GetClearance( nullptr ); VECTOR2I shape_pos( pad->ShapePos() ); if( !rect_area.Collide( SEG( shape_pos, shape_pos ), bb_radius ) ) continue; wxString clearanceSource; int minClearance = pad->GetClearance( nullptr, &clearanceSource ); int widths = itemWidth / 2; int center2centerAllowed = minClearance + widths; SHAPE_POLY_SET padOutline; pad->TransformShapeWithClearanceToPolygon( padOutline, 0 ); OPT minSeg; SEG::ecoord center2center_squared = 0; for( const SEG& itemSeg : itemShape ) { SEG::ecoord thisCenter2center_squared = padOutline.SquaredDistance( itemSeg ); if( !minSeg || thisCenter2center_squared < center2center_squared ) { minSeg = itemSeg; center2center_squared = thisCenter2center_squared; } } if( center2center_squared < SEG::Square( center2centerAllowed ) ) { int actual = std::max( 0.0, sqrt( center2center_squared ) - widths ); DRC_ITEM* drcItem = new DRC_ITEM( DRCE_PAD_NEAR_COPPER ); msg.Printf( drcItem->GetErrorText() + _( " (%s %s; actual %s)" ), clearanceSource, MessageTextFromValue( userUnits(), minClearance, true ), MessageTextFromValue( userUnits(), actual, true ) ); drcItem->SetErrorMessage( msg ); drcItem->SetItems( pad, aItem ); MARKER_PCB* marker = new MARKER_PCB( drcItem, pad->GetPosition() ); addMarkerToPcb( marker ); } } } void DRC::testCopperTextItem( BOARD_ITEM* aTextItem ) { EDA_TEXT* text = dynamic_cast( aTextItem ); if( text == nullptr ) return; std::vector textShape; // a buffer to store the text shape (set of segments) int penWidth = text->GetEffectiveTextPenWidth(); // So far the bounding box makes up the text-area text->TransformTextShapeToSegmentList( textShape ); if( textShape.size() == 0 ) // Should not happen (empty text?) return; EDA_RECT bbox = text->GetTextBox(); SHAPE_RECT rect_area( bbox.GetX(), bbox.GetY(), bbox.GetWidth(), bbox.GetHeight() ); wxString msg; // Test tracks and vias for( auto track : m_pcb->Tracks() ) { if( !track->IsOnLayer( aTextItem->GetLayer() ) ) continue; wxString clearanceSource; int minClearance = track->GetClearance( nullptr, &clearanceSource ); int widths = ( track->GetWidth() + penWidth ) / 2; int center2centerAllowed = minClearance + widths; SEG trackSeg( track->GetStart(), track->GetEnd() ); // Fast test to detect a track segment candidate inside the text bounding box if( !rect_area.Collide( trackSeg, center2centerAllowed ) ) continue; OPT minSeg; SEG::ecoord center2center_squared = 0; for( unsigned jj = 0; jj < textShape.size(); jj += 2 ) { SEG textSeg( textShape[jj], textShape[jj+1] ); SEG::ecoord thisDist_squared = trackSeg.SquaredDistance( textSeg ); if( !minSeg || thisDist_squared < center2center_squared ) { minSeg = textSeg; center2center_squared = thisDist_squared; } } if( center2center_squared < SEG::Square( center2centerAllowed ) ) { int actual = std::max( 0.0, sqrt( center2center_squared ) - widths ); int errorCode = ( track->Type() == PCB_VIA_T ) ? DRCE_VIA_NEAR_COPPER : DRCE_TRACK_NEAR_COPPER; DRC_ITEM* drcItem = new DRC_ITEM( errorCode ); msg.Printf( drcItem->GetErrorText() + _( " (%s %s; actual %s)" ), clearanceSource, MessageTextFromValue( userUnits(), minClearance, true ), MessageTextFromValue( userUnits(), actual, true ) ); drcItem->SetErrorMessage( msg ); drcItem->SetItems( track, aTextItem ); wxPoint pos = getLocation( track, minSeg.get() ); MARKER_PCB* marker = new MARKER_PCB( drcItem, pos ); addMarkerToPcb( marker ); } } // Test pads for( auto pad : m_pcb->GetPads() ) { if( !pad->IsOnLayer( aTextItem->GetLayer() ) ) continue; // Fast test to detect a pad candidate inside the text bounding box // Finer test (time consumming) is made only for pads near the text. int bb_radius = pad->GetBoundingRadius() + pad->GetClearance( NULL ); VECTOR2I shape_pos( pad->ShapePos() ); if( !rect_area.Collide( SEG( shape_pos, shape_pos ), bb_radius ) ) continue; wxString clearanceSource; int minClearance = pad->GetClearance( nullptr, &clearanceSource ); int widths = penWidth / 2; int center2centerAllowed = minClearance + widths; SHAPE_POLY_SET padOutline; pad->TransformShapeWithClearanceToPolygon( padOutline, 0 ); OPT minSeg; SEG::ecoord center2center_squared = 0; for( unsigned jj = 0; jj < textShape.size(); jj += 2 ) { SEG textSeg( textShape[jj], textShape[jj+1] ); SEG::ecoord thisCenter2center_squared = padOutline.SquaredDistance( textSeg ); if( !minSeg || thisCenter2center_squared < center2center_squared ) { minSeg = textSeg; center2center_squared = thisCenter2center_squared; } } if( center2center_squared < SEG::Square( center2centerAllowed ) ) { int actual = std::max( 0.0, sqrt( center2center_squared ) - widths ); DRC_ITEM* drcItem = new DRC_ITEM( DRCE_PAD_NEAR_COPPER ); msg.Printf( drcItem->GetErrorText() + _( " (%s %s; actual %s)" ), clearanceSource, MessageTextFromValue( userUnits(), minClearance, true ), MessageTextFromValue( userUnits(), actual, true ) ); drcItem->SetErrorMessage( msg ); drcItem->SetItems( pad, aTextItem ); MARKER_PCB* marker = new MARKER_PCB( drcItem, pad->GetPosition() ); addMarkerToPcb( marker ); } } } void DRC::testOutline() { wxString msg; wxPoint error_loc( m_pcb->GetBoardEdgesBoundingBox().GetPosition() ); m_board_outlines.RemoveAllContours(); if( !m_pcb->GetBoardPolygonOutlines( m_board_outlines, nullptr, &error_loc ) ) { DRC_ITEM* drcItem = new DRC_ITEM( DRCE_INVALID_OUTLINE ); msg.Printf( drcItem->GetErrorText() + _( " (not a closed shape)" ) ); drcItem->SetErrorMessage( msg ); drcItem->SetItems( m_pcb ); MARKER_PCB* marker = new MARKER_PCB( drcItem, error_loc ); addMarkerToPcb( marker ); } } void DRC::testDisabledLayers() { BOARD* board = m_pcbEditorFrame->GetBoard(); wxCHECK( board, /*void*/ ); LSET disabledLayers = board->GetEnabledLayers().flip(); wxString msg; // Perform the test only for copper layers disabledLayers &= LSET::AllCuMask(); for( TRACK* track : board->Tracks() ) { if( disabledLayers.test( track->GetLayer() ) ) { DRC_ITEM* drcItem = new DRC_ITEM( DRCE_DISABLED_LAYER_ITEM ); msg.Printf( drcItem->GetErrorText() + _( "layer %s" ), track->GetLayerName() ); drcItem->SetErrorMessage( msg ); drcItem->SetItems( track ); MARKER_PCB* marker = new MARKER_PCB( drcItem, track->GetPosition() ); addMarkerToPcb( marker ); } } for( MODULE* module : board->Modules() ) { module->RunOnChildren( [&]( BOARD_ITEM* child ) { if( disabledLayers.test( child->GetLayer() ) ) { DRC_ITEM* drcItem = new DRC_ITEM( DRCE_DISABLED_LAYER_ITEM ); msg.Printf( drcItem->GetErrorText() + _( "layer %s" ), child->GetLayerName() ); drcItem->SetErrorMessage( msg ); drcItem->SetItems( child ); MARKER_PCB* marker = new MARKER_PCB( drcItem, child->GetPosition() ); addMarkerToPcb( marker ); } } ); } for( ZONE_CONTAINER* zone : board->Zones() ) { if( disabledLayers.test( zone->GetLayer() ) ) { DRC_ITEM* drcItem = new DRC_ITEM( DRCE_DISABLED_LAYER_ITEM ); msg.Printf( drcItem->GetErrorText() + _( "layer %s" ), zone->GetLayerName() ); drcItem->SetErrorMessage( msg ); drcItem->SetItems( zone ); MARKER_PCB* marker = new MARKER_PCB( drcItem, zone->GetPosition() ); addMarkerToPcb( marker ); } } } void DRC::testTextVars() { BOARD* board = m_pcbEditorFrame->GetBoard(); for( MODULE* module : board->Modules() ) { module->RunOnChildren( [&]( BOARD_ITEM* child ) { if( child->Type() == PCB_MODULE_TEXT_T ) { TEXTE_MODULE* text = static_cast( child ); if( text->GetShownText().Matches( wxT( "*${*}*" ) ) ) { DRC_ITEM* drcItem = new DRC_ITEM( DRCE_UNRESOLVED_VARIABLE ); drcItem->SetItems( text ); MARKER_PCB* marker = new MARKER_PCB( drcItem, text->GetPosition() ); addMarkerToPcb( marker ); } } } ); } for( BOARD_ITEM* drawing : board->Drawings() ) { if( drawing->Type() == PCB_TEXT_T ) { TEXTE_PCB* text = static_cast( drawing ); if( text->GetShownText().Matches( wxT( "*${*}*" ) ) ) { DRC_ITEM* drcItem = new DRC_ITEM( DRCE_UNRESOLVED_VARIABLE ); drcItem->SetItems( text ); MARKER_PCB* marker = new MARKER_PCB( drcItem, text->GetPosition() ); addMarkerToPcb( marker ); } } } } bool DRC::doPadToPadsDrc( D_PAD* aRefPad, D_PAD** aStart, D_PAD** aEnd, int x_limit ) { const static LSET all_cu = LSET::AllCuMask(); LSET layerMask = aRefPad->GetLayerSet() & all_cu; /* used to test DRC pad to holes: this dummy pad has the size and shape of the hole * to test pad to pad hole DRC, using the pad to pad DRC test function. * Therefore, this dummy pad is a circle or an oval. * A pad must have a parent because some functions expect a non null parent * to find the parent board, and some other data */ MODULE dummymodule( m_pcb ); // Creates a dummy parent D_PAD dummypad( &dummymodule ); // Ensure the hole is on all copper layers dummypad.SetLayerSet( all_cu | dummypad.GetLayerSet() ); for( D_PAD** pad_list = aStart; pad_listGetPosition().x > x_limit // because the list is sorted by X values if( pad->GetPosition().x > x_limit ) break; // No problem if pads which are on copper layers are on different copper layers, // (pads can be only on a technical layer, to build complex pads) // but their hole (if any ) can create DRC error because they are on all // copper layers, so we test them if( ( pad->GetLayerSet() & layerMask ) == 0 && ( pad->GetLayerSet() & all_cu ) != 0 && ( aRefPad->GetLayerSet() & all_cu ) != 0 ) { // if holes are in the same location and have the same size and shape, // this can be accepted if( pad->GetPosition() == aRefPad->GetPosition() && pad->GetDrillSize() == aRefPad->GetDrillSize() && pad->GetDrillShape() == aRefPad->GetDrillShape() ) { if( aRefPad->GetDrillShape() == PAD_DRILL_SHAPE_CIRCLE ) continue; // for oval holes: must also have the same orientation if( pad->GetOrientation() == aRefPad->GetOrientation() ) continue; } /* Here, we must test clearance between holes and pads * dummy pad size and shape is adjusted to pad drill size and shape */ if( pad->GetDrillSize().x ) { // pad under testing has a hole, test this hole against pad reference dummypad.SetPosition( pad->GetPosition() ); dummypad.SetSize( pad->GetDrillSize() ); dummypad.SetShape( pad->GetDrillShape() == PAD_DRILL_SHAPE_OBLONG ? PAD_SHAPE_OVAL : PAD_SHAPE_CIRCLE ); dummypad.SetOrientation( pad->GetOrientation() ); wxString source; int minClearance = aRefPad->GetClearance( nullptr, &source ); int actual; if( !checkClearancePadToPad( aRefPad, &dummypad, minClearance, &actual ) ) { DRC_ITEM* drcItem = new DRC_ITEM( DRCE_HOLE_NEAR_PAD ); msg.Printf( drcItem->GetErrorText() + _( " (%s %s; actual %s)" ), source, MessageTextFromValue( userUnits(), minClearance, true ), MessageTextFromValue( userUnits(), actual, true ) ); drcItem->SetErrorMessage( msg ); drcItem->SetItems( pad, aRefPad ); MARKER_PCB* marker = new MARKER_PCB( drcItem, pad->GetPosition() ); addMarkerToPcb( marker ); return false; } } if( aRefPad->GetDrillSize().x ) // pad reference has a hole { dummypad.SetPosition( aRefPad->GetPosition() ); dummypad.SetSize( aRefPad->GetDrillSize() ); dummypad.SetShape( aRefPad->GetDrillShape() == PAD_DRILL_SHAPE_OBLONG ? PAD_SHAPE_OVAL : PAD_SHAPE_CIRCLE ); dummypad.SetOrientation( aRefPad->GetOrientation() ); wxString source; int minClearance = pad->GetClearance( nullptr, &source ); int actual; if( !checkClearancePadToPad( pad, &dummypad, minClearance, &actual ) ) { DRC_ITEM* drcItem = new DRC_ITEM( DRCE_HOLE_NEAR_PAD ); msg.Printf( drcItem->GetErrorText() + _( " (%s %s; actual %s)" ), source, MessageTextFromValue( userUnits(), minClearance, true ), MessageTextFromValue( userUnits(), actual, true ) ); drcItem->SetErrorMessage( msg ); drcItem->SetItems( aRefPad, pad ); MARKER_PCB* marker = new MARKER_PCB( drcItem, aRefPad->GetPosition() ); addMarkerToPcb( marker ); return false; } } continue; } // The pad must be in a net (i.e pt_pad->GetNet() != 0 ), // But no problem if pads have the same netcode (same net) if( pad->GetNetCode() && ( aRefPad->GetNetCode() == pad->GetNetCode() ) ) continue; // if pads are from the same footprint if( pad->GetParent() == aRefPad->GetParent() ) { // and have the same pad number ( equivalent pads ) // one can argue that this 2nd test is not necessary, that any // two pads from a single module are acceptable. This 2nd test // should eventually be a configuration option. if( pad->PadNameEqual( aRefPad ) ) continue; } // if either pad has no drill and is only on technical layers, not a clearance violation if( ( ( pad->GetLayerSet() & layerMask ) == 0 && !pad->GetDrillSize().x ) || ( ( aRefPad->GetLayerSet() & layerMask ) == 0 && !aRefPad->GetDrillSize().x ) ) { continue; } wxString source; int minClearance = aRefPad->GetClearance( nullptr, &source ); int actual; if( !checkClearancePadToPad( aRefPad, pad, minClearance, &actual ) ) { DRC_ITEM* drcItem = new DRC_ITEM( DRCE_PAD_NEAR_PAD ); msg.Printf( drcItem->GetErrorText() + _( " (%s %s; actual %s)" ), source, MessageTextFromValue( userUnits(), minClearance, true ), MessageTextFromValue( userUnits(), actual, true ) ); drcItem->SetErrorMessage( msg ); drcItem->SetItems( aRefPad, pad ); MARKER_PCB* marker = new MARKER_PCB( drcItem, aRefPad->GetPosition() ); addMarkerToPcb( marker ); return false; } } return true; } void DRC::doCourtyardsDrc() { DRC_COURTYARD_TESTER drc_overlap( [&]( MARKER_PCB* aMarker ) { addMarkerToPcb( aMarker ); } ); drc_overlap.RunDRC( *m_pcb ); } void DRC::TestFootprints( NETLIST& aNetlist, BOARD* aPCB, EDA_UNITS aUnits, std::vector& aDRCList ) { wxString msg; auto comp = []( const MODULE* x, const MODULE* y ) { return x->GetReference().CmpNoCase( y->GetReference() ) < 0; }; auto mods = std::set( comp ); if( !aPCB->GetDesignSettings().Ignore( DRCE_DUPLICATE_FOOTPRINT ) ) { // Search for duplicate footprints on the board for( MODULE* mod : aPCB->Modules() ) { auto ins = mods.insert( mod ); if( !ins.second ) { DRC_ITEM* item = new DRC_ITEM( DRCE_DUPLICATE_FOOTPRINT ); item->SetItems( mod, *ins.first ); aDRCList.push_back( item ); } } } if( !aPCB->GetDesignSettings().Ignore( DRCE_MISSING_FOOTPRINT ) ) { // Search for component footprints in the netlist but not on the board. for( unsigned ii = 0; ii < aNetlist.GetCount(); ii++ ) { COMPONENT* component = aNetlist.GetComponent( ii ); MODULE* module = aPCB->FindModuleByReference( component->GetReference() ); if( module == NULL ) { msg.Printf( _( "Missing footprint %s (%s)" ), component->GetReference(), component->GetValue() ); DRC_ITEM* item = new DRC_ITEM( DRCE_MISSING_FOOTPRINT ); item->SetErrorMessage( msg ); aDRCList.push_back( item ); } } } if( !aPCB->GetDesignSettings().Ignore( DRCE_EXTRA_FOOTPRINT ) ) { // Search for component footprints found on board but not in netlist. for( auto module : mods ) { COMPONENT* component = aNetlist.GetComponentByReference( module->GetReference() ); if( component == NULL ) { DRC_ITEM* item = new DRC_ITEM( DRCE_EXTRA_FOOTPRINT ); item->SetItems( module ); aDRCList.push_back( item ); } } } } void DRC::setTransitions() { Go( &DRC::ShowDRCDialog, PCB_ACTIONS::runDRC.MakeEvent() ); } const int EPSILON = Mils2iu( 5 ); wxPoint DRC::getLocation( TRACK* aTrack, ZONE_CONTAINER* aConflictZone ) const { SHAPE_POLY_SET* conflictOutline; if( aConflictZone->IsFilled() ) conflictOutline = const_cast( &aConflictZone->GetFilledPolysList() ); else conflictOutline = aConflictZone->Outline(); wxPoint pt1 = aTrack->GetPosition(); wxPoint pt2 = aTrack->GetEnd(); // If the mid-point is in the zone, then that's a fine place for the marker if( conflictOutline->SquaredDistance( ( pt1 + pt2 ) / 2 ) == 0 ) return ( pt1 + pt2 ) / 2; // Otherwise do a binary search for a "good enough" marker location else { while( GetLineLength( pt1, pt2 ) > EPSILON ) { if( conflictOutline->SquaredDistance( pt1 ) < conflictOutline->SquaredDistance( pt2 ) ) pt2 = ( pt1 + pt2 ) / 2; else pt1 = ( pt1 + pt2 ) / 2; } // Once we're within EPSILON pt1 and pt2 are "equivalent" return pt1; } } wxPoint DRC::getLocation( TRACK* aTrack, const SEG& aConflictSeg ) const { wxPoint pt1 = aTrack->GetPosition(); wxPoint pt2 = aTrack->GetEnd(); // Do a binary search along the track for a "good enough" marker location while( GetLineLength( pt1, pt2 ) > EPSILON ) { if( aConflictSeg.SquaredDistance( pt1 ) < aConflictSeg.SquaredDistance( pt2 ) ) pt2 = ( pt1 + pt2 ) / 2; else pt1 = ( pt1 + pt2 ) / 2; } // Once we're within EPSILON pt1 and pt2 are "equivalent" return pt1; }