/* * This program source code file is part of KiCad, a free EDA CAD application. * * Copyright (C) 2021-2023 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 static bool isCopper( const PNS::ITEM* aItem ) { if( !aItem ) return false; BOARD_ITEM* parent = aItem->Parent(); if( parent && parent->Type() == PCB_PAD_T ) { PAD* pad = static_cast( parent ); if( !pad->IsOnCopperLayer() ) return false; if( pad->GetAttribute() != PAD_ATTRIB::NPTH ) return true; // round NPTH with a hole size >= pad size are not on a copper layer // All other NPTH are seen on copper layers // This is a basic criteria, but probably enough for a NPTH if( pad->GetShape() == PAD_SHAPE::CIRCLE ) { if( pad->GetSize().x <= pad->GetDrillSize().x ) return false; } return true; } return true; } static bool isHole( const PNS::ITEM* aItem ) { if( !aItem ) return false; return aItem->OfKind( PNS::ITEM::HOLE_T ); } static bool isEdge( const PNS::ITEM* aItem ) { if( !aItem ) return false; const BOARD_ITEM *parent = aItem->BoardItem(); return parent && ( parent->IsOnLayer( Edge_Cuts ) || parent->IsOnLayer( Margin ) ); } class MOCK_RULE_RESOLVER : public PNS::RULE_RESOLVER { public: MOCK_RULE_RESOLVER() : m_clearanceEpsilon( 10 ) { } virtual ~MOCK_RULE_RESOLVER() {} virtual int Clearance( const PNS::ITEM* aA, const PNS::ITEM* aB, bool aUseClearanceEpsilon = true ) override { PNS::CONSTRAINT constraint; int rv = 0; LAYER_RANGE layers; if( !aB ) layers = aA->Layers(); else if( isEdge( aA ) ) layers = aB->Layers(); else if( isEdge( aB ) ) layers = aA->Layers(); else layers = aA->Layers().Intersection( aB->Layers() ); // Normalize layer range (no -1 magic numbers) layers = layers.Intersection( LAYER_RANGE( PCBNEW_LAYER_ID_START, PCB_LAYER_ID_COUNT - 1 ) ); for( int layer = layers.Start(); layer <= layers.End(); ++layer ) { if( isHole( aA ) && isHole( aB) ) { if( QueryConstraint( PNS::CONSTRAINT_TYPE::CT_HOLE_TO_HOLE, aA, aB, layer, &constraint ) ) { if( constraint.m_Value.Min() > rv ) rv = constraint.m_Value.Min(); } } else if( isHole( aA ) || isHole( aB ) ) { if( QueryConstraint( PNS::CONSTRAINT_TYPE::CT_HOLE_CLEARANCE, aA, aB, layer, &constraint ) ) { if( constraint.m_Value.Min() > rv ) rv = constraint.m_Value.Min(); } } else if( isCopper( aA ) && ( !aB || isCopper( aB ) ) ) { if( QueryConstraint( PNS::CONSTRAINT_TYPE::CT_CLEARANCE, aA, aB, layer, &constraint ) ) { if( constraint.m_Value.Min() > rv ) rv = constraint.m_Value.Min(); } } else if( isEdge( aA ) || ( aB && isEdge( aB ) ) ) { if( QueryConstraint( PNS::CONSTRAINT_TYPE::CT_EDGE_CLEARANCE, aA, aB, layer, &constraint ) ) { if( constraint.m_Value.Min() > rv ) rv = constraint.m_Value.Min(); } } } return rv; } virtual PNS::NET_HANDLE DpCoupledNet( PNS::NET_HANDLE aNet ) override { return nullptr; } virtual int DpNetPolarity( PNS::NET_HANDLE aNet ) override { return -1; } virtual bool DpNetPair( const PNS::ITEM* aItem, PNS::NET_HANDLE& aNetP, PNS::NET_HANDLE& aNetN ) override { return false; } virtual int NetCode( PNS::NET_HANDLE aNet ) override { return -1; } virtual wxString NetName( PNS::NET_HANDLE aNet ) override { return wxEmptyString; } virtual bool QueryConstraint( PNS::CONSTRAINT_TYPE aType, const PNS::ITEM* aItemA, const PNS::ITEM* aItemB, int aLayer, PNS::CONSTRAINT* aConstraint ) override { ITEM_KEY key; key.a = aItemA; key.b = aItemB; key.type = aType; auto it = m_ruleMap.find( key ); if( it == m_ruleMap.end() ) { int cl; switch( aType ) { case PNS::CONSTRAINT_TYPE::CT_CLEARANCE: cl = m_defaultClearance; break; case PNS::CONSTRAINT_TYPE::CT_HOLE_TO_HOLE: cl = m_defaultHole2Hole; break; case PNS::CONSTRAINT_TYPE::CT_HOLE_CLEARANCE: cl = m_defaultHole2Copper; break; default: return false; } //printf("GetDef %s %s %d cl %d\n", aItemA->KindStr().c_str(), aItemB->KindStr().c_str(), aType, cl ); aConstraint->m_Type = aType; aConstraint->m_Value.SetMin( cl ); return true; } else { *aConstraint = it->second; } return true; } int ClearanceEpsilon() const override { return m_clearanceEpsilon; } struct ITEM_KEY { const PNS::ITEM* a = nullptr; const PNS::ITEM* b = nullptr; PNS::CONSTRAINT_TYPE type; bool operator==( const ITEM_KEY& other ) const { return a == other.a && b == other.b && type == other.type; } bool operator<( const ITEM_KEY& other ) const { if( a < other.a ) { return true; } else if ( a == other.a ) { if( b < other.b ) return true; else if ( b == other.b ) return type < other.type; } return false; } }; bool IsInNetTie( const PNS::ITEM* aA ) override { return false; } bool IsNetTieExclusion( const PNS::ITEM* aItem, const VECTOR2I& aCollisionPos, const PNS::ITEM* aCollidingItem ) override { return false; } bool IsKeepout( const PNS::ITEM* aA, const PNS::ITEM* aB ) override { return false; } void AddMockRule( PNS::CONSTRAINT_TYPE aType, const PNS::ITEM* aItemA, const PNS::ITEM* aItemB, PNS::CONSTRAINT& aConstraint ) { ITEM_KEY key; key.a = aItemA; key.b = aItemB; key.type = aType; m_ruleMap[key] = aConstraint; } int m_defaultClearance = 200000; int m_defaultHole2Hole = 220000; int m_defaultHole2Copper = 210000; private: std::map m_ruleMap; int m_clearanceEpsilon; }; struct PNS_TEST_FIXTURE; class MOCK_PNS_KICAD_IFACE : public PNS_KICAD_IFACE_BASE { public: MOCK_PNS_KICAD_IFACE( PNS_TEST_FIXTURE *aFixture ) : m_testFixture( aFixture ) {} ~MOCK_PNS_KICAD_IFACE() {} void HideItem( PNS::ITEM* aItem ) override {}; void DisplayItem( const PNS::ITEM* aItem, int aClearance, bool aEdit = false, bool aIsHeadTrace = false ) override {}; PNS::RULE_RESOLVER* GetRuleResolver() override; private: PNS_TEST_FIXTURE* m_testFixture; }; struct PNS_TEST_FIXTURE { PNS_TEST_FIXTURE() : m_settingsManager( true /* headless */ ) { m_router = new PNS::ROUTER; m_iface = new MOCK_PNS_KICAD_IFACE( this ); m_router->SetInterface( m_iface ); } SETTINGS_MANAGER m_settingsManager; PNS::ROUTER* m_router; MOCK_RULE_RESOLVER m_ruleResolver; MOCK_PNS_KICAD_IFACE* m_iface; //std::unique_ptr m_board; }; PNS::RULE_RESOLVER* MOCK_PNS_KICAD_IFACE::GetRuleResolver() { return &m_testFixture->m_ruleResolver; } static void dumpObstacles( const PNS::NODE::OBSTACLES &obstacles ) { for( const PNS::OBSTACLE& obs : obstacles ) { printf( "%p [%s] - %p [%s], clearance %d\n", obs.m_head, obs.m_head->KindStr().c_str(), obs.m_item, obs.m_item->KindStr().c_str(), obs.m_clearance ); } } BOOST_FIXTURE_TEST_CASE( PNSHoleCollisions, PNS_TEST_FIXTURE ) { PNS::VIA* v1 = new PNS::VIA( VECTOR2I( 0, 1000000 ), LAYER_RANGE( F_Cu, B_Cu ), 50000, 10000 ); PNS::VIA* v2 = new PNS::VIA( VECTOR2I( 0, 2000000 ), LAYER_RANGE( F_Cu, B_Cu ), 50000, 10000 ); std::unique_ptr world ( new PNS::NODE ); world->SetMaxClearance( 10000000 ); world->SetRuleResolver( &m_ruleResolver ); world->AddRaw( v1 ); world->AddRaw( v2 ); BOOST_TEST_MESSAGE( "via to via, no violations" ); { PNS::NODE::OBSTACLES obstacles; int count = world->QueryColliding( v1, obstacles ); dumpObstacles( obstacles ); BOOST_CHECK_EQUAL( obstacles.size(), 0 ); BOOST_CHECK_EQUAL( count, 0 ); } BOOST_TEST_MESSAGE( "via to via, forced copper to copper violation" ); { PNS::NODE::OBSTACLES obstacles; m_ruleResolver.m_defaultClearance = 1000000; world->QueryColliding( v1, obstacles ); dumpObstacles( obstacles ); BOOST_CHECK_EQUAL( obstacles.size(), 1 ); const auto first = *obstacles.begin(); BOOST_CHECK_EQUAL( first.m_head, v1 ); BOOST_CHECK_EQUAL( first.m_item, v2 ); BOOST_CHECK_EQUAL( first.m_clearance, m_ruleResolver.m_defaultClearance ); } BOOST_TEST_MESSAGE( "via to via, forced hole to hole violation" ); { PNS::NODE::OBSTACLES obstacles; m_ruleResolver.m_defaultClearance = 200000; m_ruleResolver.m_defaultHole2Hole = 1000000; world->QueryColliding( v1, obstacles ); dumpObstacles( obstacles ); BOOST_CHECK_EQUAL( obstacles.size(), 1 ); auto iter = obstacles.begin(); const auto first = *iter++; BOOST_CHECK_EQUAL( first.m_head, v1->Hole() ); BOOST_CHECK_EQUAL( first.m_item, v2->Hole() ); BOOST_CHECK_EQUAL( first.m_clearance, m_ruleResolver.m_defaultHole2Hole ); } BOOST_TEST_MESSAGE( "via to via, forced copper to hole violation" ); { PNS::NODE::OBSTACLES obstacles; m_ruleResolver.m_defaultHole2Hole = 220000; m_ruleResolver.m_defaultHole2Copper = 1000000; world->QueryColliding( v1, obstacles ); dumpObstacles( obstacles ); BOOST_CHECK_EQUAL( obstacles.size(), 2 ); auto iter = obstacles.begin(); const auto first = *iter++; // There is no guarantee on what order the two collisions will be in... BOOST_CHECK( ( first.m_head == v1 && first.m_item == v2->Hole() ) || ( first.m_head == v1->Hole() && first.m_item == v2 ) ); BOOST_CHECK_EQUAL( first.m_clearance, m_ruleResolver.m_defaultHole2Copper ); } }