52static std::unordered_set<const NODE*> allocNodes;
65 allocNodes.insert(
this );
74 wxLogTrace( wxT(
"PNS" ), wxT(
"attempting to free a node that has kids." ) );
79 if( allocNodes.find(
this ) == allocNodes.end() )
81 wxLogTrace( wxT(
"PNS" ), wxT(
"attempting to free an already-free'd node." ) );
85 allocNodes.erase(
this );
90 std::vector<const ITEM*> toDelete;
96 if( item->BelongsTo(
this ) && item->OfKind(
ITEM::HOLE_T ) )
99 HOLE* hole =
static_cast<HOLE*
>( item );
107 toDelete.push_back( item );
111 for(
const ITEM* item : toDelete )
113 wxLogTrace( wxT(
"PNS" ), wxT(
"del item %p type %s" ), item, item->KindStr().c_str() );
159 JOINT_MAP::iterator j;
169 wxLogTrace( wxT(
"PNS" ), wxT(
"%d items, %d joints, %d overrides" ),
191 m_override( nullptr )
235 if(
m_item == aCandidate )
241 if(
visit( aCandidate ) )
267 assert( allocNodes.find(
this ) != allocNodes.end() );
282 return aObstacles.size();
293 for(
int i = 0; i < aLine->
CLine().SegmentCount(); i++ )
306 if( obstacleList.empty() )
330 std::vector<SHAPE_LINE_CHAIN::INTERSECTION> intersectingPts;
331 int layer = aLine->
Layer();
333 for(
const OBSTACLE& obstacle : obstacleList )
336 + aLine->
Width() / 2;
338 obstacleHull = obstacle.m_item->Hull( clearance, 0, layer );
343 obstacleHull.
Clear();
352 intersectingPts.clear();
355 for(
const auto& ip : intersectingPts )
359 updateNearest( ip, obstacle );
366 +
via.Diameter( aLine->
Layer() ) / 2;
368 obstacleHull = obstacle.m_item->Hull( viaClearance, 0, layer );
373 obstacleHull.
Clear();
381 intersectingPts.clear();
385 updateNearest( ip, obstacle );
390 nearest = (*obstacleList.begin());
427 const LINE* line =
static_cast<const LINE*
>( aItemA );
537 aSolid->SetOwner(
this );
578 switch( aItem->
Kind() )
607 for(
size_t i = 0; i < l.
ArcCount(); i++ )
619 auto newarc = std::make_unique< ARC >( aLine, s );
620 aLine.
Link( newarc.get() );
621 Add( std::move( newarc ),
true );
645 std::unique_ptr<SEGMENT> newseg = std::make_unique<SEGMENT>( aLine, s );
646 aLine.
Link( newseg.get() );
647 Add( std::move( newseg ),
true );
665bool NODE::Add( std::unique_ptr< SEGMENT > aSegment,
bool aAllowRedundant )
667 if( aSegment->Seg().A == aSegment->Seg().B )
669 wxLogTrace( wxT(
"PNS" ),
670 wxT(
"attempting to add a segment with same end coordinates, ignoring." ) );
694bool NODE::Add( std::unique_ptr< ARC > aArc,
bool aAllowRedundant )
719 if( edgeExclusion->Collide( aPos ) )
729 bool holeRemoved =
false;
794 std::vector<ITEM*> links( aJoint->
LinkList() );
806 auto range =
m_joints.equal_range( tag );
813 for(
auto f = range.first; f != range.second; ++f )
824 bool completelyErased =
false;
831 completelyErased =
true;
836 for(
ITEM* link : links )
840 else if( !completelyErased )
869 add( aNewItem.release() );
915 switch( aItem->
Kind() )
941 LINE* l =
static_cast<LINE*
>( aItem );
956 via->Hole()->SetOwner(
via );
972 std::vector<LINKED_ITEM*>& segRefs = aLine.
Links();
991 bool& aGuardHit,
bool aStopAtLockedJoints,
bool aFollowLockedSegments )
993 bool prevReversed =
false;
997 for(
int count = 0 ; ; ++count )
999 const VECTOR2I p = aCurrent->
Anchor( aScanDirection ^ prevReversed );
1005 aCorners[aPos] = jt->
Pos();
1006 aSegments[aPos] = aCurrent;
1007 aArcReversed[aPos] =
false;
1011 if( ( aScanDirection && jt->
Pos() == aCurrent->
Anchor( 0 ) )
1012 || ( !aScanDirection && jt->
Pos() == aCurrent->
Anchor( 1 ) ) )
1014 aArcReversed[aPos] =
true;
1018 aPos += ( aScanDirection ? 1 : -1 );
1020 if( count && guard == p )
1022 if( aPos >= 0 && aPos < aLimit )
1023 aSegments[aPos] =
nullptr;
1031 if(
locked || aPos < 0 || aPos == aLimit )
1034 aCurrent = jt->
NextSegment( aCurrent, aFollowLockedSegments );
1039 prevReversed = ( aCurrent && jt->
Pos() == aCurrent->
Anchor( aScanDirection ) );
1045 bool aStopAtLockedJoints,
bool aFollowLockedSegments )
1047 const int MaxVerts = 1024 * 16;
1049 std::array<VECTOR2I, MaxVerts + 1> corners;
1050 std::array<LINKED_ITEM*, MaxVerts + 1> segs;
1051 std::array<bool, MaxVerts + 1> arcReversed;
1054 bool guardHit =
false;
1056 int i_start = MaxVerts / 2;
1057 int i_end = i_start + 1;
1064 followLine( aSeg,
false, i_start, MaxVerts, corners.data(), segs.data(), arcReversed.data(),
1065 guardHit, aStopAtLockedJoints, aFollowLockedSegments );
1069 followLine( aSeg,
true, i_end, MaxVerts, corners.data(), segs.data(), arcReversed.data(),
1070 guardHit, aStopAtLockedJoints, aFollowLockedSegments );
1076 bool originSet =
false;
1080 for(
int i = i_start + 1; i < i_end; i++ )
1088 if( li && prev_seg != li )
1092 const ARC* arc =
static_cast<const ARC*
>( li );
1097 ssize_t lastShape = nSegs ? line.
ArcIndex(
static_cast<ssize_t
>( nSegs ) - 1 ) : -1;
1105 if( li == aSeg && aOriginSegmentIndex && !originSet )
1109 *aOriginSegmentIndex = line.
PointCount() - 1;
1121 if( aOriginSegmentIndex && *aOriginSegmentIndex >= pl.
SegmentCount() )
1124 wxASSERT_MSG( pl.
SegmentCount() != 0,
"assembled line should never be empty" );
1149 JOINT j_start, j_end;
1156 if( id_end < id_start )
1157 std::swap( id_end, id_start );
1159 if( id_start >= 0 && id_end >= 0 )
1162 aLines.push_back( line );
1173 const SEGMENT* locked_seg =
nullptr;
1174 std::vector<VVIA*> vvias;
1178 JOINT joint = jointPair.second;
1183 int n_seg = 0, n_solid = 0, n_vias = 0;
1186 bool is_width_change =
false;
1187 bool is_locked =
false;
1199 else if(
const auto t = dyn_cast<const PNS::SEGMENT*>( item ) )
1203 if( prev_w >= 0 && w != prev_w )
1205 is_width_change =
true;
1208 max_w = std::max( w, max_w );
1211 is_locked = t->IsLocked();
1216 if( ( is_width_change || n_seg >= 3 || is_locked ) && n_solid == 0 && n_vias == 0 )
1227 locked_seg->
Seg().
B :
1228 locked_seg->
Seg().
A;
1235 for(
auto vvia : vvias )
1237 Add( ItemCast<VIA>( std::move( std::unique_ptr<VVIA>( vvia ) ) ) );
1251 if( f == end && !
isRoot() )
1259 if( f->second.Pos() == aPos && f->second.Net() == aNet && f->second.Layers().Overlaps( aLayer ) )
1284 JOINT_MAP::iterator f =
m_joints.find( tag );
1286 std::pair<JOINT_MAP::iterator, JOINT_MAP::iterator> range;
1293 for( f = range.first; f != range.second; ++f )
1298 JOINT jt( aPos, aLayers, aNet );
1305 range =
m_joints.equal_range( tag );
1307 if( range.first ==
m_joints.end() )
1310 for( f = range.first; f != range.second; ++f )
1312 if( aLayers.
Overlaps( f->second.Layers() ) )
1314 jt.
Merge( f->second );
1328 wxLogTrace( wxT(
"PNS" ), wxT(
"joint layers %d-%d, net %d, pos %s, links: %d" ),
1359 std::unordered_set<SEGMENT*> all_segs;
1362 for( i = m_items.begin(); i != m_items.end(); i++ )
1365 all_segs.insert(
static_cast<SEGMENT*
>( *i ) );
1370 for( i =
m_root->m_items.begin(); i !=
m_root->m_items.end(); i++ )
1373 all_segs.insert(
static_cast<SEGMENT*
>(*i) );
1377 JOINT_MAP::iterator j;
1383 wxLogTrace( wxT(
"PNS" ), wxT(
"joint : %s, links : %d\n" ),
1384 j->second.GetPos().Format().c_str(), j->second.LinkCount() );
1385 JOINT::LINKED_ITEMS::const_iterator k;
1387 for( k = j->second.GetLinkList().begin(); k != j->second.GetLinkList().end(); ++k )
1389 const ITEM* m_item = *k;
1391 switch( m_item->GetKind() )
1396 wxLogTrace( wxT(
"PNS" ), wxT(
" -> seg %s %s\n" ),
1397 seg->GetSeg().A.
Format().c_str(),
1398 seg->GetSeg().B.
Format().c_str() );
1409 int lines_count = 0;
1411 while( !all_segs.empty() )
1413 SEGMENT* s = *all_segs.begin();
1416 LINE::LinkedSegments* seg_refs = l->GetLinkedSegments();
1420 wxLogTrace( wxT(
"PNS" ), wxT(
"Line: %s, net %d " ),
1421 l->GetLine().
Format().c_str(), l->GetNet() );
1424 for( std::vector<SEGMENT*>::iterator j = seg_refs->begin(); j != seg_refs->end(); ++j )
1426 wxLogTrace( wxT(
"PNS" ), wxT(
"%s " ), (*j)->GetSeg().A.Format().c_str() );
1428 if( j + 1 == seg_refs->end() )
1429 wxLogTrace( wxT(
"PNS" ), wxT(
"%s\n" ), (*j)->GetSeg().B.Format().c_str() );
1431 all_segs.erase( *j );
1437 wxLogTrace( wxT(
"PNS" ), wxT(
"Local joints: %d, lines : %d \n" ),
1455 aRemoved.push_back( item );
1458 aAdded.push_back( item );
1467 for(
NODE* node : kids )
1469 node->releaseChildren();
1480 std::vector<const ITEM*> cacheCheckItems;
1485 if( !item->BelongsTo(
this ) )
1535 for(
ITEM* item : *l_cur )
1537 if( item->OfKind( aKindMask ) && item->IsRoutable() )
1538 aItems.insert( item );
1548 for(
ITEM* item : *l_root )
1550 if( !
Overrides( item ) && item->OfKind( aKindMask ) && item->IsRoutable() )
1551 aItems.insert( item );
1562 item->SetRank( -1 );
1563 item->Mark( item->Marker() & ~aMarkerMask );
1570 std::vector<ITEM*> garbage;
1574 if( item->Marker() & aMarker )
1575 garbage.emplace_back( item );
1578 for(
ITEM* item : garbage )
1601 && ( (
A == a2 &&
B == b2 ) || (
A == b2 &&
B == a2 ) ) )
1630 ARC* seg2 =
static_cast<ARC*
>( item );
1636 && ( (
A == a2 &&
B == b2 ) || (
A == b2 &&
B == a2 ) ) )
1660 for( JOINT_MAP::value_type& j :
m_joints )
1662 if( !j.second.Layers().Overlaps( aLayerMask ) )
1665 if( aBox.
Contains( j.second.Pos() ) && j.second.LinkCount( aKindMask ) )
1667 aJoints.push_back( &j.second );
1677 if( !
Overrides( &j.second ) && j.second.Layers().Overlaps( aLayerMask ) )
1679 if( aBox.
Contains( j.second.Pos() ) && j.second.LinkCount( aKindMask ) )
1681 aJoints.push_back( &j.second );
1700 for(
ITEM* item : *l_cur )
1702 if( item->Parent() == aParent )
1714 std::vector<ITEM*> ret;
1718 if( item->Parent() == aParent )
1719 ret.push_back( item );
1737 if( item->Net() == handle.
net && item->Layers().Overlaps(handle.
layers) )
1738 return static_cast<VIA*
>( item );
A base class derived from BOARD_ITEM for items that can be connected and have a net,...
NETINFO_ITEM * GetNet() const
Return #NET_INFO object for a given item.
A base class for any item which can be embedded within the BOARD container class, and therefore insta...
virtual bool IsConnected() const
Returns information if the object is derived from BOARD_CONNECTED_ITEM.
constexpr coord_type GetLeft() const
constexpr bool Contains(const Vec &aPoint) const
constexpr coord_type GetRight() const
constexpr coord_type GetTop() const
constexpr coord_type GetBottom() const
@ ROUNDED_90
H/V with filleted corners.
@ MITERED_90
H/V only (90-degree corners)
virtual VECTOR2I Anchor(int n) const override
const SHAPE * Shape(int aLayer) const override
Return the geometrical shape of the item.
ITEM * ParentPadVia() const override
void Remove(ITEM *aItem)
Removes an item from the spatial index.
std::list< ITEM * > NET_ITEMS_LIST
int Size() const
Returns number of items stored in the index.
void Add(ITEM *aItem)
Adds item to the spatial index.
int Query(const ITEM *aItem, int aMinDistance, Visitor &aVisitor) const
Searches items in the index that are in proximity of aItem.
NET_ITEMS_LIST * GetItemsForNet(NET_HANDLE aNet)
Returns list of all items in a given net.
void Add(const LINE &aLine)
std::vector< ITEM * > & Items()
const std::vector< ITEM * > & CItems() const
Base class for PNS router board items.
void SetLayers(const PNS_LAYER_RANGE &aLayers)
virtual const std::string Format() const
virtual void Unmark(int aMarker=-1) const
virtual const SHAPE * Shape(int aLayer) const
Return the geometrical shape of the item.
const PNS_LAYER_RANGE & Layers() const
virtual NET_HANDLE Net() const
PnsKind Kind() const
Return the type (kind) of the item.
void SetNet(NET_HANDLE aNet)
virtual void SetRank(int aRank)
virtual int Layer() const
bool Collide(const ITEM *aHead, const NODE *aNode, int aLayer, COLLISION_SEARCH_CONTEXT *aCtx=nullptr) const
Check for a collision (clearance violation) with between us and item aOther.
bool OfKind(int aKindMask) const
virtual VECTOR2I Anchor(int n) const
bool LayersOverlap(const ITEM *aOther) const
Return true if the set of layers spanned by aOther overlaps our layers.
virtual HOLE * Hole() const
virtual bool HasHole() const
A 2D point on a given set of layers and belonging to a certain net, that links together a number of b...
const std::vector< ITEM * > & LinkList() const
NET_HANDLE Net() const override
int LinkCount(int aMask=-1) const
void Lock(bool aLock=true)
void Link(ITEM *aItem)
Unlink a given board item from the joint (upon its removal from a NODE)
LINKED_ITEM * NextSegment(LINKED_ITEM *aCurrent, bool aAllowLockedSegs=false) const
HASH_TAG m_tag
< hash tag for unordered_multimap
void Merge(const JOINT &aJoint)
bool Unlink(ITEM *aItem)
For trivial joints, return the segment adjacent to (aCurrent).
const VECTOR2I & Pos() const
Represents a track on a PCB, connecting two non-trivial joints (that is, vias, pads,...
void ClipVertexRange(int aStart, int aEnd)
Return the number of corners of angles specified by mask aAngles.
const VECTOR2I & CPoint(int aIdx) const
const SHAPE_LINE_CHAIN & CLine() const
SHAPE_LINE_CHAIN & Line()
void SetWidth(int aWidth)
Return line width.
int Width() const
Return true if the line is geometrically identical as line aOther.
virtual int Width() const
void Link(LINKED_ITEM *aLink)
bool IsLinked() const
Check if the segment aLink is a part of the line.
bool ContainsLink(const LINKED_ITEM *aItem) const
std::vector< LINKED_ITEM * > & Links()
virtual void ClearLinks()
Return the number of segments that were assembled together to form this line.
Keep the router "world" - i.e.
NODE * Branch()
Create a lightweight copy (called branch) of self that tracks the changes (added/removed items) wrs t...
void RemoveByMarker(int aMarker)
NODE * m_root
root node of the whole hierarchy
int FindLinesBetweenJoints(const JOINT &aA, const JOINT &aB, std::vector< LINE > &aLines)
Find the joints corresponding to the ends of line aLine.
std::vector< ITEM * > ITEM_VECTOR
int GetClearance(const ITEM *aA, const ITEM *aB, bool aUseClearanceEpsilon=true) const
Return the pre-set worst case clearance between any pair of items.
void followLine(LINKED_ITEM *aCurrent, bool aScanDirection, int &aPos, int aLimit, VECTOR2I *aCorners, LINKED_ITEM **aSegments, bool *aArcReversed, bool &aGuardHit, bool aStopAtLockedJoints, bool aFollowLockedSegments)
void addSolid(SOLID *aSeg)
void Replace(ITEM *aOldItem, std::unique_ptr< ITEM > aNewItem)
Replace an item with another one.
bool Overrides(ITEM *aItem) const
void removeSegmentIndex(SEGMENT *aSeg)
void rebuildJoint(const JOINT *aJoint, const ITEM *aItem)
void GetUpdatedItems(ITEM_VECTOR &aRemoved, ITEM_VECTOR &aAdded)
Return the list of items removed and added in this branch with respect to the root branch.
void addSegment(SEGMENT *aSeg)
std::vector< std::unique_ptr< SHAPE > > m_edgeExclusions
ARC * findRedundantArc(const VECTOR2I &A, const VECTOR2I &B, const PNS_LAYER_RANGE &lr, NET_HANDLE aNet)
JOINT_MAP::value_type TagJointPair
bool QueryEdgeExclusions(const VECTOR2I &aPos) const
void doRemove(ITEM *aItem)
OPT_OBSTACLE CheckColliding(const ITEM *aItem, int aKindMask=ITEM::ANY_T)
Check if the item collides with anything else in the world, and if found, returns the obstacle.
const JOINT * FindJoint(const VECTOR2I &aPos, int aLayer, NET_HANDLE aNet) const
Search for a joint at a given position, layer and belonging to given net.
void addHole(HOLE *aHole)
std::optional< OBSTACLE > OPT_OBSTACLE
void unlinkJoint(const VECTOR2I &aPos, const PNS_LAYER_RANGE &aLayers, NET_HANDLE aNet, ITEM *aWhere)
Helpers for adding/removing items.
std::unordered_set< ITEM * > m_garbageItems
void Dump(bool aLong=false)
void FindLineEnds(const LINE &aLine, JOINT &aA, JOINT &aB)
Destroy all child nodes. Applicable only to the root node.
RULE_RESOLVER * GetRuleResolver() const
Return the number of joints.
JOINT & touchJoint(const VECTOR2I &aPos, const PNS_LAYER_RANGE &aLayers, NET_HANDLE aNet)
Touch a joint and links it to an m_item.
bool Add(std::unique_ptr< SEGMENT > aSegment, bool aAllowRedundant=false)
Add an item to the current node.
int QueryJoints(const BOX2I &aBox, std::vector< JOINT * > &aJoints, PNS_LAYER_RANGE aLayerMask=PNS_LAYER_RANGE::All(), int aKindMask=ITEM::ANY_T)
std::set< OBSTACLE > OBSTACLES
INDEX * m_index
Geometric/Net index of the items.
std::unordered_set< ITEM * > m_override
hash of root's items that have been changed in this node
void AllItemsInNet(NET_HANDLE aNet, std::set< ITEM * > &aItems, int aKindMask=-1)
OPT_OBSTACLE NearestObstacle(const LINE *aLine, const COLLISION_SEARCH_OPTIONS &aOpts=COLLISION_SEARCH_OPTIONS())
Follow the line in search of an obstacle that is nearest to the starting to the line's starting point...
void LockJoint(const VECTOR2I &aPos, const ITEM *aItem, bool aLock)
void removeArcIndex(ARC *aVia)
void AddEdgeExclusion(std::unique_ptr< SHAPE > aShape)
int QueryColliding(const ITEM *aItem, OBSTACLES &aObstacles, const COLLISION_SEARCH_OPTIONS &aOpts=COLLISION_SEARCH_OPTIONS()) const
Find items colliding (closer than clearance) with the item aItem.
int m_maxClearance
worst case item-item clearance
VIA * FindViaByHandle(const VIA_HANDLE &handle) const
void removeViaIndex(VIA *aVia)
void add(ITEM *aItem, bool aAllowRedundant=false)
void removeSolidIndex(SOLID *aSeg)
int m_depth
depth of the node (number of parent nodes in the inheritance chain)
std::set< NODE * > m_children
list of nodes branched from this one
ITEM * FindItemByParent(const BOARD_ITEM *aParent)
JOINT_MAP m_joints
hash table with the joints, linking the items.
std::vector< ITEM * > FindItemsByParent(const BOARD_ITEM *aParent)
NODE * m_parent
node this node was branched from
void ClearRanks(int aMarkerMask=MK_HEAD|MK_VIOLATION)
void Remove(ARC *aArc)
Remove an item from this branch.
void Commit(NODE *aNode)
Apply the changes from a given branch (aNode) to the root branch.
RULE_RESOLVER * m_ruleResolver
Design rules resolver.
~NODE()
Return the expected clearance between items a and b.
const LINE AssembleLine(LINKED_ITEM *aSeg, int *aOriginSegmentIndex=nullptr, bool aStopAtLockedJoints=false, bool aFollowLockedSegments=false)
Follow the joint map to assemble a line connecting two non-trivial joints starting from segment aSeg.
SEGMENT * findRedundantSegment(const VECTOR2I &A, const VECTOR2I &B, const PNS_LAYER_RANGE &lr, NET_HANDLE aNet)
void linkJoint(const VECTOR2I &aPos, const PNS_LAYER_RANGE &aLayers, NET_HANDLE aNet, ITEM *aWhere)
Unlink an item from a joint.
const ITEM_SET HitTest(const VECTOR2I &aPoint) const
Find all items that contain the point aPoint.
OBSTACLE_VISITOR(const ITEM *aItem)
const NODE * m_node
node we are searching in (either root or a branch)
const ITEM * m_item
the item we are looking for collisions with
bool visit(ITEM *aCandidate)
std::optional< int > m_layerContext
void SetWorld(const NODE *aNode, const NODE *aOverride=nullptr)
const NODE * m_override
node that overrides root entries
void SetOwner(const ITEM_OWNER *aOwner)
Set the node that owns this item.
bool BelongsTo(const ITEM_OWNER *aNode) const
const ITEM_OWNER * Owner() const
Return the owner of this item, or NULL if there's none.
virtual DEBUG_DECORATOR * GetDebugDecorator()=0
ROUTER_IFACE * GetInterface() const
ROUTING_SETTINGS & Settings()
static ROUTER * GetInstance()
DIRECTION_45::CORNER_MODE GetCornerMode() const
virtual void ClearCacheForItems(std::vector< const ITEM * > &aItems)
virtual int ClearanceEpsilon() const
virtual int Clearance(const ITEM *aA, const ITEM *aB, bool aUseClearanceEpsilon=true)=0
virtual const std::string Format() const override
virtual bool HasHole() const override
virtual HOLE * Hole() const override
const VECTOR2I & Pos() const
const VECTOR2I & Pos() const
virtual HOLE * Hole() const override
virtual bool HasHole() const override
Represent a contiguous set of PCB layers.
bool Overlaps(const PNS_LAYER_RANGE &aOther) const
bool IsMultilayer() const
SHAPE_ARC Reversed() const
const VECTOR2I & GetP1() const
const VECTOR2I & GetP0() const
Represent a polyline containing arcs as well as line segments: A chain of connected line and/or arc s...
const SHAPE_ARC & Arc(size_t aArc) const
int PointCount() const
Return the number of points (vertices) in this line chain.
ssize_t ArcIndex(size_t aSegment) const
Return the arc index for the given segment index.
void Clear()
Remove all points from the line chain.
void Append(int aX, int aY, bool aAllowDuplication=false)
Append a new point at the end of the line chain.
const VECTOR2I & CPoint(int aIndex) const
Return a reference to a given point in the line chain.
int SegmentCount() const
Return the number of segments in this line chain.
int PathLength(const VECTOR2I &aP, int aIndex=-1) const
Compute the walk path length from the beginning of the line chain and the point aP belonging to our l...
void RemoveDuplicatePoints()
Remove the duplicate points from the line chain.
const SEG CSegment(int aIndex) const
Return a constant copy of the aIndex segment in the line chain.
bool IsArcSegment(size_t aSegment) const
int Find(const VECTOR2I &aP, int aThreshold=0) const
Search for point aP.
const BOX2I BBox(int aClearance=0) const override
Compute a bounding box of the shape, with a margin of aClearance a collision.
virtual bool Collide(const VECTOR2I &aP, int aClearance=0, int *aActual=nullptr, VECTOR2I *aLocation=nullptr) const
Check if the boundary of shape (this) lies closer to the point aP than aClearance,...
const std::string Format() const
Return the vector formatted as a string.
Push and Shove diff pair dimensions (gap) settings dialog.
void HullIntersection(const SHAPE_LINE_CHAIN &hull, const SHAPE_LINE_CHAIN &line, SHAPE_LINE_CHAIN::INTERSECTIONS &ips)
static std::vector< std::string > split(const std::string &aStr, const std::string &aDelim)
Split the input string into a vector of output strings.
const COLLISION_SEARCH_OPTIONS options
std::set< OBSTACLE > & obstacles
std::function< bool(const ITEM *)> m_filter
bool m_useClearanceEpsilon
bool operator()(ITEM *aItem) override
HIT_VISITOR(ITEM_SET &aTab, const VECTOR2I &aPoint)
< Joints are hashed by their position, layers and net.
bool operator()(ITEM *aCandidate) override
COLLISION_SEARCH_CONTEXT * m_ctx
DEFAULT_OBSTACLE_VISITOR(COLLISION_SEARCH_CONTEXT *aCtx, const ITEM *aItem)
virtual ~DEFAULT_OBSTACLE_VISITOR()
Hold an object colliding with another object, along with some useful data about the collision.
int m_distFirst
... and the distance thereof
int m_maxFanoutWidth
worst case (largest) width of the tracks connected to the item
ITEM * m_head
Line we search collisions against.
VECTOR2I m_ipFirst
First intersection between m_head and m_hull.
ITEM * m_item
Item found to be colliding with m_head.
Represent an intersection between two line segments.
VECTOR2I p
Point of intersection between our and their.
int index_their
index of the intersecting corner/segment in the 'their' (Intersect() method parameter) line.
VECTOR2< int32_t > VECTOR2I