doxygen/pns__diff__pair__placer_8cpp_source.html

/*

 * KiRouter - a push-and-(sometimes-)shove PCB router

 *

 * Copyright (C) 2013-2015 CERN

 * Copyright (C) 2016-2023 KiCad Developers, see AUTHORS.txt for contributors.

 * Author: Tomasz Wlostowski <[email protected]>

 *

 * 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 3 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, see <http://www.gnu.org/licenses/>.

 */


#include "pns_walkaround.h"

#include "pns_shove.h"

#include "pns_router.h"

#include "pns_diff_pair_placer.h"

#include "pns_solid.h"

#include "pns_topology.h"

#include "pns_debug_decorator.h"

#include "pns_arc.h"


namespace PNS {


DIFF_PAIR_PLACER::DIFF_PAIR_PLACER( ROUTER* aRouter ) :

    PLACEMENT_ALGO( aRouter )

{

    m_state = RT_START;

    m_chainedPlacement = false;

    m_initialDiagonal = false;

    m_startDiagonal = false;

    m_fitOk = false;

    m_netP = nullptr;

    m_netN = nullptr;

    m_iteration = 0;

    m_world = nullptr;

    m_shove = nullptr;

    m_currentNode = nullptr;

    m_lastNode = nullptr;

    m_placingVia = false;

    m_viaDiameter = 0;

    m_viaDrill = 0;

    m_currentWidth = 0;

    m_currentLayer = 0;

    m_startsOnVia = false;

    m_orthoMode = false;

    m_snapOnTarget = false;

    m_currentEndItem = nullptr;

    m_currentTraceOk = false;

    m_idle = true;

}


DIFF_PAIR_PLACER::~DIFF_PAIR_PLACER()

{}


void DIFF_PAIR_PLACER::setWorld( NODE* aWorld )

{

    m_world = aWorld;

}


const VIA DIFF_PAIR_PLACER::makeVia( const VECTOR2I& aP, NET_HANDLE aNet )

{

    const PNS_LAYER_RANGE layers( m_sizes.GetLayerTop(), m_sizes.GetLayerBottom() );


    VIA v( aP, layers, m_sizes.ViaDiameter(), m_sizes.ViaDrill(), aNet, m_sizes.ViaType() );


    return v;

}


void DIFF_PAIR_PLACER::SetOrthoMode ( bool aOrthoMode )

{

    m_orthoMode = aOrthoMode;


    if( !m_idle )

        Move( m_currentEnd, nullptr );

}


bool DIFF_PAIR_PLACER::ToggleVia( bool aEnabled )

{

    m_placingVia = aEnabled;


    if( !m_idle )

        Move( m_currentEnd, nullptr );


    return true;

}


bool DIFF_PAIR_PLACER::rhMarkObstacles( const VECTOR2I& aP )

{

    if( !routeHead( aP ) )

        return false;


    bool collP = static_cast<bool>( m_currentNode->CheckColliding( &m_currentTrace.PLine() ) );

    bool collN = static_cast<bool>( m_currentNode->CheckColliding( &m_currentTrace.NLine() ) );


    m_fitOk = !( collP || collN ) ;


    return m_fitOk;

}


bool DIFF_PAIR_PLACER::propagateDpHeadForces ( const VECTOR2I& aP, VECTOR2I& aNewP )

{

    VIA virtHead = makeVia( aP, nullptr );


    if( m_placingVia )

    {

        virtHead.SetDiameter( 0, viaGap() + 2 * virtHead.Diameter( 0 ) );

    }

    else

    {

        virtHead.SetLayer( m_currentLayer );

        virtHead.SetDiameter( 0, m_sizes.DiffPairGap() + 2 * m_sizes.DiffPairWidth() );

    }


    bool solidsOnly = true;


    if( Settings().Mode() == RM_MarkObstacles )

    {

        aNewP = aP;

        return true;

    }

    else if( Settings().Mode() == RM_Walkaround )

    {

        solidsOnly = false;

    }


    // fixme: I'm too lazy to do it well. Circular approximaton will do for the moment.


    // Note: this code is lifted from VIA::PushoutForce and then optimized for this use case and to

    // check proper clearances to the diff pair line.  It can be removed if some specialized

    // pushout for traces / diff pairs is implemented.  Just calling VIA::PushoutForce does not work

    // as the via may have different resolved clearance to items than the diff pair should.

    int                   maxIter  = 40;

    int                   iter     = 0;

    bool                  collided = false;

    VECTOR2I              force, totalForce;

    std::set<const ITEM*> handled;


    while( iter < maxIter )

    {

        NODE::OPT_OBSTACLE obs = m_currentNode->CheckColliding( &virtHead, solidsOnly ?

                                                                           ITEM::SOLID_T :

                                                                           ITEM::ANY_T  );

        if( !obs || handled.count( obs->m_item ) )

            break;


        int clearance = m_currentNode->GetClearance( obs->m_item, &m_currentTrace.PLine(), false );

        VECTOR2I layerForce;

        collided = false;


        for( int viaLayer : virtHead.RelevantShapeLayers( obs->m_item ) )

        {

            collided |= obs->m_item->Shape( viaLayer )->Collide( virtHead.Shape( viaLayer ),

                                                                 clearance, &layerForce );


            if( layerForce.SquaredEuclideanNorm() > force.SquaredEuclideanNorm() )

                force = layerForce;

        }


        if( collided )

        {

            totalForce += force;

            virtHead.SetPos( virtHead.Pos() + force );

        }


        handled.insert( obs->m_item );


        iter++;

    }


    bool succeeded = ( !collided || iter != maxIter );


    if( succeeded )

    {

        aNewP = aP + force;

        return true;

    }


    return false;

}


bool DIFF_PAIR_PLACER::attemptWalk( NODE* aNode, DIFF_PAIR* aCurrent, DIFF_PAIR& aWalk,

                                    bool aPFirst, bool aWindCw, bool aSolidsOnly )

{

    WALKAROUND walkaround( aNode, Router() );

    WALKAROUND::STATUS wf1;


    walkaround.SetSolidsOnly( aSolidsOnly );

    walkaround.SetIterationLimit( Settings().WalkaroundIterationLimit() );

    walkaround.SetAllowedPolicies( { WALKAROUND::WP_SHORTEST } );


    SHOVE shove( aNode, Router() );

    LINE walkP, walkN;


    aWalk = *aCurrent;


    int iter = 0;


    DIFF_PAIR cur( *aCurrent );


    bool currentIsP = aPFirst;


    int mask = aSolidsOnly ? ITEM::SOLID_T : ITEM::ANY_T;


    do

    {

        LINE preWalk = ( currentIsP ? cur.PLine() : cur.NLine() );

        LINE preShove = ( currentIsP ? cur.NLine() : cur.PLine() );

        LINE postWalk;


        if( !aNode->CheckColliding ( &preWalk, mask ) )

        {

            currentIsP = !currentIsP;


            if( !aNode->CheckColliding( &preShove, mask ) )

                break;

            else

                continue;

        }


        auto wf1 = walkaround.Route( preWalk );


        if( wf1.status[ WALKAROUND::WP_SHORTEST ] != WALKAROUND::ST_DONE )

            return false;


        postWalk = wf1.lines[ WALKAROUND::WP_SHORTEST ];


        LINE postShove( preShove );


        shove.ForceClearance( true, cur.Gap() - 2 * PNS_HULL_MARGIN );


        bool sh1;


        sh1 = shove.ShoveObstacleLine( postWalk, preShove, postShove );


        if( !sh1 )

            return false;


        postWalk.Line().Simplify();

        postShove.Line().Simplify();


        cur.SetShape( postWalk.CLine(), postShove.CLine(), !currentIsP );


        currentIsP = !currentIsP;


        if( !aNode->CheckColliding( &postShove, mask ) )

            break;


        iter++;

    }

    while( iter < 3 );


    if( iter == 3 )

        return false;


    aWalk.SetShape( cur.CP(), cur.CN() );


    return true;

}


bool DIFF_PAIR_PLACER::tryWalkDp( NODE* aNode, DIFF_PAIR &aPair, bool aSolidsOnly )

{

    DIFF_PAIR best;

    double bestScore = 100000000000000.0;


    for( int attempt = 0; attempt <= 3; attempt++ )

    {

        DIFF_PAIR p;

        NODE *tmp = m_currentNode->Branch();


        bool pfirst = ( attempt & 1 ) ? true : false;

        bool wind_cw = ( attempt & 2 ) ? true : false;


        if( attemptWalk( tmp, &aPair, p, pfirst, wind_cw, aSolidsOnly ) )

        {

        //    double len = p.TotalLength();

            double cl   = 1 + p.CoupledLength();

            double skew = p.Skew();


            double score = cl + fabs( skew ) * 3.0;


            if( score < bestScore )

            {

                bestScore = score;

                best = p;

            }

        }


        delete tmp;

    }


    if( bestScore > 0.0 )

    {

        OPTIMIZER optimizer( m_currentNode );


        aPair.SetShape( best );

        optimizer.Optimize( &aPair );


        return true;

    }


    return false;

}


bool DIFF_PAIR_PLACER::rhWalkOnly( const VECTOR2I& aP )

{

    if( !routeHead ( aP ) )

        return false;


    m_fitOk = tryWalkDp( m_currentNode, m_currentTrace, false );


    return m_fitOk;

}


bool DIFF_PAIR_PLACER::route( const VECTOR2I& aP )

{

    switch( Settings().Mode() )

    {

    case RM_MarkObstacles:

        return rhMarkObstacles( aP );

    case RM_Walkaround:

        return rhWalkOnly( aP );

    case RM_Shove:

        return rhShoveOnly( aP );

    default:

        break;

    }


    return false;

}


bool DIFF_PAIR_PLACER::rhShoveOnly( const VECTOR2I& aP )

{

    m_currentNode = m_shove->CurrentNode();


    bool ok = routeHead( aP );


    m_fitOk  = false;


    if( !ok )

        return false;


    if( !tryWalkDp( m_currentNode, m_currentTrace, true ) )

        return false;


    LINE pLine( m_currentTrace.PLine() );

    LINE nLine( m_currentTrace.NLine() );

    ITEM_SET head;


    head.Add( &pLine );

    head.Add( &nLine );


    SHOVE::SHOVE_STATUS status = SHOVE::SH_INCOMPLETE; //->ShoveMultiLines( head );


    m_currentNode = m_shove->CurrentNode();


    if( status == SHOVE::SH_OK )

    {

        m_currentNode = m_shove->CurrentNode();


        if( !m_currentNode->CheckColliding( &m_currentTrace.PLine() ) &&

            !m_currentNode->CheckColliding( &m_currentTrace.NLine() ) )

        {

            m_fitOk = true;

        }

    }


    return m_fitOk;

}


const ITEM_SET DIFF_PAIR_PLACER::Traces()

{

      ITEM_SET t;


      t.Add( &m_currentTrace.PLine() );

      t.Add( &m_currentTrace.NLine() );


      return t;

}


void DIFF_PAIR_PLACER::FlipPosture()

{

    m_startDiagonal = !m_startDiagonal;


    if( !m_idle )

        Move( m_currentEnd, nullptr );

}


NODE* DIFF_PAIR_PLACER::CurrentNode( bool aLoopsRemoved ) const

{

    if( m_lastNode )

        return m_lastNode;


    return m_currentNode;

}


bool DIFF_PAIR_PLACER::SetLayer( int aLayer )

{

    if( m_idle )

    {

        m_currentLayer = aLayer;

        return true;

    }

    else if( m_chainedPlacement || !m_prevPair )

    {

        return false;

    }

    else if( !m_prevPair->PrimP() || ( m_prevPair->PrimP()->OfKind( ITEM::VIA_T ) &&

                m_prevPair->PrimP()->Layers().Overlaps( aLayer ) ) )

    {

        m_currentLayer = aLayer;

        m_start = *m_prevPair;

        initPlacement();

        Move( m_currentEnd, nullptr );

        return true;

    }


    return false;

}


OPT_VECTOR2I getDanglingAnchor( NODE* aNode, ITEM* aItem )

{

    switch( aItem->Kind() )

    {

    case ITEM::LINE_T:

    {

        LINE* l = static_cast<LINE*>( aItem );


        if( !l->PointCount() )

            return OPT_VECTOR2I();

        else

            return l->CPoint( 0 );

    }

    case ITEM::VIA_T:

    case ITEM::SOLID_T:

        return aItem->Anchor( 0 );


    case ITEM::ARC_T:

    {

        ARC* a = static_cast<ARC*>( aItem );


        const JOINT* jA = aNode->FindJoint( aItem->Anchor( 0 ), aItem );

        const JOINT* jB = aNode->FindJoint( aItem->Anchor( 1 ), aItem );


        if( jA && jA->LinkCount() == 1 )

            return a->Arc().GetP0();

        else if( jB && jB->LinkCount() == 1 )

            return a->Arc().GetP1();

        else

            return OPT_VECTOR2I();

    }

    case ITEM::SEGMENT_T:

    {

        SEGMENT* s = static_cast<SEGMENT*>( aItem );


        const JOINT* jA = aNode->FindJoint( aItem->Anchor( 0 ), aItem );

        const JOINT* jB = aNode->FindJoint( aItem->Anchor( 1 ), aItem );


        if( jA && jA->LinkCount() == 1 )

            return s->Seg().A;

        else if( jB && jB->LinkCount() == 1 )

            return s->Seg().B;

        else

            return OPT_VECTOR2I();

    }


    default:

        return OPT_VECTOR2I();

    }

}


bool DIFF_PAIR_PLACER::FindDpPrimitivePair( NODE* aWorld, const VECTOR2I& aP, ITEM* aItem,

                                            DP_PRIMITIVE_PAIR& aPair, wxString* aErrorMsg )

{

    NET_HANDLE netP, netN;


    bool result = aWorld->GetRuleResolver()->DpNetPair( aItem, netP, netN );


    if( !result )

    {

        if( aErrorMsg )

        {

            *aErrorMsg = _( "Unable to find complementary differential pair "

                            "nets. Make sure the names of the nets belonging "

                            "to a differential pair end with either N/P or +/-." );

        }

        return false;

    }


    NET_HANDLE refNet = aItem->Net();

    NET_HANDLE coupledNet = ( refNet == netP ) ? netN : netP;


    OPT_VECTOR2I refAnchor = getDanglingAnchor( aWorld, aItem );

    ITEM* primRef = aItem;


    if( !refAnchor )

    {

        if( aErrorMsg )

        {

            *aErrorMsg = _( "Can't find a suitable starting point.  If starting "

                            "from an existing differential pair make sure you are "

                            "at the end." );

        }


        return false;

    }


    std::set<ITEM*> coupledItems;


    aWorld->AllItemsInNet( coupledNet, coupledItems );

    double bestDist = std::numeric_limits<double>::max();

    bool found = false;


    for( ITEM* item : coupledItems )

    {

        if( item->Kind() == aItem->Kind() )

        {

            OPT_VECTOR2I anchor = getDanglingAnchor( aWorld, item );


            if( !anchor )

                continue;


            double dist = ( *anchor - *refAnchor ).EuclideanNorm();


            bool shapeMatches = true;


            if( item->OfKind( ITEM::SOLID_T | ITEM::VIA_T ) && item->Layers() != aItem->Layers() )

            {

                shapeMatches = false;

            }


            if( dist < bestDist && shapeMatches )

            {

                found = true;

                bestDist = dist;


                if( refNet != netP )

                {

                    aPair = DP_PRIMITIVE_PAIR ( item, primRef );

                    aPair.SetAnchors( *anchor, *refAnchor );

                }

                else

                {

                    aPair = DP_PRIMITIVE_PAIR( primRef, item );

                    aPair.SetAnchors( *refAnchor, *anchor );

                }

            }

        }

    }


    if( !found )

    {

        if( aErrorMsg )

        {

            *aErrorMsg = wxString::Format( _( "Can't find a suitable starting point "

                                              "for coupled net \"%s\"." ),

                                           aWorld->GetRuleResolver()->NetName( coupledNet ) );

        }


        return false;

    }


    return true;

}


int DIFF_PAIR_PLACER::viaGap() const

{

    return std::max( m_sizes.DiffPairViaGap(),

                     m_sizes.GetDiffPairHoleToHole() + m_sizes.ViaDrill() - m_sizes.ViaDiameter() );

}


int DIFF_PAIR_PLACER::gap() const

{

    return m_sizes.DiffPairGap() + m_sizes.DiffPairWidth();

}


bool DIFF_PAIR_PLACER::Start( const VECTOR2I& aP, ITEM* aStartItem )

{

    VECTOR2I p( aP );


    setWorld( Router()->GetWorld() );

    m_currentNode = m_world;


    wxString err_msg;


    if( !FindDpPrimitivePair( m_currentNode, aP, aStartItem, m_start, &err_msg ) )

    {

        Router()->SetFailureReason( err_msg );

        return false;

    }


    m_netP = m_start.PrimP()->Net();

    m_netN = m_start.PrimN()->Net();


    m_currentStart = p;

    m_currentEnd = p;

    m_placingVia = false;

    m_chainedPlacement = false;

    m_currentTraceOk = false;

    m_currentTrace = DIFF_PAIR();

    m_currentTrace.SetNets( m_netP, m_netN );


    initPlacement();


    return true;

}


void DIFF_PAIR_PLACER::initPlacement()

{

    m_idle = false;

    m_orthoMode = false;

    m_currentEndItem = nullptr;

    m_startDiagonal = m_initialDiagonal;


    NODE* world = Router()->GetWorld();


    world->KillChildren();

    NODE* rootNode = world->Branch();


    setWorld( rootNode );


    m_lastNode = nullptr;

    m_currentNode = rootNode;


    m_shove = std::make_unique<SHOVE>( m_currentNode, Router() );

}


bool DIFF_PAIR_PLACER::routeHead( const VECTOR2I& aP )

{

    m_fitOk = false;


    DP_GATEWAYS gwsEntry( gap() );

    DP_GATEWAYS gwsTarget( gap() );


    if( !m_prevPair )

        m_prevPair = m_start;


    gwsEntry.BuildFromPrimitivePair( *m_prevPair, m_startDiagonal );


    DP_PRIMITIVE_PAIR target;


    if( FindDpPrimitivePair( m_currentNode, aP, m_currentEndItem, target ) )

    {

        gwsTarget.BuildFromPrimitivePair( target, m_startDiagonal );

        m_snapOnTarget = true;

    }

    else

    {

        VECTOR2I fp;


        if( !propagateDpHeadForces( aP, fp ) )

            return false;


        VECTOR2I midp, dirV;

        m_prevPair->CursorOrientation( fp, midp, dirV );


        VECTOR2I fpProj = SEG( midp, midp + dirV ).LineProject( fp );


        // compute 'leader point' distance from the cursor (project cursor position

        // on the extension of the starting segment pair of the DP)

        int lead_dist = ( fpProj - fp ).EuclideanNorm();


        gwsTarget.SetFitVias( m_placingVia, m_sizes.ViaDiameter(), viaGap() );


        // far from the initial segment extension line -> allow a 45-degree obtuse turn

        if( lead_dist > ( m_sizes.DiffPairGap() + m_sizes.DiffPairWidth() ) / 2 )

        {

            gwsTarget.BuildForCursor( fp );

        }

        else

        {

            // close to the initial segment extension line -> keep straight part only, project

            // as close as possible to the cursor.

            gwsTarget.BuildForCursor( fpProj );

            gwsTarget.FilterByOrientation( DIRECTION_45::ANG_STRAIGHT | DIRECTION_45::ANG_HALF_FULL,

                                           DIRECTION_45( dirV ) );

        }


        m_snapOnTarget = false;

    }


    m_currentTrace.SetGap( gap() );

    m_currentTrace.SetLayer( m_currentLayer );


    bool result = gwsEntry.FitGateways( gwsEntry, gwsTarget, m_startDiagonal, m_currentTrace );


    if( result )

    {

        m_currentTraceOk = true;

        m_currentTrace.SetNets( m_netP, m_netN );

        m_currentTrace.SetWidth( m_sizes.DiffPairWidth() );

        m_currentTrace.SetGap( m_sizes.DiffPairGap() );


        if( m_placingVia )

        {

            m_currentTrace.AppendVias ( makeVia( m_currentTrace.CP().CPoint( -1 ), m_netP ),

                                        makeVia( m_currentTrace.CN().CPoint( -1 ), m_netN ) );

        }

        else

        {

            m_currentTrace.RemoveVias();

        }


        return true;

    }


    return m_currentTraceOk;

}


bool DIFF_PAIR_PLACER::Move( const VECTOR2I& aP , ITEM* aEndItem )

{

    m_currentEndItem = aEndItem;

    m_fitOk = false;


    delete m_lastNode;

    m_lastNode = nullptr;


    bool retval = route( aP );


    NODE* latestNode = m_currentNode;

    m_lastNode = latestNode->Branch();


    assert( m_lastNode != nullptr );

    m_currentEnd = aP;


    updateLeadingRatLine();


    return retval;

}


void DIFF_PAIR_PLACER::UpdateSizes( const SIZES_SETTINGS& aSizes )

{

    m_sizes = aSizes;


    if( !m_idle )

    {

        m_currentTrace.SetWidth( m_sizes.DiffPairWidth() );

        m_currentTrace.SetGap( m_sizes.DiffPairGap() );


        if( m_currentTrace.EndsWithVias() )

        {

            m_currentTrace.SetViaDiameter( m_sizes.ViaDiameter() );

            m_currentTrace.SetViaDrill( m_sizes.ViaDrill() );

        }

    }

}


bool DIFF_PAIR_PLACER::FixRoute( const VECTOR2I& aP, ITEM* aEndItem, bool aForceFinish )

{

    if( !m_fitOk && !Settings().AllowDRCViolations() )

        return false;


    if( m_currentTrace.CP().SegmentCount() < 1 || m_currentTrace.CN().SegmentCount() < 1 )

        return false;


    if( m_currentTrace.CP().SegmentCount() > 1 )

        m_initialDiagonal = !DIRECTION_45( m_currentTrace.CP().CSegment( -2 ) ).IsDiagonal();


    TOPOLOGY topo( m_lastNode );


    if( !m_snapOnTarget && !m_currentTrace.EndsWithVias() && !aForceFinish &&

        !Settings().GetFixAllSegments() )

    {

        SHAPE_LINE_CHAIN newP( m_currentTrace.CP() );

        SHAPE_LINE_CHAIN newN( m_currentTrace.CN() );


        if( newP.SegmentCount() > 1 && newN.SegmentCount() > 1 )

        {

            newP.Remove( -1, -1 );

            newN.Remove( -1, -1 );

        }


        m_currentTrace.SetShape( newP, newN );

    }


    if( m_currentTrace.EndsWithVias() )

    {

        m_lastNode->Add( Clone( m_currentTrace.PLine().Via() ) );

        m_lastNode->Add( Clone( m_currentTrace.NLine().Via() ) );

        m_chainedPlacement = false;

    }

    else

    {

        m_chainedPlacement = !m_snapOnTarget && !aForceFinish;

    }


    LINE lineP( m_currentTrace.PLine() );

    LINE lineN( m_currentTrace.NLine() );


    m_lastNode->Add( lineP );

    m_lastNode->Add( lineN );


    topo.SimplifyLine( &lineP );

    topo.SimplifyLine( &lineN );


    m_prevPair = m_currentTrace.EndingPrimitives();


    CommitPlacement();

    m_placingVia = false;


    if( m_snapOnTarget || aForceFinish )

    {

        m_idle = true;

        return true;

    }

    else

    {

        initPlacement();

        return false;

    }

}


bool DIFF_PAIR_PLACER::AbortPlacement()

{

    m_world->KillChildren();

    return true;

}


bool DIFF_PAIR_PLACER::HasPlacedAnything() const

{

     return m_currentTrace.CP().SegmentCount() > 0 || m_currentTrace.CN().SegmentCount() > 0;

}


bool DIFF_PAIR_PLACER::CommitPlacement()

{

    if( m_lastNode )

        Router()->CommitRouting( m_lastNode );


    m_lastNode = nullptr;

    m_currentNode = nullptr;

    return true;

}


void DIFF_PAIR_PLACER::GetModifiedNets( std::vector<NET_HANDLE> &aNets ) const

{

    aNets.push_back( m_netP );

    aNets.push_back( m_netN );

}


void DIFF_PAIR_PLACER::updateLeadingRatLine()

{

    SHAPE_LINE_CHAIN ratLineN, ratLineP;

    TOPOLOGY topo( m_lastNode );


    if( topo.LeadingRatLine( &m_currentTrace.PLine(), ratLineP ) )

        m_router->GetInterface()->DisplayRatline( ratLineP, m_netP );


    if( topo.LeadingRatLine ( &m_currentTrace.NLine(), ratLineN ) )

        m_router->GetInterface()->DisplayRatline( ratLineN, m_netN );

}


const std::vector<NET_HANDLE> DIFF_PAIR_PLACER::CurrentNets() const

{

    std::vector<NET_HANDLE> rv;

    rv.push_back( m_netP );

    rv.push_back( m_netN );

    return rv;

}


}

BITMAPS::anchor
@ anchor

DIRECTION_45
Represent route directions & corner angles in a 45-degree metric.
Definition: direction45.h:37

DIRECTION_45::ANG_HALF_FULL
@ ANG_HALF_FULL
Definition: direction45.h:83

DIRECTION_45::ANG_STRAIGHT
@ ANG_STRAIGHT
Definition: direction45.h:82

DIRECTION_45::IsDiagonal
bool IsDiagonal() const
Returns true if the direction is diagonal (e.g.
Definition: direction45.h:213

PNS::ALGO_BASE::Router
ROUTER * Router() const
Return current router settings.
Definition: pns_algo_base.h:54

PNS::ALGO_BASE::m_router
ROUTER * m_router
Definition: pns_algo_base.h:87

PNS::ALGO_BASE::Settings
ROUTING_SETTINGS & Settings() const
Return the logger object, allowing to dump geometry to a file.
Definition: pns_algo_base.cpp:28

PNS::ARC
Definition: pns_arc.h:38

PNS::ARC::Arc
SHAPE_ARC & Arc()
Definition: pns_arc.h:115

PNS::DIFF_PAIR_PLACER::CurrentNode
NODE * CurrentNode(bool aLoopsRemoved=false) const override
Return the most recent world state.
Definition: pns_diff_pair_placer.cpp:411

PNS::DIFF_PAIR_PLACER::SetOrthoMode
void SetOrthoMode(bool aOrthoMode) override
Function SetOrthoMode()
Definition: pns_diff_pair_placer.cpp:81

PNS::DIFF_PAIR_PLACER::HasPlacedAnything
bool HasPlacedAnything() const override
Definition: pns_diff_pair_placer.cpp:855

PNS::DIFF_PAIR_PLACER::m_chainedPlacement
bool m_chainedPlacement
Definition: pns_diff_pair_placer.h:225

PNS::DIFF_PAIR_PLACER::m_world
NODE * m_world
current routing start point (end of tail, beginning of head)
Definition: pns_diff_pair_placer.h:239

PNS::DIFF_PAIR_PLACER::m_currentEndItem
ITEM * m_currentEndItem
Definition: pns_diff_pair_placer.h:277

PNS::DIFF_PAIR_PLACER::gap
int gap() const
Definition: pns_diff_pair_placer.cpp:600

PNS::DIFF_PAIR_PLACER::tryWalkDp
bool tryWalkDp(NODE *aNode, DIFF_PAIR &aPair, bool aSolidsOnly)
route step, walk around mode
Definition: pns_diff_pair_placer.cpp:277

PNS::DIFF_PAIR_PLACER::propagateDpHeadForces
bool propagateDpHeadForces(const VECTOR2I &aP, VECTOR2I &aNewP)
Definition: pns_diff_pair_placer.cpp:115

PNS::DIFF_PAIR_PLACER::~DIFF_PAIR_PLACER
~DIFF_PAIR_PLACER()
Definition: pns_diff_pair_placer.cpp:61

PNS::DIFF_PAIR_PLACER::m_netN
NET_HANDLE m_netN
Definition: pns_diff_pair_placer.h:230

PNS::DIFF_PAIR_PLACER::m_currentTrace
DIFF_PAIR m_currentTrace
Definition: pns_diff_pair_placer.h:274

PNS::DIFF_PAIR_PLACER::rhMarkObstacles
bool rhMarkObstacles(const VECTOR2I &aP)
Definition: pns_diff_pair_placer.cpp:101

PNS::DIFF_PAIR_PLACER::m_currentWidth
int m_currentWidth
Definition: pns_diff_pair_placer.h:265

PNS::DIFF_PAIR_PLACER::m_viaDiameter
int m_viaDiameter
current via drill
Definition: pns_diff_pair_placer.h:259

PNS::DIFF_PAIR_PLACER::m_orthoMode
bool m_orthoMode
Definition: pns_diff_pair_placer.h:270

PNS::DIFF_PAIR_PLACER::m_prevPair
std::optional< DP_PRIMITIVE_PAIR > m_prevPair
current algorithm iteration
Definition: pns_diff_pair_placer.h:233

PNS::DIFF_PAIR_PLACER::m_currentTraceOk
bool m_currentTraceOk
Definition: pns_diff_pair_placer.h:275

PNS::DIFF_PAIR_PLACER::m_currentStart
VECTOR2I m_currentStart
Definition: pns_diff_pair_placer.h:273

PNS::DIFF_PAIR_PLACER::m_startDiagonal
bool m_startDiagonal
Definition: pns_diff_pair_placer.h:227

PNS::DIFF_PAIR_PLACER::m_state
State m_state
Definition: pns_diff_pair_placer.h:223

PNS::DIFF_PAIR_PLACER::ToggleVia
bool ToggleVia(bool aEnabled) override
Enable/disable a via at the end of currently routed trace.
Definition: pns_diff_pair_placer.cpp:90

PNS::DIFF_PAIR_PLACER::route
bool route(const VECTOR2I &aP)
Re-route the current track to point aP.
Definition: pns_diff_pair_placer.cpp:333

PNS::DIFF_PAIR_PLACER::AbortPlacement
bool AbortPlacement() override
Definition: pns_diff_pair_placer.cpp:848

PNS::DIFF_PAIR_PLACER::m_iteration
int m_iteration
pointer to world to search colliding items
Definition: pns_diff_pair_placer.h:236

PNS::DIFF_PAIR_PLACER::rhShoveOnly
bool rhShoveOnly(const VECTOR2I &aP)
route step, mark obstacles mode
Definition: pns_diff_pair_placer.cpp:351

PNS::DIFF_PAIR_PLACER::Start
bool Start(const VECTOR2I &aP, ITEM *aStartItem) override
Start routing a single track at point aP, taking item aStartItem as anchor (unless NULL).
Definition: pns_diff_pair_placer.cpp:606

PNS::DIFF_PAIR_PLACER::CommitPlacement
bool CommitPlacement() override
Definition: pns_diff_pair_placer.cpp:861

PNS::DIFF_PAIR_PLACER::m_fitOk
bool m_fitOk
Definition: pns_diff_pair_placer.h:228

PNS::DIFF_PAIR_PLACER::Traces
const ITEM_SET Traces() override
Return the complete routed line, as a single-member ITEM_SET.
Definition: pns_diff_pair_placer.cpp:391

PNS::DIFF_PAIR_PLACER::GetModifiedNets
void GetModifiedNets(std::vector< NET_HANDLE > &aNets) const override
Function GetModifiedNets.
Definition: pns_diff_pair_placer.cpp:872

PNS::DIFF_PAIR_PLACER::m_viaDrill
int m_viaDrill
current track width
Definition: pns_diff_pair_placer.h:262

PNS::DIFF_PAIR_PLACER::FlipPosture
void FlipPosture() override
Toggle the current posture (straight/diagonal) of the trace head.
Definition: pns_diff_pair_placer.cpp:402

PNS::DIFF_PAIR_PLACER::m_currentLayer
int m_currentLayer
Definition: pns_diff_pair_placer.h:267

PNS::DIFF_PAIR_PLACER::DIFF_PAIR_PLACER
DIFF_PAIR_PLACER(ROUTER *aRouter)
Definition: pns_diff_pair_placer.cpp:33

PNS::DIFF_PAIR_PLACER::viaGap
int viaGap() const
Definition: pns_diff_pair_placer.cpp:593

PNS::DIFF_PAIR_PLACER::RT_START
@ RT_START
Definition: pns_diff_pair_placer.h:218

PNS::DIFF_PAIR_PLACER::m_initialDiagonal
bool m_initialDiagonal
Definition: pns_diff_pair_placer.h:226

PNS::DIFF_PAIR_PLACER::attemptWalk
bool attemptWalk(NODE *aNode, DIFF_PAIR *aCurrent, DIFF_PAIR &aWalk, bool aPFirst, bool aWindCw, bool aSolidsOnly)
Definition: pns_diff_pair_placer.cpp:197

PNS::DIFF_PAIR_PLACER::setWorld
void setWorld(NODE *aWorld)
Set the board to route.
Definition: pns_diff_pair_placer.cpp:65

PNS::DIFF_PAIR_PLACER::m_netP
NET_HANDLE m_netP
Definition: pns_diff_pair_placer.h:230

PNS::DIFF_PAIR_PLACER::m_idle
bool m_idle
Definition: pns_diff_pair_placer.h:279

PNS::DIFF_PAIR_PLACER::m_snapOnTarget
bool m_snapOnTarget
Definition: pns_diff_pair_placer.h:271

PNS::DIFF_PAIR_PLACER::m_currentNode
NODE * m_currentNode
Postprocessed world state (including marked collisions & removed loops)
Definition: pns_diff_pair_placer.h:248

PNS::DIFF_PAIR_PLACER::m_currentEnd
VECTOR2I m_currentEnd
Definition: pns_diff_pair_placer.h:273

PNS::DIFF_PAIR_PLACER::initPlacement
void initPlacement()
Initialize placement of a new line with given parameters.
Definition: pns_diff_pair_placer.cpp:638

PNS::DIFF_PAIR_PLACER::CurrentNets
const std::vector< NET_HANDLE > CurrentNets() const override
Return the net of currently routed track.
Definition: pns_diff_pair_placer.cpp:892

PNS::DIFF_PAIR_PLACER::routeHead
bool routeHead(const VECTOR2I &aP)
Definition: pns_diff_pair_placer.cpp:659

PNS::DIFF_PAIR_PLACER::m_startsOnVia
bool m_startsOnVia
Definition: pns_diff_pair_placer.h:269

PNS::DIFF_PAIR_PLACER::UpdateSizes
void UpdateSizes(const SIZES_SETTINGS &aSizes) override
Perform on-the-fly update of the width, via diameter & drill size from a settings class.
Definition: pns_diff_pair_placer.cpp:764

PNS::DIFF_PAIR_PLACER::FindDpPrimitivePair
static bool FindDpPrimitivePair(NODE *aWorld, const VECTOR2I &aP, ITEM *aItem, DP_PRIMITIVE_PAIR &aPair, wxString *aErrorMsg=nullptr)
Definition: pns_diff_pair_placer.cpp:498

PNS::DIFF_PAIR_PLACER::rhWalkOnly
bool rhWalkOnly(const VECTOR2I &aP)
route step, shove mode
Definition: pns_diff_pair_placer.cpp:322

PNS::DIFF_PAIR_PLACER::Move
bool Move(const VECTOR2I &aP, ITEM *aEndItem) override
Move the end of the currently routed trace to the point aP, taking aEndItem as anchor (if not NULL).
Definition: pns_diff_pair_placer.cpp:742

PNS::DIFF_PAIR_PLACER::m_start
DP_PRIMITIVE_PAIR m_start
Definition: pns_diff_pair_placer.h:232

PNS::DIFF_PAIR_PLACER::FixRoute
bool FixRoute(const VECTOR2I &aP, ITEM *aEndItem, bool aForceFinish) override
Commit the currently routed track to the parent node, taking aP as the final end point and aEndItem a...
Definition: pns_diff_pair_placer.cpp:782

PNS::DIFF_PAIR_PLACER::m_lastNode
NODE * m_lastNode
Definition: pns_diff_pair_placer.h:251

PNS::DIFF_PAIR_PLACER::m_placingVia
bool m_placingVia
current via diameter
Definition: pns_diff_pair_placer.h:256

PNS::DIFF_PAIR_PLACER::updateLeadingRatLine
void updateLeadingRatLine()
Draw the "leading" ratsnest line, which connects the end of currently routed track and the nearest ye...
Definition: pns_diff_pair_placer.cpp:879

PNS::DIFF_PAIR_PLACER::makeVia
const VIA makeVia(const VECTOR2I &aP, NET_HANDLE aNet)
Definition: pns_diff_pair_placer.cpp:71

PNS::DIFF_PAIR_PLACER::m_sizes
SIZES_SETTINGS m_sizes
Are we placing a via?
Definition: pns_diff_pair_placer.h:253

PNS::DIFF_PAIR_PLACER::SetLayer
bool SetLayer(int aLayer) override
Set the current routing layer.
Definition: pns_diff_pair_placer.cpp:420

PNS::DIFF_PAIR_PLACER::m_shove
std::unique_ptr< SHOVE > m_shove
Current world state.
Definition: pns_diff_pair_placer.h:245

PNS::DIFF_PAIR
Basic class for a differential pair.
Definition: pns_diff_pair.h:235

PNS::DIFF_PAIR::AppendVias
void AppendVias(const VIA &aViaP, const VIA &aViaN)
Definition: pns_diff_pair.h:393

PNS::DIFF_PAIR::CN
const SHAPE_LINE_CHAIN & CN() const
Definition: pns_diff_pair.h:479

PNS::DIFF_PAIR::EndingPrimitives
DP_PRIMITIVE_PAIR EndingPrimitives()
Definition: pns_diff_pair.cpp:769

PNS::DIFF_PAIR::CoupledLength
double CoupledLength() const
Definition: pns_diff_pair.cpp:894

PNS::DIFF_PAIR::RemoveVias
void RemoveVias()
Definition: pns_diff_pair.h:402

PNS::DIFF_PAIR::Skew
double Skew() const
Definition: pns_diff_pair.cpp:833

PNS::DIFF_PAIR::NLine
LINE & NLine()
Definition: pns_diff_pair.h:444

PNS::DIFF_PAIR::SetViaDiameter
void SetViaDiameter(int aDiameter)
Definition: pns_diff_pair.h:414

PNS::DIFF_PAIR::SetViaDrill
void SetViaDrill(int aDrill)
Definition: pns_diff_pair.h:420

PNS::DIFF_PAIR::SetShape
void SetShape(const SHAPE_LINE_CHAIN &aP, const SHAPE_LINE_CHAIN &aN, bool aSwapLanes=false)
Definition: pns_diff_pair.h:347

PNS::DIFF_PAIR::Gap
int Gap() const
Definition: pns_diff_pair.h:388

PNS::DIFF_PAIR::EndsWithVias
bool EndsWithVias() const
Definition: pns_diff_pair.h:409

PNS::DIFF_PAIR::SetGap
void SetGap(int aGap)
Definition: pns_diff_pair.h:382

PNS::DIFF_PAIR::SetNets
void SetNets(NET_HANDLE aP, NET_HANDLE aN)
Definition: pns_diff_pair.h:367

PNS::DIFF_PAIR::CP
const SHAPE_LINE_CHAIN & CP() const
Definition: pns_diff_pair.h:478

PNS::DIFF_PAIR::PLine
LINE & PLine()
Definition: pns_diff_pair.h:436

PNS::DIFF_PAIR::SetWidth
void SetWidth(int aWidth)
Definition: pns_diff_pair.h:373

PNS::DP_GATEWAYS
A set of gateways calculated for the cursor or starting/ending primitive pair.
Definition: pns_diff_pair.h:168

PNS::DP_GATEWAYS::SetFitVias
void SetFitVias(bool aEnable, int aDiameter=0, int aViaGap=-1)
Definition: pns_diff_pair.h:181

PNS::DP_GATEWAYS::BuildFromPrimitivePair
void BuildFromPrimitivePair(const DP_PRIMITIVE_PAIR &aPair, bool aPreferDiagonal)
Definition: pns_diff_pair.cpp:423

PNS::DP_GATEWAYS::FitGateways
bool FitGateways(DP_GATEWAYS &aEntry, DP_GATEWAYS &aTarget, bool aPrefDiagonal, DIFF_PAIR &aDp)
Definition: pns_diff_pair.cpp:341

PNS::DP_GATEWAYS::FilterByOrientation
void FilterByOrientation(int aAngleMask, DIRECTION_45 aRefOrientation)
Definition: pns_diff_pair.cpp:396

PNS::DP_GATEWAYS::BuildForCursor
void BuildForCursor(const VECTOR2I &aCursorPos)
Definition: pns_diff_pair.cpp:551

PNS::DP_PRIMITIVE_PAIR
Store starting/ending primitives (pads, vias or segments) for a differential pair.
Definition: pns_diff_pair.h:120

PNS::DP_PRIMITIVE_PAIR::PrimN
ITEM * PrimN() const
Definition: pns_diff_pair.h:139

PNS::DP_PRIMITIVE_PAIR::PrimP
ITEM * PrimP() const
Definition: pns_diff_pair.h:138

PNS::DP_PRIMITIVE_PAIR::SetAnchors
void SetAnchors(const VECTOR2I &aAnchorP, const VECTOR2I &aAnchorN)
Definition: pns_diff_pair.cpp:47

PNS::ITEM_SET
Definition: pns_itemset.h:37

PNS::ITEM_SET::Add
void Add(const LINE &aLine)
Definition: pns_itemset.cpp:33

PNS::ITEM
Base class for PNS router board items.
Definition: pns_item.h:97

PNS::ITEM::Layers
const PNS_LAYER_RANGE & Layers() const
Definition: pns_item.h:199

PNS::ITEM::Net
virtual NET_HANDLE Net() const
Definition: pns_item.h:197

PNS::ITEM::Kind
PnsKind Kind() const
Return the type (kind) of the item.
Definition: pns_item.h:170

PNS::ITEM::RelevantShapeLayers
std::set< int > RelevantShapeLayers(const ITEM *aOther) const
Returns the set of layers on which either this or the other item can have a unique shape.
Definition: pns_item.cpp:94

PNS::ITEM::SetLayer
void SetLayer(int aLayer)
Definition: pns_item.h:202

PNS::ITEM::SOLID_T
@ SOLID_T
Definition: pns_item.h:103

PNS::ITEM::LINE_T
@ LINE_T
Definition: pns_item.h:104

PNS::ITEM::ARC_T
@ ARC_T
Definition: pns_item.h:107

PNS::ITEM::SEGMENT_T
@ SEGMENT_T
Definition: pns_item.h:106

PNS::ITEM::VIA_T
@ VIA_T
Definition: pns_item.h:108

PNS::ITEM::ANY_T
@ ANY_T
Definition: pns_item.h:111

PNS::ITEM::Anchor
virtual VECTOR2I Anchor(int n) const
Definition: pns_item.h:255

PNS::JOINT
A 2D point on a given set of layers and belonging to a certain net, that links together a number of b...
Definition: pns_joint.h:43

PNS::JOINT::LinkCount
int LinkCount(int aMask=-1) const
Definition: pns_joint.h:312

PNS::LINE
Represents a track on a PCB, connecting two non-trivial joints (that is, vias, pads,...
Definition: pns_line.h:62

PNS::LINE::CPoint
const VECTOR2I & CPoint(int aIdx) const
Definition: pns_line.h:146

PNS::LINE::CLine
const SHAPE_LINE_CHAIN & CLine() const
Definition: pns_line.h:138

PNS::LINE::Line
SHAPE_LINE_CHAIN & Line()
Definition: pns_line.h:137

PNS::LINE::Via
VIA & Via()
Definition: pns_line.h:198

PNS::LINE::PointCount
int PointCount() const
Definition: pns_line.h:141

PNS::NODE
Keep the router "world" - i.e.
Definition: pns_node.h:231

PNS::NODE::Branch
NODE * Branch()
Create a lightweight copy (called branch) of self that tracks the changes (added/removed items) wrs t...
Definition: pns_node.cpp:143

PNS::NODE::GetClearance
int GetClearance(const ITEM *aA, const ITEM *aB, bool aUseClearanceEpsilon=true) const
Return the pre-set worst case clearance between any pair of items.
Definition: pns_node.cpp:129

PNS::NODE::CheckColliding
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.
Definition: pns_node.cpp:410

PNS::NODE::FindJoint
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.
Definition: pns_node.cpp:1242

PNS::NODE::OPT_OBSTACLE
std::optional< OBSTACLE > OPT_OBSTACLE
Definition: pns_node.h:241

PNS::NODE::GetRuleResolver
RULE_RESOLVER * GetRuleResolver() const
Return the number of joints.
Definition: pns_node.h:269

PNS::NODE::Add
bool Add(std::unique_ptr< SEGMENT > aSegment, bool aAllowRedundant=false)
Add an item to the current node.
Definition: pns_node.cpp:665

PNS::NODE::AllItemsInNet
void AllItemsInNet(NET_HANDLE aNet, std::set< ITEM * > &aItems, int aKindMask=-1)
Definition: pns_node.cpp:1529

PNS::NODE::KillChildren
void KillChildren()
Definition: pns_node.cpp:1523

PNS::OPTIMIZER
Perform various optimizations of the lines being routed, attempting to make the lines shorter and les...
Definition: pns_optimizer.h:95

PNS::OPTIMIZER::Optimize
static bool Optimize(const LINE *aLine, int aEffortLevel, NODE *aWorld, const VECTOR2I &aV=VECTOR2I(0, 0))
Definition: pns_optimizer.cpp:1106

PNS::PLACEMENT_ALGO
PLACEMENT_ALGO.
Definition: pns_placement_algo.h:46

PNS::ROUTER_IFACE::DisplayRatline
virtual void DisplayRatline(const SHAPE_LINE_CHAIN &aRatline, NET_HANDLE aNetCode)=0

PNS::ROUTER
Definition: pns_router.h:125

PNS::ROUTER::GetInterface
ROUTER_IFACE * GetInterface() const
Definition: pns_router.h:223

PNS::ROUTER::SetFailureReason
void SetFailureReason(const wxString &aReason)
Definition: pns_router.h:218

PNS::ROUTER::CommitRouting
void CommitRouting()
Definition: pns_router.cpp:921

PNS::ROUTER::GetWorld
NODE * GetWorld() const
Definition: pns_router.h:169

PNS::RULE_RESOLVER::DpNetPair
virtual bool DpNetPair(const ITEM *aItem, NET_HANDLE &aNetP, NET_HANDLE &aNetN)=0

PNS::RULE_RESOLVER::NetName
virtual wxString NetName(NET_HANDLE aNet)=0

PNS::SEGMENT
Definition: pns_segment.h:39

PNS::SEGMENT::Seg
const SEG & Seg() const
Definition: pns_segment.h:90

PNS::SHOVE
The actual Push and Shove algorithm.
Definition: pns_shove.h:46

PNS::SHOVE::ForceClearance
void ForceClearance(bool aEnabled, int aClearance)
Definition: pns_shove.h:88

PNS::SHOVE::SHOVE_STATUS
SHOVE_STATUS
Definition: pns_shove.h:50

PNS::SHOVE::SH_INCOMPLETE
@ SH_INCOMPLETE
Definition: pns_shove.h:53

PNS::SHOVE::SH_OK
@ SH_OK
Definition: pns_shove.h:51

PNS::SHOVE::ShoveObstacleLine
bool ShoveObstacleLine(const LINE &aCurLine, const LINE &aObstacleLine, LINE &aResultLine)
Definition: pns_shove.cpp:428

PNS::SIZES_SETTINGS
Definition: pns_sizes_settings.h:38

PNS::SIZES_SETTINGS::ViaType
VIATYPE ViaType() const
Definition: pns_sizes_settings.h:120

PNS::SIZES_SETTINGS::ViaDrill
int ViaDrill() const
Definition: pns_sizes_settings.h:102

PNS::SIZES_SETTINGS::DiffPairWidth
int DiffPairWidth() const
Definition: pns_sizes_settings.h:80

PNS::SIZES_SETTINGS::ViaDiameter
int ViaDiameter() const
Definition: pns_sizes_settings.h:99

PNS::SIZES_SETTINGS::GetLayerBottom
int GetLayerBottom() const
Definition: pns_sizes_settings.cpp:55

PNS::SIZES_SETTINGS::GetLayerTop
int GetLayerTop() const
Definition: pns_sizes_settings.cpp:46

PNS::SIZES_SETTINGS::DiffPairGap
int DiffPairGap() const
Definition: pns_sizes_settings.h:81

PNS::SIZES_SETTINGS::GetDiffPairHoleToHole
int GetDiffPairHoleToHole() const
Definition: pns_sizes_settings.h:135

PNS::SIZES_SETTINGS::DiffPairViaGap
int DiffPairViaGap() const
Definition: pns_sizes_settings.h:83

PNS::TOPOLOGY
Definition: pns_topology.h:40

PNS::TOPOLOGY::LeadingRatLine
bool LeadingRatLine(const LINE *aTrack, SHAPE_LINE_CHAIN &aRatLine)
Definition: pns_topology.cpp:143

PNS::TOPOLOGY::SimplifyLine
bool SimplifyLine(LINE *aLine)
Definition: pns_topology.cpp:39

PNS::VIA
Definition: pns_via.h:59

PNS::VIA::Diameter
int Diameter(int aLayer) const
Definition: pns_via.h:191

PNS::VIA::SetDiameter
void SetDiameter(int aLayer, int aDiameter)
Definition: pns_via.h:198

PNS::VIA::Pos
const VECTOR2I & Pos() const
Definition: pns_via.h:175

PNS::VIA::Shape
const SHAPE * Shape(int aLayer) const override
Return the geometrical shape of the item.
Definition: pns_via.h:229

PNS::VIA::SetPos
void SetPos(const VECTOR2I &aPos)
Definition: pns_via.h:177

PNS::WALKAROUND
Definition: pns_walkaround.h:37

PNS::WALKAROUND::SetIterationLimit
void SetIterationLimit(const int aIterLimit)
Definition: pns_walkaround.h:93

PNS::WALKAROUND::SetSolidsOnly
void SetSolidsOnly(bool aSolidsOnly)
Definition: pns_walkaround.h:98

PNS::WALKAROUND::Route
STATUS Route(const LINE &aInitialPath, LINE &aWalkPath, bool aOptimize=true)

PNS::WALKAROUND::SetAllowedPolicies
void SetAllowedPolicies(std::vector< WALK_POLICY > aPolicies)
Definition: pns_walkaround.cpp:370

PNS::WALKAROUND::WP_SHORTEST
@ WP_SHORTEST
Definition: pns_walkaround.h:73

PNS::WALKAROUND::STATUS
STATUS
Definition: pns_walkaround.h:61

PNS::WALKAROUND::ST_DONE
@ ST_DONE
Definition: pns_walkaround.h:64

PNS_LAYER_RANGE
Represent a contiguous set of PCB layers.
Definition: pns_layerset.h:32

SEG
Definition: seg.h:42

SEG::A
VECTOR2I A
Definition: seg.h:49

SEG::B
VECTOR2I B
Definition: seg.h:50

SEG::LineProject
VECTOR2I LineProject(const VECTOR2I &aP) const
Compute the perpendicular projection point of aP on a line passing through ends of the segment.
Definition: seg.cpp:371

SHAPE_ARC::GetP1
const VECTOR2I & GetP1() const
Definition: shape_arc.h:115

SHAPE_ARC::GetP0
const VECTOR2I & GetP0() const
Definition: shape_arc.h:114

SHAPE_LINE_CHAIN
Represent a polyline containing arcs as well as line segments: A chain of connected line and/or arc s...
Definition: shape_line_chain.h:83

SHAPE_LINE_CHAIN::Simplify
void Simplify(int aMaxError=0)
Simplify the line chain by removing colinear adjacent segments and duplicate vertices.
Definition: shape_line_chain.cpp:2592

SHAPE_LINE_CHAIN::CPoint
const VECTOR2I & CPoint(int aIndex) const
Return a reference to a given point in the line chain.
Definition: shape_line_chain.h:407

SHAPE_LINE_CHAIN::SegmentCount
int SegmentCount() const
Return the number of segments in this line chain.
Definition: shape_line_chain.h:314

SHAPE_LINE_CHAIN::Remove
void Remove(int aStartIndex, int aEndIndex)
Remove the range of points [start_index, end_index] from the line chain.
Definition: shape_line_chain.cpp:1124

SHAPE_LINE_CHAIN::CSegment
const SEG CSegment(int aIndex) const
Return a constant copy of the aIndex segment in the line chain.
Definition: shape_line_chain.h:377

VECTOR2< int32_t >

VECTOR2::SquaredEuclideanNorm
constexpr extended_type SquaredEuclideanNorm() const
Compute the squared euclidean norm of the vector, which is defined as (x ** 2 + y ** 2).
Definition: vector2d.h:307

_
#define _(s)
Definition: eda_3d_actions.cpp:35

PNS
Push and Shove diff pair dimensions (gap) settings dialog.
Definition: dialog_pns_diff_pair_dimensions.h:33

PNS::getDanglingAnchor
OPT_VECTOR2I getDanglingAnchor(NODE *aNode, ITEM *aItem)
Definition: pns_diff_pair_placer.cpp:445

PNS::RM_MarkObstacles
@ RM_MarkObstacles
Ignore collisions, mark obstacles.
Definition: pns_routing_settings.h:41

PNS::RM_Walkaround
@ RM_Walkaround
Only walk around.
Definition: pns_routing_settings.h:43

PNS::RM_Shove
@ RM_Shove
Only shove.
Definition: pns_routing_settings.h:42

PNS::NET_HANDLE
void * NET_HANDLE
Definition: pns_item.h:54

PNS::Clone
std::unique_ptr< typename std::remove_const< T >::type > Clone(const T &aItem)
Definition: pns_item.h:327

pns_arc.h

pns_debug_decorator.h

pns_diff_pair_placer.h

PNS_HULL_MARGIN
#define PNS_HULL_MARGIN
Definition: pns_line.h:45

pns_router.h

pns_shove.h

pns_solid.h

pns_topology.h

pns_walkaround.h

OPT_VECTOR2I
std::optional< VECTOR2I > OPT_VECTOR2I
Definition: seg.h:39