doxygen/pns__meander_8cpp_source.html

/*

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

 *

 * Copyright (C) 2013-2014 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_node.h"

#include "pns_itemset.h"

#include "pns_meander.h"

#include "pns_meander_placer_base.h"

#include "pns_router.h"

#include "pns_debug_decorator.h"


namespace PNS {


const MEANDER_SETTINGS& MEANDER_SHAPE::Settings() const

{

 return m_placer->MeanderSettings();

}


const MEANDER_SETTINGS& MEANDERED_LINE::Settings() const

{

 return m_placer->MeanderSettings();

}


void MEANDERED_LINE::MeanderSegment( const SEG& aBase, bool aSide, int aBaseIndex )

{

 double base_len = aBase.Length();


 SHAPE_LINE_CHAIN lc;


 bool singleSided = Settings().m_singleSided;

 bool side = aSide;

 VECTOR2D dir( aBase.B - aBase.A );


 if( !m_dual )

 AddCorner( aBase.A );


 bool turning = false;

 bool started = false;


 m_last = aBase.A;


 do

 {

 MEANDER_SHAPE m( m_placer, m_width, m_dual );


 m.SetBaselineOffset( m_baselineOffset );

 m.SetBaseIndex( aBaseIndex );


 double thr = (double) m.spacing();


 bool fail = false;

 double remaining = base_len - ( m_last - aBase.A ).EuclideanNorm();


 auto flipInitialSide =

 [&]()

 {

 MEANDER_SETTINGS settings = m_placer->MeanderSettings();

 settings.m_initialSide = (PNS::MEANDER_SIDE) -settings.m_initialSide;

 m_placer->UpdateSettings( settings );

 };


 auto addSingleIfFits =

 [&]()

 {

 fail = true;


 if( m.Fit( MT_SINGLE, aBase, m_last, side ) )

 {

 AddMeander( new MEANDER_SHAPE( m ) );

 fail = false;

 started = false;

 }


 if( fail && !singleSided )

 {

 if( m.Fit( MT_SINGLE, aBase, m_last, !side ) )

 {

 if( !started )

 flipInitialSide();


 AddMeander( new MEANDER_SHAPE( m ) );

 fail = false;

 started = false;

 side = !side;

 }

 }

 };


 if( remaining < Settings( ).m_step )

 break;


 if( !singleSided && remaining > 3.0 * thr )

 {

 if( !turning )

 {

 for( int i = 0; i < 2; i++ )

 {

 bool checkSide = ( i == 0 ) ? side : !side;


 if( m.Fit( MT_CHECK_START, aBase, m_last, checkSide ) )

 {

 if( !started && checkSide != side )

 flipInitialSide();


 turning = true;

 AddMeander( new MEANDER_SHAPE( m ) );

 side = !checkSide;

 started = true;

 break;

 }

 }


 if( !turning )

 addSingleIfFits();

 }

 else

 {

 bool rv = m.Fit( MT_CHECK_FINISH, aBase, m_last, side );


 if( rv )

 {

 m.Fit( MT_TURN, aBase, m_last, side );

 AddMeander( new MEANDER_SHAPE( m ) );

 side = !side;

 started = true;

 }

 else

 {

 m.Fit( MT_FINISH, aBase, m_last, side );

 started = false;

 AddMeander( new MEANDER_SHAPE( m ) );

 turning = false;

 }

 }

 }

 else if( !singleSided && started )

 {

 bool rv = m.Fit( MT_FINISH, aBase, m_last, side );


 if( rv )

 AddMeander( new MEANDER_SHAPE( m ) );


 break;


 }

 else if( !turning && remaining > thr * 2.0 )

 {

 addSingleIfFits();

 }

 else

 {

 fail = true;

 }


 remaining = base_len - ( m_last - aBase.A ).EuclideanNorm( );


 if( remaining < Settings( ).m_step )

 break;


 if( fail )

 {

 MEANDER_SHAPE tmp( m_placer, m_width, m_dual );

 tmp.SetBaselineOffset( m_baselineOffset );

 tmp.SetBaseIndex( aBaseIndex );


 int nextP = tmp.spacing() - 2 * tmp.cornerRadius() + Settings().m_step;

 VECTOR2I pn = m_last + dir.Resize( nextP );


 if( aBase.Contains( pn ) && !m_dual )

 AddCorner( pn );

 else

 break;

 }


 } while( true );


 if( !m_dual )

 AddCorner( aBase.B );

}


int MEANDER_SHAPE::MinAmplitude() const

{

 int minAmplitude = Settings().m_minAmplitude;


 // DP meanders don't really support smaller amplitudes

 minAmplitude = std::max( minAmplitude, std::abs( m_baselineOffset ) * 2 );


 // The path length won't be correct with very small arcs

 if( m_placer->MeanderSettings().m_cornerStyle == MEANDER_STYLE_ROUND )

 minAmplitude = std::max( minAmplitude, m_width + std::abs( m_baselineOffset ) * 2 );


 return minAmplitude;

}


int MEANDER_SHAPE::cornerRadius() const

{

 int rPercent = Settings().m_cornerRadiusPercentage;

 int optCr = static_cast<int>( static_cast<SEG::ecoord>( spacing() ) * rPercent / 200 );

 int minCr = std::abs( m_baselineOffset );

 int maxCr = std::min( m_amplitude / 2, spacing() / 2 );


 if( maxCr > minCr )

 return std::clamp( optCr, minCr, maxCr );

 else

 return maxCr;

}


int MEANDER_SHAPE::spacing( ) const

{

 if( !m_dual )

 {

 return std::max( m_width + m_placer->Clearance(), Settings().m_spacing );

 }

 else

 {

 int sp = m_width + m_placer->Clearance() + ( 2 * std::abs( m_baselineOffset ) );

 return std::max( sp, Settings().m_spacing );

 }

}


SHAPE_LINE_CHAIN MEANDER_SHAPE::makeMiterShape( const VECTOR2D& aP, const VECTOR2D& aDir,

 bool aSide )

{

 SHAPE_LINE_CHAIN lc;


 if( aDir.EuclideanNorm( ) == 0.0f )

 {

 lc.Append( aP );

 return lc;

 }


 VECTOR2D dir_u( aDir );

 VECTOR2D dir_v( aDir.Perpendicular( ) );

 VECTOR2D p = aP;

 lc.Append( ( int ) p.x, ( int ) p.y );


 // fixme: refactor

 switch( m_placer->MeanderSettings().m_cornerStyle )

 {

 case MEANDER_STYLE_ROUND:

 {

 VECTOR2D center = aP + dir_v * ( aSide ? -1.0 : 1.0 );


 lc.Append( SHAPE_ARC( center, aP, ( aSide ? -ANGLE_90 : ANGLE_90 ) ) );

 break;

 }


 case MEANDER_STYLE_CHAMFER:

 {

 double radius = (double) aDir.EuclideanNorm();

 double correction = 0;


 if( m_dual && radius > m_meanCornerRadius )

 correction = (double)( -2 * abs(m_baselineOffset) ) * tan( 22.5 * M_PI / 180.0 );


 VECTOR2D dir_cu = dir_u.Resize( correction );

 VECTOR2D dir_cv = dir_v.Resize( correction );


 p = aP - dir_cu;

 lc.Append( ( int ) p.x, ( int ) p.y );

 p = aP + dir_u + (dir_v + dir_cv) * ( aSide ? -1.0 : 1.0 );

 lc.Append( ( int ) p.x, ( int ) p.y );

 break;

 }


 default:

 break;

 }


 p = aP + dir_u + dir_v * ( aSide ? -1.0 : 1.0 );

 lc.Append( ( int ) p.x, ( int ) p.y );


 return lc;

}


void MEANDER_SHAPE::start( SHAPE_LINE_CHAIN* aTarget, const VECTOR2D& aWhere, const VECTOR2D& aDir )

{

 m_currentTarget = aTarget;

 m_currentTarget->Clear();

 m_currentTarget->Append( aWhere );

 m_currentDir = aDir;

 m_currentPos = aWhere;

}


void MEANDER_SHAPE::forward( int aLength )

{

 // Very small segments cause problems.

 if( aLength < 5 )

 return;


 m_currentPos += m_currentDir.Resize( aLength );

 m_currentTarget->Append( m_currentPos );

}


void MEANDER_SHAPE::turn( const EDA_ANGLE& aAngle )

{

 RotatePoint( m_currentDir, aAngle );

}


void MEANDER_SHAPE::miter( int aRadius, bool aSide )

{

 if( aRadius <= 0 )

 {

 turn( aSide ? ANGLE_90 : -ANGLE_90 );

 return;

 }


 VECTOR2D dir = m_currentDir.Resize( (double) aRadius );

 SHAPE_LINE_CHAIN lc = makeMiterShape( m_currentPos, dir, aSide );


 m_currentPos = lc.CPoint( -1 );

 turn( aSide ? ANGLE_90 : -ANGLE_90 );


 m_currentTarget->Append( lc );

}


void MEANDER_SHAPE::uShape( int aSides, int aCorner, int aTop )

{

 forward( aSides );

 miter( aCorner, true );

 forward( aTop );

 miter( aCorner, true );

 forward( aSides );

}


SHAPE_LINE_CHAIN MEANDER_SHAPE::genMeanderShape( const VECTOR2D& aP, const VECTOR2D& aDir,

 bool aSide, MEANDER_TYPE aType,

 int aBaselineOffset )

{

 int cr = cornerRadius();

 int offset = aBaselineOffset;

 int spc = spacing();

 int amplitude = m_amplitude;

 int targetBaseLen = m_targetBaseLen;


 if( aSide )

 offset *= -1;


 VECTOR2D dir_u_b( aDir.Resize( offset ) );

 VECTOR2D dir_v_b( dir_u_b.Perpendicular() );


 if( 2 * cr > amplitude )

 cr = amplitude / 2;


 if( 2 * cr > spc )

 cr = spc / 2;


 if( cr - offset < 0 )

 cr = offset;


 m_meanCornerRadius = cr;


 int sCorner = cr - offset;

 int uCorner = cr + offset;

 int startSide = amplitude - 2 * cr + std::abs( offset );

 int turnSide = amplitude - cr;

 int top = spc - 2 * cr;


 SHAPE_LINE_CHAIN lc;


 start( &lc, aP + dir_v_b, aDir );


 switch( aType )

 {

 case MT_EMPTY:

 {

 lc.Append( aP + dir_v_b + aDir );

 break;

 }

 case MT_START:

 {

 if( targetBaseLen )

 top = std::max( top, targetBaseLen - sCorner - uCorner * 2 + offset );


 miter( sCorner, false );

 uShape( startSide, uCorner, top );

 forward( std::min( sCorner, uCorner ) );

 forward( std::abs( offset ) );

 break;

 }


 case MT_FINISH:

 {

 if( targetBaseLen )

 top = std::max( top, targetBaseLen - cr - spc );


 start( &lc, aP - dir_u_b, aDir );

 turn( -ANGLE_90 );

 forward( std::min( sCorner, uCorner ) );

 forward( std::abs( offset ) );

 uShape( startSide, uCorner, top );

 miter( sCorner, false );


 if( targetBaseLen >= spc + cr )

 lc.Append( aP + dir_v_b + aDir.Resize( targetBaseLen ) );

 else

 lc.Append( aP + dir_v_b + aDir.Resize( 2 * spc - cr ) );


 break;

 }


 case MT_TURN:

 {

 if( targetBaseLen )

 top = std::max( top, targetBaseLen - uCorner * 2 + offset * 2 );


 start( &lc, aP - dir_u_b, aDir );

 turn( -ANGLE_90 );

 forward( std::abs( offset ) );

 uShape( turnSide, uCorner, top );

 forward( std::abs( offset ) );

 break;

 }


 case MT_SINGLE:

 {

 if( targetBaseLen )

 top = std::max( top, ( targetBaseLen - sCorner * 2 - uCorner * 2 ) / 2 );


 miter( sCorner, false );

 uShape( startSide, uCorner, top );

 miter( sCorner, false );

 lc.Append( aP + dir_v_b + aDir.Resize( 2 * spc ) );

 break;

 }


 default:

 break;

 }


 if( aSide )

 {

 SEG axis( aP, aP + aDir );


 lc.Mirror( axis );

 }


 return lc;

}


bool MEANDERED_LINE::CheckSelfIntersections( MEANDER_SHAPE* aShape, int aClearance )

{

 for( int i = m_meanders.size() - 1; i >= 0; i-- )

 {

 MEANDER_SHAPE* m = m_meanders[i];


 if( m->Type() == MT_EMPTY || m->Type() == MT_CORNER )

 continue;


 const SEG& b1 = aShape->BaseSegment();

 const SEG& b2 = m->BaseSegment();


 if( b1.ApproxParallel( b2 ) )

 continue;


 int n = m->CLine( 0 ).SegmentCount();


 for( int j = n - 1; j >= 0; j-- )

 {

 if( aShape->CLine( 0 ).Collide( m->CLine( 0 ) .CSegment( j ), aClearance ) )

 return false;

 }

 }


 return true;

}


bool MEANDER_SHAPE::Fit( MEANDER_TYPE aType, const SEG& aSeg, const VECTOR2I& aP, bool aSide )

{

 const MEANDER_SETTINGS& st = Settings();


 bool checkMode = false;

 MEANDER_TYPE prim1, prim2;


 if( aType == MT_CHECK_START )

 {

 prim1 = MT_START;

 prim2 = MT_TURN;

 checkMode = true;

 }

 else if( aType == MT_CHECK_FINISH )

 {

 prim1 = MT_TURN;

 prim2 = MT_FINISH;

 checkMode = true;

 }


 if( checkMode )

 {

 MEANDER_SHAPE m1( m_placer, m_width, m_dual );

 MEANDER_SHAPE m2( m_placer, m_width, m_dual );


 m1.SetBaselineOffset( m_baselineOffset );

 m2.SetBaselineOffset( m_baselineOffset );


 bool c1 = m1.Fit( prim1, aSeg, aP, aSide );

 bool c2 = false;


 if( c1 )

 c2 = m2.Fit( prim2, aSeg, m1.End(), !aSide );


 if( c1 && c2 )

 {

 m_type = prim1;

 m_shapes[0] = m1.m_shapes[0];

 m_shapes[1] = m1.m_shapes[1];

 m_baseSeg =aSeg;

 m_p0 = aP;

 m_side = aSide;

 m_amplitude = m1.Amplitude();

 m_dual = m1.m_dual;

 m_baseSeg = m1.m_baseSeg;

 m_baseIndex = m1.m_baseIndex;

 updateBaseSegment();

 m_baselineOffset = m1.m_baselineOffset;

 return true;

 }

 else

 {

 return false;

 }

 }


 int minAmpl = MinAmplitude();

 int maxAmpl = std::max( st.m_maxAmplitude, minAmpl );


 for( int ampl = maxAmpl; ampl >= minAmpl; ampl -= st.m_step )

 {

 m_amplitude = ampl;


 if( m_dual )

 {

 m_shapes[0] = genMeanderShape( aP, aSeg.B - aSeg.A, aSide, aType, m_baselineOffset );

 m_shapes[1] = genMeanderShape( aP, aSeg.B - aSeg.A, aSide, aType, -m_baselineOffset );

 }

 else

 {

 m_shapes[0] = genMeanderShape( aP, aSeg.B - aSeg.A, aSide, aType, 0 );

 }


 m_type = aType;

 m_baseSeg = aSeg;

 m_p0 = aP;

 m_side = aSide;


 updateBaseSegment();


 if( m_placer->CheckFit( this ) )

 return true;

 }


 return false;

}


void MEANDER_SHAPE::Recalculate()

{

 m_shapes[0] = genMeanderShape( m_p0, m_baseSeg.B - m_baseSeg.A, m_side, m_type,

 m_dual ? m_baselineOffset : 0 );


 if( m_dual )

 m_shapes[1] = genMeanderShape( m_p0, m_baseSeg.B - m_baseSeg.A, m_side, m_type,

 -m_baselineOffset );


 updateBaseSegment();

}


void MEANDER_SHAPE::Resize( int aAmpl )

{

 if( aAmpl < 0 )

 return;


 m_amplitude = aAmpl;


 Recalculate();

}


void MEANDER_SHAPE::MakeEmpty()

{

 updateBaseSegment();


 VECTOR2I dir = m_clippedBaseSeg.B - m_clippedBaseSeg.A;


 m_type = MT_EMPTY;

 m_amplitude = 0;


 m_shapes[0] = genMeanderShape( m_p0, dir, m_side, m_type, m_dual ? m_baselineOffset : 0 );


 if( m_dual )

 m_shapes[1] = genMeanderShape( m_p0, dir, m_side, m_type, -m_baselineOffset );

}


void MEANDERED_LINE::AddCorner( const VECTOR2I& aA, const VECTOR2I& aB )

{

 MEANDER_SHAPE* m = new MEANDER_SHAPE( m_placer, m_width, m_dual );


 m->MakeCorner( aA, aB );

 m_last = aA;


 m_meanders.push_back( m );

}


void MEANDERED_LINE::AddArc( const SHAPE_ARC& aArc1, const SHAPE_ARC& aArc2 )

{

 MEANDER_SHAPE* m = new MEANDER_SHAPE( m_placer, m_width, m_dual );


 m->MakeArc( aArc1, aArc2 );

 m_last = aArc1.GetP1();


 m_meanders.push_back( m );

}


void MEANDERED_LINE::AddArcAndPt( const SHAPE_ARC& aArc1, const VECTOR2I& aPt2 )

{

 SHAPE_ARC arc2( aPt2, aPt2, aPt2, 0 );


 AddArc( aArc1, arc2 );

}


void MEANDERED_LINE::AddPtAndArc( const VECTOR2I& aPt1, const SHAPE_ARC& aArc2 )

{

 SHAPE_ARC arc1( aPt1, aPt1, aPt1, 0 );


 AddArc( arc1, aArc2 );

}


void MEANDER_SHAPE::MakeCorner( const VECTOR2I& aP1, const VECTOR2I& aP2 )

{

 SetType( MT_CORNER );

 m_shapes[0].Clear();

 m_shapes[1].Clear();

 m_shapes[0].Append( aP1 );

 m_shapes[1].Append( aP2 );

 m_clippedBaseSeg.A = aP1;

 m_clippedBaseSeg.B = aP1;

}


void MEANDER_SHAPE::MakeArc( const SHAPE_ARC& aArc1, const SHAPE_ARC& aArc2 )

{

 SetType( MT_CORNER );

 m_shapes[0].Clear();

 m_shapes[1].Clear();

 m_shapes[0].Append( aArc1 );

 m_shapes[1].Append( aArc2 );

 m_clippedBaseSeg.A = aArc1.GetP1();

 m_clippedBaseSeg.B = aArc1.GetP1();

}


void MEANDERED_LINE::AddMeander( MEANDER_SHAPE* aShape )

{

 m_last = aShape->BaseSegment().B;

 m_meanders.push_back( aShape );

}


void MEANDERED_LINE::Clear()

{

 for( MEANDER_SHAPE* m : m_meanders )

 delete m;


 m_meanders.clear( );

}


int MEANDER_SHAPE::BaselineLength() const

{

 return m_clippedBaseSeg.Length();

}


long long int MEANDER_SHAPE::CurrentLength() const

{

 return CLine( 0 ).Length();

}


long long int MEANDER_SHAPE::MinTunableLength() const

{

 MEANDER_SHAPE copy = *this;


 copy.SetTargetBaselineLength( BaselineLength() );

 copy.Resize( copy.MinAmplitude() );


 return copy.CurrentLength();

}


void MEANDER_SHAPE::updateBaseSegment( )

{

 if( m_dual )

 {

 VECTOR2I midpA = ( CLine( 0 ).CPoint( 0 ) + CLine( 1 ).CPoint( 0 ) ) / 2;

 VECTOR2I midpB = ( CLine( 0 ).CPoint( -1 ) + CLine( 1 ).CPoint( -1 ) ) / 2;


 m_clippedBaseSeg.A = m_baseSeg.LineProject( midpA );

 m_clippedBaseSeg.B = m_baseSeg.LineProject( midpB );

 }

 else

 {

 m_clippedBaseSeg.A = m_baseSeg.LineProject( CLine( 0 ).CPoint( 0 ) );

 m_clippedBaseSeg.B = m_baseSeg.LineProject( CLine( 0 ).CPoint( -1 ) );

 }

}


}

BITMAPS::copy
@ copy

EDA_ANGLE
Definition: eda_angle.h:37

PNS::MEANDERED_LINE::AddMeander
void AddMeander(MEANDER_SHAPE *aShape)
Add a new meander shape to the meandered line.
Definition: pns_meander.cpp:690

PNS::MEANDERED_LINE::m_placer
MEANDER_PLACER_BASE * m_placer
Definition: pns_meander.h:595

PNS::MEANDERED_LINE::AddCorner
void AddCorner(const VECTOR2I &aA, const VECTOR2I &aB=VECTOR2I(0, 0))
Create a dummy meander shape representing a line corner.
Definition: pns_meander.cpp:628

PNS::MEANDERED_LINE::Clear
void Clear()
Clear the line geometry, removing all corners and meanders.
Definition: pns_meander.cpp:697

PNS::MEANDERED_LINE::m_baselineOffset
int m_baselineOffset
Definition: pns_meander.h:600

PNS::MEANDERED_LINE::m_meanders
std::vector< MEANDER_SHAPE * > m_meanders
Definition: pns_meander.h:596

PNS::MEANDERED_LINE::m_last
VECTOR2I m_last
Definition: pns_meander.h:593

PNS::MEANDERED_LINE::m_width
int m_width
Definition: pns_meander.h:599

PNS::MEANDERED_LINE::MeanderSegment
void MeanderSegment(const SEG &aSeg, bool aSide, int aBaseIndex=0)
Fit maximum amplitude meanders on a given segment and adds to the current line.
Definition: pns_meander.cpp:43

PNS::MEANDERED_LINE::AddArc
void AddArc(const SHAPE_ARC &aArc1, const SHAPE_ARC &aArc2=SHAPE_ARC())
Create a dummy meander shape representing an arc corner.
Definition: pns_meander.cpp:639

PNS::MEANDERED_LINE::AddArcAndPt
void AddArcAndPt(const SHAPE_ARC &aArc1, const VECTOR2I &aPt2)
Create a dummy meander shape representing an arc corner.
Definition: pns_meander.cpp:650

PNS::MEANDERED_LINE::CheckSelfIntersections
bool CheckSelfIntersections(MEANDER_SHAPE *aShape, int aClearance)
Check if the given shape is intersecting with any other meander in the current line.
Definition: pns_meander.cpp:472

PNS::MEANDERED_LINE::m_dual
bool m_dual
Definition: pns_meander.h:598

PNS::MEANDERED_LINE::Settings
const MEANDER_SETTINGS & Settings() const
Definition: pns_meander.cpp:37

PNS::MEANDERED_LINE::AddPtAndArc
void AddPtAndArc(const VECTOR2I &aPt1, const SHAPE_ARC &aArc2)
Create a dummy meander shape representing an arc corner.
Definition: pns_meander.cpp:658

PNS::MEANDER_PLACER_BASE::UpdateSettings
virtual void UpdateSettings(const MEANDER_SETTINGS &aSettings)
Definition: pns_meander_placer_base.cpp:84

PNS::MEANDER_PLACER_BASE::CheckFit
virtual bool CheckFit(MEANDER_SHAPE *aShape)
Checks if it's OK to place the shape aShape (i.e.
Definition: pns_meander_placer_base.h:110

PNS::MEANDER_PLACER_BASE::Clearance
virtual int Clearance()
Return the clearance of the track(s) being length tuned.
Definition: pns_meander_placer_base.cpp:67

PNS::MEANDER_PLACER_BASE::MeanderSettings
virtual const MEANDER_SETTINGS & MeanderSettings() const
Return the current meandering configuration.
Definition: pns_meander_placer_base.cpp:292

PNS::MEANDER_SETTINGS
Dimensions for the meandering algorithm.
Definition: pns_meander.h:68

PNS::MEANDER_SETTINGS::m_minAmplitude
int m_minAmplitude
Maximum meandering amplitude.
Definition: pns_meander.h:128

PNS::MEANDER_SETTINGS::m_cornerRadiusPercentage
int m_cornerRadiusPercentage
Place meanders on one side.
Definition: pns_meander.h:154

PNS::MEANDER_SETTINGS::m_initialSide
MEANDER_SIDE m_initialSide
Allowable tuning error.
Definition: pns_meander.h:160

PNS::MEANDER_SETTINGS::m_singleSided
bool m_singleSided
Initial side when placing meanders at segment.
Definition: pns_meander.h:157

PNS::MEANDER_SETTINGS::m_step
int m_step
Length PadToDie.
Definition: pns_meander.h:137

PNS::MEANDER_SETTINGS::m_cornerStyle
MEANDER_STYLE m_cornerStyle
Rounding percentage (0 - 100).
Definition: pns_meander.h:151

PNS::MEANDER_SETTINGS::m_maxAmplitude
int m_maxAmplitude
Meandering period/spacing (see dialog picture for explanation).
Definition: pns_meander.h:131

PNS::MEANDER_SHAPE
The geometry of a single meander.
Definition: pns_meander.h:173

PNS::MEANDER_SHAPE::m_type
MEANDER_TYPE m_type
The placer that placed this meander.
Definition: pns_meander.h:414

PNS::MEANDER_SHAPE::MinAmplitude
int MinAmplitude() const
Definition: pns_meander.cpp:202

PNS::MEANDER_SHAPE::m_placer
MEANDER_PLACER_BASE * m_placer
Dual or single line.
Definition: pns_meander.h:417

PNS::MEANDER_SHAPE::m_baseSeg
SEG m_baseSeg
Base segment (clipped).
Definition: pns_meander.h:441

PNS::MEANDER_SHAPE::m_clippedBaseSeg
SEG m_clippedBaseSeg
Side (true = right).
Definition: pns_meander.h:444

PNS::MEANDER_SHAPE::Amplitude
int Amplitude() const
Definition: pns_meander.h:232

PNS::MEANDER_SHAPE::SetType
void SetType(MEANDER_TYPE aType)
Set the type of the meander.
Definition: pns_meander.h:200

PNS::MEANDER_SHAPE::m_targetBaseLen
int m_targetBaseLen
First point of the meandered line.
Definition: pns_meander.h:435

PNS::MEANDER_SHAPE::End
VECTOR2I End() const
Definition: pns_meander.h:287

PNS::MEANDER_SHAPE::genMeanderShape
SHAPE_LINE_CHAIN genMeanderShape(const VECTOR2D &aP, const VECTOR2D &aDir, bool aSide, MEANDER_TYPE aType, int aBaselineOffset=0)
Recalculate the clipped baseline after the parameters of the meander have been changed.
Definition: pns_meander.cpp:356

PNS::MEANDER_SHAPE::start
void start(SHAPE_LINE_CHAIN *aTarget, const VECTOR2D &aWhere, const VECTOR2D &aDir)
Move turtle forward by aLength.
Definition: pns_meander.cpp:301

PNS::MEANDER_SHAPE::SetBaseIndex
void SetBaseIndex(int aIndex)
Set an auxiliary index of the segment being meandered in its original LINE.
Definition: pns_meander.h:216

PNS::MEANDER_SHAPE::m_baselineOffset
int m_baselineOffset
Average radius of meander corners (for correction of DP meanders).
Definition: pns_meander.h:429

PNS::MEANDER_SHAPE::m_currentDir
VECTOR2D m_currentDir
The current turtle position.
Definition: pns_meander.h:456

PNS::MEANDER_SHAPE::m_width
int m_width
Amplitude of the meander.
Definition: pns_meander.h:423

PNS::MEANDER_SHAPE::m_currentPos
VECTOR2D m_currentPos
The line the turtle is drawing on.
Definition: pns_meander.h:459

PNS::MEANDER_SHAPE::m_shapes
SHAPE_LINE_CHAIN m_shapes[2]
Index of the meandered segment in the base line.
Definition: pns_meander.h:450

PNS::MEANDER_SHAPE::CurrentLength
long long int CurrentLength() const
Definition: pns_meander.cpp:712

PNS::MEANDER_SHAPE::m_side
bool m_side
The actual shapes (0 used for single, both for dual).
Definition: pns_meander.h:447

PNS::MEANDER_SHAPE::updateBaseSegment
void updateBaseSegment()
Return sanitized corner radius value.
Definition: pns_meander.cpp:729

PNS::MEANDER_SHAPE::makeMiterShape
SHAPE_LINE_CHAIN makeMiterShape(const VECTOR2D &aP, const VECTOR2D &aDir, bool aSide)
Produce a meander shape of given type.
Definition: pns_meander.cpp:245

PNS::MEANDER_SHAPE::MakeArc
void MakeArc(const SHAPE_ARC &aArc1, const SHAPE_ARC &aArc2=SHAPE_ARC())
Create a dummy meander shape representing an arc corner.
Definition: pns_meander.cpp:678

PNS::MEANDER_SHAPE::m_baseIndex
int m_baseIndex
The current turtle direction.
Definition: pns_meander.h:453

PNS::MEANDER_SHAPE::m_currentTarget
SHAPE_LINE_CHAIN * m_currentTarget
Definition: pns_meander.h:462

PNS::MEANDER_SHAPE::m_dual
bool m_dual
Width of the line.
Definition: pns_meander.h:420

PNS::MEANDER_SHAPE::Recalculate
void Recalculate()
Recalculate the line chain representing the meander's shape.
Definition: pns_meander.cpp:588

PNS::MEANDER_SHAPE::miter
void miter(int aRadius, bool aSide)
Tell the turtle to draw an U-like shape.
Definition: pns_meander.cpp:328

PNS::MEANDER_SHAPE::MinTunableLength
long long int MinTunableLength() const
Definition: pns_meander.cpp:718

PNS::MEANDER_SHAPE::Resize
void Resize(int aAmpl)
Change the amplitude of the meander shape to aAmpl and recalculates the resulting line chain.
Definition: pns_meander.cpp:601

PNS::MEANDER_SHAPE::m_meanCornerRadius
int m_meanCornerRadius
Minimum length of the base segment to target when resizing.
Definition: pns_meander.h:432

PNS::MEANDER_SHAPE::spacing
int spacing() const
The type of meander.
Definition: pns_meander.cpp:231

PNS::MEANDER_SHAPE::m_amplitude
int m_amplitude
Offset wrs the base segment (dual only).
Definition: pns_meander.h:426

PNS::MEANDER_SHAPE::cornerRadius
int cornerRadius() const
Return sanitized spacing value.
Definition: pns_meander.cpp:217

PNS::MEANDER_SHAPE::turn
void turn(const EDA_ANGLE &aAngle)
Tell the turtle to draw a mitered corner of given radius and turn direction.
Definition: pns_meander.cpp:322

PNS::MEANDER_SHAPE::SetBaselineOffset
void SetBaselineOffset(int aOffset)
Set the parallel offset between the base segment and the meandered line.
Definition: pns_meander.h:366

PNS::MEANDER_SHAPE::forward
void forward(int aLength)
Turn the turtle by aAngle.
Definition: pns_meander.cpp:311

PNS::MEANDER_SHAPE::Type
MEANDER_TYPE Type() const
Definition: pns_meander.h:208

PNS::MEANDER_SHAPE::m_p0
VECTOR2I m_p0
Base segment (unclipped).
Definition: pns_meander.h:438

PNS::MEANDER_SHAPE::Settings
const MEANDER_SETTINGS & Settings() const
Definition: pns_meander.cpp:31

PNS::MEANDER_SHAPE::MakeEmpty
void MakeEmpty()
Replace the meander with straight bypass line(s), effectively clearing it.
Definition: pns_meander.cpp:612

PNS::MEANDER_SHAPE::Fit
bool Fit(MEANDER_TYPE aType, const SEG &aSeg, const VECTOR2I &aP, bool aSide)
Attempt to fit a meander of a given type onto a segment, avoiding collisions with other board feature...
Definition: pns_meander.cpp:500

PNS::MEANDER_SHAPE::uShape
void uShape(int aSides, int aCorner, int aTop)
Generate a 90-degree circular arc.
Definition: pns_meander.cpp:346

PNS::MEANDER_SHAPE::CLine
const SHAPE_LINE_CHAIN & CLine(int aShape) const
Definition: pns_meander.h:295

PNS::MEANDER_SHAPE::BaselineLength
int BaselineLength() const
Definition: pns_meander.cpp:706

PNS::MEANDER_SHAPE::BaseSegment
const SEG & BaseSegment() const
Return the base segment the meander was fitted to.
Definition: pns_meander.h:322

PNS::MEANDER_SHAPE::MakeCorner
void MakeCorner(const VECTOR2I &aP1, const VECTOR2I &aP2=VECTOR2I(0, 0))
Create a dummy meander shape representing a line corner.
Definition: pns_meander.cpp:666

SEG
Definition: seg.h:42

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

SEG::ecoord
VECTOR2I::extended_type ecoord
Definition: seg.h:44

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

SEG::Length
int Length() const
Return the length (this).
Definition: seg.h:326

SEG::ApproxParallel
bool ApproxParallel(const SEG &aSeg, int aDistanceThreshold=1) const
Definition: seg.cpp:403

SEG::Contains
bool Contains(const SEG &aSeg) const
Definition: seg.h:307

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:312

SHAPE_ARC
Definition: shape_arc.h:37

SHAPE_ARC::GetP1
const VECTOR2I & GetP1() const
Definition: shape_arc.h:113

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::Collide
virtual bool Collide(const VECTOR2I &aP, int aClearance=0, int *aActual=nullptr, VECTOR2I *aLocation=nullptr) const override
Check if point aP lies closer to us than aClearance.
Definition: shape_line_chain.cpp:439

SHAPE_LINE_CHAIN::Clear
void Clear()
Remove all points from the line chain.
Definition: shape_line_chain.h:244

SHAPE_LINE_CHAIN::Mirror
void Mirror(bool aX=true, bool aY=false, const VECTOR2I &aRef={ 0, 0 })
Mirror the line points about y or x (or both).
Definition: shape_line_chain.cpp:706

SHAPE_LINE_CHAIN::Append
void Append(int aX, int aY, bool aAllowDuplication=false)
Append a new point at the end of the line chain.
Definition: shape_line_chain.h:498

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:396

SHAPE_LINE_CHAIN::SegmentCount
int SegmentCount() const
Return the number of segments in this line chain.
Definition: shape_line_chain.h:297

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:351

SHAPE_LINE_CHAIN::Length
long long int Length() const
Return length of the line chain in Euclidean metric.
Definition: shape_line_chain.cpp:688

VECTOR2< double >

VECTOR2::x
T x
Definition: vector2d.h:78

VECTOR2::y
T y
Definition: vector2d.h:78

VECTOR2::EuclideanNorm
T EuclideanNorm() const
Compute the Euclidean norm of the vector, which is defined as sqrt(x ** 2 + y ** 2).
Definition: vector2d.h:265

VECTOR2::Perpendicular
VECTOR2< T > Perpendicular() const
Compute the perpendicular vector.
Definition: vector2d.h:279

VECTOR2::Resize
VECTOR2< T > Resize(T aNewLength) const
Return a vector of the same direction, but length specified in aNewLength.
Definition: vector2d.h:350

ANGLE_90
static constexpr EDA_ANGLE & ANGLE_90
Definition: eda_angle.h:439

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

PNS::MEANDER_TYPE
MEANDER_TYPE
Shapes of available meanders.
Definition: pns_meander.h:38

PNS::MT_TURN
@ MT_TURN
Definition: pns_meander.h:42

PNS::MT_CHECK_START
@ MT_CHECK_START
Definition: pns_meander.h:43

PNS::MT_CHECK_FINISH
@ MT_CHECK_FINISH
Definition: pns_meander.h:44

PNS::MT_START
@ MT_START
Definition: pns_meander.h:40

PNS::MT_FINISH
@ MT_FINISH
Definition: pns_meander.h:41

PNS::MT_EMPTY
@ MT_EMPTY
Definition: pns_meander.h:47

PNS::MT_CORNER
@ MT_CORNER
Definition: pns_meander.h:45

PNS::MT_SINGLE
@ MT_SINGLE
Definition: pns_meander.h:39

PNS::MEANDER_SIDE
MEANDER_SIDE
Definition: pns_meander.h:58

PNS::MEANDER_STYLE_ROUND
@ MEANDER_STYLE_ROUND
Definition: pns_meander.h:52

PNS::MEANDER_STYLE_CHAMFER
@ MEANDER_STYLE_CHAMFER
Definition: pns_meander.h:53

std::abs
EDA_ANGLE abs(const EDA_ANGLE &aAngle)
Definition: eda_angle.h:426

pns_debug_decorator.h

pns_itemset.h

pns_meander.h

pns_meander_placer_base.h

pns_node.h

pns_router.h

correction
constexpr double correction
Definition: render_settings.cpp:60

m2
MATRIX3x3D m2(VECTOR3I{ 6, 6, 6 }, { 1, 1, 1 }, { 3, 3, 3 })
Test suite for KiCad math code.

RotatePoint
void RotatePoint(int *pX, int *pY, const EDA_ANGLE &aAngle)
Calculate the new point of coord coord pX, pY, for a rotation center 0, 0.
Definition: trigo.cpp:228

EuclideanNorm
double EuclideanNorm(const VECTOR2I &vector)
Definition: trigo.h:128