/* * KiRouter - a push-and-(sometimes-)shove PCB router * * Copyright (C) 2013-2014 CERN * Author: Tomasz Wlostowski * * 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 . */ #include // God forgive me doing this... #include #include "trace.h" #include "pns_node.h" #include "pns_itemset.h" #include "pns_topology.h" #include "pns_meander.h" #include "pns_meander_placer_base.h" #include "pns_router.h" const PNS_MEANDER_SETTINGS& PNS_MEANDER_SHAPE::Settings() const { return m_placer->MeanderSettings(); } const PNS_MEANDER_SETTINGS& PNS_MEANDERED_LINE::Settings() const { return m_placer->MeanderSettings(); } void PNS_MEANDERED_LINE::MeanderSegment( const SEG& aBase, int aBaseIndex ) { double base_len = aBase.Length(); SHAPE_LINE_CHAIN lc; bool side = true; VECTOR2D dir( aBase.B - aBase.A ); if( !m_dual ) AddCorner( aBase.A ); bool turning = false; bool started = false; m_last = aBase.A; do { PNS_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(); if( remaining < Settings( ).m_step ) break; if( remaining > 3.0 * thr ) { if( !turning ) { for( int i = 0; i < 2; i++ ) { if ( m.Fit( MT_CHECK_START, aBase, m_last, i ) ) { turning = true; AddMeander( new PNS_MEANDER_SHAPE( m ) ); side = !i; started = true; break; } } if( !turning ) { fail = true; for( int i = 0; i < 2; i++ ) { if ( m.Fit ( MT_SINGLE, aBase, m_last, i ) ) { AddMeander( new PNS_MEANDER_SHAPE( m ) ); fail = false; started = false; side = !i; break; } } } } else { bool rv = m.Fit( MT_CHECK_FINISH, aBase, m_last, side ); if( rv ) { m.Fit( MT_TURN, aBase, m_last, side ); AddMeander( new PNS_MEANDER_SHAPE( m ) ); started = true; } else { m.Fit( MT_FINISH, aBase, m_last, side ); started = false; AddMeander( new PNS_MEANDER_SHAPE( m ) ); turning = false; } side = !side; } } else if( started ) { bool rv = m.Fit( MT_FINISH, aBase, m_last, side ); if( rv ) AddMeander( new PNS_MEANDER_SHAPE( m ) ); break; } else { fail = true; } remaining = base_len - ( m_last - aBase.A ).EuclideanNorm( ); if( remaining < Settings( ).m_step ) break; if( fail ) { PNS_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 PNS_MEANDER_SHAPE::cornerRadius() const { int cr = (int64_t) spacing() * Settings().m_cornerRadiusPercentage / 200; return cr; } int PNS_MEANDER_SHAPE::spacing( ) const { if ( !m_dual ) return std::max( 2 * m_width, Settings().m_spacing ); else { int sp = 2 * ( m_width + std::abs( m_baselineOffset ) ); return std::max ( sp, Settings().m_spacing ); } } SHAPE_LINE_CHAIN PNS_MEANDER_SHAPE::circleQuad( VECTOR2D aP, 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( ) ); const int ArcSegments = Settings().m_cornerArcSegments; double radius = (double) aDir.EuclideanNorm(); double angleStep = M_PI / 2.0 / (double) ArcSegments; double correction = 12.0 * radius * ( 1.0 - cos( angleStep / 2.0 ) ); if( !m_dual ) correction = 0.0; else if( radius < m_meanCornerRadius ) correction = 0.0; VECTOR2D p = aP; lc.Append( ( int ) p.x, ( int ) p.y ); VECTOR2D dir_uu = dir_u.Resize( radius - correction ); VECTOR2D dir_vv = dir_v.Resize( radius - correction ); VECTOR2D shift = dir_u.Resize( correction ); for( int i = ArcSegments - 1; i >= 0; i-- ) { double alpha = (double) i / (double) ( ArcSegments - 1 ) * M_PI / 2.0; p = aP + shift + dir_uu * cos( alpha ) + dir_vv * ( aSide ? -1.0 : 1.0 ) * ( 1.0 - sin( alpha ) ); lc.Append( ( int ) p.x, ( int ) p.y ); } p = aP + dir_u + dir_v * ( aSide ? -1.0 : 1.0 ); lc.Append( ( int ) p.x, ( int ) p.y ); return lc; } VECTOR2I PNS_MEANDER_SHAPE::reflect( VECTOR2I p, const SEG& line ) { typedef int64_t ecoord; VECTOR2I d = line.B - line.A; ecoord l_squared = d.Dot( d ); ecoord t = d.Dot( p - line.A ); VECTOR2I c, rv; if( !l_squared ) c = p; else { c.x = line.A.x + rescale( t, (ecoord) d.x, l_squared ); c.y = line.A.y + rescale( t, (ecoord) d.y, l_squared ); } return 2 * c - p; } void PNS_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 PNS_MEANDER_SHAPE::forward( int aLength ) { m_currentPos += m_currentDir.Resize( aLength ); m_currentTarget->Append( m_currentPos ); } void PNS_MEANDER_SHAPE::turn( int aAngle ) { m_currentDir = m_currentDir.Rotate( (double) aAngle * M_PI / 180.0 ); } void PNS_MEANDER_SHAPE::arc( int aRadius, bool aSide ) { if( aRadius <= 0 ) { turn( aSide ? -90 : 90 ); return; } VECTOR2D dir = m_currentDir.Resize( (double) aRadius ); SHAPE_LINE_CHAIN arc = circleQuad( m_currentPos, dir, aSide ); m_currentPos = arc.CPoint( -1 ); m_currentDir = dir.Rotate( aSide ? -M_PI / 2.0 : M_PI / 2.0 ); m_currentTarget->Append ( arc ); } void PNS_MEANDER_SHAPE::uShape( int aSides, int aCorner, int aTop ) { forward( aSides ); arc( aCorner, true ); forward( aTop ); arc( aCorner, true ); forward( aSides ); } SHAPE_LINE_CHAIN PNS_MEANDER_SHAPE::genMeanderShape( VECTOR2D aP, VECTOR2D aDir, bool aSide, PNS_MEANDER_TYPE aType, int aAmpl, int aBaselineOffset ) { const PNS_MEANDER_SETTINGS& st = Settings(); int cr = cornerRadius(); int offset = aBaselineOffset; int spc = spacing(); if( aSide ) offset *= -1; VECTOR2D dir_u_b( aDir.Resize( offset ) ); VECTOR2D dir_v_b( dir_u_b.Perpendicular() ); if( 2 * cr > aAmpl ) { cr = aAmpl / 2; } if( 2 * cr > spc ) { cr = spc / 2; } m_meanCornerRadius = 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: { arc( cr - offset, false ); uShape( aAmpl - 2 * cr + std::abs( offset ), cr + offset, spc - 2 * cr ); forward( std::min( cr - offset, cr + offset ) ); forward( std::abs( offset ) ); break; } case MT_FINISH: { start( &lc, aP - dir_u_b, aDir ); turn ( 90 ); forward( std::min( cr - offset, cr + offset ) ); forward( std::abs( offset ) ); uShape( aAmpl - 2 * cr + std::abs( offset ), cr + offset, spc - 2 * cr ); arc( cr - offset, false ); break; } case MT_TURN: { start( &lc, aP - dir_u_b, aDir ); turn( 90 ); forward( std::abs( offset ) ); uShape ( aAmpl - cr, cr + offset, spc - 2 * cr ); forward( std::abs( offset ) ); break; } case MT_SINGLE: { arc( cr - offset, false ); uShape( aAmpl - 2 * cr + std::abs( offset ), cr + offset, spc - 2 * cr ); arc( cr - offset, false ); lc.Append( aP + dir_v_b + aDir.Resize ( 2 * st.m_spacing ) ); break; } default: break; } if( aSide ) { SEG axis ( aP, aP + aDir ); for( int i = 0; i < lc.PointCount(); i++ ) lc.Point( i ) = reflect( lc.CPoint( i ), axis ); } return lc; } bool PNS_MEANDERED_LINE::CheckSelfIntersections( PNS_MEANDER_SHAPE* aShape, int aClearance ) { for( int i = m_meanders.size() - 1; i >= 0; i-- ) { PNS_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 PNS_MEANDER_SHAPE::Fit( PNS_MEANDER_TYPE aType, const SEG& aSeg, const VECTOR2I& aP, bool aSide ) { const PNS_MEANDER_SETTINGS& st = Settings(); bool checkMode = false; PNS_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 ) { PNS_MEANDER_SHAPE m1( m_placer, m_width, m_dual ); PNS_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 = st.m_minAmplitude; int maxAmpl = st.m_maxAmplitude; if( m_dual ) { minAmpl = std::max( minAmpl, 2 * std::abs( m_baselineOffset ) ); maxAmpl = std::max( maxAmpl, 2 * std::abs( m_baselineOffset ) ); } for( int ampl = maxAmpl; ampl >= minAmpl; ampl -= st.m_step ) { if( m_dual ) { m_shapes[0] = genMeanderShape( aP, aSeg.B - aSeg.A, aSide, aType, ampl, m_baselineOffset ); m_shapes[1] = genMeanderShape( aP, aSeg.B - aSeg.A, aSide, aType, ampl, -m_baselineOffset ); } else { m_shapes[0] = genMeanderShape( aP, aSeg.B - aSeg.A, aSide, aType, ampl, 0 ); } m_type = aType; m_baseSeg = aSeg; m_p0 = aP; m_side = aSide; m_amplitude = ampl; updateBaseSegment(); if( m_placer->CheckFit( this ) ) return true; } return false; } void PNS_MEANDER_SHAPE::Recalculate() { m_shapes[0] = genMeanderShape( m_p0, m_baseSeg.B - m_baseSeg.A, m_side, m_type, m_amplitude, 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_amplitude, -m_baselineOffset ); updateBaseSegment(); } void PNS_MEANDER_SHAPE::Resize( int aAmpl ) { if( aAmpl < 0 ) return; m_amplitude = aAmpl; Recalculate(); } void PNS_MEANDER_SHAPE::MakeEmpty() { updateBaseSegment(); VECTOR2I dir = m_clippedBaseSeg.B - m_clippedBaseSeg.A; m_type = MT_EMPTY; m_shapes[0] = genMeanderShape ( m_p0, dir, m_side, m_type, 0, m_dual ? m_baselineOffset : 0 ); if( m_dual ) m_shapes[1] = genMeanderShape( m_p0, dir, m_side, m_type, 0, -m_baselineOffset ); } void PNS_MEANDERED_LINE::AddCorner( const VECTOR2I& aA, const VECTOR2I& aB ) { PNS_MEANDER_SHAPE* m = new PNS_MEANDER_SHAPE( m_placer, m_width, m_dual ); m->MakeCorner( aA, aB ); m_last = aA; m_meanders.push_back( m ); } void PNS_MEANDER_SHAPE::MakeCorner( VECTOR2I aP1, 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 PNS_MEANDERED_LINE::AddMeander( PNS_MEANDER_SHAPE* aShape ) { m_last = aShape->BaseSegment().B; m_meanders.push_back( aShape ); } void PNS_MEANDERED_LINE::Clear() { for( PNS_MEANDER_SHAPE* m : m_meanders ) { delete m; } m_meanders.clear( ); } int PNS_MEANDER_SHAPE::BaselineLength() const { return m_clippedBaseSeg.Length(); } int PNS_MEANDER_SHAPE::MaxTunableLength() const { return CLine( 0 ).Length(); } void PNS_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 ) ); } }