472 lines
12 KiB
C++
472 lines
12 KiB
C++
/*
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* This program source code file is part of KICAD, a free EDA CAD application.
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*
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* Copyright (C) 2013-2017 CERN
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* Copyright (C) 2019-2020 KiCad Developers, see AUTHORS.txt for contributors.
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*
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* @author Maciej Suminski <maciej.suminski@cern.ch>
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* @author Tomasz Wlostowski <tomasz.wlostowski@cern.ch>
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*
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* This program is free software; you can redistribute it and/or
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* modify it under the terms of the GNU General Public License
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* as published by the Free Software Foundation; either version 2
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* of the License, or (at your option) any later version.
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*
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* This program is distributed in the hope that it will be useful,
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* but WITHOUT ANY WARRANTY; without even the implied warranty of
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* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
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* GNU General Public License for more details.
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*
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* You should have received a copy of the GNU General Public License
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* along with this program; if not, you may find one here:
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* http://www.gnu.org/licenses/old-licenses/gpl-2.0.html
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* or you may search the http://www.gnu.org website for the version 2 license,
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* or you may write to the Free Software Foundation, Inc.,
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* 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301, USA
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*/
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/**
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* @file ratsnest_data.cpp
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* @brief Class that computes missing connections on a PCB.
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*/
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#ifdef PROFILE
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#include <profile.h>
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#endif
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#include <ratsnest/ratsnest_data.h>
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#include <functional>
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using namespace std::placeholders;
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#include <algorithm>
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#include <cassert>
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#include <limits>
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#include <delaunator.hpp>
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class disjoint_set
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{
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public:
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disjoint_set( size_t size )
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{
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m_data.resize( size );
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m_depth.resize( size, 0 );
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for( size_t i = 0; i < size; i++ )
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m_data[i] = i;
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}
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int find( int aVal )
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{
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int root = aVal;
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while( m_data[root] != root )
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root = m_data[root];
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// Compress the path
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while( m_data[aVal] != aVal )
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{
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auto& tmp = m_data[aVal];
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aVal = tmp;
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tmp = root;
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}
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return root;
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}
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bool unite( int aVal1, int aVal2 )
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{
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aVal1 = find( aVal1 );
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aVal2 = find( aVal2 );
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if( aVal1 != aVal2 )
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{
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if( m_depth[aVal1] < m_depth[aVal2] )
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{
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m_data[aVal1] = aVal2;
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}
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else
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{
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m_data[aVal2] = aVal1;
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if( m_depth[aVal1] == m_depth[aVal2] )
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m_depth[aVal1]++;
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}
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return true;
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}
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return false;
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}
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private:
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std::vector<int> m_data;
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std::vector<int> m_depth;
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};
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void RN_NET::kruskalMST( const std::vector<CN_EDGE> &aEdges )
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{
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disjoint_set dset( m_nodes.size() );
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m_rnEdges.clear();
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int i = 0;
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for( auto& node : m_nodes )
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node->SetTag( i++ );
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for( auto& tmp : aEdges )
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{
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int u = tmp.GetSourceNode()->GetTag();
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int v = tmp.GetTargetNode()->GetTag();
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if( dset.unite( u, v ) )
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{
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if( tmp.GetWeight() > 0 )
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m_rnEdges.push_back( tmp );
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}
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}
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}
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class RN_NET::TRIANGULATOR_STATE
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{
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private:
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std::multiset<CN_ANCHOR_PTR, CN_PTR_CMP> m_allNodes;
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// Checks if all nodes in aNodes lie on a single line. Requires the nodes to
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// have unique coordinates!
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bool areNodesColinear( const std::vector<CN_ANCHOR_PTR>& aNodes ) const
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{
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if ( aNodes.size() <= 2 )
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return true;
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const VECTOR2I p0( aNodes[0]->Pos() );
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const VECTOR2I v0( aNodes[1]->Pos() - p0 );
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for( unsigned i = 2; i < aNodes.size(); i++ )
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{
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const VECTOR2I v1 = aNodes[i]->Pos() - p0;
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if( v0.Cross( v1 ) != 0 )
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return false;
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}
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return true;
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}
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public:
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void Clear()
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{
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m_allNodes.clear();
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}
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void AddNode( CN_ANCHOR_PTR aNode )
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{
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m_allNodes.insert( aNode );
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}
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void Triangulate( std::vector<CN_EDGE>& mstEdges)
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{
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std::vector<double> node_pts;
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using ANCHOR_LIST = std::vector<CN_ANCHOR_PTR>;
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ANCHOR_LIST anchors;
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std::vector<ANCHOR_LIST> anchorChains( m_allNodes.size() );
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node_pts.reserve( 2 * m_allNodes.size() );
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anchors.reserve( m_allNodes.size() );
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CN_ANCHOR_PTR prev = nullptr;
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for( const auto& n : m_allNodes )
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{
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if( !prev || prev->Pos() != n->Pos() )
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{
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node_pts.push_back( n->Pos().x );
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node_pts.push_back( n->Pos().y );
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anchors.push_back( n );
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prev = n;
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}
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anchorChains[anchors.size() - 1].push_back( n );
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}
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if( anchors.size() < 2 )
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{
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return;
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}
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else if( areNodesColinear( anchors ) )
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{
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// special case: all nodes are on the same line - there's no
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// triangulation for such set. In this case, we sort along any coordinate
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// and chain the nodes together.
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for( size_t i = 0; i < anchors.size() - 1; i++ )
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{
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auto src = anchors[i];
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auto dst = anchors[i + 1];
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mstEdges.emplace_back( src, dst, src->Dist( *dst ) );
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}
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}
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else
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{
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delaunator::Delaunator delaunator( node_pts );
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auto& triangles = delaunator.triangles;
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for( size_t i = 0; i < triangles.size(); i += 3 )
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{
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auto src = anchors[triangles[i]];
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auto dst = anchors[triangles[i + 1]];
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mstEdges.emplace_back( src, dst, src->Dist( *dst ) );
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src = anchors[triangles[i + 1]];
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dst = anchors[triangles[i + 2]];
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mstEdges.emplace_back( src, dst, src->Dist( *dst ) );
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src = anchors[triangles[i + 2]];
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dst = anchors[triangles[i]];
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mstEdges.emplace_back( src, dst, src->Dist( *dst ) );
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}
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for( size_t i = 0; i < delaunator.halfedges.size(); i++ )
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{
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if( delaunator.halfedges[i] == delaunator::INVALID_INDEX )
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continue;
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auto src = anchors[triangles[i]];
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auto dst = anchors[triangles[delaunator.halfedges[i]]];
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mstEdges.emplace_back( src, dst, src->Dist( *dst ) );
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}
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}
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for( size_t i = 0; i < anchorChains.size(); i++ )
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{
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auto& chain = anchorChains[i];
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if( chain.size() < 2 )
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continue;
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std::sort( chain.begin(), chain.end(),
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[] ( const CN_ANCHOR_PTR& a, const CN_ANCHOR_PTR& b ) {
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return a->GetCluster().get() < b->GetCluster().get();
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} );
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for( unsigned int j = 1; j < chain.size(); j++ )
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{
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const auto& prevNode = chain[j - 1];
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const auto& curNode = chain[j];
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int weight = prevNode->GetCluster() != curNode->GetCluster() ? 1 : 0;
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mstEdges.emplace_back( prevNode, curNode, weight );
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}
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}
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}
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};
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RN_NET::RN_NET() : m_dirty( true )
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{
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m_triangulator.reset( new TRIANGULATOR_STATE );
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}
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void RN_NET::compute()
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{
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// Special cases do not need complicated algorithms (actually, it does not work well with
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// the Delaunay triangulator)
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if( m_nodes.size() <= 2 )
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{
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m_rnEdges.clear();
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// Check if the only possible connection exists
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if( m_boardEdges.size() == 0 && m_nodes.size() == 2 )
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{
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auto last = ++m_nodes.begin();
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// There can be only one possible connection, but it is missing
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CN_EDGE edge ( *m_nodes.begin(), *last );
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edge.GetSourceNode()->SetTag( 0 );
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edge.GetTargetNode()->SetTag( 1 );
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m_rnEdges.push_back( edge );
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}
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else
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{
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// Set tags to m_nodes as connected
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for( const auto& node : m_nodes )
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node->SetTag( 0 );
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}
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return;
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}
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m_triangulator->Clear();
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for( const auto& n : m_nodes )
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{
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m_triangulator->AddNode( n );
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}
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std::vector<CN_EDGE> triangEdges;
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triangEdges.reserve( m_nodes.size() + m_boardEdges.size() );
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#ifdef PROFILE
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PROF_COUNTER cnt("triangulate");
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#endif
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m_triangulator->Triangulate( triangEdges );
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#ifdef PROFILE
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cnt.Show();
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#endif
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for( const auto& e : m_boardEdges )
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triangEdges.emplace_back( e );
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std::sort( triangEdges.begin(), triangEdges.end() );
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// Get the minimal spanning tree
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#ifdef PROFILE
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PROF_COUNTER cnt2("mst");
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#endif
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kruskalMST( triangEdges );
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#ifdef PROFILE
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cnt2.Show();
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#endif
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}
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void RN_NET::Update()
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{
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compute();
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m_dirty = false;
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}
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void RN_NET::Clear()
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{
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m_rnEdges.clear();
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m_boardEdges.clear();
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m_nodes.clear();
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m_dirty = true;
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}
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void RN_NET::AddCluster( CN_CLUSTER_PTR aCluster )
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{
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CN_ANCHOR_PTR firstAnchor;
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for( auto item : *aCluster )
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{
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bool isZone = dynamic_cast<CN_ZONE_LAYER*>(item) != nullptr;
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auto& anchors = item->Anchors();
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unsigned int nAnchors = isZone ? 1 : anchors.size();
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if( nAnchors > anchors.size() )
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nAnchors = anchors.size();
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for( unsigned int i = 0; i < nAnchors; i++ )
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{
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anchors[i]->SetCluster( aCluster );
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m_nodes.insert( anchors[i] );
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if( firstAnchor )
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{
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if( firstAnchor != anchors[i] )
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{
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m_boardEdges.emplace_back( firstAnchor, anchors[i], 0 );
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}
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}
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else
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{
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firstAnchor = anchors[i];
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}
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}
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}
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}
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bool RN_NET::NearestBicoloredPair( const RN_NET& aOtherNet, CN_ANCHOR_PTR& aNode1,
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CN_ANCHOR_PTR& aNode2 ) const
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{
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bool rv = false;
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VECTOR2I::extended_type distMax = VECTOR2I::ECOORD_MAX;
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auto verify = [&]( auto& aTestNode1, auto& aTestNode2 )
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{
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auto squaredDist = ( aTestNode1->Pos() - aTestNode2->Pos() ).SquaredEuclideanNorm();
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if( squaredDist < distMax )
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{
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rv = true;
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distMax = squaredDist;
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aNode1 = aTestNode1;
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aNode2 = aTestNode2;
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}
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};
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/// Sweep-line algorithm to cut the number of comparisons to find the closest point
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///
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/// Step 1: The outer loop needs to be the subset (selected nodes) as it is a linear search
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for( const auto& nodeA : aOtherNet.m_nodes )
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{
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if( nodeA->GetNoLine() )
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continue;
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/// Step 2: O( log n ) search to identify a close element ordered by x
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/// The fwd_it iterator will move forward through the elements while
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/// the rev_it iterator will move backward through the same set
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auto fwd_it = m_nodes.lower_bound( nodeA );
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auto rev_it = std::make_reverse_iterator( fwd_it );
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for( ; fwd_it != m_nodes.end(); ++fwd_it )
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{
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const std::shared_ptr<CN_ANCHOR>& nodeB = *fwd_it;
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if( nodeB->GetNoLine() )
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continue;
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VECTOR2I::extended_type distX = nodeA->Pos().x - nodeB->Pos().x;
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/// As soon as the x distance (primary sort) is larger than the smallest distance,
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/// stop checking further elements
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if( distX * distX > distMax )
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break;
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verify( nodeA, nodeB );
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}
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/// Step 3: using the same starting point, check points backwards for closer points
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for( ; rev_it != m_nodes.rend(); ++rev_it )
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{
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const std::shared_ptr<CN_ANCHOR>& nodeB = *rev_it;
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if( nodeB->GetNoLine() )
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continue;
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VECTOR2I::extended_type distX = nodeA->Pos().x - nodeB->Pos().x;
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if( distX * distX > distMax )
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break;
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verify( nodeA, nodeB );
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}
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}
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return rv;
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}
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void RN_NET::SetVisible( bool aEnabled )
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{
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for( auto& edge : m_rnEdges )
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edge.SetVisible( aEnabled );
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}
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