/* * This program source code file is part of KICAD, a free EDA CAD application. * * Copyright (C) 2016-2017 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 2 * 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, you may find one here: * http://www.gnu.org/licenses/old-licenses/gpl-2.0.html * or you may search the http://www.gnu.org website for the version 2 license, * or you may write to the Free Software Foundation, Inc., * 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301, USA */ #ifndef __POLY_GRID_PARTITION_H #define __POLY_GRID_PARTITION_H #include #include #include #include #include #include #include #include #include #include /** * POLY_GRID_PARTITION * * Provides a fast test for point inside polygon by splitting the edges * of the polygon into a rectangular grid. */ class POLY_GRID_PARTITION { private: enum HASH_FLAG { LEAD_H = 1, LEAD_V = 2, TRAIL_H = 4, TRAIL_V = 8 }; using EDGE_LIST = std::vector; template inline void hash_combine( std::size_t& seed, const T& v ) { std::hash hasher; seed ^= hasher( v ) + 0x9e3779b9 + (seed << 6) + (seed >> 2); } struct segsEqual { bool operator()( const SEG& a, const SEG& b ) const { return (a.A == b.A && a.B == b.B) || (a.A == b.B && a.B == b.A); } }; struct segHash { std::size_t operator()( const SEG& a ) const { return a.A.x + a.B.x + a.A.y + a.B.y; } }; const VECTOR2I grid2poly( const VECTOR2I& p ) const { int px = rescale( p.x, m_bbox.GetWidth(), m_gridSize ) + m_bbox.GetPosition().x; int py = rescale( p.y, m_bbox.GetHeight(), m_gridSize ) + m_bbox.GetPosition().y; // (int) floor( (double) p.y / m_gridSize * (double) m_bbox.GetHeight() + m_bbox.GetPosition().y ); return VECTOR2I( px, py ); } void stupid_test() const { for(int i = 0; i < 16;i++) assert( poly2gridX(grid2polyX(i)) == i); } int grid2polyX( int x ) const { return rescale( x, m_bbox.GetWidth(), m_gridSize ) + m_bbox.GetPosition().x; } int grid2polyY( int y ) const { return rescale( y, m_bbox.GetHeight(), m_gridSize ) + m_bbox.GetPosition().y; } const VECTOR2I poly2grid( const VECTOR2I& p ) const { int px = rescale( p.x - m_bbox.GetPosition().x, m_gridSize, m_bbox.GetWidth() ); int py = rescale( p.y - m_bbox.GetPosition().y, m_gridSize, m_bbox.GetHeight() ); if( px < 0 ) px = 0; if( px >= m_gridSize ) px = m_gridSize - 1; if( py < 0 ) py = 0; if( py >= m_gridSize ) py = m_gridSize - 1; return VECTOR2I( px, py ); } int poly2gridX( int x ) const { int px = rescale( x - m_bbox.GetPosition().x, m_gridSize, m_bbox.GetWidth() ); if( px < 0 ) px = 0; if( px >= m_gridSize ) px = m_gridSize - 1; return px; } int poly2gridY( int y ) const { int py = rescale( y - m_bbox.GetPosition().y, m_gridSize, m_bbox.GetHeight() ); if( py < 0 ) py = 0; if( py >= m_gridSize ) py = m_gridSize - 1; return py; } void build( const SHAPE_LINE_CHAIN& aPolyOutline, int gridSize ) { m_outline = aPolyOutline; //if (orientation(m_outline) < 0) // m_outline = m_outline.Reverse(); m_bbox = m_outline.BBox(); m_gridSize = gridSize; m_outline.SetClosed( true ); m_grid.reserve( gridSize * gridSize ); for( int y = 0; y < gridSize; y++ ) { for( int x = 0; x < gridSize; x++ ) { m_grid.emplace_back( ); } } VECTOR2I ref_v( 0, 1 ); VECTOR2I ref_h( 0, 1 ); m_flags.reserve( m_outline.SegmentCount() ); std::unordered_map edgeSet; for( int i = 0; i 0 ) { flags |= TRAIL_H; } } m_flags.push_back( flags ); if( edge.A.y == edge.B.y ) continue; std::set indices; indices.insert( m_gridSize * poly2gridY( edge.A.y ) + poly2gridX( edge.A.x ) ); indices.insert( m_gridSize * poly2gridY( edge.B.y ) + poly2gridX( edge.B.x ) ); if( edge.A.x > edge.B.x ) std::swap( edge.A, edge.B ); dir = edge.B - edge.A; if( dir.x != 0 ) { int gx0 = poly2gridX( edge.A.x ); int gx1 = poly2gridX( edge.B.x ); for( int x = gx0; x <= gx1; x++ ) { int px = grid2polyX( x ); int py = ( edge.A.y + rescale( dir.y, px - edge.A.x, dir.x ) ); int yy = poly2gridY( py ); indices.insert( m_gridSize * yy + x ); if( x > 0 ) indices.insert( m_gridSize * yy + x - 1 ); } } if( edge.A.y > edge.B.y ) std::swap( edge.A, edge.B ); dir = edge.B - edge.A; if( dir.y != 0 ) { int gy0 = poly2gridY( edge.A.y ); int gy1 = poly2gridY( edge.B.y ); for( int y = gy0; y <= gy1; y++ ) { int py = grid2polyY( y ); int px = ( edge.A.x + rescale( dir.x, py - edge.A.y, dir.y ) ); int xx = poly2gridX( px ); indices.insert( m_gridSize * y + xx ); if( y > 0 ) indices.insert( m_gridSize * (y - 1) + xx ); } } for( auto idx : indices ) m_grid[idx].push_back( i ); } } bool inRange( int v1, int v2, int x ) const { if( v1 < v2 ) { return x >= v1 && x <= v2; } return x >= v2 && x <= v1; } struct SCAN_STATE { SCAN_STATE() { dist_prev = INT_MAX; dist_max = INT_MAX; nearest = -1; nearest_prev = -1; }; int dist_prev; int dist_max; int nearest_prev; int nearest; }; void scanCell( SCAN_STATE& state, const EDGE_LIST& cell, const VECTOR2I& aP, int cx, int cy ) const { int cx0 = grid2polyX(cx); int cx1 = grid2polyX(cx + 1); for( auto index : cell ) { const SEG& edge = m_outline.CSegment( index ); if( m_flags[index] == 0 ) { if ( aP.y == edge.A.y && inRange( edge.A.x, edge.B.x, aP.x ) ) // we belong to the outline { state.nearest = index; state.dist_max = 0; return; } else { continue; } } if( inRange( edge.A.y, edge.B.y, aP.y ) ) { int dist = 0; int x0; if( edge.A.y == aP.y ) { x0 = edge.A.x; } else if( edge.B.y == aP.y ) { x0 = edge.B.x; } else { x0 = edge.A.x + rescale( ( edge.B.x - edge.A.x ), (aP.y - edge.A.y), (edge.B.y - edge.A.y ) ); } if( x0 < cx0 || x0 > cx1 ) { continue; } dist = aP.x - x0; if( dist == 0 ) { if( state.nearest_prev < 0 || state.nearest != index ) { state.dist_prev = state.dist_max; state.nearest_prev = state.nearest; } state.nearest = index; state.dist_max = 0; return; } if( dist != 0 && std::abs( dist ) <= std::abs( state.dist_max ) ) { if( state.nearest_prev < 0 || state.nearest != index ) { state.dist_prev = state.dist_max; state.nearest_prev = state.nearest; } state.dist_max = dist; state.nearest = index; } } } } public: POLY_GRID_PARTITION( const SHAPE_LINE_CHAIN& aPolyOutline, int gridSize ) { build( aPolyOutline, gridSize ); } int containsPoint( const VECTOR2I& aP, bool debug = false ) const { const auto gridPoint = poly2grid( aP ); if( !m_bbox.Contains( aP ) ) return 0; SCAN_STATE state; const EDGE_LIST& cell = m_grid[ m_gridSize * gridPoint.y + gridPoint.x ]; scanCell( state, cell, aP, gridPoint.x, gridPoint.y ); if( state.nearest < 0 ) { state = SCAN_STATE(); for( int d = 1; d <= m_gridSize; d++ ) { int xl = gridPoint.x - d; int xh = gridPoint.x + d; if( xl >= 0 ) { const EDGE_LIST& cell2 = m_grid[ m_gridSize * gridPoint.y + xl ]; scanCell( state, cell2, aP, xl, gridPoint.y ); if( state.nearest >= 0 ) break; } if( xh < m_gridSize ) { const EDGE_LIST& cell2 = m_grid[ m_gridSize * gridPoint.y + xh ]; scanCell( state, cell2, aP, xh, gridPoint.y ); if( state.nearest >= 0 ) break; } } } if( state.nearest < 0 ) return 0; if( state.dist_max == 0 ) return 1; // special case for diagonal 'slits', e.g. two segments that partially overlap each other. if( state.nearest_prev >= 0 && state.dist_max == state.dist_prev ) { int d = std::abs( state.nearest_prev - state.nearest ); if( (d == 1) && ( (m_flags[state.nearest_prev] & m_flags[state.nearest]) == 0 ) ) { return 0; } } if( state.dist_max > 0 ) { return m_flags[state.nearest] & LEAD_H ? 1 : 0; } else { return m_flags[state.nearest] & TRAIL_H ? 1 : 0; } } bool checkClearance( const VECTOR2I& aP, int aClearance ) { int gx0 = poly2gridX( aP.x - aClearance - 1); int gx1 = poly2gridX( aP.x + aClearance + 1); int gy0 = poly2gridY( aP.y - aClearance - 1); int gy1 = poly2gridY( aP.y + aClearance + 1); using ecoord = VECTOR2I::extended_type; ecoord dist = (ecoord) aClearance * aClearance; for ( int gx = gx0; gx <= gx1; gx++ ) { for ( int gy = gy0; gy <= gy1; gy++ ) { const auto& cell = m_grid [ m_gridSize * gy + gx]; for ( auto index : cell ) { const auto& seg = m_outline.Segment( index ); if ( seg.SquaredDistance(aP) <= dist ) return true; } } } return false; } int ContainsPoint( const VECTOR2I& aP, int aClearance = 0 ) // const { if( containsPoint(aP) ) return 1; if( aClearance > 0 ) return checkClearance ( aP, aClearance ); return 0; } const BOX2I& BBox() const { return m_bbox; } private: int m_gridSize; SHAPE_LINE_CHAIN m_outline; BOX2I m_bbox; std::vector m_flags; std::vector m_grid; }; #endif