/* * This program source code file is part of KICAD, a free EDA CAD application. * * Copyright (C) 2014 CERN * @author Maciej Suminski * * 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 */ #include "edit_constraints.h" #include "edit_points.h" #include #include #include void EC_VERTICAL::Apply( EDIT_POINT& aHandle ) { VECTOR2I point = aHandle.GetPosition(); point.x = m_constrainer.GetPosition().x; aHandle.SetPosition( point ); } void EC_HORIZONTAL::Apply( EDIT_POINT& aHandle ) { VECTOR2I point = aHandle.GetPosition(); point.y = m_constrainer.GetPosition().y; aHandle.SetPosition( point ); } void EC_45DEGREE::Apply( EDIT_POINT& aHandle ) { // Current line vector VECTOR2I lineVector( aHandle.GetPosition() - m_constrainer.GetPosition() ); double angle = lineVector.Angle(); // Find the closest angle, which is a multiple of 45 degrees double newAngle = KiROUND( angle / ( M_PI / 4.0 ) ) * M_PI / 4.0; VECTOR2I newLineVector = lineVector.Rotate( newAngle - angle ); aHandle.SetPosition( m_constrainer.GetPosition() + newLineVector ); } EC_LINE::EC_LINE( EDIT_POINT& aConstrained, const EDIT_POINT& aConstrainer ) : EDIT_CONSTRAINT( aConstrained ), m_constrainer( aConstrainer ) { m_line = m_constrained.GetPosition() - m_constrainer.GetPosition(); } void EC_LINE::Apply( EDIT_POINT& aHandle ) { SEG main( m_constrainer.GetPosition(), m_constrainer.GetPosition() + m_line ); SEG projection( aHandle.GetPosition(), aHandle.GetPosition() + m_line.Perpendicular() ); if( OPT_VECTOR2I intersect = projection.IntersectLines( main ) ) aHandle.SetPosition( *intersect ); } void EC_CIRCLE::Apply( EDIT_POINT& aHandle ) { VECTOR2I centerToEnd = m_end.GetPosition() - m_center.GetPosition(); VECTOR2I centerToPoint = aHandle.GetPosition() - m_center.GetPosition(); int radius = centerToEnd.EuclideanNorm(); double angle = centerToPoint.Angle(); VECTOR2I newLine( radius, 0 ); newLine = newLine.Rotate( angle ); aHandle.SetPosition( m_center.GetPosition() + newLine ); } EC_CONVERGING::EC_CONVERGING( EDIT_LINE& aLine, EDIT_POINTS& aPoints ) : EDIT_CONSTRAINT( aLine ), m_colinearConstraint( NULL ), m_editPoints( aPoints ) { // Dragged segment endings EDIT_POINT& origin = aLine.GetOrigin(); EDIT_POINT& end = aLine.GetEnd(); // Previous and next points, to make constraining lines (adjacent to the dragged line) EDIT_POINT& prevOrigin = *aPoints.Previous( origin, false ); EDIT_POINT& nextEnd = *aPoints.Next( end, false ); // Constraints for segments adjacent to the dragged one m_originSideConstraint = new EC_LINE( origin, prevOrigin ); m_endSideConstraint = new EC_LINE( end, nextEnd ); // Store the current vector of the line m_draggedVector = end.GetPosition() - origin.GetPosition(); // Check for colinearity SEG originSide( origin.GetPosition(), prevOrigin.GetPosition() ); SEG endSide( end.GetPosition(), nextEnd.GetPosition() ); SEG dragged( origin.GetPosition(), end.GetPosition() ); if( dragged.Collinear( originSide ) ) m_colinearConstraint = m_originSideConstraint; else if( dragged.Collinear( endSide ) ) m_colinearConstraint = m_endSideConstraint; } EC_CONVERGING::~EC_CONVERGING() { delete m_originSideConstraint; delete m_endSideConstraint; // m_colinearConstraint should not be freed, it is a pointer to one of the above } void EC_CONVERGING::Apply( EDIT_LINE& aHandle ) { // The dragged segment endpoints EDIT_POINT& origin = aHandle.GetOrigin(); EDIT_POINT& end = aHandle.GetEnd(); if( m_colinearConstraint ) { m_colinearConstraint->Apply( origin ); m_colinearConstraint->Apply( end ); } // The dragged segment SEG dragged( origin.GetPosition(), origin.GetPosition() + m_draggedVector ); // Do not allow points on the adjacent segments move freely m_originSideConstraint->Apply(); m_endSideConstraint->Apply(); EDIT_POINT& prevOrigin = *m_editPoints.Previous( origin, false ); EDIT_POINT& nextEnd = *m_editPoints.Next( end, false ); // Two segments adjacent to the dragged segment SEG originSide = SEG( origin.GetPosition(), prevOrigin.GetPosition() ); SEG endSide = SEG( end.GetPosition(), nextEnd.GetPosition() ); // First intersection point (dragged segment against origin side) if( OPT_VECTOR2I originIntersect = dragged.IntersectLines( originSide ) ) origin.SetPosition( *originIntersect ); // Second intersection point (dragged segment against end side) if( OPT_VECTOR2I endIntersect = dragged.IntersectLines( endSide ) ) end.SetPosition( *endIntersect ); // Check if adjacent segments intersect (did we dragged the line to the point that it may // create a selfintersecting polygon?) originSide = SEG( origin.GetPosition(), prevOrigin.GetPosition() ); endSide = SEG( end.GetPosition(), nextEnd.GetPosition() ); if( OPT_VECTOR2I originEndIntersect = endSide.Intersect( originSide ) ) { // Triangle intersect by definition if( m_editPoints.LinesSize() > 3 ) { origin.SetPosition( *originEndIntersect ); end.SetPosition( *originEndIntersect ); } } } EC_SNAPLINE::EC_SNAPLINE( EDIT_LINE& aLine, V2D_TRANSFORM_FUN aSnapFun ) : EDIT_CONSTRAINT( aLine ), m_snapFun( std::move(aSnapFun) ) {} void EC_SNAPLINE::Apply( EDIT_LINE& aHandle ) { VECTOR2D delta = aHandle.GetEnd().GetPosition() - aHandle.GetOrigin().GetPosition(); aHandle.GetOrigin().SetPosition( m_snapFun( aHandle.GetOrigin().GetPosition() ) ); aHandle.GetEnd().SetPosition( aHandle.GetOrigin().GetPosition() + delta ); }