/* Copyright (C) 2001-2006, William Joseph. All Rights Reserved. This file is part of GtkRadiant. GtkRadiant 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. GtkRadiant 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 GtkRadiant; if not, write to the Free Software Foundation, Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA */ #if !defined( INCLUDED_DRAGPLANES_H ) #define INCLUDED_DRAGPLANES_H #include "selectable.h" #include "selectionlib.h" #include "math/aabb.h" #include "math/line.h" // local must be a pure rotation inline Vector3 translation_to_local( const Vector3& translation, const Matrix4& local ){ return matrix4_get_translation_vec3( matrix4_multiplied_by_matrix4( matrix4_translated_by_vec3( matrix4_transposed( local ), translation ), local ) ); } // local must be a pure rotation inline Vector3 translation_from_local( const Vector3& translation, const Matrix4& local ){ return matrix4_get_translation_vec3( matrix4_multiplied_by_matrix4( matrix4_translated_by_vec3( local, translation ), matrix4_transposed( local ) ) ); } class DragPlanes { public: ObservedSelectable m_selectable_right; // +x ObservedSelectable m_selectable_left; // -x ObservedSelectable m_selectable_front; // +y ObservedSelectable m_selectable_back; // -y ObservedSelectable m_selectable_top; // +z ObservedSelectable m_selectable_bottom; // -z AABB m_bounds; DragPlanes( const SelectionChangeCallback& onchanged ) : m_selectable_right( onchanged ), m_selectable_left( onchanged ), m_selectable_front( onchanged ), m_selectable_back( onchanged ), m_selectable_top( onchanged ), m_selectable_bottom( onchanged ){ } bool isSelected() const { return m_selectable_right.isSelected() || m_selectable_left.isSelected() || m_selectable_front.isSelected() || m_selectable_back.isSelected() || m_selectable_top.isSelected() || m_selectable_bottom.isSelected(); } void setSelected( bool selected ){ m_selectable_right.setSelected( selected ); m_selectable_left.setSelected( selected ); m_selectable_front.setSelected( selected ); m_selectable_back.setSelected( selected ); m_selectable_top.setSelected( selected ); m_selectable_bottom.setSelected( selected ); } void selectPlanes( const AABB& aabb, Selector& selector, SelectionTest& test, const PlaneCallback& selectedPlaneCallback, const Matrix4& rotation = g_matrix4_identity ){ Line line( test.getNear(), test.getFar() ); Vector3 corners[8]; aabb_corners_oriented( aabb, rotation, corners ); Plane3 planes[6]; aabb_planes_oriented( aabb, rotation, planes ); for ( Vector3* i = corners; i != corners + 8; ++i ) { *i = vector3_subtracted( line_closest_point( line, *i ), *i ); } if ( vector3_dot( planes[0].normal(), corners[1] ) > 0 && vector3_dot( planes[0].normal(), corners[2] ) > 0 && vector3_dot( planes[0].normal(), corners[5] ) > 0 && vector3_dot( planes[0].normal(), corners[6] ) > 0 ) { Selector_add( selector, m_selectable_right ); selectedPlaneCallback( planes[0] ); //globalOutputStream() << "right\n"; } if ( vector3_dot( planes[1].normal(), corners[0] ) > 0 && vector3_dot( planes[1].normal(), corners[3] ) > 0 && vector3_dot( planes[1].normal(), corners[4] ) > 0 && vector3_dot( planes[1].normal(), corners[7] ) > 0 ) { Selector_add( selector, m_selectable_left ); selectedPlaneCallback( planes[1] ); //globalOutputStream() << "left\n"; } if ( vector3_dot( planes[2].normal(), corners[0] ) > 0 && vector3_dot( planes[2].normal(), corners[1] ) > 0 && vector3_dot( planes[2].normal(), corners[4] ) > 0 && vector3_dot( planes[2].normal(), corners[5] ) > 0 ) { Selector_add( selector, m_selectable_front ); selectedPlaneCallback( planes[2] ); //globalOutputStream() << "front\n"; } if ( vector3_dot( planes[3].normal(), corners[2] ) > 0 && vector3_dot( planes[3].normal(), corners[3] ) > 0 && vector3_dot( planes[3].normal(), corners[6] ) > 0 && vector3_dot( planes[3].normal(), corners[7] ) > 0 ) { Selector_add( selector, m_selectable_back ); selectedPlaneCallback( planes[3] ); //globalOutputStream() << "back\n"; } if ( vector3_dot( planes[4].normal(), corners[0] ) > 0 && vector3_dot( planes[4].normal(), corners[1] ) > 0 && vector3_dot( planes[4].normal(), corners[2] ) > 0 && vector3_dot( planes[4].normal(), corners[3] ) > 0 ) { Selector_add( selector, m_selectable_top ); selectedPlaneCallback( planes[4] ); //globalOutputStream() << "top\n"; } if ( vector3_dot( planes[5].normal(), corners[4] ) > 0 && vector3_dot( planes[5].normal(), corners[5] ) > 0 && vector3_dot( planes[5].normal(), corners[6] ) > 0 && vector3_dot( planes[5].normal(), corners[7] ) > 0 ) { Selector_add( selector, m_selectable_bottom ); selectedPlaneCallback( planes[5] ); //globalOutputStream() << "bottom\n"; } m_bounds = aabb; } void selectReversedPlanes( const AABB& aabb, Selector& selector, const SelectedPlanes& selectedPlanes, const Matrix4& rotation = g_matrix4_identity ){ Plane3 planes[6]; aabb_planes_oriented( aabb, rotation, planes ); if ( selectedPlanes.contains( plane3_flipped( planes[0] ) ) ) { Selector_add( selector, m_selectable_right ); } if ( selectedPlanes.contains( plane3_flipped( planes[1] ) ) ) { Selector_add( selector, m_selectable_left ); } if ( selectedPlanes.contains( plane3_flipped( planes[2] ) ) ) { Selector_add( selector, m_selectable_front ); } if ( selectedPlanes.contains( plane3_flipped( planes[3] ) ) ) { Selector_add( selector, m_selectable_back ); } if ( selectedPlanes.contains( plane3_flipped( planes[4] ) ) ) { Selector_add( selector, m_selectable_top ); } if ( selectedPlanes.contains( plane3_flipped( planes[5] ) ) ) { Selector_add( selector, m_selectable_bottom ); } } AABB evaluateResize( const Vector3& translation ) const { Vector3 min = m_bounds.origin - m_bounds.extents; Vector3 max = m_bounds.origin + m_bounds.extents; if ( m_bounds.extents[0] != 0 ) { if ( m_selectable_right.isSelected() ) { max[0] += translation[0]; //globalOutputStream() << "moving right\n"; } if ( m_selectable_left.isSelected() ) { min[0] += translation[0]; //globalOutputStream() << "moving left\n"; } } if ( m_bounds.extents[1] != 0 ) { if ( m_selectable_front.isSelected() ) { max[1] += translation[1]; //globalOutputStream() << "moving front\n"; } if ( m_selectable_back.isSelected() ) { min[1] += translation[1]; //globalOutputStream() << "moving back\n"; } } if ( m_bounds.extents[2] != 0 ) { if ( m_selectable_top.isSelected() ) { max[2] += translation[2]; //globalOutputStream() << "moving top\n"; } if ( m_selectable_bottom.isSelected() ) { min[2] += translation[2]; //globalOutputStream() << "moving bottom\n"; } } return AABB( vector3_mid( min, max ), vector3_scaled( vector3_subtracted( max, min ), 0.5 ) ); } AABB evaluateResize( const Vector3& translation, const Matrix4& rotation ) const { AABB aabb( evaluateResize( translation_to_local( translation, rotation ) ) ); aabb.origin = m_bounds.origin + translation_from_local( aabb.origin - m_bounds.origin, rotation ); return aabb; } Matrix4 evaluateTransform( const Vector3& translation ) const { AABB aabb( evaluateResize( translation ) ); Vector3 scale( m_bounds.extents[0] != 0 ? aabb.extents[0] / m_bounds.extents[0] : 1, m_bounds.extents[1] != 0 ? aabb.extents[1] / m_bounds.extents[1] : 1, m_bounds.extents[2] != 0 ? aabb.extents[2] / m_bounds.extents[2] : 1 ); Matrix4 matrix( matrix4_translation_for_vec3( aabb.origin - m_bounds.origin ) ); matrix4_pivoted_scale_by_vec3( matrix, scale, m_bounds.origin ); return matrix; } }; #endif