/* ************************************************************************** description -------------------- copyright : (C) 2000-2001 by Andreas Zehender email : zehender@kde.org ************************************************************************** ************************************************************************** * * * 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. * * * **************************************************************************/ #include "pmcamera.h" #include "pmxmlhelper.h" #include "pmcameraedit.h" #include "pmmemento.h" #include "pmviewstructure.h" #include "pm3dcontrolpoint.h" #include "pmvectorcontrolpoint.h" #include "pmenumproperty.h" #include PMDefinePropertyClass( PMCamera, PMCameraProperty ); PMDefineEnumPropertyClass( PMCamera, PMCamera::CameraType, PMCameraTypeProperty ); PMViewStructure* PMCamera::s_pDefaultViewStructure = 0; PMMetaObject* PMCamera::s_pMetaObject = 0; PMObject* createNewCamera( PMPart* part ) { return new PMCamera( part ); } const PMVector locationDefault = PMVector( 0.0, 0.0, 0.0 ); const PMVector lookAtDefault = PMVector( 0.0, 0.0, 1.0 ); const PMVector directionDefault = PMVector( 0.0, 0.0, 1.0 ); const PMVector upDefault = PMVector( 0.0, 1.0, 0.0 ); const PMVector rightDefault = PMVector( 4.0/3.0, 0.0, 0.0 ); const PMVector skyDefault = PMVector( 0.0, 1.0, 0.0 ); //const double aspectDefault = 1.0; const bool angleEnabledDefault = false; const double angleDefault = 90.0; const PMCamera::CameraType cameraTypeDefault = PMCamera::Perspective; const int cylinderTypeDefault = 1; const bool focalBlurDefault = false; const double apertureDefault = 0.4; const int blurSamplesDefault = 10; const PMVector focalPointDefault = PMVector( 0.0, 0.0, 0.0 ); const double confidenceDefault = 0.9; const double varianceDefault = 0.008; const bool c_defaultExport = true; PMCamera::PMCamera( PMPart* part ) : Base( part ) { m_location = locationDefault; m_lookAt = lookAtDefault; m_direction = directionDefault; m_up = upDefault; m_right = rightDefault; m_sky = skyDefault; m_angle = angleDefault; m_angleEnabled = angleEnabledDefault; m_cameraType = cameraTypeDefault; m_cylinderType = cylinderTypeDefault; m_focalBlurEnabled = focalBlurDefault; m_aperture = apertureDefault; m_blurSamples = blurSamplesDefault; m_focalPoint = focalPointDefault; m_confidence = confidenceDefault; m_variance = varianceDefault; m_export = c_defaultExport; } PMCamera::PMCamera( const PMCamera& c ) : Base( c ) { m_location = c.m_location; m_lookAt = c.m_lookAt; m_direction = c.m_direction; m_up = c.m_up; m_right = c.m_right; m_sky = c.m_sky; m_angle = c.m_angle; m_angleEnabled = c.m_angleEnabled; m_cameraType = c.m_cameraType; m_cylinderType = c.m_cylinderType; m_focalBlurEnabled = c.m_focalBlurEnabled; m_aperture = c.m_aperture; m_blurSamples = c.m_blurSamples; m_focalPoint = c.m_focalPoint; m_confidence = c.m_confidence; m_variance = c.m_variance; m_export = c.m_export; } PMCamera::~PMCamera( ) { } TQString PMCamera::description( ) const { return i18n( "camera" ); } void PMCamera::serialize( TQDomElement& e, TQDomDocument& doc ) const { e.setAttribute( "camera_type", cameraTypeToString( m_cameraType ) ); e.setAttribute( "cylinder_type", m_cylinderType ); e.setAttribute( "location", m_location.serializeXML( ) ); e.setAttribute( "sky", m_sky.serializeXML( ) ); e.setAttribute( "direction", m_direction.serializeXML( ) ); e.setAttribute( "right", m_right.serializeXML( ) ); e.setAttribute( "up", m_up.serializeXML( ) ); e.setAttribute( "look_at", m_lookAt.serializeXML( ) ); e.setAttribute( "angle_enabled", m_angleEnabled ); e.setAttribute( "angle", m_angle ); e.setAttribute( "focal_blur", m_focalBlurEnabled ); e.setAttribute( "aperture", m_aperture ); e.setAttribute( "blur_samples", m_blurSamples ); e.setAttribute( "focal_point", m_focalPoint.serializeXML( ) ); e.setAttribute( "confidence", m_confidence ); e.setAttribute( "variance", m_variance ); e.setAttribute( "export", m_export ); Base::serialize( e, doc ); } void PMCamera::readAttributes( const PMXMLHelper& h ) { m_cameraType = stringToCameraType( h.stringAttribute( "camera_type", "perspective" ) ); m_cylinderType = h.intAttribute( "cylinder_type", cylinderTypeDefault ); m_location = h.vectorAttribute( "location", locationDefault ); m_sky = h.vectorAttribute( "sky", skyDefault ); m_direction = h.vectorAttribute( "direction", directionDefault ); m_right = h.vectorAttribute( "right", rightDefault ); m_up = h.vectorAttribute( "up", upDefault ); m_lookAt = h.vectorAttribute( "look_at", lookAtDefault ); m_angleEnabled = h.boolAttribute( "angle_enabled", angleEnabledDefault ); m_angle = h.doubleAttribute( "angle", angleDefault ); m_focalBlurEnabled = h.boolAttribute( "focal_blur", focalBlurDefault ); m_aperture = h.doubleAttribute( "aperture", apertureDefault ); m_blurSamples = h.intAttribute( "blur_samples", blurSamplesDefault ); m_focalPoint = h.vectorAttribute( "focal_point", focalPointDefault ); m_confidence = h.doubleAttribute( "confidence", confidenceDefault ); m_variance = h.doubleAttribute( "variance", varianceDefault ); m_export = h.boolAttribute( "export", c_defaultExport ); Base::readAttributes( h ); } PMMetaObject* PMCamera::metaObject( ) const { if( !s_pMetaObject ) { s_pMetaObject = new PMMetaObject( "Camera", Base::metaObject( ), createNewCamera ); s_pMetaObject->addProperty( new PMCameraProperty( "location", &PMCamera::setLocation, &PMCamera::location ) ); s_pMetaObject->addProperty( new PMCameraProperty( "lookAt", &PMCamera::setLookAt, &PMCamera::lookAt ) ); s_pMetaObject->addProperty( new PMCameraProperty( "up", &PMCamera::setUp, &PMCamera::up ) ); s_pMetaObject->addProperty( new PMCameraProperty( "right", &PMCamera::setRight, &PMCamera::right ) ); s_pMetaObject->addProperty( new PMCameraProperty( "direction", &PMCamera::setDirection, &PMCamera::direction ) ); s_pMetaObject->addProperty( new PMCameraProperty( "sky", &PMCamera::setSky, &PMCamera::sky ) ); s_pMetaObject->addProperty( new PMCameraProperty( "aspect", 0, &PMCamera::aspect ) ); s_pMetaObject->addProperty( new PMCameraProperty( "angleEnabled", &PMCamera::enableAngle, &PMCamera::isAngleEnabled ) ); s_pMetaObject->addProperty( new PMCameraProperty( "angle", &PMCamera::setAngle, &PMCamera::angle ) ); PMCameraTypeProperty* p = new PMCameraTypeProperty( "cameraType", &PMCamera::setCameraType, &PMCamera::cameraType ); p->addEnumValue( "Perspective", Perspective ); p->addEnumValue( "Orthographic", Orthographic ); p->addEnumValue( "FishEye", FishEye ); p->addEnumValue( "UltraWideAngle", UltraWideAngle ); p->addEnumValue( "Omnimax", Omnimax ); p->addEnumValue( "Panoramic", Panoramic ); p->addEnumValue( "Cylinder", Cylinder ); s_pMetaObject->addProperty( p ); s_pMetaObject->addProperty( new PMCameraProperty( "cylinderType", &PMCamera::setCylinderType, &PMCamera::cylinderType ) ); s_pMetaObject->addProperty( new PMCameraProperty( "focalBlurEnabled", &PMCamera::enableFocalBlur, &PMCamera::isFocalBlurEnabled ) ); s_pMetaObject->addProperty( new PMCameraProperty( "aperture", &PMCamera::setAperture, &PMCamera::aperture ) ); s_pMetaObject->addProperty( new PMCameraProperty( "blurSamples", &PMCamera::setBlurSamples, &PMCamera::blurSamples ) ); s_pMetaObject->addProperty( new PMCameraProperty( "focalPoint", &PMCamera::setFocalPoint, &PMCamera::focalPoint ) ); s_pMetaObject->addProperty( new PMCameraProperty( "confidence", &PMCamera::setConfidence, &PMCamera::confidence ) ); s_pMetaObject->addProperty( new PMCameraProperty( "variance", &PMCamera::setVariance, &PMCamera::variance ) ); s_pMetaObject->addProperty( new PMCameraProperty( "export", &PMCamera::setExportPovray, &PMCamera::exportPovray ) ); } return s_pMetaObject; } void PMCamera::setLocation( const PMVector& p ) { if( p != m_location ) { if( m_pMemento ) m_pMemento->addData( s_pMetaObject, PMLocationID, m_location ); m_location = p; m_location.resize( 3 ); setViewStructureChanged( ); } } void PMCamera::setLookAt( const PMVector& p ) { if( p != m_lookAt ) { if( m_pMemento ) m_pMemento->addData( s_pMetaObject, PMLookAtID, m_lookAt ); m_lookAt = p; m_lookAt.resize( 3 ); setViewStructureChanged( ); } } void PMCamera::setUp( const PMVector& v ) { if( v != m_up ) { if( m_pMemento ) m_pMemento->addData( s_pMetaObject, PMUpID, m_up ); m_up = v; m_up.resize( 3 ); setViewStructureChanged( ); } } void PMCamera::setRight( const PMVector& v ) { if( v != m_right ) { if( m_pMemento ) m_pMemento->addData( s_pMetaObject, PMRightID, m_right ); m_right = v; m_right.resize( 3 ); setViewStructureChanged( ); } } void PMCamera::setDirection( const PMVector& v ) { if( v != m_direction ) { if( m_pMemento ) m_pMemento->addData( s_pMetaObject, PMDirectionID, m_direction ); m_direction = v; m_direction.resize( 3 ); setViewStructureChanged( ); } } void PMCamera::setSky( const PMVector& v ) { if( v != m_sky ) { if( m_pMemento ) m_pMemento->addData( s_pMetaObject, PMSkyID, m_sky ); m_sky = v; m_sky.resize( 3 ); setViewStructureChanged( ); } } double PMCamera::aspect( ) const { double d = m_up.abs( ); if( approxZero( d ) ) return 1.0; return m_right.abs( ) / d; } void PMCamera::enableAngle( bool yes ) { if( yes != m_angleEnabled ) { if( m_pMemento ) m_pMemento->addData( s_pMetaObject, PMAngleEnabledID, m_angleEnabled ); m_angleEnabled = yes; setViewStructureChanged( ); } } void PMCamera::setAngle( double a ) { if( a != m_angle ) { if( m_pMemento ) m_pMemento->addData( s_pMetaObject, PMAngleID, m_angle ); m_angle = a; setViewStructureChanged( ); } } void PMCamera::setCameraType( PMCamera::CameraType t ) { if( t != m_cameraType ) { if( m_pMemento ) m_pMemento->addData( s_pMetaObject, PMCameraTypeID, m_cameraType ); m_cameraType = t; setViewStructureChanged( ); } } void PMCamera::setCylinderType( int t ) { if( ( t < 1 ) || ( t > 4 ) ) kdError( PMArea ) << "Invalid type in PMCylinder::setCylinderType\n"; else if( t != m_cylinderType ) { if( m_pMemento ) m_pMemento->addData( s_pMetaObject, PMCylinderTypeID, m_cylinderType ); m_cylinderType = t; setViewStructureChanged( ); } } void PMCamera::enableFocalBlur( bool yes ) { if( yes != m_focalBlurEnabled ) { if( m_pMemento ) m_pMemento->addData( s_pMetaObject, PMFocalBlurID, m_focalBlurEnabled ); m_focalBlurEnabled = yes; } } void PMCamera::setAperture( double a ) { if( a < 0 ) kdError( PMArea ) << "Aperture < 0 in PMCylinder::setAperture\n"; else if( a != m_aperture ) { if( m_pMemento ) m_pMemento->addData( s_pMetaObject, PMApertureID, m_aperture ); m_aperture = a; } } void PMCamera::setBlurSamples( int s ) { if( s < 0 ) kdError( PMArea ) << "Samples < 0 in PMCylinder::setBlutSamples\n"; else if( s != m_blurSamples ) { if( m_pMemento ) m_pMemento->addData( s_pMetaObject, PMBlurSamplesID, m_blurSamples ); m_blurSamples = s; } } void PMCamera::setFocalPoint( const PMVector& v ) { if( v != m_focalPoint ) { if( m_pMemento ) m_pMemento->addData( s_pMetaObject, PMFocalPointID, m_focalPoint ); m_focalPoint = v; } } void PMCamera::setConfidence( double c ) { if( ( c < 0.0 ) || ( c > 1.0 ) ) kdError( PMArea ) << "Confidence not in [0.0 1.0] in PMCylinder::setConfidence\n"; else if( c != m_confidence ) { if( m_pMemento ) m_pMemento->addData( s_pMetaObject, PMConfidenceID, m_confidence ); m_confidence = c; } } void PMCamera::setVariance( double v ) { if( v < 0 ) kdError( PMArea ) << "Variance < 0 in PMCylinder::setVariance\n"; else if( v != m_variance ) { if( m_pMemento ) m_pMemento->addData( s_pMetaObject, PMVarianceID, m_variance ); m_variance = v; } } void PMCamera::setExportPovray( bool ex ) { if( m_export != ex ) { if( m_pMemento ) m_pMemento->addData( s_pMetaObject, PMExportID, m_export ); m_export = ex; } } PMDialogEditBase* PMCamera::editWidget( TQWidget* parent ) const { return new PMCameraEdit( parent ); } void PMCamera::restoreMemento( PMMemento* s ) { PMMementoDataIterator it( s ); PMMementoData* data; for( ; it.current( ); ++it ) { data = it.current( ); if( data->objectType( ) == s_pMetaObject ) { switch( data->valueID( ) ) { case PMLocationID: setLocation( data->vectorData( ) ); break; case PMLookAtID: setLookAt( data->vectorData( ) ); break; case PMUpID: setUp( data->vectorData( ) ); break; case PMRightID: setRight( data->vectorData( ) ); break; case PMDirectionID: setDirection( data->vectorData( ) ); break; case PMSkyID: setSky( data->vectorData( ) ); break; case PMAngleEnabledID: enableAngle( data->boolData( ) ); break; case PMAngleID: setAngle( data->doubleData( ) ); break; case PMCameraTypeID: setCameraType( ( CameraType ) data->intData( ) ); break; case PMCylinderTypeID: setCylinderType( data->intData( ) ); break; case PMFocalBlurID: enableFocalBlur( data->boolData( ) ); break; case PMBlurSamplesID: setBlurSamples( data->intData( ) ); break; case PMFocalPointID: setFocalPoint( data->vectorData( ) ); break; case PMConfidenceID: setConfidence( data->doubleData( ) ); break; case PMVarianceID: setVariance( data->doubleData( ) ); break; case PMApertureID: setAperture( data->doubleData( ) ); break; case PMExportID: setExportPovray( data->boolData( ) ); break; default: kdError( PMArea ) << "Wrong ID in PMCamera::restoreMemento\n"; break; } } } Base::restoreMemento( s ); } void PMCamera::createViewStructure( ) { PMVector newUp, newRight, newDirection, tmp; double upLen, rightLen; if( !m_pViewStructure ) { m_pViewStructure = new PMViewStructure( defaultViewStructure( ) ); m_pViewStructure->points( ).detach( ); } PMPointArray& points = m_pViewStructure->points( ); calculateLookAtAngle( newRight, newUp, newDirection ); points[0] = m_lookAt; points[1] = m_location; upLen = newUp.abs( ); rightLen = newRight.abs( ); if( rightLen > upLen ) { newUp /= rightLen; newRight /= rightLen; newDirection /= rightLen; } else { newUp /= upLen; newRight /= upLen; newDirection /= upLen; } newRight /= 2.0; newUp /= 2.0; tmp = m_location + newDirection; points[2] = tmp - newRight + newUp; points[3] = tmp - newRight - newUp; points[4] = tmp + newRight - newUp; points[5] = tmp + newRight + newUp; // points[6] = m_location + m_sky; } PMViewStructure* PMCamera::defaultViewStructure( ) const { if( !s_pDefaultViewStructure ) { s_pDefaultViewStructure = new PMViewStructure( 6, 9 ); PMLineArray& lines = s_pDefaultViewStructure->lines( ); lines[0] = PMLine( 0, 1 ); lines[1] = PMLine( 1, 2 ); lines[2] = PMLine( 1, 3 ); lines[3] = PMLine( 1, 4 ); lines[4] = PMLine( 1, 5 ); lines[5] = PMLine( 2, 3 ); lines[6] = PMLine( 2, 5 ); lines[7] = PMLine( 3, 4 ); lines[8] = PMLine( 4, 5 ); // lines[9] = PMLine( 1, 6 ); } return s_pDefaultViewStructure; } void PMCamera::controlPoints( PMControlPointList& list ) { PMControlPoint* p; p = new PM3DControlPoint( m_location, PMLocationID, i18n( "Location" ) ); list.append( p ); list.append( new PM3DControlPoint( m_lookAt, PMLookAtID, i18n( "Look at" ) ) ); } void PMCamera::controlPointsChanged( PMControlPointList& list ) { PMControlPoint* p; for( p = list.first( ); p; p = list.next( ) ) { if( p->changed( ) ) { switch( p->id( ) ) { case PMLocationID: setLocation( ( ( PM3DControlPoint* ) p )->point( ) ); break; case PMLookAtID: setLookAt( ( ( PM3DControlPoint* ) p )->point( ) ); break; default: kdError( PMArea ) << "Wrong ID in PMCamera::controlPointsChanged\n"; break; } } } } void PMCamera::calculateLookAtAngle( PMVector& right, PMVector& up, PMVector& direction ) { PMVector tmpVector; double directionLen, upLen, rightLen, handedness, angle; angle = m_angle; if( m_cameraType == Perspective ) { if( angle < 0.0 ) angle = angleDefault; if( angle >= 180.0 ) angle = angleDefault; } else angle = 90.0; directionLen = m_direction.abs( ); upLen = m_up.abs( ); rightLen = m_right.abs( ); // for safety: if vector is null vector, use the default one if( approxZero( directionLen ) ) { direction = directionDefault; directionLen = direction.abs( ); } else direction = m_direction; if( approxZero( upLen ) ) { up = upDefault; upLen = up.abs( ); } else up = m_up; if( approxZero( rightLen ) ) { right = rightDefault; rightLen = right.abs( ); } else right = m_right; if( m_angleEnabled ) { // calculate angle direction /= directionLen; directionLen = 0.5 * rightLen / tan( angle * M_PI / 360.0 ); direction *= directionLen; } // calculate handedness tmpVector = PMVector::cross( up, direction ); handedness = PMVector::dot( tmpVector, right ); direction = m_lookAt - m_location; if( approxZero( direction.abs( ) ) ) { // Camera location and look_at point are the same direction = directionDefault; } // normalize new direction direction /= direction.abs( ); tmpVector = right; right = PMVector::cross( m_sky, direction ); if( approxZero( right.abs( ) ) ) right = tmpVector; right /= right.abs( ); up = PMVector::cross( direction, right ); direction *= directionLen; if( handedness > 0.0 ) right *= rightLen; else right *= -rightLen; up *= upLen; } TQString PMCamera::cameraTypeToString( PMCamera::CameraType t ) { TQString str( "perspective" ); switch( t ) { case Perspective: break; case Orthographic: str = "orthographic"; break; case FishEye: str = "fisheye"; break; case UltraWideAngle: str = "ultra_wide_angle"; break; case Omnimax: str = "omnimax"; break; case Panoramic: str = "panoramic"; break; case Cylinder: str = "cylinder"; break; } return str; } PMCamera::CameraType PMCamera::stringToCameraType( const TQString& str ) { CameraType t = Perspective; if( str == "perspective" ) t = Perspective; else if( str == "orthographic" ) t = Orthographic; else if( str == "fisheye" ) t = FishEye; else if( str == "ultra_wide_angle" ) t = UltraWideAngle; else if( str == "omnimax" ) t = Omnimax; else if( str == "panoramic" ) t = Panoramic; else if( str == "cylinder" ) t = Cylinder; else kdDebug( PMArea ) << "Unknown camera type\n"; return t; } void PMCamera::cleanUp( ) const { if( s_pDefaultViewStructure ) { delete s_pDefaultViewStructure; s_pDefaultViewStructure = 0; } if( s_pMetaObject ) { delete s_pMetaObject; s_pMetaObject = 0; } Base::cleanUp( ); }