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tdegraphics/kpovmodeler/pmblobcylinder.cpp

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/*
**************************************************************************
description
--------------------
copyright : (C) 2002 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 "pmblobcylinder.h"
#include "pmxmlhelper.h"
#include "pmboxedit.h"
#include "pmmemento.h"
#include "pm3dcontrolpoint.h"
#include "pmdefaults.h"
#include "pmdistancecontrolpoint.h"
#include "pmblobcylinderedit.h"
#include <klocale.h>
PMDefinePropertyClass( PMBlobCylinder, PMBlobCylinderProperty );
PMMetaObject* PMBlobCylinder::s_pMetaObject = 0;
PMObject* createNewBlobCylinder( PMPart* part )
{
return new PMBlobCylinder( part );
}
const double c_defaultRadius = 0.5;
const PMVector c_defaultEnd1 = PMVector ( 0, 0.5, 0 );
const PMVector c_defaultEnd2 = PMVector ( 0, -0.5, 0 );
const double c_defaultStrength = 1.0;
/** default cylinder structure */
PMViewStructure* PMBlobCylinder::s_pDefaultViewStructure = 0;
int PMBlobCylinder::s_vStep = c_defaultBlobCylinderVSteps;
int PMBlobCylinder::s_uStep = c_defaultBlobCylinderUSteps;
int PMBlobCylinder::s_parameterKey = 0;
PMBlobCylinder::PMBlobCylinder( PMPart* part )
: Base( part )
{
m_end1 = c_defaultEnd1;
m_end2 = c_defaultEnd2;
m_radius = c_defaultRadius;
m_strength = c_defaultStrength;
}
PMBlobCylinder::PMBlobCylinder( const PMBlobCylinder& c )
: Base( c )
{
m_end1 = c.m_end1;
m_end2 = c.m_end2;
m_radius = c.m_radius;
m_strength = c.m_strength;
}
PMBlobCylinder::~PMBlobCylinder( )
{
}
TQString PMBlobCylinder::description( ) const
{
return i18n( "blob cylinder" );
}
void PMBlobCylinder::serialize( TQDomElement& e, TQDomDocument& doc ) const
{
e.setAttribute( "end_a", m_end1.serializeXML( ) );
e.setAttribute( "end_b", m_end2.serializeXML( ) );
e.setAttribute( "radius", m_radius );
e.setAttribute( "strength", m_strength );
Base::serialize( e, doc );
}
void PMBlobCylinder::readAttributes( const PMXMLHelper& h )
{
m_end1 = h.vectorAttribute( "end_a", c_defaultEnd1 );
m_end2 = h.vectorAttribute( "end_b", c_defaultEnd2 );
m_radius = h.doubleAttribute( "radius", c_defaultRadius );
m_strength = h.doubleAttribute( "strength", c_defaultStrength );
Base::readAttributes( h );
}
PMMetaObject* PMBlobCylinder::tqmetaObject( ) const
{
if( !s_pMetaObject )
{
s_pMetaObject = new PMMetaObject( "BlobCylinder", Base::tqmetaObject( ),
createNewBlobCylinder );
s_pMetaObject->addProperty(
new PMBlobCylinderProperty( "end1", &PMBlobCylinder::setEnd1,
&PMBlobCylinder::end1 ) );
s_pMetaObject->addProperty(
new PMBlobCylinderProperty( "end2", &PMBlobCylinder::setEnd2,
&PMBlobCylinder::end2 ) );
s_pMetaObject->addProperty(
new PMBlobCylinderProperty( "radius", &PMBlobCylinder::setRadius,
&PMBlobCylinder::radius ) );
s_pMetaObject->addProperty(
new PMBlobCylinderProperty( "strength", &PMBlobCylinder::setStrength,
&PMBlobCylinder::strength ) );
}
return s_pMetaObject;
}
void PMBlobCylinder::setEnd1( const PMVector& p )
{
if( p != m_end1 )
{
if( m_pMemento )
m_pMemento->addData( s_pMetaObject, PMEnd1ID, m_end1 );
m_end1 = p;
m_end1.resize( 3 );
setViewStructureChanged( );
}
}
void PMBlobCylinder::setEnd2( const PMVector& p )
{
if( p != m_end2 )
{
if( m_pMemento )
m_pMemento->addData( s_pMetaObject, PMEnd2ID, m_end2 );
m_end2 = p;
m_end2.resize( 3 );
setViewStructureChanged( );
}
}
void PMBlobCylinder::setRadius( double radius )
{
if( m_radius != radius )
{
if( m_pMemento )
m_pMemento->addData( s_pMetaObject, PMRadiusID, m_radius );
m_radius = radius;
setViewStructureChanged( );
}
}
void PMBlobCylinder::setStrength( double s )
{
if( s != m_strength )
{
if( m_pMemento )
m_pMemento->addData( s_pMetaObject, PMStrengthID, m_strength );
m_strength = s;
}
}
PMDialogEditBase* PMBlobCylinder::editWidget( TQWidget* parent ) const
{
return new PMBlobCylinderEdit( parent );
}
void PMBlobCylinder::restoreMemento( PMMemento* s )
{
PMMementoDataIterator it( s );
PMMementoData* data;
for( ; it.current( ); ++it )
{
data = it.current( );
if( data->objectType( ) == s_pMetaObject )
{
switch( data->valueID( ) )
{
case PMEnd1ID:
setEnd1( data->vectorData( ) );
break;
case PMEnd2ID:
setEnd2( data->vectorData( ) );
break;
case PMRadiusID:
setRadius( data->doubleData( ) );
break;
case PMStrengthID:
setStrength( data->doubleData( ) );
break;
default:
kdError( PMArea ) << "Wrong ID in PMBlobCylinder::restoreMemento\n";
break;
}
}
}
Base::restoreMemento( s );
}
bool PMBlobCylinder::isDefault( )
{
if( ( m_end1 == c_defaultEnd1 ) && ( m_end2 == c_defaultEnd2 )
&& ( m_radius == c_defaultRadius )
&& globalDetail( ) )
return true;
return false;
}
void PMBlobCylinder::createViewStructure( )
{
if( !m_pViewStructure )
{
m_pViewStructure = new PMViewStructure( defaultViewStructure ( ) );
m_pViewStructure->points( ).detach( );
}
int uStep = (int)( ( (float)s_uStep / 2 ) * ( displayDetail( ) + 1 ) );
int vStep = (int)( ( (float)s_vStep / 2 ) * ( displayDetail( ) + 1 ) );
unsigned ptsSize = vStep * uStep * 2 + 2;
unsigned lineSize = vStep * uStep * 4 + vStep;
if( ptsSize != m_pViewStructure->points( ).size( ) )
m_pViewStructure->points( ).resize( ptsSize );
createPoints( m_pViewStructure->points( ), m_end1, m_end2, m_radius, uStep, vStep );
if( lineSize != m_pViewStructure->lines( ).size( ) )
{
m_pViewStructure->lines( ).detach( );
m_pViewStructure->lines( ).resize( lineSize );
createLines( m_pViewStructure->lines( ), uStep, vStep );
}
}
PMViewStructure* PMBlobCylinder::defaultViewStructure( ) const
{
if( !s_pDefaultViewStructure || s_pDefaultViewStructure->parameterKey( ) != viewStructureParameterKey( ) )
{
delete s_pDefaultViewStructure;
s_pDefaultViewStructure = 0;
int uStep = (int)( ( (float)s_uStep / 2 ) * ( displayDetail( ) + 1 ) );
int vStep = (int)( ( (float)s_vStep / 2 ) * ( displayDetail( ) + 1 ) );
s_pDefaultViewStructure =
new PMViewStructure( vStep * uStep * 2 + 2,
vStep * uStep * 4 + vStep );
createPoints( s_pDefaultViewStructure->points( ), c_defaultEnd1,
c_defaultEnd2, c_defaultRadius, uStep, vStep );
createLines( s_pDefaultViewStructure->lines( ), uStep, vStep );
}
return s_pDefaultViewStructure;
}
void PMBlobCylinder::createLines( PMLineArray& lines, int uStep, int vStep )
{
int u, v;
int offset = 0;
// horizontal lines
for( u = 0; u < ( uStep * 2 ); u++ )
{
for( v = 0; v < ( vStep - 1 ); v++ )
lines[offset + v] =
PMLine( u * vStep + v + 1, u * vStep + v + 2 );
lines[offset + vStep - 1] =
PMLine( u * vStep + 1, u * vStep + vStep );
offset += vStep;
}
// vertical lines
// lines at the "north pole"
for( v = 0; v < vStep; v++ )
lines[offset + v] = PMLine( 0, v + 1 );
offset += vStep;
for( v = 0; v < vStep; v++ )
{
for( u = 0; u < ( 2 * uStep - 1 ); u++ )
{
lines[offset + u] =
PMLine( u * vStep + v + 1, ( u + 1 ) * vStep + v + 1 );
}
offset += ( 2 * uStep - 1 );
}
// lines at the "south pole"
for( v = 0; v < vStep; v++ )
lines[offset + v] = PMLine( ( 2 * uStep - 1 ) * vStep + v + 1,
2 * uStep * vStep + 1 );
// offset += vStep;
}
void PMBlobCylinder::createPoints( PMPointArray& points, const PMVector& end1,
const PMVector& end2, double radius, int uStep, int vStep )
{
double uRadStep = M_PI / uStep / 2.0;
double vRadStep = 2 * M_PI / vStep;
double du = uRadStep;
if( radius < 0 )
radius = -radius;
PMVector pointAt = end2 - end1;
double pl = pointAt.abs( );
if( approxZero( pl ) )
pointAt = PMVector( 0.0, 0.0, 1.0 );
else
pointAt /= pl;
PMMatrix rotation = PMMatrix::rotation( pointAt, vRadStep );
PMVector ortho = pointAt.orthogonal( );
ortho /= ortho.abs( );
points[0] = PMPoint( end1 - pointAt * radius );
points[vStep * uStep * 2 + 1] = PMPoint( end2 + pointAt * radius );
int u, v;
for( u = 0; u < uStep; u++ )
{
PMVector end = ortho * radius * sin( du );
PMVector pv = pointAt * radius * cos( du );
PMVector e1 = end1 - pv;
PMVector e2 = end2 + pv;
for( v = 0; v < vStep; v++ )
{
points[u * vStep + v + 1] = PMPoint( e1 + end );
points[vStep * uStep * 2 - ( u + 1 ) * vStep + v + 1]
= PMPoint( e2 + end );
end = rotation * end;
}
du += uRadStep;
}
}
void PMBlobCylinder::controlPoints( PMControlPointList & list )
{
PMVector center, angle1, angle2;
center = m_end1 - m_end2;
double pl = center.abs( );
if( approxZero( pl ) )
center = PMVector( 0.0, 1.0, 0.0 );
else
center /= pl;
angle1 = center.orthogonal( );
angle2 = PMVector::cross( center, angle1 );
PM3DControlPoint* pb = new PM3DControlPoint( m_end1, PMEnd1ID, i18n( "End 1" ) );
list.append( pb );
list.append( new PM3DControlPoint( m_end2, PMEnd2ID, i18n( "End 2" ) ) );
list.append( new PMDistanceControlPoint( pb, angle1, m_radius, PMRadiusID, i18n( "Radius (1)" ) ) );
list.append( new PMDistanceControlPoint( pb, angle2, m_radius, PMRadiusID, i18n( "Radius (2)" ) ) );
}
void PMBlobCylinder::controlPointsChanged( PMControlPointList & list )
{
PMControlPoint* p;
bool pointChanged = false;
bool radiusChanged = false;
for( p = list.first( ); p; p = list.next( ) )
{
if( p->changed( ) )
{
switch( p->id( ) )
{
case PMEnd1ID:
setEnd1( ( ( PM3DControlPoint *) p)->point( ) );
pointChanged = true;
break;
case PMEnd2ID:
setEnd2( ( ( PM3DControlPoint *) p)->point( ) );
pointChanged = true;
break;
case PMRadiusID:
setRadius( ( ( PMDistanceControlPoint *) p)->distance( ) );
radiusChanged = true;
break;
default:
kdError( PMArea ) << "Wrong ID in PMBlobCylinder::controlPointsChanged\n";
break;
}
}
}
if( pointChanged )
{
PMVector center, angle1, angle2;
bool firstPoint = true;
center = m_end1 - m_end2;
double pl = center.abs( );
if( approxZero( pl ) )
center = PMVector( 0.0, 1.0, 0.0 );
else
center /= pl;
angle1 = center.orthogonal( );
angle2 = PMVector::cross( center, angle1 );
for( p = list.first( ); p; p = list.next( ) )
if( p->id( ) == PMRadiusID )
{
if( firstPoint )
{
( ( PMDistanceControlPoint *) p)->setDirection( angle1 );
firstPoint = false;
}
else
( ( PMDistanceControlPoint *) p)->setDirection( angle2 );
}
}
if( radiusChanged )
for( p = list.first( ); p; p = list.next( ) )
if( p->id( ) == PMRadiusID )
( ( PMDistanceControlPoint *) p)->setDistance( m_radius );
}
void PMBlobCylinder::setUSteps( int u )
{
if( u >= 2 )
{
s_uStep = u;
if( s_pDefaultViewStructure )
{
delete s_pDefaultViewStructure;
s_pDefaultViewStructure = 0;
}
}
else
kdDebug( PMArea ) << "PMBlobCylinder::setUSteps: U must be greater than 1\n";
s_parameterKey++;
}
void PMBlobCylinder::setVSteps( int v )
{
if( v >= 4 )
{
s_vStep = v;
if( s_pDefaultViewStructure )
{
delete s_pDefaultViewStructure;
s_pDefaultViewStructure = 0;
}
}
else
kdDebug( PMArea ) << "PMBlobCylinder::setVSteps: V must be greater than 3\n";
s_parameterKey++;
}
void PMBlobCylinder::cleanUp( ) const
{
if( s_pDefaultViewStructure )
delete s_pDefaultViewStructure;
s_pDefaultViewStructure = 0;
if( s_pMetaObject )
{
delete s_pMetaObject;
s_pMetaObject = 0;
}
Base::cleanUp( );
}