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tdegraphics/kpovmodeler/pmpovray31serialization.cpp

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64 KiB

/*
**************************************************************************
description
--------------------
copyright : (C) 2003 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 "pmpovray31serialization.h"
#include "pmoutputdevice.h"
#include "pmallobjects.h"
const double c_defaultPatchFlatness = 0;
void PMPov31SerBicubicPatch( const PMObject* object, const PMMetaObject* tqmetaObject, PMOutputDevice* dev )
{
PMBicubicPatch* o = ( PMBicubicPatch* ) object;
int u, v;
TQString str, line;
dev->objectBegin( "bicubic_patch" );
dev->writeName( object->name( ) );
str.setNum( o->patchType( ) );
dev->writeLine( "type " + str );
if( !approx( o->flatness( ), c_defaultPatchFlatness ) )
{
str.setNum( o->flatness( ) );
dev->writeLine( "flatness " + str );
}
str.setNum( o->uSteps( ) );
dev->writeLine( "u_steps " + str );
str.setNum( o->vSteps( ) );
dev->writeLine( "v_steps " + str );
for( v = 0; v < 4; v++ )
{
line = o->controlPoint( v*4 ).serialize( );
for( u = 1; u < 4; u++ )
line += TQString( ", " ) + o->controlPoint( u+4*v ).serialize( );
if( v != 3 )
line += ",";
dev->writeLine( line );
}
dev->callSerialization( object, tqmetaObject->superClass( ) );
dev->objectEnd( );
}
void PMPov31SerBlendMapModifiers( const PMObject* object, const PMMetaObject*, PMOutputDevice* dev )
{
PMBlendMapModifiers* o = ( PMBlendMapModifiers* ) object;
TQString str;
if( o->isFrequencyEnabled( ) )
{
str.setNum( o->frequency( ) );
dev->writeLine( "frequency " + str );
}
if( o->isPhaseEnabled( ) )
{
str.setNum( o->phase( ) );
dev->writeLine( "phase " + str );
}
if( o->isWaveFormEnabled( ) )
{
switch( o->waveFormType( ) )
{
case PMBlendMapModifiers::RampWave:
dev->writeLine( "ramp_wave" );
break;
case PMBlendMapModifiers::TriangleWave:
dev->writeLine( "triangle_wave" );
break;
case PMBlendMapModifiers::SineWave:
dev->writeLine( "sine_wave" );
break;
case PMBlendMapModifiers::ScallopWave:
dev->writeLine( "scallop_wave" );
break;
case PMBlendMapModifiers::CubicWave:
dev->writeLine( "cubic_wave" );
break;
case PMBlendMapModifiers::PolyWave:
str.setNum( o->waveFormExponent( ) );
dev->writeLine( "poly_wave " + str );
break;
}
}
}
void PMPov31SerBlob( const PMObject* object, const PMMetaObject* tqmetaObject, PMOutputDevice* dev )
{
PMBlob* o = ( PMBlob* ) object;
dev->objectBegin( "blob" );
dev->writeName( object->name( ) );
dev->writeLine( TQString( "threshold %1" ).tqarg( o->threshold( ) ) );
dev->callSerialization( object, tqmetaObject->superClass( ) );
if( o->sturm( ) )
dev->writeLine( "sturm" );
if( o->hierarchy( ) )
dev->writeLine( "hierarchy" );
dev->objectEnd( );
}
void PMPov31SerBlobCylinder( const PMObject* object, const PMMetaObject* tqmetaObject, PMOutputDevice* dev )
{
PMBlobCylinder* o = ( PMBlobCylinder* ) object;
dev->objectBegin( "cylinder" );
dev->writeName( object->name( ) );
TQString str1;
str1.setNum( o->radius( ) );
dev->writeLine( o->end1( ).serialize( ) + ", " + o->end2( ).serialize( )
+ ", " + str1 + "," );
dev->writeLine( TQString( "strength %1" ).tqarg( o->strength( ) ) );
dev->callSerialization( object, tqmetaObject->superClass( ) );
dev->objectEnd( );
}
void PMPov31SerBlobSphere( const PMObject* object, const PMMetaObject* tqmetaObject, PMOutputDevice* dev )
{
PMBlobSphere* o = ( PMBlobSphere* ) object;
dev->objectBegin( "sphere" );
dev->writeName( object->name( ) );
dev->writeLine( o->centre( ).serialize( ) + TQString( ", %1," ).tqarg( o->radius( ) ) );
dev->writeLine( TQString( "strength %1" ).tqarg( o->strength( ) ) );
dev->callSerialization( object, tqmetaObject->superClass( ) );
dev->objectEnd( );
}
void PMPov31SerBoundedBy( const PMObject* object, const PMMetaObject* tqmetaObject, PMOutputDevice* dev )
{
PMBoundedBy* o = ( PMBoundedBy* ) object;
dev->objectBegin( "bounded_by" );
if( o->clippedBy( ) )
dev->writeLine( "clipped_by" );
dev->callSerialization( object, tqmetaObject->superClass( ) );
dev->objectEnd( );
}
void PMPov31SerBox( const PMObject* object, const PMMetaObject* tqmetaObject, PMOutputDevice* dev )
{
PMBox* o = ( PMBox* ) object;
dev->objectBegin( "box" );
dev->writeName( object->name( ) );
dev->writeLine( o->corner1( ).serialize( ) + ", " + o->corner2( ).serialize( ) );
dev->callSerialization( object, tqmetaObject->superClass( ) );
dev->objectEnd( );
}
void PMPov31SerBumpMap( const PMObject* object, const PMMetaObject*, PMOutputDevice* dev )
{
PMBumpMap* o = ( PMBumpMap* ) object;
TQString str1;
dev->objectBegin( "bump_map" );
switch( o->bitmapType( ) )
{
case PMBumpMap::BitmapGif:
dev->writeLine( "gif" );
break;
case PMBumpMap::BitmapTga:
dev->writeLine( "tga" );
break;
case PMBumpMap::BitmapIff:
dev->writeLine( "iff" );
break;
case PMBumpMap::BitmapPpm:
dev->writeLine( "ppm" );
break;
case PMBumpMap::BitmapPgm:
dev->writeLine( "pgm" );
break;
case PMBumpMap::BitmapPng:
dev->writeLine( "png" );
break;
case PMBumpMap::BitmapJpeg:
dev->writeLine( "jpeg" );
break;
case PMBumpMap::BitmapTiff:
dev->writeLine( "tiff" );
break;
case PMBumpMap::BitmapSys:
dev->writeLine( "sys" );
break;
}
dev->writeLine( "\"" + o->bitmapFile( ) + "\"" );
if( o->isOnceEnabled( ) )
dev->writeLine( "once" );
switch( o->mapType( ) )
{
case PMBumpMap::MapPlanar:
dev->writeLine( "map_type 0" );
break;
case PMBumpMap::MapSpherical:
dev->writeLine( "map_type 1" );
break;
case PMBumpMap::MapCylindrical:
dev->writeLine( "map_type 2" );
break;
case PMBumpMap::MapToroidal:
dev->writeLine( "map_type 5" );
break;
}
switch( o->interpolateType( ) )
{
case PMBumpMap::InterpolateBilinear:
dev->writeLine( "interpolate 2" );
break;
case PMBumpMap::InterpolateNormalized:
dev->writeLine( "interpolate 4" );
break;
default:
break;
}
if( o->isUseIndexEnabled( ) )
dev->writeLine( "use_index" );
if( o->bumpSize( ) )
{
str1.setNum( o->bumpSize( ) );
dev->writeLine( "bump_size " + str1 );
}
dev->objectEnd( );
}
void PMPov31SerCamera( const PMObject* object, const PMMetaObject* tqmetaObject, PMOutputDevice* dev )
{
PMCamera* o = ( PMCamera* ) object;
dev->objectBegin( "camera" );
TQString str;
dev->writeName( object->name( ) );
if( o->cameraType( ) == PMCamera::Cylinder )
{
str.setNum( o->cylinderType( ) );
dev->writeLine( "cylinder " + str );
}
else
dev->writeLine( o->cameraTypeToString( o->cameraType( ) ) );
dev->writeLine( "location " + o->location( ).serialize( ) );
dev->writeLine( "sky " + o->sky( ).serialize( ) );
dev->writeLine( "direction " + o->direction( ).serialize( ) );
dev->writeLine( "right " + o->right( ).serialize( ) );
dev->writeLine( "up " + o->up( ).serialize( ) );
dev->writeLine( "look_at " + o->lookAt( ).serialize( ) );
if( ( o->cameraType( ) != PMCamera::Orthographic ) &&
( o->cameraType( ) != PMCamera::Omnimax ) &&
( o->cameraType( ) != PMCamera::Panoramic ) && o->isAngleEnabled( ) )
{
str.setNum( o->angle( ) );
dev->writeLine( "angle " + str );
}
if( o->isFocalBlurEnabled( ) && ( o->cameraType( ) == PMCamera::Perspective ) )
{
str.setNum( o->aperture( ) );
dev->writeLine( "aperture " + str );
str.setNum( o->blurSamples( ) );
dev->writeLine( "blur_samples " + str );
dev->writeLine( "focal_point " + o->focalPoint( ).serialize( ) );
str.setNum( o->confidence( ) );
dev->writeLine( "confidence " + str );
str.setNum( o->variance( ) );
dev->writeLine( "variance " + str );
}
dev->callSerialization( object, tqmetaObject->superClass( ) );
dev->objectEnd( );
}
void PMPov31SerClippedBy( const PMObject* object, const PMMetaObject* tqmetaObject, PMOutputDevice* dev )
{
PMClippedBy* o = ( PMClippedBy* ) object;
dev->objectBegin( "clipped_by" );
if( o->boundedBy( ) )
dev->writeLine( "bounded_by" );
dev->callSerialization( object, tqmetaObject->superClass( ) );
dev->objectEnd( );
}
void PMPov31SerComment( const PMObject* object, const PMMetaObject*, PMOutputDevice* dev )
{
PMComment* o = ( PMComment* ) object;
dev->writeComment( o->text( ) );
}
void PMPov31SerCompositeObject( const PMObject* object, const PMMetaObject*, PMOutputDevice* dev )
{
PMCompositeObject* o = ( PMCompositeObject* ) object;
PMObject* tmp;
for( tmp = o->firstChild( ); tmp; tmp = tmp->nextSibling( ) )
if( tmp->exportPovray( ) )
dev->serialize( tmp );
}
void PMPov31SerCone( const PMObject* object, const PMMetaObject* tqmetaObject, PMOutputDevice* dev )
{
PMCone* o = ( PMCone* ) object;
dev->objectBegin( "cone" );
dev->writeName( object->name( ) );
TQString str1;
str1.setNum( o->radius1( ) );
dev->writeLine( o->end1( ).serialize( ) + ", " + str1 + "," );
str1.setNum( o->radius2( ) );
dev->writeLine( o->end2( ).serialize( ) + ", " + str1 );
if( o->open( ) )
dev->writeLine( TQString( "open" ) );
dev->callSerialization( object, tqmetaObject->superClass( ) );
dev->objectEnd( );
}
void PMPov31SerCSG( const PMObject* object, const PMMetaObject* tqmetaObject, PMOutputDevice* dev )
{
PMCSG* o = ( PMCSG* ) object;
switch( o->csgType( ) )
{
case PMCSG::CSGUnion:
dev->objectBegin( "union" );
break;
case PMCSG::CSGIntersection:
dev->objectBegin( "intersection" );
break;
case PMCSG::CSGDifference:
dev->objectBegin( "difference" );
break;
case PMCSG::CSGMerge:
dev->objectBegin( "merge" );
break;
}
dev->writeName( object->name( ) );
dev->callSerialization( object, tqmetaObject->superClass( ) );
dev->objectEnd( );
}
void PMPov31SerCylinder( const PMObject* object, const PMMetaObject* tqmetaObject, PMOutputDevice* dev )
{
PMCylinder* o = ( PMCylinder* ) object;
dev->objectBegin( "cylinder" );
dev->writeName( object->name( ) );
TQString str1;
str1.setNum( o->radius( ) );
dev->writeLine( o->end1( ).serialize( ) + ", " + o->end2( ).serialize( )
+ ", " + str1 );
if( o->open( ) )
dev->writeLine( TQString( "open" ) );
dev->callSerialization( object, tqmetaObject->superClass( ) );
dev->objectEnd( );
}
void PMPov31SerDeclare( const PMObject* object, const PMMetaObject* tqmetaObject, PMOutputDevice* dev )
{
PMDeclare* o = ( PMDeclare* ) object;
if( o->firstChild( ) )
{
dev->declareBegin( o->id( ) );
dev->callSerialization( object, tqmetaObject->superClass( ) );
}
}
void PMPov31SerDensity( const PMObject* object, const PMMetaObject* tqmetaObject, PMOutputDevice* dev )
{
bool bObject = true;
if( object->parent( ) )
if( object->parent( )->type( ) == "DensityMap" )
bObject = false;
if( bObject )
dev->objectBegin( "density" );
dev->callSerialization( object, tqmetaObject->superClass( ) );
if( bObject )
dev->objectEnd( );
}
void PMPov31SerDisc( const PMObject* object, const PMMetaObject* tqmetaObject, PMOutputDevice* dev )
{
PMDisc* o = ( PMDisc* ) object;
dev->objectBegin( "disc" );
dev->writeName( object->name( ) );
TQString str1, str2;
str1.setNum( o->radius( ) );
if( o->radius( ) != 0.0 )
{
str2.setNum( o->holeRadius( ) );
dev->writeLine( o->center( ).serialize( ) + "," + o->normal( ).serialize( ) + ", " + str1 + "," + str2 );
}
else
{
dev->writeLine( o->center( ).serialize( ) + "," + o->normal( ).serialize( ) + ", " + str1 );
}
dev->callSerialization( object, tqmetaObject->superClass( ) );
dev->objectEnd( );
}
void PMPov31SerFinish( const PMObject* object, const PMMetaObject* tqmetaObject, PMOutputDevice* dev )
{
PMFinish* o = ( PMFinish* ) object;
TQString str1;
dev->objectBegin( "finish" );
dev->callSerialization( object, tqmetaObject->superClass( ) );
if( o->isAmbientEnabled( ) )
dev->writeLine( "ambient " + o->ambientColor( ).serialize( ) );
if( o->isDiffuseEnabled( ) )
{
str1.setNum( o->diffuse( ) );
dev->writeLine( "diffuse " + str1 );
}
if( o->isBrillianceEnabled( ) )
{
str1.setNum( o->brilliance( ) );
dev->writeLine( "brilliance " + str1 );
}
if( o->isPhongEnabled( ) )
{
str1.setNum( o->phong( ) );
dev->writeLine( "phong " + str1 );
}
if( o->isPhongSizeEnabled( ) )
{
str1.setNum( o->phongSize( ) );
dev->writeLine( "phong_size " + str1 );
}
if( o->isMetallicEnabled( ) )
{
str1.setNum( o->metallic( ) );
dev->writeLine( "metallic " + str1 );
}
if( o->isSpecularEnabled( ) )
{
str1.setNum( o->specular( ) );
dev->writeLine( "specular " + str1 );
}
if( o->isRoughnessEnabled( ) )
{
str1.setNum( o->roughness( ) );
dev->writeLine( "roughness " + str1 );
}
if( o->isReflectionEnabled( ) )
{
dev->writeLine( "reflection " + o->reflectionColor( ).serialize( ) );
}
if( o->isExponentEnabled( ) )
{
str1.setNum( o->reflectionExponent( ) );
dev->writeLine( "reflection_exponent " + str1 );
}
if( o->irid( ) )
{
str1.setNum( o->iridAmount( ) );
dev->writeLine( "irid { " + str1 );
str1.setNum( o->iridThickness( ) );
dev->writeLine( "thickness " + str1 );
str1.setNum( o->iridTurbulence( ) );
dev->writeLine( "turbulence " + str1 + " } " );
}
if( o->isCrandEnabled( ) )
{
str1.setNum( o->crand( ) );
dev->writeLine( "crand " + str1 );
}
dev->objectEnd( );
}
const int c_defaultFogOctaves = 6;
const double c_defaultFogLambda = 2.0;
const double c_defaultFogOmega = 0.5;
const double c_defaultFogTurbDepth = 0.5;
void PMPov31SerFog( const PMObject* object, const PMMetaObject*, PMOutputDevice* dev )
{
PMFog* o = ( PMFog* ) object;
TQString str;
dev->objectBegin( "fog" );
// Serialize the name of this object
dev->writeName( object->name( ) );
// Serialize a possible link
if( o->linkedObject( ) )
{
if( o->linkedObject( )->firstChild( ) )
dev->writeLine( o->linkedObject( )->id( ) );
else
{
TQString text;
text = o->name( );
if( text.isEmpty( ) )
text = o->description( );
dev->writeComment( TQString( "No prototype for %1" ).tqarg( text ) );
}
}
str.setNum( o->fogType( ) );
dev->writeLine( "fog_type " + str );
str.setNum( o->distance( ) );
dev->writeLine( "distance " + str );
dev->writeLine( " " + o->color( ).serialize( ) + " " );
if( o->isTurbulenceEnabled( ) )
{
dev->writeLine( "turbulence " + o->valueVector( ).serialize( ) );
if( o->octaves( ) != c_defaultFogOctaves )
{
str.setNum(o->octaves( ));
dev->writeLine( "octaves " + str );
}
if( o->omega( ) != c_defaultFogOmega )
{
str.setNum(o->omega( ));
dev->writeLine( "omega " + str );
}
if( o->lambda( ) != c_defaultFogLambda )
{
str.setNum(o->lambda( ));
dev->writeLine( "lambda " + str );
}
if( o->depth( ) != c_defaultFogTurbDepth )
{
str.setNum(o->depth( ));
dev->writeLine( "turb_depth " + str );
}
}
if( o->fogType( ) == 2 )
{
// Serialize ground fog variables
str.setNum( o->fogOffset( ) );
dev->writeLine( "fog_offset " + str );
str.setNum( o->fogAlt( ) );
dev->writeLine( "fog_alt " + str );
dev->writeLine( "up " + o->up( ).serialize( ) );
}
// Serialize the tqchildren of this object
dev->callSerialization( object, object->tqmetaObject( )->superClass( )->superClass( ) );
dev->objectEnd( );
}
const double c_defaultGlobalSettingsAdcBailout = 1.0 / 255.0;
const PMColor c_defaultGlobalSettingsAmbientLight = PMColor( 1.0, 1.0, 1.0, 0.0, 0.0 );
const double c_defaultGlobalSettingsAssumedGamma = 0.0;
const bool c_defaultGlobalSettingsHfGray16 = false;
const PMColor c_defaultGlobalSettingsIridWaveLength = PMColor( 0.25, 0.18, 0.14, 0.0, 0.0 );
const int c_defaultGlobalSettingsMaxIntersections = 0; // ???
const int c_defaultGlobalSettingsMaxTraceLevel = 0; // ???
const int c_defaultGlobalSettingsNumberWaves = 10;
const bool c_defaultGlobalSettingsRadiosity = false;
const double c_defaultGlobalSettingsBrightness = 1.0;
const int c_defaultGlobalSettingsCount = 35;
const double c_defaultGlobalSettingsDistanceMaximum = 0; // ???
const double c_defaultGlobalSettingsErrorBound = 1.8;
const double c_defaultGlobalSettingsGrayThreshold = 0.0;
const double c_defaultGlobalSettingsLowErrorFactor = 0.5;
const double c_defaultGlobalSettingsMinimumReuse = 0.015;
const int c_defaultGlobalSettingsNearestCount = 5;
const int c_defaultGlobalSettingsRecursionLimit = 2;
void PMPov31SerGlobalSettings( const PMObject* object, const PMMetaObject*, PMOutputDevice* dev )
{
PMGlobalSettings* o = ( PMGlobalSettings* ) object;
TQString str1;
dev->objectBegin( "global_settings" );
if( o->adcBailout( ) != c_defaultGlobalSettingsAdcBailout )
{
str1.setNum( o->adcBailout( ) );
dev->writeLine( "adc_bailout " + str1 );
}
if( o->ambientLight( ) != c_defaultGlobalSettingsAmbientLight )
dev->writeLine( "ambient_light " + o->ambientLight( ).serialize( ) );
if( o->assumedGamma( ) != c_defaultGlobalSettingsAssumedGamma )
{
str1.setNum( o->assumedGamma( ) );
dev->writeLine( "assumed_gamma " + str1 );
}
if( o->hfGray16( ) != c_defaultGlobalSettingsHfGray16 )
{
if( o->hfGray16( ) )
dev->writeLine( "hf_gray_16 on" );
else
dev->writeLine( "hf_gray_16 off" );
}
if( o->iridWaveLength( ) != c_defaultGlobalSettingsIridWaveLength )
dev->writeLine( "irid_wavelength " + o->iridWaveLength( ).serialize( ) );
if( o->maxTraceLevel( ) != c_defaultGlobalSettingsMaxTraceLevel )
{
str1.setNum( o->maxTraceLevel( ) );
dev->writeLine( "max_trace_level " + str1 );
}
if( o->maxIntersections( ) != c_defaultGlobalSettingsMaxIntersections )
{
str1.setNum( o->maxIntersections( ) );
dev->writeLine( "max_intersections " + str1 );
}
if( o->numberWaves( ) != c_defaultGlobalSettingsNumberWaves )
{
str1.setNum( o->numberWaves( ) );
dev->writeLine( "number_of_waves " + str1 );
}
if( o->isRadiosityEnabled( ) )
{
dev->objectBegin( "radiosity" );
if( o->brightness( ) != c_defaultGlobalSettingsBrightness )
{
str1.setNum( o->brightness( ) );
dev->writeLine( "brightness " + str1 );
}
if( o->count( ) != c_defaultGlobalSettingsCount )
{
str1.setNum( o->count( ) );
dev->writeLine( "count " + str1 );
}
if( o->distanceMaximum( ) != c_defaultGlobalSettingsDistanceMaximum )
{
str1.setNum( o->distanceMaximum( ) );
dev->writeLine( "distance_maximum " + str1 );
}
if( o->errorBound( ) != c_defaultGlobalSettingsErrorBound )
{
str1.setNum( o->errorBound( ) );
dev->writeLine( "error_bound " + str1 );
}
if( o->grayThreshold( ) != c_defaultGlobalSettingsGrayThreshold )
{
str1.setNum( o->grayThreshold( ) );
dev->writeLine( "gray_threshold " + str1 );
}
if( o->lowErrorFactor( ) != c_defaultGlobalSettingsLowErrorFactor )
{
str1.setNum( o->lowErrorFactor( ) );
dev->writeLine( "low_error_factor " + str1 );
}
if( o->minimumReuse( ) != c_defaultGlobalSettingsMinimumReuse )
{
str1.setNum( o->minimumReuse( ) );
dev->writeLine( "minimuo->reuse( ) " + str1 );
}
if( o->nearestCount( ) != c_defaultGlobalSettingsNearestCount )
{
str1.setNum( o->nearestCount( ) );
dev->writeLine( "nearest_count " + str1 );
}
if( o->recursionLimit( ) != c_defaultGlobalSettingsRecursionLimit )
{
str1.setNum( o->recursionLimit( ) );
dev->writeLine( "recursion_limit " + str1 );
}
dev->objectEnd( );
}
dev->objectEnd( );
}
void PMPov31SerGraphicalObject( const PMObject* object, const PMMetaObject* tqmetaObject, PMOutputDevice* dev )
{
PMGraphicalObject* o = ( PMGraphicalObject* ) object;
dev->callSerialization( object, tqmetaObject->superClass( ) );
if( o->noShadow( ) )
dev->writeLine( "no_shadow" );
}
void PMPov31SerHeightField( const PMObject* object, const PMMetaObject* tqmetaObject, PMOutputDevice* dev )
{
PMHeightField* o = ( PMHeightField* ) object;
dev->objectBegin( "height_field" );
dev->writeName( object->name( ) );
dev->writeLine( o->typeToString( o->heightFieldType( ) ) + " \"" + o->fileName( ) + "\"" );
if( o->waterLevel( ) > 0.0 )
dev->writeLine( TQString( "water_level %1" ).tqarg( o->waterLevel( ) ) );
if( !o->hierarchy( ) )
dev->writeLine( "hierarchy off" );
if( o->smooth( ) )
dev->writeLine( "smooth" );
dev->callSerialization( object, tqmetaObject->superClass( ) );
dev->objectEnd( );
}
void PMPov31SerImageMap( const PMObject* object, const PMMetaObject*, PMOutputDevice* dev )
{
PMImageMap* o = ( PMImageMap* ) object;
typedef TQValueList<PMPaletteValue> PMPaletteValueList;
PMPaletteValueList values;
PMPaletteValueList::ConstIterator tmpPalette;
TQString str1, str2;
dev->objectBegin( "image_map" );
switch( o->bitmapType( ) )
{
case PMImageMap::BitmapGif:
dev->writeLine( "gif" );
break;
case PMImageMap::BitmapTga:
dev->writeLine( "tga" );
break;
case PMImageMap::BitmapIff:
dev->writeLine( "iff" );
break;
case PMImageMap::BitmapPpm:
dev->writeLine( "ppm" );
break;
case PMImageMap::BitmapPgm:
dev->writeLine( "pgm" );
break;
case PMImageMap::BitmapPng:
dev->writeLine( "png" );
break;
case PMImageMap::BitmapJpeg:
dev->writeLine( "jpeg" );
break;
case PMImageMap::BitmapTiff:
dev->writeLine( "tiff" );
break;
case PMImageMap::BitmapSys:
dev->writeLine( "sys" );
break;
}
dev->writeLine( "\"" + o->bitmapFile( ) + "\"" );
values = o->filters( );
for( tmpPalette = values.begin( ); tmpPalette != values.end( ); ++tmpPalette )
{
str1.setNum( ( *tmpPalette ).index( ) );
str2.setNum( ( *tmpPalette ).value( ) );
dev->writeLine( "filter " + str1 + ", " + str2 );
}
values = o->transmits( );
for( tmpPalette = values.begin( ); tmpPalette != values.end( ); ++tmpPalette )
{
str1.setNum( ( *tmpPalette ).index( ) );
str2.setNum( ( *tmpPalette ).value( ) );
dev->writeLine( "transmit " + str1 + ", " + str2 );
}
if( o->isFilterAllEnabled( ) )
{
str1.setNum( o->filterAll( ) );
dev->writeLine( "filter all " + str1 );
}
if( o->isTransmitAllEnabled( ) )
{
str1.setNum( o->transmitAll( ) );
dev->writeLine( "transmit all " + str1 );
}
if( o->isOnceEnabled( ) )
dev->writeLine( "once" );
switch( o->mapType( ) )
{
case PMImageMap::MapPlanar:
dev->writeLine( "map_type 0" );
break;
case PMImageMap::MapSpherical:
dev->writeLine( "map_type 1" );
break;
case PMImageMap::MapCylindrical:
dev->writeLine( "map_type 2" );
break;
case PMImageMap::MapToroidal:
dev->writeLine( "map_type 5" );
break;
}
switch( o->interpolateType( ) )
{
case PMImageMap::InterpolateBilinear:
dev->writeLine( "interpolate 2" );
break;
case PMImageMap::InterpolateNormalized:
dev->writeLine( "interpolate 4" );
break;
default:
break;
}
dev->objectEnd( );
}
void PMPov31SerInterior( const PMObject* object, const PMMetaObject* tqmetaObject, PMOutputDevice* dev )
{
PMInterior* o = ( PMInterior* ) object;
TQString str1;
dev->objectBegin( "interior" );
dev->callSerialization( object, tqmetaObject->superClass( ) );
if( o->isIorEnabled( ) )
{
str1.setNum( o->ior( ) );
dev->writeLine( "ior " + str1 );
}
if( o->isCausticsEnabled( ) )
{
str1.setNum( o->caustics( ) );
dev->writeLine( "caustics " + str1 );
}
if( o->isFadeDistanceEnabled( ) )
{
str1.setNum( o->fadeDistance( ) );
dev->writeLine( "fade_distance " + str1 );
}
if( o->isFadeDistanceEnabled( ) )
{
str1.setNum( o->fadeDistance( ) );
dev->writeLine( "fade_distance " + str1 );
}
dev->objectEnd( );
}
void PMPov31SerJuliaFractal( const PMObject* object, const PMMetaObject* tqmetaObject, PMOutputDevice* dev )
{
PMJuliaFractal* o = ( PMJuliaFractal* ) object;
dev->objectBegin( "julia_fractal" );
dev->writeName( object->name( ) );
dev->writeLine( o->juliaParameter( ).serialize( ) );
dev->writeLine( o->algebraTypeToString( o->algebraType( ) ) );
if( o->functionType( ) == PMJuliaFractal::FTpwr )
dev->writeLine( TQString( "pwr(%1, %2)" ).tqarg( o->exponent( )[0] ).
arg( o->exponent( )[1] ) );
else
dev->writeLine( o->functionTypeToString( o->functionType( ) ) );
dev->writeLine( TQString( "max_iteration %1" ).tqarg( o->maximumIterations( ) ) );
dev->writeLine( TQString( "precision %1" ).tqarg( o->precision( ) ) );
dev->writeLine( TQString( "slice %1, %2" ).tqarg( o->sliceNormal( ).serialize( ) )
.tqarg( o->sliceDistance( ) ) );
dev->callSerialization( object, tqmetaObject->superClass( ) );
dev->objectEnd( );
}
void PMPov31SerLathe( const PMObject* object, const PMMetaObject* tqmetaObject, PMOutputDevice* dev )
{
PMLathe* o = ( PMLathe* ) object;
dev->objectBegin( "lathe" );
dev->writeName( object->name( ) );
switch( o->splineType( ) )
{
case PMLathe::LinearSpline:
dev->writeLine( "linear_spline" );
break;
case PMLathe::QuadraticSpline:
dev->writeLine( "quadratic_spline" );
break;
case PMLathe::CubicSpline:
dev->writeLine( "cubic_spline" );
break;
case PMLathe::BezierSpline:
dev->writeLine( "bezier_spline" );
break;
}
int num = o->points( ).count( );
dev->writeLine( TQString( "%1," ).tqarg( num ) );
bool first = true;
TQValueList<PMVector> points = o->points( );
TQValueList<PMVector>::ConstIterator it = points.begin( );
for( ; it != points.end( ); ++it )
{
if( !first )
dev->write( ", " );
dev->write( ( *it ).serialize( ) );
first = false;
}
dev->writeLine( "" );
if( o->sturm( ) )
dev->writeLine( "sturm" );
dev->callSerialization( object, tqmetaObject->superClass( ) );
dev->objectEnd( );
}
const double c_defaultLightTightness = 10;
const int c_defaultLightAdaptive = 0;
void PMPov31SerLight( const PMObject* object, const PMMetaObject* tqmetaObject, PMOutputDevice* dev )
{
PMLight* o = ( PMLight* ) object;
dev->objectBegin( TQString( "light_source" ) );
dev->writeName( object->name( ) );
dev->writeLine( o->location( ).serialize( ) + ", " + o->color( ).serialize( ) );
if( o->lightType( ) == PMLight::SpotLight )
dev->writeLine( TQString( "spotlight" ) );
else if( o->lightType( ) == PMLight::CylinderLight )
dev->writeLine( TQString( "cylinder" ) );
else if( o->lightType( ) == PMLight::ShadowlessLight )
dev->writeLine( TQString( "shadowless" ) );
if( ( o->lightType( ) == PMLight::SpotLight ) ||
( o->lightType( ) == PMLight::CylinderLight ) )
{
dev->writeLine( TQString( "radius %1" ).tqarg( o->radius( ) ) );
dev->writeLine( TQString( "falloff %1" ).tqarg( o->falloff( ) ) );
if( o->tightness( ) != c_defaultLightTightness )
dev->writeLine( TQString( "tightness %1" ).tqarg( o->tightness( ) ) );
dev->writeLine( TQString( "point_at " ) + o->pointAt( ).serialize( ) );
}
if( o->isAreaLight( ) )
{
dev->writeLine( TQString( "area_light " ) + o->axis1( ).serialize( )
+ TQString( ", " ) + o->axis2( ).serialize( )
+ TQString( ", %1, %2" ).tqarg( o->size1( ) ).tqarg( o->size2( ) ) );
if( o->adaptive( ) != c_defaultLightAdaptive )
dev->writeLine( TQString( "adaptive %1" ).tqarg( o->adaptive( ) ) );
if( o->jitter( ) )
dev->writeLine( TQString( "jitter" ) );
}
if( o->fading( ) )
{
dev->writeLine( TQString( "fade_distance %1" ).tqarg( o->fadeDistance( ) ) );
dev->writeLine( TQString( "fade_power %1" ).tqarg( o->fadePower( ) ) );
}
if( !o->mediaInteraction( ) )
dev->writeLine( TQString( "media_interaction off" ) );
if( !o->mediaAttenuation( ) )
dev->writeLine( TQString( "media_attenuation off" ) );
dev->callSerialization( object, tqmetaObject->superClass( ) );
dev->objectEnd( );
}
void PMPov31SerListPattern( const PMObject* object, const PMMetaObject* tqmetaObject, PMOutputDevice* dev )
{
PMListPattern* o = ( PMListPattern* ) object;
TQString str1;
switch( o->listType( ) )
{
case PMListPattern::ListPatternBrick:
dev->writeLine( "brick" );
break;
case PMListPattern::ListPatternChecker:
dev->writeLine( "checker " );
break;
case PMListPattern::ListPatternHexagon:
dev->writeLine( "hexagon " );
break;
}
dev->callSerialization( object, tqmetaObject->superClass( ) );
if( o->listType( ) == PMListPattern::ListPatternBrick )
{
dev->writeLine( "brick_size " +
o->brickSize( ).serialize( ) );
str1.setNum( o->mortar( ) );
dev->writeLine( "mortar " + str1 );
}
}
void PMPov31SerTextureList( const PMObject* object, const PMMetaObject* tqmetaObject, PMOutputDevice* dev )
{
dev->callSerialization( object, tqmetaObject->superClass( ) );
}
void PMPov31SerPigmentList( const PMObject* object, const PMMetaObject* tqmetaObject, PMOutputDevice* dev )
{
dev->callSerialization( object, tqmetaObject->superClass( ) );
}
void PMPov31SerColorList( const PMObject* object, const PMMetaObject* tqmetaObject, PMOutputDevice* dev )
{
dev->callSerialization( object, tqmetaObject->superClass( ) );
}
void PMPov31SerDensityList( const PMObject* object, const PMMetaObject* tqmetaObject, PMOutputDevice* dev )
{
dev->callSerialization( object, tqmetaObject->superClass( ) );
}
void PMPov31SerNormalList( const PMObject* object, const PMMetaObject*, PMOutputDevice* dev )
{
PMNormalList* o = ( PMNormalList* ) object;
TQString str1;
switch( o->listType( ) )
{
case PMNormalList::ListPatternBrick:
dev->writeLine( "brick " );
break;
case PMNormalList::ListPatternChecker:
dev->writeLine( "checker " );
break;
case PMNormalList::ListPatternHexagon:
dev->writeLine( "hexagon " );
break;
}
if( o->depth( ) )
{
str1.setNum( o->depth( ) );
dev->writeLine( str1 );
}
if( o->listType( ) == PMNormalList::ListPatternBrick )
{
dev->writeLine( "brick_size " +
o->brickSize( ).serialize( ) );
str1.setNum( o->mortar( ) );
dev->writeLine( "mortar " + str1 );
}
}
void PMPov31SerLooksLike( const PMObject* object, const PMMetaObject* tqmetaObject, PMOutputDevice* dev )
{
dev->objectBegin( "looks_like" );
dev->writeName( object->name( ) );
dev->callSerialization( object, tqmetaObject->superClass( ) );
dev->objectEnd( );
}
void PMPov31SerMaterial( const PMObject* object, const PMMetaObject* tqmetaObject, PMOutputDevice* dev )
{
dev->objectBegin( "material" );
dev->callSerialization( object, tqmetaObject->superClass( ) );
dev->objectEnd( );
}
void PMPov31SerMaterialMap( const PMObject* object, const PMMetaObject* tqmetaObject, PMOutputDevice* dev )
{
PMMaterialMap* o = ( PMMaterialMap* ) object;
TQString str1;
dev->objectBegin( "material_map" );
switch( o->bitmapType( ) )
{
case PMMaterialMap::BitmapGif:
dev->writeLine( "gif" );
break;
case PMMaterialMap::BitmapTga:
dev->writeLine( "tga" );
break;
case PMMaterialMap::BitmapIff:
dev->writeLine( "iff" );
break;
case PMMaterialMap::BitmapPpm:
dev->writeLine( "ppm" );
break;
case PMMaterialMap::BitmapPgm:
dev->writeLine( "pgm" );
break;
case PMMaterialMap::BitmapPng:
dev->writeLine( "png" );
break;
case PMMaterialMap::BitmapJpeg:
dev->writeLine( "jpeg" );
break;
case PMMaterialMap::BitmapTiff:
dev->writeLine( "tiff" );
break;
case PMMaterialMap::BitmapSys:
dev->writeLine( "sys" );
break;
}
dev->writeLine( "\"" + o->bitmapFile( ) + "\"" );
if( o->isOnceEnabled( ) )
dev->writeLine( "once" );
switch( o->mapType( ) )
{
case PMMaterialMap::MapPlanar:
dev->writeLine( "map_type 0" );
break;
case PMMaterialMap::MapSpherical:
dev->writeLine( "map_type 1" );
break;
case PMMaterialMap::MapCylindrical:
dev->writeLine( "map_type 2" );
break;
case PMMaterialMap::MapToroidal:
dev->writeLine( "map_type 5" );
break;
}
switch( o->interpolateType( ) )
{
case PMMaterialMap::InterpolateBilinear:
dev->writeLine( "interpolate 2" );
break;
case PMMaterialMap::InterpolateNormalized:
dev->writeLine( "interpolate 4" );
break;
default:
break;
}
dev->callSerialization( object, tqmetaObject->superClass( ) );
dev->objectEnd( );
}
const int c_defaultMediaIntervals = 10;
const int c_defaultMediaSamplesMin = 1;
const int c_defaultMediaSamplesMax = 1;
const double c_defaultMediaConfidence = 0.9;
const double c_defaultMediaVariance = 0.0078125;
const double c_defaultMediaRatio = 0.9;
const double c_defaultMediaScatteringEccentricity = 0;
const double c_defaultMediaScatteringExtinction = 1.0;
void PMPov31SerMedia( const PMObject* object, const PMMetaObject* tqmetaObject, PMOutputDevice* dev )
{
PMMedia* o = ( PMMedia* ) object;
TQString str1;
TQString str2;
dev->objectBegin( "media" );
dev->callSerialization( object, tqmetaObject->superClass( ) );
if( o->intervals( ) != c_defaultMediaIntervals )
{
str1.setNum( o->intervals( ) );
dev->writeLine( "intervals " + str1 );
}
if( o->samplesMin( ) != c_defaultMediaSamplesMin ||
o->samplesMax( ) != c_defaultMediaSamplesMax )
{
str1.setNum( o->samplesMin( ) );
str2.setNum( o->samplesMax( ) );
dev->writeLine( "samples " + str1 + "," + str2 );
}
if( o->confidence( ) != c_defaultMediaConfidence )
{
str1.setNum( o->confidence( ) );
dev->writeLine( "confidence " + str1 );
}
if( o->variance( ) != c_defaultMediaVariance )
{
str1.setNum( o->variance( ) );
dev->writeLine( "variance " + str1 );
}
if( o->ratio( ) != c_defaultMediaRatio )
{
str1.setNum( o->ratio( ) );
dev->writeLine( "ratio " + str1 );
}
if( o->isAbsorptionEnabled( ) )
{
dev->writeLine( "absorption " + o->absorption( ).serialize( ) );
}
if( o->isEmissionEnabled( ) )
{
dev->writeLine( "emission " + o->emission( ).serialize( ) );
}
if( o->isScatteringEnabled( ) )
{
dev->objectBegin( "scattering" );
str1.setNum( o->scatteringType( ) );
dev->writeLine( str1 + ", " + o->scatteringColor( ).serialize( ) );
if( o->scatteringType( ) == 5 && o->scatteringEccentricity( )
!= c_defaultMediaScatteringEccentricity )
{
str1.setNum( o->scatteringEccentricity( ) );
dev->writeLine( "eccentricity " + str1 );
}
if( o->scatteringExtinction( ) != c_defaultMediaScatteringExtinction )
{
str1.setNum( o->scatteringExtinction( ) );
dev->writeLine( "extinction " + str1 );
}
dev->objectEnd( );
}
dev->objectEnd( );
}
void PMPov31SerNamedObject( const PMObject* object, const PMMetaObject* tqmetaObject, PMOutputDevice* dev )
{
dev->callSerialization( object, tqmetaObject->superClass( ) );
}
void PMPov31SerNormal( const PMObject* object, const PMMetaObject* tqmetaObject, PMOutputDevice* dev )
{
PMNormal* o = ( PMNormal* ) object;
TQString str1;
bool bObject = true;
if( o->parent( ) )
if( o->parent( )->type( ) == "NormalMap" )
bObject = false;
if( bObject )
dev->objectBegin( "normal" );
dev->callSerialization( object, tqmetaObject->superClass( ) );
if( o->isBumpSizeEnabled( ) )
{
str1.setNum( o->bumpSize( ) );
dev->writeLine( "bump_size " + str1 );
}
if( bObject )
dev->objectEnd( );
}
void PMPov31SerObjectLink( const PMObject* object, const PMMetaObject* tqmetaObject, PMOutputDevice* dev )
{
PMObjectLink* o = ( PMObjectLink* ) object;
bool writeComment = true;
if( o->linkedObject( ) )
{
if( o->linkedObject( )->firstChild( ) )
{
dev->objectBegin( "object" );
dev->writeName( object->name( ) );
dev->writeLine( o->linkedObject( )->id( ) );
dev->callSerialization( object, tqmetaObject->superClass( ) );
writeComment = false;
dev->objectEnd( );
}
}
if( writeComment )
{
TQString text;
text = o->name( );
if( text.isEmpty( ) )
text = o->description( );
dev->writeComment( TQString( "No prototype for %1" ).tqarg( text ) );
}
}
const int c_defaultPatternOctaves = 6;
const double c_defaultPatternOmega = 0.5;
const double c_defaultPatternLambda = 2.0;
void PMPov31SerPattern( const PMObject* object, const PMMetaObject*, PMOutputDevice* dev )
{
PMPattern* o = ( PMPattern* ) object;
TQString str;
// pattern type
switch( o->patternType( ) )
{
case PMPattern::PatternAgate:
dev->writeLine( "agate" );
break;
case PMPattern::PatternAverage:
dev->writeLine( "average" );
break;
case PMPattern::PatternBoxed:
dev->writeLine( "boxed" );
break;
case PMPattern::PatternBozo:
dev->writeLine( "bozo" );
break;
case PMPattern::PatternBumps:
dev->writeLine( "bumps" );
break;
case PMPattern::PatternCrackle:
dev->writeLine( "crackle" );
break;
case PMPattern::PatternCylindrical:
dev->writeLine( "cylindrical" );
break;
case PMPattern::PatternDensity:
dev->writeLine( "density_file df3 \"" + o->densityFile( ) + "\"");
break;
case PMPattern::PatternDents:
dev->writeLine( "dents" );
break;
case PMPattern::PatternGradient:
dev->writeLine( "gradient " + o->gradient( ).serialize( ) );
break;
case PMPattern::PatternGranite:
dev->writeLine( "granite" );
break;
case PMPattern::PatternLeopard:
dev->writeLine( "leopard" );
break;
case PMPattern::PatternMandel:
str.setNum( o->maxIterations( ) );
dev->writeLine( "mandel " + str );
break;
case PMPattern::PatternMarble:
dev->writeLine( "marble" );
break;
case PMPattern::PatternOnion:
dev->writeLine( "onion" );
break;
case PMPattern::PatternPlanar:
dev->writeLine( "planar" );
break;
case PMPattern::PatternQuilted:
dev->writeLine( "quilted" );
break;
case PMPattern::PatternRadial:
dev->writeLine( "radial" );
break;
case PMPattern::PatternRipples:
dev->writeLine( "ripples" );
break;
case PMPattern::PatternSpherical:
dev->writeLine( "spherical" );
break;
case PMPattern::PatternSpiral1:
str.setNum( o->spiralNumberArms( ) );
dev->writeLine( "spiral1 " + str );
break;
case PMPattern::PatternSpiral2:
str.setNum( o->spiralNumberArms( ) );
dev->writeLine( "spiral2 " + str );
break;
case PMPattern::PatternSpotted:
dev->writeLine( "spotted" );
break;
case PMPattern::PatternWaves:
dev->writeLine( "waves" );
break;
case PMPattern::PatternWood:
dev->writeLine( "wood" );
break;
case PMPattern::PatternWrinkles:
dev->writeLine( "wrinkles" );
break;
default:
break;
}
// depth
if( o->parent( ) )
{
if( o->depth( ) && o->parent( )->type( ) == "Normal" )
{
str.setNum( o->depth( ) );
dev->writeLine( str );
}
}
// modifiers
switch( o->patternType( ) )
{
case PMPattern::PatternAgate:
str.setNum( o->agateTurbulence( ) );
dev->writeLine( "agate_turb " + str );
break;
case PMPattern::PatternDensity:
str.setNum( o->densityInterpolate( ) );
dev->writeLine( "interpolate " + str );
break;
case PMPattern::PatternQuilted:
str.setNum( o->quiltControl0( ) );
dev->writeLine( "control0 " + str );
str.setNum( o->quiltControl1( ) );
dev->writeLine( "control1 " + str );
break;
default:
break;
}
if( o->isTurbulenceEnabled( ) )
{
dev->writeLine( "turbulence " + o->valueVector( ).serialize( ) );
if( o->octaves( ) != c_defaultPatternOctaves )
{
str.setNum( o->octaves( ) );
dev->writeLine( "octaves " + str );
}
if( o->omega( ) != c_defaultPatternOmega )
{
str.setNum( o->omega( ) );
dev->writeLine( "omega " + str );
}
if( o->lambda( ) != c_defaultPatternLambda )
{
str.setNum( o->lambda( ) );
dev->writeLine( "lambda " + str );
}
}
}
void PMPov31SerPigment( const PMObject* object, const PMMetaObject* tqmetaObject, PMOutputDevice* dev )
{
PMPigment* o = ( PMPigment* ) object;
bool bObject = true;
if( o->parent( ) )
if( o->parent( )->type( ) == "PigmentMap" )
bObject = false;
if( bObject )
dev->objectBegin( "pigment" );
dev->callSerialization( object, tqmetaObject->superClass( ) );
if( bObject )
dev->objectEnd( );
}
void PMPov31SerPlane( const PMObject* object, const PMMetaObject* tqmetaObject, PMOutputDevice* dev )
{
PMPlane* o = ( PMPlane* ) object;
dev->objectBegin( "plane" );
dev->writeName( object->name( ) );
TQString str1;
str1.setNum( o->distance( ) );
dev->writeLine( o->normal( ).serialize( ) + ", " + str1 );
dev->callSerialization( object, tqmetaObject->superClass( ) );
dev->objectEnd( );
}
void PMPov31SerPolynom( const PMObject* object, const PMMetaObject* tqmetaObject, PMOutputDevice* dev )
{
PMPolynom* o = ( PMPolynom* ) object;
PMVector coefficients = o->coefficients( );
if( o->polynomOrder( ) == 2 )
dev->objectBegin( "quadric" );
else if( o->polynomOrder( ) == 3 )
dev->objectBegin( "cubic" );
else if( o->polynomOrder( ) == 4 )
dev->objectBegin( "quartic" );
else
dev->objectBegin( "poly" );
dev->writeName( object->name( ) );
if( o->polynomOrder( ) == 2 )
{
dev->writeLine( TQString( "<%1, %2, %3>," ).tqarg( coefficients[0] )
.tqarg( coefficients[4] ).tqarg( coefficients[7] ) );
dev->writeLine( TQString( "<%1, %2, %3>," ).tqarg( coefficients[1] )
.tqarg( coefficients[2] ).tqarg( coefficients[5] ) );
dev->writeLine( TQString( "<%1, %2, %3>, %4" ).tqarg( coefficients[3] )
.tqarg( coefficients[6] ).tqarg( coefficients[8] )
.tqarg( coefficients[9] ) );
}
else
{
if( o->polynomOrder( ) > 4 )
dev->writeLine( TQString( "%1," ).tqarg( o->polynomOrder( ) ) );
int size = coefficients.size( );
int i;
TQString hlp;
dev->write( "<" );
for( i = 0; i < size; i++ )
{
hlp.setNum( coefficients[i] );
dev->write( hlp );
if( i != ( size - 1 ) )
{
dev->write( ", " );
if( ( ( i + 1 ) % 5 ) == 0 )
dev->writeLine( "" );
}
}
dev->writeLine( ">" );
if( o->sturm( ) )
dev->writeLine( "sturm" );
}
dev->callSerialization( object, tqmetaObject->superClass( ) );
dev->objectEnd( );
}
void PMPov31SerPovrayMatrix( const PMObject* object, const PMMetaObject*, PMOutputDevice* dev )
{
PMPovrayMatrix* o = ( PMPovrayMatrix* ) object;
dev->writeLine( TQString( "matrix < %1, %2, %3," ).tqarg( o->values( )[0] )
.tqarg( o->values( )[1] ).tqarg( o->values( )[2] ) );
dev->writeLine( TQString( " %1, %2, %3," ).tqarg( o->values( )[3] )
.tqarg( o->values( )[4] ).tqarg( o->values( )[5] ) );
dev->writeLine( TQString( " %1, %2, %3," ).tqarg( o->values( )[6] )
.tqarg( o->values( )[7] ).tqarg( o->values( )[8] ) );
dev->writeLine( TQString( " %1, %2, %3 >" ).tqarg( o->values( )[9] )
.tqarg( o->values( )[10] ).tqarg( o->values( )[11] ) );
}
void PMPov31SerPrism( const PMObject* object, const PMMetaObject* tqmetaObject, PMOutputDevice* dev )
{
PMPrism* o = ( PMPrism* ) object;
dev->objectBegin( "prism" );
dev->writeName( object->name( ) );
switch( o->splineType( ) )
{
case PMPrism::LinearSpline:
dev->writeLine( "linear_spline" );
break;
case PMPrism::QuadraticSpline:
dev->writeLine( "quadratic_spline" );
break;
case PMPrism::CubicSpline:
dev->writeLine( "cubic_spline" );
break;
case PMPrism::BezierSpline:
dev->writeLine( "bezier_spline" );
break;
}
switch( o->sweepType( ) )
{
case PMPrism::LinearSweep:
dev->writeLine( "linear_sweep" );
break;
case PMPrism::ConicSweep:
dev->writeLine( "conic_sweep" );
break;
}
dev->writeLine( TQString( "%1, %2," ).tqarg( o->height1( ) ).tqarg( o->height2( ) ) );
// count number of points
TQValueList< TQValueList<PMVector> > points = o->points( );
TQValueList< TQValueList<PMVector> >::ConstIterator spit = points.begin( );
int lines = 0;
for( ; spit != points.end( ); ++spit )
{
if( o->splineType( ) != PMPrism::BezierSpline )
lines += ( *spit ).count( ) + 1;
else
lines += ( *spit ).count( ) / 3 * 4;
}
dev->writeLine( TQString( "%1," ).tqarg( lines ) );
for( spit = points.begin( ); spit != points.end( ); ++spit )
{
bool first = true;
TQValueList<PMVector> fullPoints = o->expandedPoints( *spit );
TQValueList<PMVector>::ConstIterator it = fullPoints.begin( );
for( ; it != fullPoints.end( ); ++it )
{
if( !first )
dev->write( ", " );
dev->write( ( *it ).serialize( ) );
first = false;
}
TQValueList< TQValueList<PMVector> >::ConstIterator spit2 = spit;
spit2++;
if( spit2 != points.end( ) )
dev->write( "," );
dev->writeLine( "" );
}
if( o->open( ) )
dev->writeLine( "open" );
if( o->sturm( ) )
dev->writeLine( "sturm" );
dev->callSerialization( object, tqmetaObject->superClass( ) );
dev->objectEnd( );
}
void PMPov31SerQuickColor( const PMObject* object, const PMMetaObject*, PMOutputDevice* dev )
{
PMQuickColor* o = ( PMQuickColor* ) object;
dev->writeLine( "quick_color " + o->color( ).serialize( ) );
}
void PMPov31SerRainbow( const PMObject* object, const PMMetaObject* tqmetaObject, PMOutputDevice* dev )
{
PMRainbow* o = ( PMRainbow* ) object;
TQString str1;
dev->objectBegin( "rainbow" );
dev->callSerialization( object, tqmetaObject->superClass( ) );
if( o->isDirectionEnabled( ) )
dev->writeLine( "direction " + o->direction( ).serialize( ) );
if( o->isAngleEnabled( ) )
{
str1.setNum( o->angle( ) );
dev->writeLine( "angle " + str1 );
}
if( o->isWidthEnabled( ) )
{
str1.setNum( o->width( ) );
dev->writeLine( "width " + str1 );
}
if( o->isDistanceEnabled( ) )
{
str1.setNum( o->distance( ) );
dev->writeLine( "distance " + str1 );
}
if( o->isJitterEnabled( ) )
{
str1.setNum( o->jitter( ) );
dev->writeLine( "jitter " + str1 );
}
if( o->isUpEnabled( ) )
dev->writeLine( "up " + o->up( ).serialize( ) );
if( o->isArcAngleEnabled( ) )
{
str1.setNum( o->arcAngle( ) );
dev->writeLine( "arc_angle " + str1 );
}
if( o->isFalloffAngleEnabled( ) )
{
str1.setNum( o->falloffAngle( ) );
dev->writeLine( "falloff_angle " + str1 );
}
dev->objectEnd( );
}
void PMPov31SerRaw( const PMObject* object, const PMMetaObject*, PMOutputDevice* dev )
{
PMRaw* o = ( PMRaw* ) object;
dev->writeLine( "//*PMRawBegin" );
TQString tmp = o->code( );
TQTextStream str( &tmp, IO_ReadOnly );
while( !str.atEnd( ) )
dev->writeLine( str.readLine( ) );
dev->writeLine( "//*PMRawEnd" );
}
void PMPov31SerRotate( const PMObject* object, const PMMetaObject*, PMOutputDevice* dev )
{
PMRotate* o = ( PMRotate* ) object;
PMVector rotate = o->rotation( );
TQString vector;
TQTextStream str( &vector, IO_WriteOnly );
int i;
bool z[3];
for( i = 0; i < 3; i++ )
z[i] = approxZero( rotate[i] );
if( !z[0] && z[1] && z[2] )
{
str << "x*";
i = 0;
}
else if( z[0] && !z[1] && z[2] )
{
str << "y*";
i = 1;
}
else if( z[0] && z[1] && !z[2] )
{
str << "z*";
i = 2;
}
if( i < 3 )
{
if( rotate[i] > 0 )
str << rotate[i];
else
str << "(" << rotate[i] << ")";
}
else
{
str << '<';
for( i = 0; i < 3; i++ )
{
if( i > 0 )
str << ", ";
str << rotate[i];
}
str << '>';
}
dev->writeLine( "rotate " + vector );
}
void PMPov31SerScale( const PMObject* object, const PMMetaObject* , PMOutputDevice* dev )
{
PMScale* o = ( PMScale* ) object;
PMVector scale = o->scale( );
if( approx( scale[0], scale[1] ) &&
approx( scale[1], scale[2] ) )
dev->writeLine( TQString( "scale %1" ).tqarg( scale[0] ) );
else
dev->writeLine( "scale " + scale.serialize( ) );
}
void PMPov31SerScene( const PMObject* object, const PMMetaObject* tqmetaObject, PMOutputDevice* dev )
{
dev->callSerialization( object, tqmetaObject->superClass( ) );
}
void PMPov31SerSkySphere( const PMObject* object, const PMMetaObject* tqmetaObject, PMOutputDevice* dev )
{
dev->objectBegin( "sky_sphere" );
dev->callSerialization( object, tqmetaObject->superClass( ) );
dev->objectEnd( );
}
void PMPov31SerSlope( const PMObject* object, const PMMetaObject* , PMOutputDevice* dev )
{
PMSlope* o = ( PMSlope* ) object;
TQString str1,str2;
str1.setNum(o->height( ));
str2.setNum(o->slope( ));
dev->writeLine( "<" + str1 + ", " + str2 + ">" );
}
void PMPov31SerSolidColor( const PMObject* object, const PMMetaObject* , PMOutputDevice* dev )
{
PMSolidColor* o = ( PMSolidColor* ) object;
dev->writeLine( o->color( ).serialize( true ) );
}
void PMPov31SerSolidObject( const PMObject* object, const PMMetaObject* tqmetaObject, PMOutputDevice* dev )
{
PMSolidObject* o = ( PMSolidObject* ) object;
dev->callSerialization( object, tqmetaObject->superClass( ) );
switch( o->hollow( ) )
{
case PMTrue:
dev->writeLine( "hollow" );
break;
case PMFalse:
dev->writeLine( "hollow false" );
break;
case PMUnspecified:
break;
}
if( o->inverse( ) )
dev->writeLine( "inverse" );
}
void PMPov31SerSurfaceOfRevolution( const PMObject* object, const PMMetaObject* tqmetaObject, PMOutputDevice* dev )
{
PMSurfaceOfRevolution* o = ( PMSurfaceOfRevolution* ) object;
dev->objectBegin( "sor" );
dev->writeName( object->name( ) );
int num = o->points( ).count( );
dev->writeLine( TQString( "%1," ).tqarg( num ) );
bool first = true;
TQValueList<PMVector> points = o->points( );
TQValueList<PMVector>::ConstIterator it = points.begin( );
for( ; it != points.end( ); ++it )
{
if( !first )
dev->write( ", " );
dev->write( ( *it ).serialize( ) );
first = false;
}
dev->writeLine( "" );
if( o->open( ) )
dev->writeLine( "open" );
if( o->sturm( ) )
dev->writeLine( "sturm" );
dev->callSerialization( object, tqmetaObject->superClass( ) );
dev->objectEnd( );
}
void PMPov31SerSphere( const PMObject* object, const PMMetaObject* tqmetaObject, PMOutputDevice* dev )
{
PMSphere* o = ( PMSphere* ) object;
dev->objectBegin( "sphere" );
dev->writeName( object->name( ) );
TQString str;
str.setNum( o->radius( ) );
dev->writeLine( o->centre( ).serialize( ) + ", " + str );
dev->callSerialization( object, tqmetaObject->superClass( ) );
dev->objectEnd( );
}
void PMPov31SerSuperquadricEllipsoid( const PMObject* object, const PMMetaObject* tqmetaObject, PMOutputDevice* dev )
{
PMSuperquadricEllipsoid* o = ( PMSuperquadricEllipsoid* ) object;
dev->objectBegin( "superellipsoid" );
dev->writeName( object->name( ) );
dev->writeLine( TQString( "<%1, %2>" ).tqarg( o->eastWestExponent( ) )
.tqarg( o->northSouthExponent( ) ) );
dev->callSerialization( object, tqmetaObject->superClass( ) );
dev->objectEnd( );
}
void PMPov31SerText( const PMObject* object, const PMMetaObject* tqmetaObject, PMOutputDevice* dev )
{
PMText* o = ( PMText* ) object;
dev->objectBegin( "text" );
dev->writeName( object->name( ) );
dev->writeLine( TQString( "ttf \"" ) + o->font( ) + "\"" );
dev->writeLine( PMOutputDevice::escapeAndQuoteString( o->text( ) ) );
dev->writeLine( TQString( "%1, " ).tqarg( o->thickness( ) )
+ o->offset( ).serialize( ) );
dev->callSerialization( object, tqmetaObject->superClass( ) );
dev->objectEnd( );
}
void PMPov31SerTexture( const PMObject* object, const PMMetaObject* tqmetaObject, PMOutputDevice* dev )
{
PMTexture* o = ( PMTexture* ) object;
bool bObject = true;
if( o->parent( ) )
if( o->parent( )->type( ) == "TextureMap" )
bObject = false;
if( bObject )
dev->objectBegin( "texture" );
dev->callSerialization( object, tqmetaObject->superClass( ) );
if( bObject )
dev->objectEnd( );
}
void PMPov31SerTextureBase( const PMObject* object, const PMMetaObject* tqmetaObject, PMOutputDevice* dev )
{
PMTextureBase* o = ( PMTextureBase* ) object;
dev->writeName( object->name( ) );
PMDeclare* linkedObject = o->linkedObject( );
if( linkedObject)
{
if( linkedObject->firstChild( ) )
dev->writeLine( linkedObject->id( ) );
else
{
TQString text;
text = o->name( );
if( text.isEmpty( ) )
text = o->description( );
dev->writeComment( TQString( "No prototype for %1" ).tqarg( text ) );
}
}
dev->callSerialization( object, tqmetaObject->superClass( ) );
}
void PMPov31SerTextureMapBase( const PMObject* object, const PMMetaObject* , PMOutputDevice* dev )
{
PMTextureMapBase* o = ( PMTextureMapBase* ) object;
TQValueList<double> mapValues = o->mapValues( );
TQValueList<double>::ConstIterator it = mapValues.begin( );
PMObject* c = o->firstChild( );
double value = 0.0;
/* Take care of a possible link */
if( o->linkedObject( ) )
{
if( o->linkedObject( )->firstChild( ) )
dev->writeLine( o->linkedObject( )->id( ) );
else
{
TQString text;
text = o->name( );
if( text.isEmpty( ) )
text = o->description( );
dev->writeComment( TQString( "No prototype for %1" ).tqarg( text ) );
}
}
/* Serialize the map */
for( ; c; c = c->nextSibling( ) )
{
if( c->type( ) == o->mapType( ) )
{
value = 1.0;
if( it != mapValues.end( ) )
value = *it;
dev->write( TQString( "[ %1 " ).tqarg( value ) );
dev->serialize( c );
dev->writeLine( "]" );
++it;
}
}
}
void PMPov31SerTextureMap( const PMObject* object, const PMMetaObject* tqmetaObject, PMOutputDevice* dev )
{
dev->objectBegin( "texture_map" );
dev->callSerialization( object, tqmetaObject->superClass( ) );
dev->objectEnd( );
}
void PMPov31SerPigmentMap( const PMObject* object, const PMMetaObject* tqmetaObject, PMOutputDevice* dev )
{
dev->objectBegin( "pigment_map" );
dev->callSerialization( object, tqmetaObject->superClass( ) );
dev->objectEnd( );
}
void PMPov31SerColorMap( const PMObject* object, const PMMetaObject* tqmetaObject, PMOutputDevice* dev )
{
dev->objectBegin( "color_map" );
dev->callSerialization( object, tqmetaObject->superClass( ) );
dev->objectEnd( );
}
void PMPov31SerNormalMap( const PMObject* object, const PMMetaObject* tqmetaObject, PMOutputDevice* dev )
{
dev->objectBegin( "normal_map" );
dev->callSerialization( object, tqmetaObject->superClass( ) );
dev->objectEnd( );
}
void PMPov31SerSlopeMap( const PMObject* object, const PMMetaObject* tqmetaObject, PMOutputDevice* dev )
{
dev->objectBegin( "slope_map" );
dev->callSerialization( object, tqmetaObject->superClass( ) );
dev->objectEnd( );
}
void PMPov31SerDensityMap( const PMObject* object, const PMMetaObject* tqmetaObject, PMOutputDevice* dev )
{
dev->objectBegin( "density_map" );
dev->callSerialization( object, tqmetaObject->superClass( ) );
dev->objectEnd( );
}
void PMPov31SerTorus( const PMObject* object, const PMMetaObject* tqmetaObject, PMOutputDevice* dev )
{
PMTorus* o = ( PMTorus* ) object;
dev->objectBegin( "torus" );
dev->writeName( object->name( ) );
TQString strMinor;
TQString strMajor;
strMinor.setNum( o->minorRadius( ) );
strMajor.setNum( o->majorRadius( ) );
dev->writeLine(strMajor + ", " + strMinor);
if( o->sturm( ) )
dev->writeLine( TQString( "sturm" ) );
dev->callSerialization( object, tqmetaObject->superClass( ) );
dev->objectEnd( );
}
void PMPov31SerTranslate( const PMObject* object, const PMMetaObject* , PMOutputDevice* dev )
{
PMTranslate* o = ( PMTranslate* ) object;
TQString vector;
TQTextStream str( &vector, IO_WriteOnly );
int i;
bool z[3];
PMVector move = o->translation( );
for( i = 0; i < 3; i++ )
z[i] = approxZero( move[i] );
if( !z[0] && z[1] && z[2] )
{
str << "x*";
i = 0;
}
else if( z[0] && !z[1] && z[2] )
{
str << "y*";
i = 1;
}
else if( z[0] && z[1] && !z[2] )
{
str << "z*";
i = 2;
}
if( i < 3 )
{
if( move[i] > 0 )
str << move[i];
else
str << "(" << move[i] << ")";
}
else
{
str << '<';
for( i = 0; i < 3; i++ )
{
if( i > 0 )
str << ", ";
str << move[i];
}
str << '>';
}
dev->writeLine( "translate " + vector );
}
void PMPov31SerTriangle( const PMObject* object, const PMMetaObject* tqmetaObject, PMOutputDevice* dev )
{
PMTriangle* o = ( PMTriangle* ) object;
if( o->isSmoothTriangle( ) )
{
dev->objectBegin( "smooth_triangle" );
dev->writeName( object->name( ) );
dev->writeLine( o->point( 0 ).serialize( ) + ", " + o->normal( 0 ).serialize( ) + "," );
dev->writeLine( o->point( 1 ).serialize( ) + ", " + o->normal( 1 ).serialize( ) + "," );
dev->writeLine( o->point( 2 ).serialize( ) + ", " + o->normal( 2 ).serialize( ) );
dev->callSerialization( object, tqmetaObject->superClass( ) );
dev->objectEnd( );
}
else
{
dev->objectBegin( "triangle" );
dev->writeName( object->name( ) );
dev->writeLine( o->point( 0 ).serialize( ) + ", " + o->point( 1 ).serialize( )
+ ", " + o->point( 2 ).serialize( ) );
dev->callSerialization( object, tqmetaObject->superClass( ) );
dev->objectEnd( );
}
}
const PMVector c_warpDirectionDefault = PMVector( 1.0, 0.0, 0.0 );
const PMVector c_warpOffsetDefault = PMVector( 0.0, 0.0, 0.0 );
const PMVector c_warpFlipDefault = PMVector( 0.0, 0.0, 0.0 );
const PMVector c_warpLocationDefault = PMVector( 0.0, 0.0, 0.0 );
const double c_warpRadiusDefault = 0;
const double c_warpStrengthDefault = 0;
const double c_warpFalloffDefault = 0;
const bool c_warpInverseDefault = false;
const PMVector c_warpRepeatDefault = PMVector( 0.0, 0.0, 0.0 );
const PMVector c_warpTurbulenceDefault = PMVector( 0.0, 0.0, 0.0 );
const PMVector c_warpValueVectorDefault = PMVector( 0.0, 0.0, 0.0 );
const int c_warpOctavesDefault = 6;
const double c_warpOmegaDefault = 0.5;
const double c_warpLambdaDefault = 2.0;
void PMPov31SerWarp( const PMObject* object, const PMMetaObject* , PMOutputDevice* dev )
{
PMWarp* o = ( PMWarp* ) object;
TQString str1;
dev->objectBegin( "warp" );
switch( o->warpType( ) )
{
case PMWarp::Repeat:
dev->writeLine( "repeat" );
dev->writeLine( o->direction( ).serialize( ) );
dev->writeLine( "offset " + o->offset( ).serialize( ) );
dev->writeLine( "flip " + o->flip( ).serialize( ) );
break;
case PMWarp::BlackHole:
dev->writeLine( "black_hole" );
dev->writeLine( o->location( ).serialize( ) );
str1.setNum(o->radius( ));
dev->writeLine( ", " + str1 );
if( o->strength( ) != c_warpStrengthDefault )
{
str1.setNum( o->strength( ));
dev->writeLine( "strength " + str1 );
}
if( o->falloff( ) != c_warpFalloffDefault )
{
str1.setNum( o->falloff( ));
dev->writeLine( "falloff " + str1 );
}
if( o->inverse( ) != c_warpInverseDefault )
{
if( o->inverse( ) ) dev->writeLine( "inverse" );
}
if( o->repeat( ) != c_warpRepeatDefault )
{
dev->writeLine( "repeat " + o->repeat( ).serialize( ) );
}
if( o->turbulence( ) != c_warpTurbulenceDefault )
{
dev->writeLine( "turbulence " + o->turbulence( ).serialize( ) );
}
break;
case PMWarp::Turbulence:
dev->writeLine( "turbulence " + o->valueVector( ).serialize( ) );
if( o->octaves( ) != c_warpOctavesDefault )
{
str1.setNum(o->octaves( ));
dev->writeLine( "octaves " + str1 );
}
if( o->omega( ) != c_warpOmegaDefault )
{
str1.setNum( o->omega( ) );
dev->writeLine( "omega " + str1 );
}
if( o->lambda( ) != c_warpLambdaDefault )
{
str1.setNum( o->lambda( ) );
dev->writeLine( "lambda " + str1 );
}
break;
default:
break;
}
dev->objectEnd( );
}
void PMPov31SerDetailObject( const PMObject* object, const PMMetaObject* tqmetaObject, PMOutputDevice* dev )
{
dev->callSerialization( object, tqmetaObject->superClass( ) );
}