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/* -*- Mode: C++; tab-width: 4; indent-tabs-mode: nil; c-basic-offset: 4 -*- */
/*
* This file is part of the LibreOffice project.
*
* This Source Code Form is subject to the terms of the Mozilla Public
* License, v. 2.0. If a copy of the MPL was not distributed with this
* file, You can obtain one at http://mozilla.org/MPL/2.0/.
*
* This file incorporates work covered by the following license notice:
*
* Licensed to the Apache Software Foundation (ASF) under one or more
* contributor license agreements. See the NOTICE file distributed
* with this work for additional information regarding copyright
* ownership. The ASF licenses this file to you under the Apache
* License, Version 2.0 (the "License"); you may not use this file
* except in compliance with the License. You may obtain a copy of
* the License at http://www.apache.org/licenses/LICENSE-2.0 .
*/
#include <processor3d/zbufferprocessor3d.hxx>
#include <basegfx/raster/bzpixelraster.hxx>
#include <basegfx/raster/rasterconvert3d.hxx>
#include <drawinglayer/attribute/materialattribute3d.hxx>
#include <texture/texture.hxx>
#include <basegfx/polygon/b3dpolygon.hxx>
#include <basegfx/polygon/b3dpolypolygon.hxx>
#include <basegfx/polygon/b3dpolygontools.hxx>
#include <basegfx/polygon/b3dpolypolygontools.hxx>
#include <drawinglayer/attribute/sdrlightingattribute3d.hxx>
#include <o3tl/safeint.hxx>
#include <svtools/optionsdrawinglayer.hxx>
using namespace com::sun::star;
class ZBufferRasterConverter3D : public basegfx::RasterConverter3D
{
private:
const drawinglayer::processor3d::DefaultProcessor3D& mrProcessor;
basegfx::BZPixelRaster& mrBuffer;
// interpolators for a single line span
basegfx::ip_single maIntZ;
basegfx::ip_triple maIntColor;
basegfx::ip_triple maIntNormal;
basegfx::ip_double maIntTexture;
basegfx::ip_triple maIntInvTexture;
// current material to use for rasterconversion
const drawinglayer::attribute::MaterialAttribute3D* mpCurrentMaterial;
// some boolean flags for line span interpolator usages
bool mbModifyColor : 1;
bool mbUseTex : 1;
bool mbHasTexCoor : 1;
bool mbHasInvTexCoor : 1;
bool mbUseNrm : 1;
bool mbUseCol : 1;
void getTextureCoor(basegfx::B2DPoint& rTarget) const
{
if(mbHasTexCoor)
{
rTarget.setX(maIntTexture.getX().getVal());
rTarget.setY(maIntTexture.getY().getVal());
}
else if(mbHasInvTexCoor)
{
const double fZFactor(maIntInvTexture.getZ().getVal());
const double fInvZFactor(basegfx::fTools::equalZero(fZFactor) ? 1.0 : 1.0 / fZFactor);
rTarget.setX(maIntInvTexture.getX().getVal() * fInvZFactor);
rTarget.setY(maIntInvTexture.getY().getVal() * fInvZFactor);
}
}
void incrementLineSpanInterpolators(double fStep)
{
maIntZ.increment(fStep);
if(mbUseTex)
{
if(mbHasTexCoor)
{
maIntTexture.increment(fStep);
}
else if(mbHasInvTexCoor)
{
maIntInvTexture.increment(fStep);
}
}
if(mbUseNrm)
{
maIntNormal.increment(fStep);
}
if(mbUseCol)
{
maIntColor.increment(fStep);
}
}
double decideColorAndOpacity(basegfx::BColor& rColor) const
{
// init values with full opacity and material color
OSL_ENSURE(nullptr != mpCurrentMaterial, "CurrentMaterial not set (!)");
double fOpacity(1.0);
rColor = mpCurrentMaterial->getColor();
if(mbUseTex)
{
basegfx::B2DPoint aTexCoor(0.0, 0.0);
getTextureCoor(aTexCoor);
if(mrProcessor.getGeoTexSvx())
{
// calc color in spot. This may also set to invisible already when
// e.g. bitmap textures have transparent parts
mrProcessor.getGeoTexSvx()->modifyBColor(aTexCoor, rColor, fOpacity);
}
if(basegfx::fTools::more(fOpacity, 0.0) && mrProcessor.getTransparenceGeoTexSvx())
{
// calc opacity. Object has a 2nd texture, a transparence texture
mrProcessor.getTransparenceGeoTexSvx()->modifyOpacity(aTexCoor, fOpacity);
}
}
if(basegfx::fTools::more(fOpacity, 0.0))
{
if(mrProcessor.getGeoTexSvx())
{
if(mbUseNrm)
{
// blend texture with phong
rColor = mrProcessor.getSdrLightingAttribute().solveColorModel(
basegfx::B3DVector(maIntNormal.getX().getVal(), maIntNormal.getY().getVal(), maIntNormal.getZ().getVal()),
rColor,
mpCurrentMaterial->getSpecular(),
mpCurrentMaterial->getEmission(),
mpCurrentMaterial->getSpecularIntensity());
}
else if(mbUseCol)
{
// blend texture with gouraud
basegfx::BColor aBlendColor(maIntColor.getX().getVal(), maIntColor.getY().getVal(), maIntColor.getZ().getVal());
rColor *= aBlendColor;
}
else if(mrProcessor.getModulate())
{
// blend texture with single material color
rColor *= mpCurrentMaterial->getColor();
}
}
else
{
if(mbUseNrm)
{
// modify color with phong
rColor = mrProcessor.getSdrLightingAttribute().solveColorModel(
basegfx::B3DVector(maIntNormal.getX().getVal(), maIntNormal.getY().getVal(), maIntNormal.getZ().getVal()),
rColor,
mpCurrentMaterial->getSpecular(),
mpCurrentMaterial->getEmission(),
mpCurrentMaterial->getSpecularIntensity());
}
else if(mbUseCol)
{
// modify color with gouraud
rColor.setRed(maIntColor.getX().getVal());
rColor.setGreen(maIntColor.getY().getVal());
rColor.setBlue(maIntColor.getZ().getVal());
}
}
if(mbModifyColor)
{
rColor = mrProcessor.getBColorModifierStack().getModifiedColor(rColor);
}
}
return fOpacity;
}
void setupLineSpanInterpolators(const basegfx::RasterConversionLineEntry3D& rA, const basegfx::RasterConversionLineEntry3D& rB)
{
// get inverse XDelta
const double xInvDelta(1.0 / (rB.getX().getVal() - rA.getX().getVal()));
// prepare Z-interpolator
const double fZA(rA.getZ().getVal());
const double fZB(rB.getZ().getVal());
maIntZ = basegfx::ip_single(fZA, (fZB - fZA) * xInvDelta);
// get bools and init other interpolators on demand accordingly
mbModifyColor = mrProcessor.getBColorModifierStack().count();
mbHasTexCoor = SCANLINE_EMPTY_INDEX != rA.getTextureIndex() && SCANLINE_EMPTY_INDEX != rB.getTextureIndex();
mbHasInvTexCoor = SCANLINE_EMPTY_INDEX != rA.getInverseTextureIndex() && SCANLINE_EMPTY_INDEX != rB.getInverseTextureIndex();
const bool bTextureActive(mrProcessor.getGeoTexSvx() || mrProcessor.getTransparenceGeoTexSvx());
mbUseTex = bTextureActive && (mbHasTexCoor || mbHasInvTexCoor || mrProcessor.getSimpleTextureActive());
const bool bUseColorTex(mbUseTex && mrProcessor.getGeoTexSvx());
const bool bNeedNrmOrCol(!bUseColorTex || mrProcessor.getModulate());
mbUseNrm = bNeedNrmOrCol && SCANLINE_EMPTY_INDEX != rA.getNormalIndex() && SCANLINE_EMPTY_INDEX != rB.getNormalIndex();
mbUseCol = !mbUseNrm && bNeedNrmOrCol && SCANLINE_EMPTY_INDEX != rA.getColorIndex() && SCANLINE_EMPTY_INDEX != rB.getColorIndex();
if(mbUseTex)
{
if(mbHasTexCoor)
{
const basegfx::ip_double& rTA(getTextureInterpolators()[rA.getTextureIndex()]);
const basegfx::ip_double& rTB(getTextureInterpolators()[rB.getTextureIndex()]);
maIntTexture = basegfx::ip_double(
rTA.getX().getVal(), (rTB.getX().getVal() - rTA.getX().getVal()) * xInvDelta,
rTA.getY().getVal(), (rTB.getY().getVal() - rTA.getY().getVal()) * xInvDelta);
}
else if(mbHasInvTexCoor)
{
const basegfx::ip_triple& rITA(getInverseTextureInterpolators()[rA.getInverseTextureIndex()]);
const basegfx::ip_triple& rITB(getInverseTextureInterpolators()[rB.getInverseTextureIndex()]);
maIntInvTexture = basegfx::ip_triple(
rITA.getX().getVal(), (rITB.getX().getVal() - rITA.getX().getVal()) * xInvDelta,
rITA.getY().getVal(), (rITB.getY().getVal() - rITA.getY().getVal()) * xInvDelta,
rITA.getZ().getVal(), (rITB.getZ().getVal() - rITA.getZ().getVal()) * xInvDelta);
}
}
if(mbUseNrm)
{
const basegfx::ip_triple& rNA(getNormalInterpolators()[rA.getNormalIndex()]);
const basegfx::ip_triple& rNB(getNormalInterpolators()[rB.getNormalIndex()]);
maIntNormal = basegfx::ip_triple(
rNA.getX().getVal(), (rNB.getX().getVal() - rNA.getX().getVal()) * xInvDelta,
rNA.getY().getVal(), (rNB.getY().getVal() - rNA.getY().getVal()) * xInvDelta,
rNA.getZ().getVal(), (rNB.getZ().getVal() - rNA.getZ().getVal()) * xInvDelta);
}
if(mbUseCol)
{
const basegfx::ip_triple& rCA(getColorInterpolators()[rA.getColorIndex()]);
const basegfx::ip_triple& rCB(getColorInterpolators()[rB.getColorIndex()]);
maIntColor = basegfx::ip_triple(
rCA.getX().getVal(), (rCB.getX().getVal() - rCA.getX().getVal()) * xInvDelta,
rCA.getY().getVal(), (rCB.getY().getVal() - rCA.getY().getVal()) * xInvDelta,
rCA.getZ().getVal(), (rCB.getZ().getVal() - rCA.getZ().getVal()) * xInvDelta);
}
}
virtual void processLineSpan(const basegfx::RasterConversionLineEntry3D& rA, const basegfx::RasterConversionLineEntry3D& rB, sal_Int32 nLine, sal_uInt32 nSpanCount) override;
public:
ZBufferRasterConverter3D(basegfx::BZPixelRaster& rBuffer, const drawinglayer::processor3d::ZBufferProcessor3D& rProcessor)
: mrProcessor(rProcessor),
mrBuffer(rBuffer),
mpCurrentMaterial(nullptr),
mbModifyColor(false),
mbUseTex(false),
mbHasTexCoor(false),
mbHasInvTexCoor(false),
mbUseNrm(false),
mbUseCol(false)
{}
void setCurrentMaterial(const drawinglayer::attribute::MaterialAttribute3D& rMaterial)
{
mpCurrentMaterial = &rMaterial;
}
};
void ZBufferRasterConverter3D::processLineSpan(const basegfx::RasterConversionLineEntry3D& rA, const basegfx::RasterConversionLineEntry3D& rB, sal_Int32 nLine, sal_uInt32 nSpanCount)
{
if(nSpanCount & 0x0001)
return;
if(nLine < 0 || o3tl::make_unsigned(nLine) >= mrBuffer.getHeight())
return;
sal_uInt32 nXA(std::min(mrBuffer.getWidth(), static_cast<sal_uInt32>(std::max(sal_Int32(0), basegfx::fround(rA.getX().getVal())))));
const sal_uInt32 nXB(std::min(mrBuffer.getWidth(), static_cast<sal_uInt32>(std::max(sal_Int32(0), basegfx::fround(rB.getX().getVal())))));
if(nXA >= nXB)
return;
// prepare the span interpolators
setupLineSpanInterpolators(rA, rB);
// bring span interpolators to start condition by incrementing with the possible difference of
// clamped and non-clamped XStart. Interpolators are setup relying on double precision
// X-values, so that difference is the correct value to compensate for possible clampings
incrementLineSpanInterpolators(static_cast<double>(nXA) - rA.getX().getVal());
// prepare scanline index
sal_uInt32 nScanlineIndex(mrBuffer.getIndexFromXY(nXA, static_cast<sal_uInt32>(nLine)));
basegfx::BColor aNewColor;
while(nXA < nXB)
{
// early-test Z values if we need to do anything at all
const double fNewZ(std::clamp(maIntZ.getVal(), 0.0, 65535.0));
const sal_uInt16 nNewZ(static_cast< sal_uInt16 >(fNewZ));
sal_uInt16& rOldZ(mrBuffer.getZ(nScanlineIndex));
if(nNewZ > rOldZ)
{
// detect color and opacity for this pixel
const sal_uInt16 nOpacity(std::max(sal_Int16(0), static_cast< sal_Int16 >(decideColorAndOpacity(aNewColor) * 255.0)));
if(nOpacity > 0)
{
// avoid color overrun
aNewColor.clamp();
if(nOpacity >= 0x00ff)
{
// full opacity (not transparent), set z and color
rOldZ = nNewZ;
mrBuffer.getBPixel(nScanlineIndex) = basegfx::BPixel(aNewColor, 0xff);
}
else
{
basegfx::BPixel& rDest = mrBuffer.getBPixel(nScanlineIndex);
if(rDest.getAlpha())
{
// mix new color by using
// color' = color * (1 - opacity) + newcolor * opacity
const sal_uInt16 nTransparence(255 - nOpacity);
rDest.setRed(static_cast<sal_uInt8>(((rDest.getRed() * nTransparence) + (static_cast<sal_uInt16>(255.0 * aNewColor.getRed()) * nOpacity)) >> 8));
rDest.setGreen(static_cast<sal_uInt8>(((rDest.getGreen() * nTransparence) + (static_cast<sal_uInt16>(255.0 * aNewColor.getGreen()) * nOpacity)) >> 8));
rDest.setBlue(static_cast<sal_uInt8>(((rDest.getBlue() * nTransparence) + (static_cast<sal_uInt16>(255.0 * aNewColor.getBlue()) * nOpacity)) >> 8));
if(255 != rDest.getAlpha())
{
// both are transparent, mix new opacity by using
// opacity = newopacity * (1 - oldopacity) + oldopacity
rDest.setAlpha(static_cast<sal_uInt8>((nOpacity * (255 - rDest.getAlpha())) >> 8) + rDest.getAlpha());
}
}
else
{
// dest is unused, set color
rDest = basegfx::BPixel(aNewColor, static_cast<sal_uInt8>(nOpacity));
}
}
}
}
// increments
nScanlineIndex++;
nXA++;
incrementLineSpanInterpolators(1.0);
}
}
// helper class to buffer output for transparent rasterprimitives (filled areas
// and lines) until the end of processing. To ensure correct transparent
// visualisation, ZBuffers require to not set Z and to mix with the transparent
// color. If transparent rasterprimitives overlap, it gets necessary to
// paint transparent rasterprimitives from back to front to ensure that the
// mixing happens from back to front. For that purpose, transparent
// rasterprimitives are held in this class during the processing run, remember
// all data and will be rendered
class RasterPrimitive3D
{
private:
std::shared_ptr< drawinglayer::texture::GeoTexSvx > mpGeoTexSvx;
std::shared_ptr< drawinglayer::texture::GeoTexSvx > mpTransparenceGeoTexSvx;
drawinglayer::attribute::MaterialAttribute3D maMaterial;
basegfx::B3DPolyPolygon maPolyPolygon;
double mfCenterZ;
bool mbModulate : 1;
bool mbFilter : 1;
bool mbSimpleTextureActive : 1;
bool mbIsLine : 1;
public:
RasterPrimitive3D(
const std::shared_ptr< drawinglayer::texture::GeoTexSvx >& pGeoTexSvx,
const std::shared_ptr< drawinglayer::texture::GeoTexSvx >& pTransparenceGeoTexSvx,
const drawinglayer::attribute::MaterialAttribute3D& rMaterial,
const basegfx::B3DPolyPolygon& rPolyPolygon,
bool bModulate,
bool bFilter,
bool bSimpleTextureActive,
bool bIsLine)
: mpGeoTexSvx(pGeoTexSvx),
mpTransparenceGeoTexSvx(pTransparenceGeoTexSvx),
maMaterial(rMaterial),
maPolyPolygon(rPolyPolygon),
mfCenterZ(basegfx::utils::getRange(rPolyPolygon).getCenter().getZ()),
mbModulate(bModulate),
mbFilter(bFilter),
mbSimpleTextureActive(bSimpleTextureActive),
mbIsLine(bIsLine)
{
}
bool operator<(const RasterPrimitive3D& rComp) const
{
return mfCenterZ < rComp.mfCenterZ;
}
const std::shared_ptr< drawinglayer::texture::GeoTexSvx >& getGeoTexSvx() const { return mpGeoTexSvx; }
const std::shared_ptr< drawinglayer::texture::GeoTexSvx >& getTransparenceGeoTexSvx() const { return mpTransparenceGeoTexSvx; }
const drawinglayer::attribute::MaterialAttribute3D& getMaterial() const { return maMaterial; }
const basegfx::B3DPolyPolygon& getPolyPolygon() const { return maPolyPolygon; }
bool getModulate() const { return mbModulate; }
bool getFilter() const { return mbFilter; }
bool getSimpleTextureActive() const { return mbSimpleTextureActive; }
bool getIsLine() const { return mbIsLine; }
};
namespace drawinglayer::processor3d
{
void ZBufferProcessor3D::rasterconvertB3DPolygon(const attribute::MaterialAttribute3D& rMaterial, const basegfx::B3DPolygon& rHairline) const
{
if(getTransparenceCounter())
{
// transparent output; record for later sorting and painting from
// back to front
maRasterPrimitive3Ds.push_back(RasterPrimitive3D(
getGeoTexSvx(),
getTransparenceGeoTexSvx(),
rMaterial,
basegfx::B3DPolyPolygon(rHairline),
getModulate(),
getFilter(),
getSimpleTextureActive(),
true));
}
else
{
// do rasterconversion
mpZBufferRasterConverter3D->setCurrentMaterial(rMaterial);
if(mnAntiAlialize > 1)
{
const bool bForceLineSnap(SvtOptionsDrawinglayer::IsAntiAliasing() && SvtOptionsDrawinglayer::IsSnapHorVerLinesToDiscrete());
if(bForceLineSnap)
{
basegfx::B3DHomMatrix aTransform;
basegfx::B3DPolygon aSnappedHairline(rHairline);
const double fScaleDown(1.0 / mnAntiAlialize);
const double fScaleUp(mnAntiAlialize);
// take oversampling out
aTransform.scale(fScaleDown, fScaleDown, 1.0);
aSnappedHairline.transform(aTransform);
// snap to integer
aSnappedHairline = basegfx::utils::snapPointsOfHorizontalOrVerticalEdges(aSnappedHairline);
// add oversampling again
aTransform.identity();
aTransform.scale(fScaleUp, fScaleUp, 1.0);
aSnappedHairline.transform(aTransform);
mpZBufferRasterConverter3D->rasterconvertB3DPolygon(aSnappedHairline, mnStartLine, mnStopLine, mnAntiAlialize);
}
else
{
mpZBufferRasterConverter3D->rasterconvertB3DPolygon(rHairline, mnStartLine, mnStopLine, mnAntiAlialize);
}
}
else
{
mpZBufferRasterConverter3D->rasterconvertB3DPolygon(rHairline, mnStartLine, mnStopLine, 1);
}
}
}
void ZBufferProcessor3D::rasterconvertB3DPolyPolygon(const attribute::MaterialAttribute3D& rMaterial, const basegfx::B3DPolyPolygon& rFill) const
{
if(getTransparenceCounter())
{
// transparent output; record for later sorting and painting from
// back to front
maRasterPrimitive3Ds.push_back(RasterPrimitive3D(
getGeoTexSvx(),
getTransparenceGeoTexSvx(),
rMaterial,
rFill,
getModulate(),
getFilter(),
getSimpleTextureActive(),
false));
}
else
{
mpZBufferRasterConverter3D->setCurrentMaterial(rMaterial);
mpZBufferRasterConverter3D->rasterconvertB3DPolyPolygon(rFill, &maInvEyeToView, mnStartLine, mnStopLine);
}
}
ZBufferProcessor3D::ZBufferProcessor3D(
const geometry::ViewInformation3D& rViewInformation3D,
const attribute::SdrSceneAttribute& rSdrSceneAttribute,
const attribute::SdrLightingAttribute& rSdrLightingAttribute,
const basegfx::B2DRange& rVisiblePart,
sal_uInt16 nAntiAlialize,
double fFullViewSizeX,
double fFullViewSizeY,
basegfx::BZPixelRaster& rBZPixelRaster,
sal_uInt32 nStartLine,
sal_uInt32 nStopLine)
: DefaultProcessor3D(rViewInformation3D, rSdrSceneAttribute, rSdrLightingAttribute),
mnAntiAlialize(nAntiAlialize),
mnStartLine(nStartLine),
mnStopLine(nStopLine)
{
// create DeviceToView for Z-Buffer renderer since Z is handled
// different from standard 3D transformations (Z is mirrored). Also
// the transformation includes the step from unit device coordinates
// to discrete units ([-1.0 .. 1.0] -> [minDiscrete .. maxDiscrete]
basegfx::B3DHomMatrix aDeviceToView;
{
// step one:
//
// bring from [-1.0 .. 1.0] in X,Y and Z to [0.0 .. 1.0]. Also
// necessary to
// - flip Y due to screen orientation
// - flip Z due to Z-Buffer orientation from back to front
aDeviceToView.scale(0.5, -0.5, -0.5);
aDeviceToView.translate(0.5, 0.5, 0.5);
}
{
// step two:
//
// bring from [0.0 .. 1.0] in X,Y and Z to view coordinates
//
// #i102611#
// also: scale Z to [1.5 .. 65534.5]. Normally, a range of [0.0 .. 65535.0]
// could be used, but a 'unused' value is needed, so '0' is used what reduces
// the range to [1.0 .. 65535.0]. It has also shown that small numerical errors
// (smaller as basegfx::fTools::mfSmallValue, which is 0.000000001) happen.
// Instead of checking those by basegfx::fTools methods which would cost
// runtime, just add another 0.5 tolerance to the start and end of the Z-Buffer
// range, thus resulting in [1.5 .. 65534.5]
const double fMaxZDepth(65533.0);
aDeviceToView.translate(-rVisiblePart.getMinX(), -rVisiblePart.getMinY(), 0.0);
if(mnAntiAlialize)
aDeviceToView.scale(fFullViewSizeX * mnAntiAlialize, fFullViewSizeY * mnAntiAlialize, fMaxZDepth);
else
aDeviceToView.scale(fFullViewSizeX, fFullViewSizeY, fMaxZDepth);
aDeviceToView.translate(0.0, 0.0, 1.5);
}
// update local ViewInformation3D with own DeviceToView
const geometry::ViewInformation3D aNewViewInformation3D(
getViewInformation3D().getObjectTransformation(),
getViewInformation3D().getOrientation(),
getViewInformation3D().getProjection(),
aDeviceToView,
getViewInformation3D().getViewTime(),
getViewInformation3D().getExtendedInformationSequence());
updateViewInformation(aNewViewInformation3D);
// prepare inverse EyeToView transformation. This can be done in constructor
// since changes in object transformations when processing TransformPrimitive3Ds
// do not influence this prepared partial transformation
maInvEyeToView = getViewInformation3D().getDeviceToView() * getViewInformation3D().getProjection();
maInvEyeToView.invert();
// prepare maRasterRange
maRasterRange.reset();
maRasterRange.expand(basegfx::B2DPoint(0.0, nStartLine));
maRasterRange.expand(basegfx::B2DPoint(rBZPixelRaster.getWidth(), nStopLine));
// create the raster converter
mpZBufferRasterConverter3D.reset( new ZBufferRasterConverter3D(rBZPixelRaster, *this) );
}
ZBufferProcessor3D::~ZBufferProcessor3D()
{
mpZBufferRasterConverter3D.reset();
if(!maRasterPrimitive3Ds.empty())
{
OSL_FAIL("ZBufferProcessor3D: destructed, but there are unrendered transparent geometries. Use ZBufferProcessor3D::finish() to render these (!)");
}
}
void ZBufferProcessor3D::finish()
{
if(maRasterPrimitive3Ds.empty())
return;
// there are transparent rasterprimitives
const sal_uInt32 nSize(maRasterPrimitive3Ds.size());
if(nSize > 1)
{
// sort them from back to front
std::sort(maRasterPrimitive3Ds.begin(), maRasterPrimitive3Ds.end());
}
for(sal_uInt32 a(0); a < nSize; a++)
{
// paint each one by setting the remembered data and calling
// the render method
const RasterPrimitive3D& rCandidate = maRasterPrimitive3Ds[a];
mpGeoTexSvx = rCandidate.getGeoTexSvx();
mpTransparenceGeoTexSvx = rCandidate.getTransparenceGeoTexSvx();
mbModulate = rCandidate.getModulate();
mbFilter = rCandidate.getFilter();
mbSimpleTextureActive = rCandidate.getSimpleTextureActive();
if(rCandidate.getIsLine())
{
rasterconvertB3DPolygon(
rCandidate.getMaterial(),
rCandidate.getPolyPolygon().getB3DPolygon(0));
}
else
{
rasterconvertB3DPolyPolygon(
rCandidate.getMaterial(),
rCandidate.getPolyPolygon());
}
}
// delete them to signal the destructor that all is done and
// to allow asserting there
maRasterPrimitive3Ds.clear();
}
} // end of namespace
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