void setPolytope(osg::Polytope& polytope, osg::Plane& referencePlane)
        {
            _referencePlane = referencePlane;

            const PlaneMask currentMask = polytope.getCurrentMask();
            PlaneMask selector_mask = 0x1;

            const PlaneList& planeList = polytope.getPlaneList();
            unsigned int numActivePlanes = 0;

            PlaneList::const_iterator itr;
            for(itr=planeList.begin(); itr!=planeList.end(); ++itr)
            {
                if (currentMask&selector_mask) ++numActivePlanes;
                selector_mask <<= 1;
            }

            _plane_mask = 0x0;
            _planes.clear();
            _planes.reserve(numActivePlanes);
            _lines.clear();

            selector_mask=0x1;
            for(itr=planeList.begin(); itr!=planeList.end(); ++itr)
            {
                if (currentMask&selector_mask)
                {
                    _planes.push_back(*itr);
                    _plane_mask <<= 1;
                    _plane_mask |= 0x1;
                }
                selector_mask <<= 1;
            }
        }
void ComputeBoundsVisitor::getPolytope(osg::Polytope& polytope, float margin) const
{
    float delta = _bb.radius()*margin;
    polytope.add( osg::Plane(0.0, 0.0, 1.0, -(_bb.zMin()-delta)) );
    polytope.add( osg::Plane(0.0, 0.0, -1.0, (_bb.zMax()+delta)) );

    polytope.add( osg::Plane(1.0, 0.0, 0.0, -(_bb.xMin()-delta)) );
    polytope.add( osg::Plane(-1.0, 0.0, 0.0, (_bb.xMax()+delta)) );

    polytope.add( osg::Plane(0.0, 1.0, 0.0, -(_bb.yMin()-delta)) );
    polytope.add( osg::Plane(0.0, -1.0, 0.0, (_bb.yMax()+delta)) );
}
Exemplo n.º 3
0
bool ossimPlanetBoundingBox::intersects(const osg::Polytope& frustum)const
{
   const osg::Polytope::PlaneList& planeList = frustum.getPlaneList();
   unsigned int idx = 0;
   unsigned int ptIdx = 0;
   unsigned int outsideCount    = 0;
   unsigned int upperBound = planeList.size();
   double testValue = 0.0;
   for(; idx < upperBound;++idx)
   {
      const osg::Vec4& plane = planeList[idx].asVec4();
      outsideCount = 0;
      for(ptIdx = 0; ptIdx < 8; ++ptIdx)
      {
         testValue =  (((((double)plane[0])*theCorners[ptIdx][0] +
                         ((double)plane[1])*theCorners[ptIdx][1] +
                         ((double)plane[2])*theCorners[ptIdx][2])) + (double)plane[3]);
         if(testValue >-FLT_EPSILON)
         {
            break;
         }
         else
         {
            ++outsideCount;
         }
      }
      if(outsideCount == 8)
      {
         return false;
      }
   }
   
   return true;
}
Exemplo n.º 4
0
inline bool CheckAndMultiplyBoxIfWithinPolytope
    ( osg::BoundingBox & bb, osg::Matrix & m, osg::Polytope &p )
{
    if( !bb.valid() ) return false;

    osg::Vec3 o = bb._min * m, s[3];

    for( int i = 0; i < 3; i ++ )
        s[i] = osg::Vec3( m(i,0), m(i,1), m(i,2) ) * ( bb._max[i] - bb._min[i] );

    for( osg::Polytope::PlaneList::iterator it = p.getPlaneList().begin();
         it != p.getPlaneList().end();
         ++it )
    {
        float dist = it->distance( o ), dist_min = dist, dist_max = dist;

        for( int i = 0; i < 3; i ++ ) {
            dist = it->dotProductNormal( s[i] );
            if( dist < 0 ) dist_min += dist; else dist_max += dist;
        }

        if( dist_max < 0 )
            return false;
    }

    bb._max = bb._min = o;
#if 1
    for( int i = 0; i < 3; i ++ )
        for( int j = 0; j < 3; j ++ )
            if( s[i][j] < 0 ) bb._min[j] += s[i][j]; else bb._max[j] += s[i][j];
#else
    b.expandBy( o + s[0] );
    b.expandBy( o + s[1] );
    b.expandBy( o + s[2] );
    b.expandBy( o + s[0] + s[1] );
    b.expandBy( o + s[0] + s[2] );
    b.expandBy( o + s[1] + s[2] );
    b.expandBy( o + s[0] + s[1] + s[2] );
#endif

#if ( IGNORE_OBJECTS_LARGER_THAN_HEIGHT > 0 )
   if( bb._max[2] - bb._min[2] > IGNORE_OBJECTS_LARGER_THAN_HEIGHT ) // ignore huge objects
       return false;
#endif

    return true;
}
Exemplo n.º 5
0
bool
Feature::getWorldBoundingPolytope(const SpatialReference* srs,
                                  osg::Polytope&          out_polytope) const
{
    osg::BoundingSphered bs;
    if ( getWorldBound(srs, bs) && bs.valid() )
    {
        out_polytope.clear();

        // add planes for the four sides of the BS. Normals point inwards.
        out_polytope.add( osg::Plane(osg::Vec3d( 1, 0,0), osg::Vec3d(-bs.radius(),0,0)) );
        out_polytope.add( osg::Plane(osg::Vec3d(-1, 0,0), osg::Vec3d( bs.radius(),0,0)) );
        out_polytope.add( osg::Plane(osg::Vec3d( 0, 1,0), osg::Vec3d(0, -bs.radius(),0)) );
        out_polytope.add( osg::Plane(osg::Vec3d( 0,-1,0), osg::Vec3d(0,  bs.radius(),0)) );

        // for a projected feature, we're done. For a geocentric one, transform the polytope
        // into world (ECEF) space.
        if ( srs->isGeographic() && !srs->isPlateCarre() )
        {
            const osg::EllipsoidModel* e = srs->getEllipsoid();

            // add a bottom cap, unless the bounds are sufficiently large.
            double minRad = std::min(e->getRadiusPolar(), e->getRadiusEquator());
            double maxRad = std::max(e->getRadiusPolar(), e->getRadiusEquator());
            double zeroOffset = bs.center().length();
            if ( zeroOffset > minRad * 0.1 )
            {
                out_polytope.add( osg::Plane(osg::Vec3d(0,0,1), osg::Vec3d(0,0,-maxRad+zeroOffset)) );
            }
        }

        // transform the clipping planes ito ECEF space
        GeoPoint refPoint;
        refPoint.fromWorld( srs, bs.center() );

        osg::Matrix local2world;
        refPoint.createLocalToWorld( local2world );

        out_polytope.transform( local2world );

        return true;
    }
    return false;
}
bool
GeoCell::intersects( const osg::Polytope& tope ) const
{
    const osg::Polytope::PlaneList& planes = tope.getPlaneList();
    for( osg::Polytope::PlaneList::const_iterator i = planes.begin(); i != planes.end(); ++i )
    {
        if ( i->intersect( _boundaryPoints ) < 0 )
            return false;
    }
    return true;
}
bool PrecipitationEffect::build(const osg::Vec3 eyeLocal, int i, int j, int k, float startTime, PrecipitationDrawableSet& pds, osg::Polytope& frustum, osgUtil::CullVisitor* cv) const
{
    osg::Vec3 position = _origin + osg::Vec3(float(i)*_du.x(), float(j)*_dv.y(), float(k+1)*_dw.z());
    osg::Vec3 scale(_du.x(), _dv.y(), -_dw.z());

    osg::BoundingBox bb(position.x(), position.y(), position.z()+scale.z(),
                        position.x()+scale.x(), position.y()+scale.y(), position.z());

    if (!frustum.contains(bb)) return false;

    osg::Vec3 center = position + scale*0.5f;
    float distance = (center-eyeLocal).length();

    osg::Matrix* mymodelview = 0;
    if (distance < _nearTransition)
    {
        PrecipitationDrawable::DepthMatrixStartTime& mstp = pds._quadPrecipitationDrawable->getCurrentCellMatrixMap()[PrecipitationDrawable::Cell(i,k,j)];
        mstp.depth = distance;
        mstp.startTime = startTime;
        mymodelview = &mstp.modelview;
    }
    else if (distance <= _farTransition)
    {
        if (_useFarLineSegments)
        {
            PrecipitationDrawable::DepthMatrixStartTime& mstp = pds._linePrecipitationDrawable->getCurrentCellMatrixMap()[PrecipitationDrawable::Cell(i,k,j)];
            mstp.depth = distance;
            mstp.startTime = startTime;
            mymodelview = &mstp.modelview;
        }
        else
        {
            PrecipitationDrawable::DepthMatrixStartTime& mstp = pds._pointPrecipitationDrawable->getCurrentCellMatrixMap()[PrecipitationDrawable::Cell(i,k,j)];
            mstp.depth = distance;
            mstp.startTime = startTime;
            mymodelview = &mstp.modelview;
        }
    }
    else
    {
        return false;
    }

    *mymodelview = *(cv->getModelViewMatrix());
    mymodelview->preMultTranslate(position);
    mymodelview->preMultScale(scale);

    cv->updateCalculatedNearFar(*(cv->getModelViewMatrix()),bb);

    return true;
}
Exemplo n.º 8
0
bool DebugShadowMap::ViewData::DebugPolytope
( const osg::Polytope & p, const char * name )
{
    bool result = false;
#if defined( _DEBUG    ) || defined( DEBUG )
    if( !name ) name = "";

    osg::Polytope & p_prev = _polytopeMap[ std::string( name ) ];

    result = ( p.getPlaneList() != p_prev.getPlaneList() );

    if( result ) {
        std::cout << "Polytope<" << name
                  << "> size(" << p.getPlaneList().size() << ")"
                  << std::endl;

        if( p.getPlaneList().size() == p_prev.getPlaneList().size() ) {
            for( unsigned i = 0; i < p.getPlaneList().size(); ++i )
            {
                if( p.getPlaneList()[i] != p_prev.getPlaneList()[i] )
                {
                    std::cout << "Plane<" << i
                        << "> ("
                        << p.getPlaneList()[i].asVec4()[0] << ", "
                        << p.getPlaneList()[i].asVec4()[1] << ", "
                        << p.getPlaneList()[i].asVec4()[2] << ", "
                        << p.getPlaneList()[i].asVec4()[3] << ")"
                        << std::endl;
                }
            }
        }
    }

    p_prev = p;
#endif
    return result;
}
Exemplo n.º 9
0
void LightPointNode::traverse(osg::NodeVisitor& nv)
{
    if (_lightPointList.empty())
    {
        // no light points so no op.
        return;
    }

    //#define USE_TIMER
    #ifdef USE_TIMER
    osg::Timer timer;
    osg::Timer_t t1=0,t2=0,t3=0,t4=0,t5=0,t6=0,t7=0,t8=0;
    #endif


#ifdef USE_TIMER
    t1 = timer.tick();
#endif

    osgUtil::CullVisitor* cv = nv.asCullVisitor();

#ifdef USE_TIMER
    t2 = timer.tick();
#endif


    // should we disable small feature culling here?
    if (cv /*&& !cv->isCulled(_bbox)*/)
    {

        osg::Matrix matrix = *(cv->getModelViewMatrix());
        osg::RefMatrix& projection = *(cv->getProjectionMatrix());
        osgUtil::StateGraph* rg = cv->getCurrentStateGraph();

        if (rg->leaves_empty())
        {
            // this is first leaf to be added to StateGraph
            // and therefore should not already know current render bin,
            // so need to add it.
            cv->getCurrentRenderBin()->addStateGraph(rg);
        }

#ifdef USE_TIMER
        t3 = timer.tick();
#endif


        LightPointDrawable* drawable = NULL;
        osg::Referenced* object = rg->getUserData();
        if (object)
        {
            if (typeid(*object)==typeid(LightPointDrawable))
            {
                // resuse the user data attached to the render graph.
                drawable = static_cast<LightPointDrawable*>(object);

            }
            else if (typeid(*object)==typeid(LightPointSpriteDrawable))
            {
                drawable = static_cast<LightPointSpriteDrawable*>(object);
            }
            else
            {
                // will need to replace UserData.
                OSG_WARN << "Warning: Replacing osgUtil::StateGraph::_userData to support osgSim::LightPointNode, may have undefined results."<<std::endl;
            }
        }

        if (!drawable)
        {
            drawable = _pointSprites ? new LightPointSpriteDrawable : new LightPointDrawable;
            rg->setUserData(drawable);

            if (cv->getFrameStamp())
            {
                drawable->setSimulationTime(cv->getFrameStamp()->getSimulationTime());
            }
        }

        // search for a drawable in the RenderLeaf list equal to the attached the one attached to StateGraph user data
        // as this will be our special light point drawable.
        osgUtil::StateGraph::LeafList::iterator litr;
        for(litr = rg->_leaves.begin();
            litr != rg->_leaves.end() && (*litr)->_drawable.get()!=drawable;
            ++litr)
        {}

        if (litr == rg->_leaves.end())
        {
            // haven't found the drawable added in the RenderLeaf list, therefore this may be the
            // first time through LightPointNode in this frame, so need to add drawable into the StateGraph RenderLeaf list
            // and update its time signatures.

            drawable->reset();
            rg->addLeaf(new osgUtil::RenderLeaf(drawable,&projection,NULL,FLT_MAX));

            // need to update the drawable's frame count.
            if (cv->getFrameStamp())
            {
                drawable->updateSimulationTime(cv->getFrameStamp()->getSimulationTime());
            }

        }

#ifdef USE_TIMER
        t4 = timer.tick();
#endif


#ifdef USE_TIMER
        t7 = timer.tick();
#endif


        if (cv->getComputeNearFarMode() != osgUtil::CullVisitor::DO_NOT_COMPUTE_NEAR_FAR)
            cv->updateCalculatedNearFar(matrix,_bbox);


        const float minimumIntensity = 1.0f/256.0f;
        const osg::Vec3 eyePoint = cv->getEyeLocal();

        double time=drawable->getSimulationTime();
        double timeInterval=drawable->getSimulationTimeInterval();

        const osg::Polytope clipvol(cv->getCurrentCullingSet().getFrustum());
        const bool computeClipping = false;//(clipvol.getCurrentMask()!=0);

        //LightPointDrawable::ColorPosition cp;
        for(LightPointList::iterator itr=_lightPointList.begin();
            itr!=_lightPointList.end();
            ++itr)
        {
            const LightPoint& lp = *itr;

            if (!lp._on) continue;

            const osg::Vec3& position = lp._position;

            // skip light point if it is not contianed in the view frustum.
            if (computeClipping && !clipvol.contains(position)) continue;

            // delta vector between eyepoint and light point.
            osg::Vec3 dv(eyePoint-position);

            float intensity = (_lightSystem.valid()) ? _lightSystem->getIntensity() : lp._intensity;

            // slip light point if its intensity is 0.0 or negative.
            if (intensity<=minimumIntensity) continue;

            // (SIB) Clip on distance, if close to limit, add transparancy
            float distanceFactor = 1.0f;
            if (_maxVisibleDistance2!=FLT_MAX)
            {
                if (dv.length2()>_maxVisibleDistance2) continue;
                else if (_maxVisibleDistance2 > 0)
                    distanceFactor = 1.0f - osg::square(dv.length2() / _maxVisibleDistance2);
            }

            osg::Vec4 color = lp._color;

            // check the sector.
            if (lp._sector.valid())
            {
                intensity *= (*lp._sector)(dv);

                // skip light point if it is intensity is 0.0 or negative.
                if (intensity<=minimumIntensity) continue;

            }

            // temporary accounting of intensity.
            //color *= intensity;

            // check the blink sequence.
            bool doBlink = lp._blinkSequence.valid();
            if (doBlink && _lightSystem.valid())
                doBlink = (_lightSystem->getAnimationState() == LightPointSystem::ANIMATION_ON);

            if (doBlink)
            {
                osg::Vec4 bs = lp._blinkSequence->color(time,timeInterval);
                color[0] *= bs[0];
                color[1] *= bs[1];
                color[2] *= bs[2];
                color[3] *= bs[3];
            }

            // if alpha value is less than the min intentsity then skip
            if (color[3]<=minimumIntensity) continue;

            float pixelSize = cv->pixelSize(position,lp._radius);

            //            cout << "pixelsize = "<<pixelSize<<endl;

            // adjust pixel size to account for intensity.
            if (intensity!=1.0) pixelSize *= sqrt(intensity);

            // adjust alpha to account for max range (Fade on distance)
            color[3] *= distanceFactor;

            // round up to the minimum pixel size if required.
            float orgPixelSize = pixelSize;
            if (pixelSize<_minPixelSize) pixelSize = _minPixelSize;

            osg::Vec3 xpos(position*matrix);

            if (lp._blendingMode==LightPoint::BLENDED)
            {
                if (pixelSize<1.0f)
                {
                    // need to use alpha blending...
                    color[3] *= pixelSize;
                    // color[3] *= osg::square(pixelSize);

                    if (color[3]<=minimumIntensity) continue;

                    drawable->addBlendedLightPoint(0, xpos,color);
                }
                else if (pixelSize<_maxPixelSize)
                {

                    unsigned int lowerBoundPixelSize = (unsigned int)pixelSize;
                    float remainder = osg::square(pixelSize-(float)lowerBoundPixelSize);

                    // (SIB) Add transparency if pixel is clamped to minpixelsize
                    if (orgPixelSize<_minPixelSize)
                        color[3] *= (2.0/3.0) + (1.0/3.0) * sqrt(orgPixelSize / pixelSize);

                    drawable->addBlendedLightPoint(lowerBoundPixelSize-1, xpos,color);
                    color[3] *= remainder;
                    drawable->addBlendedLightPoint(lowerBoundPixelSize, xpos,color);
                }
                else // use a billboard geometry.
                {
                    drawable->addBlendedLightPoint((unsigned int)(_maxPixelSize-1.0), xpos,color);
                }
            }
            else // ADDITIVE blending.
            {
                if (pixelSize<1.0f)
                {
                    // need to use alpha blending...
                    color[3] *= pixelSize;
                    // color[3] *= osg::square(pixelSize);

                    if (color[3]<=minimumIntensity) continue;

                    drawable->addAdditiveLightPoint(0, xpos,color);
                }
                else if (pixelSize<_maxPixelSize)
                {

                    unsigned int lowerBoundPixelSize = (unsigned int)pixelSize;
                    float remainder = osg::square(pixelSize-(float)lowerBoundPixelSize);

                    // (SIB) Add transparency if pixel is clamped to minpixelsize
                    if (orgPixelSize<_minPixelSize)
                        color[3] *= (2.0/3.0) + (1.0/3.0) * sqrt(orgPixelSize / pixelSize);

                    float alpha = color[3];
                    color[3] = alpha*(1.0f-remainder);
                    drawable->addAdditiveLightPoint(lowerBoundPixelSize-1, xpos,color);
                    color[3] = alpha*remainder;
                    drawable->addAdditiveLightPoint(lowerBoundPixelSize, xpos,color);
                }
                else // use a billboard geometry.
                {
                    drawable->addAdditiveLightPoint((unsigned int)(_maxPixelSize-1.0), xpos,color);
                }
            }
        }

#ifdef USE_TIMER
        t8 = timer.tick();
#endif

    }
#ifdef USE_TIMER
    cout << "compute"<<endl;
    cout << "  t2-t1="<<t2-t1<<endl;
    cout << "  t4-t3="<<t4-t3<<endl;
    cout << "  t6-t5="<<t6-t5<<endl;
    cout << "  t8-t7="<<t8-t7<<endl;
    cout << "_lightPointList.size()="<<_lightPointList.size()<<endl;
    cout << "  t8-t7/size = "<<(float)(t8-t7)/(float)_lightPointList.size()<<endl;
#endif
}
Exemplo n.º 10
0
void ComputeBoundsVisitor::getBase(osg::Polytope& polytope, float margin) const
{
    float delta = _bb.radius()*margin;
    polytope.add( osg::Plane(0.0, 0.0, 1.0, -(_bb.zMin()-delta)) );
}
Exemplo n.º 11
0
bool SiltEffect::build(const osg::Vec3 eyeLocal, int i, int j, int k, float startTime, SiltDrawableSet& pds, osg::Polytope& frustum, osgUtil::CullVisitor* cv) const
{
    osg::Vec3 position = _origin + osg::Vec3(float(i)*_du.x(), float(j)*_dv.y(), float(k+1)*_dw.z());
    osg::Vec3 scale(_du.x(), _dv.y(), -_dw.z());

    osg::BoundingBox bb(position.x(), position.y(), position.z()+scale.z(),
        position.x()+scale.x(), position.y()+scale.y(), position.z());

    if ( !frustum.contains(bb) ) 
        return false;

    osg::Vec3 center = position + scale*0.5f;
    float distance = (center-eyeLocal).length();

    osg::Matrix* mymodelview = 0;

    if (distance < _nearTransition)
    {
        SiltDrawable::DepthMatrixStartTime& mstp 
            = pds._quadSiltDrawable->getCurrentCellMatrixMap()[SiltDrawable::Cell(i,k,j)];
        
        mstp.depth = distance;
        mstp.startTime = startTime;
        mymodelview = &mstp.modelview;
    }
    else if (distance <= _farTransition)
    {
        SiltDrawable::DepthMatrixStartTime& mstp 
            = pds._pointSiltDrawable->getCurrentCellMatrixMap()[SiltDrawable::Cell(i,k,j)];
        
        mstp.depth = distance;
        mstp.startTime = startTime;
        mymodelview = &mstp.modelview;
    }
    else
    {
        return false;
    }

    *mymodelview = *(cv->getModelViewMatrix());

#if OPENSCENEGRAPH_MAJOR_VERSION > 2 || \
    (OPENSCENEGRAPH_MAJOR_VERSION == 2 && OPENSCENEGRAPH_MINOR_VERSION > 7) || \
    (OPENSCENEGRAPH_MAJOR_VERSION == 2 && OPENSCENEGRAPH_MINOR_VERSION == 7 && OPENSCENEGRAPH_PATCH_VERSION >= 3)

    // preMultTranslate and preMultScale introduced in rev 8868, which was 
    // before OSG 2.7.3.
    mymodelview->preMultTranslate(position);
    mymodelview->preMultScale(scale);

#else

    // Otherwise use unoptimized versions
    mymodelview->preMult(osg::Matrix::translate(position));
    mymodelview->preMult(osg::Matrix::scale(scale));

#endif

    cv->updateCalculatedNearFar(*(cv->getModelViewMatrix()),bb);

    return true;
}