示例#1
0
MFloatVector anisotropicShaderNode::calcHalfVector( 
	const MFloatVector& view, 
	const MFloatVector& light ) const
{
    MFloatVector H = (light + view) / 2.0;
    H.normalize();
    return H;
}
//color_transform
void Ocio_log_convert::color_transform(MFloatVector& vec_input_color)
{
    //pixels
    float pixels[3];
    vec_input_color.get(pixels);

    //pixel_r, pixel_g, pixel_b;
    float* pixel_r = &pixels[0];
    float* pixel_g = &pixels[1];
    float* pixel_b = &pixels[2];

    //convert
    OCIO_functionality::color_transform_single_pixel(pixel_r, pixel_g, pixel_b, processor);

    //set colors back to vec_input_color
    vec_input_color.x = pixels[0];
    vec_input_color.y = pixels[1];
    vec_input_color.z = pixels[2];
}
示例#3
0
//
//      Deform computation
//
MStatus jhMeshBlur::deform( MDataBlock& block,MItGeometry& iter,const MMatrix& m,unsigned int multiIndex)
{
    MStatus returnStatus;

    // Envelope
    float envData = block.inputValue(envelope, &returnStatus).asFloat();
	CHECK_MSTATUS(returnStatus);

    if(envData == 0)
		return MS::kFailure;

    /*
     VARIABLES
     */
    //float factor = block.inputValue(aShapeFactor, &returnStatus).asFloat();
    float fStrength = block.inputValue(aStrength, &returnStatus).asFloat();
	CHECK_MSTATUS(returnStatus);
	
	if (fStrength == 0)
		return MS::kFailure;
	
    float fThreshold = block.inputValue(aTreshhold, &returnStatus).asFloat();
	CHECK_MSTATUS(returnStatus);
    float fW = 0.0f; // weight
    float fDistance;
    fStrength *= envData;

    double dKracht = block.inputValue(aInterpPower, &returnStatus).asDouble();
	CHECK_MSTATUS(returnStatus);
    double dDotProduct;  // Dotproduct of the point

    bool bTweakblur = block.inputValue(aTweakBlur, &returnStatus).asBool();
	CHECK_MSTATUS(returnStatus);
	
    bool bQuad = block.inputValue(aQuadInterp, &returnStatus).asBool();
	CHECK_MSTATUS(returnStatus);
	
	MTime inTime = block.inputValue(aTime).asTime();
    int nTijd = (int)inTime.as(MTime::kFilm);


    MFloatVectorArray currentNormals;   // normals of mesh
    MFnPointArrayData fnPoints;         // help converting to MPointArrays
    MFloatVector dirVector;             // direction vector of the point
    MFloatVector normal;                // normal of the point
    MPointArray savedPoints;            // save all point before edited
    MMatrix matInv = m.inverse();       // inversed matrix
    MPoint ptA;                         // current point (iter mesh)
    MPoint ptB;                         // previous point (iter mesh)
    MPoint ptC;                         // mesh before previous point (iter mesh)

    // get node, use node to get inputGeom, use inputGeom to get mesh data, use mesh data to get normal data
    MFnDependencyNode nodeFn(this->thisMObject());

    MPlug inGeomPlug(nodeFn.findPlug(this->inputGeom,true));
    MObject inputObject(inGeomPlug.asMObject());
    MFnMesh inMesh(inputObject);

    inMesh.getVertexNormals(true, currentNormals);

    // get the previous mesh data
    MPlug oldMeshPlug = nodeFn.findPlug(MString("oldMesh"));
    MPlug oldMeshPositionsAPlug = oldMeshPlug.elementByLogicalIndex((multiIndex*4) + 0);
    MPlug oldMeshPositionsBPlug = oldMeshPlug.elementByLogicalIndex((multiIndex*4) + 1);
    MPlug oldMeshPositionsCPlug = oldMeshPlug.elementByLogicalIndex((multiIndex*4) + 2); // cache for tweak mode
    MPlug oldMeshPositionsDPlug = oldMeshPlug.elementByLogicalIndex((multiIndex*4) + 3); // cache for tweak mode

    // convert to MPointArrays
    MObject objOldMeshA;
    MObject objOldMeshB;
    MObject objOldMeshC; // cache
    MObject objOldMeshD; // cache

    oldMeshPositionsAPlug.getValue(objOldMeshA);
    oldMeshPositionsBPlug.getValue(objOldMeshB);
    oldMeshPositionsCPlug.getValue(objOldMeshC); // cache
    oldMeshPositionsDPlug.getValue(objOldMeshD); // cache

    fnPoints.setObject(objOldMeshA);
    MPointArray oldMeshPositionsA = fnPoints.array();
    
    fnPoints.setObject(objOldMeshB);
    MPointArray oldMeshPositionsB = fnPoints.array();
    
    fnPoints.setObject(objOldMeshC);
    MPointArray oldMeshPositionsC = fnPoints.array(); // cache
    
    fnPoints.setObject(objOldMeshD);
    MPointArray oldMeshPositionsD = fnPoints.array(); // cache

    
    
    // If mesh position variables are empty,fill them with default values
    if(oldMeshPositionsA.length() == 0 || nTijd <= 1){
        iter.allPositions(oldMeshPositionsA);

        for(int i=0; i < oldMeshPositionsA.length(); i++)
        {
            // convert to world
            oldMeshPositionsA[i] = oldMeshPositionsA[i] * m;
        }
		
        oldMeshPositionsB.copy(oldMeshPositionsA);
        oldMeshPositionsC.copy(oldMeshPositionsA); // cache
        oldMeshPositionsD.copy(oldMeshPositionsA); // cache
    }
	
	// get back old date again
	if (bTweakblur == true) { // restore cache
		oldMeshPositionsA.copy(oldMeshPositionsC);
		oldMeshPositionsB.copy(oldMeshPositionsD);
	}
    
    
    iter.allPositions(savedPoints);
    for(int i=0; i < savedPoints.length(); i++)
    {
        // convert points to world points
        savedPoints[i] = savedPoints[i] * m;
    }

    // Actual Iteration through points
    for (; !iter.isDone(); iter.next()){
        // get current position
        ptA = iter.position();
        // get old positions
        ptB = oldMeshPositionsA[iter.index()] * matInv;
        ptC = oldMeshPositionsB[iter.index()] * matInv;

        fDistance = ptA.distanceTo(ptB);
        fW = weightValue(block,multiIndex,iter.index());


        if (fDistance * (fStrength*fW) < fThreshold && fThreshold > 0){
            iter.setPosition(ptA);
        } else {
            // aim/direction vector to calculate strength
            dirVector = (ptA - ptB); // (per punt)
            dirVector.normalize();

            normal = currentNormals[iter.index()];

            dDotProduct = normal.x * dirVector.x + normal.y * dirVector.y + normal.z * dirVector.z;

            
            if(bQuad == true){
                MVector vecA(((ptB - ptC) + (ptA - ptB)) / 2);
                vecA.normalize();

                MPoint hiddenPt(ptB + (vecA * fDistance) * dKracht);
                ptA = quadInterpBetween(ptB, hiddenPt, ptA, (1 - fStrength * fW) + (linearInterp(dDotProduct, -1, 1) * (fStrength * fW) ) );
            } else {
                MPoint halfway = (ptA - ptB) * 0.5;
                MPoint offset = halfway * dDotProduct * (fStrength*fW);
                ptA = ptA - ((halfway * (fStrength*fW)) - offset); // + (offset * strength);
            }
            // set new value

            iter.setPosition(ptA);
        }
    }
    if(bTweakblur == false){
        oldMeshPositionsD.copy(oldMeshPositionsB);
        oldMeshPositionsC.copy(oldMeshPositionsA);
        oldMeshPositionsB.copy(oldMeshPositionsA);
        oldMeshPositionsA.copy(savedPoints);

        // Save back to plugs
        objOldMeshA = fnPoints.create(oldMeshPositionsA);
        objOldMeshB = fnPoints.create(oldMeshPositionsB);
        objOldMeshC = fnPoints.create(oldMeshPositionsC);
        objOldMeshD = fnPoints.create(oldMeshPositionsD);
		
        oldMeshPositionsAPlug.setValue(objOldMeshA);
        oldMeshPositionsBPlug.setValue(objOldMeshB);
        oldMeshPositionsCPlug.setValue(objOldMeshC);
        oldMeshPositionsDPlug.setValue(objOldMeshD);
    }
    
    return returnStatus;
}
示例#4
0
//
// DESCRIPTION:
///////////////////////////////////////////////////////
MStatus PhongNode::compute(
const MPlug&      plug,
      MDataBlock& block )
{
    if ((plug != aOutColor) && (plug.parent() != aOutColor))
		return MS::kUnknownParameter;

    MFloatVector resultColor(0.0,0.0,0.0);

    // get sample surface shading parameters
    MFloatVector& surfaceNormal = block.inputValue( aNormalCamera ).asFloatVector();
    MFloatVector& cameraPosition = block.inputValue( aPointCamera ).asFloatVector();

	// use for raytracing api enhancement below
	MFloatVector point = cameraPosition;
	MFloatVector normal = surfaceNormal;

    MFloatVector& surfaceColor  = block.inputValue( aColor ).asFloatVector();
    MFloatVector& incandescence = block.inputValue( aIncandescence ).asFloatVector();
    float diffuseReflectivity = block.inputValue( aDiffuseReflectivity ).asFloat();
    // float translucenceCoeff   = block.inputValue( aTranslucenceCoeff ).asFloat();
	// User-defined Reflection Color Gain
	float reflectGain = block.inputValue( aReflectGain ).asFloat();

    // Phong shading attributes
    float power = block.inputValue( aPower ).asFloat();
    float spec = block.inputValue( aSpecularity ).asFloat();

    float specularR, specularG, specularB;
    float diffuseR, diffuseG, diffuseB;
    diffuseR = diffuseG = diffuseB = specularR = specularG = specularB = 0.0;

    // get light list
    MArrayDataHandle lightData = block.inputArrayValue( aLightData );
    int numLights = lightData.elementCount();

    // iterate through light list and get ambient/diffuse values
    for( int count=1; count <= numLights; count++ )
    {
        MDataHandle currentLight = lightData.inputValue();
        MFloatVector& lightIntensity = currentLight.child(aLightIntensity).asFloatVector();

        // Find the blind data
        void*& blindData = currentLight.child( aLightBlindData ).asAddr();

        // find ambient component
        if( currentLight.child(aLightAmbient).asBool() ) {
            diffuseR += lightIntensity[0];
            diffuseG += lightIntensity[1];
            diffuseB += lightIntensity[2];
        }

        MFloatVector& lightDirection = currentLight.child(aLightDirection).asFloatVector();

        if ( blindData == NULL )
        {
			// find diffuse and specular component
			if( currentLight.child(aLightDiffuse).asBool() )
			{
			    float cosln = lightDirection * surfaceNormal;;
			    if( cosln > 0.0f )  // calculate only if facing light
			    {
			         diffuseR += lightIntensity[0] * ( cosln * diffuseReflectivity );
			         diffuseG += lightIntensity[1] * ( cosln * diffuseReflectivity );
			         diffuseB += lightIntensity[2] * ( cosln * diffuseReflectivity );
			    }

			    CHECK_MSTATUS( cameraPosition.normalize() );

				if( cosln > 0.0f ) // calculate only if facing light
				{
				    float RV = ( ( (2*surfaceNormal) * cosln ) - lightDirection ) * cameraPosition;
				    if( RV > 0.0 ) RV = 0.0;
				    if( RV < 0.0 ) RV = -RV;

				    if ( power < 0 ) power = -power;

				    float s = spec * powf( RV, power );

				    specularR += lightIntensity[0] * s;
				    specularG += lightIntensity[1] * s;
				    specularB += lightIntensity[2] * s;
				}
			}
        }
        else
        {
			float cosln = MRenderUtil::diffuseReflectance( blindData, lightDirection, point, surfaceNormal, true );
			if( cosln > 0.0f )  // calculate only if facing light
			{
			     diffuseR += lightIntensity[0] * ( cosln * diffuseReflectivity );
			     diffuseG += lightIntensity[1] * ( cosln * diffuseReflectivity );
			     diffuseB += lightIntensity[2] * ( cosln * diffuseReflectivity );
			}

			CHECK_MSTATUS ( cameraPosition.normalize() );

			if ( currentLight.child(aLightSpecular).asBool() )
			{
				MFloatVector specLightDirection = lightDirection;
				MDataHandle directionH = block.inputValue( aRayDirection );
				MFloatVector direction = directionH.asFloatVector();
				float lightAttenuation = 1.0;

				specLightDirection = MRenderUtil::maximumSpecularReflection( blindData,
										lightDirection, point, surfaceNormal, direction );
				lightAttenuation = MRenderUtil::lightAttenuation( blindData, point, surfaceNormal, false );

				// Are we facing the light
				if ( specLightDirection * surfaceNormal > 0.0f )
				{
					float power2 = block.inputValue( aPower ).asFloat();
					MFloatVector rv = 2 * surfaceNormal * ( surfaceNormal * direction ) - direction;
					float s = spec * powf( rv * specLightDirection, power2 );

					specularR += lightIntensity[0] * s * lightAttenuation;
					specularG += lightIntensity[1] * s * lightAttenuation;
					specularB += lightIntensity[2] * s * lightAttenuation;
				}
			 }
       }
       if( !lightData.next() ) break;
    }

    // factor incident light with surface color and add incandescence
    resultColor[0] = ( diffuseR * surfaceColor[0] ) + specularR + incandescence[0];
    resultColor[1] = ( diffuseG * surfaceColor[1] ) + specularG + incandescence[1];
    resultColor[2] = ( diffuseB * surfaceColor[2] ) + specularB + incandescence[2];

	// add the reflection color
	if (reflectGain > 0.0) {

		MStatus status;

		// required attributes for using raytracer
		// origin, direction, sampler, depth, and object id.
		//
		MDataHandle originH = block.inputValue( aRayOrigin, &status);
		MFloatVector origin = originH.asFloatVector();

		MDataHandle directionH = block.inputValue( aRayDirection, &status);
		MFloatVector direction = directionH.asFloatVector();

		MDataHandle samplerH = block.inputValue( aRaySampler, &status);
		void*& samplerPtr = samplerH.asAddr();

		MDataHandle depthH = block.inputValue( aRayDepth, &status);
		short depth = depthH.asShort();

		MDataHandle objH = block.inputValue( aObjectId, &status);
		void*& objId = objH.asAddr();

		MFloatVector reflectColor;
		MFloatVector reflectTransparency;

		MFloatVector& triangleNormal = block.inputValue( aTriangleNormalCamera ).asFloatVector();

		// compute reflected ray
		MFloatVector l = -direction;
		float dot = l * normal;
		if( dot < 0.0 ) dot = -dot;
		MFloatVector refVector = 2 * normal * dot - l; 	// reflection ray
		float dotRef = refVector * triangleNormal;
		if( dotRef < 0.0 ) {
		    const float s = 0.01f;
			MFloatVector mVec = refVector - dotRef * triangleNormal;
			mVec.normalize();
			refVector = mVec + s * triangleNormal;
		}
		CHECK_MSTATUS ( refVector.normalize() );

		status = MRenderUtil::raytrace(
				point,    	//  origin
				refVector,  //  direction
				objId,		//  object id
				samplerPtr, //  sampler info
				depth,		//  ray depth
				reflectColor,	// output color and transp
				reflectTransparency);

		// add in the reflection color
		resultColor[0] += reflectGain * (reflectColor[0]);
		resultColor[1] += reflectGain * (reflectColor[1]);
		resultColor[2] += reflectGain * (reflectColor[2]);

	}

    // set ouput color attribute
    MDataHandle outColorHandle = block.outputValue( aOutColor );
    MFloatVector& outColor = outColorHandle.asFloatVector();
    outColor = resultColor;
    outColorHandle.setClean();

    return MS::kSuccess;
}
示例#5
0
MStatus anisotropicShaderNode::compute( const MPlug& plug, MDataBlock& block )
{
    if ((plug == aOutColor) || (plug.parent() == aOutColor))
	{
        MFloatVector resultColor(0.0,0.0,0.0);
        MFloatVector diffuseColor( 0.0,0.0,0.0 );
        MFloatVector specularColor( 0.0,0.0,0.0 );
        MFloatVector ambientColor( 0.0,0.0,0.0 );

        // get matrix
        MFloatMatrix& matrixOToW = block.inputValue( aMatrixOToW ).asFloatMatrix();
        MFloatMatrix& matrixWToC = block.inputValue( aMatrixWToC ).asFloatMatrix();

        // spin scratch around this vector (in object space )
        MFloatVector& A = block.inputValue( aAxesVector ).asFloatVector();
        A.normalize();

        // spin scratch around this vector (in world space )
        MFloatVector wa = A * matrixOToW;
        wa.normalize();

        // spin scratch around this vector (in camera space )
        MFloatVector ca = wa * matrixWToC;
        ca.normalize();

        MFloatVector& surfacePoint = block.inputValue( aPointCamera ).asFloatVector();

        // get sample surface shading parameters
        MFloatVector& N = block.inputValue( aNormalCamera ).asFloatVector();
        MFloatVector& surfaceColor = block.inputValue( aColor ).asFloatVector();

        float diffuseReflectivity = block.inputValue( aDiffuseReflectivity ).asFloat();
        float specularCoeff = block.inputValue( aSpecularCoeff ).asFloat();

        // get light list
        MArrayDataHandle lightData = block.inputArrayValue( aLightData );
        int numLights = lightData.elementCount();

        // iterate through light list and get ambient/diffuse values
        for( int count=0; count < numLights; count++ ) {
            MDataHandle currentLight = lightData.inputValue();

            MFloatVector& lightIntensity = 
                currentLight.child( aLightIntensity ).asFloatVector();
            MFloatVector& lightDirection = 
                currentLight.child( aLightDirection ).asFloatVector();

            // find ambient component
            if( currentLight.child(aLightAmbient).asBool()) {
                ambientColor[0] += lightIntensity[0] * surfaceColor[0];
                ambientColor[1] += lightIntensity[1] * surfaceColor[1];
                ambientColor[2] += lightIntensity[2] * surfaceColor[2];
            }

            float cosln = lightDirection * N;
            if( cosln > 0.0f ){ // illuminated!

                // find diffuse component
                if( currentLight.child(aLightDiffuse).asBool()) {
                
                    float cosDif = cosln * diffuseReflectivity;
                    diffuseColor[0] += lightIntensity[0] * cosDif * surfaceColor[0];
                    diffuseColor[1] += lightIntensity[1] * cosDif * surfaceColor[1];
                    diffuseColor[2] += lightIntensity[2] * cosDif * surfaceColor[2];
                }

                // find specular component
                if( currentLight.child( aLightSpecular).asBool()){

                    MFloatVector& rayDirection = block.inputValue( aRayDirection ).asFloatVector();
                    MFloatVector viewDirection = -rayDirection;
                    MFloatVector half = calcHalfVector( viewDirection, lightDirection );


                    // Beckmann function

                    MFloatVector nA;
                    if( fabs(1.0-fabs(N*ca)) <= 0.0001f ){
                        MFloatPoint oo( 0.0,0.0,0.0 );
                        MFloatPoint ow = oo * matrixOToW;
                        MFloatPoint oc = ow * matrixWToC;
                        MFloatVector origin( oc[0], oc[1], oc[2] );
                        nA = origin - surfacePoint;
                        nA.normalize();
                    }else{
                        nA = ca;
                    }

                    MFloatVector x = N ^ nA;
                    x.normalize();
                    MFloatVector y = N ^ x;
                    y.normalize();

                    MFloatVector azimuthH = N ^ half;
                    azimuthH = N ^ azimuthH;
                    azimuthH.normalize();

                    float cos_phai = x * azimuthH;
                    float sin_phai = 0.0;
                    if( fabs(1 - cos_phai*cos_phai) < 0.0001 ){
                        sin_phai = 0.0;
                    }else{
                        sin_phai = sqrtf( 1.0f - cos_phai*cos_phai );
                    }
                    double co = pow( (half * N), 4.0f );
                    double t = tan( acos(half*N) );
                    t *= -t;

                    float rough1 = block.inputValue( aRoughness1 ).asFloat();
                    float rough2 = block.inputValue( aRoughness2 ).asFloat();

                    double aaa = cos_phai / rough1;
                    double bbb = sin_phai / rough2;

                    t = t * ( aaa*aaa + bbb*bbb );

                    double D = pow( (1.0/((double)rough1*(double)rough2 * co)), t );

                    double aa = (2.0 * (N*half) * (N*viewDirection) ) / (viewDirection*half);
                    double bb = (2.0 * (N*half) * (N*lightDirection) ) / (viewDirection*half);
                    double cc = 1.0;
                    double G = 0.0;
                    G = MIN( aa, bb );
                    G = MIN( G, cc );

                    float s = (float) (D * G /
                            (double)((N*lightDirection) * (N*viewDirection)));
                    MFloatVector& specColor = block.inputValue( aSpecColor ).asFloatVector();
                    specularColor[0] += lightIntensity[0] * specColor[0] * 
                                            s * specularCoeff;
                    specularColor[1] += lightIntensity[1] * specColor[1] * 
                                            s * specularCoeff;
                    specularColor[2] += lightIntensity[2] * specColor[2] * 
                                            s * specularCoeff;
                }
            }

            if( !lightData.next() ){
                break;
            }
        }

        // result = specular + diffuse + ambient;
        resultColor = diffuseColor + specularColor + ambientColor;

        MFloatVector& transparency = block.inputValue( aInTransparency ).asFloatVector();
        resultColor[0] *= ( 1.0f - transparency[0] );
        resultColor[1] *= ( 1.0f - transparency[1] );
        resultColor[2] *= ( 1.0f - transparency[2] );

        // set ouput color attribute
        MDataHandle outColorHandle = block.outputValue( aOutColor );
        MFloatVector& outColor = outColorHandle.asFloatVector();
        outColor = resultColor;
        outColorHandle.setClean();
        block.setClean( plug );
    }
	else if ((plug == aOutTransparency) || (plug.parent() == aOutTransparency))
	{
        MFloatVector& tr = block.inputValue( aInTransparency ).asFloatVector();

        // set ouput color attribute
        MDataHandle outTransHandle = block.outputValue( aOutTransparency );
        MFloatVector& outTrans = outTransHandle.asFloatVector();
        outTrans = tr;
        block.setClean( plug );
    } else
		return MS::kUnknownParameter;

    return MS::kSuccess;
}
//CURRENTLY ONLY SAVING THE MOST RELEVANT DATA
void Exporter::extractCamera(MObject& cam)
{
	MSpace::Space world_space = MSpace::kWorld;
	MSpace::Space transform_space = MSpace::kTransform;

	//Temp storage for camera
	cameraData TempCameraStorage;

	//Create a fucntion set for the camera
	MFnCamera fn(cam);

	//Ignore orthographic cameras. Top, right, left....
	if (fn.isOrtho())
		return;

	//attach a function set to the parent transform
	MFnDependencyNode fnParent(fn.parent(0));

	//Output some camera info
	std::cout << "Camera: " << fn.name().asChar()
		<< "\n\tparent "
		<< fnParent.name().asChar()
		<< std::endl;

	//Get Transform experimentation
	MFnTransform fs(fn.parent(0));
	MMatrix matrix = fs.transformation().asMatrix();
	std::cout << "\nTransform Matrix: " << matrix << std::endl;

	TempCameraStorage.transformMatrix = matrix;

	//aspect ratio
	std::cout << "\nAspect ratio: " << fn.aspectRatio()
		<< std::endl;
	TempCameraStorage.aspectRatio = fn.aspectRatio();

	//near clipping plane
	std::cout << "\nNear: : " << fn.nearClippingPlane()
		<< std::endl;
	TempCameraStorage.nearClippingPlane = fn.nearClippingPlane();

	//far clipping plane
	std::cout << "\nFar: " << fn.farClippingPlane()
		<< std::endl;
	TempCameraStorage.farClippingPlane = fn.farClippingPlane();

	//horizontal field of view
	std::cout << "\nHorizontal fov: " << fn.horizontalFieldOfView()
		<< std::endl;

	//vertical field of view
	std::cout << "\nVertical fov: " << fn.verticalFieldOfView()
		<< std::endl;
	TempCameraStorage.verticalFieldOfView = fn.verticalFieldOfView();

	//badly formated Projection matrix
	std::cout << "\nProjectionMatrix: " << fn.projectionMatrix()
		<< std::endl;
	TempCameraStorage.projectionMatrix = fn.projectionMatrix();



	MFloatMatrix modelMatrix = fs.transformation().asMatrix().matrix;
	MFloatVector direction = modelMatrix * (MFloatVector)fn.viewDirection();

	direction.normalize();
	direction.x *= -1.0f;
	direction.y *= -1.0f;

	//Up direction
	std::cout << "\nUp Vector: " << fn.upDirection()
		<< std::endl;
	TempCameraStorage.upVector = fn.upDirection();

	//view direction
	std::cout << "\nView Direction: " << direction
		<< std::endl;
	TempCameraStorage.viewDirection = direction;

	/*
		MQuaternion rotation;
		MEulerRotation eulerRotation1;

		fs.getRotation(rotation, transform_space);
		fs.getRotation(eulerRotation1);

		MEulerRotation eulerRotation2 = rotation.asEulerRotation(); // samma som eulerRotation1
		*/

	TempCameraStorage.position = fs.translation(transform_space);
	//pushback to store everything
	scene_.cameras.push_back(TempCameraStorage);

}