MStatus EntityNode::Initialize()
{
MAYA_START_EXCEPTION_HANDLING();
MStatus stat;
////////////////////////////////////////////////////////////////////////////////////////////////////
// Create a string attribute "ArtFilePath"
MFnTypedAttribute tAttr;
s_ArtFilePath = tAttr.create("ArtFilePath", "afp", MFnData::kString, &stat);
MCheckErr(stat, "Unable to create attr: ArtFilePath");
tAttr.setReadable(true);
tAttr.setWritable(false);
stat = addAttribute(s_ArtFilePath);
MCheckErr(stat, "Unable to add attr: ArtFilePath");
////////////////////////////////////////////////////////////////////////////////////////////////////
// Create an array attribute "ImportNodes"
MFnMessageAttribute mAttr;
m_ImportNodes = mAttr.create( "ImortObjects", "ios", &stat );
MCheckErr(stat, "Unable to create attr: ImportNodes");
mAttr.setArray( true );
stat = addAttribute(m_ImportNodes);
MCheckErr(stat, "Unable to add attr: ImportNodes");
MAYA_FINISH_EXCEPTION_HANDLING();
return MS::kSuccess;
}
void lrutils::createFKCtlFromLocation(MVectorArray location, MObject joint, MString prefix, unsigned int num, MString icon, MString color, MObject parent, MObject& fkCtlObj, MObject& fkCtlGroupObj, MString layerName, MObject metaDataNode) {
MStatus status;
MDGModifier dgMod;
//used for holding results from executed commands
MStringArray result;
MFnDependencyNode depMetaDataNodeFn(metaDataNode);
//used for creating metaParent attributes for objects
MFnMessageAttribute mAttr;
MFnTransform jointFn(joint);
//create the control object and set its color
status = MGlobal::executeCommand( "python(\"control = rig101().rig101WCGetByName('" + icon + "')\");" );
status = MGlobal::executeCommand( "python(\"Utils.setControllerColor(control, '" + color + "')\");" );
status = MGlobal::executeCommand( MString("python(\"control.fullPath()\");"), result );
//get the MObject for the controller
status = lrutils::getObjFromName(result[0], fkCtlObj);
MyCheckStatus(status, "lrutils::getObjFromName() failed");
MFnTransform fkCtlFn( fkCtlObj );
lrutils::setLocation(fkCtlObj, location, MFnTransform::MFnTransform(), false, false, true);
//set controller name
MString fkCtlName = prefix + "_FK_"+num+"_CTL";
dgMod.renameNode(fkCtlObj, fkCtlName);
//add the metaParent attribute to the controller
MObject controlAttr = mAttr.create("metaParent", "metaParent");
fkCtlFn.addAttribute(controlAttr);
//connect the controller's metaParent to the MDSpine node
status = dgMod.connect( depMetaDataNodeFn.findPlug("FKControllers"), fkCtlFn.findPlug("metaParent") );
dgMod.doIt();
//create the fk control null
lrutils::makeHomeNull(fkCtlObj, MFnTransform(), fkCtlGroupObj);
lrutils::setLocation(fkCtlGroupObj, location, MFnTransform::MFnTransform(), true, true, false);
MFnTransform fkCtlGroupFn( fkCtlGroupObj );
if(!parent.isNull()) {
MFnTransform parentFn(parent);
MGlobal::executeCommand("parent " + fkCtlGroupFn.fullPathName() + " " + parentFn.fullPathName() + ";");
}
//add the metaParent attribute to the controller group
fkCtlGroupFn.addAttribute(mAttr.create("metaParent", "metaParent"));
//connect the controller group's metaParent to the MDGlobal node
status = dgMod.connect( depMetaDataNodeFn.findPlug("FKControllerGroups"), fkCtlGroupFn.findPlug("metaParent") );
MyCheckStatus(status, "connect failed");
dgMod.doIt();
MGlobal::executeCommand("parentConstraint -mo " + fkCtlFn.fullPathName() + " " + jointFn.fullPathName() + ";",result);
MObject jointParentConstraintObj;
status = lrutils::getObjFromName(result[0], jointParentConstraintObj);
MyCheckStatus(status, "lrutils::getObjFromName() failed");
MFnTransform jointParentConstraintFn(jointParentConstraintObj);
jointParentConstraintFn.addAttribute(mAttr.create("metaParent", "metaParent"));
status = dgMod.connect( depMetaDataNodeFn.findPlug("FKJointParentConstraints"), jointParentConstraintFn.findPlug("metaParent"));
dgMod.doIt();
//set the display layers for the controller and controller group
MGlobal::executeCommand("editDisplayLayerMembers -noRecurse "+ layerName+" "+ fkCtlFn.fullPathName()+";");
MGlobal::executeCommand("editDisplayLayerMembers -noRecurse "+ layerName+" "+ fkCtlGroupFn.fullPathName()+";");
MGlobal::executeCommand("select -cl;");
}
MStatus inverseSkinCluster::initialize()
{
MStatus status;
MFnNumericAttribute nAttr;
MFnMatrixAttribute mAttr;
MFnMessageAttribute msgAttr;
MFnTypedAttribute tAttr;
aInMesh = tAttr.create( "inMesh", "inMesh", MFnData::kMesh );
tAttr.setStorable( true );
CHECK_MSTATUS_AND_RETURN_IT( addAttribute( aInMesh ) );
aGeomMatrix = mAttr.create( "geomMatrix", "geomMatrix" );
tAttr.setCached( false );
CHECK_MSTATUS_AND_RETURN_IT( addAttribute( aGeomMatrix ) );
aMatrix = mAttr.create( "matrix", "matrix" );
mAttr.setArray( true );
mAttr.setStorable( true );
mAttr.setUsesArrayDataBuilder( true );
CHECK_MSTATUS_AND_RETURN_IT( addAttribute( aMatrix ) );
aBindPreMatrix = mAttr.create( "bindPreMatrix", "bindPreMatrix" );
mAttr.setArray( true );
mAttr.setStorable( true );
mAttr.setUsesArrayDataBuilder( true );
CHECK_MSTATUS_AND_RETURN_IT( addAttribute( aBindPreMatrix ) );
aUpdateMatrix = nAttr.create( "updateMatrix", "updateMatrix", MFnNumericData::kBoolean, false );
nAttr.setStorable( false );
CHECK_MSTATUS_AND_RETURN_IT( addAttribute( aUpdateMatrix ) );
aTargetSkinCluster = msgAttr.create( "targetSkinCluster", "targetSkinCluster" );
CHECK_MSTATUS_AND_RETURN_IT( addAttribute( aTargetSkinCluster ) );
aUpdateWeightList = nAttr.create( "updateWeightList", "updateWeightList", MFnNumericData::kBoolean, false );
nAttr.setStorable( false );
CHECK_MSTATUS_AND_RETURN_IT( addAttribute( aUpdateWeightList ) );
CHECK_MSTATUS_AND_RETURN_IT( attributeAffects( aInMesh, outputGeom ) );
CHECK_MSTATUS_AND_RETURN_IT( attributeAffects( aGeomMatrix, outputGeom ) );
CHECK_MSTATUS_AND_RETURN_IT( attributeAffects( aMatrix, outputGeom ) );
CHECK_MSTATUS_AND_RETURN_IT( attributeAffects( aBindPreMatrix, outputGeom ) );
CHECK_MSTATUS_AND_RETURN_IT( attributeAffects( aUpdateMatrix, outputGeom ) );
CHECK_MSTATUS_AND_RETURN_IT( attributeAffects( aUpdateWeightList, outputGeom ) );
CHECK_MSTATUS_AND_RETURN_IT( attributeAffects( aTargetSkinCluster, outputGeom ) );
CHECK_MSTATUS_AND_RETURN_IT( attributeAffects( aMatrix, outputGeom ) );
return MS::kSuccess;
}
std::vector<MObject> lrutils::buildSkeletonFromGuide(std::vector<MVectorArray> locations, MString prefix, MPlug metaDataPlug, MObject metaParentJoint, MString layerName) {
MDGModifier dgMod;
MStatus status;
std::vector<MObject> joints;
MFnMessageAttribute mAttr;
MObject parentJoint;
unsigned int jointNum = 0;
for (std::vector<MVectorArray>::iterator it = locations.begin(); it != locations.end(); ++it) {
MVectorArray location = *it;
MObject joint = createJointFromLocation(location, prefix, jointNum, parentJoint);
joints.push_back(joint);
MFnTransform jointFn( joint );
//add metaParent attributes to joint
if(!metaDataPlug.isNull()) {
MObject jointAttr = mAttr.create("metaParent", "metaParent");
jointFn.addAttribute(jointAttr);
//connect the metaparent attribute to the MDSpine node
status = dgMod.connect( metaDataPlug, jointFn.findPlug("metaParent") );
MyCheckStatus(status, "connect failed");
dgMod.doIt();
}
//if layer name is provided, add the joint to that display layer
if(layerName != "") {
MGlobal::executeCommand("editDisplayLayerMembers -noRecurse "+ layerName+" "+ jointFn.name()+";");
}
parentJoint = joint;
jointNum++;
}
//orient the joint chain
MFnTransform topJointFn(joints.at(0));
MGlobal::executeCommand("joint -e -zso -oj \"xyz\" -sao \"yup\" -ch " + topJointFn.fullPathName() + ";");
//if meta parent joint is not null, parent first joint to it
if(!metaParentJoint.isNull()) {
MFnTransform firstJointFn(joints.at(0));
MFnTransform metaParentJointFn(metaParentJoint);
MGlobal::executeCommand("parent " + firstJointFn.fullPathName() + " " + metaParentJointFn.fullPathName() + ";");
//orient the parent joint
MGlobal::executeCommand("joint -e -zso -oj \"xyz\" -sao \"yup\" -ch " + metaParentJointFn.fullPathName() + ";");
}
return joints;
}
MStatus nailConstraintNode::initialize()
{
MStatus status;
MFnMessageAttribute fnMsgAttr;
MFnNumericAttribute fnNumericAttr;
MFnMatrixAttribute fnMatrixAttr;
ia_rigidBody = fnMsgAttr.create("inRigidBody", "inrb", &status);
MCHECKSTATUS(status, "creating inRigidBody attribute")
status = addAttribute(ia_rigidBody);
MCHECKSTATUS(status, "adding inRigidBody attribute")
ia_damping = fnNumericAttr.create("damping", "dmp", MFnNumericData::kDouble, 1.0, &status);
MCHECKSTATUS(status, "creating damping attribute")
fnNumericAttr.setKeyable(true);
status = addAttribute(ia_damping);
MCHECKSTATUS(status, "adding damping attribute")
ca_constraint = fnNumericAttr.create("ca_constraint", "caco", MFnNumericData::kBoolean, 0, &status);
MCHECKSTATUS(status, "creating ca_constraint attribute")
fnNumericAttr.setConnectable(false);
fnNumericAttr.setHidden(true);
fnNumericAttr.setStorable(false);
fnNumericAttr.setKeyable(false);
status = addAttribute(ca_constraint);
MCHECKSTATUS(status, "adding ca_constraint attribute")
ca_constraintParam = fnNumericAttr.create("ca_constraintParam", "cacop", MFnNumericData::kBoolean, 0, &status);
MCHECKSTATUS(status, "creating ca_constraintParam attribute")
fnNumericAttr.setConnectable(false);
fnNumericAttr.setHidden(true);
fnNumericAttr.setStorable(false);
fnNumericAttr.setKeyable(false);
status = addAttribute(ca_constraintParam);
MCHECKSTATUS(status, "adding ca_constraintParam attribute")
status = attributeAffects(ia_rigidBody, ca_constraint);
MCHECKSTATUS(status, "adding attributeAffects(ia_rigidBody, ca_constraint)")
status = attributeAffects(ia_rigidBody, ca_constraintParam);
MCHECKSTATUS(status, "adding attributeAffects(ia_rigidBody, ca_constraintParam)")
status = attributeAffects(ia_damping, ca_constraintParam);
MCHECKSTATUS(status, "adding attributeAffects(ia_damping, ca_constraintParam)")
return MS::kSuccess;
}
MStatus MayaRenderGlobalsNode::initialize()
{
MFnNumericAttribute nAttr;
MFnTypedAttribute tAttr;
MFnGenericAttribute gAttr;
MFnEnumAttribute eAttr;
MFnMessageAttribute mAttr;
MStatus stat = MStatus::kSuccess;
filtertype = eAttr.create("filtertype", "filtertype", 0, &stat);
CHECK_MSTATUS(addAttribute( filtertype ));
imageFormat = eAttr.create("imageFormat", "imageFormat", 0, &stat);
CHECK_MSTATUS(addAttribute( imageFormat ));
sceneScale = nAttr.create("sceneScale", "sceneScale", MFnNumericData::kFloat, 1.0f);
CHECK_MSTATUS(addAttribute( sceneScale ));
useSunLightConnection = nAttr.create("useSunLightConnection", "useSunLightConnection", MFnNumericData::kBoolean, false);
CHECK_MSTATUS(addAttribute( useSunLightConnection ));
exportSceneFile = nAttr.create("exportSceneFile", "exportSceneFile", MFnNumericData::kBoolean, false);
CHECK_MSTATUS(addAttribute( exportSceneFile ));
exportSceneFileName = tAttr.create("exportSceneFileName", "exportSceneFileName", MFnNumericData::kString);
tAttr.setUsedAsFilename(true);
CHECK_MSTATUS(addAttribute( exportSceneFileName ));
// sampling adaptive
minSamples = nAttr.create("minSamples", "minSamples", MFnNumericData::kInt, 1);
CHECK_MSTATUS(addAttribute( minSamples ));
maxSamples = nAttr.create("maxSamples", "maxSamples", MFnNumericData::kInt, 16);
CHECK_MSTATUS(addAttribute( maxSamples ));
// sampling raster based
samplesX = nAttr.create("samplesX", "samplesX", MFnNumericData::kInt, 3);
CHECK_MSTATUS(addAttribute( samplesX ));
samplesY = nAttr.create("samplesY", "samplesY", MFnNumericData::kInt, 3);
CHECK_MSTATUS(addAttribute( samplesY ));
doMotionBlur = nAttr.create("doMotionBlur", "doMotionBlur", MFnNumericData::kBoolean, false);
CHECK_MSTATUS(addAttribute( doMotionBlur ));
motionBlurRange = nAttr.create("motionBlurRange", "motionBlurRange", MFnNumericData::kFloat, 0.4);
CHECK_MSTATUS(addAttribute( motionBlurRange ));
motionBlurType = eAttr.create("motionBlurType", "motionBlurType", 0, &stat);
stat = eAttr.addField( "Center", 0 );
stat = eAttr.addField( "FrameStart", 1 );
stat = eAttr.addField( "FrameEnd", 2 );
CHECK_MSTATUS(addAttribute( motionBlurType ));
doDof = nAttr.create("doDof", "doDof", MFnNumericData::kBoolean, false);
CHECK_MSTATUS(addAttribute( doDof ));
xftimesamples = nAttr.create("xftimesamples", "xftimesamples", MFnNumericData::kInt, 2);
CHECK_MSTATUS(addAttribute(xftimesamples));
geotimesamples = nAttr.create("geotimesamples", "geotimesamples", MFnNumericData::kInt, 2);
CHECK_MSTATUS(addAttribute(geotimesamples));
MString numCpu = getenv("NUMBER_OF_PROCESSORS");
int numberOfProcessors = numCpu.asInt();
threads = nAttr.create("threads", "threads", MFnNumericData::kInt, numberOfProcessors);
nAttr.setMin(1);
CHECK_MSTATUS(addAttribute( threads ));
translatorVerbosity = eAttr.create("translatorVerbosity", "translatorVerbosity", 2, &stat);
stat = eAttr.addField( "Info", 0 );
stat = eAttr.addField( "Error", 1 );
stat = eAttr.addField( "Warning", 2 );
stat = eAttr.addField( "Progress", 3 );
stat = eAttr.addField( "Debug", 4 );
stat = eAttr.addField( "None", 5 );
CHECK_MSTATUS(addAttribute( translatorVerbosity ));
rendererVerbosity = nAttr.create("rendererVerbosity", "rendererVerbosity", MFnNumericData::kInt, 2);
CHECK_MSTATUS(addAttribute( rendererVerbosity ));
detectShapeDeform = nAttr.create("detectShapeDeform", "detectShapeDeform", MFnNumericData::kBoolean, true);
CHECK_MSTATUS(addAttribute( detectShapeDeform ));
filtersize = nAttr.create("filtersize", "filtersize", MFnNumericData::kInt, 3);
CHECK_MSTATUS(addAttribute( filtersize ));
tilesize = nAttr.create("tilesize", "tilesize", MFnNumericData::kInt, 64);
CHECK_MSTATUS(addAttribute( tilesize ));
basePath = tAttr.create("basePath", "basePath", MFnNumericData::kString);
CHECK_MSTATUS(addAttribute( basePath ));
imagePath = tAttr.create("imagePath", "imagePath", MFnNumericData::kString);
CHECK_MSTATUS(addAttribute( imagePath ));
imageName = tAttr.create("imageName", "imageName", MFnNumericData::kString);
CHECK_MSTATUS(addAttribute( imageName ));
gamma = nAttr.create("gamma", "gamma", MFnNumericData::kFloat, 1.0f);
CHECK_MSTATUS(addAttribute( gamma ));
maxTraceDepth = nAttr.create("maxTraceDepth", "maxTraceDepth", MFnNumericData::kInt, 4);
CHECK_MSTATUS(addAttribute( maxTraceDepth ));
sunLightConnection = mAttr.create("sunLightConnection", "sunLightConnection");
CHECK_MSTATUS(addAttribute( sunLightConnection ));
adaptiveSampling = nAttr.create("adaptiveSampling", "adaptiveSampling", MFnNumericData::kBoolean, false);
CHECK_MSTATUS(addAttribute( adaptiveSampling ));
optimizedTexturePath = tAttr.create("optimizedTexturePath", "optimizedTexturePath", MFnNumericData::kString);
tAttr.setUsedAsFilename(true);
CHECK_MSTATUS(addAttribute( optimizedTexturePath ));
useOptimizedTextures = nAttr.create("useOptimizedTextures", "useOptimizedTextures", MFnNumericData::kBoolean, false);
CHECK_MSTATUS(addAttribute( useOptimizedTextures ));
exrDataTypeHalf = nAttr.create("exrDataTypeHalf", "exrDataTypeHalf", MFnNumericData::kBoolean, false);
CHECK_MSTATUS(addAttribute(exrDataTypeHalf));
exrMergeChannels = nAttr.create("exrMergeChannels", "exrMergeChannels", MFnNumericData::kBoolean, true);
CHECK_MSTATUS(addAttribute(exrMergeChannels));
return MStatus::kSuccess;
}
MStatus mtmEnvLight::initialize()
{
MFnTypedAttribute tAttr;
MFnNumericAttribute nAttr;
MFnLightDataAttribute lAttr;
MFnEnumAttribute eAttr;
MFnMessageAttribute mAttr;
MStatus stat;
//aColor = nAttr.createColor( "color", "c" );
//CHECK_MSTATUS ( nAttr.setKeyable(true) );
//CHECK_MSTATUS ( nAttr.setStorable(true) );
//CHECK_MSTATUS ( nAttr.setDefault(0.0f, 0.58824f, 0.644f) );
aLightColor = nAttr.createColor( "lightColor", "lightColor" );
CHECK_MSTATUS ( nAttr.setKeyable(true) );
CHECK_MSTATUS ( nAttr.setStorable(true) );
nAttr.setDefault(0.7f, 0.58824f, 0.344f);
aShadowColor = nAttr.createColor( "shadowColor", "sc" );
CHECK_MSTATUS ( nAttr.setKeyable(true) );
CHECK_MSTATUS ( nAttr.setStorable(true) );
CHECK_MSTATUS ( nAttr.setDefault(0.0f, 0.0f, 0.0f) );
aPosition = nAttr.createPoint( "position", "pos" );
CHECK_MSTATUS ( nAttr.setKeyable(true) );
CHECK_MSTATUS ( nAttr.setStorable(true) );
aInputDirection = nAttr.createPoint( "inputDirection", "id" );
CHECK_MSTATUS ( nAttr.setKeyable(true) );
CHECK_MSTATUS ( nAttr.setStorable(true) );
CHECK_MSTATUS ( nAttr.setDefault(-1.0f, 0.0f, 0.0f) );
aInputAmbient = nAttr.create( "ambientOn", "an", MFnNumericData::kBoolean);
CHECK_MSTATUS ( nAttr.setKeyable(true) );
CHECK_MSTATUS ( nAttr.setStorable(true) );
CHECK_MSTATUS ( nAttr.setHidden(false) );
CHECK_MSTATUS ( nAttr.setDefault(true) );
aInputDiffuse = nAttr.create( "emitDiffuse", "dn", MFnNumericData::kBoolean);
CHECK_MSTATUS ( nAttr.setKeyable(true) );
CHECK_MSTATUS ( nAttr.setStorable(true) );
CHECK_MSTATUS ( nAttr.setHidden(false) );
CHECK_MSTATUS ( nAttr.setDefault(true) );
aInputSpecular = nAttr.create( "emitSpecular", "sn", MFnNumericData::kBoolean);
CHECK_MSTATUS ( nAttr.setKeyable(true) );
CHECK_MSTATUS ( nAttr.setStorable(true) );
CHECK_MSTATUS ( nAttr.setHidden(false) );
CHECK_MSTATUS ( nAttr.setDefault(true) );
aIntensity = nAttr.create( "intensity", "i", MFnNumericData::kFloat);
CHECK_MSTATUS ( nAttr.setKeyable(true) );
CHECK_MSTATUS ( nAttr.setStorable(true) );
CHECK_MSTATUS ( nAttr.setHidden(false) );
CHECK_MSTATUS ( nAttr.setDefault(1.0f) );
samplingquality = nAttr.create( "samplingquality", "samplingquality", MFnNumericData::kFloat, 1.0);
envmap = tAttr.create( "envmap", "envmap", MFnNumericData::kString);
tAttr.setUsedAsFilename(true);
areamap = tAttr.create( "areamap", "areamap", MFnNumericData::kString);
tAttr.setUsedAsFilename(true);
areafullsphere = nAttr.create( "areafullsphere", "areafullsphere", MFnNumericData::kBoolean, true);
envintensity = nAttr.createColor( "envintensity", "envintensity" );
nAttr.setDefault(1.0f, 1.0f, 1.0f);
raybackground = nAttr.create( "raybackground", "raybackground", MFnNumericData::kBoolean, false);
castshadow = nAttr.create( "castshadow", "castshadow", MFnNumericData::kBoolean, true);
envtype = eAttr.create( "envtype", "envtype", 0, &stat);
stat = eAttr.addField( "Direct Lighting", 0 );
stat = eAttr.addField( "Ambient Occlusion", 1 );
stat = eAttr.addField( "Full Irradiance", 2 );
stat = eAttr.addField( "Raytrace Background", 3 );
eAttr.setDefault(0);
doraysamples = nAttr.create( "doraysamples", "doraysamples", MFnNumericData::kBoolean, false);
doadaptive = nAttr.create( "doadaptive", "doadaptive", MFnNumericData::kBoolean, false);
domaxdist = nAttr.create( "domaxdist", "domaxdist", MFnNumericData::kBoolean, false);
maxdist = nAttr.create( "maxdist", "maxdist", MFnNumericData::kFloat, 10.0);
coneangle = nAttr.create( "coneangle", "coneangle", MFnNumericData::kFloat, 45.0);
envtint = nAttr.createColor( "envtint", "envtint" );
nAttr.setDefault(1.0f, 1.0f, 1.0f);
shadowI = nAttr.create( "shadowI", "shadowI", MFnNumericData::kFloat, 1.0);
samples = nAttr.create( "samples", "samples", MFnNumericData::kInt, 32);
MFnStringData fnStringData;
MObject defaultObjectMask;
defaultObjectMask = fnStringData.create( "*" );
objectmask = tAttr.create( "objectmask", "objectmask", MFnNumericData::kString, defaultObjectMask);
usePortalGeometry = nAttr.create( "usePortalGeometry", "usePortalGeometry", MFnNumericData::kBoolean, false);
portalGeometry = mAttr.create( "portalGeometry", "portalGeometry");
mAttr.setConnectable(true);
mAttr.accepts(MFnData::kAny);
// Outputs
aLightDirection = nAttr.createPoint( "lightDirection", "ld" );
CHECK_MSTATUS ( nAttr.setStorable(false) );
CHECK_MSTATUS ( nAttr.setHidden(true) );
CHECK_MSTATUS ( nAttr.setReadable(true) );
CHECK_MSTATUS ( nAttr.setWritable(false) );
CHECK_MSTATUS ( nAttr.setDefault(-1.0f, 0.0f, 0.0f) );
aLightIntensity = nAttr.createColor( "lightIntensity", "li" );
CHECK_MSTATUS ( nAttr.setStorable(false) );
CHECK_MSTATUS ( nAttr.setHidden(true) );
CHECK_MSTATUS ( nAttr.setReadable(true) );
CHECK_MSTATUS ( nAttr.setWritable(false) );
CHECK_MSTATUS ( nAttr.setDefault(1.0f, 0.5f, 0.2f) );
aLightAmbient = nAttr.create( "lightAmbient", "la",
MFnNumericData::kBoolean);
CHECK_MSTATUS ( nAttr.setStorable(false) );
CHECK_MSTATUS ( nAttr.setHidden(true) );
CHECK_MSTATUS ( nAttr.setReadable(true) );
CHECK_MSTATUS ( nAttr.setWritable(false) );
nAttr.setDefault(true);
aLightDiffuse = nAttr.create( "lightDiffuse", "ldf",
MFnNumericData::kBoolean);
CHECK_MSTATUS ( nAttr.setStorable(false) );
CHECK_MSTATUS ( nAttr.setHidden(true) );
CHECK_MSTATUS ( nAttr.setReadable(true) );
CHECK_MSTATUS ( nAttr.setWritable(false) );
CHECK_MSTATUS ( nAttr.setDefault(true) );
aLightSpecular = nAttr.create( "lightSpecular", "ls",
MFnNumericData::kBoolean);
CHECK_MSTATUS ( nAttr.setStorable(false) );
CHECK_MSTATUS ( nAttr.setHidden(true) );
CHECK_MSTATUS ( nAttr.setReadable(true) );
CHECK_MSTATUS ( nAttr.setWritable(false) );
CHECK_MSTATUS ( nAttr.setDefault(true) );
aLightShadowFraction = nAttr.create("lightShadowFraction","lsf",
MFnNumericData::kFloat);
CHECK_MSTATUS ( nAttr.setStorable(false) );
CHECK_MSTATUS ( nAttr.setHidden(true) );
CHECK_MSTATUS ( nAttr.setReadable(true) );
CHECK_MSTATUS ( nAttr.setWritable(false) );
CHECK_MSTATUS ( nAttr.setDefault(0.0f) );
aPreShadowIntensity = nAttr.create("preShadowIntensity","psi",
MFnNumericData::kFloat);
CHECK_MSTATUS ( nAttr.setStorable(false) );
CHECK_MSTATUS ( nAttr.setHidden(true) );
CHECK_MSTATUS ( nAttr.setReadable(true) );
CHECK_MSTATUS ( nAttr.setWritable(false) );
CHECK_MSTATUS ( nAttr.setDefault(0.0f) );
aLightBlindData = nAttr.createAddr("lightBlindData","lbld");
CHECK_MSTATUS ( nAttr.setStorable(false) );
CHECK_MSTATUS ( nAttr.setHidden(true) );
CHECK_MSTATUS ( nAttr.setReadable(true) );
CHECK_MSTATUS ( nAttr.setWritable(false) );
aLightData = lAttr.create( "lightData", "ltd",
aLightDirection, aLightIntensity,
aLightAmbient,
aLightDiffuse, aLightSpecular,
aLightShadowFraction,
aPreShadowIntensity, aLightBlindData);
CHECK_MSTATUS ( nAttr.setReadable(true) );
CHECK_MSTATUS ( nAttr.setWritable(false) );
CHECK_MSTATUS ( lAttr.setStorable(false) );
CHECK_MSTATUS ( lAttr.setHidden(true) );
lAttr.setDefault(-1.0f, 0.0f, 0.0f, 1.0f, 0.5f, 0.2f, true, true,
true, 0.0f, 1.0f, NULL);
CHECK_MSTATUS ( addAttribute(coneangle) );
CHECK_MSTATUS ( addAttribute(samples) );
CHECK_MSTATUS ( addAttribute(objectmask) );
CHECK_MSTATUS ( addAttribute(shadowI) );
CHECK_MSTATUS ( addAttribute(envtint) );
CHECK_MSTATUS ( addAttribute(maxdist) );
CHECK_MSTATUS ( addAttribute(domaxdist) );
CHECK_MSTATUS ( addAttribute(doadaptive) );
CHECK_MSTATUS ( addAttribute(doraysamples) );
CHECK_MSTATUS ( addAttribute(envtype) );
CHECK_MSTATUS ( addAttribute(castshadow) );
CHECK_MSTATUS ( addAttribute(raybackground) );
CHECK_MSTATUS ( addAttribute(envintensity) );
CHECK_MSTATUS ( addAttribute(areafullsphere) );
CHECK_MSTATUS ( addAttribute(areamap) );
CHECK_MSTATUS ( addAttribute(envmap) );
CHECK_MSTATUS ( addAttribute(samplingquality) );
CHECK_MSTATUS ( addAttribute(usePortalGeometry) );
CHECK_MSTATUS ( addAttribute(portalGeometry) );
//CHECK_MSTATUS ( addAttribute(aColor) );
CHECK_MSTATUS ( addAttribute(aLightColor) );
CHECK_MSTATUS ( addAttribute(aShadowColor) );
CHECK_MSTATUS ( addAttribute(aPosition) );
CHECK_MSTATUS ( addAttribute(aInputDirection) );
CHECK_MSTATUS ( addAttribute(aInputAmbient) );
CHECK_MSTATUS ( addAttribute(aInputDiffuse) );
CHECK_MSTATUS ( addAttribute(aInputSpecular) );
CHECK_MSTATUS ( addAttribute(aIntensity) );
CHECK_MSTATUS ( addAttribute(aLightData) );
CHECK_MSTATUS ( attributeAffects (aLightIntensity, aLightData) );
CHECK_MSTATUS ( attributeAffects (aLightDirection, aLightData) );
CHECK_MSTATUS ( attributeAffects (aLightAmbient, aLightData) );
CHECK_MSTATUS ( attributeAffects (aLightDiffuse, aLightData) );
CHECK_MSTATUS ( attributeAffects (aLightSpecular, aLightData) );
CHECK_MSTATUS ( attributeAffects (aLightShadowFraction, aLightData) );
CHECK_MSTATUS ( attributeAffects (aPreShadowIntensity, aLightData) );
CHECK_MSTATUS ( attributeAffects (aLightBlindData, aLightData) );
CHECK_MSTATUS ( attributeAffects (aLightData, aLightData) );
//CHECK_MSTATUS ( attributeAffects (aColor, aLightData) );
CHECK_MSTATUS ( attributeAffects (aPosition, aLightData) );
CHECK_MSTATUS ( attributeAffects (aInputDirection, aLightData) );
CHECK_MSTATUS ( attributeAffects (aInputAmbient, aLightData) );
CHECK_MSTATUS ( attributeAffects (aInputDiffuse, aLightData) );
CHECK_MSTATUS ( attributeAffects (aInputSpecular, aLightData) );
CHECK_MSTATUS ( attributeAffects (aIntensity, aLightData) );
return MS::kSuccess;
}
MStatus hingeConstraintNode::initialize()
{
MStatus status;
MFnMessageAttribute fnMsgAttr;
MFnNumericAttribute fnNumericAttr;
MFnMatrixAttribute fnMatrixAttr;
ia_rigidBody = fnMsgAttr.create("inRigidBody", "inrb", &status);
MCHECKSTATUS(status, "creating inRigidBody attribute")
status = addAttribute(ia_rigidBody);
MCHECKSTATUS(status, "adding inRigidBody attribute")
ia_damping = fnNumericAttr.create("damping", "dmp", MFnNumericData::kDouble, 1.0, &status);
MCHECKSTATUS(status, "creating damping attribute")
fnNumericAttr.setKeyable(true);
status = addAttribute(ia_damping);
MCHECKSTATUS(status, "adding damping attribute")
ia_lowerLimit = fnNumericAttr.create("lowerLimit", "llmt", MFnNumericData::kDouble, -1.57, &status);
MCHECKSTATUS(status, "creating lower limit attribute")
fnNumericAttr.setKeyable(true);
status = addAttribute(ia_lowerLimit);
MCHECKSTATUS(status, "adding lower limit attribute")
ia_upperLimit = fnNumericAttr.create("upperLimit", "ulmt", MFnNumericData::kDouble, 1.57, &status);
MCHECKSTATUS(status, "creating upper limit attribute")
fnNumericAttr.setKeyable(true);
status = addAttribute(ia_upperLimit);
MCHECKSTATUS(status, "adding upper limit attribute")
ia_limitSoftness = fnNumericAttr.create("limitSoftness", "lmSo", MFnNumericData::kDouble, 0.9, &status);
MCHECKSTATUS(status, "creating limitSoftness attribute")
fnNumericAttr.setKeyable(true);
status = addAttribute(ia_limitSoftness);
MCHECKSTATUS(status, "adding limitSoftness attribute")
ia_biasFactor = fnNumericAttr.create("biasFactor", "biFa", MFnNumericData::kDouble, 0.3, &status);
MCHECKSTATUS(status, "creating biasFactor attribute")
fnNumericAttr.setKeyable(true);
status = addAttribute(ia_biasFactor);
MCHECKSTATUS(status, "adding biasFactor attribute")
ia_relaxationFactor = fnNumericAttr.create("relaxationFactor", "reFa", MFnNumericData::kDouble, 1.0, &status);
MCHECKSTATUS(status, "creating relaxationFactor attribute")
fnNumericAttr.setKeyable(true);
status = addAttribute(ia_relaxationFactor);
MCHECKSTATUS(status, "adding relaxationFactor attribute")
ia_hingeAxis = fnNumericAttr.createPoint("hingeAxis", "hgAx", &status);
status = fnNumericAttr.setDefault((double) 0.0, (double) 0.0, (double) 1.0);
MCHECKSTATUS(status, "creating hingeAxis attribute")
status = addAttribute(ia_hingeAxis);
MCHECKSTATUS(status, "adding hingeAxis attribute")
//------------------------------------------------------------------------------
ia_enableAngularMotor = fnNumericAttr.create("enableAngularMotor", "enAM", MFnNumericData::kBoolean, false, &status);
MCHECKSTATUS(status, "creating enableAngularMotor attribute")
status = addAttribute(ia_enableAngularMotor);
MCHECKSTATUS(status, "adding enableAngularMotor attribute")
ia_motorTargetVelocity = fnNumericAttr.create("motorTargetVelocity", "mTV", MFnNumericData::kDouble, 1, &status);
MCHECKSTATUS(status, "creating motorTargetVelocity attribute")
fnNumericAttr.setKeyable(true);
status = addAttribute(ia_motorTargetVelocity);
MCHECKSTATUS(status, "adding motorTargetVelocity attribute")
ia_maxMotorImpulse = fnNumericAttr.create("maxMotorImpulse", "mMI", MFnNumericData::kDouble, 1, &status);
MCHECKSTATUS(status, "creating maxMotorImpulse attribute")
fnNumericAttr.setKeyable(true);
status = addAttribute(ia_maxMotorImpulse);
MCHECKSTATUS(status, "adding maxMotorImpulse attribute")
//------------------------------------------------------------------------------
ca_constraint = fnNumericAttr.create("ca_constraint", "caco", MFnNumericData::kBoolean, 0, &status);
MCHECKSTATUS(status, "creating ca_constraint attribute")
fnNumericAttr.setConnectable(false);
fnNumericAttr.setHidden(true);
fnNumericAttr.setStorable(false);
fnNumericAttr.setKeyable(false);
status = addAttribute(ca_constraint);
MCHECKSTATUS(status, "adding ca_constraint attribute")
ca_constraintParam = fnNumericAttr.create("ca_constraintParam", "cacop", MFnNumericData::kBoolean, 0, &status);
MCHECKSTATUS(status, "creating ca_constraintParam attribute")
fnNumericAttr.setConnectable(false);
fnNumericAttr.setHidden(true);
fnNumericAttr.setStorable(false);
fnNumericAttr.setKeyable(false);
status = addAttribute(ca_constraintParam);
MCHECKSTATUS(status, "adding ca_constraintParam attribute")
status = attributeAffects(ia_rigidBody, ca_constraint);
MCHECKSTATUS(status, "adding attributeAffects(ia_rigidBody, ca_constraint)")
status = attributeAffects(ia_rigidBody, ca_constraintParam);
MCHECKSTATUS(status, "adding attributeAffects(ia_rigidBody, ca_constraintParam)")
status = attributeAffects(ia_damping, ca_constraintParam);
MCHECKSTATUS(status, "adding attributeAffects(ia_damping, ca_constraintParam)")
status = attributeAffects(ia_lowerLimit, ca_constraintParam);
MCHECKSTATUS(status, "adding attributeAffects(ia_lowerLimit, ca_constraintParam)")
status = attributeAffects(ia_upperLimit, ca_constraintParam);
MCHECKSTATUS(status, "adding attributeAffects(ia_upperLimit, ca_constraintParam)")
status = attributeAffects(ia_limitSoftness, ca_constraintParam);
MCHECKSTATUS(status, "adding attributeAffects(ia_limitSoftness, ca_constraintParam)")
status = attributeAffects(ia_biasFactor, ca_constraintParam);
MCHECKSTATUS(status, "adding attributeAffects(ia_biasFactor, ca_constraintParam)")
status = attributeAffects(ia_relaxationFactor, ca_constraintParam);
MCHECKSTATUS(status, "adding attributeAffects(ia_relaxationFactor, ca_constraintParam)")
status = attributeAffects(ia_hingeAxis, ca_constraintParam);
MCHECKSTATUS(status, "adding attributeAffects(ia_hingeAxis, ca_constraintParam)")
status = attributeAffects(ia_enableAngularMotor, ca_constraintParam);
MCHECKSTATUS(status, "adding attributeAffects(ia_enableAngularMotor, ca_constraintParam)")
status = attributeAffects(ia_motorTargetVelocity, ca_constraintParam);
MCHECKSTATUS(status, "adding attributeAffects(ia_motorTargetVelocity, ca_constraintParam)")
status = attributeAffects(ia_maxMotorImpulse, ca_constraintParam);
MCHECKSTATUS(status, "adding attributeAffects(ia_maxMotorImpulse, ca_constraintParam)")
return MS::kSuccess;
}
MStatus Layered::initialize()
{
MFnNumericAttribute nAttr;
MFnLightDataAttribute lAttr;
MFnTypedAttribute tAttr;
MFnGenericAttribute gAttr;
MFnEnumAttribute eAttr;
MFnMessageAttribute mAttr;
MStatus status; // Status will be used to hold the MStatus value
// returned by each api function call. It is important
// to check the status returned by a call to aid in
// debugging. Failed API calls can result in subtle
// errors that can be difficult to track down, you may
// wish to use the CHECK_MSTATUS macro for any API
// call where you do not need to provide your own
// error handling.
//
baseShader = nAttr.createColor("baseShader", "baseShader");
CHECK_MSTATUS(addAttribute(baseShader));
layerWeight = nAttr.create("layerWeight", "layerWeight", MFnNumericData::kFloat, 0, &status);
nAttr.setArray(true);
CHECK_MSTATUS(addAttribute(layerWeight));
layerTexture = mAttr.create("layerTexture", "layerTexture");
mAttr.setArray(true);
CHECK_MSTATUS(addAttribute(layerTexture));
layerShader = nAttr.createColor("layerShader", "layerShader");
nAttr.setArray(true);
CHECK_MSTATUS(addAttribute(layerShader));
outColor = nAttr.createColor("outColor", "outColor");
CHECK_MSTATUS(addAttribute(outColor));
//---------------------------- automatically created attributes start ------------------------------------
//---------------------------- automatically created attributes end ------------------------------------
aTranslucenceCoeff = nAttr.create("translucenceCoeff", "tc",
MFnNumericData::kFloat, 0, &status);
CHECK_MSTATUS(status);
CHECK_MSTATUS(nAttr.setKeyable(true));
CHECK_MSTATUS(nAttr.setStorable(true));
CHECK_MSTATUS(nAttr.setDefault(0.0f));
aDiffuseReflectivity = nAttr.create("diffuseReflectivity", "drfl",
MFnNumericData::kFloat, 0, &status);
CHECK_MSTATUS(status);
CHECK_MSTATUS(nAttr.setKeyable(true));
CHECK_MSTATUS(nAttr.setStorable(true));
CHECK_MSTATUS(nAttr.setDefault(0.8f));
aColor = nAttr.createColor("color", "c", &status);
CHECK_MSTATUS(status);
CHECK_MSTATUS(nAttr.setKeyable(true));
CHECK_MSTATUS(nAttr.setStorable(true));
CHECK_MSTATUS(nAttr.setDefault(0.0f, 0.58824f, 0.644f));
aIncandescence = nAttr.createColor("incandescence", "ic", &status);
CHECK_MSTATUS(status);
CHECK_MSTATUS(nAttr.setKeyable(true));
CHECK_MSTATUS(nAttr.setStorable(true));
CHECK_MSTATUS(nAttr.setDefault(0.0f, 0.0f, 0.0f));
aInTransparency = nAttr.createColor("transparency", "it", &status);
CHECK_MSTATUS(status);
CHECK_MSTATUS(nAttr.setKeyable(true));
CHECK_MSTATUS(nAttr.setStorable(true));
CHECK_MSTATUS(nAttr.setDefault(0.0f, 0.0f, 0.0f));
CHECK_MSTATUS(nAttr.setHidden(false));
CHECK_MSTATUS(nAttr.setReadable(true));
CHECK_MSTATUS(nAttr.setWritable(false));
aOutTransparency = nAttr.createColor("outTransparency", "ot", &status);
CHECK_MSTATUS(status);
CHECK_MSTATUS(nAttr.setHidden(false));
CHECK_MSTATUS(nAttr.setReadable(true));
CHECK_MSTATUS(nAttr.setWritable(false));
// Camera Normals
//
aNormalCameraX = nAttr.create("normalCameraX", "nx",
MFnNumericData::kFloat, 0, &status);
CHECK_MSTATUS(status);
CHECK_MSTATUS(nAttr.setStorable(false));
CHECK_MSTATUS(nAttr.setDefault(1.0f));
aNormalCameraY = nAttr.create("normalCameraY", "ny",
MFnNumericData::kFloat, 0, &status);
CHECK_MSTATUS(status);
CHECK_MSTATUS(nAttr.setStorable(false));
CHECK_MSTATUS(nAttr.setDefault(1.0f));
aNormalCameraZ = nAttr.create("normalCameraZ", "nz",
MFnNumericData::kFloat, 0, &status);
CHECK_MSTATUS(status);
CHECK_MSTATUS(nAttr.setStorable(false));
CHECK_MSTATUS(nAttr.setDefault(1.0f));
aNormalCamera = nAttr.create("normalCamera", "n", aNormalCameraX,
aNormalCameraY, aNormalCameraZ, &status);
CHECK_MSTATUS(status);
CHECK_MSTATUS(nAttr.setStorable(false));
CHECK_MSTATUS(nAttr.setDefault(1.0f, 1.0f, 1.0f));
CHECK_MSTATUS(nAttr.setHidden(true));
// Light Direction
//
aLightDirectionX = nAttr.create("lightDirectionX", "ldx",
MFnNumericData::kFloat, 0, &status);
CHECK_MSTATUS(status);
CHECK_MSTATUS(nAttr.setStorable(false));
CHECK_MSTATUS(nAttr.setHidden(true));
CHECK_MSTATUS(nAttr.setReadable(true));
CHECK_MSTATUS(nAttr.setWritable(false));
CHECK_MSTATUS(nAttr.setDefault(1.0f));
aLightDirectionY = nAttr.create("lightDirectionY", "ldy",
MFnNumericData::kFloat, 0, &status);
CHECK_MSTATUS(status);
CHECK_MSTATUS(nAttr.setStorable(false));
CHECK_MSTATUS(nAttr.setHidden(true));
CHECK_MSTATUS(nAttr.setReadable(true));
CHECK_MSTATUS(nAttr.setWritable(false));
CHECK_MSTATUS(nAttr.setDefault(1.0f));
aLightDirectionZ = nAttr.create("lightDirectionZ", "ldz",
MFnNumericData::kFloat, 0, &status);
CHECK_MSTATUS(status);
CHECK_MSTATUS(nAttr.setStorable(false));
CHECK_MSTATUS(nAttr.setHidden(true));
CHECK_MSTATUS(nAttr.setReadable(true));
CHECK_MSTATUS(nAttr.setWritable(false));
CHECK_MSTATUS(nAttr.setDefault(1.0f));
aLightDirection = nAttr.create("lightDirection", "ld",
aLightDirectionX, aLightDirectionY, aLightDirectionZ,
&status);
CHECK_MSTATUS(status);
CHECK_MSTATUS(nAttr.setStorable(false));
CHECK_MSTATUS(nAttr.setHidden(true));
CHECK_MSTATUS(nAttr.setReadable(true));
CHECK_MSTATUS(nAttr.setWritable(false));
CHECK_MSTATUS(nAttr.setDefault(1.0f, 1.0f, 1.0f));
// Light Intensity
//
aLightIntensityR = nAttr.create("lightIntensityR", "lir",
MFnNumericData::kFloat, 0, &status);
CHECK_MSTATUS(status);
CHECK_MSTATUS(nAttr.setStorable(false));
CHECK_MSTATUS(nAttr.setHidden(true));
CHECK_MSTATUS(nAttr.setReadable(true));
CHECK_MSTATUS(nAttr.setWritable(false));
CHECK_MSTATUS(nAttr.setDefault(1.0f));
aLightIntensityG = nAttr.create("lightIntensityG", "lig",
MFnNumericData::kFloat, 0, &status);
CHECK_MSTATUS(status);
CHECK_MSTATUS(nAttr.setStorable(false));
CHECK_MSTATUS(nAttr.setHidden(true));
CHECK_MSTATUS(nAttr.setReadable(true));
CHECK_MSTATUS(nAttr.setWritable(false));
CHECK_MSTATUS(nAttr.setDefault(1.0f));
aLightIntensityB = nAttr.create("lightIntensityB", "lib",
MFnNumericData::kFloat, 0, &status);
CHECK_MSTATUS(status);
CHECK_MSTATUS(nAttr.setStorable(false));
CHECK_MSTATUS(nAttr.setHidden(true));
CHECK_MSTATUS(nAttr.setReadable(true));
CHECK_MSTATUS(nAttr.setWritable(false));
CHECK_MSTATUS(nAttr.setDefault(1.0f));
aLightIntensity = nAttr.create("lightIntensity", "li",
aLightIntensityR, aLightIntensityG, aLightIntensityB,
&status);
CHECK_MSTATUS(status);
CHECK_MSTATUS(nAttr.setStorable(false));
CHECK_MSTATUS(nAttr.setHidden(true));
CHECK_MSTATUS(nAttr.setReadable(true));
CHECK_MSTATUS(nAttr.setWritable(false));
CHECK_MSTATUS(nAttr.setDefault(1.0f, 1.0f, 1.0f));
// Light
//
aLightAmbient = nAttr.create("lightAmbient", "la",
MFnNumericData::kBoolean, 0, &status);
CHECK_MSTATUS(status);
CHECK_MSTATUS(nAttr.setStorable(false));
CHECK_MSTATUS(nAttr.setHidden(true));
CHECK_MSTATUS(nAttr.setReadable(true));
CHECK_MSTATUS(nAttr.setWritable(false));
CHECK_MSTATUS(nAttr.setDefault(true));
aLightDiffuse = nAttr.create("lightDiffuse", "ldf",
MFnNumericData::kBoolean, 0, &status);
CHECK_MSTATUS(status);
CHECK_MSTATUS(nAttr.setStorable(false));
CHECK_MSTATUS(nAttr.setHidden(true));
CHECK_MSTATUS(nAttr.setReadable(true));
CHECK_MSTATUS(nAttr.setWritable(false));
CHECK_MSTATUS(nAttr.setDefault(true));
aLightSpecular = nAttr.create("lightSpecular", "ls",
MFnNumericData::kBoolean, 0, &status);
CHECK_MSTATUS(status);
CHECK_MSTATUS(nAttr.setStorable(false));
CHECK_MSTATUS(nAttr.setHidden(true));
CHECK_MSTATUS(nAttr.setReadable(true));
CHECK_MSTATUS(nAttr.setWritable(false));
CHECK_MSTATUS(nAttr.setDefault(false));
aLightShadowFraction = nAttr.create("lightShadowFraction", "lsf",
MFnNumericData::kFloat, 0, &status);
CHECK_MSTATUS(status);
CHECK_MSTATUS(nAttr.setStorable(false));
CHECK_MSTATUS(nAttr.setHidden(true));
CHECK_MSTATUS(nAttr.setReadable(true));
CHECK_MSTATUS(nAttr.setWritable(false));
CHECK_MSTATUS(nAttr.setDefault(1.0f));
aPreShadowIntensity = nAttr.create("preShadowIntensity", "psi",
MFnNumericData::kFloat, 0, &status);
CHECK_MSTATUS(status);
CHECK_MSTATUS(nAttr.setStorable(false));
CHECK_MSTATUS(nAttr.setHidden(true));
CHECK_MSTATUS(nAttr.setReadable(true));
CHECK_MSTATUS(nAttr.setWritable(false));
CHECK_MSTATUS(nAttr.setDefault(1.0f));
aLightBlindData = nAttr.createAddr("lightBlindData", "lbld",
&status);
CHECK_MSTATUS(status);
CHECK_MSTATUS(nAttr.setStorable(false));
CHECK_MSTATUS(nAttr.setHidden(true));
CHECK_MSTATUS(nAttr.setReadable(true));
CHECK_MSTATUS(nAttr.setWritable(false));
aLightData = lAttr.create("lightDataArray", "ltd", aLightDirection,
aLightIntensity, aLightAmbient, aLightDiffuse, aLightSpecular,
aLightShadowFraction, aPreShadowIntensity, aLightBlindData,
&status);
CHECK_MSTATUS(status);
CHECK_MSTATUS(lAttr.setArray(true));
CHECK_MSTATUS(lAttr.setStorable(false));
CHECK_MSTATUS(lAttr.setHidden(true));
CHECK_MSTATUS(lAttr.setDefault(0.0f, 0.0f, 0.0f, 0.0f, 0.0f, 0.0f,
true, true, false, 1.0f, 1.0f, NULL));
// Next we will add the attributes we have defined to the node
//
CHECK_MSTATUS(addAttribute(aTranslucenceCoeff));
CHECK_MSTATUS(addAttribute(aDiffuseReflectivity));
CHECK_MSTATUS(addAttribute(aColor));
CHECK_MSTATUS(addAttribute(aIncandescence));
CHECK_MSTATUS(addAttribute(aInTransparency));
CHECK_MSTATUS(addAttribute(outColor));
CHECK_MSTATUS(addAttribute(aOutTransparency));
CHECK_MSTATUS(addAttribute(aNormalCamera));
// Only add the parent of the compound
CHECK_MSTATUS(addAttribute(aLightData));
CHECK_MSTATUS(attributeAffects(layerTexture, outColor));
CHECK_MSTATUS(attributeAffects(layerWeight, outColor));
CHECK_MSTATUS(attributeAffects(aTranslucenceCoeff, outColor));
CHECK_MSTATUS(attributeAffects(aDiffuseReflectivity, outColor));
CHECK_MSTATUS(attributeAffects(aColor, outColor));
CHECK_MSTATUS(attributeAffects(aInTransparency, aOutTransparency));
CHECK_MSTATUS(attributeAffects(aInTransparency, outColor));
CHECK_MSTATUS(attributeAffects(aIncandescence, outColor));
CHECK_MSTATUS(attributeAffects(aLightIntensityR, outColor));
CHECK_MSTATUS(attributeAffects(aLightIntensityB, outColor));
CHECK_MSTATUS(attributeAffects(aLightIntensityG, outColor));
CHECK_MSTATUS(attributeAffects(aLightIntensity, outColor));
CHECK_MSTATUS(attributeAffects(aNormalCameraX, outColor));
CHECK_MSTATUS(attributeAffects(aNormalCameraY, outColor));
CHECK_MSTATUS(attributeAffects(aNormalCameraZ, outColor));
CHECK_MSTATUS(attributeAffects(aNormalCamera, outColor));
CHECK_MSTATUS(attributeAffects(aLightDirectionX, outColor));
CHECK_MSTATUS(attributeAffects(aLightDirectionY, outColor));
CHECK_MSTATUS(attributeAffects(aLightDirectionZ, outColor));
CHECK_MSTATUS(attributeAffects(aLightDirection, outColor));
CHECK_MSTATUS(attributeAffects(aLightAmbient, outColor));
CHECK_MSTATUS(attributeAffects(aLightSpecular, outColor));
CHECK_MSTATUS(attributeAffects(aLightDiffuse, outColor));
CHECK_MSTATUS(attributeAffects(aLightShadowFraction, outColor));
CHECK_MSTATUS(attributeAffects(aPreShadowIntensity, outColor));
CHECK_MSTATUS(attributeAffects(aLightBlindData, outColor));
CHECK_MSTATUS(attributeAffects(aLightData, outColor));
return( MS::kSuccess );
}
MStatus liqDisplacementNode::initialize()
{
MFnTypedAttribute tAttr;
MFnStringData tDefault;
MFnNumericAttribute nAttr;
MFnMessageAttribute mAttr;
MFnEnumAttribute eAttr;
MStatus status;
// Create input attributes
aRmanShader = tAttr.create( MString("rmanShader"), MString("rms"), MFnData::kString, aRmanShader, &status );
MAKE_INPUT(tAttr);
aRmanShaderLong = tAttr.create( MString("rmanShaderLong"), MString("rml"), MFnData::kString, aRmanShaderLong, &status );
MAKE_INPUT(tAttr);
aRmanShaderLif = tAttr.create( MString("rmanShaderLif"), MString("lif"), MFnData::kString, aRmanShaderLif, &status );
MAKE_INPUT(tAttr);
aRmanParams = tAttr.create( MString("rmanParams"), MString("rpr"), MFnData::kStringArray, aRmanParams, &status );
MAKE_INPUT(tAttr);
aRmanDetails = tAttr.create( MString("rmanDetails"), MString("rdt"), MFnData::kStringArray, aRmanDetails, &status );
MAKE_INPUT(tAttr);
aRmanTypes = tAttr.create( MString("rmanTypes"), MString("rty"), MFnData::kStringArray, aRmanTypes, &status );
MAKE_INPUT(tAttr);
aRmanDefaults = tAttr.create( MString("rmanDefaults"), MString("rdf"), MFnData::kStringArray, aRmanDefaults, &status );
MAKE_INPUT(tAttr);
aRmanArraySizes = tAttr.create( MString("rmanArraySizes"), MString("ras"), MFnData::kIntArray, aRmanArraySizes, &status );
MAKE_INPUT(tAttr);
aRmanLifCmds = tAttr.create( MString("rmanLifCmds"), MString("rlc"), MFnData::kStringArray, aRmanLifCmds, &status );
MAKE_INPUT(tAttr);
aPreviewPrimitive = eAttr.create( "previewPrimitive", "pvp", 7, &status );
eAttr.addField( "Sphere", 0 );
eAttr.addField( "Cube", 1 );
eAttr.addField( "Cylinder", 2 );
eAttr.addField( "Torus", 3 );
eAttr.addField( "Plane", 4 );
eAttr.addField( "Teapot", 5 );
eAttr.addField( "Custom", 6 );
eAttr.addField( "(globals)",7 );
MAKE_NONKEYABLE_INPUT(eAttr);
CHECK_MSTATUS(eAttr.setConnectable(false));
aPreviewCustomPrimitive = tAttr.create( MString("previewCustomPrimitive"), MString("pcp"), MFnData::kString, aPreviewCustomPrimitive, &status );
MAKE_INPUT(tAttr);
aPreviewCustomBackplane = tAttr.create( MString("previewCustomBackplane"), MString("pcb"), MFnData::kString, aPreviewCustomBackplane, &status );
MAKE_INPUT(tAttr);
aPreviewObjectSize = nAttr.create("previewObjectSize", "pos", MFnNumericData::kDouble, 1.0, &status);
MAKE_NONKEYABLE_INPUT(nAttr);
CHECK_MSTATUS(nAttr.setConnectable(false));
aPreviewPixelSamples = nAttr.create("previewPixelSamples", "pxs", MFnNumericData::kInt, 3, &status);
MAKE_NONKEYABLE_INPUT(nAttr);
CHECK_MSTATUS(nAttr.setConnectable(false));
aPreviewShadingRate = nAttr.create("previewShadingRate", "psr", MFnNumericData::kDouble, 1.0, &status);
MAKE_NONKEYABLE_INPUT(nAttr);
CHECK_MSTATUS(nAttr.setConnectable(false));
aPreviewBackplane = nAttr.create("previewBackplane", "pbp", MFnNumericData::kBoolean, true, &status);
MAKE_NONKEYABLE_INPUT(nAttr);
CHECK_MSTATUS(nAttr.setConnectable(false));
aShaderSpace = tAttr.create( MString("shaderSpace"), MString("ssp"), MFnData::kString, aShaderSpace, &status );
MAKE_INPUT(tAttr);
aDisplacementBound = nAttr.create("displacementBound", "db", MFnNumericData::kDouble, 0.0, &status);
MAKE_INPUT(nAttr);
MObject defaultSpaceObj = tDefault.create( MString("shader"), &status);
aDisplacementBoundSpace = tAttr.create( MString("displacementBoundSpace"), MString("dbs"), MFnData::kString, defaultSpaceObj, &status );
MAKE_INPUT(tAttr);
aOutputInShadow = nAttr.create("outputInShadow", "ois", MFnNumericData::kBoolean, 0.0, &status);
MAKE_NONKEYABLE_INPUT(nAttr);
// refreshPreview must be true to allow refresh
aRefreshPreview = nAttr.create("refreshPreview", "rfp", MFnNumericData::kBoolean, 0.0, &status);
MAKE_NONKEYABLE_INPUT(nAttr);
CHECK_MSTATUS(nAttr.setHidden(true));
// Create output attributes
aDisplacement = nAttr.create("displacement", "d", MFnNumericData::kFloat, 0.0, &status);
MAKE_OUTPUT(nAttr);
aOutColor = nAttr.createColor("outColor", "oc");
MAKE_OUTPUT(nAttr);
aAssignedObjects = mAttr.create("liqAssignedObjects", "ao");
MAKE_OUTPUT(mAttr);
CHECK_MSTATUS(addAttribute(aRmanShader));
CHECK_MSTATUS(addAttribute(aRmanShaderLong));
CHECK_MSTATUS(addAttribute(aRmanShaderLif));
CHECK_MSTATUS(addAttribute(aRmanParams));
CHECK_MSTATUS(addAttribute(aRmanDetails));
CHECK_MSTATUS(addAttribute(aRmanTypes));
CHECK_MSTATUS(addAttribute(aRmanDefaults));
CHECK_MSTATUS(addAttribute(aRmanArraySizes));
CHECK_MSTATUS(addAttribute(aRmanLifCmds));
CHECK_MSTATUS(addAttribute(aPreviewPrimitive));
CHECK_MSTATUS(addAttribute(aPreviewCustomPrimitive));
CHECK_MSTATUS(addAttribute(aPreviewCustomBackplane));
CHECK_MSTATUS(addAttribute(aPreviewObjectSize));
CHECK_MSTATUS(addAttribute(aPreviewPixelSamples));
CHECK_MSTATUS(addAttribute(aPreviewShadingRate));
CHECK_MSTATUS(addAttribute(aPreviewBackplane));
CHECK_MSTATUS(addAttribute(aShaderSpace));
CHECK_MSTATUS(addAttribute(aDisplacementBound));
CHECK_MSTATUS(addAttribute(aDisplacementBoundSpace));
CHECK_MSTATUS(addAttribute(aOutputInShadow));
CHECK_MSTATUS(addAttribute(aRefreshPreview));
CHECK_MSTATUS(addAttribute(aAssignedObjects));
CHECK_MSTATUS(addAttribute(aDisplacement));
CHECK_MSTATUS(addAttribute(aOutColor));
CHECK_MSTATUS(attributeAffects(aRmanShaderLong, aDisplacement));
CHECK_MSTATUS(attributeAffects(aRmanShaderLif, aDisplacement));
return MS::kSuccess;
}
MStatus MayaToAppleseedGlobals::initialize()
{
MayaRenderGlobalsNode::initialize();
MFnNumericAttribute nAttr;
MFnTypedAttribute tAttr;
MFnGenericAttribute gAttr;
MFnEnumAttribute eAttr;
MFnMessageAttribute mAttr;
MStatus stat = MStatus::kSuccess;
sampling_mode = eAttr.create("sampling_mode", "sampling_mode", 0, &stat);
stat = eAttr.addField("qmc", 0);
stat = eAttr.addField("rng", 1);
CHECK_MSTATUS(addAttribute(sampling_mode));
tile_ordering = eAttr.create("tile_ordering", "tile_ordering", 2, &stat);
stat = eAttr.addField("linear", 0);
stat = eAttr.addField("spiral", 1);
stat = eAttr.addField("hilbert", 2);
stat = eAttr.addField("random", 3);
CHECK_MSTATUS(addAttribute(tile_ordering));
bitdepth = eAttr.create( "bitdepth", "bitdepth", 3, &stat);
stat = eAttr.addField( "8bit Integer", 0 );
stat = eAttr.addField( "16bit Integer", 1 );
stat = eAttr.addField( "32bit Integer", 2 );
stat = eAttr.addField( "16bit Float(Half)", 3 );
stat = eAttr.addField( "32bit Float", 4 );
stat = eAttr.addField( "64bit Double", 5 );
CHECK_MSTATUS(addAttribute( bitdepth ));
pixel_renderer = eAttr.create( "pixel_renderer", "pixel_renderer", 0, &stat);
stat = eAttr.addField( "adaptive", 0 );
stat = eAttr.addField( "uniform", 1 );
CHECK_MSTATUS(addAttribute( pixel_renderer ));
colorSpace = eAttr.create( "colorSpace", "colorSpace", 0, &stat);
stat = eAttr.addField( "linear_rgb", 0 );
stat = eAttr.addField( "srgb", 1 );
stat = eAttr.addField( "ciexyz", 2 );
CHECK_MSTATUS(addAttribute( colorSpace ));
lightingEngine = eAttr.create( "lightingEngine", "lightingEngine", 0, &stat);
stat = eAttr.addField( "Unidirectional Path tracing", 0 );
stat = eAttr.addField( "Distributed Raytracing", 1 );
stat = eAttr.addField( "Stochastic Progressive Photon Mapping", 2 );
CHECK_MSTATUS(addAttribute( lightingEngine ));
clamping = nAttr.create("clamping", "clamping", MFnNumericData::kBoolean, false);
CHECK_MSTATUS(addAttribute( clamping ));
maxError = nAttr.create("maxError", "maxError", MFnNumericData::kFloat, 0.01f);
CHECK_MSTATUS(addAttribute( maxError ));
adaptiveQuality = nAttr.create("adaptiveQuality", "adaptiveQuality", MFnNumericData::kFloat, 3.0f);
CHECK_MSTATUS(addAttribute( adaptiveQuality ));
enable_caustics = nAttr.create("enable_caustics", "enable_caustics", MFnNumericData::kBoolean, false);
CHECK_MSTATUS(addAttribute( enable_caustics ));
enable_dl = nAttr.create("enable_dl", "enable_ibl", MFnNumericData::kBoolean, true);
CHECK_MSTATUS(addAttribute( enable_dl ));
enable_diagnostics = nAttr.create("enable_diagnostics", "enable_diagnostics", MFnNumericData::kBoolean, false);
CHECK_MSTATUS(addAttribute( enable_diagnostics ));
diffuseDepth = nAttr.create("diffuseDepth", "diffuseDepth", MFnNumericData::kInt, 4);
CHECK_MSTATUS(addAttribute( diffuseDepth ));
texCacheSize = nAttr.create("texCacheSize", "texCacheSize", MFnNumericData::kInt, 512);
CHECK_MSTATUS(addAttribute( texCacheSize ));
frameRendererPasses = nAttr.create("frameRendererPasses", "frameRendererPasses", MFnNumericData::kInt, 1);
CHECK_MSTATUS(addAttribute( frameRendererPasses ));
glossyDepth = nAttr.create("glossyDepth", "glossyDepth", MFnNumericData::kInt, 4);
CHECK_MSTATUS(addAttribute( glossyDepth ));
environmentSamples = nAttr.create("environmentSamples", "environmentSamples", MFnNumericData::kInt, 1);
CHECK_MSTATUS(addAttribute( environmentSamples ));
bsdfSamples = nAttr.create("bsdfSamples", "bsdfSamples", MFnNumericData::kInt, 1);
CHECK_MSTATUS(addAttribute( bsdfSamples ));
next_event_estimation = nAttr.create("next_event_estimation", "next_event_estimation", MFnNumericData::kBoolean, true);
CHECK_MSTATUS(addAttribute( next_event_estimation ));
assemblySBVH = nAttr.create("assemblySBVH", "assemblySBVH", MFnNumericData::kBoolean, false);
CHECK_MSTATUS(addAttribute( assemblySBVH ));
max_path_length = nAttr.create("max_path_length", "max_path_length", MFnNumericData::kFloat, 8.0f);
CHECK_MSTATUS(addAttribute(max_path_length));
rr_min_path_length = nAttr.create("rr_min_path_length", "rr_min_path_length", MFnNumericData::kFloat, 3.0f);
CHECK_MSTATUS(addAttribute( rr_min_path_length ));
path_tracing_max_path_length = nAttr.create("path_tracing_max_path_length", "path_tracing_max_path_length", MFnNumericData::kFloat, 0.0f);
CHECK_MSTATUS(addAttribute(path_tracing_max_path_length));
path_tracing_rr_min_path_length = nAttr.create("path_tracing_rr_min_path_length", "path_tracing_rr_min_path_length", MFnNumericData::kFloat, 8.0f);
CHECK_MSTATUS(addAttribute(path_tracing_rr_min_path_length));
photon_tracing_max_path_length = nAttr.create("photon_tracing_max_path_length", "photon_tracing_max_path_length", MFnNumericData::kFloat, 8.0f);
CHECK_MSTATUS(addAttribute(photon_tracing_max_path_length));
photon_tracing_rr_min_path_length = nAttr.create("photon_tracing_rr_min_path_length", "photon_tracing_rr_min_path_length", MFnNumericData::kFloat, 3.0f);
CHECK_MSTATUS(addAttribute(photon_tracing_rr_min_path_length));
max_ray_intensity = nAttr.create("max_ray_intensity", "max_ray_intensity", MFnNumericData::kFloat, 0.0f);
CHECK_MSTATUS(addAttribute( max_ray_intensity ));
// reduced to auto because we do not need the others (I hope) remove the whole attribute in the next release
assemblyExportType = eAttr.create( "assemblyExportType", "assemblyExportType", 0, &stat);
stat = eAttr.addField( "Auto", 0 );
CHECK_MSTATUS(addAttribute( assemblyExportType ));
assemblyPolyTheshold = nAttr.create("assemblyPolyTheshold", "assemblyPolyTheshold", MFnNumericData::kInt, 10000);
CHECK_MSTATUS(addAttribute( assemblyPolyTheshold ));
environmentType = eAttr.create( "environmentType", "environmentType", 0, &stat);
stat = eAttr.addField("Constant", 0);
stat = eAttr.addField("ConstantHemisphere", 1);
stat = eAttr.addField("Gradient", 2);
stat = eAttr.addField("Latitude Longitude", 3 );
stat = eAttr.addField("Mirror Ball", 4 );
stat = eAttr.addField("Physical Sky", 5);
stat = eAttr.addField("OSL Environment", 6);
CHECK_MSTATUS(addAttribute(environmentType));
environmentColor = nAttr.createColor("environmentColor", "environmentColor");
nAttr.setDefault(0.6f, 0.7f, 0.9f);
nAttr.setConnectable(false);
CHECK_MSTATUS(addAttribute( environmentColor ));
gradientHorizon = nAttr.createColor("gradientHorizon", "gradientHorizon");
nAttr.setDefault(0.8f, 0.8f, 0.9f);
nAttr.setConnectable(false);
CHECK_MSTATUS(addAttribute( gradientHorizon ));
gradientZenit = nAttr.createColor("gradientZenit", "gradientZenit");
nAttr.setDefault(0.2f, 0.3f, 0.6f);
nAttr.setConnectable(false);
CHECK_MSTATUS(addAttribute( gradientZenit ));
environmentMap = nAttr.createColor("environmentMap", "environmentMap");
nAttr.setDefault(0.6f, 0.7f, 0.9f);
CHECK_MSTATUS(addAttribute( environmentMap ));
environmentIntensity = nAttr.create("environmentIntensity", "environmentIntensity", MFnNumericData::kFloat, 1.0f);
nAttr.setConnectable(false);
CHECK_MSTATUS(addAttribute( environmentIntensity ));
directLightSamples = nAttr.create("directLightSamples", "directLightSamples", MFnNumericData::kFloat, 1.0f);
CHECK_MSTATUS(addAttribute( directLightSamples ));
latlongHoShift = nAttr.create("latlongHoShift", "latlongHoShift", MFnNumericData::kFloat, .0f);
CHECK_MSTATUS(addAttribute( latlongHoShift ));
latlongVeShift = nAttr.create("latlongVeShift", "latlongVeShift", MFnNumericData::kFloat, .0f);
CHECK_MSTATUS(addAttribute( latlongVeShift ));
AOVs = mAttr.create("AOVs", "AOVs");
mAttr.setArray(true);
mAttr.indexMatters(false);
CHECK_MSTATUS(addAttribute( AOVs ));
ground_albedo = nAttr.create("ground_albedo", "ground_albedo", MFnNumericData::kFloat, .0f);
CHECK_MSTATUS(addAttribute( ground_albedo ));
horizon_shift = nAttr.create("horizon_shift", "horizon_shift", MFnNumericData::kFloat, -0.05f);
CHECK_MSTATUS(addAttribute( horizon_shift ));
luminance_multiplier = nAttr.create("luminance_multiplier", "luminance_multiplier", MFnNumericData::kFloat, 1.0f);
CHECK_MSTATUS(addAttribute( luminance_multiplier ));
saturation_multiplier = nAttr.create("saturation_multiplier", "saturation_multiplier", MFnNumericData::kFloat, 1.0f);
CHECK_MSTATUS(addAttribute( saturation_multiplier ));
sun_phi = nAttr.create("sun_phi", "sun_phi", MFnNumericData::kFloat, .0f);
CHECK_MSTATUS(addAttribute( sun_phi ));
sun_theta = nAttr.create("sun_theta", "sun_theta", MFnNumericData::kFloat, 60.0f);
CHECK_MSTATUS(addAttribute( sun_theta ));
turbidity = nAttr.create("turbidity", "turbidity", MFnNumericData::kFloat, 3.0f);
CHECK_MSTATUS(addAttribute( turbidity ));
turbidity_max = nAttr.create("turbidity_max", "turbidity_max", MFnNumericData::kFloat, 3.0f);
CHECK_MSTATUS(addAttribute( turbidity_max ));
turbidity_min = nAttr.create("turbidity_min", "turbidity_min", MFnNumericData::kFloat, 3.0f);
CHECK_MSTATUS(addAttribute( turbidity_min ));
skyModel = eAttr.create( "skyModel", "skyModel", 0, &stat);
stat = eAttr.addField( "Preetham", 0 );
stat = eAttr.addField( "Hosek", 1 );
CHECK_MSTATUS(addAttribute( skyModel ));
physicalSun = nAttr.create("physicalSun", "physicalSun", MFnNumericData::kBoolean, false);
CHECK_MSTATUS(addAttribute( physicalSun ));
physicalSunConnection = mAttr.create("physicalSunConnection", "physicalSunConnection");
CHECK_MSTATUS(addAttribute( physicalSunConnection ));
sunTurbidity = nAttr.create("sunTurbidity", "sunTurbidity", MFnNumericData::kFloat, 3.0f);
CHECK_MSTATUS(addAttribute( sunTurbidity ));
sunExitanceMultiplier = nAttr.create("sunExitanceMultiplier", "sunExitanceMultiplier", MFnNumericData::kFloat, 1.0f);
CHECK_MSTATUS(addAttribute( sunExitanceMultiplier ));
sppmAlpha = nAttr.create("sppmAlpha", "sppmAlpha", MFnNumericData::kFloat, .8f);
CHECK_MSTATUS(addAttribute( sppmAlpha ));
dl_mode = eAttr.create("dl_mode", "dl_mode", 0, &stat);
stat = eAttr.addField("RT Direct Lighting", 0);
stat = eAttr.addField("SPPM Direct Lighting", 1);
stat = eAttr.addField("No Direct Lighting", 2);
CHECK_MSTATUS(addAttribute(dl_mode));
env_photons_per_pass = nAttr.create("env_photons_per_pass", "env_photons_per_pass", MFnNumericData::kInt, 100000);
CHECK_MSTATUS(addAttribute( env_photons_per_pass ));
initial_radius = nAttr.create("initial_radius", "initial_radius", MFnNumericData::kFloat, .5f);
CHECK_MSTATUS(addAttribute( initial_radius ));
light_photons_per_pass = nAttr.create("light_photons_per_pass", "light_photons_per_pass", MFnNumericData::kInt, 100000);
CHECK_MSTATUS(addAttribute( light_photons_per_pass ));
max_photons_per_estimate = nAttr.create("max_photons_per_estimate", "max_photons_per_estimate", MFnNumericData::kInt, 100);
CHECK_MSTATUS(addAttribute( max_photons_per_estimate ));
photons_per_pass = nAttr.create("photons_per_pass", "photons_per_pass", MFnNumericData::kInt, 100000);
CHECK_MSTATUS(addAttribute( photons_per_pass ));
photon_type = eAttr.create("photon_type", "photon_type", 1, &stat);
stat = eAttr.addField("Monochromatic", 0);
stat = eAttr.addField("Polychromatic", 1);
CHECK_MSTATUS(addAttribute(photon_type));
return stat;
}
MStatus dSolverNode::initialize()
{
MStatus status;
MFnEnumAttribute fnEnumAttr;
MFnMessageAttribute fnMsgAttr;
MFnUnitAttribute fnUnitAttr;
MFnNumericAttribute fnNumericAttr;
//
ssSolverType = fnEnumAttr.create( "ssSolverType", "ssst", 0, &status );
MCHECKSTATUS(status, "creating ssSolverType attribute")
fnEnumAttr.addField( "Bullet Physics", 0 );
fnEnumAttr.addField( "Ageia PhysX", 1 );
fnEnumAttr.addField( "Stanford PhysBAM", 2 );
status = addAttribute(ssSolverType);
MCHECKSTATUS(status, "adding ssSolverType attribute")
//
ia_time = fnUnitAttr.create( "inTime", "it", MFnUnitAttribute::kTime, 0.0, &status );
MCHECKSTATUS(status, "creating ia_time attribute")
fnUnitAttr.setHidden(true);
status = addAttribute(ia_time);
MCHECKSTATUS(status, "adding ia_time attribute")
ia_startTime = fnUnitAttr.create( "startTime", "stm", MFnUnitAttribute::kTime, 1.0, &status );
MCHECKSTATUS(status, "creating ia_startTime attribute")
status = addAttribute(ia_startTime);
MCHECKSTATUS(status, "adding ia_startTime attribute")
oa_rigidBodies = fnMsgAttr.create("rigidBodies", "rbds", &status);
MCHECKSTATUS(status, "creating oa_rigidBodies attribute")
status = addAttribute(oa_rigidBodies);
MCHECKSTATUS(status, "adding oa_rigidBodies attribute")
ia_gravity = fnNumericAttr.createPoint("gravity", "grvt", &status);
MCHECKSTATUS(status, "creating gravity attribute")
fnNumericAttr.setDefault(0.0, -9.81, 0.0);
fnNumericAttr.setKeyable(true);
status = addAttribute(ia_gravity);
MCHECKSTATUS(status, "adding ia_gravity attribute")
ia_substeps = fnNumericAttr.create("substeps", "sbs", MFnNumericData::kInt, 1, &status);
MCHECKSTATUS(status, "creating substeps attribute")
fnNumericAttr.setKeyable(true);
status = addAttribute(ia_substeps);
MCHECKSTATUS(status, "adding ia_substeps attribute")
ia_enabled = fnNumericAttr.create("enabled", "enbl", MFnNumericData::kBoolean, true, &status);
MCHECKSTATUS(status, "creating enabled attribute")
status = addAttribute(ia_enabled);
MCHECKSTATUS(status, "adding ia_enabled attribute")
ia_splitImpulse = fnNumericAttr.create("splitImpulse", "spli", MFnNumericData::kBoolean, false, &status);
MCHECKSTATUS(status, "creating splitImpulse attribute")
status = addAttribute(ia_splitImpulse);
MCHECKSTATUS(status, "adding ia_splitImpulse attribute")
status = attributeAffects(ia_time, oa_rigidBodies);
MCHECKSTATUS(status, "adding attributeAffects(ia_time, oa_rigidBodies)")
status = attributeAffects(ia_enabled, oa_rigidBodies);
MCHECKSTATUS(status, "adding attributeAffects(ia_enabled, oa_rigidBodies)")
return MS::kSuccess;
}
MStatus sixdofConstraintNode::initialize()
{
MStatus status;
MFnMessageAttribute fnMsgAttr;
MFnNumericAttribute fnNumericAttr;
MFnMatrixAttribute fnMatrixAttr;
ia_rigidBodyA = fnMsgAttr.create("inRigidBodyA", "inrbA", &status);
MCHECKSTATUS(status, "creating inRigidBodyA attribute")
status = addAttribute(ia_rigidBodyA);
MCHECKSTATUS(status, "adding inRigidBody attribute")
ia_rigidBodyB = fnMsgAttr.create("inRigidBodyB", "inrbB", &status);
MCHECKSTATUS(status, "creating inRigidBodyB attribute")
status = addAttribute(ia_rigidBodyB);
MCHECKSTATUS(status, "adding inRigidBodyB attribute")
ia_damping = fnNumericAttr.create("damping", "dmp", MFnNumericData::kDouble, 1.0, &status);
MCHECKSTATUS(status, "creating damping attribute")
fnNumericAttr.setKeyable(true);
status = addAttribute(ia_damping);
MCHECKSTATUS(status, "adding damping attribute")
ia_breakThreshold = fnNumericAttr.create("breakThreshold", "brkThrsh", MFnNumericData::kDouble, 100.0, &status);
MCHECKSTATUS(status, "creating breakThreshold attribute")
fnNumericAttr.setKeyable(true);
status = addAttribute(ia_breakThreshold);
MCHECKSTATUS(status, "adding breakThreshold attribute")
ia_disableCollide = fnNumericAttr.create("disableCollide", "dsblColl", MFnNumericData::kBoolean, true, &status);
MCHECKSTATUS(status, "creating disableCollide attribute")
fnNumericAttr.setHidden(true);
fnNumericAttr.setKeyable(true);
status = addAttribute(ia_disableCollide);
MCHECKSTATUS(status, "adding disableCollide attribute")
ia_lowerLinLimit = fnNumericAttr.createPoint("lowerLinLimit", "lllt", &status);
MCHECKSTATUS(status, "creating lower linear limit attribute")
status = fnNumericAttr.setDefault((double) 0.0, (double) 0.0, (double) 0.0);
fnNumericAttr.setKeyable(true);
status = addAttribute(ia_lowerLinLimit);
MCHECKSTATUS(status, "adding lower linear limit attribute")
ia_upperLinLimit = fnNumericAttr.createPoint("upperLinLimit", "ullt", &status);
MCHECKSTATUS(status, "creating upper linear limit attribute")
status = fnNumericAttr.setDefault((double) 0.0, (double) 0.0, (double) 0.0);
fnNumericAttr.setKeyable(true);
status = addAttribute(ia_upperLinLimit);
MCHECKSTATUS(status, "adding upper linear limit attribute")
ia_lowerAngLimit = fnNumericAttr.createPoint("lowerAngLimit", "lalt", &status);
MCHECKSTATUS(status, "creating lower angular limit attribute")
status = fnNumericAttr.setDefault((double) 0.0, (double) 0.0, (double) 0.0);
fnNumericAttr.setKeyable(true);
status = addAttribute(ia_lowerAngLimit);
MCHECKSTATUS(status, "adding lower angular limit attribute")
ia_upperAngLimit = fnNumericAttr.createPoint("upperAngLimit", "ualt", &status);
MCHECKSTATUS(status, "creating upper angular limit attribute")
status = fnNumericAttr.setDefault((double) 0.0, (double) 0.0, (double) 0.0);
fnNumericAttr.setKeyable(true);
status = addAttribute(ia_upperAngLimit);
MCHECKSTATUS(status, "adding upper angular limit attribute")
ca_constraint = fnNumericAttr.create("ca_constraint", "caco", MFnNumericData::kBoolean, 0, &status);
MCHECKSTATUS(status, "creating ca_constraint attribute")
fnNumericAttr.setConnectable(false);
fnNumericAttr.setHidden(true);
fnNumericAttr.setStorable(false);
fnNumericAttr.setKeyable(false);
status = addAttribute(ca_constraint);
MCHECKSTATUS(status, "adding ca_constraint attribute")
ca_constraintParam = fnNumericAttr.create("ca_constraintParam", "cacop", MFnNumericData::kBoolean, 0, &status);
MCHECKSTATUS(status, "creating ca_constraintParam attribute")
fnNumericAttr.setConnectable(false);
fnNumericAttr.setHidden(true);
fnNumericAttr.setStorable(false);
fnNumericAttr.setKeyable(false);
status = addAttribute(ca_constraintParam);
MCHECKSTATUS(status, "adding ca_constraintParam attribute")
ia_rotationInA = fnNumericAttr.createPoint("rotationInA", "hgRotA", &status);
status = fnNumericAttr.setDefault((double) 0.0, (double) 0.0, (double) 0.0);
MCHECKSTATUS(status, "creating rotationInA attribute")
status = addAttribute(ia_rotationInA);
MCHECKSTATUS(status, "adding rotationInA attribute")
ia_rotationInB = fnNumericAttr.createPoint("rotationInB", "hgRotB", &status);
status = fnNumericAttr.setDefault((double) 0.0, (double) 0.0, (double) 0.0);
MCHECKSTATUS(status, "creating rotationInB attribute")
status = addAttribute(ia_rotationInB);
MCHECKSTATUS(status, "adding rotationInB attribute")
ia_pivotInA = fnNumericAttr.createPoint("pivotInA", "pivinA", &status);
status = fnNumericAttr.setDefault((double) 0.0, (double) 0.0, (double) 0.0);
MCHECKSTATUS(status, "creating pivotInA attribute")
status = addAttribute(ia_pivotInA);
MCHECKSTATUS(status, "adding pivotInA attribute")
ia_pivotInB = fnNumericAttr.createPoint("pivotInB", "pivinB", &status);
status = fnNumericAttr.setDefault((double) 0.0, (double) 0.0, (double) 0.0);
MCHECKSTATUS(status, "creating pivotInB attribute")
status = addAttribute(ia_pivotInB);
MCHECKSTATUS(status, "adding pivotInB attribute")
status = attributeAffects(ia_rigidBodyA, ca_constraint);
MCHECKSTATUS(status, "adding attributeAffects(ia_rigidBodyA, ca_constraint)")
status = attributeAffects(ia_rigidBodyA, ca_constraintParam);
MCHECKSTATUS(status, "adding attributeAffects(ia_rigidBodyA, ca_constraintParam)")
status = attributeAffects(ia_rigidBodyB, ca_constraint);
MCHECKSTATUS(status, "adding attributeAffects(ia_rigidBodyB, ca_constraint)")
status = attributeAffects(ia_rigidBodyB, ca_constraintParam);
MCHECKSTATUS(status, "adding attributeAffects(ia_rigidBodyB, ca_constraintParam)")
status = attributeAffects(ia_damping, ca_constraintParam);
MCHECKSTATUS(status, "adding attributeAffects(ia_damping, ca_constraintParam)")
status = attributeAffects(ia_breakThreshold, ca_constraintParam);
MCHECKSTATUS(status, "adding attributeAffects(ia_breakThreshold, ca_constraintParam)")
status = attributeAffects(ia_disableCollide, ca_constraint);
MCHECKSTATUS(status, "adding attributeAffects(ia_disableCollide, ca_constraint)")
status = attributeAffects(ia_lowerLinLimit, ca_constraintParam);
MCHECKSTATUS(status, "adding attributeAffects(ia_lowerLinLimit, ca_constraintParam)")
status = attributeAffects(ia_upperLinLimit, ca_constraintParam);
MCHECKSTATUS(status, "adding attributeAffects(ia_upperLinLimit, ca_constraintParam)")
status = attributeAffects(ia_lowerAngLimit, ca_constraintParam);
MCHECKSTATUS(status, "adding attributeAffects(ia_lowerAngLimit, ca_constraintParam)")
status = attributeAffects(ia_upperAngLimit, ca_constraintParam);
MCHECKSTATUS(status, "adding attributeAffects(ia_upperAngLimit, ca_constraintParam)")
status = attributeAffects(ia_rotationInA, ca_constraintParam);
MCHECKSTATUS(status, "adding attributeAffects(ia_rotationInA, ca_constraintParam)")
status = attributeAffects(ia_rotationInB, ca_constraintParam);
MCHECKSTATUS(status, "adding attributeAffects(ia_rotationInB, ca_constraintParam)")
status = attributeAffects(ia_pivotInA, ca_constraintParam);
MCHECKSTATUS(status, "adding attributeAffects(ia_pivotInA, ca_constraintParam)")
status = attributeAffects(ia_pivotInB, ca_constraintParam);
MCHECKSTATUS(status, "adding attributeAffects(ia_pivotInB, ca_constraintParam)")
return MS::kSuccess;
}
MStatus SoftBodyNode::initialize()
{
MFnMessageAttribute fnMsgAttr;
MStatus status = MStatus::kSuccess;
ia_solver = fnMsgAttr.create("solver", "solv", &status);
MCHECKSTATUS(status, "creating solver attribute")
status = addAttribute(ia_solver);
MCHECKSTATUS(status, "adding solver attribute")
MFnNumericAttribute fnNumericAttr;
ca_solver = fnNumericAttr.create("ca_solver", "caso", MFnNumericData::kBoolean, 0, &status);
MCHECKSTATUS(status, "creating ca_solver attribute")
fnNumericAttr.setConnectable(false);
fnNumericAttr.setHidden(true);
fnNumericAttr.setStorable(false);
fnNumericAttr.setKeyable(false);
status = addAttribute(ca_solver);
MCHECKSTATUS(status, "adding ca_solver attribute")
ca_softBody = fnNumericAttr.create("ca_softBody", "casb", MFnNumericData::kBoolean, 0, &status);
MCHECKSTATUS(status, "creating ca_softBody attribute")
fnNumericAttr.setConnectable(false);
fnNumericAttr.setHidden(true);
fnNumericAttr.setStorable(false);
fnNumericAttr.setKeyable(false);
status = addAttribute(ca_softBody);
MCHECKSTATUS(status, "adding ca_softBody attribute")
inputMesh = fnMsgAttr.create("inMesh", "inmsh", &status);
MCHECKSTATUS(status, "creating inMesh attribute")
status = addAttribute(inputMesh);
MCHECKSTATUS(status, "adding inMesh attribute")
outputMesh = fnMsgAttr.create("outMesh", "outmsh", &status);
MCHECKSTATUS(status, "creating outMesh attribute")
status = addAttribute(outputMesh);
MCHECKSTATUS(status, "adding outMesh attribute")
/*
Note that these initial* attributes are not in use for soft bodies at the moment
*/
ia_initialPosition = fnNumericAttr.createPoint("initialPosition", "inpo", &status);
MCHECKSTATUS(status, "creating initialPosition attribute")
status = addAttribute(ia_initialPosition);
MCHECKSTATUS(status, "adding initialPosition attribute")
ia_initialRotation = fnNumericAttr.createPoint("initialRotation", "inro", &status);
MCHECKSTATUS(status, "creating initialRotation attribute")
status = addAttribute(ia_initialRotation);
MCHECKSTATUS(status, "adding initialRotation attribute")
ia_initialVelocity = fnNumericAttr.createPoint("initialVelocity", "inve", &status);
MCHECKSTATUS(status, "creating initialVelocity attribute")
status = addAttribute(ia_initialVelocity);
MCHECKSTATUS(status, "adding initialVelocity attribute")
ia_initialSpin = fnNumericAttr.createPoint("initialSpin", "insp", &status);
MCHECKSTATUS(status, "creating initialSpin attribute")
status = addAttribute(ia_initialSpin);
MCHECKSTATUS(status, "adding initialSpin attribute")
// total soft body mass
ia_mass = fnNumericAttr.create("mass", "ma", MFnNumericData::kDouble, DEFAULT_MASS, &status);
MCHECKSTATUS(status, "creating mass attribute")
fnNumericAttr.setKeyable(true);
status = addAttribute(ia_mass);
MCHECKSTATUS(status, "adding mass attribute")
// create dynamic friction coefficient attribute
ia_dynamicFrictionCoeff = fnNumericAttr.create("dynamicfrictioncoeff", "dfc", MFnNumericData::kDouble, DEFAULT_DFC, &status);
MCHECKSTATUS(status, "creating dynamicfrictioncoeff attribute")
fnNumericAttr.setKeyable(true);
status = addAttribute(ia_dynamicFrictionCoeff);
MCHECKSTATUS(status, "adding dynamicfrictioncoeff attribute")
// create collision margin attribute
ia_collisionMargin = fnNumericAttr.create("collisionmargin", "cmargin", MFnNumericData::kFloat, DEFAULT_CMARGIN, &status);
MCHECKSTATUS(status, "creating collisionmargin attribute")
fnNumericAttr.setKeyable(false);
status = addAttribute(ia_collisionMargin);
MCHECKSTATUS(status, "adding collision attribute")
// collision clusters attribute
ia_numClusters = fnNumericAttr.create("numclusters", "nclust", MFnNumericData::kInt, DEFAULT_CLUSTERS, &status);
MCHECKSTATUS(status, "creating numclusters attribute")
fnNumericAttr.setKeyable(false);
status = addAttribute(ia_numClusters);
MCHECKSTATUS(status, "adding numclusters attribute")
ca_softBodyParam = fnNumericAttr.create("ca_softBodyParam", "casbp", MFnNumericData::kBoolean, 0, &status);
MCHECKSTATUS(status, "creating ca_softBodyParam attribute")
fnNumericAttr.setConnectable(false);
fnNumericAttr.setHidden(true);
fnNumericAttr.setStorable(false);
fnNumericAttr.setKeyable(false);
status = addAttribute(ca_softBodyParam);
MCHECKSTATUS(status, "adding ca_softBodyParam attribute")
status = attributeAffects(inputMesh, ca_softBody);
MCHECKSTATUS(status, "adding attributeAffects(inputMesh, ca_softBody)")
status = attributeAffects(ia_solver, ca_solver);
MCHECKSTATUS(status, "adding attributeAffects(ia_solver, ca_solver)")
// connect soft body parameters to ca_softBodyParam connection
status = attributeAffects(ia_mass, ca_softBodyParam);
MCHECKSTATUS(status, "adding attributeAffects(ia_mass, ca_softBodyParam)")
status = attributeAffects(ia_dynamicFrictionCoeff, ca_softBodyParam);
MCHECKSTATUS(status, "adding attributeAffects(ia_dynamicFrictionCoeff, ca_softBodyParam)")
status = attributeAffects(ia_collisionMargin, ca_softBodyParam);
MCHECKSTATUS(status, "adding attributeAffects(ia_collisionMargin, ca_softBodyParam)")
status = attributeAffects(ia_numClusters, ca_softBodyParam);
MCHECKSTATUS(status, "adding attributeAffects(ia_numClusters, ca_softBodyParam)")
return status;
}
MStatus boidsBrain::initialize()
{
MStatus status;
MFnNumericAttribute nAttr;
MFnTypedAttribute tAttr;
MFnEnumAttribute eAttr;
MFnMessageAttribute mAttr;
// MFnUnitAttribute uAttr;
// MString attrOpt;
printf("initializing Boidz Locator node\n");
MGlobal:: displayInfo("initializing Boidz Locator node");
nodeCreateAttrNum(simulationLength, sl, kInt, BDZ_SIMLEN );
nodeCreateAttrNum(framesPerSecond, fps, kInt, BDZ_FPS );
nodeCreateAttrNum(startFrame, stf, kInt, BDZ_STF );
particleSystem = mAttr.create("particleSystem", "ps");
nodeAddAttribute(particleSystem);
nodeCreateAttrNum(boidsNumber, bn, kInt, BDZ_NUM );
nodeCreateAttrTyp(logFilePath, lp);
nodeCreateAttrTyp(logFileName, ln);
// inputSurface = tAttr.create( "inputSurface", "is",MFnData::kNurbsSurface,&stat );
// nodeCreateAttrTyped(logFileName, ln, BDZ_LOGNAME);
logFileType = eAttr.create("logFileType", "lt", BDZ_LOGTYPE);
eAttr.addField("nCache file", 0);
eAttr.addField("log file", 1);
eAttr.addField("XML file", 2);
// eAttr.setStorable(true);
// nodeCreateAttrNum(logFileType, lt, kDouble, BDZ_LOGTYPE);
nodeAddAttribute(logFileType);
nodeCreateRuleAttributes(alignment, a)
nodeCreateRuleAttributes(cohesion, c)
nodeCreateRuleAttributes(separation, s)
nodeCreateRuleAttributes(follow, f)
/*
nodeCreateAttrNum(distance, d, kDouble, BDZ_DIST)
nodeCreateAttrNum(repulsionFactor, rf, kDouble, BDZ_REPULSION)
nodeCreateAttrNum(cohesionFactor, cf, kDouble, BDZ_COHESION)
nodeCreateAttrNum(separationFactor, sf, kDouble, BDZ_SEPARATION)
nodeCreateAttrNum(approachFactor, af, kDouble, BDZ_APPROACH)
*/
locomotionMode = eAttr.create("locomotionMode", "lm", BDZ_LOCMODE);
eAttr.addField("physical", 0);
eAttr.addField("simple", 1);
nodeAddAttribute(locomotionMode);
// nodeCreateAttrNum(locomotionMode, lm, kInt, BDZ_LOCMODE)
nodeCreateAttrNum(maxSpeed, ms, kDouble, BDZ_MAXSPEED)
nodeCreateAttrNum(maxForce, mf, kDouble, BDZ_MAXACCEL)
// nodeCreateAttrNum(mass, mss, kDouble, BDZ_MASS)
// check for error
if( status != MS::kSuccess ) {
status.perror("Unable to attach one or more attributes to the boidsBrain node");
return status;
}
MGlobal:: displayInfo("boidsBrain node attributes applied");
return MS::kSuccess;
}
MStatus rigidBodyNode::initialize()
{
MStatus status;
MFnMessageAttribute fnMsgAttr;
MFnNumericAttribute fnNumericAttr;
MFnMatrixAttribute fnMatrixAttr;
MFnTypedAttribute typedAttr;
ia_collisionShape = fnMsgAttr.create("inCollisionShape", "incs", &status);
MCHECKSTATUS(status, "creating inCollisionShape attribute")
status = addAttribute(ia_collisionShape);
MCHECKSTATUS(status, "adding inCollisionShape attribute")
ia_solver = fnMsgAttr.create("solver", "solv", &status);
MCHECKSTATUS(status, "creating solver attribute")
status = addAttribute(ia_solver);
MCHECKSTATUS(status, "adding solver attribute")
ia_mass = fnNumericAttr.create("mass", "ma", MFnNumericData::kDouble, 1.0, &status);
MCHECKSTATUS(status, "creating mass attribute")
fnNumericAttr.setKeyable(true);
status = addAttribute(ia_mass);
MCHECKSTATUS(status, "adding mass attribute")
ia_restitution = fnNumericAttr.create("restitution", "rst", MFnNumericData::kDouble, 0.1, &status);
MCHECKSTATUS(status, "creating restitution attribute")
fnNumericAttr.setKeyable(true);
status = addAttribute(ia_restitution);
MCHECKSTATUS(status, "adding restitution attribute")
ia_friction = fnNumericAttr.create("friction", "fc", MFnNumericData::kDouble, 0.5, &status);
MCHECKSTATUS(status, "creating friction attribute")
fnNumericAttr.setKeyable(true);
status = addAttribute(ia_friction);
MCHECKSTATUS(status, "adding friction attribute")
ia_linearDamping = fnNumericAttr.create("linearDamping", "ld", MFnNumericData::kDouble, 0.3, &status);
MCHECKSTATUS(status, "creating linearDamping attribute")
fnNumericAttr.setKeyable(true);
status = addAttribute(ia_linearDamping);
MCHECKSTATUS(status, "adding linearDamping attribute")
ia_angularDamping = fnNumericAttr.create("angularDamping", "ad", MFnNumericData::kDouble, 0.3, &status);
MCHECKSTATUS(status, "creating angularDamping attribute")
fnNumericAttr.setKeyable(true);
status = addAttribute(ia_angularDamping);
MCHECKSTATUS(status, "adding angularDamping attribute")
ia_initialPosition = fnNumericAttr.createPoint("initialPosition", "inpo", &status);
MCHECKSTATUS(status, "creating initialPosition attribute")
status = addAttribute(ia_initialPosition);
MCHECKSTATUS(status, "adding initialPosition attribute")
ia_initialRotation = fnNumericAttr.createPoint("initialRotation", "inro", &status);
MCHECKSTATUS(status, "creating initialRotation attribute")
status = addAttribute(ia_initialRotation);
MCHECKSTATUS(status, "adding initialRotation attribute")
ia_initialVelocity = fnNumericAttr.createPoint("initialVelocity", "inve", &status);
MCHECKSTATUS(status, "creating initialVelocity attribute")
status = addAttribute(ia_initialVelocity);
MCHECKSTATUS(status, "adding initialVelocity attribute")
ia_initialSpin = fnNumericAttr.createPoint("initialSpin", "insp", &status);
MCHECKSTATUS(status, "creating initialSpin attribute")
status = addAttribute(ia_initialSpin);
MCHECKSTATUS(status, "adding initialSpin attribute")
ia_externalForce = fnNumericAttr.createPoint("externalForce", "exfo", &status);
MCHECKSTATUS(status, "creating externalForce attribute")
status = addAttribute(ia_externalForce);
MCHECKSTATUS(status, "adding externalForce attribute")
ia_externalTorque = fnNumericAttr.createPoint("externalTorque", "exto", &status);
MCHECKSTATUS(status, "creating externalTorque attribute")
status = addAttribute(ia_externalTorque);
MCHECKSTATUS(status, "adding externalTorque attribute")
ca_rigidBody = fnNumericAttr.create("ca_rigidBody", "carb", MFnNumericData::kBoolean, 0, &status);
MCHECKSTATUS(status, "creating ca_rigidBody attribute")
fnNumericAttr.setConnectable(false);
fnNumericAttr.setHidden(true);
fnNumericAttr.setStorable(false);
fnNumericAttr.setKeyable(false);
status = addAttribute(ca_rigidBody);
MCHECKSTATUS(status, "adding ca_rigidBody attribute")
ca_rigidBodyParam = fnNumericAttr.create("ca_rigidBodyParam", "carbp", MFnNumericData::kBoolean, 0, &status);
MCHECKSTATUS(status, "creating ca_rigidBodyParam attribute")
fnNumericAttr.setConnectable(false);
fnNumericAttr.setHidden(true);
fnNumericAttr.setStorable(false);
fnNumericAttr.setKeyable(false);
status = addAttribute(ca_rigidBodyParam);
MCHECKSTATUS(status, "adding ca_rigidBodyParam attribute")
ca_solver = fnNumericAttr.create("ca_solver", "caso", MFnNumericData::kBoolean, 0, &status);
MCHECKSTATUS(status, "creating ca_solver attribute")
fnNumericAttr.setConnectable(false);
fnNumericAttr.setHidden(true);
fnNumericAttr.setStorable(false);
fnNumericAttr.setKeyable(false);
status = addAttribute(ca_solver);
MCHECKSTATUS(status, "adding ca_solver attribute")
oa_contactCount = fnNumericAttr.create("contactCount", "contactCount", MFnNumericData::kInt, 0, &status);
MCHECKSTATUS(status, "creating oa_contactCount attribute")
fnNumericAttr.setConnectable(true);
fnNumericAttr.setHidden(true);
fnNumericAttr.setStorable(false);
fnNumericAttr.setKeyable(false);
status = addAttribute(oa_contactCount);
MCHECKSTATUS(status, "adding oa_contactCount attribute");
MFnStringArrayData stringArrayData;
oa_contactName = typedAttr.create("contactName", "contactName", MFnData::kStringArray, stringArrayData.create(), &status);
MCHECKSTATUS(status, "creating oa_contactName attribute")
typedAttr.setHidden(true);
status = addAttribute(oa_contactName);
MCHECKSTATUS(status, "adding oa_contactName attribute");
oa_contactPosition = typedAttr.create("contactPosition", "contactPosition", MFnVectorArrayData::kVectorArray, &status);
MCHECKSTATUS(status, "creating oa_contactPosition attribute")
typedAttr.setHidden(true);
status = addAttribute(oa_contactPosition);
MCHECKSTATUS(status, "adding oa_contactPosition attribute");
status = attributeAffects(ia_mass, ca_rigidBody);
MCHECKSTATUS(status, "adding attributeAffects(ia_mass, ca_rigidBodyParam)")
status = attributeAffects(ia_collisionShape, ca_rigidBody);
MCHECKSTATUS(status, "adding attributeAffects(ia_collisionShape, ca_rigidBody)")
status = attributeAffects(ia_collisionShape, ca_rigidBodyParam);
MCHECKSTATUS(status, "adding attributeAffects(ia_collisionShape, ca_rigidBodyParam)")
status = attributeAffects(ia_mass, ca_rigidBodyParam);
MCHECKSTATUS(status, "adding attributeAffects(ia_mass, ca_rigidBodyParam)")
status = attributeAffects(ia_restitution, ca_rigidBodyParam);
MCHECKSTATUS(status, "adding attributeAffects(ia_restitution, ca_rigidBodyParam)")
status = attributeAffects(ia_friction, ca_rigidBodyParam);
MCHECKSTATUS(status, "adding attributeAffects(ia_friction, ca_rigidBodyParam)")
status = attributeAffects(ia_linearDamping, ca_rigidBodyParam);
MCHECKSTATUS(status, "adding attributeAffects(ia_linearDamping, ca_rigidBodyParam)")
status = attributeAffects(ia_angularDamping, ca_rigidBodyParam);
MCHECKSTATUS(status, "adding attributeAffects(ia_angularDamping, ca_rigidBodyParam)")
status = attributeAffects(ia_initialPosition, ca_rigidBodyParam);
MCHECKSTATUS(status, "adding attributeAffects(ia_initialPosition, ca_rigidBodyParam)")
status = attributeAffects(ia_solver, ca_solver);
MCHECKSTATUS(status, "adding attributeAffects(ia_solver, ca_solver)")
return MS::kSuccess;
}
MStatus liqSurfaceNode::initialize()
{
MFnTypedAttribute tAttr;
MFnStringData tDefault;
MFnNumericAttribute nAttr;
MFnEnumAttribute eAttr;
MFnMessageAttribute mAttr;
MFnLightDataAttribute lAttr;
MStatus status;
// Create input attributes
aRmanShader = tAttr.create( MString("rmanShader"), MString("rms"), MFnData::kString, aRmanShader, &status );
MAKE_INPUT(tAttr);
aRmanShaderLong = tAttr.create( MString("rmanShaderLong"), MString("rml"), MFnData::kString, aRmanShaderLong, &status );
MAKE_INPUT(tAttr);
aRmanShaderLif = tAttr.create( MString("rmanShaderLif"), MString("lif"), MFnData::kString, aRmanShaderLif, &status );
MAKE_INPUT(tAttr);
aRmanParams = tAttr.create( MString("rmanParams"), MString("rpr"), MFnData::kStringArray, aRmanParams, &status );
MAKE_INPUT(tAttr);
aRmanDetails = tAttr.create( MString("rmanDetails"), MString("rdt"), MFnData::kStringArray, aRmanDetails, &status );
MAKE_INPUT(tAttr);
aRmanTypes = tAttr.create( MString("rmanTypes"), MString("rty"), MFnData::kStringArray, aRmanTypes, &status );
MAKE_INPUT(tAttr);
aRmanDefaults = tAttr.create( MString("rmanDefaults"), MString("rdf"), MFnData::kStringArray, aRmanDefaults, &status );
MAKE_INPUT(tAttr);
aRmanArraySizes = tAttr.create( MString("rmanArraySizes"), MString("ras"), MFnData::kIntArray, aRmanArraySizes, &status );
MAKE_INPUT(tAttr);
aRmanLifCmds = tAttr.create( MString("rmanLifCmds"), MString("rlc"), MFnData::kStringArray, aRmanLifCmds, &status );
MAKE_INPUT(tAttr);
aPreviewPrimitive = eAttr.create( "previewPrimitive", "pvp", 7, &status );
eAttr.addField( "Sphere", 0 );
eAttr.addField( "Cube", 1 );
eAttr.addField( "Cylinder", 2 );
eAttr.addField( "Torus", 3 );
eAttr.addField( "Plane", 4 );
eAttr.addField( "Teapot", 5 );
eAttr.addField( "Custom", 6 );
eAttr.addField( "(globals)",7 );
MAKE_NONKEYABLE_INPUT(eAttr);
CHECK_MSTATUS(eAttr.setConnectable(false));
aPreviewCustomPrimitive = tAttr.create( MString("previewCustomPrimitive"), MString("pcp"), MFnData::kString, aPreviewCustomPrimitive, &status );
MAKE_INPUT(tAttr);
aPreviewCustomBackplane = tAttr.create( MString("previewCustomBackplane"), MString("pcb"), MFnData::kString, aPreviewCustomBackplane, &status );
MAKE_INPUT(tAttr);
aPreviewCustomLightRig = tAttr.create( MString("previewCustomLights"), MString("pcl"), MFnData::kString, aPreviewCustomLightRig, &status );
MAKE_INPUT(tAttr);
aPreviewObjectSize = nAttr.create("previewObjectSize", "pos", MFnNumericData::kDouble, 1.0, &status);
MAKE_NONKEYABLE_INPUT(nAttr);
CHECK_MSTATUS(nAttr.setConnectable(false));
aPreviewPixelSamples = nAttr.create("previewPixelSamples", "pxs", MFnNumericData::kInt, 3, &status);
MAKE_NONKEYABLE_INPUT(nAttr);
CHECK_MSTATUS(nAttr.setConnectable(false));
aPreviewShadingRate = nAttr.create("previewShadingRate", "psr", MFnNumericData::kDouble, 1.0, &status);
MAKE_NONKEYABLE_INPUT(nAttr);
CHECK_MSTATUS(nAttr.setConnectable(false));
aPreviewBackplane = nAttr.create("previewBackplane", "pbp", MFnNumericData::kBoolean, true, &status);
MAKE_NONKEYABLE_INPUT(nAttr);
CHECK_MSTATUS(nAttr.setConnectable(false));
aPreviewIntensity = nAttr.create("previewIntensity", "pi", MFnNumericData::kDouble, 1.0, &status);
MAKE_NONKEYABLE_INPUT(nAttr);
CHECK_MSTATUS(nAttr.setConnectable(false));
aGLPreviewTexture = nAttr.createColor("GLPreviewTexture", "gpt");
nAttr.setDefault( -1.0, -1.0, -1.0 );
nAttr.setDisconnectBehavior( MFnAttribute::kReset );
MAKE_INPUT(nAttr);
aColor = nAttr.createColor("color", "cs");
nAttr.setDefault( 1.0, 1.0, 1.0 );
nAttr.setDisconnectBehavior( MFnAttribute::kReset );
MAKE_INPUT(nAttr);
aOpacity = nAttr.createColor("opacity", "os");
nAttr.setDefault( 1.0, 1.0, 1.0 );
MAKE_INPUT(nAttr);
aShaderSpace = tAttr.create( MString("shaderSpace"), MString("ssp"), MFnData::kString, aShaderSpace, &status );
MAKE_INPUT(tAttr);
aDisplacementBound = nAttr.create("displacementBound", "db", MFnNumericData::kDouble, 0.0, &status);
MAKE_INPUT(nAttr);
MObject defaultSpaceObj = tDefault.create( MString("shader"), &status);
aDisplacementBoundSpace = tAttr.create( MString("displacementBoundSpace"), MString("dbs"), MFnData::kString, defaultSpaceObj, &status );
MAKE_INPUT(tAttr);
aOutputInShadow = nAttr.create("outputInShadow", "ois", MFnNumericData::kBoolean, 0.0, &status);
MAKE_NONKEYABLE_INPUT(nAttr);
// resolution attribute for maya's hardware renderer
aResolution = nAttr.create("resolution", "res", MFnNumericData::kInt, 8, &status);
CHECK_MSTATUS(nAttr.setStorable( true ));
CHECK_MSTATUS(nAttr.setReadable( true ));
CHECK_MSTATUS(nAttr.setWritable( true ));
CHECK_MSTATUS(nAttr.setHidden( true ));
// refreshPreview must be true to allow refresh
aRefreshPreview = nAttr.create("refreshPreview", "rfp", MFnNumericData::kBoolean, 0.0, &status);
MAKE_NONKEYABLE_INPUT(nAttr);
CHECK_MSTATUS(nAttr.setHidden(true));
// dynamic shader attr
aCi = nAttr.createColor("Ci", "ci");
nAttr.setDefault( 1.0, 1.0, 1.0 );
MAKE_INPUT(nAttr);
aOi = nAttr.createColor("Oi", "oi");
nAttr.setDefault( 1.0, 1.0, 1.0 );
MAKE_INPUT(nAttr);
// create attributes for maya renderer
// lambertian control
aMayaIgnoreLights = nAttr.create("mayaIgnoreLights", "mil", MFnNumericData::kBoolean, 0.0, &status);
MAKE_INPUT(nAttr);
aMayaKa = nAttr.create("mayaKa", "mka", MFnNumericData::kFloat, 0.2, &status);
MAKE_INPUT(nAttr);
aMayaKd = nAttr.create("mayaKd", "mkd", MFnNumericData::kFloat, 0.8, &status);
MAKE_INPUT(nAttr);
// Camera Normals
aNormalCameraX = nAttr.create( "normalCameraX", "nx", MFnNumericData::kFloat, 0, &status );
CHECK_MSTATUS( status );
CHECK_MSTATUS( nAttr.setStorable( false ) );
CHECK_MSTATUS( nAttr.setDefault( 1.0f ) );
aNormalCameraY = nAttr.create( "normalCameraY", "ny", MFnNumericData::kFloat, 0, &status );
CHECK_MSTATUS( status );
CHECK_MSTATUS( nAttr.setStorable( false ) );
CHECK_MSTATUS( nAttr.setDefault( 1.0f ) );
aNormalCameraZ = nAttr.create( "normalCameraZ", "nz", MFnNumericData::kFloat, 0, &status );
CHECK_MSTATUS( status );
CHECK_MSTATUS( nAttr.setStorable( false ) );
CHECK_MSTATUS( nAttr.setDefault( 1.0f ) );
aNormalCamera = nAttr.create( "normalCamera","n", aNormalCameraX, aNormalCameraY, aNormalCameraZ, &status );
CHECK_MSTATUS( status );
CHECK_MSTATUS( nAttr.setStorable( false ) );
CHECK_MSTATUS( nAttr.setDefault( 1.0f, 1.0f, 1.0f ) );
CHECK_MSTATUS( nAttr.setHidden( true ) );
// Light Direction
aLightDirectionX = nAttr.create( "lightDirectionX", "ldx", MFnNumericData::kFloat, 0, &status );
CHECK_MSTATUS( status );
CHECK_MSTATUS( nAttr.setStorable( false ) );
CHECK_MSTATUS( nAttr.setHidden( true ) );
CHECK_MSTATUS( nAttr.setReadable( false ) );
CHECK_MSTATUS( nAttr.setDefault( 1.0f ) );
aLightDirectionY = nAttr.create( "lightDirectionY", "ldy", MFnNumericData::kFloat, 0, &status );
CHECK_MSTATUS( status );
CHECK_MSTATUS( nAttr.setStorable( false ) );
CHECK_MSTATUS( nAttr.setHidden( true ) );
CHECK_MSTATUS( nAttr.setReadable( false ) );
CHECK_MSTATUS( nAttr.setDefault( 1.0f ) );
aLightDirectionZ = nAttr.create( "lightDirectionZ", "ldz", MFnNumericData::kFloat, 0, &status );
CHECK_MSTATUS( status );
CHECK_MSTATUS( nAttr.setStorable( false ) );
CHECK_MSTATUS( nAttr.setHidden( true ) );
CHECK_MSTATUS( nAttr.setReadable( false ) );
CHECK_MSTATUS( nAttr.setDefault( 1.0f ) );
aLightDirection = nAttr.create( "lightDirection", "ld", aLightDirectionX, aLightDirectionY, aLightDirectionZ, &status );
CHECK_MSTATUS( status );
CHECK_MSTATUS( nAttr.setStorable( false ) );
CHECK_MSTATUS( nAttr.setHidden( true ) );
CHECK_MSTATUS( nAttr.setReadable( false ) );
CHECK_MSTATUS( nAttr.setDefault( 1.0f, 1.0f, 1.0f ) );
// Light Intensity
aLightIntensityR = nAttr.create( "lightIntensityR", "lir", MFnNumericData::kFloat, 0, &status );
CHECK_MSTATUS( status );
CHECK_MSTATUS( nAttr.setStorable( false ) );
CHECK_MSTATUS( nAttr.setHidden( true ) );
CHECK_MSTATUS( nAttr.setReadable( false ) );
CHECK_MSTATUS( nAttr.setDefault( 1.0f ) );
aLightIntensityG = nAttr.create( "lightIntensityG", "lig", MFnNumericData::kFloat, 0, &status );
CHECK_MSTATUS( status );
CHECK_MSTATUS( nAttr.setStorable( false ) );
CHECK_MSTATUS( nAttr.setHidden( true ) );
CHECK_MSTATUS( nAttr.setReadable( false ) );
CHECK_MSTATUS( nAttr.setDefault( 1.0f ) );
aLightIntensityB = nAttr.create( "lightIntensityB", "lib", MFnNumericData::kFloat, 0, &status );
CHECK_MSTATUS( status );
CHECK_MSTATUS( nAttr.setStorable( false ) );
CHECK_MSTATUS( nAttr.setHidden( true ) );
CHECK_MSTATUS( nAttr.setReadable( false ) );
CHECK_MSTATUS( nAttr.setDefault( 1.0f ) );
aLightIntensity = nAttr.create( "lightIntensity", "li", aLightIntensityR, aLightIntensityG, aLightIntensityB, &status );
CHECK_MSTATUS( status );
CHECK_MSTATUS( nAttr.setStorable( false ) );
CHECK_MSTATUS( nAttr.setHidden( true ) );
CHECK_MSTATUS( nAttr.setReadable( false ) );
CHECK_MSTATUS( nAttr.setDefault( 1.0f, 1.0f, 1.0f ) );
// Light
aLightAmbient = nAttr.create( "lightAmbient", "la", MFnNumericData::kBoolean, 0, &status );
CHECK_MSTATUS( status );
CHECK_MSTATUS( nAttr.setStorable( false ) );
CHECK_MSTATUS( nAttr.setHidden( true ) );
CHECK_MSTATUS( nAttr.setReadable( false ) );
CHECK_MSTATUS( nAttr.setDefault( true ) );
aLightDiffuse = nAttr.create( "lightDiffuse", "ldf", MFnNumericData::kBoolean, 0, &status );
CHECK_MSTATUS( status );
CHECK_MSTATUS( nAttr.setStorable( false ) );
CHECK_MSTATUS( nAttr.setHidden( true ) );
CHECK_MSTATUS( nAttr.setReadable( false ) );
CHECK_MSTATUS( nAttr.setDefault( true ) );
aLightSpecular = nAttr.create( "lightSpecular", "ls", MFnNumericData::kBoolean, 0, &status );
CHECK_MSTATUS( status );
CHECK_MSTATUS( nAttr.setStorable( false ) );
CHECK_MSTATUS( nAttr.setHidden( true ) );
CHECK_MSTATUS( nAttr.setReadable( false ) );
CHECK_MSTATUS( nAttr.setDefault( false ) );
aLightShadowFraction = nAttr.create( "lightShadowFraction", "lsf", MFnNumericData::kFloat, 0, &status );
CHECK_MSTATUS( status );
CHECK_MSTATUS( nAttr.setStorable( false ) );
CHECK_MSTATUS( nAttr.setReadable( true ) );
CHECK_MSTATUS( nAttr.setWritable( true ) );
CHECK_MSTATUS( nAttr.setDefault( 1.0f ) );
aPreShadowIntensity = nAttr.create( "preShadowIntensity", "psi", MFnNumericData::kFloat, 0, &status );
CHECK_MSTATUS( status );
CHECK_MSTATUS( nAttr.setStorable( false ) );
CHECK_MSTATUS( nAttr.setHidden( true ) );
CHECK_MSTATUS( nAttr.setReadable( false ) );
CHECK_MSTATUS( nAttr.setDefault( 1.0f ) );
#if MAYA_API_VERSION >= 800
aLightBlindData = nAttr.createAddr( "lightBlindData", "lbld", 0, &status );
CHECK_MSTATUS( status );
CHECK_MSTATUS( nAttr.setStorable( false ) );
CHECK_MSTATUS( nAttr.setHidden( true ) );
CHECK_MSTATUS( nAttr.setReadable( false ) );
CHECK_MSTATUS( nAttr.setDefault( (void*) 0 ) );
#else
aLightBlindData = nAttr.create( "lightBlindData", "lbld", MFnNumericData::kLong, 0, &status );
CHECK_MSTATUS( status );
CHECK_MSTATUS( nAttr.setStorable( false ) );
CHECK_MSTATUS( nAttr.setHidden( true ) );
CHECK_MSTATUS( nAttr.setReadable( false ) );
CHECK_MSTATUS( nAttr.setDefault( 0 ) );
#endif
aLightData = lAttr.create( "lightDataArray", "ltd", aLightDirection,
aLightIntensity, aLightAmbient, aLightDiffuse, aLightSpecular,
aLightShadowFraction, aPreShadowIntensity, aLightBlindData,
&status );
CHECK_MSTATUS( status );
CHECK_MSTATUS( lAttr.setArray( true ) );
CHECK_MSTATUS( lAttr.setStorable( false ) );
CHECK_MSTATUS( lAttr.setHidden( true ) );
CHECK_MSTATUS( lAttr.setDefault( 0.0f, 0.0f, 0.0f, 0.0f, 0.0f, 0.0f, true, true, false, 1.0f, 1.0f, 0 ) );
// Create output attributes
aOutColor = nAttr.createColor("outColor", "oc");
MAKE_OUTPUT(nAttr);
aOutTransparency = nAttr.createColor("outTransparency", "ot");
MAKE_OUTPUT(nAttr);
aAssignedObjects = mAttr.create("liqAssignedObjects", "ao");
MAKE_OUTPUT(mAttr);
CHECK_MSTATUS(addAttribute(aRmanShader));
CHECK_MSTATUS(addAttribute(aRmanShaderLong));
CHECK_MSTATUS(addAttribute(aRmanShaderLif));
CHECK_MSTATUS(addAttribute(aRmanParams));
CHECK_MSTATUS(addAttribute(aRmanDetails));
CHECK_MSTATUS(addAttribute(aRmanTypes));
CHECK_MSTATUS(addAttribute(aRmanDefaults));
CHECK_MSTATUS(addAttribute(aRmanArraySizes));
CHECK_MSTATUS(addAttribute(aRmanLifCmds));
CHECK_MSTATUS(addAttribute(aPreviewPrimitive));
CHECK_MSTATUS(addAttribute(aPreviewCustomPrimitive));
CHECK_MSTATUS(addAttribute(aPreviewCustomBackplane));
CHECK_MSTATUS(addAttribute(aPreviewCustomLightRig));
CHECK_MSTATUS(addAttribute(aPreviewObjectSize));
CHECK_MSTATUS(addAttribute(aPreviewPixelSamples));
CHECK_MSTATUS(addAttribute(aPreviewShadingRate));
CHECK_MSTATUS(addAttribute(aPreviewBackplane));
CHECK_MSTATUS(addAttribute(aPreviewIntensity));
CHECK_MSTATUS(addAttribute(aGLPreviewTexture));
CHECK_MSTATUS(addAttribute(aCi));
CHECK_MSTATUS(addAttribute(aOi));
CHECK_MSTATUS(addAttribute(aColor));
CHECK_MSTATUS(addAttribute(aOpacity));
CHECK_MSTATUS(addAttribute(aShaderSpace));
CHECK_MSTATUS(addAttribute(aDisplacementBound));
CHECK_MSTATUS(addAttribute(aDisplacementBoundSpace));
CHECK_MSTATUS(addAttribute(aOutputInShadow));
CHECK_MSTATUS(addAttribute(aResolution));
CHECK_MSTATUS(addAttribute(aRefreshPreview));
CHECK_MSTATUS(addAttribute(aMayaIgnoreLights));
CHECK_MSTATUS(addAttribute(aMayaKa));
CHECK_MSTATUS(addAttribute(aMayaKd));
CHECK_MSTATUS(addAttribute(aNormalCamera));
CHECK_MSTATUS(addAttribute(aLightData));
CHECK_MSTATUS(addAttribute(aAssignedObjects));
CHECK_MSTATUS(addAttribute(aOutColor));
CHECK_MSTATUS(addAttribute(aOutTransparency));
CHECK_MSTATUS(attributeAffects( aColor, aOutColor ));
CHECK_MSTATUS(attributeAffects( aOpacity, aOutColor ));
CHECK_MSTATUS(attributeAffects( aGLPreviewTexture, aOutColor ));
CHECK_MSTATUS(attributeAffects( aMayaIgnoreLights, aOutColor ));
CHECK_MSTATUS(attributeAffects( aMayaKa, aOutColor ));
CHECK_MSTATUS(attributeAffects( aMayaKd, aOutColor ));
CHECK_MSTATUS(attributeAffects( aLightIntensityR, aOutColor ));
CHECK_MSTATUS(attributeAffects( aLightIntensityB, aOutColor ));
CHECK_MSTATUS(attributeAffects( aLightIntensityG, aOutColor ));
CHECK_MSTATUS(attributeAffects( aLightIntensity, aOutColor ));
CHECK_MSTATUS(attributeAffects( aNormalCameraX, aOutColor ));
CHECK_MSTATUS(attributeAffects( aNormalCameraY, aOutColor ));
CHECK_MSTATUS(attributeAffects( aNormalCameraZ, aOutColor ));
CHECK_MSTATUS(attributeAffects( aNormalCamera, aOutColor ));
CHECK_MSTATUS(attributeAffects( aLightDirectionX, aOutColor ));
CHECK_MSTATUS(attributeAffects( aLightDirectionY, aOutColor ));
CHECK_MSTATUS(attributeAffects( aLightDirectionZ, aOutColor ));
CHECK_MSTATUS(attributeAffects( aLightDirection, aOutColor ));
CHECK_MSTATUS(attributeAffects( aLightAmbient, aOutColor ));
CHECK_MSTATUS(attributeAffects( aLightSpecular, aOutColor ));
CHECK_MSTATUS(attributeAffects( aLightDiffuse, aOutColor ));
CHECK_MSTATUS(attributeAffects( aLightShadowFraction, aOutColor ));
CHECK_MSTATUS(attributeAffects( aPreShadowIntensity, aOutColor ));
CHECK_MSTATUS(attributeAffects( aLightBlindData, aOutColor ));
CHECK_MSTATUS(attributeAffects( aLightData, aOutColor ));
return MS::kSuccess;
}
MStatus sixdofConstraintNode::initialize()
{
MStatus status;
MFnMessageAttribute fnMsgAttr;
MFnNumericAttribute fnNumericAttr;
MFnMatrixAttribute fnMatrixAttr;
ia_rigidBodyA = fnMsgAttr.create("inRigidBodyA", "inrbA", &status);
MCHECKSTATUS(status, "creating inRigidBodyA attribute")
status = addAttribute(ia_rigidBodyA);
MCHECKSTATUS(status, "adding inRigidBody attribute")
ia_rigidBodyB = fnMsgAttr.create("inRigidBodyB", "inrbB", &status);
MCHECKSTATUS(status, "creating inRigidBodyB attribute")
status = addAttribute(ia_rigidBodyB);
MCHECKSTATUS(status, "adding inRigidBodyB attribute")
ia_damping = fnNumericAttr.create("damping", "dmp", MFnNumericData::kDouble, 1.0, &status);
MCHECKSTATUS(status, "creating damping attribute")
fnNumericAttr.setKeyable(true);
status = addAttribute(ia_damping);
MCHECKSTATUS(status, "adding damping attribute")
ia_lowerLinLimit = fnNumericAttr.create("lowerLinLimit", "lllt", MFnNumericData::kDouble, 1, &status);
MCHECKSTATUS(status, "creating lower linear limit attribute")
fnNumericAttr.setKeyable(true);
status = addAttribute(ia_lowerLinLimit);
MCHECKSTATUS(status, "adding lower linear limit attribute")
ia_upperLinLimit = fnNumericAttr.create("upperLinLimit", "ullt", MFnNumericData::kDouble, -1, &status);
MCHECKSTATUS(status, "creating upper linear limit attribute")
fnNumericAttr.setKeyable(true);
status = addAttribute(ia_upperLinLimit);
MCHECKSTATUS(status, "adding upper linear limit attribute")
ia_lowerAngLimit = fnNumericAttr.create("lowerAngLimit", "lalt", MFnNumericData::kDouble, 0, &status);
MCHECKSTATUS(status, "creating lower angular limit attribute")
fnNumericAttr.setKeyable(true);
status = addAttribute(ia_lowerAngLimit);
MCHECKSTATUS(status, "adding lower angular limit attribute")
ia_upperAngLimit = fnNumericAttr.create("upperAngLimit", "ualt", MFnNumericData::kDouble, 0, &status);
MCHECKSTATUS(status, "creating upper angular limit attribute")
fnNumericAttr.setKeyable(true);
status = addAttribute(ia_upperAngLimit);
MCHECKSTATUS(status, "adding upper angular limit attribute")
ca_constraint = fnNumericAttr.create("ca_constraint", "caco", MFnNumericData::kBoolean, 0, &status);
MCHECKSTATUS(status, "creating ca_constraint attribute")
fnNumericAttr.setConnectable(false);
fnNumericAttr.setHidden(true);
fnNumericAttr.setStorable(false);
fnNumericAttr.setKeyable(false);
status = addAttribute(ca_constraint);
MCHECKSTATUS(status, "adding ca_constraint attribute")
ca_constraintParam = fnNumericAttr.create("ca_constraintParam", "cacop", MFnNumericData::kBoolean, 0, &status);
MCHECKSTATUS(status, "creating ca_constraintParam attribute")
fnNumericAttr.setConnectable(false);
fnNumericAttr.setHidden(true);
fnNumericAttr.setStorable(false);
fnNumericAttr.setKeyable(false);
status = addAttribute(ca_constraintParam);
MCHECKSTATUS(status, "adding ca_constraintParam attribute")
status = attributeAffects(ia_rigidBodyA, ca_constraint);
MCHECKSTATUS(status, "adding attributeAffects(ia_rigidBodyA, ca_constraint)")
status = attributeAffects(ia_rigidBodyA, ca_constraintParam);
MCHECKSTATUS(status, "adding attributeAffects(ia_rigidBodyA, ca_constraintParam)")
status = attributeAffects(ia_rigidBodyB, ca_constraint);
MCHECKSTATUS(status, "adding attributeAffects(ia_rigidBodyB, ca_constraint)")
status = attributeAffects(ia_rigidBodyB, ca_constraintParam);
MCHECKSTATUS(status, "adding attributeAffects(ia_rigidBodyB, ca_constraintParam)")
status = attributeAffects(ia_damping, ca_constraintParam);
MCHECKSTATUS(status, "adding attributeAffects(ia_damping, ca_constraintParam)")
status = attributeAffects(ia_lowerLinLimit, ca_constraintParam);
MCHECKSTATUS(status, "adding attributeAffects(ia_lowerLinLimit, ca_constraintParam)")
status = attributeAffects(ia_upperLinLimit, ca_constraintParam);
MCHECKSTATUS(status, "adding attributeAffects(ia_upperLinLimit, ca_constraintParam)")
status = attributeAffects(ia_lowerAngLimit, ca_constraintParam);
MCHECKSTATUS(status, "adding attributeAffects(ia_lowerAngLimit, ca_constraintParam)")
status = attributeAffects(ia_upperAngLimit, ca_constraintParam);
MCHECKSTATUS(status, "adding attributeAffects(ia_upperAngLimit, ca_constraintParam)")
return MS::kSuccess;
}
MStatus MayaToIndigoGlobals::initialize()
{
MayaRenderGlobalsNode::initialize();
MFnNumericAttribute nAttr;
MFnTypedAttribute tAttr;
MFnGenericAttribute gAttr;
MFnEnumAttribute eAttr;
MFnMessageAttribute mAttr;
MStatus stat = MStatus::kSuccess;
// ------------- automatically created attributes start ----------- //
white_point = eAttr.create("white_point", "white_point", 4, &stat);
stat = eAttr.addField( "User", 0 );
stat = eAttr.addField( "A", 1 );
stat = eAttr.addField( "B", 2 );
stat = eAttr.addField( "C", 3 );
stat = eAttr.addField( "D50", 4 );
stat = eAttr.addField( "D55", 5 );
stat = eAttr.addField( "D65", 6 );
stat = eAttr.addField( "D75", 7 );
stat = eAttr.addField( "E", 8 );
stat = eAttr.addField( "F1", 9 );
stat = eAttr.addField( "F2", 10 );
stat = eAttr.addField( "F3", 11 );
stat = eAttr.addField( "F4", 12 );
stat = eAttr.addField( "F5", 13 );
stat = eAttr.addField( "F6", 14 );
stat = eAttr.addField( "F7", 15 );
stat = eAttr.addField( "F8", 16 );
stat = eAttr.addField( "F9", 17 );
stat = eAttr.addField( "F10", 18 );
stat = eAttr.addField( "F11", 19 );
stat = eAttr.addField( "F12", 20 );
CHECK_MSTATUS(addAttribute( white_point ));
white_pointX = nAttr.create("white_pointX", "white_pointX", MFnNumericData::kFloat, 0.0);
CHECK_MSTATUS(addAttribute( white_pointX ));
white_pointY = nAttr.create("white_pointY", "white_pointY", MFnNumericData::kFloat, 0.0);
CHECK_MSTATUS(addAttribute( white_pointY ));
bih_tri_threshold = nAttr.create("bih_tri_threshold", "bih_tri_threshold", MFnNumericData::kInt, 1100000);
CHECK_MSTATUS(addAttribute( bih_tri_threshold ));
metropolis = nAttr.create("metropolis", "metropolis", MFnNumericData::kBoolean, true);
CHECK_MSTATUS(addAttribute( metropolis ));
large_mutation_prob = nAttr.create("large_mutation_prob", "large_mutation_prob", MFnNumericData::kFloat, 0.1);
CHECK_MSTATUS(addAttribute( large_mutation_prob ));
max_change = nAttr.create("max_change", "max_change", MFnNumericData::kFloat, .01);
CHECK_MSTATUS(addAttribute( max_change ));
max_num_consec_rejections = nAttr.create("max_num_consec_rejections", "max_num_consec_rejections", MFnNumericData::kInt, 1000);
CHECK_MSTATUS(addAttribute( max_num_consec_rejections ));
logging = nAttr.create("logging", "logging", MFnNumericData::kBoolean, true);
CHECK_MSTATUS(addAttribute( logging ));
path_tracing = eAttr.create("path_tracing", "path_tracing", 0, &stat);
stat = eAttr.addField( "bidirectional", 0 );
stat = eAttr.addField( "backwards", 1 );
CHECK_MSTATUS(addAttribute( path_tracing ));
tone_mapper = eAttr.create("tone_mapper", "tone_mapper", 1, &stat);
stat = eAttr.addField( "linear", 0 );
stat = eAttr.addField( "reinhard", 1 );
stat = eAttr.addField( "camera", 2 );
CHECK_MSTATUS(addAttribute( tone_mapper ));
tone_linearScale = nAttr.create("tone_linearScale", "tone_linearScale", MFnNumericData::kFloat, 1.0);
nAttr.setMin(0.0001);
nAttr.setMax(100);
CHECK_MSTATUS(addAttribute( tone_linearScale ));
tone_reinhardPreScale = nAttr.create("tone_reinhardPreScale", "tone_reinhardPreScale", MFnNumericData::kFloat, 1.0);
CHECK_MSTATUS(addAttribute( tone_reinhardPreScale ));
tone_reinhardPostScale = nAttr.create("tone_reinhardPostScale", "tone_reinhardPostScale", MFnNumericData::kFloat, 1.0);
CHECK_MSTATUS(addAttribute( tone_reinhardPostScale ));
tone_reinhardBurn = nAttr.create("tone_reinhardBurn", "tone_reinhardBurn", MFnNumericData::kFloat, 10.0);
CHECK_MSTATUS(addAttribute( tone_reinhardBurn ));
tone_cameraResponse_function_path = tAttr.create("tone_cameraResponse_function_path", "tone_cameraResponse_function_path", MFnNumericData::kString);
CHECK_MSTATUS(addAttribute( tone_cameraResponse_function_path ));
tone_cameraEv_adjust = nAttr.create("tone_cameraEv_adjust", "tone_cameraEv_adjust", MFnNumericData::kFloat, 0.0);
CHECK_MSTATUS(addAttribute( tone_cameraEv_adjust ));
tone_cameraFilm_iso = nAttr.create("tone_cameraFilm_iso", "tone_cameraFilm_iso", MFnNumericData::kFloat, 200.0);
CHECK_MSTATUS(addAttribute( tone_cameraFilm_iso ));
save_untonemapped_exr = nAttr.create("save_untonemapped_exr", "save_untonemapped_exr", MFnNumericData::kBoolean, false);
CHECK_MSTATUS(addAttribute( save_untonemapped_exr ));
save_tonemapped_exr = nAttr.create("save_tonemapped_exr", "save_tonemapped_exr", MFnNumericData::kBoolean, true);
CHECK_MSTATUS(addAttribute( save_tonemapped_exr ));
save_igi = nAttr.create("save_igi", "save_igi", MFnNumericData::kBoolean, false);
CHECK_MSTATUS(addAttribute( save_igi ));
image_save_period = nAttr.create("image_save_period", "image_save_period", MFnNumericData::kFloat, 60);
CHECK_MSTATUS(addAttribute( image_save_period ));
halt_time = nAttr.create("halt_time", "halt_time", MFnNumericData::kFloat, -1);
CHECK_MSTATUS(addAttribute( halt_time ));
halt_samples_per_pixel = nAttr.create("halt_samples_per_pixel", "halt_samples_per_pixel", MFnNumericData::kInt, -1);
CHECK_MSTATUS(addAttribute( halt_samples_per_pixel ));
hybrid = nAttr.create("hybrid", "hybrid", MFnNumericData::kBoolean, false);
CHECK_MSTATUS(addAttribute( hybrid ));
auto_choose_num_threads = nAttr.create("auto_choose_num_threads", "auto_choose_num_threads", MFnNumericData::kBoolean, true);
CHECK_MSTATUS(addAttribute( auto_choose_num_threads ));
num_threads = nAttr.create("num_threads", "num_threads", MFnNumericData::kBoolean, 1);
CHECK_MSTATUS(addAttribute( num_threads ));
super_sample_factor = nAttr.create("super_sample_factor", "super_sample_factor", MFnNumericData::kInt, 2);
CHECK_MSTATUS(addAttribute( super_sample_factor ));
watermark = nAttr.create("watermark", "watermark", MFnNumericData::kBoolean, false);
CHECK_MSTATUS(addAttribute( watermark ));
info_overlay = nAttr.create("info_overlay", "info_overlay", MFnNumericData::kBoolean, false);
CHECK_MSTATUS(addAttribute( info_overlay ));
cache_trees = nAttr.create("cache_trees", "cache_trees", MFnNumericData::kBoolean, true);
CHECK_MSTATUS(addAttribute( cache_trees ));
aperture_diffraction = nAttr.create("aperture_diffraction", "aperture_diffraction", MFnNumericData::kBoolean, true);
CHECK_MSTATUS(addAttribute( aperture_diffraction ));
post_process_diffraction = nAttr.create("post_process_diffraction", "post_process_diffraction", MFnNumericData::kBoolean, true);
CHECK_MSTATUS(addAttribute( post_process_diffraction ));
render_foreground_alpha = nAttr.create("render_foreground_alpha", "render_foreground_alpha", MFnNumericData::kBoolean, false);
CHECK_MSTATUS(addAttribute( render_foreground_alpha ));
splat_filter = eAttr.create("splat_filter", "splat_filter", 0, &stat);
stat = eAttr.addField( "fastbox", 0 );
stat = eAttr.addField( "radial", 1 );
stat = eAttr.addField( "mn_cubic", 2 );
CHECK_MSTATUS(addAttribute( splat_filter ));
splat_filter_cubic_b = nAttr.create("splat_filter_cubic_b", "splat_filter_cubic_b", MFnNumericData::kFloat, 0.6);
CHECK_MSTATUS(addAttribute( splat_filter_cubic_b ));
splat_filter_cubic_ring = nAttr.create("splat_filter_cubic_ring", "splat_filter_cubic_ring", MFnNumericData::kFloat, 0.2);
CHECK_MSTATUS(addAttribute( splat_filter_cubic_ring ));
downsize_filter = eAttr.create("downsize_filter", "downsize_filter", 0, &stat);
stat = eAttr.addField( "mn_cubic", 0 );
stat = eAttr.addField( "gauss", 1 );
stat = eAttr.addField( "sharp", 2 );
CHECK_MSTATUS(addAttribute( downsize_filter ));
downsize_filter_cubic_radius = nAttr.create("downsize_filter_cubic_radius", "downsize_filter_cubic_radius", MFnNumericData::kFloat, 2);
CHECK_MSTATUS(addAttribute( downsize_filter_cubic_radius ));
vignetting = nAttr.create("vignetting", "vignetting", MFnNumericData::kBoolean, true);
CHECK_MSTATUS(addAttribute( vignetting ));
gpu = nAttr.create("gpu", "gpu", MFnNumericData::kBoolean, false);
CHECK_MSTATUS(addAttribute( gpu ));
selected_gpu_device = eAttr.create("selected_gpu_device", "selected_gpu_device", 0, &stat);
stat = eAttr.addField( "CUDA", 0 );
stat = eAttr.addField( "OPEN_CL", 1 );
CHECK_MSTATUS(addAttribute( selected_gpu_device ));
glass_acceleration = nAttr.create("glass_acceleration", "glass_acceleration", MFnNumericData::kBoolean, false);
CHECK_MSTATUS(addAttribute( glass_acceleration ));
environmentType = eAttr.create("environmentType", "environmentType", 1, &stat);
stat = eAttr.addField( "Off", 0 );
stat = eAttr.addField( "Color/Map", 1 );
stat = eAttr.addField( "Sun", 2 );
CHECK_MSTATUS(addAttribute( environmentType ));
environmentColor = nAttr.createColor("environmentColor", "environmentColor");
nAttr.setDefault(0.4,0.4,1.0);
CHECK_MSTATUS(addAttribute( environmentColor ));
environmentSun = mAttr.create("environmentSun", "environmentSun");
CHECK_MSTATUS(addAttribute( environmentSun ));
turbidity = nAttr.create("turbidity", "turbidity", MFnNumericData::kFloat, 2.0);
CHECK_MSTATUS(addAttribute( turbidity ));
extra_atmospheric = nAttr.create("extra_atmospheric", "extra_atmospheric", MFnNumericData::kBoolean, false);
CHECK_MSTATUS(addAttribute( extra_atmospheric ));
sun_layer = nAttr.create("sun_layer", "sun_layer", MFnNumericData::kInt, 0);
CHECK_MSTATUS(addAttribute( sun_layer ));
sky_layer = nAttr.create("sky_layer", "sky_layer", MFnNumericData::kInt, 0);
CHECK_MSTATUS(addAttribute( sky_layer ));
sky_model = eAttr.create("sky_model", "sky_model", 0, &stat);
stat = eAttr.addField( "original", 0 );
stat = eAttr.addField( "captured-simulation", 1 );
CHECK_MSTATUS(addAttribute( sky_model ));
environmentMapType = eAttr.create("environmentMapType", "environmentMapType", 0, &stat);
stat = eAttr.addField( "Spherical", 0 );
stat = eAttr.addField( "Lat-Long", 1 );
CHECK_MSTATUS(addAttribute( environmentMapType ));
environmentMapMultiplier = nAttr.create("environmentMapMultiplier", "environmentMapMultiplier", MFnNumericData::kFloat, 1.0);
CHECK_MSTATUS(addAttribute( environmentMapMultiplier ));
MFnStringData fnStringData;
MObject defaultString;
defaultString = fnStringData.create( "notepad.exe" );
preferredTextEditor = tAttr.create("preferredTextEditor", "preferredTextEditor", MFnNumericData::kString, defaultString);
CHECK_MSTATUS(addAttribute( preferredTextEditor ));
// ------------- automatically created attributes end ----------- //
return stat;
}
MStatus lrutils::loadGeoReference(MString geoFilePath, MString geoName, MString & name, MObject & geoObj) {
MStatus status = MS::kFailure;
MString projPath = MGlobal::executeCommandStringResult(MString("workspace -q -rd;"),false,false);
MString relativePath = geoFilePath.substring(2,geoFilePath.numChars() - 1);
//assemble the full file path of the geometry file
MString fullGeoPath = projPath + relativePath;
//load the geometry file as a reference into the current scene
//check to see if the referenced file has already been used
MStringArray refNodeList;
status = MFileIO::getReferences(refNodeList, true);
MyCheckStatus(status, "getReferences failed");
int numReferences = 0;
for(unsigned int i = 0; i < refNodeList.length(); i++) {
MString tmp = refNodeList[i];
string tmp1 = tmp.asChar();
string tmp2 = fullGeoPath.asChar();
if(std::string::npos != tmp1.find(tmp2))
numReferences++;
}
string str (geoFilePath.asChar());
string key ("/");
size_t found = str.rfind(key);
string fileName = str.substr(found+1,str.length()-found-4);
string fileNamespace;
if(numReferences > 0) {
stringstream tmp;
tmp << fileName << (numReferences+1);
fileNamespace = tmp.str();
} else { fileNamespace = fileName; }
{
stringstream tmp;
tmp << "file -r -type \"mayaAscii\" -gl -loadReferenceDepth \"all\" -namespace \"" << fileNamespace.c_str() << "\" -options \"v=0\" \"" << fullGeoPath.asChar() << "\";";
MString referenceCommand = MString(tmp.str().c_str());
MGlobal::executeCommand(referenceCommand);
}
//get the referenced geometry transform node and add the metaParent
//attribute to it
MSelectionList selection;
if(numReferences > 0) {
name += (boost::lexical_cast<string>(numReferences+1)).c_str();
}
stringstream geoRefName;
geoRefName << fileNamespace << ":" << geoName;
MString mGeoRefName = MString(geoRefName.str().c_str());
status = selection.add( mGeoRefName, true );
MyCheckStatusReturn(status, "add geoRefName "+mGeoRefName+" to selection failed.");
if(selection.length() )
selection.getDependNode(0, geoObj);
MFnTransform transformFn;
transformFn.setObject(geoObj);
MFnMessageAttribute mAttr;
MObject transformAttr = mAttr.create("metaParent", "metaParent");
transformFn.addAttribute(transformAttr);
if( !geoObj.isNull() )
status = MS::kSuccess;
return status;
}
MStatus collisionShapeNode::initialize()
{
MStatus status;
MFnMessageAttribute fnMsgAttr;
MFnNumericAttribute fnNumericAttr;
MFnEnumAttribute fnEnumAttr;
ia_type = fnEnumAttr.create("type", "tp", 7, &status);
MCHECKSTATUS(status, "creating type attribute")
fnEnumAttr.addField("Convex Hull", 0);
fnEnumAttr.addField("Mesh", 1);
fnEnumAttr.addField("Cylinder", 2);
fnEnumAttr.addField("Capsule", 3);
fnEnumAttr.addField("Box", 4);
fnEnumAttr.addField("Sphere", 5);
fnEnumAttr.addField("Plane", 6);
fnEnumAttr.addField("BvhMesh", 7);
fnEnumAttr.addField("HACD", 8);
fnEnumAttr.setKeyable(true);
status = addAttribute(ia_type);
MCHECKSTATUS(status, "adding type attribute")
ia_scale = fnNumericAttr.createPoint("scale", "sc", &status);
MCHECKSTATUS(status, "creating ia_scale attribute")
fnNumericAttr.setDefault(1.0, 1.0, 1.0);
fnNumericAttr.setKeyable(true);
status = addAttribute(ia_scale);
MCHECKSTATUS(status, "adding ia_scale attribute")
oa_collisionShape = fnMsgAttr.create("outCollisionShape", "oucs", &status);
MCHECKSTATUS(status, "creating outCollisionShape attribute")
status = addAttribute(oa_collisionShape);
MCHECKSTATUS(status, "adding outCollisionShape attribute")
ia_shape = fnMsgAttr.create("inShape", "insh", &status);
MCHECKSTATUS(status, "creating inShape attribute")
status = addAttribute(ia_shape);
MCHECKSTATUS(status, "adding inShape attribute")
ca_collisionShape = fnNumericAttr.create("ca_collisionShape", "ccs", MFnNumericData::kBoolean, 0, &status);
MCHECKSTATUS(status, "creating ca_collisionShape attribute")
fnNumericAttr.setWorldSpace(true);
fnNumericAttr.setConnectable(false);
fnNumericAttr.setHidden(true);
fnNumericAttr.setStorable(false);
fnNumericAttr.setKeyable(false);
status = addAttribute(ca_collisionShape);
MCHECKSTATUS(status, "adding ca_collisionShape attribute")
ca_collisionShapeParam = fnNumericAttr.create("collisionShapeParam", "cspm", MFnNumericData::kBoolean, 0, &status);
MCHECKSTATUS(status, "creating ca_collisionShapeParam attribute")
fnNumericAttr.setConnectable(false);
fnNumericAttr.setHidden(true);
fnNumericAttr.setStorable(false);
fnNumericAttr.setKeyable(false);
status = addAttribute(ca_collisionShapeParam);
MCHECKSTATUS(status, "adding ca_collisionShapeParam attribute")
//
status = attributeAffects(ia_shape, oa_collisionShape);
MCHECKSTATUS(status, "adding attributeAffects(ia_shape, oa_collisionShape)")
status = attributeAffects(ia_type, oa_collisionShape);
MCHECKSTATUS(status, "adding attributeAffects(ia_type, oa_collisionShape)")
status = attributeAffects(ia_scale, oa_collisionShape);
MCHECKSTATUS(status, "adding attributeAffects(ia_scale, oa_collisionShape)")
//
status = attributeAffects(ia_shape, ca_collisionShape);
MCHECKSTATUS(status, "adding attributeAffects(ia_shape, ca_collisionShape)")
status = attributeAffects(ia_type, ca_collisionShape);
MCHECKSTATUS(status, "adding attributeAffects(ia_shape, ca_collisionShape)")
//
status = attributeAffects(ia_shape, ca_collisionShapeParam);
MCHECKSTATUS(status, "adding attributeAffects(ia_shape, oa_collisionShapeParam)")
status = attributeAffects(ia_scale, ca_collisionShapeParam);
MCHECKSTATUS(status, "adding attributeAffects(ia_scale, oa_collisionShapeParam)")
status = attributeAffects(ia_type, ca_collisionShapeParam);
MCHECKSTATUS(status, "adding attributeAffects(ia_type, oa_collisionShapeParam)")
return MS::kSuccess;
}
MObject GlobalComponent::loadComponent(MDGModifier & dgMod) {
MStatus status = MS::kFailure;
this->m_metaDataNode = dgMod.createNode( "MDGlobalNode", &status );
MyCheckStatus(status, "createNode failed");
MString metaNodeName = "MGN_";
metaNodeName += this->m_rigName + "_";
metaNodeName += this->m_pCompGuide->getName();
dgMod.renameNode(this->m_metaDataNode, metaNodeName);
MFnDependencyNode depMetaDataNodeFn(this->m_metaDataNode);
status = dgMod.newPlugValueFloat( depMetaDataNodeFn.findPlug("version"), this->m_pCompGuide->getVersion() );
MyCheckStatus(status, "newPlugValueFloat() failed");
status = dgMod.newPlugValueString( depMetaDataNodeFn.findPlug("rigId"), this->m_pCompGuide->getRigId() );
MyCheckStatus(status, "newPlugValueInt() failed");
GlobalComponentGuidePtr globalGuide = boost::dynamic_pointer_cast<GlobalComponentGuide>(this->m_pCompGuide);
MString ctlColor = globalGuide->getColor();
MString ctlIcon = globalGuide->getIcon();
status = MGlobal::executeCommand( "python(\"control = rig101().rig101WCGetByName('" + ctlIcon + "')\");" );
status = MGlobal::executeCommand( "python(\"Utils.setControllerColor(control, '" + ctlColor + "')\");" );
MCommandResult res;
status = MGlobal::executeCommand( MString("python(\"control.fullPath()\");"), res );
int resType = res.resultType();
if( resType == MCommandResult::kString ) {
MString sResult;
res.getResult(sResult);
MObject ctlObj;
status = lrutils::getObjFromName(sResult, ctlObj);
MyCheckStatus(status, "lrutils::getObjFromName() failed");
MVectorArray ctlLocation = this->m_pCompGuide->getLocation(0);
MFnTransform transformFn( ctlObj );
lrutils::setLocation(ctlObj, ctlLocation, MFnTransform::MFnTransform(), false, false, true);
MString ctlName = this->m_rigName + "_" + this->m_pCompGuide->getName() + "_CTL";
dgMod.renameNode(ctlObj, ctlName);
dgMod.doIt();
//add the metaParent attribute to the controller
MFnMessageAttribute mAttr;
MObject transformAttr = mAttr.create("metaParent", "metaParent");
transformFn.addAttribute(transformAttr);
//connect the controller's metaParent to the MDGlobal node
status = dgMod.connect( depMetaDataNodeFn.findPlug("controller"), transformFn.findPlug("metaParent") );
MObject ctlGroupObj;
lrutils::makeHomeNull(ctlObj, MFnTransform(), ctlGroupObj);
lrutils::setLocation(ctlGroupObj, ctlLocation, MFnTransform::MFnTransform(), true, true, false);
MFnTransform ctlGroupFn( ctlGroupObj );
//add the metaParent attribute to the controller group
ctlGroupFn.addAttribute(mAttr.create("metaParent", "metaParent"));
//connect the controller group's metaParent to the MDGlobal node
status = dgMod.connect( depMetaDataNodeFn.findPlug("controllerGroup"), ctlGroupFn.findPlug("metaParent") );
MyCheckStatus(status, "connect failed");
MObject metaRootObj;
status = lrutils::getMetaRootByName(metaRootObj, this->m_rigName);
MyCheckStatus(status, "lrutils::getMetaRootByName() failed");
MObject rigCtlGroupObj;
status = lrutils::getMetaNodeConnection(metaRootObj, rigCtlGroupObj, "ctlGroup");
MyCheckStatus(status, "lrutils::getMetaNodeConnection() failed");
MFnTransform rigCtlGroupFn( rigCtlGroupObj );
rigCtlGroupFn.addChild( ctlGroupObj );
//add controller to controller display layer
MObject controlLayerObj;
status = lrutils::getMetaNodeConnection(metaRootObj, controlLayerObj, "ctlLayer");
MyCheckStatus(status, "lrutils::getMetaNodeConnection() failed");
MFnDependencyNode controlLayerFn(controlLayerObj);
MString controlLayerName = controlLayerFn.name();
MGlobal::executeCommand("editDisplayLayerMembers -noRecurse "+controlLayerName+" "+rigCtlGroupFn.name()+";");
//create parent constraints from the global controller to the rig group
MObject rigRigGroupObj;
status = lrutils::getMetaNodeConnection(metaRootObj, rigRigGroupObj, "rigGroup");
MFnTransform rigRigGroupFn( rigRigGroupObj );
MGlobal::executeCommand("parentConstraint -mo "+transformFn.name()+" "+rigRigGroupFn.name()+";", res);
//connect the parent constraint object to the component's metadata node
MStringArray sResults;
res.getResult(sResults);
status = lrutils::getObjFromName(sResults[0], this->m_rigParentConstraint);
MyCheckStatus(status, "lrutils::getObjFromName() failed");
MFnTransform rigParentConstraintFn( this->m_rigParentConstraint);
rigParentConstraintFn.addAttribute(mAttr.create("metaParent", "metaParent"));
status = dgMod.connect( depMetaDataNodeFn.findPlug("rigParentConstraint"), rigParentConstraintFn.findPlug("metaParent"));
//create the scale constraint from the global controller to the rig group
MGlobal::executeCommand("scaleConstraint -mo "+transformFn.name()+" "+rigRigGroupFn.name()+";", res);
//connect the scale constraint object to the component's metadata node
res.getResult(sResults);
status = lrutils::getObjFromName(sResults[0], this->m_rigScaleConstraint);
MyCheckStatus(status, "lrutils::getObjFromName() failed");
MFnTransform rigScaleConstraintFn( this->m_rigScaleConstraint );
rigScaleConstraintFn.addAttribute(mAttr.create("metaParent", "metaParent"));
status = dgMod.connect( depMetaDataNodeFn.findPlug("rigScaleConstraint"), rigScaleConstraintFn.findPlug("metaParent"));
//create scale constraint from the global controller to the noTransform group
MObject rigNoTransformGroupObj;
status = lrutils::getMetaNodeConnection(metaRootObj, rigNoTransformGroupObj, "noTransformGroup");
MFnTransform rigNoTransformGroupFn( rigNoTransformGroupObj );
MGlobal::executeCommand("scaleConstraint -mo "+transformFn.name()+" "+rigNoTransformGroupFn.name()+";", res);
//connect the scale constraint object to the component's metadata node
res.getResult(sResults);
status = lrutils::getObjFromName(sResults[0], this->m_noTransformScaleConstraint);
MyCheckStatus(status, "lrutils::getObjFromName() failed");
MFnTransform noTransformScaleConstraintFn( this->m_noTransformScaleConstraint);
noTransformScaleConstraintFn.addAttribute(mAttr.create("metaParent", "metaParent"));
status = dgMod.connect( depMetaDataNodeFn.findPlug("noTransformScaleConstraint"), noTransformScaleConstraintFn.findPlug("metaParent"));
}
return this->m_metaDataNode;
}
void EntityNode::AddImportNode( const MObject& object )
{
MStatus stat;
MObjectHandle handle( object );
if( !handle.isValid() )
{
return;
}
MFnDependencyNode nodeFn( object, &stat );
MCheckNoErr( stat, "Unable to create depenency node fn set" );
nodeFn.setDoNotWrite( true );
//MItDependencyGraph childrenIt (MItDependencyGraph::kUpstream);
//for ( childrenIt.reset( nodeFn.object() ); !childrenIt.isDone(); childrenIt.next() )
//{
// MFnDependencyNode( childrenIt.item() ).setDoNotWrite( true );
//}
MString name = nodeFn.name( &stat );
MCheckNoErr( stat, "Unable to get node name" );
if( name == "" )
{
return;
}
// don't connect dag nodes to the ImportNodes attributeb array
if( object.hasFn( MFn::kDagNode ) )
{
return;
}
#ifdef _DEBUG
std::cout << "Adding: " << name.asTChar() << std::endl;
#endif
//create ImportMessage attrib on the imported object if necessary
if( !nodeFn.hasAttribute( "ImportMessage", &stat ) )
{
MFnMessageAttribute mAttr;
MObject importMessage = mAttr.create( "ImportMessage", "imp", &stat );
MCheckNoErr(stat, "Unable to create attr: ImportMessage");
stat = nodeFn.addAttribute( importMessage );
MCheckNoErr(stat, "Unable to add attr: ImportNodes");
}
MPlug importMsg = nodeFn.findPlug( "ImportMessage", &stat );
MCheckNoErr(stat, "Unable to find attr: ImportMessage");
MPlug importPlug( thisMObject(), m_ImportNodes );
u32 currentIdx = importPlug.numConnectedElements();
MPlug importElement = importPlug.elementByLogicalIndex( currentIdx );
MDGModifier mod;
//if it's currently connected, disconnect it
if( importMsg.isConnected() )
{
MPlugArray plugs;
importMsg.connectedTo( plugs, true, false );
if( plugs.length() == 1 )
{
mod.disconnect( importMsg, plugs[0] );
}
}
stat = mod.connect( importMsg, importElement );
mod.doIt();
}
MStatus inSpecular::initialize()
{
MFnNumericAttribute nAttr;
MFnLightDataAttribute lAttr;
MFnTypedAttribute tAttr;
MFnGenericAttribute gAttr;
MFnEnumAttribute eAttr;
MFnMessageAttribute mAttr;
MStatus status; // Status will be used to hold the MStatus value
// returned by each api function call. It is important
// to check the status returned by a call to aid in
// debugging. Failed API calls can result in subtle
// errors that can be difficult to track down, you may
// wish to use the CHECK_MSTATUS macro for any API
// call where you do not need to provide your own
// error handling.
//
//---------------------------- automatically created attributes start ------------------------------------
backface_emit = nAttr.create("backface_emit", "backface_emit", MFnNumericData::kBoolean, false);
CHECK_MSTATUS(addAttribute( backface_emit ));
layer = nAttr.create("layer", "layer", MFnNumericData::kInt, 0);
CHECK_MSTATUS(addAttribute( layer ));
iesProfile = tAttr.create("iesProfile", "iesProfile", MFnNumericData::kString);
CHECK_MSTATUS(addAttribute( iesProfile ));
internal_medium_name = mAttr.create("internal_medium_name", "internal_medium_name");
CHECK_MSTATUS(addAttribute( internal_medium_name ));
bump = nAttr.create("bump", "bump", MFnNumericData::kFloat, 0.0);
CHECK_MSTATUS(addAttribute( bump ));
base_emission = nAttr.createColor("base_emission", "base_emission");
nAttr.setDefault(0.0,0.0,0.0);
CHECK_MSTATUS(addAttribute( base_emission ));
displacement = nAttr.create("displacement", "displacement", MFnNumericData::kFloat, 0.0);
CHECK_MSTATUS(addAttribute( displacement ));
emission = nAttr.createColor("emission", "emission");
nAttr.setDefault(0.0,0.0,0.0);
CHECK_MSTATUS(addAttribute( emission ));
normalMap = nAttr.createColor("normalMap", "normalMap");
nAttr.setDefault(0,0,0);
CHECK_MSTATUS(addAttribute( normalMap ));
transparent = nAttr.create("transparent", "transparent", MFnNumericData::kBoolean, false);
CHECK_MSTATUS(addAttribute( transparent ));
//---------------------------- automatically created attributes end ------------------------------------
// Input Attributes
//
aTranslucenceCoeff = nAttr.create( "translucenceCoeff", "tc",
MFnNumericData::kFloat, 0, &status );
CHECK_MSTATUS( status );
CHECK_MSTATUS( nAttr.setKeyable( true ) );
CHECK_MSTATUS( nAttr.setStorable( true ) );
CHECK_MSTATUS( nAttr.setDefault( 0.0f ) );
aDiffuseReflectivity = nAttr.create( "diffuseReflectivity", "drfl",
MFnNumericData::kFloat, 0, &status );
CHECK_MSTATUS( status );
CHECK_MSTATUS( nAttr.setKeyable( true ) );
CHECK_MSTATUS( nAttr.setStorable( true ) );
CHECK_MSTATUS( nAttr.setDefault( 0.8f ) );
aColor = nAttr.createColor( "color", "c", &status );
CHECK_MSTATUS( status );
CHECK_MSTATUS( nAttr.setKeyable( true ) );
CHECK_MSTATUS( nAttr.setStorable( true ) );
CHECK_MSTATUS( nAttr.setDefault( 0.0f, 0.58824f, 0.644f ) );
aIncandescence = nAttr.createColor( "incandescence", "ic", &status );
CHECK_MSTATUS( status );
CHECK_MSTATUS( nAttr.setKeyable( true ) );
CHECK_MSTATUS( nAttr.setStorable( true ) );
CHECK_MSTATUS( nAttr.setDefault( 0.0f, 0.0f, 0.0f ) );
aInTransparency = nAttr.createColor( "transparency", "it", &status );
CHECK_MSTATUS( status );
CHECK_MSTATUS( nAttr.setKeyable( true ) );
CHECK_MSTATUS( nAttr.setStorable( true ) );
CHECK_MSTATUS( nAttr.setDefault( 0.0f, 0.0f, 0.0f ) );
// Color Output
//
aOutColor = nAttr.createColor( "outColor", "oc", &status );
CHECK_MSTATUS( status );
CHECK_MSTATUS( nAttr.setHidden( false ) );
CHECK_MSTATUS( nAttr.setReadable( true ) );
CHECK_MSTATUS( nAttr.setWritable( false ) );
aOutTransparency = nAttr.createColor( "outTransparency", "ot", &status );
CHECK_MSTATUS( status );
CHECK_MSTATUS( nAttr.setHidden( false ) );
CHECK_MSTATUS( nAttr.setReadable( true ) );
CHECK_MSTATUS( nAttr.setWritable( false ) );
// Camera Normals
//
aNormalCameraX = nAttr.create( "normalCameraX", "nx",
MFnNumericData::kFloat, 0, &status );
CHECK_MSTATUS( status );
CHECK_MSTATUS( nAttr.setStorable( false ) );
CHECK_MSTATUS( nAttr.setDefault( 1.0f ) );
aNormalCameraY = nAttr.create( "normalCameraY", "ny",
MFnNumericData::kFloat, 0, &status );
CHECK_MSTATUS( status );
CHECK_MSTATUS( nAttr.setStorable( false ) );
CHECK_MSTATUS( nAttr.setDefault( 1.0f ) );
aNormalCameraZ = nAttr.create( "normalCameraZ", "nz",
MFnNumericData::kFloat, 0, &status );
CHECK_MSTATUS( status );
CHECK_MSTATUS( nAttr.setStorable( false ) );
CHECK_MSTATUS( nAttr.setDefault( 1.0f ) );
aNormalCamera = nAttr.create( "normalCamera","n", aNormalCameraX,
aNormalCameraY, aNormalCameraZ, &status );
CHECK_MSTATUS( status );
CHECK_MSTATUS( nAttr.setStorable( false ) );
CHECK_MSTATUS( nAttr.setDefault( 1.0f, 1.0f, 1.0f ) );
CHECK_MSTATUS( nAttr.setHidden( true ) );
// Light Direction
//
aLightDirectionX = nAttr.create( "lightDirectionX", "ldx",
MFnNumericData::kFloat, 0, &status );
CHECK_MSTATUS( status );
CHECK_MSTATUS ( nAttr.setStorable(false) );
CHECK_MSTATUS ( nAttr.setHidden(true) );
CHECK_MSTATUS ( nAttr.setReadable(true) );
CHECK_MSTATUS ( nAttr.setWritable(false) );
CHECK_MSTATUS( nAttr.setDefault( 1.0f ) );
aLightDirectionY = nAttr.create( "lightDirectionY", "ldy",
MFnNumericData::kFloat, 0, &status );
CHECK_MSTATUS( status );
CHECK_MSTATUS ( nAttr.setStorable(false) );
CHECK_MSTATUS ( nAttr.setHidden(true) );
CHECK_MSTATUS ( nAttr.setReadable(true) );
CHECK_MSTATUS ( nAttr.setWritable(false) );
CHECK_MSTATUS( nAttr.setDefault( 1.0f ) );
aLightDirectionZ = nAttr.create( "lightDirectionZ", "ldz",
MFnNumericData::kFloat, 0, &status );
CHECK_MSTATUS( status );
CHECK_MSTATUS ( nAttr.setStorable(false) );
CHECK_MSTATUS ( nAttr.setHidden(true) );
CHECK_MSTATUS ( nAttr.setReadable(true) );
CHECK_MSTATUS ( nAttr.setWritable(false) );
CHECK_MSTATUS( nAttr.setDefault( 1.0f ) );
aLightDirection = nAttr.create( "lightDirection", "ld",
aLightDirectionX, aLightDirectionY, aLightDirectionZ,
&status );
CHECK_MSTATUS( status );
CHECK_MSTATUS ( nAttr.setStorable(false) );
CHECK_MSTATUS ( nAttr.setHidden(true) );
CHECK_MSTATUS ( nAttr.setReadable(true) );
CHECK_MSTATUS ( nAttr.setWritable(false) );
CHECK_MSTATUS( nAttr.setDefault( 1.0f, 1.0f, 1.0f ) );
// Light Intensity
//
aLightIntensityR = nAttr.create( "lightIntensityR", "lir",
MFnNumericData::kFloat, 0, &status );
CHECK_MSTATUS( status );
CHECK_MSTATUS ( nAttr.setStorable(false) );
CHECK_MSTATUS ( nAttr.setHidden(true) );
CHECK_MSTATUS ( nAttr.setReadable(true) );
CHECK_MSTATUS ( nAttr.setWritable(false) );
CHECK_MSTATUS( nAttr.setDefault( 1.0f ) );
aLightIntensityG = nAttr.create( "lightIntensityG", "lig",
MFnNumericData::kFloat, 0, &status );
CHECK_MSTATUS( status );
CHECK_MSTATUS ( nAttr.setStorable(false) );
CHECK_MSTATUS ( nAttr.setHidden(true) );
CHECK_MSTATUS ( nAttr.setReadable(true) );
CHECK_MSTATUS ( nAttr.setWritable(false) );
CHECK_MSTATUS( nAttr.setDefault( 1.0f ) );
aLightIntensityB = nAttr.create( "lightIntensityB", "lib",
MFnNumericData::kFloat, 0, &status );
CHECK_MSTATUS( status );
CHECK_MSTATUS ( nAttr.setStorable(false) );
CHECK_MSTATUS ( nAttr.setHidden(true) );
CHECK_MSTATUS ( nAttr.setReadable(true) );
CHECK_MSTATUS ( nAttr.setWritable(false) );
CHECK_MSTATUS( nAttr.setDefault( 1.0f ) );
aLightIntensity = nAttr.create( "lightIntensity", "li",
aLightIntensityR, aLightIntensityG, aLightIntensityB,
&status );
CHECK_MSTATUS( status );
CHECK_MSTATUS ( nAttr.setStorable(false) );
CHECK_MSTATUS ( nAttr.setHidden(true) );
CHECK_MSTATUS ( nAttr.setReadable(true) );
CHECK_MSTATUS ( nAttr.setWritable(false) );
CHECK_MSTATUS( nAttr.setDefault( 1.0f, 1.0f, 1.0f ) );
// Light
//
aLightAmbient = nAttr.create( "lightAmbient", "la",
MFnNumericData::kBoolean, 0, &status );
CHECK_MSTATUS( status );
CHECK_MSTATUS ( nAttr.setStorable(false) );
CHECK_MSTATUS ( nAttr.setHidden(true) );
CHECK_MSTATUS ( nAttr.setReadable(true) );
CHECK_MSTATUS ( nAttr.setWritable(false) );
CHECK_MSTATUS( nAttr.setDefault( true ) );
aLightDiffuse = nAttr.create( "lightDiffuse", "ldf",
MFnNumericData::kBoolean, 0, &status );
CHECK_MSTATUS( status );
CHECK_MSTATUS ( nAttr.setStorable(false) );
CHECK_MSTATUS ( nAttr.setHidden(true) );
CHECK_MSTATUS ( nAttr.setReadable(true) );
CHECK_MSTATUS ( nAttr.setWritable(false) );
CHECK_MSTATUS( nAttr.setDefault( true ) );
aLightSpecular = nAttr.create( "lightSpecular", "ls",
MFnNumericData::kBoolean, 0, &status );
CHECK_MSTATUS( status );
CHECK_MSTATUS ( nAttr.setStorable(false) );
CHECK_MSTATUS ( nAttr.setHidden(true) );
CHECK_MSTATUS ( nAttr.setReadable(true) );
CHECK_MSTATUS ( nAttr.setWritable(false) );
CHECK_MSTATUS( nAttr.setDefault( false ) );
aLightShadowFraction = nAttr.create( "lightShadowFraction", "lsf",
MFnNumericData::kFloat, 0, &status );
CHECK_MSTATUS( status );
CHECK_MSTATUS ( nAttr.setStorable(false) );
CHECK_MSTATUS ( nAttr.setHidden(true) );
CHECK_MSTATUS ( nAttr.setReadable(true) );
CHECK_MSTATUS ( nAttr.setWritable(false) );
CHECK_MSTATUS( nAttr.setDefault( 1.0f ) );
aPreShadowIntensity = nAttr.create( "preShadowIntensity", "psi",
MFnNumericData::kFloat, 0, &status );
CHECK_MSTATUS( status );
CHECK_MSTATUS ( nAttr.setStorable(false) );
CHECK_MSTATUS ( nAttr.setHidden(true) );
CHECK_MSTATUS ( nAttr.setReadable(true) );
CHECK_MSTATUS ( nAttr.setWritable(false) );
CHECK_MSTATUS( nAttr.setDefault( 1.0f ) );
aLightBlindData = nAttr.createAddr( "lightBlindData", "lbld",
&status );
CHECK_MSTATUS( status );
CHECK_MSTATUS ( nAttr.setStorable(false) );
CHECK_MSTATUS ( nAttr.setHidden(true) );
CHECK_MSTATUS ( nAttr.setReadable(true) );
CHECK_MSTATUS ( nAttr.setWritable(false) );
aLightData = lAttr.create( "lightDataArray", "ltd", aLightDirection,
aLightIntensity, aLightAmbient, aLightDiffuse, aLightSpecular,
aLightShadowFraction, aPreShadowIntensity, aLightBlindData,
&status );
CHECK_MSTATUS( status );
CHECK_MSTATUS( lAttr.setArray( true ) );
CHECK_MSTATUS( lAttr.setStorable( false ) );
CHECK_MSTATUS( lAttr.setHidden( true ) );
CHECK_MSTATUS( lAttr.setDefault( 0.0f, 0.0f, 0.0f, 0.0f, 0.0f, 0.0f,
true, true, false, 1.0f, 1.0f, NULL ) );
// Next we will add the attributes we have defined to the node
//
CHECK_MSTATUS( addAttribute( aTranslucenceCoeff ) );
CHECK_MSTATUS( addAttribute( aDiffuseReflectivity ) );
CHECK_MSTATUS( addAttribute( aColor ) );
CHECK_MSTATUS( addAttribute( aIncandescence ) );
CHECK_MSTATUS( addAttribute( aInTransparency ) );
CHECK_MSTATUS( addAttribute( aOutColor ) );
CHECK_MSTATUS( addAttribute( aOutTransparency ) );
CHECK_MSTATUS( addAttribute( aNormalCamera ) );
// Only add the parent of the compound
CHECK_MSTATUS( addAttribute( aLightData ) );
// The attributeAffects() method is used to indicate when the input
// attribute affects the output attribute. This knowledge allows Maya
// to optimize dependencies in the graph in more complex nodes where
// there may be several inputs and outputs, but not all the inputs
// affect all the outputs.
//
CHECK_MSTATUS( attributeAffects( aTranslucenceCoeff, aOutColor ) );
CHECK_MSTATUS( attributeAffects( aDiffuseReflectivity, aOutColor ) );
CHECK_MSTATUS( attributeAffects( aColor, aOutColor ) );
CHECK_MSTATUS( attributeAffects( aInTransparency, aOutTransparency ) );
CHECK_MSTATUS( attributeAffects( aInTransparency, aOutColor ) );
CHECK_MSTATUS( attributeAffects( aIncandescence, aOutColor ) );
CHECK_MSTATUS( attributeAffects( aLightIntensityR, aOutColor ) );
CHECK_MSTATUS( attributeAffects( aLightIntensityB, aOutColor ) );
CHECK_MSTATUS( attributeAffects( aLightIntensityG, aOutColor ) );
CHECK_MSTATUS( attributeAffects( aLightIntensity, aOutColor ) );
CHECK_MSTATUS( attributeAffects( aNormalCameraX, aOutColor ) );
CHECK_MSTATUS( attributeAffects( aNormalCameraY, aOutColor ) );
CHECK_MSTATUS( attributeAffects( aNormalCameraZ, aOutColor ) );
CHECK_MSTATUS( attributeAffects( aNormalCamera, aOutColor ) );
CHECK_MSTATUS( attributeAffects( aLightDirectionX, aOutColor ) );
CHECK_MSTATUS( attributeAffects( aLightDirectionY, aOutColor ) );
CHECK_MSTATUS( attributeAffects( aLightDirectionZ, aOutColor ) );
CHECK_MSTATUS( attributeAffects( aLightDirection, aOutColor ) );
CHECK_MSTATUS( attributeAffects( aLightAmbient, aOutColor ) );
CHECK_MSTATUS( attributeAffects( aLightSpecular, aOutColor ) );
CHECK_MSTATUS( attributeAffects( aLightDiffuse, aOutColor ) );
CHECK_MSTATUS( attributeAffects( aLightShadowFraction, aOutColor ) );
CHECK_MSTATUS( attributeAffects( aPreShadowIntensity, aOutColor ) );
CHECK_MSTATUS( attributeAffects( aLightBlindData, aOutColor ) );
CHECK_MSTATUS( attributeAffects( aLightData, aOutColor ) );
return( MS::kSuccess );
}
