MStatus sgBulgeDeformer::initialize() { MStatus status; MFnNumericAttribute nAttr; MFnTypedAttribute tAttr; MFnMatrixAttribute mAttr; MFnCompoundAttribute cAttr; aBulgeWeight = nAttr.create(nameBulgeWeight, nameBulgeWeight, MFnNumericData::kFloat, 1.0); nAttr.setStorable(false); nAttr.setKeyable(true); addAttribute(aBulgeWeight); aBulgeRadius = nAttr.create(nameBulgeRadius, nameBulgeRadius, MFnNumericData::kDouble, 0); nAttr.setMin(0); nAttr.setStorable(false); nAttr.setKeyable(true); addAttribute(aBulgeRadius); aBulgeInputs = cAttr.create(nameBulgeInputs, nameBulgeInputs); aMatrix = mAttr.create(nameMatrix, nameMatrix); aMesh = tAttr.create(nameMesh, nameMesh, MFnData::kMesh ); cAttr.addChild(aMatrix); cAttr.addChild(aMesh); cAttr.setArray(true); addAttribute(aBulgeInputs); attributeAffects(aBulgeWeight, outputGeom); attributeAffects(aBulgeRadius, outputGeom); attributeAffects(aBulgeInputs, outputGeom); return status; }
MStatus blendCurve::initialize() { MStatus status; MFnNumericAttribute nAttr; MFnTypedAttribute tAttr; MFnCompoundAttribute cAttr; aInputs = cAttr.create( "inputs", "inputs" ); aInputCurve = tAttr.create( "inputCurve", "inputCurve", MFnData::kNurbsCurve ); tAttr.setStorable( false ); aWeight = nAttr.create( "weight", "weight", MFnNumericData::kFloat, 1.0 ); nAttr.setMin( 0.0 ); nAttr.setMax( 1.0 ); nAttr.setKeyable( true ); aBlendPosition = nAttr.create( "blendPosition", "blendPosition", MFnNumericData::kFloat, 1.0 ); nAttr.setMin( 0.0 ); nAttr.setMax( 1.0 ); nAttr.setKeyable( true ); aBlendArea = nAttr.create( "blendArea", "blendArea", MFnNumericData::kFloat, 0.5 ); nAttr.setMin( 0.0 ); nAttr.setMax( 1.0 ); nAttr.setKeyable( true ); cAttr.addChild( aInputCurve ); cAttr.addChild( aWeight ); cAttr.addChild( aBlendPosition ); cAttr.addChild( aBlendArea ); cAttr.setArray( true ); CHECK_MSTATUS_AND_RETURN_IT( addAttribute( aInputs ) ); CHECK_MSTATUS_AND_RETURN_IT( attributeAffects( aInputs, outputGeom ) ); return MS::kSuccess; }
MPlug TransformationMatrixParameterHandler<T>::doCreate( IECore::ConstParameterPtr parameter, const MString &plugName, MObject &node ) const { typename IECore::TypedParameter<IECore::TransformationMatrix<T> >::ConstPtr p = IECore::runTimeCast<const IECore::TypedParameter<IECore::TransformationMatrix<T> > >( parameter ); if( !p ) { return MPlug(); } MFnCompoundAttribute fnCAttr; MObject attribute = fnCAttr.create( plugName, plugName ); MFnNumericAttribute fnNAttr; MFnUnitAttribute fnUAttr; // As TransformationMatrix embodies a fairly comprehensive rotation model, were going to be a little // more basic here, and just supply a V3f rotation and pretend that the Quartonean isn't there. ///\todo Expose rotation order and rotationOrientation. // These use the '0', '1' and '2' child suffixes instead of 'X' 'Y' and 'Z' to match those created by fnNAttr.create() @ L188. MObject p1 = fnUAttr.create( plugName + g_attributeNames[ TRANSLATE_INDEX ] + "0", plugName + g_attributeNames[ TRANSLATE_INDEX ] + "0", MFnUnitAttribute::kDistance ); MObject p2 = fnUAttr.create( plugName + g_attributeNames[ TRANSLATE_INDEX ] + "1", plugName + g_attributeNames[ TRANSLATE_INDEX ] + "1", MFnUnitAttribute::kDistance ); MObject p3 = fnUAttr.create( plugName + g_attributeNames[ TRANSLATE_INDEX ] + "2", plugName + g_attributeNames[ TRANSLATE_INDEX ] + "2", MFnUnitAttribute::kDistance ); fnCAttr.addChild( fnNAttr.create( plugName + g_attributeNames[ TRANSLATE_INDEX ], plugName + g_attributeNames[ TRANSLATE_INDEX ], p1, p2, p3 ) ); p1 = fnUAttr.create( plugName + g_attributeNames[ ROTATE_INDEX ] + "0", plugName + g_attributeNames[ ROTATE_INDEX ] + "0", MFnUnitAttribute::kAngle ); p2 = fnUAttr.create( plugName + g_attributeNames[ ROTATE_INDEX ] + "1", plugName + g_attributeNames[ ROTATE_INDEX ] + "1", MFnUnitAttribute::kAngle ); p3 = fnUAttr.create( plugName + g_attributeNames[ ROTATE_INDEX ] + "2", plugName + g_attributeNames[ ROTATE_INDEX ] + "2", MFnUnitAttribute::kAngle ); fnCAttr.addChild( fnNAttr.create( plugName + g_attributeNames[ ROTATE_INDEX ], plugName + g_attributeNames[ ROTATE_INDEX ], p1, p2, p3 ) ); for( unsigned int i=2; i<8; i++ ) { fnCAttr.addChild( fnNAttr.create( plugName + g_attributeNames[i], plugName + g_attributeNames[i], NumericTraits<Imath::Vec3<T> >::dataType() ) ); } MPlug result = finishCreating( parameter, attribute, node ); if( !doUpdate( parameter, result ) ) { return MPlug(); // failure } if( !finishUpdating( parameter, result ) ) { return MPlug(); // failure } return result; }
MStatus weightList::initialize() { MStatus status; MFnNumericAttribute numAtt; aBias = numAtt.create( "bias", "b", MFnNumericData::kFloat); addAttribute(aBias); aWeights = numAtt.create("weights", "w", MFnNumericData::kFloat, -1000.0, &status); numAtt.setKeyable(true); numAtt.setArray(true); numAtt.setReadable(true); numAtt.setUsesArrayDataBuilder(true); // setIndexMatters() will only affect array attributes with setReadable set to false, // i.e. destination attributes. We have set the default value to an unlikely value // to guarantee an entry is created regardless of its value. // numAtt.setIndexMatters(true); addAttribute(aWeights); MFnCompoundAttribute cmpAttr; aWeightsList = cmpAttr.create("weightsList", "wl", &status); cmpAttr.setArray(true); cmpAttr.addChild(aWeights); cmpAttr.setReadable(true); cmpAttr.setUsesArrayDataBuilder(true); // cmpAttr.setIndexMatters(true); addAttribute(aWeightsList); attributeAffects(aBias, aWeightsList); return MStatus::kSuccess; }
void MFnCompoundAttrAddBool( MFnCompoundAttribute &attr, const char* full, const char* brief, bool def ) { MStatus status; MFnNumericAttribute boolAttr; MObject boolObj = boolAttr.create( full, brief, MFnNumericData::kBoolean, (def? 1.0 : 0.0), &status ); attr.addChild( boolObj ); }
MStatus clusterControledCurve::initialize() { MStatus status; MFnNumericAttribute nAttr; MFnMatrixAttribute mAttr; MFnTypedAttribute tAttr; MFnCompoundAttribute cAttr; aInputCurve = tAttr.create( "inputCurve", "inputCurve", MFnData::kNurbsCurve ); tAttr.setStorable( true ); CHECK_MSTATUS( addAttribute( aInputCurve ) ); aInputCurveMatrix = mAttr.create( "inputCurveMatrix", "inputCurveMatrix" ); mAttr.setStorable( true ); CHECK_MSTATUS( addAttribute( aInputCurveMatrix ) ); aDumyMatrix = mAttr.create( "dumyMatrix", "dumyMatrix" ); mAttr.setStorable( true ); CHECK_MSTATUS( addAttribute( aDumyMatrix ) ); aBindPreMatrix = mAttr.create( "bindPreMatrix", "bindPreMatrix" ); mAttr.setStorable( true ); mAttr.setArray( true ); nAttr.setUsesArrayDataBuilder( true ); CHECK_MSTATUS( addAttribute( aBindPreMatrix ) ); aMatrix = mAttr.create( "matrix", "matrix" ); mAttr.setStorable( true ); mAttr.setArray( true ); CHECK_MSTATUS( addAttribute( aMatrix ) ); aWeightList = cAttr.create( "weightList", "weightList" ); aWeights = nAttr.create( "weights", "weights", MFnNumericData::kFloat, 0.0 ); nAttr.setArray( true ); nAttr.setUsesArrayDataBuilder( true ); cAttr.addChild( aWeights ); cAttr.setArray( true ); cAttr.setStorable( true ); CHECK_MSTATUS( addAttribute( aWeightList ) ); aUpdate = nAttr.create( "update", "update", MFnNumericData::kBoolean, false ); nAttr.setStorable( true ); CHECK_MSTATUS( addAttribute( aUpdate ) ); aOutputCurve = tAttr.create( "outputCurve", "outputCurve", MFnData::kNurbsCurve ); CHECK_MSTATUS( addAttribute( aOutputCurve ) ); CHECK_MSTATUS( attributeAffects( aInputCurve, aOutputCurve ) ); CHECK_MSTATUS( attributeAffects( aInputCurveMatrix, aOutputCurve ) ); CHECK_MSTATUS( attributeAffects( aDumyMatrix, aOutputCurve ) ); CHECK_MSTATUS( attributeAffects( aBindPreMatrix, aOutputCurve ) ); CHECK_MSTATUS( attributeAffects( aMatrix, aOutputCurve ) ); CHECK_MSTATUS( attributeAffects( aWeightList, aOutputCurve ) ); CHECK_MSTATUS( attributeAffects( aUpdate, aOutputCurve ) ); return MS::kSuccess; }
void MFnCompoundAttrAddEnum( MFnCompoundAttribute &attr, const char* full, const char* brief, const char** pEnumStrings, unsigned short count, unsigned short def ) { MStatus status; MFnEnumAttribute enumAttr; MObject enumObj = enumAttr.create( full, brief, def, &status ); for(short index = 0; index < count; ++index) enumAttr.addField( pEnumStrings[index], index ); attr.addChild( enumObj ); }
void MFnCompoundAttrAddString( MFnCompoundAttribute &attr, const char* full, const char* brief, const char* def ) { MStatus status; MFnTypedAttribute stringAttribute; MObject strinAttrObj = stringAttribute.create( full, brief, MFnData::kString, &status ); // Default strings don't get saved, so setting values for defaults in AddRenderContextAttribute //if( def != 0 ) //{ // MFnStringData defaultString; // MObject defaultStringObj = defaultString.create(def); // stringAttribute.setDefault(defaultStringObj); //} attr.addChild( strinAttrObj ); }
MPlug BoxParameterHandler<T>::doCreate( IECore::ConstParameterPtr parameter, const MString &plugName, MObject &node ) const { typename IECore::TypedParameter<Box<T> >::ConstPtr p = IECore::runTimeCast<const IECore::TypedParameter<Box<T > > >( parameter ); if( !p ) { return MPlug(); } MFnNumericAttribute fnNAttr; MFnCompoundAttribute fnCAttr; MObject oMin, oMax; switch( T::dimensions() ) { case 2 : { MObject oMinX = fnNAttr.create( plugName + "MinX", plugName + "MinX", NumericTraits<T>::baseDataType() ); MObject oMinY = fnNAttr.create( plugName + "MinY", plugName + "MinY", NumericTraits<T>::baseDataType() ); oMin = fnNAttr.create( plugName + "Min", plugName + "Min", oMinX, oMinY ); MObject oMaxX = fnNAttr.create( plugName + "MaxX", plugName + "MaxX", NumericTraits<T>::baseDataType() ); MObject oMaxY = fnNAttr.create( plugName + "MaxY", plugName + "MaxY", NumericTraits<T>::baseDataType() ); oMax = fnNAttr.create( plugName + "Max", plugName + "Max", oMaxX, oMaxY ); } break; case 3 : oMin = fnNAttr.createPoint( plugName + "Min", plugName + "Min" ); oMax = fnNAttr.createPoint( plugName + "Max", plugName + "Max" ); break; default : return MPlug(); } MObject attribute = fnCAttr.create( plugName, plugName ); fnCAttr.addChild( oMin ); fnCAttr.addChild( oMax ); MPlug result = finishCreating( parameter, attribute, node ); doUpdate( parameter, result ); return result; }
MStatus geometrySurfaceConstraint::initialize() { MFnNumericAttribute nAttr; MStatus status; // constraint attributes { // Geometry: mesh, readable, not writable, delete on disconnect MFnTypedAttribute typedAttrNotWritable; geometrySurfaceConstraint::constraintGeometry = typedAttrNotWritable.create( "constraintGeometry", "cg", MFnData::kMesh, &status ); if (!status) { status.perror("typedAttrNotWritable.create:cgeom"); return status;} status = typedAttrNotWritable.setReadable(true); if (!status) { status.perror("typedAttrNotWritable.setReadable:cgeom"); return status;} status = typedAttrNotWritable.setWritable(false); if (!status) { status.perror("typedAttrNotWritable.setWritable:cgeom"); return status;} status = typedAttrNotWritable.setDisconnectBehavior(MFnAttribute::kDelete); if (!status) { status.perror("typedAttrNotWritable.setDisconnectBehavior:cgeom"); return status;} } // Parent inverse matrix: delete on disconnect MFnTypedAttribute typedAttr; geometrySurfaceConstraint::constraintParentInverseMatrix = typedAttr.create( "constraintPim", "ci", MFnData::kMatrix, &status ); if (!status) { status.perror("typedAttr.create:matrix"); return status;} status = typedAttr.setDisconnectBehavior(MFnAttribute::kDelete); if (!status) { status.perror("typedAttr.setDisconnectBehavior:cgeom"); return status;} // Target geometry: mesh, delete on disconnect geometrySurfaceConstraint::targetGeometry = typedAttr.create( "targetGeometry", "tg", MFnData::kMesh, &status ); if (!status) { status.perror("typedAttr.create:tgeom"); return status;} status = typedAttr.setDisconnectBehavior(MFnAttribute::kDelete); if (!status) { status.perror("typedAttr.setDisconnectBehavior:cgeom"); return status;} targetTransform = typedAttr.create( "targetTransform", "ttm", MFnData::kMatrix, &status ); if (!status) { status.perror("typedAttr.create:targetTransform"); return status;} status = typedAttr.setDisconnectBehavior(MFnAttribute::kDelete); if (!status) { status.perror("typedAttr.setDisconnectBehavior:targetTransform"); return status;} // Target weight: double, min 0, default 1.0, keyable, delete on disconnect MFnNumericAttribute typedAttrKeyable; geometrySurfaceConstraint::targetWeight = typedAttrKeyable.create( "weight", "wt", MFnNumericData::kDouble, 1.0, &status ); if (!status) { status.perror("typedAttrKeyable.create:weight"); return status;} status = typedAttrKeyable.setMin( (double) 0 ); if (!status) { status.perror("typedAttrKeyable.setMin"); return status;} status = typedAttrKeyable.setKeyable( true ); if (!status) { status.perror("typedAttrKeyable.setKeyable"); return status;} status = typedAttrKeyable.setDisconnectBehavior(MFnAttribute::kDelete); if (!status) { status.perror("typedAttrKeyable.setDisconnectBehavior:cgeom"); return status;} { // Compound target(geometry,weight): array, delete on disconnect MFnCompoundAttribute compoundAttr; geometrySurfaceConstraint::compoundTarget = compoundAttr.create( "target", "tgt",&status ); if (!status) { status.perror("compoundAttr.create"); return status;} status = compoundAttr.addChild( geometrySurfaceConstraint::targetTransform ); if (!status) { status.perror("compoundAttr.addChild targetTransform"); return status;} status = compoundAttr.addChild( geometrySurfaceConstraint::targetGeometry ); if (!status) { status.perror("compoundAttr.addChild"); return status;} status = compoundAttr.addChild( geometrySurfaceConstraint::targetWeight ); if (!status) { status.perror("compoundAttr.addChild"); return status;} status = compoundAttr.setArray( true ); if (!status) { status.perror("compoundAttr.setArray"); return status;} status = compoundAttr.setDisconnectBehavior(MFnAttribute::kDelete); if (!status) { status.perror("typedAttrKeyable.setDisconnectBehavior:cgeom"); return status;} } MFnNumericAttribute numAttr; constraintTranslateX = numAttr.create( "constraintTranslateX", "ctx", MFnNumericData::kDouble, 0.0, &status ); if(!status) { MGlobal::displayInfo("failed to create attrib constraintTranslateX"); return status; } numAttr.setReadable(true); numAttr.setWritable(false); addAttribute(constraintTranslateX); constraintTranslateY = numAttr.create( "constraintTranslateY", "cty", MFnNumericData::kDouble, 0.0, &status ); if(!status) { MGlobal::displayInfo("failed to create attrib constraintTranslateY"); return status; } numAttr.setReadable(true); numAttr.setWritable(false); addAttribute(constraintTranslateY); constraintTranslateZ = numAttr.create( "constraintTranslateZ", "ctz", MFnNumericData::kDouble, 0.0, &status ); if(!status) { MGlobal::displayInfo("failed to create attrib constraintTranslateY"); return status; } numAttr.setReadable(true); numAttr.setWritable(false); addAttribute(constraintTranslateZ); constraintTargetX = numAttr.create( "constraintTargetX", "ttx", MFnNumericData::kDouble, 0.0, &status ); if(!status) { MGlobal::displayInfo("failed to create attrib constraintTargetX"); return status; } addAttribute(constraintTargetX); constraintTargetY = numAttr.create( "constraintTargetY", "tty", MFnNumericData::kDouble, 0.0, &status ); if(!status) { MGlobal::displayInfo("failed to create attrib constraintTargetY"); return status; } addAttribute(constraintTargetY); constraintTargetZ = numAttr.create( "constraintTargetZ", "ttz", MFnNumericData::kDouble, 0.0, &status ); if(!status) { MGlobal::displayInfo("failed to create attrib constraintTargetZ"); return status; } addAttribute(constraintTargetZ); constraintObjectX = numAttr.create( "constraintObjectX", "otx", MFnNumericData::kDouble, 0.0, &status ); if(!status) { MGlobal::displayInfo("failed to create attrib constraintObjectX"); return status; } addAttribute(constraintObjectX); constraintObjectY = numAttr.create( "constraintObjectY", "oty", MFnNumericData::kDouble, 0.0, &status ); if(!status) { MGlobal::displayInfo("failed to create attrib constraintObjectY"); return status; } addAttribute(constraintObjectY); constraintObjectZ = numAttr.create( "constraintObjectZ", "otz", MFnNumericData::kDouble, 0.0, &status ); if(!status) { MGlobal::displayInfo("failed to create attrib constraintObjectZ"); return status; } addAttribute(constraintObjectZ); targetOffset = numAttr.create("targetOffset", "tgo", MFnNumericData::k3Double, 0.0, &status); if (!status) { status.perror("addAttribute targetOffset"); return status;} addAttribute(targetOffset); targetRestP = numAttr.create("targetRestAt", "tgrt", MFnNumericData::k3Double, 0.0, &status); if (!status) { status.perror("addAttribute targetRestAt"); return status;} addAttribute(targetRestP); status = addAttribute( geometrySurfaceConstraint::constraintParentInverseMatrix ); if (!status) { status.perror("addAttribute"); return status;} status = addAttribute( geometrySurfaceConstraint::constraintGeometry ); if (!status) { status.perror("addAttribute"); return status;} status = addAttribute( geometrySurfaceConstraint::compoundTarget ); if (!status) { status.perror("addAttribute"); return status;} status = attributeAffects( compoundTarget, constraintGeometry ); if (!status) { status.perror("attributeAffects"); return status;} status = attributeAffects( targetTransform, constraintGeometry ); if (!status) { status.perror("attributeAffects"); return status;} status = attributeAffects( targetGeometry, constraintGeometry ); if (!status) { status.perror("attributeAffects"); return status;} status = attributeAffects( targetWeight, constraintGeometry ); if (!status) { status.perror("attributeAffects"); return status;} status = attributeAffects( constraintParentInverseMatrix, constraintGeometry ); if (!status) { status.perror("attributeAffects"); return status;} attributeAffects(targetTransform, constraintTranslateX); attributeAffects(targetTransform, constraintTranslateY); attributeAffects(targetTransform, constraintTranslateZ); return MS::kSuccess; }
// Attributes initialisation MStatus DA_GridGenerator::initialize() { MStatus stat; MFnCompoundAttribute cAttr; MFnNumericAttribute nAttr; MFnEnumAttribute eAttr; MFnTypedAttribute tAttr; // // Controls // aWidth = nAttr.create("width", "w", MFnNumericData::kDouble, 1.0); nAttr.setMin(0.001); nAttr.setChannelBox(true); nAttr.setKeyable(true); stat = addAttribute(aWidth); CHECK_MSTATUS(stat); aHeight = nAttr.create("height", "h", MFnNumericData::kDouble, 1.0); nAttr.setMin(0.001); nAttr.setChannelBox(true); nAttr.setKeyable(true); stat = addAttribute(aHeight); CHECK_MSTATUS(stat); aResolutionX = nAttr.create("resolutionX", "resx", MFnNumericData::kInt, 10); nAttr.setMin(2); nAttr.setChannelBox(true); nAttr.setKeyable(true); aResolutionY = nAttr.create("resolutionY", "resy", MFnNumericData::kInt, 10); nAttr.setMin(2); nAttr.setChannelBox(true); nAttr.setKeyable(true); aResolution = cAttr.create("resolution", "res"); stat = cAttr.addChild(aResolutionX); CHECK_MSTATUS(stat); stat = cAttr.addChild(aResolutionY); CHECK_MSTATUS(stat); stat = addAttribute(aResolution); CHECK_MSTATUS(stat); aPattern = eAttr.create("pattern","pat",0); eAttr.addField(DA_GridGeneratorPatterns::NONE, 0); eAttr.addField(DA_GridGeneratorPatterns::BRICK_U, 1); eAttr.addField(DA_GridGeneratorPatterns::BRICK_V, 2); eAttr.setChannelBox(true); eAttr.setKeyable(true); stat = addAttribute(aPattern); CHECK_MSTATUS(stat); // // Outputs // aOutDynamicArray = tAttr.create("outDynamicArray", "oda", MFnData::kDynArrayAttrs); tAttr.setWritable(false); // Just output stat = addAttribute(aOutDynamicArray); CHECK_MSTATUS(stat); // // Attributes affects // attributeAffects(aWidth, aOutDynamicArray); attributeAffects(aHeight, aOutDynamicArray); attributeAffects(aResolutionX, aOutDynamicArray); attributeAffects(aResolutionY, aOutDynamicArray); attributeAffects(aPattern, aOutDynamicArray); // Done return stat; }
MStatus SurfaceAttach::initialize() { MFnTypedAttribute fnTypeAttr; MFnNumericAttribute fnNumAttr; MFnUnitAttribute fnUnitAttr; MFnCompoundAttribute fnCompoundAttr; MFnEnumAttribute fnEnumAttr; MFnMatrixAttribute fnMatAttr; MStatus stat; // Input Attributes direction = fnEnumAttr.create("direction", "dire", 0); fnEnumAttr.addField("U", 0); fnEnumAttr.addField("V", 1); surface = fnTypeAttr.create("surface", "surface", MFnData::kNurbsSurface); parentInverse = fnMatAttr.create("parentInverse", "ps", MFnMatrixAttribute::kDouble); fnMatAttr.setKeyable(true); samples = fnNumAttr.create("samples", "samples", MFnNumericData::kInt, 1000); fnNumAttr.setKeyable(true); fnNumAttr.setMin(1.0); staticLength = fnNumAttr.create("staticLength", "staticLength", MFnNumericData::kDouble, 0.0001); fnNumAttr.setKeyable(true); fnNumAttr.setMin(0.0001); offset = fnNumAttr.create("offset", "offset", MFnNumericData::kDouble, 0.0); fnNumAttr.setKeyable(true); genus = fnEnumAttr.create("type", "type", 0); fnEnumAttr.addField("Parametric", 0); fnEnumAttr.addField("Percentage", 1); fnEnumAttr.addField("FixedLength", 2); fnEnumAttr.setKeyable(true); reverse = fnNumAttr.create("reverse", "reverse", MFnNumericData::kBoolean, false); fnNumAttr.setKeyable(true); inU = fnNumAttr.create("inU", "U", MFnNumericData::kDouble, 0.5); fnNumAttr.setKeyable(true); inV = fnNumAttr.create("inV", "V", MFnNumericData::kDouble, 0.5); fnNumAttr.setKeyable(true); inUV = fnCompoundAttr.create("inUV", "inUV"); fnCompoundAttr.setKeyable(true); fnCompoundAttr.setArray(true); fnCompoundAttr.addChild(inU); fnCompoundAttr.addChild(inV); fnCompoundAttr.setUsesArrayDataBuilder(true); // Output Attributes translateX = fnNumAttr.create("translateX", "translateX", MFnNumericData::kDouble); fnNumAttr.setWritable(false); fnNumAttr.setStorable(false); translateY = fnNumAttr.create("translateY", "translateY", MFnNumericData::kDouble); fnNumAttr.setWritable(false); fnNumAttr.setStorable(false); translateZ = fnNumAttr.create("translateZ", "translateZ", MFnNumericData::kDouble); fnNumAttr.setWritable(false); fnNumAttr.setStorable(false); translate = fnNumAttr.create("translate", "translate", translateX, translateY, translateZ); fnNumAttr.setWritable(false); fnNumAttr.setStorable(false); rotateX = fnUnitAttr.create("rotateX", "rotateX", MFnUnitAttribute::kAngle); fnUnitAttr.setWritable(false); fnUnitAttr.setStorable(false); rotateY = fnUnitAttr.create("rotateY", "rotateY", MFnUnitAttribute::kAngle); fnUnitAttr.setWritable(false); fnUnitAttr.setStorable(false); rotateZ = fnUnitAttr.create("rotateZ", "rotateZ", MFnUnitAttribute::kAngle); fnUnitAttr.setWritable(false); fnUnitAttr.setStorable(false); rotate = fnNumAttr.create("rotate", "rotate", rotateX, rotateY, rotateZ); fnNumAttr.setWritable(false); out = fnCompoundAttr.create("out", "out"); fnCompoundAttr.setWritable(false); fnCompoundAttr.setArray(true); fnCompoundAttr.addChild(translate); fnCompoundAttr.addChild(rotate); fnCompoundAttr.setUsesArrayDataBuilder(true); // These aren't going to fail, give me a break :) // Add Attributes SurfaceAttach::addAttribute(direction); SurfaceAttach::addAttribute(surface); SurfaceAttach::addAttribute(parentInverse); SurfaceAttach::addAttribute(samples); SurfaceAttach::addAttribute(staticLength); SurfaceAttach::addAttribute(offset); SurfaceAttach::addAttribute(genus); SurfaceAttach::addAttribute(reverse); SurfaceAttach::addAttribute(inUV); SurfaceAttach::addAttribute(out); // Attribute Affects SurfaceAttach::attributeAffects(direction, translate); SurfaceAttach::attributeAffects(surface, translate); SurfaceAttach::attributeAffects(parentInverse, translate); SurfaceAttach::attributeAffects(staticLength, translate); SurfaceAttach::attributeAffects(samples, translate); SurfaceAttach::attributeAffects(offset, translate); SurfaceAttach::attributeAffects(genus, translate); SurfaceAttach::attributeAffects(reverse, translate); SurfaceAttach::attributeAffects(inU, translate); SurfaceAttach::attributeAffects(inV, translate); SurfaceAttach::attributeAffects(direction, rotate); SurfaceAttach::attributeAffects(surface, rotate); SurfaceAttach::attributeAffects(parentInverse, rotate); SurfaceAttach::attributeAffects(staticLength, rotate); SurfaceAttach::attributeAffects(samples, rotate); SurfaceAttach::attributeAffects(offset, rotate); SurfaceAttach::attributeAffects(genus, rotate); SurfaceAttach::attributeAffects(reverse, rotate); SurfaceAttach::attributeAffects(inU, rotate); SurfaceAttach::attributeAffects(inV, rotate); return MS::kSuccess; }
//----------------------------------------------------------------------------- // //----------------------------------------------------------------------------- MStatus CVstWeldNode::Initialize() { MFnCompoundAttribute cFn; MFnEnumAttribute eFn; MFnGenericAttribute gFn; MFnMatrixAttribute mFn; MFnNumericAttribute nFn; MFnTypedAttribute tFn; MFnUnitAttribute uFn; m_iaWorldGeometry = gFn.create( "worldGeometry", "wgeo" ); gFn.setHidden( true ); gFn.setStorable( false ); gFn.addAccept( MFnData::kMesh ); gFn.addAccept( MFnData::kNurbsCurve ); gFn.addAccept( MFnData::kNurbsSurface ); m_iaType = eFn.create( "type", "typ", kMeshFace ); eFn.addField( "meshFace", kMeshFace ); m_iaInt = nFn.create( "int", "i", MFnNumericData::kInt ); m_iaFloat0 = nFn.create( "float0", "f0", MFnNumericData::kDouble ); m_iaFloat1 = nFn.create( "float1", "f1", MFnNumericData::kDouble ); m_iaOffsetMatrix = mFn.create( "offsetMatrix", "omat" ); m_iaInverseParentSpace = mFn.create( "inverseParentSpace", "ips" ); m_iaRotateOrder = eFn.create( "rotateOrder", "ro", 0 ); eFn.addField( "xyz", 0 ); eFn.addField( "yzx", 1 ); eFn.addField( "zxy", 2 ); eFn.addField( "xzy", 3 ); eFn.addField( "yxz", 4 ); eFn.addField( "zyx", 5 ); m_iaWeldInput = cFn.create( "weldInput", "wi" ); cFn.setArray( true ); cFn.addChild( m_iaType ); cFn.addChild( m_iaInt ); cFn.addChild( m_iaFloat0 ); cFn.addChild( m_iaFloat1 ); cFn.addChild( m_iaOffsetMatrix ); cFn.addChild( m_iaInverseParentSpace ); cFn.addChild( m_iaRotateOrder ); m_oaTranslateX = uFn.create( "translateX", "tx", MFnUnitAttribute::kDistance ); m_oaTranslateY = uFn.create( "translateY", "ty", MFnUnitAttribute::kDistance ); m_oaTranslateZ = uFn.create( "translateZ", "tz", MFnUnitAttribute::kDistance ); m_oaTranslate = nFn.create( "translate", "t", m_oaTranslateX, m_oaTranslateY, m_oaTranslateZ ); m_oaRotateX = uFn.create( "rotateX", "rx", MFnUnitAttribute::kAngle ); m_oaRotateY = uFn.create( "rotateY", "ry", MFnUnitAttribute::kAngle ); m_oaRotateZ = uFn.create( "rotateZ", "rz", MFnUnitAttribute::kAngle ); m_oaRotate = nFn.create( "rotate", "r", m_oaRotateX, m_oaRotateY, m_oaRotateZ ); m_oaWeldOutput = cFn.create( "weldOutput", "wo" ); cFn.setArray( true ); cFn.addChild( m_oaTranslate ); cFn.addChild( m_oaRotate ); cFn.setUsesArrayDataBuilder( true ); addAttribute( m_iaWorldGeometry ); addAttribute( m_iaWeldInput ); addAttribute( m_oaWeldOutput ); attributeAffects( m_iaWorldGeometry, m_oaWeldOutput ); attributeAffects( m_iaWeldInput, m_oaWeldOutput ); return MS::kSuccess; }
MStatus geometrySurfaceConstraint::initialize() { MFnNumericAttribute nAttr; MStatus status; // constraint attributes { // Geometry: mesh, readable, not writable, delete on disconnect MFnTypedAttribute typedAttrNotWritable; geometrySurfaceConstraint::constraintGeometry = typedAttrNotWritable.create( "constraintGeometry", "cg", MFnData::kMesh, &status ); if (!status) { status.perror("typedAttrNotWritable.create:cgeom"); return status;} status = typedAttrNotWritable.setReadable(true); if (!status) { status.perror("typedAttrNotWritable.setReadable:cgeom"); return status;} status = typedAttrNotWritable.setWritable(false); if (!status) { status.perror("typedAttrNotWritable.setWritable:cgeom"); return status;} status = typedAttrNotWritable.setDisconnectBehavior(MFnAttribute::kDelete); if (!status) { status.perror("typedAttrNotWritable.setDisconnectBehavior:cgeom"); return status;} } { // Parent inverse matrix: delete on disconnect MFnTypedAttribute typedAttr; geometrySurfaceConstraint::constraintParentInverseMatrix = typedAttr.create( "constraintPim", "ci", MFnData::kMatrix, &status ); if (!status) { status.perror("typedAttr.create:matrix"); return status;} status = typedAttr.setDisconnectBehavior(MFnAttribute::kDelete); if (!status) { status.perror("typedAttr.setDisconnectBehavior:cgeom"); return status;} // Target geometry: mesh, delete on disconnect geometrySurfaceConstraint::targetGeometry = typedAttr.create( "targetGeometry", "tg", MFnData::kMesh, &status ); if (!status) { status.perror("typedAttr.create:tgeom"); return status;} status = typedAttr.setDisconnectBehavior(MFnAttribute::kDelete); if (!status) { status.perror("typedAttr.setDisconnectBehavior:cgeom"); return status;} } { // Target weight: double, min 0, default 1.0, keyable, delete on disconnect MFnNumericAttribute typedAttrKeyable; geometrySurfaceConstraint::targetWeight = typedAttrKeyable.create( "weight", "wt", MFnNumericData::kDouble, 1.0, &status ); if (!status) { status.perror("typedAttrKeyable.create:weight"); return status;} status = typedAttrKeyable.setMin( (double) 0 ); if (!status) { status.perror("typedAttrKeyable.setMin"); return status;} status = typedAttrKeyable.setKeyable( true ); if (!status) { status.perror("typedAttrKeyable.setKeyable"); return status;} status = typedAttrKeyable.setDisconnectBehavior(MFnAttribute::kDelete); if (!status) { status.perror("typedAttrKeyable.setDisconnectBehavior:cgeom"); return status;} } { // Compound target(geometry,weight): array, delete on disconnect MFnCompoundAttribute compoundAttr; geometrySurfaceConstraint::compoundTarget = compoundAttr.create( "target", "tgt",&status ); if (!status) { status.perror("compoundAttr.create"); return status;} status = compoundAttr.addChild( geometrySurfaceConstraint::targetGeometry ); if (!status) { status.perror("compoundAttr.addChild"); return status;} status = compoundAttr.addChild( geometrySurfaceConstraint::targetWeight ); if (!status) { status.perror("compoundAttr.addChild"); return status;} status = compoundAttr.setArray( true ); if (!status) { status.perror("compoundAttr.setArray"); return status;} status = compoundAttr.setDisconnectBehavior(MFnAttribute::kDelete); if (!status) { status.perror("typedAttrKeyable.setDisconnectBehavior:cgeom"); return status;} } status = addAttribute( geometrySurfaceConstraint::constraintParentInverseMatrix ); if (!status) { status.perror("addAttribute"); return status;} status = addAttribute( geometrySurfaceConstraint::constraintGeometry ); if (!status) { status.perror("addAttribute"); return status;} status = addAttribute( geometrySurfaceConstraint::compoundTarget ); if (!status) { status.perror("addAttribute"); return status;} status = attributeAffects( compoundTarget, constraintGeometry ); if (!status) { status.perror("attributeAffects"); return status;} status = attributeAffects( targetGeometry, constraintGeometry ); if (!status) { status.perror("attributeAffects"); return status;} status = attributeAffects( targetWeight, constraintGeometry ); if (!status) { status.perror("attributeAffects"); return status;} status = attributeAffects( constraintParentInverseMatrix, constraintGeometry ); if (!status) { status.perror("attributeAffects"); return status;} return MS::kSuccess; }
MStatus sgHair_controlJoint::initialize() { MStatus status; MFnTypedAttribute tAttr; MFnMatrixAttribute mAttr; MFnMessageAttribute msgAttr; MFnNumericAttribute nAttr; MFnUnitAttribute uAttr; MFnCompoundAttribute cAttr; aInputBaseCurve = tAttr.create( "inputBaseCurve", "inputBaseCurve", MFnData::kNurbsCurve ); tAttr.setStorable( true ); CHECK_MSTATUS_AND_RETURN_IT( addAttribute( aInputBaseCurve ) ); aInputBaseCurveMatrix = mAttr.create( "inputBaseCurveMatrix", "inputBaseCurveMatrix" ); mAttr.setStorable( true ); CHECK_MSTATUS_AND_RETURN_IT( addAttribute( aInputBaseCurveMatrix ) ); aJointParentBaseMatrix = mAttr.create( "jointParentBaseMatrix", "jointParentBaseMatrix" ); mAttr.setStorable( true ); CHECK_MSTATUS_AND_RETURN_IT( addAttribute( aJointParentBaseMatrix ) ); aGravityParam = nAttr.create( "gravityParam", "gravityParam", MFnNumericData::kDouble, 0.0 ); nAttr.setMin( 0.0 ); nAttr.setStorable( true ); CHECK_MSTATUS_AND_RETURN_IT( addAttribute( aGravityParam ) ); aGravityRange = nAttr.create( "gravityRange", "gravityRange", MFnNumericData::kDouble, 0.0 ); nAttr.setMin( 0.0 ); nAttr.setStorable( true ); CHECK_MSTATUS_AND_RETURN_IT( addAttribute( aGravityRange ) ); aGravityWeight = nAttr.create( "gravityWeight", "gravityWeight", MFnNumericData::kDouble, 0.0 ); nAttr.setMin( 0.0 ); nAttr.setMax( 1.0 ); nAttr.setStorable( true ); CHECK_MSTATUS_AND_RETURN_IT( addAttribute( aGravityWeight ) ); aGravityOffsetMatrix = mAttr.create( "gravityOffsetMatrix", "gravityOffsetMatrix" ); mAttr.setStorable( true ); CHECK_MSTATUS_AND_RETURN_IT( addAttribute( aGravityOffsetMatrix ) ); aStaticRotation = nAttr.create( "staticRotation", "staticRotation", MFnNumericData::kBoolean, false ); nAttr.setStorable( true ); CHECK_MSTATUS_AND_RETURN_IT( addAttribute( aStaticRotation ) ); aOutput = cAttr.create( "output", "output" ); aOutTransX = nAttr.create( "outTransX", "otx", MFnNumericData::kDouble ); aOutTransY = nAttr.create( "outTransY", "oty", MFnNumericData::kDouble ); aOutTransZ = nAttr.create( "outTransZ", "otz", MFnNumericData::kDouble ); aOutTrans = nAttr.create( "outTrans", "ot", aOutTransX, aOutTransY, aOutTransZ ); aOutOrientX = uAttr.create( "outRotateX", "orx", MFnUnitAttribute::kAngle, 0.0 ); aOutOrientY = uAttr.create( "outRotateY", "ory", MFnUnitAttribute::kAngle, 0.0 ); aOutOrientZ = uAttr.create( "outRotateZ", "orz", MFnUnitAttribute::kAngle, 0.0 ); aOutOrient = nAttr.create( "outRotate", "outRotate", aOutOrientX, aOutOrientY, aOutOrientZ ); cAttr.addChild( aOutTrans ); cAttr.addChild( aOutOrient ); cAttr.setStorable( false ); cAttr.setArray( true ); cAttr.setUsesArrayDataBuilder( true ); CHECK_MSTATUS_AND_RETURN_IT( addAttribute( aOutput ) ); CHECK_MSTATUS_AND_RETURN_IT( attributeAffects( aGravityParam, aOutput ) ); CHECK_MSTATUS_AND_RETURN_IT( attributeAffects( aGravityRange, aOutput ) ); CHECK_MSTATUS_AND_RETURN_IT( attributeAffects( aGravityWeight, aOutput ) ); CHECK_MSTATUS_AND_RETURN_IT( attributeAffects( aJointParentBaseMatrix, aOutput ) ); CHECK_MSTATUS_AND_RETURN_IT( attributeAffects( aGravityOffsetMatrix, aOutput ) ); CHECK_MSTATUS_AND_RETURN_IT( attributeAffects( aInputBaseCurve, aOutput ) ); CHECK_MSTATUS_AND_RETURN_IT( attributeAffects( aInputBaseCurveMatrix, aOutput ) ); CHECK_MSTATUS_AND_RETURN_IT( attributeAffects( aStaticRotation, aOutput ) ); return MS::kSuccess; }
MStatus MG_nurbsRivet::initialize() { //This is the nurbs input attribute MFnTypedAttribute typedFn; MFnCompoundAttribute compund; MFnNumericAttribute numFn; MFnMatrixAttribute matrixFn; inputNurbSurface = typedFn.create("inputNurbSurface","in",MFnData::kNurbsSurface); typedFn.setStorable(true); addAttribute(inputNurbSurface); //This is the input point attribute inputPointX = numFn.create("inputPointX","ipx",MFnNumericData::kDouble,0); numFn.setStorable(true); numFn.setKeyable(true); addAttribute(inputPointX); inputPointY = numFn.create("inputPointY","ipy",MFnNumericData::kDouble,0); numFn.setStorable(true); numFn.setKeyable(true); addAttribute(inputPointY); inputPointZ = numFn.create("inputPointZ","ipz",MFnNumericData::kDouble,0); numFn.setStorable(true); numFn.setKeyable(true); addAttribute(inputPointZ); inputPoint= compund.create("inputPoint","ip"); compund.addChild(inputPointX); compund.addChild(inputPointY); compund.addChild(inputPointZ); addAttribute(inputPoint); //This is the recompute point checkbox recompute = numFn.create("recompute","r",MFnNumericData::kBoolean,1); numFn.setKeyable(true); numFn.setStorable(true); addAttribute(recompute); //This is U attribute uValue = numFn.create("uValue","u",MFnNumericData::kFloat , 0); numFn.setKeyable(true); numFn.setStorable(true); addAttribute(uValue); //This is V attribute vValue = numFn.create("vValue","v",MFnNumericData::kFloat , 0 ); numFn.setKeyable(true); numFn.setStorable(true); addAttribute(vValue); //This is the output translate attribute outputX = numFn.create("outputTranslateX","otx",MFnNumericData::kDouble,0); numFn.setStorable(true); numFn.setKeyable(true); addAttribute(outputX); outputY = numFn.create("outputTranslateY","oty",MFnNumericData::kDouble,0); numFn.setStorable(true); numFn.setKeyable(true); addAttribute(outputY); outputZ = numFn.create("outputTranslateZ","otz",MFnNumericData::kDouble,0); numFn.setStorable(true); numFn.setKeyable(true); addAttribute(outputZ); output= compund.create("outputTranslate","ot"); compund.addChild(outputX); compund.addChild(outputY); compund.addChild(outputZ); compund.setKeyable(false); compund.setStorable(false); compund.setWritable(false); addAttribute(output); //output = numFn.createPoint("outputTranslate","ot"); //numFn.setKeyable(false); //numFn.setStorable(false); //numFn.setWritable(false); //addAttribute(output); //This is the output rotate attribute outputRotateX = numFn.create("outputRotateX","orx",MFnNumericData::kDouble,0); numFn.setStorable(true); numFn.setKeyable(true); addAttribute(outputRotateX); outputRotateY = numFn.create("outputRotateY","ory",MFnNumericData::kDouble,0); numFn.setStorable(true); numFn.setKeyable(true); addAttribute(outputRotateY); outputRotateZ = numFn.create("outputRotateZ","orz",MFnNumericData::kDouble,0); numFn.setStorable(true); numFn.setKeyable(true); addAttribute(outputRotateZ); outputRotate= compund.create("outputRotate","oro"); compund.addChild(outputRotateX); compund.addChild(outputRotateY); compund.addChild(outputRotateZ); compund.setKeyable(false); compund.setStorable(false); compund.setWritable(false); addAttribute(outputRotate); //Those are all the matrix input outputMatrix =matrixFn.create("outputMatrix","om"); matrixFn.setKeyable(false); matrixFn.setStorable(false); matrixFn.setWritable(false); addAttribute(outputMatrix); //offset matrix offsetMatrix =matrixFn.create("offsetMatrix","ofm"); MMatrix defMatrix; defMatrix.setToIdentity(); matrixFn.setDefault(defMatrix); matrixFn.setKeyable(false); matrixFn.setStorable(true); matrixFn.setWritable(true); addAttribute(offsetMatrix); //all the attr affects attributeAffects (recompute,output); attributeAffects (inputPoint,output); attributeAffects (inputNurbSurface,output); attributeAffects (uValue,output); attributeAffects (vValue,output); attributeAffects (offsetMatrix,output); attributeAffects (recompute,outputRotate); attributeAffects (inputPoint,outputRotate); attributeAffects (inputNurbSurface,outputRotate); attributeAffects (uValue,outputRotate); attributeAffects (vValue,outputRotate); attributeAffects (offsetMatrix,outputRotate); attributeAffects (recompute,outputMatrix); attributeAffects (inputPoint,outputMatrix); attributeAffects (inputNurbSurface,outputMatrix); attributeAffects (uValue,outputMatrix); attributeAffects (vValue,outputMatrix); attributeAffects (offsetMatrix,outputMatrix); return MS::kSuccess; }
MStatus SargassoNode::initialize() { MFnNumericAttribute nAttr; MStatus status; MFnTypedAttribute typedAttr; MFnMatrixAttribute pimAttr; aconstraintParentInverseMatrix = pimAttr.create( "constraintParentInvMat", "cpim", MFnMatrixAttribute::kDouble, &status ); pimAttr.setArray(true); pimAttr.setStorable(false); pimAttr.setDisconnectBehavior(MFnAttribute::kDelete); status = addAttribute(aconstraintParentInverseMatrix); if (!status) { status.perror("addAttribute parent inverse matrix"); return status;} MFnNumericAttribute numAttr; constraintTranslateX = numAttr.create( "constraintTranslateX", "ctx", MFnNumericData::kDouble, 0.0, &status ); if(!status) { MGlobal::displayInfo("failed to create attrib constraintTranslateX"); return status; } constraintTranslateY = numAttr.create( "constraintTranslateY", "cty", MFnNumericData::kDouble, 0.0, &status ); if(!status) { MGlobal::displayInfo("failed to create attrib constraintTranslateY"); return status; } constraintTranslateZ = numAttr.create( "constraintTranslateZ", "ctz", MFnNumericData::kDouble, 0.0, &status ); if(!status) { MGlobal::displayInfo("failed to create attrib constraintTranslateY"); return status; } MFnUnitAttribute angleAttr; constraintRotateX = angleAttr.create( "constraintRotateX", "crx", MFnUnitAttribute::kAngle , 0.0, &status ); if(!status) { MGlobal::displayInfo("failed to create attrib constraintRotateX"); return status; } constraintRotateY = angleAttr.create( "constraintRotateY", "cry", MFnUnitAttribute::kAngle , 0.0, &status ); if(!status) { MGlobal::displayInfo("failed to create attrib constraintRotateY"); return status; } constraintRotateZ = angleAttr.create( "constraintRotateZ", "crz", MFnUnitAttribute::kAngle , 0.0, &status ); if(!status) { MGlobal::displayInfo("failed to create attrib constraintRotateY"); return status; } { // Compound target(geometry,weight): array, delete on disconnect MFnCompoundAttribute compoundAttr; compoundOutput = compoundAttr.create( "outValue", "otv",&status ); if (!status) { status.perror("compoundAttr.create"); return status;} status = compoundAttr.addChild( constraintTranslateX ); if (!status) { status.perror("compoundAttr.addChild tx"); return status;} status = compoundAttr.addChild( constraintTranslateY ); if (!status) { status.perror("compoundAttr.addChild ty"); return status;} status = compoundAttr.addChild( constraintTranslateZ ); if (!status) { status.perror("compoundAttr.addChild tz"); return status;} compoundAttr.addChild( constraintRotateX ); compoundAttr.addChild( constraintRotateY ); compoundAttr.addChild( constraintRotateZ ); compoundAttr.setArray( true ); //status = compoundAttr.setDisconnectBehavior(MFnAttribute::kDelete); //if (!status) { status.perror("typedAttrKeyable.setDisconnectBehavior:cgeom"); return status;} } status = addAttribute( compoundOutput ); if (!status) { status.perror("addAttribute"); return status;} MPointArray defaultPntArray; MFnPointArrayData pntArrayDataFn; pntArrayDataFn.create( defaultPntArray ); atargetRestP = typedAttr.create( "targetRestP", "tgrp", MFnData::kPointArray, pntArrayDataFn.object()); typedAttr.setStorable(true); addAttribute(atargetRestP); MIntArray defaultIntArray; MFnIntArrayData intArrayDataFn; intArrayDataFn.create( defaultIntArray ); atargetTri = typedAttr.create( "targetTriangle", "tgtri", MFnData::kIntArray, intArrayDataFn.object()); typedAttr.setStorable(true); addAttribute(atargetTri); atargetBind = typedAttr.create( "targetBindId", "tgbdi", MFnData::kIntArray, intArrayDataFn.object()); typedAttr.setStorable(true); addAttribute(atargetBind); aobjTri = typedAttr.create( "objectTriId", "obti", MFnData::kIntArray, intArrayDataFn.object()); typedAttr.setStorable(true); addAttribute(aobjTri); atargetNv = numAttr.create( "targetNumV", "tgnv", MFnNumericData::kInt, 0, &status ); addAttribute(atargetNv); atargetNt = numAttr.create( "targetNumTri", "tgnt", MFnNumericData::kInt, 0, &status ); addAttribute(atargetNt); MVectorArray defaultVectArray; MFnVectorArrayData vectArrayDataFn; vectArrayDataFn.create( defaultVectArray ); aobjLocal = typedAttr.create( "objectLocalP", "oblp", MFnData::kVectorArray, vectArrayDataFn.object()); typedAttr.setStorable(true); addAttribute(aobjLocal); aobjN = numAttr.create( "objectCount", "obct", MFnNumericData::kInt, 0, &status ); addAttribute(aobjN); atargetMesh = typedAttr.create("targetMesh", "tgms", MFnMeshData::kMesh, &status); typedAttr.setStorable(false); addAttribute(atargetMesh); attributeAffects(atargetMesh, compoundOutput); // attributeAffects(aconstraintParentInverseMatrix, compoundOutput); return MS::kSuccess; }
MStatus retargetLocator::initialize() { MFnNumericAttribute nAttr; MFnMatrixAttribute mAttr; MFnEnumAttribute eAttr; MFnUnitAttribute uAttr; MFnCompoundAttribute cAttr; MFnTypedAttribute tAttr; aOutput = nAttr.create( "output", "output", MFnNumericData::kDouble ); nAttr.setStorable( false ); CHECK_MSTATUS( addAttribute( aOutput ) ); aDiscMatrix = mAttr.create( "discMatrix", "discMatrix" ); mAttr.setStorable( true ); CHECK_MSTATUS( addAttribute( aDiscMatrix ) ); CHECK_MSTATUS( attributeAffects( aDiscMatrix, aOutput ) ); aDiscAxis = eAttr.create( "discAxis", "discAxis", 0 ); eAttr.addField( "X", 0 ); eAttr.addField( "Y", 1 ); eAttr.addField( "Z", 2 ); eAttr.setStorable( true ); eAttr.setChannelBox( true ); eAttr.setReadable( true ); CHECK_MSTATUS( addAttribute( aDiscAxis ) ); CHECK_MSTATUS( attributeAffects( aDiscAxis, aOutput ) ); aDiscDivision = nAttr.create( "discDivision", "discDivision", MFnNumericData::kInt, 32 ); nAttr.setMin( 1 ); nAttr.setMax( 32 ); nAttr.setStorable( true ); nAttr.setChannelBox( true ); CHECK_MSTATUS( addAttribute( aDiscDivision ) ); CHECK_MSTATUS( attributeAffects( aDiscDivision, aOutput ) ); aDiscAngle = uAttr.create( "discAngle", "discAngle", MFnUnitAttribute::kAngle, 0.0 ); uAttr.setStorable( true ); uAttr.setChannelBox( true ); CHECK_MSTATUS( addAttribute( aDiscAngle ) ); CHECK_MSTATUS( attributeAffects( aDiscAngle, aOutput ) ); aDiscOffsetX = nAttr.create( "discOffsetX", "discOffsetX", MFnNumericData::kDouble, 0.0 ); aDiscOffsetY = nAttr.create( "discOffsetY", "discOffsetY", MFnNumericData::kDouble, 0.0 ); aDiscOffsetZ = nAttr.create( "discOffsetZ", "discOffsetZ", MFnNumericData::kDouble, 0.0 ); aDiscOffset = nAttr.create( "discOffset", "discOffset", aDiscOffsetX, aDiscOffsetY, aDiscOffsetZ ); uAttr.setStorable( true ); uAttr.setChannelBox( true ); CHECK_MSTATUS( addAttribute( aDiscOffset ) ); CHECK_MSTATUS( attributeAffects( aDiscOffset, aOutput ) ); aDiscSizeX = nAttr.create( "discSizeX", "discSizeX", MFnNumericData::kDouble, 1.0 ); aDiscSizeY = nAttr.create( "discSizeY", "discSizeY", MFnNumericData::kDouble, 1.0 ); aDiscSizeZ = nAttr.create( "discSizeZ", "discSizeZ", MFnNumericData::kDouble, 1.0 ); aDiscSize = nAttr.create( "discSize", "discSize", aDiscSizeX, aDiscSizeY, aDiscSizeZ ); uAttr.setStorable( true ); uAttr.setChannelBox( true ); CHECK_MSTATUS( addAttribute( aDiscSize ) ); CHECK_MSTATUS( attributeAffects( aDiscSize, aOutput ) ); aDiscActiveColor = nAttr.createColor( "discActiveColor", "discActiveColor" ); nAttr.setStorable( true ); nAttr.setUsedAsColor(true); nAttr.setDefault(1.0f, 1.0f, 1.0f); CHECK_MSTATUS( addAttribute( aDiscActiveColor ) ); CHECK_MSTATUS( attributeAffects( aDiscActiveColor, aOutput ) ); aDiscLeadColor = nAttr.createColor( "discLeadColor", "discLeadColor" ); nAttr.setStorable( true ); nAttr.setUsedAsColor(true); nAttr.setDefault(.263f, 1.0f, .639f); CHECK_MSTATUS( addAttribute( aDiscLeadColor ) ); CHECK_MSTATUS( attributeAffects( aDiscLeadColor, aOutput ) ); aDiscDefaultColor = nAttr.createColor( "discDefaultColor", "discDefaultColor" ); nAttr.setStorable( true ); nAttr.setUsedAsColor(true); nAttr.setDefault(.0f, .016f, .376f); CHECK_MSTATUS( addAttribute( aDiscDefaultColor ) ); CHECK_MSTATUS( attributeAffects( aDiscDefaultColor, aOutput ) ); aDiscFillAlpha = nAttr.create( "discFillAlpha", "discFillAlpha", MFnNumericData::kFloat, 0.1f ); nAttr.setStorable( true ); nAttr.setMin( 0.0f ); nAttr.setMax( 1.0f ); CHECK_MSTATUS( addAttribute( aDiscFillAlpha ) ); CHECK_MSTATUS( attributeAffects( aDiscFillAlpha, aOutput ) ); aDiscLineAlpha = nAttr.create( "discLineAlpha", "discLineAlpha", MFnNumericData::kFloat, 1.0f ); nAttr.setStorable( true ); nAttr.setMin( 0.0f ); nAttr.setMax( 1.0f ); CHECK_MSTATUS( addAttribute( aDiscLineAlpha ) ); CHECK_MSTATUS( attributeAffects( aDiscLineAlpha, aOutput ) ); aArrow = cAttr.create( "arrow", "arrow" ); aInheritMatrix = nAttr.create( "inheritMatrix", "inheritMatrix", MFnNumericData::kBoolean, false ); aInputMesh = tAttr.create( "inputMesh", "inputMesh", MFnData::kMesh ); aAimMatrix = mAttr.create( "aimMatrix", "aimMatrix" ); aStartSize = nAttr.create( "startSize", "startSize", MFnNumericData::kFloat, 0.5f ); aSize = nAttr.create( "size", "size", MFnNumericData::kFloat, 1.0f ); aActiveColor = nAttr.createColor( "activeColor", "activeColor" ); nAttr.setUsedAsColor(true); nAttr.setDefault(1.0f, 1.0f, 1.0f); aLeadColor = nAttr.createColor( "leadColor", "leadColor" ); nAttr.setUsedAsColor(true); nAttr.setDefault(.263f, 1.0f, .639f); aDefaultColor = nAttr.createColor( "defaultColor", "defaultColor" ); nAttr.setUsedAsColor(true); nAttr.setDefault(.0f, .016f, .376f); aFillAlpha = nAttr.create( "fillAlpha", "fillAlpha", MFnNumericData::kFloat, 0.1f ); aLineAlpha = nAttr.create( "lineAlpha", "lineAlpha", MFnNumericData::kFloat, 1.0f ); aOffsetX = nAttr.create( "offsetX", "offsetX", MFnNumericData::kDouble, 0.0 ); aOffsetY = nAttr.create( "offsetY", "offsetY", MFnNumericData::kDouble, 0.0 ); aOffsetZ = nAttr.create( "offsetZ", "offsetZ", MFnNumericData::kDouble, 0.0 ); aOffset = nAttr.create( "offset", "offset", aOffsetX, aOffsetY, aOffsetZ ); cAttr.addChild( aInheritMatrix ); cAttr.addChild( aAimMatrix ); cAttr.addChild( aInputMesh ); cAttr.addChild( aStartSize ); cAttr.addChild( aSize ); cAttr.addChild( aActiveColor ); cAttr.addChild( aLeadColor ); cAttr.addChild( aDefaultColor ); cAttr.addChild( aFillAlpha ); cAttr.addChild( aLineAlpha ); cAttr.addChild( aOffset ); cAttr.setArray( true ); cAttr.setStorable( true ); CHECK_MSTATUS( addAttribute( aArrow ) ); CHECK_MSTATUS( attributeAffects( aArrow, aOutput ) ); return MS::kSuccess; }
MStatus MG_vectorGL::initialize() { //Declaring all the needed attribute function sets MFnEnumAttribute enumFn; MFnMatrixAttribute matrixFn; MFnNumericAttribute numFn; MFnCompoundAttribute compA; drawIt =numFn.create("drawIt","drw",MFnNumericData::kBoolean,1); numFn.setKeyable(true); numFn.setStorable(true); addAttribute(drawIt); arrowSize =numFn.create("arrowSize","as",MFnNumericData::kDouble,1); numFn.setKeyable(true); numFn.setStorable(true); addAttribute(arrowSize); fakeOut =numFn.create("fakeOut","fo",MFnNumericData::kBoolean,1); numFn.setKeyable(true); numFn.setStorable(true); addAttribute(fakeOut); upVecX =numFn.create("upVecX","uvx",MFnNumericData::kDouble,0); numFn.setStorable(true); addAttribute(upVecX); upVecY =numFn.create("upVecY","uvy",MFnNumericData::kDouble,1); numFn.setStorable(true); addAttribute(upVecY); upVecZ =numFn.create("upVecZ","uvz",MFnNumericData::kDouble,0); numFn.setStorable(true); addAttribute(upVecZ); upVec= compA.create("upVec","uv" ); compA.addChild(upVecX); compA.addChild(upVecY); compA.addChild(upVecZ); addAttribute(upVec); vecX =numFn.create("vecX","vx",MFnNumericData::kDouble,0); numFn.setStorable(true); addAttribute(vecX); vecY =numFn.create("vecY","vy",MFnNumericData::kDouble,1); numFn.setStorable(true); addAttribute(vecY); vecZ =numFn.create("vecZ","vz",MFnNumericData::kDouble,0); numFn.setStorable(true); addAttribute(vecZ); vecs= compA.create("vecs","vs" ); compA.addChild(vecX); compA.addChild(vecY); compA.addChild(vecZ); compA.setArray(true); addAttribute(vecs); startPointX =numFn.create("startPointX","spx",MFnNumericData::kDouble,0); numFn.setStorable(true); addAttribute(startPointX); startPointY =numFn.create("startPointY","spy",MFnNumericData::kDouble,0); numFn.setStorable(true); addAttribute(startPointY); startPointZ =numFn.create("startPointZ","spz",MFnNumericData::kDouble,0); numFn.setStorable(true); addAttribute(startPointZ); startPoint= compA.create("startPoints","sp" ); compA.addChild(startPointX); compA.addChild(startPointY); compA.addChild(startPointZ); compA.setArray(true); addAttribute(startPoint); attributeAffects(arrowSize , fakeOut); attributeAffects(startPoint , fakeOut); attributeAffects(upVec , fakeOut); attributeAffects(drawIt , fakeOut); attributeAffects(vecs , fakeOut); return MS::kSuccess; }
MStatus MG_softIk::initialize() { //This is the nurbs input attribute MFnTypedAttribute typedFn; MFnCompoundAttribute compund; MFnNumericAttribute numFn; MFnMatrixAttribute matrixFn; startMatrix =matrixFn.create("startMatrix","stm"); addAttribute(startMatrix); endMatrix =matrixFn.create("endMatrix","enm"); addAttribute(endMatrix); upInitLength = numFn.create("upInitLength","uil",MFnNumericData::kDouble,0); numFn.setStorable(true); numFn.setKeyable(true); addAttribute(upInitLength); downInitLength = numFn.create("downInitLength","dil",MFnNumericData::kDouble,0); numFn.setStorable(true); numFn.setKeyable(true); addAttribute(downInitLength); globalScale = numFn.create("globalScale","gb",MFnNumericData::kDouble,0); numFn.setStorable(true); numFn.setKeyable(true); numFn.setMin(0.001); addAttribute(globalScale); softDistance = numFn.create("softDistance","sd",MFnNumericData::kDouble,0); numFn.setMin(0.001); numFn.setStorable(true); numFn.setKeyable(true); addAttribute(softDistance); stretch = numFn.create("stretch","str",MFnNumericData::kDouble,0); numFn.setMin(0.0); numFn.setMax(1.0); numFn.setStorable(true); numFn.setKeyable(true); addAttribute(stretch); slide = numFn.create("slide","sld",MFnNumericData::kDouble,0.5); numFn.setMin(0.0); numFn.setMax(1.0); numFn.setStorable(true); numFn.setKeyable(true); addAttribute(slide); upScale = numFn.create("upScale","ups",MFnNumericData::kDouble,1); numFn.setStorable(false); numFn.setKeyable(false); numFn.setWritable(false); addAttribute(upScale); downScale = numFn.create("downScale","dws",MFnNumericData::kDouble,1); numFn.setStorable(false); numFn.setKeyable(false); numFn.setWritable(false); addAttribute(downScale); outputTranslateX = numFn.create("outputTranslateX","otx",MFnNumericData::kDouble,0); numFn.setStorable(false); numFn.setKeyable(false); numFn.setWritable(false); addAttribute(outputTranslateX); outputTranslateY = numFn.create("outputTranslateY","oty",MFnNumericData::kDouble,0); numFn.setStorable(false); numFn.setWritable(false); numFn.setKeyable(false); addAttribute(outputTranslateY); outputTranslateZ = numFn.create("outputTranslateZ","otz",MFnNumericData::kDouble,0); numFn.setStorable(false); numFn.setKeyable(false); numFn.setWritable(false); addAttribute(outputTranslateZ); outputTranslate= compund.create("outputTranslate","ot"); compund.addChild(outputTranslateX); compund.addChild(outputTranslateY); compund.addChild(outputTranslateZ); compund.setStorable(false); compund.setKeyable(false); compund.setWritable(false); addAttribute(outputTranslate); attributeAffects( startMatrix ,outputTranslate) ; attributeAffects( endMatrix ,outputTranslate) ; attributeAffects( softDistance ,outputTranslate) ; attributeAffects( stretch ,outputTranslate) ; attributeAffects( slide ,outputTranslate) ; attributeAffects( globalScale ,outputTranslate) ; attributeAffects( startMatrix ,upScale) ; attributeAffects( endMatrix ,upScale) ; attributeAffects( stretch ,upScale) ; attributeAffects( softDistance ,upScale) ; attributeAffects( slide ,upScale) ; attributeAffects( globalScale ,upScale) ; attributeAffects( startMatrix ,downScale) ; attributeAffects( endMatrix ,downScale) ; attributeAffects( softDistance ,downScale) ; attributeAffects( stretch ,downScale) ; attributeAffects( slide ,downScale) ; attributeAffects( globalScale ,downScale) ; return MS::kSuccess; }
MStatus MG_dotProduct::initialize(){ //Input vector 1 MFnNumericAttribute numericAttrFn; vector1 = numericAttrFn.createPoint("vector1","v1"); addAttribute(vector1); numericAttrFn.setStorable(true); //Input vector 2 vector2 = numericAttrFn.createPoint("vector2","v2"); addAttribute(vector2); numericAttrFn.setStorable(true); //Projection axis attributes ,needs to be created as compound in order to set a default value // X axis projAxisXa = numericAttrFn.create("xAxisProjectionX","xPrjx",MFnNumericData::kFloat,1); addAttribute(projAxisXa); numericAttrFn.setStorable(true); projAxisXb = numericAttrFn.create("xAxisProjectionY","xPrjy",MFnNumericData::kFloat,0); addAttribute(projAxisXa); numericAttrFn.setStorable(true); projAxisXc = numericAttrFn.create("xAxisProjectionZ","xPrjz",MFnNumericData::kFloat,0); addAttribute(projAxisXa); numericAttrFn.setStorable(true); MFnCompoundAttribute compund; projAxisX= compund.create("xAxisProjection","xproj"); compund.addChild(projAxisXa); compund.addChild(projAxisXb); compund.addChild(projAxisXc); addAttribute(projAxisX); // Y axis projAxisYa = numericAttrFn.create("yAxisProjectionX","yPrjx",MFnNumericData::kFloat,0); addAttribute(projAxisYa); numericAttrFn.setStorable(true); projAxisYb = numericAttrFn.create("yAxisProjectionY","yPrjy",MFnNumericData::kFloat,1); addAttribute(projAxisYb); numericAttrFn.setStorable(true); projAxisYc = numericAttrFn.create("yAxisProjectionZ","yPrjz",MFnNumericData::kFloat,0); addAttribute(projAxisYc); numericAttrFn.setStorable(true); projAxisY= compund.create("yAxisProjection","yproj"); compund.addChild(projAxisYa); compund.addChild(projAxisYb); compund.addChild(projAxisYc); addAttribute(projAxisY); // Z axis projAxisZa = numericAttrFn.create("zAxisProjectionX","zPrjx",MFnNumericData::kFloat,0); addAttribute(projAxisZa); numericAttrFn.setStorable(true); projAxisZb = numericAttrFn.create("zAxisProjectionY","zPrjy",MFnNumericData::kFloat,0); addAttribute(projAxisZb); numericAttrFn.setStorable(true); projAxisZc = numericAttrFn.create("zAxisProjectionZ","zPrjz",MFnNumericData::kFloat,1); addAttribute(projAxisZc); numericAttrFn.setStorable(true); projAxisZ= compund.create("zAxisProjection","zproj"); compund.addChild(projAxisZa); compund.addChild(projAxisZb); compund.addChild(projAxisZc); addAttribute(projAxisZ); //normalize attribute normalize=numericAttrFn.create("normalize","n",MFnNumericData::kBoolean ); addAttribute(normalize); numericAttrFn.setStorable(true); //Output attribute that will hold the dot product value dotProductA = numericAttrFn.create("dotProduct","dp",MFnNumericData::kFloat); addAttribute(dotProductA); numericAttrFn.setWritable(false); numericAttrFn.setStorable(false); //dot product max value dotProductMax = numericAttrFn.create("dotProductMaxValue","dpm",MFnNumericData::kFloat); addAttribute(dotProductMax); numericAttrFn.setWritable(false); numericAttrFn.setStorable(false); //Input vector1 projection on vector 2 proj1on2 = numericAttrFn.createPoint("projectionV1onV2","pV1"); addAttribute(proj1on2); numericAttrFn.setWritable(false); numericAttrFn.setStorable(false); //Input vector2 projection on vector 1 proj2on1 = numericAttrFn.createPoint("projectionV2onV1","pV2"); addAttribute(proj2on1); numericAttrFn.setWritable(false); numericAttrFn.setStorable(false); //angle inbetween angleInBetweenAttr = numericAttrFn.create("angleInBetween","aib",MFnNumericData::kFloat); addAttribute(angleInBetweenAttr); numericAttrFn.setWritable(false); numericAttrFn.setStorable(false); //Output attribute that will hold Xvalue of the angle inbetween angleX = numericAttrFn.create("angleX","ax",MFnNumericData::kFloat); addAttribute(angleX); numericAttrFn.setWritable(false); numericAttrFn.setStorable(false); //Output attribute that will hold Xvalue of the angle inbetween angleY = numericAttrFn.create("angleY","ay",MFnNumericData::kFloat); addAttribute(angleY); numericAttrFn.setWritable(false); numericAttrFn.setStorable(false); //Output attribute that will hold Xvalue of the angle inbetween angleZ = numericAttrFn.create("angleZ","az",MFnNumericData::kFloat); addAttribute(angleZ); numericAttrFn.setWritable(false); numericAttrFn.setStorable(false); //setting attribute affects attributeAffects(vector1,dotProductA); attributeAffects(vector2,dotProductA); attributeAffects(normalize,dotProductA); attributeAffects(vector1,dotProductMax); attributeAffects(vector2,dotProductMax); attributeAffects(normalize,dotProductMax); attributeAffects(vector1,proj1on2); attributeAffects(vector2,proj1on2); attributeAffects(vector1,proj2on1); attributeAffects(vector2,proj2on1); attributeAffects(vector1,angleInBetweenAttr); attributeAffects(vector2,angleInBetweenAttr); attributeAffects(vector1,angleX); attributeAffects(vector2,angleX); attributeAffects(vector1,angleY); attributeAffects(vector2,angleY); attributeAffects(vector1,angleZ); attributeAffects(vector2,angleZ); attributeAffects(projAxisXa,angleX); attributeAffects(projAxisXb,angleX); attributeAffects(projAxisXc,angleX); attributeAffects(projAxisYa,angleX); attributeAffects(projAxisYb,angleX); attributeAffects(projAxisYc,angleX); attributeAffects(projAxisZa,angleX); attributeAffects(projAxisZb,angleX); attributeAffects(projAxisZc,angleX); attributeAffects(projAxisXa,angleY); attributeAffects(projAxisXb,angleY); attributeAffects(projAxisXc,angleY); attributeAffects(projAxisYa,angleY); attributeAffects(projAxisYb,angleY); attributeAffects(projAxisYc,angleY); attributeAffects(projAxisZa,angleY); attributeAffects(projAxisZb,angleY); attributeAffects(projAxisZc,angleY); attributeAffects(projAxisXb,angleZ); attributeAffects(projAxisXc,angleZ); attributeAffects(projAxisYa,angleZ); attributeAffects(projAxisYb,angleZ); attributeAffects(projAxisYc,angleZ); attributeAffects(projAxisZa,angleZ); attributeAffects(projAxisZb,angleZ); attributeAffects(projAxisZc,angleZ); return MS::kSuccess; }