Exemplo n.º 1
0
def softSelectionClusterWeights(*args):

    sel = mc.ls(sl=True, o=True)

    if not sel:
        raise RuntimeError('Please select some vertices.')

    weights = getSoftSelectionWeights()

    if not weights:
        raise RuntimeError('Please select some vertices.')

    #get manipulator position for pivot
    mc.setToolTo('Move')
    moveMode = mc.manipMoveContext('Move', query=True, mode=True)
    mc.manipMoveContext('Move', edit=True, mode=0)
    position = mc.manipMoveContext('Move', query=True, position=True)
    mc.manipMoveContext('Move', edit=True, mode=moveMode)

    clusterNode, clusterHandle = mc.cluster(sel[0])

    for vert in mc.ls(sel[0]+'.vtx[*]', fl=True, l=True):
        weight = 0.0
        if vert in weights.keys():
            weight = weights[vert]
        mc.percent(clusterNode, vert, v=weight)

    #set cluster pivot
    mc.xform(clusterHandle, a=True, ws=True, piv=(position[0], position[1], position[2]))
    clusterShape = mc.listRelatives(clusterHandle, c=True, s=True)
    mc.setAttr(clusterShape[0] + '.origin', position[0], position[1], position[2])
Exemplo n.º 2
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def softModToCluster():
    softTransform = rig.ls(sl = True)[0]
    solftMod = rig.listConnections(softTransform,s = False,d = True,type = 'softMod')[0]
    modifModel = rig.listConnections(solftMod,s = False,d = True,type = 'mesh')
    
    if modifModel:
        origPos = rig.xform(softTransform,q = True,t = True,wd = True)
        
        for mesh in modifModel:
            prePos = []
            curPos = []
            weights = []
            vtxs = rig.ls(mesh+'.vtx[*]',fl = True)
            
            rig.xform(softTransform,t = (0,0,0),wd = True)
            for vtx in vtxs:
                pos = rig.xform(vtx,q = True,t = True,wd = True)
                prePos.append(pos)
                
            rig.xform(softTransform,t = (0,1,0),wd = True)
            for vtx in vtxs:
                pos = rig.xform(vtx,q = True,t = True,wd = True)
                curPos.append(pos)  
                
            weights = [math.pow(math.pow(pos[0]-curPos[i][0],2)+math.pow(pos[1]-curPos[i][1],2)+math.pow(pos[2]-curPos[i][2],2),0.5) for i,pos in enumerate(prePos)]
            rig.xform(softTransform,t = (0,0,0),wd = True)
            
            CLS = rig.cluster(mesh,n = mesh+'_CLS')
            for i,vtx in enumerate(vtxs):
                rig.percent(CLS[0],vtx,v = weights[i])
                
        rig.xform(softTransform,t = origPos,wd = True)
Exemplo n.º 3
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 def copy(self, mesh):
     self.cluster_list = []
     self.point_dict = {}
     self.cls_weight_dict = {}
         
     dummy = common.TemporaryReparent().main(mode='create')
     common.TemporaryReparent().main(mesh, dummyParent=dummy, mode='cut')
     
     cluster = cmds.ls(cmds.listHistory(mesh), type='cluster', l=True)
     for cls in cluster:
         set_node = cmds.ls(cmds.listHistory(cls, f=True), type='objectSet', l=True)[0]
         cmds.select(set_node)
         vertices = cmds.ls(sl=True)
         vertices = cmds.filterExpand(vertices, sm=31)
         cmds.select(vertices, r=True)
         try:
             weights = cmds.percent(cls, q=True, v=True)
             print weights
         #値が取れないときアンドゥするとなぜか直ることがある
         except Exception as e:
             print e.message
             cmds.delete(cls)
             cmds.undo()
             set_node = cmds.ls(cmds.listHistory(cls, f=True), type='objectSet', l=True)[0]
             vertices = cmds.ls(sl=True)
             vertices = cmds.filterExpand(vertices, sm=31)
             cmds.select(vertices, r=True)
             weights = cmds.percent(cls, q=True, v=True)
         self.cluster_list.append(cls)
         self.cls_weight_dict[cls] = weights
         self.point_dict[cls] = vertices
     common.TemporaryReparent().main(mesh, dummyParent=dummy, mode='parent')#コピーのおわったメッシュの子供を元に戻す
     common.TemporaryReparent().main(dummyParent=dummy, mode='delete')#ダミー親削除
     return self.point_dict, self.cls_weight_dict
Exemplo n.º 4
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def setWeights(mode, *args):
    """mode: "zero" to zero all weights or "selection" to apply weights to selection"""

#---------------- if current selection is a transform then do the whole thing by this mult value. . . . 

    deformers = cmds.textScrollList(widgets["defTSL"], q=True, selectItem=True)
    if mode == "selection":
        c, w = getWeights()
        if not c or not w:
            cmds.warning("zbw_deformerWeights(line 85): Couldn't get the components.")
            return()

        mult = cmds.floatFieldGrp(widgets["weightFFG"], q=True, v1=True)
        for d in deformers:
            for each in zip(c, w):
                cmds.percent(d, each[0], v=(each[1]*mult))

    if mode == "zero":
        t = cmds.textFieldGrp(widgets["objTFG"], q=True, tx=True)
        sel = []
        if rig.isType(t, "mesh"):
            sel = cmds.ls("{0}.vtx[*]".format(t), fl=True)
        elif rig.isType(t, "nurbsCurve") or rig.isType(t, "nurbsSurface"):
            sel = cmds.ls("{0}.cv[*]".format(t), fl=True)

        for d in deformers:
            if sel:
                for each in sel:
                    cmds.percent(d, each, v=0)
Exemplo n.º 5
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def softSelectionClusterWeights(*args):
    
    sel = mc.ls(sl=True, o=True)
    
    if not sel:
        raise RuntimeError('Please select some vertices.')

    weights = getSoftSelectionWeights()
    
    if not weights:
        raise RuntimeError('Please select some vertices.')
    
    #get manipulator position for pivot
    mc.setToolTo('Move')
    moveMode = mc.manipMoveContext('Move', query=True, mode=True)
    mc.manipMoveContext('Move', edit=True, mode=0)
    position = mc.manipMoveContext('Move', query=True, position=True)
    mc.manipMoveContext('Move', edit=True, mode=moveMode)

    clusterNode, clusterHandle = mc.cluster(sel[0])
    
    for vert in mc.ls(sel[0]+'.vtx[*]', fl=True, l=True):
        weight = 0.0
        if vert in weights.keys():
            weight = weights[vert]
        mc.percent(clusterNode, vert, v=weight)

    #set cluster pivot
    mc.xform(clusterHandle, a=True, ws=True, piv=(position[0], position[1], position[2]))
    clusterShape = mc.listRelatives(clusterHandle, c=True, s=True)
    mc.setAttr(clusterShape[0] + '.origin', position[0], position[1], position[2])    
Exemplo n.º 6
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def createCluster(selection_list):
    target_point_weight = {}
    for dag_path, point_weight_list in selection_list.items():
        _getConvertedData(dag_path, point_weight_list, target_point_weight)
    cmds.softSelect(e=True, sse=False)
    cmds.select(target_point_weight.keys())
    cluster_node = cmds.cluster()
    for point, weight in target_point_weight.items():
        cmds.percent(cluster_node[0], point, v=weight)
Exemplo n.º 7
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def createSoftCluster():
    softElementData = softSelection()
    selection = ["%s.vtx[%d]" % (el[0], el[1]) for el in softElementData]

    mc.select(selection, r=True)
    cluster = mc.cluster(relative=True)

    for i in range(len(softElementData)):
        mc.percent(cluster[0], selection[i], v=softElementData[i][2])
    mc.select(cluster[1], r=True)
Exemplo n.º 8
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def importDeformer(dagnode, j):

    if dagnode not in j:
        rigUtils.log('Dagnode not found in json file: %s' % dagnode)
        return

    # temporarily disable deleteComponent nodes
    for delComp in cmds.ls('deleteComponent*'):
        cmds.setAttr('%s.nodeState' % delComp, 1)

    skincluster = rigUtils.findSkinClusterOnNode(dagnode)
    dict = j[dagnode]

    for deformer in dict:

        if deformer == 'skinCluster': continue
        if not cmds.objExists(deformer): continue

        pointdata = dict[deformer]
        set = '%sSet' % deformer
        existingdeformers = mel.eval('findRelatedDeformer "%s"' % dagnode)

        # ffd
        if cmds.objectType(deformer, isType='ffd'):
            i = 0
            while(True):
                if i == len(pointdata): break
                if pointdata[i] == '1' and cmds.objExists(set):
                    cmds.sets('%s.vtx[%s]' % (dagnode, i), add=set)
                i = i + 1
            
            if skincluster: cmds.reorderDeformers(skincluster,deformer,dagnode)
                
            continue

        # all other deformers
        if not deformer in existingdeformers:
            if cmds.objExists(set): cmds.sets(dagnode, add=set)

        i = 0
        while(True):
            if i == len(pointdata): break
            value = pointdata[i]
            cmds.percent(deformer, '%s.vtx[%s]' % (dagnode, i), v=float(value))
            i = i + 1

        if skincluster: cmds.reorderDeformers(skincluster, deformer, dagnode)

        rigUtils.log('Deformer weighting updated: %s' % deformer)

    # turn deleteComponent nodes back on
    for delComp in cmds.ls('deleteComponent*'):
        cmds.setAttr('%s.nodeState' % delComp, 0)
Exemplo n.º 9
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 def paste(self, mesh):
     if not self.cluster_list:
         return
     for cls in self.cluster_list:
         weights = self.cls_weight_dict[cls]
         print 'paste cls :', cls
         cmds.select(cl=True)
         points = self.point_dict[cls]
         newcls = cmds.cluster(points, n=cls)
         for i, v in enumerate(points):
             cmds.percent(newcls[0], v, v=(weights[i]))
     return newcls
Exemplo n.º 10
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def deformerMirror(node, handle_list, axis, search, replace):

    if not isinstance(handle_list, (list, tuple, set)):
        handle_list = [handle_list]

    with OptimiseContext():
        for handle in handle_list:
            if not mc.listRelatives(handle, shapes=True, type='clusterHandle'):
                log.warning('Current version only supports Cluster deformers.')
                continue

            shapes = mc.listRelatives(node, shapes=True)
            current_data = get_deformer_info_by_node(node, handle)

            closest_point_node = mc.createNode('closestPointOnMesh')
            for data in current_data:
                point_pos = mc.pointPosition(data[0], local=True)
                inv_pos = point_pos
                inv_pos[axis] *= -1
                mc.setAttr(node + '.inPosition', *inv_pos)
                mc.connectAttr(shapes[0] + '.outMesh',
                               closest_point_node + '.inMesh',
                               force=True)
                closest_index = mc.getAttr(closest_point_node +
                                           '.closestVertexIndex')
                data[0] = node + '.vtx[{}]'.format(closest_index)

            mc.delete(closest_point_node)

            amount = len(current_data)
            new_points = [current_data[x][0] for x in range(amount)]
            deformer = mc.listConnections(handle + '.worldMatrix[0]',
                                          type='cluster',
                                          d=True)
            new_cluster = mc.cluster(new_points,
                                     rel=mc.getAttr(deformer + '.relative'))
            for x in range(amount):
                mc.percent(new_cluster[0],
                           current_data[x][0],
                           v=current_data[x][1])

            # Mirror deformer pivot
            a_pos = mc.xform(node, q=True, ws=True, rp=True)
            pos = b_pos = mc.xform(handle, q=True, ws=True, rp=True)
            pos[axis - 1] = b_pos[axis - 1] - (
                (b_pos[axis - 1] - a_pos[axis - 1]) * 2)
            mc.xform(new_cluster[1],
                     a=True,
                     ws=True,
                     piv=(pos[0], pos[1], pos[2]))
            mc.setAttr(new_cluster[0] + '.origin', pos[0], pos[1], pos[2])
            mc.rename(new_cluster[1], handle.replace(search, replace))
Exemplo n.º 11
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def use_weight_set():
    cmds.select(cmds.cluster(cmds.textScrollList('UI_cluster_list', q=True, si=True)[0], q=True, g=True)[0])
    mel.eval("ConvertSelectionToVertices;")
    weights = cmds.percent (cmds.textScrollList('UI_cluster_list', q=True, si=True)[0], q=True, v=True)
    cmds.filterExpand( ex=True, sm=31 )
    elements = cmds.ls(sl=True, fl=True)
    return elements, weights
Exemplo n.º 12
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def get_cluster_verticies_on_mesh(mesh_transform, cluster_handle):
    cluster_deformer_node = cmds.listConnections(
        (cluster_handle + ".worldMatrix[0]"), type="cluster", destination=1)
    cluster_set = cmds.listConnections(cluster_deformer_node[0],
                                       type="objectSet")
    extracted_verts = cmds.sets(cluster_set[0], q=1)

    # 28: Control Vertices (CVs)
    # 31: Polygon Vertices
    # 36: Subdivision Mesh Points
    # 46: Lattice Points
    extracted_verts = cmds.filterExpand(
        extracted_verts, selectionMask=(28, 31, 36, 46))  # Filter Points Only

    # Isolate vertices on mesh
    verticies_on_mesh = []
    for vertex in extracted_verts:
        name = vertex.encode('utf-8')
        if name.startswith(mesh_transform):
            verticies_on_mesh.append(vertex)

    # Pair Verticies with their weights
    verticies_with_weights = []
    for vertex in verticies_on_mesh:
        vertex_weight_pair = [vertex]
        valueW = cmds.percent(cluster_deformer_node[0], vertex, q=1, v=1)
        vertex_weight_pair.append(valueW[0])
        verticies_with_weights.append(vertex_weight_pair)

    return verticies_with_weights
Exemplo n.º 13
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    def createClusterDeformers(self):
        # Create clusters on the top, middle, and bottom of our wire deformer curve.
        topCluster = cmds.cluster("%s.cv[1:2]" % self.wireDeformerCurve,
                                  name="%s_TOP_CLS" % self.name,
                                  relative=True)
        midCluster = cmds.cluster("%s.cv[1]" % self.wireDeformerCurve,
                                  name="%s_MID_CLS" % self.name,
                                  relative=True)
        bottomCluster = cmds.cluster("%s.cv[0:1]" % self.wireDeformerCurve,
                                     name="%s_BOT_CLS" % self.name,
                                     relative=True)
        clusters = [topCluster, midCluster, bottomCluster]

        # Shift the pivots to the controls on the base plane.
        cmds.setAttr("%sShape.originY" % str(topCluster[1]),
                     (self.distance / 2) * -1)
        cmds.setAttr("%sShape.originY" % str(bottomCluster[1]),
                     (self.distance / 2))
        cmds.move(0, (self.distance / 2) * -1, 0,
                  "%s.rotatePivot" % str(topCluster[1]),
                  "%s.scalePivot" % str(topCluster[1]))
        cmds.move(0, 0, 0, "%s.rotatePivot" % str(midCluster[1]),
                  "%s.scalePivot" % str(midCluster[1]))
        cmds.move(self.distance / 2, 0, 0,
                  "%s.rotatePivot" % str(bottomCluster[1]),
                  "%s.scalePivot" % str(bottomCluster[1]))

        # Adjust the weight towards the end points.
        cmds.percent(topCluster[0],
                     "%s.cv[1]" % self.wireDeformerCurve,
                     value=0.5)
        cmds.percent(bottomCluster[0],
                     "%s.cv[1]" % self.wireDeformerCurve,
                     value=0.5)

        # Group the clusters and connect them to their respective controls.
        group = cmds.group(name="%s_CLS_GRP" % self.name, empty=True)
        for index in range(len(clusters)):
            cmds.connectAttr("%s.translate" % str(self.controlCurves[index]),
                             "%s.translate" % str(clusters[index][1]))
            self.parentObject(clusters[index][1], group)
        self.parentObject(group, self.noMoveGroup)
        self.hideObject(group)
        return clusters
Exemplo n.º 14
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def TransWeightToCluster():
    ModelName = mc.textField('ClusterModelFLD', q=True, tx=True)
    SkinModel = mc.textField('SkinModelFLD', q=True, tx=True)
    ClusterName =  mc.textField('ClusterNameFLD', q=True, tx=True)
    JointName =  mc.textField('JointNameFLD', q=True, tx=True)
    #- get the cluster Node Name..
    if mc.nodeType(ClusterName) == 'transform':
        ClusterName = mc.listConnections(ClusterName, t='cluster')[0]
    else:
        pass

    #- get SkinNode Name
    SkinClusterNode = mel.eval('findRelatedSkinCluster ' + SkinModel)

    #- set Value
    ModelVts = mc.polyEvaluate(SkinModel, v=True)
    JointID = mc.skinCluster(SkinClusterNode, q=True, inf=True).index(JointName)
    for i in range(ModelVts):
        SkinWeight = mc.skinPercent(SkinClusterNode, '%s.vtx[%s]'%(SkinModel, i), q=True, v=True)[JointID]
        mc.percent(ClusterName, '%s.vtx[%s]'%(ModelName, i), v=SkinWeight)
Exemplo n.º 15
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    def Transfer(self):
        sel = cmds.ls(sl=True)

        curves = []
        joints = []
        wires = []
        obj = None

        for obj in sel:
            if cmds.nodeType(cmds.listRelatives(obj,
                                                shapes=True)) == 'nurbsCurve':
                curves.append(obj)
            elif cmds.joint(obj, exists=obj):
                joints.append(obj)
            else:
                obj = obj

        if obj is not None:
            verts = cmds.ls(obj + '.vtx[0: ]', fl=True)
            clusters = cmds.listConnections(cmds.listRelatives(object,
                                                               shapes=True)[0],
                                            t='skinCluster')[0]

            i = 1
            for curve in curves:
                wires.append(cmds.wire(object, dds=[i, 999999999], w=curve)[0])

            i = 0
            for jnt in joints:
                for vert in verts:
                    skinWeight = cmds.skinPercent(clusters,
                                                  vert,
                                                  transform=jnt,
                                                  q=True,
                                                  value=True)
                    cmds.percent(wires[i], vert, v=skinWeight)
                i += 1

        else:
            cmds.warning('Tool requires an object to be selected')
Exemplo n.º 16
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def createSoftCluster(excludeObjs=None, supportTypes=None):
    # determind select objects
    initSel = cmd.ls(sl=1, ap=1, st=1)
    firstSelObj, firstSelType = initSel[0], initSel[1]

    if firstSelType == 'transform':
        object = firstSelObj
    elif firstSelType in ['float3', 'double3']:
        object = cmd.listRelatives(cmd.listRelatives(p=True, f=1), p=True,
                                   f=1)[0]
    else:
        cmd.error('Selected objects Unsupported!')
        return

    # query manipulator's position
    cmd.setToolTo('Move')
    currentMoveMode = cmd.manipMoveContext('Move', q=True, m=True)
    cmd.manipMoveContext('Move', e=True, m=0)
    position = cmd.manipMoveContext('Move', q=True, p=True)
    cmd.manipMoveContext('Move', e=True, m=currentMoveMode)

    # query influenced elements and correspond weights
    elements = cmd.softSelectionQuery(cmp=1, exo=excludeObjs, t=supportTypes)
    weights = cmd.softSelectionQuery(w=1, exo=excludeObjs, t=supportTypes)

    # create cluster with elements and set weights
    try:
        clusterNode, clusterHandle = cmd.cluster(elements,
                                                 n='%s_softCluster' %
                                                 object.split('|')[-1])
    except:
        cmd.error('Selected objects Unsupported!')
        return

    for i in xrange(len(elements)):
        cmd.percent(clusterNode, elements[i], v=weights[i])

    repositionCluster(clusterHandle, position)

    return clusterNode, clusterHandle
Exemplo n.º 17
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def softCluster():
    selectionVrts = cmds.ls(selection=True, flatten=True)
    if selectionVrts:
        posVtx = _getAverage(selectionVrts)
        cmds.softSelect(sse=True)
        softElementData = _softSelection()
        selection = ["%s.vtx[%d]" % (el[0], el[1]) for el in softElementData]
        model = selectionVrts[0].split('.')[0]
        cmds.select(model, r=True)
        cluster = cmds.cluster(name='%s_cls' % model,
                               relative=False,
                               bindState=True)
        clusterGrp = cmds.createNode('transform', name='%s_grp' % cluster[1])
        cmds.xform(cluster,
                   rotatePivot=posVtx,
                   scalePivot=posVtx,
                   objectSpace=True)
        cmds.xform(clusterGrp,
                   rotatePivot=posVtx,
                   scalePivot=posVtx,
                   objectSpace=True)
        cmds.parent(cluster[1], clusterGrp)
        cmds.connectAttr('%s.worldInverseMatrix' % clusterGrp,
                         '%s.bindPreMatrix' % cluster[0])
        weight = [0.0]
        zero = 0.0
        VertexNb = cmds.polyEvaluate(model, v=1) - 1
        for x in range(VertexNb):
            weight.append(zero)
        cmds.setAttr('{0}.weightList[0].weights[0:{1}]'.format(
            cluster[0], VertexNb),
                     *weight,
                     size=len(weight))
        shape = cmds.listRelatives(cluster[1], shapes=True)[0]
        cmds.setAttr('%s.originX' % shape, posVtx[0])
        cmds.setAttr('%s.originY' % shape, posVtx[1])
        cmds.setAttr('%s.originZ' % shape, posVtx[2])
        for i in range(len(softElementData)):
            cmds.percent(cluster[0], selection[i], v=softElementData[i][2])
        cmds.select(cluster[1], r=True)
def deformerMirror(object, deformerHandle, axis, search, replace):
    if not mc.objectType(mc.listRelatives(deformerHandle, c=1, s=1)[0],
                         isType='clusterHandle'):
        mc.warning('Current version only supports cluster deformers')
        return
    shapes = mc.listRelatives(object, s=1, c=1)
    oldList = filterDeformer(object, deformerHandle)
    for pair in oldList:
        pointPos = mc.pointPosition(pair[0], l=1)
        node = mc.createNode('closestPointOnMesh')
        mc.setAttr(('%s.inPosition' % node), *invertValue(pointPos, axis))
        try:
            mc.connectAttr('%s.outMesh' % shapes[0], '%s.inMesh' % node, f=1)
        except:
            pass
        else:
            pair[0] = '%s.vtx[%s]' % (
                object, mc.getAttr('%s.closestVertexIndex' % node))
            mc.delete(node)

    amount = len(oldList)
    newPoints = [oldList[x][0] for x in range(amount)]
    clusDeformer = mc.listConnections('%s.worldMatrix[0]' % deformerHandle,
                                      type='cluster',
                                      d=1)
    newClus = mc.cluster(newPoints,
                         rel=mc.getAttr('%s.relative' % clusDeformer[0]))
    for x in range(amount):
        mc.percent(newClus[0], oldList[x][0], v=oldList[x][1])

    aPos = mc.xform(object, q=1, ws=1, rp=1)
    pos = bPos = mc.xform(deformerHandle, q=1, ws=1, rp=1)
    pos[axis -
        1] = bPos[(axis - 1)] - (bPos[(axis - 1)] - aPos[(axis - 1)]) * 2
    mc.xform(newClus, a=1, ws=1, piv=(pos[0], pos[1], pos[2]))
    mc.setAttr(
        mc.listRelatives(newClus, c=1, s=1)[0] + '.origin', pos[0], pos[1],
        pos[2])
    mc.rename(newClus[1], deformerHandle.replace(search, replace))
Exemplo n.º 19
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def __copyClusterWeight(*args):
    srcCluName,srcShape = cmds.button(widgets["bt_srcCluster"],q=True,l=True).split(" ")
    dstCluName,dstShape = cmds.button(widgets["bt_dstCluster"],q=True,l=True).split(" ")

    srcCluName = srcCluName.split(":")[-1][:-1]
    srcShape = srcShape.split(":")[-1][:-1]

    dstCluName = dstCluName.split(":")[-1][:-1]
    dstShape = dstShape.split(":")[-1][:-1]
        
    wd = __getBarycentricCoordsWeights(srcShape,dstShape)

    mult = cmds.floatField(widgets["ff_mult"],q=True,v=True)
    
    for i,j in zip(wd["srcVtxs"],wd["tgtVtxs"]):
        v1 = cmds.percent(srcCluName,i[0][0],q=True,v=True)[0] * i[1][0]
        v2 = cmds.percent(srcCluName,i[0][1],q=True,v=True)[0] * i[1][1]
        v3 = cmds.percent(srcCluName,i[0][2],q=True,v=True)[0] * i[1][2]
        cVal =  (v1 + v2 + v3) * mult
        cmds.percent(dstCluName,j,v=cVal)
    om.MGlobal.displayInfo("Done!")
    __buttonInit()
Exemplo n.º 20
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def create_soft_cluster():
    """
    Create a Cluster deformer using the current soft selection.

    :return: New cluster deformer.
    :rtype: str
    """
    elements, weights = _get_soft_selection()

    # Get the average position from the move manipulator
    mc.setToolTo('Move')
    current_mode = mc.manipMoveContext('Move', q=True, m=True)
    mc.manipMoveContext('Move', e=True, m=0)
    position = mc.manipMoveContext('Move', q=True, p=True)
    mc.manipMoveContext('Move', e=True, m=current_mode)

    obj = mc.listRelatives(mc.listRelatives(parent=True), parent=True)
    new_cluster = mc.cluster(elements, n=obj[0] + '_softCluster')
    for i in range(len(elements)):
        mc.percent(new_cluster[0], elements[i], v=weights[i])

    _reposition_cluster_deformer(new_cluster[1], position)
Exemplo n.º 21
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def create_cluster():
    cluster_name = cmds.textField('UI_cluster_clusterPrefix', q=True, tx=True) + cmds.textField('UI_cluster_clusterName', q=True, tx=True)
    cluster_name = cluster_name.replace (" ", "_")
    
# cluster soft selections
    # Use Weight Set Override
    if cmds.checkBox('UI_useWeights_CheckBox', q=True, value=True) is True:
        elements, weights = use_weight_set()
    else:
        elements, weights = softSelection()
        cmds.softSelect( sse=0)
        mel.eval("polyConvertToShell;")
    vertex_count = cmds.ls(sl=True, fl=True)


    if cmds.objExists("loc_guide_deformer") is True:
        parent_cluster(cluster_name)
    else:
        cmds.cluster (name = cluster_name, bs = True)
    for vertex in vertex_count:
        cmds.percent (cluster_name, vertex, value = 0)
    for x in range(len(elements)):
        cmds.percent (cluster_name, elements[x], value = weights[x])
def getInfoDeformer(deformerHandle):
    results = []
    cDeformer = mc.listConnections(deformerHandle + '.worldMatrix[0]',
                                   type='cluster',
                                   d=1)
    cSet = mc.listConnections(cDeformer[0], type='objectSet')
    components = mc.filterExpand(mc.sets(cSet[0], q=1), sm=(28, 31, 36, 46))
    for vertex in components:
        vert = [vertex]
        vertWeight = mc.percent(cDeformer[0], vertex, q=1, v=1)
        vert.append(vertWeight[0])
        results.append(vert)

    return results
def TransWeightToCluster():
    ModelName = mc.textField('ClusterModelFLD', q=True, tx=True)
    SkinModel = mc.textField('SkinModelFLD', q=True, tx=True)
    ClusterName = mc.textField('ClusterNameFLD', q=True, tx=True)
    JointName = mc.textField('JointNameFLD', q=True, tx=True)
    #- get the cluster Node Name..
    if mc.nodeType(ClusterName) == 'transform':
        ClusterName = mc.listConnections(ClusterName, t='cluster')[0]
    else:
        pass

    #- get SkinNode Name
    SkinClusterNode = mel.eval('findRelatedSkinCluster ' + SkinModel)

    #- set Value
    ModelVts = mc.polyEvaluate(SkinModel, v=True)
    JointID = mc.skinCluster(SkinClusterNode, q=True,
                             inf=True).index(JointName)
    for i in range(ModelVts):
        SkinWeight = mc.skinPercent(SkinClusterNode,
                                    '%s.vtx[%s]' % (SkinModel, i),
                                    q=True,
                                    v=True)[JointID]
        mc.percent(ClusterName, '%s.vtx[%s]' % (ModelName, i), v=SkinWeight)
Exemplo n.º 24
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    def setWeight(self, *a):
        fc = cmds.radioCollection('rc_awwFc', q=1, select=1)
        et = cmds.radioCollection('rc_awwEt', q=1, select=1)
        sv = cmds.floatSliderGrp('fs_awwA', q=1, value=1)
        ev = cmds.floatSliderGrp('fs_awwB', q=1, value=1)

        sl = cmds.ls(selection=1, long=1)
        sls = cmds.ls(selection=1)
        selList = []
        for i, x in enumerate(sl):
            sn = sls[i]
            sp = cmds.listRelatives(x, shapes=1)[0]
            w = cmds.listConnections(sp, type='wire')[0]
            if w is not None:
                sd = cmds.getAttr(x + '.spans') + cmds.getAttr(x + '.degree')
                for j in range(sd):
                    r = float(j) / float(sd - 1)
                    wt = mel.eval('linstep(' + str(sv) + ',' + str(ev) + ',' +
                                  str(r) + ')')
                    if fc == 'rb_awwSc':
                        wt = mel.eval('smoothstep(' + str(sv) + ',' + str(ev) +
                                      ',' + str(r) + ')')
                    print wt
                    cmds.percent(w, x + '.cv[' + str(j) + ']', v=wt)
def TransWeightToJoint():

    ModelName = mc.textField('ClusterModelFLD', q=True, tx=True)
    SkinModel = mc.textField('SkinModelFLD', q=True, tx=True)
    ClusterName = mc.textField('ClusterNameFLD', q=True, tx=True)
    JointName = mc.textField('JointNameFLD', q=True, tx=True)
    #- get the cluster Node Name..
    if mc.nodeType(ClusterName) == 'transform':
        ClusterName = mc.listConnections(ClusterName, t='cluster')[0]
    else:
        pass

    #- get the Model Id and connect groupparts
    ModeID = mc.listRelatives(mc.cluster(ClusterName, q=True, g=True),
                              p=True).index(ModelName)
    GroupParts = mc.connectionInfo(ClusterName +
                                   '.input[%d].inputGeometry' % ModeID,
                                   sfd=True).split('.')[0]

    #- get Inflution Vts
    Points = [
        '%s.%s' % (ModelName, Vtx)
        for Vtx in mc.getAttr(GroupParts + '.inputComponents')
    ]

    #- get Cluster Value
    WeightDT = {}
    for VVtx in mc.ls(Points, fl=True):
        VtxID = re.search('(?<=\[)\d+(?=\])', VVtx).group()
        WeightValue = mc.percent(ClusterName, VVtx, q=True, v=True)
        WeightDT[VtxID] = WeightValue[0]

    #- get SkinNode Name
    SkinClusterNode = mel.eval('findRelatedSkinCluster ' + SkinModel)

    #- Remove Joint weights
    ModelVts = mc.polyEvaluate(SkinModel, v=True)
    mc.skinPercent(SkinClusterNode,
                   '%s.vtx[0:%s]' % (SkinModel, ModelVts),
                   tv=(JointName, 0))

    #- set Weight Value
    for VtxID, WeightV in WeightDT.iteritems():
        mc.skinPercent(SkinClusterNode,
                       '%s.vtx[%s]' % (SkinModel, VtxID),
                       tv=(JointName, WeightV))
Exemplo n.º 26
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def get_deformer_info(handle):
    """
    Return the vertices and weights for the deformer.

    :param handle: Deformer handle object.
    :type handle: str

    :return: list(list(str, float))
    """
    deformer = mc.listConnections(handle + '.worldMatrix[0]',
                                  type='cluster',
                                  d=True)[0]
    obj_set = mc.listConnections(deformer, type='objectSet')[0]
    components = mc.filterExpand(mc.sets(obj_set, q=True), sm=(28, 31, 36, 46))
    results = [[vertex,
                mc.percent(deformer, vertex, q=True, v=True)[0]]
               for vertex in components]
    return results
Exemplo n.º 27
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def TransWeightToJoint():

    ModelName = mc.textField('ClusterModelFLD', q=True, tx=True)
    SkinModel = mc.textField('SkinModelFLD', q=True, tx=True)
    ClusterName =  mc.textField('ClusterNameFLD', q=True, tx=True)
    JointName =  mc.textField('JointNameFLD', q=True, tx=True)
    #- get the cluster Node Name..
    if mc.nodeType(ClusterName) == 'transform':
        ClusterName = mc.listConnections(ClusterName, t='cluster')[0]
    else:
        pass

    #- get the Model Id and connect groupparts
    ModeID = mc.listRelatives(mc.cluster(ClusterName, q=True, g=True), p=True).index(ModelName)
    GroupParts = mc.connectionInfo(ClusterName + '.input[%d].inputGeometry'%ModeID, sfd=True).split('.')[0]


    #- get Inflution Vts
    Points = ['%s.%s'%(ModelName,Vtx)  for Vtx in mc.getAttr(GroupParts + '.inputComponents')]


    #- get Cluster Value
    WeightDT = {}
    for VVtx in mc.ls(Points, fl=True):
        VtxID = re.search('(?<=\[)\d+(?=\])', VVtx).group()
        WeightValue = mc.percent(ClusterName, VVtx,  q=True, v=True)
        WeightDT[VtxID] = WeightValue[0]

    #- get SkinNode Name
    SkinClusterNode = mel.eval('findRelatedSkinCluster ' + SkinModel)


    #- Remove Joint weights
    ModelVts = mc.polyEvaluate(SkinModel, v=True)
    mc.skinPercent(SkinClusterNode, '%s.vtx[0:%s]'%(SkinModel, ModelVts), tv=(JointName, 0))

    #- set Weight Value
    for VtxID, WeightV in WeightDT.iteritems():
        mc.skinPercent(SkinClusterNode, '%s.vtx[%s]'%(SkinModel, VtxID), tv=(JointName, WeightV))
Exemplo n.º 28
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def ss_deformerWeight(*args):
    #args: deformer name
    #method
    deformedGeometryNode = cmds.listRelatives(cmds.ls(selection=True),
                                              parent=True)[0]
    deformer = str(args[0])
    method = args[1]
    elements, weights = softSelection()
    for e in range(len(elements)):
        if method == 0:
            cmds.percent(deformer,
                         deformedGeometryNode + '.vtx[{}]'.format(elements[e]),
                         addPercent=weights[e])
        elif method == 1:
            cmds.percent(deformer,
                         deformedGeometryNode + '.vtx[{}]'.format(elements[e]),
                         multiplyPercent=weights[e])
        elif method == 2:
            cmds.percent(deformer,
                         deformedGeometryNode + '.vtx[{}]'.format(elements[e]),
                         value=weights[e])
Exemplo n.º 29
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    def cluster(self,
                 character = None,
                 mod = None,
                 side = None,
                 name = None,
                 suffix = None,
                 geometry = None,
                 origin = [0,0,0],
                 weightObj = None,
                 weightValue = 1,
                 parent = None,
                 show = True,
                 lockAttr = None,
                 ihi = True):
        #--- this method creates a cluster deformer
        #--- select the specified geometry
        cmds.select(geometry)        
        #--- create a cluster deformer
        node = cmds.cluster()
        filter_name = (name + node[0].split('Handle')[0][0].upper() +
                       node[0].split('Handle')[0][1:])
        #--- rename the cluster deformer
        node = self.__rename_node(mod = mod,
                                  side = side,
                                  name = filter_name,
                                  suffix = suffix,
                                  obj = node)
        #--- get the cluster deform node
        node.append(cmds.listConnections(node[0])[0])
        #--- create a group on top and parent the deformer under the group
        node_grp = cmds.createNode('transform')
        cmds.parent(node[0], node_grp)
        #--- rename the node group
        node_grp = self.__rename_node(mod = mod,
                                      side = side,
                                      name = filter_name,
                                      suffix = 'GRP',
                                      obj = node_grp)[0]        
        #--- take care of the node's settings
        #--- origin
        ori_x= cmds.getAttr(node[1] + '.originX')
        ori_y= cmds.getAttr(node[1] + '.originY')
        ori_z= cmds.getAttr(node[1] + '.originZ')
        new_origin = [ori_x + origin[0], ori_y + origin[1], ori_z + origin[2]]
        cmds.setAttr(node[1] + '.origin', 
                     new_origin[0], 
                     new_origin[1], 
                     new_origin[2])
        cmds.xform(node[0], pivots = new_origin, worldSpace = True)
        #--- reposition the pivot of the group to the location of the cluster
        cmds.xform(node_grp, pivots = new_origin, worldSpace = True)        
        #--- weightValue
        if weightObj:
            if isinstance(weightObj, list):
                if isinstance(weightValue, list):
                    for obj, val in zip(weightObj, weightValue):
                        cmds.percent(node[-1], obj, value = val)
                else:
                    for obj in weightObj:
                        cmds.percent(node[-1], obj, value = weightValue)
            else:
                cmds.percent(node[-1], weightObj, value = weightValue)

        #--- parent the group under the specified parent
        if parent:
            if not isinstance(parent, list):
                cmds.parent(node_grp, parent)
            else:
                raise Exception("Specified parent: " + 
                                parent + 'is not a valid')
        #--- show or hide transform
        if not show:
            if isinstance(target, list):
                for t in target:
                    cmds.setAttr(t + '.v', 0)
            else:
                cmds.setAttr(target + '.v', 0)
        #--- lock specified attributes
        if lockAttr:
            if node:
                cmds.setAttr(node + '.' + lockAttr, lock = True)
        #--- set isHistoricalInteresting attribute
        if not ihi:
            cmds.setAttr(node + '.ihi', 0)
        #--- return node
        return node
Exemplo n.º 30
0
    def buildDeformers(self, ribbonPlane, controls=(), folGrp=()):
        # Create a target blendshape controlled by deformers
        flexiBlend = cmds.duplicate(ribbonPlane, n='flexiPlaneSetup_bShp_surface01')
        flexiBlendNode = cmds.blendShape(flexiBlend, ribbonPlane, n='%s_bShpNode_surface01' % self.name)

        # Turn blendshape on
        cmds.setAttr('%s.%s' % (flexiBlendNode[0], flexiBlend[0]), 1)

        # Create a wire deformer controled by ribbon controls
        wireCurve = cmds.curve(
            n='%s_wire_surface01' % self.name, d=2, p=[(-self.numJnts, 0, 0), (0, 0, 0), (self.numJnts, 0, 0)])
        topClstr = cmds.cluster('%s.cv[0:1]' % wireCurve, rel=1, n='%s_cl_a01' % self.name)
        midClstr = cmds.cluster('%s.cv[1]' % wireCurve, rel=1, n='%s_cl_mid01' % self.name)
        botClstr = cmds.cluster('%s.cv[1:2]' % wireCurve, rel=1, n='%s_cl_b01' % self.name)
        clsGrp = cmds.group(topClstr, midClstr, botClstr, n='%s_cls01' % self.name)

        for attr in ['scalePivot', 'rotatePivot']:
            cmds.setAttr('%s.%s' % (topClstr[1], attr), -self.numJnts, 0, 0)
        for attr in ['scalePivot', 'rotatePivot']:
            cmds.setAttr('%s.%s' % (botClstr[1], attr), self.numJnts, 0, 0)

        cmds.setAttr('%sShape.originX' % topClstr[1], (-self.numJnts))
        cmds.setAttr('%sShape.originX' % botClstr[1], (self.numJnts))
        cmds.percent(topClstr[0], '%s.cv[1]' % wireCurve, v=0.5)
        cmds.percent(botClstr[0], '%s.cv[1]' % wireCurve, v=0.5)

        # Create twist and wire blend shape deformers
        twistNode = cmds.nonLinear(flexiBlend, type='twist')
        cmds.wire(flexiBlend, w=wireCurve, dds=[0, 20], foc=0, n='%s_wireAttrs_surface01' % self.name)
        cmds.xform(twistNode, ro=(0, 0, 90))
        twistNode[0] = cmds.rename(twistNode[0], '%s_twistAttrs_surface01' % self.name)
        twistNode[1] = cmds.rename(twistNode[1], '%s_twist_surface01' % self.name)

        # Setup squash and stretch via utilitiy nodes
        arcLen = cmds.arclen(wireCurve, ch=1)
        arcLen = cmds.rename(arcLen, '%s_curveInfo01' % self.name)
        arcLenValue = cmds.getAttr('%s.arcLength' % arcLen)
        squashDivNode = cmds.createNode('multiplyDivide', n='%s_div_squashStretch_length01' % self.name)
        volDivNode = cmds.createNode('multiplyDivide', n='%s_div_volume01' % self.name)
        squashCondNode = cmds.createNode('condition', n='%s_cond_volume01' % self.name)

        cmds.setAttr('%s.operation' % squashDivNode, 2)
        cmds.setAttr('%s.input2X' % squashDivNode, arcLenValue)
        cmds.setAttr('%s.operation' % volDivNode, 2)
        cmds.setAttr('%s.input1X' % volDivNode, 1)
        cmds.setAttr('%s.secondTerm' % squashCondNode, 1)

        cmds.connectAttr('%s.arcLength' % arcLen, '%s.input1X' % squashDivNode)
        cmds.connectAttr('%s.outputX' % squashDivNode, '%s.input2X' % volDivNode)
        cmds.connectAttr('%s.outputX' % volDivNode, '%s.colorIfTrueR' % squashCondNode)

        # Set visibility options
        for obj in [flexiBlend[0], wireCurve, twistNode[1], clsGrp]:
            cmds.setAttr('%s.visibility' % obj, 0)

        # Connect controls to cluster deformers if they exist
        if len(controls) > 1:
            topCon = controls[0][0]
            botCon = controls[0][1]
            midCon = controls[0][2]

            for con, clstr in zip([topCon, botCon], [topClstr[1], botClstr[1]]):
                cmds.connectAttr('%s.translate' % con, '%s.translate' % clstr)

            cmds.connectAttr('%s.translate' % midCon, '%s.translate' % midClstr[1])

            # Connect controls to twist deformer
            cmds.connectAttr('%s.rotateX' % topCon, '%s.endAngle' % twistNode[0])
            cmds.connectAttr('%s.rotateX' % botCon, '%s.startAngle' % twistNode[0])
            cmds.connectAttr('%s.volEnable' % controls[1], '%s.firstTerm' % squashCondNode)

        # Scale contraint each follicle to global move group
        for fol in cmds.listRelatives(folGrp, c=1):
            cmds.scaleConstraint(self.moveGrp, fol, mo=0)
            for shape in cmds.listRelatives(fol, s=1):
                cmds.setAttr('%s.visibility' % shape, 0)

        # Parent nodes
        cmds.parent(flexiBlend, wireCurve, clsGrp, twistNode[1],
                    '%s_wire_surface01BaseWire' % self.name, self.extrasGrp)
Exemplo n.º 31
0
def createRibbon(*args):
    #Gather information
    width = cmds.floatField('widthField', query=True, value=True)
    numJoints = cmds.intField('jointsField', query=True, value=True)
    prefix = cmds.textField('prefixField', query=True, text=True)
    scaleGrp = cmds.textField('scaleGrpField', query=True, text=True)
    topPoint = (width / 2)
    endPoint = (width / 2 * -1)

    #Create the main groups
    grpNoTransform = cmds.group(empty=True, name=(prefix + 'noTransform_grp'))
    grpTransform = cmds.group(empty=True, name=(prefix + 'transform_grp'))
    grpCtrl = cmds.group(empty=True,
                         name=(prefix + 'ctrl_grp'),
                         parent=grpTransform)
    grpSurface = cmds.group(empty=True,
                            name=(prefix + 'surface_grp'),
                            parent=grpTransform)
    grpSurfaces = cmds.group(empty=True,
                             name=(prefix + 'surfaces_grp'),
                             parent=grpNoTransform)
    grpDeformers = cmds.group(empty=True,
                              name=(prefix + 'deformer_grp'),
                              parent=grpNoTransform)
    grpFollMain = cmds.group(empty=True,
                             name=(prefix + 'follicles_skin_grp'),
                             parent=grpNoTransform)
    grpFollVolume = cmds.group(empty=True,
                               name=(prefix + 'follicles_volume_grp'),
                               parent=grpNoTransform)
    grpCluster = cmds.group(empty=True,
                            name=(prefix + 'cluster_grp'),
                            parent=grpNoTransform)
    grpMisc = cmds.group(empty=True,
                         name=(prefix + 'misc_grp'),
                         parent=grpNoTransform)

    #Create a NURBS-plane to use as a base
    tmpPlane = cmds.nurbsPlane(axis=(0, 1, 0),
                               width=width,
                               lengthRatio=(1.0 / width),
                               u=numJoints,
                               v=1,
                               degree=3,
                               ch=0)[0]
    #Create the NURBS-planes to use in the setup
    geoPlane = cmds.duplicate(tmpPlane, name=(prefix + 'geo'))
    geoPlaneTwist = cmds.duplicate(tmpPlane, name=(prefix + 'twist_blnd_geo'))
    geoPlaneSine = cmds.duplicate(tmpPlane, name=(prefix + 'sine_blnd_geo'))
    geoPlaneWire = cmds.duplicate(tmpPlane, name=(prefix + 'wire_blnd_geo'))
    geoPlaneVolume = cmds.duplicate(tmpPlane, name=(prefix + 'volume_geo'))
    #Offset the volume-plane
    cmds.setAttr((geoPlaneVolume[0] + '.translateZ'), -0.5)
    #Delete the base surface
    cmds.delete(tmpPlane)

    #Create the controllers
    ctrlTop = createCurveCtrl(name=(prefix + 'top_ctrl'),
                              freezeTransforms=1,
                              color=9,
                              pos=(topPoint, 0, 0))
    ctrlMid = createCurveCtrl(name=(prefix + 'mid_ctrl'),
                              freezeTransforms=1,
                              color=9,
                              pos=(0, 0, 0))
    ctrlEnd = createCurveCtrl(name=(prefix + 'end_ctrl'),
                              freezeTransforms=1,
                              color=9,
                              pos=(endPoint, 0, 0))
    #Group the controllers
    grpTop = grpObject(objects=[ctrlTop],
                       snapTrans=1,
                       keepTransforms=0,
                       keepHi=1,
                       empty=0,
                       suffix='_grp')[0]
    grpMid = grpObject(objects=[ctrlMid],
                       snapTrans=1,
                       keepTransforms=0,
                       keepHi=1,
                       empty=0,
                       suffix='_grp')[0]
    grpEnd = grpObject(objects=[ctrlEnd],
                       snapTrans=1,
                       keepTransforms=0,
                       keepHi=1,
                       empty=0,
                       suffix='_grp')[0]
    #PointConstraint the midCtrl between the top/end
    midConst = cmds.pointConstraint(ctrlTop, ctrlEnd, grpMid)

    #Add attributes: Twist/Roll attributes
    addAttribute(objects=[ctrlTop, ctrlMid, ctrlEnd],
                 longName=['twistSep'],
                 niceName=['---------------'],
                 at="enum",
                 en='Twist',
                 lock=1,
                 k=True)
    addAttribute(objects=[ctrlTop, ctrlEnd],
                 longName=['twist'],
                 at="float",
                 k=True)
    addAttribute(objects=[ctrlTop, ctrlEnd],
                 longName=['twistOffset'],
                 at="float",
                 k=True)
    addAttribute(objects=[ctrlTop, ctrlEnd],
                 longName=['affectToMid'],
                 at="float",
                 min=0,
                 max=10,
                 dv=10,
                 k=True)
    addAttribute(objects=[ctrlMid], longName=['roll'], at="float", k=True)
    addAttribute(objects=[ctrlMid],
                 longName=['rollOffset'],
                 at="float",
                 k=True)
    #Add attributes: Volume attributes
    addAttribute(objects=[ctrlMid],
                 longName=['volumeSep'],
                 niceName=['---------------'],
                 at="enum",
                 en='Volume',
                 lock=1,
                 k=True)
    addAttribute(objects=[ctrlMid],
                 longName=['volume'],
                 at="float",
                 min=-1,
                 max=1,
                 k=True)
    addAttribute(objects=[ctrlMid],
                 longName=['volumeMultiplier'],
                 at="float",
                 min=1,
                 dv=3,
                 k=True)
    addAttribute(objects=[ctrlMid],
                 longName=['startDropoff'],
                 at="float",
                 min=0,
                 max=1,
                 dv=1,
                 k=True)
    addAttribute(objects=[ctrlMid],
                 longName=['endDropoff'],
                 at="float",
                 min=0,
                 max=1,
                 dv=1,
                 k=True)
    addAttribute(objects=[ctrlMid],
                 longName=['volumeScale'],
                 at="float",
                 min=endPoint * 0.9,
                 max=topPoint * 2,
                 k=True)
    addAttribute(objects=[ctrlMid],
                 longName=['volumePosition'],
                 min=endPoint,
                 max=topPoint,
                 at="float",
                 k=True)
    #Add attributes: Sine attributes
    addAttribute(objects=[ctrlMid],
                 longName=['sineSep'],
                 niceName=['---------------'],
                 attributeType='enum',
                 en="Sine:",
                 keyable=True,
                 lock=1)
    addAttribute(objects=[ctrlMid],
                 longName=['amplitude'],
                 attributeType="float",
                 keyable=True)
    addAttribute(objects=[ctrlMid],
                 longName=['offset'],
                 attributeType="float",
                 keyable=True)
    addAttribute(objects=[ctrlMid],
                 longName=['twist'],
                 attributeType="float",
                 keyable=True)
    addAttribute(objects=[ctrlMid],
                 longName=['sineLength'],
                 min=0.1,
                 dv=2,
                 attributeType="float",
                 keyable=True)
    #Add attributes: Extra attributes
    addAttribute(objects=[ctrlMid],
                 longName=['extraSep'],
                 niceName=['---------------'],
                 at="enum",
                 en='Extra',
                 lock=1,
                 k=True)
    addAttribute(objects=[ctrlMid],
                 longName=['showExtraCtrl'],
                 at="enum",
                 en='Hide:Show:',
                 k=True)
    cmds.setAttr((ctrlMid + '.showExtraCtrl'), 1)

    #Create deformers: Twist deformer, Sine deformer, Squash deformer
    twistDef = nonlinearDeformer(objects=[geoPlaneTwist[0]],
                                 defType='twist',
                                 name=geoPlaneTwist[0],
                                 lowBound=-1,
                                 highBound=1,
                                 rotate=(0, 0, 90))
    sineDef = nonlinearDeformer(objects=[geoPlaneSine[0]],
                                defType='sine',
                                name=geoPlaneSine[0],
                                lowBound=-1,
                                highBound=1,
                                rotate=(0, 0, 90))
    squashDef = nonlinearDeformer(objects=[geoPlaneVolume[0]],
                                  defType='squash',
                                  name=geoPlaneVolume[0],
                                  lowBound=-1,
                                  highBound=1,
                                  rotate=(0, 0, 90))
    cmds.setAttr((sineDef[0] + '.dropoff'), 1)
    #Create deformers: Wire deformer
    deformCrv = cmds.curve(p=[(topPoint, 0, 0), (0, 0, 0), (endPoint, 0, 0)],
                           degree=2)
    deformCrv = cmds.rename(deformCrv, (prefix + 'ribbon_wire_crv'))
    wireDef = cmds.wire(geoPlaneWire, dds=(0, 15), wire=deformCrv)
    wireDef[0] = cmds.rename(wireDef[0], (geoPlaneWire[0] + '_wire'))
    #Create deformers: Clusters
    clsTop = cmds.cluster((deformCrv + '.cv[0:1]'), relative=1)
    clsMid = cmds.cluster((deformCrv + '.cv[1]'), relative=1)
    clsEnd = cmds.cluster((deformCrv + '.cv[1:2]'), relative=1)
    clsTop[0] = cmds.rename(clsTop[0], (ctrlTop + '_top_cluster'))
    clsTop[1] = cmds.rename(clsTop[1], (ctrlTop + '_top_clusterHandle'))
    clsMid[0] = cmds.rename(clsMid[0], (ctrlMid + '_mid_cluster'))
    clsMid[1] = cmds.rename(clsMid[1], (ctrlMid + '_mid_clusterHandle'))
    clsEnd[0] = cmds.rename(clsEnd[0], (ctrlEnd + '_end_cluster'))
    clsEnd[1] = cmds.rename(clsEnd[1], (ctrlEnd + '_end_clusterHandle'))
    cmds.setAttr((cmds.listRelatives(clsTop[1], type="shape")[0] + '.originX'),
                 topPoint)
    cmds.setAttr((cmds.listRelatives(clsEnd[1], type="shape")[0] + '.originX'),
                 endPoint)
    setPivot(objects=[clsTop[1]],
             rotatePivot=1,
             scalePivot=1,
             pivot=(topPoint, 0, 0))
    setPivot(objects=[clsEnd[1]],
             rotatePivot=1,
             scalePivot=1,
             pivot=(endPoint, 0, 0))
    cmds.percent(clsTop[0], (deformCrv + '.cv[1]'), v=0.5)
    cmds.percent(clsEnd[0], (deformCrv + '.cv[1]'), v=0.5)
    posTopPma = cmds.shadingNode('plusMinusAverage',
                                 asUtility=1,
                                 name=(prefix + 'top_ctrl_pos_pma'))
    cmds.connectAttr((ctrlTop + '.translate'), (posTopPma + '.input3D[0]'))
    cmds.connectAttr((grpTop + '.translate'), (posTopPma + '.input3D[1]'))
    posEndPma = cmds.shadingNode('plusMinusAverage',
                                 asUtility=1,
                                 name=(prefix + 'end_ctrl_pos_pma'))
    cmds.connectAttr((ctrlEnd + '.translate'), (posEndPma + '.input3D[0]'))
    cmds.connectAttr((grpEnd + '.translate'), (posEndPma + '.input3D[1]'))
    cmds.connectAttr((posTopPma + '.output3D'), (clsTop[1] + '.translate'))
    cmds.connectAttr((ctrlMid + '.translate'), (clsMid[1] + '.translate'))
    cmds.connectAttr((posEndPma + '.output3D'), (clsEnd[1] + '.translate'))
    #Create deformers: Blendshape
    blndDef = cmds.blendShape(geoPlaneWire[0],
                              geoPlaneTwist[0],
                              geoPlaneSine[0],
                              geoPlane[0],
                              name=(prefix + 'blendShape'),
                              weight=[(0, 1), (1, 1), (2, 1)])

    #Twist deformer: Sum the twist and the roll
    sumTopPma = cmds.shadingNode('plusMinusAverage',
                                 asUtility=1,
                                 name=(prefix + 'twist_top_sum_pma'))
    cmds.connectAttr((ctrlTop + '.twist'), (sumTopPma + '.input1D[0]'))
    cmds.connectAttr((ctrlTop + '.twistOffset'), (sumTopPma + '.input1D[1]'))
    cmds.connectAttr((ctrlMid + '.roll'), (sumTopPma + '.input1D[2]'))
    cmds.connectAttr((ctrlMid + '.rollOffset'), (sumTopPma + '.input1D[3]'))
    cmds.connectAttr((sumTopPma + '.output1D'), (twistDef[0] + '.startAngle'))
    sumEndPma = cmds.shadingNode('plusMinusAverage',
                                 asUtility=1,
                                 name=(prefix + 'twist_low_sum_pma'))
    cmds.connectAttr((ctrlEnd + '.twist'), (sumEndPma + '.input1D[0]'))
    cmds.connectAttr((ctrlEnd + '.twistOffset'), (sumEndPma + '.input1D[1]'))
    cmds.connectAttr((ctrlMid + '.roll'), (sumEndPma + '.input1D[2]'))
    cmds.connectAttr((ctrlMid + '.rollOffset'), (sumEndPma + '.input1D[3]'))
    cmds.connectAttr((sumEndPma + '.output1D'), (twistDef[0] + '.endAngle'))
    #Twist deformer: Set up the affect of the deformer
    topAffMdl = cmds.shadingNode('multDoubleLinear',
                                 asUtility=1,
                                 name=(prefix + 'twist_top_affect_mdl'))
    cmds.setAttr((topAffMdl + '.input1'), -0.1)
    cmds.connectAttr((ctrlTop + '.affectToMid'), (topAffMdl + '.input2'))
    cmds.connectAttr((topAffMdl + '.output'), (twistDef[0] + '.lowBound'))
    endAffMdl = cmds.shadingNode('multDoubleLinear',
                                 asUtility=1,
                                 name=(prefix + 'twist_end_affect_mdl'))
    cmds.setAttr((endAffMdl + '.input1'), 0.1)
    cmds.connectAttr((ctrlEnd + '.affectToMid'), (endAffMdl + '.input2'))
    cmds.connectAttr((endAffMdl + '.output'), (twistDef[0] + '.highBound'))

    #Squash deformer: Set up the connections for the volume control
    volumeRevfMdl = cmds.shadingNode('multDoubleLinear',
                                     asUtility=1,
                                     name=(prefix + 'volume_reverse_mdl'))
    cmds.setAttr((volumeRevfMdl + '.input1'), -1)
    cmds.connectAttr((ctrlMid + '.volume'), (volumeRevfMdl + '.input2'))
    cmds.connectAttr((volumeRevfMdl + '.output'), (squashDef[0] + '.factor'))
    cmds.connectAttr((ctrlMid + '.startDropoff'),
                     (squashDef[0] + '.startSmoothness'))
    cmds.connectAttr((ctrlMid + '.endDropoff'),
                     (squashDef[0] + '.endSmoothness'))
    cmds.connectAttr((ctrlMid + '.volumePosition'),
                     (squashDef[1] + '.translateX'))
    #Squash deformer: Set up the volume scaling
    sumScalePma = cmds.shadingNode('plusMinusAverage',
                                   asUtility=1,
                                   name=(prefix + 'volume_scale_sum_pma'))
    cmds.setAttr((sumScalePma + '.input1D[0]'), topPoint)
    cmds.connectAttr((ctrlMid + '.volumeScale'), (sumScalePma + '.input1D[1]'))
    cmds.connectAttr((sumScalePma + '.output1D'), (squashDef[1] + '.scaleY'))

    #Sine deformer: Set up the connections for the sine
    cmds.connectAttr((ctrlMid + '.amplitude'), (sineDef[0] + '.amplitude'))
    cmds.connectAttr((ctrlMid + '.offset'), (sineDef[0] + '.offset'))
    cmds.connectAttr((ctrlMid + '.twist'), (sineDef[1] + '.rotateY'))
    cmds.connectAttr((ctrlMid + '.sineLength'), (sineDef[0] + '.wavelength'))

    #Cleanup: Hierarchy
    cmds.parent(geoPlaneWire[0], geoPlaneTwist[0], geoPlaneSine[0],
                geoPlaneVolume[0], grpSurfaces)
    cmds.parent(twistDef[1], sineDef[1], squashDef[1], grpDeformers)
    cmds.parent(clsTop[1], clsMid[1], clsEnd[1], grpCluster)
    cmds.parent(grpTop, grpMid, grpEnd, grpCtrl)
    cmds.parent(geoPlane[0], grpSurface)
    cmds.parent(deformCrv,
                (cmds.listConnections(wireDef[0] + '.baseWire[0]')[0]),
                grpMisc)
    #Cleanup: Visibility
    cmds.hide(grpSurfaces, grpDeformers, grpCluster, grpMisc)
    for x in cmds.listConnections(ctrlMid):
        cmds.setAttr((x + '.isHistoricallyInteresting'), 0)
        for y in cmds.listConnections(x):
            cmds.setAttr((y + '.isHistoricallyInteresting'), 0)

    #Update the scale-group
    scaleGrp = scaleGrp if scaleGrp else grpTransform
    #Create follicles: The main-surface and the volume-surface
    for x in range(0, numJoints):
        #Declare a variable for the current index
        num = str(x + 1)
        #Get the normalized position of where to place the current follicle
        uVal = ((0.5 / numJoints) * (x + 1) * 2) - ((0.5 /
                                                     (numJoints * 2)) * 2)
        #Create a follicle for the bind-plane and the volume-plane
        follicleS = createFollicle(scaleGrp=scaleGrp,
                                   inputSurface=cmds.listRelatives(
                                       geoPlane[0], type="shape"),
                                   uVal=uVal,
                                   name=(prefix + num + '_follicle'))
        follicleV = createFollicle(scaleGrp=None,
                                   inputSurface=cmds.listRelatives(
                                       geoPlaneVolume[0], type="shape"),
                                   uVal=uVal,
                                   vVal=0,
                                   name=(prefix + num + '_volume_follicle'))
        cmds.parent(follicleS[0], grpFollMain)
        cmds.parent(follicleV[0], grpFollVolume)
        #Create a joint, controller and a group for the current skin-follicle
        cmds.select(clear=True)
        follicleJoint = cmds.joint(name=(prefix + num + '_jnt'), radius=0.1)
        follicleCtrl = cmds.circle(name=(prefix + num + '_ctrl'),
                                   c=(0, 0, 0),
                                   nr=(1, 0, 0),
                                   sw=360,
                                   r=0.5,
                                   d=3,
                                   s=8,
                                   ch=0)[0]
        follicleXform = cmds.group(name=(prefix + num + '_xform_grp'),
                                   empty=True)
        cmds.parent(follicleXform, follicleS[0])
        cmds.parent(follicleCtrl, follicleXform)
        cmds.parent(follicleJoint, follicleCtrl)
        cmds.delete(cmds.parentConstraint(follicleS[0], follicleXform))
        #Set the color and connect the visibility-switch for the controller
        cmds.setAttr((cmds.listRelatives(follicleCtrl, shapes=True)[0] +
                      '.overrideEnabled'), 1)
        cmds.setAttr((cmds.listRelatives(follicleCtrl, shapes=True)[0] +
                      '.overrideColor'), 12)
        cmds.connectAttr(
            (ctrlMid + '.showExtraCtrl'),
            (cmds.listRelatives(follicleCtrl, shapes=True)[0] + '.visibility'))
        #Make the connections for the volume
        multMpd = cmds.shadingNode('multiplyDivide',
                                   asUtility=1,
                                   name=(prefix + num + '_multiplier_mpd'))
        cmds.connectAttr((ctrlMid + '.volumeMultiplier'),
                         (multMpd + '.input1Z'))
        cmds.connectAttr((follicleV[0] + '.translate'), (multMpd + '.input2'))
        sumPma = cmds.shadingNode('plusMinusAverage',
                                  asUtility=1,
                                  name=(prefix + num + '_volume_sum_pma'))
        cmds.connectAttr((multMpd + '.outputZ'), (sumPma + '.input1D[0]'))
        cmds.setAttr((sumPma + '.input1D[1]'), 1)
        cmds.connectAttr((sumPma + '.output1D'), (follicleXform + '.scaleY'))
        cmds.connectAttr((sumPma + '.output1D'), (follicleXform + '.scaleZ'))
Exemplo n.º 32
0
def mirrorWeightsCmd(rbsNode, upperIdx):
	destIdx = upperIdx

	# get destination prefix
	destPrfx = _getTargetNameFromIdx(rbsNode, destIdx)[0]

	# ask for the source
	srcPrfx = cmds.layoutDialog(t='Mirror bulge weights', ui=lambda *x: _mirrorWeightsDialog(rbsNode, destPrfx))
	if len(srcPrfx) > 1:
		return

	# find the source index
	idxPrfxList = _getEyeIdxPrfxList(rbsNode)

	srcIdx = -1
	for lowerIdx, prfx in idxPrfxList:
		if prfx == srcPrfx:
			srcIdx = lowerIdx + 1
			break

	if srcIdx < 0:
		raise Exception, 'Cannot find the index of target %s' % srcPrfx

	# membership set
	objSetNode = _getMembershipSet(rbsNode)
	affectedVtxList = cmds.ls(cmds.sets(objSetNode, q=True) or [], fl=True)

	# find original shape
	obj = cmds.listRelatives(cmds.deformer(rbsNode, q=True, g=True), p=True, pa=True)[0]
	origShape = [s for s in cmds.listRelatives(obj, s=True, pa=True) if cmds.getAttr('%s.intermediateObject' % s)][0]

	# get the original point position
	origAffectedVtxList = ['%s%s' % (origShape, vtx[vtx.rindex('.'):]) for vtx in affectedVtxList]
	vtxCount = len(origAffectedVtxList)
	posList = cmds.xform(origAffectedVtxList, q=True, os=True, t=True)
	posList = [posList[i:i+3] for i in xrange(0, len(posList), 3)]

	# create a symmetry map (it stores the indices of the opposite vertices)
	cmds.progressBar('mainProgressBar', e=True, beginProgress=True, isInterruptable=False, status='Generating symmetry map...', maxValue=vtxCount)
	symmMap = [-1]*len(affectedVtxList)
	for i, pos in enumerate(posList):
		cmds.progressBar('mainProgressBar', e=True, step=1)
		# avoid doing the test twice for the opposite vertex
		if symmMap[i] != -1:
			continue

		oppIdx = -1
		minDistance = 1000000.0

		for j, otherPos in enumerate(posList):
			dist = (otherPos[0]+pos[0])**2 + (otherPos[1]-pos[1])**2 + (otherPos[2]-pos[2])**2
			if dist < minDistance:
				minDistance = dist
				oppIdx = j

		symmMap[i] = oppIdx
		symmMap[oppIdx] = i
	cmds.progressBar('mainProgressBar', e=True, endProgress=True)

	# disconnect paint weights
	_disconnectPaintWeights(rbsNode)

	srcAttr = '%s.it[%d].%s' % (rbsNode, srcIdx, _wAttr)
	destAttr = '%s.it[%d].%s' % (rbsNode, destIdx, _wAttr)
	pAttr = '%s.weightList[0].weights' % rbsNode

	# copy weights from source to paint
	cmds.connectAttr(srcAttr, pAttr, f=True)
	cmds.getAttr(pAttr, mi=True)
	cmds.disconnectAttr(srcAttr, pAttr)

	# connect paint to destination weights
	cmds.connectAttr(pAttr, destAttr, f=True)

	affectedWeightList = cmds.percent(rbsNode, affectedVtxList, q=True, v=True)

	# set weights
	cmds.progressBar('mainProgressBar', e=True, beginProgress=True, isInterruptable=False, status='Setting weights...', maxValue=vtxCount)
	for i, vtx in enumerate(affectedVtxList):
		cmds.progressBar('mainProgressBar', e=True, step=1)
		cmds.percent(rbsNode, vtx, v=affectedWeightList[symmMap[i]])
	cmds.progressBar('mainProgressBar', e=True, endProgress=True)

	# show the paint tool
	cmds.select(obj)
	cmds.setToolTo(cmds.artAttrCtx(oaa='%s.%s.weights' % (_rbsNodeName, rbsNode)))
Exemplo n.º 33
0
def softSelectDef(*args):
    """calls on getSoftSelection() to get the weights of the softSelect and then puts it all under a cluster and a control"""

    ssDefName = cmds.textFieldGrp(widgets["ssdTFG"], q=True, tx=True)

    if not cmds.objExists("%s_CLS"%ssDefName):
        ssScale = cmds.floatFieldGrp(widgets["ssScaleFFG"], q=True, v1=True)
        ssIncrement = cmds.checkBoxGrp(widgets["ssIncrCBG"], q=True, v1=True)
        ssCheck = cmds.checkBoxGrp(widgets["ssCheckCBG"], q=True, v1=True)
        ssParent = cmds.checkBoxGrp(widgets["ssParentCBG"], q=True, v1=True)
        ssCPOM = cmds.checkBoxGrp(widgets["ssCPOMCBG"], q=True, v1=True)

        #this gets the verts selected and their respective weights in the soft selection
        elements,weights = getSoftSelection()

        #get transform and mesh
        xform = elements[0].partition(".")[0]
        #maybe here I should check for "orig", etc and exclude them?
        mesh = cmds.listRelatives(xform, f=True, s=True)[0]

        #check if there are other deformers on the obj
        if ssCheck:
            deformers = []
            deformers = getDeformers(xform)
            if deformers:
                cmds.confirmDialog( title='Deformer Alert!', message='Found some deformers on %s.\nYou may want to put the softmod\n early in the input list'%xform, button=['OK'], defaultButton='OK', cancelButton='OK', dismissString='OK' )

        #select each of the points from the list and create a cluster
        cmds.select(cl=True)
        for elem in elements:
            cmds.select(elem, add=True)

        clus = cmds.cluster(relative=True, name="%s_CLS"%ssDefName)

        for i in range(len(elements)):
            element = elements[i]
            value = weights[i]
            #percent -v 0.5 thisCluster pSphere1.vtx[241] ;
            cmds.percent(clus[0], element,  v=value, )

        #get cluster position
        clusPos = cmds.xform(clus[1], ws=True, q=True, rp=True)

        if ssCPOM:

            #create closest point on mesh (surface?) node
            cpomNode = cmds.shadingNode("closestPointOnMesh", asUtility=True, n="%s_CPOM"%ssDefName)

            #--------------------
            #inputs and outputs for "closestPointOnMesh":

            #inputs:
            #"mesh"->"inputMesh" (mesh node of transform)
            #"clusPos"->"inPosition"
            #"worldMatrix"(transform of object)->"inputMatrix"

            #outputs:
            #"position"->surfacepoint in space
            #"u"->parameter u
            #"v"->parameter v
            #"normal"->normal vector
            #---------------------

            #connect up object to cpom
            cmds.connectAttr("%s.outMesh"%mesh, "%s.inMesh"%cpomNode)
            cmds.setAttr("%s.inPosition"%cpomNode, clusPos[0], clusPos[1], clusPos[2])
            cmds.connectAttr("%s.worldMatrix"%mesh, "%s.inputMatrix"%cpomNode)

            cpomPos = cmds.getAttr("%s.position"%cpomNode)[0]

            #delete cpom node
            cmds.delete(cpomNode)

        else:
            cpomPos = avgElementPos(elements)
    #TO-DO----------------see if you can't orient things to the verts (maybe only with cpom?)

        #now create a control
        control = "%s_CTRL"%ssDefName
        cmds.curve(n=control, d=1, p=[[0.0, 1.0, 0.0], [-0.382683, 0.92388000000000003, 0.0], [-0.70710700000000004, 0.70710700000000004, 0.0], [-0.92388000000000003, 0.382683, 0.0], [-1.0, 0.0, 0.0], [-0.92388000000000003, -0.382683, 0.0], [-0.70710700000000004, -0.70710700000000004, 0.0], [-0.382683, -0.92388000000000003, 0.0], [0.0, -1.0, 0.0], [0.382683, -0.92388000000000003, 0.0], [0.70710700000000004, -0.70710700000000004, 0.0], [0.92388000000000003, -0.382683, 0.0], [1.0, 0.0, 0.0], [0.92388000000000003, 0.382683, 0.0], [0.70710700000000004, 0.70710700000000004, 0.0], [0.382683, 0.92388000000000003, 0.0], [0.0, 1.0, 0.0], [0.0, 0.92388000000000003, 0.382683], [0.0, 0.70710700000000004, 0.70710700000000004], [0.0, 0.382683, 0.92388000000000003], [0.0, 0.0, 1.0], [0.0, -0.382683, 0.92388000000000003], [0.0, -0.70710700000000004, 0.70710700000000004], [0.0, -0.92388000000000003, 0.382683], [0.0, -1.0, 0.0], [0.0, -0.92388000000000003, -0.382683], [0.0, -0.70710700000000004, -0.70710700000000004], [0.0, -0.382683, -0.92388000000000003], [0.0, 0.0, -1.0], [0.0, 0.382683, -0.92388000000000003], [0.0, 0.70710700000000004, -0.70710700000000004], [0.0, 0.92388000000000003, -0.382683], [0.0, 1.0, 0.0], [-0.382683, 0.92388000000000003, 0.0], [-0.70710700000000004, 0.70710700000000004, 0.0], [-0.92388000000000003, 0.382683, 0.0], [-1.0, 0.0, 0.0], [-0.92388000000000003, 0.0, 0.382683], [-0.70710700000000004, 0.0, 0.70710700000000004], [-0.382683, 0.0, 0.92388000000000003], [0.0, 0.0, 1.0], [0.382683, 0.0, 0.92388000000000003], [0.70710700000000004, 0.0, 0.70710700000000004], [0.92388000000000003, 0.0, 0.382683], [1.0, 0.0, 0.0], [0.92388000000000003, 0.0, -0.382683], [0.70710700000000004, 0.0, -0.70710700000000004], [0.382683, 0.0, -0.92388000000000003], [0.0, 0.0, -1.0], [-0.382683, 0.0, -0.92388000000000003], [-0.70710700000000004, 0.0, -0.70710700000000004], [-0.92388000000000003, 0.0, -0.382683], [-1.0, 0.0, 0.0]])
        cmds.select(cl=True)

        #scale the control
        scaleCtrl([control], ssScale)

        shapes = cmds.listRelatives(control, shapes=True)
        for shape in shapes:
            cmds.setAttr("%s.overrideEnabled"%shape, 1)
            cmds.setAttr("%s.overrideColor"%shape, 14)
        controlGrp = cmds.group(control, n="%s_GRP"%control)

        #put the control at the cpomPos
        cmds.xform(controlGrp, ws=True, t=(cpomPos[0],cpomPos[1],cpomPos[2]))

        clusHandShape = cmds.listRelatives(clus[1], s=True)

        # #move the cluster control to the control space (weighted node)
        cmds.cluster(clus[0], e=True, bs=1, wn=(control, control))

        cmds.setAttr("%s.originX"%clusHandShape[0], 0.0)
        cmds.setAttr("%s.originY"%clusHandShape[0], 0.0)
        cmds.setAttr("%s.originZ"%clusHandShape[0], 0.0)

        cmds.delete(clus[1])

        cmds.setAttr("%s.visibility"%clusHandShape[0], 0)

        if ssParent:
            cmds.parent(controlGrp, xform)

        cmds.select(control, r=True)

        if ssIncrement == 1:
            print "trying to rename"
            split = ssDefName.rpartition("_")
            end = split[2]
            isInt = integerTest(end)

            if isInt:
                newNum = int(end) + 1
                newName = "%s%s%02d"%(split[0], split[1], newNum)
                cmds.textFieldGrp(widgets["ssdTFG"], tx=newName, e=True)
            else:
                newName = "%s_01"%ssDefName
                cmds.textFieldGrp(widgets["ssdTFG"], tx=newName, e=True)
    else:
        cmds.warning("An object/cluster of that name already exists! Please choose another name!")
Exemplo n.º 34
0
def flexiPlaneSetup(prefix='flexiPlane', numJoints=5):
    width = numJoints * 2

    # Create Nurbs surface
    flexiPlane = cmds.nurbsPlane(w=width, lr=0.1,
                                 u=width / 2, v=1, ax=[0, 1, 0])

    flexiPlane = cmds.rename(flexiPlane[0], '%s_surface01' % prefix)
    cmds.delete(flexiPlane, constructionHistory=1)

    # Create plane follicles
    mel.eval('createHair %s 1 2 0 0 0 0 1 0 1 1 1;' % str(width / 2))
    for obj in ['hairSystem1', 'pfxHair1', 'nucleus1']:
        cmds.delete(obj)
    folChildren = cmds.listRelatives('hairSystem1Follicles', ad=1)
    cmds.delete([i for i in folChildren if 'curve' in i])
    folGrp = cmds.rename('hairSystem1Follicles', '%s_flcs01' % prefix)

    alphabetList = map(chr, range(97, 123))
    folChildren = cmds.listRelatives(str(folGrp), c=1)

    for obj, letter in zip(folChildren, alphabetList):
        folJnt = cmds.joint(p=cmds.xform(obj, t=1, q=1), n='%s_bind_%s01' % (prefix, letter))
        cmds.parent(folJnt, obj)
        cmds.rename(obj, '%s_flc_%s01' % (prefix, letter))

    # Add controls
    squareCons = ['%s_cnt_a01' % prefix, '%s_cnt_b01' % prefix, '%s_midBend01' % prefix]

    for squareCon in squareCons:
        squareCon = cmds.curve(n=squareCon, d=1, p=[(-1, 0, -1), (1, 0, -1), (1, 0, 1), (-1, 0, 1), (-1, 0, -1)])
        cmds.scale(.75, .75, .75, squareCon, r=1)
        cmds.setAttr('%s.overrideEnabled' % squareCon, 1)
        cmds.setAttr('%s.overrideColor' % squareCon, 17)
        cmds.xform(squareCon, roo='xzy')

    cmds.xform(squareCons[0], t=(-width / 2, 0, 0), ws=1)
    cmds.xform(squareCons[1], t=(width / 2, 0, 0), ws=1)
    cmds.xform(squareCons[2], t=(0, 0, 0), ws=1)
    cmds.makeIdentity(squareCons, a=1)

    squareConGrp = cmds.group(squareCons[0], squareCons[1], n='%s_cnts01' % prefix)
    midConGrp = cmds.group(squareCons[2], n='%s_midCnt01' % prefix)
    cmds.parent(midConGrp, squareConGrp)
    cmds.pointConstraint(squareCons[1], squareCons[0], midConGrp, mo=0)

    # Create a target blendshape controlled by deformers
    flexiBlend = cmds.duplicate(flexiPlane, n='flexiPlaneSetup_bShp_surface01')
    flexiBlendNode = cmds.blendShape(flexiBlend, flexiPlane, n='%s_bShpNode_surface01' % prefix)
    cmds.setAttr('%s.%s' % (flexiBlendNode[0], flexiBlend[0]), 1)
    wireCurve = cmds.curve(n='%s_wire_surface01' % prefix, d=2, p=[(-width / 2, 0, 0), (0, 0, 0), (width / 2, 0, 0)])
    topClstr = cmds.cluster('%s.cv[0:1]' % wireCurve, rel=1, n='%s_cl_a01' % prefix)
    midClstr = cmds.cluster('%s.cv[1]' % wireCurve, rel=1, n='%s_cl_mid01' % prefix)
    botClstr = cmds.cluster('%s.cv[1:2]' % wireCurve, rel=1, n='%s_cl_b01' % prefix)
    clsGrp = cmds.group(topClstr, midClstr, botClstr, n='%s_cls01' % prefix)

    for attr in ['scalePivot', 'rotatePivot']:
        cmds.setAttr('%s.%s' % (topClstr[1], attr), -width / 2, 0, 0)
    for attr in ['scalePivot', 'rotatePivot']:
        cmds.setAttr('%s.%s' % (botClstr[1], attr), width / 2, 0, 0)

    cmds.setAttr('%sShape.originX' % topClstr[1], (-width / 2))
    cmds.setAttr('%sShape.originX' % botClstr[1], (width / 2))
    cmds.percent(topClstr[0], '%s.cv[1]' % wireCurve, v=0.5)
    cmds.percent(botClstr[0], '%s.cv[1]' % wireCurve, v=0.5)

    # Create twist and wire blend shape deformers
    twistNode = cmds.nonLinear(flexiBlend, type='twist')
    cmds.wire(flexiBlend, w=wireCurve, dds=[0, 20], foc=0, n='%s_wireAttrs_surface01' % prefix)
    cmds.xform(twistNode, ro=(0, 0, 90))
    twistNode[0] = cmds.rename(twistNode[0], '%s_twistAttrs_surface01' % prefix)
    twistNode[1] = cmds.rename(twistNode[1], '%s_twist_surface01' % prefix)

    # Connect controls to cluster deformers
    cmds.connectAttr('%s.translate' % squareCons[0], '%s.translate' % topClstr[1])
    cmds.connectAttr('%s.translate' % squareCons[1], '%s.translate' % botClstr[1])
    cmds.connectAttr('%s.translate' % squareCons[2], '%s.translate' % midClstr[1])

    # Connect controls to twist deformer
    cmds.connectAttr('%s.rotateX' % squareCons[0], '%s.endAngle' % twistNode[0])
    cmds.connectAttr('%s.rotateX' % squareCons[1], '%s.startAngle' % twistNode[0])

    # Organize hiearchy nodes and groups
    rootGrp = cmds.group(em=1, n='%s01' % prefix)
    moveGrp = cmds.group(em=1, n='%s_globalMove01' % prefix)
    extrasGrp = cmds.group(em=1, n='%s_extraNodes01' % prefix)

    cmds.parent(flexiBlend, folGrp, wireCurve, twistNode[1], clsGrp, '%s_wire_surface01BaseWire' % prefix, extrasGrp)
    cmds.parent(flexiPlane, squareConGrp, moveGrp)
    cmds.parent(moveGrp, extrasGrp, rootGrp)

    # Scale contraint each follicle to global move group
    for fol in cmds.listRelatives(folGrp, c=1):
        cmds.scaleConstraint(moveGrp, fol, mo=0)
Exemplo n.º 35
0
    def cluster(self,
                character=None,
                mod=None,
                side=None,
                name=None,
                suffix=None,
                geometry=None,
                origin=[0, 0, 0],
                weightObj=None,
                weightValue=1,
                parent=None,
                show=True,
                lockAttr=None,
                ihi=True):
        #--- this method creates a cluster deformer
        #--- select the specified geometry
        cmds.select(geometry)
        #--- create a cluster deformer
        node = cmds.cluster()
        filter_name = (name + node[0].split('Handle')[0][0].upper() +
                       node[0].split('Handle')[0][1:])
        #--- rename the cluster deformer
        node = self.__rename_node(mod=mod,
                                  side=side,
                                  name=filter_name,
                                  suffix=suffix,
                                  obj=node)
        #--- get the cluster deform node
        node.append(cmds.listConnections(node[0])[0])
        #--- create a group on top and parent the deformer under the group
        node_grp = cmds.createNode('transform')
        cmds.parent(node[0], node_grp)
        #--- rename the node group
        node_grp = self.__rename_node(mod=mod,
                                      side=side,
                                      name=filter_name,
                                      suffix='GRP',
                                      obj=node_grp)[0]
        #--- take care of the node's settings
        #--- origin
        ori_x = cmds.getAttr(node[1] + '.originX')
        ori_y = cmds.getAttr(node[1] + '.originY')
        ori_z = cmds.getAttr(node[1] + '.originZ')
        new_origin = [ori_x + origin[0], ori_y + origin[1], ori_z + origin[2]]
        cmds.setAttr(node[1] + '.origin', new_origin[0], new_origin[1],
                     new_origin[2])
        cmds.xform(node[0], pivots=new_origin, worldSpace=True)
        #--- reposition the pivot of the group to the location of the cluster
        cmds.xform(node_grp, pivots=new_origin, worldSpace=True)
        #--- weightValue
        if weightObj:
            if isinstance(weightObj, list):
                if isinstance(weightValue, list):
                    for obj, val in zip(weightObj, weightValue):
                        cmds.percent(node[-1], obj, value=val)
                else:
                    for obj in weightObj:
                        cmds.percent(node[-1], obj, value=weightValue)
            else:
                cmds.percent(node[-1], weightObj, value=weightValue)

        #--- parent the group under the specified parent
        if parent:
            if not isinstance(parent, list):
                cmds.parent(node_grp, parent)
            else:
                raise Exception("Specified parent: " + parent +
                                'is not a valid')
        #--- show or hide transform
        if not show:
            if isinstance(target, list):
                for t in target:
                    cmds.setAttr(t + '.v', 0)
            else:
                cmds.setAttr(target + '.v', 0)
        #--- lock specified attributes
        if lockAttr:
            if node:
                cmds.setAttr(node + '.' + lockAttr, lock=True)
        #--- set isHistoricalInteresting attribute
        if not ihi:
            cmds.setAttr(node + '.ihi', 0)
        #--- return node
        return node
Exemplo n.º 36
0
    def __init__(self,
                 name='felxi',
                 amount=5,
                 width=10,
                 side=Position.left,
                 debug=False):
        """
		:param name:    Name of component.
		:param amount:  Amount of follicles to be created.
		:param width:   Total length of the plane.
		"""
        # Global Node
        globalGrp = cmds.group(name='{}_global_grp'.format(name), em=True)
        masterGrp = cmds.group(globalGrp, name='{}_grp'.format(name))

        # Nurbs Plane
        axis = [0, 1, 0]
        plane = cmds.nurbsPlane(name='{}_plane'.format(name),
                                ax=axis,
                                w=width,
                                lr=0.1,
                                d=3,
                                u=amount,
                                v=1,
                                ch=0)[0]
        planeShape = cmds.listRelatives(plane, shapes=True)[0]
        cmds.parent(plane, globalGrp)

        # BlendShape
        dup = cmds.duplicate(plane, name='{}_twist_blend'.format(plane))
        blendshape = cmds.blendShape(dup,
                                     plane,
                                     name='{}_blendShape0'.format(name),
                                     weight=[0, 1])

        step = 1.0 / float(amount - 1)
        uPos = 0
        vPos = 0.5
        posList = []

        for x in range(amount):
            posList.append(uPos)
            uPos += step

        if side == Position.right:
            posList = list(reversed(posList))

        # Follicles
        follicleList = []
        follicleScale = []
        for x in range(amount):
            follicle = createFollicle('{}_{}_follicle'.format(name, x),
                                      debug=debug)
            follicleTransform = follicle[0]
            follicleShape = follicle[1]

            cmds.connectAttr('{}.local'.format(planeShape),
                             '{}.inputSurface'.format(follicleShape))
            cmds.connectAttr('{}.worldMatrix[0]'.format(planeShape),
                             '{}.inputWorldMatrix'.format(follicleShape))
            cmds.setAttr('{}.parameterU'.format(follicleShape), posList[x])
            cmds.setAttr('{}.parameterV'.format(follicleShape), vPos)
            cmds.setAttr('{}.v'.format(follicleShape), 0)
            follicleScale.append(
                cmds.scaleConstraint(globalGrp, follicleTransform, mo=True)[0])
            follicleList.append(follicleTransform)

        # Locators
        pos = [width / 2 * -1, 0, width / 2]
        if side == Position.right:
            pos = list(reversed(pos))

        locList = []
        locGrpList = []
        i = 0
        for x in pos:
            loc = cmds.spaceLocator(name='{}_{}_locator'.format(name, i))[0]
            cmds.xform(loc, ws=True, t=[x, 0, 0])
            freezeTransform(loc)
            cmds.parent(loc, globalGrp)
            locList.append(loc)
            i += 1

        # Curve
        clusterList = []
        clusterGrp = cmds.group(name='{}_cluster_grp'.format(name), em=True)
        curve = makeNurbsCurve(locList, n='{}_curve'.format(name), d=2)
        i = 0
        for x in ['0:1', '1', '1:2']:
            cluster = cmds.cluster('{}.cv[{}]'.format(curve, x),
                                   rel=True,
                                   name='{}_{}_cluster'.format(name, i))
            clusterShape = cluster[0]
            cluster = cluster[1]
            cmds.xform(cluster, ws=True, rp=[pos[i], 0, 0])
            cmds.setAttr('{}.v'.format(cluster), 0)
            cmds.connectAttr('{}.t'.format(locList[i]), '{}.t'.format(cluster))
            cmds.parent(cluster, clusterGrp)
            clusterList.append(clusterShape)
            i += 1

        cmds.percent(clusterList[0], '{}.cv[1]'.format(curve), v=.5)
        cmds.percent(clusterList[-1], '{}.cv[1]'.format(curve), v=.5)

        # TwistDeformer
        twist = cmds.nonLinear(dup, type='twist', name='{}_twist'.format(name))
        twistShape = cmds.rename(twist[0], '{}_twist'.format(name))
        twistTransform = cmds.rename(twist[1], '{}_twistHandle'.format(name))
        cmds.setAttr('{}.rz'.format(twistTransform),
                     -90 if side == Position.left else 90)

        rangeNode = cmds.createNode('setRange',
                                    name='{}_twist_setRange0'.format(name))
        addList = []
        for axis in ['x', 'y', 'z']:
            cmds.setAttr('{}.oldMax{}'.format(rangeNode, axis.upper()), 1)

        cmds.addAttr(globalGrp, ln='startTwist', min=0, max=1, dv=1, k=True)
        cmds.addAttr(globalGrp, ln='endTwist', min=0, max=1, dv=1, k=True)
        cmds.addAttr(globalGrp,
                     ln='startTwistAmount',
                     k=True,
                     at='doubleAngle')
        cmds.addAttr(globalGrp, ln='endTwistAmount', k=True, at='doubleAngle')
        cmds.addAttr(globalGrp, ln='startTwistAdd', k=True, at='doubleAngle')
        cmds.addAttr(globalGrp, ln='endTwistAdd', k=True, at='doubleAngle')
        cmds.addAttr(
            globalGrp,
            ln='twistSide',
            min=-1,
            max=1,
            dv=-1 if side == Position.left else 1,
            k=True,
        )

        mirror = cmds.createNode('multiplyDivide',
                                 name='{}_mirror_mult0'.format(name))

        axis = 'X'
        for attr in ['start', 'end']:
            add = cmds.createNode('addDoubleLinear',
                                  name='{}_{}_add0'.format(name, attr))
            cmds.connectAttr('{}.{}TwistAmount'.format(globalGrp, attr),
                             '{}.input1'.format(add))
            cmds.connectAttr('{}.{}TwistAdd'.format(globalGrp, attr),
                             '{}.input2'.format(add))

            cmds.connectAttr('{}.output'.format(add),
                             '{}.max{}'.format(rangeNode, axis))
            cmds.connectAttr('{}.{}Twist'.format(globalGrp, attr),
                             '{}.value{}'.format(rangeNode, axis))

            cmds.connectAttr('{}.twistSide'.format(globalGrp),
                             '{}.input1{}'.format(mirror, axis))
            cmds.connectAttr('{}.outValue{}'.format(rangeNode, axis),
                             '{}.input2{}'.format(mirror, axis))
            cmds.connectAttr('{}.output{}'.format(mirror, axis),
                             '{}.{}Angle'.format(twistShape, attr))
            axis = 'Y'

        # Wire Deformer
        wire = cmds.wire(dup, wire=curve, name='{}_wire0'.format(name))
        wireShape = wire[0]
        wireBaseTransform = cmds.listConnections(
            '{}.baseWire[0]'.format(wireShape))[0]
        cmds.setAttr('{}.dropoffDistance[0]'.format(wire[0]), 20)

        # SnS
        cmds.addAttr(globalGrp, ln='sns', min=0, max=1, dv=1, k=True)
        cmds.addAttr(globalGrp, ln='snsAdd', k=True)
        # cmds.addAttr(globalGrp, ln='snsHighBound', k=True, min=0, max=1, dv=1)
        # cmds.addAttr(globalGrp, ln='snsLowBound', k=True, min=0, max=1, dv=1)

        curveInfo = createCurveInfo(curve)
        divideA = cmds.createNode('multiplyDivide',
                                  name='{}_divide0'.format(name))
        cmds.setAttr('{}.operation'.format(divideA), 2)
        cmds.setAttr('{}.input2X'.format(divideA), width)
        divideB = cmds.createNode('multiplyDivide',
                                  name='{}_divide0'.format(name))
        cmds.setAttr('{}.operation'.format(divideB), 2)
        cmds.setAttr('{}.input1X'.format(divideB), 1)

        cmds.connectAttr('{}.arcLength'.format(curveInfo),
                         '{}.input1X'.format(divideA))
        cmds.connectAttr('{}.outputX'.format(divideA),
                         '{}.input2X'.format(divideB))

        setRange = cmds.createNode('setRange',
                                   name='{}_sns_setRange0'.format(name))
        cmds.setAttr('{}.minX'.format(setRange), 1)
        cmds.setAttr('{}.oldMaxX'.format(setRange), 1)
        cmds.connectAttr('{}.sns'.format(globalGrp),
                         '{}.valueX'.format(setRange))
        cmds.connectAttr('{}.outputX'.format(divideB),
                         '{}.maxX'.format(setRange))

        add = cmds.createNode('addDoubleLinear', name='{}_add0'.format(name))
        cmds.connectAttr('{}.outValueX'.format(setRange),
                         '{}.input1'.format(add))
        cmds.connectAttr('{}.snsAdd'.format(globalGrp),
                         '{}.input2'.format(add))

        var = 0
        step = 1.0 / float(amount - 1)
        stepRangePos = []

        for x in range(amount):
            if x == 0:
                stepRangePos.append(.1)
            else:
                stepRangePos.append(var)
            var += step

        stepRangeNeg = list(reversed(stepRangePos))

        for scale in follicleScale:
            i = follicleScale.index(scale)
            for axis in ['y', 'z']:
                cmds.connectAttr('{}.output'.format(add),
                                 '{}.offset{}'.format(scale, axis.upper()))

        # Hierarchy
        extrasGrp = cmds.group(clusterGrp,
                               curve,
                               twistTransform,
                               dup,
                               wireBaseTransform,
                               name='{}_extras_grp'.format(name))
        cmds.setAttr('{}.v'.format(extrasGrp), 0)
        cmds.setAttr('{}.inheritsTransform'.format(extrasGrp), 0)

        follicleGrp = cmds.group(follicleList,
                                 name='{}_follicle_grp'.format(name))
        cmds.setAttr('{}.inheritsTransform'.format(follicleGrp), 0)
        cmds.parent(extrasGrp, follicleGrp, masterGrp)

        for x in [follicleGrp, clusterGrp, extrasGrp, plane]:
            lockKeyableAttributes(x)

        setVisibility(globalGrp)
        lockScale(globalGrp)

        # Return
        self.plane = plane
        self.planeShape = planeShape
        self.planeBlend = dup
        self.planeBlendShape = blendshape
        self.follicle = follicleList
        self.curve = curve
        self.twist = twistTransform
        self.twistShape = twistShape
        self.wire = wire
        self.wireBase = wireBaseTransform
        self.control = locList
        self.group = locGrpList
        self.parent = globalGrp
        self.masterGroup = masterGrp
        self.extra = extrasGrp
def Cas_convertRigidToSmooth_cmd(object):
    def getObjectVertices(ob, verts):

        ov = cmds.polyListComponentConversion(ob, tv=1)
        ov = cmds.filterExpand(ov, ex=1, fp=1, sm=31)

        verts = cmds.filterExpand(verts, ex=1, fp=1, sm=31)

        # print ov
        # print verts

        com = []
        for v in verts:
            if v in ov:
                com.append(v)
        return com

    """
	"""
    warningCount = 0
    num = 0

    objects = object[:]
    # objects.append(object)

    allClusters = []
    # get all the joint cluster names
    jCluster = cmds.ls(typ="jointCluster")
    # print cmds.cluster(jCluster,q=1,g=1)
    # print jCluster
    # return
    if jCluster == None:
        return [num, warningCount]

    for objT in objects:
        obj = cmds.listRelatives(objT, s=1, pa=1)  # full path!!!
        if obj == None:
            continue
            # print obj
            # objShape = obj[0]
            # iterate through to see if any clusters are connected to the object
        joint = []
        cluster = []
        jointSet = []
        # find related clusters jointsets and joints
        for c in jCluster:
            jc = []
            jc = cmds.cluster(c, q=1, g=1)
            # print obj[0]

            if obj[0] in jc:
                # print "deformer found"
                # print jc
                deformer = Cas_CRTS_getJointDeformer(c)
                if deformer != None:
                    joint.append(deformer)
                    jointSet.append(Cas_CRTS_getJointSet(c))
                    cluster.append(c)
                    if c not in allClusters:
                        allClusters.append(c)
                        # check if any jointcluster exists for this object
        if cluster == []:
            # print "No jointCluster found for node : %s" %objT
            continue

            # now joint should contain all the joints names which i need to bind my new object to
            # bind skin

            # print joint
            # print objT
            # return

        newClusterName = []
        try:
            newClusterName = cmds.skinCluster(joint, objT, tst=True)[0]
        except Exception, msg:
            Cas_IO.Cas_printWarning("Failed to assign skinCluster. skinCluster may exist already for node : %s" % objT)
            warningCount = warningCount + 1
            continue
        else:
            print "jointCluster found for node : %s" % objT

            # setAttr "skinCluster4.normalizeWeights" 1;
            # cmds.setAttr(newClusterName+".normalizeWeights",0)

            # now needs to copy weights over.
        index = 0
        for c in cluster:

            jSet = jointSet[index]
            jsetName = jSet[0].split(".")
            # print jsetName
            vertices = cmds.sets(jsetName[0], q=1)

            vertices = getObjectVertices(objT, vertices)

            # print vertices
            if (vertices == None) or (vertices == []):
                # print "skip"
                index = index + 1
                continue

            deformer = joint[index]
            parentDeformer = cmds.listRelatives(deformer, p=1)
            # print parentDeformer
            # vertices = cmds.filterExpand(vertices,ex=1,fp=1,sm=31)
            cmds.select(vertices)

            value = cmds.percent(c, q=1, v=1)

            # print len(value)
            # print len(vertices)

            if not parentDeformer == None:
                cmds.skinPercent(newClusterName, vertices, tv=([parentDeformer[0], 1]))

                # for j in joint:
                # 	cmds.skinPercent(newClusterName,vertices,tv=([j,0]))

            i = 0
            for v in value:
                cmds.skinPercent(newClusterName, vertices[i], tv=([deformer, v]))

                # if not parentDeformer == None:
                # 	cmds.skinPercent(newClusterName,vertices[i],tv=([parentDeformer[0],(1-v)]))
                # print i
                i += 1

            cmds.percent(c, vertices, v=0)
            index = index + 1
        num = num + 1
Exemplo n.º 38
0
def mirrorWeightsCmd(rbsNode, upperIdx):
    destIdx = upperIdx

    # get destination prefix
    destPrfx = _getTargetNameFromIdx(rbsNode, destIdx)[0]

    # ask for the source
    srcPrfx = cmds.layoutDialog(
        t='Mirror bulge weights',
        ui=lambda *x: _mirrorWeightsDialog(rbsNode, destPrfx))
    if len(srcPrfx) > 1:
        return

    # find the source index
    idxPrfxList = _getEyeIdxPrfxList(rbsNode)

    srcIdx = -1
    for lowerIdx, prfx in idxPrfxList:
        if prfx == srcPrfx:
            srcIdx = lowerIdx + 1
            break

    if srcIdx < 0:
        raise Exception, 'Cannot find the index of target %s' % srcPrfx

    # membership set
    objSetNode = _getMembershipSet(rbsNode)
    affectedVtxList = cmds.ls(cmds.sets(objSetNode, q=True) or [], fl=True)

    # find original shape
    obj = cmds.listRelatives(cmds.deformer(rbsNode, q=True, g=True),
                             p=True,
                             pa=True)[0]
    origShape = [
        s for s in cmds.listRelatives(obj, s=True, pa=True)
        if cmds.getAttr('%s.intermediateObject' % s)
    ][0]

    # get the original point position
    origAffectedVtxList = [
        '%s%s' % (origShape, vtx[vtx.rindex('.'):]) for vtx in affectedVtxList
    ]
    vtxCount = len(origAffectedVtxList)
    posList = cmds.xform(origAffectedVtxList, q=True, os=True, t=True)
    posList = [posList[i:i + 3] for i in xrange(0, len(posList), 3)]

    # create a symmetry map (it stores the indices of the opposite vertices)
    cmds.progressBar('mainProgressBar',
                     e=True,
                     beginProgress=True,
                     isInterruptable=False,
                     status='Generating symmetry map...',
                     maxValue=vtxCount)
    symmMap = [-1] * len(affectedVtxList)
    for i, pos in enumerate(posList):
        cmds.progressBar('mainProgressBar', e=True, step=1)
        # avoid doing the test twice for the opposite vertex
        if symmMap[i] != -1:
            continue

        oppIdx = -1
        minDistance = 1000000.0

        for j, otherPos in enumerate(posList):
            dist = (otherPos[0] + pos[0])**2 + (otherPos[1] - pos[1])**2 + (
                otherPos[2] - pos[2])**2
            if dist < minDistance:
                minDistance = dist
                oppIdx = j

        symmMap[i] = oppIdx
        symmMap[oppIdx] = i
    cmds.progressBar('mainProgressBar', e=True, endProgress=True)

    # disconnect paint weights
    _disconnectPaintWeights(rbsNode)

    srcAttr = '%s.it[%d].%s' % (rbsNode, srcIdx, _wAttr)
    destAttr = '%s.it[%d].%s' % (rbsNode, destIdx, _wAttr)
    pAttr = '%s.weightList[0].weights' % rbsNode

    # copy weights from source to paint
    cmds.connectAttr(srcAttr, pAttr, f=True)
    cmds.getAttr(pAttr, mi=True)
    cmds.disconnectAttr(srcAttr, pAttr)

    # connect paint to destination weights
    cmds.connectAttr(pAttr, destAttr, f=True)

    affectedWeightList = cmds.percent(rbsNode, affectedVtxList, q=True, v=True)

    # set weights
    cmds.progressBar('mainProgressBar',
                     e=True,
                     beginProgress=True,
                     isInterruptable=False,
                     status='Setting weights...',
                     maxValue=vtxCount)
    for i, vtx in enumerate(affectedVtxList):
        cmds.progressBar('mainProgressBar', e=True, step=1)
        cmds.percent(rbsNode, vtx, v=affectedWeightList[symmMap[i]])
    cmds.progressBar('mainProgressBar', e=True, endProgress=True)

    # show the paint tool
    cmds.select(obj)
    cmds.setToolTo(
        cmds.artAttrCtx(oaa='%s.%s.weights' % (_rbsNodeName, rbsNode)))
Exemplo n.º 39
0
def softSelectDef(*args):
    """calls on getSoftSelection() to get the weights of the softSelect and then puts it all under a cluster and a control"""

    elements,weights = getSoftSelection()

    print elements
    print weights

    #get transform and mesh
    xform = elements[0].partition(".")[0]
    #maybe here I should check for "orig", etc and exclude them?
    mesh = cmds.listRelatives(xform, f=True, s=True)[0]

    #select each of the points from the list and create a cluster
    cmds.select(cl=True)
    for elem in elements:
        cmds.select(elem, add=True)

    clus = cmds.cluster(relative=True, name="thisCluster")


    for i in range(len(elements)):
        element = elements[i]
        value = weights[i]
        #percent -v 0.5 thisCluster pSphere1.vtx[241] ;
        cmds.percent(clus[0], element,  v=value, )

    #get cluster position
    clusPos = cmds.xform(clus[1], ws=True, q=True, rp=True)

    #create closest point on mesh (surface?) node
    cpomNode = cmds.shadingNode("closestPointOnMesh", asUtility=True, n="tempCPOM")

    #--------------------
    #inputs and outputs for "closestPointOnMesh":

    #inputs:
    #"mesh"->"inputMesh" (mesh node of transform)
    #"clusPos"->"inPosition"
    #"worldMatrix"(transform of object)->"inputMatrix"

    #outputs:
    #"position"->surfacepoint in space
    #"u"->parameter u
    #"v"->parameter v
    #"normal"->normal vector
    #---------------------

    #connect up object to cpom
    cmds.connectAttr("%s.outMesh"%mesh, "%s.inMesh"%cpomNode)
    cmds.setAttr("%s.inPosition"%cpomNode, clusPos[0], clusPos[1], clusPos[2])
    cmds.connectAttr("%s.worldMatrix"%mesh, "%s.inputMatrix"%cpomNode)

    cpomPos = cmds.getAttr("%s.position"%cpomNode)[0]

    #delete cpom node
    cmds.delete(cpomNode)

    #now create a control, orient it to the follicle
    control = "controlName"
    cmds.curve(n=control, d=1, p=[[0.0, 1.0, 0.0], [-0.382683, 0.92388000000000003, 0.0], [-0.70710700000000004, 0.70710700000000004, 0.0], [-0.92388000000000003, 0.382683, 0.0], [-1.0, 0.0, 0.0], [-0.92388000000000003, -0.382683, 0.0], [-0.70710700000000004, -0.70710700000000004, 0.0], [-0.382683, -0.92388000000000003, 0.0], [0.0, -1.0, 0.0], [0.382683, -0.92388000000000003, 0.0], [0.70710700000000004, -0.70710700000000004, 0.0], [0.92388000000000003, -0.382683, 0.0], [1.0, 0.0, 0.0], [0.92388000000000003, 0.382683, 0.0], [0.70710700000000004, 0.70710700000000004, 0.0], [0.382683, 0.92388000000000003, 0.0], [0.0, 1.0, 0.0], [0.0, 0.92388000000000003, 0.382683], [0.0, 0.70710700000000004, 0.70710700000000004], [0.0, 0.382683, 0.92388000000000003], [0.0, 0.0, 1.0], [0.0, -0.382683, 0.92388000000000003], [0.0, -0.70710700000000004, 0.70710700000000004], [0.0, -0.92388000000000003, 0.382683], [0.0, -1.0, 0.0], [0.0, -0.92388000000000003, -0.382683], [0.0, -0.70710700000000004, -0.70710700000000004], [0.0, -0.382683, -0.92388000000000003], [0.0, 0.0, -1.0], [0.0, 0.382683, -0.92388000000000003], [0.0, 0.70710700000000004, -0.70710700000000004], [0.0, 0.92388000000000003, -0.382683], [0.0, 1.0, 0.0], [-0.382683, 0.92388000000000003, 0.0], [-0.70710700000000004, 0.70710700000000004, 0.0], [-0.92388000000000003, 0.382683, 0.0], [-1.0, 0.0, 0.0], [-0.92388000000000003, 0.0, 0.382683], [-0.70710700000000004, 0.0, 0.70710700000000004], [-0.382683, 0.0, 0.92388000000000003], [0.0, 0.0, 1.0], [0.382683, 0.0, 0.92388000000000003], [0.70710700000000004, 0.0, 0.70710700000000004], [0.92388000000000003, 0.0, 0.382683], [1.0, 0.0, 0.0], [0.92388000000000003, 0.0, -0.382683], [0.70710700000000004, 0.0, -0.70710700000000004], [0.382683, 0.0, -0.92388000000000003], [0.0, 0.0, -1.0], [-0.382683, 0.0, -0.92388000000000003], [-0.70710700000000004, 0.0, -0.70710700000000004], [-0.92388000000000003, 0.0, -0.382683], [-1.0, 0.0, 0.0]])
    cmds.select(cl=True)
    shapes = cmds.listRelatives(control, shapes=True)
    for shape in shapes:
        cmds.setAttr("%s.overrideEnabled"%shape, 1)
        cmds.setAttr("%s.overrideColor"%shape, 14)
    controlGrp = cmds.group(control, n="%s_GRP"%control)

    #put the control at the cpomPos
    cmds.xform(controlGrp, ws=True, t=(cpomPos[0],cpomPos[1],cpomPos[2]))

    clusHandShape = cmds.listRelatives(clus[1], s=True)

    # #move the cluster control to the control space (weighted node)
    cmds.cluster(clus[0], e=True, bs=1, wn=(control, control))

    cmds.setAttr("%s.originX"%clusHandShape[0], 0.0)
    cmds.setAttr("%s.originY"%clusHandShape[0], 0.0)
    cmds.setAttr("%s.originZ"%clusHandShape[0], 0.0)

    cmds.delete(clus[1])

    cmds.setAttr("%s.visibility"%clusHandShape[0], 0)
Exemplo n.º 40
0
class analyticGPUClusters(BaseAnalytic):
    """
    Analyze the usage mode of cluster node.
    """
    def run(self):
        """
        Examine animated cluster nodes and check how they are used.  It checks
        whether they are used for fixed rigid transform, weighted rigid transform
        or per-vertex-weighted transform.

        When the 'details' option is set the CSV columns are:
            ClusterNode         : Name of the animated cluster node
            envelope_is_static : True if the envelope is not animated and its value is 1
            uses_weights         : True if weights are used in the node
            uses_same_weight      : True if weight is the same for all vertices
            Mode                : Mode for this node
            supported_geometry   : True if the geometry processed by animated cluster node
                                  is supported by deformer evaluator

        otherwise the CSV columns are:
            ClusterMode        : Description of the usage for the animated cluster node
            Mode               : Mode for animated cluster nodes meeting this criteria
            supported_geometry  : True if the geometry processed by animated cluster nodes
                                 meeting this criteria is supported by deformer evaluator
            Count              : Number of animated cluster nodes in this mode

            See is_supported_geometry() for what criteria a geometry must meet to be supported.

        One row is output for every animated cluster node.

        The "Mode" is an integer value with the following meaning:
        - 1 => Rigid transform          : cluster node only performs a rigid transform
        - 2 => Weighted rigid transform : cluster node performs a rigid transform, but it
                                          is weighted down by a factor
        - 3 => Per-vertex transform     : cluster node computes a different transform for
                                          each individually-weighted vertex

        Return True if the analysis succeeded, else False
        """
        with emModeManager() as em_manager:
            em_manager.setMode('ems')
            em_manager.rebuild()

            # Get all animated nodes.
            try:
                json_nodes = json.loads(
                    cmds.dbpeek(op='graph', eg=True, all=True, a='nodes'))
                animated_nodes = set(json_nodes['nodes'])
            except Exception, ex:
                self.error('Graph examination failure ({0:s})'.format(str(ex)))
                return

        if not animated_nodes:
            self.warning('No GPU animation to examine')
            return

        # Loop and process only cluster nodes.
        cluster_nodes = []
        for node in animated_nodes:
            if cmds.nodeType(node) == 'cluster':
                # Check the envelope attribute.
                envelope_source = cmds.listConnections(node + '.envelope',
                                                       source=True,
                                                       destination=False)
                if envelope_source and len(envelope_source) > 0:
                    envelope_is_static = False
                else:
                    envelope = cmds.getAttr(node + '.envelope')
                    if envelope == 1:
                        envelope_is_static = True
                    else:
                        envelope_is_static = False

                # Now loop over each output geometry as separate usage of this node.
                geometries = cmds.cluster(node, query=True, geometry=True)
                geometry_indices = cmds.cluster(node,
                                                query=True,
                                                geometryIndices=True)
                if geometries == None or geometry_indices == None:
                    continue

                cluster_geometry = dict(zip(geometry_indices, geometries))
                for index, geometry in cluster_geometry.items():
                    # Check if the deformed geometry is supported.
                    supported_geometry = analyticGPUDeformers.is_supported_geometry(
                        geometry)

                    # Check if weights are used.
                    uses_weights = False
                    weight_plug = '%s.weightList[%d]' % (node, index)
                    weights_source = cmds.listConnections(weight_plug,
                                                          source=True,
                                                          destination=False)
                    if weights_source and len(weights_source) > 0:
                        # If they are animated, we consider they don't have default value.
                        uses_weights = True

                    uses_same_weight = False
                    common_value = None
                    if not uses_weights:
                        uses_same_weight = True

                        # Check if the weights have non default value.
                        weights = cmds.percent(node,
                                               geometry,
                                               query=True,
                                               value=True)
                        for weight in weights:
                            if common_value == None:
                                common_value = weight
                            else:
                                if common_value != weight:
                                    uses_same_weight = False
                                    break

                    if (not uses_same_weight) or (common_value != 1):
                        uses_weights = True

                    # Determine the mode.
                    if uses_weights:
                        mode = 3
                    else:
                        if envelope_is_static:
                            mode = 1
                        else:
                            mode = 2

                    # Append the info.
                    nodeName = '%s[%d]' % (self._node_name(node), index)
                    cluster_nodes.append(
                        (nodeName, envelope_is_static, uses_weights,
                         uses_same_weight, mode, supported_geometry))

        if not cluster_nodes:
            self.warning('No GPU clusters to examine')
            return

        # Output to CSV.
        if self.option(OPTION_DETAILS):
            self._output_csv([
                'ClusterNode', 'EnvelopeIsStatic', 'UsesWeights',
                'UsesSameWeight', 'Mode', 'SupportedGeometry'
            ])
            output_rows = cluster_nodes
        else:
            self._output_csv(
                ['ClusterType', 'Mode', 'SupportedGeometry', 'Count'])

            # Build the summary using different categories.
            categories = [
                ('Rigid_Supported', (1, True)),
                ('Weighted_Supported', (2, True)),
                ('PerVertex_Supported', (3, True)),
                ('Rigid_NotSupported', (1, False)),
                ('Weighted_NotSupported', (2, False)),
                ('PerVertex_NotSupported', (3, False)),
            ]

            # Loop over each "category" and count the number of collected nodes (in cluster_nodes)
            # meeting the criteria for each category.
            #
            # Here, the criteria to know whether or not a node belongs to a category is:
            # - The "mode" (see help above for description of the modes)
            # - Whether or not the cluster node drives a supported mesh (vs another type of geometry)
            summary = []
            for category in categories:
                name = category[0]
                criteria = category[1]
                tester = lambda x, criteria_to_check=criteria: x[
                    4:] == criteria_to_check
                count = len([node for node in cluster_nodes if tester(node)])

                summary.append((name, criteria[0], criteria[1], count))

            output_rows = summary

        for row in output_rows:
            self._output_csv(list(row))
Exemplo n.º 41
0
def Cas_convertRigidToSmooth_cmd(object):
    def getObjectVertices(ob, verts):

        ov = cmds.polyListComponentConversion(ob, tv=1)
        ov = cmds.filterExpand(ov, ex=1, fp=1, sm=31)

        verts = cmds.filterExpand(verts, ex=1, fp=1, sm=31)

        #print ov
        #print verts

        com = []
        for v in verts:
            if v in ov:
                com.append(v)
        return com

    """
	"""
    warningCount = 0
    num = 0

    objects = object[:]
    #objects.append(object)

    allClusters = []
    #get all the joint cluster names
    jCluster = cmds.ls(typ="jointCluster")
    #print cmds.cluster(jCluster,q=1,g=1)
    #print jCluster
    #return
    if jCluster == None:
        return [num, warningCount]

    for objT in objects:
        obj = cmds.listRelatives(objT, s=1, pa=1)  #full path!!!
        if obj == None:
            continue
        #print obj
        #objShape = obj[0]
        #iterate through to see if any clusters are connected to the object
        joint = []
        cluster = []
        jointSet = []
        #find related clusters jointsets and joints
        for c in jCluster:
            jc = []
            jc = cmds.cluster(c, q=1, g=1)
            #print obj[0]

            if obj[0] in jc:
                #print "deformer found"
                #print jc
                deformer = Cas_CRTS_getJointDeformer(c)
                if deformer != None:
                    joint.append(deformer)
                    jointSet.append(Cas_CRTS_getJointSet(c))
                    cluster.append(c)
                    if c not in allClusters:
                        allClusters.append(c)
        #check if any jointcluster exists for this object
        if cluster == []:
            #print "No jointCluster found for node : %s" %objT
            continue

        #now joint should contain all the joints names which i need to bind my new object to
        #bind skin

        #print joint
        #print objT
        #return

        newClusterName = []
        try:
            newClusterName = cmds.skinCluster(joint, objT, tst=True)[0]
        except Exception, msg:
            Cas_IO.Cas_printWarning(
                "Failed to assign skinCluster. skinCluster may exist already for node : %s"
                % objT)
            warningCount = warningCount + 1
            continue
        else:
            print "jointCluster found for node : %s" % objT

        #setAttr "skinCluster4.normalizeWeights" 1;
        #cmds.setAttr(newClusterName+".normalizeWeights",0)

        #now needs to copy weights over.
        index = 0
        for c in cluster:

            jSet = jointSet[index]
            jsetName = jSet[0].split(".")
            #print jsetName
            vertices = cmds.sets(jsetName[0], q=1)

            vertices = getObjectVertices(objT, vertices)

            #print vertices
            if (vertices == None) or (vertices == []):
                #print "skip"
                index = index + 1
                continue

            deformer = joint[index]
            parentDeformer = cmds.listRelatives(deformer, p=1)
            #print parentDeformer
            #vertices = cmds.filterExpand(vertices,ex=1,fp=1,sm=31)
            cmds.select(vertices)

            value = cmds.percent(c, q=1, v=1)

            #print len(value)
            #print len(vertices)

            if not parentDeformer == None:
                cmds.skinPercent(newClusterName,
                                 vertices,
                                 tv=([parentDeformer[0], 1]))

            #for j in joint:
            #	cmds.skinPercent(newClusterName,vertices,tv=([j,0]))

            i = 0
            for v in value:
                cmds.skinPercent(newClusterName,
                                 vertices[i],
                                 tv=([deformer, v]))

                #if not parentDeformer == None:
                #	cmds.skinPercent(newClusterName,vertices[i],tv=([parentDeformer[0],(1-v)]))
                #print i
                i += 1

            cmds.percent(c, vertices, v=0)
            index = index + 1
        num = num + 1
Exemplo n.º 42
0
def mirror_cluster():

    is_current_setup_valid = True
    mesh_transform = global_settings.get("loaded_mesh")
    cluster_handle = global_settings.get("loaded_cluster_handle")
    mirror_axis = cmds.radioButtonGrp("mirror_axis_btn_grp", q=1, sl=1)

    if cmds.objExists(mesh_transform) == True:
        if cmds.objectType(
                cmds.listRelatives(mesh_transform,
                                   children=True)[0]) != "mesh":
            is_current_setup_valid = False
    else:
        is_current_setup_valid = False

    if cmds.objExists(cluster_handle) == True:
        if cmds.objectType(
                cmds.listRelatives(cluster_handle,
                                   children=True)[0]) != "clusterHandle":
            is_current_setup_valid = False
    else:
        is_current_setup_valid = False

    if is_current_setup_valid:
        mesh_shape = cmds.listRelatives(mesh_transform, s=1, c=1)
        verticies_selected_mesh = get_cluster_verticies_on_mesh(
            mesh_transform, cluster_handle)
        mirrored_vertices = []

        for vertex in verticies_selected_mesh:
            vertex_position = cmds.pointPosition(vertex[0], local=1)

            # Utility node used to collect information about the other side of the mesh
            closest_point_node = cmds.createNode('closestPointOnMesh')

            if mirror_axis == 1:

                cmds.setAttr((closest_point_node + ".inPosition"),
                             -vertex_position[0], vertex_position[1],
                             vertex_position[2])
            elif mirror_axis == 2:
                cmds.setAttr((closest_point_node + ".inPosition"),
                             vertex_position[0], -vertex_position[1],
                             vertex_position[2])
            else:
                cmds.setAttr((closest_point_node + ".inPosition"),
                             vertex_position[0], vertex_position[1],
                             -vertex_position[2])

            try:
                cmds.connectAttr((mesh_shape[0] + ".outMesh"),
                                 (closest_point_node + ".inMesh"),
                                 force=1)
            except:
                pass

            mirrored_vertex = (
                mesh_transform + ".vtx[" +
                str(cmds.getAttr(
                    (closest_point_node + ".closestVertexIndex"))) + "]"
            )  # Find mirrored vertex
            vertex[
                0] = mirrored_vertex  # Replace previous pair vertex with new found one
            mirrored_vertices.append(mirrored_vertex)
            cmds.delete(closest_point_node)  # Delete utility node

        cluster_deformer_node = cmds.listConnections(
            (cluster_handle + ".worldMatrix[0]"),
            type="cluster",
            destination=1)
        is_relative = cmds.getAttr((cluster_deformer_node[0] + ".relative"))

        new_cluster_name = cluster_handle.replace(
            cmds.textField("search_text_field", q=True, text=True),
            cmds.textField("replace_text_field", q=True, text=True))
        new_cluster = cmds.cluster(mirrored_vertices, rel=is_relative)

        #Transfer weight back to new cluster
        for num in range(len(verticies_selected_mesh)):
            cmds.percent(new_cluster[0],
                         verticies_selected_mesh[num][0],
                         v=verticies_selected_mesh[num][1])

        cmds.rename(new_cluster_name)
    else:
        cmds.warning(
            "Something went wrong. Please try loading the objects again.")
Exemplo n.º 43
0
def ribbonBuild():
    
    # check for matrixNodes.mll plug (comes with Maya, but might be off)
    
    if cmds.pluginInfo('matrixNodes.mll', q=True) == False:
        cmds.loadPlugin('matixNodes.mll')
        
    max = 3
    rstats = ["castsShadows", "receiveShadows", "motionBlur", "primaryVisibility", "smoothShading", "smoothShading", "visibleInReflections", "visibleInRefractions"]
    locGrp = cmds.group( em=True, n="ribbon_grp_#" )
    
    # set primary vector (down the chain, i.e: x, y or z) and other default values
    
    jointDown = 'x'
    divisions = 3
    planeW  = divisions * 2
    posIncr = 0
    increment = 0.5
    v = 0.5
    
    # create the ribbon nurb surface
    
    nameFP = cmds.nurbsPlane( ch=False, u=divisions, v=1, ax=[0,1,0], p=[0,0,0], lr=0.2, w=planeW, n="ribbonPlane1" )[0]
    
    # diag print
    
    print( increment )
    print( posIncr )
    
    for i in xrange(0, divisions):
        
        posNode = cmds.pointOnSurface( nameFP, ch=True, top=1, u=posIncr, v=0.5 )
        posLoc = cmds.group(em=True, n='posNode_'+ str(i))
        cmds.connectAttr( '{0}.position'.format(posNode), '{0}.translate'.format(posLoc) )
        
        posIncr += 0.5
        
        posX = cmds.getAttr( '{0}.positionX'.format(posNode) )
        posY = cmds.getAttr( '{0}.positionY'.format(posNode) )
        posZ = cmds.getAttr( '{0}.positionZ'.format(posNode) )
        
        newJoint = cmds.joint(p=[posX, posY, posZ], n='ribbon_jnt_bn')
        
        # set-up parent rotations for joints to follow surface correctly
        # this follows a process similar to Michael Bazhutkin's river script
        
        aimCon = cmds.createNode('aimConstraint')
        cmds.connectAttr( '{0}.normal'.format(posNode), '{0}.target[0].targetTranslate'.format(aimCon), f=True )
        cmds.connectAttr( '{0}.tangentV'.format(posNode), '{0}.worldUpVector'.format(aimCon), f=True )
        cmds.connectAttr( '{0}.constraintRotate'.format(aimCon), '{0}.rotate'.format(posLoc), f=True )
        
        cmds.parent(aimCon, posLoc)
        cmds.parent(posLoc, locGrp)
        
		# switch statement look-alike for py..
		
        for case in switch(jointDown):
			if case('x'):
				cmds.setAttr( '{0}.aimVector'.format(aimCon), type='double3', *list( (0,1,0) ) )
				cmds.setAttr( '{0}.upVector'.format(aimCon), type='double3', *list( (0,0,1) ) )
				break
			if case('y'):
				cmds.setAttr( '{0}.aimVector'.format(aimCon), type='double3', *list( (0,1,0) ) )
				cmds.setAttr( '{0}.upVector'.format(aimCon), type='double3', *list( (0,0,1) ) )
				break
			if case('z'):
				cmds.setAttr( '{0}.aimVector'.format(aimCon), type='double3', *list( (0,1,0) ) )
				cmds.setAttr( '{0}.upVector'.format(aimCon), type='double3', *list( (0,0,1) ) )
				break
			if case(): #default
				print("Couldn't found a valid joint down value (x, y, z")
				
	
    #print 'lol'
    topCtrl = cmds.circle( n='ribbon1_top_ctrl', ch=False )[0]
    botCtrl = cmds.circle( n='ribbon1_bottom_ctrl', ch=False )[0]
    midCtrl = cmds.circle( n='ribbon1_mid_ctrl', ch=False )[0]
    
    # set to origin (creation points were recorded away from origin, otherwise this would be unnecessary)
    
    setToOrigin(topCtrl)
    setToOrigin(botCtrl)
    
    # two more curves that will serve as the god ctrl
    
    leftMainCurve = cmds.circle( n='pHolder_1', ch=False, r=0.3)[0]
    rightMainCurve = cmds.circle( n='pHolder_2',ch=False, r=0.3)[0]
    
    setToOrigin(leftMainCurve)
    setToOrigin(rightMainCurve)
    
    # groupFreeze stuff
    
    topOffset = grpFreeze(topCtrl)
    botOffset = grpFreeze(botCtrl)
    midOffset = grpFreeze(midCtrl)
    
    # position things
    
    topCtrlPOS = cmds.pointOnSurface(nameFP, ch=False, p=True, u=1, v=0.5)
    midCtrlPOS = cmds.pointOnSurface(nameFP, ch=False, p=True, u=0.5, v=0.5)
    botCtrlPOS = cmds.pointOnSurface(nameFP, ch=False, p=True, u=0, v=0.5)
    
    cmds.setAttr('{0}.translate'.format(topOffset), *topCtrlPOS )
    cmds.setAttr('{0}.translate'.format(midOffset), *midCtrlPOS )
    cmds.setAttr('{0}.translate'.format(botOffset), *botCtrlPOS )
    
    midCtrlPOS[2] -= 1.5
    cmds.setAttr('{0}.translate'.format(rightMainCurve), *midCtrlPOS )
    midCtrlPOS[2] += 3.0
    cmds.setAttr('{0}.translate'.format(leftMainCurve), *midCtrlPOS )
    midCtrlPOS[2] -= 1.5
    
    # create god ctrl for ribbon
    mainCtrl = cmds.group(em=True, n='ribbon_main_ctrl')
    parentShape(rightMainCurve, mainCtrl)
    parentShape(leftMainCurve, mainCtrl)
    mainCtrlOffset = grpFreeze(mainCtrl)
    
    # point constraint god ctrl freeze grp between top and bot
    midCtrlPC = cmds.pointConstraint( topCtrl, botCtrl, midOffset, mo=False, w=1)
    
    # create bShape for surface
    bShape = cmds.duplicate(nameFP, n='ribbon_bShape_1')[0]
    cmds.xform(bShape, ws=True, t=[0,0,5])
    bShapeNode = cmds.blendShape(bShape, nameFP, en=1, n='ribbon_blendNode_1')
    cmds.setAttr('{0}.{1}'.format(bShapeNode[0],bShape), 1)
    
    # get POSI position of 0%, 50% and 100% of surface to get wire curve positions
    cInitPOS = cmds.pointOnSurface(bShape, p=True, top=1, u=0.0, v=0.5)
    cMidPOS = cmds.pointOnSurface(bShape, p=True, top=1, u=0.5, v=0.5)
    cEndPOS = cmds.pointOnSurface(bShape, p=True, top=1, u=1, v=0.5)
    
    # wire, clusters
    rWireCurve = cmds.curve( n='ribbon_wire_curve_1', p=[ cInitPOS, cMidPOS, cEndPOS ], d=2, k=[0,0,1,1] )
    wireCIn = cmds.cluster('{0}.cv[0:1]'.format(rWireCurve), rel=True, en=1, n='ribbon_wireCL_init_1')
    wireCMid = cmds.cluster('{0}.cv[1]'.format(rWireCurve), rel=True, en=1, n='ribbon_wireCL_mid_1')
    wireCEnd = cmds.cluster('{0}.cv[1:2]'.format(rWireCurve), rel=True, en=1, n='ribbon_wireCL_end_1')
    
    # cluster pivots and origins
    cDict = { wireCIn[1] : cInitPOS, wireCMid[1] : cMidPOS, wireCEnd[1] : cEndPOS }
    for cl, pos in cDict.items():
        #print pos
        cmds.xform(cl, pivots= pos)
        cmds.setAttr('{0}Shape.origin'.format(cl), *pos)
    
    # cluster weights    
    cmds.percent(wireCIn[0], '{0}.cv[1]'.format(rWireCurve), v=0.5 )
    cmds.percent(wireCEnd[0], '{0}.cv[1]'.format(rWireCurve), v=0.5 )
    
    # bShape deformers [could also just skin surface to previously created joints..]
    wireDeformer = cmds.wire(bShape, dds=[(1,25), (0,25)], en=1, ce=0, li=0, w=rWireCurve, n='ribbon_bShape_wireNode_1')
    twistDeformer = cmds.nonLinear( bShape, type='twist', foc=1, n='ribbon_bShape_twistNode_1')
    cmds.setAttr('{0}.rotateZ'.format(twistDeformer[1]), 90)
    cmds.hide(twistDeformer[1])
    
    for attr in rstats:
        cmds.setAttr('{0}Shape.{1}'.format(bShape, attr), 0)
        cmds.setAttr('{0}Shape.{1}'.format(nameFP, attr), 0)
    
    # connect controls to cluster handles    
    ctrlDict = {topCtrl : wireCEnd[1], midCtrl : wireCMid[1], botCtrl : wireCIn[1] }
    for ctrl, cl in ctrlDict.items():
        cmds.connectAttr('{0}.translate'.format(ctrl), '{0}.translate'.format(cl), f=True )
    
    cmds.connectAttr('{0}.rotateX'.format(botCtrl), '{0}.endAngle'.format(twistDeformer[0]) )
    cmds.connectAttr('{0}.rotateX'.format(topCtrl), '{0}.startAngle'.format(twistDeformer[0]) )
    
    # group stuff
    
    controlsGrp = cmds.group(em=True, n='ribbon_controls_grp_1')
    cmds.parent( topOffset, midOffset, botOffset, controlsGrp )
    
    clustersGrp = cmds.group(em=True, n='ribbon_clusters_grp_1')
    cmds.parent( wireCIn[1], wireCMid[1], wireCEnd[1], clustersGrp )
    
    moveGrp = cmds.group(em=True, n='ribbon_move_grp_1')
    cmds.parent(controlsGrp, nameFP, moveGrp)
    
    extraGrp = cmds.group(em=True, n='ribbon_extras_grp_1')
    cmds.parent( clustersGrp, locGrp, rWireCurve, '{0}BaseWire'.format(rWireCurve), bShape, twistDeformer[1], extraGrp)
    
    godGrp = cmds.group(em=True, n='ribbon_main_grp_1')
    cmds.parent( extraGrp, mainCtrlOffset, godGrp )
    cmds.parent( moveGrp, mainCtrl )
    
    toHideList = [ bShape, rWireCurve, clustersGrp ]
    for object in toHideList:
        cmds.hide(object)
    
    locators = cmds.listRelatives(locGrp, c=True)
    for loc in locators:
        cmds.scaleConstraint(moveGrp, loc, offset=[1,1,1])
Exemplo n.º 44
0
    def buildDeformers(self, ribbonPlane, controls=(), folGrp=()):
        # Create a target blendshape controlled by deformers
        flexiBlend = cmds.duplicate(ribbonPlane,
                                    n='flexiPlaneSetup_bShp_surface01')
        flexiBlendNode = cmds.blendShape(flexiBlend,
                                         ribbonPlane,
                                         n='%s_bShpNode_surface01' % self.name)

        # Turn blendshape on
        cmds.setAttr('%s.%s' % (flexiBlendNode[0], flexiBlend[0]), 1)

        # Create a wire deformer controled by ribbon controls
        wireCurve = cmds.curve(n='%s_wire_surface01' % self.name,
                               d=2,
                               p=[(-self.numJnts, 0, 0), (0, 0, 0),
                                  (self.numJnts, 0, 0)])
        topClstr = cmds.cluster('%s.cv[0:1]' % wireCurve,
                                rel=1,
                                n='%s_cl_a01' % self.name)
        midClstr = cmds.cluster('%s.cv[1]' % wireCurve,
                                rel=1,
                                n='%s_cl_mid01' % self.name)
        botClstr = cmds.cluster('%s.cv[1:2]' % wireCurve,
                                rel=1,
                                n='%s_cl_b01' % self.name)
        clsGrp = cmds.group(topClstr,
                            midClstr,
                            botClstr,
                            n='%s_cls01' % self.name)

        for attr in ['scalePivot', 'rotatePivot']:
            cmds.setAttr('%s.%s' % (topClstr[1], attr), -self.numJnts, 0, 0)
        for attr in ['scalePivot', 'rotatePivot']:
            cmds.setAttr('%s.%s' % (botClstr[1], attr), self.numJnts, 0, 0)

        cmds.setAttr('%sShape.originX' % topClstr[1], (-self.numJnts))
        cmds.setAttr('%sShape.originX' % botClstr[1], (self.numJnts))
        cmds.percent(topClstr[0], '%s.cv[1]' % wireCurve, v=0.5)
        cmds.percent(botClstr[0], '%s.cv[1]' % wireCurve, v=0.5)

        # Create twist and wire blend shape deformers
        twistNode = cmds.nonLinear(flexiBlend, type='twist')
        cmds.wire(flexiBlend,
                  w=wireCurve,
                  dds=[0, 20],
                  foc=0,
                  n='%s_wireAttrs_surface01' % self.name)
        cmds.xform(twistNode, ro=(0, 0, 90))
        twistNode[0] = cmds.rename(twistNode[0],
                                   '%s_twistAttrs_surface01' % self.name)
        twistNode[1] = cmds.rename(twistNode[1],
                                   '%s_twist_surface01' % self.name)

        # Setup squash and stretch via utilitiy nodes
        arcLen = cmds.arclen(wireCurve, ch=1)
        arcLen = cmds.rename(arcLen, '%s_curveInfo01' % self.name)
        arcLenValue = cmds.getAttr('%s.arcLength' % arcLen)
        squashDivNode = cmds.createNode('multiplyDivide',
                                        n='%s_div_squashStretch_length01' %
                                        self.name)
        volDivNode = cmds.createNode('multiplyDivide',
                                     n='%s_div_volume01' % self.name)
        squashCondNode = cmds.createNode('condition',
                                         n='%s_cond_volume01' % self.name)

        cmds.setAttr('%s.operation' % squashDivNode, 2)
        cmds.setAttr('%s.input2X' % squashDivNode, arcLenValue)
        cmds.setAttr('%s.operation' % volDivNode, 2)
        cmds.setAttr('%s.input1X' % volDivNode, 1)
        cmds.setAttr('%s.secondTerm' % squashCondNode, 1)

        cmds.connectAttr('%s.arcLength' % arcLen, '%s.input1X' % squashDivNode)
        cmds.connectAttr('%s.outputX' % squashDivNode,
                         '%s.input2X' % volDivNode)
        cmds.connectAttr('%s.outputX' % volDivNode,
                         '%s.colorIfTrueR' % squashCondNode)

        # Set visibility options
        for obj in [flexiBlend[0], wireCurve, twistNode[1], clsGrp]:
            cmds.setAttr('%s.visibility' % obj, 0)

        # Connect controls to cluster deformers if they exist
        if len(controls) > 1:
            topCon = controls[0][0]
            botCon = controls[0][1]
            midCon = controls[0][2]

            for con, clstr in zip([topCon, botCon],
                                  [topClstr[1], botClstr[1]]):
                cmds.connectAttr('%s.translate' % con, '%s.translate' % clstr)

            cmds.connectAttr('%s.translate' % midCon,
                             '%s.translate' % midClstr[1])

            # Connect controls to twist deformer
            cmds.connectAttr('%s.rotateX' % topCon,
                             '%s.endAngle' % twistNode[0])
            cmds.connectAttr('%s.rotateX' % botCon,
                             '%s.startAngle' % twistNode[0])
            cmds.connectAttr('%s.volEnable' % controls[1],
                             '%s.firstTerm' % squashCondNode)

        # Scale contraint each follicle to global move group
        for fol in cmds.listRelatives(folGrp, c=1):
            cmds.scaleConstraint(self.moveGrp, fol, mo=0)
            for shape in cmds.listRelatives(fol, s=1):
                cmds.setAttr('%s.visibility' % shape, 0)

        # Parent nodes
        cmds.parent(flexiBlend, wireCurve, clsGrp, twistNode[1],
                    '%s_wire_surface01BaseWire' % self.name, self.extrasGrp)
Exemplo n.º 45
0
def importDeformersByMirroredObject(dagnode, file):

    # look for the mapping
    if not os.path.exists(file):
        rigUtils.log('Skin file not found - skipping: %s' % file)
        return

    rigUtils.log('Reading file: %s' % file)

    f = open(file, 'r')
    j = json.loads(f.read())
    f.close()

    # get the mirrored object
    buffer = dagnode.split('_')
    locus = buffer[0][-1]

    if locus == 'R':
        buffer[0] = '%sL' % buffer[0][:-1]
        mirror = string.join(buffer, '_')
    elif locus == 'L':
        buffer[0] = '%sR' % buffer[0][:-1]
        mirror = string.join(buffer, '_')
    else:
        rigUtils.log('Select a valid mesh')
        return

    if mirror not in j:
        rigUtils.log('Mirror object not found in json file: %s' % mirror)
        return

    # get the skin cluster on the target object
    skincluster = rigUtils.findSkinClusterOnNode(dagnode)

    # step through the deformers of the mirrored object
    dict = j[mirror]
    for mirrorDeformer in dict:

        if mirrorDeformer == 'skinCluster': continue
        if not cmds.objExists(mirrorDeformer): continue

        # get the corresponding deformer on the target object
        buffer = mirrorDeformer.split('_')
        locus = buffer[0][-1]

        if locus == 'R':
            buffer[0] = '%sL' % buffer[0][:-1]
            deformer = string.join(buffer, '_')
        elif locus == 'L':
            buffer[0] = '%sR' % buffer[0][:-1]
            deformer = string.join(buffer, '_')
        else:
            deformer = mirrorDeformer

        pointdata = dict[mirrorDeformer]
        set = '%sSet' % deformer

        # ffd
        if cmds.objectType(deformer, isType='ffd'):
            i = 0
            while(True):
                if i == len(pointdata): break
                if pointdata[i] == '1' and cmds.objExists(set):
                    cmds.sets('%s.vtx[%s]' % (dagnode, i), add=set)
                i = i + 1
            continue

        # if the corresponding deformer isn't influencing the target object, make it so
        existingdeformers = mel.eval('findRelatedDeformer "%s"' % dagnode)
        if not deformer in existingdeformers:
            if cmds.objExists(set): cmds.sets(dagnode, add=set)

        # step through each vert and update the weights for the target objects deformer
        i = 0
        while(True):
            if i == len(pointdata): break
            value = pointdata[i]
            cmds.percent(deformer, '%s.vtx[%s]' % (dagnode, i), v=float(value))
            i = i + 1

        # rearrange the deformers to come before any skincluster
        if skincluster: cmds.reorderDeformers(skincluster, deformer, dagnode)

        rigUtils.log('Deformer weighting updated: %s' % deformer)
Exemplo n.º 46
0
 def __createPanelCtrls(self, baseJnts):
     """
     create controller for panel
     """       
     if not(self.lEyeLoc):
         print "create the face locators"
     if not cmds.objExists(self.eyelidCrvGrpName):
         eyeLidCrvGrp = cmds.group(em =1, n = self.eyelidCrvGrpName, p = self.crvGrp)
         
     allLidsCtlGrp = []
     for ud in self.uploPrefix:
         for lr in self.prefix:
             #- left right + upper lower prefix
             uploPrefix = lr + ud
             ctlP = uploPrefix + "Ctrl0"
             kids = cmds.listRelatives(ctlP, ad=True, type ='transform')   
             if kids:
                 cmds.delete(kids)
             lidJnts = cmds.ls(uploPrefix +  self.blinkJntName + "*" + self.jntSuffix, type = 'joint')
             lidJntsLen = len(lidJnts)
 
             #- making lids Ctrl group
             lidsCtrlGrp = cmds.group(em=True, w =True, n = uploPrefix + self.eyelidName + self.ctlSuffix + self.grpSuffix)
             cmds.parent(lidsCtrlGrp, ctlP)
             allLidsCtlGrp.append(lidsCtrlGrp)
             cntPos = cmds.xform(ctlP, q=1, ws =1, t = 1)
             
             #- creating controller 
             if lr == self.prefix[0]:
                 cColor = 6
             else:
                 cColor = 17
                 
             for pos in ['Center', 'InCorner', 'OutCorner']:
                 lidCtl, lidCtlP = self.circleController(uploPrefix + pos + self.ctlSuffix,
                                                         'xy',
                                                         self.ctlSize * 0.1,
                                                         color = cColor,
                                                         lockAttr = ['tz',
                                                                     'sc',
                                                                     'ro',
                                                                     'vi'])
                 cmds.xform(lidCtlP, ws = True, t =(cntPos[0], cntPos[1], cntPos[2]))
                 cmds.parent(lidCtlP, lidsCtrlGrp)
                 if pos == 'InCorner':
                     cmds.setAttr(lidCtl +'.tx', -1)
                 elif pos == 'OutCorner':
                     cmds.setAttr(lidCtl +'.tx', 1)
             details = []
             for i in range(1, lidJntsLen+1):
                 detailCtl = self.circleController(uploPrefix + 'Detail'+ str(i).zfill(2) + self.ctlSuffix,
                                                   'xy',
                                                   self.ctlSize * 0.05,
                                                   color = cColor,
                                                   lockAttr = ['tz',
                                                               'sc',
                                                               'ro',
                                                               'vi'])
                 details.append(detailCtl[0])
                 detailCtlP = detailCtl[1]
                 cmds.parent(detailCtlP, ctlP)
                 increment = 2.0 /(lidJntsLen+1)
                 cmds.setAttr(detailCtlP + ".tx", increment*i - 1.0)
                 cmds.setAttr(detailCtlP + ".ty", 0)
                 cmds.setAttr(detailCtlP + ".tz", 0)
 
             #- eyelids controller curve shape(different number of points)          
             tempCtlCrv = cmds.curve(d = 3, p =([0,0,0],[0.33,0,0],[0.66,0,0],[1,0,0])) 
             cmds.rebuildCurve(tempCtlCrv, rt = 0, d = 3, kr = 0, s = 2)   
             lidCtlCrv = cmds.rename(tempCtlCrv, uploPrefix +'Ctl' + self.crvSuffix)
             cmds.parent(lidCtlCrv, self.eyelidCrvGrpName) 
             ctlCrvCv = cmds.ls(lidCtlCrv + '.cv[*]', fl =True)#!!check same curve exist if Error : list index out of range
                     
             #- corner twist curves setup(curves for corner Adjust 06/23/2016)
             cornerCrv = cmds.duplicate(lidCtlCrv, n = uploPrefix +'Corner' + self.crvSuffix)
             cornerCrvCv = cmds.ls(cornerCrv[0] + '.cv[*]', fl =True)
 
             if self.uploPrefix[0] in uploPrefix:
                 inCls = cmds.cluster(cornerCrvCv[0:2], n = uploPrefix[:2] +'inTwistCls')
                 cmds.percent(inCls[0], cornerCrvCv[1],  v = 0.3)
                 cmds.parent(inCls, self.eyelidClsGrpName)
                 outCls = cmds.cluster(cornerCrvCv[3:5], n = uploPrefix[:2] +'outTwistCls')
                 cmds.percent(outCls[0], cornerCrvCv[3], v = 0.3)
                 cmds.parent(outCls, self.eyelidClsGrpName)
                 
             elif self.uploPrefix[1] in uploPrefix:
                 cmds.sets(cornerCrvCv[0:2], add = uploPrefix[:2] +'inTwistClsSet')
                 cmds.percent(uploPrefix[:2] +'inTwistCls', cornerCrvCv[1], v = 0.3) 
                 cmds.sets(cornerCrvCv[3:5], add = uploPrefix[:2] +'outTwistClsSet')
                 cmds.percent(uploPrefix[:2] +'outTwistCls', cornerCrvCv[3], v = 0.3)
                 
                 #- corner twist setup(no need to use ClsHandle.rotateZ)
                 cmds.connectAttr(uploPrefix[:2] + self.innerOuter[0] + "LidTwist.tx" , uploPrefix[:2] +'inTwistClsHandle.tx')
                 cmds.connectAttr(uploPrefix[:2] + self.innerOuter[0] + "LidTwist.ty" , uploPrefix[:2] +'inTwistClsHandle.ty')
                 
                 cmds.connectAttr(uploPrefix[:2] + self.innerOuter[1] + "LidTwist.tx" , uploPrefix[:2] +'outTwistClsHandle.tx')
                 cmds.connectAttr(uploPrefix[:2] + self.innerOuter[1] + "LidTwist.ty" , uploPrefix[:2] +'outTwistClsHandle.ty')
 
             #- lidCtl drive the center controlPoints on ctlCrv
             #corner ctls setup                    
             cmds.connectAttr(uploPrefix + "InCorner" + self.ctlSuffix + ".ty" , ctlCrvCv[0] + ".yValue")
             cmds.connectAttr(uploPrefix + "InCorner" + self.ctlSuffix + ".ty" , ctlCrvCv[1] + ".yValue")
             cmds.setAttr(ctlCrvCv[0] + ".xValue" , lock = True)     
             cmds.setAttr(ctlCrvCv[1] + ".xValue" , lock = True) 
 
             cmds.connectAttr(uploPrefix + "OutCorner" + self.ctlSuffix + ".ty" , ctlCrvCv[3] + ".yValue")
             cmds.connectAttr(uploPrefix + "OutCorner" + self.ctlSuffix + ".ty" , ctlCrvCv[4] + ".yValue")
             cmds.setAttr(ctlCrvCv[3] + ".xValue", lock = True)  
             cmds.setAttr(ctlCrvCv[4] + ".xValue", lock = True)
                                  
             cntAddD = cmds.shadingNode('addDoubleLinear', asUtility=True, n= uploPrefix + "Cnt_AddD")    
             if self.prefix[0] in uploPrefix: #left
                 #- center ctrl.tx drives center point(lidCtl_crv) 
                 lCntMult = cmds.shadingNode('multiplyDivide', asUtility=True, n = uploPrefix +'Cnt_mult') 
                 cmds.connectAttr(uploPrefix + "Center" + self.ctlSuffix + ".tx", cntAddD + ".input1")
                 cmds.setAttr(cntAddD + ".input2", 0.5) 
                 cmds.connectAttr(cntAddD + ".output" , ctlCrvCv[2] + ".xValue")
                 #- center ctrl.ty drives ctlCrv center cv[2].yValue
                 cmds.connectAttr(uploPrefix + "Center" + self.ctlSuffix + ".ty" , lCntMult + ".input1Y")
                 cmds.setAttr(lCntMult + ".input2Y", 2) 
                 cmds.connectAttr(lCntMult + ".outputY", ctlCrvCv[2] + ".yValue")                
                 
             if self.prefix[1] in uploPrefix: #right
                 #- center ctrl.tx drives ctlCrv center cv[2].xValue 
                 rCntMult = cmds.shadingNode('multiplyDivide', asUtility=True, n = uploPrefix +'Cnt_mult')
                 cmds.connectAttr(uploPrefix + "Center" + self.ctlSuffix + ".tx" , rCntMult + ".input1X") 
                 cmds.setAttr(rCntMult + ".input2X", -1)
                 cmds.connectAttr(rCntMult + ".outputX", cntAddD + ".input1")
                 cmds.setAttr(cntAddD + ".input2", 0.5) 
                 cmds.connectAttr(cntAddD + ".output" , ctlCrvCv[2] + ".xValue")            
                 #center ctrl.ty drives ctlCrv center cv[2].yValue 
                 cmds.connectAttr(uploPrefix + "Center" + self.ctlSuffix + ".ty" , rCntMult + ".input1Y")
                 cmds.setAttr(rCntMult + ".input2Y", 2) 
                 cmds.connectAttr(rCntMult + ".outputY", ctlCrvCv[2] + ".yValue") 
 
             detailPCtls = cmds.ls(uploPrefix + "Detail*" + self.grpSuffix, type = 'transform')
             incrementYPoc = 1.0/(lidJntsLen +1)
             incrementXPoc = 1.0/(lidJntsLen -1)    
             for i in range(1, lidJntsLen+1):
                 #- POC for positionX on the eyelids ctl curve 
                 ctlXPOC = cmds.shadingNode('pointOnCurveInfo', asUtility=True, n = uploPrefix + 'CtlXPoc' + str(i).zfill(2)) 
                 cmds.connectAttr(uploPrefix + "Ctl_crvShape.worldSpace", ctlXPOC + '.inputCurve')   
                 cmds.setAttr(ctlXPOC + '.turnOnPercentage', 1)        
                 cmds.setAttr(ctlXPOC + '.parameter', incrementXPoc *(i-1))
                 
                 #- POC for positionY on the eyelids ctl curve
                 ctlYPOC = cmds.shadingNode('pointOnCurveInfo', asUtility=True, n = uploPrefix + 'CtlYPoc' + str(i).zfill(2)) 
                 cmds.connectAttr(uploPrefix + "Ctl_crvShape.worldSpace", ctlYPOC + '.inputCurve')   
                 cmds.setAttr(ctlYPOC + '.turnOnPercentage', 1)        
                 cmds.setAttr(ctlYPOC + '.parameter', incrementYPoc *i)
                 
                 #- POC on ctlCrv drive detail control parent  
                 cntRemoveX = cmds.shadingNode('addDoubleLinear', asUtility=True, n= uploPrefix +"RemoveX"+ str(i).zfill(2))
                 momMult = cmds.shadingNode('multiplyDivide', asUtility=True, n = uploPrefix +'Mom'+ str(i).zfill(2)+'_mult')
                 cmds.connectAttr(ctlYPOC +".positionY", detailPCtls[i-1] + ".ty")
                 
                 #- Xvalue match between POC and CtrlP(detailPCtls[i] = 2*ctlPoc -1)
                 cmds.connectAttr(ctlXPOC +".positionX", momMult + ".input1X")
                 cmds.setAttr(momMult + ".input2X", 2)        
                 cmds.connectAttr(momMult + ".outputX", cntRemoveX + ".input1")            
                 cmds.setAttr(cntRemoveX  + ".input2", -1)
                 cmds.connectAttr(cntRemoveX +".output", detailPCtls[i-1] + ".tx")
                 
                 #- curves for corner Adjust 06/23/2016
                 cornerPOC = cmds.shadingNode('pointOnCurveInfo', asUtility=True, n = uploPrefix + 'CornerPoc' + str(i).zfill(2)) 
                 cmds.connectAttr(uploPrefix +"Corner" + self.crvSuffix + ".worldSpace", cornerPOC + '.inputCurve')   
                 cmds.setAttr(cornerPOC + '.turnOnPercentage', 1)        
                 cmds.setAttr(cornerPOC + '.parameter', incrementXPoc*(i-1))   
Exemplo n.º 47
0
def nmpWrapToJoints():
    ''' Main Function for Extracting the Wrap Weights to Each Joint '''
    # Query Selected Geo with Wrap Deformer --- Get Geo Verts
    objects     = cmds.ls(sl=True, flatten=True)
    
    if not objects:
        raise Exception, 'Please Select Geometry'
    sourceVerts = []
    geoNames    = []
    
    # Separate SourceVerts from Wrapped Geos
    for obj in objects:
        if '.vtx' in obj:
            sourceVerts.append(obj)
        else:
            geoNames.append(obj)
    
    #----------------------------------------------------------------------------------------
    
    # Check for Wrap Deformer --- Retrieve Source Geo from Wrap
    wraps = []
    for geoName in geoNames:
        geoHistory = cmds.listHistory(geoName)
        wrap       = cmds.ls(geoHistory, type='wrap')
        destSkinCluster = nmpGetSkinFromGeo(geoName)
        if destSkinCluster:
            cmds.delete(destSkinCluster)
        if wrap:
            wraps.append(wrap[0])
        else:
            raise Exception, 'No Wrap Deformer Found on ' + geoName
            
    sourceGeo  = cmds.connectionInfo(wraps[0] + '.inflType[0]', sfd=True).split('.')[0]
    
    # If SourceGeo Wasn't Found Try Nurbs Surface Connection
    if not sourceGeo:
        sourceGeoShape  = cmds.connectionInfo(wraps[0] + '.driverPoints[0]', sfd=True).split('.')[0]
        sourceGeo = cmds.listRelatives(sourceGeoShape, p=True)[0]
        sourceVerts = cmds.ls(sourceGeo + '.cv[*]', flatten=True)
        
    #----------------------------------------------------------------------------------------
    
    # Get SkinCluster + Joints of SourceGeo
    indexes = []
    joints = []
    sourceSkinCluster = ''
    try:
        sourceSkinCluster = nmpGetSkinFromGeo(sourceGeo)            
    except:
        raise Exception, 'No SkinCluster Found on Source Geometry'
    
    nmpHoldUnholdInfluences(sourceSkinCluster)
    joints = cmds.skinCluster(sourceSkinCluster, q=True, inf=True)
       
    # If Source Verts Were Selected -> Find Out Which Joints are Affecting those Verts Only to Increase Speed
    if sourceVerts:
        weightedJoints = []      
        for vert in sourceVerts:
            valuesAll = cmds.skinPercent(sourceSkinCluster, vert, q=True, v=True)
            values = cmds.skinPercent(sourceSkinCluster, vert, q=True, v=True, ib=.0001)
            indexes = [ valuesAll.index(value) for value in values if value ]
            
            for i in indexes:
                if joints[i] not in weightedJoints:
                    weightedJoints.append( joints[i] )
                    
        #print 'Weighted Joints = ' + str(weightedJoints)
        indexes = [ joints.index(joint) for joint in weightedJoints ]
        joints = weightedJoints
    
    else:
        sourceVerts = cmds.ls(sourceGeo + '.vtx[*]', flatten=True)
        indexes = [ i for i in range(len(joints)) ]
    
    # Create A Cluster for Every Joint/Influence Object
    clusters, clusterHandles = [], []
    for joint in joints:
        cluster, clusterHan = cmds.cluster(sourceVerts)
        worldPos = cmds.xform(joint, q=True, ws=True, rp=True)
        cmds.xform(clusterHan, ws=True, rp=worldPos)
        cmds.setAttr(clusterHan + '.origin', worldPos[0],worldPos[1], worldPos[2])
        clusters.append(cluster)
        clusterHandles.append(clusterHan)
        
    length = len(sourceVerts)
    amount = 0
    cmds.progressWindow(title='Transferring Wrap Weights', progress=amount, status='Retrieving Joint Weights', isInterruptable=True )

    #----------------------------------------------------------------------------------------
    
    # Retrieve Joint Weights for Each Vert --> apply Those to each corresponding Cluster
    for a,vert in enumerate(sourceVerts):
        values = cmds.skinPercent(sourceSkinCluster, vert, q=True, v=True)
        
        for i,cluster in enumerate(clusters):
            cmds.percent(cluster, vert, v=values[indexes[i]])
            
        if cmds.progressWindow( query=True, isCancelled=True ) : break
        amount = int( str( a/float(length) * 100 ).split('.')[0] )
        cmds.progressWindow( edit=True, progress=amount, status=('Retrieving Joint Weights: ' + `amount` + '%' ) )
    
    #----------------------------------------------------------------------------------------
    
    # Check Each Joint in Source SkinCluster ---> Separate by type Joints and Influence Objects
    bindJoints = []
    influenceObjects = []
    for joint in joints:
        if cmds.nodeType(joint) == 'joint':
            bindJoints.append(joint)
        else:
            influenceObjects.append(joint)
    if not bindJoints:
        bindJoints.append( cmds.joint(p=[0,0,0], n='nmpTempJoint') )
                
    # Iterate Through Each Piece of Wrapped Geo --> Assign Skin Weights
    for i,geoName in enumerate(geoNames):
        destSkinCluster = cmds.skinCluster(bindJoints, geoName)[0]
        
        # Add Influence Objects To SkinCluster if They Exist in sourceSkinCluster
        if influenceObjects:
            cmds.skinCluster(destSkinCluster, e=True, ai=influenceObjects)
        
        # Get Weights for Each Joint - Return Value Per Cluster = [ [joint, distance], [joint, distance], ....... ]
        length = len(clusterHandles)
        amount = 0
        cmds.progressWindow(e=True, progress=amount, status= 'Calculating Wrap Weights...', isInterruptable=True )
        values = []
        for i,clusterHan in enumerate(clusterHandles):
            values.append( nmpExtractWeights(clusterHan, joints[i], destSkinCluster, geoName) )
            if cmds.progressWindow( query=True, isCancelled=True ) : break
            amount = int( str( i/float(length) * 100 ).split('.')[0] )
            cmds.progressWindow( edit=True, progress=amount, status=('Calculating Wrap Weights : %s...' % geoName  + `amount` + '%' ) )
    
        #----------------------------------------------------------------------------------------
    
        # Create List of Lists of Each Verts weights --- [ [transform, value] ]  --- Reduces Amount of skinPercent Calls
        vertWeights = [  ]
        verts = cmds.ls(geoName + '.vtx[*]', flatten=True)
        for i in range( len(verts) ):
            appendObj = []
            for i2 in range( len(values) ):
                appendObj.append( [ values[i2][0][0], values[i2][i][1] ])
                
            vertWeights.append(appendObj)
    
        length = len(verts)
        amount = 0
        cmds.progressWindow(e=True, progress=amount, status='Assigning Weights: ' + geoName, isInterruptable=True )
        
        # Clear All Weights to Avoid "Greater Than 1.0 Weight" Error
        cmds.setAttr(destSkinCluster + '.normalizeWeights', 0)
        cmds.skinPercent(destSkinCluster, geoName, pruneWeights=1.0 )
    
        #----------------------------------------------------------------------------------------
        
        # Assign SkinWeights
        for i,vert in enumerate(verts):
            cmds.skinPercent(destSkinCluster, vert, tv=vertWeights[i] )
            if cmds.progressWindow( query=True, isCancelled=True ) : break
            amount = int( str( i/float(length) * 100 ).split('.')[0] )
            cmds.progressWindow( edit=True, progress=amount, status=('Assigning Weights: ' + geoName + '  ' + `amount` + '%' ) )
        
        # Prune off any small excess weighting that normalizeing missed
        cmds.setAttr(destSkinCluster + '.normalizeWeights', 1)
        cmds.skinPercent(destSkinCluster, geoName, pruneWeights=.005 )

    cmds.delete(clusters, clusterHandles, wraps)
    try: cmds.delete('nmpTempJoint')
    except: pass
    cmds.progressWindow(endProgress=1)
    
    #----------------------------------------------------------------------------------------
    
    print 'Wrap Weights Transfered !!!',      
Exemplo n.º 48
0
    def buildStickyLips(cls, *args):
        '''
		Main method.
		'''

        # Duplicate geometry
        oriGeo = cls.upperLipEdges[0].rsplit('.e')[0]

        logger.debug('Geometry Name: %s' % oriGeo)

        dupGeo = cmds.duplicate(oriGeo, n=oriGeo + '_stickyLipsSrcCrv_geo')[0]

        cmds.select(dupGeo, r=True)
        tak_cleanUpModel.delHis()
        tak_cleanUpModel.delInterMediObj()

        cmds.select(oriGeo, dupGeo, r=True)
        tak_misc.TransSkinWeights()

        # Convert polygon edges to curves
        dupGeoUpperEdges = cls.rplcStrInList(cls.upperLipEdges, oriGeo, dupGeo)
        cmds.select(dupGeoUpperEdges, r=True)
        upperLipCrv = mel.eval('polyToCurve -form 2 -degree 3;')
        upperLipCrv = cmds.rename(upperLipCrv[0], 'upper_lip_sticky_crv')

        dupGeoLowerEdges = cls.rplcStrInList(cls.lowerLipEdges, oriGeo, dupGeo)
        cmds.select(dupGeoLowerEdges, r=True)
        lowerLipCrv = mel.eval('polyToCurve -form 2 -degree 3;')
        lowerLipCrv = cmds.rename(lowerLipCrv[0], 'lower_lip_sticky_crv')

        # Create sticky lips curve
        stickyLipsCrv = cmds.duplicate(upperLipCrv, n='stickyLips_crv')[0]

        stickyLipsCrvShp = cmds.listRelatives(stickyLipsCrv, s=True)[0]
        upperLipCrvShp = cmds.listRelatives(upperLipCrv, s=True)[0]
        lowerLipCrvShp = cmds.listRelatives(lowerLipCrv, s=True)[0]

        avgCrvNode = cmds.createNode('avgCurves', n='stickyLips_avgCurve')
        cmds.setAttr('%s.automaticWeight' % avgCrvNode, 0)
        cmds.setAttr('%s.normalizeWeights' % avgCrvNode, 0)
        cmds.connectAttr('%s.worldSpace[0]' % upperLipCrvShp,
                         '%s.inputCurve1' % avgCrvNode)
        cmds.connectAttr('%s.worldSpace[0]' % lowerLipCrvShp,
                         '%s.inputCurve2' % avgCrvNode)
        cmds.connectAttr('%s.outputCurve' % avgCrvNode,
                         '%s.create' % stickyLipsCrvShp)

        # Grouping
        stklGrp = cmds.createNode('transform', n='stickyLips_grp')
        cmds.parent(dupGeo, upperLipCrv, lowerLipCrv, stickyLipsCrv, stklGrp)
        cmds.setAttr('%s.visibility' % stklGrp, 0)

        # Assign wire deformer to the geometry
        wire = cmds.wire(oriGeo, w=stickyLipsCrv)[0]
        cmds.setAttr('%s.scale[0]' % wire, 0)
        cmds.setAttr('%s.envelope' % wire, 2)
        cmds.setAttr('%s.envelope' % wire, lock=True)
        cmds.connectAttr('%s.outputCurve' % avgCrvNode,
                         '%sBaseWireShape.create' % stickyLipsCrv)

        # Weighting
        vtxNumber = cmds.polyEvaluate(oriGeo, vertex=True)
        cmds.percent(wire, '%s.vtx[0:%d]' % (oriGeo, vtxNumber - 1), v=0)
        wireVtxList = cmds.polyListComponentConversion(cls.upperLipEdges,
                                                       cls.lowerLipEdges,
                                                       tv=True)
        cmds.percent(wire, wireVtxList, v=1)
Exemplo n.º 49
0
def createRibbon(*args):
    #Gather information
    width     = cmds.floatField('widthField', query=True, value=True)
    numJoints = cmds.intField('jointsField', query=True, value=True)
    prefix    = cmds.textField('prefixField', query=True, text=True)
    scaleGrp  = cmds.textField('scaleGrpField', query=True, text=True)
    topPoint  = (width/2)
    endPoint  = (width/2*-1)


    #Create the main groups
    grpNoTransform = cmds.group(empty=True, name=(prefix + 'noTransform_grp'))
    grpTransform   = cmds.group(empty=True, name=(prefix + 'transform_grp'))
    grpCtrl        = cmds.group(empty=True, name=(prefix + 'ctrl_grp'), parent=grpTransform)
    grpSurface     = cmds.group(empty=True, name=(prefix + 'surface_grp'), parent=grpTransform)
    grpSurfaces    = cmds.group(empty=True, name=(prefix + 'surfaces_grp'), parent=grpNoTransform)
    grpDeformers   = cmds.group(empty=True, name=(prefix + 'deformer_grp'), parent=grpNoTransform)
    grpFollMain    = cmds.group(empty=True, name=(prefix + 'follicles_skin_grp'), parent=grpNoTransform)
    grpFollVolume  = cmds.group(empty=True, name=(prefix + 'follicles_volume_grp'), parent=grpNoTransform)
    grpCluster     = cmds.group(empty=True, name=(prefix + 'cluster_grp'), parent=grpNoTransform)
    grpMisc        = cmds.group(empty=True, name=(prefix + 'misc_grp'), parent=grpNoTransform)


    #Create a NURBS-plane to use as a base
    tmpPlane = cmds.nurbsPlane(axis=(0,1,0), width=width, lengthRatio=(1.0 / width), u=numJoints, v=1, degree=3, ch=0)[0]
    #Create the NURBS-planes to use in the setup
    geoPlane       = cmds.duplicate(tmpPlane, name=(prefix + 'geo'))
    geoPlaneTwist  = cmds.duplicate(tmpPlane, name=(prefix + 'twist_blnd_geo'))
    geoPlaneSine   = cmds.duplicate(tmpPlane, name=(prefix + 'sine_blnd_geo'))
    geoPlaneWire   = cmds.duplicate(tmpPlane, name=(prefix + 'wire_blnd_geo'))
    geoPlaneVolume = cmds.duplicate(tmpPlane, name=(prefix + 'volume_geo'))
    #Offset the volume-plane
    cmds.setAttr((geoPlaneVolume[0] + '.translateZ'), -0.5)
    #Delete the base surface
    cmds.delete(tmpPlane)


    #Create the controllers
    ctrlTop = createCurveCtrl(name=(prefix + 'top_ctrl'), freezeTransforms=1, color=9, pos=(topPoint,0,0))
    ctrlMid = createCurveCtrl(name=(prefix + 'mid_ctrl'), freezeTransforms=1, color=9, pos=(0,0,0))
    ctrlEnd = createCurveCtrl(name=(prefix + 'end_ctrl'), freezeTransforms=1, color=9, pos=(endPoint,0,0))
    #Group the controllers
    grpTop = grpObject(objects=[ctrlTop], snapTrans=1, keepTransforms=0, keepHi=1, empty=0, suffix='_grp')[0]
    grpMid = grpObject(objects=[ctrlMid], snapTrans=1, keepTransforms=0, keepHi=1, empty=0, suffix='_grp')[0]
    grpEnd = grpObject(objects=[ctrlEnd], snapTrans=1, keepTransforms=0, keepHi=1, empty=0, suffix='_grp')[0]
    #PointConstraint the midCtrl between the top/end
    midConst = cmds.pointConstraint(ctrlTop, ctrlEnd, grpMid)


    #Add attributes: Twist/Roll attributes
    addAttribute(objects=[ctrlTop,ctrlMid,ctrlEnd],longName=['twistSep'],niceName=['---------------'],at="enum",en='Twist',lock=1,k=True)
    addAttribute(objects=[ctrlTop,ctrlEnd],longName=['twist'],at="float",k=True)
    addAttribute(objects=[ctrlTop,ctrlEnd],longName=['twistOffset'],at="float",k=True)
    addAttribute(objects=[ctrlTop,ctrlEnd],longName=['affectToMid'],at="float",min=0, max=10,dv=10,k=True)
    addAttribute(objects=[ctrlMid],longName=['roll'],at="float",k=True)
    addAttribute(objects=[ctrlMid],longName=['rollOffset'],at="float",k=True)
    #Add attributes: Volume attributes
    addAttribute(objects=[ctrlMid],longName=['volumeSep'],niceName=['---------------'],at="enum",en='Volume',lock=1,k=True)
    addAttribute(objects=[ctrlMid],longName=['volume'],at="float",min=-1,max=1,k=True)
    addAttribute(objects=[ctrlMid],longName=['volumeMultiplier'],at="float",min=1,dv=3,k=True)
    addAttribute(objects=[ctrlMid],longName=['startDropoff'],at="float",min=0, max=1, dv=1,k=True)
    addAttribute(objects=[ctrlMid],longName=['endDropoff'],at="float",min=0, max=1, dv=1, k=True)
    addAttribute(objects=[ctrlMid],longName=['volumeScale'],at="float",min=endPoint*0.9, max=topPoint*2,k=True)
    addAttribute(objects=[ctrlMid],longName=['volumePosition'],min=endPoint,max=topPoint,at="float",k=True)
    #Add attributes: Sine attributes
    addAttribute(objects=[ctrlMid], longName=['sineSep'], niceName=['---------------'], attributeType='enum', en="Sine:", keyable=True, lock=1)
    addAttribute(objects=[ctrlMid], longName=['amplitude'], attributeType="float", keyable=True)
    addAttribute(objects=[ctrlMid], longName=['offset'], attributeType="float", keyable=True)
    addAttribute(objects=[ctrlMid], longName=['twist'], attributeType="float", keyable=True)
    addAttribute(objects=[ctrlMid], longName=['sineLength'], min=0.1, dv=2, attributeType="float", keyable=True)
    #Add attributes: Extra attributes
    addAttribute(objects=[ctrlMid],longName=['extraSep'],niceName=['---------------'],at="enum",en='Extra',lock=1,k=True)
    addAttribute(objects=[ctrlMid],longName=['showExtraCtrl'],at="enum",en='Hide:Show:',k=True)
    cmds.setAttr((ctrlMid + '.showExtraCtrl'), 1)


    #Create deformers: Twist deformer, Sine deformer, Squash deformer
    twistDef  = nonlinearDeformer(objects=[geoPlaneTwist[0]],  defType='twist',  name=geoPlaneTwist[0],  lowBound=-1, highBound=1, rotate=(0,0,90))
    sineDef   = nonlinearDeformer(objects=[geoPlaneSine[0]],   defType='sine',   name=geoPlaneSine[0],   lowBound=-1, highBound=1, rotate=(0,0,90))
    squashDef = nonlinearDeformer(objects=[geoPlaneVolume[0]], defType='squash', name=geoPlaneVolume[0], lowBound=-1, highBound=1, rotate=(0,0,90))
    cmds.setAttr((sineDef[0] + '.dropoff'), 1)
    #Create deformers: Wire deformer
    deformCrv = cmds.curve(p=[(topPoint,0,0),(0,0,0),(endPoint,0,0)], degree=2)
    deformCrv = cmds.rename(deformCrv, (prefix + 'ribbon_wire_crv'))
    wireDef = cmds.wire(geoPlaneWire, dds=(0,15), wire=deformCrv)
    wireDef[0] = cmds.rename(wireDef[0], (geoPlaneWire[0] + '_wire'))
    #Create deformers: Clusters
    clsTop = cmds.cluster((deformCrv + '.cv[0:1]'), relative=1)
    clsMid = cmds.cluster((deformCrv + '.cv[1]'), relative=1)
    clsEnd = cmds.cluster((deformCrv + '.cv[1:2]'), relative=1)
    clsTop[0] = cmds.rename(clsTop[0], (ctrlTop + '_top_cluster'))
    clsTop[1] = cmds.rename(clsTop[1], (ctrlTop + '_top_clusterHandle'))
    clsMid[0] = cmds.rename(clsMid[0], (ctrlMid + '_mid_cluster'))
    clsMid[1] = cmds.rename(clsMid[1], (ctrlMid + '_mid_clusterHandle'))
    clsEnd[0] = cmds.rename(clsEnd[0], (ctrlEnd + '_end_cluster'))
    clsEnd[1] = cmds.rename(clsEnd[1], (ctrlEnd + '_end_clusterHandle'))
    cmds.setAttr((cmds.listRelatives(clsTop[1], type="shape")[0] + '.originX'), topPoint)
    cmds.setAttr((cmds.listRelatives(clsEnd[1], type="shape")[0] + '.originX'), endPoint)
    setPivot(objects=[clsTop[1]], rotatePivot=1, scalePivot=1, pivot=(topPoint,0,0))
    setPivot(objects=[clsEnd[1]], rotatePivot=1, scalePivot=1, pivot=(endPoint,0,0))
    cmds.percent(clsTop[0], (deformCrv + '.cv[1]'), v=0.5)
    cmds.percent(clsEnd[0], (deformCrv + '.cv[1]'), v=0.5)
    posTopPma = cmds.shadingNode('plusMinusAverage', asUtility=1, name = (prefix + 'top_ctrl_pos_pma'))
    cmds.connectAttr((ctrlTop + '.translate'), (posTopPma + '.input3D[0]'))
    cmds.connectAttr((grpTop + '.translate'), (posTopPma + '.input3D[1]'))
    posEndPma = cmds.shadingNode('plusMinusAverage', asUtility=1, name = (prefix + 'end_ctrl_pos_pma'))
    cmds.connectAttr((ctrlEnd + '.translate'), (posEndPma + '.input3D[0]'))
    cmds.connectAttr((grpEnd + '.translate'), (posEndPma + '.input3D[1]'))
    cmds.connectAttr((posTopPma + '.output3D'), (clsTop[1] + '.translate'))
    cmds.connectAttr((ctrlMid + '.translate'), (clsMid[1] + '.translate'))
    cmds.connectAttr((posEndPma + '.output3D'), (clsEnd[1] + '.translate'))
    #Create deformers: Blendshape
    blndDef = cmds.blendShape(geoPlaneWire[0], geoPlaneTwist[0], geoPlaneSine[0], geoPlane[0], name=(prefix + 'blendShape'),weight=[(0,1),(1,1),(2,1)])


    #Twist deformer: Sum the twist and the roll
    sumTopPma = cmds.shadingNode('plusMinusAverage', asUtility=1, name = (prefix + 'twist_top_sum_pma'))
    cmds.connectAttr((ctrlTop + '.twist'), (sumTopPma + '.input1D[0]'))
    cmds.connectAttr((ctrlTop + '.twistOffset'), (sumTopPma + '.input1D[1]'))
    cmds.connectAttr((ctrlMid + '.roll'), (sumTopPma + '.input1D[2]'))
    cmds.connectAttr((ctrlMid + '.rollOffset'), (sumTopPma + '.input1D[3]'))
    cmds.connectAttr((sumTopPma + '.output1D'), (twistDef[0] + '.startAngle'))
    sumEndPma = cmds.shadingNode('plusMinusAverage', asUtility=1, name = (prefix + 'twist_low_sum_pma'))
    cmds.connectAttr((ctrlEnd + '.twist'), (sumEndPma + '.input1D[0]'))
    cmds.connectAttr((ctrlEnd + '.twistOffset'), (sumEndPma + '.input1D[1]'))
    cmds.connectAttr((ctrlMid + '.roll'), (sumEndPma + '.input1D[2]'))
    cmds.connectAttr((ctrlMid + '.rollOffset'), (sumEndPma + '.input1D[3]'))
    cmds.connectAttr((sumEndPma + '.output1D'), (twistDef[0] + '.endAngle'))
    #Twist deformer: Set up the affect of the deformer
    topAffMdl = cmds.shadingNode('multDoubleLinear', asUtility=1, name = (prefix + 'twist_top_affect_mdl'))
    cmds.setAttr((topAffMdl + '.input1'), -0.1)
    cmds.connectAttr((ctrlTop + '.affectToMid'), (topAffMdl + '.input2'))
    cmds.connectAttr((topAffMdl + '.output'), (twistDef[0] + '.lowBound'))
    endAffMdl = cmds.shadingNode('multDoubleLinear', asUtility=1, name = (prefix + 'twist_end_affect_mdl'))
    cmds.setAttr((endAffMdl + '.input1'), 0.1)
    cmds.connectAttr((ctrlEnd + '.affectToMid'), (endAffMdl + '.input2'))
    cmds.connectAttr((endAffMdl + '.output'), (twistDef[0] + '.highBound'))

    #Squash deformer: Set up the connections for the volume control
    volumeRevfMdl = cmds.shadingNode('multDoubleLinear', asUtility=1, name = (prefix + 'volume_reverse_mdl'))
    cmds.setAttr((volumeRevfMdl + '.input1'), -1)
    cmds.connectAttr((ctrlMid + '.volume'), (volumeRevfMdl + '.input2'))
    cmds.connectAttr((volumeRevfMdl + '.output'), (squashDef[0] + '.factor'))
    cmds.connectAttr((ctrlMid + '.startDropoff'), (squashDef[0] + '.startSmoothness'))
    cmds.connectAttr((ctrlMid + '.endDropoff'), (squashDef[0] + '.endSmoothness'))
    cmds.connectAttr((ctrlMid + '.volumePosition'), (squashDef[1] + '.translateX'))
    #Squash deformer: Set up the volume scaling
    sumScalePma = cmds.shadingNode('plusMinusAverage', asUtility=1, name = (prefix + 'volume_scale_sum_pma'))
    cmds.setAttr((sumScalePma + '.input1D[0]'), topPoint)
    cmds.connectAttr((ctrlMid + '.volumeScale'), (sumScalePma + '.input1D[1]'))
    cmds.connectAttr((sumScalePma + '.output1D'), (squashDef[1] + '.scaleY'))

    #Sine deformer: Set up the connections for the sine
    cmds.connectAttr((ctrlMid + '.amplitude'), (sineDef[0] + '.amplitude'))
    cmds.connectAttr((ctrlMid + '.offset'), (sineDef[0] + '.offset'))
    cmds.connectAttr((ctrlMid + '.twist'), (sineDef[1] + '.rotateY'))
    cmds.connectAttr((ctrlMid + '.sineLength'), (sineDef[0] + '.wavelength'))

    #Cleanup: Hierarchy
    cmds.parent(geoPlaneWire[0], geoPlaneTwist[0], geoPlaneSine[0], geoPlaneVolume[0], grpSurfaces)
    cmds.parent(twistDef[1], sineDef[1], squashDef[1], grpDeformers)
    cmds.parent(clsTop[1], clsMid[1], clsEnd[1], grpCluster)
    cmds.parent(grpTop, grpMid, grpEnd, grpCtrl)
    cmds.parent(geoPlane[0], grpSurface)
    cmds.parent(deformCrv, (cmds.listConnections(wireDef[0] + '.baseWire[0]')[0]), grpMisc)
    #Cleanup: Visibility
    cmds.hide(grpSurfaces, grpDeformers, grpCluster, grpMisc)
    for x in cmds.listConnections(ctrlMid):
        cmds.setAttr((x + '.isHistoricallyInteresting'), 0)
        for y in cmds.listConnections(x):
            cmds.setAttr((y + '.isHistoricallyInteresting'), 0)

    #Update the scale-group
    scaleGrp = scaleGrp if scaleGrp else grpTransform
    #Create follicles: The main-surface and the volume-surface
    for x in range(0, numJoints):
        #Declare a variable for the current index
        num = str(x + 1)
        #Get the normalized position of where to place the current follicle
        uVal = ((0.5 / numJoints) * (x + 1) * 2) - ((0.5 / (numJoints * 2)) * 2)
        #Create a follicle for the bind-plane and the volume-plane
        follicleS = createFollicle(scaleGrp=scaleGrp, inputSurface=cmds.listRelatives(geoPlane[0], type="shape"), uVal=uVal, name=(prefix + num + '_follicle'))
        follicleV = createFollicle(scaleGrp=None, inputSurface=cmds.listRelatives(geoPlaneVolume[0], type="shape"), uVal=uVal, vVal=0, name=(prefix + num + '_volume_follicle'))
        cmds.parent(follicleS[0], grpFollMain)
        cmds.parent(follicleV[0], grpFollVolume)
        #Create a joint, controller and a group for the current skin-follicle
        cmds.select(clear=True)
        follicleJoint = cmds.joint(name=(prefix + num + '_jnt'), radius=0.1)
        follicleCtrl = cmds.circle(name=(prefix + num + '_ctrl'), c=(0,0,0), nr=(1,0,0), sw=360, r=0.5, d=3, s=8, ch=0)[0]
        follicleXform = cmds.group(name=(prefix + num + '_xform_grp'), empty=True)
        cmds.parent(follicleXform, follicleS[0])
        cmds.parent(follicleCtrl, follicleXform)
        cmds.parent(follicleJoint, follicleCtrl)
        cmds.delete(cmds.parentConstraint(follicleS[0], follicleXform))
        #Set the color and connect the visibility-switch for the controller
        cmds.setAttr((cmds.listRelatives(follicleCtrl, shapes=True)[0] + '.overrideEnabled'), 1)
        cmds.setAttr((cmds.listRelatives(follicleCtrl, shapes=True)[0] + '.overrideColor'), 12)
        cmds.connectAttr((ctrlMid + '.showExtraCtrl'), (cmds.listRelatives(follicleCtrl, shapes=True)[0] + '.visibility'))
        #Make the connections for the volume
        multMpd = cmds.shadingNode('multiplyDivide', asUtility=1, name = (prefix + num + '_multiplier_mpd'))
        cmds.connectAttr((ctrlMid + '.volumeMultiplier'), (multMpd + '.input1Z'))
        cmds.connectAttr((follicleV[0] + '.translate'), (multMpd + '.input2'))
        sumPma = cmds.shadingNode('plusMinusAverage', asUtility=1, name = (prefix + num + '_volume_sum_pma'))
        cmds.connectAttr((multMpd + '.outputZ'), (sumPma + '.input1D[0]'))
        cmds.setAttr((sumPma + '.input1D[1]'), 1)
        cmds.connectAttr((sumPma + '.output1D'), (follicleXform + '.scaleY'))
        cmds.connectAttr((sumPma + '.output1D'), (follicleXform + '.scaleZ'))