Ejemplo n.º 1
0
def ik_stretch(ikhnd):
    '''

    '''
    jts = cmds.ikHandle(ikhnd, q=True, jl=True)
    cu_s = cmds.ikHandle(ikhnd, q=True, c=True)
    cu = cmds.listRelatives(cu_s, p=1)[0]
    cmds.addAttr(ikhnd, longName='ik_stretch', k=1, defaultValue=1.0, minValue=0.0, maxValue=1.)

    dcu = cmds.duplicate(cu, n=cu + '_base_scale')[0]
    dcu_s = cmds.listRelatives(dcu, c=1)[0]

    cf = cmds.createNode('curveInfo')
    dcf = cmds.createNode('curveInfo')
    bl = cmds.createNode('blendTwoAttr')
    md = cmds.createNode('multiplyDivide')

    cmds.connectAttr(cu_s + '.worldSpace', cf + '.inputCurve')
    cmds.connectAttr(dcu_s + '.worldSpace', dcf + '.inputCurve')
    cmds.connectAttr(dcf + '.arcLength', bl + '.input[0]')
    cmds.connectAttr(cf + '.arcLength', bl + '.input[1]')
    cmds.connectAttr(ikhnd + '.ik_stretch', bl + '.attributesBlender')
    cmds.connectAttr(bl + '.output', md + '.input1X')

    cmds.setAttr(md + '.input2X', cmds.getAttr(cf + '.arcLength'), l=1)
    cmds.setAttr(md + '.operation', 2)
    cmds.setAttr(dcu + '.v', 0)

    for j in jts:
        cmds.connectAttr(md + '.outputX', j + '.sx')

    return dcu
Ejemplo n.º 2
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def orderNextTo(objects, target):
    '''
    places 'objects'/[objects] next to 'target' in hierarchy and ordering

    I found most of the time I use the get/setOrder stuff to relocate objs to another
    with parenting and if in world and hierarchy Nr and all that shit.. this does it inline
    '''
    if not isinstance(objects, list):
        objects = [objects]
    handledObjs = []
    targetParent = m.listRelatives(target, parent=True, fullPath=True)
    targetNr = getOrder(target)
    # handle each object on its own no matter how its parented
    for o in objects:
        oParent = m.listRelatives(o, parent=1, fullPath=1)
        if oParent != targetParent:
            if targetParent:
                o = m.parent(o, targetParent)[0]
            else:
                o = m.parent(o, world=1)[0]
        # else if in same hierarchy already decrease count if obj is before target
        elif getOrder(o) <= targetNr:
            targetNr -= 1
        handledObjs.append(o)
    setOrder(handledObjs, targetNr + 1)
    m.select(handledObjs)
    return handledObjs
Ejemplo n.º 3
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def unparent(shape):
	'''
	Unparent shape nodes from a source parent
	@param shape: Shape or transform to unparent shapes from
	@type shape: str
	'''
	# Checks
	if not mc.objExists(shape):
		raise Exception('Object "'+shape+'" does not exist!!')
	
	# Get shapes
	if mc.ls(shape,type='transform'):
		transform = shape
		shapes = mc.listRelatives(shape,s=True,pa=True)
	else:
		transform = mc.listRelatives(shape,p=True,pa=True)[0]
		shapes = [shape]
	
	# Create shape holder
	shapeHolder = transform+'Shapes'
	if not mc.objExists(shapeHolder): shapeHolder = mc.createNode('transform',n=shapeHolder)
	targetXform = mc.xform(transform,q=True,ws=True,m=True)
	mc.xform(shapeHolder,ws=True,m=targetXform)
	
	# Unparent shapes
	for shape in shapes:
		mc.parent(shape,shapeHolder,s=True,r=True)
	
	# Return Result
	return shapeHolder
Ejemplo n.º 4
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def copyCrvShape():
    sel = mc.ls(sl = True)
    if len(sel)>1:
        crvShape = mc.listRelatives(sel[0] , s = True)
        crvDegree = mc.getAttr(crvShape[0]+'.degree')
        crvSpans = mc.getAttr(crvShape[0]+'.spans')
        crvCvs = crvDegree + crvSpans
        for j in range(0,crvCvs+1):
            pos = mc.xform(sel[0] + '.cv[ '+str(j)+ ']' , q = True , os = True , t = True )
            for i in range(0,len(sel)):
                if i == 0:
                    continue
                else :
                    mc.xform(sel[i] + '.cv[ '+str(j)+ ']' , os = True , t = pos )
    else :
        searchQuery = mc.textField('searchUI' ,q = True ,tx = True)
        raplaceQuery = mc.textField('replaceUI' ,q = True ,tx = True)
        newCrv = sel[0].replace(searchQuery,raplaceQuery)
        crvShape = mc.listRelatives(sel[0] , s = True)
        crvDegree = mc.getAttr(crvShape[0]+'.degree')
        crvSpans = mc.getAttr(crvShape[0]+'.spans')
        crvCvs = crvDegree + crvSpans
        for j in range(0,crvCvs+1):
            pos = mc.xform(sel[0] + '.cv[ '+str(j)+ ']' , q = True , ws = True , t = True )
            mc.xform(newCrv + '.cv[ '+str(j)+ ']' , ws = True , t = (-pos[0],pos[1],pos[2]) )
Ejemplo n.º 5
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def getShapes(geo,nonIntermediates=True,intermediates=True):
	'''
	Return a list of shapes under a transform parent
	@param geo: Transform to list shapes for
	@type geo: str
	@param nonIntermediates: List non intermediate shapes
	@type nonIntermediates: bool
	@param intermediates: List intermediate shapes
	@type intermediates: bool
	'''
	# Checks
	if not mc.objExists(geo):
		raise Exception('Object "'+geo+'" does not exist!!')
	if isShape(geo):
		geo = mc.listRelatives(geo,p=True,pa=True)[0]
	
	# Get Shapes
	shapes = []
	if nonIntermediates:
		nonIntShapes = mc.listRelatives(geo,s=True,ni=True,pa=True)
		if nonIntShapes: shapes.extend(nonIntShapes)
	if intermediates:
		shapes.extend(listIntermediates(geo))
	
	# Return Result
	return shapes
Ejemplo n.º 6
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    def filterSelection(self):
        """
            from a raw list of items, returns 1 dict containing:
            {[meshes], [cameras], [locators], [lights]}
        """
        # get current selection
        cmds.select(hi = True)
        selection = [str(item) for item in cmds.ls(sl = True)]

        # fill the items dict from the raw selection
        items = {}
        # meshes
        items['meshes'] = [cmds.listRelatives(node, p=True, fullPath=True)[0] \
                    for node in selection if cmds.nodeType(node) == "mesh"]
        # cameras
        items['cameras'] = [cmds.listRelatives(node, p=True, fullPath=True)[0] \
                    for node in selection if cmds.nodeType(node) == "camera"]
        # locators
        items['locators'] = [cmds.listRelatives(node, p=True, fullPath=True)[0] \
                    for node in selection if cmds.nodeType(node) == "locator"]
        # lights
        items['lights'] = [cmds.listRelatives(node, p=True, fullPath=True)[0] \
                    for node in selection if 'Light' in cmds.nodeType(node)]

        return items
Ejemplo n.º 7
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def listIntermediates(geo):
	'''
	Return a list of intermediate shapes under a transform parent
	@param geo: Transform to list intermediate shapes for
	@type geo: str
	'''
	# Checks
	if not mc.objExists(geo):
		raise Exception('Object "'+geo+'" does not exist!!')
	if isShape(geo):
		geo = mc.listRelatives(geo,p=True,pa=True)[0]
	
	# Get Non Intermediate Shapes
	shapes = mc.listRelatives(geo,s=True,ni=True,pa=True)
	
	# Get All Shapes
	allShapes = mc.listRelatives(geo,s=True,pa=True)
	
	# Get Intermediate Shapes
	if not allShapes: return []
	if not shapes: return allShapes
	intShapes = list(set(allShapes) - set(shapes))
	
	# Return Result
	return intShapes
Ejemplo n.º 8
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    def _setup_wire_deformer(self, mesh, wire, wirebase, curve,
                             parent, complexity):
        """Setup the wire deformer. If complexity is 1 or higher call this
        function recursively to create a wire deformer on the nurbs surface.

        @param mesh(string): PolyMesh used to wire deform
        @param wire(string): Descriptive part of the name of the wire deformer
        @param wirebase(string): Descriptive part of the name of the base wire
        @param curve(string): Curve used for wireTool deformer
        @param parent(string): Parent node of the wire setup
        @param complexity(uint): complexity level value
        """
        w = wire
        wb = wirebase
        cmds.wire(mesh, w=curve, dds=[0, 10000], n=w, foc=False)
        cmds.rename(cmds.listConnections('%s.baseWire[0]' % w)[0], wb)
        if not cmds.listRelatives(curve, p=True) == [self.wire_grp]:
            cmds.parent(curve, wb, self.wire_grp)
        # end if
        wbs = cmds.listRelatives(wb, ad=True, type='shape')[0]
        cs = cmds.listRelatives(curve, ad=True, type='shape')[0]
        cmds.setAttr('%s.rotation' % w, 0)
        # connect to showHistory
        cmds.connectAttr('%s.showHistory' % self.mod_grp, '%s.ihi' % w)
        cmds.connectAttr('%s.showHistory' % self.mod_grp, '%s.ihi' % wb)
        cmds.connectAttr('%s.showHistory' % self.mod_grp, '%s.ihi' % wbs)
        cmds.connectAttr('%s.showHistory' % self.mod_grp, '%s.ihi' % cs)
        if complexity:
            cmds.duplicate(self.curve, n=self.nrbcurve)
            return self._setup_wire_deformer(self.surface, self.nrbwire,
                                             self.nrbwirebase, self.nrbcurve,
                                             self.parent, 0)
Ejemplo n.º 9
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def select_node_by_type(nodeType):
    sel = cmds.ls(sl=True, l=True)
    sel_ad = cmds.listRelatives(sel, ad=True, f=True) + sel
    cmds.select(cl=True)
    for node in sel_ad:
        if cmds.nodeType(node) == nodeType:
            cmds.select((cmds.listRelatives(node, p=True)), add=True)
Ejemplo n.º 10
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def copyBitSettings():
    '''
    Copies the bit shape settings (OpenGL stuff) from the second object to the
    first (in selection order).
    '''
    selList = cmds.ls( selection=True, long=True )
    depFn = OpenMaya.MFnDependencyNode()
    
    if len(selList) == 2:
        # First object is target.
        targetShape = cmds.listRelatives( selList[0], shapes=True, fullPath=True )[0]
        targetShapeMObj = NodeUtility.getDependNode( targetShape )
        depFn.setObject( targetShapeMObj )
        targetShapeType = depFn.typeName()
        
        # Second object is source.
        sourceShape = cmds.listRelatives( selList[1], shapes=True, fullPath=True )[0]
        sourceShapeMObj = NodeUtility.getDependNode( sourceShape )
        depFn.setObject( sourceShapeMObj )
        sourceShapeType = depFn.typeName()
        
        if targetShapeType == sourceShapeType:        
            # The types match. Do the copy of attribute settings.
            for attr in cmds.listAttr( sourceShape, multi=True, keyable=True ):
                # Get the plugs.
                sourcePlug = NodeUtility.getPlug( sourceShape, attr )
                targetPlug = NodeUtility.getPlug( targetShape, attr )
                
                # Get the source plug value.
                sourcePlugValue = NodeUtility.getPlugValue( sourcePlug )
                
                # Set the target's plug value.
                NodeUtility.setPlugValue( targetPlug, sourcePlugValue )
        else:
            raise ValueError( '{0} and {1} do not match.'.format( selList[0], selList[1] ) )
Ejemplo n.º 11
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def getNodesOverload(poseObj, nodes, *args):

    # NOTE: poseObj already has an attr 'metaRig' which is filled
    # automatically in the main buildInternalPoseData() call
    metaNode = poseObj.metaRig
    currentSelection = cmds.ls(sl=True, l=True)
    filteredNodes = []

    if not issubclass(type(metaNode), r9Meta.MetaHIKControlSetNode):
        # see if we have a left or right controller selected and switch to the
        # appropriate subMetaSystem

        if cmds.getAttr('%s.mirrorSide' % currentSelection[0]) == 1:
            print '\nFinger : PoseOverload Handler : %s >> side: Left' % metaNode
            filteredNodes = metaNode.L_ArmSystem.L_FingerSystem.getChildren()
            [filteredNodes.append(node) for node in cmds.listRelatives(filteredNodes, type='joint', ad=True, f=True)]

        elif cmds.getAttr('%s.mirrorSide' % currentSelection[0]) == 2:
            print '\nFinger : PoseOverload Handler : %s >> side: Right' % metaNode
            filteredNodes = metaNode.R_ArmSystem.R_FingerSystem.getChildren()
            [filteredNodes.append(node) for node in cmds.listRelatives(filteredNodes, type='joint', ad=True, f=True)]
    else:
        if currentSelection[0] == metaNode.LeftWristEffector or currentSelection[0] == metaNode.LeftHand:
            [filteredNodes.append(node) for node in cmds.listRelatives(metaNode.LeftHand, type='joint', ad=True, f=True)]
        elif currentSelection[0] == metaNode.RightWristEffector or currentSelection[0] == metaNode.RightHand:
            [filteredNodes.append(node) for node in cmds.listRelatives(metaNode.RightHand, type='joint', ad=True, f=True)]

    # modify the actual PoseData object, changing the data to be matched on index
    # rather than using the standard name or metaMap matching
    poseObj.metaPose = False
    poseObj.matchMethod = 'index'

    return filteredNodes
Ejemplo n.º 12
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def rename_objects(*args):
	objs = meshes = cmds.ls( selection=True )
	txt = fix_string( cmds.textField('txt_input',q=True,text=True) )
	alphabet = ['a','b','c','d','e','f','g','h','i','j','k','l',]
	if len(objs) == 1:
		ob = objs[0]
		shape = cmds.listRelatives(ob, shapes=True)[0]

		t_name = txt + '_t'
		m_name = txt

		cmds.rename(shape, m_name)
		cmds.rename(ob , t_name)
		return True


	if len(objs) > 1:
		count = 0
		for ob in objs:

			shape = cmds.listRelatives(ob, shapes=True)[0]

			t_name = txt + '_t_' + alphabet[count]
			m_name = txt + '_' + alphabet[count]

			cmds.rename(shape, m_name)
			cmds.rename(ob , t_name)
			count+=1
		return True
	else:
		print'Nothing to do'
		return False
Ejemplo n.º 13
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 def performTranferV1(self):
     getMesh=cmds.ls(sl=1)
     if len(getMesh)<2:
         print "select a skinned mesh group and an unskinned target mesh group"
         return
     else:
         pass
     getMeshController=getMesh[0]
     getMeshTarget=getMesh[1]
     getChildrenController=cmds.listRelatives(getMeshController, c=1, typ="transform")
     if getChildrenController==None:
         getChildrenController=([getMeshController])
     getChildrenTarget=cmds.listRelatives(getMeshTarget, c=1, typ="transform")
     if getChildrenTarget==None:
         getChildrenTarget=([getMeshTarget])
     result = cmds.promptDialog( 
                 title='find XML', 
                 message="Enter path", 
                 text="C:\Users\\"+str(getFolderName)+"\Documents\maya\projects\default\scenes\\", 
                 button=['Continue','Cancel'],
                 defaultButton='Continue', 
                 cancelButton='Cancel', 
                 dismissString='Cancel' )
     if result == 'Continue':
         skinPath=cmds.promptDialog(q=1)
         if skinPath:
             pass
         else:
             print "nothing collected"
     self.callJointsWin(getChildrenController, getChildrenTarget, skinPath)
Ejemplo n.º 14
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 def insepectDuplicatesShapes(self):
     geometrys   = mc.listRelatives(mc.ls(type=('mesh', 'nurbsSurface')), p=True, path=True)
     u_geometrys = []
     for geo in geometrys:
         if len(mc.listRelatives(geo, s=True)) > 1:
             u_geometrys.append(geo) 
     return u_geometrys
Ejemplo n.º 15
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def write_hierarchy(guide):
    """
    Simple hierarchy data structure

    :param      position:       Guide node
    :type       position:       Guide, str
    :returns:   Guide

    **Example**:

    >>> write_hierarchy("C_spine_0_gde")
    """
    try:
        guide = guide.joint
    except Exception:
        guide = str(guide)

        if not cmds.objExists(guide):
            raise NameError("'%s' is not a guide." % guide)

    data = {}
    all_guides = cmds.listRelatives(guide, allDescendents=True, type="joint") or []
    all_guides.insert(0, guide)
    for guide in all_guides:
        children = [Guide.validate(c) for c in cmds.listRelatives(guide, children=True, type="joint") or []]
        guide = Guide.validate(guide)

        data[guide] = children
    return data
Ejemplo n.º 16
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def createDistanceNodeBetweenPosInfoNodes (node1,node2):
    """
    >>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>
    DESCRIPTION:
    Creates a distance node between two position info nodes

    ARGUMENTS:
    node1(string)
    node2(string)

    RETURNS:
    returnList[0] - distance object
    returnList[1] - shape node
    returnList[2] - shape node distance attribute
    >>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>
    """
    returnList =[]
    distShapeBuffer = mc.createNode ('distanceDimShape')
    distBuffer = (mc.listRelatives (distShapeBuffer,parent=True))
    mc.connectAttr ((node1+'.position'),(distShapeBuffer+'.startPoint'))
    mc.connectAttr ((node2+'.position'),(distShapeBuffer+'.endPoint'))
    distanceObj = mc.rename (distBuffer, (node1+'_to_'+node2+'_distNode') )
    newDistShapeBuffer = (mc.listRelatives (distanceObj,shapes=True))
    returnList.append (distanceObj)
    returnList.append (newDistShapeBuffer[0])
    returnList.append (newDistShapeBuffer[0]+'.distance')
    return returnList
def multObjShapeUpdate():
    sel_objs = cmds.ls(sl=True,fl=True)
    if len(sel_objs)>0:
        files_to_import = cmds.fileDialog2(fileFilter =  '*.obj', dialogStyle = 2, caption = 'import multiple object files', fileMode = 4,okc="Import")
        if len(files_to_import) == len(sel_objs):
            object_names = [file_to_import.split('/')[-1].split('.obj')[0] for file_to_import in files_to_import]
            if len(sel_objs) == len([x for x in object_names if x in sel_objs]):
                for file_to_import in files_to_import:
                    object_name  = file_to_import.split('/')[-1].split('.obj')[0]
                    returnedNodes = cmds.file('%s' % file_to_import, i = True, type = "OBJ", rnn=True, ignoreVersion = True, options = "mo=0",  loadReferenceDepth  = "all"  )
                    cmds.delete(cmds.ls(returnedNodes,type="objectSet"))
                    geo = cmds.listRelatives(cmds.ls(returnedNodes,g=1)[0],p=1)
                    cmds.rename( geo, "newShape_{0}".format(object_name))
                new_shapes = [s for s in cmds.listRelatives(cmds.ls(g=1),p=1) if "newShape_" in s]
                cur_shapes = sel_objs
                for new in new_shapes:
                    for cur in cur_shapes:
                        if new.split("newShape_")[1] == cur:
                            blendshapeNd = cmds.blendShape(new,cur)[0]
                            cmds.setAttr("{0}.{1}".format(blendshapeNd,new),1)
                cmds.delete(cur_shapes,ch=True)
                cmds.delete(new_shapes)
                cmds.confirmDialog(m="---===All Shapes Updated!===---")
            else:
                cmds.confirmDialog(m="--==Not Matching The Name!==--")
        else:
            cmds.confirmDialog(m="--==Please Select The Same Number Of Objects!==--")
    else:
        cmds.confirmDialog(m="--==Please Select Something!==--")
    def dump(self):
        eval_joints = ["root"]
        skeleton_def = []

        while len(eval_joints) > 0:
            current_node = eval_joints[0]
            eval_joints = eval_joints[1:]
            joint_def = [":{0}".format(current_node)]

            if current_node[-3:] == "_rt":
                # Skip the right part of skeleton tree
                continue

            child_nodes = cmds.listRelatives(current_node)
            if current_node == "root":
                # Split root from pelvis
                eval_joints += child_nodes
            else:
                while child_nodes is not None:
                    joint_def.append("{0}:{1}".format(current_node, child_nodes[0]))
                    eval_joints += child_nodes[1:]

                    current_node = child_nodes[0]
                    child_nodes = cmds.listRelatives(current_node)

            skeleton_def.append(joint_def)

        self.display_script(skeleton_def)
Ejemplo n.º 19
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def createDistanceNodeBetweenObjects (obj1,obj2):
    """
    >>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>
    DESCRIPTION:
    Creates a distance node between objects

    ARGUMENTS:
    obj1(string)
    obj2(string)

    RETURNS:
    none
    >>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>
    """
    """ Creates a distance node between objects """
    pos1 = returnWorldSpacePosition (obj1)
    pos2 = returnWorldSpacePosition (obj2)
    tmp = mc.distanceDimension( sp=pos1, ep=pos2 )
    distBuffer = mc.listRelatives ( [tmp], p=True)
    distanceObj = mc.rename (distBuffer, (obj1+'_to_'+obj2+'_distMeas') )
    #return the stupid locators it makes so we can connect our own stuff
    distanceStartPoint = (distanceObj+'Shape.startPoint')
    distanceEndPoint = (distanceObj+'Shape.endPoint')
    locAttr1connection =  (mc.connectionInfo (distanceStartPoint,sourceFromDestination=True))
    locAttr2connection =  (mc.connectionInfo (distanceEndPoint,sourceFromDestination=True))
    locAttr1Stripped = '.'.join(locAttr1connection.split('.')[0:-1])
    locAttr2Stripped = '.'.join(locAttr2connection.split('.')[0:-1])
    loc1Buffer = (mc.listRelatives (locAttr1Stripped,parent=True))
    loc2Buffer = (mc.listRelatives (locAttr2Stripped,parent=True))
    #distObj1 = mc.rename (loc1Buffer, (obj1+'_distLoc') )
    #distObj2 = mc.rename (loc2Buffer, (obj2+'_distLoc') )
    
    return distanceObj
 def deformCharacterShapeSel(self, value):
     RN = mc.referenceQuery(self.core.skCharacter[int(value)-1], referenceNode=1)
     Nodes = mc.referenceQuery(RN, nodes=1)
     self.characterdeformShape = []
     self.allCharacterRightdeformShape = []
     for item in Nodes:
         if self.nodeTypeSelf(item) in self.shapeType:
             self.characterdeformShape.append(item)
     for each in self.characterdeformShape:
         itemP = mc.listRelatives(each, p=1)[0]
         itemPP = mc.listRelatives(itemP, p=1)
         if itemPP != None and mc.getAttr('%s.v'%itemP) != 0 and mc.getAttr('%s.v'%itemPP[0]) != 0:
             self.allCharacterRightdeformShape.append(each)
             self.allCharacterRightdeformShape.reverse()
     for item in self.allCharacterRightdeformShape:
         if mc.filterExpand( item, sm=(10,12)) == None:
             self.allCharacterRightdeformShape.remove(item)
     for item in self.allCharacterRightdeformShape:
         if item.endswith('Orig') == True:
             self.allCharacterRightdeformShape.remove(item)
     for item in self.allCharacterRightdeformShape:
         if item.endswith('Orig') == True:
             self.allCharacterRightdeformShape.remove(item)
     for item in self.allCharacterRightdeformShape:
         if item.endswith('Orig') == True:
             self.allCharacterRightdeformShape.remove(item)
     for item in self.allCharacterRightdeformShape:
         if item.endswith('Orig') == True:
             self.allCharacterRightdeformShape.remove(item)
     for item in self.allCharacterRightdeformShape:
         if item.endswith('Orig') == True:
             self.allCharacterRightdeformShape.remove(item)
     return self.allCharacterRightdeformShape
Ejemplo n.º 21
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 def loadSurfaceGroup(self, *args ):
     
     sels = cmds.ls( sl=1 )
     
     if not sels: cmds.error( "Select Surface Group" )
     
     children = cmds.listRelatives( sels[-1], c=1, ad=1 )
     
     if not children: cmds.error( "Select Surface Group" )
     
     
     surfaceGrp = ''
     
     for child in children:
         shapes = cmds.listRelatives( child, s=1 )
         if not shapes: continue
         for shape in shapes:
             if cmds.nodeType( shape ) == 'nurbsSurface':
                 surfaceGrp = sels[-1]
                 break
         if surfaceGrp: break
             
     if not surfaceGrp:
         cmds.error( "Select Surface Group" )
     
     cmds.textField( self._surfaceGroup, e=1, tx=surfaceGrp )
     
     if not cmds.attributeQuery( 'sets', node=surfaceGrp, ex=1 ):
         fnc.addArrayMessageAttribute( surfaceGrp, 'sets' )
         
     self.saveData()
Ejemplo n.º 22
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 def __check_scene(self):
     #--- this method checks the scene
     #--- check if something is selected
     sel = cmds.ls(selection = True)
     if sel:
         #--- check if selection is a mesh
         transform = None
         for i in sel:
             if cmds.nodeType(i) == 'transform':
                 transform = i
         if cmds.listRelatives(transform, allDescendents = True, type = 'mesh'):
             mesh = cmds.listRelatives(transform,
                                       allDescendents = True,
                                       type = 'mesh')[0]
             if cmds.nodeType(mesh) == 'mesh':
                 #--- store the mesh
                 self.mesh = transform
                 #--- get current frame
                 self.currentFrame = cmds.currentTime(query = True)
                 #--- get timestamp
                 ts = str(time.time())
                 self.time_stamp = str(ts.split('.')[0] + ts.split('.')[1])
             else:
                 raise Exception('The selected object is not a mesh!')
         else:
             raise Exception('The selected object is not a mesh!')
     else:
         raise Exception('You have to select a mesh, dude!')
Ejemplo n.º 23
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    def _findRelativesByType(self, embeddedRoot, resList=['lo', 'md', 'hi', 'apos'], byType='shape', resExcludeList=[]):
        shapes = None

        searchResList = list(set(resList) - set(resExcludeList))
        #print 'searchResList: %s'%searchResList
        if embeddedRoot != 'master':
            shapes = []
            for res in searchResList:
                if cmds.objExists('%s|%s'%(embeddedRoot, res)):
                    resShapes = cmds.listRelatives('%s|%s'%(embeddedRoot, res), ad=True, type=byType, f=True)
                    if resShapes:
                        shapes.extend(resShapes)
            if not shapes:
                shapes = None
        else:
            embeddedCodes = self._findEmbeddedAssets()
            index = embeddedCodes.index('master')
            embeddedCodes.pop(index)

            if cmds.objExists('|master'):
                children = cmds.listRelatives('|master')
                if children:
                    shapes = []
                    for child in children:
                        if child not in embeddedCodes:
                            if child in searchResList:
                                #print 'child:%s' % child
                                if cmds.objExists('|master|%s'%child):
                                    childShapes = cmds.listRelatives('|master|%s'%child, ad=True, type=byType, f=True)
                                    if childShapes:
                                        shapes.extend(childShapes)
        if not shapes:
            shapes = None

        return shapes
Ejemplo n.º 24
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def extractFaces( faceList, delete=False ):
	'''
	extracts the given faces into a separate object - unlike the maya function, this is actually
	useful...  the given faces are extracted to a separate object, and can be optionally deleted from
	the original mesh if desired, or just duplicated out.
	'''
	newMeshes = []

	#get a list of meshes present in the facelist
	cDict = componentListToDict( faceList )
	for mesh, faces in cDict.iteritems():
		#is the mesh a shape or a transform - if its a shape, get its transform
		if cmd.nodeType( mesh ) == 'mesh':
			mesh = cmd.listRelatives( mesh, pa=True, p=True )[ 0 ]

		dupeMesh = cmd.duplicate( mesh, renameChildren=True )[ 0 ]
		children = cmd.listRelatives( dupeMesh, pa=True, typ='transform' )
		if children: cmd.delete( children )

		#now delete all faces except those we want to keep
		cmd.select( [ '%s.f[%d]' % (dupeMesh, idx) for idx in range( numFaces( dupeMesh ) ) ] )
		cmd.select( [ '%s.f[%d]' % (dupeMesh, idx) for idx in faces ], deselect=True )
		cmd.delete()

		newMeshes.append( dupeMesh )

	if delete:
		cmd.delete( faceList )

	return newMeshes
Ejemplo n.º 25
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    def getCamera(self):
        _selection = cmds.ls(selection=True)

        # check selection length
        if len(_selection) == 0:

            # check panel for camera if selection is empty
            _panel = cmds.getPanel(withFocus=True)
            _typeOfPanel = mm.eval("getPanel -typeOf " + _panel)

            # check if modelpanel with camera is active
            if _typeOfPanel == "modelPanel":

                # get camera from modelpanel
                _cameraname = cmds.modelPanel(_panel, query=True, camera=True)
                _camerashape = cmds.listRelatives(_cameraname, shapes=True)[0]
            else:
                # no selection, no modelpanel active
                _cameraname = "Nul"
                _camerashape = "Nul"

        else:
            # selection is not emtpy
            _cameraname = _selection[0]
            _camerashape = cmds.listRelatives(_cameraname, shapes=True)[0]

            # check if selected shape is camera
            if cmds.nodeType(_camerashape) != "camera":
                # selection is not camera
                _cameraname = "Nul"
                _camerashape = "Nul"

        self.name = _cameraname
        self.shape = _camerashape
Ejemplo n.º 26
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    def setImageRes(self):
        """ Sets image width to resolution """
        skyDomeLgtList = self.getSkyDomeLgtList()
        areaLgtList = self.getAreaLgtList()
        print ''
        print '-------------------------------------------------'
        for lgt in skyDomeLgtList:
            lgtName = mc.listRelatives(lgt,p=True)
            img = self.imgPath(lgt)
            if img == 'None':
                print '# '+ lgtName[0] + '  ===> no file image attached'
            else:
                xres = self.imgInfo(str(img))
                mc.setAttr(lgt+'.resolution',int(xres))
                print '# ' + lgtName[0] + ' ===> set resolution to [ ' + str(xres) + ' ]'
        for lgt in areaLgtList:
            lgtName = mc.listRelatives(lgt,p=True)
            img = self.imgPath(lgt)
            if img == 'None':
                print '# '+ lgtName[0] + '  ===> no file image attached'
            else:
                xres = self.imgInfo(str(img))
                mc.setAttr(lgt+'.aiResolution',int(xres))
                print '# ' + lgtName[0] + ' ===> set resolution to [ ' + str(xres) + ' ]'        

        print '-------------------------------------------------'
        print ''
Ejemplo n.º 27
0
def transferUvHierarchy( fromTopGroup, toTopGroup):
    fromChildren = cmds.listRelatives( fromTopGroup, ad=True, type='mesh', fullPath=True)[1:]
    toChildren = cmds.listRelatives( toTopGroup, ad=True, type='mesh', fullPath=True)[1:]
    
    print fromChildren
    tmp = copy.copy(fromChildren)
    for fChild in tmp:
        split = fChild.split("|")[1:]
        #print split
        split[0] = toTopGroup
        tChild = "|" + "|".join( split)
        print fChild, tChild
        if tChild in toChildren:
            
            fromChildren.remove( fChild)
            toChildren.remove( tChild)
            cmds.select( fChild, r=True)
            tShapes = getShapes(tChild)
            print 'transfered \n%s \n | \n%s' % (fChild, tChild)
            tChildShapeOrig = tShapes[0]+'Orig'
            
            if (cmds.objectType(fChild) == 'transform' and cmds.objectType(tChild) == 'transform' and cmds.objectType(tChildShapeOrig) == 'mesh'):
                cmds.select( tChildShapeOrig, add=True)
                cmds.transferAttributes( transferPositions=0, transferNormals=0, transferUVs=2, transferColors=0, sampleSpace=4, sourceUvSpace="map1", targetUvSpace="map1", searchMethod=3, flipUVs=0, colorBorders=1)
    print toChildren
    print fromChildren
Ejemplo n.º 28
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def BindSkeletons(source, dest, method='connect'):
    '''
    From 2 given root joints search through each hierarchy for child joints, match
    them based on node name, then connect their trans/rots directly, or 
    parentConstrain them. Again cmds for speed
    '''
    sourceJoints = cmds.listRelatives(source, ad=True, f=True, type='joint')
    destJoints = cmds.listRelatives(dest, ad=True, f=True, type='joint')
 
    if cmds.nodeType(source) == 'joint':
        sourceJoints.append(source)
    if cmds.nodeType(dest) == 'joint':
        destJoints.append(dest)
        
    attrs = ['rotateX', 'rotateY', 'rotateZ', 'translateX', 'translateY', 'translateZ']   
     
    for sJnt, dJnt in MatchGivenHierarchys(sourceJoints, destJoints):
        if method == 'connect':
            for attr in attrs:
                try:
                    cmds.connectAttr('%s.%s' % (sJnt, attr), '%s.%s' % (dJnt, attr), f=True)
                except:
                    pass
        elif method == 'constrain':
            try:
                cmds.parentConstraint(sJnt, dJnt, mo=True)    
            except:
                pass
Ejemplo n.º 29
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def altFrame(*args):
    # cmds.nodeType(sel), object type
    # optimize, real slow
    pnl = cmds.getPanel(withFocus=True)
    typ = cmds.getPanel(typeOf=pnl)
    if typ == 'modelPanel':
        sel = cmds.ls(sl=True, fl=True)
        gs = ac.GraphSelection()
        locs = []
        if sel:
            for item in sel:
                if cmds.objectType(item, i='transform') or cmds.objectType(item, i='joint'):
                    loc = cn.locator(obj=item, ro='zxy', X=0.35, constrain=False, shape=False)[0]
                    locs.append(loc)
                else:
                    try:
                        print cmds.listRelatives(item, parent=True)[0], '_______________'
                        loc = cn.locator(obj=cmds.listRelatives(item, parent=True)[0], ro='zxy', X=0.35, constrain=False, shape=False)
                        print loc, '_____________________'
                        loc = loc[0]
                        locs.append(loc)
                    except:
                        message('didnt frame object: ' + item)
            cmds.select(locs)
            mel.eval("fitPanel -selected;")
            cmds.delete(locs)
            gs.reselect()
        else:
            message('select an object')
    else:
        mel.eval("fitPanel -selected;")
Ejemplo n.º 30
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def orientJoint (objects = [], aim = [1,0,0], up = [0,0,1]):

    crossVector = getCrossVector(objects[0], objects[1], objects[-1])
    
    for i in range(len(objects)-1):
        jointParents = cmds.listRelatives(objects[i], p=True)
        
        if jointParents:
            jointParent = jointParents[0]
            
        children = cmds.listRelatives(objects[i], c=True, type='transform')
        tempGrp = cmds.group(objects[i])
        
        cmds.parent(children, tempGrp)
        cmds.parent(objects[i], world=True)
        
        cmds.delete(cmds.aimConstraint(objects[i+1], objects[i], aimVector=aim, upVector=up, worldUpType='vector', worldUpVector = crossVector))

        cmds.parent(children, objects[i])
        
        if jointParents:
            cmds.parent(objects[i], jointParent)
            
        cmds.delete(tempGrp)
    
    cmds.makeIdentity(objects[0], apply=True, r=True) 
Ejemplo n.º 31
0
    def Light_Export_Fn(self):
        File_Path = QFileDialog.getSaveFileName(self,
                                                caption=u"1",
                                                directory=".",
                                                filter="json (*.json)")
        # 空数组处理
        try:
            if type(File_Path) is tuple:
                File_Path = File_Path[0]
            if type(File_Path) is list:
                File_Path = File_Path[0]
        except:
            traceback.print_exc()
            return

        Light_Json = {}
        Light_Json['Generate_Application'] = "Maya"
        Light_Json['LightData'] = {}

        lightList = cmds.ls(type='lightList')[0]
        lightList = cmds.listConnections(lightList + ".lights")
        for lightName in lightList:
            if cmds.getAttr(lightName + ".visibility") == 0:
                continue
            light = cmds.listRelatives(lightName, c=1)[0]
            Light_Json['LightData'][lightName] = {}
            Light_Json['LightData'][lightName]['Name'] = light
            Light_Json['LightData'][lightName]['Type'] = cmds.objectType(light)
            Light_Json['LightData'][lightName]['Intensity'] = cmds.getAttr(
                light + ".intensity")
            Light_Json['LightData'][lightName]['Exposure'] = cmds.getAttr(
                light + ".aiExposure")
            Light_Json['LightData'][lightName]['color'] = {}
            Light_Json['LightData'][lightName]['color']["R"] = cmds.getAttr(
                light + ".color")[0][0]
            Light_Json['LightData'][lightName]['color']["G"] = cmds.getAttr(
                light + ".color")[0][1]
            Light_Json['LightData'][lightName]['color']["B"] = cmds.getAttr(
                light + ".color")[0][2]
            Light_Json['LightData'][lightName]['Translate'] = {}
            Light_Json['LightData'][lightName]['Translate'][
                'tx'] = cmds.getAttr(lightName + ".tx")
            Light_Json['LightData'][lightName]['Translate'][
                'ty'] = cmds.getAttr(lightName + ".ty")
            Light_Json['LightData'][lightName]['Translate'][
                'tz'] = cmds.getAttr(lightName + ".tz")
            Light_Json['LightData'][lightName]['Rotate'] = {}
            Light_Json['LightData'][lightName]['Rotate']['rx'] = cmds.getAttr(
                lightName + ".rx")
            Light_Json['LightData'][lightName]['Rotate']['ry'] = cmds.getAttr(
                lightName + ".ry")
            Light_Json['LightData'][lightName]['Rotate']['rz'] = cmds.getAttr(
                lightName + ".rz")
            Light_Json['LightData'][lightName]['Scale'] = {}
            Light_Json['LightData'][lightName]['Scale']['sx'] = cmds.getAttr(
                lightName + ".sx")
            Light_Json['LightData'][lightName]['Scale']['sy'] = cmds.getAttr(
                lightName + ".sy")
            Light_Json['LightData'][lightName]['Scale']['sz'] = cmds.getAttr(
                lightName + ".sz")
            if cmds.objectType(light) == "spotLight":
                Light_Json['LightData'][lightName]['coneAngle'] = cmds.getAttr(
                    light + ".coneAngle")
                Light_Json['LightData'][lightName][
                    'penumbraAngle'] = cmds.getAttr(light + ".penumbraAngle")
                Light_Json['LightData'][lightName]['dropoff'] = cmds.getAttr(
                    light + ".dropoff")

        try:
            with open(File_Path, 'w') as f:
                json.dump(Light_Json, f, indent=4)
            QMessageBox.warning(self, u"Success", u"Json Export Success!")

        except:
            QMessageBox.warning(self, u"Warning",
                                u"Fail to export the Json file")
Ejemplo n.º 32
0
    def om_get_skin_weight(self):
        self.node_weight_dict = {}
        self.node_vtx_dict = {}
        self.inf_id_list = list()
        self.influences_dict = {}
        self.all_influences = list()
        self.all_skin_clusters = {}
        self.mesh_node_list = list()
        self.show_dict = {}  #選択セルに表示をフォーカスする辞書
        self.node_skinFn_dict = {}
        for mesh_path_name, skin_vtx in self.dag_skin_id_dict.items():
            skinFn = skin_vtx[0]  #スキンFn
            vtxArry = skin_vtx[1]  #バーテックスIDのリスト
            skinName = skin_vtx[2]  #スキン名
            meshPath = skin_vtx[3]
            #print skinName, vtxArry

            self.node_skinFn_dict[mesh_path_name] = skinFn
            #print mesh_path_name
            if cmds.nodeType(meshPath) == 'mesh':
                mesh_path_name = cmds.listRelatives(mesh_path_name,
                                                    p=True,
                                                    f=True)[0]

            # シェイプの取得
            #meshPath = self.om_get_shape(mesh_path_name)
            #meshNode = meshPath.node()

            #print 'try to get skin weight :', mesh_path_name, skinFn, vtxArry
            #print 'try to get skin weight :', meshPath.fullPathName()

            # 指定の頂点をコンポーネントとして取得する
            singleIdComp = om2.MFnSingleIndexedComponent()
            vertexComp = singleIdComp.create(om2.MFn.kMeshVertComponent)
            singleIdComp.addElements(vtxArry)

            # インフルエンスの数のIntArray
            infDags = skinFn.influenceObjects()  #インフルエンスを全取得
            infIndices = om2.MIntArray(len(infDags), 0)
            for x in xrange(len(infDags)):
                infIndices[x] = int(skinFn.indexForInfluenceObject(infDags[x]))
            #print 'get influence id list :', infIndices

            # すべてのウエイトの値を取得

            try:
                #print 'get weight :',meshPath , vertexComp , weights , infCountPtr
                weights = skinFn.getWeights(meshPath, vertexComp)
            except Exception as e:
                print 'get skin weight error :', e.message
                continue
            #print 'check weight data type :', type(weights)
            #print "getWeights :", weights
            weights = self.conv_weight_shape(len(infIndices), weights[0])
            #print "getWeights :", weights

            #インフルエンス名をフルパスで取得
            influence_list = [
                infDags[x].fullPathName() for x in range(len(infIndices))
            ]
            #print 'all ifluences :', influence_list

            self.node_vtx_dict[mesh_path_name] = vtxArry
            self.all_skin_clusters[mesh_path_name] = skinName
            self.mesh_node_list.append(mesh_path_name)
            self.inf_id_list.append(infIndices)
            self.node_weight_dict[mesh_path_name] = weights  #全ての頂点のウエイト一覧
            self.influences_dict[mesh_path_name] = influence_list
            self.all_influences += influence_list
            self.show_dict[mesh_path_name] = vtxArry
        #全てのインフルエンスをまとめる
        self.all_influences = sorted(list(set(self.all_influences)))
Ejemplo n.º 33
0
import maya.cmds as mc
import pymel.core as pm

sourceSkeleton = "og"  # source skeleton root joint
targetSkeleton = "new"  # target skeleton root joint

# count the joints in the hierarchies
hierarchy1 = []
hierarchy2 = []

sourceSkeletonList = mc.listRelatives(sourceSkeleton,
                                      c=True,
                                      ad=True,
                                      typ='joint')
targetSkeletonList = mc.listRelatives(targetSkeleton,
                                      c=True,
                                      ad=True,
                                      typ='joint')

for bone in sourceSkeletonList:
    hierarchy1.append(bone)

for bone in targetSkeletonList:
    hierarchy2.append(bone)

jointCount1 = (len(hierarchy1))
jointCount2 = (len(hierarchy2))

if jointCount1 != jointCount2:

    mc.error("Oops  -different number of joints in skeletons!")
Ejemplo n.º 34
0
 def StretchyIkSetup(self, armSels):
     
     if hasattr(armSels, '__getitem__'):
 
         #declare variables for the various joints
         self.firstJointPos=cmds.xform(armSels[0], q=1, ws=1, t=1)
         self.secondJointPos=cmds.xform(armSels[1], q=1, ws=1, t=1)
         self.lastJointPos=cmds.xform(armSels[2], q=1, ws=1, t=1)
         self.lastJointRot=cmds.xform(armSels[2], q=1, ws=1, ro=1)
         self.secondJointPosLocal=cmds.xform(armSels[1], q=1, t=1)
         self.lastJointPosLocal=cmds.xform(armSels[2], q=1, t=1)
             
         #Create an IK handle on first and last Joints.
         self.tempIKName= str(armSels[0]) + "IK_Hndl"
         self.ikName=cmds.ikHandle(ee=armSels[2], sj=armSels[0], n=self.tempIKName)
         
         #Create locators for the first and last joint. 
         self.jnt1Loc=cmds.spaceLocator(p=(0, 0, 0))
         cmds.move(self.firstJointPos[0], self.firstJointPos[1], self.firstJointPos[2])
         self.jnt2Loc=cmds.spaceLocator(p=(0, 0, 0))
         cmds.move(self.lastJointPos[0], self.lastJointPos[1], self.lastJointPos[2])
         self.jnt1LocShape=cmds.listRelatives(self.jnt1Loc, s=1)
         self.jnt2LocShape=cmds.listRelatives(self.jnt2Loc, s=1)
         
         #create a control for the IK handle, give it a stretchy attribute.
         self.ikCtrlTempName = str(armSels[0]) + "_IK_Ctrl"
         self.ikJointControl = cmds.circle(c=(0, 0, 0), n=self.ikCtrlTempName)
         cmds.addAttr(ln="Stretchy", at="float", keyable=True)
         self.ourControlGrp = cmds.group(n=(str(armSels[0]) + "_IK_Ctrl_Grp"), em=True)
         cmds.move(self.lastJointPos[0], self.lastJointPos[1], self.lastJointPos[2], self.ourControlGrp, ws=1)  
         cmds.rotate(self.lastJointRot[0], self.lastJointRot[1], self.lastJointRot[2], self.ourControlGrp, ws=1)  
         cmds.parent(self.ikCtrlTempName , self.ourControlGrp)
         cmds.move(0,0,0, self.ikJointControl, ls=True)
         cmds.rotate(0,0,0, self.ikJointControl)
         
         #create a "Distance between" Node for... well. getting the distance between the two nodes. 
         self.distanceTest=str(cmds.shadingNode('distanceBetween', asUtility=1))
         
         #create all of these nodes for all the different things we need to set up for the system.
         self.arm01DistanceNode=str(cmds.shadingNode('multiplyDivide', asUtility=1))
         cmds.setAttr((self.arm01DistanceNode + ".input1X"), self.secondJointPosLocal[0])
         self.arm02DistanceNode=str(cmds.shadingNode('multiplyDivide', asUtility=1))
         cmds.setAttr((self.arm02DistanceNode + ".input1X"), self.lastJointPosLocal[0])
         self.chainLengthPMA=str(cmds.shadingNode('plusMinusAverage', asUtility=1))
         self.distanceScalar=str(cmds.shadingNode('multiplyDivide', asUtility=1))
         cmds.setAttr((self.distanceScalar + ".operation"), 2)
         self.stretchCondition=str(cmds.shadingNode('condition', asUtility=1))
         cmds.setAttr((self.stretchCondition + ".operation"), 2)
         self.colorBlendNode=str(cmds.shadingNode('blendColors', asUtility=1))
         cmds.setAttr((self.colorBlendNode + ".color2R"), 1)
         self.arm01ScaleMD=str(cmds.shadingNode('multiplyDivide', asUtility=1))
         self.arm02ScaleMD=str(cmds.shadingNode('multiplyDivide', asUtility=1))
         
         
         #connect them attributes
         self.LinkConstraints(self.jnt1LocShape[0], "worldPosition[0]", self.distanceTest, "point1")
         self.LinkConstraints(self.jnt2LocShape[0], "worldPosition[0]", self.distanceTest, "point2")
         self.LinkConstraints(self.arm01DistanceNode, "outputX", self.chainLengthPMA, "input1D[0]")
         self.LinkConstraints(self.arm02DistanceNode, "outputX", self.chainLengthPMA, "input1D[1]")
         self.LinkConstraints(self.chainLengthPMA, "output1D", self.distanceScalar, "input2X")
         self.LinkConstraints(self.distanceTest, "distance", self.distanceScalar, "input1X")
         self.LinkConstraints(self.distanceTest, "distance", self.stretchCondition, "firstTerm")
         self.LinkConstraints(self.chainLengthPMA, "output1D", self.stretchCondition, "secondTerm")
         self.LinkConstraints(self.distanceScalar, "outputX", self.stretchCondition, "colorIfTrueR")
         self.LinkConstraints(self.stretchCondition, "outColorR", self.colorBlendNode, "color1R")
         self.LinkConstraints(self.arm01DistanceNode, "outputX", self.arm01ScaleMD, "input1X")
         self.LinkConstraints(self.arm02DistanceNode, "outputX", self.arm02ScaleMD, "input1X")
         self.LinkConstraints(self.colorBlendNode, "outputR", self.arm01ScaleMD, "input2X")
         self.LinkConstraints(self.colorBlendNode, "outputR", self.arm02ScaleMD, "input2X")
         self.LinkConstraints(self.arm01ScaleMD, "outputX", armSels[1], "translateX")
         self.LinkConstraints(self.arm02ScaleMD, "outputX", armSels[2], "translateX")
         self.LinkConstraints((str(armSels[0]) + "_IK_Ctrl"), "Stretchy", self.colorBlendNode, "blender")
         cmds.parentConstraint(self.ikCtrlTempName, self.tempIKName,  mo=True )
         cmds.parentConstraint(self.ikCtrlTempName, self.jnt2Loc,  mo=True )
         cmds.scaleConstraint(self.ikCtrlTempName, self.tempIKName,  mo=True )
         cmds.scaleConstraint(self.ikCtrlTempName, self.jnt2Loc,  mo=True )
 
     else:
         print("Generic Error Message")
         return        
Ejemplo n.º 35
0
def IMPORTFILE(outputReference, listImportWidget, batchMode, home):
    py.scriptEditorInfo(suppressWarnings=1, e=1)
    validSelection = 0
    animationSelection = True
    if (str(listImportWidget) != "none" and
        ("." not in str(listImportWidget) or "<" in str(listImportWidget))):
        #IF FILE NAME ISN'T PROVIDED BY OUTSIDE SOURCES, GET IT FROM LIBRARY
        try:
            selectedAnimation = listImportWidget.currentItem().text()
        except:
            animationSelection = False
    customFile = home + "CUSTOM.json" if (".json"
                                          not in home.split("/")[-1]) else home
    customFileCheck = py.file(customFile, q=1, ex=1)
    if (customFileCheck == 1):
        with open(customFile, 'r') as f:
            line = json.load(f)
    if (outputReference == "none" and animationSelection == True):
        outputReference = line['IMPORT FILE (PATH)'] + selectedAnimation
    #GET RIG PATH FROM CUSTOM (USE "LITE" PATH IF IN BATCH MODE)
    rigPath = line['RIG (FULL NAME)']
    rigLitePath = rigPath.replace("CHAR_", "LITE_")
    if (py.file(rigLitePath, q=1, ex=1) == 1 and line['EXPORT AS .MA'] == 0
            and batchMode == 1 and animationSelection == True):
        rigPath = rigLitePath
    inputNameSpace = "inputFile"
    outputNameSpace = "outputFile"
    i = 1
    while (py.namespace(exists=outputNameSpace) == 1):
        outputNameSpace = outputNameSpace + str(i)
        i += 1
    i = 1
    while (py.namespace(exists=inputNameSpace) == 1):
        inputNameSpace = inputNameSpace + str(i)
        i += 1
    #IF SELECTED, CHECK NAMESPACE IF CONTROLLER IS VALID
    selections = py.ls(sl=1)
    if (selections != [] and animationSelection == True):
        i = 0
        while (i < len(selections)):
            RiGGiE = py.listAttr(selections[i], st=["RiGGiE"], r=1)
            if (isinstance(RiGGiE, list) == 1):
                selections = selections[i]
                try:
                    filePath = py.referenceQuery(selections, filename=1)
                    if (":" in selections):
                        name = selections.split(":")[-1]
                    else:
                        name = selections
                    if (len(selections) > len(name)):
                        nameSpace = selections[0:(len(selections) - len(name))]
                    else:
                        nameSpace = ""
                    if ("_" in nameSpace):
                        correctedName = nameSpace.replace("_", "")
                        py.file(filePath,
                                referenceNode="nameSpace",
                                namespace=correctedName,
                                e=1)
                        inputNameSpace = correctedName
                    else:
                        inputNameSpace = nameSpace
                except:
                    inputNameSpace = "none"
                validSelection = 1
                break
            if (i == len(selections) - 1):
                selections = []
                py.headsUpMessage(
                    '"No valid controllers selected..." - HiGGiE', t=2)
                print '"No valid controllers selected..." - HiGGiE'
            i += 1
    #REFERENCE IN THE INPUT RIG (TARGET) AND output RIG (ANIMATED)
    if ((py.file(rigPath, q=1, ex=1) == 1 or inputNameSpace == "none")
            and py.file(outputReference, q=1, ex=1) == 1
            and animationSelection == True):
        #try:#IF FAILS, THEN USER IS IMPORTING THE SAME FILE INTO ITSELF
        py.file(outputReference,
                namespace=outputNameSpace,
                prompt=0,
                mnp=1,
                iv=1,
                gr=1,
                r=1)
        referenceGroup = py.ls(sl=1)[0]
        py.setAttr(referenceGroup + ".v", 0)
        try:
            firstItem = py.listRelatives(referenceGroup,
                                         type="joint",
                                         c=1,
                                         s=0)[-1]
        except:
            firstItem = py.listRelatives(referenceGroup,
                                         type="joint",
                                         ad=1,
                                         s=0)[-1]
        nameSpaceBreakdown = firstItem.split(":")[:-1]
        officialOutputNameSpace = ""
        i = 0
        while (i < len(nameSpaceBreakdown)):
            officialOutputNameSpace = officialOutputNameSpace + nameSpaceBreakdown[
                i] + ":"
            i += 1
        outputNameSpace = officialOutputNameSpace[:-1]
        #IMPORT INPUT RIG IF NO RIG IS SELECTED
        if (inputNameSpace != "none" and validSelection == 0):
            initialObjects = py.ls(type="transform", o=1)
            py.file(rigPath,
                    namespace=inputNameSpace,
                    prompt=0,
                    mnp=1,
                    iv=1,
                    r=1)
        #FIND OFFICIAL NAMESPACE OF INPUT RIG
        if (selections == []):
            allObjects = py.ls(type="transform", o=1)
            allTransforms = list(set(allObjects) - set(initialObjects))
            i = 0
            while (i < len(allTransforms)):
                if ("_" in allTransforms[i]):
                    if (allTransforms[i].split("_")[-1] == "CTRL"):
                        rigController = allTransforms[i]
                        break
                i += 1
            if (":" in rigController):
                name = rigController.split(":")[-1]
                inputNameSpace = rigController[0:(len(rigController) -
                                                  len(name))]
            else:
                inputNameSpace = "none"
            selections = rigController
        joints = py.ls(outputNameSpace + ":*", type="joint")
        if (joints != []):
            py.select(selections, r=1)
            animationTransfer.ANIMATIONTRANSFER(inputNameSpace,
                                                outputNameSpace,
                                                outputReference, home)
        else:
            py.headsUpMessage('"No joints found in animated file..." - HiGGiE',
                              t=2)
            print '"No joints found in animated file..." - HiGGiE'
        #except:
        #    py.headsUpMessage('"Can not reference the same file into itself." - HiGGiE', t=2);
        #    print '"Can not reference the same file into itself." - HiGGiE';
    elif (animationSelection == False):
        py.headsUpMessage(
            '"You must select a valid animation in the library." - HiGGiE',
            t=2)
        print '"You must select a valid animation in the library." - HiGGiE'
    else:
        py.headsUpMessage('"Import file(s) do not exist..." - HiGGiE', t=2)
        print '"Import file(s) do not exist..." - HiGGiE'
Ejemplo n.º 36
0
 else:
     smdName = util.names.nodeName('softMod', baseName)
         
 vtxPlug = mesh
 mesh = mel.eval('plugNode("{0}")'.format(str(vtxPlug)))
 if vtxPlug != mesh:
     softModPos = cmds.xform(vtxPlug, ws=1, t=1, q=1)
 else:
     softModPos = cmds.xform(mesh, ws=1, rp=1, q=1)
 
 # Piv ctl
 softModCenterCtlGrp = cmds.createNode('transform',
     n=util.names.nodeName('transform', '{0}PivotGrp'.format(baseName)))
 softModCenterCtl = cmds.spaceLocator(n=util.names.nodeName('transform', '{0}Pivot'.format(baseName)))[0]
 cmds.parent(softModCenterCtl, softModCenterCtlGrp)
 locatorShape = cmds.listRelatives(softModCenterCtl, children=1, type='locator')[0]
 grpParent = softModCenterCtlGrp
 
 # Soft Mod ctl
 softModCtlGrp = cmds.createNode('transform',
     n=util.names.nodeName('transform', '{0}Grp'.format(baseName)))
 softModCtl = cmds.circle(
     n=util.names.nodeName('transform', '{0}'.format(baseName)))[0]
 cmds.parent(softModCtl, softModCtlGrp)
 cmds.parent(softModCtlGrp, softModCenterCtl)
 
 meshConnections = cmds.listConnections('{0}.inMesh'.format(mesh), s=1, d=0, plugs=1)
 if attachToMesh and meshConnections:
     # Create a transform constrained to the mesh
     rivetGrp = cmds.createNode('transform',
         n=util.names.addModifier(softModCenterCtlGrp, 'transform', addSuffix='Rivet'))
Ejemplo n.º 37
0
def deformer(mod=None, side=None, name=None, suffix=None, obj=None):
    """ Rename the given node and return its final name """
    #--- check which one of the given obj is the transform node
    trn = list()
    non = list()
    if isinstance(obj, list):
        for i in obj:
            if cmds.nodeType(i) == 'transform':
                trn.append(i)
            else:
                if not cmds.nodeType(i) == 'shape':
                    non.append(i)
    else:
        if cmds.nodeType(obj) == 'transform':
            trn.append(obj)
        else:
            if not cmds.nodeType(obj) == 'shape':
                non.append(obj)
    if trn:
        obj = trn[0]
    if non:
        non = non[0]
    obj_name = None
    #--- get the curve name based on the given specifications
    if mod:
        if side:
            if name:
                if suffix:
                    #--- side_modName_suffix
                    obj_name = (side + '_' + mod + name[0].upper() + name[1:] +
                                '_' + suffix)
                else:
                    #--- side_modName
                    obj_name = side + '_' + mod + name[0].upper() + name[1:]
            else:
                if suffix:
                    #--- side_modCrv_suffix
                    obj_name = (side + '_' + mod + obj[0].upper() + obj[1:] +
                                '_' + suffix)
                else:
                    #--- side_modCrv
                    obj_name = side + '_' + mod + obj[0].upper() + obj[1:]
        else:
            if name:
                if suffix:
                    #--- modName_suffix
                    obj_name = mod + name[0].upper() + name[1:] + '_' + suffix
                else:
                    #--- modName
                    obj_name = mod + name[0].upper() + name[1:]
            else:
                #--- modCrv
                obj_name = mod + obj[0].upper() + obj[1:]
    else:
        if side:
            if name:
                if suffix:
                    #--- side_name_suffix
                    obj_name = side + '_' + name + '_' + suffix
                else:
                    #--- side_name
                    obj_name = side + '_' + name
            else:
                if suffix:
                    #--- side_obj_suffix
                    obj_name = side + '_' + obj + '_' + suffix
                else:
                    #--- side_obj
                    obj_name = side + '_' + obj
        else:
            if name:
                if suffix:
                    #--- name_suffix
                    obj_name = name + '_' + suffix
                else:
                    #--- name
                    obj_name = name
            else:
                #--- obj
                obj_name = obj
    #--- rename the obj
    transform = cmds.rename(obj, obj_name)
    shape = list()
    if cmds.listRelatives(transform, children=True):
        shape = cmds.listRelatives(transform,
                                   allDescendents=True,
                                   type='shape')[0]
    #--- rename the nonTransform/nonShape obj
    result = list()
    if non:
        if cmds.objExists(non):
            non = cmds.rename(non, obj_name + non[0].upper() + non[1:])
            result = [transform, shape, non]
        else:
            if shape:
                result = [transform, shape]
            else:
                result = transform
    else:
        result = [transform, shape]
    return result
Ejemplo n.º 38
0
def BtoT():
	global jnt
	ben = many[j]
	tjo = mc.listRelatives(ben)
	twi = tjo[0]
	if '_L' in '{}'.format(ben):
		a = ben.split('_bend_L')
		for i in get:
			if a[0] in i:
				if '_L' in '{}'.format(i):
					if 'bend' not in '{}'.format(i):
						if 'twist' not in '{}'.format(i):
							jnt = i
	elif '_R' in '{}'.format(ben):
		a = ben.split('_bend_R')
		for i in get:
			if a[0] in i:
				if '_R' in '{}'.format(i):
					if 'bend' not in '{}'.format(i):
						if 'twist' not in '{}'.format(i):
							jnt = i
	else:
		a = ben.split('_bend')
		for i in get:
			if a[0] in i:
				if '_L' not in '{}'.format(i):
					if '_R' not in '{}'.format(i):
						if 'bend' not in '{}'.format(i):
							if 'twist' not in '{}'.format(i):
								jnt = i
	
	if bant >= 1:
		for i in baim:
			if jnt in i:
				roop()

	#create node
	aim = mc.createNode('aimConstraint', n='{}_afterSplitTwistDriver'.format(jnt))
	mc.select('{}'.format(aim), r=True)
	mc.addAttr(ln='bend', nc=3, at='double3')
	mc.addAttr(ln='twist', nc=3, at='double3')
	for i in range(3):
		mc.addAttr(ln='bend{}'.format(xyz[i]), at='doubleAngle', p='bend', k=True)
		mc.addAttr(ln='twist{}'.format(xyz[i]), at='doubleAngle', p='twist', k=True)

	oc1 = mc.createNode('orientConstraint', n='{}_afterSplitTwist'.format(jnt))
	oc2 = mc.createNode('orientConstraint', n='{}_rot'.format(jnt))
	oc3 = mc.createNode('orientConstraint', n='{}_twistRot'.format(jnt))
	pb1 = mc.createNode('pairBlend', n='{}_weightedTwist'.format(jnt))
	mc.addAttr(ln='inRot2', nc=3, at='double3', w=False)
	for i in range(3):
		mc.addAttr(ln='inRot2{}'.format(xyz[0]), at='doubleAngle', p='inRot2', w=False)

	pb2 = mc.createNode('pairBlend', n='{}_rotSafeRot'.format(jnt))
	pb3 = mc.createNode('pairBlend', n='{}_twistRotSafeRot'.format(jnt))

	grp = mc.group('{}'.format(oc1),'{}'.format(oc2),'{}'.format(oc3), n='{}_BendTwist'.format(jnt))
	mc.parent('{}'.format(aim), '{}'.format(jnt))
	mc.parent('{}'.format(grp), '{}'.format(jnt))
	mc.setAttr('{}.visibility'.format(grp), 0)


	#setAttr
	mc.setAttr('{}.target[0].targetTranslateX'.format(aim), 1)
	mc.setAttr('{}.worldUpType'.format(aim), 4)
	mc.setAttr('{}.interpType'.format(oc2), 2)
	mc.setAttr('{}.interpType'.format(oc3), 2)
	mc.setAttr('{}.rotateMode'.format(pb2), 2)
	mc.setAttr('{}.rotateMode'.format(pb3), 2)
	mc.setAttr('{}.rotInterpolation'.format(pb2), 1)
	mc.setAttr('{}.rotInterpolation'.format(pb3), 1)
	for i in range(3):
		mc.setAttr('{0}.translate{1}'.format(aim, xyz[i]), 0)


	#connectAttr
	mc.connectAttr('{}.constraintRotate'.format(aim), '{}.bend'.format(aim))
	mc.connectAttr('{}.constraintRotate'.format(aim), '{}.constraintJointOrient'.format(oc1))
	mc.connectAttr('{}.constraintRotate'.format(oc1), '{}.twist'.format(aim))
	mc.connectAttr('{}.matrix'.format(aim), '{}.target[0].targetParentMatrix'.format(aim))
	mc.connectAttr('{}.matrix'.format(aim), '{}.target[0].targetParentMatrix'.format(oc1))
	mc.connectAttr('{}.bend'.format(aim), '{}.target[0].targetJointOrient'.format(oc2))
	mc.connectAttr('{}.twist'.format(aim), '{}.inRotate1'.format(pb1))
	mc.connectAttr('{}.inRot2'.format(pb1), '{}.inRotate2'.format(pb1))
	mc.connectAttr('{}.outRotate'.format(pb1), '{}.target[0].targetRotate'.format(oc2))
	mc.connectAttr('{}.constraintRotate'.format(oc2), '{}.inRotate2'.format(pb2))
	mc.connectAttr('{}.constraintRotate'.format(oc2), '{}.constraintJointOrient'.format(oc3))
	mc.connectAttr('{}.rotate'.format(jnt), '{}.target[0].targetRotate'.format(oc3))
	mc.connectAttr('{}.constraintRotate'.format(oc3), '{}.inRotate2'.format(pb3))
	mc.connectAttr('{}.twistWeight'.format(twi), '{}.weight'.format(pb1))
	for i in range(3):
		mc.connectAttr('{0}.rotate{1}'.format(jnt, xyz[i]), '{0}.rotate{1}'.format(aim, xyz[i]))
		mc.connectAttr('{0}.translate{1}'.format(jnt, xyz[i]), '{0}.translate{1}'.format(ben, xyz[i]))
		mc.connectAttr('{0}.scale{1}'.format(jnt, xyz[i]), '{0}.scale{1}'.format(ben, xyz[i]))
		mc.connectAttr('{0}.shear{1}'.format(jnt, she[i]), '{0}.shear{1}'.format(ben, she[i]))
		mc.connectAttr('{0}.scale{1}'.format(ben, xyz[i]), '{0}.scale{1}'.format(twi, xyz[i]))
		mc.connectAttr('{0}.outRotate{1}'.format(pb2, xyz[i]), '{0}.rotate{1}'.format(ben, xyz[i]))
		mc.connectAttr('{0}.outRotate{1}'.format(pb3, xyz[i]), '{0}.rotate{1}'.format(twi, xyz[i]))

	roop()
 def getParent(self, obj, *args, **kwargs):
     return mc.listRelatives(obj, p=1)
Ejemplo n.º 40
0
	def checkObjectSetKey(self):
		'''
		驱动过的物体是否锁定并设置成了不可K帧。
		'''
		geoName = self.getGeoGroup()
		notGroup = ['hair_G' , 'arnold_loc*' , 'yeti_G' , 'cloth_G']
		
		if not geoName:
			OpenMaya.MGlobal_displayWarning('not geo group') 
		else:
			notGroup.append(geoName[0])
				
		notTransList = []
		for n in notGroup:
			if pm.objExists(n):
				for i in pm.ls(n , tr = True):
					notTransList += self.notCkeck(pm.PyNode(i))

		jointSel =  cmds.ls( type = 'joint') 
		if jointSel:
			for jnt in jointSel:
				attr = cmds.listAttr(jnt , k = True)
				if attr:
					for a in attr:
						value = cmds.getAttr(jnt+'.'+a , k = True)
						if value:
							if jnt not in self.keyjointList:
								self.keyjointList.append(jnt)
								continue
		
		
					
					
		all = cmds.ls(dag= True , type = 'transform' )
		
		if not all:
			OpenMaya.MGlobal_displayInfo('file not object')
			return 
		

		conList = cmds.ls( type =['constraint','joint'])
		ctrlList = [ cmds.listRelatives(s , p = True)[0] for s in  cmds.ls(type = ['nurbsCurve' ,'camera'])]
		transList = [t for t in all if t not in conList+ctrlList+notTransList]
		attrs = ['t' , 'r' , 's'  ]
		
		for t in transList:
			attr = cmds.listAttr(t , k = True ,sn = True)
			if attr:
				for at in attr:
					if at not in self.setKeyDict.keys():
						continue
					value1 = cmds.getAttr(t +'.'+ at  , l = True)
					if not value1:
						value = cmds.getAttr(t +'.'+ at)
						if value != self.setKeyDict[at] :
							if t not in self.keyOverName:
								self.keyOverName.append(t)
								continue
						if cmds.listConnections(t +'.'+ at , s = True , d = False):
							if t not in self.keyOverName:
								self.keyOverName.append(t)
		
			for at in attrs:
				valueX = cmds.getAttr(t +'.'+ at +'x' , l = True)
				valueY = cmds.getAttr(t +'.'+ at +'y'  , l = True)
				valueZ = cmds.getAttr(t +'.'+ at +'z' , l = True)
				if valueX == True and valueX == True and valueX == True:
					continue
				if cmds.listConnections(t +'.'+ at , s = True , d = False):
					if t not in self.keyOverName:
						self.keyOverName.append(t)
					continue
				
				 
		return 	self.keyOverName+self.keyjointList
Ejemplo n.º 41
0
    def sqGenerateCurves(self, *args):
        self.edgeList = cmds.ls(selection=True, flatten=True)
        if not self.edgeList == None and not self.edgeList == [] and not self.edgeList == "":
            self.baseCurve = cmds.polyToCurve(name="baseCurve",
                                              form=2,
                                              degree=1)[0]
            cmds.select(self.baseCurve + ".ep[*]")
            cmds.insertKnotCurve(cmds.ls(selection=True, flatten=True),
                                 constructionHistory=True,
                                 curveOnSurface=True,
                                 numberOfKnots=1,
                                 addKnots=False,
                                 insertBetween=True,
                                 replaceOriginal=True)

            pointListA, pointListB, sideA, sideB = self.sqGetPointLists()

            toDeleteList = []
            p = 2
            for k in range((sideA + 2), (sideB - 1)):
                if p % 2 == 0:
                    toDeleteList.append(self.baseCurve + ".cv[" + str(k) + "]")
                    toDeleteList.append(self.baseCurve + ".cv[" +
                                        str(k + len(pointListA) - 1) + "]")
                p = p + 1
            q = 2
            m = sideA - 2
            if m >= 0:
                while m >= 0:
                    if not m == sideA and not m == sideB:
                        if q % 2 == 0:
                            toDeleteList.append(self.baseCurve + ".cv[" +
                                                str(m) + "]")
                    m = m - 1
                    q = q + 1

            cmds.delete(toDeleteList)
            cmds.insertKnotCurve([
                self.baseCurve + ".u[" + str(len(pointListA) - 1) + "]",
                self.baseCurve + ".ep[" + str(len(pointListA) - 1) + "]"
            ],
                                 constructionHistory=True,
                                 curveOnSurface=True,
                                 numberOfKnots=1,
                                 addKnots=False,
                                 insertBetween=True,
                                 replaceOriginal=True)

            pointListA, pointListB, sideA, sideB = self.sqGetPointLists()

            posListA, posListB = [], []
            for i in range(0, len(pointListA) - 1):
                posListA.append(
                    cmds.xform(pointListA[i],
                               query=True,
                               worldSpace=True,
                               translation=True))
                posListB.append(
                    cmds.xform(pointListB[i],
                               query=True,
                               worldSpace=True,
                               translation=True))

            self.mainCurveA = cmds.curve(name="StickyLips_Main_A_Crv",
                                         degree=1,
                                         point=posListA)
            self.mainCurveB = cmds.curve(name="StickyLips_Main_B_Crv",
                                         degree=1,
                                         point=posListB)

            cmds.rename(
                cmds.listRelatives(self.mainCurveA, children=True,
                                   shapes=True)[0], self.mainCurveA + "Shape")
            cmds.rename(
                cmds.listRelatives(self.mainCurveB, children=True,
                                   shapes=True)[0], self.mainCurveB + "Shape")

            cmds.select(self.mainCurveA + ".cv[*]")
            self.curveLenght = len(cmds.ls(selection=True, flatten=True))
            cmds.select(clear=True)

            self.sqCheckCurveDirection(self.mainCurveA)
            self.sqCheckCurveDirection(self.mainCurveB)

            self.baseCurveA = cmds.duplicate(self.mainCurveA,
                                             name=self.mainCurveA.replace(
                                                 "_Main_", "_Base_"))[0]
            self.baseCurveB = cmds.duplicate(self.mainCurveB,
                                             name=self.mainCurveB.replace(
                                                 "_Main_", "_Base_"))[0]

            cmds.delete(self.baseCurve)
            self.maxIter = len(posListA)

            cmds.group(self.mainCurveA,
                       self.mainCurveB,
                       self.baseCurveA,
                       self.baseCurveB,
                       name="StickyLips_StaticData_Grp")
        else:
            mel.eval("warning \"Please, select an closed edgeLoop.\";")
 def cleanup(self, *args, **kwargs):
     root=self.root
     #blow away constraints
     const=mc.ls(type="constraint")
     if const:
         mc.delete(const)
     
     #kill display layers
     dispLayers=mc.ls(type="displayLayer")
     if dispLayers:
         mc.delete(dispLayers)
     
     #flatten geometry hierarchy
     if mc.objExists(self.geoGrp):
         geo=[]
         for obj in mc.listRelatives(self.geoGrp, ad=1):
             if mc.objectType(obj)=="mesh" and self.getParent(self.getParent(obj))!=self.geoGrp:
                 geo.append(self.getParent(obj)[0])
         geo=list(set(geo))
         try:
             mc.parent(geo, self.geoGrp)
         except:
             print "Can't parent %s to %s"%(geo, self.geoGrp)
             pass
         #delete non mesh groups in geo group
         geoChildren=mc.listRelatives(self.geoGrp, c=1)
         for dag in geoChildren:
             meshes=None
             children=mc.listRelatives(dag, c=1)
             if children:
                 for child in children:
                     if mc.objectType(child)=="mesh":
                         meshes=child
             if not meshes:
                 mc.delete(dag)
     else:
         mc.group(em=1, n=self.geoGrp)
         mc.parent(mc.listRelatives(mc.ls(type="mesh"), p=1), self.geoGrp)
     
     #clean out root and move joints and geo into root
     if mc.objExists(root)!=1:
         mc.group(em=1, n=root)
     else:
         mc.parent(mc.listRelatives(root, c=1), w=1)
     
     mc.parent(self.geoGrp, root)
     
     mc.lockNode(self.jntGrp, l=0)
     mc.parent(self.jntGrp, root)
     
     safeList=mc.listRelatives(root, ad=1)
     safeList.append(root)
     
     killList=mc.ls(dag=1)
     for i in safeList:
         try:
             killList.remove(i)
         except:
             pass
     
     mc.delete(killList)
Ejemplo n.º 43
0
    def _publish_camera(self, item, publish_template, fields, comment, sg_task,
                        primary_publish_path, progress_cb, thumbnail_path):
        """
        Publishes the selected camera
        """
        errors = []

        print "<publish> publish camera called"

        # set publish path and publish name based on publish template and item name respectively.
        fields['name'] = item['name'].replace(":", "_")
        secondary_publish_path = publish_template.apply_fields(fields)
        secondary_publish_name = fields.get(
            "name").upper()  # we want an uppercase name
        if not secondary_publish_name:
            secondary_publish_name = os.path.basename(secondary_publish_path)

        print "<publish> using name for publish: %s" % secondary_publish_name

        # check if camera has already been published.
        if os.path.exists(secondary_publish_path):
            print "<publish> The published camera named '%s' already exists!" % secondary_publish_path
            errors.append("The published camera named '%s' already exists!" %
                          secondary_publish_path)
            return errors

        # select the camera
        try:
            cmds.select(item['name'],
                        visible=True,
                        hierarchy=True,
                        replace=True)
            print "<publish> selected %s" % item['name']
        except ValueError as e:
            errors.append('Unable to select camera [%s]' % item['name'])
            return errors

        # find the animated frame range to use:
        start_frame, end_frame = self._find_scene_animation_range()

        # bake out camera if grouped
        if not cmds.listRelatives(item['name'], allParents=True) is None:
            dup_name = self._bake_camera(item, start_frame, end_frame)
        else:
            dup_name = item['name']
            self._unlock_camera(dup_name)
            if not cmds.getAttr(''.join([dup_name, '.sx'])) == 1:
                cmds.setAttr(''.join([dup_name, '.sx']), 1)
                cmds.setAttr(''.join([dup_name, '.sy']), 1)
                cmds.setAttr(''.join([dup_name, '.sz']), 1)

        alembic_args_string = ''.join(["-root |", dup_name])
        alembic_args = [alembic_args_string]

        if start_frame and end_frame:
            alembic_args.append("-fr %d %d" % (start_frame, end_frame))

        # Set the output path:
        # Note: The AbcExport command expects forward slashes!
        alembic_args.append("-file %s" %
                            secondary_publish_path.replace("\\", "/"))

        # build the export command.  Note, use AbcExport -help in Maya for
        # more detailed Alembic export help
        abc_export_cmd = ("AbcExport -j \"%s\"" % " ".join(alembic_args))

        # ...and execute it:
        progress_cb(30, "Exporting Alembic cache")
        try:
            self.parent.log_debug("Executing command: %s" % abc_export_cmd)
            mel.eval(abc_export_cmd)
        except Exception, e:
            raise TankError("Failed to export Alembic Cache: %s" % e)
Ejemplo n.º 44
0
    def sqCreateStickyLipsCtrlAttr(self, *args):
        if not cmds.objExists(self.optionCtrl):
            cmds.circle(name=self.optionCtrl, constructionHistory=False)
        cmds.addAttr(self.optionCtrl,
                     longName='stickyLips',
                     attributeType='bool')
        cmds.setAttr(self.optionCtrl + '.stickyLips', edit=True, keyable=True)

        for i in range(0, self.maxIter):
            cmds.addAttr(self.optionCtrl,
                         longName="stickyLipsWireLocator" + str(i),
                         attributeType='float',
                         keyable=False)

        for i in range(0, self.maxIter):
            for wireNode in self.wireNodeList:
                cmds.connectAttr(
                    self.optionCtrl + ".stickyLipsWireLocator" + str(i),
                    wireNode + ".wireLocatorEnvelope[" + str(i) + "]")

        slTextCurve = cmds.textCurves(ch=False,
                                      font="Arial|w400|h-08",
                                      text="StickyLips",
                                      name="StickyLips_Label_Txt")[0]
        if "Shape" in slTextCurve:
            slTextCurve = cmds.rename(slTextCurve,
                                      slTextCurve[:slTextCurve.find("Shape")])
        t = 0
        slCharTransformList = cmds.listRelatives(slTextCurve,
                                                 children=True,
                                                 type="transform")
        for charTransform in slCharTransformList:
            txValue = cmds.getAttr(charTransform + ".tx")
            sLTextShapeList = cmds.listRelatives(charTransform,
                                                 allDescendents=True,
                                                 type="nurbsCurve")
            for i, textShape in enumerate(sLTextShapeList):
                textShape = cmds.rename(textShape,
                                        "StickyLips_Txt_" + str(t) + "Shape")
                cmds.parent(textShape, slTextCurve, shape=True, relative=True)
                cmds.move(txValue, 0, 0, textShape + ".cv[:]", relative=True)
                t = t + 1
            cmds.delete(charTransform)
        cmds.setAttr(slTextCurve + ".translateX", -0.1)
        cmds.setAttr(slTextCurve + ".translateY", 0.25)
        cmds.setAttr(slTextCurve + ".scaleX", 0.1)
        cmds.setAttr(slTextCurve + ".scaleY", 0.1)
        cmds.setAttr(slTextCurve + ".scaleZ", 0.1)
        cmds.setAttr(slTextCurve + ".template", 1)
        cmds.makeIdentity(slTextCurve, apply=True)

        sideNameList = ["L", "R"]
        for side in sideNameList:
            bg = cmds.circle(name=side + "_StickyLips_Bg",
                             normal=(0, 0, 1),
                             radius=1,
                             degree=1,
                             sections=4,
                             constructionHistory=False)[0]
            cmds.setAttr(bg + ".rotateZ", 45)
            cmds.setAttr(bg + ".translateX", 0.5)
            cmds.makeIdentity(bg, apply=True)
            cmds.setAttr(bg + ".scaleX", 0.85)
            cmds.setAttr(bg + ".scaleY", 0.15)
            cmds.makeIdentity(bg, apply=True)
            cmds.setAttr(bg + ".template", 1)

            self.sliderCtrl = cmds.circle(name=side + "_StickyLips_Ctrl",
                                          normal=(0, 0, 1),
                                          radius=0.1,
                                          degree=3,
                                          constructionHistory=False)[0]
            attrToHideList = [
                'ty', 'tz', 'rx', 'ry', 'rz', 'sx', 'sy', 'sz', 'v'
            ]
            for attr in attrToHideList:
                cmds.setAttr(self.sliderCtrl + "." + attr,
                             edit=True,
                             lock=True,
                             keyable=False)
            cmds.transformLimits(self.sliderCtrl,
                                 translationX=(0, 1),
                                 enableTranslationX=(1, 1))

        distPos = 1.0 / self.maxIter
        for i in range(0, self.maxIter):
            lPosA = (i * distPos)
            lPosB = (lPosA + distPos)
            rPosB = 1 - (i * distPos)
            rPosA = (rPosB - distPos)
            if i > 0:
                lPosA = lPosA - (distPos * 0.33)
                rPosA = rPosA - (distPos * 0.33)
            cmds.setDrivenKeyframe(self.optionCtrl,
                                   attribute="stickyLipsWireLocator" + str(i),
                                   currentDriver=sideNameList[0] +
                                   "_StickyLips_Ctrl.translateX",
                                   driverValue=lPosA,
                                   value=0,
                                   inTangentType="linear",
                                   outTangentType="linear")
            cmds.setDrivenKeyframe(self.optionCtrl,
                                   attribute="stickyLipsWireLocator" + str(i),
                                   currentDriver=sideNameList[0] +
                                   "_StickyLips_Ctrl.translateX",
                                   driverValue=lPosB,
                                   value=1,
                                   inTangentType="linear",
                                   outTangentType="linear")
            cmds.setDrivenKeyframe(self.optionCtrl,
                                   attribute="stickyLipsWireLocator" + str(i),
                                   currentDriver=sideNameList[1] +
                                   "_StickyLips_Ctrl.translateX",
                                   driverValue=rPosA,
                                   value=0,
                                   inTangentType="linear",
                                   outTangentType="linear")
            cmds.setDrivenKeyframe(self.optionCtrl,
                                   attribute="stickyLipsWireLocator" + str(i),
                                   currentDriver=sideNameList[1] +
                                   "_StickyLips_Ctrl.translateX",
                                   driverValue=rPosB,
                                   value=1,
                                   inTangentType="linear",
                                   outTangentType="linear")

        lSliderGrp = cmds.group(sideNameList[0] + "_StickyLips_Ctrl",
                                sideNameList[0] + "_StickyLips_Bg",
                                name=sideNameList[0] + "_StickyLips_Ctrl_Grp")
        rSliderGrp = cmds.group(sideNameList[1] + "_StickyLips_Ctrl",
                                sideNameList[1] + "_StickyLips_Bg",
                                name=sideNameList[1] + "_StickyLips_Ctrl_Grp")
        cmds.setAttr(rSliderGrp + ".rotateZ", 180)
        cmds.setAttr(rSliderGrp + ".translateY", -0.25)
        sliderGrp = cmds.group(lSliderGrp,
                               rSliderGrp,
                               slTextCurve,
                               name="StickyLips_Ctrl_Grp")
Ejemplo n.º 45
0
def setPublishPose(rig, con):

    ###create pub group
    #query parent
    pnt = cmds.listRelatives(con, p=True)[0]
    pub_nul = ''
    #name sort
    if cmds.attributeQuery('publishPose', node='rig_GRP', ex=True) is False:
        cmds.addAttr(rig,
                     k=True,
                     ln='publishPose',
                     at='double',
                     min=0,
                     max=1,
                     dv=0)

    cmds.setAttr(rig + '.publishPose', 1)

    pub_nul = cmds.group(con, n=con.replace('_CON', 'PublishPose_NUL'))

    cmds.xform(pub_nul, os=True, rp=(0, 0, 0))

    ###end create pub group
    ###set pub pose
    #
    loc = cmds.spaceLocator(n=con.replace('_CON', 'PubPose_LOC'))[0]
    pbd = cmds.createNode('pairBlend')
    cmds.setAttr(pbd + '.rotInterpolation', 1)

    prefix = con.split('_')[0]

    if 'IK_foot' in con:
        pos1 = cmds.xform(prefix + '_IK_leg_JNT', q=True, rp=True, ws=True)
        pos2 = cmds.xform(prefix + '_IK_lowLeg_JNT', q=True, rp=True, ws=True)
        pos3 = cmds.xform(prefix + '_IK_foot_JNT', q=True, rp=True, ws=True)

        dis1 = abs(
            math.sqrt(
                math.pow(pos1[0] - pos2[0], 2) +
                math.pow(pos1[1] - pos2[1], 2) +
                math.pow(pos1[2] - pos2[2], 2)))
        dis2 = abs(
            math.sqrt(
                math.pow(pos2[0] - pos3[0], 2) +
                math.pow(pos2[1] - pos3[1], 2) +
                math.pow(pos2[2] - pos3[2], 2)))

        distance = dis1 + dis2
        cmds.delete(cmds.pointConstraint(prefix + '_IK_leg_JNT', loc, w=True))

        if 'Vec' in con:
            cmds.move(0, distance * -0.5, 5, loc, r=True)
            pbd = cmds.listConnections(
                con.replace('_CON', 'Space_NUL') + '.t')[0]
            dcm1 = cmds.listConnections(pbd + '.inTranslate1')[0]
            dcm2 = cmds.listConnections(pbd + '.inTranslate2')[0]
            mmx1 = cmds.listConnections(dcm1 + '.inputMatrix')[0]
            mmx2 = cmds.listConnections(dcm2 + '.inputMatrix')[0]
            loc1 = cmds.listConnections(mmx1 + '.matrixIn[0]')[0]
            loc2 = cmds.listConnections(mmx2 + '.matrixIn[0]')[0]

            t1 = cmds.getAttr(loc1 + '.t')[0]
            cmds.delete(cmds.parentConstraint(loc, loc1, w=True))
            t2 = cmds.getAttr(loc1 + '.t')[0]

            pbd = cmds.createNode('pairBlend')
            cmds.setAttr(pbd + '.inTranslate1', t1[0], t1[1], t1[2])
            cmds.setAttr(pbd + '.inTranslate2', t2[0], t2[1], t2[2])
            cmds.connectAttr(pbd + '.outTranslate', loc1 + '.t', f=True)
            cmds.connectAttr(rig + '.publishPose', pbd + '.weight', f=True)
            cmds.setAttr(loc1 + '.t', t1[0], t1[1], t1[2])

            t1 = cmds.getAttr(loc2 + '.t')[0]
            cmds.delete(cmds.parentConstraint(loc, loc2, w=True))
            t2 = cmds.getAttr(loc2 + '.t')[0]
            pbd = cmds.createNode('pairBlend')
            cmds.setAttr(pbd + '.inTranslate1', t1[0], t1[1], t1[2])
            cmds.setAttr(pbd + '.inTranslate2', t2[0], t2[1], t2[2])
            cmds.connectAttr(pbd + '.outTranslate', loc2 + '.t', f=True)
            cmds.connectAttr(rig + '.publishPose', pbd + '.weight', f=True)
            cmds.setAttr(loc2 + '.t', t1[0], t1[1], t1[2])
            cmds.delete(cmds.parentConstraint(loc, con, w=True))
            cmds.setAttr(con + '.t', 0, 0, 0)
        else:
            cmds.delete(cmds.pointConstraint(con, loc, w=True,
                                             skip=('x', 'z')))

            t1 = cmds.getAttr(con + '.t')[0]
            cmds.delete(cmds.pointConstraint(loc, con, w=True))
            t2 = cmds.getAttr(con + '.t')[0]
            pbd = cmds.createNode('pairBlend')
            cmds.setAttr(pbd + '.inTranslate1', t1[0], t1[1], t1[2])
            cmds.setAttr(pbd + '.inTranslate2', t2[0], t2[1], t2[2])

            cmds.connectAttr(pbd + '.outTranslate', pub_nul + '.t', f=True)
            cmds.connectAttr(rig + '.publishPose', pbd + '.weight', f=True)
            cmds.setAttr(con + '.t', t1[0], t1[1], t1[2])

    if 'root' in con:

        pos0 = cmds.xform(con, q=True, rp=True, ws=True)
        pos1 = cmds.xform('L_IK_leg_JNT', q=True, rp=True, ws=True)
        pos2 = cmds.xform('L_IK_lowLeg_JNT', q=True, rp=True, ws=True)
        pos3 = cmds.xform('L_IK_foot_JNT', q=True, rp=True, ws=True)
        pos4 = cmds.xform('L_IK_ball_JNT', q=True, rp=True, ws=True)

        dis1 = abs(
            math.sqrt(
                math.pow(pos1[0] - pos1[0], 2) +
                math.pow(pos0[1] - pos1[1], 2) +
                math.pow(pos1[2] - pos1[2], 2)))
        dis2 = abs(
            math.sqrt(
                math.pow(pos1[0] - pos2[0], 2) +
                math.pow(pos1[1] - pos2[1], 2) +
                math.pow(pos1[2] - pos2[2], 2)))
        dis3 = abs(
            math.sqrt(
                math.pow(pos2[0] - pos3[0], 2) +
                math.pow(pos2[1] - pos3[1], 2) +
                math.pow(pos2[2] - pos3[2], 2)))
        dis4 = abs(
            math.sqrt(
                math.pow(pos3[0] - pos3[0], 2) +
                math.pow(pos3[1] - pos4[1], 2) +
                math.pow(pos3[2] - pos3[2], 2)))

        dis5 = abs(
            math.sqrt(
                math.pow(pos1[0] - pos3[0], 2) +
                math.pow(pos1[1] - pos3[1], 2) +
                math.pow(pos1[2] - pos3[2], 2)))

        distance = dis1 + dis2 + dis3 + dis4 * 0.95
        cmds.setAttr(loc + '.t', 0, distance, 0)
        t1 = cmds.getAttr(con + '.t')[0]
        r1 = cmds.getAttr(con + '.r')[0]
        cmds.delete(cmds.parentConstraint(loc, con, w=True))
        t2 = cmds.getAttr(con + '.t')[0]
        r2 = cmds.getAttr(con + '.r')[0]
        pbd = cmds.createNode('pairBlend')
        cmds.setAttr(pbd + '.inTranslate1', t1[0], t1[1], t1[2])
        cmds.setAttr(pbd + '.inTranslate2', t2[0], t2[1], t2[2])
        cmds.setAttr(pbd + '.inRotate1', r1[0], r1[1], r1[2])
        cmds.setAttr(pbd + '.inRotate2', r2[0], r2[1], r2[2])
        cmds.connectAttr(pbd + '.outTranslate', pub_nul + '.t', f=True)
        cmds.connectAttr(pbd + '.outRotate', pub_nul + '.r', f=True)

        cmds.connectAttr(rig + '.publishPose', pbd + '.weight', f=True)
        cmds.setAttr(con + '.t', t1[0], t1[1], t1[2])
        cmds.setAttr(con + '.r', r1[0], r1[1], r1[2])
    if 'Body' in con:
        pos1 = cmds.xform(con, q=True, rp=True, ws=True)
        pos2 = cmds.xform('root_CON', q=True, rp=True, ws=True)
        distance = abs(
            math.sqrt(
                math.pow(pos1[0] - pos2[0], 2) +
                math.pow(pos1[1] - pos2[1], 2) +
                math.pow(pos1[2] - pos2[2], 2)))
        cmds.delete(
            cmds.pointConstraint('root_CON',
                                 loc,
                                 w=True,
                                 offset=(0, distance, 0)))
        t1 = cmds.getAttr(con + '.t')[0]
        r1 = cmds.getAttr(con + '.r')[0]
        cmds.delete(cmds.parentConstraint(loc, con, w=True))
        t2 = cmds.getAttr(con + '.t')[0]
        r2 = cmds.getAttr(con + '.r')[0]
        pbd = cmds.createNode('pairBlend')
        cmds.setAttr(pbd + '.inTranslate1', t1[0], t1[1], t1[2])
        cmds.setAttr(pbd + '.inTranslate2', t2[0], t2[1], t2[2])
        cmds.setAttr(pbd + '.inRotate1', r1[0], r1[1], r1[2])
        cmds.setAttr(pbd + '.inRotate2', r2[0], r2[1], r2[2])
        cmds.connectAttr(pbd + '.outTranslate', pub_nul + '.t', f=True)
        cmds.connectAttr(pbd + '.outRotate', pub_nul + '.r', f=True)

        cmds.connectAttr(rig + '.publishPose', pbd + '.weight', f=True)
        cmds.setAttr(con + '.t', t1[0], t1[1], t1[2])
        cmds.setAttr(con + '.r', r1[0], r1[1], r1[2])

    if 'hip' in con:
        pos1 = cmds.xform(con, q=True, rp=True, ws=True)
        pos2 = cmds.xform('root_CON', q=True, rp=True, ws=True)
        distance = abs(
            math.sqrt(
                math.pow(pos1[0] - pos2[0], 2) +
                math.pow(pos1[1] - pos2[1], 2) +
                math.pow(pos1[2] - pos2[2], 2)))
        cmds.delete(
            cmds.pointConstraint('root_CON',
                                 loc,
                                 w=True,
                                 offset=(0, distance * -1, 0)))
        t1 = cmds.getAttr(con + '.t')[0]
        r1 = cmds.getAttr(con + '.r')[0]
        cmds.delete(cmds.parentConstraint(loc, con, w=True))
        t2 = cmds.getAttr(con + '.t')[0]
        r2 = cmds.getAttr(con + '.r')[0]
        pbd = cmds.createNode('pairBlend')
        cmds.setAttr(pbd + '.inTranslate1', t1[0], t1[1], t1[2])
        cmds.setAttr(pbd + '.inTranslate2', t2[0], t2[1], t2[2])
        cmds.setAttr(pbd + '.inRotate1', r1[0], r1[1], r1[2])
        cmds.setAttr(pbd + '.inRotate2', r2[0], r2[1], r2[2])
        cmds.connectAttr(pbd + '.outTranslate', pub_nul + '.t', f=True)
        cmds.connectAttr(pbd + '.outRotate', pub_nul + '.r', f=True)

        cmds.connectAttr(rig + '.publishPose', pbd + '.weight', f=True)
        cmds.setAttr(con + '.t', t1[0], t1[1], t1[2])
        cmds.setAttr(con + '.r', r1[0], r1[1], r1[2])

    if 'head' in con:
        r1 = cmds.getAttr(con + '.r')[0]
        cmds.delete(cmds.orientConstraint(loc, con, w=True))
        r2 = cmds.getAttr(con + '.r')[0]
        pbd = cmds.createNode('pairBlend')
        cmds.setAttr(pbd + '.inRotate1', r1[0], r1[1], r1[2])
        cmds.setAttr(pbd + '.inRotate2', r2[0], r2[1], r2[2])
        cmds.connectAttr(pbd + '.outRotate', pub_nul + '.r', f=True)

        cmds.connectAttr(rig + '.publishPose', pbd + '.weight', f=True)
        cmds.setAttr(con + '.r', r1[0], r1[1], r1[2])

    if 'FK_leg' in con:

        cmds.delete(cmds.orientConstraint(prefix + '_IK_leg_JNT', loc, w=True))
        r1 = cmds.getAttr(con + '.r')[0]
        cmds.delete(cmds.orientConstraint(loc, con, w=True))
        r2 = cmds.getAttr(con + '.r')[0]

        pbd = cmds.createNode('pairBlend')
        cmds.setAttr(pbd + '.inRotate1', r1[0], r1[1], r1[2])
        cmds.setAttr(pbd + '.inRotate2', r2[0], r2[1], r2[2])
        cmds.connectAttr(pbd + '.outRotate', pub_nul + '.r', f=True)

        cmds.connectAttr(rig + '.publishPose', pbd + '.weight', f=True)
        cmds.setAttr(con + '.r', r1[0], r1[1], r1[2])

    if 'FK_lowLeg' in con:

        cmds.delete(
            cmds.orientConstraint(prefix + '_IK_lowLeg_JNT', loc, w=True))
        r1 = cmds.getAttr(con + '.r')[0]
        cmds.delete(cmds.orientConstraint(loc, con, w=True))
        r2 = cmds.getAttr(con + '.r')[0]
        pbd = cmds.createNode('pairBlend')
        cmds.setAttr(pbd + '.inRotate1', r1[0], r1[1], r1[2])
        cmds.setAttr(pbd + '.inRotate2', r2[0], r2[1], r2[2])
        cmds.connectAttr(pbd + '.outRotate', pub_nul + '.r', f=True)

        cmds.connectAttr(rig + '.publishPose', pbd + '.weight', f=True)
        cmds.setAttr(con + '.r', r1[0], r1[1], r1[2])
    if 'FK_foot' in con:
        cmds.delete(cmds.orientConstraint(prefix + '_IK_foot_JNT', loc,
                                          w=True))
        r1 = cmds.getAttr(con + '.r')[0]
        cmds.delete(cmds.orientConstraint(loc, con, w=True))
        r2 = cmds.getAttr(con + '.r')[0]
        pbd = cmds.createNode('pairBlend')
        cmds.setAttr(pbd + '.inRotate1', r1[0], r1[1], r1[2])
        cmds.setAttr(pbd + '.inRotate2', r2[0], r2[1], r2[2])
        cmds.connectAttr(pbd + '.outRotate', pub_nul + '.r', f=True)

        cmds.connectAttr(rig + '.publishPose', pbd + '.weight', f=True)
        cmds.setAttr(con + '.r', r1[0], r1[1], r1[2])

    if 'FK_upArm' in con:
        if 'L' in prefix:
            cmds.setAttr(loc + '.r', 0, 5, 0)
            r1 = cmds.getAttr(con + '.r')[0]
            cmds.delete(cmds.orientConstraint(loc, con, w=True))
            r2 = cmds.getAttr(con + '.r')[0]
            pbd = cmds.createNode('pairBlend')
            cmds.setAttr(pbd + '.inRotate1', r1[0], r1[1], r1[2])
            cmds.setAttr(pbd + '.inRotate2', r2[0], r2[1], r2[2])
            cmds.connectAttr(pbd + '.outRotate', pub_nul + '.r', f=True)

            cmds.connectAttr(rig + '.publishPose', pbd + '.weight', f=True)
            cmds.setAttr(con + '.r', r1[0], r1[1], r1[2])
        if 'R' in prefix:
            cmds.setAttr(loc + '.r', -180, -5, 0)
            r1 = cmds.getAttr(con + '.r')[0]
            cmds.delete(cmds.orientConstraint(loc, con, w=True))
            r2 = cmds.getAttr(con + '.r')[0]
            pbd = cmds.createNode('pairBlend')
            cmds.setAttr(pbd + '.inRotate1', r1[0], r1[1], r1[2])
            cmds.setAttr(pbd + '.inRotate2', r2[0], r2[1], r2[2])
            cmds.connectAttr(pbd + '.outRotate', pub_nul + '.r', f=True)

            cmds.connectAttr(rig + '.publishPose', pbd + '.weight', f=True)
            cmds.setAttr(con + '.r', r1[0], r1[1], r1[2])

    if 'FK_foreArm' in con:
        if 'L' in prefix:
            cmds.setAttr(loc + '.r', 0, -5, 0)
            r1 = cmds.getAttr(con + '.r')[0]
            cmds.delete(cmds.orientConstraint(loc, con, w=True))
            r2 = cmds.getAttr(con + '.r')[0]
            pbd = cmds.createNode('pairBlend')
            cmds.setAttr(pbd + '.inRotate1', r1[0], r1[1], r1[2])
            cmds.setAttr(pbd + '.inRotate2', r2[0], r2[1], r2[2])
            cmds.connectAttr(pbd + '.outRotate', pub_nul + '.r', f=True)

            cmds.connectAttr(rig + '.publishPose', pbd + '.weight', f=True)
            cmds.setAttr(con + '.r', r1[0], r1[1], r1[2])

        if 'R' in prefix:
            cmds.setAttr(loc + '.r', -180, 5, 0)
            r1 = cmds.getAttr(con + '.r')[0]
            cmds.delete(cmds.orientConstraint(loc, con, w=True))
            r2 = cmds.getAttr(con + '.r')[0]
            pbd = cmds.createNode('pairBlend')
            cmds.setAttr(pbd + '.inRotate1', r1[0], r1[1], r1[2])
            cmds.setAttr(pbd + '.inRotate2', r2[0], r2[1], r2[2])
            cmds.connectAttr(pbd + '.outRotate', pub_nul + '.r', f=True)

            cmds.connectAttr(rig + '.publishPose', pbd + '.weight', f=True)
            cmds.setAttr(con + '.r', r1[0], r1[1], r1[2])

    if 'FK_hand' in con:
        if 'L' in prefix:
            cmds.setAttr(loc + '.r', 0, -5, 0)
            r1 = cmds.getAttr(con + '.r')[0]
            cmds.delete(cmds.orientConstraint(loc, con, w=True))
            r2 = cmds.getAttr(con + '.r')[0]
            pbd = cmds.createNode('pairBlend')
            cmds.setAttr(pbd + '.inRotate1', r1[0], r1[1], r1[2])
            cmds.setAttr(pbd + '.inRotate2', r2[0], r2[1], r2[2])
            cmds.connectAttr(pbd + '.outRotate', pub_nul + '.r', f=True)

            cmds.connectAttr(rig + '.publishPose', pbd + '.weight', f=True)
            cmds.setAttr(con + '.r', r1[0], r1[1], r1[2])

        if 'R' in prefix:
            cmds.setAttr(loc + '.r', -180, 5, 0)
            r1 = cmds.getAttr(con + '.r')[0]
            cmds.delete(cmds.orientConstraint(loc, con, w=True))
            r2 = cmds.getAttr(con + '.r')[0]
            pbd = cmds.createNode('pairBlend')
            cmds.setAttr(pbd + '.inRotate1', r1[0], r1[1], r1[2])
            cmds.setAttr(pbd + '.inRotate2', r2[0], r2[1], r2[2])
            cmds.connectAttr(pbd + '.outRotate', pub_nul + '.r', f=True)

            cmds.connectAttr(rig + '.publishPose', pbd + '.weight', f=True)
            cmds.setAttr(con + '.r', r1[0], r1[1], r1[2])
    if 'IK_hand' in con:
        if 'Vec' in con:
            cmds.delete(
                cmds.parentConstraint(prefix + '_FK_foreArm_CON', loc, w=True))
            pbd = cmds.listConnections(
                con.replace('_CON', 'Space_NUL') + '.t')[0]
            dcm1 = cmds.listConnections(pbd + '.inTranslate1')[0]
            dcm2 = cmds.listConnections(pbd + '.inTranslate2')[0]
            mmx1 = cmds.listConnections(dcm1 + '.inputMatrix')[0]
            mmx2 = cmds.listConnections(dcm2 + '.inputMatrix')[0]
            loc1 = cmds.listConnections(mmx1 + '.matrixIn[0]')[0]
            loc2 = cmds.listConnections(mmx2 + '.matrixIn[0]')[0]
            t1 = cmds.getAttr(loc1 + '.t')[0]
            cmds.delete(cmds.parentConstraint(loc, loc1, w=True))
            cmds.move(0, 0, -2.5, loc1, r=True)
            t2 = cmds.getAttr(loc1 + '.t')[0]
            pbd = cmds.createNode('pairBlend')
            cmds.setAttr(pbd + '.inTranslate1', t1[0], t1[1], t1[2])
            cmds.setAttr(pbd + '.inTranslate2', t2[0], t2[1], t2[2])
            cmds.connectAttr(pbd + '.outTranslate', loc1 + '.t', f=True)
            cmds.connectAttr(rig + '.publishPose', pbd + '.weight', f=True)
            cmds.setAttr(loc1 + '.t', t1[0], t1[1], t1[2])

            t1 = cmds.getAttr(loc2 + '.t')[0]
            cmds.delete(cmds.parentConstraint(loc, loc2, w=True))
            cmds.move(0, 0, -2.5, loc2, r=True)
            t2 = cmds.getAttr(loc2 + '.t')[0]
            pbd = cmds.createNode('pairBlend')
            cmds.setAttr(pbd + '.inTranslate1', t1[0], t1[1], t1[2])
            cmds.setAttr(pbd + '.inTranslate2', t2[0], t2[1], t2[2])
            cmds.connectAttr(pbd + '.outTranslate', loc2 + '.t', f=True)
            cmds.connectAttr(rig + '.publishPose', pbd + '.weight', f=True)
            cmds.setAttr(loc2 + '.t', t1[0], t1[1], t1[2])
            cmds.setAttr(con + '.t', 0, 0, 0)
        else:
            cmds.delete(
                cmds.parentConstraint(prefix + '_FK_hand_CON', loc, w=True))
            t1 = cmds.getAttr(con + '.t')[0]
            cmds.delete(cmds.pointConstraint(loc, con, w=True))
            t2 = cmds.getAttr(con + '.t')[0]
            pbd = cmds.createNode('pairBlend')
            cmds.setAttr(pbd + '.inTranslate1', t1[0], t1[1], t1[2])
            cmds.setAttr(pbd + '.inTranslate2', t2[0], t2[1], t2[2])
            cmds.connectAttr(pbd + '.outTranslate', pub_nul + '.t', f=True)

            cmds.connectAttr(rig + '.publishPose', pbd + '.weight', f=True)
            cmds.setAttr(con + '.t', t1[0], t1[1], t1[2])
            if 'Sub' in con:
                r1 = cmds.getAttr(con + '.r')[0]
                cmds.delete(cmds.orientConstraint(loc, con, w=True))
                r2 = cmds.getAttr(con + '.r')[0]
                pbd = cmds.createNode('pairBlend')
                cmds.setAttr(pbd + '.inRotate1', r1[0], r1[1], r1[2])
                cmds.setAttr(pbd + '.inRotate2', r2[0], r2[1], r2[2])
                cmds.connectAttr(pbd + '.outRotate', pub_nul + '.r', f=True)

                cmds.connectAttr(rig + '.publishPose', pbd + '.weight', f=True)
                cmds.setAttr(con + '.r', r1[0], r1[1], r1[2])

    if 'thumb' in con:
        if 'L' in prefix:
            cmds.setAttr(loc + '.r', 80, -30, -30)
            r1 = cmds.getAttr(con + '.r')[0]
            cmds.delete(cmds.orientConstraint(loc, con, w=True))
            r2 = cmds.getAttr(con + '.r')[0]
            pbd = cmds.createNode('pairBlend')
            cmds.setAttr(pbd + '.inRotate1', r1[0], r1[1], r1[2])
            cmds.setAttr(pbd + '.inRotate2', r2[0], r2[1], r2[2])
            cmds.connectAttr(pbd + '.outRotate', pub_nul + '.r', f=True)

            cmds.connectAttr(rig + '.publishPose', pbd + '.weight', f=True)
            cmds.setAttr(con + '.r', r1[0], r1[1], r1[2])
        if 'R' in prefix:
            cmds.setAttr(loc + '.r', -100, 30, 30)
            r1 = cmds.getAttr(con + '.r')[0]
            cmds.delete(cmds.orientConstraint(loc, con, w=True))
            r2 = cmds.getAttr(con + '.r')[0]
            pbd = cmds.createNode('pairBlend')
            cmds.setAttr(pbd + '.inRotate1', r1[0], r1[1], r1[2])
            cmds.setAttr(pbd + '.inRotate2', r2[0], r2[1], r2[2])
            cmds.connectAttr(pbd + '.outRotate', pub_nul + '.r', f=True)

            cmds.connectAttr(rig + '.publishPose', pbd + '.weight', f=True)
            cmds.setAttr(con + '.r', r1[0], r1[1], r1[2])
    if 'index' in con:
        if 'L' in prefix:
            cmds.setAttr(loc + '.r', 0, -5, 0)
            r1 = cmds.getAttr(con + '.r')[0]
            cmds.delete(cmds.orientConstraint(loc, con, w=True))
            r2 = cmds.getAttr(con + '.r')[0]
            pbd = cmds.createNode('pairBlend')
            cmds.setAttr(pbd + '.inRotate1', r1[0], r1[1], r1[2])
            cmds.setAttr(pbd + '.inRotate2', r2[0], r2[1], r2[2])
            cmds.connectAttr(pbd + '.outRotate', pub_nul + '.r', f=True)

            cmds.connectAttr(rig + '.publishPose', pbd + '.weight', f=True)
            cmds.setAttr(con + '.r', r1[0], r1[1], r1[2])
        if 'R' in prefix:
            cmds.setAttr(loc + '.r', -180, 5, 0)
            r1 = cmds.getAttr(con + '.r')[0]
            cmds.delete(cmds.orientConstraint(loc, con, w=True))
            r2 = cmds.getAttr(con + '.r')[0]
            pbd = cmds.createNode('pairBlend')
            cmds.setAttr(pbd + '.inRotate1', r1[0], r1[1], r1[2])
            cmds.setAttr(pbd + '.inRotate2', r2[0], r2[1], r2[2])
            cmds.connectAttr(pbd + '.outRotate', pub_nul + '.r', f=True)

            cmds.connectAttr(rig + '.publishPose', pbd + '.weight', f=True)
            cmds.setAttr(con + '.r', r1[0], r1[1], r1[2])
    if 'middle' in con:
        if 'L' in prefix:
            cmds.setAttr(loc + '.r', 0, -5, 0)
            r1 = cmds.getAttr(con + '.r')[0]
            cmds.delete(cmds.orientConstraint(loc, con, w=True))
            r2 = cmds.getAttr(con + '.r')[0]
            pbd = cmds.createNode('pairBlend')
            cmds.setAttr(pbd + '.inRotate1', r1[0], r1[1], r1[2])
            cmds.setAttr(pbd + '.inRotate2', r2[0], r2[1], r2[2])
            cmds.connectAttr(pbd + '.outRotate', pub_nul + '.r', f=True)

            cmds.connectAttr(rig + '.publishPose', pbd + '.weight', f=True)
            cmds.setAttr(con + '.r', r1[0], r1[1], r1[2])
        if 'R' in prefix:
            cmds.setAttr(loc + '.r', -180, 5, 0)
            r1 = cmds.getAttr(con + '.r')[0]
            cmds.delete(cmds.orientConstraint(loc, con, w=True))
            r2 = cmds.getAttr(con + '.r')[0]
            pbd = cmds.createNode('pairBlend')
            cmds.setAttr(pbd + '.inRotate1', r1[0], r1[1], r1[2])
            cmds.setAttr(pbd + '.inRotate2', r2[0], r2[1], r2[2])
            cmds.connectAttr(pbd + '.outRotate', pub_nul + '.r', f=True)

            cmds.connectAttr(rig + '.publishPose', pbd + '.weight', f=True)
            cmds.setAttr(con + '.r', r1[0], r1[1], r1[2])
    if 'ring' in con:
        if 'L' in prefix:
            cmds.setAttr(loc + '.r', 0, -5, 0)
            r1 = cmds.getAttr(con + '.r')[0]
            cmds.delete(cmds.orientConstraint(loc, con, w=True))
            r2 = cmds.getAttr(con + '.r')[0]
            pbd = cmds.createNode('pairBlend')
            cmds.setAttr(pbd + '.inRotate1', r1[0], r1[1], r1[2])
            cmds.setAttr(pbd + '.inRotate2', r2[0], r2[1], r2[2])
            cmds.connectAttr(pbd + '.outRotate', pub_nul + '.r', f=True)

            cmds.connectAttr(rig + '.publishPose', pbd + '.weight', f=True)
            cmds.setAttr(con + '.r', r1[0], r1[1], r1[2])
        if 'R' in prefix:
            cmds.setAttr(loc + '.r', -180, 5, 0)
            r1 = cmds.getAttr(con + '.r')[0]
            cmds.delete(cmds.orientConstraint(loc, con, w=True))
            r2 = cmds.getAttr(con + '.r')[0]
            pbd = cmds.createNode('pairBlend')
            cmds.setAttr(pbd + '.inRotate1', r1[0], r1[1], r1[2])
            cmds.setAttr(pbd + '.inRotate2', r2[0], r2[1], r2[2])
            cmds.connectAttr(pbd + '.outRotate', pub_nul + '.r', f=True)

            cmds.connectAttr(rig + '.publishPose', pbd + '.weight', f=True)
            cmds.setAttr(con + '.r', r1[0], r1[1], r1[2])
    if 'pinky' in con:
        if 'L' in prefix:
            cmds.setAttr(loc + '.r', 0, -5, 0)
            r1 = cmds.getAttr(con + '.r')[0]
            cmds.delete(cmds.orientConstraint(loc, con, w=True))
            r2 = cmds.getAttr(con + '.r')[0]
            pbd = cmds.createNode('pairBlend')
            cmds.setAttr(pbd + '.inRotate1', r1[0], r1[1], r1[2])
            cmds.setAttr(pbd + '.inRotate2', r2[0], r2[1], r2[2])
            cmds.connectAttr(pbd + '.outRotate', pub_nul + '.r', f=True)

            cmds.connectAttr(rig + '.publishPose', pbd + '.weight', f=True)
            cmds.setAttr(con + '.r', r1[0], r1[1], r1[2])
        if 'R' in prefix:
            cmds.setAttr(loc + '.r', -180, 5, 0)
            r1 = cmds.getAttr(con + '.r')[0]
            cmds.delete(cmds.orientConstraint(loc, con, w=True))
            r2 = cmds.getAttr(con + '.r')[0]
            pbd = cmds.createNode('pairBlend')
            cmds.setAttr(pbd + '.inRotate1', r1[0], r1[1], r1[2])
            cmds.setAttr(pbd + '.inRotate2', r2[0], r2[1], r2[2])
            cmds.connectAttr(pbd + '.outRotate', pub_nul + '.r', f=True)

            cmds.connectAttr(rig + '.publishPose', pbd + '.weight', f=True)
            cmds.setAttr(con + '.r', r1[0], r1[1], r1[2])
    cmds.setAttr('rig_GRP.publishPose', 0)
    cmds.delete(loc)
    return
import maya.cmds as cmds

sels = cmds.ls(sl=1)

for i in range(len(sels) - 1):
    selP = cmds.listRelatives(sels[i], p=1, f=1)
    if selP:
        cmds.parent(selP[0], sels[i + 1])
    else:
        cmds.parent(sels[i], sels[i + 1])
Ejemplo n.º 47
0
# -*- coding: utf-8 -*-
from maya import cmds

ctrlShape = cmds.createNode('locator')
ctrlTransform = cmds.listRelatives(ctrlShape,p=True,f=True)
if isinstance(ctrlTransform,list):
    ctrlTransform = ctrlTransform[0]
jt = cmds.createNode('joint',n='followJoint')

attrName = 'follow'
if not cmds.attributeQuery(attrName,n=ctrlTransform,ex=True):
    cmds.addAttr(ctrlTransform,ln=attrName,at='double',min=0.0,max=1.0,dv=0.1)
    cmds.setAttr('%s.%s'%(ctrlTransform,attrName),e=True,k=True)

exp  = '{\n\t$tx1 = %s.translateX;\n'%ctrlTransform
exp += '\t$ty1 = %s.translateY;\n'%ctrlTransform
exp += '\t$tz1 = %s.translateZ;\n'%ctrlTransform
exp += '\t$tx2 = %s.translateX;\n'%jt
exp += '\t$ty2 = %s.translateY;\n'%jt
exp += '\t$tz2 = %s.translateZ;\n'%jt
exp += '\t\n\t$f  = %s.follow;\n'%ctrlTransform
exp += '\t$dx = $tx1;\n'
exp += '\t$dy = $ty1;\n'
exp += '\t$dz = $tz1;\n'
exp += '\tif ($f > 0.0)\n\t{\n\t\t$dx = ($tx1-$tx2)*$f;\n'
exp += '\t\t$dy = ($ty1-$ty2)*$f;\n'
exp += '\t\t$dz = ($tz1-$tz2)*$f;\n'
exp += '\t}\n\t%s.translateX += $dx;\n'%jt
exp += '\t%s.translateY += $dy;\n'%jt
exp += '\t%s.translateZ += $dz;\n'%jt
exp += '}'
Ejemplo n.º 48
0
    def etc_set(self):
        ### attribute
        # sup con vis
        for x in range(8):
            cmds.addAttr(TP.AA['PL'][x],
                         ln='sub_con_vis',
                         at='enum',
                         en='off:on:')
            cmds.setAttr(TP.AA['PL'][x] + '.sub_con_vis', e=1, keyable=1)
            cmds.connectAttr(TP.AA['PL'][x] + '.sub_con_vis',
                             TP.AA['CL'][x] + '.visibility')
        # FK / IK switch
        for x in range(2):
            switchCon = controllerShape(TP.conVis['key'][x][0] + '_CON',
                                        'cross', 'yellow')
            switchNul = cmds.group(switchCon,
                                   n=TP.conVis['key'][x][0] + '_NUL')
            cmds.delete(cmds.pointConstraint(TP.conVis['key'][x][1],
                                             switchNul))
            cmds.parent(switchNul, TP.conVis['key'][x][1])
            cmds.move(5, 0, 0, ws=1, r=1)
            cmds.addAttr(switchCon,
                         ln=TP.conVis['attr'][0],
                         at='enum',
                         en='off:on:')
            cmds.setAttr(switchCon + '.' + TP.conVis['attr'][0],
                         e=1,
                         keyable=1)
            cmds.addAttr(switchCon,
                         ln=TP.conVis['attr'][1],
                         at='enum',
                         en='off:on:')
            cmds.setAttr(switchCon + '.' + TP.conVis['attr'][1],
                         e=1,
                         keyable=1)
        for x in range(2):
            top_list = TP.conVis['vis'][x]
            for y in top_list:
                for z in y:
                    if len(y) == 1:
                        cmds.connectAttr(
                            TP.conVis['key'][x][0] + '_CON.' +
                            TP.conVis['attr'][0], z + '.visibility')
                    else:
                        cmds.connectAttr(
                            TP.conVis['key'][x][0] + '_CON.' +
                            TP.conVis['attr'][1], z + '.visibility')
                    cmds.setAttr(TP.conVis['key'][x][0] + '_CON.IK_con_vis', 1)
        ### Parent node
        cmds.group(p='noneTransform_GRP', em=1, n='locator_GRP')
        cmds.parent(TP.noneTrans_list, 'locator_GRP')
        cmds.parent(TP.attach_list, 'attach_GRP')
        cmds.parent(TP.auxillary_list, 'auxillary_GRP')
        cmds.parent(TP.neck_list, 'C_neck_GRP')
        cmds.parent(TP.spine_list, 'C_spine_GRP')
        cmds.parent(TP.L_foreLeg_list, 'L_foreLeg_GRP')
        cmds.parent(TP.R_foreLeg_list, 'R_foreLeg_GRP')
        cmds.parent(TP.L_hindLeg_list, 'L_hindLeg_GRP')
        cmds.parent(TP.R_hindLeg_list, 'R_hindLeg_GRP')
        cmds.parent(TP.tail_list, 'C_tail_GRP')
        cmds.delete(TP.delete_list)
        cmds.select(TP.noneTrans_list, r=1)
        cmds.select('templateJoint_GRP', tgl=1)
        cmds.select(TP.hide_list, tgl=1)
        cmds.select(TP.hide_list2, tgl=1)
        cmds.HideSelectedObjects()

        ### Rotate controler
        self.controlerRotate(TP.rotate_con_list_A, 0, 0, -90)
        self.controlerRotate(TP.rotate_con_list_B, -90, 0, 0)

        ### controler Color
        for x in TP.R_con_list:
            conShapeName = cmds.listRelatives(x, s=1)[0]
            cmds.setAttr(conShapeName + '.overrideEnabled', 1)
            cmds.setAttr(conShapeName + '.overrideColor', 13)
        for x in TP.switch_con_list:
            conShapeName = cmds.listRelatives(x, s=1)[0]
            cmds.setAttr(conShapeName + '.overrideEnabled', 1)
            cmds.setAttr(conShapeName + '.overrideColor', 14)

        ### controler Scale
        for x in TP.scale_con_list:
            scale_value = 2
            CRV_shape_name = cmds.listRelatives(x, s=1)[0]
            CRV_span_num = cmds.getAttr(CRV_shape_name + '.spans')
            cmds.select(x + '.cv[0:%s]' % (CRV_span_num))
            cmds.scale(scale_value, scale_value, scale_value, r=1)

        ### controler Parent
        for x in range(2):
            PL = TP.parent_list['PL'][x]
            for y in TP.parent_list['CL'][x]:
                cmds.parentConstraint(PL, y, mo=1)
        ### hindLeg Parent
        cmds.setAttr('L_rig_hip_JNT.inheritsTransform', 0)
        cmds.setAttr('R_rig_hip_JNT.inheritsTransform', 0)
        itemList = ['.sx', '.sy', '.sz']
        for x in TP.targetjointList:
            for y in itemList:
                cmds.connectAttr('place_CON.globalScale', x + y)
Ejemplo n.º 49
0
def poleVector(pvGuide,
               jnt,
               module,
               extraName,
               limbType,
               moduleName,
               limbIK,
               arrow=False,
               parent=None):
    """ Create a polevector control for an ik handle.
    [Args]:
    pvGuide (string) - The name of the poleVector guide locator
    jnt (string) - The name of the joint to aim at
    module (class) - The limb module class
    extraName (string) - The extra name of the module
    limbType (string) - The name of the limb type
    moduleName (string) - The module name
    limbIK (class) - The ik class
    arrow (bool) - Toggles creating an arrow from the start of the joint chain instead
    """
    col = utils.getColors(module.side)
    cmds.delete(cmds.aimConstraint(jnt, pvGuide))
    if not arrow:
        module.pvCtrl = ctrlFn.ctrl(name='{}{}PV'.format(extraName, limbType),
                                    side=module.side,
                                    guide=pvGuide,
                                    skipNum=True,
                                    deleteGuide=True,
                                    parent=module.ikCtrlGrp.name,
                                    scaleOffset=module.rig.scaleOffset,
                                    rig=module.rig)
        module.pvCtrl.modifyShape(shape='3dArrow',
                                  color=col['col1'],
                                  rotation=(0, 180, 0),
                                  scale=(0.4, 0.4, 0.4))
        module.pvCtrl.lockAttr(['r', 's'])
        module.pvCtrl.constrain(limbIK.hdl, typ='poleVector')
        module.pvCtrl.spaceSwitching(
            [module.rig.globalCtrl.ctrlEnd, module.ikCtrl.ctrlEnd])
        pvCrv = cmds.curve(d=1,
                           p=[
                               cmds.xform(module.pvCtrl.ctrl.name,
                                          q=1,
                                          ws=1,
                                          t=1),
                               cmds.xform(jnt, q=1, ws=1, t=1)
                           ])
        cmds.setAttr('{}.it'.format(pvCrv), 0)
        cmds.parent(pvCrv, module.pvCtrl.offsetGrps[0].name, r=1)
        pvCrv = cmds.rename(
            pvCrv, '{}{}PVLine{}'.format(moduleName, limbType,
                                         suffix['nurbsCrv']))
        cmds.setAttr('{}Shape.overrideEnabled'.format(pvCrv), 1)
        cmds.setAttr('{}Shape.overrideDisplayType'.format(pvCrv), 1)
        cmds.select(cl=1)
        cmds.select('{}.cv[1]'.format(pvCrv))
        pvJntCluHdl = utils.newNode('cluster',
                                    name='{}{}PVJnt'.format(
                                        extraName, limbType),
                                    side=module.side,
                                    parent=jnt)
        cmds.select('{}.cv[0]'.format(pvCrv))
        pvCtrlCluHdl = utils.newNode('cluster',
                                     name='{}{}PVCtrl'.format(
                                         extraName, limbType),
                                     side=module.side,
                                     parent=module.pvCtrl.ctrlEnd)
        utils.setColor(pvJntCluHdl.name, color=None)
        utils.setColor(pvCtrlCluHdl.name, color=None)
    else:
        ikStartJnt = cmds.listRelatives(jnt, p=1)[0]
        module.pvCtrl = ctrlFn.ctrl(name='{}{}PV'.format(extraName, limbType),
                                    side=module.side,
                                    guide=ikStartJnt,
                                    skipNum=True,
                                    parent=module.ikCtrlGrp.name,
                                    scaleOffset=module.rig.scaleOffset,
                                    rig=module.rig)
        module.pvCtrl.modifyShape(shape='pvArrow',
                                  color=col['col2'],
                                  scale=(0.4, 0.4, 0.4))
        module.pvCtrl.lockAttr(['t', 's', 'rx'])
        cmds.delete(cmds.aimConstraint(pvGuide, module.pvCtrl.rootGrp.name))
        if parent:
            cmds.parentConstraint(parent, module.pvCtrl.rootGrp.name, mo=1)
        cmds.parent(pvGuide, module.pvCtrl.ctrlEnd)
        cmds.poleVectorConstraint(pvGuide, limbIK.hdl)
        utils.setShapeColor(pvGuide, color=None)
Ejemplo n.º 50
0
def groundConstraint(mesh, obj):
    name = mesh + '_' + obj

    # 1 create a CPOM node and connect input
    # ############################################################
    # create input position locator and closest point locator:
    pos = cmd.xform(obj, q=True, translation=True, ws=True)
    colLoc = cmd.spaceLocator(n=name + '_collisionLoc')[0]
    cmd.xform(colLoc, translation=pos, ws=True)
    ctrlLoc = cmd.spaceLocator(n=name + '_ctrlLoc', p=pos)[0]
    cmd.xform(ctrlLoc, cp=True)

    cmd.parent(colLoc, ctrlLoc)

    # closest point on mesh node:
    CPOM = cmd.shadingNode('closestPointOnMesh',
                           asUtility=True,
                           n=name + '_CPOM')

    # connect ground mesh to CPOM
    meshShape = cmd.listRelatives(mesh, shapes=True)[0]
    cmd.connectAttr(meshShape + '.worldMesh[0]', CPOM + '.inMesh')
    cmd.connectAttr(meshShape + '.worldMatrix[0]', CPOM + '.inputMatrix')

    # connect ctrl locator and collision locator to CPOM
    # decompose ctrlLoc
    if cmd.pluginInfo('decomposeMatrix', q=True, loaded=True) == False:
        cmd.loadPlugin('decomposeMatrix')

    colLocDM = cmd.shadingNode('decomposeMatrix',
                               asUtility=True,
                               n=colLoc + '_decomposeMatrix')
    cmd.connectAttr(colLoc + '.worldMatrix', colLocDM + '.inputMatrix')
    cmd.connectAttr(colLocDM + '.outputTranslate', CPOM + '.inPosition')
    # ############################################################

    # 2, fix rotation: make obj rotates on surface: normal constraint
    #############################################################
    # create vector product nodes:
    ax_x = cmd.shadingNode('vectorProduct', asUtility=True, n=name + 'ax_x')
    ax_z = cmd.shadingNode('vectorProduct', asUtility=True, n=name + 'ax_z')
    for node in [ax_x, ax_z]:
        cmd.setAttr(node + '.operation', 2)  #cross product
        cmd.setAttr(node + '.normalizeOutput', 1)  #normalize output

    # normal from CPOM --> vector product nodes
    cmd.setAttr(ax_z + '.input1X', 1)
    cmd.connectAttr(CPOM + '.result.normal', ax_z + '.input2')

    cmd.connectAttr(CPOM + '.result.normal', ax_x + '.input1')
    cmd.connectAttr(ax_z + '.output', ax_x + '.input2')

    # create a 4X4 matrix
    fourbyfour = cmd.shadingNode('fourByFourMatrix',
                                 asUtility=True,
                                 n=name + '_fourByFourMatrix')

    # connect translate/rotate output to matrix
    cmd.connectAttr(ax_x + '.outputX', fourbyfour + '.in00')
    cmd.connectAttr(ax_x + '.outputY', fourbyfour + '.in01')
    cmd.connectAttr(ax_x + '.outputZ', fourbyfour + '.in02')

    cmd.connectAttr(CPOM + '.result.normalX', fourbyfour + '.in10')
    cmd.connectAttr(CPOM + '.result.normalY', fourbyfour + '.in11')
    cmd.connectAttr(CPOM + '.result.normalZ', fourbyfour + '.in12')

    cmd.connectAttr(ax_z + '.outputX', fourbyfour + '.in20')
    cmd.connectAttr(ax_z + '.outputY', fourbyfour + '.in21')
    cmd.connectAttr(ax_z + '.outputZ', fourbyfour + '.in22')

    cmd.connectAttr(CPOM + '.result.positionX', fourbyfour + '.in30')
    cmd.connectAttr(CPOM + '.result.positionY', fourbyfour + '.in31')
    cmd.connectAttr(CPOM + '.result.positionZ', fourbyfour + '.in32')
    #############################################################

    # 3, detect if collision is happening
    #############################################################
    # create the difference matrix
    diffMatrix = cmd.shadingNode('multMatrix',
                                 asUtility=True,
                                 n=name + '_diffMatrix')
    # connect output from 4X4 and colLoc inverse worldMatrix to diffMatrix
    cmd.connectAttr(fourbyfour + '.output', diffMatrix + '.matrixIn[0]')
    cmd.connectAttr(colLoc + '.worldInverseMatrix[0]',
                    diffMatrix + '.matrixIn[1]')

    # decompose diffMatrix and create a condition node
    diffMatrixDM = cmd.shadingNode('decomposeMatrix',
                                   asUtility=True,
                                   n=diffMatrix + '_decomposeMatrix')
    cmd.connectAttr(diffMatrix + '.matrixSum', diffMatrixDM + '.inputMatrix')

    # condition: if diffMatrixDM.ty<0, then collision not happen (true=happe, false = not happen)
    condition = cmd.shadingNode('condition',
                                asUtility=True,
                                n=name + '_condition')
    cmd.setAttr(condition + '.operation', 2)  #greater than
    cmd.setAttr(condition + '.colorIfTrueR', 1)
    cmd.setAttr(condition + '.colorIfFalseR', 0)

    cmd.connectAttr(diffMatrixDM + '.outputTranslate.outputTranslateY',
                    condition + '.firstTerm')

    # blending: collision happen----> collide weight =1, collision not happen---> collide weight =0:
    blend = cmd.shadingNode('pairBlend', asUtility=True, n=name + '_blend')
    cmd.connectAttr(condition + '.outColorR', blend + '.weight')

    # blend ctrl loc and collision loc:
    # decompose ctrlLoc
    ctrlLocDM = cmd.shadingNode('decomposeMatrix',
                                asUtility=True,
                                n=ctrlLoc + '_decomposeMatrix')
    cmd.connectAttr(ctrlLoc + '.worldMatrix', ctrlLocDM + '.inputMatrix')

    # decompose 4X4
    fourbyfourDM = cmd.shadingNode('decomposeMatrix',
                                   asUtility=True,
                                   n=fourbyfour + '_decomposeMatrix')
    cmd.connectAttr(fourbyfour + '.output', fourbyfourDM + '.inputMatrix')

    # blend:
    cmd.connectAttr(ctrlLocDM + '.outputTranslate', blend + '.inTranslate1')
    cmd.connectAttr(ctrlLocDM + '.outputRotate', blend + '.inRotate1')
    cmd.connectAttr(fourbyfourDM + '.outputTranslate', blend + '.inTranslate2')
    cmd.connectAttr(fourbyfourDM + '.outputRotate', blend + '.inRotate2')
    ########################################################################

    # 5. offset obj position(contact)
    ########################################################################
    offsetMatrix = cmd.shadingNode('multMatrix',
                                   asUtility=True,
                                   n=name + 'offsetMatrix')
    cmd.connectAttr(diffMatrix + '.matrixSum', offsetMatrix + '.matrixIn[0]')
    cmd.connectAttr(ctrlLoc + '.worldMatrix[0]', offsetMatrix + '.matrixIn[1]')

    cmd.connectAttr(offsetMatrix + '.matrixSum',
                    fourbyfourDM + '.inputMatrix',
                    force=True)

    # 5. connect result to obj
    ########################################################################
    objGrp = cmd.group(obj, n=obj + '_collision_Grp', r=True)
    cmd.connectAttr(blend + '.outTranslate', objGrp + '.translate')
    cmd.connectAttr(blend + '.outRotate', objGrp + '.rotate')

    return (ctrlLoc, colLoc, objGrp)
Ejemplo n.º 51
0
def bend_chain(crv, controller, bones_nbr):
    jnt_nbr = bones_nbr + 1
    # get shape
    crv_shape = mc.listRelatives(crv, c=True, s=True)[0]

    # calculation of the number of cv
    crv_degree = mc.getAttr(crv_shape + '.degree')
    crv_span = mc.getAttr(crv_shape + '.spans')

    cv_nbr = crv_degree + crv_span

    # place curve pivot on first cv
    crv_info = mc.createNode('curveInfo', n=crv + '_curveInfo')
    mc.connectAttr(crv_shape + '.worldSpace', crv_info + '.inputCurve')

    cv_tx = mc.getAttr(crv_info + '.controlPoints[0].xValue')
    cv_ty = mc.getAttr(crv_info + '.controlPoints[0].yValue')
    cv_tz = mc.getAttr(crv_info + '.controlPoints[0].zValue')
    mc.xform(crv, piv=(cv_tx, cv_ty, cv_tz), ws=True)

    # Stretch creation
    mult = mc.shadingNode('multiplyDivide', asUtility=True,
                          name='multiplyDivide_STRETCH_' + crv)
    mc.connectAttr('%s.arcLength' % crv_info, '%s.input1X' % mult)
    crv_length = mc.getAttr(crv_info + '.arcLength')
    mc.setAttr(mult + '.input2X', crv_length)
    mc.setAttr(mult + '.operation', 2)

    # Joint chain creation
    jnt_length = crv_length / bones_nbr
    first_jnt = mc.joint(p=(cv_tx, cv_ty, cv_tz), name='SK_' + crv + '_0')

    for i in range(1, jnt_nbr):
        i = str(i)
        current_jnt = mc.joint(p=(jnt_length, 0, 0), r=True,
                               name='SK_' + crv + '_' + i)
        mc.connectAttr(mult + '.outputX',
                       current_jnt + '.scaleX')

    # ikSpline creation
    ik = 'IKSPLINE_' + crv
    mc.ikHandle(curve=crv, ee='SK_' + crv + '_' + str(bones_nbr),
                sol='ikSplineSolver', sj=first_jnt,
                name=ik, ccv=0)
    jnt_rotation = mc.xform(first_jnt, q=True, ro=True)

    # Orig joint
    orig.orig([first_jnt], 'orig')

    # offset de l'ik
    orig.orig([ik], 'orig')

    for j in range(0, cv_nbr):
        # Creation des clusters :)

        cls_nbr = str(j)
        cv = (crv + '.cv[' + cls_nbr + ']')

        mc.select(cv)
        cluster = mc.cluster()
        mc.select(deselect=True)

        # Recuperation de la position des clusters
        cls_pos_x = mc.getAttr('%s.controlPoints[%s].xValue'
                               % (crv_info, cls_nbr))
        cls_pos_y = mc.getAttr('%s.controlPoints[%s].yValue'
                               % (crv_info, cls_nbr))
        cls_pos_z = mc.getAttr('%s.controlPoints[%s].zValue'
                               % (crv_info, cls_nbr))

        # Controllers creation
        ctrl = mc.duplicate(controller, name='%s_%s_ctrl' % (crv, cls_nbr))
        ctrl = mc.rename(ctrl, '%s_%s_ctrl' % (crv, cls_nbr))
        mc.xform(ctrl, t=(cls_pos_x, cls_pos_y, cls_pos_z), ws=True)
        mc.xform(ctrl, ro=jnt_rotation)

        # Controllers orig
        orig.orig([ctrl], 'orig')

        # Cluster hierarchy

        mc.parent(cluster, ctrl)

    mc.select('%s_*_ctrl_orig' % crv)
    mc.group(name='%s_ctrl_grp' % crv)
    mc.select(deselect=True)
Ejemplo n.º 52
0
def createLayeredSplineIK(jnts,
                          name,
                          rig=None,
                          side='C',
                          extraName='',
                          parent=None,
                          dyn=False):
    """ Create a layered spline IK.
    [Args]:
    jnts (list)(string) - The names of the joints to create the IK with
    name (string) - The name of the IK
    rig (class) - The rig class to use
    side (string) - The side of the IK
    extraName (string) - The extra name of the IK
    parent (string) - The name of the parent
    dyn (bool) - Toggles dynamics on the spline IK
    """
    moduleName = utils.setupBodyPartName(extraName, side)
    col = utils.getColors(side)
    ## create base layer jnts
    tmpCrv = utils.createCrvFromObjs(jnts, crvName='tmpCrv')
    ctrlGrp = utils.newNode('group',
                            name='{}{}Ctrls'.format(extraName, name),
                            side=side,
                            parent=rig.ctrlsGrp.name if rig else None,
                            skipNum=True)
    mechGrp = utils.newNode('group',
                            name='{}{}Mech'.format(extraName, name),
                            side=side,
                            parent=rig.mechGrp.name if rig else None,
                            skipNum=True)
    baseJnts = utils.createJntsFromCrv(tmpCrv,
                                       numOfJnts=4,
                                       side=side,
                                       name='{}{}_baseLayer'.format(
                                           extraName, name))
    if rig:
        cmds.parent(jnts[0], rig.skelGrp.name)
    cmds.parent(baseJnts[0], mechGrp.name)
    ## parent locs to base jnts
    ## base layer ctrls
    baseLayerLocs = []
    baseLayerCtrls = []
    baseCtrlParent = ctrlGrp.name
    for each in baseJnts:
        baseLoc = utils.newNode('locator',
                                name='{}{}_baseLayer'.format(extraName, name),
                                side=side)
        baseLoc.parent(each, relative=True)
        utils.setShapeColor(baseLoc.name, color=None)
        baseLayerLocs.append(baseLoc)
        baseCtrl = ctrlFn.ctrl(name='{}{}_baseLayer'.format(extraName, name),
                               guide=each,
                               side=side,
                               parent=baseCtrlParent,
                               rig=rig,
                               scaleOffset=rig.scaleOffset)
        baseCtrl.constrain(each)
        baseCtrl.modifyShape(shape='cube', color=col['col2'], scale=(1, 1, 1))
        baseLayerCtrls.append(baseCtrl)
        baseCtrlParent = baseCtrl.ctrlEnd
    baseSpaces = [rig.globalCtrl.ctrlEnd]
    if parent:
        baseSpaces.insert(0, parent)
    baseLayerCtrls[0].spaceSwitching(parents=baseSpaces,
                                     niceNames=None,
                                     constraint='parent',
                                     dv=0)

    ## mid layer crv FROM BASE JNTS
    midCrv = utils.createCrvFromObjs(baseJnts,
                                     crvName='{}_midLayer'.format(name),
                                     side=side,
                                     extraName=extraName)
    ## create mid jnts
    midJnts = utils.createJntsFromCrv(tmpCrv,
                                      numOfJnts=7,
                                      side=side,
                                      name='{}{}_midLayer'.format(
                                          extraName, name))
    cmds.parent(midJnts[0], mechGrp.name)
    cmds.delete(tmpCrv)
    ## parent locs to mid jnts
    ## create mid ctrls - parent constrain root grp to mid jnts
    midLayerLocs = []
    midLayerCtrls = []
    midCtrlParent = ctrlGrp.name
    for each in midJnts:
        midCtrl = ctrlFn.ctrl(name='{}{}_midLayer'.format(extraName, name),
                              guide=each,
                              side=side,
                              parent=midCtrlParent,
                              rig=rig,
                              scaleOffset=rig.scaleOffset)
        cmds.parentConstraint(each, midCtrl.rootGrp.name, mo=1)
        midCtrl.modifyShape(shape='sphere',
                            color=col['col1'],
                            scale=(0.4, 0.4, 0.4))
        midLayerCtrls.append(midCtrl)
        midLoc = utils.newNode('locator',
                               name='{}{}_midLayer'.format(extraName, name),
                               side=side)
        utils.setShapeColor(midLoc.name, color=None)
        midLoc.parent(midCtrl.ctrlEnd, relative=True)
        midLayerLocs.append(midLoc)
        midCtrlParent = midCtrl.ctrlEnd
    ## ik spline mid crv to mid jnts
    midIKSpline = ikFn.ik(sj=midJnts[0],
                          ej=midJnts[-1],
                          name='{}{}_midLayerIK'.format(extraName, name),
                          side=side)
    midIKSpline.createSplineIK(crv=midCrv, parent=mechGrp.name)
    midIKSpline.addStretch(operation='both',
                           mode='length',
                           globalScaleAttr=rig.scaleAttr if rig else None)
    midIKSpline.advancedTwist(baseLayerCtrls[0].ctrlEnd,
                              endObj=baseLayerCtrls[-1].ctrlEnd,
                              wuType=4)
    ## connect mid crv cvs to base locators
    for i, each in enumerate(baseLayerLocs):
        cmds.connectAttr('{}.wp'.format(each.name),
                         '{}Shape.cv[{}]'.format(midCrv, i))
    ## create skin crv FROM MID JNTS
    skinCrvIn = utils.createCrvFromObjs(midJnts,
                                        side=side,
                                        extraName=extraName,
                                        crvName='{}_skinLayer{}'.format(
                                            name, 'DynIn' if dyn else ''))
    skinCrvInShape = cmds.listRelatives(skinCrvIn, s=1)[0]
    if dyn:
        dynMechGrp = utils.newNode('group',
                                   name='{}Dynamics'.format(name),
                                   side=side,
                                   parent=mechGrp.name,
                                   skipNum=True)
        cmds.parent(skinCrvIn, dynMechGrp.name)
        skinCrv = utils.createCrvFromObjs(midJnts,
                                          crvName='{}_skinLayer'.format(name),
                                          side=side,
                                          extraName=extraName)
        ## create output curve
        dynOutCrv = utils.createCrvFromObjs(
            midJnts,
            side=side,
            extraName=extraName,
            crvName='{}_skinLayerDynOut'.format(name))
        cmds.parent(dynOutCrv, dynMechGrp.name)
        dynOutCrvShape = cmds.listRelatives(dynOutCrv, s=1)[0]
        ## create follicle
        fol = utils.newNode('follicle',
                            name='{}_skinLayerDyn'.format(name),
                            side=side,
                            parent=dynMechGrp.name)
        cmds.setAttr('{}.restPose'.format(fol.name), 1)
        cmds.setAttr('{}.startDirection'.format(fol.name), 1)
        cmds.setAttr('{}.degree'.format(fol.name), 3)
        ## create hair system
        hs = utils.newNode('hairSystem',
                           name='{}_skinLayerDyn'.format(name),
                           side=side,
                           parent=dynMechGrp.name)
        ## create nucleus
        nuc = utils.newNode('nucleus',
                            name='{}_skinLayerDyn'.format(name),
                            side=side,
                            parent=dynMechGrp.name)
        ## connect shit
        fol.connect('startPosition',
                    '{}.local'.format(skinCrvInShape),
                    mode='to')
        fol.connect('startPositionMatrix',
                    '{}.wm'.format(skinCrvIn),
                    mode='to')
        fol.connect('currentPosition',
                    '{}.outputHair[0]'.format(hs.name),
                    mode='to')
        fol.connect('outCurve',
                    '{}.create'.format(dynOutCrvShape),
                    mode='from')
        fol.connect('outHair', '{}.inputHair[0]'.format(hs.name), mode='from')
        hs.connect('currentState',
                   '{}.inputActive[0]'.format(nuc.name),
                   mode='from')
        hs.connect('startState',
                   '{}.inputActiveStart[0]'.format(nuc.name),
                   mode='from')
        hs.connect('nextState',
                   '{}.outputObjects[0]'.format(nuc.name),
                   mode='to')
        hs.connect('startFrame', '{}.startFrame'.format(nuc.name), mode='to')
        hs.connect('currentTime', 'time1.outTime', mode='to')
        nuc.connect('currentTime', 'time1.outTime', mode='to')
        ## blend shape curves
        blendNode = cmds.blendShape(skinCrvIn,
                                    dynOutCrv,
                                    skinCrv,
                                    n='{}_{}Dynamics{}'.format(
                                        side, name, suffix['blend']))[0]
        ## connect blend shape to attribute
        ##- create dyn control
        dynCtrl = ctrlFn.ctrl(name='{}Settings'.format(name),
                              guide='{}_{}SettingsGuide{}'.format(
                                  side, name, suffix['locator']),
                              rig=rig,
                              deleteGuide=True,
                              side=side,
                              skipNum=True,
                              parent=rig.settingCtrlsGrp.name)
        dynCtrl.makeSettingCtrl(ikfk=False, parent=jnts[0])
        dynCtrl.addAttr('dynSwitch',
                        nn='Dynamics Switch',
                        minVal=0,
                        maxVal=1,
                        defaultVal=1)
        dynSwitchRev = utils.newNode('reverse',
                                     name='{}DynamicsSwitch'.format(name),
                                     side=side)
        cmds.connectAttr(dynCtrl.ctrl.dynSwitch,
                         '{}.{}'.format(blendNode, dynOutCrv))
        dynSwitchRev.connect('inputX', dynCtrl.ctrl.dynSwitch, mode='to')
        dynSwitchRev.connect('outputX',
                             '{}.{}'.format(blendNode, skinCrvIn),
                             mode='from')

    else:
        skinCrv = skinCrvIn

    ## ik spline skin crv to skin jnts
    skinIKSpline = ikFn.ik(sj=jnts[0],
                           ej=jnts[-1],
                           name='{}{}_skinLayerIK'.format(extraName, name),
                           side=side)
    skinIKSpline.createSplineIK(crv=skinCrv, parent=mechGrp.name)
    skinIKSpline.addStretch(operation='both',
                            mode='length',
                            globalScaleAttr=rig.scaleAttr if rig else None)
    skinIKSpline.advancedTwist(midLayerCtrls[0].ctrlEnd,
                               endObj=midLayerCtrls[-1].ctrlEnd,
                               wuType=4)
    ## connect skin crv cvs to mid locators
    for i, each in enumerate(midLayerLocs):
        cmds.connectAttr('{}.wp'.format(each.name),
                         '{}Shape.cv[{}]'.format(skinCrvIn, i))
Ejemplo n.º 53
0
def __makeTransform(dagNode):
    if cmds.objectType(dagNode, isAType='transform'):
        return dagNode
    xform = cmds.listRelatives(dagNode, path=True, parent=True)[0]
    return xform
Ejemplo n.º 54
0
    def create(self, geo, worldSpace=False):
        meshes = cmds.listRelatives(geo, f=1, ni=1, s=1, type='mesh')
        if not meshes:
            cmds.warning('No Geometry Selected. Skipping.')
            return False
        nucleus = mel.eval('getActiveNucleusNode(false, true);')
        self.clothNodes = []
        for mesh in meshes:
            conns = cmds.listConnections(mesh, sh=1, type='nBase')
            if not conns:

                meshTforms = mel.eval('listTransforms("{}")'.format(mesh))
                tform = meshTforms[0]

                nCloth = utils.newNode('nCloth',
                                       name=self.name,
                                       side=self.side)

                mel.eval('hideParticleAttrs("{}")'.format(nCloth.name))
                self.clothNodes.append(nCloth)

                nCloth.connect('currentTime', 'time1.outTime', mode='to')
                wrapPlugs = cmds.listConnections('{}.worldMesh'.format(mesh),
                                                 d=1,
                                                 p=1,
                                                 sh=1,
                                                 type='wrap')
                nCloth.connect('inputMesh',
                               '{}.worldMesh'.format(mesh),
                               mode='to')

                oldMeshName = mesh.rsplit('|')[-1]
                # newMeshName = '{}_{}InputMesh_{}'.format(mesh.split('_', 1)[0], self.name,
                #                                           mesh.rsplit('_', 1)[-1])
                newMeshName = utils.setupName('{}InputMesh'.format(self.name),
                                              suffix='_{}'.format(
                                                  oldMeshName.rsplit('_')[-1]),
                                              side=oldMeshName.split('_')[0])
                print newMeshName
                mesh = cmds.rename(mesh, newMeshName)

                outMesh = utils.newNode('mesh',
                                        name='{}OutputMesh'.format(self.name),
                                        side=self.side)

                outMesh.renameNode(oldMeshName)

                if not worldSpace:
                    cmds.parent(outMesh.name, tform, s=1, r=1)
                    cmds.delete(outMesh.transform)
                    nCloth.setAttr('localSpaceOutput', True)
                shadCons = cmds.listConnections(
                    '{}.instObjGroups[0]'.format(mesh),
                    d=1,
                    sh=1,
                    type='shadingEngine')
                # if len(shadCons) > 0:
                if shadCons:
                    cmds.hyperShade(outMesh.name, assign=shadCons[0])
                else:
                    cmds.sets(outMesh.name, add='initialShadingGroup')

                outMesh.setAttr('quadSplit', 0)
                nCloth.connect('outputMesh',
                               '{}.inMesh'.format(outMesh.name),
                               mode='from')

                mel.eval('addActiveToNSystem("{}", "{}")'.format(
                    nCloth.name, nucleus))
                nCloth.connect('startFrame',
                               '{}.startFrame'.format(nucleus),
                               mode='to')
                cmds.setAttr('{}.intermediateObject'.format(mesh), 1)
                clothTforms = mel.eval('listTransforms "{}"'.format(
                    nCloth.name))
                cmds.setAttr('{}.translate'.format(clothTforms[0]), l=True)
                cmds.setAttr('{}.rotate'.format(clothTforms[0]), l=True)
                cmds.setAttr('{}.scale'.format(clothTforms[0]), l=True)

                ## todo: add shit about thickness for collisions

                if wrapPlugs:
                    mel.eval(
                        'if( !`exists transferWrapConns` ){ source "removeNCloth.mel"; } transferWrapConns( "'
                        + wrapPlugs + '", "' + outMesh.name + '" );')
        return True
Ejemplo n.º 55
0
def SK_fingerEditPose(obj,attribute):
    selObj = obj
    attrName = attribute
    ctrlAttr = rig.connectionInfo(selObj+'.ctrl',sfd = True)
    midJnt = ctrlAttr.split('.')[0]
    rootJnt = rig.listRelatives(midJnt,p = True)[0]
    ikCon = rig.connectionInfo(rootJnt+'.scale',sfd = True).split('.')[0]
    controlName = ikCon.split('_')[0]+'_Switch'
    
    if not rig.objExists(controlName):
        scaleVal = rig.getAttr(ikCon+'.scaleVal')
        curveName = rig.rename(SK_b29(4),controlName)
        rig.setAttr(curveName+'.scale',0.1*scaleVal,0.1*scaleVal,0.1*scaleVal)
        rig.setAttr(curveName+'.rz',90)
        SK_freezeObj(curveName)
        SK_snapToObj(midJnt,curveName)
        rig.parent(curveName,midJnt)
        SK_hideLockAll(curveName)    
    
    if not (rig.attributeQuery(attrName,node = controlName,ex = True)):
        rig.addAttr(controlName,ln = attrName,at = 'float',minValue = -1,maxValue = 1,dv = 1,k = True)
    ctrls = [ctrl.split('.')[0] for ctrl in rig.connectionInfo(midJnt+'.ctrl',dfs = True)]
    ctrls = [ctrl for ctrl in ctrls if not ('_End' in ctrl)]
    for ctrl in ctrls:
        attrs = rig.listAttr(ctrl,k = True)
        for attr in attrs:
            attrV = rig.getAttr(ctrl+'.'+attr)
            if(math.fabs(attrV) > 0.01):
                ctrlJnt = rig.listRelatives(ctrl,p = True)[0]
                attrJnt = attrName+'_'+attr    
                
                if(rig.attributeQuery(attrJnt,node = ctrlJnt,ex = True)):
                    rig.setAttr(ctrlJnt+'.'+attrJnt,attrV)

                
                else:    
  
                    rig.addAttr(ctrlJnt,ln = attrJnt,at = 'float',dv = attrV)
                    
                    lsConnectJnt = rig.listConnections(ctrlJnt+'.'+attr,s = True,d = False,scn = True,p = True)
                    if lsConnectJnt:
                        lsConnectJnt = lsConnectJnt[0]
                        if 'plusMinusAverage' == rig.nodeType(lsConnectJnt.split('.')[0]):
                            existsMPA = lsConnectJnt.split('.')[0]
                            numMPA = len(rig.getAttr(existsMPA+'.input1D[*]'))
                            existsMD = SK_MDNode(controlName)
                            if existsMD:
                                inMD,inMD1,outMD = existsMD
                                rig.connectAttr(ctrlJnt+'.'+attrJnt,inMD)                
                                rig.connectAttr(controlName+'.'+attrName,inMD1)
                                rig.connectAttr(outMD,existsMPA+'.input1D['+str(numMPA)+']')
                            else:
                                jntMD = rig.createNode('multiplyDivide',n = ctrl+'_MD',ss = True)
                                rig.connectAttr(ctrlJnt+'.'+attrJnt,jntMD+'.input1X')                
                                rig.connectAttr(controlName+'.'+attrName,jntMD+'.input2X')
                                rig.connectAttr(jntMD+'.outputX',existsMPA+'.input1D['+str(numMPA)+']')
                        else:
                            existsMD = SK_MDNode(controlName)
                            jntMPA = rig.createNode('plusMinusAverage',n = ctrl+'_MPA',ss = True)
                            
                            if existsMD:
                                inMD,inMD1,outMD = existsMD
                                rig.connectAttr(ctrlJnt+'.'+attrJnt,inMD)                
                                rig.connectAttr(controlName+'.'+attrName,inMD1)
                                rig.connectAttr(outMD,jntMPA+'.input1D[1]')
                            else:
                                jntMD = rig.createNode('multiplyDivide',n = ctrl+'_MD',ss = True)
                                rig.connectAttr(ctrlJnt+'.'+attrJnt,jntMD+'.input1X')                
                                rig.connectAttr(controlName+'.'+attrName,jntMD+'.input2X')
                                rig.connectAttr(jntMD+'.outputX',jntMPA+'.input1D[1]')
                            rig.connectAttr(lsConnectJnt,jntMPA+'.input1D[0]')                    
                            rig.connectAttr(jntMPA+'.output1D',ctrlJnt+'.'+attr,f = True)
                                                
                    else:
                        existsMD = SK_MDNode(controlName)
                        jntMPA = rig.createNode('plusMinusAverage',n = ctrl+'_MPA',ss = True)
                        
                        if existsMD:
                            inMD,inMD1,outMD = existsMD
                            rig.connectAttr(ctrlJnt+'.'+attrJnt,inMD)                
                            rig.connectAttr(controlName+'.'+attrName,inMD1)
                            rig.connectAttr(outMD,jntMPA+'.input1D[1]')
                        else:
                            jntMD = rig.createNode('multiplyDivide',n = ctrl+'_MD',ss = True)
                            rig.connectAttr(ctrlJnt+'.'+attrJnt,jntMD+'.input1X')                
                            rig.connectAttr(controlName+'.'+attrName,jntMD+'.input2X')
                            rig.connectAttr(jntMD+'.outputX',jntMPA+'.input1D[1]')
        #                rig.connectAttr(lsConnectJnt,jntMPA+'.input1D[0]')                    
                    if(rig.getAttr(ctrlJnt+'.'+attr,l = True)):
                        rig.setAttr(ctrlJnt+'.'+attr,l = False)                    
                        rig.connectAttr(jntMPA+'.output1D',ctrlJnt+'.'+attr,f = True)
                        
                    
                    
    for ctrl in ctrls:
        attrs = rig.listAttr(ctrl,k = True)
        for attr in attrs:
            attrV = rig.getAttr(ctrl+'.'+attr)
            if(math.fabs(attrV) > 0.01):
                rig.setAttr(ctrl+'.'+attr,0)
Ejemplo n.º 56
0
mirrorX['mode'] = 'mirror'
mirrorX['pivot'] = [0, 0, 0, 0, 0, 0, 1, 1, 1]
mirrorX['namePrefix'] = ['r', 'l']
mirrorX['nameReplace'] = ['', '']
mirrorX['nameIncr'] = ''
mirrorX['nameAdd'] = []
mirrorX['noneMirrorAxe'] = -1

#BUILD
for lod in ['Hi', 'Low']:
    modelClass_duplicateAndBuild(('head' + lod + '_GRP'), [mirrorX])

#REORDER HIERARCHY

#CLEAN HIERARCHY
grps = mc.listRelatives("ALL_GRP", c=True)
for i in range(0, len(grps)):
    childrens = mc.listRelatives(grps[i], c=True)
    if (childrens == None) or (len(childrens) == 0): mc.delete(grps[i])

#REORDER HIERARCHY
mc.createNode("transform", n="all_GRP")
mc.createNode("transform", n="hi_GRP", p="all_GRP")
mc.createNode("transform", n="low_GRP", p="all_GRP")
mc.parent(mc.ls("ALL_GRP|*Low_GRP"), "low_GRP")
mc.parent(mc.ls("ALL_GRP|*_GRP"), "hi_GRP")
mc.delete("ALL_GRP")

#___________________________________________________________________________SAVE TO MODEL
rwi.mayaScene_save(
    'D:/mcantat_BDD/projects/flyAway/assets/howie/maya/scenes/howie_model.ma')
Ejemplo n.º 57
0
    def colorControl(self, Nameof, Type, colorname):
        sels = cmds.ls(sl=True)
        SizeofSelection = len(sels)

        if SizeofSelection < 1:
            Cirr = cmds.circle(c=(0, 0, 0), name=(Nameof))
            shapes = cmds.listRelatives(Cirr, children=True, shapes=True)

            for shape in shapes:
                cmds.setAttr('%s.overrideEnabled' % shape, True)
                cmds.setAttr('%s.overrideColor' % shape, colorname)

        #RENAME

        if Type == "Group":

            if SizeofSelection < 1:
                print("Set a default one")

            else:
                dups = cmds.duplicate(sels)
                dups = cmds.polyUnite(dups)
                cmds.delete(dups, constructionHistory=True)
                BoxLimits = cmds.xform(dups[0], query=True, boundingBox=True)
                cmds.delete(dups[0])
                XDirect = ((BoxLimits[0]) + (BoxLimits[3])) / 2
                YDirect = ((BoxLimits[1]) + (BoxLimits[4])) / 2
                ZDirect = ((BoxLimits[2]) + (BoxLimits[5])) / 2
                Cirr = cmds.circle(c=(XDirect, YDirect, ZDirect),
                                   name=("Group " + Nameof))
                shapes = cmds.listRelatives(Cirr, children=True, shapes=True)

                for shape in shapes:
                    cmds.setAttr('%s.overrideEnabled' % shape, True)
                    cmds.setAttr('%s.overrideColor' % shape, colorname)

        if Type == "Single":

            if SizeofSelection < 1:
                print("Set a default one")

            else:
                for i in range(len(sels)):
                    BoxLimits = cmds.xform(sels[i],
                                           query=True,
                                           worldSpace=True,
                                           boundingBox=True)
                    XDirect = ((BoxLimits[0]) + (BoxLimits[3])) / 2
                    YDirect = ((BoxLimits[1]) + (BoxLimits[4])) / 2
                    ZDirect = ((BoxLimits[2]) + (BoxLimits[5])) / 2
                    Cirr = cmds.circle(c=(XDirect, YDirect, ZDirect),
                                       name=self.RenameContrl(sels[i], Nameof))
                    shapes = cmds.listRelatives(Cirr,
                                                children=True,
                                                shapes=True)

                    for shape in shapes:
                        cmds.setAttr('%s.overrideEnabled' % shape, True)
                        cmds.setAttr('%s.overrideColor' % shape, colorname)

        else:
            print("no objects selected, will put one in at default")
Ejemplo n.º 58
0
def iterParents( obj ):
	parent = cmd.listRelatives( obj, p=True, pa=True )
	while parent is not None:
		yield parent[ 0 ]
		parent = cmd.listRelatives( parent[ 0 ], p=True, pa=True )
Ejemplo n.º 59
0
def link(src_root, dst_root):

    srcs = collect_by_name(src_root, type='mesh')
    dsts = collect_by_name(dst_root, type='mesh')

    for name, src_node in sorted(srcs.iteritems()):

        dst_node = dsts.get(name)
        if not dst_node:
            continue

        # Only bother transferring attributes on meshes that have a connection
        # to an alembic node. This isn't a very strong connection, but it
        # seems to work for us.
        is_deformed = False
        for node in cmds.listHistory(src_node) or ():
            type_ = cmds.nodeType(node)
            if type_ == 'AlembicNode':
                is_deformed = True
                break
        if not is_deformed:
            continue

        print 'mesh {}: {} -> {}'.format(name, src_node, dst_node)

        src_transform = cmds.listRelatives(src_node, parent=True, path=True)[0]
        dst_transform = cmds.listRelatives(dst_node, parent=True, path=True)[0]

        transfer = cmds.transferAttributes(
            src_transform,
            dst_transform,
            afterReference=1,  # To play nice with references.
            transferPositions=1,
            transferNormals=1,
            sampleSpace=4,  # 4 == components
        )[0]

        print '    transferAttributes:', transfer

    srcs = collect_by_name(src_root, type='transform')
    dsts = collect_by_name(dst_root, type='transform')

    for name, src_node in sorted(srcs.iteritems()):

        dst_node = dsts.get(name)
        if not dst_node:
            continue

        print 'transform {}: {} -> {}'.format(name, src_node, dst_node)

        is_alembiced = False
        if True:
            for node in cmds.listConnections(src_node,
                                             skipConversionNodes=True,
                                             source=True,
                                             destination=False) or ():
                if cmds.nodeType(node) == 'AlembicNode':
                    is_alembiced = True
                    print '    is alembiced:', node
                    break

        is_animated = False
        if True:
            for attr in ('tx', 'ty', 'tz', 'rx', 'ry', 'rz', 'sx', 'sy', 'sz'):
                connections = cmds.listConnections('{}.{}'.format(
                    src_node, attr),
                                                   source=True,
                                                   destination=False)
                if connections:
                    is_animated = True
                    print '    is animated: {} is connected'.format(attr)
                    break

        is_transformed = False
        if True:
            for attr in ('tx', 'ty', 'tz', 'rx', 'ry', 'rz', 'sx', 'sy', 'sz'):
                src_value = cmds.getAttr('{}.{}'.format(src_node, attr))
                dst_value = cmds.getAttr('{}.{}'.format(dst_node, attr))
                if src_value != dst_value:
                    if abs(src_value - dst_value) > 1e-12:
                        is_transformed = True
                        print '    is transformed: src {} {} != dst {}'.format(
                            attr, src_value, dst_value)
                    else:
                        print '    has minor transform: src {} {} != dst {}'.format(
                            attr, src_value, dst_value)
                    break

        is_group = False
        has_shapes = False
        if True:
            children = cmds.listRelatives(src_node)
            child_shapes = cmds.listRelatives(src_node, shapes=True)

            has_shapes = bool(child_shapes)
            is_group = bool(children and not has_shapes)

            if is_group:
                print '    is group: {} children with no shapes'.format(
                    len(children))
            elif has_shapes:
                print '    has shapes: {} children with {} shapes'.format(
                    len(children), len(child_shapes))

        # Kevin asked to never constrain things which have shapes.
        do_constraint = (is_alembiced or is_animated
                         or is_transformed) and not has_shapes

        if do_constraint:

            # Bulk of transform is handled by a parent constraint...
            constraint = cmds.parentConstraint(src_node,
                                               dst_node,
                                               name='abc_link_parent_' +
                                               name)[0]
            print '    parentConstraint:', constraint
            constraint = cmds.scaleConstraint(src_node,
                                              dst_node,
                                              name='abc_link_scale_' + name)[0]
            print '    scaleConstraint:', constraint

        # We really do want to connect all the visibility regardless of animation.
        if name != 'hi':
            # ... and other attributed are done directly.
            for attr_name in ('visibility', ):
                cmds.connectAttr(src_node + '.' + attr_name,
                                 dst_node + '.' + attr_name,
                                 force=True)
                print '    {}: {} -> {}'.format(attr_name, src_node, dst_node)
def SetDisplayColor(Unuse=None):
    Value = int(re.search('\d+$', mc.iconTextRadioCollection("UI_ColorCollide", q=True, sl=True)).group())
    for OBJ in mc.ls(sl=True):
        for shp in mc.listRelatives(OBJ, s=True, path=True) or []:
            mc.setAttr(OBJ + '.ove', 1)
            mc.setAttr(OBJ + '.ovc', Value)