def triangulateMesh(isObj, simplify, smoothe):
if isObj and not cmds.objExists('triObj'):
cmds.select(baseObject)
cmds.duplicate(baseObject, name = "triObj")
cmds.select('triObj')
if smoothe:
cmds.polySmooth('triObj', c=smoothe)
cmds.polyReduce(ver = 1)
cmds.polyReduce(ver = 1)
if simplify > 0:
cmds.polyReduce(ver = 1, p = simplify)
num_faces = cmds.polyEvaluate('triObj', f=True)
print "Triangulating faces..."
#iterate over faces
face_i = 0
while face_i < num_faces:
if ((num_faces - face_i) % 5 == 0):
print "Triangulate check: Approximately " + str(num_faces - face_i) + " faces remaining...."
face = cmds.select('triObj.f['+ str(face_i)+']')
verts = getCorners(isObj,face_i)
if not isCoplanar(verts):
cmds.polyTriangulate('triObj.f['+ str(face_i)+']')
num_faces = cmds.polyEvaluate('triObj', f=True)
face_i +=1
def changeNumberOfJoints(self, *args):
self.blueprint_UI_instance.deleteScriptJob()
joints = self.getJoints()
numJoints = len(joints)
newNumJoints = cmds.intField(self.numberOfJointsField, q=True, value=True)
startPos = cmds.xform(self.getTranslationControl(joints[0]), q=True, ws=True, t=True)
endPos = cmds.xform(self.getTranslationControl(joints[numJoints-1]), q=True, ws=True, t=True)
hookObject = self.findHookObjectForLock()
rotationOrder = cmds.getAttr(joints[0] + ".rotateOrder")
sao_local = cmds.getAttr(self.moduleNamespace+":module_grp.sao_local")
sao_world = cmds.getAttr(self.moduleNamespace+":module_grp.sao_world")
self.delete()
newInstance = Spline(self.userSpecifiedName, hookObject, newNumJoints, startPos, endPos)
newInstance.install()
# We have to refer to the new instance stored in memory
newJoints = newInstance.getJoints()
cmds.setAttr(newJoints[0]+".rotateOrder", rotationOrder)
cmds.setAttr(newInstance.moduleNamespace+":module_grp.sao_local", sao_local)
cmds.setAttr(newInstance.moduleNamespace+":module_grp.sao_world", sao_world)
self.blueprint_UI_instance.createScriptJob()
cmds.select(newInstance.moduleNamespace+":module_transform", replace=True)
def publish(self, makePreview = False, tags = '', notes = '' ): """export shader to library""" shad = mn.Node( self.name ) mc.select( shad.shader, ne = True ) exportPath = self.path + self.name + '.ma' if self.published: #Make a bakup self.saveVersion() print 'make a f*****g backup!' else: os.makedirs( self.path ) self._savedata( tags, notes, None ) n = mn.Node( self.name ) """ if not n.a.id.exists: n.a.id.add() print self.id n.a.id.v = self.id if not n.a.category.exists: n.a.category.add() n.a.category = self.category if not n.a.path.exists: n.a.path.add() n.a.path.v = exportPath """ mc.file( exportPath , force = True, options = "v=0", typ = "mayaAscii", pr = True, es = True ) self.settexturespath( self.path + 'Textures/', exportPath ) previewtime = 0 if makePreview: print 'creating preview' previewtime = self.preview()
def m(p, _t=None):
if not _t:
_t = mc.ls(sl=1)
for i in range (0,len(_t)):
mc.select(_t[i])
mc.move(p[0],p[1],p[2])
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
def create(self, parent_transform, style):
"""Create shape"""
self.parent = parent_transform
# Add style
curve_data = Style()[style]
for curve in curve_data:
temp = cmds.curve(name="temp_curve", d=1, p=curve['points'], k=curve['knot'])
# Parent curve under transform
shapes = cmds.listRelatives(temp, shapes=True)
for shape_index, shape in enumerate(shapes):
cmds.parent(shape, parent_transform, shape=True, r=True)
# Rename shape to be tidy
new_shape = cmds.rename(shape, "%s%s" % (self.name, shape_index))
self.nodes.append(new_shape)
# Remove temp transform
cmds.delete(temp)
# Set colors
self.set_color(name.get_position(self.parent))
# Match values
self.scale_shapes(self.scale)
self.rotate_shapes(self.rotate)
# Clear selection
cmds.select(cl=True)
def edgeLoopWeights(edgeList):
"""
"""
# Check Edge List
if not edgeList: raise Exception('Invalid or empty edge list!')
edgeList = cmds.filterExpand(edgeList, ex=True, sm=32) or []
if not edgeList: raise Exception('Invalid edge list! List of polygon edges required...')
# Get Mesh from Edges
mesh = list(set(cmds.ls(edgeList, o=True) or []))
if len(mesh) > 1:
raise Exception('Edges from multiple mesh shapes were supplied! ' + str(mesh))
mesh = mesh[0]
for edge in edgeList:
# Get Edge ID
edgeID = glTools.utils.component.index(edge)
# Get Vertices from Edge
edgeVerts = cmds.polyListComponentConversion(edge, fe=True, tv=True)
# Get Average Vertex Weights
cmds.select(edgeVerts)
glTools.tools.copyPasteWeights.averageWeights()
# Select Edge Loop Vertices
cmds.polySelect(mesh, edgeLoop=edgeID)
loopEdges = cmds.ls(sl=1, fl=1)
loopVerts = cmds.polyListComponentConversion(loopEdges, fe=True, tv=True)
cmds.select(loopVerts)
glTools.tools.copyPasteWeights.pasteWeights()
# Return Result
return mesh
def __init__(self) :
# create a promptDialog for the base group name of our mesh this will help to
# avoid name conflicts, may be good to modify this at some stage to check if mesh
# exists and prompt to replace data / key
result = cmds.promptDialog(
title='Name',
message='Enter Name for import',
button=['OK', 'Cancel'],
defaultButton='OK',
cancelButton='Cancel',
dismissString='Cancel')
# if ok was pressed lets process the data
if result == 'OK':
# first we get the text entered by the user
self.m_text = cmds.promptDialog(query=True, text=True)
# now get the obj file to import
self.m_objFileName=cmds.fileDialog2(caption="Please select obj file to import",fileFilter="*.obj", fm=1)
cmds.file(self.m_objFileName,i=True,type="OBJ",ns=self.m_text)
# now the xml file
basicFilter = "*.xml"
self.m_pointBakeFile=cmds.fileDialog2(caption="Please select xml file to import",fileFilter=basicFilter, fm=1)
# select the object imported
print self.m_pointBakeFile
cmds.select("%s:Mesh"%(self.m_text))
# and pass control back to the parser
parser = xml.sax.make_parser()
parser.setContentHandler(ParseHandler("%s:Mesh"%(self.m_text)))
parser.parse(open(str(self.m_pointBakeFile[0]),"r"))
def crear(self): #Tipo 1 if(self.edififio_seleccionado == 0): cmds.polyCube(w = self.anchura, d = self.Largo, h = self.Anchura_random, n = str(self.EdificioName)) #Tipo 2 elif(self.edififio_seleccionado == 1): cmds.polyCube(w = self.anchura, d = self.Largo, h = self.Anchura_random, n = str(self.EdificioName)) #Modificamos las caras aleatoriamente for i in range(0, random.randrange(0,3)): cmds.polyExtrudeFacet(str(self.EdificioName) + ".f[1]", kft = False, ls = (0.8, 0.8, 0)) cmds.polyExtrudeFacet(str(self.EdificioName) + ".f[1]", kft = False, ltz = 30) #Tipo 3 else: cmds.polyCube(w = self.anchura, d = self.Largo, h = self.Anchura_random, sx = self.xDiv, sy = self.yDiv, sz = self.zDiv, n = str(self.EdificioName)) sides = [] #Seleccionamos el edificio for i in range(0, 8): if(i != 1 and i != 3): sides.append(str(self.EdificioName) + ".f[" + str(self.xDiv * self.yDiv * i) + ":" + str((self.xDiv * self.yDiv * (i+1)) - 1) + "]") #Modificamos las caras para generar ventanas cmds.polyExtrudeFacet(sides[0], sides[1], sides[2], sides[3], sides[4], sides[5], kft = False, ls = (0.8, 0.8, 0)) windows = cmds.ls(sl = True) cmds.polyExtrudeFacet(windows[1], windows[2], windows[3], kft = False, ltz = -0.2) cmds.select( self.EdificioName)
def orderedVertsEdgeLoop(cls):
"""
#select 2 adjasent vertices ( corner and direction vertex)
#list vertexes on edge loop( for curves )
"""
myVert = cmds.ls( os=1, fl=1 )
if len(myVert)==2:
firstVert = myVert[0]
secondVert = myVert[1]
cmds.select (firstVert,secondVert, r =1)
mel.eval('ConvertSelectionToContainedEdges')
firstEdge = cmds.ls( sl=1 )[0]
cmds.polySelectSp( firstEdge, loop =1 )
edges = cmds.ls( sl=1, fl=1 )
edgeDict = cls.getEdgeVertDict(edges) #{edge: [vert1, vert2], ...}
ordered = [firstVert, secondVert]
for i in range( len(edges)-2 ):
del edgeDict[firstEdge]
#print edgeDict
for x, y in edgeDict.iteritems():
if secondVert in y:
xVerts = y
xVerts.remove(secondVert)
firstEdge = x
secondVert = xVerts[0]
ordered.append( secondVert )
return ordered
else:
print 'select 2 adjasent vertex!!'
def checkSelObj(self):
"""检查选中的物体是否为mesh节点
Description:
选有物体且所选的是mesh节点,返回True
没选物体或所选物体类型不符合,则返回False
Arguments:
无
Returns:
result = True:通过检查
result = False:没通过检查,释放所有选择
"""
selObj = cmds.ls(sl =True)
lenOfSel = len(selObj)
result = True
if lenOfSel < 1:
cmds.confirmDialog(title = "Warning", message = "Please Select Objects!", button = "OK", defaultButton = "OK")
result = False
else:
for eachObj in selObj:
if cmds.nodeType(eachObj) != "transform":
cmds.confirmDialog(title = "Warning", message = "There Has An Object With Incorrect Type!", button = "OK", defaultButton = "OK")
cmds.select(deselect = True) #去除所有选择
result = False
break
return result
def _publish_gpu_for_item(self, item, output, work_template, primary_publish_path, sg_task, comment, thumbnail_path, progress_cb):
"""
Export a gpu cache for the specified item and publish it to Shotgun.
"""
group_name = item["name"].strip("|")
debug(app = None, method = '_publish_gpu_for_item', message = 'group_name: %s' % group_name, verbose = False)
tank_type = output["tank_type"]
publish_template = output["publish_template"]
# get the current scene path and extract fields from it using the work template:
scene_path = os.path.abspath(cmds.file(query=True, sn= True))
fields = work_template.get_fields(scene_path)
publish_version = fields["version"]
# update fields with the group name:
fields["grp_name"] = group_name
## create the publish path by applying the fields with the publish template:
publish_path = publish_template.apply_fields(fields)
#'@asset_root/publish/gpu/{name}[_{grp_name}].v{version}.abc'
gpuFileName = os.path.splitext(publish_path)[0].split('\\')[-1]
fileDir = '/'.join(publish_path.split('\\')[0:-1])
debug(app = None, method = '_publish_gpu_for_item', message = 'gpuFileName: %s' % gpuFileName, verbose = False)
## Now fix the shaders
shd.fixDGForGPU()
if cmds.objExists('CORE_ARCHIVES_hrc'):
cmds.setAttr('CORE_ARCHIVES_hrc.visiblity', 0)
if cmds.objExists('ROOT_ARCHIVES_DNT_hrc'):
cmds.setAttr('ROOT_ARCHIVES_DNT_hrc.visiblity', 0)
## build and execute the gpu cache export command for this item:
try:
print '====================='
print 'Exporting gpu now to %s\%s' % (fileDir, gpuFileName)
#PUT THE FILE EXPORT COMMAND HERE
cmds.select(clear = True)
for geo in cmds.listRelatives(group_name, children = True):
if 'geo_hrc' in geo:
geoGroup = str(group_name)
debug(app = None, method = '_publish_gpu_for_item', message = 'geoGroup: %s' % geoGroup, verbose = False)
cmds.select(geoGroup)
debug(app = None, method = '_publish_gpu_for_item', message = 'geoGroup: %s' % geoGroup, verbose = False)
debug(app = None, method = '_publish_gpu_for_item', message = "gpuCache -startTime 1 -endTime 1 -optimize -optimizationThreshold 40000 -directory \"%s\" -fileName %s %s;" % (fileDir, gpuFileName, geoGroup), verbose = False)
mel.eval("gpuCache -startTime 1 -endTime 1 -optimize -optimizationThreshold 40000 -directory \"%s\" -fileName %s %s;" % (fileDir, gpuFileName, geoGroup))
print 'Finished gpu export...'
print '====================='
if cmds.objExists('dgSHD'):
## Now reconnect the FileIn nodes
for key, var in filesDict.items():
cmds.connectAttr('%s.outColor' % key, '%s.color' % var)
except Exception, e:
raise TankError("Failed to export gpu cache file")
def mirrorJoints(self, topJoint = '', prefix = ['l_', 'r_']):
"""
mirroring joint, top node needs to contain 'l_' as prefix
"""
lPrefix = prefix[0]
rPrefix = prefix[1]
cmds.select(cl = True)
cmds.joint(n = 'temp_jnt')
cmds.select(topJoint, r = True)
cmds.select('temp_jnt', tgl = True)
self.toggleSelect(topJoint, 'temp_jnt')
cmds.parent()
cmds.select(topJoint, r = True)
cmds.mirrorJoint(mirrorYZ = True, mirrorBehavior = True, myz = True, searchReplace = prefix)
rJoint = rPrefix + topJoint.split(lPrefix)[-1]
cmds.select(topJoint, rJoint)
cmds.parent(w = True)
cmds.delete('temp_jnt')
return rJoint
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)
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
def maya_move(angular_velocity, time_step):
objects = cmds.ls(sl=True)
if objects == []:
print('* Please select at least an object.')
return
trajectory = cmds.ls('trajectory')
for i, o in enumerate(objects):
x = cmds.getAttr(o + '.translateX')
y = cmds.getAttr(o + '.translateY')
z = cmds.getAttr(o + '.translateZ')
loc = [x, y, z]
state = make_state(loc)
state = simulate_circle(state, angular_velocity, time_step)
old_loc = loc
loc = get_location(state)
cmds.select(o)
cmds.move(loc[0], loc[1], loc[2])
# draw trajectory for the first object
if i == 0:
if trajectory == []:
cv = cmds.curve(point=[old_loc, loc], degree=1)
cmds.rename(cv, 'trajectory')
else:
cmds.curve('trajectory', point=[loc], degree=1, append=True)
# keep all objects selected
cmds.select(objects)
def select_samename_node(name):
sel = cmds.ls(sl=True)
cmds.select(cl=True)
sel_hr = cmds.listRelatives(sel, ad=True) + sel
for node in sel_hr:
if node.count(name):
cmds.select(node, add=True)
def main():
mm.eval('selectCurveCV("all");')
sel = mc.ls(sl=1, fl=1)
grpname = (sel[0].split('.'))
grpname = grpname[0]+"_grp"
grp = mc.group(em=1, n=grpname)
for i in sel:
iname = i.replace('[', '')
iname = iname.replace(']','')
iname = iname.replace('.','_')
locname = iname+"_loc"
clusname = iname+"_clus"
mc.select(i, r=1)
print "here"
cluster = mc.cluster(n=clusname)
location = mc.xform(cluster, q=1, ws=1, sp=1)
print location
locator = mc.spaceLocator(n=locname, p=(location[0], location[1], location[2]))
mc.xform(locator, cp=1)
set_vis = clusname+"Handle.visibility"
mc.setAttr(set_vis, 0)
mc.parent(cluster, locator)
mc.parent(locator, grp)
shape = mc.listRelatives(locator)
mc.setAttr((shape[0]+".overrideEnabled"),1)
mc.setAttr((shape[0]+".overrideColor"),17)
def build(numBindJoints=6, numSpans=None, name='', numSkinJoints=3, width=None):
'''
builds a nurbs ribbon
If width is not specified, width will be set to numBindJoints
If numSpans is not specified, it will be set to numBindJoints
'''
if not width:
width = numBindJoints
if not numSpans:
numSpans = numBindJoints
main_grp = cmds.group(empty=1, name=(name + '_grp'))
plane = cmds.nurbsPlane(axis=(0, 1, 0), ch=0, lengthRatio=(1.0 / width), w=width, u=numSpans, name=(name + '_nurbsPlane'))[0]
cmds.parent(plane, main_grp)
# Creat Skin joints
skinJoints = []
skinJointPositions = common.pointsAlongVector( start=[width*.5, 0, 0], end=[width*-.5, 0, 0], divisions=(numSkinJoints-1) )
for index in range(len(skinJointPositions)):
cmds.select(main_grp)
j = cmds.joint(position = skinJointPositions[index], name=(name + '_' + str(index) + '_jnt'))
skinJoints.append(j)
# Add skinning to ribbon
cmds.skinCluster(skinJoints, plane, tsb=1, name=(plane + '_skinCluster'))
cmds.setAttr(plane+'.inheritsTransform', 0)
# Add follicles
for index in range(numBindJoints):
f = rivet.build( mesh=plane, paramU=(1.0 / (numBindJoints-1) * index), paramV=0.5, name=(name + '_' + str(index)))
cmds.parent(f, main_grp)
j = cmds.joint(name=(name + '_' + str(index) + '_bnd'))
def confirmJoints(self):
"""
draw joints in locator position
"""
#- Getting Ball and Toe Location
self.leftHipPos = cmds.xform('l_hip_Adjust_ctl', q = True, ws = True, t = True)
self.leftKneePos = cmds.xform('l_knee_Adjust_ctl', q = True, ws = True, t = True)
self.leftAnklePos = cmds.xform('l_ankle_Adjust_ctl', q = True, ws = True, t = True)
self.leftBallPos = cmds.xform('l_ball_Adjust_ctl', q = True, ws = True, t = True)
self.leftToePos = cmds.xform('l_toe_Adjust_ctl', q = True, ws = True, t = True)
self.leftHeelPos = cmds.xform('l_heel_PivotPosition', q = True, ws = True, t = True)
self.leftSideInPos = cmds.xform('l_sidein_PivotPosition', q = True, ws = True, t = True)
self.leftSideOutPos = cmds.xform('l_sideout_PivotPosition', q = True, ws = True, t = True)
#duplicate pivots
cmds.duplicate('l_heel_PivotPosition', n = 'r_heel_PivotPosition', rr = True)
cmds.xform('r_heel_PivotPosition', t = [-self.leftHeelPos[0], self.leftHeelPos[1], self.leftHeelPos[2]])
cmds.duplicate('l_sidein_PivotPosition', n = 'r_sidein_PivotPosition', rr = True)
cmds.xform('r_sidein_PivotPosition', t = [-self.leftSideInPos[0], self.leftSideInPos[1], self.leftSideInPos[2]])
cmds.duplicate('l_sideout_PivotPosition', n = 'r_sideout_PivotPosition', rr = True)
cmds.xform('r_sideout_PivotPosition', t = [-self.leftSideOutPos[0], self.leftSideOutPos[1], self.leftSideOutPos[2]])
cmds.select(cl = True)
print 'leg Parts : ' , self.legParts
for elem in self.legElement :
jointPos = cmds.xform(self.left + elem + '_Adjust_ctl', t = True, q = True, ws = True)
cmds.joint(n = '%s%s_jnt' %(self.left, elem), p = jointPos)
#- orient joint
cmds.joint(self.lHipJnt, e = True, oj = 'xzy', secondaryAxisOrient = 'yup', ch = True, zso = True)
#- delete position locators
cmds.delete(self.legParts)
def legCleanup(self):
for lr in self.lrPrefix:
#- hide heel pivot
cmds.setAttr('%sheel_PivotPosition.visibility' %lr, 0)
#- placing extra control
cmds.select('%sleg_extra_ctl_grp' %lr, r = True)
cmds.select('%sankle_jnt' %lr, tgl = True)
cmds.parent()
#- hide attribute
cmds.setAttr('%sleg_pv_ctl.visibility' %lr, keyable = False, channelBox = False)
cmds.setAttr('%sleg_ctl.visibility' %lr, keyable = False, channelBox = False)
#- clean up hierarchy
self.util.group(['%sik_hip_jnt' %lr, '%sfk_hip_jnt' %lr], '%sfkik_leg_jnt_grp' %lr)
self.util.group(['%ship_jnt' %lr, '%sfkik_leg_jnt_grp' %lr], '%sleg_jnt_grp' %lr)
#- hide stretchIK locator
cmds.setAttr('%sstretch_leg_grp.visibility' %lr, 0)
self.util.group(['l_leg_jnt_grp', 'r_leg_jnt_grp'], 'leg_jnt_grp')
children = ['l_leg_pv_ctl_grp', 'r_leg_pv_ctl_grp',
'l_fk_hip_ctl_grp', 'r_fk_hip_ctl_grp',
'l_leg_ctl_grp', 'r_leg_ctl_grp']
self.util.group(children, 'leg_ctl_grp')
self.util.group(['l_stretch_leg_grp', 'r_stretch_leg_grp'], 'stretch_leg_grp')
self.util.group(['l_heel_PivotPosition', 'r_heel_PivotPosition', 'stretch_leg_grp'], 'leg_misc_grp')
def _finger_hydraulics(self):
"""Connects the finger hydraulics."""
for side in ['L', 'R']:
for finger in ['pointer', 'middle', 'ring']:
start_jnt = '%s_%sBase_result_%s' % (side, finger, self.nc.joint)
end_jnt = '%s_%s1_result_%s' % (side, finger, self.nc.joint)
if finger == 'ring':
finger = 'pinky'
# END if
start_hydraulic = '%s_%sHydraulicsStart_%s_%s' % (side, finger, self.nc.joint, self.nc.group)
mid_hydraulic = '%s_%sHydraulicsMid_%s_%s' % (side, finger, self.nc.joint, self.nc.group)
end_hydraulic = '%s_%sHydraulicsEnd_%s_%s' % (side, finger, self.nc.joint, self.nc.group)
cmds.select(cl=True)
start_offset = cmds.group(n='%s_%sBaseOffset_%s' % (side, finger, self.nc.group), empty=True)
cmds.select(cl=True)
end_offset = cmds.group(n='%s_%s2Offset_%s' % (side, finger, self.nc.group), empty=True)
self.c.snap_a_to_b(start_offset, start_hydraulic)
self.c.snap_a_to_b(end_offset, end_hydraulic)
cmds.parent(start_offset, start_jnt)
cmds.parent(end_offset, end_jnt)
cmds.parent(start_hydraulic, start_offset)
cmds.parent(end_hydraulic, end_offset)
try:
cmds.parent(mid_hydraulic, '%s_hand_%s' % (side, self.nc.group))
except Exception as err:
print err
def __init__(self, start_face):
self.start_face = start_face
cmds.select(self.start_face)
self.start_face_sel = cmds.ls(sl=True)
self.slice_point = self.start_face_sel[0].find('.')
self.geom_name = self.start_face_sel[0][:int(self.slice_point)]
self.ordered_list = [self.start_face]
def mirror_chain(self, side = None):
#create one temporary joint at the origin
tmp_jnt = cmds.joint(position = [0, 0, 0])
#parent the chain to that joint
cmds.parent(self.fk_joint_names[0], tmp_jnt)
#mirror the chain and rename the mirrored side
if side == 'L':
self.mirrored_fk_joint_names = cmds.mirrorJoint(self.fk_joint_names[0], mirrorYZ = 1, mirrorBehavior = 1, searchReplace = (side, 'R'))
elif side == 'l':
self.mirrored_fk_joint_names = cmds.mirrorJoint(self.fk_joint_names[0], mirrorYZ = 1, mirrorBehavior = 1, searchReplace = (side, 'r'))
elif side == 'R':
self.mirrored_fk_joint_names = cmds.mirrorJoint(self.fk_joint_names[0], mirrorYZ = 1, mirrorBehavior = 1, searchReplace = (side, 'L'))
elif side == 'r':
self.mirrored_fk_joint_names = cmds.mirrorJoint(self.fk_joint_names[0], mirrorYZ = 1, mirrorBehavior = 1, searchReplace = (side, 'l'))
else:
self.mirrored_fk_joint_names = cmds.mirrorJoint(self.fk_joint_names[0], mirrorYZ = 1, mirrorBehavior = 1)
#unparent the chain and delete the temporary joint
cmds.parent(self.fk_joint_names[0], self.mirrored_fk_joint_names[0], world = 1)
cmds.delete(tmp_jnt)
cmds.select(clear = 1)
return self.mirrored_fk_joint_names
def mirror_chain(self, side = None):
#create one temporary joint at the origin
tmp_jnt = cmds.joint(position = [0, 0, 0])
#parent the chain to that joint
cmds.parent(self.ik_joint_names[0], tmp_jnt)
#mirror the chain and rename the mirrored side
if side == 'L':
self.mirrored_ik_joint_names = cmds.mirrorJoint(self.ik_joint_names[0], mirrorYZ = 1, mirrorBehavior = 1, searchReplace = (side, 'R'))
elif side == 'l':
self.mirrored_ik_joint_names = cmds.mirrorJoint(self.ik_joint_names[0], mirrorYZ = 1, mirrorBehavior = 1, searchReplace = (side, 'r'))
elif side == 'R':
self.mirrored_ik_joint_names = cmds.mirrorJoint(self.ik_joint_names[0], mirrorYZ = 1, mirrorBehavior = 1, searchReplace = (side, 'L'))
elif side == 'r':
self.mirrored_ik_joint_names = cmds.mirrorJoint(self.ik_joint_names[0], mirrorYZ = 1, mirrorBehavior = 1, searchReplace = (side, 'l'))
else:
self.mirrored_ik_joint_names = cmds.mirrorJoint(self.ik_joint_names[0], mirrorYZ = 1, mirrorBehavior = 1)
#unparent the chain and delete the temporary joint
cmds.parent(self.ik_joint_names[0], self.mirrored_ik_joint_names[0], world = 1)
cmds.delete(tmp_jnt)
cmds.select(clear = 1)
#rename the side of the mirrored effector correctly and store the ik and effector in a list
mirrored_ik = self.mirrored_ik_joint_names[0][0] + self.ik_handle_names[-1][1:]
mirrored_eff = cmds.rename(self.mirrored_ik_joint_names[-1], self.mirrored_ik_joint_names[0][0] + self.ik_handle_names[-1][1:])
self.mirrored_ik_handle_names = [mirrored_ik, mirrored_eff]
self.mirrored_ik_joint_names.pop(-1)
def csvWrite():
""" This is the path where the csv will be written. Change this to a path on your local machine. """
path = "R:/System/CSV_files/armCsv.csv"
""" Open the csv in maya for writing """
writer = csv.writer(open(path, 'wb'), delimiter=',')
""" Create a new list based off your selection """
selectionList = cmds.ls(sl=True)
""" Clear the selection """
cmds.select(clear=True)
for selection in selectionList:
""" An empty list to hold both the joint names and the positions """
jointInfo = []
pos = cmds.xform(selection, q=True, t=True, ws=True)
""" Append the name of the locator and it's position to a new list"""
""" I am splitting the positions into seperate variables to make things easier when I try read them later """
jointInfo.append(selection)
jointInfo.append(pos[0])
jointInfo.append(pos[1])
jointInfo.append(pos[2])
""" At this point you could use the joint info to build joints """
""" Write the data to csv """
writer.writerow(jointInfo)
""" Print the joint info so you can see what is happening """
print jointInfo
def cutSkin(mesh, weightThreshold=0.25, reducePercent=None, parentShape=False):
"""
Extract a per influence proxy mesh from a skinned mesh based on influence weights.
@param mesh: Mesh to extract faces from
@type mesh: str
@param weightThreshold: Influence to use to extract faces
@type weightThreshold: float
@param reducePercent: Influence to use to extract faces
@type reducePercent: int or None
"""
# Initialize
startTime = cmds.timerX()
cmds.undoInfo(state=False)
# Get Skin Info
skin = glTools.utils.skinCluster.findRelatedSkinCluster(mesh)
if not skin:
print('Cut Skin: Mesh "" has no skinCluster! Skipping...')
return None
# Prune Weights
glTools.utils.skinCluster.lockSkinClusterWeights(skin, lock=False, lockAttr=False)
pruneWts = glTools.utils.mathUtils.distributeValue(10, rangeStart=0.001, rangeEnd=weightThreshold)
cmds.select(mesh)
for wt in pruneWts:
try:
mel.eval('doPruneSkinClusterWeightsArgList 1 {"' + str(wt) + '"}')
except Exception, e:
print('Prune weight FAILED (' + mesh + ')! ' + str(e))
break
def orientJoints(s):
"""
Face joints in the correct direction.
"""
sel = cmds.ls(sl=True)
err = cmds.undoInfo(openChunk=True)
try:
markers = s.markers
joints = markers.keys()
with ReSeat(joints):
for j in joints:
m = markers[j]
if cmds.objExists(m.marker) and cmds.objExists(j):
with Isolate(j):
m.setJoint()
try:
cmds.makeIdentity(
j,
apply=True,
r=True) # Freeze Rotations
except RuntimeError:
pass
else: # User deleted marker / joint. Stop tracking.
m.removeMarker()
del markers[j]
cmds.select(sel, r=True)
except Exception as err:
raise
finally:
cmds.undoInfo(closeChunk=True)
if err: cmds.undo()
def export_static_ogre(*args):
export_dir = get_export_dir()
objects = get_objects()
ogre_mesh_files = []
if (cmds.file(q=True, sceneName=True)==''):
print 'Not a valid scene. Try saving it.'
return False
if not export_dir:
print ("Empty Scene? unable to export.")
else:
print ('Export Directory:\n %s\nOgre files\n' % export_dir)
for ob in objects:
name = ob
if cmds.nodeType(ob) == 'transform':
name = cmds.listRelatives(ob)[0]
cmds.select(ob, r=True)
_path = os.path.abspath( export_dir + ('/%s.mesh' % name) )
ogre_path = _path.replace(os.sep, '/')
# print ('select %s' % ob)
print (' %s' % ogre_path)
ogre_mesh_files.append(ogre_path)
# 'ogreExport -sel -obj -lu mm -scale 1 -mesh \"aaa.mesh\" -shared -v -n -c -t -tangents TANGENT -tangentsplitmirrored;''
command = 'ogreExport -sel -obj -lu mm -scale 0.1 -mesh \"%s\" -shared -n -c -t -tangents TANGENT -tangentsplitmirrored;' % ogre_path
mm.eval(command)
cmds.select(objects)
print 'fixing materials'
fix_xml_material_names(ogre_mesh_files)
def selectNode():
"""
Select node from reference edits UI.
"""
# Get Selected Ref Node
refNode = cmds.textScrollList('refEdits_refListTSL', q=True, si=True)
if not refNode: return
refNS = glTools.utils.reference.getNamespace(refNode[0]) + ':'
# Get Selected Nodes
nodeList = cmds.textScrollList('refEdits_nodeListTSL', q=True, si=True)
if not nodeList: return
# Select Nodes
selNodes = []
for node in nodeList:
# Check Node
editNode = node
if not cmds.objExists(node): node = node.split('|')[-1]
if not cmds.objExists(node): node = refNS + node
if not cmds.objExists(node): raise Exception('Reference edit node "' + editNode + '" not found!')
# Append to Selection List
selNodes.append(node)
# Select Node
if selNodes: cmds.select(selNodes)
def generate_simple_ik_leg(is_using_ball):
ik_jnts = [] # For changing its color later
jnt_tag_length = len(settings.get('jnt_tag'))
# ============================= Start of Main Function =============================
hip_jnt_start_rp_fk = stored_joints.get("hip_jnt") # Hip
if len(cmds.listRelatives(hip_jnt_start_rp_fk, type='joint') or []) > 0: # Check if hip has children
knee_jnt_middle_rp_fk = cmds.listRelatives(hip_jnt_start_rp_fk, type='joint')[0] # Knee
ankle_jnt_end_rp_fk = stored_joints.get("ankle_jnt") # Ankle
if is_using_ball:
ball_jnt_end_sc1_fk = stored_joints.get("ball_jnt") # Ball
if len(cmds.listRelatives(ball_jnt_end_sc1_fk, type='joint') or []) > 0: # Check if ball has children
toe_jnt_end_sc2_fk = cmds.listRelatives(ball_jnt_end_sc1_fk, type='joint')[0] # Toe
# Creates IK Skeleton
start_joint_rp_ik = cmds.duplicate(hip_jnt_start_rp_fk, po=True, name = hip_jnt_start_rp_fk[:-jnt_tag_length] + "_IK_Jnt") # Create IK Hip
middle_joint_rp_ik = cmds.duplicate(knee_jnt_middle_rp_fk, po=True, name = knee_jnt_middle_rp_fk[:-jnt_tag_length] + "_IK_Jnt") # Create IK Knee
end_joint_rp_ik = cmds.duplicate(ankle_jnt_end_rp_fk, po=True, name = ankle_jnt_end_rp_fk[:-jnt_tag_length] + "_IK_Jnt") # Create IK Ankle
ik_jnts.append(start_joint_rp_ik)
ik_jnts.append(middle_joint_rp_ik)
ik_jnts.append(end_joint_rp_ik)
if is_using_ball:
end_joint_sc1_ik = cmds.duplicate(ball_jnt_end_sc1_fk, po=True, name = ball_jnt_end_sc1_fk[:-jnt_tag_length] + "_IK_Jnt") # Create IK Ball
end_joint_sc2_ik = cmds.duplicate(toe_jnt_end_sc2_fk, po=True, name = ball_jnt_end_sc1_fk[:-jnt_tag_length] + "_IK_Jnt") # Create IK Toe
ik_jnts.append(end_joint_sc1_ik)
ik_jnts.append(end_joint_sc2_ik)
# Recreate Hierarchy (IK Skeleton)
if len(cmds.listRelatives(start_joint_rp_ik, parent=True) or []) != 0: # Check if parent is already world
cmds.parent( start_joint_rp_ik, world=True)
cmds.parent( middle_joint_rp_ik, start_joint_rp_ik )
cmds.parent( end_joint_rp_ik, middle_joint_rp_ik )
if is_using_ball:
cmds.parent( end_joint_sc1_ik, end_joint_rp_ik )
cmds.parent( end_joint_sc2_ik, end_joint_sc1_ik )
# Parent Constraints
start_joint_rp_ik_pConstraint = cmds.parentConstraint( start_joint_rp_ik, hip_jnt_start_rp_fk )
middle_joint_rp_ik_pConstraint = cmds.parentConstraint( middle_joint_rp_ik, knee_jnt_middle_rp_fk )
end_joint_rp_ik_pConstraint = cmds.parentConstraint( end_joint_rp_ik, ankle_jnt_end_rp_fk )
if is_using_ball:
end_joint_sc1_ik_pConstraint = cmds.parentConstraint( end_joint_sc1_ik, ball_jnt_end_sc1_fk )
# Create Main Rotate-Plane IK Solver
ikHandle_name = start_joint_rp_ik[0][:-jnt_tag_length] + 'RP_ikHandle'
ikHandle_rp = cmds.ikHandle( n=ikHandle_name, sj=start_joint_rp_ik[0], ee=end_joint_rp_ik[0], sol='ikRPsolver')
# Create Ankle to Ball Single-Chain IK Solver
if is_using_ball:
ikHandle_name = end_joint_rp_ik[0][:-jnt_tag_length] + 'SC_ikHandle'
ikHandle_sc_ball = cmds.ikHandle( n=ikHandle_name, sj=end_joint_rp_ik[0], ee=end_joint_sc1_ik[0], sol='ikSCsolver')
ikHandle_name = end_joint_sc2_ik[0][:-4] + 'SC_ikHandle'
ikHandle_sc_toe = cmds.ikHandle( n=ikHandle_name, sj=end_joint_sc1_ik[0], ee=end_joint_sc2_ik[0], sol='ikSCsolver')
if settings.get("using_custom_ik_ctrl"):
ik_control = settings.get("custom_ik_ctrl_name")
else:
ik_control = cmds.curve(name = start_joint_rp_ik[0][:-jnt_tag_length] + 'Ctrl', p=[[-0.569, 0.569, -0.569], [-0.569, 0.569, 0.569], \
[0.569, 0.569, 0.569], [0.569, 0.569, -0.569], [-0.569, 0.569, -0.569], [-0.569, -0.569, -0.569], \
[0.569, -0.569, -0.569], [0.569, 0.569, -0.569], [0.569, 0.569, 0.569], [0.569, -0.569, 0.569], \
[0.569, -0.569, -0.569], [-0.569, -0.569, -0.569], [-0.569, -0.569, 0.569], [0.569, -0.569, 0.569], \
[0.569, 0.569, 0.569], [-0.569, 0.569, 0.569], [-0.569, -0.569, 0.569]],d=1) # Creates Cube
ik_ctrl_grp = cmds.group(name=(ik_control+'Grp'))
placement_constraint = cmds.pointConstraint(end_joint_rp_ik,ik_ctrl_grp)
cmds.delete(placement_constraint)
# Constraint IK Handles to IK Control
cmds.parentConstraint(ik_control, ikHandle_rp[0], maintainOffset=True)
if is_using_ball:
cmds.parentConstraint(ik_control, ikHandle_sc_ball[0], maintainOffset=True)
cmds.parentConstraint(ik_control, ikHandle_sc_toe[0], maintainOffset=True)
if settings.get("using_custom_pvector_ctrl"):
pvector_ctrl = settings.get("custom_pvector_ctrl")
else:
pvector_ctrl = cmds.curve(name= ik_control[:-4] + 'pvector_ctrlCtrl', p=[[0.268, 0.268, 0.0], [0.535, 0.268, 0.0], [0.535, -0.268, -0.0], [0.268, -0.268, -0.0], [0.268, -0.535, -0.0], [-0.268, -0.535, -0.0], [-0.268, -0.268, -0.0], [-0.535, -0.268, -0.0], [-0.535, 0.268, 0.0], [-0.268, 0.268, 0.0], [-0.268, 0.535, 0.0], [0.268, 0.535, 0.0], [0.268, 0.268, 0.0]],d=1)
pvector_ctrl_ctrl_grp = cmds.group(name=(pvector_ctrl +'Grp'))
placement_constraint = cmds.pointConstraint(middle_joint_rp_ik,pvector_ctrl_ctrl_grp)
cmds.delete(placement_constraint)
cmds.poleVectorConstraint( pvector_ctrl, ikHandle_rp[0] )
#Check if exists (use checker before running)
if settings.get("using_custom_ikfk_switch"):
ik_switch_ctrl = settings.get("custom_ikfk_switch_name")
else:
ik_switch_ctrl_before_naming = create_fkik_switch()
ik_switch_ctrl = cmds.rename(ik_switch_ctrl_before_naming, ik_control.replace("_IK_Ctrl", "_") + "switch_ikfkCtrl")
cmds.setAttr(ik_switch_ctrl + ".overrideEnabled", 1)
cmds.setAttr(ik_switch_ctrl + ".overrideColor", 17) #Yellow
cmds.addAttr(ik_switch_ctrl, niceName='IK FK Switch', longName='ikSwitch', attributeType='bool', defaultValue = 1, keyable = True )
cmds.addAttr(ik_switch_ctrl, niceName='IK FK Influence', longName='ikInfluence', attributeType='double', defaultValue = 1, keyable = True )
lock_hide_attr(ik_switch_ctrl, ['tx','ty','tz','rx','ry','rz', 'sx','sy','sz','v'],True,False)
ik_switch_ctrlGrp = cmds.group(name=(ik_switch_ctrl+'Grp'))
reverse_node = cmds.createNode('reverse')
cmds.connectAttr('%s.ikSwitch' % ik_switch_ctrl, '%s.inputX' % reverse_node)
ctrl_name = hip_jnt_start_rp_fk[:-jnt_tag_length] + settings.get("ctrl_grp_tag")
if cmds.objExists(ctrl_name):
cmds.connectAttr('%s.outputX' % reverse_node, '%s.v' % ctrl_name)
ctrl_name = knee_jnt_middle_rp_fk[:-jnt_tag_length] + settings.get("ctrl_grp_tag")
if cmds.objExists(ctrl_name):
cmds.connectAttr('%s.outputX' % reverse_node, '%s.v' % ctrl_name)
ctrl_name = ankle_jnt_end_rp_fk[:-jnt_tag_length] + settings.get("ctrl_grp_tag")
if cmds.objExists(ctrl_name):
cmds.connectAttr('%s.outputX' % reverse_node, '%s.v' % ctrl_name)
if is_using_ball:
ctrl_name = ball_jnt_end_sc1_fk[:-jnt_tag_length] + settings.get("ctrl_grp_tag")
if cmds.objExists(ctrl_name):
cmds.connectAttr('%s.outputX' % reverse_node, '%s.v' % ctrl_name)
cmds.connectAttr('%s.ikSwitch' % ik_switch_ctrl, '%s.v' % ik_control)
cmds.connectAttr('%s.ikSwitch' % ik_switch_ctrl, '%s.v' % pvector_ctrl)
# Main Ctrl IK Influence
# Creates Condition (IK Switch is one) >
# Reverse goes to FK weight, true data is passed to IK Weight
condition_node = cmds.createNode('condition')
cmds.setAttr(condition_node + '.secondTerm', 1)
cmds.setAttr(condition_node + '.colorIfFalseR', 0)
cmds.setAttr(condition_node + '.colorIfFalseG', 0)
cmds.setAttr(condition_node + '.colorIfFalseB', 0)
cmds.connectAttr('%s.ikSwitch' % ik_switch_ctrl, '%s.firstTerm' % condition_node)
cmds.connectAttr('%s.ikInfluence' % ik_switch_ctrl, '%s.colorIfTrueR' % condition_node)
start_joint_rp_ik_pConstraint_lwn = get_last_weight_number(start_joint_rp_ik_pConstraint[0])
middle_joint_rp_ik_pConstraint_lwn = get_last_weight_number(middle_joint_rp_ik_pConstraint[0])
end_joint_rp_ik_pConstraint_lwn = get_last_weight_number(end_joint_rp_ik_pConstraint[0])
if is_using_ball:
end_joint_sc1_ik_pConstraint_lwn = get_last_weight_number(end_joint_sc1_ik_pConstraint[0])
cmds.connectAttr('%s.outColorR' % condition_node, start_joint_rp_ik_pConstraint[0] + '.' + start_joint_rp_ik[0] + "W" + start_joint_rp_ik_pConstraint_lwn)
cmds.connectAttr('%s.outColorR' % condition_node, middle_joint_rp_ik_pConstraint[0] + '.' + middle_joint_rp_ik[0] + "W" + middle_joint_rp_ik_pConstraint_lwn)
cmds.connectAttr('%s.outColorR' % condition_node, end_joint_rp_ik_pConstraint[0] + '.' + end_joint_rp_ik[0] + "W" + end_joint_rp_ik_pConstraint_lwn)
if is_using_ball:
cmds.connectAttr('%s.outColorR' % condition_node, end_joint_sc1_ik_pConstraint[0] + '.' + end_joint_sc1_ik[0] + "W" + end_joint_sc1_ik_pConstraint_lwn)
reverse_condition_node = cmds.createNode('reverse')
cmds.connectAttr('%s.outColorR' % condition_node, '%s.inputX' % reverse_condition_node)
#Connects constraint weights to reverse node
def connect_non_ik_weights(constraintName, nonIKWeightList):
for obj in nonIKWeightList:
cmds.connectAttr('%s.outputX' % reverse_condition_node, constraintName + '.' + obj)
connect_non_ik_weights(start_joint_rp_ik_pConstraint[0],get_all_weights_but_not_last(start_joint_rp_ik_pConstraint[0]))
connect_non_ik_weights(middle_joint_rp_ik_pConstraint[0],get_all_weights_but_not_last(middle_joint_rp_ik_pConstraint[0]))
connect_non_ik_weights(end_joint_rp_ik_pConstraint[0],get_all_weights_but_not_last(end_joint_rp_ik_pConstraint[0]))
if is_using_ball:
connect_non_ik_weights(end_joint_sc1_ik_pConstraint[0],get_all_weights_but_not_last(end_joint_sc1_ik_pConstraint[0]))
# Colorize Control Start ------------------
if settings.get("using_colorize_ctrls"):
controls = [ik_control, pvector_ctrl]
for ctrl in controls:
if True == True:
cmds.setAttr(ctrl + ".overrideEnabled", 1)
if 'right_' in ctrl:
cmds.setAttr(ctrl + ".overrideColor", 13) #Red
elif 'left_' in ctrl:
cmds.setAttr(ctrl + ".overrideColor", 6) #Blue
else:
cmds.setAttr(ctrl + ".overrideColor", 17) #Yellow
# Create setup grp
main_ik_grp_name = hip_jnt_start_rp_fk.replace("Jnt","")
main_ik_grp = cmds.group(name=main_ik_grp_name + "_IK_Setup_grp",em=True)
cmds.parent(start_joint_rp_ik, main_ik_grp) # Parent to Setup Grp (IK Skeleton)
solvers_ik_grp = cmds.group(name=main_ik_grp_name + "_solvers_grp",em=True)
# Parent to Setup Grp (Solvers)
if is_using_ball:
cmds.parent(ikHandle_sc_ball[0], solvers_ik_grp)
cmds.parent(ikHandle_sc_toe[0], solvers_ik_grp)
cmds.parent(ikHandle_rp[0], solvers_ik_grp) # Parent to Setup Grp (Solvers)
cmds.parent(solvers_ik_grp, main_ik_grp) # Parent to Setup Grp (Solvers)
cmds.setAttr(solvers_ik_grp + ".v", 0) #Make solvers grp invisible
cmds.setAttr(start_joint_rp_ik[0] + ".v", 0) #Make ik skeleton invisible
ctrls_ik_grp = cmds.group(name=main_ik_grp_name + "_controls_grp",em=True)
generated_ctrls = [ik_switch_ctrlGrp,pvector_ctrl_ctrl_grp,ik_ctrl_grp]
for ctrl in generated_ctrls:
if cmds.objExists(ctrl):
cmds.parent(ctrl, ctrls_ik_grp)
cmds.parent(ctrls_ik_grp, main_ik_grp)
ctrls_children = cmds.listRelatives(ctrls_ik_grp, c=True)
if ctrls_children == None:
cmds.delete(ctrls_ik_grp)
# Add some color to the new outliner elements
change_outliner_color(main_ik_grp,[0.240,1,0.062])
change_outliner_color(solvers_ik_grp,[1,1,0.126])
change_outliner_color(ctrls_ik_grp,[1,0.479,0.172])
for jnt in ik_jnts:
change_outliner_color(jnt[0],[0.763,0.332,0.892])
# If not using Ball, make IK control rotate ankle
if is_using_ball == False:
cmds.orientConstraint(ik_control,end_joint_rp_ik)
# Make leg stretchy
if settings.get('make_stretchy'):
cmds.select(ikHandle_rp)
ikHandle = cmds.ls(selection=True, type="ikHandle")
stretchy_grp = make_stretchy_legs(ikHandle)
cmds.parent(stretchy_grp, main_ik_grp)
change_outliner_color(stretchy_grp,[1,0,0])
cmds.setAttr(stretchy_grp + ".v", 0) #Make it invisible
cmds.select(ik_control)
#to make this a little bicer we will use a list.
#A list = list of items like you would take shopping.#
#To save us some typing we can make a list with all of our joint names in it.#
#In fact, we can make a list of lists so we can have a list for each joint name and position#
#We use square brackets to encapsulate each item in list.#
#That list of lists can even be saved to a variable#
jointinfo = (['joint_upperarm',[0.0,5.0,0.0]],['joint_lowerarm',[1.0,5.0,2.0]],['joint_hand',[0.0,5.0,4.0]])
print jointinfo
#so we have our list, but how do we work with it?
#for this we will call upon the power of loop
cmds.select(d=True)
for item in jointinfo:
#//print item #print each loop variables in jointinfo
#//print item[0] #print each loop variables of index0 in jointinfo // the index 0 of listed item
#//print item[1] #print each loop variables of index1 in jointinfo // the index 1 of listem item
cmds.joint(n=item[0],p=item[1]) #this creates joints, with name assigned to listed items index 0, position to listem items index 1
//////
#define a list of strings and assign it to the mylist variable.
mylist = ('a','b')
#enter a for loop and print each item in my list
for item in mylist:
def process(self, instance):
# get settings
framerange = [
instance.data.get("frameStart", 1),
instance.data.get("frameEnd", 1)
]
handles = instance.data.get("handles", 0)
step = instance.data.get("step", 1.0)
bake_to_worldspace = instance.data("bakeToWorldSpace", True)
# get cameras
members = instance.data['setMembers']
cameras = cmds.ls(members,
leaf=True,
shapes=True,
long=True,
dag=True,
type="camera")
# validate required settings
assert len(cameras) == 1, "Not a single camera found in extraction"
assert isinstance(step, float), "Step must be a float value"
camera = cameras[0]
# Define extract output file path
dir_path = self.staging_dir(instance)
filename = "{0}.abc".format(instance.name)
path = os.path.join(dir_path, filename)
# Perform alembic extraction
with avalon.maya.maintained_selection():
cmds.select(camera, replace=True, noExpand=True)
# Enforce forward slashes for AbcExport because we're
# embedding it into a job string
path = path.replace("\\", "/")
job_str = ' -selection -dataFormat "ogawa" '
job_str += ' -attrPrefix cb'
job_str += ' -frameRange {0} {1} '.format(framerange[0] - handles,
framerange[1] + handles)
job_str += ' -step {0} '.format(step)
if bake_to_worldspace:
transform = cmds.listRelatives(camera,
parent=True,
fullPath=True)[0]
job_str += ' -worldSpace -root {0}'.format(transform)
job_str += ' -file "{0}"'.format(path)
with lib.evaluation("off"):
with avalon.maya.suspended_refresh():
cmds.AbcExport(j=job_str, verbose=False)
if "representations" not in instance.data:
instance.data["representations"] = []
representation = {
'name': 'abc',
'ext': 'abc',
'files': filename,
"stagingDir": dir_path,
}
instance.data["representations"].append(representation)
self.log.info("Extracted instance '{0}' to: {1}".format(
instance.name, path))
def Select_OBJ_Fun(self,selectTarget):
if selectTarget != "":
cmds.select(selectTarget)
def check(self):
cmds.text('sme_startFrame_label', e=True, en=1)
cmds.floatField('sme_startFrame', e=True, en=1)
cmds.text('sme_endFrame_label', e=True, en=1)
cmds.floatField('sme_endFrame', e=True, en=1)
cmds.text('sme_totalFrames_label',
e=True,
en=1,
l='Total Frames: ' + str(someGlobals.globals['startFrame'] +
someGlobals.globals['endFrame']))
cmds.optionMenu('sme_frameRate', e=True, en=1)
filename = re.sub('[^\w\-_\. ]', '',
cmds.textField('sme_rigFilename', q=True,
tx=True)).replace(' ', '')
cmds.textField('sme_rigFilename', e=True, tx=filename)
dataExists = ''
if os.path.isfile(someGlobals.globals['exportPath'] + filename +
'.fbx'):
dataExists = ' - Data Exists!'
cmds.text('sme_rigDataExists_label', e=True, l=dataExists)
name = re.sub('[^\w\-_\.\ ]', '',
cmds.textField('sme_rigName', q=True,
tx=True)).replace(' ', '')
cmds.textField('sme_rigName', e=True, tx=name)
rig = cmds.textField('sme_rigToSample', q=True,
tx=True).replace(' ', '')
cmds.textField('sme_rigToSample', e=True, tx=rig)
selectEnable = 0
selectCommand = lambda *args: cmds.select(rig, r=True)
selectColor = someGlobals.color['red']
if cmds.objExists(rig):
selectEnable = 1
selectCommand = lambda *args: cmds.select(rig, r=True)
selectColor = someGlobals.color['blue']
bakeEnable = 1
bakeColor = someGlobals.color['green']
bakeLabel = 'Bake and Export Rig'
bakeCommand = lambda *args: self.batch()
if len(filename) < 1 or len(name) < 1 or cmds.objExists(rig) == False:
bakeEnable = 0
bakeColor = someGlobals.color['red']
bakeLabel = 'Errors Found in Rig Export Parameters'
bakeCommand = ''
if (os.path.exists(someGlobals.globals['exportPath']) == False):
bakeEnable = 0
bakeColor = someGlobals.color['red']
bakeCommand = ''
bakeLabel = 'Invalid Export Path'
# lets update our globals
rigFilename = {'filename': filename}
rigName = {'name': name}
rigNode = {'node': rig}
someGlobals.rig.update(rigFilename)
someGlobals.rig.update(rigName)
someGlobals.rig.update(rigNode)
cmds.button('sme_selectRigToExport_button',
e=True,
en=selectEnable,
bgc=selectColor,
c=selectCommand)
cmds.button('sme_rigBake_button',
e=True,
en=bakeEnable,
bgc=bakeColor,
l=bakeLabel,
c=bakeCommand)
def Cam_Item_Pressing_Event(self, e):
"""
mousePressEvent
# Note 点击事件触发
"""
## Note 清空所有颜色轮廓
for i, child in enumerate(self.Cam_Item_Widget.Item_Layout.children()):
if i != 0:
if child.Cam_Item.styleSheet() != "":
child.Cam_Item.setStyleSheet("")
self.Cam_Item_Widget.setStyleSheet("")
## Note 坐标偏移
offset = 90 - self.Cam_Item_Widget.Scroll_Offset
for i, child in enumerate(self.Cam_Item_Widget.Item_Layout.children()):
if i != 0:
## Note 如果坐标匹配则载入相关数据
if child.geometry().contains(e.pos().x(),
e.pos().y() - offset):
child.Cam_Item.setStyleSheet(
"#Cam_Item{border:3px solid red}")
CamName = child.Cam_LE.text()
self.Cam_Attribute_Widget.Cam_Name_Label.setText(
u"<center> - %s - </center>" % CamName)
self.Cam_Attribute_Widget.Cam_Input_Toggle.setVisible(True)
self.Cam_Attribute_Widget.Cam_Input_Layout.setVisible(True)
self.Cam_Attribute_Widget.Cam_Output_Toggle.setVisible(
True)
self.Cam_Attribute_Widget.Cam_Output_Layout.setVisible(
True)
self.Cam_Attribute_Widget.Add_CamGrp_Layout.setVisible(
True)
self.Cam_Attribute_Widget.Strat_Time_Layout.setVisible(
True)
self.Cam_Attribute_Widget.End_Time_Layout.setVisible(True)
self.Cam_Attribute_Widget.Auto_Catch_Label.setVisible(True)
self.Cam_Attribute_Widget.Add_Loc_Layout.setVisible(True)
self.Cam_Attribute_Widget.Current_Item = child
if os.path.exists(GUI_STATE_PATH):
GUI_STATE = {}
with open(GUI_STATE_PATH, 'r') as f:
GUI_STATE = json.load(f)
Attr = GUI_STATE['Cam_Item'][CamName]["Attr"]
self.Cam_Attribute_Widget.Add_Crv_LE.setText(
Attr["Add_Crv_LE"])
self.Cam_Attribute_Widget.Add_Loc_LE.setText(
Attr["Add_Loc_LE"])
self.Cam_Attribute_Widget.Add_Motion_Path_LE.setText(
Attr["Add_Motion_Path_LE"])
self.Cam_Attribute_Widget.Add_CamGrp_LE.setText(
Attr["Add_CamGrp_LE"])
# Note 检查选择
if self.Cam_Attribute_Widget.Check_Selection():
self.Cam_Attribute_Widget.Strat_Time_SB.setValue(
int(Attr["Strat_Time_SB"]))
self.Cam_Attribute_Widget.End_Time_SB.setValue(
int(Attr["End_Time_SB"]))
cmds.select(Attr["Add_CamGrp_LE"])
self.Cam_Attribute_Widget.Add_CamGrp_Pick_Fun()
cmds.select(Attr["Add_CamGrp_LE"])
else:
self.Cam_Attribute_Widget.Strat_Time_SB.setValue(0)
self.Cam_Attribute_Widget.End_Time_SB.setValue(0)
cmds.select(cl=1)
self.Cam_Attribute_Widget.Add_CamGrp_Pick_Fun()
self.Cam_Attribute_Widget.Add_Motion_Path_Pick_Fun(
)
self.Cam_Attribute_Widget.Add_Crv_Pick_Fun()
self.Cam_Attribute_Widget.Add_Loc_Pick_Fun()
self.Save_Json_Fun()
else:
QMessageBox.warning(self, u"Warning", u"加载参数失败")
break
else:
## Note 遍历全部对象说明没有匹配 使用默认情况
if self.Cam_Item_Widget.Cam_Base_Label.geometry().contains(
e.pos().x(),
e.pos().y() - 40):
self.Cam_Item_Widget.setStyleSheet(
"#Cam_Base_Layout{border:3px solid red}")
self.Cam_Attribute_Widget.Current_Item = self.Cam_Item_Widget
self.Cam_Attribute_Widget.Cam_Input_Toggle.setVisible(True)
self.Cam_Attribute_Widget.Cam_Input_Layout.setVisible(True)
self.Cam_Attribute_Widget.Cam_Output_Toggle.setVisible(False)
self.Cam_Attribute_Widget.Cam_Output_Layout.setVisible(False)
# self.Cam_Attribute_Widget.Add_CamGrp_Layout.setVisible(False)
self.Cam_Attribute_Widget.Strat_Time_Layout.setVisible(False)
self.Cam_Attribute_Widget.End_Time_Layout.setVisible(False)
self.Cam_Attribute_Widget.Auto_Catch_Label.setVisible(False)
# self.Cam_Attribute_Widget.Add_Loc_Layout.setVisible(False)
Cam_Base_Name = self.Cam_Item_Widget.Cam_LE.text()
self.Cam_Attribute_Widget.Cam_Name_Label.setText(
u"<center> - %s - </center>" % Cam_Base_Name)
Attr = self.Cam_Item_Widget.Attr
self.Cam_Attribute_Widget.Add_Crv_LE.setText(
Attr["Add_Crv_LE"])
self.Cam_Attribute_Widget.Add_Motion_Path_LE.setText(
Attr["Add_Motion_Path_LE"])
self.Cam_Attribute_Widget.Add_CamGrp_LE.setText(
Attr["Add_CamGrp_LE"])
self.Cam_Attribute_Widget.Add_Loc_LE.setText(
Attr["Add_Loc_LE"])
# Note 检查选择
if self.Cam_Attribute_Widget.Check_Selection():
cmds.select(Attr["Add_Crv_LE"])
self.Cam_Attribute_Widget.Add_Crv_Pick_Fun()
cmds.select(Attr["Add_CamGrp_LE"])
self.Cam_Attribute_Widget.Add_CamGrp_Pick_Fun()
cmds.select(Attr["Add_Loc_LE"])
self.Cam_Attribute_Widget.Add_Loc_Pick_Fun()
cmds.select(Attr["Add_CamGrp_LE"])
else:
cmds.select(cl=1)
self.Cam_Attribute_Widget.Add_Motion_Path_Pick_Fun()
self.Cam_Attribute_Widget.Add_Crv_Pick_Fun()
self.Cam_Attribute_Widget.Add_CamGrp_Pick_Fun()
self.Save_Json_Fun()
else:
self.Default_Attr_Setting()
def if_exists_select(obj):
if cmds.objExists(obj):
cmds.select(obj)
cmds.headsUpMessage(obj + " selected", verticalOffset=150 )
else:
cmds.warning("Object doesn't exist! Did you delete or rename it after loading?")
def CreateButtonPush(*args):
currentValue = cmds.optionMenu('Object_Type', query=True, value=True)
if currentValue == 'Fluid Emitter':
set = cmds.ls(type='fluidEmitter')
if bool(set): # Condition If No Objects Type In Scene
cmds.select(set)
cmds.sets(name='fluidEmitterQSS', text='gCharacterSet')
print('Created Quick Selection Set with all Fluid Emitters')
else:
print('No Fluid Emitter in Scene')
elif currentValue == 'nParticle/Particle Emitter':
set = cmds.ls(exactType='pointEmitter')
if bool(set): # Condition If No Objects Type In Scene
cmds.select(set)
cmds.sets(name='particleEmitterQSS', text='gCharacterSet')
print('Created Quick Selection Set with all Particle Emitters')
else:
print('No Particle Emitter in Scene')
elif currentValue == 'nRigid':
set = cmds.ls(type='nRigid')
if bool(set): # Condition If No Objects Type In Scene
cmds.select(set)
cmds.sets(name='nRigidQSS', text='gCharacterSet')
print('Created Quick Selection Set with all nRigids')
else:
print('No nRigid in Scene')
elif currentValue == 'Fluid Container':
set = cmds.ls(type='fluidShape')
if bool(set): # Condition If No Objects Type In Scene
cmds.select(set)
cmds.sets(name='fluidShapeQSS', text='gCharacterSet')
print('Created Quick Selection Set with all Fluid Containers')
else:
print('No Fluid Container in Scene')
elif currentValue == 'Nucleus':
set = cmds.ls(type='nucleus')
if bool(set): # Condition If No Objects Type In Scene
cmds.select(set)
cmds.sets(name='nucleusQSS', text='gCharacterSet')
print('Created Quick Selection Set with all Nucleus')
else:
print('No Nucleus in Scene')
elif currentValue == 'nParticle':
set = cmds.ls(type='nParticle')
if bool(set): # Condition If No Objects Type In Scene
cmds.select(set)
cmds.sets(name='nParticleQSS', text='gCharacterSet')
print('Created Quick Selection Set with all nParticles')
else:
print('No nParticle in Scene')
elif currentValue == 'Force Field':
set = cmds.ls(type='field')
if bool(set): # Condition If No Objects Type In Scene
cmds.select(set)
cmds.sets(name='forceFieldQSS', text='gCharacterSet')
print('Created Quick Selection Set with all Force Fields')
else:
print('No Force Field in Scene')
elif currentValue == 'Legacy Particle':
set = cmds.ls(exactType='particle')
if bool(set): # Condition If No Objects Type In Scene
cmds.select(set)
cmds.sets(name='ParticleQSS', text='gCharacterSet')
print('Created Quick Selection Set with all Particles')
else:
print('No Particle in Scene')
elif currentValue == 'nCloth':
set = cmds.ls(exactType='nCloth')
if bool(set): # Condition If No Objects Type In Scene
cmds.select(set)
cmds.sets(name='nClothQSS', text='gCharacterSet')
print('Created Quick Selection Set with all nClothes')
else:
print('No nCloth in Scene')
elif currentValue == 'Dynamic Constraint':
set = cmds.ls(exactType='dynamicConstraint')
if bool(set): # Condition If No Objects Type In Scene
cmds.select(set)
cmds.sets(name='dynamicConstraintQSS', text='gCharacterSet')
print('Created Quick Selection Set with all Dynamic Constraints')
else:
print('No Dynamic Constraint in Scene')
elif currentValue == 'Rigid Body':
set = cmds.ls(exactType='rigidBody')
if bool(set): # Condition If No Objects Type In Scene
cmds.select(set)
cmds.sets(name='rigidBodyQSS', text='gCharacterSet')
print('Created Quick Selection Set with all Rigid Bodies')
else:
print('No Rigid Body in Scene')
elif currentValue == 'Rigid Constraint':
set = cmds.ls(exactType='rigidConstraint')
if bool(set): # Condition If No Objects Type In Scene
cmds.select(set)
cmds.sets(name='rigidConstraintQSS', text='gCharacterSet')
print('Created Quick Selection Set with all Rigid Constraints')
else:
print('No Rigid Constraint in Scene')
elif currentValue == 'Anim Constraint':
set = cmds.ls(type='constraint')
if bool(set): # Condition If No Objects Type In Scene
cmds.select(set)
cmds.sets(name='constraintQSS', text='gCharacterSet')
print('Created Quick Selection Set with all Anim Constraints')
else:
print('No Anim Constraint in Scene')
elif currentValue == 'Rigid Body':
set = cmds.ls(type='rigidBody')
if bool(set): # Condition If No Objects Type In Scene
cmds.select(set)
cmds.sets(name='rigidBodyQSS', text='gCharacterSet')
print('Created Quick Selection Set with all Rigid bodies')
else:
print('No Rigid Body in Scene')
def testRename(self):
# open tree.ma scene in test-samples
mayaUtils.openTreeScene()
# clear selection to start off
cmds.select(clear=True)
# select a USD object.
mayaPathSegment = mayaUtils.createUfePathSegment(
'|world|Tree_usd|Tree_usdShape')
usdPathSegment = usdUtils.createUfePathSegment('/TreeBase')
treebasePath = ufe.Path([mayaPathSegment, usdPathSegment])
treebaseItem = ufe.Hierarchy.createItem(treebasePath)
ufe.GlobalSelection.get().append(treebaseItem)
# get the USD stage
stage = mayaUsd.ufe.getStage(str(mayaPathSegment))
# by default edit target is set to the Rootlayer.
self.assertEqual(stage.GetEditTarget().GetLayer(),
stage.GetRootLayer())
self.assertTrue(stage.GetRootLayer().GetPrimAtPath("/TreeBase"))
# get default prim
defaultPrim = stage.GetDefaultPrim()
self.assertEqual(defaultPrim.GetName(), 'TreeBase')
# TreeBase has two childern: leavesXform, trunk
assert len(defaultPrim.GetChildren()) == 2
# get prim spec for defaultPrim
primspec = stage.GetEditTarget().GetPrimSpecForScenePath(
defaultPrim.GetPath())
# set primspec name
primspec.name = "TreeBase_potato"
# get the renamed prim
renamedPrim = stage.GetPrimAtPath('/TreeBase_potato')
# One must use the SdfLayer API for setting the defaultPrim when you rename the prim it identifies.
stage.SetDefaultPrim(renamedPrim)
# get defaultPrim again
defaultPrim = stage.GetDefaultPrim()
self.assertEqual(defaultPrim.GetName(), 'TreeBase_potato')
# make sure we have a valid prims after the primspec rename
assert stage.GetPrimAtPath('/TreeBase_potato')
assert stage.GetPrimAtPath('/TreeBase_potato/leavesXform')
# prim should be called TreeBase_potato
potatoPrim = stage.GetPrimAtPath('/TreeBase_potato')
self.assertEqual(potatoPrim.GetName(), 'TreeBase_potato')
# prim should be called leaves
leavesPrimSpec = stage.GetObjectAtPath(
'/TreeBase_potato/leavesXform/leaves')
self.assertEqual(leavesPrimSpec.GetName(), 'leaves')
def CreatePlaneBtnCmd():
#create paramaters
#get base shape
#get number of divisions
#Gather Info
NumberOfDivision = mc.intSliderGrp(divisitonintField, q=True, v=True)
createCtroller = mc.checkBox(createCtrlCB, q=True, v=True)
controllerType = mc.radioCollection("ControllerSelectionID",
q=True,
sl=True)
NameBase = mc.textFieldGrp("ControllerTextFieldID", q=True, tx=True)
specifyBaseShape = mc.checkBox(SpecifyBaseShapeCB, q=True, v=True)
BaseShapeFiledText = mc.textField("BasicShapeTextFieldID", q=True, tx=True)
printInfo()
#get selection:
if (mc.ls(sl=True)):
sel = mc.ls(sl=True)[0]
else:
mc.error("Nothing is selected")
return
#get Shapes:
ShapeNodeList = mc.listRelatives(sel, s=True)
BaseShape = ""
TargetShape = ""
for item in ShapeNodeList:
if mc.getAttr(item + ".intermediateObject"):
BaseShape = item
else:
TargetShape = item
if specifyBaseShape and BaseShape == "":
BaseShape = BaseShapeFiledText
if BaseShape == "":
print mc.error(
"Cannot Find Baseshape, please specify BaseShape Mannually")
#gether per vertex translation and object translation
baseVertexLocations = GetVertexLocations(BaseShape)
targetVertexLocations = GetVertexLocations(TargetShape)
baseTranslation = getTranslateNodePostion(BaseShape)
targetTranslation = getTranslateNodePostion(TargetShape)
#printMVector(baseTranslation)
#get the bounding box of the offsetted vertex
boundingBoxInfo = GetBoundingBox(baseVertexLocations,
targetVertexLocations, baseTranslation,
targetTranslation)
boundingBox = boundingBoxInfo[0]
bIsBoundingBoxValid = boundingBoxInfo[1]
#print boundingBox, bIsBoundingBoxValid
if (not bIsBoundingBoxValid):
mc.error("There is no different between seleted shape and base shape")
#create divistion Planes:
MakeDivistionPlan(boundingBox, baseTranslation, targetTranslation,
TargetShape, BaseShape, NumberOfDivision)
print "Divistion Planes Created Succesfully!"
mc.select(sel, r=True)
def selEdgeByIntArray(self, inputArray, add=False):
if not add:
cmds.select(cl=1)
for i in inputArray:
vertString = '%s.e[%s]' % (self.polyName, str(i))
cmds.select(vertString, add=1)
def testRenameUndo(self):
'''Rename USD node.'''
# open usdCylinder.ma scene in test-samples
mayaUtils.openCylinderScene()
# clear selection to start off
cmds.select(clear=True)
# select a USD object.
mayaPathSegment = mayaUtils.createUfePathSegment(
'|world|mayaUsdTransform|shape')
usdPathSegment = usdUtils.createUfePathSegment('/pCylinder1')
cylinderPath = ufe.Path([mayaPathSegment, usdPathSegment])
cylinderItem = ufe.Hierarchy.createItem(cylinderPath)
cylinderHierarchy = ufe.Hierarchy.hierarchy(cylinderItem)
propsItem = cylinderHierarchy.parent()
propsHierarchy = ufe.Hierarchy.hierarchy(propsItem)
propsChildrenPre = propsHierarchy.children()
ufe.GlobalSelection.get().append(cylinderItem)
# get the USD stage
stage = mayaUsd.ufe.getStage(str(mayaPathSegment))
# check GetLayerStack behavior
self.assertEqual(stage.GetLayerStack()[0], stage.GetSessionLayer())
self.assertEqual(stage.GetEditTarget().GetLayer(),
stage.GetRootLayer())
# by default edit target is set to the Rootlayer.
self.assertEqual(stage.GetEditTarget().GetLayer(),
stage.GetRootLayer())
# rename
cylinderItemType = cylinderItem.nodeType()
newName = 'pCylinder1_Renamed'
cmds.rename(newName)
# The renamed item is in the selection.
snIter = iter(ufe.GlobalSelection.get())
pCylinder1Item = next(snIter)
pCylinder1RenName = str(pCylinder1Item.path().back())
self.assertEqual(pCylinder1RenName, newName)
propsChildren = propsHierarchy.children()
self.assertEqual(len(propsChildren), len(propsChildrenPre))
self.assertIn(pCylinder1Item, propsChildren)
cmds.undo()
self.assertEqual(cylinderItemType,
ufe.GlobalSelection.get().back().nodeType())
def childrenNames(children):
return [str(child.path().back()) for child in children]
propsHierarchy = ufe.Hierarchy.hierarchy(propsItem)
propsChildren = propsHierarchy.children()
propsChildrenNames = childrenNames(propsChildren)
self.assertNotIn(pCylinder1RenName, propsChildrenNames)
self.assertIn('pCylinder1', propsChildrenNames)
self.assertEqual(len(propsChildren), len(propsChildrenPre))
cmds.redo()
self.assertEqual(cylinderItemType,
ufe.GlobalSelection.get().back().nodeType())
propsHierarchy = ufe.Hierarchy.hierarchy(propsItem)
propsChildren = propsHierarchy.children()
propsChildrenNames = childrenNames(propsChildren)
self.assertIn(pCylinder1RenName, propsChildrenNames)
self.assertNotIn('pCylinder1', propsChildrenNames)
self.assertEqual(len(propsChildren), len(propsChildrenPre))
for j in range(4):
mc.rename('IndexLoc' + str(j + 4), 'MiddleLoc' + str(j))
for j in range(4, 8):
mc.rename('IndexLoc' + str(j + 4), 'RingLoc' + str(j - 4))
for j in range(8, 12):
mc.rename('IndexLoc' + str(j + 4), 'PinkieLoc' + str(j - 8))
createLoc()
#create IK FK SKIN joints (arm)
shoulderLT = mc.getAttr('ShoulderLeftLoc.t')[0]
elbowLT = mc.getAttr('ElbowLeftLoc.t')[0]
wristLT = mc.getAttr('WristLeftLoc.t')[0]
mc.select(clear=True)
shouder_FK = mc.joint(n='shoulder_FK_JNT')
mc.joint(shouder_FK,
e=True,
p=(shoulderLT[0], shoulderLT[1], shoulderLT[2]),
rad=0.5,
oj='xyz',
sao='yup')
elbow_FK = mc.joint(n='elbow_FK_JNT')
mc.joint(elbow_FK,
e=True,
p=(elbowLT[0], elbowLT[1], elbowLT[2]),
rad=0.5,
oj='xyz',
sao='yup')
wrist_FK = mc.joint(n='wrist_FK_JNT')
def follicleRivet(surface, baseName=None, U=0.5, V=0.5, attr=False, shape=True, p=None):
'''
Create follicle on surface as a rivet hook
# return rivet
Options:
-baseName (string): base name string used as prefix for all nodes
-U (float): u placement
-v (float): v placement
-attr (bool): add U and V position option attributes to rivet
-shape (bool): add locator shaped curve to rivet
-p (node): rivet target parent node
author: guillaume barlier
'''
# sanity check
surface, surfaceShp = shapeFunctions.filterShpAndTransform(surface)
if not (surface and surfaceShp):
return
# define baseName
if not baseName:
baseName = 'rivet'
# create follicle
follicleShp = cmds.createNode('follicle')
follicle = cmds.listRelatives(follicleShp, p=True)[0]
cmds.setAttr('%s.inheritsTransform'%follicle, 0)
cmds.connectAttr('%s.outRotate'%follicleShp, '%s.rotate'%follicle, f=True)
cmds.connectAttr('%s.outTranslate'%follicleShp, '%s.translate'%follicle, f=True)
# set U V
cmds.setAttr('%s.pu'%follicleShp, U)
cmds.setAttr('%s.pv'%follicleShp, V)
# rename follicle (createNode create the shape)
follicle = cmds.rename(follicle, baseName)
follicleShp = cmds.listRelatives(follicle, s=True)[0]
# connect surface to follicle
cmds.connectAttr('%s.worldMatrix[0]'%surfaceShp, '%s.inputWorldMatrix'%follicleShp, f=True)
if cmds.nodeType(surfaceShp) == 'nurbsSurface':
cmds.connectAttr('%s.local'%surfaceShp, '%s.inputSurface'%follicleShp, f=True)
elif cmds.nodeType(surfaceShp) == 'mesh':
cmds.connectAttr('%s.worldMesh[0]'%surfaceShp, '%s.inputMesh'%follicleShp, f=True)
# add curve locator shape
locatorShp = None
if shape:
# rename.hide follicle shape
follicleShp = cmds.rename(follicleShp, baseName+'FollicleShape')
cmds.setAttr('%s.v'%follicleShp, 0)
# add curve locator shape
locatorShp = handleFunctions.curveLocator(baseName+'CrvLoc', p=follicle, s=True)
cmds.reorder(locatorShp, front=True )
controlFunctions.colorShape([locatorShp], 4)
# add custom attribute
if attr:
attributeFunctions.createSeparator(follicle)
cmds.addAttr(follicle, ln='parameterU', sn='pu', at='double')
cmds.setAttr('%s.pu'%follicle, U, k=True)
cmds.connectAttr('%s.pu'%follicle, '%s.pu'%follicleShp, f=True)
cmds.addAttr(follicle, ln='parameterV', sn='pv', at='double')
cmds.setAttr('%s.pv'%follicle, V, k=True)
cmds.connectAttr('%s.pv'%follicle, '%s.pv'%follicleShp, f=True)
# parent rivet
if p and cmds.objExists(p):
cmds.parent(follicle, p)
# clean and lock
attributeFunctions.lockAndHideTransforms(follicle)
attributeFunctions.lockAll(follicleShp)
cmds.select(cl=True)
return follicle
def install_custom(self, joints):
cmds.select(clear=True)
ikJoints = []
if not self.mirrored:
index = 0
for joint in self.jointInfo:
ikJoints.append(
cmds.joint(n=self.moduleNamespace + ":IK_" + joint[0],
p=joint[1],
absolute=True,
rotationOrder="xyz"))
cmds.setAttr(ikJoints[index] + ".visibility", 0)
if index != 0:
cmds.joint(ikJoints[index - 1],
edit=True,
oj="xyz",
sao="yup")
index += 1
else:
rootJointName = self.jointInfo[0][0]
tempDuplicateNodes = cmds.duplicate(self.originalModule + ":IK_" +
rootJointName,
renameChildren=True)
cmds.delete(tempDuplicateNodes.pop())
mirrorXY = False
mirrorYZ = False
mirrorXZ = False
if self.mirrorPlane == "XY":
mirrorXY = True
elif self.mirrorPlane == "YZ":
mirrorYZ = True
elif self.mirrorPlane == "XZ":
mirrorXZ = True
mirrorBehavior = False
if self.rotationFunction == "behavior":
mirrorBehavior = True
mirrorJoints = cmds.mirrorJoint(tempDuplicateNodes[0],
mirrorXY=mirrorXY,
mirrorXZ=mirrorXZ,
mirrorYZ=mirrorYZ,
mirrorBehavior=mirrorBehavior)
cmds.delete(tempDuplicateNodes)
cmds.xform(mirrorJoints[0],
ws=True,
a=True,
translation=cmds.xform(self.moduleNamespace + ":" +
rootJointName,
q=True,
ws=True,
t=True))
for i in range(3):
jointName = self.jointInfo[i][0]
newName = cmds.rename(
mirrorJoints[i], self.moduleNamespace + ":IK_" + jointName)
ikJoints.append(newName)
utils.addNodeToContainer(self.containerName, ikJoints)
for joint in ikJoints:
jointName = utils.stripAllNamespaces(joint)[1]
cmds.container(
self.containerName,
edit=True,
publishAndBind=[joint + ".rotate", jointName + "_R"])
cmds.setAttr(ikJoints[0] + ".preferredAngleY", -50.0)
cmds.setAttr(ikJoints[1] + ".preferredAngleY", 50.0)
# Call on the stretchy ik function from utils
ikNodes = utils.RP_2segment_stretchy_IK(ikJoints[0], ikJoints[1],
ikJoints[2],
self.containerName)
locators = (ikNodes[0], ikNodes[1], ikNodes[2])
distanceNodes = ikNodes[3]
# Point constraint stretch locators to transform control objects
constraints = []
for i in range(3):
constraints.append(
cmds.pointConstraint(self.getTranslationControl(joints[i]),
locators[i],
maintainOffset=False)[0])
cmds.parent(locators[i],
self.moduleNamespace + ":module_grp",
absolute=True)
cmds.setAttr(locators[i] + ".visibility", 0)
utils.addNodeToContainer(self.containerName, constraints)
scaleTarget = self.getTranslationControl(joints[1])
paRepresentation = self.createPreferredAngleRepresentation(
ikJoints[1], scaleTarget)
cmds.setAttr(paRepresentation + ".axis", lock=True)
def createLoc():
mc.spaceLocator(n='FootLoc')
mc.scale(0.6, 0.6, 0.6)
mc.color(rgb=(0, 0, 1))
mc.spaceLocator(n='AnkleLoc')
mc.move(0, head * 0.5, 0)
mc.scale(0.2, 0.2, 0.2)
mc.color(rgb=(0.5, 0, 0))
mc.spaceLocator(n='KneeLoc')
mc.move(0, head * 2, 0)
mc.scale(0.3, 0.3, 0.3)
mc.color(rgb=(0.5, 0.2, 0))
mc.spaceLocator(n='PelvisLoc')
mc.move(0, head * 4, 0)
mc.scale(0.4, 0.4, 0.4)
mc.color(rgb=(0.5, 0.2, 0.5))
mc.spaceLocator(n='NeckLoc')
mc.move(0, head * 6.5, 0)
mc.scale(0.2, 0.2, 0.2)
mc.color(rgb=(0, 0.2, 0.5))
mc.spaceLocator(n='ShoulderLeftLoc')
mc.move(head, head * 6.5, 0)
mc.scale(0.2, 0.2, 0.2)
mc.color(rgb=(0, 0.2, 0.5))
mc.spaceLocator(n='ElbowLeftLoc')
mc.move(head * 2.5, head * 6.5, 0)
mc.scale(0.2, 0.2, 0.2)
mc.color(rgb=(0, 0.2, 0.5))
mc.spaceLocator(n='WristLeftLoc')
mc.move(head * 3.7, head * 6.5, 0)
mc.scale(0.2, 0.2, 0.2)
mc.color(rgb=(0, 0.2, 0.5))
mc.spaceLocator(n='IndexLoc3')
mc.move(head * 4.4, head * 6.5, 0)
mc.scale(0.1, 0.1, 0.1)
mc.color(rgb=(0, 0.2, 0.5))
mc.spaceLocator(n='IndexLoc0')
fingerEnd = mc.getAttr('IndexLoc3.tx')
wrist = mc.getAttr('WristLeftLoc.tx')
halfhand = wrist + (fingerEnd - wrist) * 0.5
mc.move(halfhand, head * 6.5, 0)
mc.scale(0.05, 0.05, 0.05)
mc.spaceLocator(n='IndexLoc1')
fingerEnd = mc.getAttr('IndexLoc3.tx')
middlefingerRoot = mc.getAttr('IndexLoc0.tx')
halfmiddleFinger = middlefingerRoot + (fingerEnd - middlefingerRoot) * 0.5
mc.move(halfmiddleFinger, head * 6.5, 0)
mc.scale(0.05, 0.05, 0.05)
mc.spaceLocator(n='IndexLoc2')
fingerEnd = mc.getAttr('IndexLoc3.tx')
IndexLoc1 = mc.getAttr('IndexLoc1.tx')
halfmiddleSecondFinger = IndexLoc1 + (fingerEnd - IndexLoc1) * 0.5
mc.move(halfmiddleSecondFinger, head * 6.5, 0)
mc.scale(0.05, 0.05, 0.05)
mc.select('IndexLoc0', 'IndexLoc1', 'IndexLoc2', 'IndexLoc3')
mc.move(0, 0, 0.2, r=True)
mc.spaceLocator(n='ShoulderRightLoc')
mc.move(-head, head * 6.5, 0)
mc.scale(0.2, 0.2, 0.2)
mc.color(rgb=(0, 0.2, 0.5))
mc.spaceLocator(n='HeadLoc')
mc.move(0, head * 7, 0)
mc.scale(0.5, 0.5, 0.5)
mc.color(rgb=(0, 0.2, 0.5))
mc.spaceLocator(n='HeadEndLoc')
mc.move(0, head * 8, 0)
mc.scale(0.7, 0.7, 0.7)
mc.color(rgb=(0, 0, 2))
#other fingers besides index
for i in range(3):
mc.select('IndexLoc0', 'IndexLoc1', 'IndexLoc2', 'IndexLoc3')
mc.duplicate()
mc.move(0, 0, -0.2 * (i + 1), r=True)
for j in range(4):
mc.rename('IndexLoc' + str(j + 4), 'MiddleLoc' + str(j))
for j in range(4, 8):
mc.rename('IndexLoc' + str(j + 4), 'RingLoc' + str(j - 4))
for j in range(8, 12):
mc.rename('IndexLoc' + str(j + 4), 'PinkieLoc' + str(j - 8))
def move_pointer(x, y, z, m):
cmds.select("pointer" + str(m))
cmds.move(x, y, z, absolute=True, worldSpace=True, worldSpaceDistance=True)
def selObj(self , tex = None , *args): cmds.select(cmds.textScrollList(tex,q=1,si=1))
def export_obj(name):
obj_path = os.path.dirname(os.path.realpath(__file__)) + "/folded/snapshots/" + name + ".obj"
print("Saving file as " + obj_path)
cmds.select(clear=True)
cmds.select("shirt")
mel.eval('file -force -options "groups=0;ptgroups=1;materials=1;smoothing=1;normals=1" -typ "OBJexport" -pr -es "%s";' % obj_path)
def createRig(unusedBasename='DomeStereoCamera'):
"""
Creates a new stereo rig. Uses a series of Maya commands to build
a stereo rig.
The optional argument basename defines the base name for each DAG
object that will be created.
"""
#Create a random camera letter "extension" to fix the unique camera issue with the camera aim, and aim+up add-on bug
import string
import random
randomLetterPostfix = random.choice(string.ascii_uppercase)
#print ("The StereoCameraRig Random letter extension is: DomeStereoCamera" + randomLetterPostfix)
#Put a temp throwaway value of unusedBasename as the createRig input variable
#Define basename here instead of the regular createRig() variable
basename = 'DomeStereoCamera' + randomLetterPostfix
# Create the root of the rig
#
root = cmds.createNode('stereoRigTransform', name=basename)
# The actual basename use is the name of the top transform. If a
# second rig is created, the default base name may be incremented
# (e.g. stereoRig1). We want to use the same name for the whole
# hierarchy.
# If such a name already exists, root will be a partial path. Keep
# only the last part for the name.
#
rootName = root.split('|')[-1]
# Create the center (main) camera
# Connect the center camera attributes to the root
# Change any default parameters.
#
centerCam = cmds.createNode('stereoRigCamera',
name=rootName + 'CenterCamShape',
parent=root)
for attr in [
'stereo', 'interaxialSeparation', 'zeroParallax', 'toeInAdjust',
'filmOffsetRightCam', 'filmOffsetLeftCam'
]:
cmds.connectAttr(centerCam + '.' + attr, root + '.' + attr)
cmds.connectAttr(centerCam + '.focalLength', root + '.focalLengthInput')
#cmds.setAttr( centerCam + '.stereo', 2 )
cmds.setAttr(centerCam + '.renderable', 0)
# Create the Frustum node, connect it to the root.
#
frustum = __createFrustumNode(centerCam, root, rootName + 'Frustum')
# Create the left & right eye cameras
#
leftCam = __createSlaveCamera(centerCam, rootName + 'Left', root)
rightCam = __createSlaveCamera(centerCam, rootName + 'Right', root)
# Set up message attribute connections to define the role of each camera
#
cmds.connectAttr(leftCam + '.message', frustum + '.leftCamera')
cmds.connectAttr(rightCam + '.message', frustum + '.rightCamera')
cmds.connectAttr(centerCam + '.message', frustum + '.centerCamera')
# Connect the specific left and right output attributes of the root
# transform to the corresponding left and right camera attributes.
#
cmds.connectAttr(root + '.stereoLeftOffset', leftCam + '.translateX')
cmds.connectAttr(root + '.stereoRightOffset', rightCam + '.translateX')
cmds.connectAttr(root + '.stereoLeftAngle', leftCam + '.rotateY')
cmds.connectAttr(root + '.stereoRightAngle', rightCam + '.rotateY')
cmds.connectAttr(root + '.filmBackOutputLeft', leftCam + '.hfo')
cmds.connectAttr(root + '.filmBackOutputRight', rightCam + '.hfo')
# Lock the attributes that should not be manipulated by the artist.
#
for attr in ['translate', 'rotate']:
cmds.setAttr(leftCam + '.' + attr, lock=True)
cmds.setAttr(rightCam + '.' + attr, lock=True)
#---------------------------------------------------------------------------
# Custom Domemaster3D Setup code
#---------------------------------------------------------------------------
import os
import sys
# 18 mm focal length = 90 degree FOV
defaultRealtimeFOV = 18
# 4 mm focal length = 160 degree FOV
#defaultRealtimeFOV = 4
domeOverrideFOV = int(
os.getenv('DOMEMASTER3D_MAYA_REALTIME_FOV', defaultRealtimeFOV))
if ((domeOverrideFOV >= 3) and (domeOverrideFOV <= 3500)):
print("Using a Domemaster3D realtime viewport FOV value of " +
str(domeOverrideFOV) + ".\n")
else:
print(
"The \"DOMEMASTER3D_MAYA_REALTIME_FOV\" environment variable overridden FOV Value of "
+ str(domeOverrideFOV) +
" is outside of the acceptable range of 3 mm to 3500mm that Maya accepts as a valid camera field of view value. The default value of "
+ str(defaultRealtimeFOV) + " will be used instead.\n")
domeOverrideFOV = defaultRealtimeFOV
# Use the default FOV value or pull the FOV value from the DOMEMASTER3D_MAYA_REALTIME_FOV env variable
cmds.setAttr(centerCam + '.focalLength', domeOverrideFOV)
# 4 mm focal length = 160 degree FOV
#cmds.setAttr( centerCam + '.focalLength', 4 )
# 18 mm focal length = 90 degree FOV
#cmds.setAttr( centerCam + '.focalLength', 18 )
#cmds.setAttr( centerCam + '.stereo', 0 )
#cmds.setAttr( centerCam + '.zeroParallax', 0.1 )
#cmds.setAttr( centerCam + '.interaxialSeparation', 0 )
# Create the fulldome stereo lens shaders
createLensShaders(centerCam, leftCam, rightCam)
#Align the base camera to point upwards
cmds.setAttr(root + '.rotateX', 90)
cmds.setAttr(root + '.rotateY', 0)
cmds.setAttr(root + '.rotateZ', 0)
# Link the new attribute 'Cam Locator Scale' to the dome camera's locator size control
cmds.addAttr(root,
longName='Cam_Locator_Scale',
niceName='Cam Locator Scale',
attributeType='double',
defaultValue=1.0,
minValue=0.01)
cmds.setAttr(root + '.Cam_Locator_Scale', keyable=False, channelBox=True)
# Result: Connected DomeStereoCamera.Cam_Locator_Scale to DomeStereoCameraLeftShape.locatorScale. //
cmds.connectAttr(root + '.Cam_Locator_Scale',
centerCam + '.locatorScale',
force=True)
cmds.connectAttr(root + '.Cam_Locator_Scale',
leftCam + '.locatorScale',
force=True)
cmds.connectAttr(root + '.Cam_Locator_Scale',
rightCam + '.locatorScale',
force=True)
#---------------------------------------------------------------------------
cmds.select(root)
return [root, leftCam, rightCam]
def uiLoadParentNameObject(self, parentNameObject):
assert mc.objExists(
parentNameObject) is True, "'%s' doesn't exist" % parentNameObject
mc.select(cl=True)
mc.select(parentNameObject)
uiLoadAutoNameObject(self)
def release_pointer(time, m):
cmds.select(clear=True)
mel.eval('select -tgl pointer' + str(m) + ';')
mel.eval('setKeyframe -t ' + str(time) + ' { \"dynamicConstraintShape' + str(m) + '.gls\" };')
mel.eval('setAttr \"dynamicConstraintShape' + str(m) + '.glueStrength\" 0;')
mel.eval('setKeyframe -t ' + str(time+1) + ' { \"dynamicConstraintShape' + str(m) + '.gls\" };')
def ReplaceEyesWithExternalMeshes():
oldEyes = mayaUtils.FindMeshByWildcard('FemaleEyes')
jointLeft = cmds.ls('eye_l', type='joint')[0]
jointRight = cmds.ls('eye_r', type='joint')[0]
print oldEyes
print jointLeft
print jointRight
#get old eyes mesh vertical (Y) size
oldSizeY = mayaUtils.GetBoundingBox(oldEyes)[1]
print oldSizeY
cmds.delete(oldEyes)
mayaUtils.CleanUnusedMaterials()
print GetSharedResourcesPath()
leftEyeFilePath = os.path.join(GetSharedResourcesPath(), 'Eye_Left.obj')
print leftEyeFilePath
leftEyeMesh = cmds.ls(cmds.file(leftEyeFilePath,
i=True,
returnNewNodes=True),
transforms=True)[0]
externalSizeY = mayaUtils.GetBoundingBox(leftEyeMesh)[1]
print externalSizeY
rightEyeFilePath = os.path.join(GetSharedResourcesPath(), 'Eye_Right.obj')
rightEyeMesh = cmds.ls(cmds.file(rightEyeFilePath,
i=True,
returnNewNodes=True),
transforms=True)[0]
scaleFactor = oldSizeY / externalSizeY
print 'Scale factor = {}'.format(scaleFactor)
#scale and move new eyes
cmds.scale(scaleFactor,
scaleFactor,
scaleFactor,
leftEyeMesh,
relative=True)
cmds.matchTransform(leftEyeMesh, jointLeft, position=True, rotation=True)
cmds.rotate(0, '90deg', 0, leftEyeMesh, relative=True)
cmds.makeIdentity(leftEyeMesh,
apply=True,
translate=True,
rotate=True,
scale=True,
normal=1)
cmds.delete(leftEyeMesh, constructionHistory=True)
cmds.scale(scaleFactor,
scaleFactor,
scaleFactor,
rightEyeMesh,
relative=True)
cmds.matchTransform(rightEyeMesh, jointRight, position=True, rotation=True)
cmds.rotate(0, '90deg', 0, rightEyeMesh, relative=True)
cmds.makeIdentity(rightEyeMesh,
apply=True,
translate=True,
rotate=True,
scale=True,
normal=1)
cmds.delete(rightEyeMesh, constructionHistory=True)
#binding
cmds.skinCluster(jointLeft, leftEyeMesh, tsb=True)
cmds.select(clear=True)
cmds.skinCluster(jointRight, rightEyeMesh, tsb=True)
cmds.select(clear=True)
cmds.polyUniteSkinned([leftEyeMesh, rightEyeMesh], ch=False)
cmds.rename('FemaleEyes')
cmds.select(clear=True)
sha = cmds.shadingNode('lambert', asShader=True, name='Eyes')
sg = cmds.sets(empty=True,
renderable=True,
noSurfaceShader=True,
name='Eyes_sg')
cmds.connectAttr(sha + '.outColor', sg + '.surfaceShader', f=True)
cmds.sets('FemaleEyes', e=True, forceElement=sg)
def copyAnimation(source=None,
destination=None,
pasteMethod='replace',
offset=0,
start=None,
end=None,
layer=None):
'''
Actually do the copy and paste from one node to another. If start and end frame is specified,
set a temporary key before copying, and delete it afterward.
'''
if layer:
mc.select(destination)
mc.animLayer(layer, edit=True, addSelectedObjects=True)
#we want to make sure rotation values are within 360 degrees, so we don't get flipping when blending layers.
utl.minimizeRotationCurves(source)
utl.minimizeRotationCurves(destination)
if pasteMethod == 'replaceCompletely' or not start or not end:
mc.copyKey(source)
if layer:
mc.animLayer(layer, edit=True, selected=True)
mc.pasteKey(destination, option=pasteMethod, timeOffset=offset)
else:
#need to do this per animation curve, unfortunately, to make sure we're not adding or removing too many keys
animCurves = mc.keyframe(source, query=True, name=True)
if not animCurves:
return
#story cut keytimes as 2 separate lists means we only have to run 2 cutkey commands, rather than looping through each
cutStart = list()
cutEnd = list()
for curve in animCurves:
#does it have keyframes on the start and end frames?
startKey = mc.keyframe(curve,
time=(start, ),
query=True,
timeChange=True)
endKey = mc.keyframe(curve,
time=(end, ),
query=True,
timeChange=True)
#if it doesn't set a temporary key for start and end
#and store the curve name in the appropriate list
if not startKey:
mc.setKeyframe(curve, time=(start, ), insert=True)
cutStart.append(curve)
if not endKey:
mc.setKeyframe(curve, time=(end, ), insert=True)
cutEnd.append(curve)
mc.copyKey(source, time=(start, end))
if layer:
for each in mc.ls(type='animLayer'):
mc.animLayer(each, edit=True, selected=False, preferred=False)
mc.animLayer(layer, edit=True, selected=True, preferred=True)
mc.pasteKey(destination,
option=pasteMethod,
time=(start, end),
copies=1,
connect=0,
timeOffset=offset)
#if we set temporary source keys, delete them now
if cutStart:
mc.cutKey(cutStart, time=(start, ))
if cutEnd:
mc.cutKey(cutEnd, time=(end, ))
def PostprocessGenitaliaObject(genitaliaMeshWildcard):
with mayaUtils.DebugTimer(
'PostprocessGenitaliaObject(genitaliaMeshWildcard={0})'.format(
genitaliaMeshWildcard)):
genitaliaMesh = mayaUtils.FindMeshByWildcard(genitaliaMeshWildcard)
if not genitaliaMesh:
print 'Genitalia mesh not found. Aborted'
return
print 'Processing {0}'.format(genitaliaMesh)
genitaliaMesh = cmds.rename(genitaliaMesh,
'FemaleGenitalia') #rename to proper name
#replace material with original torso mat
facesWithTorsoMat = mayaUtils.GetFacesByMatsWildcard(
genitaliaMesh, 'Torso*')
mayaUtils.AssignObjectListToShader(facesWithTorsoMat,
'Body') #use new material name
# mayaUtils.ArrangeUVByMat(genitaliaMesh, 'Body', su=0.5, sv=0.5, u=0.5, v=0.5)
mayaUtils.AppendShadingGroupByMat(genitaliaMesh, 'Anus', 'V****a')
mayaUtils.RenameMaterial('Anus', 'BodyGenitalia')
cmds.bakePartialHistory(genitaliaMesh, prePostDeformers=True)
bodyMesh = mayaUtils.FindMeshByWildcard('FemaleBody' + '*',
checkForMatWithName='Body')
if not bodyMesh:
print '{0} mesh not found. Aborted'
return
cmds.select(clear=True)
borderVertsList = mayaUtils.GetBorderVertices(genitaliaMesh)
borderVertsList = cmds.filterExpand(borderVertsList,
sm=31,
expand=True)
bodySkinCluster = mayaUtils.GetSkinCluster(bodyMesh)
genitaliaSkinCluster = mayaUtils.GetSkinCluster(genitaliaMesh)
#transfer attributes manually
for v in borderVertsList:
pos = cmds.pointPosition(v, world=True)
#print pos
closestVert = mayaUtils.GetClosestVertex(bodyMesh, pos)
closestVertPos = cmds.xform(closestVert, t=True, ws=True, q=True)
closestVertNormal = cmds.polyNormalPerVertex(closestVert,
query=True,
xyz=True)
# set position
cmds.move(closestVertPos[0],
closestVertPos[1],
closestVertPos[2],
v,
absolute=True,
worldSpace=True)
# set normal
cmds.polyNormalPerVertex(v,
xyz=(closestVertNormal[0],
closestVertNormal[1],
closestVertNormal[2]))
referenceVertInfluences = cmds.skinPercent(bodySkinCluster,
closestVert,
query=True,
transform=None,
ignoreBelow=0.00001)
targetInfluences = cmds.skinCluster(genitaliaSkinCluster,
query=True,
influence=True)
targetTransformValues = []
for i in referenceVertInfluences:
if i not in targetInfluences:
cmds.skinCluster(genitaliaSkinCluster,
e=True,
addInfluence=i,
weight=0.0)
#print i
referenceInfluenceValuePerVertex = cmds.skinPercent(
bodySkinCluster,
closestVert,
query=True,
transform=i,
transformValue=True)
targetTransformValues.append(
(i, referenceInfluenceValuePerVertex))
#print targetTransformValues
# set weight
cmds.skinPercent(genitaliaSkinCluster,
v,
transformValue=targetTransformValues)
cmds.bakePartialHistory(genitaliaMesh, prePostDeformers=True)
def FixNewJointsOrientation():
with mayaUtils.DebugTimer('FixNewJointsOrientation'):
# Root
mayaUtils.RotateJoint("DAZ_root", 0, 0, 0)
# Spine
CopyJointPosition('DAZ_pelvis', 'DAZ_thigh_l', 'yz')
mayaUtils.RotateJoint("DAZ_pelvis", -90, 0, 90)
mayaUtils.RotateJoint("DAZ_spine_01", -90, 0, 90)
AimJointForUnreal('DAZ_spine_01', 'DAZ_spine_02')
mayaUtils.RotateJoint("DAZ_spine_02", -90, 0, 90)
AimJointForUnreal('DAZ_spine_02', 'DAZ_spine_03')
mayaUtils.RotateJoint("DAZ_spine_03", -90, 0, 90)
AimJointForUnreal('DAZ_spine_03', 'DAZ_neck_01')
mayaUtils.RotateJoint("DAZ_breast_l", -90, 0, 0)
mayaUtils.RotateJoint("DAZ_breast_r", 90, 0, 0)
mayaUtils.RotateJoint("DAZ_neck_01", -90, 0, 90)
AimJointForUnreal('DAZ_neck_01', 'DAZ_head')
mayaUtils.RotateJoint("DAZ_head", -90, 0, 90)
# Leg Left
mayaUtils.RotateJoint("DAZ_thigh_l", -90, 0, 90)
mayaUtils.RotateJoint("DAZ_thigh_twist_01_l", -90, 0, 90)
mayaUtils.RotateJoint("DAZ_calf_l", -90, 0, 90)
# copy rotation from Leg
cmds.xform('DAZ_foot_l',
absolute=True,
rotation=cmds.xform('calf_l',
q=True,
absolute=True,
rotation=True))
mayaUtils.RotateJoint("DAZ_foot_l", -90, 0, 90)
AimFootJoint('DAZ_foot_l',
'DAZ_ball_l',
inAimVector=[0, -1, 0],
inUpVector=[1, 0, 0])
mayaUtils.RotateJoint("DAZ_ball_l", 0, -90,
0) #TODO near but not ideal
# Leg Right
mayaUtils.RotateJoint("DAZ_thigh_r", 90, 0, -90)
mayaUtils.RotateJoint("DAZ_thigh_twist_01_r", 90, 0, -90)
mayaUtils.RotateJoint("DAZ_calf_r", 90, 0, -90)
# copy rotation from Leg
cmds.xform('DAZ_foot_r',
absolute=True,
rotation=cmds.xform('calf_r',
q=True,
absolute=True,
rotation=True))
mayaUtils.RotateJoint("DAZ_foot_r", 90, 0, -90)
AimFootJoint('DAZ_foot_r',
'DAZ_ball_r',
inAimVector=[0, 1, 0],
inUpVector=[-1, 0, 0])
mayaUtils.RotateJoint("DAZ_ball_r", 180, 90, 0)
# Arm Left
#TODO TEST
CopyJointPosition('DAZ_clavicle_l', 'DAZ_spine_03', 'z')
mayaUtils.RotateJoint("DAZ_clavicle_l", -90)
AimJointForUnreal('DAZ_clavicle_l', 'DAZ_upperarm_l')
mayaUtils.RotateJoint("DAZ_upperarm_l", -90)
mayaUtils.RotateJoint("DAZ_upperarm_twist_01_l", -90)
mayaUtils.RotateJoint("DAZ_lowerarm_l", -90)
mayaUtils.RotateJoint("DAZ_lowerarm_twist_01_l", -90)
mayaUtils.RotateJoint("DAZ_hand_l", -180)
mayaUtils.RotateJoint('DAZ_thumb_01_l', -90)
mayaUtils.RotateJoint('DAZ_thumb_02_l', -90)
mayaUtils.RotateJoint('DAZ_thumb_03_l', -90)
#mayaUtils.RotateJoint('DAZ_HandIndex0_L', 90)
mayaUtils.RotateJoint('DAZ_index_01_l', 180)
mayaUtils.RotateJoint('DAZ_index_02_l', 180)
mayaUtils.RotateJoint('DAZ_index_03_l', 180)
#mayaUtils.RotateJoint('DAZ_HandMid0_L', 90)
mayaUtils.RotateJoint('DAZ_middle_01_l', 180)
mayaUtils.RotateJoint('DAZ_middle_02_l', 180)
mayaUtils.RotateJoint('DAZ_middle_03_l', 180)
#mayaUtils.RotateJoint('DAZ_HandRing0_L', 90)
mayaUtils.RotateJoint('DAZ_ring_01_l', 180)
mayaUtils.RotateJoint('DAZ_ring_02_l', 180)
mayaUtils.RotateJoint('DAZ_ring_03_l', 180)
#mayaUtils.RotateJoint('DAZ_HandPinky0_L', 90)
mayaUtils.RotateJoint('DAZ_pinky_01_l', 180)
mayaUtils.RotateJoint('DAZ_pinky_02_l', 180)
mayaUtils.RotateJoint('DAZ_pinky_03_l', 180)
# Arm Right
#TODO TEST
CopyJointPosition('DAZ_clavicle_r', 'DAZ_spine_03', 'z')
mayaUtils.RotateJoint("DAZ_clavicle_r", 90)
AimJointForUnreal('DAZ_clavicle_r',
'DAZ_upperarm_r',
inAimVector=[-1.0, 0.0, 0.0])
mayaUtils.RotateJoint("DAZ_upperarm_r", 90)
mayaUtils.RotateJoint("DAZ_upperarm_twist_01_r", 90)
mayaUtils.RotateJoint("DAZ_lowerarm_r", 90)
mayaUtils.RotateJoint("DAZ_lowerarm_twist_01_r", 90)
mayaUtils.RotateJoint("DAZ_hand_r", 0)
mayaUtils.RotateJoint('DAZ_thumb_01_r', 90)
mayaUtils.RotateJoint('DAZ_thumb_02_r', 90)
mayaUtils.RotateJoint('DAZ_thumb_03_r', 90)
#mayaUtils.RotateJoint('DAZ_HandIndex0_R', -90, 180)
mayaUtils.RotateJoint('DAZ_index_01_r', 0)
mayaUtils.RotateJoint('DAZ_index_02_r', 0)
mayaUtils.RotateJoint('DAZ_index_03_r', 0)
#mayaUtils.RotateJoint('DAZ_HandMid0_R', -90, 180)
mayaUtils.RotateJoint('DAZ_middle_01_r', 0)
mayaUtils.RotateJoint('DAZ_middle_02_r', 0)
mayaUtils.RotateJoint('DAZ_middle_03_r', 0)
#mayaUtils.RotateJoint('DAZ_HandRing0_R', -90, 180)
mayaUtils.RotateJoint('DAZ_ring_01_r', 0)
mayaUtils.RotateJoint('DAZ_ring_02_r', 0)
mayaUtils.RotateJoint('DAZ_ring_03_r', 0)
#mayaUtils.RotateJoint('DAZ_HandPinky0_R', -90, 180)
mayaUtils.RotateJoint('DAZ_pinky_01_r', 0)
mayaUtils.RotateJoint('DAZ_pinky_02_r', 0)
mayaUtils.RotateJoint('DAZ_pinky_03_r', 0)
#Toes
for t in [
'toebig_01', 'toebig_02', 'toeindex_01', 'toeindex_02',
'toemid_01', 'toemid_02', 'toering_01', 'toering_02',
'toepinky_01', 'toepinky_02'
]:
mayaUtils.RotateJoint('DAZ_' + t + '_l', 0, 90)
mayaUtils.RotateJoint('DAZ_' + t + '_r', 0, -90)
# facial rig
mayaUtils.RotateJoint("DAZ_tongue_01", 0, -90, 0)
mayaUtils.RotateJoint("DAZ_tongue_02", 0, -90, 0)
mayaUtils.RotateJoint("DAZ_tongue_03", 0, -90, 0)
mayaUtils.RotateJoint("DAZ_tongue_04", 0, -90, 0)
mayaUtils.RotateJoint("DAZ_eye_l", 0, -90, 180)
mayaUtils.RotateJoint("DAZ_eye_r", 0, -90, 180)
# selecting original joints of face rig
children = cmds.listRelatives('DAZ_head', allDescendents=True) or []
for child in children:
if child in ['DAZ_eye_l', 'DAZ_eye_r'
] or child.startswith('DAZ_tongue_'):
continue # skip already rotated
mayaUtils.RotateJoint('DAZ_' + child, 0, -90,
0) # but rotating skeleton copy
cmds.select(clear=True)
def thighJnts(side):
import maya.cmds as mc
# refer to the no roll attribute control
attrCtrl = "%s_leg_SW_ctrl" % side
rev = mc.createNode("reverse", n="%s_leg_01_no_twist_rev" % side)
mc.connectAttr("%s.%s_nr" % (attrCtrl, side), "%s.ix" % rev)
# refer to thigh joints
jnt1 = ("%s_leg_01_deform_ctrl_01" % side)
jnt2 = ("%s_leg_01_deform_ctrl_02" % side)
jnt3 = ("%s_leg_01_deform_ctrl_03" % side)
jnt4 = ("%s_leg_01_deform_ctrl_04" % side)
# refer to thigh nt joints
ntjnt1 = ("%s_leg_01_no_twist_ctrl_01" % side)
ntjnt2 = ("%s_leg_01_no_twist_ctrl_02" % side)
ntjnt3 = ("%s_leg_01_no_twist_ctrl_03" % side)
ntjnt4 = ("%s_leg_01_no_twist_ctrl_04" % side)
# controls
tempCrcl1 = mc.circle(n="%s_tempCircle1" % side)
mc.delete(tempCrcl1, ch=True)
mc.rotate(90, 0, 0, "%s.cv[0:9]" % tempCrcl1[0], r=1)
mc.scale(1.2, .6, .3, "%s.cv[0:9]" % tempCrcl1[0], r=1)
mc.parent("%sShape" % tempCrcl1[0], ntjnt1, s=True, r=True)
mc.select(cl=True)
mc.delete(tempCrcl1[0])
oriConst1 = mc.orientConstraint(jnt1, ntjnt1, mo=True)
mc.connectAttr("%s.ox" % rev, "%s.w0" % oriConst1[0])
tempCrcl2 = mc.circle(n="%s_tempCircle2" % side)
mc.delete(tempCrcl2, ch=True)
mc.rotate(90, 0, 0, "%s.cv[0:9]" % tempCrcl2[0], r=1)
mc.scale(1.2, .6, .3, "%s.cv[0:9]" % tempCrcl2[0], r=1)
mc.parent("%sShape" % tempCrcl2[0], ntjnt2, s=True, r=True)
mc.select(cl=True)
mc.delete(tempCrcl2[0])
oriConst2 = mc.orientConstraint(jnt2, ntjnt2, mo=True)
mc.connectAttr("%s.ox" % rev, "%s.w0" % oriConst2[0])
tempCrcl3 = mc.circle(n="%s_tempCircle3" % side)
mc.delete(tempCrcl3, ch=True)
mc.rotate(90, 0, 0, "%s.cv[0:9]" % tempCrcl3[0], r=1)
mc.scale(1.2, .6, .3, "%s.cv[0:9]" % tempCrcl3[0], r=1)
mc.parent("%sShape" % tempCrcl3[0], ntjnt3, s=True, r=True)
mc.select(cl=True)
mc.delete(tempCrcl3[0])
oriConst3 = mc.orientConstraint(jnt3, ntjnt3, mo=True)
mc.connectAttr("%s.ox" % rev, "%s.w0" % oriConst3[0])
tempCrcl4 = mc.circle(n="%s_tempCircle4" % side)
mc.delete(tempCrcl4, ch=True)
mc.rotate(90, 0, 0, "%s.cv[0:9]" % tempCrcl4[0], r=1)
mc.scale(1.2, .6, .3, "%s.cv[0:9]" % tempCrcl4[0], r=1)
mc.parent("%sShape" % tempCrcl4[0], ntjnt4, s=True, r=True)
mc.select(cl=True)
mc.delete(tempCrcl4[0])
oriConst4 = mc.orientConstraint(jnt4, ntjnt4, mo=True)
mc.connectAttr("%s.ox" % rev, "%s.w0" % oriConst4[0])
theSet = mc.sets(ntjnt1,
ntjnt2,
ntjnt3,
ntjnt4,
n="%s_thigh_NoTwistJoints_skin_set" % side)
mc.sets(theSet, add="skin_set")
def CollapseUVTile(shape, pUVtile):
cmds.select(clear=True)
print 'CollapseUVTile shape: {0}, pUVtile: {1}'.format(shape, pUVtile)
matched_faces = selUtils.GetFacesInUTile(shape, pUVtile)
cmds.polyEditUV(matched_faces, relative=True, uValue=(-1.0 * pUVtile))
cmds.select(clear=True)
def legsfollicles(side, section):
import maya.cmds as mc
# list important objects
constantName = ("%s_leg_%s_deform" % (side, section))
legSwitch = ("%s_leg_SW_ctrl" % side)
deformGRP = ("%s_leg_%s_deform_grp" % (side, section))
surface = ("%s_ns_no_twist" % constantName)
# first transformGeometry
tg0 = mc.createNode("transformGeometry", n="%s_tg0" % surface)
mc.connectAttr(
"%sShape.local" % surface,
"%s.ig" % tg0,
)
mc.connectAttr("%s.wim" % deformGRP, "%s.txf" % tg0)
# first curveFromSurfaceIso
cfsi0 = mc.createNode("curveFromSurfaceIso",
n="%s_cfsi0" % surface)
mc.connectAttr("%s.og" % tg0, "%s.is" % cfsi0)
mc.setAttr("%s.minValue" % cfsi0, 0)
mc.setAttr("%s.maxValue" % cfsi0, 1)
# second curveFromSurfaceIso
cfsi1 = mc.createNode("curveFromSurfaceIso",
n="%s_cfsi1" % surface)
mc.connectAttr("%s.og" % tg0, "%s.is" % cfsi1)
mc.setAttr("%s.minValue" % cfsi1, 0)
mc.setAttr("%s.maxValue" % cfsi1, 1)
mc.setAttr("%s.iv" % cfsi1, 1)
# first rebuildCurve
rc0 = mc.createNode("rebuildCurve", n="%s_rc0" % surface)
mc.connectAttr("%s.oc" % cfsi0, "%s.ic" % rc0)
mc.setAttr("%s.keepRange" % rc0, 0)
# second rebuildCurve
rc1 = mc.createNode("rebuildCurve", n="%s_rc1" % surface)
mc.connectAttr("%s.oc" % cfsi1, "%s.ic" % rc1)
mc.setAttr("%s.keepRange" % rc1, 0)
# evenspread switch
essw = mc.createNode("blendTwoAttr", n="%s_essw" % surface)
mc.connectAttr("%s.evenspread" % deformGRP, "%s.ab" % essw)
mc.setAttr("%s.i[0]" % essw, 1)
# first avgCurves
ac0 = mc.createNode("avgCurves", n="%s_ac0" % surface)
mc.connectAttr("%s.oc" % cfsi0, "%s.ic1" % ac0)
mc.connectAttr("%s.oc" % rc0, "%s.ic2" % ac0)
mc.connectAttr("%s.o" % essw, "%s.w1" % ac0)
mc.connectAttr("%s.evenspread" % deformGRP, "%s.w2" % ac0)
mc.setAttr("%s.automaticWeight" % ac0, 0)
# second avgCurves
ac1 = mc.createNode("avgCurves", n="%s_ac1" % surface)
mc.connectAttr("%s.oc" % cfsi1, "%s.ic1" % ac1)
mc.connectAttr("%s.oc" % rc1, "%s.ic2" % ac1)
mc.connectAttr("%s.o" % essw, "%s.w1" % ac1)
mc.connectAttr("%s.evenspread" % deformGRP, "%s.w2" % ac1)
mc.setAttr("%s.automaticWeight" % ac1, 0)
# loft
loft = mc.createNode("loft", n="%s_loft" % surface)
mc.connectAttr("%s.oc" % ac0, "%s.ic[0]" % loft)
mc.connectAttr("%s.oc" % ac1, "%s.ic[1]" % loft)
mc.setAttr("%s.uniform" % loft, 1)
mc.setAttr("%s.autoReverse" % loft, 0)
mc.setAttr("%s.reverseSurfaceNormals" % loft, 1)
# second transformGeometry
tg1 = mc.createNode("transformGeometry", n="%s_tg1" % surface)
mc.connectAttr(
"%s.os" % loft,
"%s.ig" % tg1,
)
mc.connectAttr("%s.wm[0]" % deformGRP, "%s.txf" % tg1)
# --------------------------
# follicles
# first follicle
fol1 = mc.createNode("follicle", n="%s_att_01Shape" % surface)
mc.connectAttr("%s.og" % tg1, "%s.is" % fol1)
mc.connectAttr("%s.outRotate" % fol1, "%s_att_01.r" % surface)
mc.connectAttr("%s.outTranslate" % fol1, "%s_att_01.t" % surface)
mc.parent("%s_att_01" % surface, deformGRP)
mc.setAttr("%s.parameterU" % fol1, 0.125)
mc.setAttr("%s.parameterV" % fol1, 0.5)
mc.setAttr("%s_att_01.inheritsTransform" % surface, 0)
# second follicle
fol2 = mc.createNode("follicle", n="%s_att_02Shape" % surface)
mc.connectAttr("%s.og" % tg1, "%s.is" % fol2)
mc.connectAttr("%s.outRotate" % fol2, "%s_att_02.r" % surface)
mc.connectAttr("%s.outTranslate" % fol2, "%s_att_02.t" % surface)
mc.parent("%s_att_02" % surface, deformGRP)
mc.setAttr("%s.parameterU" % fol2, 0.375)
mc.setAttr("%s.parameterV" % fol2, 0.5)
mc.setAttr("%s_att_02.inheritsTransform" % surface, 0)
# third follicle
fol3 = mc.createNode("follicle", n="%s_att_03Shape" % surface)
mc.connectAttr("%s.og" % tg1, "%s.is" % fol3)
mc.connectAttr("%s.outRotate" % fol3, "%s_att_03.r" % surface)
mc.connectAttr("%s.outTranslate" % fol3, "%s_att_03.t" % surface)
mc.parent("%s_att_03" % surface, deformGRP)
mc.setAttr("%s.parameterU" % fol3, 0.625)
mc.setAttr("%s.parameterV" % fol3, 0.5)
mc.setAttr("%s_att_03.inheritsTransform" % surface, 0)
# fourth follicle
fol4 = mc.createNode("follicle", n="%s_att_04Shape" % surface)
mc.connectAttr("%s.og" % tg1, "%s.is" % fol4)
mc.connectAttr("%s.outRotate" % fol4, "%s_att_04.r" % surface)
mc.connectAttr("%s.outTranslate" % fol4, "%s_att_04.t" % surface)
mc.parent("%s_att_04" % surface, deformGRP)
mc.setAttr("%s.parameterU" % fol4, 0.875)
mc.setAttr("%s.parameterV" % fol4, 0.5)
mc.setAttr("%s_att_04.inheritsTransform" % surface, 0)
# --------------------------
# post follicle actions
# first orig joint
jntOrig1 = mc.duplicate(
"%s_leg_%s_deform_SKN_01_orig" % (side, section),
po=True,
n="%s_leg_%s_no_twist_SKN_01_orig" % (side, section),
ic=False)
mc.setAttr("%s.v" % jntOrig1[0], k=True, cb=True, l=False)
mc.setAttr("%s.v" % jntOrig1[0], 1)
mc.setAttr("%s.ds" % jntOrig1[0], 0)
jnt1 = mc.joint(n="%s_leg_%s_no_twist_SKN_01" % (side, section))
mc.parent(jnt1, jntOrig1[0], r=True)
mc.select(cl=True)
jntCtrl1 = mc.joint(n="%s_leg_%s_no_twist_ctrl_01" %
(side, section))
mc.parent(jntCtrl1, jntOrig1[0], r=True)
mc.parent(jntOrig1[0], "%s_att_01" % surface, r=True)
mc.parent(jntOrig1[0], deformGRP)
mc.setAttr("%s.drawStyle" % jntOrig1[0], 2)
mc.setAttr("%s.drawStyle" % jnt1, 2)
mc.setAttr("%s.drawStyle" % jntCtrl1, 2)
# first multMatrix
mm1 = mc.createNode("multMatrix",
n="%s_leg_%s_no_twist_SKN_01_mm" %
(side, section))
mc.connectAttr("%s_att_01.m" % surface, "%s.i[0]" % mm1)
mc.connectAttr("%s.pim" % jntOrig1[0], "%s.i[1]" % mm1)
# first decomposeMatrix
dm1 = mc.createNode("decomposeMatrix",
n="%s_leg_%s_no_twist_SKN_01_dm" %
(side, section))
mc.connectAttr("%s.o" % mm1, "%s.inputMatrix" % dm1)
mc.connectAttr("%s.outputRotate" % dm1, "%s.r" % jntOrig1[0])
mc.connectAttr("%s.outputTranslate" % dm1, "%s.t" % jntOrig1[0])
mc.setAttr("%s.jo" % jntOrig1[0], 0, 0, 0)
# connect joints accordingly
mc.connectAttr("%s.t" % jntCtrl1, "%s.t" % jnt1)
mc.connectAttr("%s.r" % jntCtrl1, "%s.r" % jnt1)
mc.connectAttr("%s.s" % jntCtrl1, "%s.s" % jnt1)
mc.connectAttr("%s.ro" % jntCtrl1, "%s.ro" % jnt1)
# second orig joint
jntOrig2 = mc.duplicate(
"%s_leg_%s_deform_SKN_02_orig" % (side, section),
po=True,
n="%s_leg_%s_no_twist_SKN_02_orig" % (side, section),
ic=False)
mc.setAttr("%s.v" % jntOrig2[0], k=True, cb=True, l=False)
mc.setAttr("%s.v" % jntOrig2[0], 1)
mc.setAttr("%s.ds" % jntOrig2[0], 0)
jnt2 = mc.joint(n="%s_leg_%s_no_twist_SKN_02" % (side, section))
mc.parent(jnt2, jntOrig2[0], r=True)
mc.select(cl=True)
jntCtrl2 = mc.joint(n="%s_leg_%s_no_twist_ctrl_02" %
(side, section))
mc.parent(jntCtrl2, jntOrig2[0], r=True)
mc.parent(jntOrig2[0], "%s_att_02" % surface, r=True)
mc.parent(jntOrig2[0], deformGRP)
mc.setAttr("%s.drawStyle" % jntOrig2[0], 2)
mc.setAttr("%s.drawStyle" % jnt2, 2)
mc.setAttr("%s.drawStyle" % jntCtrl2, 2)
# second multMatrix
mm2 = mc.createNode("multMatrix",
n="%s_leg_%s_no_twist_SKN_02_mm" %
(side, section))
mc.connectAttr("%s_att_02.m" % surface, "%s.i[0]" % mm2)
mc.connectAttr("%s.pim" % jntOrig2[0], "%s.i[1]" % mm2)
# second decomposeMatrix
dm2 = mc.createNode("decomposeMatrix",
n="%s_leg_%s_no_twist_SKN_02_dm" %
(side, section))
mc.connectAttr("%s.o" % mm2, "%s.inputMatrix" % dm2)
mc.connectAttr("%s.outputRotate" % dm2, "%s.r" % jntOrig2[0])
mc.connectAttr("%s.outputTranslate" % dm2, "%s.t" % jntOrig2[0])
mc.setAttr("%s.jo" % jntOrig2[0], 0, 0, 0)
# connect joints accordingly
mc.connectAttr("%s.t" % jntCtrl2, "%s.t" % jnt2)
mc.connectAttr("%s.r" % jntCtrl2, "%s.r" % jnt2)
mc.connectAttr("%s.s" % jntCtrl2, "%s.s" % jnt2)
mc.connectAttr("%s.ro" % jntCtrl2, "%s.ro" % jnt2)
# third orig joint
jntOrig3 = mc.duplicate(
"%s_leg_%s_deform_SKN_03_orig" % (side, section),
po=True,
n="%s_leg_%s_no_twist_SKN_03_orig" % (side, section),
ic=False)
mc.setAttr("%s.v" % jntOrig3[0], k=True, cb=True, l=False)
mc.setAttr("%s.v" % jntOrig3[0], 1)
mc.setAttr("%s.ds" % jntOrig3[0], 0)
jnt3 = mc.joint(n="%s_leg_%s_no_twist_SKN_03" % (side, section))
mc.parent(jnt3, jntOrig3[0], r=True)
mc.select(cl=True)
jntCtrl3 = mc.joint(n="%s_leg_%s_no_twist_ctrl_03" %
(side, section))
mc.parent(jntCtrl3, jntOrig3[0], r=True)
mc.parent(jntOrig3[0], "%s_att_03" % surface, r=True)
mc.parent(jntOrig3[0], deformGRP)
mc.setAttr("%s.drawStyle" % jntOrig3[0], 2)
mc.setAttr("%s.drawStyle" % jnt3, 2)
mc.setAttr("%s.drawStyle" % jntCtrl3, 2)
# third multMatrix
mm3 = mc.createNode("multMatrix",
n="%s_leg_%s_no_twist_SKN_03_mm" %
(side, section))
mc.connectAttr("%s_att_03.m" % surface, "%s.i[0]" % mm3)
mc.connectAttr("%s.pim" % jntOrig3[0], "%s.i[1]" % mm3)
# third decomposeMatrix
dm3 = mc.createNode("decomposeMatrix",
n="%s_leg_%s_no_twist_SKN_03_dm" %
(side, section))
mc.connectAttr("%s.o" % mm3, "%s.inputMatrix" % dm3)
mc.connectAttr("%s.outputRotate" % dm3, "%s.r" % jntOrig3[0])
mc.connectAttr("%s.outputTranslate" % dm3, "%s.t" % jntOrig3[0])
mc.setAttr("%s.jo" % jntOrig3[0], 0, 0, 0)
# connect joints accordingly
mc.connectAttr("%s.t" % jntCtrl3, "%s.t" % jnt3)
mc.connectAttr("%s.r" % jntCtrl3, "%s.r" % jnt3)
mc.connectAttr("%s.s" % jntCtrl3, "%s.s" % jnt3)
mc.connectAttr("%s.ro" % jntCtrl3, "%s.ro" % jnt3)
# fourth orig joint
jntOrig4 = mc.duplicate(
"%s_leg_%s_deform_SKN_04_orig" % (side, section),
po=True,
n="%s_leg_%s_no_twist_SKN_04_orig" % (side, section),
ic=False)
mc.setAttr("%s.v" % jntOrig4[0], k=True, cb=True, l=False)
mc.setAttr("%s.v" % jntOrig4[0], 1)
mc.setAttr("%s.ds" % jntOrig4[0], 0)
jnt4 = mc.joint(n="%s_leg_%s_no_twist_SKN_04" % (side, section))
mc.parent(jnt4, jntOrig4[0], r=True)
mc.select(cl=True)
jntCtrl4 = mc.joint(n="%s_leg_%s_no_twist_ctrl_04" %
(side, section))
mc.parent(jntCtrl4, jntOrig4[0], r=True)
mc.parent(jntOrig4[0], "%s_att_04" % surface, r=True)
mc.parent(jntOrig4[0], deformGRP)
mc.setAttr("%s.drawStyle" % jntOrig4[0], 2)
mc.setAttr("%s.drawStyle" % jnt4, 2)
mc.setAttr("%s.drawStyle" % jntCtrl4, 2)
# fourth multMatrix
mm4 = mc.createNode("multMatrix",
n="%s_leg_%s_no_twist_SKN_04_mm" %
(side, section))
mc.connectAttr("%s_att_04.m" % surface, "%s.i[0]" % mm4)
mc.connectAttr("%s.pim" % jntOrig4[0], "%s.i[1]" % mm4)
# fourth decomposeMatrix
dm4 = mc.createNode("decomposeMatrix",
n="%s_leg_%s_no_twist_SKN_04_dm" %
(side, section))
mc.connectAttr("%s.o" % mm4, "%s.inputMatrix" % dm4)
mc.connectAttr("%s.outputRotate" % dm4, "%s.r" % jntOrig4[0])
mc.connectAttr("%s.outputTranslate" % dm4, "%s.t" % jntOrig4[0])
mc.setAttr("%s.jo" % jntOrig4[0], 0, 0, 0)
# connect joints accordingly
mc.connectAttr("%s.t" % jntCtrl4, "%s.t" % jnt4)
mc.connectAttr("%s.r" % jntCtrl4, "%s.r" % jnt4)
mc.connectAttr("%s.s" % jntCtrl4, "%s.s" % jnt4)
mc.connectAttr("%s.ro" % jntCtrl4, "%s.ro" % jnt4)
def MakeBendCorrectiveJoint(name, referenceJnt, parentJnt, donorJntsList=None):
if donorJntsList is None:
donorJntsList = [parentJnt, referenceJnt]
skinClusters = mayaUtils.GetAllSkinClustersInfluencedByJoints(
donorJntsList, True)
print 'Creating bend corrective joint {0} parented: {1}, referenced: {2}, skins: {3}'.format(
name, parentJnt, referenceJnt, skinClusters)
cmds.select(clear=True)
cmds.select(referenceJnt)
cmds.joint(name=name)
if not parentJnt == referenceJnt:
cmds.parent(name, parentJnt)
cmds.orientConstraint(donorJntsList, name, maintainOffset=True)
cmds.select(clear=True)
for skinClusterName in skinClusters:
cmds.skinCluster(skinClusterName,
e=True,
selectInfluenceVerts=donorJntsList[0])
sel = cmds.ls(selection=True, flatten=True)
onlyVertices = cmds.filterExpand(sel, sm=31, expand=True)
intersectedVerts = []
prune_value = 0.001
for v in onlyVertices:
if cmds.skinPercent(
skinClusterName, v, transform=donorJntsList[0],
query=True) > prune_value:
if cmds.skinPercent(
skinClusterName, v, transform=donorJntsList[1],
query=True) > prune_value:
intersectedVerts.append(v)
cmds.skinCluster(skinClusterName,
e=True,
addInfluence=name,
weight=0.0)
cmds.select(clear=True)
for v in intersectedVerts:
sumNewWeight = 0
transformValueList = []
oldWeights = []
jointsCount = len(donorJntsList)
for j in donorJntsList:
w = cmds.skinPercent(skinClusterName,
v,
transform=j,
query=True)
#print 'skinPercent Vert: {0} j:{1} w:{2}'.format(v, j, w)
oldWeights.append(w)
totalWeight = sum(oldWeights)
for i in range(0, jointsCount):
newWeight = oldWeights[i] * hazMath.SmoothStep01(
hazMath.Clamp01(oldWeights[i] / totalWeight))
sumNewWeight += newWeight
transformValueList.append([donorJntsList[i], newWeight])
totalWeight -= prune_value
transformValueList.append([
name,
hazMath.Clamp(totalWeight - sumNewWeight, 0.0, totalWeight)
])
cmds.skinPercent(skinClusterName,
v,
transformValue=transformValueList)
