Esempio n. 1
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def split_joint (joint, splits):
    #check if joint have child joint
    if not joint.getChildren(type='joint'):
        return
    
    prefix = joint.name()
    
    # Determine Amount of Spacing
    endJoint = joint.getChildren(type='joint')[0]
    spacing = endJoint.tx.get() / (splits + 1)

    # Split Joints
    split_joints = []
    radius = joint.radius.get()
    
    for x in range (1, splits + 1) :
        newJoint = pm.PyNode(pm.insertJoint(joint))
        newJoint.radius.set(radius)
        newJoint.rename("%s_split_%d" %(prefix, x))
        newJoint.tx.set(spacing)

        split_joints.append(newJoint)
        joint = newJoint

    endJoint.tx.set(spacing)
    
    return split_joints
Esempio n. 2
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def placeJointChain(startLoc, endLoc, numJoints=3, 
                      parent=None, name='jointChain'):
    joints = []
    startJoint = placeJoint(
            getWsLocation(startLoc),
            name = '%s%02d' % (name, 1),
            parent = parent)
    endJoint = placeJoint(
            getWsLocation(endLoc),
            name = '%s%02d' % (name, numJoints),
            parent = startJoint)
    dist = endJoint.getTranslation()
    dist = dist / float(numJoints-1)

    joints.append(startJoint)
    for i in range(2,numJoints):
        insideJoint = pm.insertJoint(joints[-1])
        insideJoint = toPmNodes(insideJoint)[0]
        insideJoint = pm.rename(insideJoint,
                                '%s%02d' % (name, i))
        insideJoint.translateBy(dist)
        endJoint.translateBy(-dist)
        joints.append(insideJoint)
    joints.append(endJoint)

    return joints
Esempio n. 3
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 def addManyJoint(firstJoint, secondJoint, num=1):
     jointRadius = firstJoint.getRadius()
     firstPoint = firstJoint.getTranslation(space='world')
     secondPoint = secondJoint.getTranslation(space='world')
     for n in range(0,num):
         newJoint = pm.insertJoint(firstJoint)
         #追加したジョイントの位置を計算する
         px = secondPoint[0] + (((firstPoint[0]-secondPoint[0])/(num+1))*(n+1))
         py = secondPoint[1] + (((firstPoint[1]-secondPoint[1])/(num+1))*(n+1))
         pz = secondPoint[2] + (((firstPoint[2]-secondPoint[2])/(num+1))*(n+1))
         #newJointはunicode型なのでpyMelの機能が使えない。ここではcmdsを使用する
         cmds.joint(newJoint, e=True, component=True, position=[px, py, pz], radius=jointRadius)
Esempio n. 4
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 def split_joints(n=5):
     selection = ls(selection=True)
     if JointSplitter.validate_for_split_joint(selection):
         first_joint = ls(selection=True)[0]
         fj = pm.joint(pm.general.ls(selection=True)[0], query=True, position=True)
         lj = pm.joint(pm.general.ls(selection=True)[1], query=True, position=True)
         fj_vector = dt.Vector(fj[0], fj[1], fj[2])
         lj_vector = dt.Vector(lj[0], lj[1], lj[2])
         new_joint = 0
         pm.select(deselect=True)
         for i in range(0, n - 1):
             split_point = fj_vector.__mul__((n - i - 1.0) / n).__add__(lj_vector.__mul__(i + 1.0) / n)
             new_joint = pm.insertJoint(new_joint if i > 0 else first_joint)
             pm.joint(new_joint, edit=True, component=True, position=split_point)
Esempio n. 5
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 def split_joints(first_joint, second_joint, n=5):
     if not (first_joint or second_joint):
         return -1
     JointSplitter.flatten_joints(first_joint, second_joint)
     fj = pm.joint(first_joint, query=True, position=True)
     lj = pm.joint(second_joint, query=True, position=True)
     fj_vector = dt.Vector(fj[0], fj[1], fj[2])
     lj_vector = dt.Vector(lj[0], lj[1], lj[2])
     new_joint = None
     pm.select(deselect=True)
     for i in range(0, n - 1):
         split_point = fj_vector.__mul__(
             (n - i - 1.0) / n).__add__(lj_vector.__mul__(i + 1.0) / n)
         new_joint = pm.insertJoint(new_joint if i > 0 else first_joint)
         pm.joint(new_joint,
                  edit=True,
                  component=True,
                  position=split_point)
     pm.select(d=True)
Esempio n. 6
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    def makeJointHair(self, sel, hairSystem):

        simDuped = pm.duplicate(sel, n='sim_%s' % sel.nodeName())[0]
        mixDuped = pm.duplicate(sel, n='mix_%s' % sel.nodeName())[0]
        wgtDuped = pm.duplicate(sel, n='weight_%s' % sel.nodeName())[0]

        selJointList = self.getJointChainList(sel)
        simJointList = self.getJointChainList(simDuped)
        mixJointList = self.getJointChainList(mixDuped)
        wgtJointList = self.getJointChainList(wgtDuped)

        if not (selJointList and simJointList and mixJointList):
            return False

        num = len(selJointList)
        pos = sel.getTranslation(space='world')
        ctrlGrp = pm.group(n='%s_ctrls#' % sel.nodeName(), em=1)

        axis, circle = self.makeXformController(
            '%s_top_ctrl#' % sel.nodeName(),
            '%s_top_ctrl_axis#' % sel.nodeName(), selJointList[0])
        circle.addAttr('space',
                       at='enum',
                       en='World:Local',
                       k=1,
                       dv=self.dnspRBGval - 1)
        circle.addAttr('ctrl_size', at='double', k=1, dv=1.0)
        circle.attr('ctrl_size') >> circle.attr('scaleX')
        circle.attr('ctrl_size') >> circle.attr('scaleY')
        circle.attr('ctrl_size') >> circle.attr('scaleZ')

        pntMatrix = []

        skclList = list(set(sel.outputs(type='skinCluster')))

        for i in xrange(num):

            if i != 0:
                pm.rename(simJointList[i],
                          'sim_%s' % simJointList[i].nodeName())
                pm.rename(mixJointList[i],
                          'mix_%s' % mixJointList[i].nodeName())

            pos = selJointList[i].getTranslation(space='world')
            ofstJoint = pm.rename(
                pm.insertJoint(mixJointList[i]),
                mixJointList[i].nodeName().replace('mix', 'offset'))

            pntMatrix.append(pos)

            attrList = ['tx', 'ty', 'tz', 'rx', 'ry', 'rz']
            for attr in attrList:
                simJointList[i].attr(attr) >> mixJointList[i].attr(attr)

            pm.parentConstraint(ofstJoint, selJointList[i], mo=True)

            mixJointList[i].attr('radius').set(0.0)
            ofstJoint.attr('radius').set(0.0)

            if not (i == num - 1 and not self.pctlCBXval):
                ''' # If on, no controllers will be created to the joints which does't have any skinCluster
				for skcl in skclList:
					if selJointList[i] in skcl.getInfluence():
						break
				else:
					continue
				'''

                if self.ctshRBGval == 1:
                    ctrl = self.makeCircleController(
                        '%s_ctrl' % selJointList[i].nodeName())
                elif self.ctshRBGval == 2:
                    ctrl = self.makePinController('%s_ctrl' %
                                                  selJointList[i].nodeName())
                elif self.ctshRBGval == 3:
                    ctrl = self.makeOctaController('%s_ctrl' %
                                                   selJointList[i].nodeName())

                ctrl.attr('overrideEnabled').set(1)
                ctrl.attr('overrideColor').set((self.colrPLTval))

                ctrlAxis = pm.group(ctrl,
                                    n='%s_ctrl_axis' %
                                    selJointList[i].nodeName())
                ctrlAxis.attr('rotatePivot').set([0, 0, 0])
                ctrlAxis.attr('scalePivot').set([0, 0, 0])

                circle.attr('ctrl_size') >> ctrl.attr('scaleX')
                circle.attr('ctrl_size') >> ctrl.attr('scaleY')
                circle.attr('ctrl_size') >> ctrl.attr('scaleZ')

                pm.parentConstraint(mixJointList[i], ctrlAxis)
                pm.parentConstraint(ctrl, ofstJoint)
                pm.parent(ctrlAxis, ctrlGrp)

            # Pour weights to simJointList temporarily

            for skcl in skclList:

                if selJointList[i] in skcl.getInfluence():

                    skcl.addInfluence(wgtJointList[i], wt=0)
                    inflList = skcl.getInfluence()

                    isMaintainMax = skcl.attr('maintainMaxInfluences').get()
                    maxInfl = skcl.attr('maxInfluences').get()

                    isFullInfl = False
                    if isMaintainMax and maxInfl == len(inflList):
                        isFullInfl = True
                        skcl.attr('maintainMaxInfluences').set(False)

                    for infl in inflList:
                        if infl == selJointList[i] or infl == wgtJointList[i]:
                            infl.attr('lockInfluenceWeights').set(False)
                        else:
                            infl.attr('lockInfluenceWeights').set(True)

                    for geo in skcl.getGeometry():
                        pm.skinPercent(skcl,
                                       geo.verts,
                                       nrm=True,
                                       tv=[selJointList[i], 0])

                    skcl.removeInfluence(selJointList[i])

                    if isFullInfl:
                        skcl.attr('maintainMaxInfluences').set(True)

        crv1d = pm.curve(d=1, p=pntMatrix)
        crv = pm.fitBspline(crv1d, ch=1, tol=0.001)

        follicle, hcrv, hairSystem = self.assignHair(crv, hairSystem)

        follicleGrp = follicle.getParent()
        curveGrp = hcrv.getParent()

        ikhandle = pm.ikHandle(sj=simJointList[0],
                               ee=simJointList[num - 1],
                               c=hcrv,
                               createCurve=0,
                               solver='ikSplineSolver')[0]

        # Pour back

        for i in xrange(num):

            for skcl in skclList:

                if wgtJointList[i] in skcl.getInfluence():

                    skcl.addInfluence(selJointList[i], wt=0)
                    inflList = skcl.getInfluence()

                    isMaintainMax = skcl.attr('maintainMaxInfluences').get()
                    maxInfl = skcl.attr('maxInfluences').get()

                    isFullInfl = False
                    if isMaintainMax and maxInfl == len(inflList):
                        isFullInfl = True
                        skcl.attr('maintainMaxInfluences').set(False)

                    for infl in inflList:
                        if infl == selJointList[i] or infl == wgtJointList[i]:
                            infl.attr('lockInfluenceWeights').set(False)
                        else:
                            infl.attr('lockInfluenceWeights').set(True)

                    for geo in skcl.getGeometry():
                        pm.skinPercent(skcl,
                                       geo.verts,
                                       nrm=True,
                                       tv=[wgtJointList[i], 0])

                    for infl in inflList:
                        infl.attr('lockInfluenceWeights').set(False)

                    attrList = [
                        wgtJointList[i].attr('message'),
                        wgtJointList[i].attr('bindPose')
                    ]
                    for attr in attrList:
                        for dst in pm.connectionInfo(attr, dfs=True):
                            dst = pm.Attribute(dst)
                            if dst.node().type() == 'dagPose':
                                attr // dst

                    if isFullInfl:
                        skcl.attr('maintainMaxInfluences').set(True)

        pm.delete(wgtJointList)

        simGrp = pm.group(simJointList[0], follicle, n='sim_joints#')
        xformer = pm.group(simGrp,
                           mixJointList[0],
                           selJointList[0],
                           n='%s_transformer#' % sel.nodeName())

        hcrv.attr('scalePivot').set(
            selJointList[0].getTranslation(space='world'))
        hcrv.attr('rotatePivot').set(
            selJointList[0].getTranslation(space='world'))
        ctrlGrp.attr('scalePivot').set(
            selJointList[0].getTranslation(space='world'))
        ctrlGrp.attr('rotatePivot').set(
            selJointList[0].getTranslation(space='world'))
        simGrp.attr('scalePivot').set(
            selJointList[0].getTranslation(space='world'))
        simGrp.attr('rotatePivot').set(
            selJointList[0].getTranslation(space='world'))

        mixJointList[0].attr('template').set(1)
        hcrv.attr('template').set(1)
        hairSystem.attr('iterations').set(20)
        xformer.attr('scalePivot').set(axis.getTranslation())
        xformer.attr('rotatePivot').set(axis.getTranslation())

        wcnst = pm.parentConstraint(circle, hcrv, mo=True)
        lcnst = pm.parentConstraint(circle, xformer, mo=True)

        rev = pm.shadingNode('reverse', asUtility=True)
        circle.attr('space') >> wcnst.attr('%sW0' % wcnst.getTargetList()[0])
        circle.attr('space') >> rev.attr('inputX')
        rev.attr('outputX') >> lcnst.attr('%sW0' % lcnst.getTargetList()[0])

        pm.delete(follicleGrp, curveGrp, crv1d)
        pm.hide(simGrp)

        crvGrp = self.makeGroupIfNotExist('hairSystemOutputCurves', 0)
        ikGrp = self.makeGroupIfNotExist('hairSystemIKHandles', 1)
        nodesGrp = self.makeGroupIfNotExist('hairSystemNodes', 1)

        pm.parent(hcrv, crvGrp)
        pm.parent(ikhandle, ikGrp)

        if hairSystem.getParent() != nodesGrp:
            pm.parent(hairSystem, nodesGrp)

        if not pm.objExists(self.topName):
            topGrp = pm.group(n=self.topName, em=1)
            pm.parent(nodesGrp, ikGrp, crvGrp, xformer, axis, ctrlGrp, topGrp)
        else:
            pm.parent(xformer, axis, ctrlGrp, self.topName)

        topNode = pm.PyNode(self.topName)

        self.lockXformAttrs(topNode, False)
        self.lockXformAttrs(ctrlGrp, False)
        self.lockXformAttrs(crvGrp, False)
        self.lockXformAttrs(ikGrp, False)
        self.lockXformAttrs(nodesGrp, False)

        pm.select(topNode, r=1)

        self.selList.pop(0)

        windowName = 'hairSystem_Window'

        if pm.window(windowName, ex=1):
            pm.deleteUI(windowName)

        if self.selList:
            self.dialog(self.selList[0])

        pm.displayInfo('"Make Joint Hair" has been successfully done.')

        return True
Esempio n. 7
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def createIKspline(IK_chain = None, ikSpineGrp = None):
    """
    maj:
     x-- add pelvis control
     -- add follow on mid ctrl
     
    debug: 
     -- orient ik mid ctrl in the same orientation then other controllers
     
    """
    
    # insert joints
#     global IKjointList, dwCtrl,upCtrl
    
    IKjointList = []
    jointIt = 3
    for jnt in IK_chain:
        IKjointList.append(jnt)
        child = jnt.getChildren()
        if len(child)>0:
            num = jointIt
            rad = pm.joint(jnt, query = True , radius = True)[0]
            dist = pm.joint(child[0], query = True , relative = True, position = True)[0]
            gap = dist/(num)
            for i in range((num-1),0,-1):
                newJnt = pm.insertJoint(jnt)
                pm.joint( newJnt, edit = True,component = True, relative = True, radius = rad, position = ((gap*i),0,0))
                IKjointList.append(newJnt)
    
    # create ikhandle
    IKspine = pm.ikHandle(solver = "ikSplineSolver", name = "IKspine", simplifyCurve = True, startJoint = IK_chain[0], endEffector = IK_chain[(len(IK_chain)-1)], createCurve = True, numSpans = 4)
    IKhandle = IKspine[0]
    IKcurve = IKspine[2]
    
    IKhandle.setParent(ikSpineGrp)
    curveJointList = pm.ikHandle(IKhandle, query = True, jointList = True)
    
    # create clusters on point
    cvsList = (IKcurve.getShape()).getCVs()
    
    clusterGrp = pm.group(name = "cluster_grp", empty = True)
    clusterGrp.setParent(ikSpineGrp)
    
    ctrlGrp = pm.group(name = "IK_ctrls_grp", empty = True)
    ctrlGrp.setParent(ikSpineGrp)
    
    # parent cluster to sphere
    ctrlList = []
    clusterList = []
    for i,cv in enumerate(cvsList):
        cluster = pm.cluster("curve1.cv[%s]" % i)
        cluster[0].setAttr("relative", 1)
        tmpCluster = cluster[1]
        tmpCluster.setParent(clusterGrp)
        clusterList.append(tmpCluster)
        
        oneCtrl = helpers.createNurbsSphere(rad = 0.5)
        ctrlList.append(oneCtrl)
    #     oneCtrl.setParent(ctrlGrp)
        tmpPoint = pm.pointConstraint(tmpCluster, oneCtrl)
        pm.delete(tmpPoint)
        pm.pointConstraint(oneCtrl, tmpCluster)
        
        
    for c in ctrlList:
        c.setParent(ctrlGrp)
    
    ctrlListGrp = helpers.insertGroups(ctrlList)
    
    # create main ctrls
    # orient up and down ctrls as joint selection
    upCtrlGrp, upCtrl = helpers.createOneCircle([1,0,0], sel = sel[0], rad = 4, suf= "_IK_ctrl")
    dwCtrlGrp, dwCtrl = helpers.createOneCircle([1,0,0], sel = sel[len(sel)-1], rad = 4, suf= "_IK_ctrl")
    idMid =  int((pm.datatypes.round(float(len(ctrlListGrp))/2)) - 1)
    midCtrlGrp, midCtrl = helpers.createOneCircle([0,1,0], sel = ctrlList[idMid], rad = 4, suf= "_IK_ctrl")
    
    upCtrlGrp.setParent(ctrlGrp)
    dwCtrlGrp.setParent(ctrlGrp)
    midCtrlGrp.setParent(ctrlGrp)
    
    upLoc = helpers.createOneLoc(parentToWorld = False, s = upCtrl)
    dwLoc = helpers.createOneLoc(parentToWorld = False, s = dwCtrl)
    upLoc.setAttr("tz", 2)
    dwLoc.setAttr("tz", 2)
    
    # parent sphere ctrls to main ctrls
    ctrlListGrp[0].setParent(upCtrl)
    ctrlListGrp[1].setParent(upCtrl)
    ctrlListGrp[idMid - 1].setParent(midCtrl)
    ctrlListGrp[idMid].setParent(midCtrl)
    ctrlListGrp[idMid + 1].setParent(midCtrl)
    ctrlListGrp[(len(ctrlListGrp)-2)].setParent(dwCtrl)
    ctrlListGrp[(len(ctrlListGrp)-1)].setParent(dwCtrl)
    
    # add twist
    IKhandle.setAttr("dTwistControlEnable", 1)
    IKhandle.setAttr("dWorldUpType", 2)
    IKhandle.setAttr("dWorldUpAxis", 3)
    
    pm.connectAttr(upLoc.worldMatrix, IKhandle.dWorldUpMatrix, force = True)
    pm.connectAttr(dwLoc.worldMatrix, IKhandle.dWorldUpMatrixEnd, force = True)
    
    #### add stretch
    # add parameters on upper control
    pm.addAttr(dwCtrl, longName  = "________", attributeType  = "enum", enumName = "CTRLS:")
    pm.setAttr(dwCtrl.________, keyable = True, lock = True)
    
    
    # make stretch editable
    pm.addAttr(dwCtrl, longName  = "stretch", attributeType  = "double", min = 0, max = 1, dv = 0) 
#     pm.addAttr(dwCtrl, longName  = "squash", attributeType  = "double", min = 0, max = 1, dv = 0)
    pm.addAttr(dwCtrl, longName  = "followJoint", attributeType  = "double", min = 0, max = 1, dv = 1)
    pm.addAttr(dwCtrl, longName  = "followCtrl", attributeType  = "double", min = 0, max = 1, dv = 0)
    
    pm.setAttr(dwCtrl.stretch, keyable = True)
#     pm.setAttr(dwCtrl.squash, keyable = True)
    pm.setAttr(dwCtrl.followJoint, keyable = True)
    pm.setAttr(dwCtrl.followCtrl, keyable = True)
    
    subFollowNode = pm.createNode('plusMinusAverage', name = "follow_mode_compense")
    subFollowNode.setAttr("input1D[0]", 1)
    subFollowNode.setAttr('operation', 2)
    pm.connectAttr(dwCtrl.followJoint, subFollowNode.input1D[1], f = True)
    pm.connectAttr(subFollowNode.output1D, dwCtrl.followCtrl, f = True)
    
    newJointsNum = (len(IKjointList))
    
    # add arclenght on curve
    arcLenNode = pm.arclen(IKcurve, ch = True)
    defaultSize = arcLenNode.getAttr("arcLength")
    
    # multiply/divide default size by current size
    mdNode = pm.createNode("multiplyDivide")
    mdNode.setAttr("operation", 2 )
    mdNode.setAttr("input2X", arcLenNode.getAttr("arcLength") )
    pm.connectAttr(arcLenNode.arcLength, mdNode.input1X)
    
    # average to calculate stretch addition : stretch - 1
    addStretchNode = pm.createNode("plusMinusAverage", name = "add_stretch")
    addStretchNode.setAttr("operation", 2)
    pm.connectAttr(mdNode.outputX, addStretchNode.input1D[0])
    addStretchNode.setAttr("input1D[1]", 1)
    
    # multiplydivide to mutiply stretch addition by strecth parameter
    stretchMultiplyNode = pm.createNode("multiplyDivide",  name = "multiply_stretch")
    pm.connectAttr(addStretchNode.output1D, stretchMultiplyNode.input1X)
    pm.connectAttr(dwCtrl.stretch, stretchMultiplyNode.input2X)
    
    # average to addition 1 + stretch addition
    addStretchFinalNode = pm.createNode("plusMinusAverage", name = "add_stretch")
    addStretchFinalNode.setAttr("operation", 1)
    pm.connectAttr(stretchMultiplyNode.outputX, addStretchFinalNode.input1D[0])
    addStretchFinalNode.setAttr("input1D[1]", 1)
    
    for jnt in IKjointList:
        jntNode =  (pm.PyNode(jnt))
        try:
            pm.connectAttr(addStretchFinalNode.output1D, jntNode.scaleX)
        except:
            print(Exception)
            
    ## add parametrable squash
    
    
    
    ## follow control on neck
    lastJoint = IKjointList[-1]
    IKfollowJnt = pm.duplicate(lastJoint, name = (lastJoint.nodeName() + "_follow"))[0]
    IKfollowJnt.setAttr("scaleX", 1)
    IKfollowJnt.setParent(ikSpineGrp)
    
    """
    tmp = IKfollowJnt.getParent()
    if tmp:
        tmp.setAttr("scaleX", 1)
        IKfollowJnt.setParent(world = True)
        pm.delete(tmp)
    """
    
    constrain = pm.parentConstraint(dwCtrl, IK_chain[len(IK_chain)-1], IKfollowJnt)
    
    for attr in pm.listAttr(constrain, visible = True, keyable= True):
                if 'IKW' in attr:
#                     print(attr)
                    pm.connectAttr(dwCtrl.followJoint, '%s.%s' % (constrain,attr))
                    ikFound = True
                elif 'ctrl' in attr:
#                     print(attr)
                    pm.connectAttr(dwCtrl.followCtrl, '%s.%s' % (constrain,attr))
                    
    
    ##### ik pelvis
    # follow control on pelvis
        # duplicate first joint as follow_pelvis_joint
    pelvisIKjoint = pm.duplicate(IKjointList[0], parentOnly = True, name = (IKjointList[0].nodeName() + "_pelvis_follow_joint"))[0]
    pelvisIKjoint.jointOrient.set([0,0,0])
    
        # duplicate down ctrl as pelvis ctrl
    pelvisIKctrlList = pm.duplicate(upCtrl, name = (upCtrl.nodeName() + "_pelvis"))
    pelvisIKctrl = pelvisIKctrlList[0]
    toDel = pm.listRelatives(pelvisIKctrl, children = True, type = "transform")
    pm.delete(toDel)
    

    
    manageCtrl.scaleShape(sel = pelvisIKctrl, scalX = True, scalY = True, scalZ = True, scale = 0.9)
    
        # parent pelvis ctrl under down ctrl
    pm.parent(pelvisIKctrl, upCtrl)
    helpers.createOneHelper(sel = pelvisIKctrl, freezeGrp = False, hierarchyParent = "insert")
    
        # add loc on  IKjointList[0]
    IKpelvisJointLocGrp, IKpelvisJointLoc = helpers.createOneHelper(type = "loc", sel = IKjointList[0], freezeGrp = False, hierarchyParent = "child")
        # add loc on  pelvis ctrl
    IKpelvisCtrlLocGrp, IKpelvisCtrlLoc = helpers.createOneHelper(type = "loc", sel = pelvisIKctrl, freezeGrp = False, hierarchyParent = "child")
        
        # parent constraint follow_pelvis_joint to locs
    IKpelvisConstraint = pm.parentConstraint(IKpelvisJointLoc, IKpelvisCtrlLoc, pelvisIKjoint)
    
        # add attributes on base controller
    pm.addAttr(upCtrl, ln =  "_______" , attributeType  = "enum", enumName = "CTRLS:")
    pm.addAttr(upCtrl, ln =  "followJoint" , at  = 'double', min = 0, max = 1, dv = 0)
    pm.addAttr(upCtrl, ln =  "followCtrl" , at  = 'double', min = 0, max = 1)
    
    pm.setAttr(upCtrl._______ , keyable = True, lock = True)
    pm.setAttr(upCtrl.followJoint, keyable = True)
    pm.setAttr(upCtrl.followCtrl, keyable = True)
    
    pelvisSubFollowNode = pm.createNode('plusMinusAverage', name = "pelvis_follow_mode_compense")
    pelvisSubFollowNode.setAttr("input1D[0]", 1)
    pelvisSubFollowNode.setAttr('operation', 2)
    pm.connectAttr(upCtrl.followJoint, pelvisSubFollowNode.input1D[1], f = True)
    pm.connectAttr(pelvisSubFollowNode.output1D, upCtrl.followCtrl, f = True)
    
        # connect attributes to constraint parent
    contraintList = pm.parentConstraint(IKpelvisConstraint, query = True, targetList = True )
    # pprint(contraintList)
    
    weightAliasList = pm.parentConstraint(IKpelvisConstraint, query = True, weightAliasList  = True )
    # pprint(weightAliasList)
    
    
    # pprint(IKpelvisJointLoc)
    
    for i,c in enumerate(contraintList):
        if c == IKpelvisJointLoc:
            pm.connectAttr(upCtrl.followJoint, weightAliasList[i] )
        elif c == IKpelvisCtrlLoc:
            pm.connectAttr(upCtrl.followCtrl, weightAliasList[i] )
        
        ## constraint deformation system to follow ik
        
    
    # return good array of ik joint to parent on
                    
    return IKfollowJnt, pelvisIKjoint
Esempio n. 8
0
	def bendyLimb( self , *args ):
		print 'ehm_leg........................bendyLimb'       
		
		#============================================================================
		# duplicate main leg joints and rename bendy joints
		
		self.segMainJnts = pm.duplicate (self.upLegJnt )

		# delete not joint nodes under the hierarchy if any
		extraShapes = pm.listRelatives (self.segMainJnts[0], ad=True )

		for extraShape in extraShapes :
			if not pm.objectType(extraShape) == "joint":
				pm.delete(extraShape)

		self.segMainJnt = pm.ls (self.segMainJnts[0] )[0]
		self.segMainJnts = pm.listRelatives (self.segMainJnts[0], ad=True )
		self.segMainJnts.append(self.segMainJnt)
		self.segMainJnts.reverse()


		#============================================================================
		# create locators for positioning and orienting "curvy_midCtrl"

		# upLeg_rev_loc
		upLeg_rev_loc =  pm.spaceLocator ( p = (0,0,0) )

		pm.parent ( upLeg_rev_loc , self.upLegJnt )
		pm.rename ( upLeg_rev_loc , self.side + "_upLeg_rev_loc" )

		upLeg_rev_loc.translate.translateX.set  ( self.dist + self.dist/20 ) 
		upLeg_rev_loc.translate.translateY.set  ( 0 )
		upLeg_rev_loc.translate.translateZ.set  ( (self.dist/200) )

		upLeg_rev_loc.rotate.set (0,0,0)


		
		#============================================================================
		# find the position of self.kneeJnt to create empty group for this loc
		# we can compensate the length of leg parts by scaling this group

		upLeg_rev_loc_grp = pm.group ( n = upLeg_rev_loc.name() + "_grp" )
		pm.xform ( upLeg_rev_loc_grp , ws=True , piv = self.kneePos)

		# we need to make this locator scalable. if not, we won't be able to scale upLeg or knee seperately
		upLeg_rev_loc_mdn = pm.createNode ("multiplyDivide" , n = upLeg_rev_loc.name() + "_mdn" )
		upLeg_rev_loc_mdn.operation.set ( 2 )
		upLeg_rev_loc_mdn.input1X.set ( 1 )

		self.upLegJnt.scaleX >>  upLeg_rev_loc_mdn.input2X

		upLeg_rev_loc_mdn.outputX >> upLeg_rev_loc_grp.scaleX

		
		#============================================================================
		# knee_rev_loc

		knee_rev_loc =  pm.spaceLocator ( p = (0,0,0) )
		pm.parent ( knee_rev_loc , self.kneeJnt )
		pm.rename ( knee_rev_loc , self.side + "_knee_rev_loc" )

		knee_rev_loc.translate.translateX.set (self.dist/-20)
		knee_rev_loc.translate.translateY.set ( 0 )
		knee_rev_loc.translate.translateZ.set (self.dist/200)

		knee_rev_loc.rotate.set (0,0,0) 


		pm.select(knee_rev_loc)
		knee_rev_loc_grp = pm.group ( n = knee_rev_loc.name() + "_grp" )
		pm.xform ( knee_rev_loc_grp , ws=True , piv = self.kneePos )
				  

		# we need to make this locator scalable. if not, we won't be able to scale upLeg or knee seperately

		knee_rev_loc_mdn = pm.createNode ("multiplyDivide" , n = knee_rev_loc.name() + "_mdn")
		knee_rev_loc_mdn.operation.set ( 2 )
		knee_rev_loc_mdn.input1X.set ( 1 )
		self.kneeJnt.scaleX          >>         knee_rev_loc_mdn.input2X
		knee_rev_loc_mdn.outputX     >>         knee_rev_loc_grp.scaleX



		# L_knee_aim_loc 
		#================
		knee_aim_loc =  pm.spaceLocator ( p = (0,0,0) )
		pm.parent (  knee_aim_loc , self.kneeJnt )
		pm.rename ( knee_aim_loc , self.side + "_knee_aim_loc" )

		pm.pointConstraint( upLeg_rev_loc , knee_rev_loc , knee_aim_loc )

		# creating the curvy_midCtrl_Parent for mid_joint position ( main purpose of this part )
		self.midCtrlParent = pm.group ( em = True )
		pm.pointConstraint(  self.kneeJnt , self.midCtrlParent )
		pm.aimConstraint ( knee_aim_loc, self.midCtrlParent , aimVector = (0,0,-1) , upVector = (-1,0,0) , worldUpType = "object" , worldUpObject = self.upLegJnt )
		pm.rename ( self.midCtrlParent , self.side + "_curvy_midCtrl_Parent")



		#============================================================================
		# finding the position for segMainJnts and creating them

		self.midJntPosition = 0.0


		midJnt = self.segMainJnts[0]


		# create upLeg seg joints
		for  i in ( range (self.legNumOfJnts-1) ) :
			
			midJntPosition = (self.kneeJnt.translate.translateX.get() / self.legNumOfJnts )
				
			midJnt = pm.insertJoint ( midJnt )
				
			pm.joint  (  midJnt , e = True , relative = True , component = True ,   position = ( midJntPosition  , 0 , 0 )  )

		#=============        
		# create knee seg joints 
		# create an extra joint on knee in segmenty so that we could create two ikSplines for the whole leg

		midJnt = self.segMainJnts[1]

		midJntParent = midJnt.duplicate()
		pm.delete ( pm.listRelatives ( midJntParent , allDescendents = True) )
		pm.parent ( midJnt , midJntParent)

		for  i in ( range (self.legNumOfJnts-1) ) :
			
			midJntPosition = (self.ankleJnt.translate.translateX.get() / self.legNumOfJnts )
				
			midJnt = pm.insertJoint ( midJnt )
				
			pm.joint  (  midJnt , e = True , relative = True , component = True ,   position = ( midJntPosition  , 0 , 0 )  )


		segJnts = pm.listRelatives ( self.segMainJnts[0] , allDescendents = True)
		segJnts.append ( self.segMainJnts[0] )
		segJnts.reverse()

		
		pm.select (segJnts)
		
		
		segJnts = Renamer ( objs=segJnts, name=self.side+"_leg_seg_###_jnt" , hierarchyMode=False).newJnts

		
		# select skin joint
		tempSkinJnts = pm.ls ( segJnts [ 0 : self.legNumOfJnts ] , segJnts [  self.legNumOfJnts+1 : self.legNumOfJnts*2+1 ] ) 

		# add skin jnt to skinJnts list
		for jnt in tempSkinJnts :
			self.skinJnts.append ( jnt )
		
		# rename them
		pm.select ( tempSkinJnts )
		SearchReplaceNames (  "_jnt", "_skinJnt", tempSkinJnts )



		#============================================================================
		# creating ik splines for segmenty joints
		pm.select ( segJnts[0] )
		pm.select ( segJnts[self.legNumOfJnts] , add = True )
		self.upLeg_seg_ik_stuff = pm.ikHandle ( sol = "ikSplineSolver" , parentCurve = False , ns = 2 )
		self.upLeg_seg_ikh = pm.rename ( self.upLeg_seg_ik_stuff[0] , self.side + "_upLeg_seg_ikh" )
		upLeg_seg_eff = pm.rename ( self.upLeg_seg_ik_stuff[1] , self.side + "_upLeg_seg_eff" )
		upLeg_seg_crv = pm.rename ( self.upLeg_seg_ik_stuff[2] , self.side + "_upLeg_seg_crv" )
		pm.select ( segJnts[self.legNumOfJnts+1] )
		pm.select ( segJnts[self.legNumOfJnts*2+1] , add = True )
		self.knee_seg_ik_stuff = pm.ikHandle ( sol = "ikSplineSolver" , parentCurve = False , ns = 2 )
		knee_seg_ikh = pm.rename ( self.knee_seg_ik_stuff[0] , self.side + "_knee_seg_ikh" )
		knee_seg_eff = pm.rename ( self.knee_seg_ik_stuff[1] , self.side + "_knee_seg_eff" )
		knee_seg_crv = pm.rename ( self.knee_seg_ik_stuff[2] , self.side + "_knee_seg_crv" )


		#============================================================================
		# creating curvy_midCtrl_jnt

		curvy_midCtrl_jnt = pm.joint ( p = ( self.kneePos[0] , self.kneePos[1] ,self.kneePos[2] ) , name = ( self.side + "_curvy_midCtrl_jnt" ) )

		# creating ctrl curve for curvy_midCtrl_jnt

		self.midCtrl = Circle8Crv ( self.legSize*1.2 , self.side+"_leg_toon_ctrl")
		pm.parent (self.midCtrl , self.midCtrlParent )
				
		self.midCtrl.rotate.set (0,0,0)
		self.midCtrl.translate.set (0,0,0) 

		pm.parent (curvy_midCtrl_jnt , self.midCtrl )
		curvy_midCtrl_jnt.jointOrient.set (0,0,0) 

		LockHideAttr ( objs=curvy_midCtrl_jnt , attrs="vv")

		LockHideAttr ( objs=self.midCtrl , attrs="sy")
		LockHideAttr ( objs=self.midCtrl , attrs="sz")
		LockHideAttr ( objs=self.midCtrl , attrs="v")

		
		#============================================================================
		# skinning the seg_crvs



		#==========
		# before skinning we should make sure that leg is completely staright.
		# we temporarly parent segmenty ikCurve to joint

		pm.parent ( knee_seg_crv , self.kneeJnt )

		if self.FKIKMode != "IK" :
			# tempKneeOri = pm.getAttr ( self.kneeJnt.jointOrient )
			tempKneeOri = self.kneeJnt.jointOrient.get()
			self.kneeJnt.jointOrient.set(0,0,0) 
		 
		else : # find position for putting the ik so that leg gets straight
			tempAnkleIKLoc = pm.spaceLocator ( p = (0,0,0) )
			pm.parent (tempAnkleIKLoc , self.upLegJnt  )
			tempAnkleIKLoc.rotate.set(0,0,0)
			legLen =   ( self.kneeJnt.translate.translateX.get() + self.ankleJnt.translate.translateX.get() )
			tempAnkleIKLoc.translate.set( legLen ,0,0)
			tempAnkleIKPos = pm.xform ( tempAnkleIKLoc , q=True , ws=True ,  translation = True )
			pm.parent (self.IKlegDistLocs[1], w=True)
			# straighten the leg for skinning
			self.IKlegDistLocs[1].translate.set( tempAnkleIKPos )



		#==========
		upLeg_seg_crv_skinCluster = ( pm.skinCluster( upLeg_seg_crv ,  self.upLegJnt , curvy_midCtrl_jnt , toSelectedBones = True ) )

		knee_seg_crv_skinCluster = ( pm.skinCluster( knee_seg_crv ,  curvy_midCtrl_jnt , self.kneeJnt , toSelectedBones = True ) )


		#==========
		pm.setAttr ( upLeg_seg_crv.tx ,  lock=False )
		pm.setAttr ( upLeg_seg_crv.ty ,  lock=False )
		pm.setAttr ( upLeg_seg_crv.tz ,  lock=False )

		pm.setAttr ( upLeg_seg_crv.rx ,  lock=False )
		pm.setAttr ( upLeg_seg_crv.ry ,  lock=False )
		pm.setAttr ( upLeg_seg_crv.rz ,  lock=False )
				
		pm.setAttr ( knee_seg_crv.tx ,  lock=False )
		pm.setAttr ( knee_seg_crv.ty ,  lock=False )
		pm.setAttr ( knee_seg_crv.tz ,  lock=False )

		pm.setAttr ( knee_seg_crv.rx ,  lock=False )
		pm.setAttr ( knee_seg_crv.ry ,  lock=False )
		pm.setAttr ( knee_seg_crv.rz ,  lock=False )


		pm.parent ( knee_seg_crv , w =True )

		pm.setAttr ( upLeg_seg_crv.tx ,  lock=True )
		pm.setAttr ( upLeg_seg_crv.ty ,  lock=True )
		pm.setAttr ( upLeg_seg_crv.tz ,  lock=True )

		pm.setAttr ( upLeg_seg_crv.rx ,  lock=True )
		pm.setAttr ( upLeg_seg_crv.ry ,  lock=True )
		pm.setAttr ( upLeg_seg_crv.rz ,  lock=True )
				
		pm.setAttr ( knee_seg_crv.tx ,  lock=True )
		pm.setAttr ( knee_seg_crv.ty ,  lock=True )
		pm.setAttr ( knee_seg_crv.tz ,  lock=True )

		pm.setAttr ( knee_seg_crv.rx ,  lock=True )
		pm.setAttr ( knee_seg_crv.ry ,  lock=True )
		pm.setAttr ( knee_seg_crv.rz ,  lock=True )


		if self.FKIKMode != "IK" :
			self.kneeJnt.jointOrient.set ( tempKneeOri )


		else:
			# now that we have skinned segmenty curves, we can put the leg to it's default pose
			pm.parent  ( self.IKlegDistLocs[1] , self.ankleIKCtrl  )
			self.IKlegDistLocs[1].translate.set( 0,0,0 )




		# setting the weights
		pm.skinPercent ( upLeg_seg_crv_skinCluster , (upLeg_seg_crv + ".cv[3:4]") , transformValue = ( curvy_midCtrl_jnt, 1)  )
		pm.skinPercent ( knee_seg_crv_skinCluster , (knee_seg_crv + ".cv[0:1]") , transformValue = ( curvy_midCtrl_jnt, 1)  )

		pm.skinPercent ( upLeg_seg_crv_skinCluster , (upLeg_seg_crv + ".cv[2]") , transformValue = ( curvy_midCtrl_jnt, 0.5)  )
		pm.skinPercent ( knee_seg_crv_skinCluster , (knee_seg_crv + ".cv[2]") , transformValue = ( curvy_midCtrl_jnt, 0.5)  )

		pm.skinPercent ( upLeg_seg_crv_skinCluster , (upLeg_seg_crv + ".cv[1]") , transformValue = ( curvy_midCtrl_jnt, 0.1)  )
		pm.skinPercent ( knee_seg_crv_skinCluster , (knee_seg_crv + ".cv[3]") , transformValue = ( curvy_midCtrl_jnt, 0.1)  )



		#============================================================================
		# making the joints stratchable 
			
		MakeSplineStretchy ( ikCrv=upLeg_seg_crv , stretchSwitch=True , volume=False , thicknessPlace="end")
		upLeg_seg_crv.inheritsTransform.set ( 0 ) 

		MakeSplineStretchy ( ikCrv=knee_seg_crv , stretchSwitch=True , volume=False ,thicknessPlace="start")
		knee_seg_crv.inheritsTransform.set ( 0 )


		#============================================================================
		# setting the twist parameters for the segmenty joints

		self.upLeg_seg_ikh.dTwistControlEnable.set ( 1 )
		self.upLeg_seg_ikh.dWorldUpType.set ( 4 )
		self.upLeg_seg_ikh.dWorldUpVectorX.set ( 1 )
		self.upLeg_seg_ikh.dWorldUpVectorY.set ( 0 )
		pm.connectAttr ( self.kneeJnt + ".worldMatrix[0]" , self.upLeg_seg_ikh + ".dWorldUpMatrixEnd" , f = True )

		knee_seg_ikh.dTwistControlEnable.set ( 1 )
		knee_seg_ikh.dWorldUpType.set ( 4 )
		pm.connectAttr ( self.kneeJnt + ".worldMatrix[0]" , knee_seg_ikh + ".dWorldUpMatrix" , f = True )
		pm.connectAttr ( self.ankleJnt + ".worldMatrix[0]" , knee_seg_ikh + ".dWorldUpMatrixEnd" , f = True )
Esempio n. 9
0
def splitJnt(numSegments, joints=None, name='C_split##_skinJnt'):
    '''

    Args:
        numSegments: number of segments
        joints: the two joints in an array ['start_jnt', 'end_jnt']
        name: the name, ## will be replaced with 01, 02 ...

    Returns: the list of new joints ['C_split01_jnt', ...]

    '''
    if numSegments < 2:
        pm.error("The number of segments has to be greater than 1.. ")

    # for all selected joints
    joint = None
    splitJnts = []

    if joints == None:
        joints = pm.ls(sl=1, type='joint')

    for joint in joints:

        prevJoint = joint

        child = pm.listRelatives(joint, children=1, type='joint')
        if child == []:
            print("Joint: " + str(joint) + " has no children joints.\n")
            continue

        else:
            print("Joint: " + str(joint) + " has children joints.\n")
            child = child[0]
            # axis
            radius = pm.getAttr("%s.radius" % joint)
            axis = getJointAxis(child)

            # make sure the rotation order on $joint is correct.
            rotOrderIndex = int(pm.getAttr("%s.rotateOrder" % joint))

            # calculate spacing
            attr = ("t" + axis)
            childT = pm.getAttr("%s.%s" % (child, attr))
            print 'childT is %s' % childT
            space = childT / numSegments

            # create a series of locators along the joint based on the number of segments.
            locators = []
            for x in range(0, (numSegments - 1)):
                # align locator to joint

                locator = pm.spaceLocator()
                locators.append(locator)

                pm.parent(locator, joint)

                pm.setAttr("%s.t" % locator, (0, 0, 0))
                # offset
                pm.setAttr("%s.%s" % (locator, attr), (space * (x + 1)))
                # insert a joint
                newJoint = pm.PyNode(pm.insertJoint(prevJoint))

        splitJnts.append(newJoint)

        # get the position of the locator
        position = pm.xform(locator, q=1, rp=1, ws=1)

        # move the joint there
        pm.move(position, ws=1, pcp=1)

        pm.setAttr("%s.radius" % newJoint, radius)
        pm.setAttr("%s.rotateOrder" % newJoint, rotOrderIndex)

        prevJoint = newJoint
        pm.delete(locator)
    pm.select(joint)
    # mo_stringUtils.renameHierarchy()

    return splitJnts