Beispiel #1
0
def createCurves(shapes, color, name=""):
    list = []
    for shape in shapes:
        if name:
            crv = cmds.curve(
                n=name,
                p=shape['points'],
                d=shape['degree'],
                k=shape['knot']
            )
        else:
            crv = cmds.curve(
                p=shape['points'],
                d=shape['degree'],
                k=shape['knot']
            )
        list.append(crv)

    for x in range(len(list)-1):
        cmds.makeIdentity(list[x+1], apply=True, t=1, r=1, s=1, n=0)
        shapes = utility.getShapes(list[x+1])
        cmds.parent(shapes, list[0], add=1, s=1)
        cmds.delete(list[x+1])

    utility.applyColor(list[0], color)
    cmds.select(list[0])
    return list[0]
Beispiel #2
0
def mergeCurves(curves):
    curves = utility.unParentToWorld(curves)

    for curve in curves:
        cmds.makeIdentity(curve, a=1)
        cmds.bakePartialHistory(curve, pc=1)

    # set newTransform as first in selection
    groupTransform = curves[0]

    # get groupTransform
    grp = cmds.group(em=1)
    #cmds.matchTransform(grp, groupTransform)
    groupTransform = grp

    for curve in curves:
        # make sure curveShapes don't move
        cmds.makeIdentity(curve, a=1)

        # merge to groupTransform
        curveShapes = utility.getShapes(curve)
        for curveShape in curveShapes:
            cmds.parent(curveShape, groupTransform, r=1, s=1)

        # delect rest
        cmds.delete(curve)

    # center pivot and clear history
    cmds.xform(groupTransform, cp=1)
    cmds.bakePartialHistory(groupTransform, pc=1)
    cmds.select(groupTransform)
Beispiel #3
0
def replaceCurves(originCurve, targetCurve):
    snapPivot(originCurve, targetCurve)

    targetShape = utility.getShapes(targetCurve)
    if targetShape:
        cmds.delete(targetShape)

    curveShapes = utility.getShapes(originCurve)
    for curveShape in curveShapes:
        cmds.parent(curveShape, targetCurve, r=1, s=1)

    originCurve = utility.unParentToWorld([originCurve])
    # delect
    cmds.delete(originCurve)

    cmds.select(targetCurve)
Beispiel #4
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def applyCurvesColor(color, *args):
    sl = cmds.ls(sl=1)

    if len(sl) < 1:
        return False

    for curve in sl:
        shapes = utility.getShapes(curve)
        for shape in shapes:
            if cmds.objectType(shape, i='nurbsCurve'):
                utility.applyColor(curve, color)
Beispiel #5
0
def saveCurve(curve):
    shapes = utility.getShapes(curve)
    name = curve.split("|")[-1]
    info = {}
    info['name'] = name
    info['icon'] = name+'.png'
    info['shape'] = []
    for shape in shapes:
        curveInfo = cmds.shadingNode("curveInfo", au=1)
        cmds.connectAttr(shape+'.worldSpace[0]', curveInfo+'.inputCurve', f=1)
        shapeinfo = {
            'points': cmds.getAttr(curveInfo+'.cp[:]'),
            'degree': cmds.getAttr(shape+'.degree'),
            'knot': cmds.getAttr(curveInfo+'.knots[:]')
        }
        # print(cmds.getAttr(curveInfo+'.cp[:]'))
        # print(cmds.getAttr(shape+'.degree'))
        # print(cmds.getAttr(curveInfo+'.knots[:]'))
        cmds.delete(curveInfo)
        info['shape'].append(shapeinfo)
    cmds.select(curve)
    json_path = CURVE_PATH + '%s.json' % name
    img_path = CURVE_PATH + '%s.png' % name

    with open(json_path, 'w') as f:
        json.dump(info, f)

    window = cmds.window(w=120, h=131)
    cmds.paneLayout()
    panel = cmds.modelPanel()
    editor = cmds.modelPanel(panel, me=1, q=1)
    cmds.modelEditor(editor, e=1)
    cmds.modelEditor(editor, e=1, grid=0, hud=0,
                     manipulators=0, selectionHiliteDisplay=1)
    cmds.isolateSelect(panel, state=1)
    cmds.isolateSelect(panel, loadSelected=True)

    cmds.showWindow(window)
    cmds.setFocus(panel)
    cmds.viewFit(curve)
    cmds.refresh(cv=True, fe="png", fn=img_path)
    cmds.isolateSelect(panel, state=0)
    cmds.deleteUI(window)

    return info
Beispiel #6
0
def autoSplineFKIK(jnt_start, jnt_end, panel):
    ik_jnt_list = []

    jnt_i = jnt_end
    render_jnt_list = []

    while True:
        print("start: " + jnt_i)
        render_jnt_list.append(jnt_i)
        name = jnt_i.split("|")[-1]

        ik_jnt_i = cmds.duplicate(jnt_i, n=name + "_ik", parentOnly=1)[0]
        ik_jnt_list.append(ik_jnt_i)

        if jnt_i == jnt_start:
            print("end loop")
            break
        else:
            prt = utility.getPrt(jnt_i)
            if prt:
                jnt_i = prt
                print("end: " + jnt_i)
            else:
                break

    # reparent
    for inx in range(len(ik_jnt_list)):
        if inx < len(ik_jnt_list) - 1:
            ik_jnt_list[inx] = cmds.parent(ik_jnt_list[inx],
                                           ik_jnt_list[inx + 1])[0]
        else:
            if utility.getPrt(ik_jnt_list[inx]):
                ik_jnt_list[inx] = cmds.parent(ik_jnt_list[inx], w=1)[0]

    # -------------------------------------------------------------------------------
    # create splineIK
    # -------------------------------------------------------------------------------
    name = jnt_start.split("|")[-1]
    [spline_ikHandle, effector,
     spline_crv] = cmds.ikHandle(name=name + "_spline_ikHandle",
                                 sj=ik_jnt_list[-1],
                                 ee=ik_jnt_list[0],
                                 solver='ikSplineSolver')

    spline_crv = cmds.rename(spline_crv, name + '_spline_crv')

    # -------------------------------------------------------------------------------
    # create cluster jnt
    # -------------------------------------------------------------------------------
    CTL_COUNT = 3
    pr = 0.0
    cluster_jnt_list = []
    ik_ctl_list = []
    fk_ctl_list = []
    radius = cmds.joint(render_jnt_list[0], q=1, radius=1)[0]
    for i in range(CTL_COUNT):

        pos = cmds.pointOnCurve(spline_crv, pr=pr, p=1, top=1)
        tangent = cmds.pointOnCurve(spline_crv, pr=pr, t=1, top=1)

        pr = pr + 1.0 / (CTL_COUNT - 1)

        cmds.select(cl=1)
        c_jnt = cmds.joint(name=name + "_c" + str(i) + "_jnt", p=pos)
        cluster_jnt_list.append(c_jnt)

        ik_ctl = functions.createCurves(curvesInfo[2]['shape'],
                                        (0.26, 0.84, 1.0),
                                        name=name + "_c" + str(i) + "_ik_ctl")
        ik_ctl_list.append(ik_ctl)
        cmds.xform(ik_ctl, t=pos, s=[radius * 3, radius * 3, radius * 3])
        fk_ctl = functions.createCurves(curvesInfo[0]['shape'], (1, 0.8, 0.0),
                                        name=name + "_c" + str(i) + "_fk_ctl")
        fk_ctl_list.append(fk_ctl)
        WorldUpVector = utility.getVector(jnt_start)
        utility.vectorToRotate(fk_ctl, tangent, worldUp=WorldUpVector)
        cmds.xform(fk_ctl, t=pos, s=[radius * 4, radius * 4, radius * 4])
        cmds.xform(fk_ctl, p=1, rotateOrder='xzy')

        print(tangent)
        print(pos)

    cluster_jnt_list = cluster_jnt_list[::-1]
    ik_ctl_list = ik_ctl_list[::-1]
    fk_ctl_list = fk_ctl_list[::-1]
    for inx in range(len(fk_ctl_list) - 1):
        cmds.parent(fk_ctl_list[inx], fk_ctl_list[inx + 1])

    functions.groupIt(ik_ctl_list)
    functions.groupIt(fk_ctl_list)

    # -------------------------------------------------------------------------------
    # constraint ik fk
    # -------------------------------------------------------------------------------
    constraint_list = []
    for inx in range(len(cluster_jnt_list)):

        cmds.select(ik_ctl_list[inx])
        cmds.select(fk_ctl_list[inx], add=1)
        cmds.select(cluster_jnt_list[inx], add=1)

        constraint = cmds.parentConstraint(mo=1)[0]
        constraint_list.append(constraint)

    WorldUpVector = utility.getVector(jnt_start)
    WorldUpVectorEnd = utility.getVector(jnt_end)

    cmds.setAttr("%s.dTwistControlEnable" % spline_ikHandle, True)
    cmds.setAttr("%s.dWorldUpType" % spline_ikHandle, 4)
    cmds.setAttr("%s.dWorldUpVectorX" % spline_ikHandle, WorldUpVector[0])
    cmds.setAttr("%s.dWorldUpVectorY" % spline_ikHandle, WorldUpVector[1])
    cmds.setAttr("%s.dWorldUpVectorZ" % spline_ikHandle, WorldUpVector[2])
    cmds.setAttr("%s.dWorldUpVectorEndX" % spline_ikHandle,
                 WorldUpVectorEnd[0])
    cmds.setAttr("%s.dWorldUpVectorEndY" % spline_ikHandle,
                 WorldUpVectorEnd[1])
    cmds.setAttr("%s.dWorldUpVectorEndZ" % spline_ikHandle,
                 WorldUpVectorEnd[2])

    cmds.connectAttr("%s.worldMatrix[0]" % cluster_jnt_list[-1],
                     "%s.dWorldUpMatrix" % spline_ikHandle,
                     f=1)
    cmds.connectAttr("%s.worldMatrix[0]" % cluster_jnt_list[0],
                     "%s.dWorldUpMatrixEnd" % spline_ikHandle,
                     f=1)

    # -------------------------------------------------------------------------------
    # connecting node
    # -------------------------------------------------------------------------------
    attr_name = name + '_FKIK'
    attr_full_name = panel + '.' + attr_name

    # check if it already has 'fkik'
    if cmds.attributeQuery(attr_name, node=panel, ex=1):
        cmds.addAttr(attr_full_name,
                     k=1,
                     e=1,
                     ln=attr_name,
                     at="float",
                     max=1.0,
                     min=0.0)
    else:
        cmds.addAttr(panel, k=1, ln=attr_name, at="float", max=1.0, min=0.0)

    # set to 0
    cmds.setAttr(attr_full_name, 0)

    # clear old one
    range_node = cmds.listConnections(attr_full_name, d=1, s=0)

    if not range_node:
        range_node = cmds.shadingNode("setRange", au=1)
        cmds.connectAttr(attr_full_name, "%s.valueX" % range_node, f=1)
        cmds.connectAttr(attr_full_name, "%s.valueY" % range_node, f=1)
        cmds.setAttr("%s.oldMaxX" % range_node, 1.0)
        cmds.setAttr("%s.oldMaxY" % range_node, 1.0)
        cmds.setAttr("%s.maxX" % range_node, 1.0)
        cmds.setAttr("%s.minY" % range_node, 1.0)
    else:
        range_node = range_node[0]

    print(range_node)

    # connect node
    for inx, constraint in enumerate(constraint_list):

        ik_weight_name = constraint + "." + ik_ctl_list[inx] + "W0"
        fk_weight_name = constraint + "." + fk_ctl_list[inx] + "W1"
        ik_ctl_vis_name = ik_ctl_list[inx] + ".visibility"
        fk_ctl_vis_name = fk_ctl_list[inx] + ".visibility"

        cmds.connectAttr("%s.outValueX" % range_node, ik_weight_name, f=1)
        cmds.connectAttr("%s.outValueX" % range_node, ik_ctl_vis_name, f=1)
        cmds.connectAttr("%s.outValueY" % range_node, fk_weight_name, f=1)
        cmds.connectAttr("%s.outValueY" % range_node, fk_ctl_vis_name, f=1)

    crvInfo_node = cmds.shadingNode("curveInfo", au=1)
    divide_node = cmds.shadingNode("multiplyDivide", au=1)
    spline_crvShape = utility.getShapes(spline_crv)[0]
    cmds.connectAttr("%s.worldSpace[0]" % spline_crvShape,
                     "%s.inputCurve" % crvInfo_node,
                     f=1)

    originL = cmds.getAttr("%s.arcLength" % crvInfo_node)
    print(originL)

    cmds.setAttr("%s.operation" % divide_node, 2)
    cmds.setAttr("%s.input2X" % divide_node, originL)
    cmds.connectAttr("%s.arcLength" % crvInfo_node,
                     "%s.input1X" % divide_node,
                     f=1)

    for inx in range(len(ik_jnt_list)):
        cmds.connectAttr("%s.outputX" % divide_node,
                         "%s.scaleX" % ik_jnt_list[inx],
                         f=1)

    cmds.select(spline_crv)
    cmds.select(cluster_jnt_list, add=1)
    cmds.skinCluster(dr=1.0, maximumInfluences=2)

    for inx in range(len(ik_jnt_list)):
        cmds.select(ik_jnt_list[inx])
        cmds.select(render_jnt_list[inx], add=1)
        cmds.parentConstraint(mo=0)

    misc_grp = cmds.ls("DoNotTouch")
    if not misc_grp:
        misc_grp = cmds.group(name="DoNotTouch", em=1)

    hide_list = [spline_ikHandle, spline_crv, ik_jnt_list[-1]]
    hide_list.extend(cluster_jnt_list)
    misc_list = [spline_ikHandle, spline_crv, ik_jnt_list[-1]]
    misc_list.extend(cluster_jnt_list)

    for obj in hide_list:
        cmds.hide(obj)

    for obj in misc_list:
        cmds.parent(obj, misc_grp)

    utility.lockHideObj(fk_ctl_list, ['sx', 'sy', 'sz', 'v'])
    utility.lockHideObj(ik_ctl_list, ['sx', 'sy', 'sz', 'v'])

    prt = utility.getPrt(jnt_start)
    if prt:
        cmds.select(prt)
        cmds.select(ik_jnt_list[-1], add=1)
        cmds.parentConstraint(mo=1)
Beispiel #7
0
def autoFKIK(jnt_start, jnt_end, panel):
    # -------------------------------------------------------------------------------
    # create ik joint match render joint
    # -------------------------------------------------------------------------------
    ik_jnt_list = []

    jnt_i = jnt_end
    render_jnt_list = []

    while True:
        print("start: " + jnt_i)
        render_jnt_list.append(jnt_i)
        name = jnt_i.split("|")[-1]

        ik_jnt_i = cmds.duplicate(jnt_i, n=name + "_ik", parentOnly=1)[0]
        ik_jnt_list.append(ik_jnt_i)

        if jnt_i == jnt_start:
            print("end loop")
            break
        else:
            prt = utility.getPrt(jnt_i)
            if prt:
                jnt_i = prt
                print("end: " + jnt_i)
            else:
                break

    # reparent
    for inx in range(len(ik_jnt_list)):
        if inx < len(ik_jnt_list) - 1:
            ik_jnt_list[inx] = cmds.parent(ik_jnt_list[inx],
                                           ik_jnt_list[inx + 1])[0]
        else:
            if utility.getPrt(ik_jnt_list[inx]):
                ik_jnt_list[inx] = cmds.parent(ik_jnt_list[inx], w=1)[0]

    name = jnt_start.split("|")[-1]
    ikHandle = cmds.ikHandle(name=name + "_ikHandle",
                             sj=ik_jnt_list[-1],
                             ee=ik_jnt_list[0])[0]

    # -------------------------------------------------------------------------------
    # create ik ctls
    # -------------------------------------------------------------------------------

    radius1 = cmds.joint(jnt_end, q=1, radius=1)[0]

    ik_ctl = functions.createCurves(curvesInfo[2]['shape'], (0.26, 0.84, 1.0),
                                    name=name + "_ik_ctl")

    cmds.bakePartialHistory(ik_ctl, pc=1)
    cmds.matchTransform(ik_ctl, ikHandle)

    cmds.xform(ik_ctl, s=[radius1 * 3, radius1 * 3, radius1 * 3])
    functions.groupIt([ik_ctl])

    # Constraint
    cmds.select(ik_ctl)
    cmds.select(ikHandle, add=1)

    ik_constraint = cmds.parentConstraint(mo=1)[0]

    cmds.select(ik_ctl)
    cmds.select(ik_jnt_list[0], add=1)
    cmds.orientConstraint(mo=1)

    # -------------------------------------------------------------------------------
    # create pole ctls
    # -------------------------------------------------------------------------------
    ik_pole = functions.createCurves(curvesInfo[1]['shape'], (1.0, 0.1, 0.21),
                                     name=name + "_ik_pole")
    #cmds.bakePartialHistory(ik_pole, pc=1)

    middle_jnt = render_jnt_list[len(render_jnt_list) // 2]
    radius2 = cmds.joint(middle_jnt, q=1, radius=1)[0]

    cmds.matchTransform(ik_pole, middle_jnt, pos=1)

    pole_vector = cmds.getAttr(ikHandle + '.poleVector')[0]
    pole_vector = utility.vectorMult(pole_vector, radius2 * 4)

    cmds.xform(ik_pole, r=1, ws=1, t=pole_vector)
    cmds.xform(ik_pole, s=[radius2, radius2, radius2])

    functions.groupIt([ik_pole])

    cmds.select(ik_pole)
    cmds.select(ikHandle, add=1)

    pole_constraint = cmds.poleVectorConstraint()[0]

    pole_help = functions.createCurves(curvesInfo[3]['shape'], (0.3, 0.3, 0.3),
                                       name=name + "_pole_help")
    shapes = utility.getShapes(pole_help)
    for shape in shapes:
        cmds.setAttr(shape + '.overrideDisplayType', 1)

    cmds.select(pole_help + '.cv[0]')
    pole_c1 = cmds.cluster(name=name + "_pole_c1")[1]

    cmds.select(pole_help + '.cv[1]')
    pole_c2 = cmds.cluster(name=name + "_pole_c2")[1]

    cmds.select(middle_jnt)
    cmds.select(pole_c1, add=1)
    cmds.pointConstraint(mo=0)

    cmds.select(ik_pole)
    cmds.select(pole_c2, add=1)
    cmds.pointConstraint(mo=0)
    # -------------------------------------------------------------------------------
    # create fk ctls
    # -------------------------------------------------------------------------------
    fk_ctl_list = []

    for inx in range(len(render_jnt_list)):
        name = render_jnt_list[inx].split("|")[-1]
        radius = cmds.joint(render_jnt_list[inx], q=1, radius=1)[0]

        fk_ctl = functions.createCurves(curvesInfo[0]['shape'], (1, 0.8, 0.0),
                                        name=name + "_fk_ctl")

        cmds.bakePartialHistory(fk_ctl, pc=1)
        fk_ctl_list.append(fk_ctl)
        cmds.matchTransform(fk_ctl, render_jnt_list[inx])
        print(radius)
        cmds.xform(fk_ctl, s=[radius * 4, radius * 4, radius * 4])
        cmds.xform(fk_ctl, p=1, rotateOrder='xzy')

    for inx in range(len(fk_ctl_list) - 1):
        fk_ctl_list[inx] = cmds.parent(fk_ctl_list[inx],
                                       fk_ctl_list[inx + 1])[0]
    print(fk_ctl_list)
    functions.groupIt(fk_ctl_list)

    constraint_list = []

    for inx in range(len(render_jnt_list)):

        cmds.select(ik_jnt_list[inx])
        cmds.select(fk_ctl_list[inx], add=1)
        cmds.select(render_jnt_list[inx], add=1)

        constraint = cmds.parentConstraint(mo=1)[0]
        constraint_list.append(constraint)

    print("render jnt: ")
    print(render_jnt_list)
    print("ik jnt: ")
    print(ik_jnt_list)
    print("fk ctl: ")
    print(fk_ctl_list)
    print("constraints: ")
    print(constraint_list)

    # -------------------------------------------------------------------------------
    # connecting node
    # -------------------------------------------------------------------------------
    attr_name = name + '_FKIK'
    attr_full_name = panel + '.' + attr_name

    # check if it already has 'fkik'
    if cmds.attributeQuery(attr_name, node=panel, ex=1):
        cmds.addAttr(attr_full_name,
                     k=1,
                     e=1,
                     ln=attr_name,
                     at="float",
                     max=1.0,
                     min=0.0)
    else:
        cmds.addAttr(panel, k=1, ln=attr_name, at="float", max=1.0, min=0.0)

    # set to 0
    cmds.setAttr(attr_full_name, 0)

    # clear old one
    range_node = cmds.listConnections(attr_full_name, d=1, s=0)

    if not range_node:
        range_node = cmds.shadingNode("setRange", au=1)
        cmds.connectAttr(attr_full_name, "%s.valueX" % range_node, f=1)
        cmds.connectAttr(attr_full_name, "%s.valueY" % range_node, f=1)
        cmds.setAttr("%s.oldMaxX" % range_node, 1.0)
        cmds.setAttr("%s.oldMaxY" % range_node, 1.0)
        cmds.setAttr("%s.maxX" % range_node, 1.0)
        cmds.setAttr("%s.minY" % range_node, 1.0)
    else:
        range_node = range_node[0]

    print(range_node)

    # connect node
    for inx, constraint in enumerate(constraint_list):

        ik_weight_name = constraint + "." + ik_jnt_list[inx] + "W0"
        fk_weight_name = constraint + "." + fk_ctl_list[inx] + "W1"
        fk_ctl_vis_name = fk_ctl_list[inx] + ".visibility"

        cmds.connectAttr("%s.outValueX" % range_node, ik_weight_name, f=1)
        cmds.connectAttr("%s.outValueY" % range_node, fk_weight_name, f=1)
        cmds.connectAttr("%s.outValueY" % range_node, fk_ctl_vis_name, f=1)

    cmds.connectAttr("%s.outValueX" % range_node, ik_ctl + ".visibility", f=1)
    cmds.connectAttr("%s.outValueX" % range_node, ik_pole + ".visibility", f=1)
    cmds.connectAttr("%s.outValueX" % range_node,
                     pole_help + ".visibility",
                     f=1)

    divide_node = cmds.shadingNode("multiplyDivide", au=1)
    clamp_node = cmds.shadingNode("clamp", au=1)

    distanceD = cmds.distanceDimension(sp=(0, 2, 2), ep=(1, 5, 6))
    [loc1, loc2] = cmds.listConnections(distanceD, d=0, s=1)

    #cmds.matchTransform(loc1,ik_ctl)
    #loc1 = cmds.parent(loc1,ik_ctl)[0]
    #cmds.matchTransform(loc2,render_jnt_list[-1])
    #loc2 = cmds.parent(loc2,render_jnt_list[-1])[0]

    cmds.select(ik_ctl)
    cmds.select(loc1, add=1)
    cmds.pointConstraint(mo=0)

    cmds.select(ik_jnt_list[-1])
    cmds.select(loc2, add=1)
    cmds.pointConstraint(mo=0)

    originL = 0
    for inx in range(len(ik_jnt_list) - 1):
        originL += cmds.getAttr("%s.translateX" % ik_jnt_list[inx])
    print(originL)

    cmds.setAttr("%s.operation" % divide_node, 2)
    cmds.setAttr("%s.input2X" % divide_node, originL)
    cmds.setAttr("%s.minR" % clamp_node, 1.0)
    cmds.setAttr("%s.maxR" % clamp_node, 10.0)
    cmds.connectAttr("%s.distance" % distanceD,
                     "%s.input1X" % divide_node,
                     f=1)
    cmds.connectAttr("%s.outputX" % divide_node, "%s.inputR" % clamp_node, f=1)

    for inx in range(len(ik_jnt_list)):
        cmds.connectAttr("%s.outputR" % clamp_node,
                         "%s.scaleX" % ik_jnt_list[inx],
                         f=1)

    misc_grp = cmds.ls("DoNotTouch")
    if not misc_grp:
        misc_grp = cmds.group(name="DoNotTouch", em=1)

    hide_list = [
        ikHandle, pole_c1, pole_c2, ik_jnt_list[-1], loc1, loc2,
        utility.getPrt(distanceD)
    ]
    misc_list = [
        ikHandle, pole_help, pole_c1, ik_jnt_list[-1], pole_c2, loc1, loc2,
        utility.getPrt(distanceD)
    ]

    for obj in hide_list:
        cmds.hide(obj)

    for obj in misc_list:
        cmds.parent(obj, misc_grp)

    utility.lockHideObj(fk_ctl_list, ['tx', 'ty', 'tz', 'sx', 'sy', 'sz', 'v'])
    utility.lockHideObj([ik_pole], ['rx', 'ry', 'rz', 'sx', 'sy', 'sz', 'v'])
    utility.lockHideObj([ik_ctl], ['sx', 'sy', 'sz', 'v'])

    prt = utility.getPrt(jnt_start)
    if prt:
        cmds.select(prt)
        cmds.select(ik_jnt_list[-1], add=1)
        cmds.parentConstraint(mo=1)
Beispiel #8
0
def spaceSwitchSetup(targets, contained):
    contained_grp = utility.getPrt(contained)
    if not contained_grp or utility.getShapes(contained_grp):
        contained_grp = groupIt([contained])[0]

    select_list = []

    # check if it already parentconstrainted
    constraint = cmds.listConnections(
        "%s.translateX" % contained_grp, d=0, s=1)
    oldLoc = ''
    loc_name = contained.split("|")[-1].split(":")[-1] + '_loc'
    if constraint:
        constraint = constraint[0]

        loc_weight_name = cmds.listAttr(constraint, st=loc_name+"*", ud=1)
        print(loc_name)
        print(loc_weight_name)
        if loc_weight_name:
            target_name = cmds.listConnections(
                constraint+'.'+loc_weight_name[0], d=1, s=0, p=1)[0]
            target_name = target_name.replace(
                'targetWeight', 'targetTranslate')
            oldLoc = cmds.listConnections(target_name, d=0, s=1)[0]

    if not oldLoc:
        loc = cmds.spaceLocator(name=loc_name)[0]
        cmds.matchTransform(loc, contained_grp)
        contained_grp_prt = utility.getPrt(contained_grp)
        if contained_grp_prt:
            loc = cmds.parent(loc, contained_grp_prt)[0]

        cmds.setAttr("%s.v"%loc, 0)
        utility.fixedObj([loc])

        oldLoc = loc

    print(oldLoc)
    select_list.append(oldLoc)
    loc_name = oldLoc.split("|")[-1].split(":")[-1]
    print(loc_name)

    for target in targets:
        select_list.append(target)

    select_list.append(contained_grp)

    cmds.select(cl=1)
    for obj in select_list:
        cmds.select(obj, add=1)

    constraint = cmds.parentConstraint(mo=1)[0]

    target_list = cmds.listAttr(constraint, st="*W*", ud=1)
    print(target_list)

    # edit enum
    enumName = ''
    parentInx = 0
    for inx, target in enumerate(target_list):
        if loc_name == target[0:-2]:
            parentInx = inx
            enumName = enumName + ":origin"
        else:
            enumName = enumName + ":" + target[0:-2]

    enumName = enumName[1:]

    if cmds.attributeQuery('follow', node=contained, ex=1):
        # edit
        cmds.addAttr("%s.follow" % contained, k=1, e=1,
                     ln="follow", at="enum", en=enumName)
    else:
        # create
        cmds.addAttr(contained, k=1, ln="follow", at="enum", en=enumName)

    # set to parent as defualt
    cmds.setAttr("%s.follow" % contained, parentInx)

    condition_nodes = cmds.listConnections("%s.follow" % contained, d=1, s=0)
    # print(condition_nodes)
    if condition_nodes:
        for nodes in condition_nodes:
            cmds.delete(nodes)
    # connect node
    for inx, target in enumerate(target_list):
        condition_node = cmds.shadingNode("condition", au=1)

        cmds.connectAttr("%s.follow" % contained,
                         "%s.firstTerm" % condition_node, f=1)

        weight_name = constraint+"."+target

        cmds.connectAttr("%s.outColorR" % condition_node, weight_name, f=1)
        cmds.setAttr("%s.secondTerm" % condition_node, inx)
        cmds.setAttr("%s.operation" % condition_node, 1)
    
    cmds.select(contained)