def addObjects(self): po = dt.Vector(self.settings["ctlOffsetPosX"], self.settings["ctlOffsetPosY"], self.settings["ctlOffsetPosZ"]) so = dt.Vector(self.settings["ctlOffsetSclX"], self.settings["ctlOffsetSclY"], self.settings["ctlOffsetSclZ"]) ro = [ self.settings["ctlOffsetRotX"], self.settings["ctlOffsetRotY"], self.settings["ctlOffsetRotZ"] ] ro = set(map(lambda x: math.radians(x), ro)) ro = dt.Vector(*ro) self.normal = self.guide.blades["blade"].z * -1 self.binormal = self.guide.blades["blade"].x self.length0 = vec.getDistance(self.guide.apos[0], self.guide.apos[1]) t = tra.getTransformLookingAt(self.guide.apos[0], self.guide.apos[1], self.normal, axis="xy", negate=self.negate) self.ctl_npo = pri.addTransform(self.root, self.getName("ctl_npo"), t) self.ctl = self.addCtl( self.ctl_npo, "ctl", t, self.color_fk, "cube", w=(self.length0 * so.x), h=(self.size * .1 * so.y), d=(self.size * .1 * so.z), po=(dt.Vector(.5 * self.length0 * self.n_factor, 0, 0) + po)) t = tra.getTransformFromPos(self.guide.apos[0]) self.orbit_ref1 = pri.addTransform(self.root, self.getName("orbit_ref1"), t) t = tra.getTransformFromPos(self.guide.apos[1]) self.orbit_ref2 = pri.addTransform(self.root, self.getName("orbit_ref2"), t) self.orbit_cns = pri.addTransform(self.ctl, self.getName("orbit_cns"), t) self.orbit_npo = pri.addTransform(self.orbit_cns, self.getName("orbit_npo"), t) self.orbit_ctl = self.addCtl(self.orbit_npo, "orbit_ctl", t, self.color_fk, "sphere", w=self.length0 / 4) self.jnt_pos.append([self.ctl, "shoulder"])
def addObjects(self): """Add all the objects needed to create the component.""" t = transform.getTransformFromPos(self.guide.pos["root"]) self.eyeOver_npo = primitive.addTransform(self.root, self.getName("eyeOver_npo"), t) self.eyeOver_ctl = self.addCtl(self.eyeOver_npo, "Over_ctl", t, self.color_fk, "sphere", w=1 * self.size, tp=self.parentCtlTag, guide_loc_ref="root") self.eye_npo = primitive.addTransform(self.eyeOver_ctl, self.getName("eye_npo"), t) self.eyeFK_ctl = self.addCtl(self.eye_npo, "fk_ctl", t, self.color_fk, "arrow", w=1 * self.size, tp=self.eyeOver_ctl) # look at t = transform.getTransformFromPos(self.guide.pos["look"]) self.ik_cns = primitive.addTransform(self.root, self.getName("ik_cns"), t) self.eyeIK_npo = primitive.addTransform(self.ik_cns, self.getName("ik_npo"), t) self.eyeIK_ctl = self.addCtl(self.eyeIK_npo, "ik_ctl", t, self.color_fk, "circle", w=.5 * self.size, tp=self.eyeFK_ctl, ro=datatypes.Vector([1.5708, 0, 0]), guide_loc_ref="look") attribute.setKeyableAttributes(self.eyeIK_ctl, self.t_params) self.jnt_pos.append([self.eyeFK_ctl, "eye", "parent_relative_jnt"]) self.jnt_pos.append( [self.eyeOver_ctl, "eyeOver", "parent_relative_jnt", False])
def addRoot(self): """Add a root object to the guide. This method can initialize the object or draw it. Root object is a simple transform with a specific display and a setting property. Returns: dagNode: The root """ if "root" not in self.tra.keys(): self.tra["root"] = transform.getTransformFromPos( datatypes.Vector(0, 0, 0)) self.root = icon.guideRootIcon(self.parent, self.getName("root"), color=13, m=self.tra["root"]) # Add Parameters from parameter definition list. for scriptName in self.paramNames: paramDef = self.paramDefs[scriptName] paramDef.create(self.root) return self.root
def addLoc(self, name, parent, position=None): """Add a loc object to the guide. This mehod can initialize the object or draw it. Loc object is a simple null to define a position or a tranformation in the guide. Args: name (str): Local name of the element. parent (dagNode): The parent of the element. position (vector): The default position of the element. Returns: dagNode: The locator object. """ if name not in self.tra.keys(): self.tra[name] = transform.getTransformFromPos(position) if name in self.prim.keys(): # this functionality is not implemented. The actual design from # softimage Gear should be review to fit in Maya. loc = self.prim[name].create(parent, self.getName(name), self.tra[name], color=17) else: loc = icon.guideLocatorIcon(parent, self.getName(name), color=17, m=self.tra[name]) return loc
def addEyeMesh(self, name, parent, position=None): """Add a loc object to the guide. This mehod can initialize the object or draw it. Loc object is a simple null to define a position or a tranformation in the guide. Args: name (str): Local name of the element. parent (dagNode): The parent of the element. position (vector): The default position of the element. Returns: dagNode: The locator object. """ if name not in self.tra.keys(): self.tra[name] = transform.getTransformFromPos(position) eyeMesh = pm.polySphere(name=self.getName(name), subdivisionsX=30, subdivisionsY=45, radius=0.5)[0] eyeMesh.setTransformation(self.tra[name]) pm.parent(eyeMesh, parent) eyeMesh.setTranslation return eyeMesh
def addBlade(self, name, parentPos, parentDir): """Add a blade object to the guide. This mehod can initialize the object or draw it. Blade object is a 3points curve to define a plan in the guide. Args: name (str): Local name of the element. parentPos (dagNode): The parent of the element. parentDir (dagNode): The direction constraint of the element. Returns: dagNode: The created blade curve. """ if name not in self.blades.keys(): self.blades[name] = vector.Blade( transform.getTransformFromPos(datatypes.Vector(0, 0, 0))) offset = False else: offset = True blade = icon.guideBladeIcon(parent=parentPos, name=self.getName(name), lenX=.5, color=[0, 0, 1], m=self.blades[name].transform) aim_cns = applyop.aimCns(blade, parentDir, axis="xy", wupType=2, wupVector=[0, 1, 0], wupObject=self.root, maintainOffset=offset) pnt_cns = pm.pointConstraint(parentPos, blade) aim_cns.isHistoricallyInteresting.set(False) pnt_cns.isHistoricallyInteresting.set(False) offsetAttr = attribute.addAttribute(blade, "bladeRollOffset", "float", aim_cns.attr("offsetX").get()) pm.connectAttr(offsetAttr, aim_cns.attr("offsetX")) scaleAttr = attribute.addAttribute(blade, "bladeScale", "float", 1, minValue=0.1, maxValue=100) for axis in "xyz": pm.connectAttr(scaleAttr, blade.attr("s{}".format(axis))) attribute.lockAttribute(blade, attributes=[ "tx", "ty", "tz", "rx", "ry", "rz", "sx", "sy", "sz", "v", "ro" ]) return blade
def addObjects(self): """Add all the objects needed to create the component.""" if self.settings["neutralRotation"]: t = transform.getTransformFromPos(self.guide.pos["root"]) else: t = self.guide.tra["root"] if self.settings["mirrorBehaviour"] and self.negate: scl = [1, 1, -1] else: scl = [1, 1, 1] t = transform.setMatrixScale(t, scl) self.ik_cns = primitive.addTransform(self.root, self.getName("ik_cns"), t) self.SDKctl = self.addCtl( self.ik_cns, "SDK_ctl", t, self.color_ik, "cube", w=self.settings["ctlSize"] * self.size * 1.35, h=self.settings["ctlSize"] * self.size * 0.75, d=self.settings["ctlSize"] * self.size * 0.75, tp=self.parentCtlTag) self.ctl = self.addCtl(self.SDKctl, "ctl", t, self.color_fk, "sphere", w=self.settings["ctlSize"] * self.size, h=self.settings["ctlSize"] * self.size, d=self.settings["ctlSize"] * self.size, tp=self.parentCtlTag) # we need to set the rotation order before lock any rotation axis if self.settings["k_ro"]: rotOderList = ["XYZ", "YZX", "ZXY", "XZY", "YXZ", "ZYX"] attribute.setRotOrder( self.ctl, rotOderList[self.settings["default_rotorder"]]) attribute.setRotOrder( self.SDKctl, rotOderList[self.settings["default_rotorder"]]) params = [ s for s in ["tx", "ty", "tz", "ro", "rx", "ry", "rz", "sx", "sy", "sz"] if self.settings["k_" + s] ] attribute.setKeyableAttributes(self.ctl, params) attribute.setKeyableAttributes(self.SDKctl, params) if self.settings["joint"]: self.jnt_pos.append([self.ctl, 0, None, self.settings["uniScale"]])
def addSliderSurface(self, name, parent, position=None): """pass.""" if name not in self.tra.keys(): self.tra[name] = transform.getTransformFromPos(position) pm.importFile( os.path.join(os.path.dirname(__file__), "assets", "surface.ma")) sliding_surface = pm.PyNode("sliding_surface") pm.rename(sliding_surface, self.getName("sliding_surface")) sliding_surface.setTransformation(self.tra[name]) pm.parent(sliding_surface, parent) return sliding_surface
def _foreachControlOption(self, controlParentGrp, ctlOptions): oName = ctlOptions[0] oSide = ctlOptions[1] o_icon = ctlOptions[2] color = ctlOptions[3] wd = ctlOptions[4] oPar = ctlOptions[5] point = ctlOptions[6] position = transform.getTransformFromPos(point) scl = [1, 1, 1] if self.negate: scl = [-1, 1, 1] t = transform.setMatrixScale(position, scl) npo = addTransform(controlParentGrp, self.getName("%s_npo" % oName, oSide), t) npoBuffer = addTransform(npo, self.getName("%s_bufferNpo" % oName, oSide), t) # Create casual control if o_icon is not "npo": if o_icon == "sphere": rot_offset = None else: rot_offset = datatypes.Vector(1.57079633, 0, 0) ctl = self.addCtl( npoBuffer, "{}_ctl".format(oName), t, color, o_icon, w=wd, d=wd, ro=rot_offset, po=datatypes.Vector(0, 0, 0), ) # Create buffer node instead else: ctl = addTransform(npoBuffer, self.getName("%s_HookNpo" % oName, oSide), t) # Create up vectors for each control upv = addTransform(ctl, self.getName("%s_upv" % oName, oSide), t) upv.attr("tz").set(self.FRONT_OFFSET) return ctl, upv
def addObjects(self): """Add all the objects needed to create the component.""" if self.settings["neutralRotation"]: t = transform.getTransformFromPos(self.guide.pos["root"]) else: t = self.guide.tra["root"] if self._needToMirror(): scl = [1, 1, 1] scl[0] = -1 if self.settings["mirrorAxisX"] else 1 scl[1] = -1 if self.settings["mirrorAxisY"] else 1 scl[2] = -1 if self.settings["mirrorAxisZ"] else 1 t = transform.setMatrixScale(t, scl) rx = self.settings["mirrorAxisX"] * math.pi ry = self.settings["mirrorAxisY"] * math.pi rz = self.settings["mirrorAxisZ"] * math.pi # t = pm.datatypes.TransformationMatrix(t) # t.addRotation((rx, ry, rz), 'XYZ', 'object') else: scl = [1, 1, 1] t = transform.setMatrixScale(t, scl) self.ik_cns = primitive.addTransform( self.root, self.getName("ik_cns"), t) self.ctl = self.addCtl(self.ik_cns, "ctl", t, self.color_ik, self.settings["icon"], w=self.settings["ctlSize"] * self.size, h=self.settings["ctlSize"] * self.size, d=self.settings["ctlSize"] * self.size, tp=self.parentCtlTag) # we need to set the rotation order before lock any rotation axis if self.settings["k_ro"]: rotOderList = ["XYZ", "YZX", "ZXY", "XZY", "YXZ", "ZYX"] attribute.setRotOrder( self.ctl, rotOderList[self.settings["default_rotorder"]]) params = [s for s in ["tx", "ty", "tz", "ro", "rx", "ry", "rz", "sx", "sy", "sz"] if self.settings["k_" + s]] ymt_util.setKeyableAttributesDontLockVisibility(self.ctl, params) if self.settings["joint"]: self.jnt_pos.append([self.ctl, 0, None, self.settings["uniScale"]])
def addObjects(self): """Add all the objects needed to create the component.""" if self.settings["neutralRotation"]: t = transform.getTransformFromPos(self.guide.pos["root"]) else: t = self.guide.tra["root"] if self.settings["mirrorBehaviour"] and self.negate: scl = [1, 1, -1] else: scl = [1, 1, 1] t = transform.setMatrixScale(t, scl) if self.settings["joint"] and self.settings["leafJoint"]: pm.displayInfo("Skipping ctl creation, just leaf joint") self.have_ctl = False else: self.have_ctl = True self.ik_cns = primitive.addTransform(self.root, self.getName("ik_cns"), t) self.ctl = self.addCtl(self.ik_cns, "ctl", t, self.color_ik, self.settings["icon"], w=self.settings["ctlSize"] * self.size, h=self.settings["ctlSize"] * self.size, d=self.settings["ctlSize"] * self.size, tp=self.parentCtlTag, guide_loc_ref="root") # we need to set the rotation order before lock any rotation axis if self.settings["k_ro"]: rotOderList = ["XYZ", "YZX", "ZXY", "XZY", "YXZ", "ZYX"] attribute.setRotOrder( self.ctl, rotOderList[self.settings["default_rotorder"]]) params = [ s for s in ["tx", "ty", "tz", "ro", "rx", "ry", "rz", "sx", "sy", "sz"] if self.settings["k_" + s] ] attribute.setKeyableAttributes(self.ctl, params) if self.settings["joint"]: # TODO WIP: add new attr for seeting leaf joint + not build objcts if self.settings["leafJoint"]: self.jnt_pos.append([t, 0, None, self.settings["uniScale"]]) else: self.jnt_pos.append( [self.ctl, 0, None, self.settings["uniScale"]])
def addObjects(self): """Add all the objects needed to create the component.""" self.normal = self.guide.blades["blade"].z * -1 self.binormal = self.guide.blades["blade"].x self.length0 = vector.getDistance(self.guide.apos[0], self.guide.apos[1]) t = transform.getTransformLookingAt(self.guide.apos[0], self.guide.apos[1], self.normal, axis="xy", negate=self.negate) self.ctl_npo = primitive.addTransform(self.root, self.getName("ctl_npo"), t) self.ctl = self.addCtl(self.ctl_npo, "ctl", t, self.color_fk, "cube", w=self.length0, h=self.size * .1, d=self.size * .1, po=datatypes.Vector( .5 * self.length0 * self.n_factor, 0, 0), tp=self.parentCtlTag) t = transform.getTransformFromPos(self.guide.apos[1]) self.orbit_ref1 = primitive.addTransform(self.ctl, self.getName("orbit_ref1"), t) self.orbit_ref2 = primitive.addTransform(self.root, self.getName("orbit_ref2"), t) self.orbit_cns = primitive.addTransform(self.ctl, self.getName("orbit_cns"), t) self.orbit_npo = primitive.addTransform(self.orbit_cns, self.getName("orbit_npo"), t) self.orbit_ctl = self.addCtl(self.orbit_npo, "orbit_ctl", t, self.color_fk, "sphere", w=self.length0 / 4, tp=self.ctl) self.jnt_pos.append([self.ctl, "shoulder"])
def modalPositions(self): """Launch a modal dialog to set position of the guide.""" self.sections_number = None self.dir_axis = None self.spacing = None for name in self.save_transform: if "#" in name: init_window = chain_guide_initializer.exec_window() if init_window: self.sections_number = init_window.sections_number self.dir_axis = init_window.dir_axis self.spacing = init_window.spacing else: return False if self.sections_number: if self.dir_axis == 0: # X offVec = datatypes.Vector(self.spacing, 0, 0) elif self.dir_axis == 3: # -X offVec = datatypes.Vector(self.spacing * -1, 0, 0) elif self.dir_axis == 1: # Y offVec = datatypes.Vector(0, self.spacing, 0) elif self.dir_axis == 4: # -Y offVec = datatypes.Vector(0, self.spacing * -1, 0) elif self.dir_axis == 2: # Z offVec = datatypes.Vector(0, 0, self.spacing) elif self.dir_axis == 5: # -Z offVec = datatypes.Vector(0, 0, self.spacing * -1) newPosition = datatypes.Vector(0, 0.0, 0) for i in range(self.sections_number): newPosition = offVec + newPosition localName = string.replaceSharpWithPadding(name, i) self.tra[localName] = transform.getTransformFromPos( newPosition) return True
def addBlade(self, name, parentPos, parentDir): """Add a blade object to the guide. This mehod can initialize the object or draw it. Blade object is a 3points curve to define a plan in the guide. Args: name (str): Local name of the element. parentPos (dagNode): The parent of the element. parentDir (dagNode): The direction constraint of the element. Returns: dagNode: The created blade curve. """ if name not in self.blades.keys(): self.blades[name] = vector.Blade( transform.getTransformFromPos(datatypes.Vector(0, 0, 0))) offset = False else: offset = True dist = .6 * self.root.attr("scaleX").get() blade = icon.guideBladeIcon(parent=parentPos, name=self.getName(name), lenX=dist, color=13, m=self.blades[name].transform) aim_cns = applyop.aimCns(blade, parentDir, axis="xy", wupType=2, wupVector=[0, 1, 0], wupObject=self.root, maintainOffset=offset) pm.pointConstraint(parentPos, blade) offsetAttr = attribute.addAttribute(blade, "bladeRollOffset", "float", aim_cns.attr("offsetX").get()) pm.connectAttr(offsetAttr, aim_cns.attr("offsetX")) attribute.lockAttribute(blade) return blade
def addObjects(self): """Add all the objects needed to create the component.""" self.WIP = self.options["mode"] self.normal = self.getNormalFromPos(self.guide.apos) self.binormal = self.getBiNormalFromPos(self.guide.apos) self.length0 = vector.getDistance(self.guide.apos[0], self.guide.apos[1]) self.length1 = vector.getDistance(self.guide.apos[1], self.guide.apos[2]) self.length2 = vector.getDistance(self.guide.apos[2], self.guide.apos[3]) # 1 bone chain for upv ref self.armChainUpvRef = primitive.add2DChain( self.root, self.getName("armUpvRef%s_jnt"), [self.guide.apos[0], self.guide.apos[2]], self.normal, False, self.WIP) negateOri = self.armChainUpvRef[1].getAttr("jointOrientZ") * -1 self.armChainUpvRef[1].setAttr("jointOrientZ", negateOri) # FK Controlers ----------------------------------- t = transform.getTransformLookingAt(self.guide.apos[0], self.guide.apos[1], self.normal, "xz", self.negate) self.fk0_npo = primitive.addTransform(self.root, self.getName("fk0_npo"), t) vec_po = datatypes.Vector(.5 * self.length0 * self.n_factor, 0, 0) self.fk0_ctl = self.addCtl(self.fk0_npo, "fk0_ctl", t, self.color_fk, "cube", w=self.length0, h=self.size * .1, d=self.size * .1, po=vec_po, tp=self.parentCtlTag) attribute.setKeyableAttributes( self.fk0_ctl, ["tx", "ty", "tz", "ro", "rx", "ry", "rz", "sx"]) t = transform.getTransformLookingAt(self.guide.apos[1], self.guide.apos[2], self.normal, "xz", self.negate) self.fk1_npo = primitive.addTransform(self.fk0_ctl, self.getName("fk1_npo"), t) vec_po = datatypes.Vector(.5 * self.length1 * self.n_factor, 0, 0) self.fk1_ctl = self.addCtl(self.fk1_npo, "fk1_ctl", t, self.color_fk, "cube", w=self.length1, h=self.size * .1, d=self.size * .1, po=vec_po, tp=self.fk0_ctl) attribute.setKeyableAttributes( self.fk1_ctl, ["tx", "ty", "tz", "ro", "rx", "ry", "rz", "sx"]) t = transform.getTransformLookingAt(self.guide.apos[2], self.guide.apos[3], self.normal, "xz", self.negate) # Define the wrist transform (wt) if self.settings["guideOrientWrist"]: wt = self.guide.tra["wrist"] if self.settings["mirrorIK"] and self.negate: scl = [1, 1, -1] else: scl = [1, 1, 1] wt = transform.setMatrixScale(wt, scl) t = wt self.fk2_npo = primitive.addTransform(self.fk1_ctl, self.getName("fk2_npo"), t) vec_po = datatypes.Vector(.5 * self.length2 * self.n_factor, 0, 0) self.fk2_ctl = self.addCtl(self.fk2_npo, "fk2_ctl", t, self.color_fk, "cube", w=self.length2, h=self.size * .1, d=self.size * .1, po=vec_po, tp=self.fk1_ctl) attribute.setKeyableAttributes(self.fk2_ctl) self.fk_ctl = [self.fk0_ctl, self.fk1_ctl, self.fk2_ctl] for x in self.fk_ctl: attribute.setInvertMirror(x, ["tx", "ty", "tz"]) # IK upv --------------------------------- # create tip point self.tip_ref = primitive.addTransform( self.armChainUpvRef[0], self.getName("tip_ref"), self.armChainUpvRef[0].getMatrix(worldSpace=True)) # create interpolate obj self.interpolate_lvl = primitive.addTransform( self.armChainUpvRef[0], self.getName("int_lvl"), self.armChainUpvRef[0].getMatrix(worldSpace=True)) # create roll npo and ctl self.roll_ctl_npo = primitive.addTransform( self.root, self.getName("roll_ctl_npo"), self.armChainUpvRef[0].getMatrix(worldSpace=True)) if self.negate: off_x = -1.5708 else: off_x = 1.5708 off_y = 1.5708 self.roll_ctl = self.addCtl(self.roll_ctl_npo, "roll_ctl", transform.getTransform(self.roll_ctl_npo), self.color_ik, "compas", w=self.size * .3, ro=datatypes.Vector([off_x, off_y, 0]), tp=self.parentCtlTag) attribute.setKeyableAttributes(self.roll_ctl, ["rx"]) # create upv control v = self.guide.apos[2] - self.guide.apos[0] v = self.normal ^ v v.normalize() v *= self.size * .8 v += self.guide.apos[1] self.upv_cns = primitive.addTransformFromPos(self.root, self.getName("upv_cns"), v) self.upv_ctl = self.addCtl(self.upv_cns, "upv_ctl", transform.getTransform(self.upv_cns), self.color_ik, "diamond", w=self.size * .12, tp=self.parentCtlTag) if self.settings["mirrorMid"]: if self.negate: self.upv_cns.rz.set(180) self.upv_cns.sy.set(-1) else: attribute.setInvertMirror(self.upv_ctl, ["tx"]) attribute.setKeyableAttributes(self.upv_ctl, self.t_params) # IK Controlers ----------------------------------- self.ik_cns = primitive.addTransformFromPos(self.root, self.getName("ik_cns"), self.guide.pos["wrist"]) t = transform.getTransformFromPos(self.guide.pos["wrist"]) if self.settings["guideOrientWrist"]: t = wt self.ik_cns.setMatrix(t) self.ik_cns.setTranslation(self.guide.pos["wrist"], space="world") self.ikcns_ctl = self.addCtl(self.ik_cns, "ikcns_ctl", t, self.color_ik, "null", w=self.size * .12, tp=self.parentCtlTag) attribute.setInvertMirror(self.ikcns_ctl, ["tx", "ty", "tz"]) if self.negate: m = transform.getTransformLookingAt(self.guide.pos["wrist"], self.guide.pos["eff"], self.normal, "x-y", True) else: m = transform.getTransformLookingAt(self.guide.pos["wrist"], self.guide.pos["eff"], self.normal, "xy", False) if self.settings["guideOrientWrist"]: m = wt self.ik_ctl = self.addCtl(self.ikcns_ctl, "ik_ctl", m, self.color_ik, "cube", w=self.size * .12, h=self.size * .12, d=self.size * .12, tp=self.roll_ctl) if self.settings["mirrorIK"]: if self.negate: self.ik_cns.sx.set(-1) self.ik_ctl.rz.set(self.ik_ctl.rz.get() * -1) else: attribute.setInvertMirror(self.ik_ctl, ["tx", "ry", "rz"]) attribute.setKeyableAttributes(self.ik_ctl) self.ik_ctl_ref = primitive.addTransform(self.ik_ctl, self.getName("ikCtl_ref"), m) # IK rotation controls if self.settings["ikTR"]: self.ikRot_npo = primitive.addTransform(self.root, self.getName("ikRot_npo"), m) self.ikRot_cns = primitive.addTransform(self.ikRot_npo, self.getName("ikRot_cns"), m) self.ikRot_ctl = self.addCtl(self.ikRot_cns, "ikRot_ctl", m, self.color_ik, "sphere", w=self.size * .12, tp=self.ik_ctl) attribute.setKeyableAttributes(self.ikRot_ctl, self.r_params) # References -------------------------------------- # Calculate again the transfor for the IK ref. This way align with FK trnIK_ref = transform.getTransformLookingAt(self.guide.pos["wrist"], self.guide.pos["eff"], self.normal, "xz", self.negate) if self.settings["guideOrientWrist"]: trnIK_ref = wt self.ik_ref = primitive.addTransform(self.ik_ctl_ref, self.getName("ik_ref"), trnIK_ref) self.fk_ref = primitive.addTransform(self.fk_ctl[2], self.getName("fk_ref"), trnIK_ref) # Chain -------------------------------------------- # The outputs of the ikfk2bone solver self.bone0 = primitive.addLocator( self.root, self.getName("0_bone"), transform.getTransform(self.fk_ctl[0])) self.bone0_shp = self.bone0.getShape() self.bone0_shp.setAttr("localPositionX", self.n_factor * .5) self.bone0_shp.setAttr("localScale", .5, 0, 0) self.bone0.setAttr("sx", self.length0) self.bone0.setAttr("visibility", False) self.bone1 = primitive.addLocator( self.root, self.getName("1_bone"), transform.getTransform(self.fk_ctl[1])) self.bone1_shp = self.bone1.getShape() self.bone1_shp.setAttr("localPositionX", self.n_factor * .5) self.bone1_shp.setAttr("localScale", .5, 0, 0) self.bone1.setAttr("sx", self.length1) self.bone1.setAttr("visibility", False) self.ctrn_loc = primitive.addTransformFromPos(self.root, self.getName("ctrn_loc"), self.guide.apos[1]) self.eff_loc = primitive.addTransformFromPos(self.root, self.getName("eff_loc"), self.guide.apos[2]) # Mid Controler ------------------------------------ t = transform.getTransform(self.ctrn_loc) self.mid_cns = primitive.addTransform(self.ctrn_loc, self.getName("mid_cns"), t) self.mid_ctl = self.addCtl(self.mid_cns, "mid_ctl", t, self.color_ik, "sphere", w=self.size * .2, tp=self.parentCtlTag) attribute.setKeyableAttributes( self.mid_ctl, params=["tx", "ty", "tz", "ro", "rx", "ry", "rz", "sx"]) if self.settings["mirrorMid"]: if self.negate: self.mid_cns.rz.set(180) self.mid_cns.sz.set(-1) self.mid_ctl_twst_npo = primitive.addTransform( self.mid_ctl, self.getName("mid_twst_npo"), t) self.mid_ctl_twst_ref = primitive.addTransform( self.mid_ctl_twst_npo, self.getName("mid_twst_ref"), t) else: self.mid_ctl_twst_ref = self.mid_ctl attribute.setInvertMirror(self.mid_ctl, ["tx", "ty", "tz"]) # Roll join ref self.rollRef = primitive.add2DChain(self.root, self.getName("rollChain"), self.guide.apos[:2], self.normal, self.negate) for x in self.rollRef: x.setAttr("visibility", False) self.tws0_loc = primitive.addTransform( self.rollRef[0], self.getName("tws0_loc"), transform.getTransform(self.fk_ctl[0])) self.tws0_rot = primitive.addTransform( self.tws0_loc, self.getName("tws0_rot"), transform.getTransform(self.fk_ctl[0])) self.tws1_npo = primitive.addTransform( self.ctrn_loc, self.getName("tws1_npo"), transform.getTransform(self.ctrn_loc)) self.tws1_loc = primitive.addTransform( self.tws1_npo, self.getName("tws1_loc"), transform.getTransform(self.ctrn_loc)) self.tws1_rot = primitive.addTransform( self.tws1_loc, self.getName("tws1_rot"), transform.getTransform(self.ctrn_loc)) # thickness control self.thick_lvl = primitive.addTransform( self.mid_ctl, self.getName("thickness_lvl"), transform.getTransform(self.ctrn_loc)) self.thick_ctl = self.addCtl(self.thick_lvl, "thickness_ctl", transform.getTransform(self.mid_ctl), self.color_ik, "arrow", w=self.size * .1, ro=datatypes.Vector([0, 1.5708, 0]), tp=self.mid_ctl) if self.negate and not self.settings["mirrorMid"]: self.thick_ctl.rz.set(180) self.thick_ctl.sz.set(-1) attribute.setKeyableAttributes(self.thick_ctl, ["tx", "ty"]) self.tws1B_loc = primitive.addTransform( self.ctrn_loc, self.getName("tws1B_loc"), transform.getTransform(self.ctrn_loc)) self.tws1B_rot = primitive.addTransform( self.tws1B_loc, self.getName("tws1B_rot"), transform.getTransform(self.ctrn_loc)) self.tws2_npo = primitive.addTransform( self.root, self.getName("tws2_npo"), transform.getTransform(self.fk_ctl[2])) self.tws2_loc = primitive.addTransform( self.tws2_npo, self.getName("tws2_loc"), transform.getTransform(self.fk_ctl[2])) self.tws2_rot = primitive.addTransform( self.tws2_loc, self.getName("tws2_rot"), transform.getTransform(self.fk_ctl[2])) # angle reader ---------------------------------------- t = transform.getTransformLookingAt(self.guide.apos[1], self.guide.apos[2], self.normal, "xy") self.readerA = primitive.addTransform(self.root, self.getName("readerA_loc"), t) self.readerB = primitive.addTransform(self.readerA, self.getName("readerB_loc"), t) self.readerB.rotateOrder.set(2) # Divisions ---------------------------------------- # We have at least one division at the start, the end and one for the # elbow. + 2 for elbow angle control if self.settings["supportJoints"]: ej = 2 else: ej = 0 self.divisions = self.settings["div0"] + self.settings["div1"] + 3 + ej self.div_cns = [] if self.settings["extraTweak"]: tagP = self.parentCtlTag self.tweak_ctl = [] for i in range(self.divisions): div_cns = primitive.addTransform(self.root, self.getName("div%s_loc" % i)) self.div_cns.append(div_cns) if self.settings["extraTweak"]: t = transform.getTransform(div_cns) tweak_ctl = self.addCtl(div_cns, "tweak%s_ctl" % i, t, self.color_fk, "square", w=self.size * .15, d=self.size * .15, ro=datatypes.Vector([0, 0, 1.5708]), tp=tagP) attribute.setKeyableAttributes(tweak_ctl) tagP = tweak_ctl self.tweak_ctl.append(tweak_ctl) self.jnt_pos.append([tweak_ctl, i, None, False]) else: self.jnt_pos.append([div_cns, i]) # End reference ------------------------------------ # To help the deformation on the wrist self.jnt_pos.append([self.eff_loc, 'end']) # match IK FK references self.match_fk0_off = self.add_match_ref(self.fk_ctl[1], self.root, "matchFk0_npo", False) self.match_fk0 = self.add_match_ref(self.fk_ctl[0], self.match_fk0_off, "fk0_mth") self.match_fk1_off = self.add_match_ref(self.fk_ctl[2], self.root, "matchFk1_npo", False) self.match_fk1 = self.add_match_ref(self.fk_ctl[1], self.match_fk1_off, "fk1_mth") if self.settings["ikTR"]: reference = self.ikRot_ctl self.match_ikRot = self.add_match_ref(self.ikRot_ctl, self.fk2_ctl, "ikRot_mth") else: reference = self.ik_ctl self.match_fk2 = self.add_match_ref(self.fk_ctl[2], reference, "fk2_mth") self.match_ik = self.add_match_ref(self.ik_ctl, self.fk2_ctl, "ik_mth") self.match_ikUpv = self.add_match_ref(self.upv_ctl, self.fk0_ctl, "upv_mth") # add visual reference self.line_ref = icon.connection_display_curve( self.getName("visalRef"), [self.upv_ctl, self.mid_ctl])
def addObjects(self): # blades computation self.normal = self.guide.blades["blade"].z self.binormal = self.guide.blades["blade"].x self.fk_npo = [] self.fk_ctl = [] self.spring_cns = [] self.spring_aim = [] self.spring_lvl = [] self.spring_ref = [] self.spring_npo = [] self.spring_target = [] self.fk_local_out = [] self.fk_global_out = [] self.fk_global_ref = [] parent = self.root self.previousTag = self.parentCtlTag for i, t in enumerate( transform.getChainTransform(self.guide.apos, self.normal, self.negate)): dist = vector.getDistance(self.guide.apos[i], self.guide.apos[i + 1]) # output global_t = transform.setMatrixPosition( datatypes.Matrix(), transform.getPositionFromMatrix(t)) fk_global_out_npo = primitive.addTransform( parent, self.getName("fk%s_global_out_npo" % i), global_t) fk_global_out = primitive.addTransform( fk_global_out_npo, self.getName("fk%s_global_out" % i), global_t) self.fk_global_out.append(fk_global_out) fk_local_out_npo = primitive.addTransform( parent, self.getName("fk%s_local_out_npo" % i), t) fk_local_out = primitive.addTransform( fk_local_out_npo, self.getName("fk%s_local_out" % i), t) self.fk_local_out.append(fk_local_out) fk_npo = primitive.addTransform(parent, self.getName("fk%s_npo" % i), t) spring_aim = primitive.addTransform( fk_npo, self.getName("spring%s_aim" % i), t) spring_cns = primitive.addTransform( fk_npo, self.getName("spring%s_cns" % i), t) fk_ctl = self.addCtl(spring_cns, "fk%s_ctl" % i, t, self.color_fk, "cube", w=dist, h=self.size * .1, d=self.size * .1, po=datatypes.Vector(dist * .5 * self.n_factor, 0, 0), tp=self.previousTag, lp=False) self.previousTag = fk_ctl t = transform.getTransformFromPos(self.guide.apos[i + 1]) spring_npo = primitive.addTransform( parent, self.getName("spring%s_npo" % i), t) spring_target = primitive.addTransform( spring_npo, self.getName("spring%s" % i), t) parent = fk_ctl self.spring_cns.append(spring_cns) self.spring_aim.append(spring_aim) self.addToGroup(spring_cns, "PLOT") self.fk_npo.append(fk_npo) self.fk_ctl.append(fk_ctl) attribute.setKeyableAttributes(self.fk_ctl, self.tr_params) self.spring_target.append(spring_target) # fk global ref fk_global_ref = primitive.addTransform( fk_ctl, self.getName("fk%s_global_ref" % i), global_t) self.fk_global_ref.append(fk_global_ref) attribute.setKeyableAttributes(fk_global_ref, []) # Chain of deformers ------------------------------- self.loc = [] parent = self.root for i, t in enumerate( transform.getChainTransform(self.guide.apos, self.normal, self.negate)): loc = primitive.addTransform(parent, self.getName("%s_loc" % i), t) self.loc.append(loc) self.jnt_pos.append([loc, i]) parent = loc
def addObjects(self): """Add all the objects needed to create the component.""" t = transform.getTransformFromPos(self.guide.pos["root"]) self.eyeOver_npo = primitive.addTransform( self.root, self.getName("eyeOver_npo"), t) self.eyeOver_ctl = self.addCtl(self.eyeOver_npo, "Over_ctl", t, self.color_fk, "sphere", w=1 * self.size, tp=self.parentCtlTag) self.eye_npo = primitive.addTransform(self.root, self.getName("eye_npo"), t) self.eyeFK_ctl = self.addCtl(self.eye_npo, "fk_ctl", t, self.color_fk, "arrow", w=1 * self.size, tp=self.eyeOver_ctl) # look at t = transform.getTransformFromPos(self.guide.pos["look"]) self.ik_cns = primitive.addTransform( self.root, self.getName("ik_cns"), t) self.eyeIK_npo = primitive.addTransform( self.ik_cns, self.getName("ik_npo"), t) self.eyeIK_ctl = self.addCtl(self.eyeIK_npo, "ik_ctl", t, self.color_fk, "circle", w=.5 * self.size, tp=self.eyeFK_ctl, ro=datatypes.Vector([1.5708, 0, 0])) attribute.setKeyableAttributes(self.eyeIK_ctl, self.t_params) t = self.guide.tra["root"] self.pull_srt = primitive.addTransform(self.eyeOver_ctl, self.getName('pull_srt'), t) t = self.guide.tra["lids"] self.lids_srt = primitive.addTransform(self.pull_srt, self.getName('lids_srt'), t) if local: self.lids_srt.inheritsTransform.set(0) self.topLids=[] self.topEnds=[] self.btmLids=[] self.btmEnds=[] for key in ['topLid1', 'topLid2', 'topLid3', 'btmLid1', 'btmLid2', 'btmLid3']: pos = self.guide.pos['root'] # # Lookat should be (0, localPosY, localPosZ) * lids worldMtx # localV = datatypes.VectorN(self.guide.pos[key][0], self.guide.pos[key][1], self.guide.pos[key][2], 1.0) m = self.guide.tra['lids'] localV = localV*m.inverse() localV[0] = 0 localV = localV*self.guide.tra['lids'] lookat = datatypes.Vector(localV[0], localV[1], localV[2]) normal = mathUtils.getMatrixAxisAsVector(self.lids_srt.worldMatrix[0], 'y') t = transform.getTransformLookingAt(pos, lookat, normal, axis="zy", negate=False) node = (primitive.addTransform(self.lids_srt, self.getName('%s_srt' % key), t)) t = transform.setMatrixPosition(t, self.guide.pos[key]) end = (primitive.addTransform(node, self.getName('%s_end_srt' % key), t)) if 'top' in key: self.topLids.append(node) self.topEnds.append(end) else: self.btmLids.append(node) self.btmEnds.append(end) self.jnt_pos.append([self.eyeFK_ctl, "eye", "parent_relative_jnt"]) self.jnt_pos.append( [self.pull_srt, "eyePull", "parent_relative_jnt", False]) for end in self.topEnds + self.btmEnds: self.jnt_pos.append([end, end.name().replace('_end_srt', ''), "parent_relative_jnt"])
def rig(edge_loop="", up_vertex="", low_vertex="", name_prefix="", thickness=0.3, do_skin=True, rigid_loops=5, falloff_loops=8, head_joint=None, jaw_joint=None, parent_node=None, control_name="ctl", upper_lip_ctl=None, lower_lip_ctl=None): ###### # Var ###### FRONT_OFFSET = .02 NB_ROPE = 15 ################## # Helper functions ################## def setName(name, side="C", idx=None): namesList = [name_prefix, side, name] if idx is not None: namesList[1] = side + str(idx) name = "_".join(namesList) return name ############### # Checkers ############## # Loop if edge_loop: try: edge_loop = [pm.PyNode(e) for e in edge_loop.split(",")] except pm.MayaNodeError: pm.displayWarning( "Some of the edges listed in edge loop can not be found") return else: pm.displayWarning("Please set the edge loop first") return # Vertex if up_vertex: try: up_vertex = pm.PyNode(up_vertex) except pm.MayaNodeError: pm.displayWarning("%s can not be found" % up_vertex) return else: pm.displayWarning("Please set the upper lip central vertex") return if low_vertex: try: low_vertex = pm.PyNode(low_vertex) except pm.MayaNodeError: pm.displayWarning("%s can not be found" % low_vertex) return else: pm.displayWarning("Please set the lower lip central vertex") return # skinnign data if do_skin: if not head_joint: pm.displayWarning("Please set the Head Jnt or unCheck Compute " "Topological Autoskin") return else: try: head_joint = pm.PyNode(head_joint) except pm.MayaNodeError: pm.displayWarning( "Head Joint: %s can not be found" % head_joint ) return if not jaw_joint: pm.displayWarning("Please set the Jaw Jnt or unCheck Compute " "Topological Autoskin") return else: try: jaw_joint = pm.PyNode(jaw_joint) except pm.MayaNodeError: pm.displayWarning("Jaw Joint: %s can not be found" % jaw_joint) return # check if the rig already exist in the current scene if pm.ls(setName("root")): pm.displayWarning("The object %s already exist in the scene. Please " "choose another name prefix" % setName("root")) return ##################### # Root creation ##################### lips_root = primitive.addTransform(None, setName("root")) lipsCrv_root = primitive.addTransform(lips_root, setName("crvs")) lipsRope_root = primitive.addTransform(lips_root, setName("rope")) ##################### # Geometry ##################### geo = pm.listRelatives(edge_loop[0], parent=True)[0] ##################### # Groups ##################### try: ctlSet = pm.PyNode("rig_controllers_grp") except pm.MayaNodeError: pm.sets(n="rig_controllers_grp", em=True) ctlSet = pm.PyNode("rig_controllers_grp") try: defset = pm.PyNode("rig_deformers_grp") except pm.MayaNodeError: pm.sets(n="rig_deformers_grp", em=True) defset = pm.PyNode("rig_deformers_grp") ##################### # Curves creation ##################### # get extreme position using the outer loop extr_v = meshNavigation.getExtremeVertexFromLoop(edge_loop) upPos = extr_v[0] lowPos = extr_v[1] inPos = extr_v[2] outPos = extr_v[3] edgeList = extr_v[4] vertexList = extr_v[5] upPos = up_vertex lowPos = low_vertex # upper crv upLip_edgeRange = meshNavigation.edgeRangeInLoopFromMid(edgeList, upPos, inPos, outPos) upCrv = curve.createCuveFromEdges(upLip_edgeRange, setName("upperLip"), parent=lipsCrv_root) # store the closest vertex by curv cv index. To be use fo the auto skining upLip_closestVtxList = [] # offset upper lip Curve cvs = upCrv.getCVs(space="world") for i, cv in enumerate(cvs): closestVtx = meshNavigation.getClosestVertexFromTransform(geo, cv) upLip_closestVtxList.append(closestVtx) if i == 0: # we know the curv starts from right to left offset = [cv[0] - thickness, cv[1], cv[2] - thickness] elif i == len(cvs) - 1: offset = [cv[0] + thickness, cv[1], cv[2] - thickness] else: offset = [cv[0], cv[1] + thickness, cv[2]] upCrv.setCV(i, offset, space='world') # lower crv lowLip_edgeRange = meshNavigation.edgeRangeInLoopFromMid(edgeList, lowPos, inPos, outPos) lowCrv = curve.createCuveFromEdges(lowLip_edgeRange, setName("lowerLip"), parent=lipsCrv_root) lowLip_closestVtxList = [] # offset lower lip Curve cvs = lowCrv.getCVs(space="world") for i, cv in enumerate(cvs): closestVtx = meshNavigation.getClosestVertexFromTransform(geo, cv) lowLip_closestVtxList.append(closestVtx) if i == 0: # we know the curv starts from right to left offset = [cv[0] - thickness, cv[1], cv[2] - thickness] elif i == len(cvs) - 1: offset = [cv[0] + thickness, cv[1], cv[2] - thickness] else: # we populate the closest vertext list here to skipt the first # and latest point offset = [cv[0], cv[1] - thickness, cv[2]] lowCrv.setCV(i, offset, space='world') upCrv_ctl = curve.createCurveFromCurve(upCrv, setName("upCtl_crv"), nbPoints=7, parent=lipsCrv_root) lowCrv_ctl = curve.createCurveFromCurve(lowCrv, setName("lowCtl_crv"), nbPoints=7, parent=lipsCrv_root) upRope = curve.createCurveFromCurve(upCrv, setName("upRope_crv"), nbPoints=NB_ROPE, parent=lipsCrv_root) lowRope = curve.createCurveFromCurve(lowCrv, setName("lowRope_crv"), nbPoints=NB_ROPE, parent=lipsCrv_root) upCrv_upv = curve.createCurveFromCurve(upCrv, setName("upCrv_upv"), nbPoints=7, parent=lipsCrv_root) lowCrv_upv = curve.createCurveFromCurve(lowCrv, setName("lowCrv_upv"), nbPoints=7, parent=lipsCrv_root) upRope_upv = curve.createCurveFromCurve(upCrv, setName("upRope_upv"), nbPoints=NB_ROPE, parent=lipsCrv_root) lowRope_upv = curve.createCurveFromCurve(lowCrv, setName("lowRope_upv"), nbPoints=NB_ROPE, parent=lipsCrv_root) # offset upv curves for crv in [upCrv_upv, lowCrv_upv, upRope_upv, lowRope_upv]: cvs = crv.getCVs(space="world") for i, cv in enumerate(cvs): # we populate the closest vertext list here to skipt the first # and latest point offset = [cv[0], cv[1], cv[2] + FRONT_OFFSET] crv.setCV(i, offset, space='world') rigCrvs = [upCrv, lowCrv, upCrv_ctl, lowCrv_ctl, upRope, lowRope, upCrv_upv, lowCrv_upv, upRope_upv, lowRope_upv] for crv in rigCrvs: crv.attr("visibility").set(False) ################## # Joints ################## lvlType = "transform" # upper joints upperJoints = [] cvs = upCrv.getCVs(space="world") pm.progressWindow(title='Creating Upper Joints', progress=0, max=len(cvs)) for i, cv in enumerate(cvs): pm.progressWindow(e=True, step=1, status='\nCreating Joint for %s' % cv) oTransUpV = pm.PyNode(pm.createNode( lvlType, n=setName("upLipRopeUpv", idx=str(i).zfill(3)), p=lipsRope_root, ss=True)) oTrans = pm.PyNode( pm.createNode(lvlType, n=setName("upLipRope", idx=str(i).zfill(3)), p=lipsRope_root, ss=True)) oParam, oLength = curve.getCurveParamAtPosition(upRope, cv) uLength = curve.findLenghtFromParam(upRope, oParam) u = uLength / oLength applyop.pathCns( oTransUpV, upRope_upv, cnsType=False, u=u, tangent=False) cns = applyop.pathCns( oTrans, upRope, cnsType=False, u=u, tangent=False) cns.setAttr("worldUpType", 1) cns.setAttr("frontAxis", 0) cns.setAttr("upAxis", 1) pm.connectAttr(oTransUpV.attr("worldMatrix[0]"), cns.attr("worldUpMatrix")) # getting joint parent if head_joint and isinstance(head_joint, (str, string_types)): try: j_parent = pm.PyNode(head_joint) except pm.MayaNodeError: j_parent = False elif head_joint and isinstance(head_joint, pm.PyNode): j_parent = head_joint else: j_parent = False jnt = rigbits.addJnt(oTrans, noReplace=True, parent=j_parent) upperJoints.append(jnt) pm.sets(defset, add=jnt) pm.progressWindow(e=True, endProgress=True) # lower joints lowerJoints = [] cvs = lowCrv.getCVs(space="world") pm.progressWindow(title='Creating Lower Joints', progress=0, max=len(cvs)) for i, cv in enumerate(cvs): pm.progressWindow(e=True, step=1, status='\nCreating Joint for %s' % cv) oTransUpV = pm.PyNode(pm.createNode( lvlType, n=setName("lowLipRopeUpv", idx=str(i).zfill(3)), p=lipsRope_root, ss=True)) oTrans = pm.PyNode(pm.createNode( lvlType, n=setName("lowLipRope", idx=str(i).zfill(3)), p=lipsRope_root, ss=True)) oParam, oLength = curve.getCurveParamAtPosition(lowRope, cv) uLength = curve.findLenghtFromParam(lowRope, oParam) u = uLength / oLength applyop.pathCns(oTransUpV, lowRope_upv, cnsType=False, u=u, tangent=False) cns = applyop.pathCns(oTrans, lowRope, cnsType=False, u=u, tangent=False) cns.setAttr("worldUpType", 1) cns.setAttr("frontAxis", 0) cns.setAttr("upAxis", 1) pm.connectAttr(oTransUpV.attr("worldMatrix[0]"), cns.attr("worldUpMatrix")) # getting joint parent if jaw_joint and isinstance(jaw_joint, (str, string_types)): try: j_parent = pm.PyNode(jaw_joint) except pm.MayaNodeError: pass elif jaw_joint and isinstance(jaw_joint, pm.PyNode): j_parent = jaw_joint else: j_parent = False jnt = rigbits.addJnt(oTrans, noReplace=True, parent=j_parent) lowerJoints.append(jnt) pm.sets(defset, add=jnt) pm.progressWindow(e=True, endProgress=True) ################## # Controls ################## # Controls lists upControls = [] upVec = [] upNpo = [] lowControls = [] lowVec = [] lowNpo = [] # controls options axis_list = ["sx", "sy", "sz", "ro"] upCtlOptions = [["corner", "R", "square", 4, .05, axis_list], ["upOuter", "R", "circle", 14, .03, []], ["upInner", "R", "circle", 14, .03, []], ["upper", "C", "square", 4, .05, axis_list], ["upInner", "L", "circle", 14, .03, []], ["upOuter", "L", "circle", 14, .03, []], ["corner", "L", "square", 4, .05, axis_list]] lowCtlOptions = [["lowOuter", "R", "circle", 14, .03, []], ["lowInner", "R", "circle", 14, .03, []], ["lower", "C", "square", 4, .05, axis_list], ["lowInner", "L", "circle", 14, .03, []], ["lowOuter", "L", "circle", 14, .03, []]] params = ["tx", "ty", "tz", "rx", "ry", "rz"] # upper controls cvs = upCrv_ctl.getCVs(space="world") pm.progressWindow(title='Upper controls', progress=0, max=len(cvs)) v0 = transform.getTransformFromPos(cvs[0]) v1 = transform.getTransformFromPos(cvs[-1]) distSize = vector.getDistance(v0, v1) * 3 for i, cv in enumerate(cvs): pm.progressWindow(e=True, step=1, status='\nCreating control for%s' % cv) t = transform.getTransformFromPos(cv) # Get nearest joint for orientation of controls joints = upperJoints + lowerJoints nearest_joint = None nearest_distance = None for joint in joints: distance = vector.getDistance( transform.getTranslation(joint), cv ) if nearest_distance is None or distance < nearest_distance: nearest_distance = distance nearest_joint = joint if nearest_joint: t = transform.setMatrixPosition( transform.getTransform(nearest_joint), cv ) temp = primitive.addTransform( lips_root, setName("temp"), t ) temp.rx.set(0) t = transform.getTransform(temp) pm.delete(temp) oName = upCtlOptions[i][0] oSide = upCtlOptions[i][1] o_icon = upCtlOptions[i][2] color = upCtlOptions[i][3] wd = upCtlOptions[i][4] oPar = upCtlOptions[i][5] npo = primitive.addTransform(lips_root, setName("%s_npo" % oName, oSide), t) upNpo.append(npo) ctl = icon.create(npo, setName("%s_%s" % (oName, control_name), oSide), t, icon=o_icon, w=wd * distSize, d=wd * distSize, ro=datatypes.Vector(1.57079633, 0, 0), po=datatypes.Vector(0, 0, .07 * distSize), color=color) upControls.append(ctl) name_split = control_name.split("_") if len(name_split) == 2 and name_split[-1] == "ghost": pass else: pm.sets(ctlSet, add=ctl) attribute.addAttribute(ctl, "isCtl", "bool", keyable=False) attribute.setKeyableAttributes(ctl, params + oPar) upv = primitive.addTransform(ctl, setName("%s_upv" % oName, oSide), t) upv.attr("tz").set(FRONT_OFFSET) upVec.append(upv) if oSide == "R": npo.attr("sx").set(-1) pm.progressWindow(e=True, endProgress=True) # lower controls cvs = lowCrv_ctl.getCVs(space="world") pm.progressWindow(title='Lower controls', progress=0, max=len(cvs)) for i, cv in enumerate(cvs[1:-1]): pm.progressWindow(e=True, step=1, status='\nCreating control for%s' % cv) t = transform.getTransformFromPos(cv) # Get nearest joint for orientation of controls joints = upperJoints + lowerJoints nearest_joint = None nearest_distance = None for joint in joints: distance = vector.getDistance( transform.getTranslation(joint), cv ) if nearest_distance is None or distance < nearest_distance: nearest_distance = distance nearest_joint = joint if nearest_joint: t = transform.setMatrixPosition( transform.getTransform(nearest_joint), cv ) temp = primitive.addTransform( lips_root, setName("temp"), t ) temp.rx.set(0) t = transform.getTransform(temp) pm.delete(temp) oName = lowCtlOptions[i][0] oSide = lowCtlOptions[i][1] o_icon = lowCtlOptions[i][2] color = lowCtlOptions[i][3] wd = lowCtlOptions[i][4] oPar = lowCtlOptions[i][5] npo = primitive.addTransform(lips_root, setName("%s_npo" % oName, oSide), t) lowNpo.append(npo) ctl = icon.create(npo, setName("%s_%s" % (oName, control_name), oSide), t, icon=o_icon, w=wd * distSize, d=wd * distSize, ro=datatypes.Vector(1.57079633, 0, 0), po=datatypes.Vector(0, 0, .07 * distSize), color=color) lowControls.append(ctl) name_split = control_name.split("_") if len(name_split) == 2 and control_name.split("_")[-1] == "ghost": pass else: pm.sets(ctlSet, add=ctl) attribute.addAttribute(ctl, "isCtl", "bool", keyable=False) attribute.setKeyableAttributes(ctl, params + oPar) upv = primitive.addTransform(ctl, setName("%s_upv" % oName, oSide), t) upv.attr("tz").set(FRONT_OFFSET) lowVec.append(upv) if oSide == "R": npo.attr("sx").set(-1) pm.progressWindow(e=True, endProgress=True) # reparentig controls pm.parent(upNpo[1], lowNpo[0], upControls[0]) pm.parent(upNpo[2], upNpo[4], upControls[3]) pm.parent(upNpo[-2], lowNpo[-1], upControls[-1]) pm.parent(lowNpo[1], lowNpo[3], lowControls[2]) # Connecting control crvs with controls applyop.gear_curvecns_op(upCrv_ctl, upControls) applyop.gear_curvecns_op(lowCrv_ctl, [upControls[0]] + lowControls + [upControls[-1]]) applyop.gear_curvecns_op(upCrv_upv, upVec) applyop.gear_curvecns_op(lowCrv_upv, [upVec[0]] + lowVec + [upVec[-1]]) # adding wires pm.wire(upCrv, w=upCrv_ctl, dropoffDistance=[0, 1000]) pm.wire(lowCrv, w=lowCrv_ctl, dropoffDistance=[0, 1000]) pm.wire(upRope, w=upCrv_ctl, dropoffDistance=[0, 1000]) pm.wire(lowRope, w=lowCrv_ctl, dropoffDistance=[0, 1000]) pm.wire(upRope_upv, w=upCrv_upv, dropoffDistance=[0, 1000]) pm.wire(lowRope_upv, w=lowCrv_upv, dropoffDistance=[0, 1000]) # setting constrains # up cns_node = pm.parentConstraint(upControls[0], upControls[3], upControls[1].getParent(), mo=True, skipRotate=["x", "y", "z"]) cns_node.attr(upControls[0].name() + "W0").set(.75) cns_node.attr(upControls[3].name() + "W1").set(.25) cns_node.interpType.set(0) # noFlip cns_node = pm.parentConstraint(upControls[0], upControls[3], upControls[2].getParent(), mo=True, skipRotate=["x", "y", "z"]) cns_node.attr(upControls[0].name() + "W0").set(.25) cns_node.attr(upControls[3].name() + "W1").set(.75) cns_node.interpType.set(0) # noFlip cns_node = pm.parentConstraint(upControls[3], upControls[6], upControls[4].getParent(), mo=True, skipRotate=["x", "y", "z"]) cns_node.attr(upControls[3].name() + "W0").set(.75) cns_node.attr(upControls[6].name() + "W1").set(.25) cns_node.interpType.set(0) # noFlip cns_node = pm.parentConstraint(upControls[3], upControls[6], upControls[5].getParent(), mo=True, skipRotate=["x", "y", "z"]) cns_node.attr(upControls[3].name() + "W0").set(.25) cns_node.attr(upControls[6].name() + "W1").set(.75) cns_node.interpType.set(0) # noFlip # low cns_node = pm.parentConstraint(upControls[0], lowControls[2], lowControls[0].getParent(), mo=True, skipRotate=["x", "y", "z"]) cns_node.attr(upControls[0].name() + "W0").set(.75) cns_node.attr(lowControls[2].name() + "W1").set(.25) cns_node.interpType.set(0) # noFlip cns_node = pm.parentConstraint(upControls[0], lowControls[2], lowControls[1].getParent(), mo=True, skipRotate=["x", "y", "z"]) cns_node.attr(upControls[0].name() + "W0").set(.25) cns_node.attr(lowControls[2].name() + "W1").set(.75) cns_node.interpType.set(0) # noFlip cns_node = pm.parentConstraint(lowControls[2], upControls[6], lowControls[3].getParent(), mo=True, skipRotate=["x", "y", "z"]) cns_node.attr(lowControls[2].name() + "W0").set(.75) cns_node.attr(upControls[6].name() + "W1").set(.25) cns_node.interpType.set(0) # noFlip cns_node = pm.parentConstraint(lowControls[2], upControls[6], lowControls[4].getParent(), mo=True, skipRotate=["x", "y", "z"]) cns_node.attr(lowControls[2].name() + "W0").set(.25) cns_node.attr(upControls[6].name() + "W1").set(.75) cns_node.interpType.set(0) # noFlip ########################################### # Connecting rig ########################################### if parent_node: try: if isinstance(parent_node, string_types): parent_node = pm.PyNode(parent_node) parent_node.addChild(lips_root) except pm.MayaNodeError: pm.displayWarning("The Lips rig can not be parent to: %s. Maybe " "this object doesn't exist." % parent_node) if head_joint and jaw_joint: try: if isinstance(head_joint, string_types): head_joint = pm.PyNode(head_joint) except pm.MayaNodeError: pm.displayWarning("Head Joint or Upper Lip Joint %s. Can not be " "fount in the scene" % head_joint) return try: if isinstance(jaw_joint, string_types): jaw_joint = pm.PyNode(jaw_joint) except pm.MayaNodeError: pm.displayWarning("Jaw Joint or Lower Lip Joint %s. Can not be " "fount in the scene" % jaw_joint) return ref_ctls = [head_joint, jaw_joint] if upper_lip_ctl and lower_lip_ctl: try: if isinstance(upper_lip_ctl, string_types): upper_lip_ctl = pm.PyNode(upper_lip_ctl) except pm.MayaNodeError: pm.displayWarning("Upper Lip Ctl %s. Can not be " "fount in the scene" % upper_lip_ctl) return try: if isinstance(lower_lip_ctl, string_types): lower_lip_ctl = pm.PyNode(lower_lip_ctl) except pm.MayaNodeError: pm.displayWarning("Lower Lip Ctl %s. Can not be " "fount in the scene" % lower_lip_ctl) return ref_ctls = [upper_lip_ctl, lower_lip_ctl] # in order to avoid flips lets create a reference transform # also to avoid flips, set any multi target parentConstraint to noFlip ref_cns_list = [] print (ref_ctls) for cns_ref in ref_ctls: t = transform.getTransformFromPos( cns_ref.getTranslation(space='world')) ref = pm.createNode("transform", n=cns_ref.name() + "_cns", p=cns_ref, ss=True) ref.setMatrix(t, worldSpace=True) ref_cns_list.append(ref) # right corner connection cns_node = pm.parentConstraint(ref_cns_list[0], ref_cns_list[1], upControls[0].getParent(), mo=True) cns_node.interpType.set(0) # noFlip # left corner connection cns_node = pm.parentConstraint(ref_cns_list[0], ref_cns_list[1], upControls[-1].getParent(), mo=True) cns_node.interpType.set(0) # noFlip # up control connection cns_node = pm.parentConstraint(ref_cns_list[0], upControls[3].getParent(), mo=True) # low control connection cns_node = pm.parentConstraint(ref_cns_list[1], lowControls[2].getParent(), mo=True) ########################################### # Auto Skinning ########################################### if do_skin: # eyelid vertex rows totalLoops = rigid_loops + falloff_loops vertexLoopList = meshNavigation.getConcentricVertexLoop(vertexList, totalLoops) vertexRowList = meshNavigation.getVertexRowsFromLoops(vertexLoopList) # we set the first value 100% for the first initial loop skinPercList = [1.0] # we expect to have a regular grid topology for r in range(rigid_loops): for rr in range(2): skinPercList.append(1.0) increment = 1.0 / float(falloff_loops) # we invert to smooth out from 100 to 0 inv = 1.0 - increment for r in range(falloff_loops): for rr in range(2): if inv < 0.0: inv = 0.0 skinPercList.append(inv) inv -= increment # this loop add an extra 0.0 indices to avoid errors for r in range(10): for rr in range(2): skinPercList.append(0.0) # base skin if head_joint: try: head_joint = pm.PyNode(head_joint) except pm.MayaNodeError: pm.displayWarning( "Auto skin aborted can not find %s " % head_joint) return # Check if the object has a skinCluster objName = pm.listRelatives(geo, parent=True)[0] skinCluster = skin.getSkinCluster(objName) if not skinCluster: skinCluster = pm.skinCluster(head_joint, geo, tsb=True, nw=2, n='skinClsEyelid') lipsJoints = upperJoints + lowerJoints closestVtxList = upLip_closestVtxList + lowLip_closestVtxList pm.progressWindow(title='Auto skinning process', progress=0, max=len(lipsJoints)) for i, jnt in enumerate(lipsJoints): pm.progressWindow(e=True, step=1, status='\nSkinning %s' % jnt) skinCluster.addInfluence(jnt, weight=0) v = closestVtxList[i] for row in vertexRowList: if v in row: for i, rv in enumerate(row): # find the deformer with max value for each vertex w = pm.skinPercent(skinCluster, rv, query=True, value=True) transJoint = pm.skinPercent(skinCluster, rv, query=True, t=None) max_value = max(w) max_index = w.index(max_value) perc = skinPercList[i] t_value = [(jnt, perc), (transJoint[max_index], 1.0 - perc)] pm.skinPercent(skinCluster, rv, transformValue=t_value) pm.progressWindow(e=True, endProgress=True)
def addObjects(self): """Add all the objects needed to create the component.""" self.WIP = self.options["mode"] self.normal = self.getNormalFromPos(self.guide.apos) self.binormal = self.getBiNormalFromPos(self.guide.apos) self.length0 = vector.getDistance(self.guide.apos[0], self.guide.apos[1]) self.length1 = vector.getDistance(self.guide.apos[1], self.guide.apos[2]) self.length2 = vector.getDistance(self.guide.apos[2], self.guide.apos[3]) # 1 bone chain for upv ref self.legChainUpvRef = primitive.add2DChain( self.root, self.getName("legUpvRef%s_jnt"), [self.guide.apos[0], self.guide.apos[2]], self.normal, False, self.WIP) self.legChainUpvRef[1].setAttr( "jointOrientZ", self.legChainUpvRef[1].getAttr("jointOrientZ") * -1) # extra neutral pose t = transform.getTransformFromPos(self.guide.apos[0]) self.root_npo = primitive.addTransform(self.root, self.getName("root_npo"), t) self.root_ctl = self.addCtl(self.root_npo, "root_ctl", t, self.color_fk, "circle", w=self.length0 / 6, tp=self.parentCtlTag) # FK Controlers ----------------------------------- t = transform.getTransformLookingAt(self.guide.apos[0], self.guide.apos[1], self.normal, "xz", self.negate) self.fk0_npo = primitive.addTransform(self.root_ctl, self.getName("fk0_npo"), t) po_vec = datatypes.Vector(.5 * self.length0 * self.n_factor, 0, 0) self.fk0_ctl = self.addCtl(self.fk0_npo, "fk0_ctl", t, self.color_fk, "cube", w=self.length0, h=self.size * .1, d=self.size * .1, po=po_vec, tp=self.root_ctl) attribute.setKeyableAttributes( self.fk0_ctl, ["tx", "ty", "tz", "ro", "rx", "ry", "rz", "sx"]) t = transform.getTransformLookingAt(self.guide.apos[1], self.guide.apos[2], self.normal, "xz", self.negate) self.fk1_npo = primitive.addTransform(self.fk0_ctl, self.getName("fk1_npo"), t) po_vec = datatypes.Vector(.5 * self.length1 * self.n_factor, 0, 0) self.fk1_ctl = self.addCtl(self.fk1_npo, "fk1_ctl", t, self.color_fk, "cube", w=self.length1, h=self.size * .1, d=self.size * .1, po=po_vec, tp=self.fk0_ctl) attribute.setKeyableAttributes( self.fk1_ctl, ["tx", "ty", "tz", "ro", "rx", "ry", "rz", "sx"]) t = transform.getTransformLookingAt(self.guide.apos[2], self.guide.apos[3], self.normal, "xz", self.negate) self.fk2_npo = primitive.addTransform(self.fk1_ctl, self.getName("fk2_npo"), t) po_vec = datatypes.Vector(.5 * self.length2 * self.n_factor, 0, 0) self.fk2_ctl = self.addCtl(self.fk2_npo, "fk2_ctl", t, self.color_fk, "cube", w=self.length2, h=self.size * .1, d=self.size * .1, po=po_vec, tp=self.fk1_ctl) attribute.setKeyableAttributes(self.fk2_ctl) self.fk_ctl = [self.fk0_ctl, self.fk1_ctl, self.fk2_ctl] for x in self.fk_ctl: attribute.setInvertMirror(x, ["tx", "ty", "tz"]) # IK Controlers ----------------------------------- self.ik_cns = primitive.addTransformFromPos(self.root_ctl, self.getName("ik_cns"), self.guide.pos["ankle"]) self.ikcns_ctl = self.addCtl(self.ik_cns, "ikcns_ctl", transform.getTransformFromPos( self.guide.pos["ankle"]), self.color_ik, "null", w=self.size * .12, tp=self.root_ctl) attribute.setInvertMirror(self.ikcns_ctl, ["tx"]) m = transform.getTransformLookingAt(self.guide.pos["ankle"], self.guide.pos["eff"], self.x_axis, "zx", False) self.ik_ctl = self.addCtl(self.ikcns_ctl, "ik_ctl", transform.getTransformFromPos( self.guide.pos["ankle"]), self.color_ik, "cube", w=self.size * .12, h=self.size * .12, d=self.size * .12) attribute.setKeyableAttributes(self.ik_ctl) attribute.setRotOrder(self.ik_ctl, "XZY") attribute.setInvertMirror(self.ik_ctl, ["tx", "ry", "rz"]) # upv v = self.guide.apos[2] - self.guide.apos[0] v = self.normal ^ v v.normalize() v *= self.size * .5 v += self.guide.apos[1] self.upv_cns = primitive.addTransformFromPos(self.ik_ctl, self.getName("upv_cns"), v) self.upv_ctl = self.addCtl(self.upv_cns, "upv_ctl", transform.getTransform(self.upv_cns), self.color_ik, "diamond", w=self.size * .12, tp=self.root_ctl) self.add_controller_tag(self.ik_ctl, self.upv_ctl) if self.settings["mirrorMid"]: if self.negate: self.upv_cns.rz.set(180) self.upv_cns.sy.set(-1) else: attribute.setInvertMirror(self.upv_ctl, ["tx"]) attribute.setKeyableAttributes(self.upv_ctl, self.t_params) # References -------------------------------------- self.ik_ref = primitive.addTransform( self.ik_ctl, self.getName("ik_ref"), transform.getTransform(self.ik_ctl)) self.fk_ref = primitive.addTransform( self.fk_ctl[2], self.getName("fk_ref"), transform.getTransform(self.ik_ctl)) # Chain -------------------------------------------- # The outputs of the ikfk2bone solver self.bone0 = primitive.addLocator( self.root_ctl, self.getName("0_bone"), transform.getTransform(self.fk_ctl[0])) self.bone0_shp = self.bone0.getShape() self.bone0_shp.setAttr("localPositionX", self.n_factor * .5) self.bone0_shp.setAttr("localScale", .5, 0, 0) self.bone0.setAttr("sx", self.length0) self.bone0.setAttr("visibility", False) self.bone1 = primitive.addLocator( self.root_ctl, self.getName("1_bone"), transform.getTransform(self.fk_ctl[1])) self.bone1_shp = self.bone1.getShape() self.bone1_shp.setAttr("localPositionX", self.n_factor * .5) self.bone1_shp.setAttr("localScale", .5, 0, 0) self.bone1.setAttr("sx", self.length1) self.bone1.setAttr("visibility", False) self.ctrn_loc = primitive.addTransformFromPos(self.root_ctl, self.getName("ctrn_loc"), self.guide.apos[1]) self.eff_loc = primitive.addTransformFromPos(self.root_ctl, self.getName("eff_loc"), self.guide.apos[2]) # tws_ref t = transform.getRotationFromAxis(datatypes.Vector(0, -1, 0), self.normal, "xz", self.negate) t = transform.setMatrixPosition(t, self.guide.pos["ankle"]) # addind an npo parent transform to fix flip in Maya 2018.2 self.tws_npo = primitive.addTransform(self.eff_loc, self.getName("tws_npo"), t) self.tws_ref = primitive.addTransform(self.tws_npo, self.getName("tws_ref"), t) # Mid Controler ------------------------------------ t = transform.getTransform(self.ctrn_loc) self.mid_cns = primitive.addTransform(self.ctrn_loc, self.getName("mid_cns"), t) self.mid_ctl = self.addCtl(self.mid_cns, "mid_ctl", t, self.color_ik, "sphere", w=self.size * .2, tp=self.root_ctl) attribute.setKeyableAttributes( self.mid_ctl, params=["tx", "ty", "tz", "ro", "rx", "ry", "rz", "sx"]) if self.settings["mirrorMid"]: if self.negate: self.mid_cns.rz.set(180) self.mid_cns.sz.set(-1) else: attribute.setInvertMirror(self.mid_ctl, ["tx", "ty", "tz"]) # Twist references --------------------------------- x = datatypes.Vector(0, -1, 0) x = x * transform.getTransform(self.eff_loc) z = datatypes.Vector(self.normal.x, self.normal.y, self.normal.z) z = z * transform.getTransform(self.eff_loc) m = transform.getRotationFromAxis(x, z, "xz", self.negate) m = transform.setMatrixPosition(m, transform.getTranslation(self.ik_ctl)) self.rollRef = primitive.add2DChain(self.root, self.getName("rollChain"), self.guide.apos[:2], self.normal, self.negate, self.WIP) self.tws0_loc = primitive.addTransform( self.rollRef[0], self.getName("tws0_loc"), transform.getTransform(self.fk_ctl[0])) self.tws0_rot = primitive.addTransform( self.tws0_loc, self.getName("tws0_rot"), transform.getTransform(self.fk_ctl[0])) self.tws1_loc = primitive.addTransform( self.ctrn_loc, self.getName("tws1_loc"), transform.getTransform(self.ctrn_loc)) self.tws1_rot = primitive.addTransform( self.tws1_loc, self.getName("tws1_rot"), transform.getTransform(self.ctrn_loc)) # thickness control self.thick_lvl = primitive.addTransform( self.mid_ctl, self.getName("thickness_lvl"), transform.getTransform(self.ctrn_loc)) self.thick_ctl = self.addCtl(self.thick_lvl, "thickness_ctl", transform.getTransform(self.mid_ctl), self.color_ik, "arrow", w=self.size * .1, ro=datatypes.Vector([0, 1.5708, 0]), tp=self.mid_ctl) if self.negate and not self.settings["mirrorMid"]: self.thick_ctl.rz.set(180) self.thick_ctl.sz.set(-1) attribute.setKeyableAttributes(self.thick_ctl, ["tx", "ty"]) self.tws1B_loc = primitive.addTransform( self.ctrn_loc, self.getName("tws1B_loc"), transform.getTransform(self.ctrn_loc)) self.tws1B_rot = primitive.addTransform( self.tws1B_loc, self.getName("tws1B_rot"), transform.getTransform(self.ctrn_loc)) self.tws2_loc = primitive.addTransform( self.root_ctl, self.getName("tws2_loc"), transform.getTransform(self.tws_ref)) self.tws2_rot = primitive.addTransform( self.tws2_loc, self.getName("tws2_rot"), transform.getTransform(self.tws_ref)) self.tws2_rot.setAttr("sx", .001) # angle reader ---------------------------------------- t = transform.getTransformLookingAt(self.guide.apos[1], self.guide.apos[0], self.binormal, "yz") self.readerA = primitive.addTransform(self.root, self.getName("readerA_loc"), t) self.readerB = primitive.addTransform(self.readerA, self.getName("readerB_loc"), t) self.readerB.rotateOrder.set(2) # Divisions ---------------------------------------- # We have at least one division at the start, the end and one for # the elbow. + 2 for knee angle control if self.settings["supportJoints"]: ej = 2 else: ej = 0 self.divisions = self.settings["div0"] + self.settings["div1"] + 3 + ej self.div_cns = [] if self.settings["extraTweak"]: tagP = self.parentCtlTag self.tweak_ctl = [] for i in range(self.divisions): div_cns = primitive.addTransform(self.root_ctl, self.getName("div%s_loc" % i)) self.div_cns.append(div_cns) if self.settings["extraTweak"]: t = transform.getTransform(div_cns) tweak_ctl = self.addCtl(div_cns, "tweak%s_ctl" % i, t, self.color_fk, "square", w=self.size * .15, d=self.size * .15, ro=datatypes.Vector([0, 0, 1.5708]), tp=tagP) attribute.setKeyableAttributes(tweak_ctl) tagP = tweak_ctl self.tweak_ctl.append(tweak_ctl) self.jnt_pos.append([tweak_ctl, i, None, False]) else: self.jnt_pos.append([div_cns, i]) # End reference ------------------------------------ # To help the deformation on the ankle self.end_ref = primitive.addTransform(self.tws2_rot, self.getName("end_ref"), m) self.jnt_pos.append([self.end_ref, 'end']) # match IK FK references self.match_fk0_off = self.add_match_ref(self.fk_ctl[1], self.root, "matchFk0_npo", False) self.match_fk0 = self.add_match_ref(self.fk_ctl[0], self.match_fk0_off, "fk0_mth") self.match_fk1_off = self.add_match_ref(self.fk_ctl[2], self.root, "matchFk1_npo", False) self.match_fk1 = self.add_match_ref(self.fk_ctl[1], self.match_fk1_off, "fk1_mth") self.match_fk2 = self.add_match_ref(self.fk_ctl[2], self.ik_ctl, "fk2_mth") self.match_ik = self.add_match_ref(self.ik_ctl, self.fk2_ctl, "ik_mth") self.match_ikUpv = self.add_match_ref(self.upv_ctl, self.fk0_ctl, "upv_mth") # add visual reference self.line_ref = icon.connection_display_curve( self.getName("visalRef"), [self.upv_ctl, self.mid_ctl])
def _addControls(self, crv_ctl, option, sidecut): cvs = crv_ctl.getCVs(space="world") pm.progressWindow(title='controls', progress=0, max=len(cvs)) v0 = transform.getTransformFromPos(cvs[0]) v1 = transform.getTransformFromPos(cvs[-1]) distSize = vector.getDistance(v0, v1) * 3 npos = [] ctls = [] upvs = [] params = ["tx", "ty", "tz", "rx", "ry", "rz"] joints = self.upJoints + self.lowJoints iterator = enumerate(cvs) if sidecut: iterator = enumerate(cvs[1:-1]) for i, cv in iterator: pm.progressWindow(e=True, step=1, status='\nCreating control for%s' % cv) t = transform.getTransformFromPos(cv) # Get nearest joint for orientation of controls nearest_joint = None nearest_distance = None for joint in joints: distance = vector.getDistance(transform.getTranslation(joint), cv) if nearest_distance is None or distance < nearest_distance: nearest_distance = distance nearest_joint = joint if nearest_joint: t = transform.setMatrixPosition( transform.getTransform(nearest_joint), cv) temp = addTransform(self.root, self.getName("temp"), t) # temp.rx.set(0) t = transform.getTransform(temp) pm.delete(temp) # print(i, nearest_joint, temp) oName = option[i][0] oSide = option[i][1] o_icon = option[i][2] color = option[i][3] wd = option[i][4] oPar = option[i][5] if oSide == "R": scl = [1, 1, -1] else: scl = [1, 1, 1] t = transform.setMatrixScale(t, scl) npo = addTransform(self.root, self.getName("%s_npo" % oName, oSide), t) npos.append(npo) ctl = self.addCtl( npo, self.getName("{}_{}".format(oName, self.ctlName), oSide), t, color, o_icon, w=wd * distSize, d=wd * distSize, ro=datatypes.Vector(1.57079633, 0, 0), po=datatypes.Vector(0, 0, .07 * distSize), ) ctls.append(ctl) ymt_util.setKeyableAttributesDontLockVisibility(ctl, params + oPar) upv = addTransform(ctl, self.getName("%s_upv" % oName, oSide), t) upv.attr("tz").set(self.FRONT_OFFSET) upvs.append(upv) self.addToSubGroup(ctl, self.primaryControllersGroupName) pm.progressWindow(e=True, endProgress=True) return npos, ctls, upvs
def addObjects(self): """Add all the objects needed to create the component.""" self.WIP = self.options["mode"] self.normal = self.getNormalFromPos(self.guide.apos) self.length0 = vector.getDistance(self.guide.apos[0], self.guide.apos[1]) self.length1 = vector.getDistance(self.guide.apos[1], self.guide.apos[2]) self.length2 = vector.getDistance(self.guide.apos[2], self.guide.apos[3]) # 1 bone chain for upv ref self.legChainUpvRef = primitive.add2DChain( self.root, self.getName("legUpvRef%s_jnt"), [self.guide.apos[0], self.guide.apos[2]], self.normal, False, self.WIP) self.legChainUpvRef[1].setAttr( "jointOrientZ", self.legChainUpvRef[1].getAttr("jointOrientZ") * -1) # extra neutral pose t = transform.getTransformFromPos(self.guide.apos[0]) self.root_npo = primitive.addTransform(self.root, self.getName("root_npo"), t) self.root_ctl = self.addCtl(self.root_npo, "root_ctl", t, self.color_fk, "circle", w=self.length0 / 6, tp=self.parentCtlTag) # FK Controlers ----------------------------------- t = transform.getTransformLookingAt(self.guide.apos[0], self.guide.apos[1], self.normal, "xz", self.negate) self.fk0_npo = primitive.addTransform(self.root_ctl, self.getName("fk0_npo"), t) self.fk0_ctl = self.addCtl(self.fk0_npo, "fk0_ctl", t, self.color_fk, "cube", w=self.length0, h=self.size * .1, d=self.size * .1, po=datatypes.Vector( .5 * self.length0 * self.n_factor, 0, 0), tp=self.root_ctl) attribute.setKeyableAttributes( self.fk0_ctl, ["tx", "ty", "tz", "ro", "rx", "ry", "rz", "sx"]) t = transform.getTransformLookingAt(self.guide.apos[1], self.guide.apos[2], self.normal, "xz", self.negate) self.fk1_npo = primitive.addTransform(self.fk0_ctl, self.getName("fk1_npo"), t) self.fk1_ctl = self.addCtl(self.fk1_npo, "fk1_ctl", t, self.color_fk, "cube", w=self.length1, h=self.size * .1, d=self.size * .1, po=datatypes.Vector( .5 * self.length1 * self.n_factor, 0, 0), tp=self.fk0_ctl) attribute.setKeyableAttributes( self.fk1_ctl, ["tx", "ty", "tz", "ro", "rx", "ry", "rz", "sx"]) t = transform.getTransformLookingAt(self.guide.apos[2], self.guide.apos[3], self.normal, "xz", self.negate) self.fk2_npo = primitive.addTransform(self.fk1_ctl, self.getName("fk2_npo"), t) self.fk2_ctl = self.addCtl(self.fk2_npo, "fk2_ctl", t, self.color_fk, "cube", w=self.length2, h=self.size * .1, d=self.size * .1, po=datatypes.Vector( .5 * self.length2 * self.n_factor, 0, 0), tp=self.fk1_ctl) attribute.setKeyableAttributes(self.fk2_ctl) self.fk_ctl = [self.fk0_ctl, self.fk1_ctl, self.fk2_ctl] for x in self.fk_ctl: attribute.setInvertMirror(x, ["tx", "ty", "tz"]) # IK Controlers ----------------------------------- self.ik_cns = primitive.addTransformFromPos(self.root_ctl, self.getName("ik_cns"), self.guide.pos["ankle"]) self.ikcns_ctl = self.addCtl(self.ik_cns, "ikcns_ctl", transform.getTransformFromPos( self.guide.pos["ankle"]), self.color_ik, "null", w=self.size * .12, tp=self.root_ctl) attribute.setInvertMirror(self.ikcns_ctl, ["tx"]) m = transform.getTransformLookingAt(self.guide.pos["ankle"], self.guide.pos["eff"], self.x_axis, "zx", False) self.ik_ctl = self.addCtl(self.ikcns_ctl, "ik_ctl", transform.getTransformFromPos( self.guide.pos["ankle"]), self.color_ik, "cube", w=self.size * .12, h=self.size * .12, d=self.size * .12, tp=self.ikcns_ctl) attribute.setKeyableAttributes(self.ik_ctl) attribute.setRotOrder(self.ik_ctl, "XZY") attribute.setInvertMirror(self.ik_ctl, ["tx", "ry", "rz"]) # upv v = self.guide.apos[2] - self.guide.apos[0] v = self.normal ^ v v.normalize() v *= self.size * .5 v += self.guide.apos[1] self.upv_cns = primitive.addTransformFromPos(self.ik_ctl, self.getName("upv_cns"), v) self.upv_ctl = self.addCtl(self.upv_cns, "upv_ctl", transform.getTransform(self.upv_cns), self.color_ik, "diamond", w=self.size * .12, tp=self.root_ctl) if self.settings["mirrorMid"]: if self.negate: self.upv_cns.rz.set(180) self.upv_cns.sy.set(-1) else: attribute.setInvertMirror(self.upv_ctl, ["tx"]) attribute.setKeyableAttributes(self.upv_ctl, self.t_params) # References -------------------------------------- self.ik_ref = primitive.addTransform( self.ik_ctl, self.getName("ik_ref"), transform.getTransform(self.ik_ctl)) self.fk_ref = primitive.addTransform( self.fk_ctl[2], self.getName("fk_ref"), transform.getTransform(self.ik_ctl)) # Chain -------------------------------------------- # The outputs of the ikfk2bone solver self.bone0 = primitive.addLocator( self.root_ctl, self.getName("0_bone"), transform.getTransform(self.fk_ctl[0])) self.bone0_shp = self.bone0.getShape() self.bone0_shp.setAttr("localPositionX", self.n_factor * .5) self.bone0_shp.setAttr("localScale", .5, 0, 0) self.bone0.setAttr("sx", self.length0) self.bone0.setAttr("visibility", False) self.bone1 = primitive.addLocator( self.root_ctl, self.getName("1_bone"), transform.getTransform(self.fk_ctl[1])) self.bone1_shp = self.bone1.getShape() self.bone1_shp.setAttr("localPositionX", self.n_factor * .5) self.bone1_shp.setAttr("localScale", .5, 0, 0) self.bone1.setAttr("sx", self.length1) self.bone1.setAttr("visibility", False) tA = transform.getTransformLookingAt(self.guide.apos[0], self.guide.apos[1], self.normal, "xz", self.negate) tA = transform.setMatrixPosition(tA, self.guide.apos[1]) tB = transform.getTransformLookingAt(self.guide.apos[1], self.guide.apos[2], self.normal, "xz", self.negate) t = transform.getInterpolateTransformMatrix(tA, tB) self.ctrn_loc = primitive.addTransform(self.root, self.getName("ctrn_loc"), t) self.eff_loc = primitive.addTransformFromPos(self.root_ctl, self.getName("eff_loc"), self.guide.apos[2]) # tws_ref t = transform.getRotationFromAxis(datatypes.Vector(0, -1, 0), self.normal, "xz", self.negate) t = transform.setMatrixPosition(t, self.guide.pos["ankle"]) self.tws_ref = primitive.addTransform(self.eff_loc, self.getName("tws_ref"), t) # Mid Controler ------------------------------------ t = transform.getTransform(self.ctrn_loc) self.mid_cns = primitive.addTransform(self.ctrn_loc, self.getName("mid_cns"), t) self.mid_ctl = self.addCtl(self.mid_cns, "mid_ctl", t, self.color_ik, "sphere", w=self.size * .2, tp=self.root_ctl) if self.settings["mirrorMid"]: if self.negate: self.mid_cns.rz.set(180) self.mid_cns.sz.set(-1) else: attribute.setInvertMirror(self.mid_ctl, ["tx", "ty", "tz"]) attribute.setKeyableAttributes(self.mid_ctl, self.t_params) # Twist references --------------------------------- x = datatypes.Vector(0, -1, 0) x = x * transform.getTransform(self.eff_loc) z = datatypes.Vector(self.normal.x, self.normal.y, self.normal.z) z = z * transform.getTransform(self.eff_loc) m = transform.getRotationFromAxis(x, z, "xz", self.negate) m = transform.setMatrixPosition(m, transform.getTranslation(self.ik_ctl)) self.tws0_loc = primitive.addTransform( self.root_ctl, self.getName("tws0_loc"), transform.getTransform(self.fk_ctl[0])) self.tws0_rot = primitive.addTransform( self.tws0_loc, self.getName("tws0_rot"), transform.getTransform(self.fk_ctl[0])) self.tws1_loc = primitive.addTransform( self.ctrn_loc, self.getName("tws1_loc"), transform.getTransform(self.ctrn_loc)) self.tws1_rot = primitive.addTransform( self.tws1_loc, self.getName("tws1_rot"), transform.getTransform(self.ctrn_loc)) self.tws1A_npo = primitive.addTransform(self.mid_ctl, self.getName("tws1A_npo"), tA) self.tws1A_loc = primitive.addTransform(self.tws1A_npo, self.getName("tws1A_loc"), tA) self.tws1B_npo = primitive.addTransform(self.mid_ctl, self.getName("tws1B_npo"), tB) self.tws1B_loc = primitive.addTransform(self.tws1B_npo, self.getName("tws1B_loc"), tB) self.tws2_npo = primitive.addTransform( self.root, self.getName("tws2_npo"), transform.getTransform(self.fk_ctl[2])) self.tws2_loc = primitive.addTransform( self.tws2_npo, self.getName("tws2_loc"), transform.getTransform(self.fk_ctl[2])) self.tws2_rot = primitive.addTransform( self.tws2_npo, self.getName("tws2_rot"), transform.getTransform(self.fk_ctl[2])) # Roll twist chain --------------------------------- # Arm self.uplegChainPos = [] ii = 1.0 / (self.settings["div0"] + 1) i = 0.0 for p in range(self.settings["div0"] + 2): self.uplegChainPos.append( vector.linearlyInterpolate(self.guide.pos["root"], self.guide.pos["knee"], blend=i)) i = i + ii self.uplegTwistChain = primitive.add2DChain( self.root, self.getName("uplegTwist%s_jnt"), self.uplegChainPos, self.normal, False, self.WIP) # Forearm self.lowlegChainPos = [] ii = 1.0 / (self.settings["div1"] + 1) i = 0.0 for p in range(self.settings["div1"] + 2): self.lowlegChainPos.append( vector.linearlyInterpolate(self.guide.pos["knee"], self.guide.pos["ankle"], blend=i)) i = i + ii self.lowlegTwistChain = primitive.add2DChain( self.root, self.getName("lowlegTwist%s_jnt"), self.lowlegChainPos, self.normal, False, self.WIP) pm.parent(self.lowlegTwistChain[0], self.mid_ctl) # Hand Aux chain and nonroll self.auxChainPos = [] ii = .5 i = 0.0 for p in range(3): self.auxChainPos.append( vector.linearlyInterpolate(self.guide.pos["ankle"], self.guide.pos["eff"], blend=i)) i = i + ii t = self.root.getMatrix(worldSpace=True) self.aux_npo = primitive.addTransform(self.root, self.getName("aux_npo"), t) self.auxTwistChain = primitive.add2DChain( self.aux_npo, self.getName("auxTwist%s_jnt"), self.lowlegChainPos[:3], self.normal, False, self.WIP) # Non Roll join ref --------------------------------- self.uplegRollRef = primitive.add2DChain( self.root, self.getName("uplegRollRef%s_jnt"), self.uplegChainPos[:2], self.normal, False, self.WIP) self.lowlegRollRef = primitive.add2DChain( self.aux_npo, self.getName("lowlegRollRef%s_jnt"), self.lowlegChainPos[:2], self.normal, False, self.WIP) # Divisions ---------------------------------------- # We have at least one division at the start, the end and one for the # elbow. + 2 for knee angle control self.divisions = self.settings["div0"] + self.settings["div1"] + 4 self.div_cns = [] for i in range(self.divisions): div_cns = primitive.addTransform(self.root_ctl, self.getName("div%s_loc" % i)) self.div_cns.append(div_cns) self.jnt_pos.append([div_cns, i]) # End reference ------------------------------------ # To help the deformation on the ankle self.end_ref = primitive.addTransform(self.eff_loc, self.getName("end_ref"), m) for a in "xyz": self.end_ref.attr("s%s" % a).set(1.0) if self.negate: self.end_ref.attr("ry").set(-180.0) self.jnt_pos.append([self.end_ref, 'end']) # Tangent controls t = transform.getInterpolateTransformMatrix(self.fk_ctl[0], self.tws1A_npo, .5) self.uplegTangentA_loc = primitive.addTransform( self.root_ctl, self.getName("uplegTangentA_loc"), self.fk_ctl[0].getMatrix(worldSpace=True)) self.uplegTangentA_npo = primitive.addTransform( self.uplegTangentA_loc, self.getName("uplegTangentA_npo"), t) self.uplegTangentA_ctl = self.addCtl(self.uplegTangentA_npo, "uplegTangentA_ctl", t, self.color_ik, "circle", w=self.size * .2, ro=datatypes.Vector( 0, 0, 1.570796), tp=self.mid_ctl) if self.negate: self.uplegTangentA_npo.rz.set(180) self.uplegTangentA_npo.sz.set(-1) attribute.setKeyableAttributes(self.uplegTangentA_ctl, self.t_params) t = transform.getInterpolateTransformMatrix(self.fk_ctl[0], self.tws1A_npo, .9) self.uplegTangentB_npo = primitive.addTransform( self.tws1A_loc, self.getName("uplegTangentB_npo"), t) self.uplegTangentB_ctl = self.addCtl(self.uplegTangentB_npo, "uplegTangentB_ctl", t, self.color_ik, "circle", w=self.size * .1, ro=datatypes.Vector( 0, 0, 1.570796), tp=self.mid_ctl) if self.negate: self.uplegTangentB_npo.rz.set(180) self.uplegTangentB_npo.sz.set(-1) attribute.setKeyableAttributes(self.uplegTangentB_ctl, self.t_params) tC = self.tws1B_npo.getMatrix(worldSpace=True) tC = transform.setMatrixPosition(tC, self.guide.apos[2]) t = transform.getInterpolateTransformMatrix(self.tws1B_npo, tC, .1) self.lowlegTangentA_npo = primitive.addTransform( self.tws1B_loc, self.getName("lowlegTangentA_npo"), t) self.lowlegTangentA_ctl = self.addCtl(self.lowlegTangentA_npo, "lowlegTangentA_ctl", t, self.color_ik, "circle", w=self.size * .1, ro=datatypes.Vector( 0, 0, 1.570796), tp=self.mid_ctl) if self.negate: self.lowlegTangentA_npo.rz.set(180) self.lowlegTangentA_npo.sz.set(-1) attribute.setKeyableAttributes(self.lowlegTangentA_ctl, self.t_params) t = transform.getInterpolateTransformMatrix(self.tws1B_npo, tC, .5) self.lowlegTangentB_loc = primitive.addTransform( self.root, self.getName("lowlegTangentB_loc"), tC) self.lowlegTangentB_npo = primitive.addTransform( self.lowlegTangentB_loc, self.getName("lowlegTangentB_npo"), t) self.lowlegTangentB_ctl = self.addCtl(self.lowlegTangentB_npo, "lowlegTangentB_ctl", t, self.color_ik, "circle", w=self.size * .2, ro=datatypes.Vector( 0, 0, 1.570796), tp=self.mid_ctl) if self.negate: self.lowlegTangentB_npo.rz.set(180) self.lowlegTangentB_npo.sz.set(-1) attribute.setKeyableAttributes(self.lowlegTangentB_ctl, self.t_params) t = self.mid_ctl.getMatrix(worldSpace=True) self.kneeTangent_npo = primitive.addTransform( self.mid_ctl, self.getName("kneeTangent_npo"), t) self.kneeTangent_ctl = self.addCtl(self.kneeTangent_npo, "kneeTangent_ctl", t, self.color_fk, "circle", w=self.size * .25, ro=datatypes.Vector(0, 0, 1.570796), tp=self.mid_ctl) if self.negate: self.kneeTangent_npo.rz.set(180) self.kneeTangent_npo.sz.set(-1) attribute.setKeyableAttributes(self.kneeTangent_ctl, self.t_params) # match IK FK references self.match_fk0_off = self.add_match_ref(self.fk_ctl[1], self.root, "matchFk0_npo", False) self.match_fk0 = self.add_match_ref(self.fk_ctl[0], self.match_fk0_off, "fk0_mth") self.match_fk1_off = self.add_match_ref(self.fk_ctl[2], self.root, "matchFk1_npo", False) self.match_fk1 = self.add_match_ref(self.fk_ctl[1], self.match_fk1_off, "fk1_mth") self.match_fk2 = self.add_match_ref(self.fk_ctl[2], self.ik_ctl, "fk2_mth") self.match_ik = self.add_match_ref(self.ik_ctl, self.fk2_ctl, "ik_mth") self.match_ikUpv = self.add_match_ref(self.upv_ctl, self.fk0_ctl, "upv_mth") # add visual reference self.line_ref = icon.connection_display_curve( self.getName("visalRef"), [self.upv_ctl, self.mid_ctl])
def addObjects(self): """Add all the objects needed to create the component.""" # jaw control t = transform.getTransformFromPos(self.guide.pos["jaw"]) self.ctl_npo = primitive.addTransform(self.root, self.getName("ctl_npo"), t) self.jaw_ctl = self.addCtl(self.ctl_npo, "jaw_ctl", t, self.color_fk, "circle", w=1 * self.size, ro=datatypes.Vector([1.5708, 0, 0]), tp=self.parentCtlTag) attribute.setKeyableAttributes(self.jaw_ctl, ["tx", "ty", "tz", "rz"]) # mouth center t = transform.getTransformFromPos(self.guide.pos["rotcenter"]) self.mouthCenter_npo = primitive.addTransform( self.root, self.getName("mouthCenter_npo"), t) self.mouthCenter = primitive.addTransform(self.mouthCenter_npo, self.getName("mouthCenter"), t) # jaw "UPPER" t = transform.getTransformFromPos(self.guide.pos["root"]) self.jawUp_npo = primitive.addTransform(self.mouthCenter, self.getName("jawUpper_npo"), t) self.jawUp_pos = primitive.addTransform(self.jawUp_npo, self.getName("jawUpper_pos"), t) self.jawUp_rot = primitive.addTransform(self.jawUp_pos, self.getName("jawUpper_rot"), t) # jaw "LOWER" t = transform.getTransformFromPos(self.guide.pos["root"]) self.jawLow_npo = primitive.addTransform(self.mouthCenter, self.getName("jaw_npo"), t) self.jawLow_pos = primitive.addTransform(self.jawLow_npo, self.getName("jawLow_pos"), t) self.jawLow_rot = primitive.addTransform(self.jawLow_pos, self.getName("jawLow_rot"), t) # lips t = transform.getTransformFromPos(self.guide.pos["lipup"]) self.lipup_npo = primitive.addTransform(self.jawUp_rot, self.getName("lipup_npo"), t) self.lipup_ctl = self.addCtl(self.lipup_npo, "lipup_ctl", t, self.color_fk, "square", d=.15 * self.size, w=1 * self.size, ro=datatypes.Vector([1.5708, 0, 0]), tp=self.jaw_ctl) t = transform.getTransformFromPos(self.guide.pos["liplow"]) self.liplow_npo = primitive.addTransform(self.jawLow_rot, self.getName("liplow_npo"), t) self.liplow_ctl = self.addCtl(self.liplow_npo, "liplow_ctl", t, self.color_fk, "square", d=.15 * self.size, w=1 * self.size, ro=datatypes.Vector([1.5708, 0, 0]), tp=self.jaw_ctl) # teeth t = transform.getTransformFromPos(self.guide.pos["lipup"]) self.teethup_npo = primitive.addTransform(self.jawUp_rot, self.getName("teethup_npo"), t) self.teethup_ctl = self.addCtl(self.teethup_npo, "teethup_ctl", t, self.color_ik, "square", d=.1 * self.size, w=.7 * self.size, ro=datatypes.Vector([1.5708, 0, 0]), tp=self.lipup_ctl) t = transform.getTransformFromPos(self.guide.pos["liplow"]) self.teethlow_npo = primitive.addTransform( self.jawLow_rot, self.getName("teethlow_npo"), t) self.teethlow_ctl = self.addCtl(self.teethlow_npo, "teethlow_ctl", t, self.color_ik, "square", d=.1 * self.size, w=.7 * self.size, ro=datatypes.Vector([1.5708, 0, 0]), tp=self.liplow_ctl) self.jnt_pos.append( [self.jawLow_rot, "jaw", "parent_relative_jnt", False]) self.jnt_pos.append( [self.lipup_ctl, "lipup", "parent_relative_jnt", False]) # relative 0 is the jaw jnt self.jnt_pos.append([self.liplow_ctl, "liplow", "jaw", False]) self.jnt_pos.append( [self.teethup_ctl, "teethup", "parent_relative_jnt", False]) self.jnt_pos.append([self.teethlow_ctl, "teethlow", "jaw", False])
def addObjects(self): """Add all the objects needed to create the component.""" self.setup = primitive.addTransformFromPos( self.setupWS, self.getName("WS")) attribute.lockAttribute(self.setup) self.WIP = self.options["mode"] self.normal = self.getNormalFromPos(self.guide.apos) self.length0 = vector.getDistance(self.guide.apos[0], self.guide.apos[1]) self.length1 = vector.getDistance(self.guide.apos[1], self.guide.apos[2]) self.length2 = vector.getDistance(self.guide.apos[2], self.guide.apos[3]) self.length3 = vector.getDistance(self.guide.apos[3], self.guide.apos[4]) # 3bones chain self.chain3bones = primitive.add2DChain( self.setup, self.getName("chain3bones%s_jnt"), self.guide.apos[0:4], self.normal, False, self.WIP) # 2bones chain self.chain2bones = primitive.add2DChain( self.setup, self.getName("chain2bones%s_jnt"), self.guide.apos[0:3], self.normal, False, self.WIP) # Leg chain self.legBones = primitive.add2DChain( self.root, self.getName("legBones%s_jnt"), self.guide.apos[0:4], self.normal, False, self.WIP) # Leg chain FK ref self.legBonesFK = primitive.add2DChain( self.root, self.getName("legFK%s_jnt"), self.guide.apos[0:4], self.normal, False, self.WIP) # Leg chain IK ref self.legBonesIK = primitive.add2DChain( self.root, self.getName("legIK%s_jnt"), self.guide.apos[0:4], self.normal, False, self.WIP) # 1 bone chain for upv ref self.legChainUpvRef = primitive.add2DChain( self.root, self.getName("legUpvRef%s_jnt"), [self.guide.apos[0], self.guide.apos[3]], self.normal, False, self.WIP) # mid joints self.mid1_jnt = primitive.addJoint( self.legBones[0], self.getName("mid1_jnt"), self.legBones[1].getMatrix(worldSpace=True), self.WIP) self.mid1_jnt.attr("radius").set(3) self.mid1_jnt.setAttr("jointOrient", 0, 0, 0) self.mid2_jnt = primitive.addJoint( self.legBones[1], self.getName("mid2_jnt"), self.legBones[2].getMatrix(worldSpace=True), self.WIP) self.mid2_jnt.attr("radius").set(3) self.mid2_jnt.setAttr("jointOrient", 0, 0, 0) # base Controlers ----------------------------------- t = transform.getTransformFromPos(self.guide.apos[0]) self.root_npo = primitive.addTransform( self.root, self.getName("root_npo"), t) self.root_ctl = self.addCtl(self.root_npo, "root_ctl", t, self.color_fk, "circle", w=self.length0 / 6, tp=self.parentCtlTag) attribute.lockAttribute(self.root_ctl, ["sx", "sy", "sz", "v"]) # FK Controlers ----------------------------------- t = transform.getTransformLookingAt(self.guide.apos[0], self.guide.apos[1], self.normal, "xz", self.negate) self.fk0_npo = primitive.addTransform( self.root_ctl, self.getName("fk0_npo"), t) self.fk0_ctl = self.addCtl( self.fk0_npo, "fk0_ctl", t, self.color_fk, "cube", w=self.length0, h=self.size * .1, d=self.size * .1, po=datatypes.Vector(.5 * self.length0 * self.n_factor, 0, 0), tp=self.root_ctl) attribute.setKeyableAttributes(self.fk0_ctl) t = transform.getTransformLookingAt(self.guide.apos[1], self.guide.apos[2], self.normal, "xz", self.negate) self.fk1_npo = primitive.addTransform( self.fk0_ctl, self.getName("fk1_npo"), t) self.fk1_ctl = self.addCtl( self.fk1_npo, "fk1_ctl", t, self.color_fk, "cube", w=self.length1, h=self.size * .1, d=self.size * .1, po=datatypes.Vector(.5 * self.length1 * self.n_factor, 0, 0), tp=self.fk0_ctl) attribute.setKeyableAttributes(self.fk1_ctl) t = transform.getTransformLookingAt(self.guide.apos[2], self.guide.apos[3], self.normal, "xz", self.negate) self.fk2_npo = primitive.addTransform( self.fk1_ctl, self.getName("fk2_npo"), t) self.fk2_ctl = self.addCtl( self.fk2_npo, "fk2_ctl", t, self.color_fk, "cube", w=self.length2, h=self.size * .1, d=self.size * .1, po=datatypes.Vector(.5 * self.length2 * self.n_factor, 0, 0), tp=self.fk1_ctl) attribute.setKeyableAttributes(self.fk2_ctl) t = transform.getTransformLookingAt(self.guide.apos[3], self.guide.apos[4], self.normal, "xz", self.negate) self.fk3_npo = primitive.addTransform( self.fk2_ctl, self.getName("fk3_npo"), t) self.fk3_ctl = self.addCtl( self.fk3_npo, "fk3_ctl", t, self.color_fk, "cube", w=self.length3, h=self.size * .1, d=self.size * .1, po=datatypes.Vector(.5 * self.length3 * self.n_factor, 0, 0), tp=self.fk2_ctl) attribute.setKeyableAttributes(self.fk3_ctl) self.fk_ctl = [self.fk0_ctl, self.fk1_ctl, self.fk2_ctl, self.fk3_ctl] for x in self.fk_ctl: attribute.setInvertMirror(x, ["tx", "ty", "tz"]) # Mid Controlers ------------------------------------ self.knee_lvl = primitive.addTransform( self.root, self.getName("knee_lvl"), transform.getTransform(self.mid1_jnt)) self.knee_ctl = self.addCtl( self.knee_lvl, "knee_ctl", transform.getTransform(self.mid1_jnt), self.color_ik, "sphere", w=self.size * .2, tp=self.root_ctl) attribute.setInvertMirror(self.knee_ctl, ["tx", "ty", "tz"]) attribute.lockAttribute(self.knee_ctl, ["sx", "sy", "sz", "v"]) self.ankle_lvl = primitive.addTransform( self.root, self.getName("ankle_lvl"), transform.getTransform(self.mid2_jnt)) self.ankle_ctl = self.addCtl( self.ankle_lvl, "ankle_ctl", transform.getTransform(self.mid2_jnt), self.color_ik, "sphere", w=self.size * .2, tp=self.knee_ctl) attribute.setInvertMirror(self.ankle_ctl, ["tx", "ty", "tz"]) attribute.lockAttribute(self.ankle_ctl, ["sx", "sy", "sz", "v"]) # IK controls -------------------------------------------------------- # foot IK # "z-x", t_align = transform.getTransformLookingAt(self.guide.apos[3], self.guide.apos[4], self.normal, "zx", False) if self.settings["ikOri"]: t = transform.getTransformFromPos(self.guide.pos["foot"]) # t = transform.getTransformLookingAt(self.guide.pos["foot"], # self.guide.pos["eff"], # self.x_axis, # "zx", # False) else: t = t_align self.ik_cns = primitive.addTransform( self.root_ctl, self.getName("ik_cns"), t) self.ikcns_ctl = self.addCtl(self.ik_cns, "ikcns_ctl", t, self.color_ik, "null", w=self.size * .12, tp=self.ankle_ctl) attribute.setInvertMirror(self.ikcns_ctl, ["tx"]) attribute.lockAttribute(self.ikcns_ctl, ["sx", "sy", "sz", "v"]) self.ik_ctl = self.addCtl(self.ikcns_ctl, "ik_ctl", t, self.color_ik, "cube", w=self.size * .12, h=self.size * .12, d=self.size * .12, tp=self.ikcns_ctl) attribute.setKeyableAttributes(self.ik_ctl) attribute.setRotOrder(self.ik_ctl, "XZY") attribute.setInvertMirror(self.ik_ctl, ["tx", "ry", "rz"]) attribute.lockAttribute(self.ik_ctl, ["sx", "sy", "sz", "v"]) # 2 bones ik layer self.ik2b_ikCtl_ref = primitive.addTransform( self.ik_ctl, self.getName("ik2B_A_ref"), t_align) self.ik2b_bone_ref = primitive.addTransform( self.chain3bones[3], self.getName("ik2B_B_ref"), t_align) self.ik2b_blend = primitive.addTransform( self.ik_ctl, self.getName("ik2B_blend"), t_align) self.roll_ctl = self.addCtl(self.ik2b_blend, "roll_ctl", t_align, self.color_ik, "crossarrow", w=self.length2 * .5 * self.n_factor, tp=self.ik_ctl) self.ik2b_ik_npo = primitive.addTransform( self.roll_ctl, self.getName("ik2B_ik_npo"), transform.getTransform(self.chain3bones[-1])) self.ik2b_ik_ref = primitive.addTransformFromPos( self.ik2b_ik_npo, self.getName("ik2B_ik_ref"), self.guide.pos["ankle"]) attribute.lockAttribute( self.roll_ctl, ["tx", "ty", "tz", "sx", "sy", "sz", "v"]) # upv v = self.guide.apos[2] - self.guide.apos[0] v = self.normal ^ v v.normalize() v *= self.size * .5 v += self.guide.apos[1] self.upv_lvl = primitive.addTransformFromPos( self.root, self.getName("upv_lvl"), v) self.upv_cns = primitive.addTransformFromPos( self.upv_lvl, self.getName("upv_cns"), v) self.upv_ctl = self.addCtl(self.upv_cns, "upv_ctl", transform.getTransform(self.upv_cns), self.color_ik, "diamond", w=self.size * .12, tp=self.ik_ctl) attribute.setInvertMirror(self.upv_ctl, ["tx"]) attribute.setKeyableAttributes(self.upv_ctl, ["tx", "ty", "tz"]) # Soft IK objects 3 bones chain -------------------------------- t = transform.getTransformLookingAt(self.guide.pos["root"], self.guide.pos["foot"], self.x_axis, "zx", False) self.aim_tra = primitive.addTransform( self.root_ctl, self.getName("aimSoftIK"), t) t = transform.getTransformFromPos(self.guide.pos["foot"]) self.wristSoftIK = primitive.addTransform( self.aim_tra, self.getName("wristSoftIK"), t) self.softblendLoc = primitive.addTransform( self.root, self.getName("softblendLoc"), t) # Soft IK objects 2 Bones chain ---------------------------- t = transform.getTransformLookingAt(self.guide.pos["root"], self.guide.pos["ankle"], self.x_axis, "zx", False) self.aim_tra2 = primitive.addTransform( self.root_ctl, self.getName("aimSoftIK2"), t) t = transform.getTransformFromPos(self.guide.pos["ankle"]) self.ankleSoftIK = primitive.addTransform( self.aim_tra2, self.getName("ankleSoftIK"), t) self.softblendLoc2 = primitive.addTransform( self.root, self.getName("softblendLoc2"), t) # References -------------------------------------- self.ik_ref = primitive.addTransform( self.ik_ctl, self.getName("ik_ref"), transform.getTransform(self.ik_ctl)) self.fk_ref = primitive.addTransform( self.fk_ctl[3], self.getName("fk_ref"), transform.getTransform(self.ik_ctl)) # twist references -------------------------------------- self.rollRef = primitive.add2DChain(self.root, self.getName("rollChain"), self.guide.apos[:2], self.normal, False, self.WIP) self.tws0_loc = primitive.addTransform( self.rollRef[0], self.getName("tws0_loc"), transform.getTransform(self.legBones[0])) self.tws0_rot = primitive.addTransform( self.tws0_loc, self.getName("tws0_rot"), transform.getTransform(self.legBones[0])) self.tws0_rot.setAttr("sx", .001) self.tws1_loc = primitive.addTransform( self.mid1_jnt, self.getName("tws1_loc"), transform.getTransform(self.mid1_jnt)) self.tws1_rot = primitive.addTransform( self.tws1_loc, self.getName("tws1_rot"), transform.getTransform(self.mid1_jnt)) self.tws1_rot.setAttr("sx", .001) self.tws2_loc = primitive.addTransform( self.mid2_jnt, self.getName("tws2_loc"), transform.getTransform(self.mid2_jnt)) self.tws2_rot = primitive.addTransform( self.tws2_loc, self.getName("tws2_rot"), transform.getTransform(self.mid2_jnt)) self.tws2_rot.setAttr("sx", .001) self.tws3_loc = primitive.addTransform( self.legBones[3], self.getName("tws3_loc"), transform.getTransform(self.legBones[3])) self.tws3_rot = primitive.addTransform( self.tws3_loc, self.getName("tws3_rot"), transform.getTransform(self.legBones[3])) self.tws3_rot.setAttr("sx", .001) # Divisions ---------------------------------------- # We have at least one division at the start, the end and one for # the knee and one ankle o_set = self.settings self.divisions = o_set["div0"] + o_set["div1"] + o_set["div2"] + 4 self.div_cns = [] for i in range(self.divisions): div_cns = primitive.addTransform(self.root_ctl, self.getName("div%s_loc" % i)) self.div_cns.append(div_cns) self.jnt_pos.append([div_cns, i]) # End reference ------------------------------------ # To help the deformation on the foot self.end_ref = primitive.addTransform( self.tws3_rot, self.getName("end_ref"), transform.getTransform(self.legBones[3])) self.jnt_pos.append([self.end_ref, 'end']) # match IK FK references self.match_fk0_off = primitive.addTransform( self.root, self.getName("matchFk0_npo"), transform.getTransform(self.fk_ctl[1])) self.match_fk0 = primitive.addTransform( self.match_fk0_off, self.getName("fk0_mth"), transform.getTransform(self.fk_ctl[0])) self.match_fk1_off = primitive.addTransform( self.root, self.getName("matchFk1_npo"), transform.getTransform(self.fk_ctl[2])) self.match_fk1 = primitive.addTransform( self.match_fk1_off, self.getName("fk1_mth"), transform.getTransform(self.fk_ctl[1])) self.match_fk2_off = primitive.addTransform( self.root, self.getName("matchFk2_npo"), transform.getTransform(self.fk_ctl[3])) self.match_fk2 = primitive.addTransform( self.match_fk2_off, self.getName("fk2_mth"), transform.getTransform(self.fk_ctl[2])) self.match_fk3 = primitive.addTransform( self.ik_ctl, self.getName("fk3_mth"), transform.getTransform(self.fk_ctl[3])) self.match_ik = primitive.addTransform( self.fk3_ctl, self.getName("ik_mth"), transform.getTransform(self.ik_ctl)) self.match_ikUpv = primitive.addTransform( self.fk0_ctl, self.getName("upv_mth"), transform.getTransform(self.upv_ctl)) # add visual reference self.line_ref = icon.connection_display_curve( self.getName("visalRef"), [self.upv_ctl, self.knee_ctl])
def addObjects(self): """Add all the objects needed to create the component.""" self.normal = self.getNormalFromPos(self.guide.apos) self.binormal = self.getBiNormalFromPos(self.guide.apos) self.length0 = vector.getDistance( self.guide.apos[0], self.guide.apos[1]) self.length1 = vector.getDistance( self.guide.apos[1], self.guide.apos[2]) self.length2 = vector.getDistance( self.guide.apos[2], self.guide.apos[3]) # FK Controlers ----------------------------------- # *ms* set npo @ Tpose, to make the fk rotation work # best with rot order"yzx" self.fk_cns = primitive.addTransformFromPos( self.root, self.getName("fk_cns"), self.guide.apos[0]) vec_offset = ((self.guide.apos[1] - self.guide.apos[0]) * [1, 0, 0]) tpv = self.guide.apos[0] + vec_offset t = transform.getTransformLookingAt(self.guide.apos[0], self.guide.apos[1], self.normal, "xz", self.negate) # *ms* add FK isolation self.fk0_npo = primitive.addTransform( self.fk_cns, self.getName("fk0_npo"), t) t = transform.getTransformLookingAt(self.guide.apos[0], self.guide.apos[1], self.normal, "xz", self.negate) po_off = datatypes.Vector(.35 * self.length0 * self.n_factor, 0, 0) self.fk0_ctl = self.addCtl(self.fk0_npo, "fk0_ctl", t, self.color_fk, "cube", w=self.length0 * .7, h=self.size * .1, d=self.size * .1, po=po_off, tp=self.parentCtlTag) attribute.setKeyableAttributes(self.fk0_ctl) # *ms* add fk roll control Simage style po_off = datatypes.Vector(.85 * self.length0 * self.n_factor, 0, 0) self.fk0_roll_ctl = self.addCtl(self.fk0_ctl, "fk0_roll_ctl", t, self.color_fk, "cube", w=self.length0 * .3, h=self.size * .1, d=self.size * 0.1, po=po_off, tp=self.fk0_ctl) attribute.setRotOrder(self.fk0_roll_ctl, "YZX") attribute.setKeyableAttributes(self.fk0_roll_ctl, ["rx"]) self.fk0_mtx = primitive.addTransform( self.root, self.getName("fk0_mtx"), t) t = transform.setMatrixPosition(t, self.guide.apos[1]) self.fk1_ref = primitive.addTransform( self.fk0_roll_ctl, self.getName("fk1_ref"), t) self.fk1_loc = primitive.addTransform( self.root, self.getName("fk1_loc"), t) t = transform.getTransformLookingAt(self.guide.apos[1], self.guide.apos[2], self.normal, "xz", self.negate) self.fk1_npo = primitive.addTransform( self.fk1_loc, self.getName("fk1_npo"), t) po_off = datatypes.Vector(.35 * self.length1 * self.n_factor, 0, 0) self.fk1_ctl = self.addCtl(self.fk1_npo, "fk1_ctl", t, self.color_fk, "cube", w=self.length1 * .7, h=self.size * .1, d=self.size * .1, po=po_off, tp=self.fk0_roll_ctl) attribute.setKeyableAttributes(self.fk1_ctl) self.fk1_mtx = primitive.addTransform( self.fk1_ctl, self.getName("fk1_mtx"), t) po_off = datatypes.Vector(.85 * self.length1 * self.n_factor, 0, 0) self.fk1_roll_ctl = self.addCtl(self.fk1_ctl, "fk1_roll_ctl", t, self.color_fk, "cube", w=self.length1 * .3, h=self.size * .1, d=self.size * .1, po=po_off, tp=self.fk1_ctl) attribute.setRotOrder(self.fk1_roll_ctl, "XYZ") attribute.setKeyableAttributes(self.fk1_roll_ctl, ["rx"]) t = transform.getTransformLookingAt(self.guide.apos[2], self.guide.apos[3], self.normal, "xz", self.negate) # *ms* buffer object to feed into ikfk solver for hand seperation self.fk2_mtx = primitive.addTransform(self.fk1_roll_ctl, self.getName("fk2_mtx"), t) # fk2_loc is need to take the effector position + bone1 rotation t1 = transform.getTransformLookingAt(self.guide.apos[2], self.guide.apos[1], self.normal, "-xz", self.negate) self.fk2_loc = primitive.addTransform( self.root, self.getName("fk2_loc"), t1) self.fk2_npo = primitive.addTransform(self.fk2_loc, self.getName("fk2_npo"), t) po_off = datatypes.Vector(.5 * self.length2 * self.n_factor, 0, 0) self.fk2_ctl = self.addCtl(self.fk2_npo, "fk2_ctl", t, self.color_fk, "cube", w=self.length2, h=self.size * .1, d=self.size * .1, po=po_off, tp=self.fk1_roll_ctl) attribute.setKeyableAttributes(self.fk2_ctl) self.fk_ctl = [self.fk0_roll_ctl, self.fk1_mtx, self.fk2_ctl] self.fk_ctls = [self.fk0_ctl, self.fk0_roll_ctl, self.fk1_ctl, self.fk1_roll_ctl, self.fk2_ctl] for x in self.fk_ctls: attribute.setInvertMirror(x, ["tx", "ty", "tz"]) # IK Controlers ----------------------------------- self.ik_cns = primitive.addTransformFromPos( self.root, self.getName("ik_cns"), self.guide.pos["wrist"]) self.ikcns_ctl = self.addCtl( self.ik_cns, "ikcns_ctl", transform.getTransformFromPos(self.guide.pos["wrist"]), self.color_ik, "null", w=self.size * .12, tp=self.parentCtlTag) attribute.setInvertMirror(self.ikcns_ctl, ["tx", "ty", "tz"]) if self.negate: m = transform.getTransformLookingAt(self.guide.pos["wrist"], self.guide.pos["eff"], self.normal, "x-y", True) else: m = transform.getTransformLookingAt(self.guide.pos["wrist"], self.guide.pos["eff"], self.normal, "xy", False) self.ik_ctl = self.addCtl(self.ikcns_ctl, "ik_ctl", m, self.color_ik, "cube", w=self.size * .12, h=self.size * .12, d=self.size * .12, tp=self.ikcns_ctl) attribute.setKeyableAttributes(self.ik_ctl) attribute.setInvertMirror(self.ik_ctl, ["tx", "ry", "rz"]) # upv v = self.guide.apos[2] - self.guide.apos[0] v = self.normal ^ v v.normalize() v *= self.size * .5 v += self.guide.apos[1] # *ms* auto up vector ------------------------------ self.upv_cns = primitive.addTransformFromPos(self.root, self.getName("upv_cns"), self.guide.apos[0]) self.upv_auv = primitive.addTransformFromPos(self.root, self.getName("upv_auv"), self.guide.apos[0]) self.upv_mtx = primitive.addTransformFromPos(self.upv_cns, self.getName("upv_mtx"), self.guide.apos[0]) self.upv_npo = primitive.addTransformFromPos(self.upv_mtx, self.getName("upv_npo"), v) self.upv_ctl = self.addCtl(self.upv_npo, "upv_ctl", transform.getTransform(self.upv_npo), self.color_ik, "diamond", w=self.size * .12, tp=self.parentCtlTag) attribute.setKeyableAttributes(self.upv_ctl, self.t_params) attribute.setInvertMirror(self.upv_ctl, ["tx"]) # References -------------------------------------- # Calculate again the transfor for the IK ref. This way align with FK trnIK_ref = transform.getTransformLookingAt(self.guide.pos["wrist"], self.guide.pos["eff"], self.normal, "xz", self.negate) self.ik_ref = primitive.addTransform(self.ik_ctl, self.getName("ik_ref"), trnIK_ref) self.fk_ref = primitive.addTransform(self.fk_ctl[2], self.getName("fk_ref"), trnIK_ref) # Chain -------------------------------------------- # take outputs of the ikfk2bone solver self.bone0 = primitive.addLocator( self.root, self.getName("0_bone"), transform.getTransform(self.fk_ctl[0])) self.bone0_shp = self.bone0.getShape() self.bone0_shp.setAttr("localPositionX", self.n_factor * .5) self.bone0_shp.setAttr("localScale", .5, 0, 0) self.bone0.setAttr("sx", self.length0) self.bone0.setAttr("visibility", False) self.bone1 = primitive.addLocator( self.root, self.getName("1_bone"), transform.getTransform(self.fk_ctl[1])) self.bone1_shp = self.bone1.getShape() self.bone1_shp.setAttr("localPositionX", self.n_factor * .5) self.bone1_shp.setAttr("localScale", .5, 0, 0) self.bone1.setAttr("sx", self.length1) self.bone1.setAttr("visibility", False) self.ctrn_loc = primitive.addTransformFromPos(self.root, self.getName("ctrn_loc"), self.guide.apos[1]) # eff npo --- take the effector output of gear ik solver self.eff_npo = primitive.addTransformFromPos(self.root, self.getName("eff_npo"), self.guide.apos[2]) # eff loc --- take the fk ik blend result self.eff_loc = primitive.addTransformFromPos(self.eff_npo, self.getName("eff_loc"), self.guide.apos[2]) # Mid Controler ------------------------------------ self.mid_ctl = self.addCtl(self.ctrn_loc, "mid_ctl", transform.getTransform(self.ctrn_loc), self.color_ik, "sphere", w=self.size * .2, tp=self.parentCtlTag) attribute.setInvertMirror(self.mid_ctl, ["tx", "ty", "tz"]) # *ms* add elbow thickness # Roll join ref self.tws0_npo = primitive.addTransform( self.root, self.getName("tws0_npo"), transform.getTransform(self.fk_ctl[0])) self.tws0_loc = primitive.addTransform( self.tws0_npo, self.getName("tws0_loc"), transform.getTransform(self.fk_ctl[0])) self.tws0_rot = primitive.addTransform( self.tws0_loc, self.getName("tws0_rot"), transform.getTransform(self.fk_ctl[0])) self.tws1_npo = primitive.addTransform( self.ctrn_loc, self.getName("tws1_npo"), transform.getTransform(self.ctrn_loc)) self.tws1_loc = primitive.addTransform( self.tws1_npo, self.getName("tws1_loc"), transform.getTransform(self.ctrn_loc)) self.tws1_rot = primitive.addTransform( self.tws1_loc, self.getName("tws1_rot"), transform.getTransform(self.ctrn_loc)) self.tws2_loc = primitive.addTransform( self.tws1_npo, self.getName("tws2_loc"), transform.getTransform(self.ctrn_loc)) self.tws2_rot = primitive.addTransform( self.tws2_loc, self.getName("tws2_rot"), transform.getTransform(self.ctrn_loc)) self.tws3_npo = primitive.addTransform( self.root, self.getName("tws3_npo"), transform.getTransform(self.fk_ctl[2])) self.tws3_loc = primitive.addTransform( self.tws3_npo, self.getName("tws3_loc"), transform.getTransform(self.fk_ctl[2])) self.tws3_rot = primitive.addTransform( self.tws3_loc, self.getName("tws3_rot"), transform.getTransform(self.fk_ctl[2])) # Divisions ---------------------------------------- # We have at least one division at the start, the end and one for the # elbow. + 2 for elbow angle control # separate up and dn limb self.divisions = self.settings["div0"] + self.settings["div1"] + 3 + 2 self.divisions0 = self.settings["div0"] + 2 self.divisions1 = self.settings["div1"] + 2 self.div_cns = [] self.div_cnsUp = [] self.div_cnsDn = [] self.div_ctls = [] self.div_org = primitive.addTransform( self.root, self.getName("div_org"), transform.getTransform(self.root)) self.previousTag = self.parentCtlTag for i in range(self.divisions0): div_cns = primitive.addTransform( self.div_org, self.getName("div%s_loc" % i)) if self.negate: div_ctl = self.addCtl( div_cns, self.getName("div%s_ctl" % i), transform.getTransform(div_cns), self.color_fk, "square", d=self.size * .05, w=self.size * .1, po=datatypes.Vector(0, self.size * -0.05, 0), ro=datatypes.Vector(0, 0, datatypes.radians(90)), tp=self.previousTag) else: div_ctl = self.addCtl( div_cns, self.getName("div%s_ctl" % i), transform.getTransform(div_cns), self.color_fk, "square", d=self.size * .05, w=self.size * .1, po=datatypes.Vector(0, self.size * 0.05, 0), ro=datatypes.Vector(0, 0, datatypes.radians(90)), tp=self.previousTag) attribute.setKeyableAttributes(div_ctl) self.previousTag = div_ctl self.div_cns.append(div_cns) self.div_cnsUp.append(div_cns) self.jnt_pos.append([div_ctl, i]) self.div_ctls.append(div_ctl) # mid division d = self.divisions0 self.div_mid = primitive.addTransform( self.div_org, self.getName("div%s_loc" % d), transform.getTransform(self.mid_ctl)) if self.negate: self.div_mid_ctl = self.addCtl( self.div_mid, self.getName("div%s_ctl" % d), transform.getTransform(self.div_mid), self.color_fk, "square", d=self.size * .05, w=self.size * .1, po=datatypes.Vector(0, self.size * -0.05, 0), ro=datatypes.Vector(0, 0, datatypes.radians(90)), tp=self.previousTag) else: self.div_mid_ctl = self.addCtl( self.div_mid, self.getName("div%s_ctl" % d), transform.getTransform(self.div_mid), self.color_fk, "square", d=self.size * .05, w=self.size * .1, po=datatypes.Vector(0, self.size * 0.05, 0), ro=datatypes.Vector(0, 0, datatypes.radians(90)), tp=self.previousTag) attribute.setKeyableAttributes(self.div_mid_ctl) self.previousTag = div_ctl self.div_cns.append(self.div_mid) self.jnt_pos.append([self.div_mid_ctl, self.divisions0]) self.div_ctls.append(self.div_mid_ctl) # down division for i in range(self.divisions1): dd = i + self.divisions1 + 1 div_cns = primitive.addTransform( self.div_org, self.getName("div%s_loc" % dd)) if self.negate: div_ctl = self.addCtl( div_cns, self.getName("div%s_ctl" % dd), transform.getTransform(div_cns), self.color_fk, "square", d=self.size * .05, w=self.size * .1, po=datatypes.Vector(0, self.size * -0.05, 0), ro=datatypes.Vector(0, 0, datatypes.radians(90)), tp=self.previousTag) else: div_ctl = self.addCtl( div_cns, self.getName("div%s_ctl" % dd), transform.getTransform(div_cns), self.color_fk, "square", d=self.size * .05, w=self.size * .1, po=datatypes.Vector(0, self.size * 0.05, 0), ro=datatypes.Vector(0, 0, datatypes.radians(90)), tp=self.previousTag) attribute.setKeyableAttributes(div_ctl) self.previousTag = div_ctl self.div_cns.append(div_cns) self.div_cnsDn.append(div_cns) self.jnt_pos.append([div_ctl, i + self.divisions0 + 1]) self.div_ctls.append(div_ctl) # End reference ------------------------------------ # To help the deformation on the wrist self.jnt_pos.append([self.eff_loc, 'end']) # match IK FK references self.match_fk0 = self.add_match_ref(self.fk_ctl[0], self.root, "fk0_mth") self.match_fk1 = self.add_match_ref(self.fk_ctl[1], self.root, "fk1_mth") self.match_fk2 = self.add_match_ref(self.fk_ctl[2], self.ik_ctl, "fk2_mth") self.match_ik = self.add_match_ref(self.ik_ctl, self.fk2_ctl, "ik_mth") self.match_ikUpv = self.add_match_ref(self.upv_ctl, self.fk0_roll_ctl, "upv_mth") # add visual reference self.line_ref = icon.connection_display_curve( self.getName("visalRef"), [self.upv_ctl, self.mid_ctl])
def addObjects(self): """Add all the objects needed to create the component.""" self.WIP = self.options["mode"] self.up_axis = pm.upAxis(q=True, axis=True) self.blade_normal = self.guide.blades["blade"].z * -1 self.blade_binormal = self.guide.blades["blade"].x self.normal = self.getNormalFromPos(self.guide.apos) self.binormal = self.getBiNormalFromPos(self.guide.apos) self.length0 = vector.getDistance( self.guide.apos[0], self.guide.apos[1] ) self.length1 = vector.getDistance( self.guide.apos[1], self.guide.apos[2] ) self.length2 = vector.getDistance( self.guide.apos[2], self.guide.apos[3] ) # 1 bone chain for upv ref self.armChainUpvRef = primitive.add2DChain( self.root, self.getName("armUpvRef%s_jnt"), [self.guide.apos[0], self.guide.apos[2]], self.normal, False, self.WIP, ) negateOri = self.armChainUpvRef[1].getAttr("jointOrientZ") * -1 self.armChainUpvRef[1].setAttr("jointOrientZ", negateOri) # FK Controlers ----------------------------------- t = transform.getTransformLookingAt( self.guide.apos[0], self.guide.apos[1], self.normal, "xz", self.negate, ) if self.settings["FK_rest_T_Pose"]: x = datatypes.Vector(1, 0, 0) if self.negate: z_dir = -1 else: z_dir = 1 if self.up_axis == "y": z = datatypes.Vector(0, z_dir, 0) else: z = datatypes.Vector(0, 0, z_dir) t_npo = transform.getRotationFromAxis(x, z, "xz", False) t_npo = transform.setMatrixPosition(t_npo, self.guide.apos[0]) else: t_npo = t self.fk0_npo = primitive.addTransform( self.root, self.getName("fk0_npo"), t_npo ) vec_po = datatypes.Vector(0.5 * self.length0 * self.n_factor, 0, 0) self.fk0_ctl = self.addCtl( self.fk0_npo, "fk0_ctl", t, self.color_fk, "cube", w=self.length0, h=self.size * 0.1, d=self.size * 0.1, po=vec_po, tp=self.parentCtlTag, ) attribute.setKeyableAttributes( self.fk0_ctl, ["tx", "ty", "tz", "ro", "rx", "ry", "rz", "sx"] ) t = transform.getTransformLookingAt( self.guide.apos[1], self.guide.apos[2], self.normal, "xz", self.negate, ) if self.settings["FK_rest_T_Pose"]: t_npo = transform.setMatrixPosition( transform.getTransform(self.fk0_ctl), self.guide.apos[1] ) else: t_npo = t self.fk1_npo = primitive.addTransform( self.fk0_ctl, self.getName("fk1_npo"), t_npo ) vec_po = datatypes.Vector(0.5 * self.length1 * self.n_factor, 0, 0) self.fk1_ctl = self.addCtl( self.fk1_npo, "fk1_ctl", t, self.color_fk, "cube", w=self.length1, h=self.size * 0.1, d=self.size * 0.1, po=vec_po, tp=self.fk0_ctl, ) attribute.setKeyableAttributes( self.fk1_ctl, ["tx", "ty", "tz", "ro", "rx", "ry", "rz", "sx"] ) if self.settings["use_blade"]: t = transform.getTransformLookingAt( self.guide.apos[2], self.guide.apos[3], self.blade_normal, "x-z", self.negate, ) else: t = transform.getTransformLookingAt( self.guide.apos[2], self.guide.apos[3], self.normal, "xz", self.negate, ) if self.settings["FK_rest_T_Pose"]: t_npo = transform.setMatrixPosition( transform.getTransform(self.fk1_ctl), self.guide.apos[2] ) else: t_npo = t self.fk2_npo = primitive.addTransform( self.fk1_ctl, self.getName("fk2_npo"), t_npo ) vec_po = datatypes.Vector(0.5 * self.length2 * self.n_factor, 0, 0) self.fk2_ctl = self.addCtl( self.fk2_npo, "fk2_ctl", t, self.color_fk, "cube", w=self.length2, h=self.size * 0.1, d=self.size * 0.1, po=vec_po, tp=self.fk1_ctl, ) attribute.setKeyableAttributes(self.fk2_ctl) self.fk_ctl = [self.fk0_ctl, self.fk1_ctl, self.fk2_ctl] for x in self.fk_ctl: attribute.setInvertMirror(x, ["tx", "ty", "tz"]) # IK upv --------------------------------- # create tip point self.tip_ref = primitive.addTransform( self.armChainUpvRef[0], self.getName("tip_ref"), self.armChainUpvRef[0].getMatrix(worldSpace=True), ) # create interpolate obj self.interpolate_lvl = primitive.addTransform( self.armChainUpvRef[0], self.getName("int_lvl"), self.armChainUpvRef[0].getMatrix(worldSpace=True), ) # create roll npo and ctl self.roll_ctl_npo = primitive.addTransform( self.root, self.getName("roll_ctl_npo"), self.armChainUpvRef[0].getMatrix(worldSpace=True), ) if self.negate: off_x = -1.5708 else: off_x = 1.5708 off_y = 1.5708 self.roll_ctl = self.addCtl( self.roll_ctl_npo, "roll_ctl", transform.getTransform(self.roll_ctl_npo), self.color_ik, "compas", w=self.size * 0.3, ro=datatypes.Vector([off_x, off_y, 0]), tp=self.parentCtlTag, ) attribute.setKeyableAttributes(self.roll_ctl, ["rx"]) # create upv control v = self.guide.apos[2] - self.guide.apos[0] v = self.normal ^ v v.normalize() v *= self.size * 0.8 v += self.guide.apos[1] self.upv_cns = primitive.addTransformFromPos( self.root, self.getName("upv_cns"), v ) self.upv_ctl = self.addCtl( self.upv_cns, "upv_ctl", transform.getTransform(self.upv_cns), self.color_ik, "diamond", w=self.size * 0.12, tp=self.parentCtlTag, ) if self.settings["mirrorMid"]: if self.negate: self.upv_cns.rz.set(180) self.upv_cns.sy.set(-1) else: attribute.setInvertMirror(self.upv_ctl, ["tx"]) attribute.setKeyableAttributes(self.upv_ctl, self.t_params) # IK Controlers ----------------------------------- self.ik_cns = primitive.addTransformFromPos( self.root, self.getName("ik_cns"), self.guide.pos["wrist"] ) t = transform.getTransformFromPos(self.guide.pos["wrist"]) self.ikcns_ctl = self.addCtl( self.ik_cns, "ikcns_ctl", t, self.color_ik, "null", w=self.size * 0.12, tp=self.parentCtlTag, ) attribute.setInvertMirror(self.ikcns_ctl, ["tx", "ty", "tz"]) if self.settings["use_blade"]: normal = self.blade_normal axis_ref1 = "xz" axis_ref2 = "x-z" else: normal = self.normal axis_ref1 = "x-y" axis_ref2 = "xy" if self.negate: m = transform.getTransformLookingAt( self.guide.pos["wrist"], self.guide.pos["eff"], normal, axis_ref1, True, ) else: m = transform.getTransformLookingAt( self.guide.pos["wrist"], self.guide.pos["eff"], normal, axis_ref2, False, ) self.ik_ctl = self.addCtl( self.ikcns_ctl, "ik_ctl", m, self.color_ik, "cube", w=self.size * 0.12, h=self.size * 0.12, d=self.size * 0.12, tp=self.roll_ctl, ) if self.settings["mirrorIK"]: if self.negate: self.ik_cns.sx.set(-1) self.ik_ctl.ry.set(self.ik_ctl.ry.get() * -1) self.ik_ctl.rz.set(self.ik_ctl.rz.get() * -1) else: attribute.setInvertMirror(self.ik_ctl, ["tx", "ry", "rz"]) attribute.setKeyableAttributes(self.ik_ctl) self.ik_ctl_ref = primitive.addTransform( self.ik_ctl, self.getName("ikCtl_ref"), m ) # IK rotation controls if self.settings["ikTR"]: self.ikRot_npo = primitive.addTransform( self.root, self.getName("ikRot_npo"), m ) self.ikRot_cns = primitive.addTransform( self.ikRot_npo, self.getName("ikRot_cns"), m ) self.ikRot_ctl = self.addCtl( self.ikRot_cns, "ikRot_ctl", m, self.color_ik, "sphere", w=self.size * 0.12, tp=self.ik_ctl, ) attribute.setKeyableAttributes(self.ikRot_ctl, self.r_params) # References -------------------------------------- # Calculate again the transfor for the IK ref. This way align with FK if self.settings["use_blade"]: normal = self.blade_normal axis_ref = "x-z" else: normal = self.normal axis_ref = "xz" trnIK_ref = transform.getTransformLookingAt( self.guide.pos["wrist"], self.guide.pos["eff"], normal, axis_ref, self.negate, ) self.ik_ref = primitive.addTransform( self.ik_ctl_ref, self.getName("ik_ref"), trnIK_ref ) self.fk_ref = primitive.addTransform( self.fk_ctl[2], self.getName("fk_ref"), trnIK_ref ) # Chain -------------------------------------------- # The outputs of the ikfk2bone solver self.bone0 = primitive.addLocator( self.root, self.getName("0_bone"), transform.getTransform(self.fk_ctl[0]), ) self.bone0_shp = self.bone0.getShape() self.bone0_shp.setAttr("localPositionX", self.n_factor * 0.5) self.bone0_shp.setAttr("localScale", 0.5, 0, 0) self.bone0.setAttr("sx", self.length0) self.bone0.setAttr("visibility", False) self.bone1 = primitive.addLocator( self.root, self.getName("1_bone"), transform.getTransform(self.fk_ctl[1]), ) self.bone1_shp = self.bone1.getShape() self.bone1_shp.setAttr("localPositionX", self.n_factor * 0.5) self.bone1_shp.setAttr("localScale", 0.5, 0, 0) self.bone1.setAttr("sx", self.length1) self.bone1.setAttr("visibility", False) self.ctrn_loc = primitive.addTransformFromPos( self.root, self.getName("ctrn_loc"), self.guide.apos[1] ) self.eff_loc = primitive.addTransformFromPos( self.root, self.getName("eff_loc"), self.guide.apos[2] ) if self.settings["use_blade"]: # set the offset rotation for the hand self.off_t = transform.getTransformLookingAt( self.guide.pos["wrist"], self.guide.pos["eff"], self.blade_normal, axis="xy", negate=self.negate, ) self.eff_jnt_off = primitive.addTransform( self.eff_loc, self.getName("eff_off"), self.off_t ) # Mid Controler ------------------------------------ t = transform.getTransform(self.ctrn_loc) self.mid_cns = primitive.addTransform( self.ctrn_loc, self.getName("mid_cns"), t ) self.mid_ctl = self.addCtl( self.mid_cns, "mid_ctl", t, self.color_ik, "sphere", w=self.size * 0.2, tp=self.parentCtlTag, ) attribute.setKeyableAttributes( self.mid_ctl, params=["tx", "ty", "tz", "ro", "rx", "ry", "rz", "sx"], ) if self.settings["mirrorMid"]: if self.negate: self.mid_cns.rz.set(180) self.mid_cns.sz.set(-1) self.mid_ctl_twst_npo = primitive.addTransform( self.mid_ctl, self.getName("mid_twst_npo"), t ) self.mid_ctl_twst_ref = primitive.addTransform( self.mid_ctl_twst_npo, self.getName("mid_twst_ref"), t ) else: self.mid_ctl_twst_ref = self.mid_ctl attribute.setInvertMirror(self.mid_ctl, ["tx", "ty", "tz"]) # Roll join ref self.rollRef = primitive.add2DChain( self.root, self.getName("rollChain"), self.guide.apos[:2], self.normal, self.negate, ) for x in self.rollRef: x.setAttr("visibility", False) if self.settings["div0"]: twst0_parent = self.rollRef[0] else: twst0_parent = self.root self.tws0_loc = primitive.addTransform( twst0_parent, self.getName("tws0_loc"), transform.getTransform(self.fk_ctl[0]), ) self.tws0_rot = primitive.addTransform( self.tws0_loc, self.getName("tws0_rot"), transform.getTransform(self.fk_ctl[0]), ) self.tws1_npo = primitive.addTransform( self.ctrn_loc, self.getName("tws1_npo"), transform.getTransform(self.ctrn_loc), ) self.tws1_loc = primitive.addTransform( self.tws1_npo, self.getName("tws1_loc"), transform.getTransform(self.ctrn_loc), ) self.tws1_rot = primitive.addTransform( self.tws1_loc, self.getName("tws1_rot"), transform.getTransform(self.ctrn_loc), ) self.tws2_npo = primitive.addTransform( self.root, self.getName("tws2_npo"), transform.getTransform(self.fk_ctl[2]), ) self.tws2_loc = primitive.addTransform( self.tws2_npo, self.getName("tws2_loc"), transform.getTransform(self.fk_ctl[2]), ) self.tws2_rot = primitive.addTransform( self.tws2_loc, self.getName("tws2_rot"), transform.getTransform(self.fk_ctl[2]), ) # Divisions ---------------------------------------- self.divisions = self.settings["div0"] + self.settings["div1"] + 2 self.div_cns = [] if self.settings["extraTweak"]: tagP = self.parentCtlTag self.tweak_ctl = [] for i in range(self.divisions): div_cns = primitive.addTransform( self.root, self.getName("div%s_loc" % i) ) self.div_cns.append(div_cns) if self.settings["extraTweak"]: t = transform.getTransform(div_cns) tweak_ctl = self.addCtl( div_cns, "tweak%s_ctl" % i, t, self.color_fk, "square", w=self.size * 0.15, d=self.size * 0.15, ro=datatypes.Vector([0, 0, 1.5708]), tp=tagP, ) attribute.setKeyableAttributes(tweak_ctl) tagP = tweak_ctl self.tweak_ctl.append(tweak_ctl) driver = tweak_ctl else: driver = div_cns # joint Description Name jd_names = ast.literal_eval( self.settings["jointNamesDescription_custom"] ) jdn_upperarm = jd_names[0] jdn_lowerarm = jd_names[1] jdn_upperarm_twist = jd_names[2] jdn_lowerarm_twist = jd_names[3] jdn_hand = jd_names[4] # setting the joints if i == 0: self.jnt_pos.append([driver, jdn_upperarm]) current_parent = "root" twist_name = jdn_upperarm_twist twist_idx = 1 increment = 1 elif i == self.settings["div0"] + 1: self.jnt_pos.append([driver, jdn_lowerarm, current_parent]) twist_name = jdn_lowerarm_twist current_parent = "elbow" twist_idx = self.settings["div1"] increment = -1 else: self.jnt_pos.append( [ driver, string.replaceSharpWithPadding(twist_name, twist_idx), current_parent, ] ) twist_idx += increment if self.settings["use_blade"]: eff_loc = self.eff_jnt_off else: eff_loc = self.eff_loc self.jnt_pos.append([eff_loc, jdn_hand, current_parent]) # match IK FK references self.match_fk0_off = self.add_match_ref( self.fk_ctl[1], self.root, "matchFk0_npo", False ) self.match_fk0 = self.add_match_ref( self.fk_ctl[0], self.match_fk0_off, "fk0_mth" ) self.match_fk1_off = self.add_match_ref( self.fk_ctl[2], self.root, "matchFk1_npo", False ) self.match_fk1 = self.add_match_ref( self.fk_ctl[1], self.match_fk1_off, "fk1_mth" ) if self.settings["ikTR"]: reference = self.ikRot_ctl self.match_ikRot = self.add_match_ref( self.ikRot_ctl, self.fk2_ctl, "ikRot_mth" ) else: reference = self.ik_ctl self.match_fk2 = self.add_match_ref( self.fk_ctl[2], reference, "fk2_mth" ) self.match_ik = self.add_match_ref(self.ik_ctl, self.fk2_ctl, "ik_mth") self.match_ikUpv = self.add_match_ref( self.upv_ctl, self.fk0_ctl, "upv_mth" ) # add visual reference self.line_ref = icon.connection_display_curve( self.getName("visalRef"), [self.upv_ctl, self.mid_ctl] )
def addObjects(self): """Add all the objects needed to create the component.""" self.normal = self.guide.blades["blade"].z * -1 self.binormal = self.guide.blades["blade"].x self.WIP = self.options["mode"] self.noXForm = pm.createNode('transform', name=self.getName('noXForm')) self.noXForm.setParent(self.root) self.noXForm.inheritsTransform.set(0) # IK controllers ------------------------------------ self.ik_npo = [] self.ik_ctl = [] self.ik_ref = [] self.ik_off = [] t = self.guide.tra["root"] t = transform.getTransformLookingAt(self.guide.apos[0], self.guide.apos[1], -self.normal, "xz", self.negate) self.ik_cns = primitive.addTransform(self.root, self.getName("ik_cns"), t) t = self.guide.tra["root"] self.fk_cns = primitive.addTransform(self.root, self.getName("fk_cns"), t) self.fk_cns.inheritsTransform.set(0) self.fk_cns.r.set(0, 0, 0) self.previusTag = self.parentCtlTag for i, v in enumerate(self.guide.apos): num = str(i + 1).zfill(2) t = transform.getTransformFromPos(v) npo = primitive.addTransform(self.ik_cns, self.getName('ik_%s_zeroSrt' % num), t) npo.r.set((0, 0, 0)) self.ik_npo.append(npo) ctl = self.addCtl(npo, "ik_%s_ctl" % num, t, self.color_ik, "square", h=self.size * .25, w=self.size * .25, tp=self.previusTag) ctl.r.set(0, 0, 0) self.ik_ctl.append(ctl) self.previusTag = ctl # Curves -------------------------------------- self.ikCrv = curveUtils.curveThroughPoints(positions=self.guide.apos, name=self.getName('ik_crv'), degree=2, rebuild=1) self.ikCrv.setParent(self.noXForm) guidePositions = [(i, 0, 0) for i in range(numSamples)] self.ikRailCrv = curveUtils.curveThroughPoints( positions=guidePositions, name=self.getName('ik_rail_crv'), degree=1, rebuild=1) self.ikRailCrv.setParent(self.noXForm) fkPositions = [(i, 0, 0) for i in range(self.settings['num_fk_ctls'])] self.fkCrv = curveUtils.curveThroughPoints(positions=fkPositions, name=self.getName('fk_crv'), degree=2, rebuild=1) self.fkCrv.setParent(self.noXForm) self.fkRailCrv = curveUtils.curveThroughPoints( positions=fkPositions, name=self.getName('fk_rail_crv'), degree=2, rebuild=1) sinePositions = [(i, 0, 0) for i in range(self.settings['num_joints'])] self.sineCrv = curveUtils.curveThroughPoints( positions=sinePositions, name=self.getName('sine_crv'), degree=1, rebuild=0) self.sineCrv.setParent(self.noXForm) # Start and end aimers --------------------------------- self.aim_loc = pm.spaceLocator(name=self.getName('start_aim_loc')) self.aim_loc.setParent(self.ik_cns) self.aim_end_loc = pm.spaceLocator(name=self.getName('end_aim_loc')) self.aim_end_loc.setParent(self.ik_ctl[-1]) self.aim_end_loc.t.set((0, 0, 0)) # FK ctls ------------------------------------- self.fk_npo = [] self.fk_ctl = [] self.fk_avg = [] self.previusTag = self.parentCtlTag for i in range(self.settings['num_fk_ctls']): num = str(i + 1).zfill(2) npo = primitive.addTransform(self.fk_cns, self.getName('fk_%s_zeroSrt' % num), t) self.fk_npo.append(npo) ctl = self.addCtl(npo, "fk_%s_ctl" % num, t, self.color_fk, "circle", r=self.size * .05, tp=self.previusTag) self.fk_ctl.append(ctl) self.previusTag = ctl avg = pm.createNode('transform', name=self.getName('fk_%s_avgSrt' % num)) avg.setParent(npo) avg.t.set(0, 0, 0) self.fk_avg.append(avg)
def addObjects(self): """Add all the objects needed to create the component.""" self.WIP = self.options["mode"] self.up_axis = pm.upAxis(q=True, axis=True) self.normal = self.getNormalFromPos(self.guide.apos) self.length0 = vector.getDistance( self.guide.apos[0], self.guide.apos[1]) self.length1 = vector.getDistance( self.guide.apos[1], self.guide.apos[2]) self.length2 = vector.getDistance( self.guide.apos[2], self.guide.apos[3]) # 1 bone chain for upv ref self.legChainUpvRef = primitive.add2DChain( self.root, self.getName("legUpvRef%s_jnt"), [self.guide.apos[0], self.guide.apos[2]], self.normal, False, self.WIP) self.legChainUpvRef[1].setAttr( "jointOrientZ", self.legChainUpvRef[1].getAttr("jointOrientZ") * -1) # extra neutral pose t = transform.getTransformFromPos(self.guide.apos[0]) self.root_npo = primitive.addTransform(self.root, self.getName("root_npo"), t) self.root_ctl = self.addCtl(self.root_npo, "root_ctl", t, self.color_fk, "circle", w=self.length0 / 6, tp=self.parentCtlTag) # FK Controlers ----------------------------------- t = transform.getTransformLookingAt(self.guide.apos[0], self.guide.apos[1], self.normal, "xz", self.negate) if self.settings["FK_rest_T_Pose"]: if self.negate: x_dir = 1 else: x_dir = -1 if self.up_axis == "y": x = datatypes.Vector(0, x_dir, 0) else: x = datatypes.Vector(0, 0, x_dir) z = datatypes.Vector(-1, 0, 0) t_npo = transform.getRotationFromAxis(x, z, "xz", False) t_npo = transform.setMatrixPosition(t_npo, self.guide.apos[0]) else: t_npo = t self.fk0_npo = primitive.addTransform(self.root_ctl, self.getName("fk0_npo"), t_npo) po_vec = datatypes.Vector(.5 * self.length0 * self.n_factor, 0, 0) self.fk0_ctl = self.addCtl(self.fk0_npo, "fk0_ctl", t, self.color_fk, "cube", w=self.length0, h=self.size * .1, d=self.size * .1, po=po_vec, tp=self.root_ctl) attribute.setKeyableAttributes( self.fk0_ctl, ["tx", "ty", "tz", "ro", "rx", "ry", "rz", "sx"]) t = transform.getTransformLookingAt(self.guide.apos[1], self.guide.apos[2], self.normal, "xz", self.negate) if self.settings["FK_rest_T_Pose"]: t_npo = transform.setMatrixPosition( transform.getTransform(self.fk0_ctl), self.guide.apos[1]) else: t_npo = t self.fk1_npo = primitive.addTransform( self.fk0_ctl, self.getName("fk1_npo"), t_npo) po_vec = datatypes.Vector(.5 * self.length1 * self.n_factor, 0, 0) self.fk1_ctl = self.addCtl(self.fk1_npo, "fk1_ctl", t, self.color_fk, "cube", w=self.length1, h=self.size * .1, d=self.size * .1, po=po_vec, tp=self.fk0_ctl) attribute.setKeyableAttributes( self.fk1_ctl, ["tx", "ty", "tz", "ro", "rx", "ry", "rz", "sx"]) t = transform.getTransformLookingAt(self.guide.apos[2], self.guide.apos[3], self.normal, "xz", self.negate) if self.settings["FK_rest_T_Pose"]: t_npo = transform.setMatrixPosition( transform.getTransform(self.fk0_ctl), self.guide.apos[2]) else: t_npo = t self.fk2_npo = primitive.addTransform( self.fk1_ctl, self.getName("fk2_npo"), t_npo) if self.settings["FK_rest_T_Pose"]: self.fk2_npo.rz.set(90) po_vec = datatypes.Vector(.5 * self.length2 * self.n_factor, 0, 0) self.fk2_ctl = self.addCtl(self.fk2_npo, "fk2_ctl", t, self.color_fk, "cube", w=self.length2, h=self.size * .1, d=self.size * .1, po=po_vec, tp=self.fk1_ctl) attribute.setKeyableAttributes(self.fk2_ctl) self.fk_ctl = [self.fk0_ctl, self.fk1_ctl, self.fk2_ctl] for x in self.fk_ctl: attribute.setInvertMirror(x, ["tx", "ty", "tz"]) # IK Controlers ----------------------------------- self.ik_cns = primitive.addTransformFromPos(self.root_ctl, self.getName("ik_cns"), self.guide.pos["ankle"]) self.ikcns_ctl = self.addCtl( self.ik_cns, "ikcns_ctl", transform.getTransformFromPos(self.guide.pos["ankle"]), self.color_ik, "null", w=self.size * .12, tp=self.root_ctl) attribute.setInvertMirror(self.ikcns_ctl, ["tx"]) # m = transform.getTransformLookingAt(self.guide.pos["ankle"], # self.guide.pos["eff"], # self.x_axis, # "zx", # False) # if self.settings["FK_rest_T_Pose"]: # t_ik = transform.getTransformLookingAt(self.guide.pos["ankle"], # self.guide.pos["eff"], # self.normal * -1, # "zx", # False) # else: t_ik = transform.getTransformFromPos(self.guide.pos["ankle"]) self.ik_ctl = self.addCtl( self.ikcns_ctl, "ik_ctl", t_ik, self.color_ik, "cube", w=self.size * .12, h=self.size * .12, d=self.size * .12) attribute.setKeyableAttributes(self.ik_ctl) attribute.setRotOrder(self.ik_ctl, "XZY") attribute.setInvertMirror(self.ik_ctl, ["tx", "ry", "rz"]) # upv v = self.guide.apos[2] - self.guide.apos[0] v = self.normal ^ v v.normalize() v *= self.size * .5 v += self.guide.apos[1] self.upv_cns = primitive.addTransformFromPos(self.ik_ctl, self.getName("upv_cns"), v) self.upv_ctl = self.addCtl( self.upv_cns, "upv_ctl", transform.getTransform(self.upv_cns), self.color_ik, "diamond", w=self.size * .12, tp=self.root_ctl) self.add_controller_tag(self.ik_ctl, self.upv_ctl) if self.settings["mirrorMid"]: if self.negate: self.upv_cns.rz.set(180) self.upv_cns.sy.set(-1) else: attribute.setInvertMirror(self.upv_ctl, ["tx"]) attribute.setKeyableAttributes(self.upv_ctl, self.t_params) # References -------------------------------------- self.ik_ref = primitive.addTransform( self.ik_ctl, self.getName("ik_ref"), transform.getTransform(self.ik_ctl)) self.fk_ref = primitive.addTransform( self.fk_ctl[2], self.getName("fk_ref"), transform.getTransform(self.ik_ctl)) # Chain -------------------------------------------- # The outputs of the ikfk2bone solver self.bone0 = primitive.addLocator( self.root_ctl, self.getName("0_bone"), transform.getTransform(self.fk_ctl[0])) self.bone0_shp = self.bone0.getShape() self.bone0_shp.setAttr("localPositionX", self.n_factor * .5) self.bone0_shp.setAttr("localScale", .5, 0, 0) self.bone0.setAttr("sx", self.length0) self.bone0.setAttr("visibility", False) self.bone1 = primitive.addLocator( self.root_ctl, self.getName("1_bone"), transform.getTransform(self.fk_ctl[1])) self.bone1_shp = self.bone1.getShape() self.bone1_shp.setAttr("localPositionX", self.n_factor * .5) self.bone1_shp.setAttr("localScale", .5, 0, 0) self.bone1.setAttr("sx", self.length1) self.bone1.setAttr("visibility", False) self.ctrn_loc = primitive.addTransformFromPos(self.root_ctl, self.getName("ctrn_loc"), self.guide.apos[1]) self.eff_loc = primitive.addTransformFromPos(self.root_ctl, self.getName("eff_loc"), self.guide.apos[2]) # tws_ref t = transform.getRotationFromAxis( datatypes.Vector(0, -1, 0), self.normal, "xz", self.negate) t = transform.setMatrixPosition(t, self.guide.pos["ankle"]) # addind an npo parent transform to fix flip in Maya 2018.2 self.tws_npo = primitive.addTransform( self.eff_loc, self.getName("tws_npo"), t) self.tws_ref = primitive.addTransform( self.tws_npo, self.getName("tws_ref"), t) # Mid Controler ------------------------------------ t = transform.getTransform(self.ctrn_loc) self.mid_cns = primitive.addTransform( self.ctrn_loc, self.getName("mid_cns"), t) self.mid_ctl = self.addCtl(self.mid_cns, "mid_ctl", t, self.color_ik, "sphere", w=self.size * .2, tp=self.root_ctl) attribute.setKeyableAttributes(self.mid_ctl, params=["tx", "ty", "tz", "ro", "rx", "ry", "rz", "sx"]) if self.settings["mirrorMid"]: if self.negate: self.mid_cns.rz.set(180) self.mid_cns.sz.set(-1) else: attribute.setInvertMirror(self.mid_ctl, ["tx", "ty", "tz"]) # Twist references --------------------------------- x = datatypes.Vector(0, -1, 0) x = x * transform.getTransform(self.eff_loc) z = datatypes.Vector(self.normal.x, self.normal.y, self.normal.z) z = z * transform.getTransform(self.eff_loc) m = transform.getRotationFromAxis(x, z, "xz", self.negate) m = transform.setMatrixPosition( m, transform.getTranslation(self.ik_ctl)) self.rollRef = primitive.add2DChain(self.root, self.getName("rollChain"), self.guide.apos[:2], self.normal, self.negate, self.WIP) t = transform.getTransformLookingAt(self.guide.pos["base"], self.guide.apos[1], self.normal, "xz", self.negate) self.tws0_loc = primitive.addTransform( self.root_ctl, self.getName("tws0_loc"), t) self.tws0_rot = primitive.addTransform( self.tws0_loc, self.getName("tws0_rot"), t) self.tws1_loc = primitive.addTransform( self.ctrn_loc, self.getName("tws1_loc"), transform.getTransform(self.ctrn_loc)) self.tws1_rot = primitive.addTransform( self.tws1_loc, self.getName("tws1_rot"), transform.getTransform(self.ctrn_loc)) self.tws2_loc = primitive.addTransform( self.root_ctl, self.getName("tws2_loc"), transform.getTransform(self.tws_ref)) self.tws2_rot = primitive.addTransform( self.tws2_loc, self.getName("tws2_rot"), transform.getTransform(self.tws_ref)) self.tws2_rot.setAttr("sx", .001) # Divisions ---------------------------------------- self.divisions = self.settings["div0"] + self.settings["div1"] + 2 self.div_cns = [] if self.settings["extraTweak"]: tagP = self.parentCtlTag self.tweak_ctl = [] for i in range(self.divisions): div_cns = primitive.addTransform(self.root_ctl, self.getName("div%s_loc" % i)) self.div_cns.append(div_cns) if self.settings["extraTweak"]: t = transform.getTransform(div_cns) tweak_ctl = self.addCtl(div_cns, "tweak%s_ctl" % i, t, self.color_fk, "square", w=self.size * .15, d=self.size * .15, ro=datatypes.Vector([0, 0, 1.5708]), tp=tagP) attribute.setKeyableAttributes(tweak_ctl) tagP = tweak_ctl self.tweak_ctl.append(tweak_ctl) driver = tweak_ctl else: driver = div_cns # setting the joints if i == 0: self.jnt_pos.append([driver, "thigh"]) current_parent = "root" twist_name = "thigh_twist_" twist_idx = 1 increment = 1 elif i == self.settings["div0"] + 1: self.jnt_pos.append([driver, "calf", current_parent]) twist_name = "calf_twist_" current_parent = "knee" twist_idx = self.settings["div1"] increment = -1 else: self.jnt_pos.append( [driver, twist_name + str(twist_idx).zfill(2), current_parent]) twist_idx += increment # End reference ------------------------------------ # To help the deformation on the ankle self.end_ref = primitive.addTransform(self.tws2_rot, self.getName("end_ref"), m) # set the offset rotation for the hand self.end_jnt_off = primitive.addTransform(self.end_ref, self.getName("end_off"), m) if self.up_axis == "z": self.end_jnt_off.rz.set(-90) self.jnt_pos.append([self.end_jnt_off, 'foot', current_parent]) # match IK FK references self.match_fk0_off = self.add_match_ref(self.fk_ctl[1], self.root, "matchFk0_npo", False) self.match_fk0 = self.add_match_ref(self.fk_ctl[0], self.match_fk0_off, "fk0_mth") self.match_fk1_off = self.add_match_ref(self.fk_ctl[2], self.root, "matchFk1_npo", False) self.match_fk1 = self.add_match_ref(self.fk_ctl[1], self.match_fk1_off, "fk1_mth") self.match_fk2 = self.add_match_ref(self.fk_ctl[2], self.ik_ctl, "fk2_mth") self.match_ik = self.add_match_ref(self.ik_ctl, self.fk2_ctl, "ik_mth") self.match_ikUpv = self.add_match_ref(self.upv_ctl, self.fk0_ctl, "upv_mth") # add visual reference self.line_ref = icon.connection_display_curve( self.getName("visalRef"), [self.upv_ctl, self.mid_ctl])
def set_softik_dummy(self, arm_comp): # -------------------------------------------------- # refs: https://qiita.com/hossan_TK9004/items/a76a58a49f6affb1ab21 nt = cmds.createNode('network', n='softIK_info') cmds.addAttr(nt, ln='ikMaxLength', at='float') cmds.addAttr(nt, ln='startLengthSoftCorrection', at='float') # get max Distance rootVector = self.guide.apos[0] currentVector = arm_comp.guide.pos["wrist"] t = tra.getTransformFromPos(arm_comp.guide.pos["wrist"]) self.softdummy_npo = pri.addTransform(self.root, self.getName("softdummy_npo"), t) pm.pointConstraint(self.softdummy_npo, arm_comp.dummy_ikh, maintainOffset=False) distanceVector = rootVector - currentVector maxDistance = distanceVector.length() softStartLength = maxDistance * 0.8 cmds.setAttr('{}.ikMaxLength'.format(nt), maxDistance) cmds.setAttr('{}.startLengthSoftCorrection'.format(nt), softStartLength) # culculate soft pct distNode = cmds.shadingNode('distanceBetween', au=True, n='currentLength') down, _, up = findPathAtoB(arm_comp.ik_ctl, self.root) ikMat = pm.createNode("multMatrix") for i, d in enumerate(down): pm.connectAttr("{}.matrix".format(d), "{}.matrixIn[{}]".format(ikMat, i)) pm.connectAttr("{}.matrixSum".format(ikMat), "{}.inMatrix2".format(distNode)) # --- culLength = cmds.shadingNode('plusMinusAverage', au=True, n='culLength') cmds.setAttr('{}.operation'.format(culLength), 2) cmds.connectAttr('{}.distance'.format(distNode), '{}.input2D[0].input2Dx'.format(culLength)) cmds.connectAttr('{}.startLengthSoftCorrection'.format(nt), '{}.input2D[1].input2Dx'.format(culLength)) cmds.connectAttr('{}.ikMaxLength'.format(nt), '{}.input2D[0].input2Dy'.format(culLength)) cmds.connectAttr('{}.startLengthSoftCorrection'.format(nt), '{}.input2D[1].input2Dy'.format(culLength)) culSoftPct = cmds.shadingNode('multiplyDivide', au=True, n='culSoftPct') cmds.setAttr('{}.operation'.format(culSoftPct), 2) cmds.connectAttr('{}.output2Dx'.format(culLength), '{}.input1X'.format(culSoftPct)) cmds.connectAttr('{}.output2Dy'.format(culLength), '{}.input2X'.format(culSoftPct)) # create animCurveNode culSoftLength = cmds.shadingNode('multDoubleLinear', au=True, n='culSoftLength') cv = cmds.createNode('animCurveUU', n='softCorrectionCurve') cmds.connectAttr('{}.outputX'.format(culSoftPct), '{}.input'.format(cv)) cmds.connectAttr('{}.output'.format(cv), '{}.input1'.format(culSoftLength)) cmds.connectAttr('{}.output2Dy'.format(culLength), '{}.input2'.format(culSoftLength)) cmds.setDrivenKeyframe(culSoftLength, at=('input1'), cd='{}.outputX'.format(culSoftPct), dv=0.0, v=0.0, itt='clamped', ott='clamped') cmds.setDrivenKeyframe(culSoftLength, at=('input1'), cd='{}.outputX'.format(culSoftPct), dv=1.0, v=1.0, itt='clamped', ott='clamped') angle = cmds.keyTangent(cv, q=True, index=(0, 0), inAngle=True)[0] cmds.keyframe(cv, index=(1, 1), floatChange=2) cmds.keyTangent(cv, index=(1, 1), itt='flat', ott='flat') cmds.keyTangent(cv, index=(0, 0), inAngle=angle) cmds.setAttr('{}.preInfinity'.format(cv), 1) cmds.setAttr('{}.postInfinity'.format(cv), 1) # cul softLength culAllSoftLength = cmds.shadingNode('addDoubleLinear', au=True, n='culAllSoftLength') cmds.connectAttr('{}.output'.format(culSoftLength), '{}.input1'.format(culAllSoftLength)) cmds.connectAttr('{}.startLengthSoftCorrection'.format(nt), '{}.input2'.format(culAllSoftLength)) culSoftLengthPct = cmds.shadingNode('multiplyDivide', au=True, n='culSoftLengthPct') cmds.setAttr('{}.operation'.format(culSoftLengthPct), 2) cmds.connectAttr('{}.output'.format(culAllSoftLength), '{}.input1X'.format(culSoftLengthPct)) cmds.connectAttr('{}.distance'.format(distNode), '{}.input2X'.format(culSoftLengthPct)) trans = pm.createNode('math_TranslationFromMatrix') softedTrns = cmds.shadingNode('multiplyDivide', au=True, n='softedTrns') cmds.connectAttr('{}.outputX'.format(culSoftLengthPct), '{}.input1X'.format(softedTrns)) cmds.connectAttr('{}.outputX'.format(culSoftLengthPct), '{}.input1Y'.format(softedTrns)) cmds.connectAttr('{}.outputX'.format(culSoftLengthPct), '{}.input1Z'.format(softedTrns)) cmds.connectAttr('{}.outputX'.format(trans), '{}.input2X'.format(softedTrns)) cmds.connectAttr('{}.outputY'.format(trans), '{}.input2Y'.format(softedTrns)) cmds.connectAttr('{}.outputZ'.format(trans), '{}.input2Z'.format(softedTrns)) # createCondition cond = cmds.shadingNode('condition', au=True, n='checkCurrentDistance') cmds.setAttr('{}.operation'.format(cond), 2) cmds.connectAttr('{}.distance'.format(distNode), '{}.firstTerm'.format(cond)) cmds.connectAttr('{}.startLengthSoftCorrection'.format(nt), '{}.secondTerm'.format(cond)) cmds.connectAttr('{}.matrixSum'.format(ikMat), '{}.input'.format(trans)) cmds.connectAttr('{}.outputX'.format(trans), '{}.colorIfFalseR'.format(cond)) cmds.connectAttr('{}.outputY'.format(trans), '{}.colorIfFalseG'.format(cond)) cmds.connectAttr('{}.outputZ'.format(trans), '{}.colorIfFalseB'.format(cond)) cmds.connectAttr('{}.outputX'.format(softedTrns), '{}.colorIfTrueR'.format(cond)) cmds.connectAttr('{}.outputY'.format(softedTrns), '{}.colorIfTrueG'.format(cond)) cmds.connectAttr('{}.outputZ'.format(softedTrns), '{}.colorIfTrueB'.format(cond)) # connect softIK cmds.connectAttr('{}.outColorR'.format(cond), '{}.translateX'.format(self.softdummy_npo)) cmds.connectAttr('{}.outColorG'.format(cond), '{}.translateY'.format(self.softdummy_npo)) cmds.connectAttr('{}.outColorB'.format(cond), '{}.translateZ'.format(self.softdummy_npo)) # apply offset to rest angle cmds.setAttr( "{}.inputX".format(arm_comp.dummy_chain_offset), -1. * cmds.getAttr("{}.rx".format(arm_comp.dummy_chain[0]))) cmds.setAttr( "{}.inputY".format(arm_comp.dummy_chain_offset), -1. * cmds.getAttr("{}.ry".format(arm_comp.dummy_chain[0]))) cmds.setAttr( "{}.inputZ".format(arm_comp.dummy_chain_offset), -1. * cmds.getAttr("{}.rz".format(arm_comp.dummy_chain[0]))) cmds.setAttr( "{}.rotationOrder".format(arm_comp.dummy_chain_offset), cmds.getAttr("{}.rotateOrder".format(arm_comp.dummy_chain[0])))