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.npo = primitive.addTransform(self.root, self.getName("npo"), t) self.ctl = self.addCtl(self.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) self.mtx = primitive.addTransform(self.npo, self.getName("mtx"), t) t1 = transform.setMatrixPosition(t, self.guide.apos[1]) t2 = transform.getInterpolateTransformMatrix(t, t1, blend=0.98) self.loc = primitive.addTransform(self.mtx, self.getName("loc"), t2) self.end = primitive.addTransform(self.ctl, self.getName("end"), t1) self.jnt_pos.append([self.mtx, "root"]) self.jnt_pos.append([self.loc, 'end']) attribute.setKeyableAttributes(self.ctl) attribute.setInvertMirror(self.ctl, ["tx", "ty", "tz"])
def addObjects(self): """Add all the objects needed to create the component.""" self.normal = self.guide.blades["blade"].z * -1 # Ik Controlers ------------------------------------ t = transform.getTransformLookingAt(self.guide.pos["tan1"], self.guide.pos["neck"], self.normal, "yx", self.negate) t = transform.setMatrixPosition(t, self.guide.pos["neck"]) self.ik_cns = primitive.addTransform(self.root, self.getName("ik_cns"), t) self.ik_ctl = self.addCtl(self.ik_cns, "ik_ctl", t, self.color_ik, "compas", w=self.size * .5, tp=self.parentCtlTag) attribute.setKeyableAttributes(self.ik_ctl, self.tr_params) attribute.setRotOrder(self.ik_ctl, "ZXY") attribute.setInvertMirror(self.ik_ctl, ["tx", "ry", "rz"]) # Tangents ----------------------------------------- if self.settings["tangentControls"]: t = transform.setMatrixPosition(t, self.guide.pos["tan1"]) self.tan1_loc = primitive.addTransform(self.ik_ctl, self.getName("tan1_loc"), t) self.tan1_ctl = self.addCtl(self.tan1_loc, "tan1_ctl", t, self.color_ik, "sphere", w=self.size * .2, tp=self.ik_ctl) attribute.setKeyableAttributes(self.tan1_ctl, self.t_params) attribute.setInvertMirror(self.tan1_ctl, ["tx"]) t = transform.getTransformLookingAt(self.guide.pos["root"], self.guide.pos["tan0"], self.normal, "yx", self.negate) t = transform.setMatrixPosition(t, self.guide.pos["tan0"]) self.tan0_loc = primitive.addTransform(self.root, self.getName("tan0_loc"), t) self.tan0_ctl = self.addCtl(self.tan0_loc, "tan0_ctl", t, self.color_ik, "sphere", w=self.size * .2, tp=self.ik_ctl) attribute.setKeyableAttributes(self.tan0_ctl, self.t_params) attribute.setInvertMirror(self.tan0_ctl, ["tx"]) # Curves ------------------------------------------- self.mst_crv = curve.addCnsCurve( self.root, self.getName("mst_crv"), [self.root, self.tan0_ctl, self.tan1_ctl, self.ik_ctl], 3) self.slv_crv = curve.addCurve(self.root, self.getName("slv_crv"), [datatypes.Vector()] * 10, False, 3) self.mst_crv.setAttr("visibility", False) else: t = transform.setMatrixPosition(t, self.guide.pos["tan1"]) self.tan1_loc = primitive.addTransform(self.ik_ctl, self.getName("tan1_loc"), t) t = transform.getTransformLookingAt(self.guide.pos["root"], self.guide.pos["tan0"], self.normal, "yx", self.negate) t = transform.setMatrixPosition(t, self.guide.pos["tan0"]) self.tan0_loc = primitive.addTransform(self.root, self.getName("tan0_loc"), t) # Curves ------------------------------------------- self.mst_crv = curve.addCnsCurve( self.root, self.getName("mst_crv"), [self.root, self.tan0_loc, self.tan1_loc, self.ik_ctl], 3) self.slv_crv = curve.addCurve(self.root, self.getName("slv_crv"), [datatypes.Vector()] * 10, False, 3) self.mst_crv.setAttr("visibility", False) self.slv_crv.setAttr("visibility", False) # Division ----------------------------------------- # The user only define how many intermediate division he wants. # First and last divisions are an obligation. parentdiv = self.root parentctl = self.root self.div_cns = [] self.fk_ctl = [] self.fk_npo = [] self.scl_npo = [] self.twister = [] self.ref_twist = [] parent_twistRef = primitive.addTransform( self.root, self.getName("reference"), transform.getTransform(self.root)) t = transform.getTransformLookingAt(self.guide.pos["root"], self.guide.pos["neck"], self.normal, "yx", self.negate) self.intMRef = primitive.addTransform(self.root, self.getName("intMRef"), t) self.previousCtlTag = self.parentCtlTag for i in range(self.settings["division"]): # References div_cns = primitive.addTransform(parentdiv, self.getName("%s_cns" % i), t) pm.setAttr(div_cns + ".inheritsTransform", False) self.div_cns.append(div_cns) parentdiv = div_cns scl_npo = primitive.addTransform(parentctl, self.getName("%s_scl_npo" % i), transform.getTransform(parentctl)) # Controlers (First and last one are fake) if i in [self.settings["division"] - 1]: # 0, fk_ctl = primitive.addTransform( scl_npo, self.getName("%s_loc" % i), transform.getTransform(parentctl)) fk_npo = fk_ctl else: fk_npo = primitive.addTransform( scl_npo, self.getName("fk%s_npo" % i), transform.getTransform(parentctl)) fk_ctl = self.addCtl(fk_npo, "fk%s_ctl" % i, transform.getTransform(parentctl), self.color_fk, "cube", w=self.size * .2, h=self.size * .05, d=self.size * .2, tp=self.previousCtlTag) attribute.setKeyableAttributes(self.fk_ctl) attribute.setRotOrder(fk_ctl, "ZXY") self.previousCtlTag = fk_ctl self.fk_ctl.append(fk_ctl) self.scl_npo.append(scl_npo) self.fk_npo.append(fk_npo) parentctl = fk_ctl self.jnt_pos.append([fk_ctl, i]) t = transform.getTransformLookingAt( self.guide.pos["root"], self.guide.pos["neck"], self.guide.blades["blade"].z * -1, "yx", self.negate) twister = primitive.addTransform(parent_twistRef, self.getName("%s_rot_ref" % i), t) ref_twist = primitive.addTransform(parent_twistRef, self.getName("%s_pos_ref" % i), t) ref_twist.setTranslation(datatypes.Vector(0.0, 0, 1.0), space="preTransform") self.twister.append(twister) self.ref_twist.append(ref_twist) for x in self.fk_ctl[:-1]: attribute.setInvertMirror(x, ["tx", "rz", "ry"]) # Head --------------------------------------------- t = transform.getTransformLookingAt(self.guide.pos["head"], self.guide.pos["eff"], self.normal, "yx", self.negate) self.head_cns = primitive.addTransform(self.root, self.getName("head_cns"), t) dist = vector.getDistance(self.guide.pos["head"], self.guide.pos["eff"]) self.head_ctl = self.addCtl(self.head_cns, "head_ctl", t, self.color_fk, "cube", w=self.size * .5, h=dist, d=self.size * .5, po=datatypes.Vector(0, dist * .5, 0), tp=self.previousCtlTag) attribute.setRotOrder(self.head_ctl, "ZXY") attribute.setInvertMirror(self.head_ctl, ["tx", "rz", "ry"]) self.jnt_pos.append([self.head_ctl, "head"])
def addObjects(self): self.WIP = self.options["mode"] self.normal = self.getNormalFromPos(self.guide.apos) self.binormal = self.getBiNormalFromPos(self.guide.apos) self.length0 = vec.getDistance(self.guide.apos[0], self.guide.apos[1]) self.length1 = vec.getDistance(self.guide.apos[1], self.guide.apos[2]) self.length2 = vec.getDistance(self.guide.apos[2], self.guide.apos[3]) # FK Controlers ----------------------------------- t = tra.getTransformLookingAt(self.guide.apos[0], self.guide.apos[1], self.normal, "xz", self.negate) self.fk0_npo = pri.addTransform(self.root, 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=dt.Vector( .5 * self.length0 * self.n_factor, 0, 0)) att.setKeyableAttributes(self.fk0_ctl) t = tra.getTransformLookingAt(self.guide.apos[1], self.guide.apos[2], self.normal, "xz", self.negate) self.fk1_npo = pri.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=dt.Vector( .5 * self.length1 * self.n_factor, 0, 0)) att.setKeyableAttributes(self.fk1_ctl) t = tra.getTransformLookingAt(self.guide.apos[2], self.guide.apos[3], self.normal, "xz", self.negate) self.fk2_npo = pri.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=dt.Vector( .5 * self.length2 * self.n_factor, 0, 0)) att.setKeyableAttributes(self.fk2_ctl) self.fk_ctl = [self.fk0_ctl, self.fk1_ctl, self.fk2_ctl] for x in self.fk_ctl: att.setInvertMirror(x, ["tx", "ty", "tz"]) # IK Controlers ----------------------------------- self.ik_cns = pri.addTransformFromPos(self.root, self.getName("ik_cns"), self.guide.pos["wrist"]) self.ikcns_ctl = self.addCtl(self.ik_cns, "ikcns_ctl", tra.getTransformFromPos( self.guide.pos["wrist"]), self.color_ik, "null", w=self.size * .12) att.setInvertMirror(self.ikcns_ctl, ["tx", "ty", "tz"]) if self.negate: m = tra.getTransformLookingAt(self.guide.pos["wrist"], self.guide.pos["eff"], self.normal, "x-y", True) else: m = tra.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) att.setKeyableAttributes(self.ik_ctl) att.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 = pri.addTransformFromPos(self.root, self.getName("upv_cns"), v) self.upv_ctl = self.addCtl(self.upv_cns, "upv_ctl", tra.getTransform(self.upv_cns), self.color_ik, "diamond", w=self.size * .12) att.setInvertMirror(self.upv_ctl, ["tx"]) # References -------------------------------------- # Calculate again the transfor for the IK ref. This way align with FK trnIK_ref = tra.getTransformLookingAt(self.guide.pos["wrist"], self.guide.pos["eff"], self.normal, "xz", self.negate) self.ik_ref = pri.addTransform(self.ik_ctl, self.getName("ik_ref"), trnIK_ref) self.fk_ref = pri.addTransform(self.fk_ctl[2], self.getName("fk_ref"), trnIK_ref) # Chain -------------------------------------------- # The outputs of the ikfk2bone solver self.bone0 = pri.addLocator(self.root, self.getName("0_bone"), tra.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) bShape = self.bone0.getShape() bShape.setAttr("visibility", False) self.bone1 = pri.addLocator(self.root, self.getName("1_bone"), tra.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) bShape = self.bone1.getShape() bShape.setAttr("visibility", False) #Elbow control tA = tra.getTransformLookingAt(self.guide.apos[0], self.guide.apos[1], self.normal, "xz", self.negate) tA = tra.setMatrixPosition(tA, self.guide.apos[1]) tB = tra.getTransformLookingAt(self.guide.apos[1], self.guide.apos[2], self.normal, "xz", self.negate) t = tra.getInterpolateTransformMatrix(tA, tB) self.ctrn_loc = pri.addTransform(self.root, self.getName("ctrn_loc"), t) #match IK FK references self.match_fk0_off = pri.addTransform(self.root, self.getName("matchFk0_npo"), tra.getTransform(self.fk_ctl[1])) # self.match_fk0_off.attr("tx").set(1.0) self.match_fk0 = pri.addTransform(self.match_fk0_off, self.getName("fk0_mth"), tra.getTransform(self.fk_ctl[0])) self.match_fk1_off = pri.addTransform(self.root, self.getName("matchFk1_npo"), tra.getTransform(self.fk_ctl[2])) # self.match_fk1_off.attr("tx").set(1.0) self.match_fk1 = pri.addTransform(self.match_fk1_off, self.getName("fk1_mth"), tra.getTransform(self.fk_ctl[1])) self.match_fk2 = pri.addTransform(self.ik_ctl, self.getName("fk2_mth"), tra.getTransform(self.fk_ctl[2])) self.match_ik = pri.addTransform(self.fk2_ctl, self.getName("ik_mth"), tra.getTransform(self.ik_ctl)) self.match_ikUpv = pri.addTransform(self.fk0_ctl, self.getName("upv_mth"), tra.getTransform(self.upv_ctl)) # Eff locator self.eff_loc = pri.addTransformFromPos(self.root, self.getName("eff_loc"), self.guide.apos[2]) # Mid Controler ------------------------------------ self.mid_ctl = self.addCtl(self.ctrn_loc, "mid_ctl", tra.getTransform(self.ctrn_loc), self.color_ik, "sphere", w=self.size * .2) att.setInvertMirror(self.mid_ctl, ["tx", "ty", "tz"]) #Roll join ref--------------------------------- self.tws0_loc = pri.addTransform(self.root, self.getName("tws0_loc"), tra.getTransform(self.fk_ctl[0])) self.tws1_npo = pri.addTransform(self.ctrn_loc, self.getName("tws1_npo"), tra.getTransform(self.ctrn_loc)) self.tws1_loc = pri.addTransform(self.tws1_npo, self.getName("tws1_loc"), tra.getTransform(self.ctrn_loc)) self.tws1A_npo = pri.addTransform(self.mid_ctl, self.getName("tws1A_npo"), tA) self.tws1A_loc = pri.addTransform(self.tws1A_npo, self.getName("tws1A_loc"), tA) self.tws1B_npo = pri.addTransform(self.mid_ctl, self.getName("tws1B_npo"), tB) self.tws1B_loc = pri.addTransform(self.tws1B_npo, self.getName("tws1B_loc"), tB) self.tws2_npo = pri.addTransform(self.root, self.getName("tws2_npo"), tra.getTransform(self.fk_ctl[2])) self.tws2_loc = pri.addTransform(self.tws2_npo, self.getName("tws2_loc"), tra.getTransform(self.fk_ctl[2])) # Roll twist chain --------------------------------- #Arm self.armChainPos = [] ii = 1.0 / (self.settings["div0"] + 1) i = 0.0 for p in range(self.settings["div0"] + 2): self.armChainPos.append( vec.linearlyInterpolate(self.guide.pos["root"], self.guide.pos["elbow"], blend=i)) i = i + ii self.armTwistChain = pri.add2DChain(self.root, self.getName("armTwist%s_jnt"), self.armChainPos, self.normal, False, self.WIP) #Forearm self.forearmChainPos = [] ii = 1.0 / (self.settings["div1"] + 1) i = 0.0 for p in range(self.settings["div1"] + 2): self.forearmChainPos.append( vec.linearlyInterpolate(self.guide.pos["elbow"], self.guide.pos["wrist"], blend=i)) i = i + ii self.forearmTwistChain = pri.add2DChain( self.root, self.getName("forearmTwist%s_jnt"), self.forearmChainPos, self.normal, False, self.WIP) pm.parent(self.forearmTwistChain[0], self.mid_ctl) #Hand Aux chain and nonroll self.auxChainPos = [] ii = .5 i = 0.0 for p in range(3): self.auxChainPos.append( vec.linearlyInterpolate(self.guide.pos["wrist"], self.guide.pos["eff"], blend=i)) i = i + ii t = self.root.getMatrix(worldSpace=True) self.aux_npo = pri.addTransform(self.root, self.getName("aux_npo"), t) self.auxTwistChain = pri.add2DChain(self.aux_npo, self.getName("auxTwist%s_jnt"), self.auxChainPos, self.normal, False, self.WIP) #Non Roll join ref --------------------------------- self.armRollRef = pri.add2DChain(self.root, self.getName("armRollRef%s_jnt"), self.armChainPos[:2], self.normal, False, self.WIP) self.forearmRollRef = pri.add2DChain( self.aux_npo, self.getName("forearmRollRef%s_jnt"), self.auxChainPos[: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 elbow angle control self.divisions = self.settings["div0"] + self.settings["div1"] + 4 self.div_cns = [] for i in range(self.divisions): div_cns = pri.addTransform(self.root, 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 wrist self.end_ref = pri.addTransform(self.eff_loc, self.getName("end_ref"), tra.getTransform(self.eff_loc)) if self.negate: self.end_ref.attr("rz").set(180.0) self.jnt_pos.append([self.end_ref, "end"]) # Tangent controls t = tra.getInterpolateTransformMatrix(self.fk_ctl[0], self.tws1A_npo, .3333) self.armTangentA_loc = pri.addTransform( self.root, self.getName("armTangentA_loc"), self.fk_ctl[0].getMatrix(worldSpace=True)) self.armTangentA_npo = pri.addTransform( self.armTangentA_loc, self.getName("armTangentA_npo"), t) self.armTangentA_ctl = self.addCtl(self.armTangentA_npo, "armTangentA_ctl", t, self.color_ik, "circle", w=self.size * .2, ro=dt.Vector(0, 0, 1.570796)) t = tra.getInterpolateTransformMatrix(self.fk_ctl[0], self.tws1A_npo, .6666) self.armTangentB_npo = pri.addTransform( self.tws1A_loc, self.getName("armTangentB_npo"), t) self.armTangentB_ctl = self.addCtl(self.armTangentB_npo, "armTangentB_ctl", t, self.color_ik, "circle", w=self.size * .2, ro=dt.Vector(0, 0, 1.570796)) tC = self.tws1B_npo.getMatrix(worldSpace=True) tC = tra.setMatrixPosition(tC, self.guide.apos[2]) t = tra.getInterpolateTransformMatrix(self.tws1B_npo, tC, .3333) self.forearmTangentA_npo = pri.addTransform( self.tws1B_loc, self.getName("forearmTangentA_npo"), t) self.forearmTangentA_ctl = self.addCtl(self.forearmTangentA_npo, "forearmTangentA_ctl", t, self.color_ik, "circle", w=self.size * .2, ro=dt.Vector(0, 0, 1.570796)) t = tra.getInterpolateTransformMatrix(self.tws1B_npo, tC, .6666) self.forearmTangentB_loc = pri.addTransform( self.root, self.getName("forearmTangentB_loc"), tC) self.forearmTangentB_npo = pri.addTransform( self.forearmTangentB_loc, self.getName("forearmTangentB_npo"), t) self.forearmTangentB_ctl = self.addCtl(self.forearmTangentB_npo, "forearmTangentB_ctl", t, self.color_ik, "circle", w=self.size * .2, ro=dt.Vector(0, 0, 1.570796)) t = self.mid_ctl.getMatrix(worldSpace=True) self.elbowTangent_npo = pri.addTransform( self.mid_ctl, self.getName("elbowTangent_npo"), t) self.elbowTangent_ctl = self.addCtl(self.elbowTangent_npo, "elbowTangent_ctl", t, self.color_fk, "circle", w=self.size * .25, ro=dt.Vector(0, 0, 1.570796))
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 = 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 = primitive.addTransform( self.ik_ctl, self.getName("fk2_mth"), transform.getTransform(self.fk_ctl[2])) self.match_ik = primitive.addTransform( self.fk2_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.mid_ctl])
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) 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 --------------------------------- 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.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"]) 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) 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.upv_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) 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)) 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 ---------------------------------------- # We have at least one division at the start, the end and one for the # elbow. + 2 for elbow angle control self.divisions = self.settings["div0"] + self.settings["div1"] + 3 + 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 * .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 = 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])) if self.settings["ikTR"]: reference = self.ikRot_ctl self.match_ikRot = primitive.addTransform( self.fk2_ctl, self.getName("ikRot_mth"), transform.getTransform(self.ikRot_ctl)) else: reference = self.ik_ctl self.match_fk2 = primitive.addTransform( reference, self.getName("fk2_mth"), transform.getTransform(self.fk_ctl[2])) self.match_ik = primitive.addTransform( self.fk2_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))
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 if self.settings["ikOri"]: t = transform.getTransformLookingAt(self.guide.pos["foot"], self.guide.pos["eff"], self.x_axis, "zx", False) else: t = transform.getTransformLookingAt(self.guide.apos[3], self.guide.apos[4], self.normal, "z-x", False) 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) self.ik2b_bone_ref = primitive.addTransform(self.chain3bones[3], self.getName("ik2B_B_ref"), t) self.ik2b_blend = primitive.addTransform(self.ik_ctl, self.getName("ik2B_blend"), t) self.roll_ctl = self.addCtl(self.ik2b_blend, "roll_ctl", t, 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'])
def addObjects(self): self.normal = self.getNormalFromPos(self.guide.apos) self.binormal = self.getBiNormalFromPos(self.guide.apos) self.length0 = vec.getDistance(self.guide.apos[0], self.guide.apos[1]) self.length1 = vec.getDistance(self.guide.apos[1], self.guide.apos[2]) self.length2 = vec.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 = pri.addTransformFromPos(self.root, self.getName("fk_cns"), self.guide.apos[0]) tpv = self.guide.apos[0] + ( (self.guide.apos[1] - self.guide.apos[0]) * [1, 0, 0]) t = tra.getTransformLookingAt(self.guide.apos[0], tpv, self.normal, "xz", self.negate) # *ms* add FK isolation self.fk0_npo = pri.addTransform(self.fk_cns, self.getName("fk0_npo"), t) t = tra.getTransformLookingAt(self.guide.apos[0], self.guide.apos[1], self.normal, "xz", self.negate) self.fk0_ctl = self.addCtl(self.fk0_npo, "fk0_ctl", t, self.color_fk, "cube", w=self.length0 * .55, h=self.size * .1, d=self.size * .1, po=dt.Vector( .35 * self.length0 * self.n_factor, 0, 0)) att.setKeyableAttributes(self.fk0_ctl) # *ms* add fk roll control Simage style self.fk0_roll_ctl = self.addCtl(self.fk0_ctl, "fk0_roll_ctl", t, self.color_fk, "cube", w=self.length0 * .45, h=self.size * .1, d=self.size * .1, po=dt.Vector( .85 * self.length0 * self.n_factor, 0, 0)) att.setKeyableAttributes(self.fk0_roll_ctl) t = tra.getTransformLookingAt(self.guide.apos[1], self.guide.apos[2], self.normal, "xz", self.negate) self.fk1_npo = pri.addTransform(self.fk0_roll_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=dt.Vector( .5 * self.length1 * self.n_factor, 0, 0)) att.setKeyableAttributes(self.fk1_ctl) t = tra.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 = pri.addTransform(self.fk1_ctl, self.getName("fk2_mtx"), t) # fk2_npo is need to take the effector position self.fk2_npo = pri.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=dt.Vector( .5 * self.length2 * self.n_factor, 0, 0)) att.setKeyableAttributes(self.fk2_ctl) self.fk_ctl = [self.fk0_roll_ctl, self.fk1_ctl, self.fk2_ctl] for x in self.fk_ctl: att.setInvertMirror(x, ["tx", "ty", "tz"]) # IK Controlers ----------------------------------- self.ik_cns = pri.addTransformFromPos(self.root, self.getName("ik_cns"), self.guide.pos["wrist"]) self.ikcns_ctl = self.addCtl(self.ik_cns, "ikcns_ctl", tra.getTransformFromPos( self.guide.pos["wrist"]), self.color_ik, "null", w=self.size * .12) att.setInvertMirror(self.ikcns_ctl, ["tx", "ty", "tz"]) if self.negate: m = tra.getTransformLookingAt(self.guide.pos["wrist"], self.guide.pos["eff"], self.normal, "x-y", True) else: m = tra.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) att.setKeyableAttributes(self.ik_ctl) att.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 = pri.addTransformFromPos(self.root, self.getName("upv_cns"), self.guide.apos[0]) self.upv_auv = pri.addTransformFromPos(self.upv_cns, self.getName("upv_auv"), self.guide.apos[0]) self.upv_mtx = pri.addTransformFromPos(self.upv_cns, self.getName("upv_mtx"), self.guide.apos[0]) self.upv_npo = pri.addTransformFromPos(self.upv_mtx, self.getName("upv_npo"), v) self.upv_ctl = self.addCtl(self.upv_npo, "upv_ctl", tra.getTransform(self.upv_npo), self.color_ik, "diamond", w=self.size * .12) att.setKeyableAttributes(self.upv_ctl, self.t_params) att.setInvertMirror(self.upv_ctl, ["tx"]) # References -------------------------------------- # Calculate again the transfor for the IK ref. This way align with FK trnIK_ref = tra.getTransformLookingAt(self.guide.pos["wrist"], self.guide.pos["eff"], self.normal, "xz", self.negate) self.ik_ref = pri.addTransform(self.ik_ctl, self.getName("ik_ref"), trnIK_ref) self.fk_ref = pri.addTransform(self.fk_ctl[2], self.getName("fk_ref"), trnIK_ref) # Chain -------------------------------------------- # The outputs of the ikfk2bone solver self.bone0 = pri.addLocator(self.root, self.getName("0_bone"), tra.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 = pri.addLocator(self.root, self.getName("1_bone"), tra.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 = pri.addTransformFromPos(self.root, self.getName("ctrn_loc"), self.guide.apos[1]) self.eff_npo = pri.addTransformFromPos(self.root, self.getName("eff_npo"), self.guide.apos[2]) self.eff_loc = pri.addTransformFromPos(self.eff_npo, self.getName("eff_loc"), self.guide.apos[2]) # Mid Controler ------------------------------------ self.mid_ctl = self.addCtl(self.ctrn_loc, "mid_ctl", tra.getTransform(self.ctrn_loc), self.color_ik, "sphere", w=self.size * .2) att.setInvertMirror(self.mid_ctl, ["tx", "ty", "tz"]) # *ms* add elbow thickness # # Twist references --------------------------------- # x = dt.Vector(0,-1,0) # x = x * tra.getTransform(self.eff_loc) # z = dt.Vector(self.normal.x,self.normal.y,self.normal.z) # z = z * tra.getTransform(self.eff_loc) # m = tra.getRotationFromAxis(x, z, "xz", self.negate) # m = tra.setMatrixPosition(m, tra.getTranslation(self.ik_ctl)) #Roll join ref #self.rollRef = pri.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_npo = pri.addTransform(self.root, self.getName("tws0_npo"), tra.getTransform(self.fk_ctl[0])) self.tws0_loc = pri.addTransform(self.tws0_npo, self.getName("tws0_loc"), tra.getTransform(self.fk_ctl[0])) self.tws0_rot = pri.addTransform(self.tws0_loc, self.getName("tws0_rot"), tra.getTransform(self.fk_ctl[0])) self.tws1_npo = pri.addTransform(self.ctrn_loc, self.getName("tws1_npo"), tra.getTransform(self.ctrn_loc)) self.tws1_loc = pri.addTransform(self.tws1_npo, self.getName("tws1_loc"), tra.getTransform(self.ctrn_loc)) self.tws1_rot = pri.addTransform(self.tws1_loc, self.getName("tws1_rot"), tra.getTransform(self.ctrn_loc)) self.tws2_npo = pri.addTransform(self.root, self.getName("tws2_npo"), tra.getTransform(self.fk_ctl[2])) self.tws2_loc = pri.addTransform(self.tws2_npo, self.getName("tws2_loc"), tra.getTransform(self.fk_ctl[2])) self.tws2_rot = pri.addTransform(self.tws2_loc, self.getName("tws2_rot"), tra.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 self.divisions = self.settings["div0"] + self.settings["div1"] + 3 + 2 self.div_cns = [] for i in range(self.divisions): div_cns = pri.addTransform(self.root, 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 wrist self.jnt_pos.append([self.eff_loc, 'end']) # self.end_ref = pri.addTransform(self.eff_loc, self.getName("end_ref"), m) # for a in "xyz": # self.end_ref.attr("s%s"%a).set(1.0) # self.end_ref.attr("r%s"%a).set(0.0) # self.jnt_pos.append([self.end_ref, 'end']) #match IK FK references self.match_fk0_off = pri.addTransform(self.root, self.getName("matchFk0_npo"), tra.getTransform(self.fk_ctl[1])) # self.match_fk0_off.attr("tx").set(1.0) self.match_fk0 = pri.addTransform(self.match_fk0_off, self.getName("fk0_mth"), tra.getTransform(self.fk_ctl[0])) self.match_fk1_off = pri.addTransform(self.root, self.getName("matchFk1_npo"), tra.getTransform(self.fk_ctl[2])) # self.match_fk1_off.attr("tx").set(1.0) self.match_fk1 = pri.addTransform(self.match_fk1_off, self.getName("fk1_mth"), tra.getTransform(self.fk_ctl[1])) self.match_fk2 = pri.addTransform(self.ik_ctl, self.getName("fk2_mth"), tra.getTransform(self.fk_ctl[2])) self.match_ik = pri.addTransform(self.fk2_ctl, self.getName("ik_mth"), tra.getTransform(self.ik_ctl)) self.match_ikUpv = pri.addTransform(self.fk0_ctl, self.getName("upv_mth"), tra.getTransform(self.upv_ctl))
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) 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, 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) 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"]) 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"]) # 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)) 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 ---------------------------------------- # 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"] + 3 + 2 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.tws2_rot, self.getName("end_ref"), m) 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 = primitive.addTransform( self.ik_ctl, self.getName("fk2_mth"), transform.getTransform(self.fk_ctl[2])) self.match_ik = primitive.addTransform( self.fk2_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))
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], tpv, 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 = primitive.addTransform( self.root, self.getName("fk0_mth"), transform.getTransform(self.fk_ctl[0])) self.match_fk1 = primitive.addTransform( self.root, self.getName("fk1_mth"), transform.getTransform(self.fk_ctl[1])) self.match_fk2 = primitive.addTransform( self.ik_ctl, self.getName("fk2_mth"), transform.getTransform(self.fk_ctl[2])) self.match_ik = primitive.addTransform( self.fk2_ctl, self.getName("ik_mth"), transform.getTransform(self.ik_ctl)) self.match_ikUpv = primitive.addTransform( self.fk0_roll_ctl, self.getName("upv_mth"), transform.getTransform(self.upv_ctl))
def addObjects(self): """Add all the objects needed to create the component.""" # Auto bend with position controls -------------------- if self.settings["autoBend"]: self.autoBendChain = primitive.add2DChain( self.root, self.getName("autoBend%s_jnt"), [self.guide.apos[0], self.guide.apos[1]], self.guide.blades["blade"].z * -1, False, True) for j in self.autoBendChain: j.drawStyle.set(2) # Ik Controlers ------------------------------------ t = transform.getTransformLookingAt(self.guide.apos[0], self.guide.apos[1], self.guide.blades["blade"].z * -1, "yx", self.negate) self.ik0_npo = primitive.addTransform( self.root, self.getName("ik0_npo"), t) self.ik0_ctl = self.addCtl(self.ik0_npo, "ik0_ctl", t, self.color_ik, "compas", w=self.size, tp=self.parentCtlTag) attribute.setKeyableAttributes(self.ik0_ctl, self.tr_params) attribute.setRotOrder(self.ik0_ctl, "ZXY") attribute.setInvertMirror(self.ik0_ctl, ["tx", "ry", "rz"]) t = transform.setMatrixPosition(t, self.guide.apos[1]) if self.settings["autoBend"]: self.autoBend_npo = primitive.addTransform( self.root, self.getName("spinePosition_npo"), t) self.autoBend_ctl = self.addCtl(self.autoBend_npo, "spinePosition_ctl", t, self.color_ik, "square", w=self.size, d=.3 * self.size, tp=self.parentCtlTag) attribute.setKeyableAttributes(self.autoBend_ctl, ["tx", "ty", "tz", "ry"]) attribute.setInvertMirror(self.autoBend_ctl, ["tx", "ry"]) self.ik1_npo = primitive.addTransform( self.autoBendChain[0], self.getName("ik1_npo"), t) self.ik1autoRot_lvl = primitive.addTransform( self.ik1_npo, self.getName("ik1autoRot_lvl"), t) self.ik1_ctl = self.addCtl(self.ik1autoRot_lvl, "ik1_ctl", t, self.color_ik, "compas", w=self.size, tp=self.autoBend_ctl) else: t = transform.setMatrixPosition(t, self.guide.apos[1]) self.ik1_npo = primitive.addTransform( self.root, self.getName("ik1_npo"), t) self.ik1_ctl = self.addCtl(self.ik1_npo, "ik1_ctl", t, self.color_ik, "compas", w=self.size, tp=self.ik0_ctl) attribute.setKeyableAttributes(self.ik1_ctl, self.tr_params) attribute.setRotOrder(self.ik1_ctl, "ZXY") attribute.setInvertMirror(self.ik1_ctl, ["tx", "ry", "rz"]) # Tangent controllers ------------------------------- if self.settings["centralTangent"]: vec_pos = vector.linearlyInterpolate(self.guide.apos[0], self.guide.apos[1], .33) t = transform.setMatrixPosition(t, vec_pos) self.tan0_npo = primitive.addTransform( self.ik0_ctl, self.getName("tan0_npo"), t) self.tan0_off = primitive.addTransform( self.tan0_npo, self.getName("tan0_off"), t) self.tan0_ctl = self.addCtl(self.tan0_off, "tan0_ctl", t, self.color_ik, "sphere", w=self.size * .1, tp=self.ik0_ctl) attribute.setKeyableAttributes(self.tan0_ctl, self.t_params) vec_pos = vector.linearlyInterpolate(self.guide.apos[0], self.guide.apos[1], .66) t = transform.setMatrixPosition(t, vec_pos) self.tan1_npo = primitive.addTransform( self.ik1_ctl, self.getName("tan1_npo"), t) self.tan1_off = primitive.addTransform( self.tan1_npo, self.getName("tan1_off"), t) self.tan1_ctl = self.addCtl(self.tan1_off, "tan1_ctl", t, self.color_ik, "sphere", w=self.size * .1, tp=self.ik0_ctl) attribute.setKeyableAttributes(self.tan1_ctl, self.t_params) # Tangent mid control vec_pos = vector.linearlyInterpolate(self.guide.apos[0], self.guide.apos[1], .5) t = transform.setMatrixPosition(t, vec_pos) self.tan_npo = primitive.addTransform( self.tan0_npo, self.getName("tan_npo"), t) self.tan_ctl = self.addCtl(self.tan_npo, "tan_ctl", t, self.color_fk, "sphere", w=self.size * .2, tp=self.ik1_ctl) attribute.setKeyableAttributes(self.tan_ctl, self.t_params) attribute.setInvertMirror(self.tan_ctl, ["tx"]) else: vec_pos = vector.linearlyInterpolate(self.guide.apos[0], self.guide.apos[1], .33) t = transform.setMatrixPosition(t, vec_pos) self.tan0_npo = primitive.addTransform( self.ik0_ctl, self.getName("tan0_npo"), t) self.tan0_ctl = self.addCtl(self.tan0_npo, "tan0_ctl", t, self.color_ik, "sphere", w=self.size * .2, tp=self.ik0_ctl) attribute.setKeyableAttributes(self.tan0_ctl, self.t_params) vec_pos = vector.linearlyInterpolate(self.guide.apos[0], self.guide.apos[1], .66) t = transform.setMatrixPosition(t, vec_pos) self.tan1_npo = primitive.addTransform( self.ik1_ctl, self.getName("tan1_npo"), t) self.tan1_ctl = self.addCtl(self.tan1_npo, "tan1_ctl", t, self.color_ik, "sphere", w=self.size * .2, tp=self.ik1_ctl) attribute.setKeyableAttributes(self.tan1_ctl, self.t_params) attribute.setInvertMirror(self.tan0_ctl, ["tx"]) attribute.setInvertMirror(self.tan1_ctl, ["tx"]) # Curves ------------------------------------------- self.mst_crv = curve.addCnsCurve( self.root, self.getName("mst_crv"), [self.ik0_ctl, self.tan0_ctl, self.tan1_ctl, self.ik1_ctl], 3) self.slv_crv = curve.addCurve(self.root, self.getName("slv_crv"), [datatypes.Vector()] * 10, False, 3) self.mst_crv.setAttr("visibility", False) self.slv_crv.setAttr("visibility", False) # Division ----------------------------------------- # The user only define how many intermediate division he wants. # First and last divisions are an obligation. parentdiv = self.root parentctl = self.root self.div_cns = [] self.fk_ctl = [] self.fk_npo = [] self.scl_transforms = [] self.twister = [] self.ref_twist = [] t = transform.getTransformLookingAt( self.guide.apos[0], self.guide.apos[1], self.guide.blades["blade"].z * -1, "yx", self.negate) parent_twistRef = primitive.addTransform( self.root, self.getName("reference"), transform.getTransform(self.root)) self.jointList = [] self.preiviousCtlTag = self.parentCtlTag for i in range(self.settings["division"]): # References div_cns = primitive.addTransform(parentdiv, self.getName("%s_cns" % i)) pm.setAttr(div_cns + ".inheritsTransform", False) self.div_cns.append(div_cns) parentdiv = div_cns # Controlers (First and last one are fake) # if i in [0]: # TODO: add option setting to add or not the first and last # controller for the fk # if i in [0, self.settings["division"] - 1] and False: if i in [0, self.settings["division"] - 1]: fk_ctl = primitive.addTransform( parentctl, self.getName("%s_loc" % i), transform.getTransform(parentctl)) fk_npo = fk_ctl if i in [self.settings["division"] - 1]: self.fk_ctl.append(fk_ctl) else: fk_npo = primitive.addTransform( parentctl, self.getName("fk%s_npo" % (i - 1)), transform.getTransform(parentctl)) fk_ctl = self.addCtl(fk_npo, "fk%s_ctl" % (i - 1), transform.getTransform(parentctl), self.color_fk, "cube", w=self.size, h=self.size * .05, d=self.size, tp=self.preiviousCtlTag) attribute.setKeyableAttributes(self.fk_ctl) attribute.setRotOrder(fk_ctl, "ZXY") self.fk_ctl.append(fk_ctl) self.preiviousCtlTag = fk_ctl # setAttr(fk_npo+".inheritsTransform", False) self.fk_npo.append(fk_npo) parentctl = fk_ctl scl_ref = primitive.addTransform(parentctl, self.getName("%s_scl_ref" % i), transform.getTransform(parentctl)) self.scl_transforms.append(scl_ref) # Deformers (Shadow) self.jnt_pos.append([scl_ref, i]) # Twist references (This objects will replace the spinlookup slerp # solver behavior) t = transform.getTransformLookingAt( self.guide.apos[0], self.guide.apos[1], self.guide.blades["blade"].z * -1, "yx", self.negate) twister = primitive.addTransform( parent_twistRef, self.getName("%s_rot_ref" % i), t) ref_twist = primitive.addTransform( parent_twistRef, self.getName("%s_pos_ref" % i), t) ref_twist.setTranslation( datatypes.Vector(1.0, 0, 0), space="preTransform") self.twister.append(twister) self.ref_twist.append(ref_twist) # TODO: update this part with the optiona FK controls update for x in self.fk_ctl[:-1]: attribute.setInvertMirror(x, ["tx", "rz", "ry"]) # Connections (Hooks) ------------------------------ self.cnx0 = primitive.addTransform(self.root, self.getName("0_cnx")) self.cnx1 = primitive.addTransform(self.root, self.getName("1_cnx"))
def addObjects(self): """ """ self.WIP = self.options["mode"] self.normal = self.getNormalFromPos(self.guide.apos) self.binormal = self.getBiNormalFromPos(self.guide.apos) self.length0 = vec.getDistance(self.guide.apos[0], self.guide.apos[1]) self.length1 = vec.getDistance(self.guide.apos[1], self.guide.apos[2]) self.length2 = vec.getDistance(self.guide.apos[2], self.guide.apos[3]) # 1 bone chain for upv ref self.armChainUpvRef = pri.add2DChain( self.root, self.getName("armUpvRef%s_jnt"), [self.guide.apos[0], self.guide.apos[2]], self.normal, False, self.WIP) self.armChainUpvRef[1].setAttr( "jointOrientZ", self.armChainUpvRef[1].getAttr("jointOrientZ") * -1) # FK Controlers ----------------------------------- t = tra.getTransformLookingAt(self.guide.apos[0], self.guide.apos[1], self.normal, "xz", self.negate) self.fk0_npo = pri.addTransform(self.root, 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=dt.Vector( .5 * self.length0 * self.n_factor, 0, 0)) att.setKeyableAttributes(self.fk0_ctl) t = tra.getTransformLookingAt(self.guide.apos[1], self.guide.apos[2], self.normal, "xz", self.negate) self.fk1_npo = pri.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=dt.Vector( .5 * self.length1 * self.n_factor, 0, 0)) att.setKeyableAttributes(self.fk1_ctl) t = tra.getTransformLookingAt(self.guide.apos[2], self.guide.apos[3], self.normal, "xz", self.negate) self.fk2_npo = pri.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=dt.Vector( .5 * self.length2 * self.n_factor, 0, 0)) att.setKeyableAttributes(self.fk2_ctl) self.fk_ctl = [self.fk0_ctl, self.fk1_ctl, self.fk2_ctl] for x in self.fk_ctl: att.setInvertMirror(x, ["tx", "ty", "tz"]) # IK Controlers ----------------------------------- self.ik_cns = pri.addTransformFromPos(self.root, self.getName("ik_cns"), self.guide.pos["wrist"]) self.ikcns_ctl = self.addCtl(self.ik_cns, "ikcns_ctl", tra.getTransformFromPos( self.guide.pos["wrist"]), self.color_ik, "null", w=self.size * .12) att.setInvertMirror(self.ikcns_ctl, ["tx", "ty", "tz"]) if self.negate: m = tra.getTransformLookingAt(self.guide.pos["wrist"], self.guide.pos["eff"], self.normal, "x-y", True) else: m = tra.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) att.setKeyableAttributes(self.ik_ctl) att.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 = pri.addTransformFromPos(self.root, self.getName("upv_cns"), v) self.upv_ctl = self.addCtl(self.upv_cns, "upv_ctl", tra.getTransform(self.upv_cns), self.color_ik, "diamond", w=self.size * .12) att.setKeyableAttributes(self.upv_ctl, self.t_params) att.setInvertMirror(self.upv_ctl, ["tx"]) #IK rotation controls if self.settings["ikTR"]: self.ikRot_npo = pri.addTransform(self.root, self.getName("ikRot_npo"), m) self.ikRot_cns = pri.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) att.setKeyableAttributes(self.ikRot_ctl, ["rx", "ry", "rz"]) # References -------------------------------------- # Calculate again the transfor for the IK ref. This way align with FK trnIK_ref = tra.getTransformLookingAt(self.guide.pos["wrist"], self.guide.pos["eff"], self.normal, "xz", self.negate) self.ik_ref = pri.addTransform(self.ik_ctl, self.getName("ik_ref"), trnIK_ref) self.fk_ref = pri.addTransform(self.fk_ctl[2], self.getName("fk_ref"), trnIK_ref) # Chain -------------------------------------------- # The outputs of the ikfk2bone solver self.bone0 = pri.addLocator(self.root, self.getName("0_bone"), tra.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 = pri.addLocator(self.root, self.getName("1_bone"), tra.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 = pri.addTransformFromPos(self.root, self.getName("ctrn_loc"), self.guide.apos[1]) self.eff_loc = pri.addTransformFromPos(self.root, self.getName("eff_loc"), self.guide.apos[2]) # Mid Controler ------------------------------------ self.mid_ctl = self.addCtl(self.ctrn_loc, "mid_ctl", tra.getTransform(self.ctrn_loc), self.color_ik, "sphere", w=self.size * .2) att.setInvertMirror(self.mid_ctl, ["tx", "ty", "tz"]) #Roll join ref self.rollRef = pri.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 = pri.addTransform(self.rollRef[0], self.getName("tws0_loc"), tra.getTransform(self.fk_ctl[0])) self.tws0_rot = pri.addTransform(self.tws0_loc, self.getName("tws0_rot"), tra.getTransform(self.fk_ctl[0])) self.tws1_npo = pri.addTransform(self.ctrn_loc, self.getName("tws1_npo"), tra.getTransform(self.ctrn_loc)) self.tws1_loc = pri.addTransform(self.tws1_npo, self.getName("tws1_loc"), tra.getTransform(self.ctrn_loc)) self.tws1_rot = pri.addTransform(self.tws1_loc, self.getName("tws1_rot"), tra.getTransform(self.ctrn_loc)) self.tws2_npo = pri.addTransform(self.root, self.getName("tws2_npo"), tra.getTransform(self.fk_ctl[2])) self.tws2_loc = pri.addTransform(self.tws2_npo, self.getName("tws2_loc"), tra.getTransform(self.fk_ctl[2])) self.tws2_rot = pri.addTransform(self.tws2_loc, self.getName("tws2_rot"), tra.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 self.divisions = self.settings["div0"] + self.settings["div1"] + 3 + 2 self.div_cns = [] for i in range(self.divisions): div_cns = pri.addTransform(self.root, 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 wrist self.jnt_pos.append([self.eff_loc, 'end']) #match IK FK references self.match_fk0_off = pri.addTransform(self.root, self.getName("matchFk0_npo"), tra.getTransform(self.fk_ctl[1])) # self.match_fk0_off.attr("tx").set(1.0) self.match_fk0 = pri.addTransform(self.match_fk0_off, self.getName("fk0_mth"), tra.getTransform(self.fk_ctl[0])) self.match_fk1_off = pri.addTransform(self.root, self.getName("matchFk1_npo"), tra.getTransform(self.fk_ctl[2])) # self.match_fk1_off.attr("tx").set(1.0) self.match_fk1 = pri.addTransform(self.match_fk1_off, self.getName("fk1_mth"), tra.getTransform(self.fk_ctl[1])) self.match_fk2 = pri.addTransform(self.ik_ctl, self.getName("fk2_mth"), tra.getTransform(self.fk_ctl[2])) self.match_ik = pri.addTransform(self.fk2_ctl, self.getName("ik_mth"), tra.getTransform(self.ik_ctl)) self.match_ikUpv = pri.addTransform(self.fk0_ctl, self.getName("upv_mth"), tra.getTransform(self.upv_ctl))