def addObjects(self): self.normal = self.guide.blades["blade"].z self.binormal = self.guide.blades["blade"].x self.isFk = self.settings["mode"] != 1 self.isIk = self.settings["mode"] != 0 self.isFkIk = self.settings["mode"] == 2 # FK controlers ------------------------------------ if self.isFk: self.fk_npo = [] self.fk_ctl = [] parent = self.root for i, t in enumerate(tra.getChainTransform(self.guide.apos, self.normal, self.negate)): dist = vec.getDistance(self.guide.apos[i], self.guide.apos[i+1]) fk_npo = pri.addTransform(parent, self.getName("fk%s_npo"%i), t) fk_ctl = self.addCtl(fk_npo, "fk%s_ctl"%i, t, self.color_fk, "cube", w=dist, h=self.size*.1, d=self.size*.1, po=dt.Vector(dist*.5*self.n_factor,0,0)) parent = fk_ctl self.fk_npo.append(fk_npo) self.fk_ctl.append(fk_ctl) # IK controlers ------------------------------------ if self.isIk: normal = vec.getTransposedVector(self.normal, [self.guide.apos[0], self.guide.apos[1]], [self.guide.apos[-2], self.guide.apos[-1]]) t = tra.getTransformLookingAt(self.guide.apos[-2], self.guide.apos[-1], normal, "xy", self.negate) t = tra.setMatrixPosition(t, self.guide.apos[-1]) self.ik_cns = pri.addTransform(self.root, self.getName("ik_cns"), t) self.ikcns_ctl = self.addCtl(self.ik_cns, "ikcns_ctl", t, self.color_ik, "null", w=self.size) self.ik_ctl = self.addCtl(self.ikcns_ctl, "ik_ctl", t, self.color_ik, "cube", w=self.size*.3, h=self.size*.3, d=self.size*.3) v = self.guide.apos[-1] - self.guide.apos[0] v = v ^ self.normal v.normalize() v *= self.size 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*.1) # Chain self.chain = pri.add2DChain(self.root, self.getName("chain"), self.guide.apos, self.normal, self.negate) self.ikh = pri.addIkHandle(self.root, self.getName("ikh"), self.chain) # Chain of deformers ------------------------------- self.loc = [] parent = self.root for i, t in enumerate(tra.getChainTransform(self.guide.apos, self.normal, self.negate)): loc = pri.addTransform(parent, self.getName("%s_loc"%i), t) self.addShadow(loc, i) self.loc.append(loc) parent = loc
def addOperators(self): """Create operators and set the relations for the component rig Apply operators, constraints, expressions to the hierarchy. In order to keep the code clean and easier to debug, we shouldn't create any new object in this method. """ # 1 bone chain Upv ref ============================== self.ikHandleUpvRef = primitive.addIkHandle( self.root, self.getName("ikHandleLegChainUpvRef"), self.legChainUpvRef, "ikSCsolver") pm.pointConstraint(self.ik_ctl, self.ikHandleUpvRef) pm.parentConstraint(self.legChainUpvRef[0], self.ik_ctl, self.upv_cns, mo=True) # Visibilities ------------------------------------- # shape.dispGeometry # fk fkvis_node = node.createReverseNode(self.blend_att) for shp in self.fk0_ctl.getShapes(): pm.connectAttr(fkvis_node + ".outputX", shp.attr("visibility")) for shp in self.fk1_ctl.getShapes(): pm.connectAttr(fkvis_node + ".outputX", shp.attr("visibility")) for shp in self.fk2_ctl.getShapes(): pm.connectAttr(fkvis_node + ".outputX", shp.attr("visibility")) # ik for shp in self.upv_ctl.getShapes(): pm.connectAttr(self.blend_att, shp.attr("visibility")) for shp in self.ikcns_ctl.getShapes(): pm.connectAttr(self.blend_att, shp.attr("visibility")) for shp in self.ik_ctl.getShapes(): pm.connectAttr(self.blend_att, shp.attr("visibility")) for shp in self.line_ref.getShapes(): pm.connectAttr(self.blend_att, shp.attr("visibility")) # IK Solver ----------------------------------------- out = [self.bone0, self.bone1, self.ctrn_loc, self.eff_loc] o_node = applyop.gear_ikfk2bone_op(out, self.root_ctl, self.ik_ref, self.upv_ctl, self.fk_ctl[0], self.fk_ctl[1], self.fk_ref, self.length0, self.length1, self.negate) pm.connectAttr(self.blend_att, o_node + ".blend") if self.negate: mulVal = -1 else: mulVal = 1 node.createMulNode(self.roll_att, mulVal, o_node + ".roll") # pm.connectAttr(self.roll_att, o_node+".roll") pm.connectAttr(self.scale_att, o_node + ".scaleA") pm.connectAttr(self.scale_att, o_node + ".scaleB") pm.connectAttr(self.maxstretch_att, o_node + ".maxstretch") pm.connectAttr(self.slide_att, o_node + ".slide") pm.connectAttr(self.softness_att, o_node + ".softness") pm.connectAttr(self.reverse_att, o_node + ".reverse") # Twist references --------------------------------- o_node = applyop.gear_mulmatrix_op( self.eff_loc.attr("worldMatrix"), self.root.attr("worldInverseMatrix")) dm_node = pm.createNode("decomposeMatrix") pm.connectAttr(o_node + ".output", dm_node + ".inputMatrix") pm.connectAttr(dm_node + ".outputTranslate", self.tws2_npo.attr("translate")) dm_node = pm.createNode("decomposeMatrix") pm.connectAttr(o_node + ".output", dm_node + ".inputMatrix") pm.connectAttr(dm_node + ".outputRotate", self.tws2_npo.attr("rotate")) # spline IK for twist jnts self.ikhUpLegTwist, self.uplegTwistCrv = applyop.splineIK( self.getName("uplegTwist"), self.uplegTwistChain, parent=self.root, cParent=self.bone0) self.ikhLowLegTwist, self.lowlegTwistCrv = applyop.splineIK( self.getName("lowlegTwist"), self.lowlegTwistChain, parent=self.root, cParent=self.bone1) # references self.ikhUpLegRef, self.tmpCrv = applyop.splineIK( self.getName("uplegRollRef"), self.uplegRollRef, parent=self.root, cParent=self.bone0) self.ikhLowLegRef, self.tmpCrv = applyop.splineIK( self.getName("lowlegRollRef"), self.lowlegRollRef, parent=self.root, cParent=self.eff_loc) self.ikhAuxTwist, self.tmpCrv = applyop.splineIK( self.getName("auxTwist"), self.auxTwistChain, parent=self.root, cParent=self.eff_loc) # setting connexions for ikhUpLegTwist self.ikhUpLegTwist.attr("dTwistControlEnable").set(True) self.ikhUpLegTwist.attr("dWorldUpType").set(4) self.ikhUpLegTwist.attr("dWorldUpAxis").set(3) self.ikhUpLegTwist.attr("dWorldUpVectorZ").set(1.0) self.ikhUpLegTwist.attr("dWorldUpVectorY").set(0.0) self.ikhUpLegTwist.attr("dWorldUpVectorEndZ").set(1.0) self.ikhUpLegTwist.attr("dWorldUpVectorEndY").set(0.0) pm.connectAttr(self.uplegRollRef[0].attr("worldMatrix[0]"), self.ikhUpLegTwist.attr("dWorldUpMatrix")) pm.connectAttr(self.bone0.attr("worldMatrix[0]"), self.ikhUpLegTwist.attr("dWorldUpMatrixEnd")) # setting connexions for ikhAuxTwist self.ikhAuxTwist.attr("dTwistControlEnable").set(True) self.ikhAuxTwist.attr("dWorldUpType").set(4) self.ikhAuxTwist.attr("dWorldUpAxis").set(3) self.ikhAuxTwist.attr("dWorldUpVectorZ").set(1.0) self.ikhAuxTwist.attr("dWorldUpVectorY").set(0.0) self.ikhAuxTwist.attr("dWorldUpVectorEndZ").set(1.0) self.ikhAuxTwist.attr("dWorldUpVectorEndY").set(0.0) pm.connectAttr(self.lowlegRollRef[0].attr("worldMatrix[0]"), self.ikhAuxTwist.attr("dWorldUpMatrix")) pm.connectAttr(self.tws_ref.attr("worldMatrix[0]"), self.ikhAuxTwist.attr("dWorldUpMatrixEnd")) pm.connectAttr(self.auxTwistChain[1].attr("rx"), self.ikhLowLegTwist.attr("twist")) pm.parentConstraint(self.bone1, self.aux_npo, maintainOffset=True) # scale arm length for twist chain (not the squash and stretch) arclen_node = pm.arclen(self.uplegTwistCrv, ch=True) alAttrUpLeg = arclen_node.attr("arcLength") muldiv_nodeArm = pm.createNode("multiplyDivide") pm.connectAttr(arclen_node.attr("arcLength"), muldiv_nodeArm.attr("input1X")) muldiv_nodeArm.attr("input2X").set(alAttrUpLeg.get()) muldiv_nodeArm.attr("operation").set(2) for jnt in self.uplegTwistChain: pm.connectAttr(muldiv_nodeArm.attr("outputX"), jnt.attr("sx")) # scale forearm length for twist chain (not the squash and stretch) arclen_node = pm.arclen(self.lowlegTwistCrv, ch=True) alAttrLowLeg = arclen_node.attr("arcLength") muldiv_nodeLowLeg = pm.createNode("multiplyDivide") pm.connectAttr(arclen_node.attr("arcLength"), muldiv_nodeLowLeg.attr("input1X")) muldiv_nodeLowLeg.attr("input2X").set(alAttrLowLeg.get()) muldiv_nodeLowLeg.attr("operation").set(2) for jnt in self.lowlegTwistChain: pm.connectAttr(muldiv_nodeLowLeg.attr("outputX"), jnt.attr("sx")) # scale compensation for the first twist join dm_node = pm.createNode("decomposeMatrix") pm.connectAttr(self.root.attr("worldMatrix[0]"), dm_node.attr("inputMatrix")) pm.connectAttr(dm_node.attr("outputScale"), self.uplegTwistChain[0].attr("inverseScale")) pm.connectAttr(dm_node.attr("outputScale"), self.lowlegTwistChain[0].attr("inverseScale")) # tangent controls muldiv_node = pm.createNode("multiplyDivide") muldiv_node.attr("input2X").set(-1) pm.connectAttr(self.tws1A_npo.attr("rz"), muldiv_node.attr("input1X")) muldiv_nodeBias = pm.createNode("multiplyDivide") pm.connectAttr(muldiv_node.attr("outputX"), muldiv_nodeBias.attr("input1X")) pm.connectAttr(self.roundness_att, muldiv_nodeBias.attr("input2X")) pm.connectAttr(muldiv_nodeBias.attr("outputX"), self.tws1A_loc.attr("rz")) if self.negate: axis = "xz" else: axis = "-xz" applyop.aimCns(self.tws1A_npo, self.tws0_loc, axis=axis, wupType=2, wupVector=[0, 0, 1], wupObject=self.mid_ctl, maintainOffset=False) applyop.aimCns(self.lowlegTangentB_loc, self.lowlegTangentA_npo, axis=axis, wupType=2, wupVector=[0, 0, 1], wupObject=self.mid_ctl, maintainOffset=False) pm.pointConstraint(self.eff_loc, self.lowlegTangentB_loc) muldiv_node = pm.createNode("multiplyDivide") muldiv_node.attr("input2X").set(-1) pm.connectAttr(self.tws1B_npo.attr("rz"), muldiv_node.attr("input1X")) muldiv_nodeBias = pm.createNode("multiplyDivide") pm.connectAttr(muldiv_node.attr("outputX"), muldiv_nodeBias.attr("input1X")) pm.connectAttr(self.roundness_att, muldiv_nodeBias.attr("input2X")) pm.connectAttr(muldiv_nodeBias.attr("outputX"), self.tws1B_loc.attr("rz")) if self.negate: axis = "-xz" else: axis = "xz" applyop.aimCns(self.tws1B_npo, self.tws2_loc, axis=axis, wupType=2, wupVector=[0, 0, 1], wupObject=self.mid_ctl, maintainOffset=False) applyop.aimCns(self.uplegTangentA_loc, self.uplegTangentB_npo, axis=axis, wupType=2, wupVector=[0, 0, 1], wupObject=self.mid_ctl, maintainOffset=False) # Volume ------------------------------------------- distA_node = node.createDistNode(self.tws0_loc, self.tws1_loc) distB_node = node.createDistNode(self.tws1_loc, self.tws2_loc) add_node = node.createAddNode(distA_node + ".distance", distB_node + ".distance") div_node = node.createDivNode(add_node + ".output", self.root_ctl.attr("sx")) # comp scaling issue dm_node = pm.createNode("decomposeMatrix") pm.connectAttr(self.root.attr("worldMatrix"), dm_node + ".inputMatrix") div_node2 = node.createDivNode(div_node + ".outputX", dm_node + ".outputScaleX") self.volDriver_att = div_node2 + ".outputX" # connecting tangent scaele compensation after volume to # avoid duplicate some nodes distA_node = node.createDistNode(self.tws0_loc, self.mid_ctl) distB_node = node.createDistNode(self.mid_ctl, self.tws2_loc) div_nodeUpLeg = node.createDivNode(distA_node + ".distance", dm_node.attr("outputScaleX")) div_node2 = node.createDivNode(div_nodeUpLeg + ".outputX", distA_node.attr("distance").get()) pm.connectAttr(div_node2.attr("outputX"), self.tws1A_loc.attr("sx")) pm.connectAttr(div_node2.attr("outputX"), self.uplegTangentA_loc.attr("sx")) div_nodeLowLeg = node.createDivNode(distB_node + ".distance", dm_node.attr("outputScaleX")) div_node2 = node.createDivNode(div_nodeLowLeg + ".outputX", distB_node.attr("distance").get()) pm.connectAttr(div_node2.attr("outputX"), self.tws1B_loc.attr("sx")) pm.connectAttr(div_node2.attr("outputX"), self.lowlegTangentB_loc.attr("sx")) # conection curve cnts = [ self.uplegTangentA_loc, self.uplegTangentA_ctl, self.uplegTangentB_ctl, self.kneeTangent_ctl ] applyop.gear_curvecns_op(self.uplegTwistCrv, cnts) cnts = [ self.kneeTangent_ctl, self.lowlegTangentA_ctl, self.lowlegTangentB_ctl, self.lowlegTangentB_loc ] applyop.gear_curvecns_op(self.lowlegTwistCrv, cnts) # Tangent controls vis for shp in self.uplegTangentA_ctl.getShapes(): pm.connectAttr(self.tangentVis_att, shp.attr("visibility")) for shp in self.uplegTangentB_ctl.getShapes(): pm.connectAttr(self.tangentVis_att, shp.attr("visibility")) for shp in self.lowlegTangentA_ctl.getShapes(): pm.connectAttr(self.tangentVis_att, shp.attr("visibility")) for shp in self.lowlegTangentB_ctl.getShapes(): pm.connectAttr(self.tangentVis_att, shp.attr("visibility")) for shp in self.kneeTangent_ctl.getShapes(): pm.connectAttr(self.tangentVis_att, shp.attr("visibility")) # Divisions ---------------------------------------- # at 0 or 1 the division will follow exactly the rotation of the # controler.. and we wont have this nice tangent + roll for i, div_cns in enumerate(self.div_cns): if i < (self.settings["div0"] + 2): mulmat_node = applyop.gear_mulmatrix_op( self.uplegTwistChain[i] + ".worldMatrix", div_cns + ".parentInverseMatrix") lastUpLegDiv = div_cns else: o_node = self.lowlegTwistChain[i - (self.settings["div0"] + 2)] mulmat_node = applyop.gear_mulmatrix_op( o_node + ".worldMatrix", div_cns + ".parentInverseMatrix") lastLowLegDiv = div_cns dm_node = node.createDecomposeMatrixNode(mulmat_node + ".output") pm.connectAttr(dm_node + ".outputTranslate", div_cns + ".t") pm.connectAttr(dm_node + ".outputRotate", div_cns + ".r") # Squash n Stretch o_node = applyop.gear_squashstretch2_op( div_cns, None, pm.getAttr(self.volDriver_att), "x") pm.connectAttr(self.volume_att, o_node + ".blend") pm.connectAttr(self.volDriver_att, o_node + ".driver") pm.connectAttr(self.st_att[i], o_node + ".stretch") pm.connectAttr(self.sq_att[i], o_node + ".squash") # force translation for last loc arm and foreamr applyop.gear_mulmatrix_op(self.kneeTangent_ctl.worldMatrix, lastUpLegDiv.parentInverseMatrix, lastUpLegDiv, "t") applyop.gear_mulmatrix_op(self.tws2_loc.worldMatrix, lastLowLegDiv.parentInverseMatrix, lastLowLegDiv, "t") # NOTE: next line fix the issue on meters. # This is special case becasuse the IK solver from mGear use the # scale as lenght and we have shear # TODO: check for a more clean and elegant solution instead of # re-match the world matrix again transform.matchWorldTransform(self.fk_ctl[0], self.match_fk0_off) transform.matchWorldTransform(self.fk_ctl[1], self.match_fk1_off) transform.matchWorldTransform(self.fk_ctl[0], self.match_fk0) transform.matchWorldTransform(self.fk_ctl[1], self.match_fk1) # match IK/FK ref pm.parentConstraint(self.bone0, self.match_fk0_off, mo=True) pm.parentConstraint(self.bone1, self.match_fk1_off, mo=True) return
def addOperators(self): """Create operators and set the relations for the component rig Apply operators, constraints, expressions to the hierarchy. In order to keep the code clean and easier to debug, we shouldn't create any new object in this method. """ # 1 bone chain Upv ref ============================================== self.ikHandleUpvRef = primitive.addIkHandle( self.root, self.getName("ikHandleArmChainUpvRef"), self.armChainUpvRef, "ikSCsolver") pm.pointConstraint(self.ik_ctl, self.ikHandleUpvRef) pm.parentConstraint(self.armChainUpvRef[0], self.upv_cns, mo=True) # Visibilities ------------------------------------- # fk fkvis_node = node.createReverseNode(self.blend_att) for shp in self.fk0_ctl.getShapes(): pm.connectAttr(fkvis_node + ".outputX", shp.attr("visibility")) for shp in self.fk1_ctl.getShapes(): pm.connectAttr(fkvis_node + ".outputX", shp.attr("visibility")) for shp in self.fk2_ctl.getShapes(): pm.connectAttr(fkvis_node + ".outputX", shp.attr("visibility")) # ik for shp in self.upv_ctl.getShapes(): pm.connectAttr(self.blend_att, shp.attr("visibility")) for shp in self.ikcns_ctl.getShapes(): pm.connectAttr(self.blend_att, shp.attr("visibility")) for shp in self.ik_ctl.getShapes(): pm.connectAttr(self.blend_att, shp.attr("visibility")) if self.settings["ikTR"]: for shp in self.ikRot_ctl.getShapes(): pm.connectAttr(self.blend_att, shp.attr("visibility")) # Controls ROT order ----------------------------------- attribute.setRotOrder(self.fk0_ctl, "XZY") attribute.setRotOrder(self.fk1_ctl, "XYZ") attribute.setRotOrder(self.fk2_ctl, "YZX") attribute.setRotOrder(self.ik_ctl, "XYZ") # IK Solver ----------------------------------------- out = [self.bone0, self.bone1, self.ctrn_loc, self.eff_loc] o_node = applyop.gear_ikfk2bone_op(out, self.root, self.ik_ref, self.upv_ctl, self.fk_ctl[0], self.fk_ctl[1], self.fk_ref, self.length0, self.length1, self.negate) if self.settings["ikTR"]: # connect the control inputs outEff_dm = o_node.listConnections(c=True)[-1][1] inAttr = self.ikRot_npo.attr("translate") outEff_dm.attr("outputTranslate") >> inAttr outEff_dm.attr("outputScale") >> self.ikRot_npo.attr("scale") dm_node = node.createDecomposeMatrixNode(o_node.attr("outB")) dm_node.attr("outputRotate") >> self.ikRot_npo.attr("rotate") # rotation mulM_node = applyop.gear_mulmatrix_op( self.ikRot_ctl.attr("worldMatrix"), self.eff_loc.attr("parentInverseMatrix")) intM_node = applyop.gear_intmatrix_op(o_node.attr("outEff"), mulM_node.attr("output"), o_node.attr("blend")) dm_node = node.createDecomposeMatrixNode(intM_node.attr("output")) dm_node.attr("outputRotate") >> self.eff_loc.attr("rotate") transform.matchWorldTransform(self.fk2_ctl, self.ikRot_cns) # scale: this fix the scalin popping issue intM_node = applyop.gear_intmatrix_op( self.fk2_ctl.attr("worldMatrix"), self.ik_ctl_ref.attr("worldMatrix"), o_node.attr("blend")) mulM_node = applyop.gear_mulmatrix_op( intM_node.attr("output"), self.eff_loc.attr("parentInverseMatrix")) dm_node = node.createDecomposeMatrixNode(mulM_node.attr("output")) dm_node.attr("outputScale") >> self.eff_loc.attr("scale") pm.connectAttr(self.blend_att, o_node + ".blend") if self.negate: mulVal = -1 else: mulVal = 1 node.createMulNode(self.roll_att, mulVal, o_node + ".roll") pm.connectAttr(self.scale_att, o_node + ".scaleA") pm.connectAttr(self.scale_att, o_node + ".scaleB") pm.connectAttr(self.maxstretch_att, o_node + ".maxstretch") pm.connectAttr(self.slide_att, o_node + ".slide") pm.connectAttr(self.softness_att, o_node + ".softness") pm.connectAttr(self.reverse_att, o_node + ".reverse") # Twist references --------------------------------- pm.pointConstraint(self.mid_ctl_twst_ref, self.tws1_npo, maintainOffset=False) pm.connectAttr(self.mid_ctl.scaleX, self.tws1_loc.scaleX) pm.orientConstraint(self.mid_ctl_twst_ref, self.tws1_npo, maintainOffset=False) o_node = applyop.gear_mulmatrix_op(self.eff_loc.attr( "worldMatrix"), self.root.attr("worldInverseMatrix")) dm_node = pm.createNode("decomposeMatrix") pm.connectAttr(o_node + ".output", dm_node + ".inputMatrix") pm.connectAttr(dm_node + ".outputTranslate", self.tws2_npo.attr("translate")) dm_node = pm.createNode("decomposeMatrix") pm.connectAttr(o_node + ".output", dm_node + ".inputMatrix") pm.connectAttr(dm_node + ".outputRotate", self.tws2_npo.attr("rotate")) o_node = applyop.gear_mulmatrix_op( self.eff_loc.attr("worldMatrix"), self.tws2_rot.attr("parentInverseMatrix")) dm_node = pm.createNode("decomposeMatrix") pm.connectAttr(o_node + ".output", dm_node + ".inputMatrix") attribute.setRotOrder(self.tws2_rot, "XYZ") pm.connectAttr(dm_node + ".outputRotate", self.tws2_rot + ".rotate") self.tws0_rot.setAttr("sx", .001) self.tws2_rot.setAttr("sx", .001) add_node = node.createAddNode(self.roundness_att, .001) pm.connectAttr(add_node + ".output", self.tws1_rot.attr("sx")) pm.connectAttr(self.armpit_roll_att, self.tws0_rot + ".rotateX") # Roll Shoulder applyop.splineIK(self.getName("rollRef"), self.rollRef, parent=self.root, cParent=self.bone0) # Volume ------------------------------------------- distA_node = node.createDistNode(self.tws0_loc, self.tws1_loc) distB_node = node.createDistNode(self.tws1_loc, self.tws2_loc) add_node = node.createAddNode(distA_node + ".distance", distB_node + ".distance") div_node = node.createDivNode(add_node + ".output", self.root.attr("sx")) dm_node = pm.createNode("decomposeMatrix") pm.connectAttr(self.root.attr("worldMatrix"), dm_node + ".inputMatrix") div_node2 = node.createDivNode(div_node + ".outputX", dm_node + ".outputScaleX") self.volDriver_att = div_node2 + ".outputX" if self.settings["extraTweak"]: for tweak_ctl in self.tweak_ctl: for shp in tweak_ctl.getShapes(): pm.connectAttr(self.tweakVis_att, shp.attr("visibility")) # Divisions ---------------------------------------- # at 0 or 1 the division will follow exactly the rotation of the # controler.. and we wont have this nice tangent + roll for i, div_cns in enumerate(self.div_cns): if i < (self.settings["div0"] + 1): perc = i * .5 / (self.settings["div0"] + 1.0) elif i < (self.settings["div0"] + 2): perc = .49 elif i < (self.settings["div0"] + 3): perc = .50 elif i < (self.settings["div0"] + 4): perc = .51 else: perc = .5 + \ (i - self.settings["div0"] - 3.0) * .5 / \ (self.settings["div1"] + 1.0) perc = max(.001, min(.990, perc)) # Roll if self.negate: o_node = applyop.gear_rollsplinekine_op( div_cns, [self.tws2_rot, self.tws1_rot, self.tws0_rot], 1 - perc, 40) else: o_node = applyop.gear_rollsplinekine_op( div_cns, [self.tws0_rot, self.tws1_rot, self.tws2_rot], perc, 40) pm.connectAttr(self.resample_att, o_node + ".resample") pm.connectAttr(self.absolute_att, o_node + ".absolute") # Squash n Stretch o_node = applyop.gear_squashstretch2_op( div_cns, None, pm.getAttr(self.volDriver_att), "x") pm.connectAttr(self.volume_att, o_node + ".blend") pm.connectAttr(self.volDriver_att, o_node + ".driver") pm.connectAttr(self.st_att[i], o_node + ".stretch") pm.connectAttr(self.sq_att[i], o_node + ".squash") # match IK/FK ref pm.parentConstraint(self.bone0, self.match_fk0_off, mo=True) pm.parentConstraint(self.bone1, self.match_fk1_off, mo=True) if self.settings["ikTR"]: transform.matchWorldTransform(self.ikRot_ctl, self.match_ikRot) transform.matchWorldTransform(self.fk_ctl[2], self.match_fk2) return
def addOperators(self): """Create operators and set the relations for the component rig Apply operators, constraints, expressions to the hierarchy. In order to keep the code clean and easier to debug, we shouldn't create any new object in this method. """ # Soft condition soft_cond_node = node.createConditionNode(self.soft_attr, 0.0001, 4, 0.0001, self.soft_attr) self.soft_attr_cond = soft_cond_node.outColorR if self.settings["ikSolver"]: self.ikSolver = "ikRPsolver" else: pm.mel.eval("ikSpringSolver;") self.ikSolver = "ikSpringSolver" # 1 bone chain Upv ref =============================== self.ikHandleUpvRef = primitive.addIkHandle( self.root, self.getName("ikHandleLegChainUpvRef"), self.legChainUpvRef, "ikSCsolver") pm.pointConstraint(self.ik_ctl, self.ikHandleUpvRef) pm.parentConstraint(self.legChainUpvRef[0], self.upv_cns, mo=True) # mid joints ================================================ for xjnt, midJ in zip(self.legBones[1:3], [self.mid1_jnt, self.mid2_jnt]): node.createPairBlend(None, xjnt, .5, 1, midJ) pm.connectAttr(xjnt + ".translate", midJ + ".translate", f=True) pm.parentConstraint(self.mid1_jnt, self.knee_lvl) pm.parentConstraint(self.mid2_jnt, self.ankle_lvl) # joint length multiply multJnt1_node = node.createMulNode(self.boneALenght_attr, self.boneALenghtMult_attr) multJnt2_node = node.createMulNode(self.boneBLenght_attr, self.boneBLenghtMult_attr) multJnt3_node = node.createMulNode(self.boneCLenght_attr, self.boneCLenghtMult_attr) # # IK 3 bones =============================================== self.ikHandle = primitive.addIkHandle(self.softblendLoc, self.getName("ik3BonesHandle"), self.chain3bones, self.ikSolver, self.upv_ctl) # TwistTest if [round(elem, 4) for elem in transform.getTranslation(self.chain3bones[1])] \ != [round(elem, 4) for elem in self.guide.apos[1]]: add_nodeTwist = node.createAddNode(180.0, self.roll_att) else: add_nodeTwist = node.createAddNode(0, self.roll_att) if self.negate: mulVal = 1 else: mulVal = -1 node.createMulNode(add_nodeTwist + ".output", mulVal, self.ikHandle.attr("twist")) # stable spring solver doble rotation pm.pointConstraint(self.root_ctl, self.chain3bones[0]) # softIK 3 bones operators applyop.aimCns(self.aim_tra, self.ik_ref, axis="zx", wupType=4, wupVector=[1, 0, 0], wupObject=self.root_ctl, maintainOffset=False) plusTotalLength_node = node.createPlusMinusAverage1D([ multJnt1_node.attr("outputX"), multJnt2_node.attr("outputX"), multJnt3_node.attr("outputX") ]) subtract1_node = node.createPlusMinusAverage1D( [plusTotalLength_node.attr("output1D"), self.soft_attr_cond], 2) distance1_node = node.createDistNode(self.ik_ref, self.aim_tra) div1_node = node.createDivNode(1.0, self.rig.global_ctl + ".sx") mult1_node = node.createMulNode(distance1_node + ".distance", div1_node + ".outputX") subtract2_node = node.createPlusMinusAverage1D( [mult1_node.attr("outputX"), subtract1_node.attr("output1D")], 2) div2_node = node.createDivNode(subtract2_node + ".output1D", self.soft_attr_cond) mult2_node = node.createMulNode(-1, div2_node + ".outputX") power_node = node.createPowNode(self.softSpeed_attr, mult2_node + ".outputX") mult3_node = node.createMulNode(self.soft_attr_cond, power_node + ".outputX") subtract3_node = node.createPlusMinusAverage1D([ plusTotalLength_node.attr("output1D"), mult3_node.attr("outputX") ], 2) cond1_node = node.createConditionNode( self.soft_attr_cond, 0, 2, subtract3_node + ".output1D", plusTotalLength_node + ".output1D") cond2_node = node.createConditionNode(mult1_node + ".outputX", subtract1_node + ".output1D", 2, cond1_node + ".outColorR", mult1_node + ".outputX") pm.connectAttr(cond2_node + ".outColorR", self.wristSoftIK + ".tz") # soft blend pc_node = pm.pointConstraint(self.wristSoftIK, self.ik_ref, self.softblendLoc) node.createReverseNode(self.stretch_attr, pc_node + ".target[0].targetWeight") pm.connectAttr(self.stretch_attr, pc_node + ".target[1].targetWeight", f=True) # Stretch distance2_node = node.createDistNode(self.softblendLoc, self.wristSoftIK) mult4_node = node.createMulNode(distance2_node + ".distance", div1_node + ".outputX") # bones for i, mulNode in enumerate( [multJnt1_node, multJnt2_node, multJnt3_node]): div3_node = node.createDivNode(mulNode + ".outputX", plusTotalLength_node + ".output1D") mult5_node = node.createMulNode(mult4_node + ".outputX", div3_node + ".outputX") mult6_node = node.createMulNode(self.stretch_attr, mult5_node + ".outputX") node.createPlusMinusAverage1D( [mulNode.attr("outputX"), mult6_node.attr("outputX")], 1, self.chain3bones[i + 1] + ".tx") # IK 2 bones =============================================== self.ikHandle2 = primitive.addIkHandle(self.softblendLoc2, self.getName("ik2BonesHandle"), self.chain2bones, self.ikSolver, self.upv_ctl) node.createMulNode(self.roll_att, mulVal, self.ikHandle2.attr("twist")) # stable spring solver doble rotation pm.pointConstraint(self.root_ctl, self.chain2bones[0]) parentc_node = pm.parentConstraint(self.ik2b_ikCtl_ref, self.ik2b_bone_ref, self.ik2b_blend) node.createReverseNode(self.fullIK_attr, parentc_node + ".target[0].targetWeight") pm.connectAttr(self.fullIK_attr, parentc_node + ".target[1].targetWeight", f=True) # softIK 2 bones operators applyop.aimCns(self.aim_tra2, self.ik2b_ik_ref, axis="zx", wupType=4, wupVector=[1, 0, 0], wupObject=self.root_ctl, maintainOffset=False) plusTotalLength_node = node.createPlusMinusAverage1D( [multJnt1_node.attr("outputX"), multJnt2_node.attr("outputX")]) subtract1_node = node.createPlusMinusAverage1D( [plusTotalLength_node.attr("output1D"), self.soft_attr_cond], 2) distance1_node = node.createDistNode(self.ik2b_ik_ref, self.aim_tra2) div1_node = node.createDivNode(1, self.rig.global_ctl + ".sx") mult1_node = node.createMulNode(distance1_node + ".distance", div1_node + ".outputX") subtract2_node = node.createPlusMinusAverage1D( [mult1_node.attr("outputX"), subtract1_node.attr("output1D")], 2) div2_node = node.createDivNode(subtract2_node + ".output1D", self.soft_attr_cond) mult2_node = node.createMulNode(-1, div2_node + ".outputX") power_node = node.createPowNode(self.softSpeed_attr, mult2_node + ".outputX") mult3_node = node.createMulNode(self.soft_attr_cond, power_node + ".outputX") subtract3_node = node.createPlusMinusAverage1D([ plusTotalLength_node.attr("output1D"), mult3_node.attr("outputX") ], 2) cond1_node = node.createConditionNode( self.soft_attr_cond, 0, 2, subtract3_node + ".output1D", plusTotalLength_node + ".output1D") cond2_node = node.createConditionNode(mult1_node + ".outputX", subtract1_node + ".output1D", 2, cond1_node + ".outColorR", mult1_node + ".outputX") pm.connectAttr(cond2_node + ".outColorR", self.ankleSoftIK + ".tz") # soft blend pc_node = pm.pointConstraint(self.ankleSoftIK, self.ik2b_ik_ref, self.softblendLoc2) node.createReverseNode(self.stretch_attr, pc_node + ".target[0].targetWeight") pm.connectAttr(self.stretch_attr, pc_node + ".target[1].targetWeight", f=True) # Stretch distance2_node = node.createDistNode(self.softblendLoc2, self.ankleSoftIK) mult4_node = node.createMulNode(distance2_node + ".distance", div1_node + ".outputX") for i, mulNode in enumerate([multJnt1_node, multJnt2_node]): div3_node = node.createDivNode(mulNode + ".outputX", plusTotalLength_node + ".output1D") mult5_node = node.createMulNode(mult4_node + ".outputX", div3_node + ".outputX") mult6_node = node.createMulNode(self.stretch_attr, mult5_node + ".outputX") node.createPlusMinusAverage1D( [mulNode.attr("outputX"), mult6_node.attr("outputX")], 1, self.chain2bones[i + 1] + ".tx") # IK/FK connections for i, x in enumerate(self.fk_ctl): pm.parentConstraint(x, self.legBonesFK[i], mo=True) for i, x in enumerate([self.chain2bones[0], self.chain2bones[1]]): pm.parentConstraint(x, self.legBonesIK[i], mo=True) pm.pointConstraint(self.ik2b_ik_ref, self.legBonesIK[2]) applyop.aimCns(self.legBonesIK[2], self.roll_ctl, axis="xy", wupType=4, wupVector=[0, 1, 0], wupObject=self.legBonesIK[1], maintainOffset=False) pm.connectAttr(self.chain3bones[-1].attr("tx"), self.legBonesIK[-1].attr("tx")) # foot twist roll pm.orientConstraint(self.ik_ref, self.legBonesIK[-1], mo=True) node.createMulNode(-1, self.chain3bones[-1].attr("tx"), self.ik2b_ik_ref.attr("tx")) for i, x in enumerate(self.legBones): node.createPairBlend(self.legBonesFK[i], self.legBonesIK[i], self.blend_att, 1, x) # Twist references ---------------------------------------- self.ikhArmRef, self.tmpCrv = applyop.splineIK( self.getName("legRollRef"), self.rollRef, parent=self.root, cParent=self.legBones[0]) initRound = .001 multVal = 1 multTangent_node = node.createMulNode(self.roundnessKnee_att, multVal) add_node = node.createAddNode(multTangent_node + ".outputX", initRound) pm.connectAttr(add_node + ".output", self.tws1_rot.attr("sx")) for x in ["translate"]: pm.connectAttr(self.knee_ctl.attr(x), self.tws1_loc.attr(x)) for x in "xy": pm.connectAttr(self.knee_ctl.attr("r" + x), self.tws1_loc.attr("r" + x)) multTangent_node = node.createMulNode(self.roundnessAnkle_att, multVal) add_node = node.createAddNode(multTangent_node + ".outputX", initRound) pm.connectAttr(add_node + ".output", self.tws2_rot.attr("sx")) for x in ["translate"]: pm.connectAttr(self.ankle_ctl.attr(x), self.tws2_loc.attr(x)) for x in "xy": pm.connectAttr(self.ankle_ctl.attr("r" + x), self.tws2_loc.attr("r" + x)) # Volume ------------------------------------------- distA_node = node.createDistNode(self.tws0_loc, self.tws1_loc) distB_node = node.createDistNode(self.tws1_loc, self.tws2_loc) distC_node = node.createDistNode(self.tws2_loc, self.tws3_loc) add_node = node.createAddNode(distA_node + ".distance", distB_node + ".distance") add_node2 = node.createAddNode(distC_node + ".distance", add_node + ".output") div_node = node.createDivNode(add_node2 + ".output", self.root_ctl.attr("sx")) # comp scaling dm_node = node.createDecomposeMatrixNode(self.root.attr("worldMatrix")) div_node2 = node.createDivNode(div_node + ".outputX", dm_node + ".outputScaleX") self.volDriver_att = div_node2 + ".outputX" # Flip Offset ---------------------------------------- pm.connectAttr(self.ankleFlipOffset_att, self.tws2_loc.attr("rz")) pm.connectAttr(self.kneeFlipOffset_att, self.tws1_loc.attr("rz")) # Divisions ---------------------------------------- # at 0 or 1 the division will follow exactly the rotation of the # controler.. and we wont have this nice tangent + roll for i, div_cns in enumerate(self.div_cns): subdiv = False if i == len(self.div_cns) - 1 or i == 0: subdiv = 45 else: subdiv = 45 if i < (self.settings["div0"] + 1): perc = i * .333 / (self.settings["div0"] + 1.0) elif i < (self.settings["div0"] + self.settings["div1"] + 2): perc = i * .333 / (self.settings["div0"] + 1.0) else: perc = (.5 + (i - self.settings["div0"] - 3.0) * .5 / (self.settings["div1"] + 1.0)) if i < (self.settings["div0"] + 2): perc = i * .333 / (self.settings["div0"] + 1.0) elif i < (self.settings["div0"] + self.settings["div1"] + 3): perc = (.333 + (i - self.settings["div0"] - 1) * .333 / (self.settings["div1"] + 1.0)) else: perc = ( .666 + (i - self.settings["div1"] - self.settings["div0"] - 2.0) * .333 / (self.settings["div2"] + 1.0)) # we neet to offset the ankle and knee point to force the bone # orientation to the nex bone span if perc == .333: perc = .3338 elif perc == .666: perc = .6669 perc = max(.001, min(.999, perc)) # Roll cts = [self.tws0_rot, self.tws1_rot, self.tws2_rot, self.tws3_rot] o_node = applyop.gear_rollsplinekine_op(div_cns, cts, perc, subdiv) pm.connectAttr(self.resample_att, o_node + ".resample") pm.connectAttr(self.absolute_att, o_node + ".absolute") # Squash n Stretch o_node = applyop.gear_squashstretch2_op( div_cns, None, pm.getAttr(self.volDriver_att), "x") pm.connectAttr(self.volume_att, o_node + ".blend") pm.connectAttr(self.volDriver_att, o_node + ".driver") pm.connectAttr(self.st_att[i], o_node + ".stretch") pm.connectAttr(self.sq_att[i], o_node + ".squash") # Visibilities ------------------------------------- # fk fkvis_node = node.createReverseNode(self.blend_att) for ctrl in self.fk_ctl: for shp in ctrl.getShapes(): pm.connectAttr(fkvis_node + ".outputX", shp.attr("visibility")) # ik for ctrl in [self.ik_ctl, self.roll_ctl]: for shp in ctrl.getShapes(): pm.connectAttr(self.blend_att, shp.attr("visibility")) # setup leg o_node scale compensate pm.connectAttr(self.rig.global_ctl + ".scale", self.setup + ".scale") return
def addOperators(self): """Create operators and set the relations for the component rig Apply operators, constraints, expressions to the hierarchy. In order to keep the code clean and easier to debug, we shouldn't create any new object in this method. """ # 1 bone chain Upv ref =========================== self.ikHandleUpvRef = primitive.addIkHandle( self.root, self.getName("ikHandleLegChainUpvRef"), self.legChainUpvRef, "ikSCsolver") pm.pointConstraint(self.ik_ctl, self.ikHandleUpvRef) pm.parentConstraint(self.legChainUpvRef[0], self.ik_ctl, self.upv_cns, mo=True) # Visibilities ------------------------------------- # shape.dispGeometry # fk fkvis_node = node.createReverseNode(self.blend_att) for shp in self.fk0_ctl.getShapes(): pm.connectAttr(fkvis_node + ".outputX", shp.attr("visibility")) for shp in self.fk1_ctl.getShapes(): pm.connectAttr(fkvis_node + ".outputX", shp.attr("visibility")) for shp in self.fk2_ctl.getShapes(): pm.connectAttr(fkvis_node + ".outputX", shp.attr("visibility")) # ik for shp in self.upv_ctl.getShapes(): pm.connectAttr(self.blend_att, shp.attr("visibility")) for shp in self.ikcns_ctl.getShapes(): pm.connectAttr(self.blend_att, shp.attr("visibility")) for shp in self.ik_ctl.getShapes(): pm.connectAttr(self.blend_att, shp.attr("visibility")) # IK Solver ----------------------------------------- out = [self.bone0, self.bone1, self.ctrn_loc, self.eff_loc] o_node = applyop.gear_ikfk2bone_op(out, self.root_ctl, self.ik_ref, self.upv_ctl, self.fk_ctl[0], self.fk_ctl[1], self.fk_ref, self.length0, self.length1, self.negate) pm.connectAttr(self.blend_att, o_node + ".blend") if self.negate: mulVal = -1 else: mulVal = 1 node.createMulNode(self.roll_att, mulVal, o_node + ".roll") pm.connectAttr(self.scale_att, o_node + ".scaleA") pm.connectAttr(self.scale_att, o_node + ".scaleB") pm.connectAttr(self.maxstretch_att, o_node + ".maxstretch") pm.connectAttr(self.slide_att, o_node + ".slide") pm.connectAttr(self.softness_att, o_node + ".softness") pm.connectAttr(self.reverse_att, o_node + ".reverse") # Twist references --------------------------------- self.ikhArmRef, self.tmpCrv = applyop.splineIK( self.getName("legRollRef"), self.rollRef, parent=self.root, cParent=self.bone0) pm.pointConstraint(self.mid_ctl, self.tws1_loc, maintainOffset=False) pm.scaleConstraint(self.mid_ctl, self.tws1_loc, maintainOffset=False) applyop.oriCns(self.mid_ctl, self.tws1_rot, maintainOffset=False) pm.pointConstraint(self.eff_loc, self.tws2_loc, maintainOffset=False) pm.scaleConstraint(self.eff_loc, self.tws2_loc, maintainOffset=False) applyop.oriCns(self.bone1, self.tws2_loc, maintainOffset=False) applyop.oriCns(self.tws_ref, self.tws2_rot) self.tws0_loc.setAttr("sx", .001) self.tws2_loc.setAttr("sx", .001) add_node = node.createAddNode(self.roundness_att, .001) pm.connectAttr(add_node + ".output", self.tws1_rot.attr("sx")) # Volume ------------------------------------------- distA_node = node.createDistNode(self.tws0_loc, self.tws1_loc) distB_node = node.createDistNode(self.tws1_loc, self.tws2_loc) add_node = node.createAddNode(distA_node + ".distance", distB_node + ".distance") div_node = node.createDivNode(add_node + ".output", self.root_ctl.attr("sx")) # comp scaling issue dm_node = pm.createNode("decomposeMatrix") pm.connectAttr(self.root.attr("worldMatrix"), dm_node + ".inputMatrix") div_node2 = node.createDivNode(div_node + ".outputX", dm_node + ".outputScaleX") self.volDriver_att = div_node2 + ".outputX" # Divisions ---------------------------------------- # at 0 or 1 the division will follow exactly the rotation of the # controler.. and we wont have this nice tangent + roll for i, div_cns in enumerate(self.div_cns): subdiv = False if i == len(self.div_cns) - 1 or i == 0: subdiv = 45 else: subdiv = 10 if i < (self.settings["div0"] + 1): perc = i * .5 / (self.settings["div0"] + 1.0) elif i < (self.settings["div0"] + 2): perc = .49 subdiv = 45 elif i < (self.settings["div0"] + 3): perc = .50 subdiv = 45 elif i < (self.settings["div0"] + 4): perc = .51 subdiv = 45 else: perc = (.5 + (i - self.settings["div0"] - 3.0) * .5 / (self.settings["div1"] + 1.0)) perc = max(.001, min(.999, perc)) # Roll if self.negate: o_node = applyop.gear_rollsplinekine_op( div_cns, [self.tws2_rot, self.tws1_rot, self.tws0_rot], 1 - perc, subdiv) else: o_node = applyop.gear_rollsplinekine_op( div_cns, [self.tws0_rot, self.tws1_rot, self.tws2_rot], perc, subdiv) pm.connectAttr(self.resample_att, o_node + ".resample") pm.connectAttr(self.absolute_att, o_node + ".absolute") # Squash n Stretch o_node = applyop.gear_squashstretch2_op( div_cns, None, pm.getAttr(self.volDriver_att), "x") pm.connectAttr(self.volume_att, o_node + ".blend") pm.connectAttr(self.volDriver_att, o_node + ".driver") pm.connectAttr(self.st_att[i], o_node + ".stretch") pm.connectAttr(self.sq_att[i], o_node + ".squash") # NOTE: next line fix the issue on meters. # This is special case becasuse the IK solver from mGear use # the scale as lenght and we have shear # TODO: check for a more clean and elegant solution instead of # re-match the world matrix again # transform.matchWorldTransform(self.fk_ctl[0], self.match_fk0_off) # transform.matchWorldTransform(self.fk_ctl[1], self.match_fk1_off) # transform.matchWorldTransform(self.fk_ctl[0], self.match_fk0) # transform.matchWorldTransform(self.fk_ctl[1], self.match_fk1) # match IK/FK ref pm.parentConstraint(self.bone0, self.match_fk0_off, mo=True) pm.parentConstraint(self.bone1, self.match_fk1_off, mo=True) return
def addOperators(self): """Create operators and set the relations for the component rig Apply operators, constraints, expressions to the hierarchy. In order to keep the code clean and easier to debug, we shouldn't create any new object in this method. """ # Auto bend ---------------------------- if self.settings["autoBend"]: mul_node = node.createMulNode( [self.autoBendChain[0].ry, self.autoBendChain[0].rz], [self.sideBend_att, self.frontBend_att]) mul_node.outputX >> self.ik1autoRot_lvl.rz mul_node.outputY >> self.ik1autoRot_lvl.rx self.ikHandleAutoBend = primitive.addIkHandle( self.autoBend_ctl, self.getName("ikHandleAutoBend"), self.autoBendChain, "ikSCsolver") # Tangent position --------------------------------- # common part d = vector.getDistance(self.guide.apos[0], self.guide.apos[1]) dist_node = node.createDistNode(self.ik0_ctl, self.ik1_ctl) rootWorld_node = node.createDecomposeMatrixNode( self.root.attr("worldMatrix")) div_node = node.createDivNode(dist_node + ".distance", rootWorld_node + ".outputScaleX") div_node = node.createDivNode(div_node + ".outputX", d) # tan0 mul_node = node.createMulNode(self.tan0_att, self.tan0_npo.getAttr("ty")) res_node = node.createMulNode(mul_node + ".outputX", div_node + ".outputX") pm.connectAttr(res_node + ".outputX", self.tan0_npo.attr("ty")) # tan1 mul_node = node.createMulNode(self.tan1_att, self.tan1_npo.getAttr("ty")) res_node = node.createMulNode(mul_node + ".outputX", div_node + ".outputX") pm.connectAttr(res_node + ".outputX", self.tan1_npo.attr("ty")) # Tangent Mid -------------------------------------- if self.settings["centralTangent"]: tanIntMat = applyop.gear_intmatrix_op( self.tan0_npo.attr("worldMatrix"), self.tan1_npo.attr("worldMatrix"), .5) applyop.gear_mulmatrix_op( tanIntMat.attr("output"), self.tan_npo.attr("parentInverseMatrix[0]"), self.tan_npo) pm.connectAttr(self.tan_ctl.attr("translate"), self.tan0_off.attr("translate")) pm.connectAttr(self.tan_ctl.attr("translate"), self.tan1_off.attr("translate")) # Curves ------------------------------------------- op = applyop.gear_curveslide2_op( self.slv_crv, self.mst_crv, 0, 1.5, .5, .5) pm.connectAttr(self.position_att, op + ".position") pm.connectAttr(self.maxstretch_att, op + ".maxstretch") pm.connectAttr(self.maxsquash_att, op + ".maxsquash") pm.connectAttr(self.softness_att, op + ".softness") # Volume driver ------------------------------------ crv_node = node.createCurveInfoNode(self.slv_crv) # Division ----------------------------------------- for i in range(self.settings["division"]): # References u = i / (self.settings["division"] - 1.0) cns = applyop.pathCns( self.div_cns[i], self.slv_crv, False, u, True) cns.setAttr("frontAxis", 1) # front axis is 'Y' cns.setAttr("upAxis", 0) # front axis is 'X' # Roll intMatrix = applyop.gear_intmatrix_op( self.ik0_ctl + ".worldMatrix", self.ik1_ctl + ".worldMatrix", u) dm_node = node.createDecomposeMatrixNode(intMatrix + ".output") pm.connectAttr(dm_node + ".outputRotate", self.twister[i].attr("rotate")) pm.parentConstraint(self.twister[i], self.ref_twist[i], maintainOffset=True) pm.connectAttr(self.ref_twist[i] + ".translate", cns + ".worldUpVector") # compensate scale reference div_node = node.createDivNode([1, 1, 1], [rootWorld_node + ".outputScaleX", rootWorld_node + ".outputScaleY", rootWorld_node + ".outputScaleZ"]) # Squash n Stretch op = applyop.gear_squashstretch2_op( self.scl_transforms[i], self.root, pm.arclen(self.slv_crv), "y", div_node + ".output") pm.connectAttr(self.volume_att, op + ".blend") pm.connectAttr(crv_node + ".arcLength", op + ".driver") pm.connectAttr(self.st_att[i], op + ".stretch") pm.connectAttr(self.sq_att[i], op + ".squash") # Controlers if i == 0: mulmat_node = applyop.gear_mulmatrix_op( self.div_cns[i].attr("worldMatrix"), self.root.attr("worldInverseMatrix")) dm_node = node.createDecomposeMatrixNode( mulmat_node + ".output") pm.connectAttr(dm_node + ".outputTranslate", self.fk_npo[i].attr("t")) else: mulmat_node = applyop.gear_mulmatrix_op( self.div_cns[i].attr("worldMatrix"), self.div_cns[i - 1].attr("worldInverseMatrix")) dm_node = node.createDecomposeMatrixNode( mulmat_node + ".output") mul_node = node.createMulNode(div_node + ".output", dm_node + ".outputTranslate") pm.connectAttr(mul_node + ".output", self.fk_npo[i].attr("t")) pm.connectAttr(dm_node + ".outputRotate", self.fk_npo[i].attr("r")) # Orientation Lock if i == 0: dm_node = node.createDecomposeMatrixNode( self.ik0_ctl + ".worldMatrix") blend_node = node.createBlendNode( [dm_node + ".outputRotate%s" % s for s in "XYZ"], [cns + ".rotate%s" % s for s in "XYZ"], self.lock_ori0_att) self.div_cns[i].attr("rotate").disconnect() pm.connectAttr(blend_node + ".output", self.div_cns[i] + ".rotate") elif i == self.settings["division"] - 1: dm_node = node.createDecomposeMatrixNode( self.ik1_ctl + ".worldMatrix") blend_node = node.createBlendNode( [dm_node + ".outputRotate%s" % s for s in "XYZ"], [cns + ".rotate%s" % s for s in "XYZ"], self.lock_ori1_att) self.div_cns[i].attr("rotate").disconnect() pm.connectAttr(blend_node + ".output", self.div_cns[i] + ".rotate") # Connections (Hooks) ------------------------------ pm.parentConstraint(self.scl_transforms[0], self.cnx0) pm.scaleConstraint(self.scl_transforms[0], self.cnx0) pm.parentConstraint(self.scl_transforms[-1], self.cnx1) pm.scaleConstraint(self.scl_transforms[-1], self.cnx1)
def addOperators(self): # 1 bone chain Upv ref ===================================================================================== self.ikHandleUpvRef = pri.addIkHandle( self.root, self.getName("ikHandleLegChainUpvRef"), self.armChainUpvRef, "ikSCsolver") pm.pointConstraint(self.ik_ctl, self.ikHandleUpvRef) pm.parentConstraint(self.armChainUpvRef[0], self.upv_cns, mo=True) # Visibilities ------------------------------------- # fk fkvis_node = nod.createReverseNode(self.blend_att) for shp in self.fk0_ctl.getShapes(): pm.connectAttr(fkvis_node + ".outputX", shp.attr("visibility")) for shp in self.fk1_ctl.getShapes(): pm.connectAttr(fkvis_node + ".outputX", shp.attr("visibility")) for shp in self.fk2_ctl.getShapes(): pm.connectAttr(fkvis_node + ".outputX", shp.attr("visibility")) # ik for shp in self.upv_ctl.getShapes(): pm.connectAttr(self.blend_att, shp.attr("visibility")) for shp in self.ikcns_ctl.getShapes(): pm.connectAttr(self.blend_att, shp.attr("visibility")) for shp in self.ik_ctl.getShapes(): pm.connectAttr(self.blend_att, shp.attr("visibility")) if self.settings["ikTR"]: for shp in self.ikRot_ctl.getShapes(): pm.connectAttr(self.blend_att, shp.attr("visibility")) # Controls ROT order ----------------------------------- att.setRotOrder(self.fk0_ctl, "XZY") att.setRotOrder(self.fk1_ctl, "XYZ") att.setRotOrder(self.fk2_ctl, "YZX") # att.setRotOrder(self.ik_ctl, "ZYX") att.setRotOrder(self.ik_ctl, "XYZ") # IK Solver ----------------------------------------- out = [self.bone0, self.bone1, self.ctrn_loc, self.eff_loc] node = aop.gear_ikfk2bone_op(out, self.root, self.ik_ref, self.upv_ctl, self.fk_ctl[0], self.fk_ctl[1], self.fk_ref, self.length0, self.length1, self.negate) if self.settings["ikTR"]: #connect the control inputs outEff_dm = node.listConnections(c=True)[-1][1] outEff_dm.attr("outputTranslate") >> self.ikRot_npo.attr( "translate") outEff_dm.attr("outputScale") >> self.ikRot_npo.attr("scale") dm_node = nod.createDecomposeMatrixNode(node.attr("outB")) dm_node.attr("outputRotate") >> self.ikRot_npo.attr("rotate") #rotation # intM_node = aop.gear_intmatrix_op(node.attr("outEff"), self.ikRot_ctl.attr("worldMatrix"), node.attr("blend")) # mulM_node = aop.gear_mulmatrix_op(intM_node.attr("output"), self.eff_loc.attr("parentInverseMatrix")) # dm_node = nod.createDecomposeMatrixNode(mulM_node.attr("output")) mulM_node = aop.gear_mulmatrix_op( self.ikRot_ctl.attr("worldMatrix"), self.eff_loc.attr("parentInverseMatrix")) intM_node = aop.gear_intmatrix_op(node.attr("outEff"), mulM_node.attr("output"), node.attr("blend")) dm_node = nod.createDecomposeMatrixNode(intM_node.attr("output")) dm_node.attr("outputRotate") >> self.eff_loc.attr("rotate") #scale: this fix the scalin popping issue intM_node = aop.gear_intmatrix_op(self.fk2_ctl.attr("worldMatrix"), self.ik_ctl.attr("worldMatrix"), node.attr("blend")) mulM_node = aop.gear_mulmatrix_op( intM_node.attr("output"), self.eff_loc.attr("parentInverseMatrix")) dm_node = nod.createDecomposeMatrixNode(mulM_node.attr("output")) dm_node.attr("outputScale") >> self.eff_loc.attr("scale") pm.connectAttr(self.blend_att, node + ".blend") pm.connectAttr(self.roll_att, node + ".roll") pm.connectAttr(self.scale_att, node + ".scaleA") pm.connectAttr(self.scale_att, node + ".scaleB") pm.connectAttr(self.maxstretch_att, node + ".maxstretch") pm.connectAttr(self.slide_att, node + ".slide") pm.connectAttr(self.softness_att, node + ".softness") pm.connectAttr(self.reverse_att, node + ".reverse") # Twist references --------------------------------- pm.pointConstraint(self.mid_ctl, self.tws1_npo, maintainOffset=False) pm.scaleConstraint(self.mid_ctl, self.tws1_npo, maintainOffset=False) pm.orientConstraint(self.mid_ctl, self.tws1_npo, maintainOffset=False) node = aop.gear_mulmatrix_op(self.eff_loc.attr("worldMatrix"), self.root.attr("worldInverseMatrix")) dm_node = pm.createNode("decomposeMatrix") pm.connectAttr(node + ".output", dm_node + ".inputMatrix") pm.connectAttr(dm_node + ".outputTranslate", self.tws2_npo.attr("translate")) dm_node = pm.createNode("decomposeMatrix") pm.connectAttr(node + ".output", dm_node + ".inputMatrix") pm.connectAttr(dm_node + ".outputRotate", self.tws2_npo.attr("rotate")) node = aop.gear_mulmatrix_op(self.eff_loc.attr("worldMatrix"), self.tws2_rot.attr("parentInverseMatrix")) dm_node = pm.createNode("decomposeMatrix") pm.connectAttr(node + ".output", dm_node + ".inputMatrix") att.setRotOrder(self.tws2_rot, "XYZ") pm.connectAttr(dm_node + ".outputRotate", self.tws2_rot + ".rotate") self.tws0_rot.setAttr("sx", .001) self.tws2_rot.setAttr("sx", .001) add_node = nod.createAddNode(self.roundness_att, .001) pm.connectAttr(add_node + ".output", self.tws1_rot.attr("sx")) pm.connectAttr(self.armpit_roll_att, self.tws0_rot + ".rotateX") #Roll Shoulder aop.splineIK(self.getName("rollRef"), self.rollRef, parent=self.root, cParent=self.bone0) # Volume ------------------------------------------- distA_node = nod.createDistNode(self.tws0_loc, self.tws1_loc) distB_node = nod.createDistNode(self.tws1_loc, self.tws2_loc) add_node = nod.createAddNode(distA_node + ".distance", distB_node + ".distance") div_node = nod.createDivNode(add_node + ".output", self.root.attr("sx")) dm_node = pm.createNode("decomposeMatrix") pm.connectAttr(self.root.attr("worldMatrix"), dm_node + ".inputMatrix") div_node2 = nod.createDivNode(div_node + ".outputX", dm_node + ".outputScaleX") self.volDriver_att = div_node2 + ".outputX" # Divisions ---------------------------------------- # at 0 or 1 the division will follow exactly the rotation of the controler.. and we wont have this nice tangent + roll for i, div_cns in enumerate(self.div_cns): if i < (self.settings["div0"] + 1): perc = i * .5 / (self.settings["div0"] + 1.0) elif i < (self.settings["div0"] + 2): perc = .49 elif i < (self.settings["div0"] + 3): perc = .50 elif i < (self.settings["div0"] + 4): perc = .51 else: perc = .5 + (i - self.settings["div0"] - 3.0) * .5 / (self.settings["div1"] + 1.0) perc = max(.001, min(.990, perc)) # Roll if self.negate: node = aop.gear_rollsplinekine_op( div_cns, [self.tws2_rot, self.tws1_rot, self.tws0_rot], 1 - perc, 40) else: node = aop.gear_rollsplinekine_op( div_cns, [self.tws0_rot, self.tws1_rot, self.tws2_rot], perc, 40) pm.connectAttr(self.resample_att, node + ".resample") pm.connectAttr(self.absolute_att, node + ".absolute") # Squash n Stretch node = aop.gear_squashstretch2_op(div_cns, None, pm.getAttr(self.volDriver_att), "x") pm.connectAttr(self.volume_att, node + ".blend") pm.connectAttr(self.volDriver_att, node + ".driver") pm.connectAttr(self.st_att[i], node + ".stretch") pm.connectAttr(self.sq_att[i], node + ".squash") # match IK/FK ref pm.parentConstraint(self.bone0, self.match_fk0_off, mo=True) pm.parentConstraint(self.bone1, self.match_fk1_off, mo=True) return
def addOperators(self): # 1 bone chain Upv ref ===================================================================================== self.ikHandleUpvRef = pri.addIkHandle(self.root, self.getName("ikHandleLegChainUpvRef"), self.armChainUpvRef, "ikSCsolver") pm.pointConstraint(self.ik_ctl, self.ikHandleUpvRef) pm.parentConstraint( self.armChainUpvRef[0], self.upv_cns, mo=True) # Visibilities ------------------------------------- # fk fkvis_node = nod.createReverseNode(self.blend_att) for shp in self.fk0_ctl.getShapes(): pm.connectAttr(fkvis_node+".outputX", shp.attr("visibility")) for shp in self.fk1_ctl.getShapes(): pm.connectAttr(fkvis_node+".outputX", shp.attr("visibility")) for shp in self.fk2_ctl.getShapes(): pm.connectAttr(fkvis_node+".outputX", shp.attr("visibility")) # ik for shp in self.upv_ctl.getShapes(): pm.connectAttr(self.blend_att, shp.attr("visibility")) for shp in self.ikcns_ctl.getShapes(): pm.connectAttr(self.blend_att, shp.attr("visibility")) for shp in self.ik_ctl.getShapes(): pm.connectAttr(self.blend_att, shp.attr("visibility")) if self.settings["ikTR"]: for shp in self.ikRot_ctl.getShapes(): pm.connectAttr(self.blend_att, shp.attr("visibility")) # Controls ROT order ----------------------------------- att.setRotOrder(self.fk0_ctl, "XZY") att.setRotOrder(self.fk1_ctl, "XYZ") att.setRotOrder(self.fk2_ctl, "YZX") # att.setRotOrder(self.ik_ctl, "ZYX") att.setRotOrder(self.ik_ctl, "XYZ") # IK Solver ----------------------------------------- out = [self.bone0, self.bone1, self.ctrn_loc, self.eff_loc] node = aop.gear_ikfk2bone_op(out, self.root, self.ik_ref, self.upv_ctl, self.fk_ctl[0], self.fk_ctl[1], self.fk_ref, self.length0, self.length1, self.negate) if self.settings["ikTR"]: #connect the control inputs outEff_dm = node.listConnections(c=True)[-1][1] outEff_dm.attr("outputTranslate") >> self.ikRot_npo.attr("translate") outEff_dm.attr("outputScale") >> self.ikRot_npo.attr("scale") dm_node = nod.createDecomposeMatrixNode(node.attr("outB")) dm_node.attr("outputRotate") >> self.ikRot_npo.attr("rotate") #rotation mulM_node = aop.gear_mulmatrix_op(self.ikRot_ctl.attr("worldMatrix"), self.eff_loc.attr("parentInverseMatrix")) intM_node = aop.gear_intmatrix_op(node.attr("outEff"), mulM_node.attr("output"), node.attr("blend")) dm_node = nod.createDecomposeMatrixNode(intM_node.attr("output")) dm_node.attr("outputRotate") >> self.eff_loc.attr("rotate") tra.matchWorldTransform(self.fk2_ctl, self.ikRot_cns) #scale: this fix the scalin popping issue intM_node = aop.gear_intmatrix_op(self.fk2_ctl.attr("worldMatrix"), self.ik_ctl_ref.attr("worldMatrix"), node.attr("blend")) mulM_node = aop.gear_mulmatrix_op(intM_node.attr("output"), self.eff_loc.attr("parentInverseMatrix")) dm_node = nod.createDecomposeMatrixNode(mulM_node.attr("output")) dm_node.attr("outputScale") >> self.eff_loc.attr("scale") pm.connectAttr(self.blend_att, node+".blend") if self.negate: mulVal = -1 else: mulVal = 1 nod.createMulNode(self.roll_att, mulVal, node+".roll") pm.connectAttr(self.scale_att, node+".scaleA") pm.connectAttr(self.scale_att, node+".scaleB") pm.connectAttr(self.maxstretch_att, node+".maxstretch") pm.connectAttr(self.slide_att, node+".slide") pm.connectAttr(self.softness_att, node+".softness") pm.connectAttr(self.reverse_att, node+".reverse") # Twist references --------------------------------- node = aop.gear_mulmatrix_op(self.eff_loc.attr("worldMatrix"), self.root.attr("worldInverseMatrix")) dm_node = pm.createNode("decomposeMatrix") pm.connectAttr(node+".output", dm_node+".inputMatrix") pm.connectAttr(dm_node+".outputTranslate", self.tws2_npo.attr("translate")) dm_node = pm.createNode("decomposeMatrix") pm.connectAttr(node+".output", dm_node+".inputMatrix") pm.connectAttr(dm_node+".outputRotate", self.tws2_npo.attr("rotate")) #spline IK for twist jnts self.ikhArmTwist, self.armTwistCrv = aop.splineIK(self.getName("armTwist"), self.armTwistChain, parent=self.root, cParent=self.bone0 ) self.ikhForearmTwist, self.forearmTwistCrv = aop.splineIK(self.getName("forearmTwist"), self.forearmTwistChain, parent=self.root, cParent=self.bone1 ) #references self.ikhArmRef, self.tmpCrv = aop.splineIK(self.getName("armRollRef"), self.armRollRef, parent=self.root, cParent=self.bone0 ) self.ikhForearmRef, self.tmpCrv = aop.splineIK(self.getName("forearmRollRef"), self.forearmRollRef, parent=self.root, cParent=self.eff_loc ) self.ikhAuxTwist, self.tmpCrv = aop.splineIK(self.getName("auxTwist"), self.auxTwistChain, parent=self.root, cParent=self.eff_loc ) #setting connexions for ikhArmTwist self.ikhArmTwist.attr("dTwistControlEnable").set(True) self.ikhArmTwist.attr("dWorldUpType").set(4) self.ikhArmTwist.attr("dWorldUpAxis").set(3) self.ikhArmTwist.attr("dWorldUpVectorZ").set(1.0) self.ikhArmTwist.attr("dWorldUpVectorY").set(0.0) self.ikhArmTwist.attr("dWorldUpVectorEndZ").set(1.0) self.ikhArmTwist.attr("dWorldUpVectorEndY").set(0.0) pm.connectAttr(self.armRollRef[0].attr("worldMatrix[0]"), self.ikhArmTwist.attr("dWorldUpMatrix")) pm.connectAttr(self.bone0.attr("worldMatrix[0]"), self.ikhArmTwist.attr("dWorldUpMatrixEnd")) #setting connexions for ikhAuxTwist self.ikhAuxTwist.attr("dTwistControlEnable").set(True) self.ikhAuxTwist.attr("dWorldUpType").set(4) self.ikhAuxTwist.attr("dWorldUpAxis").set(3) self.ikhAuxTwist.attr("dWorldUpVectorZ").set(1.0) self.ikhAuxTwist.attr("dWorldUpVectorY").set(0.0) self.ikhAuxTwist.attr("dWorldUpVectorEndZ").set(1.0) self.ikhAuxTwist.attr("dWorldUpVectorEndY").set(0.0) pm.connectAttr(self.forearmRollRef[0].attr("worldMatrix[0]"), self.ikhAuxTwist.attr("dWorldUpMatrix")) pm.connectAttr(self.eff_loc.attr("worldMatrix[0]"), self.ikhAuxTwist.attr("dWorldUpMatrixEnd")) pm.connectAttr(self.auxTwistChain[1].attr("rx"), self.ikhForearmTwist.attr("twist")) pm.parentConstraint(self.bone1, self.aux_npo, maintainOffset=True) #scale arm length for twist chain (not the squash and stretch) arclen_node = pm.arclen(self.armTwistCrv, ch=True) alAttrArm = arclen_node.attr("arcLength") muldiv_nodeArm = pm.createNode("multiplyDivide") pm.connectAttr(arclen_node.attr("arcLength"), muldiv_nodeArm.attr("input1X")) muldiv_nodeArm.attr("input2X").set(alAttrArm.get()) muldiv_nodeArm.attr("operation").set(2) for jnt in self.armTwistChain: pm.connectAttr(muldiv_nodeArm.attr("outputX"),jnt.attr("sx")) #scale forearm length for twist chain (not the squash and stretch) arclen_node = pm.arclen(self.forearmTwistCrv, ch=True) alAttrForearm = arclen_node.attr("arcLength") muldiv_nodeForearm = pm.createNode("multiplyDivide") pm.connectAttr(arclen_node.attr("arcLength"), muldiv_nodeForearm.attr("input1X")) muldiv_nodeForearm.attr("input2X").set(alAttrForearm.get()) muldiv_nodeForearm.attr("operation").set(2) for jnt in self.forearmTwistChain: pm.connectAttr(muldiv_nodeForearm.attr("outputX"),jnt.attr("sx")) #scale compensation for the first twist join dm_node = pm.createNode("decomposeMatrix") pm.connectAttr(self.root.attr("worldMatrix[0]"), dm_node.attr("inputMatrix")) pm.connectAttr(dm_node.attr("outputScale"), self.armTwistChain[0].attr("inverseScale")) pm.connectAttr(dm_node.attr("outputScale"), self.forearmTwistChain[0].attr("inverseScale")) #tangent controls muldiv_node = pm.createNode("multiplyDivide") muldiv_node.attr("input2X").set(-1) pm.connectAttr(self.tws1A_npo.attr("rz"), muldiv_node.attr("input1X")) muldiv_nodeBias = pm.createNode("multiplyDivide") pm.connectAttr(muldiv_node.attr("outputX"), muldiv_nodeBias.attr("input1X")) pm.connectAttr(self.roundness_att, muldiv_nodeBias.attr("input2X")) pm.connectAttr(muldiv_nodeBias.attr("outputX"), self.tws1A_loc.attr("rz") ) if self.negate: axis = "xz" else: axis = "-xz" aop.aimCns(self.tws1A_npo, self.tws0_loc, axis=axis, wupType=2, wupVector=[0,0,1], wupObject=self.mid_ctl, maintainOffset=False) aop.aimCns(self.forearmTangentB_loc, self.forearmTangentA_npo, axis=axis, wupType=2, wupVector=[0,0,1], wupObject=self.mid_ctl, maintainOffset=False) pm.pointConstraint(self.eff_loc, self.forearmTangentB_loc) muldiv_node = pm.createNode("multiplyDivide") muldiv_node.attr("input2X").set(-1) pm.connectAttr(self.tws1B_npo.attr("rz"), muldiv_node.attr("input1X")) muldiv_nodeBias = pm.createNode("multiplyDivide") pm.connectAttr(muldiv_node.attr("outputX"), muldiv_nodeBias.attr("input1X")) pm.connectAttr(self.roundness_att, muldiv_nodeBias.attr("input2X")) pm.connectAttr(muldiv_nodeBias.attr("outputX"), self.tws1B_loc.attr("rz") ) if self.negate: axis = "-xz" else: axis = "xz" aop.aimCns(self.tws1B_npo, self.tws2_loc, axis=axis, wupType=2, wupVector=[0,0,1], wupObject=self.mid_ctl, maintainOffset=False) aop.aimCns(self.armTangentA_loc, self.armTangentB_npo, axis=axis, wupType=2, wupVector=[0,0,1], wupObject=self.mid_ctl, maintainOffset=False) # Volume ------------------------------------------- distA_node = nod.createDistNode(self.tws0_loc, self.tws1_loc) distB_node = nod.createDistNode(self.tws1_loc, self.tws2_loc) add_node = nod.createAddNode(distA_node+".distance", distB_node+".distance") div_node = nod.createDivNode(add_node+".output", self.root.attr("sx")) dm_node = pm.createNode("decomposeMatrix") pm.connectAttr(self.root.attr("worldMatrix"), dm_node+".inputMatrix") div_node2 = nod.createDivNode(div_node+".outputX", dm_node+".outputScaleX") self.volDriver_att = div_node2+".outputX" # connecting tangent scaele compensation after volume to aboid duplicate some nodes ------------------------------ distA_node = nod.createDistNode(self.tws0_loc, self.mid_ctl) distB_node = nod.createDistNode(self.mid_ctl, self.tws2_loc) div_nodeArm = nod.createDivNode(distA_node+".distance", dm_node.attr("outputScaleX")) div_node2 = nod.createDivNode(div_nodeArm+".outputX", distA_node.attr("distance").get()) pm.connectAttr(div_node2.attr("outputX"), self.tws1A_loc.attr("sx")) pm.connectAttr(div_node2.attr("outputX"), self.armTangentA_loc.attr("sx")) div_nodeForearm = nod.createDivNode(distB_node+".distance", dm_node.attr("outputScaleX")) div_node2 = nod.createDivNode(div_nodeForearm+".outputX", distB_node.attr("distance").get()) pm.connectAttr(div_node2.attr("outputX"), self.tws1B_loc.attr("sx")) pm.connectAttr(div_node2.attr("outputX"), self.forearmTangentB_loc.attr("sx")) #conection curve aop.gear_curvecns_op(self.armTwistCrv, [ self.armTangentA_loc, self.armTangentA_ctl, self.armTangentB_ctl,self.elbowTangent_ctl ]) aop.gear_curvecns_op(self.forearmTwistCrv, [ self.elbowTangent_ctl, self.forearmTangentA_ctl, self.forearmTangentB_ctl,self.forearmTangentB_loc ]) #Tangent controls vis for shp in self.armTangentA_ctl.getShapes(): pm.connectAttr( self.tangentVis_att, shp.attr("visibility")) for shp in self.armTangentB_ctl.getShapes(): pm.connectAttr( self.tangentVis_att, shp.attr("visibility")) for shp in self.forearmTangentA_ctl.getShapes(): pm.connectAttr( self.tangentVis_att, shp.attr("visibility")) for shp in self.forearmTangentB_ctl.getShapes(): pm.connectAttr( self.tangentVis_att, shp.attr("visibility")) for shp in self.elbowTangent_ctl.getShapes(): pm.connectAttr( self.tangentVis_att, shp.attr("visibility")) # Divisions ---------------------------------------- # at 0 or 1 the division will follow exactly the rotation of the controler.. and we wont have this nice tangent + roll for i, div_cns in enumerate(self.div_cns): if i < (self.settings["div0"]+2): mulmat_node = aop.gear_mulmatrix_op(self.armTwistChain[i]+".worldMatrix", div_cns+".parentInverseMatrix") lastArmDiv = div_cns else: mulmat_node = aop.gear_mulmatrix_op(self.forearmTwistChain[i-(self.settings["div0"]+2)]+".worldMatrix", div_cns+".parentInverseMatrix") lastForeDiv = div_cns dm_node = nod.createDecomposeMatrixNode(mulmat_node+".output") pm.connectAttr(dm_node+".outputTranslate", div_cns+".t") pm.connectAttr(dm_node+".outputRotate", div_cns+".r") # Squash n Stretch node = aop.gear_squashstretch2_op(div_cns, None, pm.getAttr(self.volDriver_att), "x") pm.connectAttr(self.volume_att, node+".blend") pm.connectAttr(self.volDriver_att, node+".driver") pm.connectAttr(self.st_att[i], node+".stretch") pm.connectAttr(self.sq_att[i], node+".squash") #force translation for last loc arm and foreamr aop.gear_mulmatrix_op(self.elbowTangent_ctl.worldMatrix,lastArmDiv.parentInverseMatrix, lastArmDiv, "t" ) aop.gear_mulmatrix_op(self.tws2_loc.worldMatrix,lastForeDiv.parentInverseMatrix, lastForeDiv, "t" ) # return # NOTE: next line fix the issue on meters. # This is special case becasuse the IK solver from mGear use the scale as lenght and we have shear # TODO: check for a more clean and elegant solution instead of re-match the world matrix again tra.matchWorldTransform(self.fk_ctl[0], self.match_fk0_off) tra.matchWorldTransform(self.fk_ctl[1], self.match_fk1_off) tra.matchWorldTransform(self.fk_ctl[0], self.match_fk0) tra.matchWorldTransform(self.fk_ctl[1], self.match_fk1) # match IK/FK ref pm.parentConstraint(self.bone0, self.match_fk0_off, mo=True) pm.parentConstraint(self.bone1, self.match_fk1_off, mo=True) if self.settings["ikTR"]: tra.matchWorldTransform(self.ikRot_ctl,self.match_ikRot ) tra.matchWorldTransform(self.fk_ctl[2], self.match_fk2 )
def addOperators(self): """Create operators and set the relations for the component rig Apply operators, constraints, expressions to the hierarchy. In order to keep the code clean and easier to debug, we shouldn't create any new object in this method. """ # Visibilities ------------------------------------- if self.isFkIk: # fk fkvis_node = node.createReverseNode(self.blend_att) for fk_ctl in self.fk_ctl: for shp in fk_ctl.getShapes(): pm.connectAttr(fkvis_node + ".outputX", shp.attr("visibility")) # ik for shp in self.upv_ctl.getShapes(): pm.connectAttr(self.blend_att, shp.attr("visibility")) for shp in self.ikcns_ctl.getShapes(): pm.connectAttr(self.blend_att, shp.attr("visibility")) for shp in self.ik_ctl.getShapes(): pm.connectAttr(self.blend_att, shp.attr("visibility")) # FK Chain ----------------------------------------- if self.isFk: for off, ref in zip(self.fk_off[1:], self.fk_ref): applyop.gear_mulmatrix_op(ref.worldMatrix, off.parentInverseMatrix, off, "rt") # IK Chain ----------------------------------------- if self.isIk: self.ikh = primitive.addIkHandle(self.root, self.getName("ikh"), self.chain) self.ikh.attr("visibility").set(False) # Constraint and up vector pm.pointConstraint(self.ik_ctl, self.ikh, maintainOffset=False) pm.poleVectorConstraint(self.upv_ctl, self.ikh) # TwistTest o_list = [round(elem, 4) for elem in transform.getTranslation(self.chain[1])] \ != [round(elem, 4) for elem in self.guide.apos[1]] if o_list: add_nodeTwist = node.createAddNode(180.0, self.roll_att) pm.connectAttr(add_nodeTwist + ".output", self.ikh.attr("twist")) else: pm.connectAttr(self.roll_att, self.ikh.attr("twist")) # Chain of deformers ------------------------------- for i, loc in enumerate(self.loc): if self.settings["mode"] == 0: # fk only pm.parentConstraint(self.fk_ctl[i], loc, maintainOffset=False) pm.connectAttr(self.fk_ctl[i] + ".scale", loc + ".scale") elif self.settings["mode"] == 1: # ik only pm.parentConstraint(self.chain[i], loc, maintainOffset=False) elif self.settings["mode"] == 2: # fk/ik rev_node = node.createReverseNode(self.blend_att) # orientation cns = pm.parentConstraint(self.fk_ctl[i], self.chain[i], loc, maintainOffset=False) cns.interpType.set(0) weight_att = pm.parentConstraint(cns, query=True, weightAliasList=True) pm.connectAttr(rev_node + ".outputX", weight_att[0]) pm.connectAttr(self.blend_att, weight_att[1]) # scaling blend_node = pm.createNode("blendColors") pm.connectAttr(self.chain[i].attr("scale"), blend_node + ".color1") pm.connectAttr(self.fk_ctl[i].attr("scale"), blend_node + ".color2") pm.connectAttr(self.blend_att, blend_node + ".blender") pm.connectAttr(blend_node + ".output", loc + ".scale")
def addOperators(self): # Visibilities ------------------------------------- if self.isFkIk: # fk fkvis_node = nod.createReverseNode(self.blend_att) for fk_ctl in self.fk_ctl: for shp in fk_ctl.getShapes(): pm.connectAttr(fkvis_node+".outputX", shp.attr("visibility")) # ik for shp in self.upv_ctl.getShapes(): pm.connectAttr(self.blend_att, shp.attr("visibility")) for shp in self.ikcns_ctl.getShapes(): pm.connectAttr(self.blend_att, shp.attr("visibility")) for shp in self.ik_ctl.getShapes(): pm.connectAttr(self.blend_att, shp.attr("visibility")) # IK Chain ----------------------------------------- if self.isIk: self.ikh = pri.addIkHandle(self.root, self.getName("ikh"), self.chain) self.ikh.attr("visibility").set(False) #Constraint and up vector pm.pointConstraint(self.ik_ctl, self.ikh, maintainOffset=False) pm.poleVectorConstraint(self.upv_ctl, self.ikh) # TwistTest if [round(elem, 4) for elem in tra.getTranslation(self.chain[1])] != [round(elem, 4) for elem in self.guide.apos[1]]: add_nodeTwist = nod.createAddNode(180.0, self.roll_att) pm.connectAttr(add_nodeTwist+".output", self.ikh.attr("twist")) else: pm.connectAttr(self.roll_att, self.ikh.attr("twist")) # Chain of deformers ------------------------------- for i, loc in enumerate(self.loc): if self.settings["mode"] == 0: # fk only pm.parentConstraint(self.fk_ctl[i], loc, maintainOffset=False) pm.connectAttr(self.fk_ctl[i]+".scale", loc+".scale") elif self.settings["mode"] == 1: # ik only pm.parentConstraint( self.chain[i], loc, maintainOffset=False) elif self.settings["mode"] == 2: # fk/ik rev_node = nod.createReverseNode(self.blend_att) # orientation cns = pm.parentConstraint(self.fk_ctl[i], self.chain[i], loc, maintainOffset=False) weight_att = pm.parentConstraint(cns, query=True, weightAliasList=True) pm.connectAttr(rev_node+".outputX", weight_att[0]) pm.connectAttr(self.blend_att, weight_att[1]) #scaling blend_node = pm.createNode("blendColors") pm.connectAttr(self.chain[i].attr("scale"), blend_node+".color1") pm.connectAttr(self.fk_ctl[i].attr("scale"), blend_node+".color2") pm.connectAttr(self.blend_att, blend_node+".blender") pm.connectAttr(blend_node+".output", loc+".scale")