from .node_container_common import * from .base_definitions import MantisNode, NodeSocket from .xForm_containers import xFormArmature, xFormBone from math import pi, tau def TellClasses(): return [ # utility InputFloat, InputIntNode, InputVector, InputBoolean, InputBooleanThreeTuple, InputRotationOrder, InputTransformSpace, InputString, InputMatrix, InputExistingGeometryObject, InputExistingGeometryData, UtilityGeometryOfXForm, UtilityNameOfXForm, UtilityPointFromCurve, UtilityMatrixFromCurve, UtilityMatricesFromCurve, UtilityMetaRig, UtilityBoneProperties, UtilityDriverVariable, UtilityDriver, UtilityFCurve, UtilityKeyframe, UtilitySwitch, UtilityCombineThreeBool, UtilityCombineVector, UtilitySeparateVector, UtilityCatStrings, UtilityGetBoneLength, UtilityPointFromBoneMatrix, UtilitySetBoneLength, UtilityMatrixSetLocation, UtilityMatrixGetLocation, UtilityMatrixFromXForm, UtilityAxesFromMatrix, UtilityBoneMatrixHeadTailFlip, UtilityMatrixTransform, UtilityTransformationMatrix, UtilityIntToString, UtilityArrayGet, UtilitySetBoneMatrixTail, # Control flow switches UtilityCompare, UtilityChoose, # useful NoOp: UtilityPrint, ] def matrix_from_head_tail(head, tail): from mathutils import Vector, Quaternion, Matrix rotation = Vector((0,1,0)).rotation_difference((tail-head).normalized()).to_matrix() m= Matrix.LocRotScale(head, rotation, None) m[3][3] = (tail-head).length return m #*#-------------------------------#++#-------------------------------#*# # U T I L I T Y N O D E S #*#-------------------------------#++#-------------------------------#*# class InputFloat(MantisNode): '''A node representing float input''' def __init__(self, signature, base_tree): super().__init__(signature, base_tree) outputs = ["Float Input"] self.outputs.init_sockets(outputs) self.init_parameters() self.node_type = 'UTILITY' self.prepared = True self.executed = True class InputIntNode(MantisNode): '''A node representing integer input''' def __init__(self, signature, base_tree): super().__init__(signature, base_tree) outputs = ["Integer"] self.outputs.init_sockets(outputs) self.init_parameters() self.node_type = 'UTILITY' self.prepared = True self.executed = True class InputVector(MantisNode): '''A node representing vector input''' def __init__(self, signature, base_tree): super().__init__(signature, base_tree) outputs = [""] self.outputs.init_sockets(outputs) self.init_parameters() self.node_type = 'UTILITY' self.prepared = True self.executed = True class InputBoolean(MantisNode): '''A node representing boolean input''' def __init__(self, signature, base_tree): super().__init__(signature, base_tree) outputs = [""] self.outputs.init_sockets(outputs) self.init_parameters() self.node_type = 'UTILITY' self.prepared = True self.executed = True class InputBooleanThreeTuple(MantisNode): '''A node representing a tuple of three booleans''' def __init__(self, signature, base_tree): super().__init__(signature, base_tree) outputs = [""] self.outputs.init_sockets(outputs) self.init_parameters() self.node_type = 'UTILITY' self.prepared = True self.executed = True class InputRotationOrder(MantisNode): '''A node representing string input for rotation order''' def __init__(self, signature, base_tree): super().__init__(signature, base_tree) outputs = [""] self.outputs.init_sockets(outputs) self.init_parameters() self.node_type = 'UTILITY' self.prepared = True self.executed = True class InputTransformSpace(MantisNode): '''A node representing string input for transform space''' def __init__(self, signature, base_tree): super().__init__(signature, base_tree) outputs = [""] self.outputs.init_sockets(outputs) self.init_parameters() self.node_type = 'UTILITY' self.prepared = True self.executed = True def evaluate_input(self, input_name): return self.parameters[""] class InputString(MantisNode): '''A node representing string input''' def __init__(self, signature, base_tree): super().__init__(signature, base_tree) outputs = [""] self.outputs.init_sockets(outputs) self.init_parameters() self.node_type = 'UTILITY' self.prepared = True self.executed = True class InputMatrix(MantisNode): '''A node representing axis-angle quaternion input''' def __init__(self, signature, base_tree): super().__init__(signature, base_tree) outputs = ["Matrix",] self.outputs.init_sockets(outputs) self.init_parameters() self.node_type = 'UTILITY' self.prepared = True self.executed = True class UtilityMatrixFromCurve(MantisNode): '''Get a matrix from a curve''' def __init__(self, signature, base_tree): super().__init__(signature, base_tree) inputs = [ "Curve" , "Total Divisions" , "Matrix Index" , ] outputs = [ "Matrix" , ] self.inputs.init_sockets(inputs) self.outputs.init_sockets(outputs) self.init_parameters() self.node_type = "UTILITY" def bPrepare(self, bContext = None,): from mathutils import Matrix import bpy m = Matrix.Identity(4) curve = bpy.data.objects.get(self.evaluate_input("Curve")) if not curve: prRed(f"No curve found for {self}. Using an Identity matrix instead.") m[3][3] = 1.0 else: from .utilities import mesh_from_curve, data_from_ribbon_mesh if not bContext: # TODO find out if this is bad or a HACK or if it is OK bContext = bpy.context # IMPORTANT TODO: I need to be able to reuse this m # First, try to get the one we made before m_name = curve.name+'.'+self.base_tree.execution_id if not (m := bpy.data.meshes.get(m_name)): m = mesh_from_curve(curve, bContext) m.name = m_name # num_divisions = self.evaluate_input("Total Divisions") m_index = self.evaluate_input("Matrix Index") factors = [1/num_divisions*m_index, 1/num_divisions*(m_index+1)] data = data_from_ribbon_mesh(m, [factors], curve.matrix_world) # print(data) # this is in world space... let's just convert it back m = matrix_from_head_tail(data[0][0][0], data[0][0][1]) m.translation -= curve.location # TODO HACK TODO # all the nodes should work in world-space, and it should be the responsibility # of the xForm node to convert! self.parameters["Matrix"] = m self.prepared = True self.executed = True def bFinalize(self, bContext=None): import bpy curve_name = self.evaluate_input("Curve") curve = bpy.data.objects.get(curve_name) m_name = curve.name+'.'+self.base_tree.execution_id if (mesh := bpy.data.meshes.get(m_name)): bpy.data.meshes.remove(mesh) class UtilityPointFromCurve(MantisNode): '''Get a point from a curve''' def __init__(self, signature, base_tree): super().__init__(signature, base_tree) inputs = [ "Curve" , "Factor" , ] outputs = [ "Point" , ] self.inputs.init_sockets(inputs) self.outputs.init_sockets(outputs) self.init_parameters() self.node_type = "UTILITY" def bPrepare(self, bContext = None,): from mathutils import Matrix import bpy curve = bpy.data.objects.get(self.evaluate_input("Curve")) if not curve: raise RuntimeError(f"No curve found for {self}.") else: from .utilities import mesh_from_curve, data_from_ribbon_mesh if not bContext: # TODO find out if this is bad or a HACK or if it is OK bContext = bpy.context # IMPORTANT TODO: I need to be able to reuse this m # First, try to get the one we made before m_name = curve.name+'.'+self.base_tree.execution_id if not (m := bpy.data.meshes.get(m_name)): m = mesh_from_curve(curve, bContext) m.name = m_name # num_divisions = 1 factors = [self.evaluate_input("Factor")] data = data_from_ribbon_mesh(m, [factors], curve.matrix_world) p = data[0][0][0] - curve.location self.parameters["Point"] = p self.prepared, self.executed = True, True def bFinalize(self, bContext=None): import bpy curve_name = self.evaluate_input("Curve") curve = bpy.data.objects.get(curve_name) m_name = curve.name+'.'+self.base_tree.execution_id if (mesh := bpy.data.meshes.get(m_name)): bpy.data.meshes.remove(mesh) class UtilityMatricesFromCurve(MantisNode): '''Get matrices from a curve''' def __init__(self, signature, base_tree): super().__init__(signature, base_tree) inputs = [ "Curve" , "Total Divisions" , ] self.outputs = [ "Matrices" , ] self.inputs.init_sockets(inputs) self.outputs.init_sockets(outputs) self.init_parameters() self.node_type = "UTILITY" def bPrepare(self, bContext = None,): import time # start_time = time.time() # from mathutils import Matrix import bpy m = Matrix.Identity(4) curve_name = self.evaluate_input("Curve") curve = bpy.data.objects.get(curve_name) if not curve: prRed(f"No curve found for {self}. Using an Identity matrix instead.") m[3][3] = 1.0 else: from .utilities import mesh_from_curve, data_from_ribbon_mesh if not bContext: bContext = bpy.context m_name = curve.name+'.'+self.base_tree.execution_id if not (mesh := bpy.data.meshes.get(m_name)): mesh = mesh_from_curve(curve, bContext) mesh.name = m_name num_divisions = self.evaluate_input("Total Divisions") factors = [0.0] + [(1/num_divisions*(i+1)) for i in range(num_divisions)] data = data_from_ribbon_mesh(mesh, [factors], curve.matrix_world) # 0 is the spline index. 0 selects points as opposed to normals or whatever. matrices = [matrix_from_head_tail(data[0][0][i], data[0][0][i+1]) for i in range(num_divisions)] for link in self.outputs["Matrices"].links: for i, m in enumerate(matrices): name = "Matrix"+str(i).zfill(4) if not (out := self.outputs.get(name)): # reuse them if there are multiple links. out = self.outputs[name] = NodeSocket(name = name, node=self) c = out.connect(link.to_node, link.to_socket) # prOrange(c) self.parameters[name] = m # print (mesh) link.die() self.prepared = True self.executed = True # prGreen(f"Matrices from curves took {time.time() - start_time} seconds.") def bFinalize(self, bContext=None): import bpy curve_name = self.evaluate_input("Curve") curve = bpy.data.objects.get(curve_name) m_name = curve.name+'.'+self.base_tree.execution_id if (mesh := bpy.data.meshes.get(m_name)): prGreen(f"Freeing mesh data {m_name}...") bpy.data.meshes.remove(mesh) class UtilityMetaRig(MantisNode): '''A node representing an armature object''' def __init__(self, signature, base_tree): super().__init__(signature, base_tree) inputs = [ "Meta-Armature" , "Meta-Bone" , ] outputs = [ "Matrix" , ] self.inputs.init_sockets(inputs) self.outputs.init_sockets(outputs) self.init_parameters() self.node_type = "UTILITY" def bPrepare(self, bContext = None,): #kinda clumsy, whatever import bpy from mathutils import Matrix m = Matrix.Identity(4) meta_rig = self.evaluate_input("Meta-Armature") meta_bone = self.evaluate_input("Meta-Bone") if meta_rig: if ( armOb := bpy.data.objects.get(meta_rig) ): m = armOb.matrix_world if ( b := armOb.data.bones.get(meta_bone)): # calculate the correct object-space matrix m = Matrix.Identity(3) bones = [] # from the last ancestor, mult the matrices until we get to b while (b): bones.append(b); b = b.parent while (bones): b = bones.pop(); m = m @ b.matrix m = Matrix.Translation(b.head_local) @ m.to_4x4() # m[3][3] = b.length # this is where I arbitrarily decided to store length # else: # prRed("no bone for MetaRig node ", self) else: raise RuntimeError(wrapRed(f"No meta-rig input for MetaRig node {self}")) self.parameters["Matrix"] = m self.prepared = True self.executed = True class UtilityBoneProperties(MantisNode): '''A node representing a bone's gettable properties''' def __init__(self, signature, base_tree): super().__init__(signature, base_tree) outputs = [ "matrix" , "matrix_local" , "matrix_basis" , "head" , "tail" , "length" , "rotation" , "location" , "scale" , ] self.outputs.init_sockets(outputs) self.init_parameters() self.node_type = "UTILITY" self.prepared = True self.executed = True def fill_parameters(self, prototype=None): return # TODO this should probably be moved to Links class UtilityDriverVariable(MantisNode): '''A node representing an armature object''' def __init__(self, signature, base_tree): super().__init__(signature, base_tree) inputs = [ "Variable Type" , "Property" , "Property Index" , "Evaluation Space", "Rotation Mode" , "xForm 1" , "xForm 2" , ] outputs = [ "Driver Variable", ] self.inputs.init_sockets(inputs) self.outputs.init_sockets(outputs) self.init_parameters() self.node_type = "DRIVER" # MUST be run in Pose mode self.prepared = True def evaluate_input(self, input_name): if input_name == 'Property': if self.inputs.get('Property'): if self.inputs['Property'].is_linked: # get the name instead... trace = trace_single_line(self, input_name) return trace[1].name # the name of the socket return self.parameters["Property"] return super().evaluate_input(input_name) def GetxForm(self, index=1): trace = trace_single_line(self, "xForm 1" if index == 1 else "xForm 2") for node in trace[0]: if (node.__class__ in [xFormArmature, xFormBone]): return node #this will fetch the first one, that's good! return None def bExecute(self, bContext = None,): prepare_parameters(self) #prPurple ("Executing Driver Variable Node") xForm1 = self.GetxForm() xForm2 = self.GetxForm(index=2) # kinda clumsy if xForm1 : xForm1 = xForm1.bGetObject() if xForm2 : xForm2 = xForm2.bGetObject() v_type = self.evaluate_input("Variable Type") i = self.evaluate_input("Property Index"); dVarChannel = "" if (i >= 0): #negative values will use the vector property. if self.evaluate_input("Property") == 'location': if i == 0: dVarChannel = "LOC_X" elif i == 1: dVarChannel = "LOC_Y" elif i == 2: dVarChannel = "LOC_Z" else: raise RuntimeError("Invalid property index for %s" % self) if self.evaluate_input("Property") == 'rotation': if i == 0: dVarChannel = "ROT_X" elif i == 1: dVarChannel = "ROT_Y" elif i == 2: dVarChannel = "ROT_Z" elif i == 3: dVarChannel = "ROT_W" else: raise RuntimeError("Invalid property index for %s" % self) if self.evaluate_input("Property") == 'scale': if i == 0: dVarChannel = "SCALE_X" elif i == 1: dVarChannel = "SCALE_Y" elif i == 2: dVarChannel = "SCALE_Z" elif i == 3: dVarChannel = "SCALE_AVG" else: raise RuntimeError("Invalid property index for %s" % self) if self.evaluate_input("Property") == 'scale_average': dVarChannel = "SCALE_AVG" if dVarChannel: v_type = "TRANSFORMS" my_var = { "owner" : xForm1, # will be filled in by Driver "prop" : self.evaluate_input("Property"), # will be filled in by Driver "type" : v_type, "space" : self.evaluate_input("Evaluation Space"), "rotation_mode" : self.evaluate_input("Rotation Mode"), "xForm 1" : xForm1,#self.GetxForm(index = 1), "xForm 2" : xForm2,#self.GetxForm(index = 2), "channel" : dVarChannel,} # Push parameter to downstream connected node.connected: if (out := self.outputs["Driver Variable"]).is_linked: self.parameters[out.name] = my_var for link in out.links: link.to_node.parameters[link.to_socket] = my_var self.executed = True class UtilityKeyframe(MantisNode): '''A node representing a keyframe for a F-Curve''' def __init__(self, signature, base_tree): super().__init__(signature, base_tree) inputs = [ "Frame" , "Value" , ] outputs = [ "Keyframe" , ] additional_parameters = {"Keyframe":{}} self.inputs.init_sockets(inputs) self.outputs.init_sockets(outputs) self.init_parameters( additional_parameters=additional_parameters) self.node_type = "DRIVER" # MUST be run in Pose mode setup_custom_props(self) def bPrepare(self, bContext = None,): key = self.parameters["Keyframe"] from mathutils import Vector key["co"]= Vector( (self.evaluate_input("Frame"), self.evaluate_input("Value"),)) key["type"]="GENERATED" key["interpolation"] = "LINEAR" # eventually this will have the right data, TODO # self.parameters["Keyframe"] = key self.prepared = True self.executed = True class UtilityFCurve(MantisNode): '''A node representing an armature object''' def __init__(self, signature, base_tree): super().__init__(signature, base_tree) inputs = [ "Extrapolation Mode", ] outputs = [ "fCurve", ] self.inputs.init_sockets(inputs) self.outputs.init_sockets(outputs) self.init_parameters() self.node_type = "UTILITY" setup_custom_props(self) self.prepared = True def evaluate_input(self, input_name): return super().evaluate_input(input_name) def bExecute(self, bContext = None,): prepare_parameters(self) from .utilities import get_node_prototype np = get_node_prototype(self.signature, self.base_tree) extrap_mode = self.evaluate_input("Extrapolation Mode") keys = [] # ugly but whatever #['amplitude', 'back', 'bl_rna', 'co', 'co_ui', 'easing', 'handle_left', 'handle_left_type', 'handle_right', 'handle_right_type', # 'interpolation', 'period', 'rna_type', 'select_control_point', 'select_left_handle', 'select_right_handle', 'type'] for k in self.inputs.keys(): if k == 'Extrapolation Mode' : continue # print (self.inputs[k]) if (key := self.evaluate_input(k)) is None: prOrange(f"WARN: No keyframe connected to {self}:{k}. Skipping Link.") else: keys.append(key) if len(keys) <1: prOrange(f"WARN: no keys in fCurve {self}.") keys.append(extrap_mode) self.parameters["fCurve"] = keys self.executed = True #TODO make the fCurve data a data class instead of a dict class UtilityDriver(MantisNode): '''A node representing an armature object''' def __init__(self, signature, base_tree): super().__init__(signature, base_tree) inputs = [ "Driver Type" , "Expression" , "fCurve" , ] outputs = [ "Driver", ] from .drivers import MantisDriver additional_parameters = { "Driver":MantisDriver(), } self.inputs.init_sockets(inputs) self.outputs.init_sockets(outputs) self.init_parameters(additional_parameters=additional_parameters) self.node_type = "DRIVER" # MUST be run in Pose mode setup_custom_props(self) self.prepared = True def bExecute(self, bContext = None,): prepare_parameters(self) from .drivers import MantisDriver #prPurple("Executing Driver Node") my_vars = [] keys = self.evaluate_input("fCurve") if keys is None or len(keys) <2: prWhite(f"INFO: no fCurve connected to {self}; using default fCurve.") from mathutils import Vector keys = [ {"co":Vector( (0, 0,)), "type":"GENERATED", "interpolation":"LINEAR" }, {"co":Vector( (1, 1,)), "type":"GENERATED", "interpolation":"LINEAR" }, "CONSTANT",] for inp in list(self.inputs.keys() )[3:]: if (new_var := self.evaluate_input(inp)): new_var["name"] = inp my_vars.append(new_var) else: raise RuntimeError(f"Failed to initialize Driver variable for {self}") my_driver ={ "owner" : None, "prop" : None, # will be filled out in the node that uses the driver "expression" : self.evaluate_input("Expression"), "ind" : -1, # same here "type" : self.evaluate_input("Driver Type"), "vars" : my_vars, "keys" : keys[:-1], "extrapolation" : keys[-1] } my_driver = MantisDriver(my_driver) self.parameters["Driver"].update(my_driver) print("Initializing driver %s " % (wrapPurple(self.__repr__())) ) self.executed = True class UtilitySwitch(MantisNode): '''A node representing an armature object''' def __init__(self, signature, base_tree): super().__init__(signature, base_tree) inputs = { "Parameter" , "Parameter Index" , "Invert Switch" , } outputs = [ "Driver", ] from .drivers import MantisDriver additional_parameters = { "Driver":MantisDriver(), } self.inputs.init_sockets(inputs) self.outputs.init_sockets(outputs) self.init_parameters(additional_parameters=additional_parameters) self.node_type = "DRIVER" # MUST be run in Pose mode self.prepared = True def evaluate_input(self, input_name): if input_name == 'Parameter': if self.inputs['Parameter'].is_connected: trace = trace_single_line(self, input_name) return trace[1].name # the name of the socket return self.parameters["Parameter"] return super().evaluate_input(input_name) def GetxForm(self,): trace = trace_single_line(self, "Parameter" ) for node in trace[0]: if (node.__class__ in [xFormArmature, xFormBone]): return node #this will fetch the first one, that's good! return None def bExecute(self, bContext = None,): #prepare_parameters(self) #prPurple ("Executing Switch Node") xForm = self.GetxForm() if xForm : xForm = xForm.bGetObject() if not xForm: raise RuntimeError("Could not evaluate xForm for %s" % self) from .drivers import MantisDriver my_driver ={ "owner" : None, "prop" : None, # will be filled out in the node that uses the driver "ind" : -1, # same here "type" : "SCRIPTED", "vars" : [ { "owner" : xForm, "prop" : self.evaluate_input("Parameter"), "name" : "a", "type" : "SINGLE_PROP", } ], "keys" : [ { "co":(0,0), "interpolation": "LINEAR", "type":"KEYFRAME",}, #display type { "co":(1,1), "interpolation": "LINEAR", "type":"KEYFRAME",},], "extrapolation": 'CONSTANT', } my_driver ["expression"] = "a" my_driver = MantisDriver(my_driver) # this makes it so I can check for type later! if self.evaluate_input("Invert Switch") == True: my_driver ["expression"] = "1 - a" # this way, regardless of what order things are handled, the # driver is sent to the next node. # In the case of some drivers, the parameter may be sent out # before it's filled in (because there is a circular dependency) # I want to support this behaviour because Blender supports it. # We do not make a copy. We update the driver, so that # the same instance is filled out. self.parameters["Driver"].update(my_driver) print("Initializing driver %s " % (wrapPurple(self.__repr__())) ) self.executed = True class UtilityCombineThreeBool(MantisNode): '''A node for combining three booleans into a boolean three-tuple''' def __init__(self, signature, base_tree): super().__init__(signature, base_tree) inputs = [ "X" , "Y" , "Z" , ] outputs = [ "Three-Bool", ] self.inputs.init_sockets(inputs) self.outputs.init_sockets(outputs) self.init_parameters() self.node_type = "UTILITY" def bPrepare(self, bContext = None,): self.parameters["Three-Bool"] = ( self.evaluate_input("X"), self.evaluate_input("Y"), self.evaluate_input("Z"), ) self.prepared = True self.executed = True # Note this is a copy of the above. This needs to be de-duplicated. class UtilityCombineVector(MantisNode): '''A node for combining three floats into a vector''' def __init__(self, signature, base_tree): super().__init__(signature, base_tree) super().__init__(signature, base_tree) inputs = [ "X" , "Y" , "Z" , ] outputs = [ "Vector", ] self.inputs.init_sockets(inputs) self.outputs.init_sockets(outputs) self.init_parameters() self.node_type = "UTILITY" def bPrepare(self, bContext = None,): #prPurple("Executing CombineVector Node") prepare_parameters(self) self.parameters["Vector"] = ( self.evaluate_input("X"), self.evaluate_input("Y"), self.evaluate_input("Z"), ) self.prepared = True self.executed = True class UtilitySeparateVector(MantisNode): '''A node for separating a vector into three floats''' def __init__(self, signature, base_tree): super().__init__(signature, base_tree) inputs = [ "Vector" ] outputs = [ "X" , "Y" , "Z" , ] self.inputs.init_sockets(inputs) self.outputs.init_sockets(outputs) self.init_parameters() self.node_type = "UTILITY" def bPrepare(self, bContext = None,): self.parameters["X"] = self.evaluate_input("Vector")[0] self.parameters["Y"] = self.evaluate_input("Vector")[1] self.parameters["Z"] = self.evaluate_input("Vector")[2] self.prepared = True self.executed = True class UtilityCatStrings(MantisNode): '''A node representing an armature object''' def __init__(self, signature, base_tree): super().__init__(signature, base_tree) inputs = [ "String_1" , "String_2" , ] outputs = [ "OutputString" , ] self.inputs.init_sockets(inputs) self.outputs.init_sockets(outputs) self.init_parameters() self.node_type = "UTILITY" def bPrepare(self, bContext = None,): self.parameters["OutputString"] = self.evaluate_input("String_1")+self.evaluate_input("String_2") self.prepared = True self.executed = True class InputExistingGeometryObject(MantisNode): '''A node representing an existing object''' def __init__(self, signature, base_tree): super().__init__(signature, base_tree) inputs = [ "Name" , ] outputs = [ "Object" , ] self.inputs.init_sockets(inputs) self.outputs.init_sockets(outputs) self.init_parameters() self.node_type = "XFORM" def bPrepare(self, bContext=None): from bpy import data name = self.evaluate_input("Name") if name: self.bObject = data.objects.get( name ) else: self.bObject = None if self is None and (name := self.evaluate_input("Name")): prRed(f"No object found with name {name} in {self}") self.prepared = True; self.executed = True def bGetObject(self, mode=''): return self.bObject class InputExistingGeometryData(MantisNode): '''A node representing existing object data''' def __init__(self, signature, base_tree): super().__init__(signature, base_tree) inputs = [ "Name" , ] outputs = [ "Geometry" , ] self.inputs.init_sockets(inputs) self.outputs.init_sockets(outputs) self.init_parameters() self.node_type = "UTILITY" self.prepared = True self.executed = True # the mode argument is only for interface consistency def bGetObject(self, mode=''): from bpy import data # first try Curve, then try Mesh bObject = data.curves.get(self.evaluate_input("Name")) if not bObject: bObject = data.meshes.get(self.evaluate_input("Name")) if bObject is None: raise RuntimeError(f"Could not find a mesh or curve datablock named \"{self.evaluate_input('Name')}\" for node {self}") return bObject class UtilityGeometryOfXForm(MantisNode): '''A node representing existing object data''' def __init__(self, signature, base_tree): super().__init__(signature, base_tree) inputs = [ "xForm" , ] outputs = [ "Geometry" , ] self.inputs.init_sockets(inputs) self.outputs.init_sockets(outputs) self.init_parameters() self.node_type = "UTILITY" self.prepared = True self.executed = True # mode for interface consistency def bGetObject(self, mode=''): if not (self.inputs.get('xForm') and self.inputs['xForm'].links): prOrange(f"WARN: Cannot retrieve data from {self}, there is no xForm node connected.") return None xf = self.inputs["xForm"].links[0].from_node if xf.node_type == 'XFORM': xf_ob = xf.bGetObject() if xf_ob.type in ['MESH', 'CURVE']: return xf_ob.data prOrange(f"WARN: Cannot retrieve data from {self}, the connected xForm is not a mesh or curve.") return None class UtilityNameOfXForm(MantisNode): '''A node representing existing object data''' def __init__(self, signature, base_tree): super().__init__(signature, base_tree) inputs = [ "xForm" , ] outputs = [ "Name" , ] self.inputs.init_sockets(inputs) self.outputs.init_sockets(outputs) self.init_parameters() self.node_type = "UTILITY" # mode for interface consistency def bPrepare(self, bContext = None,): if not (self.inputs.get('xForm') and self.inputs['xForm'].links): prOrange(f"WARN: Cannot retrieve data from {self}, there is no xForm node connected.") return '' xf = self.inputs["xForm"].links[0].from_node self.parameters["Name"] = xf.evaluate_input('Name') self.prepared, self.executed = True, True class UtilityGetBoneLength(MantisNode): '''A node to get the length of a bone matrix''' def __init__(self, signature, base_tree): super().__init__(signature, base_tree) inputs = [ "Bone Matrix" , ] outputs = [ "Bone Length" , ] self.inputs.init_sockets(inputs) self.outputs.init_sockets(outputs) self.init_parameters() self.node_type = "UTILITY" def bPrepare(self, bContext = None,): if l := self.evaluate_input("Bone Matrix"): self.parameters["Bone Length"] = l[3][3] self.prepared = True self.executed = True class UtilityPointFromBoneMatrix(MantisNode): '''A node representing an armature object''' def __init__(self, signature, base_tree): super().__init__(signature, base_tree) inputs = [ "Bone Matrix" , "Head/Tail" , ] outputs = [ "Point" , ] self.inputs.init_sockets(inputs) self.outputs.init_sockets(outputs) self.init_parameters() self.node_type = "UTILITY" # TODO: find out why this is sometimes not ready at bPrepare phase def bPrepare(self, bContext = None,): from mathutils import Vector matrix = self.evaluate_input("Bone Matrix") head, rotation, _scale = matrix.copy().decompose() tail = head.copy() + (rotation @ Vector((0,1,0)))*matrix[3][3] self.parameters["Point"] = head.lerp(tail, self.evaluate_input("Head/Tail")) self.prepared = True self.executed = True class UtilitySetBoneLength(MantisNode): '''Sets the length of a Bone's matrix''' def __init__(self, signature, base_tree): super().__init__(signature, base_tree) inputs = [ "Bone Matrix" , "Length" , ] outputs = [ "Bone Matrix" , ] self.inputs.init_sockets(inputs) self.outputs.init_sockets(outputs) self.init_parameters() self.node_type = "UTILITY" def bPrepare(self, bContext = None,): from mathutils import Vector if matrix := self.evaluate_input("Bone Matrix"): matrix = matrix.copy() # print (self.inputs["Length"].links) matrix[3][3] = self.evaluate_input("Length") self.parameters["Length"] = self.evaluate_input("Length") self.parameters["Bone Matrix"] = matrix self.prepared = True self.executed = True class UtilityMatrixSetLocation(MantisNode): '''Sets the location of a matrix''' def __init__(self, signature, base_tree): super().__init__(signature, base_tree) inputs = [ "Matrix" , "Location" , ] outputs = [ "Matrix" , ] self.inputs.init_sockets(inputs) self.outputs.init_sockets(outputs) self.init_parameters() self.node_type = "UTILITY" def bPrepare(self, bContext = None,): from mathutils import Vector if matrix := self.evaluate_input("Matrix"): matrix = matrix.copy() # print (self.inputs["Length"].links) loc = self.evaluate_input("Location") matrix[0][3] = loc[0]; matrix[1][3] = loc[1]; matrix[2][3] = loc[2] self.parameters["Matrix"] = matrix self.prepared = True self.executed = True class UtilityMatrixGetLocation(MantisNode): '''Gets the location of a matrix''' def __init__(self, signature, base_tree): super().__init__(signature, base_tree) inputs = [ "Matrix" , ] outputs = [ "Location" , ] self.inputs.init_sockets(inputs) self.outputs.init_sockets(outputs) self.init_parameters() self.node_type = "UTILITY" def bPrepare(self, bContext = None,): from mathutils import Vector if matrix := self.evaluate_input("Matrix"): self.parameters["Location"] = matrix.to_translation() self.prepared = True; self.executed = True class UtilityMatrixFromXForm(MantisNode): """Returns the matrix of the given xForm node.""" def __init__(self, signature, base_tree): super().__init__(signature, base_tree) inputs = [ "xForm" , ] outputs = [ "Matrix" , ] self.node_type = "UTILITY" self.inputs.init_sockets(inputs) self.outputs.init_sockets(outputs) self.init_parameters() def GetxForm(self): trace = trace_single_line(self, "xForm") for node in trace[0]: if (node.node_type == 'XFORM'): return node raise GraphError("%s is not connected to an xForm" % self) def bPrepare(self, bContext = None,): from mathutils import Vector, Matrix self.parameters["Matrix"] = Matrix.Identity(4) if matrix := self.GetxForm().parameters.get("Matrix"): self.parameters["Matrix"] = matrix.copy() elif hasattr(self.GetxForm().bObject, "matrix"): self.parameters["Matrix"] = self.GetxForm().bObject.matrix.copy() elif hasattr(self.GetxForm().bObject, "matrix_world"): self.parameters["Matrix"] = self.GetxForm().bObject.matrix_world.copy() else: prRed(f"Could not find matrix for {self} - check if the referenced object exists.") self.prepared = True; self.executed = True class UtilityAxesFromMatrix(MantisNode): """Returns the axes of the given matrix.""" def __init__(self, signature, base_tree): super().__init__(signature, base_tree) inputs = [ "Matrix" , ] outputs = [ "X Axis" , "Y Axis" , "Z Axis" , ] self.inputs.init_sockets(inputs) self.outputs.init_sockets(outputs) self.init_parameters() self.node_type = "UTILITY" def bPrepare(self, bContext = None,): from mathutils import Vector if matrix := self.evaluate_input("Matrix"): matrix= matrix.copy().to_3x3() self.parameters['X Axis'] = matrix @ Vector((1,0,0)) self.parameters['Y Axis'] = matrix @ Vector((0,1,0)) self.parameters['Z Axis'] = matrix @ Vector((0,0,1)) self.prepared = True; self.executed = True class UtilityBoneMatrixHeadTailFlip(MantisNode): def __init__(self, signature, base_tree): super().__init__(signature, base_tree) inputs = [ "Bone Matrix" , ] outputs = [ "Bone Matrix" , ] self.inputs.init_sockets(inputs) self.outputs.init_sockets(outputs) self.init_parameters() self.node_type = "UTILITY" def bPrepare(self, bContext = None,): from mathutils import Vector, Matrix, Quaternion from bpy.types import Bone if matrix := self.evaluate_input("Bone Matrix"): axis, roll = Bone.AxisRollFromMatrix(matrix.to_3x3()) new_mat = Bone.MatrixFromAxisRoll(-1*axis, roll) length = matrix[3][3] new_mat.resize_4x4() # last column contains new_mat[0][3] = matrix[0][3] + axis[0]*length # x location new_mat[1][3] = matrix[1][3] + axis[1]*length # y location new_mat[2][3] = matrix[2][3] + axis[2]*length # z location new_mat[3][3] = length # length self.parameters["Bone Matrix"] = new_mat self.prepared, self.executed = True, True class UtilityMatrixTransform(MantisNode): def __init__(self, signature, base_tree): super().__init__(signature, base_tree) inputs = [ "Matrix 1" , "Matrix 2" , ] outputs = [ "Out Matrix" , ] self.inputs.init_sockets(inputs) self.outputs.init_sockets(outputs) self.init_parameters() self.node_type = "UTILITY" def bPrepare(self, bContext = None,): from mathutils import Vector mat1 = self.evaluate_input("Matrix 1"); mat2 = self.evaluate_input("Matrix 2") if mat1 and mat2: mat1copy = mat1.copy() self.parameters["Out Matrix"] = mat2 @ mat1copy self.parameters["Out Matrix"].translation = mat1copy.to_translation()+ mat2.to_translation() else: raise RuntimeError(wrapRed(f"Node {self} did not receive all matrix inputs... found input 1? {mat1 is not None}, 2? {mat2 is not None}")) self.prepared = True self.executed = True class UtilityTransformationMatrix(MantisNode): def __init__(self, signature, base_tree): super().__init__(signature, base_tree) inputs = [ "Operation" , "Vector" , "W" , ] outputs = [ "Matrix" , ] self.inputs.init_sockets(inputs) self.outputs.init_sockets(outputs) self.init_parameters() self.node_type = "UTILITY" def bPrepare(self, bContext = None,): from mathutils import Matrix, Vector if (operation := self.evaluate_input("Operation")) == 'ROTATE_AXIS_ANGLE': # this can, will, and should fail if the axis is 0,0,0 self.parameters["Matrix"] = rotMat = Matrix.Rotation(self.evaluate_input("W"), 4, Vector(self.evaluate_input("Vector")).normalized()) elif (operation := self.evaluate_input("Operation")) == 'TRANSLATE': m = Matrix.Identity(4) if axis := self.evaluate_input("Vector"): m[0][3]=axis[0];m[1][3]=axis[1];m[2][3]=axis[2] self.parameters['Matrix'] = m elif (operation := self.evaluate_input("Operation")) == 'SCALE': self.parameters["Matrix"] = Matrix.Scale(self.evaluate_input("W"), 4, Vector(self.evaluate_input("Vector")).normalized()) else: raise NotImplementedError(self.evaluate_input("Operation").__repr__()+ " Operation not yet implemented.") self.prepared = True self.executed = True class UtilityIntToString(MantisNode): def __init__(self, signature, base_tree): super().__init__(signature, base_tree) inputs = [ "Number" , "Zero Padding" , ] outputs = [ "String" , ] self.inputs.init_sockets(inputs) self.outputs.init_sockets(outputs) self.init_parameters() self.node_type = "UTILITY" def bPrepare(self, bContext = None,): number = self.evaluate_input("Number") zeroes = self.evaluate_input("Zero Padding") # I'm casting to int because I want to support any number, even though the node asks for int. self.parameters["String"] = str(int(number)).zfill(int(zeroes)) self.prepared = True self.executed = True class UtilityArrayGet(MantisNode): def __init__(self, signature, base_tree): super().__init__(signature, base_tree) inputs = [ "Index" , "OoB Behaviour" , "Array" , ] outputs = [ "Output" , ] self.inputs.init_sockets(inputs) self.outputs.init_sockets(outputs) self.init_parameters() self.node_type = "UTILITY" def bPrepare(self, bContext = None,): if self.prepared == False: # sort the array entries for inp in self.inputs.values(): inp.links.sort(key=lambda a : -a.multi_input_sort_id) oob = self.evaluate_input("OoB Behaviour") index = self.evaluate_input("Index") from .utilities import cap, wrap # we must assume that the array has sent the correct number of links if oob == 'WRAP': index = index % len(self.inputs['Array'].links) if oob == 'HOLD': index = cap(index, len(self.inputs['Array'].links)-1) # relink the connections and then kill all the links to and from the array from .utilities import init_connections, init_dependencies l = self.inputs["Array"].links[index] for link in self.outputs["Output"].links: to_node = link.to_node l.from_node.outputs[l.from_socket].connect(to_node, link.to_socket) link.die() init_dependencies(to_node) from_node=l.from_node for inp in self.inputs.values(): for l in inp.links: l.die() init_connections(from_node) if self in from_node.hierarchy_connections: raise RuntimeError() # this is intentional because the Array Get is kind of a weird hybrid between a Utility and a Schema # so it should be removed from the tree when it is done. it has already dealt with the actual links. # however I think this is redundant. Check. self.hierarchy_connections, self.connections = [], [] self.hierarchy_dependencies, self.dependencies = [], [] self.prepared = True self.executed = True class UtilitySetBoneMatrixTail(MantisNode): def __init__(self, signature, base_tree): super().__init__(signature, base_tree) inputs = { "Matrix" , "Tail Location" , } outputs = [ "Result" , ] self.inputs.init_sockets(inputs) self.outputs.init_sockets(outputs) self.init_parameters() self.node_type = "UTILITY" def bPrepare(self, bContext = None,): from mathutils import Matrix matrix = self.evaluate_input("Matrix") if matrix is None: matrix = Matrix.Identity(4) #just do this for now lol self.parameters["Result"] = matrix_from_head_tail(matrix.translation, self.evaluate_input("Tail Location")) self.prepared = True self.executed = True class UtilityPrint(MantisNode): def __init__(self, signature, base_tree): super().__init__(signature, base_tree) inputs = [ "Input" , ] self.inputs.init_sockets(inputs) self.outputs.init_sockets(outputs) self.init_parameters() self.node_type = "UTILITY" def bPrepare(self, bContext = None,): if my_input := self.evaluate_input("Input"): print("Preparation phase: ", wrapWhite(self), wrapGreen(my_input)) # else: # prRed("No input to print.") self.prepared = True def bExecute(self, bContext = None,): if my_input := self.evaluate_input("Input"): print("Execution phase: ", wrapWhite(self), wrapGreen(my_input)) # else: # prRed("No input to print.") self.executed = True class UtilityCompare(MantisNode): def __init__(self, signature, base_tree): super().__init__(signature, base_tree) inputs = [ "A" , "B" , ] outputs = [ "Result" , ] self.inputs.init_sockets(inputs) self.outputs.init_sockets(outputs) self.init_parameters() self.node_type = "UTILITY" def bPrepare(self, bContext = None,): self.parameters["Result"] = self.evaluate_input("A") == self.evaluate_input("B") self.prepared = True; self.executed = True class UtilityChoose(MantisNode): def __init__(self, signature, base_tree): super().__init__(signature, base_tree) inputs = [ "Condition" , "A" , "B" , ] outputs = [ "Result" , ] self.inputs.init_sockets(inputs) self.outputs.init_sockets(outputs) self.init_parameters() self.node_type = "UTILITY" def bPrepare(self, bContext = None,): condition = self.evaluate_input("Condition") if condition: self.parameters["Result"] = self.evaluate_input("B") else: self.parameters["Result"] = self.evaluate_input("A") self.prepared = True self.executed = True