fix: operate node and "remembered" math ops

We reimplemented the OperateMathNode entirely, and it should now be relatively to entirely robust. It works based on an enum, just like `MapMathNode`, which enormously simplifies the node itself. Note that we're not quite done with sympy+jax implementations of everything, nor validating that all operations have an implementation valid for all the `InfoFlow`s that prompted it, but, nonetheless, such fixes should be easy to work out as we go. We also finally managed to implement "remembering". In essence, "remembering" causes `FlowPending` to not reset the dynamic enums in math / extract nodes. The implementation is generally per-node, and a bit of boilerplate, but it seems quite robust on the whole - allowing one to "keep a node tree around" even after removing simulation data. Extract of sim data is of course more leniant, as it also "remembers" when there is `NoFlow`. Only new `Sim Data` will reset the extraction filter enum. Caches are kept (not memory efficient, but convenient for me), but only `FlowPending` is actually passed along the `InfoFlow`. This is the semantics we want - having to deal with this all is a tradeoff of having data-driven enums, but all in all, it still feels like the right approach.
2024-05-18 18:02:15 +02:00 · 2024-05-18 18:02:15 +02:00 · 532f0246b5
parent 035d8971f3
commit 532f0246b5
10 changed files with 360 additions and 253 deletions
--- a/src/blender_maxwell/node_trees/maxwell_sim_nodes/contracts/flow_kinds/flow_kinds.py
+++ b/src/blender_maxwell/node_trees/maxwell_sim_nodes/contracts/flow_kinds/flow_kinds.py
@ -80,7 +80,6 @@ class FlowKind(enum.StrEnum):
 				unit_system,
 			)
 		if kind == FlowKind.LazyArrayRange:
 			log.debug([kind, flow_obj, unit_system])
 			return flow_obj.rescale_to_unit_system(unit_system)
 		if kind == FlowKind.Params:
--- a/src/blender_maxwell/node_trees/maxwell_sim_nodes/contracts/flow_kinds/info.py
+++ b/src/blender_maxwell/node_trees/maxwell_sim_nodes/contracts/flow_kinds/info.py
@ -74,6 +74,12 @@ class InfoFlow:
 	output_mathtype: spux.MathType = dataclasses.field()
 	output_unit: spux.Unit | None = dataclasses.field()
 	@property
 	def output_shape_len(self) -> int:
 		if self.output_shape is None:
 			return 0
 		return len(self.output_shape)
 	# Pinned Dimension Information
 	## TODO: Add PhysicalType
 	pinned_dim_names: list[str] = dataclasses.field(default_factory=list)
--- a/src/blender_maxwell/node_trees/maxwell_sim_nodes/node_tree.py
+++ b/src/blender_maxwell/node_trees/maxwell_sim_nodes/node_tree.py
@ -477,7 +477,7 @@ def populate_missing_persistence(_) -> None:
 # - Blender Registration
 ####################
 bpy.app.handlers.load_post.append(initialize_sim_tree_node_link_cache)
-bpy.app.handlers.load_post.append(populate_missing_persistence)
+# bpy.app.handlers.load_post.append(populate_missing_persistence)
 ## TODO: Move to top-level registration.
 BL_REGISTER = [
--- a/src/blender_maxwell/node_trees/maxwell_sim_nodes/nodes/analysis/extract_data.py
+++ b/src/blender_maxwell/node_trees/maxwell_sim_nodes/nodes/analysis/extract_data.py
@ -73,9 +73,14 @@ class ExtractDataNode(base.MaxwellSimNode):
 	####################
 	# - Computed: Sim Data
 	####################
-	@events.on_value_changed(socket_name='Sim Data')
+	@events.on_value_changed(
-	def on_sim_data_changed(self) -> None:  # noqa: D102
+		socket_name='Sim Data',
-		log.critical('On Value Changed: Sim Data')
+		input_sockets={'Sim Data'},
 		input_sockets_optional={'Sim Data': True},
 	)
 	def on_sim_data_changed(self, input_sockets) -> None:  # noqa: D102
 		has_sim_data = not ct.FlowSignal.check(input_sockets['Sim Data'])
 		if has_sim_data:
 			self.sim_data = bl_cache.Signal.InvalidateCache
 	@bl_cache.cached_bl_property()
@ -112,9 +117,14 @@ class ExtractDataNode(base.MaxwellSimNode):
 	####################
 	# - Computed Properties: Monitor Data
 	####################
-	@events.on_value_changed(socket_name='Monitor Data')
+	@events.on_value_changed(
-	def on_monitor_data_changed(self) -> None:  # noqa: D102
+		socket_name='Monitor Data',
-		log.critical('On Value Changed: Sim Data')
+		input_sockets={'Monitor Data'},
 		input_sockets_optional={'Monitor Data': True},
 	)
 	def on_monitor_data_changed(self, input_sockets) -> None:  # noqa: D102
 		has_monitor_data = not ct.FlowSignal.check(input_sockets['Monitor Data'])
 		if has_monitor_data:
 			self.monitor_data = bl_cache.Signal.InvalidateCache
 	@bl_cache.cached_bl_property()
@ -319,6 +329,7 @@ class ExtractDataNode(base.MaxwellSimNode):
 		# Loaded
 		props={'extract_filter'},
 		input_sockets={'Sim Data'},
 		input_sockets_optional={'Sim Data': True},
 	)
 	def compute_monitor_data(
 		self, props: dict, input_sockets: dict
@ -347,6 +358,7 @@ class ExtractDataNode(base.MaxwellSimNode):
 		props={'extract_filter'},
 		input_sockets={'Monitor Data'},
 		input_socket_kinds={'Monitor Data': ct.FlowKind.Value},
 		input_sockets_optional={'Monitor Data': True},
 	)
 	def compute_expr(
 		self, props: dict, input_sockets: dict
@ -376,6 +388,7 @@ class ExtractDataNode(base.MaxwellSimNode):
 		# Loaded
 		output_sockets={'Expr'},
 		output_socket_kinds={'Expr': ct.FlowKind.Array},
 		output_sockets_optional={'Expr': True},
 	)
 	def compute_extracted_data_lazy(
 		self, output_sockets: dict
@ -436,9 +449,18 @@ class ExtractDataNode(base.MaxwellSimNode):
 		has_monitor_data = not ct.FlowSignal.check(monitor_data)
 		# Edge Case: Dangling 'flux' Access on 'FieldMonitor'
 		## -> Sometimes works - UNLESS the FieldMonitor doesn't have all fields.
 		## -> We don't allow 'flux' attribute access, but it can dangle.
 		## -> (The method is called when updating each depschain component.)
 		if monitor_data_type == 'Field' and extract_filter == 'flux':
 			return ct.FlowSignal.FlowPending
 		# Retrieve XArray
 		if has_monitor_data and extract_filter is not None:
-			xarr = getattr(monitor_data, extract_filter)
+			xarr = getattr(monitor_data, extract_filter, None)
 			if xarr is None:
 				return ct.FlowSignal.FlowPending
 		else:
 			return ct.FlowSignal.FlowPending
--- a/src/blender_maxwell/node_trees/maxwell_sim_nodes/nodes/analysis/math/map_math.py
+++ b/src/blender_maxwell/node_trees/maxwell_sim_nodes/nodes/analysis/math/map_math.py
@ -99,6 +99,9 @@ class MapOperation(enum.StrEnum):
 	Chol = enum.auto()
 	Svd = enum.auto()
 	####################
 	# - UI
 	####################
 	@staticmethod
 	def to_name(value: typ.Self) -> str:
 		MO = MapOperation
@ -150,6 +153,9 @@ class MapOperation(enum.StrEnum):
 			i,
 		)
 	####################
 	# - Ops from Shape
 	####################
 	@staticmethod
 	def by_element_shape(shape: tuple[int, ...] | None) -> list[typ.Self]:
 		MO = MapOperation
@ -198,10 +204,21 @@ class MapOperation(enum.StrEnum):
 		return []
-	def jax_func(self, user_expr_func: ct.LazyValueFuncFlow | None = None):
+	def jax_func_expr(self, user_expr_func: ct.LazyValueFuncFlow):
 		MO = MapOperation
-		if self == MO.UserExpr and user_expr_func is not None:
+		if self == MO.UserExpr:
 			return lambda data: user_expr_func.func(data)
 		msg = "Can't generate JAX function for user-provided expression when MapOperation is not `UserExpr`"
 		raise ValueError(msg)
 	@property
 	def jax_func(self):
 		MO = MapOperation
 		if self == MO.UserExpr:
 			msg = "Can't generate JAX function without user-provided expression when MapOperation is `UserExpr`"
 			raise ValueError(msg)
 		return {
 			# By Number
 			MO.Real: lambda data: jnp.real(data),
@ -386,8 +403,6 @@ class MapMathNode(base.MaxwellSimNode):
 		return 'noshape'
 	output_shape: tuple[int, ...] | None = bl_cache.BLField(None)
 	def search_operations(self) -> list[ct.BLEnumElement]:
 		if self.expr_output_shape != 'noshape':
 			return [
@ -472,12 +487,12 @@ class MapMathNode(base.MaxwellSimNode):
 		if has_expr and operation is not None:
 			if not has_mapper:
 				return expr.compose_within(
-					operation.jax_func(),
+					operation.jax_func,
 					supports_jax=True,
 				)
 			if operation == MapOperation.UserExpr and has_mapper:
 				return expr.compose_within(
-					operation.jax_func(user_expr_func=mapper),
+					operation.jax_func_expr(user_expr_func=mapper),
 					supports_jax=True,
 				)
 		return ct.FlowSignal.FlowPending
--- a/src/blender_maxwell/node_trees/maxwell_sim_nodes/nodes/analysis/math/operate_math.py
+++ b/src/blender_maxwell/node_trees/maxwell_sim_nodes/nodes/analysis/math/operate_math.py
@ -29,37 +29,226 @@ from ... import base, events
 log = logger.get(__name__)
-FUNCS = {
+
 ####################
 # - Operation Enum
 ####################
 class BinaryOperation(enum.StrEnum):
 	"""Valid operations for the `OperateMathNode`.
 	Attributes:
 		Add: Addition w/broadcasting.
 		Sub: Subtraction w/broadcasting.
 		Mul: Hadamard-product multiplication.
 		Div: Hadamard-product based division.
 		Pow: Elementwise expontiation.
 		Atan2: Quadrant-respecting arctangent variant.
 		VecVecDot: Dot product for vectors.
 		Cross: Cross product.
 		MatVecDot: Matrix-Vector dot product.
 		LinSolve: Solve a linear system.
 		LsqSolve: Minimize error of an underdetermined linear system.
 		MatMatDot: Matrix-Matrix dot product.
 	"""
 	# Number | Number
-	'ADD': lambda exprs: exprs[0] + exprs[1],
+	Add = enum.auto()
-	'SUB': lambda exprs: exprs[0] - exprs[1],
+	Sub = enum.auto()
-	'MUL': lambda exprs: exprs[0] * exprs[1],
+	Mul = enum.auto()
-	'DIV': lambda exprs: exprs[0] / exprs[1],
+	Div = enum.auto()
-	'POW': lambda exprs: exprs[0] ** exprs[1],
+	Pow = enum.auto()
-	'ATAN2': lambda exprs: sp.atan2(exprs[1], exprs[0]),
+	Atan2 = enum.auto()
 	# Vector | Vector
 	'VEC_VEC_DOT': lambda exprs: exprs[0].dot(exprs[1]),
 	'CROSS': lambda exprs: exprs[0].cross(exprs[1]),
 }
 SP_FUNCS = FUNCS
 JAX_FUNCS = FUNCS | {
 	# Number | *
 	'ATAN2': lambda exprs: jnp.atan2(exprs[1], exprs[0]),
 	# Vector | Vector
-	'VEC_VEC_DOT': lambda exprs: jnp.matmul(exprs[0], exprs[1]),
+	VecVecDot = enum.auto()
-	'CROSS': lambda exprs: jnp.cross(exprs[0], exprs[1]),
+	Cross = enum.auto()
 	# Matrix | Vector
-	'MAT_VEC_DOT': lambda exprs: jnp.matmul(exprs[0], exprs[1]),
+	MatVecDot = enum.auto()
-	'LIN_SOLVE': lambda exprs: jnp.linalg.solve(exprs[0], exprs[1]),
+	LinSolve = enum.auto()
-	'LSQ_SOLVE': lambda exprs: jnp.linalg.lstsq(exprs[0], exprs[1]),
+	LsqSolve = enum.auto()
 	# Matrix | Matrix
-	'MAT_MAT_DOT': lambda exprs: jnp.matmul(exprs[0], exprs[1]),
+	MatMatDot = enum.auto()
-}
+
 	####################
 	# - UI
 	####################
 	@staticmethod
 	def to_name(value: typ.Self) -> str:
 		BO = BinaryOperation
 		return {
 			# Number | Number
 			BO.Add: 'ℓ + r',
 			BO.Sub: 'ℓ - r',
 			BO.Mul: 'ℓ ⊙ r',  ## Notation for Hadamard Product
 			BO.Div: 'ℓ / r',
 			BO.Pow: 'ℓʳ',
 			BO.Atan2: 'atan2(ℓ,r)',
 			# Vector | Vector
 			BO.VecVecDot: '𝐥 · 𝐫',
 			BO.Cross: 'cross(L,R)',
 			# Matrix | Vector
 			BO.MatVecDot: '𝐋 · 𝐫',
 			BO.LinSolve: '𝐋 ∖ 𝐫',
 			BO.LsqSolve: 'argminₓ∥𝐋𝐱−𝐫∥₂',
 			# Matrix | Matrix
 			BO.MatMatDot: '𝐋 · 𝐑',
 		}[value]
 	@staticmethod
 	def to_icon(value: typ.Self) -> str:
 		return ''
 	def bl_enum_element(self, i: int) -> ct.BLEnumElement:
 		BO = BinaryOperation
 		return (
 			str(self),
 			BO.to_name(self),
 			BO.to_name(self),
 			BO.to_icon(self),
 			i,
 		)
 	####################
 	# - Ops from Shape
 	####################
 	@staticmethod
 	def by_infos(info_l: int, info_r: int) -> list[typ.Self]:
 		"""Deduce valid binary operations from the shapes of the inputs."""
 		BO = BinaryOperation
 		ops_number_number = [
 			BO.Add,
 			BO.Sub,
 			BO.Mul,
 			BO.Div,
 			BO.Pow,
 			BO.Atan2,
 		]
 		match (info_l.output_shape_len, info_r.output_shape_len):
 			# Number | *
 			## Number | Number
 			case (0, 0):
 				return ops_number_number
 			## Number | Vector
 			## -> Broadcasting allows Number|Number ops to work as-is.
 			case (0, 1):
 				return ops_number_number
 			## Number | Matrix
 			## -> Broadcasting allows Number|Number ops to work as-is.
 			case (0, 2):
 				return ops_number_number
 			# Vector | *
 			## Vector | Number
 			case (1, 0):
 				return ops_number_number
 			## Vector | Number
 			case (1, 1):
 				return [*ops_number_number, BO.VecVecDot, BO.Cross]
 			## Vector | Matrix
 			case (1, 2):
 				return []
 			# Matrix | *
 			## Matrix | Number
 			case (2, 0):
 				return [*ops_number_number, BO.MatMatDot]
 			## Matrix | Vector
 			case (2, 1):
 				return [BO.MatVecDot, BO.LinSolve, BO.LsqSolve]
 			## Matrix | Matrix
 			case (2, 2):
 				return [*ops_number_number, BO.MatMatDot]
 		return []
 	####################
 	# - Function Properties
 	####################
 	@property
 	def sp_func(self):
 		"""Deduce an appropriate sympy-based function that implements the binary operation for symbolic inputs."""
 		BO = BinaryOperation
 		## TODO: Make this compatible with sp.Matrix inputs
 		return {
 			# Number | Number
 			BO.Add: lambda exprs: exprs[0] + exprs[1],
 			BO.Sub: lambda exprs: exprs[0] - exprs[1],
 			BO.Mul: lambda exprs: exprs[0] * exprs[1],
 			BO.Div: lambda exprs: exprs[0] / exprs[1],
 			BO.Pow: lambda exprs: exprs[0] ** exprs[1],
 			BO.Atan2: lambda exprs: sp.atan2(exprs[1], exprs[0]),
 		}[self]
 	@property
 	def jax_func(self):
 		"""Deduce an appropriate jax-based function that implements the binary operation for array inputs."""
 		BO = BinaryOperation
 		return {
 			# Number | Number
 			BO.Add: lambda exprs: exprs[0] + exprs[1],
 			BO.Sub: lambda exprs: exprs[0] - exprs[1],
 			BO.Mul: lambda exprs: exprs[0] * exprs[1],
 			BO.Div: lambda exprs: exprs[0] / exprs[1],
 			BO.Pow: lambda exprs: exprs[0] ** exprs[1],
 			BO.Atan2: lambda exprs: sp.atan2(exprs[1], exprs[0]),
 			# Vector | Vector
 			BO.VecVecDot: lambda exprs: jnp.dot(exprs[0], exprs[1]),
 			BO.Cross: lambda exprs: jnp.cross(exprs[0], exprs[1]),
 			# Matrix | Vector
 			BO.MatVecDot: lambda exprs: jnp.matmul(exprs[0], exprs[1]),
 			BO.LinSolve: lambda exprs: jnp.linalg.solve(exprs[0], exprs[1]),
 			BO.LsqSolve: lambda exprs: jnp.linalg.lstsq(exprs[0], exprs[1]),
 			# Matrix | Matrix
 			BO.MatMatDot: lambda exprs: jnp.matmul(exprs[0], exprs[1]),
 		}[self]
 	####################
 	# - InfoFlow Transform
 	####################
 	def transform_infos(self, info_l: ct.InfoFlow, info_r: ct.InfoFlow):
 		BO = BinaryOperation
 		info_largest = (
 			info_l if info_l.output_shape_len > info_l.output_shape_len else info_l
 		)
 		info_any = info_largest
 		return {
 			# Number | * or * | Number
 			BO.Add: info_largest,
 			BO.Sub: info_largest,
 			BO.Mul: info_largest,
 			BO.Div: info_largest,
 			BO.Pow: info_largest,
 			BO.Atan2: info_largest,
 			# Vector | Vector
 			BO.VecVecDot: info_any,
 			BO.Cross: info_any,
 			# Matrix | Vector
 			BO.MatVecDot: info_r,
 			BO.LinSolve: info_r,
 			BO.LsqSolve: info_r,
 			# Matrix | Matrix
 			BO.MatMatDot: info_any,
 		}[self]
 ####################
 # - Node
 ####################
 class OperateMathNode(base.MaxwellSimNode):
-	r"""Applies a function that depends on two inputs.
+	r"""Applies a binary function between two expressions.
 	Attributes:
 		category: The category of operations to apply to the inputs.
@ -76,196 +265,86 @@ class OperateMathNode(base.MaxwellSimNode):
 		'Expr R': sockets.ExprSocketDef(active_kind=ct.FlowKind.LazyValueFunc),
 	}
 	output_sockets: typ.ClassVar = {
-		'Expr': sockets.ExprSocketDef(active_kind=ct.FlowKind.LazyValueFunc),
+		'Expr': sockets.ExprSocketDef(
 			active_kind=ct.FlowKind.LazyValueFunc, show_info_columns=True
 		),
 	}
 	####################
 	# - Properties
 	####################
-	category: enum.StrEnum = bl_cache.BLField(
+	@events.on_value_changed(
-		enum_cb=lambda self, _: self.search_categories()
+		socket_name={'Expr L', 'Expr R'},
 		input_sockets={'Expr L', 'Expr R'},
 		input_socket_kinds={'Expr L': ct.FlowKind.Info, 'Expr R': ct.FlowKind.Info},
 		input_sockets_optional={'Expr L': True, 'Expr R': True},
 	)
 	def on_input_exprs_changed(self, input_sockets) -> None:  # noqa: D102
 		has_info_l = not ct.FlowSignal.check(input_sockets['Expr L'])
 		has_info_r = not ct.FlowSignal.check(input_sockets['Expr R'])
 		info_l_pending = ct.FlowSignal.check_single(
 			input_sockets['Expr L'], ct.FlowSignal.FlowPending
 		)
 		info_r_pending = ct.FlowSignal.check_single(
 			input_sockets['Expr R'], ct.FlowSignal.FlowPending
 		)
-	operation: enum.StrEnum = bl_cache.BLField(
+		if has_info_l and has_info_r and not info_l_pending and not info_r_pending:
-		enum_cb=lambda self, _: self.search_operations()
+			self.expr_infos = bl_cache.Signal.InvalidateCache
 	@bl_cache.cached_bl_property()
 	def expr_infos(self) -> tuple[ct.InfoFlow, ct.InfoFlow] | None:
 		info_l = self._compute_input('Expr L', kind=ct.FlowKind.Info)
 		info_r = self._compute_input('Expr R', kind=ct.FlowKind.Info)
 		has_info_l = not ct.FlowSignal.check(info_l)
 		has_info_r = not ct.FlowSignal.check(info_r)
 		if has_info_l and has_info_r:
 			return (info_l, info_r)
 		return None
 	operation: BinaryOperation = bl_cache.BLField(
 		enum_cb=lambda self, _: self.search_operations(),
 		cb_depends_on={'expr_infos'},
 	)
 	def search_categories(self) -> list[ct.BLEnumElement]:
 		"""Deduce and return a list of valid categories for the current socket set and input data."""
 		expr_l_info = self._compute_input(
 			'Expr L',
 			kind=ct.FlowKind.Info,
 		)
 		expr_r_info = self._compute_input(
 			'Expr R',
 			kind=ct.FlowKind.Info,
 		)
 		has_expr_l_info = not ct.FlowSignal.check(expr_l_info)
 		has_expr_r_info = not ct.FlowSignal.check(expr_r_info)
 		# Categories by Socket Set
 		NUMBER_NUMBER = (
 			'Number | Number',
 			'Number | Number',
 			'Operations between numerical elements',
 		)
 		NUMBER_VECTOR = (
 			'Number | Vector',
 			'Number | Vector',
 			'Operations between numerical and vector elements',
 		)
 		NUMBER_MATRIX = (
 			'Number | Matrix',
 			'Number | Matrix',
 			'Operations between numerical and matrix elements',
 		)
 		VECTOR_VECTOR = (
 			'Vector | Vector',
 			'Vector | Vector',
 			'Operations between vector elements',
 		)
 		MATRIX_VECTOR = (
 			'Matrix | Vector',
 			'Matrix | Vector',
 			'Operations between vector and matrix elements',
 		)
 		MATRIX_MATRIX = (
 			'Matrix | Matrix',
 			'Matrix | Matrix',
 			'Operations between matrix elements',
 		)
 		categories = []
 		if has_expr_l_info and has_expr_r_info:
 			# Check Valid Broadcasting
 			## Number | Number
 			if expr_l_info.output_shape is None and expr_r_info.output_shape is None:
 				categories = [NUMBER_NUMBER]
 			## * | Number
 			elif expr_r_info.output_shape is None:
 				categories = []
 			## Number | Vector
 			elif (
 				expr_l_info.output_shape is None and len(expr_r_info.output_shape) == 1
 			):
 				categories = [NUMBER_VECTOR]
 			## Number | Matrix
 			elif (
 				expr_l_info.output_shape is None and len(expr_r_info.output_shape) == 2
 			):
 				categories = [NUMBER_MATRIX]
 			## Vector | Vector
 			elif (
 				len(expr_l_info.output_shape) == 1
 				and len(expr_r_info.output_shape) == 1
 			):
 				categories = [VECTOR_VECTOR]
 			## Matrix | Vector
 			elif (
 				len(expr_l_info.output_shape) == 2  # noqa: PLR2004
 				and len(expr_r_info.output_shape) == 1
 			):
 				categories = [MATRIX_VECTOR]
 			## Matrix | Matrix
 			elif (
 				len(expr_l_info.output_shape) == 2  # noqa: PLR2004
 				and len(expr_r_info.output_shape) == 2  # noqa: PLR2004
 			):
 				categories = [MATRIX_MATRIX]
 		return [
 			(*category, '', i) if category is not None else None
 			for i, category in enumerate(categories)
 		]
 	def search_operations(self) -> list[ct.BLEnumElement]:
-		items = []
+		if self.expr_infos is not None:
 		if self.category in ['Number | Number', 'Number | Vector', 'Number | Matrix']:
 			items += [
 				('ADD', 'L + R', 'Add'),
 				('SUB', 'L - R', 'Subtract'),
 				('MUL', 'L · R', 'Multiply'),
 				('DIV', 'L / R', 'Divide'),
 				('POW', 'L^R', 'Power'),
 				('ATAN2', 'atan2(L,R)', 'atan2(L,R)'),
 			]
 		if self.category == 'Vector | Vector':
 			if items:
 				items += [None]
 			items += [
 				('VEC_VEC_DOT', 'L · R', 'Vector-Vector Product'),
 				('CROSS', 'L x R', 'Cross Product'),
 			]
 		if self.category == 'Matrix | Vector':
 			if items:
 				items += [None]
 			items += [
 				('MAT_VEC_DOT', 'L · R', 'Matrix-Vector Product'),
 				('LIN_SOLVE', 'Lx = R -> x', 'Linear Solve'),
 				('LSQ_SOLVE', 'Lx = R ~> x', 'Least Squares Solve'),
 			]
 		if self.category == 'Matrix | Matrix':
 			if items:
 				items += [None]
 			items += [
 				('MAT_MAT_DOT', 'L · R', 'Matrix-Matrix Product'),
 			]
 			return [
-			(*item, '', i) if item is not None else None for i, item in enumerate(items)
+				operation.bl_enum_element(i)
 				for i, operation in enumerate(
 					BinaryOperation.by_infos(*self.expr_infos)
 				)
 			]
 		return []
 	####################
 	# - UI
 	####################
 	def draw_label(self):
-		labels = {
+		"""Show the current operation (if any) in the node's header label.
 			'ADD': lambda: 'L + R',
 			'SUB': lambda: 'L - R',
 			'MUL': lambda: 'L · R',
 			'DIV': lambda: 'L / R',
 			'POW': lambda: 'L^R',
 			'ATAN2': lambda: 'atan2(L,R)',
 		}
-		if (label := labels.get(self.operation)) is not None:
+		Notes:
-			return 'Operate: ' + label()
+			Called by Blender to determine the text to place in the node's header.
 		"""
 		if self.operation is not None:
 			return 'Op: ' + BinaryOperation.to_name(self.operation)
 		return self.bl_label
 	def draw_props(self, _: bpy.types.Context, layout: bpy.types.UILayout) -> None:
-		layout.prop(self, self.blfields['category'], text='')
+		"""Draw node properties in the node.
 		Parameters:
 			col: UI target for drawing.
 		"""
 		layout.prop(self, self.blfields['operation'], text='')
 	####################
-	# - Events
+	# - FlowKind.Value|LazyValueFunc
 	####################
 	@events.on_value_changed(
 		# Trigger
 		socket_name={'Expr L', 'Expr R'},
 		run_on_init=True,
 	)
 	def on_socket_changed(self) -> None:
 		# Recompute Valid Categories
 		self.category = bl_cache.Signal.ResetEnumItems
 		self.operation = bl_cache.Signal.ResetEnumItems
 	@events.on_value_changed(
 		prop_name='category',
 		run_on_init=True,
 	)
 	def on_category_changed(self) -> None:
 		self.operation = bl_cache.Signal.ResetEnumItems
 	####################
 	# - Output
 	####################
 	@events.computes_output_socket(
 		'Expr',
@ -285,8 +364,10 @@ class OperateMathNode(base.MaxwellSimNode):
 		has_expr_l_value = not ct.FlowSignal.check(expr_l)
 		has_expr_r_value = not ct.FlowSignal.check(expr_r)
 		# Compute Sympy Function
 		## -> The operation enum directly provides the appropriate function.
 		if has_expr_l_value and has_expr_r_value and operation is not None:
-			return SP_FUNCS[operation]([expr_l, expr_r])
+			operation.sp_func([expr_l, expr_r])
 		return ct.Flowsignal.FlowPending
@ -311,43 +392,17 @@ class OperateMathNode(base.MaxwellSimNode):
 		has_expr_l = not ct.FlowSignal.check(expr_l)
 		has_expr_r = not ct.FlowSignal.check(expr_r)
 		# Compute Jax Function
 		## -> The operation enum directly provides the appropriate function.
 		if has_expr_l and has_expr_r:
 			return (expr_l | expr_r).compose_within(
-				JAX_FUNCS[operation],
+				operation.jax_func,
 				supports_jax=True,
 			)
 		return ct.FlowSignal.FlowPending
 	@events.computes_output_socket(
 		'Expr',
 		kind=ct.FlowKind.Array,
 		output_sockets={'Expr'},
 		output_socket_kinds={
 			'Expr': {ct.FlowKind.LazyValueFunc, ct.FlowKind.Params},
 		},
 		unit_systems={'BlenderUnits': ct.UNITS_BLENDER},
 	)
 	def compute_array(self, output_sockets, unit_systems) -> ct.ArrayFlow:
 		lazy_value_func = output_sockets['Expr'][ct.FlowKind.LazyValueFunc]
 		params = output_sockets['Expr'][ct.FlowKind.Params]
 		has_lazy_value_func = not ct.FlowSignal.check(lazy_value_func)
 		has_params = not ct.FlowSignal.check(params)
 		if has_lazy_value_func and has_params:
 			unit_system = unit_systems['BlenderUnits']
 			return ct.ArrayFlow(
 				values=lazy_value_func.func_jax(
 					*params.scaled_func_args(unit_system),
 					**params.scaled_func_kwargs(unit_system),
 				),
 				unit=None,
 			)
 		return ct.FlowSignal.FlowPending
 	####################
-	# - Auxiliary: Info
+	# - FlowKind.Info
 	####################
 	@events.computes_output_socket(
 		'Expr',
@ -367,17 +422,20 @@ class OperateMathNode(base.MaxwellSimNode):
 		has_info_l = not ct.FlowSignal.check(info_l)
 		has_info_r = not ct.FlowSignal.check(info_r)
-		# Return Info of RHS
+		# Compute Info
-		## -> Fundamentall, this is why 'category' only has the given options.
+		## -> The operation enum directly provides the appropriate transform.
-		## -> Via 'category', we enforce that the operated-on structure is always RHS.
+		if (
-		## -> That makes it super duper easy to track info changes.
+			has_info_l
-		if has_info_l and has_info_r and operation is not None:
+			and has_info_r
-			return info_r
+			and operation is not None
 			and operation in BinaryOperation.by_infos(info_l, info_r)
 		):
 			return operation.transform_infos(info_l, info_r)
 		return ct.FlowSignal.FlowPending
 	####################
-	# - Auxiliary: Params
+	# - FlowKind.Params
 	####################
 	@events.computes_output_socket(
 		'Expr',
@ -397,8 +455,11 @@ class OperateMathNode(base.MaxwellSimNode):
 		has_params_l = not ct.FlowSignal.check(params_l)
 		has_params_r = not ct.FlowSignal.check(params_r)
 		# Compute Params
 		## -> Operations don't add new parameters, so just concatenate L|R.
 		if has_params_l and has_params_r and operation is not None:
 			return params_l | params_r
 		return ct.FlowSignal.FlowPending
--- a/src/blender_maxwell/node_trees/maxwell_sim_nodes/sockets/expr.py
+++ b/src/blender_maxwell/node_trees/maxwell_sim_nodes/sockets/expr.py
@ -186,7 +186,7 @@ class ExprBLSocket(base.MaxwellSimSocket):
 	# UI: Info
 	show_info_columns: bool = bl_cache.BLField(False)
 	info_columns: set[InfoDisplayCol] = bl_cache.BLField(
-		{InfoDisplayCol.MathType, InfoDisplayCol.Unit}
+		{InfoDisplayCol.Length, InfoDisplayCol.MathType}
 	)
 	####################
--- a/src/blender_maxwell/utils/bl_cache/bl_field.py
+++ b/src/blender_maxwell/utils/bl_cache/bl_field.py
@ -329,8 +329,8 @@ class BLField:
 				# Retrieve Old Enum Item
 				## -> This is verbatim what is being used.
 				## -> De-Coerce None -> 'NONE' to avoid special-cased search.
-				_old_item = self.bl_prop.read(bl_instance)
+				old_item = self.bl_prop.read(bl_instance)
-				old_item = 'NONE' if _old_item is None else _old_item
+				raw_old_item = 'NONE' if old_item is None else str(old_item)
 				# Swap Enum Items
 				## -> This is the hot stuff - the enum elements are overwritten.
@ -343,7 +343,7 @@ class BLField:
 				## -> If so, the user will expect it to "remain".
 				## -> Thus, we set it - Blender sees a change, user doesn't.
 				## -> DO NOT trigger on_prop_changed (since "nothing changed").
-				if any(old_item == item[0] for item in current_items):
+				if any(raw_old_item == item[0] for item in current_items):
 					self.suppress_next_update(bl_instance)
 					self.bl_prop.write(bl_instance, old_item)
 					## -> TODO: Don't write if not needed.
@ -352,10 +352,8 @@ class BLField:
 				## -> In this case, fallback to the first current item.
 				## -> DO trigger on_prop_changed (since it changed!)
 				else:
-					_first_current_item = current_items[0][0]
+					raw_first_current_item = current_items[0][0]
-					first_current_item = (
+					first_current_item = self.bl_prop.decode(raw_first_current_item)
 						_first_current_item if _first_current_item != 'NONE' else None
 					)
 					self.suppress_next_update(bl_instance)
 					self.bl_prop.write(bl_instance, first_current_item)
--- a/src/blender_maxwell/utils/bl_cache/bl_prop.py
+++ b/src/blender_maxwell/utils/bl_cache/bl_prop.py
@ -198,7 +198,12 @@ class BLProp:
 		)
 	def read(self, bl_instance: bl_instance.BLInstance) -> typ.Any:
-		"""Read the Blender property's particular value on the given `bl_instance`."""
+		"""Read the persisted Blender property value for this property, from a particular `BLInstance`.
 		Parameters:
 			bl_instance: The Blender object to
 				**NOTE**: `bl_instance` must not be `None`, as neighboring methods sometimes allow.
 		"""
 		persisted_value = self.decode(
 			managed_cache.read(
 				bl_instance,
--- a/src/blender_maxwell/utils/bl_instance.py
+++ b/src/blender_maxwell/utils/bl_instance.py
@ -50,6 +50,7 @@ class BLInstance:
 	# - Attributes
 	####################
 	instance_id: bpy.props.StringProperty(default='')
 	is_updating: bpy.props.BoolProperty(default=False)
 	blfields: typ.ClassVar[dict[str, str]] = MappingProxyType({})
 	blfield_deps: typ.ClassVar[dict[str, list[str]]] = MappingProxyType({})