Compare commits
2 Commits
a3551c68b7
...
d0615d0372
Author | SHA1 | Date |
---|---|---|
Sofus Albert Høgsbro Rose | d0615d0372 | |
Sofus Albert Høgsbro Rose | 44a0ea95d3 |
|
@ -369,15 +369,6 @@ class FuncFlow:
|
|||
|
||||
return data | {info.output: self.realize(params, symbol_values=symbol_values)}
|
||||
|
||||
# return {
|
||||
# dim: (
|
||||
# dim_idx
|
||||
# if info.has_idx_cont(dim) or info.has_idx_labels(dim)
|
||||
# else ??
|
||||
# )
|
||||
# for dim, dim_idx in self.dims
|
||||
# } | {info.output: output_data}
|
||||
|
||||
####################
|
||||
# - Composition Operations
|
||||
####################
|
||||
|
|
|
@ -251,7 +251,7 @@ class ParamsFlow:
|
|||
func_args=self.func_args + other.func_args,
|
||||
func_kwargs=self.func_kwargs | other.func_kwargs,
|
||||
symbols=self.symbols | other.symbols,
|
||||
is_differentiable=self.is_differentiable & other.is_differentiable,
|
||||
is_differentiable=self.is_differentiable and other.is_differentiable,
|
||||
)
|
||||
|
||||
def compose_within(
|
||||
|
|
|
@ -453,10 +453,17 @@ class MaxwellSimNode(bpy.types.Node, bl_instance.BLInstance):
|
|||
created_sockets[socket_name] = socket_def
|
||||
|
||||
# Initialize Just-Created BL Sockets
|
||||
for socket_name, socket_def in created_sockets.items():
|
||||
socket_def.preinit(all_bl_sockets[socket_name])
|
||||
socket_def.init(all_bl_sockets[socket_name])
|
||||
socket_def.postinit(all_bl_sockets[socket_name])
|
||||
for bl_socket_name, socket_def in created_sockets.items():
|
||||
socket_def.preinit(all_bl_sockets[bl_socket_name])
|
||||
socket_def.init(all_bl_sockets[bl_socket_name])
|
||||
socket_def.postinit(all_bl_sockets[bl_socket_name])
|
||||
|
||||
# Invalidate Cached NoFlows
|
||||
self._compute_input.invalidate(
|
||||
input_socket_name=bl_socket_name,
|
||||
kind=...,
|
||||
unit_system=...,
|
||||
)
|
||||
|
||||
def _sync_sockets(self) -> None:
|
||||
"""Synchronize the node's sockets with the active sockets.
|
||||
|
|
|
@ -110,10 +110,11 @@ class AdiabAbsorbBoundCondNode(base.MaxwellSimNode):
|
|||
col.label(text='2ε₀/Δt')
|
||||
|
||||
####################
|
||||
# - Output
|
||||
# - FlowKind.Value
|
||||
####################
|
||||
@events.computes_output_socket(
|
||||
'BC',
|
||||
# Loaded
|
||||
props={'active_socket_set'},
|
||||
input_sockets={
|
||||
'Layers',
|
||||
|
@ -124,33 +125,154 @@ class AdiabAbsorbBoundCondNode(base.MaxwellSimNode):
|
|||
'σ Order': True,
|
||||
'σ Range': True,
|
||||
},
|
||||
output_sockets={'BC'},
|
||||
output_socket_kinds={'BC': ct.FlowKind.Params},
|
||||
)
|
||||
def compute_adiab_absorber_bound_cond(self, props, input_sockets) -> td.Absorber:
|
||||
def compute_bc_value(self, props, input_sockets, output_sockets) -> td.Absorber:
|
||||
r"""Computes the adiabatic absorber boundary condition based on the active socket set.
|
||||
|
||||
- **Simple**: Use `tidy3d`'s default parameters for defining the absorber parameters (apart from number of layers).
|
||||
- **Full**: Use the user-defined $\sigma$ parameters, specifically polynomial order and sim-relative min/max conductivity values.
|
||||
"""
|
||||
log.debug(
|
||||
'%s: Computing "%s" Adiabatic Absorber Boundary Condition (Input Sockets = %s)',
|
||||
self.sim_node_name,
|
||||
props['active_socket_set'],
|
||||
input_sockets,
|
||||
)
|
||||
output_params = output_sockets['BC']
|
||||
layers = input_sockets['Layers']
|
||||
|
||||
# Simple PML
|
||||
if props['active_socket_set'] == 'Simple':
|
||||
return td.Absorber(num_layers=input_sockets['Layers'])
|
||||
has_output_params = not ct.FlowSignal.check(output_params)
|
||||
has_layers = not ct.FlowSignal.check(layers)
|
||||
|
||||
# Full PML
|
||||
return td.Absorber(
|
||||
num_layers=input_sockets['Layers'],
|
||||
parameters=td.AbsorberParams(
|
||||
sigma_order=input_sockets['σ Order'],
|
||||
sigma_min=input_sockets['σ Range'][0],
|
||||
sigma_max=input_sockets['σ Range'][1],
|
||||
),
|
||||
)
|
||||
active_socket_set = props['active_socket_set']
|
||||
if has_layers and has_output_params and not output_params.symbols:
|
||||
# Simple PML
|
||||
if active_socket_set == 'Simple':
|
||||
return td.Absorber(num_layers=layers)
|
||||
|
||||
# Full PML
|
||||
sig_order = input_sockets['σ Order']
|
||||
sig_range = input_sockets['σ Range']
|
||||
|
||||
has_sig_order = not ct.FlowSignal.check(sig_order)
|
||||
has_sig_range = not ct.FlowSignal.check(sig_range)
|
||||
|
||||
if has_sig_order and has_sig_range:
|
||||
return td.Absorber(
|
||||
num_layers=layers,
|
||||
parameters=td.AbsorberParams(
|
||||
sigma_order=sig_order,
|
||||
sigma_min=sig_range[0],
|
||||
sigma_max=sig_range[1],
|
||||
),
|
||||
)
|
||||
return ct.FlowSignal.FlowPending
|
||||
|
||||
####################
|
||||
# - FlowKind.Func
|
||||
####################
|
||||
@events.computes_output_socket(
|
||||
'BC',
|
||||
kind=ct.FlowKind.Func,
|
||||
# Loaded
|
||||
props={'active_socket_set'},
|
||||
input_sockets={
|
||||
'Layers',
|
||||
'σ Order',
|
||||
'σ Range',
|
||||
},
|
||||
input_socket_kinds={
|
||||
'Layers': ct.FlowKind.Func,
|
||||
'σ Order': ct.FlowKind.Func,
|
||||
'σ Range': ct.FlowKind.Func,
|
||||
},
|
||||
input_sockets_optional={
|
||||
'σ Order': True,
|
||||
'σ Range': True,
|
||||
},
|
||||
output_sockets={'BC'},
|
||||
output_socket_kinds={'BC': ct.FlowKind.Params},
|
||||
)
|
||||
def compute_bc_func(self, props, input_sockets, output_sockets) -> td.Absorber:
|
||||
r"""Computes the adiabatic absorber boundary condition based on the active socket set.
|
||||
|
||||
- **Simple**: Use `tidy3d`'s default parameters for defining the absorber parameters (apart from number of layers).
|
||||
- **Full**: Use the user-defined $\sigma$ parameters, specifically polynomial order and sim-relative min/max conductivity values.
|
||||
"""
|
||||
layers = input_sockets['Layers']
|
||||
|
||||
has_layers = not ct.FlowSignal.check(layers)
|
||||
|
||||
active_socket_set = props['active_socket_set']
|
||||
if has_layers:
|
||||
# Simple PML
|
||||
if active_socket_set == 'Simple':
|
||||
return layers.compose_within(
|
||||
enclosing_func=lambda _layers: td.Absorber(num_layers=_layers),
|
||||
supports_jax=False,
|
||||
)
|
||||
|
||||
# Full PML
|
||||
sig_order = input_sockets['σ Order']
|
||||
sig_range = input_sockets['σ Range']
|
||||
|
||||
has_sig_order = not ct.FlowSignal.check(sig_order)
|
||||
has_sig_range = not ct.FlowSignal.check(sig_range)
|
||||
|
||||
if has_sig_order and has_sig_range:
|
||||
return (layers | sig_order | sig_range).compose_within(
|
||||
enclosing_func=lambda els: td.Absorber(
|
||||
num_layers=els[0][0],
|
||||
parameters=td.AbsorberParams(
|
||||
sigma_order=els[0][1],
|
||||
sigma_min=els[1][0],
|
||||
sigma_max=els[1][1],
|
||||
),
|
||||
),
|
||||
supports_jax=False,
|
||||
)
|
||||
return ct.FlowSignal.FlowPending
|
||||
|
||||
####################
|
||||
# - FlowKind.Params
|
||||
####################
|
||||
@events.computes_output_socket(
|
||||
'BC',
|
||||
kind=ct.FlowKind.Params,
|
||||
# Loaded
|
||||
props={'active_socket_set'},
|
||||
input_sockets={
|
||||
'Layers',
|
||||
'σ Order',
|
||||
'σ Range',
|
||||
},
|
||||
input_socket_kinds={
|
||||
'Layers': ct.FlowKind.Params,
|
||||
'σ Order': ct.FlowKind.Params,
|
||||
'σ Range': ct.FlowKind.Params,
|
||||
},
|
||||
input_sockets_optional={
|
||||
'σ Order': True,
|
||||
'σ Range': True,
|
||||
},
|
||||
)
|
||||
def compute_params(self, props, input_sockets) -> td.Box:
|
||||
layers = input_sockets['Layers']
|
||||
|
||||
has_layers = not ct.FlowSignal.check(layers)
|
||||
|
||||
active_socket_set = props['active_socket_set']
|
||||
if has_layers:
|
||||
# Simple PML
|
||||
if active_socket_set == 'Simple':
|
||||
return layers
|
||||
|
||||
# Full PML
|
||||
sig_order = input_sockets['σ Order']
|
||||
sig_range = input_sockets['σ Range']
|
||||
|
||||
has_sig_order = not ct.FlowSignal.check(sig_order)
|
||||
has_sig_range = not ct.FlowSignal.check(sig_range)
|
||||
|
||||
if has_sig_order and has_sig_range:
|
||||
return layers | sig_order | sig_range
|
||||
return ct.FlowSignal.FlowPending
|
||||
|
||||
|
||||
####################
|
||||
|
|
|
@ -187,10 +187,11 @@ class BlochBoundCondNode(base.MaxwellSimNode):
|
|||
}
|
||||
|
||||
####################
|
||||
# - Output
|
||||
# - FlowKind.Value
|
||||
####################
|
||||
@events.computes_output_socket(
|
||||
'BC',
|
||||
# Loaded
|
||||
props={'active_socket_set', 'valid_sim_axis'},
|
||||
input_sockets={
|
||||
'Angled Source',
|
||||
|
@ -202,9 +203,11 @@ class BlochBoundCondNode(base.MaxwellSimNode):
|
|||
'Sim Domain': True,
|
||||
'Bloch Vector': True,
|
||||
},
|
||||
output_sockets={'BC'},
|
||||
output_socket_kinds={'BC': ct.FlowKind.Params},
|
||||
)
|
||||
def compute_bloch_bound_cond(
|
||||
self, props, input_sockets
|
||||
def compute_value(
|
||||
self, props, input_sockets, output_sockets
|
||||
) -> td.Periodic | td.BlochBoundary:
|
||||
r"""Computes the Bloch boundary condition.
|
||||
|
||||
|
@ -213,34 +216,165 @@ class BlochBoundCondNode(base.MaxwellSimNode):
|
|||
The Bloch boundary axis **must** be orthogonal to the source's injection axis.
|
||||
- **Manual**: Set the Bloch vector to the user-specified value.
|
||||
"""
|
||||
log.debug(
|
||||
'%s: Computing Bloch Boundary Condition (Socket Set = %s)',
|
||||
self.sim_node_name,
|
||||
props['active_socket_set'],
|
||||
)
|
||||
|
||||
# Naive
|
||||
if props['active_socket_set'] == 'Naive':
|
||||
return td.Periodic()
|
||||
|
||||
# Source-Derived
|
||||
if props['active_socket_set'] == 'Source-Derived':
|
||||
sim_domain = input_sockets['Sim Domain']
|
||||
valid_sim_axis = props['valid_sim_axis']
|
||||
|
||||
has_sim_domain = not ct.FlowSignal.check(sim_domain)
|
||||
|
||||
if has_sim_domain:
|
||||
return td.BlochBoundary.from_source(
|
||||
source=input_sockets['Angled Source'],
|
||||
domain_size=sim_domain['size'][valid_sim_axis.axis],
|
||||
axis=valid_sim_axis.axis,
|
||||
medium=sim_domain['medium'],
|
||||
)
|
||||
output_params = output_sockets['BC']
|
||||
has_output_params = not ct.FlowSignal.check(output_params)
|
||||
if not has_output_params or (has_output_params and output_params.symbols):
|
||||
return ct.FlowSignal.FlowPending
|
||||
|
||||
# Manual
|
||||
return td.BlochBoundary(bloch_vec=input_sockets['Bloch Vector'])
|
||||
active_socket_set = props['active_socket_set']
|
||||
match active_socket_set:
|
||||
case 'Naive':
|
||||
return td.Periodic()
|
||||
|
||||
case 'Source-Derived':
|
||||
angled_source = input_sockets['Angled Source']
|
||||
sim_domain = input_sockets['Sim Domain']
|
||||
|
||||
has_angled_source = not ct.FlowSignal.check(angled_source)
|
||||
has_sim_domain = not ct.FlowSignal.check(sim_domain)
|
||||
|
||||
if has_angled_source and has_sim_domain:
|
||||
valid_sim_axis = props['valid_sim_axis']
|
||||
return td.BlochBoundary.from_source(
|
||||
source=angled_source,
|
||||
domain_size=sim_domain['size'][valid_sim_axis.axis],
|
||||
axis=valid_sim_axis.axis,
|
||||
medium=sim_domain['medium'],
|
||||
)
|
||||
return ct.FlowSignal.FlowPending
|
||||
|
||||
case 'Manual':
|
||||
bloch_vector = input_sockets['Bloch Vector']
|
||||
has_bloch_vector = not ct.FlowSignal.check(bloch_vector)
|
||||
|
||||
if has_bloch_vector:
|
||||
return td.BlochBoundary(bloch_vec=bloch_vector)
|
||||
return ct.FlowSignal.FlowPending
|
||||
|
||||
####################
|
||||
# - FlowKind.Func
|
||||
####################
|
||||
@events.computes_output_socket(
|
||||
'BC',
|
||||
kind=ct.FlowKind.Func,
|
||||
# Loaded
|
||||
props={'active_socket_set', 'valid_sim_axis'},
|
||||
input_sockets={
|
||||
'Angled Source',
|
||||
'Sim Domain',
|
||||
'Bloch Vector',
|
||||
},
|
||||
input_socket_kinds={
|
||||
'Angled Source': ct.FlowKind.Func,
|
||||
'Sim Domain': ct.FlowKind.Func,
|
||||
'Bloch Vector': ct.FlowKind.Func,
|
||||
},
|
||||
input_sockets_optional={
|
||||
'Angled Source': True,
|
||||
'Sim Domain': True,
|
||||
'Bloch Vector': True,
|
||||
},
|
||||
output_sockets={'BC'},
|
||||
output_socket_kinds={'BC': ct.FlowKind.Params},
|
||||
)
|
||||
def compute_bc_func(self, props, input_sockets, output_sockets) -> td.Absorber:
|
||||
r"""Computes the adiabatic absorber boundary condition based on the active socket set.
|
||||
|
||||
- **Simple**: Use `tidy3d`'s default parameters for defining the absorber parameters (apart from number of layers).
|
||||
- **Full**: Use the user-defined $\sigma$ parameters, specifically polynomial order and sim-relative min/max conductivity values.
|
||||
"""
|
||||
output_params = output_sockets['BC']
|
||||
has_output_params = not ct.FlowSignal.check(output_params)
|
||||
if not has_output_params:
|
||||
return ct.FlowSignal.FlowPending
|
||||
|
||||
active_socket_set = props['active_socket_set']
|
||||
match active_socket_set:
|
||||
case 'Naive':
|
||||
return ct.FuncFlow(
|
||||
func=lambda: td.Periodic(),
|
||||
supports_jax=False,
|
||||
)
|
||||
|
||||
case 'Source-Derived':
|
||||
angled_source = input_sockets['Angled Source']
|
||||
sim_domain = input_sockets['Sim Domain']
|
||||
|
||||
has_angled_source = not ct.FlowSignal.check(angled_source)
|
||||
has_sim_domain = not ct.FlowSignal.check(sim_domain)
|
||||
|
||||
if has_angled_source and has_sim_domain:
|
||||
valid_sim_axis = props['valid_sim_axis']
|
||||
return (angled_source | sim_domain).compose_within(
|
||||
enclosing_func=lambda els: td.BlochBoundary.from_source(
|
||||
source=els[0],
|
||||
domain_size=els[1]['size'][valid_sim_axis.axis],
|
||||
axis=valid_sim_axis.axis,
|
||||
medium=els[1]['medium'],
|
||||
),
|
||||
supports_jax=False,
|
||||
)
|
||||
return ct.FlowSignal.FlowPending
|
||||
|
||||
case 'Manual':
|
||||
bloch_vector = input_sockets['Bloch Vector']
|
||||
has_bloch_vector = not ct.FlowSignal.check(bloch_vector)
|
||||
|
||||
if has_bloch_vector:
|
||||
return bloch_vector.compose_within(
|
||||
enclosing_func=lambda: td.BlochBoundary(bloch_vec=bloch_vector),
|
||||
supports_jax=False,
|
||||
)
|
||||
return ct.FlowSignal.FlowPending
|
||||
|
||||
####################
|
||||
# - FlowKind.Params
|
||||
####################
|
||||
@events.computes_output_socket(
|
||||
'BC',
|
||||
kind=ct.FlowKind.Params,
|
||||
# Loaded
|
||||
props={'active_socket_set'},
|
||||
input_sockets={
|
||||
'Angled Source',
|
||||
'Sim Domain',
|
||||
'Bloch Vector',
|
||||
},
|
||||
input_socket_kinds={
|
||||
'Angled Source': ct.FlowKind.Params,
|
||||
'Sim Domain': ct.FlowKind.Params,
|
||||
'Bloch Vector': ct.FlowKind.Params,
|
||||
},
|
||||
input_sockets_optional={
|
||||
'Angled Source': True,
|
||||
'Sim Domain': True,
|
||||
'Bloch Vector': True,
|
||||
},
|
||||
)
|
||||
def compute_bc_params(self, props, input_sockets) -> ct.ParamsFlow | ct.FlowSignal:
|
||||
active_socket_set = props['active_socket_set']
|
||||
match active_socket_set:
|
||||
case 'Naive':
|
||||
return ct.ParamsFlow()
|
||||
|
||||
case 'Source-Derived':
|
||||
angled_source = input_sockets['Angled Source']
|
||||
sim_domain = input_sockets['Sim Domain']
|
||||
|
||||
has_angled_source = not ct.FlowSignal.check(angled_source)
|
||||
has_sim_domain = not ct.FlowSignal.check(sim_domain)
|
||||
|
||||
if has_sim_domain and has_angled_source:
|
||||
return angled_source | sim_domain
|
||||
return ct.FlowSignal.FlowPending
|
||||
|
||||
case 'Manual':
|
||||
bloch_vector = input_sockets['Bloch Vector']
|
||||
has_bloch_vector = not ct.FlowSignal.check(bloch_vector)
|
||||
|
||||
if has_bloch_vector:
|
||||
return bloch_vector
|
||||
return ct.FlowSignal.FlowPending
|
||||
|
||||
|
||||
####################
|
||||
|
|
|
@ -93,10 +93,11 @@ class BoundCondsNode(base.MaxwellSimNode):
|
|||
}
|
||||
|
||||
####################
|
||||
# - Output Socket Computation
|
||||
# - FlowKind.Value
|
||||
####################
|
||||
@events.computes_output_socket(
|
||||
'BCs',
|
||||
kind=ct.FlowKind.Value,
|
||||
input_sockets={'X', 'Y', 'Z', '+X', '-X', '+Y', '-Y', '+Z', '-Z'},
|
||||
input_sockets_optional={
|
||||
'X': True,
|
||||
|
|
|
@ -34,6 +34,8 @@ log = logger.get(__name__)
|
|||
|
||||
|
||||
class BoxStructureNode(base.MaxwellSimNode):
|
||||
"""A generic, differentiable box structure with configurable size and center."""
|
||||
|
||||
node_type = ct.NodeType.BoxStructure
|
||||
bl_label = 'Box Structure'
|
||||
use_sim_node_name = True
|
||||
|
@ -205,8 +207,8 @@ class BoxStructureNode(base.MaxwellSimNode):
|
|||
if has_center and has_size and has_medium:
|
||||
if props['differentiable'] == (
|
||||
center.is_differentiable
|
||||
& size.is_differentiable
|
||||
& medium.is_differentiable
|
||||
and size.is_differentiable
|
||||
and medium.is_differentiable
|
||||
):
|
||||
return center | size | medium
|
||||
return ct.FlowSignal.FlowPending
|
||||
|
|
Loading…
Reference in New Issue