"""A sub-module containing the configuration container class :class:`.Model` which is
used for building and manipulating interferometer systems."""
from __future__ import annotations
from collections import OrderedDict, defaultdict
from copy import copy, deepcopy
from functools import reduce
import inspect
import math
from numbers import Number
import weakref
import logging
from contextlib import contextmanager
from functools import wraps
from typing import Any
import warnings
import numpy as np
import networkx as nx
from deprecated import deprecated
from .config import config_instance
from .components import (
Port,
NodeDirection,
Connector,
Space,
Surface,
FrequencyGenerator,
Cavity,
Wire,
Gauss,
)
from .components.general import InteractionType, Variable
from .components.readout import _Readout, ReadoutDetectorOutput
from .components.dof import DegreeOfFreedom
from .components.general import CouplingType
from .components.node import NodeType, OpticalNode, Node, SignalNode
from .components.trace_dependency import TraceDependency
from . import detectors
from .element import ModelElement
from .env import warn, has_pygraphviz
from .exceptions import (
FinesseException,
NodeException,
ComponentNotConnected,
BeamTraceException,
ModelMissingAttributeError,
ModelClassAttributeError,
ContextualValueError,
)
from .freeze import Freezable
from .frequency import Fsig
from .gaussian import BeamParam, transform_beam_param
from .locks import Lock
from .paths import OpticalPath
from .tree import TreeNode
from .solutions import BaseSolution, BeamTraceSolution, SeriesSolution
from .tracing.forest import TraceForest
from .tracing import tools as tracetools
from .utilities import valid_name, pairwise, ngettext, is_iterable
from .utilities.components import refractive_index
from .utilities.homs import make_modes, insert_modes, remove_modes
from .utilities.tables import NumberTable
from finesse.utilities.network_filter import NetworkType
from .warnings import ModelParameterSettingWarning, CavityUnstableWarning
from .simulations import BaseSimulation
from .simulations.base import ModelSettings
from .parameter import Parameter
from finesse.utilities.collections import OrderedSet
[docs]def locked_when_built(func):
@wraps(func)
def wrapper(self, *args, **kwargs):
if self.is_built:
raise Exception(
f"Model has been built for a simulation, cannot use {func} here"
)
return func(self, *args, **kwargs)
return wrapper
LOGGER = logging.getLogger(__name__)
[docs]class IOMatrix:
[docs] def __init__(self, model):
self._model = model
self._terms = {}
[docs] def clear(self):
self._terms.clear()
def _check_key(a, b):
raise NotImplementedError()
def __getitem__(self, key):
if type(key) is tuple:
if key[0] in self._terms:
return self._terms[key[0]][key[1]]
else:
raise KeyError(f"{key[0]} not in Matrix")
else:
if key in self._terms:
return self._terms[key]
else:
raise KeyError(f"{key} not in Matrix")
def __setitem__(self, key, value):
if len(key) != 2:
raise Exception("Expected pair of string names as key")
a, b = key
if key[0] not in self._terms:
self._terms[key[0]] = {}
self._terms[key[0]][key[1]] = value
def __bool__(self):
return bool(self._terms)
[docs]class OutputMatrix(IOMatrix):
def _check_key(self, a, b):
if not isinstance(a, _Readout):
raise Exception(f"First index should be a Readout element name not `{a}`")
if not isinstance(b, DegreeOfFreedom):
raise Exception(
f"Second index should be a DegreeOfFreedom element name not `{a}`"
)
[docs]class Event(list):
"""Event subscription.
A list of callable objects. Calling an instance of this will cause a
call to each item in the list in ascending order by index.
Example Usage:
>>> def f(x):
... print 'f(%s)' % x
>>> def g(x):
... print 'g(%s)' % x
>>> e = Event()
>>> e()
>>> e.append(f)
>>> e(123)
f(123)
>>> e.remove(f)
>>> e()
>>> e += (f, g)
>>> e(10)
f(10)
g(10)
>>> del e[0]
>>> e(2)
g(2)
Notes
-----
Code from https://stackoverflow.com/questions/1092531/event-system-in-python
"""
def __call__(self, *args, **kwargs):
for f in self:
f(*args, **kwargs)
def __repr__(self):
return "<Event(%s)>" % list.__repr__(self)
[docs]def make_optical_network_view(model):
"""From a given model return a view of the full network that just contains the
optical nodes and edges."""
return nx.subgraph_view(
model.network,
filter_node=lambda n: model.network.nodes[n]["type"] == NodeType.OPTICAL,
filter_edge=lambda i, o: model.network[i][o]["coupling_type"]
== CouplingType.OPTICAL_TO_OPTICAL,
)
[docs]class Model(Freezable):
"""Optical configuration class for handling models of interferometers.
This class stores the interferometer configuration as a directed graph and contains
methods to interface with this data structure.
"""
[docs] def __init__(self):
# The model graph.
self.__network = nx.DiGraph()
# The optical graph. We need to store optical network separately for tracing
# correct paths through optical-optical couplings only.
self.__opt_net_view = make_optical_network_view(self)
# The syntax used to build the model, if parsed from KatScript.
self.syntax_graph = None
self.__is_built = False
# Some simple events that occur within the model that elements can register
# themselves with.
self._on_pre_build = Event() # Called just before a simulation is built.
self._on_unbuild = Event() # Called after unbuild() has been completed.
# Components and detectors.
self.__cavities = OrderedDict()
self.__components = OrderedDict()
self.__detectors = OrderedDict()
self.__locks = OrderedDict()
self.__dofs = OrderedDict()
self.__lock_model_change = False
self.__not_removable = OrderedSet()
# Frequency storage.
self.__frequencies = OrderedSet()
self.__frequency_change_callbacks = []
self.__freq_map = None
self._frequency_generators = []
# internal dict to store mode() call args for unparsing
self.__mode_setting = {}
self.alternate_name_map = {}
# Storage class for all the model settings that affects the output of a
# simulation.
self._settings = ModelSettings()
# Higher order mode related attributes.
self._settings.homs = np.zeros(1, dtype=(np.intc, 2)) # [(0, 0)]
self._settings.is_modal = False
self._settings.phase_config.zero_k00 = False
self._settings.phase_config.zero_tem00_gouy = True
# whether to use the Finesse2 phase conventions on transmission
self._settings.phase_config.v2_transmission_phase = False
# Constants.
config_consts = config_instance()["constants"]
self._settings.set_lambda0(config_consts.getfloat("lambda0"))
# Ratio of epsilon_0/c, used in converting between power and optical fields.
# Typically use just renormalise and use 1, putting optical fields in units of
# sqrt{W}.
self._settings.EPSILON0_C = 1
self._settings.UNIT_VACUUM = 1
self._settings.x_scale = config_consts.getfloat("x_scale")
# Beam tracing attributes.
self.__gausses = {}
self.__last_trace = None
self.__trace_order = [] # Order of TraceDependency objects for beam tracing
# Get argument names and values from beam_trace method and set the default
# simulation tracing config dict with these
self.__default_sim_trace_config = {
arg: value.default
for arg, value in inspect.signature(self.beam_trace).parameters.items()
}
self.__default_sim_trace_config["retrace"] = True
self.__default_sim_trace_config["unstable_handling"] = "auto"
self.__sim_trace_config = self.__default_sim_trace_config.copy()
self.__trace_forest = TraceForest(self, self.sim_trace_config["symmetric"])
self._rebuild_trace_forest = True
# The root action.
self.__analysis = None
self.__inmtx_dc = InputMatrix(self)
self.yaxis = None
self.force_refill = False
# List of all model elements.
self.__elements = OrderedDict()
self.__model_parameters = OrderedDict()
# Models always have a signal element.
self.add(Fsig("fsig", None), unremovable=True)
self._freeze()
def __setattr__(self, name, value):
# Need this method to stop overwriting model elements by accident, or
# on purpose
obj = self.__dict__.get(name)
if obj is None:
super().__setattr__(name, value)
elif isinstance(obj, Parameter):
obj.value = value
elif isinstance(obj, ModelElement):
raise AttributeError(f"Cannot overwrite element `{repr(obj)}` in model")
else:
super().__setattr__(name, value)
[docs] def info(
self,
modes=True,
components=True,
detectors=True,
cavities=True,
locks=True,
):
"""Get string containing information about this model.
Parameters
----------
modes, components, detectors, cavities, locks : bool, optional
Show model component information.
Returns
-------
str
The model information.
"""
from .utilities import format_section, format_bullet_list
pieces = []
if modes:
pieces.append(
format_section(
ngettext(len(self.homs), "{n} optical mode", "{n} optical modes"),
format_bullet_list(self.homs),
)
)
if components:
pieces.append(
format_section(
ngettext(len(self.components), "{n} component", "{n} components"),
format_bullet_list(self.components),
)
)
if detectors:
pieces.append(
format_section(
ngettext(len(self.detectors), "{n} detector", "{n} detectors"),
format_bullet_list(self.detectors),
)
)
if cavities:
pieces.append(
format_section(
ngettext(len(self.cavities), "{n} cavity", "{n} cavities"),
format_bullet_list(self.cavities),
)
)
if locks:
pieces.append(
format_section(
ngettext(len(self.locks), "{n} locking loop", "{n} locking loops"),
format_bullet_list(self.locks),
)
)
text = str(self) + "\n\n" + "\n".join(pieces)
return text
[docs] def deepcopy(self):
return deepcopy(self)
def __deepcopy__(self, memo):
new = object.__new__(type(self))
memo[id(self)] = new
new.after_deepcopy = []
# fields to exclude from copying straight away
# -> see below for cavities
# -> TraceForest instances are non-copyable by design so
# new model must rebuild its trace_forest by itself
exclude = [
"_Model__cavities",
"_Model__trace_forest",
]
sdict = {}
for k, v in self.__dict__.items():
if k in exclude:
sdict[k] = None
else:
sdict[k] = v
# need to ensure cavities are copied after everything else otherwise
# the copy operations on the source and target nodes may result in
# key errors on the memo as the new nodes haven't been created yet
cdict = {"_Model__cavities": self.__dict__["_Model__cavities"]}
new.__dict__.update(deepcopy(sdict, memo))
new.__dict__.update(deepcopy(cdict, memo))
# update all the weakrefs we have in the network
for n in new.network.nodes:
new.network.nodes[n]["weakref"] = weakref.ref(
memo[id(self.network.nodes[n]["weakref"]())]
)
new.network.nodes[n]["owner"] = weakref.ref(
memo[id(self.network.nodes[n]["owner"]())]
)
for e in new.network.edges:
new.network.edges[e]["in_ref"] = weakref.ref(
memo[id(self.network.edges[e]["in_ref"]())]
)
new.network.edges[e]["out_ref"] = weakref.ref(
memo[id(self.network.edges[e]["out_ref"]())]
)
new.network.edges[e]["owner"] = weakref.ref(
memo[id(self.network.edges[e]["owner"]())]
)
new.__opt_net_view = make_optical_network_view(new)
new.__trace_forest = TraceForest(
new, self.sim_trace_config["symmetric"], self.trace_forest.forest.trees
)
new._rebuild_trace_forest = True
new.__last_trace = None
if self.is_built:
# If we deepcopy from a built state then make sure we clean up the model
# state to get rid of any old data stored
new.unbuild()
# Final run of any later updates
for _ in new.after_deepcopy:
_()
del new.after_deepcopy # cleanup as this shouldn't be kept
return new
[docs] def add_parameter(
self,
name,
value,
*,
description=None,
dtype=float,
units="",
is_geometric=False,
changeable_during_simulation=True,
):
"""Adds a new parameter to the Model. This can be used to add a custom parameter
to the model that are not defined by elements themselves.
Parameters
----------
name : str
Name of the parameter
value : numeric | symbolic
The initial value of the parameter, this can be a simple numeric value or some
FINESSE symbolic
desription : str, optional
A descritive text of what this parameter is
dtype : str, optional
The datatype, typically float, int, bool
units : str, optional
Units of the parameter for display purposes
is_geometric : bool, optional
Whether this parameter is being used to recompute what the ABCD state
of the model is. This should only be true if this is directly used to
set what the ABCD matrices are. If you are just using a reference of this
for another geometric parameter this does not have to be True.
changeable_during_simulation : bool, optional
Whether this parameter is allowed to be changed during the simulation
add_to_model_namespace : bool, optional
Whether to add this to the main model namespace or not
Examples
--------
Here we add some new parameters:
>>> import finesse
>>> model = finesse.Model()
>>> A = model.add_parameter('A', 1, units='W')
>>> B = model.add_parameter('B', A.ref +1)
These act like normal element parameters, so references can be made to
make symbolic equations and links between elements. These will be
unparsed as variables in KatScript:
>>> print(model.unparse())
variable A value=1.0 units='W'
variable B value=(A+1)
"""
if name in self.__model_parameters:
raise FinesseException(f"A parameter with the name `{name}` already exists")
if hasattr(self, name):
raise FinesseException(
f"The `{name}` is already used by `{getattr(self, name)}` in this model, choose a different one"
)
from finesse.parameter import Parameter, ParameterInfo
pinfo = ParameterInfo(
name,
description,
dtype,
dtype,
units,
is_geometric,
changeable_during_simulation,
)
p = self.__model_parameters[name] = Parameter(pinfo, self)
p.value = value
# Store in the global model namespace for access
self._unfreeze()
setattr(self, name, p)
self._freeze()
return p
@property
def parameters(self):
"Returns any parameters added to this model, see also :attr:`.Model.all_parameters`."
return tuple(self.__model_parameters.values())
@property
def all_parameters(self):
"""Returns a generator of all the parameters in this model and the elements
added to this model."""
from itertools import chain
return chain(
(p for el in self.elements.values() for p in el.parameters),
self.__model_parameters.values(),
)
[docs] def sort_elements(self, key):
"""Sort the display order of the elements in the model.
This order is used for determining the order of plot traces and other listings.
Element sorting is useful for example when parsing KatScript into a model, where
adding of elements to the model may not be performed in the same order as the
corresponding definitions in the script. To ensure consistency to the user, this
method can be used to sort the parsed elements back into their original script
order.
Notes
-----
The sort performed by this method is stable.
Parameters
----------
key : callable
Specifies a function that takes a single argument - a tuple containing the
element name and object - and returns a comparison key.
"""
LOGGER.debug("sorting model elements (redefining __elements dict)")
self.__elements = dict(sorted(self.__elements.items(), key=key))
[docs] def element_order(self, element):
"""Get the order in which `element` was added to the model."""
return list(self.elements).index(element.name)
@property
def input_matrix_dc(self):
"""The DC input matrix is used to relate degrees of freedoms and readouts within
a model. This information is used to generate DC locks to put the model at an
operating point defined by the error signals used.
:`getter`: Returns an InputMatrix object.
"""
return self.__inmtx_dc
@property
def analysis(self):
"""The root action to apply to the model when :meth:`Model.run` is called.
:`getter`: Returns the root analysis attached to this model.
:`setter`: Sets the model's root analysis.
"""
return self.__analysis
@analysis.setter
@locked_when_built
def analysis(self, action):
self.__analysis = action
@property
def readouts(self):
"""Returns all readouts in the model."""
return self.get_elements_of_type(_Readout)
@property
def elements(self):
"""Dictionary of all the model elements with the keys as their names."""
return self.__elements.copy()
@property
def network(self):
"""The directed graph object containing the optical configuration as a
:class:`networkx.DiGraph` instance.
The `network` stores :class:`.Node` instances as nodes and :class:`.Space`
instances as edges, where the former has access to its associated component via
:attr:`.Node.component`.
See the NetworkX documentation for further details and a reference to the data
structures and algorithms within this module.
:`getter`: Returns the directed graph object containing the configuration
(read-only).
"""
return self.__network
@property
def optical_network(self):
"""A read-only view of the directed graph object stored by :attr:`Model.network`
but only containing nodes of type :class:`.OpticalNode` and only with edges that
have couplings to optical nodes.
:`getter`: Returns the optical-only directed graph-view (read-only).
"""
assert self.__opt_net_view._graph is self.network
return self.__opt_net_view
def filter_node(node):
return self.network.nodes[node]["type"] == NodeType.OPTICAL
return nx.subgraph_view(self.network, filter_node=filter_node)
[docs] def to_component_network(self, add_edge_info: bool = False):
"""Generate an undirected graph containing components as the nodes of the graph
and connections (spaces, wires) between component nodes as the edges of the
graph.
Returns
-------
:class:`networkx.Graph`
The component network.
"""
c_net = nx.Graph()
# Add components as nodes.
for component in self.components:
c_net.add_node(component.name)
# Add spaces, wires as edges.
for u, v, data in self.network.edges(data=True):
# Resolve the owning object.
owner = data["owner"]()
if not isinstance(owner, (Space, Wire)):
continue
# Resolve the connected objects.
in_ref = data["in_ref"]()
out_ref = data["out_ref"]()
u = in_ref.component.name
v = out_ref.component.name
if u not in c_net.nodes or v not in c_net.nodes:
# Only add edges between components (not e.g. connections between components and
# spaces, like phase couplings).
continue
if add_edge_info:
# add info on connections between nodes for verbose component tree
out_name = f"{out_ref.component.name}.{out_ref.port.name}"
in_name = f"{in_ref.component.name}.{in_ref.port.name}"
c_net.nodes[u][v] = f"{out_name} ↔ {in_name}"
c_net.nodes[v][u] = f"{in_name} ↔ {out_name}"
# Since the network is a graph, not a digraph, we only need to add one direction.
if (u, v) not in c_net.edges:
c_net.add_edge(u, v, connection=data["owner"])
return c_net
def __nodes_of(self, *node_types) -> list[Node]:
return [
attr["weakref"]()
for _, attr in self.__network.nodes(data=True)
if attr["weakref"]().type in node_types
]
@property
def optical_nodes(self) -> list[Node]:
"""The optical nodes stored in the model.
:`getter`: Returns a list of all the optical nodes in the model (read-only).
"""
return self.__nodes_of(NodeType.OPTICAL)
@property
def signal_nodes(self) -> list[Node]:
"""The signal nodes stored in the model.
:`getter`: Returns a list of all the signal nodes in the model (read-only).
"""
return self.__nodes_of(NodeType.ELECTRICAL, NodeType.MECHANICAL)
@property
def gausses(self):
"""A dictionary of optical node to :class:`.Gauss` instance mappings.
:`getter`: Returns the dictionary of user defined beam parameter nodes
(read-only).
"""
return self.__gausses
@property
def lambda0(self):
"""The default wavelength to use for the model.
:`getter`: Returns wavelength in meters
:`setter`: Sets the wavelength in meters
"""
return self._settings.lambda0
@lambda0.setter
@locked_when_built
def lambda0(self, value):
self._settings.set_lambda0(float(value))
# Update the wavelengths of Gauss object beam parameters
for gauss in self.__gausses.values():
gauss.qx.wavelength = self._settings.lambda0
gauss.qy.wavelength = self._settings.lambda0
@property
def f0(self):
"""The default frequency to use for the model. This is determinde by the value
of `lambda0`.
:`getter`: Returns frequency in Hertz
"""
return self._settings.f0
@property
def k0(self):
"""The default wavenumber used for the model. This is determinde by the value of
`lambda0`.
:`getter`: Returns frequency in Hertz
"""
return self._settings.k0
@property
def is_modal(self):
"""Flag indicating whether the model is modal or plane-wave.
:`getter`: `True` if the modal is modal, `False` if it is plane-wave.
"""
return self._settings.is_modal
@property
def hom_labels(self):
"""Labels for the HOMs present in this model."""
return tuple(f"{n},{m}" for n, m in self.homs)
@property
def homs(self):
"""An array of higher-order modes (HOMs) included in the model.
:`getter`: Returns a copy of the array of the HOMs in the model.
:`setter`: Sets the HOMs to be included in the model. See :meth:`Model.modes`
for the options available.
"""
return self._settings.homs
@homs.setter
@locked_when_built
def homs(self, value):
self.modes(value)
@property
def modes_setting(self):
# Used by unparser.
return self.__mode_setting
@property
def mode_index_map(self):
"""An ordered dictionary where the key type is the modes in the model and the
mapped type is the index of the mode.
:`getter`: Returns the map of modes to indices (read-only).
"""
return {(n, m): i for i, (n, m) in enumerate(self._settings.homs)}
[docs] @locked_when_built
def include_modes(self, modes):
"""Inserts the mode indices in `modes` into the :attr:`.Model.homs` array at the
correct (sorted) position(s).
Parameters
----------
modes : sequence, str
A single mode index pair or an iterable of mode indices. Each
element must unpack to two integer convertible values.
"""
self._settings.homs = insert_modes(self._settings.homs, modes)
if not self._settings.is_modal:
self._settings.is_modal = True
LOGGER.info(f"Turning on HOMs --> switching model: {self!r} to modal.")
self.__mode_setting["include"] = modes
[docs] @locked_when_built
def remove_modes(self, modes):
"""Removes the mode indices in `modes` from the :attr:`.Model.homs` array.
Parameters
----------
modes : sequence, str
A single mode index pair or an iterable of mode indices. Each
element must unpack to two integer convertible values.
"""
self._settings.homs = remove_modes(self._settings.homs, modes)
self.__mode_setting["remove"] = modes
[docs] @locked_when_built
def switch_off_homs(self):
"""Turns off HOMs, switching the model to a plane wave basis."""
LOGGER.info("Turning off HOMs --> switching model to plane wave.")
self._settings.homs = np.zeros(1, dtype=(np.intc, 2))
self._settings.is_modal = False
[docs] @locked_when_built
def modes(self, modes=None, maxtem=None, include=None, remove=None):
"""Select the HOM indices to include in the model.
See :ref:`selecting_modes` for examples on using this method.
Parameters
----------
modes : sequence, str, optional; default: None
Identifier for the mode indices to generate. This can be:
- An iterable of mode indices, where each element in the iterable must
unpack to two integer convertible values.
- A string identifying the type of modes to include, must be one of "off",
"even", "odd", "x" or "y".
maxtem : int, optional; default: None
Optional maximum mode order.
include : sequence, str, optional
A single mode index pair, or an iterable of mode indices, to include. Each
element must unpack to two integer convertible values.
remove : sequence, str, optional
A single mode index pair, or an iterable of mode indices, to remove. Each
element must unpack to two integer convertible values.
See Also
--------
Model.include_modes : Insert mode indices into :attr:`Model.homs` at the
correct (sorted) positions.
Model.remove_modes : Remove mode index pairs from the model.
Examples
--------
See :ref:`selecting_modes`.
"""
if (
(modes is None)
and (maxtem is None)
and (include is None)
and (remove is None)
):
if self._settings.is_modal:
return self.homs
else:
return None
if not self._settings.is_modal:
self._settings.is_modal = True
LOGGER.info("Turning on HOMs --> switching model to modal.")
# NOTE (sjr) Commenting this out for now as it can cause confusion when
# parsing a file - e.g. adding a cavity, gauss object before
# maxtem is set will trigger this statement and erroneously lead
# the user to believe that only the 00 mode is present
# if modes is None and maxtem == 0 and include is None and remove is None:
# warn(
# "Modal model enabled with only HG00. Call Model.modes to add modes."
# )
def do_make_modes(*args, **kwargs):
try:
return make_modes(*args, **kwargs)
except ContextualValueError as e:
# make_modes uses different parameters to this method so we need to
# rewrite the parameters.
if "select" in e.params:
# Note: ensure the signature order is retained!
params = {"modes": e.params["select"], **e.params}
params.pop("select")
e.params = params
raise e
if modes is None: # maxtem
if maxtem is None:
self.switch_off_homs()
else:
self._settings.homs = do_make_modes(maxtem=maxtem)
elif isinstance(modes, str): # identifier
if modes.casefold() == "off":
self.switch_off_homs()
else:
if maxtem is None:
raise ValueError(
f"Argument maxtem must be specified for modes argument of "
f"{modes}"
)
self._settings.homs = do_make_modes(modes, maxtem)
else: # iterable of mode indices
self._settings.homs = do_make_modes(modes)
if include is not None:
self.include_modes(include)
if remove is not None:
self.remove_modes(remove)
# remember the modes setting for use in the unparser
self.__mode_setting["modes"] = modes
self.__mode_setting["maxtem"] = maxtem
self.__mode_setting["include"] = include
self.__mode_setting["remove"] = remove
[docs] @locked_when_built
def add_all_ad(self, node, f=0):
"""Adds amplitude detectors at the specified `node` and frequency `f` for all
Higher Order Modes in the model.
Parameters
----------
node : :class:`.OpticalNode`
Node to add the detectors at.
f : scalar, :class:`.Parameter` or :class:`.ParameterRef`
Frequency of the field to detect.
Returns
-------
dets : list
A list of all the amplitude detector instances added to the model.
"""
node_name = node.tag
if node_name is None or not valid_name(node_name):
node_name = node.full_name.replace(".", "_")
ads = []
for n, m in self._settings.homs:
ad = detectors.AmplitudeDetector(f"ad_{n}_{m}_{node_name}", node, f, n, m)
self.add(ad)
ads.append(ad)
return ads
[docs] @locked_when_built
def add_fd_to_every_node(self, freq=0):
"""Adds a FieldDetector at every optical node in model at a given frequency
The name of each FieldDetector is automatically generated using the following
pattern: ``E_<component>_<port>_<node>``
Parameters
----------
f : scalar, :class:`.Parameter` or :class:`.ParameterRef`
Frequency of the field to detect.
Returns
-------
dets : list
A list of all the field detector instances added to the model.
"""
nodes = self.optical_nodes
fds = []
for node in nodes:
fd_name = f"E_{node.full_name.replace('.','_')}"
fd = detectors.FieldDetector(fd_name, node, freq)
self.add(fd)
fds.append(fd)
return fds
@property
def phase_level(self):
"""An integer corresponding to the phase level given to the phase command of a
Finesse 2 kat script.
:`getter`: Returns the phase level.
:`setter`: Sets the phase level - turns on/off specific flags
for the scaling of coupling coefficient and Gouy phases.
"""
warn(
"`Model.phase_level = n` deprecrated, use `Model.phase_config` instead",
DeprecationWarning,
)
lvl = 0
if self._settings.phase_config.zero_k00:
lvl += 1
if self._settings.phase_config.zero_tem00_gouy:
lvl += 2
return lvl
@phase_level.setter
@locked_when_built
def phase_level(self, value):
# No public alternative...
warn(
"`Model.phase_level = n` deprecrated, use `Model.phase_config` instead",
DeprecationWarning,
)
if value == 0:
self._settings.phase_config.zero_k00 = False
self._settings.phase_config.zero_tem00_gouy = False
elif value == 1:
self._settings.phase_config.zero_k00 = True
self._settings.phase_config.zero_tem00_gouy = False
elif value == 2:
self._settings.phase_config.zero_k00 = False
self._settings.phase_config.zero_tem00_gouy = True
elif value == 3:
self._settings.phase_config.zero_k00 = True
self._settings.phase_config.zero_tem00_gouy = True
else:
raise ValueError(f"Value is not valid {value}")
[docs] @locked_when_built
def phase_config(self, zero_k00=False, zero_tem00_gouy=True):
"""Coupling coefficient and Gouy phase scaling:
- phase_level 3 == zero_k00=True, zero_tem00_gouy=True
- phase_level 2 == zero_k00=False, zero_tem00_gouy=True
- phase_level 1 == zero_k00=True, zero_tem00_gouy=False
- phase_level 0 == zero_k00=False, zero_tem00_gouy=False
See also :ref:`phase_configurations`
This can be used to change the computation of light field phases in the
Hermite-Gauss mode. In general, in the presence of higher order modes,
the "macroscopic length" of a space is no longer an integer number of
wavelengths for the TEM00 mode because of the Gouy phase.
Furthermore, the coupling coefficients :math:`k_{nmnm}`
contribute to the phase when there is a mode mismatch.
For correct analysis these effects have to be taken into account. On the
other hand, these extra phase offsets make it very difficult to set a
resonance condition or operating point intuitively. In most cases
another phase offset can be added to all modes so that the phase of the
TEM00 becomes zero.
This method allows setting these phase offsets for the propagation
through free space, for the coupling coefficients, or both. Regardless
of the setting, the phases for all higher modes are changed accordingly
such that the relative phases remain correct.
Parameters
----------
zero_k00 : bool, optional
Scale phase for k0000 (TEM00 to TEM00) coupling coefficients to 0. Defaults
to True.
zero_tem00_gouy : bool, optional
Ensure that all Gouy phases for TEM00 are 0. Defaults to True.
"""
self._settings.phase_config.zero_k00 = zero_k00
self._settings.phase_config.zero_tem00_gouy = zero_tem00_gouy
@property
def Nhoms(self):
"""Number of higher-order modes (HOMs) included in the model.
:`getter`: Returns the number of HOMs in the model (read-only).
"""
return self._settings.num_HOMs
@property
def frequencies(self):
"""The frequencies stored in the model as a :py:class:`list` instance.
:`getter`: Returns a list of the model frequencies (read-only).
"""
return tuple(self.__frequencies)
@property
def source_frequencies(self):
"""The source frequencies stored in the model as a :py:class:`dict` instance.
The frequencies are the keys, and the values are list of components that depend
on the given frequency.
:`getter`: Returns a dict of the model source frequencies (read-only).
"""
return tuple(self.__source_frequencies.keys())
@property
def components(self):
"""The components stored in the model as a tuple object.
:`getter`: Returns a tuple of the components in the model (read-only).
"""
return tuple(self.__components.keys())
@property
def detectors(self):
"""The detectors stored in the model as a tuple object.
:`getter`: Returns a tuple of the detectors in the model (read-only).
"""
return tuple(self.__detectors.keys())
@property
def cavities(self):
"""The cavities stored in the model as a tuple object.
:`getter`: Returns a tuple of the cavities in the model (read-only).
"""
return tuple(self.__cavities.keys())
@property
def locks(self):
return tuple(self.__locks.keys())
@property
def dofs(self):
return tuple(self.__dofs.keys())
@property
def is_built(self):
"""Flag indicating whether the model has been built.
When this evaluates to `True`, the structure of the underlying matrix
should not be changed.
:`getter`: `True` if the model has been built, `False` otherwise.
"""
return self.__is_built
@property
def trace_order(self):
"""A list of beam tracing dependencies, ordered by their tracing priority.
Dependency (i.e. :class:`.Cavity` and :class:`.Gauss`) objects are ordered
in this list according to the priority in which they will be traced during
the beam tracing routine.
This ordering is strictly defined as follows:
Dependencies will be sorted in order of *descending* :attr:`.TraceDependency.priority`
value. Any dependencies which have equal :attr:`.TraceDependency.priority` value are
sorted *alphabetically* according to their names.
Please be aware that this means if no priority values have been given to any
:class:`.TraceDependency` instance in the model, as is the default when creating
these objects, then this trace order list is simply sorted alphabetically by the
dependency names.
.. note::
Regardless of their positions in this list, the *internal* traces of
:class:`.Cavity` objects will always be performed first. Internal cavity
traces are defined as the traces which propagate the cavity eigenmode
through all the nodes of the cavity path.
Importantly, however, the order in which :class:`.Cavity` objects appear
in this trace order list *will* also determine the order in which their internal
traces are performed. This is relevant only for when there are overlapping
cavities in the model - recycling cavities in dual-recycled Michelson interferometer
configurations are a typical case of this.
As always see :meth:`.Model.beam_trace` and :ref:`tracing_manual` for more details
on the inner workings of the beam tracing routines.
Temporary overriding of this order for a given :meth:`.Model.beam_trace` call
can be performed by specifying the ``order`` argument for this method call.
To override this ordering for a simulation, one should use the ``"order"`` keyword
argument of :meth:`.Model.sim_trace_config_manager` to temporarily use any arbitrary
dependency order within a context.
:`getter`: Returns a list giving the order in which dependencies will be traced. Read-only.
"""
return self.__trace_order.copy()
@property
def trace_order_names(self):
"""A convenience property to retrieve a list of the names of each
:class:`.TraceDependency` instance in :attr:`.Model.trace_order`.
:`getter`: Returns a list of the names of the dependencies in the order they will
be traced. Read-only.
"""
return [d.name for d in self.trace_order]
def __insert_trace_dependency(self, dep):
self.__trace_order.append(dep)
self._resort_trace_dependencies()
def _resort_trace_dependencies(self):
# Sort in order of descending priority and ensure dependencies
# with equal priority are sorted alphabetically by name
self.__trace_order.sort(key=lambda x: (-x.priority, x.name))
@property
def trace_forest(self):
"""The :class:`.TraceForest` instance held by the model.
This is a representation of the beam tracing paths from each dependency which takes
on a form corresponding to the last call to :meth:`.Model.beam_trace`. See the
documentation for :class:`.TraceForest` itself for details on what exactly this
object is, and the various methods and properties it exposes.
.. hint::
Most of the time users will not need to touch this property as it is generally
just used internally. Beam tracing functionality should instead be used via
the carefully designed interfaces, i.e: :meth:`.Model.beam_trace` for full model
beam traces, :meth:`.Model.propagate_beam` for propagating an arbitrary beam
through a path etc. See :mod:`.tracing.tools` for details on various beam tracing
tools.
Despite the above, it *can* sometimes be useful to query this property to get a visual
representation of how the beam tracing paths look in your model. To do this one
can simply print the return of this property, i.e.::
print(model.trace_forest)
to get a forest-like structure of all the beam tracing trees which represent the
current state (as of the last :meth:`.Model.beam_trace` call) of the model.
:`getter`: The :class:`.TraceForest` object associated with this model. Read-only.
"""
return self.__trace_forest
[docs] @contextmanager
def sim_trace_config_manager(self, **kwargs):
"""Change the :attr:`.Model.sim_trace_config` within a context.
This provides a convenient pattern through which one can temporarily
set the simulation beam tracing behaviour in a ``with`` block. The
method :meth:`.Model.reset_sim_trace_config` is called on exit.
Parameters
----------
kwargs : keyword arguments
See :attr:`.Model.sim_trace_config`.
Examples
--------
Temporarily change the tracing order::
with model.sim_trace_config_manager(order=["cavXARM", "gaussBS", "cavYARM"]):
out = model.run("noxaxis()")
Disable certain dependencies in a context::
with model.sim_trace_config_manager(disable="cavIMC"):
out = model.run("noxaxis()")
Switch off re-tracing and enable only two specific trace dependencies::
with model.sim_trace_config_manager(
retrace=False, enable_only=["cavXARM", "cavYARM"]
):
out = model.run("noxaxis()")
Use asymmetric tracing and mask all data points where any unstable cavity
is encountered::
with model.sim_trace_config_manager(symmetric=False, unstable_handling="mask"):
out = model.run("noxaxis()")
"""
diff = set(kwargs) - set(self.sim_trace_config)
if diff:
raise KeyError(
"The following arguments are not sim_trace_config "
f"options: {', '.join(diff)}"
)
self.sim_trace_config.update(kwargs)
try:
yield
finally:
self.reset_sim_trace_config()
@property
def sim_trace_config(self):
"""Dictionary corresponding to beam tracing configuration options for
simulations.
The (string) keys of this dict are:
* The arguments of :meth:`.Model.beam_trace`, see the linked docs for descriptions
of each of these. These config values are passed to the initial beam trace
call when building a modal simulation, thereby determining the structure of
both the :attr:`.Model.trace_forest` used for computing the initial beam
parameters, as well as the trace forest of changing beam paths as stored by
the simulation itself.
* "retrace" --- flag determining whether beam tracing is re-executed, during a
simulation, whenever some dependent parameter changes. This is ``True`` by
default, meaning that any paths in the model with changing geometric parameters
will automatically be retraced during the simulation. Setting this to ``False``
means that the initial beam parameters (from the beam trace executed at the
start of the simulation) are used for all data points, regardless of whether
any geometric parameter is changing or not.
* "unstable_handling" --- the strategy to use when encountering unstable optical
cavities during a simulation (as a potential result of scanning geometric
parameters). The accepted values for this config option are:
* "auto" --- (default) contingency :class:`.TraceForest` instances are created when
entering unstable cavity regions; or, if there are no stable :class:`.TraceDependency`
objects, detector outputs are masked appropriately in these regions.
* "mask" --- detector outputs masked appropriately whenever an unstable cavity
is encountered; i.e. nothing else (scatter matrices, gouy phases, refills etc.)
is computed for such data points.
* "abort" --- immediately aborts the simulation, if an unstable cavity is encountered,
by raising a :class:`.BeamTraceException`.
.. hint::
Most of the time it is better to use :meth:`.Model.sim_trace_config_manager` to
temporarily set simulation beam tracing configuration options, rather than modifying
the entries here directly (which then requires manual re-setting as outlined below).
:`getter`: Beam tracing configuration options for simulations.
Examples
--------
One can use this property to change the behaviour of beam tracing for a simulation. For
example, this::
model.sim_trace_config["disable"] = "cav1"
would switch off tracing from the trace-dependency named `"cav1"` during a simulation.
It can also be used to temporarily override the trace order used, without modifying
:attr:`.TraceDependency.priority` values and, thus, without modifying the actual
:attr:`.Model.trace_order`. For example::
model.sim_trace_config["order"] = ["gL0", "cav2", "cav1"]
would set the trace ordering for the next simulation using this model to the order given.
To reset the `sim_trace_config` dict entries to the default values,
call :meth:`.Model.reset_sim_trace_config`.
"""
return self.__sim_trace_config
@property
def sim_initial_trace_args(self):
"""Filtered dictionary of :attr:`.Model.sim_trace_config` corresponding to only
those options which match the arguments of :meth:`.Model.beam_trace`.
The arguments of :meth:`.Model.beam_trace`, see the linked docs for descriptions
of each of these. These config values are passed to the initial beam trace
call when building a modal simulation, thereby determining the structure of
both the :attr:`.Model.trace_forest` used for computing the initial beam
parameters, as well as the trace forest of changing beam paths as stored by
the simulation itself.
.. note::
The return value is a new filtered dict, not a sub-view of :attr:`.Model.sim_trace_config`,
thus modifying this dict does not affect the entries in :attr:`.Model.sim_trace_config`.
"""
return {
k: self.sim_trace_config[k]
for k in inspect.signature(self.beam_trace).parameters.keys()
}
[docs] def reset_sim_trace_config(self):
"""Resets the simulation beam tracing configuration dict, given by
:attr:`.Model.sim_trace_config`, to the default values."""
self.__sim_trace_config = self.__default_sim_trace_config.copy()
@property
def is_traced(self):
"""Flag indicating whether the model has been traced.
.. warning::
This flag only indicates whether a beam trace has been performed on the model,
it *does not* mean that the last stored beam trace (i.e. :attr:`.Model.last_trace`)
corresponds to the latest state of the model.
:`getter`: `True` if the mode has been traced at least once, `False` otherwise.
"""
return self.last_trace is not None
@property
def last_trace(self):
"""An instance of :class:`.BeamTraceSolution` containing the output of the most
recently stored beam trace performed on the model.
:`getter`: Returns a copy of the most recently stored beam trace output. Read-
only.
"""
return copy(self.__last_trace)
[docs] @locked_when_built
def tag_node(self, node, tag):
"""Tag a node with a unique name.
Access to this node can then be performed with::
node = model.<tag_name>
Parameters
----------
node : :class:`.Node`
An instance of a node already present in the model.
tag : str
Unique tag name of the node.
"""
self.__node_exists_check(node)
if hasattr(self, tag):
raise Exception(f"Tagged name: {tag} already exists in the model.")
node._set_tag(tag)
self._unfreeze()
setattr(self, tag, node)
self._freeze()
[docs] def get_parameters(
self, *, include=None, exclude=None, are_changing=None, are_symbolic=None
):
"""Get all or a filtered list of parameters from all elements in the model.
Parameters
----------
include : [iterable|str], optional
Parameters that *should* be included.
If a single string is given it can be a Unix file style wildcard (See ``fnmatch``).
A value of None means everything is included.
If an iterable is provided it must be a list of names or Parameter objects.
exclude : [iterable|str], optional
Parameters that *should not* be included.
If a single string is given it can be a Unix file style wildcard (See ``fnmatch``).
A value of None means nothing is excluded.
If an iterable is provided it must be a list of names or Parameter objects.
are_changing : boolean, optional
Filter if Parameter has a value that will be marked as changing during a simulation.
Note this might be a user chaniging variable or a symbolic value whose arguments
are changing.
are_symbolic : boolean, optional
Filter if Parameter has a symbolic value. If set to None, not filtering is done.
Returns
-------
parameters : list
List of filtered Parameters
Examples
--------
>>> model = finesse.Model()
>>> model.parse('''
... l l1
... l l2
... lens L1 f=100
... link(l1, L1, l2)
... pd P1 L1.p1.o
... pd P2 L1.p2.o
... ''')
>>> print(model.get_parameters(include='*f*'))
>>> print(model.get_parameters(include='*f*', exclude='l2*'))
[<fsig.f=None @ 0x7f7fc449a580>, <l1.f=0.0 @ 0x7f7fc449a340>,
<l2.f=0.0 @ 0x7f7fc449a880>, <L1.f=100.0 @ 0x7f7fc449aac0>]
[<fsig.f=None @ 0x7f7fc449a580>, <l1.f=0.0 @ 0x7f7fc449a340>,
<L1.f=100.0 @ 0x7f7fc449aac0>]
"""
from fnmatch import fnmatch
name_predicates = []
bool_predicates = []
if exclude is not None:
if isinstance(exclude, str):
name_predicates.append(lambda x: not fnmatch(x, exclude))
else:
name_predicates.append(lambda x: (x not in exclude))
if include is not None:
if isinstance(include, str):
name_predicates.append(lambda x: fnmatch(x, include))
else:
name_predicates.append(lambda x: (x in include))
if are_changing is not None:
bool_predicates.append(lambda x: x.is_changing == are_changing)
if are_symbolic is not None:
bool_predicates.append(lambda x: x.is_symbolic == are_symbolic)
return [ # get all parameters
p
for p in self.all_parameters
if all(pred(p.full_name) for pred in name_predicates)
and all(pred(p) for pred in bool_predicates)
]
[docs] @contextmanager
def temporary_parameters(self, include=None, exclude=None):
"""Context manager that lets user change any ModelParameter then return it to
the original value once completed. When the Model is in this temporary state it
cannot have any structural changes, such as adding or removing components.
There is also the ability to include or exclude certain parameters from reverting
back to their previous values if needed.
Parameters
----------
include : iterable or str, optional
Parameters that *should* be reverted once the context has exitted.
If a single string is given it can be a Unix file style wildcard (See ``fnmatch``).
A value of None means everything is included.
If an iterable is provided it must be a list of names or Parameter objects.
exclude : iterable or str, optional
Parameters that *should not* be reverted once the context has exitted.
If a single string is given it can be a Unix file style wildcard (See ``fnmatch``).
A value of None means nothing is excluded.
If an iterable is provided it must be a list of names or Parameter objects.
Examples
--------
.. code-block::
import finesse
model = finesse.Model()
model.parse('''
l l1 P=1
m m1 R=0.99 T=0.01 Rc=-1934
m m2 R=1 T=0 Rc=2245
m m3 R=1 T=0 Rc=10000
'''
)
with model.temporary_parameters():
model.m1.Rc = 100
print(model.m1.Rc)
print(model.m1.Rc)
# Only reset m2 parameters
with model.temporary_parameters(include="m2.*"):
...
# Only reset m2.phi and m1.phi parameters
with model.temporary_parameters(include=("m2.phi", "m1.phi")):
...
# Reset everything apart from all phi parameters
with model.temporary_parameters(exclude="*.phi"):
...
# Reset everything apart from all phi parameters
with model.temporary_parameters(exclude="m[1-3].phi"):
...
"""
params = self.get_parameters(include=include, exclude=exclude)
try:
self.__lock_model_change = True # stop any structural changes to model
# Get the current values of all parameters
initial_values = {p: copy(p.value) for p in params}
initial_settings = deepcopy(self._settings)
yield self
except Exception as ex:
raise ex
finally:
# Reset the values on exit
with warnings.catch_warnings():
warnings.filterwarnings("ignore", category=ModelParameterSettingWarning)
for p in params:
if p.value != initial_values[p]:
p.value = initial_values[p]
self._settings = initial_settings
self.__lock_model_change = False
[docs] @locked_when_built
def remove(self, obj):
"""Removes an object from the model.
.. note::
If a string is passed, it will be looked up
via self.elements.
Parameters
----------
obj : :class:`.Frequency` or sub-class of :class:`.ModelElement`
The object to remove from the model.
Raises
------
Exception
If the matrix has already been built or there is no component
with the given name in the model.
"""
if self.__lock_model_change:
raise FinesseException("Model is locked and cannot be added or removed to.")
if isinstance(obj, str):
obj = self.elements[obj]
if obj in self.__not_removable:
raise FinesseException(f"{obj} cannot be removed from the model.")
if isinstance(obj, ModelElement):
# Check that any of this elements parameters are not being referenced by
# someone else in the model
symbolic_params = (
p for p in self.all_parameters if p.is_symbolic and p.owner is not obj
)
for sp in symbolic_params:
sp_id_parameters = tuple(id(_) for _ in sp.value.parameters())
for p in obj.parameters:
if id(p) in sp_id_parameters:
raise FinesseException(
f"Cannot remove element {repr(obj)}.\nParameter {repr(p)} is being used by {repr(sp)}."
)
if obj in self.__components:
nodes = obj.nodes
# stores (port1, port2) keys where port1 should now connect to port2
pairs = {}
for name, node in nodes.items():
if node.type != NodeType.OPTICAL or not node.is_input:
continue
predecessors = list(self.network.predecessors(name))
if not predecessors:
continue
pre = predecessors[0]
# immediate successors of the node - always exist
im_succ = list(self.network.successors(name))
# find only the successor node which is at a different port
match = list(
filter(
lambda n: self.network.nodes[n]["weakref"]().port
!= node.port,
im_succ,
)
)[0]
# successors of the immediate successors
successors = list(self.network.successors(match))
if not successors:
continue
succ = successors[0]
p1 = self.network.nodes[pre]["weakref"]().port
p2 = self.network.nodes[succ]["weakref"]().port
# don't add the port pair again if we already did the
# previous propagation from the opposite port
if (p2, p1) not in pairs:
p1_space = p1.space
p2_space = p2.space
pairs[(p1, p2)] = p1_space.L.value + p2_space.L.value
self.network.remove_edge(pre, name)
self.network.remove_edge(
node.opposite.full_name,
self.network.nodes[pre]["weakref"]().opposite.full_name,
)
self.network.remove_edge(match, succ)
self.network.remove_edge(
self.network.nodes[succ]["weakref"]().opposite.full_name,
self.network.nodes[match]["weakref"]().opposite.full_name,
)
for n in p1.nodes:
try:
self.network.remove_edge(
p1_space.phase_sig.i.full_name, n.full_name
)
except nx.exception.NetworkXError:
pass
for n in p2.nodes:
try:
self.network.remove_edge(
p2_space.phase_sig.i.full_name, n.full_name
)
except nx.exception.NetworkXError:
pass
self.network.remove_node(name)
del self.__elements[p1_space.name]
del self.__elements[p2_space.name]
for (p, s), L in pairs.items():
self.connect(p, s, L=L)
del self.__components[obj]
self._rebuild_trace_forest = True
elif isinstance(obj, (Space, Wire)):
# Remove any connections from this element
self.network.remove_edges_from(
(
(n[0].full_name, n[1].full_name)
for n in obj.all_internal_connections.values()
)
)
# Remove any signal nodes too
self.network.remove_nodes_from((n.full_name for n in obj.signal_nodes))
if isinstance(obj, Space):
if isinstance(obj.p1.i.component, Surface):
obj.p1.i.component._resymbolise_ABCDs()
if isinstance(obj.p2.o.component, Surface):
obj.p2.o.component._resymbolise_ABCDs()
elif obj in self.detectors:
del self.__detectors[obj]
elif obj in self.__cavities or obj in self.__gausses.values():
args = ("order", "disable", "enable_only")
for arg in args:
thing = self.__sim_trace_config[arg]
if thing is not None:
if obj in thing:
thing.remove(obj)
elif obj.name in thing:
thing.remove(obj.name)
if obj in self.__trace_order:
self.__trace_order.remove(obj)
if obj in self.__cavities:
del self.__cavities[obj]
elif obj in self.__gausses.values():
del self.__gausses[obj.node]
self._rebuild_trace_forest = True
elif obj in self.__locks:
del self.__locks[obj]
elif obj in self.__dofs:
del self.__dofs[obj]
elif isinstance(obj, ReadoutDetectorOutput):
self.network.remove_nodes_from(
(n.full_name for n in obj.readout.signal_nodes)
)
self._rebuild_trace_forest = True
else:
raise Exception(
"Element with name {} not in this model".format(obj.name)
)
if hasattr(obj, "_on_remove"):
obj._on_remove()
obj._set_model(None)
del self.__elements[obj.name]
# Remove element from any namespaces
for namespace in obj._namespace:
parent = self
for _ in namespace.split("."):
if len(_) > 0:
if hasattr(parent, _):
parent = getattr(parent, _)
delattr(parent, obj.name)
else:
raise TypeError(
"Object {} not recongised as a Finesse ModelElement.".format(obj)
)
[docs] def get(self, attr):
"""Get an attribute of the model using a string path representation like
`l1.p1.o.q`. If a :class:`ModelElement`, :class:`Node`, or a :class:`Port` is
given it will try to return the equivalent object in this model.
Parameters
----------
attr : [str | ModelElement | Node | Port]
An object to get from the model. Could be a generic string, or
Examples
--------
Parse a simple model and extract the laser power model parameter:
>>> import finesse
>>> kat = finesse.Model()
>>> kat.parse('''
... l l1 P=2
... s s1 l1.p1 m1.p1
... m m1 R=0.5 T=0.5
... pd Pr m1.p1
... pd Pt m1.p2
... ''')
>>> kat.get("l1.P")
<l1.P=2.0 @ 0x11aa56588>
See Also
--------
:method:`Model.get_element`
"""
if isinstance(attr, str):
return self._reduce_model_path(attr.strip().split("."))
elif isinstance(attr, ModelElement):
return self.get_element(attr)
elif hasattr(attr, "full_name"):
return self.get(attr.full_name)
elif hasattr(attr, "name"):
return self.get(attr.name)
else:
raise FinesseException(
f"model.get() should be provided with a str, ModelElement, Node, or Port, or some object that has a name or full_name attribute. Not {repr(attr)} ({type(attr)})"
)
[docs] @deprecated(reason="Use `Model.get`.")
def reduce_get_attr(self, attr):
return self.get(attr)
[docs] def set(self, attr, value):
"""Set an attribute of the model using a string path representation like
`l1.p1.o.q`."""
attrs = attr.split(".")
# Set the final attribute.
setattr(
self._reduce_model_path(attrs[:-1]),
attrs[-1],
value,
)
[docs] @deprecated(reason="Use `Model.set`.")
def reduce_set_attr(self, attr, value):
return self.set(attr, value)
def _reduce_model_path(
self,
attrs: list[str],
check_namespaces: bool = True,
) -> Any:
"""Recursively follow the attribute names in `attrs` by calling `getattr`,
starting at this model. Only meant to find object attributes, like `s1.p1.o`,
not class attributes like `parse`, `__dict__` etcetera.
Parameters
----------
attrs : list[str]
List of attribute names describing a model path, e.g. `l1.P` as `['l1', 'P']
check_namespaces: bool
Whether to check namespaces such as `.spaces` or `.wires`. Defaults to True
Returns
-------
Any
The resolved attribute
Raises
------
ModelClassAttributeError
When the model path resolves to a class attribute that is not a property
ModelMissingAttributeError
When the model path fails to resolve
"""
targets = [self]
if check_namespaces:
# we check the namespaces first, since the model is the most likely target
# and a missing attribute on the model produces the most helpful suggestions
# https://gitlab.com/ifosim/finesse/finesse3/-/issues/622
targets = self._get_namespaces() + targets
orig_attrs = deepcopy(attrs)
while len(targets):
resolved_attrs = []
target = targets.pop(0)
attrs = deepcopy(orig_attrs)
while len(attrs):
attr_name = attrs.pop(0)
try:
attribute = getattr(target, attr_name)
try:
class_attr = getattr(type(target), attr_name)
if not isinstance(class_attr, property):
raise ModelClassAttributeError(
target, resolved_attrs, attr_name
)
except AttributeError:
pass
if len(attrs):
target = attribute
else:
return attribute
except AttributeError:
if not len(targets):
raise ModelMissingAttributeError(
target, resolved_attrs, attr_name
)
resolved_attrs.append(attr_name)
def _get_namespace_paths(self) -> OrderedSet[str]:
# namespaces are not really documented, but every ModelElement has a
# '_namespaces' attribute. This is (by convention) a tuple of strings
# starting with a '.', like '(".", ".spaces"). This tells the Model class
# to save the ModelElement under these namespaces, creating "Freezable"
# objects as parents where necessary.
namespace_paths: OrderedSet[str] = OrderedSet()
for element in self.__elements.values():
assert isinstance(element, ModelElement)
namespace_paths |= OrderedSet(element._namespace)
if "." in namespace_paths:
namespace_paths.remove(".")
return namespace_paths
def _get_namespaces(self) -> list[Freezable]:
namespaces = []
for namespace in sorted(self._get_namespace_paths()):
if namespace.startswith("."):
namespace = namespace[1:]
namespaces.append(reduce(getattr, namespace.split("."), self))
return namespaces
[docs] @locked_when_built
def add(self, obj, *, unremovable=False):
"""Adds an element (or sequence of elements) to the model - these can be
:class:`.ModelElement` sub-class instances.
When the object is added, an attribute defined by `obj.name` is set within
the model allowing access to the object just added via `model.obj_name` where
`obj_name = obj.name`.
Parameters
----------
obj : Sub-class of :class:`.ModelElement` (or sequence of)
The object(s) to add to the model.
unremovable : bool, optional
When True, this object will not be able to be removed from this model
Returns
-------
element : ModelElement
The object that was added
Raises
------
Exception
If the matrix has already been built, the component has already
been added to the model or `obj` is not of a valid type.
"""
if self.__lock_model_change:
raise FinesseException("Model is locked and cannot be added or removed to.")
if is_iterable(obj):
return [self.add(o) for o in obj]
try:
if obj._model is not None:
raise FinesseException(
f"Element {obj.name} already thinks it is attached to a different model"
)
except ComponentNotConnected:
pass
if obj.name in self.__elements:
raise FinesseException(
f"An element with the name {obj.name} is already present"
f" in the model ({self.__elements[obj.name]})"
)
if obj._unique_element:
if len(self.get_elements_of_type(type(obj))) > 0:
raise FinesseException(
f"An element with type {type(obj)} has already been added to the model"
)
assert isinstance(obj, ModelElement)
obj._set_model(self)
add_to_elements = True
if isinstance(obj, Space):
for node in obj.nodes.values():
self.__add_node_to_graph(node, obj)
for key in obj._registered_connections:
From, To = obj._registered_connections[key]
From_name, To_name = obj._registered_connections[key]
From = obj.nodes[From_name]
To = obj.nodes[To_name]
self.__add_connection_to_graph(key, From, To, obj)
# Need to re-calculate symbolic ABCD matrices for connected
# surfaces now that refractive index symbols are different
if isinstance(obj.p1.i.component, Surface):
obj.p1.i.component._resymbolise_ABCDs()
if isinstance(obj.p2.o.component, Surface):
obj.p2.o.component._resymbolise_ABCDs()
elif isinstance(obj, Wire):
# Wires only have one connection each
self.__add_connection_to_graph("WIRE", obj.nodeA, obj.nodeB, obj)
elif isinstance(obj, detectors.Detector):
# Tell component to associate itself with this model
if obj.name in self.__detectors:
raise FinesseException(
f"Detector with name {obj.name} already added to this model"
)
if obj.node is not None and obj.node._model != self:
raise FinesseException(
f"The node of detector {obj.name}, {obj.node}, is not part of {self!r}"
)
elif isinstance(obj, detectors.CavityPropertyDetector):
obj._set_cavity()
elif isinstance(obj, detectors.Gouy):
obj._lookup_spaces()
self.__detectors[obj] = len(self.__detectors)
# If the detector needs a modal basis defined then
# switch on modes if not modal already
if obj.needs_trace:
if not self.is_modal:
self.modes(maxtem=0)
elif isinstance(obj, Cavity):
if obj.name in self.__cavities:
raise Exception(f"cavity {repr(obj.name)} already added to this model")
self.__cavities[obj] = len(self.__cavities)
# compute all the cavity properties (including path determination)
obj.initialise()
self.__insert_trace_dependency(obj)
if not obj.is_stable:
warn(
f"cavity {repr(obj.name)} added to the model is unstable",
CavityUnstableWarning,
)
# Turn on HOMs if model is still plane-wave
if not self.is_modal:
self.modes(maxtem=0)
elif isinstance(obj, Connector):
if obj.name in self.__components:
raise Exception(f"Element {repr(obj.name)} already added to this model")
for _ in obj.nodes.values():
self.__add_node_to_graph(_, obj)
for key in obj._registered_connections:
From_name, To_name = obj._registered_connections[key]
From = obj.nodes[From_name]
To = obj.nodes[To_name]
self.__add_connection_to_graph(key, From, To, obj)
self.__components[obj] = len(self.__components)
if isinstance(obj, FrequencyGenerator):
self._frequency_generators.append(obj)
if isinstance(obj, DegreeOfFreedom):
self.__dofs[obj] = len(self.__dofs)
elif isinstance(obj, Lock):
self.__locks[obj] = len(self.__locks)
elif isinstance(obj, Gauss):
obj.qx.wavelength = self.lambda0
obj.qy.wavelength = self.lambda0
space = obj.node.space
if space is not None:
nr = space.nr.value
else:
nr = 1.0
obj.qx.nr = nr
obj.qy.nr = nr
current_gauss = self.__gausses.get(obj.node)
if current_gauss is not None:
raise ValueError(
f"A Gauss object with name {current_gauss.name} already exists "
f"at the node {obj.node.full_name}"
)
self.__gausses[obj.node] = obj
self.__insert_trace_dependency(obj)
# Turn on HOMs if model is still plane-wave
if not self.is_modal:
self.modes(maxtem=0)
elif isinstance(obj, Variable):
# Variables are not normal model elements in this regard as they
# simply add a new parameter to the model but the elemnt isn't actually
# saved anymore
obj._add_to_model_namespace = False
add_to_elements = False
return self.add_parameter(
obj.name,
obj.value,
description=obj.description,
units=obj.units,
is_geometric=obj.is_geometric,
changeable_during_simulation=obj.changeable_during_simulation,
dtype=float,
)
elif isinstance(obj, ModelElement):
# Model elements come in a variety of forms, which are dealt with above
# if the object isn't any of these the bare minimum contract is that we
# tell it to associate itself with this model and call _on_add to let it
# do some initialisation if necessary
pass
else:
raise Exception("Could not add object {}".format(str(obj)))
if obj._add_to_model_namespace:
# If the elment requests asks it will be added to the model namespace
if hasattr(self, obj.name):
raise Exception(
f"Not a valid {obj.__class__.__name__} name. An attribute "
f"called `{obj.name}` already exists in the Model"
)
# Can add objects to multiple namespaces for collecting
# together like components as well as easy access
assert isinstance(obj._namespace, tuple)
for namespace in obj._namespace:
parent = self
for _ in namespace.split("."):
if len(_) > 0:
if hasattr(parent, _):
curr = getattr(parent, _)
else:
curr = Freezable()
parent._unfreeze()
setattr(parent, _, curr)
parent._freeze()
parent = curr
parent._unfreeze()
setattr(parent, obj.name, obj)
parent._freeze()
if hasattr(obj, "_on_add"):
obj._on_add(self)
if hasattr(obj, "_on_frequency_change"):
self.__frequency_change_callbacks.append(obj._on_frequency_change)
if add_to_elements:
self.__elements[obj.name] = obj
if unremovable:
self.__not_removable.add(obj)
# All model elements should be freezable so that users don't get confused
# when they misspell certain attributes and set to them, such as mirror.r
obj._freeze()
# Notify that the TraceForest needs rebuilding on next beam_trace call
# when adding an object which can change the forest structure
self._rebuild_trace_forest = isinstance(obj, (Connector, TraceDependency))
return obj
@locked_when_built
def __add_node_to_graph(self, node, owner):
if not self.network.has_node(node.full_name):
ref = node.full_name
self.network.add_node(
ref, weakref=weakref.ref(node), owner=weakref.ref(owner)
)
self.network.nodes[ref]["type"] = node.type
if node.type == NodeType.OPTICAL:
self.network.nodes[ref]["optical"] = True
elif node.type == NodeType.MECHANICAL:
self.network.nodes[ref]["mechanical"] = True
elif node.type == NodeType.ELECTRICAL:
self.network.nodes[ref]["electrical"] = True
else:
raise Exception("Type unhandled")
elif not owner._borrows_nodes and node.type == NodeType.OPTICAL:
raise Exception("Node {} already added".format(node))
@locked_when_built
def __add_connection_to_graph(self, name, From, To, owner):
for _ in [From, To]:
if not self.network.has_node(_.full_name):
raise Exception("Node {} hasn't been added".format(_))
self.network.add_edge(
From.full_name,
To.full_name,
name=name,
in_ref=weakref.ref(From),
out_ref=weakref.ref(To),
owner=weakref.ref(owner),
length=1,
coupling_type=owner.coupling_type(From, To),
internal=From is To, # if edge is to the same element
)
[docs] @locked_when_built
def parse(self, text, spec=None):
"""Parses kat script and adds the resulting objects to the model.
Parameters
----------
text : :py:class:`str`
The kat script to parse.
spec : :class:`.KatSpec`, optional
The language specification to use. Defaults to the shared :class:`.KatSpec`
instance.
See Also
--------
parse_file : Parse script file.
parse_legacy : Parse Finesse 2 kat script.
parse_legacy_file : Parse Finesse 2 kat script file.
"""
from .script import parse
parse(text, model=self, spec=spec)
[docs] @locked_when_built
def parse_file(self, path, spec=None):
"""Parses kat script from a file and adds the resulting objects to the model.
Parameters
----------
path : str, :class:`pathlib.Path`, or file-like
The path or file object to read kat script from. If an open file object is
passed, it will be read from and left open. If a path is passed, it will be
opened, read from, then closed.
spec : :class:`.KatSpec`, optional
The language specification to use. Defaults to the shared :class:`.KatSpec`
instance.
See Also
--------
parse : Parse script.
parse_legacy : Parse Finesse 2 kat script.
parse_legacy_file : Parse Finesse 2 kat script file.
"""
from .script import parse_file
parse_file(path, model=self, spec=spec)
[docs] @locked_when_built
def parse_legacy(self, text):
"""Parses legacy (Finesse 2) kat script and adds the resulting objects to the
model.
Parameters
----------
text : :py:class:`str`
The kat script to parse.
See Also
--------
parse_legacy_file : Parse Finesse 2 kat script file.
parse : Parse Finesse 3 kat script.
parse_file : Parse Finesse 3 kat script file.
"""
from .script import parse_legacy
parse_legacy(text, model=self)
[docs] @locked_when_built
def parse_legacy_file(self, path):
"""Parses legacy (Finesse 2) kat script from a file and adds the resulting
objects to the model.
Parameters
----------
path : str, :class:`pathlib.Path`, or file-like
The path or file object to read kat script from. If an open file object is
passed, it will be read from and left open. If a path is passed, it will be
opened, read from, then closed.
See Also
--------
parse_legacy : Parse Finesse 2 kat script.
parse : Parse Finesse 3 kat script.
parse_file : Parse Finesse 3 kat script file.
"""
from .script import parse_legacy_file
parse_legacy_file(path, model=self)
[docs] def unparse(self, inplace=True):
"""Serialise the model to kat script.
Returns
-------
str
The generated kat script.
"""
from .script import unparse
return unparse(self, ref_graph=self.syntax_graph if inplace else None)
[docs] def unparse_file(self, path, inplace=True):
"""Serialise the model to kat script in a file.
Parameters
----------
path : str, :class:`pathlib.Path`, or file-like
The path or file object to write kat script to. If an open file object is
passed, it will be written to and left open. If a path is passed, it will be
opened, written to, then closed.
"""
from .script import unparse_file
unparse_file(path, self, ref_graph=self.syntax_graph if inplace else None)
[docs] @locked_when_built
def merge(
self, other, from_comp, from_port, to_comp, to_port, name=None, L=0, nr=1
):
"""Merges the model `other` with this model using a connection at the specified
ports.
.. note::
Upon completion of this method call the `Model` instance `other` will
be invalidated. All components and nodes within `other` will be associated
with **only** this model.
Parameters
----------
other : :class:`.Model`
A model configuration to merge into this model instance.
from_comp : Sub-class of :class:`.Connector`
The component to start a connection from.
from_port : int
Port of `from_comp` to initiate the connection from.
to_comp : Sub-class of :class:`.Connector`
The component to bridge the connection to.
to_port : int
Port of `to_comp` to bridge the connection to.
name : str
Name of connecting :class:`.Space` instance.
L : float
Length of the connecting space.
nr : float
Index of refraction of the connecting space.
"""
self._unfreeze()
raise NotImplementedError()
self._settings.homs_view += other.homs
# combine components/detectors
for node in list(other.network.nodes):
try:
self.add(node.component)
except Exception:
continue
# combine spaces
for edge_tuple in list(other.network.edges):
for edge in edge_tuple:
try:
self.add(edge.space)
except Exception:
continue
# combine cavities
for cav in other.cavities:
self.add(cav)
# check self.__opt_net_view correctly points to correct new graph if this
# is ever reused
self.__network = nx.compose(self.__network, other.network)
self.connect(from_comp, from_port, to_comp, to_port, name=name, L=L, nr=nr)
self._freeze()
[docs] @locked_when_built
def add_frequency(self, freq):
"""Add a specific optical carrier frequency to the model description.
Parameters
----------
:class:`float` or :class:`.Frequency`
The frequency to add.
"""
if freq in self.__frequencies:
warn(f"frequency {repr(freq.name)} already added to model")
else:
self.__frequencies.add(freq)
[docs] def get_frequency_object(self, frequency_value):
if frequency_value in self.__freq_map:
return self.__freq_map[frequency_value][0]
else:
return None
[docs] @locked_when_built
def chain(self, *args, start=None, port=None):
"""Utility function for connecting multiple connectable objects in a sequential
list together. Between each item the connection details can be specified, such
as length or refractive index. This function also adds the elements to the model
and returns those as a tuple to for the user to store if required.
Examples
--------
Make a quick 1m cavity and store the added components into variables::
l1, m1, m2 = ifo.chain(Laser('l1'), Mirror('m1'), 1, Mirror('m2'))
Or be more specific about connection parameters by providing a dictionary. This
dictionary is passed to the :meth:`Model.connect` method as kwargs so see there
for which options you can specify. For optical connections we can set lengths
and refractive index of the space using a dictionary::
ifo.chain(
Laser('l1'),
Mirror('AR'),
{'L':1e-2, 'nr':1.45},
Mirror('HR')
)
In the above case a auto-generated space name will be made. If you want to
explicitly set a name use `{'L':1e-2, 'nr':1.45, 'name':"my_space"},`
The starting point of the chain can be specfied for more complicated setups like
a Michelson::
ifo = Model()
ifo.chain(Laser('lsr'), Beamsplitter('bs'))
# connecting YARM to BS
ifo.chain(
1,
Mirror('itmy'),
1,
Mirror('etmy'),
start=ifo.bs,
port=2,
)
# connecting XARM to BS
ifo.chain(
1,
Mirror('itmx'),
1,
Mirror('etmx'),
start=ifo.bs,
port=3,
)
Parameters
----------
start: component, optional
This is the component to start the chain from. If None, then a completely
new chain of components is generated.
port: int, optional (required if `start` defined)
The port number at the `start` component provided to start the chain from.
This must be a free unconnected port at the `start` component or an
exception will be thrown.
Returns
-------
tuple
A tuple containing the objects added. The `start` component is never
returned.
"""
connectors = []
connections = []
was_prev_connector = False
if start is not None:
if start not in self.components:
raise Exception("Component %s is not in this model" % start)
if port is None:
raise Exception(
"Port keyword argument must also be"
"provided if specifying a start for"
"the chain."
)
connectors.append(start)
was_prev_connector = True
for i, item in enumerate(args):
if isinstance(item, Space) or isinstance(item, Wire):
connections.append({"connector": item})
was_prev_connector = False
elif isinstance(item, Connector):
if was_prev_connector:
if i == 0 and start is not None:
connections.append({"port": port})
else:
connections.append({})
connectors.append(item)
was_prev_connector = True
self.add(item)
elif isinstance(item, Number):
connections.append({"L": item})
if i == 0 and start is not None:
connections[-1]["port"] = port
was_prev_connector = False
else:
connections.append(item)
was_prev_connector = False
pairs = list(pairwise(connectors))
# There should always be an equal number of connections
# for each pair of components, otherwise we are missing something...
assert len(pairs) == len(connections)
for (a, b), conn in zip(pairs, connections):
if "port" in conn:
port = conn["port"]
del conn["port"]
else:
if len(a.optical_nodes) == 2:
port = a.p1
elif len(a.optical_nodes) == 4:
port = a.p2
elif len(a.optical_nodes) > 4:
break
else:
raise Exception("Unhandled: " + str(a, len(a.nodes)))
if type(port) is int:
port = a.ports[port - 1]
self.connect(port, b.p1, **conn)
# Don't return the starting point the user specified
if start is None:
return connectors
else:
return connectors[1:]
[docs] @locked_when_built
def link(self, *args, verbose=False):
"""Connect multiple components together in one quick command. In many models a
collection of components just need to be connected together without having to
specify each port exactly. This command accepts multiple components as
arguments, each is connected to the next. Interally the `link` command is
creating spaces and wires between components but giving them automatically
generated names. Therefore, the `link` command is useful when you are not
interested in what the spaces or wires are called, which is often the case in
readout paths or signal feedback loops.
This command will try to connect components in the "obvious" way. For
example, a collection of two-port optical components will be connected
one after another, the second port of the first item connected to the
first port of the second component, etc.
Explicit ports can also be provided if exact connections are required.
For example, at a beamsplitter, if you want to link through on
transmission then use `..., BS.p1, BS.p3, ...`. Using just `BS` here
would result in using the first and second ports, a reflection.
Links can contain a mix of optical and signal nodes. When going from
optical to signal nodes they must be specified verbosely. For example,
a DC readout component `PD`, you would need to specify
`..., PD, PD.DC, ...`.
Parameters
----------
*args : [Components | float | Port]
Separate arguments of either components or ports. A float value
will create a space or wire with the provided length or time delay.
verbose : bool, optional
Print out what the link command is doing
Examples
--------
Here we make a linear optical cavity
>>> model = finesse.Model()
>>> model.parse('''
... l l1
... m ITM T=0.014 R=1-ITM.T
... m ETM T=50u R=1-ETM.T
... bs BS R=0.5 T=0.5
... # A local readout on tranmission of the cavity
... l lo
... readout_dc TRANS
... fsig(1)
... link(l1, ITM, 4000, ETM, BS.p1, BS.p2, TRANS, verbose=True)
... link(lo, BS.p4)
... ''')
Flagging the `verbose` argument will result in the linking process being
printed for further clarification of what it is doing. Multiple links can
be done to specify separate paths as is done above for the connection
between `lo` and `BS`.
The auto-generated spaces can be seen with:
>>> print(list(model.spaces.items()))
[('l1_p1__ITM_p1', <'l1_p1__ITM_p1' @ 0x7f98da6ab760 (Space)>),
('ITM_p2__ETM_p1', <'ITM_p2__ETM_p1' @ 0x7f98da6b8ac0 (Space)>),
('ETM_p2__BS_p1', <'ETM_p2__BS_p1' @ 0x7f98da6b8a90 (Space)>),
('BS_p2__TRANS_p1', <'BS_p2__TRANS_p1' @ 0x7f98db1f37c0 (Space)>),
('lo_p1__BS_p4', <'lo_p1__BS_p4' @ 0x7f98da6ab4c0 (Space)>)]
Links can also be used to do quick feedback loops and connections. For
example, the small signal DC output of the readout above could be connected
to the laser amplitude modulation using:
>>> link(l1, ITM, 4000, ETM, BS, TRANS, TRANS.DC, l1.amp)
Similarly, the auto-generated wires can be seen with:
>>> print(list(model.wires.items()))
[('TRANS_DC__l1_amp', <'TRANS_DC__l1_amp' @ 0x7f98da6d8ac0 (Wire)>)]
"""
def grab_between(predicate, args):
"""Yields a pair of objects with any objects matching the predicate in
between."""
items = []
between = []
for x in args:
if type(x) is str:
try:
x = self.get_element(x)
except KeyError:
x = self.get(x)
if predicate(x):
items.append(x)
else:
between.append(x)
if len(items) == 2:
yield tuple(items), tuple(between)
items.pop(0)
between.clear()
def get_component(obj):
if isinstance(obj, ModelElement):
return obj
else:
return obj.component
items = grab_between(lambda x: isinstance(x, (ModelElement, Port, Node)), args)
for objs, details in items:
comps = [get_component(_) for _ in objs]
if verbose:
print("Connecting", " to ".join((_.name for _ in comps)))
if all(comps[0] is _ for _ in comps):
if verbose:
print(
f"{objs[0]!r} and {objs[1]!r} are of the same element so skipping this connection"
)
else:
self.connect(*objs, *details, verbose=verbose)
[docs] def get_open_ports(self):
"""Return all optical ports that are not connected to a space."""
open_ports = {}
for node in self.optical_nodes:
if node.space is None: # Not connected to anything = open port
open_ports[node.port] = None
return tuple(open_ports.keys())
[docs] def get_elements_connected_to(self, element):
"""Returns a set of elements that `element` is connected to.
Parameters
----------
element : str or :class:.`Element`
Element to query connections of
"""
element = self.get_element(element)
edges = []
for node in element.nodes:
for edge in self.network.in_edges(node, data=True):
if edge[2]["owner"]() is not element:
edges.append(edge)
for edge in self.network.out_edges(node, data=True):
if edge[2]["owner"]() is not element:
edges.append(edge)
# spaces and wires connecting this element to something
connected_to = OrderedSet()
for _ in edges:
connected_to.add(_[2]["owner"]())
return connected_to
[docs] @locked_when_built
def connect(
self,
A,
B,
L=0,
nr=1,
gain=1,
*,
delay=None,
name=None,
verbose=False,
connector=None,
):
"""Connects two ports in a model together. The ports should be of the same type,
e.g. both optical ports.
This method will also accept components from the user, in such cases it
will loop through the ports and use the first one in `.ports` that is
currently unconnected.
As `connect` will try to be somewhat smart in guessing what the user is
trying to connect, use `verbose=True` to print what is actually
getting connected.
Parameters
----------
A : :class:`.Connector` or :class:`.Port`
Component to connect
B : :class:`.Connector` or :class:`.Port`
Other component to connect
L : float, optional
Length of newly created :class:`.Space` or :class:`.Wire`
instance. If connecting electronics, L will be treated as
a delay in seconds
nr : float, optional
Index of refraction of newly created :class:`.Space`.
gain : float, symbol, optional
Gain of a wire connection for simply scaling between two signals
delay : float, optional
Delay time for electrical connections.
name : str, optional
Name of newly created :class:`.Space` or :class:`.Wire` instance.
verbose : bool, optional
When True, the actual connections being made will be printed.
Raises
------
Exception
If matrix has already been built, either of `compA` or
`compB` are not present in the model, either of `portA` or
`portB` are already connected or either of `portA` or
`portB` are not valid options at the specified component(s).
"""
ports = [None, None]
if isinstance(A, str):
A = self.get(A)
if isinstance(B, str):
B = self.get(B)
for item in [A, B]:
# Check if these have been added to a model, if not add to this
# if item._model is None:
try:
_ = item._model
except ComponentNotConnected:
if hasattr(item, "component"):
# In case some port or node has been provided instead
# get the actual component to add
self.add(item.component)
else:
self.add(item)
def signal_ports(obj):
return tuple(
p
for p in obj.ports
if p.type in (NodeType.MECHANICAL, NodeType.ELECTRICAL)
)
def get_input_port(ports):
if ports[0].nodes[0].direction == NodeDirection.INPUT:
rtn = ports[0]
else:
rtn = ports[1]
if verbose:
print(f"Selecting input port {rtn!r} from {ports}")
return rtn
def get_output_port(ports):
if ports[0].nodes[0].direction == NodeDirection.INPUT:
rtn = ports[1]
else:
rtn = ports[0]
if verbose:
print(f"Selecting output port {rtn!r} from {ports}")
return rtn
def is_electronic_component(obj):
return all(p.type == NodeType.ELECTRICAL for p in obj.ports)
def get_next_optical_port(obj):
rtn = None
for p in obj.ports:
if not p.is_connected and p.type == NodeType.OPTICAL:
rtn = p
break
if rtn is None:
raise FinesseException(
f"No unconnected optical ports left at {obj.name} to automatically choose from. Please specify an electrical or mechanical one if that was your aim."
)
if verbose:
print(f"Selecting port {rtn!r} for {obj!r}")
return p
# Aim here is to try and be smart and accept some more user friendly
# inputs rather than always specifying the port name.
for i, obj in enumerate((A, B)):
if isinstance(obj, Port): # User gave us a port so just use that
ports[i] = obj
elif isinstance(obj, SignalNode):
ports[i] = obj
elif isinstance(obj, ModelElement):
Np = len(obj.ports)
if Np == 1:
# just select the first port as that's our only option
ports[i] = obj.ports[0]
elif Np > 1:
# multiple ports! So which one to choose?
if i == 0:
# If we are the first argument...
if is_electronic_component(obj):
if Np == 2:
# if the first component is a two port electronics
# grab the output port
ports[i] = get_output_port(obj.ports)
else:
raise Exception(
f"Must specify a port when connecting {A!r} as it has more than 1 port."
)
else:
ports[i] = get_next_optical_port(obj)
else:
# From the A object try and guess what to look for
# on the second B object.
ptype = ports[0].type
if ptype == NodeType.OPTICAL:
# connecting from an optical port, so find the frst optical
# port that isn't connected to anything else
ports[i] = get_next_optical_port(obj)
else: # must be elec or mech signal node
# connecting from an elec port, now find an input port
sig_ports = signal_ports(obj)
Nsp = len(sig_ports)
if Nsp == 1: # just select the only option we have
ports[i] = sig_ports[0]
elif Nsp == 2:
ports[i] = get_input_port(sig_ports)
else:
raise FinesseException(
f"Too many signal ports to choose from at {obj!r} to automatically choose from. Specify one of {sig_ports}"
)
else:
raise Exception("Model element {} has no ports".format(obj.name))
elif isinstance(obj, OpticalNode):
raise FinesseException(
f"Optical node {obj!r} cannot be explicitly connected to. Use its port instead `{obj.port.full_name}`."
)
else:
raise FinesseException(f"Input {obj!r} cannot be connected")
if connector is None:
try:
if all(p.type == NodeType.OPTICAL for p in ports):
if delay is not None:
raise Exception("Can't set delay for an optical space")
connector = Space(name, *ports, L=L, nr=nr)
elif all(isinstance(p, SignalNode) for p in ports):
# User specified signal nodes so just wire them up directly
connector = Wire(
name, *ports, delay=(delay if delay is None else L), gain=gain
)
elif (
ports[0].type == NodeType.ELECTRICAL
or ports[0].type == NodeType.MECHANICAL
):
if nr != 1:
raise Exception(
"Can't set refractive index for an electronic connection"
)
if delay is None:
delay = L
connector = Wire(name, *ports, delay=delay, gain=gain)
else:
raise FinesseException(
f"Do not know how to connect {ports[0]!r} to {ports[1]!r}"
)
except Exception as ex:
raise FinesseException(
f"Whilst trying to connect {ports[0]!r} to {ports[1]!r}, the following exception occurred:\n{ex}"
)
else:
connector.connect(*ports)
self.add(connector)
[docs] @locked_when_built
def disconnect(self, A, B):
"""Disconnects two elements `A` and `B`."""
[docs] def get_network(
self, network_type: str | NetworkType = NetworkType.FULL, add_edge_info=False
) -> nx.Graph:
"""Get specified network.
Parameters
----------
network_type : str, optional
The network type to export: full (nodes, ports and components), "components" (just
components), or "optical" (the optical subnetwork).
Returns
-------
:class:`networkx.DiGraph`
The network.
Raises
------
ValueError
If the specified network_type is unknown.
"""
if isinstance(network_type, str):
network_type = NetworkType(network_type.casefold())
return network_type.get_network(self, add_edge_info)
[docs] def display_signal_blockdiagram(self, *nodes, **kwargs):
"""Displays a block diagram of the signal paths in this model. It will only
contain electrical and mechanical connections made. Optical couplings are not
shown.
Parameters
----------
remove_mechanical_to_mechanical : bool, optional
If true, mechanical to mechanical node edges are removed. On by
default as the result block diagram is complicated.
*nodes : :class:`Node`
Nodes to show the path of
"""
from finesse.utilities.blockdiag import display_loops_blockdiag
display_loops_blockdiag(self, *nodes, **kwargs)
[docs] def plot_graph(
self,
layout: str = "neato",
graphviz=True,
network_type: str | NetworkType = NetworkType.COMPONENT,
root: str | ModelElement | Node | None = None,
show_detectors: bool = False,
radius: int | None = None,
directed: bool = False,
**kwargs,
):
"""Plot the node network. See also :ref:`model_visualization`
Parameters
----------
layout : str, optional
The networkx plotting layout engine, see NetworkX manual for more details.
Choose from:
circular, fruchterman_reingold, kamada_kawai, multipartite,
planar, random, shell, spectral, spiral, spring, neato, dot,
fdp, sfdp, or circo
graphviz : bool, optional
Whether to use the graphviz library for better node layouts
(needs optional dependency), by default True
network_type : str | NetworkType, optional
Which network to plot, can be one of 'optical', 'component', 'full',
by default NetworkType.COMPONENT
root : str | ModelElement | Node | None, optional
In combination with ``radius``, the root node of the graph to use for
distance based filtering, by default ``None``. When ``network_type`` is
``components``, ``None`` will default to the first
:class:`.finesse.components.laser.Laser` found in the model.
show_detectors : bool, optional
Whether to add detectors to the graph, by default False
radius : int >= 1 | None, optional
Must be used in combination with ``root``, only include nodes of the network
that are ``radius`` or less edges away from the root node, by default None,
meaning that no nodes are filtered out.
directed : bool, optional
Whether to use directed distance-based filtering, by default False. If set
to True, will only include outgoing edges from the root node. See also
the ``undirected`` argument of :func:`networkx.generators.ego.ego_graph`
Notes
-----
Uses :func:`networkx.generators.ego.ego_graph` for the distance-based filtering.
"""
from .plotting import plot_graph
if (
NetworkType(network_type) is not NetworkType.COMPONENT
and root is None
and radius is not None
):
raise ValueError(
"Need to specify a root if `network_type` is not "
f"'{NetworkType.COMPONENT}' and `radius` is not None"
)
if graphviz and not has_pygraphviz():
warnings.warn(
"Graphviz plot requested, but graphviz is not available."
"Reverting to networkx.",
stacklevel=2,
)
graphviz = False
if not has_pygraphviz() and layout in ["neato", "dot", "fdp", "sfdp", "circo"]:
warnings.warn(
f"Requested layout {layout} not available in networkx, reverting to"
" spring layout.",
stacklevel=2,
)
layout = "spring"
network_filter = NetworkType(network_type).filter_class(
model=self,
root=root,
radius=radius,
undirected=not directed,
add_detectors=show_detectors,
)
return plot_graph(
network_filter.run(), layout=layout, graphviz=graphviz, **kwargs
)
def __toggle_param_locks(self, state):
"""Togglin."""
LOGGER.info(f"Toggle parameter lock to {state}")
for k in self.__elements:
el = self.__elements[k]
for p in el._params:
# if this is marked as tunable then don't lock it
if p.is_tunable and state is True:
p._locked = False
LOGGER.info(f"{repr(p)} is not being locked")
else:
p._locked = state
[docs] def get_changing_edges_elements(self):
"""
Returns
-------
tuple(set of (node1-name, node2-name) edges, dict(weakref(element):list))
Returns a list of the network edges that will be changing, further information
on the edge can be retreived directly from the model network. Also returned is
a dictionary of elements and which parameter is changing
"""
changing_elements = defaultdict(OrderedSet)
changing_edges = OrderedSet()
for _ in self.network.edges():
owner = self.network.edges[_]["owner"]
if owner() not in changing_elements:
for p in owner().parameters:
if p.is_changing:
changing_elements[owner].add(p)
changing_edges.add(_)
return changing_edges, changing_elements
[docs] def unbuild(self):
"""If a model has been built then this function undoes the process so the model
can be changed and rebuilt if required."""
if not self.is_built:
raise Exception("Model has not been built")
# To unfreeze a graph you have to rebuild it
self.__network = nx.DiGraph(self.__network)
# Need to make a new view too otherwise we miss new additions to the graph
self.__opt_net_view = make_optical_network_view(self)
self.__toggle_param_locks(False)
self.__is_built = False
self._on_unbuild() # fire event
[docs] @locked_when_built
def run(
self,
analysis=None,
return_state=False,
progress_bar=False,
simulation_type=None,
simulation_options=None,
):
"""Runs the current analysis set for this model. If no analysis has been set in
the model and the ``analysis`` argument is None, then this will run a
``Noxaxis()`` on the current model.
If a separate analysis has been provided with the `analysis` argument then
this will be run instead of what has been set to `model.analysis`.
Parameters
----------
analysis : [str, Action], optional
KatScript code for an analysis or an analysis object to run.
return_state : bool, optional
Whether to return the state of each model generated by this analysis.
progress_bar : bool, optional
Whether to show progress bars or not
Returns
-------
sol : Solution Object
Solution to the analysis being performed
states : objects, only when return_state == True
States generated by the analysis
Examples
--------
Run a model with the analysis specified in the original KatScript:
>>> import finesse
>>> model = finesse.Model()
>>> model.parse('''
... l l1
... pd P l1.p1.o
... ''')
>>> model.run("for(l1.P, [0, 1, 2, 3], print(l1.P))")
Or you can run a separate analysis:
>>> model.run("noxaxis()")
"""
from .analysis.actions import Noxaxis, Action
curr_analysis = self.analysis
if analysis is None:
# nothing has been set so use what is in the model or noxaxis if nothing
_analysis = self.analysis or Noxaxis()
elif isinstance(analysis, str):
# Katscript analysis requested
self.parse(analysis)
_analysis = self.analysis
elif isinstance(analysis, Action):
_analysis = analysis
else:
raise ValueError(f"Cannot handle analysis input `{analysis}`")
rtn = _analysis._run(
self,
return_state=return_state,
progress_bar=progress_bar,
simulation_type=simulation_type,
simulation_options=simulation_options,
)
self.analysis = curr_analysis
if not return_state:
s = rtn
else:
s, states = rtn
# Return first actual solution for something rather than base
# unless there's multiple children
while (type(s) is BaseSolution or type(s) is SeriesSolution) and len(
s.children
) == 1:
_s = s.children[0]
_s.parent = None
s.children.clear()
s = _s
if not return_state:
return s
else:
return s, states
[docs] def get_element(self, value):
"""Returns an element in this model that matches the requested value. This input
can be either a string name or an element that might be owned by another model.
In the latter case the `name` attribute will be extracted from the value and a
search done in this model for an equivalent element.
Parameters
----------
value : [str|`Element`]
Name or equivalently named `Element` object to extract from this
model.
Raises
------
`KeyError` when element cannot be found or `FinesseException` when the
input `value` cannot be used.
Examples
--------
>>> import finesse
>>> model = finesse.Model()
>>> model.parse('''
... l l1 P=1
... l l2 P=2
... ''')
>>> model.get_element('l1'), model.get_element('l2')
(<'l1' @ 0x122cf9fa0 (Laser)>, <'l2' @ 0x122cf9f40 (Laser)>)
Creating a copy of the model and getting elements will return elements
with the same name but different `id`.
>>> model2 = model.deepcopy()
>>> model2.get_element('l1'), model2.get_element('l2')
(<'l1' @ 0x122d35c10 (Laser)>, <'l2' @ 0x122d35df0 (Laser)>)
Now if we try and select `l1` using an element from a different model we
should get the correct element with name `l1` from that model
>>> model.get_element(model2.l1)
<'l1' @ 0x122cf9fa0 (Laser)>
>>> model2.get_element(model.l1)
<'l1' @ 0x122d35c10 (Laser)>
"""
if isinstance(value, str):
return self.elements[value]
elif hasattr(value, "name"):
return self.elements[value.name]
else:
raise FinesseException(f"Cannot get an element using the input {value}")
[docs] def get_elements_of_type(
self, *element_type: type | str
) -> tuple[ModelElement, ...]:
"""Extracts elements of a specific type from this model.
Parameters
----------
*element_type : type or sequence of types
The element type(s) to retrieve.
Returns
-------
tuple
The filtered results.
Examples
--------
>>> IFO.get_elements_of_type(finesse.components.Mirror)
(<'m2' @ 0x7ff81a50b6a0 (Mirror)>, <'m1' @ 0x7ff81a50be48 (Mirror)>)
>>> tuple(IFO.get_elements_of_type("Mirror"))
(<'m2' @ 0x7ff81a50b6a0 (Mirror)>, <'m1' @ 0x7ff81a50be48 (Mirror)>)
>>> IFO.get_elements_of_type(finesse.components.Mirror, finesse.components.Beamsplitter))
(<'m2' @ 0x7ff81a50b6a0 (Mirror)>, <'m1' @ 0x7ff81a50be48 (Mirror)>, <'bs1' @ 0x7ff81a50bf33 (Beamsplitter)>)
"""
# circular import
from finesse.script import KATSPEC
element_types = []
for el_type in element_type:
if isinstance(el_type, str):
element_types.append(KATSPEC.get_element_class(el_type))
elif isinstance(el_type, type):
element_types.append(el_type)
return tuple(
el for el in self.elements.values() if isinstance(el, tuple(element_types))
)
[docs] def get_active_signal_nodes(self):
"""Returns the electrical and mechanical nodes that are active in a model, i.e.
ones that need to be solved for because:
* they have both input and output edges
* have output edges and is a signal input
* is used by a detector
* has an input optical edge and some output edge
This could be more sophisticated and perhaps use the graph
in a more correct way. For example, this will not prune
some long line of electrical components connected to a
mechanical node that drives some optical field. Or in other
words, it will not determine if an input edge has an active
node on the other end.
Returns
-------
tuple of nodes
"""
active = OrderedSet()
for node in self.signal_nodes:
# can be some signal gen input
# or this node might be used as some output
is_active = (
node.has_signal_injection or len(node.used_in_detector_output) > 0
)
if not is_active:
full_name = node.full_name
# For a node to be potentially active it needs to have
# both input and output edges. If not then there will
# not be any information flowinging through it, as we're
# not injecting, etc. into it either
is_active |= (
self.network.in_degree(full_name) > 0
and self.network.out_degree(full_name) > 0
)
if is_active:
active.add(node)
# add nodes that wires will need
if hasattr(self, "wires"):
for w in self.wires:
active.add(w.nodeA)
active.add(w.nodeB)
return tuple(active)
def __pre_build_checks(self):
# TODO (sjr) Probably need different checks dependent upon what type
# of simulation is about to built and executed eventually
if not self.is_modal:
dets_req_trace = list(filter(lambda d: d.needs_trace, self.detectors))
if dets_req_trace:
warn(
f"Switching on modes (at maxtem = 0) as the model contains the "
f"following detectors which require a modal basis: "
f"{[d.name for d in dets_req_trace]}"
)
self.modes(maxtem=0)
expect_unstable_handle = ("auto", "mask", "abort")
unstable_handle = self.sim_trace_config.get("unstable_handling")
if unstable_handle not in expect_unstable_handle:
raise ValueError(
"Expected 'unstable_handling' entry of sim_trace_config to be one of "
f"{', '.join(expect_unstable_handle)}; but got {unstable_handle}."
)
if self._settings.phase_config.zero_k00:
if not np.all(self.homs[0] == [0, 0]):
raise RuntimeError(
"Model phase configuration is set up to zero HG00 -> HG00 "
"coupling coefficients but the HG00 mode is not included!"
)
@locked_when_built
def _build(self, frequencies=None, simulation_type=None, simulation_options=None):
"""
NOTE: Consider using :function:`finesse.model.Model.built()`
instead of this method.
This is the first step required to run a
simulation of the model. At this stage the layout and connections
of the model must be finalised so that the underlying sparse matrix
can be allocated and laid out. If this changes the model must be
rebuilt.
What this method returns are Simulation objects. These are the
matrix representation of the model which are used to generate
numerical outputs. The Simulation and Model objects are linked
together, changing the Model parameters will result in the
Simulation objects using the new values when they are solved.
A custom list of carrier frequencies can be specfied to run the simulations
with. Audio frequencies will be generated from this list separately by the code. `None` will
result in the default algorithm computing the required frequency bins,
:func:`.frequency.generate_frequency_list`, which can be
called by the user and added to if additional frequency bins are required.
Parameters
----------
frequencies : list of :class:`.Symbol`
Custom list of carrier frequencies can be specfied to run the simulations with.
simulation_options : dict
Options for the simulation to run
Returns
-------
sim : object
A single simulation object is returned that should be used to perform
simulations with this model.
Raises
------
Exception
If the model is in a built state already. It must be destroyed
first before it can be built again.
"""
if frequencies:
raise NotImplementedError("Custom frequencies not implemented yet")
self.__pre_build_checks()
self._on_pre_build()
nx.freeze(self.network)
self.__is_built = True
self.__toggle_param_locks(True)
if simulation_type is None:
from finesse.simulations.sparse.simulation import SparseMatrixSimulation
from finesse.simulations.sparse.KLU import KLUSolver
simulation_type = SparseMatrixSimulation
defaults = {
"carrier_solver": KLUSolver,
"signal_solver": KLUSolver,
}
if simulation_options is not None:
defaults.update(simulation_options)
simulation_options = defaults
elif not issubclass(simulation_type, BaseSimulation):
raise FinesseException(
"A simulation should be based on the BaseSimulation class."
)
return simulation_type(
self,
"sim",
simulation_options,
)
[docs] @locked_when_built
@contextmanager
def built(self, simulation_type=None, simulation_options=None):
"""Context manager for making a simulation to work with. Once the context
manager has been closed the simulation object and all its memory will be freed
up.
Parameters
----------
simulation_options : dict
Options for type of simulation to run and its settings
Yields
------
BaseSimulation
Simulation object to interact with after it has been built.
Examples
--------
>>> import finesse
>>> model = finesse.script.parse('''
... ... some KatScript ...
... ''')
>>>
>>> with model.built() as sim:
... # interact with simulation object
... ...
"""
sim = self._build(
simulation_type=simulation_type, simulation_options=simulation_options
)
try:
sim.__enter__()
assert sim is not None
# Yield and let the caller do something with the model
yield sim
finally:
sim.__exit__(None, None, None)
self.unbuild()
def __node_exists_check(self, node):
if not self.network.has_node(node.full_name):
raise NodeException("Node {} is not in the model".format(node), node)
[docs] def path(self, from_node, to_node, via_node=None, symbolic=False):
"""Retrieves an ordered container of the path trace between the specified nodes.
The return type is an :class:`.OpticalPath` instance which stores an underlying
list of the path data (see the documentation for :class:`.OpticalPath` for details).
Parameters
----------
from_node : :class:`.Node`
Node to trace from.
to_node : :class:`.Node`
Node to trace to.
via_node : :class:`.Node` (or sequence of)
Node(s) to traverse via in the path.
symbolic : bool, optional
Whether to make a symbolic calculation of path lengths
Returns
-------
out : :class:`.OpticalPath`
A container of the nodes and components between `from_node` and `to_node`
in order.
Raises
------
e1 : :class:`.NodeException`
If either of `from_node`, `to_node` are not contained within the model.
e2 : :obj:`networkx.NetworkXNoPath`
If no path can be found between `from_node` and `to_node`.
"""
from_node, to_node, via_node = self.__parse_path_nodes(
from_node, to_node, via_node
)
try:
self.__node_exists_check(from_node)
self.__node_exists_check(to_node)
except NodeException:
raise
if (from_node is to_node) and (via_node is None):
return OpticalPath([])
from_node = from_node.full_name
to_node = to_node.full_name
if via_node is None:
try:
path = nx.shortest_path(self.optical_network, from_node, to_node)
except nx.exception.NetworkXNoPath:
raise
path_between = []
for node in path:
node_ref = self.network.nodes[node]["weakref"]()
path_between.append((node_ref, node_ref.component))
fullpath = []
for node, comp in path_between:
if node.is_input:
fullpath.append((node, comp))
else:
fullpath.append((node, node.space))
return OpticalPath(fullpath, symbolic=symbolic)
if not is_iterable(via_node):
via_node = [via_node]
via_node = [via.full_name for via in via_node]
try:
paths = [nx.shortest_path(self.optical_network, from_node, via_node[0])]
# find intermediate paths
for i, node in enumerate(via_node[:-1]):
paths.append(
nx.shortest_path(self.optical_network, node, via_node[i + 1])
)
paths.append(nx.shortest_path(self.optical_network, via_node[-1], to_node))
except nx.exception.NetworkXNoPath:
raise
path_between = [
(
self.network.nodes[node]["weakref"](),
self.network.nodes[node]["weakref"]().component,
)
for node in paths[0]
]
for path in paths[1:]:
path_between += [
(
self.network.nodes[node]["weakref"](),
self.network.nodes[node]["weakref"]().component,
)
for node in path
][
1:
] # don't want to repeat via node
fullpath = []
for node, comp in path_between:
if node.is_input:
fullpath.append((node, comp))
else:
fullpath.append((node, node.space))
return OpticalPath(fullpath)
[docs] def sub_model(self, from_node, to_node):
"""Obtains a subgraph of the complete configuration graph between the two
specified nodes.
Parameters
----------
from_node : :class:`.Node`
Node to trace from.
to_node : :class:`.Node`
Node to trace to.
Returns
-------
G : ``networkx.graphviews.SubDiGraph``
A SubGraph view of the subgraph between `from_node` and `to_node`.
"""
try:
self.__node_exists_check(from_node)
self.__node_exists_check(to_node)
except NodeException:
raise
nodes_between_set = {
node
for path in nx.all_simple_paths(
self.__network, source=from_node, target=to_node
)
for node in path
}
return self.__network.subgraph(nodes_between_set)
[docs] def component_tree(
self,
root: ModelElement | str | None = None,
network_type: str | NetworkType = NetworkType.COMPONENT,
show_detectors: bool = False,
show_ports: bool = False,
radius: int | None = None,
directed: bool = False,
) -> TreeNode:
"""Retrieves a tree containing the network representing the components connected
to the specified root. See also :ref:`model_visualization`.
Parameters
----------
root : str | ModelElement | Node | None, optional
Root element/node to start drawing the tree from. Is also used in
combination with ``radius``, for distance based filtering, by default
``None``. When ``network_type`` is ``components``, ``None`` will default to
the first :class:`.finesse.components.laser.Laser` found in the model.
network_type : str | NetworkType, optional
Which network to plot, can be one of 'optical', 'component', 'full',
by default NetworkType.COMPONENT
show_detectors : bool, optional
Whether to add detectors to the graph, by default False
show_ports : bool, optional
Whether to show by which ports components are connected, by default False
radius : int >= 1 | None, optional
Must be used in combination with ``root``, only include nodes of the network
that are ``radius`` or less edges away from the root node, by default None,
meaning that no nodes are filtered out.
directed : bool, optional
Whether to use directed distance-based filtering, by default False. If set
to True, will only include outgoing edges from the root node. See also
the ``undirected`` argument of :func:`networkx.generators.ego.ego_graph`
Returns
-------
:class:`.TreeNode`
The root tree node, with connected components as branches.
Raises
------
ValueError
If the specified root is not a model element.
Notes
-----
Uses :func:`networkx.generators.ego.ego_graph` for the distance-based filtering.
"""
if NetworkType(network_type) is not NetworkType.COMPONENT and root is None:
raise ValueError(
"Need to specify a root if `network_type` is not "
f"'{NetworkType.COMPONENT}'"
)
network_filter = NetworkType(network_type).filter_class(
model=self,
root=root,
radius=radius,
undirected=not directed,
add_edge_info=show_ports,
add_detectors=show_detectors,
)
return TreeNode.from_network(network_filter.run(), network_filter.root_str)
# Method name is a little mis-leading here but anyway...
def _update_symbolic_abcds(self):
"""Updates the *numeric* ABCD matrices of all components which have geometric
parameters which contain symbolic references to other parameters."""
# TODO (sjr) Replace with a loop over just pre-determined geometric parameters
# for efficiency, probably not a big deal currently though (I hope)
done = set()
for el in self.__elements.values():
if el in done:
continue
for p in el.parameters:
# TODO (jwp): determine if is_symbolic is being updated correctly
if p.is_geometric and p.is_symbolic:
el._re_eval_abcds()
done.add(el)
[docs] def detect_mismatches(self, ignore_AR=True, **kwargs):
"""Detect the mode mismatches in the model.
If you want to display these mismatches in a nicely formatted
table then use :meth:`Model.mismatches_table`.
Parameters
----------
ignore_AR : bool, optional
When True, with surfaces with R=0 the reflection mismatch is ignored
kwargs : Keyword arguments
Arguments to pass to :meth:`Model.beam_trace`.
Returns
-------
mismatches : dict
A dictionary of `(n1, n2): mms` where `n1` is the From node
and `n2` is the To node. The value `mms` is another dict
consisting of ``"x"`` and ``"y"`` keys mapping to the mismatch
values for the tangential and sagittal planes, respectively.
"""
# Perform the beam trace first so that trace_forest
# gets updated if needs be
trace = self.beam_trace(store=False, **kwargs)
mismatches = {}
couplings = self.trace_forest.find_potential_mismatch_couplings()
# No mode mismatch couplings present
if not couplings:
return mismatches
for node1, node2 in sorted(couplings, key=lambda npair: npair[0].full_name):
component = node1.component
if (
ignore_AR
and component.interaction_type(node1, node2)
== InteractionType.REFLECTION
):
if hasattr(component, "R") and component.R.value == 0:
continue
qx1, qy1 = trace[node1]
qx2, qy2 = trace[node2]
nr1 = refractive_index(node1)
nr2 = refractive_index(node2)
# Both nodes attached to same component by definition
comp = node1.component
Mx = comp.ABCD(node1, node2, direction="x")
My = comp.ABCD(node1, node2, direction="y")
qx1_matched = transform_beam_param(Mx, qx1, nr1, nr2)
qy1_matched = transform_beam_param(My, qy1, nr1, nr2)
mismatches[(node1, node2)] = {}
if qx1_matched != qx2:
mismatches[(node1, node2)]["x"] = BeamParam.mismatch(qx1_matched, qx2)
if qy1_matched != qy2:
mismatches[(node1, node2)]["y"] = BeamParam.mismatch(qy1_matched, qy2)
# Remove the entry if the mismatch values in both planes were zero
if not mismatches[(node1, node2)]:
del mismatches[(node1, node2)]
return mismatches
[docs] def mismatches_table(self, ignore_AR=True, numfmt="{:.4f}", **kwargs):
"""Prints the mismatches computed by :meth:`Model.detect_mismatches` to an
easily readable table.
Parameters
----------
ignore_AR : bool, optional
When True, with surfaces with R=0 the reflection mismatch is ignored
numfmt : str or func or array, optional
Either a function to format numbers or a formatting string. The
function must return a string. Can also be an array with one option per
row, column or cell. Defaults to "{:.4f}".
kwargs : Keyword arguments
Arguments to pass to :meth:`Model.beam_trace`.
"""
headerrow = ["Coupling", "Mismatch (x)", "Mismatch (y)"]
rownames = []
table = []
mismatches = self.detect_mismatches(ignore_AR=ignore_AR, **kwargs)
for (n1, n2), mm_values in mismatches.items():
mmx = mm_values.get("x", 0)
mmy = mm_values.get("y", 0)
table.append([mmx, mmy])
rownames.append(f"{n1.full_name} -> {n2.full_name}")
return NumberTable(table, headerrow, rownames, numfmt=numfmt)
[docs] def compute_space_gouys(self, deg=True, **kwargs):
"""Calculate the Gouy phases accumulated over each space.
If you want to display these phases in a nicely formatted
table then use :meth:`Model.space_gouys_table`.
Parameters
----------
deg : bool, optional; default = True
Whether to convert each phase to degrees.
kwargs : Keyword arguments
Arguments to pass to :meth:`Model.beam_trace`.
Returns
-------
gouys : dict
A dictionary of `space: gouy` where `space` is a :class:`.Space`
object and `gouy` is another dict consisting of ``"x"`` and ``"y"``
keys mapping to the Gouy phase values for the tangential and
sagittal planes, respectively.
"""
trace = self.beam_trace(store=False, **kwargs)
scale_func = math.degrees if deg else lambda x: x
gouys = {}
for space in self.spaces:
qx_p1o, qy_p1o = trace[space.p1.i]
qx_p2i, qy_p2i = trace[space.p2.o]
gouys[space] = {
"x": scale_func(abs(qx_p2i.psi - qx_p1o.psi)),
"y": scale_func(abs(qy_p2i.psi - qy_p1o.psi)),
}
return gouys
[docs] def space_gouys_table(self, deg=True, numfmt="{:.4f}", **kwargs):
"""Prints the space Gouy phases, as computed by
:meth:`Model.compute_space_gouys`, to an easily readable table.
Parameters
----------
deg : bool, optional; default = True
Whether to convert each phase to degrees.
fmtber_format : str or func or array, optional
Either a function to format numbers or a formatting string. The
function must return a string. Can also be an array with one option per
row, column or cell. Defaults to "{:.4f}".
kwargs : Keyword arguments
Arguments to pass to :meth:`Model.beam_trace`.
"""
units = "deg" if deg else "rad"
headers = ["Space", f"Gouy (x) [{units}]", f"Gouy (y) [{units}]"]
table = []
rownames = []
gouys = self.compute_space_gouys(deg=deg, **kwargs)
for space, gouy_d in gouys.items():
gouy_x = gouy_d.get("x", 0)
gouy_y = gouy_d.get("y", 0)
table.append([gouy_x, gouy_y])
rownames.append(f"{space.name}")
return NumberTable(table, headers, rownames, numfmt=numfmt)
[docs] @locked_when_built
def create_mismatch(self, node, w0_mm=0, z_mm=0):
"""Sets the beam parameters such that a mismatch of the specified percentage
magnitude (in terms of :math:`w_0` and :math:`z`) exists at the given `node`.
Parameters
----------
node : :class:`.OpticalNode`
The node to to create the mismatch at.
w0_mm : float or sequence, optional
The percentage magnitude of the mismatch in the waist size. This
can also be a two-element sequence specifying the waist size mismatches
for an astigmatic beam. Defaults to zero percent for both planes.
z_mm : float or sequence, optional
The percentage magntiude of the mismatch in the distance to
the waist. This can also be a two-element sequence specifying the distance
to waist mismatches for an astigmatic beam. Defaults to zero percent for
both planes.
Returns
-------
gauss : :class:`.Gauss`
The Gauss object created or modified via this mismatch.
"""
if not self.__network.has_node(node.full_name):
raise NodeException("Specified node does not exist within the model", node)
trace = self.beam_trace(store=False)
qx, qy = trace[node]
qx_w0, qy_w0 = qx.w0, qy.w0
qx_z, qy_z = qx.z, qy.z
if not is_iterable(w0_mm):
qx_w0 *= 1 + (w0_mm / 100)
qy_w0 *= 1 + (w0_mm / 100)
else:
qx_w0 *= 1 + (w0_mm[0] / 100)
qy_w0 *= 1 + (w0_mm[1] / 100)
if not is_iterable(z_mm):
qx_z *= 1 + (z_mm / 100)
qy_z *= 1 + (z_mm / 100)
else:
qx_z *= 1 + (z_mm[0] / 100)
qy_z *= 1 + (z_mm[1] / 100)
nr = refractive_index(node)
qx_bp = BeamParam(w0=qx_w0, z=qx_z, nr=nr)
qy_bp = BeamParam(w0=qy_w0, z=qy_z, nr=nr)
if node in self.__gausses:
self.update_gauss(node, qx_bp, qy_bp)
else:
name = f"AUTO_MM_{node.component.name}"
self.add(Gauss(name, node, qx=qx_bp, qy=qy_bp))
return self.__gausses.get(node)
[docs] @locked_when_built
def add_matched_gauss(self, node, name=None, priority=0, matched_to=None):
"""Adds a :class:`.Gauss` object mode matched to the model at the specified
`node`. If `matched_to` is given then the Gauss object will be matched to this,
otherwise it will be mode matched to whichever dependency the `node` relies upon
currently.
Parameters
----------
node :class:`.OpticalNode`
The node instance to add the Gauss at.
name : str, optional
Optional name of the new Gauss object. If not specified then the name
will be automatically given as "AUTO_MM_nodename" where `nodename` is
the node's :attr:`full name <.Node.full_name>`.
priority : int, optional; default: 0
The priority value of the Gauss object. See :attr:`.TraceDependency.priority`
for details on the argument.
matched_to : :class:`.TraceDependency`, optional
The trace dependency to solely match to.
"""
if not self.__network.has_node(node.full_name):
raise NodeException("Specified node does not exist within the model", node)
if node in self.__gausses:
raise ValueError(f"A Gauss object already exists at node {node.full_name}")
if matched_to is not None and not isinstance(
matched_to, (TraceDependency, str)
):
raise ValueError("Expected matched_to arg to be of type TraceDependency.")
trace = self.beam_trace(enable_only=matched_to, store=False)
qx, qy = trace[node]
if name is None:
name = f"AUTO_MM_{node.component.name}"
self.add(Gauss(name, node, qx=qx, qy=qy, priority=priority))
return self.__gausses.get(node)
[docs] def update_gauss(self, node, qx=None, qy=None):
"""Update the value of a manual beam parameter (i.e. :class:`.Gauss` object) at
the specified `node`.
Parameters
----------
node : :class:`.OpticalNode`
The node instance to update the gauss at.
qx : :class:`.BeamParam` or complex, optional
Beam parameter in tangential plane.
qy : :class:`.BeamParam` or complex, optional
Beam parameter in sagittal plane.
"""
if not isinstance(node, OpticalNode):
raise TypeError(
f"Expected argument 'node' to be of type OpticalNode "
f"but got value of type {type(node)}"
)
gauss = self.__gausses.get(node)
if gauss is None:
raise ValueError(
f"Node {node.full_name} has no Gauss object associated with it."
)
if qx is None and qy is None:
warn("Model.update_gauss called with no change to qx, qy.")
if qx is not None:
self.__gausses[node].qx = qx
if qy is not None:
self.__gausses[node].qy = qy
[docs] def cavity_mismatch(self, cav1=None, cav2=None):
"""See :func:`finesse.tracing.tools.compute_cavity_mismatches`"""
return tracetools.compute_cavity_mismatches(self, cav1, cav2)
[docs] def cavity_mismatches_table(self, direction=None, percent=False, numfmt="{:.2e}"):
"""Prints the mismatches between each cavity in an easily readable table format.
If either of each cavity in a coupling is unstable then the mismatch values
between these will be displayed as ``nan``.
Parameters
----------
direction : str, optional; default: None
The plane to compute mismatches in, "x" for tangential, "y" for sagittal. If
not given then tables for both planes will be printed.
percent : bool, optional; default: False
Whether mismatch values are displayed in terms of percentage. Defaults to
False such that the values are given as fractional mismatches.
numfmt : str or func or array, optional
Either a function to format numbers or a formatting string. The
function must return a string. Can also be an array with one option per
row, column or cell. Defaults to "{:.4f}".
"""
if not self.cavities:
warn("No cavities present in the model.")
return
mmx, mmy = self.cavity_mismatch()
headers = [cav.name for cav in self.cavities]
names_x = []
names_y = []
table_x = []
table_y = []
scale = 100 if percent else 1
for cav1 in self.cavities:
names_x.append(cav1.name)
names_y.append(cav1.name)
row_x = []
row_y = []
for cav2 in self.cavities:
row_x.append(scale * mmx[(cav1.name, cav2.name)])
row_y.append(scale * mmy[(cav1.name, cav2.name)])
table_x.append(row_x)
table_y.append(row_y)
if direction is None:
direction = "x", "y"
result = []
if "x" in direction:
headers_x = headers.copy()
headers_x.insert(0, "(Tangential plane)")
result.append(NumberTable(table_x, headers_x, names_x, numfmt=numfmt))
if "y" in direction:
headers_y = headers.copy()
headers_y.insert(0, " (Sagittal plane) ")
result.append(NumberTable(table_y, headers_y, names_y, numfmt=numfmt))
return result
def __optical_node_from_str(self, name, dir_if_port="o", reject_ports=False):
args = name.split(".")
is_port = False
if len(args) == 2: # name is a port string
if reject_ports:
raise ValueError(
f"Via port {name} is ambiguous, cannot safely assume node "
"direction. Please specify the full node string instead."
)
name += "." + dir_if_port
is_port = True
else:
if len(args) != 3:
raise ValueError(f"Unexpected port or node name format: {name}")
# return self.network.nodes[name]["weakref"]()
# Issue 388: get full name node from model instead which avoids the issue
# of borrowed nodes full names not being stored in the model graph
if is_port:
return getattr(self.get(name).port, dir_if_port)
else:
return self.get(name)
def __parse_path_nodes(self, from_node, to_node, via_node):
if from_node is not None and not isinstance(from_node, OpticalNode):
if isinstance(from_node, Port):
# Issue 388: bit hacky but to get around the borrowed node stuff
# as in the port here might be a space port which has the opposite
# i/o nodes to the port of an element which actually owns the nodes
# we get the original port and the output of that...
from_node = from_node.o.port.o
elif isinstance(from_node, str):
from_node = self.__optical_node_from_str(from_node, dir_if_port="o")
else:
raise TypeError("Unexpected type for from_node.")
if to_node is not None and not isinstance(to_node, OpticalNode):
if isinstance(to_node, Port):
to_node = to_node.i.port.i # Issue 388 hack
elif isinstance(to_node, str):
to_node = self.__optical_node_from_str(to_node, dir_if_port="i")
else:
raise TypeError("Unexpected type for to_node.")
if via_node is not None and not isinstance(via_node, OpticalNode):
if isinstance(via_node, Port):
raise ValueError(
f"Via port {via_node} is ambiguous, cannot safely assume node "
"direction. Please specify the optical node instead."
)
elif isinstance(via_node, str):
via_node = self.__optical_node_from_str(via_node, reject_ports=True)
else:
raise TypeError("Unexpected type for via_node.")
return from_node, to_node, via_node
[docs] def ABCD(
self,
from_node=None,
to_node=None,
via_node=None,
path=None,
direction="x",
symbolic=False,
solution_name=None,
):
"""See :func:`finesse.tracing.tools.compute_abcd`
.. note::
The only difference to the above function is that any of `from_node`, `to_node`,
`via_node` can be specified as strings.
"""
fn, tn, vn = self.__parse_path_nodes(from_node, to_node, via_node)
return tracetools.compute_abcd(
fn, tn, vn, path, direction, symbolic, solution_name
)
[docs] def acc_gouy(
self,
from_node=None,
to_node=None,
via_node=None,
path=None,
q_in=None,
direction="x",
symbolic=False,
degrees=True,
**kwargs,
):
"""See :func:`finesse.tracing.tools.acc_gouy`
.. note::
The only difference to the above function is that any of `from_node`, `to_node`,
`via_node` can be specified as strings.
"""
fn, tn, vn = self.__parse_path_nodes(from_node, to_node, via_node)
return tracetools.acc_gouy(
fn,
tn,
vn,
path,
q_in,
direction,
symbolic,
degrees,
**kwargs,
)
[docs] def propagate_beam(
self,
from_node=None,
to_node=None,
via_node=None,
path=None,
q_in=None,
direction="x",
symbolic=False,
simplify=False,
solution_name=None,
**kwargs,
):
"""See :func:`finesse.tracing.tools.propagate_beam`
.. note::
The only difference to the above function is that any of `from_node`, `to_node`,
`via_node` can be specified as strings.
"""
fn, tn, vn = self.__parse_path_nodes(from_node, to_node, via_node)
return tracetools.propagate_beam(
fn,
tn,
vn,
path,
q_in,
direction,
symbolic,
simplify,
solution_name,
**kwargs,
)
[docs] def propagate_beam_astig(
self,
from_node=None,
to_node=None,
via_node=None,
path=None,
qx_in=None,
qy_in=None,
symbolic=False,
solution_name=None,
**kwargs,
):
"""See :func:`finesse.tracing.tools.propagate_beam_astig`
.. note::
The only difference to the above function is that any of `from_node`, `to_node`,
`via_node` can be specified as strings.
"""
fn, tn, vn = self.__parse_path_nodes(from_node, to_node, via_node)
return tracetools.propagate_beam_astig(
fn,
tn,
vn,
path,
qx_in,
qy_in,
symbolic,
solution_name,
**kwargs,
)
[docs] def beam_trace(
self,
order=None,
disable=None,
enable_only=None,
symmetric=True,
store=True,
solution_name="beam_trace",
):
"""Performs a full beam trace on the model, calculating the beam parameters at
each optical node.
Beam tracing requires at least one stable :class:`.TraceDependency` object -
defined as a :class:`.Gauss` or :class:`.Cavity` object - in the model. Note
that :class:`.Cavity` objects are not determined automatically, they must be
explicitly added to the model.
The order in which the beam tracing is performed is as follows:
* All internal cavity traces are carried out initially, i.e. any nodes
that are part of a path of a :class:`.Cavity` instance in the model will
be traced using the cavity eigenmode as the basis. See the note below for
what happens in the case of overlapping cavities.
* If `order` is **not** specified, then the dependency ordering given by
:attr:`.Model.trace_order` is used; i.e. beam traces are performed from
each dependency in this list where any overlapping trees from multiple
dependencies will always use the first dependency's tree.
* If `order` **is** specified, then beam traces from each dependency given in this
argument will be carried out in the given order, in the same way as above. This
effectively allows temporary overriding of the trace order for specific beam
trace calls.
Certain dependencies can be switched off via the `disable` or `enable_only` arguments.
Full details on the beam tracing algorithm are given in :ref:`tracing_manual`.
.. note::
.. rubric:: Overlapping cavities
In complicated configurations, such as dual-recycled Michelson interferometers, it is
often the case that there will be *overlapping* cavities; i.e. cavities which share
common optical nodes in their paths. This naturally leads to the question - in which
basis are these common nodes being set?
The algorithm used by this method will prioritise the internal trace of the cavity
as follows:
* If `order` is **not** given then the cavity appearing first in :attr:`.Model.trace_order`
will be used for setting the beam parameters of all nodes in this cavity path - *including*
any nodes which are shared with other cavity instances.
* Otherwise, the cavity appearing first in `order` will be used in the same way.
Parameters
----------
order : sequence, optional; default: None
A priority list of dependencies to trace in order. These dependencies
can be either :class:`.Cavity` / :class:`.Gauss` objects or the names of these
objects. If this argument is not specified then beam tracing will be performed
using the order defined in :attr:`.Model.trace_order`.
This argument allows temporary overriding of the model trace order for a given
beam trace call, without needing to change the :attr:`.TraceDependency.priority`
values of any dependencies in the model (which would affect all future beam
traces in which `order` is not specified). Note that, if specifying this argument,
a sub-set of the trace dependencies in the model can be given --- any dependencies
not in the given `order` will retain their original ordering.
disable : sequence, optional: default: None
A single dependency or list of dependencies to disable. These dependencies can
be either :class:`.Cavity` / :class:`.Gauss` objects or the names of these objects.
Note that this argument is ignored if `enable_only` is specified.
enable_only : sequence, optional: default: None
A single dependency or list of dependencies to explicity enable, all other
dependencies will be switched off for the trace call. These dependencies can
be either :class:`.Cavity` / :class:`.Gauss` objects or the names of these objects.
symmetric : bool, optional; default: true
Flag to determine whether the beam parameters at :attr:`.OpticalNode.opposite` nodes
of each node encountered during the beam trace get set to the :meth:`.BeamParam.reverse`
of the "forward" propagated beam parameter.
store : bool, optional; default: True
Flag to determine whether to store the results of a beam trace in
in the :attr:`Model.last_trace` property. Note that if this is set
to False then accessing beam parameters via :class:`.OpticalNode`
instances directly will give the *last stored* beam parameter at that
node (i.e. not those given by this trace call).
Raises
------
ex : :class:`.BeamTraceException`
If there are no :class:`.Gauss` objects or stable :class:`.Cavity` instances
present in the model.
ex_v: :class:`.ValueError`
If `order` was specified and it contains an invalid item.
ex_tr : :class:`.TotalReflectionError`
If a :class:`.Beamsplitter` object is present in the model with an angle of
incidence and associated refractive indices giving total internal reflection.
Returns
-------
out : :class:`.BeamTraceSolution`
An object representing the results of the tracing routine.
"""
LOGGER.info("Beam trace triggered on %s", self)
# No override given
if order is None:
order = self.trace_order
# Override to model trace_order given, so verify and make it
else:
order = self.__make_trace_order_override(order)
# No cavities nor gausses present
if not order:
raise BeamTraceException(_invalid_trace_reason())
Norder = len(order)
Ndeps = len(self.cavities) + len(self.gausses)
if Norder != Ndeps:
raise BeamTraceException(
f"Bug encountered! Length of trace order dependency list ({Norder}) "
f"not equal to number of tracing dependencies ({Ndeps})."
)
self._update_symbolic_abcds()
# Remove specific dependencies from order
if disable is not None and enable_only is None:
if not is_iterable(disable):
disable = [disable]
for item in disable:
if isinstance(item, str):
item_obj = self.__elements.get(item)
else:
item_obj = item
if isinstance(item_obj, TraceDependency):
try:
order.remove(item_obj)
except ValueError:
LOGGER.info(
f"Ignoring duplicate item {repr(item)} in disable sequence"
)
else:
LOGGER.info(
f"ignoring unrecognised item {repr(item)} in disable sequence"
)
# Filter order to just contain dependencies in enable_only
if enable_only is not None:
if disable is not None:
warn("Ignoring argument 'disable' as 'enable_only' has been given.")
if not is_iterable(enable_only):
enable_only = [enable_only]
else:
enable_only = list(enable_only)
for i, item in enumerate(enable_only):
if isinstance(item, str):
item_obj = self.__elements.get(item)
else:
item_obj = item
if not isinstance(item_obj, TraceDependency):
warn(
f"ignoring unrecognised item {repr(item_obj)} in enable_only "
f"sequence"
)
enable_only[i] = item_obj
order = list(filter(lambda x: x in enable_only, order))
all_cavities = list(filter(lambda x: isinstance(x, Cavity), order))
stable_cavities = list(filter(lambda x: x.is_stable, all_cavities))
gausses = list(filter(lambda x: isinstance(x, Gauss), order))
if not stable_cavities and not gausses:
raise BeamTraceException(_invalid_trace_reason(all_cavities))
# Ensure only gausses and *stable* cavities get passed to trace forest planting
order = list(filter(lambda x: x in stable_cavities or x in gausses, order))
unstable_cavities = OrderedSet(all_cavities).difference(stable_cavities)
if unstable_cavities:
warn(
f"The cavities {[uc.name for uc in unstable_cavities]} are unstable "
f"and will not be used for beam tracing.",
CavityUnstableWarning,
)
# Save the planet! Here we only clear and re-plant the forest if:
# - a component has been added / removed from the model since last
# call (taken into account in Model.add, Model.remove already)
# - the symmetric flag has changed since the last plant
# - or the tracing priority has changed
self._rebuild_trace_forest |= (
self.trace_forest.symmetric != symmetric
or self.trace_forest.dependencies != order
)
if self._rebuild_trace_forest:
LOGGER.info(
"Re-planting the model trace forest with dependency order: %s",
[d.name for d in order],
)
self.trace_forest.symmetric = symmetric
self.trace_forest.plant(order)
LOGGER.info("Planted the full model trace forest: %s", self.trace_forest)
self._rebuild_trace_forest = False
trace_results = self.trace_forest.trace_beam()
trace = BeamTraceSolution(solution_name, trace_results)
LOGGER.debug("\n%s", trace)
if store:
self.__last_trace = trace
return trace
def __make_trace_order_override(self, override):
"""Construct an override list for the current trace order."""
if not is_iterable(override):
override = [override]
order = []
# For all the items in value, append these in
# order to the new dependency order list
for item in override:
if isinstance(item, str):
dep = self.__elements.get(item)
if dep is None:
raise ValueError(
f"Error in tracing order override:\n"
f" No item of name {item} exists in the model."
)
else:
dep = item
if isinstance(dep, Cavity):
if dep not in self.__cavities:
raise ValueError(
f"Error in tracing order override:\n"
f" Cavity {dep.name} is not part of the model."
)
elif isinstance(dep, Gauss):
if dep not in self.__gausses.values():
raise ValueError(
f"Error in tracing order override:\n"
f" Gauss {dep.name} is not part of the model."
)
else:
raise ValueError(
f"Error in tracing order override:\n"
f" Item {dep} is neither a Cavity nor a Gauss object."
)
if dep in order:
LOGGER.info(
f"ignoring duplicate dependency {repr(dep.name)} in tracing order "
f"override"
)
else:
order.append(dep)
# Take all the remaining dependencies that were not in override and
# append these to the end of the dependency order list
# -> this means that the original order of those dependencies is
# retained, the only ordering that has changed is those that
# were included in the override
for item in self.trace_order:
if item not in order:
order.append(item)
return order
def _invalid_trace_reason(cavities=None):
msg = """Unable to perform a beam trace!
- No manually set beam parameters have been specified.
"""
def gfactor_str(cavity):
gx, gy = cavity.g
if cavity.gx == cavity.gy:
return f"g = {gx}"
return f"gx = {gx}, gy = {gy}"
if cavities is None:
cavities = []
crit = ", ".join(
[f"{cav.name}: {gfactor_str(cav)}" for cav in cavities if cav.is_critical]
)
unst = ", ".join(
[
f"{cav.name}: {gfactor_str(cav)}"
for cav in cavities
if not cav.is_stable and not cav.is_critical
]
)
if cavities:
msg += f"""
- All cavities included in the model are unstable / critical.
- Critical cavities -- {crit}
- Unstable cavities -- {unst}
"""
else:
msg += """
- No cavities are present in the model. Note that cavity objects must be
explicitly added, they are NOT auto-generated from your configuration.
"""
return msg