# Copyright 2020 The PyMC Developers # # Licensed under the Apache License, Version 2.0 (the "License"); # you may not use this file except in compliance with the License. # You may obtain a copy of the License at # # http://www.apache.org/licenses/LICENSE-2.0 # # Unless required by applicable law or agreed to in writing, software # distributed under the License is distributed on an "AS IS" BASIS, # WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. # See the License for the specific language governing permissions and # limitations under the License. import warnings from typing import ( Callable, Dict, Generator, Iterable, List, Optional, Sequence, Set, Tuple, Union, ) import aesara import aesara.tensor as at import numpy as np import pandas as pd import scipy.sparse as sps from aeppl.abstract import MeasurableVariable from aeppl.logprob import CheckParameterValue from aesara import config, scalar from aesara.compile.mode import Mode, get_mode from aesara.gradient import grad from aesara.graph import node_rewriter from aesara.graph.basic import ( Apply, Constant, Variable, clone_get_equiv, graph_inputs, vars_between, walk, ) from aesara.graph.fg import FunctionGraph from aesara.graph.op import Op, compute_test_value from aesara.sandbox.rng_mrg import MRG_RandomStream as RandomStream from aesara.scalar.basic import Cast from aesara.tensor.basic import _as_tensor_variable from aesara.tensor.elemwise import Elemwise from aesara.tensor.random.op import RandomVariable from aesara.tensor.random.var import ( RandomGeneratorSharedVariable, RandomStateSharedVariable, ) from aesara.tensor.shape import SpecifyShape from aesara.tensor.sharedvar import SharedVariable from aesara.tensor.subtensor import AdvancedIncSubtensor, AdvancedIncSubtensor1 from aesara.tensor.var import TensorConstant, TensorVariable from pymc.exceptions import ShapeError from pymc.vartypes import continuous_types, isgenerator, typefilter PotentialShapeType = Union[int, np.ndarray, Sequence[Union[int, Variable]], TensorVariable] __all__ = [ "gradient", "hessian", "hessian_diag", "inputvars", "cont_inputs", "floatX", "intX", "smartfloatX", "jacobian", "CallableTensor", "join_nonshared_inputs", "make_shared_replacements", "generator", "set_at_rng", "at_rng", "convert_observed_data", ] def convert_observed_data(data): """Convert user provided dataset to accepted formats.""" if hasattr(data, "to_numpy") and hasattr(data, "isnull"): # typically, but not limited to pandas objects vals = data.to_numpy() null_data = data.isnull() if hasattr(null_data, "to_numpy"): # pandas Series mask = null_data.to_numpy() else: # pandas Index mask = null_data if mask.any(): # there are missing values ret = np.ma.MaskedArray(vals, mask) else: ret = vals elif isinstance(data, np.ndarray): if isinstance(data, np.ma.MaskedArray): if not data.mask.any(): # empty mask ret = data.filled() else: # already masked and rightly so ret = data else: # already a ndarray, but not masked mask = np.isnan(data) if np.any(mask): ret = np.ma.MaskedArray(data, mask) else: # no masking required ret = data elif isinstance(data, Variable): ret = data elif sps.issparse(data): ret = data elif isgenerator(data): ret = generator(data) else: ret = np.asarray(data) # type handling to enable index variables when data is int: if hasattr(data, "dtype"): if "int" in str(data.dtype): return intX(ret) # otherwise, assume float: else: return floatX(ret) # needed for uses of this function other than with pm.Data: else: return floatX(ret) @_as_tensor_variable.register(pd.Series) @_as_tensor_variable.register(pd.DataFrame) def dataframe_to_tensor_variable(df: pd.DataFrame, *args, **kwargs) -> TensorVariable: return at.as_tensor_variable(df.to_numpy(), *args, **kwargs) def change_rv_size( rv: TensorVariable, new_size: PotentialShapeType, expand: Optional[bool] = False, ) -> TensorVariable: """Change or expand the size of a `RandomVariable`. Parameters ========== rv The old `RandomVariable` output. new_size The new size. expand: Expand the existing size by `new_size`. """ # Check the dimensionality of the `new_size` kwarg new_size_ndim = np.ndim(new_size) if new_size_ndim > 1: raise ShapeError("The `new_size` must be ≤1-dimensional.", actual=new_size_ndim) elif new_size_ndim == 0: new_size = (new_size,) # Extract the RV node that is to be resized, together with its inputs, name and tag assert rv.owner.op is not None if isinstance(rv.owner.op, SpecifyShape): rv = rv.owner.inputs[0] rv_node = rv.owner rng, size, dtype, *dist_params = rv_node.inputs name = rv.name tag = rv.tag if expand: shape = tuple(rv_node.op._infer_shape(size, dist_params)) size = shape[: len(shape) - rv_node.op.ndim_supp] new_size = tuple(new_size) + tuple(size) # Make sure the new size is a tensor. This dtype-aware conversion helps # to not unnecessarily pick up a `Cast` in some cases (see #4652). new_size = at.as_tensor(new_size, ndim=1, dtype="int64") new_rv_node = rv_node.op.make_node(rng, new_size, dtype, *dist_params) new_rv = new_rv_node.outputs[-1] new_rv.name = name for k, v in tag.__dict__.items(): new_rv.tag.__dict__.setdefault(k, v) # Update "traditional" rng default_update, if that was set for old RV default_update = getattr(rng, "default_update", None) if default_update is not None and default_update is rv_node.outputs[0]: rng.default_update = new_rv_node.outputs[0] if config.compute_test_value != "off": compute_test_value(new_rv_node) return new_rv def extract_rv_and_value_vars( var: TensorVariable, ) -> Tuple[TensorVariable, TensorVariable]: """Return a random variable and it's observations or value variable, or ``None``. Parameters ========== var A variable corresponding to a ``RandomVariable``. Returns ======= The first value in the tuple is the ``RandomVariable``, and the second is the measure/log-likelihood value variable that corresponds with the latter. """ if not var.owner: return None, None if isinstance(var.owner.op, RandomVariable): rv_value = getattr(var.tag, "observations", getattr(var.tag, "value_var", None)) return var, rv_value return None, None def extract_obs_data(x: TensorVariable) -> np.ndarray: """Extract data from observed symbolic variables. Raises ------ TypeError """ if isinstance(x, Constant): return x.data if isinstance(x, SharedVariable): return x.get_value() if x.owner and isinstance(x.owner.op, Elemwise) and isinstance(x.owner.op.scalar_op, Cast): array_data = extract_obs_data(x.owner.inputs[0]) return array_data.astype(x.type.dtype) if x.owner and isinstance(x.owner.op, (AdvancedIncSubtensor, AdvancedIncSubtensor1)): array_data = extract_obs_data(x.owner.inputs[0]) mask_idx = tuple(extract_obs_data(i) for i in x.owner.inputs[2:]) mask = np.zeros_like(array_data) mask[mask_idx] = 1 return np.ma.MaskedArray(array_data, mask) raise TypeError(f"Data cannot be extracted from {x}") def walk_model( graphs: Iterable[TensorVariable], walk_past_rvs: bool = False, stop_at_vars: Optional[Set[TensorVariable]] = None, expand_fn: Callable[[TensorVariable], Iterable[TensorVariable]] = lambda var: [], ) -> Generator[TensorVariable, None, None]: """Walk model graphs and yield their nodes. By default, these walks will not go past ``RandomVariable`` nodes. Parameters ========== graphs The graphs to walk. walk_past_rvs If ``True``, the walk will not terminate at ``RandomVariable``s. stop_at_vars A list of variables at which the walk will terminate. expand_fn A function that returns the next variable(s) to be traversed. """ if stop_at_vars is None: stop_at_vars = set() def expand(var): new_vars = expand_fn(var) if ( var.owner and (walk_past_rvs or not isinstance(var.owner.op, RandomVariable)) and (var not in stop_at_vars) ): new_vars.extend(reversed(var.owner.inputs)) return new_vars yield from walk(graphs, expand, False) def replace_rvs_in_graphs( graphs: Iterable[TensorVariable], replacement_fn: Callable[[TensorVariable], Dict[TensorVariable, TensorVariable]], initial_replacements: Optional[Dict[TensorVariable, TensorVariable]] = None, **kwargs, ) -> Tuple[TensorVariable, Dict[TensorVariable, TensorVariable]]: """Replace random variables in graphs This will *not* recompute test values. Parameters ========== graphs The graphs in which random variables are to be replaced. Returns ======= Tuple containing the transformed graphs and a ``dict`` of the replacements that were made. """ replacements = {} if initial_replacements: replacements.update(initial_replacements) def expand_replace(var): new_nodes = [] if var.owner and isinstance(var.owner.op, RandomVariable): new_nodes.extend(replacement_fn(var, replacements)) return new_nodes for var in walk_model(graphs, expand_fn=expand_replace, **kwargs): pass if replacements: inputs = [i for i in graph_inputs(graphs) if not isinstance(i, Constant)] equiv = {k: k for k in replacements.keys()} equiv = clone_get_equiv(inputs, graphs, False, False, equiv) fg = FunctionGraph( [equiv[i] for i in inputs], [equiv[o] for o in graphs], clone=False, ) fg.replace_all(replacements.items(), import_missing=True) graphs = list(fg.outputs) return graphs, replacements def rvs_to_value_vars( graphs: Iterable[TensorVariable], apply_transforms: bool = False, initial_replacements: Optional[Dict[TensorVariable, TensorVariable]] = None, **kwargs, ) -> Tuple[TensorVariable, Dict[TensorVariable, TensorVariable]]: """Clone and replace random variables in graphs with their value variables. This will *not* recompute test values in the resulting graphs. Parameters ========== graphs The graphs in which to perform the replacements. apply_transforms If ``True``, apply each value variable's transform. initial_replacements A ``dict`` containing the initial replacements to be made. """ # Avoid circular dependency from pymc.distributions import NoDistribution def transform_replacements(var, replacements): rv_var, rv_value_var = extract_rv_and_value_vars(var) if rv_value_var is None: # If RandomVariable does not have a value_var and corresponds to # a NoDistribution, we allow further replacements in upstream graph if isinstance(rv_var.owner.op, NoDistribution): return rv_var.owner.inputs else: warnings.warn( f"No value variable found for {rv_var}; " "the random variable will not be replaced." ) return [] transform = getattr(rv_value_var.tag, "transform", None) if transform is None or not apply_transforms: replacements[var] = rv_value_var # In case the value variable is itself a graph, we walk it for # potential replacements return [rv_value_var] trans_rv_value = transform.backward(rv_value_var, *rv_var.owner.inputs) replacements[var] = trans_rv_value # Walk the transformed variable and make replacements return [trans_rv_value] # Clone original graphs inputs = [i for i in graph_inputs(graphs) if not isinstance(i, Constant)] equiv = clone_get_equiv(inputs, graphs, False, False, {}) graphs = [equiv[n] for n in graphs] if initial_replacements: initial_replacements = { equiv.get(k, k): equiv.get(v, v) for k, v in initial_replacements.items() } return replace_rvs_in_graphs(graphs, transform_replacements, initial_replacements, **kwargs) def inputvars(a): """ Get the inputs into Aesara variables Parameters ---------- a: Aesara variable Returns ------- r: list of tensor variables that are inputs """ return [ v for v in graph_inputs(makeiter(a)) if isinstance(v, TensorVariable) and not isinstance(v, TensorConstant) ] def cont_inputs(a): """ Get the continuous inputs into Aesara variables Parameters ---------- a: Aesara variable Returns ------- r: list of tensor variables that are continuous inputs """ return typefilter(inputvars(a), continuous_types) def floatX(X): """ Convert an Aesara tensor or numpy array to aesara.config.floatX type. """ try: return X.astype(aesara.config.floatX) except AttributeError: # Scalar passed return np.asarray(X, dtype=aesara.config.floatX) _conversion_map = {"float64": "int32", "float32": "int16", "float16": "int8", "float8": "int8"} def intX(X): """ Convert a aesara tensor or numpy array to aesara.tensor.int32 type. """ intX = _conversion_map[aesara.config.floatX] try: return X.astype(intX) except AttributeError: # Scalar passed return np.asarray(X, dtype=intX) def smartfloatX(x): """ Converts numpy float values to floatX and leaves values of other types unchanged. """ if str(x.dtype).startswith("float"): x = floatX(x) return x """ Aesara derivative functions """ def gradient1(f, v): """flat gradient of f wrt v""" return at.flatten(grad(f, v, disconnected_inputs="warn")) empty_gradient = at.zeros(0, dtype="float32") def gradient(f, vars=None): if vars is None: vars = cont_inputs(f) if vars: return at.concatenate([gradient1(f, v) for v in vars], axis=0) else: return empty_gradient def jacobian1(f, v): """jacobian of f wrt v""" f = at.flatten(f) idx = at.arange(f.shape[0], dtype="int32") def grad_i(i): return gradient1(f[i], v) return aesara.map(grad_i, idx)[0] def jacobian(f, vars=None): if vars is None: vars = cont_inputs(f) if vars: return at.concatenate([jacobian1(f, v) for v in vars], axis=1) else: return empty_gradient def jacobian_diag(f, x): idx = at.arange(f.shape[0], dtype="int32") def grad_ii(i, f, x): return grad(f[i], x)[i] return aesara.scan( grad_ii, sequences=[idx], n_steps=f.shape[0], non_sequences=[f, x], name="jacobian_diag" )[0] @aesara.config.change_flags(compute_test_value="ignore") def hessian(f, vars=None): return -jacobian(gradient(f, vars), vars) @aesara.config.change_flags(compute_test_value="ignore") def hessian_diag1(f, v): g = gradient1(f, v) idx = at.arange(g.shape[0], dtype="int32") def hess_ii(i): return gradient1(g[i], v)[i] return aesara.map(hess_ii, idx)[0] @aesara.config.change_flags(compute_test_value="ignore") def hessian_diag(f, vars=None): if vars is None: vars = cont_inputs(f) if vars: return -at.concatenate([hessian_diag1(f, v) for v in vars], axis=0) else: return empty_gradient def makeiter(a): if isinstance(a, (tuple, list)): return a else: return [a] class IdentityOp(scalar.UnaryScalarOp): @staticmethod def st_impl(x): return x def impl(self, x): return x def grad(self, inp, grads): return grads def c_code(self, node, name, inp, out, sub): return f"{out[0]} = {inp[0]};" def __eq__(self, other): return isinstance(self, type(other)) def __hash__(self): return hash(type(self)) scalar_identity = IdentityOp(scalar.upgrade_to_float, name="scalar_identity") identity = Elemwise(scalar_identity, name="identity") def make_shared_replacements(point, vars, model): """ Makes shared replacements for all *other* variables than the ones passed. This way functions can be called many times without setting unchanging variables. Allows us to use func.trust_input by removing the need for DictToArrayBijection and kwargs. Parameters ---------- point: dictionary mapping variable names to sample values vars: list of variables not to make shared model: model Returns ------- Dict of variable -> new shared variable """ othervars = set(model.value_vars) - set(vars) return { var: aesara.shared(point[var.name], var.name + "_shared", shape=var.broadcastable) for var in othervars } def join_nonshared_inputs( point: Dict[str, np.ndarray], xs: List[TensorVariable], vars: List[TensorVariable], shared, make_shared: bool = False, ): """ Takes a list of Aesara Variables and joins their non shared inputs into a single input. Parameters ---------- point: a sample point xs: list of Aesara tensors vars: list of variables to join Returns ------- tensors, inarray tensors: list of same tensors but with inarray as input inarray: vector of inputs """ if not vars: raise ValueError("Empty list of variables.") joined = at.concatenate([var.ravel() for var in vars]) if not make_shared: tensor_type = joined.type inarray = tensor_type("inarray") else: if point is None: raise ValueError("A point is required when `make_shared` is True") joined_values = np.concatenate([point[var.name].ravel() for var in vars]) inarray = aesara.shared(joined_values, "inarray") if aesara.config.compute_test_value != "off": inarray.tag.test_value = joined.tag.test_value replace = {} last_idx = 0 for var in vars: shape = point[var.name].shape arr_len = np.prod(shape, dtype=int) replace[var] = reshape_t(inarray[last_idx : last_idx + arr_len], shape).astype(var.dtype) last_idx += arr_len replace.update(shared) xs_special = [aesara.clone_replace(x, replace, rebuild_strict=False) for x in xs] return xs_special, inarray def reshape_t(x, shape): """Work around fact that x.reshape(()) doesn't work""" if shape != (): return x.reshape(shape) else: return x[0] class PointFunc: """Wraps so a function so it takes a dict of arguments instead of arguments.""" def __init__(self, f): self.f = f def __call__(self, state): return self.f(**state) class CallableTensor: """Turns a symbolic variable with one input into a function that returns symbolic arguments with the one variable replaced with the input. """ def __init__(self, tensor): self.tensor = tensor def __call__(self, input): """Replaces the single input of symbolic variable to be the passed argument. Parameters ---------- input: TensorVariable """ (oldinput,) = inputvars(self.tensor) return aesara.clone_replace(self.tensor, {oldinput: input}, rebuild_strict=False) class GeneratorOp(Op): """ Generator Op is designed for storing python generators inside aesara graph. __call__ creates TensorVariable It has 2 new methods - var.set_gen(gen): sets new generator - var.set_default(value): sets new default value (None erases default value) If generator is exhausted, variable will produce default value if it is not None, else raises `StopIteration` exception that can be caught on runtime. Parameters ---------- gen: generator that implements __next__ (py3) or next (py2) method and yields np.arrays with same types default: np.array with the same type as generator produces """ __props__ = ("generator",) def __init__(self, gen, default=None): from pymc.data import GeneratorAdapter super().__init__() if not isinstance(gen, GeneratorAdapter): gen = GeneratorAdapter(gen) self.generator = gen self.set_default(default) def make_node(self, *inputs): gen_var = self.generator.make_variable(self) return Apply(self, [], [gen_var]) def perform(self, node, inputs, output_storage, params=None): if self.default is not None: output_storage[0][0] = next(self.generator, self.default) else: output_storage[0][0] = next(self.generator) def do_constant_folding(self, fgraph, node): return False __call__ = aesara.config.change_flags(compute_test_value="off")(Op.__call__) def set_gen(self, gen): from pymc.data import GeneratorAdapter if not isinstance(gen, GeneratorAdapter): gen = GeneratorAdapter(gen) if not gen.tensortype == self.generator.tensortype: raise ValueError("New generator should yield the same type") self.generator = gen def set_default(self, value): if value is None: self.default = None else: value = np.asarray(value, self.generator.tensortype.dtype) t1 = (False,) * value.ndim t2 = self.generator.tensortype.broadcastable if not t1 == t2: raise ValueError("Default value should have the same type as generator") self.default = value def generator(gen, default=None): """ Generator variable with possibility to set default value and new generator. If generator is exhausted variable will produce default value if it is not None, else raises `StopIteration` exception that can be caught on runtime. Parameters ---------- gen: generator that implements __next__ (py3) or next (py2) method and yields np.arrays with same types default: np.array with the same type as generator produces Returns ------- TensorVariable It has 2 new methods - var.set_gen(gen): sets new generator - var.set_default(value): sets new default value (None erases default value) """ return GeneratorOp(gen, default)() _at_rng = RandomStream() def at_rng(random_seed=None): """ Get the package-level random number generator or new with specified seed. Parameters ---------- random_seed: int If not None returns *new* aesara random generator without replacing package global one Returns ------- `aesara.tensor.random.utils.RandomStream` instance `aesara.tensor.random.utils.RandomStream` instance passed to the most recent call of `set_at_rng` """ if random_seed is None: return _at_rng else: ret = RandomStream(random_seed) return ret def set_at_rng(new_rng): """ Set the package-level random number generator. Parameters ---------- new_rng: `aesara.tensor.random.utils.RandomStream` instance The random number generator to use. """ # pylint: disable=global-statement global _at_rng # pylint: enable=global-statement if isinstance(new_rng, int): new_rng = RandomStream(new_rng) _at_rng = new_rng def floatX_array(x): return floatX(np.array(x)) def ix_(*args): """ Aesara np.ix_ analog See numpy.lib.index_tricks.ix_ for reference """ out = [] nd = len(args) for k, new in enumerate(args): if new is None: out.append(slice(None)) new = at.as_tensor(new) if new.ndim != 1: raise ValueError("Cross index must be 1 dimensional") new = new.reshape((1,) * k + (new.size,) + (1,) * (nd - k - 1)) out.append(new) return tuple(out) def largest_common_dtype(tensors): dtypes = { str(t.dtype) if hasattr(t, "dtype") else smartfloatX(np.asarray(t)).dtype for t in tensors } return np.stack([np.ones((), dtype=dtype) for dtype in dtypes]).dtype @node_rewriter(tracks=[CheckParameterValue]) def local_remove_check_parameter(fgraph, node): """Rewrite that removes Aeppl's CheckParameterValue This is used when compile_rv_inplace """ if isinstance(node.op, CheckParameterValue): return [node.inputs[0]] @node_rewriter(tracks=[CheckParameterValue]) def local_check_parameter_to_ninf_switch(fgraph, node): if isinstance(node.op, CheckParameterValue): logp_expr, *logp_conds = node.inputs if len(logp_conds) > 1: logp_cond = at.all(logp_conds) else: (logp_cond,) = logp_conds out = at.switch(logp_cond, logp_expr, -np.inf) out.name = node.op.msg if out.dtype != node.outputs[0].dtype: out = at.cast(out, node.outputs[0].dtype) return [out] aesara.compile.optdb["canonicalize"].register( "local_remove_check_parameter", local_remove_check_parameter, use_db_name_as_tag=False, ) aesara.compile.optdb["canonicalize"].register( "local_check_parameter_to_ninf_switch", local_check_parameter_to_ninf_switch, use_db_name_as_tag=False, ) def find_rng_nodes( variables: Iterable[Variable], ) -> List[Union[RandomStateSharedVariable, RandomGeneratorSharedVariable]]: """Return RNG variables in a graph""" return [ node for node in graph_inputs(variables) if isinstance(node, (RandomStateSharedVariable, RandomGeneratorSharedVariable)) ] SeedSequenceSeed = Optional[Union[int, Sequence[int], np.ndarray, np.random.SeedSequence]] def reseed_rngs( rngs: Sequence[SharedVariable], seed: SeedSequenceSeed, ) -> None: """Create a new set of RandomState/Generator for each rng based on a seed""" bit_generators = [ np.random.PCG64(sub_seed) for sub_seed in np.random.SeedSequence(seed).spawn(len(rngs)) ] for rng, bit_generator in zip(rngs, bit_generators): new_rng: Union[np.random.RandomState, np.random.Generator] if isinstance(rng, at.random.var.RandomStateSharedVariable): new_rng = np.random.RandomState(bit_generator) else: new_rng = np.random.Generator(bit_generator) rng.set_value(new_rng, borrow=True) def compile_pymc( inputs, outputs, random_seed: SeedSequenceSeed = None, mode=None, **kwargs, ) -> Callable[..., Union[np.ndarray, List[np.ndarray]]]: """Use ``aesara.function`` with specialized pymc rewrites always enabled. This function also ensures shared RandomState/Generator used by RandomVariables in the graph are updated across calls, to ensure independent draws. Parameters ---------- inputs: list of TensorVariables, optional Inputs of the compiled Aesara function outputs: list of TensorVariables, optional Outputs of the compiled Aesara function random_seed: int, array-like of int or SeedSequence, optional Seed used to override any RandomState/Generator shared variables in the graph. If not specified, the value of original shared variables will still be overwritten. mode: optional Aesara mode used to compile the function Included rewrites ----------------- random_make_inplace Ensures that compiled functions containing random variables will produce new samples on each call. local_check_parameter_to_ninf_switch Replaces Aeppl's CheckParameterValue assertions is logp expressions with Switches that return -inf in place of the assert. Optional rewrites ----------------- local_remove_check_parameter Replaces Aeppl's CheckParameterValue assertions is logp expressions. This is used as an alteranative to the default local_check_parameter_to_ninf_switch whenenver this function is called within a model context and the model `check_bounds` flag is set to False. """ # Create an update mapping of RandomVariable's RNG so that it is automatically # updated after every function call rng_updates = {} output_to_list = outputs if isinstance(outputs, (list, tuple)) else [outputs] for random_var in ( var for var in vars_between(inputs, output_to_list) if var.owner and isinstance(var.owner.op, (RandomVariable, MeasurableVariable)) and var not in inputs ): # All nodes in `vars_between(inputs, outputs)` have owners. # But mypy doesn't know, so we just assert it: assert random_var.owner.op is not None if isinstance(random_var.owner.op, RandomVariable): rng = random_var.owner.inputs[0] if not hasattr(rng, "default_update"): rng_updates[rng] = random_var.owner.outputs[0] else: rng_updates[rng] = rng.default_update else: update_fn = getattr(random_var.owner.op, "update", None) if update_fn is not None: rng_updates.update(update_fn(random_var.owner)) # We always reseed random variables as this provides RNGs with no chances of collision if rng_updates: reseed_rngs(rng_updates.keys(), random_seed) # If called inside a model context, see if check_bounds flag is set to False try: from pymc.model import modelcontext model = modelcontext(None) check_bounds = model.check_bounds except TypeError: check_bounds = True check_parameter_opt = ( "local_check_parameter_to_ninf_switch" if check_bounds else "local_remove_check_parameter" ) mode = get_mode(mode) opt_qry = mode.provided_optimizer.including("random_make_inplace", check_parameter_opt) mode = Mode(linker=mode.linker, optimizer=opt_qry) aesara_function = aesara.function( inputs, outputs, updates={**rng_updates, **kwargs.pop("updates", {})}, mode=mode, **kwargs, ) return aesara_function