Source code for gemseo.formulations.idf

# Copyright 2021 IRT Saint Exupéry,
# This program is free software; you can redistribute it and/or
# modify it under the terms of the GNU Lesser General Public
# License version 3 as published by the Free Software Foundation.
# This program is distributed in the hope that it will be useful,
# but WITHOUT ANY WARRANTY; without even the implied warranty of
# Lesser General Public License for more details.
# You should have received a copy of the GNU Lesser General Public License
# along with this program; if not, write to the Free Software Foundation,
# Inc., 51 Franklin Street, Fifth Floor, Boston, MA  02110-1301, USA.
# Contributors:
#    INITIAL AUTHORS - initial API and implementation and/or
#                        initial documentation
#        :author: Francois Gallard, Charlie Vanaret
"""The Individual Discipline Feasible (IDF) formulation."""
from __future__ import annotations

import logging
from typing import Iterable
from typing import Sequence

from numpy import abs as np_abs
from numpy import concatenate
from numpy import eye
from numpy import ndarray
from numpy import ones_like
from numpy import zeros

from gemseo.algos.design_space import DesignSpace
from gemseo.core.chain import MDOParallelChain
from gemseo.core.coupling_structure import MDOCouplingStructure
from gemseo.core.discipline import MDODiscipline
from gemseo.core.execution_sequence import ExecutionSequence
from gemseo.core.execution_sequence import ExecutionSequenceFactory
from gemseo.core.formulation import MDOFormulation
from gemseo.core.mdofunctions.consistency_constraint import ConsistencyCstr
from gemseo.core.mdofunctions.function_from_discipline import FunctionFromDiscipline
from gemseo.core.mdofunctions.mdo_function import MDOFunction
from gemseo.mda.mda_chain import MDAChain

LOGGER = logging.getLogger(__name__)

[docs]class IDF(MDOFormulation): """The Individual Discipline Feasible (IDF) formulation. This formulation draws an optimization architecture where the coupling variables of strongly coupled disciplines is made consistent by adding equality constraints on the coupling variables at top level, the optimization problem with respect to the local, global design variables and coupling variables is made at the top level. The disciplinary analysis is made at each optimization iteration while the multidisciplinary analysis is made at the optimum. """ def __init__( self, disciplines: Sequence[MDODiscipline], objective_name: str, design_space: DesignSpace, maximize_objective: bool = False, normalize_constraints: bool = True, n_processes: int = 1, use_threading: bool = True, start_at_equilibrium: bool = False, grammar_type: str = MDODiscipline.JSON_GRAMMAR_TYPE, ) -> None: """ Args: normalize_constraints: If True, the outputs of the coupling consistency constraints are scaled. n_processes: The maximum simultaneous number of threads, if ``use_threading`` is True, or processes otherwise, used to parallelize the execution. use_threading: Whether to use threads instead of processes to parallelize the execution; multiprocessing will copy (serialize) all the disciplines, while threading will share all the memory. This is important to note if you want to execute the same discipline multiple times, you shall use multiprocessing. start_at_equilibrium: If True, an MDA is used to initialize the coupling variables. """ super().__init__( disciplines, objective_name, design_space, maximize_objective=maximize_objective, grammar_type=grammar_type, ) if n_processes > 1: "Running IDF formulation in parallel on n_processes = %s", n_processes, ) self._parallel_exec = MDOParallelChain( self.disciplines, use_threading=use_threading, grammar_type=grammar_type, n_processes=n_processes, ) else: self._parallel_exec = None self.coupling_structure = MDOCouplingStructure(disciplines) self.all_couplings = self.coupling_structure.all_couplings self._update_design_space() self.normalize_constraints = normalize_constraints self._build_constraints() self._build_objective_from_disc(objective_name) if start_at_equilibrium: self._compute_equilibrium() def _compute_equilibrium(self) -> None: """Run an MDA to compute the initial target couplings at equilibrium. The values at equilibrium are set in the initial design space. """ current_x = self.design_space.get_current_value(as_dict=True) # run MDA to initialize target coupling variables mda = MDAChain(self.disciplines) res = mda.execute(current_x) for name in self.all_couplings: value = res[name] "IDF: changing the initial value of %s " "from %s to %s (equilibrium)", name, str(current_x[name]), str(value), ) self.design_space.set_current_variable(name, value) def _update_design_space(self): """Update the design space with the required variables.""" strong_couplings = set(self.all_couplings) variables_names = set(self.opt_problem.design_space.variables_names) if not strong_couplings.issubset(variables_names): missing = strong_couplings - variables_names raise ValueError( "IDF formulation needs coupling variables as design variables, " f"missing variables: {missing}." ) self._set_default_input_values_from_design_space()
[docs] def get_top_level_disc(self) -> list[MDODiscipline]: # All functions and constraints are built from the top level disc # If we are in parallel mode: return the parallel execution if self._parallel_exec is not None: return [self._parallel_exec] # Otherwise the disciplines are top level return self.disciplines
def _get_normalization_factor( self, output_couplings: Iterable[str], ) -> ndarray: """Compute [abs(ub-lb)] for all output couplings. Args: output_couplings: The names of the variables for normalization. Returns: The concatenation of the normalization factors for all output couplings. """ norm_fact = [] for output in output_couplings: u_b = self.design_space.get_upper_bound(output) l_b = self.design_space.get_lower_bound(output) norm_fact.append(np_abs(u_b - l_b)) return concatenate(norm_fact) def _generate_consistency_cstr( self, output_couplings: Sequence[str], ) -> MDOFunction: """Generate the consistency constraints for a discipline. Args: output_couplings: The names of the output couplings. Returns: A function computing the consistency constraints. """ coupl_func = FunctionFromDiscipline(output_couplings, self) dv_names_of_disc = coupl_func.args if self.normalize_constraints: norm_fact = self._get_normalization_factor(output_couplings) else: norm_fact = 1.0 def coupl_min_x( x_vec: ndarray, ) -> ndarray: """Function to compute the consistency constraints. Args: x_vect: The design variable vector. Returns: The value of the consistency constraints. Equal to zero if the disciplines are at equilibrium. """ x_sw = self.mask_x_swap_order(output_couplings, x_vec) coupl = coupl_func(x_vec) if self.normalize_constraints: return (coupl - x_sw) / norm_fact return coupl - x_sw def coupl_min_x_jac( x_vec: ndarray, ) -> ndarray: """Function to compute the gradient of the consistency constraints. Args: x_vect: The design variable vector. Returns: The value of the gradient of the consistency constraints. """ coupl_jac = coupl_func.jac(x_vec) # pylint: disable=E1102 if len(coupl_jac.shape) > 1: # IN this case it is harder since a block diagonal # matrix with -Id should be placed for each output # coupling, at the right place n_outs = coupl_jac.shape[0] x_jac_2d = zeros((n_outs, len(x_vec)), dtype=x_vec.dtype) x_names = self.get_optim_variables_names() o_min = 0 o_max = 0 for out in output_couplings: # self._reference_input_data[out].size o_len = self._get_dv_length(out) i_min = 0 i_max = 0 o_max += o_len for x_i in x_names: # self._reference_input_data[x_i].size x_len = self._get_dv_length(x_i) i_max += x_len if x_i == out: x_jac_2d[o_min:o_max, i_min:i_max] = eye(x_len) i_min = i_max o_min = o_max x_jac = x_jac_2d else: # This is surprising but there is a duality between the masking # operation in the function inputs and the unmasking of its # outputs x_jac = self.unmask_x_swap_order(output_couplings, ones_like(x_vec)) if self.normalize_constraints: return (coupl_jac - x_jac) / norm_fact[:, None] return coupl_jac - x_jac expr = "" for out_c in output_couplings: expr += out_c + "(" + ", ".join(dv_names_of_disc) + ") - " expr += str(out_c) + "" + "\n" name = return MDOFunction( coupl_min_x, name, args=dv_names_of_disc, expr=expr, jac=coupl_min_x_jac, outvars=coupl_func.outvars, f_type=MDOFunction.TYPE_EQ, ) def _build_constraints(self) -> None: """Build the constraints. In IDF formulation, the consistency constraints are "y - y_copy = 0". """ # Building constraints per generator couplings for discipline in self.disciplines: couplings = self.coupling_structure.get_output_couplings( discipline, strong=False ) if couplings: cstr = ConsistencyCstr(couplings, self) self.opt_problem.add_eq_constraint(cstr)
[docs] def get_expected_workflow( self, ) -> list[ExecutionSequence, tuple[ExecutionSequence]]: return ExecutionSequenceFactory.parallel(self.disciplines)
[docs] def get_expected_dataflow( self, ) -> list[tuple[MDODiscipline, MDODiscipline, list[str]]]: return []