diff --git a/rrompy/reduction_methods/standard/greedy/generic_greedy_approximant.py b/rrompy/reduction_methods/standard/greedy/generic_greedy_approximant.py
index ccd31d9..30b923a 100644
--- a/rrompy/reduction_methods/standard/greedy/generic_greedy_approximant.py
+++ b/rrompy/reduction_methods/standard/greedy/generic_greedy_approximant.py
@@ -1,651 +1,644 @@
# Copyright (C) 2018 by the RROMPy authors
#
# This file is part of RROMPy.
#
# RROMPy is free software: you can redistribute it and/or modify
# it under the terms of the GNU Lesser General Public License as published by
# the Free Software Foundation, either version 3 of the License, or
# (at your option) any later version.
#
# RROMPy is distributed in the hope that it will be useful,
# but WITHOUT ANY WARRANTY; without even the implied warranty of
# MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
# GNU Lesser General Public License for more details.
#
# You should have received a copy of the GNU Lesser General Public License
# along with RROMPy. If not, see .
#
from abc import abstractmethod
from copy import deepcopy as copy
import numpy as np
from matplotlib import pyplot as plt
from rrompy.hfengines.base.linear_affine_engine import checkIfAffine
from rrompy.reduction_methods.standard.generic_standard_approximant import (
GenericStandardApproximant)
from rrompy.utilities.base.types import (Np1D, Np2D, Tuple, List, normEng,
paramVal, paramList, sampList)
from rrompy.utilities.base import verbosityManager as vbMng
from rrompy.utilities.numerical import dot
from rrompy.utilities.expression import expressionEvaluator
from rrompy.solver import normEngine
from rrompy.utilities.exception_manager import (RROMPyException, RROMPyAssert,
RROMPyWarning)
from rrompy.sampling.sample_list import sampleList
from rrompy.parameter import emptyParameterList, parameterList
from rrompy.utilities.parallel import masterCore
__all__ = ['GenericGreedyApproximant']
def localL2Distance(mus:Np2D, badmus:Np2D) -> Np2D:
return np.linalg.norm(np.tile(mus[..., np.newaxis], [1, 1, len(badmus)])
- badmus[..., np.newaxis].T, axis = 1)
def pruneSamples(mus:paramList, badmus:paramList,
tol : float = 1e-8) -> Np1D:
"""Remove from mus all the elements which are too close to badmus."""
if isinstance(mus, (parameterList, sampleList)): mus = mus.data
if isinstance(badmus, (parameterList, sampleList)): badmus = badmus.data
if len(badmus) == 0: return np.arange(len(mus))
proximity = np.min(localL2Distance(mus, badmus), axis = 1)
return np.where(proximity <= tol)[0]
class GenericGreedyApproximant(GenericStandardApproximant):
"""
ROM greedy interpolant computation for parametric problems
(ABSTRACT).
Args:
HFEngine: HF problem solver.
mu0(optional): Default parameter. Defaults to 0.
approxParameters(optional): Dictionary containing values for main
parameters of approximant. Recognized keys are:
- 'POD': whether to compute POD of snapshots; defaults to True;
- 'scaleFactorDer': scaling factors for derivative computation;
defaults to 'AUTO';
- 'S': number of starting training points;
- 'sampler': sample point generator;
- 'greedyTol': uniform error tolerance for greedy algorithm;
defaults to 1e-2;
- 'collinearityTol': collinearity tolerance for greedy algorithm;
defaults to 0.;
- 'maxIter': maximum number of greedy steps; defaults to 1e2;
- 'nTestPoints': number of test points; defaults to 5e2;
- 'trainSetGenerator': training sample points generator; defaults
to sampler.
Defaults to empty dict.
approx_state(optional): Whether to approximate state. Defaults to
False.
verbosity(optional): Verbosity level. Defaults to 10.
Attributes:
HFEngine: HF problem solver.
mu0: Default parameter.
mus: Array of snapshot parameters.
approxParameters: Dictionary containing values for main parameters of
approximant. Recognized keys are in parameterList.
parameterListSoft: Recognized keys of soft approximant parameters:
- 'POD': whether to compute POD of snapshots;
- 'scaleFactorDer': scaling factors for derivative computation;
- 'greedyTol': uniform error tolerance for greedy algorithm;
- 'collinearityTol': collinearity tolerance for greedy algorithm;
- 'maxIter': maximum number of greedy steps;
- 'nTestPoints': number of test points;
- 'trainSetGenerator': training sample points generator.
parameterListCritical: Recognized keys of critical approximant
parameters:
- 'S': total number of samples current approximant relies upon;
- 'sampler': sample point generator.
approx_state: Whether to approximate state.
verbosity: Verbosity level.
POD: whether to compute POD of snapshots.
scaleFactorDer: Scaling factors for derivative computation.
S: number of test points.
sampler: Sample point generator.
greedyTol: Uniform error tolerance for greedy algorithm.
collinearityTol: Collinearity tolerance for greedy algorithm.
maxIter: maximum number of greedy steps.
nTestPoints: number of starting training points.
trainSetGenerator: training sample points generator.
muBounds: list of bounds for parameter values.
samplingEngine: Sampling engine.
estimatorNormEngine: Engine for estimator norm computation.
uHF: High fidelity solution(s) with parameter(s) lastSolvedHF as
sampleList.
lastSolvedHF: Parameter(s) corresponding to last computed high fidelity
solution(s) as parameterList.
uApproxReduced: Reduced approximate solution(s) with parameter(s)
lastSolvedApprox as sampleList.
lastSolvedApproxReduced: Parameter(s) corresponding to last computed
reduced approximate solution(s) as parameterList.
uApprox: Approximate solution(s) with parameter(s) lastSolvedApprox as
sampleList.
lastSolvedApprox: Parameter(s) corresponding to last computed
approximate solution(s) as parameterList.
"""
def __init__(self, *args, **kwargs):
self._preInit()
self._addParametersToList(["greedyTol", "collinearityTol", "maxIter",
"nTestPoints"], [1e-2, 0., 1e2, 5e2],
["trainSetGenerator"], ["AUTO"])
super().__init__(*args, **kwargs)
self._postInit()
@property
def greedyTol(self):
"""Value of greedyTol."""
return self._greedyTol
@greedyTol.setter
def greedyTol(self, greedyTol):
if greedyTol < 0:
raise RROMPyException("greedyTol must be non-negative.")
if hasattr(self, "_greedyTol") and self.greedyTol is not None:
greedyTolold = self.greedyTol
else:
greedyTolold = -1
self._greedyTol = greedyTol
self._approxParameters["greedyTol"] = self.greedyTol
if greedyTolold != self.greedyTol:
self.resetSamples()
@property
def collinearityTol(self):
"""Value of collinearityTol."""
return self._collinearityTol
@collinearityTol.setter
def collinearityTol(self, collinearityTol):
if collinearityTol < 0:
raise RROMPyException("collinearityTol must be non-negative.")
if (hasattr(self, "_collinearityTol")
and self.collinearityTol is not None):
collinearityTolold = self.collinearityTol
else:
collinearityTolold = -1
self._collinearityTol = collinearityTol
self._approxParameters["collinearityTol"] = self.collinearityTol
if collinearityTolold != self.collinearityTol:
self.resetSamples()
@property
def maxIter(self):
"""Value of maxIter."""
return self._maxIter
@maxIter.setter
def maxIter(self, maxIter):
if maxIter <= 0: raise RROMPyException("maxIter must be positive.")
if hasattr(self, "_maxIter") and self.maxIter is not None:
maxIterold = self.maxIter
else:
maxIterold = -1
self._maxIter = maxIter
self._approxParameters["maxIter"] = self.maxIter
if maxIterold != self.maxIter:
self.resetSamples()
@property
def nTestPoints(self):
"""Value of nTestPoints."""
return self._nTestPoints
@nTestPoints.setter
def nTestPoints(self, nTestPoints):
if nTestPoints <= 0:
raise RROMPyException("nTestPoints must be positive.")
if not np.isclose(nTestPoints, np.int(nTestPoints)):
raise RROMPyException("nTestPoints must be an integer.")
nTestPoints = np.int(nTestPoints)
if hasattr(self, "_nTestPoints") and self.nTestPoints is not None:
nTestPointsold = self.nTestPoints
else:
nTestPointsold = -1
self._nTestPoints = nTestPoints
self._approxParameters["nTestPoints"] = self.nTestPoints
if nTestPointsold != self.nTestPoints:
self.resetSamples()
@property
def trainSetGenerator(self):
"""Value of trainSetGenerator."""
return self._trainSetGenerator
@trainSetGenerator.setter
def trainSetGenerator(self, trainSetGenerator):
if (isinstance(trainSetGenerator, (str,))
and trainSetGenerator.upper() == "AUTO"):
trainSetGenerator = self.sampler
if 'generatePoints' not in dir(trainSetGenerator):
raise RROMPyException("trainSetGenerator type not recognized.")
if (hasattr(self, '_trainSetGenerator')
and self.trainSetGenerator not in [None, "AUTO"]):
trainSetGeneratorOld = self.trainSetGenerator
self._trainSetGenerator = trainSetGenerator
self._approxParameters["trainSetGenerator"] = self.trainSetGenerator
if (not 'trainSetGeneratorOld' in locals()
or trainSetGeneratorOld != self.trainSetGenerator):
self.resetSamples()
def resetSamples(self):
"""Reset samples."""
super().resetSamples()
self._mus = emptyParameterList()
def initEstimatorNormEngine(self, normEngn : normEng = None):
"""Initialize estimator norm engine."""
if (normEngn is not None or not hasattr(self, "estimatorNormEngine")
or self.estimatorNormEngine is None):
if normEngn is None:
if self.approx_state:
if not hasattr(self.HFEngine, "energyNormDualMatrix"):
self.HFEngine.buildEnergyNormDualForm()
estimatorEnergyMatrix = self.HFEngine.energyNormDualMatrix
else:
estimatorEnergyMatrix = self.HFEngine.outputNormMatrix
else:
if hasattr(normEngn, "buildEnergyNormDualForm"):
if not hasattr(normEngn, "energyNormDualMatrix"):
normEngn.buildEnergyNormDualForm()
estimatorEnergyMatrix = normEngn.energyNormDualMatrix
else:
estimatorEnergyMatrix = normEngn
self.estimatorNormEngine = normEngine(estimatorEnergyMatrix)
def _affineResidualMatricesContraction(self, rb:Np2D, rA : Np2D = None) \
-> Tuple[Np1D, Np1D, Np1D]:
self.assembleReducedResidualBlocks(full = rA is not None)
# 'ij,jk,ik->k', resbb, radiusb, radiusb.conj()
ff = np.sum(self.trainedModel.data.resbb.dot(rb) * rb.conj(), axis = 0)
if rA is None: return ff
# 'ijk,jkl,il->l', resAb, radiusA, radiusb.conj()
Lf = np.sum(np.tensordot(self.trainedModel.data.resAb, rA, 2)
* rb.conj(), axis = 0)
# 'ijkl,klt,ijt->t', resAA, radiusA, radiusA.conj()
LL = np.sum(np.tensordot(self.trainedModel.data.resAA, rA, 2)
* rA.conj(), axis = (0, 1))
return ff, Lf, LL
def getErrorEstimatorAffine(self, mus:Np1D) -> Np1D:
"""Standard residual estimator."""
checkIfAffine(self.HFEngine, "apply affinity-based error estimator")
self.HFEngine.buildA()
self.HFEngine.buildb()
mus = self.checkParameterList(mus)
tMverb, self.trainedModel.verbosity = self.trainedModel.verbosity, 0
uApproxRs = self.getApproxReduced(mus).data
self.trainedModel.verbosity = tMverb
muTestEff = self.HFEngine.mapParameterList(mus)
radiusA = np.empty((len(self.HFEngine.thAs), len(mus)),
dtype = np.complex)
radiusb = np.empty((len(self.HFEngine.thbs), len(mus)),
dtype = np.complex)
for j, thA in enumerate(self.HFEngine.thAs):
radiusA[j] = expressionEvaluator(thA[0], muTestEff)
for j, thb in enumerate(self.HFEngine.thbs):
radiusb[j] = expressionEvaluator(thb[0], muTestEff)
radiusA = np.expand_dims(uApproxRs, 1) * radiusA
ff, Lf, LL = self._affineResidualMatricesContraction(radiusb, radiusA)
err = np.abs((LL - 2. * np.real(Lf) + ff) / ff) ** .5
return err
def errorEstimator(self, mus:Np1D, return_max : bool = False) -> Np1D:
setupOK = self.setupApproxLocal()
if setupOK > 0:
err = np.empty(len(mus))
err[:] = np.nan
if not return_max: return err
return err, [- setupOK], np.nan
mus = self.checkParameterList(mus)
vbMng(self.trainedModel, "INIT",
"Evaluating error estimator at mu = {}.".format(mus), 10)
err = self.getErrorEstimatorAffine(mus)
vbMng(self.trainedModel, "DEL", "Done evaluating error estimator", 10)
if not return_max: return err
idxMaxEst = [np.argmax(err)]
return err, idxMaxEst, err[idxMaxEst]
def _isLastSampleCollinear(self) -> bool:
"""Check collinearity of last sample."""
if self.collinearityTol <= 0.: return False
if self.POD:
reff = self.samplingEngine.RPOD[:, -1]
else:
RROMPyWarning(("Repeated orthogonalization of the samples for "
"collinearity check. Consider setting POD to "
"True."))
if not hasattr(self, "_PODEngine"):
from rrompy.sampling import PODEngine
self._PODEngine = PODEngine(self.HFEngine)
reff = self._PODEngine.generalizedQR(self.samplingEngine.samples,
only_R = True,
is_state = True)[:, -1]
cLevel = np.abs(reff[-1]) / np.linalg.norm(reff)
cLevel = np.inf if np.isclose(cLevel, 0.) else cLevel ** -1.
vbMng(self, "MAIN", "Collinearity indicator {:.4e}.".format(cLevel), 3)
return cLevel > self.collinearityTol
def plotEstimator(self, est:Np1D, idxMax:List[int], estMax:List[float]):
if (not (np.any(np.isnan(est)) or np.any(np.isinf(est)))
and masterCore()):
fig = plt.figure(figsize = plt.figaspect(1. / self.npar))
for jpar in range(self.npar):
ax = fig.add_subplot(1, self.npar, 1 + jpar)
musre = np.array(self.muTest.re.data)
errCP = copy(est)
idx = np.delete(np.arange(self.npar), jpar)
while len(musre) > 0:
if self.npar == 1:
currIdx = np.arange(len(musre))
else:
currIdx = np.where(np.isclose(np.sum(
np.abs(musre[:, idx] - musre[0, idx]), 1), 0.))[0]
ax.semilogy(musre[currIdx, jpar], errCP[currIdx], 'k',
linewidth = 1)
musre = np.delete(musre, currIdx, 0)
errCP = np.delete(errCP, currIdx)
ax.semilogy([self.muBounds.re(0, jpar),
self.muBounds.re(-1, jpar)],
[self.greedyTol] * 2, 'r--')
ax.semilogy(self.mus.re(jpar),
2. * self.greedyTol * np.ones(len(self.mus)), '*m')
if len(idxMax) > 0 and estMax is not None:
ax.semilogy(self.muTest.re(idxMax, jpar), estMax, 'xr')
ax.set_xlim(*list(self.sampler.lims.re(jpar)))
ax.grid()
plt.tight_layout()
plt.show()
def greedyNextSample(self, muidx:int, plotEst : str = "NONE")\
-> Tuple[Np1D, int, float, paramVal]:
"""Compute next greedy snapshot of solution map."""
RROMPyAssert(self._mode, message = "Cannot add greedy sample.")
mus = copy(self.muTest[muidx])
self.muTest.pop(muidx)
for j, mu in enumerate(mus):
vbMng(self, "MAIN",
("Adding sample point no. {} at {} to training "
"set.").format(len(self.mus) + 1, mu), 3)
self.mus.append(mu)
self._S = len(self.mus)
self._approxParameters["S"] = self.S
if (self.samplingEngine.nsamples <= len(mus) - j - 1
or not np.allclose(mu, self.samplingEngine.mus[j - len(mus)])):
self.samplingEngine.nextSample(mu)
if self._isLastSampleCollinear():
vbMng(self, "MAIN",
("Collinearity above tolerance detected. Starting "
"preemptive greedy loop termination."), 3)
self._collinearityFlag = 1
errorEstTest = np.empty(len(self.muTest))
errorEstTest[:] = np.nan
return errorEstTest, [-1], np.nan, np.nan
errorEstTest, muidx, maxErrorEst = self.errorEstimator(self.muTest,
True)
if plotEst == "ALL":
self.plotEstimator(errorEstTest, muidx, maxErrorEst)
return errorEstTest, muidx, maxErrorEst, self.muTest[muidx]
def _preliminaryTraining(self):
"""Initialize starting snapshots of solution map."""
RROMPyAssert(self._mode, message = "Cannot start greedy algorithm.")
if self.samplingEngine.nsamples > 0: return
self.resetSamples()
self.computeScaleFactor()
self.samplingEngine.scaleFactor = self.scaleFactorDer
self.mus = self.trainSetGenerator.generatePoints(self.S)
while len(self.mus) > self.S: self.mus.pop()
muTestBase = self.sampler.generatePoints(self.nTestPoints, False)
idxPop = pruneSamples(self.HFEngine.mapParameterList(muTestBase),
self.HFEngine.mapParameterList(self.mus),
1e-10 * self.scaleFactor[0])
muTestBase.pop(idxPop)
muLast = copy(self.mus[-1])
self.mus.pop()
if len(self.mus) > 0:
vbMng(self, "MAIN",
("Adding first {} sample point{} at {} to training "
"set.").format(self.S - 1, "" + "s" * (self.S > 2),
self.mus), 3)
self.samplingEngine.iterSample(self.mus)
self._S = len(self.mus)
self._approxParameters["S"] = self.S
self.muTest = emptyParameterList()
self.muTest.reset((len(muTestBase) + 1, self.mus.shape[1]))
self.muTest[: -1] = muTestBase.data
self.muTest[-1] = muLast.data
@abstractmethod
def setupApproxLocal(self) -> int:
if self.checkComputedApprox(): return -1
RROMPyAssert(self._mode, message = "Cannot setup approximant.")
vbMng(self, "INIT", "Setting up local approximant.", 5)
pass
vbMng(self, "DEL", "Done setting up local approximant.", 5)
return 0
def setupApprox(self, plotEst : str = "NONE") -> int:
"""Compute greedy snapshots of solution map."""
if self.checkComputedApprox(): return -1
RROMPyAssert(self._mode, message = "Cannot start greedy algorithm.")
vbMng(self, "INIT", "Starting computation of snapshots.", 3)
self._collinearityFlag = 0
self._preliminaryTraining()
muidx, self.firstGreedyIter = [len(self.muTest) - 1], True
errorEstTest, maxErrorEst = [np.inf], np.inf
max2ErrorEst, trainedModelOld = np.inf, None
while self.firstGreedyIter or (len(self.muTest) > 0
and (maxErrorEst is None or max2ErrorEst > self.greedyTol)
and self.samplingEngine.nsamples < self.maxIter):
muTestOld, errorEstTestOld = self.muTest, errorEstTest
muidxOld, maxErrorEstOld = muidx, maxErrorEst
- errorEstTest, muidx, maxErrorEst, mu = self.greedyNextSample(
- muidx, plotEst)
+ errorEstTest, muidx, maxErrorEst, mu = self.greedyNextSample(muidx,
+ plotEst)
if maxErrorEst is not None and (np.any(np.isnan(maxErrorEst))
or np.any(np.isinf(maxErrorEst))):
if self._collinearityFlag == 0 and not self.firstGreedyIter:
RROMPyWarning(("Instability in a posteriori "
"estimator. Starting preemptive greedy "
"loop termination."))
self.muTest, errorEstTest = muTestOld, errorEstTestOld
- self.mus.pop(-1)
- self.samplingEngine.popSample()
- if self.firstGreedyIter:
- if muidx[0] < 0:
- self.trainedModel = None
- raise RROMPyException(("Instability in approximant "
- "computation. Aborting greedy "
- "iterations."))
- else:
- self._approxParameters = (
- trainedModelOld.data.approxParameters)
- self._S = trainedModelOld.data.approxParameters["S"]
- self._approxParameters["S"] = self.S
- self.trainedModel.data = copy(trainedModelOld.data)
+ if self.firstGreedyIter and muidx[0] < 0:
+ self.trainedModel = None
+ raise RROMPyException(("Instability in approximant "
+ "computation. Aborting greedy "
+ "iterations."))
+ self._S = trainedModelOld.data.approxParameters["S"]
+ self._approxParameters["S"] = self.S
+ while self.samplingEngine.nsamples > self.S:
+ self.samplingEngine.popSample()
+ while len(self.mus) > self.S: self.mus.pop(-1)
muidx, maxErrorEst = muidxOld, maxErrorEstOld
break
if maxErrorEst is not None:
max2ErrorEst = np.max(maxErrorEst)
vbMng(self, "MAIN", ("Uniform testing error estimate "
"{:.4e}.").format(max2ErrorEst), 3)
if self.firstGreedyIter:
trainedModelOld = copy(self.trainedModel)
else:
trainedModelOld.data = copy(self.trainedModel.data)
self.firstGreedyIter = False
+ vbMng(self, "DEL", ("Done computing snapshots (final snapshot count: "
+ "{}).").format(self.S), 3)
if (maxErrorEst is None or max2ErrorEst <= self.greedyTol
or np.any(np.isnan(maxErrorEst)) or np.any(np.isinf(maxErrorEst))):
while self.samplingEngine.nsamples > self.S:
self.samplingEngine.popSample()
while len(self.mus) > self.S: self.mus.pop(-1)
else:
- self._S = self.samplingEngine.nsamples
- self._approxParameters["S"] = self.S
while len(self.mus) < self.S:
self.mus.append(self.samplingEngine.mus[len(self.mus)])
self.setupApproxLocal()
if plotEst == "LAST":
self.plotEstimator(errorEstTest, muidx, maxErrorEst)
- vbMng(self, "DEL",
- ("Done computing snapshots (final snapshot count: "
- "{}).").format(self.samplingEngine.nsamples), 3)
return 0
def assembleReducedResidualGramian(self, pMat:sampList):
"""
Build residual gramian of reduced linear system through projections.
"""
self.initEstimatorNormEngine()
if (not hasattr(self.trainedModel.data, "gramian")
or self.trainedModel.data.gramian is None):
gramian = self.estimatorNormEngine.innerProduct(pMat, pMat)
else:
Sold = self.trainedModel.data.gramian.shape[0]
S = len(self.mus)
if Sold > S:
gramian = self.trainedModel.data.gramian[: S, : S]
else:
idxOld = list(range(Sold))
idxNew = list(range(Sold, S))
gramian = np.empty((S, S), dtype = np.complex)
gramian[: Sold, : Sold] = self.trainedModel.data.gramian
gramian[: Sold, Sold :] = (
self.estimatorNormEngine.innerProduct(pMat(idxNew),
pMat(idxOld)))
gramian[Sold :, : Sold] = gramian[: Sold, Sold :].T.conj()
gramian[Sold :, Sold :] = (
self.estimatorNormEngine.innerProduct(pMat(idxNew),
pMat(idxNew)))
self.trainedModel.data.gramian = gramian
def assembleReducedResidualBlocksbb(self, bs:List[Np1D]):
"""
Build blocks (of type bb) of reduced linear system through projections.
"""
self.initEstimatorNormEngine()
nbs = len(bs)
if (not hasattr(self.trainedModel.data, "resbb")
or self.trainedModel.data.resbb is None):
resbb = np.empty((nbs, nbs), dtype = np.complex)
for i in range(nbs):
Mbi = bs[i]
resbb[i, i] = self.estimatorNormEngine.innerProduct(Mbi, Mbi)
for j in range(i):
Mbj = bs[j]
resbb[i, j] = self.estimatorNormEngine.innerProduct(Mbj,
Mbi)
for i in range(nbs):
for j in range(i + 1, nbs):
resbb[i, j] = resbb[j, i].conj()
self.trainedModel.data.resbb = resbb
def assembleReducedResidualBlocksAb(self, As:List[Np2D], bs:List[Np1D],
pMat:sampList):
"""
Build blocks (of type Ab) of reduced linear system through projections.
"""
self.initEstimatorNormEngine()
nAs = len(As)
nbs = len(bs)
S = len(self.mus)
if (not hasattr(self.trainedModel.data, "resAb")
or self.trainedModel.data.resAb is None):
if isinstance(pMat, (parameterList, sampleList)): pMat = pMat.data
resAb = np.empty((nbs, S, nAs), dtype = np.complex)
for j in range(nAs):
MAj = dot(As[j], pMat)
for i in range(nbs):
Mbi = bs[i]
resAb[i, :, j] = self.estimatorNormEngine.innerProduct(MAj,
Mbi)
else:
Sold = self.trainedModel.data.resAb.shape[1]
if Sold == S: return
if Sold > S:
resAb = self.trainedModel.data.resAb[:, : S, :]
else:
if isinstance(pMat, (parameterList, sampleList)):
pMat = pMat.data
resAb = np.empty((nbs, S, nAs), dtype = np.complex)
resAb[:, : Sold, :] = self.trainedModel.data.resAb
for j in range(nAs):
MAj = dot(As[j], pMat[:, Sold :])
for i in range(nbs):
Mbi = bs[i]
resAb[i, Sold :, j] = (
self.estimatorNormEngine.innerProduct(MAj, Mbi))
self.trainedModel.data.resAb = resAb
def assembleReducedResidualBlocksAA(self, As:List[Np2D], pMat:sampList):
"""
Build blocks (of type AA) of reduced linear system through projections.
"""
self.initEstimatorNormEngine()
nAs = len(As)
S = len(self.mus)
if (not hasattr(self.trainedModel.data, "resAA")
or self.trainedModel.data.resAA is None):
if isinstance(pMat, (parameterList, sampleList)): pMat = pMat.data
resAA = np.empty((S, nAs, S, nAs), dtype = np.complex)
for i in range(nAs):
MAi = dot(As[i], pMat)
resAA[:, i, :, i] = (
self.estimatorNormEngine.innerProduct(MAi, MAi))
for j in range(i):
MAj = dot(As[j], pMat)
resAA[:, i, :, j] = (
self.estimatorNormEngine.innerProduct(MAj, MAi))
for i in range(nAs):
for j in range(i + 1, nAs):
resAA[:, i, :, j] = resAA[:, j, :, i].T.conj()
else:
Sold = self.trainedModel.data.resAA.shape[0]
if Sold == S: return
if Sold > S:
resAA = self.trainedModel.data.resAA[: S, :, : S, :]
else:
if isinstance(pMat, (parameterList, sampleList)):
pMat = pMat.data
resAA = np.empty((S, nAs, S, nAs), dtype = np.complex)
resAA[: Sold, :, : Sold, :] = self.trainedModel.data.resAA
for i in range(nAs):
MAi = dot(As[i], pMat)
resAA[: Sold, i, Sold :, i] = (
self.estimatorNormEngine.innerProduct(MAi[:, Sold :],
MAi[:, : Sold]))
resAA[Sold :, i, : Sold, i] = resAA[: Sold, i,
Sold :, i].T.conj()
resAA[Sold :, i, Sold :, i] = (
self.estimatorNormEngine.innerProduct(MAi[:, Sold :],
MAi[:, Sold :]))
for j in range(i):
MAj = dot(As[j], pMat)
resAA[: Sold, i, Sold :, j] = (
self.estimatorNormEngine.innerProduct(MAj[:, Sold :],
MAi[:, : Sold]))
resAA[Sold :, i, : Sold, j] = (
self.estimatorNormEngine.innerProduct(MAj[:, : Sold],
MAi[:, Sold :]))
resAA[Sold :, i, Sold :, j] = (
self.estimatorNormEngine.innerProduct(MAj[:, Sold :],
MAi[:, Sold :]))
for i in range(nAs):
for j in range(i + 1, nAs):
resAA[: Sold, i, Sold :, j] = (
resAA[Sold :, j, : Sold, i].T.conj())
resAA[Sold :, i, : Sold, j] = (
resAA[: Sold, j, Sold :, i].T.conj())
resAA[Sold :, i, Sold :, j] = (
resAA[Sold :, j, Sold :, i].T.conj())
self.trainedModel.data.resAA = resAA
def assembleReducedResidualBlocks(self, full : bool = False):
"""Build affine blocks of affine decomposition of residual."""
if full:
checkIfAffine(self.HFEngine, "assemble reduced residual blocks")
else:
checkIfAffine(self.HFEngine, "assemble reduced RHS blocks", True)
self.HFEngine.buildb()
self.assembleReducedResidualBlocksbb(self.HFEngine.bs)
if full:
pMat = self.samplingEngine.projectionMatrix
self.HFEngine.buildA()
self.assembleReducedResidualBlocksAb(self.HFEngine.As,
self.HFEngine.bs, pMat)
self.assembleReducedResidualBlocksAA(self.HFEngine.As, pMat)
diff --git a/rrompy/reduction_methods/standard/greedy/rational_interpolant_greedy.py b/rrompy/reduction_methods/standard/greedy/rational_interpolant_greedy.py
index 01bb945..e40f4cf 100644
--- a/rrompy/reduction_methods/standard/greedy/rational_interpolant_greedy.py
+++ b/rrompy/reduction_methods/standard/greedy/rational_interpolant_greedy.py
@@ -1,543 +1,544 @@
# Copyright (C) 2018 by the RROMPy authors
#
# This file is part of RROMPy.
#
# RROMPy is free software: you can redistribute it and/or modify
# it under the terms of the GNU Lesser General Public License as published by
# the Free Software Foundation, either version 3 of the License, or
# (at your option) any later version.
#
# RROMPy is distributed in the hope that it will be useful,
# but WITHOUT ANY WARRANTY; without even the implied warranty of
# MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
# GNU Lesser General Public License for more details.
#
# You should have received a copy of the GNU Lesser General Public License
# along with RROMPy. If not, see .
#
from copy import deepcopy as copy
import numpy as np
from rrompy.hfengines.base.linear_affine_engine import checkIfAffine
from .generic_greedy_approximant import GenericGreedyApproximant
from rrompy.utilities.poly_fitting.polynomial import (polybases, polyfitname,
PolynomialInterpolator as PI,
polyvander)
from rrompy.utilities.numerical import dot
from rrompy.utilities.numerical.degree import totalDegreeN
from rrompy.utilities.expression import expressionEvaluator
from rrompy.reduction_methods.standard import RationalInterpolant
from rrompy.utilities.base.types import Np1D, Tuple, paramVal, List
from rrompy.utilities.base.verbosity_depth import (verbosityManager as vbMng,
getVerbosityDepth, setVerbosityDepth)
from rrompy.utilities.poly_fitting import customFit
from rrompy.utilities.exception_manager import (RROMPyWarning, RROMPyException,
RROMPyAssert, RROMPy_FRAGILE)
from rrompy.sampling import sampleList, emptySampleList
__all__ = ['RationalInterpolantGreedy']
class RationalInterpolantGreedy(GenericGreedyApproximant, RationalInterpolant):
"""
ROM greedy rational interpolant computation for parametric problems.
Args:
HFEngine: HF problem solver.
mu0(optional): Default parameter. Defaults to 0.
approxParameters(optional): Dictionary containing values for main
parameters of approximant. Recognized keys are:
- 'POD': whether to compute POD of snapshots; defaults to True;
- 'scaleFactorDer': scaling factors for derivative computation;
defaults to 'AUTO';
- 'S': number of starting training points;
- 'sampler': sample point generator;
- 'greedyTol': uniform error tolerance for greedy algorithm;
defaults to 1e-2;
- 'collinearityTol': collinearity tolerance for greedy algorithm;
defaults to 0.;
- 'maxIter': maximum number of greedy steps; defaults to 1e2;
- 'nTestPoints': number of test points; defaults to 5e2;
- 'trainSetGenerator': training sample points generator; defaults
to sampler;
- 'polybasis': type of basis for interpolation; defaults to
'MONOMIAL';
- 'errorEstimatorKind': kind of error estimator; available values
include 'AFFINE', 'DISCREPANCY', 'LOOK_AHEAD',
'LOOK_AHEAD_RES', 'LOOK_AHEAD_OUTPUT', and 'NONE'; defaults to
'NONE';
- 'interpRcond': tolerance for interpolation; defaults to None;
- 'robustTol': tolerance for robust rational denominator
management; defaults to 0;
- 'correctorForce': whether corrector should forcefully delete bad
poles; defaults to False;
- 'correctorTol': tolerance for corrector step; defaults to 0.,
i.e. no bad poles;
- 'correctorMaxIter': maximum number of corrector iterations;
defaults to 1.
Defaults to empty dict.
approx_state(optional): Whether to approximate state. Defaults and must
be True.
verbosity(optional): Verbosity level. Defaults to 10.
Attributes:
HFEngine: HF problem solver.
mu0: Default parameter.
mus: Array of snapshot parameters.
approxParameters: Dictionary containing values for main parameters of
approximant. Recognized keys are in parameterList.
parameterListSoft: Recognized keys of soft approximant parameters:
- 'POD': whether to compute POD of snapshots;
- 'scaleFactorDer': scaling factors for derivative computation;
- 'greedyTol': uniform error tolerance for greedy algorithm;
- 'collinearityTol': collinearity tolerance for greedy algorithm;
- 'maxIter': maximum number of greedy steps;
- 'nTestPoints': number of test points;
- 'trainSetGenerator': training sample points generator;
- 'errorEstimatorKind': kind of error estimator;
- 'interpRcond': tolerance for interpolation;
- 'robustTol': tolerance for robust rational denominator
management;
- 'correctorForce': whether corrector should forcefully delete bad
poles;
- 'correctorTol': tolerance for corrector step;
- 'correctorMaxIter': maximum number of corrector iterations.
parameterListCritical: Recognized keys of critical approximant
parameters:
- 'S': total number of samples current approximant relies upon;
- 'sampler': sample point generator.
approx_state: Whether to approximate state.
verbosity: Verbosity level.
POD: whether to compute POD of snapshots.
scaleFactorDer: Scaling factors for derivative computation.
S: number of test points.
sampler: Sample point generator.
greedyTol: uniform error tolerance for greedy algorithm.
collinearityTol: Collinearity tolerance for greedy algorithm.
maxIter: maximum number of greedy steps.
nTestPoints: number of starting training points.
trainSetGenerator: training sample points generator.
robustTol: tolerance for robust rational denominator management.
correctorForce: Whether corrector should forcefully delete bad poles.
correctorTol: Tolerance for corrector step.
correctorMaxIter: Maximum number of corrector iterations.
errorEstimatorKind: kind of error estimator.
interpRcond: tolerance for interpolation.
robustTol: tolerance for robust rational denominator management.
muBounds: list of bounds for parameter values.
samplingEngine: Sampling engine.
estimatorNormEngine: Engine for estimator norm computation.
uHF: High fidelity solution(s) with parameter(s) lastSolvedHF as
sampleList.
lastSolvedHF: Parameter(s) corresponding to last computed high fidelity
solution(s) as parameterList.
uApproxReduced: Reduced approximate solution(s) with parameter(s)
lastSolvedApprox as sampleList.
lastSolvedApproxReduced: Parameter(s) corresponding to last computed
reduced approximate solution(s) as parameterList.
uApprox: Approximate solution(s) with parameter(s) lastSolvedApprox as
sampleList.
lastSolvedApprox: Parameter(s) corresponding to last computed
approximate solution(s) as parameterList.
"""
_allowedEstimatorKinds = ["AFFINE", "DISCREPANCY", "LOOK_AHEAD",
"LOOK_AHEAD_RES", "LOOK_AHEAD_OUTPUT", "NONE"]
def __init__(self, *args, **kwargs):
self._preInit()
self._addParametersToList(["errorEstimatorKind"], ["DISCREPANCY"],
toBeExcluded = ["M", "N", "polydegreetype",
"radialDirectionalWeights"])
super().__init__(*args, **kwargs)
if not self.approx_state and self.errorEstimatorKind not in [
"LOOK_AHEAD", "LOOK_AHEAD_OUTPUT", "NONE"]:
raise RROMPyException(("Must compute greedy approximation of "
"state, unless error estimator allows "
"otherwise."))
self._postInit()
@property
def approx_state(self):
"""Value of approx_state."""
return self._approx_state
@approx_state.setter
def approx_state(self, approx_state):
RationalInterpolant.approx_state.fset(self, approx_state)
if (not self.approx_state and hasattr(self, "_errorEstimatorKind")
and self.errorEstimatorKind not in [
"LOOK_AHEAD", "LOOK_AHEAD_OUTPUT", "NONE"]):
raise RROMPyException(("Must compute greedy approximation of "
"state, unless error estimator allows "
"otherwise."))
@property
def E(self):
"""Value of E."""
self._E = self.sampleBatchIdx - 1
return self._E
@E.setter
def E(self, E):
RROMPyWarning(("E is used just to simplify inheritance, and its value "
"cannot be changed from that of sampleBatchIdx - 1."))
def _setMAuto(self):
self.M = self.E
def _setNAuto(self):
self.N = self.E
@property
def polydegreetype(self):
"""Value of polydegreetype."""
return "TOTAL"
@polydegreetype.setter
def polydegreetype(self, polydegreetype):
RROMPyWarning(("polydegreetype is used just to simplify inheritance, "
"and its value cannot be changed from 'TOTAL'."))
@property
def polybasis(self):
"""Value of polybasis."""
return self._polybasis
@polybasis.setter
def polybasis(self, polybasis):
try:
polybasis = polybasis.upper().strip().replace(" ","")
if polybasis not in polybases:
raise RROMPyException("Sample type not recognized.")
self._polybasis = polybasis
except:
RROMPyWarning(("Prescribed polybasis not recognized. Overriding "
"to 'MONOMIAL'."))
self._polybasis = "MONOMIAL"
self._approxParameters["polybasis"] = self.polybasis
@property
def errorEstimatorKind(self):
"""Value of errorEstimatorKind."""
return self._errorEstimatorKind
@errorEstimatorKind.setter
def errorEstimatorKind(self, errorEstimatorKind):
errorEstimatorKind = errorEstimatorKind.upper()
if errorEstimatorKind not in self._allowedEstimatorKinds:
RROMPyWarning(("Error estimator kind not recognized. Overriding "
"to 'NONE'."))
errorEstimatorKind = "NONE"
self._errorEstimatorKind = errorEstimatorKind
self._approxParameters["errorEstimatorKind"] = self.errorEstimatorKind
if (self.errorEstimatorKind not in [
"LOOK_AHEAD", "LOOK_AHEAD_OUTPUT", "NONE"]
and hasattr(self, "_approx_state") and not self.approx_state):
raise RROMPyException(("Must compute greedy approximation of "
"state, unless error estimator allows "
"otherwise."))
def _polyvanderAuxiliary(self, mus, deg, *args):
return polyvander(mus, deg, *args)
def getErrorEstimatorDiscrepancy(self, mus:Np1D) -> Np1D:
"""Discrepancy-based residual estimator."""
checkIfAffine(self.HFEngine, "apply discrepancy-based error estimator")
mus = self.checkParameterList(mus)
muCTest = self.trainedModel.centerNormalize(mus)
tMverb, self.trainedModel.verbosity = self.trainedModel.verbosity, 0
QTest = self.trainedModel.getQVal(mus)
QTzero = np.where(QTest == 0.)[0]
if len(QTzero) > 0:
RROMPyWarning(("Adjusting estimator to avoid division by "
"numerically zero denominator."))
QTest[QTzero] = np.finfo(np.complex).eps / (1. + self.N)
self.HFEngine.buildA()
self.HFEngine.buildb()
nAs, nbs = self.HFEngine.nAs, self.HFEngine.nbs
muTrainEff = self.HFEngine.mapParameterList(self.mus)
muTestEff = self.HFEngine.mapParameterList(mus)
PTrain = self.trainedModel.getPVal(self.mus).data.T
QTrain = self.trainedModel.getQVal(self.mus)
QTzero = np.where(QTrain == 0.)[0]
if len(QTzero) > 0:
RROMPyWarning(("Adjusting estimator to avoid division by "
"numerically zero denominator."))
QTrain[QTzero] = np.finfo(np.complex).eps / (1. + self.N)
PTest = self.trainedModel.getPVal(mus).data
self.trainedModel.verbosity = tMverb
radiusAbTrain = np.empty((self.S, nAs * self.S + nbs),
dtype = np.complex)
radiusA = np.empty((self.S, nAs, len(mus)), dtype = np.complex)
radiusb = np.empty((nbs, len(mus)), dtype = np.complex)
for j, thA in enumerate(self.HFEngine.thAs):
idxs = j * self.S + np.arange(self.S)
radiusAbTrain[:, idxs] = expressionEvaluator(thA[0], muTrainEff,
(self.S, 1)) * PTrain
radiusA[:, j] = PTest * expressionEvaluator(thA[0], muTestEff,
(len(mus),))
for j, thb in enumerate(self.HFEngine.thbs):
idx = nAs * self.S + j
radiusAbTrain[:, idx] = QTrain * expressionEvaluator(thb[0],
muTrainEff, (self.S,))
radiusb[j] = QTest * expressionEvaluator(thb[0], muTestEff,
(len(mus),))
QRHSNorm2 = self._affineResidualMatricesContraction(radiusb)
vanTrain = self._polyvanderAuxiliary(self._musUniqueCN, self.E,
self.polybasis0, self._derIdxs,
self._reorder)
interpPQ = customFit(vanTrain, radiusAbTrain,
rcond = self.interpRcond)
vanTest = self._polyvanderAuxiliary(muCTest, self.E, self.polybasis0)
DradiusAb = vanTest.dot(interpPQ)
radiusA = (radiusA
- DradiusAb[:, : - nbs].reshape(len(mus), -1, self.S).T)
radiusb = radiusb - DradiusAb[:, - nbs :].T
ff, Lf, LL = self._affineResidualMatricesContraction(radiusb, radiusA)
err = np.abs((LL - 2. * np.real(Lf) + ff) / QRHSNorm2) ** .5
return err
def getErrorEstimatorLookAhead(self, mus:Np1D,
what : str = "") -> Tuple[Np1D, List[int]]:
"""Residual estimator based on look-ahead idea."""
errTest, QTest, idxMaxEst = self._EIMStep(mus)
_approx_state_old = self.approx_state
if what == "OUTPUT" and _approx_state_old: self._approx_state = False
self.initEstimatorNormEngine()
self._approx_state = _approx_state_old
mu_muTestSample = mus[idxMaxEst]
app_muTestSample = self.getApproxReduced(mu_muTestSample)
if self._mode == RROMPy_FRAGILE:
if what == "RES" and not self.HFEngine.isCEye:
raise RROMPyException(("Cannot compute LOOK_AHEAD_RES "
"estimator in fragile mode for "
"non-scalar C."))
app_muTestSample = dot(self.trainedModel.data.projMat[:,
: app_muTestSample.shape[0]],
app_muTestSample)
else:
app_muTestSample = dot(self.samplingEngine.projectionMatrix,
app_muTestSample)
if what == "RES":
errmu = self.HFEngine.residual(mu_muTestSample, app_muTestSample,
post_c = False)
solmu = self.HFEngine.residual(mu_muTestSample, None,
post_c = False)
else:
for j, mu in enumerate(mu_muTestSample):
uEx = self.samplingEngine.nextSample(mu)
if j == 0:
solmu = emptySampleList()
solmu.reset((len(uEx), len(mu_muTestSample)),
dtype = uEx.dtype)
solmu[j] = uEx
if what == "OUTPUT" and self.approx_state:
solmu = sampleList(self.HFEngine.applyC(solmu))
app_muTestSample = sampleList(self.HFEngine.applyC(
app_muTestSample))
errmu = solmu - app_muTestSample
errsamples = (self.estimatorNormEngine.norm(errmu)
/ self.estimatorNormEngine.norm(solmu))
musT = copy(self.mus)
musT.append(mu_muTestSample)
musT = self.trainedModel.centerNormalize(musT)
musC = self.trainedModel.centerNormalize(mus)
errT = np.zeros((len(musT), len(mu_muTestSample)), dtype = np.complex)
errT[np.arange(len(self.mus), len(musT)),
np.arange(len(mu_muTestSample))] = errsamples * QTest[idxMaxEst]
vanT = self._polyvanderAuxiliary(musT, self.E + 1, self.polybasis)
fitOut = customFit(vanT, errT, full = True, rcond = self.interpRcond)
vbMng(self, "MAIN",
("Fitting {} samples with degree {} through {}... Conditioning "
"of LS system: {:.4e}.").format(len(vanT), self.E + 1,
polyfitname(self.polybasis),
fitOut[1][2][0] / fitOut[1][2][-1]), 15)
vanC = self._polyvanderAuxiliary(musC, self.E + 1, self.polybasis)
err = np.sum(np.abs(vanC.dot(fitOut[0])), axis = -1) / QTest
return err, idxMaxEst
def getErrorEstimatorNone(self, mus:Np1D) -> Np1D:
"""EIM-based residual estimator."""
err = np.max(self._EIMStep(mus, True), axis = 1)
err *= self.greedyTol / np.mean(err)
return err
def _EIMStep(self, mus:Np1D,
only_one : bool = False) -> Tuple[Np1D, Np1D, List[int]]:
"""Residual estimator based on look-ahead idea."""
mus = self.checkParameterList(mus)
tMverb, self.trainedModel.verbosity = self.trainedModel.verbosity, 0
QTest = self.trainedModel.getQVal(mus)
QTzero = np.where(QTest == 0.)[0]
if len(QTzero) > 0:
RROMPyWarning(("Adjusting estimator to avoid division by "
"numerically zero denominator."))
QTest[QTzero] = np.finfo(np.complex).eps / (1. + self.N)
QTest = np.abs(QTest)
muCTest = self.trainedModel.centerNormalize(mus)
muCTrain = self.trainedModel.centerNormalize(self.mus)
self.trainedModel.verbosity = tMverb
vanTest = self._polyvanderAuxiliary(muCTest, self.E, self.polybasis)
vanTestNext = self._polyvanderAuxiliary(muCTest, self.E + 1,
self.polybasis)[:,
vanTest.shape[1] :]
idxsTest = np.arange(vanTestNext.shape[1])
basis = np.zeros((len(idxsTest), 0), dtype = float)
idxMaxEst = []
while len(idxsTest) > 0:
vanTrial = self._polyvanderAuxiliary(muCTrain, self.E,
self.polybasis)
vanTrialNext = self._polyvanderAuxiliary(muCTrain, self.E + 1,
self.polybasis)[:,
vanTrial.shape[1] :]
vanTrial = np.hstack((vanTrial, vanTrialNext.dot(basis).reshape(
len(vanTrialNext), basis.shape[1])))
valuesTrial = vanTrialNext[:, idxsTest]
vanTestEff = np.hstack((vanTest, vanTestNext.dot(basis).reshape(
len(vanTestNext), basis.shape[1])))
vanTestNextEff = vanTestNext[:, idxsTest]
try:
coeffTest = np.linalg.solve(vanTrial, valuesTrial)
except np.linalg.LinAlgError as e:
raise RROMPyException(e)
errTest = (np.abs(vanTestNextEff - vanTestEff.dot(coeffTest))
/ np.expand_dims(QTest, 1))
if only_one: return errTest
idxMaxErr = np.unravel_index(np.argmax(errTest), errTest.shape)
idxMaxEst += [idxMaxErr[0]]
muCTrain.append(muCTest[idxMaxErr[0]])
basis = np.pad(basis, [(0, 0), (0, 1)], "constant")
basis[idxsTest[idxMaxErr[1]], -1] = 1.
idxsTest = np.delete(idxsTest, idxMaxErr[1])
return errTest, QTest, idxMaxEst
def errorEstimator(self, mus:Np1D, return_max : bool = False) -> Np1D:
"""Standard residual-based error estimator."""
setupOK = self.setupApproxLocal()
if setupOK > 0:
err = np.empty(len(mus))
err[:] = np.nan
if not return_max: return err
return err, [- setupOK], np.nan
mus = self.checkParameterList(mus)
vbMng(self.trainedModel, "INIT",
"Evaluating error estimator at mu = {}.".format(mus), 10)
if self.errorEstimatorKind == "AFFINE":
err = self.getErrorEstimatorAffine(mus)
else:
self._setupInterpolationIndices()
if self.errorEstimatorKind == "DISCREPANCY":
err = self.getErrorEstimatorDiscrepancy(mus)
elif self.errorEstimatorKind[: 10] == "LOOK_AHEAD":
err, idxMaxEst = self.getErrorEstimatorLookAhead(mus,
self.errorEstimatorKind[11 :])
else: #if self.errorEstimatorKind == "NONE":
err = self.getErrorEstimatorNone(mus)
vbMng(self.trainedModel, "DEL", "Done evaluating error estimator", 10)
if not return_max: return err
if self.errorEstimatorKind[: 10] != "LOOK_AHEAD":
idxMaxEst = np.empty(self.sampleBatchSize, dtype = int)
errCP = copy(err)
for j in range(self.sampleBatchSize):
k = np.argmax(errCP)
idxMaxEst[j] = k
if j + 1 < self.sampleBatchSize:
musZero = self.trainedModel.centerNormalize(mus, mus[k])
errCP *= np.linalg.norm(musZero.data, axis = 1)
return err, idxMaxEst, err[idxMaxEst]
def plotEstimator(self, *args, **kwargs):
super().plotEstimator(*args, **kwargs)
if self.errorEstimatorKind == "NONE":
vbMng(self, "MAIN",
("Warning! Error estimator has been arbitrarily normalized "
"before plotting."), 15)
def greedyNextSample(self, *args,
**kwargs) -> Tuple[Np1D, int, float, paramVal]:
"""Compute next greedy snapshot of solution map."""
RROMPyAssert(self._mode, message = "Cannot add greedy sample.")
self.sampleBatchIdx += 1
self.sampleBatchSize = totalDegreeN(self.npar - 1, self.sampleBatchIdx)
err, muidx, maxErr, muNext = super().greedyNextSample(*args, **kwargs)
if maxErr is not None and (np.any(np.isnan(maxErr))
or np.any(np.isinf(maxErr))):
self.sampleBatchIdx -= 1
self.sampleBatchSize = totalDegreeN(self.npar - 1,
self.sampleBatchIdx)
if (self.errorEstimatorKind == "NONE" and not np.isnan(maxErr)
and not np.isinf(maxErr)):
maxErr = None
return err, muidx, maxErr, muNext
def _setSampleBatch(self, maxS:int):
self.sampleBatchIdx, self.sampleBatchSize, S = -1, 0, 0
nextBatchSize = 1
while S + nextBatchSize <= maxS:
self.sampleBatchIdx += 1
self.sampleBatchSize = nextBatchSize
S += self.sampleBatchSize
nextBatchSize = totalDegreeN(self.npar - 1,
self.sampleBatchIdx + 1)
return S
def _preliminaryTraining(self):
"""Initialize starting snapshots of solution map."""
RROMPyAssert(self._mode, message = "Cannot start greedy algorithm.")
if self.samplingEngine.nsamples > 0: return
self._S = self._setSampleBatch(self.S)
super()._preliminaryTraining()
self.M, self.N = ("AUTO",) * 2
def setupApproxLocal(self) -> int:
"""Compute rational interpolant."""
if self.checkComputedApprox(): return -1
RROMPyAssert(self._mode, message = "Cannot setup approximant.")
self.verbosity -= 10
vbMng(self, "INIT", "Setting up local approximant.", 5)
pMat = self.samplingEngine.projectionMatrix
if self.trainedModel is not None:
pMat = pMat[:, len(self.trainedModel.data.mus) :]
self._setupTrainedModel(pMat, self.trainedModel is not None)
self.catchInstability = 2
vbDepth = getVerbosityDepth()
unstable = False
if self.E > 0:
try:
Q = self._setupDenominator()[0]
except RROMPyException as RE:
setVerbosityDepth(vbDepth)
RROMPyWarning("Downgraded {}: {}".format(RE.__class__.__name__,
RE))
unstable = True
else:
Q = PI()
Q.coeffs = np.ones((1,) * self.npar, dtype = np.complex)
Q.npar = self.npar
Q.polybasis = self.polybasis
if not unstable:
self.trainedModel.data.Q = copy(Q)
try:
P = copy(self._setupNumerator())
except RROMPyException as RE:
setVerbosityDepth(vbDepth)
RROMPyWarning("Downgraded {}: {}".format(RE.__class__.__name__,
RE))
unstable = True
if not unstable:
self.trainedModel.data.P = copy(P)
self.trainedModel.data.approxParameters = copy(
self.approxParameters)
vbMng(self, "DEL", "Done setting up local approximant.", 5)
self.catchInstability = 0
self.verbosity += 10
return 1 * unstable
def setupApprox(self, plotEst : str = "NONE") -> int:
val = super().setupApprox(plotEst)
- if val == 0:
+ if val == 0 and self.correctorTol > 0. and (self.correctorMaxIter > 1
+ or self.correctorForce):
self._iterCorrector()
self.trainedModel.data.approxParameters = copy(
self.approxParameters)
return val
def loadTrainedModel(self, filename:str):
"""Load trained reduced model from file."""
super().loadTrainedModel(filename)
self._setSampleBatch(self.S + 1)