"""Definitions of common exceptions for `polys` module. """ from sympy.utilities import public @public class BasePolynomialError(Exception): """Base class for polynomial related exceptions. """ def new(self, *args): raise NotImplementedError("abstract base class") @public class ExactQuotientFailed(BasePolynomialError): def __init__(self, f, g, dom=None): self.f, self.g, self.dom = f, g, dom def __str__(self): # pragma: no cover from sympy.printing.str import sstr if self.dom is None: return "%s does not divide %s" % (sstr(self.g), sstr(self.f)) else: return "%s does not divide %s in %s" % (sstr(self.g), sstr(self.f), sstr(self.dom)) def new(self, f, g): return self.__class__(f, g, self.dom) @public class PolynomialDivisionFailed(BasePolynomialError): def __init__(self, f, g, domain): self.f = f self.g = g self.domain = domain def __str__(self): if self.domain.is_EX: msg = "You may want to use a different simplification algorithm. Note " \ "that in general it's not possible to guarantee to detect zero " \ "in this domain." elif not self.domain.is_Exact: msg = "Your working precision or tolerance of computations may be set " \ "improperly. Adjust those parameters of the coefficient domain " \ "and try again." else: msg = "Zero detection is guaranteed in this coefficient domain. This " \ "may indicate a bug in SymPy or the domain is user defined and " \ "doesn't implement zero detection properly." return "couldn't reduce degree in a polynomial division algorithm when " \ "dividing %s by %s. This can happen when it's not possible to " \ "detect zero in the coefficient domain. The domain of computation " \ "is %s. %s" % (self.f, self.g, self.domain, msg) @public class OperationNotSupported(BasePolynomialError): def __init__(self, poly, func): self.poly = poly self.func = func def __str__(self): # pragma: no cover return "`%s` operation not supported by %s representation" % (self.func, self.poly.rep.__class__.__name__) @public class HeuristicGCDFailed(BasePolynomialError): pass class ModularGCDFailed(BasePolynomialError): pass @public class HomomorphismFailed(BasePolynomialError): pass @public class IsomorphismFailed(BasePolynomialError): pass @public class ExtraneousFactors(BasePolynomialError): pass @public class EvaluationFailed(BasePolynomialError): pass @public class RefinementFailed(BasePolynomialError): pass @public class CoercionFailed(BasePolynomialError): pass @public class NotInvertible(BasePolynomialError): pass @public class NotReversible(BasePolynomialError): pass @public class NotAlgebraic(BasePolynomialError): pass @public class DomainError(BasePolynomialError): pass @public class PolynomialError(BasePolynomialError): pass @public class UnificationFailed(BasePolynomialError): pass @public class GeneratorsError(BasePolynomialError): pass @public class GeneratorsNeeded(GeneratorsError): pass @public class ComputationFailed(BasePolynomialError): def __init__(self, func, nargs, exc): self.func = func self.nargs = nargs self.exc = exc def __str__(self): return "%s(%s) failed without generators" % (self.func, ', '.join(map(str, self.exc.exprs[:self.nargs]))) @public class UnivariatePolynomialError(PolynomialError): pass @public class MultivariatePolynomialError(PolynomialError): pass @public class PolificationFailed(PolynomialError): def __init__(self, opt, origs, exprs, seq=False): if not seq: self.orig = origs self.expr = exprs self.origs = [origs] self.exprs = [exprs] else: self.origs = origs self.exprs = exprs self.opt = opt self.seq = seq def __str__(self): # pragma: no cover if not self.seq: return "Cannot construct a polynomial from %s" % str(self.orig) else: return "Cannot construct polynomials from %s" % ', '.join(map(str, self.origs)) @public class OptionError(BasePolynomialError): pass @public class FlagError(OptionError): pass