"""Implementation of RootOf class and related tools. """ from sympy.core.basic import Basic from sympy.core import (S, Expr, Integer, Float, I, oo, Add, Lambda, symbols, sympify, Rational, Dummy) from sympy.core.cache import cacheit from sympy.core.relational import is_le from sympy.core.sorting import ordered from sympy.polys.domains import QQ from sympy.polys.polyerrors import ( MultivariatePolynomialError, GeneratorsNeeded, PolynomialError, DomainError) from sympy.polys.polyfuncs import symmetrize, viete from sympy.polys.polyroots import ( roots_linear, roots_quadratic, roots_binomial, preprocess_roots, roots) from sympy.polys.polytools import Poly, PurePoly, factor from sympy.polys.rationaltools import together from sympy.polys.rootisolation import ( dup_isolate_complex_roots_sqf, dup_isolate_real_roots_sqf) from sympy.utilities import lambdify, public, sift, numbered_symbols from mpmath import mpf, mpc, findroot, workprec from mpmath.libmp.libmpf import dps_to_prec, prec_to_dps from sympy.multipledispatch import dispatch from itertools import chain __all__ = ['CRootOf'] class _pure_key_dict: """A minimal dictionary that makes sure that the key is a univariate PurePoly instance. Examples ======== Only the following actions are guaranteed: >>> from sympy.polys.rootoftools import _pure_key_dict >>> from sympy import PurePoly >>> from sympy.abc import x, y 1) creation >>> P = _pure_key_dict() 2) assignment for a PurePoly or univariate polynomial >>> P[x] = 1 >>> P[PurePoly(x - y, x)] = 2 3) retrieval based on PurePoly key comparison (use this instead of the get method) >>> P[y] 1 4) KeyError when trying to retrieve a nonexisting key >>> P[y + 1] Traceback (most recent call last): ... KeyError: PurePoly(y + 1, y, domain='ZZ') 5) ability to query with ``in`` >>> x + 1 in P False NOTE: this is a *not* a dictionary. It is a very basic object for internal use that makes sure to always address its cache via PurePoly instances. It does not, for example, implement ``get`` or ``setdefault``. """ def __init__(self): self._dict = {} def __getitem__(self, k): if not isinstance(k, PurePoly): if not (isinstance(k, Expr) and len(k.free_symbols) == 1): raise KeyError k = PurePoly(k, expand=False) return self._dict[k] def __setitem__(self, k, v): if not isinstance(k, PurePoly): if not (isinstance(k, Expr) and len(k.free_symbols) == 1): raise ValueError('expecting univariate expression') k = PurePoly(k, expand=False) self._dict[k] = v def __contains__(self, k): try: self[k] return True except KeyError: return False _reals_cache = _pure_key_dict() _complexes_cache = _pure_key_dict() def _pure_factors(poly): _, factors = poly.factor_list() return [(PurePoly(f, expand=False), m) for f, m in factors] def _imag_count_of_factor(f): """Return the number of imaginary roots for irreducible univariate polynomial ``f``. """ terms = [(i, j) for (i,), j in f.terms()] if any(i % 2 for i, j in terms): return 0 # update signs even = [(i, I**i*j) for i, j in terms] even = Poly.from_dict(dict(even), Dummy('x')) return int(even.count_roots(-oo, oo)) @public def rootof(f, x, index=None, radicals=True, expand=True): """An indexed root of a univariate polynomial. Returns either a :obj:`ComplexRootOf` object or an explicit expression involving radicals. Parameters ========== f : Expr Univariate polynomial. x : Symbol, optional Generator for ``f``. index : int or Integer radicals : bool Return a radical expression if possible. expand : bool Expand ``f``. """ return CRootOf(f, x, index=index, radicals=radicals, expand=expand) @public class RootOf(Expr): """Represents a root of a univariate polynomial. Base class for roots of different kinds of polynomials. Only complex roots are currently supported. """ __slots__ = ('poly',) def __new__(cls, f, x, index=None, radicals=True, expand=True): """Construct a new ``CRootOf`` object for ``k``-th root of ``f``.""" return rootof(f, x, index=index, radicals=radicals, expand=expand) @public class ComplexRootOf(RootOf): """Represents an indexed complex root of a polynomial. Roots of a univariate polynomial separated into disjoint real or complex intervals and indexed in a fixed order: * real roots come first and are sorted in increasing order; * complex roots come next and are sorted primarily by increasing real part, secondarily by increasing imaginary part. Currently only rational coefficients are allowed. Can be imported as ``CRootOf``. To avoid confusion, the generator must be a Symbol. Examples ======== >>> from sympy import CRootOf, rootof >>> from sympy.abc import x CRootOf is a way to reference a particular root of a polynomial. If there is a rational root, it will be returned: >>> CRootOf.clear_cache() # for doctest reproducibility >>> CRootOf(x**2 - 4, 0) -2 Whether roots involving radicals are returned or not depends on whether the ``radicals`` flag is true (which is set to True with rootof): >>> CRootOf(x**2 - 3, 0) CRootOf(x**2 - 3, 0) >>> CRootOf(x**2 - 3, 0, radicals=True) -sqrt(3) >>> rootof(x**2 - 3, 0) -sqrt(3) The following cannot be expressed in terms of radicals: >>> r = rootof(4*x**5 + 16*x**3 + 12*x**2 + 7, 0); r CRootOf(4*x**5 + 16*x**3 + 12*x**2 + 7, 0) The root bounds can be seen, however, and they are used by the evaluation methods to get numerical approximations for the root. >>> interval = r._get_interval(); interval (-1, 0) >>> r.evalf(2) -0.98 The evalf method refines the width of the root bounds until it guarantees that any decimal approximation within those bounds will satisfy the desired precision. It then stores the refined interval so subsequent requests at or below the requested precision will not have to recompute the root bounds and will return very quickly. Before evaluation above, the interval was >>> interval (-1, 0) After evaluation it is now >>> r._get_interval() # doctest: +SKIP (-165/169, -206/211) To reset all intervals for a given polynomial, the :meth:`_reset` method can be called from any CRootOf instance of the polynomial: >>> r._reset() >>> r._get_interval() (-1, 0) The :meth:`eval_approx` method will also find the root to a given precision but the interval is not modified unless the search for the root fails to converge within the root bounds. And the secant method is used to find the root. (The ``evalf`` method uses bisection and will always update the interval.) >>> r.eval_approx(2) -0.98 The interval needed to be slightly updated to find that root: >>> r._get_interval() (-1, -1/2) The ``evalf_rational`` will compute a rational approximation of the root to the desired accuracy or precision. >>> r.eval_rational(n=2) -69629/71318 >>> t = CRootOf(x**3 + 10*x + 1, 1) >>> t.eval_rational(1e-1) 15/256 - 805*I/256 >>> t.eval_rational(1e-1, 1e-4) 3275/65536 - 414645*I/131072 >>> t.eval_rational(1e-4, 1e-4) 6545/131072 - 414645*I/131072 >>> t.eval_rational(n=2) 104755/2097152 - 6634255*I/2097152 Notes ===== Although a PurePoly can be constructed from a non-symbol generator RootOf instances of non-symbols are disallowed to avoid confusion over what root is being represented. >>> from sympy import exp, PurePoly >>> PurePoly(x) == PurePoly(exp(x)) True >>> CRootOf(x - 1, 0) 1 >>> CRootOf(exp(x) - 1, 0) # would correspond to x == 0 Traceback (most recent call last): ... sympy.polys.polyerrors.PolynomialError: generator must be a Symbol See Also ======== eval_approx eval_rational """ __slots__ = ('index',) is_complex = True is_number = True is_finite = True def __new__(cls, f, x, index=None, radicals=False, expand=True): """ Construct an indexed complex root of a polynomial. See ``rootof`` for the parameters. The default value of ``radicals`` is ``False`` to satisfy ``eval(srepr(expr) == expr``. """ x = sympify(x) if index is None and x.is_Integer: x, index = None, x else: index = sympify(index) if index is not None and index.is_Integer: index = int(index) else: raise ValueError("expected an integer root index, got %s" % index) poly = PurePoly(f, x, greedy=False, expand=expand) if not poly.is_univariate: raise PolynomialError("only univariate polynomials are allowed") if not poly.gen.is_Symbol: # PurePoly(sin(x) + 1) == PurePoly(x + 1) but the roots of # x for each are not the same: issue 8617 raise PolynomialError("generator must be a Symbol") degree = poly.degree() if degree <= 0: raise PolynomialError("Cannot construct CRootOf object for %s" % f) if index < -degree or index >= degree: raise IndexError("root index out of [%d, %d] range, got %d" % (-degree, degree - 1, index)) elif index < 0: index += degree dom = poly.get_domain() if not dom.is_Exact: poly = poly.to_exact() roots = cls._roots_trivial(poly, radicals) if roots is not None: return roots[index] coeff, poly = preprocess_roots(poly) dom = poly.get_domain() if not dom.is_ZZ: raise NotImplementedError("CRootOf is not supported over %s" % dom) root = cls._indexed_root(poly, index, lazy=True) return coeff * cls._postprocess_root(root, radicals) @classmethod def _new(cls, poly, index): """Construct new ``CRootOf`` object from raw data. """ obj = Expr.__new__(cls) obj.poly = PurePoly(poly) obj.index = index try: _reals_cache[obj.poly] = _reals_cache[poly] _complexes_cache[obj.poly] = _complexes_cache[poly] except KeyError: pass return obj def _hashable_content(self): return (self.poly, self.index) @property def expr(self): return self.poly.as_expr() @property def args(self): return (self.expr, Integer(self.index)) @property def free_symbols(self): # CRootOf currently only works with univariate expressions # whose poly attribute should be a PurePoly with no free # symbols return set() def _eval_is_real(self): """Return ``True`` if the root is real. """ self._ensure_reals_init() return self.index < len(_reals_cache[self.poly]) def _eval_is_imaginary(self): """Return ``True`` if the root is imaginary. """ self._ensure_reals_init() if self.index >= len(_reals_cache[self.poly]): ivl = self._get_interval() return ivl.ax*ivl.bx <= 0 # all others are on one side or the other return False # XXX is this necessary? @classmethod def real_roots(cls, poly, radicals=True): """Get real roots of a polynomial. """ return cls._get_roots("_real_roots", poly, radicals) @classmethod def all_roots(cls, poly, radicals=True): """Get real and complex roots of a polynomial. """ return cls._get_roots("_all_roots", poly, radicals) @classmethod def _get_reals_sqf(cls, currentfactor, use_cache=True): """Get real root isolating intervals for a square-free factor.""" if use_cache and currentfactor in _reals_cache: real_part = _reals_cache[currentfactor] else: _reals_cache[currentfactor] = real_part = \ dup_isolate_real_roots_sqf( currentfactor.rep.to_list(), currentfactor.rep.dom, blackbox=True) return real_part @classmethod def _get_complexes_sqf(cls, currentfactor, use_cache=True): """Get complex root isolating intervals for a square-free factor.""" if use_cache and currentfactor in _complexes_cache: complex_part = _complexes_cache[currentfactor] else: _complexes_cache[currentfactor] = complex_part = \ dup_isolate_complex_roots_sqf( currentfactor.rep.to_list(), currentfactor.rep.dom, blackbox=True) return complex_part @classmethod def _get_reals(cls, factors, use_cache=True): """Compute real root isolating intervals for a list of factors. """ reals = [] for currentfactor, k in factors: try: if not use_cache: raise KeyError r = _reals_cache[currentfactor] reals.extend([(i, currentfactor, k) for i in r]) except KeyError: real_part = cls._get_reals_sqf(currentfactor, use_cache) new = [(root, currentfactor, k) for root in real_part] reals.extend(new) reals = cls._reals_sorted(reals) return reals @classmethod def _get_complexes(cls, factors, use_cache=True): """Compute complex root isolating intervals for a list of factors. """ complexes = [] for currentfactor, k in ordered(factors): try: if not use_cache: raise KeyError c = _complexes_cache[currentfactor] complexes.extend([(i, currentfactor, k) for i in c]) except KeyError: complex_part = cls._get_complexes_sqf(currentfactor, use_cache) new = [(root, currentfactor, k) for root in complex_part] complexes.extend(new) complexes = cls._complexes_sorted(complexes) return complexes @classmethod def _reals_sorted(cls, reals): """Make real isolating intervals disjoint and sort roots. """ cache = {} for i, (u, f, k) in enumerate(reals): for j, (v, g, m) in enumerate(reals[i + 1:]): u, v = u.refine_disjoint(v) reals[i + j + 1] = (v, g, m) reals[i] = (u, f, k) reals = sorted(reals, key=lambda r: r[0].a) for root, currentfactor, _ in reals: if currentfactor in cache: cache[currentfactor].append(root) else: cache[currentfactor] = [root] for currentfactor, root in cache.items(): _reals_cache[currentfactor] = root return reals @classmethod def _refine_imaginary(cls, complexes): sifted = sift(complexes, lambda c: c[1]) complexes = [] for f in ordered(sifted): nimag = _imag_count_of_factor(f) if nimag == 0: # refine until xbounds are neg or pos for u, f, k in sifted[f]: while u.ax*u.bx <= 0: u = u._inner_refine() complexes.append((u, f, k)) else: # refine until all but nimag xbounds are neg or pos potential_imag = list(range(len(sifted[f]))) while True: assert len(potential_imag) > 1 for i in list(potential_imag): u, f, k = sifted[f][i] if u.ax*u.bx > 0: potential_imag.remove(i) elif u.ax != u.bx: u = u._inner_refine() sifted[f][i] = u, f, k if len(potential_imag) == nimag: break complexes.extend(sifted[f]) return complexes @classmethod def _refine_complexes(cls, complexes): """return complexes such that no bounding rectangles of non-conjugate roots would intersect. In addition, assure that neither ay nor by is 0 to guarantee that non-real roots are distinct from real roots in terms of the y-bounds. """ # get the intervals pairwise-disjoint. # If rectangles were drawn around the coordinates of the bounding # rectangles, no rectangles would intersect after this procedure. for i, (u, f, k) in enumerate(complexes): for j, (v, g, m) in enumerate(complexes[i + 1:]): u, v = u.refine_disjoint(v) complexes[i + j + 1] = (v, g, m) complexes[i] = (u, f, k) # refine until the x-bounds are unambiguously positive or negative # for non-imaginary roots complexes = cls._refine_imaginary(complexes) # make sure that all y bounds are off the real axis # and on the same side of the axis for i, (u, f, k) in enumerate(complexes): while u.ay*u.by <= 0: u = u.refine() complexes[i] = u, f, k return complexes @classmethod def _complexes_sorted(cls, complexes): """Make complex isolating intervals disjoint and sort roots. """ complexes = cls._refine_complexes(complexes) # XXX don't sort until you are sure that it is compatible # with the indexing method but assert that the desired state # is not broken C, F = 0, 1 # location of ComplexInterval and factor fs = {i[F] for i in complexes} for i in range(1, len(complexes)): if complexes[i][F] != complexes[i - 1][F]: # if this fails the factors of a root were not # contiguous because a discontinuity should only # happen once fs.remove(complexes[i - 1][F]) for i, cmplx in enumerate(complexes): # negative im part (conj=True) comes before # positive im part (conj=False) assert cmplx[C].conj is (i % 2 == 0) # update cache cache = {} # -- collate for root, currentfactor, _ in complexes: cache.setdefault(currentfactor, []).append(root) # -- store for currentfactor, root in cache.items(): _complexes_cache[currentfactor] = root return complexes @classmethod def _reals_index(cls, reals, index): """ Map initial real root index to an index in a factor where the root belongs. """ i = 0 for j, (_, currentfactor, k) in enumerate(reals): if index < i + k: poly, index = currentfactor, 0 for _, currentfactor, _ in reals[:j]: if currentfactor == poly: index += 1 return poly, index else: i += k @classmethod def _complexes_index(cls, complexes, index): """ Map initial complex root index to an index in a factor where the root belongs. """ i = 0 for j, (_, currentfactor, k) in enumerate(complexes): if index < i + k: poly, index = currentfactor, 0 for _, currentfactor, _ in complexes[:j]: if currentfactor == poly: index += 1 index += len(_reals_cache[poly]) return poly, index else: i += k @classmethod def _count_roots(cls, roots): """Count the number of real or complex roots with multiplicities.""" return sum(k for _, _, k in roots) @classmethod def _indexed_root(cls, poly, index, lazy=False): """Get a root of a composite polynomial by index. """ factors = _pure_factors(poly) # If the given poly is already irreducible, then the index does not # need to be adjusted, and we can postpone the heavy lifting of # computing and refining isolating intervals until that is needed. # Note, however, that `_pure_factors()` extracts a negative leading # coeff if present, so `factors[0][0]` may differ from `poly`, and # is the "normalized" version of `poly` that we must return. if lazy and len(factors) == 1 and factors[0][1] == 1: return factors[0][0], index reals = cls._get_reals(factors) reals_count = cls._count_roots(reals) if index < reals_count: return cls._reals_index(reals, index) else: complexes = cls._get_complexes(factors) return cls._complexes_index(complexes, index - reals_count) def _ensure_reals_init(self): """Ensure that our poly has entries in the reals cache. """ if self.poly not in _reals_cache: self._indexed_root(self.poly, self.index) def _ensure_complexes_init(self): """Ensure that our poly has entries in the complexes cache. """ if self.poly not in _complexes_cache: self._indexed_root(self.poly, self.index) @classmethod def _real_roots(cls, poly): """Get real roots of a composite polynomial. """ factors = _pure_factors(poly) reals = cls._get_reals(factors) reals_count = cls._count_roots(reals) roots = [] for index in range(0, reals_count): roots.append(cls._reals_index(reals, index)) return roots def _reset(self): """ Reset all intervals """ self._all_roots(self.poly, use_cache=False) @classmethod def _all_roots(cls, poly, use_cache=True): """Get real and complex roots of a composite polynomial. """ factors = _pure_factors(poly) reals = cls._get_reals(factors, use_cache=use_cache) reals_count = cls._count_roots(reals) roots = [] for index in range(0, reals_count): roots.append(cls._reals_index(reals, index)) complexes = cls._get_complexes(factors, use_cache=use_cache) complexes_count = cls._count_roots(complexes) for index in range(0, complexes_count): roots.append(cls._complexes_index(complexes, index)) return roots @classmethod @cacheit def _roots_trivial(cls, poly, radicals): """Compute roots in linear, quadratic and binomial cases. """ if poly.degree() == 1: return roots_linear(poly) if not radicals: return None if poly.degree() == 2: return roots_quadratic(poly) elif poly.length() == 2 and poly.TC(): return roots_binomial(poly) else: return None @classmethod def _preprocess_roots(cls, poly): """Take heroic measures to make ``poly`` compatible with ``CRootOf``.""" dom = poly.get_domain() if not dom.is_Exact: poly = poly.to_exact() coeff, poly = preprocess_roots(poly) dom = poly.get_domain() if not dom.is_ZZ: raise NotImplementedError( "sorted roots not supported over %s" % dom) return coeff, poly @classmethod def _postprocess_root(cls, root, radicals): """Return the root if it is trivial or a ``CRootOf`` object. """ poly, index = root roots = cls._roots_trivial(poly, radicals) if roots is not None: return roots[index] else: return cls._new(poly, index) @classmethod def _get_roots(cls, method, poly, radicals): """Return postprocessed roots of specified kind. """ if not poly.is_univariate: raise PolynomialError("only univariate polynomials are allowed") # get rid of gen and it's free symbol d = Dummy() poly = poly.subs(poly.gen, d) x = symbols('x') # see what others are left and select x or a numbered x # that doesn't clash free_names = {str(i) for i in poly.free_symbols} for x in chain((symbols('x'),), numbered_symbols('x')): if x.name not in free_names: poly = poly.xreplace({d: x}) break coeff, poly = cls._preprocess_roots(poly) roots = [] for root in getattr(cls, method)(poly): roots.append(coeff*cls._postprocess_root(root, radicals)) return roots @classmethod def clear_cache(cls): """Reset cache for reals and complexes. The intervals used to approximate a root instance are updated as needed. When a request is made to see the intervals, the most current values are shown. `clear_cache` will reset all CRootOf instances back to their original state. See Also ======== _reset """ global _reals_cache, _complexes_cache _reals_cache = _pure_key_dict() _complexes_cache = _pure_key_dict() def _get_interval(self): """Internal function for retrieving isolation interval from cache. """ self._ensure_reals_init() if self.is_real: return _reals_cache[self.poly][self.index] else: reals_count = len(_reals_cache[self.poly]) self._ensure_complexes_init() return _complexes_cache[self.poly][self.index - reals_count] def _set_interval(self, interval): """Internal function for updating isolation interval in cache. """ self._ensure_reals_init() if self.is_real: _reals_cache[self.poly][self.index] = interval else: reals_count = len(_reals_cache[self.poly]) self._ensure_complexes_init() _complexes_cache[self.poly][self.index - reals_count] = interval def _eval_subs(self, old, new): # don't allow subs to change anything return self def _eval_conjugate(self): if self.is_real: return self expr, i = self.args return self.func(expr, i + (1 if self._get_interval().conj else -1)) def eval_approx(self, n, return_mpmath=False): """Evaluate this complex root to the given precision. This uses secant method and root bounds are used to both generate an initial guess and to check that the root returned is valid. If ever the method converges outside the root bounds, the bounds will be made smaller and updated. """ prec = dps_to_prec(n) with workprec(prec): g = self.poly.gen if not g.is_Symbol: d = Dummy('x') if self.is_imaginary: d *= I func = lambdify(d, self.expr.subs(g, d)) else: expr = self.expr if self.is_imaginary: expr = self.expr.subs(g, I*g) func = lambdify(g, expr) interval = self._get_interval() while True: if self.is_real: a = mpf(str(interval.a)) b = mpf(str(interval.b)) if a == b: root = a break x0 = mpf(str(interval.center)) x1 = x0 + mpf(str(interval.dx))/4 elif self.is_imaginary: a = mpf(str(interval.ay)) b = mpf(str(interval.by)) if a == b: root = mpc(mpf('0'), a) break x0 = mpf(str(interval.center[1])) x1 = x0 + mpf(str(interval.dy))/4 else: ax = mpf(str(interval.ax)) bx = mpf(str(interval.bx)) ay = mpf(str(interval.ay)) by = mpf(str(interval.by)) if ax == bx and ay == by: root = mpc(ax, ay) break x0 = mpc(*map(str, interval.center)) x1 = x0 + mpc(*map(str, (interval.dx, interval.dy)))/4 try: # without a tolerance, this will return when (to within # the given precision) x_i == x_{i-1} root = findroot(func, (x0, x1)) # If the (real or complex) root is not in the 'interval', # then keep refining the interval. This happens if findroot # accidentally finds a different root outside of this # interval because our initial estimate 'x0' was not close # enough. It is also possible that the secant method will # get trapped by a max/min in the interval; the root # verification by findroot will raise a ValueError in this # case and the interval will then be tightened -- and # eventually the root will be found. # # It is also possible that findroot will not have any # successful iterations to process (in which case it # will fail to initialize a variable that is tested # after the iterations and raise an UnboundLocalError). if self.is_real or self.is_imaginary: if not bool(root.imag) == self.is_real and ( a <= root <= b): if self.is_imaginary: root = mpc(mpf('0'), root.real) break elif (ax <= root.real <= bx and ay <= root.imag <= by): break except (UnboundLocalError, ValueError): pass interval = interval.refine() # update the interval so we at least (for this precision or # less) don't have much work to do to recompute the root self._set_interval(interval) if return_mpmath: return root return (Float._new(root.real._mpf_, prec) + I*Float._new(root.imag._mpf_, prec)) def _eval_evalf(self, prec, **kwargs): """Evaluate this complex root to the given precision.""" # all kwargs are ignored return self.eval_rational(n=prec_to_dps(prec))._evalf(prec) def eval_rational(self, dx=None, dy=None, n=15): """ Return a Rational approximation of ``self`` that has real and imaginary component approximations that are within ``dx`` and ``dy`` of the true values, respectively. Alternatively, ``n`` digits of precision can be specified. The interval is refined with bisection and is sure to converge. The root bounds are updated when the refinement is complete so recalculation at the same or lesser precision will not have to repeat the refinement and should be much faster. The following example first obtains Rational approximation to 1e-8 accuracy for all roots of the 4-th order Legendre polynomial. Since the roots are all less than 1, this will ensure the decimal representation of the approximation will be correct (including rounding) to 6 digits: >>> from sympy import legendre_poly, Symbol >>> x = Symbol("x") >>> p = legendre_poly(4, x, polys=True) >>> r = p.real_roots()[-1] >>> r.eval_rational(10**-8).n(6) 0.861136 It is not necessary to a two-step calculation, however: the decimal representation can be computed directly: >>> r.evalf(17) 0.86113631159405258 """ dy = dy or dx if dx: rtol = None dx = dx if isinstance(dx, Rational) else Rational(str(dx)) dy = dy if isinstance(dy, Rational) else Rational(str(dy)) else: # 5 binary (or 2 decimal) digits are needed to ensure that # a given digit is correctly rounded # prec_to_dps(dps_to_prec(n) + 5) - n <= 2 (tested for # n in range(1000000) rtol = S(10)**-(n + 2) # +2 for guard digits interval = self._get_interval() while True: if self.is_real: if rtol: dx = abs(interval.center*rtol) interval = interval.refine_size(dx=dx) c = interval.center real = Rational(c) imag = S.Zero if not rtol or interval.dx < abs(c*rtol): break elif self.is_imaginary: if rtol: dy = abs(interval.center[1]*rtol) dx = 1 interval = interval.refine_size(dx=dx, dy=dy) c = interval.center[1] imag = Rational(c) real = S.Zero if not rtol or interval.dy < abs(c*rtol): break else: if rtol: dx = abs(interval.center[0]*rtol) dy = abs(interval.center[1]*rtol) interval = interval.refine_size(dx, dy) c = interval.center real, imag = map(Rational, c) if not rtol or ( interval.dx < abs(c[0]*rtol) and interval.dy < abs(c[1]*rtol)): break # update the interval so we at least (for this precision or # less) don't have much work to do to recompute the root self._set_interval(interval) return real + I*imag CRootOf = ComplexRootOf @dispatch(ComplexRootOf, ComplexRootOf) def _eval_is_eq(lhs, rhs): # noqa:F811 # if we use is_eq to check here, we get infinite recurion return lhs == rhs @dispatch(ComplexRootOf, Basic) # type:ignore def _eval_is_eq(lhs, rhs): # noqa:F811 # CRootOf represents a Root, so if rhs is that root, it should set # the expression to zero *and* it should be in the interval of the # CRootOf instance. It must also be a number that agrees with the # is_real value of the CRootOf instance. if not rhs.is_number: return None if not rhs.is_finite: return False z = lhs.expr.subs(lhs.expr.free_symbols.pop(), rhs).is_zero if z is False: # all roots will make z True but we don't know # whether this is the right root if z is True return False o = rhs.is_real, rhs.is_imaginary s = lhs.is_real, lhs.is_imaginary assert None not in s # this is part of initial refinement if o != s and None not in o: return False re, im = rhs.as_real_imag() if lhs.is_real: if im: return False i = lhs._get_interval() a, b = [Rational(str(_)) for _ in (i.a, i.b)] return sympify(a <= rhs and rhs <= b) i = lhs._get_interval() r1, r2, i1, i2 = [Rational(str(j)) for j in ( i.ax, i.bx, i.ay, i.by)] return is_le(r1, re) and is_le(re,r2) and is_le(i1,im) and is_le(im,i2) @public class RootSum(Expr): """Represents a sum of all roots of a univariate polynomial. """ __slots__ = ('poly', 'fun', 'auto') def __new__(cls, expr, func=None, x=None, auto=True, quadratic=False): """Construct a new ``RootSum`` instance of roots of a polynomial.""" coeff, poly = cls._transform(expr, x) if not poly.is_univariate: raise MultivariatePolynomialError( "only univariate polynomials are allowed") if func is None: func = Lambda(poly.gen, poly.gen) else: is_func = getattr(func, 'is_Function', False) if is_func and 1 in func.nargs: if not isinstance(func, Lambda): func = Lambda(poly.gen, func(poly.gen)) else: raise ValueError( "expected a univariate function, got %s" % func) var, expr = func.variables[0], func.expr if coeff is not S.One: expr = expr.subs(var, coeff*var) deg = poly.degree() if not expr.has(var): return deg*expr if expr.is_Add: add_const, expr = expr.as_independent(var) else: add_const = S.Zero if expr.is_Mul: mul_const, expr = expr.as_independent(var) else: mul_const = S.One func = Lambda(var, expr) rational = cls._is_func_rational(poly, func) factors, terms = _pure_factors(poly), [] for poly, k in factors: if poly.is_linear: term = func(roots_linear(poly)[0]) elif quadratic and poly.is_quadratic: term = sum(map(func, roots_quadratic(poly))) else: if not rational or not auto: term = cls._new(poly, func, auto) else: term = cls._rational_case(poly, func) terms.append(k*term) return mul_const*Add(*terms) + deg*add_const @classmethod def _new(cls, poly, func, auto=True): """Construct new raw ``RootSum`` instance. """ obj = Expr.__new__(cls) obj.poly = poly obj.fun = func obj.auto = auto return obj @classmethod def new(cls, poly, func, auto=True): """Construct new ``RootSum`` instance. """ if not func.expr.has(*func.variables): return func.expr rational = cls._is_func_rational(poly, func) if not rational or not auto: return cls._new(poly, func, auto) else: return cls._rational_case(poly, func) @classmethod def _transform(cls, expr, x): """Transform an expression to a polynomial. """ poly = PurePoly(expr, x, greedy=False) return preprocess_roots(poly) @classmethod def _is_func_rational(cls, poly, func): """Check if a lambda is a rational function. """ var, expr = func.variables[0], func.expr return expr.is_rational_function(var) @classmethod def _rational_case(cls, poly, func): """Handle the rational function case. """ roots = symbols('r:%d' % poly.degree()) var, expr = func.variables[0], func.expr f = sum(expr.subs(var, r) for r in roots) p, q = together(f).as_numer_denom() domain = QQ[roots] p = p.expand() q = q.expand() try: p = Poly(p, domain=domain, expand=False) except GeneratorsNeeded: p, p_coeff = None, (p,) else: p_monom, p_coeff = zip(*p.terms()) try: q = Poly(q, domain=domain, expand=False) except GeneratorsNeeded: q, q_coeff = None, (q,) else: q_monom, q_coeff = zip(*q.terms()) coeffs, mapping = symmetrize(p_coeff + q_coeff, formal=True) formulas, values = viete(poly, roots), [] for (sym, _), (_, val) in zip(mapping, formulas): values.append((sym, val)) for i, (coeff, _) in enumerate(coeffs): coeffs[i] = coeff.subs(values) n = len(p_coeff) p_coeff = coeffs[:n] q_coeff = coeffs[n:] if p is not None: p = Poly(dict(zip(p_monom, p_coeff)), *p.gens).as_expr() else: (p,) = p_coeff if q is not None: q = Poly(dict(zip(q_monom, q_coeff)), *q.gens).as_expr() else: (q,) = q_coeff return factor(p/q) def _hashable_content(self): return (self.poly, self.fun) @property def expr(self): return self.poly.as_expr() @property def args(self): return (self.expr, self.fun, self.poly.gen) @property def free_symbols(self): return self.poly.free_symbols | self.fun.free_symbols @property def is_commutative(self): return True def doit(self, **hints): if not hints.get('roots', True): return self _roots = roots(self.poly, multiple=True) if len(_roots) < self.poly.degree(): return self else: return Add(*[self.fun(r) for r in _roots]) def _eval_evalf(self, prec): try: _roots = self.poly.nroots(n=prec_to_dps(prec)) except (DomainError, PolynomialError): return self else: return Add(*[self.fun(r) for r in _roots]) def _eval_derivative(self, x): var, expr = self.fun.args func = Lambda(var, expr.diff(x)) return self.new(self.poly, func, self.auto)