def _separate_sq(p): """ helper function for ``_minimal_polynomial_sq`` It selects a rational ``g`` such that the polynomial ``p`` consists of a sum of terms whose surds squared have gcd equal to ``g`` and a sum of terms with surds squared prime with ``g``; then it takes the field norm to eliminate ``sqrt(g)`` See simplify.simplify.split_surds and polytools.sqf_norm. Examples ======== >>> from sympy import sqrt >>> from sympy.abc import x >>> from sympy.polys.numberfields import _separate_sq >>> p= -x + sqrt(2) + sqrt(3) + sqrt(7) >>> p = _separate_sq(p); p -x**2 + 2*sqrt(3)*x + 2*sqrt(7)*x - 2*sqrt(21) - 8 >>> p = _separate_sq(p); p -x**4 + 4*sqrt(7)*x**3 - 32*x**2 + 8*sqrt(7)*x + 20 >>> p = _separate_sq(p); p -x**8 + 48*x**6 - 536*x**4 + 1728*x**2 - 400 """ from sympy.simplify.simplify import _split_gcd, _mexpand from sympy.utilities.iterables import sift def is_sqrt(expr): return expr.is_Pow and expr.exp is S.Half # p = c1*sqrt(q1) + ... + cn*sqrt(qn) -> a = [(c1, q1), .., (cn, qn)] a = [] for y in p.args: if not y.is_Mul: if is_sqrt(y): a.append((S.One, y**2)) elif y.is_Atom: a.append((y, S.One)) elif y.is_Pow and y.exp.is_integer: a.append((y, S.One)) else: raise NotImplementedError continue sifted = sift(y.args, is_sqrt) a.append((Mul(*sifted[False]), Mul(*sifted[True])**2)) a.sort(key=lambda z: z[1]) if a[-1][1] is S.One: # there are no surds return p surds = [z for y, z in a] for i in range(len(surds)): if surds[i] != 1: break g, b1, b2 = _split_gcd(*surds[i:]) a1 = [] a2 = [] for y, z in a: if z in b1: a1.append(y*z**S.Half) else: a2.append(y*z**S.Half) p1 = Add(*a1) p2 = Add(*a2) p = _mexpand(p1**2) - _mexpand(p2**2) return p
def _separate_sq(p): """ helper function for ``_minimal_polynomial_sq`` It selects a rational ``g`` such that the polynomial ``p`` consists of a sum of terms whose surds squared have gcd equal to ``g`` and a sum of terms with surds squared prime with ``g``; then it takes the field norm to eliminate ``sqrt(g)`` See simplify.simplify.split_surds and polytools.sqf_norm. Examples ======== >>> from sympy import sqrt >>> from sympy.abc import x >>> from sympy.polys.numberfields import _separate_sq >>> p= -x + sqrt(2) + sqrt(3) + sqrt(7) >>> p = _separate_sq(p); p -x**2 + 2*sqrt(3)*x + 2*sqrt(7)*x - 2*sqrt(21) - 8 >>> p = _separate_sq(p); p -x**4 + 4*sqrt(7)*x**3 - 32*x**2 + 8*sqrt(7)*x + 20 >>> p = _separate_sq(p); p -x**8 + 48*x**6 - 536*x**4 + 1728*x**2 - 400 """ from sympy.simplify.simplify import _split_gcd, _mexpand from sympy.utilities.iterables import sift def is_sqrt(expr): return expr.is_Pow and expr.exp is S.Half # p = c1*sqrt(q1) + ... + cn*sqrt(qn) -> a = [(c1, q1), .., (cn, qn)] a = [] for y in p.args: if not y.is_Mul: if is_sqrt(y): a.append((S.One, y**2)) elif y.is_Atom: a.append((y, S.One)) elif y.is_Pow and y.exp.is_integer: a.append((y, S.One)) else: raise NotImplementedError continue sifted = sift(y.args, is_sqrt) a.append((Mul(*sifted[False]), Mul(*sifted[True])**2)) a.sort(key=lambda z: z[1]) if a[-1][1] is S.One: # there are no surds return p surds = [z for y, z in a] for i in range(len(surds)): if surds[i] != 1: break g, b1, b2 = _split_gcd(*surds[i:]) a1 = [] a2 = [] for y, z in a: if z in b1: a1.append(y * z**S.Half) else: a2.append(y * z**S.Half) p1 = Add(*a1) p2 = Add(*a2) p = _mexpand(p1**2) - _mexpand(p2**2) return p