Univariate polynomial base class¶
AUTHORS:
- William Stein: first version 
- Martin Albrecht: added singular coercion 
- Robert Bradshaw: moved Polynomial_generic_dense to Cython 
- Miguel Marco: implemented resultant in the case where PARI fails 
- Simon King: used a faster way of conversion from the base ring 
- Kwankyu Lee (2013-06-02): enhanced - quo_rem()
- Julian Rueth (2012-05-25,2014-05-09): fixed is_squarefree() for imperfect fields, fixed division without remainder over QQbar; added - _cache_keyfor polynomials with unhashable coefficients
- Simon King (2013-10): implemented copying of - PolynomialBaseringInjection
- Bruno Grenet (2014-07-13): enhanced - quo_rem()
- Kiran Kedlaya (2016-03): added root counting 
- Edgar Costa (2017-07): added rational reconstruction 
- Kiran Kedlaya (2017-09): added reciprocal transform, trace polynomial 
- David Zureick-Brown (2017-09): added is_weil_polynomial 
- Sebastian Oehms (2018-10): made - roots()and- factor()work over more cases of proper integral domains (see Issue #26421)
- class sage.rings.polynomial.polynomial_element.ConstantPolynomialSection[source]¶
- Bases: - Map- This class is used for conversion from a polynomial ring to its base ring. - Since Issue #9944, it calls the - constant_coefficient()method, which can be optimized for a particular polynomial type.- EXAMPLES: - sage: P0.<y_1> = GF(3)[] sage: P1.<y_2,y_1,y_0> = GF(3)[] sage: P0(-y_1) 2*y_1 sage: phi = GF(3).convert_map_from(P0); phi Generic map: From: Univariate Polynomial Ring in y_1 over Finite Field of size 3 To: Finite Field of size 3 sage: type(phi) <class 'sage.rings.polynomial.polynomial_element.ConstantPolynomialSection'> sage: phi(P0.one()) 1 sage: phi(y_1) Traceback (most recent call last): ... TypeError: y_1 is not a constant polynomial - >>> from sage.all import * >>> P0 = GF(Integer(3))['y_1']; (y_1,) = P0._first_ngens(1) >>> P1 = GF(Integer(3))['y_2, y_1, y_0']; (y_2, y_1, y_0,) = P1._first_ngens(3) >>> P0(-y_1) 2*y_1 >>> phi = GF(Integer(3)).convert_map_from(P0); phi Generic map: From: Univariate Polynomial Ring in y_1 over Finite Field of size 3 To: Finite Field of size 3 >>> type(phi) <class 'sage.rings.polynomial.polynomial_element.ConstantPolynomialSection'> >>> phi(P0.one()) 1 >>> phi(y_1) Traceback (most recent call last): ... TypeError: y_1 is not a constant polynomial 
- class sage.rings.polynomial.polynomial_element.Polynomial[source]¶
- Bases: - CommutativePolynomial- A polynomial. - EXAMPLES: - sage: R.<y> = QQ['y'] sage: S.<x> = R['x'] sage: S Univariate Polynomial Ring in x over Univariate Polynomial Ring in y over Rational Field sage: f = x*y; f y*x sage: type(f) <class 'sage.rings.polynomial.polynomial_element.Polynomial_generic_dense'> sage: p = (y+1)^10; p(1) 1024 - >>> from sage.all import * >>> R = QQ['y']; (y,) = R._first_ngens(1) >>> S = R['x']; (x,) = S._first_ngens(1) >>> S Univariate Polynomial Ring in x over Univariate Polynomial Ring in y over Rational Field >>> f = x*y; f y*x >>> type(f) <class 'sage.rings.polynomial.polynomial_element.Polynomial_generic_dense'> >>> p = (y+Integer(1))**Integer(10); p(Integer(1)) 1024 - _add_(right)[source]¶
- Add two polynomials. - EXAMPLES: - sage: R = ZZ['x'] sage: p = R([1,2,3,4]) sage: q = R([4,-3,2,-1]) sage: p + q # indirect doctest 3*x^3 + 5*x^2 - x + 5 - >>> from sage.all import * >>> R = ZZ['x'] >>> p = R([Integer(1),Integer(2),Integer(3),Integer(4)]) >>> q = R([Integer(4),-Integer(3),Integer(2),-Integer(1)]) >>> p + q # indirect doctest 3*x^3 + 5*x^2 - x + 5 
 - _lmul_(left)[source]¶
- Multiply - selfon the left by a scalar.- EXAMPLES: - sage: R.<x> = ZZ[] sage: f = (x^3 + x + 5) sage: f._lmul_(7) 7*x^3 + 7*x + 35 sage: 7*f 7*x^3 + 7*x + 35 - >>> from sage.all import * >>> R = ZZ['x']; (x,) = R._first_ngens(1) >>> f = (x**Integer(3) + x + Integer(5)) >>> f._lmul_(Integer(7)) 7*x^3 + 7*x + 35 >>> Integer(7)*f 7*x^3 + 7*x + 35 
 - _rmul_(right)[source]¶
- Multiply - selfon the right by a scalar.- EXAMPLES: - sage: R.<x> = ZZ[] sage: f = (x^3 + x + 5) sage: f._rmul_(7) 7*x^3 + 7*x + 35 sage: f*7 7*x^3 + 7*x + 35 - >>> from sage.all import * >>> R = ZZ['x']; (x,) = R._first_ngens(1) >>> f = (x**Integer(3) + x + Integer(5)) >>> f._rmul_(Integer(7)) 7*x^3 + 7*x + 35 >>> f*Integer(7) 7*x^3 + 7*x + 35 
 - _mul_(right)[source]¶
- EXAMPLES: - sage: R.<x> = ZZ[] sage: (x - 4) * (x^2 - 8*x + 16) x^3 - 12*x^2 + 48*x - 64 sage: C.<t> = PowerSeriesRing(ZZ) sage: D.<s> = PolynomialRing(C) sage: z = (1 + O(t)) + t*s^2 sage: z*z t^2*s^4 + (2*t + O(t^2))*s^2 + 1 + O(t) ## More examples from trac 2943, added by Kiran S. Kedlaya 2 Dec 09 sage: C.<t> = PowerSeriesRing(Integers()) sage: D.<s> = PolynomialRing(C) sage: z = 1 + (t + O(t^2))*s + (t^2 + O(t^3))*s^2 sage: z*z (t^4 + O(t^5))*s^4 + (2*t^3 + O(t^4))*s^3 + (3*t^2 + O(t^3))*s^2 + (2*t + O(t^2))*s + 1 - >>> from sage.all import * >>> R = ZZ['x']; (x,) = R._first_ngens(1) >>> (x - Integer(4)) * (x**Integer(2) - Integer(8)*x + Integer(16)) x^3 - 12*x^2 + 48*x - 64 >>> C = PowerSeriesRing(ZZ, names=('t',)); (t,) = C._first_ngens(1) >>> D = PolynomialRing(C, names=('s',)); (s,) = D._first_ngens(1) >>> z = (Integer(1) + O(t)) + t*s**Integer(2) >>> z*z t^2*s^4 + (2*t + O(t^2))*s^2 + 1 + O(t) ## More examples from trac 2943, added by Kiran S. Kedlaya 2 Dec 09 >>> C = PowerSeriesRing(Integers(), names=('t',)); (t,) = C._first_ngens(1) >>> D = PolynomialRing(C, names=('s',)); (s,) = D._first_ngens(1) >>> z = Integer(1) + (t + O(t**Integer(2)))*s + (t**Integer(2) + O(t**Integer(3)))*s**Integer(2) >>> z*z (t^4 + O(t^5))*s^4 + (2*t^3 + O(t^4))*s^3 + (3*t^2 + O(t^3))*s^2 + (2*t + O(t^2))*s + 1 
 - _mul_trunc_(right, n)[source]¶
- Return the truncated multiplication of two polynomials up to - n.- This is the default implementation that does the multiplication and then truncate! There are custom implementations in several subclasses: - EXAMPLES: - sage: R = QQ['x']['y'] sage: y = R.gen() sage: x = R.base_ring().gen() sage: p1 = 1 - x*y + 2*y**3 sage: p2 = -1/3 + y**5 sage: p1._mul_trunc_(p2, 5) -2/3*y^3 + 1/3*x*y - 1/3 - >>> from sage.all import * >>> R = QQ['x']['y'] >>> y = R.gen() >>> x = R.base_ring().gen() >>> p1 = Integer(1) - x*y + Integer(2)*y**Integer(3) >>> p2 = -Integer(1)/Integer(3) + y**Integer(5) >>> p1._mul_trunc_(p2, Integer(5)) -2/3*y^3 + 1/3*x*y - 1/3 - Todo - implement a generic truncated Karatsuba and use it here. 
 - adams_operator(*args, **kwds)[source]¶
- Deprecated: Use - adams_operator_on_roots()instead. See Issue #36396 for details.
 - adams_operator_on_roots(n, monic=False)[source]¶
- Return the polynomial whose roots are the \(n\)-th powers of the roots of - self.- INPUT: - n– integer
- monic– boolean (default:- False) if set to- True, force the output to be monic
 - EXAMPLES: - sage: # needs sage.libs.pari sage.libs.singular sage: f = cyclotomic_polynomial(30) sage: f.adams_operator_on_roots(7) == f True sage: f.adams_operator_on_roots(6) == cyclotomic_polynomial(5)**2 True sage: f.adams_operator_on_roots(10) == cyclotomic_polynomial(3)**4 True sage: f.adams_operator_on_roots(15) == cyclotomic_polynomial(2)**8 True sage: f.adams_operator_on_roots(30) == cyclotomic_polynomial(1)**8 True sage: x = polygen(QQ) sage: f = x^2 - 2*x + 2 sage: f.adams_operator_on_roots(10) # needs sage.libs.singular x^2 + 1024 - >>> from sage.all import * >>> # needs sage.libs.pari sage.libs.singular >>> f = cyclotomic_polynomial(Integer(30)) >>> f.adams_operator_on_roots(Integer(7)) == f True >>> f.adams_operator_on_roots(Integer(6)) == cyclotomic_polynomial(Integer(5))**Integer(2) True >>> f.adams_operator_on_roots(Integer(10)) == cyclotomic_polynomial(Integer(3))**Integer(4) True >>> f.adams_operator_on_roots(Integer(15)) == cyclotomic_polynomial(Integer(2))**Integer(8) True >>> f.adams_operator_on_roots(Integer(30)) == cyclotomic_polynomial(Integer(1))**Integer(8) True >>> x = polygen(QQ) >>> f = x**Integer(2) - Integer(2)*x + Integer(2) >>> f.adams_operator_on_roots(Integer(10)) # needs sage.libs.singular x^2 + 1024 - When - selfis monic, the output will have leading coefficient \(\pm1\) depending on the degree, but we can force it to be monic:- sage: R.<a,b,c> = ZZ[] sage: x = polygen(R) sage: f = (x - a) * (x - b) * (x - c) sage: f.adams_operator_on_roots(3).factor() # needs sage.libs.singular (-1) * (x - a^3) * (x - b^3) * (x - c^3) sage: f.adams_operator_on_roots(3, monic=True).factor() # needs sage.libs.singular (x - a^3) * (x - b^3) * (x - c^3) - >>> from sage.all import * >>> R = ZZ['a, b, c']; (a, b, c,) = R._first_ngens(3) >>> x = polygen(R) >>> f = (x - a) * (x - b) * (x - c) >>> f.adams_operator_on_roots(Integer(3)).factor() # needs sage.libs.singular (-1) * (x - a^3) * (x - b^3) * (x - c^3) >>> f.adams_operator_on_roots(Integer(3), monic=True).factor() # needs sage.libs.singular (x - a^3) * (x - b^3) * (x - c^3) 
 - add_bigoh(prec)[source]¶
- Return the power series of precision at most - precgot by adding \(O(q^\text{prec})\) to self, where \(q\) is its variable.- EXAMPLES: - sage: R.<x> = ZZ[] sage: f = 1 + 4*x + x^3 sage: f.add_bigoh(7) 1 + 4*x + x^3 + O(x^7) sage: f.add_bigoh(2) 1 + 4*x + O(x^2) sage: f.add_bigoh(2).parent() Power Series Ring in x over Integer Ring - >>> from sage.all import * >>> R = ZZ['x']; (x,) = R._first_ngens(1) >>> f = Integer(1) + Integer(4)*x + x**Integer(3) >>> f.add_bigoh(Integer(7)) 1 + 4*x + x^3 + O(x^7) >>> f.add_bigoh(Integer(2)) 1 + 4*x + O(x^2) >>> f.add_bigoh(Integer(2)).parent() Power Series Ring in x over Integer Ring 
 - all_roots_in_interval(a=None, b=None)[source]¶
- Return - Trueif the roots of this polynomial are all real and contained in the given interval.- EXAMPLES: - sage: # needs sage.libs.pari sage: R.<x> = PolynomialRing(ZZ) sage: pol = (x - 1)^2 * (x - 2)^2 * (x - 3) sage: pol.all_roots_in_interval(1, 3) True sage: pol.all_roots_in_interval(1.01, 3) False sage: pol = chebyshev_T(5, x) sage: pol.all_roots_in_interval(-1, 1) True sage: pol = chebyshev_T(5, x/2) sage: pol.all_roots_in_interval(-1, 1) False sage: pol.all_roots_in_interval() True - >>> from sage.all import * >>> # needs sage.libs.pari >>> R = PolynomialRing(ZZ, names=('x',)); (x,) = R._first_ngens(1) >>> pol = (x - Integer(1))**Integer(2) * (x - Integer(2))**Integer(2) * (x - Integer(3)) >>> pol.all_roots_in_interval(Integer(1), Integer(3)) True >>> pol.all_roots_in_interval(RealNumber('1.01'), Integer(3)) False >>> pol = chebyshev_T(Integer(5), x) >>> pol.all_roots_in_interval(-Integer(1), Integer(1)) True >>> pol = chebyshev_T(Integer(5), x/Integer(2)) >>> pol.all_roots_in_interval(-Integer(1), Integer(1)) False >>> pol.all_roots_in_interval() True 
 - any_irreducible_factor(degree=None, assume_squarefree=False, assume_equal_deg=False, ext_degree=None)[source]¶
- Return an irreducible factor of this polynomial. - INPUT: - degree–- Noneor positive integer (default:- None). Used for polynomials over finite fields. If- None, returns the first factor found (usually the smallest). Otherwise, attempts to return an irreducible factor of- selfof chosen degree- degree.
- assume_squarefree– boolean (default:- False); Used for polynomials over finite fields. If- True, this polynomial is assumed to be squarefree.
- assume_equal_deg– boolean (default:- False); Used for polynomials over finite fields. If- True, this polynomial is assumed to be the product of irreducible polynomials of degree equal to- degree.
- ext_degree– positive integer or- None(default); used for polynomials over finite fields. If not- Noneonly returns irreducible factors of- selfwhose degree divides- ext_degree.
 - EXAMPLES: - sage: # needs sage.rings.finite_rings sage: F = GF(163) sage: R.<x> = F[] sage: f = (x + 40)^3 * (x^5 + 76*x^4 + 93*x^3 + 112*x^2 + 22*x + 27)^2 * (x^6 + 50*x^5 + 143*x^4 + 162*x^2 + 109*x + 140) sage: f.any_irreducible_factor() x + 40 sage: f.any_irreducible_factor(degree=5) x^5 + 76*x^4 + 93*x^3 + 112*x^2 + 22*x + 27 - >>> from sage.all import * >>> # needs sage.rings.finite_rings >>> F = GF(Integer(163)) >>> R = F['x']; (x,) = R._first_ngens(1) >>> f = (x + Integer(40))**Integer(3) * (x**Integer(5) + Integer(76)*x**Integer(4) + Integer(93)*x**Integer(3) + Integer(112)*x**Integer(2) + Integer(22)*x + Integer(27))**Integer(2) * (x**Integer(6) + Integer(50)*x**Integer(5) + Integer(143)*x**Integer(4) + Integer(162)*x**Integer(2) + Integer(109)*x + Integer(140)) >>> f.any_irreducible_factor() x + 40 >>> f.any_irreducible_factor(degree=Integer(5)) x^5 + 76*x^4 + 93*x^3 + 112*x^2 + 22*x + 27 - When the polynomial is known to be squarefree we can optimise the call by setting - assume_squarefreeto be- True:- sage: # needs sage.rings.finite_rings sage: F = GF(163) sage: R.<x> = F[] sage: g = (x - 1) * (x^3 + 7*x + 161) sage: g.any_irreducible_factor(assume_squarefree=True) x + 162 sage: g.any_irreducible_factor(degree=3, assume_squarefree=True) x^3 + 7*x + 161 - >>> from sage.all import * >>> # needs sage.rings.finite_rings >>> F = GF(Integer(163)) >>> R = F['x']; (x,) = R._first_ngens(1) >>> g = (x - Integer(1)) * (x**Integer(3) + Integer(7)*x + Integer(161)) >>> g.any_irreducible_factor(assume_squarefree=True) x + 162 >>> g.any_irreducible_factor(degree=Integer(3), assume_squarefree=True) x^3 + 7*x + 161 - If we ask for an irreducible factor which does not exist, the function will throw a - ValueError:- sage: # needs sage.rings.finite_rings sage: F = GF(163) sage: R.<x> = F[] sage: g = (x - 1) * (x^3 + 7*x + 161) sage: g.any_irreducible_factor(degree=2, assume_squarefree=True) Traceback (most recent call last): ... ValueError: no irreducible factor of degree 2 could be computed from x^4 + 162*x^3 + 7*x^2 + 154*x + 2 - >>> from sage.all import * >>> # needs sage.rings.finite_rings >>> F = GF(Integer(163)) >>> R = F['x']; (x,) = R._first_ngens(1) >>> g = (x - Integer(1)) * (x**Integer(3) + Integer(7)*x + Integer(161)) >>> g.any_irreducible_factor(degree=Integer(2), assume_squarefree=True) Traceback (most recent call last): ... ValueError: no irreducible factor of degree 2 could be computed from x^4 + 162*x^3 + 7*x^2 + 154*x + 2 - If we assume that the polynomial is product of irreducible polynomials of the same degree, we must also supply the degree: - sage: # needs sage.rings.finite_rings sage: F = GF(163) sage: R.<x> = F[] sage: h = (x + 57) * (x + 98) * (x + 117) * (x + 145) sage: h.any_irreducible_factor(degree=1, assume_equal_deg=True) # random x + 98 sage: h.any_irreducible_factor(assume_equal_deg=True) Traceback (most recent call last): ... ValueError: degree must be known if distinct degree factorisation is assumed - >>> from sage.all import * >>> # needs sage.rings.finite_rings >>> F = GF(Integer(163)) >>> R = F['x']; (x,) = R._first_ngens(1) >>> h = (x + Integer(57)) * (x + Integer(98)) * (x + Integer(117)) * (x + Integer(145)) >>> h.any_irreducible_factor(degree=Integer(1), assume_equal_deg=True) # random x + 98 >>> h.any_irreducible_factor(assume_equal_deg=True) Traceback (most recent call last): ... ValueError: degree must be known if distinct degree factorisation is assumed - Also works for extension fields and even characteristic: - sage: F.<z4> = GF(2^4) sage: R.<x> = F[] sage: f = (x + z4^3 + z4^2)^4 * (x^2 + z4*x + z4) * (x^2 + (z4^3 + z4^2 + z4)*x + z4^2 + z4 + 1) sage: f.any_irreducible_factor() x + z4^3 + z4^2 sage: f.any_irreducible_factor(degree=2) # random x^2 + (z4^3 + z4^2 + z4)*x + z4^2 + z4 + 1 - >>> from sage.all import * >>> F = GF(Integer(2)**Integer(4), names=('z4',)); (z4,) = F._first_ngens(1) >>> R = F['x']; (x,) = R._first_ngens(1) >>> f = (x + z4**Integer(3) + z4**Integer(2))**Integer(4) * (x**Integer(2) + z4*x + z4) * (x**Integer(2) + (z4**Integer(3) + z4**Integer(2) + z4)*x + z4**Integer(2) + z4 + Integer(1)) >>> f.any_irreducible_factor() x + z4^3 + z4^2 >>> f.any_irreducible_factor(degree=Integer(2)) # random x^2 + (z4^3 + z4^2 + z4)*x + z4^2 + z4 + 1 - We can also use this function for polynomials which are not defined over finite fields, but this simply falls back to a slow method of factorisation: - sage: R.<x> = ZZ[] sage: f = 3*x^4 + 2*x^3 sage: f.any_irreducible_factor() 3*x + 2 - >>> from sage.all import * >>> R = ZZ['x']; (x,) = R._first_ngens(1) >>> f = Integer(3)*x**Integer(4) + Integer(2)*x**Integer(3) >>> f.any_irreducible_factor() 3*x + 2 
 - any_root(ring=None, degree=None, assume_squarefree=False, assume_equal_deg=False)[source]¶
- Return a root of this polynomial in the given ring. - INPUT: - ring– the ring in which a root is sought; by default this is the coefficient ring
- degree–- Noneor nonzero integer; used for polynomials over finite fields. Return a root of degree- abs(degree)over the ground field. If negative, also assumes that all factors of this polynomial are of degree- abs(degree). If- None, returns a root of minimal degree contained within the given ring.
- assume_squarefree– boolean; used for polynomials over finite fields. If- True, this polynomial is assumed to be squarefree.
- assume_equal_deg– boolean; used for polynomials over finite fields. If- True, all factors of this polynomial are assumed to have degree- degree. Note that- degreemust be set.
 - Warning - Negative degree input will be deprecated. Instead use - assume_equal_deg.- Note - For finite fields, - any_root()is non-deterministic when finding linear roots of a polynomial over the base ring. However, if- degreeis greater than one, or- ringis an extension of the base ring, then the root computed is found by attempting to return a root after factorisation. Roots found in this way are deterministic. This may change in the future. For all other rings or fields, roots are found by first fully-factoring- selfand the output is deterministic.- EXAMPLES: - sage: # needs sage.rings.finite_rings sage: R.<x> = GF(11)[] sage: f = 7*x^7 + 8*x^6 + 4*x^5 + x^4 + 6*x^3 + 10*x^2 + 8*x + 5 sage: f.any_root() 2 sage: f.factor() (7) * (x + 9) * (x^6 + 10*x^4 + 6*x^3 + 5*x^2 + 2*x + 2) sage: f = x^6 + 10*x^4 + 6*x^3 + 5*x^2 + 2*x + 2 sage: root = f.any_root(GF(11^6, 'a')) sage: roots = sorted(f.roots(GF(11^6, 'a'), multiplicities=False)) sage: roots [10*a^5 + 2*a^4 + 8*a^3 + 9*a^2 + a, a^5 + a^4 + 7*a^3 + 2*a^2 + 10*a, 9*a^5 + 5*a^4 + 10*a^3 + 8*a^2 + 3*a + 1, 2*a^5 + 8*a^4 + 3*a^3 + 6*a + 2, a^5 + 3*a^4 + 8*a^3 + 2*a^2 + 3*a + 4, 10*a^5 + 3*a^4 + 8*a^3 + a^2 + 10*a + 4] sage: root in roots True sage: # needs sage.rings.finite_rings sage: g = (x-1) * (x^2 + 3*x + 9) * (x^5 + 5*x^4 + 8*x^3 + 5*x^2 + 3*x + 5) sage: g.any_root(ring=GF(11^10, 'b'), degree=1) 1 sage: root = g.any_root(ring=GF(11^10, 'b'), degree=2) sage: roots = (x^2 + 3*x + 9).roots(ring=GF(11^10, 'b'), multiplicities=False) sage: root in roots True sage: root = g.any_root(ring=GF(11^10, 'b'), degree=5) sage: roots = (x^5 + 5*x^4 + 8*x^3 + 5*x^2 + 3*x + 5).roots(ring=GF(11^10, 'b'), multiplicities=False) sage: root in roots True - >>> from sage.all import * >>> # needs sage.rings.finite_rings >>> R = GF(Integer(11))['x']; (x,) = R._first_ngens(1) >>> f = Integer(7)*x**Integer(7) + Integer(8)*x**Integer(6) + Integer(4)*x**Integer(5) + x**Integer(4) + Integer(6)*x**Integer(3) + Integer(10)*x**Integer(2) + Integer(8)*x + Integer(5) >>> f.any_root() 2 >>> f.factor() (7) * (x + 9) * (x^6 + 10*x^4 + 6*x^3 + 5*x^2 + 2*x + 2) >>> f = x**Integer(6) + Integer(10)*x**Integer(4) + Integer(6)*x**Integer(3) + Integer(5)*x**Integer(2) + Integer(2)*x + Integer(2) >>> root = f.any_root(GF(Integer(11)**Integer(6), 'a')) >>> roots = sorted(f.roots(GF(Integer(11)**Integer(6), 'a'), multiplicities=False)) >>> roots [10*a^5 + 2*a^4 + 8*a^3 + 9*a^2 + a, a^5 + a^4 + 7*a^3 + 2*a^2 + 10*a, 9*a^5 + 5*a^4 + 10*a^3 + 8*a^2 + 3*a + 1, 2*a^5 + 8*a^4 + 3*a^3 + 6*a + 2, a^5 + 3*a^4 + 8*a^3 + 2*a^2 + 3*a + 4, 10*a^5 + 3*a^4 + 8*a^3 + a^2 + 10*a + 4] >>> root in roots True >>> # needs sage.rings.finite_rings >>> g = (x-Integer(1)) * (x**Integer(2) + Integer(3)*x + Integer(9)) * (x**Integer(5) + Integer(5)*x**Integer(4) + Integer(8)*x**Integer(3) + Integer(5)*x**Integer(2) + Integer(3)*x + Integer(5)) >>> g.any_root(ring=GF(Integer(11)**Integer(10), 'b'), degree=Integer(1)) 1 >>> root = g.any_root(ring=GF(Integer(11)**Integer(10), 'b'), degree=Integer(2)) >>> roots = (x**Integer(2) + Integer(3)*x + Integer(9)).roots(ring=GF(Integer(11)**Integer(10), 'b'), multiplicities=False) >>> root in roots True >>> root = g.any_root(ring=GF(Integer(11)**Integer(10), 'b'), degree=Integer(5)) >>> roots = (x**Integer(5) + Integer(5)*x**Integer(4) + Integer(8)*x**Integer(3) + Integer(5)*x**Integer(2) + Integer(3)*x + Integer(5)).roots(ring=GF(Integer(11)**Integer(10), 'b'), multiplicities=False) >>> root in roots True 
 - args()[source]¶
- Return the generator of this polynomial ring, which is the (only) argument used when calling - self.- EXAMPLES: - sage: R.<x> = QQ[] sage: x.args() (x,) - >>> from sage.all import * >>> R = QQ['x']; (x,) = R._first_ngens(1) >>> x.args() (x,) - A constant polynomial has no variables, but still takes a single argument. - sage: R(2).args() (x,) - >>> from sage.all import * >>> R(Integer(2)).args() (x,) 
 - base_extend(R)[source]¶
- Return a copy of this polynomial but with coefficients in - R, if there is a natural map from the coefficient ring of- selfto- R.- EXAMPLES: - sage: R.<x> = QQ[] sage: f = x^3 - 17*x + 3 sage: f.base_extend(GF(7)) Traceback (most recent call last): ... TypeError: no such base extension sage: f.change_ring(GF(7)) x^3 + 4*x + 3 - >>> from sage.all import * >>> R = QQ['x']; (x,) = R._first_ngens(1) >>> f = x**Integer(3) - Integer(17)*x + Integer(3) >>> f.base_extend(GF(Integer(7))) Traceback (most recent call last): ... TypeError: no such base extension >>> f.change_ring(GF(Integer(7))) x^3 + 4*x + 3 
 - base_ring()[source]¶
- Return the base ring of the parent of - self.- EXAMPLES: - sage: R.<x> = ZZ[] sage: x.base_ring() Integer Ring sage: (2*x + 3).base_ring() Integer Ring - >>> from sage.all import * >>> R = ZZ['x']; (x,) = R._first_ngens(1) >>> x.base_ring() Integer Ring >>> (Integer(2)*x + Integer(3)).base_ring() Integer Ring 
 - change_ring(R)[source]¶
- Return a copy of this polynomial but with coefficients in - R, if at all possible.- INPUT: - R– a ring or morphism
 - EXAMPLES: - sage: K.<z> = CyclotomicField(3) # needs sage.rings.number_field sage: f = K.defining_polynomial() # needs sage.rings.number_field sage: f.change_ring(GF(7)) # needs sage.rings.finite_rings sage.rings.number_field x^2 + x + 1 - >>> from sage.all import * >>> K = CyclotomicField(Integer(3), names=('z',)); (z,) = K._first_ngens(1)# needs sage.rings.number_field >>> f = K.defining_polynomial() # needs sage.rings.number_field >>> f.change_ring(GF(Integer(7))) # needs sage.rings.finite_rings sage.rings.number_field x^2 + x + 1 - sage: # needs sage.rings.number_field sage: K.<z> = CyclotomicField(3) sage: R.<x> = K[] sage: f = x^2 + z sage: f.change_ring(K.embeddings(CC)[1]) # needs sage.rings.real_mpfr x^2 - 0.500000000000000 - 0.866025403784438*I - >>> from sage.all import * >>> # needs sage.rings.number_field >>> K = CyclotomicField(Integer(3), names=('z',)); (z,) = K._first_ngens(1) >>> R = K['x']; (x,) = R._first_ngens(1) >>> f = x**Integer(2) + z >>> f.change_ring(K.embeddings(CC)[Integer(1)]) # needs sage.rings.real_mpfr x^2 - 0.500000000000000 - 0.866025403784438*I - sage: R.<x> = QQ[] sage: f = x^2 + 1 sage: f.change_ring(QQ.embeddings(CC)[0]) # needs sage.rings.real_mpfr x^2 + 1.00000000000000 - >>> from sage.all import * >>> R = QQ['x']; (x,) = R._first_ngens(1) >>> f = x**Integer(2) + Integer(1) >>> f.change_ring(QQ.embeddings(CC)[Integer(0)]) # needs sage.rings.real_mpfr x^2 + 1.00000000000000 
 - change_variable_name(var)[source]¶
- Return a new polynomial over the same base ring but in a different variable. - EXAMPLES: - sage: x = polygen(QQ,'x') sage: f = -2/7*x^3 + (2/3)*x - 19/993; f -2/7*x^3 + 2/3*x - 19/993 sage: f.change_variable_name('theta') -2/7*theta^3 + 2/3*theta - 19/993 - >>> from sage.all import * >>> x = polygen(QQ,'x') >>> f = -Integer(2)/Integer(7)*x**Integer(3) + (Integer(2)/Integer(3))*x - Integer(19)/Integer(993); f -2/7*x^3 + 2/3*x - 19/993 >>> f.change_variable_name('theta') -2/7*theta^3 + 2/3*theta - 19/993 
 - coefficients(sparse=True)[source]¶
- Return the coefficients of the monomials appearing in - self.- If - sparse=True(the default), it returns only the nonzero coefficients. Otherwise, it returns the same value as- self.list(). (In this case, it may be slightly faster to invoke- self.list()directly.) In either case, the coefficients are ordered by increasing degree.- EXAMPLES: - sage: _.<x> = PolynomialRing(ZZ) sage: f = 3*x^4 + 2*x^2 + 1 sage: f.coefficients() [1, 2, 3] sage: f.coefficients(sparse=False) [1, 0, 2, 0, 3] - >>> from sage.all import * >>> _ = PolynomialRing(ZZ, names=('x',)); (x,) = _._first_ngens(1) >>> f = Integer(3)*x**Integer(4) + Integer(2)*x**Integer(2) + Integer(1) >>> f.coefficients() [1, 2, 3] >>> f.coefficients(sparse=False) [1, 0, 2, 0, 3] 
 - complex_roots()[source]¶
- Return the complex roots of this polynomial, without multiplicities. - Calls - self.roots(ring=CC), unless this is a polynomial with floating-point coefficients, in which case it is uses the appropriate precision from the input coefficients.- EXAMPLES: - sage: # needs sage.libs.pari sage.rings.real_mpfr sage: x = polygen(ZZ) sage: (x^3 - 1).complex_roots() # note: low order bits slightly different on ppc. [1.00000000000000, -0.500000000000000 - 0.86602540378443...*I, -0.500000000000000 + 0.86602540378443...*I] - >>> from sage.all import * >>> # needs sage.libs.pari sage.rings.real_mpfr >>> x = polygen(ZZ) >>> (x**Integer(3) - Integer(1)).complex_roots() # note: low order bits slightly different on ppc. [1.00000000000000, -0.500000000000000 - 0.86602540378443...*I, -0.500000000000000 + 0.86602540378443...*I] 
 - compose_power(k, algorithm=None, monic=False)[source]¶
- Return the \(k\)-th iterate of the composed product of this polynomial with itself. - INPUT: - k– nonnegative integer
- algorithm–- None(default),- 'resultant', or- 'BFSS'; see- composed_op()
- monic– boolean (default:- False); see- composed_op()
 - OUTPUT: - The polynomial of degree \(d^k\) where \(d\) is the degree, whose roots are all \(k\)-fold products of roots of this polynomial. That is, \(f*f*\dots*f\) where this is \(f\) and \(f*f=\) - f.composed_op(f, operator.mul).- EXAMPLES: - sage: R.<a,b,c> = ZZ[] sage: x = polygen(R) sage: f = (x - a) * (x - b) * (x - c) sage: f.compose_power(2).factor() # needs sage.libs.singular sage.modules (x - a^2) * (x - b^2) * (x - c^2) * (x - a*b)^2 * (x - a*c)^2 * (x - b*c)^2 sage: # needs sage.libs.singular sage.modules sage: x = polygen(QQ) sage: f = x^2 - 2*x + 2 sage: f2 = f.compose_power(2); f2 x^4 - 4*x^3 + 8*x^2 - 16*x + 16 sage: f2 == f.composed_op(f, operator.mul) True sage: f3 = f.compose_power(3); f3 x^8 - 8*x^7 + 32*x^6 - 64*x^5 + 128*x^4 - 512*x^3 + 2048*x^2 - 4096*x + 4096 sage: f3 == f2.composed_op(f, operator.mul) True sage: f4 = f.compose_power(4) sage: f4 == f3.composed_op(f, operator.mul) True - >>> from sage.all import * >>> R = ZZ['a, b, c']; (a, b, c,) = R._first_ngens(3) >>> x = polygen(R) >>> f = (x - a) * (x - b) * (x - c) >>> f.compose_power(Integer(2)).factor() # needs sage.libs.singular sage.modules (x - a^2) * (x - b^2) * (x - c^2) * (x - a*b)^2 * (x - a*c)^2 * (x - b*c)^2 >>> # needs sage.libs.singular sage.modules >>> x = polygen(QQ) >>> f = x**Integer(2) - Integer(2)*x + Integer(2) >>> f2 = f.compose_power(Integer(2)); f2 x^4 - 4*x^3 + 8*x^2 - 16*x + 16 >>> f2 == f.composed_op(f, operator.mul) True >>> f3 = f.compose_power(Integer(3)); f3 x^8 - 8*x^7 + 32*x^6 - 64*x^5 + 128*x^4 - 512*x^3 + 2048*x^2 - 4096*x + 4096 >>> f3 == f2.composed_op(f, operator.mul) True >>> f4 = f.compose_power(Integer(4)) >>> f4 == f3.composed_op(f, operator.mul) True 
 - compose_trunc(other, n)[source]¶
- Return the composition of - selfand- other, truncated to \(O(x^n)\).- This method currently works for some specific coefficient rings only. - EXAMPLES: - sage: Pol.<x> = CBF[] # needs sage.libs.flint sage: (1 + x + x^2/2 + x^3/6 + x^4/24 + x^5/120).compose_trunc(1 + x, 2) # needs sage.libs.flint ([2.708333333333333 +/- ...e-16])*x + [2.71666666666667 +/- ...e-15] sage: Pol.<x> = QQ['y'][] sage: (1 + x + x^2/2 + x^3/6 + x^4/24 + x^5/120).compose_trunc(1 + x, 2) Traceback (most recent call last): ... NotImplementedError: truncated composition is not implemented for this subclass of polynomials - >>> from sage.all import * >>> Pol = CBF['x']; (x,) = Pol._first_ngens(1)# needs sage.libs.flint >>> (Integer(1) + x + x**Integer(2)/Integer(2) + x**Integer(3)/Integer(6) + x**Integer(4)/Integer(24) + x**Integer(5)/Integer(120)).compose_trunc(Integer(1) + x, Integer(2)) # needs sage.libs.flint ([2.708333333333333 +/- ...e-16])*x + [2.71666666666667 +/- ...e-15] >>> Pol = QQ['y']['x']; (x,) = Pol._first_ngens(1) >>> (Integer(1) + x + x**Integer(2)/Integer(2) + x**Integer(3)/Integer(6) + x**Integer(4)/Integer(24) + x**Integer(5)/Integer(120)).compose_trunc(Integer(1) + x, Integer(2)) Traceback (most recent call last): ... NotImplementedError: truncated composition is not implemented for this subclass of polynomials 
 - composed_op(p1, p2, op, algorithm=None, monic=False)[source]¶
- Return the composed sum, difference, product or quotient of this polynomial with another one. - In the case of two monic polynomials \(p_1\) and \(p_2\) over an integral domain, the composed sum, difference, etc. are given by \[\prod_{p_1(a)=p_2(b)=0}(x - (a \ast b)), \qquad \ast ∈ \{ +, -, ×, / \}\]- where the roots \(a\) and \(b\) are to be considered in the algebraic closure of the fraction field of the coefficients and counted with multiplicities. If the polynomials are not monic this quantity is multiplied by \(\alpha_1^{\deg(p_2)} \alpha_2^{\deg(p_1)}\) where \(\alpha_1\) and \(\alpha_2\) are the leading coefficients of \(p_1\) and \(p_2\) respectively. - INPUT: - p2– univariate polynomial belonging to the same polynomial ring as this polynomial
- op–- operator.OPwhere- OP=addor- subor- mulor- truediv
- algorithm– can be- 'resultant'or- 'BFSS'; by default the former is used when the polynomials have few nonzero coefficients and small degrees or if the base ring is not \(\ZZ\) or \(\QQ\). Otherwise the latter is used.
- monic– whether to return a monic polynomial. If- Truethe coefficients of the result belong to the fraction field of the coefficients.
 - ALGORITHM: - The computation is straightforward using resultants. Indeed for the composed sum it would be \(Res_y(p_1(x-y), p_2(y))\). However, the method from [BFSS2006] using series expansions is asymptotically much faster. - Note that the algorithm - BFSSwith polynomials with coefficients in \(\ZZ\) needs to perform operations over \(\QQ\).- Todo - The [BFSS2006] algorithm has been implemented here only in the case of polynomials over rationals. For other rings of zero characteristic (or if the characteristic is larger than the product of the degrees), one needs to implement a generic method - _exp_series. In the general case of nonzero characteristic there is an alternative algorithm in the same paper.
- The Newton series computation can be done much more efficiently! See [BFSS2006]. 
 - EXAMPLES: - sage: x = polygen(ZZ) sage: p1 = x^2 - 1 sage: p2 = x^4 - 1 sage: p1.composed_op(p2, operator.add) # needs sage.libs.singular x^8 - 4*x^6 + 4*x^4 - 16*x^2 sage: p1.composed_op(p2, operator.mul) # needs sage.libs.singular x^8 - 2*x^4 + 1 sage: p1.composed_op(p2, operator.truediv) # needs sage.libs.singular x^8 - 2*x^4 + 1 - >>> from sage.all import * >>> x = polygen(ZZ) >>> p1 = x**Integer(2) - Integer(1) >>> p2 = x**Integer(4) - Integer(1) >>> p1.composed_op(p2, operator.add) # needs sage.libs.singular x^8 - 4*x^6 + 4*x^4 - 16*x^2 >>> p1.composed_op(p2, operator.mul) # needs sage.libs.singular x^8 - 2*x^4 + 1 >>> p1.composed_op(p2, operator.truediv) # needs sage.libs.singular x^8 - 2*x^4 + 1 - This function works over any field. However for base rings other than \(\ZZ\) and \(\QQ\) only the resultant algorithm is available: - sage: # needs sage.rings.number_field sage: x = polygen(QQbar) sage: p1 = x**2 - AA(2).sqrt() sage: p2 = x**3 - AA(3).sqrt() sage: r1 = p1.roots(multiplicities=False) sage: r2 = p2.roots(multiplicities=False) sage: p = p1.composed_op(p2, operator.add); p x^6 - 4.242640687119285?*x^4 - 3.464101615137755?*x^3 + 6*x^2 - 14.69693845669907?*x + 0.1715728752538099? sage: all(p(x+y).is_zero() for x in r1 for y in r2) True sage: x = polygen(GF(2)) sage: p1 = x**2 + x - 1 sage: p2 = x**3 + x - 1 sage: p_add = p1.composed_op(p2, operator.add); p_add # needs sage.libs.singular x^6 + x^5 + x^3 + x^2 + 1 sage: p_mul = p1.composed_op(p2, operator.mul); p_mul # needs sage.libs.singular x^6 + x^4 + x^2 + x + 1 sage: p_div = p1.composed_op(p2, operator.truediv); p_div # needs sage.libs.singular x^6 + x^5 + x^4 + x^2 + 1 sage: # needs sage.rings.finite_rings sage: K = GF(2**6, 'a') sage: r1 = p1.roots(K, multiplicities=False) sage: r2 = p2.roots(K, multiplicities=False) sage: all(p_add(x1+x2).is_zero() for x1 in r1 for x2 in r2) # needs sage.libs.singular True sage: all(p_mul(x1*x2).is_zero() for x1 in r1 for x2 in r2) # needs sage.libs.singular True sage: all(p_div(x1/x2).is_zero() for x1 in r1 for x2 in r2) # needs sage.libs.singular True - >>> from sage.all import * >>> # needs sage.rings.number_field >>> x = polygen(QQbar) >>> p1 = x**Integer(2) - AA(Integer(2)).sqrt() >>> p2 = x**Integer(3) - AA(Integer(3)).sqrt() >>> r1 = p1.roots(multiplicities=False) >>> r2 = p2.roots(multiplicities=False) >>> p = p1.composed_op(p2, operator.add); p x^6 - 4.242640687119285?*x^4 - 3.464101615137755?*x^3 + 6*x^2 - 14.69693845669907?*x + 0.1715728752538099? >>> all(p(x+y).is_zero() for x in r1 for y in r2) True >>> x = polygen(GF(Integer(2))) >>> p1 = x**Integer(2) + x - Integer(1) >>> p2 = x**Integer(3) + x - Integer(1) >>> p_add = p1.composed_op(p2, operator.add); p_add # needs sage.libs.singular x^6 + x^5 + x^3 + x^2 + 1 >>> p_mul = p1.composed_op(p2, operator.mul); p_mul # needs sage.libs.singular x^6 + x^4 + x^2 + x + 1 >>> p_div = p1.composed_op(p2, operator.truediv); p_div # needs sage.libs.singular x^6 + x^5 + x^4 + x^2 + 1 >>> # needs sage.rings.finite_rings >>> K = GF(Integer(2)**Integer(6), 'a') >>> r1 = p1.roots(K, multiplicities=False) >>> r2 = p2.roots(K, multiplicities=False) >>> all(p_add(x1+x2).is_zero() for x1 in r1 for x2 in r2) # needs sage.libs.singular True >>> all(p_mul(x1*x2).is_zero() for x1 in r1 for x2 in r2) # needs sage.libs.singular True >>> all(p_div(x1/x2).is_zero() for x1 in r1 for x2 in r2) # needs sage.libs.singular True 
 - constant_coefficient()[source]¶
- Return the constant coefficient of this polynomial. - OUTPUT: element of base ring - EXAMPLES: - sage: R.<x> = QQ[] sage: f = -2*x^3 + 2*x - 1/3 sage: f.constant_coefficient() -1/3 - >>> from sage.all import * >>> R = QQ['x']; (x,) = R._first_ngens(1) >>> f = -Integer(2)*x**Integer(3) + Integer(2)*x - Integer(1)/Integer(3) >>> f.constant_coefficient() -1/3 
 - content_ideal()[source]¶
- Return the content ideal of this polynomial, defined as the ideal generated by its coefficients. - EXAMPLES: - sage: R.<x> = IntegerModRing(4)[] sage: f = x^4 + 3*x^2 + 2 sage: f.content_ideal() Ideal (2, 3, 1) of Ring of integers modulo 4 - >>> from sage.all import * >>> R = IntegerModRing(Integer(4))['x']; (x,) = R._first_ngens(1) >>> f = x**Integer(4) + Integer(3)*x**Integer(2) + Integer(2) >>> f.content_ideal() Ideal (2, 3, 1) of Ring of integers modulo 4 - When the base ring is a gcd ring, the content as a ring element is the generator of the content ideal: - sage: R.<x> = ZZ[] sage: f = 2*x^3 - 4*x^2 + 6*x - 10 sage: f.content_ideal().gen() 2 - >>> from sage.all import * >>> R = ZZ['x']; (x,) = R._first_ngens(1) >>> f = Integer(2)*x**Integer(3) - Integer(4)*x**Integer(2) + Integer(6)*x - Integer(10) >>> f.content_ideal().gen() 2 
 - cyclotomic_part()[source]¶
- Return the product of the irreducible factors of this polynomial which are cyclotomic polynomials. - The algorithm assumes that the polynomial has rational coefficients. - EXAMPLES: - sage: P.<x> = PolynomialRing(Integers()) sage: pol = 2*(x^4 + 1) sage: pol.cyclotomic_part() x^4 + 1 sage: pol = x^4 + 2 sage: pol.cyclotomic_part() 1 sage: pol = (x^4 + 1)^2 * (x^4 + 2) sage: pol.cyclotomic_part() x^8 + 2*x^4 + 1 sage: P.<x> = PolynomialRing(QQ) sage: pol = (x^4 + 1)^2 * (x^4 + 2) sage: pol.cyclotomic_part() x^8 + 2*x^4 + 1 sage: pol = (x - 1) * x * (x + 2) sage: pol.cyclotomic_part() x - 1 - >>> from sage.all import * >>> P = PolynomialRing(Integers(), names=('x',)); (x,) = P._first_ngens(1) >>> pol = Integer(2)*(x**Integer(4) + Integer(1)) >>> pol.cyclotomic_part() x^4 + 1 >>> pol = x**Integer(4) + Integer(2) >>> pol.cyclotomic_part() 1 >>> pol = (x**Integer(4) + Integer(1))**Integer(2) * (x**Integer(4) + Integer(2)) >>> pol.cyclotomic_part() x^8 + 2*x^4 + 1 >>> P = PolynomialRing(QQ, names=('x',)); (x,) = P._first_ngens(1) >>> pol = (x**Integer(4) + Integer(1))**Integer(2) * (x**Integer(4) + Integer(2)) >>> pol.cyclotomic_part() x^8 + 2*x^4 + 1 >>> pol = (x - Integer(1)) * x * (x + Integer(2)) >>> pol.cyclotomic_part() x - 1 
 - degree(gen=None)[source]¶
- Return the degree of this polynomial. The zero polynomial has degree \(-1\). - EXAMPLES: - sage: x = ZZ['x'].0 sage: f = x^93 + 2*x + 1 sage: f.degree() 93 sage: x = PolynomialRing(QQ, 'x', sparse=True).0 sage: f = x^100000 sage: f.degree() 100000 - >>> from sage.all import * >>> x = ZZ['x'].gen(0) >>> f = x**Integer(93) + Integer(2)*x + Integer(1) >>> f.degree() 93 >>> x = PolynomialRing(QQ, 'x', sparse=True).gen(0) >>> f = x**Integer(100000) >>> f.degree() 100000 - sage: x = QQ['x'].0 sage: f = 2006*x^2006 - x^2 + 3 sage: f.degree() 2006 sage: f = 0*x sage: f.degree() -1 sage: f = x + 33 sage: f.degree() 1 - >>> from sage.all import * >>> x = QQ['x'].gen(0) >>> f = Integer(2006)*x**Integer(2006) - x**Integer(2) + Integer(3) >>> f.degree() 2006 >>> f = Integer(0)*x >>> f.degree() -1 >>> f = x + Integer(33) >>> f.degree() 1 - AUTHORS: - Naqi Jaffery (2006-01-24): examples 
 
 - denominator()[source]¶
- Return a denominator of - self.- First, the lcm of the denominators of the entries of - selfis computed and returned. If this computation fails, the unit of the parent of- selfis returned.- Note that some subclasses may implement their own - denominator()method. For example, see- sage.rings.polynomial.polynomial_rational_flint.Polynomial_rational_flint- Warning - This is not the denominator of the rational function defined by - self, which would always be 1 since- selfis a polynomial.- EXAMPLES: - First we compute the denominator of a polynomial with integer coefficients, which is of course 1. - sage: R.<x> = ZZ[] sage: f = x^3 + 17*x + 1 sage: f.denominator() 1 - >>> from sage.all import * >>> R = ZZ['x']; (x,) = R._first_ngens(1) >>> f = x**Integer(3) + Integer(17)*x + Integer(1) >>> f.denominator() 1 - Next we compute the denominator of a polynomial with rational coefficients. - sage: R.<x> = PolynomialRing(QQ) sage: f = (1/17)*x^19 - (2/3)*x + 1/3; f 1/17*x^19 - 2/3*x + 1/3 sage: f.denominator() 51 - >>> from sage.all import * >>> R = PolynomialRing(QQ, names=('x',)); (x,) = R._first_ngens(1) >>> f = (Integer(1)/Integer(17))*x**Integer(19) - (Integer(2)/Integer(3))*x + Integer(1)/Integer(3); f 1/17*x^19 - 2/3*x + 1/3 >>> f.denominator() 51 - Finally, we try to compute the denominator of a polynomial with coefficients in the real numbers, which is a ring whose elements do not have a - denominator()method.- sage: # needs sage.rings.real_mpfr sage: R.<x> = RR[] sage: f = x + RR('0.3'); f x + 0.300000000000000 sage: f.denominator() 1.00000000000000 - >>> from sage.all import * >>> # needs sage.rings.real_mpfr >>> R = RR['x']; (x,) = R._first_ngens(1) >>> f = x + RR('0.3'); f x + 0.300000000000000 >>> f.denominator() 1.00000000000000 - Check that the denominator is an element over the base whenever the base has no - denominator()method. This closes Issue #9063.- sage: R.<a> = GF(5)[] sage: x = R(0) sage: x.denominator() 1 sage: type(x.denominator()) <class 'sage.rings.finite_rings.integer_mod.IntegerMod_int'> sage: isinstance(x.numerator() / x.denominator(), Polynomial) True sage: isinstance(x.numerator() / R(1), Polynomial) False - >>> from sage.all import * >>> R = GF(Integer(5))['a']; (a,) = R._first_ngens(1) >>> x = R(Integer(0)) >>> x.denominator() 1 >>> type(x.denominator()) <class 'sage.rings.finite_rings.integer_mod.IntegerMod_int'> >>> isinstance(x.numerator() / x.denominator(), Polynomial) True >>> isinstance(x.numerator() / R(Integer(1)), Polynomial) False 
 - derivative(*args)[source]¶
- The formal derivative of this polynomial, with respect to variables supplied in - args.- Multiple variables and iteration counts may be supplied; see documentation for the global - derivative()function for more details.- See also - _derivative()- EXAMPLES: - sage: R.<x> = PolynomialRing(QQ) sage: g = -x^4 + x^2/2 - x sage: g.derivative() -4*x^3 + x - 1 sage: g.derivative(x) -4*x^3 + x - 1 sage: g.derivative(x, x) -12*x^2 + 1 sage: g.derivative(x, 2) -12*x^2 + 1 - >>> from sage.all import * >>> R = PolynomialRing(QQ, names=('x',)); (x,) = R._first_ngens(1) >>> g = -x**Integer(4) + x**Integer(2)/Integer(2) - x >>> g.derivative() -4*x^3 + x - 1 >>> g.derivative(x) -4*x^3 + x - 1 >>> g.derivative(x, x) -12*x^2 + 1 >>> g.derivative(x, Integer(2)) -12*x^2 + 1 - sage: R.<t> = PolynomialRing(ZZ) sage: S.<x> = PolynomialRing(R) sage: f = t^3*x^2 + t^4*x^3 sage: f.derivative() 3*t^4*x^2 + 2*t^3*x sage: f.derivative(x) 3*t^4*x^2 + 2*t^3*x sage: f.derivative(t) 4*t^3*x^3 + 3*t^2*x^2 - >>> from sage.all import * >>> R = PolynomialRing(ZZ, names=('t',)); (t,) = R._first_ngens(1) >>> S = PolynomialRing(R, names=('x',)); (x,) = S._first_ngens(1) >>> f = t**Integer(3)*x**Integer(2) + t**Integer(4)*x**Integer(3) >>> f.derivative() 3*t^4*x^2 + 2*t^3*x >>> f.derivative(x) 3*t^4*x^2 + 2*t^3*x >>> f.derivative(t) 4*t^3*x^3 + 3*t^2*x^2 
 - dict(copy=None)[source]¶
- Return a sparse dictionary representation of this univariate polynomial. - EXAMPLES: - sage: R.<x> = QQ[] sage: f = x^3 + -1/7*x + 13 sage: f.monomial_coefficients() {0: 13, 1: -1/7, 3: 1} - >>> from sage.all import * >>> R = QQ['x']; (x,) = R._first_ngens(1) >>> f = x**Integer(3) + -Integer(1)/Integer(7)*x + Integer(13) >>> f.monomial_coefficients() {0: 13, 1: -1/7, 3: 1} - dictis an alias:- sage: f.dict() {0: 13, 1: -1/7, 3: 1} - >>> from sage.all import * >>> f.dict() {0: 13, 1: -1/7, 3: 1} 
 - diff(*args)[source]¶
- The formal derivative of this polynomial, with respect to variables supplied in - args.- Multiple variables and iteration counts may be supplied; see documentation for the global - derivative()function for more details.- See also - _derivative()- EXAMPLES: - sage: R.<x> = PolynomialRing(QQ) sage: g = -x^4 + x^2/2 - x sage: g.derivative() -4*x^3 + x - 1 sage: g.derivative(x) -4*x^3 + x - 1 sage: g.derivative(x, x) -12*x^2 + 1 sage: g.derivative(x, 2) -12*x^2 + 1 - >>> from sage.all import * >>> R = PolynomialRing(QQ, names=('x',)); (x,) = R._first_ngens(1) >>> g = -x**Integer(4) + x**Integer(2)/Integer(2) - x >>> g.derivative() -4*x^3 + x - 1 >>> g.derivative(x) -4*x^3 + x - 1 >>> g.derivative(x, x) -12*x^2 + 1 >>> g.derivative(x, Integer(2)) -12*x^2 + 1 - sage: R.<t> = PolynomialRing(ZZ) sage: S.<x> = PolynomialRing(R) sage: f = t^3*x^2 + t^4*x^3 sage: f.derivative() 3*t^4*x^2 + 2*t^3*x sage: f.derivative(x) 3*t^4*x^2 + 2*t^3*x sage: f.derivative(t) 4*t^3*x^3 + 3*t^2*x^2 - >>> from sage.all import * >>> R = PolynomialRing(ZZ, names=('t',)); (t,) = R._first_ngens(1) >>> S = PolynomialRing(R, names=('x',)); (x,) = S._first_ngens(1) >>> f = t**Integer(3)*x**Integer(2) + t**Integer(4)*x**Integer(3) >>> f.derivative() 3*t^4*x^2 + 2*t^3*x >>> f.derivative(x) 3*t^4*x^2 + 2*t^3*x >>> f.derivative(t) 4*t^3*x^3 + 3*t^2*x^2 
 - differentiate(*args)[source]¶
- The formal derivative of this polynomial, with respect to variables supplied in - args.- Multiple variables and iteration counts may be supplied; see documentation for the global - derivative()function for more details.- See also - _derivative()- EXAMPLES: - sage: R.<x> = PolynomialRing(QQ) sage: g = -x^4 + x^2/2 - x sage: g.derivative() -4*x^3 + x - 1 sage: g.derivative(x) -4*x^3 + x - 1 sage: g.derivative(x, x) -12*x^2 + 1 sage: g.derivative(x, 2) -12*x^2 + 1 - >>> from sage.all import * >>> R = PolynomialRing(QQ, names=('x',)); (x,) = R._first_ngens(1) >>> g = -x**Integer(4) + x**Integer(2)/Integer(2) - x >>> g.derivative() -4*x^3 + x - 1 >>> g.derivative(x) -4*x^3 + x - 1 >>> g.derivative(x, x) -12*x^2 + 1 >>> g.derivative(x, Integer(2)) -12*x^2 + 1 - sage: R.<t> = PolynomialRing(ZZ) sage: S.<x> = PolynomialRing(R) sage: f = t^3*x^2 + t^4*x^3 sage: f.derivative() 3*t^4*x^2 + 2*t^3*x sage: f.derivative(x) 3*t^4*x^2 + 2*t^3*x sage: f.derivative(t) 4*t^3*x^3 + 3*t^2*x^2 - >>> from sage.all import * >>> R = PolynomialRing(ZZ, names=('t',)); (t,) = R._first_ngens(1) >>> S = PolynomialRing(R, names=('x',)); (x,) = S._first_ngens(1) >>> f = t**Integer(3)*x**Integer(2) + t**Integer(4)*x**Integer(3) >>> f.derivative() 3*t^4*x^2 + 2*t^3*x >>> f.derivative(x) 3*t^4*x^2 + 2*t^3*x >>> f.derivative(t) 4*t^3*x^3 + 3*t^2*x^2 
 - discriminant()[source]¶
- Return the discriminant of - self.- The discriminant is \[R_n := a_n^{2 n-2} \prod_{1<i<j<n} (r_i-r_j)^2,\]- where \(n\) is the degree of - self, \(a_n\) is the leading coefficient of- self, and the roots of- selfare \(r_1, \ldots, r_n\).- OUTPUT: an element of the base ring of the polynomial ring - ALGORITHM: - Uses the identity \(R_n(f) := (-1)^{n (n-1)/2} R(f, f') a_n^{n-k-2}\), where \(n\) is the degree of - self, \(a_n\) is the leading coefficient of- self, \(f'\) is the derivative of \(f\), and \(k\) is the degree of \(f'\). Calls- resultant().- EXAMPLES: - In the case of elliptic curves in special form, the discriminant is easy to calculate: - sage: R.<x> = QQ[] sage: f = x^3 + x + 1 sage: d = f.discriminant(); d # needs sage.libs.pari -31 sage: d.parent() is QQ # needs sage.libs.pari True sage: EllipticCurve([1, 1]).discriminant()/16 # needs sage.libs.pari sage.schemes -31 - >>> from sage.all import * >>> R = QQ['x']; (x,) = R._first_ngens(1) >>> f = x**Integer(3) + x + Integer(1) >>> d = f.discriminant(); d # needs sage.libs.pari -31 >>> d.parent() is QQ # needs sage.libs.pari True >>> EllipticCurve([Integer(1), Integer(1)]).discriminant()/Integer(16) # needs sage.libs.pari sage.schemes -31 - sage: R.<x> = QQ[] sage: f = 2*x^3 + x + 1 sage: d = f.discriminant(); d # needs sage.libs.pari -116 - >>> from sage.all import * >>> R = QQ['x']; (x,) = R._first_ngens(1) >>> f = Integer(2)*x**Integer(3) + x + Integer(1) >>> d = f.discriminant(); d # needs sage.libs.pari -116 - We can compute discriminants over univariate and multivariate polynomial rings: - sage: R.<a> = QQ[] sage: S.<x> = R[] sage: f = a*x + x + a + 1 sage: d = f.discriminant(); d # needs sage.libs.pari 1 sage: d.parent() is R # needs sage.libs.pari True - >>> from sage.all import * >>> R = QQ['a']; (a,) = R._first_ngens(1) >>> S = R['x']; (x,) = S._first_ngens(1) >>> f = a*x + x + a + Integer(1) >>> d = f.discriminant(); d # needs sage.libs.pari 1 >>> d.parent() is R # needs sage.libs.pari True - sage: R.<a, b> = QQ[] sage: S.<x> = R[] sage: f = x^2 + a + b sage: d = f.discriminant(); d # needs sage.libs.pari -4*a - 4*b sage: d.parent() is R # needs sage.libs.pari True - >>> from sage.all import * >>> R = QQ['a, b']; (a, b,) = R._first_ngens(2) >>> S = R['x']; (x,) = S._first_ngens(1) >>> f = x**Integer(2) + a + b >>> d = f.discriminant(); d # needs sage.libs.pari -4*a - 4*b >>> d.parent() is R # needs sage.libs.pari True 
 - dispersion(other=None)[source]¶
- Compute the dispersion of a pair of polynomials. - The dispersion of \(f\) and \(g\) is the largest nonnegative integer \(n\) such that \(f(x + n)\) and \(g(x)\) have a nonconstant common factor. - When - otheris- None, compute the auto-dispersion of- self, i.e., its dispersion with itself.- See also - EXAMPLES: - sage: Pol.<x> = QQ[] sage: x.dispersion(x + 1) # needs sage.libs.pari 1 sage: (x + 1).dispersion(x) # needs sage.libs.pari -Infinity sage: # needs sage.libs.pari sage.rings.number_field sage.symbolic sage: Pol.<x> = QQbar[] sage: pol = Pol([sqrt(5), 1, 3/2]) sage: pol.dispersion() 0 sage: (pol*pol(x+3)).dispersion() 3 - >>> from sage.all import * >>> Pol = QQ['x']; (x,) = Pol._first_ngens(1) >>> x.dispersion(x + Integer(1)) # needs sage.libs.pari 1 >>> (x + Integer(1)).dispersion(x) # needs sage.libs.pari -Infinity >>> # needs sage.libs.pari sage.rings.number_field sage.symbolic >>> Pol = QQbar['x']; (x,) = Pol._first_ngens(1) >>> pol = Pol([sqrt(Integer(5)), Integer(1), Integer(3)/Integer(2)]) >>> pol.dispersion() 0 >>> (pol*pol(x+Integer(3))).dispersion() 3 
 - dispersion_set(other=None)[source]¶
- Compute the dispersion set of two polynomials. - The dispersion set of \(f\) and \(g\) is the set of nonnegative integers \(n\) such that \(f(x + n)\) and \(g(x)\) have a nonconstant common factor. - When - otheris- None, compute the auto-dispersion set of- self, i.e., its dispersion set with itself.- ALGORITHM: - See Section 4 of Man & Wright [MW1994]. - See also - EXAMPLES: - sage: Pol.<x> = QQ[] sage: x.dispersion_set(x + 1) # needs sage.libs.pari [1] sage: (x + 1).dispersion_set(x) # needs sage.libs.pari [] sage: pol = x^3 + x - 7 sage: (pol*pol(x+3)^2).dispersion_set() # needs sage.libs.pari [0, 3] - >>> from sage.all import * >>> Pol = QQ['x']; (x,) = Pol._first_ngens(1) >>> x.dispersion_set(x + Integer(1)) # needs sage.libs.pari [1] >>> (x + Integer(1)).dispersion_set(x) # needs sage.libs.pari [] >>> pol = x**Integer(3) + x - Integer(7) >>> (pol*pol(x+Integer(3))**Integer(2)).dispersion_set() # needs sage.libs.pari [0, 3] 
 - divides(p)[source]¶
- Return - Trueif this polynomial divides \(p\).- This method is only implemented for polynomials over an integral domain. - EXAMPLES: - sage: R.<x> = ZZ[] sage: (2*x + 1).divides(4*x**2 - 1) True sage: (2*x + 1).divides(4*x**2 + 1) False sage: (2*x + 1).divides(R(0)) True sage: R(0).divides(2*x + 1) False sage: R(0).divides(R(0)) True sage: S.<y> = R[] sage: p = x * y**2 + (2*x + 1) * y + x + 1 sage: q = (x + 1) * y + (3*x + 2) sage: q.divides(p) False sage: q.divides(p * q) True sage: R.<x> = Zmod(6)[] sage: p = 4*x + 3 sage: q = 5*x**2 + x + 2 sage: q.divides(p) False sage: p.divides(q) False - >>> from sage.all import * >>> R = ZZ['x']; (x,) = R._first_ngens(1) >>> (Integer(2)*x + Integer(1)).divides(Integer(4)*x**Integer(2) - Integer(1)) True >>> (Integer(2)*x + Integer(1)).divides(Integer(4)*x**Integer(2) + Integer(1)) False >>> (Integer(2)*x + Integer(1)).divides(R(Integer(0))) True >>> R(Integer(0)).divides(Integer(2)*x + Integer(1)) False >>> R(Integer(0)).divides(R(Integer(0))) True >>> S = R['y']; (y,) = S._first_ngens(1) >>> p = x * y**Integer(2) + (Integer(2)*x + Integer(1)) * y + x + Integer(1) >>> q = (x + Integer(1)) * y + (Integer(3)*x + Integer(2)) >>> q.divides(p) False >>> q.divides(p * q) True >>> R = Zmod(Integer(6))['x']; (x,) = R._first_ngens(1) >>> p = Integer(4)*x + Integer(3) >>> q = Integer(5)*x**Integer(2) + x + Integer(2) >>> q.divides(p) False >>> p.divides(q) False 
 - euclidean_degree()[source]¶
- Return the degree of this element as an element of a Euclidean domain. - If this polynomial is defined over a field, this is simply its - degree().- EXAMPLES: - sage: R.<x> = QQ[] sage: x.euclidean_degree() 1 sage: R.<x> = ZZ[] sage: x.euclidean_degree() Traceback (most recent call last): ... NotImplementedError - >>> from sage.all import * >>> R = QQ['x']; (x,) = R._first_ngens(1) >>> x.euclidean_degree() 1 >>> R = ZZ['x']; (x,) = R._first_ngens(1) >>> x.euclidean_degree() Traceback (most recent call last): ... NotImplementedError 
 - exponents()[source]¶
- Return the exponents of the monomials appearing in - self.- EXAMPLES: - sage: _.<x> = PolynomialRing(ZZ) sage: f = x^4 + 2*x^2 + 1 sage: f.exponents() [0, 2, 4] - >>> from sage.all import * >>> _ = PolynomialRing(ZZ, names=('x',)); (x,) = _._first_ngens(1) >>> f = x**Integer(4) + Integer(2)*x**Integer(2) + Integer(1) >>> f.exponents() [0, 2, 4] 
 - factor(**kwargs)[source]¶
- Return the factorization of - selfover its base ring.- INPUT: - kwargs– any keyword arguments are passed to the method- _factor_univariate_polynomial()of the base ring if it defines such a method.
 - OUTPUT: - A factorization of - selfover its parent into a unit and irreducible factors. If the parent is a polynomial ring over a field, these factors are monic.- EXAMPLES: - Factorization is implemented over various rings. Over \(\QQ\): - sage: x = QQ['x'].0 sage: f = (x^3 - 1)^2 sage: f.factor() # needs sage.libs.pari (x - 1)^2 * (x^2 + x + 1)^2 - >>> from sage.all import * >>> x = QQ['x'].gen(0) >>> f = (x**Integer(3) - Integer(1))**Integer(2) >>> f.factor() # needs sage.libs.pari (x - 1)^2 * (x^2 + x + 1)^2 - Since \(\QQ\) is a field, the irreducible factors are monic: - sage: f = 10*x^5 - 1 sage: f.factor() # needs sage.libs.pari (10) * (x^5 - 1/10) sage: f = 10*x^5 - 10 sage: f.factor() # needs sage.libs.pari (10) * (x - 1) * (x^4 + x^3 + x^2 + x + 1) - >>> from sage.all import * >>> f = Integer(10)*x**Integer(5) - Integer(1) >>> f.factor() # needs sage.libs.pari (10) * (x^5 - 1/10) >>> f = Integer(10)*x**Integer(5) - Integer(10) >>> f.factor() # needs sage.libs.pari (10) * (x - 1) * (x^4 + x^3 + x^2 + x + 1) - Over \(\ZZ\) the irreducible factors need not be monic: - sage: x = ZZ['x'].0 sage: f = 10*x^5 - 1 sage: f.factor() # needs sage.libs.pari 10*x^5 - 1 - >>> from sage.all import * >>> x = ZZ['x'].gen(0) >>> f = Integer(10)*x**Integer(5) - Integer(1) >>> f.factor() # needs sage.libs.pari 10*x^5 - 1 - We factor a non-monic polynomial over a finite field of 25 elements: - sage: # needs sage.rings.finite_rings sage: k.<a> = GF(25) sage: R.<x> = k[] sage: f = 2*x^10 + 2*x + 2*a sage: F = f.factor(); F (2) * (x + a + 2) * (x^2 + 3*x + 4*a + 4) * (x^2 + (a + 1)*x + a + 2) * (x^5 + (3*a + 4)*x^4 + (3*a + 3)*x^3 + 2*a*x^2 + (3*a + 1)*x + 3*a + 1) - >>> from sage.all import * >>> # needs sage.rings.finite_rings >>> k = GF(Integer(25), names=('a',)); (a,) = k._first_ngens(1) >>> R = k['x']; (x,) = R._first_ngens(1) >>> f = Integer(2)*x**Integer(10) + Integer(2)*x + Integer(2)*a >>> F = f.factor(); F (2) * (x + a + 2) * (x^2 + 3*x + 4*a + 4) * (x^2 + (a + 1)*x + a + 2) * (x^5 + (3*a + 4)*x^4 + (3*a + 3)*x^3 + 2*a*x^2 + (3*a + 1)*x + 3*a + 1) - Notice that the unit factor is included when we multiply \(F\) back out: - sage: expand(F) # needs sage.rings.finite_rings sage.symbolic 2*x^10 + 2*x + 2*a - >>> from sage.all import * >>> expand(F) # needs sage.rings.finite_rings sage.symbolic 2*x^10 + 2*x + 2*a - A new ring. In the example below, we set the special method - _factor_univariate_polynomial()in the base ring which is called to factor univariate polynomials. This facility can be used to easily extend polynomial factorization to work over new rings you introduce:- sage: # needs sage.libs.ntl sage: R.<x> = PolynomialRing(IntegerModRing(4), implementation="NTL") sage: (x^2).factor() Traceback (most recent call last): ... NotImplementedError: factorization of polynomials over rings with composite characteristic is not implemented sage: def my_factor(f): ....: return f.change_ring(ZZ).factor() sage: R.base_ring()._factor_univariate_polynomial = my_factor sage: (x^2).factor() # needs sage.libs.pari x^2 sage: del R.base_ring()._factor_univariate_polynomial # clean up - >>> from sage.all import * >>> # needs sage.libs.ntl >>> R = PolynomialRing(IntegerModRing(Integer(4)), implementation="NTL", names=('x',)); (x,) = R._first_ngens(1) >>> (x**Integer(2)).factor() Traceback (most recent call last): ... NotImplementedError: factorization of polynomials over rings with composite characteristic is not implemented >>> def my_factor(f): ... return f.change_ring(ZZ).factor() >>> R.base_ring()._factor_univariate_polynomial = my_factor >>> (x**Integer(2)).factor() # needs sage.libs.pari x^2 >>> del R.base_ring()._factor_univariate_polynomial # clean up - Arbitrary precision real and complex factorization: - sage: # needs sage.libs.pari sage.rings.real_mpfr sage: R.<x> = RealField(100)[] sage: F = factor(x^2 - 3); F (x - 1.7320508075688772935274463415) * (x + 1.7320508075688772935274463415) sage: expand(F) x^2 - 3.0000000000000000000000000000 sage: factor(x^2 + 1) x^2 + 1.0000000000000000000000000000 sage: # needs sage.libs.pari sage.rings.real_mpfr sage: R.<x> = ComplexField(100)[] sage: F = factor(x^2 + 3); F (x - 1.7320508075688772935274463415*I) * (x + 1.7320508075688772935274463415*I) sage: expand(F) x^2 + 3.0000000000000000000000000000 sage: factor(x^2 + 1) (x - I) * (x + I) sage: f = R(I) * (x^2 + 1) ; f I*x^2 + I sage: F = factor(f); F (1.0000000000000000000000000000*I) * (x - I) * (x + I) sage: expand(F) I*x^2 + I - >>> from sage.all import * >>> # needs sage.libs.pari sage.rings.real_mpfr >>> R = RealField(Integer(100))['x']; (x,) = R._first_ngens(1) >>> F = factor(x**Integer(2) - Integer(3)); F (x - 1.7320508075688772935274463415) * (x + 1.7320508075688772935274463415) >>> expand(F) x^2 - 3.0000000000000000000000000000 >>> factor(x**Integer(2) + Integer(1)) x^2 + 1.0000000000000000000000000000 >>> # needs sage.libs.pari sage.rings.real_mpfr >>> R = ComplexField(Integer(100))['x']; (x,) = R._first_ngens(1) >>> F = factor(x**Integer(2) + Integer(3)); F (x - 1.7320508075688772935274463415*I) * (x + 1.7320508075688772935274463415*I) >>> expand(F) x^2 + 3.0000000000000000000000000000 >>> factor(x**Integer(2) + Integer(1)) (x - I) * (x + I) >>> f = R(I) * (x**Integer(2) + Integer(1)) ; f I*x^2 + I >>> F = factor(f); F (1.0000000000000000000000000000*I) * (x - I) * (x + I) >>> expand(F) I*x^2 + I - Over a number field: - sage: # needs sage.rings.number_field sage: K.<z> = CyclotomicField(15) sage: x = polygen(K) sage: ((x^3 + z*x + 1)^3 * (x - z)).factor() (x - z) * (x^3 + z*x + 1)^3 sage: cyclotomic_polynomial(12).change_ring(K).factor() (x^2 - z^5 - 1) * (x^2 + z^5) sage: ((x^3 + z*x + 1)^3 * (x/(z+2) - 1/3)).factor() (-1/331*z^7 + 3/331*z^6 - 6/331*z^5 + 11/331*z^4 - 21/331*z^3 + 41/331*z^2 - 82/331*z + 165/331) * (x - 1/3*z - 2/3) * (x^3 + z*x + 1)^3 - >>> from sage.all import * >>> # needs sage.rings.number_field >>> K = CyclotomicField(Integer(15), names=('z',)); (z,) = K._first_ngens(1) >>> x = polygen(K) >>> ((x**Integer(3) + z*x + Integer(1))**Integer(3) * (x - z)).factor() (x - z) * (x^3 + z*x + 1)^3 >>> cyclotomic_polynomial(Integer(12)).change_ring(K).factor() (x^2 - z^5 - 1) * (x^2 + z^5) >>> ((x**Integer(3) + z*x + Integer(1))**Integer(3) * (x/(z+Integer(2)) - Integer(1)/Integer(3))).factor() (-1/331*z^7 + 3/331*z^6 - 6/331*z^5 + 11/331*z^4 - 21/331*z^3 + 41/331*z^2 - 82/331*z + 165/331) * (x - 1/3*z - 2/3) * (x^3 + z*x + 1)^3 - Over a relative number field: - sage: # needs sage.rings.number_field sage: x = polygen(QQ) sage: K.<z> = CyclotomicField(3) sage: L.<a> = K.extension(x^3 - 2) sage: t = polygen(L, 't') sage: f = (t^3 + t + a) * (t^5 + t + z); f t^8 + t^6 + a*t^5 + t^4 + z*t^3 + t^2 + (a + z)*t + z*a sage: f.factor() (t^3 + t + a) * (t^5 + t + z) - >>> from sage.all import * >>> # needs sage.rings.number_field >>> x = polygen(QQ) >>> K = CyclotomicField(Integer(3), names=('z',)); (z,) = K._first_ngens(1) >>> L = K.extension(x**Integer(3) - Integer(2), names=('a',)); (a,) = L._first_ngens(1) >>> t = polygen(L, 't') >>> f = (t**Integer(3) + t + a) * (t**Integer(5) + t + z); f t^8 + t^6 + a*t^5 + t^4 + z*t^3 + t^2 + (a + z)*t + z*a >>> f.factor() (t^3 + t + a) * (t^5 + t + z) - Over the real double field: - sage: # needs numpy sage: R.<x> = RDF[] sage: (-2*x^2 - 1).factor() (-2.0) * (x^2 + 0.5000000000000001) sage: (-2*x^2 - 1).factor().expand() -2.0*x^2 - 1.0000000000000002 sage: f = (x - 1)^3 sage: f.factor() # abs tol 2e-5 (x - 1.0000065719436413) * (x^2 - 1.9999934280563585*x + 0.9999934280995487) - >>> from sage.all import * >>> # needs numpy >>> R = RDF['x']; (x,) = R._first_ngens(1) >>> (-Integer(2)*x**Integer(2) - Integer(1)).factor() (-2.0) * (x^2 + 0.5000000000000001) >>> (-Integer(2)*x**Integer(2) - Integer(1)).factor().expand() -2.0*x^2 - 1.0000000000000002 >>> f = (x - Integer(1))**Integer(3) >>> f.factor() # abs tol 2e-5 (x - 1.0000065719436413) * (x^2 - 1.9999934280563585*x + 0.9999934280995487) - The above output is incorrect because it relies on the - roots()method, which does not detect that all the roots are real:- sage: f.roots() # abs tol 2e-5 # needs numpy [(1.0000065719436413, 1)] - >>> from sage.all import * >>> f.roots() # abs tol 2e-5 # needs numpy [(1.0000065719436413, 1)] - Over the complex double field the factors are approximate and therefore occur with multiplicity 1: - sage: # needs numpy sage.rings.complex_double sage: R.<x> = CDF[] sage: f = (x^2 + 2*R(I))^3 sage: F = f.factor() sage: F # abs tol 3e-5 (x - 1.0000138879287663 + 1.0000013435286879*I) * (x - 0.9999942196864997 + 0.9999873009803959*I) * (x - 0.9999918923847313 + 1.0000113554909125*I) * (x + 0.9999908759550227 - 1.0000069659624138*I) * (x + 0.9999985293216753 - 0.9999886153831807*I) * (x + 1.0000105947233 - 1.0000044186544053*I) sage: [f(t[0][0]).abs() for t in F] # abs tol 1e-13 [1.979365054e-14, 1.97936298566e-14, 1.97936990747e-14, 3.6812407475e-14, 3.65211563729e-14, 3.65220890052e-14] - >>> from sage.all import * >>> # needs numpy sage.rings.complex_double >>> R = CDF['x']; (x,) = R._first_ngens(1) >>> f = (x**Integer(2) + Integer(2)*R(I))**Integer(3) >>> F = f.factor() >>> F # abs tol 3e-5 (x - 1.0000138879287663 + 1.0000013435286879*I) * (x - 0.9999942196864997 + 0.9999873009803959*I) * (x - 0.9999918923847313 + 1.0000113554909125*I) * (x + 0.9999908759550227 - 1.0000069659624138*I) * (x + 0.9999985293216753 - 0.9999886153831807*I) * (x + 1.0000105947233 - 1.0000044186544053*I) >>> [f(t[Integer(0)][Integer(0)]).abs() for t in F] # abs tol 1e-13 [1.979365054e-14, 1.97936298566e-14, 1.97936990747e-14, 3.6812407475e-14, 3.65211563729e-14, 3.65220890052e-14] - Factoring polynomials over \(\ZZ/n\ZZ\) for composite \(n\) is not implemented: - sage: R.<x> = PolynomialRing(Integers(35)) sage: f = (x^2 + 2*x + 2) * (x^2 + 3*x + 9) sage: f.factor() Traceback (most recent call last): ... NotImplementedError: factorization of polynomials over rings with composite characteristic is not implemented - >>> from sage.all import * >>> R = PolynomialRing(Integers(Integer(35)), names=('x',)); (x,) = R._first_ngens(1) >>> f = (x**Integer(2) + Integer(2)*x + Integer(2)) * (x**Integer(2) + Integer(3)*x + Integer(9)) >>> f.factor() Traceback (most recent call last): ... NotImplementedError: factorization of polynomials over rings with composite characteristic is not implemented - Factoring polynomials over the algebraic numbers (see Issue #8544): - sage: R.<x> = QQbar[] # needs sage.rings.number_field sage: (x^8 - 1).factor() # needs sage.rings.number_field (x - 1) * (x - 0.7071067811865475? - 0.7071067811865475?*I) * (x - 0.7071067811865475? + 0.7071067811865475?*I) * (x - I) * (x + I) * (x + 0.7071067811865475? - 0.7071067811865475?*I) * (x + 0.7071067811865475? + 0.7071067811865475?*I) * (x + 1) - >>> from sage.all import * >>> R = QQbar['x']; (x,) = R._first_ngens(1)# needs sage.rings.number_field >>> (x**Integer(8) - Integer(1)).factor() # needs sage.rings.number_field (x - 1) * (x - 0.7071067811865475? - 0.7071067811865475?*I) * (x - 0.7071067811865475? + 0.7071067811865475?*I) * (x - I) * (x + I) * (x + 0.7071067811865475? - 0.7071067811865475?*I) * (x + 0.7071067811865475? + 0.7071067811865475?*I) * (x + 1) - Factoring polynomials over the algebraic reals (see Issue #8544): - sage: R.<x> = AA[] # needs sage.rings.number_field sage: (x^8 + 1).factor() # needs sage.rings.number_field (x^2 - 1.847759065022574?*x + 1.000000000000000?) * (x^2 - 0.7653668647301795?*x + 1.000000000000000?) * (x^2 + 0.7653668647301795?*x + 1.000000000000000?) * (x^2 + 1.847759065022574?*x + 1.000000000000000?) - >>> from sage.all import * >>> R = AA['x']; (x,) = R._first_ngens(1)# needs sage.rings.number_field >>> (x**Integer(8) + Integer(1)).factor() # needs sage.rings.number_field (x^2 - 1.847759065022574?*x + 1.000000000000000?) * (x^2 - 0.7653668647301795?*x + 1.000000000000000?) * (x^2 + 0.7653668647301795?*x + 1.000000000000000?) * (x^2 + 1.847759065022574?*x + 1.000000000000000?) 
 - gcd(other)[source]¶
- Return a greatest common divisor of this polynomial and - other.- INPUT: - other– a polynomial in the same ring as this polynomial
 - OUTPUT: - A greatest common divisor as a polynomial in the same ring as this polynomial. If the base ring is a field, the return value is a monic polynomial. - Note - The actual algorithm for computing greatest common divisors depends on the base ring underlying the polynomial ring. If the base ring defines a method - _gcd_univariate_polynomial(), then this method will be called (see examples below).- EXAMPLES: - sage: R.<x> = QQ[] sage: (2*x^2).gcd(2*x) x sage: R.zero().gcd(0) 0 sage: (2*x).gcd(0) x - >>> from sage.all import * >>> R = QQ['x']; (x,) = R._first_ngens(1) >>> (Integer(2)*x**Integer(2)).gcd(Integer(2)*x) x >>> R.zero().gcd(Integer(0)) 0 >>> (Integer(2)*x).gcd(Integer(0)) x - One can easily add gcd functionality to new rings by providing a method - _gcd_univariate_polynomial:- sage: # needs sage.rings.number_field sage.symbolic sage: O = ZZ[-sqrt(5)] sage: R.<x> = O[] sage: a = O.1 sage: p = x + a sage: q = x^2 - 5 sage: p.gcd(q) Traceback (most recent call last): ... NotImplementedError: Order of conductor 2 generated by a in Number Field in a with defining polynomial x^2 - 5 with a = -2.236067977499790? does not provide a gcd implementation for univariate polynomials sage: S.<x> = O.number_field()[] sage: O._gcd_univariate_polynomial = lambda f, g: R(S(f).gcd(S(g))) sage: p.gcd(q) x + a sage: del O._gcd_univariate_polynomial - >>> from sage.all import * >>> # needs sage.rings.number_field sage.symbolic >>> O = ZZ[-sqrt(Integer(5))] >>> R = O['x']; (x,) = R._first_ngens(1) >>> a = O.gen(1) >>> p = x + a >>> q = x**Integer(2) - Integer(5) >>> p.gcd(q) Traceback (most recent call last): ... NotImplementedError: Order of conductor 2 generated by a in Number Field in a with defining polynomial x^2 - 5 with a = -2.236067977499790? does not provide a gcd implementation for univariate polynomials >>> S = O.number_field()['x']; (x,) = S._first_ngens(1) >>> O._gcd_univariate_polynomial = lambda f, g: R(S(f).gcd(S(g))) >>> p.gcd(q) x + a >>> del O._gcd_univariate_polynomial - Use multivariate implementation for polynomials over polynomials rings: - sage: R.<x> = ZZ[] sage: S.<y> = R[] sage: T.<z> = S[] sage: r = 2*x*y + z sage: p = r * (3*x*y*z - 1) sage: q = r * (x + y + z - 2) sage: p.gcd(q) # needs sage.libs.singular z + 2*x*y sage: R.<x> = QQ[] sage: S.<y> = R[] sage: r = 2*x*y + 1 sage: p = r * (x - 1/2 * y) sage: q = r * (x*y^2 - x + 1/3) sage: p.gcd(q) # needs sage.libs.singular 2*x*y + 1 - >>> from sage.all import * >>> R = ZZ['x']; (x,) = R._first_ngens(1) >>> S = R['y']; (y,) = S._first_ngens(1) >>> T = S['z']; (z,) = T._first_ngens(1) >>> r = Integer(2)*x*y + z >>> p = r * (Integer(3)*x*y*z - Integer(1)) >>> q = r * (x + y + z - Integer(2)) >>> p.gcd(q) # needs sage.libs.singular z + 2*x*y >>> R = QQ['x']; (x,) = R._first_ngens(1) >>> S = R['y']; (y,) = S._first_ngens(1) >>> r = Integer(2)*x*y + Integer(1) >>> p = r * (x - Integer(1)/Integer(2) * y) >>> q = r * (x*y**Integer(2) - x + Integer(1)/Integer(3)) >>> p.gcd(q) # needs sage.libs.singular 2*x*y + 1 
 - global_height(prec=None)[source]¶
- Return the (projective) global height of the polynomial. - This returns the absolute logarithmic height of the coefficients thought of as a projective point. - INPUT: - prec– desired floating point precision (default: default- RealFieldprecision)
 - OUTPUT: a real number - EXAMPLES: - sage: R.<x> = PolynomialRing(QQ) sage: f = 3*x^3 + 2*x^2 + x sage: exp(f.global_height()) # needs sage.symbolic 3.00000000000000 - >>> from sage.all import * >>> R = PolynomialRing(QQ, names=('x',)); (x,) = R._first_ngens(1) >>> f = Integer(3)*x**Integer(3) + Integer(2)*x**Integer(2) + x >>> exp(f.global_height()) # needs sage.symbolic 3.00000000000000 - Scaling should not change the result: - sage: R.<x> = PolynomialRing(QQ) sage: f = 1/25*x^2 + 25/3*x + 1 sage: f.global_height() # needs sage.symbolic 6.43775164973640 sage: g = 100 * f sage: g.global_height() # needs sage.symbolic 6.43775164973640 - >>> from sage.all import * >>> R = PolynomialRing(QQ, names=('x',)); (x,) = R._first_ngens(1) >>> f = Integer(1)/Integer(25)*x**Integer(2) + Integer(25)/Integer(3)*x + Integer(1) >>> f.global_height() # needs sage.symbolic 6.43775164973640 >>> g = Integer(100) * f >>> g.global_height() # needs sage.symbolic 6.43775164973640 - sage: R.<x> = PolynomialRing(QQbar) # needs sage.rings.number_field sage: f = QQbar(i)*x^2 + 3*x # needs sage.rings.number_field sage: f.global_height() # needs sage.rings.number_field 1.09861228866811 - >>> from sage.all import * >>> R = PolynomialRing(QQbar, names=('x',)); (x,) = R._first_ngens(1)# needs sage.rings.number_field >>> f = QQbar(i)*x**Integer(2) + Integer(3)*x # needs sage.rings.number_field >>> f.global_height() # needs sage.rings.number_field 1.09861228866811 - sage: # needs sage.rings.number_field sage: R.<x> = PolynomialRing(QQ) sage: K.<k> = NumberField(x^2 + 5) sage: T.<t> = PolynomialRing(K) sage: f = 1/1331 * t^2 + 5 * t + 7 sage: f.global_height() 9.13959596745043 - >>> from sage.all import * >>> # needs sage.rings.number_field >>> R = PolynomialRing(QQ, names=('x',)); (x,) = R._first_ngens(1) >>> K = NumberField(x**Integer(2) + Integer(5), names=('k',)); (k,) = K._first_ngens(1) >>> T = PolynomialRing(K, names=('t',)); (t,) = T._first_ngens(1) >>> f = Integer(1)/Integer(1331) * t**Integer(2) + Integer(5) * t + Integer(7) >>> f.global_height() 9.13959596745043 - sage: R.<x> = QQ[] sage: f = 1/123*x^2 + 12 sage: f.global_height(prec=2) # needs sage.symbolic 8.0 - >>> from sage.all import * >>> R = QQ['x']; (x,) = R._first_ngens(1) >>> f = Integer(1)/Integer(123)*x**Integer(2) + Integer(12) >>> f.global_height(prec=Integer(2)) # needs sage.symbolic 8.0 - sage: R.<x> = QQ[] sage: f = 0*x sage: f.global_height() # needs sage.rings.real_mpfr 0.000000000000000 - >>> from sage.all import * >>> R = QQ['x']; (x,) = R._first_ngens(1) >>> f = Integer(0)*x >>> f.global_height() # needs sage.rings.real_mpfr 0.000000000000000 
 - gradient()[source]¶
- Return a list of the partial derivative of - selfwith respect to the variable of this univariate polynomial.- There is only one partial derivative. - EXAMPLES: - sage: P.<x> = QQ[] sage: f = x^2 + (2/3)*x + 1 sage: f.gradient() [2*x + 2/3] sage: f = P(1) sage: f.gradient() [0] - >>> from sage.all import * >>> P = QQ['x']; (x,) = P._first_ngens(1) >>> f = x**Integer(2) + (Integer(2)/Integer(3))*x + Integer(1) >>> f.gradient() [2*x + 2/3] >>> f = P(Integer(1)) >>> f.gradient() [0] 
 - hamming_weight()[source]¶
- Return the number of nonzero coefficients of - self.- Also called weight, Hamming weight or sparsity. - EXAMPLES: - sage: R.<x> = ZZ[] sage: f = x^3 - x sage: f.number_of_terms() 2 sage: R(0).number_of_terms() 0 sage: f = (x + 1)^100 sage: f.number_of_terms() 101 sage: S = GF(5)['y'] sage: S(f).number_of_terms() 5 sage: cyclotomic_polynomial(105).number_of_terms() 33 - >>> from sage.all import * >>> R = ZZ['x']; (x,) = R._first_ngens(1) >>> f = x**Integer(3) - x >>> f.number_of_terms() 2 >>> R(Integer(0)).number_of_terms() 0 >>> f = (x + Integer(1))**Integer(100) >>> f.number_of_terms() 101 >>> S = GF(Integer(5))['y'] >>> S(f).number_of_terms() 5 >>> cyclotomic_polynomial(Integer(105)).number_of_terms() 33 - The method - hamming_weight()is an alias:- sage: f.hamming_weight() 101 - >>> from sage.all import * >>> f.hamming_weight() 101 
 - has_cyclotomic_factor()[source]¶
- Return - Trueif the given polynomial has a nontrivial cyclotomic factor.- The algorithm assumes that the polynomial has rational coefficients. - If the polynomial is known to be irreducible, it may be slightly more efficient to call - is_cyclotomic()instead.- EXAMPLES: - sage: pol.<x> = PolynomialRing(Rationals()) sage: u = x^5 - 1; u.has_cyclotomic_factor() True sage: u = x^5 - 2; u.has_cyclotomic_factor() False sage: u = pol(cyclotomic_polynomial(7)) * pol.random_element() # random sage: u.has_cyclotomic_factor() # random True - >>> from sage.all import * >>> pol = PolynomialRing(Rationals(), names=('x',)); (x,) = pol._first_ngens(1) >>> u = x**Integer(5) - Integer(1); u.has_cyclotomic_factor() True >>> u = x**Integer(5) - Integer(2); u.has_cyclotomic_factor() False >>> u = pol(cyclotomic_polynomial(Integer(7))) * pol.random_element() # random >>> u.has_cyclotomic_factor() # random True 
 - homogenize(var='h')[source]¶
- Return the homogenization of this polynomial. - The polynomial itself is returned if it is homogeneous already. Otherwise, its monomials are multiplied with the smallest powers of - varsuch that they all have the same total degree.- INPUT: - var– a variable in the polynomial ring (as a string, an element of the ring, or- 0) or a name for a new variable (default:- 'h')
 - OUTPUT: - If - varspecifies the variable in the polynomial ring, then a homogeneous element in that ring is returned. Otherwise, a homogeneous element is returned in a polynomial ring with an extra last variable- var.- EXAMPLES: - sage: R.<x> = QQ[] sage: f = x^2 + 1 sage: f.homogenize() x^2 + h^2 - >>> from sage.all import * >>> R = QQ['x']; (x,) = R._first_ngens(1) >>> f = x**Integer(2) + Integer(1) >>> f.homogenize() x^2 + h^2 - The parameter - varcan be used to specify the name of the variable:- sage: g = f.homogenize('z'); g x^2 + z^2 sage: g.parent() Multivariate Polynomial Ring in x, z over Rational Field - >>> from sage.all import * >>> g = f.homogenize('z'); g x^2 + z^2 >>> g.parent() Multivariate Polynomial Ring in x, z over Rational Field - However, if the polynomial is homogeneous already, then that parameter is ignored and no extra variable is added to the polynomial ring: - sage: f = x^2 sage: g = f.homogenize('z'); g x^2 sage: g.parent() Univariate Polynomial Ring in x over Rational Field - >>> from sage.all import * >>> f = x**Integer(2) >>> g = f.homogenize('z'); g x^2 >>> g.parent() Univariate Polynomial Ring in x over Rational Field - For compatibility with the multivariate case, if - varspecifies the variable of the polynomial ring, then the monomials are multiplied with the smallest powers of- varsuch that the result is homogeneous; in other words, we end up with a monomial whose leading coefficient is the sum of the coefficients of the polynomial:- sage: f = x^2 + x + 1 sage: f.homogenize('x') 3*x^2 - >>> from sage.all import * >>> f = x**Integer(2) + x + Integer(1) >>> f.homogenize('x') 3*x^2 - In positive characteristic, the degree can drop in this case: - sage: R.<x> = GF(2)[] sage: f = x + 1 sage: f.homogenize(x) 0 - >>> from sage.all import * >>> R = GF(Integer(2))['x']; (x,) = R._first_ngens(1) >>> f = x + Integer(1) >>> f.homogenize(x) 0 - For compatibility with the multivariate case, the parameter - varcan also be 0 to specify the variable in the polynomial ring:- sage: R.<x> = QQ[] sage: f = x^2 + x + 1 sage: f.homogenize(0) 3*x^2 - >>> from sage.all import * >>> R = QQ['x']; (x,) = R._first_ngens(1) >>> f = x**Integer(2) + x + Integer(1) >>> f.homogenize(Integer(0)) 3*x^2 
 - integral(var=None)[source]¶
- Return the integral of this polynomial. - By default, the integration variable is the variable of the polynomial. - Otherwise, the integration variable is the optional parameter - var- Note - The integral is always chosen so that the constant term is 0. - EXAMPLES: - sage: R.<x> = ZZ[] sage: R(0).integral() 0 sage: f = R(2).integral(); f 2*x - >>> from sage.all import * >>> R = ZZ['x']; (x,) = R._first_ngens(1) >>> R(Integer(0)).integral() 0 >>> f = R(Integer(2)).integral(); f 2*x - Note that the integral lives over the fraction field of the scalar coefficients: - sage: f.parent() Univariate Polynomial Ring in x over Rational Field sage: R(0).integral().parent() Univariate Polynomial Ring in x over Rational Field sage: f = x^3 + x - 2 sage: g = f.integral(); g 1/4*x^4 + 1/2*x^2 - 2*x sage: g.parent() Univariate Polynomial Ring in x over Rational Field - >>> from sage.all import * >>> f.parent() Univariate Polynomial Ring in x over Rational Field >>> R(Integer(0)).integral().parent() Univariate Polynomial Ring in x over Rational Field >>> f = x**Integer(3) + x - Integer(2) >>> g = f.integral(); g 1/4*x^4 + 1/2*x^2 - 2*x >>> g.parent() Univariate Polynomial Ring in x over Rational Field - This shows that the issue at Issue #7711 is resolved: - sage: # needs sage.rings.finite_rings sage: P.<x,z> = PolynomialRing(GF(2147483647)) sage: Q.<y> = PolynomialRing(P) sage: p = x + y + z sage: p.integral() -1073741823*y^2 + (x + z)*y sage: # needs sage.rings.finite_rings sage: P.<x,z> = PolynomialRing(GF(next_prime(2147483647))) sage: Q.<y> = PolynomialRing(P) sage: p = x + y + z sage: p.integral() 1073741830*y^2 + (x + z)*y - >>> from sage.all import * >>> # needs sage.rings.finite_rings >>> P = PolynomialRing(GF(Integer(2147483647)), names=('x', 'z',)); (x, z,) = P._first_ngens(2) >>> Q = PolynomialRing(P, names=('y',)); (y,) = Q._first_ngens(1) >>> p = x + y + z >>> p.integral() -1073741823*y^2 + (x + z)*y >>> # needs sage.rings.finite_rings >>> P = PolynomialRing(GF(next_prime(Integer(2147483647))), names=('x', 'z',)); (x, z,) = P._first_ngens(2) >>> Q = PolynomialRing(P, names=('y',)); (y,) = Q._first_ngens(1) >>> p = x + y + z >>> p.integral() 1073741830*y^2 + (x + z)*y - A truly convoluted example: - sage: A.<a1, a2> = PolynomialRing(ZZ) sage: B.<b> = PolynomialRing(A) sage: C.<c> = PowerSeriesRing(B) sage: R.<x> = PolynomialRing(C) sage: f = a2*x^2 + c*x - a1*b sage: f.parent() Univariate Polynomial Ring in x over Power Series Ring in c over Univariate Polynomial Ring in b over Multivariate Polynomial Ring in a1, a2 over Integer Ring sage: f.integral() 1/3*a2*x^3 + 1/2*c*x^2 - a1*b*x sage: f.integral().parent() Univariate Polynomial Ring in x over Power Series Ring in c over Univariate Polynomial Ring in b over Multivariate Polynomial Ring in a1, a2 over Rational Field sage: g = 3*a2*x^2 + 2*c*x - a1*b sage: g.integral() a2*x^3 + c*x^2 - a1*b*x sage: g.integral().parent() Univariate Polynomial Ring in x over Power Series Ring in c over Univariate Polynomial Ring in b over Multivariate Polynomial Ring in a1, a2 over Rational Field - >>> from sage.all import * >>> A = PolynomialRing(ZZ, names=('a1', 'a2',)); (a1, a2,) = A._first_ngens(2) >>> B = PolynomialRing(A, names=('b',)); (b,) = B._first_ngens(1) >>> C = PowerSeriesRing(B, names=('c',)); (c,) = C._first_ngens(1) >>> R = PolynomialRing(C, names=('x',)); (x,) = R._first_ngens(1) >>> f = a2*x**Integer(2) + c*x - a1*b >>> f.parent() Univariate Polynomial Ring in x over Power Series Ring in c over Univariate Polynomial Ring in b over Multivariate Polynomial Ring in a1, a2 over Integer Ring >>> f.integral() 1/3*a2*x^3 + 1/2*c*x^2 - a1*b*x >>> f.integral().parent() Univariate Polynomial Ring in x over Power Series Ring in c over Univariate Polynomial Ring in b over Multivariate Polynomial Ring in a1, a2 over Rational Field >>> g = Integer(3)*a2*x**Integer(2) + Integer(2)*c*x - a1*b >>> g.integral() a2*x^3 + c*x^2 - a1*b*x >>> g.integral().parent() Univariate Polynomial Ring in x over Power Series Ring in c over Univariate Polynomial Ring in b over Multivariate Polynomial Ring in a1, a2 over Rational Field - Integration with respect to a variable in the base ring: - sage: R.<x> = QQ[] sage: t = PolynomialRing(R,'t').gen() sage: f = x*t + 5*t^2 sage: f.integral(x) 5*x*t^2 + 1/2*x^2*t - >>> from sage.all import * >>> R = QQ['x']; (x,) = R._first_ngens(1) >>> t = PolynomialRing(R,'t').gen() >>> f = x*t + Integer(5)*t**Integer(2) >>> f.integral(x) 5*x*t^2 + 1/2*x^2*t 
 - inverse_mod(a, m)[source]¶
- Invert the polynomial - awith respect to- m, or raise a- ValueErrorif no such inverse exists.- The parameter - mmay be either a single polynomial or an ideal (for consistency with- inverse_mod()in other rings).- See also - If you are only interested in the inverse modulo a monomial \(x^k\) then you might use the specialized method - inverse_series_trunc()which is much faster.- EXAMPLES: - sage: S.<t> = QQ[] sage: f = inverse_mod(t^2 + 1, t^3 + 1); f -1/2*t^2 - 1/2*t + 1/2 sage: f * (t^2 + 1) % (t^3 + 1) 1 sage: f = t.inverse_mod((t + 1)^7); f -t^6 - 7*t^5 - 21*t^4 - 35*t^3 - 35*t^2 - 21*t - 7 sage: (f * t) + (t + 1)^7 1 sage: t.inverse_mod(S.ideal((t + 1)^7)) == f True - >>> from sage.all import * >>> S = QQ['t']; (t,) = S._first_ngens(1) >>> f = inverse_mod(t**Integer(2) + Integer(1), t**Integer(3) + Integer(1)); f -1/2*t^2 - 1/2*t + 1/2 >>> f * (t**Integer(2) + Integer(1)) % (t**Integer(3) + Integer(1)) 1 >>> f = t.inverse_mod((t + Integer(1))**Integer(7)); f -t^6 - 7*t^5 - 21*t^4 - 35*t^3 - 35*t^2 - 21*t - 7 >>> (f * t) + (t + Integer(1))**Integer(7) 1 >>> t.inverse_mod(S.ideal((t + Integer(1))**Integer(7))) == f True - This also works over inexact rings, but note that due to rounding error the product may not always exactly equal the constant polynomial 1 and have extra terms with coefficients close to zero. - sage: # needs scipy sage.modules sage: R.<x> = RDF[] sage: epsilon = RDF(1).ulp()*50 # Allow an error of up to 50 ulp sage: f = inverse_mod(x^2 + 1, x^5 + x + 1); f # abs tol 1e-14 0.4*x^4 - 0.2*x^3 - 0.4*x^2 + 0.2*x + 0.8 sage: poly = f * (x^2 + 1) % (x^5 + x + 1) sage: # Remove noisy zero terms: sage: parent(poly)([0.0 if abs(c) <= epsilon else c ....: for c in poly.coefficients(sparse=False)]) 1.0 sage: f = inverse_mod(x^3 - x + 1, x - 2); f 0.14285714285714285 sage: f * (x^3 - x + 1) % (x - 2) 1.0 sage: g = 5*x^3 + x - 7; m = x^4 - 12*x + 13; f = inverse_mod(g, m); f -0.0319636125...*x^3 - 0.0383269759...*x^2 - 0.0463050900...*x + 0.346479687... sage: poly = f*g % m sage: # Remove noisy zero terms: sage: parent(poly)([0.0 if abs(c) <= epsilon else c # abs tol 1e-14 ....: for c in poly.coefficients(sparse=False)]) 1.0000000000000004 - >>> from sage.all import * >>> # needs scipy sage.modules >>> R = RDF['x']; (x,) = R._first_ngens(1) >>> epsilon = RDF(Integer(1)).ulp()*Integer(50) # Allow an error of up to 50 ulp >>> f = inverse_mod(x**Integer(2) + Integer(1), x**Integer(5) + x + Integer(1)); f # abs tol 1e-14 0.4*x^4 - 0.2*x^3 - 0.4*x^2 + 0.2*x + 0.8 >>> poly = f * (x**Integer(2) + Integer(1)) % (x**Integer(5) + x + Integer(1)) >>> # Remove noisy zero terms: >>> parent(poly)([RealNumber('0.0') if abs(c) <= epsilon else c ... for c in poly.coefficients(sparse=False)]) 1.0 >>> f = inverse_mod(x**Integer(3) - x + Integer(1), x - Integer(2)); f 0.14285714285714285 >>> f * (x**Integer(3) - x + Integer(1)) % (x - Integer(2)) 1.0 >>> g = Integer(5)*x**Integer(3) + x - Integer(7); m = x**Integer(4) - Integer(12)*x + Integer(13); f = inverse_mod(g, m); f -0.0319636125...*x^3 - 0.0383269759...*x^2 - 0.0463050900...*x + 0.346479687... >>> poly = f*g % m >>> # Remove noisy zero terms: >>> parent(poly)([RealNumber('0.0') if abs(c) <= epsilon else c # abs tol 1e-14 ... for c in poly.coefficients(sparse=False)]) 1.0000000000000004 - ALGORITHM: Solve the system \(as + mt = 1\), returning \(s\) as the inverse of \(a\) mod \(m\). - Uses the Euclidean algorithm for exact rings, and solves a linear system for the coefficients of \(s\) and \(t\) for inexact rings (as the Euclidean algorithm may not converge in that case). - AUTHORS: - Robert Bradshaw (2007-05-31) 
 
 - inverse_of_unit()[source]¶
- EXAMPLES: - sage: R.<x> = QQ[] sage: f = x - 90283 sage: f.inverse_of_unit() Traceback (most recent call last): ... ArithmeticError: x - 90283 is not a unit in Univariate Polynomial Ring in x over Rational Field sage: f = R(-90283); g = f.inverse_of_unit(); g -1/90283 sage: parent(g) Univariate Polynomial Ring in x over Rational Field - >>> from sage.all import * >>> R = QQ['x']; (x,) = R._first_ngens(1) >>> f = x - Integer(90283) >>> f.inverse_of_unit() Traceback (most recent call last): ... ArithmeticError: x - 90283 is not a unit in Univariate Polynomial Ring in x over Rational Field >>> f = R(-Integer(90283)); g = f.inverse_of_unit(); g -1/90283 >>> parent(g) Univariate Polynomial Ring in x over Rational Field 
 - inverse_series_trunc(prec)[source]¶
- Return a polynomial approximation of precision - precof the inverse series of this polynomial.- See also - The method - inverse_mod()allows more generally to invert this polynomial with respect to any ideal.- EXAMPLES: - sage: x = polygen(ZZ) sage: s = (1 + x).inverse_series_trunc(5) sage: s x^4 - x^3 + x^2 - x + 1 sage: s * (1 + x) x^5 + 1 - >>> from sage.all import * >>> x = polygen(ZZ) >>> s = (Integer(1) + x).inverse_series_trunc(Integer(5)) >>> s x^4 - x^3 + x^2 - x + 1 >>> s * (Integer(1) + x) x^5 + 1 - Note that the constant coefficient needs to be a unit: - sage: ZZx.<x> = ZZ[] sage: ZZxy.<y> = ZZx[] sage: (1+x + y**2).inverse_series_trunc(4) Traceback (most recent call last): ... ValueError: constant term x + 1 is not a unit sage: (1+x + y**2).change_ring(ZZx.fraction_field()).inverse_series_trunc(4) (-1/(x^2 + 2*x + 1))*y^2 + 1/(x + 1) - >>> from sage.all import * >>> ZZx = ZZ['x']; (x,) = ZZx._first_ngens(1) >>> ZZxy = ZZx['y']; (y,) = ZZxy._first_ngens(1) >>> (Integer(1)+x + y**Integer(2)).inverse_series_trunc(Integer(4)) Traceback (most recent call last): ... ValueError: constant term x + 1 is not a unit >>> (Integer(1)+x + y**Integer(2)).change_ring(ZZx.fraction_field()).inverse_series_trunc(Integer(4)) (-1/(x^2 + 2*x + 1))*y^2 + 1/(x + 1) - The method works over any polynomial ring: - sage: R = Zmod(4) sage: Rx.<x> = R[] sage: Rxy.<y> = Rx[] sage: p = 1 + (1+2*x)*y + x**2*y**4 sage: q = p.inverse_series_trunc(10) sage: (p*q).truncate(11) (2*x^4 + 3*x^2 + 3)*y^10 + 1 - >>> from sage.all import * >>> R = Zmod(Integer(4)) >>> Rx = R['x']; (x,) = Rx._first_ngens(1) >>> Rxy = Rx['y']; (y,) = Rxy._first_ngens(1) >>> p = Integer(1) + (Integer(1)+Integer(2)*x)*y + x**Integer(2)*y**Integer(4) >>> q = p.inverse_series_trunc(Integer(10)) >>> (p*q).truncate(Integer(11)) (2*x^4 + 3*x^2 + 3)*y^10 + 1 - Even noncommutative ones: - sage: # needs sage.modules sage: M = MatrixSpace(ZZ, 2) sage: x = polygen(M) sage: p = M([1,2,3,4])*x^3 + M([-1,0,0,1])*x^2 + M([1,3,-1,0])*x + M.one() sage: q = p.inverse_series_trunc(5) sage: (p*q).truncate(5) == M.one() True sage: q = p.inverse_series_trunc(13) sage: (p*q).truncate(13) == M.one() True - >>> from sage.all import * >>> # needs sage.modules >>> M = MatrixSpace(ZZ, Integer(2)) >>> x = polygen(M) >>> p = M([Integer(1),Integer(2),Integer(3),Integer(4)])*x**Integer(3) + M([-Integer(1),Integer(0),Integer(0),Integer(1)])*x**Integer(2) + M([Integer(1),Integer(3),-Integer(1),Integer(0)])*x + M.one() >>> q = p.inverse_series_trunc(Integer(5)) >>> (p*q).truncate(Integer(5)) == M.one() True >>> q = p.inverse_series_trunc(Integer(13)) >>> (p*q).truncate(Integer(13)) == M.one() True - AUTHORS: - David Harvey (2006-09-09): Newton’s method implementation for power series 
- Vincent Delecroix (2014-2015): move the implementation directly in polynomial 
 
 - is_constant()[source]¶
- Return - Trueif this is a constant polynomial.- OUTPUT: boolean; - Trueif and only if this polynomial is constant- EXAMPLES: - sage: R.<x> = ZZ[] sage: x.is_constant() False sage: R(2).is_constant() True sage: R(0).is_constant() True - >>> from sage.all import * >>> R = ZZ['x']; (x,) = R._first_ngens(1) >>> x.is_constant() False >>> R(Integer(2)).is_constant() True >>> R(Integer(0)).is_constant() True 
 - is_cyclotomic(certificate=False, algorithm='pari')[source]¶
- Test if this polynomial is a cyclotomic polynomial. - A cyclotomic polynomial is a monic, irreducible polynomial such that all roots are roots of unity. - By default the answer is a boolean. But if - certificateis- True, the result is a nonnegative integer: it is- 0if- selfis not cyclotomic, and a positive integer- nif- selfis the \(n\)-th cyclotomic polynomial.- INPUT: - certificate– boolean (default:- False); only works with- algorithmset to- 'pari'
- algorithm– either- 'pari'(default) or- 'sage'
 - ALGORITHM: - The native algorithm implemented in Sage uses the first algorithm of [BD1989]. The algorithm in PARI (using pari:poliscyclo) is more subtle since it does compute the inverse of the Euler \(\phi\) function to determine the \(n\) such that the polynomial is the \(n\)-th cyclotomic polynomial. - EXAMPLES: - Quick tests: - sage: # needs sage.libs.pari sage: P.<x> = ZZ['x'] sage: (x - 1).is_cyclotomic() True sage: (x + 1).is_cyclotomic() True sage: (x^2 - 1).is_cyclotomic() False sage: (x^2 + x + 1).is_cyclotomic(certificate=True) 3 sage: (x^2 + 2*x + 1).is_cyclotomic(certificate=True) 0 - >>> from sage.all import * >>> # needs sage.libs.pari >>> P = ZZ['x']; (x,) = P._first_ngens(1) >>> (x - Integer(1)).is_cyclotomic() True >>> (x + Integer(1)).is_cyclotomic() True >>> (x**Integer(2) - Integer(1)).is_cyclotomic() False >>> (x**Integer(2) + x + Integer(1)).is_cyclotomic(certificate=True) 3 >>> (x**Integer(2) + Integer(2)*x + Integer(1)).is_cyclotomic(certificate=True) 0 - Test first 100 cyclotomic polynomials: - sage: all(cyclotomic_polynomial(i).is_cyclotomic() for i in range(1, 101)) # needs sage.libs.pari True - >>> from sage.all import * >>> all(cyclotomic_polynomial(i).is_cyclotomic() for i in range(Integer(1), Integer(101))) # needs sage.libs.pari True - Some more tests: - sage: # needs sage.libs.pari sage: f = x^16 + x^14 - x^10 + x^8 - x^6 + x^2 + 1 sage: f.is_cyclotomic(algorithm='pari') False sage: f.is_cyclotomic(algorithm='sage') False sage: g = x^16 + x^14 - x^10 - x^8 - x^6 + x^2 + 1 sage: g.is_cyclotomic(algorithm='pari') True sage: g.is_cyclotomic(algorithm='sage') True sage: y = polygen(QQ) sage: (y/2 - 1/2).is_cyclotomic() False sage: (2*(y/2 - 1/2)).is_cyclotomic() # needs sage.libs.pari True - >>> from sage.all import * >>> # needs sage.libs.pari >>> f = x**Integer(16) + x**Integer(14) - x**Integer(10) + x**Integer(8) - x**Integer(6) + x**Integer(2) + Integer(1) >>> f.is_cyclotomic(algorithm='pari') False >>> f.is_cyclotomic(algorithm='sage') False >>> g = x**Integer(16) + x**Integer(14) - x**Integer(10) - x**Integer(8) - x**Integer(6) + x**Integer(2) + Integer(1) >>> g.is_cyclotomic(algorithm='pari') True >>> g.is_cyclotomic(algorithm='sage') True >>> y = polygen(QQ) >>> (y/Integer(2) - Integer(1)/Integer(2)).is_cyclotomic() False >>> (Integer(2)*(y/Integer(2) - Integer(1)/Integer(2))).is_cyclotomic() # needs sage.libs.pari True - Invalid arguments: - sage: (x - 3).is_cyclotomic(algorithm='sage', certificate=True) # needs sage.libs.pari Traceback (most recent call last): ... ValueError: no implementation of the certificate within Sage - >>> from sage.all import * >>> (x - Integer(3)).is_cyclotomic(algorithm='sage', certificate=True) # needs sage.libs.pari Traceback (most recent call last): ... ValueError: no implementation of the certificate within Sage - Test using other rings: - sage: z = polygen(GF(5)) sage: (z - 1).is_cyclotomic() Traceback (most recent call last): ... NotImplementedError: not implemented in nonzero characteristic - >>> from sage.all import * >>> z = polygen(GF(Integer(5))) >>> (z - Integer(1)).is_cyclotomic() Traceback (most recent call last): ... NotImplementedError: not implemented in nonzero characteristic 
 - is_cyclotomic_product()[source]¶
- Test whether this polynomial is a product of cyclotomic polynomials. - This method simply calls the function pari:poliscycloprod from the Pari library. - EXAMPLES: - sage: x = polygen(ZZ) sage: (x^5 - 1).is_cyclotomic_product() # needs sage.libs.pari True sage: (x^5 + x^4 - x^2 + 1).is_cyclotomic_product() # needs sage.libs.pari False sage: p = prod(cyclotomic_polynomial(i) for i in [2, 5, 7, 12]) sage: p.is_cyclotomic_product() # needs sage.libs.pari True sage: (x^5 - 1/3).is_cyclotomic_product() False sage: x = polygen(Zmod(5)) sage: (x - 1).is_cyclotomic_product() Traceback (most recent call last): ... NotImplementedError: not implemented in nonzero characteristic - >>> from sage.all import * >>> x = polygen(ZZ) >>> (x**Integer(5) - Integer(1)).is_cyclotomic_product() # needs sage.libs.pari True >>> (x**Integer(5) + x**Integer(4) - x**Integer(2) + Integer(1)).is_cyclotomic_product() # needs sage.libs.pari False >>> p = prod(cyclotomic_polynomial(i) for i in [Integer(2), Integer(5), Integer(7), Integer(12)]) >>> p.is_cyclotomic_product() # needs sage.libs.pari True >>> (x**Integer(5) - Integer(1)/Integer(3)).is_cyclotomic_product() False >>> x = polygen(Zmod(Integer(5))) >>> (x - Integer(1)).is_cyclotomic_product() Traceback (most recent call last): ... NotImplementedError: not implemented in nonzero characteristic 
 - is_gen()[source]¶
- Return - Trueif this polynomial is the distinguished generator of the parent polynomial ring.- EXAMPLES: - sage: R.<x> = QQ[] sage: R(1).is_gen() False sage: R(x).is_gen() True - >>> from sage.all import * >>> R = QQ['x']; (x,) = R._first_ngens(1) >>> R(Integer(1)).is_gen() False >>> R(x).is_gen() True - Important - this function doesn’t return - Trueif- selfequals the generator; it returns- Trueif- selfis the generator.- sage: f = R([0,1]); f x sage: f.is_gen() False sage: f is x False sage: f == x True - >>> from sage.all import * >>> f = R([Integer(0),Integer(1)]); f x >>> f.is_gen() False >>> f is x False >>> f == x True 
 - is_homogeneous()[source]¶
- Return - Trueif this polynomial is homogeneous.- EXAMPLES: - sage: P.<x> = PolynomialRing(QQ) sage: x.is_homogeneous() True sage: P(0).is_homogeneous() True sage: (x + 1).is_homogeneous() False - >>> from sage.all import * >>> P = PolynomialRing(QQ, names=('x',)); (x,) = P._first_ngens(1) >>> x.is_homogeneous() True >>> P(Integer(0)).is_homogeneous() True >>> (x + Integer(1)).is_homogeneous() False 
 - is_irreducible()[source]¶
- Return whether this polynomial is irreducible. - EXAMPLES: - sage: R.<x> = ZZ[] sage: (x^3 + 1).is_irreducible() # needs sage.libs.pari False sage: (x^2 - 1).is_irreducible() # needs sage.libs.pari False sage: (x^3 + 2).is_irreducible() # needs sage.libs.pari True sage: R(0).is_irreducible() False - >>> from sage.all import * >>> R = ZZ['x']; (x,) = R._first_ngens(1) >>> (x**Integer(3) + Integer(1)).is_irreducible() # needs sage.libs.pari False >>> (x**Integer(2) - Integer(1)).is_irreducible() # needs sage.libs.pari False >>> (x**Integer(3) + Integer(2)).is_irreducible() # needs sage.libs.pari True >>> R(Integer(0)).is_irreducible() False - The base ring does matter: for example, \(2x\) is irreducible as a polynomial in \(\QQ[x]\), but not in \(\ZZ[x]\): - sage: R.<x> = ZZ[] sage: R(2*x).is_irreducible() # needs sage.libs.pari False sage: R.<x> = QQ[] sage: R(2*x).is_irreducible() # needs sage.libs.pari True - >>> from sage.all import * >>> R = ZZ['x']; (x,) = R._first_ngens(1) >>> R(Integer(2)*x).is_irreducible() # needs sage.libs.pari False >>> R = QQ['x']; (x,) = R._first_ngens(1) >>> R(Integer(2)*x).is_irreducible() # needs sage.libs.pari True 
 - is_lorentzian(explain=False)[source]¶
- Return - Trueif this is a Lorentzian polynomial.- A univariate real polynomial is Lorentzian if and only if it is a monomial with positive coefficient, or zero. The definition is more involved for multivariate real polynomials. - INPUT: - explain– boolean (default:- False); if- Truereturn a tuple whose first element is the boolean result of the test, and the second element is a string describing the reason the test failed, or- Noneif the test succeeded
 - EXAMPLES: - sage: P.<x> = QQ[] sage: p1 = x^2 sage: p1.is_lorentzian() True sage: p2 = 1 + x^2 sage: p2.is_lorentzian() False sage: p3 = P.zero() sage: p3.is_lorentzian() True sage: p4 = -2*x^3 sage: p4.is_lorentzian() False - >>> from sage.all import * >>> P = QQ['x']; (x,) = P._first_ngens(1) >>> p1 = x**Integer(2) >>> p1.is_lorentzian() True >>> p2 = Integer(1) + x**Integer(2) >>> p2.is_lorentzian() False >>> p3 = P.zero() >>> p3.is_lorentzian() True >>> p4 = -Integer(2)*x**Integer(3) >>> p4.is_lorentzian() False - It is an error to check if a polynomial is Lorentzian if its base ring is not a subring of the real numbers, as the notion is not defined in this case: - sage: # needs sage.rings.real_mpfr sage: Q.<y> = CC[] sage: q = y^2 sage: q.is_lorentzian() Traceback (most recent call last): ... NotImplementedError: is_lorentzian only implemented for real polynomials - >>> from sage.all import * >>> # needs sage.rings.real_mpfr >>> Q = CC['y']; (y,) = Q._first_ngens(1) >>> q = y**Integer(2) >>> q.is_lorentzian() Traceback (most recent call last): ... NotImplementedError: is_lorentzian only implemented for real polynomials - The method can give a reason for a polynomial failing to be Lorentzian: - sage: p = x^2 + 2*x sage: p.is_lorentzian(explain=True) (False, 'inhomogeneous') - >>> from sage.all import * >>> p = x**Integer(2) + Integer(2)*x >>> p.is_lorentzian(explain=True) (False, 'inhomogeneous') - REFERENCES: - For full definitions and related discussion, see [BrHu2019] and [HMMS2019]. 
 - is_monic()[source]¶
- Return - Trueif this polynomial is monic. The zero polynomial is by definition not monic.- EXAMPLES: - sage: x = QQ['x'].0 sage: f = x + 33 sage: f.is_monic() True sage: f = 0*x sage: f.is_monic() False sage: f = 3*x^3 + x^4 + x^2 sage: f.is_monic() True sage: f = 2*x^2 + x^3 + 56*x^5 sage: f.is_monic() False - >>> from sage.all import * >>> x = QQ['x'].gen(0) >>> f = x + Integer(33) >>> f.is_monic() True >>> f = Integer(0)*x >>> f.is_monic() False >>> f = Integer(3)*x**Integer(3) + x**Integer(4) + x**Integer(2) >>> f.is_monic() True >>> f = Integer(2)*x**Integer(2) + x**Integer(3) + Integer(56)*x**Integer(5) >>> f.is_monic() False - AUTHORS: - Naqi Jaffery (2006-01-24): examples 
 
 - is_monomial()[source]¶
- Return - Trueif- selfis a monomial, i.e., a power of the generator.- EXAMPLES: - sage: R.<x> = QQ[] sage: x.is_monomial() True sage: (x + 1).is_monomial() False sage: (x^2).is_monomial() True sage: R(1).is_monomial() True - >>> from sage.all import * >>> R = QQ['x']; (x,) = R._first_ngens(1) >>> x.is_monomial() True >>> (x + Integer(1)).is_monomial() False >>> (x**Integer(2)).is_monomial() True >>> R(Integer(1)).is_monomial() True - The coefficient must be 1: - sage: (2*x^5).is_monomial() False - >>> from sage.all import * >>> (Integer(2)*x**Integer(5)).is_monomial() False - To allow a non-1 leading coefficient, use - is_term():- sage: (2*x^5).is_term() True - >>> from sage.all import * >>> (Integer(2)*x**Integer(5)).is_term() True - Warning - The definition of - is_monomial()in Sage up to 4.7.1 was the same as- is_term(), i.e., it allowed a coefficient not equal to 1.
 - is_nilpotent()[source]¶
- Return - Trueif this polynomial is nilpotent.- EXAMPLES: - sage: R = Integers(12) sage: S.<x> = R[] sage: f = 5 + 6*x sage: f.is_nilpotent() False sage: f = 6 + 6*x^2 sage: f.is_nilpotent() True sage: f^2 0 - >>> from sage.all import * >>> R = Integers(Integer(12)) >>> S = R['x']; (x,) = S._first_ngens(1) >>> f = Integer(5) + Integer(6)*x >>> f.is_nilpotent() False >>> f = Integer(6) + Integer(6)*x**Integer(2) >>> f.is_nilpotent() True >>> f**Integer(2) 0 - EXERCISE (Atiyah-McDonald, Ch 1): Let \(A[x]\) be a polynomial ring in one variable. Then \(f=\sum a_i x^i \in A[x]\) is nilpotent if and only if every \(a_i\) is nilpotent. 
 - is_one()[source]¶
- Test whether this polynomial is 1. - EXAMPLES: - sage: R.<x> = QQ[] sage: (x - 3).is_one() False sage: R(1).is_one() True sage: R2.<y> = R[] sage: R2(x).is_one() False sage: R2(1).is_one() True sage: R2(-1).is_one() False - >>> from sage.all import * >>> R = QQ['x']; (x,) = R._first_ngens(1) >>> (x - Integer(3)).is_one() False >>> R(Integer(1)).is_one() True >>> R2 = R['y']; (y,) = R2._first_ngens(1) >>> R2(x).is_one() False >>> R2(Integer(1)).is_one() True >>> R2(-Integer(1)).is_one() False 
 - is_primitive(n=None, n_prime_divs=None)[source]¶
- Return - Trueif the polynomial is primitive.- The semantics of “primitive” depend on the polynomial coefficients. - (field theory) A polynomial of degree \(m\) over a finite field \(\GF{q}\) is primitive if it is irreducible and its root in \(\GF{q^m}\) generates the multiplicative group \(\GF{q^m}^*\). 
- (ring theory) A polynomial over a ring is primitive if its coefficients generate the unit ideal. 
 - Calling - is_primitive()on a polynomial over an infinite field will raise an error.- The additional inputs to this function are to speed up computation for field semantics (see note). - INPUT: - n– (default:- None) if provided, should equal \(q-1\) where- self.parent()is the field with \(q\) elements; otherwise it will be computed
- n_prime_divs– (default:- None) if provided, should be a list of the prime divisors of \(n\); otherwise it will be computed
 - Note - Computation of the prime divisors of \(n\) can dominate the running time of this method, so performing this computation externally (e.g., - pdivs = n.prime_divisors()) is a good idea for repeated calls to- is_primitive()for polynomials of the same degree.- Results may be incorrect if the wrong \(n\) and/or factorization are provided. - EXAMPLES: - Field semantics examples. - sage: # needs sage.rings.finite_rings sage: R.<x> = GF(2)['x'] sage: f = x^4 + x^3 + x^2 + x + 1 sage: f.is_irreducible(), f.is_primitive() (True, False) sage: f = x^3 + x + 1 sage: f.is_irreducible(), f.is_primitive() (True, True) sage: R.<x> = GF(3)[] sage: f = x^3 - x + 1 sage: f.is_irreducible(), f.is_primitive() (True, True) sage: f = x^2 + 1 sage: f.is_irreducible(), f.is_primitive() (True, False) sage: R.<x> = GF(5)[] sage: f = x^2 + x + 1 sage: f.is_primitive() False sage: f = x^2 - x + 2 sage: f.is_primitive() True sage: x = polygen(QQ); f = x^2 + 1 sage: f.is_primitive() Traceback (most recent call last): ... NotImplementedError: is_primitive() not defined for polynomials over infinite fields. - >>> from sage.all import * >>> # needs sage.rings.finite_rings >>> R = GF(Integer(2))['x']; (x,) = R._first_ngens(1) >>> f = x**Integer(4) + x**Integer(3) + x**Integer(2) + x + Integer(1) >>> f.is_irreducible(), f.is_primitive() (True, False) >>> f = x**Integer(3) + x + Integer(1) >>> f.is_irreducible(), f.is_primitive() (True, True) >>> R = GF(Integer(3))['x']; (x,) = R._first_ngens(1) >>> f = x**Integer(3) - x + Integer(1) >>> f.is_irreducible(), f.is_primitive() (True, True) >>> f = x**Integer(2) + Integer(1) >>> f.is_irreducible(), f.is_primitive() (True, False) >>> R = GF(Integer(5))['x']; (x,) = R._first_ngens(1) >>> f = x**Integer(2) + x + Integer(1) >>> f.is_primitive() False >>> f = x**Integer(2) - x + Integer(2) >>> f.is_primitive() True >>> x = polygen(QQ); f = x**Integer(2) + Integer(1) >>> f.is_primitive() Traceback (most recent call last): ... NotImplementedError: is_primitive() not defined for polynomials over infinite fields. - Ring semantics examples. - sage: x = polygen(ZZ) sage: f = 5*x^2 + 2 sage: f.is_primitive() True sage: f = 5*x^2 + 5 sage: f.is_primitive() False sage: # needs sage.rings.number_field sage: K = NumberField(x^2 + 5, 'a') sage: R = K.ring_of_integers() sage: a = R.gen(1) sage: a^2 -5 sage: f = a*x + 2 sage: f.is_primitive() True sage: f = (1+a)*x + 2 sage: f.is_primitive() False sage: x = polygen(Integers(10)) sage: f = 5*x^2 + 2 sage: #f.is_primitive() #BUG:: elsewhere in Sage, should return True sage: f = 4*x^2 + 2 sage: #f.is_primitive() #BUG:: elsewhere in Sage, should return False - >>> from sage.all import * >>> x = polygen(ZZ) >>> f = Integer(5)*x**Integer(2) + Integer(2) >>> f.is_primitive() True >>> f = Integer(5)*x**Integer(2) + Integer(5) >>> f.is_primitive() False >>> # needs sage.rings.number_field >>> K = NumberField(x**Integer(2) + Integer(5), 'a') >>> R = K.ring_of_integers() >>> a = R.gen(Integer(1)) >>> a**Integer(2) -5 >>> f = a*x + Integer(2) >>> f.is_primitive() True >>> f = (Integer(1)+a)*x + Integer(2) >>> f.is_primitive() False >>> x = polygen(Integers(Integer(10))) >>> f = Integer(5)*x**Integer(2) + Integer(2) >>> #f.is_primitive() #BUG:: elsewhere in Sage, should return True >>> f = Integer(4)*x**Integer(2) + Integer(2) >>> #f.is_primitive() #BUG:: elsewhere in Sage, should return False 
 - is_real_rooted()[source]¶
- Return - Trueif the roots of this polynomial are all real.- EXAMPLES: - sage: # needs sage.libs.pari sage: R.<x> = PolynomialRing(ZZ) sage: pol = chebyshev_T(5, x) sage: pol.is_real_rooted() True sage: pol = x^2 + 1 sage: pol.is_real_rooted() False - >>> from sage.all import * >>> # needs sage.libs.pari >>> R = PolynomialRing(ZZ, names=('x',)); (x,) = R._first_ngens(1) >>> pol = chebyshev_T(Integer(5), x) >>> pol.is_real_rooted() True >>> pol = x**Integer(2) + Integer(1) >>> pol.is_real_rooted() False 
 - is_square(root=False)[source]¶
- Return whether or not polynomial is square. - If the optional argument - rootis set to- True, then also returns the square root (or- None, if the polynomial is not square).- INPUT: - root– whether or not to also return a square root (default:- False)
 - OUTPUT: - boolean; whether or not a square 
- (optional) an actual square root if found, and - Noneotherwise
 - EXAMPLES: - sage: R.<x> = PolynomialRing(QQ) sage: (x^2 + 2*x + 1).is_square() True sage: (x^4 + 2*x^3 - x^2 - 2*x + 1).is_square(root=True) (True, x^2 + x - 1) sage: f = 12 * (x + 1)^2 * (x + 3)^2 sage: f.is_square() False sage: f.is_square(root=True) (False, None) sage: h = f/3; h 4*x^4 + 32*x^3 + 88*x^2 + 96*x + 36 sage: h.is_square(root=True) (True, 2*x^2 + 8*x + 6) sage: S.<y> = PolynomialRing(RR) sage: g = 12 * (y + 1)^2 * (y + 3)^2 sage: g.is_square() True - >>> from sage.all import * >>> R = PolynomialRing(QQ, names=('x',)); (x,) = R._first_ngens(1) >>> (x**Integer(2) + Integer(2)*x + Integer(1)).is_square() True >>> (x**Integer(4) + Integer(2)*x**Integer(3) - x**Integer(2) - Integer(2)*x + Integer(1)).is_square(root=True) (True, x^2 + x - 1) >>> f = Integer(12) * (x + Integer(1))**Integer(2) * (x + Integer(3))**Integer(2) >>> f.is_square() False >>> f.is_square(root=True) (False, None) >>> h = f/Integer(3); h 4*x^4 + 32*x^3 + 88*x^2 + 96*x + 36 >>> h.is_square(root=True) (True, 2*x^2 + 8*x + 6) >>> S = PolynomialRing(RR, names=('y',)); (y,) = S._first_ngens(1) >>> g = Integer(12) * (y + Integer(1))**Integer(2) * (y + Integer(3))**Integer(2) >>> g.is_square() True 
 - is_squarefree()[source]¶
- Return - Falseif this polynomial is not square-free, i.e., if there is a non-unit \(g\) in the polynomial ring such that \(g^2\) divides- self.- Warning - This method is not consistent with - squarefree_decomposition()since the latter does not factor the content of a polynomial. See the examples below.- EXAMPLES: - sage: R.<x> = QQ[] sage: f = (x-1) * (x-2) * (x^2-5) * (x^17-3); f x^21 - 3*x^20 - 3*x^19 + 15*x^18 - 10*x^17 - 3*x^4 + 9*x^3 + 9*x^2 - 45*x + 30 sage: f.is_squarefree() True sage: (f * (x^2-5)).is_squarefree() False - >>> from sage.all import * >>> R = QQ['x']; (x,) = R._first_ngens(1) >>> f = (x-Integer(1)) * (x-Integer(2)) * (x**Integer(2)-Integer(5)) * (x**Integer(17)-Integer(3)); f x^21 - 3*x^20 - 3*x^19 + 15*x^18 - 10*x^17 - 3*x^4 + 9*x^3 + 9*x^2 - 45*x + 30 >>> f.is_squarefree() True >>> (f * (x**Integer(2)-Integer(5))).is_squarefree() False - A generic implementation is available, which relies on gcd computations: - sage: # needs sage.libs.pari sage: R.<x> = ZZ[] sage: (2*x).is_squarefree() True sage: (4*x).is_squarefree() False sage: (2*x^2).is_squarefree() False sage: R(0).is_squarefree() False sage: S.<y> = QQ[] sage: R.<x> = S[] sage: (2*x*y).is_squarefree() True sage: (2*x*y^2).is_squarefree() False - >>> from sage.all import * >>> # needs sage.libs.pari >>> R = ZZ['x']; (x,) = R._first_ngens(1) >>> (Integer(2)*x).is_squarefree() True >>> (Integer(4)*x).is_squarefree() False >>> (Integer(2)*x**Integer(2)).is_squarefree() False >>> R(Integer(0)).is_squarefree() False >>> S = QQ['y']; (y,) = S._first_ngens(1) >>> R = S['x']; (x,) = R._first_ngens(1) >>> (Integer(2)*x*y).is_squarefree() True >>> (Integer(2)*x*y**Integer(2)).is_squarefree() False - In positive characteristic, we compute the square-free decomposition or a full factorization, depending on which is available: - sage: K.<t> = FunctionField(GF(3)) sage: R.<x> = K[] sage: (x^3 - x).is_squarefree() True sage: (x^3 - 1).is_squarefree() # needs sage.libs.pari False sage: (x^3 + t).is_squarefree() # needs sage.libs.pari True sage: (x^3 + t^3).is_squarefree() # needs sage.libs.pari False - >>> from sage.all import * >>> K = FunctionField(GF(Integer(3)), names=('t',)); (t,) = K._first_ngens(1) >>> R = K['x']; (x,) = R._first_ngens(1) >>> (x**Integer(3) - x).is_squarefree() True >>> (x**Integer(3) - Integer(1)).is_squarefree() # needs sage.libs.pari False >>> (x**Integer(3) + t).is_squarefree() # needs sage.libs.pari True >>> (x**Integer(3) + t**Integer(3)).is_squarefree() # needs sage.libs.pari False - In the following example, \(t^2\) is a unit in the base field: - sage: R(t^2).is_squarefree() True - >>> from sage.all import * >>> R(t**Integer(2)).is_squarefree() True - This method is not consistent with - squarefree_decomposition():- sage: R.<x> = ZZ[] sage: f = 4 * x sage: f.is_squarefree() # needs sage.libs.pari False sage: f.squarefree_decomposition() # needs sage.libs.pari (4) * x - >>> from sage.all import * >>> R = ZZ['x']; (x,) = R._first_ngens(1) >>> f = Integer(4) * x >>> f.is_squarefree() # needs sage.libs.pari False >>> f.squarefree_decomposition() # needs sage.libs.pari (4) * x - If you want this method equally not to consider the content, you can remove it as in the following example: - sage: c = f.content() sage: (f/c).is_squarefree() # needs sage.libs.pari True - >>> from sage.all import * >>> c = f.content() >>> (f/c).is_squarefree() # needs sage.libs.pari True - If the base ring is not an integral domain, the question is not mathematically well-defined: - sage: R.<x> = IntegerModRing(9)[] sage: pol = (x + 3) * (x + 6); pol x^2 sage: pol.is_squarefree() Traceback (most recent call last): ... TypeError: is_squarefree() is not defined for polynomials over Ring of integers modulo 9 - >>> from sage.all import * >>> R = IntegerModRing(Integer(9))['x']; (x,) = R._first_ngens(1) >>> pol = (x + Integer(3)) * (x + Integer(6)); pol x^2 >>> pol.is_squarefree() Traceback (most recent call last): ... TypeError: is_squarefree() is not defined for polynomials over Ring of integers modulo 9 
 - is_term()[source]¶
- Return - Trueif this polynomial is a nonzero element of the base ring times a power of the variable.- EXAMPLES: - sage: R.<x> = QQ[] sage: x.is_term() True sage: R(0).is_term() False sage: R(1).is_term() True sage: (3*x^5).is_term() True sage: (1 + 3*x^5).is_term() False - >>> from sage.all import * >>> R = QQ['x']; (x,) = R._first_ngens(1) >>> x.is_term() True >>> R(Integer(0)).is_term() False >>> R(Integer(1)).is_term() True >>> (Integer(3)*x**Integer(5)).is_term() True >>> (Integer(1) + Integer(3)*x**Integer(5)).is_term() False - To require that the coefficient is 1, use - is_monomial()instead:- sage: (3*x^5).is_monomial() False - >>> from sage.all import * >>> (Integer(3)*x**Integer(5)).is_monomial() False 
 - is_unit()[source]¶
- Return - Trueif this polynomial is a unit.- EXAMPLES: - sage: a = Integers(90384098234^3) sage: b = a(2*191*236607587) sage: b.is_nilpotent() True sage: # needs sage.libs.pari sage: R.<x> = a[] sage: f = 3 + b*x + b^2*x^2 sage: f.is_unit() True sage: f = 3 + b*x + b^2*x^2 + 17*x^3 sage: f.is_unit() False - >>> from sage.all import * >>> a = Integers(Integer(90384098234)**Integer(3)) >>> b = a(Integer(2)*Integer(191)*Integer(236607587)) >>> b.is_nilpotent() True >>> # needs sage.libs.pari >>> R = a['x']; (x,) = R._first_ngens(1) >>> f = Integer(3) + b*x + b**Integer(2)*x**Integer(2) >>> f.is_unit() True >>> f = Integer(3) + b*x + b**Integer(2)*x**Integer(2) + Integer(17)*x**Integer(3) >>> f.is_unit() False - EXERCISE (Atiyah-McDonald, Ch 1): Let \(A[x]\) be a polynomial ring in one variable. Then \(f=\sum a_i x^i \in A[x]\) is a unit if and only if \(a_0\) is a unit and \(a_1,\ldots, a_n\) are nilpotent. 
 - is_weil_polynomial(return_q=False)[source]¶
- Return - Trueif this is a Weil polynomial.- This polynomial must have rational or integer coefficients. - INPUT: - self– polynomial with rational or integer coefficients
- return_q– (default:- False) if- True, return a second value \(q\) which is the prime power with respect to which this is \(q\)-Weil, or 0 if there is no such value
 - EXAMPLES: - sage: polRing.<x> = PolynomialRing(Rationals()) sage: P0 = x^4 + 5*x^3 + 15*x^2 + 25*x + 25 sage: P1 = x^4 + 25*x^3 + 15*x^2 + 5*x + 25 sage: P2 = x^4 + 5*x^3 + 25*x^2 + 25*x + 25 sage: P0.is_weil_polynomial(return_q=True) # needs sage.libs.pari (True, 5) sage: P0.is_weil_polynomial(return_q=False) # needs sage.libs.pari True sage: P1.is_weil_polynomial(return_q=True) (False, 0) sage: P1.is_weil_polynomial(return_q=False) False sage: P2.is_weil_polynomial() # needs sage.libs.pari False - >>> from sage.all import * >>> polRing = PolynomialRing(Rationals(), names=('x',)); (x,) = polRing._first_ngens(1) >>> P0 = x**Integer(4) + Integer(5)*x**Integer(3) + Integer(15)*x**Integer(2) + Integer(25)*x + Integer(25) >>> P1 = x**Integer(4) + Integer(25)*x**Integer(3) + Integer(15)*x**Integer(2) + Integer(5)*x + Integer(25) >>> P2 = x**Integer(4) + Integer(5)*x**Integer(3) + Integer(25)*x**Integer(2) + Integer(25)*x + Integer(25) >>> P0.is_weil_polynomial(return_q=True) # needs sage.libs.pari (True, 5) >>> P0.is_weil_polynomial(return_q=False) # needs sage.libs.pari True >>> P1.is_weil_polynomial(return_q=True) (False, 0) >>> P1.is_weil_polynomial(return_q=False) False >>> P2.is_weil_polynomial() # needs sage.libs.pari False - See also - Polynomial rings have a method - weil_polynomials()to compute sets of Weil polynomials. This computation uses the iterator- sage.rings.polynomial.weil.weil_polynomials.WeilPolynomials.- AUTHORS: - David Zureick-Brown (2017-10-01) 
 - is_zero()[source]¶
- Test whether this polynomial is zero. - EXAMPLES: - sage: R = GF(2)['x']['y'] sage: R([0,1]).is_zero() False sage: R([0]).is_zero() True sage: R([-1]).is_zero() False - >>> from sage.all import * >>> R = GF(Integer(2))['x']['y'] >>> R([Integer(0),Integer(1)]).is_zero() False >>> R([Integer(0)]).is_zero() True >>> R([-Integer(1)]).is_zero() False 
 - lc()[source]¶
- Return the leading coefficient of this polynomial. - OUTPUT: element of the base ring - This method is the same as - leading_coefficient().- EXAMPLES: - sage: R.<x> = QQ[] sage: f = (-2/5)*x^3 + 2*x - 1/3 sage: f.lc() -2/5 - >>> from sage.all import * >>> R = QQ['x']; (x,) = R._first_ngens(1) >>> f = (-Integer(2)/Integer(5))*x**Integer(3) + Integer(2)*x - Integer(1)/Integer(3) >>> f.lc() -2/5 
 - lcm(other)[source]¶
- Let \(f\) and \(g\) be two polynomials. Then this function returns the monic least common multiple of \(f\) and \(g\). 
 - leading_coefficient()[source]¶
- Return the leading coefficient of this polynomial. - OUTPUT: element of the base ring - EXAMPLES: - sage: R.<x> = QQ[] sage: f = (-2/5)*x^3 + 2*x - 1/3 sage: f.leading_coefficient() -2/5 - >>> from sage.all import * >>> R = QQ['x']; (x,) = R._first_ngens(1) >>> f = (-Integer(2)/Integer(5))*x**Integer(3) + Integer(2)*x - Integer(1)/Integer(3) >>> f.leading_coefficient() -2/5 
 - list(copy=True)[source]¶
- Return a new copy of the list of the underlying elements of - self.- EXAMPLES: - sage: R.<x> = QQ[] sage: f = (-2/5)*x^3 + 2*x - 1/3 sage: v = f.list(); v [-1/3, 2, 0, -2/5] - >>> from sage.all import * >>> R = QQ['x']; (x,) = R._first_ngens(1) >>> f = (-Integer(2)/Integer(5))*x**Integer(3) + Integer(2)*x - Integer(1)/Integer(3) >>> v = f.list(); v [-1/3, 2, 0, -2/5] - Note that - vis a list, it is mutable, and each call to the- list()method returns a new list:- sage: type(v) <... 'list'> sage: v[0] = 5 sage: f.list() [-1/3, 2, 0, -2/5] - >>> from sage.all import * >>> type(v) <... 'list'> >>> v[Integer(0)] = Integer(5) >>> f.list() [-1/3, 2, 0, -2/5] - Here is an example with a generic polynomial ring: - sage: R.<x> = QQ[] sage: S.<y> = R[] sage: f = y^3 + x*y - 3*x; f y^3 + x*y - 3*x sage: type(f) <class 'sage.rings.polynomial.polynomial_element.Polynomial_generic_dense'> sage: v = f.list(); v [-3*x, x, 0, 1] sage: v[0] = 10 sage: f.list() [-3*x, x, 0, 1] - >>> from sage.all import * >>> R = QQ['x']; (x,) = R._first_ngens(1) >>> S = R['y']; (y,) = S._first_ngens(1) >>> f = y**Integer(3) + x*y - Integer(3)*x; f y^3 + x*y - 3*x >>> type(f) <class 'sage.rings.polynomial.polynomial_element.Polynomial_generic_dense'> >>> v = f.list(); v [-3*x, x, 0, 1] >>> v[Integer(0)] = Integer(10) >>> f.list() [-3*x, x, 0, 1] 
 - lm()[source]¶
- Return the leading monomial of this polynomial. - EXAMPLES: - sage: R.<x> = QQ[] sage: f = (-2/5)*x^3 + 2*x - 1/3 sage: f.lm() x^3 sage: R(5).lm() 1 sage: R(0).lm() 0 sage: R(0).lm().parent() is R True - >>> from sage.all import * >>> R = QQ['x']; (x,) = R._first_ngens(1) >>> f = (-Integer(2)/Integer(5))*x**Integer(3) + Integer(2)*x - Integer(1)/Integer(3) >>> f.lm() x^3 >>> R(Integer(5)).lm() 1 >>> R(Integer(0)).lm() 0 >>> R(Integer(0)).lm().parent() is R True 
 - local_height(v, prec=None)[source]¶
- Return the maximum of the local height of the coefficients of this polynomial. - INPUT: - v– a prime or prime ideal of the base ring
- prec– desired floating point precision (default: default- RealFieldprecision)
 - OUTPUT: a real number - EXAMPLES: - sage: R.<x> = PolynomialRing(QQ) sage: f = 1/1331*x^2 + 1/4000*x sage: f.local_height(1331) # needs sage.rings.real_mpfr 7.19368581839511 - >>> from sage.all import * >>> R = PolynomialRing(QQ, names=('x',)); (x,) = R._first_ngens(1) >>> f = Integer(1)/Integer(1331)*x**Integer(2) + Integer(1)/Integer(4000)*x >>> f.local_height(Integer(1331)) # needs sage.rings.real_mpfr 7.19368581839511 - sage: # needs sage.rings.number_field sage: R.<x> = QQ[] sage: K.<k> = NumberField(x^2 - 5) sage: T.<t> = K[] sage: I = K.ideal(3) sage: f = 1/3*t^2 + 3 sage: f.local_height(I) 1.09861228866811 - >>> from sage.all import * >>> # needs sage.rings.number_field >>> R = QQ['x']; (x,) = R._first_ngens(1) >>> K = NumberField(x**Integer(2) - Integer(5), names=('k',)); (k,) = K._first_ngens(1) >>> T = K['t']; (t,) = T._first_ngens(1) >>> I = K.ideal(Integer(3)) >>> f = Integer(1)/Integer(3)*t**Integer(2) + Integer(3) >>> f.local_height(I) 1.09861228866811 - sage: R.<x> = QQ[] sage: f = 1/2*x^2 + 2 sage: f.local_height(2, prec=2) # needs sage.rings.real_mpfr 0.75 - >>> from sage.all import * >>> R = QQ['x']; (x,) = R._first_ngens(1) >>> f = Integer(1)/Integer(2)*x**Integer(2) + Integer(2) >>> f.local_height(Integer(2), prec=Integer(2)) # needs sage.rings.real_mpfr 0.75 
 - local_height_arch(i, prec=None)[source]¶
- Return the maximum of the local height at the - i-th infinite place of the coefficients of this polynomial.- INPUT: - i– integer
- prec– desired floating point precision (default: default- RealFieldprecision)
 - OUTPUT: a real number - EXAMPLES: - sage: R.<x> = PolynomialRing(QQ) sage: f = 210*x^2 sage: f.local_height_arch(0) # needs sage.rings.real_mpfr 5.34710753071747 - >>> from sage.all import * >>> R = PolynomialRing(QQ, names=('x',)); (x,) = R._first_ngens(1) >>> f = Integer(210)*x**Integer(2) >>> f.local_height_arch(Integer(0)) # needs sage.rings.real_mpfr 5.34710753071747 - sage: # needs sage.rings.number_field sage: R.<x> = QQ[] sage: K.<k> = NumberField(x^2 - 5) sage: T.<t> = K[] sage: f = 1/2*t^2 + 3 sage: f.local_height_arch(1, prec=52) 1.09861228866811 - >>> from sage.all import * >>> # needs sage.rings.number_field >>> R = QQ['x']; (x,) = R._first_ngens(1) >>> K = NumberField(x**Integer(2) - Integer(5), names=('k',)); (k,) = K._first_ngens(1) >>> T = K['t']; (t,) = T._first_ngens(1) >>> f = Integer(1)/Integer(2)*t**Integer(2) + Integer(3) >>> f.local_height_arch(Integer(1), prec=Integer(52)) 1.09861228866811 - sage: R.<x> = QQ[] sage: f = 1/2*x^2 + 3 sage: f.local_height_arch(0, prec=2) # needs sage.rings.real_mpfr 1.0 - >>> from sage.all import * >>> R = QQ['x']; (x,) = R._first_ngens(1) >>> f = Integer(1)/Integer(2)*x**Integer(2) + Integer(3) >>> f.local_height_arch(Integer(0), prec=Integer(2)) # needs sage.rings.real_mpfr 1.0 
 - lt()[source]¶
- Return the leading term of this polynomial. - EXAMPLES: - sage: R.<x> = QQ[] sage: f = (-2/5)*x^3 + 2*x - 1/3 sage: f.lt() -2/5*x^3 sage: R(5).lt() 5 sage: R(0).lt() 0 sage: R(0).lt().parent() is R True - >>> from sage.all import * >>> R = QQ['x']; (x,) = R._first_ngens(1) >>> f = (-Integer(2)/Integer(5))*x**Integer(3) + Integer(2)*x - Integer(1)/Integer(3) >>> f.lt() -2/5*x^3 >>> R(Integer(5)).lt() 5 >>> R(Integer(0)).lt() 0 >>> R(Integer(0)).lt().parent() is R True 
 - map_coefficients(f, new_base_ring=None)[source]¶
- Return the polynomial obtained by applying - fto the nonzero coefficients of- self.- If - fis a- sage.categories.map.Map, then the resulting polynomial will be defined over the codomain of- f. Otherwise, the resulting polynomial will be over the same ring as- self. Set- new_base_ringto override this behaviour.- INPUT: - f– a callable that will be applied to the coefficients of- self
- new_base_ring– (optional) if given, the resulting polynomial will be defined over this ring
 - EXAMPLES: - sage: R.<x> = ZZ[] sage: f = x^2 + 2 sage: f.map_coefficients(lambda a: a + 42) 43*x^2 + 44 sage: R.<x> = PolynomialRing(ZZ, sparse=True) sage: f = x^(2^32) + 2 sage: f.map_coefficients(lambda a: a + 42) 43*x^4294967296 + 44 sage: # needs sage.symbolic sage: R.<x> = SR[] sage: f = (1+I)*x^2 + 3*x - I sage: f.map_coefficients(lambda z: z.conjugate()) (-I + 1)*x^2 + 3*x + I sage: R.<x> = PolynomialRing(SR, sparse=True) sage: f = (1+I)*x^(2^32) - I sage: f.map_coefficients(lambda z: z.conjugate()) (-I + 1)*x^4294967296 + I - >>> from sage.all import * >>> R = ZZ['x']; (x,) = R._first_ngens(1) >>> f = x**Integer(2) + Integer(2) >>> f.map_coefficients(lambda a: a + Integer(42)) 43*x^2 + 44 >>> R = PolynomialRing(ZZ, sparse=True, names=('x',)); (x,) = R._first_ngens(1) >>> f = x**(Integer(2)**Integer(32)) + Integer(2) >>> f.map_coefficients(lambda a: a + Integer(42)) 43*x^4294967296 + 44 >>> # needs sage.symbolic >>> R = SR['x']; (x,) = R._first_ngens(1) >>> f = (Integer(1)+I)*x**Integer(2) + Integer(3)*x - I >>> f.map_coefficients(lambda z: z.conjugate()) (-I + 1)*x^2 + 3*x + I >>> R = PolynomialRing(SR, sparse=True, names=('x',)); (x,) = R._first_ngens(1) >>> f = (Integer(1)+I)*x**(Integer(2)**Integer(32)) - I >>> f.map_coefficients(lambda z: z.conjugate()) (-I + 1)*x^4294967296 + I - Examples with different base ring: - sage: R.<x> = ZZ[] sage: k = GF(2) sage: residue = lambda x: k(x) sage: f = 4*x^2 + x + 3 sage: g = f.map_coefficients(residue); g x + 1 sage: g.parent() Univariate Polynomial Ring in x over Integer Ring sage: g = f.map_coefficients(residue, new_base_ring=k); g x + 1 sage: g.parent() # needs sage.libs.ntl Univariate Polynomial Ring in x over Finite Field of size 2 (using GF2X) sage: residue = k.coerce_map_from(ZZ) sage: g = f.map_coefficients(residue); g x + 1 sage: g.parent() # needs sage.libs.ntl Univariate Polynomial Ring in x over Finite Field of size 2 (using GF2X) - >>> from sage.all import * >>> R = ZZ['x']; (x,) = R._first_ngens(1) >>> k = GF(Integer(2)) >>> residue = lambda x: k(x) >>> f = Integer(4)*x**Integer(2) + x + Integer(3) >>> g = f.map_coefficients(residue); g x + 1 >>> g.parent() Univariate Polynomial Ring in x over Integer Ring >>> g = f.map_coefficients(residue, new_base_ring=k); g x + 1 >>> g.parent() # needs sage.libs.ntl Univariate Polynomial Ring in x over Finite Field of size 2 (using GF2X) >>> residue = k.coerce_map_from(ZZ) >>> g = f.map_coefficients(residue); g x + 1 >>> g.parent() # needs sage.libs.ntl Univariate Polynomial Ring in x over Finite Field of size 2 (using GF2X) 
 - mod(other)[source]¶
- Remainder of division of - selfby- other.- EXAMPLES: - sage: R.<x> = ZZ[] sage: x % (x+1) -1 sage: (x^3 + x - 1) % (x^2 - 1) 2*x - 1 - >>> from sage.all import * >>> R = ZZ['x']; (x,) = R._first_ngens(1) >>> x % (x+Integer(1)) -1 >>> (x**Integer(3) + x - Integer(1)) % (x**Integer(2) - Integer(1)) 2*x - 1 
 - monic()[source]¶
- Return this polynomial divided by its leading coefficient. Does not change this polynomial. - EXAMPLES: - sage: x = QQ['x'].0 sage: f = 2*x^2 + x^3 + 56*x^5 sage: f.monic() x^5 + 1/56*x^3 + 1/28*x^2 sage: f = (1/4)*x^2 + 3*x + 1 sage: f.monic() x^2 + 12*x + 4 - >>> from sage.all import * >>> x = QQ['x'].gen(0) >>> f = Integer(2)*x**Integer(2) + x**Integer(3) + Integer(56)*x**Integer(5) >>> f.monic() x^5 + 1/56*x^3 + 1/28*x^2 >>> f = (Integer(1)/Integer(4))*x**Integer(2) + Integer(3)*x + Integer(1) >>> f.monic() x^2 + 12*x + 4 - The following happens because \(f = 0\) cannot be made into a monic polynomial - sage: f = 0*x sage: f.monic() Traceback (most recent call last): ... ZeroDivisionError: rational division by zero - >>> from sage.all import * >>> f = Integer(0)*x >>> f.monic() Traceback (most recent call last): ... ZeroDivisionError: rational division by zero - Notice that the monic version of a polynomial over the integers is defined over the rationals. - sage: x = ZZ['x'].0 sage: f = 3*x^19 + x^2 - 37 sage: g = f.monic(); g x^19 + 1/3*x^2 - 37/3 sage: g.parent() Univariate Polynomial Ring in x over Rational Field - >>> from sage.all import * >>> x = ZZ['x'].gen(0) >>> f = Integer(3)*x**Integer(19) + x**Integer(2) - Integer(37) >>> g = f.monic(); g x^19 + 1/3*x^2 - 37/3 >>> g.parent() Univariate Polynomial Ring in x over Rational Field - AUTHORS: - Naqi Jaffery (2006-01-24): examples 
 
 - monomial_coefficient(m)[source]¶
- Return the coefficient in the base ring of the monomial - min- self, where- mmust have the same parent as- self.- INPUT: - m– a monomial
 - OUTPUT: coefficient in base ring - EXAMPLES: - sage: P.<x> = QQ[] sage: f = 2 * x sage: c = f.monomial_coefficient(x); c 2 sage: c.parent() Rational Field sage: f = x^9 - 1/2*x^2 + 7*x + 5/11 sage: f.monomial_coefficient(x^9) 1 sage: f.monomial_coefficient(x^2) -1/2 sage: f.monomial_coefficient(x) 7 sage: f.monomial_coefficient(x^0) 5/11 sage: f.monomial_coefficient(x^3) 0 - >>> from sage.all import * >>> P = QQ['x']; (x,) = P._first_ngens(1) >>> f = Integer(2) * x >>> c = f.monomial_coefficient(x); c 2 >>> c.parent() Rational Field >>> f = x**Integer(9) - Integer(1)/Integer(2)*x**Integer(2) + Integer(7)*x + Integer(5)/Integer(11) >>> f.monomial_coefficient(x**Integer(9)) 1 >>> f.monomial_coefficient(x**Integer(2)) -1/2 >>> f.monomial_coefficient(x) 7 >>> f.monomial_coefficient(x**Integer(0)) 5/11 >>> f.monomial_coefficient(x**Integer(3)) 0 
 - monomial_coefficients(copy=None)[source]¶
- Return a sparse dictionary representation of this univariate polynomial. - EXAMPLES: - sage: R.<x> = QQ[] sage: f = x^3 + -1/7*x + 13 sage: f.monomial_coefficients() {0: 13, 1: -1/7, 3: 1} - >>> from sage.all import * >>> R = QQ['x']; (x,) = R._first_ngens(1) >>> f = x**Integer(3) + -Integer(1)/Integer(7)*x + Integer(13) >>> f.monomial_coefficients() {0: 13, 1: -1/7, 3: 1} - dictis an alias:- sage: f.dict() {0: 13, 1: -1/7, 3: 1} - >>> from sage.all import * >>> f.dict() {0: 13, 1: -1/7, 3: 1} 
 - monomials()[source]¶
- Return the list of the monomials in - selfin a decreasing order of their degrees.- EXAMPLES: - sage: P.<x> = QQ[] sage: f = x^2 + (2/3)*x + 1 sage: f.monomials() [x^2, x, 1] sage: f = P(3/2) sage: f.monomials() [1] sage: f = P(0) sage: f.monomials() [] sage: f = x sage: f.monomials() [x] sage: f = - 1/2*x^2 + x^9 + 7*x + 5/11 sage: f.monomials() [x^9, x^2, x, 1] sage: # needs sage.rings.number_field sage: x = polygen(ZZ, 'x') sage: K.<rho> = NumberField(x**2 + 1) sage: R.<y> = QQ[] sage: p = rho * y sage: p.monomials() [y] - >>> from sage.all import * >>> P = QQ['x']; (x,) = P._first_ngens(1) >>> f = x**Integer(2) + (Integer(2)/Integer(3))*x + Integer(1) >>> f.monomials() [x^2, x, 1] >>> f = P(Integer(3)/Integer(2)) >>> f.monomials() [1] >>> f = P(Integer(0)) >>> f.monomials() [] >>> f = x >>> f.monomials() [x] >>> f = - Integer(1)/Integer(2)*x**Integer(2) + x**Integer(9) + Integer(7)*x + Integer(5)/Integer(11) >>> f.monomials() [x^9, x^2, x, 1] >>> # needs sage.rings.number_field >>> x = polygen(ZZ, 'x') >>> K = NumberField(x**Integer(2) + Integer(1), names=('rho',)); (rho,) = K._first_ngens(1) >>> R = QQ['y']; (y,) = R._first_ngens(1) >>> p = rho * y >>> p.monomials() [y] 
 - multiplication_trunc(other, n)[source]¶
- Truncated multiplication. - EXAMPLES: - sage: R.<x> = ZZ[] sage: (x^10 + 5*x^5 + x^2 - 3).multiplication_trunc(x^7 - 3*x^3 + 1, 11) x^10 + x^9 - 15*x^8 - 3*x^7 + 2*x^5 + 9*x^3 + x^2 - 3 - >>> from sage.all import * >>> R = ZZ['x']; (x,) = R._first_ngens(1) >>> (x**Integer(10) + Integer(5)*x**Integer(5) + x**Integer(2) - Integer(3)).multiplication_trunc(x**Integer(7) - Integer(3)*x**Integer(3) + Integer(1), Integer(11)) x^10 + x^9 - 15*x^8 - 3*x^7 + 2*x^5 + 9*x^3 + x^2 - 3 - Check that coercion is working: - sage: R2 = QQ['x'] sage: x2 = R2.gen() sage: p1 = (x^3 + 1).multiplication_trunc(x2^3 - 2, 5); p1 -x^3 - 2 sage: p2 = (x2^3 + 1).multiplication_trunc(x^3 - 2, 5); p2 -x^3 - 2 sage: parent(p1) == parent(p2) == R2 True - >>> from sage.all import * >>> R2 = QQ['x'] >>> x2 = R2.gen() >>> p1 = (x**Integer(3) + Integer(1)).multiplication_trunc(x2**Integer(3) - Integer(2), Integer(5)); p1 -x^3 - 2 >>> p2 = (x2**Integer(3) + Integer(1)).multiplication_trunc(x**Integer(3) - Integer(2), Integer(5)); p2 -x^3 - 2 >>> parent(p1) == parent(p2) == R2 True 
 - newton_raphson(n, x0)[source]¶
- Return a list of n iterative approximations to a root of this polynomial, computed using the Newton-Raphson method. - The Newton-Raphson method is an iterative root-finding algorithm. For \(f(x)\) a polynomial, as is the case here, this is essentially the same as Horner’s method. - INPUT: - n– integer; the number of iterations
- x0– an initial guess \(x_0\)
 - OUTPUT: list of numbers hopefully approximating a root of \(f(x)=0\) - If one of the iterates is a critical point of \(f\), a - ZeroDivisionErrorexception is raised.- EXAMPLES: - sage: x = PolynomialRing(RealField(), 'x').gen() # needs sage.rings.real_mpfr sage: f = x^2 - 2 # needs sage.rings.real_mpfr sage: f.newton_raphson(4, 1) # needs sage.rings.real_mpfr [1.50000000000000, 1.41666666666667, 1.41421568627451, 1.41421356237469] - >>> from sage.all import * >>> x = PolynomialRing(RealField(), 'x').gen() # needs sage.rings.real_mpfr >>> f = x**Integer(2) - Integer(2) # needs sage.rings.real_mpfr >>> f.newton_raphson(Integer(4), Integer(1)) # needs sage.rings.real_mpfr [1.50000000000000, 1.41666666666667, 1.41421568627451, 1.41421356237469] - AUTHORS: - David Joyner and William Stein (2005-11-28) 
 
 - newton_slopes(p, lengths=False)[source]¶
- Return the \(p\)-adic slopes of the Newton polygon of - self, when this makes sense.- OUTPUT: - If - lengthsis- False, a list of rational numbers. If- lengthsis- True, a list of couples \((s,l)\) where \(s\) is the slope and \(l\) the length of the corresponding segment in the Newton polygon.- EXAMPLES: - sage: x = QQ['x'].0 sage: f = x^3 + 2 sage: f.newton_slopes(2) # needs sage.libs.pari [1/3, 1/3, 1/3] sage: R.<x> = PolynomialRing(ZZ, sparse=True) sage: p = x^5 + 6*x^2 + 4 sage: p.newton_slopes(2) # needs sage.libs.pari [1/2, 1/2, 1/3, 1/3, 1/3] sage: p.newton_slopes(2, lengths=True) [(1/2, 2), (1/3, 3)] sage: (x^2^100 + 27).newton_slopes(3, lengths=True) [(3/1267650600228229401496703205376, 1267650600228229401496703205376)] - >>> from sage.all import * >>> x = QQ['x'].gen(0) >>> f = x**Integer(3) + Integer(2) >>> f.newton_slopes(Integer(2)) # needs sage.libs.pari [1/3, 1/3, 1/3] >>> R = PolynomialRing(ZZ, sparse=True, names=('x',)); (x,) = R._first_ngens(1) >>> p = x**Integer(5) + Integer(6)*x**Integer(2) + Integer(4) >>> p.newton_slopes(Integer(2)) # needs sage.libs.pari [1/2, 1/2, 1/3, 1/3, 1/3] >>> p.newton_slopes(Integer(2), lengths=True) [(1/2, 2), (1/3, 3)] >>> (x**Integer(2)**Integer(100) + Integer(27)).newton_slopes(Integer(3), lengths=True) [(3/1267650600228229401496703205376, 1267650600228229401496703205376)] - ALGORITHM: Uses PARI if - lengthsis- False.
 - norm(p)[source]¶
- Return the \(p\)-norm of this polynomial. - DEFINITION: For integer \(p\), the \(p\)-norm of a polynomial is the \(p\)th root of the sum of the \(p\)th powers of the absolute values of the coefficients of the polynomial. - INPUT: - p– positive integer or +infinity; the degree of the norm
 - EXAMPLES: - sage: # needs sage.rings.real_mpfr sage: R.<x> = RR[] sage: f = x^6 + x^2 + -x^4 - 2*x^3 sage: f.norm(2) 2.64575131106459 sage: (sqrt(1^2 + 1^2 + (-1)^2 + (-2)^2)).n() # needs sage.symbolic 2.64575131106459 - >>> from sage.all import * >>> # needs sage.rings.real_mpfr >>> R = RR['x']; (x,) = R._first_ngens(1) >>> f = x**Integer(6) + x**Integer(2) + -x**Integer(4) - Integer(2)*x**Integer(3) >>> f.norm(Integer(2)) 2.64575131106459 >>> (sqrt(Integer(1)**Integer(2) + Integer(1)**Integer(2) + (-Integer(1))**Integer(2) + (-Integer(2))**Integer(2))).n() # needs sage.symbolic 2.64575131106459 - sage: f.norm(1) # needs sage.rings.real_mpfr 5.00000000000000 sage: f.norm(infinity) # needs sage.rings.real_mpfr 2.00000000000000 - >>> from sage.all import * >>> f.norm(Integer(1)) # needs sage.rings.real_mpfr 5.00000000000000 >>> f.norm(infinity) # needs sage.rings.real_mpfr 2.00000000000000 - sage: f.norm(-1) # needs sage.rings.real_mpfr Traceback (most recent call last): ... ValueError: The degree of the norm must be positive - >>> from sage.all import * >>> f.norm(-Integer(1)) # needs sage.rings.real_mpfr Traceback (most recent call last): ... ValueError: The degree of the norm must be positive - AUTHORS: - Didier Deshommes 
- William Stein: fix bugs, add definition, etc. 
 
 - nth_root(n)[source]¶
- Return a \(n\)-th root of this polynomial. - This is computed using Newton method in the ring of power series. This method works only when the base ring is an integral domain. Moreover, for polynomial whose coefficient of lower degree is different from 1, the elements of the base ring should have a method - nth_root()implemented.- EXAMPLES: - sage: R.<x> = ZZ[] sage: a = 27 * (x+3)**6 * (x+5)**3 sage: a.nth_root(3) 3*x^3 + 33*x^2 + 117*x + 135 sage: b = 25 * (x^2 + x + 1) sage: b.nth_root(2) Traceback (most recent call last): ... ValueError: not a 2nd power sage: R(0).nth_root(3) 0 sage: R.<x> = QQ[] sage: a = 1/4 * (x/7 + 3/2)^2 * (x/2 + 5/3)^4 sage: a.nth_root(2) 1/56*x^3 + 103/336*x^2 + 365/252*x + 25/12 sage: # needs sage.rings.number_field sage: K.<sqrt2> = QuadraticField(2) sage: R.<x> = K[] sage: a = (x + sqrt2)^3 * ((1+sqrt2)*x - 1/sqrt2)^6 sage: b = a.nth_root(3); b (2*sqrt2 + 3)*x^3 + (2*sqrt2 + 2)*x^2 + (-2*sqrt2 - 3/2)*x + 1/2*sqrt2 sage: b^3 == a True sage: # needs sage.rings.number_field sage: R.<x> = QQbar[] sage: p = x**3 + QQbar(2).sqrt() * x - QQbar(3).sqrt() sage: r = (p**5).nth_root(5) sage: r * p[0] == p * r[0] True sage: p = (x+1)^20 + x^20 sage: p.nth_root(20) Traceback (most recent call last): ... ValueError: not a 20th power sage: # needs sage.rings.finite_rings sage: z = GF(4).gen() sage: R.<x> = GF(4)[] sage: p = z*x**4 + 2*x - 1 sage: r = (p**15).nth_root(15) sage: r * p[0] == p * r[0] True sage: ((x+1)**2).nth_root(2) x + 1 sage: ((x+1)**4).nth_root(4) x + 1 sage: ((x+1)**12).nth_root(12) x + 1 sage: (x^4 + x^3 + 1).nth_root(2) Traceback (most recent call last): ... ValueError: not a 2nd power sage: p = (x+1)^17 + x^17 sage: r = p.nth_root(17) Traceback (most recent call last): ... ValueError: not a 17th power sage: R1.<x> = QQ[] sage: R2.<y> = R1[] sage: R3.<z> = R2[] sage: (((y**2+x)*z^2 + x*y*z + 2*x)**3).nth_root(3) (y^2 + x)*z^2 + x*y*z + 2*x sage: ((x+y+z)**5).nth_root(5) z + y + x - >>> from sage.all import * >>> R = ZZ['x']; (x,) = R._first_ngens(1) >>> a = Integer(27) * (x+Integer(3))**Integer(6) * (x+Integer(5))**Integer(3) >>> a.nth_root(Integer(3)) 3*x^3 + 33*x^2 + 117*x + 135 >>> b = Integer(25) * (x**Integer(2) + x + Integer(1)) >>> b.nth_root(Integer(2)) Traceback (most recent call last): ... ValueError: not a 2nd power >>> R(Integer(0)).nth_root(Integer(3)) 0 >>> R = QQ['x']; (x,) = R._first_ngens(1) >>> a = Integer(1)/Integer(4) * (x/Integer(7) + Integer(3)/Integer(2))**Integer(2) * (x/Integer(2) + Integer(5)/Integer(3))**Integer(4) >>> a.nth_root(Integer(2)) 1/56*x^3 + 103/336*x^2 + 365/252*x + 25/12 >>> # needs sage.rings.number_field >>> K = QuadraticField(Integer(2), names=('sqrt2',)); (sqrt2,) = K._first_ngens(1) >>> R = K['x']; (x,) = R._first_ngens(1) >>> a = (x + sqrt2)**Integer(3) * ((Integer(1)+sqrt2)*x - Integer(1)/sqrt2)**Integer(6) >>> b = a.nth_root(Integer(3)); b (2*sqrt2 + 3)*x^3 + (2*sqrt2 + 2)*x^2 + (-2*sqrt2 - 3/2)*x + 1/2*sqrt2 >>> b**Integer(3) == a True >>> # needs sage.rings.number_field >>> R = QQbar['x']; (x,) = R._first_ngens(1) >>> p = x**Integer(3) + QQbar(Integer(2)).sqrt() * x - QQbar(Integer(3)).sqrt() >>> r = (p**Integer(5)).nth_root(Integer(5)) >>> r * p[Integer(0)] == p * r[Integer(0)] True >>> p = (x+Integer(1))**Integer(20) + x**Integer(20) >>> p.nth_root(Integer(20)) Traceback (most recent call last): ... ValueError: not a 20th power >>> # needs sage.rings.finite_rings >>> z = GF(Integer(4)).gen() >>> R = GF(Integer(4))['x']; (x,) = R._first_ngens(1) >>> p = z*x**Integer(4) + Integer(2)*x - Integer(1) >>> r = (p**Integer(15)).nth_root(Integer(15)) >>> r * p[Integer(0)] == p * r[Integer(0)] True >>> ((x+Integer(1))**Integer(2)).nth_root(Integer(2)) x + 1 >>> ((x+Integer(1))**Integer(4)).nth_root(Integer(4)) x + 1 >>> ((x+Integer(1))**Integer(12)).nth_root(Integer(12)) x + 1 >>> (x**Integer(4) + x**Integer(3) + Integer(1)).nth_root(Integer(2)) Traceback (most recent call last): ... ValueError: not a 2nd power >>> p = (x+Integer(1))**Integer(17) + x**Integer(17) >>> r = p.nth_root(Integer(17)) Traceback (most recent call last): ... ValueError: not a 17th power >>> R1 = QQ['x']; (x,) = R1._first_ngens(1) >>> R2 = R1['y']; (y,) = R2._first_ngens(1) >>> R3 = R2['z']; (z,) = R3._first_ngens(1) >>> (((y**Integer(2)+x)*z**Integer(2) + x*y*z + Integer(2)*x)**Integer(3)).nth_root(Integer(3)) (y^2 + x)*z^2 + x*y*z + 2*x >>> ((x+y+z)**Integer(5)).nth_root(Integer(5)) z + y + x - Here we consider a base ring without - nth_rootmethod. The third example with a non-trivial coefficient of lowest degree raises an error:- sage: # needs sage.libs.pari sage: R.<x> = QQ[] sage: R2 = R.quotient(x**2 + 1) sage: x = R2.gen() sage: R3.<y> = R2[] sage: (y**2 - 2*y + 1).nth_root(2) -y + 1 sage: (y**3).nth_root(3) y sage: (y**2 + x).nth_root(2) Traceback (most recent call last): ... AttributeError: ... has no attribute 'nth_root'... - >>> from sage.all import * >>> # needs sage.libs.pari >>> R = QQ['x']; (x,) = R._first_ngens(1) >>> R2 = R.quotient(x**Integer(2) + Integer(1)) >>> x = R2.gen() >>> R3 = R2['y']; (y,) = R3._first_ngens(1) >>> (y**Integer(2) - Integer(2)*y + Integer(1)).nth_root(Integer(2)) -y + 1 >>> (y**Integer(3)).nth_root(Integer(3)) y >>> (y**Integer(2) + x).nth_root(Integer(2)) Traceback (most recent call last): ... AttributeError: ... has no attribute 'nth_root'... 
 - number_of_real_roots()[source]¶
- Return the number of real roots of this polynomial, counted without multiplicity. - EXAMPLES: - sage: # needs sage.libs.pari sage: R.<x> = PolynomialRing(ZZ) sage: pol = (x - 1)^2 * (x - 2)^2 * (x - 3) sage: pol.number_of_real_roots() 3 sage: pol = (x - 1) * (x - 2) * (x - 3) sage: # needs sage.libs.pari sage.rings.real_mpfr sage: pol2 = pol.change_ring(CC) sage: pol2.number_of_real_roots() 3 sage: R.<x> = PolynomialRing(CC) sage: pol = (x - 1) * (x - CC(I)) sage: pol.number_of_real_roots() 1 - >>> from sage.all import * >>> # needs sage.libs.pari >>> R = PolynomialRing(ZZ, names=('x',)); (x,) = R._first_ngens(1) >>> pol = (x - Integer(1))**Integer(2) * (x - Integer(2))**Integer(2) * (x - Integer(3)) >>> pol.number_of_real_roots() 3 >>> pol = (x - Integer(1)) * (x - Integer(2)) * (x - Integer(3)) >>> # needs sage.libs.pari sage.rings.real_mpfr >>> pol2 = pol.change_ring(CC) >>> pol2.number_of_real_roots() 3 >>> R = PolynomialRing(CC, names=('x',)); (x,) = R._first_ngens(1) >>> pol = (x - Integer(1)) * (x - CC(I)) >>> pol.number_of_real_roots() 1 
 - number_of_roots_in_interval(a=None, b=None)[source]¶
- Return the number of roots of this polynomial in the interval \([a,b]\), counted without multiplicity. The endpoints \(a\), \(b\) default to - -Infinity,- Infinity(which are also valid input values).- Calls the PARI routine pari:polsturm. - Note that as of version 2.8, PARI includes the left endpoint of the interval (and no longer uses Sturm’s algorithm on exact inputs). pari:polsturm requires a polynomial with real coefficients; in case PARI returns an error, we try again after taking the GCD of - selfwith its complex conjugate.- EXAMPLES: - sage: # needs sage.libs.pari sage: R.<x> = PolynomialRing(ZZ) sage: pol = (x - 1)^2 * (x - 2)^2 * (x - 3) sage: pol.number_of_roots_in_interval(1, 2) 2 sage: pol.number_of_roots_in_interval(1.01, 2) 1 sage: pol.number_of_roots_in_interval(None, 2) 2 sage: pol.number_of_roots_in_interval(1, Infinity) 3 sage: pol.number_of_roots_in_interval() 3 sage: pol = (x - 1) * (x - 2) * (x - 3) sage: # needs sage.libs.pari sage.rings.real_mpfr sage: pol2 = pol.change_ring(CC) sage: pol2.number_of_roots_in_interval() 3 sage: R.<x> = PolynomialRing(CC) sage: pol = (x - 1) * (x - CC(I)) sage: pol.number_of_roots_in_interval(0, 2) 1 - >>> from sage.all import * >>> # needs sage.libs.pari >>> R = PolynomialRing(ZZ, names=('x',)); (x,) = R._first_ngens(1) >>> pol = (x - Integer(1))**Integer(2) * (x - Integer(2))**Integer(2) * (x - Integer(3)) >>> pol.number_of_roots_in_interval(Integer(1), Integer(2)) 2 >>> pol.number_of_roots_in_interval(RealNumber('1.01'), Integer(2)) 1 >>> pol.number_of_roots_in_interval(None, Integer(2)) 2 >>> pol.number_of_roots_in_interval(Integer(1), Infinity) 3 >>> pol.number_of_roots_in_interval() 3 >>> pol = (x - Integer(1)) * (x - Integer(2)) * (x - Integer(3)) >>> # needs sage.libs.pari sage.rings.real_mpfr >>> pol2 = pol.change_ring(CC) >>> pol2.number_of_roots_in_interval() 3 >>> R = PolynomialRing(CC, names=('x',)); (x,) = R._first_ngens(1) >>> pol = (x - Integer(1)) * (x - CC(I)) >>> pol.number_of_roots_in_interval(Integer(0), Integer(2)) 1 
 - number_of_terms()[source]¶
- Return the number of nonzero coefficients of - self.- Also called weight, Hamming weight or sparsity. - EXAMPLES: - sage: R.<x> = ZZ[] sage: f = x^3 - x sage: f.number_of_terms() 2 sage: R(0).number_of_terms() 0 sage: f = (x + 1)^100 sage: f.number_of_terms() 101 sage: S = GF(5)['y'] sage: S(f).number_of_terms() 5 sage: cyclotomic_polynomial(105).number_of_terms() 33 - >>> from sage.all import * >>> R = ZZ['x']; (x,) = R._first_ngens(1) >>> f = x**Integer(3) - x >>> f.number_of_terms() 2 >>> R(Integer(0)).number_of_terms() 0 >>> f = (x + Integer(1))**Integer(100) >>> f.number_of_terms() 101 >>> S = GF(Integer(5))['y'] >>> S(f).number_of_terms() 5 >>> cyclotomic_polynomial(Integer(105)).number_of_terms() 33 - The method - hamming_weight()is an alias:- sage: f.hamming_weight() 101 - >>> from sage.all import * >>> f.hamming_weight() 101 
 - numerator()[source]¶
- Return a numerator of - self, computed as- self * self.denominator().- Note that some subclasses may implement its own numerator function. For example, see - sage.rings.polynomial.polynomial_rational_flint.Polynomial_rational_flint- Warning - This is not the numerator of the rational function defined by - self, which would always be- selfsince- selfis a polynomial.- EXAMPLES: - First we compute the numerator of a polynomial with integer coefficients, which is of course - self.- sage: R.<x> = ZZ[] sage: f = x^3 + 17*x + 1 sage: f.numerator() x^3 + 17*x + 1 sage: f == f.numerator() True - >>> from sage.all import * >>> R = ZZ['x']; (x,) = R._first_ngens(1) >>> f = x**Integer(3) + Integer(17)*x + Integer(1) >>> f.numerator() x^3 + 17*x + 1 >>> f == f.numerator() True - Next we compute the numerator of a polynomial with rational coefficients. - sage: R.<x> = PolynomialRing(QQ) sage: f = (1/17)*x^19 - (2/3)*x + 1/3; f 1/17*x^19 - 2/3*x + 1/3 sage: f.numerator() 3*x^19 - 34*x + 17 sage: f == f.numerator() False - >>> from sage.all import * >>> R = PolynomialRing(QQ, names=('x',)); (x,) = R._first_ngens(1) >>> f = (Integer(1)/Integer(17))*x**Integer(19) - (Integer(2)/Integer(3))*x + Integer(1)/Integer(3); f 1/17*x^19 - 2/3*x + 1/3 >>> f.numerator() 3*x^19 - 34*x + 17 >>> f == f.numerator() False - We try to compute the denominator of a polynomial with coefficients in the real numbers, which is a ring whose elements do not have a denominator method. - sage: # needs sage.rings.real_mpfr sage: R.<x> = RR[] sage: f = x + RR('0.3'); f x + 0.300000000000000 sage: f.numerator() x + 0.300000000000000 - >>> from sage.all import * >>> # needs sage.rings.real_mpfr >>> R = RR['x']; (x,) = R._first_ngens(1) >>> f = x + RR('0.3'); f x + 0.300000000000000 >>> f.numerator() x + 0.300000000000000 - We check that the computation of the numerator and denominator are valid. - sage: # needs sage.rings.number_field sage.symbolic sage: K = NumberField(symbolic_expression('x^3+2'), 'a')['s,t']['x'] sage: f = K.random_element() sage: f.numerator() / f.denominator() == f True sage: R = RR['x'] sage: f = R.random_element() sage: f.numerator() / f.denominator() == f True - >>> from sage.all import * >>> # needs sage.rings.number_field sage.symbolic >>> K = NumberField(symbolic_expression('x^3+2'), 'a')['s,t']['x'] >>> f = K.random_element() >>> f.numerator() / f.denominator() == f True >>> R = RR['x'] >>> f = R.random_element() >>> f.numerator() / f.denominator() == f True 
 - ord(p=None)[source]¶
- This is the same as the valuation of - selfat \(p\). See the documentation for- valuation().- EXAMPLES: - sage: R.<x> = ZZ[] sage: (x^2 + x).ord(x + 1) 1 - >>> from sage.all import * >>> R = ZZ['x']; (x,) = R._first_ngens(1) >>> (x**Integer(2) + x).ord(x + Integer(1)) 1 
 - padded_list(n=None)[source]¶
- Return list of coefficients of - selfup to (but not including) \(q^n\).- Includes 0s in the list on the right so that the list has length \(n\). - INPUT: - n– (default:- None) if given, an integer that is at least 0
 - EXAMPLES: - sage: x = polygen(QQ) sage: f = 1 + x^3 + 23*x^5 sage: f.padded_list() [1, 0, 0, 1, 0, 23] sage: f.padded_list(10) [1, 0, 0, 1, 0, 23, 0, 0, 0, 0] sage: len(f.padded_list(10)) 10 sage: f.padded_list(3) [1, 0, 0] sage: f.padded_list(0) [] sage: f.padded_list(-1) Traceback (most recent call last): ... ValueError: n must be at least 0 - >>> from sage.all import * >>> x = polygen(QQ) >>> f = Integer(1) + x**Integer(3) + Integer(23)*x**Integer(5) >>> f.padded_list() [1, 0, 0, 1, 0, 23] >>> f.padded_list(Integer(10)) [1, 0, 0, 1, 0, 23, 0, 0, 0, 0] >>> len(f.padded_list(Integer(10))) 10 >>> f.padded_list(Integer(3)) [1, 0, 0] >>> f.padded_list(Integer(0)) [] >>> f.padded_list(-Integer(1)) Traceback (most recent call last): ... ValueError: n must be at least 0 
 - plot(xmin=None, xmax=None, *args, **kwds)[source]¶
- Return a plot of this polynomial. - INPUT: - xmin– float
- xmax– float
- *args, **kwds– passed to either plot or point
 - OUTPUT: a graphic object - EXAMPLES: - sage: x = polygen(GF(389)) sage: plot(x^2 + 1, rgbcolor=(0,0,1)) # needs sage.plot Graphics object consisting of 1 graphics primitive sage: x = polygen(QQ) sage: plot(x^2 + 1, rgbcolor=(1,0,0)) # needs sage.plot Graphics object consisting of 1 graphics primitive - >>> from sage.all import * >>> x = polygen(GF(Integer(389))) >>> plot(x**Integer(2) + Integer(1), rgbcolor=(Integer(0),Integer(0),Integer(1))) # needs sage.plot Graphics object consisting of 1 graphics primitive >>> x = polygen(QQ) >>> plot(x**Integer(2) + Integer(1), rgbcolor=(Integer(1),Integer(0),Integer(0))) # needs sage.plot Graphics object consisting of 1 graphics primitive 
 - polynomial(var)[source]¶
- Let - varbe one of the variables of the parent of- self. This returns- selfviewed as a univariate polynomial in- varover the polynomial ring generated by all the other variables of the parent.- For univariate polynomials, if - varis the generator of the parent ring, we return this polynomial, otherwise raise an error.- EXAMPLES: - sage: R.<x> = QQ[] sage: (x + 1).polynomial(x) x + 1 - >>> from sage.all import * >>> R = QQ['x']; (x,) = R._first_ngens(1) >>> (x + Integer(1)).polynomial(x) x + 1 
 - power_trunc(n, prec)[source]¶
- Truncated - n-th power of this polynomial up to precision- prec.- INPUT: - n– nonnegative integer; power to be taken
- prec– integer; the precision
 - EXAMPLES: - sage: R.<x> = ZZ[] sage: (3*x^2 - 2*x + 1).power_trunc(5, 8) -1800*x^7 + 1590*x^6 - 1052*x^5 + 530*x^4 - 200*x^3 + 55*x^2 - 10*x + 1 sage: ((3*x^2 - 2*x + 1)^5).truncate(8) -1800*x^7 + 1590*x^6 - 1052*x^5 + 530*x^4 - 200*x^3 + 55*x^2 - 10*x + 1 sage: S.<y> = R[] sage: (x + y).power_trunc(5,5) 5*x*y^4 + 10*x^2*y^3 + 10*x^3*y^2 + 5*x^4*y + x^5 sage: ((x + y)^5).truncate(5) 5*x*y^4 + 10*x^2*y^3 + 10*x^3*y^2 + 5*x^4*y + x^5 sage: R.<x> = GF(3)[] sage: p = x^2 - x + 1 sage: q = p.power_trunc(80, 20); q x^19 + x^18 + ... + 2*x^4 + 2*x^3 + x + 1 sage: (p^80).truncate(20) == q True sage: R.<x> = GF(7)[] sage: p = (x^2 + x + 1).power_trunc(2^100, 100); p 2*x^99 + x^98 + x^95 + 2*x^94 + ... + 3*x^2 + 2*x + 1 sage: for i in range(100): ....: q1 = (x^2 + x + 1).power_trunc(2^100 + i, 100) ....: q2 = p * (x^2 + x + 1).power_trunc(i, 100) ....: q2 = q2.truncate(100) ....: assert q1 == q2, "i = {}".format(i) - >>> from sage.all import * >>> R = ZZ['x']; (x,) = R._first_ngens(1) >>> (Integer(3)*x**Integer(2) - Integer(2)*x + Integer(1)).power_trunc(Integer(5), Integer(8)) -1800*x^7 + 1590*x^6 - 1052*x^5 + 530*x^4 - 200*x^3 + 55*x^2 - 10*x + 1 >>> ((Integer(3)*x**Integer(2) - Integer(2)*x + Integer(1))**Integer(5)).truncate(Integer(8)) -1800*x^7 + 1590*x^6 - 1052*x^5 + 530*x^4 - 200*x^3 + 55*x^2 - 10*x + 1 >>> S = R['y']; (y,) = S._first_ngens(1) >>> (x + y).power_trunc(Integer(5),Integer(5)) 5*x*y^4 + 10*x^2*y^3 + 10*x^3*y^2 + 5*x^4*y + x^5 >>> ((x + y)**Integer(5)).truncate(Integer(5)) 5*x*y^4 + 10*x^2*y^3 + 10*x^3*y^2 + 5*x^4*y + x^5 >>> R = GF(Integer(3))['x']; (x,) = R._first_ngens(1) >>> p = x**Integer(2) - x + Integer(1) >>> q = p.power_trunc(Integer(80), Integer(20)); q x^19 + x^18 + ... + 2*x^4 + 2*x^3 + x + 1 >>> (p**Integer(80)).truncate(Integer(20)) == q True >>> R = GF(Integer(7))['x']; (x,) = R._first_ngens(1) >>> p = (x**Integer(2) + x + Integer(1)).power_trunc(Integer(2)**Integer(100), Integer(100)); p 2*x^99 + x^98 + x^95 + 2*x^94 + ... + 3*x^2 + 2*x + 1 >>> for i in range(Integer(100)): ... q1 = (x**Integer(2) + x + Integer(1)).power_trunc(Integer(2)**Integer(100) + i, Integer(100)) ... q2 = p * (x**Integer(2) + x + Integer(1)).power_trunc(i, Integer(100)) ... q2 = q2.truncate(Integer(100)) ... assert q1 == q2, "i = {}".format(i) 
 - prec()[source]¶
- Return the precision of this polynomial. This is always infinity, since polynomials are of infinite precision by definition (there is no big-oh). - EXAMPLES: - sage: x = polygen(ZZ) sage: (x^5 + x + 1).prec() +Infinity sage: x.prec() +Infinity - >>> from sage.all import * >>> x = polygen(ZZ) >>> (x**Integer(5) + x + Integer(1)).prec() +Infinity >>> x.prec() +Infinity 
 - pseudo_quo_rem(other)[source]¶
- Compute the pseudo-division of two polynomials. - INPUT: - other– a nonzero polynomial
 - OUTPUT: - \(Q\) and \(R\) such that \(l^{m-n+1} \mathrm{self} = Q \cdot\mathrm{other} + R\) where \(m\) is the degree of this polynomial, \(n\) is the degree of - other, \(l\) is the leading coefficient of- other. The result is such that \(\deg(R) < \deg(\mathrm{other})\).- ALGORITHM: - Algorithm 3.1.2 in [Coh1993]. - EXAMPLES: - sage: R.<x> = PolynomialRing(ZZ, sparse=True) sage: p = x^4 + 6*x^3 + x^2 - x + 2 sage: q = 2*x^2 - 3*x - 1 sage: quo, rem = p.pseudo_quo_rem(q); quo, rem (4*x^2 + 30*x + 51, 175*x + 67) sage: 2^(4-2+1)*p == quo*q + rem True sage: S.<T> = R[] sage: p = (-3*x^2 - x)*T^3 - 3*x*T^2 + (x^2 - x)*T + 2*x^2 + 3*x - 2 sage: q = (-x^2 - 4*x - 5)*T^2 + (6*x^2 + x + 1)*T + 2*x^2 - x sage: quo, rem = p.pseudo_quo_rem(q); quo, rem ((3*x^4 + 13*x^3 + 19*x^2 + 5*x)*T + 18*x^4 + 12*x^3 + 16*x^2 + 16*x, (-113*x^6 - 106*x^5 - 133*x^4 - 101*x^3 - 42*x^2 - 41*x)*T - 34*x^6 + 13*x^5 + 54*x^4 + 126*x^3 + 134*x^2 - 5*x - 50) sage: (-x^2 - 4*x - 5)^(3-2+1) * p == quo*q + rem True - >>> from sage.all import * >>> R = PolynomialRing(ZZ, sparse=True, names=('x',)); (x,) = R._first_ngens(1) >>> p = x**Integer(4) + Integer(6)*x**Integer(3) + x**Integer(2) - x + Integer(2) >>> q = Integer(2)*x**Integer(2) - Integer(3)*x - Integer(1) >>> quo, rem = p.pseudo_quo_rem(q); quo, rem (4*x^2 + 30*x + 51, 175*x + 67) >>> Integer(2)**(Integer(4)-Integer(2)+Integer(1))*p == quo*q + rem True >>> S = R['T']; (T,) = S._first_ngens(1) >>> p = (-Integer(3)*x**Integer(2) - x)*T**Integer(3) - Integer(3)*x*T**Integer(2) + (x**Integer(2) - x)*T + Integer(2)*x**Integer(2) + Integer(3)*x - Integer(2) >>> q = (-x**Integer(2) - Integer(4)*x - Integer(5))*T**Integer(2) + (Integer(6)*x**Integer(2) + x + Integer(1))*T + Integer(2)*x**Integer(2) - x >>> quo, rem = p.pseudo_quo_rem(q); quo, rem ((3*x^4 + 13*x^3 + 19*x^2 + 5*x)*T + 18*x^4 + 12*x^3 + 16*x^2 + 16*x, (-113*x^6 - 106*x^5 - 133*x^4 - 101*x^3 - 42*x^2 - 41*x)*T - 34*x^6 + 13*x^5 + 54*x^4 + 126*x^3 + 134*x^2 - 5*x - 50) >>> (-x**Integer(2) - Integer(4)*x - Integer(5))**(Integer(3)-Integer(2)+Integer(1)) * p == quo*q + rem True 
 - radical()[source]¶
- Return the radical of - self.- Over a field, this is the product of the distinct irreducible factors of - self. (This is also sometimes called the “square-free part” of- self, but that term is ambiguous; it is sometimes used to mean the quotient of- selfby its maximal square factor.)- EXAMPLES: - sage: P.<x> = ZZ[] sage: t = (x^2-x+1)^3 * (3*x-1)^2 sage: t.radical() 3*x^3 - 4*x^2 + 4*x - 1 sage: radical(12 * x^5) 6*x - >>> from sage.all import * >>> P = ZZ['x']; (x,) = P._first_ngens(1) >>> t = (x**Integer(2)-x+Integer(1))**Integer(3) * (Integer(3)*x-Integer(1))**Integer(2) >>> t.radical() 3*x^3 - 4*x^2 + 4*x - 1 >>> radical(Integer(12) * x**Integer(5)) 6*x - If - selfhas a factor of multiplicity divisible by the characteristic (see Issue #8736):- sage: P.<x> = GF(2)[] sage: (x^3 + x^2).radical() # needs sage.rings.finite_rings x^2 + x - >>> from sage.all import * >>> P = GF(Integer(2))['x']; (x,) = P._first_ngens(1) >>> (x**Integer(3) + x**Integer(2)).radical() # needs sage.rings.finite_rings x^2 + x 
 - rational_reconstruct(*args, **kwds)[source]¶
- Deprecated: Use - rational_reconstruction()instead. See Issue #12696 for details.
 - rational_reconstruction(m, n_deg=None, d_deg=None)[source]¶
- Return a tuple of two polynomials - (n, d)where- self * dis congruent to- nmodulo- mand- n.degree() <= n_degand- d.degree() <= d_deg.- INPUT: - m– a univariate polynomial
- n_deg– (optional) an integer; the default is \(\lfloor (\deg(m) - 1)/2 \rfloor\)
- d_deg– (optional) an integer; the default is \(\lfloor (\deg(m) - 1)/2 \rfloor\)
 - ALGORITHM: - The algorithm is based on the extended Euclidean algorithm for the polynomial greatest common divisor. - EXAMPLES: - Over \(\QQ[z]\): - sage: z = PolynomialRing(QQ, 'z').gen() sage: p = -z**16 - z**15 - z**14 + z**13 + z**12 + z**11 - z**5 - z**4 - z**3 + z**2 + z + 1 sage: m = z**21 sage: n, d = p.rational_reconstruction(m); n, d (z^4 + 2*z^3 + 3*z^2 + 2*z + 1, z^10 + z^9 + z^8 + z^7 + z^6 + z^5 + z^4 + z^3 + z^2 + z + 1) sage: ((p*d - n) % m).is_zero() True - >>> from sage.all import * >>> z = PolynomialRing(QQ, 'z').gen() >>> p = -z**Integer(16) - z**Integer(15) - z**Integer(14) + z**Integer(13) + z**Integer(12) + z**Integer(11) - z**Integer(5) - z**Integer(4) - z**Integer(3) + z**Integer(2) + z + Integer(1) >>> m = z**Integer(21) >>> n, d = p.rational_reconstruction(m); n, d (z^4 + 2*z^3 + 3*z^2 + 2*z + 1, z^10 + z^9 + z^8 + z^7 + z^6 + z^5 + z^4 + z^3 + z^2 + z + 1) >>> ((p*d - n) % m).is_zero() True - Over \(\ZZ[z]\): - sage: z = PolynomialRing(ZZ, 'z').gen() sage: p = -z**16 - z**15 - z**14 + z**13 + z**12 + z**11 - z**5 - z**4 - z**3 + z**2 + z + 1 sage: m = z**21 sage: n, d = p.rational_reconstruction(m); n, d (z^4 + 2*z^3 + 3*z^2 + 2*z + 1, z^10 + z^9 + z^8 + z^7 + z^6 + z^5 + z^4 + z^3 + z^2 + z + 1) sage: ((p*d - n) % m).is_zero() True - >>> from sage.all import * >>> z = PolynomialRing(ZZ, 'z').gen() >>> p = -z**Integer(16) - z**Integer(15) - z**Integer(14) + z**Integer(13) + z**Integer(12) + z**Integer(11) - z**Integer(5) - z**Integer(4) - z**Integer(3) + z**Integer(2) + z + Integer(1) >>> m = z**Integer(21) >>> n, d = p.rational_reconstruction(m); n, d (z^4 + 2*z^3 + 3*z^2 + 2*z + 1, z^10 + z^9 + z^8 + z^7 + z^6 + z^5 + z^4 + z^3 + z^2 + z + 1) >>> ((p*d - n) % m).is_zero() True - Over an integral domain, - dmight not be monic:- sage: P = PolynomialRing(ZZ, 'x') sage: x = P.gen() sage: p = 7*x^5 - 10*x^4 + 16*x^3 - 32*x^2 + 128*x + 256 sage: m = x^5 sage: n, d = p.rational_reconstruction(m, 3, 2); n, d (-32*x^3 + 384*x^2 + 2304*x + 2048, 5*x + 8) sage: ((p*d - n) % m).is_zero() True sage: n, d = p.rational_reconstruction(m, 4, 0); n, d (-10*x^4 + 16*x^3 - 32*x^2 + 128*x + 256, 1) sage: ((p*d - n) % m).is_zero() True - >>> from sage.all import * >>> P = PolynomialRing(ZZ, 'x') >>> x = P.gen() >>> p = Integer(7)*x**Integer(5) - Integer(10)*x**Integer(4) + Integer(16)*x**Integer(3) - Integer(32)*x**Integer(2) + Integer(128)*x + Integer(256) >>> m = x**Integer(5) >>> n, d = p.rational_reconstruction(m, Integer(3), Integer(2)); n, d (-32*x^3 + 384*x^2 + 2304*x + 2048, 5*x + 8) >>> ((p*d - n) % m).is_zero() True >>> n, d = p.rational_reconstruction(m, Integer(4), Integer(0)); n, d (-10*x^4 + 16*x^3 - 32*x^2 + 128*x + 256, 1) >>> ((p*d - n) % m).is_zero() True - Over \(\QQ(t)[z]\): - sage: P = PolynomialRing(QQ, 't') sage: t = P.gen() sage: Pz = PolynomialRing(P.fraction_field(), 'z') sage: z = Pz.gen() sage: # p = (1 + t^2*z + z^4) / (1 - t*z) sage: p = (1 + t^2*z + z^4)*(1 - t*z).inverse_mod(z^9) sage: m = z^9 sage: n, d = p.rational_reconstruction(m); n, d (-1/t*z^4 - t*z - 1/t, z - 1/t) sage: ((p*d - n) % m).is_zero() True sage: w = PowerSeriesRing(P.fraction_field(), 'w').gen() sage: n = -10*t^2*z^4 + (-t^2 + t - 1)*z^3 + (-t - 8)*z^2 + z + 2*t^2 - t sage: d = z^4 + (2*t + 4)*z^3 + (-t + 5)*z^2 + (t^2 + 2)*z + t^2 + 2*t + 1 sage: prec = 9 sage: x = n.subs(z=w)/d.subs(z=w) + O(w^prec) sage: # needs sage.libs.flint (otherwise timeout) sage: nc, dc = Pz(x.list()).rational_reconstruction(z^prec) sage: (nc, dc) == (n, d) True - >>> from sage.all import * >>> P = PolynomialRing(QQ, 't') >>> t = P.gen() >>> Pz = PolynomialRing(P.fraction_field(), 'z') >>> z = Pz.gen() >>> # p = (1 + t^2*z + z^4) / (1 - t*z) >>> p = (Integer(1) + t**Integer(2)*z + z**Integer(4))*(Integer(1) - t*z).inverse_mod(z**Integer(9)) >>> m = z**Integer(9) >>> n, d = p.rational_reconstruction(m); n, d (-1/t*z^4 - t*z - 1/t, z - 1/t) >>> ((p*d - n) % m).is_zero() True >>> w = PowerSeriesRing(P.fraction_field(), 'w').gen() >>> n = -Integer(10)*t**Integer(2)*z**Integer(4) + (-t**Integer(2) + t - Integer(1))*z**Integer(3) + (-t - Integer(8))*z**Integer(2) + z + Integer(2)*t**Integer(2) - t >>> d = z**Integer(4) + (Integer(2)*t + Integer(4))*z**Integer(3) + (-t + Integer(5))*z**Integer(2) + (t**Integer(2) + Integer(2))*z + t**Integer(2) + Integer(2)*t + Integer(1) >>> prec = Integer(9) >>> x = n.subs(z=w)/d.subs(z=w) + O(w**prec) >>> # needs sage.libs.flint (otherwise timeout) >>> nc, dc = Pz(x.list()).rational_reconstruction(z**prec) >>> (nc, dc) == (n, d) True - Over \(\QQ[t][z]\): - sage: P = PolynomialRing(QQ, 't') sage: t = P.gen() sage: z = PolynomialRing(P, 'z').gen() sage: # p = (1 + t^2*z + z^4) / (1 - t*z) mod z^9 sage: p = (1 + t^2*z + z^4) * sum((t*z)**i for i in range(9)) sage: m = z^9 sage: n, d = p.rational_reconstruction(m,); n, d (-z^4 - t^2*z - 1, t*z - 1) sage: ((p*d - n) % m).is_zero() True - >>> from sage.all import * >>> P = PolynomialRing(QQ, 't') >>> t = P.gen() >>> z = PolynomialRing(P, 'z').gen() >>> # p = (1 + t^2*z + z^4) / (1 - t*z) mod z^9 >>> p = (Integer(1) + t**Integer(2)*z + z**Integer(4)) * sum((t*z)**i for i in range(Integer(9))) >>> m = z**Integer(9) >>> n, d = p.rational_reconstruction(m,); n, d (-z^4 - t^2*z - 1, t*z - 1) >>> ((p*d - n) % m).is_zero() True - Over \(\QQ_5\): - sage: # needs sage.rings.padics sage: x = PolynomialRing(Qp(5), 'x').gen() sage: p = 4*x^5 + 3*x^4 + 2*x^3 + 2*x^2 + 4*x + 2 sage: m = x^6 sage: n, d = p.rational_reconstruction(m, 3, 2) sage: ((p*d - n) % m).is_zero() True - >>> from sage.all import * >>> # needs sage.rings.padics >>> x = PolynomialRing(Qp(Integer(5)), 'x').gen() >>> p = Integer(4)*x**Integer(5) + Integer(3)*x**Integer(4) + Integer(2)*x**Integer(3) + Integer(2)*x**Integer(2) + Integer(4)*x + Integer(2) >>> m = x**Integer(6) >>> n, d = p.rational_reconstruction(m, Integer(3), Integer(2)) >>> ((p*d - n) % m).is_zero() True - Can also be used to obtain known Padé approximations: - sage: z = PowerSeriesRing(QQ, 'z').gen() sage: P = PolynomialRing(QQ, 'x') sage: x = P.gen() sage: p = P(z.exp().list()) sage: m = x^5 sage: n, d = p.rational_reconstruction(m, 4, 0); n, d (1/24*x^4 + 1/6*x^3 + 1/2*x^2 + x + 1, 1) sage: ((p*d - n) % m).is_zero() True sage: m = x^3 sage: n, d = p.rational_reconstruction(m, 1, 1); n, d (-x - 2, x - 2) sage: ((p*d - n) % m).is_zero() True sage: p = P(log(1-z).list()) sage: m = x^9 sage: n, d = p.rational_reconstruction(m, 4, 4); n, d (25/6*x^4 - 130/3*x^3 + 105*x^2 - 70*x, x^4 - 20*x^3 + 90*x^2 - 140*x + 70) sage: ((p*d - n) % m).is_zero() True sage: p = P(sqrt(1+z).list()) sage: m = x^6 sage: n, d = p.rational_reconstruction(m, 3, 2); n, d (1/6*x^3 + 3*x^2 + 8*x + 16/3, x^2 + 16/3*x + 16/3) sage: ((p*d - n) % m).is_zero() True sage: p = P((2*z).exp().list()) sage: m = x^7 sage: n, d = p.rational_reconstruction(m, 3, 3); n, d (-x^3 - 6*x^2 - 15*x - 15, x^3 - 6*x^2 + 15*x - 15) sage: ((p*d - n) % m).is_zero() True - >>> from sage.all import * >>> z = PowerSeriesRing(QQ, 'z').gen() >>> P = PolynomialRing(QQ, 'x') >>> x = P.gen() >>> p = P(z.exp().list()) >>> m = x**Integer(5) >>> n, d = p.rational_reconstruction(m, Integer(4), Integer(0)); n, d (1/24*x^4 + 1/6*x^3 + 1/2*x^2 + x + 1, 1) >>> ((p*d - n) % m).is_zero() True >>> m = x**Integer(3) >>> n, d = p.rational_reconstruction(m, Integer(1), Integer(1)); n, d (-x - 2, x - 2) >>> ((p*d - n) % m).is_zero() True >>> p = P(log(Integer(1)-z).list()) >>> m = x**Integer(9) >>> n, d = p.rational_reconstruction(m, Integer(4), Integer(4)); n, d (25/6*x^4 - 130/3*x^3 + 105*x^2 - 70*x, x^4 - 20*x^3 + 90*x^2 - 140*x + 70) >>> ((p*d - n) % m).is_zero() True >>> p = P(sqrt(Integer(1)+z).list()) >>> m = x**Integer(6) >>> n, d = p.rational_reconstruction(m, Integer(3), Integer(2)); n, d (1/6*x^3 + 3*x^2 + 8*x + 16/3, x^2 + 16/3*x + 16/3) >>> ((p*d - n) % m).is_zero() True >>> p = P((Integer(2)*z).exp().list()) >>> m = x**Integer(7) >>> n, d = p.rational_reconstruction(m, Integer(3), Integer(3)); n, d (-x^3 - 6*x^2 - 15*x - 15, x^3 - 6*x^2 + 15*x - 15) >>> ((p*d - n) % m).is_zero() True - Over \(\RR[z]\): - sage: # needs sage.rings.real_mpfr sage: z = PowerSeriesRing(RR, 'z').gen() sage: P = PolynomialRing(RR, 'x') sage: x = P.gen() sage: p = P((2*z).exp().list()) sage: m = x^7 sage: n, d = p.rational_reconstruction(m, 3, 3); n, d # absolute tolerance 1e-10 (-x^3 - 6.0*x^2 - 15.0*x - 15.0, x^3 - 6.0*x^2 + 15.0*x - 15.0) - >>> from sage.all import * >>> # needs sage.rings.real_mpfr >>> z = PowerSeriesRing(RR, 'z').gen() >>> P = PolynomialRing(RR, 'x') >>> x = P.gen() >>> p = P((Integer(2)*z).exp().list()) >>> m = x**Integer(7) >>> n, d = p.rational_reconstruction(m, Integer(3), Integer(3)); n, d # absolute tolerance 1e-10 (-x^3 - 6.0*x^2 - 15.0*x - 15.0, x^3 - 6.0*x^2 + 15.0*x - 15.0) 
 - real_roots()[source]¶
- Return the real roots of this polynomial, without multiplicities. - Calls - self.roots(ring=RR), unless this is a polynomial with floating-point real coefficients, in which case it calls- self.roots().- EXAMPLES: - sage: x = polygen(ZZ) sage: (x^2 - x - 1).real_roots() # needs sage.libs.pari sage.rings.real_mpfr [-0.618033988749895, 1.61803398874989] - >>> from sage.all import * >>> x = polygen(ZZ) >>> (x**Integer(2) - x - Integer(1)).real_roots() # needs sage.libs.pari sage.rings.real_mpfr [-0.618033988749895, 1.61803398874989] 
 - reciprocal_transform(R=1, q=1)[source]¶
- Transform a general polynomial into a self-reciprocal polynomial. - The input \(Q\) and output \(P\) satisfy the relation \[P(x) = Q(x + q/x) x^{\deg(Q)} R(x).\]- In this relation, \(Q\) has all roots in the real interval \([-2\sqrt{q}, 2\sqrt{q}]\) if and only if \(P\) has all roots on the circle \(|x| = \sqrt{q}\) and \(R\) divides \(x^2-q\). - See also - The inverse operation is - trace_polynomial().- INPUT: - R– polynomial
- q– scalar (default: \(1\))
 - EXAMPLES: - sage: pol.<x> = PolynomialRing(Rationals()) sage: u = x^2 + x - 1 sage: u.reciprocal_transform() x^4 + x^3 + x^2 + x + 1 sage: u.reciprocal_transform(R=x-1) x^5 - 1 sage: u.reciprocal_transform(q=3) x^4 + x^3 + 5*x^2 + 3*x + 9 - >>> from sage.all import * >>> pol = PolynomialRing(Rationals(), names=('x',)); (x,) = pol._first_ngens(1) >>> u = x**Integer(2) + x - Integer(1) >>> u.reciprocal_transform() x^4 + x^3 + x^2 + x + 1 >>> u.reciprocal_transform(R=x-Integer(1)) x^5 - 1 >>> u.reciprocal_transform(q=Integer(3)) x^4 + x^3 + 5*x^2 + 3*x + 9 
 - resultant(other)[source]¶
- Return the resultant of - selfand- other.- INPUT: - other– a polynomial
 - OUTPUT: an element of the base ring of the polynomial ring - ALGORITHM: - Uses PARI’s function pari:polresultant. For base rings that are not supported by PARI, the resultant is computed as the determinant of the Sylvester matrix. - EXAMPLES: - sage: R.<x> = QQ[] sage: f = x^3 + x + 1; g = x^3 - x - 1 sage: r = f.resultant(g); r # needs sage.libs.pari -8 sage: r.parent() is QQ # needs sage.libs.pari True - >>> from sage.all import * >>> R = QQ['x']; (x,) = R._first_ngens(1) >>> f = x**Integer(3) + x + Integer(1); g = x**Integer(3) - x - Integer(1) >>> r = f.resultant(g); r # needs sage.libs.pari -8 >>> r.parent() is QQ # needs sage.libs.pari True - We can compute resultants over univariate and multivariate polynomial rings: - sage: R.<a> = QQ[] sage: S.<x> = R[] sage: f = x^2 + a; g = x^3 + a sage: r = f.resultant(g); r # needs sage.libs.pari a^3 + a^2 sage: r.parent() is R # needs sage.libs.pari True - >>> from sage.all import * >>> R = QQ['a']; (a,) = R._first_ngens(1) >>> S = R['x']; (x,) = S._first_ngens(1) >>> f = x**Integer(2) + a; g = x**Integer(3) + a >>> r = f.resultant(g); r # needs sage.libs.pari a^3 + a^2 >>> r.parent() is R # needs sage.libs.pari True - sage: R.<a, b> = QQ[] sage: S.<x> = R[] sage: f = x^2 + a; g = x^3 + b sage: r = f.resultant(g); r # needs sage.libs.pari a^3 + b^2 sage: r.parent() is R # needs sage.libs.pari True - >>> from sage.all import * >>> R = QQ['a, b']; (a, b,) = R._first_ngens(2) >>> S = R['x']; (x,) = S._first_ngens(1) >>> f = x**Integer(2) + a; g = x**Integer(3) + b >>> r = f.resultant(g); r # needs sage.libs.pari a^3 + b^2 >>> r.parent() is R # needs sage.libs.pari True 
 - reverse(degree=None)[source]¶
- Return polynomial but with the coefficients reversed. - If an optional - degreeargument is given, the coefficient list will be truncated or zero padded as necessary before reversing it. Assuming that the constant coefficient of- selfis nonzero, the reverse polynomial will have the specified degree.- EXAMPLES: - sage: R.<x> = ZZ[]; S.<y> = R[] sage: f = y^3 + x*y - 3*x; f y^3 + x*y - 3*x sage: f.reverse() -3*x*y^3 + x*y^2 + 1 sage: f.reverse(degree=2) -3*x*y^2 + x*y sage: f.reverse(degree=5) -3*x*y^5 + x*y^4 + y^2 - >>> from sage.all import * >>> R = ZZ['x']; (x,) = R._first_ngens(1); S = R['y']; (y,) = S._first_ngens(1) >>> f = y**Integer(3) + x*y - Integer(3)*x; f y^3 + x*y - 3*x >>> f.reverse() -3*x*y^3 + x*y^2 + 1 >>> f.reverse(degree=Integer(2)) -3*x*y^2 + x*y >>> f.reverse(degree=Integer(5)) -3*x*y^5 + x*y^4 + y^2 
 - revert_series(n)[source]¶
- Return a polynomial - fsuch that- f(self(x)) = self(f(x)) = x mod x^n.- Currently, this is only implemented over some coefficient rings. - EXAMPLES: - sage: Pol.<x> = QQ[] sage: (x + x^3/6 + x^5/120).revert_series(6) 3/40*x^5 - 1/6*x^3 + x sage: Pol.<x> = CBF[] # needs sage.libs.flint sage: (x + x^3/6 + x^5/120).revert_series(6) # needs sage.libs.flint ([0.075000000000000 +/- ...e-17])*x^5 + ([-0.166666666666667 +/- ...e-16])*x^3 + x sage: # needs sage.symbolic sage: Pol.<x> = SR[] sage: x.revert_series(6) Traceback (most recent call last): ... NotImplementedError: only implemented for certain base rings - >>> from sage.all import * >>> Pol = QQ['x']; (x,) = Pol._first_ngens(1) >>> (x + x**Integer(3)/Integer(6) + x**Integer(5)/Integer(120)).revert_series(Integer(6)) 3/40*x^5 - 1/6*x^3 + x >>> Pol = CBF['x']; (x,) = Pol._first_ngens(1)# needs sage.libs.flint >>> (x + x**Integer(3)/Integer(6) + x**Integer(5)/Integer(120)).revert_series(Integer(6)) # needs sage.libs.flint ([0.075000000000000 +/- ...e-17])*x^5 + ([-0.166666666666667 +/- ...e-16])*x^3 + x >>> # needs sage.symbolic >>> Pol = SR['x']; (x,) = Pol._first_ngens(1) >>> x.revert_series(Integer(6)) Traceback (most recent call last): ... NotImplementedError: only implemented for certain base rings 
 - root_field(names, check_irreducible=True)[source]¶
- Return the field generated by the roots of the irreducible polynomial - self. The output is either a number field, relative number field, a quotient of a polynomial ring over a field, or the fraction field of the base ring.- EXAMPLES: - sage: R.<x> = QQ['x'] sage: f = x^3 + x + 17 sage: f.root_field('a') # needs sage.rings.number_field Number Field in a with defining polynomial x^3 + x + 17 - >>> from sage.all import * >>> R = QQ['x']; (x,) = R._first_ngens(1) >>> f = x**Integer(3) + x + Integer(17) >>> f.root_field('a') # needs sage.rings.number_field Number Field in a with defining polynomial x^3 + x + 17 - sage: R.<x> = QQ['x'] sage: f = x - 3 sage: f.root_field('b') # needs sage.rings.number_field Rational Field - >>> from sage.all import * >>> R = QQ['x']; (x,) = R._first_ngens(1) >>> f = x - Integer(3) >>> f.root_field('b') # needs sage.rings.number_field Rational Field - sage: R.<x> = ZZ['x'] sage: f = x^3 + x + 17 sage: f.root_field('b') # needs sage.rings.number_field Number Field in b with defining polynomial x^3 + x + 17 - >>> from sage.all import * >>> R = ZZ['x']; (x,) = R._first_ngens(1) >>> f = x**Integer(3) + x + Integer(17) >>> f.root_field('b') # needs sage.rings.number_field Number Field in b with defining polynomial x^3 + x + 17 - sage: # needs sage.rings.number_field sage: y = QQ['x'].0 sage: L.<a> = NumberField(y^3 - 2) sage: R.<x> = L['x'] sage: f = x^3 + x + 17 sage: f.root_field('c') Number Field in c with defining polynomial x^3 + x + 17 over its base field - >>> from sage.all import * >>> # needs sage.rings.number_field >>> y = QQ['x'].gen(0) >>> L = NumberField(y**Integer(3) - Integer(2), names=('a',)); (a,) = L._first_ngens(1) >>> R = L['x']; (x,) = R._first_ngens(1) >>> f = x**Integer(3) + x + Integer(17) >>> f.root_field('c') Number Field in c with defining polynomial x^3 + x + 17 over its base field - sage: # needs sage.rings.finite_rings sage: R.<x> = PolynomialRing(GF(9, 'a')) sage: f = x^3 + x^2 + 8 sage: K.<alpha> = f.root_field(); K Univariate Quotient Polynomial Ring in alpha over Finite Field in a of size 3^2 with modulus x^3 + x^2 + 2 sage: alpha^2 + 1 alpha^2 + 1 sage: alpha^3 + alpha^2 1 - >>> from sage.all import * >>> # needs sage.rings.finite_rings >>> R = PolynomialRing(GF(Integer(9), 'a'), names=('x',)); (x,) = R._first_ngens(1) >>> f = x**Integer(3) + x**Integer(2) + Integer(8) >>> K = f.root_field(names=('alpha',)); (alpha,) = K._first_ngens(1); K Univariate Quotient Polynomial Ring in alpha over Finite Field in a of size 3^2 with modulus x^3 + x^2 + 2 >>> alpha**Integer(2) + Integer(1) alpha^2 + 1 >>> alpha**Integer(3) + alpha**Integer(2) 1 - sage: R.<x> = QQ[] sage: f = x^2 sage: K.<alpha> = f.root_field() # needs sage.libs.pari Traceback (most recent call last): ... ValueError: polynomial must be irreducible - >>> from sage.all import * >>> R = QQ['x']; (x,) = R._first_ngens(1) >>> f = x**Integer(2) >>> K = f.root_field(names=('alpha',)); (alpha,) = K._first_ngens(1)# needs sage.libs.pari Traceback (most recent call last): ... ValueError: polynomial must be irreducible 
 - roots(ring=None, multiplicities=True, algorithm=None, **kwds)[source]¶
- Return the roots of this polynomial (by default, in the base ring of this polynomial). - INPUT: - ring– the ring to find roots in
- multiplicities– boolean (default:- True); if- Truereturn list of pairs \((r, n)\), where \(r\) is the root and \(n\) is the multiplicity. If- False, just return the unique roots, with no information about multiplicities.
- algorithm– the root-finding algorithm to use. We attempt to select a reasonable algorithm by default, but this lets the caller override our choice.
 - By default, this finds all the roots that lie in the base ring of the polynomial. However, the ring parameter can be used to specify a ring to look for roots in. - If the polynomial and the output ring are both exact (integers, rationals, finite fields, etc.), then the output should always be correct (or raise an exception, if that case is not yet handled). - If the output ring is approximate (floating-point real or complex numbers), then the answer will be estimated numerically, using floating-point arithmetic of at least the precision of the output ring. If the polynomial is ill-conditioned, meaning that a small change in the coefficients of the polynomial will lead to a relatively large change in the location of the roots, this may give poor results. Distinct roots may be returned as multiple roots, multiple roots may be returned as distinct roots, real roots may be lost entirely (because the numerical estimate thinks they are complex roots). Note that polynomials with multiple roots are always ill-conditioned; there’s a footnote at the end of the docstring about this. - If the output ring is a - RealIntervalFieldor- ComplexIntervalFieldof a given precision, then the answer will always be correct (or an exception will be raised, if a case is not implemented). Each root will be contained in one of the returned intervals, and the intervals will be disjoint. (The returned intervals may be of higher precision than the specified output ring.)- At the end of this docstring (after the examples) is a description of all the cases implemented in this function, and the algorithms used. That section also describes the possibilities for the - algorithmkeyword, for the cases where multiple algorithms exist.- EXAMPLES: - sage: # needs sage.libs.pari sage: x = QQ['x'].0 sage: f = x^3 - 1 sage: f.roots() [(1, 1)] sage: f.roots(ring=CC) # ... - low order bits slightly different on ppc # needs sage.rings.real_mpfr [(1.00000000000000, 1), (-0.500000000000000 - 0.86602540378443...*I, 1), (-0.500000000000000 + 0.86602540378443...*I, 1)] sage: f = (x^3 - 1)^2 sage: f.roots() [(1, 2)] sage: f = -19*x + 884736 sage: f.roots() [(884736/19, 1)] sage: (f^20).roots() [(884736/19, 20)] - >>> from sage.all import * >>> # needs sage.libs.pari >>> x = QQ['x'].gen(0) >>> f = x**Integer(3) - Integer(1) >>> f.roots() [(1, 1)] >>> f.roots(ring=CC) # ... - low order bits slightly different on ppc # needs sage.rings.real_mpfr [(1.00000000000000, 1), (-0.500000000000000 - 0.86602540378443...*I, 1), (-0.500000000000000 + 0.86602540378443...*I, 1)] >>> f = (x**Integer(3) - Integer(1))**Integer(2) >>> f.roots() [(1, 2)] >>> f = -Integer(19)*x + Integer(884736) >>> f.roots() [(884736/19, 1)] >>> (f**Integer(20)).roots() [(884736/19, 20)] - sage: # needs sage.rings.number_field sage: K.<z> = CyclotomicField(3) sage: f = K.defining_polynomial() sage: f.roots(ring=GF(7)) [(4, 1), (2, 1)] sage: g = f.change_ring(GF(7)) sage: g.roots() [(4, 1), (2, 1)] sage: g.roots(multiplicities=False) [4, 2] - >>> from sage.all import * >>> # needs sage.rings.number_field >>> K = CyclotomicField(Integer(3), names=('z',)); (z,) = K._first_ngens(1) >>> f = K.defining_polynomial() >>> f.roots(ring=GF(Integer(7))) [(4, 1), (2, 1)] >>> g = f.change_ring(GF(Integer(7))) >>> g.roots() [(4, 1), (2, 1)] >>> g.roots(multiplicities=False) [4, 2] - A new ring. In the example below, we add the special method - _roots_univariate_polynomial()to the base ring, and observe that this method is called instead to find roots of polynomials over this ring. This facility can be used to easily extend root finding to work over new rings you introduce:- sage: R.<x> = QQ[] sage: (x^2 + 1).roots() # needs sage.libs.pari [] sage: def my_roots(f, *args, **kwds): ....: return f.change_ring(CDF).roots() sage: QQ._roots_univariate_polynomial = my_roots sage: (x^2 + 1).roots() # abs tol 1e-14 # needs numpy [(2.7755575615628914e-17 - 1.0*I, 1), (0.9999999999999997*I, 1)] sage: del QQ._roots_univariate_polynomial - >>> from sage.all import * >>> R = QQ['x']; (x,) = R._first_ngens(1) >>> (x**Integer(2) + Integer(1)).roots() # needs sage.libs.pari [] >>> def my_roots(f, *args, **kwds): ... return f.change_ring(CDF).roots() >>> QQ._roots_univariate_polynomial = my_roots >>> (x**Integer(2) + Integer(1)).roots() # abs tol 1e-14 # needs numpy [(2.7755575615628914e-17 - 1.0*I, 1), (0.9999999999999997*I, 1)] >>> del QQ._roots_univariate_polynomial - An example over RR, which illustrates that only the roots in RR are returned: - sage: # needs numpy sage.rings.real_mpfr sage: x = RR['x'].0 sage: f = x^3 - 2 sage: f.roots() [(1.25992104989487, 1)] sage: f.factor() (x - 1.25992104989487) * (x^2 + 1.25992104989487*x + 1.58740105196820) sage: x = RealField(100)['x'].0 sage: f = x^3 - 2 sage: f.roots() [(1.2599210498948731647672106073, 1)] - >>> from sage.all import * >>> # needs numpy sage.rings.real_mpfr >>> x = RR['x'].gen(0) >>> f = x**Integer(3) - Integer(2) >>> f.roots() [(1.25992104989487, 1)] >>> f.factor() (x - 1.25992104989487) * (x^2 + 1.25992104989487*x + 1.58740105196820) >>> x = RealField(Integer(100))['x'].gen(0) >>> f = x**Integer(3) - Integer(2) >>> f.roots() [(1.2599210498948731647672106073, 1)] - sage: # needs sage.rings.real_mpfr sage: x = CC['x'].0 sage: f = x^3 - 2 sage: f.roots() # needs numpy [(1.25992104989487, 1), (-0.62996052494743... - 1.09112363597172*I, 1), (-0.62996052494743... + 1.09112363597172*I, 1)] sage: f.roots(algorithm='pari') # needs sage.libs.pari [(1.25992104989487, 1), (-0.629960524947437 - 1.09112363597172*I, 1), (-0.629960524947437 + 1.09112363597172*I, 1)] - >>> from sage.all import * >>> # needs sage.rings.real_mpfr >>> x = CC['x'].gen(0) >>> f = x**Integer(3) - Integer(2) >>> f.roots() # needs numpy [(1.25992104989487, 1), (-0.62996052494743... - 1.09112363597172*I, 1), (-0.62996052494743... + 1.09112363597172*I, 1)] >>> f.roots(algorithm='pari') # needs sage.libs.pari [(1.25992104989487, 1), (-0.629960524947437 - 1.09112363597172*I, 1), (-0.629960524947437 + 1.09112363597172*I, 1)] - Another example showing that only roots in the base ring are returned: - sage: x = polygen(ZZ) sage: f = (2*x - 3) * (x - 1) * (x + 1) sage: f.roots() # needs sage.libs.pari [(1, 1), (-1, 1)] sage: f.roots(ring=QQ) # needs sage.libs.pari [(3/2, 1), (1, 1), (-1, 1)] - >>> from sage.all import * >>> x = polygen(ZZ) >>> f = (Integer(2)*x - Integer(3)) * (x - Integer(1)) * (x + Integer(1)) >>> f.roots() # needs sage.libs.pari [(1, 1), (-1, 1)] >>> f.roots(ring=QQ) # needs sage.libs.pari [(3/2, 1), (1, 1), (-1, 1)] - An example where we compute the roots lying in a subring of the base ring: - sage: Pols.<n> = QQ[] sage: pol = (n - 1/2)^2 * (n - 1)^2 * (n - 2) sage: pol.roots(ZZ) # needs sage.libs.pari [(2, 1), (1, 2)] - >>> from sage.all import * >>> Pols = QQ['n']; (n,) = Pols._first_ngens(1) >>> pol = (n - Integer(1)/Integer(2))**Integer(2) * (n - Integer(1))**Integer(2) * (n - Integer(2)) >>> pol.roots(ZZ) # needs sage.libs.pari [(2, 1), (1, 2)] - An example involving large numbers: - sage: # needs numpy sage.rings.real_mpfr sage: x = RR['x'].0 sage: f = x^2 - 1e100 sage: f.roots() [(-1.00000000000000e50, 1), (1.00000000000000e50, 1)] sage: f = x^10 - 2 * (5*x - 1)^2 sage: f.roots(multiplicities=False) [-1.6772670339941..., 0.19995479628..., 0.20004530611..., 1.5763035161844...] - >>> from sage.all import * >>> # needs numpy sage.rings.real_mpfr >>> x = RR['x'].gen(0) >>> f = x**Integer(2) - RealNumber('1e100') >>> f.roots() [(-1.00000000000000e50, 1), (1.00000000000000e50, 1)] >>> f = x**Integer(10) - Integer(2) * (Integer(5)*x - Integer(1))**Integer(2) >>> f.roots(multiplicities=False) [-1.6772670339941..., 0.19995479628..., 0.20004530611..., 1.5763035161844...] - sage: # needs numpy sage.rings.real_mpfr sage: x = CC['x'].0 sage: i = CC.0 sage: f = (x - 1) * (x - i) sage: f.roots(multiplicities=False) [1.00000000000000, 1.00000000000000*I] sage: g = (x - 1.33 + 1.33*i) * (x - 2.66 - 2.66*i) sage: g.roots(multiplicities=False) [1.33000000000000 - 1.33000000000000*I, 2.66000000000000 + 2.66000000000000*I] - >>> from sage.all import * >>> # needs numpy sage.rings.real_mpfr >>> x = CC['x'].gen(0) >>> i = CC.gen(0) >>> f = (x - Integer(1)) * (x - i) >>> f.roots(multiplicities=False) [1.00000000000000, 1.00000000000000*I] >>> g = (x - RealNumber('1.33') + RealNumber('1.33')*i) * (x - RealNumber('2.66') - RealNumber('2.66')*i) >>> g.roots(multiplicities=False) [1.33000000000000 - 1.33000000000000*I, 2.66000000000000 + 2.66000000000000*I] - Describing roots using radical expressions: - sage: x = QQ['x'].0 sage: f = x^2 + 2 sage: f.roots(SR) # needs sage.symbolic [(-I*sqrt(2), 1), (I*sqrt(2), 1)] sage: f.roots(SR, multiplicities=False) # needs sage.symbolic [-I*sqrt(2), I*sqrt(2)] - >>> from sage.all import * >>> x = QQ['x'].gen(0) >>> f = x**Integer(2) + Integer(2) >>> f.roots(SR) # needs sage.symbolic [(-I*sqrt(2), 1), (I*sqrt(2), 1)] >>> f.roots(SR, multiplicities=False) # needs sage.symbolic [-I*sqrt(2), I*sqrt(2)] - The roots of some polynomials cannot be described using radical expressions: - sage: (x^5 - x + 1).roots(SR) # needs sage.symbolic [] - >>> from sage.all import * >>> (x**Integer(5) - x + Integer(1)).roots(SR) # needs sage.symbolic [] - For some other polynomials, no roots can be found at the moment due to the way roots are computed. Issue #17516 addresses these defects. Until that gets implemented, one such example is the following: - sage: f = x^6 - 300*x^5 + 30361*x^4 - 1061610*x^3 + 1141893*x^2 - 915320*x + 101724 sage: f.roots() # needs sage.libs.pari [] - >>> from sage.all import * >>> f = x**Integer(6) - Integer(300)*x**Integer(5) + Integer(30361)*x**Integer(4) - Integer(1061610)*x**Integer(3) + Integer(1141893)*x**Integer(2) - Integer(915320)*x + Integer(101724) >>> f.roots() # needs sage.libs.pari [] - A purely symbolic roots example: - sage: # needs sage.symbolic sage: X = var('X') sage: f = expand((X - 1) * (X - I)^3 * (X^2 - sqrt(2))); f X^6 - (3*I + 1)*X^5 - sqrt(2)*X^4 + (3*I - 3)*X^4 + (3*I + 1)*sqrt(2)*X^3 + (I + 3)*X^3 - (3*I - 3)*sqrt(2)*X^2 - I*X^2 - (I + 3)*sqrt(2)*X + I*sqrt(2) sage: f.roots() [(I, 3), (-2^(1/4), 1), (2^(1/4), 1), (1, 1)] - >>> from sage.all import * >>> # needs sage.symbolic >>> X = var('X') >>> f = expand((X - Integer(1)) * (X - I)**Integer(3) * (X**Integer(2) - sqrt(Integer(2)))); f X^6 - (3*I + 1)*X^5 - sqrt(2)*X^4 + (3*I - 3)*X^4 + (3*I + 1)*sqrt(2)*X^3 + (I + 3)*X^3 - (3*I - 3)*sqrt(2)*X^2 - I*X^2 - (I + 3)*sqrt(2)*X + I*sqrt(2) >>> f.roots() [(I, 3), (-2^(1/4), 1), (2^(1/4), 1), (1, 1)] - The same operation, performed over a polynomial ring with symbolic coefficients: - sage: # needs sage.symbolic sage: X = SR['X'].0 sage: f = (X - 1) * (X - I)^3 * (X^2 - sqrt(2)); f X^6 + (-3*I - 1)*X^5 + (-sqrt(2) + 3*I - 3)*X^4 + ((3*I + 1)*sqrt(2) + I + 3)*X^3 + (-(3*I - 3)*sqrt(2) - I)*X^2 + (-(I + 3)*sqrt(2))*X + I*sqrt(2) sage: f.roots() [(I, 3), (-2^(1/4), 1), (2^(1/4), 1), (1, 1)] sage: f.roots(multiplicities=False) [I, -2^(1/4), 2^(1/4), 1] - >>> from sage.all import * >>> # needs sage.symbolic >>> X = SR['X'].gen(0) >>> f = (X - Integer(1)) * (X - I)**Integer(3) * (X**Integer(2) - sqrt(Integer(2))); f X^6 + (-3*I - 1)*X^5 + (-sqrt(2) + 3*I - 3)*X^4 + ((3*I + 1)*sqrt(2) + I + 3)*X^3 + (-(3*I - 3)*sqrt(2) - I)*X^2 + (-(I + 3)*sqrt(2))*X + I*sqrt(2) >>> f.roots() [(I, 3), (-2^(1/4), 1), (2^(1/4), 1), (1, 1)] >>> f.roots(multiplicities=False) [I, -2^(1/4), 2^(1/4), 1] - A couple of examples where the base ring does not have a factorization algorithm (yet). Note that this is currently done via a rather naive enumeration, so could be very slow: - sage: R = Integers(6) sage: S.<x> = R['x'] sage: p = x^2 - 1 sage: p.roots() Traceback (most recent call last): ... NotImplementedError: root finding with multiplicities for this polynomial not implemented (try the multiplicities=False option) sage: p.roots(multiplicities=False) # needs sage.libs.pari [5, 1] sage: R = Integers(9) sage: A = PolynomialRing(R, 'y') sage: y = A.gen() sage: f = 10*y^2 - y^3 - 9 sage: f.roots(multiplicities=False) # needs sage.libs.pari [1, 0, 3, 6] - >>> from sage.all import * >>> R = Integers(Integer(6)) >>> S = R['x']; (x,) = S._first_ngens(1) >>> p = x**Integer(2) - Integer(1) >>> p.roots() Traceback (most recent call last): ... NotImplementedError: root finding with multiplicities for this polynomial not implemented (try the multiplicities=False option) >>> p.roots(multiplicities=False) # needs sage.libs.pari [5, 1] >>> R = Integers(Integer(9)) >>> A = PolynomialRing(R, 'y') >>> y = A.gen() >>> f = Integer(10)*y**Integer(2) - y**Integer(3) - Integer(9) >>> f.roots(multiplicities=False) # needs sage.libs.pari [1, 0, 3, 6] - An example over the complex double field (where root finding is fast, thanks to NumPy): - sage: # needs numpy sage.rings.complex_double sage: R.<x> = CDF[] sage: f = R.cyclotomic_polynomial(5); f x^4 + x^3 + x^2 + x + 1.0 sage: f.roots(multiplicities=False) # abs tol 1e-9 [-0.8090169943749469 - 0.5877852522924724*I, -0.8090169943749473 + 0.5877852522924724*I, 0.30901699437494773 - 0.951056516295154*I, 0.30901699437494756 + 0.9510565162951525*I] sage: [z^5 for z in f.roots(multiplicities=False)] # abs tol 2e-14 [0.9999999999999957 - 1.2864981197413038e-15*I, 0.9999999999999976 + 3.062854959141552e-15*I, 1.0000000000000024 + 1.1331077795295987e-15*I, 0.9999999999999953 - 2.0212861992297117e-15*I] sage: f = CDF['x']([1,2,3,4]); f 4.0*x^3 + 3.0*x^2 + 2.0*x + 1.0 sage: r = f.roots(multiplicities=False) sage: [f(a).abs() for a in r] # abs tol 1e-14 [2.574630599127759e-15, 1.457101633618084e-15, 1.1443916996305594e-15] - >>> from sage.all import * >>> # needs numpy sage.rings.complex_double >>> R = CDF['x']; (x,) = R._first_ngens(1) >>> f = R.cyclotomic_polynomial(Integer(5)); f x^4 + x^3 + x^2 + x + 1.0 >>> f.roots(multiplicities=False) # abs tol 1e-9 [-0.8090169943749469 - 0.5877852522924724*I, -0.8090169943749473 + 0.5877852522924724*I, 0.30901699437494773 - 0.951056516295154*I, 0.30901699437494756 + 0.9510565162951525*I] >>> [z**Integer(5) for z in f.roots(multiplicities=False)] # abs tol 2e-14 [0.9999999999999957 - 1.2864981197413038e-15*I, 0.9999999999999976 + 3.062854959141552e-15*I, 1.0000000000000024 + 1.1331077795295987e-15*I, 0.9999999999999953 - 2.0212861992297117e-15*I] >>> f = CDF['x']([Integer(1),Integer(2),Integer(3),Integer(4)]); f 4.0*x^3 + 3.0*x^2 + 2.0*x + 1.0 >>> r = f.roots(multiplicities=False) >>> [f(a).abs() for a in r] # abs tol 1e-14 [2.574630599127759e-15, 1.457101633618084e-15, 1.1443916996305594e-15] - Another example over RDF: - sage: x = RDF['x'].0 sage: ((x^3 - 1)).roots() # abs tol 4e-16 # needs numpy [(1.0000000000000002, 1)] sage: ((x^3 - 1)).roots(multiplicities=False) # abs tol 4e-16 # needs numpy [1.0000000000000002] - >>> from sage.all import * >>> x = RDF['x'].gen(0) >>> ((x**Integer(3) - Integer(1))).roots() # abs tol 4e-16 # needs numpy [(1.0000000000000002, 1)] >>> ((x**Integer(3) - Integer(1))).roots(multiplicities=False) # abs tol 4e-16 # needs numpy [1.0000000000000002] - More examples involving the complex double field: - sage: # needs numpy sage.rings.complex_double sage.rings.real_mpfr sage: x = CDF['x'].0 sage: i = CDF.0 sage: f = x^3 + 2*i; f x^3 + 2.0*I sage: f.roots() [(-1.09112363597172... - 0.62996052494743...*I, 1), (...1.25992104989487...*I, 1), (1.09112363597172... - 0.62996052494743...*I, 1)] sage: f.roots(multiplicities=False) [-1.09112363597172... - 0.62996052494743...*I, ...1.25992104989487...*I, 1.09112363597172... - 0.62996052494743...*I] sage: [abs(f(z)) for z in f.roots(multiplicities=False)] # abs tol 1e-14 [8.95090418262362e-16, 8.728374398092689e-16, 1.0235750533041806e-15] sage: f = i*x^3 + 2; f I*x^3 + 2.0 sage: f.roots() [(-1.09112363597172... + 0.62996052494743...*I, 1), (...1.25992104989487...*I, 1), (1.09112363597172... + 0.62996052494743...*I, 1)] sage: abs(f(f.roots()[0][0])) # abs tol 1e-13 1.1102230246251565e-16 - >>> from sage.all import * >>> # needs numpy sage.rings.complex_double sage.rings.real_mpfr >>> x = CDF['x'].gen(0) >>> i = CDF.gen(0) >>> f = x**Integer(3) + Integer(2)*i; f x^3 + 2.0*I >>> f.roots() [(-1.09112363597172... - 0.62996052494743...*I, 1), (...1.25992104989487...*I, 1), (1.09112363597172... - 0.62996052494743...*I, 1)] >>> f.roots(multiplicities=False) [-1.09112363597172... - 0.62996052494743...*I, ...1.25992104989487...*I, 1.09112363597172... - 0.62996052494743...*I] >>> [abs(f(z)) for z in f.roots(multiplicities=False)] # abs tol 1e-14 [8.95090418262362e-16, 8.728374398092689e-16, 1.0235750533041806e-15] >>> f = i*x**Integer(3) + Integer(2); f I*x^3 + 2.0 >>> f.roots() [(-1.09112363597172... + 0.62996052494743...*I, 1), (...1.25992104989487...*I, 1), (1.09112363597172... + 0.62996052494743...*I, 1)] >>> abs(f(f.roots()[Integer(0)][Integer(0)])) # abs tol 1e-13 1.1102230246251565e-16 - Examples using real root isolation: - sage: x = polygen(ZZ) sage: f = x^2 - x - 1 sage: f.roots() # needs sage.libs.pari [] sage: f.roots(ring=AA) # needs sage.rings.number_field [(-0.618033988749895?, 1), (1.618033988749895?, 1)] sage: # needs sage.rings.real_interval_field sage: f.roots(ring=RIF) [(-0.6180339887498948482045868343657?, 1), (1.6180339887498948482045868343657?, 1)] sage: f.roots(ring=RIF, multiplicities=False) [-0.6180339887498948482045868343657?, 1.6180339887498948482045868343657?] sage: f.roots(ring=RealIntervalField(150)) [(-0.6180339887498948482045868343656381177203091798057628621354486227?, 1), (1.618033988749894848204586834365638117720309179805762862135448623?, 1)] sage: f = f^2 * (x - 1) sage: f.roots(ring=RIF) [(-0.6180339887498948482045868343657?, 2), (1.0000000000000000000000000000000?, 1), (1.6180339887498948482045868343657?, 2)] sage: f.roots(ring=RIF, multiplicities=False) [-0.6180339887498948482045868343657?, 1.0000000000000000000000000000000?, 1.6180339887498948482045868343657?] - >>> from sage.all import * >>> x = polygen(ZZ) >>> f = x**Integer(2) - x - Integer(1) >>> f.roots() # needs sage.libs.pari [] >>> f.roots(ring=AA) # needs sage.rings.number_field [(-0.618033988749895?, 1), (1.618033988749895?, 1)] >>> # needs sage.rings.real_interval_field >>> f.roots(ring=RIF) [(-0.6180339887498948482045868343657?, 1), (1.6180339887498948482045868343657?, 1)] >>> f.roots(ring=RIF, multiplicities=False) [-0.6180339887498948482045868343657?, 1.6180339887498948482045868343657?] >>> f.roots(ring=RealIntervalField(Integer(150))) [(-0.6180339887498948482045868343656381177203091798057628621354486227?, 1), (1.618033988749894848204586834365638117720309179805762862135448623?, 1)] >>> f = f**Integer(2) * (x - Integer(1)) >>> f.roots(ring=RIF) [(-0.6180339887498948482045868343657?, 2), (1.0000000000000000000000000000000?, 1), (1.6180339887498948482045868343657?, 2)] >>> f.roots(ring=RIF, multiplicities=False) [-0.6180339887498948482045868343657?, 1.0000000000000000000000000000000?, 1.6180339887498948482045868343657?] - Examples using complex root isolation: - sage: x = polygen(ZZ) sage: p = x^5 - x - 1 sage: p.roots() # needs sage.libs.pari [] sage: p.roots(ring=CIF) # needs sage.rings.complex_interval_field [(1.167303978261419?, 1), (-0.764884433600585? - 0.352471546031727?*I, 1), (-0.764884433600585? + 0.352471546031727?*I, 1), (0.181232444469876? - 1.083954101317711?*I, 1), (0.181232444469876? + 1.083954101317711?*I, 1)] sage: p.roots(ring=ComplexIntervalField(200)) # needs sage.rings.complex_interval_field [(1.167303978261418684256045899854842180720560371525489039140082?, 1), (-0.76488443360058472602982318770854173032899665194736756700778? - 0.35247154603172624931794709140258105439420648082424733283770?*I, 1), (-0.76488443360058472602982318770854173032899665194736756700778? + 0.35247154603172624931794709140258105439420648082424733283770?*I, 1), (0.18123244446987538390180023778112063996871646618462304743774? - 1.08395410131771066843034449298076657427364024315511565430114?*I, 1), (0.18123244446987538390180023778112063996871646618462304743774? + 1.08395410131771066843034449298076657427364024315511565430114?*I, 1)] sage: rts = p.roots(ring=QQbar); rts # needs sage.rings.number_field [(1.167303978261419?, 1), (-0.7648844336005847? - 0.3524715460317263?*I, 1), (-0.7648844336005847? + 0.3524715460317263?*I, 1), (0.1812324444698754? - 1.083954101317711?*I, 1), (0.1812324444698754? + 1.083954101317711?*I, 1)] sage: p.roots(ring=AA) # needs sage.rings.number_field [(1.167303978261419?, 1)] sage: p = (x - rts[4][0])^2 * (3*x^2 + x + 1) # needs sage.rings.number_field sage: p.roots(ring=QQbar) # needs sage.rings.number_field [(-0.1666666666666667? - 0.552770798392567?*I, 1), (-0.1666666666666667? + 0.552770798392567?*I, 1), (0.1812324444698754? + 1.083954101317711?*I, 2)] sage: p.roots(ring=CIF) # needs sage.rings.complex_interval_field [(-0.1666666666666667? - 0.552770798392567?*I, 1), (-0.1666666666666667? + 0.552770798392567?*I, 1), (0.1812324444698754? + 1.083954101317711?*I, 2)] - >>> from sage.all import * >>> x = polygen(ZZ) >>> p = x**Integer(5) - x - Integer(1) >>> p.roots() # needs sage.libs.pari [] >>> p.roots(ring=CIF) # needs sage.rings.complex_interval_field [(1.167303978261419?, 1), (-0.764884433600585? - 0.352471546031727?*I, 1), (-0.764884433600585? + 0.352471546031727?*I, 1), (0.181232444469876? - 1.083954101317711?*I, 1), (0.181232444469876? + 1.083954101317711?*I, 1)] >>> p.roots(ring=ComplexIntervalField(Integer(200))) # needs sage.rings.complex_interval_field [(1.167303978261418684256045899854842180720560371525489039140082?, 1), (-0.76488443360058472602982318770854173032899665194736756700778? - 0.35247154603172624931794709140258105439420648082424733283770?*I, 1), (-0.76488443360058472602982318770854173032899665194736756700778? + 0.35247154603172624931794709140258105439420648082424733283770?*I, 1), (0.18123244446987538390180023778112063996871646618462304743774? - 1.08395410131771066843034449298076657427364024315511565430114?*I, 1), (0.18123244446987538390180023778112063996871646618462304743774? + 1.08395410131771066843034449298076657427364024315511565430114?*I, 1)] >>> rts = p.roots(ring=QQbar); rts # needs sage.rings.number_field [(1.167303978261419?, 1), (-0.7648844336005847? - 0.3524715460317263?*I, 1), (-0.7648844336005847? + 0.3524715460317263?*I, 1), (0.1812324444698754? - 1.083954101317711?*I, 1), (0.1812324444698754? + 1.083954101317711?*I, 1)] >>> p.roots(ring=AA) # needs sage.rings.number_field [(1.167303978261419?, 1)] >>> p = (x - rts[Integer(4)][Integer(0)])**Integer(2) * (Integer(3)*x**Integer(2) + x + Integer(1)) # needs sage.rings.number_field >>> p.roots(ring=QQbar) # needs sage.rings.number_field [(-0.1666666666666667? - 0.552770798392567?*I, 1), (-0.1666666666666667? + 0.552770798392567?*I, 1), (0.1812324444698754? + 1.083954101317711?*I, 2)] >>> p.roots(ring=CIF) # needs sage.rings.complex_interval_field [(-0.1666666666666667? - 0.552770798392567?*I, 1), (-0.1666666666666667? + 0.552770798392567?*I, 1), (0.1812324444698754? + 1.083954101317711?*I, 2)] - In some cases, it is possible to isolate the roots of polynomials over complex ball fields: - sage: # needs sage.libs.flint sage: Pol.<x> = CBF[] sage: set((x^2 + 2).roots(multiplicities=False)) {[+/- ...e-19] + [-1.414213562373095 +/- ...e-17]*I, [+/- ...e-19] + [1.414213562373095 +/- ...e-17]*I} sage: (x^3 - 1/2).roots(RBF, multiplicities=False) [[0.7937005259840997 +/- ...e-17]] sage: ((x - 1)^2).roots(multiplicities=False, proof=False) doctest:... UserWarning: roots may have been lost... [[1.000000000... +/- ...] + [+/- ...]*I, [1.000000000... +/- ...] + [+/- ...]*I] sage: ((x - 1)^2).roots(multiplicities=False, proof=False, warn=False) [[1.000000000... +/- ...] + [+/- ...]*I, [1.000000000... +/- ...] + [+/- ...]*I] - >>> from sage.all import * >>> # needs sage.libs.flint >>> Pol = CBF['x']; (x,) = Pol._first_ngens(1) >>> set((x**Integer(2) + Integer(2)).roots(multiplicities=False)) {[+/- ...e-19] + [-1.414213562373095 +/- ...e-17]*I, [+/- ...e-19] + [1.414213562373095 +/- ...e-17]*I} >>> (x**Integer(3) - Integer(1)/Integer(2)).roots(RBF, multiplicities=False) [[0.7937005259840997 +/- ...e-17]] >>> ((x - Integer(1))**Integer(2)).roots(multiplicities=False, proof=False) doctest:... UserWarning: roots may have been lost... [[1.000000000... +/- ...] + [+/- ...]*I, [1.000000000... +/- ...] + [+/- ...]*I] >>> ((x - Integer(1))**Integer(2)).roots(multiplicities=False, proof=False, warn=False) [[1.000000000... +/- ...] + [+/- ...]*I, [1.000000000... +/- ...] + [+/- ...]*I] - Note that coefficients in a number field with defining polynomial \(x^2 + 1\) are considered to be Gaussian rationals (with the generator mapping to \(+I\)), if you ask for complex roots. - sage: # needs sage.rings.number_field sage: K.<im> = QuadraticField(-1) sage: y = polygen(K) sage: p = y^4 - 2 - im sage: p.roots(ring=CC) [(-1.2146389322441... - 0.14142505258239...*I, 1), (-0.14142505258239... + 1.2146389322441...*I, 1), (0.14142505258239... - 1.2146389322441...*I, 1), (1.2146389322441... + 0.14142505258239...*I, 1)] sage: p = p^2 * (y^2 - 2) sage: p.roots(ring=CIF) [(-1.414213562373095?, 1), (1.414213562373095?, 1), (-1.214638932244183? - 0.141425052582394?*I, 2), (-0.141425052582394? + 1.214638932244183?*I, 2), (0.141425052582394? - 1.214638932244183?*I, 2), (1.214638932244183? + 0.141425052582394?*I, 2)] - >>> from sage.all import * >>> # needs sage.rings.number_field >>> K = QuadraticField(-Integer(1), names=('im',)); (im,) = K._first_ngens(1) >>> y = polygen(K) >>> p = y**Integer(4) - Integer(2) - im >>> p.roots(ring=CC) [(-1.2146389322441... - 0.14142505258239...*I, 1), (-0.14142505258239... + 1.2146389322441...*I, 1), (0.14142505258239... - 1.2146389322441...*I, 1), (1.2146389322441... + 0.14142505258239...*I, 1)] >>> p = p**Integer(2) * (y**Integer(2) - Integer(2)) >>> p.roots(ring=CIF) [(-1.414213562373095?, 1), (1.414213562373095?, 1), (-1.214638932244183? - 0.141425052582394?*I, 2), (-0.141425052582394? + 1.214638932244183?*I, 2), (0.141425052582394? - 1.214638932244183?*I, 2), (1.214638932244183? + 0.141425052582394?*I, 2)] - Note that one should not use NumPy when wanting high precision output as it does not support any of the high precision types: - sage: # needs numpy sage.rings.real_mpfr sage.symbolic sage: R.<x> = RealField(200)[] sage: f = x^2 - R(pi) sage: f.roots() [(-1.7724538509055160272981674833411451827975494561223871282138, 1), (1.7724538509055160272981674833411451827975494561223871282138, 1)] sage: f.roots(algorithm='numpy') doctest... UserWarning: NumPy does not support arbitrary precision arithmetic. The roots found will likely have less precision than you expect. [(-1.77245385090551..., 1), (1.77245385090551..., 1)] - >>> from sage.all import * >>> # needs numpy sage.rings.real_mpfr sage.symbolic >>> R = RealField(Integer(200))['x']; (x,) = R._first_ngens(1) >>> f = x**Integer(2) - R(pi) >>> f.roots() [(-1.7724538509055160272981674833411451827975494561223871282138, 1), (1.7724538509055160272981674833411451827975494561223871282138, 1)] >>> f.roots(algorithm='numpy') doctest... UserWarning: NumPy does not support arbitrary precision arithmetic. The roots found will likely have less precision than you expect. [(-1.77245385090551..., 1), (1.77245385090551..., 1)] - We can also find roots over number fields: - sage: K.<z> = CyclotomicField(15) # needs sage.rings.number_field sage: R.<x> = PolynomialRing(K) # needs sage.rings.number_field sage: (x^2 + x + 1).roots() # needs sage.rings.number_field [(z^5, 1), (-z^5 - 1, 1)] - >>> from sage.all import * >>> K = CyclotomicField(Integer(15), names=('z',)); (z,) = K._first_ngens(1)# needs sage.rings.number_field >>> R = PolynomialRing(K, names=('x',)); (x,) = R._first_ngens(1)# needs sage.rings.number_field >>> (x**Integer(2) + x + Integer(1)).roots() # needs sage.rings.number_field [(z^5, 1), (-z^5 - 1, 1)] - There are many combinations of floating-point input and output types that work. (Note that some of them are quite pointless like using - algorithm='numpy'with high-precision types.)- sage: # needs numpy sage.rings.complex_double sage.rings.real_mpfr sage: rflds = (RR, RDF, RealField(100)) sage: cflds = (CC, CDF, ComplexField(100)) sage: def cross(a, b): ....: return list(cartesian_product_iterator([a, b])) sage: flds = cross(rflds, rflds) + cross(rflds, cflds) + cross(cflds, cflds) sage: for (fld_in, fld_out) in flds: ....: x = polygen(fld_in) ....: f = x^3 - fld_in(2) ....: x2 = polygen(fld_out) ....: f2 = x2^3 - fld_out(2) ....: for algo in (None, 'pari', 'numpy'): ....: rts = f.roots(ring=fld_out, multiplicities=False) ....: rts = sorted(rts, key=lambda x: x.imag()) ....: if fld_in == fld_out and algo is None: ....: print("{} {}".format(fld_in, rts)) ....: for rt in rts: ....: assert(abs(f2(rt)) <= 1e-10) ....: assert(rt.parent() == fld_out) Real Field with 53 bits of precision [1.25992104989487] Real Double Field [1.25992104989...] Real Field with 100 bits of precision [1.2599210498948731647672106073] Complex Field with 53 bits of precision [-0.62996052494743... - 1.09112363597172*I, 1.25992104989487, -0.62996052494743... + 1.09112363597172*I] Complex Double Field [-0.629960524947... - 1.0911236359717...*I, 1.25992104989487..., -0.629960524947... + 1.0911236359717...*I] Complex Field with 100 bits of precision [-0.62996052494743658238360530364 - 1.0911236359717214035600726142*I, 1.2599210498948731647672106073, -0.62996052494743658238360530364 + 1.0911236359717214035600726142*I] - >>> from sage.all import * >>> # needs numpy sage.rings.complex_double sage.rings.real_mpfr >>> rflds = (RR, RDF, RealField(Integer(100))) >>> cflds = (CC, CDF, ComplexField(Integer(100))) >>> def cross(a, b): ... return list(cartesian_product_iterator([a, b])) >>> flds = cross(rflds, rflds) + cross(rflds, cflds) + cross(cflds, cflds) >>> for (fld_in, fld_out) in flds: ... x = polygen(fld_in) ... f = x**Integer(3) - fld_in(Integer(2)) ... x2 = polygen(fld_out) ... f2 = x2**Integer(3) - fld_out(Integer(2)) ... for algo in (None, 'pari', 'numpy'): ... rts = f.roots(ring=fld_out, multiplicities=False) ... rts = sorted(rts, key=lambda x: x.imag()) ... if fld_in == fld_out and algo is None: ... print("{} {}".format(fld_in, rts)) ... for rt in rts: ... assert(abs(f2(rt)) <= RealNumber('1e-10')) ... assert(rt.parent() == fld_out) Real Field with 53 bits of precision [1.25992104989487] Real Double Field [1.25992104989...] Real Field with 100 bits of precision [1.2599210498948731647672106073] Complex Field with 53 bits of precision [-0.62996052494743... - 1.09112363597172*I, 1.25992104989487, -0.62996052494743... + 1.09112363597172*I] Complex Double Field [-0.629960524947... - 1.0911236359717...*I, 1.25992104989487..., -0.629960524947... + 1.0911236359717...*I] Complex Field with 100 bits of precision [-0.62996052494743658238360530364 - 1.0911236359717214035600726142*I, 1.2599210498948731647672106073, -0.62996052494743658238360530364 + 1.0911236359717214035600726142*I] - Note that we can find the roots of a polynomial with algebraic coefficients: - sage: # needs sage.rings.number_field sage: rt2 = sqrt(AA(2)) sage: rt3 = sqrt(AA(3)) sage: x = polygen(AA) sage: f = (x - rt2) * (x - rt3); f x^2 - 3.146264369941973?*x + 2.449489742783178? sage: rts = f.roots(); rts [(1.414213562373095?, 1), (1.732050807568878?, 1)] sage: rts[0][0] == rt2 True sage: f.roots(ring=RealIntervalField(150)) [(1.414213562373095048801688724209698078569671875376948073176679738?, 1), (1.732050807568877293527446341505872366942805253810380628055806980?, 1)] - >>> from sage.all import * >>> # needs sage.rings.number_field >>> rt2 = sqrt(AA(Integer(2))) >>> rt3 = sqrt(AA(Integer(3))) >>> x = polygen(AA) >>> f = (x - rt2) * (x - rt3); f x^2 - 3.146264369941973?*x + 2.449489742783178? >>> rts = f.roots(); rts [(1.414213562373095?, 1), (1.732050807568878?, 1)] >>> rts[Integer(0)][Integer(0)] == rt2 True >>> f.roots(ring=RealIntervalField(Integer(150))) [(1.414213562373095048801688724209698078569671875376948073176679738?, 1), (1.732050807568877293527446341505872366942805253810380628055806980?, 1)] - We can handle polynomials with huge coefficients. - This number doesn’t even fit in an IEEE double-precision float, but - RRand- CCallow a much larger range of floating-point numbers:- sage: bigc = 2^1500 sage: CDF(bigc) # needs sage.rings.complex_double +infinity sage: CC(bigc) # needs sage.rings.real_mpfr 3.50746621104340e451 - >>> from sage.all import * >>> bigc = Integer(2)**Integer(1500) >>> CDF(bigc) # needs sage.rings.complex_double +infinity >>> CC(bigc) # needs sage.rings.real_mpfr 3.50746621104340e451 - Polynomials using such large coefficients can’t be handled by numpy, but pari can deal with them: - sage: x = polygen(QQ) sage: p = x + bigc sage: p.roots(ring=RR, algorithm='numpy') # needs numpy sage.rings.real_mpfr Traceback (most recent call last): ... LinAlgError: Array must not contain infs or NaNs sage: p.roots(ring=RR, algorithm='pari') # needs sage.libs.pari sage.rings.real_mpfr [(-3.50746621104340e451, 1)] sage: p.roots(ring=AA) # needs sage.rings.number_field [(-3.5074662110434039?e451, 1)] sage: p.roots(ring=QQbar) # needs sage.rings.number_field [(-3.5074662110434039?e451, 1)] sage: p = bigc*x + 1 sage: p.roots(ring=RR) # needs numpy [(-2.85106096489671e-452, 1)] sage: p.roots(ring=AA) # needs sage.rings.number_field [(-2.8510609648967059?e-452, 1)] sage: p.roots(ring=QQbar) # needs sage.rings.number_field [(-2.8510609648967059?e-452, 1)] sage: p = x^2 - bigc sage: p.roots(ring=RR) # needs numpy [(-5.92238652153286e225, 1), (5.92238652153286e225, 1)] sage: p.roots(ring=QQbar) # needs sage.rings.number_field [(-5.9223865215328558?e225, 1), (5.9223865215328558?e225, 1)] - >>> from sage.all import * >>> x = polygen(QQ) >>> p = x + bigc >>> p.roots(ring=RR, algorithm='numpy') # needs numpy sage.rings.real_mpfr Traceback (most recent call last): ... LinAlgError: Array must not contain infs or NaNs >>> p.roots(ring=RR, algorithm='pari') # needs sage.libs.pari sage.rings.real_mpfr [(-3.50746621104340e451, 1)] >>> p.roots(ring=AA) # needs sage.rings.number_field [(-3.5074662110434039?e451, 1)] >>> p.roots(ring=QQbar) # needs sage.rings.number_field [(-3.5074662110434039?e451, 1)] >>> p = bigc*x + Integer(1) >>> p.roots(ring=RR) # needs numpy [(-2.85106096489671e-452, 1)] >>> p.roots(ring=AA) # needs sage.rings.number_field [(-2.8510609648967059?e-452, 1)] >>> p.roots(ring=QQbar) # needs sage.rings.number_field [(-2.8510609648967059?e-452, 1)] >>> p = x**Integer(2) - bigc >>> p.roots(ring=RR) # needs numpy [(-5.92238652153286e225, 1), (5.92238652153286e225, 1)] >>> p.roots(ring=QQbar) # needs sage.rings.number_field [(-5.9223865215328558?e225, 1), (5.9223865215328558?e225, 1)] - Check that Issue #30522 is fixed: - sage: PolynomialRing(SR, names="x")("x^2").roots() # needs sage.symbolic [(0, 2)] - >>> from sage.all import * >>> PolynomialRing(SR, names="x")("x^2").roots() # needs sage.symbolic [(0, 2)] - Check that Issue #30523 is fixed: - sage: PolynomialRing(SR, names="x")("x^2 + q").roots() # needs sage.symbolic [(-sqrt(-q), 1), (sqrt(-q), 1)] - >>> from sage.all import * >>> PolynomialRing(SR, names="x")("x^2 + q").roots() # needs sage.symbolic [(-sqrt(-q), 1), (sqrt(-q), 1)] - ALGORITHM: - For brevity, we will use - RRto mean any- RealFieldof any precision; similarly for- RIF,- CC, and- CIF. Since Sage has no specific implementation of Gaussian rationals (or of number fields with embedding, at all), when we refer to Gaussian rationals below we will accept any number field with defining polynomial \(x^2+1\), mapping the field generator to +I.- We call the base ring of the polynomial \(K\), and the ring given by the - ringargument \(L\). (If- ringis not specified, then \(L\) is the same as \(K\).)- If \(K\) and \(L\) are floating-point ( - RDF,- CDF,- RR, or- CC), then a floating-point root-finder is used. If \(L\) is- RDFor- CDF, then we default to using NumPy’s- roots(); otherwise, we use PARI’s function pari:polroots. This choice can be overridden with- algorithm='pari'or- algorithm='numpy'. If the algorithm is unspecified and NumPy’s- roots()algorithm fails, then we fall back to PARI (NumPy will fail if some coefficient is infinite, for instance).- If \(L\) is - SR(or one of its subrings), then the roots will be radical expressions, computed as the solutions of a symbolic polynomial expression. At the moment this delegates to- sage.symbolic.expression.Expression.solve()which in turn uses Maxima to find radical solutions. Some solutions may be lost in this approach. Once Issue #17516 gets implemented, all possible radical solutions should become available.- If \(L\) is - AAor- RIF, and \(K\) is- ZZ,- QQ, or- AA, then the root isolation algorithm- sage.rings.polynomial.real_roots.real_roots()is used. (You can call- real_roots()directly to get more control than this method gives.)- If \(L\) is - QQbaror- CIF, and \(K\) is- ZZ,- QQ,- AA,- QQbar, or the Gaussian rationals, then the root isolation algorithm- sage.rings.polynomial.complex_roots.complex_roots()is used. (You can call- complex_roots()directly to get more control than this method gives.)- If \(L\) is - AAand \(K\) is- QQbaror the Gaussian rationals, then- complex_roots()is used (as above) to find roots in- QQbar, then these roots are filtered to select only the real roots.- If \(L\) is floating-point and \(K\) is not, then we attempt to change the polynomial ring to \(L\) (using - change_ring()) (or, if \(L\) is complex and \(K\) is not, to the corresponding real field). Then we use either PARI or NumPy as specified above.- For all other cases where \(K\) is different from \(L\), we attempt to use - .change_ring(L). When that fails but \(L\) is a subring of \(K\), we also attempt to compute the roots over \(K\) and filter the ones belonging to \(L\).- The next method, which is used if \(K\) is an integral domain, is to attempt to factor the polynomial. If this succeeds, then for every degree-one factor \(ax+b\), we add \(-b/a\) as a root (as long as this quotient is actually in the desired ring). - If factoring over \(K\) is not implemented (or \(K\) is not an integral domain), and \(K\) is finite, then we find the roots by enumerating all elements of \(K\) and checking whether the polynomial evaluates to zero at that value. - Note - We mentioned above that polynomials with multiple roots are always ill-conditioned; if your input is given to \(n\) bits of precision, you should not expect more than \(n/k\) good bits for a \(k\)-fold root. (You can get solutions that make the polynomial evaluate to a number very close to zero; basically the problem is that with a multiple root, there are many such numbers, and it’s difficult to choose between them.) - To see why this is true, consider the naive floating-point error analysis model where you just pretend that all floating-point numbers are somewhat imprecise - a little ‘fuzzy’, if you will. Then the graph of a floating-point polynomial will be a fuzzy line. Consider the graph of \((x-1)^3\); this will be a fuzzy line with a horizontal tangent at \(x=1\), \(y=0\). If the fuzziness extends up and down by about j, then it will extend left and right by about cube_root(j). 
 - shift(n)[source]¶
- Return this polynomial multiplied by the power \(x^n\). If \(n\) is negative, terms below \(x^n\) will be discarded. Does not change this polynomial (since polynomials are immutable). - EXAMPLES: - sage: R.<x> = QQ[] sage: p = x^2 + 2*x + 4 sage: p.shift(0) x^2 + 2*x + 4 sage: p.shift(-1) x + 2 sage: p.shift(-5) 0 sage: p.shift(2) x^4 + 2*x^3 + 4*x^2 - >>> from sage.all import * >>> R = QQ['x']; (x,) = R._first_ngens(1) >>> p = x**Integer(2) + Integer(2)*x + Integer(4) >>> p.shift(Integer(0)) x^2 + 2*x + 4 >>> p.shift(-Integer(1)) x + 2 >>> p.shift(-Integer(5)) 0 >>> p.shift(Integer(2)) x^4 + 2*x^3 + 4*x^2 - One can also use the infix shift operator: - sage: f = x^3 + x sage: f >> 2 x sage: f << 2 x^5 + x^3 - >>> from sage.all import * >>> f = x**Integer(3) + x >>> f >> Integer(2) x >>> f << Integer(2) x^5 + x^3 - AUTHORS: - David Harvey (2006-08-06) 
- Robert Bradshaw (2007-04-18): Added support for infix operator. 
 
 - specialization(D=None, phi=None)[source]¶
- Specialization of this polynomial. - Given a family of polynomials defined over a polynomial ring. A specialization is a particular member of that family. The specialization can be specified either by a dictionary or a - SpecializationMorphism.- INPUT: - D– dictionary (optional)
- phi–- SpecializationMorphism(optional)
 - OUTPUT: a new polynomial - EXAMPLES: - sage: R.<c> = PolynomialRing(ZZ) sage: S.<z> = PolynomialRing(R) sage: F = c*z^2 + c^2 sage: F.specialization({c:2}) 2*z^2 + 4 - >>> from sage.all import * >>> R = PolynomialRing(ZZ, names=('c',)); (c,) = R._first_ngens(1) >>> S = PolynomialRing(R, names=('z',)); (z,) = S._first_ngens(1) >>> F = c*z**Integer(2) + c**Integer(2) >>> F.specialization({c:Integer(2)}) 2*z^2 + 4 - sage: A.<c> = QQ[] sage: R.<x> = Frac(A)[] sage: X = (1 + x/c).specialization({c:20}) sage: X 1/20*x + 1 sage: X.parent() Univariate Polynomial Ring in x over Rational Field - >>> from sage.all import * >>> A = QQ['c']; (c,) = A._first_ngens(1) >>> R = Frac(A)['x']; (x,) = R._first_ngens(1) >>> X = (Integer(1) + x/c).specialization({c:Integer(20)}) >>> X 1/20*x + 1 >>> X.parent() Univariate Polynomial Ring in x over Rational Field 
 - splitting_field(names=None, map=False, **kwds)[source]¶
- Compute the absolute splitting field of a given polynomial. - INPUT: - names– (default:- None) a variable name for the splitting field
- map– boolean (default:- False); also return an embedding of- selfinto the resulting field
- kwds– additional keywords depending on the type. Currently, only number fields are implemented. See- sage.rings.number_field.splitting_field.splitting_field()for the documentation of these keywords.
 - OUTPUT: - If - mapis- False, the splitting field as an absolute field. If- mapis- True, a tuple- (K, phi)where- phiis an embedding of the base field of- selfin- K.- EXAMPLES: - sage: R.<x> = PolynomialRing(ZZ) sage: K.<a> = (x^3 + 2).splitting_field(); K # needs sage.rings.number_field Number Field in a with defining polynomial x^6 + 3*x^5 + 6*x^4 + 11*x^3 + 12*x^2 - 3*x + 1 sage: K.<a> = (x^3 - 3*x + 1).splitting_field(); K # needs sage.rings.number_field Number Field in a with defining polynomial x^3 - 3*x + 1 - >>> from sage.all import * >>> R = PolynomialRing(ZZ, names=('x',)); (x,) = R._first_ngens(1) >>> K = (x**Integer(3) + Integer(2)).splitting_field(names=('a',)); (a,) = K._first_ngens(1); K # needs sage.rings.number_field Number Field in a with defining polynomial x^6 + 3*x^5 + 6*x^4 + 11*x^3 + 12*x^2 - 3*x + 1 >>> K = (x**Integer(3) - Integer(3)*x + Integer(1)).splitting_field(names=('a',)); (a,) = K._first_ngens(1); K # needs sage.rings.number_field Number Field in a with defining polynomial x^3 - 3*x + 1 - Relative situation: - sage: # needs sage.rings.number_field sage: R.<x> = PolynomialRing(QQ) sage: K.<a> = NumberField(x^3 + 2) sage: S.<t> = PolynomialRing(K) sage: L.<b> = (t^2 - a).splitting_field() sage: L Number Field in b with defining polynomial t^6 + 2 - >>> from sage.all import * >>> # needs sage.rings.number_field >>> R = PolynomialRing(QQ, names=('x',)); (x,) = R._first_ngens(1) >>> K = NumberField(x**Integer(3) + Integer(2), names=('a',)); (a,) = K._first_ngens(1) >>> S = PolynomialRing(K, names=('t',)); (t,) = S._first_ngens(1) >>> L = (t**Integer(2) - a).splitting_field(names=('b',)); (b,) = L._first_ngens(1) >>> L Number Field in b with defining polynomial t^6 + 2 - With - map=True, we also get the embedding of the base field into the splitting field:- sage: L.<b>, phi = (t^2 - a).splitting_field(map=True) # needs sage.rings.number_field sage: phi # needs sage.rings.number_field Ring morphism: From: Number Field in a with defining polynomial x^3 + 2 To: Number Field in b with defining polynomial t^6 + 2 Defn: a |--> b^2 - >>> from sage.all import * >>> L, phi = (t**Integer(2) - a).splitting_field(map=True, names=('b',)); (b,) = L._first_ngens(1)# needs sage.rings.number_field >>> phi # needs sage.rings.number_field Ring morphism: From: Number Field in a with defining polynomial x^3 + 2 To: Number Field in b with defining polynomial t^6 + 2 Defn: a |--> b^2 - An example over a finite field: - sage: P.<x> = PolynomialRing(GF(7)) sage: t = x^2 + 1 sage: t.splitting_field('b') # needs sage.rings.finite_rings Finite Field in b of size 7^2 sage: P.<x> = PolynomialRing(GF(7^3, 'a')) # needs sage.rings.finite_rings sage: t = x^2 + 1 sage: t.splitting_field('b', map=True) # needs sage.rings.finite_rings (Finite Field in b of size 7^6, Ring morphism: From: Finite Field in a of size 7^3 To: Finite Field in b of size 7^6 Defn: a |--> 2*b^4 + 6*b^3 + 2*b^2 + 3*b + 2) - >>> from sage.all import * >>> P = PolynomialRing(GF(Integer(7)), names=('x',)); (x,) = P._first_ngens(1) >>> t = x**Integer(2) + Integer(1) >>> t.splitting_field('b') # needs sage.rings.finite_rings Finite Field in b of size 7^2 >>> P = PolynomialRing(GF(Integer(7)**Integer(3), 'a'), names=('x',)); (x,) = P._first_ngens(1)# needs sage.rings.finite_rings >>> t = x**Integer(2) + Integer(1) >>> t.splitting_field('b', map=True) # needs sage.rings.finite_rings (Finite Field in b of size 7^6, Ring morphism: From: Finite Field in a of size 7^3 To: Finite Field in b of size 7^6 Defn: a |--> 2*b^4 + 6*b^3 + 2*b^2 + 3*b + 2) - If the extension is trivial and the generators have the same name, the map will be the identity: - sage: t = 24*x^13 + 2*x^12 + 14 sage: t.splitting_field('a', map=True) # needs sage.rings.finite_rings (Finite Field in a of size 7^3, Identity endomorphism of Finite Field in a of size 7^3) sage: t = x^56 - 14*x^3 sage: t.splitting_field('b', map=True) # needs sage.rings.finite_rings (Finite Field in b of size 7^3, Ring morphism: From: Finite Field in a of size 7^3 To: Finite Field in b of size 7^3 Defn: a |--> b) - >>> from sage.all import * >>> t = Integer(24)*x**Integer(13) + Integer(2)*x**Integer(12) + Integer(14) >>> t.splitting_field('a', map=True) # needs sage.rings.finite_rings (Finite Field in a of size 7^3, Identity endomorphism of Finite Field in a of size 7^3) >>> t = x**Integer(56) - Integer(14)*x**Integer(3) >>> t.splitting_field('b', map=True) # needs sage.rings.finite_rings (Finite Field in b of size 7^3, Ring morphism: From: Finite Field in a of size 7^3 To: Finite Field in b of size 7^3 Defn: a |--> b) - See also - sage.rings.number_field.splitting_field.splitting_field()for more examples over number fields
 - square()[source]¶
- Return the square of this polynomial. - Todo - This is just a placeholder; for now it just uses ordinary multiplication. But generally speaking, squaring is faster than ordinary multiplication, and it’s frequently used, so subclasses may choose to provide a specialised squaring routine. 
- Perhaps this even belongs at a lower level? RingElement or something? 
 - AUTHORS: - David Harvey (2006-09-09) 
 - EXAMPLES: - sage: R.<x> = QQ[] sage: f = x^3 + 1 sage: f.square() x^6 + 2*x^3 + 1 sage: f*f x^6 + 2*x^3 + 1 - >>> from sage.all import * >>> R = QQ['x']; (x,) = R._first_ngens(1) >>> f = x**Integer(3) + Integer(1) >>> f.square() x^6 + 2*x^3 + 1 >>> f*f x^6 + 2*x^3 + 1 
 - squarefree_decomposition()[source]¶
- Return the square-free decomposition of this polynomial. This is a partial factorization into square-free, coprime polynomials. - EXAMPLES: - sage: x = polygen(QQ) sage: p = 37 * (x - 1)^3 * (x - 2)^3 * (x - 1/3)^7 * (x - 3/7) sage: p.squarefree_decomposition() (37*x - 111/7) * (x^2 - 3*x + 2)^3 * (x - 1/3)^7 sage: p = 37 * (x - 2/3)^2 sage: p.squarefree_decomposition() (37) * (x - 2/3)^2 sage: x = polygen(GF(3)) sage: x.squarefree_decomposition() x sage: f = QQbar['x'](1) # needs sage.rings.number_field sage: f.squarefree_decomposition() # needs sage.rings.number_field 1 - >>> from sage.all import * >>> x = polygen(QQ) >>> p = Integer(37) * (x - Integer(1))**Integer(3) * (x - Integer(2))**Integer(3) * (x - Integer(1)/Integer(3))**Integer(7) * (x - Integer(3)/Integer(7)) >>> p.squarefree_decomposition() (37*x - 111/7) * (x^2 - 3*x + 2)^3 * (x - 1/3)^7 >>> p = Integer(37) * (x - Integer(2)/Integer(3))**Integer(2) >>> p.squarefree_decomposition() (37) * (x - 2/3)^2 >>> x = polygen(GF(Integer(3))) >>> x.squarefree_decomposition() x >>> f = QQbar['x'](Integer(1)) # needs sage.rings.number_field >>> f.squarefree_decomposition() # needs sage.rings.number_field 1 
 - subresultants(other)[source]¶
- Return the nonzero subresultant polynomials of - selfand- other.- INPUT: - other– a polynomial
 - OUTPUT: list of polynomials in the same ring as - self- EXAMPLES: - sage: R.<x> = ZZ[] sage: f = x^8 + x^6 - 3*x^4 - 3*x^3 + 8*x^2 + 2*x - 5 sage: g = 3*x^6 + 5*x^4 - 4*x^2 - 9*x + 21 sage: f.subresultants(g) [260708, 9326*x - 12300, 169*x^2 + 325*x - 637, 65*x^2 + 125*x - 245, 25*x^4 - 5*x^2 + 15, 15*x^4 - 3*x^2 + 9] - >>> from sage.all import * >>> R = ZZ['x']; (x,) = R._first_ngens(1) >>> f = x**Integer(8) + x**Integer(6) - Integer(3)*x**Integer(4) - Integer(3)*x**Integer(3) + Integer(8)*x**Integer(2) + Integer(2)*x - Integer(5) >>> g = Integer(3)*x**Integer(6) + Integer(5)*x**Integer(4) - Integer(4)*x**Integer(2) - Integer(9)*x + Integer(21) >>> f.subresultants(g) [260708, 9326*x - 12300, 169*x^2 + 325*x - 637, 65*x^2 + 125*x - 245, 25*x^4 - 5*x^2 + 15, 15*x^4 - 3*x^2 + 9] - ALGORITHM: - We use the schoolbook algorithm with Lazard’s optimization described in [Duc1998] - REFERENCES: - Wikipedia article Polynomial_greatest_common_divisor#Subresultants 
 - subs(in_dict=None, *args, **kwds)[source]¶
- Substitute the variable in - self.- EXAMPLES: - sage: R.<x> = QQ[] sage: f = x^3 + x - 3 sage: f.subs(x=5) 127 sage: f.subs(5) 127 sage: f.subs({x:2}) 7 sage: f.subs({}) x^3 + x - 3 sage: f.subs({'x':2}) Traceback (most recent call last): ... TypeError: keys do not match self's parent - >>> from sage.all import * >>> R = QQ['x']; (x,) = R._first_ngens(1) >>> f = x**Integer(3) + x - Integer(3) >>> f.subs(x=Integer(5)) 127 >>> f.subs(Integer(5)) 127 >>> f.subs({x:Integer(2)}) 7 >>> f.subs({}) x^3 + x - 3 >>> f.subs({'x':Integer(2)}) Traceback (most recent call last): ... TypeError: keys do not match self's parent 
 - sylvester_matrix(right, variable=None)[source]¶
- Return the Sylvester matrix of - selfand- right.- Note that the Sylvester matrix is not defined if one of the polynomials is zero. - INPUT: - right– a polynomial in the same ring as- self
- variable– (optional) included for compatibility with the multivariate case only; the variable of the polynomials
 - EXAMPLES: - sage: R.<x> = PolynomialRing(ZZ) sage: f = (6*x + 47) * (7*x^2 - 2*x + 38) sage: g = (6*x + 47) * (3*x^3 + 2*x + 1) sage: M = f.sylvester_matrix(g); M # needs sage.modules [ 42 317 134 1786 0 0 0] [ 0 42 317 134 1786 0 0] [ 0 0 42 317 134 1786 0] [ 0 0 0 42 317 134 1786] [ 18 141 12 100 47 0 0] [ 0 18 141 12 100 47 0] [ 0 0 18 141 12 100 47] - >>> from sage.all import * >>> R = PolynomialRing(ZZ, names=('x',)); (x,) = R._first_ngens(1) >>> f = (Integer(6)*x + Integer(47)) * (Integer(7)*x**Integer(2) - Integer(2)*x + Integer(38)) >>> g = (Integer(6)*x + Integer(47)) * (Integer(3)*x**Integer(3) + Integer(2)*x + Integer(1)) >>> M = f.sylvester_matrix(g); M # needs sage.modules [ 42 317 134 1786 0 0 0] [ 0 42 317 134 1786 0 0] [ 0 0 42 317 134 1786 0] [ 0 0 0 42 317 134 1786] [ 18 141 12 100 47 0 0] [ 0 18 141 12 100 47 0] [ 0 0 18 141 12 100 47] - If the polynomials share a non-constant common factor then the determinant of the Sylvester matrix will be zero: - sage: M.determinant() # needs sage.modules 0 - >>> from sage.all import * >>> M.determinant() # needs sage.modules 0 - If - selfand- rightare polynomials of positive degree, the determinant of the Sylvester matrix is the resultant of the polynomials.:- sage: h1 = R._random_nonzero_element() sage: h2 = R._random_nonzero_element() sage: M1 = h1.sylvester_matrix(h2) # needs sage.modules sage: M1.determinant() == h1.resultant(h2) # needs sage.libs.pari sage.modules True - >>> from sage.all import * >>> h1 = R._random_nonzero_element() >>> h2 = R._random_nonzero_element() >>> M1 = h1.sylvester_matrix(h2) # needs sage.modules >>> M1.determinant() == h1.resultant(h2) # needs sage.libs.pari sage.modules True - The rank of the Sylvester matrix is related to the degree of the gcd of - selfand- right:- sage: f.gcd(g).degree() == f.degree() + g.degree() - M.rank() # needs sage.modules True sage: h1.gcd(h2).degree() == h1.degree() + h2.degree() - M1.rank() # needs sage.modules True - >>> from sage.all import * >>> f.gcd(g).degree() == f.degree() + g.degree() - M.rank() # needs sage.modules True >>> h1.gcd(h2).degree() == h1.degree() + h2.degree() - M1.rank() # needs sage.modules True 
 - symmetric_power(k, monic=False)[source]¶
- Return the polynomial whose roots are products of \(k\)-th distinct roots of this. - EXAMPLES: - sage: x = polygen(QQ) sage: f = x^4 - x + 2 sage: [f.symmetric_power(k) for k in range(5)] # needs sage.libs.singular [x - 1, x^4 - x + 2, x^6 - 2*x^4 - x^3 - 4*x^2 + 8, x^4 - x^3 + 8, x - 2] sage: f = x^5 - 2*x + 2 sage: [f.symmetric_power(k) for k in range(6)] # needs sage.libs.singular [x - 1, x^5 - 2*x + 2, x^10 + 2*x^8 - 4*x^6 - 8*x^5 - 8*x^4 - 8*x^3 + 16, x^10 + 4*x^7 - 8*x^6 + 16*x^5 - 16*x^4 + 32*x^2 + 64, x^5 + 2*x^4 - 16, x + 2] sage: R.<a,b,c,d> = ZZ[] sage: x = polygen(R) sage: f = (x - a) * (x - b) * (x - c) * (x - d) sage: [f.symmetric_power(k).factor() for k in range(5)] # needs sage.libs.singular [x - 1, (-x + d) * (-x + c) * (-x + b) * (-x + a), (x - a*b) * (x - a*c) * (x - b*c) * (x - a*d) * (x - b*d) * (x - c*d), (x - a*b*c) * (x - a*b*d) * (x - a*c*d) * (x - b*c*d), x - a*b*c*d] - >>> from sage.all import * >>> x = polygen(QQ) >>> f = x**Integer(4) - x + Integer(2) >>> [f.symmetric_power(k) for k in range(Integer(5))] # needs sage.libs.singular [x - 1, x^4 - x + 2, x^6 - 2*x^4 - x^3 - 4*x^2 + 8, x^4 - x^3 + 8, x - 2] >>> f = x**Integer(5) - Integer(2)*x + Integer(2) >>> [f.symmetric_power(k) for k in range(Integer(6))] # needs sage.libs.singular [x - 1, x^5 - 2*x + 2, x^10 + 2*x^8 - 4*x^6 - 8*x^5 - 8*x^4 - 8*x^3 + 16, x^10 + 4*x^7 - 8*x^6 + 16*x^5 - 16*x^4 + 32*x^2 + 64, x^5 + 2*x^4 - 16, x + 2] >>> R = ZZ['a, b, c, d']; (a, b, c, d,) = R._first_ngens(4) >>> x = polygen(R) >>> f = (x - a) * (x - b) * (x - c) * (x - d) >>> [f.symmetric_power(k).factor() for k in range(Integer(5))] # needs sage.libs.singular [x - 1, (-x + d) * (-x + c) * (-x + b) * (-x + a), (x - a*b) * (x - a*c) * (x - b*c) * (x - a*d) * (x - b*d) * (x - c*d), (x - a*b*c) * (x - a*b*d) * (x - a*c*d) * (x - b*c*d), x - a*b*c*d] 
 - trace_polynomial()[source]¶
- Compute the trace polynomial and cofactor. - The input \(P\) and output \(Q\) satisfy the relation \[P(x) = Q(x + q/x) x^{\deg(Q)} R(x).\]- In this relation, \(Q\) has all roots in the real interval \([-2\sqrt{q}, 2\sqrt{q}]\) if and only if \(P\) has all roots on the circle \(|x| = \sqrt{q}\) and \(R\) divides \(x^2-q\). We thus require that the base ring of this polynomial have a coercion to the real numbers. - See also - The inverse operation is - reciprocal_transform().- OUTPUT: - Q– trace polynomial
- R– cofactor
- q– scaling factor
 - EXAMPLES: - sage: pol.<x> = PolynomialRing(Rationals()) sage: u = x^5 - 1; u.trace_polynomial() (x^2 + x - 1, x - 1, 1) sage: u = x^4 + x^3 + 5*x^2 + 3*x + 9 sage: u.trace_polynomial() (x^2 + x - 1, 1, 3) - >>> from sage.all import * >>> pol = PolynomialRing(Rationals(), names=('x',)); (x,) = pol._first_ngens(1) >>> u = x**Integer(5) - Integer(1); u.trace_polynomial() (x^2 + x - 1, x - 1, 1) >>> u = x**Integer(4) + x**Integer(3) + Integer(5)*x**Integer(2) + Integer(3)*x + Integer(9) >>> u.trace_polynomial() (x^2 + x - 1, 1, 3) - We check that this function works for rings that have a coercion to the reals: - sage: # needs sage.rings.number_field sage: K.<a> = NumberField(x^2 - 2, embedding=1.4) sage: u = x^4 + a*x^3 + 3*x^2 + 2*a*x + 4 sage: u.trace_polynomial() (x^2 + a*x - 1, 1, 2) sage: (u*(x^2-2)).trace_polynomial() (x^2 + a*x - 1, x^2 - 2, 2) sage: (u*(x^2-2)^2).trace_polynomial() (x^4 + a*x^3 - 9*x^2 - 8*a*x + 8, 1, 2) sage: (u*(x^2-2)^3).trace_polynomial() (x^4 + a*x^3 - 9*x^2 - 8*a*x + 8, x^2 - 2, 2) sage: u = x^4 + a*x^3 + 3*x^2 + 4*a*x + 16 sage: u.trace_polynomial() (x^2 + a*x - 5, 1, 4) sage: (u*(x-2)).trace_polynomial() (x^2 + a*x - 5, x - 2, 4) sage: (u*(x+2)).trace_polynomial() (x^2 + a*x - 5, x + 2, 4) - >>> from sage.all import * >>> # needs sage.rings.number_field >>> K = NumberField(x**Integer(2) - Integer(2), embedding=RealNumber('1.4'), names=('a',)); (a,) = K._first_ngens(1) >>> u = x**Integer(4) + a*x**Integer(3) + Integer(3)*x**Integer(2) + Integer(2)*a*x + Integer(4) >>> u.trace_polynomial() (x^2 + a*x - 1, 1, 2) >>> (u*(x**Integer(2)-Integer(2))).trace_polynomial() (x^2 + a*x - 1, x^2 - 2, 2) >>> (u*(x**Integer(2)-Integer(2))**Integer(2)).trace_polynomial() (x^4 + a*x^3 - 9*x^2 - 8*a*x + 8, 1, 2) >>> (u*(x**Integer(2)-Integer(2))**Integer(3)).trace_polynomial() (x^4 + a*x^3 - 9*x^2 - 8*a*x + 8, x^2 - 2, 2) >>> u = x**Integer(4) + a*x**Integer(3) + Integer(3)*x**Integer(2) + Integer(4)*a*x + Integer(16) >>> u.trace_polynomial() (x^2 + a*x - 5, 1, 4) >>> (u*(x-Integer(2))).trace_polynomial() (x^2 + a*x - 5, x - 2, 4) >>> (u*(x+Integer(2))).trace_polynomial() (x^2 + a*x - 5, x + 2, 4) 
 - truncate(n)[source]¶
- Return the polynomial of degree \(< n\) which is equivalent to - selfmodulo \(x^n\).- EXAMPLES: - sage: R.<x> = ZZ[]; S.<y> = PolynomialRing(R, sparse=True) sage: f = y^3 + x*y - 3*x; f y^3 + x*y - 3*x sage: f.truncate(2) x*y - 3*x sage: f.truncate(1) -3*x sage: f.truncate(0) 0 - >>> from sage.all import * >>> R = ZZ['x']; (x,) = R._first_ngens(1); S = PolynomialRing(R, sparse=True, names=('y',)); (y,) = S._first_ngens(1) >>> f = y**Integer(3) + x*y - Integer(3)*x; f y^3 + x*y - 3*x >>> f.truncate(Integer(2)) x*y - 3*x >>> f.truncate(Integer(1)) -3*x >>> f.truncate(Integer(0)) 0 
 - valuation(p=None)[source]¶
- If \(f = a_r x^r + a_{r+1}x^{r+1} + \cdots\), with \(a_r\) nonzero, then the valuation of \(f\) is \(r\). The valuation of the zero polynomial is \(\infty\). - If a prime (or non-prime) \(p\) is given, then the valuation is the largest power of \(p\) which divides - self.- The valuation at \(\infty\) is - -self.degree().- EXAMPLES: - sage: P.<x> = ZZ[] sage: (x^2 + x).valuation() 1 sage: (x^2 + x).valuation(x + 1) 1 sage: (x^2 + 1).valuation() 0 sage: (x^3 + 1).valuation(infinity) -3 sage: P(0).valuation() +Infinity - >>> from sage.all import * >>> P = ZZ['x']; (x,) = P._first_ngens(1) >>> (x**Integer(2) + x).valuation() 1 >>> (x**Integer(2) + x).valuation(x + Integer(1)) 1 >>> (x**Integer(2) + Integer(1)).valuation() 0 >>> (x**Integer(3) + Integer(1)).valuation(infinity) -3 >>> P(Integer(0)).valuation() +Infinity 
 - variable_name()[source]¶
- Return name of variable used in this polynomial as a string. - OUTPUT: string - EXAMPLES: - sage: R.<t> = QQ[] sage: f = t^3 + 3/2*t + 5 sage: f.variable_name() 't' - >>> from sage.all import * >>> R = QQ['t']; (t,) = R._first_ngens(1) >>> f = t**Integer(3) + Integer(3)/Integer(2)*t + Integer(5) >>> f.variable_name() 't' 
 - variables()[source]¶
- Return the tuple of variables occurring in this polynomial. - EXAMPLES: - sage: R.<x> = QQ[] sage: x.variables() (x,) - >>> from sage.all import * >>> R = QQ['x']; (x,) = R._first_ngens(1) >>> x.variables() (x,) - A constant polynomial has no variables. - sage: R(2).variables() () - >>> from sage.all import * >>> R(Integer(2)).variables() () 
 - xgcd(other)[source]¶
- Return an extended gcd of this polynomial and - other.- INPUT: - other– a polynomial in the same ring as this polynomial
 - OUTPUT: - A tuple - (r, s, t)where- ris a greatest common divisor of this polynomial and- other, and- sand- tare such that- r = s*self + t*otherholds.- Note - The actual algorithm for computing the extended gcd depends on the base ring underlying the polynomial ring. If the base ring defines a method - _xgcd_univariate_polynomial(), then this method will be called (see examples below).- EXAMPLES: - sage: # needs sage.rings.number_field sage: R.<x> = QQbar[] sage: (2*x^2).gcd(2*x) x sage: R.zero().gcd(0) 0 sage: (2*x).gcd(0) x - >>> from sage.all import * >>> # needs sage.rings.number_field >>> R = QQbar['x']; (x,) = R._first_ngens(1) >>> (Integer(2)*x**Integer(2)).gcd(Integer(2)*x) x >>> R.zero().gcd(Integer(0)) 0 >>> (Integer(2)*x).gcd(Integer(0)) x - One can easily add xgcd functionality to new rings by providing a method - _xgcd_univariate_polynomial():- sage: R.<x> = QQ[] sage: S.<y> = R[] sage: h1 = y*x sage: h2 = y^2*x^2 sage: h1.xgcd(h2) Traceback (most recent call last): ... NotImplementedError: Univariate Polynomial Ring in x over Rational Field does not provide an xgcd implementation for univariate polynomials sage: T.<x,y> = QQ[] sage: def poor_xgcd(f, g): ....: ret = S(T(f).gcd(g)) ....: if ret == f: return ret, S.one(), S.zero() ....: if ret == g: return ret, S.zero(), S.one() ....: raise NotImplementedError sage: R._xgcd_univariate_polynomial = poor_xgcd sage: h1.xgcd(h2) (x*y, 1, 0) sage: del R._xgcd_univariate_polynomial - >>> from sage.all import * >>> R = QQ['x']; (x,) = R._first_ngens(1) >>> S = R['y']; (y,) = S._first_ngens(1) >>> h1 = y*x >>> h2 = y**Integer(2)*x**Integer(2) >>> h1.xgcd(h2) Traceback (most recent call last): ... NotImplementedError: Univariate Polynomial Ring in x over Rational Field does not provide an xgcd implementation for univariate polynomials >>> T = QQ['x, y']; (x, y,) = T._first_ngens(2) >>> def poor_xgcd(f, g): ... ret = S(T(f).gcd(g)) ... if ret == f: return ret, S.one(), S.zero() ... if ret == g: return ret, S.zero(), S.one() ... raise NotImplementedError >>> R._xgcd_univariate_polynomial = poor_xgcd >>> h1.xgcd(h2) (x*y, 1, 0) >>> del R._xgcd_univariate_polynomial 
 
- class sage.rings.polynomial.polynomial_element.PolynomialBaseringInjection[source]¶
- Bases: - Morphism- This class is used for conversion from a ring to a polynomial over that ring. - It calls the - _new_constant_poly()method on the generator, which should be optimized for a particular polynomial type.- Technically, it should be a method of the polynomial ring, but few polynomial rings are Cython classes, and so, as a method of a Cython polynomial class, it is faster. - EXAMPLES: - We demonstrate that most polynomial ring classes use polynomial base injection maps for coercion. They are supposed to be the fastest maps for that purpose. See Issue #9944. - sage: # needs sage.rings.padics sage: R.<x> = Qp(3)[] sage: R.coerce_map_from(R.base_ring()) Polynomial base injection morphism: From: 3-adic Field with capped relative precision 20 To: Univariate Polynomial Ring in x over 3-adic Field with capped relative precision 20 sage: R.<x,y> = Qp(3)[] sage: R.coerce_map_from(R.base_ring()) Polynomial base injection morphism: From: 3-adic Field with capped relative precision 20 To: Multivariate Polynomial Ring in x, y over 3-adic Field with capped relative precision 20 sage: R.<x,y> = QQ[] sage: R.coerce_map_from(R.base_ring()) Polynomial base injection morphism: From: Rational Field To: Multivariate Polynomial Ring in x, y over Rational Field sage: R.<x> = QQ[] sage: R.coerce_map_from(R.base_ring()) Polynomial base injection morphism: From: Rational Field To: Univariate Polynomial Ring in x over Rational Field - >>> from sage.all import * >>> # needs sage.rings.padics >>> R = Qp(Integer(3))['x']; (x,) = R._first_ngens(1) >>> R.coerce_map_from(R.base_ring()) Polynomial base injection morphism: From: 3-adic Field with capped relative precision 20 To: Univariate Polynomial Ring in x over 3-adic Field with capped relative precision 20 >>> R = Qp(Integer(3))['x, y']; (x, y,) = R._first_ngens(2) >>> R.coerce_map_from(R.base_ring()) Polynomial base injection morphism: From: 3-adic Field with capped relative precision 20 To: Multivariate Polynomial Ring in x, y over 3-adic Field with capped relative precision 20 >>> R = QQ['x, y']; (x, y,) = R._first_ngens(2) >>> R.coerce_map_from(R.base_ring()) Polynomial base injection morphism: From: Rational Field To: Multivariate Polynomial Ring in x, y over Rational Field >>> R = QQ['x']; (x,) = R._first_ngens(1) >>> R.coerce_map_from(R.base_ring()) Polynomial base injection morphism: From: Rational Field To: Univariate Polynomial Ring in x over Rational Field - By Issue #9944, there are now only very few exceptions: - sage: PolynomialRing(QQ,names=[]).coerce_map_from(QQ) Call morphism: From: Rational Field To: Multivariate Polynomial Ring in no variables over Rational Field - >>> from sage.all import * >>> PolynomialRing(QQ,names=[]).coerce_map_from(QQ) Call morphism: From: Rational Field To: Multivariate Polynomial Ring in no variables over Rational Field - is_injective()[source]¶
- Return whether this morphism is injective. - EXAMPLES: - sage: R.<x> = ZZ[] sage: S.<y> = R[] sage: S.coerce_map_from(R).is_injective() True - >>> from sage.all import * >>> R = ZZ['x']; (x,) = R._first_ngens(1) >>> S = R['y']; (y,) = S._first_ngens(1) >>> S.coerce_map_from(R).is_injective() True - Check that Issue #23203 has been resolved: - sage: R.is_subring(S) # indirect doctest True - >>> from sage.all import * >>> R.is_subring(S) # indirect doctest True 
 
- class sage.rings.polynomial.polynomial_element.Polynomial_generic_dense[source]¶
- Bases: - Polynomial- A generic dense polynomial. - EXAMPLES: - sage: f = QQ['x']['y'].random_element() sage: loads(f.dumps()) == f True - >>> from sage.all import * >>> f = QQ['x']['y'].random_element() >>> loads(f.dumps()) == f True - constant_coefficient()[source]¶
- Return the constant coefficient of this polynomial. - OUTPUT: element of base ring - EXAMPLES: - sage: R.<t> = QQ[] sage: S.<x> = R[] sage: f = x*t + x + t sage: f.constant_coefficient() t - >>> from sage.all import * >>> R = QQ['t']; (t,) = R._first_ngens(1) >>> S = R['x']; (x,) = S._first_ngens(1) >>> f = x*t + x + t >>> f.constant_coefficient() t 
 - degree(gen=None)[source]¶
- EXAMPLES: - sage: R.<x> = RDF[] sage: f = (1+2*x^7)^5 sage: f.degree() 35 - >>> from sage.all import * >>> R = RDF['x']; (x,) = R._first_ngens(1) >>> f = (Integer(1)+Integer(2)*x**Integer(7))**Integer(5) >>> f.degree() 35 
 - is_term()[source]¶
- Return - Trueif this polynomial is a nonzero element of the base ring times a power of the variable.- EXAMPLES: - sage: # needs sage.symbolic sage: R.<x> = SR[] sage: R(0).is_term() False sage: R(1).is_term() True sage: (3*x^5).is_term() True sage: (1 + 3*x^5).is_term() False - >>> from sage.all import * >>> # needs sage.symbolic >>> R = SR['x']; (x,) = R._first_ngens(1) >>> R(Integer(0)).is_term() False >>> R(Integer(1)).is_term() True >>> (Integer(3)*x**Integer(5)).is_term() True >>> (Integer(1) + Integer(3)*x**Integer(5)).is_term() False 
 - list(copy=True)[source]¶
- Return a new copy of the list of the underlying elements of - self.- EXAMPLES: - sage: R.<x> = GF(17)[] sage: f = (1+2*x)^3 + 3*x; f 8*x^3 + 12*x^2 + 9*x + 1 sage: f.list() [1, 9, 12, 8] - >>> from sage.all import * >>> R = GF(Integer(17))['x']; (x,) = R._first_ngens(1) >>> f = (Integer(1)+Integer(2)*x)**Integer(3) + Integer(3)*x; f 8*x^3 + 12*x^2 + 9*x + 1 >>> f.list() [1, 9, 12, 8] 
 - quo_rem(other)[source]¶
- Return the quotient and remainder of the Euclidean division of - selfand- other.- Raises a - ZeroDivisionErrorif- otheris zero. Raises an- ArithmeticErrorif the division is not exact.- EXAMPLES: - sage: P.<x> = QQ[] sage: R.<y> = P[] sage: f = y^10 + R.random_element(9) sage: g = y^5 + R.random_element(4) sage: q, r = f.quo_rem(g) sage: f == q*g + r True sage: g = x*y^5 sage: f.quo_rem(g) Traceback (most recent call last): ... ArithmeticError: division non exact (consider coercing to polynomials over the fraction field) sage: g = 0 sage: f.quo_rem(g) Traceback (most recent call last): ... ZeroDivisionError: division by zero polynomial - >>> from sage.all import * >>> P = QQ['x']; (x,) = P._first_ngens(1) >>> R = P['y']; (y,) = R._first_ngens(1) >>> f = y**Integer(10) + R.random_element(Integer(9)) >>> g = y**Integer(5) + R.random_element(Integer(4)) >>> q, r = f.quo_rem(g) >>> f == q*g + r True >>> g = x*y**Integer(5) >>> f.quo_rem(g) Traceback (most recent call last): ... ArithmeticError: division non exact (consider coercing to polynomials over the fraction field) >>> g = Integer(0) >>> f.quo_rem(g) Traceback (most recent call last): ... ZeroDivisionError: division by zero polynomial - Polynomials over noncommutative rings are also allowed (after Issue #34733): - sage: # needs sage.combinat sage.modules sage: HH = QuaternionAlgebra(QQ, -1, -1) sage: P.<x> = HH[] sage: f = P.random_element(5) sage: g = P.random_element((0, 5)) sage: q, r = f.quo_rem(g) sage: f == q*g + r True - >>> from sage.all import * >>> # needs sage.combinat sage.modules >>> HH = QuaternionAlgebra(QQ, -Integer(1), -Integer(1)) >>> P = HH['x']; (x,) = P._first_ngens(1) >>> f = P.random_element(Integer(5)) >>> g = P.random_element((Integer(0), Integer(5))) >>> q, r = f.quo_rem(g) >>> f == q*g + r True 
 - shift(n)[source]¶
- Return this polynomial multiplied by the power \(x^n\). - If \(n\) is negative, terms below \(x^n\) will be discarded. Does not change this polynomial. - EXAMPLES: - sage: R.<x> = PolynomialRing(PolynomialRing(QQ,'y'), 'x') sage: p = x^2 + 2*x + 4 sage: type(p) <class 'sage.rings.polynomial.polynomial_element.Polynomial_generic_dense'> sage: p.shift(0) x^2 + 2*x + 4 sage: p.shift(-1) x + 2 sage: p.shift(2) x^4 + 2*x^3 + 4*x^2 - >>> from sage.all import * >>> R = PolynomialRing(PolynomialRing(QQ,'y'), 'x', names=('x',)); (x,) = R._first_ngens(1) >>> p = x**Integer(2) + Integer(2)*x + Integer(4) >>> type(p) <class 'sage.rings.polynomial.polynomial_element.Polynomial_generic_dense'> >>> p.shift(Integer(0)) x^2 + 2*x + 4 >>> p.shift(-Integer(1)) x + 2 >>> p.shift(Integer(2)) x^4 + 2*x^3 + 4*x^2 - AUTHORS: - David Harvey (2006-08-06) 
 
 - truncate(n)[source]¶
- Return the polynomial of degree \(< n\) which is equivalent to - selfmodulo \(x^n\).- EXAMPLES: - sage: S.<q> = QQ['t']['q'] sage: f = (1 + q^10 + q^11 + q^12).truncate(11); f q^10 + 1 sage: f = (1 + q^10 + q^100).truncate(50); f q^10 + 1 sage: f.degree() 10 sage: f = (1 + q^10 + q^100).truncate(500); f q^100 + q^10 + 1 - >>> from sage.all import * >>> S = QQ['t']['q']; (q,) = S._first_ngens(1) >>> f = (Integer(1) + q**Integer(10) + q**Integer(11) + q**Integer(12)).truncate(Integer(11)); f q^10 + 1 >>> f = (Integer(1) + q**Integer(10) + q**Integer(100)).truncate(Integer(50)); f q^10 + 1 >>> f.degree() 10 >>> f = (Integer(1) + q**Integer(10) + q**Integer(100)).truncate(Integer(500)); f q^100 + q^10 + 1 
 
- class sage.rings.polynomial.polynomial_element.Polynomial_generic_dense_inexact[source]¶
- Bases: - Polynomial_generic_dense- A dense polynomial over an inexact ring. - AUTHOR: - Xavier Caruso (2013-03) 
 - degree(secure=False)[source]¶
- INPUT: - secure– boolean (default:- False)
 - OUTPUT: the degree of - self- If - secureis- Trueand the degree of this polynomial is not determined (because the leading coefficient is indistinguishable from 0), an error is raised- If - secureis- False, the returned value is the largest \(n\) so that the coefficient of \(x^n\) does not compare equal to \(0\).- EXAMPLES: - sage: # needs sage.rings.padics sage: K = Qp(3, 10) sage: R.<T> = K[] sage: f = T + 2; f (1 + O(3^10))*T + 2 + O(3^10) sage: f.degree() 1 sage: (f - T).degree() 0 sage: (f - T).degree(secure=True) Traceback (most recent call last): ... PrecisionError: the leading coefficient is indistinguishable from 0 sage: # needs sage.rings.padics sage: x = O(3^5) sage: li = [3^i * x for i in range(0,5)]; li [O(3^5), O(3^6), O(3^7), O(3^8), O(3^9)] sage: f = R(li); f O(3^9)*T^4 + O(3^8)*T^3 + O(3^7)*T^2 + O(3^6)*T + O(3^5) sage: f.degree() -1 sage: f.degree(secure=True) Traceback (most recent call last): ... PrecisionError: the leading coefficient is indistinguishable from 0 - >>> from sage.all import * >>> # needs sage.rings.padics >>> K = Qp(Integer(3), Integer(10)) >>> R = K['T']; (T,) = R._first_ngens(1) >>> f = T + Integer(2); f (1 + O(3^10))*T + 2 + O(3^10) >>> f.degree() 1 >>> (f - T).degree() 0 >>> (f - T).degree(secure=True) Traceback (most recent call last): ... PrecisionError: the leading coefficient is indistinguishable from 0 >>> # needs sage.rings.padics >>> x = O(Integer(3)**Integer(5)) >>> li = [Integer(3)**i * x for i in range(Integer(0),Integer(5))]; li [O(3^5), O(3^6), O(3^7), O(3^8), O(3^9)] >>> f = R(li); f O(3^9)*T^4 + O(3^8)*T^3 + O(3^7)*T^2 + O(3^6)*T + O(3^5) >>> f.degree() -1 >>> f.degree(secure=True) Traceback (most recent call last): ... PrecisionError: the leading coefficient is indistinguishable from 0 - AUTHOR: - Xavier Caruso (2013-03) 
 
 - prec_degree()[source]¶
- Return the largest \(n\) so that precision information is stored about the coefficient of \(x^n\). - Always greater than or equal to degree. - EXAMPLES: - sage: # needs sage.rings.padics sage: K = Qp(3, 10) sage: R.<T> = K[] sage: f = T + 2; f (1 + O(3^10))*T + 2 + O(3^10) sage: f.degree() 1 sage: f.prec_degree() 1 sage: g = f - T; g # needs sage.rings.padics O(3^10)*T + 2 + O(3^10) sage: g.degree() # needs sage.rings.padics 0 sage: g.prec_degree() # needs sage.rings.padics 1 - >>> from sage.all import * >>> # needs sage.rings.padics >>> K = Qp(Integer(3), Integer(10)) >>> R = K['T']; (T,) = R._first_ngens(1) >>> f = T + Integer(2); f (1 + O(3^10))*T + 2 + O(3^10) >>> f.degree() 1 >>> f.prec_degree() 1 >>> g = f - T; g # needs sage.rings.padics O(3^10)*T + 2 + O(3^10) >>> g.degree() # needs sage.rings.padics 0 >>> g.prec_degree() # needs sage.rings.padics 1 - AUTHOR: - Xavier Caruso (2013-03) 
 
 
- sage.rings.polynomial.polynomial_element.generic_power_trunc(p, n, prec)[source]¶
- Generic truncated power algorithm. - INPUT: - p– a polynomial
- n– integer (of type- sage.rings.integer.Integer)
- prec– a precision (should fit into a C- long)
 
- sage.rings.polynomial.polynomial_element.is_Polynomial(f)[source]¶
- Return - Trueif- fis of type univariate polynomial.- This function is deprecated. - INPUT: - f– an object
 - EXAMPLES: - sage: from sage.rings.polynomial.polynomial_element import is_Polynomial sage: R.<x> = ZZ[] sage: is_Polynomial(x^3 + x + 1) doctest:...: DeprecationWarning: the function is_Polynomial is deprecated; use isinstance(x, sage.rings.polynomial.polynomial_element.Polynomial) instead See https://github.com/sagemath/sage/issues/32709 for details. True sage: S.<y> = R[] sage: f = y^3 + x*y - 3*x; f y^3 + x*y - 3*x sage: is_Polynomial(f) True - >>> from sage.all import * >>> from sage.rings.polynomial.polynomial_element import is_Polynomial >>> R = ZZ['x']; (x,) = R._first_ngens(1) >>> is_Polynomial(x**Integer(3) + x + Integer(1)) doctest:...: DeprecationWarning: the function is_Polynomial is deprecated; use isinstance(x, sage.rings.polynomial.polynomial_element.Polynomial) instead See https://github.com/sagemath/sage/issues/32709 for details. True >>> S = R['y']; (y,) = S._first_ngens(1) >>> f = y**Integer(3) + x*y - Integer(3)*x; f y^3 + x*y - 3*x >>> is_Polynomial(f) True - However this function does not return - Truefor genuine multivariate polynomial type objects or symbolic polynomials, since those are not of the same data type as univariate polynomials:- sage: R.<x,y> = QQ[] sage: f = y^3 + x*y - 3*x; f y^3 + x*y - 3*x sage: is_Polynomial(f) False sage: # needs sage.symbolic sage: var('x,y') (x, y) sage: f = y^3 + x*y - 3*x; f y^3 + x*y - 3*x sage: is_Polynomial(f) False - >>> from sage.all import * >>> R = QQ['x, y']; (x, y,) = R._first_ngens(2) >>> f = y**Integer(3) + x*y - Integer(3)*x; f y^3 + x*y - 3*x >>> is_Polynomial(f) False >>> # needs sage.symbolic >>> var('x,y') (x, y) >>> f = y**Integer(3) + x*y - Integer(3)*x; f y^3 + x*y - 3*x >>> is_Polynomial(f) False 
- sage.rings.polynomial.polynomial_element.polynomial_is_variable(x)[source]¶
- Test whether the given polynomial is a variable of its parent ring. - Implemented for instances of - Polynomialand- MPolynomial.- See also - EXAMPLES: - sage: from sage.rings.polynomial.polynomial_element import polynomial_is_variable sage: R.<x> = QQ[] sage: polynomial_is_variable(x) True sage: polynomial_is_variable(R([0,1])) True sage: polynomial_is_variable(x^2) False sage: polynomial_is_variable(R(42)) False - >>> from sage.all import * >>> from sage.rings.polynomial.polynomial_element import polynomial_is_variable >>> R = QQ['x']; (x,) = R._first_ngens(1) >>> polynomial_is_variable(x) True >>> polynomial_is_variable(R([Integer(0),Integer(1)])) True >>> polynomial_is_variable(x**Integer(2)) False >>> polynomial_is_variable(R(Integer(42))) False - sage: R.<y,z> = QQ[] sage: polynomial_is_variable(y) True sage: polynomial_is_variable(z) True sage: polynomial_is_variable(y^2) False sage: polynomial_is_variable(y+z) False sage: polynomial_is_variable(R(42)) False - >>> from sage.all import * >>> R = QQ['y, z']; (y, z,) = R._first_ngens(2) >>> polynomial_is_variable(y) True >>> polynomial_is_variable(z) True >>> polynomial_is_variable(y**Integer(2)) False >>> polynomial_is_variable(y+z) False >>> polynomial_is_variable(R(Integer(42))) False - sage: polynomial_is_variable(42) False - >>> from sage.all import * >>> polynomial_is_variable(Integer(42)) False 
- sage.rings.polynomial.polynomial_element.universal_discriminant()[source]¶
- Return the discriminant of the ‘universal’ univariate polynomial \(a_n x^n + \cdots + a_1 x + a_0\) in \(\ZZ[a_0, \ldots, a_n][x]\). - INPUT: - n– degree of the polynomial
 - OUTPUT: - The discriminant as a polynomial in \(n + 1\) variables over \(\ZZ\). The result will be cached, so subsequent computations of discriminants of the same degree will be faster. - EXAMPLES: - sage: # needs sage.libs.pari sage: from sage.rings.polynomial.polynomial_element import universal_discriminant sage: universal_discriminant(1) 1 sage: universal_discriminant(2) a1^2 - 4*a0*a2 sage: universal_discriminant(3) a1^2*a2^2 - 4*a0*a2^3 - 4*a1^3*a3 + 18*a0*a1*a2*a3 - 27*a0^2*a3^2 sage: universal_discriminant(4).degrees() (3, 4, 4, 4, 3) - >>> from sage.all import * >>> # needs sage.libs.pari >>> from sage.rings.polynomial.polynomial_element import universal_discriminant >>> universal_discriminant(Integer(1)) 1 >>> universal_discriminant(Integer(2)) a1^2 - 4*a0*a2 >>> universal_discriminant(Integer(3)) a1^2*a2^2 - 4*a0*a2^3 - 4*a1^3*a3 + 18*a0*a1*a2*a3 - 27*a0^2*a3^2 >>> universal_discriminant(Integer(4)).degrees() (3, 4, 4, 4, 3) - See also