Esempio n. 1
0
 def fdiff(self, argindex=3):
     if argindex != 3:
         raise ArgumentIndexError(self, argindex)
     nap = Tuple(*[a + 1 for a in self.ap])
     nbq = Tuple(*[b + 1 for b in self.bq])
     fac = Mul(*self.ap) / Mul(*self.bq)
     return fac * hyper(nap, nbq, self.argument)
Esempio n. 2
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 def integrand(self, s):
     """ Get the defining integrand D(s). """
     from diofant import gamma
     return self.argument**s \
         * Mul(*(gamma(b - s) for b in self.bm)) \
         * Mul(*(gamma(1 - a + s) for a in self.an)) \
         / Mul(*(gamma(1 - b + s) for b in self.bother)) \
         / Mul(*(gamma(a - s) for a in self.aother))
Esempio n. 3
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 def _eval_rewrite_as_Sum(self, ap, bq, z):
     from diofant.functions import factorial, RisingFactorial, Piecewise
     from diofant import Sum
     n = Dummy("n", integer=True)
     rfap = Tuple(*[RisingFactorial(a, n) for a in ap])
     rfbq = Tuple(*[RisingFactorial(b, n) for b in bq])
     coeff = Mul(*rfap) / Mul(*rfbq)
     return Piecewise((Sum(coeff * z**n / factorial(n),
                           (n, 0, oo)), self.convergence_statement),
                      (self, True))
Esempio n. 4
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 def _eval_factor(self, **hints):
     if 1 == len(self.limits):
         summand = self.function.factor(**hints)
         if summand.is_Mul:
             out = sift(
                 summand.args, lambda w: w.is_commutative and not set(
                     self.variables) & w.free_symbols)
             return Mul(*out[True]) * self.func(Mul(*out[False]), *
                                                self.limits)
     else:
         summand = self.func(self.function, self.limits[0:-1]).factor()
         if not summand.has(self.variables[-1]):
             return self.func(1, [self.limits[-1]]).doit() * summand
     return self
Esempio n. 5
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def divisor_count(n, modulus=1):
    """Return the number of divisors of ``n``.

    If ``modulus`` is not 1 then only those that are divisible by
    ``modulus`` are counted.

    References
    ==========

    .. [1] http://www.mayer.dial.pipex.com/maths/formulae.htm

    Examples
    ========

    >>> from diofant import divisor_count
    >>> divisor_count(6)
    4

    See Also
    ========

    factorint, divisors, totient
    """

    if not modulus:
        return 0
    elif modulus != 1:
        n, r = divmod(n, modulus)
        if r:
            return 0
    if n == 0:
        return 0
    return Mul(*[v + 1 for k, v in factorint(n).items() if k > 1])
Esempio n. 6
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 def _sqrt(d):
     # remove squares from square root since both will be represented
     # in the results; a similar thing is happening in roots() but
     # must be duplicated here because not all quadratics are binomials
     co = []
     other = []
     for di in Mul.make_args(d):
         if di.is_Pow and di.exp.is_Integer and di.exp % 2 == 0:
             co.append(Pow(di.base, di.exp//2))
         else:
             other.append(di)
     if co:
         d = Mul(*other)
         co = Mul(*co)
         return co*sqrt(d)
     return sqrt(d)
Esempio n. 7
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 def eval(cls, n, k=1):
     n = sympify(n)
     k = sympify(k)
     if n.is_prime:
         return 1 + n**k
     if n.is_Integer:
         if n <= 0:
             raise ValueError("n must be a positive integer")
         else:
             return Mul(*[(p**(k * (e + 1)) - 1) /
                          (p**k - 1) if k != 0 else e + 1
                          for p, e in factorint(n).items()])
Esempio n. 8
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    def _eval_expand_log(self, deep=True, **hints):
        from diofant import unpolarify, expand_log
        from diofant.concrete import Sum, Product
        force = hints.get('force', False)
        if (len(self.args) == 2):
            return expand_log(self.func(*self.args), deep=deep, force=force)
        arg = self.args[0]
        if arg.is_Integer:
            # remove perfect powers
            p = perfect_power(int(arg))
            if p is not False:
                return p[1]*self.func(p[0])
        elif arg.is_Mul:
            expr = []
            nonpos = []
            for x in arg.args:
                if force or x.is_positive or x.is_polar:
                    a = self.func(x)
                    if isinstance(a, log):
                        expr.append(self.func(x)._eval_expand_log(**hints))
                    else:
                        expr.append(a)
                elif x.is_negative:
                    a = self.func(-x)
                    expr.append(a)
                    nonpos.append(S.NegativeOne)
                else:
                    nonpos.append(x)
            return Add(*expr) + log(Mul(*nonpos))
        elif arg.is_Pow:
            if force or (arg.exp.is_extended_real and arg.base.is_positive) or \
                    arg.base.is_polar:
                b = arg.base
                e = arg.exp
                a = self.func(b)
                if isinstance(a, log):
                    return unpolarify(e) * a._eval_expand_log(**hints)
                else:
                    return unpolarify(e) * a
        elif isinstance(arg, Product):
            if arg.function.is_positive:
                return Sum(log(arg.function), *arg.limits)

        return self.func(arg)
Esempio n. 9
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def test_core_mul():
    for c in (Mul, Mul(x, 4)):
        check(c)
Esempio n. 10
0
 def as_base_exp(self):
     if self.exp == 0:
         return self, Integer(1)
     return self.func(1), Mul(*self.args)
Esempio n. 11
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def heurisch(f,
             x,
             rewrite=False,
             hints=None,
             mappings=None,
             retries=3,
             degree_offset=0,
             unnecessary_permutations=None):
    """
    Compute indefinite integral using heuristic Risch algorithm.

    This is a heuristic approach to indefinite integration in finite
    terms using the extended heuristic (parallel) Risch algorithm, based
    on Manuel Bronstein's "Poor Man's Integrator" [1]_.

    The algorithm supports various classes of functions including
    transcendental elementary or special functions like Airy,
    Bessel, Whittaker and Lambert.

    Note that this algorithm is not a decision procedure. If it isn't
    able to compute the antiderivative for a given function, then this is
    not a proof that such a functions does not exist.  One should use
    recursive Risch algorithm in such case.  It's an open question if
    this algorithm can be made a full decision procedure.

    This is an internal integrator procedure. You should use toplevel
    'integrate' function in most cases,  as this procedure needs some
    preprocessing steps and otherwise may fail.

    Parameters
    ==========

    heurisch(f, x, rewrite=False, hints=None)

    f : Expr
        expression
    x : Symbol
        variable

    rewrite : Boolean, optional
        force rewrite 'f' in terms of 'tan' and 'tanh', default False.
    hints : None or list
        a list of functions that may appear in anti-derivate.  If
        None (default) - no suggestions at all, if empty list - try
        to figure out.

    Examples
    ========

    >>> from diofant import tan
    >>> from diofant.integrals.heurisch import heurisch
    >>> from diofant.abc import x, y

    >>> heurisch(y*tan(x), x)
    y*log(tan(x)**2 + 1)/2

    References
    ==========

    .. [1] Manuel Bronstein's "Poor Man's Integrator",
           http://www-sop.inria.fr/cafe/Manuel.Bronstein/pmint/index.html

    .. [2] K. Geddes, L. Stefanus, On the Risch-Norman Integration
           Method and its Implementation in Maple, Proceedings of
           ISSAC'89, ACM Press, 212-217.

    .. [3] J. H. Davenport, On the Parallel Risch Algorithm (I),
           Proceedings of EUROCAM'82, LNCS 144, Springer, 144-157.

    .. [4] J. H. Davenport, On the Parallel Risch Algorithm (III):
           Use of Tangents, SIGSAM Bulletin 16 (1982), 3-6.

    .. [5] J. H. Davenport, B. M. Trager, On the Parallel Risch
           Algorithm (II), ACM Transactions on Mathematical
           Software 11 (1985), 356-362.

    See Also
    ========

    diofant.integrals.integrals.Integral.doit
    diofant.integrals.integrals.Integral
    diofant.integrals.heurisch.components
    """
    f = sympify(f)
    if x not in f.free_symbols:
        return f * x

    if not f.is_Add:
        indep, f = f.as_independent(x)
    else:
        indep = S.One

    rewritables = {
        (sin, cos, cot): tan,
        (sinh, cosh, coth): tanh,
    }

    if rewrite:
        for candidates, rule in rewritables.items():
            f = f.rewrite(candidates, rule)
    else:
        for candidates in rewritables.keys():
            if f.has(*candidates):
                break
        else:
            rewrite = True

    terms = components(f, x)

    if hints is not None:
        if not hints:
            a = Wild('a', exclude=[x])
            b = Wild('b', exclude=[x])
            c = Wild('c', exclude=[x])

            for g in set(terms):  # using copy of terms
                if g.is_Function:
                    if g.func is li:
                        M = g.args[0].match(a * x**b)

                        if M is not None:
                            terms.add(
                                x *
                                (li(M[a] * x**M[b]) -
                                 (M[a] * x**M[b])**(-1 / M[b]) * Ei(
                                     (M[b] + 1) * log(M[a] * x**M[b]) / M[b])))
                            # terms.add( x*(li(M[a]*x**M[b]) - (x**M[b])**(-1/M[b])*Ei((M[b]+1)*log(M[a]*x**M[b])/M[b])) )
                            # terms.add( x*(li(M[a]*x**M[b]) - x*Ei((M[b]+1)*log(M[a]*x**M[b])/M[b])) )
                            # terms.add( li(M[a]*x**M[b]) - Ei((M[b]+1)*log(M[a]*x**M[b])/M[b]) )

                elif g.is_Pow:
                    if g.base is S.Exp1:
                        M = g.exp.match(a * x**2)

                        if M is not None:
                            if M[a].is_positive:
                                terms.add(erfi(sqrt(M[a]) * x))
                            else:  # M[a].is_negative or unknown
                                terms.add(erf(sqrt(-M[a]) * x))

                        M = g.exp.match(a * x**2 + b * x + c)

                        if M is not None:
                            if M[a].is_positive:
                                terms.add(
                                    sqrt(pi / 4 * (-M[a])) *
                                    exp(M[c] - M[b]**2 / (4 * M[a])) * erfi(
                                        sqrt(M[a]) * x + M[b] /
                                        (2 * sqrt(M[a]))))
                            elif M[a].is_negative:
                                terms.add(
                                    sqrt(pi / 4 * (-M[a])) *
                                    exp(M[c] - M[b]**2 / (4 * M[a])) * erf(
                                        sqrt(-M[a]) * x - M[b] /
                                        (2 * sqrt(-M[a]))))

                        M = g.exp.match(a * log(x)**2)

                        if M is not None:
                            if M[a].is_positive:
                                terms.add(
                                    erfi(
                                        sqrt(M[a]) * log(x) + 1 /
                                        (2 * sqrt(M[a]))))
                            if M[a].is_negative:
                                terms.add(
                                    erf(
                                        sqrt(-M[a]) * log(x) - 1 /
                                        (2 * sqrt(-M[a]))))

                    elif g.exp.is_Rational and g.exp.q == 2:
                        M = g.base.match(a * x**2 + b)

                        if M is not None and M[b].is_positive:
                            if M[a].is_positive:
                                terms.add(asinh(sqrt(M[a] / M[b]) * x))
                            elif M[a].is_negative:
                                terms.add(asin(sqrt(-M[a] / M[b]) * x))

                        M = g.base.match(a * x**2 - b)

                        if M is not None and M[b].is_positive:
                            if M[a].is_positive:
                                terms.add(acosh(sqrt(M[a] / M[b]) * x))
                            elif M[a].is_negative:
                                terms.add((-M[b] / 2 * sqrt(-M[a]) * atan(
                                    sqrt(-M[a]) * x / sqrt(M[a] * x**2 - M[b]))
                                           ))

        else:
            terms |= set(hints)

    for g in set(terms):  # using copy of terms
        terms |= components(cancel(g.diff(x)), x)

    # TODO: caching is significant factor for why permutations work at all. Change this.
    V = _symbols('x', len(terms))

    # sort mapping expressions from largest to smallest (last is always x).
    mapping = list(
        reversed(
            list(
                zip(*ordered(  #
                    [(a[0].as_independent(x)[1], a)
                     for a in zip(terms, V)])))[1]))  #
    rev_mapping = {v: k for k, v in mapping}  #
    if mappings is None:  #
        # optimizing the number of permutations of mapping               #
        assert mapping[-1][0] == x  # if not, find it and correct this comment
        unnecessary_permutations = [mapping.pop(-1)]
        mappings = permutations(mapping)
    else:
        unnecessary_permutations = unnecessary_permutations or []

    def _substitute(expr):
        return expr.subs(mapping)

    for mapping in mappings:
        mapping = list(mapping)
        mapping = mapping + unnecessary_permutations
        diffs = [_substitute(cancel(g.diff(x))) for g in terms]
        denoms = [g.as_numer_denom()[1] for g in diffs]
        if all(h.is_polynomial(*V)
               for h in denoms) and _substitute(f).is_rational_function(*V):
            denom = reduce(lambda p, q: lcm(p, q, *V), denoms)
            break
    else:
        if not rewrite:
            result = heurisch(
                f,
                x,
                rewrite=True,
                hints=hints,
                unnecessary_permutations=unnecessary_permutations)

            if result is not None:
                return indep * result
        return

    numers = [cancel(denom * g) for g in diffs]

    def _derivation(h):
        return Add(*[d * h.diff(v) for d, v in zip(numers, V)])

    def _deflation(p):
        for y in V:
            if not p.has(y):
                continue

            if _derivation(p) is not S.Zero:
                c, q = p.as_poly(y).primitive()
                return _deflation(c) * gcd(q, q.diff(y)).as_expr()
        else:
            return p

    def _splitter(p):
        for y in V:
            if not p.has(y):
                continue

            if _derivation(y) is not S.Zero:
                c, q = p.as_poly(y).primitive()

                q = q.as_expr()

                h = gcd(q, _derivation(q), y)
                s = quo(h, gcd(q, q.diff(y), y), y)

                c_split = _splitter(c)

                if s.as_poly(y).degree() == 0:
                    return c_split[0], q * c_split[1]

                q_split = _splitter(cancel(q / s))

                return c_split[0] * q_split[0] * s, c_split[1] * q_split[1]
        else:
            return S.One, p

    special = {}

    for term in terms:
        if term.is_Function:
            if term.func is tan:
                special[1 + _substitute(term)**2] = False
            elif term.func is tanh:
                special[1 + _substitute(term)] = False
                special[1 - _substitute(term)] = False
            elif term.func is LambertW:
                special[_substitute(term)] = True

    F = _substitute(f)

    P, Q = F.as_numer_denom()

    u_split = _splitter(denom)
    v_split = _splitter(Q)

    polys = set(list(v_split) + [u_split[0]] + list(special.keys()))

    s = u_split[0] * Mul(*[k for k, v in special.items() if v])
    polified = [p.as_poly(*V) for p in [s, P, Q]]

    if None in polified:
        return

    # --- definitions for _integrate ---
    a, b, c = [p.total_degree() for p in polified]

    poly_denom = (s * v_split[0] * _deflation(v_split[1])).as_expr()

    def _exponent(g):
        if g.is_Pow:
            if g.exp.is_Rational and g.exp.q != 1:
                if g.exp.p > 0:
                    return g.exp.p + g.exp.q - 1
                else:
                    return abs(g.exp.p + g.exp.q)
            else:
                return 1
        elif not g.is_Atom and g.args:
            return max([_exponent(h) for h in g.args])
        else:
            return 1

    A, B = _exponent(f), a + max(b, c)

    if A > 1 and B > 1:
        monoms = itermonomials(V, A + B - 1 + degree_offset)
    else:
        monoms = itermonomials(V, A + B + degree_offset)

    poly_coeffs = _symbols('A', len(monoms))

    poly_part = Add(*[
        poly_coeffs[i] * monomial for i, monomial in enumerate(ordered(monoms))
    ])

    reducibles = set()

    for poly in polys:
        if poly.has(*V):
            try:
                factorization = factor(poly, greedy=True)
            except PolynomialError:
                factorization = poly
            factorization = poly

            if factorization.is_Mul:
                reducibles |= set(factorization.args)
            else:
                reducibles.add(factorization)

    def _integrate(field=None):
        irreducibles = set()

        for poly in reducibles:
            for z in poly.free_symbols:
                if z in V:
                    break  # should this be: `irreducibles |= \
            else:  # set(root_factors(poly, z, filter=field))`
                continue  # and the line below deleted?
                #                          |
                #                          V
            irreducibles |= set(root_factors(poly, z, filter=field))

        log_coeffs, log_part = [], []
        B = _symbols('B', len(irreducibles))

        # Note: the ordering matters here
        for poly, b in reversed(list(ordered(zip(irreducibles, B)))):
            if poly.has(*V):
                poly_coeffs.append(b)
                log_part.append(b * log(poly))

        # TODO: Currently it's better to use symbolic expressions here instead
        # of rational functions, because it's simpler and FracElement doesn't
        # give big speed improvement yet. This is because cancelation is slow
        # due to slow polynomial GCD algorithms. If this gets improved then
        # revise this code.
        candidate = poly_part / poly_denom + Add(*log_part)
        h = F - _derivation(candidate) / denom
        raw_numer = h.as_numer_denom()[0]

        # Rewrite raw_numer as a polynomial in K[coeffs][V] where K is a field
        # that we have to determine. We can't use simply atoms() because log(3),
        # sqrt(y) and similar expressions can appear, leading to non-trivial
        # domains.
        syms = set(poly_coeffs) | set(V)
        non_syms = set()

        def find_non_syms(expr):
            if expr.is_Integer or expr.is_Rational:
                pass  # ignore trivial numbers
            elif expr in syms:
                pass  # ignore variables
            elif not expr.has(*syms):
                non_syms.add(expr)
            elif expr.is_Add or expr.is_Mul or expr.is_Pow:
                list(map(find_non_syms, expr.args))
            else:
                # TODO: Non-polynomial expression. This should have been
                # filtered out at an earlier stage.
                raise PolynomialError

        try:
            find_non_syms(raw_numer)
        except PolynomialError:
            return
        else:
            ground, _ = construct_domain(non_syms, field=True)

        coeff_ring = PolyRing(poly_coeffs, ground)
        ring = PolyRing(V, coeff_ring)

        numer = ring.from_expr(raw_numer)

        solution = solve_lin_sys(numer.coeffs(), coeff_ring)

        if solution is None:
            return
        else:
            solution = [(coeff_ring.symbols[coeff_ring.index(k)], v.as_expr())
                        for k, v in solution.items()]
            return candidate.subs(solution).subs(
                list(zip(poly_coeffs, [S.Zero] * len(poly_coeffs))))

    if not (F.free_symbols - set(V)):
        solution = _integrate('Q')

        if solution is None:
            solution = _integrate()
    else:
        solution = _integrate()

    if solution is not None:
        antideriv = solution.subs(rev_mapping)
        antideriv = cancel(antideriv).expand(force=True)

        if antideriv.is_Add:
            antideriv = antideriv.as_independent(x)[1]

        return indep * antideriv
    else:
        if retries >= 0:
            result = heurisch(
                f,
                x,
                mappings=mappings,
                rewrite=rewrite,
                hints=hints,
                retries=retries - 1,
                unnecessary_permutations=unnecessary_permutations)

            if result is not None:
                return indep * result

        return
Esempio n. 12
0
def rsolve_ratio(coeffs, f, n, **hints):
    """
    Given linear recurrence operator `\operatorname{L}` of order `k`
    with polynomial coefficients and inhomogeneous equation
    `\operatorname{L} y = f`, where `f` is a polynomial, we seek
    for all rational solutions over field `K` of characteristic zero.

    This procedure accepts only polynomials, however if you are
    interested in solving recurrence with rational coefficients
    then use ``rsolve`` which will pre-process the given equation
    and run this procedure with polynomial arguments.

    The algorithm performs two basic steps:

        (1) Compute polynomial `v(n)` which can be used as universal
            denominator of any rational solution of equation
            `\operatorname{L} y = f`.

        (2) Construct new linear difference equation by substitution
            `y(n) = u(n)/v(n)` and solve it for `u(n)` finding all its
            polynomial solutions. Return ``None`` if none were found.

    Algorithm implemented here is a revised version of the original
    Abramov's algorithm, developed in 1989. The new approach is much
    simpler to implement and has better overall efficiency. This
    method can be easily adapted to q-difference equations case.

    Besides finding rational solutions alone, this functions is
    an important part of Hyper algorithm were it is used to find
    particular solution of inhomogeneous part of a recurrence.

    Examples
    ========

    >>> from diofant.abc import x
    >>> from diofant.solvers.recurr import rsolve_ratio
    >>> rsolve_ratio([-2*x**3 + x**2 + 2*x - 1, 2*x**3 + x**2 - 6*x,
    ... - 2*x**3 - 11*x**2 - 18*x - 9, 2*x**3 + 13*x**2 + 22*x + 8], 0, x)
    C2*(2*x - 3)/(2*(x**2 - 1))

    References
    ==========

    .. [1] S. A. Abramov, Rational solutions of linear difference
           and q-difference equations with polynomial coefficients,
           in: T. Levelt, ed., Proc. ISSAC '95, ACM Press, New York,
           1995, 285-289

    See Also
    ========

    rsolve_hyper
    """
    f = sympify(f)

    if not f.is_polynomial(n):
        return

    coeffs = list(map(sympify, coeffs))

    r = len(coeffs) - 1

    A, B = coeffs[r], coeffs[0]
    A = A.subs(n, n - r).expand()

    h = Dummy('h')

    res = resultant(A, B.subs(n, n + h), n)

    if not res.is_polynomial(h):
        p, q = res.as_numer_denom()
        res = quo(p, q, h)

    nni_roots = list(
        roots(res, h, filter='Z', predicate=lambda r: r >= 0).keys())

    if not nni_roots:
        return rsolve_poly(coeffs, f, n, **hints)
    else:
        C, numers = S.One, [S.Zero] * (r + 1)

        for i in range(int(max(nni_roots)), -1, -1):
            d = gcd(A, B.subs(n, n + i), n)

            A = quo(A, d, n)
            B = quo(B, d.subs(n, n - i), n)

            C *= Mul(*[d.subs(n, n - j) for j in range(0, i + 1)])

        denoms = [C.subs(n, n + i) for i in range(0, r + 1)]

        for i in range(0, r + 1):
            g = gcd(coeffs[i], denoms[i], n)

            numers[i] = quo(coeffs[i], g, n)
            denoms[i] = quo(denoms[i], g, n)

        for i in range(0, r + 1):
            numers[i] *= Mul(*(denoms[:i] + denoms[i + 1:]))

        result = rsolve_poly(numers, f * Mul(*denoms), n, **hints)

        if result is not None:
            if hints.get('symbols', False):
                return simplify(result[0] / C), result[1]
            else:
                return simplify(result / C)
        else:
            return
Esempio n. 13
0
def factorint(n,
              limit=None,
              use_trial=True,
              use_rho=True,
              use_pm1=True,
              verbose=False,
              visual=None):
    r"""
    Given a positive integer ``n``, ``factorint(n)`` returns a dict containing
    the prime factors of ``n`` as keys and their respective multiplicities
    as values. For example:

    >>> from diofant.ntheory import factorint
    >>> factorint(2000)    # 2000 = (2**4) * (5**3)
    {2: 4, 5: 3}
    >>> factorint(65537)   # This number is prime
    {65537: 1}

    For input less than 2, factorint behaves as follows:

        - ``factorint(1)`` returns the empty factorization, ``{}``
        - ``factorint(0)`` returns ``{0:1}``
        - ``factorint(-n)`` adds ``-1:1`` to the factors and then factors ``n``

    Partial Factorization:

    If ``limit`` (> 3) is specified, the search is stopped after performing
    trial division up to (and including) the limit (or taking a
    corresponding number of rho/p-1 steps). This is useful if one has
    a large number and only is interested in finding small factors (if
    any). Note that setting a limit does not prevent larger factors
    from being found early; it simply means that the largest factor may
    be composite. Since checking for perfect power is relatively cheap, it is
    done regardless of the limit setting.

    This number, for example, has two small factors and a huge
    semi-prime factor that cannot be reduced easily:

    >>> from diofant.ntheory import isprime
    >>> a = 1407633717262338957430697921446883
    >>> f = factorint(a, limit=10000)
    >>> f == {991: 1, int(202916782076162456022877024859): 1, 7: 1}
    True
    >>> isprime(max(f))
    False

    This number has a small factor and a residual perfect power whose
    base is greater than the limit:

    >>> factorint(3*101**7, limit=5)
    {3: 1, 101: 7}

    Visual Factorization:

    If ``visual`` is set to ``True``, then it will return a visual
    factorization of the integer.  For example:

    >>> from diofant import pprint
    >>> pprint(factorint(4200, visual=True), use_unicode=False)
     3  1  2  1
    2 *3 *5 *7

    Note that this is achieved by using the evaluate=False flag in Mul
    and Pow. If you do other manipulations with an expression where
    evaluate=False, it may evaluate.  Therefore, you should use the
    visual option only for visualization, and use the normal dictionary
    returned by visual=False if you want to perform operations on the
    factors.

    You can easily switch between the two forms by sending them back to
    factorint:

    >>> from diofant import Mul, Pow
    >>> regular = factorint(1764); regular
    {2: 2, 3: 2, 7: 2}
    >>> pprint(factorint(regular), use_unicode=False)
     2  2  2
    2 *3 *7

    >>> visual = factorint(1764, visual=True); pprint(visual, use_unicode=False)
     2  2  2
    2 *3 *7
    >>> print(factorint(visual))
    {2: 2, 3: 2, 7: 2}

    If you want to send a number to be factored in a partially factored form
    you can do so with a dictionary or unevaluated expression:

    >>> factorint(factorint({4: 2, 12: 3})) # twice to toggle to dict form
    {2: 10, 3: 3}
    >>> factorint(Mul(4, 12, evaluate=False))
    {2: 4, 3: 1}

    The table of the output logic is:

        ====== ====== ======= =======
                       Visual
        ------ ----------------------
        Input  True   False   other
        ====== ====== ======= =======
        dict    mul    dict    mul
        n       mul    dict    dict
        mul     mul    dict    dict
        ====== ====== ======= =======

    Notes
    =====

    The function switches between multiple algorithms. Trial division
    quickly finds small factors (of the order 1-5 digits), and finds
    all large factors if given enough time. The Pollard rho and p-1
    algorithms are used to find large factors ahead of time; they
    will often find factors of the order of 10 digits within a few
    seconds:

    >>> factors = factorint(12345678910111213141516)
    >>> for base, exp in sorted(factors.items()):
    ...     print('%s %s' % (base, exp))
    ...
    2 2
    2507191691 1
    1231026625769 1

    Any of these methods can optionally be disabled with the following
    boolean parameters:

        - ``use_trial``: Toggle use of trial division
        - ``use_rho``: Toggle use of Pollard's rho method
        - ``use_pm1``: Toggle use of Pollard's p-1 method

    ``factorint`` also periodically checks if the remaining part is
    a prime number or a perfect power, and in those cases stops.


    If ``verbose`` is set to ``True``, detailed progress is printed.

    See Also
    ========

    smoothness, smoothness_p, divisors
    """
    factordict = {}
    if visual and not isinstance(n, Mul) and not isinstance(n, dict):
        factordict = factorint(n,
                               limit=limit,
                               use_trial=use_trial,
                               use_rho=use_rho,
                               use_pm1=use_pm1,
                               verbose=verbose,
                               visual=False)
    elif isinstance(n, Mul):
        factordict = {
            int(k): int(v)
            for k, v in list(n.as_powers_dict().items())
        }
    elif isinstance(n, dict):
        factordict = n
    if factordict and (isinstance(n, Mul) or isinstance(n, dict)):
        # check it
        for k in list(factordict.keys()):
            if isprime(k):
                continue
            e = factordict.pop(k)
            d = factorint(k,
                          limit=limit,
                          use_trial=use_trial,
                          use_rho=use_rho,
                          use_pm1=use_pm1,
                          verbose=verbose,
                          visual=False)
            for k, v in d.items():
                if k in factordict:
                    factordict[k] += v * e
                else:
                    factordict[k] = v * e
    if visual or (type(n) is dict and visual is not True
                  and visual is not False):
        if factordict == {}:
            return S.One
        if -1 in factordict:
            factordict.pop(-1)
            args = [S.NegativeOne]
        else:
            args = []
        args.extend(
            [Pow(*i, evaluate=False) for i in sorted(factordict.items())])
        return Mul(*args, evaluate=False)
    elif isinstance(n, dict) or isinstance(n, Mul):
        return factordict

    assert use_trial or use_rho or use_pm1

    n = as_int(n)
    if limit:
        limit = int(limit)

    # special cases
    if n < 0:
        factors = factorint(-n,
                            limit=limit,
                            use_trial=use_trial,
                            use_rho=use_rho,
                            use_pm1=use_pm1,
                            verbose=verbose,
                            visual=False)
        factors[-1] = 1
        return factors

    if limit and limit < 2:
        if n == 1:
            return {}
        return {n: 1}
    elif n < 10:
        # doing this we are assured of getting a limit > 2
        # when we have to compute it later
        return [{
            0: 1
        }, {}, {
            2: 1
        }, {
            3: 1
        }, {
            2: 2
        }, {
            5: 1
        }, {
            2: 1,
            3: 1
        }, {
            7: 1
        }, {
            2: 3
        }, {
            3: 2
        }][n]

    factors = {}

    # do simplistic factorization
    if verbose:
        sn = str(n)
        if len(sn) > 50:
            print('Factoring %s' % sn[:5] + '..(%i other digits)..' %
                  (len(sn) - 10) + sn[-5:])
        else:
            print('Factoring', n)

    if use_trial:
        # this is the preliminary factorization for small factors
        small = 2**15
        fail_max = 600
        small = min(small, limit or small)
        if verbose:
            print(trial_int_msg % (2, small, fail_max))
        n, next_p = _factorint_small(factors, n, small, fail_max)
    else:
        next_p = 2
    if factors and verbose:
        for k in sorted(factors):
            print(factor_msg % (k, factors[k]))
    if next_p == 0:
        if n > 1:
            factors[int(n)] = 1
        if verbose:
            print(complete_msg)
        return factors

    # continue with more advanced factorization methods

    # first check if the simplistic run didn't finish
    # because of the limit and check for a perfect
    # power before exiting
    try:
        if limit and next_p > limit:
            if verbose:
                print('Exceeded limit:', limit)

            _check_termination(factors, n, limit, use_trial, use_rho, use_pm1,
                               verbose)

            if n > 1:
                factors[int(n)] = 1
            return factors
        else:
            # Before quitting (or continuing on)...

            # ...do a Fermat test since it's so easy and we need the
            # square root anyway. Finding 2 factors is easy if they are
            # "close enough." This is the big root equivalent of dividing by
            # 2, 3, 5.
            sqrt_n = integer_nthroot(n, 2)[0]
            a = sqrt_n + 1
            a2 = a**2
            b2 = a2 - n
            for i in range(3):
                b, fermat = integer_nthroot(b2, 2)
                if fermat:
                    break
                b2 += 2 * a + 1  # equiv to (a+1)**2 - n
                a += 1
            if fermat:
                if verbose:
                    print(fermat_msg)
                if limit:
                    limit -= 1
                for r in [a - b, a + b]:
                    facs = factorint(r,
                                     limit=limit,
                                     use_trial=use_trial,
                                     use_rho=use_rho,
                                     use_pm1=use_pm1,
                                     verbose=verbose)
                    factors.update(facs)
                raise StopIteration

            # ...see if factorization can be terminated
            _check_termination(factors, n, limit, use_trial, use_rho, use_pm1,
                               verbose)

    except StopIteration:
        if verbose:
            print(complete_msg)
        return factors

    # these are the limits for trial division which will
    # be attempted in parallel with pollard methods
    low, high = next_p, 2 * next_p

    limit = limit or sqrt_n
    # add 1 to make sure limit is reached in primerange calls
    limit += 1

    while 1:

        try:
            high_ = high
            if limit < high_:
                high_ = limit

            # Trial division
            if use_trial:
                if verbose:
                    print(trial_msg % (low, high_))
                ps = sieve.primerange(low, high_)
                n, found_trial = _trial(factors, n, ps, verbose)
                if found_trial:
                    _check_termination(factors, n, limit, use_trial, use_rho,
                                       use_pm1, verbose)
            else:
                found_trial = False

            if high > limit:
                if verbose:
                    print('Exceeded limit:', limit)
                if n > 1:
                    factors[int(n)] = 1
                raise StopIteration

            # Only used advanced methods when no small factors were found
            if not found_trial:
                if (use_pm1 or use_rho):
                    high_root = max(int(math.log(high_**0.7)), low, 3)

                    # Pollard p-1
                    if use_pm1:
                        if verbose:
                            print(pm1_msg % (high_root, high_))
                        c = pollard_pm1(n, B=high_root, seed=high_)
                        if c:
                            # factor it and let _trial do the update
                            ps = factorint(c,
                                           limit=limit - 1,
                                           use_trial=use_trial,
                                           use_rho=use_rho,
                                           use_pm1=use_pm1,
                                           verbose=verbose)
                            n, _ = _trial(factors, n, ps, verbose=False)
                            _check_termination(factors, n, limit, use_trial,
                                               use_rho, use_pm1, verbose)

                    # Pollard rho
                    if use_rho:
                        max_steps = high_root
                        if verbose:
                            print(rho_msg % (1, max_steps, high_))
                        c = pollard_rho(n,
                                        retries=1,
                                        max_steps=max_steps,
                                        seed=high_)
                        if c:
                            # factor it and let _trial do the update
                            ps = factorint(c,
                                           limit=limit - 1,
                                           use_trial=use_trial,
                                           use_rho=use_rho,
                                           use_pm1=use_pm1,
                                           verbose=verbose)
                            n, _ = _trial(factors, n, ps, verbose=False)
                            _check_termination(factors, n, limit, use_trial,
                                               use_rho, use_pm1, verbose)

        except StopIteration:
            if verbose:
                print(complete_msg)
            return factors

        low, high = high, high * 2
Esempio n. 14
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def roots(f, *gens, **flags):
    """
    Computes symbolic roots of a univariate polynomial.

    Given a univariate polynomial f with symbolic coefficients (or
    a list of the polynomial's coefficients), returns a dictionary
    with its roots and their multiplicities.

    Only roots expressible via radicals will be returned.  To get
    a complete set of roots use RootOf class or numerical methods
    instead. By default cubic and quartic formulas are used in
    the algorithm. To disable them because of unreadable output
    set ``cubics=False`` or ``quartics=False`` respectively. If cubic
    roots are real but are expressed in terms of complex numbers
    (casus irreducibilis [1]) the ``trig`` flag can be set to True to
    have the solutions returned in terms of cosine and inverse cosine
    functions.

    To get roots from a specific domain set the ``filter`` flag with
    one of the following specifiers: Z, Q, R, I, C. By default all
    roots are returned (this is equivalent to setting ``filter='C'``).

    By default a dictionary is returned giving a compact result in
    case of multiple roots.  However to get a list containing all
    those roots set the ``multiple`` flag to True; the list will
    have identical roots appearing next to each other in the result.
    (For a given Poly, the all_roots method will give the roots in
    sorted numerical order.)

    Examples
    ========

    >>> from diofant import Poly, roots, sqrt
    >>> from diofant.abc import x, y

    >>> roots(x**2 - 1, x) == {-1: 1, 1: 1}
    True

    >>> p = Poly(x**2-1, x)
    >>> roots(p) == {-1: 1, 1: 1}
    True

    >>> p = Poly(x**2-y, x, y)

    >>> roots(Poly(p, x)) == {-sqrt(y): 1, sqrt(y): 1}
    True

    >>> roots(x**2 - y, x) == {-sqrt(y): 1, sqrt(y): 1}
    True

    >>> roots([1, 0, -1]) == {-1: 1, 1: 1}
    True

    References
    ==========

    .. [1] http://en.wikipedia.org/wiki/Cubic_function#Trigonometric_.28and_hyperbolic.29_method
    """
    from diofant.polys.polytools import to_rational_coeffs
    flags = dict(flags)

    auto = flags.pop('auto', True)
    cubics = flags.pop('cubics', True)
    trig = flags.pop('trig', False)
    quartics = flags.pop('quartics', True)
    quintics = flags.pop('quintics', False)
    multiple = flags.pop('multiple', False)
    filter = flags.pop('filter', None)
    predicate = flags.pop('predicate', None)

    if isinstance(f, list):
        if gens:
            raise ValueError('redundant generators given')

        x = Dummy('x')

        poly, i = {}, len(f) - 1

        for coeff in f:
            poly[i], i = sympify(coeff), i - 1

        f = Poly(poly, x, field=True)
    else:
        try:
            f = Poly(f, *gens, **flags)
            if f.length == 2 and f.degree() != 1:
                # check for foo**n factors in the constant
                n = f.degree()
                npow_bases = []
                expr = f.as_expr()
                con = expr.as_independent(*gens)[0]
                for p in Mul.make_args(con):
                    if p.is_Pow and not p.exp % n:
                        npow_bases.append(p.base**(p.exp/n))
                    else:
                        other.append(p)
                    if npow_bases:
                        b = Mul(*npow_bases)
                        B = Dummy()
                        d = roots(Poly(expr - con + B**n*Mul(*others), *gens,
                            **flags), *gens, **flags)
                        rv = {}
                        for k, v in d.items():
                            rv[k.subs(B, b)] = v
                        return rv

        except GeneratorsNeeded:
            if multiple:
                return []
            else:
                return {}

        if f.is_multivariate:
            raise PolynomialError('multivariate polynomials are not supported')

    def _update_dict(result, root, k):
        if root in result:
            result[root] += k
        else:
            result[root] = k

    def _try_decompose(f):
        """Find roots using functional decomposition. """
        factors, roots = f.decompose(), []

        for root in _try_heuristics(factors[0]):
            roots.append(root)

        for factor in factors[1:]:
            previous, roots = list(roots), []

            for root in previous:
                g = factor - Poly(root, f.gen)

                for root in _try_heuristics(g):
                    roots.append(root)

        return roots

    def _try_heuristics(f):
        """Find roots using formulas and some tricks. """
        if f.is_ground:
            return []
        if f.is_monomial:
            return [Integer(0)]*f.degree()

        if f.length() == 2:
            if f.degree() == 1:
                return list(map(cancel, roots_linear(f)))
            else:
                return roots_binomial(f)

        result = []

        for i in [-1, 1]:
            if not f.eval(i):
                f = f.quo(Poly(f.gen - i, f.gen))
                result.append(i)
                break

        n = f.degree()

        if n == 1:
            result += list(map(cancel, roots_linear(f)))
        elif n == 2:
            result += list(map(cancel, roots_quadratic(f)))
        elif f.is_cyclotomic:
            result += roots_cyclotomic(f)
        elif n == 3 and cubics:
            result += roots_cubic(f, trig=trig)
        elif n == 4 and quartics:
            result += roots_quartic(f)
        elif n == 5 and quintics:
            result += roots_quintic(f)

        return result

    (k,), f = f.terms_gcd()

    if not k:
        zeros = {}
    else:
        zeros = {Integer(0): k}

    coeff, f = preprocess_roots(f)

    if auto and f.get_domain().has_Ring:
        f = f.to_field()

    rescale_x = None
    translate_x = None

    result = {}

    if not f.is_ground:
        if not f.get_domain().is_Exact:
            for r in f.nroots():
                _update_dict(result, r, 1)
        elif f.degree() == 1:
            result[roots_linear(f)[0]] = 1
        elif f.length() == 2:
            roots_fun = roots_quadratic if f.degree() == 2 else roots_binomial
            for r in roots_fun(f):
                _update_dict(result, r, 1)
        else:
            _, factors = Poly(f.as_expr()).factor_list()
            if len(factors) == 1 and f.degree() == 2:
                for r in roots_quadratic(f):
                    _update_dict(result, r, 1)
            else:
                if len(factors) == 1 and factors[0][1] == 1:
                    if f.get_domain().is_EX:
                        res = to_rational_coeffs(f)
                        if res:
                            if res[0] is None:
                                translate_x, f = res[2:]
                            else:
                                rescale_x, f = res[1], res[-1]
                            result = roots(f)
                            if not result:
                                for root in _try_decompose(f):
                                    _update_dict(result, root, 1)
                    else:
                        for root in _try_decompose(f):
                            _update_dict(result, root, 1)
                else:
                    for factor, k in factors:
                        for r in _try_heuristics(Poly(factor, f.gen, field=True)):
                            _update_dict(result, r, k)

    if coeff is not S.One:
        _result, result, = result, {}

        for root, k in _result.items():
            result[coeff*root] = k

    result.update(zeros)

    if filter not in [None, 'C']:
        handlers = {
            'Z': lambda r: r.is_Integer,
            'Q': lambda r: r.is_Rational,
            'R': lambda r: r.is_extended_real,
            'I': lambda r: r.is_imaginary,
        }

        try:
            query = handlers[filter]
        except KeyError:
            raise ValueError("Invalid filter: %s" % filter)

        for zero in dict(result).keys():
            if not query(zero):
                del result[zero]

    if predicate is not None:
        for zero in dict(result).keys():
            if not predicate(zero):
                del result[zero]
    if rescale_x:
        result1 = {}
        for k, v in result.items():
            result1[k*rescale_x] = v
        result = result1
    if translate_x:
        result1 = {}
        for k, v in result.items():
            result1[k + translate_x] = v
        result = result1

    if not multiple:
        return result
    else:
        zeros = []

        for zero in ordered(result):
            zeros.extend([zero]*result[zero])

        return zeros
Esempio n. 15
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    def eval(cls, p, q):
        from diofant.core.add import Add
        from diofant.core.mul import Mul
        from diofant.core.singleton import S
        from diofant.core.exprtools import gcd_terms
        from diofant.polys.polytools import gcd

        def doit(p, q):
            """Try to return p % q if both are numbers or +/-p is known
            to be less than or equal q.
            """

            if p.is_infinite or q.is_infinite:
                return nan
            if (p == q or p == -q
                    or p.is_Pow and p.exp.is_Integer and p.base == q
                    or p.is_integer and q == 1):
                return S.Zero

            if q.is_Number:
                if p.is_Number:
                    return (p % q)
                if q == 2:
                    if p.is_even:
                        return S.Zero
                    elif p.is_odd:
                        return S.One

            # by ratio
            r = p / q
            try:
                d = int(r)
            except TypeError:
                pass
            else:
                rv = p - d * q
                if (rv * q).is_nonnegative:
                    return rv
                elif (rv * q).is_nonpositive:
                    return rv + q

            # by difference
            d = p - q
            if d.is_negative:
                if q.is_negative:
                    return d
                elif q.is_positive:
                    return p

        rv = doit(p, q)
        if rv is not None:
            return rv

        # denest
        if p.func is cls:
            # easy
            qinner = p.args[1]
            if qinner == q:
                return p
            # XXX other possibilities?

        # extract gcd; any further simplification should be done by the user
        G = gcd(p, q)
        if G != 1:
            p, q = [
                gcd_terms(i / G, clear=False, fraction=False) for i in (p, q)
            ]
        pwas, qwas = p, q

        # simplify terms
        # (x + y + 2) % x -> Mod(y + 2, x)
        if p.is_Add:
            args = []
            for i in p.args:
                a = cls(i, q)
                if a.count(cls) > i.count(cls):
                    args.append(i)
                else:
                    args.append(a)
            if args != list(p.args):
                p = Add(*args)

        else:
            # handle coefficients if they are not Rational
            # since those are not handled by factor_terms
            # e.g. Mod(.6*x, .3*y) -> 0.3*Mod(2*x, y)
            cp, p = p.as_coeff_Mul()
            cq, q = q.as_coeff_Mul()
            ok = False
            if not cp.is_Rational or not cq.is_Rational:
                r = cp % cq
                if r == 0:
                    G *= cq
                    p *= int(cp / cq)
                    ok = True
            if not ok:
                p = cp * p
                q = cq * q

        # simple -1 extraction
        if p.could_extract_minus_sign() and q.could_extract_minus_sign():
            G, p, q = [-i for i in (G, p, q)]

        # check again to see if p and q can now be handled as numbers
        rv = doit(p, q)
        if rv is not None:
            return rv * G

        # put 1.0 from G on inside
        if G.is_Float and G == 1:
            p *= G
            return cls(p, q, evaluate=False)
        elif G.is_Mul and G.args[0].is_Float and G.args[0] == 1:
            p = G.args[0] * p
            G = Mul._from_args(G.args[1:])
        return G * cls(p, q, evaluate=(p, q) != (pwas, qwas))
Esempio n. 16
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def rsolve_hyper(coeffs, f, n, **hints):
    """
    Given linear recurrence operator `\operatorname{L}` of order `k`
    with polynomial coefficients and inhomogeneous equation
    `\operatorname{L} y = f` we seek for all hypergeometric solutions
    over field `K` of characteristic zero.

    The inhomogeneous part can be either hypergeometric or a sum
    of a fixed number of pairwise dissimilar hypergeometric terms.

    The algorithm performs three basic steps:

        (1) Group together similar hypergeometric terms in the
            inhomogeneous part of `\operatorname{L} y = f`, and find
            particular solution using Abramov's algorithm.

        (2) Compute generating set of `\operatorname{L}` and find basis
            in it, so that all solutions are linearly independent.

        (3) Form final solution with the number of arbitrary
            constants equal to dimension of basis of `\operatorname{L}`.

    Term `a(n)` is hypergeometric if it is annihilated by first order
    linear difference equations with polynomial coefficients or, in
    simpler words, if consecutive term ratio is a rational function.

    The output of this procedure is a linear combination of fixed
    number of hypergeometric terms. However the underlying method
    can generate larger class of solutions - D'Alembertian terms.

    Note also that this method not only computes the kernel of the
    inhomogeneous equation, but also reduces in to a basis so that
    solutions generated by this procedure are linearly independent

    Examples
    ========

    >>> from diofant.solvers import rsolve_hyper
    >>> from diofant.abc import x

    >>> rsolve_hyper([-1, -1, 1], 0, x)
    C0*(1/2 + sqrt(5)/2)**x + C1*(-sqrt(5)/2 + 1/2)**x

    >>> rsolve_hyper([-1, 1], 1 + x, x)
    C0 + x*(x + 1)/2

    References
    ==========

    .. [1] M. Petkovšek, Hypergeometric solutions of linear recurrences
           with polynomial coefficients, J. Symbolic Computation,
           14 (1992), 243-264.

    .. [2] M. Petkovšek, H. S. Wilf, D. Zeilberger, A = B, 1996.
    """
    coeffs = list(map(sympify, coeffs))

    f = sympify(f)

    r, kernel, symbols = len(coeffs) - 1, [], set()

    if not f.is_zero:
        if f.is_Add:
            similar = {}

            for g in f.expand().args:
                if not g.is_hypergeometric(n):
                    return

                for h in similar.keys():
                    if hypersimilar(g, h, n):
                        similar[h] += g
                        break
                else:
                    similar[g] = S.Zero

            inhomogeneous = []

            for g, h in similar.items():
                inhomogeneous.append(g + h)
        elif f.is_hypergeometric(n):
            inhomogeneous = [f]
        else:
            return

        for i, g in enumerate(inhomogeneous):
            coeff, polys = S.One, coeffs[:]
            denoms = [S.One] * (r + 1)

            s = hypersimp(g, n)

            for j in range(1, r + 1):
                coeff *= s.subs(n, n + j - 1)

                p, q = coeff.as_numer_denom()

                polys[j] *= p
                denoms[j] = q

            for j in range(0, r + 1):
                polys[j] *= Mul(*(denoms[:j] + denoms[j + 1:]))

            R = rsolve_ratio(polys, Mul(*denoms), n, symbols=True)
            if R is not None:
                R, syms = R
                if syms:
                    R = R.subs(zip(syms, [0] * len(syms)))

            if R:
                inhomogeneous[i] *= R
            else:
                return

            result = Add(*inhomogeneous)
            result = simplify(result)
    else:
        result = S.Zero

    Z = Dummy('Z')

    p, q = coeffs[0], coeffs[r].subs(n, n - r + 1)

    p_factors = [z for z in roots(p, n).keys()]
    q_factors = [z for z in roots(q, n).keys()]

    factors = [(S.One, S.One)]

    for p in p_factors:
        for q in q_factors:
            if p.is_integer and q.is_integer and p <= q:
                continue
            else:
                factors += [(n - p, n - q)]

    p = [(n - p, S.One) for p in p_factors]
    q = [(S.One, n - q) for q in q_factors]

    factors = p + factors + q

    for A, B in factors:
        polys, degrees = [], []
        D = A * B.subs(n, n + r - 1)

        for i in range(0, r + 1):
            a = Mul(*[A.subs(n, n + j) for j in range(0, i)])
            b = Mul(*[B.subs(n, n + j) for j in range(i, r)])

            poly = quo(coeffs[i] * a * b, D, n)
            polys.append(poly.as_poly(n))

            if not poly.is_zero:
                degrees.append(polys[i].degree())

        d, poly = max(degrees), S.Zero

        for i in range(0, r + 1):
            coeff = polys[i].nth(d)

            if coeff is not S.Zero:
                poly += coeff * Z**i

        for z in roots(poly, Z).keys():
            if z.is_zero:
                continue

            (C, s) = rsolve_poly([polys[i] * z**i for i in range(r + 1)],
                                 0,
                                 n,
                                 symbols=True)

            if C is not None and C is not S.Zero:
                symbols |= set(s)

                ratio = z * A * C.subs(n, n + 1) / B / C
                ratio = simplify(ratio)

                skip = max([-1] + [
                    v for v in roots(Mul(*ratio.as_numer_denom()), n).keys()
                    if v.is_Integer
                ]) + 1
                K = product(ratio, (n, skip, n - 1))

                if K.has(factorial, FallingFactorial, RisingFactorial):
                    K = simplify(K)

                if casoratian(kernel + [K], n, zero=False) != 0:
                    kernel.append(K)

    kernel.sort(key=default_sort_key)
    sk = list(zip(numbered_symbols('C'), kernel))

    for C, ker in sk:
        result += C * ker

    if hints.get('symbols', False):
        symbols |= {s for s, k in sk}
        return result, list(symbols)
    else:
        return result
Esempio n. 17
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    def _eval_product(self, term, limits):
        from diofant.concrete.delta import deltaproduct, _has_simple_delta
        from diofant.concrete.summations import summation
        from diofant.functions import KroneckerDelta, RisingFactorial

        (k, a, n) = limits

        if k not in term.free_symbols:
            if (term - 1).is_zero:
                return S.One
            return term**(n - a + 1)

        if a == n:
            return term.subs(k, a)

        if term.has(KroneckerDelta) and _has_simple_delta(term, limits[0]):
            return deltaproduct(term, limits)

        dif = n - a
        if dif.is_Integer:
            return Mul(*[term.subs(k, a + i) for i in range(dif + 1)])

        elif term.is_polynomial(k):
            poly = term.as_poly(k)

            A = B = Q = S.One

            all_roots = roots(poly)

            M = 0
            for r, m in all_roots.items():
                M += m
                A *= RisingFactorial(a - r, n - a + 1)**m
                Q *= (n - r)**m

            if M < poly.degree():
                arg = quo(poly, Q.as_poly(k))
                B = self.func(arg, (k, a, n)).doit()

            return poly.LC()**(n - a + 1) * A * B

        elif term.is_Add:
            p, q = term.as_numer_denom()

            p = self._eval_product(p, (k, a, n))
            q = self._eval_product(q, (k, a, n))

            return p / q

        elif term.is_Mul:
            exclude, include = [], []

            for t in term.args:
                p = self._eval_product(t, (k, a, n))

                if p is not None:
                    exclude.append(p)
                else:
                    include.append(t)

            if not exclude:
                return
            else:
                arg = term._new_rawargs(*include)
                A = Mul(*exclude)
                B = self.func(arg, (k, a, n)).doit()
                return A * B

        elif term.is_Pow:
            if not term.base.has(k):
                s = summation(term.exp, (k, a, n))

                return term.base**s
            elif not term.exp.has(k):
                p = self._eval_product(term.base, (k, a, n))

                if p is not None:
                    return p**term.exp

        elif isinstance(term, Product):
            evaluated = term.doit()
            f = self._eval_product(evaluated, limits)
            if f is None:
                return self.func(evaluated, limits)
            else:
                return f
Esempio n. 18
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def evalf_mul(v, prec, options):
    res = pure_complex(v)
    if res:
        # the only pure complex that is a mul is h*I
        _, h = res
        im, _, im_acc, _ = evalf(h, prec, options)
        return None, im, None, im_acc
    args = list(v.args)

    # see if any argument is NaN or oo and thus warrants a special return
    special = []
    from diofant.core.numbers import Float
    for arg in args:
        arg = evalf(arg, prec, options)
        if arg[0] is None:
            continue
        arg = Float._new(arg[0], 1)
        if arg is S.NaN or arg.is_infinite:
            special.append(arg)
    if special:
        from diofant.core.mul import Mul
        special = Mul(*special)
        return evalf(special, prec + 4, {})

    # With guard digits, multiplication in the real case does not destroy
    # accuracy. This is also true in the complex case when considering the
    # total accuracy; however accuracy for the real or imaginary parts
    # separately may be lower.
    acc = prec

    # XXX: big overestimate
    working_prec = prec + len(args) + 5

    # Empty product is 1
    start = man, exp, bc = MPZ(1), 0, 1

    # First, we multiply all pure real or pure imaginary numbers.
    # direction tells us that the result should be multiplied by
    # I**direction; all other numbers get put into complex_factors
    # to be multiplied out after the first phase.
    last = len(args)
    direction = 0
    args.append(S.One)
    complex_factors = []

    for i, arg in enumerate(args):
        if i != last and pure_complex(arg):
            args[-1] = (args[-1] * arg).expand()
            continue
        elif i == last and arg is S.One:
            continue
        re, im, re_acc, im_acc = evalf(arg, working_prec, options)
        if re and im:
            complex_factors.append((re, im, re_acc, im_acc))
            continue
        elif re:
            (s, m, e, b), w_acc = re, re_acc
        elif im:
            (s, m, e, b), w_acc = im, im_acc
            direction += 1
        else:
            return None, None, None, None
        direction += 2 * s
        man *= m
        exp += e
        bc += b
        if bc > 3 * working_prec:
            man >>= working_prec
            exp += working_prec
        acc = min(acc, w_acc)
    sign = (direction & 2) >> 1
    if not complex_factors:
        v = normalize(sign, man, exp, bitcount(man), prec, rnd)
        # multiply by i
        if direction & 1:
            return None, v, None, acc
        else:
            return v, None, acc, None
    else:
        # initialize with the first term
        if (man, exp, bc) != start:
            # there was a real part; give it an imaginary part
            re, im = (sign, man, exp, bitcount(man)), (0, MPZ(0), 0, 0)
            i0 = 0
        else:
            # there is no real part to start (other than the starting 1)
            wre, wim, wre_acc, wim_acc = complex_factors[0]
            acc = min(acc, complex_accuracy((wre, wim, wre_acc, wim_acc)))
            re = wre
            im = wim
            i0 = 1

        for wre, wim, wre_acc, wim_acc in complex_factors[i0:]:
            # acc is the overall accuracy of the product; we aren't
            # computing exact accuracies of the product.
            acc = min(acc, complex_accuracy((wre, wim, wre_acc, wim_acc)))

            use_prec = working_prec
            A = mpf_mul(re, wre, use_prec)
            B = mpf_mul(mpf_neg(im), wim, use_prec)
            C = mpf_mul(re, wim, use_prec)
            D = mpf_mul(im, wre, use_prec)
            re = mpf_add(A, B, use_prec)
            im = mpf_add(C, D, use_prec)
        debug("MUL: wanted", prec, "accurate bits, got", acc)
        # multiply by I
        if direction & 1:
            re, im = mpf_neg(im), re
        return re, im, acc, acc