def test_rewriting(): assert dirichlet_eta(x).rewrite(zeta) == (1 - 2**(1 - x))*zeta(x) assert zeta(x).rewrite(dirichlet_eta) == dirichlet_eta(x)/(1 - 2**(1 - x)) assert tn(dirichlet_eta(x), dirichlet_eta(x).rewrite(zeta), x) assert tn(zeta(x), zeta(x).rewrite(dirichlet_eta), x) assert zeta(x, a).rewrite(lerchphi) == lerchphi(1, x, a) assert polylog(s, z).rewrite(lerchphi) == lerchphi(z, s, 1)*z assert lerchphi(1, x, a).rewrite(zeta) == zeta(x, a) assert z*lerchphi(z, s, 1).rewrite(polylog) == polylog(s, z)
def test_lerchphi(): from diofant import combsimp, exp_polar, polylog, log, lerchphi assert hyperexpand(hyper([1, a], [a + 1], z) / a) == lerchphi(z, 1, a) assert hyperexpand(hyper([1, a, a], [a + 1, a + 1], z) / a**2) == lerchphi( z, 2, a) assert hyperexpand(hyper([1, a, a, a], [a + 1, a + 1, a + 1], z)/a**3) == \ lerchphi(z, 3, a) assert hyperexpand(hyper([1] + [a]*10, [a + 1]*10, z)/a**10) == \ lerchphi(z, 10, a) assert combsimp( hyperexpand(meijerg([0, 1 - a], [], [0], [-a], exp_polar(-I * pi) * z))) == lerchphi(z, 1, a) assert combsimp( hyperexpand( meijerg([0, 1 - a, 1 - a], [], [0], [-a, -a], exp_polar(-I * pi) * z))) == lerchphi(z, 2, a) assert combsimp( hyperexpand( meijerg([0, 1 - a, 1 - a, 1 - a], [], [0], [-a, -a, -a], exp_polar(-I * pi) * z))) == lerchphi(z, 3, a) assert hyperexpand(z * hyper([1, 1], [2], z)) == -log(1 + -z) assert hyperexpand(z * hyper([1, 1, 1], [2, 2], z)) == polylog(2, z) assert hyperexpand(z * hyper([1, 1, 1, 1], [2, 2, 2], z)) == polylog(3, z) assert hyperexpand(hyper([1, a, 1 + Rational(1, 2)], [a + 1, Rational(1, 2)], z)) == \ -2*a/(z - 1) + (-2*a**2 + a)*lerchphi(z, 1, a) # Now numerical tests. These make sure reductions etc are carried out # correctly # a rational function (polylog at negative integer order) assert can_do([2, 2, 2], [1, 1]) # NOTE these contain log(1-x) etc ... better make sure we have |z| < 1 # reduction of order for polylog assert can_do([1, 1, 1, b + 5], [2, 2, b], div=10) # reduction of order for lerchphi # XXX lerchphi in mpmath is flaky assert can_do([1, a, a, a, b + 5], [a + 1, a + 1, a + 1, b], numerical=False) # test a bug from diofant import Abs assert hyperexpand(hyper([Rational(1, 2), Rational(1, 2), Rational(1, 2), 1], [Rational(3, 2), Rational(3, 2), Rational(3, 2)], Rational(1, 4))) == \ Abs(-polylog(3, exp_polar(I*pi)/2) + polylog(3, Rational(1, 2)))
def test_derivatives(): assert zeta(x, a).diff(x) == Derivative(zeta(x, a), x) assert zeta(x, a).diff(a) == -x * zeta(x + 1, a) assert zeta(z).diff(z) == Derivative(zeta(z), z) assert lerchphi( z, s, a).diff(z) == (lerchphi(z, s - 1, a) - a * lerchphi(z, s, a)) / z pytest.raises(ArgumentIndexError, lambda: lerchphi(z, s, a).fdiff(4)) assert lerchphi(z, s, a).diff(a) == -s * lerchphi(z, s + 1, a) assert polylog(s, z).diff(z) == polylog(s - 1, z) / z pytest.raises(ArgumentIndexError, lambda: polylog(s, z).fdiff(3)) b = randcplx() c = randcplx() assert td(zeta(b, x), x) assert td(polylog(b, z), z) assert td(lerchphi(c, b, x), x) assert td(lerchphi(x, b, c), x)
def test_derivatives(): assert zeta(x, a).diff(x) == Derivative(zeta(x, a), x) assert zeta(x, a).diff(a) == -x*zeta(x + 1, a) assert zeta(z).diff(z) == Derivative(zeta(z), z) assert lerchphi( z, s, a).diff(z) == (lerchphi(z, s - 1, a) - a*lerchphi(z, s, a))/z pytest.raises(ArgumentIndexError, lambda: lerchphi(z, s, a).fdiff(4)) assert lerchphi(z, s, a).diff(a) == -s*lerchphi(z, s + 1, a) assert polylog(s, z).diff(z) == polylog(s - 1, z)/z pytest.raises(ArgumentIndexError, lambda: polylog(s, z).fdiff(3)) b = randcplx() c = randcplx() assert td(zeta(b, x), x) assert td(polylog(b, z), z) assert td(lerchphi(c, b, x), x) assert td(lerchphi(x, b, c), x)
def test_derivatives(): assert zeta(x, a).diff(x) == Derivative(zeta(x, a), x) assert zeta(x, a).diff(a) == -x*zeta(x + 1, a) assert lerchphi( z, s, a).diff(z) == (lerchphi(z, s - 1, a) - a*lerchphi(z, s, a))/z assert lerchphi(z, s, a).diff(a) == -s*lerchphi(z, s + 1, a) assert polylog(s, z).diff(z) == polylog(s - 1, z)/z b = randcplx() c = randcplx() assert td(zeta(b, x), x) assert td(polylog(b, z), z) assert td(lerchphi(c, b, x), x) assert td(lerchphi(x, b, c), x)
def test_expint(): from diofant import E1, expint, Max, re, lerchphi, Symbol, simplify, Si, Ci, Ei aneg = Symbol('a', negative=True) u = Symbol('u', polar=True) assert mellin_transform(E1(x), x, s) == (gamma(s) / s, (0, oo), True) assert inverse_mellin_transform(gamma(s) / s, s, x, (0, oo)).rewrite(expint).expand() == E1(x) assert mellin_transform(expint(a, x), x, s) == \ (gamma(s)/(a + s - 1), (Max(1 - re(a), 0), oo), True) # XXX IMT has hickups with complicated strips ... assert simplify(unpolarify( inverse_mellin_transform(gamma(s)/(aneg + s - 1), s, x, (1 - aneg, oo)).rewrite(expint).expand(func=True))) == \ expint(aneg, x) assert mellin_transform(Si(x), x, s) == \ (-2**s*sqrt(pi)*gamma(s/2 + Rational(1, 2))/( 2*s*gamma(-s/2 + 1)), (-1, 0), True) assert inverse_mellin_transform(-2**s*sqrt(pi)*gamma((s + 1)/2) / (2*s*gamma(-s/2 + 1)), s, x, (-1, 0)) \ == Si(x) assert mellin_transform(Ci(sqrt(x)), x, s) == \ (-2**(2*s - 1)*sqrt(pi)*gamma(s)/(s*gamma(-s + Rational(1, 2))), (0, 1), True) assert inverse_mellin_transform( -4**s * sqrt(pi) * gamma(s) / (2 * s * gamma(-s + Rational(1, 2))), s, u, (0, 1)).expand() == Ci(sqrt(u)) # TODO LT of Si, Shi, Chi is a mess ... assert laplace_transform(Ci(x), x, s) == (-log(1 + s**2) / 2 / s, 0, True) assert laplace_transform(expint(a, x), x, s) == \ (lerchphi(s*polar_lift(-1), 1, a), 0, Integer(0) < re(a)) assert laplace_transform(expint(1, x), x, s) == (log(s + 1) / s, 0, True) assert laplace_transform(expint(2, x), x, s) == \ ((s - log(s + 1))/s**2, 0, True) assert inverse_laplace_transform(-log(1 + s**2)/2/s, s, u).expand() == \ Heaviside(u)*Ci(u) assert inverse_laplace_transform(log(s + 1)/s, s, x).rewrite(expint) == \ Heaviside(x)*E1(x) assert inverse_laplace_transform((s - log(s + 1))/s**2, s, x).rewrite(expint).expand() == \ (expint(2, x)*Heaviside(x)).rewrite(Ei).rewrite(expint).expand()
def test_lerchphi(): assert hyperexpand(hyper([1, a], [a + 1], z)/a) == lerchphi(z, 1, a) assert hyperexpand( hyper([1, a, a], [a + 1, a + 1], z)/a**2) == lerchphi(z, 2, a) assert hyperexpand(hyper([1, a, a, a], [a + 1, a + 1, a + 1], z)/a**3) == \ lerchphi(z, 3, a) assert hyperexpand(hyper([1] + [a]*10, [a + 1]*10, z)/a**10) == \ lerchphi(z, 10, a) assert combsimp(hyperexpand(meijerg([0, 1 - a], [], [0], [-a], exp_polar(-I*pi)*z))) == lerchphi(z, 1, a) assert combsimp(hyperexpand(meijerg([0, 1 - a, 1 - a], [], [0], [-a, -a], exp_polar(-I*pi)*z))) == lerchphi(z, 2, a) assert combsimp(hyperexpand(meijerg([0, 1 - a, 1 - a, 1 - a], [], [0], [-a, -a, -a], exp_polar(-I*pi)*z))) == lerchphi(z, 3, a) assert hyperexpand(z*hyper([1, 1], [2], z)) == -log(1 + -z) assert hyperexpand(z*hyper([1, 1, 1], [2, 2], z)) == polylog(2, z) assert hyperexpand(z*hyper([1, 1, 1, 1], [2, 2, 2], z)) == polylog(3, z) assert hyperexpand(hyper([1, a, 1 + Rational(1, 2)], [a + 1, Rational(1, 2)], z)) == \ -2*a/(z - 1) + (-2*a**2 + a)*lerchphi(z, 1, a) # Now numerical tests. These make sure reductions etc are carried out # correctly # a rational function (polylog at negative integer order) assert can_do([2, 2, 2], [1, 1]) # NOTE these contain log(1-x) etc ... better make sure we have |z| < 1 # reduction of order for polylog assert can_do([1, 1, 1, b + 5], [2, 2, b], div=10) # reduction of order for lerchphi # XXX lerchphi in mpmath is flaky assert can_do( [1, a, a, a, b + 5], [a + 1, a + 1, a + 1, b], numerical=False) # test a bug assert hyperexpand(hyper([Rational(1, 2), Rational(1, 2), Rational(1, 2), 1], [Rational(3, 2), Rational(3, 2), Rational(3, 2)], Rational(1, 4))) == \ abs(-polylog(3, exp_polar(I*pi)/2) + polylog(3, Rational(1, 2)))
def test_expint(): aneg = Symbol('a', negative=True) u = Symbol('u', polar=True) assert mellin_transform(E1(x), x, s) == (gamma(s)/s, (0, oo), True) assert inverse_mellin_transform(gamma(s)/s, s, x, (0, oo)).rewrite(expint).expand() == E1(x) assert mellin_transform(expint(a, x), x, s) == \ (gamma(s)/(a + s - 1), (Max(1 - re(a), 0), oo), True) # XXX IMT has hickups with complicated strips ... assert simplify(unpolarify( inverse_mellin_transform(gamma(s)/(aneg + s - 1), s, x, (1 - aneg, oo)).rewrite(expint).expand(func=True))) == \ expint(aneg, x) assert mellin_transform(Si(x), x, s) == \ (-2**s*sqrt(pi)*gamma(s/2 + Rational(1, 2))/( 2*s*gamma(-s/2 + 1)), (-1, 0), True) assert inverse_mellin_transform(-2**s*sqrt(pi)*gamma((s + 1)/2) / (2*s*gamma(-s/2 + 1)), s, x, (-1, 0)) \ == Si(x) assert mellin_transform(Ci(sqrt(x)), x, s) == \ (-2**(2*s - 1)*sqrt(pi)*gamma(s)/(s*gamma(-s + Rational(1, 2))), (0, 1), True) assert inverse_mellin_transform( -4**s*sqrt(pi)*gamma(s)/(2*s*gamma(-s + Rational(1, 2))), s, u, (0, 1)).expand() == Ci(sqrt(u)) # TODO LT of Si, Shi, Chi is a mess ... assert laplace_transform(Ci(x), x, s) == (-log(1 + s**2)/2/s, 0, True) assert laplace_transform(expint(a, x), x, s) == \ (lerchphi(s*polar_lift(-1), 1, a), 0, Integer(0) < re(a)) assert laplace_transform(expint(1, x), x, s) == (log(s + 1)/s, 0, True) assert laplace_transform(expint(2, x), x, s) == \ ((s - log(s + 1))/s**2, 0, True) assert inverse_laplace_transform(-log(1 + s**2)/2/s, s, u).expand() == \ Heaviside(u)*Ci(u) assert inverse_laplace_transform(log(s + 1)/s, s, x).rewrite(expint) == \ Heaviside(x)*E1(x) assert inverse_laplace_transform((s - log(s + 1))/s**2, s, x).rewrite(expint).expand() == \ (expint(2, x)*Heaviside(x)).rewrite(Ei).rewrite(expint).expand()
def test_rewriting(): assert dirichlet_eta(x).rewrite(zeta) == (1 - 2**(1 - x))*zeta(x) assert zeta(x).rewrite(dirichlet_eta) == dirichlet_eta(x)/(1 - 2**(1 - x)) assert zeta(z, 2).rewrite(dirichlet_eta) == zeta(z, 2) assert zeta(z, 2).rewrite('tractable') == zeta(z, 2) assert tn(dirichlet_eta(x), dirichlet_eta(x).rewrite(zeta), x) assert tn(zeta(x), zeta(x).rewrite(dirichlet_eta), x) assert zeta(x, a).rewrite(lerchphi) == lerchphi(1, x, a) assert polylog(s, z).rewrite(lerchphi) == lerchphi(z, s, 1)*z assert lerchphi(1, x, a).rewrite(zeta) == zeta(x, a) assert z*lerchphi(z, s, 1).rewrite(polylog) == polylog(s, z) assert lerchphi(z, s, a).rewrite(zeta) == lerchphi(z, s, a)
def test_lerchphi_expansion(): assert myexpand(lerchphi(1, s, a), zeta(s, a)) assert myexpand(lerchphi(z, s, 1), polylog(s, z) / z) # direct summation assert myexpand(lerchphi(z, -1, a), a / (1 - z) + z / (1 - z)**2) assert myexpand(lerchphi(z, -3, a), None) # polylog reduction assert myexpand( lerchphi(z, s, Rational(1, 2)), 2**(s - 1) * (polylog(s, sqrt(z)) / sqrt(z) - polylog(s, polar_lift(-1) * sqrt(z)) / sqrt(z))) assert myexpand(lerchphi(z, s, 2), -1 / z + polylog(s, z) / z**2) assert myexpand(lerchphi(z, s, Rational(3, 2)), None) assert myexpand(lerchphi(z, s, Rational(7, 3)), None) assert myexpand(lerchphi(z, s, -Rational(1, 3)), None) assert myexpand(lerchphi(z, s, -Rational(5, 2)), None) # hurwitz zeta reduction assert myexpand(lerchphi(-1, s, a), 2**(-s) * zeta(s, a / 2) - 2**(-s) * zeta(s, (a + 1) / 2)) assert myexpand(lerchphi(I, s, a), None) assert myexpand(lerchphi(-I, s, a), None) assert myexpand(lerchphi(exp(2 * I * pi / 5), s, a), None)
def test_lerchphi_expansion(): assert myexpand(lerchphi(1, s, a), zeta(s, a)) assert myexpand(lerchphi(z, s, 1), polylog(s, z)/z) # direct summation assert myexpand(lerchphi(z, -1, a), a/(1 - z) + z/(1 - z)**2) assert myexpand(lerchphi(z, -3, a), None) # polylog reduction assert myexpand(lerchphi(z, s, Rational(1, 2)), 2**(s - 1)*(polylog(s, sqrt(z))/sqrt(z) - polylog(s, polar_lift(-1)*sqrt(z))/sqrt(z))) assert myexpand(lerchphi(z, s, 2), -1/z + polylog(s, z)/z**2) assert myexpand(lerchphi(z, s, Rational(3, 2)), None) assert myexpand(lerchphi(z, s, Rational(7, 3)), None) assert myexpand(lerchphi(z, s, -Rational(1, 3)), None) assert myexpand(lerchphi(z, s, -Rational(5, 2)), None) # hurwitz zeta reduction assert myexpand(lerchphi(-1, s, a), 2**(-s)*zeta(s, a/2) - 2**(-s)*zeta(s, (a + 1)/2)) assert myexpand(lerchphi(I, s, a), None) assert myexpand(lerchphi(-I, s, a), None) assert myexpand(lerchphi(exp(2*I*pi/5), s, a), None)