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llm_tutorial / .venv /lib /python3.11 /site-packages /mpmath /functions /bessel.py
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from .functions import defun, defun_wrapped
@defun
def j0(ctx, x):
 """Computes the Bessel function `J_0(x)`. See :func:`~mpmath.besselj`."""
 return ctx.besselj(0, x)
@defun
def j1(ctx, x):
 """Computes the Bessel function `J_1(x)`. See :func:`~mpmath.besselj`."""
 return ctx.besselj(1, x)
@defun
def besselj(ctx, n, z, derivative=0, **kwargs):
 if type(n) is int:
 n_isint = True
 else:
 n = ctx.convert(n)
 n_isint = ctx.isint(n)
 if n_isint:
 n = int(ctx._re(n))
 if n_isint and n < 0:
 return (-1)**n * ctx.besselj(-n, z, derivative, **kwargs)
 z = ctx.convert(z)
 M = ctx.mag(z)
 if derivative:
 d = ctx.convert(derivative)
 # TODO: the integer special-casing shouldn't be necessary.
 # However, the hypergeometric series gets inaccurate for large d
 # because of inaccurate pole cancellation at a pole far from
 # zero (needs to be fixed in hypercomb or hypsum)
 if ctx.isint(d) and d >= 0:
 d = int(d)
 orig = ctx.prec
 try:
 ctx.prec += 15
 v = ctx.fsum((-1)**k * ctx.binomial(d,k) * ctx.besselj(2*k+n-d,z)
 for k in range(d+1))
 finally:
 ctx.prec = orig
 v *= ctx.mpf(2)**(-d)
 else:
 def h(n,d):
 r = ctx.fmul(ctx.fmul(z, z, prec=ctx.prec+M), -0.25, exact=True)
 B = [0.5*(n-d+1), 0.5*(n-d+2)]
 T = [([2,ctx.pi,z],[d-2*n,0.5,n-d],[],B,[(n+1)*0.5,(n+2)*0.5],B+[n+1],r)]
 return T
 v = ctx.hypercomb(h, [n,d], **kwargs)
 else:
 # Fast case: J_n(x), n int, appropriate magnitude for fixed-point calculation
 if (not derivative) and n_isint and abs(M) < 10 and abs(n) < 20:
 try:
 return ctx._besselj(n, z)
 except NotImplementedError:
 pass
 if not z:
 if not n:
 v = ctx.one + n+z
 elif ctx.re(n) > 0:
 v = n*z
 else:
 v = ctx.inf + z + n
 else:
 #v = 0
 orig = ctx.prec
 try:
 # XXX: workaround for accuracy in low level hypergeometric series
 # when alternating, large arguments
 ctx.prec += min(3*abs(M), ctx.prec)
 w = ctx.fmul(z, 0.5, exact=True)
 def h(n):
 r = ctx.fneg(ctx.fmul(w, w, prec=max(0,ctx.prec+M)), exact=True)
 return [([w], [n], [], [n+1], [], [n+1], r)]
 v = ctx.hypercomb(h, [n], **kwargs)
 finally:
 ctx.prec = orig
 v = +v
 return v
@defun
def besseli(ctx, n, z, derivative=0, **kwargs):
 n = ctx.convert(n)
 z = ctx.convert(z)
 if not z:
 if derivative:
 raise ValueError
 if not n:
 # I(0,0) = 1
 return 1+n+z
 if ctx.isint(n):
 return 0*(n+z)
 r = ctx.re(n)
 if r == 0:
 return ctx.nan*(n+z)
 elif r > 0:
 return 0*(n+z)
 else:
 return ctx.inf+(n+z)
 M = ctx.mag(z)
 if derivative:
 d = ctx.convert(derivative)
 def h(n,d):
 r = ctx.fmul(ctx.fmul(z, z, prec=ctx.prec+M), 0.25, exact=True)
 B = [0.5*(n-d+1), 0.5*(n-d+2), n+1]
 T = [([2,ctx.pi,z],[d-2*n,0.5,n-d],[n+1],B,[(n+1)*0.5,(n+2)*0.5],B,r)]
 return T
 v = ctx.hypercomb(h, [n,d], **kwargs)
 else:
 def h(n):
 w = ctx.fmul(z, 0.5, exact=True)
 r = ctx.fmul(w, w, prec=max(0,ctx.prec+M))
 return [([w], [n], [], [n+1], [], [n+1], r)]
 v = ctx.hypercomb(h, [n], **kwargs)
 return v
@defun_wrapped
def bessely(ctx, n, z, derivative=0, **kwargs):
 if not z:
 if derivative:
 # Not implemented
 raise ValueError
 if not n:
 # ~ log(z/2)
 return -ctx.inf + (n+z)
 if ctx.im(n):
 return ctx.nan * (n+z)
 r = ctx.re(n)
 q = n+0.5
 if ctx.isint(q):
 if n > 0:
 return -ctx.inf + (n+z)
 else:
 return 0 * (n+z)
 if r < 0 and int(ctx.floor(q)) % 2:
 return ctx.inf + (n+z)
 else:
 return ctx.ninf + (n+z)
 # XXX: use hypercomb
 ctx.prec += 10
 m, d = ctx.nint_distance(n)
 if d < -ctx.prec:
 h = +ctx.eps
 ctx.prec *= 2
 n += h
 elif d < 0:
 ctx.prec -= d
 # TODO: avoid cancellation for imaginary arguments
 cos, sin = ctx.cospi_sinpi(n)
 return (ctx.besselj(n,z,derivative,**kwargs)*cos - \
 ctx.besselj(-n,z,derivative,**kwargs))/sin
@defun_wrapped
def besselk(ctx, n, z, **kwargs):
 if not z:
 return ctx.inf
 M = ctx.mag(z)
 if M < 1:
 # Represent as limit definition
 def h(n):
 r = (z/2)**2
 T1 = [z, 2], [-n, n-1], [n], [], [], [1-n], r
 T2 = [z, 2], [n, -n-1], [-n], [], [], [1+n], r
 return T1, T2
 # We could use the limit definition always, but it leads
 # to very bad cancellation (of exponentially large terms)
 # for large real z
 # Instead represent in terms of 2F0
 else:
 ctx.prec += M
 def h(n):
 return [([ctx.pi/2, z, ctx.exp(-z)], [0.5,-0.5,1], [], [], \
 [n+0.5, 0.5-n], [], -1/(2*z))]
 return ctx.hypercomb(h, [n], **kwargs)
@defun_wrapped
def hankel1(ctx,n,x,**kwargs):
 return ctx.besselj(n,x,**kwargs) + ctx.j*ctx.bessely(n,x,**kwargs)
@defun_wrapped
def hankel2(ctx,n,x,**kwargs):
 return ctx.besselj(n,x,**kwargs) - ctx.j*ctx.bessely(n,x,**kwargs)
@defun_wrapped
def whitm(ctx,k,m,z,**kwargs):
 if z == 0:
 # M(k,m,z) = 0^(1/2+m)
 if ctx.re(m) > -0.5:
 return z
 elif ctx.re(m) < -0.5:
 return ctx.inf + z
 else:
 return ctx.nan * z
 x = ctx.fmul(-0.5, z, exact=True)
 y = 0.5+m
 return ctx.exp(x) * z**y * ctx.hyp1f1(y-k, 1+2*m, z, **kwargs)
@defun_wrapped
def whitw(ctx,k,m,z,**kwargs):
 if z == 0:
 g = abs(ctx.re(m))
 if g < 0.5:
 return z
 elif g > 0.5:
 return ctx.inf + z
 else:
 return ctx.nan * z
 x = ctx.fmul(-0.5, z, exact=True)
 y = 0.5+m
 return ctx.exp(x) * z**y * ctx.hyperu(y-k, 1+2*m, z, **kwargs)
@defun
def hyperu(ctx, a, b, z, **kwargs):
 a, atype = ctx._convert_param(a)
 b, btype = ctx._convert_param(b)
 z = ctx.convert(z)
 if not z:
 if ctx.re(b) <= 1:
 return ctx.gammaprod([1-b],[a-b+1])
 else:
 return ctx.inf + z
 bb = 1+a-b
 bb, bbtype = ctx._convert_param(bb)
 try:
 orig = ctx.prec
 try:
 ctx.prec += 10
 v = ctx.hypsum(2, 0, (atype, bbtype), [a, bb], -1/z, maxterms=ctx.prec)
 return v / z**a
 finally:
 ctx.prec = orig
 except ctx.NoConvergence:
 pass
 def h(a,b):
 w = ctx.sinpi(b)
 T1 = ([ctx.pi,w],[1,-1],[],[a-b+1,b],[a],[b],z)
 T2 = ([-ctx.pi,w,z],[1,-1,1-b],[],[a,2-b],[a-b+1],[2-b],z)
 return T1, T2
 return ctx.hypercomb(h, [a,b], **kwargs)
@defun
def struveh(ctx,n,z, **kwargs):
 n = ctx.convert(n)
 z = ctx.convert(z)
 # http://functions.wolfram.com/Bessel-TypeFunctions/StruveH/26/01/02/
 def h(n):
 return [([z/2, 0.5*ctx.sqrt(ctx.pi)], [n+1, -1], [], [n+1.5], [1], [1.5, n+1.5], -(z/2)**2)]
 return ctx.hypercomb(h, [n], **kwargs)
@defun
def struvel(ctx,n,z, **kwargs):
 n = ctx.convert(n)
 z = ctx.convert(z)
 # http://functions.wolfram.com/Bessel-TypeFunctions/StruveL/26/01/02/
 def h(n):
 return [([z/2, 0.5*ctx.sqrt(ctx.pi)], [n+1, -1], [], [n+1.5], [1], [1.5, n+1.5], (z/2)**2)]
 return ctx.hypercomb(h, [n], **kwargs)
def _anger(ctx,which,v,z,**kwargs):
 v = ctx._convert_param(v)[0]
 z = ctx.convert(z)
 def h(v):
 b = ctx.mpq_1_2
 u = v*b
 m = b*3
 a1,a2,b1,b2 = m-u, m+u, 1-u, 1+u
 c, s = ctx.cospi_sinpi(u)
 if which == 0:
 A, B = [b*z, s], [c]
 if which == 1:
 A, B = [b*z, -c], [s]
 w = ctx.square_exp_arg(z, mult=-0.25)
 T1 = A, [1, 1], [], [a1,a2], [1], [a1,a2], w
 T2 = B, [1], [], [b1,b2], [1], [b1,b2], w
 return T1, T2
 return ctx.hypercomb(h, [v], **kwargs)
@defun
def angerj(ctx, v, z, **kwargs):
 return _anger(ctx, 0, v, z, **kwargs)
@defun
def webere(ctx, v, z, **kwargs):
 return _anger(ctx, 1, v, z, **kwargs)
@defun
def lommels1(ctx, u, v, z, **kwargs):
 u = ctx._convert_param(u)[0]
 v = ctx._convert_param(v)[0]
 z = ctx.convert(z)
 def h(u,v):
 b = ctx.mpq_1_2
 w = ctx.square_exp_arg(z, mult=-0.25)
 return ([u-v+1, u+v+1, z], [-1, -1, u+1], [], [], [1], \
 [b*(u-v+3),b*(u+v+3)], w),
 return ctx.hypercomb(h, [u,v], **kwargs)
@defun
def lommels2(ctx, u, v, z, **kwargs):
 u = ctx._convert_param(u)[0]
 v = ctx._convert_param(v)[0]
 z = ctx.convert(z)
 # Asymptotic expansion (GR p. 947) -- need to be careful
 # not to use for small arguments
 # def h(u,v):
 # b = ctx.mpq_1_2
 # w = -(z/2)**(-2)
 # return ([z], [u-1], [], [], [b*(1-u+v)], [b*(1-u-v)], w),
 def h(u,v):
 b = ctx.mpq_1_2
 w = ctx.square_exp_arg(z, mult=-0.25)
 T1 = [u-v+1, u+v+1, z], [-1, -1, u+1], [], [], [1], [b*(u-v+3),b*(u+v+3)], w
 T2 = [2, z], [u+v-1, -v], [v, b*(u+v+1)], [b*(v-u+1)], [], [1-v], w
 T3 = [2, z], [u-v-1, v], [-v, b*(u-v+1)], [b*(1-u-v)], [], [1+v], w
 #c1 = ctx.cospi((u-v)*b)
 #c2 = ctx.cospi((u+v)*b)
 #s = ctx.sinpi(v)
 #r1 = (u-v+1)*b
 #r2 = (u+v+1)*b
 #T2 = [c1, s, z, 2], [1, -1, -v, v], [], [-v+1], [], [-v+1], w
 #T3 = [-c2, s, z, 2], [1, -1, v, -v], [], [v+1], [], [v+1], w
 #T2 = [c1, s, z, 2], [1, -1, -v, v+u-1], [r1, r2], [-v+1], [], [-v+1], w
 #T3 = [-c2, s, z, 2], [1, -1, v, -v+u-1], [r1, r2], [v+1], [], [v+1], w
 return T1, T2, T3
 return ctx.hypercomb(h, [u,v], **kwargs)
@defun
def ber(ctx, n, z, **kwargs):
 n = ctx.convert(n)
 z = ctx.convert(z)
 # http://functions.wolfram.com/Bessel-TypeFunctions/KelvinBer2/26/01/02/0001/
 def h(n):
 r = -(z/4)**4
 cos, sin = ctx.cospi_sinpi(-0.75*n)
 T1 = [cos, z/2], [1, n], [], [n+1], [], [0.5, 0.5*(n+1), 0.5*n+1], r
 T2 = [sin, z/2], [1, n+2], [], [n+2], [], [1.5, 0.5*(n+3), 0.5*n+1], r
 return T1, T2
 return ctx.hypercomb(h, [n], **kwargs)
@defun
def bei(ctx, n, z, **kwargs):
 n = ctx.convert(n)
 z = ctx.convert(z)
 # http://functions.wolfram.com/Bessel-TypeFunctions/KelvinBei2/26/01/02/0001/
 def h(n):
 r = -(z/4)**4
 cos, sin = ctx.cospi_sinpi(0.75*n)
 T1 = [cos, z/2], [1, n+2], [], [n+2], [], [1.5, 0.5*(n+3), 0.5*n+1], r
 T2 = [sin, z/2], [1, n], [], [n+1], [], [0.5, 0.5*(n+1), 0.5*n+1], r
 return T1, T2
 return ctx.hypercomb(h, [n], **kwargs)
@defun
def ker(ctx, n, z, **kwargs):
 n = ctx.convert(n)
 z = ctx.convert(z)
 # http://functions.wolfram.com/Bessel-TypeFunctions/KelvinKer2/26/01/02/0001/
 def h(n):
 r = -(z/4)**4
 cos1, sin1 = ctx.cospi_sinpi(0.25*n)
 cos2, sin2 = ctx.cospi_sinpi(0.75*n)
 T1 = [2, z, 4*cos1], [-n-3, n, 1], [-n], [], [], [0.5, 0.5*(1+n), 0.5*(n+2)], r
 T2 = [2, z, -sin1], [-n-3, 2+n, 1], [-n-1], [], [], [1.5, 0.5*(3+n), 0.5*(n+2)], r
 T3 = [2, z, 4*cos2], [n-3, -n, 1], [n], [], [], [0.5, 0.5*(1-n), 1-0.5*n], r
 T4 = [2, z, -sin2], [n-3, 2-n, 1], [n-1], [], [], [1.5, 0.5*(3-n), 1-0.5*n], r
 return T1, T2, T3, T4
 return ctx.hypercomb(h, [n], **kwargs)
@defun
def kei(ctx, n, z, **kwargs):
 n = ctx.convert(n)
 z = ctx.convert(z)
 # http://functions.wolfram.com/Bessel-TypeFunctions/KelvinKei2/26/01/02/0001/
 def h(n):
 r = -(z/4)**4
 cos1, sin1 = ctx.cospi_sinpi(0.75*n)
 cos2, sin2 = ctx.cospi_sinpi(0.25*n)
 T1 = [-cos1, 2, z], [1, n-3, 2-n], [n-1], [], [], [1.5, 0.5*(3-n), 1-0.5*n], r
 T2 = [-sin1, 2, z], [1, n-1, -n], [n], [], [], [0.5, 0.5*(1-n), 1-0.5*n], r
 T3 = [-sin2, 2, z], [1, -n-1, n], [-n], [], [], [0.5, 0.5*(n+1), 0.5*(n+2)], r
 T4 = [-cos2, 2, z], [1, -n-3, n+2], [-n-1], [], [], [1.5, 0.5*(n+3), 0.5*(n+2)], r
 return T1, T2, T3, T4
 return ctx.hypercomb(h, [n], **kwargs)
# TODO: do this more generically?
def c_memo(f):
 name = f.__name__
 def f_wrapped(ctx):
 cache = ctx._misc_const_cache
 prec = ctx.prec
 p,v = cache.get(name, (-1,0))
 if p >= prec:
 return +v
 else:
 cache[name] = (prec, f(ctx))
 return cache[name][1]
 return f_wrapped
@c_memo
def _airyai_C1(ctx):
 return 1 / (ctx.cbrt(9) * ctx.gamma(ctx.mpf(2)/3))
@c_memo
def _airyai_C2(ctx):
 return -1 / (ctx.cbrt(3) * ctx.gamma(ctx.mpf(1)/3))
@c_memo
def _airybi_C1(ctx):
 return 1 / (ctx.nthroot(3,6) * ctx.gamma(ctx.mpf(2)/3))
@c_memo
def _airybi_C2(ctx):
 return ctx.nthroot(3,6) / ctx.gamma(ctx.mpf(1)/3)
def _airybi_n2_inf(ctx):
 prec = ctx.prec
 try:
 v = ctx.power(3,'2/3')*ctx.gamma('2/3')/(2*ctx.pi)
 finally:
 ctx.prec = prec
 return +v
# Derivatives at z = 0
# TODO: could be expressed more elegantly using triple factorials
def _airyderiv_0(ctx, z, n, ntype, which):
 if ntype == 'Z':
 if n < 0:
 return z
 r = ctx.mpq_1_3
 prec = ctx.prec
 try:
 ctx.prec += 10
 v = ctx.gamma((n+1)*r) * ctx.power(3,n*r) / ctx.pi
 if which == 0:
 v *= ctx.sinpi(2*(n+1)*r)
 v /= ctx.power(3,'2/3')
 else:
 v *= abs(ctx.sinpi(2*(n+1)*r))
 v /= ctx.power(3,'1/6')
 finally:
 ctx.prec = prec
 return +v + z
 else:
 # singular (does the limit exist?)
 raise NotImplementedError
@defun
def airyai(ctx, z, derivative=0, **kwargs):
 z = ctx.convert(z)
 if derivative:
 n, ntype = ctx._convert_param(derivative)
 else:
 n = 0
 # Values at infinities
 if not ctx.isnormal(z) and z:
 if n and ntype == 'Z':
 if n == -1:
 if z == ctx.inf:
 return ctx.mpf(1)/3 + 1/z
 if z == ctx.ninf:
 return ctx.mpf(-2)/3 + 1/z
 if n < -1:
 if z == ctx.inf:
 return z
 if z == ctx.ninf:
 return (-1)**n * (-z)
 if (not n) and z == ctx.inf or z == ctx.ninf:
 return 1/z
 # TODO: limits
 raise ValueError("essential singularity of Ai(z)")
 # Account for exponential scaling
 if z:
 extraprec = max(0, int(1.5*ctx.mag(z)))
 else:
 extraprec = 0
 if n:
 if n == 1:
 def h():
 # http://functions.wolfram.com/03.07.06.0005.01
 if ctx._re(z) > 4:
 ctx.prec += extraprec
 w = z**1.5; r = -0.75/w; u = -2*w/3
 ctx.prec -= extraprec
 C = -ctx.exp(u)/(2*ctx.sqrt(ctx.pi))*ctx.nthroot(z,4)
 return ([C],[1],[],[],[(-1,6),(7,6)],[],r),
 # http://functions.wolfram.com/03.07.26.0001.01
 else:
 ctx.prec += extraprec
 w = z**3 / 9
 ctx.prec -= extraprec
 C1 = _airyai_C1(ctx) * 0.5
 C2 = _airyai_C2(ctx)
 T1 = [C1,z],[1,2],[],[],[],[ctx.mpq_5_3],w
 T2 = [C2],[1],[],[],[],[ctx.mpq_1_3],w
 return T1, T2
 return ctx.hypercomb(h, [], **kwargs)
 else:
 if z == 0:
 return _airyderiv_0(ctx, z, n, ntype, 0)
 # http://functions.wolfram.com/03.05.20.0004.01
 def h(n):
 ctx.prec += extraprec
 w = z**3/9
 ctx.prec -= extraprec
 q13,q23,q43 = ctx.mpq_1_3, ctx.mpq_2_3, ctx.mpq_4_3
 a1=q13; a2=1; b1=(1-n)*q13; b2=(2-n)*q13; b3=1-n*q13
 T1 = [3, z], [n-q23, -n], [a1], [b1,b2,b3], \
 [a1,a2], [b1,b2,b3], w
 a1=q23; b1=(2-n)*q13; b2=1-n*q13; b3=(4-n)*q13
 T2 = [3, z, -z], [n-q43, -n, 1], [a1], [b1,b2,b3], \
 [a1,a2], [b1,b2,b3], w
 return T1, T2
 v = ctx.hypercomb(h, [n], **kwargs)
 if ctx._is_real_type(z) and ctx.isint(n):
 v = ctx._re(v)
 return v
 else:
 def h():
 if ctx._re(z) > 4:
 # We could use 1F1, but it results in huge cancellation;
 # the following expansion is better.
 # TODO: asymptotic series for derivatives
 ctx.prec += extraprec
 w = z**1.5; r = -0.75/w; u = -2*w/3
 ctx.prec -= extraprec
 C = ctx.exp(u)/(2*ctx.sqrt(ctx.pi)*ctx.nthroot(z,4))
 return ([C],[1],[],[],[(1,6),(5,6)],[],r),
 else:
 ctx.prec += extraprec
 w = z**3 / 9
 ctx.prec -= extraprec
 C1 = _airyai_C1(ctx)
 C2 = _airyai_C2(ctx)
 T1 = [C1],[1],[],[],[],[ctx.mpq_2_3],w
 T2 = [z*C2],[1],[],[],[],[ctx.mpq_4_3],w
 return T1, T2
 return ctx.hypercomb(h, [], **kwargs)
@defun
def airybi(ctx, z, derivative=0, **kwargs):
 z = ctx.convert(z)
 if derivative:
 n, ntype = ctx._convert_param(derivative)
 else:
 n = 0
 # Values at infinities
 if not ctx.isnormal(z) and z:
 if n and ntype == 'Z':
 if z == ctx.inf:
 return z
 if z == ctx.ninf:
 if n == -1:
 return 1/z
 if n == -2:
 return _airybi_n2_inf(ctx)
 if n < -2:
 return (-1)**n * (-z)
 if not n:
 if z == ctx.inf:
 return z
 if z == ctx.ninf:
 return 1/z
 # TODO: limits
 raise ValueError("essential singularity of Bi(z)")
 if z:
 extraprec = max(0, int(1.5*ctx.mag(z)))
 else:
 extraprec = 0
 if n:
 if n == 1:
 # http://functions.wolfram.com/03.08.26.0001.01
 def h():
 ctx.prec += extraprec
 w = z**3 / 9
 ctx.prec -= extraprec
 C1 = _airybi_C1(ctx)*0.5
 C2 = _airybi_C2(ctx)
 T1 = [C1,z],[1,2],[],[],[],[ctx.mpq_5_3],w
 T2 = [C2],[1],[],[],[],[ctx.mpq_1_3],w
 return T1, T2
 return ctx.hypercomb(h, [], **kwargs)
 else:
 if z == 0:
 return _airyderiv_0(ctx, z, n, ntype, 1)
 def h(n):
 ctx.prec += extraprec
 w = z**3/9
 ctx.prec -= extraprec
 q13,q23,q43 = ctx.mpq_1_3, ctx.mpq_2_3, ctx.mpq_4_3
 q16 = ctx.mpq_1_6
 q56 = ctx.mpq_5_6
 a1=q13; a2=1; b1=(1-n)*q13; b2=(2-n)*q13; b3=1-n*q13
 T1 = [3, z], [n-q16, -n], [a1], [b1,b2,b3], \
 [a1,a2], [b1,b2,b3], w
 a1=q23; b1=(2-n)*q13; b2=1-n*q13; b3=(4-n)*q13
 T2 = [3, z], [n-q56, 1-n], [a1], [b1,b2,b3], \
 [a1,a2], [b1,b2,b3], w
 return T1, T2
 v = ctx.hypercomb(h, [n], **kwargs)
 if ctx._is_real_type(z) and ctx.isint(n):
 v = ctx._re(v)
 return v
 else:
 def h():
 ctx.prec += extraprec
 w = z**3 / 9
 ctx.prec -= extraprec
 C1 = _airybi_C1(ctx)
 C2 = _airybi_C2(ctx)
 T1 = [C1],[1],[],[],[],[ctx.mpq_2_3],w
 T2 = [z*C2],[1],[],[],[],[ctx.mpq_4_3],w
 return T1, T2
 return ctx.hypercomb(h, [], **kwargs)
def _airy_zero(ctx, which, k, derivative, complex=False):
 # Asymptotic formulas are given in DLMF section 9.9
 def U(t): return t**(2/3.)*(1-7/(t**2*48))
 def T(t): return t**(2/3.)*(1+5/(t**2*48))
 k = int(k)
 if k < 1:
 raise ValueError("k cannot be less than 1")
 if not derivative in (0,1):
 raise ValueError("Derivative should lie between 0 and 1")
 if which == 0:
 if derivative:
 return ctx.findroot(lambda z: ctx.airyai(z,1),
 -U(3*ctx.pi*(4*k-3)/8))
 return ctx.findroot(ctx.airyai, -T(3*ctx.pi*(4*k-1)/8))
 if which == 1 and complex == False:
 if derivative:
 return ctx.findroot(lambda z: ctx.airybi(z,1),
 -U(3*ctx.pi*(4*k-1)/8))
 return ctx.findroot(ctx.airybi, -T(3*ctx.pi*(4*k-3)/8))
 if which == 1 and complex == True:
 if derivative:
 t = 3*ctx.pi*(4*k-3)/8 + 0.75j*ctx.ln2
 s = ctx.expjpi(ctx.mpf(1)/3) * T(t)
 return ctx.findroot(lambda z: ctx.airybi(z,1), s)
 t = 3*ctx.pi*(4*k-1)/8 + 0.75j*ctx.ln2
 s = ctx.expjpi(ctx.mpf(1)/3) * U(t)
 return ctx.findroot(ctx.airybi, s)
@defun
def airyaizero(ctx, k, derivative=0):
 return _airy_zero(ctx, 0, k, derivative, False)
@defun
def airybizero(ctx, k, derivative=0, complex=False):
 return _airy_zero(ctx, 1, k, derivative, complex)
def _scorer(ctx, z, which, kwargs):
 z = ctx.convert(z)
 if ctx.isinf(z):
 if z == ctx.inf:
 if which == 0: return 1/z
 if which == 1: return z
 if z == ctx.ninf:
 return 1/z
 raise ValueError("essential singularity")
 if z:
 extraprec = max(0, int(1.5*ctx.mag(z)))
 else:
 extraprec = 0
 if kwargs.get('derivative'):
 raise NotImplementedError
 # Direct asymptotic expansions, to avoid
 # exponentially large cancellation
 try:
 if ctx.mag(z) > 3:
 if which == 0 and abs(ctx.arg(z)) < ctx.pi/3 * 0.999:
 def h():
 return (([ctx.pi,z],[-1,-1],[],[],[(1,3),(2,3),1],[],9/z**3),)
 return ctx.hypercomb(h, [], maxterms=ctx.prec, force_series=True)
 if which == 1 and abs(ctx.arg(-z)) < 2*ctx.pi/3 * 0.999:
 def h():
 return (([-ctx.pi,z],[-1,-1],[],[],[(1,3),(2,3),1],[],9/z**3),)
 return ctx.hypercomb(h, [], maxterms=ctx.prec, force_series=True)
 except ctx.NoConvergence:
 pass
 def h():
 A = ctx.airybi(z, **kwargs)/3
 B = -2*ctx.pi
 if which == 1:
 A *= 2
 B *= -1
 ctx.prec += extraprec
 w = z**3/9
 ctx.prec -= extraprec
 T1 = [A], [1], [], [], [], [], 0
 T2 = [B,z], [-1,2], [], [], [1], [ctx.mpq_4_3,ctx.mpq_5_3], w
 return T1, T2
 return ctx.hypercomb(h, [], **kwargs)
@defun
def scorergi(ctx, z, **kwargs):
 return _scorer(ctx, z, 0, kwargs)
@defun
def scorerhi(ctx, z, **kwargs):
 return _scorer(ctx, z, 1, kwargs)
@defun_wrapped
def coulombc(ctx, l, eta, _cache={}):
 if (l, eta) in _cache and _cache[l,eta][0] >= ctx.prec:
 return +_cache[l,eta][1]
 G3 = ctx.loggamma(2*l+2)
 G1 = ctx.loggamma(1+l+ctx.j*eta)
 G2 = ctx.loggamma(1+l-ctx.j*eta)
 v = 2**l * ctx.exp((-ctx.pi*eta+G1+G2)/2 - G3)
 if not (ctx.im(l) or ctx.im(eta)):
 v = ctx.re(v)
 _cache[l,eta] = (ctx.prec, v)
 return v
@defun_wrapped
def coulombf(ctx, l, eta, z, w=1, chop=True, **kwargs):
 # Regular Coulomb wave function
 # Note: w can be either 1 or -1; the other may be better in some cases
 # TODO: check that chop=True chops when and only when it should
 #ctx.prec += 10
 def h(l, eta):
 try:
 jw = ctx.j*w
 jwz = ctx.fmul(jw, z, exact=True)
 jwz2 = ctx.fmul(jwz, -2, exact=True)
 C = ctx.coulombc(l, eta)
 T1 = [C, z, ctx.exp(jwz)], [1, l+1, 1], [], [], [1+l+jw*eta], \
 [2*l+2], jwz2
 except ValueError:
 T1 = [0], [-1], [], [], [], [], 0
 return (T1,)
 v = ctx.hypercomb(h, [l,eta], **kwargs)
 if chop and (not ctx.im(l)) and (not ctx.im(eta)) and (not ctx.im(z)) and \
 (ctx.re(z) >= 0):
 v = ctx.re(v)
 return v
@defun_wrapped
def _coulomb_chi(ctx, l, eta, _cache={}):
 if (l, eta) in _cache and _cache[l,eta][0] >= ctx.prec:
 return _cache[l,eta][1]
 def terms():
 l2 = -l-1
 jeta = ctx.j*eta
 return [ctx.loggamma(1+l+jeta) * (-0.5j),
 ctx.loggamma(1+l-jeta) * (0.5j),
 ctx.loggamma(1+l2+jeta) * (0.5j),
 ctx.loggamma(1+l2-jeta) * (-0.5j),
 -(l+0.5)*ctx.pi]
 v = ctx.sum_accurately(terms, 1)
 _cache[l,eta] = (ctx.prec, v)
 return v
@defun_wrapped
def coulombg(ctx, l, eta, z, w=1, chop=True, **kwargs):
 # Irregular Coulomb wave function
 # Note: w can be either 1 or -1; the other may be better in some cases
 # TODO: check that chop=True chops when and only when it should
 if not ctx._im(l):
 l = ctx._re(l) # XXX: for isint
 def h(l, eta):
 # Force perturbation for integers and half-integers
 if ctx.isint(l*2):
 T1 = [0], [-1], [], [], [], [], 0
 return (T1,)
 l2 = -l-1
 try:
 chi = ctx._coulomb_chi(l, eta)
 jw = ctx.j*w
 s = ctx.sin(chi); c = ctx.cos(chi)
 C1 = ctx.coulombc(l,eta)
 C2 = ctx.coulombc(l2,eta)
 u = ctx.exp(jw*z)
 x = -2*jw*z
 T1 = [s, C1, z, u, c], [-1, 1, l+1, 1, 1], [], [], \
 [1+l+jw*eta], [2*l+2], x
 T2 = [-s, C2, z, u], [-1, 1, l2+1, 1], [], [], \
 [1+l2+jw*eta], [2*l2+2], x
 return T1, T2
 except ValueError:
 T1 = [0], [-1], [], [], [], [], 0
 return (T1,)
 v = ctx.hypercomb(h, [l,eta], **kwargs)
 if chop and (not ctx._im(l)) and (not ctx._im(eta)) and (not ctx._im(z)) and \
 (ctx._re(z) >= 0):
 v = ctx._re(v)
 return v
def mcmahon(ctx,kind,prime,v,m):
 """
 Computes an estimate for the location of the Bessel function zero
 j_{v,m}, y_{v,m}, j'_{v,m} or y'_{v,m} using McMahon's asymptotic
 expansion (Abramowitz & Stegun 9.5.12-13, DLMF 20.21(vi)).
 Returns (r,err) where r is the estimated location of the root
 and err is a positive number estimating the error of the
 asymptotic expansion.
 """
 u = 4*v**2
 if kind == 1 and not prime: b = (4*m+2*v-1)*ctx.pi/4
 if kind == 2 and not prime: b = (4*m+2*v-3)*ctx.pi/4
 if kind == 1 and prime: b = (4*m+2*v-3)*ctx.pi/4
 if kind == 2 and prime: b = (4*m+2*v-1)*ctx.pi/4
 if not prime:
 s1 = b
 s2 = -(u-1)/(8*b)
 s3 = -4*(u-1)*(7*u-31)/(3*(8*b)**3)
 s4 = -32*(u-1)*(83*u**2-982*u+3779)/(15*(8*b)**5)
 s5 = -64*(u-1)*(6949*u**3-153855*u**2+1585743*u-6277237)/(105*(8*b)**7)
 if prime:
 s1 = b
 s2 = -(u+3)/(8*b)
 s3 = -4*(7*u**2+82*u-9)/(3*(8*b)**3)
 s4 = -32*(83*u**3+2075*u**2-3039*u+3537)/(15*(8*b)**5)
 s5 = -64*(6949*u**4+296492*u**3-1248002*u**2+7414380*u-5853627)/(105*(8*b)**7)
 terms = [s1,s2,s3,s4,s5]
 s = s1
 err = 0.0
 for i in range(1,len(terms)):
 if abs(terms[i]) < abs(terms[i-1]):
 s += terms[i]
 else:
 err = abs(terms[i])
 if i == len(terms)-1:
 err = abs(terms[-1])
 return s, err
def generalized_bisection(ctx,f,a,b,n):
 """
 Given f known to have exactly n simple roots within [a,b],
 return a list of n intervals isolating the roots
 and having opposite signs at the endpoints.
 TODO: this can be optimized, e.g. by reusing evaluation points.
 """
 if n < 1:
 raise ValueError("n cannot be less than 1")
 N = n+1
 points = []
 signs = []
 while 1:
 points = ctx.linspace(a,b,N)
 signs = [ctx.sign(f(x)) for x in points]
 ok_intervals = [(points[i],points[i+1]) for i in range(N-1) \
 if signs[i]*signs[i+1] == -1]
 if len(ok_intervals) == n:
 return ok_intervals
 N = N*2
def find_in_interval(ctx, f, ab):
 return ctx.findroot(f, ab, solver='illinois', verify=False)
def bessel_zero(ctx, kind, prime, v, m, isoltol=0.01, _interval_cache={}):
 prec = ctx.prec
 workprec = max(prec, ctx.mag(v), ctx.mag(m))+10
 try:
 ctx.prec = workprec
 v = ctx.mpf(v)
 m = int(m)
 prime = int(prime)
 if v < 0:
 raise ValueError("v cannot be negative")
 if m < 1:
 raise ValueError("m cannot be less than 1")
 if not prime in (0,1):
 raise ValueError("prime should lie between 0 and 1")
 if kind == 1:
 if prime: f = lambda x: ctx.besselj(v,x,derivative=1)
 else: f = lambda x: ctx.besselj(v,x)
 if kind == 2:
 if prime: f = lambda x: ctx.bessely(v,x,derivative=1)
 else: f = lambda x: ctx.bessely(v,x)
 # The first root of J' is very close to 0 for small
 # orders, and this needs to be special-cased
 if kind == 1 and prime and m == 1:
 if v == 0:
 return ctx.zero
 if v <= 1:
 # TODO: use v <= j'_{v,1} < y_{v,1}?
 r = 2*ctx.sqrt(v*(1+v)/(v+2))
 return find_in_interval(ctx, f, (r/10, 2*r))
 if (kind,prime,v,m) in _interval_cache:
 return find_in_interval(ctx, f, _interval_cache[kind,prime,v,m])
 r, err = mcmahon(ctx, kind, prime, v, m)
 if err < isoltol:
 return find_in_interval(ctx, f, (r-isoltol, r+isoltol))
 # An x such that 0 < x < r_{v,1}
 if kind == 1 and not prime: low = 2.4
 if kind == 1 and prime: low = 1.8
 if kind == 2 and not prime: low = 0.8
 if kind == 2 and prime: low = 2.0
 n = m+1
 while 1:
 r1, err = mcmahon(ctx, kind, prime, v, n)
 if err < isoltol:
 r2, err2 = mcmahon(ctx, kind, prime, v, n+1)
 intervals = generalized_bisection(ctx, f, low, 0.5*(r1+r2), n)
 for k, ab in enumerate(intervals):
 _interval_cache[kind,prime,v,k+1] = ab
 return find_in_interval(ctx, f, intervals[m-1])
 else:
 n = n*2
 finally:
 ctx.prec = prec
@defun
def besseljzero(ctx, v, m, derivative=0):
 r"""
 For a real order `\nu \ge 0` and a positive integer `m`, returns
 `j_{\nu,m}`, the `m`-th positive zero of the Bessel function of the
 first kind `J_{\nu}(z)` (see :func:`~mpmath.besselj`). Alternatively,
 with *derivative=1*, gives the first nonnegative simple zero
 `j'_{\nu,m}` of `J'_{\nu}(z)`.
 The indexing convention is that used by Abramowitz & Stegun
 and the DLMF. Note the special case `j'_{0,1} = 0`, while all other
 zeros are positive. In effect, only simple zeros are counted
 (all zeros of Bessel functions are simple except possibly `z = 0`)
 and `j_{\nu,m}` becomes a monotonic function of both `\nu`
 and `m`.
 The zeros are interlaced according to the inequalities
 .. math ::
 j'_{\nu,k} < j_{\nu,k} < j'_{\nu,k+1}
 j_{\nu,1} < j_{\nu+1,2} < j_{\nu,2} < j_{\nu+1,2} < j_{\nu,3} < \cdots
 **Examples**
 Initial zeros of the Bessel functions `J_0(z), J_1(z), J_2(z)`::
 >>> from mpmath import *
 >>> mp.dps = 25; mp.pretty = True
 >>> besseljzero(0,1); besseljzero(0,2); besseljzero(0,3)
 2.404825557695772768621632
 5.520078110286310649596604
 8.653727912911012216954199
 >>> besseljzero(1,1); besseljzero(1,2); besseljzero(1,3)
 3.831705970207512315614436
 7.01558666981561875353705
 10.17346813506272207718571
 >>> besseljzero(2,1); besseljzero(2,2); besseljzero(2,3)
 5.135622301840682556301402
 8.417244140399864857783614
 11.61984117214905942709415
 Initial zeros of `J'_0(z), J'_1(z), J'_2(z)`::
 0.0
 3.831705970207512315614436
 7.01558666981561875353705
 >>> besseljzero(1,1,1); besseljzero(1,2,1); besseljzero(1,3,1)
 1.84118378134065930264363
 5.331442773525032636884016
 8.536316366346285834358961
 >>> besseljzero(2,1,1); besseljzero(2,2,1); besseljzero(2,3,1)
 3.054236928227140322755932
 6.706133194158459146634394
 9.969467823087595793179143
 Zeros with large index::
 >>> besseljzero(0,100); besseljzero(0,1000); besseljzero(0,10000)
 313.3742660775278447196902
 3140.807295225078628895545
 31415.14114171350798533666
 >>> besseljzero(5,100); besseljzero(5,1000); besseljzero(5,10000)
 321.1893195676003157339222
 3148.657306813047523500494
 31422.9947255486291798943
 >>> besseljzero(0,100,1); besseljzero(0,1000,1); besseljzero(0,10000,1)
 311.8018681873704508125112
 3139.236339643802482833973
 31413.57032947022399485808
 Zeros of functions with large order::
 >>> besseljzero(50,1)
 57.11689916011917411936228
 >>> besseljzero(50,2)
 62.80769876483536093435393
 >>> besseljzero(50,100)
 388.6936600656058834640981
 >>> besseljzero(50,1,1)
 52.99764038731665010944037
 >>> besseljzero(50,2,1)
 60.02631933279942589882363
 >>> besseljzero(50,100,1)
 387.1083151608726181086283
 Zeros of functions with fractional order::
 >>> besseljzero(0.5,1); besseljzero(1.5,1); besseljzero(2.25,4)
 3.141592653589793238462643
 4.493409457909064175307881
 15.15657692957458622921634
 Both `J_{\nu}(z)` and `J'_{\nu}(z)` can be expressed as infinite
 products over their zeros::
 >>> v,z = 2, mpf(1)
 >>> (z/2)**v/gamma(v+1) * \
 ... nprod(lambda k: 1-(z/besseljzero(v,k))**2, [1,inf])
 ...
 0.1149034849319004804696469
 >>> besselj(v,z)
 0.1149034849319004804696469
 >>> (z/2)**(v-1)/2/gamma(v) * \
 ... nprod(lambda k: 1-(z/besseljzero(v,k,1))**2, [1,inf])
 ...
 0.2102436158811325550203884
 >>> besselj(v,z,1)
 0.2102436158811325550203884
 """
 return +bessel_zero(ctx, 1, derivative, v, m)
@defun
def besselyzero(ctx, v, m, derivative=0):
 r"""
 For a real order `\nu \ge 0` and a positive integer `m`, returns
 `y_{\nu,m}`, the `m`-th positive zero of the Bessel function of the
 second kind `Y_{\nu}(z)` (see :func:`~mpmath.bessely`). Alternatively,
 with *derivative=1*, gives the first positive zero `y'_{\nu,m}` of
 `Y'_{\nu}(z)`.
 The zeros are interlaced according to the inequalities
 .. math ::
 y_{\nu,k} < y'_{\nu,k} < y_{\nu,k+1}
 y_{\nu,1} < y_{\nu+1,2} < y_{\nu,2} < y_{\nu+1,2} < y_{\nu,3} < \cdots
 **Examples**
 Initial zeros of the Bessel functions `Y_0(z), Y_1(z), Y_2(z)`::
 >>> from mpmath import *
 >>> mp.dps = 25; mp.pretty = True
 >>> besselyzero(0,1); besselyzero(0,2); besselyzero(0,3)
 0.8935769662791675215848871
 3.957678419314857868375677
 7.086051060301772697623625
 >>> besselyzero(1,1); besselyzero(1,2); besselyzero(1,3)
 2.197141326031017035149034
 5.429681040794135132772005
 8.596005868331168926429606
 >>> besselyzero(2,1); besselyzero(2,2); besselyzero(2,3)
 3.384241767149593472701426
 6.793807513268267538291167
 10.02347797936003797850539
 Initial zeros of `Y'_0(z), Y'_1(z), Y'_2(z)`::
 >>> besselyzero(0,1,1); besselyzero(0,2,1); besselyzero(0,3,1)
 2.197141326031017035149034
 5.429681040794135132772005
 8.596005868331168926429606
 >>> besselyzero(1,1,1); besselyzero(1,2,1); besselyzero(1,3,1)
 3.683022856585177699898967
 6.941499953654175655751944
 10.12340465543661307978775
 >>> besselyzero(2,1,1); besselyzero(2,2,1); besselyzero(2,3,1)
 5.002582931446063945200176
 8.350724701413079526349714
 11.57419546521764654624265
 Zeros with large index::
 >>> besselyzero(0,100); besselyzero(0,1000); besselyzero(0,10000)
 311.8034717601871549333419
 3139.236498918198006794026
 31413.57034538691205229188
 >>> besselyzero(5,100); besselyzero(5,1000); besselyzero(5,10000)
 319.6183338562782156235062
 3147.086508524556404473186
 31421.42392920214673402828
 >>> besselyzero(0,100,1); besselyzero(0,1000,1); besselyzero(0,10000,1)
 313.3726705426359345050449
 3140.807136030340213610065
 31415.14112579761578220175
 Zeros of functions with large order::
 >>> besselyzero(50,1)
 53.50285882040036394680237
 >>> besselyzero(50,2)
 60.11244442774058114686022
 >>> besselyzero(50,100)
 387.1096509824943957706835
 >>> besselyzero(50,1,1)
 56.96290427516751320063605
 >>> besselyzero(50,2,1)
 62.74888166945933944036623
 >>> besselyzero(50,100,1)
 388.6923300548309258355475
 Zeros of functions with fractional order::
 >>> besselyzero(0.5,1); besselyzero(1.5,1); besselyzero(2.25,4)
 1.570796326794896619231322
 2.798386045783887136720249
 13.56721208770735123376018
 """
 return +bessel_zero(ctx, 2, derivative, v, m)