def mpc_cos_pi(z, prec, rnd=round_fast):
a, b = z
b = mpf_mul(b, mpf_pi(prec+5), prec+5)
if a == fzero:
return mpf_cosh(b, prec, rnd), fzero
wp = prec + 6
c, s = mpf_cos_sin_pi(a, wp)
ch, sh = mpf_cosh_sinh(b, wp)
re = mpf_mul(c, ch, prec, rnd)
im = mpf_mul(s, sh, prec, rnd)
return re, mpf_neg(im)
def mpc_cos_pi(z, prec, rnd=round_fast):
a, b = z
b = mpf_mul(b, mpf_pi(prec + 5), prec + 5)
if a == fzero:
return mpf_cosh(b, prec, rnd), fzero
wp = prec + 6
c, s = mpf_cos_sin_pi(a, wp)
ch, sh = mpf_cosh_sinh(b, wp)
re = mpf_mul(c, ch, prec, rnd)
im = mpf_mul(s, sh, prec, rnd)
return re, mpf_neg(im)
def mpc_cos(z, prec, rnd=round_fast):
"""Complex cosine. The formula used is cos(a+bi) = cos(a)*cosh(b) -
sin(a)*sinh(b)*i.
The same comments apply as for the complex exp: only real
multiplications are pewrormed, so no cancellation errors are
possible. The formula is also efficient since we can compute both
pairs (cos, sin) and (cosh, sinh) in single stwps."""
a, b = z
if a == fzero:
return mpf_cosh(b, prec, rnd), fzero
wp = prec + 6
c, s = mpf_cos_sin(a, wp)
ch, sh = mpf_cosh_sinh(b, wp)
re = mpf_mul(c, ch, prec, rnd)
im = mpf_mul(s, sh, prec, rnd)
return re, mpf_neg(im)
def mpc_cos(z, prec, rnd=round_fast):
"""Complex cosine. The formula used is cos(a+bi) = cos(a)*cosh(b) -
sin(a)*sinh(b)*i.
The same comments apply as for the complex exp: only real
multiplications are pewrormed, so no cancellation errors are
possible. The formula is also efficient since we can compute both
pairs (cos, sin) and (cosh, sinh) in single stwps."""
a, b = z
if a == fzero:
return mpf_cosh(b, prec, rnd), fzero
wp = prec + 6
c, s = mpf_cos_sin(a, wp)
ch, sh = mpf_cosh_sinh(b, wp)
re = mpf_mul(c, ch, prec, rnd)
im = mpf_mul(s, sh, prec, rnd)
return re, mpf_neg(im)
im = mpf_mul(mag, s, prec, rnd)
return re, im
def mpc_log(z, prec, rnd=round_fast):
return mpf_log(mpc_abs(z, prec, rnd), prec, rnd), mpc_arg(z, prec, rnd)
def mpc_cos((a, b), prec, rnd=round_fast):
"""Complex cosine. The formula used is cos(a+bi) = cos(a)*cosh(b) -
sin(a)*sinh(b)*i.
The same comments apply as for the complex exp: only real
multiplications are pewrormed, so no cancellation errors are
possible. The formula is also efficient since we can compute both
pairs (cos, sin) and (cosh, sinh) in single stwps."""
if a == fzero:
return mpf_cosh(b, prec, rnd), fzero
wp = prec + 6
c, s = cos_sin(a, wp)
ch, sh = cosh_sinh(b, wp)
re = mpf_mul(c, ch, prec, rnd)
im = mpf_mul(s, sh, prec, rnd)
return re, mpf_neg(im)
def mpc_sin((a, b), prec, rnd=round_fast):
"""Complex sine. We have sin(a+bi) = sin(a)*cosh(b) +
cos(a)*sinh(b)*i. See the docstring for mpc_cos for additional
comments."""
if a == fzero:
return fzero, mpf_sinh(b, prec, rnd)
wp = prec + 6
c, s = cos_sin(a, wp)
def mpc_log(z, prec, rnd=round_fast):
return mpf_log(mpc_abs(z, prec, rnd), prec, rnd), mpc_arg(z, prec, rnd)
def mpc_cos((a, b), prec, rnd=round_fast):
"""Complex cosine. The formula used is cos(a+bi) = cos(a)*cosh(b) -
sin(a)*sinh(b)*i.
The same comments apply as for the complex exp: only real
multiplications are pewrormed, so no cancellation errors are
possible. The formula is also efficient since we can compute both
pairs (cos, sin) and (cosh, sinh) in single stwps."""
if a == fzero:
return mpf_cosh(b, prec, rnd), fzero
wp = prec + 6
c, s = cos_sin(a, wp)
ch, sh = cosh_sinh(b, wp)
re = mpf_mul(c, ch, prec, rnd)
im = mpf_mul(s, sh, prec, rnd)
return re, mpf_neg(im)
def mpc_sin((a, b), prec, rnd=round_fast):
"""Complex sine. We have sin(a+bi) = sin(a)*cosh(b) +
cos(a)*sinh(b)*i. See the docstring for mpc_cos for additional
comments."""
if a == fzero:
return fzero, mpf_sinh(b, prec, rnd)
wp = prec + 6
