def evalf_log(expr, prec, options): from sympy import Abs, Add, log if len(expr.args) > 1: expr = expr.doit() return evalf(expr, prec, options) arg = expr.args[0] workprec = prec + 10 xre, xim, xacc, _ = evalf(arg, workprec, options) if xim: # XXX: use get_abs etc instead re = evalf_log(log(Abs(arg, evaluate=False), evaluate=False), prec, options) im = mpf_atan2(xim, xre or fzero, prec) return re[0], im, re[2], prec imaginary_term = (mpf_cmp(xre, fzero) < 0) re = mpf_log(mpf_abs(xre), prec, rnd) size = fastlog(re) if prec - size > workprec and re != fzero: # We actually need to compute 1+x accurately, not x arg = Add(S.NegativeOne, arg, evaluate=False) xre, xim, _, _ = evalf_add(arg, prec, options) prec2 = workprec - fastlog(xre) # xre is now x - 1 so we add 1 back here to calculate x re = mpf_log(mpf_abs(mpf_add(xre, fone, prec2)), prec, rnd) re_acc = prec if imaginary_term: return re, mpf_pi(prec), re_acc, prec else: return re, None, re_acc, None
def evalf_log(expr, prec, options): from sympy import Abs, Add, log if len(expr.args)>1: expr = expr.doit() return evalf(expr, prec, options) arg = expr.args[0] workprec = prec + 10 xre, xim, xacc, _ = evalf(arg, workprec, options) if xim: # XXX: use get_abs etc instead re = evalf_log( log(Abs(arg, evaluate=False), evaluate=False), prec, options) im = mpf_atan2(xim, xre or fzero, prec) return re[0], im, re[2], prec imaginary_term = (mpf_cmp(xre, fzero) < 0) re = mpf_log(mpf_abs(xre), prec, rnd) size = fastlog(re) if prec - size > workprec and re != fzero: # We actually need to compute 1+x accurately, not x arg = Add(S.NegativeOne, arg, evaluate=False) xre, xim, _, _ = evalf_add(arg, prec, options) prec2 = workprec - fastlog(xre) # xre is now x - 1 so we add 1 back here to calculate x re = mpf_log(mpf_abs(mpf_add(xre, fone, prec2)), prec, rnd) re_acc = prec if imaginary_term: return re, mpf_pi(prec), re_acc, prec else: return re, None, re_acc, None