From 586db6343e7b472d8dc3e63a82f4c73f99cdcbd7 Mon Sep 17 00:00:00 2001 From: siddhu8990 Date: Wed, 19 Apr 2017 14:28:34 +0530 Subject: Merged Ashish's work --- 2.3-1/src/c/elementaryFunctions/acosd/cacoss.c | 147 +++++++++++++++++++++++++ 1 file changed, 147 insertions(+) create mode 100644 2.3-1/src/c/elementaryFunctions/acosd/cacoss.c (limited to '2.3-1/src/c/elementaryFunctions/acosd/cacoss.c') diff --git a/2.3-1/src/c/elementaryFunctions/acosd/cacoss.c b/2.3-1/src/c/elementaryFunctions/acosd/cacoss.c new file mode 100644 index 00000000..97420313 --- /dev/null +++ b/2.3-1/src/c/elementaryFunctions/acosd/cacoss.c @@ -0,0 +1,147 @@ +/* + * Scilab ( http://www.scilab.org/ ) - This file is part of Scilab + * Copyright (C) 2007-2008 - INRIA - Bruno JOFRET + * Copyright (C) Bruno Pincon + * + * This file must be used under the terms of the CeCILL. + * This source file is licensed as described in the file COPYING, which + * you should have received as part of this distribution. The terms + * are also available at + * http://www.cecill.info/licences/Licence_CeCILL_V2-en.txt + * + */ + +/* + * This fonction is a translation of fortran wacos write by Bruno Pincon + * REFERENCE + * This is a Fortran-77 translation of an algorithm by + * T.E. Hull, T. F. Fairgrieve and P.T.P. Tang which + * appears in their article : + * "Implementing the Complex Arcsine and Arccosine + * Functions Using Exception Handling", ACM, TOMS, + * Vol 23, No. 3, Sept 1997, p. 299-335 + */ + +#include "acos.h" +#include "atan.h" +#include "log.h" +#include "log1p.h" +#include "sqrt.h" +#include "abs.h" +#include "lapack.h" +#include "min.h" +#include "max.h" + +#define localSign(x) (x>0 ? 1.0f : -1.0f) + +floatComplex cacoss(floatComplex z) { + static float sfltPi = 3.1415926535897932384626433f; + static float sfltPi_2 = 1.5707963267948966192313216f; + static float sfltLn2 = 0.6931471805599453094172321f; + static float sfltAcross = 1.5f; + static float sfltBcross = 0.6417f; + + float fltLsup = ssqrts((float) getOverflowThreshold())/8.0f; + float fltLinf = 4.0f * ssqrts((float) getUnderflowThreshold()); + float fltEpsm = ssqrts((float) getRelativeMachinePrecision()); + + float fltAbsReal = sabss(creals(z)); + float fltAbsImg = sabss(cimags(z)); + float fltSignReal = localSign(creals(z)); + float fltSignImg = localSign(cimags(z)); + + float fltR = 0, fltS = 0, fltA = 0, fltB = 0; + + float fltTemp = 0; + + float _pfltReal = 0; + float _pfltImg = 0; + + if( min(fltAbsReal, fltAbsImg) > fltLinf && max(fltAbsReal, fltAbsImg) <= fltLsup) + {/* we are in the safe region */ + fltR = ssqrts( (fltAbsReal + 1 )*(fltAbsReal + 1 ) + fltAbsImg*fltAbsImg); + fltS = ssqrts( (fltAbsReal - 1 )*(fltAbsReal - 1 ) + fltAbsImg*fltAbsImg); + fltA = 0.5f * ( fltR + fltS ); + fltB = fltAbsReal / fltA; + + + /* compute the real part */ + if(fltB <= sfltBcross) + _pfltReal = sacoss(fltB); + else if( fltAbsReal <= 1) + _pfltReal = satans(ssqrts(0.5f * (fltA + fltAbsReal) * (fltAbsImg*fltAbsImg / (fltR + (fltAbsReal + 1)) + (fltS + (1 - fltAbsReal)))) / fltAbsReal); + else + _pfltReal = satans((fltAbsImg * ssqrts(0.5f * ((fltA + fltAbsReal) / (fltR + (fltAbsReal + 1)) + (fltA + fltAbsReal) / (fltS + (fltAbsReal - 1))))) / fltAbsReal); + + /* compute the imaginary part */ + if(fltA <= sfltAcross) + { + float fltImg1 = 0; + + if(fltAbsReal < 1) + /* Am1 = 0.5d0*((y**2)/(R+(x+1.d0))+(y**2)/(S+(1.d0-x))) */ + fltImg1 = 0.5f * (fltAbsImg*fltAbsImg / (fltR + (fltAbsReal + 1)) + fltAbsImg*fltAbsImg / (fltS + (1 - fltAbsReal))); + else + /* Am1 = 0.5d0*((y**2)/(R+(x+1.d0))+(S+(x-1.d0))) */ + fltImg1 = 0.5f * (fltAbsImg*fltAbsImg / (fltR + (fltAbsReal + 1)) + (fltS + (fltAbsReal - 1))); + /* ai = logp1(Am1 + sqrt(Am1*(A+1.d0))) */ + fltTemp = fltImg1 + ssqrts(fltImg1 *( fltA + 1)); + _pfltImg = slog1ps(fltTemp); + } + else + /* ai = log(A + sqrt(A**2 - 1.d0)) */ + _pfltImg = slogs(fltA + ssqrts(fltA*fltA - 1)); + } + else + {/* evaluation in the special regions ... */ + if(fltAbsImg <= fltEpsm * sabss(fltAbsReal - 1)) + { + if(fltAbsReal < 1) + { + _pfltReal = sacoss(fltAbsReal); + _pfltImg = fltAbsImg / ssqrts((1 + fltAbsReal) * (1 - fltAbsReal)); + } + else + { + _pfltReal = 0; + if(fltAbsReal <= fltLsup) + { + fltTemp = (fltAbsReal - 1) + ssqrts((fltAbsReal - 1) * (fltAbsReal + 1)); + _pfltImg = slog1ps(fltTemp); + } + else + _pfltImg = sfltLn2 + slogs(fltAbsReal); + } + } + else if(fltAbsImg < fltLinf) + { + _pfltReal = ssqrts(fltAbsImg); + _pfltImg = _pfltReal; + } + else if((fltEpsm * fltAbsImg - 1 >= fltAbsReal)) + { + _pfltReal = sfltPi_2; + _pfltImg = sfltLn2 + slogs(fltAbsImg); + } + else if(fltAbsReal > 1) + { + _pfltReal = satans(fltAbsImg / fltAbsReal); + fltTemp = (fltAbsReal / fltAbsImg)*(fltAbsReal / fltAbsImg); + _pfltImg = sfltLn2 + slogs(fltAbsImg) + 0.5f * slog1ps(fltTemp); + } + else + { + float fltTemp2 = ssqrts(1 + fltAbsImg*fltAbsImg); + _pfltReal = sfltPi_2; + fltTemp = 2 * fltAbsImg * (fltAbsImg + fltTemp2); + _pfltImg = 0.5f * slog1ps(fltTemp); + } + } + if(fltSignReal < 0) + _pfltReal = sfltPi - _pfltReal; + + if(fltAbsImg != 0 || fltSignReal < 0) + _pfltImg = - fltSignImg * _pfltImg; + + return FloatComplex(_pfltReal, _pfltImg); +} -- cgit