/* * M_APM - mapmasn0.c * * Copyright (C) 2000 - 2002 Michael C. Ring * * Permission to use, copy, and distribute this software and its * documentation for any purpose with or without fee is hereby granted, * provided that the above copyright notice appear in all copies and * that both that copyright notice and this permission notice appear * in supporting documentation. * * Permission to modify the software is granted, but not the right to * distribute the modified code. Modifications are to be distributed * as patches to released version. * * This software is provided "as is" without express or implied warranty. */ /* * $Id: mapmasn0.c,v 1.2 2003/05/01 12:46:55 alby Exp $ * * This file contains the 'ARC' family of functions; ARC-SIN, * ARC-COS, ARC-TAN when the input arg is very close to 0 (zero). * * $Log: mapmasn0.c,v $ * Revision 1.2 2003/05/01 12:46:55 alby * - Updated MAPM to version 4.6.1 * - The MAPM class is now thread-safe * * Revision 1.3 2002/11/03 21:36:43 mike * Updated function parameters to use the modern style * * Revision 1.2 2000/12/02 20:11:37 mike * add comments * * Revision 1.1 2000/12/02 20:08:27 mike * Initial revision */ #include "m_apm_lc.h" /****************************************************************************/ /* Calculate arcsin using the identity : x arcsin (x) == arctan [ --------------- ] sqrt(1 - x^2) */ void M_arcsin_near_0(M_APM rr, int places, M_APM aa) { M_APM tmp5, tmp6; tmp5 = M_get_stack_var(); tmp6 = M_get_stack_var(); M_cos_to_sin(tmp5, (places + 8), aa); m_apm_divide(tmp6, (places + 8), aa, tmp5); M_arctan_near_0(rr, places, tmp6); M_restore_stack(2); } /****************************************************************************/ /* Calculate arccos using the identity : arccos (x) == PI / 2 - arcsin (x) */ void M_arccos_near_0(M_APM rr, int places, M_APM aa) { M_APM tmp1, tmp2; tmp1 = M_get_stack_var(); tmp2 = M_get_stack_var(); M_check_PI_places(places); M_arcsin_near_0(tmp1, (places + 4), aa); m_apm_subtract(tmp2, MM_lc_HALF_PI, tmp1); m_apm_round(rr, places, tmp2); M_restore_stack(2); } /****************************************************************************/ /* calculate arctan (x) with the following series: x^3 x^5 x^7 x^9 arctan (x) == x - --- + --- - --- + --- ... 3 5 7 9 */ void M_arctan_near_0(M_APM rr, int places, M_APM aa) { M_APM tmp0, tmpR, tmp2, tmpS, digit, term; int tolerance, local_precision; long m1; tmp0 = M_get_stack_var(); tmp2 = M_get_stack_var(); tmpR = M_get_stack_var(); tmpS = M_get_stack_var(); term = M_get_stack_var(); digit = M_get_stack_var(); tolerance = aa->m_apm_exponent - places - 4; local_precision = places + 8 - aa->m_apm_exponent; m_apm_copy(term, aa); m_apm_copy(tmpS, aa); m_apm_multiply(tmp0, aa, aa); m_apm_round(tmp2, (local_precision + 8), tmp0); m1 = 1; while (TRUE) { m1 += 2; m_apm_set_long(digit, m1); m_apm_multiply(tmp0, term, tmp2); m_apm_round(term, local_precision, tmp0); m_apm_divide(tmp0, local_precision, term, digit); m_apm_subtract(tmpR, tmpS, tmp0); if ((tmp0->m_apm_exponent < tolerance) || (tmp0->m_apm_sign == 0)) { m_apm_round(rr, places, tmpR); break; } m1 += 2; m_apm_set_long(digit, m1); m_apm_multiply(tmp0, term, tmp2); m_apm_round(term, local_precision, tmp0); m_apm_divide(tmp0, local_precision, term, digit); m_apm_add(tmpS, tmpR, tmp0); if ((tmp0->m_apm_exponent < tolerance) || (tmp0->m_apm_sign == 0)) { m_apm_round(rr, places, tmpS); break; } } M_restore_stack(6); /* restore the 6 locals we used here */ } /****************************************************************************/