// This may look like C code, but it is really -*- C++ -*- /* Copyright (C) 1988 Free Software Foundation written by Kurt Baudendistel (gt-eedsp!baud@gatech.edu) adapted for libg++ by Doug Lea (dl@rocky.oswego.edu) This file is part of the GNU C++ Library. This library is free software; you can redistribute it and/or modify it under the terms of the GNU Library General Public License as published by the Free Software Foundation; either version 2 of the License, or (at your option) any later version. This library is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU Library General Public License for more details. You should have received a copy of the GNU Library General Public License along with this library; if not, write to the Free Software Foundation, 675 Mass Ave, Cambridge, MA 02139, USA. */ // // Fix.cc : fixed precision class support functions // #ifdef __GNUG__ #pragma implementation #endif #include // basic operators too large to be inline short Fix16::assign(double d) { if (d == 1.0) return Fix16_m_max; else if (d > Fix16_max) { short i = Fix16_m_max; range_error(i); return i; } else if (d < Fix16_min) { short i = Fix16_m_min; range_error(i); return i; } else return round(Fix16_mult * d); } long Fix32::assign(double d) { if (d == 1.0) return Fix32_m_max; else if (d > Fix32_max) { long i = Fix32_m_max; range_error(i); return i; } else if (d < Fix32_min) { long i = Fix32_m_min; range_error(i); return i; } else return round(Fix32_mult * d); } Fix32 operator * (Fix32& a, Fix32& b) { // break a and b into lo and hi parts, and do a multiple-precision // multiply, with rounding int apos = (a.m >= 0); unsigned long ua = (apos)? a.m : - a.m; ua <<= 1; // ua is biased so result will be 31 bit mantissa, not 30: unsigned long hi_a = (ua >> 16) & ((1 << 16) - 1); unsigned long lo_a = ua & ((1 << 16) - 1); int bpos = (b.m >= 0); unsigned long ub = (bpos)? b.m : -b.m; unsigned long hi_b = (ub >> 16) & ((1 << 16) - 1); unsigned long lo_b = ub & ((1 << 16) - 1); unsigned long r = lo_a * lo_b + (1 << 15); r = (r >> 16) + hi_a * lo_b + lo_a * hi_b + (1 << 15); r = (r >> 16) + hi_a * hi_b; long p = (apos != bpos)? -r : r; return Fix32(p); } Fix16 operator / (Fix16& a, Fix16& b) { short q; int apos = (a.m >= 0); long la = (apos)? a.m : -a.m; long scaled_a = la << 15; int bpos = (b.m >= 0); short sb = (bpos)? b.m: -b.m; if (la >= sb) { q = (apos == bpos)? Fix16_m_max: Fix16_m_min; a.range_error(q); } else { q = scaled_a / sb; if ((scaled_a % sb) >= (sb / 2)) ++q; if (apos != bpos) q = -q; } return Fix16(q); } Fix32 operator / (Fix32& a, Fix32& b) { long q; int apos = (a.m >= 0); unsigned long la = (apos)? a.m : -a.m; int bpos = (b.m >= 0); unsigned long lb = (bpos)? b.m: -b.m; if (la >= lb) { q = (apos == bpos)? Fix32_m_max: Fix32_m_min; a.range_error(q); } else // standard shift-based division alg { q = 0; long r = la; for (int i = 32; i > 0; i--) { if ((unsigned long)(r) > lb) { q = (q << 1) | 1; r -= lb; } else q = (q << 1); r <<= 1; } if (apos != bpos) q = -q; // Fix sign } return Fix32(q); } // error handling void Fix16::overflow(short& i) { (*Fix16_overflow_handler)(i); } void Fix32::overflow(long& i) { (*Fix32_overflow_handler)(i); } void Fix16::range_error(short& i) { (*Fix16_range_error_handler)(i); } void Fix32::range_error(long& i) { (*Fix32_range_error_handler)(i); } // data definitions Fix16_peh Fix16_overflow_handler = Fix16_overflow_saturate; Fix32_peh Fix32_overflow_handler = Fix32_overflow_saturate; Fix16_peh Fix16_range_error_handler = Fix16_warning; Fix32_peh Fix32_range_error_handler = Fix32_warning; //function definitions Fix16_peh set_Fix16_overflow_handler(Fix16_peh new_handler) { Fix16_peh old_handler = Fix16_overflow_handler; Fix16_overflow_handler = new_handler; return old_handler; } Fix32_peh set_Fix32_overflow_handler(Fix32_peh new_handler) { Fix32_peh old_handler = Fix32_overflow_handler; Fix32_overflow_handler = new_handler; return old_handler; } void set_overflow_handler(Fix16_peh handler16, Fix32_peh handler32) { set_Fix16_overflow_handler(handler16); set_Fix32_overflow_handler(handler32); } Fix16_peh set_Fix16_range_error_handler(Fix16_peh new_handler) { Fix16_peh old_handler = Fix16_range_error_handler; Fix16_range_error_handler = new_handler; return old_handler; } Fix32_peh set_Fix32_range_error_handler(Fix32_peh new_handler) { Fix32_peh old_handler = Fix32_range_error_handler; Fix32_range_error_handler = new_handler; return old_handler; } void set_range_error_handler(Fix16_peh handler16, Fix32_peh handler32) { set_Fix16_range_error_handler(handler16); set_Fix32_range_error_handler(handler32); } void Fix16_overflow_saturate(short& i) { i = (i > 0 ? Fix16_m_min : Fix16_m_max); } void Fix16_ignore(short&) {} void Fix16_warning(short&) { cerr << "warning: Fix16 result out of range\n"; } void Fix16_overflow_warning_saturate(short& i) { cerr << "warning: Fix16 result out of range\n"; Fix16_overflow_saturate(i); } void Fix16_abort(short&) { cerr << "error: Fix16 result out of range\n"; abort(); } void Fix32_ignore(long&) {} void Fix32_overflow_saturate(long& i) { i = (i > 0 ? Fix32_m_min : Fix32_m_max); } void Fix32_warning(long&) { cerr << "warning: Fix32 result out of range\n"; } void Fix32_overflow_warning_saturate(long& i) { cerr << "warning: Fix32 result out of range\n"; Fix32_overflow_saturate(i); } void Fix32_abort(long&) { cerr << "error: Fix32 result out of range\n"; abort(); }