Current Path : /sys/amd64/compile/hs32/modules/usr/src/sys/modules/cc/cc_vegas/@/boot/ficl/ |
FreeBSD hs32.drive.ne.jp 9.1-RELEASE FreeBSD 9.1-RELEASE #1: Wed Jan 14 12:18:08 JST 2015 root@hs32.drive.ne.jp:/sys/amd64/compile/hs32 amd64 |
Current File : //sys/amd64/compile/hs32/modules/usr/src/sys/modules/cc/cc_vegas/@/boot/ficl/math64.c |
/******************************************************************* ** m a t h 6 4 . c ** Forth Inspired Command Language - 64 bit math support routines ** Author: John Sadler (john_sadler@alum.mit.edu) ** Created: 25 January 1998 ** Rev 2.03: Support for 128 bit DP math. This file really ouught to ** be renamed! ** $Id: math64.c,v 1.9 2001/12/05 07:21:34 jsadler Exp $ *******************************************************************/ /* ** Copyright (c) 1997-2001 John Sadler (john_sadler@alum.mit.edu) ** All rights reserved. ** ** Get the latest Ficl release at http://ficl.sourceforge.net ** ** I am interested in hearing from anyone who uses ficl. If you have ** a problem, a success story, a defect, an enhancement request, or ** if you would like to contribute to the ficl release, please ** contact me by email at the address above. ** ** L I C E N S E and D I S C L A I M E R ** ** Redistribution and use in source and binary forms, with or without ** modification, are permitted provided that the following conditions ** are met: ** 1. Redistributions of source code must retain the above copyright ** notice, this list of conditions and the following disclaimer. ** 2. Redistributions in binary form must reproduce the above copyright ** notice, this list of conditions and the following disclaimer in the ** documentation and/or other materials provided with the distribution. ** ** THIS SOFTWARE IS PROVIDED BY THE AUTHOR AND CONTRIBUTORS ``AS IS'' AND ** ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE ** IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ** ARE DISCLAIMED. IN NO EVENT SHALL THE AUTHOR OR CONTRIBUTORS BE LIABLE ** FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL ** DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS ** OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) ** HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT ** LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY ** OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF ** SUCH DAMAGE. */ /* $FreeBSD: release/9.1.0/sys/boot/ficl/math64.c 94290 2002-04-09 17:45:28Z dcs $ */ #include "ficl.h" #include "math64.h" /************************************************************************** m 6 4 A b s ** Returns the absolute value of an DPINT **************************************************************************/ DPINT m64Abs(DPINT x) { if (m64IsNegative(x)) x = m64Negate(x); return x; } /************************************************************************** m 6 4 F l o o r e d D i v I ** ** FROM THE FORTH ANS... ** Floored division is integer division in which the remainder carries ** the sign of the divisor or is zero, and the quotient is rounded to ** its arithmetic floor. Symmetric division is integer division in which ** the remainder carries the sign of the dividend or is zero and the ** quotient is the mathematical quotient rounded towards zero or ** truncated. Examples of each are shown in tables 3.3 and 3.4. ** ** Table 3.3 - Floored Division Example ** Dividend Divisor Remainder Quotient ** -------- ------- --------- -------- ** 10 7 3 1 ** -10 7 4 -2 ** 10 -7 -4 -2 ** -10 -7 -3 1 ** ** ** Table 3.4 - Symmetric Division Example ** Dividend Divisor Remainder Quotient ** -------- ------- --------- -------- ** 10 7 3 1 ** -10 7 -3 -1 ** 10 -7 3 -1 ** -10 -7 -3 1 **************************************************************************/ INTQR m64FlooredDivI(DPINT num, FICL_INT den) { INTQR qr; UNSQR uqr; int signRem = 1; int signQuot = 1; if (m64IsNegative(num)) { num = m64Negate(num); signQuot = -signQuot; } if (den < 0) { den = -den; signRem = -signRem; signQuot = -signQuot; } uqr = ficlLongDiv(m64CastIU(num), (FICL_UNS)den); qr = m64CastQRUI(uqr); if (signQuot < 0) { qr.quot = -qr.quot; if (qr.rem != 0) { qr.quot--; qr.rem = den - qr.rem; } } if (signRem < 0) qr.rem = -qr.rem; return qr; } /************************************************************************** m 6 4 I s N e g a t i v e ** Returns TRUE if the specified DPINT has its sign bit set. **************************************************************************/ int m64IsNegative(DPINT x) { return (x.hi < 0); } /************************************************************************** m 6 4 M a c ** Mixed precision multiply and accumulate primitive for number building. ** Multiplies DPUNS u by FICL_UNS mul and adds FICL_UNS add. Mul is typically ** the numeric base, and add represents a digit to be appended to the ** growing number. ** Returns the result of the operation **************************************************************************/ DPUNS m64Mac(DPUNS u, FICL_UNS mul, FICL_UNS add) { DPUNS resultLo = ficlLongMul(u.lo, mul); DPUNS resultHi = ficlLongMul(u.hi, mul); resultLo.hi += resultHi.lo; resultHi.lo = resultLo.lo + add; if (resultHi.lo < resultLo.lo) resultLo.hi++; resultLo.lo = resultHi.lo; return resultLo; } /************************************************************************** m 6 4 M u l I ** Multiplies a pair of FICL_INTs and returns an DPINT result. **************************************************************************/ DPINT m64MulI(FICL_INT x, FICL_INT y) { DPUNS prod; int sign = 1; if (x < 0) { sign = -sign; x = -x; } if (y < 0) { sign = -sign; y = -y; } prod = ficlLongMul(x, y); if (sign > 0) return m64CastUI(prod); else return m64Negate(m64CastUI(prod)); } /************************************************************************** m 6 4 N e g a t e ** Negates an DPINT by complementing and incrementing. **************************************************************************/ DPINT m64Negate(DPINT x) { x.hi = ~x.hi; x.lo = ~x.lo; x.lo ++; if (x.lo == 0) x.hi++; return x; } /************************************************************************** m 6 4 P u s h ** Push an DPINT onto the specified stack in the order required ** by ANS Forth (most significant cell on top) ** These should probably be macros... **************************************************************************/ void i64Push(FICL_STACK *pStack, DPINT i64) { stackPushINT(pStack, i64.lo); stackPushINT(pStack, i64.hi); return; } void u64Push(FICL_STACK *pStack, DPUNS u64) { stackPushINT(pStack, u64.lo); stackPushINT(pStack, u64.hi); return; } /************************************************************************** m 6 4 P o p ** Pops an DPINT off the stack in the order required by ANS Forth ** (most significant cell on top) ** These should probably be macros... **************************************************************************/ DPINT i64Pop(FICL_STACK *pStack) { DPINT ret; ret.hi = stackPopINT(pStack); ret.lo = stackPopINT(pStack); return ret; } DPUNS u64Pop(FICL_STACK *pStack) { DPUNS ret; ret.hi = stackPopINT(pStack); ret.lo = stackPopINT(pStack); return ret; } /************************************************************************** m 6 4 S y m m e t r i c D i v ** Divide an DPINT by a FICL_INT and return a FICL_INT quotient and a ** FICL_INT remainder. The absolute values of quotient and remainder are not ** affected by the signs of the numerator and denominator (the operation ** is symmetric on the number line) **************************************************************************/ INTQR m64SymmetricDivI(DPINT num, FICL_INT den) { INTQR qr; UNSQR uqr; int signRem = 1; int signQuot = 1; if (m64IsNegative(num)) { num = m64Negate(num); signRem = -signRem; signQuot = -signQuot; } if (den < 0) { den = -den; signQuot = -signQuot; } uqr = ficlLongDiv(m64CastIU(num), (FICL_UNS)den); qr = m64CastQRUI(uqr); if (signRem < 0) qr.rem = -qr.rem; if (signQuot < 0) qr.quot = -qr.quot; return qr; } /************************************************************************** m 6 4 U M o d ** Divides a DPUNS by base (an UNS16) and returns an UNS16 remainder. ** Writes the quotient back to the original DPUNS as a side effect. ** This operation is typically used to convert an DPUNS to a text string ** in any base. See words.c:numberSignS, for example. ** Mechanics: performs 4 ficlLongDivs, each of which produces 16 bits ** of the quotient. C does not provide a way to divide an FICL_UNS by an ** UNS16 and get an FICL_UNS quotient (ldiv is closest, but it's signed, ** unfortunately), so I've used ficlLongDiv. **************************************************************************/ #if (BITS_PER_CELL == 32) #define UMOD_SHIFT 16 #define UMOD_MASK 0x0000ffff #elif (BITS_PER_CELL == 64) #define UMOD_SHIFT 32 #define UMOD_MASK 0x00000000ffffffff #endif UNS16 m64UMod(DPUNS *pUD, UNS16 base) { DPUNS ud; UNSQR qr; DPUNS result; result.hi = result.lo = 0; ud.hi = 0; ud.lo = pUD->hi >> UMOD_SHIFT; qr = ficlLongDiv(ud, (FICL_UNS)base); result.hi = qr.quot << UMOD_SHIFT; ud.lo = (qr.rem << UMOD_SHIFT) | (pUD->hi & UMOD_MASK); qr = ficlLongDiv(ud, (FICL_UNS)base); result.hi |= qr.quot & UMOD_MASK; ud.lo = (qr.rem << UMOD_SHIFT) | (pUD->lo >> UMOD_SHIFT); qr = ficlLongDiv(ud, (FICL_UNS)base); result.lo = qr.quot << UMOD_SHIFT; ud.lo = (qr.rem << UMOD_SHIFT) | (pUD->lo & UMOD_MASK); qr = ficlLongDiv(ud, (FICL_UNS)base); result.lo |= qr.quot & UMOD_MASK; *pUD = result; return (UNS16)(qr.rem); } /************************************************************************** ** Contributed by ** Michael A. Gauland gaulandm@mdhost.cse.tek.com **************************************************************************/ #if PORTABLE_LONGMULDIV != 0 /************************************************************************** m 6 4 A d d ** **************************************************************************/ DPUNS m64Add(DPUNS x, DPUNS y) { DPUNS result; int carry; result.hi = x.hi + y.hi; result.lo = x.lo + y.lo; carry = ((x.lo | y.lo) & CELL_HI_BIT) && !(result.lo & CELL_HI_BIT); carry |= ((x.lo & y.lo) & CELL_HI_BIT); if (carry) { result.hi++; } return result; } /************************************************************************** m 6 4 S u b ** **************************************************************************/ DPUNS m64Sub(DPUNS x, DPUNS y) { DPUNS result; result.hi = x.hi - y.hi; result.lo = x.lo - y.lo; if (x.lo < y.lo) { result.hi--; } return result; } /************************************************************************** m 6 4 A S L ** 64 bit left shift **************************************************************************/ DPUNS m64ASL( DPUNS x ) { DPUNS result; result.hi = x.hi << 1; if (x.lo & CELL_HI_BIT) { result.hi++; } result.lo = x.lo << 1; return result; } /************************************************************************** m 6 4 A S R ** 64 bit right shift (unsigned - no sign extend) **************************************************************************/ DPUNS m64ASR( DPUNS x ) { DPUNS result; result.lo = x.lo >> 1; if (x.hi & 1) { result.lo |= CELL_HI_BIT; } result.hi = x.hi >> 1; return result; } /************************************************************************** m 6 4 O r ** 64 bit bitwise OR **************************************************************************/ DPUNS m64Or( DPUNS x, DPUNS y ) { DPUNS result; result.hi = x.hi | y.hi; result.lo = x.lo | y.lo; return result; } /************************************************************************** m 6 4 C o m p a r e ** Return -1 if x < y; 0 if x==y, and 1 if x > y. **************************************************************************/ int m64Compare(DPUNS x, DPUNS y) { int result; if (x.hi > y.hi) { result = +1; } else if (x.hi < y.hi) { result = -1; } else { /* High parts are equal */ if (x.lo > y.lo) { result = +1; } else if (x.lo < y.lo) { result = -1; } else { result = 0; } } return result; } /************************************************************************** f i c l L o n g M u l ** Portable versions of ficlLongMul and ficlLongDiv in C ** Contributed by: ** Michael A. Gauland gaulandm@mdhost.cse.tek.com **************************************************************************/ DPUNS ficlLongMul(FICL_UNS x, FICL_UNS y) { DPUNS result = { 0, 0 }; DPUNS addend; addend.lo = y; addend.hi = 0; /* No sign extension--arguments are unsigned */ while (x != 0) { if ( x & 1) { result = m64Add(result, addend); } x >>= 1; addend = m64ASL(addend); } return result; } /************************************************************************** f i c l L o n g D i v ** Portable versions of ficlLongMul and ficlLongDiv in C ** Contributed by: ** Michael A. Gauland gaulandm@mdhost.cse.tek.com **************************************************************************/ UNSQR ficlLongDiv(DPUNS q, FICL_UNS y) { UNSQR result; DPUNS quotient; DPUNS subtrahend; DPUNS mask; quotient.lo = 0; quotient.hi = 0; subtrahend.lo = y; subtrahend.hi = 0; mask.lo = 1; mask.hi = 0; while ((m64Compare(subtrahend, q) < 0) && (subtrahend.hi & CELL_HI_BIT) == 0) { mask = m64ASL(mask); subtrahend = m64ASL(subtrahend); } while (mask.lo != 0 || mask.hi != 0) { if (m64Compare(subtrahend, q) <= 0) { q = m64Sub( q, subtrahend); quotient = m64Or(quotient, mask); } mask = m64ASR(mask); subtrahend = m64ASR(subtrahend); } result.quot = quotient.lo; result.rem = q.lo; return result; } #endif