b6cbf7203b
This patch imports the unmodified current version of NetBSD libc. The NetBSD includes are in /nbsd_include, while the libc code itself is split between lib/nbsd_libc and common/lib/libc.
197 lines
4.6 KiB
Text
197 lines
4.6 KiB
Text
/* $NetBSD: divrem.m4,v 1.9 2002/01/21 23:40:41 ross Exp $ */
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/*
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* Copyright (c) 1994, 1995 Carnegie-Mellon University.
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* All rights reserved.
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*
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* Author: Chris G. Demetriou
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*
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* Permission to use, copy, modify and distribute this software and
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* its documentation is hereby granted, provided that both the copyright
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* notice and this permission notice appear in all copies of the
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* software, derivative works or modified versions, and any portions
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* thereof, and that both notices appear in supporting documentation.
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*
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* CARNEGIE MELLON ALLOWS FREE USE OF THIS SOFTWARE IN ITS "AS IS"
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* CONDITION. CARNEGIE MELLON DISCLAIMS ANY LIABILITY OF ANY KIND
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* FOR ANY DAMAGES WHATSOEVER RESULTING FROM THE USE OF THIS SOFTWARE.
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*
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* Carnegie Mellon requests users of this software to return to
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*
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* Software Distribution Coordinator or Software.Distribution@CS.CMU.EDU
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* School of Computer Science
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* Carnegie Mellon University
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* Pittsburgh PA 15213-3890
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*
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* any improvements or extensions that they make and grant Carnegie the
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* rights to redistribute these changes.
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*/
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/*
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* Division and remainder.
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*
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* The use of m4 is modeled after the sparc code, but the algorithm is
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* simple binary long division.
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*
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* Note that the loops could probably benefit from unrolling.
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*/
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/*
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* M4 Parameters
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* NAME name of function to generate
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* OP OP=div: t10 / t11 -> t12; OP=rem: t10 % t11 -> t12
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* S S=true: signed; S=false: unsigned
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* WORDSIZE total number of bits
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*/
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define(A, `t10')
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define(B, `t11')
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define(RESULT, `t12')
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define(BIT, `t0')
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define(I, `t1')
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define(CC, `t2')
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define(T_0, `t3')
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ifelse(S, `true', `define(NEG, `t4')')
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#include <machine/asm.h>
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LEAF(NAME, 0) /* XXX */
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lda sp, -64(sp)
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stq BIT, 0(sp)
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stq I, 8(sp)
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stq CC, 16(sp)
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stq T_0, 24(sp)
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ifelse(S, `true',
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` stq NEG, 32(sp)')
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stq A, 40(sp)
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stq B, 48(sp)
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mov zero, RESULT /* Initialize result to zero */
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ifelse(S, `true',
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`
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/* Compute sign of result. If either is negative, this is easy. */
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or A, B, NEG /* not the sign, but... */
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srl NEG, WORDSIZE - 1, NEG /* rather, or of high bits */
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blbc NEG, Ldoit /* neither negative? do it! */
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ifelse(OP, `div',
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` xor A, B, NEG /* THIS is the sign! */
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', ` mov A, NEG /* sign follows A. */
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')
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srl NEG, WORDSIZE - 1, NEG /* make negation the low bit. */
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srl A, WORDSIZE - 1, I /* is A negative? */
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blbc I, LnegB /* no. */
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/* A is negative; flip it. */
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ifelse(WORDSIZE, `32', `
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/* top 32 bits may be random junk */
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zap A, 0xf0, A
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')
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subq zero, A, A
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srl B, WORDSIZE - 1, I /* is B negative? */
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blbc I, Ldoit /* no. */
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LnegB:
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/* B is definitely negative, no matter how we got here. */
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ifelse(WORDSIZE, `32', `
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/* top 32 bits may be random junk */
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zap B, 0xf0, B
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')
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subq zero, B, B
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Ldoit:
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')
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ifelse(WORDSIZE, `32', `
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/*
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* Clear the top 32 bits of each operand, as they may
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* sign extension (if negated above), or random junk.
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*/
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zap A, 0xf0, A
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zap B, 0xf0, B
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')
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/* kill the special cases. */
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beq B, Ldotrap /* division by zero! */
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cmpult A, B, CC /* A < B? */
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/* RESULT is already zero, from above. A is untouched. */
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bne CC, Lret_result
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cmpeq A, B, CC /* A == B? */
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cmovne CC, 1, RESULT
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cmovne CC, zero, A
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bne CC, Lret_result
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/*
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* Find out how many bits of zeros are at the beginning of the divisor.
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*/
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LBbits:
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ldiq T_0, 1 /* I = 0; BIT = 1<<WORDSIZE-1 */
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mov zero, I
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sll T_0, WORDSIZE-1, BIT
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LBloop:
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and B, BIT, CC /* if bit in B is set, done. */
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bne CC, LAbits
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addq I, 1, I /* increment I, shift bit */
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srl BIT, 1, BIT
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cmplt I, WORDSIZE-1, CC /* if I leaves one bit, done. */
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bne CC, LBloop
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LAbits:
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beq I, Ldodiv /* If I = 0, divide now. */
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ldiq T_0, 1 /* BIT = 1<<WORDSIZE-1 */
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sll T_0, WORDSIZE-1, BIT
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LAloop:
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and A, BIT, CC /* if bit in A is set, done. */
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bne CC, Ldodiv
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subq I, 1, I /* decrement I, shift bit */
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srl BIT, 1, BIT
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bne I, LAloop /* If I != 0, loop again */
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Ldodiv:
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sll B, I, B /* B <<= i */
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ldiq T_0, 1
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sll T_0, I, BIT
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Ldivloop:
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cmpult A, B, CC
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or RESULT, BIT, T_0
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cmoveq CC, T_0, RESULT
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subq A, B, T_0
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cmoveq CC, T_0, A
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srl BIT, 1, BIT
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srl B, 1, B
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beq A, Lret_result
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bne BIT, Ldivloop
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Lret_result:
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ifelse(OP, `div',
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`', ` mov A, RESULT
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')
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ifelse(S, `true',
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`
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/* Check to see if we should negate it. */
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subq zero, RESULT, T_0
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cmovlbs NEG, T_0, RESULT
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')
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ldq BIT, 0(sp)
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ldq I, 8(sp)
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ldq CC, 16(sp)
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ldq T_0, 24(sp)
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ifelse(S, `true',
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` ldq NEG, 32(sp)')
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ldq A, 40(sp)
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ldq B, 48(sp)
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lda sp, 64(sp)
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ret zero, (t9), 1
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Ldotrap:
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ldiq a0, -2 /* This is the signal to SIGFPE! */
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call_pal PAL_gentrap
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ifelse(OP, `div',
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`', ` mov zero, A /* so that zero will be returned */
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')
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br zero, Lret_result
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END(NAME)
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