mingw-w64-libraries/winpthreads/src/libgcc/dll_math.c

/*-
 * Copyright (c) 1992, 1993
 *	The Regents of the University of California.  All rights reserved.
 *
 * This software was developed by the Computer Systems Engineering group
 * at Lawrence Berkeley Laboratory under DARPA contract BG 91-66 and
 * contributed to Berkeley.
 *
 * 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.
 * 4. Neither the name of the University nor the names of its contributors
 *    may be used to endorse or promote products derived from this software
 *    without specific prior written permission.
 *
 * THIS SOFTWARE IS PROVIDED BY THE REGENTS 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 REGENTS 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.
 */

#ifndef _LIBKERN_QUAD_H_
#define	_LIBKERN_QUAD_H_

/*
 * Quad arithmetic.
 *
 * This library makes the following assumptions:
 *
 *  - The type long long (aka quad_t) exists.
 *
 *  - A quad variable is exactly twice as long as `long'.
 *
 *  - The machine's arithmetic is two's complement.
 *
 * This library can provide 128-bit arithmetic on a machine with 128-bit
 * quads and 64-bit longs, for instance, or 96-bit arithmetic on machines
 * with 48-bit longs.
 */
/*
#include <sys/cdefs.h>
#include <sys/types.h>
#include <sys/limits.h>
#include <sys/syslimits.h>
*/

#include <limits.h>
typedef long long quad_t;
typedef unsigned long long u_quad_t;
typedef unsigned long u_long;
#define CHAR_BIT __CHAR_BIT__

/*
 * Define the order of 32-bit words in 64-bit words.
 * For little endian only.
 */
#define _QUAD_HIGHWORD 1
#define _QUAD_LOWWORD 0

/*
 * Depending on the desired operation, we view a `long long' (aka quad_t) in
 * one or more of the following formats.
 */
union uu {
	quad_t	q;		/* as a (signed) quad */
	quad_t	uq;		/* as an unsigned quad */
	long	sl[2];		/* as two signed longs */
	u_long	ul[2];		/* as two unsigned longs */
};

/*
 * Define high and low longwords.
 */
#define	H		_QUAD_HIGHWORD
#define	L		_QUAD_LOWWORD

/*
 * Total number of bits in a quad_t and in the pieces that make it up.
 * These are used for shifting, and also below for halfword extraction
 * and assembly.
 */
#define	QUAD_BITS	(sizeof(quad_t) * CHAR_BIT)
#define	LONG_BITS	(sizeof(long) * CHAR_BIT)
#define	HALF_BITS	(sizeof(long) * CHAR_BIT / 2)

/*
 * Extract high and low shortwords from longword, and move low shortword of
 * longword to upper half of long, i.e., produce the upper longword of
 * ((quad_t)(x) << (number_of_bits_in_long/2)).  (`x' must actually be u_long.)
 *
 * These are used in the multiply code, to split a longword into upper
 * and lower halves, and to reassemble a product as a quad_t, shifted left
 * (sizeof(long)*CHAR_BIT/2).
 */
#define	HHALF(x)	((x) >> HALF_BITS)
#define	LHALF(x)	((x) & ((1 << HALF_BITS) - 1))
#define	LHUP(x)		((x) << HALF_BITS)

typedef unsigned int	qshift_t;

quad_t		__ashldi3(quad_t, qshift_t);
quad_t		__ashrdi3(quad_t, qshift_t);
int		__cmpdi2(quad_t a, quad_t b);
quad_t		__divdi3(quad_t a, quad_t b);
quad_t		__lshrdi3(quad_t, qshift_t);
quad_t		__moddi3(quad_t a, quad_t b);
u_quad_t	__qdivrem(u_quad_t u, u_quad_t v, u_quad_t *rem);
u_quad_t	__udivdi3(u_quad_t a, u_quad_t b);
u_quad_t	__umoddi3(u_quad_t a, u_quad_t b);
int		__ucmpdi2(u_quad_t a, u_quad_t b);
quad_t	__divmoddi4(quad_t a, quad_t b, quad_t *rem);

#endif /* !_LIBKERN_QUAD_H_ */

#if defined (_X86_) && !defined (__x86_64__)
/*
 * Shift a (signed) quad value left (arithmetic shift left).
 * This is the same as logical shift left!
 */
quad_t
__ashldi3(a, shift)
	quad_t a;
	qshift_t shift;
{
	union uu aa;

	aa.q = a;
	if (shift >= LONG_BITS) {
		aa.ul[H] = shift >= QUAD_BITS ? 0 :
		    aa.ul[L] << (shift - LONG_BITS);
		aa.ul[L] = 0;
	} else if (shift > 0) {
		aa.ul[H] = (aa.ul[H] << shift) |
		    (aa.ul[L] >> (LONG_BITS - shift));
		aa.ul[L] <<= shift;
	}
	return (aa.q);
}

/*
 * Shift a (signed) quad value right (arithmetic shift right).
 */
quad_t
__ashrdi3(a, shift)
	quad_t a;
	qshift_t shift;
{
	union uu aa;

	aa.q = a;
	if (shift >= LONG_BITS) {
		long s;

		/*
		 * Smear bits rightward using the machine's right-shift
		 * method, whether that is sign extension or zero fill,
		 * to get the `sign word' s.  Note that shifting by
		 * LONG_BITS is undefined, so we shift (LONG_BITS-1),
		 * then 1 more, to get our answer.
		 */
		s = (aa.sl[H] >> (LONG_BITS - 1)) >> 1;
		aa.ul[L] = shift >= QUAD_BITS ? s :
		    aa.sl[H] >> (shift - LONG_BITS);
		aa.ul[H] = s;
	} else if (shift > 0) {
		aa.ul[L] = (aa.ul[L] >> shift) |
		    (aa.ul[H] << (LONG_BITS - shift));
		aa.sl[H] >>= shift;
	}
	return (aa.q);
}

/*
 * Return 0, 1, or 2 as a <, =, > b respectively.
 * Both a and b are considered signed---which means only the high word is
 * signed.
 */
int
__cmpdi2(a, b)
	quad_t a, b;
{
	union uu aa, bb;

	aa.q = a;
	bb.q = b;
	return (aa.sl[H] < bb.sl[H] ? 0 : aa.sl[H] > bb.sl[H] ? 2 :
	    aa.ul[L] < bb.ul[L] ? 0 : aa.ul[L] > bb.ul[L] ? 2 : 1);
}

/*
 * Divide two signed quads.
 * ??? if -1/2 should produce -1 on this machine, this code is wrong
 */
quad_t
__divdi3(a, b)
	quad_t a, b;
{
	u_quad_t ua, ub, uq;
	int neg;

	if (a < 0)
		ua = -(u_quad_t)a, neg = 1;
	else
		ua = a, neg = 0;
	if (b < 0)
		ub = -(u_quad_t)b, neg ^= 1;
	else
		ub = b;
	uq = __qdivrem(ua, ub, (u_quad_t *)0);
	return (neg ? -uq : uq);
}

/*
 * Shift an (unsigned) quad value right (logical shift right).
 */
quad_t
__lshrdi3(a, shift)
	quad_t a;
	qshift_t shift;
{
	union uu aa;

	aa.q = a;
	if (shift >= LONG_BITS) {
		aa.ul[L] = shift >= QUAD_BITS ? 0 :
		    aa.ul[H] >> (shift - LONG_BITS);
		aa.ul[H] = 0;
	} else if (shift > 0) {
		aa.ul[L] = (aa.ul[L] >> shift) |
		    (aa.ul[H] << (LONG_BITS - shift));
		aa.ul[H] >>= shift;
	}
	return (aa.q);
}

/*
 * Return remainder after dividing two signed quads.
 *
 * XXX
 * If -1/2 should produce -1 on this machine, this code is wrong.
 */
quad_t
__moddi3(a, b)
	quad_t a, b;
{
	u_quad_t ua, ub, ur;
	int neg;

	if (a < 0)
		ua = -(u_quad_t)a, neg = 1;
	else
		ua = a, neg = 0;
	if (b < 0)
		ub = -(u_quad_t)b;
	else
		ub = b;
	(void)__qdivrem(ua, ub, &ur);
	return (neg ? -ur : ur);
}


/*
 * Multiprecision divide.  This algorithm is from Knuth vol. 2 (2nd ed),
 * section 4.3.1, pp. 257--259.
 */

#define	B	(1 << HALF_BITS)	/* digit base */

/* Combine two `digits' to make a single two-digit number. */
#define	COMBINE(a, b) (((u_long)(a) << HALF_BITS) | (b))

/* select a type for digits in base B: use unsigned short if they fit */
#if ULONG_MAX == 0xffffffff && USHRT_MAX >= 0xffff
typedef unsigned short digit;
#else
typedef u_long digit;
#endif

/*
 * Shift p[0]..p[len] left `sh' bits, ignoring any bits that
 * `fall out' the left (there never will be any such anyway).
 * We may assume len >= 0.  NOTE THAT THIS WRITES len+1 DIGITS.
 */
static void
__shl(register digit *p, register int len, register int sh)
{
	register int i;

	for (i = 0; i < len; i++)
		p[i] = LHALF(p[i] << sh) | (p[i + 1] >> (HALF_BITS - sh));
	p[i] = LHALF(p[i] << sh);
}

/*
 * __qdivrem(u, v, rem) returns u/v and, optionally, sets *rem to u%v.
 *
 * We do this in base 2-sup-HALF_BITS, so that all intermediate products
 * fit within u_long.  As a consequence, the maximum length dividend and
 * divisor are 4 `digits' in this base (they are shorter if they have
 * leading zeros).
 */
u_quad_t
__qdivrem(uq, vq, arq)
	u_quad_t uq, vq, *arq;
{
	union uu tmp;
	digit *u, *v, *q;
	register digit v1, v2;
	u_long qhat, rhat, t;
	int m, n, d, j, i;
	digit uspace[5], vspace[5], qspace[5];

	/*
	 * Take care of special cases: divide by zero, and u < v.
	 */
	if (vq == 0) {
		/* divide by zero. */
		static volatile const unsigned int zero = 0;

		tmp.ul[H] = tmp.ul[L] = 1 / zero;
		if (arq)
			*arq = uq;
		return (tmp.q);
	}
	if (uq < vq) {
		if (arq)
			*arq = uq;
		return (0);
	}
	u = &uspace[0];
	v = &vspace[0];
	q = &qspace[0];

	/*
	 * Break dividend and divisor into digits in base B, then
	 * count leading zeros to determine m and n.  When done, we
	 * will have:
	 *	u = (u[1]u[2]...u[m+n]) sub B
	 *	v = (v[1]v[2]...v[n]) sub B
	 *	v[1] != 0
	 *	1 < n <= 4 (if n = 1, we use a different division algorithm)
	 *	m >= 0 (otherwise u < v, which we already checked)
	 *	m + n = 4
	 * and thus
	 *	m = 4 - n <= 2
	 */
	tmp.uq = uq;
	u[0] = 0;
	u[1] = HHALF(tmp.ul[H]);
	u[2] = LHALF(tmp.ul[H]);
	u[3] = HHALF(tmp.ul[L]);
	u[4] = LHALF(tmp.ul[L]);
	tmp.uq = vq;
	v[1] = HHALF(tmp.ul[H]);
	v[2] = LHALF(tmp.ul[H]);
	v[3] = HHALF(tmp.ul[L]);
	v[4] = LHALF(tmp.ul[L]);
	for (n = 4; v[1] == 0; v++) {
		if (--n == 1) {
			u_long rbj;	/* r*B+u[j] (not root boy jim) */
			digit q1, q2, q3, q4;

			/*
			 * Change of plan, per exercise 16.
			 *	r = 0;
			 *	for j = 1..4:
			 *		q[j] = floor((r*B + u[j]) / v),
			 *		r = (r*B + u[j]) % v;
			 * We unroll this completely here.
			 */
			t = v[2];	/* nonzero, by definition */
			q1 = u[1] / t;
			rbj = COMBINE(u[1] % t, u[2]);
			q2 = rbj / t;
			rbj = COMBINE(rbj % t, u[3]);
			q3 = rbj / t;
			rbj = COMBINE(rbj % t, u[4]);
			q4 = rbj / t;
			if (arq)
				*arq = rbj % t;
			tmp.ul[H] = COMBINE(q1, q2);
			tmp.ul[L] = COMBINE(q3, q4);
			return (tmp.q);
		}
	}

	/*
	 * By adjusting q once we determine m, we can guarantee that
	 * there is a complete four-digit quotient at &qspace[1] when
	 * we finally stop.
	 */
	for (m = 4 - n; u[1] == 0; u++)
		m--;
	for (i = 4 - m; --i >= 0;)
		q[i] = 0;
	q += 4 - m;

	/*
	 * Here we run Program D, translated from MIX to C and acquiring
	 * a few minor changes.
	 *
	 * D1: choose multiplier 1 << d to ensure v[1] >= B/2.
	 */
	d = 0;
	for (t = v[1]; t < B / 2; t <<= 1)
		d++;
	if (d > 0) {
		__shl(&u[0], m + n, d);		/* u <<= d */
		__shl(&v[1], n - 1, d);		/* v <<= d */
	}
	/*
	 * D2: j = 0.
	 */
	j = 0;
	v1 = v[1];	/* for D3 -- note that v[1..n] are constant */
	v2 = v[2];	/* for D3 */
	do {
		register digit uj0, uj1, uj2;

		/*
		 * D3: Calculate qhat (\^q, in TeX notation).
		 * Let qhat = min((u[j]*B + u[j+1])/v[1], B-1), and
		 * let rhat = (u[j]*B + u[j+1]) mod v[1].
		 * While rhat < B and v[2]*qhat > rhat*B+u[j+2],
		 * decrement qhat and increase rhat correspondingly.
		 * Note that if rhat >= B, v[2]*qhat < rhat*B.
		 */
		uj0 = u[j + 0];	/* for D3 only -- note that u[j+...] change */
		uj1 = u[j + 1];	/* for D3 only */
		uj2 = u[j + 2];	/* for D3 only */
		if (uj0 == v1) {
			qhat = B;
			rhat = uj1;
			goto qhat_too_big;
		} else {
			u_long nn = COMBINE(uj0, uj1);
			qhat = nn / v1;
			rhat = nn % v1;
		}
		while (v2 * qhat > COMBINE(rhat, uj2)) {
	qhat_too_big:
			qhat--;
			if ((rhat += v1) >= B)
				break;
		}
		/*
		 * D4: Multiply and subtract.
		 * The variable `t' holds any borrows across the loop.
		 * We split this up so that we do not require v[0] = 0,
		 * and to eliminate a final special case.
		 */
		for (t = 0, i = n; i > 0; i--) {
			t = u[i + j] - v[i] * qhat - t;
			u[i + j] = LHALF(t);
			t = (B - HHALF(t)) & (B - 1);
		}
		t = u[j] - t;
		u[j] = LHALF(t);
		/*
		 * D5: test remainder.
		 * There is a borrow if and only if HHALF(t) is nonzero;
		 * in that (rare) case, qhat was too large (by exactly 1).
		 * Fix it by adding v[1..n] to u[j..j+n].
		 */
		if (HHALF(t)) {
			qhat--;
			for (t = 0, i = n; i > 0; i--) { /* D6: add back. */
				t += u[i + j] + v[i];
				u[i + j] = LHALF(t);
				t = HHALF(t);
			}
			u[j] = LHALF(u[j] + t);
		}
		q[j] = qhat;
	} while (++j <= m);		/* D7: loop on j. */

	/*
	 * If caller wants the remainder, we have to calculate it as
	 * u[m..m+n] >> d (this is at most n digits and thus fits in
	 * u[m+1..m+n], but we may need more source digits).
	 */
	if (arq) {
		if (d) {
			for (i = m + n; i > m; --i)
				u[i] = (u[i] >> d) |
				    LHALF(u[i - 1] << (HALF_BITS - d));
			u[i] = 0;
		}
		tmp.ul[H] = COMBINE(uspace[1], uspace[2]);
		tmp.ul[L] = COMBINE(uspace[3], uspace[4]);
		*arq = tmp.q;
	}

	tmp.ul[H] = COMBINE(qspace[1], qspace[2]);
	tmp.ul[L] = COMBINE(qspace[3], qspace[4]);
	return (tmp.q);
}

/*
 * Return 0, 1, or 2 as a <, =, > b respectively.
 * Neither a nor b are considered signed.
 */
int
__ucmpdi2(a, b)
	u_quad_t a, b;
{
	union uu aa, bb;

	aa.uq = a;
	bb.uq = b;
	return (aa.ul[H] < bb.ul[H] ? 0 : aa.ul[H] > bb.ul[H] ? 2 :
	    aa.ul[L] < bb.ul[L] ? 0 : aa.ul[L] > bb.ul[L] ? 2 : 1);
}

/*
 * Divide two unsigned quads.
 */
u_quad_t
__udivdi3(a, b)
	u_quad_t a, b;
{

	return (__qdivrem(a, b, (u_quad_t *)0));
}

/*
 * Return remainder after dividing two unsigned quads.
 */
u_quad_t
__umoddi3(a, b)
	u_quad_t a, b;
{
	u_quad_t r;

	(void)__qdivrem(a, b, &r);
	return (r);
}

/*
 * Divide two signed quads.
 * This function is new in GCC 7.
 */
quad_t
__divmoddi4(a, b, rem)
	quad_t a, b, *rem;
{
	u_quad_t ua, ub, uq, ur;
	int negq, negr;

	if (a < 0)
		ua = -(u_quad_t)a, negq = 1, negr = 1;
	else
		ua = a, negq = 0, negr = 0;
	if (b < 0)
		ub = -(u_quad_t)b, negq ^= 1;
	else
		ub = b;
	uq = __qdivrem(ua, ub, &ur);
	if (rem)
		*rem = (negr ? -ur : ur);
	return (negq ? -uq : uq);
}

#else
static int __attribute__((unused)) dummy;
#endif /*deined (_X86_) && !defined (__x86_64__)*/