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libgcc2.c
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1994-06-02
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/* More subroutines needed by GCC output code on some machines. */
/* Compile this one with gcc. */
/* Copyright (C) 1989, 1992, 1993, 1994 Free Software Foundation, Inc.
This file is part of GNU CC.
GNU CC is free software; you can redistribute it and/or modify
it under the terms of the GNU General Public License as published by
the Free Software Foundation; either version 2, or (at your option)
any later version.
GNU CC 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 General Public License for more details.
You should have received a copy of the GNU General Public License
along with GNU CC; see the file COPYING. If not, write to
the Free Software Foundation, 675 Mass Ave, Cambridge, MA 02139, USA. */
/* As a special exception, if you link this library with other files,
some of which are compiled with GCC, to produce an executable,
this library does not by itself cause the resulting executable
to be covered by the GNU General Public License.
This exception does not however invalidate any other reasons why
the executable file might be covered by the GNU General Public License. */
/* It is incorrect to include config.h here, because this file is being
compiled for the target, and hence definitions concerning only the host
do not apply. */
#include "tconfig.h"
#include "machmode.h"
#ifndef L_trampoline
#include <stddef.h>
#endif
/* Don't use `fancy_abort' here even if config.h says to use it. */
#ifdef abort
#undef abort
#endif
/* In the first part of this file, we are interfacing to calls generated
by the compiler itself. These calls pass values into these routines
which have very specific modes (rather than very specific types), and
these compiler-generated calls also expect any return values to have
very specific modes (rather than very specific types). Thus, we need
to avoid using regular C language type names in this part of the file
because the sizes for those types can be configured to be anything.
Instead we use the following special type names. */
typedef unsigned int UQItype __attribute__ ((mode (QI)));
typedef int SItype __attribute__ ((mode (SI)));
typedef unsigned int USItype __attribute__ ((mode (SI)));
typedef int DItype __attribute__ ((mode (DI)));
typedef unsigned int UDItype __attribute__ ((mode (DI)));
typedef float SFtype __attribute__ ((mode (SF)));
typedef float DFtype __attribute__ ((mode (DF)));
#if LONG_DOUBLE_TYPE_SIZE == 96
typedef float XFtype __attribute__ ((mode (XF)));
#endif
#if LONG_DOUBLE_TYPE_SIZE == 128
typedef float TFtype __attribute__ ((mode (TF)));
#endif
#if BITS_PER_WORD==16
typedef int word_type __attribute__ ((mode (HI)));
#endif
#if BITS_PER_WORD==32
typedef int word_type __attribute__ ((mode (SI)));
#endif
#if BITS_PER_WORD==64
typedef int word_type __attribute__ ((mode (DI)));
#endif
/* Make sure that we don't accidentally use any normal C language built-in
type names in the first part of this file. Instead we want to use *only*
the type names defined above. The following macro definitions insure
that if we *do* accidentally use some normal C language built-in type name,
we will get a syntax error. */
#define char bogus_type
#define short bogus_type
#define int bogus_type
#define long bogus_type
#define unsigned bogus_type
#define float bogus_type
#define double bogus_type
#define SI_TYPE_SIZE (sizeof (SItype) * BITS_PER_UNIT)
/* DIstructs are pairs of SItype values in the order determined by
WORDS_BIG_ENDIAN. */
#if WORDS_BIG_ENDIAN
struct DIstruct {SItype high, low;};
#else
struct DIstruct {SItype low, high;};
#endif
/* We need this union to unpack/pack DImode values, since we don't have
any arithmetic yet. Incoming DImode parameters are stored into the
`ll' field, and the unpacked result is read from the struct `s'. */
typedef union
{
struct DIstruct s;
DItype ll;
} DIunion;
#if defined (L_udivmoddi4) || defined (L_muldi3) || defined (L_udiv_w_sdiv)
#include "longlong.h"
#endif /* udiv or mul */
extern DItype __fixunssfdi (SFtype a);
extern DItype __fixunsdfdi (DFtype a);
#if LONG_DOUBLE_TYPE_SIZE == 96
extern DItype __fixunsxfdi (XFtype a);
#endif
#if LONG_DOUBLE_TYPE_SIZE == 128
extern DItype __fixunstfdi (TFtype a);
#endif
#if defined (L_negdi2) || defined (L_divdi3) || defined (L_moddi3)
#if defined (L_divdi3) || defined (L_moddi3)
static inline
#endif
DItype
__negdi2 (u)
DItype u;
{
DIunion w;
DIunion uu;
uu.ll = u;
w.s.low = -uu.s.low;
w.s.high = -uu.s.high - ((USItype) w.s.low > 0);
return w.ll;
}
#endif
#ifdef L_lshldi3
DItype
__lshldi3 (u, b)
DItype u;
SItype b;
{
DIunion w;
SItype bm;
DIunion uu;
if (b == 0)
return u;
uu.ll = u;
bm = (sizeof (SItype) * BITS_PER_UNIT) - b;
if (bm <= 0)
{
w.s.low = 0;
w.s.high = (USItype)uu.s.low << -bm;
}
else
{
USItype carries = (USItype)uu.s.low >> bm;
w.s.low = (USItype)uu.s.low << b;
w.s.high = ((USItype)uu.s.high << b) | carries;
}
return w.ll;
}
#endif
#ifdef L_lshrdi3
DItype
__lshrdi3 (u, b)
DItype u;
SItype b;
{
DIunion w;
SItype bm;
DIunion uu;
if (b == 0)
return u;
uu.ll = u;
bm = (sizeof (SItype) * BITS_PER_UNIT) - b;
if (bm <= 0)
{
w.s.high = 0;
w.s.low = (USItype)uu.s.high >> -bm;
}
else
{
USItype carries = (USItype)uu.s.high << bm;
w.s.high = (USItype)uu.s.high >> b;
w.s.low = ((USItype)uu.s.low >> b) | carries;
}
return w.ll;
}
#endif
#ifdef L_ashldi3
DItype
__ashldi3 (u, b)
DItype u;
SItype b;
{
DIunion w;
SItype bm;
DIunion uu;
if (b == 0)
return u;
uu.ll = u;
bm = (sizeof (SItype) * BITS_PER_UNIT) - b;
if (bm <= 0)
{
w.s.low = 0;
w.s.high = (USItype)uu.s.low << -bm;
}
else
{
USItype carries = (USItype)uu.s.low >> bm;
w.s.low = (USItype)uu.s.low << b;
w.s.high = ((USItype)uu.s.high << b) | carries;
}
return w.ll;
}
#endif
#ifdef L_ashrdi3
DItype
__ashrdi3 (u, b)
DItype u;
SItype b;
{
DIunion w;
SItype bm;
DIunion uu;
if (b == 0)
return u;
uu.ll = u;
bm = (sizeof (SItype) * BITS_PER_UNIT) - b;
if (bm <= 0)
{
/* w.s.high = 1..1 or 0..0 */
w.s.high = uu.s.high >> (sizeof (SItype) * BITS_PER_UNIT - 1);
w.s.low = uu.s.high >> -bm;
}
else
{
USItype carries = (USItype)uu.s.high << bm;
w.s.high = uu.s.high >> b;
w.s.low = ((USItype)uu.s.low >> b) | carries;
}
return w.ll;
}
#endif
#ifdef L_ffsdi2
DItype
__ffsdi2 (u)
DItype u;
{
DIunion uu, w;
uu.ll = u;
w.s.high = 0;
w.s.low = ffs (uu.s.low);
if (w.s.low != 0)
return w.ll;
w.s.low = ffs (uu.s.high);
if (w.s.low != 0)
{
w.s.low += BITS_PER_UNIT * sizeof (SItype);
return w.ll;
}
return w.ll;
}
#endif
#ifdef L_muldi3
DItype
__muldi3 (u, v)
DItype u, v;
{
DIunion w;
DIunion uu, vv;
uu.ll = u,
vv.ll = v;
w.ll = __umulsidi3 (uu.s.low, vv.s.low);
w.s.high += ((USItype) uu.s.low * (USItype) vv.s.high
+ (USItype) uu.s.high * (USItype) vv.s.low);
return w.ll;
}
#endif
#ifdef L_udiv_w_sdiv
USItype
__udiv_w_sdiv (rp, a1, a0, d)
USItype *rp, a1, a0, d;
{
USItype q, r;
USItype c0, c1, b1;
if ((SItype) d >= 0)
{
if (a1 < d - a1 - (a0 >> (SI_TYPE_SIZE - 1)))
{
/* dividend, divisor, and quotient are nonnegative */
sdiv_qrnnd (q, r, a1, a0, d);
}
else
{
/* Compute c1*2^32 + c0 = a1*2^32 + a0 - 2^31*d */
sub_ddmmss (c1, c0, a1, a0, d >> 1, d << (SI_TYPE_SIZE - 1));
/* Divide (c1*2^32 + c0) by d */
sdiv_qrnnd (q, r, c1, c0, d);
/* Add 2^31 to quotient */
q += (USItype) 1 << (SI_TYPE_SIZE - 1);
}
}
else
{
b1 = d >> 1; /* d/2, between 2^30 and 2^31 - 1 */
c1 = a1 >> 1; /* A/2 */
c0 = (a1 << (SI_TYPE_SIZE - 1)) + (a0 >> 1);
if (a1 < b1) /* A < 2^32*b1, so A/2 < 2^31*b1 */
{
sdiv_qrnnd (q, r, c1, c0, b1); /* (A/2) / (d/2) */
r = 2*r + (a0 & 1); /* Remainder from A/(2*b1) */
if ((d & 1) != 0)
{
if (r >= q)
r = r - q;
else if (q - r <= d)
{
r = r - q + d;
q--;
}
else
{
r = r - q + 2*d;
q -= 2;
}
}
}
else if (c1 < b1) /* So 2^31 <= (A/2)/b1 < 2^32 */
{
c1 = (b1 - 1) - c1;
c0 = ~c0; /* logical NOT */
sdiv_qrnnd (q, r, c1, c0, b1); /* (A/2) / (d/2) */
q = ~q; /* (A/2)/b1 */
r = (b1 - 1) - r;
r = 2*r + (a0 & 1); /* A/(2*b1) */
if ((d & 1) != 0)
{
if (r >= q)
r = r - q;
else if (q - r <= d)
{
r = r - q + d;
q--;
}
else
{
r = r - q + 2*d;
q -= 2;
}
}
}
else /* Implies c1 = b1 */
{ /* Hence a1 = d - 1 = 2*b1 - 1 */
if (a0 >= -d)
{
q = -1;
r = a0 + d;
}
else
{
q = -2;
r = a0 + 2*d;
}
}
}
*rp = r;
return q;
}
#endif
#ifdef L_udivmoddi4
static const UQItype __clz_tab[] =
{
0,1,2,2,3,3,3,3,4,4,4,4,4,4,4,4,5,5,5,5,5,5,5,5,5,5,5,5,5,5,5,5,
6,6,6,6,6,6,6,6,6,6,6,6,6,6,6,6,6,6,6,6,6,6,6,6,6,6,6,6,6,6,6,6,
7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,
7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,7,
8,8,8,8,8,8,8,8,8,8,8,8,8,8,8,8,8,8,8,8,8,8,8,8,8,8,8,8,8,8,8,8,
8,8,8,8,8,8,8,8,8,8,8,8,8,8,8,8,8,8,8,8,8,8,8,8,8,8,8,8,8,8,8,8,
8,8,8,8,8,8,8,8,8,8,8,8,8,8,8,8,8,8,8,8,8,8,8,8,8,8,8,8,8,8,8,8,
8,8,8,8,8,8,8,8,8,8,8,8,8,8,8,8,8,8,8,8,8,8,8,8,8,8,8,8,8,8,8,8,
};
UDItype
__udivmoddi4 (n, d, rp)
UDItype n, d;
UDItype *rp;
{
DIunion ww;
DIunion nn, dd;
DIunion rr;
USItype d0, d1, n0, n1, n2;
USItype q0, q1;
USItype b, bm;
nn.ll = n;
dd.ll = d;
d0 = dd.s.low;
d1 = dd.s.high;
n0 = nn.s.low;
n1 = nn.s.high;
#if !UDIV_NEEDS_NORMALIZATION
if (d1 == 0)
{
if (d0 > n1)
{
/* 0q = nn / 0D */
udiv_qrnnd (q0, n0, n1, n0, d0);
q1 = 0;
/* Remainder in n0. */
}
else
{
/* qq = NN / 0d */
if (d0 == 0)
d0 = 1 / d0; /* Divide intentionally by zero. */
udiv_qrnnd (q1, n1, 0, n1, d0);
udiv_qrnnd (q0, n0, n1, n0, d0);
/* Remainder in n0. */
}
if (rp != 0)
{
rr.s.low = n0;
rr.s.high = 0;
*rp = rr.ll;
}
}
#else /* UDIV_NEEDS_NORMALIZATION */
if (d1 == 0)
{
if (d0 > n1)
{
/* 0q = nn / 0D */
count_leading_zeros (bm, d0);
if (bm != 0)
{
/* Normalize, i.e. make the most significant bit of the
denominator set. */
d0 = d0 << bm;
n1 = (n1 << bm) | (n0 >> (SI_TYPE_SIZE - bm));
n0 = n0 << bm;
}
udiv_qrnnd (q0, n0, n1, n0, d0);
q1 = 0;
/* Remainder in n0 >> bm. */
}
else
{
/* qq = NN / 0d */
if (d0 == 0)
d0 = 1 / d0; /* Divide intentionally by zero. */
count_leading_zeros (bm, d0);
if (bm == 0)
{
/* From (n1 >= d0) /\ (the most significant bit of d0 is set),
conclude (the most significant bit of n1 is set) /\ (the
leading quotient digit q1 = 1).
This special case is necessary, not an optimization.
(Shifts counts of SI_TYPE_SIZE are undefined.) */
n1 -= d0;
q1 = 1;
}
else
{
/* Normalize. */
b = SI_TYPE_SIZE - bm;
d0 = d0 << bm;
n2 = n1 >> b;
n1 = (n1 << bm) | (n0 >> b);
n0 = n0 << bm;
udiv_qrnnd (q1, n1, n2, n1, d0);
}
/* n1 != d0... */
udiv_qrnnd (q0, n0, n1, n0, d0);
/* Remainder in n0 >> bm. */
}
if (rp != 0)
{
rr.s.low = n0 >> bm;
rr.s.high = 0;
*rp = rr.ll;
}
}
#endif /* UDIV_NEEDS_NORMALIZATION */
else
{
if (d1 > n1)
{
/* 00 = nn / DD */
q0 = 0;
q1 = 0;
/* Remainder in n1n0. */
if (rp != 0)
{
rr.s.low = n0;
rr.s.high = n1;
*rp = rr.ll;
}
}
else
{
/* 0q = NN / dd */
count_leading_zeros (bm, d1);
if (bm == 0)
{
/* From (n1 >= d1) /\ (the most significant bit of d1 is set),
conclude (the most significant bit of n1 is set) /\ (the
quotient digit q0 = 0 or 1).
This special case is necessary, not an optimization. */
/* The condition on the next line takes advantage of that
n1 >= d1 (true due to program flow). */
if (n1 > d1 || n0 >= d0)
{
q0 = 1;
sub_ddmmss (n1, n0, n1, n0, d1, d0);
}
else
q0 = 0;
q1 = 0;
if (rp != 0)
{
rr.s.low = n0;
rr.s.high = n1;
*rp = rr.ll;
}
}
else
{
USItype m1, m0;
/* Normalize. */
b = SI_TYPE_SIZE - bm;
d1 = (d1 << bm) | (d0 >> b);
d0 = d0 << bm;
n2 = n1 >> b;
n1 = (n1 << bm) | (n0 >> b);
n0 = n0 << bm;
udiv_qrnnd (q0, n1, n2, n1, d1);
umul_ppmm (m1, m0, q0, d0);
if (m1 > n1 || (m1 == n1 && m0 > n0))
{
q0--;
sub_ddmmss (m1, m0, m1, m0, d1, d0);
}
q1 = 0;
/* Remainder in (n1n0 - m1m0) >> bm. */
if (rp != 0)
{
sub_ddmmss (n1, n0, n1, n0, m1, m0);
rr.s.low = (n1 << b) | (n0 >> bm);
rr.s.high = n1 >> bm;
*rp = rr.ll;
}
}
}
}
ww.s.low = q0;
ww.s.high = q1;
return ww.ll;
}
#endif
#ifdef L_divdi3
UDItype __udivmoddi4 ();
DItype
__divdi3 (u, v)
DItype u, v;
{
SItype c = 0;
DIunion uu, vv;
DItype w;
uu.ll = u;
vv.ll = v;
if (uu.s.high < 0)
c = ~c,
uu.ll = __negdi2 (uu.ll);
if (vv.s.high < 0)
c = ~c,
vv.ll = __negdi2 (vv.ll);
w = __udivmoddi4 (uu.ll, vv.ll, (UDItype *) 0);
if (c)
w = __negdi2 (w);
return w;
}
#endif
#ifdef L_moddi3
UDItype __udivmoddi4 ();
DItype
__moddi3 (u, v)
DItype u, v;
{
SItype c = 0;
DIunion uu, vv;
DItype w;
uu.ll = u;
vv.ll = v;
if (uu.s.high < 0)
c = ~c,
uu.ll = __negdi2 (uu.ll);
if (vv.s.high < 0)
vv.ll = __negdi2 (vv.ll);
(void) __udivmoddi4 (uu.ll, vv.ll, &w);
if (c)
w = __negdi2 (w);
return w;
}
#endif
#ifdef L_umoddi3
UDItype __udivmoddi4 ();
UDItype
__umoddi3 (u, v)
UDItype u, v;
{
UDItype w;
(void) __udivmoddi4 (u, v, &w);
return w;
}
#endif
#ifdef L_udivdi3
UDItype __udivmoddi4 ();
UDItype
__udivdi3 (n, d)
UDItype n, d;
{
return __udivmoddi4 (n, d, (UDItype *) 0);
}
#endif
#ifdef L_cmpdi2
word_type
__cmpdi2 (a, b)
DItype a, b;
{
DIunion au, bu;
au.ll = a, bu.ll = b;
if (au.s.high < bu.s.high)
return 0;
else if (au.s.high > bu.s.high)
return 2;
if ((USItype) au.s.low < (USItype) bu.s.low)
return 0;
else if ((USItype) au.s.low > (USItype) bu.s.low)
return 2;
return 1;
}
#endif
#ifdef L_ucmpdi2
word_type
__ucmpdi2 (a, b)
DItype a, b;
{
DIunion au, bu;
au.ll = a, bu.ll = b;
if ((USItype) au.s.high < (USItype) bu.s.high)
return 0;
else if ((USItype) au.s.high > (USItype) bu.s.high)
return 2;
if ((USItype) au.s.low < (USItype) bu.s.low)
return 0;
else if ((USItype) au.s.low > (USItype) bu.s.low)
return 2;
return 1;
}
#endif
#if defined(L_fixunstfdi) && (LONG_DOUBLE_TYPE_SIZE == 128)
#define WORD_SIZE (sizeof (SItype) * BITS_PER_UNIT)
#define HIGH_WORD_COEFF (((UDItype) 1) << WORD_SIZE)
DItype
__fixunstfdi (a)
TFtype a;
{
TFtype b;
UDItype v;
if (a < 0)
return 0;
/* Compute high word of result, as a flonum. */
b = (a / HIGH_WORD_COEFF);
/* Convert that to fixed (but not to DItype!),
and shift it into the high word. */
v = (USItype) b;
v <<= WORD_SIZE;
/* Remove high part from the TFtype, leaving the low part as flonum. */
a -= (TFtype)v;
/* Convert that to fixed (but not to DItype!) and add it in.
Sometimes A comes out negative. This is significant, since
A has more bits than a long int does. */
if (a < 0)
v -= (USItype) (- a);
else
v += (USItype) a;
return v;
}
#endif
#if defined(L_fixtfdi) && (LONG_DOUBLE_TYPE_SIZE == 128)
DItype
__fixtfdi (a)
TFtype a;
{
if (a < 0)
return - __fixunstfdi (-a);
return __fixunstfdi (a);
}
#endif
#if defined(L_fixunsxfdi) && (LONG_DOUBLE_TYPE_SIZE == 96)
#define WORD_SIZE (sizeof (SItype) * BITS_PER_UNIT)
#define HIGH_WORD_COEFF (((UDItype) 1) << WORD_SIZE)
DItype
__fixunsxfdi (a)
XFtype a;
{
XFtype b;
UDItype v;
if (a < 0)
return 0;
/* Compute high word of result, as a flonum. */
b = (a / HIGH_WORD_COEFF);
/* Convert that to fixed (but not to DItype!),
and shift it into the high word. */
v = (USItype) b;
v <<= WORD_SIZE;
/* Remove high part from the XFtype, leaving the low part as flonum. */
a -= (XFtype)v;
/* Convert that to fixed (but not to DItype!) and add it in.
Sometimes A comes out negative. This is significant, since
A has more bits than a long int does. */
if (a < 0)
v -= (USItype) (- a);
else
v += (USItype) a;
return v;
}
#endif
#if defined(L_fixxfdi) && (LONG_DOUBLE_TYPE_SIZE == 96)
DItype
__fixxfdi (a)
XFtype a;
{
if (a < 0)
return - __fixunsxfdi (-a);
return __fixunsxfdi (a);
}
#endif
#ifdef L_fixunsdfdi
#define WORD_SIZE (sizeof (SItype) * BITS_PER_UNIT)
#define HIGH_WORD_COEFF (((UDItype) 1) << WORD_SIZE)
DItype
__fixunsdfdi (a)
DFtype a;
{
DFtype b;
UDItype v;
if (a < 0)
return 0;
/* Compute high word of result, as a flonum. */
b = (a / HIGH_WORD_COEFF);
/* Convert that to fixed (but not to DItype!),
and shift it into the high word. */
v = (USItype) b;
v <<= WORD_SIZE;
/* Remove high part from the DFtype, leaving the low part as flonum. */
a -= (DFtype)v;
/* Convert that to fixed (but not to DItype!) and add it in.
Sometimes A comes out negative. This is significant, since
A has more bits than a long int does. */
if (a < 0)
v -= (USItype) (- a);
else
v += (USItype) a;
return v;
}
#endif
#ifdef L_fixdfdi
DItype
__fixdfdi (a)
DFtype a;
{
if (a < 0)
return - __fixunsdfdi (-a);
return __fixunsdfdi (a);
}
#endif
#ifdef L_fixunssfdi
#define WORD_SIZE (sizeof (SItype) * BITS_PER_UNIT)
#define HIGH_WORD_COEFF (((UDItype) 1) << WORD_SIZE)
DItype
__fixunssfdi (SFtype original_a)
{
/* Convert the SFtype to a DFtype, because that is surely not going
to lose any bits. Some day someone else can write a faster version
that avoids converting to DFtype, and verify it really works right. */
DFtype a = original_a;
DFtype b;
UDItype v;
if (a < 0)
return 0;
/* Compute high word of result, as a flonum. */
b = (a / HIGH_WORD_COEFF);
/* Convert that to fixed (but not to DItype!),
and shift it into the high word. */
v = (USItype) b;
v <<= WORD_SIZE;
/* Remove high part from the DFtype, leaving the low part as flonum. */
a -= (DFtype)v;
/* Convert that to fixed (but not to DItype!) and add it in.
Sometimes A comes out negative. This is significant, since
A has more bits than a long int does. */
if (a < 0)
v -= (USItype) (- a);
else
v += (USItype) a;
return v;
}
#endif
#ifdef L_fixsfdi
DItype
__fixsfdi (SFtype a)
{
if (a < 0)
return - __fixunssfdi (-a);
return __fixunssfdi (a);
}
#endif
#if defined(L_floatdixf) && (LONG_DOUBLE_TYPE_SIZE == 96)
#define WORD_SIZE (sizeof (SItype) * BITS_PER_UNIT)
#define HIGH_HALFWORD_COEFF (((UDItype) 1) << (WORD_SIZE / 2))
#define HIGH_WORD_COEFF (((UDItype) 1) << WORD_SIZE)
XFtype
__floatdixf (u)
DItype u;
{
XFtype d;
SItype negate = 0;
if (u < 0)
u = -u, negate = 1;
d = (USItype) (u >> WORD_SIZE);
d *= HIGH_HALFWORD_COEFF;
d *= HIGH_HALFWORD_COEFF;
d += (USItype) (u & (HIGH_WORD_COEFF - 1));
return (negate ? -d : d);
}
#endif
#if defined(L_floatditf) && (LONG_DOUBLE_TYPE_SIZE == 128)
#define WORD_SIZE (sizeof (SItype) * BITS_PER_UNIT)
#define HIGH_HALFWORD_COEFF (((UDItype) 1) << (WORD_SIZE / 2))
#define HIGH_WORD_COEFF (((UDItype) 1) << WORD_SIZE)
TFtype
__floatditf (u)
DItype u;
{
TFtype d;
SItype negate = 0;
if (u < 0)
u = -u, negate = 1;
d = (USItype) (u >> WORD_SIZE);
d *= HIGH_HALFWORD_COEFF;
d *= HIGH_HALFWORD_COEFF;
d += (USItype) (u & (HIGH_WORD_COEFF - 1));
return (negate ? -d : d);
}
#endif
#ifdef L_floatdidf
#define WORD_SIZE (sizeof (SItype) * BITS_PER_UNIT)
#define HIGH_HALFWORD_COEFF (((UDItype) 1) << (WORD_SIZE / 2))
#define HIGH_WORD_COEFF (((UDItype) 1) << WORD_SIZE)
DFtype
__floatdidf (u)
DItype u;
{
DFtype d;
SItype negate = 0;
if (u < 0)
u = -u, negate = 1;
d = (USItype) (u >> WORD_SIZE);
d *= HIGH_HALFWORD_COEFF;
d *= HIGH_HALFWORD_COEFF;
d += (USItype) (u & (HIGH_WORD_COEFF - 1));
return (negate ? -d : d);
}
#endif
#ifdef L_floatdisf
#define WORD_SIZE (sizeof (SItype) * BITS_PER_UNIT)
#define HIGH_HALFWORD_COEFF (((UDItype) 1) << (WORD_SIZE / 2))
#define HIGH_WORD_COEFF (((UDItype) 1) << WORD_SIZE)
#define DI_SIZE (sizeof (DItype) * BITS_PER_UNIT)
#if TARGET_FLOAT_FORMAT == IEEE_FLOAT_FORMAT
#define DF_SIZE 53
#define SF_SIZE 24
#else
#if TARGET_FLOAT_FORMAT == IBM_FLOAT_FORMAT
#define DF_SIZE 56
#define SF_SIZE 24
#else
#if TARGET_FLOAT_FORMAT == VAX_FLOAT_FORMAT
#define DF_SIZE 56
#define SF_SIZE 24
#else
#define DF_SIZE 0
#define SF_SIZE 0
#endif
#endif
#endif
SFtype
__floatdisf (u)
DItype u;
{
/* Do the calculation in DFmode
so that we don't lose any of the precision of the high word
while multiplying it. */
DFtype f;
SItype negate = 0;
if (u < 0)
u = -u, negate = 1;
/* Protect against double-rounding error.
Represent any low-order bits, that might be truncated in DFmode,
by a bit that won't be lost. The bit can go in anywhere below the
rounding position of the SFmode. A fixed mask and bit position
handles all usual configurations. It doesn't handle the case
of 128-bit DImode, however. */
if (DF_SIZE < DI_SIZE
&& DF_SIZE > (DI_SIZE - DF_SIZE + SF_SIZE))
{
#define REP_BIT ((USItype) 1 << (DI_SIZE - DF_SIZE))
if (u >= ((UDItype) 1 << DF_SIZE))
{
if ((USItype) u & (REP_BIT - 1))
u |= REP_BIT;
}
}
f = (USItype) (u >> WORD_SIZE);
f *= HIGH_HALFWORD_COEFF;
f *= HIGH_HALFWORD_COEFF;
f += (USItype) (u & (HIGH_WORD_COEFF - 1));
return (SFtype) (negate ? -f : f);
}
#endif
#if defined(L_fixunsxfsi) && LONG_DOUBLE_TYPE_SIZE == 96
#include "glimits.h"
USItype
__fixunsxfsi (a)
XFtype a;
{
if (a >= - (DFtype) LONG_MIN)
return (SItype) (a + LONG_MIN) - LONG_MIN;
return (SItype) a;
}
#endif
#ifdef L_fixunsdfsi
#include "glimits.h"
USItype
__fixunsdfsi (a)
DFtype a;
{
if (a >= - (DFtype) LONG_MIN)
return (SItype) (a + LONG_MIN) - LONG_MIN;
return (SItype) a;
}
#endif
#ifdef L_fixunssfsi
#include "glimits.h"
USItype
__fixunssfsi (SFtype a)
{
if (a >= - (SFtype) LONG_MIN)
return (SItype) (a + LONG_MIN) - LONG_MIN;
return (SItype) a;
}
#endif
/* From here on down, the routines use normal data types. */
#define SItype bogus_type
#define USItype bogus_type
#define DItype bogus_type
#define UDItype bogus_type
#define SFtype bogus_type
#define DFtype bogus_type
#undef char
#undef short
#undef int
#undef long
#undef unsigned
#undef float
#undef double
#ifdef L__gcc_bcmp
/* Like bcmp except the sign is meaningful.
Reult is negative if S1 is less than S2,
positive if S1 is greater, 0 if S1 and S2 are equal. */
int
__gcc_bcmp (s1, s2, size)
unsigned char *s1, *s2;
size_t size;
{
while (size > 0)
{
unsigned char c1 = *s1++, c2 = *s2++;
if (c1 != c2)
return c1 - c2;
size--;
}
return 0;
}
#endif
#ifdef L_varargs
#ifdef __i860__
#if defined(__svr4__) || defined(__alliant__)
asm (" .text");
asm (" .align 4");
/* The Alliant needs the added underscore. */
asm (".globl __builtin_saveregs");
asm ("__builtin_saveregs:");
asm (".globl ___builtin_saveregs");
asm ("___builtin_saveregs:");
asm (" andnot 0x0f,%sp,%sp"); /* round down to 16-byte boundary */
asm (" adds -96,%sp,%sp"); /* allocate stack space for reg save
area and also for a new va_list
structure */
/* Save all argument registers in the arg reg save area. The
arg reg save area must have the following layout (according
to the svr4 ABI):
struct {
union {
float freg[8];
double dreg[4];
} float_regs;
long ireg[12];
};
*/
asm (" fst.q %f8, 0(%sp)"); /* save floating regs (f8-f15) */
asm (" fst.q %f12,16(%sp)");
asm (" st.l %r16,32(%sp)"); /* save integer regs (r16-r27) */
asm (" st.l %r17,36(%sp)");
asm (" st.l %r18,40(%sp)");
asm (" st.l %r19,44(%sp)");
asm (" st.l %r20,48(%sp)");
asm (" st.l %r21,52(%sp)");
asm (" st.l %r22,56(%sp)");
asm (" st.l %r23,60(%sp)");
asm (" st.l %r24,64(%sp)");
asm (" st.l %r25,68(%sp)");
asm (" st.l %r26,72(%sp)");
asm (" st.l %r27,76(%sp)");
asm (" adds 80,%sp,%r16"); /* compute the address of the new
va_list structure. Put in into
r16 so that it will be returned
to the caller. */
/* Initialize all fields of the new va_list structure. This
structure looks like:
typedef struct {
unsigned long ireg_used;
unsigned long freg_used;
long *reg_base;
long *mem_ptr;
} va_list;
*/
asm (" st.l %r0, 0(%r16)"); /* nfixed */
asm (" st.l %r0, 4(%r16)"); /* nfloating */
asm (" st.l %sp, 8(%r16)"); /* __va_ctl points to __va_struct. */
asm (" bri %r1"); /* delayed return */
asm (" st.l %r28,12(%r16)"); /* pointer to overflow args */
#else /* not __svr4__ */
#if defined(__PARAGON__)
/*
* we'll use SVR4-ish varargs but need SVR3.2 assembler syntax,
* and we stand a better chance of hooking into libraries
* compiled by PGI. [andyp@ssd.intel.com]
*/
asm (" .text");
asm (" .align 4");
asm (".globl __builtin_saveregs");
asm ("__builtin_saveregs:");
asm (".globl ___builtin_saveregs");
asm ("___builtin_saveregs:");
asm (" andnot 0x0f,sp,sp"); /* round down to 16-byte boundary */
asm (" adds -96,sp,sp"); /* allocate stack space for reg save
area and also for a new va_list
structure */
/* Save all argument registers in the arg reg save area. The
arg reg save area must have the following layout (according
to the svr4 ABI):
struct {
union {
float freg[8];
double dreg[4];
} float_regs;
long ireg[12];
};
*/
asm (" fst.q f8, 0(sp)");
asm (" fst.q f12,16(sp)");
asm (" st.l r16,32(sp)");
asm (" st.l r17,36(sp)");
asm (" st.l r18,40(sp)");
asm (" st.l r19,44(sp)");
asm (" st.l r20,48(sp)");
asm (" st.l r21,52(sp)");
asm (" st.l r22,56(sp)");
asm (" st.l r23,60(sp)");
asm (" st.l r24,64(sp)");
asm (" st.l r25,68(sp)");
asm (" st.l r26,72(sp)");
asm (" st.l r27,76(sp)");
asm (" adds 80,sp,r16"); /* compute the address of the new
va_list structure. Put in into
r16 so that it will be returned
to the caller. */
/* Initialize all fields of the new va_list structure. This
structure looks like:
typedef struct {
unsigned long ireg_used;
unsigned long freg_used;
long *reg_base;
long *mem_ptr;
} va_list;
*/
asm (" st.l r0, 0(r16)"); /* nfixed */
asm (" st.l r0, 4(r16)"); /* nfloating */
asm (" st.l sp, 8(r16)"); /* __va_ctl points to __va_struct. */
asm (" bri r1"); /* delayed return */
asm (" st.l r28,12(r16)"); /* pointer to overflow args */
#else /* not __PARAGON__ */
asm (" .text");
asm (" .align 4");
asm (".globl ___builtin_saveregs");
asm ("___builtin_saveregs:");
asm (" mov sp,r30");
asm (" andnot 0x0f,sp,sp");
asm (" adds -96,sp,sp"); /* allocate sufficient space on the stack */
/* Fill in the __va_struct. */
asm (" st.l r16, 0(sp)"); /* save integer regs (r16-r27) */
asm (" st.l r17, 4(sp)"); /* int fixed[12] */
asm (" st.l r18, 8(sp)");
asm (" st.l r19,12(sp)");
asm (" st.l r20,16(sp)");
asm (" st.l r21,20(sp)");
asm (" st.l r22,24(sp)");
asm (" st.l r23,28(sp)");
asm (" st.l r24,32(sp)");
asm (" st.l r25,36(sp)");
asm (" st.l r26,40(sp)");
asm (" st.l r27,44(sp)");
asm (" fst.q f8, 48(sp)"); /* save floating regs (f8-f15) */
asm (" fst.q f12,64(sp)"); /* int floating[8] */
/* Fill in the __va_ctl. */
asm (" st.l sp, 80(sp)"); /* __va_ctl points to __va_struct. */
asm (" st.l r28,84(sp)"); /* pointer to more args */
asm (" st.l r0, 88(sp)"); /* nfixed */
asm (" st.l r0, 92(sp)"); /* nfloating */
asm (" adds 80,sp,r16"); /* return address of the __va_ctl. */
asm (" bri r1");
asm (" mov r30,sp");
/* recover stack and pass address to start
of data. */
#endif /* not __PARAGON__ */
#endif /* not __svr4__ */
#else /* not __i860__ */
#ifdef __sparc__
asm (".global __builtin_saveregs");
asm ("__builtin_saveregs:");
asm (".global ___builtin_saveregs");
asm ("___builtin_saveregs:");
#ifdef NEED_PROC_COMMAND
asm (".proc 020");
#endif
asm ("st %i0,[%fp+68]");
asm ("st %i1,[%fp+72]");
asm ("st %i2,[%fp+76]");
asm ("st %i3,[%fp+80]");
asm ("st %i4,[%fp+84]");
asm ("retl");
asm ("st %i5,[%fp+88]");
#ifdef NEED_TYPE_COMMAND
asm (".type __builtin_saveregs,#function");
asm (".size __builtin_saveregs,.-__builtin_saveregs");
#endif
#else /* not __sparc__ */
#if defined(__MIPSEL__) | defined(__R3000__) | defined(__R2000__) | defined(__mips__)
asm (" .text");
asm (" .ent __builtin_saveregs");
asm (" .globl __builtin_saveregs");
asm ("__builtin_saveregs:");
asm (" sw $4,0($30)");
asm (" sw $5,4($30)");
asm (" sw $6,8($30)");
asm (" sw $7,12($30)");
asm (" j $31");
asm (" .end __builtin_saveregs");
#else /* not __mips__, etc. */
void *
__builtin_saveregs ()
{
abort ();
}
#endif /* not __mips__ */
#endif /* not __sparc__ */
#endif /* not __i860__ */
#endif
#ifdef L_eprintf
#ifndef inhibit_libc
#undef NULL /* Avoid errors if stdio.h and our stddef.h mismatch. */
#include <stdio.h>
/* This is used by the `assert' macro. */
void
__eprintf (string, expression, line, filename)
const char *string;
const char *expression;
int line;
const char *filename;
{
fprintf (stderr, string, expression, line, filename);
fflush (stderr);
abort ();
}
#endif
#endif
#ifdef L_bb
/* Structure emitted by -a */
struct bb
{
long zero_word;
const char *filename;
long *counts;
long ncounts;
struct bb *next;
const unsigned long *addresses;
/* Older GCC's did not emit these fields. */
long nwords;
const char **functions;
const long *line_nums;
const char **filenames;
};
#ifdef BLOCK_PROFILER_CODE
BLOCK_PROFILER_CODE
#else
#ifndef inhibit_libc
/* Simple minded basic block profiling output dumper for
systems that don't provde tcov support. At present,
it requires atexit and stdio. */
#undef NULL /* Avoid errors if stdio.h and our stddef.h mismatch. */
#include <stdio.h>
#ifdef HAVE_ATEXIT
extern void atexit (void (*) (void));
#define ON_EXIT(FUNC,ARG) atexit ((FUNC))
#else
#ifdef sun
extern void on_exit (void*, void*);
#define ON_EXIT(FUNC,ARG) on_exit ((FUNC), (ARG))
#endif
#endif
static struct bb *bb_head = (struct bb *)0;
/* Return the number of digits needed to print a value */
/* __inline__ */ static int num_digits (long value, int base)
{
int minus = (value < 0 && base != 16);
unsigned long v = (minus) ? -value : value;
int ret = minus;
do
{
v /= base;
ret++;
}
while (v);
return ret;
}
void
__bb_exit_func (void)
{
FILE *file = fopen ("bb.out", "a");
long time_value;
if (!file)
perror ("bb.out");
else
{
struct bb *ptr;
/* This is somewhat type incorrect, but it avoids worrying about
exactly where time.h is included from. It should be ok unless
a void * differs from other pointer formats, or if sizeof(long)
is < sizeof (time_t). It would be nice if we could assume the
use of rationale standards here. */
time((void *) &time_value);
fprintf (file, "Basic block profiling finished on %s\n", ctime ((void *) &time_value));
/* We check the length field explicitly in order to allow compatibility
with older GCC's which did not provide it. */
for (ptr = bb_head; ptr != (struct bb *)0; ptr = ptr->next)
{
int i;
int func_p = (ptr->nwords >= sizeof (struct bb) && ptr->nwords <= 1000);
int line_p = (func_p && ptr->line_nums);
int file_p = (func_p && ptr->filenames);
long ncounts = ptr->ncounts;
long cnt_max = 0;
long line_max = 0;
long addr_max = 0;
int file_len = 0;
int func_len = 0;
int blk_len = num_digits (ncounts, 10);
int cnt_len;
int line_len;
int addr_len;
fprintf (file, "File %s, %ld basic blocks \n\n",
ptr->filename, ncounts);
/* Get max values for each field. */
for (i = 0; i < ncounts; i++)
{
const char *p;
int len;
if (cnt_max < ptr->counts[i])
cnt_max = ptr->counts[i];
if (addr_max < ptr->addresses[i])
addr_max = ptr->addresses[i];
if (line_p && line_max < ptr->line_nums[i])
line_max = ptr->line_nums[i];
if (func_p)
{
p = (ptr->functions[i]) ? (ptr->functions[i]) : "<none>";
len = strlen (p);
if (func_len < len)
func_len = len;
}
if (file_p)
{
p = (ptr->filenames[i]) ? (ptr->filenames[i]) : "<none>";
len = strlen (p);
if (file_len < len)
file_len = len;
}
}
addr_len = num_digits (addr_max, 16);
cnt_len = num_digits (cnt_max, 10);
line_len = num_digits (line_max, 10);
/* Now print out the basic block information. */
for (i = 0; i < ncounts; i++)
{
fprintf (file,
" Block #%*d: executed %*ld time(s) address= 0x%.*lx",
blk_len, i+1,
cnt_len, ptr->counts[i],
addr_len, ptr->addresses[i]);
if (func_p)
fprintf (file, " function= %-*s", func_len,
(ptr->functions[i]) ? ptr->functions[i] : "<none>");
if (line_p)
fprintf (file, " line= %*ld", line_len, ptr->line_nums[i]);
if (file_p)
fprintf (file, " file= %s",
(ptr->filenames[i]) ? ptr->filenames[i] : "<none>");
fprintf (file, "\n");
}
fprintf (file, "\n");
fflush (file);
}
fprintf (file, "\n\n");
fclose (file);
}
}
void
__bb_init_func (struct bb *blocks)
{
/* User is supposed to check whether the first word is non-0,
but just in case.... */
if (blocks->zero_word)
return;
#ifdef ON_EXIT
/* Initialize destructor. */
if (!bb_head)
ON_EXIT (__bb_exit_func, 0);
#endif
/* Set up linked list. */
blocks->zero_word = 1;
blocks->next = bb_head;
bb_head = blocks;
}
#endif /* not inhibit_libc */
#endif /* not BLOCK_PROFILER_CODE */
#endif /* L_bb */
/* Default free-store management functions for C++, per sections 12.5 and
17.3.3 of the Working Paper. */
#ifdef L_op_new
/* operator new (size_t), described in 17.3.3.5. This function is used by
C++ programs to allocate a block of memory to hold a single object. */
typedef void (*vfp)(void);
extern vfp __new_handler;
void *
__builtin_new (size_t sz)
{
void *p;
/* malloc (0) is unpredictable; avoid it. */
if (sz == 0)
sz = 1;
p = (void *) malloc (sz);
while (p == 0)
{
(*__new_handler) ();
p = (void *) malloc (sz);
}
return p;
}
#endif /* L_op_new */
#ifdef L_op_vnew
/* void * operator new [] (size_t), described in 17.3.3.6. This function
is used by C++ programs to allocate a block of memory for an array. */
extern void * __builtin_new (size_t);
void *
__builtin_vec_new (size_t sz)
{
return __builtin_new (sz);
}
#endif /* L_op_vnew */
#ifdef L_new_handler
/* set_new_handler (fvoid_t *) and the default new handler, described in
17.3.3.2 and 17.3.3.5. These functions define the result of a failure
to allocate the amount of memory requested from operator new or new []. */
#ifndef inhibit_libc
/* This gets us __GNU_LIBRARY__. */
#undef NULL /* Avoid errors if stdio.h and our stddef.h mismatch. */
#include <stdio.h>
#ifdef __GNU_LIBRARY__
/* Avoid forcing the library's meaning of `write' on the user program
by using the "internal" name (for use within the library) */
#define write(fd, buf, n) __write((fd), (buf), (n))
#endif
#endif /* inhibit_libc */
typedef void (*vfp)(void);
void __default_new_handler (void);
vfp __new_handler = __default_new_handler;
vfp
set_new_handler (vfp handler)
{
vfp prev_handler;
prev_handler = __new_handler;
if (handler == 0) handler = __default_new_handler;
__new_handler = handler;
return prev_handler;
}
#define MESSAGE "Virtual memory exceeded in `new'\n"
void
__default_new_handler ()
{
/* don't use fprintf (stderr, ...) because it may need to call malloc. */
/* This should really print the name of the program, but that is hard to
do. We need a standard, clean way to get at the name. */
write (2, MESSAGE, sizeof (MESSAGE));
/* don't call exit () because that may call global destructors which
may cause a loop. */
_exit (-1);
}
#endif
#ifdef L_op_delete
/* operator delete (void *), described in 17.3.3.3. This function is used
by C++ programs to return to the free store a block of memory allocated
as a single object. */
void
__builtin_delete (void *ptr)
{
if (ptr)
free (ptr);
}
#endif
#ifdef L_op_vdel
/* operator delete [] (void *), described in 17.3.3.4. This function is
used by C++ programs to return to the free store a block of memory
allocated as an array. */
extern void __builtin_delete (void *);
void
__builtin_vec_delete (void *ptr)
{
__builtin_delete (ptr);
}
#endif
/* End of C++ free-store management functions */
#ifdef L_shtab
unsigned int __shtab[] = {
0x00000001, 0x00000002, 0x00000004, 0x00000008,
0x00000010, 0x00000020, 0x00000040, 0x00000080,
0x00000100, 0x00000200, 0x00000400, 0x00000800,
0x00001000, 0x00002000, 0x00004000, 0x00008000,
0x00010000, 0x00020000, 0x00040000, 0x00080000,
0x00100000, 0x00200000, 0x00400000, 0x00800000,
0x01000000, 0x02000000, 0x04000000, 0x08000000,
0x10000000, 0x20000000, 0x40000000, 0x80000000
};
#endif
#ifdef L_clear_cache
/* Clear part of an instruction cache. */
#define INSN_CACHE_PLANE_SIZE (INSN_CACHE_SIZE / INSN_CACHE_DEPTH)
void
__clear_cache (beg, end)
char *beg, *end;
{
#ifdef CLEAR_INSN_CACHE
CLEAR_INSN_CACHE (beg, end);
#else
#ifdef INSN_CACHE_SIZE
static char array[INSN_CACHE_SIZE + INSN_CACHE_PLANE_SIZE + INSN_CACHE_LINE_WIDTH];
static int initialized = 0;
int offset;
void *start_addr
void *end_addr;
typedef (*function_ptr) ();
#if (INSN_CACHE_SIZE / INSN_CACHE_LINE_WIDTH) < 16
/* It's cheaper to clear the whole cache.
Put in a series of jump instructions so that calling the beginning
of the cache will clear the whole thing. */
if (! initialized)
{
int ptr = (((int) array + INSN_CACHE_LINE_WIDTH - 1)
& -INSN_CACHE_LINE_WIDTH);
int end_ptr = ptr + INSN_CACHE_SIZE;
while (ptr < end_ptr)
{
*(INSTRUCTION_TYPE *)ptr
= JUMP_AHEAD_INSTRUCTION + INSN_CACHE_LINE_WIDTH;
ptr += INSN_CACHE_LINE_WIDTH;
}
*(INSTRUCTION_TYPE *)(ptr - INSN_CACHE_LINE_WIDTH) = RETURN_INSTRUCTION;
initialized = 1;
}
/* Call the beginning of the sequence. */
(((function_ptr) (((int) array + INSN_CACHE_LINE_WIDTH - 1)
& -INSN_CACHE_LINE_WIDTH))
());
#else /* Cache is large. */
if (! initialized)
{
int ptr = (((int) array + INSN_CACHE_LINE_WIDTH - 1)
& -INSN_CACHE_LINE_WIDTH);
while (ptr < (int) array + sizeof array)
{
*(INSTRUCTION_TYPE *)ptr = RETURN_INSTRUCTION;
ptr += INSN_CACHE_LINE_WIDTH;
}
initialized = 1;
}
/* Find the location in array that occupies the same cache line as BEG. */
offset = ((int) beg & -INSN_CACHE_LINE_WIDTH) & (INSN_CACHE_PLANE_SIZE - 1);
start_addr = (((int) (array + INSN_CACHE_PLANE_SIZE - 1)
& -INSN_CACHE_PLANE_SIZE)
+ offset);
/* Compute the cache alignment of the place to stop clearing. */
#if 0 /* This is not needed for gcc's purposes. */
/* If the block to clear is bigger than a cache plane,
we clear the entire cache, and OFFSET is already correct. */
if (end < beg + INSN_CACHE_PLANE_SIZE)
#endif
offset = (((int) (end + INSN_CACHE_LINE_WIDTH - 1)
& -INSN_CACHE_LINE_WIDTH)
& (INSN_CACHE_PLANE_SIZE - 1));
#if INSN_CACHE_DEPTH > 1
end_addr = (start_addr & -INSN_CACHE_PLANE_SIZE) + offset;
if (end_addr <= start_addr)
end_addr += INSN_CACHE_PLANE_SIZE;
for (plane = 0; plane < INSN_CACHE_DEPTH; plane++)
{
int addr = start_addr + plane * INSN_CACHE_PLANE_SIZE;
int stop = end_addr + plane * INSN_CACHE_PLANE_SIZE;
while (addr != stop)
{
/* Call the return instruction at ADDR. */
((function_ptr) addr) ();
addr += INSN_CACHE_LINE_WIDTH;
}
}
#else /* just one plane */
do
{
/* Call the return instruction at START_ADDR. */
((function_ptr) start_addr) ();
start_addr += INSN_CACHE_LINE_WIDTH;
}
while ((start_addr % INSN_CACHE_SIZE) != offset);
#endif /* just one plane */
#endif /* Cache is large */
#endif /* Cache exists */
#endif /* CLEAR_INSN_CACHE */
}
#endif /* L_clear_cache */
#ifdef L_trampoline
/* Jump to a trampoline, loading the static chain address. */
#ifdef TRANSFER_FROM_TRAMPOLINE
TRANSFER_FROM_TRAMPOLINE
#endif
#if defined (NeXT) && defined (__MACH__)
/* Make stack executable so we can call trampolines on stack.
This is called from INITIALIZE_TRAMPOLINE in next.h. */
#ifdef NeXTStep21
#include <mach.h>
#else
#include <mach/mach.h>
#endif
void
__enable_execute_stack (addr)
char *addr;
{
kern_return_t r;
char *eaddr = addr + TRAMPOLINE_SIZE;
vm_address_t a = (vm_address_t) addr;
/* turn on execute access on stack */
r = vm_protect (task_self (), a, TRAMPOLINE_SIZE, FALSE, VM_PROT_ALL);
if (r != KERN_SUCCESS)
{
mach_error("vm_protect VM_PROT_ALL", r);
exit(1);
}
/* We inline the i-cache invalidation for speed */
#ifdef CLEAR_INSN_CACHE
CLEAR_INSN_CACHE (addr, eaddr);
#else
__clear_cache ((int) addr, (int) eaddr);
#endif
}
#endif /* defined (NeXT) && defined (__MACH__) */
#ifdef __convex__
/* Make stack executable so we can call trampolines on stack.
This is called from INITIALIZE_TRAMPOLINE in convex.h. */
#include <sys/mman.h>
#include <sys/vmparam.h>
#include <machine/machparam.h>
void
__enable_execute_stack ()
{
int fp;
static unsigned lowest = USRSTACK;
unsigned current = (unsigned) &fp & -NBPG;
if (lowest > current)
{
unsigned len = lowest - current;
mremap (current, &len, PROT_READ | PROT_WRITE | PROT_EXEC, MAP_PRIVATE);
lowest = current;
}
/* Clear instruction cache in case an old trampoline is in it. */
asm ("pich");
}
#endif /* __convex__ */
#ifdef __DOLPHIN__
/* Modified from the convex -code above. */
#include <sys/param.h>
#include <errno.h>
#include <sys/m88kbcs.h>
void
__enable_execute_stack ()
{
int save_errno;
static unsigned long lowest = USRSTACK;
unsigned long current = (unsigned long) &save_errno & -NBPC;
/* Ignore errno being set. memctl sets errno to EINVAL whenever the
address is seen as 'negative'. That is the case with the stack. */
save_errno=errno;
if (lowest > current)
{
unsigned len=lowest-current;
memctl(current,len,MCT_TEXT);
lowest = current;
}
else
memctl(current,NBPC,MCT_TEXT);
errno=save_errno;
}
#endif /* __DOLPHIN__ */
#ifdef __pyr__
#undef NULL /* Avoid errors if stdio.h and our stddef.h mismatch. */
#include <stdio.h>
#include <sys/mman.h>
#include <sys/types.h>
#include <sys/param.h>
#include <sys/vmmac.h>
/* Modified from the convex -code above.
mremap promises to clear the i-cache. */
void
__enable_execute_stack ()
{
int fp;
if (mprotect (((unsigned int)&fp/PAGSIZ)*PAGSIZ, PAGSIZ,
PROT_READ|PROT_WRITE|PROT_EXEC))
{
perror ("mprotect in __enable_execute_stack");
fflush (stderr);
abort ();
}
}
#endif /* __pyr__ */
#endif /* L_trampoline */
#ifdef L__main
#include "gbl-ctors.h"
/* Some systems use __main in a way incompatible with its use in gcc, in these
cases use the macros NAME__MAIN to give a quoted symbol and SYMBOL__MAIN to
give the same symbol without quotes for an alternative entry point. You
must define both, or niether. */
#ifndef NAME__MAIN
#define NAME__MAIN "__main"
#define SYMBOL__MAIN __main
#endif
/* Run all the global destructors on exit from the program. */
void
__do_global_dtors ()
{
#ifdef DO_GLOBAL_DTORS_BODY
DO_GLOBAL_DTORS_BODY;
#else
unsigned nptrs = (unsigned HOST_WIDE_INT) __DTOR_LIST__[0];
unsigned i;
/* Some systems place the number of pointers
in the first word of the table.
On other systems, that word is -1.
In all cases, the table is null-terminated. */
/* If the length is not recorded, count up to the null. */
if (nptrs == -1)
for (nptrs = 0; __DTOR_LIST__[nptrs + 1] != 0; nptrs++);
/* GNU LD format. */
for (i = nptrs; i >= 1; i--)
__DTOR_LIST__[i] ();
#endif
}
#ifndef INIT_SECTION_ASM_OP
/* Run all the global constructors on entry to the program. */
#ifndef ON_EXIT
#define ON_EXIT(a, b)
#else
/* Make sure the exit routine is pulled in to define the globals as
bss symbols, just in case the linker does not automatically pull
bss definitions from the library. */
extern int _exit_dummy_decl;
int *_exit_dummy_ref = &_exit_dummy_decl;
#endif /* ON_EXIT */
void
__do_global_ctors ()
{
DO_GLOBAL_CTORS_BODY;
ON_EXIT (__do_global_dtors, 0);
}
#endif /* no INIT_SECTION_ASM_OP */
#if !defined (INIT_SECTION_ASM_OP) || defined (INVOKE__main)
/* Subroutine called automatically by `main'.
Compiling a global function named `main'
produces an automatic call to this function at the beginning.
For many systems, this routine calls __do_global_ctors.
For systems which support a .init section we use the .init section
to run __do_global_ctors, so we need not do anything here. */
void
SYMBOL__MAIN ()
{
/* Support recursive calls to `main': run initializers just once. */
static int initialized = 0;
if (! initialized)
{
initialized = 1;
__do_global_ctors ();
}
}
#endif /* no INIT_SECTION_ASM_OP or INVOKE__main */
#endif /* L__main */
#ifdef L_ctors
#include "gbl-ctors.h"
/* Provide default definitions for the lists of constructors and
destructors, so that we don't get linker errors. These symbols are
intentionally bss symbols, so that gld and/or collect will provide
the right values. */
/* We declare the lists here with two elements each,
so that they are valid empty lists if no other definition is loaded. */
#if !defined(INIT_SECTION_ASM_OP) && !defined(CTOR_LISTS_DEFINED_EXTERNALLY)
#ifdef __NeXT__
/* After 2.3, try this definition on all systems. */
func_ptr __CTOR_LIST__[2] = {0, 0};
func_ptr __DTOR_LIST__[2] = {0, 0};
#else
func_ptr __CTOR_LIST__[2];
func_ptr __DTOR_LIST__[2];
#endif
#endif /* no INIT_SECTION_ASM_OP and not CTOR_LISTS_DEFINED_EXTERNALLY */
#endif /* L_ctors */
#ifdef L_exit
#include "gbl-ctors.h"
#ifndef ON_EXIT
/* If we have no known way of registering our own __do_global_dtors
routine so that it will be invoked at program exit time, then we
have to define our own exit routine which will get this to happen. */
extern void __do_global_dtors ();
extern void _cleanup ();
extern void _exit () __attribute__ ((noreturn));
void
exit (status)
int status;
{
__do_global_dtors ();
#ifdef EXIT_BODY
EXIT_BODY;
#else
_cleanup ();
#endif
_exit (status);
}
#else
int _exit_dummy_decl = 0; /* prevent compiler & linker warnings */
#endif
#endif /* L_exit */
/* In a.out systems, we need to have these dummy constructor and destructor
lists in the library.
When using `collect', the first link will resolve __CTOR_LIST__
and __DTOR_LIST__ to these symbols. We will then run "nm" on the
result, build the correct __CTOR_LIST__ and __DTOR_LIST__, and relink.
Since we don't do the second link if no constructors existed, these
dummies must be fully functional empty lists.
When using `gnu ld', these symbols will be used if there are no
constructors. If there are constructors, the N_SETV symbol defined
by the linker from the N_SETT's in input files will define __CTOR_LIST__
and __DTOR_LIST__ rather than its being allocated as common storage
by the definitions below.
When using a linker that supports constructor and destructor segments,
these definitions will not be used, since crtbegin.o and crtend.o
(from crtstuff.c) will have already defined __CTOR_LIST__ and
__DTOR_LIST__. The crt*.o files are passed directly to the linker
on its command line, by gcc. */
/* The list needs two elements: one is ignored (the old count); the
second is the terminating zero. Since both values are zero, this
declaration is not initialized, and it becomes `common'. */
#ifdef L_ctor_list
#include "gbl-ctors.h"
func_ptr __CTOR_LIST__[2];
#endif
#ifdef L_dtor_list
#include "gbl-ctors.h"
func_ptr __DTOR_LIST__[2];
#endif
