/* do not edit automatically generated by mc from varargs. */
/* varargs.mod provides a basic vararg facility for GNU Modula-2.
Copyright (C) 2015-2023 Free Software Foundation, Inc.
Contributed by Gaius Mulley <gaius@glam.ac.uk>.
This file is part of GNU Modula-2.
GNU Modula-2 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 3, or (at your option)
any later version.
GNU Modula-2 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 Modula-2; see the file COPYING3. If not see
<http://www.gnu.org/licenses/>. */
#include "config.h"
#include "system.h"
#include <stdbool.h>
# if !defined (PROC_D)
# define PROC_D
typedef void (*PROC_t) (void);
typedef struct { PROC_t proc; } PROC;
# endif
# include "GStorage.h"
#if defined(__cplusplus)
# undef NULL
# define NULL 0
#endif
#define _varargs_H
#define _varargs_C
# include "GStorage.h"
# include "Glibc.h"
# include "GSYSTEM.h"
# include "GM2RTS.h"
# define MaxArg 4
typedef struct varargs_argDesc_r varargs_argDesc;
typedef struct varargs__T6_r varargs__T6;
typedef unsigned char *varargs_ptrToByte;
typedef struct varargs__T7_a varargs__T7;
typedef varargs__T6 *varargs_vararg;
struct varargs_argDesc_r {
void *ptr;
unsigned int len;
};
struct varargs__T7_a { varargs_argDesc array[MaxArg+1]; };
struct varargs__T6_r {
unsigned int nArgs;
unsigned int i;
void *contents;
unsigned int size;
varargs__T7 arg;
};
/*
nargs - returns the number of arguments wrapped in, v.
*/
extern "C" unsigned int varargs_nargs (varargs_vararg v);
/*
arg - fills in, a, with the next argument. The size of, a, must be an exact
match with the original vararg parameter.
*/
extern "C" void varargs_arg (varargs_vararg v, unsigned char *a, unsigned int _a_high);
/*
next - assigns the next arg to be collected as, i.
*/
extern "C" void varargs_next (varargs_vararg v, unsigned int i);
/*
copy - returns a copy of, v.
*/
extern "C" varargs_vararg varargs_copy (varargs_vararg v);
/*
replace - fills the next argument with, a. The size of, a,
must be an exact match with the original vararg
parameter.
*/
extern "C" void varargs_replace (varargs_vararg v, unsigned char *a, unsigned int _a_high);
/*
end - destructor for vararg, v.
*/
extern "C" void varargs_end (varargs_vararg *v);
/*
start1 - wraps up argument, a, into a vararg.
*/
extern "C" varargs_vararg varargs_start1 (const unsigned char *a_, unsigned int _a_high);
/*
start2 - wraps up arguments, a, b, into a vararg.
*/
extern "C" varargs_vararg varargs_start2 (const unsigned char *a_, unsigned int _a_high, const unsigned char *b_, unsigned int _b_high);
/*
start3 - wraps up arguments, a, b, c, into a vararg.
*/
extern "C" varargs_vararg varargs_start3 (const unsigned char *a_, unsigned int _a_high, const unsigned char *b_, unsigned int _b_high, const unsigned char *c_, unsigned int _c_high);
/*
start4 - wraps up arguments, a, b, c, d, into a vararg.
*/
extern "C" varargs_vararg varargs_start4 (const unsigned char *a_, unsigned int _a_high, const unsigned char *b_, unsigned int _b_high, const unsigned char *c_, unsigned int _c_high, const unsigned char *d_, unsigned int _d_high);
/*
nargs - returns the number of arguments wrapped in, v.
*/
extern "C" unsigned int varargs_nargs (varargs_vararg v)
{
return v->nArgs;
/* static analysis guarentees a RETURN statement will be used before here. */
__builtin_unreachable ();
}
/*
arg - fills in, a, with the next argument. The size of, a, must be an exact
match with the original vararg parameter.
*/
extern "C" void varargs_arg (varargs_vararg v, unsigned char *a, unsigned int _a_high)
{
typedef unsigned char *arg__T1;
arg__T1 p;
unsigned int j;
if (v->i == v->nArgs)
{
M2RTS_HALT (-1); /* too many calls to arg. */
__builtin_unreachable ();
}
else
{
if ((_a_high+1) == v->arg.array[v->i].len)
{
p = static_cast<arg__T1> (v->arg.array[v->i].ptr);
j = 0;
while (j <= _a_high)
{
a[j] = (*p);
p += 1;
j += 1;
}
}
else
{
M2RTS_HALT (-1); /* parameter mismatch. */
__builtin_unreachable ();
}
v->i += 1;
}
}
/*
next - assigns the next arg to be collected as, i.
*/
extern "C" void varargs_next (varargs_vararg v, unsigned int i)
{
v->i = i;
}
/*
copy - returns a copy of, v.
*/
extern "C" varargs_vararg varargs_copy (varargs_vararg v)
{
varargs_vararg c;
unsigned int j;
unsigned int offset;
Storage_ALLOCATE ((void **) &c, sizeof (varargs__T6));
c->i = v->i;
c->nArgs = v->nArgs;
c->size = v->size;
Storage_ALLOCATE (&c->contents, c->size);
c->contents = libc_memcpy (c->contents, v->contents, static_cast<size_t> (c->size));
for (j=0; j<=c->nArgs; j++)
{
offset = (unsigned int ) (((varargs_ptrToByte) (v->contents))-((varargs_ptrToByte) (v->arg.array[j].ptr)));
c->arg.array[j].ptr = reinterpret_cast<void *> ((varargs_ptrToByte) (((varargs_ptrToByte) (c->contents))+offset));
c->arg.array[j].len = v->arg.array[j].len;
}
return c;
/* static analysis guarentees a RETURN statement will be used before here. */
__builtin_unreachable ();
}
/*
replace - fills the next argument with, a. The size of, a,
must be an exact match with the original vararg
parameter.
*/
extern "C" void varargs_replace (varargs_vararg v, unsigned char *a, unsigned int _a_high)
{
typedef unsigned char *replace__T2;
replace__T2 p;
unsigned int j;
if (v->i == v->nArgs)
{
M2RTS_HALT (-1); /* too many calls to arg. */
__builtin_unreachable ();
}
else
{
if ((_a_high+1) == v->arg.array[v->i].len)
{
p = static_cast<replace__T2> (v->arg.array[v->i].ptr);
j = 0;
while (j <= _a_high)
{
(*p) = a[j];
p += 1;
j += 1;
}
}
else
{
M2RTS_HALT (-1); /* parameter mismatch. */
__builtin_unreachable ();
}
}
}
/*
end - destructor for vararg, v.
*/
extern "C" void varargs_end (varargs_vararg *v)
{
if ((*v) != NULL)
{
Storage_DEALLOCATE (&(*v)->contents, sizeof (varargs_vararg));
Storage_DEALLOCATE ((void **) &(*v), sizeof (varargs__T6));
}
}
/*
start1 - wraps up argument, a, into a vararg.
*/
extern "C" varargs_vararg varargs_start1 (const unsigned char *a_, unsigned int _a_high)
{
varargs_vararg v;
unsigned char a[_a_high+1];
/* make a local copy of each unbounded array. */
memcpy (a, a_, _a_high+1);
Storage_ALLOCATE ((void **) &v, sizeof (varargs__T6));
v->i = 0;
v->nArgs = 1;
v->size = _a_high+1;
Storage_ALLOCATE (&v->contents, v->size);
v->contents = libc_memcpy (v->contents, &a, static_cast<size_t> (v->size));
v->arg.array[0].ptr = v->contents;
v->arg.array[0].len = v->size;
return v;
/* static analysis guarentees a RETURN statement will be used before here. */
__builtin_unreachable ();
}
/*
start2 - wraps up arguments, a, b, into a vararg.
*/
extern "C" varargs_vararg varargs_start2 (const unsigned char *a_, unsigned int _a_high, const unsigned char *b_, unsigned int _b_high)
{
typedef unsigned char *start2__T3;
varargs_vararg v;
start2__T3 p;
unsigned char a[_a_high+1];
unsigned char b[_b_high+1];
/* make a local copy of each unbounded array. */
memcpy (a, a_, _a_high+1);
memcpy (b, b_, _b_high+1);
Storage_ALLOCATE ((void **) &v, sizeof (varargs__T6));
v->i = 0;
v->nArgs = 2;
v->size = (_a_high+_b_high)+2;
Storage_ALLOCATE (&v->contents, v->size);
p = static_cast<start2__T3> (libc_memcpy (v->contents, &a, static_cast<size_t> (_a_high+1)));
v->arg.array[0].ptr = reinterpret_cast<void *> (p);
v->arg.array[0].len = _a_high+1;
p += v->arg.array[0].len;
p = static_cast<start2__T3> (libc_memcpy (reinterpret_cast<void *> (p), &b, static_cast<size_t> (_b_high+1)));
v->arg.array[1].ptr = reinterpret_cast<void *> (p);
v->arg.array[1].len = _b_high+1;
return v;
/* static analysis guarentees a RETURN statement will be used before here. */
__builtin_unreachable ();
}
/*
start3 - wraps up arguments, a, b, c, into a vararg.
*/
extern "C" varargs_vararg varargs_start3 (const unsigned char *a_, unsigned int _a_high, const unsigned char *b_, unsigned int _b_high, const unsigned char *c_, unsigned int _c_high)
{
typedef unsigned char *start3__T4;
varargs_vararg v;
start3__T4 p;
unsigned char a[_a_high+1];
unsigned char b[_b_high+1];
unsigned char c[_c_high+1];
/* make a local copy of each unbounded array. */
memcpy (a, a_, _a_high+1);
memcpy (b, b_, _b_high+1);
memcpy (c, c_, _c_high+1);
Storage_ALLOCATE ((void **) &v, sizeof (varargs__T6));
v->i = 0;
v->nArgs = 3;
v->size = ((_a_high+_b_high)+_c_high)+3;
Storage_ALLOCATE (&v->contents, v->size);
p = static_cast<start3__T4> (libc_memcpy (v->contents, &a, static_cast<size_t> (_a_high+1)));
v->arg.array[0].ptr = reinterpret_cast<void *> (p);
v->arg.array[0].len = _a_high+1;
p += v->arg.array[0].len;
p = static_cast<start3__T4> (libc_memcpy (reinterpret_cast<void *> (p), &b, static_cast<size_t> (_b_high+1)));
v->arg.array[1].ptr = reinterpret_cast<void *> (p);
v->arg.array[1].len = _b_high+1;
p += v->arg.array[1].len;
p = static_cast<start3__T4> (libc_memcpy (reinterpret_cast<void *> (p), &c, static_cast<size_t> (_c_high+1)));
v->arg.array[2].ptr = reinterpret_cast<void *> (p);
v->arg.array[2].len = _c_high+1;
return v;
/* static analysis guarentees a RETURN statement will be used before here. */
__builtin_unreachable ();
}
/*
start4 - wraps up arguments, a, b, c, d, into a vararg.
*/
extern "C" varargs_vararg varargs_start4 (const unsigned char *a_, unsigned int _a_high, const unsigned char *b_, unsigned int _b_high, const unsigned char *c_, unsigned int _c_high, const unsigned char *d_, unsigned int _d_high)
{
typedef unsigned char *start4__T5;
varargs_vararg v;
start4__T5 p;
unsigned char a[_a_high+1];
unsigned char b[_b_high+1];
unsigned char c[_c_high+1];
unsigned char d[_d_high+1];
/* make a local copy of each unbounded array. */
memcpy (a, a_, _a_high+1);
memcpy (b, b_, _b_high+1);
memcpy (c, c_, _c_high+1);
memcpy (d, d_, _d_high+1);
Storage_ALLOCATE ((void **) &v, sizeof (varargs__T6));
v->i = 0;
v->nArgs = 4;
v->size = (((_a_high+_b_high)+_c_high)+_d_high)+4;
Storage_ALLOCATE (&v->contents, v->size);
p = static_cast<start4__T5> (libc_memcpy (v->contents, &a, static_cast<size_t> (_a_high+1)));
v->arg.array[0].len = _a_high+1;
p += v->arg.array[0].len;
p = static_cast<start4__T5> (libc_memcpy (reinterpret_cast<void *> (p), &b, static_cast<size_t> (_b_high+1)));
v->arg.array[1].ptr = reinterpret_cast<void *> (p);
v->arg.array[1].len = _b_high+1;
p += v->arg.array[1].len;
p = static_cast<start4__T5> (libc_memcpy (reinterpret_cast<void *> (p), &c, static_cast<size_t> (_c_high+1)));
v->arg.array[2].ptr = reinterpret_cast<void *> (p);
v->arg.array[2].len = _c_high+1;
p += v->arg.array[2].len;
p = static_cast<start4__T5> (libc_memcpy (reinterpret_cast<void *> (p), &c, static_cast<size_t> (_c_high+1)));
v->arg.array[3].ptr = reinterpret_cast<void *> (p);
v->arg.array[3].len = _c_high+1;
return v;
/* static analysis guarentees a RETURN statement will be used before here. */
__builtin_unreachable ();
}
extern "C" void _M2_varargs_init (__attribute__((unused)) int argc,__attribute__((unused)) char *argv[],__attribute__((unused)) char *envp[])
{
}
extern "C" void _M2_varargs_fini (__attribute__((unused)) int argc,__attribute__((unused)) char *argv[],__attribute__((unused)) char *envp[])
{
}