k5-platform.h revision ab9b2e153c3a9a2b1141fefa87925b1a9beb1236
/*
* Copyright 2005 Sun Microsystems, Inc. All rights reserved.
* Use is subject to license terms.
*/
#pragma ident "%Z%%M% %I% %E% SMI"
/*
* k5-platform.h
*
* Copyright 2003, 2004 Massachusetts Institute of Technology.
* All Rights Reserved.
*
* Export of this software from the United States of America may
* require a specific license from the United States Government.
* It is the responsibility of any person or organization contemplating
* export to obtain such a license before exporting.
*
* WITHIN THAT CONSTRAINT, permission to use, copy, modify, and
* distribute this software and its documentation for any purpose and
* without fee is hereby granted, provided that the above copyright
* notice appear in all copies and that both that copyright notice and
* this permission notice appear in supporting documentation, and that
* the name of M.I.T. not be used in advertising or publicity pertaining
* to distribution of the software without specific, written prior
* permission. Furthermore if you modify this software you must label
* your software as modified software and not distribute it in such a
* fashion that it might be confused with the original M.I.T. software.
* M.I.T. makes no representations about the suitability of
* this software for any purpose. It is provided "as is" without express
* or implied warranty.
*
*
* Some platform-dependent definitions to sync up the C support level.
* Some to a C99-ish level, some related utility code.
*
* Currently:
* + make "static inline" work
* + 64-bit types and load/store code
* + SIZE_MAX
* + shared library init/fini hooks
*/
#ifndef K5_PLATFORM_H
#define K5_PLATFORM_H
#ifndef _KERNEL
#include "autoconf.h"
/* Initialization and finalization function support for libraries.
At top level, before the functions are defined or even declared:
MAKE_INIT_FUNCTION(init_fn);
MAKE_FINI_FUNCTION(fini_fn);
int init_fn(void) { ... }
void fini_fn(void) { if (INITIALIZER_RAN(init_fn)) ... }
In code, in the same file:
err = CALL_INIT_FUNCTION(init_fn);
To trigger or verify the initializer invocation from another file,
an additional function must be created.
The init_fn and fini_fn names should be chosen such that any
exported names staring with those names, and optionally followed by
additional characters, fits in with any namespace constraints on
the library in question.
Implementation outline:
Windows: MAKE_FINI_FUNCTION creates a symbol with a magic name that
is sought at library build time, and code is added to invoke the
function when the library is unloaded. MAKE_INIT_FUNCTION does
likewise, but the function is invoked when the library is loaded,
and an extra variable is declared to hold an error code and a "yes
the initializer ran" flag. CALL_INIT_FUNCTION blows up if the flag
isn't set, otherwise returns the error code.
UNIX: MAKE_INIT_FUNCTION creates and initializes a variable with a
name derived from the function name, containing a k5_once_t
(pthread_once_t or int), an error code, and a pointer to the
function. The function itself is declared static, but the
associated variable has external linkage. CALL_INIT_FUNCTION
ensures thath the function is called exactly once (pthread_once or
just check the flag) and returns the stored error code (or the
pthread_once error).
UNIX, with compiler support: MAKE_FINI_FUNCTION declares the
function as a destructor, and the run time linker support or
whatever will cause it to be invoked when the library is unloaded,
the program ends, etc.
UNIX, with linker support: MAKE_FINI_FUNCTION creates a symbol with
a magic name that is sought at library build time, and linker
options are used to mark it as a finalization function for the
library. The symbol must be exported.
UNIX, no library finalization support: The finalization function
never runs, and we leak memory. Tough.
For maximum flexibility in defining the macros, the function name
parameter should be a simple name, not even a macro defined as
another name. The function should have a unique name, and should
conform to whatever namespace is used by the library in question.
If the macro expansion needs the function to have been declared, it
must include a declaration. If it is not necessary for the symbol
name to be exported from the object file, the macro should declare
it as "static". Hence the signature must exactly match "void
foo(void)". (ANSI C allows a static declaration followed by a
non-static one; the result is internal linkage.) The macro
expansion has to come before the function, because gcc apparently
won't act on "__attribute__((constructor))" if it comes after the
function definition.
This is going to be compiler- and environment-specific, and may
require some support at library build time, and/or "asm"
statements.
It's okay for this code to require that the library be built
with the same compiler and compiler options throughout, but
we shouldn't require that the library and application use the
same compiler.
For static libraries, we don't really care about cleanup too much,
since it's all memory handling and mutex allocation which will all
be cleaned up when the program exits. Thus, it's okay if gcc-built
static libraries don't play nicely with cc-built executables when
it comes to static constructors, just as long as it doesn't cause
linking to fail.
For dynamic libraries on UNIX, we'll use pthread_once-type support
to do delayed initialization, so if finalization can't be made to
work, we'll only have memory leaks in a load/use/unload cycle. If
anyone (like, say, the OS vendor) complains about this, they can
tell us how to get a shared library finalization function invoked
automatically. */
/* Helper macros. */
# define JOIN__2_2(A,B) A ## _ ## _ ## B
# define JOIN__2(A,B) JOIN__2_2(A,B)
/* XXX Should test USE_LINKER_INIT_OPTION early, and if it's set,
always provide a function by the expected name, even if we're
delaying initialization. */
#if defined(DELAY_INITIALIZER)
/* Run the initialization code during program execution, at the latest
possible moment. This means multiple threads may be active. */
# include "k5-thread.h"
typedef struct { k5_once_t once; int error, did_run; void (*fn)(void); } k5_init_t;
# ifdef USE_LINKER_INIT_OPTION
# define MAYBE_DUMMY_INIT(NAME) \
void JOIN__2(NAME, auxinit) () { }
# else
# define MAYBE_DUMMY_INIT(NAME)
# endif
# define MAKE_INIT_FUNCTION(NAME) \
static int NAME(void); \
MAYBE_DUMMY_INIT(NAME) \
/* forward declaration for use in initializer */ \
static void JOIN__2(NAME, aux) (void); \
static k5_init_t JOIN__2(NAME, once) = \
{ K5_ONCE_INIT, 0, 0, JOIN__2(NAME, aux) }; \
static void JOIN__2(NAME, aux) (void) \
{ \
JOIN__2(NAME, once).did_run = 1; \
JOIN__2(NAME, once).error = NAME(); \
} \
/* so ';' following macro use won't get error */ \
static int NAME(void)
# define CALL_INIT_FUNCTION(NAME) \
k5_call_init_function(& JOIN__2(NAME, once))
# ifdef __GNUC__
/* Do it in macro form so we get the file/line of the invocation if
the assertion fails. */
# define k5_call_init_function(I) \
(__extension__ ({ \
k5_init_t *k5int_i = (I); \
int k5int_err = k5_once(&k5int_i->once, k5int_i->fn); \
(k5int_err \
? k5int_err \
: (assert(k5int_i->did_run != 0), k5int_i->error)); \
}))
# else /* __GNUC__ */
static int k5_call_init_function(k5_init_t *i)
{
int err;
err = k5_once(&i->once, i->fn);
if (err)
return err;
assert (i->did_run != 0);
return i->error;
}
# endif /* __GNUC__ */
/* This should be called in finalization only, so we shouldn't have
multiple active threads mucking around in our library at this
point. So ignore the once_t object and just look at the flag.
XXX Could we have problems with memory coherence between
processors if we don't invoke mutex/once routines? */
# define INITIALIZER_RAN(NAME) \
(JOIN__2(NAME, once).did_run && JOIN__2(NAME, once).error == 0)
# define PROGRAM_EXITING() (0)
#elif defined(__GNUC__) && !defined(_WIN32) && defined(CONSTRUCTOR_ATTR_WORKS)
/* Run initializer at load time, via GCC/C++ hook magic. */
# ifdef USE_LINKER_INIT_OPTION
# define MAYBE_DUMMY_INIT(NAME) \
void JOIN__2(NAME, auxinit) () { }
# else
# define MAYBE_DUMMY_INIT(NAME)
# endif
typedef struct { int error; unsigned char did_run; } k5_init_t;
# define MAKE_INIT_FUNCTION(NAME) \
MAYBE_DUMMY_INIT(NAME) \
static k5_init_t JOIN__2(NAME, ran) \
= { 0, 2 }; \
static void JOIN__2(NAME, aux)(void) \
__attribute__((constructor)); \
static int NAME(void); \
static void JOIN__2(NAME, aux)(void) \
{ \
JOIN__2(NAME, ran).error = NAME(); \
JOIN__2(NAME, ran).did_run = 3; \
} \
static int NAME(void)
# define CALL_INIT_FUNCTION(NAME) \
(JOIN__2(NAME, ran).did_run == 3 \
? JOIN__2(NAME, ran).error \
: (abort(),0))
# define INITIALIZER_RAN(NAME) (JOIN__2(NAME,ran).did_run == 3 && JOIN__2(NAME, ran).error == 0)
#elif defined(USE_LINKER_INIT_OPTION) || defined(_WIN32)
/* Run initializer at load time, via linker magic, or in the
case of WIN32, win_glue.c hard-coded knowledge. */
typedef struct { int error; unsigned char did_run; } k5_init_t;
# define MAKE_INIT_FUNCTION(NAME) \
static k5_init_t JOIN__2(NAME, ran) \
= { 0, 2 }; \
static int NAME(void); \
void JOIN__2(NAME, auxinit)() \
{ \
JOIN__2(NAME, ran).error = NAME(); \
JOIN__2(NAME, ran).did_run = 3; \
} \
static int NAME(void)
# define CALL_INIT_FUNCTION(NAME) \
(JOIN__2(NAME, ran).did_run == 3 \
? JOIN__2(NAME, ran).error \
: (abort(),0))
# define INITIALIZER_RAN(NAME) \
(JOIN__2(NAME, ran).error == 0)
# define PROGRAM_EXITING() (0)
#else
# error "Don't know how to do load-time initializers for this configuration."
# define PROGRAM_EXITING() (0)
#endif
#if defined(USE_LINKER_FINI_OPTION) || defined(_WIN32)
/* If we're told the linker option will be used, it doesn't really
matter what compiler we're using. Do it the same way
regardless. */
# define MAKE_FINI_FUNCTION(NAME) \
void NAME(void)
#elif defined(__GNUC__) && defined(DESTRUCTOR_ATTR_WORKS)
/* If we're using gcc, if the C++ support works, the compiler should
build executables and shared libraries that support the use of
static constructors and destructors. The C compiler supports a
function attribute that makes use of the same facility as C++.
XXX How do we know if the C++ support actually works? */
# define MAKE_FINI_FUNCTION(NAME) \
static void NAME(void) __attribute__((destructor))
#elif !defined(SHARED)
/* In this case, we just don't care about finalization.
The code will still define the function, but we won't do anything
with it. Annoying: This may generate unused-function warnings. */
# define MAKE_FINI_FUNCTION(NAME) \
static void NAME(void)
#else /* DELAY_INITIALIZER */
# error "Don't know how to do unload-time finalization for this configuration."
#endif /* DELAY_INITIALIZER */
#endif /* !_KERNEL */
/* 64-bit support: krb5_ui_8 and krb5_int64.
This should move to krb5.h eventually, but without the namespace
pollution from the autoconf macros. */
#if defined(HAVE_STDINT_H) || defined(HAVE_INTTYPES_H)
# ifdef HAVE_STDINT_H
# include <stdint.h>
# endif
# ifdef HAVE_INTTYPES_H
# include <inttypes.h>
# endif
# define INT64_TYPE int64_t
# define UINT64_TYPE uint64_t
#elif defined(_WIN32)
# define INT64_TYPE signed __int64
# define UINT64_TYPE unsigned __int64
#else /* not Windows, and neither stdint.h nor inttypes.h */
# define INT64_TYPE signed long long
# define UINT64_TYPE unsigned long long
#endif
#ifndef _KERNEL
#include <limits.h>
#endif /* !_KERNEL */
#ifndef SIZE_MAX
# define SIZE_MAX ((size_t)((size_t)0 - 1))
#endif
/* Read and write integer values as (unaligned) octet strings in
specific byte orders.
Add per-platform optimizations later if needed. (E.g., maybe x86
unaligned word stores and gcc/asm instructions for byte swaps,
etc.) */
static void
store_16_be (unsigned int val, unsigned char *p)
{
p[0] = (val >> 8) & 0xff;
p[1] = (val ) & 0xff;
}
static void
store_16_le (unsigned int val, unsigned char *p)
{
p[1] = (val >> 8) & 0xff;
p[0] = (val ) & 0xff;
}
static void
store_32_be (unsigned int val, unsigned char *p)
{
p[0] = (val >> 24) & 0xff;
p[1] = (val >> 16) & 0xff;
p[2] = (val >> 8) & 0xff;
p[3] = (val ) & 0xff;
}
static void
store_32_le (unsigned int val, unsigned char *p)
{
p[3] = (val >> 24) & 0xff;
p[2] = (val >> 16) & 0xff;
p[1] = (val >> 8) & 0xff;
p[0] = (val ) & 0xff;
}
static void
store_64_be (UINT64_TYPE val, unsigned char *p)
{
p[0] = (unsigned char)((val >> 56) & 0xff);
p[1] = (unsigned char)((val >> 48) & 0xff);
p[2] = (unsigned char)((val >> 40) & 0xff);
p[3] = (unsigned char)((val >> 32) & 0xff);
p[4] = (unsigned char)((val >> 24) & 0xff);
p[5] = (unsigned char)((val >> 16) & 0xff);
p[6] = (unsigned char)((val >> 8) & 0xff);
p[7] = (unsigned char)((val ) & 0xff);
}
static void
store_64_le (UINT64_TYPE val, unsigned char *p)
{
p[7] = (unsigned char)((val >> 56) & 0xff);
p[6] = (unsigned char)((val >> 48) & 0xff);
p[5] = (unsigned char)((val >> 40) & 0xff);
p[4] = (unsigned char)((val >> 32) & 0xff);
p[3] = (unsigned char)((val >> 24) & 0xff);
p[2] = (unsigned char)((val >> 16) & 0xff);
p[1] = (unsigned char)((val >> 8) & 0xff);
p[0] = (unsigned char)((val ) & 0xff);
}
static unsigned short
load_16_be (unsigned char *p)
{
return (p[1] | (p[0] << 8));
}
static unsigned short
load_16_le (unsigned char *p)
{
return (p[0] | (p[1] << 8));
}
static unsigned int
load_32_be (unsigned char *p)
{
return (p[3] | (p[2] << 8) | (p[1] << 16) | (p[0] << 24));
}
static unsigned int
load_32_le (unsigned char *p)
{
return (p[0] | (p[1] << 8) | (p[2] << 16) | (p[3] << 24));
}
static UINT64_TYPE
load_64_be (unsigned char *p)
{
return ((UINT64_TYPE)load_32_be(p) << 32) | load_32_be(p+4);
}
static UINT64_TYPE
load_64_le (unsigned char *p)
{
return ((UINT64_TYPE)load_32_le(p+4) << 32) | load_32_le(p);
}
/* Make the interfaces to getpwnam and getpwuid consistent.
Model the wrappers on the POSIX thread-safe versions, but
use the unsafe system versions if the safe ones don't exist
or we can't figure out their interfaces. */
/* SUNW15resync - just have Solaris relevant ones */
#define k5_getpwnam_r(NAME, REC, BUF, BUFSIZE, OUT) \
(*(OUT) = getpwnam_r(NAME,REC,BUF,BUFSIZE), *(OUT) == NULL ? -1 : 0)
#define k5_getpwuid_r(UID, REC, BUF, BUFSIZE, OUT) \
(*(OUT) = getpwuid_r(UID,REC,BUF,BUFSIZE), *(OUT) == NULL ? -1 : 0)
#endif /* K5_PLATFORM_H */