/* secmem.c - memory allocation from a secure heap
* Copyright (C) 1998, 1999, 2000, 2001, 2002,
* 2003, 2007 Free Software Foundation, Inc.
*
* This file is part of Libgcrypt.
*
* Libgcrypt is free software; you can redistribute it and/or modify
* it under the terms of the GNU Lesser general Public License as
* published by the Free Software Foundation; either version 2.1 of
* the License, or (at your option) any later version.
*
* Libgcrypt 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 Lesser General Public License for more details.
*
* You should have received a copy of the GNU Lesser General Public
* License along with this program; if not, see .
*/
#include
#include
#include
#include
#include
#include
#include
#include
#if defined(HAVE_MLOCK) || defined(HAVE_MMAP)
#include
#include
#include
#ifdef USE_CAPABILITIES
#include
#endif
#endif
#include "ath.h"
#include "g10lib.h"
#include "secmem.h"
#if defined (MAP_ANON) && ! defined (MAP_ANONYMOUS)
#define MAP_ANONYMOUS MAP_ANON
#endif
#define MINIMUM_POOL_SIZE 16384
#define STANDARD_POOL_SIZE 32768
#define DEFAULT_PAGE_SIZE 4096
typedef struct memblock
{
unsigned size; /* Size of the memory available to the
user. */
int flags; /* See below. */
PROPERLY_ALIGNED_TYPE aligned;
} memblock_t;
/* This flag specifies that the memory block is in use. */
#define MB_FLAG_ACTIVE (1 << 0)
/* The pool of secure memory. */
static void *pool;
/* Size of POOL in bytes. */
static size_t pool_size;
/* True, if the memory pool is ready for use. May be checked in an
atexit function. */
static volatile int pool_okay;
/* True, if the memory pool is mmapped. */
static volatile int pool_is_mmapped;
/* FIXME? */
static int disable_secmem;
static int show_warning;
static int not_locked;
static int no_warning;
static int suspend_warning;
/* Stats. */
static unsigned int cur_alloced, cur_blocks;
/* Lock protecting accesses to the memory pool. */
static ath_mutex_t secmem_lock;
/* Convenient macros. */
#define SECMEM_LOCK ath_mutex_lock (&secmem_lock)
#define SECMEM_UNLOCK ath_mutex_unlock (&secmem_lock)
/* The size of the memblock structure; this does not include the
memory that is available to the user. */
#define BLOCK_HEAD_SIZE \
offsetof (memblock_t, aligned)
/* Convert an address into the according memory block structure. */
#define ADDR_TO_BLOCK(addr) \
(memblock_t *) ((char *) addr - BLOCK_HEAD_SIZE)
/* Check whether P points into the pool. */
static int
ptr_into_pool_p (const void *p)
{
/* We need to convert pointers to addresses. This is required by
C-99 6.5.8 to avoid undefined behaviour. Using size_t is at
least only implementation defined. See also
http://lists.gnupg.org/pipermail/gcrypt-devel/2007-February/001102.html
*/
size_t p_addr = (size_t)p;
size_t pool_addr = (size_t)pool;
return p_addr >= pool_addr && p_addr < pool_addr+pool_size;
}
/* Update the stats. */
static void
stats_update (size_t add, size_t sub)
{
if (add)
{
cur_alloced += add;
cur_blocks++;
}
if (sub)
{
cur_alloced -= sub;
cur_blocks--;
}
}
/* Return the block following MB or NULL, if MB is the last block. */
static memblock_t *
mb_get_next (memblock_t *mb)
{
memblock_t *mb_next;
mb_next = (memblock_t *) ((char *) mb + BLOCK_HEAD_SIZE + mb->size);
if (! ptr_into_pool_p (mb_next))
mb_next = NULL;
return mb_next;
}
/* Return the block preceeding MB or NULL, if MB is the first
block. */
static memblock_t *
mb_get_prev (memblock_t *mb)
{
memblock_t *mb_prev, *mb_next;
if (mb == pool)
mb_prev = NULL;
else
{
mb_prev = (memblock_t *) pool;
while (1)
{
mb_next = mb_get_next (mb_prev);
if (mb_next == mb)
break;
else
mb_prev = mb_next;
}
}
return mb_prev;
}
/* If the preceeding block of MB and/or the following block of MB
exist and are not active, merge them to form a bigger block. */
static void
mb_merge (memblock_t *mb)
{
memblock_t *mb_prev, *mb_next;
mb_prev = mb_get_prev (mb);
mb_next = mb_get_next (mb);
if (mb_prev && (! (mb_prev->flags & MB_FLAG_ACTIVE)))
{
mb_prev->size += BLOCK_HEAD_SIZE + mb->size;
mb = mb_prev;
}
if (mb_next && (! (mb_next->flags & MB_FLAG_ACTIVE)))
mb->size += BLOCK_HEAD_SIZE + mb_next->size;
}
/* Return a new block, which can hold SIZE bytes. */
static memblock_t *
mb_get_new (memblock_t *block, size_t size)
{
memblock_t *mb, *mb_split;
for (mb = block; ptr_into_pool_p (mb); mb = mb_get_next (mb))
if (! (mb->flags & MB_FLAG_ACTIVE) && mb->size >= size)
{
/* Found a free block. */
mb->flags |= MB_FLAG_ACTIVE;
if (mb->size - size > BLOCK_HEAD_SIZE)
{
/* Split block. */
mb_split = (memblock_t *) (((char *) mb) + BLOCK_HEAD_SIZE + size);
mb_split->size = mb->size - size - BLOCK_HEAD_SIZE;
mb_split->flags = 0;
mb->size = size;
mb_merge (mb_split);
}
break;
}
if (! ptr_into_pool_p (mb))
mb = NULL;
return mb;
}
/* Print a warning message. */
static void
print_warn (void)
{
if (!no_warning)
log_info (_("Warning: using insecure memory!\n"));
}
/* Lock the memory pages into core and drop privileges. */
static void
lock_pool (void *p, size_t n)
{
#if defined(USE_CAPABILITIES) && defined(HAVE_MLOCK)
int err;
cap_set_proc (cap_from_text ("cap_ipc_lock+ep"));
err = mlock (p, n);
if (err && errno)
err = errno;
cap_set_proc (cap_from_text ("cap_ipc_lock+p"));
if (err)
{
if (errno != EPERM
#ifdef EAGAIN /* OpenBSD returns this */
&& errno != EAGAIN
#endif
#ifdef ENOSYS /* Some SCOs return this (function not implemented) */
&& errno != ENOSYS
#endif
#ifdef ENOMEM /* Linux might return this. */
&& errno != ENOMEM
#endif
)
log_error ("can't lock memory: %s\n", strerror (err));
show_warning = 1;
not_locked = 1;
}
#elif defined(HAVE_MLOCK)
uid_t uid;
int err;
uid = getuid ();
#ifdef HAVE_BROKEN_MLOCK
/* Under HP/UX mlock segfaults if called by non-root. Note, we have
noch checked whether mlock does really work under AIX where we
also detected a broken nlock. Note further, that using plock ()
is not a good idea under AIX. */
if (uid)
{
errno = EPERM;
err = errno;
}
else
{
err = mlock (p, n);
if (err && errno)
err = errno;
}
#else /* !HAVE_BROKEN_MLOCK */
err = mlock (p, n);
if (err && errno)
err = errno;
#endif /* !HAVE_BROKEN_MLOCK */
if (uid && ! geteuid ())
{
/* check that we really dropped the privs.
* Note: setuid(0) should always fail */
if (setuid (uid) || getuid () != geteuid () || !setuid (0))
log_fatal ("failed to reset uid: %s\n", strerror (errno));
}
if (err)
{
if (errno != EPERM
#ifdef EAGAIN /* OpenBSD returns this. */
&& errno != EAGAIN
#endif
#ifdef ENOSYS /* Some SCOs return this (function not implemented). */
&& errno != ENOSYS
#endif
#ifdef ENOMEM /* Linux might return this. */
&& errno != ENOMEM
#endif
)
log_error ("can't lock memory: %s\n", strerror (err));
show_warning = 1;
not_locked = 1;
}
#elif defined ( __QNX__ )
/* QNX does not page at all, so the whole secure memory stuff does
* not make much sense. However it is still of use because it
* wipes out the memory on a free().
* Therefore it is sufficient to suppress the warning
*/
#elif defined (HAVE_DOSISH_SYSTEM) || defined (__CYGWIN__)
/* It does not make sense to print such a warning, given the fact that
* this whole Windows !@#$% and their user base are inherently insecure
*/
#elif defined (__riscos__)
/* no virtual memory on RISC OS, so no pages are swapped to disc,
* besides we don't have mmap, so we don't use it! ;-)
* But don't complain, as explained above.
*/
#else
log_info ("Please note that you don't have secure memory on this system\n");
#endif
}
/* Initialize POOL. */
static void
init_pool (size_t n)
{
size_t pgsize;
long int pgsize_val;
memblock_t *mb;
pool_size = n;
if (disable_secmem)
log_bug ("secure memory is disabled");
#if defined(HAVE_SYSCONF) && defined(_SC_PAGESIZE)
pgsize_val = sysconf (_SC_PAGESIZE);
#elif defined(HAVE_GETPAGESIZE)
pgsize_val = getpagesize ();
#else
pgsize_val = -1;
#endif
pgsize = (pgsize_val != -1 && pgsize_val > 0)? pgsize_val:DEFAULT_PAGE_SIZE;
#if HAVE_MMAP
pool_size = (pool_size + pgsize - 1) & ~(pgsize - 1);
#ifdef MAP_ANONYMOUS
pool = mmap (0, pool_size, PROT_READ | PROT_WRITE,
MAP_PRIVATE | MAP_ANONYMOUS, -1, 0);
#else /* map /dev/zero instead */
{
int fd;
fd = open ("/dev/zero", O_RDWR);
if (fd == -1)
{
log_error ("can't open /dev/zero: %s\n", strerror (errno));
pool = (void *) -1;
}
else
{
pool = mmap (0, pool_size, PROT_READ | PROT_WRITE, MAP_PRIVATE, fd, 0);
close (fd);
}
}
#endif
if (pool == (void *) -1)
log_info ("can't mmap pool of %u bytes: %s - using malloc\n",
(unsigned) pool_size, strerror (errno));
else
{
pool_is_mmapped = 1;
pool_okay = 1;
}
#endif
if (!pool_okay)
{
pool = malloc (pool_size);
if (!pool)
log_fatal ("can't allocate memory pool of %u bytes\n",
(unsigned) pool_size);
else
pool_okay = 1;
}
/* Initialize first memory block. */
mb = (memblock_t *) pool;
mb->size = pool_size;
mb->flags = 0;
}
void
_gcry_secmem_set_flags (unsigned flags)
{
int was_susp;
SECMEM_LOCK;
was_susp = suspend_warning;
no_warning = flags & GCRY_SECMEM_FLAG_NO_WARNING;
suspend_warning = flags & GCRY_SECMEM_FLAG_SUSPEND_WARNING;
/* and now issue the warning if it is not longer suspended */
if (was_susp && !suspend_warning && show_warning)
{
show_warning = 0;
print_warn ();
}
SECMEM_UNLOCK;
}
unsigned int
_gcry_secmem_get_flags (void)
{
unsigned flags;
SECMEM_LOCK;
flags = no_warning ? GCRY_SECMEM_FLAG_NO_WARNING : 0;
flags |= suspend_warning ? GCRY_SECMEM_FLAG_SUSPEND_WARNING : 0;
flags |= not_locked ? GCRY_SECMEM_FLAG_NOT_LOCKED : 0;
SECMEM_UNLOCK;
return flags;
}
/* See _gcry_secmem_init. This function is expected to be called with
the secmem lock held. */
static void
secmem_init (size_t n)
{
if (!n)
{
#ifdef USE_CAPABILITIES
/* drop all capabilities */
cap_set_proc (cap_from_text ("all-eip"));
#elif !defined(HAVE_DOSISH_SYSTEM)
uid_t uid;
disable_secmem = 1;
uid = getuid ();
if (uid != geteuid ())
{
if (setuid (uid) || getuid () != geteuid () || !setuid (0))
log_fatal ("failed to drop setuid\n");
}
#endif
}
else
{
if (n < MINIMUM_POOL_SIZE)
n = MINIMUM_POOL_SIZE;
if (! pool_okay)
{
init_pool (n);
lock_pool (pool, n);
}
else
log_error ("Oops, secure memory pool already initialized\n");
}
}
/* Initialize the secure memory system. If running with the necessary
privileges, the secure memory pool will be locked into the core in
order to prevent page-outs of the data. Furthermore allocated
secure memory will be wiped out when released. */
void
_gcry_secmem_init (size_t n)
{
SECMEM_LOCK;
secmem_init (n);
SECMEM_UNLOCK;
}
static void *
_gcry_secmem_malloc_internal (size_t size)
{
memblock_t *mb;
if (!pool_okay)
{
/* Try to initialize the pool if the user forgot about it. */
secmem_init (STANDARD_POOL_SIZE);
if (!pool_okay)
{
log_info (_("operation is not possible without "
"initialized secure memory\n"));
return NULL;
}
}
if (not_locked && fips_mode ())
{
log_info (_("secure memory pool is not locked while in FIPS mode\n"));
return NULL;
}
if (show_warning && !suspend_warning)
{
show_warning = 0;
print_warn ();
}
/* Blocks are always a multiple of 32. */
size = ((size + 31) / 32) * 32;
mb = mb_get_new ((memblock_t *) pool, size);
if (mb)
stats_update (size, 0);
return mb ? &mb->aligned.c : NULL;
}
void *
_gcry_secmem_malloc (size_t size)
{
void *p;
SECMEM_LOCK;
p = _gcry_secmem_malloc_internal (size);
SECMEM_UNLOCK;
return p;
}
static void
_gcry_secmem_free_internal (void *a)
{
memblock_t *mb;
int size;
if (!a)
return;
mb = ADDR_TO_BLOCK (a);
size = mb->size;
/* This does not make much sense: probably this memory is held in the
* cache. We do it anyway: */
#define MB_WIPE_OUT(byte) \
wipememory2 ((memblock_t *) ((char *) mb + BLOCK_HEAD_SIZE), (byte), size);
MB_WIPE_OUT (0xff);
MB_WIPE_OUT (0xaa);
MB_WIPE_OUT (0x55);
MB_WIPE_OUT (0x00);
stats_update (0, size);
mb->flags &= ~MB_FLAG_ACTIVE;
/* Update stats. */
mb_merge (mb);
}
/* Wipe out and release memory. */
void
_gcry_secmem_free (void *a)
{
SECMEM_LOCK;
_gcry_secmem_free_internal (a);
SECMEM_UNLOCK;
}
/* Realloc memory. */
void *
_gcry_secmem_realloc (void *p, size_t newsize)
{
memblock_t *mb;
size_t size;
void *a;
SECMEM_LOCK;
mb = (memblock_t *) ((char *) p - ((size_t) &((memblock_t *) 0)->aligned.c));
size = mb->size;
if (newsize < size)
{
/* It is easier to not shrink the memory. */
a = p;
}
else
{
a = _gcry_secmem_malloc_internal (newsize);
if (a)
{
memcpy (a, p, size);
memset ((char *) a + size, 0, newsize - size);
_gcry_secmem_free_internal (p);
}
}
SECMEM_UNLOCK;
return a;
}
/* Return true if P points into the secure memory area. */
int
_gcry_private_is_secure (const void *p)
{
return pool_okay && ptr_into_pool_p (p);
}
/****************
* Warning: This code might be called by an interrupt handler
* and frankly, there should really be such a handler,
* to make sure that the memory is wiped out.
* We hope that the OS wipes out mlocked memory after
* receiving a SIGKILL - it really should do so, otherwise
* there is no chance to get the secure memory cleaned.
*/
void
_gcry_secmem_term ()
{
if (!pool_okay)
return;
wipememory2 (pool, 0xff, pool_size);
wipememory2 (pool, 0xaa, pool_size);
wipememory2 (pool, 0x55, pool_size);
wipememory2 (pool, 0x00, pool_size);
#if HAVE_MMAP
if (pool_is_mmapped)
munmap (pool, pool_size);
#endif
pool = NULL;
pool_okay = 0;
pool_size = 0;
not_locked = 0;
}
void
_gcry_secmem_dump_stats ()
{
#if 1
SECMEM_LOCK;
if (pool_okay)
log_info ("secmem usage: %u/%lu bytes in %u blocks\n",
cur_alloced, (unsigned long)pool_size, cur_blocks);
SECMEM_UNLOCK;
#else
memblock_t *mb;
int i;
SECMEM_LOCK;
for (i = 0, mb = (memblock_t *) pool;
ptr_into_pool_p (mb);
mb = mb_get_next (mb), i++)
log_info ("SECMEM: [%s] block: %i; size: %i\n",
(mb->flags & MB_FLAG_ACTIVE) ? "used" : "free",
i,
mb->size);
SECMEM_UNLOCK;
#endif
}