/*--------------------------------------------------------------------*/
/*--- The address space manager: stuff common to all platforms ---*/
/*--- ---*/
/*--- m_aspacemgr-common.c ---*/
/*--------------------------------------------------------------------*/
/*
This file is part of Valgrind, a dynamic binary instrumentation
framework.
Copyright (C) 2006-2012 OpenWorks LLP
info@open-works.co.uk
This program 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 of the
License, or (at your option) any later version.
This program 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 this program; if not, write to the Free Software
Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA
02111-1307, USA.
The GNU General Public License is contained in the file COPYING.
*/
/* *************************************************************
DO NOT INCLUDE ANY OTHER FILES HERE.
ADD NEW INCLUDES ONLY TO priv_aspacemgr.h
AND THEN ONLY AFTER READING DIRE WARNINGS THERE TOO.
************************************************************* */
#include "priv_aspacemgr.h"
#include "config.h"
/*-----------------------------------------------------------------*/
/*--- ---*/
/*--- Stuff to make aspacem almost completely independent of ---*/
/*--- the rest of Valgrind. ---*/
/*--- ---*/
/*-----------------------------------------------------------------*/
//--------------------------------------------------------------
// Simple assert and assert-like fns, which avoid dependence on
// m_libcassert, and hence on the entire debug-info reader swamp
__attribute__ ((noreturn))
void ML_(am_exit)( Int status )
{
# if defined(VGO_linux)
(void)VG_(do_syscall1)(__NR_exit_group, status);
# endif
(void)VG_(do_syscall1)(__NR_exit, status);
/* Why are we still alive here? */
/*NOTREACHED*/
*(volatile Int *)0 = 'x';
aspacem_assert(2+2 == 5);
}
void ML_(am_barf) ( HChar* what )
{
VG_(debugLog)(0, "aspacem", "Valgrind: FATAL: %s\n", what);
VG_(debugLog)(0, "aspacem", "Exiting now.\n");
ML_(am_exit)(1);
}
void ML_(am_barf_toolow) ( HChar* what )
{
VG_(debugLog)(0, "aspacem",
"Valgrind: FATAL: %s is too low.\n", what);
VG_(debugLog)(0, "aspacem", " Increase it and rebuild. "
"Exiting now.\n");
ML_(am_exit)(1);
}
void ML_(am_assert_fail)( const HChar* expr,
const Char* file,
Int line,
const Char* fn )
{
VG_(debugLog)(0, "aspacem",
"Valgrind: FATAL: aspacem assertion failed:\n");
VG_(debugLog)(0, "aspacem", " %s\n", expr);
VG_(debugLog)(0, "aspacem", " at %s:%d (%s)\n", file,line,fn);
VG_(debugLog)(0, "aspacem", "Exiting now.\n");
ML_(am_exit)(1);
}
Int ML_(am_getpid)( void )
{
SysRes sres = VG_(do_syscall0)(__NR_getpid);
aspacem_assert(!sr_isError(sres));
return sr_Res(sres);
}
//--------------------------------------------------------------
// A simple sprintf implementation, so as to avoid dependence on
// m_libcprint.
static void local_add_to_aspacem_sprintf_buf ( HChar c, void *p )
{
HChar** aspacem_sprintf_ptr = p;
*(*aspacem_sprintf_ptr)++ = c;
}
static
UInt local_vsprintf ( HChar* buf, const HChar *format, va_list vargs )
{
Int ret;
Char *aspacem_sprintf_ptr = buf;
ret = VG_(debugLog_vprintf)
( local_add_to_aspacem_sprintf_buf,
&aspacem_sprintf_ptr, format, vargs );
local_add_to_aspacem_sprintf_buf('\0', &aspacem_sprintf_ptr);
return ret;
}
UInt ML_(am_sprintf) ( HChar* buf, const HChar *format, ... )
{
UInt ret;
va_list vargs;
va_start(vargs,format);
ret = local_vsprintf(buf, format, vargs);
va_end(vargs);
return ret;
}
//--------------------------------------------------------------
// Direct access to a handful of syscalls. This avoids dependence on
// m_libc*. THESE DO NOT UPDATE THE aspacem-internal DATA
// STRUCTURES (SEGMENT ARRAY). DO NOT USE THEM UNLESS YOU KNOW WHAT
// YOU ARE DOING.
/* --- Pertaining to mappings --- */
/* Note: this is VG_, not ML_. */
SysRes VG_(am_do_mmap_NO_NOTIFY)( Addr start, SizeT length, UInt prot,
UInt flags, Int fd, Off64T offset)
{
SysRes res;
aspacem_assert(VG_IS_PAGE_ALIGNED(offset));
# if defined(VGP_x86_linux) || defined(VGP_ppc32_linux) \
|| defined(VGP_arm_linux)
/* mmap2 uses 4096 chunks even if actual page size is bigger. */
aspacem_assert((offset % 4096) == 0);
res = VG_(do_syscall6)(__NR_mmap2, (UWord)start, length,
prot, flags, fd, offset / 4096);
# elif defined(VGP_amd64_linux) || defined(VGP_ppc64_linux) \
|| defined(VGP_s390x_linux) || defined(VGP_mips32_linux)
res = VG_(do_syscall6)(__NR_mmap, (UWord)start, length,
prot, flags, fd, offset);
# elif defined(VGP_x86_darwin)
if (fd == 0 && (flags & VKI_MAP_ANONYMOUS)) {
fd = -1; // MAP_ANON with fd==0 is EINVAL
}
res = VG_(do_syscall7)(__NR_mmap, (UWord)start, length,
prot, flags, fd, offset & 0xffffffff, offset >> 32);
# elif defined(VGP_amd64_darwin)
if (fd == 0 && (flags & VKI_MAP_ANONYMOUS)) {
fd = -1; // MAP_ANON with fd==0 is EINVAL
}
res = VG_(do_syscall6)(__NR_mmap, (UWord)start, length,
prot, flags, (UInt)fd, offset);
# else
# error Unknown platform
# endif
return res;
}
static
SysRes local_do_mprotect_NO_NOTIFY(Addr start, SizeT length, UInt prot)
{
return VG_(do_syscall3)(__NR_mprotect, (UWord)start, length, prot );
}
SysRes ML_(am_do_munmap_NO_NOTIFY)(Addr start, SizeT length)
{
return VG_(do_syscall2)(__NR_munmap, (UWord)start, length );
}
#if HAVE_MREMAP
/* The following are used only to implement mremap(). */
SysRes ML_(am_do_extend_mapping_NO_NOTIFY)(
Addr old_addr,
SizeT old_len,
SizeT new_len
)
{
/* Extend the mapping old_addr .. old_addr+old_len-1 to have length
new_len, WITHOUT moving it. If it can't be extended in place,
fail. */
# if defined(VGO_linux)
return VG_(do_syscall5)(
__NR_mremap,
old_addr, old_len, new_len,
0/*flags, meaning: must be at old_addr, else FAIL */,
0/*new_addr, is ignored*/
);
# else
# error Unknown OS
# endif
}
SysRes ML_(am_do_relocate_nooverlap_mapping_NO_NOTIFY)(
Addr old_addr, Addr old_len,
Addr new_addr, Addr new_len
)
{
/* Move the mapping old_addr .. old_addr+old_len-1 to the new
location and with the new length. Only needs to handle the case
where the two areas do not overlap, neither length is zero, and
all args are page aligned. */
# if defined(VGO_linux)
return VG_(do_syscall5)(
__NR_mremap,
old_addr, old_len, new_len,
VKI_MREMAP_MAYMOVE|VKI_MREMAP_FIXED/*move-or-fail*/,
new_addr
);
# else
# error Unknown OS
# endif
}
#endif
/* --- Pertaining to files --- */
SysRes ML_(am_open) ( const Char* pathname, Int flags, Int mode )
{
SysRes res = VG_(do_syscall3)(__NR_open, (UWord)pathname, flags, mode);
return res;
}
Int ML_(am_read) ( Int fd, void* buf, Int count)
{
SysRes res = VG_(do_syscall3)(__NR_read, fd, (UWord)buf, count);
return sr_isError(res) ? -1 : sr_Res(res);
}
void ML_(am_close) ( Int fd )
{
(void)VG_(do_syscall1)(__NR_close, fd);
}
Int ML_(am_readlink)(HChar* path, HChar* buf, UInt bufsiz)
{
SysRes res;
res = VG_(do_syscall3)(__NR_readlink, (UWord)path, (UWord)buf, bufsiz);
return sr_isError(res) ? -1 : sr_Res(res);
}
Int ML_(am_fcntl) ( Int fd, Int cmd, Addr arg )
{
# if defined(VGO_linux)
SysRes res = VG_(do_syscall3)(__NR_fcntl, fd, cmd, arg);
# elif defined(VGO_darwin)
SysRes res = VG_(do_syscall3)(__NR_fcntl_nocancel, fd, cmd, arg);
# else
# error "Unknown OS"
# endif
return sr_isError(res) ? -1 : sr_Res(res);
}
/* Get the dev, inode and mode info for a file descriptor, if
possible. Returns True on success. */
Bool ML_(am_get_fd_d_i_m)( Int fd,
/*OUT*/ULong* dev,
/*OUT*/ULong* ino, /*OUT*/UInt* mode )
{
SysRes res;
struct vki_stat buf;
# if defined(VGO_linux) && defined(__NR_fstat64)
/* Try fstat64 first as it can cope with minor and major device
numbers outside the 0-255 range and it works properly for x86
binaries on amd64 systems where fstat seems to be broken. */
struct vki_stat64 buf64;
res = VG_(do_syscall2)(__NR_fstat64, fd, (UWord)&buf64);
if (!sr_isError(res)) {
*dev = (ULong)buf64.st_dev;
*ino = (ULong)buf64.st_ino;
*mode = (UInt) buf64.st_mode;
return True;
}
# endif
res = VG_(do_syscall2)(__NR_fstat, fd, (UWord)&buf);
if (!sr_isError(res)) {
*dev = (ULong)buf.st_dev;
*ino = (ULong)buf.st_ino;
*mode = (UInt) buf.st_mode;
return True;
}
return False;
}
Bool ML_(am_resolve_filename) ( Int fd, /*OUT*/HChar* buf, Int nbuf )
{
#if defined(VGO_linux)
Int i;
HChar tmp[64];
for (i = 0; i < nbuf; i++) buf[i] = 0;
ML_(am_sprintf)(tmp, "/proc/self/fd/%d", fd);
if (ML_(am_readlink)(tmp, buf, nbuf) > 0 && buf[0] == '/')
return True;
else
return False;
#elif defined(VGO_darwin)
HChar tmp[VKI_MAXPATHLEN+1];
if (0 == ML_(am_fcntl)(fd, VKI_F_GETPATH, (UWord)tmp)) {
if (nbuf > 0) {
VG_(strncpy)( buf, tmp, nbuf < sizeof(tmp) ? nbuf : sizeof(tmp) );
buf[nbuf-1] = 0;
}
if (tmp[0] == '/') return True;
}
return False;
# else
# error Unknown OS
# endif
}
/*-----------------------------------------------------------------*/
/*--- ---*/
/*--- Manage stacks for Valgrind itself. ---*/
/*--- ---*/
/*-----------------------------------------------------------------*/
/* Allocate and initialise a VgStack (anonymous valgrind space).
Protect the stack active area and the guard areas appropriately.
Returns NULL on failure, else the address of the bottom of the
stack. On success, also sets *initial_sp to what the stack pointer
should be set to. */
VgStack* VG_(am_alloc_VgStack)( /*OUT*/Addr* initial_sp )
{
Int szB;
SysRes sres;
VgStack* stack;
UInt* p;
Int i;
/* Allocate the stack. */
szB = VG_STACK_GUARD_SZB
+ VG_STACK_ACTIVE_SZB + VG_STACK_GUARD_SZB;
sres = VG_(am_mmap_anon_float_valgrind)( szB );
if (sr_isError(sres))
return NULL;
stack = (VgStack*)(AddrH)sr_Res(sres);
aspacem_assert(VG_IS_PAGE_ALIGNED(szB));
aspacem_assert(VG_IS_PAGE_ALIGNED(stack));
/* Protect the guard areas. */
sres = local_do_mprotect_NO_NOTIFY(
(Addr) &stack[0],
VG_STACK_GUARD_SZB, VKI_PROT_NONE
);
if (sr_isError(sres)) goto protect_failed;
VG_(am_notify_mprotect)(
(Addr) &stack->bytes[0],
VG_STACK_GUARD_SZB, VKI_PROT_NONE
);
sres = local_do_mprotect_NO_NOTIFY(
(Addr) &stack->bytes[VG_STACK_GUARD_SZB + VG_STACK_ACTIVE_SZB],
VG_STACK_GUARD_SZB, VKI_PROT_NONE
);
if (sr_isError(sres)) goto protect_failed;
VG_(am_notify_mprotect)(
(Addr) &stack->bytes[VG_STACK_GUARD_SZB + VG_STACK_ACTIVE_SZB],
VG_STACK_GUARD_SZB, VKI_PROT_NONE
);
/* Looks good. Fill the active area with junk so we can later
tell how much got used. */
p = (UInt*)&stack->bytes[VG_STACK_GUARD_SZB];
for (i = 0; i < VG_STACK_ACTIVE_SZB/sizeof(UInt); i++)
p[i] = 0xDEADBEEF;
*initial_sp = (Addr)&stack->bytes[VG_STACK_GUARD_SZB + VG_STACK_ACTIVE_SZB];
*initial_sp -= 8;
*initial_sp &= ~((Addr)0x1F); /* 32-align it */
VG_(debugLog)( 1,"aspacem","allocated thread stack at 0x%llx size %d\n",
(ULong)(Addr)stack, szB);
ML_(am_do_sanity_check)();
return stack;
protect_failed:
/* The stack was allocated, but we can't protect it. Unmap it and
return NULL (failure). */
(void)ML_(am_do_munmap_NO_NOTIFY)( (Addr)stack, szB );
ML_(am_do_sanity_check)();
return NULL;
}
/* Figure out how many bytes of the stack's active area have not
been used. Used for estimating if we are close to overflowing it. */
SizeT VG_(am_get_VgStack_unused_szB)( VgStack* stack, SizeT limit )
{
SizeT i;
UInt* p;
p = (UInt*)&stack->bytes[VG_STACK_GUARD_SZB];
for (i = 0; i < VG_STACK_ACTIVE_SZB/sizeof(UInt); i++) {
if (p[i] != 0xDEADBEEF)
break;
if (i * sizeof(UInt) >= limit)
break;
}
return i * sizeof(UInt);
}
/*--------------------------------------------------------------------*/
/*--- end ---*/
/*--------------------------------------------------------------------*/