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ftmemsim-valgrind/coregrind/m_syswrap/syswrap-ppc32-linux.c
Philippe Waroquiers 51c6c85e22 The semantic of the stack bounds is not consistent or is not described. 
At various places, there were either some assumption that the 'end'
boundary (highest address) was either not included, included,
or was the highest addressable word, or the highest addressable byte.
This e.g. was very visible when doing:
  ./vg-in-place -d -d ./helgrind/tests/tc01_simple_race|&grep regi
giving
  --24040:2:stacks     register 0xBEDB4000-0xBEDB4FFF as stack 0
  --24040:2:stacks     register 0x402C000-0x4A2C000 as stack 1
showing that the main stack end was (on x86) not the highest word
but the highest byte, while for the thread 1, the registered end
was a byte not part of the stack.

The attached patch ensures that stack bounds semantic are documented and
consistent. Also, some of the stack handling code is factorised.

The convention that the patch ensures and documents is:
start is the lowest addressable byte, end is the highest addressable byte.
(the words 'min' and 'max' have been kept when already used, as this wording is 
consistent with the new semantic of start/end).

In various debug log, used brackets [ and ] to make clear that
both bounds are included.

The code to guess and register the client stack was duplicated
in all the platform specific syswrap-<plat>-<os>.c files.
Code has been factorised in syswrap-generic.c

The patch has been regression tested on
   x86, amd64, ppc32/64, s390x.
It has been compiled and one test run on arm64.
Not compiled/not tested on darwin, android, mips32/64, arm


More in details, the patch does the following:

coregrind/pub_core_aspacemgr.h
include/valgrind.h
include/pub_tool_machine.h
coregrind/pub_core_scheduler.h
coregrind/pub_core_stacks.h
  - document start/end semantic in various functions
 also in pub_tool_machine.h:
  - replaces unclear 'bottommost address' by 'lowest address'
    (unclear as stack bottom is or at least can be interpreted as
     the 'functional' bottom of the stack, which is the highest
      address for 'stack growing downwards').
coregrind/pub_core_initimg.h
  replace unclear clstack_top by clstack_end
coregrind/m_main.c
  updated to clstack_end

coregrind/pub_core_threadstate.h
  renamed client_stack_highest_word to client_stack_highest_byte
coregrind/m_scheduler/scheduler.c
  computes client_stack_highest_byte as the highest addressable byte
  Update comments in call to VG_(show_sched_status)
coregrind/m_machine.c
coregrind/m_stacktrace.c
  updated to client_stack_highest_byte, and switched 
    stack_lowest/highest_word to stack_lowest/highest_byte accordingly

coregrind/m_stacks.c
  clarify semantic of start/end,
  added a comment to indicate why we invert start/end in register call
  (note that the code find_stack_by_addr was already assuming that
  end was included as the checks were doing e.g.
    sp >= i->start && sp <= i->end

coregrind/pub_core_clientstate.h
coregrind/m_clientstate.c
  renames Addr  VG_(clstk_base) to Addr  VG_(clstk_start_base)
    (start to indicate it is the lowest address, base suffix kept
     to indicate it is the initial lowest address).

coregrind/m_initimg/initimg-darwin.c
   updated to  VG_(clstk_start_base)
   replace unclear iicii.clstack_top by iicii.clstack_end
   updated clstack_max_size computation according to both bounds included.

coregrind/m_initimg/initimg-linux.c
   updated to  VG_(clstk_start_base)
   updated VG_(clstk_end) computation according to both bounds included.
   replace unclear iicii.clstack_top by iicii.clstack_end

coregrind/pub_core_aspacemgr.h
  extern Addr VG_(am_startup) : clarify semantic of the returned value
coregrind/m_aspacemgr/aspacemgr-linux.c
   removed a copy of a comment that was already in pub_core_aspacemgr.h
     (avoid double maintenance)
   renamed unclear suggested_clstack_top to suggested_clstack_end
    (note that here, it looks like suggested_clstack_top was already
     the last addressable byte)

* factorisation of the stack guessing and registration causes
  mechanical changes in the following files:
      coregrind/m_syswrap/syswrap-ppc64-linux.c
      coregrind/m_syswrap/syswrap-x86-darwin.c
      coregrind/m_syswrap/syswrap-amd64-linux.c
      coregrind/m_syswrap/syswrap-arm-linux.c
      coregrind/m_syswrap/syswrap-generic.c
      coregrind/m_syswrap/syswrap-mips64-linux.c
      coregrind/m_syswrap/syswrap-ppc32-linux.c
      coregrind/m_syswrap/syswrap-amd64-darwin.c
      coregrind/m_syswrap/syswrap-mips32-linux.c
      coregrind/m_syswrap/priv_syswrap-generic.h
      coregrind/m_syswrap/syswrap-x86-linux.c
      coregrind/m_syswrap/syswrap-s390x-linux.c
      coregrind/m_syswrap/syswrap-darwin.c
      coregrind/m_syswrap/syswrap-arm64-linux.c
 Some files to look at more in details:
  syswrap-darwin.c : the handling of sysctl(kern.usrstack) looked
    buggy to me, and has probably be made correct by the fact that
     VG_(clstk_end) is now the last addressable byte. However,unsure
    about this, as I could not find any documentation about 
    sysctl(kern.usrstack). I only find several occurences on the web,
    showing that the result of this is page aligned, which I guess
    means it must be 1+ the last addressable byte.
  syswrap-x86-darwin.c and syswrap-amd64-darwin.c
   I suspect the code that was computing client_stack_highest_word
   was wrong, and the patch makes it correct.
  syswrap-mips64-linux.c
    not sure what to do for this code. This is the only code
    that was guessing the stack differently from others.
    Kept (almost) untouched. To be discussed with mips maintainers.

coregrind/pub_core_libcassert.h
coregrind/m_libcassert.c
  * void VG_(show_sched_status):
     renamed Bool valgrind_stack_usage to Bool stack_usage
     if stack_usage, shows both the valgrind stack usage and
     the client stack boundaries
coregrind/m_scheduler/scheduler.c
coregrind/m_gdbserver/server.c
coregrind/m_gdbserver/remote-utils.c
   Updated comments in callers to VG_(show_sched_status)



git-svn-id: svn://svn.valgrind.org/valgrind/trunk@14392
2014-08-29 22:53:19 +00:00

1268 lines
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/*--------------------------------------------------------------------*/
/*--- Platform-specific syscalls stuff. syswrap-ppc32-linux.c ---*/
/*--------------------------------------------------------------------*/
/*
This file is part of Valgrind, a dynamic binary instrumentation
framework.
Copyright (C) 2005-2013 Nicholas Nethercote <njn@valgrind.org>
Copyright (C) 2005-2013 Cerion Armour-Brown <cerion@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.
*/
#if defined(VGP_ppc32_linux)
#include "pub_core_basics.h"
#include "pub_core_vki.h"
#include "pub_core_vkiscnums.h"
#include "pub_core_libcsetjmp.h" // to keep _threadstate.h happy
#include "pub_core_threadstate.h"
#include "pub_core_aspacemgr.h"
#include "pub_core_debuglog.h"
#include "pub_core_libcbase.h"
#include "pub_core_libcassert.h"
#include "pub_core_libcprint.h"
#include "pub_core_libcproc.h"
#include "pub_core_libcsignal.h"
#include "pub_core_options.h"
#include "pub_core_scheduler.h"
#include "pub_core_sigframe.h" // For VG_(sigframe_destroy)()
#include "pub_core_signals.h"
#include "pub_core_syscall.h"
#include "pub_core_syswrap.h"
#include "pub_core_tooliface.h"
#include "pub_core_stacks.h" // VG_(register_stack)
#include "priv_types_n_macros.h"
#include "priv_syswrap-generic.h" /* for decls of generic wrappers */
#include "priv_syswrap-linux.h" /* for decls of linux-ish wrappers */
#include "priv_syswrap-main.h"
/* ---------------------------------------------------------------------
clone() handling
------------------------------------------------------------------ */
/* Call f(arg1), but first switch stacks, using 'stack' as the new
stack, and use 'retaddr' as f's return-to address. Also, clear all
the integer registers before entering f.*/
__attribute__((noreturn))
void ML_(call_on_new_stack_0_1) ( Addr stack,
Addr retaddr,
void (*f)(Word),
Word arg1 );
// r3 = stack
// r4 = retaddr
// r5 = f
// r6 = arg1
asm(
".text\n"
".globl vgModuleLocal_call_on_new_stack_0_1\n"
"vgModuleLocal_call_on_new_stack_0_1:\n"
" mr %r1,%r3\n\t" // stack to %sp
" mtlr %r4\n\t" // retaddr to %lr
" mtctr %r5\n\t" // f to count reg
" mr %r3,%r6\n\t" // arg1 to %r3
" li 0,0\n\t" // zero all GP regs
" li 4,0\n\t"
" li 5,0\n\t"
" li 6,0\n\t"
" li 7,0\n\t"
" li 8,0\n\t"
" li 9,0\n\t"
" li 10,0\n\t"
" li 11,0\n\t"
" li 12,0\n\t"
" li 13,0\n\t"
" li 14,0\n\t"
" li 15,0\n\t"
" li 16,0\n\t"
" li 17,0\n\t"
" li 18,0\n\t"
" li 19,0\n\t"
" li 20,0\n\t"
" li 21,0\n\t"
" li 22,0\n\t"
" li 23,0\n\t"
" li 24,0\n\t"
" li 25,0\n\t"
" li 26,0\n\t"
" li 27,0\n\t"
" li 28,0\n\t"
" li 29,0\n\t"
" li 30,0\n\t"
" li 31,0\n\t"
" mtxer 0\n\t" // CAB: Need this?
" mtcr 0\n\t" // CAB: Need this?
" bctr\n\t" // jump to dst
" trap\n" // should never get here
".previous\n"
);
/*
Perform a clone system call. clone is strange because it has
fork()-like return-twice semantics, so it needs special
handling here.
Upon entry, we have:
int (fn)(void*) in r3
void* child_stack in r4
int flags in r5
void* arg in r6
pid_t* child_tid in r7
pid_t* parent_tid in r8
void* ??? in r9
System call requires:
int $__NR_clone in r0 (sc number)
int flags in r3 (sc arg1)
void* child_stack in r4 (sc arg2)
pid_t* parent_tid in r5 (sc arg3)
?? child_tls in r6 (sc arg4)
pid_t* child_tid in r7 (sc arg5)
void* ??? in r8 (sc arg6)
Returns an Int encoded in the linux-ppc32 way, not a SysRes.
*/
#define __NR_CLONE VG_STRINGIFY(__NR_clone)
#define __NR_EXIT VG_STRINGIFY(__NR_exit)
extern
ULong do_syscall_clone_ppc32_linux ( Word (*fn)(void *),
void* stack,
Int flags,
void* arg,
Int* child_tid,
Int* parent_tid,
vki_modify_ldt_t * );
asm(
".text\n"
".globl do_syscall_clone_ppc32_linux\n"
"do_syscall_clone_ppc32_linux:\n"
" stwu 1,-32(1)\n"
" stw 29,20(1)\n"
" stw 30,24(1)\n"
" stw 31,28(1)\n"
" mr 30,3\n" // preserve fn
" mr 31,6\n" // preserve arg
// setup child stack
" rlwinm 4,4,0,~0xf\n" // trim sp to multiple of 16 bytes
" li 0,0\n"
" stwu 0,-16(4)\n" // make initial stack frame
" mr 29,4\n" // preserve sp
// setup syscall
" li 0,"__NR_CLONE"\n" // syscall number
" mr 3,5\n" // syscall arg1: flags
// r4 already setup // syscall arg2: child_stack
" mr 5,8\n" // syscall arg3: parent_tid
" mr 6,2\n" // syscall arg4: REAL THREAD tls
" mr 7,7\n" // syscall arg5: child_tid
" mr 8,8\n" // syscall arg6: ????
" mr 9,9\n" // syscall arg7: ????
" sc\n" // clone()
" mfcr 4\n" // return CR in r4 (low word of ULong)
" cmpwi 3,0\n" // child if retval == 0
" bne 1f\n" // jump if !child
/* CHILD - call thread function */
/* Note: 2.4 kernel doesn't set the child stack pointer,
so we do it here.
That does leave a small window for a signal to be delivered
on the wrong stack, unfortunately. */
" mr 1,29\n"
" mtctr 30\n" // ctr reg = fn
" mr 3,31\n" // r3 = arg
" bctrl\n" // call fn()
// exit with result
" li 0,"__NR_EXIT"\n"
" sc\n"
// Exit returned?!
" .long 0\n"
// PARENT or ERROR - return
"1: lwz 29,20(1)\n"
" lwz 30,24(1)\n"
" lwz 31,28(1)\n"
" addi 1,1,32\n"
" blr\n"
".previous\n"
);
#undef __NR_CLONE
#undef __NR_EXIT
// forward declarations
static void setup_child ( ThreadArchState*, ThreadArchState* );
/*
When a client clones, we need to keep track of the new thread. This means:
1. allocate a ThreadId+ThreadState+stack for the the thread
2. initialize the thread's new VCPU state
3. create the thread using the same args as the client requested,
but using the scheduler entrypoint for IP, and a separate stack
for SP.
*/
static SysRes do_clone ( ThreadId ptid,
UInt flags, Addr sp,
Int *parent_tidptr,
Int *child_tidptr,
Addr child_tls)
{
const Bool debug = False;
ThreadId ctid = VG_(alloc_ThreadState)();
ThreadState* ptst = VG_(get_ThreadState)(ptid);
ThreadState* ctst = VG_(get_ThreadState)(ctid);
ULong word64;
UWord* stack;
SysRes res;
vki_sigset_t blockall, savedmask;
VG_(sigfillset)(&blockall);
vg_assert(VG_(is_running_thread)(ptid));
vg_assert(VG_(is_valid_tid)(ctid));
stack = (UWord*)ML_(allocstack)(ctid);
if (stack == NULL) {
res = VG_(mk_SysRes_Error)( VKI_ENOMEM );
goto out;
}
//? /* make a stack frame */
//? stack -= 16;
//? *(UWord *)stack = 0;
/* Copy register state
Both parent and child return to the same place, and the code
following the clone syscall works out which is which, so we
don't need to worry about it.
The parent gets the child's new tid returned from clone, but the
child gets 0.
If the clone call specifies a NULL SP for the new thread, then
it actually gets a copy of the parent's SP.
The child's TLS register (r2) gets set to the tlsaddr argument
if the CLONE_SETTLS flag is set.
*/
setup_child( &ctst->arch, &ptst->arch );
/* Make sys_clone appear to have returned Success(0) in the
child. */
{ UInt old_cr = LibVEX_GuestPPC32_get_CR( &ctst->arch.vex );
/* %r3 = 0 */
ctst->arch.vex.guest_GPR3 = 0;
/* %cr0.so = 0 */
LibVEX_GuestPPC32_put_CR( old_cr & ~(1<<28), &ctst->arch.vex );
}
if (sp != 0)
ctst->arch.vex.guest_GPR1 = sp;
ctst->os_state.parent = ptid;
/* inherit signal mask */
ctst->sig_mask = ptst->sig_mask;
ctst->tmp_sig_mask = ptst->sig_mask;
/* Start the child with its threadgroup being the same as the
parent's. This is so that any exit_group calls that happen
after the child is created but before it sets its
os_state.threadgroup field for real (in thread_wrapper in
syswrap-linux.c), really kill the new thread. a.k.a this avoids
a race condition in which the thread is unkillable (via
exit_group) because its threadgroup is not set. The race window
is probably only a few hundred or a few thousand cycles long.
See #226116. */
ctst->os_state.threadgroup = ptst->os_state.threadgroup;
ML_(guess_and_register_stack) (sp, ctst);
/* Assume the clone will succeed, and tell any tool that wants to
know that this thread has come into existence. If the clone
fails, we'll send out a ll_exit notification for it at the out:
label below, to clean up. */
vg_assert(VG_(owns_BigLock_LL)(ptid));
VG_TRACK ( pre_thread_ll_create, ptid, ctid );
if (flags & VKI_CLONE_SETTLS) {
if (debug)
VG_(printf)("clone child has SETTLS: tls at %#lx\n", child_tls);
ctst->arch.vex.guest_GPR2 = child_tls;
}
flags &= ~VKI_CLONE_SETTLS;
/* start the thread with everything blocked */
VG_(sigprocmask)(VKI_SIG_SETMASK, &blockall, &savedmask);
/* Create the new thread */
word64 = do_syscall_clone_ppc32_linux(
ML_(start_thread_NORETURN), stack, flags, &VG_(threads)[ctid],
child_tidptr, parent_tidptr, NULL
);
/* High half word64 is syscall return value. Low half is
the entire CR, from which we need to extract CR0.SO. */
/* VG_(printf)("word64 = 0x%llx\n", word64); */
res = VG_(mk_SysRes_ppc32_linux)(
/*val*/(UInt)(word64 >> 32),
/*errflag*/ (((UInt)word64) >> 28) & 1
);
VG_(sigprocmask)(VKI_SIG_SETMASK, &savedmask, NULL);
out:
if (sr_isError(res)) {
/* clone failed */
VG_(cleanup_thread)(&ctst->arch);
ctst->status = VgTs_Empty;
/* oops. Better tell the tool the thread exited in a hurry :-) */
VG_TRACK( pre_thread_ll_exit, ctid );
}
return res;
}
/* ---------------------------------------------------------------------
More thread stuff
------------------------------------------------------------------ */
void VG_(cleanup_thread) ( ThreadArchState* arch )
{
}
void setup_child ( /*OUT*/ ThreadArchState *child,
/*IN*/ ThreadArchState *parent )
{
/* We inherit our parent's guest state. */
child->vex = parent->vex;
child->vex_shadow1 = parent->vex_shadow1;
child->vex_shadow2 = parent->vex_shadow2;
}
/* ---------------------------------------------------------------------
PRE/POST wrappers for ppc32/Linux-specific syscalls
------------------------------------------------------------------ */
#define PRE(name) DEFN_PRE_TEMPLATE(ppc32_linux, name)
#define POST(name) DEFN_POST_TEMPLATE(ppc32_linux, name)
/* Add prototypes for the wrappers declared here, so that gcc doesn't
harass us for not having prototypes. Really this is a kludge --
the right thing to do is to make these wrappers 'static' since they
aren't visible outside this file, but that requires even more macro
magic. */
DECL_TEMPLATE(ppc32_linux, sys_mmap);
DECL_TEMPLATE(ppc32_linux, sys_mmap2);
DECL_TEMPLATE(ppc32_linux, sys_stat64);
DECL_TEMPLATE(ppc32_linux, sys_lstat64);
DECL_TEMPLATE(ppc32_linux, sys_fstatat64);
DECL_TEMPLATE(ppc32_linux, sys_fstat64);
DECL_TEMPLATE(ppc32_linux, sys_clone);
DECL_TEMPLATE(ppc32_linux, sys_sigreturn);
DECL_TEMPLATE(ppc32_linux, sys_rt_sigreturn);
DECL_TEMPLATE(ppc32_linux, sys_sigsuspend);
DECL_TEMPLATE(ppc32_linux, sys_spu_create);
DECL_TEMPLATE(ppc32_linux, sys_spu_run);
PRE(sys_mmap)
{
SysRes r;
PRINT("sys_mmap ( %#lx, %llu, %ld, %ld, %ld, %ld )",
ARG1, (ULong)ARG2, ARG3, ARG4, ARG5, ARG6 );
PRE_REG_READ6(long, "mmap",
unsigned long, start, unsigned long, length,
unsigned long, prot, unsigned long, flags,
unsigned long, fd, unsigned long, offset);
r = ML_(generic_PRE_sys_mmap)( tid, ARG1, ARG2, ARG3, ARG4, ARG5,
(Off64T)ARG6 );
SET_STATUS_from_SysRes(r);
}
PRE(sys_mmap2)
{
SysRes r;
// Exactly like old_mmap() except:
// - the file offset is specified in 4K units rather than bytes,
// so that it can be used for files bigger than 2^32 bytes.
PRINT("sys_mmap2 ( %#lx, %llu, %ld, %ld, %ld, %ld )",
ARG1, (ULong)ARG2, ARG3, ARG4, ARG5, ARG6 );
PRE_REG_READ6(long, "mmap2",
unsigned long, start, unsigned long, length,
unsigned long, prot, unsigned long, flags,
unsigned long, fd, unsigned long, offset);
r = ML_(generic_PRE_sys_mmap)( tid, ARG1, ARG2, ARG3, ARG4, ARG5,
4096 * (Off64T)ARG6 );
SET_STATUS_from_SysRes(r);
}
// XXX: lstat64/fstat64/stat64 are generic, but not necessarily
// applicable to every architecture -- I think only to 32-bit archs.
// We're going to need something like linux/core_os32.h for such
// things, eventually, I think. --njn
PRE(sys_stat64)
{
PRINT("sys_stat64 ( %#lx, %#lx )",ARG1,ARG2);
PRE_REG_READ2(long, "stat64", char *, file_name, struct stat64 *, buf);
PRE_MEM_RASCIIZ( "stat64(file_name)", ARG1 );
PRE_MEM_WRITE( "stat64(buf)", ARG2, sizeof(struct vki_stat64) );
}
POST(sys_stat64)
{
POST_MEM_WRITE( ARG2, sizeof(struct vki_stat64) );
}
PRE(sys_lstat64)
{
PRINT("sys_lstat64 ( %#lx(%s), %#lx )",ARG1,(char*)ARG1,ARG2);
PRE_REG_READ2(long, "lstat64", char *, file_name, struct stat64 *, buf);
PRE_MEM_RASCIIZ( "lstat64(file_name)", ARG1 );
PRE_MEM_WRITE( "lstat64(buf)", ARG2, sizeof(struct vki_stat64) );
}
POST(sys_lstat64)
{
vg_assert(SUCCESS);
if (RES == 0) {
POST_MEM_WRITE( ARG2, sizeof(struct vki_stat64) );
}
}
PRE(sys_fstatat64)
{
PRINT("sys_fstatat64 ( %ld, %#lx(%s), %#lx )",ARG1,ARG2,(char*)ARG2,ARG3);
PRE_REG_READ3(long, "fstatat64",
int, dfd, char *, file_name, struct stat64 *, buf);
PRE_MEM_RASCIIZ( "fstatat64(file_name)", ARG2 );
PRE_MEM_WRITE( "fstatat64(buf)", ARG3, sizeof(struct vki_stat64) );
}
POST(sys_fstatat64)
{
POST_MEM_WRITE( ARG3, sizeof(struct vki_stat64) );
}
PRE(sys_fstat64)
{
PRINT("sys_fstat64 ( %ld, %#lx )",ARG1,ARG2);
PRE_REG_READ2(long, "fstat64", unsigned long, fd, struct stat64 *, buf);
PRE_MEM_WRITE( "fstat64(buf)", ARG2, sizeof(struct vki_stat64) );
}
POST(sys_fstat64)
{
POST_MEM_WRITE( ARG2, sizeof(struct vki_stat64) );
}
//.. PRE(old_select, MayBlock)
//.. {
//.. /* struct sel_arg_struct {
//.. unsigned long n;
//.. fd_set *inp, *outp, *exp;
//.. struct timeval *tvp;
//.. };
//.. */
//.. PRE_REG_READ1(long, "old_select", struct sel_arg_struct *, args);
//.. PRE_MEM_READ( "old_select(args)", ARG1, 5*sizeof(UWord) );
//..
//.. {
//.. UInt* arg_struct = (UInt*)ARG1;
//.. UInt a1, a2, a3, a4, a5;
//..
//.. a1 = arg_struct[0];
//.. a2 = arg_struct[1];
//.. a3 = arg_struct[2];
//.. a4 = arg_struct[3];
//.. a5 = arg_struct[4];
//..
//.. PRINT("old_select ( %d, %p, %p, %p, %p )", a1,a2,a3,a4,a5);
//.. if (a2 != (Addr)NULL)
//.. PRE_MEM_READ( "old_select(readfds)", a2, a1/8 /* __FD_SETSIZE/8 */ );
//.. if (a3 != (Addr)NULL)
//.. PRE_MEM_READ( "old_select(writefds)", a3, a1/8 /* __FD_SETSIZE/8 */ );
//.. if (a4 != (Addr)NULL)
//.. PRE_MEM_READ( "old_select(exceptfds)", a4, a1/8 /* __FD_SETSIZE/8 */ );
//.. if (a5 != (Addr)NULL)
//.. PRE_MEM_READ( "old_select(timeout)", a5, sizeof(struct vki_timeval) );
//.. }
//.. }
PRE(sys_clone)
{
UInt cloneflags;
PRINT("sys_clone ( %lx, %#lx, %#lx, %#lx, %#lx )",ARG1,ARG2,ARG3,ARG4,ARG5);
PRE_REG_READ5(int, "clone",
unsigned long, flags,
void *, child_stack,
int *, parent_tidptr,
void *, child_tls,
int *, child_tidptr);
if (ARG1 & VKI_CLONE_PARENT_SETTID) {
PRE_MEM_WRITE("clone(parent_tidptr)", ARG3, sizeof(Int));
if (!VG_(am_is_valid_for_client)(ARG3, sizeof(Int),
VKI_PROT_WRITE)) {
SET_STATUS_Failure( VKI_EFAULT );
return;
}
}
if (ARG1 & (VKI_CLONE_CHILD_SETTID | VKI_CLONE_CHILD_CLEARTID)) {
PRE_MEM_WRITE("clone(child_tidptr)", ARG5, sizeof(Int));
if (!VG_(am_is_valid_for_client)(ARG5, sizeof(Int),
VKI_PROT_WRITE)) {
SET_STATUS_Failure( VKI_EFAULT );
return;
}
}
cloneflags = ARG1;
if (!ML_(client_signal_OK)(ARG1 & VKI_CSIGNAL)) {
SET_STATUS_Failure( VKI_EINVAL );
return;
}
/* Only look at the flags we really care about */
switch (cloneflags & (VKI_CLONE_VM | VKI_CLONE_FS
| VKI_CLONE_FILES | VKI_CLONE_VFORK)) {
case VKI_CLONE_VM | VKI_CLONE_FS | VKI_CLONE_FILES:
/* thread creation */
SET_STATUS_from_SysRes(
do_clone(tid,
ARG1, /* flags */
(Addr)ARG2, /* child SP */
(Int *)ARG3, /* parent_tidptr */
(Int *)ARG5, /* child_tidptr */
(Addr)ARG4)); /* child_tls */
break;
case VKI_CLONE_VFORK | VKI_CLONE_VM: /* vfork */
/* FALLTHROUGH - assume vfork == fork */
cloneflags &= ~(VKI_CLONE_VFORK | VKI_CLONE_VM);
case 0: /* plain fork */
SET_STATUS_from_SysRes(
ML_(do_fork_clone)(tid,
cloneflags, /* flags */
(Int *)ARG3, /* parent_tidptr */
(Int *)ARG5)); /* child_tidptr */
break;
default:
/* should we just ENOSYS? */
VG_(message)(Vg_UserMsg, "Unsupported clone() flags: 0x%lx\n", ARG1);
VG_(message)(Vg_UserMsg, "\n");
VG_(message)(Vg_UserMsg, "The only supported clone() uses are:\n");
VG_(message)(Vg_UserMsg, " - via a threads library (LinuxThreads or NPTL)\n");
VG_(message)(Vg_UserMsg, " - via the implementation of fork or vfork\n");
VG_(unimplemented)
("Valgrind does not support general clone().");
}
if (SUCCESS) {
if (ARG1 & VKI_CLONE_PARENT_SETTID)
POST_MEM_WRITE(ARG3, sizeof(Int));
if (ARG1 & (VKI_CLONE_CHILD_SETTID | VKI_CLONE_CHILD_CLEARTID))
POST_MEM_WRITE(ARG5, sizeof(Int));
/* Thread creation was successful; let the child have the chance
to run */
*flags |= SfYieldAfter;
}
}
PRE(sys_sigreturn)
{
/* See comments on PRE(sys_rt_sigreturn) in syswrap-amd64-linux.c for
an explanation of what follows. */
//ThreadState* tst;
PRINT("sys_sigreturn ( )");
vg_assert(VG_(is_valid_tid)(tid));
vg_assert(tid >= 1 && tid < VG_N_THREADS);
vg_assert(VG_(is_running_thread)(tid));
///* Adjust esp to point to start of frame; skip back up over
// sigreturn sequence's "popl %eax" and handler ret addr */
//tst = VG_(get_ThreadState)(tid);
//tst->arch.vex.guest_ESP -= sizeof(Addr)+sizeof(Word);
// Should we do something equivalent on ppc32? Who knows.
///* This is only so that the EIP is (might be) useful to report if
// something goes wrong in the sigreturn */
//ML_(fixup_guest_state_to_restart_syscall)(&tst->arch);
// Should we do something equivalent on ppc32? Who knows.
/* Restore register state from frame and remove it */
VG_(sigframe_destroy)(tid, False);
/* Tell the driver not to update the guest state with the "result",
and set a bogus result to keep it happy. */
*flags |= SfNoWriteResult;
SET_STATUS_Success(0);
/* Check to see if any signals arose as a result of this. */
*flags |= SfPollAfter;
}
PRE(sys_rt_sigreturn)
{
/* See comments on PRE(sys_rt_sigreturn) in syswrap-amd64-linux.c for
an explanation of what follows. */
//ThreadState* tst;
PRINT("rt_sigreturn ( )");
vg_assert(VG_(is_valid_tid)(tid));
vg_assert(tid >= 1 && tid < VG_N_THREADS);
vg_assert(VG_(is_running_thread)(tid));
///* Adjust esp to point to start of frame; skip back up over handler
// ret addr */
//tst = VG_(get_ThreadState)(tid);
//tst->arch.vex.guest_ESP -= sizeof(Addr);
// Should we do something equivalent on ppc32? Who knows.
///* This is only so that the EIP is (might be) useful to report if
// something goes wrong in the sigreturn */
//ML_(fixup_guest_state_to_restart_syscall)(&tst->arch);
// Should we do something equivalent on ppc32? Who knows.
/* Restore register state from frame and remove it */
VG_(sigframe_destroy)(tid, True);
/* Tell the driver not to update the guest state with the "result",
and set a bogus result to keep it happy. */
*flags |= SfNoWriteResult;
SET_STATUS_Success(0);
/* Check to see if any signals arose as a result of this. */
*flags |= SfPollAfter;
}
//.. PRE(sys_modify_ldt, Special)
//.. {
//.. PRINT("sys_modify_ldt ( %d, %p, %d )", ARG1,ARG2,ARG3);
//.. PRE_REG_READ3(int, "modify_ldt", int, func, void *, ptr,
//.. unsigned long, bytecount);
//..
//.. if (ARG1 == 0) {
//.. /* read the LDT into ptr */
//.. PRE_MEM_WRITE( "modify_ldt(ptr)", ARG2, ARG3 );
//.. }
//.. if (ARG1 == 1 || ARG1 == 0x11) {
//.. /* write the LDT with the entry pointed at by ptr */
//.. PRE_MEM_READ( "modify_ldt(ptr)", ARG2, sizeof(vki_modify_ldt_t) );
//.. }
//.. /* "do" the syscall ourselves; the kernel never sees it */
//.. SET_RESULT( VG_(sys_modify_ldt)( tid, ARG1, (void*)ARG2, ARG3 ) );
//..
//.. if (ARG1 == 0 && !VG_(is_kerror)(RES) && RES > 0) {
//.. POST_MEM_WRITE( ARG2, RES );
//.. }
//.. }
//.. PRE(sys_set_thread_area, Special)
//.. {
//.. PRINT("sys_set_thread_area ( %p )", ARG1);
//.. PRE_REG_READ1(int, "set_thread_area", struct user_desc *, u_info)
//.. PRE_MEM_READ( "set_thread_area(u_info)", ARG1, sizeof(vki_modify_ldt_t) );
//..
//.. /* "do" the syscall ourselves; the kernel never sees it */
//.. SET_RESULT( VG_(sys_set_thread_area)( tid, (void *)ARG1 ) );
//.. }
//.. PRE(sys_get_thread_area, Special)
//.. {
//.. PRINT("sys_get_thread_area ( %p )", ARG1);
//.. PRE_REG_READ1(int, "get_thread_area", struct user_desc *, u_info)
//.. PRE_MEM_WRITE( "get_thread_area(u_info)", ARG1, sizeof(vki_modify_ldt_t) );
//..
//.. /* "do" the syscall ourselves; the kernel never sees it */
//.. SET_RESULT( VG_(sys_get_thread_area)( tid, (void *)ARG1 ) );
//..
//.. if (!VG_(is_kerror)(RES)) {
//.. POST_MEM_WRITE( ARG1, sizeof(vki_modify_ldt_t) );
//.. }
//.. }
//.. // Parts of this are ppc32-specific, but the *PEEK* cases are generic.
//.. // XXX: Why is the memory pointed to by ARG3 never checked?
//.. PRE(sys_ptrace, 0)
//.. {
//.. PRINT("sys_ptrace ( %d, %d, %p, %p )", ARG1,ARG2,ARG3,ARG4);
//.. PRE_REG_READ4(int, "ptrace",
//.. long, request, long, pid, long, addr, long, data);
//.. switch (ARG1) {
//.. case VKI_PTRACE_PEEKTEXT:
//.. case VKI_PTRACE_PEEKDATA:
//.. case VKI_PTRACE_PEEKUSR:
//.. PRE_MEM_WRITE( "ptrace(peek)", ARG4,
//.. sizeof (long));
//.. break;
//.. case VKI_PTRACE_GETREGS:
//.. PRE_MEM_WRITE( "ptrace(getregs)", ARG4,
//.. sizeof (struct vki_user_regs_struct));
//.. break;
//.. case VKI_PTRACE_GETFPREGS:
//.. PRE_MEM_WRITE( "ptrace(getfpregs)", ARG4,
//.. sizeof (struct vki_user_i387_struct));
//.. break;
//.. case VKI_PTRACE_GETFPXREGS:
//.. PRE_MEM_WRITE( "ptrace(getfpxregs)", ARG4,
//.. sizeof(struct vki_user_fxsr_struct) );
//.. break;
//.. case VKI_PTRACE_SETREGS:
//.. PRE_MEM_READ( "ptrace(setregs)", ARG4,
//.. sizeof (struct vki_user_regs_struct));
//.. break;
//.. case VKI_PTRACE_SETFPREGS:
//.. PRE_MEM_READ( "ptrace(setfpregs)", ARG4,
//.. sizeof (struct vki_user_i387_struct));
//.. break;
//.. case VKI_PTRACE_SETFPXREGS:
//.. PRE_MEM_READ( "ptrace(setfpxregs)", ARG4,
//.. sizeof(struct vki_user_fxsr_struct) );
//.. break;
//.. default:
//.. break;
//.. }
//.. }
//.. POST(sys_ptrace)
//.. {
//.. switch (ARG1) {
//.. case VKI_PTRACE_PEEKTEXT:
//.. case VKI_PTRACE_PEEKDATA:
//.. case VKI_PTRACE_PEEKUSR:
//.. POST_MEM_WRITE( ARG4, sizeof (long));
//.. break;
//.. case VKI_PTRACE_GETREGS:
//.. POST_MEM_WRITE( ARG4, sizeof (struct vki_user_regs_struct));
//.. break;
//.. case VKI_PTRACE_GETFPREGS:
//.. POST_MEM_WRITE( ARG4, sizeof (struct vki_user_i387_struct));
//.. break;
//.. case VKI_PTRACE_GETFPXREGS:
//.. POST_MEM_WRITE( ARG4, sizeof(struct vki_user_fxsr_struct) );
//.. break;
//.. default:
//.. break;
//.. }
//.. }
/* NB: This is an almost identical clone of versions for x86-linux and
arm-linux, which are themselves literally identical. */
PRE(sys_sigsuspend)
{
/* The C library interface to sigsuspend just takes a pointer to
a signal mask but this system call only takes the first word of
the signal mask as an argument so only 32 signals are supported.
In fact glibc normally uses rt_sigsuspend if it is available as
that takes a pointer to the signal mask so supports more signals.
*/
*flags |= SfMayBlock;
PRINT("sys_sigsuspend ( %ld )", ARG1 );
PRE_REG_READ1(int, "sigsuspend", vki_old_sigset_t, mask);
}
PRE(sys_spu_create)
{
PRE_MEM_RASCIIZ("stat64(filename)", ARG1);
}
POST(sys_spu_create)
{
vg_assert(SUCCESS);
}
PRE(sys_spu_run)
{
*flags |= SfMayBlock;
if (ARG2 != 0)
PRE_MEM_WRITE("npc", ARG2, sizeof(unsigned int));
PRE_MEM_READ("event", ARG3, sizeof(unsigned int));
}
POST(sys_spu_run)
{
if (ARG2 != 0)
POST_MEM_WRITE(ARG2, sizeof(unsigned int));
}
#undef PRE
#undef POST
/* ---------------------------------------------------------------------
The ppc32/Linux syscall table
------------------------------------------------------------------ */
/* Add an ppc32-linux specific wrapper to a syscall table. */
#define PLAX_(sysno, name) WRAPPER_ENTRY_X_(ppc32_linux, sysno, name)
#define PLAXY(sysno, name) WRAPPER_ENTRY_XY(ppc32_linux, sysno, name)
// This table maps from __NR_xxx syscall numbers (from
// linux/include/asm-ppc/unistd.h) to the appropriate PRE/POST sys_foo()
// wrappers on ppc32 (as per sys_call_table in linux/arch/ppc/kernel/entry.S).
//
// For those syscalls not handled by Valgrind, the annotation indicate its
// arch/OS combination, eg. */* (generic), */Linux (Linux only), ?/?
// (unknown).
static SyscallTableEntry syscall_table[] = {
//.. (restart_syscall) // 0
GENX_(__NR_exit, sys_exit), // 1
GENX_(__NR_fork, sys_fork), // 2
GENXY(__NR_read, sys_read), // 3
GENX_(__NR_write, sys_write), // 4
GENXY(__NR_open, sys_open), // 5
GENXY(__NR_close, sys_close), // 6
GENXY(__NR_waitpid, sys_waitpid), // 7
GENXY(__NR_creat, sys_creat), // 8
GENX_(__NR_link, sys_link), // 9
GENX_(__NR_unlink, sys_unlink), // 10
GENX_(__NR_execve, sys_execve), // 11
GENX_(__NR_chdir, sys_chdir), // 12
GENXY(__NR_time, sys_time), // 13
GENX_(__NR_mknod, sys_mknod), // 14
//..
GENX_(__NR_chmod, sys_chmod), // 15
GENX_(__NR_lchown, sys_lchown), // 16 ## P
//.. GENX_(__NR_break, sys_ni_syscall), // 17
//.. // (__NR_oldstat, sys_stat), // 18 (obsolete)
LINX_(__NR_lseek, sys_lseek), // 19
//..
GENX_(__NR_getpid, sys_getpid), // 20
LINX_(__NR_mount, sys_mount), // 21
LINX_(__NR_umount, sys_oldumount), // 22
GENX_(__NR_setuid, sys_setuid), // 23 ## P
GENX_(__NR_getuid, sys_getuid), // 24 ## P
//..
//.. // (__NR_stime, sys_stime), // 25 * (SVr4,SVID,X/OPEN)
//.. PLAXY(__NR_ptrace, sys_ptrace), // 26
GENX_(__NR_alarm, sys_alarm), // 27
//.. // (__NR_oldfstat, sys_fstat), // 28 * L -- obsolete
GENX_(__NR_pause, sys_pause), // 29
//..
LINX_(__NR_utime, sys_utime), // 30
//.. GENX_(__NR_stty, sys_ni_syscall), // 31
//.. GENX_(__NR_gtty, sys_ni_syscall), // 32
GENX_(__NR_access, sys_access), // 33
//.. GENX_(__NR_nice, sys_nice), // 34
//..
//.. GENX_(__NR_ftime, sys_ni_syscall), // 35
//.. GENX_(__NR_sync, sys_sync), // 36
GENX_(__NR_kill, sys_kill), // 37
GENX_(__NR_rename, sys_rename), // 38
GENX_(__NR_mkdir, sys_mkdir), // 39
GENX_(__NR_rmdir, sys_rmdir), // 40
GENXY(__NR_dup, sys_dup), // 41
LINXY(__NR_pipe, sys_pipe), // 42
GENXY(__NR_times, sys_times), // 43
//.. GENX_(__NR_prof, sys_ni_syscall), // 44
//..
GENX_(__NR_brk, sys_brk), // 45
GENX_(__NR_setgid, sys_setgid), // 46
GENX_(__NR_getgid, sys_getgid), // 47
//.. // (__NR_signal, sys_signal), // 48 */* (ANSI C)
GENX_(__NR_geteuid, sys_geteuid), // 49
GENX_(__NR_getegid, sys_getegid), // 50
//.. GENX_(__NR_acct, sys_acct), // 51
LINX_(__NR_umount2, sys_umount), // 52
//.. GENX_(__NR_lock, sys_ni_syscall), // 53
LINXY(__NR_ioctl, sys_ioctl), // 54
//..
LINXY(__NR_fcntl, sys_fcntl), // 55
//.. GENX_(__NR_mpx, sys_ni_syscall), // 56
GENX_(__NR_setpgid, sys_setpgid), // 57
//.. GENX_(__NR_ulimit, sys_ni_syscall), // 58
//.. // (__NR_oldolduname, sys_olduname), // 59 Linux -- obsolete
GENX_(__NR_umask, sys_umask), // 60
GENX_(__NR_chroot, sys_chroot), // 61
//.. // (__NR_ustat, sys_ustat) // 62 SVr4 -- deprecated
GENXY(__NR_dup2, sys_dup2), // 63
GENX_(__NR_getppid, sys_getppid), // 64
GENX_(__NR_getpgrp, sys_getpgrp), // 65
GENX_(__NR_setsid, sys_setsid), // 66
LINXY(__NR_sigaction, sys_sigaction), // 67
//.. // (__NR_sgetmask, sys_sgetmask), // 68 */* (ANSI C)
//.. // (__NR_ssetmask, sys_ssetmask), // 69 */* (ANSI C)
//..
GENX_(__NR_setreuid, sys_setreuid), // 70
GENX_(__NR_setregid, sys_setregid), // 71
PLAX_(__NR_sigsuspend, sys_sigsuspend), // 72
LINXY(__NR_sigpending, sys_sigpending), // 73
//.. // (__NR_sethostname, sys_sethostname), // 74 */*
//..
GENX_(__NR_setrlimit, sys_setrlimit), // 75
//.. GENXY(__NR_getrlimit, sys_old_getrlimit), // 76
GENXY(__NR_getrusage, sys_getrusage), // 77
GENXY(__NR_gettimeofday, sys_gettimeofday), // 78
//.. GENX_(__NR_settimeofday, sys_settimeofday), // 79
//..
GENXY(__NR_getgroups, sys_getgroups), // 80
GENX_(__NR_setgroups, sys_setgroups), // 81
//.. PLAX_(__NR_select, old_select), // 82
GENX_(__NR_symlink, sys_symlink), // 83
//.. // (__NR_oldlstat, sys_lstat), // 84 -- obsolete
//..
GENX_(__NR_readlink, sys_readlink), // 85
//.. // (__NR_uselib, sys_uselib), // 86 */Linux
//.. // (__NR_swapon, sys_swapon), // 87 */Linux
//.. // (__NR_reboot, sys_reboot), // 88 */Linux
//.. // (__NR_readdir, old_readdir), // 89 -- superseded
PLAX_(__NR_mmap, sys_mmap), // 90
GENXY(__NR_munmap, sys_munmap), // 91
GENX_(__NR_truncate, sys_truncate), // 92
GENX_(__NR_ftruncate, sys_ftruncate), // 93
GENX_(__NR_fchmod, sys_fchmod), // 94
GENX_(__NR_fchown, sys_fchown), // 95
GENX_(__NR_getpriority, sys_getpriority), // 96
GENX_(__NR_setpriority, sys_setpriority), // 97
//.. GENX_(__NR_profil, sys_ni_syscall), // 98
GENXY(__NR_statfs, sys_statfs), // 99
//..
GENXY(__NR_fstatfs, sys_fstatfs), // 100
//.. LINX_(__NR_ioperm, sys_ioperm), // 101
LINXY(__NR_socketcall, sys_socketcall), // 102
LINXY(__NR_syslog, sys_syslog), // 103
GENXY(__NR_setitimer, sys_setitimer), // 104
GENXY(__NR_getitimer, sys_getitimer), // 105
GENXY(__NR_stat, sys_newstat), // 106
GENXY(__NR_lstat, sys_newlstat), // 107
GENXY(__NR_fstat, sys_newfstat), // 108
//.. // (__NR_olduname, sys_uname), // 109 -- obsolete
//..
//.. GENX_(__NR_iopl, sys_iopl), // 110
LINX_(__NR_vhangup, sys_vhangup), // 111
//.. GENX_(__NR_idle, sys_ni_syscall), // 112
//.. // (__NR_vm86old, sys_vm86old), // 113 x86/Linux-only
GENXY(__NR_wait4, sys_wait4), // 114
//..
//.. // (__NR_swapoff, sys_swapoff), // 115 */Linux
LINXY(__NR_sysinfo, sys_sysinfo), // 116
LINXY(__NR_ipc, sys_ipc), // 117
GENX_(__NR_fsync, sys_fsync), // 118
PLAX_(__NR_sigreturn, sys_sigreturn), // 119 ?/Linux
//..
PLAX_(__NR_clone, sys_clone), // 120
//.. // (__NR_setdomainname, sys_setdomainname), // 121 */*(?)
GENXY(__NR_uname, sys_newuname), // 122
//.. PLAX_(__NR_modify_ldt, sys_modify_ldt), // 123
LINXY(__NR_adjtimex, sys_adjtimex), // 124
GENXY(__NR_mprotect, sys_mprotect), // 125
LINXY(__NR_sigprocmask, sys_sigprocmask), // 126
GENX_(__NR_create_module, sys_ni_syscall), // 127
LINX_(__NR_init_module, sys_init_module), // 128
LINX_(__NR_delete_module, sys_delete_module), // 129
//..
//.. // Nb: get_kernel_syms() was removed 2.4-->2.6
//.. GENX_(__NR_get_kernel_syms, sys_ni_syscall), // 130
//.. LINX_(__NR_quotactl, sys_quotactl), // 131
GENX_(__NR_getpgid, sys_getpgid), // 132
GENX_(__NR_fchdir, sys_fchdir), // 133
//.. // (__NR_bdflush, sys_bdflush), // 134 */Linux
//..
//.. // (__NR_sysfs, sys_sysfs), // 135 SVr4
LINX_(__NR_personality, sys_personality), // 136
//.. GENX_(__NR_afs_syscall, sys_ni_syscall), // 137
LINX_(__NR_setfsuid, sys_setfsuid), // 138
LINX_(__NR_setfsgid, sys_setfsgid), // 139
LINXY(__NR__llseek, sys_llseek), // 140
GENXY(__NR_getdents, sys_getdents), // 141
GENX_(__NR__newselect, sys_select), // 142
GENX_(__NR_flock, sys_flock), // 143
GENX_(__NR_msync, sys_msync), // 144
//..
GENXY(__NR_readv, sys_readv), // 145
GENX_(__NR_writev, sys_writev), // 146
GENX_(__NR_getsid, sys_getsid), // 147
GENX_(__NR_fdatasync, sys_fdatasync), // 148
LINXY(__NR__sysctl, sys_sysctl), // 149
//..
GENX_(__NR_mlock, sys_mlock), // 150
GENX_(__NR_munlock, sys_munlock), // 151
GENX_(__NR_mlockall, sys_mlockall), // 152
LINX_(__NR_munlockall, sys_munlockall), // 153
LINXY(__NR_sched_setparam, sys_sched_setparam), // 154
//..
LINXY(__NR_sched_getparam, sys_sched_getparam), // 155
LINX_(__NR_sched_setscheduler, sys_sched_setscheduler), // 156
LINX_(__NR_sched_getscheduler, sys_sched_getscheduler), // 157
LINX_(__NR_sched_yield, sys_sched_yield), // 158
LINX_(__NR_sched_get_priority_max, sys_sched_get_priority_max),// 159
LINX_(__NR_sched_get_priority_min, sys_sched_get_priority_min),// 160
LINXY(__NR_sched_rr_get_interval, sys_sched_rr_get_interval), // 161
GENXY(__NR_nanosleep, sys_nanosleep), // 162
GENX_(__NR_mremap, sys_mremap), // 163
LINX_(__NR_setresuid, sys_setresuid), // 164
LINXY(__NR_getresuid, sys_getresuid), // 165
//.. GENX_(__NR_query_module, sys_ni_syscall), // 166
GENXY(__NR_poll, sys_poll), // 167
//.. // (__NR_nfsservctl, sys_nfsservctl), // 168 */Linux
//..
LINX_(__NR_setresgid, sys_setresgid), // 169
LINXY(__NR_getresgid, sys_getresgid), // 170
LINXY(__NR_prctl, sys_prctl), // 171
PLAX_(__NR_rt_sigreturn, sys_rt_sigreturn), // 172
LINXY(__NR_rt_sigaction, sys_rt_sigaction), // 173
LINXY(__NR_rt_sigprocmask, sys_rt_sigprocmask), // 174
LINXY(__NR_rt_sigpending, sys_rt_sigpending), // 175
LINXY(__NR_rt_sigtimedwait, sys_rt_sigtimedwait), // 176
LINXY(__NR_rt_sigqueueinfo, sys_rt_sigqueueinfo), // 177
LINX_(__NR_rt_sigsuspend, sys_rt_sigsuspend), // 178
GENXY(__NR_pread64, sys_pread64), // 179
GENX_(__NR_pwrite64, sys_pwrite64), // 180
GENX_(__NR_chown, sys_chown), // 181
GENXY(__NR_getcwd, sys_getcwd), // 182
LINXY(__NR_capget, sys_capget), // 183
LINX_(__NR_capset, sys_capset), // 184
GENXY(__NR_sigaltstack, sys_sigaltstack), // 185
LINXY(__NR_sendfile, sys_sendfile), // 186
//.. GENXY(__NR_getpmsg, sys_getpmsg), // 187
//.. GENX_(__NR_putpmsg, sys_putpmsg), // 188
// Nb: we treat vfork as fork
GENX_(__NR_vfork, sys_fork), // 189
GENXY(__NR_ugetrlimit, sys_getrlimit), // 190
LINX_(__NR_readahead, sys_readahead), // 191 */Linux
PLAX_(__NR_mmap2, sys_mmap2), // 192
GENX_(__NR_truncate64, sys_truncate64), // 193
GENX_(__NR_ftruncate64, sys_ftruncate64), // 194
//..
PLAXY(__NR_stat64, sys_stat64), // 195
PLAXY(__NR_lstat64, sys_lstat64), // 196
PLAXY(__NR_fstat64, sys_fstat64), // 197
// __NR_pciconfig_read // 198
// __NR_pciconfig_write // 199
// __NR_pciconfig_iobase // 200
// __NR_multiplexer // 201
GENXY(__NR_getdents64, sys_getdents64), // 202
//.. // (__NR_pivot_root, sys_pivot_root), // 203 */Linux
LINXY(__NR_fcntl64, sys_fcntl64), // 204
GENX_(__NR_madvise, sys_madvise), // 205
GENXY(__NR_mincore, sys_mincore), // 206
LINX_(__NR_gettid, sys_gettid), // 207
//.. LINX_(__NR_tkill, sys_tkill), // 208 */Linux
LINX_(__NR_setxattr, sys_setxattr), // 209
LINX_(__NR_lsetxattr, sys_lsetxattr), // 210
LINX_(__NR_fsetxattr, sys_fsetxattr), // 211
LINXY(__NR_getxattr, sys_getxattr), // 212
LINXY(__NR_lgetxattr, sys_lgetxattr), // 213
LINXY(__NR_fgetxattr, sys_fgetxattr), // 214
LINXY(__NR_listxattr, sys_listxattr), // 215
LINXY(__NR_llistxattr, sys_llistxattr), // 216
LINXY(__NR_flistxattr, sys_flistxattr), // 217
LINX_(__NR_removexattr, sys_removexattr), // 218
LINX_(__NR_lremovexattr, sys_lremovexattr), // 219
LINX_(__NR_fremovexattr, sys_fremovexattr), // 220
LINXY(__NR_futex, sys_futex), // 221
LINX_(__NR_sched_setaffinity, sys_sched_setaffinity), // 222
LINXY(__NR_sched_getaffinity, sys_sched_getaffinity), // 223
/* 224 currently unused */
// __NR_tuxcall // 225
LINXY(__NR_sendfile64, sys_sendfile64), // 226
//..
LINX_(__NR_io_setup, sys_io_setup), // 227
LINX_(__NR_io_destroy, sys_io_destroy), // 228
LINXY(__NR_io_getevents, sys_io_getevents), // 229
LINX_(__NR_io_submit, sys_io_submit), // 230
LINXY(__NR_io_cancel, sys_io_cancel), // 231
//..
LINX_(__NR_set_tid_address, sys_set_tid_address), // 232
LINX_(__NR_fadvise64, sys_fadvise64), // 233 */(Linux?)
LINX_(__NR_exit_group, sys_exit_group), // 234
//.. GENXY(__NR_lookup_dcookie, sys_lookup_dcookie), // 235
LINXY(__NR_epoll_create, sys_epoll_create), // 236
LINX_(__NR_epoll_ctl, sys_epoll_ctl), // 237
LINXY(__NR_epoll_wait, sys_epoll_wait), // 238
//.. // (__NR_remap_file_pages, sys_remap_file_pages), // 239 */Linux
LINXY(__NR_timer_create, sys_timer_create), // 240
LINXY(__NR_timer_settime, sys_timer_settime), // 241
LINXY(__NR_timer_gettime, sys_timer_gettime), // 242
LINX_(__NR_timer_getoverrun, sys_timer_getoverrun), // 243
LINX_(__NR_timer_delete, sys_timer_delete), // 244
LINX_(__NR_clock_settime, sys_clock_settime), // 245
LINXY(__NR_clock_gettime, sys_clock_gettime), // 246
LINXY(__NR_clock_getres, sys_clock_getres), // 247
LINXY(__NR_clock_nanosleep, sys_clock_nanosleep), // 248
// __NR_swapcontext // 249
LINXY(__NR_tgkill, sys_tgkill), // 250 */Linux
//.. GENX_(__NR_utimes, sys_utimes), // 251
GENXY(__NR_statfs64, sys_statfs64), // 252
GENXY(__NR_fstatfs64, sys_fstatfs64), // 253
LINX_(__NR_fadvise64_64, sys_fadvise64_64), // 254 */(Linux?)
// __NR_rtas // 255
/* Number 256 is reserved for sys_debug_setcontext */
/* Number 257 is reserved for vserver */
/* Number 258 is reserved for new sys_remap_file_pages */
LINX_(__NR_mbind, sys_mbind), // 259
LINXY(__NR_get_mempolicy, sys_get_mempolicy), // 260
LINX_(__NR_set_mempolicy, sys_set_mempolicy), // 261
LINXY(__NR_mq_open, sys_mq_open), // 262
LINX_(__NR_mq_unlink, sys_mq_unlink), // 263
LINX_(__NR_mq_timedsend, sys_mq_timedsend), // 264
LINXY(__NR_mq_timedreceive, sys_mq_timedreceive), // 265
LINX_(__NR_mq_notify, sys_mq_notify), // 266
LINXY(__NR_mq_getsetattr, sys_mq_getsetattr), // 267
// __NR_kexec_load // 268
/* Number 269 is reserved for sys_add_key */
/* Number 270 is reserved for sys_request_key */
/* Number 271 is reserved for sys_keyctl */
/* Number 272 is reserved for sys_waitid */
LINX_(__NR_ioprio_set, sys_ioprio_set), // 273
LINX_(__NR_ioprio_get, sys_ioprio_get), // 274
LINX_(__NR_inotify_init, sys_inotify_init), // 275
LINX_(__NR_inotify_add_watch, sys_inotify_add_watch), // 276
LINX_(__NR_inotify_rm_watch, sys_inotify_rm_watch), // 277
PLAXY(__NR_spu_run, sys_spu_run), // 278
PLAX_(__NR_spu_create, sys_spu_create), // 279
LINX_(__NR_pselect6, sys_pselect6), // 280
LINXY(__NR_ppoll, sys_ppoll), // 281
LINXY(__NR_openat, sys_openat), // 286
LINX_(__NR_mkdirat, sys_mkdirat), // 287
LINX_(__NR_mknodat, sys_mknodat), // 288
LINX_(__NR_fchownat, sys_fchownat), // 289
LINX_(__NR_futimesat, sys_futimesat), // 290
PLAXY(__NR_fstatat64, sys_fstatat64), // 291
LINX_(__NR_unlinkat, sys_unlinkat), // 292
LINX_(__NR_renameat, sys_renameat), // 293
LINX_(__NR_linkat, sys_linkat), // 294
LINX_(__NR_symlinkat, sys_symlinkat), // 295
LINX_(__NR_readlinkat, sys_readlinkat), // 296
LINX_(__NR_fchmodat, sys_fchmodat), // 297
LINX_(__NR_faccessat, sys_faccessat), // 298
LINX_(__NR_set_robust_list, sys_set_robust_list), // 299
LINXY(__NR_get_robust_list, sys_get_robust_list), // 300
LINXY(__NR_move_pages, sys_move_pages), // 301
LINXY(__NR_getcpu, sys_getcpu), // 302
LINXY(__NR_epoll_pwait, sys_epoll_pwait), // 303
LINX_(__NR_utimensat, sys_utimensat), // 304
LINXY(__NR_signalfd, sys_signalfd), // 305
LINXY(__NR_timerfd_create, sys_timerfd_create), // 306
LINXY(__NR_eventfd, sys_eventfd), // 307
LINX_(__NR_sync_file_range2, sys_sync_file_range2), // 308
LINX_(__NR_fallocate, sys_fallocate), // 309
// LINXY(__NR_subpage_prot, sys_ni_syscall), // 310
LINXY(__NR_timerfd_settime, sys_timerfd_settime), // 311
LINXY(__NR_timerfd_gettime, sys_timerfd_gettime), // 312
LINXY(__NR_signalfd4, sys_signalfd4), // 313
LINXY(__NR_eventfd2, sys_eventfd2), // 314
LINXY(__NR_epoll_create1, sys_epoll_create1), // 315
LINXY(__NR_dup3, sys_dup3), // 316
LINXY(__NR_pipe2, sys_pipe2), // 317
LINXY(__NR_inotify_init1, sys_inotify_init1), // 318
LINXY(__NR_perf_event_open, sys_perf_event_open), // 319
LINXY(__NR_preadv, sys_preadv), // 320
LINX_(__NR_pwritev, sys_pwritev), // 321
LINXY(__NR_rt_tgsigqueueinfo, sys_rt_tgsigqueueinfo),// 322
LINX_(__NR_clock_adjtime, sys_clock_adjtime), // 347
LINXY(__NR_process_vm_readv, sys_process_vm_readv), // 351
LINX_(__NR_process_vm_writev, sys_process_vm_writev) // 352
};
SyscallTableEntry* ML_(get_linux_syscall_entry) ( UInt sysno )
{
const UInt syscall_table_size
= sizeof(syscall_table) / sizeof(syscall_table[0]);
/* Is it in the contiguous initial section of the table? */
if (sysno < syscall_table_size) {
SyscallTableEntry* sys = &syscall_table[sysno];
if (sys->before == NULL)
return NULL; /* no entry */
else
return sys;
}
/* Can't find a wrapper */
return NULL;
}
#endif // defined(VGP_ppc32_linux)
/*--------------------------------------------------------------------*/
/*--- end ---*/
/*--------------------------------------------------------------------*/
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