zenithsiz/ftmemsim-valgrind
1
0
Fork 0
mirror of https://github.com/Zenithsiz/ftmemsim-valgrind.git synced 2026-02-08 04:55:52 +00:00
Code Issues Actions Packages Projects Releases Wiki Activity
ftmemsim-valgrind/coregrind/m_syswrap/syswrap-amd64-linux.c
Julian Seward cc8ccbbfb4 This commit merges in changes from branches/ASPACEM (specifically, 
changes from r4341 through r4787 inclusive).  That branch is now dead.
Please do not commit anything else to it.

For the most part the merge was not troublesome.  The main areas of
uncertainty are:

- build system: I had to import by hand Makefile.core-AM_CPPFLAGS.am
  and include it in a couple of places.  Building etc seems to still
  work, but I haven't tried building the documentation.

- syscall wrappers: Following analysis by Greg & Nick, a whole lot of
  stuff was moved from -generic to -linux after the branch was created.
  I think that is satisfactorily glued back together now.

- Regtests: although this appears to work, no .out files appear, which
  is strange, and makes it hard to diagnose regtest failures.  In
  particular memcheck/tests/x86/scalar.stderr.exp remains in a 
  conflicted state.

- amd64 is broken (slightly), and ppc32 will be unbuildable.  I'll
  attend to the former shortly.



git-svn-id: svn://svn.valgrind.org/valgrind/trunk@4789
2005-09-27 19:20:21 +00:00

1482 lines
52 KiB
C
Raw Blame History

/*--------------------------------------------------------------------*/
/*--- Platform-specific syscalls stuff. syswrap-amd64-linux.c ---*/
/*--------------------------------------------------------------------*/
/*
This file is part of Valgrind, a dynamic binary instrumentation
framework.
Copyright (C) 2000-2005 Nicholas Nethercote
njn@valgrind.org
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.
*/
#include "pub_core_basics.h"
#include "pub_core_threadstate.h"
#include "pub_core_aspacemgr.h"
#include "pub_core_debuglog.h"
#include "pub_core_options.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_main.h"
#include "pub_core_scheduler.h"
#include "pub_core_sigframe.h"
#include "pub_core_signals.h"
#include "pub_core_syscall.h"
#include "pub_core_syswrap.h"
#include "pub_core_tooliface.h"
#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"
#include "vki_unistd.h" /* for the __NR_* constants */
/* ---------------------------------------------------------------------
Stacks, thread wrappers
Note. Why is this stuff here?
------------------------------------------------------------------ */
/* Allocate a stack for this thread. They're allocated lazily, and
never freed. */
/* Allocate a stack for this thread, if it doesn't already have one.
Returns the initial stack pointer value to use, or 0 if allocation
failed. */
static Addr allocstack(ThreadId tid)
{
ThreadState* tst = VG_(get_ThreadState)(tid);
VgStack* stack;
Addr initial_SP;
/* Either the stack_base and stack_init_SP are both zero (in which
case a stack hasn't been allocated) or they are both non-zero,
in which case it has. */
if (tst->os_state.valgrind_stack_base == 0)
vg_assert(tst->os_state.valgrind_stack_init_SP == 0);
if (tst->os_state.valgrind_stack_base != 0)
vg_assert(tst->os_state.valgrind_stack_init_SP != 0);
/* If no stack is present, allocate one. */
if (tst->os_state.valgrind_stack_base == 0) {
stack = VG_(am_alloc_VgStack)( &initial_SP );
if (stack) {
tst->os_state.valgrind_stack_base = (Addr)stack;
tst->os_state.valgrind_stack_init_SP = initial_SP;
}
}
if (0)
VG_(printf)( "stack for tid %d at %p; init_SP=%p\n",
tid,
(void*)tst->os_state.valgrind_stack_base,
(void*)tst->os_state.valgrind_stack_init_SP );
return tst->os_state.valgrind_stack_init_SP;
}
/* Run a thread all the way to the end, then do appropriate exit actions
(this is the last-one-out-turn-off-the-lights bit).
*/
static void run_a_thread_NORETURN ( Word tidW )
{
ThreadId tid = (ThreadId)tidW;
VG_(debugLog)(1, "syswrap-amd64-linux",
"run_a_thread_NORETURN(tid=%lld): "
"ML_(thread_wrapper) called\n",
(ULong)tidW);
/* Run the thread all the way through. */
VgSchedReturnCode src = ML_(thread_wrapper)(tid);
VG_(debugLog)(1, "syswrap-amd64-linux",
"run_a_thread_NORETURN(tid=%lld): "
"ML_(thread_wrapper) done\n",
(ULong)tidW);
Int c = VG_(count_living_threads)();
vg_assert(c >= 1); /* stay sane */
if (c == 1) {
VG_(debugLog)(1, "syswrap-amd64-linux",
"run_a_thread_NORETURN(tid=%lld): "
"last one standing\n",
(ULong)tidW);
/* We are the last one standing. Keep hold of the lock and
carry on to show final tool results, then exit the entire system. */
VG_(shutdown_actions_NORETURN)(tid, src);
} else {
VG_(debugLog)(1, "syswrap-amd64-linux",
"run_a_thread_NORETURN(tid=%lld): "
"not last one standing\n",
(ULong)tidW);
/* OK, thread is dead, but others still exist. Just exit. */
ThreadState *tst = VG_(get_ThreadState)(tid);
/* This releases the run lock */
VG_(exit_thread)(tid);
vg_assert(tst->status == VgTs_Zombie);
/* We have to use this sequence to terminate the thread to
prevent a subtle race. If VG_(exit_thread)() had left the
ThreadState as Empty, then it could have been reallocated,
reusing the stack while we're doing these last cleanups.
Instead, VG_(exit_thread) leaves it as Zombie to prevent
reallocation. We need to make sure we don't touch the stack
between marking it Empty and exiting. Hence the
assembler. */
asm volatile (
"movl %1, %0\n" /* set tst->status = VgTs_Empty */
"movq %2, %%rax\n" /* set %rax = __NR_exit */
"movq %3, %%rdi\n" /* set %rdi = tst->os_state.exitcode */
"syscall\n" /* exit(tst->os_state.exitcode) */
: "=m" (tst->status)
: "n" (VgTs_Empty), "n" (__NR_exit), "m" (tst->os_state.exitcode));
VG_(core_panic)("Thread exit failed?\n");
}
/*NOTREACHED*/
vg_assert(0);
}
/* 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 call_on_new_stack_0_1 ( Addr stack,
Addr retaddr,
void (*f)(Word),
Word arg1 );
// %rdi == stack
// %rsi == retaddr
// %rdx == f
// %rcx == arg1
asm(
"call_on_new_stack_0_1:\n"
" movq %rdi, %rsp\n" // set stack
" pushq %rsi\n" // retaddr to stack
" pushq %rdx\n" // f to stack
" pushq %rcx\n" // arg1 to stack
" movq $0, %rax\n" // zero all GP regs
" movq $0, %rbx\n"
" movq $0, %rcx\n"
" movq $0, %rdx\n"
" movq $0, %rsi\n"
" movq $0, %rdi\n"
" movq $0, %rbp\n"
" movq $0, %r8\n"
" movq $0, %r9\n"
" movq $0, %r10\n"
" movq $0, %r11\n"
" movq $0, %r12\n"
" movq $0, %r13\n"
" movq $0, %r14\n"
" movq $0, %r15\n"
" popq %rdi\n" // arg1 to correct arg reg
" ret\n" // jump to f
" ud2\n" // should never get here
);
/*
Allocate a stack for the main thread, and run it all the way to the
end.
*/
void VG_(main_thread_wrapper_NORETURN)(ThreadId tid)
{
VG_(debugLog)(1, "syswrap-amd64-linux",
"entering VG_(main_thread_wrapper_NORETURN)\n");
Addr rsp = allocstack(tid);
/* If we can't even allocate the first thread's stack, we're hosed.
Give up. */
vg_assert2(rsp != 0, "Cannot allocate main thread's stack.");
/* shouldn't be any other threads around yet */
vg_assert( VG_(count_living_threads)() == 1 );
call_on_new_stack_0_1(
(Addr)rsp, /* stack */
0, /*bogus return address*/
run_a_thread_NORETURN, /* fn to call */
(Word)tid /* arg to give it */
);
/*NOTREACHED*/
vg_assert(0);
}
static Long start_thread_NORETURN ( void* arg )
{
ThreadState* tst = (ThreadState*)arg;
ThreadId tid = tst->tid;
run_a_thread_NORETURN ( (Word)tid );
/*NOTREACHED*/
vg_assert(0);
}
/* ---------------------------------------------------------------------
clone() handling
------------------------------------------------------------------ */
/*
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 %rdi
void* child_stack in %rsi
int flags in %rdx
void* arg in %rcx
pid_t* child_tid in %r8
pid_t* parent_tid in %r9
void* tls_ptr at 8(%rsp)
System call requires:
int $__NR_clone in %rax
int flags in %rdi
void* child_stack in %rsi
pid_t* parent_tid in %rdx
pid_t* child_tid in %r10
void* tls_ptr in %r8
Returns a Long encoded in the linux-amd64 way, not a SysRes.
*/
#define STRINGIFZ(__str) #__str
#define STRINGIFY(__str) STRINGIFZ(__str)
#define __NR_CLONE STRINGIFY(__NR_clone)
#define __NR_EXIT STRINGIFY(__NR_exit)
extern
Long do_syscall_clone_amd64_linux ( Long (*fn)(void *),
void* stack,
Long flags,
void* arg,
Long* child_tid,
Long* parent_tid,
vki_modify_ldt_t * );
asm(
"\n"
"do_syscall_clone_amd64_linux:\n"
// set up child stack, temporarily preserving fn and arg
" subq $16, %rsi\n" // make space on stack
" movq %rcx, 8(%rsi)\n" // save arg
" movq %rdi, 0(%rsi)\n" // save fn
// setup syscall
" movq $"__NR_CLONE", %rax\n" // syscall number
" movq %rdx, %rdi\n" // syscall arg1: flags
// %rsi already setup // syscall arg2: child_stack
" movq %r9, %rdx\n" // syscall arg3: parent_tid
" movq %r8, %r10\n" // syscall arg4: child_tid
" movq 8(%rsp), %r8\n" // syscall arg5: tls_ptr
" syscall\n" // clone()
" testq %rax, %rax\n" // child if retval == 0
" jnz 1f\n"
// CHILD - call thread function
" pop %rax\n" // pop fn
" pop %rdi\n" // pop fn arg1: arg
" call *%rax\n" // call fn
// exit with result
" movq %rax, %rdi\n" // arg1: return value from fn
" movq $"__NR_EXIT", %rax\n"
" syscall\n"
// Exit returned?!
" ud2\n"
"1:\n" // PARENT or ERROR
" ret\n"
);
#undef __NR_CLONE
#undef __NR_EXIT
#undef STRINGIFY
#undef STRINGIFZ
// forward declaration
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 EIP, and a separate stack
for ESP.
*/
static SysRes do_clone ( ThreadId ptid,
ULong flags, Addr rsp,
Long* parent_tidptr,
Long* child_tidptr,
Addr tlsaddr )
{
static const Bool debug = False;
ThreadId ctid = VG_(alloc_ThreadState)();
ThreadState* ptst = VG_(get_ThreadState)(ptid);
ThreadState* ctst = VG_(get_ThreadState)(ctid);
UWord* stack;
NSegment* seg;
SysRes res;
Long rax;
vki_sigset_t blockall, savedmask;
VG_(sigfillset)(&blockall);
vg_assert(VG_(is_running_thread)(ptid));
vg_assert(VG_(is_valid_tid)(ctid));
stack = (UWord*)allocstack(ctid);
if (stack == NULL) {
res = VG_(mk_SysRes_Error)( VKI_ENOMEM );
goto out;
}
/* 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 rsp for the new thread, then
it actually gets a copy of the parent's rsp.
*/
setup_child( &ctst->arch, &ptst->arch );
/* Make sys_clone appear to have returned Success(0) in the
child. */
ctst->arch.vex.guest_RAX = 0;
if (rsp != 0)
ctst->arch.vex.guest_RSP = rsp;
ctst->os_state.parent = ptid;
/* inherit signal mask */
ctst->sig_mask = ptst->sig_mask;
ctst->tmp_sig_mask = ptst->sig_mask;
/* We don't really know where the client stack is, because its
allocated by the client. The best we can do is look at the
memory mappings and try to derive some useful information. We
assume that esp starts near its highest possible value, and can
only go down to the start of the mmaped segment. */
seg = VG_(am_find_nsegment)((Addr)rsp);
if (seg && seg->kind != SkResvn) {
ctst->client_stack_highest_word = (Addr)VG_PGROUNDUP(rsp);
ctst->client_stack_szB = ctst->client_stack_highest_word - seg->start;
if (debug)
VG_(printf)("tid %d: guessed client stack range %p-%p\n",
ctid, seg->start, VG_PGROUNDUP(rsp));
} else {
VG_(message)(Vg_UserMsg, "!? New thread %d starts with RSP(%p) unmapped\n",
ctid, rsp);
ctst->client_stack_szB = 0;
}
if (flags & VKI_CLONE_SETTLS) {
if (debug)
VG_(printf)("clone child has SETTLS: tls at %p\n", tlsaddr);
ctst->arch.vex.guest_FS_ZERO = tlsaddr;
}
flags &= ~VKI_CLONE_SETTLS;
/* start the thread with everything blocked */
VG_(sigprocmask)(VKI_SIG_SETMASK, &blockall, &savedmask);
/* Create the new thread */
rax = do_syscall_clone_amd64_linux(
start_thread_NORETURN, stack, flags, &VG_(threads)[ctid],
child_tidptr, parent_tidptr, NULL
);
res = VG_(mk_SysRes_amd64_linux)( rax );
VG_(sigprocmask)(VKI_SIG_SETMASK, &savedmask, NULL);
out:
if (res.isError) {
/* clone failed */
VG_(cleanup_thread)(&ctst->arch);
ctst->status = VgTs_Empty;
}
return res;
}
/* Do a clone which is really a fork() */
static SysRes do_fork_clone ( ThreadId tid,
ULong flags, Addr rsp,
Long* parent_tidptr,
Long* child_tidptr )
{
vki_sigset_t fork_saved_mask;
vki_sigset_t mask;
SysRes res;
if (flags & (VKI_CLONE_SETTLS | VKI_CLONE_FS | VKI_CLONE_VM
| VKI_CLONE_FILES | VKI_CLONE_VFORK))
return VG_(mk_SysRes_Error)( VKI_EINVAL );
/* Block all signals during fork, so that we can fix things up in
the child without being interrupted. */
VG_(sigfillset)(&mask);
VG_(sigprocmask)(VKI_SIG_SETMASK, &mask, &fork_saved_mask);
/* Since this is the fork() form of clone, we don't need all that
VG_(clone) stuff - note that the last two arguments are the
opposite way round to x86 and ppc32 as the amd64 kernel expects
the arguments in a different order */
res = VG_(do_syscall5)( __NR_clone, flags,
(UWord)NULL, (UWord)parent_tidptr,
(UWord)child_tidptr, (UWord)NULL );
if (!res.isError && res.val == 0) {
/* child */
VG_(do_atfork_child)(tid);
/* restore signal mask */
VG_(sigprocmask)(VKI_SIG_SETMASK, &fork_saved_mask, NULL);
}
else
if (!res.isError && res.val > 0) {
/* parent */
if (VG_(clo_trace_syscalls))
VG_(printf)(" clone(fork): process %d created child %d\n",
VG_(getpid)(), res.val);
/* restore signal mask */
VG_(sigprocmask)(VKI_SIG_SETMASK, &fork_saved_mask, NULL);
}
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_shadow = parent->vex_shadow;
}
/* ---------------------------------------------------------------------
PRE/POST wrappers for AMD64/Linux-specific syscalls
------------------------------------------------------------------ */
#define PRE(name) DEFN_PRE_TEMPLATE(amd64_linux, name)
#define POST(name) DEFN_POST_TEMPLATE(amd64_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(amd64_linux, sys_clone);
DECL_TEMPLATE(amd64_linux, sys_rt_sigreturn);
DECL_TEMPLATE(amd64_linux, sys_socket);
DECL_TEMPLATE(amd64_linux, sys_setsockopt);
DECL_TEMPLATE(amd64_linux, sys_getsockopt);
DECL_TEMPLATE(amd64_linux, sys_connect);
DECL_TEMPLATE(amd64_linux, sys_accept);
DECL_TEMPLATE(amd64_linux, sys_sendto);
DECL_TEMPLATE(amd64_linux, sys_recvfrom);
DECL_TEMPLATE(amd64_linux, sys_sendmsg);
DECL_TEMPLATE(amd64_linux, sys_recvmsg);
DECL_TEMPLATE(amd64_linux, sys_shutdown);
DECL_TEMPLATE(amd64_linux, sys_bind);
DECL_TEMPLATE(amd64_linux, sys_listen);
DECL_TEMPLATE(amd64_linux, sys_getsockname);
DECL_TEMPLATE(amd64_linux, sys_getpeername);
DECL_TEMPLATE(amd64_linux, sys_socketpair);
DECL_TEMPLATE(amd64_linux, sys_semget);
DECL_TEMPLATE(amd64_linux, sys_semop);
DECL_TEMPLATE(amd64_linux, sys_semtimedop);
DECL_TEMPLATE(amd64_linux, sys_semctl);
DECL_TEMPLATE(amd64_linux, sys_msgget);
DECL_TEMPLATE(amd64_linux, sys_msgrcv);
DECL_TEMPLATE(amd64_linux, sys_msgsnd);
DECL_TEMPLATE(amd64_linux, sys_msgctl);
DECL_TEMPLATE(amd64_linux, sys_shmget);
DECL_TEMPLATE(amd64_linux, wrap_sys_shmat);
DECL_TEMPLATE(amd64_linux, sys_shmdt);
DECL_TEMPLATE(amd64_linux, sys_shmdt);
DECL_TEMPLATE(amd64_linux, sys_shmctl);
DECL_TEMPLATE(amd64_linux, sys_arch_prctl);
DECL_TEMPLATE(amd64_linux, sys_ptrace);
DECL_TEMPLATE(amd64_linux, sys_pread64);
DECL_TEMPLATE(amd64_linux, sys_pwrite64);
DECL_TEMPLATE(amd64_linux, sys_fadvise64);
PRE(sys_clone)
{
ULong cloneflags;
PRINT("sys_clone ( %x, %p, %p, %p, %p )",ARG1,ARG2,ARG3,ARG4,ARG5);
PRE_REG_READ5(int, "clone",
unsigned long, flags,
void *, child_stack,
int *, parent_tidptr,
int *, child_tidptr,
void *, tlsaddr);
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)", ARG4, sizeof(Int));
if (!VG_(am_is_valid_for_client)(ARG4, 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 ESP */
(Long *)ARG3, /* parent_tidptr */
(Long *)ARG4, /* child_tidptr */
(Addr)ARG5)); /* set_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(
do_fork_clone(tid,
cloneflags, /* flags */
(Addr)ARG2, /* child ESP */
(Long *)ARG3, /* parent_tidptr */
(Long *)ARG4)); /* child_tidptr */
break;
default:
/* should we just ENOSYS? */
VG_(message)(Vg_UserMsg, "Unsupported clone() flags: 0x%x", ARG1);
VG_(message)(Vg_UserMsg, "");
VG_(message)(Vg_UserMsg, "The only supported clone() uses are:");
VG_(message)(Vg_UserMsg, " - via a threads library (LinuxThreads or NPTL)");
VG_(message)(Vg_UserMsg, " - via the implementation of fork or vfork");
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(ARG4, sizeof(Int));
/* Thread creation was successful; let the child have the chance
to run */
*flags |= SfYieldAfter;
}
}
PRE(sys_rt_sigreturn)
{
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_RSP -= sizeof(Addr);
/* This is only so that the RIP is (might be) useful to report if
something goes wrong in the sigreturn */
ML_(fixup_guest_state_to_restart_syscall)(&tst->arch);
VG_(sigframe_destroy)(tid, True);
/* For unclear reasons, it appears we need the syscall to return
without changing %RAX. Since %RAX is the return value, and can
denote either success or failure, we must set up so that the
driver logic copies it back unchanged. Also, note %RAX is of
the guest registers written by VG_(sigframe_destroy). */
SET_STATUS_from_SysRes( VG_(mk_SysRes_amd64_linux)( tst->arch.vex.guest_RAX ) );
/* Check to see if some any signals arose as a result of this. */
*flags |= SfPollAfter;
}
PRE(sys_arch_prctl)
{
ThreadState* tst;
PRINT( "arch_prctl ( %d, %llx )", ARG1, ARG2 );
vg_assert(VG_(is_valid_tid)(tid));
vg_assert(tid >= 1 && tid < VG_N_THREADS);
vg_assert(VG_(is_running_thread)(tid));
// Nb: can't use "ARG2".."ARG5" here because that's our own macro...
PRE_REG_READ2(long, "arch_prctl",
int, option, unsigned long, arg2);
// XXX: totally wrong... we need to look at the 'option' arg, and do
// PRE_MEM_READs/PRE_MEM_WRITEs as necessary...
/* "do" the syscall ourselves; the kernel never sees it */
if (ARG1 == VKI_ARCH_SET_FS) {
tst = VG_(get_ThreadState)(tid);
tst->arch.vex.guest_FS_ZERO = ARG2;
}
else if (ARG1 == VKI_ARCH_GET_FS) {
PRE_MEM_WRITE("arch_prctl(addr)", ARG2, sizeof(unsigned long));
tst = VG_(get_ThreadState)(tid);
*(unsigned long *)ARG2 = tst->arch.vex.guest_FS_ZERO;
POST_MEM_WRITE(ARG2, sizeof(unsigned long));
}
else {
VG_(core_panic)("Unsupported arch_prtctl option");
}
/* Note; the Status writeback to guest state that happens after
this wrapper returns does not change guest_FS_ZERO; hence that
direct assignment to the guest state is safe here. */
SET_STATUS_Success( 0 );
}
// Parts of this are amd64-specific, but the *PEEK* cases are generic.
// XXX: Why is the memory pointed to by ARG3 never checked?
PRE(sys_ptrace)
{
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_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;
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;
default:
break;
}
}
PRE(sys_socket)
{
PRINT("sys_socket ( %d, %d, %d )",ARG1,ARG2,ARG3);
PRE_REG_READ3(long, "socket", int, domain, int, type, int, protocol);
}
POST(sys_socket)
{
SysRes r;
vg_assert(SUCCESS);
r = ML_(generic_POST_sys_socket)(tid, VG_(mk_SysRes_Success)(RES));
SET_STATUS_from_SysRes(r);
}
PRE(sys_setsockopt)
{
PRINT("sys_setsockopt ( %d, %d, %d, %p, %d )",ARG1,ARG2,ARG3,ARG4,ARG5);
PRE_REG_READ5(long, "setsockopt",
int, s, int, level, int, optname,
const void *, optval, int, optlen);
ML_(generic_PRE_sys_setsockopt)(tid, ARG1,ARG2,ARG3,ARG4,ARG5);
}
PRE(sys_getsockopt)
{
PRINT("sys_getsockopt ( %d, %d, %d, %p, %p )",ARG1,ARG2,ARG3,ARG4,ARG5);
PRE_REG_READ5(long, "getsockopt",
int, s, int, level, int, optname,
void *, optval, int, *optlen);
ML_(generic_PRE_sys_getsockopt)(tid, ARG1,ARG2,ARG3,ARG4,ARG5);
}
POST(sys_getsockopt)
{
vg_assert(SUCCESS);
ML_(generic_POST_sys_getsockopt)(tid, VG_(mk_SysRes_Success)(RES),
ARG1,ARG2,ARG3,ARG4,ARG5);
}
PRE(sys_connect)
{
*flags |= SfMayBlock;
PRINT("sys_connect ( %d, %p, %d )",ARG1,ARG2,ARG3);
PRE_REG_READ3(long, "connect",
int, sockfd, struct sockaddr *, serv_addr, int, addrlen);
ML_(generic_PRE_sys_connect)(tid, ARG1,ARG2,ARG3);
}
PRE(sys_accept)
{
*flags |= SfMayBlock;
PRINT("sys_accept ( %d, %p, %d )",ARG1,ARG2,ARG3);
PRE_REG_READ3(long, "accept",
int, s, struct sockaddr *, addr, int, *addrlen);
ML_(generic_PRE_sys_accept)(tid, ARG1,ARG2,ARG3);
}
POST(sys_accept)
{
SysRes r;
vg_assert(SUCCESS);
r = ML_(generic_POST_sys_accept)(tid, VG_(mk_SysRes_Success)(RES),
ARG1,ARG2,ARG3);
SET_STATUS_from_SysRes(r);
}
PRE(sys_sendto)
{
*flags |= SfMayBlock;
PRINT("sys_sendto ( %d, %s, %d, %u, %p, %d )",ARG1,ARG2,ARG3,ARG4,ARG5,ARG6);
PRE_REG_READ6(long, "sendto",
int, s, const void *, msg, int, len,
unsigned int, flags,
const struct sockaddr *, to, int, tolen);
ML_(generic_PRE_sys_sendto)(tid, ARG1,ARG2,ARG3,ARG4,ARG5,ARG6);
}
PRE(sys_recvfrom)
{
*flags |= SfMayBlock;
PRINT("sys_recvfrom ( %d, %p, %d, %u, %p, %p )",ARG1,ARG2,ARG3,ARG4,ARG5,ARG6);
PRE_REG_READ6(long, "recvfrom",
int, s, void *, buf, int, len, unsigned int, flags,
struct sockaddr *, from, int *, fromlen);
ML_(generic_PRE_sys_recvfrom)(tid, ARG1,ARG2,ARG3,ARG4,ARG5,ARG6);
}
POST(sys_recvfrom)
{
vg_assert(SUCCESS);
ML_(generic_POST_sys_recvfrom)(tid, VG_(mk_SysRes_Success)(RES),
ARG1,ARG2,ARG3,ARG4,ARG5,ARG6);
}
PRE(sys_sendmsg)
{
*flags |= SfMayBlock;
PRINT("sys_sendmsg ( %d, %p, %d )",ARG1,ARG2,ARG3);
PRE_REG_READ3(long, "sendmsg",
int, s, const struct msghdr *, msg, int, flags);
ML_(generic_PRE_sys_sendmsg)(tid, ARG1,ARG2);
}
PRE(sys_recvmsg)
{
*flags |= SfMayBlock;
PRINT("sys_recvmsg ( %d, %p, %d )",ARG1,ARG2,ARG3);
PRE_REG_READ3(long, "recvmsg", int, s, struct msghdr *, msg, int, flags);
ML_(generic_PRE_sys_recvmsg)(tid, ARG1,ARG2);
}
POST(sys_recvmsg)
{
ML_(generic_POST_sys_recvmsg)(tid, ARG1,ARG2);
}
PRE(sys_shutdown)
{
*flags |= SfMayBlock;
PRINT("sys_shutdown ( %d, %d )",ARG1,ARG2);
PRE_REG_READ2(int, "shutdown", int, s, int, how);
}
PRE(sys_bind)
{
PRINT("sys_bind ( %d, %p, %d )",ARG1,ARG2,ARG3);
PRE_REG_READ3(long, "bind",
int, sockfd, struct sockaddr *, my_addr, int, addrlen);
ML_(generic_PRE_sys_bind)(tid, ARG1,ARG2,ARG3);
}
PRE(sys_listen)
{
PRINT("sys_listen ( %d, %d )",ARG1,ARG2);
PRE_REG_READ2(long, "listen", int, s, int, backlog);
}
PRE(sys_getsockname)
{
PRINT("sys_getsockname ( %d, %p, %p )",ARG1,ARG2,ARG3);
PRE_REG_READ3(long, "getsockname",
int, s, struct sockaddr *, name, int *, namelen);
ML_(generic_PRE_sys_getsockname)(tid, ARG1,ARG2,ARG3);
}
POST(sys_getsockname)
{
vg_assert(SUCCESS);
ML_(generic_POST_sys_getsockname)(tid, VG_(mk_SysRes_Success)(RES),
ARG1,ARG2,ARG3);
}
PRE(sys_getpeername)
{
PRINT("sys_getpeername ( %d, %p, %p )",ARG1,ARG2,ARG3);
PRE_REG_READ3(long, "getpeername",
int, s, struct sockaddr *, name, int *, namelen);
ML_(generic_PRE_sys_getpeername)(tid, ARG1,ARG2,ARG3);
}
POST(sys_getpeername)
{
vg_assert(SUCCESS);
ML_(generic_POST_sys_getpeername)(tid, VG_(mk_SysRes_Success)(RES),
ARG1,ARG2,ARG3);
}
PRE(sys_socketpair)
{
PRINT("sys_socketpair ( %d, %d, %d, %p )",ARG1,ARG2,ARG3,ARG4);
PRE_REG_READ4(long, "socketpair",
int, d, int, type, int, protocol, int [2], sv);
ML_(generic_PRE_sys_socketpair)(tid, ARG1,ARG2,ARG3,ARG4);
}
POST(sys_socketpair)
{
vg_assert(SUCCESS);
ML_(generic_POST_sys_socketpair)(tid, VG_(mk_SysRes_Success)(RES),
ARG1,ARG2,ARG3,ARG4);
}
PRE(sys_semget)
{
PRINT("sys_semget ( %d, %d, %d )",ARG1,ARG2,ARG3);
PRE_REG_READ3(long, "semget", vki_key_t, key, int, nsems, int, semflg);
}
PRE(sys_semop)
{
*flags |= SfMayBlock;
PRINT("sys_semop ( %d, %p, %u )",ARG1,ARG2,ARG3);
PRE_REG_READ3(long, "semop",
int, semid, struct sembuf *, sops, unsigned, nsoops);
ML_(generic_PRE_sys_semop)(tid, ARG1,ARG2,ARG3);
}
PRE(sys_semtimedop)
{
*flags |= SfMayBlock;
PRINT("sys_semtimedop ( %d, %p, %u, %p )",ARG1,ARG2,ARG3,ARG4);
PRE_REG_READ4(long, "semtimedop",
int, semid, struct sembuf *, sops, unsigned, nsoops,
struct timespec *, timeout);
ML_(generic_PRE_sys_semtimedop)(tid, ARG1,ARG2,ARG3,ARG4);
}
PRE(sys_semctl)
{
switch (ARG3 & ~VKI_IPC_64) {
case VKI_IPC_INFO:
case VKI_SEM_INFO:
PRINT("sys_semctl ( %d, %d, %d, %p )",ARG1,ARG2,ARG3,ARG4);
PRE_REG_READ4(long, "semctl",
int, semid, int, semnum, int, cmd, struct seminfo *, arg);
break;
case VKI_IPC_STAT:
case VKI_SEM_STAT:
case VKI_IPC_SET:
PRINT("sys_semctl ( %d, %d, %d, %p )",ARG1,ARG2,ARG3,ARG4);
PRE_REG_READ4(long, "semctl",
int, semid, int, semnum, int, cmd, struct semid_ds *, arg);
break;
case VKI_GETALL:
case VKI_SETALL:
PRINT("sys_semctl ( %d, %d, %d, %p )",ARG1,ARG2,ARG3,ARG4);
PRE_REG_READ4(long, "semctl",
int, semid, int, semnum, int, cmd, unsigned short *, arg);
break;
default:
PRINT("sys_semctl ( %d, %d, %d )",ARG1,ARG2,ARG3);
PRE_REG_READ3(long, "semctl",
int, semid, int, semnum, int, cmd);
break;
}
ML_(generic_PRE_sys_semctl)(tid, ARG1,ARG2,ARG3,ARG4);
}
POST(sys_semctl)
{
ML_(generic_POST_sys_semctl)(tid, RES,ARG1,ARG2,ARG3,ARG4);
}
PRE(sys_msgget)
{
PRINT("sys_msgget ( %d, %d )",ARG1,ARG2);
PRE_REG_READ2(long, "msgget", vki_key_t, key, int, msgflg);
}
PRE(sys_msgsnd)
{
PRINT("sys_msgsnd ( %d, %p, %d, %d )",ARG1,ARG2,ARG3,ARG4);
PRE_REG_READ4(long, "msgsnd",
int, msqid, struct msgbuf *, msgp, vki_size_t, msgsz, int, msgflg);
ML_(linux_PRE_sys_msgsnd)(tid, ARG1,ARG2,ARG3,ARG4);
if ((ARG4 & VKI_IPC_NOWAIT) == 0)
*flags |= SfMayBlock;
}
PRE(sys_msgrcv)
{
PRINT("sys_msgrcv ( %d, %p, %d, %d, %d )",ARG1,ARG2,ARG3,ARG4,ARG5);
PRE_REG_READ5(long, "msgrcv",
int, msqid, struct msgbuf *, msgp, vki_size_t, msgsz,
long, msgytp, int, msgflg);
ML_(linux_PRE_sys_msgrcv)(tid, ARG1,ARG2,ARG3,ARG4,ARG5);
if ((ARG4 & VKI_IPC_NOWAIT) == 0)
*flags |= SfMayBlock;
}
POST(sys_msgrcv)
{
ML_(linux_POST_sys_msgrcv)(tid, RES,ARG1,ARG2,ARG3,ARG4,ARG5);
}
PRE(sys_msgctl)
{
PRINT("sys_msgctl ( %d, %d, %p )",ARG1,ARG2,ARG3);
PRE_REG_READ3(long, "msgctl",
int, msqid, int, cmd, struct msqid_ds *, buf);
ML_(linux_PRE_sys_msgctl)(tid, ARG1,ARG2,ARG3);
}
POST(sys_msgctl)
{
ML_(linux_POST_sys_msgctl)(tid, RES,ARG1,ARG2,ARG3);
}
PRE(sys_shmget)
{
PRINT("sys_shmget ( %d, %d, %d )",ARG1,ARG2,ARG3);
PRE_REG_READ3(long, "shmget", vki_key_t, key, vki_size_t, size, int, shmflg);
}
PRE(wrap_sys_shmat)
{
UWord arg2tmp;
PRINT("wrap_sys_shmat ( %d, %p, %d )",ARG1,ARG2,ARG3);
PRE_REG_READ3(long, "shmat",
int, shmid, const void *, shmaddr, int, shmflg);
arg2tmp = ML_(generic_PRE_sys_shmat)(tid, ARG1,ARG2,ARG3);
if (arg2tmp == 0)
SET_STATUS_Failure( VKI_EINVAL );
else
ARG2 = arg2tmp;
}
POST(wrap_sys_shmat)
{
ML_(generic_POST_sys_shmat)(tid, RES,ARG1,ARG2,ARG3);
}
PRE(sys_shmdt)
{
PRINT("sys_shmdt ( %p )",ARG1);
PRE_REG_READ1(long, "shmdt", const void *, shmaddr);
if (!ML_(generic_PRE_sys_shmdt)(tid, ARG1))
SET_STATUS_Failure( VKI_EINVAL );
}
POST(sys_shmdt)
{
ML_(generic_POST_sys_shmdt)(tid, RES,ARG1);
}
PRE(sys_shmctl)
{
PRINT("sys_shmctl ( %d, %d, %p )",ARG1,ARG2,ARG3);
PRE_REG_READ3(long, "shmctl",
int, shmid, int, cmd, struct shmid_ds *, buf);
ML_(generic_PRE_sys_shmctl)(tid, ARG1,ARG2,ARG3);
}
POST(sys_shmctl)
{
ML_(generic_POST_sys_shmctl)(tid, RES,ARG1,ARG2,ARG3);
}
PRE(sys_pread64)
{
*flags |= SfMayBlock;
PRINT("sys_pread64 ( %d, %p, %llu, %lld )",
ARG1, ARG2, (ULong)ARG3, ARG4);
PRE_REG_READ4(ssize_t, "pread64",
unsigned int, fd, char *, buf,
vki_size_t, count, vki_loff_t, offset);
PRE_MEM_WRITE( "pread64(buf)", ARG2, ARG3 );
}
POST(sys_pread64)
{
vg_assert(SUCCESS);
if (RES > 0) {
POST_MEM_WRITE( ARG2, RES );
}
}
PRE(sys_pwrite64)
{
*flags |= SfMayBlock;
PRINT("sys_pwrite64 ( %d, %p, %llu, %lld )",
ARG1, ARG2, (ULong)ARG3, ARG4);
PRE_REG_READ4(ssize_t, "pwrite64",
unsigned int, fd, const char *, buf,
vki_size_t, count, vki_loff_t, offset);
PRE_MEM_READ( "pwrite64(buf)", ARG2, ARG3 );
}
PRE(sys_fadvise64)
{
PRINT("sys_fadvise64 ( %d, %lld, %llu, %d )", ARG1,ARG2,ARG3,ARG4);
PRE_REG_READ4(long, "fadvise64",
int, fd, vki_loff_t, offset, vki_size_t, len, int, advice);
}
#undef PRE
#undef POST
/* ---------------------------------------------------------------------
The AMD64/Linux syscall table
------------------------------------------------------------------ */
/* Add an amd64-linux specific wrapper to a syscall table. */
#define PLAX_(const, name) WRAPPER_ENTRY_X_(amd64_linux, const, name)
#define PLAXY(const, name) WRAPPER_ENTRY_XY(amd64_linux, const, name)
// This table maps from __NR_xxx syscall numbers (from
// linux/include/asm-x86_64/unistd.h) to the appropriate PRE/POST sys_foo()
// wrappers on AMD64 (as per sys_call_table in
// linux/arch/x86_64/kernel/entry.S).
//
// When implementing these wrappers, you need to work out if the wrapper is
// generic, Linux-only (but arch-independent), or AMD64/Linux only.
const SyscallTableEntry ML_(syscall_table)[] = {
GENXY(__NR_read, sys_read), // 0
GENX_(__NR_write, sys_write), // 1
GENXY(__NR_open, sys_open), // 2
GENXY(__NR_close, sys_close), // 3
GENXY(__NR_stat, sys_newstat), // 4
GENXY(__NR_fstat, sys_newfstat), // 5
GENXY(__NR_lstat, sys_newlstat), // 6
GENXY(__NR_poll, sys_poll), // 7
<<<<<<< .working
LINX_(__NR_lseek, sys_lseek), // 8
LINXY(__NR_mmap, sys_mmap2), // 9
=======
GENX_(__NR_lseek, sys_lseek), // 8
GENX_(__NR_mmap, sys_mmap2), // 9
>>>>>>> .merge-right.r4787
GENXY(__NR_mprotect, sys_mprotect), // 10
GENXY(__NR_munmap, sys_munmap), // 11
GENX_(__NR_brk, sys_brk), // 12
LINXY(__NR_rt_sigaction, sys_rt_sigaction), // 13
LINXY(__NR_rt_sigprocmask, sys_rt_sigprocmask), // 14
PLAX_(__NR_rt_sigreturn, sys_rt_sigreturn), // 15
GENXY(__NR_ioctl, sys_ioctl), // 16
PLAXY(__NR_pread64, sys_pread64), // 17
PLAX_(__NR_pwrite64, sys_pwrite64), // 18
GENXY(__NR_readv, sys_readv), // 19
GENX_(__NR_writev, sys_writev), // 20
GENX_(__NR_access, sys_access), // 21
LINXY(__NR_pipe, sys_pipe), // 22
GENX_(__NR_select, sys_select), // 23
LINX_(__NR_sched_yield, sys_sched_yield), // 24
GENX_(__NR_mremap, sys_mremap), // 25
GENX_(__NR_msync, sys_msync), // 26
// (__NR_mincore, sys_mincore), // 27
GENX_(__NR_madvise, sys_madvise), // 28
PLAX_(__NR_shmget, sys_shmget), // 29
PLAXY(__NR_shmat, wrap_sys_shmat), // 30
PLAXY(__NR_shmctl, sys_shmctl), // 31
GENXY(__NR_dup, sys_dup), // 32
GENXY(__NR_dup2, sys_dup2), // 33
GENX_(__NR_pause, sys_pause), // 34
GENXY(__NR_nanosleep, sys_nanosleep), // 35
GENXY(__NR_getitimer, sys_getitimer), // 36
GENX_(__NR_alarm, sys_alarm), // 37
GENXY(__NR_setitimer, sys_setitimer), // 38
GENX_(__NR_getpid, sys_getpid), // 39
// (__NR_sendfile, sys_sendfile64), // 40
PLAXY(__NR_socket, sys_socket), // 41
PLAX_(__NR_connect, sys_connect), // 42
PLAXY(__NR_accept, sys_accept), // 43
PLAX_(__NR_sendto, sys_sendto), // 44
PLAXY(__NR_recvfrom, sys_recvfrom), // 45
PLAX_(__NR_sendmsg, sys_sendmsg), // 46
PLAXY(__NR_recvmsg, sys_recvmsg), // 47
PLAX_(__NR_shutdown, sys_shutdown), // 48
PLAX_(__NR_bind, sys_bind), // 49
PLAX_(__NR_listen, sys_listen), // 50
PLAXY(__NR_getsockname, sys_getsockname), // 51
PLAXY(__NR_getpeername, sys_getpeername), // 52
PLAXY(__NR_socketpair, sys_socketpair), // 53
PLAX_(__NR_setsockopt, sys_setsockopt), // 54
PLAXY(__NR_getsockopt, sys_getsockopt), // 55
PLAX_(__NR_clone, sys_clone), // 56
GENX_(__NR_fork, sys_fork), // 57
GENX_(__NR_vfork, sys_fork), // 58 treat as fork
GENX_(__NR_execve, sys_execve), // 59
GENX_(__NR_exit, sys_exit), // 60
GENXY(__NR_wait4, sys_wait4), // 61
GENX_(__NR_kill, sys_kill), // 62
GENXY(__NR_uname, sys_newuname), // 63
PLAX_(__NR_semget, sys_semget), // 64
PLAX_(__NR_semop, sys_semop), // 65
PLAXY(__NR_semctl, sys_semctl), // 66
PLAXY(__NR_shmdt, sys_shmdt), // 67
PLAX_(__NR_msgget, sys_msgget), // 68
PLAX_(__NR_msgsnd, sys_msgsnd), // 69
PLAXY(__NR_msgrcv, sys_msgrcv), // 70
PLAXY(__NR_msgctl, sys_msgctl), // 71
GENXY(__NR_fcntl, sys_fcntl), // 72
// (__NR_flock, sys_flock), // 73
GENX_(__NR_fsync, sys_fsync), // 74
GENX_(__NR_fdatasync, sys_fdatasync), // 75
GENX_(__NR_truncate, sys_truncate), // 76
GENX_(__NR_ftruncate, sys_ftruncate), // 77
GENXY(__NR_getdents, sys_getdents), // 78
GENXY(__NR_getcwd, sys_getcwd), // 79
GENX_(__NR_chdir, sys_chdir), // 80
GENX_(__NR_fchdir, sys_fchdir), // 81
GENX_(__NR_rename, sys_rename), // 82
GENX_(__NR_mkdir, sys_mkdir), // 83
GENX_(__NR_rmdir, sys_rmdir), // 84
GENXY(__NR_creat, sys_creat), // 85
GENX_(__NR_link, sys_link), // 86
GENX_(__NR_unlink, sys_unlink), // 87
GENX_(__NR_symlink, sys_symlink), // 88
GENX_(__NR_readlink, sys_readlink), // 89
GENX_(__NR_chmod, sys_chmod), // 90
GENX_(__NR_fchmod, sys_fchmod), // 91
GENX_(__NR_chown, sys_chown), // 92
GENX_(__NR_fchown, sys_fchown), // 93
GENX_(__NR_lchown, sys_lchown), // 94
GENX_(__NR_umask, sys_umask), // 95
GENXY(__NR_gettimeofday, sys_gettimeofday), // 96
GENXY(__NR_getrlimit, sys_getrlimit), // 97
GENXY(__NR_getrusage, sys_getrusage), // 98
LINXY(__NR_sysinfo, sys_sysinfo), // 99
GENXY(__NR_times, sys_times), // 100
PLAXY(__NR_ptrace, sys_ptrace), // 101
GENX_(__NR_getuid, sys_getuid), // 102
// (__NR_syslog, sys_syslog), // 103
GENX_(__NR_getgid, sys_getgid), // 104
GENX_(__NR_setuid, sys_setuid), // 105
GENX_(__NR_setgid, sys_setgid), // 106
GENX_(__NR_geteuid, sys_geteuid), // 107
GENX_(__NR_getegid, sys_getegid), // 108
GENX_(__NR_setpgid, sys_setpgid), // 109
GENX_(__NR_getppid, sys_getppid), // 110
GENX_(__NR_getpgrp, sys_getpgrp), // 111
GENX_(__NR_setsid, sys_setsid), // 112
GENX_(__NR_setreuid, sys_setreuid), // 113
GENX_(__NR_setregid, sys_setregid), // 114
GENXY(__NR_getgroups, sys_getgroups), // 115
GENX_(__NR_setgroups, sys_setgroups), // 116
LINX_(__NR_setresuid, sys_setresuid), // 117
LINXY(__NR_getresuid, sys_getresuid), // 118
LINX_(__NR_setresgid, sys_setresgid), // 119
LINXY(__NR_getresgid, sys_getresgid), // 120
GENX_(__NR_getpgid, sys_getpgid), // 121
LINX_(__NR_setfsuid, sys_setfsuid), // 122
LINX_(__NR_setfsgid, sys_setfsgid), // 123
GENX_(__NR_getsid, sys_getsid), // 124
// LINXY(__NR_capget, sys_capget), // 125
// LINX_(__NR_capset, sys_capset), // 126
LINXY(__NR_rt_sigpending, sys_rt_sigpending), // 127
LINXY(__NR_rt_sigtimedwait, sys_rt_sigtimedwait),// 128
LINXY(__NR_rt_sigqueueinfo, sys_rt_sigqueueinfo),// 129
LINX_(__NR_rt_sigsuspend, sys_rt_sigsuspend), // 130
GENXY(__NR_sigaltstack, sys_sigaltstack), // 131
LINX_(__NR_utime, sys_utime), // 132
GENX_(__NR_mknod, sys_mknod), // 133
// (__NR_uselib, sys_uselib), // 134
LINX_(__NR_personality, sys_personality), // 135
// (__NR_ustat, sys_ustat), // 136
GENXY(__NR_statfs, sys_statfs), // 137
// (__NR_fstatfs, sys_fstatfs), // 138
// (__NR_sysfs, sys_sysfs), // 139
// (__NR_getpriority, sys_getpriority), // 140
// (__NR_setpriority, sys_setpriority), // 141
//zz LINXY(__NR_sched_setparam, sys_sched_setparam), // 142
LINXY(__NR_sched_getparam, sys_sched_getparam), // 143
LINX_(__NR_sched_setscheduler, sys_sched_setscheduler), // 144
LINX_(__NR_sched_getscheduler, sys_sched_getscheduler), // 145
LINX_(__NR_sched_get_priority_max, sys_sched_get_priority_max), // 146
LINX_(__NR_sched_get_priority_min, sys_sched_get_priority_min), // 147
//LINX?(__NR_sched_rr_get_interval, sys_sched_rr_get_interval), // 148
GENX_(__NR_mlock, sys_mlock), // 149
GENX_(__NR_munlock, sys_munlock), // 150
GENX_(__NR_mlockall, sys_mlockall), // 151
LINX_(__NR_munlockall, sys_munlockall), // 152
// (__NR_vhangup, sys_vhangup), // 153
// (__NR_modify_ldt, sys_modify_ldt), // 154
// (__NR_pivot_root, sys_pivot_root), // 155
LINXY(__NR__sysctl, sys_sysctl), // 156
// (__NR_prctl, sys_prctl), // 157
PLAX_(__NR_arch_prctl, sys_arch_prctl), // 158
// (__NR_adjtimex, sys_adjtimex), // 159
GENX_(__NR_setrlimit, sys_setrlimit), // 160
GENX_(__NR_chroot, sys_chroot), // 161
GENX_(__NR_sync, sys_sync), // 162
// (__NR_acct, sys_acct), // 163
GENX_(__NR_settimeofday, sys_settimeofday), // 164
LINX_(__NR_mount, sys_mount), // 165
// (__NR_umount2, sys_umount), // 166
// (__NR_swapon, sys_swapon), // 167
// (__NR_swapoff, sys_swapoff), // 168
// (__NR_reboot, sys_reboot), // 169
// (__NR_sethostname, sys_sethostname), // 170
// (__NR_setdomainname, sys_setdomainname), // 171
// (__NR_iopl, stub_iopl), // 172
LINX_(__NR_ioperm, sys_ioperm), // 173
// (__NR_create_module, sys_ni_syscall), // 174
// (__NR_init_module, sys_init_module), // 175
// (__NR_delete_module, sys_delete_module), // 176
// (__NR_get_kernel_syms, sys_ni_syscall), // 177
// (__NR_query_module, sys_ni_syscall), // 178
//LINX_(__NR_quotactl, sys_quotactl), // 179
// (__NR_nfsservctl, sys_nfsservctl), // 180
// (__NR_getpmsg, sys_ni_syscall), // 181
// (__NR_putpmsg, sys_ni_syscall), // 182
// (__NR_afs_syscall, sys_ni_syscall), // 183
// (__NR_tuxcall, sys_ni_syscall), // 184
// (__NR_security, sys_ni_syscall), // 185
LINX_(__NR_gettid, sys_gettid), // 186
// (__NR_readahead, sys_readahead), // 187
//LINX_(__NR_setxattr, sys_setxattr), // 188
//LINX_(__NR_lsetxattr, sys_lsetxattr), // 189
//LINX_(__NR_fsetxattr, sys_fsetxattr), // 190
LINXY(__NR_getxattr, sys_getxattr), // 191
//LINXY(__NR_lgetxattr, sys_lgetxattr), // 192
//LINXY(__NR_fgetxattr, sys_fgetxattr), // 193
//LINXY(__NR_listxattr, sys_listxattr), // 194
//LINXY(__NR_llistxattr, sys_llistxattr), // 195
//LINXY(__NR_flistxattr, sys_flistxattr), // 196
//LINX_(__NR_removexattr, sys_removexattr), // 197
//LINX_(__NR_lremovexattr, sys_lremovexattr), // 198
//LINX_(__NR_fremovexattr, sys_fremovexattr), // 199
// (__NR_tkill, sys_tkill), // 200
GENXY(__NR_time, sys_time), /*was sys_time64*/ // 201
LINXY(__NR_futex, sys_futex), // 202
LINX_(__NR_sched_setaffinity, sys_sched_setaffinity), // 203
LINXY(__NR_sched_getaffinity, sys_sched_getaffinity), // 204
// (__NR_set_thread_area, sys_ni_syscall), // 205
LINXY(__NR_io_setup, sys_io_setup), // 206
LINX_(__NR_io_destroy, sys_io_destroy), // 207
LINXY(__NR_io_getevents, sys_io_getevents), // 208
LINX_(__NR_io_submit, sys_io_submit), // 209
LINXY(__NR_io_cancel, sys_io_cancel), // 210
// (__NR_get_thread_area, sys_ni_syscall), // 211
// (__NR_lookup_dcookie, sys_lookup_dcookie), // 212
LINXY(__NR_epoll_create, sys_epoll_create), // 213
// (__NR_epoll_ctl_old, sys_ni_syscall), // 214
// (__NR_epoll_wait_old, sys_ni_syscall), // 215
// (__NR_remap_file_pages, sys_remap_file_pages)// 216
GENXY(__NR_getdents64, sys_getdents64), // 217
LINX_(__NR_set_tid_address, sys_set_tid_address),// 218
// (__NR_restart_syscall, sys_restart_syscall),// 219
PLAX_(__NR_semtimedop, sys_semtimedop), // 220
PLAX_(__NR_fadvise64, sys_fadvise64), // 221
LINXY(__NR_timer_create, sys_timer_create), // 222
LINXY(__NR_timer_settime, sys_timer_settime), // 223
LINXY(__NR_timer_gettime, sys_timer_gettime), // 224
LINX_(__NR_timer_getoverrun, sys_timer_getoverrun), // 225
LINX_(__NR_timer_delete, sys_timer_delete), // 226
LINX_(__NR_clock_settime, sys_clock_settime), // 227
LINXY(__NR_clock_gettime, sys_clock_gettime), // 228
LINXY(__NR_clock_getres, sys_clock_getres), // 229
LINXY(__NR_clock_nanosleep, sys_clock_nanosleep),// 230
LINX_(__NR_exit_group, sys_exit_group), // 231
LINXY(__NR_epoll_wait, sys_epoll_wait), // 232
LINX_(__NR_epoll_ctl, sys_epoll_ctl), // 233
LINXY(__NR_tgkill, sys_tgkill), // 234
// (__NR_utimes, sys_utimes), // 235
// (__NR_vserver, sys_ni_syscall), // 236
// (__NR_mbind, sys_mbind), // 237
LINX_(__NR_set_mempolicy, sys_set_mempolicy), // 238
LINXY(__NR_get_mempolicy, sys_get_mempolicy), // 239
LINXY(__NR_mq_open, sys_mq_open), // 240
LINX_(__NR_mq_unlink, sys_mq_unlink), // 241
LINX_(__NR_mq_timedsend, sys_mq_timedsend), // 242
LINX_(__NR_mq_timedreceive, sys_mq_timedreceive),// 243
LINX_(__NR_mq_notify, sys_mq_notify), // 244
LINXY(__NR_mq_getsetattr, sys_mq_getsetattr), // 245
// (__NR_kexec_load, sys_ni_syscall), // 246
LINXY(__NR_waitid, sys_waitid), // 247
// LINX_(__NR_add_key, sys_add_key), // 248
// LINX_(__NR_request_key, sys_request_key), // 249
// LINXY(__NR_keyctl, sys_keyctl), // 250
// LINX_(__NR_ioprio_set, sys_ioprio_set), // 251
// LINX_(__NR_ioprio_get, sys_ioprio_get), // 252
LINX_(__NR_inotify_init, sys_inotify_init), // 253
LINX_(__NR_inotify_add_watch, sys_inotify_add_watch), // 254
LINX_(__NR_inotify_rm_watch, sys_inotify_rm_watch), // 255
};
const UInt ML_(syscall_table_size) =
sizeof(ML_(syscall_table)) / sizeof(ML_(syscall_table)[0]);
/*--------------------------------------------------------------------*/
/*--- end ---*/
/*--------------------------------------------------------------------*/
Reference in New Issue View Git Blame Copy Permalink