zenithsiz/ftmemsim-valgrind
1
0
Fork 0
mirror of https://github.com/Zenithsiz/ftmemsim-valgrind.git synced 2026-02-04 10:21:20 +00:00
Code Issues Actions Packages Projects Releases Wiki Activity
ftmemsim-valgrind/coregrind/m_syscall.c
Carl Love 98908947c7 This commit is for Bugzilla 334834. The Bugzilla contains patch 2 of 3 
to add PPC64 LE support.  The other two patches can be found in Bugzillas
334384 and 334836.

POWER PC, add the functional Little Endian support, patch 2 

The IBM POWER processor now supports both Big Endian and Little Endian.
The ABI for Little Endian also changes.  Specifically, the function
descriptor is not used, the stack size changed, accessing the TOC
changed.  Functions now have a local and a global entry point.  Register
r2 contains the TOC for local calls and register r12 contains the TOC
for global calls.  This patch makes the functional changes to the
Valgrind tool.  The patch makes the changes needed for the
none/tests/ppc32 and none/tests/ppc64 Makefile.am.  A number of the
ppc specific tests have Endian dependencies that are not fixed in
this patch.  They are fixed in the next patch.

Per Julian's comments renamed coregrind/m_dispatch/dispatch-ppc64-linux.S
to coregrind/m_dispatch/dispatch-ppc64be-linux.S  Created new file for LE
coregrind/m_dispatch/dispatch-ppc64le-linux.S.  The same was done for
coregrind/m_syswrap/syscall-ppc-linux.S.

Signed-off-by: Carl Love <carll@us.ibm.com>

git-svn-id: svn://svn.valgrind.org/valgrind/trunk@14239
2014-08-07 23:35:54 +00:00

929 lines
29 KiB
C
Raw Blame History

/*--------------------------------------------------------------------*/
/*--- Doing syscalls. m_syscall.c ---*/
/*--------------------------------------------------------------------*/
/*
This file is part of Valgrind, a dynamic binary instrumentation
framework.
Copyright (C) 2000-2013 Julian Seward
jseward@acm.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_libcassert.h"
#include "pub_core_vki.h"
#include "pub_core_vkiscnums.h"
#include "pub_core_syscall.h"
/* ---------------------------------------------------------------------
Building syscall return values.
------------------------------------------------------------------ */
#if defined(VGO_linux)
/* Make a SysRes value from a syscall return value. This is
Linux-specific.
From:
http://sources.redhat.com/cgi-bin/cvsweb.cgi/libc/sysdeps/unix/sysv/
linux/i386/sysdep.h?
rev=1.28&content-type=text/x-cvsweb-markup&cvsroot=glibc
Linux uses a negative return value to indicate syscall errors,
unlike most Unices, which use the condition codes' carry flag.
Since version 2.1 the return value of a system call might be
negative even if the call succeeded. E.g., the 'lseek' system call
might return a large offset. Therefore we must not anymore test
for < 0, but test for a real error by making sure the value in %eax
is a real error number. Linus said he will make sure the no
syscall returns a value in -1 .. -4095 as a valid result so we can
safely test with -4095.
*/
SysRes VG_(mk_SysRes_x86_linux) ( Int val ) {
SysRes res;
res._valEx = 0; /* unused except on mips-linux */
res._isError = val >= -4095 && val <= -1;
if (res._isError) {
res._val = (UInt)(-val);
} else {
res._val = (UInt)val;
}
return res;
}
/* Similarly .. */
SysRes VG_(mk_SysRes_amd64_linux) ( Long val ) {
SysRes res;
res._valEx = 0; /* unused except on mips-linux */
res._isError = val >= -4095 && val <= -1;
if (res._isError) {
res._val = (ULong)(-val);
} else {
res._val = (ULong)val;
}
return res;
}
/* PPC uses the CR7.SO bit to flag an error (CR0 in IBM-speak) */
/* Note this must be in the bottom bit of the second arg */
SysRes VG_(mk_SysRes_ppc32_linux) ( UInt val, UInt cr0so ) {
SysRes res;
res._valEx = 0; /* unused except on mips-linux */
res._isError = (cr0so & 1) != 0;
res._val = val;
return res;
}
/* As per ppc32 version, cr0.so must be in l.s.b. of 2nd arg */
SysRes VG_(mk_SysRes_ppc64_linux) ( ULong val, ULong cr0so ) {
SysRes res;
res._valEx = 0; /* unused except on mips-linux */
res._isError = (cr0so & 1) != 0;
res._val = val;
return res;
}
SysRes VG_(mk_SysRes_s390x_linux) ( Long val ) {
SysRes res;
res._valEx = 0; /* unused except on mips-linux */
res._isError = val >= -4095 && val <= -1;
if (res._isError) {
res._val = -val;
} else {
res._val = val;
}
return res;
}
SysRes VG_(mk_SysRes_arm_linux) ( Int val ) {
SysRes res;
res._valEx = 0; /* unused except on mips-linux */
res._isError = val >= -4095 && val <= -1;
if (res._isError) {
res._val = (UInt)(-val);
} else {
res._val = (UInt)val;
}
return res;
}
SysRes VG_(mk_SysRes_arm64_linux) ( Long val ) {
SysRes res;
res._valEx = 0; /* unused except on mips-linux */
res._isError = val >= -4095 && val <= -1;
if (res._isError) {
res._val = (ULong)(-val);
} else {
res._val = (ULong)val;
}
return res;
}
/* MIPS uses a3 != 0 to flag an error */
SysRes VG_(mk_SysRes_mips32_linux) ( UWord v0, UWord v1, UWord a3 ) {
SysRes res;
res._isError = (a3 != (UWord)0);
res._val = v0;
res._valEx = v1;
return res;
}
/* MIPS uses a3 != 0 to flag an error */
SysRes VG_(mk_SysRes_mips64_linux) ( ULong v0, ULong v1, ULong a3 ) {
SysRes res;
res._isError = (a3 != (ULong)0);
res._val = v0;
res._valEx = v1;
return res;
}
/* Generic constructors. */
SysRes VG_(mk_SysRes_Error) ( UWord err ) {
SysRes r;
r._valEx = 0; /* unused except on mips-linux */
r._isError = True;
r._val = err;
return r;
}
SysRes VG_(mk_SysRes_Success) ( UWord res ) {
SysRes r;
r._valEx = 0; /* unused except on mips-linux */
r._isError = False;
r._val = res;
return r;
}
#elif defined(VGO_darwin)
/* Darwin: Some syscalls return a double-word result. */
SysRes VG_(mk_SysRes_x86_darwin) ( UChar scclass, Bool isErr,
UInt wHI, UInt wLO )
{
SysRes res;
res._wHI = 0;
res._wLO = 0;
res._mode = 0; /* invalid */
vg_assert(isErr == False || isErr == True);
vg_assert(sizeof(UWord) == sizeof(UInt));
switch (scclass) {
case VG_DARWIN_SYSCALL_CLASS_UNIX:
res._wLO = wLO;
res._wHI = wHI;
res._mode = isErr ? SysRes_UNIX_ERR : SysRes_UNIX_OK;
break;
case VG_DARWIN_SYSCALL_CLASS_MACH:
vg_assert(!isErr);
vg_assert(wHI == 0);
res._wLO = wLO;
res._mode = SysRes_MACH;
break;
case VG_DARWIN_SYSCALL_CLASS_MDEP:
vg_assert(!isErr);
vg_assert(wHI == 0);
res._wLO = wLO;
res._mode = SysRes_MDEP;
break;
default:
vg_assert(0);
}
return res;
}
SysRes VG_(mk_SysRes_amd64_darwin) ( UChar scclass, Bool isErr,
ULong wHI, ULong wLO )
{
SysRes res;
res._wHI = 0;
res._wLO = 0;
res._mode = 0; /* invalid */
vg_assert(isErr == False || isErr == True);
vg_assert(sizeof(UWord) == sizeof(ULong));
switch (scclass) {
case VG_DARWIN_SYSCALL_CLASS_UNIX:
res._wLO = wLO;
res._wHI = wHI;
res._mode = isErr ? SysRes_UNIX_ERR : SysRes_UNIX_OK;
break;
case VG_DARWIN_SYSCALL_CLASS_MACH:
vg_assert(!isErr);
vg_assert(wHI == 0);
res._wLO = wLO;
res._mode = SysRes_MACH;
break;
case VG_DARWIN_SYSCALL_CLASS_MDEP:
vg_assert(!isErr);
vg_assert(wHI == 0);
res._wLO = wLO;
res._mode = SysRes_MDEP;
break;
default:
vg_assert(0);
}
return res;
}
/* Generic constructors. We assume (without checking if this makes
any sense, from the caller's point of view) that these are for the
UNIX style of syscall. */
SysRes VG_(mk_SysRes_Error) ( UWord err ) {
SysRes r;
r._wHI = 0;
r._wLO = err;
r._mode = SysRes_UNIX_ERR;
return r;
}
SysRes VG_(mk_SysRes_Success) ( UWord res ) {
SysRes r;
r._wHI = 0;
r._wLO = res;
r._mode = SysRes_UNIX_OK;
return r;
}
#else
# error "Unknown OS"
#endif
/* ---------------------------------------------------------------------
VG_(do_syscall): A function for doing syscalls.
------------------------------------------------------------------ */
#if defined(VGP_x86_linux)
/* Incoming args (syscall number + up to 6 args) come on the stack.
(ie. the C calling convention).
The syscall number goes in %eax. The args are passed to the syscall in
the regs %ebx, %ecx, %edx, %esi, %edi, %ebp, ie. the kernel's syscall
calling convention.
%eax gets the return value. Not sure which registers the kernel
clobbers, so we preserve all the callee-save regs (%esi, %edi, %ebx,
%ebp).
*/
extern UWord do_syscall_WRK (
UWord syscall_no,
UWord a1, UWord a2, UWord a3,
UWord a4, UWord a5, UWord a6
);
asm(
".text\n"
".globl do_syscall_WRK\n"
"do_syscall_WRK:\n"
" push %esi\n"
" push %edi\n"
" push %ebx\n"
" push %ebp\n"
" movl 16+ 4(%esp),%eax\n"
" movl 16+ 8(%esp),%ebx\n"
" movl 16+12(%esp),%ecx\n"
" movl 16+16(%esp),%edx\n"
" movl 16+20(%esp),%esi\n"
" movl 16+24(%esp),%edi\n"
" movl 16+28(%esp),%ebp\n"
" int $0x80\n"
" popl %ebp\n"
" popl %ebx\n"
" popl %edi\n"
" popl %esi\n"
" ret\n"
".previous\n"
);
#elif defined(VGP_amd64_linux)
/* Incoming args (syscall number + up to 6 args) come in %rdi, %rsi,
%rdx, %rcx, %r8, %r9, and the last one on the stack (ie. the C
calling convention).
The syscall number goes in %rax. The args are passed to the syscall in
the regs %rdi, %rsi, %rdx, %r10, %r8, %r9 (yes, really %r10, not %rcx),
ie. the kernel's syscall calling convention.
%rax gets the return value. %rcx and %r11 are clobbered by the syscall;
no matter, they are caller-save (the syscall clobbers no callee-save
regs, so we don't have to do any register saving/restoring).
*/
extern UWord do_syscall_WRK (
UWord syscall_no,
UWord a1, UWord a2, UWord a3,
UWord a4, UWord a5, UWord a6
);
asm(
".text\n"
".globl do_syscall_WRK\n"
"do_syscall_WRK:\n"
/* Convert function calling convention --> syscall calling
convention */
" movq %rdi, %rax\n"
" movq %rsi, %rdi\n"
" movq %rdx, %rsi\n"
" movq %rcx, %rdx\n"
" movq %r8, %r10\n"
" movq %r9, %r8\n"
" movq 8(%rsp), %r9\n" /* last arg from stack */
" syscall\n"
" ret\n"
".previous\n"
);
#elif defined(VGP_ppc32_linux)
/* Incoming args (syscall number + up to 6 args) come in %r3:%r9.
The syscall number goes in %r0. The args are passed to the syscall in
the regs %r3:%r8, i.e. the kernel's syscall calling convention.
The %cr0.so bit flags an error.
We return the syscall return value in %r3, and the %cr0.so in
the lowest bit of %r4.
We return a ULong, of which %r3 is the high word, and %r4 the low.
No callee-save regs are clobbered, so no saving/restoring is needed.
*/
extern ULong do_syscall_WRK (
UWord syscall_no,
UWord a1, UWord a2, UWord a3,
UWord a4, UWord a5, UWord a6
);
asm(
".text\n"
".globl do_syscall_WRK\n"
"do_syscall_WRK:\n"
" mr 0,3\n"
" mr 3,4\n"
" mr 4,5\n"
" mr 5,6\n"
" mr 6,7\n"
" mr 7,8\n"
" mr 8,9\n"
" sc\n" /* syscall: sets %cr0.so on error */
" mfcr 4\n" /* %cr -> low word of return var */
" rlwinm 4,4,4,31,31\n" /* rotate flag bit so to lsb, and mask it */
" blr\n" /* and return */
".previous\n"
);
#elif defined(VGP_ppc64be_linux)
/* Due to the need to return 65 bits of result, this is completely
different from the ppc32 case. The single arg register points to a
7-word block containing the syscall # and the 6 args. The syscall
result proper is put in [0] of the block, and %cr0.so is in the
bottom bit of [1]. */
extern void do_syscall_WRK ( ULong* argblock );
asm(
".align 2\n"
".globl do_syscall_WRK\n"
".section \".opd\",\"aw\"\n"
".align 3\n"
"do_syscall_WRK:\n"
".quad .do_syscall_WRK,.TOC.@tocbase,0\n"
".previous\n"
".type .do_syscall_WRK,@function\n"
".globl .do_syscall_WRK\n"
".do_syscall_WRK:\n"
" std 3,-16(1)\n" /* stash arg */
" ld 8, 48(3)\n" /* sc arg 6 */
" ld 7, 40(3)\n" /* sc arg 5 */
" ld 6, 32(3)\n" /* sc arg 4 */
" ld 5, 24(3)\n" /* sc arg 3 */
" ld 4, 16(3)\n" /* sc arg 2 */
" ld 0, 0(3)\n" /* sc number */
" ld 3, 8(3)\n" /* sc arg 1 */
" sc\n" /* result in r3 and cr0.so */
" ld 5,-16(1)\n" /* reacquire argblock ptr (r5 is caller-save) */
" std 3,0(5)\n" /* argblock[0] = r3 */
" mfcr 3\n"
" srwi 3,3,28\n"
" andi. 3,3,1\n"
" std 3,8(5)\n" /* argblock[1] = cr0.s0 & 1 */
" blr\n"
);
#elif defined(VGP_ppc64le_linux)
/* Due to the need to return 65 bits of result, this is completely
different from the ppc32 case. The single arg register points to a
7-word block containing the syscall # and the 6 args. The syscall
result proper is put in [0] of the block, and %cr0.so is in the
bottom bit of [1]. */
extern void do_syscall_WRK ( ULong* argblock );
/* Little Endian supports ELF version 2. In the future, it may support
* other versions as well.
*/
asm(
".align 2\n"
".globl do_syscall_WRK\n"
".type do_syscall_WRK,@function\n"
"do_syscall_WRK:\n"
"#if _CALL_ELF == 2" "\n"
"0: addis 2,12,.TOC.-0b@ha\n"
" addi 2,2,.TOC.-0b@l\n"
" .localentry do_syscall_WRK, .-do_syscall_WRK\n"
"#endif" "\n"
" std 3,-16(1)\n" /* stash arg */
" ld 8, 48(3)\n" /* sc arg 6 */
" ld 7, 40(3)\n" /* sc arg 5 */
" ld 6, 32(3)\n" /* sc arg 4 */
" ld 5, 24(3)\n" /* sc arg 3 */
" ld 4, 16(3)\n" /* sc arg 2 */
" ld 0, 0(3)\n" /* sc number */
" ld 3, 8(3)\n" /* sc arg 1 */
" sc\n" /* result in r3 and cr0.so */
" ld 5,-16(1)\n" /* reacquire argblock ptr (r5 is caller-save) */
" std 3,0(5)\n" /* argblock[0] = r3 */
" mfcr 3\n"
" srwi 3,3,28\n"
" andi. 3,3,1\n"
" std 3,8(5)\n" /* argblock[1] = cr0.s0 & 1 */
" blr\n"
" .size do_syscall_WRK, .-do_syscall_WRK\n"
);
#elif defined(VGP_arm_linux)
/* I think the conventions are:
args in r0 r1 r2 r3 r4 r5
sysno in r7
return value in r0, w/ same conventions as x86-linux, viz r0 in
-4096 .. -1 is an error value. All other values are success
values.
*/
extern UWord do_syscall_WRK (
UWord a1, UWord a2, UWord a3,
UWord a4, UWord a5, UWord a6,
UWord syscall_no
);
asm(
".text\n"
".globl do_syscall_WRK\n"
"do_syscall_WRK:\n"
" push {r4, r5, r7}\n"
" ldr r4, [sp, #12]\n"
" ldr r5, [sp, #16]\n"
" ldr r7, [sp, #20]\n"
" svc 0x0\n"
" pop {r4, r5, r7}\n"
" bx lr\n"
".previous\n"
);
#elif defined(VGP_arm64_linux)
/* I think the conventions are:
args in r0 r1 r2 r3 r4 r5
sysno in r8
return value in r0, w/ same conventions as x86-linux, viz r0 in
-4096 .. -1 is an error value. All other values are success
values.
r0 to r5 remain unchanged, but syscall_no is in r6 and needs
to be moved to r8 (??)
*/
extern UWord do_syscall_WRK (
UWord a1, UWord a2, UWord a3,
UWord a4, UWord a5, UWord a6,
UWord syscall_no
);
asm(
".text\n"
".globl do_syscall_WRK\n"
"do_syscall_WRK:\n"
" mov x8, x6\n"
" mov x6, 0\n"
" mov x7, 0\n"
" svc 0\n"
" ret\n"
".previous\n"
);
#elif defined(VGP_x86_darwin)
/* Incoming args (syscall number + up to 8 args) come in on the stack
The kernel's syscall calling convention is:
* the syscall number goes in eax
* the args are passed to the syscall on the stack,
pushed onto the stack R->L (that is, the usual x86
calling conventions, with the leftmost arg at the lowest
address)
Call instruction:
* UNIX: sysenter
* UNIX: int $0x80
* MACH: int $0x81
* MDEP: int $0x82
Note that the call type can be determined from the syscall number;
there is no need to inspect the actual instruction. Although obviously
the instruction must match.
Return value:
* MACH,MDEP: the return value comes back in eax
* UNIX: the return value comes back in edx:eax (hi32:lo32)
Error:
* MACH,MDEP: no error is returned
* UNIX: the carry flag indicates success or failure
nb here, sizeof(UWord) == sizeof(UInt)
*/
__private_extern__ ULong
do_syscall_unix_WRK ( UWord a1, UWord a2, UWord a3, /* 4(esp)..12(esp) */
UWord a4, UWord a5, UWord a6, /* 16(esp)..24(esp) */
UWord a7, UWord a8, /* 28(esp)..32(esp) */
UWord syscall_no, /* 36(esp) */
/*OUT*/UInt* errflag /* 40(esp) */ );
// Unix syscall: 64-bit return in edx:eax, with LSB in eax
// error indicated by carry flag: clear=good, set=bad
asm(".private_extern _do_syscall_unix_WRK\n"
"_do_syscall_unix_WRK:\n"
" movl 40(%esp), %ecx \n" /* assume syscall success */
" movl $0, (%ecx) \n"
" movl 36(%esp), %eax \n"
" int $0x80 \n"
" jnc 1f \n" /* jump if success */
" movl 40(%esp), %ecx \n" /* syscall failed - set *errflag */
" movl $1, (%ecx) \n"
" 1: ret \n"
);
__private_extern__ UInt
do_syscall_mach_WRK ( UWord a1, UWord a2, UWord a3, /* 4(esp)..12(esp) */
UWord a4, UWord a5, UWord a6, /* 16(esp)..24(esp) */
UWord a7, UWord a8, /* 28(esp)..32(esp) */
UWord syscall_no /* 36(esp) */ );
// Mach trap: 32-bit result in %eax, no error flag
asm(".private_extern _do_syscall_mach_WRK\n"
"_do_syscall_mach_WRK:\n"
" movl 36(%esp), %eax \n"
" int $0x81 \n"
" ret \n"
);
__private_extern__ UInt
do_syscall_mdep_WRK ( UWord a1, UWord a2, UWord a3, /* 4(esp)..12(esp) */
UWord a4, UWord a5, UWord a6, /* 16(esp)..24(esp) */
UWord a7, UWord a8, /* 28(esp)..32(esp) */
UWord syscall_no /* 36(esp) */ );
// mdep trap: 32-bit result in %eax, no error flag
asm(
".private_extern _do_syscall_mdep_WRK\n"
"_do_syscall_mdep_WRK:\n"
" movl 36(%esp), %eax \n"
" int $0x82 \n"
" ret \n"
);
#elif defined(VGP_amd64_darwin)
/* Incoming args (syscall number + up to 8 args) come in registers and stack
The kernel's syscall calling convention is:
* the syscall number goes in rax
* the args are passed to the syscall in registers and the stack
* the call instruction is 'syscall'
Return value:
* MACH,MDEP: the return value comes back in rax
* UNIX: the return value comes back in rdx:rax (hi64:lo64)
Error:
* MACH,MDEP: no error is returned
* UNIX: the carry flag indicates success or failure
nb here, sizeof(UWord) == sizeof(ULong)
*/
__private_extern__ UWord
do_syscall_unix_WRK ( UWord a1, UWord a2, UWord a3, /* rdi, rsi, rdx */
UWord a4, UWord a5, UWord a6, /* rcx, r8, r9 */
UWord a7, UWord a8, /* 8(rsp), 16(rsp) */
UWord syscall_no, /* 24(rsp) */
/*OUT*/ULong* errflag, /* 32(rsp) */
/*OUT*/ULong* res2 ); /* 40(rsp) */
// Unix syscall: 128-bit return in rax:rdx, with LSB in rax
// error indicated by carry flag: clear=good, set=bad
asm(".private_extern _do_syscall_unix_WRK\n"
"_do_syscall_unix_WRK:\n"
" movq %rcx, %r10 \n" /* pass rcx in r10 instead */
" movq 32(%rsp), %rax \n" /* assume syscall success */
" movq $0, (%rax) \n"
" movq 24(%rsp), %rax \n" /* load syscall_no */
" syscall \n"
" jnc 1f \n" /* jump if success */
" movq 32(%rsp), %rcx \n" /* syscall failed - set *errflag */
" movq $1, (%rcx) \n"
" 1: movq 40(%rsp), %rcx \n" /* save 2nd result word */
" movq %rdx, (%rcx) \n"
" retq \n" /* return 1st result word */
);
__private_extern__ UWord
do_syscall_mach_WRK ( UWord a1, UWord a2, UWord a3, /* rdi, rsi, rdx */
UWord a4, UWord a5, UWord a6, /* rcx, r8, r9 */
UWord a7, UWord a8, /* 8(rsp), 16(rsp) */
UWord syscall_no ); /* 24(rsp) */
// Mach trap: 64-bit result, no error flag
asm(".private_extern _do_syscall_mach_WRK\n"
"_do_syscall_mach_WRK:\n"
" movq %rcx, %r10 \n" /* pass rcx in r10 instead */
" movq 24(%rsp), %rax \n" /* load syscall_no */
" syscall \n"
" retq \n"
);
#elif defined(VGP_s390x_linux)
static UWord do_syscall_WRK (
UWord syscall_no,
UWord arg1, UWord arg2, UWord arg3,
UWord arg4, UWord arg5, UWord arg6
)
{
register UWord __arg1 asm("2") = arg1;
register UWord __arg2 asm("3") = arg2;
register UWord __arg3 asm("4") = arg3;
register UWord __arg4 asm("5") = arg4;
register UWord __arg5 asm("6") = arg5;
register UWord __arg6 asm("7") = arg6;
register ULong __svcres asm("2");
__asm__ __volatile__ (
"lgr %%r1,%1\n\t"
"svc 0\n\t"
: "=d" (__svcres)
: "a" (syscall_no),
"0" (__arg1),
"d" (__arg2),
"d" (__arg3),
"d" (__arg4),
"d" (__arg5),
"d" (__arg6)
: "1", "cc", "memory");
return (UWord) (__svcres);
}
#elif defined(VGP_mips32_linux)
/* Incoming args (syscall number + up to 6 args) come in a0 - a3 and stack.
The syscall number goes in v0. The args are passed to the syscall in
the regs a0 - a3 and stack, i.e. the kernel's syscall calling convention.
(a3 != 0) flags an error.
We return the syscall return value in v0.
MIPS version
*/
extern int do_syscall_WRK (
int a1, int a2, int a3,
int a4, int a5, int a6, int syscall_no, UWord *err,
UWord *valHi, UWord* valLo
);
asm(
".globl do_syscall_WRK\n"
".ent do_syscall_WRK\n"
".text\n"
"do_syscall_WRK:\n"
" lw $2, 24($29)\n"
" syscall\n"
" lw $8, 28($29)\n"
" sw $7, ($8)\n"
" lw $8, 32($29)\n"
" sw $3, ($8)\n" // store valHi
" lw $8, 36($29)\n"
" sw $2, ($8)\n" // store valLo
" jr $31\n"
" nop\n"
".previous\n"
".end do_syscall_WRK\n"
);
#elif defined(VGP_mips64_linux)
extern UWord do_syscall_WRK ( UWord a1, UWord a2, UWord a3, UWord a4, UWord a5,
UWord a6, UWord syscall_no, ULong* V1_val );
asm (
".text\n"
".globl do_syscall_WRK\n"
"do_syscall_WRK:\n"
" daddiu $29, $29, -8\n"
" sd $11, 0($29)\n"
" move $2, $10\n"
" syscall\n"
" ld $11, 0($29)\n"
" daddiu $29, $29, 8\n"
" sd $3, 0($11)\n" /* store vale of v1 in last param */
" sd $7, 8($11)\n" /* store vale of a3 in last param */
" jr $31\n"
".previous\n"
);
#else
# error Unknown platform
#endif
/* Finally, the generic code. This sends the call to the right
helper. */
SysRes VG_(do_syscall) ( UWord sysno, UWord a1, UWord a2, UWord a3,
UWord a4, UWord a5, UWord a6,
UWord a7, UWord a8 )
{
# if defined(VGP_x86_linux)
UWord val = do_syscall_WRK(sysno,a1,a2,a3,a4,a5,a6);
return VG_(mk_SysRes_x86_linux)( val );
# elif defined(VGP_amd64_linux)
UWord val = do_syscall_WRK(sysno,a1,a2,a3,a4,a5,a6);
return VG_(mk_SysRes_amd64_linux)( val );
# elif defined(VGP_ppc32_linux)
ULong ret = do_syscall_WRK(sysno,a1,a2,a3,a4,a5,a6);
UInt val = (UInt)(ret>>32);
UInt cr0so = (UInt)(ret);
return VG_(mk_SysRes_ppc32_linux)( val, cr0so );
# elif defined(VGP_ppc64be_linux) || defined(VGP_ppc64le_linux)
ULong argblock[7];
argblock[0] = sysno;
argblock[1] = a1;
argblock[2] = a2;
argblock[3] = a3;
argblock[4] = a4;
argblock[5] = a5;
argblock[6] = a6;
do_syscall_WRK( &argblock[0] );
return VG_(mk_SysRes_ppc64_linux)( argblock[0], argblock[1] );
# elif defined(VGP_arm_linux)
UWord val = do_syscall_WRK(a1,a2,a3,a4,a5,a6,sysno);
return VG_(mk_SysRes_arm_linux)( val );
# elif defined(VGP_arm64_linux)
UWord val = do_syscall_WRK(a1,a2,a3,a4,a5,a6,sysno);
return VG_(mk_SysRes_arm64_linux)( val );
# elif defined(VGP_x86_darwin)
UInt wLO = 0, wHI = 0, err = 0;
ULong u64;
UChar scclass = VG_DARWIN_SYSNO_CLASS(sysno);
switch (scclass) {
case VG_DARWIN_SYSCALL_CLASS_UNIX:
u64 = do_syscall_unix_WRK(a1,a2,a3,a4,a5,a6,a7,a8,
VG_DARWIN_SYSNO_FOR_KERNEL(sysno), &err);
wLO = (UInt)u64;
wHI = (UInt)(u64 >> 32);
break;
case VG_DARWIN_SYSCALL_CLASS_MACH:
wLO = do_syscall_mach_WRK(a1,a2,a3,a4,a5,a6,a7,a8,
VG_DARWIN_SYSNO_FOR_KERNEL(sysno));
err = 0;
break;
case VG_DARWIN_SYSCALL_CLASS_MDEP:
wLO = do_syscall_mdep_WRK(a1,a2,a3,a4,a5,a6,a7,a8,
VG_DARWIN_SYSNO_FOR_KERNEL(sysno));
err = 0;
break;
default:
vg_assert(0);
break;
}
return VG_(mk_SysRes_x86_darwin)( scclass, err ? True : False, wHI, wLO );
# elif defined(VGP_amd64_darwin)
ULong wLO = 0, wHI = 0, err = 0;
UChar scclass = VG_DARWIN_SYSNO_CLASS(sysno);
switch (scclass) {
case VG_DARWIN_SYSCALL_CLASS_UNIX:
wLO = do_syscall_unix_WRK(a1,a2,a3,a4,a5,a6,a7,a8,
VG_DARWIN_SYSNO_FOR_KERNEL(sysno), &err, &wHI);
break;
case VG_DARWIN_SYSCALL_CLASS_MACH:
case VG_DARWIN_SYSCALL_CLASS_MDEP:
wLO = do_syscall_mach_WRK(a1,a2,a3,a4,a5,a6,a7,a8,
VG_DARWIN_SYSNO_FOR_KERNEL(sysno));
err = 0;
break;
default:
vg_assert(0);
break;
}
return VG_(mk_SysRes_amd64_darwin)( scclass, err ? True : False, wHI, wLO );
#elif defined(VGP_s390x_linux)
UWord val;
if (sysno == __NR_mmap) {
ULong argbuf[6];
argbuf[0] = a1;
argbuf[1] = a2;
argbuf[2] = a3;
argbuf[3] = a4;
argbuf[4] = a5;
argbuf[5] = a6;
val = do_syscall_WRK(sysno,(UWord)&argbuf[0],0,0,0,0,0);
} else {
val = do_syscall_WRK(sysno,a1,a2,a3,a4,a5,a6);
}
return VG_(mk_SysRes_s390x_linux)( val );
#elif defined(VGP_mips32_linux)
UWord err = 0;
UWord valHi = 0;
UWord valLo = 0;
(void) do_syscall_WRK(a1,a2,a3,a4,a5,a6, sysno,&err,&valHi,&valLo);
return VG_(mk_SysRes_mips32_linux)( valLo, valHi, (ULong)err );
#elif defined(VGP_mips64_linux)
ULong v1_a3[2];
v1_a3[0] = 0xFF00;
v1_a3[1] = 0xFF00;
ULong V0 = do_syscall_WRK(a1,a2,a3,a4,a5,a6,sysno,v1_a3);
ULong V1 = (ULong)v1_a3[0];
ULong A3 = (ULong)v1_a3[1];
return VG_(mk_SysRes_mips64_linux)( V0, V1, A3 );
#else
# error Unknown platform
#endif
}
/* ---------------------------------------------------------------------
Names of errors.
------------------------------------------------------------------ */
/* Return a string which gives the name of an error value. Note,
unlike the standard C syserror fn, the returned string is not
malloc-allocated or writable -- treat it as a constant.
TODO: implement this properly. */
const HChar* VG_(strerror) ( UWord errnum )
{
switch (errnum) {
case VKI_EPERM: return "Operation not permitted";
case VKI_ENOENT: return "No such file or directory";
case VKI_ESRCH: return "No such process";
case VKI_EINTR: return "Interrupted system call";
case VKI_EIO: return "Input/output error";
case VKI_ENXIO: return "No such device or address";
case VKI_E2BIG: return "Argument list too long";
case VKI_ENOEXEC: return "Exec format error";
case VKI_EBADF: return "Bad file descriptor";
case VKI_ECHILD: return "No child processes";
case VKI_EAGAIN: return "Resource temporarily unavailable";
case VKI_ENOMEM: return "Cannot allocate memory";
case VKI_EACCES: return "Permission denied";
case VKI_EFAULT: return "Bad address";
case VKI_ENOTBLK: return "Block device required";
case VKI_EBUSY: return "Device or resource busy";
case VKI_EEXIST: return "File exists";
case VKI_EXDEV: return "Invalid cross-device link";
case VKI_ENODEV: return "No such device";
case VKI_ENOTDIR: return "Not a directory";
case VKI_EISDIR: return "Is a directory";
case VKI_EINVAL: return "Invalid argument";
case VKI_ENFILE: return "Too many open files in system";
case VKI_EMFILE: return "Too many open files";
case VKI_ENOTTY: return "Inappropriate ioctl for device";
case VKI_ETXTBSY: return "Text file busy";
case VKI_EFBIG: return "File too large";
case VKI_ENOSPC: return "No space left on device";
case VKI_ESPIPE: return "Illegal seek";
case VKI_EROFS: return "Read-only file system";
case VKI_EMLINK: return "Too many links";
case VKI_EPIPE: return "Broken pipe";
case VKI_EDOM: return "Numerical argument out of domain";
case VKI_ERANGE: return "Numerical result out of range";
case VKI_ENOSYS: return "Function not implemented";
case VKI_EOVERFLOW: return "Value too large for defined data type";
# if defined(VKI_ERESTARTSYS)
case VKI_ERESTARTSYS: return "ERESTARTSYS";
# endif
default: return "VG_(strerror): unknown error";
}
}
/*--------------------------------------------------------------------*/
/*--- end ---*/
/*--------------------------------------------------------------------*/
Reference in New Issue View Git Blame Copy Permalink