/*--------------------------------------------------------------------*/ /*--- Doing syscalls. m_syscall.c ---*/ /*--------------------------------------------------------------------*/ /* This file is part of Valgrind, a dynamic binary instrumentation framework. Copyright (C) 2000-2012 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; } /* 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; } /* 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_ppc64_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_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_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" ); #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_ppc64_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_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 ); #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 ---*/ /*--------------------------------------------------------------------*/