/*
This file is part of ThreadSanitizer, a dynamic data race detector
based on Valgrind.
Copyright (C) 2008-2009 Google Inc
opensource@google.com
Copyright (C) 2007-2008 OpenWorks LLP
info@open-works.co.uk
This program is free software; you can redistribute it and/or
modify it under the terms of the GNU General Public License as
published by the Free Software Foundation; either version 2 of the
License, or (at your option) any later version.
This program is distributed in the hope that it will be useful, but
WITHOUT ANY WARRANTY; without even the implied warranty of
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
General Public License for more details.
You should have received a copy of the GNU General Public License
along with this program; if not, write to the Free Software
Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA
02111-1307, USA.
The GNU General Public License is contained in the file COPYING.
*/
// Author: Konstantin Serebryany.
// Parts of the code in this file are derived from Helgrind,
// a data race detector written by Julian Seward.
// Note that the rest of ThreadSanitizer code is not derived from Helgrind
// and is published under the BSD license.
#define _GNU_SOURCE 1
#include <stdio.h>
#include <stdlib.h>
#include <assert.h>
#include <errno.h>
#include <pthread.h>
#include <fcntl.h> // O_CREAT
#include <unistd.h> // F_LOCK
#include "valgrind.h"
#include "pub_tool_basics.h"
#include "pub_tool_redir.h"
#include "pub_tool_threadstate.h"
#define NOINLINE __attribute__ ((noinline))
#include "ts_valgrind_client_requests.h"
// When replacing a function in valgrind, the replacement code
// is instrumented, so we just don't touch reads/writes in replacement
// functions.
#define EXTRA_REPLACE_PARAMS
#define EXTRA_REPLACE_ARGS
#define REPORT_READ_RANGE(x, size)
#define REPORT_WRITE_RANGE(x, size)
#include "ts_replace.h"
#define TRACE_PTH_FNS 0
#define TRACE_ANN_FNS 0
//----------- Basic stuff --------------------------- {{{1
static inline int VALGRIND_TS_THREAD_ID(void) {
unsigned int _qzz_res;
VALGRIND_DO_CLIENT_REQUEST(_qzz_res, 0 ,
TSREQ_GET_THREAD_ID,
0, 0, 0, 0, 0);
return _qzz_res;
}
static inline int VALGRIND_VG_THREAD_ID(void) {
unsigned int _qzz_res;
VALGRIND_DO_CLIENT_REQUEST(_qzz_res, 0 ,
TSREQ_GET_VG_THREAD_ID,
0, 0, 0, 0, 0);
return _qzz_res;
}
static inline int VALGRIND_TS_SEGMENT_ID(void) {
unsigned int _qzz_res;
VALGRIND_DO_CLIENT_REQUEST(_qzz_res, 0 ,
TSREQ_GET_SEGMENT_ID,
0, 0, 0, 0, 0);
return _qzz_res;
}
#define PTH_FUNC(ret_ty, f, args...) \
ret_ty I_WRAP_SONAME_FNNAME_ZZ(VG_Z_LIBPTHREAD_SONAME,f)(args); \
ret_ty I_WRAP_SONAME_FNNAME_ZZ(VG_Z_LIBPTHREAD_SONAME,f)(args)
#define NONE_FUNC(ret_ty, f, args...) \
ret_ty I_WRAP_SONAME_FNNAME_ZZ(NONE,f)(args); \
ret_ty I_WRAP_SONAME_FNNAME_ZZ(NONE,f)(args)
#define LIBC_FUNC(ret_ty, f, args...) \
ret_ty I_WRAP_SONAME_FNNAME_ZZ(VG_Z_LIBC_SONAME,f)(args); \
ret_ty I_WRAP_SONAME_FNNAME_ZZ(VG_Z_LIBC_SONAME,f)(args)
// libstdcZpZpZa = libstdc++
#define LIBSTDCXX_FUNC(ret_ty, f, args...) \
ret_ty I_WRAP_SONAME_FNNAME_ZZ(VG_Z_LIBSTDCXX_SONAME,f)(args); \
ret_ty I_WRAP_SONAME_FNNAME_ZZ(VG_Z_LIBSTDCXX_SONAME,f)(args)
// Do a client request. This is a macro rather than a function
// so as to avoid having an extra function in the stack trace.
#define DO_CREQ_v_v(_creqF) \
do { \
Word _unused_res; \
VALGRIND_DO_CLIENT_REQUEST(_unused_res, 0, \
(_creqF), \
0,0,0,0,0); \
} while (0)
#define DO_CREQ_v_W(_creqF, _ty1F,_arg1F) \
do { \
Word _unused_res, _arg1; \
assert(sizeof(_ty1F) == sizeof(Word)); \
_arg1 = (Word)(_arg1F); \
VALGRIND_DO_CLIENT_REQUEST(_unused_res, 0, \
(_creqF), \
_arg1, 0,0,0,0); \
} while (0)
#define DO_CREQ_v_WW(_creqF, _ty1F,_arg1F, _ty2F,_arg2F) \
do { \
Word _unused_res, _arg1, _arg2; \
assert(sizeof(_ty1F) == sizeof(Word)); \
assert(sizeof(_ty2F) == sizeof(Word)); \
_arg1 = (Word)(_arg1F); \
_arg2 = (Word)(_arg2F); \
VALGRIND_DO_CLIENT_REQUEST(_unused_res, 0, \
(_creqF), \
_arg1,_arg2,0,0,0); \
} while (0)
#define DO_CREQ_W_WW(_resF, _creqF, _ty1F,_arg1F, _ty2F,_arg2F) \
do { \
Word _res, _arg1, _arg2; \
assert(sizeof(_ty1F) == sizeof(Word)); \
assert(sizeof(_ty2F) == sizeof(Word)); \
_arg1 = (Word)(_arg1F); \
_arg2 = (Word)(_arg2F); \
VALGRIND_DO_CLIENT_REQUEST(_res, 2, \
(_creqF), \
_arg1,_arg2,0,0,0); \
_resF = _res; \
} while (0)
#define DO_CREQ_v_WWW(_creqF, _ty1F,_arg1F, \
_ty2F,_arg2F, _ty3F, _arg3F) \
do { \
Word _unused_res, _arg1, _arg2, _arg3; \
assert(sizeof(_ty1F) == sizeof(Word)); \
assert(sizeof(_ty2F) == sizeof(Word)); \
assert(sizeof(_ty3F) == sizeof(Word)); \
_arg1 = (Word)(_arg1F); \
_arg2 = (Word)(_arg2F); \
_arg3 = (Word)(_arg3F); \
VALGRIND_DO_CLIENT_REQUEST(_unused_res, 0, \
(_creqF), \
_arg1,_arg2,_arg3,0,0); \
} while (0)
#define DO_CREQ_v_WWWW(_creqF, _ty1F,_arg1F, _ty2F,_arg2F,\
_ty3F,_arg3F, _ty4F, _arg4F) \
do { \
Word _unused_res, _arg1, _arg2, _arg3, _arg4; \
assert(sizeof(_ty1F) == sizeof(Word)); \
assert(sizeof(_ty2F) == sizeof(Word)); \
assert(sizeof(_ty3F) == sizeof(Word)); \
assert(sizeof(_ty4F) == sizeof(Word)); \
_arg1 = (Word)(_arg1F); \
_arg2 = (Word)(_arg2F); \
_arg3 = (Word)(_arg3F); \
_arg4 = (Word)(_arg4F); \
VALGRIND_DO_CLIENT_REQUEST(_unused_res, 0, \
(_creqF), \
_arg1,_arg2,_arg3,_arg4,0); \
} while (0)
#define DO_PthAPIerror(_fnnameF, _errF) \
do { \
char* _fnname = (char*)(_fnnameF); \
long _err = (long)(int)(_errF); \
char* _errstr = lame_strerror(_err); \
DO_CREQ_v_WWW(TSREQ_PTH_API_ERROR, \
char*,_fnname, \
long,_err, char*,_errstr); \
} while (0)
static inline void IGNORE_ALL_ACCESSES_BEGIN(void) {
DO_CREQ_v_W(TSREQ_IGNORE_ALL_ACCESSES_BEGIN, void*, NULL);
}
static inline void IGNORE_ALL_ACCESSES_END(void) {
DO_CREQ_v_W(TSREQ_IGNORE_ALL_ACCESSES_END, void*, NULL);
}
static inline void IGNORE_ALL_SYNC_BEGIN(void) {
DO_CREQ_v_W(TSREQ_IGNORE_ALL_SYNC_BEGIN, void*, NULL);
}
static inline void IGNORE_ALL_SYNC_END(void) {
DO_CREQ_v_W(TSREQ_IGNORE_ALL_SYNC_END, void*, NULL);
}
static inline void IGNORE_ALL_ACCESSES_AND_SYNC_BEGIN(void) {
IGNORE_ALL_ACCESSES_BEGIN();
IGNORE_ALL_SYNC_BEGIN();
}
static inline void IGNORE_ALL_ACCESSES_AND_SYNC_END(void) {
IGNORE_ALL_ACCESSES_END();
IGNORE_ALL_SYNC_END();
}
//-------------- Wrapper for main() -------- {{{1
#define MAIN_WRAPPER_DECL \
int I_WRAP_SONAME_FNNAME_ZU(NONE,main) (long argc, char **argv, char **env)
MAIN_WRAPPER_DECL;
MAIN_WRAPPER_DECL {
int ret;
OrigFn fn;
VALGRIND_GET_ORIG_FN(fn);
DO_CREQ_v_WW(TSREQ_MAIN_IN, long, argc, char **, argv);
CALL_FN_W_WWW(ret, fn, argc, argv, env);
DO_CREQ_v_W(TSREQ_MAIN_OUT, void*, ret);
return ret;
}
//-------------- MALLOC -------------------- {{{1
// We ignore memory accesses and sync events inside malloc.
// Accesses are ignored so that we don't spend time on them.
// Sync events are ignored so that malloc does not create h-b arcs.
// Currently, we ignore only Lock/Unlock events, not any other sync events.
#define WRAP_MALLOC(soname, fnname) \
void* I_WRAP_SONAME_FNNAME_ZU(soname,fnname) (SizeT n); \
void* I_WRAP_SONAME_FNNAME_ZU(soname,fnname) (SizeT n) { \
void* ret; \
OrigFn fn;\
VALGRIND_GET_ORIG_FN(fn);\
IGNORE_ALL_ACCESSES_AND_SYNC_BEGIN(); \
CALL_FN_W_W(ret, fn, n); \
IGNORE_ALL_ACCESSES_AND_SYNC_END(); \
DO_CREQ_v_WW(TSREQ_MALLOC, void*, ret, long, n); \
return ret; \
}
#define WRAP_CALLOC(soname, fnname) \
void* I_WRAP_SONAME_FNNAME_ZU(soname,fnname) (SizeT n, SizeT c); \
void* I_WRAP_SONAME_FNNAME_ZU(soname,fnname) (SizeT n, SizeT c) { \
void* ret; \
OrigFn fn;\
VALGRIND_GET_ORIG_FN(fn);\
IGNORE_ALL_ACCESSES_AND_SYNC_BEGIN(); \
CALL_FN_W_WW(ret, fn, n, c); \
IGNORE_ALL_ACCESSES_AND_SYNC_END(); \
DO_CREQ_v_WW(TSREQ_MALLOC, void*, ret, long, n * c); \
return ret; \
}
#define WRAP_REALLOC(soname, fnname) \
void* I_WRAP_SONAME_FNNAME_ZU(soname,fnname) (void *ptr, SizeT n); \
void* I_WRAP_SONAME_FNNAME_ZU(soname,fnname) (void *ptr, SizeT n) { \
void* ret; \
OrigFn fn;\
VALGRIND_GET_ORIG_FN(fn);\
IGNORE_ALL_ACCESSES_AND_SYNC_BEGIN(); \
CALL_FN_W_WW(ret, fn, ptr, n); \
IGNORE_ALL_ACCESSES_AND_SYNC_END(); \
DO_CREQ_v_WW(TSREQ_MALLOC, void*, ret, long, n); \
return ret; \
}
#define WRAP_POSIX_MEMALIGN(soname, fnname) \
int I_WRAP_SONAME_FNNAME_ZU(soname,fnname) (void **ptr, long a, long size);\
int I_WRAP_SONAME_FNNAME_ZU(soname,fnname) (void **ptr, long a, long size){\
OrigFn fn;\
int ret;\
VALGRIND_GET_ORIG_FN(fn);\
IGNORE_ALL_ACCESSES_AND_SYNC_BEGIN(); \
CALL_FN_W_WWW(ret, fn, ptr, a, size); \
IGNORE_ALL_ACCESSES_AND_SYNC_END(); \
if (ret == 0) \
DO_CREQ_v_WW(TSREQ_MALLOC, void*, *ptr, long, size); \
return ret; \
}
#define WRAP_WORKQ_OPS(soname, fnname) \
int I_WRAP_SONAME_FNNAME_ZU(soname,fnname) (int options, void* item, \
int priority);\
int I_WRAP_SONAME_FNNAME_ZU(soname,fnname) (int options, void* item, \
int priority){\
OrigFn fn;\
int ret;\
VALGRIND_GET_ORIG_FN(fn);\
CALL_FN_W_WWW(ret, fn, options, item, priority); \
/* Trigger only on workq_ops(QUEUE_ADD) */ \
if (options == 1) { \
DO_CREQ_v_W(TSREQ_SIGNAL, void*,item); \
} \
return ret; \
}
WRAP_WORKQ_OPS(VG_Z_LIBC_SONAME, __workq_ops);
#ifdef ANDROID
#define OFF_T_SIZE 4
#else
// TODO: this is probably wrong for 32-bit code without -D_FILE_OFFSET_BITS=64
#define OFF_T_SIZE 8
#endif
// Hacky workaround for https://bugs.kde.org/show_bug.cgi?id=228471
// Used in mmap and lockf wrappers.
#if VG_WORDSIZE < OFF_T_SIZE
typedef unsigned long long OFF_T;
#define CALL_FN_W_5WO_T(ret,fn,p1,p2,p3,p4,p5,off_t_p) CALL_FN_W_7W(ret,fn,\
p1,p2,p3,p4,p5,off_t_p & 0xffffffff, off_t_p >> 32)
#define CALL_FN_W_2WO_T(ret,fn,p1,p2,off_t_p) CALL_FN_W_WWWW(ret,fn,\
p1,p2,off_t_p & 0xffffffff, off_t_p >> 32)
#else
typedef long OFF_T;
#define CALL_FN_W_5WO_T(ret,fn,p1,p2,p3,p4,p5,off_t_p) CALL_FN_W_6W(ret,fn,\
p1,p2,p3,p4,p5,off_t_p)
#define CALL_FN_W_2WO_T(ret,fn,p1,p2,off_t_p) CALL_FN_W_WWW(ret,fn,\
p1,p2,off_t_p)
#endif
#define WRAP_MMAP(soname, fnname) \
void* I_WRAP_SONAME_FNNAME_ZU(soname,fnname) (void *ptr, long size, long a, \
long b, long c, OFF_T d); \
void* I_WRAP_SONAME_FNNAME_ZU(soname,fnname) (void *ptr, long size, long a, \
long b, long c, OFF_T d){ \
void* ret;\
OrigFn fn;\
VALGRIND_GET_ORIG_FN(fn);\
IGNORE_ALL_ACCESSES_AND_SYNC_BEGIN(); \
CALL_FN_W_5WO_T(ret, fn, ptr, size, a, b, c, d); \
IGNORE_ALL_ACCESSES_AND_SYNC_END(); \
if (ret != (void*)-1) { \
DO_CREQ_v_WW(TSREQ_MMAP, void*, ret, long, size); \
} \
return ret; \
}
#define WRAP_MUNMAP(soname, fnname) \
int I_WRAP_SONAME_FNNAME_ZU(soname,fnname) (void *ptr, size_t size); \
int I_WRAP_SONAME_FNNAME_ZU(soname,fnname) (void *ptr, size_t size){ \
int ret;\
OrigFn fn;\
VALGRIND_GET_ORIG_FN(fn);\
IGNORE_ALL_ACCESSES_AND_SYNC_BEGIN(); \
CALL_FN_W_WW(ret, fn, ptr, size); \
IGNORE_ALL_ACCESSES_AND_SYNC_END(); \
if (ret == 0) { \
DO_CREQ_v_WW(TSREQ_MUNMAP, void*, ptr, size_t, size); \
} \
return ret; \
}
#define WRAP_ZONE_MALLOC(soname, fnname) \
void* I_WRAP_SONAME_FNNAME_ZU(soname,fnname) (void* zone, SizeT n); \
void* I_WRAP_SONAME_FNNAME_ZU(soname,fnname) (void* zone, SizeT n) { \
void* ret; \
OrigFn fn;\
VALGRIND_GET_ORIG_FN(fn);\
IGNORE_ALL_ACCESSES_AND_SYNC_BEGIN(); \
CALL_FN_W_WW(ret, fn, zone, n); \
IGNORE_ALL_ACCESSES_AND_SYNC_END(); \
DO_CREQ_v_WW(TSREQ_MALLOC, void*, ret, long, n); \
return ret; \
}
#define WRAP_ZONE_CALLOC(soname, fnname) \
void* I_WRAP_SONAME_FNNAME_ZU(soname,fnname) (void* zone, SizeT n, SizeT c); \
void* I_WRAP_SONAME_FNNAME_ZU(soname,fnname) (void* zone, SizeT n, SizeT c) { \
void* ret; \
OrigFn fn;\
VALGRIND_GET_ORIG_FN(fn);\
IGNORE_ALL_ACCESSES_AND_SYNC_BEGIN(); \
CALL_FN_W_WWW(ret, fn, zone, n, c); \
IGNORE_ALL_ACCESSES_AND_SYNC_END(); \
DO_CREQ_v_WW(TSREQ_MALLOC, void*, ret, long, n * c); \
return ret; \
}
#define WRAP_ZONE_REALLOC(soname, fnname) \
void* I_WRAP_SONAME_FNNAME_ZU(soname,fnname) (void* zone, void *ptr, SizeT n); \
void* I_WRAP_SONAME_FNNAME_ZU(soname,fnname) (void* zone, void *ptr, SizeT n) { \
void* ret; \
OrigFn fn;\
VALGRIND_GET_ORIG_FN(fn);\
IGNORE_ALL_ACCESSES_AND_SYNC_BEGIN(); \
CALL_FN_W_WWW(ret, fn, zone, ptr, n); \
IGNORE_ALL_ACCESSES_AND_SYNC_END(); \
DO_CREQ_v_WW(TSREQ_MALLOC, void*, ret, long, n); \
return ret; \
}
WRAP_ZONE_MALLOC(VG_Z_LIBC_SONAME, malloc_zone_malloc);
WRAP_ZONE_CALLOC(VG_Z_LIBC_SONAME, malloc_zone_calloc);
WRAP_ZONE_REALLOC(VG_Z_LIBC_SONAME, malloc_zone_realloc);
WRAP_MALLOC(VG_Z_LIBC_SONAME, malloc);
WRAP_MALLOC(NONE, malloc);
WRAP_MALLOC(VG_Z_LIBC_SONAME, valloc);
WRAP_MALLOC(NONE, valloc);
WRAP_MALLOC(VG_Z_LIBC_SONAME, pvalloc);
WRAP_MALLOC(NONE, pvalloc);
WRAP_MALLOC(NONE, _Znam);
WRAP_MALLOC(NONE, _Znwm);
WRAP_MALLOC(NONE, _Znaj);
WRAP_MALLOC(NONE, _Znwj);
WRAP_MALLOC(NONE, _ZnamRKSt9nothrow_t);
WRAP_MALLOC(NONE, _ZnwmRKSt9nothrow_t);
WRAP_MALLOC(NONE, _ZnajRKSt9nothrow_t);
WRAP_MALLOC(NONE, _ZnwjRKSt9nothrow_t);
// same for libstdc++.
WRAP_MALLOC(VG_Z_LIBSTDCXX_SONAME, _Znam);
WRAP_MALLOC(VG_Z_LIBSTDCXX_SONAME, _Znwm);
WRAP_MALLOC(VG_Z_LIBSTDCXX_SONAME, _Znaj);
WRAP_MALLOC(VG_Z_LIBSTDCXX_SONAME, _Znwj);
WRAP_MALLOC(VG_Z_LIBSTDCXX_SONAME, _ZnamRKSt9nothrow_t);
WRAP_MALLOC(VG_Z_LIBSTDCXX_SONAME, _ZnwmRKSt9nothrow_t);
WRAP_MALLOC(VG_Z_LIBSTDCXX_SONAME, _ZnajRKSt9nothrow_t);
WRAP_MALLOC(VG_Z_LIBSTDCXX_SONAME, _ZnwjRKSt9nothrow_t);
WRAP_CALLOC(VG_Z_LIBC_SONAME, calloc);
WRAP_CALLOC(NONE, calloc);
WRAP_REALLOC(VG_Z_LIBC_SONAME, realloc); // TODO: handle free inside realloc
WRAP_REALLOC(NONE, realloc); // TODO: handle free inside realloc
WRAP_REALLOC(VG_Z_LIBC_SONAME, memalign);
WRAP_REALLOC(NONE, memalign);
WRAP_POSIX_MEMALIGN(VG_Z_LIBC_SONAME, posix_memalign);
WRAP_POSIX_MEMALIGN(NONE, posix_memalign);
WRAP_MMAP(VG_Z_LIBC_SONAME, mmap);
WRAP_MMAP(NONE, mmap);
WRAP_MUNMAP(VG_Z_LIBC_SONAME, munmap);
WRAP_MUNMAP(NONE, munmap);
#define WRAP_FREE(soname, fnname) \
void I_WRAP_SONAME_FNNAME_ZU(soname,fnname) (void *ptr); \
void I_WRAP_SONAME_FNNAME_ZU(soname,fnname) (void *ptr) { \
OrigFn fn;\
VALGRIND_GET_ORIG_FN(fn);\
DO_CREQ_v_W(TSREQ_FREE, void*, ptr); \
IGNORE_ALL_ACCESSES_AND_SYNC_BEGIN(); \
CALL_FN_v_W(fn, ptr); \
IGNORE_ALL_ACCESSES_AND_SYNC_END(); \
}
#define WRAP_FREE_ZZ(soname, fnname) \
void I_WRAP_SONAME_FNNAME_ZZ(soname,fnname) (void *ptr); \
void I_WRAP_SONAME_FNNAME_ZZ(soname,fnname) (void *ptr) { \
OrigFn fn;\
VALGRIND_GET_ORIG_FN(fn);\
DO_CREQ_v_W(TSREQ_FREE, void*, ptr); \
IGNORE_ALL_ACCESSES_AND_SYNC_BEGIN(); \
CALL_FN_v_W(fn, ptr); \
IGNORE_ALL_ACCESSES_AND_SYNC_END(); \
}
#define WRAP_ZONE_FREE(soname, fnname) \
void I_WRAP_SONAME_FNNAME_ZU(soname,fnname) (void *zone, void *ptr); \
void I_WRAP_SONAME_FNNAME_ZU(soname,fnname) (void *zone, void *ptr) { \
OrigFn fn;\
VALGRIND_GET_ORIG_FN(fn);\
DO_CREQ_v_W(TSREQ_FREE, void*, ptr); \
IGNORE_ALL_ACCESSES_AND_SYNC_BEGIN(); \
CALL_FN_v_WW(fn, zone, ptr); \
IGNORE_ALL_ACCESSES_AND_SYNC_END(); \
}
WRAP_FREE(VG_Z_LIBC_SONAME, free);
WRAP_ZONE_FREE(VG_Z_LIBC_SONAME, malloc_zone_free);
WRAP_FREE(NONE, free);
WRAP_FREE(NONE, _ZdlPv);
WRAP_FREE(NONE, _ZdaPv);
WRAP_FREE(NONE, _ZdlPvRKSt9nothrow_t);
WRAP_FREE(NONE, _ZdaPvRKSt9nothrow_t);
// same for libstdc++
WRAP_FREE(VG_Z_LIBSTDCXX_SONAME, _ZdlPv);
WRAP_FREE(VG_Z_LIBSTDCXX_SONAME, _ZdaPv);
WRAP_FREE(VG_Z_LIBSTDCXX_SONAME, _ZdlPvRKSt9nothrow_t);
WRAP_FREE(VG_Z_LIBSTDCXX_SONAME, _ZdaPvRKSt9nothrow_t);
// operator delete
WRAP_FREE_ZZ(NONE, operatorZsdeleteZa);
/* Handle tcmalloc (http://code.google.com/p/google-perftools/) */
/* tc_ functions (used when tcmalloc is running in release mode) */
WRAP_MALLOC(NONE,tc_malloc);
WRAP_MALLOC(NONE,tc_new);
WRAP_MALLOC(NONE,tc_new_nothrow);
WRAP_MALLOC(NONE,tc_newarray);
WRAP_MALLOC(NONE,tc_newarray_nothrow);
WRAP_FREE(NONE,tc_free);
WRAP_FREE(NONE,tc_cfree);
WRAP_FREE(NONE,tc_delete);
WRAP_FREE(NONE,tc_delete_nothrow);
WRAP_FREE(NONE,tc_deletearray);
WRAP_FREE(NONE,tc_deletearray_nothrow);
WRAP_CALLOC(NONE,tc_calloc);
WRAP_REALLOC(NONE,tc_realloc);
WRAP_MALLOC(NONE,tc_valloc);
WRAP_POSIX_MEMALIGN(NONE,tc_memalign);
WRAP_POSIX_MEMALIGN(NONE,tc_posix_memalign);
//------------ Wrappers for stdio functions ---------
/* These functions have internal synchronization that we don't handle and get
lots of false positives. To fix this, we wrap these functions, touch their
arguments, and pass them through to the original function, ignoring all
memory accesses inside it. */
size_t I_WRAP_SONAME_FNNAME_ZU(VG_Z_LIBC_SONAME, fwrite) (const void *ptr, size_t size, size_t nmemb, void* stream);
size_t I_WRAP_SONAME_FNNAME_ZU(VG_Z_LIBC_SONAME, fwrite) (const void *ptr, size_t size, size_t nmemb, void* stream) {
size_t ret;
OrigFn fn;
ReadMemory(ptr, size * nmemb);
VALGRIND_GET_ORIG_FN(fn);
IGNORE_ALL_ACCESSES_AND_SYNC_BEGIN();
CALL_FN_W_WWWW(ret, fn, ptr, size, nmemb, stream);
IGNORE_ALL_ACCESSES_AND_SYNC_END();
return ret;
}
int I_WRAP_SONAME_FNNAME_ZU(VG_Z_LIBC_SONAME, puts) (const char *s);
int I_WRAP_SONAME_FNNAME_ZU(VG_Z_LIBC_SONAME, puts) (const char *s) {
int ret;
OrigFn fn;
ReadString(s);
VALGRIND_GET_ORIG_FN(fn);
IGNORE_ALL_ACCESSES_AND_SYNC_BEGIN();
CALL_FN_W_W(ret, fn, s);
IGNORE_ALL_ACCESSES_AND_SYNC_END();
return ret;
}
//-------------- PTHREADS -------------------- {{{1
/* A lame version of strerror which doesn't use the real libc
strerror_r, since using the latter just generates endless more
threading errors (glibc goes off and does tons of crap w.r.t.
locales etc) */
static char* lame_strerror ( long err )
{ switch (err) {
case EPERM: return "EPERM: Operation not permitted";
case ENOENT: return "ENOENT: No such file or directory";
case ESRCH: return "ESRCH: No such process";
case EINTR: return "EINTR: Interrupted system call";
case EBADF: return "EBADF: Bad file number";
case EAGAIN: return "EAGAIN: Try again";
case ENOMEM: return "ENOMEM: Out of memory";
case EACCES: return "EACCES: Permission denied";
case EFAULT: return "EFAULT: Bad address";
case EEXIST: return "EEXIST: File exists";
case EINVAL: return "EINVAL: Invalid argument";
case EMFILE: return "EMFILE: Too many open files";
case ENOSYS: return "ENOSYS: Function not implemented";
case EOVERFLOW: return "EOVERFLOW: Value too large "
"for defined data type";
case EBUSY: return "EBUSY: Device or resource busy";
case ETIMEDOUT: return "ETIMEDOUT: Connection timed out";
case EDEADLK: return "EDEADLK: Resource deadlock would occur";
case EOPNOTSUPP: return "EOPNOTSUPP: Operation not supported on "
"transport endpoint"; /* honest, guv */
default: return "tc_intercepts.c: lame_strerror(): "
"unhandled case -- please fix me!";
}
}
// libpthread sentry functions.
// Darwin implementations of several libpthread functions call other functions
// that are intercepted by ThreadSanitizer as well. To avoid reacting on those
// functions twice the status of each Valgrind thread is stored in the
// tid_inside_pthread_lib array and all the client requests from the inner
// pthread functions are ignored.
static int tid_inside_pthread_lib[VG_N_THREADS];
// A pthread_*() function must call pthread_lib_enter() if its implementation
// calls or is called by another pthread_*() function. The function that
// called pthread_lib_enter() should perform client requests to ThreadSanitizer
// iff the return value of pthread_lib_enter() is equal to 1.
static int pthread_lib_enter(void) {
int ret = 1, tid;
IGNORE_ALL_ACCESSES_BEGIN();
tid = VALGRIND_VG_THREAD_ID();
if (tid_inside_pthread_lib[tid]++) {
ret = 0;
} else {
ret = 1;
}
IGNORE_ALL_ACCESSES_END();
return ret;
}
// A pthread_*() function must call pthread_lib_exit() iff it has called
// pthread_lib_enter().
static void pthread_lib_exit(void) {
int tid;
IGNORE_ALL_ACCESSES_BEGIN();
tid = VALGRIND_VG_THREAD_ID();
tid_inside_pthread_lib[tid]--;
IGNORE_ALL_ACCESSES_END();
}
/*----------------------------------------------------------------*/
/*--- pthread_create, pthread_join, pthread_exit ---*/
/*----------------------------------------------------------------*/
static void* ThreadSanitizerStartThread ( void* xargsV )
{
volatile Word volatile* xargs = (volatile Word volatile*) xargsV;
void*(*fn)(void*) = (void*(*)(void*))xargs[0];
void* arg = (void*)xargs[1];
pthread_t me = pthread_self();
size_t stacksize = 0;
void *stackaddr = NULL;
pthread_attr_t attr;
/* Tell the tool what my pthread_t is. */
DO_CREQ_v_W(TSREQ_SET_MY_PTHREAD_T, pthread_t,me);
#ifdef VGO_darwin
/* Tell the tool what my stack size and stack top are.
This is Darwin-specific and works as long as ThreadSanitizerStartThread
is used for pthreads only.
*/
stacksize = pthread_get_stacksize_np(me);
stackaddr = pthread_get_stackaddr_np(me);
DO_CREQ_v_WW(TSREQ_SET_STACKTOP_STACKSIZE, void*, stackaddr,
size_t, stacksize);
#else
if (pthread_getattr_np(pthread_self(), &attr) == 0) {
pthread_attr_getstack(&attr, &stackaddr, &stacksize);
pthread_attr_destroy(&attr);
DO_CREQ_v_WW(TSREQ_SET_STACKTOP_STACKSIZE,
void*, (char*)stackaddr + stacksize,
size_t, stacksize);
} else {
/* Let the tool guess where the stack starts. */
DO_CREQ_v_W(TSREQ_THR_STACK_TOP, void*, &stacksize);
}
#endif
/* allow the parent to proceed. We can't let it proceed until
we're ready because (1) we need to make sure it doesn't exit and
hence deallocate xargs[] while we still need it, and (2) we
don't want either parent nor child to proceed until the tool has
been notified of the child's pthread_t. */
xargs[2] = 0;
/* Now we can no longer safely use xargs[]. */
return (void*) fn( (void*)arg );
}
static int pthread_create_WRK(pthread_t *thread, const pthread_attr_t *attr,
void *(*start) (void *), void *arg)
{
int ret;
OrigFn fn;
volatile Word xargs[3];
VALGRIND_GET_ORIG_FN(fn);
if (TRACE_PTH_FNS) {
fprintf(stderr, "<< pthread_create wrapper"); fflush(stderr);
}
xargs[0] = (Word)start;
xargs[1] = (Word)arg;
xargs[2] = 1; /* serves as a spinlock -- sigh */
IGNORE_ALL_ACCESSES_BEGIN();
CALL_FN_W_WWWW(ret, fn, thread,attr,ThreadSanitizerStartThread,&xargs[0]);
IGNORE_ALL_ACCESSES_END();
if (ret == 0) {
/* we have to wait for the child to notify the tool of its
pthread_t before continuing */
while (xargs[2] != 0) {
/* Do nothing. We need to spin until the child writes to
xargs[2]. However, that can lead to starvation in the
child and very long delays (eg, tc19_shadowmem on
ppc64-linux Fedora Core 6). So yield the cpu if we can,
to let the child run at the earliest available
opportunity. */
sched_yield();
}
} else {
DO_PthAPIerror( "pthread_create", ret );
}
if (TRACE_PTH_FNS) {
fprintf(stderr, " :: pth_create -> %d >>\n", ret);
}
return ret;
}
PTH_FUNC(int, pthreadZucreate, // pthread_create (Darwin)
pthread_t *thread, const pthread_attr_t *attr,
void *(*start) (void *), void *arg) {
return pthread_create_WRK(thread, attr, start, arg);
}
PTH_FUNC(int, pthreadZucreateZAZa, // pthread_create@* (Linux)
pthread_t *thread, const pthread_attr_t *attr,
void *(*start) (void *), void *arg) {
return pthread_create_WRK(thread, attr, start, arg);
}
// pthread_join
static int pthread_join_WRK(pthread_t thread, void** value_pointer)
{
int ret;
OrigFn fn;
VALGRIND_GET_ORIG_FN(fn);
if (TRACE_PTH_FNS) {
fprintf(stderr, "<< pthread_join wrapper"); fflush(stderr);
}
CALL_FN_W_WW(ret, fn, thread,value_pointer);
/* At least with NPTL as the thread library, this is safe because
it is guaranteed (by NPTL) that the joiner will completely gone
before pthread_join (the original) returns. See email below.*/
if (ret == 0 /*success*/) {
DO_CREQ_v_W(TSREQ_PTHREAD_JOIN_POST, pthread_t,thread);
} else {
DO_PthAPIerror( "pthread_join", ret );
}
if (TRACE_PTH_FNS) {
fprintf(stderr, " :: pth_join -> %d >>\n", ret);
}
return ret;
}
PTH_FUNC(int, pthreadZujoin, // pthread_join (Linux)
pthread_t thread, void** value_pointer)
{
return pthread_join_WRK(thread, value_pointer);
}
PTH_FUNC(int, pthreadZujoin$Za, // pthread_join$* (Darwin)
pthread_t thread, void** value_pointer)
{
return pthread_join_WRK(thread, value_pointer);
}
/* Behaviour of pthread_join on NPTL:
Me:
I have a question re the NPTL pthread_join implementation.
Suppose I am the thread 'stayer'.
If I call pthread_join(quitter), is it guaranteed that the
thread 'quitter' has really exited before pthread_join returns?
IOW, is it guaranteed that 'quitter' will not execute any further
instructions after pthread_join returns?
I believe this is true based on the following analysis of
glibc-2.5 sources. However am not 100% sure and would appreciate
confirmation.
'quitter' will be running start_thread() in nptl/pthread_create.c
The last action of start_thread() is to exit via
__exit_thread_inline(0), which simply does sys_exit
(nptl/pthread_create.c:403)
'stayer' meanwhile is waiting for lll_wait_tid (pd->tid)
(call at nptl/pthread_join.c:89)
As per comment at nptl/sysdeps/unix/sysv/linux/i386/lowlevellock.h:536,
lll_wait_tid will not return until kernel notifies via futex
wakeup that 'quitter' has terminated.
Hence pthread_join cannot return until 'quitter' really has
completely disappeared.
Drepper:
> As per comment at nptl/sysdeps/unix/sysv/linux/i386/lowlevellock.h:536,
> lll_wait_tid will not return until kernel notifies via futex
> wakeup that 'quitter' has terminated.
That's the key. The kernel resets the TID field after the thread is
done. No way the joiner can return before the thread is gone.
*/
#ifdef ANDROID
// Android-specific part. Ignore some internal synchronization in bionic.
PTH_FUNC(int, pthreadZuexit, void* retval) // pthread_exit (Android)
{
int ret;
OrigFn fn;
VALGRIND_GET_ORIG_FN(fn);
IGNORE_ALL_ACCESSES_AND_SYNC_BEGIN();
CALL_FN_W_W(ret, fn, retval);
IGNORE_ALL_ACCESSES_AND_SYNC_END();
return ret;
}
#endif
/*----------------------------------------------------------------*/
/*--- pthread_mutex_t functions ---*/
/*----------------------------------------------------------------*/
/* Handled: pthread_mutex_init pthread_mutex_destroy
pthread_mutex_lock
pthread_mutex_trylock
pthread_mutex_timedlock
pthread_mutex_unlock
pthread_spin_init pthread_spin_destroy
pthread_spin_lock
pthread_spin_trylock
pthread_spin_unlock
*/
// pthread_mutex_init
PTH_FUNC(int, pthreadZumutexZuinit, // pthread_mutex_init
pthread_mutex_t *mutex,
pthread_mutexattr_t* attr)
{
int ret;
long mbRec;
OrigFn fn;
VALGRIND_GET_ORIG_FN(fn);
if (TRACE_PTH_FNS) {
fprintf(stderr, "<< pthread_mxinit %p", mutex); fflush(stderr);
}
mbRec = 0;
if (attr) {
int ty, zzz;
zzz = pthread_mutexattr_gettype(attr, &ty);
if (zzz == 0 && ty == PTHREAD_MUTEX_RECURSIVE)
mbRec = 1;
}
CALL_FN_W_WW(ret, fn, mutex,attr);
if (ret == 0 /*success*/) {
DO_CREQ_v_WW(TSREQ_PTHREAD_RWLOCK_CREATE_POST,
pthread_mutex_t*,mutex, long,mbRec);
} else {
DO_PthAPIerror( "pthread_mutex_init", ret );
}
if (TRACE_PTH_FNS) {
fprintf(stderr, " :: mxinit -> %d >>\n", ret);
}
return ret;
}
// pthread_mutex_destroy
PTH_FUNC(int, pthreadZumutexZudestroy, // pthread_mutex_destroy
pthread_mutex_t *mutex)
{
int ret;
OrigFn fn;
VALGRIND_GET_ORIG_FN(fn);
if (TRACE_PTH_FNS) {
fprintf(stderr, "<< pthread_mxdestroy %p", mutex); fflush(stderr);
}
DO_CREQ_v_W(TSREQ_PTHREAD_RWLOCK_DESTROY_PRE,
pthread_mutex_t*,mutex);
CALL_FN_W_W(ret, fn, mutex);
if (ret != 0) {
DO_PthAPIerror( "pthread_mutex_destroy", ret );
}
if (TRACE_PTH_FNS) {
fprintf(stderr, " :: mxdestroy -> %d >>\n", ret);
}
return ret;
}
// pthread_mutex_lock
PTH_FUNC(int, pthreadZumutexZulock, // pthread_mutex_lock
pthread_mutex_t *mutex)
{
int ret;
OrigFn fn;
int is_outermost;
VALGRIND_GET_ORIG_FN(fn);
if (TRACE_PTH_FNS) {
fprintf(stderr, "<< pthread_mxlock %p", mutex); fflush(stderr);
}
is_outermost = pthread_lib_enter();
CALL_FN_W_W(ret, fn, mutex);
/* There's a hole here: libpthread now knows the lock is locked,
but the tool doesn't, so some other thread could run and detect
that the lock has been acquired by someone (this thread). Does
this matter? Not sure, but I don't think so. */
if (is_outermost) {
if ((ret == 0 /*success*/)) {
DO_CREQ_v_WW(TSREQ_PTHREAD_RWLOCK_LOCK_POST,
pthread_mutex_t*,mutex, long, 1);
} else {
DO_PthAPIerror( "pthread_mutex_lock", ret );
}
}
if (TRACE_PTH_FNS) {
fprintf(stderr, " :: mxlock -> %d >>\n", ret);
}
pthread_lib_exit();
return ret;
}
// pthread_mutex_trylock. The handling needed here is very similar
// to that for pthread_mutex_lock, except that we need to tell
// the pre-lock creq that this is a trylock-style operation, and
// therefore not to complain if the lock is nonrecursive and
// already locked by this thread -- because then it'll just fail
// immediately with EBUSY.
static int pthread_mutex_trylock_WRK(pthread_mutex_t *mutex)
{
int ret;
OrigFn fn;
VALGRIND_GET_ORIG_FN(fn);
if (TRACE_PTH_FNS) {
fprintf(stderr, "<< pthread_mxtrylock %p", mutex); fflush(stderr);
}
CALL_FN_W_W(ret, fn, mutex);
/* There's a hole here: libpthread now knows the lock is locked,
but the tool doesn't, so some other thread could run and detect
that the lock has been acquired by someone (this thread). Does
this matter? Not sure, but I don't think so. */
if (ret == 0 /*success*/) {
DO_CREQ_v_WW(TSREQ_PTHREAD_RWLOCK_LOCK_POST,
pthread_mutex_t*,mutex, long, 1);
} else {
if (ret != EBUSY)
DO_PthAPIerror( "pthread_mutex_trylock", ret );
}
if (TRACE_PTH_FNS) {
fprintf(stderr, " :: mxtrylock -> %d >>\n", ret);
}
return ret;
}
PTH_FUNC(int, pthreadZumutexZutrylock, // pthread_mutex_trylock
pthread_mutex_t *mutex)
{
return pthread_mutex_trylock_WRK(mutex);
}
// pthread_mutex_timedlock. Identical logic to pthread_mutex_trylock.
// Not implemented in Darwin pthreads.
PTH_FUNC(int, pthreadZumutexZutimedlock, // pthread_mutex_timedlock
pthread_mutex_t *mutex,
void* timeout)
{
int ret;
OrigFn fn;
VALGRIND_GET_ORIG_FN(fn);
if (TRACE_PTH_FNS) {
fprintf(stderr, "<< pthread_mxtimedlock %p %p", mutex, timeout);
fflush(stderr);
}
CALL_FN_W_WW(ret, fn, mutex,timeout);
/* There's a hole here: libpthread now knows the lock is locked,
but the tool doesn't, so some other thread could run and detect
that the lock has been acquired by someone (this thread). Does
this matter? Not sure, but I don't think so. */
if (ret == 0 /*success*/) {
DO_CREQ_v_WW(TSREQ_PTHREAD_RWLOCK_LOCK_POST,
pthread_mutex_t*,mutex, long, 1);
} else {
if (ret != ETIMEDOUT)
DO_PthAPIerror( "pthread_mutex_timedlock", ret );
}
if (TRACE_PTH_FNS) {
fprintf(stderr, " :: mxtimedlock -> %d >>\n", ret);
}
return ret;
}
// pthread_mutex_unlock
PTH_FUNC(int, pthreadZumutexZuunlock, // pthread_mutex_unlock
pthread_mutex_t *mutex)
{
int ret;
OrigFn fn;
VALGRIND_GET_ORIG_FN(fn);
if (TRACE_PTH_FNS) {
fprintf(stderr, "<< pthread_mxunlk %p", mutex); fflush(stderr);
}
DO_CREQ_v_W(TSREQ_PTHREAD_RWLOCK_UNLOCK_PRE,
pthread_mutex_t*,mutex);
CALL_FN_W_W(ret, fn, mutex);
if (ret != 0 /*error*/) {
DO_PthAPIerror( "pthread_mutex_unlock", ret );
}
if (TRACE_PTH_FNS) {
fprintf(stderr, " mxunlk -> %d >>\n", ret);
}
return ret;
}
// pthread_spin_init
PTH_FUNC(int, pthreadZuspinZuinit, void *lock, int pshared) {
int ret;
OrigFn fn;
const char *func = "pthread_spin_init";
VALGRIND_GET_ORIG_FN(fn);
if (TRACE_PTH_FNS) {
fprintf(stderr, "<< %s %p", func, lock);
}
CALL_FN_W_WW(ret, fn, lock, pshared);
if (ret == 0) {
DO_CREQ_v_W(TSREQ_PTHREAD_SPIN_LOCK_INIT_OR_UNLOCK, void *, lock);
}
if (TRACE_PTH_FNS) {
fprintf(stderr, " -- %p >>\n", lock);
}
return ret;
}
// pthread_spin_destroy
PTH_FUNC(int, pthreadZuspinZudestroy, void *lock) {
int ret;
OrigFn fn;
const char *func = "pthread_spin_destroy";
VALGRIND_GET_ORIG_FN(fn);
if (TRACE_PTH_FNS) {
fprintf(stderr, "<< %s %p", func, lock);
}
DO_CREQ_v_W(TSREQ_PTHREAD_RWLOCK_DESTROY_PRE, void*, lock);
CALL_FN_W_W(ret, fn, lock);
if (TRACE_PTH_FNS) {
fprintf(stderr, " -- %p >>\n", lock);
}
return ret;
}
// pthread_spin_lock
PTH_FUNC(int, pthreadZuspinZulock, void *lock) {
int ret;
OrigFn fn;
const char *func = "pthread_spin_lock";
VALGRIND_GET_ORIG_FN(fn);
if (TRACE_PTH_FNS) {
fprintf(stderr, "<< %s %p", func, lock);
}
CALL_FN_W_W(ret, fn, lock);
if (ret == 0) {
DO_CREQ_v_WW(TSREQ_PTHREAD_RWLOCK_LOCK_POST, void *, lock,
long, 1 /*is_w*/);
}
if (TRACE_PTH_FNS) {
fprintf(stderr, " -- %p >>\n", lock);
}
return ret;
}
// pthread_spin_trylock
PTH_FUNC(int, pthreadZuspinZutrylock, void *lock) {
int ret;
OrigFn fn;
const char *func = "pthread_spin_trylock";
VALGRIND_GET_ORIG_FN(fn);
if (TRACE_PTH_FNS) {
fprintf(stderr, "<< %s %p", func, lock);
}
CALL_FN_W_W(ret, fn, lock);
if (ret == 0) {
DO_CREQ_v_WW(TSREQ_PTHREAD_RWLOCK_LOCK_POST, void *, lock,
long, 1 /*is_w*/);
}
if (TRACE_PTH_FNS) {
fprintf(stderr, " -- %p >>\n", lock);
}
return ret;
}
// pthread_spin_unlock
PTH_FUNC(int, pthreadZuspinZuunlock, void *lock) {
int ret;
OrigFn fn;
const char *func = "pthread_spin_unlock";
VALGRIND_GET_ORIG_FN(fn);
if (TRACE_PTH_FNS) {
fprintf(stderr, "<< %s %p", func, lock);
}
DO_CREQ_v_W(TSREQ_PTHREAD_RWLOCK_UNLOCK_PRE, void*, lock);
CALL_FN_W_W(ret, fn, lock);
if (TRACE_PTH_FNS) {
fprintf(stderr, " -- %p >>\n", lock);
}
return ret;
}
/*----------------------------------------------------------------*/
/*--- pthread_cond_t functions ---*/
/*----------------------------------------------------------------*/
/* Handled: pthread_cond_wait pthread_cond_timedwait
pthread_cond_signal pthread_cond_broadcast
Unhandled: pthread_cond_init pthread_cond_destroy
-- are these important?
*/
// pthread_cond_wait
static int pthread_cond_wait_WRK(pthread_cond_t* cond, pthread_mutex_t* mutex)
{
int ret;
OrigFn fn;
int is_outermost = pthread_lib_enter();
VALGRIND_GET_ORIG_FN(fn);
if (TRACE_PTH_FNS) {
fprintf(stderr, "<< pthread_cond_wait %p %p", cond, mutex);
fflush(stderr);
}
if (is_outermost) {
DO_CREQ_v_W(TSREQ_PTHREAD_RWLOCK_UNLOCK_PRE, pthread_mutex_t*,mutex);
}
CALL_FN_W_WW(ret, fn, cond,mutex);
if (is_outermost) {
DO_CREQ_v_W(TSREQ_WAIT, void *,cond);
DO_CREQ_v_WW(TSREQ_PTHREAD_RWLOCK_LOCK_POST, void *, mutex,
long, 1 /*is_w*/);
}
if (ret != 0) {
DO_PthAPIerror( "pthread_cond_wait", ret );
}
if (TRACE_PTH_FNS) {
fprintf(stderr, " cowait -> %d >>\n", ret);
}
pthread_lib_exit();
return ret;
}
PTH_FUNC(int, pthreadZucondZuwaitZAZa, // pthread_cond_wait@*
pthread_cond_t* cond, pthread_mutex_t* mutex)
{
return pthread_cond_wait_WRK(cond, mutex);
}
PTH_FUNC(int, pthreadZucondZuwait$Za, // pthread_cond_wait$*
pthread_cond_t* cond, pthread_mutex_t* mutex)
{
return pthread_cond_wait_WRK(cond, mutex);
}
// pthread_cond_timedwait
static int pthread_cond_timedwait_WRK(pthread_cond_t* cond,
pthread_mutex_t* mutex,
struct timespec* abstime)
{
int ret;
OrigFn fn;
int is_outermost = pthread_lib_enter();
VALGRIND_GET_ORIG_FN(fn);
if (TRACE_PTH_FNS) {
fprintf(stderr, "<< pthread_cond_timedwait %p %p %p",
cond, mutex, abstime);
fflush(stderr);
}
/* Tell the tool a cond-wait is about to happen, so it can check
for bogus argument values. In return it tells us whether it
thinks the mutex is valid or not. */
if (is_outermost) {
DO_CREQ_v_W(TSREQ_PTHREAD_RWLOCK_UNLOCK_PRE, void *,mutex);
}
CALL_FN_W_WWW(ret, fn, cond,mutex,abstime);
if (is_outermost) {
if (ret == 0) {
DO_CREQ_v_W(TSREQ_WAIT, void *, cond);
}
DO_CREQ_v_WW(TSREQ_PTHREAD_RWLOCK_LOCK_POST, void *,mutex,
long, 1 /*is_w*/);
}
if (ret != 0 && ret != ETIMEDOUT) {
DO_PthAPIerror( "pthread_cond_timedwait", ret );
}
if (TRACE_PTH_FNS) {
fprintf(stderr, " cotimedwait -> %d >>\n", ret);
}
pthread_lib_exit();
return ret;
}
PTH_FUNC(int, pthreadZucondZutimedwaitZAZa, // pthread_cond_timedwait@*
pthread_cond_t* cond, pthread_mutex_t* mutex,
struct timespec* abstime)
{
return pthread_cond_timedwait_WRK(cond, mutex, abstime);
}
PTH_FUNC(int, pthreadZucondZutimedwait$Za, // pthread_cond_timedwait$*
pthread_cond_t* cond, pthread_mutex_t* mutex,
struct timespec* abstime)
{
return pthread_cond_timedwait_WRK(cond, mutex, abstime);
}
PTH_FUNC(int, pthreadZucondZutimedwaitZurelativeZunp, // pthread_cond_timedwait_relative_np
pthread_cond_t* cond, pthread_mutex_t* mutex,
struct timespec* abstime)
{
return pthread_cond_timedwait_WRK(cond, mutex, abstime);
}
// pthread_cond_signal
static int pthread_cond_signal_WRK(pthread_cond_t* cond)
{
int ret;
OrigFn fn;
VALGRIND_GET_ORIG_FN(fn);
if (TRACE_PTH_FNS) {
fprintf(stderr, "<< pthread_cond_signal %p", cond);
fflush(stderr);
}
DO_CREQ_v_W(TSREQ_SIGNAL,
pthread_cond_t*,cond);
CALL_FN_W_W(ret, fn, cond);
if (ret != 0) {
DO_PthAPIerror( "pthread_cond_signal", ret );
}
if (TRACE_PTH_FNS) {
fprintf(stderr, " cosig -> %d >>\n", ret);
}
return ret;
}
PTH_FUNC(int, pthreadZucondZusignal, // pthread_cond_signal
pthread_cond_t* cond)
{
return pthread_cond_signal_WRK(cond);
}
PTH_FUNC(int, pthreadZucondZusignalZAZa, // pthread_cond_signal@*
pthread_cond_t* cond)
{
return pthread_cond_signal_WRK(cond);
}
// pthread_cond_broadcast
// Note, this is pretty much identical, from a dependency-graph
// point of view, with cond_signal, so the code is duplicated.
// Maybe it should be commoned up.
static int pthread_cond_broadcast_WRK(pthread_cond_t* cond)
{
int ret;
OrigFn fn;
pthread_lib_enter();
VALGRIND_GET_ORIG_FN(fn);
if (TRACE_PTH_FNS) {
fprintf(stderr, "<< pthread_broadcast_signal %p", cond);
fflush(stderr);
}
DO_CREQ_v_W(TSREQ_SIGNAL,
pthread_cond_t*,cond);
CALL_FN_W_W(ret, fn, cond);
if (ret != 0) {
DO_PthAPIerror( "pthread_cond_broadcast", ret );
}
if (TRACE_PTH_FNS) {
fprintf(stderr, " cobro -> %d >>\n", ret);
}
pthread_lib_exit();
return ret;
}
PTH_FUNC(int, pthreadZucondZubroadcast, // pthread_cond_broadcast
pthread_cond_t* cond)
{
return pthread_cond_broadcast_WRK(cond);
}
PTH_FUNC(int, pthreadZucondZubroadcastZAZa, // pthread_cond_broadcast@*
pthread_cond_t* cond)
{
return pthread_cond_broadcast_WRK(cond);
}
static void do_wait(void *cv) {
DO_CREQ_v_W(TSREQ_WAIT, void *, cv);
}
/*----------------------------------------------------------------*/
/*--- pthread_barrier_t functions ---*/
/*----------------------------------------------------------------*/
#if defined(VGO_darwin) || defined(ANDROID)
typedef void pthread_barrier_t;
#endif
// pthread_barrier_wait
static int pthread_barrier_wait_WRK(pthread_barrier_t* b)
{
int ret;
OrigFn fn;
VALGRIND_GET_ORIG_FN(fn);
if (TRACE_PTH_FNS) {
fprintf(stderr, "<< pthread_barrier_wait %p", b);
fflush(stderr);
}
DO_CREQ_v_W(TSREQ_CYCLIC_BARRIER_WAIT_BEFORE, void*,b);
CALL_FN_W_W(ret, fn, b);
DO_CREQ_v_W(TSREQ_CYCLIC_BARRIER_WAIT_AFTER, void*,b);
// FIXME: handle ret
if (TRACE_PTH_FNS) {
fprintf(stderr, " pthread_barrier_wait -> %d >>\n", ret);
}
return ret;
}
PTH_FUNC(int, pthreadZubarrierZuwait, // pthread_barrier_wait
pthread_barrier_t* b)
{
return pthread_barrier_wait_WRK(b);
}
// pthread_barrier_init
PTH_FUNC(int, pthreadZubarrierZuinit, void *b, void *a, unsigned n) {
int ret;
OrigFn fn;
VALGRIND_GET_ORIG_FN(fn);
DO_CREQ_v_WW(TSREQ_CYCLIC_BARRIER_INIT, void*,b, unsigned long, n);
CALL_FN_W_WWW(ret, fn, b, a, n);
return ret;
}
/*----------------------------------------------------------------*/
/*--- pthread_rwlock_t functions ---*/
/*----------------------------------------------------------------*/
/* Handled: pthread_rwlock_init pthread_rwlock_destroy
pthread_rwlock_rdlock
pthread_rwlock_wrlock
pthread_rwlock_unlock
Unhandled: pthread_rwlock_timedrdlock
pthread_rwlock_tryrdlock
pthread_rwlock_timedwrlock
pthread_rwlock_trywrlock
*/
// pthread_rwlock_init
static int pthread_rwlock_init_WRK(pthread_rwlock_t *rwl,
pthread_rwlockattr_t* attr)
{
int ret;
OrigFn fn;
VALGRIND_GET_ORIG_FN(fn);
if (TRACE_PTH_FNS) {
fprintf(stderr, "<< pthread_rwl_init %p", rwl); fflush(stderr);
}
CALL_FN_W_WW(ret, fn, rwl,attr);
if (ret == 0 /*success*/) {
DO_CREQ_v_W(TSREQ_PTHREAD_RWLOCK_CREATE_POST,
pthread_rwlock_t*,rwl);
} else {
DO_PthAPIerror( "pthread_rwlock_init", ret );
}
if (TRACE_PTH_FNS) {
fprintf(stderr, " :: rwl_init -> %d >>\n", ret);
}
return ret;
}
PTH_FUNC(int, pthreadZurwlockZuinit, // pthread_rwlock_init
pthread_rwlock_t *rwl,
pthread_rwlockattr_t* attr)
{
return pthread_rwlock_init_WRK(rwl, attr);
}
PTH_FUNC(int, pthreadZurwlockZuinit$Za, // pthread_rwlock_init$*
pthread_rwlock_t *rwl,
pthread_rwlockattr_t* attr)
{
return pthread_rwlock_init_WRK(rwl, attr);
}
// pthread_rwlock_destroy
static int pthread_rwlock_destroy_WRK( pthread_rwlock_t *rwl)
{
int ret;
OrigFn fn;
VALGRIND_GET_ORIG_FN(fn);
if (TRACE_PTH_FNS) {
fprintf(stderr, "<< pthread_rwl_destroy %p", rwl); fflush(stderr);
}
DO_CREQ_v_W(TSREQ_PTHREAD_RWLOCK_DESTROY_PRE,
pthread_rwlock_t*,rwl);
CALL_FN_W_W(ret, fn, rwl);
if (ret != 0) {
DO_PthAPIerror( "pthread_rwlock_destroy", ret );
}
if (TRACE_PTH_FNS) {
fprintf(stderr, " :: rwl_destroy -> %d >>\n", ret);
}
return ret;
}
PTH_FUNC(int, pthreadZurwlockZudestroy, // pthread_rwlock_destroy
pthread_rwlock_t *rwl)
{
return pthread_rwlock_destroy_WRK(rwl);
}
PTH_FUNC(int, pthreadZurwlockZudestroy$Za, // pthread_rwlock_destroy$*
pthread_rwlock_t *rwl)
{
return pthread_rwlock_destroy_WRK(rwl);
}
// pthread_rwlock_wrlock
static int pthread_rwlock_wrlock_WRK(pthread_rwlock_t* rwlock)
{
int ret;
OrigFn fn;
VALGRIND_GET_ORIG_FN(fn);
if (TRACE_PTH_FNS) {
fprintf(stderr, "<< pthread_rwl_wlk %p", rwlock); fflush(stderr);
}
IGNORE_ALL_SYNC_BEGIN();
CALL_FN_W_W(ret, fn, rwlock);
IGNORE_ALL_SYNC_END();
if (ret == 0 /*success*/) {
DO_CREQ_v_WW(TSREQ_PTHREAD_RWLOCK_LOCK_POST,
pthread_rwlock_t*,rwlock, long,1/*isW*/);
} else {
DO_PthAPIerror( "pthread_rwlock_wrlock", ret );
}
if (TRACE_PTH_FNS) {
fprintf(stderr, " :: rwl_wlk -> %d >>\n", ret);
}
return ret;
}
PTH_FUNC(int, pthreadZurwlockZuwrlock, // pthread_rwlock_wrlock
pthread_rwlock_t* rwlock)
{
return pthread_rwlock_wrlock_WRK(rwlock);
}
PTH_FUNC(int, pthreadZurwlockZuwrlock$Za, // pthread_rwlock_wrlock$*
pthread_rwlock_t* rwlock)
{
return pthread_rwlock_wrlock_WRK(rwlock);
}
// pthread_rwlock_rdlock
static int pthread_rwlock_rdlock_WRK(pthread_rwlock_t* rwlock)
{
int ret;
OrigFn fn;
VALGRIND_GET_ORIG_FN(fn);
if (TRACE_PTH_FNS) {
fprintf(stderr, "<< pthread_rwl_rlk %p", rwlock); fflush(stderr);
}
IGNORE_ALL_SYNC_BEGIN();
CALL_FN_W_W(ret, fn, rwlock);
IGNORE_ALL_SYNC_END();
if (ret == 0 /*success*/) {
DO_CREQ_v_WW(TSREQ_PTHREAD_RWLOCK_LOCK_POST,
pthread_rwlock_t*,rwlock, long,0/*!isW*/);
} else {
DO_PthAPIerror( "pthread_rwlock_rdlock", ret );
}
if (TRACE_PTH_FNS) {
fprintf(stderr, " :: rwl_rlk -> %d >>\n", ret);
}
return ret;
}
PTH_FUNC(int, pthreadZurwlockZurdlock, // pthread_rwlock_rdlock
pthread_rwlock_t* rwlock)
{
return pthread_rwlock_rdlock_WRK(rwlock);
}
PTH_FUNC(int, pthreadZurwlockZurdlock$Za, // pthread_rwlock_rdlock$*
pthread_rwlock_t* rwlock)
{
return pthread_rwlock_rdlock_WRK(rwlock);
}
// pthread_rwlock_trywrlock
static int pthread_rwlock_trywrlock_WRK(pthread_rwlock_t* rwlock)
{
int ret;
OrigFn fn;
VALGRIND_GET_ORIG_FN(fn);
if (TRACE_PTH_FNS) {
fprintf(stderr, "<< pthread_rwl_trywlk %p", rwlock); fflush(stderr);
}
IGNORE_ALL_SYNC_BEGIN();
CALL_FN_W_W(ret, fn, rwlock);
IGNORE_ALL_SYNC_END();
/* There's a hole here: libpthread now knows the lock is locked,
but the tool doesn't, so some other thread could run and detect
that the lock has been acquired by someone (this thread). Does
this matter? Not sure, but I don't think so. */
if (ret == 0 /*success*/) {
DO_CREQ_v_WW(TSREQ_PTHREAD_RWLOCK_LOCK_POST,
pthread_rwlock_t*,rwlock, long,1/*isW*/);
} else {
if (ret != EBUSY)
DO_PthAPIerror( "pthread_rwlock_trywrlock", ret );
}
if (TRACE_PTH_FNS) {
fprintf(stderr, " :: rwl_trywlk -> %d >>\n", ret);
}
return ret;
}
PTH_FUNC(int, pthreadZurwlockZutrywrlock, // pthread_rwlock_trywrlock
pthread_rwlock_t* rwlock)
{
return pthread_rwlock_trywrlock_WRK(rwlock);
}
PTH_FUNC(int, pthreadZurwlockZutrywrlock$Za, // pthread_rwlock_trywrlock$*
pthread_rwlock_t* rwlock)
{
return pthread_rwlock_trywrlock_WRK(rwlock);
}
// pthread_rwlock_tryrdlock
static int pthread_rwlock_tryrdlock_WRK(pthread_rwlock_t* rwlock)
{
int ret;
OrigFn fn;
VALGRIND_GET_ORIG_FN(fn);
if (TRACE_PTH_FNS) {
fprintf(stderr, "<< pthread_rwl_tryrlk %p", rwlock); fflush(stderr);
}
IGNORE_ALL_SYNC_BEGIN();
CALL_FN_W_W(ret, fn, rwlock);
IGNORE_ALL_SYNC_END();
/* There's a hole here: libpthread now knows the lock is locked,
but the tool doesn't, so some other thread could run and detect
that the lock has been acquired by someone (this thread). Does
this matter? Not sure, but I don't think so. */
if (ret == 0 /*success*/) {
DO_CREQ_v_WW(TSREQ_PTHREAD_RWLOCK_LOCK_POST,
pthread_rwlock_t*,rwlock, long,0/*!isW*/);
} else {
if (ret != EBUSY)
DO_PthAPIerror( "pthread_rwlock_tryrdlock", ret );
}
if (TRACE_PTH_FNS) {
fprintf(stderr, " :: rwl_tryrlk -> %d >>\n", ret);
}
return ret;
}
PTH_FUNC(int, pthreadZurwlockZutryrdlock, // pthread_rwlock_tryrdlock
pthread_rwlock_t* rwlock)
{
return pthread_rwlock_tryrdlock_WRK(rwlock);
}
PTH_FUNC(int, pthreadZurwlockZutryrdlock$Za, // pthread_rwlock_tryrdlock$*
pthread_rwlock_t* rwlock)
{
return pthread_rwlock_tryrdlock_WRK(rwlock);
}
// pthread_rwlock_unlock
static int pthread_rwlock_unlock_WRK(pthread_rwlock_t* rwlock)
{
int ret;
OrigFn fn;
VALGRIND_GET_ORIG_FN(fn);
if (TRACE_PTH_FNS) {
fprintf(stderr, "<< pthread_rwl_unlk %p", rwlock); fflush(stderr);
}
DO_CREQ_v_W(TSREQ_PTHREAD_RWLOCK_UNLOCK_PRE,
pthread_rwlock_t*,rwlock);
IGNORE_ALL_SYNC_BEGIN();
CALL_FN_W_W(ret, fn, rwlock);
IGNORE_ALL_SYNC_END();
if (ret != 0 /*error*/) {
DO_PthAPIerror( "pthread_rwlock_unlock", ret );
}
if (TRACE_PTH_FNS) {
fprintf(stderr, " :: rwl_unlk -> %d >>\n", ret);
}
return ret;
}
PTH_FUNC(int, pthreadZurwlockZuunlock, // pthread_rwlock_unlock
pthread_rwlock_t* rwlock)
{
return pthread_rwlock_unlock_WRK(rwlock);
}
PTH_FUNC(int, pthreadZurwlockZuunlock$Za, // pthread_rwlock_unlock$*
pthread_rwlock_t* rwlock)
{
return pthread_rwlock_unlock_WRK(rwlock);
}
/*----------------------------------------------------------------*/
/*--- POSIX semaphores ---*/
/*----------------------------------------------------------------*/
#include <semaphore.h>
#define TRACE_SEM_FNS 0
/* Handled:
int sem_init(sem_t *sem, int pshared, unsigned value);
int sem_destroy(sem_t *sem);
int sem_wait(sem_t *sem);
int sem_post(sem_t *sem);
int sem_trywait(sem_t *sem);
Unhandled:
int sem_timedwait(sem_t *restrict sem,
const struct timespec *restrict abs_timeout);
*/
/* glibc-2.5 has sem_init@@GLIBC_2.2.5 (amd64-linux)
and sem_init@@GLIBC_2.1 (x86-linux): match sem_init@*
sem_init is not implemented for Darwin. */
PTH_FUNC(int, semZuinitZAZa, sem_t* sem, int pshared, unsigned long value)
{
OrigFn fn;
int ret;
VALGRIND_GET_ORIG_FN(fn);
if (TRACE_SEM_FNS) {
fprintf(stderr, "<< sem_init(%p,%d,%lu) ", sem,pshared,value);
fflush(stderr);
}
CALL_FN_W_WWW(ret, fn, sem,pshared,value);
if (ret == 0) {
DO_CREQ_v_WW(TSREQ_POSIX_SEM_INIT_POST,
sem_t*, sem, unsigned long, value);
} else {
DO_PthAPIerror( "sem_init", errno );
}
if (TRACE_SEM_FNS) {
fprintf(stderr, " sem_init -> %d >>\n", ret);
fflush(stderr);
}
return ret;
}
static int sem_destroy_WRK(sem_t* sem)
{
OrigFn fn;
int ret;
VALGRIND_GET_ORIG_FN(fn);
if (TRACE_SEM_FNS) {
fprintf(stderr, "<< sem_destroy(%p) ", sem);
fflush(stderr);
}
DO_CREQ_v_W(TSREQ_POSIX_SEM_DESTROY_PRE, sem_t*, sem);
CALL_FN_W_W(ret, fn, sem);
if (ret != 0) {
DO_PthAPIerror( "sem_destroy", errno );
}
if (TRACE_SEM_FNS) {
fprintf(stderr, " sem_destroy -> %d >>\n", ret);
fflush(stderr);
}
return ret;
}
/* glibc-2.5 has sem_destroy@@GLIBC_2.2.5 (amd64-linux)
and sem_destroy@@GLIBC_2.1 (x86-linux); match sem_destroy@* */
PTH_FUNC(int, semZudestroyZAZa, sem_t* sem)
{
return sem_destroy_WRK(sem);
}
// Darwin has sem_destroy.
PTH_FUNC(int, semZudestroy, sem_t* sem)
{
return sem_destroy_WRK(sem);
}
/* glibc-2.5 has sem_wait (amd64-linux); match sem_wait
and sem_wait@@GLIBC_2.1 (x86-linux); match sem_wait@* */
/* wait: decrement semaphore - acquire lockage */
static int sem_wait_WRK(sem_t* sem, const char *name, int is_try)
{
OrigFn fn;
int ret;
VALGRIND_GET_ORIG_FN(fn);
if (TRACE_SEM_FNS) {
fprintf(stderr, "<< %s(%p) ", name, sem);
fflush(stderr);
}
CALL_FN_W_W(ret, fn, sem);
if (ret == 0) {
DO_CREQ_v_W(TSREQ_WAIT, sem_t*,sem);
} else {
if (!is_try) {
DO_PthAPIerror( name, errno );
}
}
if (TRACE_SEM_FNS) {
fprintf(stderr, " %s -> %d >>\n", name, ret);
fflush(stderr);
}
return ret;
}
PTH_FUNC(int, semZuwait, sem_t* sem) { /* sem_wait */
return sem_wait_WRK(sem, "sem_wait", 0);
}
PTH_FUNC(int, semZuwaitZAZa, sem_t* sem) { /* sem_wait@* */
return sem_wait_WRK(sem, "sem_wait", 0);
}
PTH_FUNC(int, semZuwait$Za, sem_t* sem) { /* sem_wait$* */
return sem_wait_WRK(sem, "sem_wait", 0);
}
PTH_FUNC(int, semZutrywait, sem_t* sem) { /* sem_trywait */
return sem_wait_WRK(sem, "sem_trywait", 1);
}
PTH_FUNC(int, semZutrywaitZAZa, sem_t* sem) { /* sem_trywait@* */
return sem_wait_WRK(sem, "sem_trywait", 1);
}
PTH_FUNC(int, semZutrywait$Za, sem_t* sem) { /* sem_trywait$* */
return sem_wait_WRK(sem, "sem_trywait", 1);
}
/* glibc-2.5 has sem_post (amd64-linux); match sem_post
and sem_post@@GLIBC_2.1 (x86-linux); match sem_post@* */
/* post: increment semaphore - release lockage */
static int sem_post_WRK(OrigFn fn, sem_t* sem)
{
int ret;
if (TRACE_SEM_FNS) {
fprintf(stderr, "<< sem_post(%p) ", sem);
fflush(stderr);
}
DO_CREQ_v_W(TSREQ_SIGNAL, sem_t*,sem);
CALL_FN_W_W(ret, fn, sem);
if (ret != 0) {
DO_PthAPIerror( "sem_post", errno );
}
if (TRACE_SEM_FNS) {
fprintf(stderr, " sem_post -> %d >>\n", ret);
fflush(stderr);
}
return ret;
}
PTH_FUNC(int, semZupost, sem_t* sem) { /* sem_post */
OrigFn fn;
VALGRIND_GET_ORIG_FN(fn);
return sem_post_WRK(fn, sem);
}
PTH_FUNC(int, semZupostZAZa, sem_t* sem) { /* sem_post@* */
OrigFn fn;
VALGRIND_GET_ORIG_FN(fn);
return sem_post_WRK(fn, sem);
}
PTH_FUNC(int, semZupost$Za, sem_t* sem) { /* sem_post$* */
OrigFn fn;
VALGRIND_GET_ORIG_FN(fn);
return sem_post_WRK(fn, sem);
}
/* From man page:
sem_t *sem_open(const char *name, int oflag, ...);
...
The oflag argument controls whether the semaphore is created or merely
accessed by the call to sem_open(). The following flag bits may be
set in oflag:
...
If O_CREAT is set and the semaphore already exists, then O_CREAT has no
effect, except as noted under O_EXCL. Otherwise, sem_open() creates a
named semaphore. The O_CREAT flag requires a third and a fourth
argument: mode, which is of type mode_t, and value, which is of
type unsigned int. The semaphore is created with an initial value of value.
*/
static sem_t *sem_open_WRK(OrigFn fn,
const char *name, int oflag,
mode_t mode, unsigned int value) {
sem_t *ret;
CALL_FN_W_WWWW(ret, fn, name, oflag, mode, value);
if ((oflag & O_CREAT) &&
value > 0 &&
ret != SEM_FAILED) {
// This semaphore has been created with a non-zero value.
// The semaphore is initialized only on the first call to sem_open,
// next call will return an existing semaphore.
// Ideally, we need to handle it like sem_init with a non-zero value.
// But in such case we also need to handle sem_unlink.
//
// To avoid this complexity we simply do a SIGNAL here.
DO_CREQ_v_W(TSREQ_SIGNAL, sem_t*, ret);
}
return ret;
}
PTH_FUNC(sem_t *, semZuopen, const char *name, int oflag,
mode_t mode, unsigned int value) { /* sem_open */
OrigFn fn;
VALGRIND_GET_ORIG_FN(fn);
return sem_open_WRK(fn, name, oflag, mode, value);
}
PTH_FUNC(sem_t *, semZuopenZAZa, const char *name, int oflag,
mode_t mode, unsigned int value) { /* sem_open@* */
OrigFn fn;
VALGRIND_GET_ORIG_FN(fn);
return sem_open_WRK(fn, name, oflag, mode, value);
}
// atexit -> exit create a h-b arc.
static void *AtExitMagic(void) {
return (void*)0x12345678;
}
#define ATEXIT_BODY { \
OrigFn fn;\
long ret;\
VALGRIND_GET_ORIG_FN(fn);\
CALL_FN_W_W(ret, fn, callback);\
DO_CREQ_v_W(TSREQ_SIGNAL, void*, AtExitMagic());\
return ret;\
}\
NONE_FUNC(long, atexit, void *callback) ATEXIT_BODY
LIBC_FUNC(long, atexit, void *callback) ATEXIT_BODY
#define EXIT_BODY { \
OrigFn fn;\
VALGRIND_GET_ORIG_FN(fn);\
do_wait(AtExitMagic());\
CALL_FN_v_W(fn, x);\
}\
LIBC_FUNC(void, exit, int x) EXIT_BODY
NONE_FUNC(void, exit, int x) EXIT_BODY
// socket/file IO that creates happens-before arcs.
static void *SocketMagic(long s) {
return (void*)0xDEADFBAD;
}
LIBC_FUNC(int, epoll_wait, int epfd, void * events, int maxevents, int timeout) {
OrigFn fn;
long ret;
void *o;
VALGRIND_GET_ORIG_FN(fn);
// fprintf(stderr, "T%d socket epoll_wait: %d\n", VALGRIND_TS_THREAD_ID(), epfd);
CALL_FN_W_WWWW(ret, fn, epfd, events, maxevents, timeout);
o = SocketMagic(epfd);
do_wait(o);
return ret;
}
LIBC_FUNC(int, epoll_ctl, int epfd, int op, int fd, void *event) {
OrigFn fn;
long ret;
void *o;
VALGRIND_GET_ORIG_FN(fn);
// fprintf(stderr, "T%d socket epoll_ctl: %d\n", VALGRIND_TS_THREAD_ID(), epfd);
o = SocketMagic(epfd);
DO_CREQ_v_W(TSREQ_SIGNAL, void*, o);
CALL_FN_W_WWWW(ret, fn, epfd, op, fd, event);
return ret;
}
PTH_FUNC(long, send, int s, void *buf, long len, int flags) {
OrigFn fn;
long ret;
void *o;
VALGRIND_GET_ORIG_FN(fn);
// fprintf(stderr, "T%d socket send: %d %ld\n", VALGRIND_TS_THREAD_ID(), s, len);
o = SocketMagic(s);
DO_CREQ_v_W(TSREQ_SIGNAL, void*, o);
CALL_FN_W_WWWW(ret, fn, s, buf, len, flags);
return ret;
}
PTH_FUNC(long, sendmsg, int s, void *msg, int flags) {
OrigFn fn;
long ret;
void *o;
VALGRIND_GET_ORIG_FN(fn);
o = SocketMagic(s);
DO_CREQ_v_W(TSREQ_SIGNAL, void*, o);
CALL_FN_W_WWW(ret, fn, s, msg, flags);
return ret;
}
// TODO(timurrrr): sendto
PTH_FUNC(long, recv, int s, void *buf, long len, int flags) {
OrigFn fn;
long ret;
void *o;
VALGRIND_GET_ORIG_FN(fn);
CALL_FN_W_WWWW(ret, fn, s, buf, len, flags);
// fprintf(stderr, "T%d socket recv: %d %ld %ld\n", VALGRIND_TS_THREAD_ID(), s, len, ret);
o = SocketMagic(s);
if (ret >= 0) {
// Do client request only if we received something
// or the connection was closed.
do_wait(o);
}
return ret;
}
PTH_FUNC(long, recvmsg, int s, void *msg, int flags) {
OrigFn fn;
long ret;
void *o;
VALGRIND_GET_ORIG_FN(fn);
CALL_FN_W_WWW(ret, fn, s, msg, flags);
o = SocketMagic(s);
if (ret >= 0) {
// Do client request only if we received something
// or the connection was closed.
do_wait(o);
}
return ret;
}
// TODO(timurrrr): recvfrom
PTH_FUNC(long, read, int s, void *a2, long count) {
OrigFn fn;
long ret;
void *o;
VALGRIND_GET_ORIG_FN(fn);
CALL_FN_W_WWW(ret, fn, s, a2, count);
// fprintf(stderr, "T%d socket read: %d %ld %ld\n", VALGRIND_TS_THREAD_ID(), s, count, ret);
o = SocketMagic(s);
if (ret >= 0) {
// Do client request only if we read something or the EOF was reached.
do_wait(o);
}
return ret;
}
PTH_FUNC(long, write, int s, void *a2, long a3) {
OrigFn fn;
long ret;
void *o;
VALGRIND_GET_ORIG_FN(fn);
// fprintf(stderr, "T%d socket write: %d\n", VALGRIND_TS_THREAD_ID(), s);
o = SocketMagic(s);
DO_CREQ_v_W(TSREQ_SIGNAL, void*, o);
CALL_FN_W_WWW(ret, fn, s, a2, a3);
return ret;
}
/* Linux: unlink
* Darwin: unlink */
LIBC_FUNC(long, unlink, void *path) {
OrigFn fn;
long ret;
void *o;
VALGRIND_GET_ORIG_FN(fn);
o = SocketMagic((long)path);
DO_CREQ_v_W(TSREQ_SIGNAL, void*, o);
CALL_FN_W_W(ret, fn, path);
return ret;
}
/* Linux: open
* Darwin: open$NOCANCEL$UNIX2003 */
static int open_WRK(void *path, int flags, int mode) {
OrigFn fn;
long ret;
void *o;
VALGRIND_GET_ORIG_FN(fn);
o = SocketMagic((long)path);
DO_CREQ_v_W(TSREQ_SIGNAL, void*, o);
CALL_FN_W_WWW(ret, fn, path, flags, mode);
do_wait(o);
return ret;
}
LIBC_FUNC(int, open, void *path, int flags, int mode) {
return open_WRK(path, flags, mode);
}
LIBC_FUNC(int, open$Za, void *path, int flags, int mode) {
return open_WRK(path, flags, mode);
}
/* Linux: rmdir
* Darwin: rmdir */
LIBC_FUNC(int, rmdir, void *path) {
OrigFn fn;
long ret;
void *o;
VALGRIND_GET_ORIG_FN(fn);
o = SocketMagic((long)path);
DO_CREQ_v_W(TSREQ_SIGNAL, void*, o);
CALL_FN_W_W(ret, fn, path);
return ret;
}
/* Linux: opendir
* Darwin: opendir$UNIX2003 */
static long opendir_WRK(void *path) {
OrigFn fn;
long ret;
void *o;
VALGRIND_GET_ORIG_FN(fn);
CALL_FN_W_W(ret, fn, path);
o = SocketMagic((long)path);
do_wait(o);
return ret;
}
LIBC_FUNC(long, opendir, void *path) {
return opendir_WRK(path);
}
LIBC_FUNC(long, opendir$Za, void *path) {
return opendir_WRK(path);
}
#if !defined(ANDROID)
LIBC_FUNC(int, lockf, int fd, int cmd, OFF_T offset) {
OrigFn fn;
void *o;
long ret;
VALGRIND_GET_ORIG_FN(fn);
o = SocketMagic(fd);
if (cmd == F_ULOCK) {
DO_CREQ_v_W(TSREQ_SIGNAL, void*, o);
}
CALL_FN_W_2WO_T(ret, fn, fd, cmd, offset);
if (cmd == F_LOCK && ret == 0) {
do_wait(o);
}
return ret;
}
#endif
/*
Support for pthread_once and function-level static objects.
pthread_once is supported by simply ignoring everything that happens
inside pthread_once.
Another approach would be to SIGNAL when pthread_once with a given
pthread_once_t is called for the first time and to WAIT after
each pthread_once. But implementing this is a bit tricky and probably
not worth it.
Thread safe initialization of function-level static objects is
supported in gcc (strarting from 4.something).
From gcc/cp/decl.c:
--------------------------------------------------------------
Emit code to perform this initialization but once. This code
looks like:
static <type> guard;
if (!guard.first_byte) {
if (__cxa_guard_acquire (&guard)) {
bool flag = false;
try {
// Do initialization.
flag = true; __cxa_guard_release (&guard);
// Register variable for destruction at end of program.
} catch {
if (!flag) __cxa_guard_abort (&guard);
}
}
--------------------------------------------------------------
So, when __cxa_guard_acquire returns true, we start ignoring all accesses
and in __cxa_guard_release we stop ignoring them.
We also need to ignore all accesses inside these two functions.
For examples, see test106 and test108 at
http://code.google.com/p/data-race-test/source/browse/trunk/unittest/racecheck_unittest.cc
*/
PTH_FUNC(int, pthreadZuonce, void *ctl, void *rtn) {
OrigFn fn;
int ret;
VALGRIND_GET_ORIG_FN(fn);
IGNORE_ALL_ACCESSES_BEGIN();
// fprintf(stderr, "T%d: ->pthread_once\n", VALGRIND_TS_THREAD_ID);
CALL_FN_W_WW(ret, fn, ctl, rtn);
// fprintf(stderr, "T%d: <-pthread_once\n", VALGRIND_TS_THREAD_ID);
IGNORE_ALL_ACCESSES_END();
return ret;
}
LIBSTDCXX_FUNC(long, ZuZucxaZuguardZuacquire, void *p) {
OrigFn fn;
long ret;
VALGRIND_GET_ORIG_FN(fn);
// fprintf(stderr, "T%d: ->__cxa_guard_acquire\n", VALGRIND_TS_THREAD_ID());
IGNORE_ALL_ACCESSES_BEGIN();
CALL_FN_W_W(ret, fn, p);
// fprintf(stderr, "T%d: <-__cxa_guard_acquire\n", VALGRIND_TS_THREAD_ID());
if (!ret) {
IGNORE_ALL_ACCESSES_END();
}
return ret;
}
LIBSTDCXX_FUNC(long, ZuZucxaZuguardZurelease, void *p) {
OrigFn fn;
long ret;
VALGRIND_GET_ORIG_FN(fn);
// fprintf(stderr, "T%d: ->__cxa_guard_release\n", VALGRIND_TS_THREAD_ID());
CALL_FN_W_W(ret, fn, p);
// fprintf(stderr, "T%d: <-__cxa_guard_release\n", VALGRIND_TS_THREAD_ID());
IGNORE_ALL_ACCESSES_END();
return ret;
}
/*----------------------------------------------------------------*/
/*--- Replace glibc's wretched optimised string fns (again!) ---*/
/*----------------------------------------------------------------*/
/* Why we have to do all this nonsense:
Some implementations of strlen may read up to 7 bytes past the end
of the string thus touching memory which may not belong to this
string.
Such race is benign because the data read past the end of the
string is not used.
*/
// --- MEMCPY -----------------------------------------------------
//
#define MEMCPY(soname, fnname) \
void* VG_REPLACE_FUNCTION_ZU(soname,fnname) \
( void *dst, const void *src, SizeT len ); \
void* VG_REPLACE_FUNCTION_ZU(soname,fnname) \
( void *dst, const void *src, SizeT len ) \
{ return Replace_memcpy(dst, src, len); }
MEMCPY(VG_Z_LIBC_SONAME, memcpy)
MEMCPY(NONE, memcpy)
/* icc9 blats these around all over the place. Not only in the main
executable but various .so's. They are highly tuned and read
memory beyond the source boundary (although work correctly and
never go across page boundaries), so give errors when run natively,
at least for misaligned source arg. Just intercepting in the exe
only until we understand more about the problem. See
http://bugs.kde.org/show_bug.cgi?id=139776
*/
MEMCPY(NONE, _intel_fast_memcpy)
#if defined(VGO_linux)
MEMCPY(VG_Z_LIBC_SONAME, __GI_memcpy);
#endif
// --- MEMMOVE -----------------------------------------------------
//
#define MEMMOVE(soname, fnname) \
void* VG_REPLACE_FUNCTION_ZU(soname,fnname) \
( void *dst, const void *src, SizeT len ); \
void* VG_REPLACE_FUNCTION_ZU(soname,fnname) \
( void *dst, const void *src, SizeT len ) \
{ return Replace_memmove(dst, src, len); }
MEMMOVE(VG_Z_LIBC_SONAME, memmove)
MEMMOVE(NONE, memmove)
#if defined(VGO_linux)
MEMMOVE(VG_Z_LIBC_SONAME, __GI_memmove);
#endif
// --- STRCHR and INDEX -------------------------------------------
//
#define STRCHR(soname, fnname) \
char* VG_REPLACE_FUNCTION_ZU(soname,fnname) ( const char* s, int c ); \
char* VG_REPLACE_FUNCTION_ZU(soname,fnname) ( const char* s, int c ) \
{ return Replace_strchr(s, c); }
// Apparently index() is the same thing as strchr()
STRCHR(VG_Z_LIBC_SONAME, strchr)
STRCHR(VG_Z_LIBC_SONAME, index)
STRCHR(NONE, strchr)
STRCHR(NONE, index)
#if defined(VGO_linux)
STRCHR(VG_Z_LIBC_SONAME, __GI_strchr)
#endif
// --- STRCHRNUL --------------------------------------------------
//
#define STRCHRNUL(soname, fnname) \
char* VG_REPLACE_FUNCTION_ZU(soname,fnname) ( const char* s, int c ); \
char* VG_REPLACE_FUNCTION_ZU(soname,fnname) ( const char* s, int c ) \
{ return Replace_strchrnul(s, c); }
STRCHRNUL(VG_Z_LIBC_SONAME, strchrnul)
STRCHRNUL(NONE, strchrnul)
#if defined(VGO_linux)
STRCHRNUL(VG_Z_LIBC_SONAME, __GI_strchrnul)
#endif
// --- STRRCHR RINDEX -----------------------------------------------------
//
#define STRRCHR(soname, fnname) \
char* VG_REPLACE_FUNCTION_ZU(soname,fnname)( const char* str, int c ); \
char* VG_REPLACE_FUNCTION_ZU(soname,fnname)( const char* str, int c ) \
{ return Replace_strrchr(str, c); }
// Apparently rindex() is the same thing as strrchr()
STRRCHR(VG_Z_LIBC_SONAME, strrchr)
STRRCHR(VG_Z_LIBC_SONAME, rindex)
STRRCHR(NONE, strrchr)
STRRCHR(NONE, rindex)
#if defined(VGO_linux)
STRRCHR(VG_Z_LIBC_SONAME, __GI_strrchr)
#endif
// --- STRCMP -----------------------------------------------------
//
#define STRCMP(soname, fnname) \
int VG_REPLACE_FUNCTION_ZU(soname,fnname) \
( const char* s1, const char* s2 ); \
int VG_REPLACE_FUNCTION_ZU(soname,fnname) \
( const char* s1, const char* s2 ) \
{ return Replace_strcmp(s1, s2); }
STRCMP(VG_Z_LIBC_SONAME, strcmp)
STRCMP(NONE, strcmp)
#if defined(VGO_linux)
STRCMP(VG_Z_LIBC_SONAME, __GI_strcmp)
#endif
#define MEMCMP(soname, fnname) \
int VG_REPLACE_FUNCTION_ZU(soname,fnname) \
( const char* s1, const char* s2 , size_t n); \
int VG_REPLACE_FUNCTION_ZU(soname,fnname) \
( const char* s1, const char* s2 , size_t n) \
{ return Replace_memcmp(s1, s2, n); }
MEMCMP(VG_Z_LIBC_SONAME, __memcmp_ssse3)
MEMCMP(VG_Z_LIBC_SONAME, memcmp)
MEMCMP(NONE, memcmp)
#if defined(VGO_linux)
MEMCMP(VG_Z_LIBC_SONAME, __GI_memcmp)
#endif
#define MEMCHR(soname, fnname) \
void* VG_REPLACE_FUNCTION_ZU(soname,fnname) (const void *s, int c, SizeT n); \
void* VG_REPLACE_FUNCTION_ZU(soname,fnname) (const void *s, int c, SizeT n) \
{ return Replace_memchr(s, c, n); }
MEMCHR(VG_Z_LIBC_SONAME, memchr)
MEMCHR(NONE, memchr)
#define STRNCMP(soname, fnname) \
int VG_REPLACE_FUNCTION_ZU(soname,fnname) \
( const char* s1, const char* s2, size_t n); \
int VG_REPLACE_FUNCTION_ZU(soname,fnname) \
( const char* s1, const char* s2, size_t n) \
{ return Replace_strncmp(s1, s2, n); }
STRNCMP(VG_Z_LIBC_SONAME, strncmp)
STRNCMP(NONE, strncmp)
#if defined(VGO_linux)
STRNCMP(VG_Z_LIBC_SONAME, __GI_strncmp)
#endif
// --- STRLEN -----------------------------------------------------
//
// Note that this replacement often doesn't get used because gcc inlines
// calls to strlen() with its own built-in version. This can be very
// confusing if you aren't expecting it. Other small functions in this file
// may also be inline by gcc.
#define STRLEN(soname, fnname) \
SizeT VG_REPLACE_FUNCTION_ZU(soname,fnname)( const char* str ); \
SizeT VG_REPLACE_FUNCTION_ZU(soname,fnname)( const char* str ) \
{ return Replace_strlen(str); }
STRLEN(VG_Z_LIBC_SONAME, strlen)
STRLEN(NONE, strlen)
#if defined(VGO_linux)
STRLEN(VG_Z_LIBC_SONAME, __GI_strlen)
#endif
// --- STRCPY -----------------------------------------------------
//
#define STRCPY(soname, fnname) \
char* VG_REPLACE_FUNCTION_ZU(soname, fnname) ( char* dst, const char* src ); \
char* VG_REPLACE_FUNCTION_ZU(soname, fnname) ( char* dst, const char* src ) \
{ return Replace_strcpy(dst, src); }
STRCPY(VG_Z_LIBC_SONAME, strcpy)
STRCPY(NONE, strcpy)
#if defined(VGO_linux)
STRCPY(VG_Z_LIBC_SONAME, __GI_strcpy)
#endif
// --- STRNCPY -----------------------------------------------------
//
#define STRNCPY(soname, fnname) \
char* VG_REPLACE_FUNCTION_ZU(soname, fnname) ( char* dst, const char* src, size_t n ); \
char* VG_REPLACE_FUNCTION_ZU(soname, fnname) ( char* dst, const char* src, size_t n ) \
{ return Replace_strncpy(dst, src, n); }
STRNCPY(VG_Z_LIBC_SONAME, strncpy)
STRNCPY(NONE, strncpy)
#if defined(VGO_linux)
STRNCPY(VG_Z_LIBC_SONAME, __GI_strncpy)
#endif
// --- STRCAT -----------------------------------------------------
//
#define STRCAT(soname, fnname) \
char* VG_REPLACE_FUNCTION_ZU(soname, fnname) ( char* dst, const char* src); \
char* VG_REPLACE_FUNCTION_ZU(soname, fnname) ( char* dst, const char* src) \
{ return Replace_strcat(dst, src); }
STRCAT(VG_Z_LIBC_SONAME, strcat)
STRCAT(NONE, strcat)
#if defined(VGO_linux)
STRCAT(VG_Z_LIBC_SONAME, __GI_strcat)
#endif
// --- STPCPY -----------------------------------------------------
//
#define STPCPY(soname, fnname) \
char* VG_REPLACE_FUNCTION_ZU(soname, fnname) ( char* dst, const char* src ); \
char* VG_REPLACE_FUNCTION_ZU(soname, fnname) ( char* dst, const char* src ) \
{ return Replace_stpcpy(dst, src); }
STPCPY(VG_Z_LIBC_SONAME, stpcpy)
STPCPY(NONE, stpcpy)
#if defined(VGO_linux)
STPCPY(VG_Z_LIBC_SONAME, __GI_stpcpy)
#endif
//------------------------ Annotations ---------------- {{{1
#define ANN_FUNC(ret_ty, f, args...) \
ret_ty I_WRAP_SONAME_FNNAME_ZZ(Za,f)(args); \
ret_ty I_WRAP_SONAME_FNNAME_ZZ(Za,f)(args)
#define ANN_TRACE(args...) \
do{\
if(TRACE_ANN_FNS){\
int tid = VALGRIND_TS_THREAD_ID();\
int sid = VALGRIND_TS_SEGMENT_ID();\
fprintf(stderr, args);\
if(tid != 999999 && sid != 999999) fflush(stderr);\
}\
}while(0)
ANN_FUNC(int, RunningOnValgrind, void) {
return 1;
}
ANN_FUNC(const char *, ThreadSanitizerQuery, const char *query) {
Word res;
DO_CREQ_W_WW(res, TSREQ_THREAD_SANITIZER_QUERY, const char*, query, long, 0);
return (const char *)res;
}
ANN_FUNC(void, AnnotateFlushState, const char *unused_file, int unused_line) {
DO_CREQ_v_v(TSREQ_FLUSH_STATE);
}
ANN_FUNC(void, AnnotateRWLockCreate, const char *file, int line, void *lock)
{
const char *name = "AnnotateRWLockCreate";
ANN_TRACE("--#%d %s[%p] %s:%d\n", tid, name, lock, file, line);
DO_CREQ_v_WW(TSREQ_PTHREAD_RWLOCK_CREATE_POST, void*, lock, long, 0 /*non recur*/);
}
ANN_FUNC(void, AnnotateRWLockDestroy, const char *file, int line, void *lock)
{
const char *name = "AnnotateRWLockDestroy";
ANN_TRACE("--#%d %s[%p] %s:%d\n", tid, name, lock, file, line);
DO_CREQ_v_W(TSREQ_PTHREAD_RWLOCK_DESTROY_PRE, void*, lock);
}
ANN_FUNC(void, AnnotateRWLockAcquired, const char *file, int line, void *lock, int is_w)
{
const char *name = "AnnotateRWLockAcquired";
ANN_TRACE("--#%d %s[%p] rw=%d %s:%d\n", tid, name, lock, is_w, file, line);
DO_CREQ_v_WW(TSREQ_PTHREAD_RWLOCK_LOCK_POST, void*,lock,long, (long)is_w);
}
ANN_FUNC(void, AnnotateRWLockReleased, const char *file, int line, void *lock, int is_w)
{
const char *name = "AnnotateRWLockReleased";
ANN_TRACE("--#%d %s[%p] rw=%d %s:%d\n", tid, name, lock, is_w, file, line);
DO_CREQ_v_W(TSREQ_PTHREAD_RWLOCK_UNLOCK_PRE, void*, lock);
}
ANN_FUNC(void, AnnotateCondVarWait, const char *file, int line, void *cv, void *lock)
{
const char *name = "AnnotateCondVarWait";
ANN_TRACE("--#%d %s[%p|%p] %s:%d\n", tid, name, cv, lock, file, line);
do_wait(cv);
}
ANN_FUNC(void, AnnotateCondVarSignal, const char *file, int line, void *cv)
{
const char *name = "AnnotateCondVarSignal";
ANN_TRACE("--#%d %s[%p] %s:%d\n", tid, name, cv, file, line);
DO_CREQ_v_W(TSREQ_SIGNAL, void*,cv);
}
ANN_FUNC(void, AnnotateCondVarSignalAll, const char *file, int line, void *cv)
{
const char *name = "AnnotateCondVarSignalAll";
ANN_TRACE("--#%d %s[%p] %s:%d\n", tid, name, cv, file, line);
DO_CREQ_v_W(TSREQ_SIGNAL, void*,cv);
}
ANN_FUNC(void, AnnotateHappensBefore, const char *file, int line, void *obj)
{
const char *name = "AnnotateHappensBefore";
ANN_TRACE("--#%d %s[%p] %s:%d\n", tid, name, obj, file, line);
DO_CREQ_v_W(TSREQ_SIGNAL, void*, obj);
}
ANN_FUNC(void, WTFAnnotateHappensBefore, const char *file, int line, void *obj)
{
const char *name = "WTFAnnotateHappensBefore";
ANN_TRACE("--#%d %s[%p] %s:%d\n", tid, name, obj, file, line);
DO_CREQ_v_W(TSREQ_SIGNAL, void*, obj);
}
ANN_FUNC(void, AnnotateHappensAfter, const char *file, int line, void *obj)
{
const char *name = "AnnotateHappensAfter";
ANN_TRACE("--#%d %s[%p] %s:%d\n", tid, name, obj, file, line);
do_wait(obj);
}
ANN_FUNC(void, WTFAnnotateHappensAfter, const char *file, int line, void *obj)
{
const char *name = "WTFAnnotateHappensAfter";
ANN_TRACE("--#%d %s[%p] %s:%d\n", tid, name, obj, file, line);
do_wait(obj);
}
ANN_FUNC(void, AnnotatePCQCreate, const char *file, int line, void *pcq)
{
const char *name = "AnnotatePCQCreate";
ANN_TRACE("--#%d %s[%p] %s:%d\n", tid, name, pcq, file, line);
DO_CREQ_v_W(TSREQ_PCQ_CREATE, void*,pcq);
}
ANN_FUNC(void, AnnotatePCQDestroy, const char *file, int line, void *pcq)
{
const char *name = "AnnotatePCQDestroy";
ANN_TRACE("--#%d %s[%p] %s:%d\n", tid, name, pcq, file, line);
DO_CREQ_v_W(TSREQ_PCQ_DESTROY, void*,pcq);
}
ANN_FUNC(void, AnnotatePCQPut, const char *file, int line, void *pcq)
{
const char *name = "AnnotatePCQPut";
ANN_TRACE("--#%d %s[%p] %s:%d\n", tid, name, pcq, file, line);
DO_CREQ_v_W(TSREQ_PCQ_PUT, void*,pcq);
}
ANN_FUNC(void, AnnotatePCQGet, const char *file, int line, void *pcq)
{
const char *name = "AnnotatePCQGet";
ANN_TRACE("--#%d %s[%p] %s:%d\n", tid, name, pcq, file, line);
DO_CREQ_v_W(TSREQ_PCQ_GET, void*,pcq);
}
ANN_FUNC(void, AnnotateExpectRace, const char *file, int line, void *mem, char *description)
{
const char *name = "AnnotateExpectRace";
ANN_TRACE("--#%d %s[%p] %s:%d\n", tid, name, mem, file, line);
DO_CREQ_v_WW(TSREQ_EXPECT_RACE, void*,mem, char*,description);
}
ANN_FUNC(void, AnnotateFlushExpectedRaces, const char *file, int line)
{
const char *name = __FUNCTION__;
ANN_TRACE("--#%d %s\n", tid, name);
DO_CREQ_v_v(TSREQ_FLUSH_EXPECTED_RACES);
}
ANN_FUNC(void, AnnotateBenignRace, const char *file, int line, void *mem, char *description)
{
const char *name = "AnnotateBenignRace";
ANN_TRACE("--#%d %s[%p] %s:%d\n", tid, name, mem, file, line);
DO_CREQ_v_WWW(TSREQ_BENIGN_RACE, void*,mem, long, 1, char*,description);
}
ANN_FUNC(void, AnnotateBenignRaceSized, const char *file, int line, void *mem, long size, char *description)
{
const char *name = "AnnotateBenignRace";
ANN_TRACE("--#%d %s[%p] %s:%d\n", tid, name, mem, file, line);
DO_CREQ_v_WWW(TSREQ_BENIGN_RACE, char*,(char*)mem, long, size,
char*,description);
}
ANN_FUNC(void, WTFAnnotateBenignRaceSized, const char *file, int line, void *mem, long size, char *description)
{
const char *name = "WTFAnnotateBenignRace";
ANN_TRACE("--#%d %s[%p] %s:%d\n", tid, name, mem, file, line);
DO_CREQ_v_WWW(TSREQ_BENIGN_RACE, char*,(char*)mem, long, size,
char*,description);
}
ANN_FUNC(void, AnnotateNewMemory, char *file, int line, void *mem, long size)
{
const char *name = "AnnotateNewMemory";
ANN_TRACE("--#%d %s[%p,%d] %s:%d\n", tid, name, mem, (int)size, file, line);
DO_CREQ_v_WWWW(TSREQ_CLEAN_MEMORY, void*,mem, long, size, char*, file, long, (long)line);
}
ANN_FUNC(void, AnnotatePublishMemoryRange, char *file, int line, void *mem, long size)
{
const char *name = "AnnotatePublishMemoryRange";
ANN_TRACE("--#%d %s[%p,%d] %s:%d\n", tid, name, mem, (int)size, file, line);
DO_CREQ_v_WW(TSREQ_PUBLISH_MEMORY_RANGE, void*, mem, long, size);
}
ANN_FUNC(void, AnnotateUnpublishMemoryRange, char *file, int line, void *mem, long size)
{
const char *name = "AnnotateUnpublishMemoryRange";
ANN_TRACE("--#%d %s[%p,%d] %s:%d\n", tid, name, mem, (int)size, file, line);
DO_CREQ_v_WW(TSREQ_UNPUBLISH_MEMORY_RANGE, void*, mem, long, size);
}
ANN_FUNC(void, AnnotateIgnoreReadsBegin, char *file, int line, void *mu)
{
const char *name = "AnnotateIgnoreReadsBegin";
ANN_TRACE("--#%d %s[%p] %s:%d\n", tid, name, mu, file, line);
DO_CREQ_v_W(TSREQ_IGNORE_READS_BEGIN, void*, mu);
}
ANN_FUNC(void, AnnotateIgnoreReadsEnd, char *file, int line, void *mu)
{
const char *name = "AnnotateIgnoreReadsEnd";
ANN_TRACE("--#%d %s[%p] %s:%d\n", tid, name, mu, file, line);
DO_CREQ_v_W(TSREQ_IGNORE_READS_END, void*, mu);
}
ANN_FUNC(void, AnnotateIgnoreWritesBegin, char *file, int line, void *mu)
{
const char *name = "AnnotateIgnoreWritesBegin";
ANN_TRACE("--#%d %s[%p] %s:%d\n", tid, name, mu, file, line);
DO_CREQ_v_W(TSREQ_IGNORE_WRITES_BEGIN, void*, mu);
}
ANN_FUNC(void, AnnotateIgnoreWritesEnd, char *file, int line, void *mu)
{
const char *name = "AnnotateIgnoreWritesEnd";
ANN_TRACE("--#%d %s[%p] %s:%d\n", tid, name, mu, file, line);
DO_CREQ_v_W(TSREQ_IGNORE_WRITES_END, void*, mu);
}
ANN_FUNC(void, AnnotateIgnoreSyncBegin, char* file, int line, void *mu)
{
const char *name = "AnnotateIgnoreSyncBegin";
ANN_TRACE("--#%d %s[%p] %s:%d\n", tid, name, mu, file, line);
DO_CREQ_v_W(TSREQ_IGNORE_ALL_SYNC_BEGIN, void*, mu);
}
ANN_FUNC(void, AnnotateIgnoreSyncEnd, char* file, int line, void *mu)
{
const char *name = "AnnotateIgnoreSyncEnd";
ANN_TRACE("--#%d %s[%p] %s:%d\n", tid, name, mu, file, line);
DO_CREQ_v_W(TSREQ_IGNORE_ALL_SYNC_END, void*, mu);
}
ANN_FUNC(void, AnnotateEnableRaceDetection, char *file, int line, int enable)
{
const char *name = "AnnotateEnableRaceDetection";
ANN_TRACE("--#%d %s[%d] %s:%d\n", tid, name, enable, file, line);
DO_CREQ_v_W(enable == 0 ? TSREQ_GLOBAL_IGNORE_ON : TSREQ_GLOBAL_IGNORE_OFF,
long, 0);
}
ANN_FUNC(void, AnnotateThreadName, char *file, int line, const char *thread_name)
{
const char *name = "AnnotateThreadName";
ANN_TRACE("--#%d %s[%p] %s:%d\n", tid, name, thread_name, file, line);
DO_CREQ_v_W(TSREQ_SET_THREAD_NAME, const char *, thread_name);
}
ANN_FUNC(void, AnnotateMutexIsUsedAsCondVar, char *file, int line, void *mu)
{
const char *name = "AnnotateMutexIsUsedAsCondVar";
ANN_TRACE("--#%d %s[%p] %s:%d\n", tid, name, mu, file, line);
DO_CREQ_v_W(TSREQ_MUTEX_IS_USED_AS_CONDVAR, void*, mu);
}
ANN_FUNC(void, AnnotateMutexIsNotPHB, char *file, int line, void *mu)
{
const char *name = "AnnotateMutexIsNotPhb";
ANN_TRACE("--#%d %s[%p] %s:%d\n", tid, name, mu, file, line);
DO_CREQ_v_W(TSREQ_MUTEX_IS_NOT_PHB, void*, mu);
}
ANN_FUNC(void, AnnotateTraceMemory, char *file, int line, void *mem)
{
const char *name = "AnnotateTraceMemory";
ANN_TRACE("--#%d %s[%p] %s:%d\n", tid, name, mem, file, line);
DO_CREQ_v_W(TSREQ_TRACE_MEM, void*, mem);
}
#undef TRACE_ANN_FNS
#define TRACE_ANN_FNS 1
ANN_FUNC(void, AnnotateNoOp, char *file, int line, void *mem)
{
const char *name = "AnnotateNoOp";
IGNORE_ALL_ACCESSES_BEGIN();
ANN_TRACE("--#%d/%d %s[%p] %s:%d\n", tid, sid, name, mem, file, line);
IGNORE_ALL_ACCESSES_END();
}
ANN_FUNC(void, AnnotateSetVerbosity, char *file, int line, void *mem)
{
const char *name = "AnnotateSetVerbosity";
OrigFn fn;
VALGRIND_GET_ORIG_FN(fn);
fprintf(stderr, "%s fn=%p\n", name, (void*)fn.nraddr);
ANN_TRACE("--#%d/%d %s[%p] %s:%d\n", tid, sid, name, mem, file, line);
}
//-------------- NaCl Support -------------- {{{1
// A bit hackish implementation of NaCl support.
// We need to notify the valgrind core about
// a) nacl memory range
// b) nacl .nexe file
#include "coregrind/pub_core_clreq.h"
void I_WRAP_SONAME_FNNAME_ZZ(NONE, NaClSandboxMemoryStartForValgrind) (void *mem_start);
void I_WRAP_SONAME_FNNAME_ZZ(NONE, NaClSandboxMemoryStartForValgrind) (void *mem_start) {
OrigFn fn;
int res;
VALGRIND_GET_ORIG_FN(fn);
CALL_FN_v_W(fn, mem_start);
VALGRIND_DO_CLIENT_REQUEST(res, 0, VG_USERREQ__NACL_MEM_START, mem_start, 0, 0, 0, 0);
}
int I_WRAP_SONAME_FNNAME_ZZ(NONE, NaClFileNameForValgrind) (char *file);
int I_WRAP_SONAME_FNNAME_ZZ(NONE, NaClFileNameForValgrind) (char *file) {
OrigFn fn;
int ret, res;
VALGRIND_GET_ORIG_FN(fn);
CALL_FN_W_W(ret, fn, file);
VALGRIND_DO_CLIENT_REQUEST(res, 0, VG_USERREQ__NACL_FILE, file, 0, 0, 0, 0);
return ret;
}
void I_WRAP_SONAME_FNNAME_ZZ(NONE, NaClFileMappingForValgrind) (UWord vma, UWord size, UWord file_offset);
void I_WRAP_SONAME_FNNAME_ZZ(NONE, NaClFileMappingForValgrind) (UWord vma, UWord size, UWord file_offset) {
OrigFn fn;
int res;
VALGRIND_GET_ORIG_FN(fn);
CALL_FN_v_WWW(fn, vma, size, file_offset);
VALGRIND_DO_CLIENT_REQUEST(res, 0, VG_USERREQ__NACL_MMAP, vma, size, file_offset, 0, 0);
}
//-------------- Functions to Ignore -------------- {{{1
// For some functions we want to ignore everything that happens
// after they were called and before they returned.
// Is there any way that allows to do this via a command line?
#define WRAP_AND_IGNORE(soname, fnname) \
void* I_WRAP_SONAME_FNNAME_ZU(soname,fnname) (void *a1, void *a2, void *a3, void *a4); \
void* I_WRAP_SONAME_FNNAME_ZU(soname,fnname) (void *a1, void *a2, void *a3, void *a4) { \
void* ret; \
OrigFn fn;\
VALGRIND_GET_ORIG_FN(fn);\
IGNORE_ALL_ACCESSES_BEGIN(); \
CALL_FN_W_WWWW(ret, fn, a1, a2, a3, a4); \
IGNORE_ALL_ACCESSES_END(); \
return ret; \
}
WRAP_AND_IGNORE(NONE, getenv);
// {{{1 end
// vim:shiftwidth=2:softtabstop=2:expandtab