| |
| /*--------------------------------------------------------------------*/ |
| /*--- Helgrind: a Valgrind tool for detecting errors ---*/ |
| /*--- in threaded programs. hg_main.c ---*/ |
| /*--------------------------------------------------------------------*/ |
| |
| /* |
| This file is part of Helgrind, a Valgrind tool for detecting errors |
| in threaded programs. |
| |
| Copyright (C) 2007-2013 OpenWorks LLP |
| info@open-works.co.uk |
| |
| Copyright (C) 2007-2013 Apple, Inc. |
| |
| 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. |
| |
| Neither the names of the U.S. Department of Energy nor the |
| University of California nor the names of its contributors may be |
| used to endorse or promote products derived from this software |
| without prior written permission. |
| */ |
| |
| #include "pub_tool_basics.h" |
| #include "pub_tool_libcassert.h" |
| #include "pub_tool_libcbase.h" |
| #include "pub_tool_libcprint.h" |
| #include "pub_tool_threadstate.h" |
| #include "pub_tool_tooliface.h" |
| #include "pub_tool_hashtable.h" |
| #include "pub_tool_replacemalloc.h" |
| #include "pub_tool_machine.h" |
| #include "pub_tool_options.h" |
| #include "pub_tool_xarray.h" |
| #include "pub_tool_stacktrace.h" |
| #include "pub_tool_wordfm.h" |
| #include "pub_tool_debuginfo.h" // VG_(find_seginfo), VG_(seginfo_soname) |
| #include "pub_tool_redir.h" // sonames for the dynamic linkers |
| #include "pub_tool_vki.h" // VKI_PAGE_SIZE |
| #include "pub_tool_libcproc.h" // VG_(atfork) |
| #include "pub_tool_aspacemgr.h" // VG_(am_is_valid_for_client) |
| |
| #include "hg_basics.h" |
| #include "hg_wordset.h" |
| #include "hg_lock_n_thread.h" |
| #include "hg_errors.h" |
| |
| #include "libhb.h" |
| |
| #include "helgrind.h" |
| |
| |
| // FIXME: new_mem_w_tid ignores the supplied tid. (wtf?!) |
| |
| // FIXME: when client destroys a lock or a CV, remove these |
| // from our mappings, so that the associated SO can be freed up |
| |
| /*----------------------------------------------------------------*/ |
| /*--- ---*/ |
| /*----------------------------------------------------------------*/ |
| |
| /* Note this needs to be compiled with -fno-strict-aliasing, since it |
| contains a whole bunch of calls to lookupFM etc which cast between |
| Word and pointer types. gcc rightly complains this breaks ANSI C |
| strict aliasing rules, at -O2. No complaints at -O, but -O2 gives |
| worthwhile performance benefits over -O. |
| */ |
| |
| // FIXME what is supposed to happen to locks in memory which |
| // is relocated as a result of client realloc? |
| |
| // FIXME put referencing ThreadId into Thread and get |
| // rid of the slow reverse mapping function. |
| |
| // FIXME accesses to NoAccess areas: change state to Excl? |
| |
| // FIXME report errors for accesses of NoAccess memory? |
| |
| // FIXME pth_cond_wait/timedwait wrappers. Even if these fail, |
| // the thread still holds the lock. |
| |
| /* ------------ Debug/trace options ------------ */ |
| |
| // 0 for silent, 1 for some stuff, 2 for lots of stuff |
| #define SHOW_EVENTS 0 |
| |
| |
| static void all__sanity_check ( const HChar* who ); /* fwds */ |
| |
| #define HG_CLI__DEFAULT_MALLOC_REDZONE_SZB 16 /* let's say */ |
| |
| // 0 for none, 1 for dump at end of run |
| #define SHOW_DATA_STRUCTURES 0 |
| |
| |
| /* ------------ Misc comments ------------ */ |
| |
| // FIXME: don't hardwire initial entries for root thread. |
| // Instead, let the pre_thread_ll_create handler do this. |
| |
| |
| /*----------------------------------------------------------------*/ |
| /*--- Primary data structures ---*/ |
| /*----------------------------------------------------------------*/ |
| |
| /* Admin linked list of Threads */ |
| static Thread* admin_threads = NULL; |
| Thread* get_admin_threads ( void ) { return admin_threads; } |
| |
| /* Admin double linked list of Locks */ |
| /* We need a double linked list to properly and efficiently |
| handle del_LockN. */ |
| static Lock* admin_locks = NULL; |
| |
| /* Mapping table for core ThreadIds to Thread* */ |
| static Thread** map_threads = NULL; /* Array[VG_N_THREADS] of Thread* */ |
| |
| /* Mapping table for lock guest addresses to Lock* */ |
| static WordFM* map_locks = NULL; /* WordFM LockAddr Lock* */ |
| |
| /* The word-set universes for lock sets. */ |
| static WordSetU* univ_lsets = NULL; /* sets of Lock* */ |
| static WordSetU* univ_laog = NULL; /* sets of Lock*, for LAOG */ |
| static Int next_gc_univ_laog = 1; |
| /* univ_laog will be garbaged collected when the nr of element in univ_laog is |
| >= next_gc_univ_laog. */ |
| |
| /* Allow libhb to get at the universe of locksets stored |
| here. Sigh. */ |
| WordSetU* HG_(get_univ_lsets) ( void ) { return univ_lsets; } |
| |
| /* Allow libhb to get at the list of locks stored here. Ditto |
| sigh. */ |
| Lock* HG_(get_admin_locks) ( void ) { return admin_locks; } |
| |
| |
| /*----------------------------------------------------------------*/ |
| /*--- Simple helpers for the data structures ---*/ |
| /*----------------------------------------------------------------*/ |
| |
| static UWord stats__lockN_acquires = 0; |
| static UWord stats__lockN_releases = 0; |
| |
| static |
| ThreadId map_threads_maybe_reverse_lookup_SLOW ( Thread* thr ); /*fwds*/ |
| |
| /* --------- Constructors --------- */ |
| |
| static Thread* mk_Thread ( Thr* hbthr ) { |
| static Int indx = 1; |
| Thread* thread = HG_(zalloc)( "hg.mk_Thread.1", sizeof(Thread) ); |
| thread->locksetA = HG_(emptyWS)( univ_lsets ); |
| thread->locksetW = HG_(emptyWS)( univ_lsets ); |
| thread->magic = Thread_MAGIC; |
| thread->hbthr = hbthr; |
| thread->coretid = VG_INVALID_THREADID; |
| thread->created_at = NULL; |
| thread->announced = False; |
| thread->errmsg_index = indx++; |
| thread->admin = admin_threads; |
| admin_threads = thread; |
| return thread; |
| } |
| |
| // Make a new lock which is unlocked (hence ownerless) |
| // and insert the new lock in admin_locks double linked list. |
| static Lock* mk_LockN ( LockKind kind, Addr guestaddr ) { |
| static ULong unique = 0; |
| Lock* lock = HG_(zalloc)( "hg.mk_Lock.1", sizeof(Lock) ); |
| /* begin: add to double linked list */ |
| if (admin_locks) |
| admin_locks->admin_prev = lock; |
| lock->admin_next = admin_locks; |
| lock->admin_prev = NULL; |
| admin_locks = lock; |
| /* end: add */ |
| lock->unique = unique++; |
| lock->magic = LockN_MAGIC; |
| lock->appeared_at = NULL; |
| lock->acquired_at = NULL; |
| lock->hbso = libhb_so_alloc(); |
| lock->guestaddr = guestaddr; |
| lock->kind = kind; |
| lock->heldW = False; |
| lock->heldBy = NULL; |
| tl_assert(HG_(is_sane_LockN)(lock)); |
| return lock; |
| } |
| |
| /* Release storage for a Lock. Also release storage in .heldBy, if |
| any. Removes from admin_locks double linked list. */ |
| static void del_LockN ( Lock* lk ) |
| { |
| tl_assert(HG_(is_sane_LockN)(lk)); |
| tl_assert(lk->hbso); |
| libhb_so_dealloc(lk->hbso); |
| if (lk->heldBy) |
| VG_(deleteBag)( lk->heldBy ); |
| /* begin: del lock from double linked list */ |
| if (lk == admin_locks) { |
| tl_assert(lk->admin_prev == NULL); |
| if (lk->admin_next) |
| lk->admin_next->admin_prev = NULL; |
| admin_locks = lk->admin_next; |
| } |
| else { |
| tl_assert(lk->admin_prev != NULL); |
| lk->admin_prev->admin_next = lk->admin_next; |
| if (lk->admin_next) |
| lk->admin_next->admin_prev = lk->admin_prev; |
| } |
| /* end: del */ |
| VG_(memset)(lk, 0xAA, sizeof(*lk)); |
| HG_(free)(lk); |
| } |
| |
| /* Update 'lk' to reflect that 'thr' now has a write-acquisition of |
| it. This is done strictly: only combinations resulting from |
| correct program and libpthread behaviour are allowed. */ |
| static void lockN_acquire_writer ( Lock* lk, Thread* thr ) |
| { |
| tl_assert(HG_(is_sane_LockN)(lk)); |
| tl_assert(HG_(is_sane_Thread)(thr)); |
| |
| stats__lockN_acquires++; |
| |
| /* EXPOSITION only */ |
| /* We need to keep recording snapshots of where the lock was |
| acquired, so as to produce better lock-order error messages. */ |
| if (lk->acquired_at == NULL) { |
| ThreadId tid; |
| tl_assert(lk->heldBy == NULL); |
| tid = map_threads_maybe_reverse_lookup_SLOW(thr); |
| lk->acquired_at |
| = VG_(record_ExeContext)(tid, 0/*first_ip_delta*/); |
| } else { |
| tl_assert(lk->heldBy != NULL); |
| } |
| /* end EXPOSITION only */ |
| |
| switch (lk->kind) { |
| case LK_nonRec: |
| case_LK_nonRec: |
| tl_assert(lk->heldBy == NULL); /* can't w-lock recursively */ |
| tl_assert(!lk->heldW); |
| lk->heldW = True; |
| lk->heldBy = VG_(newBag)( HG_(zalloc), "hg.lNaw.1", HG_(free) ); |
| VG_(addToBag)( lk->heldBy, (UWord)thr ); |
| break; |
| case LK_mbRec: |
| if (lk->heldBy == NULL) |
| goto case_LK_nonRec; |
| /* 2nd and subsequent locking of a lock by its owner */ |
| tl_assert(lk->heldW); |
| /* assert: lk is only held by one thread .. */ |
| tl_assert(VG_(sizeUniqueBag(lk->heldBy)) == 1); |
| /* assert: .. and that thread is 'thr'. */ |
| tl_assert(VG_(elemBag)(lk->heldBy, (UWord)thr) |
| == VG_(sizeTotalBag)(lk->heldBy)); |
| VG_(addToBag)(lk->heldBy, (UWord)thr); |
| break; |
| case LK_rdwr: |
| tl_assert(lk->heldBy == NULL && !lk->heldW); /* must be unheld */ |
| goto case_LK_nonRec; |
| default: |
| tl_assert(0); |
| } |
| tl_assert(HG_(is_sane_LockN)(lk)); |
| } |
| |
| static void lockN_acquire_reader ( Lock* lk, Thread* thr ) |
| { |
| tl_assert(HG_(is_sane_LockN)(lk)); |
| tl_assert(HG_(is_sane_Thread)(thr)); |
| /* can only add reader to a reader-writer lock. */ |
| tl_assert(lk->kind == LK_rdwr); |
| /* lk must be free or already r-held. */ |
| tl_assert(lk->heldBy == NULL |
| || (lk->heldBy != NULL && !lk->heldW)); |
| |
| stats__lockN_acquires++; |
| |
| /* EXPOSITION only */ |
| /* We need to keep recording snapshots of where the lock was |
| acquired, so as to produce better lock-order error messages. */ |
| if (lk->acquired_at == NULL) { |
| ThreadId tid; |
| tl_assert(lk->heldBy == NULL); |
| tid = map_threads_maybe_reverse_lookup_SLOW(thr); |
| lk->acquired_at |
| = VG_(record_ExeContext)(tid, 0/*first_ip_delta*/); |
| } else { |
| tl_assert(lk->heldBy != NULL); |
| } |
| /* end EXPOSITION only */ |
| |
| if (lk->heldBy) { |
| VG_(addToBag)(lk->heldBy, (UWord)thr); |
| } else { |
| lk->heldW = False; |
| lk->heldBy = VG_(newBag)( HG_(zalloc), "hg.lNar.1", HG_(free) ); |
| VG_(addToBag)( lk->heldBy, (UWord)thr ); |
| } |
| tl_assert(!lk->heldW); |
| tl_assert(HG_(is_sane_LockN)(lk)); |
| } |
| |
| /* Update 'lk' to reflect a release of it by 'thr'. This is done |
| strictly: only combinations resulting from correct program and |
| libpthread behaviour are allowed. */ |
| |
| static void lockN_release ( Lock* lk, Thread* thr ) |
| { |
| Bool b; |
| tl_assert(HG_(is_sane_LockN)(lk)); |
| tl_assert(HG_(is_sane_Thread)(thr)); |
| /* lock must be held by someone */ |
| tl_assert(lk->heldBy); |
| stats__lockN_releases++; |
| /* Remove it from the holder set */ |
| b = VG_(delFromBag)(lk->heldBy, (UWord)thr); |
| /* thr must actually have been a holder of lk */ |
| tl_assert(b); |
| /* normalise */ |
| tl_assert(lk->acquired_at); |
| if (VG_(isEmptyBag)(lk->heldBy)) { |
| VG_(deleteBag)(lk->heldBy); |
| lk->heldBy = NULL; |
| lk->heldW = False; |
| lk->acquired_at = NULL; |
| } |
| tl_assert(HG_(is_sane_LockN)(lk)); |
| } |
| |
| static void remove_Lock_from_locksets_of_all_owning_Threads( Lock* lk ) |
| { |
| Thread* thr; |
| if (!lk->heldBy) { |
| tl_assert(!lk->heldW); |
| return; |
| } |
| /* for each thread that holds this lock do ... */ |
| VG_(initIterBag)( lk->heldBy ); |
| while (VG_(nextIterBag)( lk->heldBy, (UWord*)&thr, NULL )) { |
| tl_assert(HG_(is_sane_Thread)(thr)); |
| tl_assert(HG_(elemWS)( univ_lsets, |
| thr->locksetA, (UWord)lk )); |
| thr->locksetA |
| = HG_(delFromWS)( univ_lsets, thr->locksetA, (UWord)lk ); |
| |
| if (lk->heldW) { |
| tl_assert(HG_(elemWS)( univ_lsets, |
| thr->locksetW, (UWord)lk )); |
| thr->locksetW |
| = HG_(delFromWS)( univ_lsets, thr->locksetW, (UWord)lk ); |
| } |
| } |
| VG_(doneIterBag)( lk->heldBy ); |
| } |
| |
| |
| /*----------------------------------------------------------------*/ |
| /*--- Print out the primary data structures ---*/ |
| /*----------------------------------------------------------------*/ |
| |
| #define PP_THREADS (1<<1) |
| #define PP_LOCKS (1<<2) |
| #define PP_ALL (PP_THREADS | PP_LOCKS) |
| |
| |
| static const Int sHOW_ADMIN = 0; |
| |
| static void space ( Int n ) |
| { |
| Int i; |
| HChar spaces[128+1]; |
| tl_assert(n >= 0 && n < 128); |
| if (n == 0) |
| return; |
| for (i = 0; i < n; i++) |
| spaces[i] = ' '; |
| spaces[i] = 0; |
| tl_assert(i < 128+1); |
| VG_(printf)("%s", spaces); |
| } |
| |
| static void pp_Thread ( Int d, Thread* t ) |
| { |
| space(d+0); VG_(printf)("Thread %p {\n", t); |
| if (sHOW_ADMIN) { |
| space(d+3); VG_(printf)("admin %p\n", t->admin); |
| space(d+3); VG_(printf)("magic 0x%x\n", (UInt)t->magic); |
| } |
| space(d+3); VG_(printf)("locksetA %d\n", (Int)t->locksetA); |
| space(d+3); VG_(printf)("locksetW %d\n", (Int)t->locksetW); |
| space(d+0); VG_(printf)("}\n"); |
| } |
| |
| static void pp_admin_threads ( Int d ) |
| { |
| Int i, n; |
| Thread* t; |
| for (n = 0, t = admin_threads; t; n++, t = t->admin) { |
| /* nothing */ |
| } |
| space(d); VG_(printf)("admin_threads (%d records) {\n", n); |
| for (i = 0, t = admin_threads; t; i++, t = t->admin) { |
| if (0) { |
| space(n); |
| VG_(printf)("admin_threads record %d of %d:\n", i, n); |
| } |
| pp_Thread(d+3, t); |
| } |
| space(d); VG_(printf)("}\n"); |
| } |
| |
| static void pp_map_threads ( Int d ) |
| { |
| Int i, n = 0; |
| space(d); VG_(printf)("map_threads "); |
| for (i = 0; i < VG_N_THREADS; i++) { |
| if (map_threads[i] != NULL) |
| n++; |
| } |
| VG_(printf)("(%d entries) {\n", n); |
| for (i = 0; i < VG_N_THREADS; i++) { |
| if (map_threads[i] == NULL) |
| continue; |
| space(d+3); |
| VG_(printf)("coretid %d -> Thread %p\n", i, map_threads[i]); |
| } |
| space(d); VG_(printf)("}\n"); |
| } |
| |
| static const HChar* show_LockKind ( LockKind lkk ) { |
| switch (lkk) { |
| case LK_mbRec: return "mbRec"; |
| case LK_nonRec: return "nonRec"; |
| case LK_rdwr: return "rdwr"; |
| default: tl_assert(0); |
| } |
| } |
| |
| static void pp_Lock ( Int d, Lock* lk ) |
| { |
| space(d+0); VG_(printf)("Lock %p (ga %#lx) {\n", lk, lk->guestaddr); |
| if (sHOW_ADMIN) { |
| space(d+3); VG_(printf)("admin_n %p\n", lk->admin_next); |
| space(d+3); VG_(printf)("admin_p %p\n", lk->admin_prev); |
| space(d+3); VG_(printf)("magic 0x%x\n", (UInt)lk->magic); |
| } |
| space(d+3); VG_(printf)("unique %llu\n", lk->unique); |
| space(d+3); VG_(printf)("kind %s\n", show_LockKind(lk->kind)); |
| space(d+3); VG_(printf)("heldW %s\n", lk->heldW ? "yes" : "no"); |
| space(d+3); VG_(printf)("heldBy %p", lk->heldBy); |
| if (lk->heldBy) { |
| Thread* thr; |
| UWord count; |
| VG_(printf)(" { "); |
| VG_(initIterBag)( lk->heldBy ); |
| while (VG_(nextIterBag)( lk->heldBy, (UWord*)&thr, &count )) |
| VG_(printf)("%lu:%p ", count, thr); |
| VG_(doneIterBag)( lk->heldBy ); |
| VG_(printf)("}"); |
| } |
| VG_(printf)("\n"); |
| space(d+0); VG_(printf)("}\n"); |
| } |
| |
| static void pp_admin_locks ( Int d ) |
| { |
| Int i, n; |
| Lock* lk; |
| for (n = 0, lk = admin_locks; lk; n++, lk = lk->admin_next) { |
| /* nothing */ |
| } |
| space(d); VG_(printf)("admin_locks (%d records) {\n", n); |
| for (i = 0, lk = admin_locks; lk; i++, lk = lk->admin_next) { |
| if (0) { |
| space(n); |
| VG_(printf)("admin_locks record %d of %d:\n", i, n); |
| } |
| pp_Lock(d+3, lk); |
| } |
| space(d); VG_(printf)("}\n"); |
| } |
| |
| static void pp_map_locks ( Int d ) |
| { |
| void* gla; |
| Lock* lk; |
| space(d); VG_(printf)("map_locks (%d entries) {\n", |
| (Int)VG_(sizeFM)( map_locks )); |
| VG_(initIterFM)( map_locks ); |
| while (VG_(nextIterFM)( map_locks, (UWord*)&gla, |
| (UWord*)&lk )) { |
| space(d+3); |
| VG_(printf)("guest %p -> Lock %p\n", gla, lk); |
| } |
| VG_(doneIterFM)( map_locks ); |
| space(d); VG_(printf)("}\n"); |
| } |
| |
| static void pp_everything ( Int flags, const HChar* caller ) |
| { |
| Int d = 0; |
| VG_(printf)("\n"); |
| VG_(printf)("All_Data_Structures (caller = \"%s\") {\n", caller); |
| if (flags & PP_THREADS) { |
| VG_(printf)("\n"); |
| pp_admin_threads(d+3); |
| VG_(printf)("\n"); |
| pp_map_threads(d+3); |
| } |
| if (flags & PP_LOCKS) { |
| VG_(printf)("\n"); |
| pp_admin_locks(d+3); |
| VG_(printf)("\n"); |
| pp_map_locks(d+3); |
| } |
| |
| VG_(printf)("\n"); |
| VG_(printf)("}\n"); |
| VG_(printf)("\n"); |
| } |
| |
| #undef SHOW_ADMIN |
| |
| |
| /*----------------------------------------------------------------*/ |
| /*--- Initialise the primary data structures ---*/ |
| /*----------------------------------------------------------------*/ |
| |
| static void initialise_data_structures ( Thr* hbthr_root ) |
| { |
| Thread* thr; |
| WordSetID wsid; |
| |
| /* Get everything initialised and zeroed. */ |
| tl_assert(admin_threads == NULL); |
| tl_assert(admin_locks == NULL); |
| |
| tl_assert(map_threads == NULL); |
| map_threads = HG_(zalloc)( "hg.ids.1", VG_N_THREADS * sizeof(Thread*) ); |
| tl_assert(map_threads != NULL); |
| |
| tl_assert(sizeof(Addr) == sizeof(UWord)); |
| tl_assert(map_locks == NULL); |
| map_locks = VG_(newFM)( HG_(zalloc), "hg.ids.2", HG_(free), |
| NULL/*unboxed Word cmp*/); |
| tl_assert(map_locks != NULL); |
| |
| tl_assert(univ_lsets == NULL); |
| univ_lsets = HG_(newWordSetU)( HG_(zalloc), "hg.ids.4", HG_(free), |
| 8/*cacheSize*/ ); |
| tl_assert(univ_lsets != NULL); |
| /* Ensure that univ_lsets is non-empty, with lockset zero being the |
| empty lockset. hg_errors.c relies on the assumption that |
| lockset number zero in univ_lsets is always valid. */ |
| wsid = HG_(emptyWS)(univ_lsets); |
| tl_assert(wsid == 0); |
| |
| tl_assert(univ_laog == NULL); |
| if (HG_(clo_track_lockorders)) { |
| univ_laog = HG_(newWordSetU)( HG_(zalloc), "hg.ids.5 (univ_laog)", |
| HG_(free), 24/*cacheSize*/ ); |
| tl_assert(univ_laog != NULL); |
| } |
| |
| /* Set up entries for the root thread */ |
| // FIXME: this assumes that the first real ThreadId is 1 |
| |
| /* a Thread for the new thread ... */ |
| thr = mk_Thread(hbthr_root); |
| thr->coretid = 1; /* FIXME: hardwires an assumption about the |
| identity of the root thread. */ |
| tl_assert( libhb_get_Thr_hgthread(hbthr_root) == NULL ); |
| libhb_set_Thr_hgthread(hbthr_root, thr); |
| |
| /* and bind it in the thread-map table. */ |
| tl_assert(HG_(is_sane_ThreadId)(thr->coretid)); |
| tl_assert(thr->coretid != VG_INVALID_THREADID); |
| |
| map_threads[thr->coretid] = thr; |
| |
| tl_assert(VG_INVALID_THREADID == 0); |
| |
| all__sanity_check("initialise_data_structures"); |
| } |
| |
| |
| /*----------------------------------------------------------------*/ |
| /*--- map_threads :: array[core-ThreadId] of Thread* ---*/ |
| /*----------------------------------------------------------------*/ |
| |
| /* Doesn't assert if the relevant map_threads entry is NULL. */ |
| static Thread* map_threads_maybe_lookup ( ThreadId coretid ) |
| { |
| Thread* thr; |
| tl_assert( HG_(is_sane_ThreadId)(coretid) ); |
| thr = map_threads[coretid]; |
| return thr; |
| } |
| |
| /* Asserts if the relevant map_threads entry is NULL. */ |
| static inline Thread* map_threads_lookup ( ThreadId coretid ) |
| { |
| Thread* thr; |
| tl_assert( HG_(is_sane_ThreadId)(coretid) ); |
| thr = map_threads[coretid]; |
| tl_assert(thr); |
| return thr; |
| } |
| |
| /* Do a reverse lookup. Does not assert if 'thr' is not found in |
| map_threads. */ |
| static ThreadId map_threads_maybe_reverse_lookup_SLOW ( Thread* thr ) |
| { |
| ThreadId tid; |
| tl_assert(HG_(is_sane_Thread)(thr)); |
| /* Check nobody used the invalid-threadid slot */ |
| tl_assert(VG_INVALID_THREADID >= 0 && VG_INVALID_THREADID < VG_N_THREADS); |
| tl_assert(map_threads[VG_INVALID_THREADID] == NULL); |
| tid = thr->coretid; |
| tl_assert(HG_(is_sane_ThreadId)(tid)); |
| return tid; |
| } |
| |
| /* Do a reverse lookup. Warning: POTENTIALLY SLOW. Asserts if 'thr' |
| is not found in map_threads. */ |
| static ThreadId map_threads_reverse_lookup_SLOW ( Thread* thr ) |
| { |
| ThreadId tid = map_threads_maybe_reverse_lookup_SLOW( thr ); |
| tl_assert(tid != VG_INVALID_THREADID); |
| tl_assert(map_threads[tid]); |
| tl_assert(map_threads[tid]->coretid == tid); |
| return tid; |
| } |
| |
| static void map_threads_delete ( ThreadId coretid ) |
| { |
| Thread* thr; |
| tl_assert(coretid != 0); |
| tl_assert( HG_(is_sane_ThreadId)(coretid) ); |
| thr = map_threads[coretid]; |
| tl_assert(thr); |
| map_threads[coretid] = NULL; |
| } |
| |
| |
| /*----------------------------------------------------------------*/ |
| /*--- map_locks :: WordFM guest-Addr-of-lock Lock* ---*/ |
| /*----------------------------------------------------------------*/ |
| |
| /* Make sure there is a lock table entry for the given (lock) guest |
| address. If not, create one of the stated 'kind' in unheld state. |
| In any case, return the address of the existing or new Lock. */ |
| static |
| Lock* map_locks_lookup_or_create ( LockKind lkk, Addr ga, ThreadId tid ) |
| { |
| Bool found; |
| Lock* oldlock = NULL; |
| tl_assert(HG_(is_sane_ThreadId)(tid)); |
| found = VG_(lookupFM)( map_locks, |
| NULL, (UWord*)&oldlock, (UWord)ga ); |
| if (!found) { |
| Lock* lock = mk_LockN(lkk, ga); |
| lock->appeared_at = VG_(record_ExeContext)( tid, 0 ); |
| tl_assert(HG_(is_sane_LockN)(lock)); |
| VG_(addToFM)( map_locks, (UWord)ga, (UWord)lock ); |
| tl_assert(oldlock == NULL); |
| return lock; |
| } else { |
| tl_assert(oldlock != NULL); |
| tl_assert(HG_(is_sane_LockN)(oldlock)); |
| tl_assert(oldlock->guestaddr == ga); |
| return oldlock; |
| } |
| } |
| |
| static Lock* map_locks_maybe_lookup ( Addr ga ) |
| { |
| Bool found; |
| Lock* lk = NULL; |
| found = VG_(lookupFM)( map_locks, NULL, (UWord*)&lk, (UWord)ga ); |
| tl_assert(found ? lk != NULL : lk == NULL); |
| return lk; |
| } |
| |
| static void map_locks_delete ( Addr ga ) |
| { |
| Addr ga2 = 0; |
| Lock* lk = NULL; |
| VG_(delFromFM)( map_locks, |
| (UWord*)&ga2, (UWord*)&lk, (UWord)ga ); |
| /* delFromFM produces the val which is being deleted, if it is |
| found. So assert it is non-null; that in effect asserts that we |
| are deleting a (ga, Lock) pair which actually exists. */ |
| tl_assert(lk != NULL); |
| tl_assert(ga2 == ga); |
| } |
| |
| |
| |
| /*----------------------------------------------------------------*/ |
| /*--- Sanity checking the data structures ---*/ |
| /*----------------------------------------------------------------*/ |
| |
| static UWord stats__sanity_checks = 0; |
| |
| static void laog__sanity_check ( const HChar* who ); /* fwds */ |
| |
| /* REQUIRED INVARIANTS: |
| |
| Thread vs Segment/Lock/SecMaps |
| |
| for each t in Threads { |
| |
| // Thread.lockset: each element is really a valid Lock |
| |
| // Thread.lockset: each Lock in set is actually held by that thread |
| for lk in Thread.lockset |
| lk == LockedBy(t) |
| |
| // Thread.csegid is a valid SegmentID |
| // and the associated Segment has .thr == t |
| |
| } |
| |
| all thread Locksets are pairwise empty under intersection |
| (that is, no lock is claimed to be held by more than one thread) |
| -- this is guaranteed if all locks in locksets point back to their |
| owner threads |
| |
| Lock vs Thread/Segment/SecMaps |
| |
| for each entry (gla, la) in map_locks |
| gla == la->guest_addr |
| |
| for each lk in Locks { |
| |
| lk->tag is valid |
| lk->guest_addr does not have shadow state NoAccess |
| if lk == LockedBy(t), then t->lockset contains lk |
| if lk == UnlockedBy(segid) then segid is valid SegmentID |
| and can be mapped to a valid Segment(seg) |
| and seg->thr->lockset does not contain lk |
| if lk == UnlockedNew then (no lockset contains lk) |
| |
| secmaps for lk has .mbHasLocks == True |
| |
| } |
| |
| Segment vs Thread/Lock/SecMaps |
| |
| the Segment graph is a dag (no cycles) |
| all of the Segment graph must be reachable from the segids |
| mentioned in the Threads |
| |
| for seg in Segments { |
| |
| seg->thr is a sane Thread |
| |
| } |
| |
| SecMaps vs Segment/Thread/Lock |
| |
| for sm in SecMaps { |
| |
| sm properly aligned |
| if any shadow word is ShR or ShM then .mbHasShared == True |
| |
| for each Excl(segid) state |
| map_segments_lookup maps to a sane Segment(seg) |
| for each ShM/ShR(tsetid,lsetid) state |
| each lk in lset is a valid Lock |
| each thr in tset is a valid thread, which is non-dead |
| |
| } |
| */ |
| |
| |
| /* Return True iff 'thr' holds 'lk' in some mode. */ |
| static Bool thread_is_a_holder_of_Lock ( Thread* thr, Lock* lk ) |
| { |
| if (lk->heldBy) |
| return VG_(elemBag)( lk->heldBy, (UWord)thr ) > 0; |
| else |
| return False; |
| } |
| |
| /* Sanity check Threads, as far as possible */ |
| __attribute__((noinline)) |
| static void threads__sanity_check ( const HChar* who ) |
| { |
| #define BAD(_str) do { how = (_str); goto bad; } while (0) |
| const HChar* how = "no error"; |
| Thread* thr; |
| WordSetID wsA, wsW; |
| UWord* ls_words; |
| UWord ls_size, i; |
| Lock* lk; |
| for (thr = admin_threads; thr; thr = thr->admin) { |
| if (!HG_(is_sane_Thread)(thr)) BAD("1"); |
| wsA = thr->locksetA; |
| wsW = thr->locksetW; |
| // locks held in W mode are a subset of all locks held |
| if (!HG_(isSubsetOf)( univ_lsets, wsW, wsA )) BAD("7"); |
| HG_(getPayloadWS)( &ls_words, &ls_size, univ_lsets, wsA ); |
| for (i = 0; i < ls_size; i++) { |
| lk = (Lock*)ls_words[i]; |
| // Thread.lockset: each element is really a valid Lock |
| if (!HG_(is_sane_LockN)(lk)) BAD("2"); |
| // Thread.lockset: each Lock in set is actually held by that |
| // thread |
| if (!thread_is_a_holder_of_Lock(thr,lk)) BAD("3"); |
| } |
| } |
| return; |
| bad: |
| VG_(printf)("threads__sanity_check: who=\"%s\", bad=\"%s\"\n", who, how); |
| tl_assert(0); |
| #undef BAD |
| } |
| |
| |
| /* Sanity check Locks, as far as possible */ |
| __attribute__((noinline)) |
| static void locks__sanity_check ( const HChar* who ) |
| { |
| #define BAD(_str) do { how = (_str); goto bad; } while (0) |
| const HChar* how = "no error"; |
| Addr gla; |
| Lock* lk; |
| Int i; |
| // # entries in admin_locks == # entries in map_locks |
| for (i = 0, lk = admin_locks; lk; i++, lk = lk->admin_next) |
| ; |
| if (i != VG_(sizeFM)(map_locks)) BAD("1"); |
| // for each entry (gla, lk) in map_locks |
| // gla == lk->guest_addr |
| VG_(initIterFM)( map_locks ); |
| while (VG_(nextIterFM)( map_locks, |
| (UWord*)&gla, (UWord*)&lk )) { |
| if (lk->guestaddr != gla) BAD("2"); |
| } |
| VG_(doneIterFM)( map_locks ); |
| // scan through admin_locks ... |
| for (lk = admin_locks; lk; lk = lk->admin_next) { |
| // lock is sane. Quite comprehensive, also checks that |
| // referenced (holder) threads are sane. |
| if (!HG_(is_sane_LockN)(lk)) BAD("3"); |
| // map_locks binds guest address back to this lock |
| if (lk != map_locks_maybe_lookup(lk->guestaddr)) BAD("4"); |
| // look at all threads mentioned as holders of this lock. Ensure |
| // this lock is mentioned in their locksets. |
| if (lk->heldBy) { |
| Thread* thr; |
| UWord count; |
| VG_(initIterBag)( lk->heldBy ); |
| while (VG_(nextIterBag)( lk->heldBy, |
| (UWord*)&thr, &count )) { |
| // HG_(is_sane_LockN) above ensures these |
| tl_assert(count >= 1); |
| tl_assert(HG_(is_sane_Thread)(thr)); |
| if (!HG_(elemWS)(univ_lsets, thr->locksetA, (UWord)lk)) |
| BAD("6"); |
| // also check the w-only lockset |
| if (lk->heldW |
| && !HG_(elemWS)(univ_lsets, thr->locksetW, (UWord)lk)) |
| BAD("7"); |
| if ((!lk->heldW) |
| && HG_(elemWS)(univ_lsets, thr->locksetW, (UWord)lk)) |
| BAD("8"); |
| } |
| VG_(doneIterBag)( lk->heldBy ); |
| } else { |
| /* lock not held by anybody */ |
| if (lk->heldW) BAD("9"); /* should be False if !heldBy */ |
| // since lk is unheld, then (no lockset contains lk) |
| // hmm, this is really too expensive to check. Hmm. |
| } |
| } |
| |
| return; |
| bad: |
| VG_(printf)("locks__sanity_check: who=\"%s\", bad=\"%s\"\n", who, how); |
| tl_assert(0); |
| #undef BAD |
| } |
| |
| |
| static void all_except_Locks__sanity_check ( const HChar* who ) { |
| stats__sanity_checks++; |
| if (0) VG_(printf)("all_except_Locks__sanity_check(%s)\n", who); |
| threads__sanity_check(who); |
| if (HG_(clo_track_lockorders)) |
| laog__sanity_check(who); |
| } |
| static void all__sanity_check ( const HChar* who ) { |
| all_except_Locks__sanity_check(who); |
| locks__sanity_check(who); |
| } |
| |
| |
| /*----------------------------------------------------------------*/ |
| /*--- Shadow value and address range handlers ---*/ |
| /*----------------------------------------------------------------*/ |
| |
| static void laog__pre_thread_acquires_lock ( Thread*, Lock* ); /* fwds */ |
| //static void laog__handle_lock_deletions ( WordSetID ); /* fwds */ |
| static inline Thread* get_current_Thread ( void ); /* fwds */ |
| __attribute__((noinline)) |
| static void laog__handle_one_lock_deletion ( Lock* lk ); /* fwds */ |
| |
| |
| /* Block-copy states (needed for implementing realloc()). */ |
| /* FIXME this copies shadow memory; it doesn't apply the MSM to it. |
| Is that a problem? (hence 'scopy' rather than 'ccopy') */ |
| static void shadow_mem_scopy_range ( Thread* thr, |
| Addr src, Addr dst, SizeT len ) |
| { |
| Thr* hbthr = thr->hbthr; |
| tl_assert(hbthr); |
| libhb_copy_shadow_state( hbthr, src, dst, len ); |
| } |
| |
| static void shadow_mem_cread_range ( Thread* thr, Addr a, SizeT len ) |
| { |
| Thr* hbthr = thr->hbthr; |
| tl_assert(hbthr); |
| LIBHB_CREAD_N(hbthr, a, len); |
| } |
| |
| static void shadow_mem_cwrite_range ( Thread* thr, Addr a, SizeT len ) { |
| Thr* hbthr = thr->hbthr; |
| tl_assert(hbthr); |
| LIBHB_CWRITE_N(hbthr, a, len); |
| } |
| |
| static void shadow_mem_make_New ( Thread* thr, Addr a, SizeT len ) |
| { |
| libhb_srange_new( thr->hbthr, a, len ); |
| } |
| |
| static void shadow_mem_make_NoAccess_NoFX ( Thread* thr, Addr aIN, SizeT len ) |
| { |
| if (0 && len > 500) |
| VG_(printf)("make NoAccess_NoFX ( %#lx, %ld )\n", aIN, len ); |
| // has no effect (NoFX) |
| libhb_srange_noaccess_NoFX( thr->hbthr, aIN, len ); |
| } |
| |
| static void shadow_mem_make_NoAccess_AHAE ( Thread* thr, Addr aIN, SizeT len ) |
| { |
| if (0 && len > 500) |
| VG_(printf)("make NoAccess_AHAE ( %#lx, %ld )\n", aIN, len ); |
| // Actually Has An Effect (AHAE) |
| libhb_srange_noaccess_AHAE( thr->hbthr, aIN, len ); |
| } |
| |
| static void shadow_mem_make_Untracked ( Thread* thr, Addr aIN, SizeT len ) |
| { |
| if (0 && len > 500) |
| VG_(printf)("make Untracked ( %#lx, %ld )\n", aIN, len ); |
| libhb_srange_untrack( thr->hbthr, aIN, len ); |
| } |
| |
| |
| /*----------------------------------------------------------------*/ |
| /*--- Event handlers (evh__* functions) ---*/ |
| /*--- plus helpers (evhH__* functions) ---*/ |
| /*----------------------------------------------------------------*/ |
| |
| /*--------- Event handler helpers (evhH__* functions) ---------*/ |
| |
| /* Create a new segment for 'thr', making it depend (.prev) on its |
| existing segment, bind together the SegmentID and Segment, and |
| return both of them. Also update 'thr' so it references the new |
| Segment. */ |
| //zz static |
| //zz void evhH__start_new_segment_for_thread ( /*OUT*/SegmentID* new_segidP, |
| //zz /*OUT*/Segment** new_segP, |
| //zz Thread* thr ) |
| //zz { |
| //zz Segment* cur_seg; |
| //zz tl_assert(new_segP); |
| //zz tl_assert(new_segidP); |
| //zz tl_assert(HG_(is_sane_Thread)(thr)); |
| //zz cur_seg = map_segments_lookup( thr->csegid ); |
| //zz tl_assert(cur_seg); |
| //zz tl_assert(cur_seg->thr == thr); /* all sane segs should point back |
| //zz at their owner thread. */ |
| //zz *new_segP = mk_Segment( thr, cur_seg, NULL/*other*/ ); |
| //zz *new_segidP = alloc_SegmentID(); |
| //zz map_segments_add( *new_segidP, *new_segP ); |
| //zz thr->csegid = *new_segidP; |
| //zz } |
| |
| |
| /* The lock at 'lock_ga' has acquired a writer. Make all necessary |
| updates, and also do all possible error checks. */ |
| static |
| void evhH__post_thread_w_acquires_lock ( Thread* thr, |
| LockKind lkk, Addr lock_ga ) |
| { |
| Lock* lk; |
| |
| /* Basically what we need to do is call lockN_acquire_writer. |
| However, that will barf if any 'invalid' lock states would |
| result. Therefore check before calling. Side effect is that |
| 'HG_(is_sane_LockN)(lk)' is both a pre- and post-condition of this |
| routine. |
| |
| Because this routine is only called after successful lock |
| acquisition, we should not be asked to move the lock into any |
| invalid states. Requests to do so are bugs in libpthread, since |
| that should have rejected any such requests. */ |
| |
| tl_assert(HG_(is_sane_Thread)(thr)); |
| /* Try to find the lock. If we can't, then create a new one with |
| kind 'lkk'. */ |
| lk = map_locks_lookup_or_create( |
| lkk, lock_ga, map_threads_reverse_lookup_SLOW(thr) ); |
| tl_assert( HG_(is_sane_LockN)(lk) ); |
| |
| /* check libhb level entities exist */ |
| tl_assert(thr->hbthr); |
| tl_assert(lk->hbso); |
| |
| if (lk->heldBy == NULL) { |
| /* the lock isn't held. Simple. */ |
| tl_assert(!lk->heldW); |
| lockN_acquire_writer( lk, thr ); |
| /* acquire a dependency from the lock's VCs */ |
| libhb_so_recv( thr->hbthr, lk->hbso, True/*strong_recv*/ ); |
| goto noerror; |
| } |
| |
| /* So the lock is already held. If held as a r-lock then |
| libpthread must be buggy. */ |
| tl_assert(lk->heldBy); |
| if (!lk->heldW) { |
| HG_(record_error_Misc)( |
| thr, "Bug in libpthread: write lock " |
| "granted on rwlock which is currently rd-held"); |
| goto error; |
| } |
| |
| /* So the lock is held in w-mode. If it's held by some other |
| thread, then libpthread must be buggy. */ |
| tl_assert(VG_(sizeUniqueBag)(lk->heldBy) == 1); /* from precondition */ |
| |
| if (thr != (Thread*)VG_(anyElementOfBag)(lk->heldBy)) { |
| HG_(record_error_Misc)( |
| thr, "Bug in libpthread: write lock " |
| "granted on mutex/rwlock which is currently " |
| "wr-held by a different thread"); |
| goto error; |
| } |
| |
| /* So the lock is already held in w-mode by 'thr'. That means this |
| is an attempt to lock it recursively, which is only allowable |
| for LK_mbRec kinded locks. Since this routine is called only |
| once the lock has been acquired, this must also be a libpthread |
| bug. */ |
| if (lk->kind != LK_mbRec) { |
| HG_(record_error_Misc)( |
| thr, "Bug in libpthread: recursive write lock " |
| "granted on mutex/wrlock which does not " |
| "support recursion"); |
| goto error; |
| } |
| |
| /* So we are recursively re-locking a lock we already w-hold. */ |
| lockN_acquire_writer( lk, thr ); |
| /* acquire a dependency from the lock's VC. Probably pointless, |
| but also harmless. */ |
| libhb_so_recv( thr->hbthr, lk->hbso, True/*strong_recv*/ ); |
| goto noerror; |
| |
| noerror: |
| if (HG_(clo_track_lockorders)) { |
| /* check lock order acquisition graph, and update. This has to |
| happen before the lock is added to the thread's locksetA/W. */ |
| laog__pre_thread_acquires_lock( thr, lk ); |
| } |
| /* update the thread's held-locks set */ |
| thr->locksetA = HG_(addToWS)( univ_lsets, thr->locksetA, (UWord)lk ); |
| thr->locksetW = HG_(addToWS)( univ_lsets, thr->locksetW, (UWord)lk ); |
| /* fall through */ |
| |
| error: |
| tl_assert(HG_(is_sane_LockN)(lk)); |
| } |
| |
| |
| /* The lock at 'lock_ga' has acquired a reader. Make all necessary |
| updates, and also do all possible error checks. */ |
| static |
| void evhH__post_thread_r_acquires_lock ( Thread* thr, |
| LockKind lkk, Addr lock_ga ) |
| { |
| Lock* lk; |
| |
| /* Basically what we need to do is call lockN_acquire_reader. |
| However, that will barf if any 'invalid' lock states would |
| result. Therefore check before calling. Side effect is that |
| 'HG_(is_sane_LockN)(lk)' is both a pre- and post-condition of this |
| routine. |
| |
| Because this routine is only called after successful lock |
| acquisition, we should not be asked to move the lock into any |
| invalid states. Requests to do so are bugs in libpthread, since |
| that should have rejected any such requests. */ |
| |
| tl_assert(HG_(is_sane_Thread)(thr)); |
| /* Try to find the lock. If we can't, then create a new one with |
| kind 'lkk'. Only a reader-writer lock can be read-locked, |
| hence the first assertion. */ |
| tl_assert(lkk == LK_rdwr); |
| lk = map_locks_lookup_or_create( |
| lkk, lock_ga, map_threads_reverse_lookup_SLOW(thr) ); |
| tl_assert( HG_(is_sane_LockN)(lk) ); |
| |
| /* check libhb level entities exist */ |
| tl_assert(thr->hbthr); |
| tl_assert(lk->hbso); |
| |
| if (lk->heldBy == NULL) { |
| /* the lock isn't held. Simple. */ |
| tl_assert(!lk->heldW); |
| lockN_acquire_reader( lk, thr ); |
| /* acquire a dependency from the lock's VC */ |
| libhb_so_recv( thr->hbthr, lk->hbso, False/*!strong_recv*/ ); |
| goto noerror; |
| } |
| |
| /* So the lock is already held. If held as a w-lock then |
| libpthread must be buggy. */ |
| tl_assert(lk->heldBy); |
| if (lk->heldW) { |
| HG_(record_error_Misc)( thr, "Bug in libpthread: read lock " |
| "granted on rwlock which is " |
| "currently wr-held"); |
| goto error; |
| } |
| |
| /* Easy enough. In short anybody can get a read-lock on a rwlock |
| provided it is either unlocked or already in rd-held. */ |
| lockN_acquire_reader( lk, thr ); |
| /* acquire a dependency from the lock's VC. Probably pointless, |
| but also harmless. */ |
| libhb_so_recv( thr->hbthr, lk->hbso, False/*!strong_recv*/ ); |
| goto noerror; |
| |
| noerror: |
| if (HG_(clo_track_lockorders)) { |
| /* check lock order acquisition graph, and update. This has to |
| happen before the lock is added to the thread's locksetA/W. */ |
| laog__pre_thread_acquires_lock( thr, lk ); |
| } |
| /* update the thread's held-locks set */ |
| thr->locksetA = HG_(addToWS)( univ_lsets, thr->locksetA, (UWord)lk ); |
| /* but don't update thr->locksetW, since lk is only rd-held */ |
| /* fall through */ |
| |
| error: |
| tl_assert(HG_(is_sane_LockN)(lk)); |
| } |
| |
| |
| /* The lock at 'lock_ga' is just about to be unlocked. Make all |
| necessary updates, and also do all possible error checks. */ |
| static |
| void evhH__pre_thread_releases_lock ( Thread* thr, |
| Addr lock_ga, Bool isRDWR ) |
| { |
| Lock* lock; |
| Word n; |
| Bool was_heldW; |
| |
| /* This routine is called prior to a lock release, before |
| libpthread has had a chance to validate the call. Hence we need |
| to detect and reject any attempts to move the lock into an |
| invalid state. Such attempts are bugs in the client. |
| |
| isRDWR is True if we know from the wrapper context that lock_ga |
| should refer to a reader-writer lock, and is False if [ditto] |
| lock_ga should refer to a standard mutex. */ |
| |
| tl_assert(HG_(is_sane_Thread)(thr)); |
| lock = map_locks_maybe_lookup( lock_ga ); |
| |
| if (!lock) { |
| /* We know nothing about a lock at 'lock_ga'. Nevertheless |
| the client is trying to unlock it. So complain, then ignore |
| the attempt. */ |
| HG_(record_error_UnlockBogus)( thr, lock_ga ); |
| return; |
| } |
| |
| tl_assert(lock->guestaddr == lock_ga); |
| tl_assert(HG_(is_sane_LockN)(lock)); |
| |
| if (isRDWR && lock->kind != LK_rdwr) { |
| HG_(record_error_Misc)( thr, "pthread_rwlock_unlock with a " |
| "pthread_mutex_t* argument " ); |
| } |
| if ((!isRDWR) && lock->kind == LK_rdwr) { |
| HG_(record_error_Misc)( thr, "pthread_mutex_unlock with a " |
| "pthread_rwlock_t* argument " ); |
| } |
| |
| if (!lock->heldBy) { |
| /* The lock is not held. This indicates a serious bug in the |
| client. */ |
| tl_assert(!lock->heldW); |
| HG_(record_error_UnlockUnlocked)( thr, lock ); |
| tl_assert(!HG_(elemWS)( univ_lsets, thr->locksetA, (UWord)lock )); |
| tl_assert(!HG_(elemWS)( univ_lsets, thr->locksetW, (UWord)lock )); |
| goto error; |
| } |
| |
| /* test just above dominates */ |
| tl_assert(lock->heldBy); |
| was_heldW = lock->heldW; |
| |
| /* The lock is held. Is this thread one of the holders? If not, |
| report a bug in the client. */ |
| n = VG_(elemBag)( lock->heldBy, (UWord)thr ); |
| tl_assert(n >= 0); |
| if (n == 0) { |
| /* We are not a current holder of the lock. This is a bug in |
| the guest, and (per POSIX pthread rules) the unlock |
| attempt will fail. So just complain and do nothing |
| else. */ |
| Thread* realOwner = (Thread*)VG_(anyElementOfBag)( lock->heldBy ); |
| tl_assert(HG_(is_sane_Thread)(realOwner)); |
| tl_assert(realOwner != thr); |
| tl_assert(!HG_(elemWS)( univ_lsets, thr->locksetA, (UWord)lock )); |
| tl_assert(!HG_(elemWS)( univ_lsets, thr->locksetW, (UWord)lock )); |
| HG_(record_error_UnlockForeign)( thr, realOwner, lock ); |
| goto error; |
| } |
| |
| /* Ok, we hold the lock 'n' times. */ |
| tl_assert(n >= 1); |
| |
| lockN_release( lock, thr ); |
| |
| n--; |
| tl_assert(n >= 0); |
| |
| if (n > 0) { |
| tl_assert(lock->heldBy); |
| tl_assert(n == VG_(elemBag)( lock->heldBy, (UWord)thr )); |
| /* We still hold the lock. So either it's a recursive lock |
| or a rwlock which is currently r-held. */ |
| tl_assert(lock->kind == LK_mbRec |
| || (lock->kind == LK_rdwr && !lock->heldW)); |
| tl_assert(HG_(elemWS)( univ_lsets, thr->locksetA, (UWord)lock )); |
| if (lock->heldW) |
| tl_assert(HG_(elemWS)( univ_lsets, thr->locksetW, (UWord)lock )); |
| else |
| tl_assert(!HG_(elemWS)( univ_lsets, thr->locksetW, (UWord)lock )); |
| } else { |
| /* n is zero. This means we don't hold the lock any more. But |
| if it's a rwlock held in r-mode, someone else could still |
| hold it. Just do whatever sanity checks we can. */ |
| if (lock->kind == LK_rdwr && lock->heldBy) { |
| /* It's a rwlock. We no longer hold it but we used to; |
| nevertheless it still appears to be held by someone else. |
| The implication is that, prior to this release, it must |
| have been shared by us and and whoever else is holding it; |
| which in turn implies it must be r-held, since a lock |
| can't be w-held by more than one thread. */ |
| /* The lock is now R-held by somebody else: */ |
| tl_assert(lock->heldW == False); |
| } else { |
| /* Normal case. It's either not a rwlock, or it's a rwlock |
| that we used to hold in w-mode (which is pretty much the |
| same thing as a non-rwlock.) Since this transaction is |
| atomic (V does not allow multiple threads to run |
| simultaneously), it must mean the lock is now not held by |
| anybody. Hence assert for it. */ |
| /* The lock is now not held by anybody: */ |
| tl_assert(!lock->heldBy); |
| tl_assert(lock->heldW == False); |
| } |
| //if (lock->heldBy) { |
| // tl_assert(0 == VG_(elemBag)( lock->heldBy, (UWord)thr )); |
| //} |
| /* update this thread's lockset accordingly. */ |
| thr->locksetA |
| = HG_(delFromWS)( univ_lsets, thr->locksetA, (UWord)lock ); |
| thr->locksetW |
| = HG_(delFromWS)( univ_lsets, thr->locksetW, (UWord)lock ); |
| /* push our VC into the lock */ |
| tl_assert(thr->hbthr); |
| tl_assert(lock->hbso); |
| /* If the lock was previously W-held, then we want to do a |
| strong send, and if previously R-held, then a weak send. */ |
| libhb_so_send( thr->hbthr, lock->hbso, was_heldW ); |
| } |
| /* fall through */ |
| |
| error: |
| tl_assert(HG_(is_sane_LockN)(lock)); |
| } |
| |
| |
| /* ---------------------------------------------------------- */ |
| /* -------- Event handlers proper (evh__* functions) -------- */ |
| /* ---------------------------------------------------------- */ |
| |
| /* What is the Thread* for the currently running thread? This is |
| absolutely performance critical. We receive notifications from the |
| core for client code starts/stops, and cache the looked-up result |
| in 'current_Thread'. Hence, for the vast majority of requests, |
| finding the current thread reduces to a read of a global variable, |
| provided get_current_Thread_in_C_C is inlined. |
| |
| Outside of client code, current_Thread is NULL, and presumably |
| any uses of it will cause a segfault. Hence: |
| |
| - for uses definitely within client code, use |
| get_current_Thread_in_C_C. |
| |
| - for all other uses, use get_current_Thread. |
| */ |
| |
| static Thread *current_Thread = NULL, |
| *current_Thread_prev = NULL; |
| |
| static void evh__start_client_code ( ThreadId tid, ULong nDisp ) { |
| if (0) VG_(printf)("start %d %llu\n", (Int)tid, nDisp); |
| tl_assert(current_Thread == NULL); |
| current_Thread = map_threads_lookup( tid ); |
| tl_assert(current_Thread != NULL); |
| if (current_Thread != current_Thread_prev) { |
| libhb_Thr_resumes( current_Thread->hbthr ); |
| current_Thread_prev = current_Thread; |
| } |
| } |
| static void evh__stop_client_code ( ThreadId tid, ULong nDisp ) { |
| if (0) VG_(printf)(" stop %d %llu\n", (Int)tid, nDisp); |
| tl_assert(current_Thread != NULL); |
| current_Thread = NULL; |
| libhb_maybe_GC(); |
| } |
| static inline Thread* get_current_Thread_in_C_C ( void ) { |
| return current_Thread; |
| } |
| static inline Thread* get_current_Thread ( void ) { |
| ThreadId coretid; |
| Thread* thr; |
| thr = get_current_Thread_in_C_C(); |
| if (LIKELY(thr)) |
| return thr; |
| /* evidently not in client code. Do it the slow way. */ |
| coretid = VG_(get_running_tid)(); |
| /* FIXME: get rid of the following kludge. It exists because |
| evh__new_mem is called during initialisation (as notification |
| of initial memory layout) and VG_(get_running_tid)() returns |
| VG_INVALID_THREADID at that point. */ |
| if (coretid == VG_INVALID_THREADID) |
| coretid = 1; /* KLUDGE */ |
| thr = map_threads_lookup( coretid ); |
| return thr; |
| } |
| |
| static |
| void evh__new_mem ( Addr a, SizeT len ) { |
| if (SHOW_EVENTS >= 2) |
| VG_(printf)("evh__new_mem(%p, %lu)\n", (void*)a, len ); |
| shadow_mem_make_New( get_current_Thread(), a, len ); |
| if (len >= SCE_BIGRANGE_T && (HG_(clo_sanity_flags) & SCE_BIGRANGE)) |
| all__sanity_check("evh__new_mem-post"); |
| } |
| |
| static |
| void evh__new_mem_stack ( Addr a, SizeT len ) { |
| if (SHOW_EVENTS >= 2) |
| VG_(printf)("evh__new_mem_stack(%p, %lu)\n", (void*)a, len ); |
| shadow_mem_make_New( get_current_Thread(), |
| -VG_STACK_REDZONE_SZB + a, len ); |
| if (len >= SCE_BIGRANGE_T && (HG_(clo_sanity_flags) & SCE_BIGRANGE)) |
| all__sanity_check("evh__new_mem_stack-post"); |
| } |
| |
| static |
| void evh__new_mem_w_tid ( Addr a, SizeT len, ThreadId tid ) { |
| if (SHOW_EVENTS >= 2) |
| VG_(printf)("evh__new_mem_w_tid(%p, %lu)\n", (void*)a, len ); |
| shadow_mem_make_New( get_current_Thread(), a, len ); |
| if (len >= SCE_BIGRANGE_T && (HG_(clo_sanity_flags) & SCE_BIGRANGE)) |
| all__sanity_check("evh__new_mem_w_tid-post"); |
| } |
| |
| static |
| void evh__new_mem_w_perms ( Addr a, SizeT len, |
| Bool rr, Bool ww, Bool xx, ULong di_handle ) { |
| if (SHOW_EVENTS >= 1) |
| VG_(printf)("evh__new_mem_w_perms(%p, %lu, %d,%d,%d)\n", |
| (void*)a, len, (Int)rr, (Int)ww, (Int)xx ); |
| if (rr || ww || xx) |
| shadow_mem_make_New( get_current_Thread(), a, len ); |
| if (len >= SCE_BIGRANGE_T && (HG_(clo_sanity_flags) & SCE_BIGRANGE)) |
| all__sanity_check("evh__new_mem_w_perms-post"); |
| } |
| |
| static |
| void evh__set_perms ( Addr a, SizeT len, |
| Bool rr, Bool ww, Bool xx ) { |
| // This handles mprotect requests. If the memory is being put |
| // into no-R no-W state, paint it as NoAccess, for the reasons |
| // documented at evh__die_mem_munmap(). |
| if (SHOW_EVENTS >= 1) |
| VG_(printf)("evh__set_perms(%p, %lu, r=%d w=%d x=%d)\n", |
| (void*)a, len, (Int)rr, (Int)ww, (Int)xx ); |
| /* Hmm. What should we do here, that actually makes any sense? |
| Let's say: if neither readable nor writable, then declare it |
| NoAccess, else leave it alone. */ |
| if (!(rr || ww)) |
| shadow_mem_make_NoAccess_AHAE( get_current_Thread(), a, len ); |
| if (len >= SCE_BIGRANGE_T && (HG_(clo_sanity_flags) & SCE_BIGRANGE)) |
| all__sanity_check("evh__set_perms-post"); |
| } |
| |
| static |
| void evh__die_mem ( Addr a, SizeT len ) { |
| // Urr, libhb ignores this. |
| if (SHOW_EVENTS >= 2) |
| VG_(printf)("evh__die_mem(%p, %lu)\n", (void*)a, len ); |
| shadow_mem_make_NoAccess_NoFX( get_current_Thread(), a, len ); |
| if (len >= SCE_BIGRANGE_T && (HG_(clo_sanity_flags) & SCE_BIGRANGE)) |
| all__sanity_check("evh__die_mem-post"); |
| } |
| |
| static |
| void evh__die_mem_munmap ( Addr a, SizeT len ) { |
| // It's important that libhb doesn't ignore this. If, as is likely, |
| // the client is subject to address space layout randomization, |
| // then unmapped areas may never get remapped over, even in long |
| // runs. If we just ignore them we wind up with large resource |
| // (VTS) leaks in libhb. So force them to NoAccess, so that all |
| // VTS references in the affected area are dropped. Marking memory |
| // as NoAccess is expensive, but we assume that munmap is sufficiently |
| // rare that the space gains of doing this are worth the costs. |
| if (SHOW_EVENTS >= 2) |
| VG_(printf)("evh__die_mem_munmap(%p, %lu)\n", (void*)a, len ); |
| shadow_mem_make_NoAccess_AHAE( get_current_Thread(), a, len ); |
| } |
| |
| static |
| void evh__untrack_mem ( Addr a, SizeT len ) { |
| // Libhb doesn't ignore this. |
| if (SHOW_EVENTS >= 2) |
| VG_(printf)("evh__untrack_mem(%p, %lu)\n", (void*)a, len ); |
| shadow_mem_make_Untracked( get_current_Thread(), a, len ); |
| if (len >= SCE_BIGRANGE_T && (HG_(clo_sanity_flags) & SCE_BIGRANGE)) |
| all__sanity_check("evh__untrack_mem-post"); |
| } |
| |
| static |
| void evh__copy_mem ( Addr src, Addr dst, SizeT len ) { |
| if (SHOW_EVENTS >= 2) |
| VG_(printf)("evh__copy_mem(%p, %p, %lu)\n", (void*)src, (void*)dst, len ); |
| shadow_mem_scopy_range( get_current_Thread(), src, dst, len ); |
| if (len >= SCE_BIGRANGE_T && (HG_(clo_sanity_flags) & SCE_BIGRANGE)) |
| all__sanity_check("evh__copy_mem-post"); |
| } |
| |
| static |
| void evh__pre_thread_ll_create ( ThreadId parent, ThreadId child ) |
| { |
| if (SHOW_EVENTS >= 1) |
| VG_(printf)("evh__pre_thread_ll_create(p=%d, c=%d)\n", |
| (Int)parent, (Int)child ); |
| |
| if (parent != VG_INVALID_THREADID) { |
| Thread* thr_p; |
| Thread* thr_c; |
| Thr* hbthr_p; |
| Thr* hbthr_c; |
| |
| tl_assert(HG_(is_sane_ThreadId)(parent)); |
| tl_assert(HG_(is_sane_ThreadId)(child)); |
| tl_assert(parent != child); |
| |
| thr_p = map_threads_maybe_lookup( parent ); |
| thr_c = map_threads_maybe_lookup( child ); |
| |
| tl_assert(thr_p != NULL); |
| tl_assert(thr_c == NULL); |
| |
| hbthr_p = thr_p->hbthr; |
| tl_assert(hbthr_p != NULL); |
| tl_assert( libhb_get_Thr_hgthread(hbthr_p) == thr_p ); |
| |
| hbthr_c = libhb_create ( hbthr_p ); |
| |
| /* Create a new thread record for the child. */ |
| /* a Thread for the new thread ... */ |
| thr_c = mk_Thread( hbthr_c ); |
| tl_assert( libhb_get_Thr_hgthread(hbthr_c) == NULL ); |
| libhb_set_Thr_hgthread(hbthr_c, thr_c); |
| |
| /* and bind it in the thread-map table */ |
| map_threads[child] = thr_c; |
| tl_assert(thr_c->coretid == VG_INVALID_THREADID); |
| thr_c->coretid = child; |
| |
| /* Record where the parent is so we can later refer to this in |
| error messages. |
| |
| On amd64-linux, this entails a nasty glibc-2.5 specific hack. |
| The stack snapshot is taken immediately after the parent has |
| returned from its sys_clone call. Unfortunately there is no |
| unwind info for the insn following "syscall" - reading the |
| glibc sources confirms this. So we ask for a snapshot to be |
| taken as if RIP was 3 bytes earlier, in a place where there |
| is unwind info. Sigh. |
| */ |
| { Word first_ip_delta = 0; |
| # if defined(VGP_amd64_linux) |
| first_ip_delta = -3; |
| # endif |
| thr_c->created_at = VG_(record_ExeContext)(parent, first_ip_delta); |
| } |
| } |
| |
| if (HG_(clo_sanity_flags) & SCE_THREADS) |
| all__sanity_check("evh__pre_thread_create-post"); |
| } |
| |
| static |
| void evh__pre_thread_ll_exit ( ThreadId quit_tid ) |
| { |
| Int nHeld; |
| Thread* thr_q; |
| if (SHOW_EVENTS >= 1) |
| VG_(printf)("evh__pre_thread_ll_exit(thr=%d)\n", |
| (Int)quit_tid ); |
| |
| /* quit_tid has disappeared without joining to any other thread. |
| Therefore there is no synchronisation event associated with its |
| exit and so we have to pretty much treat it as if it was still |
| alive but mysteriously making no progress. That is because, if |
| we don't know when it really exited, then we can never say there |
| is a point in time when we're sure the thread really has |
| finished, and so we need to consider the possibility that it |
| lingers indefinitely and continues to interact with other |
| threads. */ |
| /* However, it might have rendezvous'd with a thread that called |
| pthread_join with this one as arg, prior to this point (that's |
| how NPTL works). In which case there has already been a prior |
| sync event. So in any case, just let the thread exit. On NPTL, |
| all thread exits go through here. */ |
| tl_assert(HG_(is_sane_ThreadId)(quit_tid)); |
| thr_q = map_threads_maybe_lookup( quit_tid ); |
| tl_assert(thr_q != NULL); |
| |
| /* Complain if this thread holds any locks. */ |
| nHeld = HG_(cardinalityWS)( univ_lsets, thr_q->locksetA ); |
| tl_assert(nHeld >= 0); |
| if (nHeld > 0) { |
| HChar buf[80]; |
| VG_(sprintf)(buf, "Exiting thread still holds %d lock%s", |
| nHeld, nHeld > 1 ? "s" : ""); |
| HG_(record_error_Misc)( thr_q, buf ); |
| } |
| |
| /* Not much to do here: |
| - tell libhb the thread is gone |
| - clear the map_threads entry, in order that the Valgrind core |
| can re-use it. */ |
| /* Cleanup actions (next 5 lines) copied in evh__atfork_child; keep |
| in sync. */ |
| tl_assert(thr_q->hbthr); |
| libhb_async_exit(thr_q->hbthr); |
| tl_assert(thr_q->coretid == quit_tid); |
| thr_q->coretid = VG_INVALID_THREADID; |
| map_threads_delete( quit_tid ); |
| |
| if (HG_(clo_sanity_flags) & SCE_THREADS) |
| all__sanity_check("evh__pre_thread_ll_exit-post"); |
| } |
| |
| /* This is called immediately after fork, for the child only. 'tid' |
| is the only surviving thread (as per POSIX rules on fork() in |
| threaded programs), so we have to clean up map_threads to remove |
| entries for any other threads. */ |
| static |
| void evh__atfork_child ( ThreadId tid ) |
| { |
| UInt i; |
| Thread* thr; |
| /* Slot 0 should never be used. */ |
| thr = map_threads_maybe_lookup( 0/*INVALID*/ ); |
| tl_assert(!thr); |
| /* Clean up all other slots except 'tid'. */ |
| for (i = 1; i < VG_N_THREADS; i++) { |
| if (i == tid) |
| continue; |
| thr = map_threads_maybe_lookup(i); |
| if (!thr) |
| continue; |
| /* Cleanup actions (next 5 lines) copied from end of |
| evh__pre_thread_ll_exit; keep in sync. */ |
| tl_assert(thr->hbthr); |
| libhb_async_exit(thr->hbthr); |
| tl_assert(thr->coretid == i); |
| thr->coretid = VG_INVALID_THREADID; |
| map_threads_delete(i); |
| } |
| } |
| |
| |
| static |
| void evh__HG_PTHREAD_JOIN_POST ( ThreadId stay_tid, Thread* quit_thr ) |
| { |
| Thread* thr_s; |
| Thread* thr_q; |
| Thr* hbthr_s; |
| Thr* hbthr_q; |
| SO* so; |
| |
| if (SHOW_EVENTS >= 1) |
| VG_(printf)("evh__post_thread_join(stayer=%d, quitter=%p)\n", |
| (Int)stay_tid, quit_thr ); |
| |
| tl_assert(HG_(is_sane_ThreadId)(stay_tid)); |
| |
| thr_s = map_threads_maybe_lookup( stay_tid ); |
| thr_q = quit_thr; |
| tl_assert(thr_s != NULL); |
| tl_assert(thr_q != NULL); |
| tl_assert(thr_s != thr_q); |
| |
| hbthr_s = thr_s->hbthr; |
| hbthr_q = thr_q->hbthr; |
| tl_assert(hbthr_s != hbthr_q); |
| tl_assert( libhb_get_Thr_hgthread(hbthr_s) == thr_s ); |
| tl_assert( libhb_get_Thr_hgthread(hbthr_q) == thr_q ); |
| |
| /* Allocate a temporary synchronisation object and use it to send |
| an imaginary message from the quitter to the stayer, the purpose |
| being to generate a dependence from the quitter to the |
| stayer. */ |
| so = libhb_so_alloc(); |
| tl_assert(so); |
| /* Send last arg of _so_send as False, since the sending thread |
| doesn't actually exist any more, so we don't want _so_send to |
| try taking stack snapshots of it. */ |
| libhb_so_send(hbthr_q, so, True/*strong_send*//*?!? wrt comment above*/); |
| libhb_so_recv(hbthr_s, so, True/*strong_recv*/); |
| libhb_so_dealloc(so); |
| |
| /* Tell libhb that the quitter has been reaped. Note that we might |
| have to be cleverer about this, to exclude 2nd and subsequent |
| notifications for the same hbthr_q, in the case where the app is |
| buggy (calls pthread_join twice or more on the same thread) AND |
| where libpthread is also buggy and doesn't return ESRCH on |
| subsequent calls. (If libpthread isn't thusly buggy, then the |
| wrapper for pthread_join in hg_intercepts.c will stop us getting |
| notified here multiple times for the same joinee.) See also |
| comments in helgrind/tests/jointwice.c. */ |
| libhb_joinedwith_done(hbthr_q); |
| |
| /* evh__pre_thread_ll_exit issues an error message if the exiting |
| thread holds any locks. No need to check here. */ |
| |
| /* This holds because, at least when using NPTL as the thread |
| library, we should be notified the low level thread exit before |
| we hear of any join event on it. The low level exit |
| notification feeds through into evh__pre_thread_ll_exit, |
| which should clear the map_threads entry for it. Hence we |
| expect there to be no map_threads entry at this point. */ |
| tl_assert( map_threads_maybe_reverse_lookup_SLOW(thr_q) |
| == VG_INVALID_THREADID); |
| |
| if (HG_(clo_sanity_flags) & SCE_THREADS) |
| all__sanity_check("evh__post_thread_join-post"); |
| } |
| |
| static |
| void evh__pre_mem_read ( CorePart part, ThreadId tid, const HChar* s, |
| Addr a, SizeT size) { |
| if (SHOW_EVENTS >= 2 |
| || (SHOW_EVENTS >= 1 && size != 1)) |
| VG_(printf)("evh__pre_mem_read(ctid=%d, \"%s\", %p, %lu)\n", |
| (Int)tid, s, (void*)a, size ); |
| shadow_mem_cread_range( map_threads_lookup(tid), a, size); |
| if (size >= SCE_BIGRANGE_T && (HG_(clo_sanity_flags) & SCE_BIGRANGE)) |
| all__sanity_check("evh__pre_mem_read-post"); |
| } |
| |
| static |
| void evh__pre_mem_read_asciiz ( CorePart part, ThreadId tid, |
| const HChar* s, Addr a ) { |
| Int len; |
| if (SHOW_EVENTS >= 1) |
| VG_(printf)("evh__pre_mem_asciiz(ctid=%d, \"%s\", %p)\n", |
| (Int)tid, s, (void*)a ); |
| // Don't segfault if the string starts in an obviously stupid |
| // place. Actually we should check the whole string, not just |
| // the start address, but that's too much trouble. At least |
| // checking the first byte is better than nothing. See #255009. |
| if (!VG_(am_is_valid_for_client) (a, 1, VKI_PROT_READ)) |
| return; |
| len = VG_(strlen)( (HChar*) a ); |
| shadow_mem_cread_range( map_threads_lookup(tid), a, len+1 ); |
| if (len >= SCE_BIGRANGE_T && (HG_(clo_sanity_flags) & SCE_BIGRANGE)) |
| all__sanity_check("evh__pre_mem_read_asciiz-post"); |
| } |
| |
| static |
| void evh__pre_mem_write ( CorePart part, ThreadId tid, const HChar* s, |
| Addr a, SizeT size ) { |
| if (SHOW_EVENTS >= 1) |
| VG_(printf)("evh__pre_mem_write(ctid=%d, \"%s\", %p, %lu)\n", |
| (Int)tid, s, (void*)a, size ); |
| shadow_mem_cwrite_range( map_threads_lookup(tid), a, size); |
| if (size >= SCE_BIGRANGE_T && (HG_(clo_sanity_flags) & SCE_BIGRANGE)) |
| all__sanity_check("evh__pre_mem_write-post"); |
| } |
| |
| static |
| void evh__new_mem_heap ( Addr a, SizeT len, Bool is_inited ) { |
| if (SHOW_EVENTS >= 1) |
| VG_(printf)("evh__new_mem_heap(%p, %lu, inited=%d)\n", |
| (void*)a, len, (Int)is_inited ); |
| // FIXME: this is kinda stupid |
| if (is_inited) { |
| shadow_mem_make_New(get_current_Thread(), a, len); |
| } else { |
| shadow_mem_make_New(get_current_Thread(), a, len); |
| } |
| if (len >= SCE_BIGRANGE_T && (HG_(clo_sanity_flags) & SCE_BIGRANGE)) |
| all__sanity_check("evh__pre_mem_read-post"); |
| } |
| |
| static |
| void evh__die_mem_heap ( Addr a, SizeT len ) { |
| Thread* thr; |
| if (SHOW_EVENTS >= 1) |
| VG_(printf)("evh__die_mem_heap(%p, %lu)\n", (void*)a, len ); |
| thr = get_current_Thread(); |
| tl_assert(thr); |
| if (HG_(clo_free_is_write)) { |
| /* Treat frees as if the memory was written immediately prior to |
| the free. This shakes out more races, specifically, cases |
| where memory is referenced by one thread, and freed by |
| another, and there's no observable synchronisation event to |
| guarantee that the reference happens before the free. */ |
| shadow_mem_cwrite_range(thr, a, len); |
| } |
| shadow_mem_make_NoAccess_NoFX( thr, a, len ); |
| if (len >= SCE_BIGRANGE_T && (HG_(clo_sanity_flags) & SCE_BIGRANGE)) |
| all__sanity_check("evh__pre_mem_read-post"); |
| } |
| |
| /* --- Event handlers called from generated code --- */ |
| |
| static VG_REGPARM(1) |
| void evh__mem_help_cread_1(Addr a) { |
| Thread* thr = get_current_Thread_in_C_C(); |
| Thr* hbthr = thr->hbthr; |
| LIBHB_CREAD_1(hbthr, a); |
| } |
| |
| static VG_REGPARM(1) |
| void evh__mem_help_cread_2(Addr a) { |
| Thread* thr = get_current_Thread_in_C_C(); |
| Thr* hbthr = thr->hbthr; |
| LIBHB_CREAD_2(hbthr, a); |
| } |
| |
| static VG_REGPARM(1) |
| void evh__mem_help_cread_4(Addr a) { |
| Thread* thr = get_current_Thread_in_C_C(); |
| Thr* hbthr = thr->hbthr; |
| LIBHB_CREAD_4(hbthr, a); |
| } |
| |
| static VG_REGPARM(1) |
| void evh__mem_help_cread_8(Addr a) { |
| Thread* thr = get_current_Thread_in_C_C(); |
| Thr* hbthr = thr->hbthr; |
| LIBHB_CREAD_8(hbthr, a); |
| } |
| |
| static VG_REGPARM(2) |
| void evh__mem_help_cread_N(Addr a, SizeT size) { |
| Thread* thr = get_current_Thread_in_C_C(); |
| Thr* hbthr = thr->hbthr; |
| LIBHB_CREAD_N(hbthr, a, size); |
| } |
| |
| static VG_REGPARM(1) |
| void evh__mem_help_cwrite_1(Addr a) { |
| Thread* thr = get_current_Thread_in_C_C(); |
| Thr* hbthr = thr->hbthr; |
| LIBHB_CWRITE_1(hbthr, a); |
| } |
| |
| static VG_REGPARM(1) |
| void evh__mem_help_cwrite_2(Addr a) { |
| Thread* thr = get_current_Thread_in_C_C(); |
| Thr* hbthr = thr->hbthr; |
| LIBHB_CWRITE_2(hbthr, a); |
| } |
| |
| static VG_REGPARM(1) |
| void evh__mem_help_cwrite_4(Addr a) { |
| Thread* thr = get_current_Thread_in_C_C(); |
| Thr* hbthr = thr->hbthr; |
| LIBHB_CWRITE_4(hbthr, a); |
| } |
| |
| static VG_REGPARM(1) |
| void evh__mem_help_cwrite_8(Addr a) { |
| Thread* thr = get_current_Thread_in_C_C(); |
| Thr* hbthr = thr->hbthr; |
| LIBHB_CWRITE_8(hbthr, a); |
| } |
| |
| static VG_REGPARM(2) |
| void evh__mem_help_cwrite_N(Addr a, SizeT size) { |
| Thread* thr = get_current_Thread_in_C_C(); |
| Thr* hbthr = thr->hbthr; |
| LIBHB_CWRITE_N(hbthr, a, size); |
| } |
| |
| |
| /* ------------------------------------------------------- */ |
| /* -------------- events to do with mutexes -------------- */ |
| /* ------------------------------------------------------- */ |
| |
| /* EXPOSITION only: by intercepting lock init events we can show the |
| user where the lock was initialised, rather than only being able to |
| show where it was first locked. Intercepting lock initialisations |
| is not necessary for the basic operation of the race checker. */ |
| static |
| void evh__HG_PTHREAD_MUTEX_INIT_POST( ThreadId tid, |
| void* mutex, Word mbRec ) |
| { |
| if (SHOW_EVENTS >= 1) |
| VG_(printf)("evh__hg_PTHREAD_MUTEX_INIT_POST(ctid=%d, mbRec=%ld, %p)\n", |
| (Int)tid, mbRec, (void*)mutex ); |
| tl_assert(mbRec == 0 || mbRec == 1); |
| map_locks_lookup_or_create( mbRec ? LK_mbRec : LK_nonRec, |
| (Addr)mutex, tid ); |
| if (HG_(clo_sanity_flags) & SCE_LOCKS) |
| all__sanity_check("evh__hg_PTHREAD_MUTEX_INIT_POST"); |
| } |
| |
| static |
| void evh__HG_PTHREAD_MUTEX_DESTROY_PRE( ThreadId tid, void* mutex, |
| Bool mutex_is_init ) |
| { |
| Thread* thr; |
| Lock* lk; |
| if (SHOW_EVENTS >= 1) |
| VG_(printf)("evh__hg_PTHREAD_MUTEX_DESTROY_PRE" |
| "(ctid=%d, %p, isInit=%d)\n", |
| (Int)tid, (void*)mutex, (Int)mutex_is_init ); |
| |
| thr = map_threads_maybe_lookup( tid ); |
| /* cannot fail - Thread* must already exist */ |
| tl_assert( HG_(is_sane_Thread)(thr) ); |
| |
| lk = map_locks_maybe_lookup( (Addr)mutex ); |
| |
| if (lk == NULL && mutex_is_init) { |
| /* We're destroying a mutex which we don't have any record of, |
| and which appears to have the value PTHREAD_MUTEX_INITIALIZER. |
| Assume it never got used, and so we don't need to do anything |
| more. */ |
| goto out; |
| } |
| |
| if (lk == NULL || (lk->kind != LK_nonRec && lk->kind != LK_mbRec)) { |
| HG_(record_error_Misc)( |
| thr, "pthread_mutex_destroy with invalid argument" ); |
| } |
| |
| if (lk) { |
| tl_assert( HG_(is_sane_LockN)(lk) ); |
| tl_assert( lk->guestaddr == (Addr)mutex ); |
| if (lk->heldBy) { |
| /* Basically act like we unlocked the lock */ |
| HG_(record_error_Misc)( |
| thr, "pthread_mutex_destroy of a locked mutex" ); |
| /* remove lock from locksets of all owning threads */ |
| remove_Lock_from_locksets_of_all_owning_Threads( lk ); |
| VG_(deleteBag)( lk->heldBy ); |
| lk->heldBy = NULL; |
| lk->heldW = False; |
| lk->acquired_at = NULL; |
| } |
| tl_assert( !lk->heldBy ); |
| tl_assert( HG_(is_sane_LockN)(lk) ); |
| |
| if (HG_(clo_track_lockorders)) |
| laog__handle_one_lock_deletion(lk); |
| map_locks_delete( lk->guestaddr ); |
| del_LockN( lk ); |
| } |
| |
| out: |
| if (HG_(clo_sanity_flags) & SCE_LOCKS) |
| all__sanity_check("evh__hg_PTHREAD_MUTEX_DESTROY_PRE"); |
| } |
| |
| static void evh__HG_PTHREAD_MUTEX_LOCK_PRE ( ThreadId tid, |
| void* mutex, Word isTryLock ) |
| { |
| /* Just check the mutex is sane; nothing else to do. */ |
| // 'mutex' may be invalid - not checked by wrapper |
| Thread* thr; |
| Lock* lk; |
| if (SHOW_EVENTS >= 1) |
| VG_(printf)("evh__hg_PTHREAD_MUTEX_LOCK_PRE(ctid=%d, mutex=%p)\n", |
| (Int)tid, (void*)mutex ); |
| |
| tl_assert(isTryLock == 0 || isTryLock == 1); |
| thr = map_threads_maybe_lookup( tid ); |
| tl_assert(thr); /* cannot fail - Thread* must already exist */ |
| |
| lk = map_locks_maybe_lookup( (Addr)mutex ); |
| |
| if (lk && (lk->kind == LK_rdwr)) { |
| HG_(record_error_Misc)( thr, "pthread_mutex_lock with a " |
| "pthread_rwlock_t* argument " ); |
| } |
| |
| if ( lk |
| && isTryLock == 0 |
| && (lk->kind == LK_nonRec || lk->kind == LK_rdwr) |
| && lk->heldBy |
| && lk->heldW |
| && VG_(elemBag)( lk->heldBy, (UWord)thr ) > 0 ) { |
| /* uh, it's a non-recursive lock and we already w-hold it, and |
| this is a real lock operation (not a speculative "tryLock" |
| kind of thing). Duh. Deadlock coming up; but at least |
| produce an error message. */ |
| const HChar* errstr = "Attempt to re-lock a " |
| "non-recursive lock I already hold"; |
| const HChar* auxstr = "Lock was previously acquired"; |
| if (lk->acquired_at) { |
| HG_(record_error_Misc_w_aux)( thr, errstr, auxstr, lk->acquired_at ); |
| } else { |
| HG_(record_error_Misc)( thr, errstr ); |
| } |
| } |
| } |
| |
| static void evh__HG_PTHREAD_MUTEX_LOCK_POST ( ThreadId tid, void* mutex ) |
| { |
| // only called if the real library call succeeded - so mutex is sane |
| Thread* thr; |
| if (SHOW_EVENTS >= 1) |
| VG_(printf)("evh__HG_PTHREAD_MUTEX_LOCK_POST(ctid=%d, mutex=%p)\n", |
| (Int)tid, (void*)mutex ); |
| |
| thr = map_threads_maybe_lookup( tid ); |
| tl_assert(thr); /* cannot fail - Thread* must already exist */ |
| |
| evhH__post_thread_w_acquires_lock( |
| thr, |
| LK_mbRec, /* if not known, create new lock with this LockKind */ |
| (Addr)mutex |
| ); |
| } |
| |
| static void evh__HG_PTHREAD_MUTEX_UNLOCK_PRE ( ThreadId tid, void* mutex ) |
| { |
| // 'mutex' may be invalid - not checked by wrapper |
| Thread* thr; |
| if (SHOW_EVENTS >= 1) |
| VG_(printf)("evh__HG_PTHREAD_MUTEX_UNLOCK_PRE(ctid=%d, mutex=%p)\n", |
| (Int)tid, (void*)mutex ); |
| |
| thr = map_threads_maybe_lookup( tid ); |
| tl_assert(thr); /* cannot fail - Thread* must already exist */ |
| |
| evhH__pre_thread_releases_lock( thr, (Addr)mutex, False/*!isRDWR*/ ); |
| } |
| |
| static void evh__HG_PTHREAD_MUTEX_UNLOCK_POST ( ThreadId tid, void* mutex ) |
| { |
| // only called if the real library call succeeded - so mutex is sane |
| Thread* thr; |
| if (SHOW_EVENTS >= 1) |
| VG_(printf)("evh__hg_PTHREAD_MUTEX_UNLOCK_POST(ctid=%d, mutex=%p)\n", |
| (Int)tid, (void*)mutex ); |
| thr = map_threads_maybe_lookup( tid ); |
| tl_assert(thr); /* cannot fail - Thread* must already exist */ |
| |
| // anything we should do here? |
| } |
| |
| |
| /* ------------------------------------------------------- */ |
| /* -------------- events to do with spinlocks ------------ */ |
| /* ------------------------------------------------------- */ |
| |
| /* All a bit of a kludge. Pretend we're really dealing with ordinary |
| pthread_mutex_t's instead, for the most part. */ |
| |
| static void evh__HG_PTHREAD_SPIN_INIT_OR_UNLOCK_PRE( ThreadId tid, |
| void* slock ) |
| { |
| Thread* thr; |
| Lock* lk; |
| /* In glibc's kludgey world, we're either initialising or unlocking |
| it. Since this is the pre-routine, if it is locked, unlock it |
| and take a dependence edge. Otherwise, do nothing. */ |
| |
| if (SHOW_EVENTS >= 1) |
| VG_(printf)("evh__hg_PTHREAD_SPIN_INIT_OR_UNLOCK_PRE" |
| "(ctid=%d, slock=%p)\n", |
| (Int)tid, (void*)slock ); |
| |
| thr = map_threads_maybe_lookup( tid ); |
| /* cannot fail - Thread* must already exist */; |
| tl_assert( HG_(is_sane_Thread)(thr) ); |
| |
| lk = map_locks_maybe_lookup( (Addr)slock ); |
| if (lk && lk->heldBy) { |
| /* it's held. So do the normal pre-unlock actions, as copied |
| from evh__HG_PTHREAD_MUTEX_UNLOCK_PRE. This stupidly |
| duplicates the map_locks_maybe_lookup. */ |
| evhH__pre_thread_releases_lock( thr, (Addr)slock, |
| False/*!isRDWR*/ ); |
| } |
| } |
| |
| static void evh__HG_PTHREAD_SPIN_INIT_OR_UNLOCK_POST( ThreadId tid, |
| void* slock ) |
| { |
| Lock* lk; |
| /* More kludgery. If the lock has never been seen before, do |
| actions as per evh__HG_PTHREAD_MUTEX_INIT_POST. Else do |
| nothing. */ |
| |
| if (SHOW_EVENTS >= 1) |
| VG_(printf)("evh__hg_PTHREAD_SPIN_INIT_OR_UNLOCK_POST" |
| "(ctid=%d, slock=%p)\n", |
| (Int)tid, (void*)slock ); |
| |
| lk = map_locks_maybe_lookup( (Addr)slock ); |
| if (!lk) { |
| map_locks_lookup_or_create( LK_nonRec, (Addr)slock, tid ); |
| } |
| } |
| |
| static void evh__HG_PTHREAD_SPIN_LOCK_PRE( ThreadId tid, |
| void* slock, Word isTryLock ) |
| { |
| evh__HG_PTHREAD_MUTEX_LOCK_PRE( tid, slock, isTryLock ); |
| } |
| |
| static void evh__HG_PTHREAD_SPIN_LOCK_POST( ThreadId tid, |
| void* slock ) |
| { |
| evh__HG_PTHREAD_MUTEX_LOCK_POST( tid, slock ); |
| } |
| |
| static void evh__HG_PTHREAD_SPIN_DESTROY_PRE( ThreadId tid, |
| void* slock ) |
| { |
| evh__HG_PTHREAD_MUTEX_DESTROY_PRE( tid, slock, 0/*!isInit*/ ); |
| } |
| |
| |
| /* ----------------------------------------------------- */ |
| /* --------------- events to do with CVs --------------- */ |
| /* ----------------------------------------------------- */ |
| |
| /* A mapping from CV to (the SO associated with it, plus some |
| auxiliary data for error checking). When the CV is |
| signalled/broadcasted upon, we do a 'send' into the SO, and when a |
| wait on it completes, we do a 'recv' from the SO. This is believed |
| to give the correct happens-before events arising from CV |
| signallings/broadcasts. |
| */ |
| |
| /* .so is the SO for this CV. |
| .mx_ga is the associated mutex, when .nWaiters > 0 |
| |
| POSIX says effectively that the first pthread_cond_{timed}wait call |
| causes a dynamic binding between the CV and the mutex, and that |
| lasts until such time as the waiter count falls to zero. Hence |
| need to keep track of the number of waiters in order to do |
| consistency tracking. */ |
| typedef |
| struct { |
| SO* so; /* libhb-allocated SO */ |
| void* mx_ga; /* addr of associated mutex, if any */ |
| UWord nWaiters; /* # threads waiting on the CV */ |
| } |
| CVInfo; |
| |
| |
| /* pthread_cond_t* -> CVInfo* */ |
| static WordFM* map_cond_to_CVInfo = NULL; |
| |
| static void map_cond_to_CVInfo_INIT ( void ) { |
| if (UNLIKELY(map_cond_to_CVInfo == NULL)) { |
| map_cond_to_CVInfo = VG_(newFM)( HG_(zalloc), |
| "hg.mctCI.1", HG_(free), NULL ); |
| tl_assert(map_cond_to_CVInfo != NULL); |
| } |
| } |
| |
| static CVInfo* map_cond_to_CVInfo_lookup_or_alloc ( void* cond ) { |
| UWord key, val; |
| map_cond_to_CVInfo_INIT(); |
| if (VG_(lookupFM)( map_cond_to_CVInfo, &key, &val, (UWord)cond )) { |
| tl_assert(key == (UWord)cond); |
| return (CVInfo*)val; |
| } else { |
| SO* so = libhb_so_alloc(); |
| CVInfo* cvi = HG_(zalloc)("hg.mctCloa.1", sizeof(CVInfo)); |
| cvi->so = so; |
| cvi->mx_ga = 0; |
| VG_(addToFM)( map_cond_to_CVInfo, (UWord)cond, (UWord)cvi ); |
| return cvi; |
| } |
| } |
| |
| static CVInfo* map_cond_to_CVInfo_lookup_NO_alloc ( void* cond ) { |
| UWord key, val; |
| map_cond_to_CVInfo_INIT(); |
| if (VG_(lookupFM)( map_cond_to_CVInfo, &key, &val, (UWord)cond )) { |
| tl_assert(key == (UWord)cond); |
| return (CVInfo*)val; |
| } else { |
| return NULL; |
| } |
| } |
| |
| static void map_cond_to_CVInfo_delete ( ThreadId tid, |
| void* cond, Bool cond_is_init ) { |
| Thread* thr; |
| UWord keyW, valW; |
| |
| thr = map_threads_maybe_lookup( tid ); |
| tl_assert(thr); /* cannot fail - Thread* must already exist */ |
| |
| map_cond_to_CVInfo_INIT(); |
| if (VG_(lookupFM)( map_cond_to_CVInfo, &keyW, &valW, (UWord)cond )) { |
| CVInfo* cvi = (CVInfo*)valW; |
| tl_assert(keyW == (UWord)cond); |
| tl_assert(cvi); |
| tl_assert(cvi->so); |
| if (cvi->nWaiters > 0) { |
| HG_(record_error_Misc)( |
| thr, "pthread_cond_destroy:" |
| " destruction of condition variable being waited upon"); |
| /* Destroying a cond var being waited upon outcome is EBUSY and |
| variable is not destroyed. */ |
| return; |
| } |
| if (!VG_(delFromFM)( map_cond_to_CVInfo, &keyW, &valW, (UWord)cond )) |
| tl_assert(0); // cond var found above, and not here ??? |
| libhb_so_dealloc(cvi->so); |
| cvi->mx_ga = 0; |
| HG_(free)(cvi); |
| } else { |
| /* We have no record of this CV. So complain about it |
| .. except, don't bother to complain if it has exactly the |
| value PTHREAD_COND_INITIALIZER, since it might be that the CV |
| was initialised like that but never used. */ |
| if (!cond_is_init) { |
| HG_(record_error_Misc)( |
| thr, "pthread_cond_destroy: destruction of unknown cond var"); |
| } |
| } |
| } |
| |
| static void evh__HG_PTHREAD_COND_SIGNAL_PRE ( ThreadId tid, void* cond ) |
| { |
| /* 'tid' has signalled on 'cond'. As per the comment above, bind |
| cond to a SO if it is not already so bound, and 'send' on the |
| SO. This is later used by other thread(s) which successfully |
| exit from a pthread_cond_wait on the same cv; then they 'recv' |
| from the SO, thereby acquiring a dependency on this signalling |
| event. */ |
| Thread* thr; |
| CVInfo* cvi; |
| //Lock* lk; |
| |
| if (SHOW_EVENTS >= 1) |
| VG_(printf)("evh__HG_PTHREAD_COND_SIGNAL_PRE(ctid=%d, cond=%p)\n", |
| (Int)tid, (void*)cond ); |
| |
| thr = map_threads_maybe_lookup( tid ); |
| tl_assert(thr); /* cannot fail - Thread* must already exist */ |
| |
| cvi = map_cond_to_CVInfo_lookup_or_alloc( cond ); |
| tl_assert(cvi); |
| tl_assert(cvi->so); |
| |
| // error-if: mutex is bogus |
| // error-if: mutex is not locked |
| // Hmm. POSIX doesn't actually say that it's an error to call |
| // pthread_cond_signal with the associated mutex being unlocked. |
| // Although it does say that it should be "if consistent scheduling |
| // is desired." For that reason, print "dubious" if the lock isn't |
| // held by any thread. Skip the "dubious" if it is held by some |
| // other thread; that sounds straight-out wrong. |
| // |
| // Anybody who writes code that signals on a CV without holding |
| // the associated MX needs to be shipped off to a lunatic asylum |
| // ASAP, even though POSIX doesn't actually declare such behaviour |
| // illegal -- it makes code extremely difficult to understand/ |
| // reason about. In particular it puts the signalling thread in |
| // a situation where it is racing against the released waiter |
| // as soon as the signalling is done, and so there needs to be |
| // some auxiliary synchronisation mechanism in the program that |
| // makes this safe -- or the race(s) need to be harmless, or |
| // probably nonexistent. |
| // |
| if (1) { |
| Lock* lk = NULL; |
| if (cvi->mx_ga != 0) { |
| lk = map_locks_maybe_lookup( (Addr)cvi->mx_ga ); |
| } |
| /* note: lk could be NULL. Be careful. */ |
| if (lk) { |
| if (lk->kind == LK_rdwr) { |
| HG_(record_error_Misc)(thr, |
| "pthread_cond_{signal,broadcast}: associated lock is a rwlock"); |
| } |
| if (lk->heldBy == NULL) { |
| HG_(record_error_Misc)(thr, |
| "pthread_cond_{signal,broadcast}: dubious: " |
| "associated lock is not held by any thread"); |
| } |
| if (lk->heldBy != NULL && 0 == VG_(elemBag)(lk->heldBy, (UWord)thr)) { |
| HG_(record_error_Misc)(thr, |
| "pthread_cond_{signal,broadcast}: " |
| "associated lock is not held by calling thread"); |
| } |
| } else { |
| /* Couldn't even find the damn thing. */ |
| // But actually .. that's not necessarily an error. We don't |
| // know the (CV,MX) binding until a pthread_cond_wait or bcast |
| // shows us what it is, and if that may not have happened yet. |
| // So just keep quiet in this circumstance. |
| //HG_(record_error_Misc)( thr, |
| // "pthread_cond_{signal,broadcast}: " |
| // "no or invalid mutex associated with cond"); |
| } |
| } |
| |
| libhb_so_send( thr->hbthr, cvi->so, True/*strong_send*/ ); |
| } |
| |
| /* returns True if it reckons 'mutex' is valid and held by this |
| thread, else False */ |
| static Bool evh__HG_PTHREAD_COND_WAIT_PRE ( ThreadId tid, |
| void* cond, void* mutex ) |
| { |
| Thread* thr; |
| Lock* lk; |
| Bool lk_valid = True; |
| CVInfo* cvi; |
| |
| if (SHOW_EVENTS >= 1) |
| VG_(printf)("evh__hg_PTHREAD_COND_WAIT_PRE" |
| "(ctid=%d, cond=%p, mutex=%p)\n", |
| (Int)tid, (void*)cond, (void*)mutex ); |
| |
| thr = map_threads_maybe_lookup( tid ); |
| tl_assert(thr); /* cannot fail - Thread* must already exist */ |
| |
| lk = map_locks_maybe_lookup( (Addr)mutex ); |
| |
| /* Check for stupid mutex arguments. There are various ways to be |
| a bozo. Only complain once, though, even if more than one thing |
| is wrong. */ |
| if (lk == NULL) { |
| lk_valid = False; |
| HG_(record_error_Misc)( |
| thr, |
| "pthread_cond_{timed}wait called with invalid mutex" ); |
| } else { |
| tl_assert( HG_(is_sane_LockN)(lk) ); |
| if (lk->kind == LK_rdwr) { |
| lk_valid = False; |
| HG_(record_error_Misc)( |
| thr, "pthread_cond_{timed}wait called with mutex " |
| "of type pthread_rwlock_t*" ); |
| } else |
| if (lk->heldBy == NULL) { |
| lk_valid = False; |
| HG_(record_error_Misc)( |
| thr, "pthread_cond_{timed}wait called with un-held mutex"); |
| } else |
| if (lk->heldBy != NULL |
| && VG_(elemBag)( lk->heldBy, (UWord)thr ) == 0) { |
| lk_valid = False; |
| HG_(record_error_Misc)( |
| thr, "pthread_cond_{timed}wait called with mutex " |
| "held by a different thread" ); |
| } |
| } |
| |
| // error-if: cond is also associated with a different mutex |
| cvi = map_cond_to_CVInfo_lookup_or_alloc(cond); |
| tl_assert(cvi); |
| tl_assert(cvi->so); |
| if (cvi->nWaiters == 0) { |
| /* form initial (CV,MX) binding */ |
| cvi->mx_ga = mutex; |
| } |
| else /* check existing (CV,MX) binding */ |
| if (cvi->mx_ga != mutex) { |
| HG_(record_error_Misc)( |
| thr, "pthread_cond_{timed}wait: cond is associated " |
| "with a different mutex"); |
| } |
| cvi->nWaiters++; |
| |
| return lk_valid; |
| } |
| |
| static void evh__HG_PTHREAD_COND_WAIT_POST ( ThreadId tid, |
| void* cond, void* mutex, |
| Bool timeout) |
| { |
| /* A pthread_cond_wait(cond, mutex) completed successfully. Find |
| the SO for this cond, and 'recv' from it so as to acquire a |
| dependency edge back to the signaller/broadcaster. */ |
| Thread* thr; |
| CVInfo* cvi; |
| |
| if (SHOW_EVENTS >= 1) |
| VG_(printf)("evh__HG_PTHREAD_COND_WAIT_POST" |
| "(ctid=%d, cond=%p, mutex=%p)\n, timeout=%d", |
| (Int)tid, (void*)cond, (void*)mutex, (Int)timeout ); |
| |
| thr = map_threads_maybe_lookup( tid ); |
| tl_assert(thr); /* cannot fail - Thread* must already exist */ |
| |
| // error-if: cond is also associated with a different mutex |
| |
| cvi = map_cond_to_CVInfo_lookup_NO_alloc( cond ); |
| if (!cvi) { |
| /* This could be either a bug in helgrind or the guest application |
| that did an error (e.g. cond var was destroyed by another thread. |
| Let's assume helgrind is perfect ... |
| Note that this is similar to drd behaviour. */ |
| HG_(record_error_Misc)(thr, "condition variable has been destroyed while" |
| " being waited upon"); |
| return; |
| } |
| |
| tl_assert(cvi); |
| tl_assert(cvi->so); |
| tl_assert(cvi->nWaiters > 0); |
| |
| if (!timeout && !libhb_so_everSent(cvi->so)) { |
| /* Hmm. How can a wait on 'cond' succeed if nobody signalled |
| it? If this happened it would surely be a bug in the threads |
| library. Or one of those fabled "spurious wakeups". */ |
| HG_(record_error_Misc)( thr, "Bug in libpthread: pthread_cond_wait " |
| "succeeded" |
| " without prior pthread_cond_post"); |
| } |
| |
| /* anyway, acquire a dependency on it. */ |
| libhb_so_recv( thr->hbthr, cvi->so, True/*strong_recv*/ ); |
| |
| cvi->nWaiters--; |
| } |
| |
| static void evh__HG_PTHREAD_COND_INIT_POST ( ThreadId tid, |
| void* cond, void* cond_attr ) |
| { |
| CVInfo* cvi; |
| |
| if (SHOW_EVENTS >= 1) |
| VG_(printf)("evh__HG_PTHREAD_COND_INIT_POST" |
| "(ctid=%d, cond=%p, cond_attr=%p)\n", |
| (Int)tid, (void*)cond, (void*) cond_attr ); |
| |
| cvi = map_cond_to_CVInfo_lookup_or_alloc( cond ); |
| tl_assert (cvi); |
| tl_assert (cvi->so); |
| } |
| |
| |
| static void evh__HG_PTHREAD_COND_DESTROY_PRE ( ThreadId tid, |
| void* cond, Bool cond_is_init ) |
| { |
| /* Deal with destroy events. The only purpose is to free storage |
| associated with the CV, so as to avoid any possible resource |
| leaks. */ |
| if (SHOW_EVENTS >= 1) |
| VG_(printf)("evh__HG_PTHREAD_COND_DESTROY_PRE" |
| "(ctid=%d, cond=%p, cond_is_init=%d)\n", |
| (Int)tid, (void*)cond, (Int)cond_is_init ); |
| |
| map_cond_to_CVInfo_delete( tid, cond, cond_is_init ); |
| } |
| |
| |
| /* ------------------------------------------------------- */ |
| /* -------------- events to do with rwlocks -------------- */ |
| /* ------------------------------------------------------- */ |
| |
| /* EXPOSITION only */ |
| static |
| void evh__HG_PTHREAD_RWLOCK_INIT_POST( ThreadId tid, void* rwl ) |
| { |
| if (SHOW_EVENTS >= 1) |
| VG_(printf)("evh__hg_PTHREAD_RWLOCK_INIT_POST(ctid=%d, %p)\n", |
| (Int)tid, (void*)rwl ); |
| map_locks_lookup_or_create( LK_rdwr, (Addr)rwl, tid ); |
| if (HG_(clo_sanity_flags) & SCE_LOCKS) |
| all__sanity_check("evh__hg_PTHREAD_RWLOCK_INIT_POST"); |
| } |
| |
| static |
| void evh__HG_PTHREAD_RWLOCK_DESTROY_PRE( ThreadId tid, void* rwl ) |
| { |
| Thread* thr; |
| Lock* lk; |
| if (SHOW_EVENTS >= 1) |
| VG_(printf)("evh__hg_PTHREAD_RWLOCK_DESTROY_PRE(ctid=%d, %p)\n", |
| (Int)tid, (void*)rwl ); |
| |
| thr = map_threads_maybe_lookup( tid ); |
| /* cannot fail - Thread* must already exist */ |
| tl_assert( HG_(is_sane_Thread)(thr) ); |
| |
| lk = map_locks_maybe_lookup( (Addr)rwl ); |
| |
| if (lk == NULL || lk->kind != LK_rdwr) { |
| HG_(record_error_Misc)( |
| thr, "pthread_rwlock_destroy with invalid argument" ); |
| } |
| |
| if (lk) { |
| tl_assert( HG_(is_sane_LockN)(lk) ); |
| tl_assert( lk->guestaddr == (Addr)rwl ); |
| if (lk->heldBy) { |
| /* Basically act like we unlocked the lock */ |
| HG_(record_error_Misc)( |
| thr, "pthread_rwlock_destroy of a locked mutex" ); |
| /* remove lock from locksets of all owning threads */ |
| remove_Lock_from_locksets_of_all_owning_Threads( lk ); |
| VG_(deleteBag)( lk->heldBy ); |
| lk->heldBy = NULL; |
| lk->heldW = False; |
| lk->acquired_at = NULL; |
| } |
| tl_assert( !lk->heldBy ); |
| tl_assert( HG_(is_sane_LockN)(lk) ); |
| |
| if (HG_(clo_track_lockorders)) |
| laog__handle_one_lock_deletion(lk); |
| map_locks_delete( lk->guestaddr ); |
| del_LockN( lk ); |
| } |
| |
| if (HG_(clo_sanity_flags) & SCE_LOCKS) |
| all__sanity_check("evh__hg_PTHREAD_RWLOCK_DESTROY_PRE"); |
| } |
| |
| static |
| void evh__HG_PTHREAD_RWLOCK_LOCK_PRE ( ThreadId tid, |
| void* rwl, |
| Word isW, Word isTryLock ) |
| { |
| /* Just check the rwl is sane; nothing else to do. */ |
| // 'rwl' may be invalid - not checked by wrapper |
| Thread* thr; |
| Lock* lk; |
| if (SHOW_EVENTS >= 1) |
| VG_(printf)("evh__hg_PTHREAD_RWLOCK_LOCK_PRE(ctid=%d, isW=%d, %p)\n", |
| (Int)tid, (Int)isW, (void*)rwl ); |
| |
| tl_assert(isW == 0 || isW == 1); /* assured us by wrapper */ |
| tl_assert(isTryLock == 0 || isTryLock == 1); /* assured us by wrapper */ |
| thr = map_threads_maybe_lookup( tid ); |
| tl_assert(thr); /* cannot fail - Thread* must already exist */ |
| |
| lk = map_locks_maybe_lookup( (Addr)rwl ); |
| if ( lk |
| && (lk->kind == LK_nonRec || lk->kind == LK_mbRec) ) { |
| /* Wrong kind of lock. Duh. */ |
| HG_(record_error_Misc)( |
| thr, "pthread_rwlock_{rd,rw}lock with a " |
| "pthread_mutex_t* argument " ); |
| } |
| } |
| |
| static |
| void evh__HG_PTHREAD_RWLOCK_LOCK_POST ( ThreadId tid, void* rwl, Word isW ) |
| { |
| // only called if the real library call succeeded - so mutex is sane |
| Thread* thr; |
| if (SHOW_EVENTS >= 1) |
| VG_(printf)("evh__hg_PTHREAD_RWLOCK_LOCK_POST(ctid=%d, isW=%d, %p)\n", |
| (Int)tid, (Int)isW, (void*)rwl ); |
| |
| tl_assert(isW == 0 || isW == 1); /* assured us by wrapper */ |
| thr = map_threads_maybe_lookup( tid ); |
| tl_assert(thr); /* cannot fail - Thread* must already exist */ |
| |
| (isW ? evhH__post_thread_w_acquires_lock |
| : evhH__post_thread_r_acquires_lock)( |
| thr, |
| LK_rdwr, /* if not known, create new lock with this LockKind */ |
| (Addr)rwl |
| ); |
| } |
| |
| static void evh__HG_PTHREAD_RWLOCK_UNLOCK_PRE ( ThreadId tid, void* rwl ) |
| { |
| // 'rwl' may be invalid - not checked by wrapper |
| Thread* thr; |
| if (SHOW_EVENTS >= 1) |
| VG_(printf)("evh__HG_PTHREAD_RWLOCK_UNLOCK_PRE(ctid=%d, rwl=%p)\n", |
| (Int)tid, (void*)rwl ); |
| |
| thr = map_threads_maybe_lookup( tid ); |
| tl_assert(thr); /* cannot fail - Thread* must already exist */ |
| |
| evhH__pre_thread_releases_lock( thr, (Addr)rwl, True/*isRDWR*/ ); |
| } |
| |
| static void evh__HG_PTHREAD_RWLOCK_UNLOCK_POST ( ThreadId tid, void* rwl ) |
| { |
| // only called if the real library call succeeded - so mutex is sane |
| Thread* thr; |
| if (SHOW_EVENTS >= 1) |
| VG_(printf)("evh__hg_PTHREAD_RWLOCK_UNLOCK_POST(ctid=%d, rwl=%p)\n", |
| (Int)tid, (void*)rwl ); |
| thr = map_threads_maybe_lookup( tid ); |
| tl_assert(thr); /* cannot fail - Thread* must already exist */ |
| |
| // anything we should do here? |
| } |
| |
| |
| /* ---------------------------------------------------------- */ |
| /* -------------- events to do with semaphores -------------- */ |
| /* ---------------------------------------------------------- */ |
| |
| /* This is similar to but not identical to the handling for condition |
| variables. */ |
| |
| /* For each semaphore, we maintain a stack of SOs. When a 'post' |
| operation is done on a semaphore (unlocking, essentially), a new SO |
| is created for the posting thread, the posting thread does a strong |
| send to it (which merely installs the posting thread's VC in the |
| SO), and the SO is pushed on the semaphore's stack. |
| |
| Later, when a (probably different) thread completes 'wait' on the |
| semaphore, we pop a SO off the semaphore's stack (which should be |
| nonempty), and do a strong recv from it. This mechanism creates |
| dependencies between posters and waiters of the semaphore. |
| |
| It may not be necessary to use a stack - perhaps a bag of SOs would |
| do. But we do need to keep track of how many unused-up posts have |
| happened for the semaphore. |
| |
| Imagine T1 and T2 both post once on a semaphore S, and T3 waits |
| twice on S. T3 cannot complete its waits without both T1 and T2 |
| posting. The above mechanism will ensure that T3 acquires |
| dependencies on both T1 and T2. |
| |
| When a semaphore is initialised with value N, we do as if we'd |
| posted N times on the semaphore: basically create N SOs and do a |
| strong send to all of then. This allows up to N waits on the |
| semaphore to acquire a dependency on the initialisation point, |
| which AFAICS is the correct behaviour. |
| |
| We don't emit an error for DESTROY_PRE on a semaphore we don't know |
| about. We should. |
| */ |
| |
| /* sem_t* -> XArray* SO* */ |
| static WordFM* map_sem_to_SO_stack = NULL; |
| |
| static void map_sem_to_SO_stack_INIT ( void ) { |
| if (map_sem_to_SO_stack == NULL) { |
| map_sem_to_SO_stack = VG_(newFM)( HG_(zalloc), "hg.mstSs.1", |
| HG_(free), NULL ); |
| tl_assert(map_sem_to_SO_stack != NULL); |
| } |
| } |
| |
| static void push_SO_for_sem ( void* sem, SO* so ) { |
| UWord keyW; |
| XArray* xa; |
| tl_assert(so); |
| map_sem_to_SO_stack_INIT(); |
| if (VG_(lookupFM)( map_sem_to_SO_stack, |
| &keyW, (UWord*)&xa, (UWord)sem )) { |
| tl_assert(keyW == (UWord)sem); |
| tl_assert(xa); |
| VG_(addToXA)( xa, &so ); |
| } else { |
| xa = VG_(newXA)( HG_(zalloc), "hg.pSfs.1", HG_(free), sizeof(SO*) ); |
| VG_(addToXA)( xa, &so ); |
| VG_(addToFM)( map_sem_to_SO_stack, (UWord)sem, (UWord)xa ); |
| } |
| } |
| |
| static SO* mb_pop_SO_for_sem ( void* sem ) { |
| UWord keyW; |
| XArray* xa; |
| SO* so; |
| map_sem_to_SO_stack_INIT(); |
| if (VG_(lookupFM)( map_sem_to_SO_stack, |
| &keyW, (UWord*)&xa, (UWord)sem )) { |
| /* xa is the stack for this semaphore. */ |
| Word sz; |
| tl_assert(keyW == (UWord)sem); |
| sz = VG_(sizeXA)( xa ); |
| tl_assert(sz >= 0); |
| if (sz == 0) |
| return NULL; /* odd, the stack is empty */ |
| so = *(SO**)VG_(indexXA)( xa, sz-1 ); |
| tl_assert(so); |
| VG_(dropTailXA)( xa, 1 ); |
| return so; |
| } else { |
| /* hmm, that's odd. No stack for this semaphore. */ |
| return NULL; |
| } |
| } |
| |
| static void evh__HG_POSIX_SEM_DESTROY_PRE ( ThreadId tid, void* sem ) |
| { |
| UWord keyW, valW; |
| SO* so; |
| |
| if (SHOW_EVENTS >= 1) |
| VG_(printf)("evh__HG_POSIX_SEM_DESTROY_PRE(ctid=%d, sem=%p)\n", |
| (Int)tid, (void*)sem ); |
| |
| map_sem_to_SO_stack_INIT(); |
| |
| /* Empty out the semaphore's SO stack. This way of doing it is |
| stupid, but at least it's easy. */ |
| while (1) { |
| so = mb_pop_SO_for_sem( sem ); |
| if (!so) break; |
| libhb_so_dealloc(so); |
| } |
| |
| if (VG_(delFromFM)( map_sem_to_SO_stack, &keyW, &valW, (UWord)sem )) { |
| XArray* xa = (XArray*)valW; |
| tl_assert(keyW == (UWord)sem); |
| tl_assert(xa); |
| tl_assert(VG_(sizeXA)(xa) == 0); /* preceding loop just emptied it */ |
| VG_(deleteXA)(xa); |
| } |
| } |
| |
| static |
| void evh__HG_POSIX_SEM_INIT_POST ( ThreadId tid, void* sem, UWord value ) |
| { |
| SO* so; |
| Thread* thr; |
| |
| if (SHOW_EVENTS >= 1) |
| VG_(printf)("evh__HG_POSIX_SEM_INIT_POST(ctid=%d, sem=%p, value=%lu)\n", |
| (Int)tid, (void*)sem, value ); |
| |
| thr = map_threads_maybe_lookup( tid ); |
| tl_assert(thr); /* cannot fail - Thread* must already exist */ |
| |
| /* Empty out the semaphore's SO stack. This way of doing it is |
| stupid, but at least it's easy. */ |
| while (1) { |
| so = mb_pop_SO_for_sem( sem ); |
| if (!so) break; |
| libhb_so_dealloc(so); |
| } |
| |
| /* If we don't do this check, the following while loop runs us out |
| of memory for stupid initial values of 'value'. */ |
| if (value > 10000) { |
| HG_(record_error_Misc)( |
| thr, "sem_init: initial value exceeds 10000; using 10000" ); |
| value = 10000; |
| } |
| |
| /* Now create 'valid' new SOs for the thread, do a strong send to |
| each of them, and push them all on the stack. */ |
| for (; value > 0; value--) { |
| Thr* hbthr = thr->hbthr; |
| tl_assert(hbthr); |
| |
| so = libhb_so_alloc(); |
| libhb_so_send( hbthr, so, True/*strong send*/ ); |
| push_SO_for_sem( sem, so ); |
| } |
| } |
| |
| static void evh__HG_POSIX_SEM_POST_PRE ( ThreadId tid, void* sem ) |
| { |
| /* 'tid' has posted on 'sem'. Create a new SO, do a strong send to |
| it (iow, write our VC into it, then tick ours), and push the SO |
| on on a stack of SOs associated with 'sem'. This is later used |
| by other thread(s) which successfully exit from a sem_wait on |
| the same sem; by doing a strong recv from SOs popped of the |
| stack, they acquire dependencies on the posting thread |
| segment(s). */ |
| |
| Thread* thr; |
| SO* so; |
| Thr* hbthr; |
| |
| if (SHOW_EVENTS >= 1) |
| VG_(printf)("evh__HG_POSIX_SEM_POST_PRE(ctid=%d, sem=%p)\n", |
| (Int)tid, (void*)sem ); |
| |
| thr = map_threads_maybe_lookup( tid ); |
| tl_assert(thr); /* cannot fail - Thread* must already exist */ |
| |
| // error-if: sem is bogus |
| |
| hbthr = thr->hbthr; |
| tl_assert(hbthr); |
| |
| so = libhb_so_alloc(); |
| libhb_so_send( hbthr, so, True/*strong send*/ ); |
| push_SO_for_sem( sem, so ); |
| } |
| |
| static void evh__HG_POSIX_SEM_WAIT_POST ( ThreadId tid, void* sem ) |
| { |
| /* A sem_wait(sem) completed successfully. Pop the posting-SO for |
| the 'sem' from this semaphore's SO-stack, and do a strong recv |
| from it. This creates a dependency back to one of the post-ers |
| for the semaphore. */ |
| |
| Thread* thr; |
| SO* so; |
| Thr* hbthr; |
| |
| if (SHOW_EVENTS >= 1) |
| VG_(printf)("evh__HG_POSIX_SEM_WAIT_POST(ctid=%d, sem=%p)\n", |
| (Int)tid, (void*)sem ); |
| |
| thr = map_threads_maybe_lookup( tid ); |
| tl_assert(thr); /* cannot fail - Thread* must already exist */ |
| |
| // error-if: sem is bogus |
| |
| so = mb_pop_SO_for_sem( sem ); |
| |
| if (so) { |
| hbthr = thr->hbthr; |
| tl_assert(hbthr); |
| |
| libhb_so_recv( hbthr, so, True/*strong recv*/ ); |
| libhb_so_dealloc(so); |
| } else { |
| /* Hmm. How can a wait on 'sem' succeed if nobody posted to it? |
| If this happened it would surely be a bug in the threads |
| library. */ |
| HG_(record_error_Misc)( |
| thr, "Bug in libpthread: sem_wait succeeded on" |
| " semaphore without prior sem_post"); |
| } |
| } |
| |
| |
| /* -------------------------------------------------------- */ |
| /* -------------- events to do with barriers -------------- */ |
| /* -------------------------------------------------------- */ |
| |
| typedef |
| struct { |
| Bool initted; /* has it yet been initted by guest? */ |
| Bool resizable; /* is resizing allowed? */ |
| UWord size; /* declared size */ |
| XArray* waiting; /* XA of Thread*. # present is 0 .. .size */ |
| } |
| Bar; |
| |
| static Bar* new_Bar ( void ) { |
| Bar* bar = HG_(zalloc)( "hg.nB.1 (new_Bar)", sizeof(Bar) ); |
| tl_assert(bar); |
| /* all fields are zero */ |
| tl_assert(bar->initted == False); |
| return bar; |
| } |
| |
| static void delete_Bar ( Bar* bar ) { |
| tl_assert(bar); |
| if (bar->waiting) |
| VG_(deleteXA)(bar->waiting); |
| HG_(free)(bar); |
| } |
| |
| /* A mapping which stores auxiliary data for barriers. */ |
| |
| /* pthread_barrier_t* -> Bar* */ |
| static WordFM* map_barrier_to_Bar = NULL; |
| |
| static void map_barrier_to_Bar_INIT ( void ) { |
| if (UNLIKELY(map_barrier_to_Bar == NULL)) { |
| map_barrier_to_Bar = VG_(newFM)( HG_(zalloc), |
| "hg.mbtBI.1", HG_(free), NULL ); |
| tl_assert(map_barrier_to_Bar != NULL); |
| } |
| } |
| |
| static Bar* map_barrier_to_Bar_lookup_or_alloc ( void* barrier ) { |
| UWord key, val; |
| map_barrier_to_Bar_INIT(); |
| if (VG_(lookupFM)( map_barrier_to_Bar, &key, &val, (UWord)barrier )) { |
| tl_assert(key == (UWord)barrier); |
| return (Bar*)val; |
| } else { |
| Bar* bar = new_Bar(); |
| VG_(addToFM)( map_barrier_to_Bar, (UWord)barrier, (UWord)bar ); |
| return bar; |
| } |
| } |
| |
| static void map_barrier_to_Bar_delete ( void* barrier ) { |
| UWord keyW, valW; |
| map_barrier_to_Bar_INIT(); |
| if (VG_(delFromFM)( map_barrier_to_Bar, &keyW, &valW, (UWord)barrier )) { |
| Bar* bar = (Bar*)valW; |
| tl_assert(keyW == (UWord)barrier); |
| delete_Bar(bar); |
| } |
| } |
| |
| |
| static void evh__HG_PTHREAD_BARRIER_INIT_PRE ( ThreadId tid, |
| void* barrier, |
| UWord count, |
| UWord resizable ) |
| { |
| Thread* thr; |
| Bar* bar; |
| |
| if (SHOW_EVENTS >= 1) |
| VG_(printf)("evh__HG_PTHREAD_BARRIER_INIT_PRE" |
| "(tid=%d, barrier=%p, count=%lu, resizable=%lu)\n", |
| (Int)tid, (void*)barrier, count, resizable ); |
| |
| thr = map_threads_maybe_lookup( tid ); |
| tl_assert(thr); /* cannot fail - Thread* must already exist */ |
| |
| if (count == 0) { |
| HG_(record_error_Misc)( |
| thr, "pthread_barrier_init: 'count' argument is zero" |
| ); |
| } |
| |
| if (resizable != 0 && resizable != 1) { |
| HG_(record_error_Misc)( |
| thr, "pthread_barrier_init: invalid 'resizable' argument" |
| ); |
| } |
| |
| bar = map_barrier_to_Bar_lookup_or_alloc(barrier); |
| tl_assert(bar); |
| |
| if (bar->initted) { |
| HG_(record_error_Misc)( |
| thr, "pthread_barrier_init: barrier is already initialised" |
| ); |
| } |
| |
| if (bar->waiting && VG_(sizeXA)(bar->waiting) > 0) { |
| tl_assert(bar->initted); |
| HG_(record_error_Misc)( |
| thr, "pthread_barrier_init: threads are waiting at barrier" |
| ); |
| VG_(dropTailXA)(bar->waiting, VG_(sizeXA)(bar->waiting)); |
| } |
| if (!bar->waiting) { |
| bar->waiting = VG_(newXA)( HG_(zalloc), "hg.eHPBIP.1", HG_(free), |
| sizeof(Thread*) ); |
| } |
| |
| tl_assert(bar->waiting); |
| tl_assert(VG_(sizeXA)(bar->waiting) == 0); |
| bar->initted = True; |
| bar->resizable = resizable == 1 ? True : False; |
| bar->size = count; |
| } |
| |
| |
| static void evh__HG_PTHREAD_BARRIER_DESTROY_PRE ( ThreadId tid, |
| void* barrier ) |
| { |
| Thread* thr; |
| Bar* bar; |
| |
| /* Deal with destroy events. The only purpose is to free storage |
| associated with the barrier, so as to avoid any possible |
| resource leaks. */ |
| if (SHOW_EVENTS >= 1) |
| VG_(printf)("evh__HG_PTHREAD_BARRIER_DESTROY_PRE" |
| "(tid=%d, barrier=%p)\n", |
| (Int)tid, (void*)barrier ); |
| |
| thr = map_threads_maybe_lookup( tid ); |
| tl_assert(thr); /* cannot fail - Thread* must already exist */ |
| |
| bar = map_barrier_to_Bar_lookup_or_alloc(barrier); |
| tl_assert(bar); |
| |
| if (!bar->initted) { |
| HG_(record_error_Misc)( |
| thr, "pthread_barrier_destroy: barrier was never initialised" |
| ); |
| } |
| |
| if (bar->initted && bar->waiting && VG_(sizeXA)(bar->waiting) > 0) { |
| HG_(record_error_Misc)( |
| thr, "pthread_barrier_destroy: threads are waiting at barrier" |
| ); |
| } |
| |
| /* Maybe we shouldn't do this; just let it persist, so that when it |
| is reinitialised we don't need to do any dynamic memory |
| allocation? The downside is a potentially unlimited space leak, |
| if the client creates (in turn) a large number of barriers all |
| at different locations. Note that if we do later move to the |
| don't-delete-it scheme, we need to mark the barrier as |
| uninitialised again since otherwise a later _init call will |
| elicit a duplicate-init error. */ |
| map_barrier_to_Bar_delete( barrier ); |
| } |
| |
| |
| /* All the threads have arrived. Now do the Interesting Bit. Get a |
| new synchronisation object and do a weak send to it from all the |
| participating threads. This makes its vector clocks be the join of |
| all the individual threads' vector clocks. Then do a strong |
| receive from it back to all threads, so that their VCs are a copy |
| of it (hence are all equal to the join of their original VCs.) */ |
| static void do_barrier_cross_sync_and_empty ( Bar* bar ) |
| { |
| /* XXX check bar->waiting has no duplicates */ |
| UWord i; |
| SO* so = libhb_so_alloc(); |
| |
| tl_assert(bar->waiting); |
| tl_assert(VG_(sizeXA)(bar->waiting) == bar->size); |
| |
| /* compute the join ... */ |
| for (i = 0; i < bar->size; i++) { |
| Thread* t = *(Thread**)VG_(indexXA)(bar->waiting, i); |
| Thr* hbthr = t->hbthr; |
| libhb_so_send( hbthr, so, False/*weak send*/ ); |
| } |
| /* ... and distribute to all threads */ |
| for (i = 0; i < bar->size; i++) { |
| Thread* t = *(Thread**)VG_(indexXA)(bar->waiting, i); |
| Thr* hbthr = t->hbthr; |
| libhb_so_recv( hbthr, so, True/*strong recv*/ ); |
| } |
| |
| /* finally, we must empty out the waiting vector */ |
| VG_(dropTailXA)(bar->waiting, VG_(sizeXA)(bar->waiting)); |
| |
| /* and we don't need this any more. Perhaps a stack-allocated |
| SO would be better? */ |
| libhb_so_dealloc(so); |
| } |
| |
| |
| static void evh__HG_PTHREAD_BARRIER_WAIT_PRE ( ThreadId tid, |
| void* barrier ) |
| { |
| /* This function gets called after a client thread calls |
| pthread_barrier_wait but before it arrives at the real |
| pthread_barrier_wait. |
| |
| Why is the following correct? It's a bit subtle. |
| |
| If this is not the last thread arriving at the barrier, we simply |
| note its presence and return. Because valgrind (at least as of |
| Nov 08) is single threaded, we are guaranteed safe from any race |
| conditions when in this function -- no other client threads are |
| running. |
| |
| If this is the last thread, then we are again the only running |
| thread. All the other threads will have either arrived at the |
| real pthread_barrier_wait or are on their way to it, but in any |
| case are guaranteed not to be able to move past it, because this |
| thread is currently in this function and so has not yet arrived |
| at the real pthread_barrier_wait. That means that: |
| |
| 1. While we are in this function, none of the other threads |
| waiting at the barrier can move past it. |
| |
| 2. When this function returns (and simulated execution resumes), |
| this thread and all other waiting threads will be able to move |
| past the real barrier. |
| |
| Because of this, it is now safe to update the vector clocks of |
| all threads, to represent the fact that they all arrived at the |
| barrier and have all moved on. There is no danger of any |
| complications to do with some threads leaving the barrier and |
| racing back round to the front, whilst others are still leaving |
| (which is the primary source of complication in correct handling/ |
| implementation of barriers). That can't happen because we update |
| here our data structures so as to indicate that the threads have |
| passed the barrier, even though, as per (2) above, they are |
| guaranteed not to pass the barrier until we return. |
| |
| This relies crucially on Valgrind being single threaded. If that |
| changes, this will need to be reconsidered. |
| */ |
| Thread* thr; |
| Bar* bar; |
| UWord present; |
| |
| if (SHOW_EVENTS >= 1) |
| VG_(printf)("evh__HG_PTHREAD_BARRIER_WAIT_PRE" |
| "(tid=%d, barrier=%p)\n", |
| (Int)tid, (void*)barrier ); |
| |
| thr = map_threads_maybe_lookup( tid ); |
| tl_assert(thr); /* cannot fail - Thread* must already exist */ |
| |
| bar = map_barrier_to_Bar_lookup_or_alloc(barrier); |
| tl_assert(bar); |
| |
| if (!bar->initted) { |
| HG_(record_error_Misc)( |
| thr, "pthread_barrier_wait: barrier is uninitialised" |
| ); |
| return; /* client is broken .. avoid assertions below */ |
| } |
| |
| /* guaranteed by _INIT_PRE above */ |
| tl_assert(bar->size > 0); |
| tl_assert(bar->waiting); |
| |
| VG_(addToXA)( bar->waiting, &thr ); |
| |
| /* guaranteed by this function */ |
| present = VG_(sizeXA)(bar->waiting); |
| tl_assert(present > 0 && present <= bar->size); |
| |
| if (present < bar->size) |
| return; |
| |
| do_barrier_cross_sync_and_empty(bar); |
| } |
| |
| |
| static void evh__HG_PTHREAD_BARRIER_RESIZE_PRE ( ThreadId tid, |
| void* barrier, |
| UWord newcount ) |
| { |
| Thread* thr; |
| Bar* bar; |
| UWord present; |
| |
| if (SHOW_EVENTS >= 1) |
| VG_(printf)("evh__HG_PTHREAD_BARRIER_RESIZE_PRE" |
| "(tid=%d, barrier=%p, newcount=%lu)\n", |
| (Int)tid, (void*)barrier, newcount ); |
| |
| thr = map_threads_maybe_lookup( tid ); |
| tl_assert(thr); /* cannot fail - Thread* must already exist */ |
| |
| bar = map_barrier_to_Bar_lookup_or_alloc(barrier); |
| tl_assert(bar); |
| |
| if (!bar->initted) { |
| HG_(record_error_Misc)( |
| thr, "pthread_barrier_resize: barrier is uninitialised" |
| ); |
| return; /* client is broken .. avoid assertions below */ |
| } |
| |
| if (!bar->resizable) { |
| HG_(record_error_Misc)( |
| thr, "pthread_barrier_resize: barrier is may not be resized" |
| ); |
| return; /* client is broken .. avoid assertions below */ |
| } |
| |
| if (newcount == 0) { |
| HG_(record_error_Misc)( |
| thr, "pthread_barrier_resize: 'newcount' argument is zero" |
| ); |
| return; /* client is broken .. avoid assertions below */ |
| } |
| |
| /* guaranteed by _INIT_PRE above */ |
| tl_assert(bar->size > 0); |
| tl_assert(bar->waiting); |
| /* Guaranteed by this fn */ |
| tl_assert(newcount > 0); |
| |
| if (newcount >= bar->size) { |
| /* Increasing the capacity. There's no possibility of threads |
| moving on from the barrier in this situation, so just note |
| the fact and do nothing more. */ |
| bar->size = newcount; |
| } else { |
| /* Decreasing the capacity. If we decrease it to be equal or |
| below the number of waiting threads, they will now move past |
| the barrier, so need to mess with dep edges in the same way |
| as if the barrier had filled up normally. */ |
| present = VG_(sizeXA)(bar->waiting); |
| tl_assert(present >= 0 && present <= bar->size); |
| if (newcount <= present) { |
| bar->size = present; /* keep the cross_sync call happy */ |
| do_barrier_cross_sync_and_empty(bar); |
| } |
| bar->size = newcount; |
| } |
| } |
| |
| |
| /* ----------------------------------------------------- */ |
| /* ----- events to do with user-specified HB edges ----- */ |
| /* ----------------------------------------------------- */ |
| |
| /* A mapping from arbitrary UWord tag to the SO associated with it. |
| The UWord tags are meaningless to us, interpreted only by the |
| user. */ |
| |
| |
| |
| /* UWord -> SO* */ |
| static WordFM* map_usertag_to_SO = NULL; |
| |
| static void map_usertag_to_SO_INIT ( void ) { |
| if (UNLIKELY(map_usertag_to_SO == NULL)) { |
| map_usertag_to_SO = VG_(newFM)( HG_(zalloc), |
| "hg.mutS.1", HG_(free), NULL ); |
| tl_assert(map_usertag_to_SO != NULL); |
| } |
| } |
| |
| static SO* map_usertag_to_SO_lookup_or_alloc ( UWord usertag ) { |
| UWord key, val; |
| map_usertag_to_SO_INIT(); |
| if (VG_(lookupFM)( map_usertag_to_SO, &key, &val, usertag )) { |
| tl_assert(key == (UWord)usertag); |
| return (SO*)val; |
| } else { |
| SO* so = libhb_so_alloc(); |
| VG_(addToFM)( map_usertag_to_SO, usertag, (UWord)so ); |
| return so; |
| } |
| } |
| |
| static void map_usertag_to_SO_delete ( UWord usertag ) { |
| UWord keyW, valW; |
| map_usertag_to_SO_INIT(); |
| if (VG_(delFromFM)( map_usertag_to_SO, &keyW, &valW, usertag )) { |
| SO* so = (SO*)valW; |
| tl_assert(keyW == usertag); |
| tl_assert(so); |
| libhb_so_dealloc(so); |
| } |
| } |
| |
| |
| static |
| void evh__HG_USERSO_SEND_PRE ( ThreadId tid, UWord usertag ) |
| { |
| /* TID is just about to notionally sent a message on a notional |
| abstract synchronisation object whose identity is given by |
| USERTAG. Bind USERTAG to a real SO if it is not already so |
| bound, and do a 'weak send' on the SO. This joins the vector |
| clocks from this thread into any vector clocks already present |
| in the SO. The resulting SO vector clocks are later used by |
| other thread(s) which successfully 'receive' from the SO, |
| thereby acquiring a dependency on all the events that have |
| previously signalled on this SO. */ |
| Thread* thr; |
| SO* so; |
| |
| if (SHOW_EVENTS >= 1) |
| VG_(printf)("evh__HG_USERSO_SEND_PRE(ctid=%d, usertag=%#lx)\n", |
| (Int)tid, usertag ); |
| |
| thr = map_threads_maybe_lookup( tid ); |
| tl_assert(thr); /* cannot fail - Thread* must already exist */ |
| |
| so = map_usertag_to_SO_lookup_or_alloc( usertag ); |
| tl_assert(so); |
| |
| libhb_so_send( thr->hbthr, so, False/*!strong_send*/ ); |
| } |
| |
| static |
| void evh__HG_USERSO_RECV_POST ( ThreadId tid, UWord usertag ) |
| { |
| /* TID has just notionally received a message from a notional |
| abstract synchronisation object whose identity is given by |
| USERTAG. Bind USERTAG to a real SO if it is not already so |
| bound. If the SO has at some point in the past been 'sent' on, |
| to a 'strong receive' on it, thereby acquiring a dependency on |
| the sender. */ |
| Thread* thr; |
| SO* so; |
| |
| if (SHOW_EVENTS >= 1) |
| VG_(printf)("evh__HG_USERSO_RECV_POST(ctid=%d, usertag=%#lx)\n", |
| (Int)tid, usertag ); |
| |
| thr = map_threads_maybe_lookup( tid ); |
| tl_assert(thr); /* cannot fail - Thread* must already exist */ |
| |
| so = map_usertag_to_SO_lookup_or_alloc( usertag ); |
| tl_assert(so); |
| |
| /* Acquire a dependency on it. If the SO has never so far been |
| sent on, then libhb_so_recv will do nothing. So we're safe |
| regardless of SO's history. */ |
| libhb_so_recv( thr->hbthr, so, True/*strong_recv*/ ); |
| } |
| |
| static |
| void evh__HG_USERSO_FORGET_ALL ( ThreadId tid, UWord usertag ) |
| { |
| /* TID declares that any happens-before edges notionally stored in |
| USERTAG can be deleted. If (as would normally be the case) a |
| SO is associated with USERTAG, then the assocation is removed |
| and all resources associated with SO are freed. Importantly, |
| that frees up any VTSs stored in SO. */ |
| if (SHOW_EVENTS >= 1) |
| VG_(printf)("evh__HG_USERSO_FORGET_ALL(ctid=%d, usertag=%#lx)\n", |
| (Int)tid, usertag ); |
| |
| map_usertag_to_SO_delete( usertag ); |
| } |
| |
| |
| /*--------------------------------------------------------------*/ |
| /*--- Lock acquisition order monitoring ---*/ |
| /*--------------------------------------------------------------*/ |
| |
| /* FIXME: here are some optimisations still to do in |
| laog__pre_thread_acquires_lock. |
| |
| The graph is structured so that if L1 --*--> L2 then L1 must be |
| acquired before L2. |
| |
| The common case is that some thread T holds (eg) L1 L2 and L3 and |
| is repeatedly acquiring and releasing Ln, and there is no ordering |
| error in what it is doing. Hence it repeatly: |
| |
| (1) searches laog to see if Ln --*--> {L1,L2,L3}, which always |
| produces the answer No (because there is no error). |
| |
| (2) adds edges {L1,L2,L3} --> Ln to laog, which are already present |
| (because they already got added the first time T acquired Ln). |
| |
| Hence cache these two events: |
| |
| (1) Cache result of the query from last time. Invalidate the cache |
| any time any edges are added to or deleted from laog. |
| |
| (2) Cache these add-edge requests and ignore them if said edges |
| have already been added to laog. Invalidate the cache any time |
| any edges are deleted from laog. |
| */ |
| |
| typedef |
| struct { |
| WordSetID inns; /* in univ_laog */ |
| WordSetID outs; /* in univ_laog */ |
| } |
| LAOGLinks; |
| |
| /* lock order acquisition graph */ |
| static WordFM* laog = NULL; /* WordFM Lock* LAOGLinks* */ |
| |
| /* EXPOSITION ONLY: for each edge in 'laog', record the two places |
| where that edge was created, so that we can show the user later if |
| we need to. */ |
| typedef |
| struct { |
| Addr src_ga; /* Lock guest addresses for */ |
| Addr dst_ga; /* src/dst of the edge */ |
| ExeContext* src_ec; /* And corresponding places where that */ |
| ExeContext* dst_ec; /* ordering was established */ |
| } |
| LAOGLinkExposition; |
| |
| static Word cmp_LAOGLinkExposition ( UWord llx1W, UWord llx2W ) { |
| /* Compare LAOGLinkExposition*s by (src_ga,dst_ga) field pair. */ |
| LAOGLinkExposition* llx1 = (LAOGLinkExposition*)llx1W; |
| LAOGLinkExposition* llx2 = (LAOGLinkExposition*)llx2W; |
| if (llx1->src_ga < llx2->src_ga) return -1; |
| if (llx1->src_ga > llx2->src_ga) return 1; |
| if (llx1->dst_ga < llx2->dst_ga) return -1; |
| if (llx1->dst_ga > llx2->dst_ga) return 1; |
| return 0; |
| } |
| |
| static WordFM* laog_exposition = NULL; /* WordFM LAOGLinkExposition* NULL */ |
| /* end EXPOSITION ONLY */ |
| |
| |
| __attribute__((noinline)) |
| static void laog__init ( void ) |
| { |
| tl_assert(!laog); |
| tl_assert(!laog_exposition); |
| tl_assert(HG_(clo_track_lockorders)); |
| |
| laog = VG_(newFM)( HG_(zalloc), "hg.laog__init.1", |
| HG_(free), NULL/*unboxedcmp*/ ); |
| |
| laog_exposition = VG_(newFM)( HG_(zalloc), "hg.laog__init.2", HG_(free), |
| cmp_LAOGLinkExposition ); |
| tl_assert(laog); |
| tl_assert(laog_exposition); |
| } |
| |
| static void laog__show ( const HChar* who ) { |
| UWord i, ws_size; |
| UWord* ws_words; |
| Lock* me; |
| LAOGLinks* links; |
| VG_(printf)("laog (requested by %s) {\n", who); |
| VG_(initIterFM)( laog ); |
| me = NULL; |
| links = NULL; |
| while (VG_(nextIterFM)( laog, (UWord*)&me, |
| (UWord*)&links )) { |
| tl_assert(me); |
| tl_assert(links); |
| VG_(printf)(" node %p:\n", me); |
| HG_(getPayloadWS)( &ws_words, &ws_size, univ_laog, links->inns ); |
| for (i = 0; i < ws_size; i++) |
| VG_(printf)(" inn %#lx\n", ws_words[i] ); |
| HG_(getPayloadWS)( &ws_words, &ws_size, univ_laog, links->outs ); |
| for (i = 0; i < ws_size; i++) |
| VG_(printf)(" out %#lx\n", ws_words[i] ); |
| me = NULL; |
| links = NULL; |
| } |
| VG_(doneIterFM)( laog ); |
| VG_(printf)("}\n"); |
| } |
| |
| static void univ_laog_do_GC ( void ) { |
| Word i; |
| LAOGLinks* links; |
| Word seen = 0; |
| Int prev_next_gc_univ_laog = next_gc_univ_laog; |
| const UWord univ_laog_cardinality = HG_(cardinalityWSU)( univ_laog); |
| |
| Bool *univ_laog_seen = HG_(zalloc) ( "hg.gc_univ_laog.1", |
| (Int) univ_laog_cardinality |
| * sizeof(Bool) ); |
| // univ_laog_seen[*] set to 0 (False) by zalloc. |
| |
| if (VG_(clo_stats)) |
| VG_(message)(Vg_DebugMsg, |
| "univ_laog_do_GC enter cardinality %'10d\n", |
| (Int)univ_laog_cardinality); |
| |
| VG_(initIterFM)( laog ); |
| links = NULL; |
| while (VG_(nextIterFM)( laog, NULL, (UWord*)&links )) { |
| tl_assert(links); |
| tl_assert(links->inns >= 0 && links->inns < univ_laog_cardinality); |
| univ_laog_seen[links->inns] = True; |
| tl_assert(links->outs >= 0 && links->outs < univ_laog_cardinality); |
| univ_laog_seen[links->outs] = True; |
| links = NULL; |
| } |
| VG_(doneIterFM)( laog ); |
| |
| for (i = 0; i < (Int)univ_laog_cardinality; i++) { |
| if (univ_laog_seen[i]) |
| seen++; |
| else |
| HG_(dieWS) ( univ_laog, (WordSet)i ); |
| } |
| |
| HG_(free) (univ_laog_seen); |
| |
| // We need to decide the value of the next_gc. |
| // 3 solutions were looked at: |
| // Sol 1: garbage collect at seen * 2 |
| // This solution was a lot slower, probably because we both do a lot of |
| // garbage collection and do not keep long enough laog WV that will become |
| // useful again very soon. |
| // Sol 2: garbage collect at a percentage increase of the current cardinality |
| // (with a min increase of 1) |
| // Trials on a small test program with 1%, 5% and 10% increase was done. |
| // 1% is slightly faster than 5%, which is slightly slower than 10%. |
| // However, on a big application, this caused the memory to be exhausted, |
| // as even a 1% increase of size at each gc becomes a lot, when many gc |
| // are done. |
| // Sol 3: always garbage collect at current cardinality + 1. |
| // This solution was the fastest of the 3 solutions, and caused no memory |
| // exhaustion in the big application. |
| // |
| // With regards to cost introduced by gc: on the t2t perf test (doing only |
| // lock/unlock operations), t2t 50 10 2 was about 25% faster than the |
| // version with garbage collection. With t2t 50 20 2, my machine started |
| // to page out, and so the garbage collected version was much faster. |
| // On smaller lock sets (e.g. t2t 20 5 2, giving about 100 locks), the |
| // difference performance is insignificant (~ 0.1 s). |
| // Of course, it might be that real life programs are not well represented |
| // by t2t. |
| |
| // If ever we want to have a more sophisticated control |
| // (e.g. clo options to control the percentage increase or fixed increased), |
| // we should do it here, eg. |
| // next_gc_univ_laog = prev_next_gc_univ_laog + VG_(clo_laog_gc_fixed); |
| // Currently, we just hard-code the solution 3 above. |
| next_gc_univ_laog = prev_next_gc_univ_laog + 1; |
| |
| if (VG_(clo_stats)) |
| VG_(message) |
| (Vg_DebugMsg, |
| "univ_laog_do_GC exit seen %'8d next gc at cardinality %'10d\n", |
| (Int)seen, next_gc_univ_laog); |
| } |
| |
| |
| __attribute__((noinline)) |
| static void laog__add_edge ( Lock* src, Lock* dst ) { |
| UWord keyW; |
| LAOGLinks* links; |
| Bool presentF, presentR; |
| if (0) VG_(printf)("laog__add_edge %p %p\n", src, dst); |
| |
| /* Take the opportunity to sanity check the graph. Record in |
| presentF if there is already a src->dst mapping in this node's |
| forwards links, and presentR if there is already a src->dst |
| mapping in this node's backwards links. They should agree! |
| Also, we need to know whether the edge was already present so as |
| to decide whether or not to update the link details mapping. We |
| can compute presentF and presentR essentially for free, so may |
| as well do this always. */ |
| presentF = presentR = False; |
| |
| /* Update the out edges for src */ |
| keyW = 0; |
| links = NULL; |
| if (VG_(lookupFM)( laog, &keyW, (UWord*)&links, (UWord)src )) { |
| WordSetID outs_new; |
| tl_assert(links); |
| tl_assert(keyW == (UWord)src); |
| outs_new = HG_(addToWS)( univ_laog, links->outs, (UWord)dst ); |
| presentF = outs_new == links->outs; |
| links->outs = outs_new; |
| } else { |
| links = HG_(zalloc)("hg.lae.1", sizeof(LAOGLinks)); |
| links->inns = HG_(emptyWS)( univ_laog ); |
| links->outs = HG_(singletonWS)( univ_laog, (UWord)dst ); |
| VG_(addToFM)( laog, (UWord)src, (UWord)links ); |
| } |
| /* Update the in edges for dst */ |
| keyW = 0; |
| links = NULL; |
| if (VG_(lookupFM)( laog, &keyW, (UWord*)&links, (UWord)dst )) { |
| WordSetID inns_new; |
| tl_assert(links); |
| tl_assert(keyW == (UWord)dst); |
| inns_new = HG_(addToWS)( univ_laog, links->inns, (UWord)src ); |
| presentR = inns_new == links->inns; |
| links->inns = inns_new; |
| } else { |
| links = HG_(zalloc)("hg.lae.2", sizeof(LAOGLinks)); |
| links->inns = HG_(singletonWS)( univ_laog, (UWord)src ); |
| links->outs = HG_(emptyWS)( univ_laog ); |
| VG_(addToFM)( laog, (UWord)dst, (UWord)links ); |
| } |
| |
| tl_assert( (presentF && presentR) || (!presentF && !presentR) ); |
| |
| if (!presentF && src->acquired_at && dst->acquired_at) { |
| LAOGLinkExposition expo; |
| /* If this edge is entering the graph, and we have acquired_at |
| information for both src and dst, record those acquisition |
| points. Hence, if there is later a violation of this |
| ordering, we can show the user the two places in which the |
| required src-dst ordering was previously established. */ |
| if (0) VG_(printf)("acquire edge %#lx %#lx\n", |
| src->guestaddr, dst->guestaddr); |
| expo.src_ga = src->guestaddr; |
| expo.dst_ga = dst->guestaddr; |
| expo.src_ec = NULL; |
| expo.dst_ec = NULL; |
| tl_assert(laog_exposition); |
| if (VG_(lookupFM)( laog_exposition, NULL, NULL, (UWord)&expo )) { |
| /* we already have it; do nothing */ |
| } else { |
| LAOGLinkExposition* expo2 = HG_(zalloc)("hg.lae.3", |
| sizeof(LAOGLinkExposition)); |
| expo2->src_ga = src->guestaddr; |
| expo2->dst_ga = dst->guestaddr; |
| expo2->src_ec = src->acquired_at; |
| expo2->dst_ec = dst->acquired_at; |
| VG_(addToFM)( laog_exposition, (UWord)expo2, (UWord)NULL ); |
| } |
| } |
| |
| if (HG_(cardinalityWSU) (univ_laog) >= next_gc_univ_laog) |
| univ_laog_do_GC(); |
| } |
| |
| __attribute__((noinline)) |
| static void laog__del_edge ( Lock* src, Lock* dst ) { |
| UWord keyW; |
| LAOGLinks* links; |
| if (0) VG_(printf)("laog__del_edge enter %p %p\n", src, dst); |
| /* Update the out edges for src */ |
| keyW = 0; |
| links = NULL; |
| if (VG_(lookupFM)( laog, &keyW, (UWord*)&links, (UWord)src )) { |
| tl_assert(links); |
| tl_assert(keyW == (UWord)src); |
| links->outs = HG_(delFromWS)( univ_laog, links->outs, (UWord)dst ); |
| } |
| /* Update the in edges for dst */ |
| keyW = 0; |
| links = NULL; |
| if (VG_(lookupFM)( laog, &keyW, (UWord*)&links, (UWord)dst )) { |
| tl_assert(links); |
| tl_assert(keyW == (UWord)dst); |
| links->inns = HG_(delFromWS)( univ_laog, links->inns, (UWord)src ); |
| } |
| |
| /* Remove the exposition of src,dst (if present) */ |
| { |
| LAOGLinkExposition *fm_expo; |
| |
| LAOGLinkExposition expo; |
| expo.src_ga = src->guestaddr; |
| expo.dst_ga = dst->guestaddr; |
| expo.src_ec = NULL; |
| expo.dst_ec = NULL; |
| |
| if (VG_(delFromFM) (laog_exposition, |
| (UWord*)&fm_expo, NULL, (UWord)&expo )) { |
| HG_(free) (fm_expo); |
| } |
| } |
| |
| /* deleting edges can increase nr of of WS so check for gc. */ |
| if (HG_(cardinalityWSU) (univ_laog) >= next_gc_univ_laog) |
| univ_laog_do_GC(); |
| if (0) VG_(printf)("laog__del_edge exit\n"); |
| } |
| |
| __attribute__((noinline)) |
| static WordSetID /* in univ_laog */ laog__succs ( Lock* lk ) { |
| UWord keyW; |
| LAOGLinks* links; |
| keyW = 0; |
| links = NULL; |
| if (VG_(lookupFM)( laog, &keyW, (UWord*)&links, (UWord)lk )) { |
| tl_assert(links); |
| tl_assert(keyW == (UWord)lk); |
| return links->outs; |
| } else { |
| return HG_(emptyWS)( univ_laog ); |
| } |
| } |
| |
| __attribute__((noinline)) |
| static WordSetID /* in univ_laog */ laog__preds ( Lock* lk ) { |
| UWord keyW; |
| LAOGLinks* links; |
| keyW = 0; |
| links = NULL; |
| if (VG_(lookupFM)( laog, &keyW, (UWord*)&links, (UWord)lk )) { |
| tl_assert(links); |
| tl_assert(keyW == (UWord)lk); |
| return links->inns; |
| } else { |
| return HG_(emptyWS)( univ_laog ); |
| } |
| } |
| |
| __attribute__((noinline)) |
| static void laog__sanity_check ( const HChar* who ) { |
| UWord i, ws_size; |
| UWord* ws_words; |
| Lock* me; |
| LAOGLinks* links; |
| VG_(initIterFM)( laog ); |
| me = NULL; |
| links = NULL; |
| if (0) VG_(printf)("laog sanity check\n"); |
| while (VG_(nextIterFM)( laog, (UWord*)&me, |
| (UWord*)&links )) { |
| tl_assert(me); |
| tl_assert(links); |
| HG_(getPayloadWS)( &ws_words, &ws_size, univ_laog, links->inns ); |
| for (i = 0; i < ws_size; i++) { |
| if ( ! HG_(elemWS)( univ_laog, |
| laog__succs( (Lock*)ws_words[i] ), |
| (UWord)me )) |
| goto bad; |
| } |
| HG_(getPayloadWS)( &ws_words, &ws_size, univ_laog, links->outs ); |
| for (i = 0; i < ws_size; i++) { |
| if ( ! HG_(elemWS)( univ_laog, |
| laog__preds( (Lock*)ws_words[i] ), |
| (UWord)me )) |
| goto bad; |
| } |
| me = NULL; |
| links = NULL; |
| } |
| VG_(doneIterFM)( laog ); |
| return; |
| |
| bad: |
| VG_(printf)("laog__sanity_check(%s) FAILED\n", who); |
| laog__show(who); |
| tl_assert(0); |
| } |
| |
| /* If there is a path in laog from 'src' to any of the elements in |
| 'dst', return an arbitrarily chosen element of 'dst' reachable from |
| 'src'. If no path exist from 'src' to any element in 'dst', return |
| NULL. */ |
| __attribute__((noinline)) |
| static |
| Lock* laog__do_dfs_from_to ( Lock* src, WordSetID dsts /* univ_lsets */ ) |
| { |
| Lock* ret; |
| Word ssz; |
| XArray* stack; /* of Lock* */ |
| WordFM* visited; /* Lock* -> void, iow, Set(Lock*) */ |
| Lock* here; |
| WordSetID succs; |
| UWord succs_size, i; |
| UWord* succs_words; |
| //laog__sanity_check(); |
| |
| /* If the destination set is empty, we can never get there from |
| 'src' :-), so don't bother to try */ |
| if (HG_(isEmptyWS)( univ_lsets, dsts )) |
| return NULL; |
| |
| ret = NULL; |
| stack = VG_(newXA)( HG_(zalloc), "hg.lddft.1", HG_(free), sizeof(Lock*) ); |
| visited = VG_(newFM)( HG_(zalloc), "hg.lddft.2", HG_(free), NULL/*unboxedcmp*/ ); |
| |
| (void) VG_(addToXA)( stack, &src ); |
| |
| while (True) { |
| |
| ssz = VG_(sizeXA)( stack ); |
| |
| if (ssz == 0) { ret = NULL; break; } |
| |
| here = *(Lock**) VG_(indexXA)( stack, ssz-1 ); |
| VG_(dropTailXA)( stack, 1 ); |
| |
| if (HG_(elemWS)( univ_lsets, dsts, (UWord)here )) { ret = here; break; } |
| |
| if (VG_(lookupFM)( visited, NULL, NULL, (UWord)here )) |
| continue; |
| |
| VG_(addToFM)( visited, (UWord)here, 0 ); |
| |
| succs = laog__succs( here ); |
| HG_(getPayloadWS)( &succs_words, &succs_size, univ_laog, succs ); |
| for (i = 0; i < succs_size; i++) |
| (void) VG_(addToXA)( stack, &succs_words[i] ); |
| } |
| |
| VG_(deleteFM)( visited, NULL, NULL ); |
| VG_(deleteXA)( stack ); |
| return ret; |
| } |
| |
| |
| /* Thread 'thr' is acquiring 'lk'. Check for inconsistent ordering |
| between 'lk' and the locks already held by 'thr' and issue a |
| complaint if so. Also, update the ordering graph appropriately. |
| */ |
| __attribute__((noinline)) |
| static void laog__pre_thread_acquires_lock ( |
| Thread* thr, /* NB: BEFORE lock is added */ |
| Lock* lk |
| ) |
| { |
| UWord* ls_words; |
| UWord ls_size, i; |
| Lock* other; |
| |
| /* It may be that 'thr' already holds 'lk' and is recursively |
| relocking in. In this case we just ignore the call. */ |
| /* NB: univ_lsets really is correct here */ |
| if (HG_(elemWS)( univ_lsets, thr->locksetA, (UWord)lk )) |
| return; |
| |
| /* First, the check. Complain if there is any path in laog from lk |
| to any of the locks already held by thr, since if any such path |
| existed, it would mean that previously lk was acquired before |
| (rather than after, as we are doing here) at least one of those |
| locks. |
| */ |
| other = laog__do_dfs_from_to(lk, thr->locksetA); |
| if (other) { |
| LAOGLinkExposition key, *found; |
| /* So we managed to find a path lk --*--> other in the graph, |
| which implies that 'lk' should have been acquired before |
| 'other' but is in fact being acquired afterwards. We present |
| the lk/other arguments to record_error_LockOrder in the order |
| in which they should have been acquired. */ |
| /* Go look in the laog_exposition mapping, to find the allocation |
| points for this edge, so we can show the user. */ |
| key.src_ga = lk->guestaddr; |
| key.dst_ga = other->guestaddr; |
| key.src_ec = NULL; |
| key.dst_ec = NULL; |
| found = NULL; |
| if (VG_(lookupFM)( laog_exposition, |
| (UWord*)&found, NULL, (UWord)&key )) { |
| tl_assert(found != &key); |
| tl_assert(found->src_ga == key.src_ga); |
| tl_assert(found->dst_ga == key.dst_ga); |
| tl_assert(found->src_ec); |
| tl_assert(found->dst_ec); |
| HG_(record_error_LockOrder)( |
| thr, lk->guestaddr, other->guestaddr, |
| found->src_ec, found->dst_ec, other->acquired_at ); |
| } else { |
| /* Hmm. This can't happen (can it?) */ |
| /* Yes, it can happen: see tests/tc14_laog_dinphils. |
| Imagine we have 3 philosophers A B C, and the forks |
| between them: |
| |
| C |
| |
| fCA fBC |
| |
| A fAB B |
| |
| Let's have the following actions: |
| A takes fCA,fAB |
| A releases fCA,fAB |
| B takes fAB,fBC |
| B releases fAB,fBC |
| C takes fBC,fCA |
| C releases fBC,fCA |
| |
| Helgrind will report a lock order error when C takes fCA. |
| Effectively, we have a deadlock if the following |
| sequence is done: |
| A takes fCA |
| B takes fAB |
| C takes fBC |
| |
| The error reported is: |
| Observed (incorrect) order fBC followed by fCA |
| but the stack traces that have established the required order |
| are not given. |
| |
| This is because there is no pair (fCA, fBC) in laog exposition : |
| the laog_exposition records all pairs of locks between a new lock |
| taken by a thread and all the already taken locks. |
| So, there is no laog_exposition (fCA, fBC) as no thread ever |
| first locked fCA followed by fBC. |
| |
| In other words, when the deadlock cycle involves more than |
| two locks, then helgrind does not report the sequence of |
| operations that created the cycle. |
| |
| However, we can report the current stack trace (where |
| lk is being taken), and the stack trace where other was acquired: |
| Effectively, the variable 'other' contains a lock currently |
| held by this thread, with its 'acquired_at'. */ |
| |
| HG_(record_error_LockOrder)( |
| thr, lk->guestaddr, other->guestaddr, |
| NULL, NULL, other->acquired_at ); |
| } |
| } |
| |
| /* Second, add to laog the pairs |
| (old, lk) | old <- locks already held by thr |
| Since both old and lk are currently held by thr, their acquired_at |
| fields must be non-NULL. |
| */ |
| tl_assert(lk->acquired_at); |
| HG_(getPayloadWS)( &ls_words, &ls_size, univ_lsets, thr->locksetA ); |
| for (i = 0; i < ls_size; i++) { |
| Lock* old = (Lock*)ls_words[i]; |
| tl_assert(old->acquired_at); |
| laog__add_edge( old, lk ); |
| } |
| |
| /* Why "except_Locks" ? We're here because a lock is being |
| acquired by a thread, and we're in an inconsistent state here. |
| See the call points in evhH__post_thread_{r,w}_acquires_lock. |
| When called in this inconsistent state, locks__sanity_check duly |
| barfs. */ |
| if (HG_(clo_sanity_flags) & SCE_LAOG) |
| all_except_Locks__sanity_check("laog__pre_thread_acquires_lock-post"); |
| } |
| |
| /* Allocates a duplicate of words. Caller must HG_(free) the result. */ |
| static UWord* UWordV_dup(UWord* words, Word words_size) |
| { |
| UInt i; |
| |
| if (words_size == 0) |
| return NULL; |
| |
| UWord *dup = HG_(zalloc) ("hg.dup.1", (SizeT) words_size * sizeof(UWord)); |
| |
| for (i = 0; i < words_size; i++) |
| dup[i] = words[i]; |
| |
| return dup; |
| } |
| |
| /* Delete from 'laog' any pair mentioning a lock in locksToDelete */ |
| |
| __attribute__((noinline)) |
| static void laog__handle_one_lock_deletion ( Lock* lk ) |
| { |
| WordSetID preds, succs; |
| UWord preds_size, succs_size, i, j; |
| UWord *preds_words, *succs_words; |
| |
| preds = laog__preds( lk ); |
| succs = laog__succs( lk ); |
| |
| // We need to duplicate the payload, as these can be garbage collected |
| // during the del/add operations below. |
| HG_(getPayloadWS)( &preds_words, &preds_size, univ_laog, preds ); |
| preds_words = UWordV_dup(preds_words, preds_size); |
| |
| HG_(getPayloadWS)( &succs_words, &succs_size, univ_laog, succs ); |
| succs_words = UWordV_dup(succs_words, succs_size); |
| |
| for (i = 0; i < preds_size; i++) |
| laog__del_edge( (Lock*)preds_words[i], lk ); |
| |
| for (j = 0; j < succs_size; j++) |
| laog__del_edge( lk, (Lock*)succs_words[j] ); |
| |
| for (i = 0; i < preds_size; i++) { |
| for (j = 0; j < succs_size; j++) { |
| if (preds_words[i] != succs_words[j]) { |
| /* This can pass unlocked locks to laog__add_edge, since |
| we're deleting stuff. So their acquired_at fields may |
| be NULL. */ |
| laog__add_edge( (Lock*)preds_words[i], (Lock*)succs_words[j] ); |
| } |
| } |
| } |
| |
| if (preds_words) |
| HG_(free) (preds_words); |
| if (succs_words) |
| HG_(free) (succs_words); |
| |
| // Remove lk information from laog links FM |
| { |
| LAOGLinks *links; |
| Lock* linked_lk; |
| |
| if (VG_(delFromFM) (laog, |
| (UWord*)&linked_lk, (UWord*)&links, (UWord)lk)) { |
| tl_assert (linked_lk == lk); |
| HG_(free) (links); |
| } |
| } |
| /* FIXME ??? What about removing lock lk data from EXPOSITION ??? */ |
| } |
| |
| //__attribute__((noinline)) |
| //static void laog__handle_lock_deletions ( |
| // WordSetID /* in univ_laog */ locksToDelete |
| // ) |
| //{ |
| // Word i, ws_size; |
| // UWord* ws_words; |
| // |
| // |
| // HG_(getPayloadWS)( &ws_words, &ws_size, univ_lsets, locksToDelete ); |
| // UWordV_dup call needed here ... |
| // for (i = 0; i < ws_size; i++) |
| // laog__handle_one_lock_deletion( (Lock*)ws_words[i] ); |
| // |
| // if (HG_(clo_sanity_flags) & SCE_LAOG) |
| // all__sanity_check("laog__handle_lock_deletions-post"); |
| //} |
| |
| |
| /*--------------------------------------------------------------*/ |
| /*--- Malloc/free replacements ---*/ |
| /*--------------------------------------------------------------*/ |
| |
| typedef |
| struct { |
| void* next; /* required by m_hashtable */ |
| Addr payload; /* ptr to actual block */ |
| SizeT szB; /* size requested */ |
| ExeContext* where; /* where it was allocated */ |
| Thread* thr; /* allocating thread */ |
| } |
| MallocMeta; |
| |
| /* A hash table of MallocMetas, used to track malloc'd blocks |
| (obviously). */ |
| static VgHashTable hg_mallocmeta_table = NULL; |
| |
| |
| static MallocMeta* new_MallocMeta ( void ) { |
| MallocMeta* md = HG_(zalloc)( "hg.new_MallocMeta.1", sizeof(MallocMeta) ); |
| tl_assert(md); |
| return md; |
| } |
| static void delete_MallocMeta ( MallocMeta* md ) { |
| HG_(free)(md); |
| } |
| |
| |
| /* Allocate a client block and set up the metadata for it. */ |
| |
| static |
| void* handle_alloc ( ThreadId tid, |
| SizeT szB, SizeT alignB, Bool is_zeroed ) |
| { |
| Addr p; |
| MallocMeta* md; |
| |
| tl_assert( ((SSizeT)szB) >= 0 ); |
| p = (Addr)VG_(cli_malloc)(alignB, szB); |
| if (!p) { |
| return NULL; |
| } |
| if (is_zeroed) |
| VG_(memset)((void*)p, 0, szB); |
| |
| /* Note that map_threads_lookup must succeed (cannot assert), since |
| memory can only be allocated by currently alive threads, hence |
| they must have an entry in map_threads. */ |
| md = new_MallocMeta(); |
| md->payload = p; |
| md->szB = szB; |
| md->where = VG_(record_ExeContext)( tid, 0 ); |
| md->thr = map_threads_lookup( tid ); |
| |
| VG_(HT_add_node)( hg_mallocmeta_table, (VgHashNode*)md ); |
| |
| /* Tell the lower level memory wranglers. */ |
| evh__new_mem_heap( p, szB, is_zeroed ); |
| |
| return (void*)p; |
| } |
| |
| /* Re the checks for less-than-zero (also in hg_cli__realloc below): |
| Cast to a signed type to catch any unexpectedly negative args. |
| We're assuming here that the size asked for is not greater than |
| 2^31 bytes (for 32-bit platforms) or 2^63 bytes (for 64-bit |
| platforms). */ |
| static void* hg_cli__malloc ( ThreadId tid, SizeT n ) { |
| if (((SSizeT)n) < 0) return NULL; |
| return handle_alloc ( tid, n, VG_(clo_alignment), |
| /*is_zeroed*/False ); |
| } |
| static void* hg_cli____builtin_new ( ThreadId tid, SizeT n ) { |
| if (((SSizeT)n) < 0) return NULL; |
| return handle_alloc ( tid, n, VG_(clo_alignment), |
| /*is_zeroed*/False ); |
| } |
| static void* hg_cli____builtin_vec_new ( ThreadId tid, SizeT n ) { |
| if (((SSizeT)n) < 0) return NULL; |
| return handle_alloc ( tid, n, VG_(clo_alignment), |
| /*is_zeroed*/False ); |
| } |
| static void* hg_cli__memalign ( ThreadId tid, SizeT align, SizeT n ) { |
| if (((SSizeT)n) < 0) return NULL; |
| return handle_alloc ( tid, n, align, |
| /*is_zeroed*/False ); |
| } |
| static void* hg_cli__calloc ( ThreadId tid, SizeT nmemb, SizeT size1 ) { |
| if ( ((SSizeT)nmemb) < 0 || ((SSizeT)size1) < 0 ) return NULL; |
| return handle_alloc ( tid, nmemb*size1, VG_(clo_alignment), |
| /*is_zeroed*/True ); |
| } |
| |
| |
| /* Free a client block, including getting rid of the relevant |
| metadata. */ |
| |
| static void handle_free ( ThreadId tid, void* p ) |
| { |
| MallocMeta *md, *old_md; |
| SizeT szB; |
| |
| /* First see if we can find the metadata for 'p'. */ |
| md = (MallocMeta*) VG_(HT_lookup)( hg_mallocmeta_table, (UWord)p ); |
| if (!md) |
| return; /* apparently freeing a bogus address. Oh well. */ |
| |
| tl_assert(md->payload == (Addr)p); |
| szB = md->szB; |
| |
| /* Nuke the metadata block */ |
| old_md = (MallocMeta*) |
| VG_(HT_remove)( hg_mallocmeta_table, (UWord)p ); |
| tl_assert(old_md); /* it must be present - we just found it */ |
| tl_assert(old_md == md); |
| tl_assert(old_md->payload == (Addr)p); |
| |
| VG_(cli_free)((void*)old_md->payload); |
| delete_MallocMeta(old_md); |
| |
| /* Tell the lower level memory wranglers. */ |
| evh__die_mem_heap( (Addr)p, szB ); |
| } |
| |
| static void hg_cli__free ( ThreadId tid, void* p ) { |
| handle_free(tid, p); |
| } |
| static void hg_cli____builtin_delete ( ThreadId tid, void* p ) { |
| handle_free(tid, p); |
| } |
| static void hg_cli____builtin_vec_delete ( ThreadId tid, void* p ) { |
| handle_free(tid, p); |
| } |
| |
| |
| static void* hg_cli__realloc ( ThreadId tid, void* payloadV, SizeT new_size ) |
| { |
| MallocMeta *md, *md_new, *md_tmp; |
| SizeT i; |
| |
| Addr payload = (Addr)payloadV; |
| |
| if (((SSizeT)new_size) < 0) return NULL; |
| |
| md = (MallocMeta*) VG_(HT_lookup)( hg_mallocmeta_table, (UWord)payload ); |
| if (!md) |
| return NULL; /* apparently realloc-ing a bogus address. Oh well. */ |
| |
| tl_assert(md->payload == payload); |
| |
| if (md->szB == new_size) { |
| /* size unchanged */ |
| md->where = VG_(record_ExeContext)(tid, 0); |
| return payloadV; |
| } |
| |
| if (md->szB > new_size) { |
| /* new size is smaller */ |
| md->szB = new_size; |
| md->where = VG_(record_ExeContext)(tid, 0); |
| evh__die_mem_heap( md->payload + new_size, md->szB - new_size ); |
| return payloadV; |
| } |
| |
| /* else */ { |
| /* new size is bigger */ |
| Addr p_new = (Addr)VG_(cli_malloc)(VG_(clo_alignment), new_size); |
| |
| /* First half kept and copied, second half new */ |
| // FIXME: shouldn't we use a copier which implements the |
| // memory state machine? |
| evh__copy_mem( payload, p_new, md->szB ); |
| evh__new_mem_heap ( p_new + md->szB, new_size - md->szB, |
| /*inited*/False ); |
| /* FIXME: can anything funny happen here? specifically, if the |
| old range contained a lock, then die_mem_heap will complain. |
| Is that the correct behaviour? Not sure. */ |
| evh__die_mem_heap( payload, md->szB ); |
| |
| /* Copy from old to new */ |
| for (i = 0; i < md->szB; i++) |
| ((UChar*)p_new)[i] = ((UChar*)payload)[i]; |
| |
| /* Because the metadata hash table is index by payload address, |
| we have to get rid of the old hash table entry and make a new |
| one. We can't just modify the existing metadata in place, |
| because then it would (almost certainly) be in the wrong hash |
| chain. */ |
| md_new = new_MallocMeta(); |
| *md_new = *md; |
| |
| md_tmp = VG_(HT_remove)( hg_mallocmeta_table, payload ); |
| tl_assert(md_tmp); |
| tl_assert(md_tmp == md); |
| |
| VG_(cli_free)((void*)md->payload); |
| delete_MallocMeta(md); |
| |
| /* Update fields */ |
| md_new->where = VG_(record_ExeContext)( tid, 0 ); |
| md_new->szB = new_size; |
| md_new->payload = p_new; |
| md_new->thr = map_threads_lookup( tid ); |
| |
| /* and add */ |
| VG_(HT_add_node)( hg_mallocmeta_table, (VgHashNode*)md_new ); |
| |
| return (void*)p_new; |
| } |
| } |
| |
| static SizeT hg_cli_malloc_usable_size ( ThreadId tid, void* p ) |
| { |
| MallocMeta *md = VG_(HT_lookup)( hg_mallocmeta_table, (UWord)p ); |
| |
| // There may be slop, but pretend there isn't because only the asked-for |
| // area will have been shadowed properly. |
| return ( md ? md->szB : 0 ); |
| } |
| |
| |
| /* For error creation: map 'data_addr' to a malloc'd chunk, if any. |
| Slow linear search. With a bit of hash table help if 'data_addr' |
| is either the start of a block or up to 15 word-sized steps along |
| from the start of a block. */ |
| |
| static inline Bool addr_is_in_MM_Chunk( MallocMeta* mm, Addr a ) |
| { |
| /* Accept 'a' as within 'mm' if 'mm's size is zero and 'a' points |
| right at it. */ |
| if (UNLIKELY(mm->szB == 0 && a == mm->payload)) |
| return True; |
| /* else normal interval rules apply */ |
| if (LIKELY(a < mm->payload)) return False; |
| if (LIKELY(a >= mm->payload + mm->szB)) return False; |
| return True; |
| } |
| |
| Bool HG_(mm_find_containing_block)( /*OUT*/ExeContext** where, |
| /*OUT*/Addr* payload, |
| /*OUT*/SizeT* szB, |
| Addr data_addr ) |
| { |
| MallocMeta* mm; |
| Int i; |
| const Int n_fast_check_words = 16; |
| |
| /* First, do a few fast searches on the basis that data_addr might |
| be exactly the start of a block or up to 15 words inside. This |
| can happen commonly via the creq |
| _VG_USERREQ__HG_CLEAN_MEMORY_HEAPBLOCK. */ |
| for (i = 0; i < n_fast_check_words; i++) { |
| mm = VG_(HT_lookup)( hg_mallocmeta_table, |
| data_addr - (UWord)(UInt)i * sizeof(UWord) ); |
| if (UNLIKELY(mm && addr_is_in_MM_Chunk(mm, data_addr))) |
| goto found; |
| } |
| |
| /* Well, this totally sucks. But without using an interval tree or |
| some such, it's hard to see how to do better. We have to check |
| every block in the entire table. */ |
| VG_(HT_ResetIter)(hg_mallocmeta_table); |
| while ( (mm = VG_(HT_Next)(hg_mallocmeta_table)) ) { |
| if (UNLIKELY(addr_is_in_MM_Chunk(mm, data_addr))) |
| goto found; |
| } |
| |
| /* Not found. Bah. */ |
| return False; |
| /*NOTREACHED*/ |
| |
| found: |
| tl_assert(mm); |
| tl_assert(addr_is_in_MM_Chunk(mm, data_addr)); |
| if (where) *where = mm->where; |
| if (payload) *payload = mm->payload; |
| if (szB) *szB = mm->szB; |
| return True; |
| } |
| |
| |
| /*--------------------------------------------------------------*/ |
| /*--- Instrumentation ---*/ |
| /*--------------------------------------------------------------*/ |
| |
| #define unop(_op, _arg1) IRExpr_Unop((_op),(_arg1)) |
| #define binop(_op, _arg1, _arg2) IRExpr_Binop((_op),(_arg1),(_arg2)) |
| #define mkexpr(_tmp) IRExpr_RdTmp((_tmp)) |
| #define mkU32(_n) IRExpr_Const(IRConst_U32(_n)) |
| #define mkU64(_n) IRExpr_Const(IRConst_U64(_n)) |
| #define assign(_t, _e) IRStmt_WrTmp((_t), (_e)) |
| |
| /* This takes and returns atoms, of course. Not full IRExprs. */ |
| static IRExpr* mk_And1 ( IRSB* sbOut, IRExpr* arg1, IRExpr* arg2 ) |
| { |
| tl_assert(arg1 && arg2); |
| tl_assert(isIRAtom(arg1)); |
| tl_assert(isIRAtom(arg2)); |
| /* Generate 32to1(And32(1Uto32(arg1), 1Uto32(arg2))). Appalling |
| code, I know. */ |
| IRTemp wide1 = newIRTemp(sbOut->tyenv, Ity_I32); |
| IRTemp wide2 = newIRTemp(sbOut->tyenv, Ity_I32); |
| IRTemp anded = newIRTemp(sbOut->tyenv, Ity_I32); |
| IRTemp res = newIRTemp(sbOut->tyenv, Ity_I1); |
| addStmtToIRSB(sbOut, assign(wide1, unop(Iop_1Uto32, arg1))); |
| addStmtToIRSB(sbOut, assign(wide2, unop(Iop_1Uto32, arg2))); |
| addStmtToIRSB(sbOut, assign(anded, binop(Iop_And32, mkexpr(wide1), |
| mkexpr(wide2)))); |
| addStmtToIRSB(sbOut, assign(res, unop(Iop_32to1, mkexpr(anded)))); |
| return mkexpr(res); |
| } |
| |
| static void instrument_mem_access ( IRSB* sbOut, |
| IRExpr* addr, |
| Int szB, |
| Bool isStore, |
| Int hWordTy_szB, |
| Int goff_sp, |
| IRExpr* guard ) /* NULL => True */ |
| { |
| IRType tyAddr = Ity_INVALID; |
| const HChar* hName = NULL; |
| void* hAddr = NULL; |
| Int regparms = 0; |
| IRExpr** argv = NULL; |
| IRDirty* di = NULL; |
| |
| // THRESH is the size of the window above SP (well, |
| // mostly above) that we assume implies a stack reference. |
| const Int THRESH = 4096 * 4; // somewhat arbitrary |
| const Int rz_szB = VG_STACK_REDZONE_SZB; |
| |
| tl_assert(isIRAtom(addr)); |
| tl_assert(hWordTy_szB == 4 || hWordTy_szB == 8); |
| |
| tyAddr = typeOfIRExpr( sbOut->tyenv, addr ); |
| tl_assert(tyAddr == Ity_I32 || tyAddr == Ity_I64); |
| |
| /* So the effective address is in 'addr' now. */ |
| regparms = 1; // unless stated otherwise |
| if (isStore) { |
| switch (szB) { |
| case 1: |
| hName = "evh__mem_help_cwrite_1"; |
| hAddr = &evh__mem_help_cwrite_1; |
| argv = mkIRExprVec_1( addr ); |
| break; |
| case 2: |
| hName = "evh__mem_help_cwrite_2"; |
| hAddr = &evh__mem_help_cwrite_2; |
| argv = mkIRExprVec_1( addr ); |
| break; |
| case 4: |
| hName = "evh__mem_help_cwrite_4"; |
| hAddr = &evh__mem_help_cwrite_4; |
| argv = mkIRExprVec_1( addr ); |
| break; |
| case 8: |
| hName = "evh__mem_help_cwrite_8"; |
| hAddr = &evh__mem_help_cwrite_8; |
| argv = mkIRExprVec_1( addr ); |
| break; |
| default: |
| tl_assert(szB > 8 && szB <= 512); /* stay sane */ |
| regparms = 2; |
| hName = "evh__mem_help_cwrite_N"; |
| hAddr = &evh__mem_help_cwrite_N; |
| argv = mkIRExprVec_2( addr, mkIRExpr_HWord( szB )); |
| break; |
| } |
| } else { |
| switch (szB) { |
| case 1: |
| hName = "evh__mem_help_cread_1"; |
| hAddr = &evh__mem_help_cread_1; |
| argv = mkIRExprVec_1( addr ); |
| break; |
| case 2: |
| hName = "evh__mem_help_cread_2"; |
| hAddr = &evh__mem_help_cread_2; |
| argv = mkIRExprVec_1( addr ); |
| break; |
| case 4: |
| hName = "evh__mem_help_cread_4"; |
| hAddr = &evh__mem_help_cread_4; |
| argv = mkIRExprVec_1( addr ); |
| break; |
| case 8: |
| hName = "evh__mem_help_cread_8"; |
| hAddr = &evh__mem_help_cread_8; |
| argv = mkIRExprVec_1( addr ); |
| break; |
| default: |
| tl_assert(szB > 8 && szB <= 512); /* stay sane */ |
| regparms = 2; |
| hName = "evh__mem_help_cread_N"; |
| hAddr = &evh__mem_help_cread_N; |
| argv = mkIRExprVec_2( addr, mkIRExpr_HWord( szB )); |
| break; |
| } |
| } |
| |
| /* Create the helper. */ |
| tl_assert(hName); |
| tl_assert(hAddr); |
| tl_assert(argv); |
| di = unsafeIRDirty_0_N( regparms, |
| hName, VG_(fnptr_to_fnentry)( hAddr ), |
| argv ); |
| |
| if (! HG_(clo_check_stack_refs)) { |
| /* We're ignoring memory references which are (obviously) to the |
| stack. In fact just skip stack refs that are within 4 pages |
| of SP (SP - the redzone, really), as that's simple, easy, and |
| filters out most stack references. */ |
| /* Generate the guard condition: "(addr - (SP - RZ)) >u N", for |
| some arbitrary N. If that is true then addr is outside the |
| range (SP - RZ .. SP + N - RZ). If N is smallish (a few |
| pages) then we can say addr is within a few pages of SP and |
| so can't possibly be a heap access, and so can be skipped. |
| |
| Note that the condition simplifies to |
| (addr - SP + RZ) >u N |
| which generates better code in x86/amd64 backends, but it does |
| not unfortunately simplify to |
| (addr - SP) >u (N - RZ) |
| (would be beneficial because N - RZ is a constant) because |
| wraparound arithmetic messes up the comparison. eg. |
| 20 >u 10 == True, |
| but (20 - 15) >u (10 - 15) == 5 >u (MAXINT-5) == False. |
| */ |
| IRTemp sp = newIRTemp(sbOut->tyenv, tyAddr); |
| addStmtToIRSB( sbOut, assign(sp, IRExpr_Get(goff_sp, tyAddr))); |
| |
| /* "addr - SP" */ |
| IRTemp addr_minus_sp = newIRTemp(sbOut->tyenv, tyAddr); |
| addStmtToIRSB( |
| sbOut, |
| assign(addr_minus_sp, |
| tyAddr == Ity_I32 |
| ? binop(Iop_Sub32, addr, mkexpr(sp)) |
| : binop(Iop_Sub64, addr, mkexpr(sp))) |
| ); |
| |
| /* "addr - SP + RZ" */ |
| IRTemp diff = newIRTemp(sbOut->tyenv, tyAddr); |
| addStmtToIRSB( |
| sbOut, |
| assign(diff, |
| tyAddr == Ity_I32 |
| ? binop(Iop_Add32, mkexpr(addr_minus_sp), mkU32(rz_szB)) |
| : binop(Iop_Add64, mkexpr(addr_minus_sp), mkU64(rz_szB))) |
| ); |
| |
| /* guardA == "guard on the address" */ |
| IRTemp guardA = newIRTemp(sbOut->tyenv, Ity_I1); |
| addStmtToIRSB( |
| sbOut, |
| assign(guardA, |
| tyAddr == Ity_I32 |
| ? binop(Iop_CmpLT32U, mkU32(THRESH), mkexpr(diff)) |
| : binop(Iop_CmpLT64U, mkU64(THRESH), mkexpr(diff))) |
| ); |
| di->guard = mkexpr(guardA); |
| } |
| |
| /* If there's a guard on the access itself (as supplied by the |
| caller of this routine), we need to AND that in to any guard we |
| might already have. */ |
| if (guard) { |
| di->guard = mk_And1(sbOut, di->guard, guard); |
| } |
| |
| /* Add the helper. */ |
| addStmtToIRSB( sbOut, IRStmt_Dirty(di) ); |
| } |
| |
| |
| /* Figure out if GA is a guest code address in the dynamic linker, and |
| if so return True. Otherwise (and in case of any doubt) return |
| False. (sidedly safe w/ False as the safe value) */ |
| static Bool is_in_dynamic_linker_shared_object( Addr64 ga ) |
| { |
| DebugInfo* dinfo; |
| const HChar* soname; |
| if (0) return False; |
| |
| dinfo = VG_(find_DebugInfo)( (Addr)ga ); |
| if (!dinfo) return False; |
| |
| soname = VG_(DebugInfo_get_soname)(dinfo); |
| tl_assert(soname); |
| if (0) VG_(printf)("%s\n", soname); |
| |
| # if defined(VGO_linux) |
| if (VG_STREQ(soname, VG_U_LD_LINUX_SO_3)) return True; |
| if (VG_STREQ(soname, VG_U_LD_LINUX_SO_2)) return True; |
| if (VG_STREQ(soname, VG_U_LD_LINUX_X86_64_SO_2)) return True; |
| if (VG_STREQ(soname, VG_U_LD64_SO_1)) return True; |
| if (VG_STREQ(soname, VG_U_LD_SO_1)) return True; |
| # elif defined(VGO_darwin) |
| if (VG_STREQ(soname, VG_U_DYLD)) return True; |
| # else |
| # error "Unsupported OS" |
| # endif |
| return False; |
| } |
| |
| static |
| IRSB* hg_instrument ( VgCallbackClosure* closure, |
| IRSB* bbIn, |
| VexGuestLayout* layout, |
| VexGuestExtents* vge, |
| VexArchInfo* archinfo_host, |
| IRType gWordTy, IRType hWordTy ) |
| { |
| Int i; |
| IRSB* bbOut; |
| Addr64 cia; /* address of current insn */ |
| IRStmt* st; |
| Bool inLDSO = False; |
| Addr64 inLDSOmask4K = 1; /* mismatches on first check */ |
| |
| const Int goff_sp = layout->offset_SP; |
| |
| if (gWordTy != hWordTy) { |
| /* We don't currently support this case. */ |
| VG_(tool_panic)("host/guest word size mismatch"); |
| } |
| |
| if (VKI_PAGE_SIZE < 4096 || VG_(log2)(VKI_PAGE_SIZE) == -1) { |
| VG_(tool_panic)("implausible or too-small VKI_PAGE_SIZE"); |
| } |
| |
| /* Set up BB */ |
| bbOut = emptyIRSB(); |
| bbOut->tyenv = deepCopyIRTypeEnv(bbIn->tyenv); |
| bbOut->next = deepCopyIRExpr(bbIn->next); |
| bbOut->jumpkind = bbIn->jumpkind; |
| bbOut->offsIP = bbIn->offsIP; |
| |
| // Copy verbatim any IR preamble preceding the first IMark |
| i = 0; |
| while (i < bbIn->stmts_used && bbIn->stmts[i]->tag != Ist_IMark) { |
| addStmtToIRSB( bbOut, bbIn->stmts[i] ); |
| i++; |
| } |
| |
| // Get the first statement, and initial cia from it |
| tl_assert(bbIn->stmts_used > 0); |
| tl_assert(i < bbIn->stmts_used); |
| st = bbIn->stmts[i]; |
| tl_assert(Ist_IMark == st->tag); |
| cia = st->Ist.IMark.addr; |
| st = NULL; |
| |
| for (/*use current i*/; i < bbIn->stmts_used; i++) { |
| st = bbIn->stmts[i]; |
| tl_assert(st); |
| tl_assert(isFlatIRStmt(st)); |
| switch (st->tag) { |
| case Ist_NoOp: |
| case Ist_AbiHint: |
| case Ist_Put: |
| case Ist_PutI: |
| case Ist_Exit: |
| /* None of these can contain any memory references. */ |
| break; |
| |
| case Ist_IMark: |
| /* no mem refs, but note the insn address. */ |
| cia = st->Ist.IMark.addr; |
| /* Don't instrument the dynamic linker. It generates a |
| lot of races which we just expensively suppress, so |
| it's pointless. |
| |
| Avoid flooding is_in_dynamic_linker_shared_object with |
| requests by only checking at transitions between 4K |
| pages. */ |
| if ((cia & ~(Addr64)0xFFF) != inLDSOmask4K) { |
| if (0) VG_(printf)("NEW %#lx\n", (Addr)cia); |
| inLDSOmask4K = cia & ~(Addr64)0xFFF; |
| inLDSO = is_in_dynamic_linker_shared_object(cia); |
| } else { |
| if (0) VG_(printf)("old %#lx\n", (Addr)cia); |
| } |
| break; |
| |
| case Ist_MBE: |
| switch (st->Ist.MBE.event) { |
| case Imbe_Fence: |
| break; /* not interesting */ |
| default: |
| goto unhandled; |
| } |
| break; |
| |
| case Ist_CAS: { |
| /* Atomic read-modify-write cycle. Just pretend it's a |
| read. */ |
| IRCAS* cas = st->Ist.CAS.details; |
| Bool isDCAS = cas->oldHi != IRTemp_INVALID; |
| if (isDCAS) { |
| tl_assert(cas->expdHi); |
| tl_assert(cas->dataHi); |
| } else { |
| tl_assert(!cas->expdHi); |
| tl_assert(!cas->dataHi); |
| } |
| /* Just be boring about it. */ |
| if (!inLDSO) { |
| instrument_mem_access( |
| bbOut, |
| cas->addr, |
| (isDCAS ? 2 : 1) |
| * sizeofIRType(typeOfIRExpr(bbIn->tyenv, cas->dataLo)), |
| False/*!isStore*/, |
| sizeofIRType(hWordTy), goff_sp, |
| NULL/*no-guard*/ |
| ); |
| } |
| break; |
| } |
| |
| case Ist_LLSC: { |
| /* We pretend store-conditionals don't exist, viz, ignore |
| them. Whereas load-linked's are treated the same as |
| normal loads. */ |
| IRType dataTy; |
| if (st->Ist.LLSC.storedata == NULL) { |
| /* LL */ |
| dataTy = typeOfIRTemp(bbIn->tyenv, st->Ist.LLSC.result); |
| if (!inLDSO) { |
| instrument_mem_access( |
| bbOut, |
| st->Ist.LLSC.addr, |
| sizeofIRType(dataTy), |
| False/*!isStore*/, |
| sizeofIRType(hWordTy), goff_sp, |
| NULL/*no-guard*/ |
| ); |
| } |
| } else { |
| /* SC */ |
| /*ignore */ |
| } |
| break; |
| } |
| |
| case Ist_Store: |
| if (!inLDSO) { |
| instrument_mem_access( |
| bbOut, |
| st->Ist.Store.addr, |
| sizeofIRType(typeOfIRExpr(bbIn->tyenv, st->Ist.Store.data)), |
| True/*isStore*/, |
| sizeofIRType(hWordTy), goff_sp, |
| NULL/*no-guard*/ |
| ); |
| } |
| break; |
| |
| case Ist_StoreG: { |
| IRStoreG* sg = st->Ist.StoreG.details; |
| IRExpr* data = sg->data; |
| IRExpr* addr = sg->addr; |
| IRType type = typeOfIRExpr(bbIn->tyenv, data); |
| tl_assert(type != Ity_INVALID); |
| instrument_mem_access( bbOut, addr, sizeofIRType(type), |
| True/*isStore*/, |
| sizeofIRType(hWordTy), |
| goff_sp, sg->guard ); |
| break; |
| } |
| |
| case Ist_LoadG: { |
| IRLoadG* lg = st->Ist.LoadG.details; |
| IRType type = Ity_INVALID; /* loaded type */ |
| IRType typeWide = Ity_INVALID; /* after implicit widening */ |
| IRExpr* addr = lg->addr; |
| typeOfIRLoadGOp(lg->cvt, &typeWide, &type); |
| tl_assert(type != Ity_INVALID); |
| instrument_mem_access( bbOut, addr, sizeofIRType(type), |
| False/*!isStore*/, |
| sizeofIRType(hWordTy), |
| goff_sp, lg->guard ); |
| break; |
| } |
| |
| case Ist_WrTmp: { |
| IRExpr* data = st->Ist.WrTmp.data; |
| if (data->tag == Iex_Load) { |
| if (!inLDSO) { |
| instrument_mem_access( |
| bbOut, |
| data->Iex.Load.addr, |
| sizeofIRType(data->Iex.Load.ty), |
| False/*!isStore*/, |
| sizeofIRType(hWordTy), goff_sp, |
| NULL/*no-guard*/ |
| ); |
| } |
| } |
| break; |
| } |
| |
| case Ist_Dirty: { |
| Int dataSize; |
| IRDirty* d = st->Ist.Dirty.details; |
| if (d->mFx != Ifx_None) { |
| /* This dirty helper accesses memory. Collect the |
| details. */ |
| tl_assert(d->mAddr != NULL); |
| tl_assert(d->mSize != 0); |
| dataSize = d->mSize; |
| if (d->mFx == Ifx_Read || d->mFx == Ifx_Modify) { |
| if (!inLDSO) { |
| instrument_mem_access( |
| bbOut, d->mAddr, dataSize, False/*!isStore*/, |
| sizeofIRType(hWordTy), goff_sp, NULL/*no-guard*/ |
| ); |
| } |
| } |
| if (d->mFx == Ifx_Write || d->mFx == Ifx_Modify) { |
| if (!inLDSO) { |
| instrument_mem_access( |
| bbOut, d->mAddr, dataSize, True/*isStore*/, |
| sizeofIRType(hWordTy), goff_sp, NULL/*no-guard*/ |
| ); |
| } |
| } |
| } else { |
| tl_assert(d->mAddr == NULL); |
| tl_assert(d->mSize == 0); |
| } |
| break; |
| } |
| |
| default: |
| unhandled: |
| ppIRStmt(st); |
| tl_assert(0); |
| |
| } /* switch (st->tag) */ |
| |
| addStmtToIRSB( bbOut, st ); |
| } /* iterate over bbIn->stmts */ |
| |
| return bbOut; |
| } |
| |
| #undef binop |
| #undef mkexpr |
| #undef mkU32 |
| #undef mkU64 |
| #undef assign |
| |
| |
| /*----------------------------------------------------------------*/ |
| /*--- Client requests ---*/ |
| /*----------------------------------------------------------------*/ |
| |
| /* Sheesh. Yet another goddam finite map. */ |
| static WordFM* map_pthread_t_to_Thread = NULL; /* pthread_t -> Thread* */ |
| |
| static void map_pthread_t_to_Thread_INIT ( void ) { |
| if (UNLIKELY(map_pthread_t_to_Thread == NULL)) { |
| map_pthread_t_to_Thread = VG_(newFM)( HG_(zalloc), "hg.mpttT.1", |
| HG_(free), NULL ); |
| tl_assert(map_pthread_t_to_Thread != NULL); |
| } |
| } |
| |
| |
| static |
| Bool hg_handle_client_request ( ThreadId tid, UWord* args, UWord* ret) |
| { |
| if (!VG_IS_TOOL_USERREQ('H','G',args[0])) |
| return False; |
| |
| /* Anything that gets past the above check is one of ours, so we |
| should be able to handle it. */ |
| |
| /* default, meaningless return value, unless otherwise set */ |
| *ret = 0; |
| |
| switch (args[0]) { |
| |
| /* --- --- User-visible client requests --- --- */ |
| |
| case VG_USERREQ__HG_CLEAN_MEMORY: |
| if (0) VG_(printf)("VG_USERREQ__HG_CLEAN_MEMORY(%#lx,%ld)\n", |
| args[1], args[2]); |
| /* Call die_mem to (expensively) tidy up properly, if there |
| are any held locks etc in the area. Calling evh__die_mem |
| and then evh__new_mem is a bit inefficient; probably just |
| the latter would do. */ |
| if (args[2] > 0) { /* length */ |
| evh__die_mem(args[1], args[2]); |
| /* and then set it to New */ |
| evh__new_mem(args[1], args[2]); |
| } |
| break; |
| |
| case _VG_USERREQ__HG_CLEAN_MEMORY_HEAPBLOCK: { |
| Addr payload = 0; |
| SizeT pszB = 0; |
| if (0) VG_(printf)("VG_USERREQ__HG_CLEAN_MEMORY_HEAPBLOCK(%#lx)\n", |
| args[1]); |
| if (HG_(mm_find_containing_block)(NULL, &payload, &pszB, args[1])) { |
| if (pszB > 0) { |
| evh__die_mem(payload, pszB); |
| evh__new_mem(payload, pszB); |
| } |
| *ret = pszB; |
| } else { |
| *ret = (UWord)-1; |
| } |
| break; |
| } |
| |
| case _VG_USERREQ__HG_ARANGE_MAKE_UNTRACKED: |
| if (0) VG_(printf)("HG_ARANGE_MAKE_UNTRACKED(%#lx,%ld)\n", |
| args[1], args[2]); |
| if (args[2] > 0) { /* length */ |
| evh__untrack_mem(args[1], args[2]); |
| } |
| break; |
| |
| case _VG_USERREQ__HG_ARANGE_MAKE_TRACKED: |
| if (0) VG_(printf)("HG_ARANGE_MAKE_TRACKED(%#lx,%ld)\n", |
| args[1], args[2]); |
| if (args[2] > 0) { /* length */ |
| evh__new_mem(args[1], args[2]); |
| } |
| break; |
| |
| /* --- --- Client requests for Helgrind's use only --- --- */ |
| |
| /* Some thread is telling us its pthread_t value. Record the |
| binding between that and the associated Thread*, so we can |
| later find the Thread* again when notified of a join by the |
| thread. */ |
| case _VG_USERREQ__HG_SET_MY_PTHREAD_T: { |
| Thread* my_thr = NULL; |
| if (0) |
| VG_(printf)("SET_MY_PTHREAD_T (tid %d): pthread_t = %p\n", (Int)tid, |
| (void*)args[1]); |
| map_pthread_t_to_Thread_INIT(); |
| my_thr = map_threads_maybe_lookup( tid ); |
| /* This assertion should hold because the map_threads (tid to |
| Thread*) binding should have been made at the point of |
| low-level creation of this thread, which should have |
| happened prior to us getting this client request for it. |
| That's because this client request is sent from |
| client-world from the 'thread_wrapper' function, which |
| only runs once the thread has been low-level created. */ |
| tl_assert(my_thr != NULL); |
| /* So now we know that (pthread_t)args[1] is associated with |
| (Thread*)my_thr. Note that down. */ |
| if (0) |
| VG_(printf)("XXXX: bind pthread_t %p to Thread* %p\n", |
| (void*)args[1], (void*)my_thr ); |
| VG_(addToFM)( map_pthread_t_to_Thread, (UWord)args[1], (UWord)my_thr ); |
| break; |
| } |
| |
| case _VG_USERREQ__HG_PTH_API_ERROR: { |
| Thread* my_thr = NULL; |
| map_pthread_t_to_Thread_INIT(); |
| my_thr = map_threads_maybe_lookup( tid ); |
| tl_assert(my_thr); /* See justification above in SET_MY_PTHREAD_T */ |
| HG_(record_error_PthAPIerror)( |
| my_thr, (HChar*)args[1], (UWord)args[2], (HChar*)args[3] ); |
| break; |
| } |
| |
| /* This thread (tid) has completed a join with the quitting |
| thread whose pthread_t is in args[1]. */ |
| case _VG_USERREQ__HG_PTHREAD_JOIN_POST: { |
| Thread* thr_q = NULL; /* quitter Thread* */ |
| Bool found = False; |
| if (0) |
| VG_(printf)("NOTIFY_JOIN_COMPLETE (tid %d): quitter = %p\n", (Int)tid, |
| (void*)args[1]); |
| map_pthread_t_to_Thread_INIT(); |
| found = VG_(lookupFM)( map_pthread_t_to_Thread, |
| NULL, (UWord*)&thr_q, (UWord)args[1] ); |
| /* Can this fail? It would mean that our pthread_join |
| wrapper observed a successful join on args[1] yet that |
| thread never existed (or at least, it never lodged an |
| entry in the mapping (via SET_MY_PTHREAD_T)). Which |
| sounds like a bug in the threads library. */ |
| // FIXME: get rid of this assertion; handle properly |
| tl_assert(found); |
| if (found) { |
| if (0) |
| VG_(printf)(".................... quitter Thread* = %p\n", |
| thr_q); |
| evh__HG_PTHREAD_JOIN_POST( tid, thr_q ); |
| } |
| break; |
| } |
| |
| /* EXPOSITION only: by intercepting lock init events we can show |
| the user where the lock was initialised, rather than only |
| being able to show where it was first locked. Intercepting |
| lock initialisations is not necessary for the basic operation |
| of the race checker. */ |
| case _VG_USERREQ__HG_PTHREAD_MUTEX_INIT_POST: |
| evh__HG_PTHREAD_MUTEX_INIT_POST( tid, (void*)args[1], args[2] ); |
| break; |
| |
| /* mutex=arg[1], mutex_is_init=arg[2] */ |
| case _VG_USERREQ__HG_PTHREAD_MUTEX_DESTROY_PRE: |
| evh__HG_PTHREAD_MUTEX_DESTROY_PRE( tid, (void*)args[1], args[2] != 0 ); |
| break; |
| |
| case _VG_USERREQ__HG_PTHREAD_MUTEX_UNLOCK_PRE: // pth_mx_t* |
| evh__HG_PTHREAD_MUTEX_UNLOCK_PRE( tid, (void*)args[1] ); |
| break; |
| |
| case _VG_USERREQ__HG_PTHREAD_MUTEX_UNLOCK_POST: // pth_mx_t* |
| evh__HG_PTHREAD_MUTEX_UNLOCK_POST( tid, (void*)args[1] ); |
| break; |
| |
| case _VG_USERREQ__HG_PTHREAD_MUTEX_LOCK_PRE: // pth_mx_t*, Word |
| evh__HG_PTHREAD_MUTEX_LOCK_PRE( tid, (void*)args[1], args[2] ); |
| break; |
| |
| case _VG_USERREQ__HG_PTHREAD_MUTEX_LOCK_POST: // pth_mx_t* |
| evh__HG_PTHREAD_MUTEX_LOCK_POST( tid, (void*)args[1] ); |
| break; |
| |
| /* This thread is about to do pthread_cond_signal on the |
| pthread_cond_t* in arg[1]. Ditto pthread_cond_broadcast. */ |
| case _VG_USERREQ__HG_PTHREAD_COND_SIGNAL_PRE: |
| case _VG_USERREQ__HG_PTHREAD_COND_BROADCAST_PRE: |
| evh__HG_PTHREAD_COND_SIGNAL_PRE( tid, (void*)args[1] ); |
| break; |
| |
| /* Entry into pthread_cond_wait, cond=arg[1], mutex=arg[2]. |
| Returns a flag indicating whether or not the mutex is believed to be |
| valid for this operation. */ |
| case _VG_USERREQ__HG_PTHREAD_COND_WAIT_PRE: { |
| Bool mutex_is_valid |
| = evh__HG_PTHREAD_COND_WAIT_PRE( tid, (void*)args[1], |
| (void*)args[2] ); |
| *ret = mutex_is_valid ? 1 : 0; |
| break; |
| } |
| |
| /* Thread successfully completed pthread_cond_init: |
| cond=arg[1], cond_attr=arg[2] */ |
| case _VG_USERREQ__HG_PTHREAD_COND_INIT_POST: |
| evh__HG_PTHREAD_COND_INIT_POST( tid, |
| (void*)args[1], (void*)args[2] ); |
| break; |
| |
| /* cond=arg[1], cond_is_init=arg[2] */ |
| case _VG_USERREQ__HG_PTHREAD_COND_DESTROY_PRE: |
| evh__HG_PTHREAD_COND_DESTROY_PRE( tid, (void*)args[1], args[2] != 0 ); |
| break; |
| |
| /* Thread successfully completed pthread_cond_wait, cond=arg[1], |
| mutex=arg[2] */ |
| case _VG_USERREQ__HG_PTHREAD_COND_WAIT_POST: |
| evh__HG_PTHREAD_COND_WAIT_POST( tid, |
| (void*)args[1], (void*)args[2], |
| (Bool)args[3] ); |
| break; |
| |
| case _VG_USERREQ__HG_PTHREAD_RWLOCK_INIT_POST: |
| evh__HG_PTHREAD_RWLOCK_INIT_POST( tid, (void*)args[1] ); |
| break; |
| |
| case _VG_USERREQ__HG_PTHREAD_RWLOCK_DESTROY_PRE: |
| evh__HG_PTHREAD_RWLOCK_DESTROY_PRE( tid, (void*)args[1] ); |
| break; |
| |
| /* rwlock=arg[1], isW=arg[2], isTryLock=arg[3] */ |
| case _VG_USERREQ__HG_PTHREAD_RWLOCK_LOCK_PRE: |
| evh__HG_PTHREAD_RWLOCK_LOCK_PRE( tid, (void*)args[1], |
| args[2], args[3] ); |
| break; |
| |
| /* rwlock=arg[1], isW=arg[2] */ |
| case _VG_USERREQ__HG_PTHREAD_RWLOCK_LOCK_POST: |
| evh__HG_PTHREAD_RWLOCK_LOCK_POST( tid, (void*)args[1], args[2] ); |
| break; |
| |
| case _VG_USERREQ__HG_PTHREAD_RWLOCK_UNLOCK_PRE: |
| evh__HG_PTHREAD_RWLOCK_UNLOCK_PRE( tid, (void*)args[1] ); |
| break; |
| |
| case _VG_USERREQ__HG_PTHREAD_RWLOCK_UNLOCK_POST: |
| evh__HG_PTHREAD_RWLOCK_UNLOCK_POST( tid, (void*)args[1] ); |
| break; |
| |
| case _VG_USERREQ__HG_POSIX_SEM_INIT_POST: /* sem_t*, unsigned long */ |
| evh__HG_POSIX_SEM_INIT_POST( tid, (void*)args[1], args[2] ); |
| break; |
| |
| case _VG_USERREQ__HG_POSIX_SEM_DESTROY_PRE: /* sem_t* */ |
| evh__HG_POSIX_SEM_DESTROY_PRE( tid, (void*)args[1] ); |
| break; |
| |
| case _VG_USERREQ__HG_POSIX_SEM_POST_PRE: /* sem_t* */ |
| evh__HG_POSIX_SEM_POST_PRE( tid, (void*)args[1] ); |
| break; |
| |
| case _VG_USERREQ__HG_POSIX_SEM_WAIT_POST: /* sem_t* */ |
| evh__HG_POSIX_SEM_WAIT_POST( tid, (void*)args[1] ); |
| break; |
| |
| case _VG_USERREQ__HG_PTHREAD_BARRIER_INIT_PRE: |
| /* pth_bar_t*, ulong count, ulong resizable */ |
| evh__HG_PTHREAD_BARRIER_INIT_PRE( tid, (void*)args[1], |
| args[2], args[3] ); |
| break; |
| |
| case _VG_USERREQ__HG_PTHREAD_BARRIER_RESIZE_PRE: |
| /* pth_bar_t*, ulong newcount */ |
| evh__HG_PTHREAD_BARRIER_RESIZE_PRE ( tid, (void*)args[1], |
| args[2] ); |
| break; |
| |
| case _VG_USERREQ__HG_PTHREAD_BARRIER_WAIT_PRE: |
| /* pth_bar_t* */ |
| evh__HG_PTHREAD_BARRIER_WAIT_PRE( tid, (void*)args[1] ); |
| break; |
| |
| case _VG_USERREQ__HG_PTHREAD_BARRIER_DESTROY_PRE: |
| /* pth_bar_t* */ |
| evh__HG_PTHREAD_BARRIER_DESTROY_PRE( tid, (void*)args[1] ); |
| break; |
| |
| case _VG_USERREQ__HG_PTHREAD_SPIN_INIT_OR_UNLOCK_PRE: |
| /* pth_spinlock_t* */ |
| evh__HG_PTHREAD_SPIN_INIT_OR_UNLOCK_PRE( tid, (void*)args[1] ); |
| break; |
| |
| case _VG_USERREQ__HG_PTHREAD_SPIN_INIT_OR_UNLOCK_POST: |
| /* pth_spinlock_t* */ |
| evh__HG_PTHREAD_SPIN_INIT_OR_UNLOCK_POST( tid, (void*)args[1] ); |
| break; |
| |
| case _VG_USERREQ__HG_PTHREAD_SPIN_LOCK_PRE: |
| /* pth_spinlock_t*, Word */ |
| evh__HG_PTHREAD_SPIN_LOCK_PRE( tid, (void*)args[1], args[2] ); |
| break; |
| |
| case _VG_USERREQ__HG_PTHREAD_SPIN_LOCK_POST: |
| /* pth_spinlock_t* */ |
| evh__HG_PTHREAD_SPIN_LOCK_POST( tid, (void*)args[1] ); |
| break; |
| |
| case _VG_USERREQ__HG_PTHREAD_SPIN_DESTROY_PRE: |
| /* pth_spinlock_t* */ |
| evh__HG_PTHREAD_SPIN_DESTROY_PRE( tid, (void*)args[1] ); |
| break; |
| |
| case _VG_USERREQ__HG_CLIENTREQ_UNIMP: { |
| /* HChar* who */ |
| HChar* who = (HChar*)args[1]; |
| HChar buf[50 + 50]; |
| Thread* thr = map_threads_maybe_lookup( tid ); |
| tl_assert( thr ); /* I must be mapped */ |
| tl_assert( who ); |
| tl_assert( VG_(strlen)(who) <= 50 ); |
| VG_(sprintf)(buf, "Unimplemented client request macro \"%s\"", who ); |
| /* record_error_Misc strdup's buf, so this is safe: */ |
| HG_(record_error_Misc)( thr, buf ); |
| break; |
| } |
| |
| case _VG_USERREQ__HG_USERSO_SEND_PRE: |
| /* UWord arbitrary-SO-tag */ |
| evh__HG_USERSO_SEND_PRE( tid, args[1] ); |
| break; |
| |
| case _VG_USERREQ__HG_USERSO_RECV_POST: |
| /* UWord arbitrary-SO-tag */ |
| evh__HG_USERSO_RECV_POST( tid, args[1] ); |
| break; |
| |
| case _VG_USERREQ__HG_USERSO_FORGET_ALL: |
| /* UWord arbitrary-SO-tag */ |
| evh__HG_USERSO_FORGET_ALL( tid, args[1] ); |
| break; |
| |
| default: |
| /* Unhandled Helgrind client request! */ |
| tl_assert2(0, "unhandled Helgrind client request 0x%lx", |
| args[0]); |
| } |
| |
| return True; |
| } |
| |
| |
| /*----------------------------------------------------------------*/ |
| /*--- Setup ---*/ |
| /*----------------------------------------------------------------*/ |
| |
| static Bool hg_process_cmd_line_option ( const HChar* arg ) |
| { |
| const HChar* tmp_str; |
| |
| if VG_BOOL_CLO(arg, "--track-lockorders", |
| HG_(clo_track_lockorders)) {} |
| else if VG_BOOL_CLO(arg, "--cmp-race-err-addrs", |
| HG_(clo_cmp_race_err_addrs)) {} |
| |
| else if VG_XACT_CLO(arg, "--history-level=none", |
| HG_(clo_history_level), 0); |
| else if VG_XACT_CLO(arg, "--history-level=approx", |
| HG_(clo_history_level), 1); |
| else if VG_XACT_CLO(arg, "--history-level=full", |
| HG_(clo_history_level), 2); |
| |
| /* If you change the 10k/30mill limits, remember to also change |
| them in assertions at the top of event_map_maybe_GC. */ |
| else if VG_BINT_CLO(arg, "--conflict-cache-size", |
| HG_(clo_conflict_cache_size), 10*1000, 30*1000*1000) {} |
| |
| /* "stuvwx" --> stuvwx (binary) */ |
| else if VG_STR_CLO(arg, "--hg-sanity-flags", tmp_str) { |
| Int j; |
| |
| if (6 != VG_(strlen)(tmp_str)) { |
| VG_(message)(Vg_UserMsg, |
| "--hg-sanity-flags argument must have 6 digits\n"); |
| return False; |
| } |
| for (j = 0; j < 6; j++) { |
| if ('0' == tmp_str[j]) { /* do nothing */ } |
| else if ('1' == tmp_str[j]) HG_(clo_sanity_flags) |= (1 << (6-1-j)); |
| else { |
| VG_(message)(Vg_UserMsg, "--hg-sanity-flags argument can " |
| "only contain 0s and 1s\n"); |
| return False; |
| } |
| } |
| if (0) VG_(printf)("XXX sanity flags: 0x%lx\n", HG_(clo_sanity_flags)); |
| } |
| |
| else if VG_BOOL_CLO(arg, "--free-is-write", |
| HG_(clo_free_is_write)) {} |
| |
| else if VG_XACT_CLO(arg, "--vts-pruning=never", |
| HG_(clo_vts_pruning), 0); |
| else if VG_XACT_CLO(arg, "--vts-pruning=auto", |
| HG_(clo_vts_pruning), 1); |
| else if VG_XACT_CLO(arg, "--vts-pruning=always", |
| HG_(clo_vts_pruning), 2); |
| |
| else if VG_BOOL_CLO(arg, "--check-stack-refs", |
| HG_(clo_check_stack_refs)) {} |
| |
| else |
| return VG_(replacement_malloc_process_cmd_line_option)(arg); |
| |
| return True; |
| } |
| |
| static void hg_print_usage ( void ) |
| { |
| VG_(printf)( |
| " --free-is-write=no|yes treat heap frees as writes [no]\n" |
| " --track-lockorders=no|yes show lock ordering errors? [yes]\n" |
| " --history-level=none|approx|full [full]\n" |
| " full: show both stack traces for a data race (can be very slow)\n" |
| " approx: full trace for one thread, approx for the other (faster)\n" |
| " none: only show trace for one thread in a race (fastest)\n" |
| " --conflict-cache-size=N size of 'full' history cache [1000000]\n" |
| " --check-stack-refs=no|yes race-check reads and writes on the\n" |
| " main stack and thread stacks? [yes]\n" |
| ); |
| } |
| |
| static void hg_print_debug_usage ( void ) |
| { |
| VG_(printf)(" --cmp-race-err-addrs=no|yes are data addresses in " |
| "race errors significant? [no]\n"); |
| VG_(printf)(" --hg-sanity-flags=<XXXXXX> sanity check " |
| " at events (X = 0|1) [000000]\n"); |
| VG_(printf)(" --hg-sanity-flags values:\n"); |
| VG_(printf)(" 010000 after changes to " |
| "lock-order-acquisition-graph\n"); |
| VG_(printf)(" 001000 at memory accesses (NB: not currently used)\n"); |
| VG_(printf)(" 000100 at mem permission setting for " |
| "ranges >= %d bytes\n", SCE_BIGRANGE_T); |
| VG_(printf)(" 000010 at lock/unlock events\n"); |
| VG_(printf)(" 000001 at thread create/join events\n"); |
| VG_(printf)( |
| " --vts-pruning=never|auto|always [auto]\n" |
| " never: is never done (may cause big space leaks in Helgrind)\n" |
| " auto: done just often enough to keep space usage under control\n" |
| " always: done after every VTS GC (mostly just a big time waster)\n" |
| ); |
| } |
| |
| static void hg_fini ( Int exitcode ) |
| { |
| if (VG_(clo_verbosity) == 1 && !VG_(clo_xml)) { |
| VG_(message)(Vg_UserMsg, |
| "For counts of detected and suppressed errors, " |
| "rerun with: -v\n"); |
| } |
| |
| if (VG_(clo_verbosity) == 1 && !VG_(clo_xml) |
| && HG_(clo_history_level) >= 2) { |
| VG_(umsg)( |
| "Use --history-level=approx or =none to gain increased speed, at\n" ); |
| VG_(umsg)( |
| "the cost of reduced accuracy of conflicting-access information\n"); |
| } |
| |
| if (SHOW_DATA_STRUCTURES) |
| pp_everything( PP_ALL, "SK_(fini)" ); |
| if (HG_(clo_sanity_flags)) |
| all__sanity_check("SK_(fini)"); |
| |
| if (VG_(clo_stats)) { |
| |
| if (1) { |
| VG_(printf)("\n"); |
| HG_(ppWSUstats)( univ_lsets, "univ_lsets" ); |
| if (HG_(clo_track_lockorders)) { |
| VG_(printf)("\n"); |
| HG_(ppWSUstats)( univ_laog, "univ_laog" ); |
| } |
| } |
| |
| //zz VG_(printf)("\n"); |
| //zz VG_(printf)(" hbefore: %'10lu queries\n", stats__hbefore_queries); |
| //zz VG_(printf)(" hbefore: %'10lu cache 0 hits\n", stats__hbefore_cache0s); |
| //zz VG_(printf)(" hbefore: %'10lu cache > 0 hits\n", stats__hbefore_cacheNs); |
| //zz VG_(printf)(" hbefore: %'10lu graph searches\n", stats__hbefore_gsearches); |
| //zz VG_(printf)(" hbefore: %'10lu of which slow\n", |
| //zz stats__hbefore_gsearches - stats__hbefore_gsearchFs); |
| //zz VG_(printf)(" hbefore: %'10lu stack high water mark\n", |
| //zz stats__hbefore_stk_hwm); |
| //zz VG_(printf)(" hbefore: %'10lu cache invals\n", stats__hbefore_invals); |
| //zz VG_(printf)(" hbefore: %'10lu probes\n", stats__hbefore_probes); |
| |
| VG_(printf)("\n"); |
| VG_(printf)(" locksets: %'8d unique lock sets\n", |
| (Int)HG_(cardinalityWSU)( univ_lsets )); |
| if (HG_(clo_track_lockorders)) { |
| VG_(printf)(" univ_laog: %'8d unique lock sets\n", |
| (Int)HG_(cardinalityWSU)( univ_laog )); |
| } |
| |
| //VG_(printf)("L(ast)L(ock) map: %'8lu inserts (%d map size)\n", |
| // stats__ga_LL_adds, |
| // (Int)(ga_to_lastlock ? VG_(sizeFM)( ga_to_lastlock ) : 0) ); |
| |
| VG_(printf)(" LockN-to-P map: %'8llu queries (%llu map size)\n", |
| HG_(stats__LockN_to_P_queries), |
| HG_(stats__LockN_to_P_get_map_size)() ); |
| |
| VG_(printf)("string table map: %'8llu queries (%llu map size)\n", |
| HG_(stats__string_table_queries), |
| HG_(stats__string_table_get_map_size)() ); |
| if (HG_(clo_track_lockorders)) { |
| VG_(printf)(" LAOG: %'8d map size\n", |
| (Int)(laog ? VG_(sizeFM)( laog ) : 0)); |
| VG_(printf)(" LAOG exposition: %'8d map size\n", |
| (Int)(laog_exposition ? VG_(sizeFM)( laog_exposition ) : 0)); |
| } |
| |
| VG_(printf)(" locks: %'8lu acquires, " |
| "%'lu releases\n", |
| stats__lockN_acquires, |
| stats__lockN_releases |
| ); |
| VG_(printf)(" sanity checks: %'8lu\n", stats__sanity_checks); |
| |
| VG_(printf)("\n"); |
| libhb_shutdown(True); |
| } |
| } |
| |
| /* FIXME: move these somewhere sane */ |
| |
| static |
| void for_libhb__get_stacktrace ( Thr* hbt, Addr* frames, UWord nRequest ) |
| { |
| Thread* thr; |
| ThreadId tid; |
| UWord nActual; |
| tl_assert(hbt); |
| thr = libhb_get_Thr_hgthread( hbt ); |
| tl_assert(thr); |
| tid = map_threads_maybe_reverse_lookup_SLOW(thr); |
| nActual = (UWord)VG_(get_StackTrace)( tid, frames, (UInt)nRequest, |
| NULL, NULL, 0 ); |
| tl_assert(nActual <= nRequest); |
| for (; nActual < nRequest; nActual++) |
| frames[nActual] = 0; |
| } |
| |
| static |
| ExeContext* for_libhb__get_EC ( Thr* hbt ) |
| { |
| Thread* thr; |
| ThreadId tid; |
| ExeContext* ec; |
| tl_assert(hbt); |
| thr = libhb_get_Thr_hgthread( hbt ); |
| tl_assert(thr); |
| tid = map_threads_maybe_reverse_lookup_SLOW(thr); |
| /* this will assert if tid is invalid */ |
| ec = VG_(record_ExeContext)( tid, 0 ); |
| return ec; |
| } |
| |
| |
| static void hg_post_clo_init ( void ) |
| { |
| Thr* hbthr_root; |
| |
| ///////////////////////////////////////////// |
| hbthr_root = libhb_init( for_libhb__get_stacktrace, |
| for_libhb__get_EC ); |
| ///////////////////////////////////////////// |
| |
| |
| if (HG_(clo_track_lockorders)) |
| laog__init(); |
| |
| initialise_data_structures(hbthr_root); |
| } |
| |
| static void hg_pre_clo_init ( void ) |
| { |
| VG_(details_name) ("Helgrind"); |
| VG_(details_version) (NULL); |
| VG_(details_description) ("a thread error detector"); |
| VG_(details_copyright_author)( |
| "Copyright (C) 2007-2013, and GNU GPL'd, by OpenWorks LLP et al."); |
| VG_(details_bug_reports_to) (VG_BUGS_TO); |
| VG_(details_avg_translation_sizeB) ( 320 ); |
| |
| VG_(basic_tool_funcs) (hg_post_clo_init, |
| hg_instrument, |
| hg_fini); |
| |
| VG_(needs_core_errors) (); |
| VG_(needs_tool_errors) (HG_(eq_Error), |
| HG_(before_pp_Error), |
| HG_(pp_Error), |
| False,/*show TIDs for errors*/ |
| HG_(update_extra), |
| HG_(recognised_suppression), |
| HG_(read_extra_suppression_info), |
| HG_(error_matches_suppression), |
| HG_(get_error_name), |
| HG_(get_extra_suppression_info), |
| HG_(print_extra_suppression_use), |
| HG_(update_extra_suppression_use)); |
| |
| VG_(needs_xml_output) (); |
| |
| VG_(needs_command_line_options)(hg_process_cmd_line_option, |
| hg_print_usage, |
| hg_print_debug_usage); |
| VG_(needs_client_requests) (hg_handle_client_request); |
| |
| // FIXME? |
| //VG_(needs_sanity_checks) (hg_cheap_sanity_check, |
| // hg_expensive_sanity_check); |
| |
| VG_(needs_malloc_replacement) (hg_cli__malloc, |
| hg_cli____builtin_new, |
| hg_cli____builtin_vec_new, |
| hg_cli__memalign, |
| hg_cli__calloc, |
| hg_cli__free, |
| hg_cli____builtin_delete, |
| hg_cli____builtin_vec_delete, |
| hg_cli__realloc, |
| hg_cli_malloc_usable_size, |
| HG_CLI__DEFAULT_MALLOC_REDZONE_SZB ); |
| |
| /* 21 Dec 08: disabled this; it mostly causes H to start more |
| slowly and use significantly more memory, without very often |
| providing useful results. The user can request to load this |
| information manually with --read-var-info=yes. */ |
| if (0) VG_(needs_var_info)(); /* optional */ |
| |
| VG_(track_new_mem_startup) ( evh__new_mem_w_perms ); |
| VG_(track_new_mem_stack_signal)( evh__new_mem_w_tid ); |
| VG_(track_new_mem_brk) ( evh__new_mem_w_tid ); |
| VG_(track_new_mem_mmap) ( evh__new_mem_w_perms ); |
| VG_(track_new_mem_stack) ( evh__new_mem_stack ); |
| |
| // FIXME: surely this isn't thread-aware |
| VG_(track_copy_mem_remap) ( evh__copy_mem ); |
| |
| VG_(track_change_mem_mprotect) ( evh__set_perms ); |
| |
| VG_(track_die_mem_stack_signal)( evh__die_mem ); |
| VG_(track_die_mem_brk) ( evh__die_mem_munmap ); |
| VG_(track_die_mem_munmap) ( evh__die_mem_munmap ); |
| VG_(track_die_mem_stack) ( evh__die_mem ); |
| |
| // FIXME: what is this for? |
| VG_(track_ban_mem_stack) (NULL); |
| |
| VG_(track_pre_mem_read) ( evh__pre_mem_read ); |
| VG_(track_pre_mem_read_asciiz) ( evh__pre_mem_read_asciiz ); |
| VG_(track_pre_mem_write) ( evh__pre_mem_write ); |
| VG_(track_post_mem_write) (NULL); |
| |
| ///////////////// |
| |
| VG_(track_pre_thread_ll_create)( evh__pre_thread_ll_create ); |
| VG_(track_pre_thread_ll_exit) ( evh__pre_thread_ll_exit ); |
| |
| VG_(track_start_client_code)( evh__start_client_code ); |
| VG_(track_stop_client_code)( evh__stop_client_code ); |
| |
| /* Ensure that requirements for "dodgy C-as-C++ style inheritance" |
| as described in comments at the top of pub_tool_hashtable.h, are |
| met. Blargh. */ |
| tl_assert( sizeof(void*) == sizeof(struct _MallocMeta*) ); |
| tl_assert( sizeof(UWord) == sizeof(Addr) ); |
| hg_mallocmeta_table |
| = VG_(HT_construct)( "hg_malloc_metadata_table" ); |
| |
| // add a callback to clean up on (threaded) fork. |
| VG_(atfork)(NULL/*pre*/, NULL/*parent*/, evh__atfork_child/*child*/); |
| } |
| |
| VG_DETERMINE_INTERFACE_VERSION(hg_pre_clo_init) |
| |
| /*--------------------------------------------------------------------*/ |
| /*--- end hg_main.c ---*/ |
| /*--------------------------------------------------------------------*/ |