/* ----------------------------------------------------------------------------- * * (c) The GHC Team 1998-2008 * * Weak pointers and weak-like things in the GC * * Documentation on the architecture of the Garbage Collector can be * found in the online commentary: * * http://hackage.haskell.org/trac/ghc/wiki/Commentary/Rts/Storage/GC * * ---------------------------------------------------------------------------*/ #include "PosixSource.h" #include "Rts.h" #include "MarkWeak.h" #include "GC.h" #include "GCThread.h" #include "Evac.h" #include "Trace.h" #include "Schedule.h" #include "Weak.h" #include "Storage.h" #include "Threads.h" /* ----------------------------------------------------------------------------- Weak Pointers traverse_weak_ptr_list is called possibly many times during garbage collection. It returns a flag indicating whether it did any work (i.e. called evacuate on any live pointers). Invariant: traverse_weak_ptr_list is called when the heap is in an idempotent state. That means that there are no pending evacuate/scavenge operations. This invariant helps the weak pointer code decide which weak pointers are dead - if there are no new live weak pointers, then all the currently unreachable ones are dead. For generational GC: we just don't try to finalize weak pointers in older generations than the one we're collecting. This could probably be optimised by keeping per-generation lists of weak pointers, but for a few weak pointers this scheme will work. There are three distinct stages to processing weak pointers: - weak_stage == WeakPtrs We process all the weak pointers whos keys are alive (evacuate their values and finalizers), and repeat until we can find no new live keys. If no live keys are found in this pass, then we evacuate the finalizers of all the dead weak pointers in order to run them. - weak_stage == WeakThreads Now, we discover which *threads* are still alive. Pointers to threads from the all_threads and main thread lists are the weakest of all: a pointers from the finalizer of a dead weak pointer can keep a thread alive. Any threads found to be unreachable are evacuated and placed on the resurrected_threads list so we can send them a signal later. - weak_stage == WeakDone No more evacuation is done. -------------------------------------------------------------------------- */ /* Which stage of processing various kinds of weak pointer are we at? * (see traverse_weak_ptr_list() below for discussion). */ typedef enum { WeakPtrs, WeakThreads, WeakDone } WeakStage; static WeakStage weak_stage; /* Weak pointers */ StgWeak *old_weak_ptr_list; // also pending finaliser list // List of threads found to be unreachable StgTSO *resurrected_threads; static void resurrectUnreachableThreads (generation *gen); static rtsBool tidyThreadList (generation *gen); void initWeakForGC(void) { old_weak_ptr_list = weak_ptr_list; weak_ptr_list = NULL; weak_stage = WeakPtrs; resurrected_threads = END_TSO_QUEUE; } rtsBool traverseWeakPtrList(void) { StgWeak *w, **last_w, *next_w; StgClosure *new; rtsBool flag = rtsFalse; const StgInfoTable *info; switch (weak_stage) { case WeakDone: return rtsFalse; case WeakPtrs: /* doesn't matter where we evacuate values/finalizers to, since * these pointers are treated as roots (iff the keys are alive). */ gct->evac_gen = 0; last_w = &old_weak_ptr_list; for (w = old_weak_ptr_list; w != NULL; w = next_w) { /* There might be a DEAD_WEAK on the list if finalizeWeak# was * called on a live weak pointer object. Just remove it. */ if (w->header.info == &stg_DEAD_WEAK_info) { next_w = ((StgDeadWeak *)w)->link; *last_w = next_w; continue; } info = get_itbl(w); switch (info->type) { case WEAK: /* Now, check whether the key is reachable. */ new = isAlive(w->key); if (new != NULL) { w->key = new; // evacuate the value and finalizer evacuate(&w->value); evacuate(&w->finalizer); // remove this weak ptr from the old_weak_ptr list *last_w = w->link; // and put it on the new weak ptr list next_w = w->link; w->link = weak_ptr_list; weak_ptr_list = w; flag = rtsTrue; debugTrace(DEBUG_weak, "weak pointer still alive at %p -> %p", w, w->key); continue; } else { last_w = &(w->link); next_w = w->link; continue; } default: barf("traverseWeakPtrList: not WEAK"); } } /* If we didn't make any changes, then we can go round and kill all * the dead weak pointers. The old_weak_ptr list is used as a list * of pending finalizers later on. */ if (flag == rtsFalse) { for (w = old_weak_ptr_list; w; w = w->link) { evacuate(&w->finalizer); } // Next, move to the WeakThreads stage after fully // scavenging the finalizers we've just evacuated. weak_stage = WeakThreads; } return rtsTrue; case WeakThreads: /* Now deal with the step->threads lists, which behave somewhat like * the weak ptr list. If we discover any threads that are about to * become garbage, we wake them up and administer an exception. */ { nat g; // Traverse thread lists for generations we collected... // ToDo when we have one gen per capability: // for (n = 0; n < n_capabilities; n++) { // if (tidyThreadList(&nurseries[n])) { // flag = rtsTrue; // } // } for (g = 0; g <= N; g++) { if (tidyThreadList(&generations[g])) { flag = rtsTrue; } } /* If we evacuated any threads, we need to go back to the scavenger. */ if (flag) return rtsTrue; /* And resurrect any threads which were about to become garbage. */ { nat g; for (g = 0; g <= N; g++) { resurrectUnreachableThreads(&generations[g]); } } weak_stage = WeakDone; // *now* we're done, return rtsTrue; // but one more round of scavenging, please } default: barf("traverse_weak_ptr_list"); return rtsTrue; } } static void resurrectUnreachableThreads (generation *gen) { StgTSO *t, *tmp, *next; for (t = gen->old_threads; t != END_TSO_QUEUE; t = next) { next = t->global_link; // ThreadFinished and ThreadComplete: we have to keep // these on the all_threads list until they // become garbage, because they might get // pending exceptions. switch (t->what_next) { case ThreadKilled: case ThreadComplete: continue; default: tmp = t; evacuate((StgClosure **)&tmp); tmp->global_link = resurrected_threads; resurrected_threads = tmp; } } } static rtsBool tidyThreadList (generation *gen) { StgTSO *t, *tmp, *next, **prev; rtsBool flag = rtsFalse; prev = &gen->old_threads; for (t = gen->old_threads; t != END_TSO_QUEUE; t = next) { tmp = (StgTSO *)isAlive((StgClosure *)t); if (tmp != NULL) { t = tmp; } ASSERT(get_itbl(t)->type == TSO); if (t->what_next == ThreadRelocated) { next = t->_link; *prev = next; continue; } next = t->global_link; // if the thread is not masking exceptions but there are // pending exceptions on its queue, then something has gone // wrong: ASSERT(t->blocked_exceptions == END_BLOCKED_EXCEPTIONS_QUEUE || (t->flags & TSO_BLOCKEX)); if (tmp == NULL) { // not alive (yet): leave this thread on the // old_all_threads list. prev = &(t->global_link); } else { // alive *prev = next; // move this thread onto the correct threads list. generation *new_gen; new_gen = Bdescr((P_)t)->gen; t->global_link = new_gen->threads; new_gen->threads = t; } } return flag; } /* ----------------------------------------------------------------------------- Evacuate every weak pointer object on the weak_ptr_list, and update the link fields. ToDo: with a lot of weak pointers, this will be expensive. We should have a per-GC weak pointer list, just like threads. -------------------------------------------------------------------------- */ void markWeakPtrList ( void ) { StgWeak *w, **last_w; last_w = &weak_ptr_list; for (w = weak_ptr_list; w; w = w->link) { // w might be WEAK, EVACUATED, or DEAD_WEAK (actually CON_STATIC) here #ifdef DEBUG { // careful to do this assertion only reading the info ptr // once, because during parallel GC it might change under our feet. const StgInfoTable *info; info = w->header.info; ASSERT(IS_FORWARDING_PTR(info) || info == &stg_DEAD_WEAK_info || INFO_PTR_TO_STRUCT(info)->type == WEAK); } #endif evacuate((StgClosure **)last_w); w = *last_w; if (w->header.info == &stg_DEAD_WEAK_info) { last_w = &(((StgDeadWeak*)w)->link); } else { last_w = &(w->link); } } }