/** * \file * Simple generational GC. * * Copyright 2011 Novell, Inc (http://www.novell.com) * Copyright 2011 Xamarin Inc (http://www.xamarin.com) * Copyright 2001-2003 Ximian, Inc * Copyright 2003-2010 Novell, Inc. * Licensed under the MIT license. See LICENSE file in the project root for full license information. */ #include "config.h" #ifdef HAVE_SGEN_GC #include #include "sgen/sgen-gc.h" #include "sgen-bridge-internals.h" #include "sgen/sgen-hash-table.h" #include "sgen/sgen-qsort.h" #include "sgen/sgen-client.h" #include "utils/mono-logger-internals.h" typedef struct { int size; int capacity; char *data; } DynArray; /*Specializations*/ typedef struct { DynArray array; } DynIntArray; typedef struct { DynArray array; } DynPtrArray; typedef struct { DynArray array; } DynSCCArray; /* * Bridge data for a single managed object * * FIXME: Optimizations: * * Don't allocate a srcs array for just one source. Most objects have * just one source, so use the srcs pointer itself. */ typedef struct _HashEntry { GCObject *obj; /* This is a duplicate - it's already stored in the hash table */ gboolean is_bridge; gboolean is_visited; int finishing_time; // "Source" managed objects pointing at this destination DynPtrArray srcs; // Index in sccs array of SCC this object was folded into int scc_index; } HashEntry; typedef struct { HashEntry entry; double weight; } HashEntryWithAccounting; // The graph of managed objects/HashEntries is reduced to a graph of strongly connected components typedef struct _SCC { int index; int api_index; // How many bridged objects does this SCC hold references to? int num_bridge_entries; // Index in global sccs array of SCCs holding pointers to this SCC DynIntArray xrefs; /* these are incoming, not outgoing */ } SCC; // Maps managed objects to corresponding HashEntry stricts static SgenHashTable hash_table = SGEN_HASH_TABLE_INIT (INTERNAL_MEM_OLD_BRIDGE_HASH_TABLE, INTERNAL_MEM_OLD_BRIDGE_HASH_TABLE_ENTRY, sizeof (HashEntry), mono_aligned_addr_hash, NULL); static int current_time; static gboolean bridge_accounting_enabled = FALSE; static SgenBridgeProcessor *bridge_processor; /* Core functions */ /* public */ /* private */ static void dyn_array_init (DynArray *da) { da->size = 0; da->capacity = 0; da->data = NULL; } static void dyn_array_uninit (DynArray *da, int elem_size) { if (da->capacity <= 0) return; sgen_free_internal_dynamic (da->data, elem_size * da->capacity, INTERNAL_MEM_BRIDGE_DATA); da->data = NULL; } static void dyn_array_ensure_capacity (DynArray *da, int capacity, int elem_size) { int old_capacity = da->capacity; char *new_data; if (capacity <= old_capacity) return; if (da->capacity == 0) da->capacity = 2; while (capacity > da->capacity) da->capacity *= 2; new_data = (char *)sgen_alloc_internal_dynamic (elem_size * da->capacity, INTERNAL_MEM_BRIDGE_DATA, TRUE); memcpy (new_data, da->data, elem_size * da->size); sgen_free_internal_dynamic (da->data, elem_size * old_capacity, INTERNAL_MEM_BRIDGE_DATA); da->data = new_data; } static void* dyn_array_add (DynArray *da, int elem_size) { void *p; dyn_array_ensure_capacity (da, da->size + 1, elem_size); p = da->data + da->size * elem_size; ++da->size; return p; } /* int */ static void dyn_array_int_init (DynIntArray *da) { dyn_array_init (&da->array); } static void dyn_array_int_uninit (DynIntArray *da) { dyn_array_uninit (&da->array, sizeof (int)); } static int dyn_array_int_size (DynIntArray *da) { return da->array.size; } static void dyn_array_int_set_size (DynIntArray *da, int size) { da->array.size = size; } static void dyn_array_int_add (DynIntArray *da, int x) { int *p = (int *)dyn_array_add (&da->array, sizeof (int)); *p = x; } static int dyn_array_int_get (DynIntArray *da, int x) { return ((int*)da->array.data)[x]; } static void dyn_array_int_set (DynIntArray *da, int idx, int val) { ((int*)da->array.data)[idx] = val; } static void dyn_array_int_ensure_capacity (DynIntArray *da, int capacity) { dyn_array_ensure_capacity (&da->array, capacity, sizeof (int)); } static void dyn_array_int_set_all (DynIntArray *dst, DynIntArray *src) { dyn_array_int_ensure_capacity (dst, src->array.size); memcpy (dst->array.data, src->array.data, src->array.size * sizeof (int)); dst->array.size = src->array.size; } /* ptr */ static void dyn_array_ptr_init (DynPtrArray *da) { dyn_array_init (&da->array); } static void dyn_array_ptr_uninit (DynPtrArray *da) { dyn_array_uninit (&da->array, sizeof (void*)); } static int dyn_array_ptr_size (DynPtrArray *da) { return da->array.size; } static void dyn_array_ptr_set_size (DynPtrArray *da, int size) { da->array.size = size; } static void* dyn_array_ptr_get (DynPtrArray *da, int x) { return ((void**)da->array.data)[x]; } static void dyn_array_ptr_add (DynPtrArray *da, void *ptr) { void **p = (void **)dyn_array_add (&da->array, sizeof (void*)); *p = ptr; } #define dyn_array_ptr_push dyn_array_ptr_add static void* dyn_array_ptr_pop (DynPtrArray *da) { void *p; int size = da->array.size; g_assert (size > 0); p = dyn_array_ptr_get (da, size - 1); --da->array.size; return p; } /*SCC */ static void dyn_array_scc_init (DynSCCArray *da) { dyn_array_init (&da->array); } static void dyn_array_scc_uninit (DynSCCArray *da) { dyn_array_uninit (&da->array, sizeof (SCC)); } static int dyn_array_scc_size (DynSCCArray *da) { return da->array.size; } static SCC* dyn_array_scc_add (DynSCCArray *da) { return (SCC *)dyn_array_add (&da->array, sizeof (SCC)); } static SCC* dyn_array_scc_get_ptr (DynSCCArray *da, int x) { return &((SCC*)da->array.data)[x]; } /* Merge code*/ static DynIntArray merge_array; static gboolean dyn_array_int_contains (DynIntArray *da, int x) { int i; for (i = 0; i < dyn_array_int_size (da); ++i) if (dyn_array_int_get (da, i) == x) return TRUE; return FALSE; } static void dyn_array_int_merge (DynIntArray *dst, DynIntArray *src) { int i, j; dyn_array_int_ensure_capacity (&merge_array, dyn_array_int_size (dst) + dyn_array_int_size (src)); dyn_array_int_set_size (&merge_array, 0); for (i = j = 0; i < dyn_array_int_size (dst) || j < dyn_array_int_size (src); ) { if (i < dyn_array_int_size (dst) && j < dyn_array_int_size (src)) { int a = dyn_array_int_get (dst, i); int b = dyn_array_int_get (src, j); if (a < b) { dyn_array_int_add (&merge_array, a); ++i; } else if (a == b) { dyn_array_int_add (&merge_array, a); ++i; ++j; } else { dyn_array_int_add (&merge_array, b); ++j; } } else if (i < dyn_array_int_size (dst)) { dyn_array_int_add (&merge_array, dyn_array_int_get (dst, i)); ++i; } else { dyn_array_int_add (&merge_array, dyn_array_int_get (src, j)); ++j; } } if (dyn_array_int_size (&merge_array) > dyn_array_int_size (dst)) { dyn_array_int_set_all (dst, &merge_array); } } static void dyn_array_int_merge_one (DynIntArray *array, int value) { int i; int tmp; int size = dyn_array_int_size (array); for (i = 0; i < size; ++i) { if (dyn_array_int_get (array, i) == value) return; else if (dyn_array_int_get (array, i) > value) break; } dyn_array_int_ensure_capacity (array, size + 1); if (i < size) { tmp = dyn_array_int_get (array, i); for (; i < size; ++i) { dyn_array_int_set (array, i, value); value = tmp; tmp = dyn_array_int_get (array, i + 1); } dyn_array_int_set (array, size, value); } else { dyn_array_int_set (array, size, value); } dyn_array_int_set_size (array, size + 1); } static void set_config (const SgenBridgeProcessorConfig *config) { if (config->accounting) { SgenHashTable table = SGEN_HASH_TABLE_INIT (INTERNAL_MEM_BRIDGE_HASH_TABLE, INTERNAL_MEM_BRIDGE_HASH_TABLE_ENTRY, sizeof (HashEntryWithAccounting), mono_aligned_addr_hash, NULL); bridge_accounting_enabled = TRUE; hash_table = table; } } static MonoGCBridgeObjectKind class_kind (MonoClass *klass) { return bridge_callbacks.bridge_class_kind (klass); } static HashEntry* get_hash_entry (GCObject *obj, gboolean *existing) { HashEntry *entry = (HashEntry *)sgen_hash_table_lookup (&hash_table, obj); HashEntry new_entry; if (entry) { if (existing) *existing = TRUE; return entry; } if (existing) *existing = FALSE; memset (&new_entry, 0, sizeof (HashEntry)); new_entry.obj = obj; dyn_array_ptr_init (&new_entry.srcs); new_entry.finishing_time = -1; new_entry.scc_index = -1; sgen_hash_table_replace (&hash_table, obj, &new_entry, NULL); return (HashEntry *)sgen_hash_table_lookup (&hash_table, obj); } static void add_source (HashEntry *entry, HashEntry *src) { dyn_array_ptr_add (&entry->srcs, src); } static void free_data (void) { GCObject *obj G_GNUC_UNUSED; HashEntry *entry; int total_srcs = 0; int max_srcs = 0; SGEN_HASH_TABLE_FOREACH (&hash_table, GCObject *, obj, HashEntry *, entry) { int entry_size = dyn_array_ptr_size (&entry->srcs); total_srcs += entry_size; if (entry_size > max_srcs) max_srcs = entry_size; dyn_array_ptr_uninit (&entry->srcs); } SGEN_HASH_TABLE_FOREACH_END; sgen_hash_table_clean (&hash_table); dyn_array_int_uninit (&merge_array); //g_print ("total srcs %d - max %d\n", total_srcs, max_srcs); } static HashEntry* register_bridge_object (GCObject *obj) { HashEntry *entry = get_hash_entry (obj, NULL); entry->is_bridge = TRUE; return entry; } static void register_finishing_time (HashEntry *entry, int t) { g_assert (entry->finishing_time < 0); entry->finishing_time = t; } static gboolean object_is_live (GCObject **objp) { GCObject *obj = *objp; GCObject *fwd = SGEN_OBJECT_IS_FORWARDED (obj); if (fwd) { *objp = fwd; return sgen_hash_table_lookup (&hash_table, fwd) == NULL; } if (!sgen_object_is_live (obj)) return FALSE; return sgen_hash_table_lookup (&hash_table, obj) == NULL; } static DynPtrArray registered_bridges; static DynPtrArray dfs_stack; static int dfs1_passes, dfs2_passes; #undef HANDLE_PTR #define HANDLE_PTR(ptr,obj) do { \ GCObject *dst = (GCObject*)*(ptr); \ if (dst && !object_is_live (&dst)) { \ dyn_array_ptr_push (&dfs_stack, obj_entry); \ dyn_array_ptr_push (&dfs_stack, get_hash_entry (dst, NULL)); \ } \ } while (0) static void dfs1 (HashEntry *obj_entry) { HashEntry *src; g_assert (dyn_array_ptr_size (&dfs_stack) == 0); dyn_array_ptr_push (&dfs_stack, NULL); dyn_array_ptr_push (&dfs_stack, obj_entry); do { GCObject *obj; ++dfs1_passes; obj_entry = (HashEntry *)dyn_array_ptr_pop (&dfs_stack); if (obj_entry) { char *start; mword desc; src = (HashEntry *)dyn_array_ptr_pop (&dfs_stack); obj = obj_entry->obj; desc = sgen_obj_get_descriptor_safe (obj); if (src) { //g_print ("link %s -> %s\n", sgen_safe_name (src->obj), sgen_safe_name (obj)); add_source (obj_entry, src); } else { //g_print ("starting with %s\n", sgen_safe_name (obj)); } if (obj_entry->is_visited) continue; obj_entry->is_visited = TRUE; dyn_array_ptr_push (&dfs_stack, obj_entry); /* NULL marks that the next entry is to be finished */ dyn_array_ptr_push (&dfs_stack, NULL); start = (char*)obj; #include "sgen/sgen-scan-object.h" } else { obj_entry = (HashEntry *)dyn_array_ptr_pop (&dfs_stack); //g_print ("finish %s\n", sgen_safe_name (obj_entry->obj)); register_finishing_time (obj_entry, current_time++); } } while (dyn_array_ptr_size (&dfs_stack) > 0); } static void scc_add_xref (SCC *src, SCC *dst) { g_assert (src != dst); g_assert (src->index != dst->index); if (dyn_array_int_contains (&dst->xrefs, src->index)) return; if (src->num_bridge_entries) { dyn_array_int_merge_one (&dst->xrefs, src->index); } else { int i; dyn_array_int_merge (&dst->xrefs, &src->xrefs); for (i = 0; i < dyn_array_int_size (&dst->xrefs); ++i) g_assert (dyn_array_int_get (&dst->xrefs, i) != dst->index); } } static void scc_add_entry (SCC *scc, HashEntry *entry) { g_assert (entry->scc_index < 0); entry->scc_index = scc->index; if (entry->is_bridge) ++scc->num_bridge_entries; } static DynSCCArray sccs; static SCC *current_scc; static void dfs2 (HashEntry *entry) { int i; g_assert (dyn_array_ptr_size (&dfs_stack) == 0); dyn_array_ptr_push (&dfs_stack, entry); do { entry = (HashEntry *)dyn_array_ptr_pop (&dfs_stack); ++dfs2_passes; if (entry->scc_index >= 0) { if (entry->scc_index != current_scc->index) scc_add_xref (dyn_array_scc_get_ptr (&sccs, entry->scc_index), current_scc); continue; } scc_add_entry (current_scc, entry); for (i = 0; i < dyn_array_ptr_size (&entry->srcs); ++i) dyn_array_ptr_push (&dfs_stack, dyn_array_ptr_get (&entry->srcs, i)); } while (dyn_array_ptr_size (&dfs_stack) > 0); } static int compare_hash_entries (const HashEntry *e1, const HashEntry *e2) { return e2->finishing_time - e1->finishing_time; } DEF_QSORT_INLINE(hash_entries, HashEntry*, compare_hash_entries) static gint64 step_1, step_2, step_3, step_4, step_5, step_6; static int fist_pass_links, second_pass_links, sccs_links; static int max_sccs_links = 0; static void register_finalized_object (GCObject *obj) { g_assert (sgen_need_bridge_processing ()); dyn_array_ptr_push (®istered_bridges, obj); } static void reset_data (void) { dyn_array_ptr_set_size (®istered_bridges, 0); } static void processing_stw_step (void) { int i; int bridge_count; SGEN_TV_DECLARE (atv); SGEN_TV_DECLARE (btv); if (!dyn_array_ptr_size (®istered_bridges)) return; SGEN_TV_GETTIME (btv); /* first DFS pass */ dyn_array_ptr_init (&dfs_stack); dyn_array_int_init (&merge_array); current_time = 0; /* First we insert all bridges into the hash table and then we do dfs1. It must be done in 2 steps since the bridge arrays doesn't come in reverse topological order, which means that we can have entry N pointing to entry N + 1. If we dfs1 entry N before N + 1 is registered we'll not consider N + 1 for this bridge pass and not create the required xref between the two. */ bridge_count = dyn_array_ptr_size (®istered_bridges); for (i = 0; i < bridge_count ; ++i) register_bridge_object ((GCObject *)dyn_array_ptr_get (®istered_bridges, i)); for (i = 0; i < bridge_count; ++i) dfs1 (get_hash_entry ((GCObject *)dyn_array_ptr_get (®istered_bridges, i), NULL)); SGEN_TV_GETTIME (atv); step_2 = SGEN_TV_ELAPSED (btv, atv); } static int num_registered_bridges, hash_table_size; static void processing_build_callback_data (int generation) { int i, j; int num_sccs, num_xrefs; int max_entries, max_xrefs; GCObject *obj G_GNUC_UNUSED; HashEntry *entry; HashEntry **all_entries; MonoGCBridgeSCC **api_sccs; MonoGCBridgeXRef *api_xrefs; SGEN_TV_DECLARE (atv); SGEN_TV_DECLARE (btv); g_assert (bridge_processor->num_sccs == 0 && bridge_processor->num_xrefs == 0); g_assert (!bridge_processor->api_sccs && !bridge_processor->api_xrefs); if (!dyn_array_ptr_size (®istered_bridges)) return; g_assert (bridge_processing_in_progress); SGEN_TV_GETTIME (atv); /* alloc and fill array of all entries */ all_entries = (HashEntry **)sgen_alloc_internal_dynamic (sizeof (HashEntry*) * hash_table.num_entries, INTERNAL_MEM_BRIDGE_DATA, TRUE); j = 0; SGEN_HASH_TABLE_FOREACH (&hash_table, GCObject *, obj, HashEntry *, entry) { g_assert (entry->finishing_time >= 0); all_entries [j++] = entry; fist_pass_links += dyn_array_ptr_size (&entry->srcs); } SGEN_HASH_TABLE_FOREACH_END; g_assert (j == hash_table.num_entries); hash_table_size = hash_table.num_entries; /* sort array according to decreasing finishing time */ qsort_hash_entries (all_entries, hash_table.num_entries); SGEN_TV_GETTIME (btv); step_3 = SGEN_TV_ELAPSED (atv, btv); /* second DFS pass */ dyn_array_scc_init (&sccs); for (i = 0; i < hash_table.num_entries; ++i) { HashEntry *entry = all_entries [i]; if (entry->scc_index < 0) { int index = dyn_array_scc_size (&sccs); current_scc = dyn_array_scc_add (&sccs); current_scc->index = index; current_scc->num_bridge_entries = 0; current_scc->api_index = -1; dyn_array_int_init (¤t_scc->xrefs); dfs2 (entry); } } /* * Compute the weight of each object. The weight of an object is its size plus the size of all * objects it points do. When the an object is pointed by multiple objects we distribute it's weight * equally among them. This distribution gives a rough estimate of the real impact of making the object * go away. * * The reasoning for this model is that complex graphs with single roots will have a bridge with very high * value in comparison to others. * * The all_entries array has all objects topologically sorted. To correctly propagate the weights it must be * done in reverse topological order - so we calculate the weight of the pointed-to objects before processing * pointer-from objects. * * We log those objects in the opposite order for no particular reason. The other constrain is that it should use the same * direction as the other logging loop that records live/dead information. */ if (bridge_accounting_enabled) { for (i = hash_table.num_entries - 1; i >= 0; --i) { double w; HashEntryWithAccounting *entry = (HashEntryWithAccounting*)all_entries [i]; entry->weight += (double)sgen_safe_object_get_size (entry->entry.obj); w = entry->weight / dyn_array_ptr_size (&entry->entry.srcs); for (j = 0; j < dyn_array_ptr_size (&entry->entry.srcs); ++j) { HashEntryWithAccounting *other = (HashEntryWithAccounting *)dyn_array_ptr_get (&entry->entry.srcs, j); other->weight += w; } } for (i = 0; i < hash_table.num_entries; ++i) { HashEntryWithAccounting *entry = (HashEntryWithAccounting*)all_entries [i]; if (entry->entry.is_bridge) { MonoClass *klass = SGEN_LOAD_VTABLE (entry->entry.obj)->klass; mono_trace (G_LOG_LEVEL_INFO, MONO_TRACE_GC, "OBJECT %s::%s (%p) weight %f", klass->name_space, klass->name, entry->entry.obj, entry->weight); } } } for (i = 0; i < hash_table.num_entries; ++i) { HashEntry *entry = all_entries [i]; second_pass_links += dyn_array_ptr_size (&entry->srcs); } SGEN_TV_GETTIME (atv); step_4 = SGEN_TV_ELAPSED (btv, atv); //g_print ("%d sccs\n", sccs.size); dyn_array_ptr_uninit (&dfs_stack); /* init data for callback */ num_sccs = 0; for (i = 0; i < dyn_array_scc_size (&sccs); ++i) { SCC *scc = dyn_array_scc_get_ptr (&sccs, i); g_assert (scc->index == i); if (scc->num_bridge_entries) ++num_sccs; sccs_links += dyn_array_int_size (&scc->xrefs); max_sccs_links = MAX (max_sccs_links, dyn_array_int_size (&scc->xrefs)); } api_sccs = (MonoGCBridgeSCC **)sgen_alloc_internal_dynamic (sizeof (MonoGCBridgeSCC*) * num_sccs, INTERNAL_MEM_BRIDGE_DATA, TRUE); num_xrefs = 0; j = 0; for (i = 0; i < dyn_array_scc_size (&sccs); ++i) { SCC *scc = dyn_array_scc_get_ptr (&sccs, i); if (!scc->num_bridge_entries) continue; api_sccs [j] = (MonoGCBridgeSCC *)sgen_alloc_internal_dynamic (sizeof (MonoGCBridgeSCC) + sizeof (MonoObject*) * scc->num_bridge_entries, INTERNAL_MEM_BRIDGE_DATA, TRUE); api_sccs [j]->is_alive = FALSE; api_sccs [j]->num_objs = scc->num_bridge_entries; scc->num_bridge_entries = 0; scc->api_index = j++; num_xrefs += dyn_array_int_size (&scc->xrefs); } SGEN_HASH_TABLE_FOREACH (&hash_table, GCObject *, obj, HashEntry *, entry) { if (entry->is_bridge) { SCC *scc = dyn_array_scc_get_ptr (&sccs, entry->scc_index); api_sccs [scc->api_index]->objs [scc->num_bridge_entries++] = (MonoObject*)entry->obj; } } SGEN_HASH_TABLE_FOREACH_END; api_xrefs = (MonoGCBridgeXRef *)sgen_alloc_internal_dynamic (sizeof (MonoGCBridgeXRef) * num_xrefs, INTERNAL_MEM_BRIDGE_DATA, TRUE); j = 0; for (i = 0; i < dyn_array_scc_size (&sccs); ++i) { int k; SCC *scc = dyn_array_scc_get_ptr (&sccs, i); if (!scc->num_bridge_entries) continue; for (k = 0; k < dyn_array_int_size (&scc->xrefs); ++k) { SCC *src_scc = dyn_array_scc_get_ptr (&sccs, dyn_array_int_get (&scc->xrefs, k)); if (!src_scc->num_bridge_entries) continue; api_xrefs [j].src_scc_index = src_scc->api_index; api_xrefs [j].dst_scc_index = scc->api_index; ++j; } } SGEN_TV_GETTIME (btv); step_5 = SGEN_TV_ELAPSED (atv, btv); /* free data */ j = 0; max_entries = max_xrefs = 0; for (i = 0; i < dyn_array_scc_size (&sccs); ++i) { SCC *scc = dyn_array_scc_get_ptr (&sccs, i); if (scc->num_bridge_entries) ++j; if (scc->num_bridge_entries > max_entries) max_entries = scc->num_bridge_entries; if (dyn_array_int_size (&scc->xrefs) > max_xrefs) max_xrefs = dyn_array_int_size (&scc->xrefs); dyn_array_int_uninit (&scc->xrefs); } dyn_array_scc_uninit (&sccs); sgen_free_internal_dynamic (all_entries, sizeof (HashEntry*) * hash_table.num_entries, INTERNAL_MEM_BRIDGE_DATA); free_data (); /* Empty the registered bridges array */ num_registered_bridges = dyn_array_ptr_size (®istered_bridges); dyn_array_ptr_set_size (®istered_bridges, 0); SGEN_TV_GETTIME (atv); step_6 = SGEN_TV_ELAPSED (btv, atv); //g_print ("%d sccs containing bridges - %d max bridge objects - %d max xrefs\n", j, max_entries, max_xrefs); bridge_processor->num_sccs = num_sccs; bridge_processor->api_sccs = api_sccs; bridge_processor->num_xrefs = num_xrefs; bridge_processor->api_xrefs = api_xrefs; } static void processing_after_callback (int generation) { int i, j; int num_sccs = bridge_processor->num_sccs; MonoGCBridgeSCC **api_sccs = bridge_processor->api_sccs; if (bridge_accounting_enabled) { for (i = 0; i < num_sccs; ++i) { for (j = 0; j < api_sccs [i]->num_objs; ++j) { GCVTable vtable = SGEN_LOAD_VTABLE (api_sccs [i]->objs [j]); mono_trace (G_LOG_LEVEL_INFO, MONO_TRACE_GC, "OBJECT %s.%s (%p) SCC [%d] %s", sgen_client_vtable_get_namespace (vtable), sgen_client_vtable_get_name (vtable), api_sccs [i]->objs [j], i, api_sccs [i]->is_alive ? "ALIVE" : "DEAD"); } } } mono_trace (G_LOG_LEVEL_INFO, MONO_TRACE_GC, "GC_OLD_BRIDGE num-objects %d num_hash_entries %d sccs size %d init %.2fms df1 %.2fms sort %.2fms dfs2 %.2fms setup-cb %.2fms free-data %.2fms links %d/%d/%d/%d dfs passes %d/%d", num_registered_bridges, hash_table_size, dyn_array_scc_size (&sccs), step_1 / 10000.0f, step_2 / 10000.0f, step_3 / 10000.0f, step_4 / 10000.0f, step_5 / 10000.0f, step_6 / 10000.0f, fist_pass_links, second_pass_links, sccs_links, max_sccs_links, dfs1_passes, dfs2_passes); step_1 = 0; /* We must cleanup since this value is used as an accumulator. */ fist_pass_links = second_pass_links = sccs_links = max_sccs_links = 0; dfs1_passes = dfs2_passes = 0; } static void describe_pointer (GCObject *obj) { HashEntry *entry; int i; for (i = 0; i < dyn_array_ptr_size (®istered_bridges); ++i) { if (obj == dyn_array_ptr_get (®istered_bridges, i)) { printf ("Pointer is a registered bridge object.\n"); break; } } entry = (HashEntry *)sgen_hash_table_lookup (&hash_table, obj); if (!entry) return; printf ("Bridge hash table entry %p:\n", entry); printf (" is bridge: %d\n", (int)entry->is_bridge); printf (" is visited: %d\n", (int)entry->is_visited); } void sgen_old_bridge_init (SgenBridgeProcessor *collector) { collector->reset_data = reset_data; collector->processing_stw_step = processing_stw_step; collector->processing_build_callback_data = processing_build_callback_data; collector->processing_after_callback = processing_after_callback; collector->class_kind = class_kind; collector->register_finalized_object = register_finalized_object; collector->describe_pointer = describe_pointer; collector->set_config = set_config; bridge_processor = collector; } #endif