/**************************************************************************/ /* */ /* OCaml */ /* */ /* Damien Doligez, projet Para, INRIA Rocquencourt */ /* */ /* Copyright 1996 Institut National de Recherche en Informatique et */ /* en Automatique. */ /* */ /* All rights reserved. This file is distributed under the terms of */ /* the GNU Lesser General Public License version 2.1, with the */ /* special exception on linking described in the file LICENSE. */ /* */ /**************************************************************************/ #define CAML_INTERNALS #include #include "caml/custom.h" #include "caml/config.h" #include "caml/fail.h" #include "caml/finalise.h" #include "caml/gc.h" #include "caml/gc_ctrl.h" #include "caml/major_gc.h" #include "caml/memory.h" #include "caml/minor_gc.h" #include "caml/misc.h" #include "caml/mlvalues.h" #include "caml/roots.h" #include "caml/signals.h" #include "caml/weak.h" #include "caml/memprof.h" #include "caml/eventlog.h" /* Pointers into the minor heap. [Caml_state->young_base] The [malloc] block that contains the heap. [Caml_state->young_start] ... [Caml_state->young_end] The whole range of the minor heap: all young blocks are inside this interval. [Caml_state->young_alloc_start]...[Caml_state->young_alloc_end] The allocation arena: newly-allocated blocks are carved from this interval, starting at [Caml_state->young_alloc_end]. [Caml_state->young_alloc_mid] is the mid-point of this interval. [Caml_state->young_ptr], [Caml_state->young_trigger], [Caml_state->young_limit] These pointers are all inside the allocation arena. - [Caml_state->young_ptr] is where the next allocation will take place. - [Caml_state->young_trigger] is how far we can allocate before triggering [caml_gc_dispatch]. Currently, it is either [Caml_state->young_alloc_start] or the mid-point of the allocation arena. - [Caml_state->young_limit] is the pointer that is compared to [Caml_state->young_ptr] for allocation. It is either: + [Caml_state->young_alloc_end] if a signal handler or finaliser or memprof callback is pending, or if a major or minor collection has been requested, or an asynchronous callback has just raised an exception, + [caml_memprof_young_trigger] if a memprof sample is planned, + or [Caml_state->young_trigger]. */ struct generic_table CAML_TABLE_STRUCT(char); void caml_alloc_minor_tables () { Caml_state->ref_table = caml_stat_alloc_noexc(sizeof(struct caml_ref_table)); if (Caml_state->ref_table == NULL) caml_fatal_error ("cannot initialize minor heap"); memset(Caml_state->ref_table, 0, sizeof(struct caml_ref_table)); Caml_state->ephe_ref_table = caml_stat_alloc_noexc(sizeof(struct caml_ephe_ref_table)); if (Caml_state->ephe_ref_table == NULL) caml_fatal_error ("cannot initialize minor heap"); memset(Caml_state->ephe_ref_table, 0, sizeof(struct caml_ephe_ref_table)); Caml_state->custom_table = caml_stat_alloc_noexc(sizeof(struct caml_custom_table)); if (Caml_state->custom_table == NULL) caml_fatal_error ("cannot initialize minor heap"); memset(Caml_state->custom_table, 0, sizeof(struct caml_custom_table)); } /* [sz] and [rsv] are numbers of entries */ static void alloc_generic_table (struct generic_table *tbl, asize_t sz, asize_t rsv, asize_t element_size) { void *new_table; tbl->size = sz; tbl->reserve = rsv; new_table = (void *) caml_stat_alloc_noexc((tbl->size + tbl->reserve) * element_size); if (new_table == NULL) caml_fatal_error ("not enough memory"); if (tbl->base != NULL) caml_stat_free (tbl->base); tbl->base = new_table; tbl->ptr = tbl->base; tbl->threshold = tbl->base + tbl->size * element_size; tbl->limit = tbl->threshold; tbl->end = tbl->base + (tbl->size + tbl->reserve) * element_size; } void caml_alloc_table (struct caml_ref_table *tbl, asize_t sz, asize_t rsv) { alloc_generic_table ((struct generic_table *) tbl, sz, rsv, sizeof (value *)); } void caml_alloc_ephe_table (struct caml_ephe_ref_table *tbl, asize_t sz, asize_t rsv) { alloc_generic_table ((struct generic_table *) tbl, sz, rsv, sizeof (struct caml_ephe_ref_elt)); } void caml_alloc_custom_table (struct caml_custom_table *tbl, asize_t sz, asize_t rsv) { alloc_generic_table ((struct generic_table *) tbl, sz, rsv, sizeof (struct caml_custom_elt)); } static void reset_table (struct generic_table *tbl) { tbl->size = 0; tbl->reserve = 0; if (tbl->base != NULL) caml_stat_free (tbl->base); tbl->base = tbl->ptr = tbl->threshold = tbl->limit = tbl->end = NULL; } static void clear_table (struct generic_table *tbl) { tbl->ptr = tbl->base; tbl->limit = tbl->threshold; } void caml_set_minor_heap_size (asize_t bsz) { char *new_heap; void *new_heap_base; CAMLassert (bsz >= Bsize_wsize(Minor_heap_min)); CAMLassert (bsz <= Bsize_wsize(Minor_heap_max)); CAMLassert (bsz % Page_size == 0); CAMLassert (bsz % sizeof (value) == 0); if (Caml_state->young_ptr != Caml_state->young_alloc_end){ CAML_EV_COUNTER (EV_C_FORCE_MINOR_SET_MINOR_HEAP_SIZE, 1); Caml_state->requested_minor_gc = 0; Caml_state->young_trigger = Caml_state->young_alloc_mid; caml_update_young_limit(); caml_empty_minor_heap (); } CAMLassert (Caml_state->young_ptr == Caml_state->young_alloc_end); new_heap = caml_stat_alloc_aligned_noexc(bsz, 0, &new_heap_base); if (new_heap == NULL) caml_raise_out_of_memory(); if (caml_page_table_add(In_young, new_heap, new_heap + bsz) != 0) caml_raise_out_of_memory(); if (Caml_state->young_start != NULL){ caml_page_table_remove(In_young, Caml_state->young_start, Caml_state->young_end); caml_stat_free (Caml_state->young_base); } Caml_state->young_base = new_heap_base; Caml_state->young_start = (value *) new_heap; Caml_state->young_end = (value *) (new_heap + bsz); Caml_state->young_alloc_start = Caml_state->young_start; Caml_state->young_alloc_mid = Caml_state->young_alloc_start + Wsize_bsize (bsz) / 2; Caml_state->young_alloc_end = Caml_state->young_end; /* caml_update_young_limit called by caml_memprof_renew_minor_sample */ Caml_state->young_trigger = Caml_state->young_alloc_start; Caml_state->young_ptr = Caml_state->young_alloc_end; Caml_state->minor_heap_wsz = Wsize_bsize (bsz); caml_memprof_renew_minor_sample(); reset_table ((struct generic_table *) Caml_state->ref_table); reset_table ((struct generic_table *) Caml_state->ephe_ref_table); reset_table ((struct generic_table *) Caml_state->custom_table); } static value oldify_todo_list = 0; /* Note that the tests on the tag depend on the fact that Infix_tag, Forward_tag, and No_scan_tag are contiguous. */ void caml_oldify_one (value v, value *p) { value result; header_t hd; mlsize_t sz, i; tag_t tag; tail_call: if (Is_block (v) && Is_young (v)){ CAMLassert ((value *) Hp_val (v) >= Caml_state->young_ptr); hd = Hd_val (v); if (hd == 0){ /* If already forwarded */ *p = Field (v, 0); /* then forward pointer is first field. */ }else{ CAMLassert_young_header(hd); tag = Tag_hd (hd); if (tag < Infix_tag){ value field0; sz = Wosize_hd (hd); result = caml_alloc_shr_for_minor_gc (sz, tag, hd); *p = result; field0 = Field (v, 0); Hd_val (v) = 0; /* Set forward flag */ Field (v, 0) = result; /* and forward pointer. */ if (sz > 1){ Field (result, 0) = field0; Field (result, 1) = oldify_todo_list; /* Add this block */ oldify_todo_list = v; /* to the "to do" list. */ }else{ CAMLassert (sz == 1); p = &Field (result, 0); v = field0; goto tail_call; } }else if (tag >= No_scan_tag){ sz = Wosize_hd (hd); result = caml_alloc_shr_for_minor_gc (sz, tag, hd); for (i = 0; i < sz; i++) Field (result, i) = Field (v, i); Hd_val (v) = 0; /* Set forward flag */ Field (v, 0) = result; /* and forward pointer. */ *p = result; }else if (tag == Infix_tag){ mlsize_t offset = Infix_offset_hd (hd); caml_oldify_one (v - offset, p); /* Cannot recurse deeper than 1. */ *p += offset; }else{ value f = Forward_val (v); tag_t ft = 0; int vv = 1; CAMLassert (tag == Forward_tag); if (Is_block (f)){ if (Is_young (f)){ vv = 1; ft = Tag_val (Hd_val (f) == 0 ? Field (f, 0) : f); }else{ vv = Is_in_value_area(f); if (vv){ ft = Tag_val (f); } } } if (!vv || ft == Forward_tag || ft == Lazy_tag #ifdef FLAT_FLOAT_ARRAY || ft == Double_tag #endif ){ /* Do not short-circuit the pointer. Copy as a normal block. */ CAMLassert (Wosize_hd (hd) == 1); result = caml_alloc_shr_for_minor_gc (1, Forward_tag, hd); *p = result; Hd_val (v) = 0; /* Set (GC) forward flag */ Field (v, 0) = result; /* and forward pointer. */ p = &Field (result, 0); v = f; goto tail_call; }else{ v = f; /* Follow the forwarding */ goto tail_call; /* then oldify. */ } } } }else{ *p = v; } } /* Test if the ephemeron is alive, everything outside minor heap is alive */ Caml_inline int ephe_check_alive_data(struct caml_ephe_ref_elt *re){ mlsize_t i; value child; for (i = CAML_EPHE_FIRST_KEY; i < Wosize_val(re->ephe); i++){ child = Field (re->ephe, i); if(child != caml_ephe_none && Is_block (child) && Is_young (child)) { if(Tag_val(child) == Infix_tag) child -= Infix_offset_val(child); if(Hd_val (child) != 0) return 0; /* Value not copied to major heap */ } } return 1; } /* Finish the work that was put off by [caml_oldify_one]. Note that [caml_oldify_one] itself is called by oldify_mopup, so we have to be careful to remove the first entry from the list before oldifying its fields. */ void caml_oldify_mopup (void) { value v, new_v, f; mlsize_t i; struct caml_ephe_ref_elt *re; int redo; again: redo = 0; while (oldify_todo_list != 0){ v = oldify_todo_list; /* Get the head. */ CAMLassert (Hd_val (v) == 0); /* It must be forwarded. */ new_v = Field (v, 0); /* Follow forward pointer. */ oldify_todo_list = Field (new_v, 1); /* Remove from list. */ f = Field (new_v, 0); if (Is_block (f) && Is_young (f)){ caml_oldify_one (f, &Field (new_v, 0)); } for (i = 1; i < Wosize_val (new_v); i++){ f = Field (v, i); if (Is_block (f) && Is_young (f)){ caml_oldify_one (f, &Field (new_v, i)); }else{ Field (new_v, i) = f; } } } /* Oldify the data in the minor heap of alive ephemeron During minor collection keys outside the minor heap are considered alive */ for (re = Caml_state->ephe_ref_table->base; re < Caml_state->ephe_ref_table->ptr; re++){ /* look only at ephemeron with data in the minor heap */ if (re->offset == 1){ value *data = &Field(re->ephe,1), v = *data; if (v != caml_ephe_none && Is_block (v) && Is_young (v)){ mlsize_t offs = Tag_val(v) == Infix_tag ? Infix_offset_val(v) : 0; v -= offs; if (Hd_val (v) == 0){ /* Value copied to major heap */ *data = Field (v, 0) + offs; } else { if (ephe_check_alive_data(re)){ caml_oldify_one(*data,data); redo = 1; /* oldify_todo_list can still be 0 */ } } } } } if (redo) goto again; } /* Make sure the minor heap is empty by performing a minor collection if needed. */ void caml_empty_minor_heap (void) { value **r; struct caml_custom_elt *elt; uintnat prev_alloc_words; struct caml_ephe_ref_elt *re; if (Caml_state->young_ptr != Caml_state->young_alloc_end){ CAMLassert_young_header(*(header_t*)Caml_state->young_ptr); if (caml_minor_gc_begin_hook != NULL) (*caml_minor_gc_begin_hook) (); prev_alloc_words = caml_allocated_words; Caml_state->in_minor_collection = 1; caml_gc_message (0x02, "<"); CAML_EV_BEGIN(EV_MINOR_LOCAL_ROOTS); caml_oldify_local_roots(); CAML_EV_END(EV_MINOR_LOCAL_ROOTS); CAML_EV_BEGIN(EV_MINOR_REF_TABLES); for (r = Caml_state->ref_table->base; r < Caml_state->ref_table->ptr; r++) { caml_oldify_one (**r, *r); } CAML_EV_END(EV_MINOR_REF_TABLES); CAML_EV_BEGIN(EV_MINOR_COPY); caml_oldify_mopup (); CAML_EV_END(EV_MINOR_COPY); /* Update the ephemerons */ for (re = Caml_state->ephe_ref_table->base; re < Caml_state->ephe_ref_table->ptr; re++){ if(re->offset < Wosize_val(re->ephe)){ /* If it is not the case, the ephemeron has been truncated */ value *key = &Field(re->ephe,re->offset), v = *key; if (v != caml_ephe_none && Is_block (v) && Is_young (v)){ mlsize_t offs = Tag_val (v) == Infix_tag ? Infix_offset_val (v) : 0; v -= offs; if (Hd_val (v) == 0){ /* Value copied to major heap */ *key = Field (v, 0) + offs; }else{ /* Value not copied so it's dead */ CAMLassert(!ephe_check_alive_data(re)); *key = caml_ephe_none; Field(re->ephe,1) = caml_ephe_none; } } } } /* Update the OCaml finalise_last values */ CAML_EV_BEGIN(EV_MINOR_UPDATE_WEAK); caml_final_update_minor_roots(); /* Trigger memprofs callbacks for blocks in the minor heap. */ caml_memprof_minor_update(); /* Run custom block finalisation of dead minor values */ for (elt = Caml_state->custom_table->base; elt < Caml_state->custom_table->ptr; elt++){ value v = elt->block; if (Hd_val (v) == 0){ /* Block was copied to the major heap: adjust GC speed numbers. */ caml_adjust_gc_speed(elt->mem, elt->max); }else{ /* Block will be freed: call finalization function, if any. */ void (*final_fun)(value) = Custom_ops_val(v)->finalize; if (final_fun != NULL) final_fun(v); } } CAML_EV_END(EV_MINOR_UPDATE_WEAK); CAML_EV_BEGIN(EV_MINOR_FINALIZED); Caml_state->stat_minor_words += Caml_state->young_alloc_end - Caml_state->young_ptr; caml_gc_clock += (double) (Caml_state->young_alloc_end - Caml_state->young_ptr) / Caml_state->minor_heap_wsz; Caml_state->young_ptr = Caml_state->young_alloc_end; clear_table ((struct generic_table *) Caml_state->ref_table); clear_table ((struct generic_table *) Caml_state->ephe_ref_table); clear_table ((struct generic_table *) Caml_state->custom_table); Caml_state->extra_heap_resources_minor = 0; caml_gc_message (0x02, ">"); Caml_state->in_minor_collection = 0; caml_final_empty_young (); CAML_EV_END(EV_MINOR_FINALIZED); Caml_state->stat_promoted_words += caml_allocated_words - prev_alloc_words; CAML_EV_COUNTER (EV_C_MINOR_PROMOTED, caml_allocated_words - prev_alloc_words); ++ Caml_state->stat_minor_collections; caml_memprof_renew_minor_sample(); if (caml_minor_gc_end_hook != NULL) (*caml_minor_gc_end_hook) (); }else{ /* The minor heap is empty nothing to do. */ caml_final_empty_young (); } #ifdef DEBUG { value *p; for (p = Caml_state->young_alloc_start; p < Caml_state->young_alloc_end; ++p) { *p = Debug_free_minor; } } #endif } #ifdef CAML_INSTR extern uintnat caml_instr_alloc_jump; #endif /*CAML_INSTR*/ /* Do a minor collection or a slice of major collection, etc. Leave enough room in the minor heap to allocate at least one object. Guaranteed not to call any OCaml callback. */ void caml_gc_dispatch (void) { CAML_EVENTLOG_DO({ CAML_EV_COUNTER(EV_C_ALLOC_JUMP, caml_instr_alloc_jump); caml_instr_alloc_jump = 0; }); if (Caml_state->young_trigger == Caml_state->young_alloc_start){ /* The minor heap is full, we must do a minor collection. */ Caml_state->requested_minor_gc = 1; }else{ /* The minor heap is half-full, do a major GC slice. */ Caml_state->requested_major_slice = 1; } if (caml_gc_phase == Phase_idle){ /* The major GC needs an empty minor heap in order to start a new cycle. If a major slice was requested, we need to do a minor collection before we can do the major slice that starts a new major GC cycle. If a minor collection was requested, we take the opportunity to start a new major GC cycle. In either case, we have to do a minor cycle followed by a major slice. */ Caml_state->requested_minor_gc = 1; Caml_state->requested_major_slice = 1; } if (Caml_state->requested_minor_gc) { /* reset the pointers first because the end hooks might allocate */ CAML_EV_BEGIN(EV_MINOR); Caml_state->requested_minor_gc = 0; Caml_state->young_trigger = Caml_state->young_alloc_mid; caml_update_young_limit(); caml_empty_minor_heap (); CAML_EV_END(EV_MINOR); } if (Caml_state->requested_major_slice) { Caml_state->requested_major_slice = 0; Caml_state->young_trigger = Caml_state->young_alloc_start; caml_update_young_limit(); CAML_EV_BEGIN(EV_MAJOR); caml_major_collection_slice (-1); CAML_EV_END(EV_MAJOR); } } /* Called by young allocations when [Caml_state->young_ptr] reaches [Caml_state->young_limit]. We may have to either call memprof or the gc. */ void caml_alloc_small_dispatch (intnat wosize, int flags, int nallocs, unsigned char* encoded_alloc_lens) { intnat whsize = Whsize_wosize (wosize); /* First, we un-do the allocation performed in [Alloc_small] */ Caml_state->young_ptr += whsize; while(1) { /* We might be here because of an async callback / urgent GC request. Take the opportunity to do what has been requested. */ if (flags & CAML_FROM_CAML) /* In the case of allocations performed from OCaml, execute asynchronous callbacks. */ caml_raise_if_exception(caml_do_pending_actions_exn ()); else { caml_check_urgent_gc (Val_unit); /* In the case of long-running C code that regularly polls with caml_process_pending_actions, force a query of all callbacks at every minor collection or major slice. */ caml_something_to_do = 1; } /* Now, there might be enough room in the minor heap to do our allocation. */ if (Caml_state->young_ptr - whsize >= Caml_state->young_trigger) break; /* If not, then empty the minor heap, and check again for async callbacks. */ CAML_EV_COUNTER (EV_C_FORCE_MINOR_ALLOC_SMALL, 1); caml_gc_dispatch (); } /* Re-do the allocation: we now have enough space in the minor heap. */ Caml_state->young_ptr -= whsize; /* Check if the allocated block has been sampled by memprof. */ if(Caml_state->young_ptr < caml_memprof_young_trigger){ if(flags & CAML_DO_TRACK) { caml_memprof_track_young(wosize, flags & CAML_FROM_CAML, nallocs, encoded_alloc_lens); /* Until the allocation actually takes place, the heap is in an invalid state (see comments in [caml_memprof_track_young]). Hence, very little heap operations are allowed before the actual allocation. Moreover, [Caml_state->young_ptr] should not be modified before the allocation, because its value has been used as the pointer to the sampled block. */ } else caml_memprof_renew_minor_sample(); } } /* Exported for backward compatibility with Lablgtk: do a minor collection to ensure that the minor heap is empty. */ CAMLexport void caml_minor_collection (void) { Caml_state->requested_minor_gc = 1; caml_gc_dispatch (); } CAMLexport value caml_check_urgent_gc (value extra_root) { if (Caml_state->requested_major_slice || Caml_state->requested_minor_gc){ CAMLparam1 (extra_root); caml_gc_dispatch(); CAMLdrop; } return extra_root; } static void realloc_generic_table (struct generic_table *tbl, asize_t element_size, ev_gc_counter ev_counter_name, char *msg_threshold, char *msg_growing, char *msg_error) { CAMLassert (tbl->ptr == tbl->limit); CAMLassert (tbl->limit <= tbl->end); CAMLassert (tbl->limit >= tbl->threshold); if (tbl->base == NULL){ alloc_generic_table (tbl, Caml_state->minor_heap_wsz / 8, 256, element_size); }else if (tbl->limit == tbl->threshold){ CAML_EV_COUNTER (ev_counter_name, 1); caml_gc_message (0x08, msg_threshold, 0); tbl->limit = tbl->end; caml_request_minor_gc (); }else{ asize_t sz; asize_t cur_ptr = tbl->ptr - tbl->base; CAMLassert (Caml_state->requested_minor_gc); tbl->size *= 2; sz = (tbl->size + tbl->reserve) * element_size; caml_gc_message (0x08, msg_growing, (intnat) sz/1024); tbl->base = caml_stat_resize_noexc (tbl->base, sz); if (tbl->base == NULL){ caml_fatal_error ("%s", msg_error); } tbl->end = tbl->base + (tbl->size + tbl->reserve) * element_size; tbl->threshold = tbl->base + tbl->size * element_size; tbl->ptr = tbl->base + cur_ptr; tbl->limit = tbl->end; } } void caml_realloc_ref_table (struct caml_ref_table *tbl) { realloc_generic_table ((struct generic_table *) tbl, sizeof (value *), EV_C_REQUEST_MINOR_REALLOC_REF_TABLE, "ref_table threshold crossed\n", "Growing ref_table to %" ARCH_INTNAT_PRINTF_FORMAT "dk bytes\n", "ref_table overflow"); } void caml_realloc_ephe_ref_table (struct caml_ephe_ref_table *tbl) { realloc_generic_table ((struct generic_table *) tbl, sizeof (struct caml_ephe_ref_elt), EV_C_REQUEST_MINOR_REALLOC_EPHE_REF_TABLE, "ephe_ref_table threshold crossed\n", "Growing ephe_ref_table to %" ARCH_INTNAT_PRINTF_FORMAT "dk bytes\n", "ephe_ref_table overflow"); } void caml_realloc_custom_table (struct caml_custom_table *tbl) { realloc_generic_table ((struct generic_table *) tbl, sizeof (struct caml_custom_elt), EV_C_REQUEST_MINOR_REALLOC_CUSTOM_TABLE, "custom_table threshold crossed\n", "Growing custom_table to %" ARCH_INTNAT_PRINTF_FORMAT "dk bytes\n", "custom_table overflow"); }