/***********************************************************************/ /* */ /* Objective Caml */ /* */ /* 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 Library General Public License. */ /* */ /***********************************************************************/ /* $Id$ */ #include #include "compact.h" #include "custom.h" #include "config.h" #include "fail.h" #include "finalise.h" #include "freelist.h" #include "gc.h" #include "gc_ctrl.h" #include "major_gc.h" #include "misc.h" #include "mlvalues.h" #include "roots.h" #include "weak.h" unsigned long percent_free; long major_heap_increment; char *heap_start, *heap_end; page_table_entry *page_table; asize_t page_low, page_high; char *gc_sweep_hp; int gc_phase; static value *gray_vals; value *gray_vals_cur, *gray_vals_end; static asize_t gray_vals_size; static int heap_is_pure; /* The heap is pure if the only gray objects below [markhp] are also in [gray_vals]. */ unsigned long allocated_words; double extra_heap_memory; extern char *fl_merge; /* Defined in freelist.c. */ static char *markhp, *chunk, *limit; static void update_weak_pointers (void); static void realloc_gray_vals (void) { value *new; Assert (gray_vals_cur == gray_vals_end); if (gray_vals_size < stat_heap_size / 128){ gc_message (0x08, "Growing gray_vals to %luk bytes\n", (long) gray_vals_size * sizeof (value) / 512); new = (value *) realloc ((char *) gray_vals, 2 * gray_vals_size * sizeof (value)); if (new == NULL){ gc_message (0x08, "No room for growing gray_vals\n", 0); gray_vals_cur = gray_vals; heap_is_pure = 0; }else{ gray_vals = new; gray_vals_cur = gray_vals + gray_vals_size; gray_vals_size *= 2; gray_vals_end = gray_vals + gray_vals_size; } }else{ gray_vals_cur = gray_vals + gray_vals_size / 2; heap_is_pure = 0; } } void darken (value v, value *p /* not used */) { if (Is_block (v) && Is_in_heap (v)) { if (Tag_val(v) == Infix_tag) v -= Infix_offset_val(v); if (Is_white_val (v)){ Hd_val (v) = Grayhd_hd (Hd_val (v)); *gray_vals_cur++ = v; if (gray_vals_cur >= gray_vals_end) realloc_gray_vals (); } } } static void start_cycle (void) { Assert (gc_phase == Phase_idle); Assert (gray_vals_cur == gray_vals); gc_message (0x01, "Starting new major GC cycle\n", 0); darken_all_roots(); gc_phase = Phase_mark; markhp = NULL; #ifdef DEBUG heap_check (); #endif } static void mark_slice (long work) { value *gray_vals_ptr; /* Local copy of gray_vals_cur */ value v, child; header_t hd; mlsize_t size, i; gc_message (0x40, "Marking %lu words\n", work); gray_vals_ptr = gray_vals_cur; while (work > 0){ if (gray_vals_ptr > gray_vals){ v = *--gray_vals_ptr; hd = Hd_val(v); Assert (Is_gray_hd (hd)); Hd_val (v) = Blackhd_hd (hd); size = Wosize_hd(hd); if (Tag_hd (hd) < No_scan_tag){ for (i = 0; i < size; i++){ child = Field (v, i); if (Is_block (child) && Is_in_heap (child)) { hd = Hd_val(child); if (Tag_hd(hd) == Infix_tag) { child -= Infix_offset_val(child); hd = Hd_val(child); } if (Is_white_hd (hd)){ Hd_val (child) = Grayhd_hd (hd); *gray_vals_ptr++ = child; if (gray_vals_ptr >= gray_vals_end) { gray_vals_cur = gray_vals_ptr; realloc_gray_vals (); gray_vals_ptr = gray_vals_cur; } } } } } work -= Whsize_wosize(size); }else if (markhp != NULL){ if (markhp == limit){ chunk = Chunk_next (chunk); if (chunk == NULL){ markhp = NULL; }else{ markhp = chunk; limit = chunk + Chunk_size (chunk); } }else{ if (Is_gray_val (Val_hp (markhp))){ Assert (gray_vals_ptr == gray_vals); *gray_vals_ptr++ = Val_hp (markhp); } markhp += Bhsize_hp (markhp); } }else if (!heap_is_pure){ heap_is_pure = 1; chunk = heap_start; markhp = chunk; limit = chunk + Chunk_size (chunk); }else if (gc_phase == Phase_mark){ /* The main marking phase is over. Handle finalised values. */ gray_vals_cur = gray_vals_ptr; final_update (); gray_vals_ptr = gray_vals_cur; gc_phase = Phase_mark_final; }else{ /* Marking is done. */ update_weak_pointers (); /* Initialise the sweep phase. */ gray_vals_cur = gray_vals_ptr; gc_sweep_hp = heap_start; fl_init_merge (); gc_phase = Phase_sweep; chunk = heap_start; gc_sweep_hp = chunk; limit = chunk + Chunk_size (chunk); work = 0; } } gray_vals_cur = gray_vals_ptr; } /* Walk through the linked list of weak arrays. Arrays that are white are removed from this list. For the other arrays, pointers to white objects are erased. */ static void update_weak_pointers (void) { value *prev = &weak_list_head; value *cur = (value *) *prev; mlsize_t sz, i; while (cur != NULL){ if (Color_val (cur) == Caml_white){ *prev = Field (cur, 0); cur = (value *) *prev; }else{ value curfield; sz = Wosize_val (cur); for (i = 1; i < sz; i++){ curfield = Field (cur, i); if (curfield != 0 && Is_block (curfield) && Is_white_val (curfield)){ Field (cur, i) = 0; } } prev = &Field (cur, 0); cur = (value *) *prev; } } } static void sweep_slice (long int work) { char *hp; header_t hd; gc_message (0x40, "Sweeping %lu words\n", work); while (work > 0){ if (gc_sweep_hp < limit){ hp = gc_sweep_hp; hd = Hd_hp (hp); work -= Whsize_hd (hd); gc_sweep_hp += Bhsize_hd (hd); switch (Color_hd (hd)){ case Caml_white: if (Tag_hd (hd) == Custom_tag){ void (*final_fun)(value) = Custom_ops_val(Val_hp(hp))->finalize; if (final_fun != NULL) final_fun(Val_hp(hp)); } gc_sweep_hp = fl_merge_block (Bp_hp (hp)); break; case Caml_blue: /* Only the blocks of the free-list are blue. See [freelist.c]. */ fl_merge = Bp_hp (hp); break; default: /* gray or black */ Assert (Color_hd (hd) == Caml_black); Hd_hp (hp) = Whitehd_hd (hd); break; } Assert (gc_sweep_hp <= limit); }else{ chunk = Chunk_next (chunk); if (chunk == NULL){ /* Sweeping is done. */ ++ stat_major_collections; work = 0; gc_phase = Phase_idle; }else{ gc_sweep_hp = chunk; limit = chunk + Chunk_size (chunk); } } } } /* The main entry point for the GC. Called after each minor GC. */ void major_collection_slice (void) { double p; /* Free memory at the start of the GC cycle (garbage + free list) (assumed): FM = stat_heap_size * percent_free / (100 + percent_free) Garbage at the start of the GC cycle: G = FM * 2/3 Proportion of free memory consumed since the previous slice: PH = allocated_words / G = 3 * allocated_words * (100 + percent_free) / (2 * stat_heap_size * percent_free) Proportion of extra-heap memory consumed since the previous slice: PE = extra_heap_memory Proportion of total work to do in this slice: P = max (PH, PE) Amount of marking work for the GC cycle: MW = stat_heap_size * 100 / (100 + percent_free) Amount of sweeping work for the GC cycle: SW = stat_heap_size Amount of marking work for this slice: MS = P * MW MS = P * stat_heap_size * 100 / (100 + percent_free) Amount of sweeping work for this slice: SS = P * SW SS = P * stat_heap_size This slice will either mark 2*MS words or sweep 2*SS words. */ #define Margin 100 /* Make it a little faster to be on the safe side. */ if (gc_phase == Phase_idle) start_cycle (); p = 1.5 * allocated_words * (100 + percent_free) / stat_heap_size / percent_free; if (p < extra_heap_memory) p = extra_heap_memory; gc_message (0x40, "allocated_words = %lu\n", allocated_words); gc_message (0x40, "extra_heap_memory = %luu\n", (unsigned long) (extra_heap_memory * 1000000)); gc_message (0x40, "amount of work to do = %luu\n", (unsigned long) (p * 1000000)); if (gc_phase == Phase_mark || gc_phase == Phase_mark_final){ long work = (long) (p * stat_heap_size * 100 / (100+percent_free)) + Margin; mark_slice (work); gc_message (0x02, "!", 0); }else{ long work = (long) (p * stat_heap_size) + Margin; Assert (gc_phase == Phase_sweep); sweep_slice (work); gc_message (0x02, "$", 0); } if (gc_phase == Phase_idle) compact_heap_maybe (); stat_major_words += allocated_words; allocated_words = 0; extra_heap_memory = 0.0; } /* The minor heap must be empty when this function is called; the minor heap is empty when this function returns. */ /* This does not call compact_heap_maybe because the estimations of free and live memory are only valid for a cycle done incrementally. Besides, this function is called by compact_heap_maybe. */ void finish_major_cycle (void) { if (gc_phase == Phase_idle) start_cycle (); if (gc_phase == Phase_mark) mark_slice (LONG_MAX); Assert (gc_phase == Phase_sweep); sweep_slice (LONG_MAX); Assert (gc_phase == Phase_idle); stat_major_words += allocated_words; allocated_words = 0; } asize_t round_heap_chunk_size (asize_t request) { Assert (major_heap_increment >= Heap_chunk_min); if (request < major_heap_increment){ Assert (major_heap_increment % Page_size == 0); return major_heap_increment; }else if (request <= Heap_chunk_max){ return ((request + Page_size - 1) >> Page_log) << Page_log; }else{ raise_out_of_memory (); /* not reached */ return 0; } } void init_major_heap (asize_t heap_size) { asize_t i; void *block; asize_t page_table_size; page_table_entry *page_table_block; stat_heap_size = round_heap_chunk_size (heap_size); Assert (stat_heap_size % Page_size == 0); heap_start = aligned_malloc (stat_heap_size + sizeof (heap_chunk_head), sizeof (heap_chunk_head), &block); if (heap_start == NULL) fatal_error ("Fatal error: not enough memory for the initial heap.\n"); heap_start += sizeof (heap_chunk_head); Assert ((unsigned long) heap_start % Page_size == 0); Chunk_size (heap_start) = stat_heap_size; Chunk_next (heap_start) = NULL; Chunk_block (heap_start) = block; heap_end = heap_start + stat_heap_size; Assert ((unsigned long) heap_end % Page_size == 0); page_low = Page (heap_start); page_high = Page (heap_end); page_table_size = page_high - page_low; page_table_block = (page_table_entry *) malloc (page_table_size * sizeof (page_table_entry)); if (page_table_block == NULL){ fatal_error ("Fatal error: not enough memory for the initial heap.\n"); } page_table = page_table_block - page_low; for (i = Page (heap_start); i < Page (heap_end); i++){ page_table [i] = In_heap; } Hd_hp (heap_start) = Make_header (Wosize_bhsize (stat_heap_size), 0, Caml_blue); fl_init_merge (); fl_merge_block (Bp_hp (heap_start)); gc_phase = Phase_idle; gray_vals_size = 2048; gray_vals = (value *) malloc (gray_vals_size * sizeof (value)); if (gray_vals == NULL) fatal_error ("Fatal error: not enough memory for the initial heap.\n"); gray_vals_cur = gray_vals; gray_vals_end = gray_vals + gray_vals_size; heap_is_pure = 1; allocated_words = 0; extra_heap_memory = 0.0; }