604 lines
18 KiB
C
604 lines
18 KiB
C
/***********************************************************************/
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/* */
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/* OCaml */
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/* */
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/* Damien Doligez, projet Para, INRIA Rocquencourt */
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/* */
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/* Copyright 1996 Institut National de Recherche en Informatique et */
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/* en Automatique. All rights reserved. This file is distributed */
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/* under the terms of the GNU Library General Public License, with */
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/* the special exception on linking described in file ../LICENSE. */
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/* */
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/***********************************************************************/
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#include <stdlib.h>
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#include <string.h>
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#include "fail.h"
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#include "freelist.h"
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#include "gc.h"
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#include "gc_ctrl.h"
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#include "major_gc.h"
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#include "memory.h"
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#include "major_gc.h"
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#include "minor_gc.h"
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#include "misc.h"
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#include "mlvalues.h"
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#include "signals.h"
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extern uintnat caml_percent_free; /* major_gc.c */
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/* Page table management */
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#define Page(p) ((uintnat) (p) >> Page_log)
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#define Page_mask ((uintnat) -1 << Page_log)
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#ifdef ARCH_SIXTYFOUR
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/* 64-bit implementation:
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The page table is represented sparsely as a hash table
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with linear probing */
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struct page_table {
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mlsize_t size; /* size == 1 << (wordsize - shift) */
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int shift;
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mlsize_t mask; /* mask == size - 1 */
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mlsize_t occupancy;
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uintnat * entries; /* [size] */
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};
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static struct page_table caml_page_table;
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/* Page table entries are the logical 'or' of
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- the key: address of a page (low Page_log bits = 0)
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- the data: a 8-bit integer */
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#define Page_entry_matches(entry,addr) \
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((((entry) ^ (addr)) & Page_mask) == 0)
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/* Multiplicative Fibonacci hashing
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(Knuth, TAOCP vol 3, section 6.4, page 518).
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HASH_FACTOR is (sqrt(5) - 1) / 2 * 2^wordsize. */
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#ifdef ARCH_SIXTYFOUR
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#define HASH_FACTOR 11400714819323198486UL
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#else
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#define HASH_FACTOR 2654435769UL
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#endif
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#define Hash(v) (((v) * HASH_FACTOR) >> caml_page_table.shift)
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int caml_page_table_lookup(void * addr)
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{
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uintnat h, e;
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h = Hash(Page(addr));
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/* The first hit is almost always successful, so optimize for this case */
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e = caml_page_table.entries[h];
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if (Page_entry_matches(e, (uintnat)addr)) return e & 0xFF;
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while(1) {
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if (e == 0) return 0;
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h = (h + 1) & caml_page_table.mask;
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e = caml_page_table.entries[h];
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if (Page_entry_matches(e, (uintnat)addr)) return e & 0xFF;
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}
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}
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int caml_page_table_initialize(mlsize_t bytesize)
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{
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uintnat pagesize = Page(bytesize);
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caml_page_table.size = 1;
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caml_page_table.shift = 8 * sizeof(uintnat);
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/* Aim for initial load factor between 1/4 and 1/2 */
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while (caml_page_table.size < 2 * pagesize) {
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caml_page_table.size <<= 1;
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caml_page_table.shift -= 1;
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}
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caml_page_table.mask = caml_page_table.size - 1;
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caml_page_table.occupancy = 0;
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caml_page_table.entries = calloc(caml_page_table.size, sizeof(uintnat));
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if (caml_page_table.entries == NULL)
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return -1;
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else
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return 0;
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}
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static int caml_page_table_resize(void)
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{
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struct page_table old = caml_page_table;
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uintnat * new_entries;
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uintnat i, h;
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caml_gc_message (0x08, "Growing page table to %lu entries\n",
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caml_page_table.size);
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new_entries = calloc(2 * old.size, sizeof(uintnat));
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if (new_entries == NULL) {
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caml_gc_message (0x08, "No room for growing page table\n", 0);
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return -1;
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}
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caml_page_table.size = 2 * old.size;
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caml_page_table.shift = old.shift - 1;
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caml_page_table.mask = caml_page_table.size - 1;
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caml_page_table.occupancy = old.occupancy;
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caml_page_table.entries = new_entries;
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for (i = 0; i < old.size; i++) {
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uintnat e = old.entries[i];
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if (e == 0) continue;
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h = Hash(Page(e));
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while (caml_page_table.entries[h] != 0)
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h = (h + 1) & caml_page_table.mask;
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caml_page_table.entries[h] = e;
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}
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free(old.entries);
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return 0;
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}
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static int caml_page_table_modify(uintnat page, int toclear, int toset)
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{
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uintnat h;
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Assert ((page & ~Page_mask) == 0);
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/* Resize to keep load factor below 1/2 */
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if (caml_page_table.occupancy * 2 >= caml_page_table.size) {
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if (caml_page_table_resize() != 0) return -1;
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}
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h = Hash(Page(page));
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while (1) {
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if (caml_page_table.entries[h] == 0) {
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caml_page_table.entries[h] = page | toset;
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caml_page_table.occupancy++;
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break;
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}
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if (Page_entry_matches(caml_page_table.entries[h], page)) {
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caml_page_table.entries[h] =
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(caml_page_table.entries[h] & ~toclear) | toset;
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break;
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}
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h = (h + 1) & caml_page_table.mask;
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}
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return 0;
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}
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#else
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/* 32-bit implementation:
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The page table is represented as a 2-level array of unsigned char */
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CAMLexport unsigned char * caml_page_table[Pagetable1_size];
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static unsigned char caml_page_table_empty[Pagetable2_size] = { 0, };
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int caml_page_table_initialize(mlsize_t bytesize)
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{
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int i;
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for (i = 0; i < Pagetable1_size; i++)
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caml_page_table[i] = caml_page_table_empty;
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return 0;
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}
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static int caml_page_table_modify(uintnat page, int toclear, int toset)
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{
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uintnat i = Pagetable_index1(page);
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uintnat j = Pagetable_index2(page);
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if (caml_page_table[i] == caml_page_table_empty) {
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unsigned char * new_tbl = calloc(Pagetable2_size, 1);
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if (new_tbl == 0) return -1;
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caml_page_table[i] = new_tbl;
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}
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caml_page_table[i][j] = (caml_page_table[i][j] & ~toclear) | toset;
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return 0;
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}
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#endif
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int caml_page_table_add(int kind, void * start, void * end)
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{
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uintnat pstart = (uintnat) start & Page_mask;
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uintnat pend = ((uintnat) end - 1) & Page_mask;
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uintnat p;
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for (p = pstart; p <= pend; p += Page_size)
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if (caml_page_table_modify(p, 0, kind) != 0) return -1;
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return 0;
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}
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int caml_page_table_remove(int kind, void * start, void * end)
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{
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uintnat pstart = (uintnat) start & Page_mask;
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uintnat pend = ((uintnat) end - 1) & Page_mask;
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uintnat p;
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for (p = pstart; p <= pend; p += Page_size)
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if (caml_page_table_modify(p, kind, 0) != 0) return -1;
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return 0;
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}
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/* Allocate a block of the requested size, to be passed to
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[caml_add_to_heap] later.
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[request] must be a multiple of [Page_size].
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[caml_alloc_for_heap] returns NULL if the request cannot be satisfied.
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The returned pointer is a hp, but the header must be initialized by
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the caller.
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*/
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char *caml_alloc_for_heap (asize_t request)
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{
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char *mem;
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void *block;
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Assert (request % Page_size == 0);
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mem = caml_aligned_malloc (request + sizeof (heap_chunk_head),
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sizeof (heap_chunk_head), &block);
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if (mem == NULL) return NULL;
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mem += sizeof (heap_chunk_head);
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Chunk_size (mem) = request;
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Chunk_block (mem) = block;
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return mem;
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}
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/* Use this function to free a block allocated with [caml_alloc_for_heap]
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if you don't add it with [caml_add_to_heap].
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*/
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void caml_free_for_heap (char *mem)
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{
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free (Chunk_block (mem));
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}
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/* Take a chunk of memory as argument, which must be the result of a
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call to [caml_alloc_for_heap], and insert it into the heap chaining.
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The contents of the chunk must be a sequence of valid blocks and
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fragments: no space between blocks and no trailing garbage. If
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some blocks are blue, they must be added to the free list by the
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caller. All other blocks must have the color [caml_allocation_color(m)].
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The caller must update [caml_allocated_words] if applicable.
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Return value: 0 if no error; -1 in case of error.
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See also: caml_compact_heap, which duplicates most of this function.
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*/
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int caml_add_to_heap (char *m)
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{
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Assert (Chunk_size (m) % Page_size == 0);
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#ifdef DEBUG
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/* Should check the contents of the block. */
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#endif /* debug */
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caml_gc_message (0x04, "Growing heap to %luk bytes\n",
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(caml_stat_heap_size + Chunk_size (m)) / 1024);
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/* Register block in page table */
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if (caml_page_table_add(In_heap, m, m + Chunk_size(m)) != 0)
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return -1;
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/* Chain this heap chunk. */
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{
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char **last = &caml_heap_start;
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char *cur = *last;
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while (cur != NULL && cur < m){
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last = &(Chunk_next (cur));
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cur = *last;
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}
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Chunk_next (m) = cur;
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*last = m;
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++ caml_stat_heap_chunks;
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}
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caml_stat_heap_size += Chunk_size (m);
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if (caml_stat_heap_size > caml_stat_top_heap_size){
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caml_stat_top_heap_size = caml_stat_heap_size;
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}
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return 0;
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}
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/* Allocate more memory from malloc for the heap.
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Return a blue block of at least the requested size.
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The blue block is chained to a sequence of blue blocks (through their
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field 0); the last block of the chain is pointed by field 1 of the
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first. There may be a fragment after the last block.
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The caller must insert the blocks into the free list.
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The request must be less than or equal to Max_wosize.
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Return NULL when out of memory.
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*/
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static char *expand_heap (mlsize_t request)
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{
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char *mem, *hp, *prev;
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asize_t over_request, malloc_request, remain;
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Assert (request <= Max_wosize);
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over_request = request + request / 100 * caml_percent_free;
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malloc_request = caml_round_heap_chunk_size (Bhsize_wosize (over_request));
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mem = caml_alloc_for_heap (malloc_request);
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if (mem == NULL){
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caml_gc_message (0x04, "No room for growing heap\n", 0);
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return NULL;
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}
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remain = malloc_request;
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prev = hp = mem;
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/* FIXME find a way to do this with a call to caml_make_free_blocks */
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while (Wosize_bhsize (remain) > Max_wosize){
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Hd_hp (hp) = Make_header (Max_wosize, 0, Caml_blue);
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#ifdef DEBUG
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caml_set_fields (Bp_hp (hp), 0, Debug_free_major);
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#endif
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hp += Bhsize_wosize (Max_wosize);
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remain -= Bhsize_wosize (Max_wosize);
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Field (Op_hp (mem), 1) = Field (Op_hp (prev), 0) = (value) Op_hp (hp);
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prev = hp;
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}
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if (remain > 1){
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Hd_hp (hp) = Make_header (Wosize_bhsize (remain), 0, Caml_blue);
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#ifdef DEBUG
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caml_set_fields (Bp_hp (hp), 0, Debug_free_major);
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#endif
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Field (Op_hp (mem), 1) = Field (Op_hp (prev), 0) = (value) Op_hp (hp);
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Field (Op_hp (hp), 0) = (value) NULL;
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}else{
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Field (Op_hp (prev), 0) = (value) NULL;
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if (remain == 1) Hd_hp (hp) = Make_header (0, 0, Caml_white);
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}
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Assert (Wosize_hp (mem) >= request);
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if (caml_add_to_heap (mem) != 0){
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caml_free_for_heap (mem);
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return NULL;
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}
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return Bp_hp (mem);
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}
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/* Remove the heap chunk [chunk] from the heap and give the memory back
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to [free].
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*/
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void caml_shrink_heap (char *chunk)
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{
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char **cp;
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/* Never deallocate the first chunk, because caml_heap_start is both the
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first block and the base address for page numbers, and we don't
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want to shift the page table, it's too messy (see above).
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It will never happen anyway, because of the way compaction works.
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(see compact.c)
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*/
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if (chunk == caml_heap_start) return;
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caml_stat_heap_size -= Chunk_size (chunk);
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caml_gc_message (0x04, "Shrinking heap to %luk bytes\n",
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(unsigned long) caml_stat_heap_size / 1024);
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#ifdef DEBUG
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{
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mlsize_t i;
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for (i = 0; i < Wsize_bsize (Chunk_size (chunk)); i++){
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((value *) chunk) [i] = Debug_free_shrink;
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}
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}
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#endif
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-- caml_stat_heap_chunks;
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/* Remove [chunk] from the list of chunks. */
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cp = &caml_heap_start;
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while (*cp != chunk) cp = &(Chunk_next (*cp));
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*cp = Chunk_next (chunk);
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/* Remove the pages of [chunk] from the page table. */
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caml_page_table_remove(In_heap, chunk, chunk + Chunk_size (chunk));
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/* Free the [malloc] block that contains [chunk]. */
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caml_free_for_heap (chunk);
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}
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color_t caml_allocation_color (void *hp)
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{
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if (caml_gc_phase == Phase_mark
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|| (caml_gc_phase == Phase_sweep && (addr)hp >= (addr)caml_gc_sweep_hp)){
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return Caml_black;
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}else{
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Assert (caml_gc_phase == Phase_idle
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|| (caml_gc_phase == Phase_sweep
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&& (addr)hp < (addr)caml_gc_sweep_hp));
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return Caml_white;
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}
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}
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CAMLexport value caml_alloc_shr (mlsize_t wosize, tag_t tag)
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{
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char *hp, *new_block;
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if (wosize > Max_wosize) caml_raise_out_of_memory ();
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hp = caml_fl_allocate (wosize);
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if (hp == NULL){
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new_block = expand_heap (wosize);
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if (new_block == NULL) {
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if (caml_in_minor_collection)
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caml_fatal_error ("Fatal error: out of memory.\n");
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else
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caml_raise_out_of_memory ();
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}
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caml_fl_add_blocks (new_block);
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hp = caml_fl_allocate (wosize);
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}
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Assert (Is_in_heap (Val_hp (hp)));
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/* Inline expansion of caml_allocation_color. */
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if (caml_gc_phase == Phase_mark
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|| (caml_gc_phase == Phase_sweep && (addr)hp >= (addr)caml_gc_sweep_hp)){
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Hd_hp (hp) = Make_header (wosize, tag, Caml_black);
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}else{
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Assert (caml_gc_phase == Phase_idle
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|| (caml_gc_phase == Phase_sweep
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&& (addr)hp < (addr)caml_gc_sweep_hp));
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Hd_hp (hp) = Make_header (wosize, tag, Caml_white);
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}
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Assert (Hd_hp (hp) == Make_header (wosize, tag, caml_allocation_color (hp)));
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caml_allocated_words += Whsize_wosize (wosize);
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if (caml_allocated_words > Wsize_bsize (caml_minor_heap_size)){
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caml_urge_major_slice ();
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}
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#ifdef DEBUG
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{
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uintnat i;
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for (i = 0; i < wosize; i++){
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Field (Val_hp (hp), i) = Debug_uninit_major;
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}
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}
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#endif
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return Val_hp (hp);
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}
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/* Dependent memory is all memory blocks allocated out of the heap
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that depend on the GC (and finalizers) for deallocation.
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For the GC to take dependent memory into account when computing
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its automatic speed setting,
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you must call [caml_alloc_dependent_memory] when you alloate some
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dependent memory, and [caml_free_dependent_memory] when you
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free it. In both cases, you pass as argument the size (in bytes)
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of the block being allocated or freed.
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*/
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CAMLexport void caml_alloc_dependent_memory (mlsize_t nbytes)
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{
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caml_dependent_size += nbytes / sizeof (value);
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caml_dependent_allocated += nbytes / sizeof (value);
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}
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CAMLexport void caml_free_dependent_memory (mlsize_t nbytes)
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{
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if (caml_dependent_size < nbytes / sizeof (value)){
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caml_dependent_size = 0;
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}else{
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caml_dependent_size -= nbytes / sizeof (value);
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}
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}
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/* Use this function to tell the major GC to speed up when you use
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finalized blocks to automatically deallocate resources (other
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than memory). The GC will do at least one cycle every [max]
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allocated resources; [res] is the number of resources allocated
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this time.
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Note that only [res/max] is relevant. The units (and kind of
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resource) can change between calls to [caml_adjust_gc_speed].
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*/
|
|
CAMLexport void caml_adjust_gc_speed (mlsize_t res, mlsize_t max)
|
|
{
|
|
if (max == 0) max = 1;
|
|
if (res > max) res = max;
|
|
caml_extra_heap_resources += (double) res / (double) max;
|
|
if (caml_extra_heap_resources > 1.0){
|
|
caml_extra_heap_resources = 1.0;
|
|
caml_urge_major_slice ();
|
|
}
|
|
if (caml_extra_heap_resources
|
|
> (double) Wsize_bsize (caml_minor_heap_size) / 2.0
|
|
/ (double) Wsize_bsize (caml_stat_heap_size)) {
|
|
caml_urge_major_slice ();
|
|
}
|
|
}
|
|
|
|
/* You must use [caml_initialize] to store the initial value in a field of
|
|
a shared block, unless you are sure the value is not a young block.
|
|
A block value [v] is a shared block if and only if [Is_in_heap (v)]
|
|
is true.
|
|
*/
|
|
/* [caml_initialize] never calls the GC, so you may call it while a block is
|
|
unfinished (i.e. just after a call to [caml_alloc_shr].) */
|
|
/* PR#6084 workaround: define it as a weak symbol */
|
|
CAMLexport CAMLweakdef void caml_initialize (value *fp, value val)
|
|
{
|
|
CAMLassert(Is_in_heap(fp));
|
|
*fp = val;
|
|
if (Is_block (val) && Is_young (val)) {
|
|
if (caml_ref_table.ptr >= caml_ref_table.limit){
|
|
caml_realloc_ref_table (&caml_ref_table);
|
|
}
|
|
*caml_ref_table.ptr++ = fp;
|
|
}
|
|
}
|
|
|
|
/* You must use [caml_modify] to change a field of an existing shared block,
|
|
unless you are sure the value being overwritten is not a shared block and
|
|
the value being written is not a young block. */
|
|
/* [caml_modify] never calls the GC. */
|
|
/* [caml_modify] can also be used to do assignment on data structures that are
|
|
in the minor heap instead of in the major heap. In this case, it
|
|
is a bit slower than simple assignment.
|
|
In particular, you can use [caml_modify] when you don't know whether the
|
|
block being changed is in the minor heap or the major heap. */
|
|
/* PR#6084 workaround: define it as a weak symbol */
|
|
|
|
CAMLexport CAMLweakdef void caml_modify (value *fp, value val)
|
|
{
|
|
/* The write barrier implemented by [caml_modify] checks for the
|
|
following two conditions and takes appropriate action:
|
|
1- a pointer from the major heap to the minor heap is created
|
|
--> add [fp] to the remembered set
|
|
2- a pointer from the major heap to the major heap is overwritten,
|
|
while the GC is in the marking phase
|
|
--> call [caml_darken] on the overwritten pointer so that the
|
|
major GC treats it as an additional root.
|
|
*/
|
|
value old;
|
|
|
|
if (Is_young((value)fp)) {
|
|
/* The modified object resides in the minor heap.
|
|
Conditions 1 and 2 cannot occur. */
|
|
*fp = val;
|
|
} else {
|
|
/* The modified object resides in the major heap. */
|
|
CAMLassert(Is_in_heap(fp));
|
|
old = *fp;
|
|
*fp = val;
|
|
if (Is_block(old)) {
|
|
/* If [old] is a pointer within the minor heap, we already
|
|
have a major->minor pointer and [fp] is already in the
|
|
remembered set. Conditions 1 and 2 cannot occur. */
|
|
if (Is_young(old)) return;
|
|
/* Here, [old] can be a pointer within the major heap.
|
|
Check for condition 2. */
|
|
if (caml_gc_phase == Phase_mark) caml_darken(old, NULL);
|
|
}
|
|
/* Check for condition 1. */
|
|
if (Is_block(val) && Is_young(val)) {
|
|
/* Add [fp] to remembered set */
|
|
if (caml_ref_table.ptr >= caml_ref_table.limit){
|
|
CAMLassert (caml_ref_table.ptr == caml_ref_table.limit);
|
|
caml_realloc_ref_table (&caml_ref_table);
|
|
}
|
|
*caml_ref_table.ptr++ = fp;
|
|
}
|
|
}
|
|
}
|
|
|
|
CAMLexport void * caml_stat_alloc (asize_t sz)
|
|
{
|
|
void * result = malloc (sz);
|
|
|
|
/* malloc() may return NULL if size is 0 */
|
|
if (result == NULL && sz != 0) caml_raise_out_of_memory ();
|
|
#ifdef DEBUG
|
|
memset (result, Debug_uninit_stat, sz);
|
|
#endif
|
|
return result;
|
|
}
|
|
|
|
CAMLexport char * caml_stat_alloc_string(value str)
|
|
{
|
|
mlsize_t sz = caml_string_length(str) + 1;
|
|
char * p = caml_stat_alloc(sz);
|
|
memcpy(p, String_val(str), sz);
|
|
return p;
|
|
}
|
|
|
|
CAMLexport void caml_stat_free (void * blk)
|
|
{
|
|
free (blk);
|
|
}
|
|
|
|
CAMLexport void * caml_stat_resize (void * blk, asize_t sz)
|
|
{
|
|
void * result = realloc (blk, sz);
|
|
|
|
if (result == NULL) caml_raise_out_of_memory ();
|
|
return result;
|
|
}
|