ocaml/byterun/memory.c

#include <string.h>
#include "fail.h"
#include "freelist.h"
#include "gc.h"
#include "gc_ctrl.h"
#include "major_gc.h"
#include "memory.h"
#include "minor_gc.h"
#include "misc.h"
#include "mlvalues.h"

/* Allocate more memory from malloc for the heap.
   Return a block of at least the requested size (in words).
   Return NULL when out of memory.
*/
static char *expand_heap (request)
     mlsize_t request;
{
  char *mem;
  char *new_page_table;
  asize_t new_page_table_size;
  asize_t malloc_request;
  asize_t i, more_pages;

  malloc_request = round_heap_chunk_size (Bhsize_wosize (request));
  gc_message ("Growing heap to %ldk\n",
	      (stat_heap_size + malloc_request) / 1024);
  mem = aligned_malloc (malloc_request + sizeof (heap_chunk_head),
                        sizeof (heap_chunk_head));
  if (mem == NULL){
    gc_message ("No room for growing heap\n", 0);
    return NULL;
  }
  mem += sizeof (heap_chunk_head);
  (((heap_chunk_head *) mem) [-1]).size = malloc_request;
  Assert (Wosize_bhsize (malloc_request) >= request);
  Hd_hp (mem) = Make_header (Wosize_bhsize (malloc_request), 0, Blue);

  if (mem < heap_start){
    more_pages = -Page (mem);
  }else if (Page (mem + malloc_request) > page_table_size){
    Assert (mem >= heap_end);
    more_pages = Page (mem + malloc_request) - page_table_size;
  }else{
    more_pages = 0;
  }

  if (more_pages != 0){
    new_page_table_size = page_table_size + more_pages;
    new_page_table = (char *) malloc (new_page_table_size);
    if (new_page_table == NULL){
      gc_message ("No room for growing page table\n", 0);
      free (mem);
      return NULL;
    }
  } else {
    new_page_table = NULL;
    new_page_table_size = 0;
  }

  if (mem < heap_start){
    Assert (more_pages != 0);
    for (i = 0; i < more_pages; i++){
      new_page_table [i] = Not_in_heap;
    }
    bcopy (page_table, new_page_table + more_pages, page_table_size);
    (((heap_chunk_head *) mem) [-1]).next = heap_start;
    heap_start = mem;
  }else{
    char **last;
    char *cur;

    if (mem >= heap_end) heap_end = mem + malloc_request;
    if (more_pages != 0){
      for (i = page_table_size; i < new_page_table_size; i++){
        new_page_table [i] = Not_in_heap;
      }
      bcopy (page_table, new_page_table, page_table_size);
    }
    last = &heap_start;
    cur = *last;
    while (cur != NULL && cur < mem){
      last = &((((heap_chunk_head *) cur) [-1]).next);
      cur = *last;
    }
    (((heap_chunk_head *) mem) [-1]).next = cur;
    *last = mem;
  }

  if (more_pages != 0){
    free (page_table);
    page_table = new_page_table;
    page_table_size = new_page_table_size;
  }

  for (i = Page (mem); i < Page (mem + malloc_request); i++){
    page_table [i] = In_heap;
  }
  stat_heap_size += malloc_request;
  return Bp_hp (mem);
}

value alloc_shr (wosize, tag)
     mlsize_t wosize;
     tag_t tag;
{
  char *hp, *new_block;

  hp = fl_allocate (wosize);
  if (hp == NULL){
    new_block = expand_heap (wosize);
    if (new_block == NULL) raise_out_of_memory ();
    fl_add_block (new_block);
    hp = fl_allocate (wosize);
  }

  Assert (Is_in_heap (Val_hp (hp)));

  if (gc_phase == Phase_mark || (addr)hp >= (addr)gc_sweep_hp){
    Hd_hp (hp) = Make_header (wosize, tag, Black);
  }else{
    Hd_hp (hp) = Make_header (wosize, tag, White);
  }
  allocated_words += Whsize_wosize (wosize);
  if (allocated_words > Wsize_bsize (minor_heap_size)) force_minor_gc ();
  return Val_hp (hp);
}

/* Use this function to tell the major GC to speed up when you use
   finalized objects to automatically deallocate extra-heap objects.
   The GC will do at least one cycle every [max] allocated words;
   [mem] is the number of words allocated this time.
   Note that only [mem/max] is relevant.  You can use numbers of bytes
   (or kilobytes, ...) instead of words.  You can change units between
   calls to [adjust_collector_speed].
*/
void adjust_gc_speed (mem, max)
     mlsize_t mem, max;
{
  if (max == 0) max = 1;
  if (mem > max) mem = max;
  extra_heap_memory += ((float) mem / max) * stat_heap_size;
  if (extra_heap_memory > stat_heap_size){
    extra_heap_memory = stat_heap_size;
  }
  if (extra_heap_memory > Wsize_bsize (minor_heap_size) / 2) force_minor_gc ();
}

/* You must use [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.
*/
/* [initialize] never calls the GC, so you may call it while an object is
   unfinished (i.e. just after a call to [alloc_shr].) */
void initialize (fp, val)
     value *fp;
     value val;
{
  *fp = val;
  Assert (Is_in_heap (fp));
  if (Is_block (val) && Is_young (val)){
    *ref_table_ptr++ = fp;
    if (ref_table_ptr >= ref_table_limit){
      realloc_ref_table ();
    }
  }
}

/* You must use [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. */
/* [modify] never calls the GC. */
void modify (fp, val)
     value *fp;
     value val;
{
  Modify (fp, val);
}

char *stat_alloc (sz)
     asize_t sz;
{
  char *result = (char *) malloc (sz);

  if (result == NULL) raise_out_of_memory ();
  return result;
}

void stat_free (blk)
     char * blk;
{
  free (blk);
}

char *stat_resize (blk, sz)
     char *blk;
     asize_t sz;
{
  char *result = (char *) realloc (blk, sz);

  if (result == NULL) raise_out_of_memory ();
  return result;
}
Passage a la version bootstrappee (franchissement du Rubicon) git-svn-id: http://caml.inria.fr/svn/ocaml/trunk@2 f963ae5c-01c2-4b8c-9fe0-0dff7051ff02 1995-05-04 03:15:53 -07:00			`#include <string.h>`
			`#include "fail.h"`
			`#include "freelist.h"`
			`#include "gc.h"`
			`#include "gc_ctrl.h"`
			`#include "major_gc.h"`
			`#include "memory.h"`
			`#include "minor_gc.h"`
			`#include "misc.h"`
			`#include "mlvalues.h"`

			`/* Allocate more memory from malloc for the heap.`
			`Return a block of at least the requested size (in words).`
			`Return NULL when out of memory.`
			`*/`
			`static char *expand_heap (request)`
			`mlsize_t request;`
			`{`
			`char *mem;`
			`char *new_page_table;`
			`asize_t new_page_table_size;`
			`asize_t malloc_request;`
			`asize_t i, more_pages;`

			`malloc_request = round_heap_chunk_size (Bhsize_wosize (request));`
			`gc_message ("Growing heap to %ldk\n",`
			`(stat_heap_size + malloc_request) / 1024);`
			`mem = aligned_malloc (malloc_request + sizeof (heap_chunk_head),`
			`sizeof (heap_chunk_head));`
			`if (mem == NULL){`
			`gc_message ("No room for growing heap\n", 0);`
			`return NULL;`
			`}`
			`mem += sizeof (heap_chunk_head);`
			`(((heap_chunk_head *) mem) [-1]).size = malloc_request;`
			`Assert (Wosize_bhsize (malloc_request) >= request);`
			`Hd_hp (mem) = Make_header (Wosize_bhsize (malloc_request), 0, Blue);`

			`if (mem < heap_start){`
			`more_pages = -Page (mem);`
			`}else if (Page (mem + malloc_request) > page_table_size){`
			`Assert (mem >= heap_end);`
			`more_pages = Page (mem + malloc_request) - page_table_size;`
			`}else{`
			`more_pages = 0;`
			`}`

			`if (more_pages != 0){`
			`new_page_table_size = page_table_size + more_pages;`
			`new_page_table = (char *) malloc (new_page_table_size);`
			`if (new_page_table == NULL){`
			`gc_message ("No room for growing page table\n", 0);`
			`free (mem);`
			`return NULL;`
			`}`
			`} else {`
			`new_page_table = NULL;`
			`new_page_table_size = 0;`
			`}`

			`if (mem < heap_start){`
			`Assert (more_pages != 0);`
			`for (i = 0; i < more_pages; i++){`
			`new_page_table [i] = Not_in_heap;`
			`}`
			`bcopy (page_table, new_page_table + more_pages, page_table_size);`
			`(((heap_chunk_head *) mem) [-1]).next = heap_start;`
			`heap_start = mem;`
			`}else{`
			`char **last;`
			`char *cur;`

			`if (mem >= heap_end) heap_end = mem + malloc_request;`
			`if (more_pages != 0){`
			`for (i = page_table_size; i < new_page_table_size; i++){`
			`new_page_table [i] = Not_in_heap;`
			`}`
			`bcopy (page_table, new_page_table, page_table_size);`
			`}`
			`last = &heap_start;`
			`cur = *last;`
			`while (cur != NULL && cur < mem){`
			`last = &((((heap_chunk_head *) cur) [-1]).next);`
			`cur = *last;`
			`}`
			`(((heap_chunk_head *) mem) [-1]).next = cur;`
			`*last = mem;`
			`}`

			`if (more_pages != 0){`
			`free (page_table);`
			`page_table = new_page_table;`
			`page_table_size = new_page_table_size;`
			`}`

			`for (i = Page (mem); i < Page (mem + malloc_request); i++){`
			`page_table [i] = In_heap;`
			`}`
			`stat_heap_size += malloc_request;`
			`return Bp_hp (mem);`
			`}`

			`value alloc_shr (wosize, tag)`
			`mlsize_t wosize;`
			`tag_t tag;`
			`{`
			`char hp, new_block;`

			`hp = fl_allocate (wosize);`
			`if (hp == NULL){`
			`new_block = expand_heap (wosize);`
			`if (new_block == NULL) raise_out_of_memory ();`
			`fl_add_block (new_block);`
			`hp = fl_allocate (wosize);`
			`}`

			`Assert (Is_in_heap (Val_hp (hp)));`

			`if (gc_phase == Phase_mark \|\| (addr)hp >= (addr)gc_sweep_hp){`
			`Hd_hp (hp) = Make_header (wosize, tag, Black);`
			`}else{`
			`Hd_hp (hp) = Make_header (wosize, tag, White);`
			`}`
			`allocated_words += Whsize_wosize (wosize);`
			`if (allocated_words > Wsize_bsize (minor_heap_size)) force_minor_gc ();`
			`return Val_hp (hp);`
			`}`

			`/* Use this function to tell the major GC to speed up when you use`
			`finalized objects to automatically deallocate extra-heap objects.`
			`The GC will do at least one cycle every [max] allocated words;`
			`[mem] is the number of words allocated this time.`
			`Note that only [mem/max] is relevant. You can use numbers of bytes`
			`(or kilobytes, ...) instead of words. You can change units between`
			`calls to [adjust_collector_speed].`
			`*/`
			`void adjust_gc_speed (mem, max)`
			`mlsize_t mem, max;`
			`{`
			`if (max == 0) max = 1;`
			`if (mem > max) mem = max;`
			`extra_heap_memory += ((float) mem / max) * stat_heap_size;`
			`if (extra_heap_memory > stat_heap_size){`
			`extra_heap_memory = stat_heap_size;`
			`}`
			`if (extra_heap_memory > Wsize_bsize (minor_heap_size) / 2) force_minor_gc ();`
			`}`

			`/* You must use [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.`
			`*/`
			`/* [initialize] never calls the GC, so you may call it while an object is`
			`unfinished (i.e. just after a call to [alloc_shr].) */`
			`void initialize (fp, val)`
			`value *fp;`
			`value val;`
			`{`
			`*fp = val;`
			`Assert (Is_in_heap (fp));`
			`if (Is_block (val) && Is_young (val)){`
			`*ref_table_ptr++ = fp;`
			`if (ref_table_ptr >= ref_table_limit){`
			`realloc_ref_table ();`
			`}`
			`}`
			`}`

			`/* You must use [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. */`
			`/* [modify] never calls the GC. */`
			`void modify (fp, val)`
			`value *fp;`
			`value val;`
			`{`
			`Modify (fp, val);`
			`}`

			`char *stat_alloc (sz)`
			`asize_t sz;`
			`{`
			`char result = (char ) malloc (sz);`

			`if (result == NULL) raise_out_of_memory ();`
			`return result;`
			`}`

			`void stat_free (blk)`
			`char * blk;`
			`{`
			`free (blk);`
			`}`

			`char *stat_resize (blk, sz)`
			`char *blk;`
			`asize_t sz;`
			`{`
			`char result = (char ) realloc (blk, sz);`

			`if (result == NULL) raise_out_of_memory ();`
			`return result;`
			`}`