* <ftp://ftp.cs.utexas.edu/pub/garbage/bigsurv.ps>.
*/
-/*
- * FIXME: GC :FULL T seems to be unable to recover a lot of unused
- * space. After cold init is complete, GC :FULL T gets us down to
- * about 44 Mb total used, but PURIFY gets us down to about 17 Mb
- * total used.
- */
-
#include <stdio.h>
#include <signal.h>
+#include <sys/ptrace.h>
+#include <linux/user.h>
+#include <errno.h>
#include "runtime.h"
#include "sbcl.h"
#include "os.h"
#include "lispregs.h"
#include "arch.h"
#include "gc.h"
-#include "gencgc.h"
-
-/* a function defined externally in assembly language, called from
- * this file */
+#include "gc-internal.h"
+#include "genesis/vector.h"
+#include "genesis/weak-pointer.h"
+#include "genesis/simple-fun.h"
+#include "genesis/static-symbols.h"
+#include "genesis/symbol.h"
+/* assembly language stub that executes trap_PendingInterrupt */
void do_pending_interrupt(void);
+
\f
/*
* GC parameters
*/
/* the number of actual generations. (The number of 'struct
- * generation' objects is one more than this, because one serves as
- * scratch when GC'ing.) */
+ * generation' objects is one more than this, because one object
+ * serves as scratch when GC'ing.) */
#define NUM_GENERATIONS 6
/* Should we use page protection to help avoid the scavenging of pages
/* Should we unmap a page and re-mmap it to have it zero filled? */
#if defined(__FreeBSD__) || defined(__OpenBSD__)
-/* Note: this can waste a lot of swap on FreeBSD so don't unmap there.
+/* comment from cmucl-2.4.8: This can waste a lot of swap on FreeBSD
+ * so don't unmap there.
*
- * Presumably this behavior exists on OpenBSD too, so don't unmap
- * there either. -- WHN 20000727 */
+ * The CMU CL comment didn't specify a version, but was probably an
+ * old version of FreeBSD (pre-4.0), so this might no longer be true.
+ * OTOH, if it is true, this behavior might exist on OpenBSD too, so
+ * for now we don't unmap there either. -- WHN 2001-04-07 */
boolean gencgc_unmap_zero = 0;
#else
boolean gencgc_unmap_zero = 1;
/* the minimum size (in bytes) for a large object*/
unsigned large_object_size = 4 * 4096;
-
-/* Should we filter stack/register pointers? This could reduce the
- * number of invalid pointers accepted. KLUDGE: It will probably
- * degrades interrupt safety during object initialization. */
-boolean enable_pointer_filter = 1;
\f
/*
* debugging
*/
-#define gc_abort() lose("GC invariant lost, file \"%s\", line %d", \
- __FILE__, __LINE__)
-/* FIXME: In CMU CL, this was "#if 0" with no explanation. Find out
- * how much it costs to make it "#if 1". If it's not too expensive,
- * keep it. */
-#if 1
-#define gc_assert(ex) do { \
- if (!(ex)) gc_abort(); \
-} while (0)
-#else
-#define gc_assert(ex)
-#endif
/* the verbosity level. All non-error messages are disabled at level 0;
* and only a few rare messages are printed at level 1. */
/* the source and destination generations. These are set before a GC starts
* scavenging. */
-static int from_space;
-static int new_space;
+int from_space;
+int new_space;
+
/* FIXME: It would be nice to use this symbolic constant instead of
* bare 4096 almost everywhere. We could also use an assertion that
* it's equal to getpagesize(). */
+
#define PAGE_BYTES 4096
/* An array of page structures is statically allocated.
* is needed. */
static void *heap_base = NULL;
+
/* Calculate the start address for the given page number. */
-inline void
-*page_address(int page_num)
+inline void *
+page_address(int page_num)
{
return (heap_base + (page_num * 4096));
}
/* a structure to hold the state of a generation */
struct generation {
- /* the first page that gc_alloc checks on its next call */
+ /* the first page that gc_alloc() checks on its next call */
int alloc_start_page;
- /* the first page that gc_alloc_unboxed checks on its next call */
+ /* the first page that gc_alloc_unboxed() checks on its next call */
int alloc_unboxed_start_page;
/* the first page that gc_alloc_large (boxed) considers on its next
* added, in which case a GC could be a waste of time */
double min_av_mem_age;
};
+/* the number of actual generations. (The number of 'struct
+ * generation' objects is one more than this, because one object
+ * serves as scratch when GC'ing.) */
+#define NUM_GENERATIONS 6
/* an array of generation structures. There needs to be one more
* generation structure than actual generations as the oldest
* generation is temporarily raised then lowered. */
-static struct generation generations[NUM_GENERATIONS+1];
+struct generation generations[NUM_GENERATIONS+1];
/* the oldest generation that is will currently be GCed by default.
* Valid values are: 0, 1, ... (NUM_GENERATIONS-1)
* search of the heap. XX Gencgc obviously needs to be better
* integrated with the Lisp code. */
static int last_free_page;
-static int last_used_page = 0;
\f
/*
* miscellaneous heap functions
count_write_protect_generation_pages(int generation)
{
int i;
- int cnt = 0;
+ int count = 0;
for (i = 0; i < last_free_page; i++)
if ((page_table[i].allocated != FREE_PAGE)
&& (page_table[i].gen == generation)
&& (page_table[i].write_protected == 1))
- cnt++;
- return(cnt);
+ count++;
+ return count;
}
-/* Count the number of pages within the given generation */
+/* Count the number of pages within the given generation. */
static int
count_generation_pages(int generation)
{
int i;
- int cnt = 0;
+ int count = 0;
for (i = 0; i < last_free_page; i++)
if ((page_table[i].allocated != 0)
&& (page_table[i].gen == generation))
- cnt++;
- return(cnt);
+ count++;
+ return count;
}
/* Count the number of dont_move pages. */
count_dont_move_pages(void)
{
int i;
- int cnt = 0;
-
- for (i = 0; i < last_free_page; i++)
- if ((page_table[i].allocated != 0)
- && (page_table[i].dont_move != 0))
- cnt++;
- return(cnt);
+ int count = 0;
+ for (i = 0; i < last_free_page; i++) {
+ if ((page_table[i].allocated != 0) && (page_table[i].dont_move != 0)) {
+ ++count;
+ }
+ }
+ return count;
}
/* Work through the pages and add up the number of bytes used for the
* given generation. */
static int
-generation_bytes_allocated (int gen)
+count_generation_bytes_allocated (int gen)
{
int i;
int result = 0;
-
for (i = 0; i < last_free_page; i++) {
if ((page_table[i].allocated != 0) && (page_table[i].gen == gen))
result += page_table[i].bytes_used;
/* Count the number of boxed pages within the given
* generation. */
- if (page_table[j].allocated == BOXED_PAGE) {
+ if (page_table[j].allocated & BOXED_PAGE) {
if (page_table[j].large_object)
large_boxed_cnt++;
else
/* Count the number of unboxed pages within the given
* generation. */
- if (page_table[j].allocated == UNBOXED_PAGE) {
+ if (page_table[j].allocated & UNBOXED_PAGE) {
if (page_table[j].large_object)
large_unboxed_cnt++;
else
}
gc_assert(generations[i].bytes_allocated
- == generation_bytes_allocated(i));
+ == count_generation_bytes_allocated(i));
fprintf(stderr,
" %8d: %5d %5d %5d %5d %8d %5d %8d %4d %3d %7.4f\n",
i,
struct alloc_region boxed_region;
struct alloc_region unboxed_region;
-/* XX hack. Current Lisp code uses the following. Need copying in/out. */
-void *current_region_free_pointer;
-void *current_region_end_addr;
-
/* The generation currently being allocated to. */
static int gc_alloc_generation;
* keeps the allocation contiguous when scavenging the newspace.
*
* The alloc_region should have been closed by a call to
- * gc_alloc_update_page_tables, and will thus be in an empty state.
+ * gc_alloc_update_page_tables(), and will thus be in an empty state.
*
* To assist the scavenging functions write-protected pages are not
* used. Free pages should not be write-protected.
{
int first_page;
int last_page;
- int region_size;
- int restart_page;
int bytes_found;
- int num_pages;
int i;
/*
&& (alloc_region->free_pointer == alloc_region->end_addr));
if (unboxed) {
- restart_page =
+ first_page =
generations[gc_alloc_generation].alloc_unboxed_start_page;
} else {
- restart_page =
+ first_page =
generations[gc_alloc_generation].alloc_start_page;
}
-
- /* Search for a contiguous free region of at least nbytes with the
- * given properties: boxed/unboxed, generation. */
- do {
- first_page = restart_page;
-
- /* First search for a page with at least 32 bytes free, which is
- * not write-protected, and which is not marked dont_move. */
- while ((first_page < NUM_PAGES)
- && (page_table[first_page].allocated != FREE_PAGE) /* not free page */
- && ((unboxed &&
- (page_table[first_page].allocated != UNBOXED_PAGE))
- || (!unboxed &&
- (page_table[first_page].allocated != BOXED_PAGE))
- || (page_table[first_page].large_object != 0)
- || (page_table[first_page].gen != gc_alloc_generation)
- || (page_table[first_page].bytes_used >= (4096-32))
- || (page_table[first_page].write_protected != 0)
- || (page_table[first_page].dont_move != 0)))
- first_page++;
- /* Check for a failure. */
- if (first_page >= NUM_PAGES) {
- fprintf(stderr,
- "Argh! gc_alloc_new_region failed on first_page, nbytes=%d.\n",
- nbytes);
- print_generation_stats(1);
- lose(NULL);
- }
-
- gc_assert(page_table[first_page].write_protected == 0);
-
- /*
- FSHOW((stderr,
- "/first_page=%d bytes_used=%d\n",
- first_page, page_table[first_page].bytes_used));
- */
-
- /* Now search forward to calculate the available region size. It
- * tries to keeps going until nbytes are found and the number of
- * pages is greater than some level. This helps keep down the
- * number of pages in a region. */
- last_page = first_page;
- bytes_found = 4096 - page_table[first_page].bytes_used;
- num_pages = 1;
- while (((bytes_found < nbytes) || (num_pages < 2))
- && (last_page < (NUM_PAGES-1))
- && (page_table[last_page+1].allocated == FREE_PAGE)) {
- last_page++;
- num_pages++;
- bytes_found += 4096;
- gc_assert(page_table[last_page].write_protected == 0);
- }
-
- region_size = (4096 - page_table[first_page].bytes_used)
+ last_page=gc_find_freeish_pages(&first_page,nbytes,unboxed,alloc_region);
+ bytes_found=(4096 - page_table[first_page].bytes_used)
+ 4096*(last_page-first_page);
- gc_assert(bytes_found == region_size);
-
- /*
- FSHOW((stderr,
- "/last_page=%d bytes_found=%d num_pages=%d\n",
- last_page, bytes_found, num_pages));
- */
-
- restart_page = last_page + 1;
- } while ((restart_page < NUM_PAGES) && (bytes_found < nbytes));
-
- /* Check for a failure. */
- if ((restart_page >= NUM_PAGES) && (bytes_found < nbytes)) {
- fprintf(stderr,
- "Argh! gc_alloc_new_region failed on restart_page, nbytes=%d.\n",
- nbytes);
- print_generation_stats(1);
- lose(NULL);
- }
-
- /*
- FSHOW((stderr,
- "/gc_alloc_new_region gen %d: %d bytes: pages %d to %d: addr=%x\n",
- gc_alloc_generation,
- bytes_found,
- first_page,
- last_page,
- page_address(first_page)));
- */
-
/* Set up the alloc_region. */
alloc_region->first_page = first_page;
alloc_region->last_page = last_page;
gc_assert(page_table[first_page].allocated == UNBOXED_PAGE);
else
gc_assert(page_table[first_page].allocated == BOXED_PAGE);
+ page_table[first_page].allocated |= OPEN_REGION_PAGE;
+
gc_assert(page_table[first_page].gen == gc_alloc_generation);
gc_assert(page_table[first_page].large_object == 0);
* broken before!) */
page_table[i].first_object_offset =
alloc_region->start_addr - page_address(i);
+ page_table[i].allocated |= OPEN_REGION_PAGE ;
}
/* Bump up last_free_page. */
last_free_page = last_page+1;
SetSymbolValue(ALLOCATION_POINTER,
(lispobj)(((char *)heap_base) + last_free_page*4096));
- if (last_page+1 > last_used_page)
- last_used_page = last_page+1;
}
}
(*new_areas)[i].size,
first_page,
offset,
- size));*/
+ size);*/
(*new_areas)[i].size += size;
return;
}
}
- /*FSHOW((stderr, "/add_new_area S1 %d %d %d\n", i, c, new_area_start));*/
(*new_areas)[new_areas_index].page = first_page;
(*new_areas)[new_areas_index].offset = offset;
/*
FSHOW((stderr,
- "/gc_alloc_update_page_tables to gen %d:\n",
+ "/gc_alloc_update_page_tables() to gen %d:\n",
gc_alloc_generation));
*/
next_page = first_page+1;
- /* Skip if no bytes were allocated */
+ /* Skip if no bytes were allocated. */
if (alloc_region->free_pointer != alloc_region->start_addr) {
orig_first_page_bytes_used = page_table[first_page].bytes_used;
/* Update the first page. */
/* If the page was free then set up the gen, and
- first_object_offset. */
+ * first_object_offset. */
if (page_table[first_page].bytes_used == 0)
gc_assert(page_table[first_page].first_object_offset == 0);
+ page_table[first_page].allocated &= ~(OPEN_REGION_PAGE);
if (unboxed)
gc_assert(page_table[first_page].allocated == UNBOXED_PAGE);
byte_cnt = 0;
- /* Calc. the number of bytes used in this page. This is not always
- the number of new bytes, unless it was free. */
+ /* Calculate the number of bytes used in this page. This is not
+ * always the number of new bytes, unless it was free. */
more = 0;
if ((bytes_used = (alloc_region->free_pointer - page_address(first_page)))>4096) {
bytes_used = 4096;
byte_cnt += bytes_used;
- /* All the rest of the pages should be free. Need to set their
- first_object_offset pointer to the start of the region, and set
- the bytes_used. */
+ /* All the rest of the pages should be free. We need to set their
+ * first_object_offset pointer to the start of the region, and set
+ * the bytes_used. */
while (more) {
+ page_table[next_page].allocated &= ~(OPEN_REGION_PAGE);
if (unboxed)
gc_assert(page_table[next_page].allocated == UNBOXED_PAGE);
else
gc_assert((byte_cnt- orig_first_page_bytes_used) == region_size);
/* Set the generations alloc restart page to the last page of
- the region. */
+ * the region. */
if (unboxed)
generations[gc_alloc_generation].alloc_unboxed_start_page =
next_page-1;
region_size,
gc_alloc_generation));
*/
- }
- else
- /* No bytes allocated. Unallocate the first_page if there are 0
- bytes_used. */
+ } else {
+ /* There are no bytes allocated. Unallocate the first_page if
+ * there are 0 bytes_used. */
+ page_table[first_page].allocated &= ~(OPEN_REGION_PAGE);
if (page_table[first_page].bytes_used == 0)
page_table[first_page].allocated = FREE_PAGE;
+ }
/* Unallocate any unused pages. */
while (next_page <= alloc_region->last_page) {
next_page++;
}
- /* Reset the alloc_region. */
- alloc_region->first_page = 0;
- alloc_region->last_page = -1;
- alloc_region->start_addr = page_address(0);
- alloc_region->free_pointer = page_address(0);
- alloc_region->end_addr = page_address(0);
+ gc_set_region_empty(alloc_region);
}
static inline void *gc_quick_alloc(int nbytes);
/* Allocate a possibly large object. */
-static void
-*gc_alloc_large(int nbytes, int unboxed, struct alloc_region *alloc_region)
+void *
+gc_alloc_large(int nbytes, int unboxed, struct alloc_region *alloc_region)
{
int first_page;
int last_page;
- int region_size;
- int restart_page;
- int bytes_found;
- int num_pages;
int orig_first_page_bytes_used;
int byte_cnt;
int more;
/*
FSHOW((stderr,
- "/gc_alloc_large for %d bytes from gen %d\n",
+ "/gc_alloc_large() for %d bytes from gen %d\n",
nbytes, gc_alloc_generation));
*/
/* If the object is small, and there is room in the current region
- then allocation it in the current region. */
+ then allocate it in the current region. */
if (!large
&& ((alloc_region->end_addr-alloc_region->free_pointer) >= nbytes))
return gc_quick_alloc(nbytes);
- /* Search for a contiguous free region of at least nbytes. If it's a
- large object then align it on a page boundary by searching for a
- free page. */
-
/* To allow the allocation of small objects without the danger of
using a page in the current boxed region, the search starts after
the current boxed free region. XX could probably keep a page
index ahead of the current region and bumped up here to save a
lot of re-scanning. */
- if (unboxed)
- restart_page = generations[gc_alloc_generation].alloc_large_unboxed_start_page;
- else
- restart_page = generations[gc_alloc_generation].alloc_large_start_page;
- if (restart_page <= alloc_region->last_page)
- restart_page = alloc_region->last_page+1;
-
- do {
- first_page = restart_page;
-
- if (large)
- while ((first_page < NUM_PAGES)
- && (page_table[first_page].allocated != FREE_PAGE))
- first_page++;
- else
- while ((first_page < NUM_PAGES)
- && (page_table[first_page].allocated != FREE_PAGE)
- && ((unboxed &&
- (page_table[first_page].allocated != UNBOXED_PAGE))
- || (!unboxed &&
- (page_table[first_page].allocated != BOXED_PAGE))
- || (page_table[first_page].large_object != 0)
- || (page_table[first_page].gen != gc_alloc_generation)
- || (page_table[first_page].bytes_used >= (4096-32))
- || (page_table[first_page].write_protected != 0)
- || (page_table[first_page].dont_move != 0)))
- first_page++;
-
- if (first_page >= NUM_PAGES) {
- fprintf(stderr,
- "Argh! gc_alloc_large failed (first_page), nbytes=%d.\n",
- nbytes);
- print_generation_stats(1);
- lose(NULL);
- }
-
- gc_assert(page_table[first_page].write_protected == 0);
-
- /*
- FSHOW((stderr,
- "/first_page=%d bytes_used=%d\n",
- first_page, page_table[first_page].bytes_used));
- */
-
- last_page = first_page;
- bytes_found = 4096 - page_table[first_page].bytes_used;
- num_pages = 1;
- while ((bytes_found < nbytes)
- && (last_page < (NUM_PAGES-1))
- && (page_table[last_page+1].allocated == FREE_PAGE)) {
- last_page++;
- num_pages++;
- bytes_found += 4096;
- gc_assert(page_table[last_page].write_protected == 0);
- }
-
- region_size = (4096 - page_table[first_page].bytes_used)
- + 4096*(last_page-first_page);
-
- gc_assert(bytes_found == region_size);
-
- /*
- FSHOW((stderr,
- "/last_page=%d bytes_found=%d num_pages=%d\n",
- last_page, bytes_found, num_pages));
- */
-
- restart_page = last_page + 1;
- } while ((restart_page < NUM_PAGES) && (bytes_found < nbytes));
- /* Check for a failure */
- if ((restart_page >= NUM_PAGES) && (bytes_found < nbytes)) {
- fprintf(stderr,
- "Argh! gc_alloc_large failed (restart_page), nbytes=%d.\n",
- nbytes);
- print_generation_stats(1);
- lose(NULL);
+ if (unboxed) {
+ first_page =
+ generations[gc_alloc_generation].alloc_large_unboxed_start_page;
+ } else {
+ first_page = generations[gc_alloc_generation].alloc_large_start_page;
+ }
+ if (first_page <= alloc_region->last_page) {
+ first_page = alloc_region->last_page+1;
}
- /*
- if (large)
- FSHOW((stderr,
- "/gc_alloc_large gen %d: %d of %d bytes: from pages %d to %d: addr=%x\n",
- gc_alloc_generation,
- nbytes,
- bytes_found,
- first_page,
- last_page,
- page_address(first_page)));
- */
+ last_page=gc_find_freeish_pages(&first_page,nbytes,unboxed,0);
gc_assert(first_page > alloc_region->last_page);
if (unboxed)
last_free_page = last_page+1;
SetSymbolValue(ALLOCATION_POINTER,
(lispobj)(((char *)heap_base) + last_free_page*4096));
- if (last_page+1 > last_used_page)
- last_used_page = last_page+1;
}
return((void *)(page_address(first_page)+orig_first_page_bytes_used));
}
-/* Allocate bytes from the boxed_region. It first checks if there is
- * room, if not then it calls gc_alloc_new_region to find a new region
- * with enough space. A pointer to the start of the region is returned. */
-static void
-*gc_alloc(int nbytes)
+int
+gc_find_freeish_pages(int *restart_page_ptr, int nbytes, int unboxed, struct alloc_region *alloc_region)
+{
+ /* if alloc_region is 0, we assume this is for a potentially large
+ object */
+ int first_page;
+ int last_page;
+ int region_size;
+ int restart_page=*restart_page_ptr;
+ int bytes_found;
+ int num_pages;
+ int large = !alloc_region && (nbytes >= large_object_size);
+
+ /* Search for a contiguous free space of at least nbytes. If it's a
+ large object then align it on a page boundary by searching for a
+ free page. */
+
+ /* To allow the allocation of small objects without the danger of
+ using a page in the current boxed region, the search starts after
+ the current boxed free region. XX could probably keep a page
+ index ahead of the current region and bumped up here to save a
+ lot of re-scanning. */
+
+ do {
+ first_page = restart_page;
+ if (large)
+ while ((first_page < NUM_PAGES)
+ && (page_table[first_page].allocated != FREE_PAGE))
+ first_page++;
+ else
+ while (first_page < NUM_PAGES) {
+ if(page_table[first_page].allocated == FREE_PAGE)
+ break;
+ /* I don't know why we need the gen=0 test, but it
+ * breaks randomly if that's omitted -dan 2003.02.26
+ */
+ if((page_table[first_page].allocated ==
+ (unboxed ? UNBOXED_PAGE : BOXED_PAGE)) &&
+ (page_table[first_page].large_object == 0) &&
+ (gc_alloc_genration == 0) &&
+ (page_table[first_page].gen == gc_alloc_generation) &&
+ (page_table[first_page].bytes_used < (4096-32)) &&
+ (page_table[first_page].write_protected == 0) &&
+ (page_table[first_page].dont_move == 0))
+ break;
+ first_page++;
+ }
+
+ if (first_page >= NUM_PAGES) {
+ fprintf(stderr,
+ "Argh! gc_find_free_space failed (first_page), nbytes=%d.\n",
+ nbytes);
+ print_generation_stats(1);
+ lose(NULL);
+ }
+
+ gc_assert(page_table[first_page].write_protected == 0);
+
+ last_page = first_page;
+ bytes_found = 4096 - page_table[first_page].bytes_used;
+ num_pages = 1;
+ while (((bytes_found < nbytes)
+ || (alloc_region && (num_pages < 2)))
+ && (last_page < (NUM_PAGES-1))
+ && (page_table[last_page+1].allocated == FREE_PAGE)) {
+ last_page++;
+ num_pages++;
+ bytes_found += 4096;
+ gc_assert(page_table[last_page].write_protected == 0);
+ }
+
+ region_size = (4096 - page_table[first_page].bytes_used)
+ + 4096*(last_page-first_page);
+
+ gc_assert(bytes_found == region_size);
+ restart_page = last_page + 1;
+ } while ((restart_page < NUM_PAGES) && (bytes_found < nbytes));
+
+ /* Check for a failure */
+ if ((restart_page >= NUM_PAGES) && (bytes_found < nbytes)) {
+ fprintf(stderr,
+ "Argh! gc_find_freeish_pages failed (restart_page), nbytes=%d.\n",
+ nbytes);
+ print_generation_stats(1);
+ lose(NULL);
+ }
+ *restart_page_ptr=first_page;
+ return last_page;
+}
+
+/* Allocate bytes. All the rest of the special-purpose allocation
+ * functions will eventually call this (instead of just duplicating
+ * parts of its code) */
+
+void *
+gc_alloc_with_region(int nbytes,int unboxed_p, struct alloc_region *my_region,
+ int quick_p)
{
void *new_free_pointer;
/* FSHOW((stderr, "/gc_alloc %d\n", nbytes)); */
/* Check whether there is room in the current alloc region. */
- new_free_pointer = boxed_region.free_pointer + nbytes;
+ new_free_pointer = my_region->free_pointer + nbytes;
- if (new_free_pointer <= boxed_region.end_addr) {
+ if (new_free_pointer <= my_region->end_addr) {
/* If so then allocate from the current alloc region. */
- void *new_obj = boxed_region.free_pointer;
- boxed_region.free_pointer = new_free_pointer;
-
- /* Check whether the alloc region is almost empty. */
- if ((boxed_region.end_addr - boxed_region.free_pointer) <= 32) {
- /* If so finished with the current region. */
- gc_alloc_update_page_tables(0, &boxed_region);
+ void *new_obj = my_region->free_pointer;
+ my_region->free_pointer = new_free_pointer;
+
+ /* Unless a `quick' alloc was requested, check whether the
+ alloc region is almost empty. */
+ if (!quick_p &&
+ (my_region->end_addr - my_region->free_pointer) <= 32) {
+ /* If so, finished with the current region. */
+ gc_alloc_update_page_tables(unboxed_p, my_region);
/* Set up a new region. */
- gc_alloc_new_region(32, 0, &boxed_region);
+ gc_alloc_new_region(32 /*bytes*/, unboxed_p, my_region);
}
+
return((void *)new_obj);
}
/* If there some room left in the current region, enough to be worth
* saving, then allocate a large object. */
/* FIXME: "32" should be a named parameter. */
- if ((boxed_region.end_addr-boxed_region.free_pointer) > 32)
- return gc_alloc_large(nbytes, 0, &boxed_region);
+ if ((my_region->end_addr-my_region->free_pointer) > 32)
+ return gc_alloc_large(nbytes, unboxed_p, my_region);
/* Else find a new region. */
/* Finished with the current region. */
- gc_alloc_update_page_tables(0, &boxed_region);
+ gc_alloc_update_page_tables(unboxed_p, my_region);
/* Set up a new region. */
- gc_alloc_new_region(nbytes, 0, &boxed_region);
+ gc_alloc_new_region(nbytes, unboxed_p, my_region);
/* Should now be enough room. */
/* Check whether there is room in the current region. */
- new_free_pointer = boxed_region.free_pointer + nbytes;
+ new_free_pointer = my_region->free_pointer + nbytes;
- if (new_free_pointer <= boxed_region.end_addr) {
+ if (new_free_pointer <= my_region->end_addr) {
/* If so then allocate from the current region. */
- void *new_obj = boxed_region.free_pointer;
- boxed_region.free_pointer = new_free_pointer;
-
+ void *new_obj = my_region->free_pointer;
+ my_region->free_pointer = new_free_pointer;
/* Check whether the current region is almost empty. */
- if ((boxed_region.end_addr - boxed_region.free_pointer) <= 32) {
+ if ((my_region->end_addr - my_region->free_pointer) <= 32) {
/* If so find, finished with the current region. */
- gc_alloc_update_page_tables(0, &boxed_region);
+ gc_alloc_update_page_tables(unboxed_p, my_region);
/* Set up a new region. */
- gc_alloc_new_region(32, 0, &boxed_region);
+ gc_alloc_new_region(32, unboxed_p, my_region);
}
return((void *)new_obj);
return((void *) NIL); /* dummy value: return something ... */
}
-/* Allocate space from the boxed_region. If there is not enough free
- * space then call gc_alloc to do the job. A pointer to the start of
- * the region is returned. */
-static inline void
-*gc_quick_alloc(int nbytes)
+void *
+gc_general_alloc(int nbytes,int unboxed_p,int quick_p)
{
- void *new_free_pointer;
+ struct alloc_region *my_region =
+ unboxed_p ? &unboxed_region : &boxed_region;
+ return gc_alloc_with_region(nbytes,unboxed_p, my_region,quick_p);
+}
- /* Check whether there is room in the current region. */
- new_free_pointer = boxed_region.free_pointer + nbytes;
- if (new_free_pointer <= boxed_region.end_addr) {
- /* If so then allocate from the current region. */
- void *new_obj = boxed_region.free_pointer;
- boxed_region.free_pointer = new_free_pointer;
- return((void *)new_obj);
- }
- /* Else call gc_alloc */
- return (gc_alloc(nbytes));
+static void *
+gc_alloc(int nbytes,int unboxed_p)
+{
+ /* this is the only function that the external interface to
+ * allocation presently knows how to call: Lisp code will never
+ * allocate large objects, or to unboxed space, or `quick'ly.
+ * Any of that stuff will only ever happen inside of GC */
+ return gc_general_alloc(nbytes,unboxed_p,0);
}
-/* Allocate space for the boxed object. If it is a large object then
- * do a large alloc else allocate from the current region. If there is
- * not enough free space then call gc_alloc to do the job. A pointer
- * to the start of the region is returned. */
-static inline void
-*gc_quick_alloc_large(int nbytes)
+/* Allocate space from the boxed_region. If there is not enough free
+ * space then call gc_alloc to do the job. A pointer to the start of
+ * the object is returned. */
+static inline void *
+gc_quick_alloc(int nbytes)
{
- void *new_free_pointer;
-
- if (nbytes >= large_object_size)
- return gc_alloc_large(nbytes, 0, &boxed_region);
+ return gc_general_alloc(nbytes,ALLOC_BOXED,ALLOC_QUICK);
+}
- /* Check whether there is room in the current region. */
- new_free_pointer = boxed_region.free_pointer + nbytes;
+/* Allocate space for the possibly large boxed object. If it is a
+ * large object then do a large alloc else use gc_quick_alloc. Note
+ * that gc_quick_alloc will eventually fall through to
+ * gc_general_alloc which may allocate the object in a large way
+ * anyway, but based on decisions about the free space in the current
+ * region, not the object size itself */
- if (new_free_pointer <= boxed_region.end_addr) {
- /* If so then allocate from the current region. */
- void *new_obj = boxed_region.free_pointer;
- boxed_region.free_pointer = new_free_pointer;
- return((void *)new_obj);
- }
+static inline void *
+gc_quick_alloc_large(int nbytes)
+{
+ if (nbytes >= large_object_size)
+ return gc_alloc_large(nbytes, ALLOC_BOXED, &boxed_region);
+ else
+ return gc_general_alloc(nbytes,ALLOC_BOXED,ALLOC_QUICK);
+}
- /* Else call gc_alloc */
- return (gc_alloc(nbytes));
+static inline void *
+gc_alloc_unboxed(int nbytes)
+{
+ return gc_general_alloc(nbytes,ALLOC_UNBOXED,0);
}
-static void
-*gc_alloc_unboxed(int nbytes)
+static inline void *
+gc_quick_alloc_unboxed(int nbytes)
{
- void *new_free_pointer;
+ return gc_general_alloc(nbytes,ALLOC_UNBOXED,ALLOC_QUICK);
+}
- /*
- FSHOW((stderr, "/gc_alloc_unboxed %d\n", nbytes));
- */
+/* Allocate space for the object. If it is a large object then do a
+ * large alloc else allocate from the current region. If there is not
+ * enough free space then call general gc_alloc_unboxed() to do the job.
+ *
+ * A pointer to the start of the object is returned. */
+static inline void *
+gc_quick_alloc_large_unboxed(int nbytes)
+{
+ if (nbytes >= large_object_size)
+ return gc_alloc_large(nbytes,ALLOC_UNBOXED,&unboxed_region);
+ else
+ return gc_quick_alloc_unboxed(nbytes);
+}
+\f
+/*
+ * scavenging/transporting routines derived from gc.c in CMU CL ca. 18b
+ */
- /* Check whether there is room in the current region. */
- new_free_pointer = unboxed_region.free_pointer + nbytes;
+extern int (*scavtab[256])(lispobj *where, lispobj object);
+extern lispobj (*transother[256])(lispobj object);
+extern int (*sizetab[256])(lispobj *where);
- if (new_free_pointer <= unboxed_region.end_addr) {
- /* If so then allocate from the current region. */
- void *new_obj = unboxed_region.free_pointer;
- unboxed_region.free_pointer = new_free_pointer;
-
- /* Check whether the current region is almost empty. */
- if ((unboxed_region.end_addr - unboxed_region.free_pointer) <= 32) {
- /* If so finished with the current region. */
- gc_alloc_update_page_tables(1, &unboxed_region);
-
- /* Set up a new region. */
- gc_alloc_new_region(32, 1, &unboxed_region);
- }
-
- return((void *)new_obj);
- }
-
- /* Else not enough free space in the current region. */
-
- /* If there is a bit of room left in the current region then
- allocate a large object. */
- if ((unboxed_region.end_addr-unboxed_region.free_pointer) > 32)
- return gc_alloc_large(nbytes,1,&unboxed_region);
-
- /* Else find a new region. */
-
- /* Finished with the current region. */
- gc_alloc_update_page_tables(1, &unboxed_region);
-
- /* Set up a new region. */
- gc_alloc_new_region(nbytes, 1, &unboxed_region);
-
- /* Should now be enough room. */
-
- /* Check whether there is room in the current region. */
- new_free_pointer = unboxed_region.free_pointer + nbytes;
-
- if (new_free_pointer <= unboxed_region.end_addr) {
- /* If so then allocate from the current region. */
- void *new_obj = unboxed_region.free_pointer;
- unboxed_region.free_pointer = new_free_pointer;
-
- /* Check whether the current region is almost empty. */
- if ((unboxed_region.end_addr - unboxed_region.free_pointer) <= 32) {
- /* If so find, finished with the current region. */
- gc_alloc_update_page_tables(1, &unboxed_region);
-
- /* Set up a new region. */
- gc_alloc_new_region(32, 1, &unboxed_region);
- }
-
- return((void *)new_obj);
- }
-
- /* shouldn't happen? */
- gc_assert(0);
- return((void *) NIL); /* dummy value: return something ... */
-}
-
-static inline void
-*gc_quick_alloc_unboxed(int nbytes)
-{
- void *new_free_pointer;
-
- /* Check whether there is room in the current region. */
- new_free_pointer = unboxed_region.free_pointer + nbytes;
-
- if (new_free_pointer <= unboxed_region.end_addr) {
- /* If so then allocate from the current region. */
- void *new_obj = unboxed_region.free_pointer;
- unboxed_region.free_pointer = new_free_pointer;
-
- return((void *)new_obj);
- }
-
- /* Else call gc_alloc */
- return (gc_alloc_unboxed(nbytes));
-}
-
-/* Allocate space for the object. If it is a large object then do a
- * large alloc else allocate from the current region. If there is not
- * enough free space then call gc_alloc to do the job.
- *
- * A pointer to the start of the region is returned. */
-static inline void
-*gc_quick_alloc_large_unboxed(int nbytes)
-{
- void *new_free_pointer;
-
- if (nbytes >= large_object_size)
- return gc_alloc_large(nbytes,1,&unboxed_region);
-
- /* Check whether there is room in the current region. */
- new_free_pointer = unboxed_region.free_pointer + nbytes;
-
- if (new_free_pointer <= unboxed_region.end_addr) {
- /* If so then allocate from the current region. */
- void *new_obj = unboxed_region.free_pointer;
- unboxed_region.free_pointer = new_free_pointer;
-
- return((void *)new_obj);
- }
-
- /* Else call gc_alloc. */
- return (gc_alloc_unboxed(nbytes));
-}
-\f
-/*
- * scavenging/transporting routines derived from gc.c in CMU CL ca. 18b
- */
-
-static int (*scavtab[256])(lispobj *where, lispobj object);
-static lispobj (*transother[256])(lispobj object);
-static int (*sizetab[256])(lispobj *where);
-
-static struct weak_pointer *weak_pointers;
-
-#define CEILING(x,y) (((x) + ((y) - 1)) & (~((y) - 1)))
-\f
-/*
- * predicates
- */
-
-static inline boolean
-from_space_p(lispobj obj)
-{
- int page_index=(void*)obj - heap_base;
- return ((page_index >= 0)
- && ((page_index = ((unsigned int)page_index)/4096) < NUM_PAGES)
- && (page_table[page_index].gen == from_space));
-}
-
-static inline boolean
-new_space_p(lispobj obj)
-{
- int page_index = (void*)obj - heap_base;
- return ((page_index >= 0)
- && ((page_index = ((unsigned int)page_index)/4096) < NUM_PAGES)
- && (page_table[page_index].gen == new_space));
-}
-\f
-/*
- * copying objects
- */
-
-/* to copy a boxed object */
-static inline lispobj
-copy_object(lispobj object, int nwords)
-{
- int tag;
- lispobj *new;
- lispobj *source, *dest;
-
- gc_assert(Pointerp(object));
- gc_assert(from_space_p(object));
- gc_assert((nwords & 0x01) == 0);
-
- /* Get tag of object. */
- tag = LowtagOf(object);
-
- /* Allocate space. */
- new = gc_quick_alloc(nwords*4);
-
- dest = new;
- source = (lispobj *) PTR(object);
-
- /* Copy the object. */
- while (nwords > 0) {
- dest[0] = source[0];
- dest[1] = source[1];
- dest += 2;
- source += 2;
- nwords -= 2;
- }
-
- /* Return Lisp pointer of new object. */
- return ((lispobj) new) | tag;
-}
-
-/* to copy a large boxed object. If the object is in a large object
+/* Copy a large boxed object. If the object is in a large object
* region then it is simply promoted, else it is copied. If it's large
* enough then it's copied to a large object region.
*
* Vectors may have shrunk. If the object is not copied the space
* needs to be reclaimed, and the page_tables corrected. */
-static lispobj
+lispobj
copy_large_object(lispobj object, int nwords)
{
int tag;
lispobj *source, *dest;
int first_page;
- gc_assert(Pointerp(object));
+ gc_assert(is_lisp_pointer(object));
gc_assert(from_space_p(object));
gc_assert((nwords & 0x01) == 0);
- if ((nwords > 1024*1024) && gencgc_verbose) {
- FSHOW((stderr, "/copy_large_object: %d bytes\n", nwords*4));
- }
/* Check whether it's a large object. */
first_page = find_page_index((void *)object);
gc_assert(page_table[next_page].bytes_used >= remaining_bytes);
page_table[next_page].gen = new_space;
- gc_assert(page_table[next_page].allocated = BOXED_PAGE);
+ gc_assert(page_table[next_page].allocated == BOXED_PAGE);
/* Adjust the bytes_used. */
old_bytes_used = page_table[next_page].bytes_used;
page_table[next_page].large_object &&
(page_table[next_page].first_object_offset ==
-(next_page - first_page)*4096)) {
- /* Checks out OK, free the page. Don't need to both zeroing
+ /* Checks out OK, free the page. Don't need to bother zeroing
* pages as this should have been done before shrinking the
* object. These pages shouldn't be write-protected as they
* should be zero filled. */
next_page++;
}
- if ((bytes_freed > 0) && gencgc_verbose)
- FSHOW((stderr, "/copy_large_boxed bytes_freed=%d\n", bytes_freed));
-
generations[from_space].bytes_allocated -= 4*nwords + bytes_freed;
generations[new_space].bytes_allocated += 4*nwords;
bytes_allocated -= bytes_freed;
return(object);
} else {
/* Get tag of object. */
- tag = LowtagOf(object);
+ tag = lowtag_of(object);
/* Allocate space. */
new = gc_quick_alloc_large(nwords*4);
dest = new;
- source = (lispobj *) PTR(object);
+ source = (lispobj *) native_pointer(object);
/* Copy the object. */
while (nwords > 0) {
}
/* to copy unboxed objects */
-static inline lispobj
+lispobj
copy_unboxed_object(lispobj object, int nwords)
{
int tag;
lispobj *new;
lispobj *source, *dest;
- gc_assert(Pointerp(object));
+ gc_assert(is_lisp_pointer(object));
gc_assert(from_space_p(object));
gc_assert((nwords & 0x01) == 0);
/* Get tag of object. */
- tag = LowtagOf(object);
+ tag = lowtag_of(object);
/* Allocate space. */
new = gc_quick_alloc_unboxed(nwords*4);
dest = new;
- source = (lispobj *) PTR(object);
+ source = (lispobj *) native_pointer(object);
/* Copy the object. */
while (nwords > 0) {
*
* KLUDGE: There's a lot of cut-and-paste duplication between this
* function and copy_large_object(..). -- WHN 20000619 */
-static lispobj
+lispobj
copy_large_unboxed_object(lispobj object, int nwords)
{
int tag;
lispobj *source, *dest;
int first_page;
- gc_assert(Pointerp(object));
+ gc_assert(is_lisp_pointer(object));
gc_assert(from_space_p(object));
gc_assert((nwords & 0x01) == 0);
}
else {
/* Get tag of object. */
- tag = LowtagOf(object);
+ tag = lowtag_of(object);
/* Allocate space. */
new = gc_quick_alloc_large_unboxed(nwords*4);
dest = new;
- source = (lispobj *) PTR(object);
+ source = (lispobj *) native_pointer(object);
/* Copy the object. */
while (nwords > 0) {
return ((lispobj) new) | tag;
}
}
-\f
-/*
- * scavenging
- */
-
-#define DIRECT_SCAV 0
-
-/* FIXME: Most calls end up going to a little trouble to compute an
- * 'nwords' value. The system might be a little simpler if this
- * function used an 'end' parameter instead. */
-static void
-scavenge(lispobj *start, long nwords)
-{
- while (nwords > 0) {
- lispobj object;
-#if DIRECT_SCAV
- int type;
-#endif
- int words_scavenged;
-
- object = *start;
-
-/* FSHOW((stderr, "Scavenge: %p, %ld\n", start, nwords)); */
-
- gc_assert(object != 0x01); /* not a forwarding pointer */
-#if DIRECT_SCAV
- type = TypeOf(object);
- words_scavenged = (scavtab[type])(start, object);
-#else
- if (Pointerp(object)) {
- /* It's a pointer. */
- if (from_space_p(object)) {
- /* It currently points to old space. Check for a forwarding
- * pointer. */
- lispobj *ptr = (lispobj *)PTR(object);
- lispobj first_word = *ptr;
-
- if (first_word == 0x01) {
- /* Yes, there's a forwarding pointer. */
- *start = ptr[1];
- words_scavenged = 1;
- }
- else
- /* Scavenge that pointer. */
- words_scavenged = (scavtab[TypeOf(object)])(start, object);
- } else {
- /* It points somewhere other than oldspace. Leave it alone. */
- words_scavenged = 1;
- }
- } else {
- if ((object & 3) == 0) {
- /* It's a fixnum: really easy.. */
- words_scavenged = 1;
- } else {
- /* It's some sort of header object or another. */
- words_scavenged = (scavtab[TypeOf(object)])(start, object);
- }
- }
-#endif
- start += words_scavenged;
- nwords -= words_scavenged;
- }
- gc_assert(nwords == 0);
-}
\f
+
/*
* code and code-related objects
*/
-
-#define RAW_ADDR_OFFSET (6*sizeof(lispobj) - type_FunctionPointer)
-
-static lispobj trans_function_header(lispobj object);
+/*
+static lispobj trans_fun_header(lispobj object);
static lispobj trans_boxed(lispobj object);
-
-#if DIRECT_SCAV
-static int
-scav_function_pointer(lispobj *where, lispobj object)
-{
- gc_assert(Pointerp(object));
-
- if (from_space_p(object)) {
- lispobj first, *first_pointer;
-
- /* object is a pointer into from space. Check to see whether
- * it has been forwarded. */
- first_pointer = (lispobj *) PTR(object);
- first = *first_pointer;
-
- if (first == 0x01) {
- /* Forwarded */
- *where = first_pointer[1];
- return 1;
- }
- else {
- int type;
- lispobj copy;
-
- /* must transport object -- object may point to either a
- * function header, a closure function header, or to a
- * closure header. */
-
- type = TypeOf(first);
- switch (type) {
- case type_FunctionHeader:
- case type_ClosureFunctionHeader:
- copy = trans_function_header(object);
- break;
- default:
- copy = trans_boxed(object);
- break;
- }
-
- if (copy != object) {
- /* Set forwarding pointer. */
- first_pointer[0] = 0x01;
- first_pointer[1] = copy;
- }
-
- first = copy;
- }
-
- gc_assert(Pointerp(first));
- gc_assert(!from_space_p(first));
-
- *where = first;
- }
- return 1;
-}
-#else
-static int
-scav_function_pointer(lispobj *where, lispobj object)
-{
- lispobj *first_pointer;
- lispobj copy;
-
- gc_assert(Pointerp(object));
-
- /* Object is a pointer into from space - no a FP. */
- first_pointer = (lispobj *) PTR(object);
-
- /* must transport object -- object may point to either a function
- * header, a closure function header, or to a closure header. */
-
- switch (TypeOf(*first_pointer)) {
- case type_FunctionHeader:
- case type_ClosureFunctionHeader:
- copy = trans_function_header(object);
- break;
- default:
- copy = trans_boxed(object);
- break;
- }
-
- if (copy != object) {
- /* Set forwarding pointer */
- first_pointer[0] = 0x01;
- first_pointer[1] = copy;
- }
-
- gc_assert(Pointerp(copy));
- gc_assert(!from_space_p(copy));
-
- *where = copy;
-
- return 1;
-}
-#endif
+*/
/* Scan a x86 compiled code object, looking for possible fixups that
* have been missed after a move.
if (!check_code_fixups)
return;
- /* It's ok if it's byte compiled code. The trace table offset will
- * be a fixnum if it's x86 compiled code - check. */
- if (code->trace_table_offset & 0x3) {
- FSHOW((stderr, "/Sniffing byte compiled code object at %x.\n", code));
- return;
- }
-
- /* Else it's x86 machine code. */
-
ncode_words = fixnum_value(code->code_size);
nheader_words = HeaderValue(*(lispobj *)code);
nwords = ncode_words + nheader_words;
unsigned d2 = *((unsigned char *)p - 2);
unsigned d3 = *((unsigned char *)p - 3);
unsigned d4 = *((unsigned char *)p - 4);
+#if QSHOW
unsigned d5 = *((unsigned char *)p - 5);
unsigned d6 = *((unsigned char *)p - 6);
+#endif
/* Check for code references. */
/* Check for a 32 bit word that looks like an absolute
}
}
-static void
-apply_code_fixups(struct code *old_code, struct code *new_code)
+void
+gencgc_apply_code_fixups(struct code *old_code, struct code *new_code)
{
int nheader_words, ncode_words, nwords;
void *constants_start_addr, *constants_end_addr;
unsigned displacement = (unsigned)new_code - (unsigned)old_code;
struct vector *fixups_vector;
- /* It's OK if it's byte compiled code. The trace table offset will
- * be a fixnum if it's x86 compiled code - check. */
- if (new_code->trace_table_offset & 0x3) {
-/* FSHOW((stderr, "/byte compiled code object at %x\n", new_code)); */
- return;
- }
-
- /* Else it's x86 machine code. */
ncode_words = fixnum_value(new_code->code_size);
nheader_words = HeaderValue(*(lispobj *)new_code);
nwords = ncode_words + nheader_words;
/* It will be 0 or the unbound-marker if there are no fixups, and
* will be an other pointer if it is valid. */
- if ((fixups == 0) || (fixups == type_UnboundMarker) || !Pointerp(fixups)) {
+ if ((fixups == 0) || (fixups == UNBOUND_MARKER_WIDETAG) ||
+ !is_lisp_pointer(fixups)) {
/* Check for possible errors. */
if (check_code_fixups)
sniff_code_object(new_code, displacement);
return;
}
- fixups_vector = (struct vector *)PTR(fixups);
+ fixups_vector = (struct vector *)native_pointer(fixups);
/* Could be pointing to a forwarding pointer. */
- if (Pointerp(fixups) && (find_page_index((void*)fixups_vector) != -1)
- && (fixups_vector->header == 0x01)) {
+ if (is_lisp_pointer(fixups) &&
+ (find_page_index((void*)fixups_vector) != -1) &&
+ (fixups_vector->header == 0x01)) {
/* If so, then follow it. */
/*SHOW("following pointer to a forwarding pointer");*/
- fixups_vector = (struct vector *)PTR((lispobj)fixups_vector->length);
+ fixups_vector = (struct vector *)native_pointer((lispobj)fixups_vector->length);
}
/*SHOW("got fixups");*/
- if (TypeOf(fixups_vector->header) == type_SimpleArrayUnsignedByte32) {
+ if (widetag_of(fixups_vector->header) ==
+ SIMPLE_ARRAY_UNSIGNED_BYTE_32_WIDETAG) {
/* Got the fixups for the code block. Now work through the vector,
and apply a fixup at each address. */
int length = fixnum_value(fixups_vector->length);
}
}
-static struct code *
-trans_code(struct code *code)
-{
- struct code *new_code;
- lispobj l_code, l_new_code;
- int nheader_words, ncode_words, nwords;
- unsigned long displacement;
- lispobj fheaderl, *prev_pointer;
-
- /* FSHOW((stderr,
- "\n/transporting code object located at 0x%08x\n",
- (unsigned long) code)); */
-
- /* If object has already been transported, just return pointer. */
- if (*((lispobj *)code) == 0x01)
- return (struct code*)(((lispobj *)code)[1]);
- gc_assert(TypeOf(code->header) == type_CodeHeader);
-
- /* Prepare to transport the code vector. */
- l_code = (lispobj) code | type_OtherPointer;
+static lispobj
+trans_boxed_large(lispobj object)
+{
+ lispobj header;
+ unsigned long length;
- ncode_words = fixnum_value(code->code_size);
- nheader_words = HeaderValue(code->header);
- nwords = ncode_words + nheader_words;
- nwords = CEILING(nwords, 2);
+ gc_assert(is_lisp_pointer(object));
- l_new_code = copy_large_object(l_code, nwords);
- new_code = (struct code *) PTR(l_new_code);
+ header = *((lispobj *) native_pointer(object));
+ length = HeaderValue(header) + 1;
+ length = CEILING(length, 2);
- /* may not have been moved.. */
- if (new_code == code)
- return new_code;
+ return copy_large_object(object, length);
+}
- displacement = l_new_code - l_code;
- /*
- FSHOW((stderr,
- "/old code object at 0x%08x, new code object at 0x%08x\n",
- (unsigned long) code,
- (unsigned long) new_code));
- FSHOW((stderr, "/Code object is %d words long.\n", nwords));
- */
+static lispobj
+trans_unboxed_large(lispobj object)
+{
+ lispobj header;
+ unsigned long length;
- /* Set forwarding pointer. */
- ((lispobj *)code)[0] = 0x01;
- ((lispobj *)code)[1] = l_new_code;
- /* Set forwarding pointers for all the function headers in the
- * code object. Also fix all self pointers. */
+ gc_assert(is_lisp_pointer(object));
- fheaderl = code->entry_points;
- prev_pointer = &new_code->entry_points;
+ header = *((lispobj *) native_pointer(object));
+ length = HeaderValue(header) + 1;
+ length = CEILING(length, 2);
- while (fheaderl != NIL) {
- struct function *fheaderp, *nfheaderp;
- lispobj nfheaderl;
+ return copy_large_unboxed_object(object, length);
+}
- fheaderp = (struct function *) PTR(fheaderl);
- gc_assert(TypeOf(fheaderp->header) == type_FunctionHeader);
+\f
+/*
+ * vector-like objects
+ */
- /* Calculate the new function pointer and the new */
- /* function header. */
- nfheaderl = fheaderl + displacement;
- nfheaderp = (struct function *) PTR(nfheaderl);
- /* Set forwarding pointer. */
- ((lispobj *)fheaderp)[0] = 0x01;
- ((lispobj *)fheaderp)[1] = nfheaderl;
+/* FIXME: What does this mean? */
+int gencgc_hash = 1;
- /* Fix self pointer. */
- nfheaderp->self = nfheaderl + RAW_ADDR_OFFSET;
+static int
+scav_vector(lispobj *where, lispobj object)
+{
+ unsigned int kv_length;
+ lispobj *kv_vector;
+ unsigned int length = 0; /* (0 = dummy to stop GCC warning) */
+ lispobj *hash_table;
+ lispobj empty_symbol;
+ unsigned int *index_vector = NULL; /* (NULL = dummy to stop GCC warning) */
+ unsigned int *next_vector = NULL; /* (NULL = dummy to stop GCC warning) */
+ unsigned int *hash_vector = NULL; /* (NULL = dummy to stop GCC warning) */
+ lispobj weak_p_obj;
+ unsigned next_vector_length = 0;
- *prev_pointer = nfheaderl;
+ /* FIXME: A comment explaining this would be nice. It looks as
+ * though SB-VM:VECTOR-VALID-HASHING-SUBTYPE is set for EQ-based
+ * hash tables in the Lisp HASH-TABLE code, and nowhere else. */
+ if (HeaderValue(object) != subtype_VectorValidHashing)
+ return 1;
- fheaderl = fheaderp->next;
- prev_pointer = &nfheaderp->next;
- }
-
- /* sniff_code_object(new_code,displacement);*/
- apply_code_fixups(code,new_code);
-
- return new_code;
-}
-
-static int
-scav_code_header(lispobj *where, lispobj object)
-{
- struct code *code;
- int nheader_words, ncode_words, nwords;
- lispobj fheaderl;
- struct function *fheaderp;
-
- code = (struct code *) where;
- ncode_words = fixnum_value(code->code_size);
- nheader_words = HeaderValue(object);
- nwords = ncode_words + nheader_words;
- nwords = CEILING(nwords, 2);
-
- /* Scavenge the boxed section of the code data block. */
- scavenge(where + 1, nheader_words - 1);
-
- /* Scavenge the boxed section of each function object in the */
- /* code data block. */
- fheaderl = code->entry_points;
- while (fheaderl != NIL) {
- fheaderp = (struct function *) PTR(fheaderl);
- gc_assert(TypeOf(fheaderp->header) == type_FunctionHeader);
-
- scavenge(&fheaderp->name, 1);
- scavenge(&fheaderp->arglist, 1);
- scavenge(&fheaderp->type, 1);
-
- fheaderl = fheaderp->next;
- }
-
- return nwords;
-}
-
-static lispobj
-trans_code_header(lispobj object)
-{
- struct code *ncode;
-
- ncode = trans_code((struct code *) PTR(object));
- return (lispobj) ncode | type_OtherPointer;
-}
-
-static int
-size_code_header(lispobj *where)
-{
- struct code *code;
- int nheader_words, ncode_words, nwords;
-
- code = (struct code *) where;
-
- ncode_words = fixnum_value(code->code_size);
- nheader_words = HeaderValue(code->header);
- nwords = ncode_words + nheader_words;
- nwords = CEILING(nwords, 2);
-
- return nwords;
-}
-
-static int
-scav_return_pc_header(lispobj *where, lispobj object)
-{
- lose("attempted to scavenge a return PC header where=0x%08x object=0x%08x",
- (unsigned long) where,
- (unsigned long) object);
- return 0; /* bogus return value to satisfy static type checking */
-}
-
-static lispobj
-trans_return_pc_header(lispobj object)
-{
- struct function *return_pc;
- unsigned long offset;
- struct code *code, *ncode;
-
- SHOW("/trans_return_pc_header: Will this work?");
-
- return_pc = (struct function *) PTR(object);
- offset = HeaderValue(return_pc->header) * 4;
-
- /* Transport the whole code object. */
- code = (struct code *) ((unsigned long) return_pc - offset);
- ncode = trans_code(code);
-
- return ((lispobj) ncode + offset) | type_OtherPointer;
-}
-
-/* On the 386, closures hold a pointer to the raw address instead of the
- * function object. */
-#ifdef __i386__
-static int
-scav_closure_header(lispobj *where, lispobj object)
-{
- struct closure *closure;
- lispobj fun;
-
- closure = (struct closure *)where;
- fun = closure->function - RAW_ADDR_OFFSET;
- scavenge(&fun, 1);
- /* The function may have moved so update the raw address. But
- * don't write unnecessarily. */
- if (closure->function != fun + RAW_ADDR_OFFSET)
- closure->function = fun + RAW_ADDR_OFFSET;
-
- return 2;
-}
-#endif
-
-static int
-scav_function_header(lispobj *where, lispobj object)
-{
- lose("attempted to scavenge a function header where=0x%08x object=0x%08x",
- (unsigned long) where,
- (unsigned long) object);
- return 0; /* bogus return value to satisfy static type checking */
-}
-
-static lispobj
-trans_function_header(lispobj object)
-{
- struct function *fheader;
- unsigned long offset;
- struct code *code, *ncode;
-
- fheader = (struct function *) PTR(object);
- offset = HeaderValue(fheader->header) * 4;
-
- /* Transport the whole code object. */
- code = (struct code *) ((unsigned long) fheader - offset);
- ncode = trans_code(code);
-
- return ((lispobj) ncode + offset) | type_FunctionPointer;
-}
-\f
-/*
- * instances
- */
-
-#if DIRECT_SCAV
-static int
-scav_instance_pointer(lispobj *where, lispobj object)
-{
- if (from_space_p(object)) {
- lispobj first, *first_pointer;
-
- /* Object is a pointer into from space. Check to see */
- /* whether it has been forwarded. */
- first_pointer = (lispobj *) PTR(object);
- first = *first_pointer;
-
- if (first == 0x01) {
- /* forwarded */
- first = first_pointer[1];
- } else {
- first = trans_boxed(object);
- gc_assert(first != object);
- /* Set forwarding pointer. */
- first_pointer[0] = 0x01;
- first_pointer[1] = first;
- }
- *where = first;
- }
- return 1;
-}
-#else
-static int
-scav_instance_pointer(lispobj *where, lispobj object)
-{
- lispobj copy, *first_pointer;
-
- /* Object is a pointer into from space - not a FP. */
- copy = trans_boxed(object);
-
- gc_assert(copy != object);
-
- first_pointer = (lispobj *) PTR(object);
-
- /* Set forwarding pointer. */
- first_pointer[0] = 0x01;
- first_pointer[1] = copy;
- *where = copy;
-
- return 1;
-}
-#endif
-\f
-/*
- * lists and conses
- */
-
-static lispobj trans_list(lispobj object);
-
-#if DIRECT_SCAV
-static int
-scav_list_pointer(lispobj *where, lispobj object)
-{
- /* KLUDGE: There's lots of cut-and-paste duplication between this
- * and scav_instance_pointer(..), scav_other_pointer(..), and
- * perhaps other functions too. -- WHN 20000620 */
-
- gc_assert(Pointerp(object));
-
- if (from_space_p(object)) {
- lispobj first, *first_pointer;
-
- /* Object is a pointer into from space. Check to see whether it has
- * been forwarded. */
- first_pointer = (lispobj *) PTR(object);
- first = *first_pointer;
-
- if (first == 0x01) {
- /* forwarded */
- first = first_pointer[1];
- } else {
- first = trans_list(object);
-
- /* Set forwarding pointer */
- first_pointer[0] = 0x01;
- first_pointer[1] = first;
- }
-
- gc_assert(Pointerp(first));
- gc_assert(!from_space_p(first));
- *where = first;
- }
- return 1;
-}
-#else
-static int
-scav_list_pointer(lispobj *where, lispobj object)
-{
- lispobj first, *first_pointer;
-
- gc_assert(Pointerp(object));
-
- /* Object is a pointer into from space - not FP. */
-
- first = trans_list(object);
- gc_assert(first != object);
-
- first_pointer = (lispobj *) PTR(object);
-
- /* Set forwarding pointer */
- first_pointer[0] = 0x01;
- first_pointer[1] = first;
-
- gc_assert(Pointerp(first));
- gc_assert(!from_space_p(first));
- *where = first;
- return 1;
-}
-#endif
-
-static lispobj
-trans_list(lispobj object)
-{
- lispobj new_list_pointer;
- struct cons *cons, *new_cons;
- lispobj cdr;
-
- gc_assert(from_space_p(object));
-
- cons = (struct cons *) PTR(object);
-
- /* Copy 'object'. */
- new_cons = (struct cons *) gc_quick_alloc(sizeof(struct cons));
- new_cons->car = cons->car;
- new_cons->cdr = cons->cdr; /* updated later */
- new_list_pointer = (lispobj)new_cons | LowtagOf(object);
-
- /* Grab the cdr before it is clobbered. */
- cdr = cons->cdr;
-
- /* Set forwarding pointer (clobbers start of list). */
- cons->car = 0x01;
- cons->cdr = new_list_pointer;
-
- /* Try to linearize the list in the cdr direction to help reduce
- * paging. */
- while (1) {
- lispobj new_cdr;
- struct cons *cdr_cons, *new_cdr_cons;
-
- if (LowtagOf(cdr) != type_ListPointer || !from_space_p(cdr)
- || (*((lispobj *)PTR(cdr)) == 0x01))
- break;
-
- cdr_cons = (struct cons *) PTR(cdr);
-
- /* Copy 'cdr'. */
- new_cdr_cons = (struct cons*) gc_quick_alloc(sizeof(struct cons));
- new_cdr_cons->car = cdr_cons->car;
- new_cdr_cons->cdr = cdr_cons->cdr;
- new_cdr = (lispobj)new_cdr_cons | LowtagOf(cdr);
-
- /* Grab the cdr before it is clobbered. */
- cdr = cdr_cons->cdr;
-
- /* Set forwarding pointer. */
- cdr_cons->car = 0x01;
- cdr_cons->cdr = new_cdr;
-
- /* Update the cdr of the last cons copied into new space to
- * keep the newspace scavenge from having to do it. */
- new_cons->cdr = new_cdr;
-
- new_cons = new_cdr_cons;
- }
-
- return new_list_pointer;
-}
-
-\f
-/*
- * scavenging and transporting other pointers
- */
-
-#if DIRECT_SCAV
-static int
-scav_other_pointer(lispobj *where, lispobj object)
-{
- gc_assert(Pointerp(object));
-
- if (from_space_p(object)) {
- lispobj first, *first_pointer;
-
- /* Object is a pointer into from space. Check to see */
- /* whether it has been forwarded. */
- first_pointer = (lispobj *) PTR(object);
- first = *first_pointer;
-
- if (first == 0x01) {
- /* Forwarded. */
- first = first_pointer[1];
- *where = first;
- } else {
- first = (transother[TypeOf(first)])(object);
-
- if (first != object) {
- /* Set forwarding pointer */
- first_pointer[0] = 0x01;
- first_pointer[1] = first;
- *where = first;
- }
- }
-
- gc_assert(Pointerp(first));
- gc_assert(!from_space_p(first));
- }
- return 1;
-}
-#else
-static int
-scav_other_pointer(lispobj *where, lispobj object)
-{
- lispobj first, *first_pointer;
-
- gc_assert(Pointerp(object));
-
- /* Object is a pointer into from space - not FP. */
- first_pointer = (lispobj *) PTR(object);
-
- first = (transother[TypeOf(*first_pointer)])(object);
-
- if (first != object) {
- /* Set forwarding pointer. */
- first_pointer[0] = 0x01;
- first_pointer[1] = first;
- *where = first;
- }
-
- gc_assert(Pointerp(first));
- gc_assert(!from_space_p(first));
-
- return 1;
-}
-#endif
-
-\f
-/*
- * immediate, boxed, and unboxed objects
- */
-
-static int
-size_pointer(lispobj *where)
-{
- return 1;
-}
-
-static int
-scav_immediate(lispobj *where, lispobj object)
-{
- return 1;
-}
-
-static lispobj
-trans_immediate(lispobj object)
-{
- lose("trying to transport an immediate");
- return NIL; /* bogus return value to satisfy static type checking */
-}
-
-static int
-size_immediate(lispobj *where)
-{
- return 1;
-}
-
-
-static int
-scav_boxed(lispobj *where, lispobj object)
-{
- return 1;
-}
-
-static lispobj
-trans_boxed(lispobj object)
-{
- lispobj header;
- unsigned long length;
-
- gc_assert(Pointerp(object));
-
- header = *((lispobj *) PTR(object));
- length = HeaderValue(header) + 1;
- length = CEILING(length, 2);
-
- return copy_object(object, length);
-}
-
-static lispobj
-trans_boxed_large(lispobj object)
-{
- lispobj header;
- unsigned long length;
-
- gc_assert(Pointerp(object));
-
- header = *((lispobj *) PTR(object));
- length = HeaderValue(header) + 1;
- length = CEILING(length, 2);
-
- return copy_large_object(object, length);
-}
-
-static int
-size_boxed(lispobj *where)
-{
- lispobj header;
- unsigned long length;
-
- header = *where;
- length = HeaderValue(header) + 1;
- length = CEILING(length, 2);
-
- return length;
-}
-
-static int
-scav_fdefn(lispobj *where, lispobj object)
-{
- struct fdefn *fdefn;
-
- fdefn = (struct fdefn *)where;
-
- /* FSHOW((stderr, "scav_fdefn, function = %p, raw_addr = %p\n",
- fdefn->function, fdefn->raw_addr)); */
-
- if ((char *)(fdefn->function + RAW_ADDR_OFFSET) == fdefn->raw_addr) {
- scavenge(where + 1, sizeof(struct fdefn)/sizeof(lispobj) - 1);
-
- /* Don't write unnecessarily. */
- if (fdefn->raw_addr != (char *)(fdefn->function + RAW_ADDR_OFFSET))
- fdefn->raw_addr = (char *)(fdefn->function + RAW_ADDR_OFFSET);
-
- return sizeof(struct fdefn) / sizeof(lispobj);
- } else {
- return 1;
- }
-}
-
-static int
-scav_unboxed(lispobj *where, lispobj object)
-{
- unsigned long length;
-
- length = HeaderValue(object) + 1;
- length = CEILING(length, 2);
-
- return length;
-}
-
-static lispobj
-trans_unboxed(lispobj object)
-{
- lispobj header;
- unsigned long length;
-
-
- gc_assert(Pointerp(object));
-
- header = *((lispobj *) PTR(object));
- length = HeaderValue(header) + 1;
- length = CEILING(length, 2);
-
- return copy_unboxed_object(object, length);
-}
-
-static lispobj
-trans_unboxed_large(lispobj object)
-{
- lispobj header;
- unsigned long length;
-
-
- gc_assert(Pointerp(object));
-
- header = *((lispobj *) PTR(object));
- length = HeaderValue(header) + 1;
- length = CEILING(length, 2);
-
- return copy_large_unboxed_object(object, length);
-}
-
-static int
-size_unboxed(lispobj *where)
-{
- lispobj header;
- unsigned long length;
-
- header = *where;
- length = HeaderValue(header) + 1;
- length = CEILING(length, 2);
-
- return length;
-}
-\f
-/*
- * vector-like objects
- */
-
-#define NWORDS(x,y) (CEILING((x),(y)) / (y))
-
-static int
-scav_string(lispobj *where, lispobj object)
-{
- struct vector *vector;
- int length, nwords;
-
- /* NOTE: Strings contain one more byte of data than the length */
- /* slot indicates. */
-
- vector = (struct vector *) where;
- length = fixnum_value(vector->length) + 1;
- nwords = CEILING(NWORDS(length, 4) + 2, 2);
-
- return nwords;
-}
-
-static lispobj
-trans_string(lispobj object)
-{
- struct vector *vector;
- int length, nwords;
-
- gc_assert(Pointerp(object));
-
- /* NOTE: A string contains one more byte of data (a terminating
- * '\0' to help when interfacing with C functions) than indicated
- * by the length slot. */
-
- vector = (struct vector *) PTR(object);
- length = fixnum_value(vector->length) + 1;
- nwords = CEILING(NWORDS(length, 4) + 2, 2);
-
- return copy_large_unboxed_object(object, nwords);
-}
-
-static int
-size_string(lispobj *where)
-{
- struct vector *vector;
- int length, nwords;
-
- /* NOTE: A string contains one more byte of data (a terminating
- * '\0' to help when interfacing with C functions) than indicated
- * by the length slot. */
-
- vector = (struct vector *) where;
- length = fixnum_value(vector->length) + 1;
- nwords = CEILING(NWORDS(length, 4) + 2, 2);
-
- return nwords;
-}
-
-/* FIXME: What does this mean? */
-int gencgc_hash = 1;
-
-static int
-scav_vector(lispobj *where, lispobj object)
-{
- unsigned int kv_length;
- lispobj *kv_vector;
- unsigned int length = 0; /* (0 = dummy to stop GCC warning) */
- lispobj *hash_table;
- lispobj empty_symbol;
- unsigned int *index_vector = NULL; /* (NULL = dummy to stop GCC warning) */
- unsigned int *next_vector = NULL; /* (NULL = dummy to stop GCC warning) */
- unsigned int *hash_vector = NULL; /* (NULL = dummy to stop GCC warning) */
- lispobj weak_p_obj;
- unsigned next_vector_length = 0;
-
- /* FIXME: A comment explaining this would be nice. It looks as
- * though SB-VM:VECTOR-VALID-HASHING-SUBTYPE is set for EQ-based
- * hash tables in the Lisp HASH-TABLE code, and nowhere else. */
- if (HeaderValue(object) != subtype_VectorValidHashing)
- return 1;
-
- if (!gencgc_hash) {
- /* This is set for backward compatibility. FIXME: Do we need
- * this any more? */
- *where = (subtype_VectorMustRehash << type_Bits) | type_SimpleVector;
- return 1;
+ if (!gencgc_hash) {
+ /* This is set for backward compatibility. FIXME: Do we need
+ * this any more? */
+ *where =
+ (subtype_VectorMustRehash<<N_WIDETAG_BITS) | SIMPLE_VECTOR_WIDETAG;
+ return 1;
}
kv_length = fixnum_value(where[1]);
/* Scavenge element 0, which may be a hash-table structure. */
scavenge(where+2, 1);
- if (!Pointerp(where[2])) {
+ if (!is_lisp_pointer(where[2])) {
lose("no pointer at %x in hash table", where[2]);
}
- hash_table = (lispobj *)PTR(where[2]);
+ hash_table = (lispobj *)native_pointer(where[2]);
/*FSHOW((stderr,"/hash_table = %x\n", hash_table));*/
- if (TypeOf(hash_table[0]) != type_InstanceHeader) {
+ if (widetag_of(hash_table[0]) != INSTANCE_HEADER_WIDETAG) {
lose("hash table not instance (%x at %x)", hash_table[0], hash_table);
}
/* Scavenge element 1, which should be some internal symbol that
* the hash table code reserves for marking empty slots. */
scavenge(where+3, 1);
- if (!Pointerp(where[3])) {
- lose("not #:%EMPTY-HT-SLOT% symbol pointer: %x", where[3]);
+ if (!is_lisp_pointer(where[3])) {
+ lose("not empty-hash-table-slot symbol pointer: %x", where[3]);
}
empty_symbol = where[3];
/* fprintf(stderr,"* empty_symbol = %x\n", empty_symbol);*/
- if (TypeOf(*(lispobj *)PTR(empty_symbol)) != type_SymbolHeader) {
- lose("not a symbol where #:%EMPTY-HT-SLOT% expected: %x",
- *(lispobj *)PTR(empty_symbol));
+ if (widetag_of(*(lispobj *)native_pointer(empty_symbol)) !=
+ SYMBOL_HEADER_WIDETAG) {
+ lose("not a symbol where empty-hash-table-slot symbol expected: %x",
+ *(lispobj *)native_pointer(empty_symbol));
}
/* Scavenge hash table, which will fix the positions of the other
scavenge(hash_table, 16);
/* Cross-check the kv_vector. */
- if (where != (lispobj *)PTR(hash_table[9])) {
+ if (where != (lispobj *)native_pointer(hash_table[9])) {
lose("hash_table table!=this table %x", hash_table[9]);
}
{
lispobj index_vector_obj = hash_table[13];
- if (Pointerp(index_vector_obj) &&
- (TypeOf(*(lispobj *)PTR(index_vector_obj)) == type_SimpleArrayUnsignedByte32)) {
- index_vector = ((unsigned int *)PTR(index_vector_obj)) + 2;
+ if (is_lisp_pointer(index_vector_obj) &&
+ (widetag_of(*(lispobj *)native_pointer(index_vector_obj)) ==
+ SIMPLE_ARRAY_UNSIGNED_BYTE_32_WIDETAG)) {
+ index_vector = ((unsigned int *)native_pointer(index_vector_obj)) + 2;
/*FSHOW((stderr, "/index_vector = %x\n",index_vector));*/
- length = fixnum_value(((unsigned int *)PTR(index_vector_obj))[1]);
+ length = fixnum_value(((unsigned int *)native_pointer(index_vector_obj))[1]);
/*FSHOW((stderr, "/length = %d\n", length));*/
} else {
lose("invalid index_vector %x", index_vector_obj);
{
lispobj next_vector_obj = hash_table[14];
- if (Pointerp(next_vector_obj) &&
- (TypeOf(*(lispobj *)PTR(next_vector_obj)) == type_SimpleArrayUnsignedByte32)) {
- next_vector = ((unsigned int *)PTR(next_vector_obj)) + 2;
+ if (is_lisp_pointer(next_vector_obj) &&
+ (widetag_of(*(lispobj *)native_pointer(next_vector_obj)) ==
+ SIMPLE_ARRAY_UNSIGNED_BYTE_32_WIDETAG)) {
+ next_vector = ((unsigned int *)native_pointer(next_vector_obj)) + 2;
/*FSHOW((stderr, "/next_vector = %x\n", next_vector));*/
- next_vector_length = fixnum_value(((unsigned int *)PTR(next_vector_obj))[1]);
+ next_vector_length = fixnum_value(((unsigned int *)native_pointer(next_vector_obj))[1]);
/*FSHOW((stderr, "/next_vector_length = %d\n", next_vector_length));*/
} else {
lose("invalid next_vector %x", next_vector_obj);
* probably other stuff too. Ugh.. */
lispobj hash_vector_obj = hash_table[15];
- if (Pointerp(hash_vector_obj) &&
- (TypeOf(*(lispobj *)PTR(hash_vector_obj))
- == type_SimpleArrayUnsignedByte32)) {
- hash_vector = ((unsigned int *)PTR(hash_vector_obj)) + 2;
+ if (is_lisp_pointer(hash_vector_obj) &&
+ (widetag_of(*(lispobj *)native_pointer(hash_vector_obj))
+ == SIMPLE_ARRAY_UNSIGNED_BYTE_32_WIDETAG)) {
+ hash_vector = ((unsigned int *)native_pointer(hash_vector_obj)) + 2;
/*FSHOW((stderr, "/hash_vector = %x\n", hash_vector));*/
- gc_assert(fixnum_value(((unsigned int *)PTR(hash_vector_obj))[1])
+ gc_assert(fixnum_value(((unsigned int *)native_pointer(hash_vector_obj))[1])
== next_vector_length);
} else {
hash_vector = NULL;
}
}
}
- return (CEILING(kv_length + 2, 2));
-}
-
-static lispobj
-trans_vector(lispobj object)
-{
- struct vector *vector;
- int length, nwords;
-
- gc_assert(Pointerp(object));
-
- vector = (struct vector *) PTR(object);
-
- length = fixnum_value(vector->length);
- nwords = CEILING(length + 2, 2);
-
- return copy_large_object(object, nwords);
-}
-
-static int
-size_vector(lispobj *where)
-{
- struct vector *vector;
- int length, nwords;
-
- vector = (struct vector *) where;
- length = fixnum_value(vector->length);
- nwords = CEILING(length + 2, 2);
-
- return nwords;
-}
-
-
-static int
-scav_vector_bit(lispobj *where, lispobj object)
-{
- struct vector *vector;
- int length, nwords;
-
- vector = (struct vector *) where;
- length = fixnum_value(vector->length);
- nwords = CEILING(NWORDS(length, 32) + 2, 2);
-
- return nwords;
-}
-
-static lispobj
-trans_vector_bit(lispobj object)
-{
- struct vector *vector;
- int length, nwords;
-
- gc_assert(Pointerp(object));
-
- vector = (struct vector *) PTR(object);
- length = fixnum_value(vector->length);
- nwords = CEILING(NWORDS(length, 32) + 2, 2);
-
- return copy_large_unboxed_object(object, nwords);
-}
-
-static int
-size_vector_bit(lispobj *where)
-{
- struct vector *vector;
- int length, nwords;
-
- vector = (struct vector *) where;
- length = fixnum_value(vector->length);
- nwords = CEILING(NWORDS(length, 32) + 2, 2);
-
- return nwords;
-}
-
-
-static int
-scav_vector_unsigned_byte_2(lispobj *where, lispobj object)
-{
- struct vector *vector;
- int length, nwords;
-
- vector = (struct vector *) where;
- length = fixnum_value(vector->length);
- nwords = CEILING(NWORDS(length, 16) + 2, 2);
-
- return nwords;
-}
-
-static lispobj
-trans_vector_unsigned_byte_2(lispobj object)
-{
- struct vector *vector;
- int length, nwords;
-
- gc_assert(Pointerp(object));
-
- vector = (struct vector *) PTR(object);
- length = fixnum_value(vector->length);
- nwords = CEILING(NWORDS(length, 16) + 2, 2);
-
- return copy_large_unboxed_object(object, nwords);
-}
-
-static int
-size_vector_unsigned_byte_2(lispobj *where)
-{
- struct vector *vector;
- int length, nwords;
-
- vector = (struct vector *) where;
- length = fixnum_value(vector->length);
- nwords = CEILING(NWORDS(length, 16) + 2, 2);
-
- return nwords;
-}
-
-
-static int
-scav_vector_unsigned_byte_4(lispobj *where, lispobj object)
-{
- struct vector *vector;
- int length, nwords;
-
- vector = (struct vector *) where;
- length = fixnum_value(vector->length);
- nwords = CEILING(NWORDS(length, 8) + 2, 2);
-
- return nwords;
-}
-
-static lispobj
-trans_vector_unsigned_byte_4(lispobj object)
-{
- struct vector *vector;
- int length, nwords;
-
- gc_assert(Pointerp(object));
-
- vector = (struct vector *) PTR(object);
- length = fixnum_value(vector->length);
- nwords = CEILING(NWORDS(length, 8) + 2, 2);
-
- return copy_large_unboxed_object(object, nwords);
-}
-
-static int
-size_vector_unsigned_byte_4(lispobj *where)
-{
- struct vector *vector;
- int length, nwords;
-
- vector = (struct vector *) where;
- length = fixnum_value(vector->length);
- nwords = CEILING(NWORDS(length, 8) + 2, 2);
-
- return nwords;
-}
-
-static int
-scav_vector_unsigned_byte_8(lispobj *where, lispobj object)
-{
- struct vector *vector;
- int length, nwords;
-
- vector = (struct vector *) where;
- length = fixnum_value(vector->length);
- nwords = CEILING(NWORDS(length, 4) + 2, 2);
-
- return nwords;
-}
-
-static lispobj
-trans_vector_unsigned_byte_8(lispobj object)
-{
- struct vector *vector;
- int length, nwords;
-
- gc_assert(Pointerp(object));
-
- vector = (struct vector *) PTR(object);
- length = fixnum_value(vector->length);
- nwords = CEILING(NWORDS(length, 4) + 2, 2);
-
- return copy_large_unboxed_object(object, nwords);
-}
-
-static int
-size_vector_unsigned_byte_8(lispobj *where)
-{
- struct vector *vector;
- int length, nwords;
-
- vector = (struct vector *) where;
- length = fixnum_value(vector->length);
- nwords = CEILING(NWORDS(length, 4) + 2, 2);
-
- return nwords;
-}
-
-
-static int
-scav_vector_unsigned_byte_16(lispobj *where, lispobj object)
-{
- struct vector *vector;
- int length, nwords;
-
- vector = (struct vector *) where;
- length = fixnum_value(vector->length);
- nwords = CEILING(NWORDS(length, 2) + 2, 2);
-
- return nwords;
-}
-
-static lispobj
-trans_vector_unsigned_byte_16(lispobj object)
-{
- struct vector *vector;
- int length, nwords;
-
- gc_assert(Pointerp(object));
-
- vector = (struct vector *) PTR(object);
- length = fixnum_value(vector->length);
- nwords = CEILING(NWORDS(length, 2) + 2, 2);
-
- return copy_large_unboxed_object(object, nwords);
-}
-
-static int
-size_vector_unsigned_byte_16(lispobj *where)
-{
- struct vector *vector;
- int length, nwords;
-
- vector = (struct vector *) where;
- length = fixnum_value(vector->length);
- nwords = CEILING(NWORDS(length, 2) + 2, 2);
-
- return nwords;
-}
-
-static int
-scav_vector_unsigned_byte_32(lispobj *where, lispobj object)
-{
- struct vector *vector;
- int length, nwords;
-
- vector = (struct vector *) where;
- length = fixnum_value(vector->length);
- nwords = CEILING(length + 2, 2);
-
- return nwords;
-}
-
-static lispobj
-trans_vector_unsigned_byte_32(lispobj object)
-{
- struct vector *vector;
- int length, nwords;
-
- gc_assert(Pointerp(object));
-
- vector = (struct vector *) PTR(object);
- length = fixnum_value(vector->length);
- nwords = CEILING(length + 2, 2);
-
- return copy_large_unboxed_object(object, nwords);
-}
-
-static int
-size_vector_unsigned_byte_32(lispobj *where)
-{
- struct vector *vector;
- int length, nwords;
-
- vector = (struct vector *) where;
- length = fixnum_value(vector->length);
- nwords = CEILING(length + 2, 2);
-
- return nwords;
-}
-
-static int
-scav_vector_single_float(lispobj *where, lispobj object)
-{
- struct vector *vector;
- int length, nwords;
-
- vector = (struct vector *) where;
- length = fixnum_value(vector->length);
- nwords = CEILING(length + 2, 2);
-
- return nwords;
-}
-
-static lispobj
-trans_vector_single_float(lispobj object)
-{
- struct vector *vector;
- int length, nwords;
-
- gc_assert(Pointerp(object));
-
- vector = (struct vector *) PTR(object);
- length = fixnum_value(vector->length);
- nwords = CEILING(length + 2, 2);
-
- return copy_large_unboxed_object(object, nwords);
-}
-
-static int
-size_vector_single_float(lispobj *where)
-{
- struct vector *vector;
- int length, nwords;
-
- vector = (struct vector *) where;
- length = fixnum_value(vector->length);
- nwords = CEILING(length + 2, 2);
-
- return nwords;
-}
-
-static int
-scav_vector_double_float(lispobj *where, lispobj object)
-{
- struct vector *vector;
- int length, nwords;
-
- vector = (struct vector *) where;
- length = fixnum_value(vector->length);
- nwords = CEILING(length * 2 + 2, 2);
-
- return nwords;
-}
-
-static lispobj
-trans_vector_double_float(lispobj object)
-{
- struct vector *vector;
- int length, nwords;
-
- gc_assert(Pointerp(object));
-
- vector = (struct vector *) PTR(object);
- length = fixnum_value(vector->length);
- nwords = CEILING(length * 2 + 2, 2);
-
- return copy_large_unboxed_object(object, nwords);
-}
-
-static int
-size_vector_double_float(lispobj *where)
-{
- struct vector *vector;
- int length, nwords;
-
- vector = (struct vector *) where;
- length = fixnum_value(vector->length);
- nwords = CEILING(length * 2 + 2, 2);
-
- return nwords;
-}
-
-#ifdef type_SimpleArrayLongFloat
-static int
-scav_vector_long_float(lispobj *where, lispobj object)
-{
- struct vector *vector;
- int length, nwords;
-
- vector = (struct vector *) where;
- length = fixnum_value(vector->length);
- nwords = CEILING(length * 3 + 2, 2);
-
- return nwords;
-}
-
-static lispobj
-trans_vector_long_float(lispobj object)
-{
- struct vector *vector;
- int length, nwords;
-
- gc_assert(Pointerp(object));
-
- vector = (struct vector *) PTR(object);
- length = fixnum_value(vector->length);
- nwords = CEILING(length * 3 + 2, 2);
-
- return copy_large_unboxed_object(object, nwords);
-}
-
-static int
-size_vector_long_float(lispobj *where)
-{
- struct vector *vector;
- int length, nwords;
-
- vector = (struct vector *) where;
- length = fixnum_value(vector->length);
- nwords = CEILING(length * 3 + 2, 2);
-
- return nwords;
-}
-#endif
-
-
-#ifdef type_SimpleArrayComplexSingleFloat
-static int
-scav_vector_complex_single_float(lispobj *where, lispobj object)
-{
- struct vector *vector;
- int length, nwords;
-
- vector = (struct vector *) where;
- length = fixnum_value(vector->length);
- nwords = CEILING(length * 2 + 2, 2);
-
- return nwords;
-}
-
-static lispobj
-trans_vector_complex_single_float(lispobj object)
-{
- struct vector *vector;
- int length, nwords;
-
- gc_assert(Pointerp(object));
-
- vector = (struct vector *) PTR(object);
- length = fixnum_value(vector->length);
- nwords = CEILING(length * 2 + 2, 2);
-
- return copy_large_unboxed_object(object, nwords);
-}
-
-static int
-size_vector_complex_single_float(lispobj *where)
-{
- struct vector *vector;
- int length, nwords;
-
- vector = (struct vector *) where;
- length = fixnum_value(vector->length);
- nwords = CEILING(length * 2 + 2, 2);
-
- return nwords;
-}
-#endif
-
-#ifdef type_SimpleArrayComplexDoubleFloat
-static int
-scav_vector_complex_double_float(lispobj *where, lispobj object)
-{
- struct vector *vector;
- int length, nwords;
-
- vector = (struct vector *) where;
- length = fixnum_value(vector->length);
- nwords = CEILING(length * 4 + 2, 2);
-
- return nwords;
-}
-
-static lispobj
-trans_vector_complex_double_float(lispobj object)
-{
- struct vector *vector;
- int length, nwords;
-
- gc_assert(Pointerp(object));
-
- vector = (struct vector *) PTR(object);
- length = fixnum_value(vector->length);
- nwords = CEILING(length * 4 + 2, 2);
-
- return copy_large_unboxed_object(object, nwords);
-}
-
-static int
-size_vector_complex_double_float(lispobj *where)
-{
- struct vector *vector;
- int length, nwords;
-
- vector = (struct vector *) where;
- length = fixnum_value(vector->length);
- nwords = CEILING(length * 4 + 2, 2);
-
- return nwords;
-}
-#endif
-
-
-#ifdef type_SimpleArrayComplexLongFloat
-static int
-scav_vector_complex_long_float(lispobj *where, lispobj object)
-{
- struct vector *vector;
- int length, nwords;
-
- vector = (struct vector *) where;
- length = fixnum_value(vector->length);
- nwords = CEILING(length * 6 + 2, 2);
-
- return nwords;
-}
-
-static lispobj
-trans_vector_complex_long_float(lispobj object)
-{
- struct vector *vector;
- int length, nwords;
-
- gc_assert(Pointerp(object));
-
- vector = (struct vector *) PTR(object);
- length = fixnum_value(vector->length);
- nwords = CEILING(length * 6 + 2, 2);
-
- return copy_large_unboxed_object(object, nwords);
+ return (CEILING(kv_length + 2, 2));
}
-static int
-size_vector_complex_long_float(lispobj *where)
-{
- struct vector *vector;
- int length, nwords;
-
- vector = (struct vector *) where;
- length = fixnum_value(vector->length);
- nwords = CEILING(length * 6 + 2, 2);
-
- return nwords;
-}
-#endif
\f
/*
* weak pointers
*/
-/* XX This is a hack adapted from cgc.c. These don't work too well with the
- * gencgc as a list of the weak pointers is maintained within the
- * objects which causes writes to the pages. A limited attempt is made
- * to avoid unnecessary writes, but this needs a re-think. */
-
+/* XX This is a hack adapted from cgc.c. These don't work too
+ * efficiently with the gencgc as a list of the weak pointers is
+ * maintained within the objects which causes writes to the pages. A
+ * limited attempt is made to avoid unnecessary writes, but this needs
+ * a re-think. */
#define WEAK_POINTER_NWORDS \
CEILING((sizeof(struct weak_pointer) / sizeof(lispobj)), 2)
return WEAK_POINTER_NWORDS;
}
-static lispobj
-trans_weak_pointer(lispobj object)
-{
- lispobj copy;
- /* struct weak_pointer *wp; */
-
- gc_assert(Pointerp(object));
-
-#if defined(DEBUG_WEAK)
- FSHOW((stderr, "Transporting weak pointer from 0x%08x\n", object));
-#endif
-
- /* Need to remember where all the weak pointers are that have */
- /* been transported so they can be fixed up in a post-GC pass. */
-
- copy = copy_object(object, WEAK_POINTER_NWORDS);
- /* wp = (struct weak_pointer *) PTR(copy);*/
-
-
- /* Push the weak pointer onto the list of weak pointers. */
- /* wp->next = weak_pointers;
- * weak_pointers = wp;*/
-
- return copy;
-}
-
-static int
-size_weak_pointer(lispobj *where)
-{
- return WEAK_POINTER_NWORDS;
-}
-
-void scan_weak_pointers(void)
-{
- struct weak_pointer *wp;
- for (wp = weak_pointers; wp != NULL; wp = wp->next) {
- lispobj value = wp->value;
- lispobj *first_pointer;
-
- first_pointer = (lispobj *)PTR(value);
-
- /*
- FSHOW((stderr, "/weak pointer at 0x%08x\n", (unsigned long) wp));
- FSHOW((stderr, "/value: 0x%08x\n", (unsigned long) value));
- */
-
- if (Pointerp(value) && from_space_p(value)) {
- /* Now, we need to check whether the object has been forwarded. If
- * it has been, the weak pointer is still good and needs to be
- * updated. Otherwise, the weak pointer needs to be nil'ed
- * out. */
- if (first_pointer[0] == 0x01) {
- wp->value = first_pointer[1];
- } else {
- /* Break it. */
- SHOW("broken");
- wp->value = NIL;
- wp->broken = T;
- }
- }
- }
-}
-\f
-/*
- * initialization
- */
-
-static int
-scav_lose(lispobj *where, lispobj object)
-{
- lose("no scavenge function for object 0x%08x", (unsigned long) object);
- return 0; /* bogus return value to satisfy static type checking */
-}
-
-static lispobj
-trans_lose(lispobj object)
-{
- lose("no transport function for object 0x%08x", (unsigned long) object);
- return NIL; /* bogus return value to satisfy static type checking */
-}
-
-static int
-size_lose(lispobj *where)
-{
- lose("no size function for object at 0x%08x", (unsigned long) where);
- return 1; /* bogus return value to satisfy static type checking */
-}
-
-static void
-gc_init_tables(void)
-{
- int i;
-
- /* Set default value in all slots of scavenge table. */
- for (i = 0; i < 256; i++) { /* FIXME: bare constant length, ick! */
- scavtab[i] = scav_lose;
- }
-
- /* For each type which can be selected by the low 3 bits of the tag
- * alone, set multiple entries in our 8-bit scavenge table (one for each
- * possible value of the high 5 bits). */
- for (i = 0; i < 32; i++) { /* FIXME: bare constant length, ick! */
- scavtab[type_EvenFixnum|(i<<3)] = scav_immediate;
- scavtab[type_FunctionPointer|(i<<3)] = scav_function_pointer;
- /* OtherImmediate0 */
- scavtab[type_ListPointer|(i<<3)] = scav_list_pointer;
- scavtab[type_OddFixnum|(i<<3)] = scav_immediate;
- scavtab[type_InstancePointer|(i<<3)] = scav_instance_pointer;
- /* OtherImmediate1 */
- scavtab[type_OtherPointer|(i<<3)] = scav_other_pointer;
- }
-
- /* Other-pointer types (those selected by all eight bits of the tag) get
- * one entry each in the scavenge table. */
- scavtab[type_Bignum] = scav_unboxed;
- scavtab[type_Ratio] = scav_boxed;
- scavtab[type_SingleFloat] = scav_unboxed;
- scavtab[type_DoubleFloat] = scav_unboxed;
-#ifdef type_LongFloat
- scavtab[type_LongFloat] = scav_unboxed;
-#endif
- scavtab[type_Complex] = scav_boxed;
-#ifdef type_ComplexSingleFloat
- scavtab[type_ComplexSingleFloat] = scav_unboxed;
-#endif
-#ifdef type_ComplexDoubleFloat
- scavtab[type_ComplexDoubleFloat] = scav_unboxed;
-#endif
-#ifdef type_ComplexLongFloat
- scavtab[type_ComplexLongFloat] = scav_unboxed;
-#endif
- scavtab[type_SimpleArray] = scav_boxed;
- scavtab[type_SimpleString] = scav_string;
- scavtab[type_SimpleBitVector] = scav_vector_bit;
- scavtab[type_SimpleVector] = scav_vector;
- scavtab[type_SimpleArrayUnsignedByte2] = scav_vector_unsigned_byte_2;
- scavtab[type_SimpleArrayUnsignedByte4] = scav_vector_unsigned_byte_4;
- scavtab[type_SimpleArrayUnsignedByte8] = scav_vector_unsigned_byte_8;
- scavtab[type_SimpleArrayUnsignedByte16] = scav_vector_unsigned_byte_16;
- scavtab[type_SimpleArrayUnsignedByte32] = scav_vector_unsigned_byte_32;
-#ifdef type_SimpleArraySignedByte8
- scavtab[type_SimpleArraySignedByte8] = scav_vector_unsigned_byte_8;
-#endif
-#ifdef type_SimpleArraySignedByte16
- scavtab[type_SimpleArraySignedByte16] = scav_vector_unsigned_byte_16;
-#endif
-#ifdef type_SimpleArraySignedByte30
- scavtab[type_SimpleArraySignedByte30] = scav_vector_unsigned_byte_32;
-#endif
-#ifdef type_SimpleArraySignedByte32
- scavtab[type_SimpleArraySignedByte32] = scav_vector_unsigned_byte_32;
-#endif
- scavtab[type_SimpleArraySingleFloat] = scav_vector_single_float;
- scavtab[type_SimpleArrayDoubleFloat] = scav_vector_double_float;
-#ifdef type_SimpleArrayLongFloat
- scavtab[type_SimpleArrayLongFloat] = scav_vector_long_float;
-#endif
-#ifdef type_SimpleArrayComplexSingleFloat
- scavtab[type_SimpleArrayComplexSingleFloat] = scav_vector_complex_single_float;
-#endif
-#ifdef type_SimpleArrayComplexDoubleFloat
- scavtab[type_SimpleArrayComplexDoubleFloat] = scav_vector_complex_double_float;
-#endif
-#ifdef type_SimpleArrayComplexLongFloat
- scavtab[type_SimpleArrayComplexLongFloat] = scav_vector_complex_long_float;
-#endif
- scavtab[type_ComplexString] = scav_boxed;
- scavtab[type_ComplexBitVector] = scav_boxed;
- scavtab[type_ComplexVector] = scav_boxed;
- scavtab[type_ComplexArray] = scav_boxed;
- scavtab[type_CodeHeader] = scav_code_header;
- /*scavtab[type_FunctionHeader] = scav_function_header;*/
- /*scavtab[type_ClosureFunctionHeader] = scav_function_header;*/
- /*scavtab[type_ReturnPcHeader] = scav_return_pc_header;*/
-#ifdef __i386__
- scavtab[type_ClosureHeader] = scav_closure_header;
- scavtab[type_FuncallableInstanceHeader] = scav_closure_header;
- scavtab[type_ByteCodeFunction] = scav_closure_header;
- scavtab[type_ByteCodeClosure] = scav_closure_header;
-#else
- scavtab[type_ClosureHeader] = scav_boxed;
- scavtab[type_FuncallableInstanceHeader] = scav_boxed;
- scavtab[type_ByteCodeFunction] = scav_boxed;
- scavtab[type_ByteCodeClosure] = scav_boxed;
-#endif
- scavtab[type_ValueCellHeader] = scav_boxed;
- scavtab[type_SymbolHeader] = scav_boxed;
- scavtab[type_BaseChar] = scav_immediate;
- scavtab[type_Sap] = scav_unboxed;
- scavtab[type_UnboundMarker] = scav_immediate;
- scavtab[type_WeakPointer] = scav_weak_pointer;
- scavtab[type_InstanceHeader] = scav_boxed;
- scavtab[type_Fdefn] = scav_fdefn;
-
- /* transport other table, initialized same way as scavtab */
- for (i = 0; i < 256; i++)
- transother[i] = trans_lose;
- transother[type_Bignum] = trans_unboxed;
- transother[type_Ratio] = trans_boxed;
- transother[type_SingleFloat] = trans_unboxed;
- transother[type_DoubleFloat] = trans_unboxed;
-#ifdef type_LongFloat
- transother[type_LongFloat] = trans_unboxed;
-#endif
- transother[type_Complex] = trans_boxed;
-#ifdef type_ComplexSingleFloat
- transother[type_ComplexSingleFloat] = trans_unboxed;
-#endif
-#ifdef type_ComplexDoubleFloat
- transother[type_ComplexDoubleFloat] = trans_unboxed;
-#endif
-#ifdef type_ComplexLongFloat
- transother[type_ComplexLongFloat] = trans_unboxed;
-#endif
- transother[type_SimpleArray] = trans_boxed_large;
- transother[type_SimpleString] = trans_string;
- transother[type_SimpleBitVector] = trans_vector_bit;
- transother[type_SimpleVector] = trans_vector;
- transother[type_SimpleArrayUnsignedByte2] = trans_vector_unsigned_byte_2;
- transother[type_SimpleArrayUnsignedByte4] = trans_vector_unsigned_byte_4;
- transother[type_SimpleArrayUnsignedByte8] = trans_vector_unsigned_byte_8;
- transother[type_SimpleArrayUnsignedByte16] = trans_vector_unsigned_byte_16;
- transother[type_SimpleArrayUnsignedByte32] = trans_vector_unsigned_byte_32;
-#ifdef type_SimpleArraySignedByte8
- transother[type_SimpleArraySignedByte8] = trans_vector_unsigned_byte_8;
-#endif
-#ifdef type_SimpleArraySignedByte16
- transother[type_SimpleArraySignedByte16] = trans_vector_unsigned_byte_16;
-#endif
-#ifdef type_SimpleArraySignedByte30
- transother[type_SimpleArraySignedByte30] = trans_vector_unsigned_byte_32;
-#endif
-#ifdef type_SimpleArraySignedByte32
- transother[type_SimpleArraySignedByte32] = trans_vector_unsigned_byte_32;
-#endif
- transother[type_SimpleArraySingleFloat] = trans_vector_single_float;
- transother[type_SimpleArrayDoubleFloat] = trans_vector_double_float;
-#ifdef type_SimpleArrayLongFloat
- transother[type_SimpleArrayLongFloat] = trans_vector_long_float;
-#endif
-#ifdef type_SimpleArrayComplexSingleFloat
- transother[type_SimpleArrayComplexSingleFloat] = trans_vector_complex_single_float;
-#endif
-#ifdef type_SimpleArrayComplexDoubleFloat
- transother[type_SimpleArrayComplexDoubleFloat] = trans_vector_complex_double_float;
-#endif
-#ifdef type_SimpleArrayComplexLongFloat
- transother[type_SimpleArrayComplexLongFloat] = trans_vector_complex_long_float;
-#endif
- transother[type_ComplexString] = trans_boxed;
- transother[type_ComplexBitVector] = trans_boxed;
- transother[type_ComplexVector] = trans_boxed;
- transother[type_ComplexArray] = trans_boxed;
- transother[type_CodeHeader] = trans_code_header;
- transother[type_FunctionHeader] = trans_function_header;
- transother[type_ClosureFunctionHeader] = trans_function_header;
- transother[type_ReturnPcHeader] = trans_return_pc_header;
- transother[type_ClosureHeader] = trans_boxed;
- transother[type_FuncallableInstanceHeader] = trans_boxed;
- transother[type_ByteCodeFunction] = trans_boxed;
- transother[type_ByteCodeClosure] = trans_boxed;
- transother[type_ValueCellHeader] = trans_boxed;
- transother[type_SymbolHeader] = trans_boxed;
- transother[type_BaseChar] = trans_immediate;
- transother[type_Sap] = trans_unboxed;
- transother[type_UnboundMarker] = trans_immediate;
- transother[type_WeakPointer] = trans_weak_pointer;
- transother[type_InstanceHeader] = trans_boxed;
- transother[type_Fdefn] = trans_boxed;
-
- /* size table, initialized the same way as scavtab */
- for (i = 0; i < 256; i++)
- sizetab[i] = size_lose;
- for (i = 0; i < 32; i++) {
- sizetab[type_EvenFixnum|(i<<3)] = size_immediate;
- sizetab[type_FunctionPointer|(i<<3)] = size_pointer;
- /* OtherImmediate0 */
- sizetab[type_ListPointer|(i<<3)] = size_pointer;
- sizetab[type_OddFixnum|(i<<3)] = size_immediate;
- sizetab[type_InstancePointer|(i<<3)] = size_pointer;
- /* OtherImmediate1 */
- sizetab[type_OtherPointer|(i<<3)] = size_pointer;
- }
- sizetab[type_Bignum] = size_unboxed;
- sizetab[type_Ratio] = size_boxed;
- sizetab[type_SingleFloat] = size_unboxed;
- sizetab[type_DoubleFloat] = size_unboxed;
-#ifdef type_LongFloat
- sizetab[type_LongFloat] = size_unboxed;
-#endif
- sizetab[type_Complex] = size_boxed;
-#ifdef type_ComplexSingleFloat
- sizetab[type_ComplexSingleFloat] = size_unboxed;
-#endif
-#ifdef type_ComplexDoubleFloat
- sizetab[type_ComplexDoubleFloat] = size_unboxed;
-#endif
-#ifdef type_ComplexLongFloat
- sizetab[type_ComplexLongFloat] = size_unboxed;
-#endif
- sizetab[type_SimpleArray] = size_boxed;
- sizetab[type_SimpleString] = size_string;
- sizetab[type_SimpleBitVector] = size_vector_bit;
- sizetab[type_SimpleVector] = size_vector;
- sizetab[type_SimpleArrayUnsignedByte2] = size_vector_unsigned_byte_2;
- sizetab[type_SimpleArrayUnsignedByte4] = size_vector_unsigned_byte_4;
- sizetab[type_SimpleArrayUnsignedByte8] = size_vector_unsigned_byte_8;
- sizetab[type_SimpleArrayUnsignedByte16] = size_vector_unsigned_byte_16;
- sizetab[type_SimpleArrayUnsignedByte32] = size_vector_unsigned_byte_32;
-#ifdef type_SimpleArraySignedByte8
- sizetab[type_SimpleArraySignedByte8] = size_vector_unsigned_byte_8;
-#endif
-#ifdef type_SimpleArraySignedByte16
- sizetab[type_SimpleArraySignedByte16] = size_vector_unsigned_byte_16;
-#endif
-#ifdef type_SimpleArraySignedByte30
- sizetab[type_SimpleArraySignedByte30] = size_vector_unsigned_byte_32;
-#endif
-#ifdef type_SimpleArraySignedByte32
- sizetab[type_SimpleArraySignedByte32] = size_vector_unsigned_byte_32;
-#endif
- sizetab[type_SimpleArraySingleFloat] = size_vector_single_float;
- sizetab[type_SimpleArrayDoubleFloat] = size_vector_double_float;
-#ifdef type_SimpleArrayLongFloat
- sizetab[type_SimpleArrayLongFloat] = size_vector_long_float;
-#endif
-#ifdef type_SimpleArrayComplexSingleFloat
- sizetab[type_SimpleArrayComplexSingleFloat] = size_vector_complex_single_float;
-#endif
-#ifdef type_SimpleArrayComplexDoubleFloat
- sizetab[type_SimpleArrayComplexDoubleFloat] = size_vector_complex_double_float;
-#endif
-#ifdef type_SimpleArrayComplexLongFloat
- sizetab[type_SimpleArrayComplexLongFloat] = size_vector_complex_long_float;
-#endif
- sizetab[type_ComplexString] = size_boxed;
- sizetab[type_ComplexBitVector] = size_boxed;
- sizetab[type_ComplexVector] = size_boxed;
- sizetab[type_ComplexArray] = size_boxed;
- sizetab[type_CodeHeader] = size_code_header;
-#if 0
- /* We shouldn't see these, so just lose if it happens. */
- sizetab[type_FunctionHeader] = size_function_header;
- sizetab[type_ClosureFunctionHeader] = size_function_header;
- sizetab[type_ReturnPcHeader] = size_return_pc_header;
-#endif
- sizetab[type_ClosureHeader] = size_boxed;
- sizetab[type_FuncallableInstanceHeader] = size_boxed;
- sizetab[type_ValueCellHeader] = size_boxed;
- sizetab[type_SymbolHeader] = size_boxed;
- sizetab[type_BaseChar] = size_immediate;
- sizetab[type_Sap] = size_unboxed;
- sizetab[type_UnboundMarker] = size_immediate;
- sizetab[type_WeakPointer] = size_weak_pointer;
- sizetab[type_InstanceHeader] = size_boxed;
- sizetab[type_Fdefn] = size_boxed;
-}
\f
/* Scan an area looking for an object which encloses the given pointer.
* Return the object start on success or NULL on failure. */
size_t count = 1;
lispobj thing = *start;
- /* If thing is an immediate then this is a cons */
- if (Pointerp(thing)
+ /* If thing is an immediate then this is a cons. */
+ if (is_lisp_pointer(thing)
|| ((thing & 3) == 0) /* fixnum */
- || (TypeOf(thing) == type_BaseChar)
- || (TypeOf(thing) == type_UnboundMarker))
+ || (widetag_of(thing) == BASE_CHAR_WIDETAG)
+ || (widetag_of(thing) == UNBOUND_MARKER_WIDETAG))
count = 2;
else
- count = (sizetab[TypeOf(thing)])(start);
+ count = (sizetab[widetag_of(thing)])(start);
- /* Check whether the pointer is within this object? */
+ /* Check whether the pointer is within this object. */
if ((pointer >= start) && (pointer < (start+count))) {
/* found it! */
/*FSHOW((stderr,"/found %x in %x %x\n", pointer, start, thing));*/
return(start);
}
- /* Round up the count */
+ /* Round up the count. */
count = CEILING(count,2);
start += count;
int page_index = find_page_index(pointer);
lispobj *start;
- /* Address may be invalid - do some checks. */
+ /* The address may be invalid, so do some checks. */
if ((page_index == -1) || (page_table[page_index].allocated == FREE_PAGE))
return NULL;
start = (lispobj *)((void *)page_address(page_index)
return (search_space(start, (pointer+2)-start, pointer));
}
-/* FIXME: There is a strong family resemblance between this function
- * and the function of the same name in purify.c. Would it be possible
- * to implement them as exactly the same function? */
+/* Is there any possibility that pointer is a valid Lisp object
+ * reference, and/or something else (e.g. subroutine call return
+ * address) which should prevent us from moving the referred-to thing? */
static int
-valid_dynamic_space_pointer(lispobj *pointer)
+possibly_valid_dynamic_space_pointer(lispobj *pointer)
{
lispobj *start_addr;
- /* Find the object start address */
+ /* Find the object start address. */
if ((start_addr = search_dynamic_space(pointer)) == NULL) {
return 0;
}
/* We need to allow raw pointers into Code objects for return
- * addresses. This will also pickup pointers to functions in code
+ * addresses. This will also pick up pointers to functions in code
* objects. */
- if (TypeOf(*start_addr) == type_CodeHeader) {
- /* X Could do some further checks here. */
+ if (widetag_of(*start_addr) == CODE_HEADER_WIDETAG) {
+ /* XXX could do some further checks here */
return 1;
}
/* If it's not a return address then it needs to be a valid Lisp
* pointer. */
- if (!Pointerp((lispobj)pointer)) {
+ if (!is_lisp_pointer((lispobj)pointer)) {
return 0;
}
/* Check that the object pointed to is consistent with the pointer
- * low tag. */
- switch (LowtagOf((lispobj)pointer)) {
- case type_FunctionPointer:
+ * low tag.
+ *
+ * FIXME: It's not safe to rely on the result from this check
+ * before an object is initialized. Thus, if we were interrupted
+ * just as an object had been allocated but not initialized, the
+ * GC relying on this result could bogusly reclaim the memory.
+ * However, we can't really afford to do without this check. So
+ * we should make it safe somehow.
+ * (1) Perhaps just review the code to make sure
+ * that WITHOUT-GCING or WITHOUT-INTERRUPTS or some such
+ * thing is wrapped around critical sections where allocated
+ * memory type bits haven't been set.
+ * (2) Perhaps find some other hack to protect against this, e.g.
+ * recording the result of the last call to allocate-lisp-memory,
+ * and returning true from this function when *pointer is
+ * a reference to that result. */
+ switch (lowtag_of((lispobj)pointer)) {
+ case FUN_POINTER_LOWTAG:
/* Start_addr should be the enclosing code object, or a closure
- header. */
- switch (TypeOf(*start_addr)) {
- case type_CodeHeader:
+ * header. */
+ switch (widetag_of(*start_addr)) {
+ case CODE_HEADER_WIDETAG:
/* This case is probably caught above. */
break;
- case type_ClosureHeader:
- case type_FuncallableInstanceHeader:
- case type_ByteCodeFunction:
- case type_ByteCodeClosure:
+ case CLOSURE_HEADER_WIDETAG:
+ case FUNCALLABLE_INSTANCE_HEADER_WIDETAG:
if ((unsigned)pointer !=
- ((unsigned)start_addr+type_FunctionPointer)) {
+ ((unsigned)start_addr+FUN_POINTER_LOWTAG)) {
if (gencgc_verbose)
FSHOW((stderr,
"/Wf2: %x %x %x\n",
return 0;
}
break;
- case type_ListPointer:
+ case LIST_POINTER_LOWTAG:
if ((unsigned)pointer !=
- ((unsigned)start_addr+type_ListPointer)) {
+ ((unsigned)start_addr+LIST_POINTER_LOWTAG)) {
if (gencgc_verbose)
FSHOW((stderr,
"/Wl1: %x %x %x\n",
return 0;
}
/* Is it plausible cons? */
- if ((Pointerp(start_addr[0])
+ if ((is_lisp_pointer(start_addr[0])
|| ((start_addr[0] & 3) == 0) /* fixnum */
- || (TypeOf(start_addr[0]) == type_BaseChar)
- || (TypeOf(start_addr[0]) == type_UnboundMarker))
- && (Pointerp(start_addr[1])
+ || (widetag_of(start_addr[0]) == BASE_CHAR_WIDETAG)
+ || (widetag_of(start_addr[0]) == UNBOUND_MARKER_WIDETAG))
+ && (is_lisp_pointer(start_addr[1])
|| ((start_addr[1] & 3) == 0) /* fixnum */
- || (TypeOf(start_addr[1]) == type_BaseChar)
- || (TypeOf(start_addr[1]) == type_UnboundMarker)))
+ || (widetag_of(start_addr[1]) == BASE_CHAR_WIDETAG)
+ || (widetag_of(start_addr[1]) == UNBOUND_MARKER_WIDETAG)))
break;
else {
if (gencgc_verbose)
pointer, start_addr, *start_addr));
return 0;
}
- case type_InstancePointer:
+ case INSTANCE_POINTER_LOWTAG:
if ((unsigned)pointer !=
- ((unsigned)start_addr+type_InstancePointer)) {
+ ((unsigned)start_addr+INSTANCE_POINTER_LOWTAG)) {
if (gencgc_verbose)
FSHOW((stderr,
"/Wi1: %x %x %x\n",
pointer, start_addr, *start_addr));
return 0;
}
- if (TypeOf(start_addr[0]) != type_InstanceHeader) {
+ if (widetag_of(start_addr[0]) != INSTANCE_HEADER_WIDETAG) {
if (gencgc_verbose)
FSHOW((stderr,
"/Wi2: %x %x %x\n",
return 0;
}
break;
- case type_OtherPointer:
+ case OTHER_POINTER_LOWTAG:
if ((unsigned)pointer !=
- ((int)start_addr+type_OtherPointer)) {
+ ((int)start_addr+OTHER_POINTER_LOWTAG)) {
if (gencgc_verbose)
FSHOW((stderr,
"/Wo1: %x %x %x\n",
pointer, start_addr, *start_addr));
return 0;
}
- /* Is it plausible? Not a cons. X should check the headers. */
- if (Pointerp(start_addr[0]) || ((start_addr[0] & 3) == 0)) {
+ /* Is it plausible? Not a cons. XXX should check the headers. */
+ if (is_lisp_pointer(start_addr[0]) || ((start_addr[0] & 3) == 0)) {
if (gencgc_verbose)
FSHOW((stderr,
"/Wo2: %x %x %x\n",
pointer, start_addr, *start_addr));
return 0;
}
- switch (TypeOf(start_addr[0])) {
- case type_UnboundMarker:
- case type_BaseChar:
+ switch (widetag_of(start_addr[0])) {
+ case UNBOUND_MARKER_WIDETAG:
+ case BASE_CHAR_WIDETAG:
if (gencgc_verbose)
FSHOW((stderr,
"*Wo3: %x %x %x\n",
return 0;
/* only pointed to by function pointers? */
- case type_ClosureHeader:
- case type_FuncallableInstanceHeader:
- case type_ByteCodeFunction:
- case type_ByteCodeClosure:
+ case CLOSURE_HEADER_WIDETAG:
+ case FUNCALLABLE_INSTANCE_HEADER_WIDETAG:
if (gencgc_verbose)
FSHOW((stderr,
"*Wo4: %x %x %x\n",
pointer, start_addr, *start_addr));
return 0;
- case type_InstanceHeader:
+ case INSTANCE_HEADER_WIDETAG:
if (gencgc_verbose)
FSHOW((stderr,
"*Wo5: %x %x %x\n",
return 0;
/* the valid other immediate pointer objects */
- case type_SimpleVector:
- case type_Ratio:
- case type_Complex:
-#ifdef type_ComplexSingleFloat
- case type_ComplexSingleFloat:
+ case SIMPLE_VECTOR_WIDETAG:
+ case RATIO_WIDETAG:
+ case COMPLEX_WIDETAG:
+#ifdef COMPLEX_SINGLE_FLOAT_WIDETAG
+ case COMPLEX_SINGLE_FLOAT_WIDETAG:
#endif
-#ifdef type_ComplexDoubleFloat
- case type_ComplexDoubleFloat:
+#ifdef COMPLEX_DOUBLE_FLOAT_WIDETAG
+ case COMPLEX_DOUBLE_FLOAT_WIDETAG:
#endif
-#ifdef type_ComplexLongFloat
- case type_ComplexLongFloat:
+#ifdef COMPLEX_LONG_FLOAT_WIDETAG
+ case COMPLEX_LONG_FLOAT_WIDETAG:
#endif
- case type_SimpleArray:
- case type_ComplexString:
- case type_ComplexBitVector:
- case type_ComplexVector:
- case type_ComplexArray:
- case type_ValueCellHeader:
- case type_SymbolHeader:
- case type_Fdefn:
- case type_CodeHeader:
- case type_Bignum:
- case type_SingleFloat:
- case type_DoubleFloat:
-#ifdef type_LongFloat
- case type_LongFloat:
+ case SIMPLE_ARRAY_WIDETAG:
+ case COMPLEX_STRING_WIDETAG:
+ case COMPLEX_BIT_VECTOR_WIDETAG:
+ case COMPLEX_VECTOR_WIDETAG:
+ case COMPLEX_ARRAY_WIDETAG:
+ case VALUE_CELL_HEADER_WIDETAG:
+ case SYMBOL_HEADER_WIDETAG:
+ case FDEFN_WIDETAG:
+ case CODE_HEADER_WIDETAG:
+ case BIGNUM_WIDETAG:
+ case SINGLE_FLOAT_WIDETAG:
+ case DOUBLE_FLOAT_WIDETAG:
+#ifdef LONG_FLOAT_WIDETAG
+ case LONG_FLOAT_WIDETAG:
#endif
- case type_SimpleString:
- case type_SimpleBitVector:
- case type_SimpleArrayUnsignedByte2:
- case type_SimpleArrayUnsignedByte4:
- case type_SimpleArrayUnsignedByte8:
- case type_SimpleArrayUnsignedByte16:
- case type_SimpleArrayUnsignedByte32:
-#ifdef type_SimpleArraySignedByte8
- case type_SimpleArraySignedByte8:
+ case SIMPLE_STRING_WIDETAG:
+ case SIMPLE_BIT_VECTOR_WIDETAG:
+ case SIMPLE_ARRAY_UNSIGNED_BYTE_2_WIDETAG:
+ case SIMPLE_ARRAY_UNSIGNED_BYTE_4_WIDETAG:
+ case SIMPLE_ARRAY_UNSIGNED_BYTE_8_WIDETAG:
+ case SIMPLE_ARRAY_UNSIGNED_BYTE_16_WIDETAG:
+ case SIMPLE_ARRAY_UNSIGNED_BYTE_32_WIDETAG:
+#ifdef SIMPLE_ARRAY_SIGNED_BYTE_8_WIDETAG
+ case SIMPLE_ARRAY_SIGNED_BYTE_8_WIDETAG:
#endif
-#ifdef type_SimpleArraySignedByte16
- case type_SimpleArraySignedByte16:
+#ifdef SIMPLE_ARRAY_SIGNED_BYTE_16_WIDETAG
+ case SIMPLE_ARRAY_SIGNED_BYTE_16_WIDETAG:
#endif
-#ifdef type_SimpleArraySignedByte30
- case type_SimpleArraySignedByte30:
+#ifdef SIMPLE_ARRAY_SIGNED_BYTE_30_WIDETAG
+ case SIMPLE_ARRAY_SIGNED_BYTE_30_WIDETAG:
#endif
-#ifdef type_SimpleArraySignedByte32
- case type_SimpleArraySignedByte32:
+#ifdef SIMPLE_ARRAY_SIGNED_BYTE_32_WIDETAG
+ case SIMPLE_ARRAY_SIGNED_BYTE_32_WIDETAG:
#endif
- case type_SimpleArraySingleFloat:
- case type_SimpleArrayDoubleFloat:
-#ifdef type_SimpleArrayLongFloat
- case type_SimpleArrayLongFloat:
+ case SIMPLE_ARRAY_SINGLE_FLOAT_WIDETAG:
+ case SIMPLE_ARRAY_DOUBLE_FLOAT_WIDETAG:
+#ifdef SIMPLE_ARRAY_LONG_FLOAT_WIDETAG
+ case SIMPLE_ARRAY_LONG_FLOAT_WIDETAG:
#endif
-#ifdef type_SimpleArrayComplexSingleFloat
- case type_SimpleArrayComplexSingleFloat:
+#ifdef SIMPLE_ARRAY_COMPLEX_SINGLE_FLOAT_WIDETAG
+ case SIMPLE_ARRAY_COMPLEX_SINGLE_FLOAT_WIDETAG:
#endif
-#ifdef type_SimpleArrayComplexDoubleFloat
- case type_SimpleArrayComplexDoubleFloat:
+#ifdef SIMPLE_ARRAY_COMPLEX_DOUBLE_FLOAT_WIDETAG
+ case SIMPLE_ARRAY_COMPLEX_DOUBLE_FLOAT_WIDETAG:
#endif
-#ifdef type_SimpleArrayComplexLongFloat
- case type_SimpleArrayComplexLongFloat:
+#ifdef SIMPLE_ARRAY_COMPLEX_LONG_FLOAT_WIDETAG
+ case SIMPLE_ARRAY_COMPLEX_LONG_FLOAT_WIDETAG:
#endif
- case type_Sap:
- case type_WeakPointer:
+ case SAP_WIDETAG:
+ case WEAK_POINTER_WIDETAG:
break;
default:
return 1;
}
-/* Adjust large bignum and vector objects. This will adjust the allocated
- * region if the size has shrunk, and move unboxed objects into unboxed
- * pages. The pages are not promoted here, and the promoted region is not
- * added to the new_regions; this is really only designed to be called from
- * preserve_pointer. Shouldn't fail if this is missed, just may delay the
- * moving of objects to unboxed pages, and the freeing of pages. */
+/* Adjust large bignum and vector objects. This will adjust the
+ * allocated region if the size has shrunk, and move unboxed objects
+ * into unboxed pages. The pages are not promoted here, and the
+ * promoted region is not added to the new_regions; this is really
+ * only designed to be called from preserve_pointer(). Shouldn't fail
+ * if this is missed, just may delay the moving of objects to unboxed
+ * pages, and the freeing of pages. */
static void
maybe_adjust_large_object(lispobj *where)
{
int boxed;
/* Check whether it's a vector or bignum object. */
- switch (TypeOf(where[0])) {
- case type_SimpleVector:
+ switch (widetag_of(where[0])) {
+ case SIMPLE_VECTOR_WIDETAG:
boxed = BOXED_PAGE;
break;
- case type_Bignum:
- case type_SimpleString:
- case type_SimpleBitVector:
- case type_SimpleArrayUnsignedByte2:
- case type_SimpleArrayUnsignedByte4:
- case type_SimpleArrayUnsignedByte8:
- case type_SimpleArrayUnsignedByte16:
- case type_SimpleArrayUnsignedByte32:
-#ifdef type_SimpleArraySignedByte8
- case type_SimpleArraySignedByte8:
+ case BIGNUM_WIDETAG:
+ case SIMPLE_STRING_WIDETAG:
+ case SIMPLE_BIT_VECTOR_WIDETAG:
+ case SIMPLE_ARRAY_UNSIGNED_BYTE_2_WIDETAG:
+ case SIMPLE_ARRAY_UNSIGNED_BYTE_4_WIDETAG:
+ case SIMPLE_ARRAY_UNSIGNED_BYTE_8_WIDETAG:
+ case SIMPLE_ARRAY_UNSIGNED_BYTE_16_WIDETAG:
+ case SIMPLE_ARRAY_UNSIGNED_BYTE_32_WIDETAG:
+#ifdef SIMPLE_ARRAY_SIGNED_BYTE_8_WIDETAG
+ case SIMPLE_ARRAY_SIGNED_BYTE_8_WIDETAG:
#endif
-#ifdef type_SimpleArraySignedByte16
- case type_SimpleArraySignedByte16:
+#ifdef SIMPLE_ARRAY_SIGNED_BYTE_16_WIDETAG
+ case SIMPLE_ARRAY_SIGNED_BYTE_16_WIDETAG:
#endif
-#ifdef type_SimpleArraySignedByte30
- case type_SimpleArraySignedByte30:
+#ifdef SIMPLE_ARRAY_SIGNED_BYTE_30_WIDETAG
+ case SIMPLE_ARRAY_SIGNED_BYTE_30_WIDETAG:
#endif
-#ifdef type_SimpleArraySignedByte32
- case type_SimpleArraySignedByte32:
+#ifdef SIMPLE_ARRAY_SIGNED_BYTE_32_WIDETAG
+ case SIMPLE_ARRAY_SIGNED_BYTE_32_WIDETAG:
#endif
- case type_SimpleArraySingleFloat:
- case type_SimpleArrayDoubleFloat:
-#ifdef type_SimpleArrayLongFloat
- case type_SimpleArrayLongFloat:
+ case SIMPLE_ARRAY_SINGLE_FLOAT_WIDETAG:
+ case SIMPLE_ARRAY_DOUBLE_FLOAT_WIDETAG:
+#ifdef SIMPLE_ARRAY_LONG_FLOAT_WIDETAG
+ case SIMPLE_ARRAY_LONG_FLOAT_WIDETAG:
#endif
-#ifdef type_SimpleArrayComplexSingleFloat
- case type_SimpleArrayComplexSingleFloat:
+#ifdef SIMPLE_ARRAY_COMPLEX_SINGLE_FLOAT_WIDETAG
+ case SIMPLE_ARRAY_COMPLEX_SINGLE_FLOAT_WIDETAG:
#endif
-#ifdef type_SimpleArrayComplexDoubleFloat
- case type_SimpleArrayComplexDoubleFloat:
+#ifdef SIMPLE_ARRAY_COMPLEX_DOUBLE_FLOAT_WIDETAG
+ case SIMPLE_ARRAY_COMPLEX_DOUBLE_FLOAT_WIDETAG:
#endif
-#ifdef type_SimpleArrayComplexLongFloat
- case type_SimpleArrayComplexLongFloat:
+#ifdef SIMPLE_ARRAY_COMPLEX_LONG_FLOAT_WIDETAG
+ case SIMPLE_ARRAY_COMPLEX_LONG_FLOAT_WIDETAG:
#endif
boxed = UNBOXED_PAGE;
break;
}
/* Find its current size. */
- nwords = (sizetab[TypeOf(where[0])])(where);
+ nwords = (sizetab[widetag_of(where[0])])(where);
first_page = find_page_index((void *)where);
gc_assert(first_page >= 0);
next_page++;
}
- if ((bytes_freed > 0) && gencgc_verbose)
- FSHOW((stderr, "/adjust_large_object freed %d\n", bytes_freed));
+ if ((bytes_freed > 0) && gencgc_verbose) {
+ FSHOW((stderr,
+ "/maybe_adjust_large_object() freed %d\n",
+ bytes_freed));
+ }
generations[from_space].bytes_allocated -= bytes_freed;
bytes_allocated -= bytes_freed;
return;
}
-/* Take a possible pointer to a list object and mark the page_table
- * so that it will not need changing during a GC.
+/* Take a possible pointer to a Lisp object and mark its page in the
+ * page_table so that it will not be relocated during a GC.
*
* This involves locating the page it points to, then backing up to
* the first page that has its first object start at offset 0, and
- * then marking all pages dont_move from the first until a page that ends
- * by being full, or having free gen.
+ * then marking all pages dont_move from the first until a page that
+ * ends by being full, or having free gen.
*
* This ensures that objects spanning pages are not broken.
*
* It is assumed that all the page static flags have been cleared at
* the start of a GC.
*
- * It is also assumed that the current gc_alloc region has been flushed and
- * the tables updated. */
+ * It is also assumed that the current gc_alloc() region has been
+ * flushed and the tables updated. */
static void
preserve_pointer(void *addr)
{
int i;
unsigned region_allocation;
- /* Address is quite likely to have been invalid - do some checks. */
+ /* quick check 1: Address is quite likely to have been invalid. */
if ((addr_page_index == -1)
|| (page_table[addr_page_index].allocated == FREE_PAGE)
|| (page_table[addr_page_index].bytes_used == 0)
|| (page_table[addr_page_index].gen != from_space)
- /* Skip if already marked dont_move */
+ /* Skip if already marked dont_move. */
|| (page_table[addr_page_index].dont_move != 0))
return;
-
+ gc_assert(!(page_table[addr_page_index].allocated & OPEN_REGION_PAGE));
+ /* (Now that we know that addr_page_index is in range, it's
+ * safe to index into page_table[] with it.) */
region_allocation = page_table[addr_page_index].allocated;
- /* Check the offset within the page.
+ /* quick check 2: Check the offset within the page.
*
* FIXME: The mask should have a symbolic name, and ideally should
* be derived from page size instead of hardwired to 0xfff.
if (((unsigned)addr & 0xfff) > page_table[addr_page_index].bytes_used)
return;
- if (enable_pointer_filter && !valid_dynamic_space_pointer(addr))
+ /* Filter out anything which can't be a pointer to a Lisp object
+ * (or, as a special case which also requires dont_move, a return
+ * address referring to something in a CodeObject). This is
+ * expensive but important, since it vastly reduces the
+ * probability that random garbage will be bogusly interpreter as
+ * a pointer which prevents a page from moving. */
+ if (!(possibly_valid_dynamic_space_pointer(addr)))
return;
+ first_page = addr_page_index;
/* Work backwards to find a page with a first_object_offset of 0.
* The pages should be contiguous with all bytes used in the same
* gen. Assumes the first_object_offset is negative or zero. */
- first_page = addr_page_index;
+
+ /* this is probably needlessly conservative. The first object in
+ * the page may not even be the one we were passed a pointer to:
+ * if this is the case, we will write-protect all the previous
+ * object's pages too.
+ */
+
while (page_table[first_page].first_object_offset != 0) {
- first_page--;
+ --first_page;
/* Do some checks. */
gc_assert(page_table[first_page].bytes_used == 4096);
gc_assert(page_table[first_page].gen == from_space);
gc_assert(page_table[first_page].allocated == region_allocation);
}
- /* Adjust any large objects before promotion as they won't be copied
- * after promotion. */
+ /* Adjust any large objects before promotion as they won't be
+ * copied after promotion. */
if (page_table[first_page].large_object) {
maybe_adjust_large_object(page_address(first_page));
- /* If a large object has shrunk then addr may now point to a free
- * area in which case it's ignored here. Note it gets through the
- * valid pointer test above because the tail looks like conses. */
+ /* If a large object has shrunk then addr may now point to a
+ * free area in which case it's ignored here. Note it gets
+ * through the valid pointer test above because the tail looks
+ * like conses. */
if ((page_table[addr_page_index].allocated == FREE_PAGE)
|| (page_table[addr_page_index].bytes_used == 0)
/* Check the offset within the page. */
/* Mark the page static. */
page_table[i].dont_move = 1;
- /* Move the page to the new_space. XX I'd rather not do this but
- * the GC logic is not quite able to copy with the static pages
- * remaining in the from space. This also requires the generation
- * bytes_allocated counters be updated. */
+ /* Move the page to the new_space. XX I'd rather not do this
+ * but the GC logic is not quite able to copy with the static
+ * pages remaining in the from space. This also requires the
+ * generation bytes_allocated counters be updated. */
page_table[i].gen = new_space;
generations[new_space].bytes_allocated += page_table[i].bytes_used;
generations[from_space].bytes_allocated -= page_table[i].bytes_used;
- /* It is essential that the pages are not write protected as they
- * may have pointers into the old-space which need scavenging. They
- * shouldn't be write protected at this stage. */
+ /* It is essential that the pages are not write protected as
+ * they may have pointers into the old-space which need
+ * scavenging. They shouldn't be write protected at this
+ * stage. */
gc_assert(!page_table[i].write_protected);
/* Check whether this is the last page in this contiguous block.. */
/* Check that the page is now static. */
gc_assert(page_table[addr_page_index].dont_move != 0);
-
- return;
-}
-
-#ifdef CONTROL_STACKS
-/* Scavenge the thread stack conservative roots. */
-static void
-scavenge_thread_stacks(void)
-{
- lispobj thread_stacks = SymbolValue(CONTROL_STACKS);
- int type = TypeOf(thread_stacks);
-
- if (LowtagOf(thread_stacks) == type_OtherPointer) {
- struct vector *vector = (struct vector *) PTR(thread_stacks);
- int length, i;
- if (TypeOf(vector->header) != type_SimpleVector)
- return;
- length = fixnum_value(vector->length);
- for (i = 0; i < length; i++) {
- lispobj stack_obj = vector->data[i];
- if (LowtagOf(stack_obj) == type_OtherPointer) {
- struct vector *stack = (struct vector *) PTR(stack_obj);
- int vector_length;
- if (TypeOf(stack->header) !=
- type_SimpleArrayUnsignedByte32) {
- return;
- }
- vector_length = fixnum_value(stack->length);
- if ((gencgc_verbose > 1) && (vector_length <= 0))
- FSHOW((stderr,
- "/weird? control stack vector length %d\n",
- vector_length));
- if (vector_length > 0) {
- lispobj *stack_pointer = (lispobj*)stack->data[0];
- if ((stack_pointer < (lispobj *)CONTROL_STACK_START) ||
- (stack_pointer > (lispobj *)CONTROL_STACK_END))
- lose("invalid stack pointer %x",
- (unsigned)stack_pointer);
- if ((stack_pointer > (lispobj *)CONTROL_STACK_START) &&
- (stack_pointer < (lispobj *)CONTROL_STACK_END)) {
- /* FIXME: Ick!
- * (1) hardwired word length = 4; and as usual,
- * when fixing this, check for other places
- * with the same problem
- * (2) calling it 'length' suggests bytes;
- * perhaps 'size' instead? */
- unsigned int length = ((unsigned)CONTROL_STACK_END -
- (unsigned)stack_pointer) / 4;
- int j;
- if (length >= vector_length) {
- lose("invalid stack size %d >= vector length %d",
- length,
- vector_length);
- }
- if (gencgc_verbose > 1) {
- FSHOW((stderr,
- "scavenging %d words of control stack %d of length %d words.\n",
- length, i, vector_length));
- }
- for (j = 0; j < length; j++) {
- preserve_pointer((void *)stack->data[1+j]);
- }
- }
- }
- }
- }
- }
}
-#endif
-
\f
/* If the given page is not write-protected, then scan it for pointers
* to younger generations or the top temp. generation, if no
* suspicious pointers are found then the page is write-protected.
*
- * Care is taken to check for pointers to the current gc_alloc region
- * if it is a younger generation or the temp. generation. This frees
- * the caller from doing a gc_alloc_update_page_tables. Actually the
- * gc_alloc_generation does not need to be checked as this is only
- * called from scavenge_generation when the gc_alloc generation is
+ * Care is taken to check for pointers to the current gc_alloc()
+ * region if it is a younger generation or the temp. generation. This
+ * frees the caller from doing a gc_alloc_update_page_tables(). Actually
+ * the gc_alloc_generation does not need to be checked as this is only
+ * called from scavenge_generation() when the gc_alloc generation is
* younger, so it just checks if there is a pointer to the current
* region.
*
- * We return 1 if the page was write-protected, else 0.
- */
+ * We return 1 if the page was write-protected, else 0. */
static int
update_page_write_prot(int page)
{
/* Skip if it's already write-protected or an unboxed page. */
if (page_table[page].write_protected
- || (page_table[page].allocated == UNBOXED_PAGE))
+ || (page_table[page].allocated & UNBOXED_PAGE))
return (0);
/* Scan the page for pointers to younger generations or the
&& ((page_table[index].gen < gen)
|| (page_table[index].gen == NUM_GENERATIONS)))
- /* Or does it point within a current gc_alloc region? */
+ /* Or does it point within a current gc_alloc() region? */
|| ((boxed_region.start_addr <= ptr)
&& (ptr <= boxed_region.free_pointer))
|| ((unboxed_region.start_addr <= ptr)
#endif
for (i = 0; i < last_free_page; i++) {
- if ((page_table[i].allocated == BOXED_PAGE)
+ if ((page_table[i].allocated & BOXED_PAGE)
&& (page_table[i].bytes_used != 0)
&& (page_table[i].gen == generation)) {
int last_page;
/* Now work forward until the end of this contiguous area
* is found. A small area is preferred as there is a
* better chance of its pages being write-protected. */
- for (last_page = i; ;last_page++)
+ for (last_page = i; ; last_page++)
/* Check whether this is the last page in this contiguous
* block. */
if ((page_table[last_page].bytes_used < 4096)
/* Or it is 4096 and is the last in the block */
- || (page_table[last_page+1].allocated != BOXED_PAGE)
+ || (!(page_table[last_page+1].allocated & BOXED_PAGE))
|| (page_table[last_page+1].bytes_used == 0)
|| (page_table[last_page+1].gen != generation)
|| (page_table[last_page+1].first_object_offset == 0))
&& (page_table[i].bytes_used != 0)
&& (page_table[i].gen == generation)
&& (page_table[i].write_protected_cleared != 0)) {
- FSHOW((stderr, "/scavenge_generation %d\n", generation));
+ FSHOW((stderr, "/scavenge_generation() %d\n", generation));
FSHOW((stderr,
"/page bytes_used=%d first_object_offset=%d dont_move=%d\n",
page_table[i].bytes_used,
page_table[i].first_object_offset,
page_table[i].dont_move));
- lose("write-protected page %d written to in scavenge_generation",
- i);
+ lose("write to protected page %d in scavenge_generation()", i);
}
}
#endif
* newspace generation.
*
* To help improve the efficiency, areas written are recorded by
- * gc_alloc and only these scavenged. Sometimes a little more will be
+ * gc_alloc() and only these scavenged. Sometimes a little more will be
* scavenged, but this causes no harm. An easy check is done that the
* scavenged bytes equals the number allocated in the previous
* scavenge.
*
* Write-protected pages could potentially be written by alloc however
* to avoid having to handle re-scavenging of write-protected pages
- * gc_alloc does not write to write-protected pages.
+ * gc_alloc() does not write to write-protected pages.
*
* New areas of objects allocated are recorded alternatively in the two
* new_areas arrays below. */
FSHOW((stderr,
"/starting one full scan of newspace generation %d\n",
generation));
-
for (i = 0; i < last_free_page; i++) {
+ /* note that this skips over open regions when it encounters them */
if ((page_table[i].allocated == BOXED_PAGE)
&& (page_table[i].bytes_used != 0)
&& (page_table[i].gen == generation)
/* The scavenge will start at the first_object_offset of page i.
*
- * We need to find the full extent of this contiguous block in case
- * objects span pages.
+ * We need to find the full extent of this contiguous
+ * block in case objects span pages.
*
- * Now work forward until the end of this contiguous area is
- * found. A small area is preferred as there is a better chance
- * of its pages being write-protected. */
+ * Now work forward until the end of this contiguous area
+ * is found. A small area is preferred as there is a
+ * better chance of its pages being write-protected. */
for (last_page = i; ;last_page++) {
- /* Check whether this is the last page in this contiguous
- * block */
+ /* Check whether this is the last page in this
+ * contiguous block */
if ((page_table[last_page].bytes_used < 4096)
/* Or it is 4096 and is the last in the block */
- || (page_table[last_page+1].allocated != BOXED_PAGE)
+ || (!(page_table[last_page+1].allocated & BOXED_PAGE))
|| (page_table[last_page+1].bytes_used == 0)
|| (page_table[last_page+1].gen != generation)
|| (page_table[last_page+1].first_object_offset == 0))
break;
}
- /* Do a limited check for write_protected pages. If all pages
- * are write_protected then no need to scavenge. Except if the
- * pages are marked dont_move. */
+ /* Do a limited check for write-protected pages. If all
+ * pages are write-protected then no need to scavenge,
+ * except if the pages are marked dont_move. */
{
int j, all_wp = 1;
for (j = i; j <= last_page; j++)
all_wp = 0;
break;
}
-#if !SC_NS_GEN_CK
- if (all_wp == 0)
-#endif
- {
- int size;
-
- /* Calculate the size. */
- if (last_page == i)
- size = (page_table[last_page].bytes_used
- - page_table[i].first_object_offset)/4;
- else
- size = (page_table[last_page].bytes_used
- + (last_page-i)*4096
- - page_table[i].first_object_offset)/4;
-
- {
-#if SC_NS_GEN_CK
- int a1 = bytes_allocated;
-#endif
- /* FSHOW((stderr,
- "/scavenge(%x,%d)\n",
- page_address(i)
- + page_table[i].first_object_offset,
- size)); */
- new_areas_ignore_page = last_page;
+ if (!all_wp) {
+ int size;
- scavenge(page_address(i)+page_table[i].first_object_offset,size);
+ /* Calculate the size. */
+ if (last_page == i)
+ size = (page_table[last_page].bytes_used
+ - page_table[i].first_object_offset)/4;
+ else
+ size = (page_table[last_page].bytes_used
+ + (last_page-i)*4096
+ - page_table[i].first_object_offset)/4;
+
+ {
+ new_areas_ignore_page = last_page;
+
+ scavenge(page_address(i) +
+ page_table[i].first_object_offset,
+ size);
-#if SC_NS_GEN_CK
- /* Flush the alloc regions updating the tables. */
- gc_alloc_update_page_tables(0, &boxed_region);
- gc_alloc_update_page_tables(1, &unboxed_region);
-
- if ((all_wp != 0) && (a1 != bytes_allocated)) {
- FSHOW((stderr,
- "alloc'ed over %d to %d\n",
- i, last_page));
- FSHOW((stderr,
- "/page: bytes_used=%d first_object_offset=%d dont_move=%d wp=%d wpc=%d\n",
- page_table[i].bytes_used,
- page_table[i].first_object_offset,
- page_table[i].dont_move,
- page_table[i].write_protected,
- page_table[i].write_protected_cleared));
- }
-#endif
- }
}
+ }
}
i = last_page;
}
}
+ FSHOW((stderr,
+ "/done with one full scan of newspace generation %d\n",
+ generation));
}
/* Do a complete scavenge of the newspace generation. */
{
int i;
- /* the new_areas array currently being written to by gc_alloc */
- struct new_area (*current_new_areas)[] = &new_areas_1;
+ /* the new_areas array currently being written to by gc_alloc() */
+ struct new_area (*current_new_areas)[] = &new_areas_1;
int current_new_areas_index;
/* the new_areas created but the previous scavenge cycle */
- struct new_area (*previous_new_areas)[] = NULL;
+ struct new_area (*previous_new_areas)[] = NULL;
int previous_new_areas_index;
-#define SC_NS_GEN_CK 0
-#if SC_NS_GEN_CK
- /* Clear the write_protected_cleared flags on all pages. */
- for (i = 0; i < NUM_PAGES; i++)
- page_table[i].write_protected_cleared = 0;
-#endif
-
/* Flush the current regions updating the tables. */
- gc_alloc_update_page_tables(0, &boxed_region);
- gc_alloc_update_page_tables(1, &unboxed_region);
+ gc_alloc_update_all_page_tables();
- /* Turn on the recording of new areas by gc_alloc. */
+ /* Turn on the recording of new areas by gc_alloc(). */
new_areas = current_new_areas;
new_areas_index = 0;
record_new_objects = 2;
/* Flush the current regions updating the tables. */
- gc_alloc_update_page_tables(0, &boxed_region);
- gc_alloc_update_page_tables(1, &unboxed_region);
+ gc_alloc_update_all_page_tables();
/* Grab new_areas_index. */
current_new_areas_index = new_areas_index;
else
current_new_areas = &new_areas_1;
- /* Set up for gc_alloc. */
+ /* Set up for gc_alloc(). */
new_areas = current_new_areas;
new_areas_index = 0;
/* Check whether previous_new_areas had overflowed. */
if (previous_new_areas_index >= NUM_NEW_AREAS) {
+
/* New areas of objects allocated have been lost so need to do a
* full scan to be sure! If this becomes a problem try
* increasing NUM_NEW_AREAS. */
record_new_objects = 2;
/* Flush the current regions updating the tables. */
- gc_alloc_update_page_tables(0, &boxed_region);
- gc_alloc_update_page_tables(1, &unboxed_region);
+ gc_alloc_update_all_page_tables();
+
} else {
+
/* Work through previous_new_areas. */
for (i = 0; i < previous_new_areas_index; i++) {
+ /* FIXME: All these bare *4 and /4 should be something
+ * like BYTES_PER_WORD or WBYTES. */
int page = (*previous_new_areas)[i].page;
int offset = (*previous_new_areas)[i].offset;
int size = (*previous_new_areas)[i].size / 4;
gc_assert((*previous_new_areas)[i].size % 4 == 0);
-
- /* FIXME: All these bare *4 and /4 should be something
- * like BYTES_PER_WORD or WBYTES. */
-
- /*FSHOW((stderr,
- "/S page %d offset %d size %d\n",
- page, offset, size*4));*/
scavenge(page_address(page)+offset, size);
}
/* Flush the current regions updating the tables. */
- gc_alloc_update_page_tables(0, &boxed_region);
- gc_alloc_update_page_tables(1, &unboxed_region);
+ gc_alloc_update_all_page_tables();
}
current_new_areas_index = new_areas_index;
current_new_areas_index));*/
}
- /* Turn off recording of areas allocated by gc_alloc. */
+ /* Turn off recording of areas allocated by gc_alloc(). */
record_new_objects = 0;
#if SC_NS_GEN_CK
return bytes_freed;
}
\f
+#if 0
/* Print some information about a pointer at the given address. */
static void
print_ptr(lispobj *addr)
*(addr+3),
*(addr+4));
}
+#endif
extern int undefined_tramp;
size_t count = 1;
lispobj thing = *(lispobj*)start;
- if (Pointerp(thing)) {
+ if (is_lisp_pointer(thing)) {
int page_index = find_page_index((void*)thing);
int to_readonly_space =
(READ_ONLY_SPACE_START <= thing &&
&& (page_table[page_index].bytes_used == 0))
lose ("Ptr %x @ %x sees free page.", thing, start);
/* Check that it doesn't point to a forwarding pointer! */
- if (*((lispobj *)PTR(thing)) == 0x01) {
+ if (*((lispobj *)native_pointer(thing)) == 0x01) {
lose("Ptr %x @ %x sees forwarding ptr.", thing, start);
}
/* Check that its not in the RO space as it would then be a
/* Does it point to a plausible object? This check slows
* it down a lot (so it's commented out).
*
- * FIXME: Add a variable to enable this dynamically. */
- /* if (!valid_dynamic_space_pointer((lispobj *)thing)) {
- * lose("ptr %x to invalid object %x", thing, start); */
+ * "a lot" is serious: it ate 50 minutes cpu time on
+ * my duron 950 before I came back from lunch and
+ * killed it.
+ *
+ * FIXME: Add a variable to enable this
+ * dynamically. */
+ /*
+ if (!possibly_valid_dynamic_space_pointer((lispobj *)thing)) {
+ lose("ptr %x to invalid object %x", thing, start);
+ }
+ */
} else {
/* Verify that it points to another valid space. */
if (!to_readonly_space && !to_static_space
if (thing & 0x3) { /* Skip fixnums. FIXME: There should be an
* is_fixnum for this. */
- switch(TypeOf(*start)) {
+ switch(widetag_of(*start)) {
/* boxed objects */
- case type_SimpleVector:
- case type_Ratio:
- case type_Complex:
- case type_SimpleArray:
- case type_ComplexString:
- case type_ComplexBitVector:
- case type_ComplexVector:
- case type_ComplexArray:
- case type_ClosureHeader:
- case type_FuncallableInstanceHeader:
- case type_ByteCodeFunction:
- case type_ByteCodeClosure:
- case type_ValueCellHeader:
- case type_SymbolHeader:
- case type_BaseChar:
- case type_UnboundMarker:
- case type_InstanceHeader:
- case type_Fdefn:
+ case SIMPLE_VECTOR_WIDETAG:
+ case RATIO_WIDETAG:
+ case COMPLEX_WIDETAG:
+ case SIMPLE_ARRAY_WIDETAG:
+ case COMPLEX_STRING_WIDETAG:
+ case COMPLEX_BIT_VECTOR_WIDETAG:
+ case COMPLEX_VECTOR_WIDETAG:
+ case COMPLEX_ARRAY_WIDETAG:
+ case CLOSURE_HEADER_WIDETAG:
+ case FUNCALLABLE_INSTANCE_HEADER_WIDETAG:
+ case VALUE_CELL_HEADER_WIDETAG:
+ case SYMBOL_HEADER_WIDETAG:
+ case BASE_CHAR_WIDETAG:
+ case UNBOUND_MARKER_WIDETAG:
+ case INSTANCE_HEADER_WIDETAG:
+ case FDEFN_WIDETAG:
count = 1;
break;
- case type_CodeHeader:
+ case CODE_HEADER_WIDETAG:
{
lispobj object = *start;
struct code *code;
int nheader_words, ncode_words, nwords;
lispobj fheaderl;
- struct function *fheaderp;
+ struct simple_fun *fheaderp;
code = (struct code *) start;
if (is_in_dynamic_space
/* It's ok if it's byte compiled code. The trace
* table offset will be a fixnum if it's x86
- * compiled code - check. */
+ * compiled code - check.
+ *
+ * FIXME: #^#@@! lack of abstraction here..
+ * This line can probably go away now that
+ * there's no byte compiler, but I've got
+ * too much to worry about right now to try
+ * to make sure. -- WHN 2001-10-06 */
&& !(code->trace_table_offset & 0x3)
/* Only when enabled */
&& verify_dynamic_code_check) {
/* Scavenge the boxed section of the code data block */
verify_space(start + 1, nheader_words - 1);
- /* Scavenge the boxed section of each function object in
- * the code data block. */
+ /* Scavenge the boxed section of each function
+ * object in the code data block. */
fheaderl = code->entry_points;
while (fheaderl != NIL) {
- fheaderp = (struct function *) PTR(fheaderl);
- gc_assert(TypeOf(fheaderp->header) == type_FunctionHeader);
+ fheaderp =
+ (struct simple_fun *) native_pointer(fheaderl);
+ gc_assert(widetag_of(fheaderp->header) == SIMPLE_FUN_HEADER_WIDETAG);
verify_space(&fheaderp->name, 1);
verify_space(&fheaderp->arglist, 1);
verify_space(&fheaderp->type, 1);
}
/* unboxed objects */
- case type_Bignum:
- case type_SingleFloat:
- case type_DoubleFloat:
-#ifdef type_ComplexLongFloat
- case type_LongFloat:
+ case BIGNUM_WIDETAG:
+ case SINGLE_FLOAT_WIDETAG:
+ case DOUBLE_FLOAT_WIDETAG:
+#ifdef COMPLEX_LONG_FLOAT_WIDETAG
+ case LONG_FLOAT_WIDETAG:
#endif
-#ifdef type_ComplexSingleFloat
- case type_ComplexSingleFloat:
+#ifdef COMPLEX_SINGLE_FLOAT_WIDETAG
+ case COMPLEX_SINGLE_FLOAT_WIDETAG:
#endif
-#ifdef type_ComplexDoubleFloat
- case type_ComplexDoubleFloat:
+#ifdef COMPLEX_DOUBLE_FLOAT_WIDETAG
+ case COMPLEX_DOUBLE_FLOAT_WIDETAG:
#endif
-#ifdef type_ComplexLongFloat
- case type_ComplexLongFloat:
+#ifdef COMPLEX_LONG_FLOAT_WIDETAG
+ case COMPLEX_LONG_FLOAT_WIDETAG:
#endif
- case type_SimpleString:
- case type_SimpleBitVector:
- case type_SimpleArrayUnsignedByte2:
- case type_SimpleArrayUnsignedByte4:
- case type_SimpleArrayUnsignedByte8:
- case type_SimpleArrayUnsignedByte16:
- case type_SimpleArrayUnsignedByte32:
-#ifdef type_SimpleArraySignedByte8
- case type_SimpleArraySignedByte8:
+ case SIMPLE_STRING_WIDETAG:
+ case SIMPLE_BIT_VECTOR_WIDETAG:
+ case SIMPLE_ARRAY_UNSIGNED_BYTE_2_WIDETAG:
+ case SIMPLE_ARRAY_UNSIGNED_BYTE_4_WIDETAG:
+ case SIMPLE_ARRAY_UNSIGNED_BYTE_8_WIDETAG:
+ case SIMPLE_ARRAY_UNSIGNED_BYTE_16_WIDETAG:
+ case SIMPLE_ARRAY_UNSIGNED_BYTE_32_WIDETAG:
+#ifdef SIMPLE_ARRAY_SIGNED_BYTE_8_WIDETAG
+ case SIMPLE_ARRAY_SIGNED_BYTE_8_WIDETAG:
#endif
-#ifdef type_SimpleArraySignedByte16
- case type_SimpleArraySignedByte16:
+#ifdef SIMPLE_ARRAY_SIGNED_BYTE_16_WIDETAG
+ case SIMPLE_ARRAY_SIGNED_BYTE_16_WIDETAG:
#endif
-#ifdef type_SimpleArraySignedByte30
- case type_SimpleArraySignedByte30:
+#ifdef SIMPLE_ARRAY_SIGNED_BYTE_30_WIDETAG
+ case SIMPLE_ARRAY_SIGNED_BYTE_30_WIDETAG:
#endif
-#ifdef type_SimpleArraySignedByte32
- case type_SimpleArraySignedByte32:
+#ifdef SIMPLE_ARRAY_SIGNED_BYTE_32_WIDETAG
+ case SIMPLE_ARRAY_SIGNED_BYTE_32_WIDETAG:
#endif
- case type_SimpleArraySingleFloat:
- case type_SimpleArrayDoubleFloat:
-#ifdef type_SimpleArrayComplexLongFloat
- case type_SimpleArrayLongFloat:
+ case SIMPLE_ARRAY_SINGLE_FLOAT_WIDETAG:
+ case SIMPLE_ARRAY_DOUBLE_FLOAT_WIDETAG:
+#ifdef SIMPLE_ARRAY_COMPLEX_LONG_FLOAT_WIDETAG
+ case SIMPLE_ARRAY_LONG_FLOAT_WIDETAG:
#endif
-#ifdef type_SimpleArrayComplexSingleFloat
- case type_SimpleArrayComplexSingleFloat:
+#ifdef SIMPLE_ARRAY_COMPLEX_SINGLE_FLOAT_WIDETAG
+ case SIMPLE_ARRAY_COMPLEX_SINGLE_FLOAT_WIDETAG:
#endif
-#ifdef type_SimpleArrayComplexDoubleFloat
- case type_SimpleArrayComplexDoubleFloat:
+#ifdef SIMPLE_ARRAY_COMPLEX_DOUBLE_FLOAT_WIDETAG
+ case SIMPLE_ARRAY_COMPLEX_DOUBLE_FLOAT_WIDETAG:
#endif
-#ifdef type_SimpleArrayComplexLongFloat
- case type_SimpleArrayComplexLongFloat:
+#ifdef SIMPLE_ARRAY_COMPLEX_LONG_FLOAT_WIDETAG
+ case SIMPLE_ARRAY_COMPLEX_LONG_FLOAT_WIDETAG:
#endif
- case type_Sap:
- case type_WeakPointer:
- count = (sizetab[TypeOf(*start)])(start);
+ case SAP_WIDETAG:
+ case WEAK_POINTER_WIDETAG:
+ count = (sizetab[widetag_of(*start)])(start);
break;
default:
}
}
-/* Check the all the free space is zero filled. */
+/* Check that all the free space is zero filled. */
static void
verify_zero_fill(void)
{
gencgc_verify_zero_fill(void)
{
/* Flush the alloc regions updating the tables. */
- boxed_region.free_pointer = current_region_free_pointer;
- gc_alloc_update_page_tables(0, &boxed_region);
- gc_alloc_update_page_tables(1, &unboxed_region);
+ gc_alloc_update_all_page_tables();
SHOW("verifying zero fill");
verify_zero_fill();
- current_region_free_pointer = boxed_region.free_pointer;
- current_region_end_addr = boxed_region.end_addr;
}
static void
}
}
-/* Garbage collect a generation. If raise is 0 the remains of the
+/* Garbage collect a generation. If raise is 0 then the remains of the
* generation are not raised to the next generation. */
static void
garbage_collect_generation(int generation, int raise)
{
unsigned long bytes_freed;
unsigned long i;
- unsigned long read_only_space_size, static_space_size;
+ unsigned long static_space_size;
gc_assert(generation <= (NUM_GENERATIONS-1));
/* Un-write-protect the old-space pages. This is essential for the
* promoted pages as they may contain pointers into the old-space
* which need to be scavenged. It also helps avoid unnecessary page
- * faults as forwarding pointer are written into them. They need to
+ * faults as forwarding pointers are written into them. They need to
* be un-protected anyway before unmapping later. */
unprotect_oldspace();
/* Scavenge the stack's conservative roots. */
{
- lispobj **ptr;
- for (ptr = (lispobj **)CONTROL_STACK_END - 1;
- ptr > (lispobj **)&raise;
+ void **ptr;
+ for (ptr = (void **)CONTROL_STACK_END - 1;
+ ptr > (void **)&raise;
ptr--) {
preserve_pointer(*ptr);
}
}
-#ifdef CONTROL_STACKS
- scavenge_thread_stacks();
-#endif
+#if QSHOW
if (gencgc_verbose > 1) {
int num_dont_move_pages = count_dont_move_pages();
- FSHOW((stderr,
- "/non-movable pages due to conservative pointers = %d (%d bytes)\n",
- num_dont_move_pages,
- /* FIXME: 4096 should be symbolic constant here and
- * prob'ly elsewhere too. */
- num_dont_move_pages * 4096));
+ fprintf(stderr,
+ "/non-movable pages due to conservative pointers = %d (%d bytes)\n",
+ num_dont_move_pages,
+ /* FIXME: 4096 should be symbolic constant here and
+ * prob'ly elsewhere too. */
+ num_dont_move_pages * 4096);
}
+#endif
/* Scavenge all the rest of the roots. */
/* Scavenge the Lisp functions of the interrupt handlers, taking
- * care to avoid SIG_DFL, SIG_IGN. */
+ * care to avoid SIG_DFL and SIG_IGN. */
for (i = 0; i < NSIG; i++) {
union interrupt_handler handler = interrupt_handlers[i];
if (!ARE_SAME_HANDLER(handler.c, SIG_IGN) &&
}
/* Scavenge the binding stack. */
- scavenge( (lispobj *) BINDING_STACK_START,
+ scavenge((lispobj *) BINDING_STACK_START,
(lispobj *)SymbolValue(BINDING_STACK_POINTER) -
(lispobj *)BINDING_STACK_START);
+ /* The original CMU CL code had scavenge-read-only-space code
+ * controlled by the Lisp-level variable
+ * *SCAVENGE-READ-ONLY-SPACE*. It was disabled by default, and it
+ * wasn't documented under what circumstances it was useful or
+ * safe to turn it on, so it's been turned off in SBCL. If you
+ * want/need this functionality, and can test and document it,
+ * please submit a patch. */
+#if 0
if (SymbolValue(SCAVENGE_READ_ONLY_SPACE) != NIL) {
- read_only_space_size =
+ unsigned long read_only_space_size =
(lispobj*)SymbolValue(READ_ONLY_SPACE_FREE_POINTER) -
(lispobj*)READ_ONLY_SPACE_START;
FSHOW((stderr,
read_only_space_size * sizeof(lispobj)));
scavenge( (lispobj *) READ_ONLY_SPACE_START, read_only_space_size);
}
+#endif
+ /* Scavenge static space. */
static_space_size =
(lispobj *)SymbolValue(STATIC_SPACE_FREE_POINTER) -
(lispobj *)STATIC_SPACE_START;
- if (gencgc_verbose > 1)
+ if (gencgc_verbose > 1) {
FSHOW((stderr,
"/scavenge static space: %d bytes\n",
static_space_size * sizeof(lispobj)));
+ }
scavenge( (lispobj *) STATIC_SPACE_START, static_space_size);
/* All generations but the generation being GCed need to be
* scavenged. The new_space generation needs special handling as
* objects may be moved in - it is handled separately below. */
- for (i = 0; i < NUM_GENERATIONS; i++)
- if ((i != generation) && (i != new_space))
+ for (i = 0; i < NUM_GENERATIONS; i++) {
+ if ((i != generation) && (i != new_space)) {
scavenge_generation(i);
+ }
+ }
/* Finally scavenge the new_space generation. Keep going until no
* more objects are moved into the new generation */
scavenge_newspace_generation(new_space);
+ /* FIXME: I tried reenabling this check when debugging unrelated
+ * GC weirdness ca. sbcl-0.6.12.45, and it failed immediately.
+ * Since the current GC code seems to work well, I'm guessing that
+ * this debugging code is just stale, but I haven't tried to
+ * figure it out. It should be figured out and then either made to
+ * work or just deleted. */
#define RESCAN_CHECK 0
#if RESCAN_CHECK
/* As a check re-scavenge the newspace once; no new objects should
scavenge_newspace_generation_one_scan(new_space);
/* Flush the current regions, updating the tables. */
- gc_alloc_update_page_tables(0, &boxed_region);
- gc_alloc_update_page_tables(1, &unboxed_region);
+ gc_alloc_update_all_page_tables();
bytes_allocated = bytes_allocated - old_bytes_allocated;
scan_weak_pointers();
/* Flush the current regions, updating the tables. */
- gc_alloc_update_page_tables(0, &boxed_region);
- gc_alloc_update_page_tables(1, &unboxed_region);
+ gc_alloc_update_all_page_tables();
/* Free the pages in oldspace, but not those marked dont_move. */
bytes_freed = free_oldspace();
++generations[generation].num_gc;
}
-/* Update last_free_page then ALLOCATION_POINTER */
+/* Update last_free_page, then SymbolValue(ALLOCATION_POINTER). */
int
update_x86_dynamic_space_free_pointer(void)
{
return 0; /* dummy value: return something ... */
}
-/* GC all generations below last_gen, raising their objects to the
- * next generation until all generations below last_gen are empty.
- * Then if last_gen is due for a GC then GC it. In the special case
- * that last_gen==NUM_GENERATIONS, the last generation is always
- * GC'ed. The valid range for last_gen is: 0,1,...,NUM_GENERATIONS.
+/* GC all generations newer than last_gen, raising the objects in each
+ * to the next older generation - we finish when all generations below
+ * last_gen are empty. Then if last_gen is due for a GC, or if
+ * last_gen==NUM_GENERATIONS (the scratch generation? eh?) we GC that
+ * too. The valid range for last_gen is: 0,1,...,NUM_GENERATIONS.
*
- * The oldest generation to be GCed will always be
- * gencgc_oldest_gen_to_gc, partly ignoring last_gen if necessary. */
+ * We stop collecting at gencgc_oldest_gen_to_gc, even if this is less than
+ * last_gen (oh, and note that by default it is NUM_GENERATIONS-1) */
+
void
collect_garbage(unsigned last_gen)
{
int gen_to_wp;
int i;
- boxed_region.free_pointer = current_region_free_pointer;
-
FSHOW((stderr, "/entering collect_garbage(%d)\n", last_gen));
if (last_gen > NUM_GENERATIONS) {
}
/* Flush the alloc regions updating the tables. */
- gc_alloc_update_page_tables(0, &boxed_region);
- gc_alloc_update_page_tables(1, &unboxed_region);
+ gc_alloc_update_all_page_tables();
/* Verify the new objects created by Lisp code. */
if (pre_verify_gen_0) {
- SHOW((stderr, "pre-checking generation 0\n"));
+ FSHOW((stderr, "pre-checking generation 0\n"));
verify_generation(0);
}
if (gencgc_verbose > 1) {
FSHOW((stderr,
- "Starting GC of generation %d with raise=%d alloc=%d trig=%d GCs=%d\n",
+ "starting GC of generation %d with raise=%d alloc=%d trig=%d GCs=%d\n",
gen,
raise,
generations[gen].bytes_allocated,
generations[gen].num_gc));
}
- /* If an older generation is being filled then update its memory
- * age. */
+ /* If an older generation is being filled, then update its
+ * memory age. */
if (raise == 1) {
generations[gen+1].cum_sum_bytes_allocated +=
generations[gen+1].bytes_allocated;
write_protect_generation_pages(gen_to_wp);
}
- /* Set gc_alloc back to generation 0. The current regions should
- * be flushed after the above GCs */
+ /* Set gc_alloc() back to generation 0. The current regions should
+ * be flushed after the above GCs. */
gc_assert((boxed_region.free_pointer - boxed_region.start_addr) == 0);
gc_alloc_generation = 0;
update_x86_dynamic_space_free_pointer();
- /* This is now done by Lisp SCRUB-CONTROL-STACK in Lisp SUB-GC, so we
- * needn't do it here: */
- /* zero_stack();*/
-
- current_region_free_pointer = boxed_region.free_pointer;
- current_region_end_addr = boxed_region.end_addr;
-
SHOW("returning from collect_garbage");
}
/* This is called by Lisp PURIFY when it is finished. All live objects
* will have been moved to the RO and Static heaps. The dynamic space
* will need a full re-initialization. We don't bother having Lisp
- * PURIFY flush the current gc_alloc region, as the page_tables are
+ * PURIFY flush the current gc_alloc() region, as the page_tables are
* re-initialized, and every page is zeroed to be sure. */
void
gc_free_heap(void)
if (gencgc_verbose > 1)
print_generation_stats(0);
- /* Initialize gc_alloc */
+ /* Initialize gc_alloc(). */
gc_alloc_generation = 0;
- boxed_region.first_page = 0;
- boxed_region.last_page = -1;
- boxed_region.start_addr = page_address(0);
- boxed_region.free_pointer = page_address(0);
- boxed_region.end_addr = page_address(0);
-
- unboxed_region.first_page = 0;
- unboxed_region.last_page = -1;
- unboxed_region.start_addr = page_address(0);
- unboxed_region.free_pointer = page_address(0);
- unboxed_region.end_addr = page_address(0);
-
-#if 0 /* Lisp PURIFY is currently running on the C stack so don't do this. */
- zero_stack();
-#endif
+
+ gc_set_region_empty(&boxed_region);
+ gc_set_region_empty(&unboxed_region);
last_free_page = 0;
SetSymbolValue(ALLOCATION_POINTER, (lispobj)((char *)heap_base));
- current_region_free_pointer = boxed_region.free_pointer;
- current_region_end_addr = boxed_region.end_addr;
-
if (verify_after_free_heap) {
/* Check whether purify has left any bad pointers. */
if (gencgc_verbose)
int i;
gc_init_tables();
+ scavtab[SIMPLE_VECTOR_WIDETAG] = scav_vector;
+ scavtab[WEAK_POINTER_WIDETAG] = scav_weak_pointer;
+ transother[SIMPLE_ARRAY_WIDETAG] = trans_boxed_large;
heap_base = (void*)DYNAMIC_SPACE_START;
bytes_allocated = 0;
- /* Initialize the generations. */
+ /* Initialize the generations.
+ *
+ * FIXME: very similar to code in gc_free_heap(), should be shared */
for (i = 0; i < NUM_GENERATIONS; i++) {
generations[i].alloc_start_page = 0;
generations[i].alloc_unboxed_start_page = 0;
/* Initialize gc_alloc. */
gc_alloc_generation = 0;
- boxed_region.first_page = 0;
- boxed_region.last_page = -1;
- boxed_region.start_addr = page_address(0);
- boxed_region.free_pointer = page_address(0);
- boxed_region.end_addr = page_address(0);
-
- unboxed_region.first_page = 0;
- unboxed_region.last_page = -1;
- unboxed_region.start_addr = page_address(0);
- unboxed_region.free_pointer = page_address(0);
- unboxed_region.end_addr = page_address(0);
+ gc_set_region_empty(&boxed_region);
+ gc_set_region_empty(&unboxed_region);
last_free_page = 0;
- current_region_free_pointer = boxed_region.free_pointer;
- current_region_end_addr = boxed_region.end_addr;
}
/* Pick up the dynamic space from after a core load.
* The ALLOCATION_POINTER points to the end of the dynamic space.
*
* XX A scan is needed to identify the closest first objects for pages. */
-void
+static void
gencgc_pickup_dynamic(void)
{
int page = 0;
generations[0].bytes_allocated = 4096*page;
bytes_allocated = 4096*page;
- current_region_free_pointer = boxed_region.free_pointer;
- current_region_end_addr = boxed_region.end_addr;
}
+
+void
+gc_initialize_pointers(void)
+{
+ gencgc_pickup_dynamic();
+}
+
+
\f
-/* a counter for how deep we are in alloc(..) calls */
-int alloc_entered = 0;
+extern boolean maybe_gc_pending ;
/* alloc(..) is the external interface for memory allocation. It
* allocates to generation 0. It is not called from within the garbage
* collector as it is only external uses that need the check for heap
* (E.g. the most significant word of a 2-word bignum in MOVE-FROM-UNSIGNED.)
*
* The check for a GC trigger is only performed when the current
- * region is full, so in most cases it's not needed. Further MAYBE-GC
- * is only called once because Lisp will remember "need to collect
- * garbage" and get around to it when it can. */
+ * region is full, so in most cases it's not needed. */
+
char *
alloc(int nbytes)
{
+ struct alloc_region *region= &boxed_region;
+ void *new_obj;
+ void *new_free_pointer;
+
/* Check for alignment allocation problems. */
- gc_assert((((unsigned)current_region_free_pointer & 0x7) == 0)
+ gc_assert((((unsigned)region->free_pointer & 0x7) == 0)
&& ((nbytes & 0x7) == 0));
-
- if (SymbolValue(PSEUDO_ATOMIC_ATOMIC)) {/* if already in a pseudo atomic */
-
- void *new_free_pointer;
-
- retry1:
- if (alloc_entered) {
- SHOW("alloc re-entered in already-pseudo-atomic case");
- }
- ++alloc_entered;
-
- /* Check whether there is room in the current region. */
- new_free_pointer = current_region_free_pointer + nbytes;
-
- /* FIXME: Shouldn't we be doing some sort of lock here, to
- * keep from getting screwed if an interrupt service routine
- * allocates memory between the time we calculate new_free_pointer
- * and the time we write it back to current_region_free_pointer?
- * Perhaps I just don't understand pseudo-atomics..
- *
- * Perhaps I don't. It looks as though what happens is if we
- * were interrupted any time during the pseudo-atomic
- * interval (which includes now) we discard the allocated
- * memory and try again. So, at least we don't return
- * a memory area that was allocated out from underneath us
- * by code in an ISR.
- * Still, that doesn't seem to prevent
- * current_region_free_pointer from getting corrupted:
- * We read current_region_free_pointer.
- * They read current_region_free_pointer.
- * They write current_region_free_pointer.
- * We write current_region_free_pointer, scribbling over
- * whatever they wrote. */
-
- if (new_free_pointer <= boxed_region.end_addr) {
- /* If so then allocate from the current region. */
- void *new_obj = current_region_free_pointer;
- current_region_free_pointer = new_free_pointer;
- alloc_entered--;
- return((void *)new_obj);
- }
-
- if (auto_gc_trigger && bytes_allocated > auto_gc_trigger) {
- /* Double the trigger. */
- auto_gc_trigger *= 2;
- alloc_entered--;
- /* Exit the pseudo-atomic. */
- SetSymbolValue(PSEUDO_ATOMIC_ATOMIC, make_fixnum(0));
- if (SymbolValue(PSEUDO_ATOMIC_INTERRUPTED) != 0) {
- /* Handle any interrupts that occurred during
- * gc_alloc(..). */
- do_pending_interrupt();
- }
- funcall0(SymbolFunction(MAYBE_GC));
- /* Re-enter the pseudo-atomic. */
- SetSymbolValue(PSEUDO_ATOMIC_INTERRUPTED, make_fixnum(0));
- SetSymbolValue(PSEUDO_ATOMIC_ATOMIC, make_fixnum(1));
- goto retry1;
- }
- /* Call gc_alloc. */
- boxed_region.free_pointer = current_region_free_pointer;
- {
- void *new_obj = gc_alloc(nbytes);
- current_region_free_pointer = boxed_region.free_pointer;
- current_region_end_addr = boxed_region.end_addr;
- alloc_entered--;
- return (new_obj);
- }
- } else {
- void *result;
- void *new_free_pointer;
-
- retry2:
- /* At least wrap this allocation in a pseudo atomic to prevent
- * gc_alloc from being re-entered. */
- SetSymbolValue(PSEUDO_ATOMIC_INTERRUPTED, make_fixnum(0));
- SetSymbolValue(PSEUDO_ATOMIC_ATOMIC, make_fixnum(1));
-
- if (alloc_entered)
- SHOW("alloc re-entered in not-already-pseudo-atomic case");
- ++alloc_entered;
-
- /* Check whether there is room in the current region. */
- new_free_pointer = current_region_free_pointer + nbytes;
-
- if (new_free_pointer <= boxed_region.end_addr) {
- /* If so then allocate from the current region. */
- void *new_obj = current_region_free_pointer;
- current_region_free_pointer = new_free_pointer;
- alloc_entered--;
- SetSymbolValue(PSEUDO_ATOMIC_ATOMIC, make_fixnum(0));
- if (SymbolValue(PSEUDO_ATOMIC_INTERRUPTED)) {
- /* Handle any interrupts that occurred during
- * gc_alloc(..). */
- do_pending_interrupt();
- goto retry2;
- }
-
- return((void *)new_obj);
- }
-
- /* KLUDGE: There's lots of code around here shared with the
- * the other branch. Is there some way to factor out the
- * duplicate code? -- WHN 19991129 */
- if (auto_gc_trigger && bytes_allocated > auto_gc_trigger) {
- /* Double the trigger. */
- auto_gc_trigger *= 2;
- alloc_entered--;
- /* Exit the pseudo atomic. */
- SetSymbolValue(PSEUDO_ATOMIC_ATOMIC, make_fixnum(0));
- if (SymbolValue(PSEUDO_ATOMIC_INTERRUPTED) != 0) {
- /* Handle any interrupts that occurred during
- * gc_alloc(..); */
- do_pending_interrupt();
- }
- funcall0(SymbolFunction(MAYBE_GC));
- goto retry2;
- }
-
- /* Else call gc_alloc. */
- boxed_region.free_pointer = current_region_free_pointer;
- result = gc_alloc(nbytes);
- current_region_free_pointer = boxed_region.free_pointer;
- current_region_end_addr = boxed_region.end_addr;
-
- alloc_entered--;
- SetSymbolValue(PSEUDO_ATOMIC_ATOMIC, make_fixnum(0));
- if (SymbolValue(PSEUDO_ATOMIC_INTERRUPTED) != 0) {
- /* Handle any interrupts that occurred during
- * gc_alloc(..). */
- do_pending_interrupt();
- goto retry2;
- }
-
- return result;
+ /* At this point we should either be in pseudo-atomic, or early
+ * enough in cold initn that interrupts are not yet enabled anyway.
+ * It would be nice to assert same.
+ */
+ gc_assert(SymbolValue(PSEUDO_ATOMIC_ATOMIC));
+
+ /* maybe we can do this quickly ... */
+ new_free_pointer = region->free_pointer + nbytes;
+ if (new_free_pointer <= region->end_addr) {
+ new_obj = (void*)(region->free_pointer);
+ region->free_pointer = new_free_pointer;
+ return(new_obj); /* yup */
+ }
+
+ /* we have to go the long way around, it seems. Check whether
+ * we should GC in the near future
+ */
+ if (auto_gc_trigger && bytes_allocated > auto_gc_trigger) {
+ auto_gc_trigger *= 2;
+ /* set things up so that GC happens when we finish the PA
+ * section. */
+ maybe_gc_pending=1;
+ SetSymbolValue(PSEUDO_ATOMIC_INTERRUPTED, make_fixnum(1));
}
+ new_obj = gc_alloc_with_region(nbytes,0,region,0);
+ return (new_obj);
}
+
\f
/*
* noise to manipulate the gc trigger stuff
object = search_dynamic_space(pc);
if (object) /* if we found something */
- if (TypeOf(*object) == type_CodeHeader) /* if it's a code object */
+ if (widetag_of(*object) == CODE_HEADER_WIDETAG) /* if it's a code object */
return(object);
return (NULL);
* catch GENCGC-related write-protect violations
*/
+void unhandled_sigmemoryfault(void);
+
/* Depending on which OS we're running under, different signals might
* be raised for a violation of write protection in the heap. This
* function factors out the common generational GC magic which needs
* Return true if this signal is a normal generational GC thing that
* we were able to handle, or false if it was abnormal and control
* should fall through to the general SIGSEGV/SIGBUS/whatever logic. */
+
int
gencgc_handle_wp_violation(void* fault_addr)
{
/* Check whether the fault is within the dynamic space. */
if (page_index == (-1)) {
+ /* It can be helpful to be able to put a breakpoint on this
+ * case to help diagnose low-level problems. */
+ unhandled_sigmemoryfault();
+
/* not within the dynamic space -- not our responsibility */
return 0;
return 1;
}
}
+
+/* This is to be called when we catch a SIGSEGV/SIGBUS, determine that
+ * it's not just a case of the program hitting the write barrier, and
+ * are about to let Lisp deal with it. It's basically just a
+ * convenient place to set a gdb breakpoint. */
+void
+unhandled_sigmemoryfault()
+{}
+
+gc_alloc_update_all_page_tables(void)
+{
+ /* Flush the alloc regions updating the tables. */
+ gc_alloc_update_page_tables(1, &unboxed_region);
+ gc_alloc_update_page_tables(0, &boxed_region);
+}
+void
+gc_set_region_empty(struct alloc_region *region)
+{
+ region->first_page = 0;
+ region->last_page = -1;
+ region->start_addr = page_address(0);
+ region->free_pointer = page_address(0);
+ region->end_addr = page_address(0);
+}
+
projects / sbcl.git / blobdiff