#include "validate.h"
#include "lispregs.h"
#include "arch.h"
-#include "fixnump.h"
#include "gc.h"
#include "gc-internal.h"
#include "thread.h"
+#include "pseudo-atomic.h"
#include "alloc.h"
#include "genesis/vector.h"
#include "genesis/weak-pointer.h"
#include "genesis/instance.h"
#include "genesis/layout.h"
#include "gencgc.h"
-#if defined(LUTEX_WIDETAG)
-#include "pthread-lutex.h"
+#if !defined(LISP_FEATURE_X86) && !defined(LISP_FEATURE_X86_64)
+#include "genesis/cons.h"
#endif
/* forward declarations */
-page_index_t gc_find_freeish_pages(long *restart_page_ptr, long nbytes,
- int unboxed);
+page_index_t gc_find_freeish_pages(page_index_t *restart_page_ptr, long nbytes,
+ int page_type_flag);
\f
/*
* scratch space by the collector, and should never get collected.
*/
enum {
- HIGHEST_NORMAL_GENERATION = 5,
- PSEUDO_STATIC_GENERATION,
- SCRATCH_GENERATION,
+ SCRATCH_GENERATION = PSEUDO_STATIC_GENERATION+1,
NUM_GENERATIONS
};
boolean enable_page_protection = 1;
/* the minimum size (in bytes) for a large object*/
-unsigned long large_object_size = 4 * PAGE_BYTES;
+#if (GENCGC_ALLOC_GRANULARITY >= PAGE_BYTES) && (GENCGC_ALLOC_GRANULARITY >= GENCGC_CARD_BYTES)
+long large_object_size = 4 * GENCGC_ALLOC_GRANULARITY;
+#elif (GENCGC_CARD_BYTES >= PAGE_BYTES) && (GENCGC_CARD_BYTES >= GENCGC_ALLOC_GRANULARITY)
+long large_object_size = 4 * GENCGC_CARD_BYTES;
+#else
+long large_object_size = 4 * PAGE_BYTES;
+#endif
\f
/*
/* the verbosity level. All non-error messages are disabled at level 0;
* and only a few rare messages are printed at level 1. */
-#ifdef QSHOW
+#if QSHOW
boolean gencgc_verbose = 1;
#else
boolean gencgc_verbose = 0;
*/
/* the total bytes allocated. These are seen by Lisp DYNAMIC-USAGE. */
-unsigned long bytes_allocated = 0;
-unsigned long auto_gc_trigger = 0;
+os_vm_size_t bytes_allocated = 0;
+os_vm_size_t auto_gc_trigger = 0;
/* the source and destination generations. These are set before a GC starts
* scavenging. */
/* An array of page structures is allocated on gc initialization.
* This helps quickly map between an address its page structure.
* page_table_pages is set from the size of the dynamic space. */
-unsigned page_table_pages;
+page_index_t page_table_pages;
struct page *page_table;
+static inline boolean page_allocated_p(page_index_t page) {
+ return (page_table[page].allocated != FREE_PAGE_FLAG);
+}
+
+static inline boolean page_no_region_p(page_index_t page) {
+ return !(page_table[page].allocated & OPEN_REGION_PAGE_FLAG);
+}
+
+static inline boolean page_allocated_no_region_p(page_index_t page) {
+ return ((page_table[page].allocated & (UNBOXED_PAGE_FLAG | BOXED_PAGE_FLAG))
+ && page_no_region_p(page));
+}
+
+static inline boolean page_free_p(page_index_t page) {
+ return (page_table[page].allocated == FREE_PAGE_FLAG);
+}
+
+static inline boolean page_boxed_p(page_index_t page) {
+ return (page_table[page].allocated & BOXED_PAGE_FLAG);
+}
+
+static inline boolean code_page_p(page_index_t page) {
+ return (page_table[page].allocated & CODE_PAGE_FLAG);
+}
+
+static inline boolean page_boxed_no_region_p(page_index_t page) {
+ return page_boxed_p(page) && page_no_region_p(page);
+}
+
+static inline boolean page_unboxed_p(page_index_t page) {
+ /* Both flags set == boxed code page */
+ return ((page_table[page].allocated & UNBOXED_PAGE_FLAG)
+ && !page_boxed_p(page));
+}
+
+static inline boolean protect_page_p(page_index_t page, generation_index_t generation) {
+ return (page_boxed_no_region_p(page)
+ && (page_table[page].bytes_used != 0)
+ && !page_table[page].dont_move
+ && (page_table[page].gen == generation));
+}
+
/* To map addresses to page structures the address of the first page
* is needed. */
static void *heap_base = NULL;
inline void *
page_address(page_index_t page_num)
{
- return (heap_base + (page_num * PAGE_BYTES));
+ return (heap_base + (page_num * GENCGC_CARD_BYTES));
+}
+
+/* Calculate the address where the allocation region associated with
+ * the page starts. */
+static inline void *
+page_region_start(page_index_t page_index)
+{
+ return page_address(page_index)-page_table[page_index].region_start_offset;
}
/* Find the page index within the page_table for the given
inline page_index_t
find_page_index(void *addr)
{
- page_index_t index = addr-heap_base;
-
- if (index >= 0) {
- index = ((unsigned long)index)/PAGE_BYTES;
+ if (addr >= heap_base) {
+ page_index_t index = ((pointer_sized_uint_t)addr -
+ (pointer_sized_uint_t)heap_base) / GENCGC_CARD_BYTES;
if (index < page_table_pages)
return (index);
}
-
return (-1);
}
-/* a structure to hold the state of a generation */
+static os_vm_size_t
+npage_bytes(page_index_t npages)
+{
+ gc_assert(npages>=0);
+ return ((os_vm_size_t)npages)*GENCGC_CARD_BYTES;
+}
+
+/* Check that X is a higher address than Y and return offset from Y to
+ * X in bytes. */
+static inline
+size_t void_diff(void *x, void *y)
+{
+ gc_assert(x >= y);
+ return (pointer_sized_uint_t)x - (pointer_sized_uint_t)y;
+}
+
+/* a structure to hold the state of a generation
+ *
+ * CAUTION: If you modify this, make sure to touch up the alien
+ * definition in src/code/gc.lisp accordingly. ...or better yes,
+ * deal with the FIXME there...
+ */
struct generation {
/* the first page that gc_alloc() checks on its next call */
page_index_t alloc_large_unboxed_start_page;
/* the bytes allocated to this generation */
- long bytes_allocated;
+ os_vm_size_t bytes_allocated;
/* the number of bytes at which to trigger a GC */
- long gc_trigger;
+ os_vm_size_t gc_trigger;
/* to calculate a new level for gc_trigger */
- long bytes_consed_between_gc;
+ os_vm_size_t bytes_consed_between_gc;
/* the number of GCs since the last raise */
int num_gc;
- /* the average age after which a GC will raise objects to the
+ /* the number of GCs to run on the generations before raising objects to the
* next generation */
- int trigger_age;
+ int number_of_gcs_before_promotion;
/* the cumulative sum of the bytes allocated to this generation. It is
* cleared after a GC on this generations, and update before new
* objects are added from a GC of a younger generation. Dividing by
* the bytes_allocated will give the average age of the memory in
* this generation since its last GC. */
- long cum_sum_bytes_allocated;
+ os_vm_size_t cum_sum_bytes_allocated;
/* a minimum average memory age before a GC will occur helps
* prevent a GC when a large number of new live objects have been
* added, in which case a GC could be a waste of time */
- double min_av_mem_age;
-
- /* A linked list of lutex structures in this generation, used for
- * implementing lutex finalization. */
-#ifdef LUTEX_WIDETAG
- struct lutex *lutexes;
-#else
- void *lutexes;
-#endif
+ double minimum_age_before_gc;
};
/* an array of generation structures. There needs to be one more
* integrated with the Lisp code. */
page_index_t last_free_page;
\f
+#ifdef LISP_FEATURE_SB_THREAD
/* This lock is to prevent multiple threads from simultaneously
* allocating new regions which overlap each other. Note that the
* majority of GC is single-threaded, but alloc() may be called from
* >1 thread at a time and must be thread-safe. This lock must be
* seized before all accesses to generations[] or to parts of
* page_table[] that other threads may want to see */
-
-#ifdef LISP_FEATURE_SB_THREAD
static pthread_mutex_t free_pages_lock = PTHREAD_MUTEX_INITIALIZER;
+/* This lock is used to protect non-thread-local allocation. */
+static pthread_mutex_t allocation_lock = PTHREAD_MUTEX_INITIALIZER;
#endif
+extern unsigned long gencgc_release_granularity;
+unsigned long gencgc_release_granularity = GENCGC_RELEASE_GRANULARITY;
+
+extern unsigned long gencgc_alloc_granularity;
+unsigned long gencgc_alloc_granularity = GENCGC_ALLOC_GRANULARITY;
+
\f
/*
* miscellaneous heap functions
/* Count the number of pages which are write-protected within the
* given generation. */
-static long
+static page_index_t
count_write_protect_generation_pages(generation_index_t generation)
{
- page_index_t i;
- long count = 0;
+ page_index_t i, count = 0;
for (i = 0; i < last_free_page; i++)
- if ((page_table[i].allocated != FREE_PAGE_FLAG)
+ if (page_allocated_p(i)
&& (page_table[i].gen == generation)
&& (page_table[i].write_protected == 1))
count++;
}
/* Count the number of pages within the given generation. */
-static long
+static page_index_t
count_generation_pages(generation_index_t generation)
{
page_index_t i;
- long count = 0;
+ page_index_t count = 0;
for (i = 0; i < last_free_page; i++)
- if ((page_table[i].allocated != FREE_PAGE_FLAG)
+ if (page_allocated_p(i)
&& (page_table[i].gen == generation))
count++;
return count;
}
-#ifdef QSHOW
-static long
+#if QSHOW
+static page_index_t
count_dont_move_pages(void)
{
page_index_t i;
- long count = 0;
+ page_index_t count = 0;
for (i = 0; i < last_free_page; i++) {
- if ((page_table[i].allocated != FREE_PAGE_FLAG)
+ if (page_allocated_p(i)
&& (page_table[i].dont_move != 0)) {
++count;
}
/* Work through the pages and add up the number of bytes used for the
* given generation. */
-static long
+static unsigned long
count_generation_bytes_allocated (generation_index_t gen)
{
page_index_t i;
- long result = 0;
+ unsigned long result = 0;
for (i = 0; i < last_free_page; i++) {
- if ((page_table[i].allocated != FREE_PAGE_FLAG)
+ if (page_allocated_p(i)
&& (page_table[i].gen == gen))
result += page_table[i].bytes_used;
}
}
/* Return the average age of the memory in a generation. */
-static double
-gen_av_mem_age(generation_index_t gen)
+extern double
+generation_average_age(generation_index_t gen)
{
if (generations[gen].bytes_allocated == 0)
return 0.0;
/ ((double)generations[gen].bytes_allocated);
}
-/* The verbose argument controls how much to print: 0 for normal
- * level of detail; 1 for debugging. */
-static void
-print_generation_stats(int verbose) /* FIXME: should take FILE argument */
+extern void
+write_generation_stats(FILE *file)
{
- generation_index_t i, gens;
+ generation_index_t i;
#if defined(LISP_FEATURE_X86) || defined(LISP_FEATURE_X86_64)
#define FPU_STATE_SIZE 27
* so they need to be saved and reset for C. */
fpu_save(fpu_state);
- /* highest generation to print */
- if (verbose)
- gens = SCRATCH_GENERATION;
- else
- gens = PSEUDO_STATIC_GENERATION;
-
/* Print the heap stats. */
- fprintf(stderr,
+ fprintf(file,
" Gen StaPg UbSta LaSta LUbSt Boxed Unboxed LB LUB !move Alloc Waste Trig WP GCs Mem-age\n");
- for (i = 0; i < gens; i++) {
+ for (i = 0; i < SCRATCH_GENERATION; i++) {
page_index_t j;
- long boxed_cnt = 0;
- long unboxed_cnt = 0;
- long large_boxed_cnt = 0;
- long large_unboxed_cnt = 0;
- long pinned_cnt=0;
+ page_index_t boxed_cnt = 0;
+ page_index_t unboxed_cnt = 0;
+ page_index_t large_boxed_cnt = 0;
+ page_index_t large_unboxed_cnt = 0;
+ page_index_t pinned_cnt=0;
for (j = 0; j < last_free_page; j++)
if (page_table[j].gen == i) {
/* Count the number of boxed pages within the given
* generation. */
- if (page_table[j].allocated & BOXED_PAGE_FLAG) {
+ if (page_boxed_p(j)) {
if (page_table[j].large_object)
large_boxed_cnt++;
else
if(page_table[j].dont_move) pinned_cnt++;
/* Count the number of unboxed pages within the given
* generation. */
- if (page_table[j].allocated & UNBOXED_PAGE_FLAG) {
+ if (page_unboxed_p(j)) {
if (page_table[j].large_object)
large_unboxed_cnt++;
else
gc_assert(generations[i].bytes_allocated
== count_generation_bytes_allocated(i));
- fprintf(stderr,
- " %1d: %5ld %5ld %5ld %5ld %5ld %5ld %5ld %5ld %5ld %8ld %5ld %8ld %4ld %3d %7.4f\n",
+ fprintf(file,
+ " %1d: %5ld %5ld %5ld %5ld",
i,
generations[i].alloc_start_page,
generations[i].alloc_unboxed_start_page,
generations[i].alloc_large_start_page,
- generations[i].alloc_large_unboxed_start_page,
- boxed_cnt,
- unboxed_cnt,
- large_boxed_cnt,
- large_unboxed_cnt,
- pinned_cnt,
+ generations[i].alloc_large_unboxed_start_page);
+ fprintf(file,
+ " %5"PAGE_INDEX_FMT" %5"PAGE_INDEX_FMT" %5"PAGE_INDEX_FMT
+ " %5"PAGE_INDEX_FMT" %5"PAGE_INDEX_FMT,
+ boxed_cnt, unboxed_cnt, large_boxed_cnt,
+ large_unboxed_cnt, pinned_cnt);
+ fprintf(file
+ " %8ld %5ld %8ld %4ld %3d %7.4f\n",
generations[i].bytes_allocated,
- (count_generation_pages(i)*PAGE_BYTES - generations[i].bytes_allocated),
+ (npage_bytes(count_generation_pages(i))
+ - generations[i].bytes_allocated),
generations[i].gc_trigger,
count_write_protect_generation_pages(i),
generations[i].num_gc,
- gen_av_mem_age(i));
+ generation_average_age(i));
}
- fprintf(stderr," Total bytes allocated=%ld\n", bytes_allocated);
+ fprintf(file," Total bytes allocated = %lu\n", (unsigned long)bytes_allocated);
+ fprintf(file," Dynamic-space-size bytes = %lu\n", (unsigned long)dynamic_space_size);
fpu_restore(fpu_state);
}
+
+extern void
+write_heap_exhaustion_report(FILE *file, long available, long requested,
+ struct thread *thread)
+{
+ fprintf(file,
+ "Heap exhausted during %s: %ld bytes available, %ld requested.\n",
+ gc_active_p ? "garbage collection" : "allocation",
+ available,
+ requested);
+ write_generation_stats(file);
+ fprintf(file, "GC control variables:\n");
+ fprintf(file, " *GC-INHIBIT* = %s\n *GC-PENDING* = %s\n",
+ SymbolValue(GC_INHIBIT,thread)==NIL ? "false" : "true",
+ (SymbolValue(GC_PENDING, thread) == T) ?
+ "true" : ((SymbolValue(GC_PENDING, thread) == NIL) ?
+ "false" : "in progress"));
+#ifdef LISP_FEATURE_SB_THREAD
+ fprintf(file, " *STOP-FOR-GC-PENDING* = %s\n",
+ SymbolValue(STOP_FOR_GC_PENDING,thread)==NIL ? "false" : "true");
+#endif
+}
+
+extern void
+print_generation_stats(void)
+{
+ write_generation_stats(stderr);
+}
+
+extern char* gc_logfile;
+char * gc_logfile = NULL;
+
+extern void
+log_generation_stats(char *logfile, char *header)
+{
+ if (logfile) {
+ FILE * log = fopen(logfile, "a");
+ if (log) {
+ fprintf(log, "%s\n", header);
+ write_generation_stats(log);
+ fclose(log);
+ } else {
+ fprintf(stderr, "Could not open gc logfile: %s\n", logfile);
+ fflush(stderr);
+ }
+ }
+}
+
+extern void
+report_heap_exhaustion(long available, long requested, struct thread *th)
+{
+ if (gc_logfile) {
+ FILE * log = fopen(gc_logfile, "a");
+ if (log) {
+ write_heap_exhaustion_report(log, available, requested, th);
+ fclose(log);
+ } else {
+ fprintf(stderr, "Could not open gc logfile: %s\n", gc_logfile);
+ fflush(stderr);
+ }
+ }
+ /* Always to stderr as well. */
+ write_heap_exhaustion_report(stderr, available, requested, th);
+}
\f
#if defined(LISP_FEATURE_X86) || defined(LISP_FEATURE_X86_64)
* OS. Generally done after a large GC.
*/
void zero_pages_with_mmap(page_index_t start, page_index_t end) {
- int i;
- void *addr = (void *) page_address(start), *new_addr;
- size_t length = PAGE_BYTES*(1+end-start);
+ page_index_t i;
+ void *addr = page_address(start), *new_addr;
+ os_vm_size_t length = npage_bytes(1+end-start);
if (start > end)
return;
+ gc_assert(length >= gencgc_release_granularity);
+ gc_assert((length % gencgc_release_granularity) == 0);
+
os_invalidate(addr, length);
new_addr = os_validate(addr, length);
if (new_addr == NULL || new_addr != addr) {
- lose("remap_free_pages: page moved, 0x%08x ==> 0x%08x", start, new_addr);
+ lose("remap_free_pages: page moved, 0x%08x ==> 0x%08x",
+ start, new_addr);
}
for (i = start; i <= end; i++) {
return;
#if defined(LISP_FEATURE_X86) || defined(LISP_FEATURE_X86_64)
- fast_bzero(page_address(start), PAGE_BYTES*(1+end-start));
+ fast_bzero(page_address(start), npage_bytes(1+end-start));
#else
- bzero(page_address(start), PAGE_BYTES*(1+end-start));
+ bzero(page_address(start), npage_bytes(1+end-start));
#endif
}
+static void
+zero_and_mark_pages(page_index_t start, page_index_t end) {
+ page_index_t i;
+
+ zero_pages(start, end);
+ for (i = start; i <= end; i++)
+ page_table[i].need_to_zero = 0;
+}
+
/* Zero the pages from START to END (inclusive), except for those
* pages that are known to already zeroed. Mark all pages in the
* ranges as non-zeroed.
*/
static void
zero_dirty_pages(page_index_t start, page_index_t end) {
- page_index_t i;
+ page_index_t i, j;
for (i = start; i <= end; i++) {
- if (page_table[i].need_to_zero == 1) {
- zero_pages(start, end);
- break;
- }
+ if (!page_table[i].need_to_zero) continue;
+ for (j = i+1; (j <= end) && (page_table[j].need_to_zero); j++);
+ zero_pages(i, j-1);
+ i = j;
}
for (i = start; i <= end; i++) {
/* The generation currently being allocated to. */
static generation_index_t gc_alloc_generation;
+static inline page_index_t
+generation_alloc_start_page(generation_index_t generation, int page_type_flag, int large)
+{
+ if (large) {
+ if (UNBOXED_PAGE_FLAG == page_type_flag) {
+ return generations[generation].alloc_large_unboxed_start_page;
+ } else if (BOXED_PAGE_FLAG & page_type_flag) {
+ /* Both code and data. */
+ return generations[generation].alloc_large_start_page;
+ } else {
+ lose("bad page type flag: %d", page_type_flag);
+ }
+ } else {
+ if (UNBOXED_PAGE_FLAG == page_type_flag) {
+ return generations[generation].alloc_unboxed_start_page;
+ } else if (BOXED_PAGE_FLAG & page_type_flag) {
+ /* Both code and data. */
+ return generations[generation].alloc_start_page;
+ } else {
+ lose("bad page_type_flag: %d", page_type_flag);
+ }
+ }
+}
+
+static inline void
+set_generation_alloc_start_page(generation_index_t generation, int page_type_flag, int large,
+ page_index_t page)
+{
+ if (large) {
+ if (UNBOXED_PAGE_FLAG == page_type_flag) {
+ generations[generation].alloc_large_unboxed_start_page = page;
+ } else if (BOXED_PAGE_FLAG & page_type_flag) {
+ /* Both code and data. */
+ generations[generation].alloc_large_start_page = page;
+ } else {
+ lose("bad page type flag: %d", page_type_flag);
+ }
+ } else {
+ if (UNBOXED_PAGE_FLAG == page_type_flag) {
+ generations[generation].alloc_unboxed_start_page = page;
+ } else if (BOXED_PAGE_FLAG & page_type_flag) {
+ /* Both code and data. */
+ generations[generation].alloc_start_page = page;
+ } else {
+ lose("bad page type flag: %d", page_type_flag);
+ }
+ }
+}
+
/* Find a new region with room for at least the given number of bytes.
*
* It starts looking at the current generation's alloc_start_page. So
* are allocated, although they will initially be empty.
*/
static void
-gc_alloc_new_region(long nbytes, int unboxed, struct alloc_region *alloc_region)
+gc_alloc_new_region(long nbytes, int page_type_flag, struct alloc_region *alloc_region)
{
page_index_t first_page;
page_index_t last_page;
- long bytes_found;
+ unsigned long bytes_found;
page_index_t i;
int ret;
&& (alloc_region->free_pointer == alloc_region->end_addr));
ret = thread_mutex_lock(&free_pages_lock);
gc_assert(ret == 0);
- if (unboxed) {
- first_page =
- generations[gc_alloc_generation].alloc_unboxed_start_page;
- } else {
- first_page =
- generations[gc_alloc_generation].alloc_start_page;
- }
- last_page=gc_find_freeish_pages(&first_page,nbytes,unboxed);
- bytes_found=(PAGE_BYTES - page_table[first_page].bytes_used)
- + PAGE_BYTES*(last_page-first_page);
+ first_page = generation_alloc_start_page(gc_alloc_generation, page_type_flag, 0);
+ last_page=gc_find_freeish_pages(&first_page, nbytes, page_type_flag);
+ bytes_found=(GENCGC_CARD_BYTES - page_table[first_page].bytes_used)
+ + npage_bytes(last_page-first_page);
/* Set up the alloc_region. */
alloc_region->first_page = first_page;
/* The first page may have already been in use. */
if (page_table[first_page].bytes_used == 0) {
- if (unboxed)
- page_table[first_page].allocated = UNBOXED_PAGE_FLAG;
- else
- page_table[first_page].allocated = BOXED_PAGE_FLAG;
+ page_table[first_page].allocated = page_type_flag;
page_table[first_page].gen = gc_alloc_generation;
page_table[first_page].large_object = 0;
- page_table[first_page].first_object_offset = 0;
+ page_table[first_page].region_start_offset = 0;
}
- if (unboxed)
- gc_assert(page_table[first_page].allocated == UNBOXED_PAGE_FLAG);
- else
- gc_assert(page_table[first_page].allocated == BOXED_PAGE_FLAG);
+ gc_assert(page_table[first_page].allocated == page_type_flag);
page_table[first_page].allocated |= OPEN_REGION_PAGE_FLAG;
gc_assert(page_table[first_page].gen == gc_alloc_generation);
gc_assert(page_table[first_page].large_object == 0);
for (i = first_page+1; i <= last_page; i++) {
- if (unboxed)
- page_table[i].allocated = UNBOXED_PAGE_FLAG;
- else
- page_table[i].allocated = BOXED_PAGE_FLAG;
+ page_table[i].allocated = page_type_flag;
page_table[i].gen = gc_alloc_generation;
page_table[i].large_object = 0;
/* This may not be necessary for unboxed regions (think it was
* broken before!) */
- page_table[i].first_object_offset =
- alloc_region->start_addr - page_address(i);
+ page_table[i].region_start_offset =
+ void_diff(page_address(i),alloc_region->start_addr);
page_table[i].allocated |= OPEN_REGION_PAGE_FLAG ;
}
/* Bump up last_free_page. */
if (last_page+1 > last_free_page) {
last_free_page = last_page+1;
- /* do we only want to call this on special occasions? like for boxed_region? */
- set_alloc_pointer((lispobj)(((char *)heap_base) + last_free_page*PAGE_BYTES));
+ /* do we only want to call this on special occasions? like for
+ * boxed_region? */
+ set_alloc_pointer((lispobj)page_address(last_free_page));
}
ret = thread_mutex_unlock(&free_pages_lock);
gc_assert(ret == 0);
- /* we can do this after releasing free_pages_lock */
- if (gencgc_zero_check) {
- long *p;
- for (p = (long *)alloc_region->start_addr;
- p < (long *)alloc_region->end_addr; p++) {
- if (*p != 0) {
- /* KLUDGE: It would be nice to use %lx and explicit casts
- * (long) in code like this, so that it is less likely to
- * break randomly when running on a machine with different
- * word sizes. -- WHN 19991129 */
- lose("The new region at %x is not zero.\n", p);
- }
- }
- }
-
#ifdef READ_PROTECT_FREE_PAGES
os_protect(page_address(first_page),
- PAGE_BYTES*(1+last_page-first_page),
+ npage_bytes(1+last_page-first_page),
OS_VM_PROT_ALL);
#endif
}
zero_dirty_pages(first_page, last_page);
+
+ /* we can do this after releasing free_pages_lock */
+ if (gencgc_zero_check) {
+ long *p;
+ for (p = (long *)alloc_region->start_addr;
+ p < (long *)alloc_region->end_addr; p++) {
+ if (*p != 0) {
+ /* KLUDGE: It would be nice to use %lx and explicit casts
+ * (long) in code like this, so that it is less likely to
+ * break randomly when running on a machine with different
+ * word sizes. -- WHN 19991129 */
+ lose("The new region at %x is not zero (start=%p, end=%p).\n",
+ p, alloc_region->start_addr, alloc_region->end_addr);
+ }
+ }
+ }
}
/* If the record_new_objects flag is 2 then all new regions created
static page_index_t new_areas_ignore_page;
struct new_area {
page_index_t page;
- long offset;
- long size;
+ size_t offset;
+ size_t size;
};
static struct new_area (*new_areas)[];
static long new_areas_index;
/* Add a new area to new_areas. */
static void
-add_new_area(page_index_t first_page, long offset, long size)
+add_new_area(page_index_t first_page, size_t offset, size_t size)
{
unsigned long new_area_start,c;
long i;
gc_abort();
}
- new_area_start = PAGE_BYTES*first_page + offset;
+ new_area_start = npage_bytes(first_page) + offset;
/* Search backwards for a prior area that this follows from. If
found this will save adding a new area. */
for (i = new_areas_index-1, c = 0; (i >= 0) && (c < 8); i--, c++) {
unsigned long area_end =
- PAGE_BYTES*((*new_areas)[i].page)
+ npage_bytes((*new_areas)[i].page)
+ (*new_areas)[i].offset
+ (*new_areas)[i].size;
/*FSHOW((stderr,
* it is safe to try to re-update the page table of this reset
* alloc_region. */
void
-gc_alloc_update_page_tables(int unboxed, struct alloc_region *alloc_region)
+gc_alloc_update_page_tables(int page_type_flag, struct alloc_region *alloc_region)
{
int more;
page_index_t first_page;
page_index_t next_page;
- int bytes_used;
- long orig_first_page_bytes_used;
- long region_size;
- long byte_cnt;
+ unsigned long bytes_used;
+ unsigned long orig_first_page_bytes_used;
+ unsigned long region_size;
+ unsigned long byte_cnt;
int ret;
/* some bytes were allocated in the region */
orig_first_page_bytes_used = page_table[first_page].bytes_used;
- gc_assert(alloc_region->start_addr == (page_address(first_page) + page_table[first_page].bytes_used));
+ gc_assert(alloc_region->start_addr ==
+ (page_address(first_page)
+ + page_table[first_page].bytes_used));
/* All the pages used need to be updated */
/* Update the first page. */
/* If the page was free then set up the gen, and
- * first_object_offset. */
+ * region_start_offset. */
if (page_table[first_page].bytes_used == 0)
- gc_assert(page_table[first_page].first_object_offset == 0);
+ gc_assert(page_table[first_page].region_start_offset == 0);
page_table[first_page].allocated &= ~(OPEN_REGION_PAGE_FLAG);
- if (unboxed)
- gc_assert(page_table[first_page].allocated == UNBOXED_PAGE_FLAG);
- else
- gc_assert(page_table[first_page].allocated == BOXED_PAGE_FLAG);
+ gc_assert(page_table[first_page].allocated & page_type_flag);
gc_assert(page_table[first_page].gen == gc_alloc_generation);
gc_assert(page_table[first_page].large_object == 0);
/* 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)))>PAGE_BYTES) {
- bytes_used = PAGE_BYTES;
+ if ((bytes_used = void_diff(alloc_region->free_pointer,
+ page_address(first_page)))
+ >GENCGC_CARD_BYTES) {
+ bytes_used = GENCGC_CARD_BYTES;
more = 1;
}
page_table[first_page].bytes_used = bytes_used;
byte_cnt += 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. */
+ /* All the rest of the pages should be free. We need to set
+ * their region_start_offset pointer to the start of the
+ * region, and set the bytes_used. */
while (more) {
page_table[next_page].allocated &= ~(OPEN_REGION_PAGE_FLAG);
- if (unboxed)
- gc_assert(page_table[next_page].allocated==UNBOXED_PAGE_FLAG);
- else
- gc_assert(page_table[next_page].allocated == BOXED_PAGE_FLAG);
+ gc_assert(page_table[next_page].allocated & page_type_flag);
gc_assert(page_table[next_page].bytes_used == 0);
gc_assert(page_table[next_page].gen == gc_alloc_generation);
gc_assert(page_table[next_page].large_object == 0);
- gc_assert(page_table[next_page].first_object_offset ==
- alloc_region->start_addr - page_address(next_page));
+ gc_assert(page_table[next_page].region_start_offset ==
+ void_diff(page_address(next_page),
+ alloc_region->start_addr));
/* Calculate the number of bytes used in this page. */
more = 0;
- if ((bytes_used = (alloc_region->free_pointer
- - page_address(next_page)))>PAGE_BYTES) {
- bytes_used = PAGE_BYTES;
+ if ((bytes_used = void_diff(alloc_region->free_pointer,
+ page_address(next_page)))>GENCGC_CARD_BYTES) {
+ bytes_used = GENCGC_CARD_BYTES;
more = 1;
}
page_table[next_page].bytes_used = bytes_used;
next_page++;
}
- region_size = alloc_region->free_pointer - alloc_region->start_addr;
+ region_size = void_diff(alloc_region->free_pointer,
+ alloc_region->start_addr);
bytes_allocated += region_size;
generations[gc_alloc_generation].bytes_allocated += region_size;
/* Set the generations alloc restart page to the last page of
* the region. */
- if (unboxed)
- generations[gc_alloc_generation].alloc_unboxed_start_page =
- next_page-1;
- else
- generations[gc_alloc_generation].alloc_start_page = next_page-1;
+ set_generation_alloc_start_page(gc_alloc_generation, page_type_flag, 0, next_page-1);
/* Add the region to the new_areas if requested. */
- if (!unboxed)
+ if (BOXED_PAGE_FLAG & page_type_flag)
add_new_area(first_page,orig_first_page_bytes_used, region_size);
/*
/* Allocate a possibly large object. */
void *
-gc_alloc_large(long nbytes, int unboxed, struct alloc_region *alloc_region)
+gc_alloc_large(long nbytes, int page_type_flag, struct alloc_region *alloc_region)
{
page_index_t first_page;
page_index_t last_page;
int orig_first_page_bytes_used;
long byte_cnt;
int more;
- long bytes_used;
+ unsigned long bytes_used;
page_index_t next_page;
int ret;
ret = thread_mutex_lock(&free_pages_lock);
gc_assert(ret == 0);
- if (unboxed) {
- first_page =
- generations[gc_alloc_generation].alloc_large_unboxed_start_page;
- } else {
- first_page = generations[gc_alloc_generation].alloc_large_start_page;
- }
+ first_page = generation_alloc_start_page(gc_alloc_generation, page_type_flag, 1);
if (first_page <= alloc_region->last_page) {
first_page = alloc_region->last_page+1;
}
- last_page=gc_find_freeish_pages(&first_page,nbytes,unboxed);
+ last_page=gc_find_freeish_pages(&first_page,nbytes, page_type_flag);
gc_assert(first_page > alloc_region->last_page);
- if (unboxed)
- generations[gc_alloc_generation].alloc_large_unboxed_start_page =
- last_page;
- else
- generations[gc_alloc_generation].alloc_large_start_page = last_page;
+
+ set_generation_alloc_start_page(gc_alloc_generation, page_type_flag, 1, last_page);
/* Set up the pages. */
orig_first_page_bytes_used = page_table[first_page].bytes_used;
/* If the first page was free then set up the gen, and
- * first_object_offset. */
+ * region_start_offset. */
if (page_table[first_page].bytes_used == 0) {
- if (unboxed)
- page_table[first_page].allocated = UNBOXED_PAGE_FLAG;
- else
- page_table[first_page].allocated = BOXED_PAGE_FLAG;
+ page_table[first_page].allocated = page_type_flag;
page_table[first_page].gen = gc_alloc_generation;
- page_table[first_page].first_object_offset = 0;
+ page_table[first_page].region_start_offset = 0;
page_table[first_page].large_object = 1;
}
- if (unboxed)
- gc_assert(page_table[first_page].allocated == UNBOXED_PAGE_FLAG);
- else
- gc_assert(page_table[first_page].allocated == BOXED_PAGE_FLAG);
+ gc_assert(page_table[first_page].allocated == page_type_flag);
gc_assert(page_table[first_page].gen == gc_alloc_generation);
gc_assert(page_table[first_page].large_object == 1);
/* Calc. 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 = nbytes+orig_first_page_bytes_used) > PAGE_BYTES) {
- bytes_used = PAGE_BYTES;
+ if ((bytes_used = nbytes+orig_first_page_bytes_used) > GENCGC_CARD_BYTES) {
+ bytes_used = GENCGC_CARD_BYTES;
more = 1;
}
page_table[first_page].bytes_used = bytes_used;
next_page = first_page+1;
/* 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. */
+ * region_start_offset pointer to the start of the region, and set
+ * the bytes_used. */
while (more) {
- gc_assert(page_table[next_page].allocated == FREE_PAGE_FLAG);
+ gc_assert(page_free_p(next_page));
gc_assert(page_table[next_page].bytes_used == 0);
- if (unboxed)
- page_table[next_page].allocated = UNBOXED_PAGE_FLAG;
- else
- page_table[next_page].allocated = BOXED_PAGE_FLAG;
+ page_table[next_page].allocated = page_type_flag;
page_table[next_page].gen = gc_alloc_generation;
page_table[next_page].large_object = 1;
- page_table[next_page].first_object_offset =
- orig_first_page_bytes_used - PAGE_BYTES*(next_page-first_page);
+ page_table[next_page].region_start_offset =
+ npage_bytes(next_page-first_page) - orig_first_page_bytes_used;
/* Calculate the number of bytes used in this page. */
more = 0;
- if ((bytes_used=(nbytes+orig_first_page_bytes_used)-byte_cnt) > PAGE_BYTES) {
- bytes_used = PAGE_BYTES;
+ bytes_used=(nbytes+orig_first_page_bytes_used)-byte_cnt;
+ if (bytes_used > GENCGC_CARD_BYTES) {
+ bytes_used = GENCGC_CARD_BYTES;
more = 1;
}
page_table[next_page].bytes_used = bytes_used;
generations[gc_alloc_generation].bytes_allocated += nbytes;
/* Add the region to the new_areas if requested. */
- if (!unboxed)
+ if (BOXED_PAGE_FLAG & page_type_flag)
add_new_area(first_page,orig_first_page_bytes_used,nbytes);
/* Bump up last_free_page */
if (last_page+1 > last_free_page) {
last_free_page = last_page+1;
- set_alloc_pointer((lispobj)(((char *)heap_base) + last_free_page*PAGE_BYTES));
+ set_alloc_pointer((lispobj)(page_address(last_free_page)));
}
ret = thread_mutex_unlock(&free_pages_lock);
gc_assert(ret == 0);
#ifdef READ_PROTECT_FREE_PAGES
os_protect(page_address(first_page),
- PAGE_BYTES*(1+last_page-first_page),
+ npage_bytes(1+last_page-first_page),
OS_VM_PROT_ALL);
#endif
void
gc_heap_exhausted_error_or_lose (long available, long requested)
{
+ struct thread *thread = arch_os_get_current_thread();
/* Write basic information before doing anything else: if we don't
* call to lisp this is a must, and even if we do there is always
* the danger that we bounce back here before the error has been
* handled, or indeed even printed.
*/
- fprintf(stderr, "Heap exhausted during %s: %ld bytes available, %ld requested.\n",
- gc_active_p ? "garbage collection" : "allocation", available, requested);
+ report_heap_exhaustion(available, requested, thread);
if (gc_active_p || (available == 0)) {
/* If we are in GC, or totally out of memory there is no way
* to sanely transfer control to the lisp-side of things.
*/
- struct thread *thread = arch_os_get_current_thread();
- print_generation_stats(1);
- fprintf(stderr, "GC control variables:\n");
- fprintf(stderr, " *GC-INHIBIT* = %s\n *GC-PENDING* = %s\n",
- SymbolValue(GC_INHIBIT,thread)==NIL ? "false" : "true",
- SymbolValue(GC_PENDING,thread)==NIL ? "false" : "true");
-#ifdef LISP_FEATURE_SB_THREAD
- fprintf(stderr, " *STOP-FOR-GC-PENDING* = %s\n",
- SymbolValue(STOP_FOR_GC_PENDING,thread)==NIL ? "false" : "true");
-#endif
lose("Heap exhausted, game over.");
}
else {
/* FIXME: assert free_pages_lock held */
(void)thread_mutex_unlock(&free_pages_lock);
- funcall2(SymbolFunction(HEAP_EXHAUSTED_ERROR),
+ gc_assert(get_pseudo_atomic_atomic(thread));
+ clear_pseudo_atomic_atomic(thread);
+ if (get_pseudo_atomic_interrupted(thread))
+ do_pending_interrupt();
+ /* Another issue is that signalling HEAP-EXHAUSTED error leads
+ * to running user code at arbitrary places, even in a
+ * WITHOUT-INTERRUPTS which may lead to a deadlock without
+ * running out of the heap. So at this point all bets are
+ * off. */
+ if (SymbolValue(INTERRUPTS_ENABLED,thread) == NIL)
+ corruption_warning_and_maybe_lose
+ ("Signalling HEAP-EXHAUSTED in a WITHOUT-INTERRUPTS.");
+ funcall2(StaticSymbolFunction(HEAP_EXHAUSTED_ERROR),
alloc_number(available), alloc_number(requested));
lose("HEAP-EXHAUSTED-ERROR fell through");
}
}
page_index_t
-gc_find_freeish_pages(page_index_t *restart_page_ptr, long nbytes, int unboxed)
+gc_find_freeish_pages(page_index_t *restart_page_ptr, long nbytes,
+ int page_type_flag)
{
- page_index_t first_page;
- page_index_t last_page;
- long region_size;
- page_index_t restart_page=*restart_page_ptr;
- long bytes_found;
- long num_pages;
- int large_p=(nbytes>=large_object_size);
+ page_index_t first_page, last_page;
+ page_index_t restart_page = *restart_page_ptr;
+ long nbytes_goal = nbytes;
+ long bytes_found = 0;
+ long most_bytes_found = 0;
+ page_index_t most_bytes_found_from, most_bytes_found_to;
+ int small_object = nbytes < GENCGC_CARD_BYTES;
/* FIXME: assert(free_pages_lock is held); */
- /* 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. */
+ if (nbytes_goal < gencgc_alloc_granularity)
+ nbytes_goal = gencgc_alloc_granularity;
+ /* Toggled by gc_and_save for heap compaction, normally -1. */
if (gencgc_alloc_start_page != -1) {
restart_page = gencgc_alloc_start_page;
}
- do {
- first_page = restart_page;
- if (large_p)
- while ((first_page < page_table_pages)
- && (page_table[first_page].allocated != FREE_PAGE_FLAG))
- first_page++;
- else
- while (first_page < page_table_pages) {
- if(page_table[first_page].allocated == FREE_PAGE_FLAG)
- break;
- if((page_table[first_page].allocated ==
- (unboxed ? UNBOXED_PAGE_FLAG : BOXED_PAGE_FLAG)) &&
+ gc_assert(nbytes>=0);
+ /* Search for a page with at least nbytes of space. We prefer
+ * not to split small objects on multiple pages, to reduce the
+ * number of contiguous allocation regions spaning multiple
+ * pages: this helps avoid excessive conservativism.
+ *
+ * For other objects, we guarantee that they start on their own
+ * page boundary.
+ */
+ first_page = restart_page;
+ while (first_page < page_table_pages) {
+ bytes_found = 0;
+ if (page_free_p(first_page)) {
+ gc_assert(0 == page_table[first_page].bytes_used);
+ bytes_found = GENCGC_CARD_BYTES;
+ } else if (small_object &&
+ (page_table[first_page].allocated == page_type_flag) &&
(page_table[first_page].large_object == 0) &&
(page_table[first_page].gen == gc_alloc_generation) &&
- (page_table[first_page].bytes_used < (PAGE_BYTES-32)) &&
(page_table[first_page].write_protected == 0) &&
(page_table[first_page].dont_move == 0)) {
- break;
- }
+ bytes_found = GENCGC_CARD_BYTES - page_table[first_page].bytes_used;
+ if (bytes_found < nbytes) {
+ if (bytes_found > most_bytes_found)
+ most_bytes_found = bytes_found;
first_page++;
+ continue;
}
-
- if (first_page >= page_table_pages)
- gc_heap_exhausted_error_or_lose(0, nbytes);
+ } else {
+ first_page++;
+ continue;
+ }
gc_assert(page_table[first_page].write_protected == 0);
+ for (last_page = first_page+1;
+ ((last_page < page_table_pages) &&
+ page_free_p(last_page) &&
+ (bytes_found < nbytes_goal));
+ last_page++) {
+ bytes_found += GENCGC_CARD_BYTES;
+ gc_assert(0 == page_table[last_page].bytes_used);
+ gc_assert(0 == page_table[last_page].write_protected);
+ }
- last_page = first_page;
- bytes_found = PAGE_BYTES - page_table[first_page].bytes_used;
- num_pages = 1;
- while (((bytes_found < nbytes)
- || (!large_p && (num_pages < 2)))
- && (last_page < (page_table_pages-1))
- && (page_table[last_page+1].allocated == FREE_PAGE_FLAG)) {
- last_page++;
- num_pages++;
- bytes_found += PAGE_BYTES;
- gc_assert(page_table[last_page].write_protected == 0);
+ if (bytes_found > most_bytes_found) {
+ most_bytes_found = bytes_found;
+ most_bytes_found_from = first_page;
+ most_bytes_found_to = last_page;
}
+ if (bytes_found >= nbytes_goal)
+ break;
- region_size = (PAGE_BYTES - page_table[first_page].bytes_used)
- + PAGE_BYTES*(last_page-first_page);
+ first_page = last_page;
+ }
- gc_assert(bytes_found == region_size);
- restart_page = last_page + 1;
- } while ((restart_page < page_table_pages) && (bytes_found < nbytes));
+ bytes_found = most_bytes_found;
+ restart_page = first_page + 1;
/* Check for a failure */
- if ((restart_page >= page_table_pages) && (bytes_found < nbytes))
- gc_heap_exhausted_error_or_lose(bytes_found, nbytes);
-
- *restart_page_ptr=first_page;
+ if (bytes_found < nbytes) {
+ gc_assert(restart_page >= page_table_pages);
+ gc_heap_exhausted_error_or_lose(most_bytes_found, nbytes);
+ }
- return last_page;
+ *restart_page_ptr = most_bytes_found_from;
+ return most_bytes_found_to-1;
}
/* Allocate bytes. All the rest of the special-purpose allocation
* functions will eventually call this */
void *
-gc_alloc_with_region(long nbytes,int unboxed_p, struct alloc_region *my_region,
+gc_alloc_with_region(long nbytes,int page_type_flag, struct alloc_region *my_region,
int quick_p)
{
void *new_free_pointer;
- if(nbytes>=large_object_size)
- return gc_alloc_large(nbytes,unboxed_p,my_region);
+ if (nbytes>=large_object_size)
+ return gc_alloc_large(nbytes, page_type_flag, my_region);
/* Check whether there is room in the current alloc region. */
new_free_pointer = my_region->free_pointer + nbytes;
/* 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) {
+ void_diff(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);
+ gc_alloc_update_page_tables(page_type_flag, my_region);
/* Set up a new region. */
- gc_alloc_new_region(32 /*bytes*/, unboxed_p, my_region);
+ gc_alloc_new_region(32 /*bytes*/, page_type_flag, my_region);
}
return((void *)new_obj);
/* Else not enough free space in the current region: retry with a
* new region. */
- gc_alloc_update_page_tables(unboxed_p, my_region);
- gc_alloc_new_region(nbytes, unboxed_p, my_region);
- return gc_alloc_with_region(nbytes,unboxed_p,my_region,0);
+ gc_alloc_update_page_tables(page_type_flag, my_region);
+ gc_alloc_new_region(nbytes, page_type_flag, my_region);
+ return gc_alloc_with_region(nbytes, page_type_flag, my_region,0);
}
/* these are only used during GC: all allocation from the mutator calls
* alloc() -> gc_alloc_with_region() with the appropriate per-thread
* region */
-void *
-gc_general_alloc(long nbytes,int unboxed_p,int quick_p)
-{
- struct alloc_region *my_region =
- unboxed_p ? &unboxed_region : &boxed_region;
- return gc_alloc_with_region(nbytes,unboxed_p, my_region,quick_p);
-}
-
static inline void *
gc_quick_alloc(long nbytes)
{
- return gc_general_alloc(nbytes,ALLOC_BOXED,ALLOC_QUICK);
+ return gc_general_alloc(nbytes, BOXED_PAGE_FLAG, ALLOC_QUICK);
}
static inline void *
gc_quick_alloc_large(long nbytes)
{
- return gc_general_alloc(nbytes,ALLOC_BOXED,ALLOC_QUICK);
+ return gc_general_alloc(nbytes, BOXED_PAGE_FLAG ,ALLOC_QUICK);
}
static inline void *
gc_alloc_unboxed(long nbytes)
{
- return gc_general_alloc(nbytes,ALLOC_UNBOXED,0);
+ return gc_general_alloc(nbytes, UNBOXED_PAGE_FLAG, 0);
}
static inline void *
gc_quick_alloc_unboxed(long nbytes)
{
- return gc_general_alloc(nbytes,ALLOC_UNBOXED,ALLOC_QUICK);
+ return gc_general_alloc(nbytes, UNBOXED_PAGE_FLAG, ALLOC_QUICK);
}
static inline void *
gc_quick_alloc_large_unboxed(long nbytes)
{
- return gc_general_alloc(nbytes,ALLOC_UNBOXED,ALLOC_QUICK);
+ return gc_general_alloc(nbytes, UNBOXED_PAGE_FLAG, ALLOC_QUICK);
}
\f
-/*
- * scavenging/transporting routines derived from gc.c in CMU CL ca. 18b
- */
-
-extern long (*scavtab[256])(lispobj *where, lispobj object);
-extern lispobj (*transother[256])(lispobj object);
-extern long (*sizetab[256])(lispobj *where);
/* 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
/* Promote the object. */
- long remaining_bytes;
+ unsigned long remaining_bytes;
page_index_t next_page;
- long bytes_freed;
- long old_bytes_used;
+ unsigned long bytes_freed;
+ unsigned long old_bytes_used;
/* Note: Any page write-protection must be removed, else a
* later scavenge_newspace may incorrectly not scavenge these
* new areas, but let's do it for them all (they'll probably
* be written anyway?). */
- gc_assert(page_table[first_page].first_object_offset == 0);
+ gc_assert(page_table[first_page].region_start_offset == 0);
next_page = first_page;
remaining_bytes = nwords*N_WORD_BYTES;
- while (remaining_bytes > PAGE_BYTES) {
+ while (remaining_bytes > GENCGC_CARD_BYTES) {
gc_assert(page_table[next_page].gen == from_space);
- gc_assert(page_table[next_page].allocated == BOXED_PAGE_FLAG);
+ gc_assert(page_boxed_p(next_page));
gc_assert(page_table[next_page].large_object);
- gc_assert(page_table[next_page].first_object_offset==
- -PAGE_BYTES*(next_page-first_page));
- gc_assert(page_table[next_page].bytes_used == PAGE_BYTES);
+ gc_assert(page_table[next_page].region_start_offset ==
+ npage_bytes(next_page-first_page));
+ gc_assert(page_table[next_page].bytes_used == GENCGC_CARD_BYTES);
+ /* Should have been unprotected by unprotect_oldspace(). */
+ gc_assert(page_table[next_page].write_protected == 0);
page_table[next_page].gen = new_space;
- /* Remove any write-protection. We should be able to rely
- * on the write-protect flag to avoid redundant calls. */
- if (page_table[next_page].write_protected) {
- os_protect(page_address(next_page), PAGE_BYTES, OS_VM_PROT_ALL);
- page_table[next_page].write_protected = 0;
- }
- remaining_bytes -= PAGE_BYTES;
+ remaining_bytes -= GENCGC_CARD_BYTES;
next_page++;
}
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_FLAG);
+ gc_assert(page_boxed_p(next_page));
/* Adjust the bytes_used. */
old_bytes_used = page_table[next_page].bytes_used;
/* Free any remaining pages; needs care. */
next_page++;
- while ((old_bytes_used == PAGE_BYTES) &&
+ while ((old_bytes_used == GENCGC_CARD_BYTES) &&
(page_table[next_page].gen == from_space) &&
- (page_table[next_page].allocated == BOXED_PAGE_FLAG) &&
+ page_boxed_p(next_page) &&
page_table[next_page].large_object &&
- (page_table[next_page].first_object_offset ==
- -(next_page - first_page)*PAGE_BYTES)) {
+ (page_table[next_page].region_start_offset ==
+ npage_bytes(next_page - first_page))) {
/* 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
next_page++;
}
- generations[from_space].bytes_allocated -= N_WORD_BYTES*nwords +
- bytes_freed;
+ generations[from_space].bytes_allocated -= N_WORD_BYTES*nwords
+ + bytes_freed;
generations[new_space].bytes_allocated += N_WORD_BYTES*nwords;
bytes_allocated -= bytes_freed;
gc_assert(from_space_p(object));
gc_assert((nwords & 0x01) == 0);
- if ((nwords > 1024*1024) && gencgc_verbose)
- FSHOW((stderr, "/copy_large_unboxed_object: %d bytes\n", nwords*N_WORD_BYTES));
+ if ((nwords > 1024*1024) && gencgc_verbose) {
+ FSHOW((stderr, "/copy_large_unboxed_object: %d bytes\n",
+ nwords*N_WORD_BYTES));
+ }
/* Check whether it's a large object. */
first_page = find_page_index((void *)object);
/* Promote the object. Note: Unboxed objects may have been
* allocated to a BOXED region so it may be necessary to
* change the region to UNBOXED. */
- long remaining_bytes;
+ unsigned long remaining_bytes;
page_index_t next_page;
- long bytes_freed;
- long old_bytes_used;
+ unsigned long bytes_freed;
+ unsigned long old_bytes_used;
- gc_assert(page_table[first_page].first_object_offset == 0);
+ gc_assert(page_table[first_page].region_start_offset == 0);
next_page = first_page;
remaining_bytes = nwords*N_WORD_BYTES;
- while (remaining_bytes > PAGE_BYTES) {
+ while (remaining_bytes > GENCGC_CARD_BYTES) {
gc_assert(page_table[next_page].gen == from_space);
- gc_assert((page_table[next_page].allocated == UNBOXED_PAGE_FLAG)
- || (page_table[next_page].allocated == BOXED_PAGE_FLAG));
+ gc_assert(page_allocated_no_region_p(next_page));
gc_assert(page_table[next_page].large_object);
- gc_assert(page_table[next_page].first_object_offset==
- -PAGE_BYTES*(next_page-first_page));
- gc_assert(page_table[next_page].bytes_used == PAGE_BYTES);
+ gc_assert(page_table[next_page].region_start_offset ==
+ npage_bytes(next_page-first_page));
+ gc_assert(page_table[next_page].bytes_used == GENCGC_CARD_BYTES);
page_table[next_page].gen = new_space;
page_table[next_page].allocated = UNBOXED_PAGE_FLAG;
- remaining_bytes -= PAGE_BYTES;
+ remaining_bytes -= GENCGC_CARD_BYTES;
next_page++;
}
/* Free any remaining pages; needs care. */
next_page++;
- while ((old_bytes_used == PAGE_BYTES) &&
+ while ((old_bytes_used == GENCGC_CARD_BYTES) &&
(page_table[next_page].gen == from_space) &&
- ((page_table[next_page].allocated == UNBOXED_PAGE_FLAG)
- || (page_table[next_page].allocated == BOXED_PAGE_FLAG)) &&
+ page_allocated_no_region_p(next_page) &&
page_table[next_page].large_object &&
- (page_table[next_page].first_object_offset ==
- -(next_page - first_page)*PAGE_BYTES)) {
+ (page_table[next_page].region_start_offset ==
+ npage_bytes(next_page - first_page))) {
/* Checks out OK, free the page. Don't need to both zeroing
* pages as this should have been done before shrinking the
* object. These pages shouldn't be write-protected, even if
next_page++;
}
- if ((bytes_freed > 0) && gencgc_verbose)
+ if ((bytes_freed > 0) && gencgc_verbose) {
FSHOW((stderr,
"/copy_large_unboxed bytes_freed=%d\n",
bytes_freed));
+ }
- generations[from_space].bytes_allocated -= nwords*N_WORD_BYTES + bytes_freed;
+ generations[from_space].bytes_allocated -=
+ nwords*N_WORD_BYTES + bytes_freed;
generations[new_space].bytes_allocated += nwords*N_WORD_BYTES;
bytes_allocated -= bytes_freed;
if (!check_code_fixups)
return;
+ FSHOW((stderr, "/sniffing code: %p, %lu\n", code, displacement));
+
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);
-#ifdef QSHOW
+#if QSHOW
unsigned d5 = *((unsigned char *)p - 5);
unsigned d6 = *((unsigned char *)p - 6);
#endif
&& (data < (code_end_addr-displacement))) {
/* function header */
if ((d4 == 0x5e)
- && (((unsigned)p - 4 - 4*HeaderValue(*((unsigned *)p-1))) == (unsigned)code)) {
+ && (((unsigned)p - 4 - 4*HeaderValue(*((unsigned *)p-1))) ==
+ (unsigned)code)) {
/* Skip the function header */
p += 6*4 - 4 - 1;
continue;
void *constants_start_addr, *constants_end_addr;
void *code_start_addr, *code_end_addr;
lispobj fixups = NIL;
- unsigned long displacement = (unsigned long)new_code - (unsigned long)old_code;
+ unsigned long displacement =
+ (unsigned long)new_code - (unsigned long)old_code;
struct vector *fixups_vector;
ncode_words = fixnum_value(new_code->code_size);
(fixups_vector->header == 0x01)) {
/* If so, then follow it. */
/*SHOW("following pointer to a forwarding pointer");*/
- fixups_vector = (struct vector *)native_pointer((lispobj)fixups_vector->length);
+ fixups_vector =
+ (struct vector *)native_pointer((lispobj)fixups_vector->length);
}
/*SHOW("got fixups");*/
/* If it's within the old_code object then it must be an
* absolute fixup (relative ones are not saved) */
if ((old_value >= (unsigned long)old_code)
- && (old_value < ((unsigned long)old_code + nwords*N_WORD_BYTES)))
+ && (old_value < ((unsigned long)old_code
+ + nwords*N_WORD_BYTES)))
/* So add the dispacement. */
*(unsigned long *)((unsigned long)code_start_addr + offset) =
old_value + displacement;
old_value - displacement;
}
} else {
- fprintf(stderr, "widetag of fixup vector is %d\n", widetag_of(fixups_vector->header));
+ /* This used to just print a note to stderr, but a bogus fixup seems to
+ * indicate real heap corruption, so a hard hailure is in order. */
+ lose("fixup vector %p has a bad widetag: %d\n",
+ fixups_vector, widetag_of(fixups_vector->header));
}
/* Check for possible errors. */
return copy_large_unboxed_object(object, length);
}
#endif
-
-\f
-/*
- * Lutexes. Using the normal finalization machinery for finalizing
- * lutexes is tricky, since the finalization depends on working lutexes.
- * So we track the lutexes in the GC and finalize them manually.
- */
-
-#if defined(LUTEX_WIDETAG)
-
-/*
- * Start tracking LUTEX in the GC, by adding it to the linked list of
- * lutexes in the nursery generation. The caller is responsible for
- * locking, and GCs must be inhibited until the registration is
- * complete.
- */
-void
-gencgc_register_lutex (struct lutex *lutex) {
- int index = find_page_index(lutex);
- generation_index_t gen;
- struct lutex *head;
-
- /* This lutex is in static space, so we don't need to worry about
- * finalizing it.
- */
- if (index == -1)
- return;
-
- gen = page_table[index].gen;
-
- gc_assert(gen >= 0);
- gc_assert(gen < NUM_GENERATIONS);
-
- head = generations[gen].lutexes;
-
- lutex->gen = gen;
- lutex->next = head;
- lutex->prev = NULL;
- if (head)
- head->prev = lutex;
- generations[gen].lutexes = lutex;
-}
-
-/*
- * Stop tracking LUTEX in the GC by removing it from the appropriate
- * linked lists. This will only be called during GC, so no locking is
- * needed.
- */
-void
-gencgc_unregister_lutex (struct lutex *lutex) {
- if (lutex->prev) {
- lutex->prev->next = lutex->next;
- } else {
- generations[lutex->gen].lutexes = lutex->next;
- }
-
- if (lutex->next) {
- lutex->next->prev = lutex->prev;
- }
-
- lutex->next = NULL;
- lutex->prev = NULL;
- lutex->gen = -1;
-}
-
-/*
- * Mark all lutexes in generation GEN as not live.
- */
-static void
-unmark_lutexes (generation_index_t gen) {
- struct lutex *lutex = generations[gen].lutexes;
-
- while (lutex) {
- lutex->live = 0;
- lutex = lutex->next;
- }
-}
-
-/*
- * Finalize all lutexes in generation GEN that have not been marked live.
- */
-static void
-reap_lutexes (generation_index_t gen) {
- struct lutex *lutex = generations[gen].lutexes;
-
- while (lutex) {
- struct lutex *next = lutex->next;
- if (!lutex->live) {
- lutex_destroy((tagged_lutex_t) lutex);
- gencgc_unregister_lutex(lutex);
- }
- lutex = next;
- }
-}
-
-/*
- * Mark LUTEX as live.
- */
-static void
-mark_lutex (lispobj tagged_lutex) {
- struct lutex *lutex = (struct lutex*) native_pointer(tagged_lutex);
-
- lutex->live = 1;
-}
-
-/*
- * Move all lutexes in generation FROM to generation TO.
- */
-static void
-move_lutexes (generation_index_t from, generation_index_t to) {
- struct lutex *tail = generations[from].lutexes;
-
- /* Nothing to move */
- if (!tail)
- return;
-
- /* Change the generation of the lutexes in FROM. */
- while (tail->next) {
- tail->gen = to;
- tail = tail->next;
- }
- tail->gen = to;
-
- /* Link the last lutex in the FROM list to the start of the TO list */
- tail->next = generations[to].lutexes;
-
- /* And vice versa */
- if (generations[to].lutexes) {
- generations[to].lutexes->prev = tail;
- }
-
- /* And update the generations structures to match this */
- generations[to].lutexes = generations[from].lutexes;
- generations[from].lutexes = NULL;
-}
-
-static long
-scav_lutex(lispobj *where, lispobj object)
-{
- mark_lutex((lispobj) where);
-
- return CEILING(sizeof(struct lutex)/sizeof(lispobj), 2);
-}
-
-static lispobj
-trans_lutex(lispobj object)
-{
- struct lutex *lutex = (struct lutex *) native_pointer(object);
- lispobj copied;
- size_t words = CEILING(sizeof(struct lutex)/sizeof(lispobj), 2);
- gc_assert(is_lisp_pointer(object));
- copied = copy_object(object, words);
-
- /* Update the links, since the lutex moved in memory. */
- if (lutex->next) {
- lutex->next->prev = (struct lutex *) native_pointer(copied);
- }
-
- if (lutex->prev) {
- lutex->prev->next = (struct lutex *) native_pointer(copied);
- } else {
- generations[lutex->gen].lutexes =
- (struct lutex *) native_pointer(copied);
- }
-
- return copied;
-}
-
-static long
-size_lutex(lispobj *where)
-{
- return CEILING(sizeof(struct lutex)/sizeof(lispobj), 2);
-}
-#endif /* LUTEX_WIDETAG */
-
\f
/*
* weak pointers
* Instead of searching the list of weak_pointers each
* time, we ensure that next is always NULL when the weak
* pointer isn't in the list, and not NULL otherwise.
- * Since we can't use NULL to denote end of list, we
- * use a pointer back to the same weak_pointer.
- */
- struct weak_pointer * wp = (struct weak_pointer*)where;
-
- if (NULL == wp->next) {
- wp->next = weak_pointers;
- weak_pointers = wp;
- if (NULL == wp->next)
- wp->next = wp;
- }
-
- /* Do not let GC scavenge the value slot of the weak pointer.
- * (That is why it is a weak pointer.) */
-
- return WEAK_POINTER_NWORDS;
-}
-
-\f
-lispobj *
-search_read_only_space(void *pointer)
-{
- lispobj *start = (lispobj *) READ_ONLY_SPACE_START;
- lispobj *end = (lispobj *) SymbolValue(READ_ONLY_SPACE_FREE_POINTER,0);
- if ((pointer < (void *)start) || (pointer >= (void *)end))
- return NULL;
- return (gc_search_space(start,
- (((lispobj *)pointer)+2)-start,
- (lispobj *) pointer));
-}
-
-lispobj *
-search_static_space(void *pointer)
-{
- lispobj *start = (lispobj *)STATIC_SPACE_START;
- lispobj *end = (lispobj *)SymbolValue(STATIC_SPACE_FREE_POINTER,0);
- if ((pointer < (void *)start) || (pointer >= (void *)end))
- return NULL;
- return (gc_search_space(start,
- (((lispobj *)pointer)+2)-start,
- (lispobj *) pointer));
-}
-
-/* a faster version for searching the dynamic space. This will work even
- * if the object is in a current allocation region. */
-lispobj *
-search_dynamic_space(void *pointer)
-{
- page_index_t page_index = find_page_index(pointer);
- lispobj *start;
-
- /* The address may be invalid, so do some checks. */
- if ((page_index == -1) ||
- (page_table[page_index].allocated == FREE_PAGE_FLAG))
- return NULL;
- start = (lispobj *)((void *)page_address(page_index)
- + page_table[page_index].first_object_offset);
- return (gc_search_space(start,
- (((lispobj *)pointer)+2)-start,
- (lispobj *)pointer));
-}
-
-#if defined(LISP_FEATURE_X86) || defined(LISP_FEATURE_X86_64)
-
-/* Helper for valid_lisp_pointer_p and
- * possibly_valid_dynamic_space_pointer.
- *
- * pointer is the pointer to validate, and start_addr is the address
- * of the enclosing object.
- */
-static int
-looks_like_valid_lisp_pointer_p(lispobj *pointer, lispobj *start_addr)
-{
- /* We need to allow raw pointers into Code objects for return
- * addresses. This will also pick up pointers to functions in code
- * objects. */
- if (widetag_of(*start_addr) == CODE_HEADER_WIDETAG)
- /* XXX could do some further checks here */
- return 1;
-
- if (!is_lisp_pointer((lispobj)pointer)) {
- return 0;
- }
-
- /* Check that the object pointed to is consistent with the pointer
- * low tag. */
- switch (lowtag_of((lispobj)pointer)) {
- case FUN_POINTER_LOWTAG:
- /* Start_addr should be the enclosing code object, or a closure
- * header. */
- switch (widetag_of(*start_addr)) {
- case CODE_HEADER_WIDETAG:
- /* This case is probably caught above. */
- break;
- case CLOSURE_HEADER_WIDETAG:
- case FUNCALLABLE_INSTANCE_HEADER_WIDETAG:
- if ((unsigned long)pointer !=
- ((unsigned long)start_addr+FUN_POINTER_LOWTAG)) {
- if (gencgc_verbose)
- FSHOW((stderr,
- "/Wf2: %x %x %x\n",
- pointer, start_addr, *start_addr));
- return 0;
- }
- break;
- default:
- if (gencgc_verbose)
- FSHOW((stderr,
- "/Wf3: %x %x %x\n",
- pointer, start_addr, *start_addr));
- return 0;
- }
- break;
- case LIST_POINTER_LOWTAG:
- if ((unsigned long)pointer !=
- ((unsigned long)start_addr+LIST_POINTER_LOWTAG)) {
- if (gencgc_verbose)
- FSHOW((stderr,
- "/Wl1: %x %x %x\n",
- pointer, start_addr, *start_addr));
- return 0;
- }
- /* Is it plausible cons? */
- if ((is_lisp_pointer(start_addr[0])
- || (fixnump(start_addr[0]))
- || (widetag_of(start_addr[0]) == CHARACTER_WIDETAG)
-#if N_WORD_BITS == 64
- || (widetag_of(start_addr[0]) == SINGLE_FLOAT_WIDETAG)
-#endif
- || (widetag_of(start_addr[0]) == UNBOUND_MARKER_WIDETAG))
- && (is_lisp_pointer(start_addr[1])
- || (fixnump(start_addr[1]))
- || (widetag_of(start_addr[1]) == CHARACTER_WIDETAG)
-#if N_WORD_BITS == 64
- || (widetag_of(start_addr[1]) == SINGLE_FLOAT_WIDETAG)
-#endif
- || (widetag_of(start_addr[1]) == UNBOUND_MARKER_WIDETAG)))
- break;
- else {
- if (gencgc_verbose)
- FSHOW((stderr,
- "/Wl2: %x %x %x\n",
- pointer, start_addr, *start_addr));
- return 0;
- }
- case INSTANCE_POINTER_LOWTAG:
- if ((unsigned long)pointer !=
- ((unsigned long)start_addr+INSTANCE_POINTER_LOWTAG)) {
- if (gencgc_verbose)
- FSHOW((stderr,
- "/Wi1: %x %x %x\n",
- pointer, start_addr, *start_addr));
- return 0;
- }
- if (widetag_of(start_addr[0]) != INSTANCE_HEADER_WIDETAG) {
- if (gencgc_verbose)
- FSHOW((stderr,
- "/Wi2: %x %x %x\n",
- pointer, start_addr, *start_addr));
- return 0;
- }
- break;
- case OTHER_POINTER_LOWTAG:
- if ((unsigned long)pointer !=
- ((unsigned long)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. 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 (widetag_of(start_addr[0])) {
- case UNBOUND_MARKER_WIDETAG:
- case NO_TLS_VALUE_MARKER_WIDETAG:
- case CHARACTER_WIDETAG:
-#if N_WORD_BITS == 64
- case SINGLE_FLOAT_WIDETAG:
-#endif
- if (gencgc_verbose)
- FSHOW((stderr,
- "*Wo3: %x %x %x\n",
- pointer, start_addr, *start_addr));
- return 0;
-
- /* only pointed to by function pointers? */
- 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 INSTANCE_HEADER_WIDETAG:
- if (gencgc_verbose)
- FSHOW((stderr,
- "*Wo5: %x %x %x\n",
- pointer, start_addr, *start_addr));
- return 0;
-
- /* the valid other immediate pointer objects */
- case SIMPLE_VECTOR_WIDETAG:
- case RATIO_WIDETAG:
- case COMPLEX_WIDETAG:
-#ifdef COMPLEX_SINGLE_FLOAT_WIDETAG
- case COMPLEX_SINGLE_FLOAT_WIDETAG:
-#endif
-#ifdef COMPLEX_DOUBLE_FLOAT_WIDETAG
- case COMPLEX_DOUBLE_FLOAT_WIDETAG:
-#endif
-#ifdef COMPLEX_LONG_FLOAT_WIDETAG
- case COMPLEX_LONG_FLOAT_WIDETAG:
-#endif
- case SIMPLE_ARRAY_WIDETAG:
- case COMPLEX_BASE_STRING_WIDETAG:
-#ifdef COMPLEX_CHARACTER_STRING_WIDETAG
- case COMPLEX_CHARACTER_STRING_WIDETAG:
-#endif
- case COMPLEX_VECTOR_NIL_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:
-#if N_WORD_BITS != 64
- case SINGLE_FLOAT_WIDETAG:
-#endif
- case DOUBLE_FLOAT_WIDETAG:
-#ifdef LONG_FLOAT_WIDETAG
- case LONG_FLOAT_WIDETAG:
-#endif
- case SIMPLE_BASE_STRING_WIDETAG:
-#ifdef SIMPLE_CHARACTER_STRING_WIDETAG
- case SIMPLE_CHARACTER_STRING_WIDETAG:
-#endif
- case SIMPLE_BIT_VECTOR_WIDETAG:
- case SIMPLE_ARRAY_NIL_WIDETAG:
- case SIMPLE_ARRAY_UNSIGNED_BYTE_2_WIDETAG:
- case SIMPLE_ARRAY_UNSIGNED_BYTE_4_WIDETAG:
- case SIMPLE_ARRAY_UNSIGNED_BYTE_7_WIDETAG:
- case SIMPLE_ARRAY_UNSIGNED_BYTE_8_WIDETAG:
- case SIMPLE_ARRAY_UNSIGNED_BYTE_15_WIDETAG:
- case SIMPLE_ARRAY_UNSIGNED_BYTE_16_WIDETAG:
-#ifdef SIMPLE_ARRAY_UNSIGNED_BYTE_29_WIDETAG
- case SIMPLE_ARRAY_UNSIGNED_BYTE_29_WIDETAG:
-#endif
- case SIMPLE_ARRAY_UNSIGNED_BYTE_31_WIDETAG:
- case SIMPLE_ARRAY_UNSIGNED_BYTE_32_WIDETAG:
-#ifdef SIMPLE_ARRAY_UNSIGNED_BYTE_60_WIDETAG
- case SIMPLE_ARRAY_UNSIGNED_BYTE_60_WIDETAG:
-#endif
-#ifdef SIMPLE_ARRAY_UNSIGNED_BYTE_63_WIDETAG
- case SIMPLE_ARRAY_UNSIGNED_BYTE_63_WIDETAG:
-#endif
-#ifdef SIMPLE_ARRAY_UNSIGNED_BYTE_64_WIDETAG
- case SIMPLE_ARRAY_UNSIGNED_BYTE_64_WIDETAG:
-#endif
-#ifdef SIMPLE_ARRAY_SIGNED_BYTE_8_WIDETAG
- case SIMPLE_ARRAY_SIGNED_BYTE_8_WIDETAG:
-#endif
-#ifdef SIMPLE_ARRAY_SIGNED_BYTE_16_WIDETAG
- case SIMPLE_ARRAY_SIGNED_BYTE_16_WIDETAG:
-#endif
-#ifdef SIMPLE_ARRAY_SIGNED_BYTE_30_WIDETAG
- case SIMPLE_ARRAY_SIGNED_BYTE_30_WIDETAG:
-#endif
-#ifdef SIMPLE_ARRAY_SIGNED_BYTE_32_WIDETAG
- case SIMPLE_ARRAY_SIGNED_BYTE_32_WIDETAG:
-#endif
-#ifdef SIMPLE_ARRAY_SIGNED_BYTE_61_WIDETAG
- case SIMPLE_ARRAY_SIGNED_BYTE_61_WIDETAG:
-#endif
-#ifdef SIMPLE_ARRAY_SIGNED_BYTE_64_WIDETAG
- case SIMPLE_ARRAY_SIGNED_BYTE_64_WIDETAG:
-#endif
- 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 SIMPLE_ARRAY_COMPLEX_SINGLE_FLOAT_WIDETAG
- case SIMPLE_ARRAY_COMPLEX_SINGLE_FLOAT_WIDETAG:
-#endif
-#ifdef SIMPLE_ARRAY_COMPLEX_DOUBLE_FLOAT_WIDETAG
- case SIMPLE_ARRAY_COMPLEX_DOUBLE_FLOAT_WIDETAG:
-#endif
-#ifdef SIMPLE_ARRAY_COMPLEX_LONG_FLOAT_WIDETAG
- case SIMPLE_ARRAY_COMPLEX_LONG_FLOAT_WIDETAG:
-#endif
- case SAP_WIDETAG:
- case WEAK_POINTER_WIDETAG:
-#ifdef LUTEX_WIDETAG
- case LUTEX_WIDETAG:
-#endif
- break;
+ * Since we can't use NULL to denote end of list, we
+ * use a pointer back to the same weak_pointer.
+ */
+ struct weak_pointer * wp = (struct weak_pointer*)where;
- default:
- if (gencgc_verbose)
- FSHOW((stderr,
- "/Wo6: %x %x %x\n",
- pointer, start_addr, *start_addr));
- return 0;
- }
- break;
- default:
- if (gencgc_verbose)
- FSHOW((stderr,
- "*W?: %x %x %x\n",
- pointer, start_addr, *start_addr));
- return 0;
+ if (NULL == wp->next) {
+ wp->next = weak_pointers;
+ weak_pointers = wp;
+ if (NULL == wp->next)
+ wp->next = wp;
}
- /* looks good */
- return 1;
+ /* Do not let GC scavenge the value slot of the weak pointer.
+ * (That is why it is a weak pointer.) */
+
+ return WEAK_POINTER_NWORDS;
}
-/* Used by the debugger to validate possibly bogus pointers before
- * calling MAKE-LISP-OBJ on them.
- *
- * FIXME: We would like to make this perfect, because if the debugger
- * constructs a reference to a bugs lisp object, and it ends up in a
- * location scavenged by the GC all hell breaks loose.
- *
- * Whereas possibly_valid_dynamic_space_pointer has to be conservative
- * and return true for all valid pointers, this could actually be eager
- * and lie about a few pointers without bad results... but that should
- * be reflected in the name.
- */
-int
-valid_lisp_pointer_p(lispobj *pointer)
+\f
+lispobj *
+search_read_only_space(void *pointer)
+{
+ lispobj *start = (lispobj *) READ_ONLY_SPACE_START;
+ lispobj *end = (lispobj *) SymbolValue(READ_ONLY_SPACE_FREE_POINTER,0);
+ if ((pointer < (void *)start) || (pointer >= (void *)end))
+ return NULL;
+ return (gc_search_space(start,
+ (((lispobj *)pointer)+2)-start,
+ (lispobj *) pointer));
+}
+
+lispobj *
+search_static_space(void *pointer)
+{
+ lispobj *start = (lispobj *)STATIC_SPACE_START;
+ lispobj *end = (lispobj *)SymbolValue(STATIC_SPACE_FREE_POINTER,0);
+ if ((pointer < (void *)start) || (pointer >= (void *)end))
+ return NULL;
+ return (gc_search_space(start,
+ (((lispobj *)pointer)+2)-start,
+ (lispobj *) pointer));
+}
+
+/* a faster version for searching the dynamic space. This will work even
+ * if the object is in a current allocation region. */
+lispobj *
+search_dynamic_space(void *pointer)
{
+ page_index_t page_index = find_page_index(pointer);
lispobj *start;
- if (((start=search_dynamic_space(pointer))!=NULL) ||
- ((start=search_static_space(pointer))!=NULL) ||
- ((start=search_read_only_space(pointer))!=NULL))
- return looks_like_valid_lisp_pointer_p(pointer, start);
- else
- return 0;
+
+ /* The address may be invalid, so do some checks. */
+ if ((page_index == -1) || page_free_p(page_index))
+ return NULL;
+ start = (lispobj *)page_region_start(page_index);
+ return (gc_search_space(start,
+ (((lispobj *)pointer)+2)-start,
+ (lispobj *)pointer));
}
+#if defined(LISP_FEATURE_X86) || defined(LISP_FEATURE_X86_64)
+
/* 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?
return looks_like_valid_lisp_pointer_p(pointer, start_addr);
}
+#endif // defined(LISP_FEATURE_X86) || defined(LISP_FEATURE_X86_64)
+
/* 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
page_index_t next_page;
long nwords;
- long remaining_bytes;
- long bytes_freed;
- long old_bytes_used;
+ unsigned long remaining_bytes;
+ unsigned long bytes_freed;
+ unsigned long old_bytes_used;
int boxed;
case SIMPLE_ARRAY_UNSIGNED_BYTE_8_WIDETAG:
case SIMPLE_ARRAY_UNSIGNED_BYTE_15_WIDETAG:
case SIMPLE_ARRAY_UNSIGNED_BYTE_16_WIDETAG:
-#ifdef SIMPLE_ARRAY_UNSIGNED_BYTE_29_WIDETAG
- case SIMPLE_ARRAY_UNSIGNED_BYTE_29_WIDETAG:
-#endif
+
+ case SIMPLE_ARRAY_UNSIGNED_FIXNUM_WIDETAG:
+
case SIMPLE_ARRAY_UNSIGNED_BYTE_31_WIDETAG:
case SIMPLE_ARRAY_UNSIGNED_BYTE_32_WIDETAG:
-#ifdef SIMPLE_ARRAY_UNSIGNED_BYTE_60_WIDETAG
- case SIMPLE_ARRAY_UNSIGNED_BYTE_60_WIDETAG:
-#endif
#ifdef SIMPLE_ARRAY_UNSIGNED_BYTE_63_WIDETAG
case SIMPLE_ARRAY_UNSIGNED_BYTE_63_WIDETAG:
#endif
#ifdef SIMPLE_ARRAY_SIGNED_BYTE_16_WIDETAG
case SIMPLE_ARRAY_SIGNED_BYTE_16_WIDETAG:
#endif
-#ifdef SIMPLE_ARRAY_SIGNED_BYTE_30_WIDETAG
- case SIMPLE_ARRAY_SIGNED_BYTE_30_WIDETAG:
-#endif
+
+ case SIMPLE_ARRAY_FIXNUM_WIDETAG:
+
#ifdef SIMPLE_ARRAY_SIGNED_BYTE_32_WIDETAG
case SIMPLE_ARRAY_SIGNED_BYTE_32_WIDETAG:
#endif
-#ifdef SIMPLE_ARRAY_SIGNED_BYTE_61_WIDETAG
- case SIMPLE_ARRAY_SIGNED_BYTE_61_WIDETAG:
-#endif
#ifdef SIMPLE_ARRAY_SIGNED_BYTE_64_WIDETAG
case SIMPLE_ARRAY_SIGNED_BYTE_64_WIDETAG:
#endif
* but lets do it for them all (they'll probably be written
* anyway?). */
- gc_assert(page_table[first_page].first_object_offset == 0);
+ gc_assert(page_table[first_page].region_start_offset == 0);
next_page = first_page;
remaining_bytes = nwords*N_WORD_BYTES;
- while (remaining_bytes > PAGE_BYTES) {
+ while (remaining_bytes > GENCGC_CARD_BYTES) {
gc_assert(page_table[next_page].gen == from_space);
- gc_assert((page_table[next_page].allocated == BOXED_PAGE_FLAG)
- || (page_table[next_page].allocated == UNBOXED_PAGE_FLAG));
+ gc_assert(page_allocated_no_region_p(next_page));
gc_assert(page_table[next_page].large_object);
- gc_assert(page_table[next_page].first_object_offset ==
- -PAGE_BYTES*(next_page-first_page));
- gc_assert(page_table[next_page].bytes_used == PAGE_BYTES);
+ gc_assert(page_table[next_page].region_start_offset ==
+ npage_bytes(next_page-first_page));
+ gc_assert(page_table[next_page].bytes_used == GENCGC_CARD_BYTES);
page_table[next_page].allocated = boxed;
/* Shouldn't be write-protected at this stage. Essential that the
* pages aren't. */
gc_assert(!page_table[next_page].write_protected);
- remaining_bytes -= PAGE_BYTES;
+ remaining_bytes -= GENCGC_CARD_BYTES;
next_page++;
}
/* Free any remaining pages; needs care. */
next_page++;
- while ((old_bytes_used == PAGE_BYTES) &&
+ while ((old_bytes_used == GENCGC_CARD_BYTES) &&
(page_table[next_page].gen == from_space) &&
- ((page_table[next_page].allocated == UNBOXED_PAGE_FLAG)
- || (page_table[next_page].allocated == BOXED_PAGE_FLAG)) &&
+ page_allocated_no_region_p(next_page) &&
page_table[next_page].large_object &&
- (page_table[next_page].first_object_offset ==
- -(next_page - first_page)*PAGE_BYTES)) {
+ (page_table[next_page].region_start_offset ==
+ npage_bytes(next_page - first_page))) {
/* It checks out OK, free the page. We don't need to both zeroing
* pages as this should have been done before shrinking the
* object. These pages shouldn't be write protected as they
/* quick check 1: Address is quite likely to have been invalid. */
if ((addr_page_index == -1)
- || (page_table[addr_page_index].allocated == FREE_PAGE_FLAG)
+ || page_free_p(addr_page_index)
|| (page_table[addr_page_index].bytes_used == 0)
|| (page_table[addr_page_index].gen != from_space)
/* Skip if already marked dont_move. */
/* quick check 2: Check the offset within the page.
*
*/
- if (((unsigned long)addr & (PAGE_BYTES - 1)) > page_table[addr_page_index].bytes_used)
+ if (((unsigned long)addr & (GENCGC_CARD_BYTES - 1)) >
+ page_table[addr_page_index].bytes_used)
return;
/* Filter out anything which can't be a pointer to a Lisp object
* address referring to something in a CodeObject). This is
* expensive but important, since it vastly reduces the
* probability that random garbage will be bogusly interpreted as
- * a pointer which prevents a page from moving. */
- if (!(possibly_valid_dynamic_space_pointer(addr)))
+ * a pointer which prevents a page from moving.
+ *
+ * This only needs to happen on x86oids, where this is used for
+ * conservative roots. Non-x86oid systems only ever call this
+ * function on known-valid lisp objects. */
+#if defined(LISP_FEATURE_X86) || defined(LISP_FEATURE_X86_64)
+ if (!(code_page_p(addr_page_index)
+ || (is_lisp_pointer((lispobj)addr) &&
+ possibly_valid_dynamic_space_pointer(addr))))
return;
+#endif
/* Find the beginning of the region. Note that there may be
* objects in the region preceding the one that we were passed a
#if 0
/* I think this'd work just as well, but without the assertions.
* -dan 2004.01.01 */
- first_page=
- find_page_index(page_address(addr_page_index)+
- page_table[addr_page_index].first_object_offset);
+ first_page = find_page_index(page_region_start(addr_page_index))
#else
first_page = addr_page_index;
- while (page_table[first_page].first_object_offset != 0) {
+ while (page_table[first_page].region_start_offset != 0) {
--first_page;
/* Do some checks. */
- gc_assert(page_table[first_page].bytes_used == PAGE_BYTES);
+ gc_assert(page_table[first_page].bytes_used == GENCGC_CARD_BYTES);
gc_assert(page_table[first_page].gen == from_space);
gc_assert(page_table[first_page].allocated == region_allocation);
}
* 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_FLAG)
+ if (page_free_p(addr_page_index)
|| (page_table[addr_page_index].bytes_used == 0)
/* Check the offset within the page. */
- || (((unsigned long)addr & (PAGE_BYTES - 1))
+ || (((unsigned long)addr & (GENCGC_CARD_BYTES - 1))
> page_table[addr_page_index].bytes_used)) {
FSHOW((stderr,
"weird? ignore ptr 0x%x to freed area of large object\n",
gc_assert(!page_table[i].write_protected);
/* Check whether this is the last page in this contiguous block.. */
- if ((page_table[i].bytes_used < PAGE_BYTES)
- /* ..or it is PAGE_BYTES and is the last in the block */
- || (page_table[i+1].allocated == FREE_PAGE_FLAG)
+ if ((page_table[i].bytes_used < GENCGC_CARD_BYTES)
+ /* ..or it is CARD_BYTES and is the last in the block */
+ || page_free_p(i+1)
|| (page_table[i+1].bytes_used == 0) /* next page free */
|| (page_table[i+1].gen != from_space) /* diff. gen */
- || (page_table[i+1].first_object_offset == 0))
+ || (page_table[i+1].region_start_offset == 0))
break;
}
/* Check that the page is now static. */
gc_assert(page_table[addr_page_index].dont_move != 0);
}
-
-#endif // defined(LISP_FEATURE_X86) || defined(LISP_FEATURE_X86_64)
-
\f
/* If the given page is not write-protected, then scan it for pointers
* to younger generations or the top temp. generation, if no
long num_words = page_table[page].bytes_used / N_WORD_BYTES;
/* Shouldn't be a free page. */
- gc_assert(page_table[page].allocated != FREE_PAGE_FLAG);
+ gc_assert(page_allocated_p(page));
gc_assert(page_table[page].bytes_used != 0);
/* Skip if it's already write-protected, pinned, or unboxed */
if (page_table[page].write_protected
/* FIXME: What's the reason for not write-protecting pinned pages? */
|| page_table[page].dont_move
- || (page_table[page].allocated & UNBOXED_PAGE_FLAG))
+ || page_unboxed_p(page))
return (0);
/* Scan the page for pointers to younger generations or the
/* Check that it's in the dynamic space */
if (index != -1)
if (/* Does it point to a younger or the temp. generation? */
- ((page_table[index].allocated != FREE_PAGE_FLAG)
+ (page_allocated_p(index)
&& (page_table[index].bytes_used != 0)
&& ((page_table[index].gen < gen)
|| (page_table[index].gen == SCRATCH_GENERATION)))
/*FSHOW((stderr, "/write-protecting page %d gen %d\n", page, gen));*/
os_protect((void *)page_addr,
- PAGE_BYTES,
+ GENCGC_CARD_BYTES,
OS_VM_PROT_READ|OS_VM_PROT_EXECUTE);
/* Note the page as protected in the page tables. */
scavenge_generations(generation_index_t from, generation_index_t to)
{
page_index_t i;
- int num_wp = 0;
+ page_index_t num_wp = 0;
#define SC_GEN_CK 0
#if SC_GEN_CK
for (i = 0; i < last_free_page; i++) {
generation_index_t generation = page_table[i].gen;
- if ((page_table[i].allocated & BOXED_PAGE_FLAG)
+ if (page_boxed_p(i)
&& (page_table[i].bytes_used != 0)
&& (generation != new_space)
&& (generation >= from)
int write_protected=1;
/* This should be the start of a region */
- gc_assert(page_table[i].first_object_offset == 0);
+ gc_assert(page_table[i].region_start_offset == 0);
/* Now work forward until the end of the region */
for (last_page = i; ; last_page++) {
write_protected =
write_protected && page_table[last_page].write_protected;
- if ((page_table[last_page].bytes_used < PAGE_BYTES)
- /* Or it is PAGE_BYTES and is the last in the block */
- || (!(page_table[last_page+1].allocated & BOXED_PAGE_FLAG))
+ if ((page_table[last_page].bytes_used < GENCGC_CARD_BYTES)
+ /* Or it is CARD_BYTES and is the last in the block */
+ || (!page_boxed_p(last_page+1))
|| (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[last_page+1].region_start_offset == 0))
break;
}
if (!write_protected) {
scavenge(page_address(i),
- (page_table[last_page].bytes_used +
- (last_page-i)*PAGE_BYTES)/N_WORD_BYTES);
+ ((unsigned long)(page_table[last_page].bytes_used
+ + npage_bytes(last_page-i)))
+ /N_WORD_BYTES);
/* Now scan the pages and write protect those that
* don't have pointers to younger generations. */
/* Check that none of the write_protected pages in this generation
* have been written to. */
for (i = 0; i < page_table_pages; i++) {
- if ((page_table[i].allocation != FREE_PAGE_FLAG)
+ if (page_allocated_p(i)
&& (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,
- "/page bytes_used=%d first_object_offset=%d dont_move=%d\n",
+ "/page bytes_used=%d region_start_offset=%lu dont_move=%d\n",
page_table[i].bytes_used,
- page_table[i].first_object_offset,
+ page_table[i].region_start_offset,
page_table[i].dont_move));
lose("write to protected page %d in scavenge_generation()\n", i);
}
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_FLAG)
+ if (page_boxed_p(i)
&& (page_table[i].bytes_used != 0)
&& (page_table[i].gen == generation)
&& ((page_table[i].write_protected == 0)
page_index_t last_page;
int all_wp=1;
- /* The scavenge will start at the first_object_offset of page i.
+ /* The scavenge will start at the region_start_offset of
+ * page i.
*
* We need to find the full extent of this contiguous
* block in case objects span pages.
/* Check whether this is the last page in this
* contiguous block */
- if ((page_table[last_page].bytes_used < PAGE_BYTES)
- /* Or it is PAGE_BYTES and is the last in the block */
- || (!(page_table[last_page+1].allocated & BOXED_PAGE_FLAG))
+ if ((page_table[last_page].bytes_used < GENCGC_CARD_BYTES)
+ /* Or it is CARD_BYTES and is the last in the block */
+ || (!page_boxed_p(last_page+1))
|| (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[last_page+1].region_start_offset == 0))
break;
}
/* Do a limited check for write-protected pages. */
if (!all_wp) {
- long size;
-
- size = (page_table[last_page].bytes_used
- + (last_page-i)*PAGE_BYTES
- - page_table[i].first_object_offset)/N_WORD_BYTES;
+ long nwords = (((unsigned long)
+ (page_table[last_page].bytes_used
+ + npage_bytes(last_page-i)
+ + page_table[i].region_start_offset))
+ / N_WORD_BYTES);
new_areas_ignore_page = last_page;
- scavenge(page_address(i) +
- page_table[i].first_object_offset,
- size);
+ scavenge(page_region_start(i), nwords);
}
i = last_page;
/* 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. */
- if (gencgc_verbose)
+ if (gencgc_verbose) {
SHOW("new_areas overflow, doing full scavenge");
+ }
/* Don't need to record new areas that get scavenged
* anyway during scavenge_newspace_generation_one_scan. */
/* Work through previous_new_areas. */
for (i = 0; i < previous_new_areas_index; i++) {
- long page = (*previous_new_areas)[i].page;
- long offset = (*previous_new_areas)[i].offset;
- long size = (*previous_new_areas)[i].size / N_WORD_BYTES;
+ page_index_t page = (*previous_new_areas)[i].page;
+ size_t offset = (*previous_new_areas)[i].offset;
+ size_t size = (*previous_new_areas)[i].size / N_WORD_BYTES;
gc_assert((*previous_new_areas)[i].size % N_WORD_BYTES == 0);
scavenge(page_address(page)+offset, size);
}
record_new_objects = 0;
#if SC_NS_GEN_CK
- /* Check that none of the write_protected pages in this generation
- * have been written to. */
- for (i = 0; i < page_table_pages; i++) {
- if ((page_table[i].allocation != FREE_PAGE_FLAG)
- && (page_table[i].bytes_used != 0)
- && (page_table[i].gen == generation)
- && (page_table[i].write_protected_cleared != 0)
- && (page_table[i].dont_move == 0)) {
- lose("write protected page %d written to in scavenge_newspace_generation\ngeneration=%d dont_move=%d\n",
- i, generation, page_table[i].dont_move);
+ {
+ page_index_t i;
+ /* Check that none of the write_protected pages in this generation
+ * have been written to. */
+ for (i = 0; i < page_table_pages; i++) {
+ if (page_allocated_p(i)
+ && (page_table[i].bytes_used != 0)
+ && (page_table[i].gen == generation)
+ && (page_table[i].write_protected_cleared != 0)
+ && (page_table[i].dont_move == 0)) {
+ lose("write protected page %d written to in scavenge_newspace_generation\ngeneration=%d dont_move=%d\n",
+ i, generation, page_table[i].dont_move);
+ }
}
}
#endif
unprotect_oldspace(void)
{
page_index_t i;
+ void *region_addr = 0;
+ void *page_addr = 0;
+ unsigned long region_bytes = 0;
for (i = 0; i < last_free_page; i++) {
- if ((page_table[i].allocated != FREE_PAGE_FLAG)
+ if (page_allocated_p(i)
&& (page_table[i].bytes_used != 0)
&& (page_table[i].gen == from_space)) {
- void *page_start;
-
- page_start = (void *)page_address(i);
/* Remove any write-protection. We should be able to rely
* on the write-protect flag to avoid redundant calls. */
if (page_table[i].write_protected) {
- os_protect(page_start, PAGE_BYTES, OS_VM_PROT_ALL);
page_table[i].write_protected = 0;
+ page_addr = page_address(i);
+ if (!region_addr) {
+ /* First region. */
+ region_addr = page_addr;
+ region_bytes = GENCGC_CARD_BYTES;
+ } else if (region_addr + region_bytes == page_addr) {
+ /* Region continue. */
+ region_bytes += GENCGC_CARD_BYTES;
+ } else {
+ /* Unprotect previous region. */
+ os_protect(region_addr, region_bytes, OS_VM_PROT_ALL);
+ /* First page in new region. */
+ region_addr = page_addr;
+ region_bytes = GENCGC_CARD_BYTES;
+ }
}
}
}
+ if (region_addr) {
+ /* Unprotect last region. */
+ os_protect(region_addr, region_bytes, OS_VM_PROT_ALL);
+ }
}
/* Work through all the pages and free any in from_space. This
* assumes that all objects have been copied or promoted to an older
* generation. Bytes_allocated and the generation bytes_allocated
* counter are updated. The number of bytes freed is returned. */
-static long
+static unsigned long
free_oldspace(void)
{
- long bytes_freed = 0;
+ unsigned long bytes_freed = 0;
page_index_t first_page, last_page;
first_page = 0;
do {
/* Find a first page for the next region of pages. */
while ((first_page < last_free_page)
- && ((page_table[first_page].allocated == FREE_PAGE_FLAG)
+ && (page_free_p(first_page)
|| (page_table[first_page].bytes_used == 0)
|| (page_table[first_page].gen != from_space)))
first_page++;
page_table[last_page].bytes_used;
page_table[last_page].allocated = FREE_PAGE_FLAG;
page_table[last_page].bytes_used = 0;
-
- /* Remove any write-protection. We should be able to rely
- * on the write-protect flag to avoid redundant calls. */
- {
- void *page_start = (void *)page_address(last_page);
-
- if (page_table[last_page].write_protected) {
- os_protect(page_start, PAGE_BYTES, OS_VM_PROT_ALL);
- page_table[last_page].write_protected = 0;
- }
- }
+ /* Should already be unprotected by unprotect_oldspace(). */
+ gc_assert(!page_table[last_page].write_protected);
last_page++;
}
while ((last_page < last_free_page)
- && (page_table[last_page].allocated != FREE_PAGE_FLAG)
+ && page_allocated_p(last_page)
&& (page_table[last_page].bytes_used != 0)
&& (page_table[last_page].gen == from_space));
#ifdef READ_PROTECT_FREE_PAGES
os_protect(page_address(first_page),
- PAGE_BYTES*(last_page-first_page),
+ npage_bytes(last_page-first_page),
OS_VM_PROT_NONE);
#endif
first_page = last_page;
page_index_t pi1 = find_page_index((void*)addr);
if (pi1 != -1)
- fprintf(stderr," %x: page %d alloc %d gen %d bytes_used %d offset %d dont_move %d\n",
+ fprintf(stderr," %x: page %d alloc %d gen %d bytes_used %d offset %lu dont_move %d\n",
(unsigned long) addr,
pi1,
page_table[pi1].allocated,
page_table[pi1].gen,
page_table[pi1].bytes_used,
- page_table[pi1].first_object_offset,
+ page_table[pi1].region_start_offset,
page_table[pi1].dont_move);
fprintf(stderr," %x %x %x %x (%x) %x %x %x %x\n",
*(addr-4),
}
#endif
+static int
+is_in_stack_space(lispobj ptr)
+{
+ /* For space verification: Pointers can be valid if they point
+ * to a thread stack space. This would be faster if the thread
+ * structures had page-table entries as if they were part of
+ * the heap space. */
+ struct thread *th;
+ for_each_thread(th) {
+ if ((th->control_stack_start <= (lispobj *)ptr) &&
+ (th->control_stack_end >= (lispobj *)ptr)) {
+ return 1;
+ }
+ }
+ return 0;
+}
+
static void
verify_space(lispobj *start, size_t words)
{
if (page_index != -1) {
/* If it's within the dynamic space it should point to a used
* page. XX Could check the offset too. */
- if ((page_table[page_index].allocated != FREE_PAGE_FLAG)
+ if (page_allocated_p(page_index)
&& (page_table[page_index].bytes_used == 0))
- lose ("Ptr %x @ %x sees free page.\n", thing, start);
+ lose ("Ptr %p @ %p sees free page.\n", thing, start);
/* Check that it doesn't point to a forwarding pointer! */
if (*((lispobj *)native_pointer(thing)) == 0x01) {
- lose("Ptr %x @ %x sees forwarding ptr.\n", thing, start);
+ lose("Ptr %p @ %p sees forwarding ptr.\n", thing, start);
}
/* Check that its not in the RO space as it would then be a
* pointer from the RO to the dynamic space. */
if (is_in_readonly_space) {
- lose("ptr to dynamic space %x from RO space %x\n",
+ lose("ptr to dynamic space %p from RO space %x\n",
thing, start);
}
/* Does it point to a plausible object? This check slows
* dynamically. */
/*
if (!possibly_valid_dynamic_space_pointer((lispobj *)thing)) {
- lose("ptr %x to invalid object %x\n", thing, start);
+ lose("ptr %p to invalid object %p\n", thing, start);
}
*/
} else {
+ extern void funcallable_instance_tramp;
/* Verify that it points to another valid space. */
- if (!to_readonly_space && !to_static_space) {
- lose("Ptr %x @ %x sees junk.\n", thing, start);
+ if (!to_readonly_space && !to_static_space
+ && (thing != (lispobj)&funcallable_instance_tramp)
+ && !is_in_stack_space(thing)) {
+ lose("Ptr %p @ %p sees junk.\n", thing, start);
}
}
} else {
count = 1;
break;
}
- nuntagged = ((struct layout *)native_pointer(layout))->n_untagged_slots;
- verify_space(start + 1, ntotal - fixnum_value(nuntagged));
+ nuntagged = ((struct layout *)
+ native_pointer(layout))->n_untagged_slots;
+ verify_space(start + 1,
+ ntotal - fixnum_value(nuntagged));
count = ntotal + 1;
break;
}
/* Only when enabled */
&& verify_dynamic_code_check) {
FSHOW((stderr,
- "/code object at %x in the dynamic space\n",
+ "/code object at %p in the dynamic space\n",
start));
}
while (fheaderl != NIL) {
fheaderp =
(struct simple_fun *) native_pointer(fheaderl);
- gc_assert(widetag_of(fheaderp->header) == SIMPLE_FUN_HEADER_WIDETAG);
+ 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);
case SIMPLE_ARRAY_UNSIGNED_BYTE_8_WIDETAG:
case SIMPLE_ARRAY_UNSIGNED_BYTE_15_WIDETAG:
case SIMPLE_ARRAY_UNSIGNED_BYTE_16_WIDETAG:
-#ifdef SIMPLE_ARRAY_UNSIGNED_BYTE_29_WIDETAG
- case SIMPLE_ARRAY_UNSIGNED_BYTE_29_WIDETAG:
-#endif
+
+ case SIMPLE_ARRAY_UNSIGNED_FIXNUM_WIDETAG:
+
case SIMPLE_ARRAY_UNSIGNED_BYTE_31_WIDETAG:
case SIMPLE_ARRAY_UNSIGNED_BYTE_32_WIDETAG:
-#ifdef SIMPLE_ARRAY_UNSIGNED_BYTE_60_WIDETAG
- case SIMPLE_ARRAY_UNSIGNED_BYTE_60_WIDETAG:
-#endif
#ifdef SIMPLE_ARRAY_UNSIGNED_BYTE_63_WIDETAG
case SIMPLE_ARRAY_UNSIGNED_BYTE_63_WIDETAG:
#endif
#ifdef SIMPLE_ARRAY_SIGNED_BYTE_16_WIDETAG
case SIMPLE_ARRAY_SIGNED_BYTE_16_WIDETAG:
#endif
-#ifdef SIMPLE_ARRAY_SIGNED_BYTE_30_WIDETAG
- case SIMPLE_ARRAY_SIGNED_BYTE_30_WIDETAG:
-#endif
+
+ case SIMPLE_ARRAY_FIXNUM_WIDETAG:
+
#ifdef SIMPLE_ARRAY_SIGNED_BYTE_32_WIDETAG
case SIMPLE_ARRAY_SIGNED_BYTE_32_WIDETAG:
#endif
-#ifdef SIMPLE_ARRAY_SIGNED_BYTE_61_WIDETAG
- case SIMPLE_ARRAY_SIGNED_BYTE_61_WIDETAG:
-#endif
#ifdef SIMPLE_ARRAY_SIGNED_BYTE_64_WIDETAG
case SIMPLE_ARRAY_SIGNED_BYTE_64_WIDETAG:
#endif
#endif
case SAP_WIDETAG:
case WEAK_POINTER_WIDETAG:
-#ifdef LUTEX_WIDETAG
- case LUTEX_WIDETAG:
+#ifdef NO_TLS_VALUE_MARKER_WIDETAG
+ case NO_TLS_VALUE_MARKER_WIDETAG:
#endif
count = (sizetab[widetag_of(*start)])(start);
break;
default:
- FSHOW((stderr,
- "/Unhandled widetag 0x%x at 0x%x\n",
- widetag_of(*start), start));
- fflush(stderr);
- gc_abort();
+ lose("Unhandled widetag %p at %p\n",
+ widetag_of(*start), start);
}
}
}
page_index_t i;
for (i = 0; i < last_free_page; i++) {
- if ((page_table[i].allocated != FREE_PAGE_FLAG)
+ if (page_allocated_p(i)
&& (page_table[i].bytes_used != 0)
&& (page_table[i].gen == generation)) {
page_index_t last_page;
int region_allocation = page_table[i].allocated;
/* This should be the start of a contiguous block */
- gc_assert(page_table[i].first_object_offset == 0);
+ gc_assert(page_table[i].region_start_offset == 0);
/* Need to find the full extent of this contiguous block in case
objects span pages. */
for (last_page = i; ;last_page++)
/* Check whether this is the last page in this contiguous
* block. */
- if ((page_table[last_page].bytes_used < PAGE_BYTES)
- /* Or it is PAGE_BYTES and is the last in the block */
+ if ((page_table[last_page].bytes_used < GENCGC_CARD_BYTES)
+ /* Or it is CARD_BYTES and is the last in the block */
|| (page_table[last_page+1].allocated != region_allocation)
|| (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[last_page+1].region_start_offset == 0))
break;
- verify_space(page_address(i), (page_table[last_page].bytes_used
- + (last_page-i)*PAGE_BYTES)/N_WORD_BYTES);
+ verify_space(page_address(i),
+ ((unsigned long)
+ (page_table[last_page].bytes_used
+ + npage_bytes(last_page-i)))
+ / N_WORD_BYTES);
i = last_page;
}
}
page_index_t page;
for (page = 0; page < last_free_page; page++) {
- if (page_table[page].allocated == FREE_PAGE_FLAG) {
+ if (page_free_p(page)) {
/* The whole page should be zero filled. */
long *start_addr = (long *)page_address(page);
long size = 1024;
}
}
} else {
- long free_bytes = PAGE_BYTES - page_table[page].bytes_used;
+ long free_bytes = GENCGC_CARD_BYTES - page_table[page].bytes_used;
if (free_bytes > 0) {
long *start_addr = (long *)((unsigned long)page_address(page)
+ page_table[page].bytes_used);
gc_assert(generation < SCRATCH_GENERATION);
for (start = 0; start < last_free_page; start++) {
- if ((page_table[start].allocated == BOXED_PAGE_FLAG)
- && (page_table[start].bytes_used != 0)
- && !page_table[start].dont_move
- && (page_table[start].gen == generation)) {
+ if (protect_page_p(start, generation)) {
void *page_start;
page_index_t last;
page_table[start].write_protected = 1;
for (last = start + 1; last < last_free_page; last++) {
- if ((page_table[last].allocated != BOXED_PAGE_FLAG)
- || (page_table[last].bytes_used == 0)
- || page_table[last].dont_move
- || (page_table[last].gen != generation))
+ if (!protect_page_p(last, generation))
break;
page_table[last].write_protected = 1;
}
page_start = (void *)page_address(start);
os_protect(page_start,
- PAGE_BYTES * (last - start),
+ npage_bytes(last - start),
OS_VM_PROT_READ | OS_VM_PROT_EXECUTE);
start = last;
}
#if !defined(LISP_FEATURE_X86) && !defined(LISP_FEATURE_X86_64)
-
static void
-scavenge_control_stack()
+scavenge_control_stack(struct thread *th)
{
- unsigned long control_stack_size;
-
- /* This is going to be a big problem when we try to port threads
- * to PPC... CLH */
- struct thread *th = arch_os_get_current_thread();
lispobj *control_stack =
(lispobj *)(th->control_stack_start);
+ unsigned long control_stack_size =
+ access_control_stack_pointer(th) - control_stack;
- control_stack_size = current_control_stack_pointer - control_stack;
scavenge(control_stack, control_stack_size);
}
-
-/* Scavenging Interrupt Contexts */
-
-static int boxed_registers[] = BOXED_REGISTERS;
-
-static void
-scavenge_interrupt_context(os_context_t * context)
-{
- int i;
-
-#ifdef reg_LIP
- unsigned long lip;
- unsigned long lip_offset;
- int lip_register_pair;
-#endif
- unsigned long pc_code_offset;
-
-#ifdef ARCH_HAS_LINK_REGISTER
- unsigned long lr_code_offset;
-#endif
-#ifdef ARCH_HAS_NPC_REGISTER
- unsigned long npc_code_offset;
-#endif
-
-#ifdef reg_LIP
- /* Find the LIP's register pair and calculate it's offset */
- /* before we scavenge the context. */
-
- /*
- * I (RLT) think this is trying to find the boxed register that is
- * closest to the LIP address, without going past it. Usually, it's
- * reg_CODE or reg_LRA. But sometimes, nothing can be found.
- */
- lip = *os_context_register_addr(context, reg_LIP);
- lip_offset = 0x7FFFFFFF;
- lip_register_pair = -1;
- for (i = 0; i < (sizeof(boxed_registers) / sizeof(int)); i++) {
- unsigned long reg;
- long offset;
- int index;
-
- index = boxed_registers[i];
- reg = *os_context_register_addr(context, index);
- if ((reg & ~((1L<<N_LOWTAG_BITS)-1)) <= lip) {
- offset = lip - reg;
- if (offset < lip_offset) {
- lip_offset = offset;
- lip_register_pair = index;
- }
- }
- }
-#endif /* reg_LIP */
-
- /* Compute the PC's offset from the start of the CODE */
- /* register. */
- pc_code_offset = *os_context_pc_addr(context) - *os_context_register_addr(context, reg_CODE);
-#ifdef ARCH_HAS_NPC_REGISTER
- npc_code_offset = *os_context_npc_addr(context) - *os_context_register_addr(context, reg_CODE);
-#endif /* ARCH_HAS_NPC_REGISTER */
-
-#ifdef ARCH_HAS_LINK_REGISTER
- lr_code_offset =
- *os_context_lr_addr(context) -
- *os_context_register_addr(context, reg_CODE);
-#endif
-
- /* Scanvenge all boxed registers in the context. */
- for (i = 0; i < (sizeof(boxed_registers) / sizeof(int)); i++) {
- int index;
- lispobj foo;
-
- index = boxed_registers[i];
- foo = *os_context_register_addr(context, index);
- scavenge(&foo, 1);
- *os_context_register_addr(context, index) = foo;
-
- scavenge((lispobj*) &(*os_context_register_addr(context, index)), 1);
- }
-
-#ifdef reg_LIP
- /* Fix the LIP */
-
- /*
- * But what happens if lip_register_pair is -1? *os_context_register_addr on Solaris
- * (see solaris_register_address in solaris-os.c) will return
- * &context->uc_mcontext.gregs[2]. But gregs[2] is REG_nPC. Is
- * that what we really want? My guess is that that is not what we
- * want, so if lip_register_pair is -1, we don't touch reg_LIP at
- * all. But maybe it doesn't really matter if LIP is trashed?
- */
- if (lip_register_pair >= 0) {
- *os_context_register_addr(context, reg_LIP) =
- *os_context_register_addr(context, lip_register_pair) + lip_offset;
- }
-#endif /* reg_LIP */
-
- /* Fix the PC if it was in from space */
- if (from_space_p(*os_context_pc_addr(context)))
- *os_context_pc_addr(context) = *os_context_register_addr(context, reg_CODE) + pc_code_offset;
-
-#ifdef ARCH_HAS_LINK_REGISTER
- /* Fix the LR ditto; important if we're being called from
- * an assembly routine that expects to return using blr, otherwise
- * harmless */
- if (from_space_p(*os_context_lr_addr(context)))
- *os_context_lr_addr(context) =
- *os_context_register_addr(context, reg_CODE) + lr_code_offset;
-#endif
-
-#ifdef ARCH_HAS_NPC_REGISTER
- if (from_space_p(*os_context_npc_addr(context)))
- *os_context_npc_addr(context) = *os_context_register_addr(context, reg_CODE) + npc_code_offset;
-#endif /* ARCH_HAS_NPC_REGISTER */
-}
-
-void
-scavenge_interrupt_contexts(void)
-{
- int i, index;
- os_context_t *context;
-
- struct thread *th=arch_os_get_current_thread();
-
- index = fixnum_value(SymbolValue(FREE_INTERRUPT_CONTEXT_INDEX,0));
-
-#if defined(DEBUG_PRINT_CONTEXT_INDEX)
- printf("Number of active contexts: %d\n", index);
-#endif
-
- for (i = 0; i < index; i++) {
- context = th->interrupt_contexts[i];
- scavenge_interrupt_context(context);
- }
-}
-
#endif
-#if defined(LISP_FEATURE_SB_THREAD)
+#if defined(LISP_FEATURE_SB_THREAD) && (defined(LISP_FEATURE_X86) || defined(LISP_FEATURE_X86_64))
static void
preserve_context_registers (os_context_t *c)
{
unsigned long bytes_freed;
page_index_t i;
unsigned long static_space_size;
-#if defined(LISP_FEATURE_X86) || defined(LISP_FEATURE_X86_64)
struct thread *th;
-#endif
+
gc_assert(generation <= HIGHEST_NORMAL_GENERATION);
/* The oldest generation can't be raised. */
/* Initialize the weak pointer list. */
weak_pointers = NULL;
-#ifdef LUTEX_WIDETAG
- unmark_lutexes(generation);
-#endif
-
/* When a generation is not being raised it is transported to a
* temporary generation (NUM_GENERATIONS), and lowered when
* done. Set up this new generation. There should be no pages
}
}
}
+#else
+ /* Non-x86oid systems don't have "conservative roots" as such, but
+ * the same mechanism is used for objects pinned for use by alien
+ * code. */
+ for_each_thread(th) {
+ lispobj pin_list = SymbolTlValue(PINNED_OBJECTS,th);
+ while (pin_list != NIL) {
+ struct cons *list_entry =
+ (struct cons *)native_pointer(pin_list);
+ preserve_pointer(list_entry->car);
+ pin_list = list_entry->cdr;
+ }
+ }
#endif
-#ifdef QSHOW
+#if QSHOW
if (gencgc_verbose > 1) {
long num_dont_move_pages = count_dont_move_pages();
fprintf(stderr,
"/non-movable pages due to conservative pointers = %d (%d bytes)\n",
num_dont_move_pages,
- num_dont_move_pages * PAGE_BYTES);
+ npage_bytes(num_dont_move_pages));
}
#endif
* If not x86, we need to scavenge the interrupt context(s) and the
* control stack.
*/
- scavenge_interrupt_contexts();
- scavenge_control_stack();
+ {
+ struct thread *th;
+ for_each_thread(th) {
+ scavenge_interrupt_contexts(th);
+ scavenge_control_stack(th);
+ }
+
+ /* Scrub the unscavenged control stack space, so that we can't run
+ * into any stale pointers in a later GC (this is done by the
+ * stop-for-gc handler in the other threads). */
+ scrub_control_stack();
+ }
#endif
/* Scavenge the Lisp functions of the interrupt handlers, taking
scavenge((lispobj *) th->binding_stack_start,len);
#ifdef LISP_FEATURE_SB_THREAD
/* do the tls as well */
- len=fixnum_value(SymbolValue(FREE_TLS_INDEX,0)) -
+ len=(SymbolValue(FREE_TLS_INDEX,0) >> WORD_SHIFT) -
(sizeof (struct thread))/(sizeof (lispobj));
scavenge((lispobj *) (th+1),len);
#endif
/* As a check re-scavenge the newspace once; no new objects should
* be found. */
{
- long old_bytes_allocated = bytes_allocated;
- long bytes_allocated;
+ os_vm_size_t old_bytes_allocated = bytes_allocated;
+ os_vm_size_t bytes_allocated;
/* Start with a full scavenge. */
scavenge_newspace_generation_one_scan(new_space);
generations[generation].alloc_large_unboxed_start_page = 0;
if (generation >= verify_gens) {
- if (gencgc_verbose)
+ if (gencgc_verbose) {
SHOW("verifying");
+ }
verify_gc();
verify_dynamic_space();
}
else
++generations[generation].num_gc;
-#ifdef LUTEX_WIDETAG
- reap_lutexes(generation);
- if (raise)
- move_lutexes(generation, generation+1);
-#endif
}
/* Update last_free_page, then SymbolValue(ALLOCATION_POINTER). */
page_index_t last_page = -1, i;
for (i = 0; i < last_free_page; i++)
- if ((page_table[i].allocated != FREE_PAGE_FLAG)
- && (page_table[i].bytes_used != 0))
+ if (page_allocated_p(i) && (page_table[i].bytes_used != 0))
last_page = i;
last_free_page = last_page+1;
- set_alloc_pointer((lispobj)(((char *)heap_base) + last_free_page*PAGE_BYTES));
+ set_alloc_pointer((lispobj)(page_address(last_free_page)));
return 0; /* dummy value: return something ... */
}
static void
-remap_free_pages (page_index_t from, page_index_t to)
+remap_page_range (page_index_t from, page_index_t to)
+{
+ /* There's a mysterious Solaris/x86 problem with using mmap
+ * tricks for memory zeroing. See sbcl-devel thread
+ * "Re: patch: standalone executable redux".
+ */
+#if defined(LISP_FEATURE_SUNOS)
+ zero_and_mark_pages(from, to);
+#else
+ const page_index_t
+ release_granularity = gencgc_release_granularity/GENCGC_CARD_BYTES,
+ release_mask = release_granularity-1,
+ end = to+1,
+ aligned_from = (from+release_mask)&~release_mask,
+ aligned_end = (end&~release_mask);
+
+ if (aligned_from < aligned_end) {
+ zero_pages_with_mmap(aligned_from, aligned_end-1);
+ if (aligned_from != from)
+ zero_and_mark_pages(from, aligned_from-1);
+ if (aligned_end != end)
+ zero_and_mark_pages(aligned_end, end-1);
+ } else {
+ zero_and_mark_pages(from, to);
+ }
+#endif
+}
+
+static void
+remap_free_pages (page_index_t from, page_index_t to, int forcibly)
{
page_index_t first_page, last_page;
+ if (forcibly)
+ return remap_page_range(from, to);
+
for (first_page = from; first_page <= to; first_page++) {
- if (page_table[first_page].allocated != FREE_PAGE_FLAG ||
- page_table[first_page].need_to_zero == 0) {
+ if (page_allocated_p(first_page) ||
+ (page_table[first_page].need_to_zero == 0))
continue;
- }
last_page = first_page + 1;
- while (page_table[last_page].allocated == FREE_PAGE_FLAG &&
- last_page < to &&
- page_table[last_page].need_to_zero == 1) {
+ while (page_free_p(last_page) &&
+ (last_page <= to) &&
+ (page_table[last_page].need_to_zero == 1))
last_page++;
- }
- /* There's a mysterious Solaris/x86 problem with using mmap
- * tricks for memory zeroing. See sbcl-devel thread
- * "Re: patch: standalone executable redux".
- */
-#if defined(LISP_FEATURE_SUNOS)
- zero_pages(first_page, last_page-1);
-#else
- zero_pages_with_mmap(first_page, last_page-1);
-#endif
+ remap_page_range(first_page, last_page-1);
first_page = last_page;
}
static page_index_t high_water_mark = 0;
FSHOW((stderr, "/entering collect_garbage(%d)\n", last_gen));
+ log_generation_stats(gc_logfile, "=== GC Start ===");
gc_active_p = 1;
}
if (gencgc_verbose > 1)
- print_generation_stats(0);
+ print_generation_stats();
do {
/* Collect the generation. */
} else {
raise =
(gen < last_gen)
- || (generations[gen].num_gc >= generations[gen].trigger_age);
+ || (generations[gen].num_gc >= generations[gen].number_of_gcs_before_promotion);
}
if (gencgc_verbose > 1) {
if (gencgc_verbose > 1) {
FSHOW((stderr, "GC of generation %d finished:\n", gen));
- print_generation_stats(0);
+ print_generation_stats();
}
gen++;
&& raise
&& (generations[gen].bytes_allocated
> generations[gen].gc_trigger)
- && (gen_av_mem_age(gen)
- > generations[gen].min_av_mem_age))));
+ && (generation_average_age(gen)
+ > generations[gen].minimum_age_before_gc))));
/* Now if gen-1 was raised all generations before gen are empty.
* If it wasn't raised then all generations before gen-1 are empty.
if (gen > small_generation_limit) {
if (last_free_page > high_water_mark)
high_water_mark = last_free_page;
- remap_free_pages(0, high_water_mark);
+ remap_free_pages(0, high_water_mark, 0);
high_water_mark = 0;
}
gc_active_p = 0;
+ log_generation_stats(gc_logfile, "=== GC End ===");
SHOW("returning from collect_garbage");
}
void
gc_free_heap(void)
{
- page_index_t page;
+ page_index_t page, last_page;
- if (gencgc_verbose > 1)
+ if (gencgc_verbose > 1) {
SHOW("entering gc_free_heap");
+ }
for (page = 0; page < page_table_pages; page++) {
/* Skip free pages which should already be zero filled. */
- if (page_table[page].allocated != FREE_PAGE_FLAG) {
+ if (page_allocated_p(page)) {
void *page_start, *addr;
+ for (last_page = page;
+ (last_page < page_table_pages) && page_allocated_p(last_page);
+ last_page++) {
+ /* Mark the page free. The other slots are assumed invalid
+ * when it is a FREE_PAGE_FLAG and bytes_used is 0 and it
+ * should not be write-protected -- except that the
+ * generation is used for the current region but it sets
+ * that up. */
+ page_table[page].allocated = FREE_PAGE_FLAG;
+ page_table[page].bytes_used = 0;
+ page_table[page].write_protected = 0;
+ }
- /* Mark the page free. The other slots are assumed invalid
- * when it is a FREE_PAGE_FLAG and bytes_used is 0 and it
- * should not be write-protected -- except that the
- * generation is used for the current region but it sets
- * that up. */
- page_table[page].allocated = FREE_PAGE_FLAG;
- page_table[page].bytes_used = 0;
-
-#ifndef LISP_FEATURE_WIN32 /* Pages already zeroed on win32? Not sure about this change. */
- /* Zero the page. */
+#ifndef LISP_FEATURE_WIN32 /* Pages already zeroed on win32? Not sure
+ * about this change. */
page_start = (void *)page_address(page);
-
- /* First, remove any write-protection. */
- os_protect(page_start, PAGE_BYTES, OS_VM_PROT_ALL);
- page_table[page].write_protected = 0;
-
- os_invalidate(page_start,PAGE_BYTES);
- addr = os_validate(page_start,PAGE_BYTES);
- if (addr == NULL || addr != page_start) {
- lose("gc_free_heap: page moved, 0x%08x ==> 0x%08x\n",
- page_start,
- addr);
- }
-#else
- page_table[page].write_protected = 0;
+ os_protect(page_start, npage_bytes(last_page-page), OS_VM_PROT_ALL);
+ remap_free_pages(page, last_page-1, 1);
+ page = last_page-1;
#endif
} else if (gencgc_zero_check_during_free_heap) {
/* Double-check that the page is zero filled. */
long *page_start;
page_index_t i;
- gc_assert(page_table[page].allocated == FREE_PAGE_FLAG);
+ gc_assert(page_free_p(page));
gc_assert(page_table[page].bytes_used == 0);
page_start = (long *)page_address(page);
- for (i=0; i<1024; i++) {
+ for (i=0; i<GENCGC_CARD_BYTES/sizeof(long); i++) {
if (page_start[i] != 0) {
lose("free region not zero at %x\n", page_start + i);
}
generations[page].gc_trigger = 2000000;
generations[page].num_gc = 0;
generations[page].cum_sum_bytes_allocated = 0;
- generations[page].lutexes = NULL;
}
if (gencgc_verbose > 1)
- print_generation_stats(0);
+ print_generation_stats();
/* Initialize gc_alloc(). */
gc_alloc_generation = 0;
if (verify_after_free_heap) {
/* Check whether purify has left any bad pointers. */
- if (gencgc_verbose)
- SHOW("checking after free_heap\n");
+ FSHOW((stderr, "checking after free_heap\n"));
verify_gc();
}
}
/* Compute the number of pages needed for the dynamic space.
* Dynamic space size should be aligned on page size. */
- page_table_pages = dynamic_space_size/PAGE_BYTES;
- gc_assert(dynamic_space_size == (size_t) page_table_pages*PAGE_BYTES);
-
+ page_table_pages = dynamic_space_size/GENCGC_CARD_BYTES;
+ gc_assert(dynamic_space_size == npage_bytes(page_table_pages));
+
+ /* Default nursery size to 5% of the total dynamic space size,
+ * min 1Mb. */
+ bytes_consed_between_gcs = dynamic_space_size/(os_vm_size_t)20;
+ if (bytes_consed_between_gcs < (1024*1024))
+ bytes_consed_between_gcs = 1024*1024;
+
+ /* The page_table must be allocated using "calloc" to initialize
+ * the page structures correctly. There used to be a separate
+ * initialization loop (now commented out; see below) but that was
+ * unnecessary and did hurt startup time. */
page_table = calloc(page_table_pages, sizeof(struct page));
gc_assert(page_table);
scavtab[WEAK_POINTER_WIDETAG] = scav_weak_pointer;
transother[SIMPLE_ARRAY_WIDETAG] = trans_boxed_large;
-#ifdef LUTEX_WIDETAG
- scavtab[LUTEX_WIDETAG] = scav_lutex;
- transother[LUTEX_WIDETAG] = trans_lutex;
- sizetab[LUTEX_WIDETAG] = size_lutex;
-#endif
-
heap_base = (void*)DYNAMIC_SPACE_START;
- /* Initialize each page structure. */
- for (i = 0; i < page_table_pages; i++) {
- /* Initialize all pages as free. */
- page_table[i].allocated = FREE_PAGE_FLAG;
- page_table[i].bytes_used = 0;
-
- /* Pages are not write-protected at startup. */
- page_table[i].write_protected = 0;
+ /* The page structures are initialized implicitly when page_table
+ * is allocated with "calloc" above. Formerly we had the following
+ * explicit initialization here (comments converted to C99 style
+ * for readability as C's block comments don't nest):
+ *
+ * // Initialize each page structure.
+ * for (i = 0; i < page_table_pages; i++) {
+ * // Initialize all pages as free.
+ * page_table[i].allocated = FREE_PAGE_FLAG;
+ * page_table[i].bytes_used = 0;
+ *
+ * // Pages are not write-protected at startup.
+ * page_table[i].write_protected = 0;
+ * }
+ *
+ * Without this loop the image starts up much faster when dynamic
+ * space is large -- which it is on 64-bit platforms already by
+ * default -- and when "calloc" for large arrays is implemented
+ * using copy-on-write of a page of zeroes -- which it is at least
+ * on Linux. In this case the pages that page_table_pages is stored
+ * in are mapped and cleared not before the corresponding part of
+ * dynamic space is used. For example, this saves clearing 16 MB of
+ * memory at startup if the page size is 4 KB and the size of
+ * dynamic space is 4 GB.
+ * FREE_PAGE_FLAG must be 0 for this to work correctly which is
+ * asserted below: */
+ {
+ /* Compile time assertion: If triggered, declares an array
+ * of dimension -1 forcing a syntax error. The intent of the
+ * assignment is to avoid an "unused variable" warning. */
+ char assert_free_page_flag_0[(FREE_PAGE_FLAG) ? -1 : 1];
+ assert_free_page_flag_0[0] = assert_free_page_flag_0[0];
}
bytes_allocated = 0;
generations[i].num_gc = 0;
generations[i].cum_sum_bytes_allocated = 0;
/* the tune-able parameters */
- generations[i].bytes_consed_between_gc = 2000000;
- generations[i].trigger_age = 1;
- generations[i].min_av_mem_age = 0.75;
- generations[i].lutexes = NULL;
+ generations[i].bytes_consed_between_gc = bytes_consed_between_gcs;
+ generations[i].number_of_gcs_before_promotion = 1;
+ generations[i].minimum_age_before_gc = 0.75;
}
/* Initialize gc_alloc. */
gencgc_pickup_dynamic(void)
{
page_index_t page = 0;
- long alloc_ptr = get_alloc_pointer();
+ void *alloc_ptr = (void *)get_alloc_pointer();
lispobj *prev=(lispobj *)page_address(page);
generation_index_t gen = PSEUDO_STATIC_GENERATION;
-
do {
lispobj *first,*ptr= (lispobj *)page_address(page);
- page_table[page].allocated = BOXED_PAGE_FLAG;
- page_table[page].gen = gen;
- page_table[page].bytes_used = PAGE_BYTES;
- page_table[page].large_object = 0;
- page_table[page].write_protected = 0;
- page_table[page].write_protected_cleared = 0;
- page_table[page].dont_move = 0;
- page_table[page].need_to_zero = 1;
+
+ if (!gencgc_partial_pickup || page_allocated_p(page)) {
+ /* It is possible, though rare, for the saved page table
+ * to contain free pages below alloc_ptr. */
+ page_table[page].gen = gen;
+ page_table[page].bytes_used = GENCGC_CARD_BYTES;
+ page_table[page].large_object = 0;
+ page_table[page].write_protected = 0;
+ page_table[page].write_protected_cleared = 0;
+ page_table[page].dont_move = 0;
+ page_table[page].need_to_zero = 1;
+ }
if (!gencgc_partial_pickup) {
+ page_table[page].allocated = BOXED_PAGE_FLAG;
first=gc_search_space(prev,(ptr+2)-prev,ptr);
- if(ptr == first) prev=ptr;
- page_table[page].first_object_offset =
- (void *)prev - page_address(page);
+ if(ptr == first)
+ prev=ptr;
+ page_table[page].region_start_offset =
+ page_address(page) - (void *)prev;
}
page++;
- } while ((long)page_address(page) < alloc_ptr);
-
-#ifdef LUTEX_WIDETAG
- /* Lutexes have been registered in generation 0 by coreparse, and
- * need to be moved to the right one manually.
- */
- move_lutexes(0, PSEUDO_STATIC_GENERATION);
-#endif
+ } while (page_address(page) < alloc_ptr);
last_free_page = page;
- generations[gen].bytes_allocated = PAGE_BYTES*page;
- bytes_allocated = PAGE_BYTES*page;
+ generations[gen].bytes_allocated = npage_bytes(page);
+ bytes_allocated = npage_bytes(page);
gc_alloc_update_all_page_tables();
write_protect_generation_pages(gen);
{
gencgc_pickup_dynamic();
}
-
-
\f
/* alloc(..) is the external interface for memory allocation. It
* The check for a GC trigger is only performed when the current
* region is full, so in most cases it's not needed. */
-lispobj *
-alloc(long nbytes)
+static inline lispobj *
+general_alloc_internal(long nbytes, int page_type_flag, struct alloc_region *region,
+ struct thread *thread)
{
- struct thread *thread=arch_os_get_current_thread();
- struct alloc_region *region=
-#ifdef LISP_FEATURE_SB_THREAD
- thread ? &(thread->alloc_region) : &boxed_region;
-#else
- &boxed_region;
-#endif
#ifndef LISP_FEATURE_WIN32
lispobj alloc_signal;
#endif
gc_assert((((unsigned long)region->free_pointer & LOWTAG_MASK) == 0)
&& ((nbytes & LOWTAG_MASK) == 0));
-#if 0
- if(all_threads)
- /* there are a few places in the C code that allocate data in the
- * heap before Lisp starts. This is before interrupts are enabled,
- * so we don't need to check for pseudo-atomic */
-#ifdef LISP_FEATURE_SB_THREAD
- if(!get_psuedo_atomic_atomic(th)) {
- register u32 fs;
- fprintf(stderr, "fatal error in thread 0x%x, tid=%ld\n",
- th,th->os_thread);
- __asm__("movl %fs,%0" : "=r" (fs) : );
- fprintf(stderr, "fs is %x, th->tls_cookie=%x \n",
- debug_get_fs(),th->tls_cookie);
- lose("If you see this message before 2004.01.31, mail details to sbcl-devel\n");
- }
-#else
- gc_assert(get_pseudo_atomic_atomic(th));
-#endif
-#endif
+ /* Must be inside a PA section. */
+ gc_assert(get_pseudo_atomic_atomic(thread));
/* maybe we can do this quickly ... */
new_free_pointer = region->free_pointer + nbytes;
return(new_obj); /* yup */
}
- /* we have to go the long way around, it seems. Check whether
- * we should GC in the near future
+ /* 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) {
- gc_assert(get_pseudo_atomic_atomic(thread));
/* Don't flood the system with interrupts if the need to gc is
* already noted. This can happen for example when SUB-GC
* allocates or after a gc triggered in a WITHOUT-GCING. */
/* set things up so that GC happens when we finish the PA
* section */
SetSymbolValue(GC_PENDING,T,thread);
- if (SymbolValue(GC_INHIBIT,thread) == NIL)
- set_pseudo_atomic_interrupted(thread);
+ if (SymbolValue(GC_INHIBIT,thread) == NIL) {
+ set_pseudo_atomic_interrupted(thread);
+#ifdef LISP_FEATURE_PPC
+ /* PPC calls alloc() from a trap or from pa_alloc(),
+ * look up the most context if it's from a trap. */
+ {
+ os_context_t *context =
+ thread->interrupt_data->allocation_trap_context;
+ maybe_save_gc_mask_and_block_deferrables
+ (context ? os_context_sigmask_addr(context) : NULL);
+ }
+#else
+ maybe_save_gc_mask_and_block_deferrables(NULL);
+#endif
+ }
}
}
- new_obj = gc_alloc_with_region(nbytes,0,region,0);
+ new_obj = gc_alloc_with_region(nbytes, page_type_flag, region, 0);
#ifndef LISP_FEATURE_WIN32
alloc_signal = SymbolValue(ALLOC_SIGNAL,thread);
if ((alloc_signal & FIXNUM_TAG_MASK) == 0) {
if ((signed long) alloc_signal <= 0) {
-#ifdef LISP_FEATURE_SB_THREAD
- kill_thread_safely(thread->os_thread, SIGPROF);
-#else
+ SetSymbolValue(ALLOC_SIGNAL, T, thread);
raise(SIGPROF);
-#endif
} else {
SetSymbolValue(ALLOC_SIGNAL,
alloc_signal - (1 << N_FIXNUM_TAG_BITS),
return (new_obj);
}
+
+lispobj *
+general_alloc(long nbytes, int page_type_flag)
+{
+ struct thread *thread = arch_os_get_current_thread();
+ /* Select correct region, and call general_alloc_internal with it.
+ * For other then boxed allocation we must lock first, since the
+ * region is shared. */
+ if (BOXED_PAGE_FLAG & page_type_flag) {
+#ifdef LISP_FEATURE_SB_THREAD
+ struct alloc_region *region = (thread ? &(thread->alloc_region) : &boxed_region);
+#else
+ struct alloc_region *region = &boxed_region;
+#endif
+ return general_alloc_internal(nbytes, page_type_flag, region, thread);
+ } else if (UNBOXED_PAGE_FLAG == page_type_flag) {
+ lispobj * obj;
+ gc_assert(0 == thread_mutex_lock(&allocation_lock));
+ obj = general_alloc_internal(nbytes, page_type_flag, &unboxed_region, thread);
+ gc_assert(0 == thread_mutex_unlock(&allocation_lock));
+ return obj;
+ } else {
+ lose("bad page type flag: %d", page_type_flag);
+ }
+}
+
+lispobj *
+alloc(long nbytes)
+{
+ gc_assert(get_pseudo_atomic_atomic(arch_os_get_current_thread()));
+ return general_alloc(nbytes, BOXED_PAGE_FLAG);
+}
\f
/*
* shared support for the OS-dependent signal handlers which
* catch GENCGC-related write-protect violations
*/
-
void unhandled_sigmemoryfault(void* addr);
/* Depending on which OS we're running under, different signals might
{
page_index_t page_index = find_page_index(fault_addr);
-#ifdef QSHOW_SIGNALS
+#if QSHOW_SIGNALS
FSHOW((stderr, "heap WP violation? fault_addr=%x, page_index=%d\n",
fault_addr, page_index));
#endif
return 0;
} else {
+ int ret;
+ ret = thread_mutex_lock(&free_pages_lock);
+ gc_assert(ret == 0);
if (page_table[page_index].write_protected) {
/* Unprotect the page. */
- os_protect(page_address(page_index), PAGE_BYTES, OS_VM_PROT_ALL);
+ os_protect(page_address(page_index), GENCGC_CARD_BYTES, OS_VM_PROT_ALL);
page_table[page_index].write_protected_cleared = 1;
page_table[page_index].write_protected = 0;
} else {
*/
if(page_table[page_index].write_protected_cleared != 1)
lose("fault in heap page %d not marked as write-protected\nboxed_region.first_page: %d, boxed_region.last_page %d\n",
- page_index, boxed_region.first_page, boxed_region.last_page);
+ page_index, boxed_region.first_page,
+ boxed_region.last_page);
}
+ ret = thread_mutex_unlock(&free_pages_lock);
+ gc_assert(ret == 0);
/* Don't worry, we can handle it. */
return 1;
}
/* Flush the alloc regions updating the tables. */
struct thread *th;
for_each_thread(th)
- gc_alloc_update_page_tables(0, &th->alloc_region);
- gc_alloc_update_page_tables(1, &unboxed_region);
- gc_alloc_update_page_tables(0, &boxed_region);
+ gc_alloc_update_page_tables(BOXED_PAGE_FLAG, &th->alloc_region);
+ gc_alloc_update_page_tables(UNBOXED_PAGE_FLAG, &unboxed_region);
+ gc_alloc_update_page_tables(BOXED_PAGE_FLAG, &boxed_region);
}
void
page_index_t i;
for (i = 0; i < last_free_page; i++) {
- if (page_table[i].allocated == FREE_PAGE_FLAG) {
+ if (page_free_p(i)) {
#ifdef READ_PROTECT_FREE_PAGES
os_protect(page_address(i),
- PAGE_BYTES,
+ GENCGC_CARD_BYTES,
OS_VM_PROT_ALL);
#endif
zero_pages(i, i);
* function being set to the value of the static symbol
* SB!VM:RESTART-LISP-FUNCTION */
void
-gc_and_save(char *filename, int prepend_runtime)
+gc_and_save(char *filename, boolean prepend_runtime,
+ boolean save_runtime_options,
+ boolean compressed, int compression_level)
{
FILE *file;
void *runtime_bytes = NULL;
/* The dumper doesn't know that pages need to be zeroed before use. */
zero_all_free_pages();
save_to_filehandle(file, filename, SymbolValue(RESTART_LISP_FUNCTION,0),
- prepend_runtime);
+ prepend_runtime, save_runtime_options,
+ compressed ? compression_level : COMPRESSION_LEVEL_NONE);
/* Oops. Save still managed to fail. Since we've mangled the stack
* beyond hope, there's not much we can do.
* (beyond FUNCALLing RESTART_LISP_FUNCTION, but I suspect that's