/* * Copyright 1988, 1989 Hans-J. Boehm, Alan J. Demers * Copyright (c) 1991-1994 by Xerox Corporation. All rights reserved. * Copyright (c) 1996 by Silicon Graphics. All rights reserved. * Copyright (c) 2000 by Hewlett-Packard Company. All rights reserved. * Copyright (c) 2009-2021 Ivan Maidanski * * THIS MATERIAL IS PROVIDED AS IS, WITH ABSOLUTELY NO WARRANTY EXPRESSED * OR IMPLIED. ANY USE IS AT YOUR OWN RISK. * * Permission is hereby granted to use or copy this program * for any purpose, provided the above notices are retained on all copies. * Permission to modify the code and to distribute modified code is granted, * provided the above notices are retained, and a notice that the code was * modified is included with the above copyright notice.
*/
#include"private/gc_priv.h" #include"gc_inline.h"/* for GC_malloc_kind */
/* * These are extra allocation routines which are likely to be less * frequently used than those in malloc.c. They are separate in the * hope that the .o file will be excluded from statically linked * executables. We should probably break this up further.
*/
#include <stdio.h> #include <string.h>
#ifndef MSWINCE # include <errno.h> #endif
/* Some externally visible but unadvertised variables to allow access to */ /* free lists from inlined allocators without including gc_priv.h */ /* or introducing dependencies on internal data structure layouts. */ #include"private/gc_alloc_ptrs.h" void ** const GC_objfreelist_ptr = GC_objfreelist; void ** const GC_aobjfreelist_ptr = GC_aobjfreelist; void ** const GC_uobjfreelist_ptr = GC_uobjfreelist; # ifdef GC_ATOMIC_UNCOLLECTABLE void ** const GC_auobjfreelist_ptr = GC_auobjfreelist; # endif
GC_API GC_ATTR_MALLOC void * GC_CALL GC_generic_or_special_malloc(size_t lb, int knd)
{ switch(knd) { case PTRFREE: case NORMAL: return GC_malloc_kind(lb, knd); case UNCOLLECTABLE: # ifdef GC_ATOMIC_UNCOLLECTABLE case AUNCOLLECTABLE: # endif return GC_generic_malloc_uncollectable(lb, knd); default: return GC_generic_malloc(lb, knd);
}
}
/* Change the size of the block pointed to by p to contain at least */ /* lb bytes. The object may be (and quite likely will be) moved. */ /* The kind (e.g. atomic) is the same as that of the old. */ /* Shrinking of large blocks is not implemented well. */
GC_API void * GC_CALL GC_realloc(void * p, size_t lb)
{ struct hblk * h;
hdr * hhdr; void * result; # ifdefined(_FORTIFY_SOURCE) && defined(__GNUC__) && !defined(__clang__) volatile/* Use cleared_p instead of p as a workaround to avoid */ /* passing alloc_size(lb) attribute associated with p */ /* to memset (including memset call inside GC_free). */ # endif
word cleared_p = (word)p;
size_t sz; /* Current size in bytes */
size_t orig_sz; /* Original sz in bytes */ int obj_kind;
if (p == 0) return(GC_malloc(lb)); /* Required by ANSI */ if (0 == lb) /* and p != NULL */ { # ifndef IGNORE_FREE
GC_free(p); # endif return NULL;
}
h = HBLKPTR(p);
hhdr = HDR(h);
sz = (size_t)hhdr->hb_sz;
obj_kind = hhdr -> hb_obj_kind;
orig_sz = sz;
if (sz > MAXOBJBYTES) { /* Round it up to the next whole heap block */
word descr = GC_obj_kinds[obj_kind].ok_descriptor;
sz = (sz + HBLKSIZE-1) & ~HBLKMASK; if (GC_obj_kinds[obj_kind].ok_relocate_descr)
descr += sz; /* GC_realloc might be changing the block size while */ /* GC_reclaim_block or GC_clear_hdr_marks is examining it. */ /* The change to the size field is benign, in that GC_reclaim */ /* (and GC_clear_hdr_marks) would work correctly with either */ /* value, since we are not changing the number of objects in */ /* the block. But seeing a half-updated value (though unlikely */ /* to occur in practice) could be probably bad. */ /* Using unordered atomic accesses on the size and hb_descr */ /* fields would solve the issue. (The alternate solution might */ /* be to initially overallocate large objects, so we do not */ /* have to adjust the size in GC_realloc, if they still fit. */ /* But that is probably more expensive, since we may end up */ /* scanning a bunch of zeros during GC.) */ # ifdef AO_HAVE_store
GC_STATIC_ASSERT(sizeof(hhdr->hb_sz) == sizeof(AO_t));
AO_store((volatile AO_t *)&hhdr->hb_sz, (AO_t)sz);
AO_store((volatile AO_t *)&hhdr->hb_descr, (AO_t)descr); # else
{
DCL_LOCK_STATE;
/* Allocate memory such that only pointers to near the */ /* beginning of the object are considered. */ /* We avoid holding allocation lock while we clear the memory. */
GC_API GC_ATTR_MALLOC void * GC_CALL
GC_generic_malloc_ignore_off_page(size_t lb, int k)
{ void *result;
size_t lg;
size_t lb_rounded;
word n_blocks;
GC_bool init;
DCL_LOCK_STATE;
if (SMALL_OBJ(lb)) return GC_generic_malloc(lb, k);
GC_ASSERT(k < MAXOBJKINDS);
lg = ROUNDED_UP_GRANULES(lb);
lb_rounded = GRANULES_TO_BYTES(lg);
n_blocks = OBJ_SZ_TO_BLOCKS(lb_rounded);
init = GC_obj_kinds[k].ok_init; if (EXPECT(get_have_errors(), FALSE))
GC_print_all_errors();
GC_INVOKE_FINALIZERS();
GC_DBG_COLLECT_AT_MALLOC(lb);
LOCK();
result = (ptr_t)GC_alloc_large(ADD_SLOP(lb), k, IGNORE_OFF_PAGE); if (NULL == result) {
GC_oom_func oom_fn = GC_oom_fn;
UNLOCK(); return (*oom_fn)(lb);
}
if (GC_debugging_started) {
BZERO(result, n_blocks * HBLKSIZE);
} else { # ifdef THREADS /* Clear any memory that might be used for GC descriptors */ /* before we release the lock. */
((word *)result)[0] = 0;
((word *)result)[1] = 0;
((word *)result)[GRANULES_TO_WORDS(lg)-1] = 0;
((word *)result)[GRANULES_TO_WORDS(lg)-2] = 0; # endif
}
GC_bytes_allocd += lb_rounded;
UNLOCK(); if (init && !GC_debugging_started) {
BZERO(result, n_blocks * HBLKSIZE);
} return(result);
}
/* Increment GC_bytes_allocd from code that doesn't have direct access */ /* to GC_arrays. */ void GC_CALL GC_incr_bytes_allocd(size_t n)
{
GC_bytes_allocd += n;
}
/* The same for GC_bytes_freed. */ void GC_CALL GC_incr_bytes_freed(size_t n)
{
GC_bytes_freed += n;
}
# ifdef PARALLEL_MARK STATICvolatile AO_t GC_bytes_allocd_tmp = 0; /* Number of bytes of memory allocated since */ /* we released the GC lock. Instead of */ /* reacquiring the GC lock just to add this in, */ /* we add it in the next time we reacquire */ /* the lock. (Atomically adding it doesn't */ /* work, since we would have to atomically */ /* update it in GC_malloc, which is too */ /* expensive.) */ # endif /* PARALLEL_MARK */
/* Return a list of 1 or more objects of the indicated size, linked */ /* through the first word in the object. This has the advantage that */ /* it acquires the allocation lock only once, and may greatly reduce */ /* time wasted contending for the allocation lock. Typical usage would */ /* be in a thread that requires many items of the same size. It would */ /* keep its own free list in thread-local storage, and call */ /* GC_malloc_many or friends to replenish it. (We do not round up */ /* object sizes, since a call indicates the intention to consume many */ /* objects of exactly this size.) */ /* We assume that the size is a multiple of GRANULE_BYTES. */ /* We return the free-list by assigning it to *result, since it is */ /* not safe to return, e.g. a linked list of pointer-free objects, */ /* since the collector would not retain the entire list if it were */ /* invoked just as we were returning. */ /* Note that the client should usually clear the link field. */
GC_API void GC_CALL GC_generic_malloc_many(size_t lb, int k, void **result)
{ void *op; void *p; void **opp;
size_t lw; /* Length in words. */
size_t lg; /* Length in granules. */
signed_word my_bytes_allocd = 0; struct obj_kind * ok = &(GC_obj_kinds[k]); struct hblk ** rlh;
DCL_LOCK_STATE;
GC_ASSERT(lb != 0 && (lb & (GRANULE_BYTES-1)) == 0); /* Currently a single object is always allocated if manual VDB. */ /* TODO: GC_dirty should be called for each linked object (but */ /* the last one) to support multiple objects allocation. */ if (!SMALL_OBJ(lb) || GC_manual_vdb) {
op = GC_generic_malloc(lb, k); if (EXPECT(0 != op, TRUE))
obj_link(op) = 0;
*result = op; # ifndef GC_DISABLE_INCREMENTAL if (GC_manual_vdb && GC_is_heap_ptr(result)) {
GC_dirty_inner(result);
REACHABLE_AFTER_DIRTY(op);
} # endif return;
}
GC_ASSERT(k < MAXOBJKINDS);
lw = BYTES_TO_WORDS(lb);
lg = BYTES_TO_GRANULES(lb); if (EXPECT(get_have_errors(), FALSE))
GC_print_all_errors();
GC_INVOKE_FINALIZERS();
GC_DBG_COLLECT_AT_MALLOC(lb); if (!EXPECT(GC_is_initialized, TRUE)) GC_init();
LOCK(); /* Do our share of marking work */ if (GC_incremental && !GC_dont_gc) {
ENTER_GC();
GC_collect_a_little_inner(1);
EXIT_GC();
} /* First see if we can reclaim a page of objects waiting to be */ /* reclaimed. */
rlh = ok -> ok_reclaim_list; if (rlh != NULL) { struct hblk * hbp;
hdr * hhdr;
while ((hbp = rlh[lg]) != NULL) {
hhdr = HDR(hbp);
rlh[lg] = hhdr -> hb_next;
GC_ASSERT(hhdr -> hb_sz == lb);
hhdr -> hb_last_reclaimed = (unsignedshort) GC_gc_no; # ifdef PARALLEL_MARK if (GC_parallel) {
signed_word my_bytes_allocd_tmp =
(signed_word)AO_load(&GC_bytes_allocd_tmp);
GC_ASSERT(my_bytes_allocd_tmp >= 0); /* We only decrement it while holding the GC lock. */ /* Thus we can't accidentally adjust it down in more */ /* than one thread simultaneously. */
if (my_bytes_allocd_tmp != 0) {
(void)AO_fetch_and_add(&GC_bytes_allocd_tmp,
(AO_t)(-my_bytes_allocd_tmp));
GC_bytes_allocd += my_bytes_allocd_tmp;
}
GC_acquire_mark_lock();
++ GC_fl_builder_count;
UNLOCK();
GC_release_mark_lock();
} # endif
op = GC_reclaim_generic(hbp, hhdr, lb,
ok -> ok_init, 0, &my_bytes_allocd); if (op != 0) { # ifdef PARALLEL_MARK if (GC_parallel) {
*result = op;
(void)AO_fetch_and_add(&GC_bytes_allocd_tmp,
(AO_t)my_bytes_allocd);
GC_acquire_mark_lock();
-- GC_fl_builder_count; if (GC_fl_builder_count == 0) GC_notify_all_builder(); # ifdef THREAD_SANITIZER
GC_release_mark_lock();
LOCK();
GC_bytes_found += my_bytes_allocd;
UNLOCK(); # else
GC_bytes_found += my_bytes_allocd; /* The result may be inaccurate. */
GC_release_mark_lock(); # endif
(void) GC_clear_stack(0); return;
} # endif /* We also reclaimed memory, so we need to adjust */ /* that count. */
GC_bytes_found += my_bytes_allocd;
GC_bytes_allocd += my_bytes_allocd; goto out;
} # ifdef PARALLEL_MARK if (GC_parallel) {
GC_acquire_mark_lock();
-- GC_fl_builder_count; if (GC_fl_builder_count == 0) GC_notify_all_builder();
GC_release_mark_lock();
LOCK(); /* GC lock is needed for reclaim list access. We */ /* must decrement fl_builder_count before reacquiring */ /* the lock. Hopefully this path is rare. */
rlh = ok -> ok_reclaim_list; /* reload rlh after locking */ if (NULL == rlh) break;
} # endif
}
} /* Next try to use prefix of global free list if there is one. */ /* We don't refill it, but we need to use it up before allocating */ /* a new block ourselves. */
opp = &(GC_obj_kinds[k].ok_freelist[lg]); if ( (op = *opp) != 0 ) {
*opp = 0;
my_bytes_allocd = 0; for (p = op; p != 0; p = obj_link(p)) {
my_bytes_allocd += lb; if ((word)my_bytes_allocd >= HBLKSIZE) {
*opp = obj_link(p);
obj_link(p) = 0; break;
}
}
GC_bytes_allocd += my_bytes_allocd; goto out;
} /* Next try to allocate a new block worth of objects of this size. */
{ struct hblk *h = GC_allochblk(lb, k, 0); if (h /* != NULL */) { /* CPPCHECK */ if (IS_UNCOLLECTABLE(k)) GC_set_hdr_marks(HDR(h));
GC_bytes_allocd += HBLKSIZE - HBLKSIZE % lb; # ifdef PARALLEL_MARK if (GC_parallel) {
GC_acquire_mark_lock();
++ GC_fl_builder_count;
UNLOCK();
GC_release_mark_lock();
op = GC_build_fl(h, lw,
(ok -> ok_init || GC_debugging_started), 0);
/* As a last attempt, try allocating a single object. Note that */ /* this may trigger a collection or expand the heap. */
op = GC_generic_malloc_inner(lb, k); if (0 != op) obj_link(op) = 0;
/* Note that the "atomic" version of this would be unsafe, since the */ /* links would not be seen by the collector. */
GC_API GC_ATTR_MALLOC void * GC_CALL GC_malloc_many(size_t lb)
{ void *result;
/* Add EXTRA_BYTES and round up to a multiple of a granule. */
lb = SIZET_SAT_ADD(lb, EXTRA_BYTES + GRANULE_BYTES - 1)
& ~(GRANULE_BYTES - 1);
/* Debug version is tricky and currently missing. */
GC_API GC_ATTR_MALLOC void * GC_CALL GC_memalign(size_t align, size_t lb)
{
size_t new_lb;
size_t offset;
ptr_t result;
if (align <= GRANULE_BYTES) return GC_malloc(lb); if (align >= HBLKSIZE/2 || lb >= HBLKSIZE/2) { if (align > HBLKSIZE) { return (*GC_get_oom_fn())(LONG_MAX-1024); /* Fail */
} return GC_malloc(lb <= HBLKSIZE? HBLKSIZE : lb); /* Will be HBLKSIZE aligned. */
} /* We could also try to make sure that the real rounded-up object size */ /* is a multiple of align. That would be correct up to HBLKSIZE. */
new_lb = SIZET_SAT_ADD(lb, align - 1);
result = (ptr_t)GC_malloc(new_lb); /* It is OK not to check result for NULL as in that case */ /* GC_memalign returns NULL too since (0 + 0 % align) is 0. */
offset = (word)result % align; if (offset != 0) {
offset = align - offset; if (!GC_all_interior_pointers) {
GC_STATIC_ASSERT(VALID_OFFSET_SZ <= HBLKSIZE);
GC_ASSERT(offset < VALID_OFFSET_SZ);
GC_register_displacement(offset);
}
}
result += offset;
GC_ASSERT((word)result % align == 0); return result;
}
/* This one exists largely to redirect posix_memalign for leaks finding. */
GC_API int GC_CALL GC_posix_memalign(void **memptr, size_t align, size_t lb)
{ /* Check alignment properly. */
size_t align_minus_one = align - 1; /* to workaround a cppcheck warning */ if (align < sizeof(void *) || (align_minus_one & align) != 0) { # ifdef MSWINCE return ERROR_INVALID_PARAMETER; # else return EINVAL; # endif
}
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