gcc/gcc/ggc-common.c
Martin Liska 643e0a3087 Fix BITMAP identifier clash.
PR bootstrap/66471
	* mem-stats-traits.h (enum mem_alloc_origin): Add _ORIGIN suffix for
	all enum values in mem_alloc_origin.
	* alloc-pool.c (dump_alloc_pool_statistics): Use newly changed enum
	name.
	* alloc-pool.h (pool_allocator::pool_allocator): Likewise.
	* bitmap.c (bitmap_register): Likewise.
	(dump_bitmap_statistics): Likewise.
	* ggc-common.c (dump_ggc_loc_statistics): Likewise.
	(ggc_record_overhead): Likewise.
	* hash-map.h: Likewise.
	* hash-set.h: Likewise.
	* hash-table.c (void dump_hash_table_loc_statistics): Likewise.
	* hash-table.h: Likewise.
	* vec.c (vec_prefix::register_overhead): Likewise.
	(vec_prefix::release_overhead): Likewise.
	(dump_vec_loc_statistics): Likewise.

From-SVN: r224315
2015-06-10 07:57:34 +00:00

1019 lines
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/* Simple garbage collection for the GNU compiler.
Copyright (C) 1999-2015 Free Software Foundation, Inc.
This file is part of GCC.
GCC is free software; you can redistribute it and/or modify it under
the terms of the GNU General Public License as published by the Free
Software Foundation; either version 3, or (at your option) any later
version.
GCC is distributed in the hope that it will be useful, but WITHOUT ANY
WARRANTY; without even the implied warranty of MERCHANTABILITY or
FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License
for more details.
You should have received a copy of the GNU General Public License
along with GCC; see the file COPYING3. If not see
<http://www.gnu.org/licenses/>. */
/* Generic garbage collection (GC) functions and data, not specific to
any particular GC implementation. */
#include "config.h"
#include "system.h"
#include "coretypes.h"
#include "ggc-internal.h"
#include "diagnostic-core.h"
#include "params.h"
#include "hosthooks.h"
#include "hosthooks-def.h"
#include "plugin.h"
#include "timevar.h"
/* When set, ggc_collect will do collection. */
bool ggc_force_collect;
/* When true, protect the contents of the identifier hash table. */
bool ggc_protect_identifiers = true;
/* Statistics about the allocation. */
static ggc_statistics *ggc_stats;
struct traversal_state;
static int compare_ptr_data (const void *, const void *);
static void relocate_ptrs (void *, void *);
static void write_pch_globals (const struct ggc_root_tab * const *tab,
struct traversal_state *state);
/* Maintain global roots that are preserved during GC. */
/* This extra vector of dynamically registered root_tab-s is used by
ggc_mark_roots and gives the ability to dynamically add new GGC root
tables, for instance from some plugins; this vector is on the heap
since it is used by GGC internally. */
typedef const struct ggc_root_tab *const_ggc_root_tab_t;
static vec<const_ggc_root_tab_t> extra_root_vec;
/* Dynamically register a new GGC root table RT. This is useful for
plugins. */
void
ggc_register_root_tab (const struct ggc_root_tab* rt)
{
if (rt)
extra_root_vec.safe_push (rt);
}
/* Mark all the roots in the table RT. */
static void
ggc_mark_root_tab (const_ggc_root_tab_t rt)
{
size_t i;
for ( ; rt->base != NULL; rt++)
for (i = 0; i < rt->nelt; i++)
(*rt->cb) (*(void **) ((char *)rt->base + rt->stride * i));
}
/* Iterate through all registered roots and mark each element. */
void
ggc_mark_roots (void)
{
const struct ggc_root_tab *const *rt;
const_ggc_root_tab_t rtp, rti;
size_t i;
for (rt = gt_ggc_deletable_rtab; *rt; rt++)
for (rti = *rt; rti->base != NULL; rti++)
memset (rti->base, 0, rti->stride);
for (rt = gt_ggc_rtab; *rt; rt++)
ggc_mark_root_tab (*rt);
FOR_EACH_VEC_ELT (extra_root_vec, i, rtp)
ggc_mark_root_tab (rtp);
if (ggc_protect_identifiers)
ggc_mark_stringpool ();
gt_clear_caches ();
if (! ggc_protect_identifiers)
ggc_purge_stringpool ();
/* Some plugins may call ggc_set_mark from here. */
invoke_plugin_callbacks (PLUGIN_GGC_MARKING, NULL);
}
/* Allocate a block of memory, then clear it. */
void *
ggc_internal_cleared_alloc (size_t size, void (*f)(void *), size_t s, size_t n
MEM_STAT_DECL)
{
void *buf = ggc_internal_alloc (size, f, s, n PASS_MEM_STAT);
memset (buf, 0, size);
return buf;
}
/* Resize a block of memory, possibly re-allocating it. */
void *
ggc_realloc (void *x, size_t size MEM_STAT_DECL)
{
void *r;
size_t old_size;
if (x == NULL)
return ggc_internal_alloc (size PASS_MEM_STAT);
old_size = ggc_get_size (x);
if (size <= old_size)
{
/* Mark the unwanted memory as unaccessible. We also need to make
the "new" size accessible, since ggc_get_size returns the size of
the pool, not the size of the individually allocated object, the
size which was previously made accessible. Unfortunately, we
don't know that previously allocated size. Without that
knowledge we have to lose some initialization-tracking for the
old parts of the object. An alternative is to mark the whole
old_size as reachable, but that would lose tracking of writes
after the end of the object (by small offsets). Discard the
handle to avoid handle leak. */
VALGRIND_DISCARD (VALGRIND_MAKE_MEM_NOACCESS ((char *) x + size,
old_size - size));
VALGRIND_DISCARD (VALGRIND_MAKE_MEM_DEFINED (x, size));
return x;
}
r = ggc_internal_alloc (size PASS_MEM_STAT);
/* Since ggc_get_size returns the size of the pool, not the size of the
individually allocated object, we'd access parts of the old object
that were marked invalid with the memcpy below. We lose a bit of the
initialization-tracking since some of it may be uninitialized. */
VALGRIND_DISCARD (VALGRIND_MAKE_MEM_DEFINED (x, old_size));
memcpy (r, x, old_size);
/* The old object is not supposed to be used anymore. */
ggc_free (x);
return r;
}
void *
ggc_cleared_alloc_htab_ignore_args (size_t c ATTRIBUTE_UNUSED,
size_t n ATTRIBUTE_UNUSED)
{
gcc_assert (c * n == sizeof (struct htab));
return ggc_cleared_alloc<htab> ();
}
/* TODO: once we actually use type information in GGC, create a new tag
gt_gcc_ptr_array and use it for pointer arrays. */
void *
ggc_cleared_alloc_ptr_array_two_args (size_t c, size_t n)
{
gcc_assert (sizeof (PTR *) == n);
return ggc_cleared_vec_alloc<PTR *> (c);
}
/* These are for splay_tree_new_ggc. */
void *
ggc_splay_alloc (int sz, void *nl)
{
gcc_assert (!nl);
return ggc_internal_alloc (sz);
}
void
ggc_splay_dont_free (void * x ATTRIBUTE_UNUSED, void *nl)
{
gcc_assert (!nl);
}
/* Print statistics that are independent of the collector in use. */
#define SCALE(x) ((unsigned long) ((x) < 1024*10 \
? (x) \
: ((x) < 1024*1024*10 \
? (x) / 1024 \
: (x) / (1024*1024))))
#define LABEL(x) ((x) < 1024*10 ? ' ' : ((x) < 1024*1024*10 ? 'k' : 'M'))
void
ggc_print_common_statistics (FILE *stream ATTRIBUTE_UNUSED,
ggc_statistics *stats)
{
/* Set the pointer so that during collection we will actually gather
the statistics. */
ggc_stats = stats;
/* Then do one collection to fill in the statistics. */
ggc_collect ();
/* At present, we don't really gather any interesting statistics. */
/* Don't gather statistics any more. */
ggc_stats = NULL;
}
/* Functions for saving and restoring GCable memory to disk. */
struct ptr_data
{
void *obj;
void *note_ptr_cookie;
gt_note_pointers note_ptr_fn;
gt_handle_reorder reorder_fn;
size_t size;
void *new_addr;
};
#define POINTER_HASH(x) (hashval_t)((intptr_t)x >> 3)
/* Helper for hashing saving_htab. */
struct saving_hasher : typed_free_remove <ptr_data>
{
typedef ptr_data *value_type;
typedef void *compare_type;
static inline hashval_t hash (const ptr_data *);
static inline bool equal (const ptr_data *, const void *);
};
inline hashval_t
saving_hasher::hash (const ptr_data *p)
{
return POINTER_HASH (p->obj);
}
inline bool
saving_hasher::equal (const ptr_data *p1, const void *p2)
{
return p1->obj == p2;
}
static hash_table<saving_hasher> *saving_htab;
/* Register an object in the hash table. */
int
gt_pch_note_object (void *obj, void *note_ptr_cookie,
gt_note_pointers note_ptr_fn)
{
struct ptr_data **slot;
if (obj == NULL || obj == (void *) 1)
return 0;
slot = (struct ptr_data **)
saving_htab->find_slot_with_hash (obj, POINTER_HASH (obj), INSERT);
if (*slot != NULL)
{
gcc_assert ((*slot)->note_ptr_fn == note_ptr_fn
&& (*slot)->note_ptr_cookie == note_ptr_cookie);
return 0;
}
*slot = XCNEW (struct ptr_data);
(*slot)->obj = obj;
(*slot)->note_ptr_fn = note_ptr_fn;
(*slot)->note_ptr_cookie = note_ptr_cookie;
if (note_ptr_fn == gt_pch_p_S)
(*slot)->size = strlen ((const char *)obj) + 1;
else
(*slot)->size = ggc_get_size (obj);
return 1;
}
/* Register an object in the hash table. */
void
gt_pch_note_reorder (void *obj, void *note_ptr_cookie,
gt_handle_reorder reorder_fn)
{
struct ptr_data *data;
if (obj == NULL || obj == (void *) 1)
return;
data = (struct ptr_data *)
saving_htab->find_with_hash (obj, POINTER_HASH (obj));
gcc_assert (data && data->note_ptr_cookie == note_ptr_cookie);
data->reorder_fn = reorder_fn;
}
/* Handy state for the traversal functions. */
struct traversal_state
{
FILE *f;
struct ggc_pch_data *d;
size_t count;
struct ptr_data **ptrs;
size_t ptrs_i;
};
/* Callbacks for htab_traverse. */
int
ggc_call_count (ptr_data **slot, traversal_state *state)
{
struct ptr_data *d = *slot;
ggc_pch_count_object (state->d, d->obj, d->size,
d->note_ptr_fn == gt_pch_p_S);
state->count++;
return 1;
}
int
ggc_call_alloc (ptr_data **slot, traversal_state *state)
{
struct ptr_data *d = *slot;
d->new_addr = ggc_pch_alloc_object (state->d, d->obj, d->size,
d->note_ptr_fn == gt_pch_p_S);
state->ptrs[state->ptrs_i++] = d;
return 1;
}
/* Callback for qsort. */
static int
compare_ptr_data (const void *p1_p, const void *p2_p)
{
const struct ptr_data *const p1 = *(const struct ptr_data *const *)p1_p;
const struct ptr_data *const p2 = *(const struct ptr_data *const *)p2_p;
return (((size_t)p1->new_addr > (size_t)p2->new_addr)
- ((size_t)p1->new_addr < (size_t)p2->new_addr));
}
/* Callbacks for note_ptr_fn. */
static void
relocate_ptrs (void *ptr_p, void *state_p)
{
void **ptr = (void **)ptr_p;
struct traversal_state *state ATTRIBUTE_UNUSED
= (struct traversal_state *)state_p;
struct ptr_data *result;
if (*ptr == NULL || *ptr == (void *)1)
return;
result = (struct ptr_data *)
saving_htab->find_with_hash (*ptr, POINTER_HASH (*ptr));
gcc_assert (result);
*ptr = result->new_addr;
}
/* Write out, after relocation, the pointers in TAB. */
static void
write_pch_globals (const struct ggc_root_tab * const *tab,
struct traversal_state *state)
{
const struct ggc_root_tab *const *rt;
const struct ggc_root_tab *rti;
size_t i;
for (rt = tab; *rt; rt++)
for (rti = *rt; rti->base != NULL; rti++)
for (i = 0; i < rti->nelt; i++)
{
void *ptr = *(void **)((char *)rti->base + rti->stride * i);
struct ptr_data *new_ptr;
if (ptr == NULL || ptr == (void *)1)
{
if (fwrite (&ptr, sizeof (void *), 1, state->f)
!= 1)
fatal_error (input_location, "can%'t write PCH file: %m");
}
else
{
new_ptr = (struct ptr_data *)
saving_htab->find_with_hash (ptr, POINTER_HASH (ptr));
if (fwrite (&new_ptr->new_addr, sizeof (void *), 1, state->f)
!= 1)
fatal_error (input_location, "can%'t write PCH file: %m");
}
}
}
/* Hold the information we need to mmap the file back in. */
struct mmap_info
{
size_t offset;
size_t size;
void *preferred_base;
};
/* Write out the state of the compiler to F. */
void
gt_pch_save (FILE *f)
{
const struct ggc_root_tab *const *rt;
const struct ggc_root_tab *rti;
size_t i;
struct traversal_state state;
char *this_object = NULL;
size_t this_object_size = 0;
struct mmap_info mmi;
const size_t mmap_offset_alignment = host_hooks.gt_pch_alloc_granularity ();
gt_pch_save_stringpool ();
timevar_push (TV_PCH_PTR_REALLOC);
saving_htab = new hash_table<saving_hasher> (50000);
for (rt = gt_ggc_rtab; *rt; rt++)
for (rti = *rt; rti->base != NULL; rti++)
for (i = 0; i < rti->nelt; i++)
(*rti->pchw)(*(void **)((char *)rti->base + rti->stride * i));
/* Prepare the objects for writing, determine addresses and such. */
state.f = f;
state.d = init_ggc_pch ();
state.count = 0;
saving_htab->traverse <traversal_state *, ggc_call_count> (&state);
mmi.size = ggc_pch_total_size (state.d);
/* Try to arrange things so that no relocation is necessary, but
don't try very hard. On most platforms, this will always work,
and on the rest it's a lot of work to do better.
(The extra work goes in HOST_HOOKS_GT_PCH_GET_ADDRESS and
HOST_HOOKS_GT_PCH_USE_ADDRESS.) */
mmi.preferred_base = host_hooks.gt_pch_get_address (mmi.size, fileno (f));
ggc_pch_this_base (state.d, mmi.preferred_base);
state.ptrs = XNEWVEC (struct ptr_data *, state.count);
state.ptrs_i = 0;
saving_htab->traverse <traversal_state *, ggc_call_alloc> (&state);
timevar_pop (TV_PCH_PTR_REALLOC);
timevar_push (TV_PCH_PTR_SORT);
qsort (state.ptrs, state.count, sizeof (*state.ptrs), compare_ptr_data);
timevar_pop (TV_PCH_PTR_SORT);
/* Write out all the scalar variables. */
for (rt = gt_pch_scalar_rtab; *rt; rt++)
for (rti = *rt; rti->base != NULL; rti++)
if (fwrite (rti->base, rti->stride, 1, f) != 1)
fatal_error (input_location, "can%'t write PCH file: %m");
/* Write out all the global pointers, after translation. */
write_pch_globals (gt_ggc_rtab, &state);
/* Pad the PCH file so that the mmapped area starts on an allocation
granularity (usually page) boundary. */
{
long o;
o = ftell (state.f) + sizeof (mmi);
if (o == -1)
fatal_error (input_location, "can%'t get position in PCH file: %m");
mmi.offset = mmap_offset_alignment - o % mmap_offset_alignment;
if (mmi.offset == mmap_offset_alignment)
mmi.offset = 0;
mmi.offset += o;
}
if (fwrite (&mmi, sizeof (mmi), 1, state.f) != 1)
fatal_error (input_location, "can%'t write PCH file: %m");
if (mmi.offset != 0
&& fseek (state.f, mmi.offset, SEEK_SET) != 0)
fatal_error (input_location, "can%'t write padding to PCH file: %m");
ggc_pch_prepare_write (state.d, state.f);
#if defined ENABLE_VALGRIND_CHECKING && defined VALGRIND_GET_VBITS
vec<char> vbits = vNULL;
#endif
/* Actually write out the objects. */
for (i = 0; i < state.count; i++)
{
if (this_object_size < state.ptrs[i]->size)
{
this_object_size = state.ptrs[i]->size;
this_object = XRESIZEVAR (char, this_object, this_object_size);
}
#if defined ENABLE_VALGRIND_CHECKING && defined VALGRIND_GET_VBITS
/* obj might contain uninitialized bytes, e.g. in the trailing
padding of the object. Avoid warnings by making the memory
temporarily defined and then restoring previous state. */
int get_vbits = 0;
size_t valid_size = state.ptrs[i]->size;
if (__builtin_expect (RUNNING_ON_VALGRIND, 0))
{
if (vbits.length () < valid_size)
vbits.safe_grow (valid_size);
get_vbits = VALGRIND_GET_VBITS (state.ptrs[i]->obj,
vbits.address (), valid_size);
if (get_vbits == 3)
{
/* We assume that first part of obj is addressable, and
the rest is unaddressable. Find out where the boundary is
using binary search. */
size_t lo = 0, hi = valid_size;
while (hi > lo)
{
size_t mid = (lo + hi) / 2;
get_vbits = VALGRIND_GET_VBITS ((char *) state.ptrs[i]->obj
+ mid, vbits.address (),
1);
if (get_vbits == 3)
hi = mid;
else if (get_vbits == 1)
lo = mid + 1;
else
break;
}
if (get_vbits == 1 || get_vbits == 3)
{
valid_size = lo;
get_vbits = VALGRIND_GET_VBITS (state.ptrs[i]->obj,
vbits.address (),
valid_size);
}
}
if (get_vbits == 1)
VALGRIND_DISCARD (VALGRIND_MAKE_MEM_DEFINED (state.ptrs[i]->obj,
state.ptrs[i]->size));
}
#endif
memcpy (this_object, state.ptrs[i]->obj, state.ptrs[i]->size);
if (state.ptrs[i]->reorder_fn != NULL)
state.ptrs[i]->reorder_fn (state.ptrs[i]->obj,
state.ptrs[i]->note_ptr_cookie,
relocate_ptrs, &state);
state.ptrs[i]->note_ptr_fn (state.ptrs[i]->obj,
state.ptrs[i]->note_ptr_cookie,
relocate_ptrs, &state);
ggc_pch_write_object (state.d, state.f, state.ptrs[i]->obj,
state.ptrs[i]->new_addr, state.ptrs[i]->size,
state.ptrs[i]->note_ptr_fn == gt_pch_p_S);
if (state.ptrs[i]->note_ptr_fn != gt_pch_p_S)
memcpy (state.ptrs[i]->obj, this_object, state.ptrs[i]->size);
#if defined ENABLE_VALGRIND_CHECKING && defined VALGRIND_GET_VBITS
if (__builtin_expect (get_vbits == 1, 0))
{
(void) VALGRIND_SET_VBITS (state.ptrs[i]->obj, vbits.address (),
valid_size);
if (valid_size != state.ptrs[i]->size)
VALGRIND_DISCARD (VALGRIND_MAKE_MEM_NOACCESS ((char *)
state.ptrs[i]->obj
+ valid_size,
state.ptrs[i]->size
- valid_size));
}
#endif
}
#if defined ENABLE_VALGRIND_CHECKING && defined VALGRIND_GET_VBITS
vbits.release ();
#endif
ggc_pch_finish (state.d, state.f);
gt_pch_fixup_stringpool ();
XDELETE (state.ptrs);
XDELETE (this_object);
delete saving_htab;
saving_htab = NULL;
}
/* Read the state of the compiler back in from F. */
void
gt_pch_restore (FILE *f)
{
const struct ggc_root_tab *const *rt;
const struct ggc_root_tab *rti;
size_t i;
struct mmap_info mmi;
int result;
/* Delete any deletable objects. This makes ggc_pch_read much
faster, as it can be sure that no GCable objects remain other
than the ones just read in. */
for (rt = gt_ggc_deletable_rtab; *rt; rt++)
for (rti = *rt; rti->base != NULL; rti++)
memset (rti->base, 0, rti->stride);
/* Read in all the scalar variables. */
for (rt = gt_pch_scalar_rtab; *rt; rt++)
for (rti = *rt; rti->base != NULL; rti++)
if (fread (rti->base, rti->stride, 1, f) != 1)
fatal_error (input_location, "can%'t read PCH file: %m");
/* Read in all the global pointers, in 6 easy loops. */
for (rt = gt_ggc_rtab; *rt; rt++)
for (rti = *rt; rti->base != NULL; rti++)
for (i = 0; i < rti->nelt; i++)
if (fread ((char *)rti->base + rti->stride * i,
sizeof (void *), 1, f) != 1)
fatal_error (input_location, "can%'t read PCH file: %m");
if (fread (&mmi, sizeof (mmi), 1, f) != 1)
fatal_error (input_location, "can%'t read PCH file: %m");
result = host_hooks.gt_pch_use_address (mmi.preferred_base, mmi.size,
fileno (f), mmi.offset);
if (result < 0)
fatal_error (input_location, "had to relocate PCH");
if (result == 0)
{
if (fseek (f, mmi.offset, SEEK_SET) != 0
|| fread (mmi.preferred_base, mmi.size, 1, f) != 1)
fatal_error (input_location, "can%'t read PCH file: %m");
}
else if (fseek (f, mmi.offset + mmi.size, SEEK_SET) != 0)
fatal_error (input_location, "can%'t read PCH file: %m");
ggc_pch_read (f, mmi.preferred_base);
gt_pch_restore_stringpool ();
}
/* Default version of HOST_HOOKS_GT_PCH_GET_ADDRESS when mmap is not present.
Select no address whatsoever, and let gt_pch_save choose what it will with
malloc, presumably. */
void *
default_gt_pch_get_address (size_t size ATTRIBUTE_UNUSED,
int fd ATTRIBUTE_UNUSED)
{
return NULL;
}
/* Default version of HOST_HOOKS_GT_PCH_USE_ADDRESS when mmap is not present.
Allocate SIZE bytes with malloc. Return 0 if the address we got is the
same as base, indicating that the memory has been allocated but needs to
be read in from the file. Return -1 if the address differs, to relocation
of the PCH file would be required. */
int
default_gt_pch_use_address (void *base, size_t size, int fd ATTRIBUTE_UNUSED,
size_t offset ATTRIBUTE_UNUSED)
{
void *addr = xmalloc (size);
return (addr == base) - 1;
}
/* Default version of HOST_HOOKS_GT_PCH_GET_ADDRESS. Return the
alignment required for allocating virtual memory. Usually this is the
same as pagesize. */
size_t
default_gt_pch_alloc_granularity (void)
{
return getpagesize ();
}
#if HAVE_MMAP_FILE
/* Default version of HOST_HOOKS_GT_PCH_GET_ADDRESS when mmap is present.
We temporarily allocate SIZE bytes, and let the kernel place the data
wherever it will. If it worked, that's our spot, if not we're likely
to be in trouble. */
void *
mmap_gt_pch_get_address (size_t size, int fd)
{
void *ret;
ret = mmap (NULL, size, PROT_READ | PROT_WRITE, MAP_PRIVATE, fd, 0);
if (ret == (void *) MAP_FAILED)
ret = NULL;
else
munmap ((caddr_t) ret, size);
return ret;
}
/* Default version of HOST_HOOKS_GT_PCH_USE_ADDRESS when mmap is present.
Map SIZE bytes of FD+OFFSET at BASE. Return 1 if we succeeded at
mapping the data at BASE, -1 if we couldn't.
This version assumes that the kernel honors the START operand of mmap
even without MAP_FIXED if START through START+SIZE are not currently
mapped with something. */
int
mmap_gt_pch_use_address (void *base, size_t size, int fd, size_t offset)
{
void *addr;
/* We're called with size == 0 if we're not planning to load a PCH
file at all. This allows the hook to free any static space that
we might have allocated at link time. */
if (size == 0)
return -1;
addr = mmap ((caddr_t) base, size, PROT_READ | PROT_WRITE, MAP_PRIVATE,
fd, offset);
return addr == base ? 1 : -1;
}
#endif /* HAVE_MMAP_FILE */
#if !defined ENABLE_GC_CHECKING && !defined ENABLE_GC_ALWAYS_COLLECT
/* Modify the bound based on rlimits. */
static double
ggc_rlimit_bound (double limit)
{
#if defined(HAVE_GETRLIMIT)
struct rlimit rlim;
# if defined (RLIMIT_AS)
/* RLIMIT_AS is what POSIX says is the limit on mmap. Presumably
any OS which has RLIMIT_AS also has a working mmap that GCC will use. */
if (getrlimit (RLIMIT_AS, &rlim) == 0
&& rlim.rlim_cur != (rlim_t) RLIM_INFINITY
&& rlim.rlim_cur < limit)
limit = rlim.rlim_cur;
# elif defined (RLIMIT_DATA)
/* ... but some older OSs bound mmap based on RLIMIT_DATA, or we
might be on an OS that has a broken mmap. (Others don't bound
mmap at all, apparently.) */
if (getrlimit (RLIMIT_DATA, &rlim) == 0
&& rlim.rlim_cur != (rlim_t) RLIM_INFINITY
&& rlim.rlim_cur < limit
/* Darwin has this horribly bogus default setting of
RLIMIT_DATA, to 6144Kb. No-one notices because RLIMIT_DATA
appears to be ignored. Ignore such silliness. If a limit
this small was actually effective for mmap, GCC wouldn't even
start up. */
&& rlim.rlim_cur >= 8 * 1024 * 1024)
limit = rlim.rlim_cur;
# endif /* RLIMIT_AS or RLIMIT_DATA */
#endif /* HAVE_GETRLIMIT */
return limit;
}
/* Heuristic to set a default for GGC_MIN_EXPAND. */
static int
ggc_min_expand_heuristic (void)
{
double min_expand = physmem_total ();
/* Adjust for rlimits. */
min_expand = ggc_rlimit_bound (min_expand);
/* The heuristic is a percentage equal to 30% + 70%*(RAM/1GB), yielding
a lower bound of 30% and an upper bound of 100% (when RAM >= 1GB). */
min_expand /= 1024*1024*1024;
min_expand *= 70;
min_expand = MIN (min_expand, 70);
min_expand += 30;
return min_expand;
}
/* Heuristic to set a default for GGC_MIN_HEAPSIZE. */
static int
ggc_min_heapsize_heuristic (void)
{
double phys_kbytes = physmem_total ();
double limit_kbytes = ggc_rlimit_bound (phys_kbytes * 2);
phys_kbytes /= 1024; /* Convert to Kbytes. */
limit_kbytes /= 1024;
/* The heuristic is RAM/8, with a lower bound of 4M and an upper
bound of 128M (when RAM >= 1GB). */
phys_kbytes /= 8;
#if defined(HAVE_GETRLIMIT) && defined (RLIMIT_RSS)
/* Try not to overrun the RSS limit while doing garbage collection.
The RSS limit is only advisory, so no margin is subtracted. */
{
struct rlimit rlim;
if (getrlimit (RLIMIT_RSS, &rlim) == 0
&& rlim.rlim_cur != (rlim_t) RLIM_INFINITY)
phys_kbytes = MIN (phys_kbytes, rlim.rlim_cur / 1024);
}
# endif
/* Don't blindly run over our data limit; do GC at least when the
*next* GC would be within 20Mb of the limit or within a quarter of
the limit, whichever is larger. If GCC does hit the data limit,
compilation will fail, so this tries to be conservative. */
limit_kbytes = MAX (0, limit_kbytes - MAX (limit_kbytes / 4, 20 * 1024));
limit_kbytes = (limit_kbytes * 100) / (110 + ggc_min_expand_heuristic ());
phys_kbytes = MIN (phys_kbytes, limit_kbytes);
phys_kbytes = MAX (phys_kbytes, 4 * 1024);
phys_kbytes = MIN (phys_kbytes, 128 * 1024);
return phys_kbytes;
}
#endif
void
init_ggc_heuristics (void)
{
#if !defined ENABLE_GC_CHECKING && !defined ENABLE_GC_ALWAYS_COLLECT
set_default_param_value (GGC_MIN_EXPAND, ggc_min_expand_heuristic ());
set_default_param_value (GGC_MIN_HEAPSIZE, ggc_min_heapsize_heuristic ());
#endif
}
/* GGC memory usage. */
struct ggc_usage: public mem_usage
{
/* Default constructor. */
ggc_usage (): m_freed (0), m_collected (0), m_overhead (0) {}
/* Constructor. */
ggc_usage (size_t allocated, size_t times, size_t peak,
size_t freed, size_t collected, size_t overhead)
: mem_usage (allocated, times, peak),
m_freed (freed), m_collected (collected), m_overhead (overhead) {}
/* Comparison operator. */
inline bool
operator< (const ggc_usage &second) const
{
return (get_balance () == second.get_balance () ?
(m_peak == second.m_peak ? m_times < second.m_times
: m_peak < second.m_peak)
: get_balance () < second.get_balance ());
}
/* Register overhead of ALLOCATED and OVERHEAD bytes. */
inline void
register_overhead (size_t allocated, size_t overhead)
{
m_allocated += allocated;
m_overhead += overhead;
m_times++;
}
/* Release overhead of SIZE bytes. */
inline void
release_overhead (size_t size)
{
m_freed += size;
}
/* Sum the usage with SECOND usage. */
ggc_usage
operator+ (const ggc_usage &second)
{
return ggc_usage (m_allocated + second.m_allocated,
m_times + second.m_times,
m_peak + second.m_peak,
m_freed + second.m_freed,
m_collected + second.m_collected,
m_overhead + second.m_overhead);
}
/* Dump usage with PREFIX, where TOTAL is sum of all rows. */
inline void
dump (const char *prefix, ggc_usage &total) const
{
long balance = get_balance ();
fprintf (stderr,
"%-48s %10li:%5.1f%%%10li:%5.1f%%"
"%10li:%5.1f%%%10li:%5.1f%%%10li\n",
prefix, (long)m_collected,
get_percent (m_collected, total.m_collected),
(long)m_freed, get_percent (m_freed, total.m_freed),
(long)balance, get_percent (balance, total.get_balance ()),
(long)m_overhead, get_percent (m_overhead, total.m_overhead),
(long)m_times);
}
/* Dump usage coupled to LOC location, where TOTAL is sum of all rows. */
inline void
dump (mem_location *loc, ggc_usage &total) const
{
char *location_string = loc->to_string ();
dump (location_string, total);
free (location_string);
}
/* Dump footer. */
inline void
dump_footer ()
{
print_dash_line ();
dump ("Total", *this);
print_dash_line ();
}
/* Get balance which is GGC allocation leak. */
inline long
get_balance () const
{
return m_allocated + m_overhead - m_collected - m_freed;
}
typedef std::pair<mem_location *, ggc_usage *> mem_pair_t;
/* Compare wrapper used by qsort method. */
static int
compare (const void *first, const void *second)
{
const mem_pair_t f = *(const mem_pair_t *)first;
const mem_pair_t s = *(const mem_pair_t *)second;
return (*f.second) < (*s.second);
}
/* Compare rows in final GGC summary dump. */
static int
compare_final (const void *first, const void *second)
{
typedef std::pair<mem_location *, ggc_usage *> mem_pair_t;
const ggc_usage *f = ((const mem_pair_t *)first)->second;
const ggc_usage *s = ((const mem_pair_t *)second)->second;
size_t a = f->m_allocated + f->m_overhead - f->m_freed;
size_t b = s->m_allocated + s->m_overhead - s->m_freed;
return a == b ? 0 : (a < b ? 1 : -1);
}
/* Dump header with NAME. */
static inline void
dump_header (const char *name)
{
fprintf (stderr, "%-48s %11s%17s%17s%16s%17s\n", name, "Garbage", "Freed",
"Leak", "Overhead", "Times");
print_dash_line ();
}
/* Freed memory in bytes. */
size_t m_freed;
/* Collected memory in bytes. */
size_t m_collected;
/* Overhead memory in bytes. */
size_t m_overhead;
};
/* GCC memory description. */
static mem_alloc_description<ggc_usage> ggc_mem_desc;
/* Dump per-site memory statistics. */
void
dump_ggc_loc_statistics (bool final)
{
if (! GATHER_STATISTICS)
return;
ggc_force_collect = true;
ggc_collect ();
ggc_mem_desc.dump (GGC_ORIGIN, final ? ggc_usage::compare_final : NULL);
ggc_force_collect = false;
}
/* Record ALLOCATED and OVERHEAD bytes to descriptor NAME:LINE (FUNCTION). */
void
ggc_record_overhead (size_t allocated, size_t overhead, void *ptr MEM_STAT_DECL)
{
ggc_usage *usage = ggc_mem_desc.register_descriptor (ptr, GGC_ORIGIN, false
FINAL_PASS_MEM_STAT);
ggc_mem_desc.register_object_overhead (usage, allocated + overhead, ptr);
usage->register_overhead (allocated, overhead);
}
/* Notice that the pointer has been freed. */
void
ggc_free_overhead (void *ptr)
{
ggc_mem_desc.release_object_overhead (ptr);
}
/* After live values has been marked, walk all recorded pointers and see if
they are still live. */
void
ggc_prune_overhead_list (void)
{
typedef hash_map<const void *, std::pair<ggc_usage *, size_t > > map_t;
map_t::iterator it = ggc_mem_desc.m_reverse_object_map->begin ();
for (; it != ggc_mem_desc.m_reverse_object_map->end (); ++it)
if (!ggc_marked_p ((*it).first))
(*it).second.first->m_collected += (*it).second.second;
delete ggc_mem_desc.m_reverse_object_map;
ggc_mem_desc.m_reverse_object_map = new map_t (13, false, false);
}