/* Copyright (C) 2010 Ben Wing.
This file is part of XEmacs.
XEmacs 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 of the License, or (at your
option) any later version.
XEmacs 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 XEmacs. If not, see . */
/* Synched up with: Not in FSF. */
/* Debugging hooks for malloc. */
/* These hooks work with gmalloc to catch allocation errors.
In particular, the following is trapped:
* Freeing the same pointer twice.
* Trying to free a pointer not returned by malloc.
* Trying to realloc a pointer not returned by malloc.
In addition, every word of every block freed is set to 0xDEADBEEF
(-559038737). This causes many uses of freed storage to be trapped or
recognized.
When you use this, the storage used by the last FREE_QUEUE_LIMIT
calls to free() is not recycled. When you call free for the Nth
time, the (N - FREE_QUEUE_LIMIT)'th block is actually recycled.
For these last FREE_QUEUE_LIMIT calls to free() a backtrace is
saved showing where it was called from. The function
find_backtrace() is provided here to be called from GDB with a
pointer (such as would be passed to free()) as argument, e.g.
(gdb) p/a *find_backtrace (0x234000). If SAVE_ARGS is defined,
the first three arguments to each function are saved as well as the
return addresses.
If UNMAPPED_FREE is defined, instead of setting every word of freed
storage to 0xDEADBEEF, every call to malloc goes on its own page(s).
When free() is called, the block is read and write protected. This
is very useful when debugging, since it usually generates a bus error
when the DEADBEEF hack might only cause some garbage to be printed.
However, this is too slow for everyday use, since it takes an enormous
number of pages.
Some other features that would be useful are:
* Checking for storage leaks.
This could be done by a GC-like facility that would scan the data
segment looking for pointers to allocated storage and tell you
about those that are no longer referenced. This could be invoked
at any time. Another possibility is to report on what allocated
storage is still in use when the process is exited. Typically
there will be a large amount, so this might not be very useful.
*/
#ifdef emacs
#include
#include "lisp.h"
#else
void *malloc (size_t);
#endif
#if !defined(HAVE_LIBMCHECK)
#include
#include "hash.h"
#ifdef UNMAPPED_FREE
#include
#include
#define ROUND_UP_TO_PAGE(i) (((i) + PAGEOFFSET) & PAGEMASK)
#endif
#include
/* System function prototypes don't belong in C source files */
/* extern void free (void *); */
static struct hash_table *pointer_table;
extern void (*__free_hook) (void *);
extern void *(*__malloc_hook) (size_t);
static void *check_malloc (size_t);
typedef void (*fun_ptr) (void);
/* free_queue is not too useful without backtrace logging */
#define FREE_QUEUE_LIMIT 1
#define TRACE_LIMIT 20
typedef struct {
fun_ptr return_pc;
#ifdef SAVE_ARGS
void *arg[3];
#endif
} fun_entry;
typedef struct {
void *address;
unsigned long length;
} free_queue_entry;
static free_queue_entry free_queue[FREE_QUEUE_LIMIT];
static int current_free;
static int strict_free_check;
static void
check_free (void *ptr)
{
__free_hook = 0;
__malloc_hook = 0;
if (!pointer_table)
pointer_table = make_hash_table (max (100, FREE_QUEUE_LIMIT * 2));
if (ptr != 0)
{
long size;
#ifdef UNMAPPED_FREE
unsigned long rounded_up_size;
#endif
EMACS_INT present = (EMACS_INT) gethash (ptr, pointer_table,
(const void **)
(void *) &size);
if (!present)
{
/* This can only happen if you try to free something that didn't
come from malloc */
#if !defined(__linux__)
/* I originally wrote: "There's really no need to drop core."
I have seen the error of my ways. -slb */
assert (!strict_free_check);
#endif
printf("Freeing unmalloc'ed memory at %p\n", ptr);
__free_hook = check_free;
__malloc_hook = check_malloc;
goto end;
}
if (size < 0)
{
/* This happens when you free twice */
#if !defined(__linux__)
/* See above comment. */
assert (!strict_free_check);
#endif
printf("Freeing %p twice\n", ptr);
__free_hook = check_free;
__malloc_hook = check_malloc;
goto end;
}
puthash (ptr, (void *)-size, pointer_table);
#ifdef UNMAPPED_FREE
/* Round up size to an even number of pages. */
rounded_up_size = ROUND_UP_TO_PAGE (size);
/* Protect the pages freed from all access */
if (strict_free_check)
mprotect (ptr, rounded_up_size, PROT_NONE);
#else
/* Set every word in the block to 0xDEADBEEF */
if (strict_free_check)
{
unsigned long long_length = (size + (sizeof (long) - 1))
/ sizeof (long);
unsigned long i;
/* Not using the DEADBEEF_CONSTANT #define, since we don't know
* that allocation sizes will be multiples of eight. */
for (i = 0; i < long_length; i++)
((unsigned long *) ptr)[i] = 0xDEADBEEF;
}
#endif
free_queue[current_free].address = ptr;
free_queue[current_free].length = size;
current_free++;
if (current_free >= FREE_QUEUE_LIMIT)
current_free = 0;
/* Really free this if there's something there */
{
void *old = free_queue[current_free].address;
if (old)
{
#ifdef UNMAPPED_FREE
unsigned long old_len = free_queue[current_free].length;
mprotect (old, old_len, PROT_READ | PROT_WRITE | PROT_EXEC);
#endif
free (old);
remhash (old, pointer_table);
}
}
}
__free_hook = check_free;
__malloc_hook = check_malloc;
end:
return;
}
static void *
check_malloc (size_t size)
{
size_t rounded_up_size;
void *result;
__free_hook = 0;
__malloc_hook = 0;
if (size == 0)
{
result = 0;
goto end;
}
#ifdef UNMAPPED_FREE
/* Round up to an even number of pages. */
rounded_up_size = ROUND_UP_TO_PAGE (size);
#else
rounded_up_size = size;
#endif
result = malloc (rounded_up_size);
if (!pointer_table)
pointer_table = make_hash_table (FREE_QUEUE_LIMIT * 2);
puthash (result, (void *)size, pointer_table);
__free_hook = check_free;
__malloc_hook = check_malloc;
end:
return result;
}
extern void *(*__realloc_hook) (void *, size_t);
#ifdef MIN
#undef MIN
#endif
#define MIN(A, B) ((A) < (B) ? (A) : (B))
/* Don't optimize realloc */
static void *
check_realloc (void * ptr, size_t size)
{
EMACS_INT present;
size_t old_size;
void *result = malloc (size);
if (!ptr) return result;
present = (EMACS_INT) gethash (ptr, pointer_table, (const void **) &old_size);
if (!present)
{
/* This can only happen by reallocing a pointer that didn't
come from malloc. */
#if !defined(__linux__)
/* see comment in check_free(). */
ABORT ();
#endif
printf("Realloc'ing unmalloc'ed pointer at %p\n", ptr);
}
if (result == 0)
goto end;
memcpy (result, ptr, MIN (size, old_size));
free (ptr);
end:
return result;
}
void enable_strict_free_check (void);
void
enable_strict_free_check (void)
{
strict_free_check = 1;
}
void disable_strict_free_check (void);
void
disable_strict_free_check (void)
{
strict_free_check = 0;
}
/* Note: All BLOCK_INPUT stuff removed from this file because it's
completely gone in XEmacs */
static void *
block_input_malloc (size_t size);
static void
block_input_free (void* ptr)
{
__free_hook = 0;
__malloc_hook = 0;
free (ptr);
__free_hook = block_input_free;
__malloc_hook = block_input_malloc;
}
static void *
block_input_malloc (size_t size)
{
void* result;
__free_hook = 0;
__malloc_hook = 0;
result = malloc (size);
__free_hook = block_input_free;
__malloc_hook = block_input_malloc;
return result;
}
static void *
block_input_realloc (void* ptr, size_t size)
{
void* result;
__free_hook = 0;
__malloc_hook = 0;
__realloc_hook = 0;
result = realloc (ptr, size);
__free_hook = block_input_free;
__malloc_hook = block_input_malloc;
__realloc_hook = block_input_realloc;
return result;
}
#ifdef emacs
void disable_free_hook (void);
void
disable_free_hook (void)
{
__free_hook = block_input_free;
__malloc_hook = block_input_malloc;
__realloc_hook = block_input_realloc;
}
void
init_free_hook (void)
{
__free_hook = check_free;
__malloc_hook = check_malloc;
__realloc_hook = check_realloc;
current_free = 0;
strict_free_check = 1;
}
void really_free_one_entry (void *, int, int *);
DEFUN ("really-free", Freally_free, 0, 1, "P", /*
Actually free the storage held by the free() debug hook.
A no-op if the free hook is disabled.
*/
(UNUSED (arg)))
{
int count[2];
Lisp_Object lisp_count[2];
if ((__free_hook != 0) && pointer_table)
{
count[0] = 0;
count[1] = 0;
__free_hook = 0;
maphash ((maphash_function)really_free_one_entry,
pointer_table, (void *)&count);
memset (free_queue, 0, sizeof (free_queue_entry) * FREE_QUEUE_LIMIT);
current_free = 0;
__free_hook = check_free;
lisp_count[0] = make_fixnum (count[0]);
lisp_count[1] = make_fixnum (count[1]);
return Fcons (lisp_count[0], lisp_count[1]);
}
else
return Fcons (make_fixnum (0), make_fixnum (0));
}
void
really_free_one_entry (void *key, int contents, int *countp)
{
if (contents < 0)
{
free (key);
#ifdef UNMAPPED_FREE
mprotect (key, -contents, PROT_READ | PROT_WRITE | PROT_EXEC);
#endif
remhash (key, pointer_table);
countp[0]++;
countp[1] += -contents;
}
}
void
syms_of_free_hook (void)
{
DEFSUBR (Freally_free);
}
#else
void (*__free_hook)(void *) = check_free;
void *(*__malloc_hook)(size_t) = check_malloc;
void *(*__realloc_hook)(void *, size_t) = check_realloc;
#endif
#endif /* !defined(HAVE_LIBMCHECK) */
#if defined(DEBUG_INPUT_BLOCKING) || defined (DEBUG_GCPRO)
/* Note: There is no more input blocking in XEmacs */
typedef enum {
block_type, unblock_type, totally_type,
gcpro1_type, gcpro2_type, gcpro3_type, gcpro4_type, gcpro5_type,
ungcpro_type
} blocktype;
struct block_input_history_struct
{
char *file;
int line;
blocktype type;
int value;
};
typedef struct block_input_history_struct block_input_history;
#endif /* DEBUG_INPUT_BLOCKING || DEBUG_GCPRO */
#ifdef DEBUG_INPUT_BLOCKING
int blhistptr;
#define BLHISTLIMIT 1000
block_input_history blhist[BLHISTLIMIT];
note_block_input (char *file, int line)
{
note_block (file, line, block_type);
assert (interrupt_input_blocked <= 2);
}
note_unblock_input (char* file, int line)
{
note_block (file, line, unblock_type);
}
note_totally_unblocked (char* file, int line)
{
note_block (file, line, totally_type);
}
note_block (char *file, int line, blocktype type)
{
blhist[blhistptr].file = file;
blhist[blhistptr].line = line;
blhist[blhistptr].type = type;
blhist[blhistptr].value = interrupt_input_blocked;
blhistptr++;
if (blhistptr >= BLHISTLIMIT)
blhistptr = 0;
}
#endif /* DEBUG_INPUT_BLOCKING */
�
#ifdef DEBUG_GCPRO
int gcprohistptr;
#define GCPROHISTLIMIT 1000
block_input_history gcprohist[GCPROHISTLIMIT];
static void
log_gcpro (char *file, int line, struct gcpro *value, blocktype type)
{
if (type == ungcpro_type)
{
if (value == gcprolist) goto OK;
assert (gcprolist);
if (value == gcprolist->next) goto OK;
assert (gcprolist->next);
if (value == gcprolist->next->next) goto OK;
assert (gcprolist->next->next);
if (value == gcprolist->next->next->next) goto OK;
assert (gcprolist->next->next->next);
if (value == gcprolist->next->next->next->next) goto OK;
ABORT ();
OK:;
}
gcprohist[gcprohistptr].file = file;
gcprohist[gcprohistptr].line = line;
gcprohist[gcprohistptr].type = type;
gcprohist[gcprohistptr].value = (int) value;
gcprohistptr++;
if (gcprohistptr >= GCPROHISTLIMIT)
gcprohistptr = 0;
}
void
debug_gcpro1 (char *file, int line, struct gcpro *gcpro1, Lisp_Object *var)
{
gcpro1->next = gcprolist; gcpro1->var = var; gcpro1->nvars = 1;
gcprolist = gcpro1;
log_gcpro (file, line, gcpro1, gcpro1_type);
}
void
debug_gcpro2 (char *file, int line, struct gcpro *gcpro1, struct gcpro *gcpro2,
Lisp_Object *var1, Lisp_Object *var2)
{
gcpro1->next = gcprolist; gcpro1->var = var1; gcpro1->nvars = 1;
gcpro2->next = gcpro1; gcpro2->var = var2; gcpro2->nvars = 1;
gcprolist = gcpro2;
log_gcpro (file, line, gcpro2, gcpro2_type);
}
void
debug_gcpro3 (char *file, int line, struct gcpro *gcpro1, struct gcpro *gcpro2,
struct gcpro *gcpro3, Lisp_Object *var1, Lisp_Object *var2,
Lisp_Object *var3)
{
gcpro1->next = gcprolist; gcpro1->var = var1; gcpro1->nvars = 1;
gcpro2->next = gcpro1; gcpro2->var = var2; gcpro2->nvars = 1;
gcpro3->next = gcpro2; gcpro3->var = var3; gcpro3->nvars = 1;
gcprolist = gcpro3;
log_gcpro (file, line, gcpro3, gcpro3_type);
}
void
debug_gcpro4 (char *file, int line, struct gcpro *gcpro1, struct gcpro *gcpro2,
struct gcpro *gcpro3, struct gcpro *gcpro4, Lisp_Object *var1,
Lisp_Object *var2, Lisp_Object *var3, Lisp_Object *var4)
{
log_gcpro (file, line, gcpro4, gcpro4_type);
gcpro1->next = gcprolist; gcpro1->var = var1; gcpro1->nvars = 1;
gcpro2->next = gcpro1; gcpro2->var = var2; gcpro2->nvars = 1;
gcpro3->next = gcpro2; gcpro3->var = var3; gcpro3->nvars = 1;
gcpro4->next = gcpro3; gcpro4->var = var4; gcpro4->nvars = 1;
gcprolist = gcpro4;
}
void
debug_gcpro5 (char *file, int line, struct gcpro *gcpro1, struct gcpro *gcpro2,
struct gcpro *gcpro3, struct gcpro *gcpro4, struct gcpro *gcpro5,
Lisp_Object *var1, Lisp_Object *var2, Lisp_Object *var3,
Lisp_Object *var4, Lisp_Object *var5)
{
log_gcpro (file, line, gcpro5, gcpro5_type);
gcpro1->next = gcprolist; gcpro1->var = var1; gcpro1->nvars = 1;
gcpro2->next = gcpro1; gcpro2->var = var2; gcpro2->nvars = 1;
gcpro3->next = gcpro2; gcpro3->var = var3; gcpro3->nvars = 1;
gcpro4->next = gcpro3; gcpro4->var = var4; gcpro4->nvars = 1;
gcpro5->next = gcpro4; gcpro5->var = var5; gcpro5->nvars = 1;
gcprolist = gcpro5;
}
void
debug_ungcpro (char *file, int line, struct gcpro *gcpro1)
{
log_gcpro (file, line, gcpro1, ungcpro_type);
gcprolist = gcpro1->next;
}
/* To be called from the debugger */
void show_gcprohist (void);
void
show_gcprohist (void)
{
int i, j;
for (i = 0, j = gcprohistptr;
i < GCPROHISTLIMIT;
i++, j++)
{
if (j >= GCPROHISTLIMIT)
j = 0;
printf ("%3d %s %d %s 0x%x\n",
j, gcprohist[j].file, gcprohist[j].line,
(gcprohist[j].type == gcpro1_type ? "GCPRO1" :
gcprohist[j].type == gcpro2_type ? "GCPRO2" :
gcprohist[j].type == gcpro3_type ? "GCPRO3" :
gcprohist[j].type == gcpro4_type ? "GCPRO4" :
gcprohist[j].type == gcpro5_type ? "GCPRO5" :
gcprohist[j].type == ungcpro_type ? "UNGCPRO" : "???"),
gcprohist[j].value);
}
fflush (stdout);
}
#endif /* DEBUG_GCPRO */