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1 732 jeremybenn
/*
2
  This is a version (aka dlmalloc) of malloc/free/realloc written by
3
  Doug Lea and released to the public domain, as explained at
4
  http://creativecommons.org/licenses/publicdomain.  Send questions,
5
  comments, complaints, performance data, etc to dl@cs.oswego.edu
6
 
7
* Version 2.8.3 Thu Sep 22 11:16:15 2005  Doug Lea  (dl at gee)
8
 
9
   Note: There may be an updated version of this malloc obtainable at
10
           ftp://gee.cs.oswego.edu/pub/misc/malloc.c
11
         Check before installing!
12
 
13
* Quickstart
14
 
15
  This library is all in one file to simplify the most common usage:
16
  ftp it, compile it (-O3), and link it into another program. All of
17
  the compile-time options default to reasonable values for use on
18
  most platforms.  You might later want to step through various
19
  compile-time and dynamic tuning options.
20
 
21
  For convenience, an include file for code using this malloc is at:
22
     ftp://gee.cs.oswego.edu/pub/misc/malloc-2.8.3.h
23
  You don't really need this .h file unless you call functions not
24
  defined in your system include files.  The .h file contains only the
25
  excerpts from this file needed for using this malloc on ANSI C/C++
26
  systems, so long as you haven't changed compile-time options about
27
  naming and tuning parameters.  If you do, then you can create your
28
  own malloc.h that does include all settings by cutting at the point
29
  indicated below. Note that you may already by default be using a C
30
  library containing a malloc that is based on some version of this
31
  malloc (for example in linux). You might still want to use the one
32
  in this file to customize settings or to avoid overheads associated
33
  with library versions.
34
 
35
* Vital statistics:
36
 
37
  Supported pointer/size_t representation:       4 or 8 bytes
38
       size_t MUST be an unsigned type of the same width as
39
       pointers. (If you are using an ancient system that declares
40
       size_t as a signed type, or need it to be a different width
41
       than pointers, you can use a previous release of this malloc
42
       (e.g. 2.7.2) supporting these.)
43
 
44
  Alignment:                                     8 bytes (default)
45
       This suffices for nearly all current machines and C compilers.
46
       However, you can define MALLOC_ALIGNMENT to be wider than this
47
       if necessary (up to 128bytes), at the expense of using more space.
48
 
49
  Minimum overhead per allocated chunk:   4 or  8 bytes (if 4byte sizes)
50
                                          8 or 16 bytes (if 8byte sizes)
51
       Each malloced chunk has a hidden word of overhead holding size
52
       and status information, and additional cross-check word
53
       if FOOTERS is defined.
54
 
55
  Minimum allocated size: 4-byte ptrs:  16 bytes    (including overhead)
56
                          8-byte ptrs:  32 bytes    (including overhead)
57
 
58
       Even a request for zero bytes (i.e., malloc(0)) returns a
59
       pointer to something of the minimum allocatable size.
60
       The maximum overhead wastage (i.e., number of extra bytes
61
       allocated than were requested in malloc) is less than or equal
62
       to the minimum size, except for requests >= mmap_threshold that
63
       are serviced via mmap(), where the worst case wastage is about
64
       32 bytes plus the remainder from a system page (the minimal
65
       mmap unit); typically 4096 or 8192 bytes.
66
 
67
  Security: static-safe; optionally more or less
68
       The "security" of malloc refers to the ability of malicious
69
       code to accentuate the effects of errors (for example, freeing
70
       space that is not currently malloc'ed or overwriting past the
71
       ends of chunks) in code that calls malloc.  This malloc
72
       guarantees not to modify any memory locations below the base of
73
       heap, i.e., static variables, even in the presence of usage
74
       errors.  The routines additionally detect most improper frees
75
       and reallocs.  All this holds as long as the static bookkeeping
76
       for malloc itself is not corrupted by some other means.  This
77
       is only one aspect of security -- these checks do not, and
78
       cannot, detect all possible programming errors.
79
 
80
       If FOOTERS is defined nonzero, then each allocated chunk
81
       carries an additional check word to verify that it was malloced
82
       from its space.  These check words are the same within each
83
       execution of a program using malloc, but differ across
84
       executions, so externally crafted fake chunks cannot be
85
       freed. This improves security by rejecting frees/reallocs that
86
       could corrupt heap memory, in addition to the checks preventing
87
       writes to statics that are always on.  This may further improve
88
       security at the expense of time and space overhead.  (Note that
89
       FOOTERS may also be worth using with MSPACES.)
90
 
91
       By default detected errors cause the program to abort (calling
92
       "abort()"). You can override this to instead proceed past
93
       errors by defining PROCEED_ON_ERROR.  In this case, a bad free
94
       has no effect, and a malloc that encounters a bad address
95
       caused by user overwrites will ignore the bad address by
96
       dropping pointers and indices to all known memory. This may
97
       be appropriate for programs that should continue if at all
98
       possible in the face of programming errors, although they may
99
       run out of memory because dropped memory is never reclaimed.
100
 
101
       If you don't like either of these options, you can define
102
       CORRUPTION_ERROR_ACTION and USAGE_ERROR_ACTION to do anything
103
       else. And if if you are sure that your program using malloc has
104
       no errors or vulnerabilities, you can define INSECURE to 1,
105
       which might (or might not) provide a small performance improvement.
106
 
107
  Thread-safety: NOT thread-safe unless USE_LOCKS defined
108
       When USE_LOCKS is defined, each public call to malloc, free,
109
       etc is surrounded with either a pthread mutex or a win32
110
       spinlock (depending on WIN32). This is not especially fast, and
111
       can be a major bottleneck.  It is designed only to provide
112
       minimal protection in concurrent environments, and to provide a
113
       basis for extensions.  If you are using malloc in a concurrent
114
       program, consider instead using ptmalloc, which is derived from
115
       a version of this malloc. (See http://www.malloc.de).
116
 
117
  System requirements: Any combination of MORECORE and/or MMAP/MUNMAP
118
       This malloc can use unix sbrk or any emulation (invoked using
119
       the CALL_MORECORE macro) and/or mmap/munmap or any emulation
120
       (invoked using CALL_MMAP/CALL_MUNMAP) to get and release system
121
       memory.  On most unix systems, it tends to work best if both
122
       MORECORE and MMAP are enabled.  On Win32, it uses emulations
123
       based on VirtualAlloc. It also uses common C library functions
124
       like memset.
125
 
126
  Compliance: I believe it is compliant with the Single Unix Specification
127
       (See http://www.unix.org). Also SVID/XPG, ANSI C, and probably
128
       others as well.
129
 
130
* Overview of algorithms
131
 
132
  This is not the fastest, most space-conserving, most portable, or
133
  most tunable malloc ever written. However it is among the fastest
134
  while also being among the most space-conserving, portable and
135
  tunable.  Consistent balance across these factors results in a good
136
  general-purpose allocator for malloc-intensive programs.
137
 
138
  In most ways, this malloc is a best-fit allocator. Generally, it
139
  chooses the best-fitting existing chunk for a request, with ties
140
  broken in approximately least-recently-used order. (This strategy
141
  normally maintains low fragmentation.) However, for requests less
142
  than 256bytes, it deviates from best-fit when there is not an
143
  exactly fitting available chunk by preferring to use space adjacent
144
  to that used for the previous small request, as well as by breaking
145
  ties in approximately most-recently-used order. (These enhance
146
  locality of series of small allocations.)  And for very large requests
147
  (>= 256Kb by default), it relies on system memory mapping
148
  facilities, if supported.  (This helps avoid carrying around and
149
  possibly fragmenting memory used only for large chunks.)
150
 
151
  All operations (except malloc_stats and mallinfo) have execution
152
  times that are bounded by a constant factor of the number of bits in
153
  a size_t, not counting any clearing in calloc or copying in realloc,
154
  or actions surrounding MORECORE and MMAP that have times
155
  proportional to the number of non-contiguous regions returned by
156
  system allocation routines, which is often just 1.
157
 
158
  The implementation is not very modular and seriously overuses
159
  macros. Perhaps someday all C compilers will do as good a job
160
  inlining modular code as can now be done by brute-force expansion,
161
  but now, enough of them seem not to.
162
 
163
  Some compilers issue a lot of warnings about code that is
164
  dead/unreachable only on some platforms, and also about intentional
165
  uses of negation on unsigned types. All known cases of each can be
166
  ignored.
167
 
168
  For a longer but out of date high-level description, see
169
     http://gee.cs.oswego.edu/dl/html/malloc.html
170
 
171
* MSPACES
172
  If MSPACES is defined, then in addition to malloc, free, etc.,
173
  this file also defines mspace_malloc, mspace_free, etc. These
174
  are versions of malloc routines that take an "mspace" argument
175
  obtained using create_mspace, to control all internal bookkeeping.
176
  If ONLY_MSPACES is defined, only these versions are compiled.
177
  So if you would like to use this allocator for only some allocations,
178
  and your system malloc for others, you can compile with
179
  ONLY_MSPACES and then do something like...
180
    static mspace mymspace = create_mspace(0,0); // for example
181
    #define mymalloc(bytes)  mspace_malloc(mymspace, bytes)
182
 
183
  (Note: If you only need one instance of an mspace, you can instead
184
  use "USE_DL_PREFIX" to relabel the global malloc.)
185
 
186
  You can similarly create thread-local allocators by storing
187
  mspaces as thread-locals. For example:
188
    static __thread mspace tlms = 0;
189
    void*  tlmalloc(size_t bytes) {
190
      if (tlms == 0) tlms = create_mspace(0, 0);
191
      return mspace_malloc(tlms, bytes);
192
    }
193
    void  tlfree(void* mem) { mspace_free(tlms, mem); }
194
 
195
  Unless FOOTERS is defined, each mspace is completely independent.
196
  You cannot allocate from one and free to another (although
197
  conformance is only weakly checked, so usage errors are not always
198
  caught). If FOOTERS is defined, then each chunk carries around a tag
199
  indicating its originating mspace, and frees are directed to their
200
  originating spaces.
201
 
202
 -------------------------  Compile-time options ---------------------------
203
 
204
Be careful in setting #define values for numerical constants of type
205
size_t. On some systems, literal values are not automatically extended
206
to size_t precision unless they are explicitly casted.
207
 
208
WIN32                    default: defined if _WIN32 defined
209
  Defining WIN32 sets up defaults for MS environment and compilers.
210
  Otherwise defaults are for unix.
211
 
212
MALLOC_ALIGNMENT         default: (size_t)8
213
  Controls the minimum alignment for malloc'ed chunks.  It must be a
214
  power of two and at least 8, even on machines for which smaller
215
  alignments would suffice. It may be defined as larger than this
216
  though. Note however that code and data structures are optimized for
217
  the case of 8-byte alignment.
218
 
219
MSPACES                  default: 0 (false)
220
  If true, compile in support for independent allocation spaces.
221
  This is only supported if HAVE_MMAP is true.
222
 
223
ONLY_MSPACES             default: 0 (false)
224
  If true, only compile in mspace versions, not regular versions.
225
 
226
USE_LOCKS                default: 0 (false)
227
  Causes each call to each public routine to be surrounded with
228
  pthread or WIN32 mutex lock/unlock. (If set true, this can be
229
  overridden on a per-mspace basis for mspace versions.)
230
 
231
FOOTERS                  default: 0
232
  If true, provide extra checking and dispatching by placing
233
  information in the footers of allocated chunks. This adds
234
  space and time overhead.
235
 
236
INSECURE                 default: 0
237
  If true, omit checks for usage errors and heap space overwrites.
238
 
239
USE_DL_PREFIX            default: NOT defined
240
  Causes compiler to prefix all public routines with the string 'dl'.
241
  This can be useful when you only want to use this malloc in one part
242
  of a program, using your regular system malloc elsewhere.
243
 
244
ABORT                    default: defined as abort()
245
  Defines how to abort on failed checks.  On most systems, a failed
246
  check cannot die with an "assert" or even print an informative
247
  message, because the underlying print routines in turn call malloc,
248
  which will fail again.  Generally, the best policy is to simply call
249
  abort(). It's not very useful to do more than this because many
250
  errors due to overwriting will show up as address faults (null, odd
251
  addresses etc) rather than malloc-triggered checks, so will also
252
  abort.  Also, most compilers know that abort() does not return, so
253
  can better optimize code conditionally calling it.
254
 
255
PROCEED_ON_ERROR           default: defined as 0 (false)
256
  Controls whether detected bad addresses cause them to bypassed
257
  rather than aborting. If set, detected bad arguments to free and
258
  realloc are ignored. And all bookkeeping information is zeroed out
259
  upon a detected overwrite of freed heap space, thus losing the
260
  ability to ever return it from malloc again, but enabling the
261
  application to proceed. If PROCEED_ON_ERROR is defined, the
262
  static variable malloc_corruption_error_count is compiled in
263
  and can be examined to see if errors have occurred. This option
264
  generates slower code than the default abort policy.
265
 
266
DEBUG                    default: NOT defined
267
  The DEBUG setting is mainly intended for people trying to modify
268
  this code or diagnose problems when porting to new platforms.
269
  However, it may also be able to better isolate user errors than just
270
  using runtime checks.  The assertions in the check routines spell
271
  out in more detail the assumptions and invariants underlying the
272
  algorithms.  The checking is fairly extensive, and will slow down
273
  execution noticeably. Calling malloc_stats or mallinfo with DEBUG
274
  set will attempt to check every non-mmapped allocated and free chunk
275
  in the course of computing the summaries.
276
 
277
ABORT_ON_ASSERT_FAILURE   default: defined as 1 (true)
278
  Debugging assertion failures can be nearly impossible if your
279
  version of the assert macro causes malloc to be called, which will
280
  lead to a cascade of further failures, blowing the runtime stack.
281
  ABORT_ON_ASSERT_FAILURE cause assertions failures to call abort(),
282
  which will usually make debugging easier.
283
 
284
MALLOC_FAILURE_ACTION     default: sets errno to ENOMEM, or no-op on win32
285
  The action to take before "return 0" when malloc fails to be able to
286
  return memory because there is none available.
287
 
288
HAVE_MORECORE             default: 1 (true) unless win32 or ONLY_MSPACES
289
  True if this system supports sbrk or an emulation of it.
290
 
291
MORECORE                  default: sbrk
292
  The name of the sbrk-style system routine to call to obtain more
293
  memory.  See below for guidance on writing custom MORECORE
294
  functions. The type of the argument to sbrk/MORECORE varies across
295
  systems.  It cannot be size_t, because it supports negative
296
  arguments, so it is normally the signed type of the same width as
297
  size_t (sometimes declared as "intptr_t").  It doesn't much matter
298
  though. Internally, we only call it with arguments less than half
299
  the max value of a size_t, which should work across all reasonable
300
  possibilities, although sometimes generating compiler warnings.  See
301
  near the end of this file for guidelines for creating a custom
302
  version of MORECORE.
303
 
304
MORECORE_CONTIGUOUS       default: 1 (true)
305
  If true, take advantage of fact that consecutive calls to MORECORE
306
  with positive arguments always return contiguous increasing
307
  addresses.  This is true of unix sbrk. It does not hurt too much to
308
  set it true anyway, since malloc copes with non-contiguities.
309
  Setting it false when definitely non-contiguous saves time
310
  and possibly wasted space it would take to discover this though.
311
 
312
MORECORE_CANNOT_TRIM      default: NOT defined
313
  True if MORECORE cannot release space back to the system when given
314
  negative arguments. This is generally necessary only if you are
315
  using a hand-crafted MORECORE function that cannot handle negative
316
  arguments.
317
 
318
HAVE_MMAP                 default: 1 (true)
319
  True if this system supports mmap or an emulation of it.  If so, and
320
  HAVE_MORECORE is not true, MMAP is used for all system
321
  allocation. If set and HAVE_MORECORE is true as well, MMAP is
322
  primarily used to directly allocate very large blocks. It is also
323
  used as a backup strategy in cases where MORECORE fails to provide
324
  space from system. Note: A single call to MUNMAP is assumed to be
325
  able to unmap memory that may have be allocated using multiple calls
326
  to MMAP, so long as they are adjacent.
327
 
328
HAVE_MREMAP               default: 1 on linux, else 0
329
  If true realloc() uses mremap() to re-allocate large blocks and
330
  extend or shrink allocation spaces.
331
 
332
MMAP_CLEARS               default: 1 on unix
333
  True if mmap clears memory so calloc doesn't need to. This is true
334
  for standard unix mmap using /dev/zero.
335
 
336
USE_BUILTIN_FFS            default: 0 (i.e., not used)
337
  Causes malloc to use the builtin ffs() function to compute indices.
338
  Some compilers may recognize and intrinsify ffs to be faster than the
339
  supplied C version. Also, the case of x86 using gcc is special-cased
340
  to an asm instruction, so is already as fast as it can be, and so
341
  this setting has no effect. (On most x86s, the asm version is only
342
  slightly faster than the C version.)
343
 
344
malloc_getpagesize         default: derive from system includes, or 4096.
345
  The system page size. To the extent possible, this malloc manages
346
  memory from the system in page-size units.  This may be (and
347
  usually is) a function rather than a constant. This is ignored
348
  if WIN32, where page size is determined using getSystemInfo during
349
  initialization.
350
 
351
USE_DEV_RANDOM             default: 0 (i.e., not used)
352
  Causes malloc to use /dev/random to initialize secure magic seed for
353
  stamping footers. Otherwise, the current time is used.
354
 
355
NO_MALLINFO                default: 0
356
  If defined, don't compile "mallinfo". This can be a simple way
357
  of dealing with mismatches between system declarations and
358
  those in this file.
359
 
360
MALLINFO_FIELD_TYPE        default: size_t
361
  The type of the fields in the mallinfo struct. This was originally
362
  defined as "int" in SVID etc, but is more usefully defined as
363
  size_t. The value is used only if  HAVE_USR_INCLUDE_MALLOC_H is not set
364
 
365
REALLOC_ZERO_BYTES_FREES    default: not defined
366
  This should be set if a call to realloc with zero bytes should
367
  be the same as a call to free. Some people think it should. Otherwise,
368
  since this malloc returns a unique pointer for malloc(0), so does
369
  realloc(p, 0).
370
 
371
LACKS_UNISTD_H, LACKS_FCNTL_H, LACKS_SYS_PARAM_H, LACKS_SYS_MMAN_H
372
LACKS_STRINGS_H, LACKS_STRING_H, LACKS_SYS_TYPES_H,  LACKS_ERRNO_H
373
LACKS_STDLIB_H                default: NOT defined unless on WIN32
374
  Define these if your system does not have these header files.
375
  You might need to manually insert some of the declarations they provide.
376
 
377
DEFAULT_GRANULARITY        default: page size if MORECORE_CONTIGUOUS,
378
                                system_info.dwAllocationGranularity in WIN32,
379
                                otherwise 64K.
380
      Also settable using mallopt(M_GRANULARITY, x)
381
  The unit for allocating and deallocating memory from the system.  On
382
  most systems with contiguous MORECORE, there is no reason to
383
  make this more than a page. However, systems with MMAP tend to
384
  either require or encourage larger granularities.  You can increase
385
  this value to prevent system allocation functions to be called so
386
  often, especially if they are slow.  The value must be at least one
387
  page and must be a power of two.  Setting to 0 causes initialization
388
  to either page size or win32 region size.  (Note: In previous
389
  versions of malloc, the equivalent of this option was called
390
  "TOP_PAD")
391
 
392
DEFAULT_TRIM_THRESHOLD    default: 2MB
393
      Also settable using mallopt(M_TRIM_THRESHOLD, x)
394
  The maximum amount of unused top-most memory to keep before
395
  releasing via malloc_trim in free().  Automatic trimming is mainly
396
  useful in long-lived programs using contiguous MORECORE.  Because
397
  trimming via sbrk can be slow on some systems, and can sometimes be
398
  wasteful (in cases where programs immediately afterward allocate
399
  more large chunks) the value should be high enough so that your
400
  overall system performance would improve by releasing this much
401
  memory.  As a rough guide, you might set to a value close to the
402
  average size of a process (program) running on your system.
403
  Releasing this much memory would allow such a process to run in
404
  memory.  Generally, it is worth tuning trim thresholds when a
405
  program undergoes phases where several large chunks are allocated
406
  and released in ways that can reuse each other's storage, perhaps
407
  mixed with phases where there are no such chunks at all. The trim
408
  value must be greater than page size to have any useful effect.  To
409
  disable trimming completely, you can set to MAX_SIZE_T. Note that the trick
410
  some people use of mallocing a huge space and then freeing it at
411
  program startup, in an attempt to reserve system memory, doesn't
412
  have the intended effect under automatic trimming, since that memory
413
  will immediately be returned to the system.
414
 
415
DEFAULT_MMAP_THRESHOLD       default: 256K
416
      Also settable using mallopt(M_MMAP_THRESHOLD, x)
417
  The request size threshold for using MMAP to directly service a
418
  request. Requests of at least this size that cannot be allocated
419
  using already-existing space will be serviced via mmap.  (If enough
420
  normal freed space already exists it is used instead.)  Using mmap
421
  segregates relatively large chunks of memory so that they can be
422
  individually obtained and released from the host system. A request
423
  serviced through mmap is never reused by any other request (at least
424
  not directly; the system may just so happen to remap successive
425
  requests to the same locations).  Segregating space in this way has
426
  the benefits that: Mmapped space can always be individually released
427
  back to the system, which helps keep the system level memory demands
428
  of a long-lived program low.  Also, mapped memory doesn't become
429
  `locked' between other chunks, as can happen with normally allocated
430
  chunks, which means that even trimming via malloc_trim would not
431
  release them.  However, it has the disadvantage that the space
432
  cannot be reclaimed, consolidated, and then used to service later
433
  requests, as happens with normal chunks.  The advantages of mmap
434
  nearly always outweigh disadvantages for "large" chunks, but the
435
  value of "large" may vary across systems.  The default is an
436
  empirically derived value that works well in most systems. You can
437
  disable mmap by setting to MAX_SIZE_T.
438
 
439
*/
440
 
441
#ifndef WIN32
442
#ifdef _WIN32
443
#define WIN32 1
444
#endif  /* _WIN32 */
445
#endif  /* WIN32 */
446
#ifdef WIN32
447
#define WIN32_LEAN_AND_MEAN
448
#include <windows.h>
449
#define HAVE_MMAP 1
450
#define HAVE_MORECORE 0
451
#define LACKS_UNISTD_H
452
#define LACKS_SYS_PARAM_H
453
#define LACKS_SYS_MMAN_H
454
#define LACKS_STRING_H
455
#define LACKS_STRINGS_H
456
#define LACKS_SYS_TYPES_H
457
#define LACKS_ERRNO_H
458
#define MALLOC_FAILURE_ACTION
459
#define MMAP_CLEARS 0 /* WINCE and some others apparently don't clear */
460
#endif  /* WIN32 */
461
 
462
#ifdef __OS2__
463
#define INCL_DOS
464
#include <os2.h>
465
#define HAVE_MMAP 1
466
#define HAVE_MORECORE 0
467
#define LACKS_SYS_MMAN_H
468
#endif  /* __OS2__ */
469
 
470
#if defined(DARWIN) || defined(_DARWIN)
471
/* Mac OSX docs advise not to use sbrk; it seems better to use mmap */
472
#ifndef HAVE_MORECORE
473
#define HAVE_MORECORE 0
474
#define HAVE_MMAP 1
475
#endif  /* HAVE_MORECORE */
476
#endif  /* DARWIN */
477
 
478
#ifndef LACKS_SYS_TYPES_H
479
#include <sys/types.h>  /* For size_t */
480
#endif  /* LACKS_SYS_TYPES_H */
481
 
482
/* The maximum possible size_t value has all bits set */
483
#define MAX_SIZE_T           (~(size_t)0)
484
 
485
#ifndef ONLY_MSPACES
486
#define ONLY_MSPACES 0
487
#endif  /* ONLY_MSPACES */
488
#ifndef MSPACES
489
#if ONLY_MSPACES
490
#define MSPACES 1
491
#else   /* ONLY_MSPACES */
492
#define MSPACES 0
493
#endif  /* ONLY_MSPACES */
494
#endif  /* MSPACES */
495
#ifndef MALLOC_ALIGNMENT
496
#define MALLOC_ALIGNMENT ((size_t)8U)
497
#endif  /* MALLOC_ALIGNMENT */
498
#ifndef FOOTERS
499
#define FOOTERS 0
500
#endif  /* FOOTERS */
501
#ifndef ABORT
502
#define ABORT  abort()
503
#endif  /* ABORT */
504
#ifndef ABORT_ON_ASSERT_FAILURE
505
#define ABORT_ON_ASSERT_FAILURE 1
506
#endif  /* ABORT_ON_ASSERT_FAILURE */
507
#ifndef PROCEED_ON_ERROR
508
#define PROCEED_ON_ERROR 0
509
#endif  /* PROCEED_ON_ERROR */
510
#ifndef USE_LOCKS
511
#define USE_LOCKS 0
512
#endif  /* USE_LOCKS */
513
#ifndef INSECURE
514
#define INSECURE 0
515
#endif  /* INSECURE */
516
#ifndef HAVE_MMAP
517
#define HAVE_MMAP 1
518
#endif  /* HAVE_MMAP */
519
#ifndef MMAP_CLEARS
520
#define MMAP_CLEARS 1
521
#endif  /* MMAP_CLEARS */
522
#ifndef HAVE_MREMAP
523
#ifdef linux
524
#define HAVE_MREMAP 1
525
#else   /* linux */
526
#define HAVE_MREMAP 0
527
#endif  /* linux */
528
#endif  /* HAVE_MREMAP */
529
#ifndef MALLOC_FAILURE_ACTION
530
#define MALLOC_FAILURE_ACTION  errno = ENOMEM;
531
#endif  /* MALLOC_FAILURE_ACTION */
532
#ifndef HAVE_MORECORE
533
#if ONLY_MSPACES
534
#define HAVE_MORECORE 0
535
#else   /* ONLY_MSPACES */
536
#define HAVE_MORECORE 1
537
#endif  /* ONLY_MSPACES */
538
#endif  /* HAVE_MORECORE */
539
#if !HAVE_MORECORE
540
#define MORECORE_CONTIGUOUS 0
541
#else   /* !HAVE_MORECORE */
542
#ifndef MORECORE
543
#define MORECORE sbrk
544
#endif  /* MORECORE */
545
#ifndef MORECORE_CONTIGUOUS
546
#define MORECORE_CONTIGUOUS 1
547
#endif  /* MORECORE_CONTIGUOUS */
548
#endif  /* HAVE_MORECORE */
549
#ifndef DEFAULT_GRANULARITY
550
#if MORECORE_CONTIGUOUS
551
#define DEFAULT_GRANULARITY (0)  /* 0 means to compute in init_mparams */
552
#else   /* MORECORE_CONTIGUOUS */
553
#define DEFAULT_GRANULARITY ((size_t)64U * (size_t)1024U)
554
#endif  /* MORECORE_CONTIGUOUS */
555
#endif  /* DEFAULT_GRANULARITY */
556
#ifndef DEFAULT_TRIM_THRESHOLD
557
#ifndef MORECORE_CANNOT_TRIM
558
#define DEFAULT_TRIM_THRESHOLD ((size_t)2U * (size_t)1024U * (size_t)1024U)
559
#else   /* MORECORE_CANNOT_TRIM */
560
#define DEFAULT_TRIM_THRESHOLD MAX_SIZE_T
561
#endif  /* MORECORE_CANNOT_TRIM */
562
#endif  /* DEFAULT_TRIM_THRESHOLD */
563
#ifndef DEFAULT_MMAP_THRESHOLD
564
#if HAVE_MMAP
565
#define DEFAULT_MMAP_THRESHOLD ((size_t)256U * (size_t)1024U)
566
#else   /* HAVE_MMAP */
567
#define DEFAULT_MMAP_THRESHOLD MAX_SIZE_T
568
#endif  /* HAVE_MMAP */
569
#endif  /* DEFAULT_MMAP_THRESHOLD */
570
#ifndef USE_BUILTIN_FFS
571
#define USE_BUILTIN_FFS 0
572
#endif  /* USE_BUILTIN_FFS */
573
#ifndef USE_DEV_RANDOM
574
#define USE_DEV_RANDOM 0
575
#endif  /* USE_DEV_RANDOM */
576
#ifndef NO_MALLINFO
577
#define NO_MALLINFO 0
578
#endif  /* NO_MALLINFO */
579
#ifndef MALLINFO_FIELD_TYPE
580
#define MALLINFO_FIELD_TYPE size_t
581
#endif  /* MALLINFO_FIELD_TYPE */
582
 
583
/*
584
  mallopt tuning options.  SVID/XPG defines four standard parameter
585
  numbers for mallopt, normally defined in malloc.h.  None of these
586
  are used in this malloc, so setting them has no effect. But this
587
  malloc does support the following options.
588
*/
589
 
590
#define M_TRIM_THRESHOLD     (-1)
591
#define M_GRANULARITY        (-2)
592
#define M_MMAP_THRESHOLD     (-3)
593
 
594
/* ------------------------ Mallinfo declarations ------------------------ */
595
 
596
#if !NO_MALLINFO
597
/*
598
  This version of malloc supports the standard SVID/XPG mallinfo
599
  routine that returns a struct containing usage properties and
600
  statistics. It should work on any system that has a
601
  /usr/include/malloc.h defining struct mallinfo.  The main
602
  declaration needed is the mallinfo struct that is returned (by-copy)
603
  by mallinfo().  The malloinfo struct contains a bunch of fields that
604
  are not even meaningful in this version of malloc.  These fields are
605
  are instead filled by mallinfo() with other numbers that might be of
606
  interest.
607
 
608
  HAVE_USR_INCLUDE_MALLOC_H should be set if you have a
609
  /usr/include/malloc.h file that includes a declaration of struct
610
  mallinfo.  If so, it is included; else a compliant version is
611
  declared below.  These must be precisely the same for mallinfo() to
612
  work.  The original SVID version of this struct, defined on most
613
  systems with mallinfo, declares all fields as ints. But some others
614
  define as unsigned long. If your system defines the fields using a
615
  type of different width than listed here, you MUST #include your
616
  system version and #define HAVE_USR_INCLUDE_MALLOC_H.
617
*/
618
 
619
/* #define HAVE_USR_INCLUDE_MALLOC_H */
620
 
621
#ifdef HAVE_USR_INCLUDE_MALLOC_H
622
#include "/usr/include/malloc.h"
623
#else /* HAVE_USR_INCLUDE_MALLOC_H */
624
 
625
struct mallinfo {
626
  MALLINFO_FIELD_TYPE arena;    /* non-mmapped space allocated from system */
627
  MALLINFO_FIELD_TYPE ordblks;  /* number of free chunks */
628
  MALLINFO_FIELD_TYPE smblks;   /* always 0 */
629
  MALLINFO_FIELD_TYPE hblks;    /* always 0 */
630
  MALLINFO_FIELD_TYPE hblkhd;   /* space in mmapped regions */
631
  MALLINFO_FIELD_TYPE usmblks;  /* maximum total allocated space */
632
  MALLINFO_FIELD_TYPE fsmblks;  /* always 0 */
633
  MALLINFO_FIELD_TYPE uordblks; /* total allocated space */
634
  MALLINFO_FIELD_TYPE fordblks; /* total free space */
635
  MALLINFO_FIELD_TYPE keepcost; /* releasable (via malloc_trim) space */
636
};
637
 
638
#endif /* HAVE_USR_INCLUDE_MALLOC_H */
639
#endif /* NO_MALLINFO */
640
 
641
#ifdef __cplusplus
642
extern "C" {
643
#endif /* __cplusplus */
644
 
645
#if !ONLY_MSPACES
646
 
647
/* ------------------- Declarations of public routines ------------------- */
648
 
649
#ifndef USE_DL_PREFIX
650
#define dlcalloc               calloc
651
#define dlfree                 free
652
#define dlmalloc               malloc
653
#define dlmemalign             memalign
654
#define dlrealloc              realloc
655
#define dlvalloc               valloc
656
#define dlpvalloc              pvalloc
657
#define dlmallinfo             mallinfo
658
#define dlmallopt              mallopt
659
#define dlmalloc_trim          malloc_trim
660
#define dlmalloc_stats         malloc_stats
661
#define dlmalloc_usable_size   malloc_usable_size
662
#define dlmalloc_footprint     malloc_footprint
663
#define dlmalloc_max_footprint malloc_max_footprint
664
#define dlindependent_calloc   independent_calloc
665
#define dlindependent_comalloc independent_comalloc
666
#endif /* USE_DL_PREFIX */
667
 
668
 
669
/*
670
  malloc(size_t n)
671
  Returns a pointer to a newly allocated chunk of at least n bytes, or
672
  null if no space is available, in which case errno is set to ENOMEM
673
  on ANSI C systems.
674
 
675
  If n is zero, malloc returns a minimum-sized chunk. (The minimum
676
  size is 16 bytes on most 32bit systems, and 32 bytes on 64bit
677
  systems.)  Note that size_t is an unsigned type, so calls with
678
  arguments that would be negative if signed are interpreted as
679
  requests for huge amounts of space, which will often fail. The
680
  maximum supported value of n differs across systems, but is in all
681
  cases less than the maximum representable value of a size_t.
682
*/
683
void* dlmalloc(size_t);
684
 
685
/*
686
  free(void* p)
687
  Releases the chunk of memory pointed to by p, that had been previously
688
  allocated using malloc or a related routine such as realloc.
689
  It has no effect if p is null. If p was not malloced or already
690
  freed, free(p) will by default cause the current program to abort.
691
*/
692
void  dlfree(void*);
693
 
694
/*
695
  calloc(size_t n_elements, size_t element_size);
696
  Returns a pointer to n_elements * element_size bytes, with all locations
697
  set to zero.
698
*/
699
void* dlcalloc(size_t, size_t);
700
 
701
/*
702
  realloc(void* p, size_t n)
703
  Returns a pointer to a chunk of size n that contains the same data
704
  as does chunk p up to the minimum of (n, p's size) bytes, or null
705
  if no space is available.
706
 
707
  The returned pointer may or may not be the same as p. The algorithm
708
  prefers extending p in most cases when possible, otherwise it
709
  employs the equivalent of a malloc-copy-free sequence.
710
 
711
  If p is null, realloc is equivalent to malloc.
712
 
713
  If space is not available, realloc returns null, errno is set (if on
714
  ANSI) and p is NOT freed.
715
 
716
  if n is for fewer bytes than already held by p, the newly unused
717
  space is lopped off and freed if possible.  realloc with a size
718
  argument of zero (re)allocates a minimum-sized chunk.
719
 
720
  The old unix realloc convention of allowing the last-free'd chunk
721
  to be used as an argument to realloc is not supported.
722
*/
723
 
724
void* dlrealloc(void*, size_t);
725
 
726
/*
727
  memalign(size_t alignment, size_t n);
728
  Returns a pointer to a newly allocated chunk of n bytes, aligned
729
  in accord with the alignment argument.
730
 
731
  The alignment argument should be a power of two. If the argument is
732
  not a power of two, the nearest greater power is used.
733
  8-byte alignment is guaranteed by normal malloc calls, so don't
734
  bother calling memalign with an argument of 8 or less.
735
 
736
  Overreliance on memalign is a sure way to fragment space.
737
*/
738
void* dlmemalign(size_t, size_t);
739
 
740
/*
741
  valloc(size_t n);
742
  Equivalent to memalign(pagesize, n), where pagesize is the page
743
  size of the system. If the pagesize is unknown, 4096 is used.
744
*/
745
void* dlvalloc(size_t);
746
 
747
/*
748
  mallopt(int parameter_number, int parameter_value)
749
  Sets tunable parameters The format is to provide a
750
  (parameter-number, parameter-value) pair.  mallopt then sets the
751
  corresponding parameter to the argument value if it can (i.e., so
752
  long as the value is meaningful), and returns 1 if successful else
753
  0.  SVID/XPG/ANSI defines four standard param numbers for mallopt,
754
  normally defined in malloc.h.  None of these are use in this malloc,
755
  so setting them has no effect. But this malloc also supports other
756
  options in mallopt. See below for details.  Briefly, supported
757
  parameters are as follows (listed defaults are for "typical"
758
  configurations).
759
 
760
  Symbol            param #  default    allowed param values
761
  M_TRIM_THRESHOLD     -1   2*1024*1024   any   (MAX_SIZE_T disables)
762
  M_GRANULARITY        -2     page size   any power of 2 >= page size
763
  M_MMAP_THRESHOLD     -3      256*1024   any   (or 0 if no MMAP support)
764
*/
765
int dlmallopt(int, int);
766
 
767
/*
768
  malloc_footprint();
769
  Returns the number of bytes obtained from the system.  The total
770
  number of bytes allocated by malloc, realloc etc., is less than this
771
  value. Unlike mallinfo, this function returns only a precomputed
772
  result, so can be called frequently to monitor memory consumption.
773
  Even if locks are otherwise defined, this function does not use them,
774
  so results might not be up to date.
775
*/
776
size_t dlmalloc_footprint(void);
777
 
778
/*
779
  malloc_max_footprint();
780
  Returns the maximum number of bytes obtained from the system. This
781
  value will be greater than current footprint if deallocated space
782
  has been reclaimed by the system. The peak number of bytes allocated
783
  by malloc, realloc etc., is less than this value. Unlike mallinfo,
784
  this function returns only a precomputed result, so can be called
785
  frequently to monitor memory consumption.  Even if locks are
786
  otherwise defined, this function does not use them, so results might
787
  not be up to date.
788
*/
789
size_t dlmalloc_max_footprint(void);
790
 
791
#if !NO_MALLINFO
792
/*
793
  mallinfo()
794
  Returns (by copy) a struct containing various summary statistics:
795
 
796
  arena:     current total non-mmapped bytes allocated from system
797
  ordblks:   the number of free chunks
798
  smblks:    always zero.
799
  hblks:     current number of mmapped regions
800
  hblkhd:    total bytes held in mmapped regions
801
  usmblks:   the maximum total allocated space. This will be greater
802
                than current total if trimming has occurred.
803
  fsmblks:   always zero
804
  uordblks:  current total allocated space (normal or mmapped)
805
  fordblks:  total free space
806
  keepcost:  the maximum number of bytes that could ideally be released
807
               back to system via malloc_trim. ("ideally" means that
808
               it ignores page restrictions etc.)
809
 
810
  Because these fields are ints, but internal bookkeeping may
811
  be kept as longs, the reported values may wrap around zero and
812
  thus be inaccurate.
813
*/
814
struct mallinfo dlmallinfo(void);
815
#endif /* NO_MALLINFO */
816
 
817
/*
818
  independent_calloc(size_t n_elements, size_t element_size, void* chunks[]);
819
 
820
  independent_calloc is similar to calloc, but instead of returning a
821
  single cleared space, it returns an array of pointers to n_elements
822
  independent elements that can hold contents of size elem_size, each
823
  of which starts out cleared, and can be independently freed,
824
  realloc'ed etc. The elements are guaranteed to be adjacently
825
  allocated (this is not guaranteed to occur with multiple callocs or
826
  mallocs), which may also improve cache locality in some
827
  applications.
828
 
829
  The "chunks" argument is optional (i.e., may be null, which is
830
  probably the most typical usage). If it is null, the returned array
831
  is itself dynamically allocated and should also be freed when it is
832
  no longer needed. Otherwise, the chunks array must be of at least
833
  n_elements in length. It is filled in with the pointers to the
834
  chunks.
835
 
836
  In either case, independent_calloc returns this pointer array, or
837
  null if the allocation failed.  If n_elements is zero and "chunks"
838
  is null, it returns a chunk representing an array with zero elements
839
  (which should be freed if not wanted).
840
 
841
  Each element must be individually freed when it is no longer
842
  needed. If you'd like to instead be able to free all at once, you
843
  should instead use regular calloc and assign pointers into this
844
  space to represent elements.  (In this case though, you cannot
845
  independently free elements.)
846
 
847
  independent_calloc simplifies and speeds up implementations of many
848
  kinds of pools.  It may also be useful when constructing large data
849
  structures that initially have a fixed number of fixed-sized nodes,
850
  but the number is not known at compile time, and some of the nodes
851
  may later need to be freed. For example:
852
 
853
  struct Node { int item; struct Node* next; };
854
 
855
  struct Node* build_list() {
856
    struct Node** pool;
857
    int n = read_number_of_nodes_needed();
858
    if (n <= 0) return 0;
859
    pool = (struct Node**)(independent_calloc(n, sizeof(struct Node), 0);
860
    if (pool == 0) die();
861
    // organize into a linked list...
862
    struct Node* first = pool[0];
863
    for (i = 0; i < n-1; ++i)
864
      pool[i]->next = pool[i+1];
865
    free(pool);     // Can now free the array (or not, if it is needed later)
866
    return first;
867
  }
868
*/
869
void** dlindependent_calloc(size_t, size_t, void**);
870
 
871
/*
872
  independent_comalloc(size_t n_elements, size_t sizes[], void* chunks[]);
873
 
874
  independent_comalloc allocates, all at once, a set of n_elements
875
  chunks with sizes indicated in the "sizes" array.    It returns
876
  an array of pointers to these elements, each of which can be
877
  independently freed, realloc'ed etc. The elements are guaranteed to
878
  be adjacently allocated (this is not guaranteed to occur with
879
  multiple callocs or mallocs), which may also improve cache locality
880
  in some applications.
881
 
882
  The "chunks" argument is optional (i.e., may be null). If it is null
883
  the returned array is itself dynamically allocated and should also
884
  be freed when it is no longer needed. Otherwise, the chunks array
885
  must be of at least n_elements in length. It is filled in with the
886
  pointers to the chunks.
887
 
888
  In either case, independent_comalloc returns this pointer array, or
889
  null if the allocation failed.  If n_elements is zero and chunks is
890
  null, it returns a chunk representing an array with zero elements
891
  (which should be freed if not wanted).
892
 
893
  Each element must be individually freed when it is no longer
894
  needed. If you'd like to instead be able to free all at once, you
895
  should instead use a single regular malloc, and assign pointers at
896
  particular offsets in the aggregate space. (In this case though, you
897
  cannot independently free elements.)
898
 
899
  independent_comallac differs from independent_calloc in that each
900
  element may have a different size, and also that it does not
901
  automatically clear elements.
902
 
903
  independent_comalloc can be used to speed up allocation in cases
904
  where several structs or objects must always be allocated at the
905
  same time.  For example:
906
 
907
  struct Head { ... }
908
  struct Foot { ... }
909
 
910
  void send_message(char* msg) {
911
    int msglen = strlen(msg);
912
    size_t sizes[3] = { sizeof(struct Head), msglen, sizeof(struct Foot) };
913
    void* chunks[3];
914
    if (independent_comalloc(3, sizes, chunks) == 0)
915
      die();
916
    struct Head* head = (struct Head*)(chunks[0]);
917
    char*        body = (char*)(chunks[1]);
918
    struct Foot* foot = (struct Foot*)(chunks[2]);
919
    // ...
920
  }
921
 
922
  In general though, independent_comalloc is worth using only for
923
  larger values of n_elements. For small values, you probably won't
924
  detect enough difference from series of malloc calls to bother.
925
 
926
  Overuse of independent_comalloc can increase overall memory usage,
927
  since it cannot reuse existing noncontiguous small chunks that
928
  might be available for some of the elements.
929
*/
930
void** dlindependent_comalloc(size_t, size_t*, void**);
931
 
932
 
933
/*
934
  pvalloc(size_t n);
935
  Equivalent to valloc(minimum-page-that-holds(n)), that is,
936
  round up n to nearest pagesize.
937
 */
938
void*  dlpvalloc(size_t);
939
 
940
/*
941
  malloc_trim(size_t pad);
942
 
943
  If possible, gives memory back to the system (via negative arguments
944
  to sbrk) if there is unused memory at the `high' end of the malloc
945
  pool or in unused MMAP segments. You can call this after freeing
946
  large blocks of memory to potentially reduce the system-level memory
947
  requirements of a program. However, it cannot guarantee to reduce
948
  memory. Under some allocation patterns, some large free blocks of
949
  memory will be locked between two used chunks, so they cannot be
950
  given back to the system.
951
 
952
  The `pad' argument to malloc_trim represents the amount of free
953
  trailing space to leave untrimmed. If this argument is zero, only
954
  the minimum amount of memory to maintain internal data structures
955
  will be left. Non-zero arguments can be supplied to maintain enough
956
  trailing space to service future expected allocations without having
957
  to re-obtain memory from the system.
958
 
959
  Malloc_trim returns 1 if it actually released any memory, else 0.
960
*/
961
int  dlmalloc_trim(size_t);
962
 
963
/*
964
  malloc_usable_size(void* p);
965
 
966
  Returns the number of bytes you can actually use in
967
  an allocated chunk, which may be more than you requested (although
968
  often not) due to alignment and minimum size constraints.
969
  You can use this many bytes without worrying about
970
  overwriting other allocated objects. This is not a particularly great
971
  programming practice. malloc_usable_size can be more useful in
972
  debugging and assertions, for example:
973
 
974
  p = malloc(n);
975
  assert(malloc_usable_size(p) >= 256);
976
*/
977
size_t dlmalloc_usable_size(void*);
978
 
979
/*
980
  malloc_stats();
981
  Prints on stderr the amount of space obtained from the system (both
982
  via sbrk and mmap), the maximum amount (which may be more than
983
  current if malloc_trim and/or munmap got called), and the current
984
  number of bytes allocated via malloc (or realloc, etc) but not yet
985
  freed. Note that this is the number of bytes allocated, not the
986
  number requested. It will be larger than the number requested
987
  because of alignment and bookkeeping overhead. Because it includes
988
  alignment wastage as being in use, this figure may be greater than
989
  zero even when no user-level chunks are allocated.
990
 
991
  The reported current and maximum system memory can be inaccurate if
992
  a program makes other calls to system memory allocation functions
993
  (normally sbrk) outside of malloc.
994
 
995
  malloc_stats prints only the most commonly interesting statistics.
996
  More information can be obtained by calling mallinfo.
997
*/
998
void  dlmalloc_stats(void);
999
 
1000
#endif /* ONLY_MSPACES */
1001
 
1002
#if MSPACES
1003
 
1004
/*
1005
  mspace is an opaque type representing an independent
1006
  region of space that supports mspace_malloc, etc.
1007
*/
1008
typedef void* mspace;
1009
 
1010
/*
1011
  create_mspace creates and returns a new independent space with the
1012
  given initial capacity, or, if 0, the default granularity size.  It
1013
  returns null if there is no system memory available to create the
1014
  space.  If argument locked is non-zero, the space uses a separate
1015
  lock to control access. The capacity of the space will grow
1016
  dynamically as needed to service mspace_malloc requests.  You can
1017
  control the sizes of incremental increases of this space by
1018
  compiling with a different DEFAULT_GRANULARITY or dynamically
1019
  setting with mallopt(M_GRANULARITY, value).
1020
*/
1021
mspace create_mspace(size_t capacity, int locked);
1022
 
1023
/*
1024
  destroy_mspace destroys the given space, and attempts to return all
1025
  of its memory back to the system, returning the total number of
1026
  bytes freed. After destruction, the results of access to all memory
1027
  used by the space become undefined.
1028
*/
1029
size_t destroy_mspace(mspace msp);
1030
 
1031
/*
1032
  create_mspace_with_base uses the memory supplied as the initial base
1033
  of a new mspace. Part (less than 128*sizeof(size_t) bytes) of this
1034
  space is used for bookkeeping, so the capacity must be at least this
1035
  large. (Otherwise 0 is returned.) When this initial space is
1036
  exhausted, additional memory will be obtained from the system.
1037
  Destroying this space will deallocate all additionally allocated
1038
  space (if possible) but not the initial base.
1039
*/
1040
mspace create_mspace_with_base(void* base, size_t capacity, int locked);
1041
 
1042
/*
1043
  mspace_malloc behaves as malloc, but operates within
1044
  the given space.
1045
*/
1046
void* mspace_malloc(mspace msp, size_t bytes);
1047
 
1048
/*
1049
  mspace_free behaves as free, but operates within
1050
  the given space.
1051
 
1052
  If compiled with FOOTERS==1, mspace_free is not actually needed.
1053
  free may be called instead of mspace_free because freed chunks from
1054
  any space are handled by their originating spaces.
1055
*/
1056
void mspace_free(mspace msp, void* mem);
1057
 
1058
/*
1059
  mspace_realloc behaves as realloc, but operates within
1060
  the given space.
1061
 
1062
  If compiled with FOOTERS==1, mspace_realloc is not actually
1063
  needed.  realloc may be called instead of mspace_realloc because
1064
  realloced chunks from any space are handled by their originating
1065
  spaces.
1066
*/
1067
void* mspace_realloc(mspace msp, void* mem, size_t newsize);
1068
 
1069
/*
1070
  mspace_calloc behaves as calloc, but operates within
1071
  the given space.
1072
*/
1073
void* mspace_calloc(mspace msp, size_t n_elements, size_t elem_size);
1074
 
1075
/*
1076
  mspace_memalign behaves as memalign, but operates within
1077
  the given space.
1078
*/
1079
void* mspace_memalign(mspace msp, size_t alignment, size_t bytes);
1080
 
1081
/*
1082
  mspace_independent_calloc behaves as independent_calloc, but
1083
  operates within the given space.
1084
*/
1085
void** mspace_independent_calloc(mspace msp, size_t n_elements,
1086
                                 size_t elem_size, void* chunks[]);
1087
 
1088
/*
1089
  mspace_independent_comalloc behaves as independent_comalloc, but
1090
  operates within the given space.
1091
*/
1092
void** mspace_independent_comalloc(mspace msp, size_t n_elements,
1093
                                   size_t sizes[], void* chunks[]);
1094
 
1095
/*
1096
  mspace_footprint() returns the number of bytes obtained from the
1097
  system for this space.
1098
*/
1099
size_t mspace_footprint(mspace msp);
1100
 
1101
/*
1102
  mspace_max_footprint() returns the peak number of bytes obtained from the
1103
  system for this space.
1104
*/
1105
size_t mspace_max_footprint(mspace msp);
1106
 
1107
 
1108
#if !NO_MALLINFO
1109
/*
1110
  mspace_mallinfo behaves as mallinfo, but reports properties of
1111
  the given space.
1112
*/
1113
struct mallinfo mspace_mallinfo(mspace msp);
1114
#endif /* NO_MALLINFO */
1115
 
1116
/*
1117
  mspace_malloc_stats behaves as malloc_stats, but reports
1118
  properties of the given space.
1119
*/
1120
void mspace_malloc_stats(mspace msp);
1121
 
1122
/*
1123
  mspace_trim behaves as malloc_trim, but
1124
  operates within the given space.
1125
*/
1126
int mspace_trim(mspace msp, size_t pad);
1127
 
1128
/*
1129
  An alias for mallopt.
1130
*/
1131
int mspace_mallopt(int, int);
1132
 
1133
#endif /* MSPACES */
1134
 
1135
#ifdef __cplusplus
1136
};  /* end of extern "C" */
1137
#endif /* __cplusplus */
1138
 
1139
/*
1140
  ========================================================================
1141
  To make a fully customizable malloc.h header file, cut everything
1142
  above this line, put into file malloc.h, edit to suit, and #include it
1143
  on the next line, as well as in programs that use this malloc.
1144
  ========================================================================
1145
*/
1146
 
1147
/* #include "malloc.h" */
1148
 
1149
/*------------------------------ internal #includes ---------------------- */
1150
 
1151
#ifdef _MSC_VER
1152
#pragma warning( disable : 4146 ) /* no "unsigned" warnings */
1153
#endif /* _MSC_VER */
1154
 
1155
#include <stdio.h>       /* for printing in malloc_stats */
1156
 
1157
#ifndef LACKS_ERRNO_H
1158
#include <errno.h>       /* for MALLOC_FAILURE_ACTION */
1159
#endif /* LACKS_ERRNO_H */
1160
#if FOOTERS
1161
#include <time.h>        /* for magic initialization */
1162
#endif /* FOOTERS */
1163
#ifndef LACKS_STDLIB_H
1164
#include <stdlib.h>      /* for abort() */
1165
#endif /* LACKS_STDLIB_H */
1166
#ifdef DEBUG
1167
#if ABORT_ON_ASSERT_FAILURE
1168
#define assert(x) if(!(x)) ABORT
1169
#else /* ABORT_ON_ASSERT_FAILURE */
1170
#include <assert.h>
1171
#endif /* ABORT_ON_ASSERT_FAILURE */
1172
#else  /* DEBUG */
1173
#define assert(x)
1174
#endif /* DEBUG */
1175
#ifndef LACKS_STRING_H
1176
#include <string.h>      /* for memset etc */
1177
#endif  /* LACKS_STRING_H */
1178
#if USE_BUILTIN_FFS
1179
#ifndef LACKS_STRINGS_H
1180
#include <strings.h>     /* for ffs */
1181
#endif /* LACKS_STRINGS_H */
1182
#endif /* USE_BUILTIN_FFS */
1183
#if HAVE_MMAP
1184
#ifndef LACKS_SYS_MMAN_H
1185
#include <sys/mman.h>    /* for mmap */
1186
#endif /* LACKS_SYS_MMAN_H */
1187
#ifndef LACKS_FCNTL_H
1188
#include <fcntl.h>
1189
#endif /* LACKS_FCNTL_H */
1190
#endif /* HAVE_MMAP */
1191
#if HAVE_MORECORE
1192
#ifndef LACKS_UNISTD_H
1193
#include <unistd.h>     /* for sbrk */
1194
#else /* LACKS_UNISTD_H */
1195
#if !defined(__FreeBSD__) && !defined(__OpenBSD__) && !defined(__NetBSD__)
1196
extern void*     sbrk(ptrdiff_t);
1197
#endif /* FreeBSD etc */
1198
#endif /* LACKS_UNISTD_H */
1199
#endif /* HAVE_MMAP */
1200
 
1201
#ifndef WIN32
1202
#ifndef malloc_getpagesize
1203
#  ifdef _SC_PAGESIZE         /* some SVR4 systems omit an underscore */
1204
#    ifndef _SC_PAGE_SIZE
1205
#      define _SC_PAGE_SIZE _SC_PAGESIZE
1206
#    endif
1207
#  endif
1208
#  ifdef _SC_PAGE_SIZE
1209
#    define malloc_getpagesize sysconf(_SC_PAGE_SIZE)
1210
#  else
1211
#    if defined(BSD) || defined(DGUX) || defined(HAVE_GETPAGESIZE)
1212
       extern size_t getpagesize();
1213
#      define malloc_getpagesize getpagesize()
1214
#    else
1215
#      ifdef WIN32 /* use supplied emulation of getpagesize */
1216
#        define malloc_getpagesize getpagesize()
1217
#      else
1218
#        ifndef LACKS_SYS_PARAM_H
1219
#          include <sys/param.h>
1220
#        endif
1221
#        ifdef EXEC_PAGESIZE
1222
#          define malloc_getpagesize EXEC_PAGESIZE
1223
#        else
1224
#          ifdef NBPG
1225
#            ifndef CLSIZE
1226
#              define malloc_getpagesize NBPG
1227
#            else
1228
#              define malloc_getpagesize (NBPG * CLSIZE)
1229
#            endif
1230
#          else
1231
#            ifdef NBPC
1232
#              define malloc_getpagesize NBPC
1233
#            else
1234
#              ifdef PAGESIZE
1235
#                define malloc_getpagesize PAGESIZE
1236
#              else /* just guess */
1237
#                define malloc_getpagesize ((size_t)4096U)
1238
#              endif
1239
#            endif
1240
#          endif
1241
#        endif
1242
#      endif
1243
#    endif
1244
#  endif
1245
#endif
1246
#endif
1247
 
1248
/* ------------------- size_t and alignment properties -------------------- */
1249
 
1250
/* The byte and bit size of a size_t */
1251
#define SIZE_T_SIZE         (sizeof(size_t))
1252
#define SIZE_T_BITSIZE      (sizeof(size_t) << 3)
1253
 
1254
/* Some constants coerced to size_t */
1255
/* Annoying but necessary to avoid errors on some plaftorms */
1256
#define SIZE_T_ZERO         ((size_t)0)
1257
#define SIZE_T_ONE          ((size_t)1)
1258
#define SIZE_T_TWO          ((size_t)2)
1259
#define TWO_SIZE_T_SIZES    (SIZE_T_SIZE<<1)
1260
#define FOUR_SIZE_T_SIZES   (SIZE_T_SIZE<<2)
1261
#define SIX_SIZE_T_SIZES    (FOUR_SIZE_T_SIZES+TWO_SIZE_T_SIZES)
1262
#define HALF_MAX_SIZE_T     (MAX_SIZE_T / 2U)
1263
 
1264
/* The bit mask value corresponding to MALLOC_ALIGNMENT */
1265
#define CHUNK_ALIGN_MASK    (MALLOC_ALIGNMENT - SIZE_T_ONE)
1266
 
1267
/* True if address a has acceptable alignment */
1268
#define is_aligned(A)       (((size_t)((A)) & (CHUNK_ALIGN_MASK)) == 0)
1269
 
1270
/* the number of bytes to offset an address to align it */
1271
#define align_offset(A)\
1272
 ((((size_t)(A) & CHUNK_ALIGN_MASK) == 0)? 0 :\
1273
  ((MALLOC_ALIGNMENT - ((size_t)(A) & CHUNK_ALIGN_MASK)) & CHUNK_ALIGN_MASK))
1274
 
1275
/* -------------------------- MMAP preliminaries ------------------------- */
1276
 
1277
/*
1278
   If HAVE_MORECORE or HAVE_MMAP are false, we just define calls and
1279
   checks to fail so compiler optimizer can delete code rather than
1280
   using so many "#if"s.
1281
*/
1282
 
1283
 
1284
/* MORECORE and MMAP must return MFAIL on failure */
1285
#define MFAIL                ((void*)(MAX_SIZE_T))
1286
#define CMFAIL               ((char*)(MFAIL)) /* defined for convenience */
1287
 
1288
#if !HAVE_MMAP
1289
#define IS_MMAPPED_BIT       (SIZE_T_ZERO)
1290
#define USE_MMAP_BIT         (SIZE_T_ZERO)
1291
#define CALL_MMAP(s)         MFAIL
1292
#define CALL_MUNMAP(a, s)    (-1)
1293
#define DIRECT_MMAP(s)       MFAIL
1294
 
1295
#else /* HAVE_MMAP */
1296
#define IS_MMAPPED_BIT       (SIZE_T_ONE)
1297
#define USE_MMAP_BIT         (SIZE_T_ONE)
1298
 
1299
#if !defined(WIN32) && !defined (__OS2__)
1300
#define CALL_MUNMAP(a, s)    munmap((a), (s))
1301
#define MMAP_PROT            (PROT_READ|PROT_WRITE)
1302
#if !defined(MAP_ANONYMOUS) && defined(MAP_ANON)
1303
#define MAP_ANONYMOUS        MAP_ANON
1304
#endif /* MAP_ANON */
1305
#ifdef MAP_ANONYMOUS
1306
#define MMAP_FLAGS           (MAP_PRIVATE|MAP_ANONYMOUS)
1307
#define CALL_MMAP(s)         mmap(0, (s), MMAP_PROT, MMAP_FLAGS, -1, 0)
1308
#else /* MAP_ANONYMOUS */
1309
/*
1310
   Nearly all versions of mmap support MAP_ANONYMOUS, so the following
1311
   is unlikely to be needed, but is supplied just in case.
1312
*/
1313
#define MMAP_FLAGS           (MAP_PRIVATE)
1314
static int dev_zero_fd = -1; /* Cached file descriptor for /dev/zero. */
1315
#define CALL_MMAP(s) ((dev_zero_fd < 0) ? \
1316
           (dev_zero_fd = open("/dev/zero", O_RDWR), \
1317
            mmap(0, (s), MMAP_PROT, MMAP_FLAGS, dev_zero_fd, 0)) : \
1318
            mmap(0, (s), MMAP_PROT, MMAP_FLAGS, dev_zero_fd, 0))
1319
#endif /* MAP_ANONYMOUS */
1320
 
1321
#define DIRECT_MMAP(s)       CALL_MMAP(s)
1322
 
1323
#elif defined(__OS2__)
1324
 
1325
/* OS/2 MMAP via DosAllocMem */
1326
static void* os2mmap(size_t size) {
1327
  void* ptr;
1328
  if (DosAllocMem(&ptr, size, OBJ_ANY|PAG_COMMIT|PAG_READ|PAG_WRITE) &&
1329
      DosAllocMem(&ptr, size, PAG_COMMIT|PAG_READ|PAG_WRITE))
1330
    return MFAIL;
1331
  return ptr;
1332
}
1333
 
1334
#define os2direct_mmap(n)     os2mmap(n)
1335
 
1336
/* This function supports releasing coalesed segments */
1337
static int os2munmap(void* ptr, size_t size) {
1338
  while (size) {
1339
    ULONG ulSize = size;
1340
    ULONG ulFlags = 0;
1341
    if (DosQueryMem(ptr, &ulSize, &ulFlags) != 0)
1342
      return -1;
1343
    if ((ulFlags & PAG_BASE) == 0 ||(ulFlags & PAG_COMMIT) == 0 ||
1344
        ulSize > size)
1345
      return -1;
1346
    if (DosFreeMem(ptr) != 0)
1347
      return -1;
1348
    ptr = ( void * ) ( ( char * ) ptr + ulSize );
1349
    size -= ulSize;
1350
  }
1351
  return 0;
1352
}
1353
 
1354
#define CALL_MMAP(s)         os2mmap(s)
1355
#define CALL_MUNMAP(a, s)    os2munmap((a), (s))
1356
#define DIRECT_MMAP(s)       os2direct_mmap(s)
1357
 
1358
#else /* WIN32 */
1359
 
1360
/* Win32 MMAP via VirtualAlloc */
1361
static void* win32mmap(size_t size) {
1362
  void* ptr = VirtualAlloc(0, size, MEM_RESERVE|MEM_COMMIT, PAGE_EXECUTE_READWRITE);
1363
  return (ptr != 0)? ptr: MFAIL;
1364
}
1365
 
1366
/* For direct MMAP, use MEM_TOP_DOWN to minimize interference */
1367
static void* win32direct_mmap(size_t size) {
1368
  void* ptr = VirtualAlloc(0, size, MEM_RESERVE|MEM_COMMIT|MEM_TOP_DOWN,
1369
                           PAGE_EXECUTE_READWRITE);
1370
  return (ptr != 0)? ptr: MFAIL;
1371
}
1372
 
1373
/* This function supports releasing coalesed segments */
1374
static int win32munmap(void* ptr, size_t size) {
1375
  MEMORY_BASIC_INFORMATION minfo;
1376
  char* cptr = ptr;
1377
  while (size) {
1378
    if (VirtualQuery(cptr, &minfo, sizeof(minfo)) == 0)
1379
      return -1;
1380
    if (minfo.BaseAddress != cptr || minfo.AllocationBase != cptr ||
1381
        minfo.State != MEM_COMMIT || minfo.RegionSize > size)
1382
      return -1;
1383
    if (VirtualFree(cptr, 0, MEM_RELEASE) == 0)
1384
      return -1;
1385
    cptr += minfo.RegionSize;
1386
    size -= minfo.RegionSize;
1387
  }
1388
  return 0;
1389
}
1390
 
1391
#define CALL_MMAP(s)         win32mmap(s)
1392
#define CALL_MUNMAP(a, s)    win32munmap((a), (s))
1393
#define DIRECT_MMAP(s)       win32direct_mmap(s)
1394
#endif /* WIN32 */
1395
#endif /* HAVE_MMAP */
1396
 
1397
#if HAVE_MMAP && HAVE_MREMAP
1398
#define CALL_MREMAP(addr, osz, nsz, mv) mremap((addr), (osz), (nsz), (mv))
1399
#else  /* HAVE_MMAP && HAVE_MREMAP */
1400
#define CALL_MREMAP(addr, osz, nsz, mv) MFAIL
1401
#endif /* HAVE_MMAP && HAVE_MREMAP */
1402
 
1403
#if HAVE_MORECORE
1404
#define CALL_MORECORE(S)     MORECORE(S)
1405
#else  /* HAVE_MORECORE */
1406
#define CALL_MORECORE(S)     MFAIL
1407
#endif /* HAVE_MORECORE */
1408
 
1409
/* mstate bit set if continguous morecore disabled or failed */
1410
#define USE_NONCONTIGUOUS_BIT (4U)
1411
 
1412
/* segment bit set in create_mspace_with_base */
1413
#define EXTERN_BIT            (8U)
1414
 
1415
 
1416
/* --------------------------- Lock preliminaries ------------------------ */
1417
 
1418
#if USE_LOCKS
1419
 
1420
/*
1421
  When locks are defined, there are up to two global locks:
1422
 
1423
  * If HAVE_MORECORE, morecore_mutex protects sequences of calls to
1424
    MORECORE.  In many cases sys_alloc requires two calls, that should
1425
    not be interleaved with calls by other threads.  This does not
1426
    protect against direct calls to MORECORE by other threads not
1427
    using this lock, so there is still code to cope the best we can on
1428
    interference.
1429
 
1430
  * magic_init_mutex ensures that mparams.magic and other
1431
    unique mparams values are initialized only once.
1432
*/
1433
 
1434
#if !defined(WIN32) && !defined(__OS2__)
1435
/* By default use posix locks */
1436
#include <pthread.h>
1437
#define MLOCK_T pthread_mutex_t
1438
#define INITIAL_LOCK(l)      pthread_mutex_init(l, NULL)
1439
#define ACQUIRE_LOCK(l)      pthread_mutex_lock(l)
1440
#define RELEASE_LOCK(l)      pthread_mutex_unlock(l)
1441
 
1442
#if HAVE_MORECORE
1443
static MLOCK_T morecore_mutex = PTHREAD_MUTEX_INITIALIZER;
1444
#endif /* HAVE_MORECORE */
1445
 
1446
static MLOCK_T magic_init_mutex = PTHREAD_MUTEX_INITIALIZER;
1447
 
1448
#elif defined(__OS2__)
1449
#define MLOCK_T HMTX
1450
#define INITIAL_LOCK(l)      DosCreateMutexSem(0, l, 0, FALSE)
1451
#define ACQUIRE_LOCK(l)      DosRequestMutexSem(*l, SEM_INDEFINITE_WAIT)
1452
#define RELEASE_LOCK(l)      DosReleaseMutexSem(*l)
1453
#if HAVE_MORECORE
1454
static MLOCK_T morecore_mutex;
1455
#endif /* HAVE_MORECORE */
1456
static MLOCK_T magic_init_mutex;
1457
 
1458
#else /* WIN32 */
1459
/*
1460
   Because lock-protected regions have bounded times, and there
1461
   are no recursive lock calls, we can use simple spinlocks.
1462
*/
1463
 
1464
#define MLOCK_T long
1465
static int win32_acquire_lock (MLOCK_T *sl) {
1466
  for (;;) {
1467
#ifdef InterlockedCompareExchangePointer
1468
    if (!InterlockedCompareExchange(sl, 1, 0))
1469
      return 0;
1470
#else  /* Use older void* version */
1471
    if (!InterlockedCompareExchange((void**)sl, (void*)1, (void*)0))
1472
      return 0;
1473
#endif /* InterlockedCompareExchangePointer */
1474
    Sleep (0);
1475
  }
1476
}
1477
 
1478
static void win32_release_lock (MLOCK_T *sl) {
1479
  InterlockedExchange (sl, 0);
1480
}
1481
 
1482
#define INITIAL_LOCK(l)      *(l)=0
1483
#define ACQUIRE_LOCK(l)      win32_acquire_lock(l)
1484
#define RELEASE_LOCK(l)      win32_release_lock(l)
1485
#if HAVE_MORECORE
1486
static MLOCK_T morecore_mutex;
1487
#endif /* HAVE_MORECORE */
1488
static MLOCK_T magic_init_mutex;
1489
#endif /* WIN32 */
1490
 
1491
#define USE_LOCK_BIT               (2U)
1492
#else  /* USE_LOCKS */
1493
#define USE_LOCK_BIT               (0U)
1494
#define INITIAL_LOCK(l)
1495
#endif /* USE_LOCKS */
1496
 
1497
#if USE_LOCKS && HAVE_MORECORE
1498
#define ACQUIRE_MORECORE_LOCK()    ACQUIRE_LOCK(&morecore_mutex);
1499
#define RELEASE_MORECORE_LOCK()    RELEASE_LOCK(&morecore_mutex);
1500
#else /* USE_LOCKS && HAVE_MORECORE */
1501
#define ACQUIRE_MORECORE_LOCK()
1502
#define RELEASE_MORECORE_LOCK()
1503
#endif /* USE_LOCKS && HAVE_MORECORE */
1504
 
1505
#if USE_LOCKS
1506
#define ACQUIRE_MAGIC_INIT_LOCK()  ACQUIRE_LOCK(&magic_init_mutex);
1507
#define RELEASE_MAGIC_INIT_LOCK()  RELEASE_LOCK(&magic_init_mutex);
1508
#else  /* USE_LOCKS */
1509
#define ACQUIRE_MAGIC_INIT_LOCK()
1510
#define RELEASE_MAGIC_INIT_LOCK()
1511
#endif /* USE_LOCKS */
1512
 
1513
 
1514
/* -----------------------  Chunk representations ------------------------ */
1515
 
1516
/*
1517
  (The following includes lightly edited explanations by Colin Plumb.)
1518
 
1519
  The malloc_chunk declaration below is misleading (but accurate and
1520
  necessary).  It declares a "view" into memory allowing access to
1521
  necessary fields at known offsets from a given base.
1522
 
1523
  Chunks of memory are maintained using a `boundary tag' method as
1524
  originally described by Knuth.  (See the paper by Paul Wilson
1525
  ftp://ftp.cs.utexas.edu/pub/garbage/allocsrv.ps for a survey of such
1526
  techniques.)  Sizes of free chunks are stored both in the front of
1527
  each chunk and at the end.  This makes consolidating fragmented
1528
  chunks into bigger chunks fast.  The head fields also hold bits
1529
  representing whether chunks are free or in use.
1530
 
1531
  Here are some pictures to make it clearer.  They are "exploded" to
1532
  show that the state of a chunk can be thought of as extending from
1533
  the high 31 bits of the head field of its header through the
1534
  prev_foot and PINUSE_BIT bit of the following chunk header.
1535
 
1536
  A chunk that's in use looks like:
1537
 
1538
   chunk-> +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
1539
           | Size of previous chunk (if P = 1)                             |
1540
           +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
1541
         +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ |P|
1542
         | Size of this chunk                                         1| +-+
1543
   mem-> +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
1544
         |                                                               |
1545
         +-                                                             -+
1546
         |                                                               |
1547
         +-                                                             -+
1548
         |                                                               :
1549
         +-      size - sizeof(size_t) available payload bytes          -+
1550
         :                                                               |
1551
 chunk-> +-                                                             -+
1552
         |                                                               |
1553
         +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
1554
       +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ |1|
1555
       | Size of next chunk (may or may not be in use)               | +-+
1556
 mem-> +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
1557
 
1558
    And if it's free, it looks like this:
1559
 
1560
   chunk-> +-                                                             -+
1561
           | User payload (must be in use, or we would have merged!)       |
1562
           +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
1563
         +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ |P|
1564
         | Size of this chunk                                         0| +-+
1565
   mem-> +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
1566
         | Next pointer                                                  |
1567
         +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
1568
         | Prev pointer                                                  |
1569
         +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
1570
         |                                                               :
1571
         +-      size - sizeof(struct chunk) unused bytes               -+
1572
         :                                                               |
1573
 chunk-> +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
1574
         | Size of this chunk                                            |
1575
         +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
1576
       +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ |0|
1577
       | Size of next chunk (must be in use, or we would have merged)| +-+
1578
 mem-> +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
1579
       |                                                               :
1580
       +- User payload                                                -+
1581
       :                                                               |
1582
       +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
1583
                                                                     |0|
1584
                                                                     +-+
1585
  Note that since we always merge adjacent free chunks, the chunks
1586
  adjacent to a free chunk must be in use.
1587
 
1588
  Given a pointer to a chunk (which can be derived trivially from the
1589
  payload pointer) we can, in O(1) time, find out whether the adjacent
1590
  chunks are free, and if so, unlink them from the lists that they
1591
  are on and merge them with the current chunk.
1592
 
1593
  Chunks always begin on even word boundaries, so the mem portion
1594
  (which is returned to the user) is also on an even word boundary, and
1595
  thus at least double-word aligned.
1596
 
1597
  The P (PINUSE_BIT) bit, stored in the unused low-order bit of the
1598
  chunk size (which is always a multiple of two words), is an in-use
1599
  bit for the *previous* chunk.  If that bit is *clear*, then the
1600
  word before the current chunk size contains the previous chunk
1601
  size, and can be used to find the front of the previous chunk.
1602
  The very first chunk allocated always has this bit set, preventing
1603
  access to non-existent (or non-owned) memory. If pinuse is set for
1604
  any given chunk, then you CANNOT determine the size of the
1605
  previous chunk, and might even get a memory addressing fault when
1606
  trying to do so.
1607
 
1608
  The C (CINUSE_BIT) bit, stored in the unused second-lowest bit of
1609
  the chunk size redundantly records whether the current chunk is
1610
  inuse. This redundancy enables usage checks within free and realloc,
1611
  and reduces indirection when freeing and consolidating chunks.
1612
 
1613
  Each freshly allocated chunk must have both cinuse and pinuse set.
1614
  That is, each allocated chunk borders either a previously allocated
1615
  and still in-use chunk, or the base of its memory arena. This is
1616
  ensured by making all allocations from the the `lowest' part of any
1617
  found chunk.  Further, no free chunk physically borders another one,
1618
  so each free chunk is known to be preceded and followed by either
1619
  inuse chunks or the ends of memory.
1620
 
1621
  Note that the `foot' of the current chunk is actually represented
1622
  as the prev_foot of the NEXT chunk. This makes it easier to
1623
  deal with alignments etc but can be very confusing when trying
1624
  to extend or adapt this code.
1625
 
1626
  The exceptions to all this are
1627
 
1628
     1. The special chunk `top' is the top-most available chunk (i.e.,
1629
        the one bordering the end of available memory). It is treated
1630
        specially.  Top is never included in any bin, is used only if
1631
        no other chunk is available, and is released back to the
1632
        system if it is very large (see M_TRIM_THRESHOLD).  In effect,
1633
        the top chunk is treated as larger (and thus less well
1634
        fitting) than any other available chunk.  The top chunk
1635
        doesn't update its trailing size field since there is no next
1636
        contiguous chunk that would have to index off it. However,
1637
        space is still allocated for it (TOP_FOOT_SIZE) to enable
1638
        separation or merging when space is extended.
1639
 
1640
     3. Chunks allocated via mmap, which have the lowest-order bit
1641
        (IS_MMAPPED_BIT) set in their prev_foot fields, and do not set
1642
        PINUSE_BIT in their head fields.  Because they are allocated
1643
        one-by-one, each must carry its own prev_foot field, which is
1644
        also used to hold the offset this chunk has within its mmapped
1645
        region, which is needed to preserve alignment. Each mmapped
1646
        chunk is trailed by the first two fields of a fake next-chunk
1647
        for sake of usage checks.
1648
 
1649
*/
1650
 
1651
struct malloc_chunk {
1652
  size_t               prev_foot;  /* Size of previous chunk (if free).  */
1653
  size_t               head;       /* Size and inuse bits. */
1654
  struct malloc_chunk* fd;         /* double links -- used only if free. */
1655
  struct malloc_chunk* bk;
1656
};
1657
 
1658
typedef struct malloc_chunk  mchunk;
1659
typedef struct malloc_chunk* mchunkptr;
1660
typedef struct malloc_chunk* sbinptr;  /* The type of bins of chunks */
1661
typedef unsigned int bindex_t;         /* Described below */
1662
typedef unsigned int binmap_t;         /* Described below */
1663
typedef unsigned int flag_t;           /* The type of various bit flag sets */
1664
 
1665
/* ------------------- Chunks sizes and alignments ----------------------- */
1666
 
1667
#define MCHUNK_SIZE         (sizeof(mchunk))
1668
 
1669
#if FOOTERS
1670
#define CHUNK_OVERHEAD      (TWO_SIZE_T_SIZES)
1671
#else /* FOOTERS */
1672
#define CHUNK_OVERHEAD      (SIZE_T_SIZE)
1673
#endif /* FOOTERS */
1674
 
1675
/* MMapped chunks need a second word of overhead ... */
1676
#define MMAP_CHUNK_OVERHEAD (TWO_SIZE_T_SIZES)
1677
/* ... and additional padding for fake next-chunk at foot */
1678
#define MMAP_FOOT_PAD       (FOUR_SIZE_T_SIZES)
1679
 
1680
/* The smallest size we can malloc is an aligned minimal chunk */
1681
#define MIN_CHUNK_SIZE\
1682
  ((MCHUNK_SIZE + CHUNK_ALIGN_MASK) & ~CHUNK_ALIGN_MASK)
1683
 
1684
/* conversion from malloc headers to user pointers, and back */
1685
#define chunk2mem(p)        ((void*)((char*)(p)       + TWO_SIZE_T_SIZES))
1686
#define mem2chunk(mem)      ((mchunkptr)((char*)(mem) - TWO_SIZE_T_SIZES))
1687
/* chunk associated with aligned address A */
1688
#define align_as_chunk(A)   (mchunkptr)((A) + align_offset(chunk2mem(A)))
1689
 
1690
/* Bounds on request (not chunk) sizes. */
1691
#define MAX_REQUEST         ((-MIN_CHUNK_SIZE) << 2)
1692
#define MIN_REQUEST         (MIN_CHUNK_SIZE - CHUNK_OVERHEAD - SIZE_T_ONE)
1693
 
1694
/* pad request bytes into a usable size */
1695
#define pad_request(req) \
1696
   (((req) + CHUNK_OVERHEAD + CHUNK_ALIGN_MASK) & ~CHUNK_ALIGN_MASK)
1697
 
1698
/* pad request, checking for minimum (but not maximum) */
1699
#define request2size(req) \
1700
  (((req) < MIN_REQUEST)? MIN_CHUNK_SIZE : pad_request(req))
1701
 
1702
 
1703
/* ------------------ Operations on head and foot fields ----------------- */
1704
 
1705
/*
1706
  The head field of a chunk is or'ed with PINUSE_BIT when previous
1707
  adjacent chunk in use, and or'ed with CINUSE_BIT if this chunk is in
1708
  use. If the chunk was obtained with mmap, the prev_foot field has
1709
  IS_MMAPPED_BIT set, otherwise holding the offset of the base of the
1710
  mmapped region to the base of the chunk.
1711
*/
1712
 
1713
#define PINUSE_BIT          (SIZE_T_ONE)
1714
#define CINUSE_BIT          (SIZE_T_TWO)
1715
#define INUSE_BITS          (PINUSE_BIT|CINUSE_BIT)
1716
 
1717
/* Head value for fenceposts */
1718
#define FENCEPOST_HEAD      (INUSE_BITS|SIZE_T_SIZE)
1719
 
1720
/* extraction of fields from head words */
1721
#define cinuse(p)           ((p)->head & CINUSE_BIT)
1722
#define pinuse(p)           ((p)->head & PINUSE_BIT)
1723
#define chunksize(p)        ((p)->head & ~(INUSE_BITS))
1724
 
1725
#define clear_pinuse(p)     ((p)->head &= ~PINUSE_BIT)
1726
#define clear_cinuse(p)     ((p)->head &= ~CINUSE_BIT)
1727
 
1728
/* Treat space at ptr +/- offset as a chunk */
1729
#define chunk_plus_offset(p, s)  ((mchunkptr)(((char*)(p)) + (s)))
1730
#define chunk_minus_offset(p, s) ((mchunkptr)(((char*)(p)) - (s)))
1731
 
1732
/* Ptr to next or previous physical malloc_chunk. */
1733
#define next_chunk(p) ((mchunkptr)( ((char*)(p)) + ((p)->head & ~INUSE_BITS)))
1734
#define prev_chunk(p) ((mchunkptr)( ((char*)(p)) - ((p)->prev_foot) ))
1735
 
1736
/* extract next chunk's pinuse bit */
1737
#define next_pinuse(p)  ((next_chunk(p)->head) & PINUSE_BIT)
1738
 
1739
/* Get/set size at footer */
1740
#define get_foot(p, s)  (((mchunkptr)((char*)(p) + (s)))->prev_foot)
1741
#define set_foot(p, s)  (((mchunkptr)((char*)(p) + (s)))->prev_foot = (s))
1742
 
1743
/* Set size, pinuse bit, and foot */
1744
#define set_size_and_pinuse_of_free_chunk(p, s)\
1745
  ((p)->head = (s|PINUSE_BIT), set_foot(p, s))
1746
 
1747
/* Set size, pinuse bit, foot, and clear next pinuse */
1748
#define set_free_with_pinuse(p, s, n)\
1749
  (clear_pinuse(n), set_size_and_pinuse_of_free_chunk(p, s))
1750
 
1751
#define is_mmapped(p)\
1752
  (!((p)->head & PINUSE_BIT) && ((p)->prev_foot & IS_MMAPPED_BIT))
1753
 
1754
/* Get the internal overhead associated with chunk p */
1755
#define overhead_for(p)\
1756
 (is_mmapped(p)? MMAP_CHUNK_OVERHEAD : CHUNK_OVERHEAD)
1757
 
1758
/* Return true if malloced space is not necessarily cleared */
1759
#if MMAP_CLEARS
1760
#define calloc_must_clear(p) (!is_mmapped(p))
1761
#else /* MMAP_CLEARS */
1762
#define calloc_must_clear(p) (1)
1763
#endif /* MMAP_CLEARS */
1764
 
1765
/* ---------------------- Overlaid data structures ----------------------- */
1766
 
1767
/*
1768
  When chunks are not in use, they are treated as nodes of either
1769
  lists or trees.
1770
 
1771
  "Small"  chunks are stored in circular doubly-linked lists, and look
1772
  like this:
1773
 
1774
    chunk-> +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
1775
            |             Size of previous chunk                            |
1776
            +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
1777
    `head:' |             Size of chunk, in bytes                         |P|
1778
      mem-> +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
1779
            |             Forward pointer to next chunk in list             |
1780
            +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
1781
            |             Back pointer to previous chunk in list            |
1782
            +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
1783
            |             Unused space (may be 0 bytes long)                .
1784
            .                                                               .
1785
            .                                                               |
1786
nextchunk-> +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
1787
    `foot:' |             Size of chunk, in bytes                           |
1788
            +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
1789
 
1790
  Larger chunks are kept in a form of bitwise digital trees (aka
1791
  tries) keyed on chunksizes.  Because malloc_tree_chunks are only for
1792
  free chunks greater than 256 bytes, their size doesn't impose any
1793
  constraints on user chunk sizes.  Each node looks like:
1794
 
1795
    chunk-> +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
1796
            |             Size of previous chunk                            |
1797
            +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
1798
    `head:' |             Size of chunk, in bytes                         |P|
1799
      mem-> +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
1800
            |             Forward pointer to next chunk of same size        |
1801
            +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
1802
            |             Back pointer to previous chunk of same size       |
1803
            +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
1804
            |             Pointer to left child (child[0])                  |
1805
            +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
1806
            |             Pointer to right child (child[1])                 |
1807
            +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
1808
            |             Pointer to parent                                 |
1809
            +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
1810
            |             bin index of this chunk                           |
1811
            +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
1812
            |             Unused space                                      .
1813
            .                                                               |
1814
nextchunk-> +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
1815
    `foot:' |             Size of chunk, in bytes                           |
1816
            +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
1817
 
1818
  Each tree holding treenodes is a tree of unique chunk sizes.  Chunks
1819
  of the same size are arranged in a circularly-linked list, with only
1820
  the oldest chunk (the next to be used, in our FIFO ordering)
1821
  actually in the tree.  (Tree members are distinguished by a non-null
1822
  parent pointer.)  If a chunk with the same size an an existing node
1823
  is inserted, it is linked off the existing node using pointers that
1824
  work in the same way as fd/bk pointers of small chunks.
1825
 
1826
  Each tree contains a power of 2 sized range of chunk sizes (the
1827
  smallest is 0x100 <= x < 0x180), which is is divided in half at each
1828
  tree level, with the chunks in the smaller half of the range (0x100
1829
  <= x < 0x140 for the top nose) in the left subtree and the larger
1830
  half (0x140 <= x < 0x180) in the right subtree.  This is, of course,
1831
  done by inspecting individual bits.
1832
 
1833
  Using these rules, each node's left subtree contains all smaller
1834
  sizes than its right subtree.  However, the node at the root of each
1835
  subtree has no particular ordering relationship to either.  (The
1836
  dividing line between the subtree sizes is based on trie relation.)
1837
  If we remove the last chunk of a given size from the interior of the
1838
  tree, we need to replace it with a leaf node.  The tree ordering
1839
  rules permit a node to be replaced by any leaf below it.
1840
 
1841
  The smallest chunk in a tree (a common operation in a best-fit
1842
  allocator) can be found by walking a path to the leftmost leaf in
1843
  the tree.  Unlike a usual binary tree, where we follow left child
1844
  pointers until we reach a null, here we follow the right child
1845
  pointer any time the left one is null, until we reach a leaf with
1846
  both child pointers null. The smallest chunk in the tree will be
1847
  somewhere along that path.
1848
 
1849
  The worst case number of steps to add, find, or remove a node is
1850
  bounded by the number of bits differentiating chunks within
1851
  bins. Under current bin calculations, this ranges from 6 up to 21
1852
  (for 32 bit sizes) or up to 53 (for 64 bit sizes). The typical case
1853
  is of course much better.
1854
*/
1855
 
1856
struct malloc_tree_chunk {
1857
  /* The first four fields must be compatible with malloc_chunk */
1858
  size_t                    prev_foot;
1859
  size_t                    head;
1860
  struct malloc_tree_chunk* fd;
1861
  struct malloc_tree_chunk* bk;
1862
 
1863
  struct malloc_tree_chunk* child[2];
1864
  struct malloc_tree_chunk* parent;
1865
  bindex_t                  index;
1866
};
1867
 
1868
typedef struct malloc_tree_chunk  tchunk;
1869
typedef struct malloc_tree_chunk* tchunkptr;
1870
typedef struct malloc_tree_chunk* tbinptr; /* The type of bins of trees */
1871
 
1872
/* A little helper macro for trees */
1873
#define leftmost_child(t) ((t)->child[0] != 0? (t)->child[0] : (t)->child[1])
1874
 
1875
/* ----------------------------- Segments -------------------------------- */
1876
 
1877
/*
1878
  Each malloc space may include non-contiguous segments, held in a
1879
  list headed by an embedded malloc_segment record representing the
1880
  top-most space. Segments also include flags holding properties of
1881
  the space. Large chunks that are directly allocated by mmap are not
1882
  included in this list. They are instead independently created and
1883
  destroyed without otherwise keeping track of them.
1884
 
1885
  Segment management mainly comes into play for spaces allocated by
1886
  MMAP.  Any call to MMAP might or might not return memory that is
1887
  adjacent to an existing segment.  MORECORE normally contiguously
1888
  extends the current space, so this space is almost always adjacent,
1889
  which is simpler and faster to deal with. (This is why MORECORE is
1890
  used preferentially to MMAP when both are available -- see
1891
  sys_alloc.)  When allocating using MMAP, we don't use any of the
1892
  hinting mechanisms (inconsistently) supported in various
1893
  implementations of unix mmap, or distinguish reserving from
1894
  committing memory. Instead, we just ask for space, and exploit
1895
  contiguity when we get it.  It is probably possible to do
1896
  better than this on some systems, but no general scheme seems
1897
  to be significantly better.
1898
 
1899
  Management entails a simpler variant of the consolidation scheme
1900
  used for chunks to reduce fragmentation -- new adjacent memory is
1901
  normally prepended or appended to an existing segment. However,
1902
  there are limitations compared to chunk consolidation that mostly
1903
  reflect the fact that segment processing is relatively infrequent
1904
  (occurring only when getting memory from system) and that we
1905
  don't expect to have huge numbers of segments:
1906
 
1907
  * Segments are not indexed, so traversal requires linear scans.  (It
1908
    would be possible to index these, but is not worth the extra
1909
    overhead and complexity for most programs on most platforms.)
1910
  * New segments are only appended to old ones when holding top-most
1911
    memory; if they cannot be prepended to others, they are held in
1912
    different segments.
1913
 
1914
  Except for the top-most segment of an mstate, each segment record
1915
  is kept at the tail of its segment. Segments are added by pushing
1916
  segment records onto the list headed by &mstate.seg for the
1917
  containing mstate.
1918
 
1919
  Segment flags control allocation/merge/deallocation policies:
1920
  * If EXTERN_BIT set, then we did not allocate this segment,
1921
    and so should not try to deallocate or merge with others.
1922
    (This currently holds only for the initial segment passed
1923
    into create_mspace_with_base.)
1924
  * If IS_MMAPPED_BIT set, the segment may be merged with
1925
    other surrounding mmapped segments and trimmed/de-allocated
1926
    using munmap.
1927
  * If neither bit is set, then the segment was obtained using
1928
    MORECORE so can be merged with surrounding MORECORE'd segments
1929
    and deallocated/trimmed using MORECORE with negative arguments.
1930
*/
1931
 
1932
struct malloc_segment {
1933
  char*        base;             /* base address */
1934
  size_t       size;             /* allocated size */
1935
  struct malloc_segment* next;   /* ptr to next segment */
1936
#if FFI_MMAP_EXEC_WRIT
1937
  /* The mmap magic is supposed to store the address of the executable
1938
     segment at the very end of the requested block.  */
1939
 
1940
# define mmap_exec_offset(b,s) (*(ptrdiff_t*)((b)+(s)-sizeof(ptrdiff_t)))
1941
 
1942
  /* We can only merge segments if their corresponding executable
1943
     segments are at identical offsets.  */
1944
# define check_segment_merge(S,b,s) \
1945
  (mmap_exec_offset((b),(s)) == (S)->exec_offset)
1946
 
1947
# define add_segment_exec_offset(p,S) ((char*)(p) + (S)->exec_offset)
1948
# define sub_segment_exec_offset(p,S) ((char*)(p) - (S)->exec_offset)
1949
 
1950
  /* The removal of sflags only works with HAVE_MORECORE == 0.  */
1951
 
1952
# define get_segment_flags(S)   (IS_MMAPPED_BIT)
1953
# define set_segment_flags(S,v) \
1954
  (((v) != IS_MMAPPED_BIT) ? (ABORT, (v)) :                             \
1955
   (((S)->exec_offset =                                                 \
1956
     mmap_exec_offset((S)->base, (S)->size)),                           \
1957
    (mmap_exec_offset((S)->base + (S)->exec_offset, (S)->size) !=       \
1958
     (S)->exec_offset) ? (ABORT, (v)) :                                 \
1959
   (mmap_exec_offset((S)->base, (S)->size) = 0), (v)))
1960
 
1961
  /* We use an offset here, instead of a pointer, because then, when
1962
     base changes, we don't have to modify this.  On architectures
1963
     with segmented addresses, this might not work.  */
1964
  ptrdiff_t    exec_offset;
1965
#else
1966
 
1967
# define get_segment_flags(S)   ((S)->sflags)
1968
# define set_segment_flags(S,v) ((S)->sflags = (v))
1969
# define check_segment_merge(S,b,s) (1)
1970
 
1971
  flag_t       sflags;           /* mmap and extern flag */
1972
#endif
1973
};
1974
 
1975
#define is_mmapped_segment(S)  (get_segment_flags(S) & IS_MMAPPED_BIT)
1976
#define is_extern_segment(S)   (get_segment_flags(S) & EXTERN_BIT)
1977
 
1978
typedef struct malloc_segment  msegment;
1979
typedef struct malloc_segment* msegmentptr;
1980
 
1981
/* ---------------------------- malloc_state ----------------------------- */
1982
 
1983
/*
1984
   A malloc_state holds all of the bookkeeping for a space.
1985
   The main fields are:
1986
 
1987
  Top
1988
    The topmost chunk of the currently active segment. Its size is
1989
    cached in topsize.  The actual size of topmost space is
1990
    topsize+TOP_FOOT_SIZE, which includes space reserved for adding
1991
    fenceposts and segment records if necessary when getting more
1992
    space from the system.  The size at which to autotrim top is
1993
    cached from mparams in trim_check, except that it is disabled if
1994
    an autotrim fails.
1995
 
1996
  Designated victim (dv)
1997
    This is the preferred chunk for servicing small requests that
1998
    don't have exact fits.  It is normally the chunk split off most
1999
    recently to service another small request.  Its size is cached in
2000
    dvsize. The link fields of this chunk are not maintained since it
2001
    is not kept in a bin.
2002
 
2003
  SmallBins
2004
    An array of bin headers for free chunks.  These bins hold chunks
2005
    with sizes less than MIN_LARGE_SIZE bytes. Each bin contains
2006
    chunks of all the same size, spaced 8 bytes apart.  To simplify
2007
    use in double-linked lists, each bin header acts as a malloc_chunk
2008
    pointing to the real first node, if it exists (else pointing to
2009
    itself).  This avoids special-casing for headers.  But to avoid
2010
    waste, we allocate only the fd/bk pointers of bins, and then use
2011
    repositioning tricks to treat these as the fields of a chunk.
2012
 
2013
  TreeBins
2014
    Treebins are pointers to the roots of trees holding a range of
2015
    sizes. There are 2 equally spaced treebins for each power of two
2016
    from TREE_SHIFT to TREE_SHIFT+16. The last bin holds anything
2017
    larger.
2018
 
2019
  Bin maps
2020
    There is one bit map for small bins ("smallmap") and one for
2021
    treebins ("treemap).  Each bin sets its bit when non-empty, and
2022
    clears the bit when empty.  Bit operations are then used to avoid
2023
    bin-by-bin searching -- nearly all "search" is done without ever
2024
    looking at bins that won't be selected.  The bit maps
2025
    conservatively use 32 bits per map word, even if on 64bit system.
2026
    For a good description of some of the bit-based techniques used
2027
    here, see Henry S. Warren Jr's book "Hacker's Delight" (and
2028
    supplement at http://hackersdelight.org/). Many of these are
2029
    intended to reduce the branchiness of paths through malloc etc, as
2030
    well as to reduce the number of memory locations read or written.
2031
 
2032
  Segments
2033
    A list of segments headed by an embedded malloc_segment record
2034
    representing the initial space.
2035
 
2036
  Address check support
2037
    The least_addr field is the least address ever obtained from
2038
    MORECORE or MMAP. Attempted frees and reallocs of any address less
2039
    than this are trapped (unless INSECURE is defined).
2040
 
2041
  Magic tag
2042
    A cross-check field that should always hold same value as mparams.magic.
2043
 
2044
  Flags
2045
    Bits recording whether to use MMAP, locks, or contiguous MORECORE
2046
 
2047
  Statistics
2048
    Each space keeps track of current and maximum system memory
2049
    obtained via MORECORE or MMAP.
2050
 
2051
  Locking
2052
    If USE_LOCKS is defined, the "mutex" lock is acquired and released
2053
    around every public call using this mspace.
2054
*/
2055
 
2056
/* Bin types, widths and sizes */
2057
#define NSMALLBINS        (32U)
2058
#define NTREEBINS         (32U)
2059
#define SMALLBIN_SHIFT    (3U)
2060
#define SMALLBIN_WIDTH    (SIZE_T_ONE << SMALLBIN_SHIFT)
2061
#define TREEBIN_SHIFT     (8U)
2062
#define MIN_LARGE_SIZE    (SIZE_T_ONE << TREEBIN_SHIFT)
2063
#define MAX_SMALL_SIZE    (MIN_LARGE_SIZE - SIZE_T_ONE)
2064
#define MAX_SMALL_REQUEST (MAX_SMALL_SIZE - CHUNK_ALIGN_MASK - CHUNK_OVERHEAD)
2065
 
2066
struct malloc_state {
2067
  binmap_t   smallmap;
2068
  binmap_t   treemap;
2069
  size_t     dvsize;
2070
  size_t     topsize;
2071
  char*      least_addr;
2072
  mchunkptr  dv;
2073
  mchunkptr  top;
2074
  size_t     trim_check;
2075
  size_t     magic;
2076
  mchunkptr  smallbins[(NSMALLBINS+1)*2];
2077
  tbinptr    treebins[NTREEBINS];
2078
  size_t     footprint;
2079
  size_t     max_footprint;
2080
  flag_t     mflags;
2081
#if USE_LOCKS
2082
  MLOCK_T    mutex;     /* locate lock among fields that rarely change */
2083
#endif /* USE_LOCKS */
2084
  msegment   seg;
2085
};
2086
 
2087
typedef struct malloc_state*    mstate;
2088
 
2089
/* ------------- Global malloc_state and malloc_params ------------------- */
2090
 
2091
/*
2092
  malloc_params holds global properties, including those that can be
2093
  dynamically set using mallopt. There is a single instance, mparams,
2094
  initialized in init_mparams.
2095
*/
2096
 
2097
struct malloc_params {
2098
  size_t magic;
2099
  size_t page_size;
2100
  size_t granularity;
2101
  size_t mmap_threshold;
2102
  size_t trim_threshold;
2103
  flag_t default_mflags;
2104
};
2105
 
2106
static struct malloc_params mparams;
2107
 
2108
/* The global malloc_state used for all non-"mspace" calls */
2109
static struct malloc_state _gm_;
2110
#define gm                 (&_gm_)
2111
#define is_global(M)       ((M) == &_gm_)
2112
#define is_initialized(M)  ((M)->top != 0)
2113
 
2114
/* -------------------------- system alloc setup ------------------------- */
2115
 
2116
/* Operations on mflags */
2117
 
2118
#define use_lock(M)           ((M)->mflags &   USE_LOCK_BIT)
2119
#define enable_lock(M)        ((M)->mflags |=  USE_LOCK_BIT)
2120
#define disable_lock(M)       ((M)->mflags &= ~USE_LOCK_BIT)
2121
 
2122
#define use_mmap(M)           ((M)->mflags &   USE_MMAP_BIT)
2123
#define enable_mmap(M)        ((M)->mflags |=  USE_MMAP_BIT)
2124
#define disable_mmap(M)       ((M)->mflags &= ~USE_MMAP_BIT)
2125
 
2126
#define use_noncontiguous(M)  ((M)->mflags &   USE_NONCONTIGUOUS_BIT)
2127
#define disable_contiguous(M) ((M)->mflags |=  USE_NONCONTIGUOUS_BIT)
2128
 
2129
#define set_lock(M,L)\
2130
 ((M)->mflags = (L)?\
2131
  ((M)->mflags | USE_LOCK_BIT) :\
2132
  ((M)->mflags & ~USE_LOCK_BIT))
2133
 
2134
/* page-align a size */
2135
#define page_align(S)\
2136
 (((S) + (mparams.page_size)) & ~(mparams.page_size - SIZE_T_ONE))
2137
 
2138
/* granularity-align a size */
2139
#define granularity_align(S)\
2140
  (((S) + (mparams.granularity)) & ~(mparams.granularity - SIZE_T_ONE))
2141
 
2142
#define is_page_aligned(S)\
2143
   (((size_t)(S) & (mparams.page_size - SIZE_T_ONE)) == 0)
2144
#define is_granularity_aligned(S)\
2145
   (((size_t)(S) & (mparams.granularity - SIZE_T_ONE)) == 0)
2146
 
2147
/*  True if segment S holds address A */
2148
#define segment_holds(S, A)\
2149
  ((char*)(A) >= S->base && (char*)(A) < S->base + S->size)
2150
 
2151
/* Return segment holding given address */
2152
static msegmentptr segment_holding(mstate m, char* addr) {
2153
  msegmentptr sp = &m->seg;
2154
  for (;;) {
2155
    if (addr >= sp->base && addr < sp->base + sp->size)
2156
      return sp;
2157
    if ((sp = sp->next) == 0)
2158
      return 0;
2159
  }
2160
}
2161
 
2162
/* Return true if segment contains a segment link */
2163
static int has_segment_link(mstate m, msegmentptr ss) {
2164
  msegmentptr sp = &m->seg;
2165
  for (;;) {
2166
    if ((char*)sp >= ss->base && (char*)sp < ss->base + ss->size)
2167
      return 1;
2168
    if ((sp = sp->next) == 0)
2169
      return 0;
2170
  }
2171
}
2172
 
2173
#ifndef MORECORE_CANNOT_TRIM
2174
#define should_trim(M,s)  ((s) > (M)->trim_check)
2175
#else  /* MORECORE_CANNOT_TRIM */
2176
#define should_trim(M,s)  (0)
2177
#endif /* MORECORE_CANNOT_TRIM */
2178
 
2179
/*
2180
  TOP_FOOT_SIZE is padding at the end of a segment, including space
2181
  that may be needed to place segment records and fenceposts when new
2182
  noncontiguous segments are added.
2183
*/
2184
#define TOP_FOOT_SIZE\
2185
  (align_offset(chunk2mem(0))+pad_request(sizeof(struct malloc_segment))+MIN_CHUNK_SIZE)
2186
 
2187
 
2188
/* -------------------------------  Hooks -------------------------------- */
2189
 
2190
/*
2191
  PREACTION should be defined to return 0 on success, and nonzero on
2192
  failure. If you are not using locking, you can redefine these to do
2193
  anything you like.
2194
*/
2195
 
2196
#if USE_LOCKS
2197
 
2198
/* Ensure locks are initialized */
2199
#define GLOBALLY_INITIALIZE() (mparams.page_size == 0 && init_mparams())
2200
 
2201
#define PREACTION(M)  ((GLOBALLY_INITIALIZE() || use_lock(M))? ACQUIRE_LOCK(&(M)->mutex) : 0)
2202
#define POSTACTION(M) { if (use_lock(M)) RELEASE_LOCK(&(M)->mutex); }
2203
#else /* USE_LOCKS */
2204
 
2205
#ifndef PREACTION
2206
#define PREACTION(M) (0)
2207
#endif  /* PREACTION */
2208
 
2209
#ifndef POSTACTION
2210
#define POSTACTION(M)
2211
#endif  /* POSTACTION */
2212
 
2213
#endif /* USE_LOCKS */
2214
 
2215
/*
2216
  CORRUPTION_ERROR_ACTION is triggered upon detected bad addresses.
2217
  USAGE_ERROR_ACTION is triggered on detected bad frees and
2218
  reallocs. The argument p is an address that might have triggered the
2219
  fault. It is ignored by the two predefined actions, but might be
2220
  useful in custom actions that try to help diagnose errors.
2221
*/
2222
 
2223
#if PROCEED_ON_ERROR
2224
 
2225
/* A count of the number of corruption errors causing resets */
2226
int malloc_corruption_error_count;
2227
 
2228
/* default corruption action */
2229
static void reset_on_error(mstate m);
2230
 
2231
#define CORRUPTION_ERROR_ACTION(m)  reset_on_error(m)
2232
#define USAGE_ERROR_ACTION(m, p)
2233
 
2234
#else /* PROCEED_ON_ERROR */
2235
 
2236
#ifndef CORRUPTION_ERROR_ACTION
2237
#define CORRUPTION_ERROR_ACTION(m) ABORT
2238
#endif /* CORRUPTION_ERROR_ACTION */
2239
 
2240
#ifndef USAGE_ERROR_ACTION
2241
#define USAGE_ERROR_ACTION(m,p) ABORT
2242
#endif /* USAGE_ERROR_ACTION */
2243
 
2244
#endif /* PROCEED_ON_ERROR */
2245
 
2246
/* -------------------------- Debugging setup ---------------------------- */
2247
 
2248
#if ! DEBUG
2249
 
2250
#define check_free_chunk(M,P)
2251
#define check_inuse_chunk(M,P)
2252
#define check_malloced_chunk(M,P,N)
2253
#define check_mmapped_chunk(M,P)
2254
#define check_malloc_state(M)
2255
#define check_top_chunk(M,P)
2256
 
2257
#else /* DEBUG */
2258
#define check_free_chunk(M,P)       do_check_free_chunk(M,P)
2259
#define check_inuse_chunk(M,P)      do_check_inuse_chunk(M,P)
2260
#define check_top_chunk(M,P)        do_check_top_chunk(M,P)
2261
#define check_malloced_chunk(M,P,N) do_check_malloced_chunk(M,P,N)
2262
#define check_mmapped_chunk(M,P)    do_check_mmapped_chunk(M,P)
2263
#define check_malloc_state(M)       do_check_malloc_state(M)
2264
 
2265
static void   do_check_any_chunk(mstate m, mchunkptr p);
2266
static void   do_check_top_chunk(mstate m, mchunkptr p);
2267
static void   do_check_mmapped_chunk(mstate m, mchunkptr p);
2268
static void   do_check_inuse_chunk(mstate m, mchunkptr p);
2269
static void   do_check_free_chunk(mstate m, mchunkptr p);
2270
static void   do_check_malloced_chunk(mstate m, void* mem, size_t s);
2271
static void   do_check_tree(mstate m, tchunkptr t);
2272
static void   do_check_treebin(mstate m, bindex_t i);
2273
static void   do_check_smallbin(mstate m, bindex_t i);
2274
static void   do_check_malloc_state(mstate m);
2275
static int    bin_find(mstate m, mchunkptr x);
2276
static size_t traverse_and_check(mstate m);
2277
#endif /* DEBUG */
2278
 
2279
/* ---------------------------- Indexing Bins ---------------------------- */
2280
 
2281
#define is_small(s)         (((s) >> SMALLBIN_SHIFT) < NSMALLBINS)
2282
#define small_index(s)      ((s)  >> SMALLBIN_SHIFT)
2283
#define small_index2size(i) ((i)  << SMALLBIN_SHIFT)
2284
#define MIN_SMALL_INDEX     (small_index(MIN_CHUNK_SIZE))
2285
 
2286
/* addressing by index. See above about smallbin repositioning */
2287
#define smallbin_at(M, i)   ((sbinptr)((char*)&((M)->smallbins[(i)<<1])))
2288
#define treebin_at(M,i)     (&((M)->treebins[i]))
2289
 
2290
/* assign tree index for size S to variable I */
2291
#if defined(__GNUC__) && defined(i386)
2292
#define compute_tree_index(S, I)\
2293
{\
2294
  size_t X = S >> TREEBIN_SHIFT;\
2295
  if (X == 0)\
2296
    I = 0;\
2297
  else if (X > 0xFFFF)\
2298
    I = NTREEBINS-1;\
2299
  else {\
2300
    unsigned int K;\
2301
    __asm__("bsrl %1,%0\n\t" : "=r" (K) : "rm"  (X));\
2302
    I =  (bindex_t)((K << 1) + ((S >> (K + (TREEBIN_SHIFT-1)) & 1)));\
2303
  }\
2304
}
2305
#else /* GNUC */
2306
#define compute_tree_index(S, I)\
2307
{\
2308
  size_t X = S >> TREEBIN_SHIFT;\
2309
  if (X == 0)\
2310
    I = 0;\
2311
  else if (X > 0xFFFF)\
2312
    I = NTREEBINS-1;\
2313
  else {\
2314
    unsigned int Y = (unsigned int)X;\
2315
    unsigned int N = ((Y - 0x100) >> 16) & 8;\
2316
    unsigned int K = (((Y <<= N) - 0x1000) >> 16) & 4;\
2317
    N += K;\
2318
    N += K = (((Y <<= K) - 0x4000) >> 16) & 2;\
2319
    K = 14 - N + ((Y <<= K) >> 15);\
2320
    I = (K << 1) + ((S >> (K + (TREEBIN_SHIFT-1)) & 1));\
2321
  }\
2322
}
2323
#endif /* GNUC */
2324
 
2325
/* Bit representing maximum resolved size in a treebin at i */
2326
#define bit_for_tree_index(i) \
2327
   (i == NTREEBINS-1)? (SIZE_T_BITSIZE-1) : (((i) >> 1) + TREEBIN_SHIFT - 2)
2328
 
2329
/* Shift placing maximum resolved bit in a treebin at i as sign bit */
2330
#define leftshift_for_tree_index(i) \
2331
   ((i == NTREEBINS-1)? 0 : \
2332
    ((SIZE_T_BITSIZE-SIZE_T_ONE) - (((i) >> 1) + TREEBIN_SHIFT - 2)))
2333
 
2334
/* The size of the smallest chunk held in bin with index i */
2335
#define minsize_for_tree_index(i) \
2336
   ((SIZE_T_ONE << (((i) >> 1) + TREEBIN_SHIFT)) |  \
2337
   (((size_t)((i) & SIZE_T_ONE)) << (((i) >> 1) + TREEBIN_SHIFT - 1)))
2338
 
2339
 
2340
/* ------------------------ Operations on bin maps ----------------------- */
2341
 
2342
/* bit corresponding to given index */
2343
#define idx2bit(i)              ((binmap_t)(1) << (i))
2344
 
2345
/* Mark/Clear bits with given index */
2346
#define mark_smallmap(M,i)      ((M)->smallmap |=  idx2bit(i))
2347
#define clear_smallmap(M,i)     ((M)->smallmap &= ~idx2bit(i))
2348
#define smallmap_is_marked(M,i) ((M)->smallmap &   idx2bit(i))
2349
 
2350
#define mark_treemap(M,i)       ((M)->treemap  |=  idx2bit(i))
2351
#define clear_treemap(M,i)      ((M)->treemap  &= ~idx2bit(i))
2352
#define treemap_is_marked(M,i)  ((M)->treemap  &   idx2bit(i))
2353
 
2354
/* index corresponding to given bit */
2355
 
2356
#if defined(__GNUC__) && defined(i386)
2357
#define compute_bit2idx(X, I)\
2358
{\
2359
  unsigned int J;\
2360
  __asm__("bsfl %1,%0\n\t" : "=r" (J) : "rm" (X));\
2361
  I = (bindex_t)J;\
2362
}
2363
 
2364
#else /* GNUC */
2365
#if  USE_BUILTIN_FFS
2366
#define compute_bit2idx(X, I) I = ffs(X)-1
2367
 
2368
#else /* USE_BUILTIN_FFS */
2369
#define compute_bit2idx(X, I)\
2370
{\
2371
  unsigned int Y = X - 1;\
2372
  unsigned int K = Y >> (16-4) & 16;\
2373
  unsigned int N = K;        Y >>= K;\
2374
  N += K = Y >> (8-3) &  8;  Y >>= K;\
2375
  N += K = Y >> (4-2) &  4;  Y >>= K;\
2376
  N += K = Y >> (2-1) &  2;  Y >>= K;\
2377
  N += K = Y >> (1-0) &  1;  Y >>= K;\
2378
  I = (bindex_t)(N + Y);\
2379
}
2380
#endif /* USE_BUILTIN_FFS */
2381
#endif /* GNUC */
2382
 
2383
/* isolate the least set bit of a bitmap */
2384
#define least_bit(x)         ((x) & -(x))
2385
 
2386
/* mask with all bits to left of least bit of x on */
2387
#define left_bits(x)         ((x<<1) | -(x<<1))
2388
 
2389
/* mask with all bits to left of or equal to least bit of x on */
2390
#define same_or_left_bits(x) ((x) | -(x))
2391
 
2392
 
2393
/* ----------------------- Runtime Check Support ------------------------- */
2394
 
2395
/*
2396
  For security, the main invariant is that malloc/free/etc never
2397
  writes to a static address other than malloc_state, unless static
2398
  malloc_state itself has been corrupted, which cannot occur via
2399
  malloc (because of these checks). In essence this means that we
2400
  believe all pointers, sizes, maps etc held in malloc_state, but
2401
  check all of those linked or offsetted from other embedded data
2402
  structures.  These checks are interspersed with main code in a way
2403
  that tends to minimize their run-time cost.
2404
 
2405
  When FOOTERS is defined, in addition to range checking, we also
2406
  verify footer fields of inuse chunks, which can be used guarantee
2407
  that the mstate controlling malloc/free is intact.  This is a
2408
  streamlined version of the approach described by William Robertson
2409
  et al in "Run-time Detection of Heap-based Overflows" LISA'03
2410
  http://www.usenix.org/events/lisa03/tech/robertson.html The footer
2411
  of an inuse chunk holds the xor of its mstate and a random seed,
2412
  that is checked upon calls to free() and realloc().  This is
2413
  (probablistically) unguessable from outside the program, but can be
2414
  computed by any code successfully malloc'ing any chunk, so does not
2415
  itself provide protection against code that has already broken
2416
  security through some other means.  Unlike Robertson et al, we
2417
  always dynamically check addresses of all offset chunks (previous,
2418
  next, etc). This turns out to be cheaper than relying on hashes.
2419
*/
2420
 
2421
#if !INSECURE
2422
/* Check if address a is at least as high as any from MORECORE or MMAP */
2423
#define ok_address(M, a) ((char*)(a) >= (M)->least_addr)
2424
/* Check if address of next chunk n is higher than base chunk p */
2425
#define ok_next(p, n)    ((char*)(p) < (char*)(n))
2426
/* Check if p has its cinuse bit on */
2427
#define ok_cinuse(p)     cinuse(p)
2428
/* Check if p has its pinuse bit on */
2429
#define ok_pinuse(p)     pinuse(p)
2430
 
2431
#else /* !INSECURE */
2432
#define ok_address(M, a) (1)
2433
#define ok_next(b, n)    (1)
2434
#define ok_cinuse(p)     (1)
2435
#define ok_pinuse(p)     (1)
2436
#endif /* !INSECURE */
2437
 
2438
#if (FOOTERS && !INSECURE)
2439
/* Check if (alleged) mstate m has expected magic field */
2440
#define ok_magic(M)      ((M)->magic == mparams.magic)
2441
#else  /* (FOOTERS && !INSECURE) */
2442
#define ok_magic(M)      (1)
2443
#endif /* (FOOTERS && !INSECURE) */
2444
 
2445
 
2446
/* In gcc, use __builtin_expect to minimize impact of checks */
2447
#if !INSECURE
2448
#if defined(__GNUC__) && __GNUC__ >= 3
2449
#define RTCHECK(e)  __builtin_expect(e, 1)
2450
#else /* GNUC */
2451
#define RTCHECK(e)  (e)
2452
#endif /* GNUC */
2453
#else /* !INSECURE */
2454
#define RTCHECK(e)  (1)
2455
#endif /* !INSECURE */
2456
 
2457
/* macros to set up inuse chunks with or without footers */
2458
 
2459
#if !FOOTERS
2460
 
2461
#define mark_inuse_foot(M,p,s)
2462
 
2463
/* Set cinuse bit and pinuse bit of next chunk */
2464
#define set_inuse(M,p,s)\
2465
  ((p)->head = (((p)->head & PINUSE_BIT)|s|CINUSE_BIT),\
2466
  ((mchunkptr)(((char*)(p)) + (s)))->head |= PINUSE_BIT)
2467
 
2468
/* Set cinuse and pinuse of this chunk and pinuse of next chunk */
2469
#define set_inuse_and_pinuse(M,p,s)\
2470
  ((p)->head = (s|PINUSE_BIT|CINUSE_BIT),\
2471
  ((mchunkptr)(((char*)(p)) + (s)))->head |= PINUSE_BIT)
2472
 
2473
/* Set size, cinuse and pinuse bit of this chunk */
2474
#define set_size_and_pinuse_of_inuse_chunk(M, p, s)\
2475
  ((p)->head = (s|PINUSE_BIT|CINUSE_BIT))
2476
 
2477
#else /* FOOTERS */
2478
 
2479
/* Set foot of inuse chunk to be xor of mstate and seed */
2480
#define mark_inuse_foot(M,p,s)\
2481
  (((mchunkptr)((char*)(p) + (s)))->prev_foot = ((size_t)(M) ^ mparams.magic))
2482
 
2483
#define get_mstate_for(p)\
2484
  ((mstate)(((mchunkptr)((char*)(p) +\
2485
    (chunksize(p))))->prev_foot ^ mparams.magic))
2486
 
2487
#define set_inuse(M,p,s)\
2488
  ((p)->head = (((p)->head & PINUSE_BIT)|s|CINUSE_BIT),\
2489
  (((mchunkptr)(((char*)(p)) + (s)))->head |= PINUSE_BIT), \
2490
  mark_inuse_foot(M,p,s))
2491
 
2492
#define set_inuse_and_pinuse(M,p,s)\
2493
  ((p)->head = (s|PINUSE_BIT|CINUSE_BIT),\
2494
  (((mchunkptr)(((char*)(p)) + (s)))->head |= PINUSE_BIT),\
2495
 mark_inuse_foot(M,p,s))
2496
 
2497
#define set_size_and_pinuse_of_inuse_chunk(M, p, s)\
2498
  ((p)->head = (s|PINUSE_BIT|CINUSE_BIT),\
2499
  mark_inuse_foot(M, p, s))
2500
 
2501
#endif /* !FOOTERS */
2502
 
2503
/* ---------------------------- setting mparams -------------------------- */
2504
 
2505
/* Initialize mparams */
2506
static int init_mparams(void) {
2507
  if (mparams.page_size == 0) {
2508
    size_t s;
2509
 
2510
    mparams.mmap_threshold = DEFAULT_MMAP_THRESHOLD;
2511
    mparams.trim_threshold = DEFAULT_TRIM_THRESHOLD;
2512
#if MORECORE_CONTIGUOUS
2513
    mparams.default_mflags = USE_LOCK_BIT|USE_MMAP_BIT;
2514
#else  /* MORECORE_CONTIGUOUS */
2515
    mparams.default_mflags = USE_LOCK_BIT|USE_MMAP_BIT|USE_NONCONTIGUOUS_BIT;
2516
#endif /* MORECORE_CONTIGUOUS */
2517
 
2518
#if (FOOTERS && !INSECURE)
2519
    {
2520
#if USE_DEV_RANDOM
2521
      int fd;
2522
      unsigned char buf[sizeof(size_t)];
2523
      /* Try to use /dev/urandom, else fall back on using time */
2524
      if ((fd = open("/dev/urandom", O_RDONLY)) >= 0 &&
2525
          read(fd, buf, sizeof(buf)) == sizeof(buf)) {
2526
        s = *((size_t *) buf);
2527
        close(fd);
2528
      }
2529
      else
2530
#endif /* USE_DEV_RANDOM */
2531
        s = (size_t)(time(0) ^ (size_t)0x55555555U);
2532
 
2533
      s |= (size_t)8U;    /* ensure nonzero */
2534
      s &= ~(size_t)7U;   /* improve chances of fault for bad values */
2535
 
2536
    }
2537
#else /* (FOOTERS && !INSECURE) */
2538
    s = (size_t)0x58585858U;
2539
#endif /* (FOOTERS && !INSECURE) */
2540
    ACQUIRE_MAGIC_INIT_LOCK();
2541
    if (mparams.magic == 0) {
2542
      mparams.magic = s;
2543
      /* Set up lock for main malloc area */
2544
      INITIAL_LOCK(&gm->mutex);
2545
      gm->mflags = mparams.default_mflags;
2546
    }
2547
    RELEASE_MAGIC_INIT_LOCK();
2548
 
2549
#if !defined(WIN32) && !defined(__OS2__)
2550
    mparams.page_size = malloc_getpagesize;
2551
    mparams.granularity = ((DEFAULT_GRANULARITY != 0)?
2552
                           DEFAULT_GRANULARITY : mparams.page_size);
2553
#elif defined (__OS2__)
2554
 /* if low-memory is used, os2munmap() would break
2555
    if it were anything other than 64k */
2556
    mparams.page_size = 4096u;
2557
    mparams.granularity = 65536u;
2558
#else /* WIN32 */
2559
    {
2560
      SYSTEM_INFO system_info;
2561
      GetSystemInfo(&system_info);
2562
      mparams.page_size = system_info.dwPageSize;
2563
      mparams.granularity = system_info.dwAllocationGranularity;
2564
    }
2565
#endif /* WIN32 */
2566
 
2567
    /* Sanity-check configuration:
2568
       size_t must be unsigned and as wide as pointer type.
2569
       ints must be at least 4 bytes.
2570
       alignment must be at least 8.
2571
       Alignment, min chunk size, and page size must all be powers of 2.
2572
    */
2573
    if ((sizeof(size_t) != sizeof(char*)) ||
2574
        (MAX_SIZE_T < MIN_CHUNK_SIZE)  ||
2575
        (sizeof(int) < 4)  ||
2576
        (MALLOC_ALIGNMENT < (size_t)8U) ||
2577
        ((MALLOC_ALIGNMENT    & (MALLOC_ALIGNMENT-SIZE_T_ONE))    != 0) ||
2578
        ((MCHUNK_SIZE         & (MCHUNK_SIZE-SIZE_T_ONE))         != 0) ||
2579
        ((mparams.granularity & (mparams.granularity-SIZE_T_ONE)) != 0) ||
2580
        ((mparams.page_size   & (mparams.page_size-SIZE_T_ONE))   != 0))
2581
      ABORT;
2582
  }
2583
  return 0;
2584
}
2585
 
2586
/* support for mallopt */
2587
static int change_mparam(int param_number, int value) {
2588
  size_t val = (size_t)value;
2589
  init_mparams();
2590
  switch(param_number) {
2591
  case M_TRIM_THRESHOLD:
2592
    mparams.trim_threshold = val;
2593
    return 1;
2594
  case M_GRANULARITY:
2595
    if (val >= mparams.page_size && ((val & (val-1)) == 0)) {
2596
      mparams.granularity = val;
2597
      return 1;
2598
    }
2599
    else
2600
      return 0;
2601
  case M_MMAP_THRESHOLD:
2602
    mparams.mmap_threshold = val;
2603
    return 1;
2604
  default:
2605
    return 0;
2606
  }
2607
}
2608
 
2609
#if DEBUG
2610
/* ------------------------- Debugging Support --------------------------- */
2611
 
2612
/* Check properties of any chunk, whether free, inuse, mmapped etc  */
2613
static void do_check_any_chunk(mstate m, mchunkptr p) {
2614
  assert((is_aligned(chunk2mem(p))) || (p->head == FENCEPOST_HEAD));
2615
  assert(ok_address(m, p));
2616
}
2617
 
2618
/* Check properties of top chunk */
2619
static void do_check_top_chunk(mstate m, mchunkptr p) {
2620
  msegmentptr sp = segment_holding(m, (char*)p);
2621
  size_t  sz = chunksize(p);
2622
  assert(sp != 0);
2623
  assert((is_aligned(chunk2mem(p))) || (p->head == FENCEPOST_HEAD));
2624
  assert(ok_address(m, p));
2625
  assert(sz == m->topsize);
2626
  assert(sz > 0);
2627
  assert(sz == ((sp->base + sp->size) - (char*)p) - TOP_FOOT_SIZE);
2628
  assert(pinuse(p));
2629
  assert(!next_pinuse(p));
2630
}
2631
 
2632
/* Check properties of (inuse) mmapped chunks */
2633
static void do_check_mmapped_chunk(mstate m, mchunkptr p) {
2634
  size_t  sz = chunksize(p);
2635
  size_t len = (sz + (p->prev_foot & ~IS_MMAPPED_BIT) + MMAP_FOOT_PAD);
2636
  assert(is_mmapped(p));
2637
  assert(use_mmap(m));
2638
  assert((is_aligned(chunk2mem(p))) || (p->head == FENCEPOST_HEAD));
2639
  assert(ok_address(m, p));
2640
  assert(!is_small(sz));
2641
  assert((len & (mparams.page_size-SIZE_T_ONE)) == 0);
2642
  assert(chunk_plus_offset(p, sz)->head == FENCEPOST_HEAD);
2643
  assert(chunk_plus_offset(p, sz+SIZE_T_SIZE)->head == 0);
2644
}
2645
 
2646
/* Check properties of inuse chunks */
2647
static void do_check_inuse_chunk(mstate m, mchunkptr p) {
2648
  do_check_any_chunk(m, p);
2649
  assert(cinuse(p));
2650
  assert(next_pinuse(p));
2651
  /* If not pinuse and not mmapped, previous chunk has OK offset */
2652
  assert(is_mmapped(p) || pinuse(p) || next_chunk(prev_chunk(p)) == p);
2653
  if (is_mmapped(p))
2654
    do_check_mmapped_chunk(m, p);
2655
}
2656
 
2657
/* Check properties of free chunks */
2658
static void do_check_free_chunk(mstate m, mchunkptr p) {
2659
  size_t sz = p->head & ~(PINUSE_BIT|CINUSE_BIT);
2660
  mchunkptr next = chunk_plus_offset(p, sz);
2661
  do_check_any_chunk(m, p);
2662
  assert(!cinuse(p));
2663
  assert(!next_pinuse(p));
2664
  assert (!is_mmapped(p));
2665
  if (p != m->dv && p != m->top) {
2666
    if (sz >= MIN_CHUNK_SIZE) {
2667
      assert((sz & CHUNK_ALIGN_MASK) == 0);
2668
      assert(is_aligned(chunk2mem(p)));
2669
      assert(next->prev_foot == sz);
2670
      assert(pinuse(p));
2671
      assert (next == m->top || cinuse(next));
2672
      assert(p->fd->bk == p);
2673
      assert(p->bk->fd == p);
2674
    }
2675
    else  /* markers are always of size SIZE_T_SIZE */
2676
      assert(sz == SIZE_T_SIZE);
2677
  }
2678
}
2679
 
2680
/* Check properties of malloced chunks at the point they are malloced */
2681
static void do_check_malloced_chunk(mstate m, void* mem, size_t s) {
2682
  if (mem != 0) {
2683
    mchunkptr p = mem2chunk(mem);
2684
    size_t sz = p->head & ~(PINUSE_BIT|CINUSE_BIT);
2685
    do_check_inuse_chunk(m, p);
2686
    assert((sz & CHUNK_ALIGN_MASK) == 0);
2687
    assert(sz >= MIN_CHUNK_SIZE);
2688
    assert(sz >= s);
2689
    /* unless mmapped, size is less than MIN_CHUNK_SIZE more than request */
2690
    assert(is_mmapped(p) || sz < (s + MIN_CHUNK_SIZE));
2691
  }
2692
}
2693
 
2694
/* Check a tree and its subtrees.  */
2695
static void do_check_tree(mstate m, tchunkptr t) {
2696
  tchunkptr head = 0;
2697
  tchunkptr u = t;
2698
  bindex_t tindex = t->index;
2699
  size_t tsize = chunksize(t);
2700
  bindex_t idx;
2701
  compute_tree_index(tsize, idx);
2702
  assert(tindex == idx);
2703
  assert(tsize >= MIN_LARGE_SIZE);
2704
  assert(tsize >= minsize_for_tree_index(idx));
2705
  assert((idx == NTREEBINS-1) || (tsize < minsize_for_tree_index((idx+1))));
2706
 
2707
  do { /* traverse through chain of same-sized nodes */
2708
    do_check_any_chunk(m, ((mchunkptr)u));
2709
    assert(u->index == tindex);
2710
    assert(chunksize(u) == tsize);
2711
    assert(!cinuse(u));
2712
    assert(!next_pinuse(u));
2713
    assert(u->fd->bk == u);
2714
    assert(u->bk->fd == u);
2715
    if (u->parent == 0) {
2716
      assert(u->child[0] == 0);
2717
      assert(u->child[1] == 0);
2718
    }
2719
    else {
2720
      assert(head == 0); /* only one node on chain has parent */
2721
      head = u;
2722
      assert(u->parent != u);
2723
      assert (u->parent->child[0] == u ||
2724
              u->parent->child[1] == u ||
2725
              *((tbinptr*)(u->parent)) == u);
2726
      if (u->child[0] != 0) {
2727
        assert(u->child[0]->parent == u);
2728
        assert(u->child[0] != u);
2729
        do_check_tree(m, u->child[0]);
2730
      }
2731
      if (u->child[1] != 0) {
2732
        assert(u->child[1]->parent == u);
2733
        assert(u->child[1] != u);
2734
        do_check_tree(m, u->child[1]);
2735
      }
2736
      if (u->child[0] != 0 && u->child[1] != 0) {
2737
        assert(chunksize(u->child[0]) < chunksize(u->child[1]));
2738
      }
2739
    }
2740
    u = u->fd;
2741
  } while (u != t);
2742
  assert(head != 0);
2743
}
2744
 
2745
/*  Check all the chunks in a treebin.  */
2746
static void do_check_treebin(mstate m, bindex_t i) {
2747
  tbinptr* tb = treebin_at(m, i);
2748
  tchunkptr t = *tb;
2749
  int empty = (m->treemap & (1U << i)) == 0;
2750
  if (t == 0)
2751
    assert(empty);
2752
  if (!empty)
2753
    do_check_tree(m, t);
2754
}
2755
 
2756
/*  Check all the chunks in a smallbin.  */
2757
static void do_check_smallbin(mstate m, bindex_t i) {
2758
  sbinptr b = smallbin_at(m, i);
2759
  mchunkptr p = b->bk;
2760
  unsigned int empty = (m->smallmap & (1U << i)) == 0;
2761
  if (p == b)
2762
    assert(empty);
2763
  if (!empty) {
2764
    for (; p != b; p = p->bk) {
2765
      size_t size = chunksize(p);
2766
      mchunkptr q;
2767
      /* each chunk claims to be free */
2768
      do_check_free_chunk(m, p);
2769
      /* chunk belongs in bin */
2770
      assert(small_index(size) == i);
2771
      assert(p->bk == b || chunksize(p->bk) == chunksize(p));
2772
      /* chunk is followed by an inuse chunk */
2773
      q = next_chunk(p);
2774
      if (q->head != FENCEPOST_HEAD)
2775
        do_check_inuse_chunk(m, q);
2776
    }
2777
  }
2778
}
2779
 
2780
/* Find x in a bin. Used in other check functions. */
2781
static int bin_find(mstate m, mchunkptr x) {
2782
  size_t size = chunksize(x);
2783
  if (is_small(size)) {
2784
    bindex_t sidx = small_index(size);
2785
    sbinptr b = smallbin_at(m, sidx);
2786
    if (smallmap_is_marked(m, sidx)) {
2787
      mchunkptr p = b;
2788
      do {
2789
        if (p == x)
2790
          return 1;
2791
      } while ((p = p->fd) != b);
2792
    }
2793
  }
2794
  else {
2795
    bindex_t tidx;
2796
    compute_tree_index(size, tidx);
2797
    if (treemap_is_marked(m, tidx)) {
2798
      tchunkptr t = *treebin_at(m, tidx);
2799
      size_t sizebits = size << leftshift_for_tree_index(tidx);
2800
      while (t != 0 && chunksize(t) != size) {
2801
        t = t->child[(sizebits >> (SIZE_T_BITSIZE-SIZE_T_ONE)) & 1];
2802
        sizebits <<= 1;
2803
      }
2804
      if (t != 0) {
2805
        tchunkptr u = t;
2806
        do {
2807
          if (u == (tchunkptr)x)
2808
            return 1;
2809
        } while ((u = u->fd) != t);
2810
      }
2811
    }
2812
  }
2813
  return 0;
2814
}
2815
 
2816
/* Traverse each chunk and check it; return total */
2817
static size_t traverse_and_check(mstate m) {
2818
  size_t sum = 0;
2819
  if (is_initialized(m)) {
2820
    msegmentptr s = &m->seg;
2821
    sum += m->topsize + TOP_FOOT_SIZE;
2822
    while (s != 0) {
2823
      mchunkptr q = align_as_chunk(s->base);
2824
      mchunkptr lastq = 0;
2825
      assert(pinuse(q));
2826
      while (segment_holds(s, q) &&
2827
             q != m->top && q->head != FENCEPOST_HEAD) {
2828
        sum += chunksize(q);
2829
        if (cinuse(q)) {
2830
          assert(!bin_find(m, q));
2831
          do_check_inuse_chunk(m, q);
2832
        }
2833
        else {
2834
          assert(q == m->dv || bin_find(m, q));
2835
          assert(lastq == 0 || cinuse(lastq)); /* Not 2 consecutive free */
2836
          do_check_free_chunk(m, q);
2837
        }
2838
        lastq = q;
2839
        q = next_chunk(q);
2840
      }
2841
      s = s->next;
2842
    }
2843
  }
2844
  return sum;
2845
}
2846
 
2847
/* Check all properties of malloc_state. */
2848
static void do_check_malloc_state(mstate m) {
2849
  bindex_t i;
2850
  size_t total;
2851
  /* check bins */
2852
  for (i = 0; i < NSMALLBINS; ++i)
2853
    do_check_smallbin(m, i);
2854
  for (i = 0; i < NTREEBINS; ++i)
2855
    do_check_treebin(m, i);
2856
 
2857
  if (m->dvsize != 0) { /* check dv chunk */
2858
    do_check_any_chunk(m, m->dv);
2859
    assert(m->dvsize == chunksize(m->dv));
2860
    assert(m->dvsize >= MIN_CHUNK_SIZE);
2861
    assert(bin_find(m, m->dv) == 0);
2862
  }
2863
 
2864
  if (m->top != 0) {   /* check top chunk */
2865
    do_check_top_chunk(m, m->top);
2866
    assert(m->topsize == chunksize(m->top));
2867
    assert(m->topsize > 0);
2868
    assert(bin_find(m, m->top) == 0);
2869
  }
2870
 
2871
  total = traverse_and_check(m);
2872
  assert(total <= m->footprint);
2873
  assert(m->footprint <= m->max_footprint);
2874
}
2875
#endif /* DEBUG */
2876
 
2877
/* ----------------------------- statistics ------------------------------ */
2878
 
2879
#if !NO_MALLINFO
2880
static struct mallinfo internal_mallinfo(mstate m) {
2881
  struct mallinfo nm = { 0, 0, 0, 0, 0, 0, 0, 0, 0, 0 };
2882
  if (!PREACTION(m)) {
2883
    check_malloc_state(m);
2884
    if (is_initialized(m)) {
2885
      size_t nfree = SIZE_T_ONE; /* top always free */
2886
      size_t mfree = m->topsize + TOP_FOOT_SIZE;
2887
      size_t sum = mfree;
2888
      msegmentptr s = &m->seg;
2889
      while (s != 0) {
2890
        mchunkptr q = align_as_chunk(s->base);
2891
        while (segment_holds(s, q) &&
2892
               q != m->top && q->head != FENCEPOST_HEAD) {
2893
          size_t sz = chunksize(q);
2894
          sum += sz;
2895
          if (!cinuse(q)) {
2896
            mfree += sz;
2897
            ++nfree;
2898
          }
2899
          q = next_chunk(q);
2900
        }
2901
        s = s->next;
2902
      }
2903
 
2904
      nm.arena    = sum;
2905
      nm.ordblks  = nfree;
2906
      nm.hblkhd   = m->footprint - sum;
2907
      nm.usmblks  = m->max_footprint;
2908
      nm.uordblks = m->footprint - mfree;
2909
      nm.fordblks = mfree;
2910
      nm.keepcost = m->topsize;
2911
    }
2912
 
2913
    POSTACTION(m);
2914
  }
2915
  return nm;
2916
}
2917
#endif /* !NO_MALLINFO */
2918
 
2919
static void internal_malloc_stats(mstate m) {
2920
  if (!PREACTION(m)) {
2921
    size_t maxfp = 0;
2922
    size_t fp = 0;
2923
    size_t used = 0;
2924
    check_malloc_state(m);
2925
    if (is_initialized(m)) {
2926
      msegmentptr s = &m->seg;
2927
      maxfp = m->max_footprint;
2928
      fp = m->footprint;
2929
      used = fp - (m->topsize + TOP_FOOT_SIZE);
2930
 
2931
      while (s != 0) {
2932
        mchunkptr q = align_as_chunk(s->base);
2933
        while (segment_holds(s, q) &&
2934
               q != m->top && q->head != FENCEPOST_HEAD) {
2935
          if (!cinuse(q))
2936
            used -= chunksize(q);
2937
          q = next_chunk(q);
2938
        }
2939
        s = s->next;
2940
      }
2941
    }
2942
 
2943
    fprintf(stderr, "max system bytes = %10lu\n", (unsigned long)(maxfp));
2944
    fprintf(stderr, "system bytes     = %10lu\n", (unsigned long)(fp));
2945
    fprintf(stderr, "in use bytes     = %10lu\n", (unsigned long)(used));
2946
 
2947
    POSTACTION(m);
2948
  }
2949
}
2950
 
2951
/* ----------------------- Operations on smallbins ----------------------- */
2952
 
2953
/*
2954
  Various forms of linking and unlinking are defined as macros.  Even
2955
  the ones for trees, which are very long but have very short typical
2956
  paths.  This is ugly but reduces reliance on inlining support of
2957
  compilers.
2958
*/
2959
 
2960
/* Link a free chunk into a smallbin  */
2961
#define insert_small_chunk(M, P, S) {\
2962
  bindex_t I  = small_index(S);\
2963
  mchunkptr B = smallbin_at(M, I);\
2964
  mchunkptr F = B;\
2965
  assert(S >= MIN_CHUNK_SIZE);\
2966
  if (!smallmap_is_marked(M, I))\
2967
    mark_smallmap(M, I);\
2968
  else if (RTCHECK(ok_address(M, B->fd)))\
2969
    F = B->fd;\
2970
  else {\
2971
    CORRUPTION_ERROR_ACTION(M);\
2972
  }\
2973
  B->fd = P;\
2974
  F->bk = P;\
2975
  P->fd = F;\
2976
  P->bk = B;\
2977
}
2978
 
2979
/* Unlink a chunk from a smallbin  */
2980
#define unlink_small_chunk(M, P, S) {\
2981
  mchunkptr F = P->fd;\
2982
  mchunkptr B = P->bk;\
2983
  bindex_t I = small_index(S);\
2984
  assert(P != B);\
2985
  assert(P != F);\
2986
  assert(chunksize(P) == small_index2size(I));\
2987
  if (F == B)\
2988
    clear_smallmap(M, I);\
2989
  else if (RTCHECK((F == smallbin_at(M,I) || ok_address(M, F)) &&\
2990
                   (B == smallbin_at(M,I) || ok_address(M, B)))) {\
2991
    F->bk = B;\
2992
    B->fd = F;\
2993
  }\
2994
  else {\
2995
    CORRUPTION_ERROR_ACTION(M);\
2996
  }\
2997
}
2998
 
2999
/* Unlink the first chunk from a smallbin */
3000
#define unlink_first_small_chunk(M, B, P, I) {\
3001
  mchunkptr F = P->fd;\
3002
  assert(P != B);\
3003
  assert(P != F);\
3004
  assert(chunksize(P) == small_index2size(I));\
3005
  if (B == F)\
3006
    clear_smallmap(M, I);\
3007
  else if (RTCHECK(ok_address(M, F))) {\
3008
    B->fd = F;\
3009
    F->bk = B;\
3010
  }\
3011
  else {\
3012
    CORRUPTION_ERROR_ACTION(M);\
3013
  }\
3014
}
3015
 
3016
/* Replace dv node, binning the old one */
3017
/* Used only when dvsize known to be small */
3018
#define replace_dv(M, P, S) {\
3019
  size_t DVS = M->dvsize;\
3020
  if (DVS != 0) {\
3021
    mchunkptr DV = M->dv;\
3022
    assert(is_small(DVS));\
3023
    insert_small_chunk(M, DV, DVS);\
3024
  }\
3025
  M->dvsize = S;\
3026
  M->dv = P;\
3027
}
3028
 
3029
/* ------------------------- Operations on trees ------------------------- */
3030
 
3031
/* Insert chunk into tree */
3032
#define insert_large_chunk(M, X, S) {\
3033
  tbinptr* H;\
3034
  bindex_t I;\
3035
  compute_tree_index(S, I);\
3036
  H = treebin_at(M, I);\
3037
  X->index = I;\
3038
  X->child[0] = X->child[1] = 0;\
3039
  if (!treemap_is_marked(M, I)) {\
3040
    mark_treemap(M, I);\
3041
    *H = X;\
3042
    X->parent = (tchunkptr)H;\
3043
    X->fd = X->bk = X;\
3044
  }\
3045
  else {\
3046
    tchunkptr T = *H;\
3047
    size_t K = S << leftshift_for_tree_index(I);\
3048
    for (;;) {\
3049
      if (chunksize(T) != S) {\
3050
        tchunkptr* C = &(T->child[(K >> (SIZE_T_BITSIZE-SIZE_T_ONE)) & 1]);\
3051
        K <<= 1;\
3052
        if (*C != 0)\
3053
          T = *C;\
3054
        else if (RTCHECK(ok_address(M, C))) {\
3055
          *C = X;\
3056
          X->parent = T;\
3057
          X->fd = X->bk = X;\
3058
          break;\
3059
        }\
3060
        else {\
3061
          CORRUPTION_ERROR_ACTION(M);\
3062
          break;\
3063
        }\
3064
      }\
3065
      else {\
3066
        tchunkptr F = T->fd;\
3067
        if (RTCHECK(ok_address(M, T) && ok_address(M, F))) {\
3068
          T->fd = F->bk = X;\
3069
          X->fd = F;\
3070
          X->bk = T;\
3071
          X->parent = 0;\
3072
          break;\
3073
        }\
3074
        else {\
3075
          CORRUPTION_ERROR_ACTION(M);\
3076
          break;\
3077
        }\
3078
      }\
3079
    }\
3080
  }\
3081
}
3082
 
3083
/*
3084
  Unlink steps:
3085
 
3086
  1. If x is a chained node, unlink it from its same-sized fd/bk links
3087
     and choose its bk node as its replacement.
3088
  2. If x was the last node of its size, but not a leaf node, it must
3089
     be replaced with a leaf node (not merely one with an open left or
3090
     right), to make sure that lefts and rights of descendents
3091
     correspond properly to bit masks.  We use the rightmost descendent
3092
     of x.  We could use any other leaf, but this is easy to locate and
3093
     tends to counteract removal of leftmosts elsewhere, and so keeps
3094
     paths shorter than minimally guaranteed.  This doesn't loop much
3095
     because on average a node in a tree is near the bottom.
3096
  3. If x is the base of a chain (i.e., has parent links) relink
3097
     x's parent and children to x's replacement (or null if none).
3098
*/
3099
 
3100
#define unlink_large_chunk(M, X) {\
3101
  tchunkptr XP = X->parent;\
3102
  tchunkptr R;\
3103
  if (X->bk != X) {\
3104
    tchunkptr F = X->fd;\
3105
    R = X->bk;\
3106
    if (RTCHECK(ok_address(M, F))) {\
3107
      F->bk = R;\
3108
      R->fd = F;\
3109
    }\
3110
    else {\
3111
      CORRUPTION_ERROR_ACTION(M);\
3112
    }\
3113
  }\
3114
  else {\
3115
    tchunkptr* RP;\
3116
    if (((R = *(RP = &(X->child[1]))) != 0) ||\
3117
        ((R = *(RP = &(X->child[0]))) != 0)) {\
3118
      tchunkptr* CP;\
3119
      while ((*(CP = &(R->child[1])) != 0) ||\
3120
             (*(CP = &(R->child[0])) != 0)) {\
3121
        R = *(RP = CP);\
3122
      }\
3123
      if (RTCHECK(ok_address(M, RP)))\
3124
        *RP = 0;\
3125
      else {\
3126
        CORRUPTION_ERROR_ACTION(M);\
3127
      }\
3128
    }\
3129
  }\
3130
  if (XP != 0) {\
3131
    tbinptr* H = treebin_at(M, X->index);\
3132
    if (X == *H) {\
3133
      if ((*H = R) == 0) \
3134
        clear_treemap(M, X->index);\
3135
    }\
3136
    else if (RTCHECK(ok_address(M, XP))) {\
3137
      if (XP->child[0] == X) \
3138
        XP->child[0] = R;\
3139
      else \
3140
        XP->child[1] = R;\
3141
    }\
3142
    else\
3143
      CORRUPTION_ERROR_ACTION(M);\
3144
    if (R != 0) {\
3145
      if (RTCHECK(ok_address(M, R))) {\
3146
        tchunkptr C0, C1;\
3147
        R->parent = XP;\
3148
        if ((C0 = X->child[0]) != 0) {\
3149
          if (RTCHECK(ok_address(M, C0))) {\
3150
            R->child[0] = C0;\
3151
            C0->parent = R;\
3152
          }\
3153
          else\
3154
            CORRUPTION_ERROR_ACTION(M);\
3155
        }\
3156
        if ((C1 = X->child[1]) != 0) {\
3157
          if (RTCHECK(ok_address(M, C1))) {\
3158
            R->child[1] = C1;\
3159
            C1->parent = R;\
3160
          }\
3161
          else\
3162
            CORRUPTION_ERROR_ACTION(M);\
3163
        }\
3164
      }\
3165
      else\
3166
        CORRUPTION_ERROR_ACTION(M);\
3167
    }\
3168
  }\
3169
}
3170
 
3171
/* Relays to large vs small bin operations */
3172
 
3173
#define insert_chunk(M, P, S)\
3174
  if (is_small(S)) insert_small_chunk(M, P, S)\
3175
  else { tchunkptr TP = (tchunkptr)(P); insert_large_chunk(M, TP, S); }
3176
 
3177
#define unlink_chunk(M, P, S)\
3178
  if (is_small(S)) unlink_small_chunk(M, P, S)\
3179
  else { tchunkptr TP = (tchunkptr)(P); unlink_large_chunk(M, TP); }
3180
 
3181
 
3182
/* Relays to internal calls to malloc/free from realloc, memalign etc */
3183
 
3184
#if ONLY_MSPACES
3185
#define internal_malloc(m, b) mspace_malloc(m, b)
3186
#define internal_free(m, mem) mspace_free(m,mem);
3187
#else /* ONLY_MSPACES */
3188
#if MSPACES
3189
#define internal_malloc(m, b)\
3190
   (m == gm)? dlmalloc(b) : mspace_malloc(m, b)
3191
#define internal_free(m, mem)\
3192
   if (m == gm) dlfree(mem); else mspace_free(m,mem);
3193
#else /* MSPACES */
3194
#define internal_malloc(m, b) dlmalloc(b)
3195
#define internal_free(m, mem) dlfree(mem)
3196
#endif /* MSPACES */
3197
#endif /* ONLY_MSPACES */
3198
 
3199
/* -----------------------  Direct-mmapping chunks ----------------------- */
3200
 
3201
/*
3202
  Directly mmapped chunks are set up with an offset to the start of
3203
  the mmapped region stored in the prev_foot field of the chunk. This
3204
  allows reconstruction of the required argument to MUNMAP when freed,
3205
  and also allows adjustment of the returned chunk to meet alignment
3206
  requirements (especially in memalign).  There is also enough space
3207
  allocated to hold a fake next chunk of size SIZE_T_SIZE to maintain
3208
  the PINUSE bit so frees can be checked.
3209
*/
3210
 
3211
/* Malloc using mmap */
3212
static void* mmap_alloc(mstate m, size_t nb) {
3213
  size_t mmsize = granularity_align(nb + SIX_SIZE_T_SIZES + CHUNK_ALIGN_MASK);
3214
  if (mmsize > nb) {     /* Check for wrap around 0 */
3215
    char* mm = (char*)(DIRECT_MMAP(mmsize));
3216
    if (mm != CMFAIL) {
3217
      size_t offset = align_offset(chunk2mem(mm));
3218
      size_t psize = mmsize - offset - MMAP_FOOT_PAD;
3219
      mchunkptr p = (mchunkptr)(mm + offset);
3220
      p->prev_foot = offset | IS_MMAPPED_BIT;
3221
      (p)->head = (psize|CINUSE_BIT);
3222
      mark_inuse_foot(m, p, psize);
3223
      chunk_plus_offset(p, psize)->head = FENCEPOST_HEAD;
3224
      chunk_plus_offset(p, psize+SIZE_T_SIZE)->head = 0;
3225
 
3226
      if (mm < m->least_addr)
3227
        m->least_addr = mm;
3228
      if ((m->footprint += mmsize) > m->max_footprint)
3229
        m->max_footprint = m->footprint;
3230
      assert(is_aligned(chunk2mem(p)));
3231
      check_mmapped_chunk(m, p);
3232
      return chunk2mem(p);
3233
    }
3234
  }
3235
  return 0;
3236
}
3237
 
3238
/* Realloc using mmap */
3239
static mchunkptr mmap_resize(mstate m, mchunkptr oldp, size_t nb) {
3240
  size_t oldsize = chunksize(oldp);
3241
  if (is_small(nb)) /* Can't shrink mmap regions below small size */
3242
    return 0;
3243
  /* Keep old chunk if big enough but not too big */
3244
  if (oldsize >= nb + SIZE_T_SIZE &&
3245
      (oldsize - nb) <= (mparams.granularity << 1))
3246
    return oldp;
3247
  else {
3248
    size_t offset = oldp->prev_foot & ~IS_MMAPPED_BIT;
3249
    size_t oldmmsize = oldsize + offset + MMAP_FOOT_PAD;
3250
    size_t newmmsize = granularity_align(nb + SIX_SIZE_T_SIZES +
3251
                                         CHUNK_ALIGN_MASK);
3252
    char* cp = (char*)CALL_MREMAP((char*)oldp - offset,
3253
                                  oldmmsize, newmmsize, 1);
3254
    if (cp != CMFAIL) {
3255
      mchunkptr newp = (mchunkptr)(cp + offset);
3256
      size_t psize = newmmsize - offset - MMAP_FOOT_PAD;
3257
      newp->head = (psize|CINUSE_BIT);
3258
      mark_inuse_foot(m, newp, psize);
3259
      chunk_plus_offset(newp, psize)->head = FENCEPOST_HEAD;
3260
      chunk_plus_offset(newp, psize+SIZE_T_SIZE)->head = 0;
3261
 
3262
      if (cp < m->least_addr)
3263
        m->least_addr = cp;
3264
      if ((m->footprint += newmmsize - oldmmsize) > m->max_footprint)
3265
        m->max_footprint = m->footprint;
3266
      check_mmapped_chunk(m, newp);
3267
      return newp;
3268
    }
3269
  }
3270
  return 0;
3271
}
3272
 
3273
/* -------------------------- mspace management -------------------------- */
3274
 
3275
/* Initialize top chunk and its size */
3276
static void init_top(mstate m, mchunkptr p, size_t psize) {
3277
  /* Ensure alignment */
3278
  size_t offset = align_offset(chunk2mem(p));
3279
  p = (mchunkptr)((char*)p + offset);
3280
  psize -= offset;
3281
 
3282
  m->top = p;
3283
  m->topsize = psize;
3284
  p->head = psize | PINUSE_BIT;
3285
  /* set size of fake trailing chunk holding overhead space only once */
3286
  chunk_plus_offset(p, psize)->head = TOP_FOOT_SIZE;
3287
  m->trim_check = mparams.trim_threshold; /* reset on each update */
3288
}
3289
 
3290
/* Initialize bins for a new mstate that is otherwise zeroed out */
3291
static void init_bins(mstate m) {
3292
  /* Establish circular links for smallbins */
3293
  bindex_t i;
3294
  for (i = 0; i < NSMALLBINS; ++i) {
3295
    sbinptr bin = smallbin_at(m,i);
3296
    bin->fd = bin->bk = bin;
3297
  }
3298
}
3299
 
3300
#if PROCEED_ON_ERROR
3301
 
3302
/* default corruption action */
3303
static void reset_on_error(mstate m) {
3304
  int i;
3305
  ++malloc_corruption_error_count;
3306
  /* Reinitialize fields to forget about all memory */
3307
  m->smallbins = m->treebins = 0;
3308
  m->dvsize = m->topsize = 0;
3309
  m->seg.base = 0;
3310
  m->seg.size = 0;
3311
  m->seg.next = 0;
3312
  m->top = m->dv = 0;
3313
  for (i = 0; i < NTREEBINS; ++i)
3314
    *treebin_at(m, i) = 0;
3315
  init_bins(m);
3316
}
3317
#endif /* PROCEED_ON_ERROR */
3318
 
3319
/* Allocate chunk and prepend remainder with chunk in successor base. */
3320
static void* prepend_alloc(mstate m, char* newbase, char* oldbase,
3321
                           size_t nb) {
3322
  mchunkptr p = align_as_chunk(newbase);
3323
  mchunkptr oldfirst = align_as_chunk(oldbase);
3324
  size_t psize = (char*)oldfirst - (char*)p;
3325
  mchunkptr q = chunk_plus_offset(p, nb);
3326
  size_t qsize = psize - nb;
3327
  set_size_and_pinuse_of_inuse_chunk(m, p, nb);
3328
 
3329
  assert((char*)oldfirst > (char*)q);
3330
  assert(pinuse(oldfirst));
3331
  assert(qsize >= MIN_CHUNK_SIZE);
3332
 
3333
  /* consolidate remainder with first chunk of old base */
3334
  if (oldfirst == m->top) {
3335
    size_t tsize = m->topsize += qsize;
3336
    m->top = q;
3337
    q->head = tsize | PINUSE_BIT;
3338
    check_top_chunk(m, q);
3339
  }
3340
  else if (oldfirst == m->dv) {
3341
    size_t dsize = m->dvsize += qsize;
3342
    m->dv = q;
3343
    set_size_and_pinuse_of_free_chunk(q, dsize);
3344
  }
3345
  else {
3346
    if (!cinuse(oldfirst)) {
3347
      size_t nsize = chunksize(oldfirst);
3348
      unlink_chunk(m, oldfirst, nsize);
3349
      oldfirst = chunk_plus_offset(oldfirst, nsize);
3350
      qsize += nsize;
3351
    }
3352
    set_free_with_pinuse(q, qsize, oldfirst);
3353
    insert_chunk(m, q, qsize);
3354
    check_free_chunk(m, q);
3355
  }
3356
 
3357
  check_malloced_chunk(m, chunk2mem(p), nb);
3358
  return chunk2mem(p);
3359
}
3360
 
3361
 
3362
/* Add a segment to hold a new noncontiguous region */
3363
static void add_segment(mstate m, char* tbase, size_t tsize, flag_t mmapped) {
3364
  /* Determine locations and sizes of segment, fenceposts, old top */
3365
  char* old_top = (char*)m->top;
3366
  msegmentptr oldsp = segment_holding(m, old_top);
3367
  char* old_end = oldsp->base + oldsp->size;
3368
  size_t ssize = pad_request(sizeof(struct malloc_segment));
3369
  char* rawsp = old_end - (ssize + FOUR_SIZE_T_SIZES + CHUNK_ALIGN_MASK);
3370
  size_t offset = align_offset(chunk2mem(rawsp));
3371
  char* asp = rawsp + offset;
3372
  char* csp = (asp < (old_top + MIN_CHUNK_SIZE))? old_top : asp;
3373
  mchunkptr sp = (mchunkptr)csp;
3374
  msegmentptr ss = (msegmentptr)(chunk2mem(sp));
3375
  mchunkptr tnext = chunk_plus_offset(sp, ssize);
3376
  mchunkptr p = tnext;
3377
  int nfences = 0;
3378
 
3379
  /* reset top to new space */
3380
  init_top(m, (mchunkptr)tbase, tsize - TOP_FOOT_SIZE);
3381
 
3382
  /* Set up segment record */
3383
  assert(is_aligned(ss));
3384
  set_size_and_pinuse_of_inuse_chunk(m, sp, ssize);
3385
  *ss = m->seg; /* Push current record */
3386
  m->seg.base = tbase;
3387
  m->seg.size = tsize;
3388
  set_segment_flags(&m->seg, mmapped);
3389
  m->seg.next = ss;
3390
 
3391
  /* Insert trailing fenceposts */
3392
  for (;;) {
3393
    mchunkptr nextp = chunk_plus_offset(p, SIZE_T_SIZE);
3394
    p->head = FENCEPOST_HEAD;
3395
    ++nfences;
3396
    if ((char*)(&(nextp->head)) < old_end)
3397
      p = nextp;
3398
    else
3399
      break;
3400
  }
3401
  assert(nfences >= 2);
3402
 
3403
  /* Insert the rest of old top into a bin as an ordinary free chunk */
3404
  if (csp != old_top) {
3405
    mchunkptr q = (mchunkptr)old_top;
3406
    size_t psize = csp - old_top;
3407
    mchunkptr tn = chunk_plus_offset(q, psize);
3408
    set_free_with_pinuse(q, psize, tn);
3409
    insert_chunk(m, q, psize);
3410
  }
3411
 
3412
  check_top_chunk(m, m->top);
3413
}
3414
 
3415
/* -------------------------- System allocation -------------------------- */
3416
 
3417
/* Get memory from system using MORECORE or MMAP */
3418
static void* sys_alloc(mstate m, size_t nb) {
3419
  char* tbase = CMFAIL;
3420
  size_t tsize = 0;
3421
  flag_t mmap_flag = 0;
3422
 
3423
  init_mparams();
3424
 
3425
  /* Directly map large chunks */
3426
  if (use_mmap(m) && nb >= mparams.mmap_threshold) {
3427
    void* mem = mmap_alloc(m, nb);
3428
    if (mem != 0)
3429
      return mem;
3430
  }
3431
 
3432
  /*
3433
    Try getting memory in any of three ways (in most-preferred to
3434
    least-preferred order):
3435
    1. A call to MORECORE that can normally contiguously extend memory.
3436
       (disabled if not MORECORE_CONTIGUOUS or not HAVE_MORECORE or
3437
       or main space is mmapped or a previous contiguous call failed)
3438
    2. A call to MMAP new space (disabled if not HAVE_MMAP).
3439
       Note that under the default settings, if MORECORE is unable to
3440
       fulfill a request, and HAVE_MMAP is true, then mmap is
3441
       used as a noncontiguous system allocator. This is a useful backup
3442
       strategy for systems with holes in address spaces -- in this case
3443
       sbrk cannot contiguously expand the heap, but mmap may be able to
3444
       find space.
3445
    3. A call to MORECORE that cannot usually contiguously extend memory.
3446
       (disabled if not HAVE_MORECORE)
3447
  */
3448
 
3449
  if (MORECORE_CONTIGUOUS && !use_noncontiguous(m)) {
3450
    char* br = CMFAIL;
3451
    msegmentptr ss = (m->top == 0)? 0 : segment_holding(m, (char*)m->top);
3452
    size_t asize = 0;
3453
    ACQUIRE_MORECORE_LOCK();
3454
 
3455
    if (ss == 0) {  /* First time through or recovery */
3456
      char* base = (char*)CALL_MORECORE(0);
3457
      if (base != CMFAIL) {
3458
        asize = granularity_align(nb + TOP_FOOT_SIZE + SIZE_T_ONE);
3459
        /* Adjust to end on a page boundary */
3460
        if (!is_page_aligned(base))
3461
          asize += (page_align((size_t)base) - (size_t)base);
3462
        /* Can't call MORECORE if size is negative when treated as signed */
3463
        if (asize < HALF_MAX_SIZE_T &&
3464
            (br = (char*)(CALL_MORECORE(asize))) == base) {
3465
          tbase = base;
3466
          tsize = asize;
3467
        }
3468
      }
3469
    }
3470
    else {
3471
      /* Subtract out existing available top space from MORECORE request. */
3472
      asize = granularity_align(nb - m->topsize + TOP_FOOT_SIZE + SIZE_T_ONE);
3473
      /* Use mem here only if it did continuously extend old space */
3474
      if (asize < HALF_MAX_SIZE_T &&
3475
          (br = (char*)(CALL_MORECORE(asize))) == ss->base+ss->size) {
3476
        tbase = br;
3477
        tsize = asize;
3478
      }
3479
    }
3480
 
3481
    if (tbase == CMFAIL) {    /* Cope with partial failure */
3482
      if (br != CMFAIL) {    /* Try to use/extend the space we did get */
3483
        if (asize < HALF_MAX_SIZE_T &&
3484
            asize < nb + TOP_FOOT_SIZE + SIZE_T_ONE) {
3485
          size_t esize = granularity_align(nb + TOP_FOOT_SIZE + SIZE_T_ONE - asize);
3486
          if (esize < HALF_MAX_SIZE_T) {
3487
            char* end = (char*)CALL_MORECORE(esize);
3488
            if (end != CMFAIL)
3489
              asize += esize;
3490
            else {            /* Can't use; try to release */
3491
              (void)CALL_MORECORE(-asize);
3492
              br = CMFAIL;
3493
            }
3494
          }
3495
        }
3496
      }
3497
      if (br != CMFAIL) {    /* Use the space we did get */
3498
        tbase = br;
3499
        tsize = asize;
3500
      }
3501
      else
3502
        disable_contiguous(m); /* Don't try contiguous path in the future */
3503
    }
3504
 
3505
    RELEASE_MORECORE_LOCK();
3506
  }
3507
 
3508
  if (HAVE_MMAP && tbase == CMFAIL) {  /* Try MMAP */
3509
    size_t req = nb + TOP_FOOT_SIZE + SIZE_T_ONE;
3510
    size_t rsize = granularity_align(req);
3511
    if (rsize > nb) { /* Fail if wraps around zero */
3512
      char* mp = (char*)(CALL_MMAP(rsize));
3513
      if (mp != CMFAIL) {
3514
        tbase = mp;
3515
        tsize = rsize;
3516
        mmap_flag = IS_MMAPPED_BIT;
3517
      }
3518
    }
3519
  }
3520
 
3521
  if (HAVE_MORECORE && tbase == CMFAIL) { /* Try noncontiguous MORECORE */
3522
    size_t asize = granularity_align(nb + TOP_FOOT_SIZE + SIZE_T_ONE);
3523
    if (asize < HALF_MAX_SIZE_T) {
3524
      char* br = CMFAIL;
3525
      char* end = CMFAIL;
3526
      ACQUIRE_MORECORE_LOCK();
3527
      br = (char*)(CALL_MORECORE(asize));
3528
      end = (char*)(CALL_MORECORE(0));
3529
      RELEASE_MORECORE_LOCK();
3530
      if (br != CMFAIL && end != CMFAIL && br < end) {
3531
        size_t ssize = end - br;
3532
        if (ssize > nb + TOP_FOOT_SIZE) {
3533
          tbase = br;
3534
          tsize = ssize;
3535
        }
3536
      }
3537
    }
3538
  }
3539
 
3540
  if (tbase != CMFAIL) {
3541
 
3542
    if ((m->footprint += tsize) > m->max_footprint)
3543
      m->max_footprint = m->footprint;
3544
 
3545
    if (!is_initialized(m)) { /* first-time initialization */
3546
      m->seg.base = m->least_addr = tbase;
3547
      m->seg.size = tsize;
3548
      set_segment_flags(&m->seg, mmap_flag);
3549
      m->magic = mparams.magic;
3550
      init_bins(m);
3551
      if (is_global(m))
3552
        init_top(m, (mchunkptr)tbase, tsize - TOP_FOOT_SIZE);
3553
      else {
3554
        /* Offset top by embedded malloc_state */
3555
        mchunkptr mn = next_chunk(mem2chunk(m));
3556
        init_top(m, mn, (size_t)((tbase + tsize) - (char*)mn) -TOP_FOOT_SIZE);
3557
      }
3558
    }
3559
 
3560
    else {
3561
      /* Try to merge with an existing segment */
3562
      msegmentptr sp = &m->seg;
3563
      while (sp != 0 && tbase != sp->base + sp->size)
3564
        sp = sp->next;
3565
      if (sp != 0 &&
3566
          !is_extern_segment(sp) &&
3567
          check_segment_merge(sp, tbase, tsize) &&
3568
          (get_segment_flags(sp) & IS_MMAPPED_BIT) == mmap_flag &&
3569
          segment_holds(sp, m->top)) { /* append */
3570
        sp->size += tsize;
3571
        init_top(m, m->top, m->topsize + tsize);
3572
      }
3573
      else {
3574
        if (tbase < m->least_addr)
3575
          m->least_addr = tbase;
3576
        sp = &m->seg;
3577
        while (sp != 0 && sp->base != tbase + tsize)
3578
          sp = sp->next;
3579
        if (sp != 0 &&
3580
            !is_extern_segment(sp) &&
3581
            check_segment_merge(sp, tbase, tsize) &&
3582
            (get_segment_flags(sp) & IS_MMAPPED_BIT) == mmap_flag) {
3583
          char* oldbase = sp->base;
3584
          sp->base = tbase;
3585
          sp->size += tsize;
3586
          return prepend_alloc(m, tbase, oldbase, nb);
3587
        }
3588
        else
3589
          add_segment(m, tbase, tsize, mmap_flag);
3590
      }
3591
    }
3592
 
3593
    if (nb < m->topsize) { /* Allocate from new or extended top space */
3594
      size_t rsize = m->topsize -= nb;
3595
      mchunkptr p = m->top;
3596
      mchunkptr r = m->top = chunk_plus_offset(p, nb);
3597
      r->head = rsize | PINUSE_BIT;
3598
      set_size_and_pinuse_of_inuse_chunk(m, p, nb);
3599
      check_top_chunk(m, m->top);
3600
      check_malloced_chunk(m, chunk2mem(p), nb);
3601
      return chunk2mem(p);
3602
    }
3603
  }
3604
 
3605
  MALLOC_FAILURE_ACTION;
3606
  return 0;
3607
}
3608
 
3609
/* -----------------------  system deallocation -------------------------- */
3610
 
3611
/* Unmap and unlink any mmapped segments that don't contain used chunks */
3612
static size_t release_unused_segments(mstate m) {
3613
  size_t released = 0;
3614
  msegmentptr pred = &m->seg;
3615
  msegmentptr sp = pred->next;
3616
  while (sp != 0) {
3617
    char* base = sp->base;
3618
    size_t size = sp->size;
3619
    msegmentptr next = sp->next;
3620
    if (is_mmapped_segment(sp) && !is_extern_segment(sp)) {
3621
      mchunkptr p = align_as_chunk(base);
3622
      size_t psize = chunksize(p);
3623
      /* Can unmap if first chunk holds entire segment and not pinned */
3624
      if (!cinuse(p) && (char*)p + psize >= base + size - TOP_FOOT_SIZE) {
3625
        tchunkptr tp = (tchunkptr)p;
3626
        assert(segment_holds(sp, (char*)sp));
3627
        if (p == m->dv) {
3628
          m->dv = 0;
3629
          m->dvsize = 0;
3630
        }
3631
        else {
3632
          unlink_large_chunk(m, tp);
3633
        }
3634
        if (CALL_MUNMAP(base, size) == 0) {
3635
          released += size;
3636
          m->footprint -= size;
3637
          /* unlink obsoleted record */
3638
          sp = pred;
3639
          sp->next = next;
3640
        }
3641
        else { /* back out if cannot unmap */
3642
          insert_large_chunk(m, tp, psize);
3643
        }
3644
      }
3645
    }
3646
    pred = sp;
3647
    sp = next;
3648
  }
3649
  return released;
3650
}
3651
 
3652
static int sys_trim(mstate m, size_t pad) {
3653
  size_t released = 0;
3654
  if (pad < MAX_REQUEST && is_initialized(m)) {
3655
    pad += TOP_FOOT_SIZE; /* ensure enough room for segment overhead */
3656
 
3657
    if (m->topsize > pad) {
3658
      /* Shrink top space in granularity-size units, keeping at least one */
3659
      size_t unit = mparams.granularity;
3660
      size_t extra = ((m->topsize - pad + (unit - SIZE_T_ONE)) / unit -
3661
                      SIZE_T_ONE) * unit;
3662
      msegmentptr sp = segment_holding(m, (char*)m->top);
3663
 
3664
      if (!is_extern_segment(sp)) {
3665
        if (is_mmapped_segment(sp)) {
3666
          if (HAVE_MMAP &&
3667
              sp->size >= extra &&
3668
              !has_segment_link(m, sp)) { /* can't shrink if pinned */
3669
            size_t newsize = sp->size - extra;
3670
            /* Prefer mremap, fall back to munmap */
3671
            if ((CALL_MREMAP(sp->base, sp->size, newsize, 0) != MFAIL) ||
3672
                (CALL_MUNMAP(sp->base + newsize, extra) == 0)) {
3673
              released = extra;
3674
            }
3675
          }
3676
        }
3677
        else if (HAVE_MORECORE) {
3678
          if (extra >= HALF_MAX_SIZE_T) /* Avoid wrapping negative */
3679
            extra = (HALF_MAX_SIZE_T) + SIZE_T_ONE - unit;
3680
          ACQUIRE_MORECORE_LOCK();
3681
          {
3682
            /* Make sure end of memory is where we last set it. */
3683
            char* old_br = (char*)(CALL_MORECORE(0));
3684
            if (old_br == sp->base + sp->size) {
3685
              char* rel_br = (char*)(CALL_MORECORE(-extra));
3686
              char* new_br = (char*)(CALL_MORECORE(0));
3687
              if (rel_br != CMFAIL && new_br < old_br)
3688
                released = old_br - new_br;
3689
            }
3690
          }
3691
          RELEASE_MORECORE_LOCK();
3692
        }
3693
      }
3694
 
3695
      if (released != 0) {
3696
        sp->size -= released;
3697
        m->footprint -= released;
3698
        init_top(m, m->top, m->topsize - released);
3699
        check_top_chunk(m, m->top);
3700
      }
3701
    }
3702
 
3703
    /* Unmap any unused mmapped segments */
3704
    if (HAVE_MMAP)
3705
      released += release_unused_segments(m);
3706
 
3707
    /* On failure, disable autotrim to avoid repeated failed future calls */
3708
    if (released == 0)
3709
      m->trim_check = MAX_SIZE_T;
3710
  }
3711
 
3712
  return (released != 0)? 1 : 0;
3713
}
3714
 
3715
/* ---------------------------- malloc support --------------------------- */
3716
 
3717
/* allocate a large request from the best fitting chunk in a treebin */
3718
static void* tmalloc_large(mstate m, size_t nb) {
3719
  tchunkptr v = 0;
3720
  size_t rsize = -nb; /* Unsigned negation */
3721
  tchunkptr t;
3722
  bindex_t idx;
3723
  compute_tree_index(nb, idx);
3724
 
3725
  if ((t = *treebin_at(m, idx)) != 0) {
3726
    /* Traverse tree for this bin looking for node with size == nb */
3727
    size_t sizebits = nb << leftshift_for_tree_index(idx);
3728
    tchunkptr rst = 0;  /* The deepest untaken right subtree */
3729
    for (;;) {
3730
      tchunkptr rt;
3731
      size_t trem = chunksize(t) - nb;
3732
      if (trem < rsize) {
3733
        v = t;
3734
        if ((rsize = trem) == 0)
3735
          break;
3736
      }
3737
      rt = t->child[1];
3738
      t = t->child[(sizebits >> (SIZE_T_BITSIZE-SIZE_T_ONE)) & 1];
3739
      if (rt != 0 && rt != t)
3740
        rst = rt;
3741
      if (t == 0) {
3742
        t = rst; /* set t to least subtree holding sizes > nb */
3743
        break;
3744
      }
3745
      sizebits <<= 1;
3746
    }
3747
  }
3748
 
3749
  if (t == 0 && v == 0) { /* set t to root of next non-empty treebin */
3750
    binmap_t leftbits = left_bits(idx2bit(idx)) & m->treemap;
3751
    if (leftbits != 0) {
3752
      bindex_t i;
3753
      binmap_t leastbit = least_bit(leftbits);
3754
      compute_bit2idx(leastbit, i);
3755
      t = *treebin_at(m, i);
3756
    }
3757
  }
3758
 
3759
  while (t != 0) { /* find smallest of tree or subtree */
3760
    size_t trem = chunksize(t) - nb;
3761
    if (trem < rsize) {
3762
      rsize = trem;
3763
      v = t;
3764
    }
3765
    t = leftmost_child(t);
3766
  }
3767
 
3768
  /*  If dv is a better fit, return 0 so malloc will use it */
3769
  if (v != 0 && rsize < (size_t)(m->dvsize - nb)) {
3770
    if (RTCHECK(ok_address(m, v))) { /* split */
3771
      mchunkptr r = chunk_plus_offset(v, nb);
3772
      assert(chunksize(v) == rsize + nb);
3773
      if (RTCHECK(ok_next(v, r))) {
3774
        unlink_large_chunk(m, v);
3775
        if (rsize < MIN_CHUNK_SIZE)
3776
          set_inuse_and_pinuse(m, v, (rsize + nb));
3777
        else {
3778
          set_size_and_pinuse_of_inuse_chunk(m, v, nb);
3779
          set_size_and_pinuse_of_free_chunk(r, rsize);
3780
          insert_chunk(m, r, rsize);
3781
        }
3782
        return chunk2mem(v);
3783
      }
3784
    }
3785
    CORRUPTION_ERROR_ACTION(m);
3786
  }
3787
  return 0;
3788
}
3789
 
3790
/* allocate a small request from the best fitting chunk in a treebin */
3791
static void* tmalloc_small(mstate m, size_t nb) {
3792
  tchunkptr t, v;
3793
  size_t rsize;
3794
  bindex_t i;
3795
  binmap_t leastbit = least_bit(m->treemap);
3796
  compute_bit2idx(leastbit, i);
3797
 
3798
  v = t = *treebin_at(m, i);
3799
  rsize = chunksize(t) - nb;
3800
 
3801
  while ((t = leftmost_child(t)) != 0) {
3802
    size_t trem = chunksize(t) - nb;
3803
    if (trem < rsize) {
3804
      rsize = trem;
3805
      v = t;
3806
    }
3807
  }
3808
 
3809
  if (RTCHECK(ok_address(m, v))) {
3810
    mchunkptr r = chunk_plus_offset(v, nb);
3811
    assert(chunksize(v) == rsize + nb);
3812
    if (RTCHECK(ok_next(v, r))) {
3813
      unlink_large_chunk(m, v);
3814
      if (rsize < MIN_CHUNK_SIZE)
3815
        set_inuse_and_pinuse(m, v, (rsize + nb));
3816
      else {
3817
        set_size_and_pinuse_of_inuse_chunk(m, v, nb);
3818
        set_size_and_pinuse_of_free_chunk(r, rsize);
3819
        replace_dv(m, r, rsize);
3820
      }
3821
      return chunk2mem(v);
3822
    }
3823
  }
3824
 
3825
  CORRUPTION_ERROR_ACTION(m);
3826
  return 0;
3827
}
3828
 
3829
/* --------------------------- realloc support --------------------------- */
3830
 
3831
static void* internal_realloc(mstate m, void* oldmem, size_t bytes) {
3832
  if (bytes >= MAX_REQUEST) {
3833
    MALLOC_FAILURE_ACTION;
3834
    return 0;
3835
  }
3836
  if (!PREACTION(m)) {
3837
    mchunkptr oldp = mem2chunk(oldmem);
3838
    size_t oldsize = chunksize(oldp);
3839
    mchunkptr next = chunk_plus_offset(oldp, oldsize);
3840
    mchunkptr newp = 0;
3841
    void* extra = 0;
3842
 
3843
    /* Try to either shrink or extend into top. Else malloc-copy-free */
3844
 
3845
    if (RTCHECK(ok_address(m, oldp) && ok_cinuse(oldp) &&
3846
                ok_next(oldp, next) && ok_pinuse(next))) {
3847
      size_t nb = request2size(bytes);
3848
      if (is_mmapped(oldp))
3849
        newp = mmap_resize(m, oldp, nb);
3850
      else if (oldsize >= nb) { /* already big enough */
3851
        size_t rsize = oldsize - nb;
3852
        newp = oldp;
3853
        if (rsize >= MIN_CHUNK_SIZE) {
3854
          mchunkptr remainder = chunk_plus_offset(newp, nb);
3855
          set_inuse(m, newp, nb);
3856
          set_inuse(m, remainder, rsize);
3857
          extra = chunk2mem(remainder);
3858
        }
3859
      }
3860
      else if (next == m->top && oldsize + m->topsize > nb) {
3861
        /* Expand into top */
3862
        size_t newsize = oldsize + m->topsize;
3863
        size_t newtopsize = newsize - nb;
3864
        mchunkptr newtop = chunk_plus_offset(oldp, nb);
3865
        set_inuse(m, oldp, nb);
3866
        newtop->head = newtopsize |PINUSE_BIT;
3867
        m->top = newtop;
3868
        m->topsize = newtopsize;
3869
        newp = oldp;
3870
      }
3871
    }
3872
    else {
3873
      USAGE_ERROR_ACTION(m, oldmem);
3874
      POSTACTION(m);
3875
      return 0;
3876
    }
3877
 
3878
    POSTACTION(m);
3879
 
3880
    if (newp != 0) {
3881
      if (extra != 0) {
3882
        internal_free(m, extra);
3883
      }
3884
      check_inuse_chunk(m, newp);
3885
      return chunk2mem(newp);
3886
    }
3887
    else {
3888
      void* newmem = internal_malloc(m, bytes);
3889
      if (newmem != 0) {
3890
        size_t oc = oldsize - overhead_for(oldp);
3891
        memcpy(newmem, oldmem, (oc < bytes)? oc : bytes);
3892
        internal_free(m, oldmem);
3893
      }
3894
      return newmem;
3895
    }
3896
  }
3897
  return 0;
3898
}
3899
 
3900
/* --------------------------- memalign support -------------------------- */
3901
 
3902
static void* internal_memalign(mstate m, size_t alignment, size_t bytes) {
3903
  if (alignment <= MALLOC_ALIGNMENT)    /* Can just use malloc */
3904
    return internal_malloc(m, bytes);
3905
  if (alignment <  MIN_CHUNK_SIZE) /* must be at least a minimum chunk size */
3906
    alignment = MIN_CHUNK_SIZE;
3907
  if ((alignment & (alignment-SIZE_T_ONE)) != 0) {/* Ensure a power of 2 */
3908
    size_t a = MALLOC_ALIGNMENT << 1;
3909
    while (a < alignment) a <<= 1;
3910
    alignment = a;
3911
  }
3912
 
3913
  if (bytes >= MAX_REQUEST - alignment) {
3914
    if (m != 0)  { /* Test isn't needed but avoids compiler warning */
3915
      MALLOC_FAILURE_ACTION;
3916
    }
3917
  }
3918
  else {
3919
    size_t nb = request2size(bytes);
3920
    size_t req = nb + alignment + MIN_CHUNK_SIZE - CHUNK_OVERHEAD;
3921
    char* mem = (char*)internal_malloc(m, req);
3922
    if (mem != 0) {
3923
      void* leader = 0;
3924
      void* trailer = 0;
3925
      mchunkptr p = mem2chunk(mem);
3926
 
3927
      if (PREACTION(m)) return 0;
3928
      if ((((size_t)(mem)) % alignment) != 0) { /* misaligned */
3929
        /*
3930
          Find an aligned spot inside chunk.  Since we need to give
3931
          back leading space in a chunk of at least MIN_CHUNK_SIZE, if
3932
          the first calculation places us at a spot with less than
3933
          MIN_CHUNK_SIZE leader, we can move to the next aligned spot.
3934
          We've allocated enough total room so that this is always
3935
          possible.
3936
        */
3937
        char* br = (char*)mem2chunk((size_t)(((size_t)(mem +
3938
                                                       alignment -
3939
                                                       SIZE_T_ONE)) &
3940
                                             -alignment));
3941
        char* pos = ((size_t)(br - (char*)(p)) >= MIN_CHUNK_SIZE)?
3942
          br : br+alignment;
3943
        mchunkptr newp = (mchunkptr)pos;
3944
        size_t leadsize = pos - (char*)(p);
3945
        size_t newsize = chunksize(p) - leadsize;
3946
 
3947
        if (is_mmapped(p)) { /* For mmapped chunks, just adjust offset */
3948
          newp->prev_foot = p->prev_foot + leadsize;
3949
          newp->head = (newsize|CINUSE_BIT);
3950
        }
3951
        else { /* Otherwise, give back leader, use the rest */
3952
          set_inuse(m, newp, newsize);
3953
          set_inuse(m, p, leadsize);
3954
          leader = chunk2mem(p);
3955
        }
3956
        p = newp;
3957
      }
3958
 
3959
      /* Give back spare room at the end */
3960
      if (!is_mmapped(p)) {
3961
        size_t size = chunksize(p);
3962
        if (size > nb + MIN_CHUNK_SIZE) {
3963
          size_t remainder_size = size - nb;
3964
          mchunkptr remainder = chunk_plus_offset(p, nb);
3965
          set_inuse(m, p, nb);
3966
          set_inuse(m, remainder, remainder_size);
3967
          trailer = chunk2mem(remainder);
3968
        }
3969
      }
3970
 
3971
      assert (chunksize(p) >= nb);
3972
      assert((((size_t)(chunk2mem(p))) % alignment) == 0);
3973
      check_inuse_chunk(m, p);
3974
      POSTACTION(m);
3975
      if (leader != 0) {
3976
        internal_free(m, leader);
3977
      }
3978
      if (trailer != 0) {
3979
        internal_free(m, trailer);
3980
      }
3981
      return chunk2mem(p);
3982
    }
3983
  }
3984
  return 0;
3985
}
3986
 
3987
/* ------------------------ comalloc/coalloc support --------------------- */
3988
 
3989
static void** ialloc(mstate m,
3990
                     size_t n_elements,
3991
                     size_t* sizes,
3992
                     int opts,
3993
                     void* chunks[]) {
3994
  /*
3995
    This provides common support for independent_X routines, handling
3996
    all of the combinations that can result.
3997
 
3998
    The opts arg has:
3999
    bit 0 set if all elements are same size (using sizes[0])
4000
    bit 1 set if elements should be zeroed
4001
  */
4002
 
4003
  size_t    element_size;   /* chunksize of each element, if all same */
4004
  size_t    contents_size;  /* total size of elements */
4005
  size_t    array_size;     /* request size of pointer array */
4006
  void*     mem;            /* malloced aggregate space */
4007
  mchunkptr p;              /* corresponding chunk */
4008
  size_t    remainder_size; /* remaining bytes while splitting */
4009
  void**    marray;         /* either "chunks" or malloced ptr array */
4010
  mchunkptr array_chunk;    /* chunk for malloced ptr array */
4011
  flag_t    was_enabled;    /* to disable mmap */
4012
  size_t    size;
4013
  size_t    i;
4014
 
4015
  /* compute array length, if needed */
4016
  if (chunks != 0) {
4017
    if (n_elements == 0)
4018
      return chunks; /* nothing to do */
4019
    marray = chunks;
4020
    array_size = 0;
4021
  }
4022
  else {
4023
    /* if empty req, must still return chunk representing empty array */
4024
    if (n_elements == 0)
4025
      return (void**)internal_malloc(m, 0);
4026
    marray = 0;
4027
    array_size = request2size(n_elements * (sizeof(void*)));
4028
  }
4029
 
4030
  /* compute total element size */
4031
  if (opts & 0x1) { /* all-same-size */
4032
    element_size = request2size(*sizes);
4033
    contents_size = n_elements * element_size;
4034
  }
4035
  else { /* add up all the sizes */
4036
    element_size = 0;
4037
    contents_size = 0;
4038
    for (i = 0; i != n_elements; ++i)
4039
      contents_size += request2size(sizes[i]);
4040
  }
4041
 
4042
  size = contents_size + array_size;
4043
 
4044
  /*
4045
     Allocate the aggregate chunk.  First disable direct-mmapping so
4046
     malloc won't use it, since we would not be able to later
4047
     free/realloc space internal to a segregated mmap region.
4048
  */
4049
  was_enabled = use_mmap(m);
4050
  disable_mmap(m);
4051
  mem = internal_malloc(m, size - CHUNK_OVERHEAD);
4052
  if (was_enabled)
4053
    enable_mmap(m);
4054
  if (mem == 0)
4055
    return 0;
4056
 
4057
  if (PREACTION(m)) return 0;
4058
  p = mem2chunk(mem);
4059
  remainder_size = chunksize(p);
4060
 
4061
  assert(!is_mmapped(p));
4062
 
4063
  if (opts & 0x2) {       /* optionally clear the elements */
4064
    memset((size_t*)mem, 0, remainder_size - SIZE_T_SIZE - array_size);
4065
  }
4066
 
4067
  /* If not provided, allocate the pointer array as final part of chunk */
4068
  if (marray == 0) {
4069
    size_t  array_chunk_size;
4070
    array_chunk = chunk_plus_offset(p, contents_size);
4071
    array_chunk_size = remainder_size - contents_size;
4072
    marray = (void**) (chunk2mem(array_chunk));
4073
    set_size_and_pinuse_of_inuse_chunk(m, array_chunk, array_chunk_size);
4074
    remainder_size = contents_size;
4075
  }
4076
 
4077
  /* split out elements */
4078
  for (i = 0; ; ++i) {
4079
    marray[i] = chunk2mem(p);
4080
    if (i != n_elements-1) {
4081
      if (element_size != 0)
4082
        size = element_size;
4083
      else
4084
        size = request2size(sizes[i]);
4085
      remainder_size -= size;
4086
      set_size_and_pinuse_of_inuse_chunk(m, p, size);
4087
      p = chunk_plus_offset(p, size);
4088
    }
4089
    else { /* the final element absorbs any overallocation slop */
4090
      set_size_and_pinuse_of_inuse_chunk(m, p, remainder_size);
4091
      break;
4092
    }
4093
  }
4094
 
4095
#if DEBUG
4096
  if (marray != chunks) {
4097
    /* final element must have exactly exhausted chunk */
4098
    if (element_size != 0) {
4099
      assert(remainder_size == element_size);
4100
    }
4101
    else {
4102
      assert(remainder_size == request2size(sizes[i]));
4103
    }
4104
    check_inuse_chunk(m, mem2chunk(marray));
4105
  }
4106
  for (i = 0; i != n_elements; ++i)
4107
    check_inuse_chunk(m, mem2chunk(marray[i]));
4108
 
4109
#endif /* DEBUG */
4110
 
4111
  POSTACTION(m);
4112
  return marray;
4113
}
4114
 
4115
 
4116
/* -------------------------- public routines ---------------------------- */
4117
 
4118
#if !ONLY_MSPACES
4119
 
4120
void* dlmalloc(size_t bytes) {
4121
  /*
4122
     Basic algorithm:
4123
     If a small request (< 256 bytes minus per-chunk overhead):
4124
       1. If one exists, use a remainderless chunk in associated smallbin.
4125
          (Remainderless means that there are too few excess bytes to
4126
          represent as a chunk.)
4127
       2. If it is big enough, use the dv chunk, which is normally the
4128
          chunk adjacent to the one used for the most recent small request.
4129
       3. If one exists, split the smallest available chunk in a bin,
4130
          saving remainder in dv.
4131
       4. If it is big enough, use the top chunk.
4132
       5. If available, get memory from system and use it
4133
     Otherwise, for a large request:
4134
       1. Find the smallest available binned chunk that fits, and use it
4135
          if it is better fitting than dv chunk, splitting if necessary.
4136
       2. If better fitting than any binned chunk, use the dv chunk.
4137
       3. If it is big enough, use the top chunk.
4138
       4. If request size >= mmap threshold, try to directly mmap this chunk.
4139
       5. If available, get memory from system and use it
4140
 
4141
     The ugly goto's here ensure that postaction occurs along all paths.
4142
  */
4143
 
4144
  if (!PREACTION(gm)) {
4145
    void* mem;
4146
    size_t nb;
4147
    if (bytes <= MAX_SMALL_REQUEST) {
4148
      bindex_t idx;
4149
      binmap_t smallbits;
4150
      nb = (bytes < MIN_REQUEST)? MIN_CHUNK_SIZE : pad_request(bytes);
4151
      idx = small_index(nb);
4152
      smallbits = gm->smallmap >> idx;
4153
 
4154
      if ((smallbits & 0x3U) != 0) { /* Remainderless fit to a smallbin. */
4155
        mchunkptr b, p;
4156
        idx += ~smallbits & 1;       /* Uses next bin if idx empty */
4157
        b = smallbin_at(gm, idx);
4158
        p = b->fd;
4159
        assert(chunksize(p) == small_index2size(idx));
4160
        unlink_first_small_chunk(gm, b, p, idx);
4161
        set_inuse_and_pinuse(gm, p, small_index2size(idx));
4162
        mem = chunk2mem(p);
4163
        check_malloced_chunk(gm, mem, nb);
4164
        goto postaction;
4165
      }
4166
 
4167
      else if (nb > gm->dvsize) {
4168
        if (smallbits != 0) { /* Use chunk in next nonempty smallbin */
4169
          mchunkptr b, p, r;
4170
          size_t rsize;
4171
          bindex_t i;
4172
          binmap_t leftbits = (smallbits << idx) & left_bits(idx2bit(idx));
4173
          binmap_t leastbit = least_bit(leftbits);
4174
          compute_bit2idx(leastbit, i);
4175
          b = smallbin_at(gm, i);
4176
          p = b->fd;
4177
          assert(chunksize(p) == small_index2size(i));
4178
          unlink_first_small_chunk(gm, b, p, i);
4179
          rsize = small_index2size(i) - nb;
4180
          /* Fit here cannot be remainderless if 4byte sizes */
4181
          if (SIZE_T_SIZE != 4 && rsize < MIN_CHUNK_SIZE)
4182
            set_inuse_and_pinuse(gm, p, small_index2size(i));
4183
          else {
4184
            set_size_and_pinuse_of_inuse_chunk(gm, p, nb);
4185
            r = chunk_plus_offset(p, nb);
4186
            set_size_and_pinuse_of_free_chunk(r, rsize);
4187
            replace_dv(gm, r, rsize);
4188
          }
4189
          mem = chunk2mem(p);
4190
          check_malloced_chunk(gm, mem, nb);
4191
          goto postaction;
4192
        }
4193
 
4194
        else if (gm->treemap != 0 && (mem = tmalloc_small(gm, nb)) != 0) {
4195
          check_malloced_chunk(gm, mem, nb);
4196
          goto postaction;
4197
        }
4198
      }
4199
    }
4200
    else if (bytes >= MAX_REQUEST)
4201
      nb = MAX_SIZE_T; /* Too big to allocate. Force failure (in sys alloc) */
4202
    else {
4203
      nb = pad_request(bytes);
4204
      if (gm->treemap != 0 && (mem = tmalloc_large(gm, nb)) != 0) {
4205
        check_malloced_chunk(gm, mem, nb);
4206
        goto postaction;
4207
      }
4208
    }
4209
 
4210
    if (nb <= gm->dvsize) {
4211
      size_t rsize = gm->dvsize - nb;
4212
      mchunkptr p = gm->dv;
4213
      if (rsize >= MIN_CHUNK_SIZE) { /* split dv */
4214
        mchunkptr r = gm->dv = chunk_plus_offset(p, nb);
4215
        gm->dvsize = rsize;
4216
        set_size_and_pinuse_of_free_chunk(r, rsize);
4217
        set_size_and_pinuse_of_inuse_chunk(gm, p, nb);
4218
      }
4219
      else { /* exhaust dv */
4220
        size_t dvs = gm->dvsize;
4221
        gm->dvsize = 0;
4222
        gm->dv = 0;
4223
        set_inuse_and_pinuse(gm, p, dvs);
4224
      }
4225
      mem = chunk2mem(p);
4226
      check_malloced_chunk(gm, mem, nb);
4227
      goto postaction;
4228
    }
4229
 
4230
    else if (nb < gm->topsize) { /* Split top */
4231
      size_t rsize = gm->topsize -= nb;
4232
      mchunkptr p = gm->top;
4233
      mchunkptr r = gm->top = chunk_plus_offset(p, nb);
4234
      r->head = rsize | PINUSE_BIT;
4235
      set_size_and_pinuse_of_inuse_chunk(gm, p, nb);
4236
      mem = chunk2mem(p);
4237
      check_top_chunk(gm, gm->top);
4238
      check_malloced_chunk(gm, mem, nb);
4239
      goto postaction;
4240
    }
4241
 
4242
    mem = sys_alloc(gm, nb);
4243
 
4244
  postaction:
4245
    POSTACTION(gm);
4246
    return mem;
4247
  }
4248
 
4249
  return 0;
4250
}
4251
 
4252
void dlfree(void* mem) {
4253
  /*
4254
     Consolidate freed chunks with preceding or succeeding bordering
4255
     free chunks, if they exist, and then place in a bin.  Intermixed
4256
     with special cases for top, dv, mmapped chunks, and usage errors.
4257
  */
4258
 
4259
  if (mem != 0) {
4260
    mchunkptr p  = mem2chunk(mem);
4261
#if FOOTERS
4262
    mstate fm = get_mstate_for(p);
4263
    if (!ok_magic(fm)) {
4264
      USAGE_ERROR_ACTION(fm, p);
4265
      return;
4266
    }
4267
#else /* FOOTERS */
4268
#define fm gm
4269
#endif /* FOOTERS */
4270
    if (!PREACTION(fm)) {
4271
      check_inuse_chunk(fm, p);
4272
      if (RTCHECK(ok_address(fm, p) && ok_cinuse(p))) {
4273
        size_t psize = chunksize(p);
4274
        mchunkptr next = chunk_plus_offset(p, psize);
4275
        if (!pinuse(p)) {
4276
          size_t prevsize = p->prev_foot;
4277
          if ((prevsize & IS_MMAPPED_BIT) != 0) {
4278
            prevsize &= ~IS_MMAPPED_BIT;
4279
            psize += prevsize + MMAP_FOOT_PAD;
4280
            if (CALL_MUNMAP((char*)p - prevsize, psize) == 0)
4281
              fm->footprint -= psize;
4282
            goto postaction;
4283
          }
4284
          else {
4285
            mchunkptr prev = chunk_minus_offset(p, prevsize);
4286
            psize += prevsize;
4287
            p = prev;
4288
            if (RTCHECK(ok_address(fm, prev))) { /* consolidate backward */
4289
              if (p != fm->dv) {
4290
                unlink_chunk(fm, p, prevsize);
4291
              }
4292
              else if ((next->head & INUSE_BITS) == INUSE_BITS) {
4293
                fm->dvsize = psize;
4294
                set_free_with_pinuse(p, psize, next);
4295
                goto postaction;
4296
              }
4297
            }
4298
            else
4299
              goto erroraction;
4300
          }
4301
        }
4302
 
4303
        if (RTCHECK(ok_next(p, next) && ok_pinuse(next))) {
4304
          if (!cinuse(next)) {  /* consolidate forward */
4305
            if (next == fm->top) {
4306
              size_t tsize = fm->topsize += psize;
4307
              fm->top = p;
4308
              p->head = tsize | PINUSE_BIT;
4309
              if (p == fm->dv) {
4310
                fm->dv = 0;
4311
                fm->dvsize = 0;
4312
              }
4313
              if (should_trim(fm, tsize))
4314
                sys_trim(fm, 0);
4315
              goto postaction;
4316
            }
4317
            else if (next == fm->dv) {
4318
              size_t dsize = fm->dvsize += psize;
4319
              fm->dv = p;
4320
              set_size_and_pinuse_of_free_chunk(p, dsize);
4321
              goto postaction;
4322
            }
4323
            else {
4324
              size_t nsize = chunksize(next);
4325
              psize += nsize;
4326
              unlink_chunk(fm, next, nsize);
4327
              set_size_and_pinuse_of_free_chunk(p, psize);
4328
              if (p == fm->dv) {
4329
                fm->dvsize = psize;
4330
                goto postaction;
4331
              }
4332
            }
4333
          }
4334
          else
4335
            set_free_with_pinuse(p, psize, next);
4336
          insert_chunk(fm, p, psize);
4337
          check_free_chunk(fm, p);
4338
          goto postaction;
4339
        }
4340
      }
4341
    erroraction:
4342
      USAGE_ERROR_ACTION(fm, p);
4343
    postaction:
4344
      POSTACTION(fm);
4345
    }
4346
  }
4347
#if !FOOTERS
4348
#undef fm
4349
#endif /* FOOTERS */
4350
}
4351
 
4352
void* dlcalloc(size_t n_elements, size_t elem_size) {
4353
  void* mem;
4354
  size_t req = 0;
4355
  if (n_elements != 0) {
4356
    req = n_elements * elem_size;
4357
    if (((n_elements | elem_size) & ~(size_t)0xffff) &&
4358
        (req / n_elements != elem_size))
4359
      req = MAX_SIZE_T; /* force downstream failure on overflow */
4360
  }
4361
  mem = dlmalloc(req);
4362
  if (mem != 0 && calloc_must_clear(mem2chunk(mem)))
4363
    memset(mem, 0, req);
4364
  return mem;
4365
}
4366
 
4367
void* dlrealloc(void* oldmem, size_t bytes) {
4368
  if (oldmem == 0)
4369
    return dlmalloc(bytes);
4370
#ifdef REALLOC_ZERO_BYTES_FREES
4371
  if (bytes == 0) {
4372
    dlfree(oldmem);
4373
    return 0;
4374
  }
4375
#endif /* REALLOC_ZERO_BYTES_FREES */
4376
  else {
4377
#if ! FOOTERS
4378
    mstate m = gm;
4379
#else /* FOOTERS */
4380
    mstate m = get_mstate_for(mem2chunk(oldmem));
4381
    if (!ok_magic(m)) {
4382
      USAGE_ERROR_ACTION(m, oldmem);
4383
      return 0;
4384
    }
4385
#endif /* FOOTERS */
4386
    return internal_realloc(m, oldmem, bytes);
4387
  }
4388
}
4389
 
4390
void* dlmemalign(size_t alignment, size_t bytes) {
4391
  return internal_memalign(gm, alignment, bytes);
4392
}
4393
 
4394
void** dlindependent_calloc(size_t n_elements, size_t elem_size,
4395
                                 void* chunks[]) {
4396
  size_t sz = elem_size; /* serves as 1-element array */
4397
  return ialloc(gm, n_elements, &sz, 3, chunks);
4398
}
4399
 
4400
void** dlindependent_comalloc(size_t n_elements, size_t sizes[],
4401
                                   void* chunks[]) {
4402
  return ialloc(gm, n_elements, sizes, 0, chunks);
4403
}
4404
 
4405
void* dlvalloc(size_t bytes) {
4406
  size_t pagesz;
4407
  init_mparams();
4408
  pagesz = mparams.page_size;
4409
  return dlmemalign(pagesz, bytes);
4410
}
4411
 
4412
void* dlpvalloc(size_t bytes) {
4413
  size_t pagesz;
4414
  init_mparams();
4415
  pagesz = mparams.page_size;
4416
  return dlmemalign(pagesz, (bytes + pagesz - SIZE_T_ONE) & ~(pagesz - SIZE_T_ONE));
4417
}
4418
 
4419
int dlmalloc_trim(size_t pad) {
4420
  int result = 0;
4421
  if (!PREACTION(gm)) {
4422
    result = sys_trim(gm, pad);
4423
    POSTACTION(gm);
4424
  }
4425
  return result;
4426
}
4427
 
4428
size_t dlmalloc_footprint(void) {
4429
  return gm->footprint;
4430
}
4431
 
4432
size_t dlmalloc_max_footprint(void) {
4433
  return gm->max_footprint;
4434
}
4435
 
4436
#if !NO_MALLINFO
4437
struct mallinfo dlmallinfo(void) {
4438
  return internal_mallinfo(gm);
4439
}
4440
#endif /* NO_MALLINFO */
4441
 
4442
void dlmalloc_stats() {
4443
  internal_malloc_stats(gm);
4444
}
4445
 
4446
size_t dlmalloc_usable_size(void* mem) {
4447
  if (mem != 0) {
4448
    mchunkptr p = mem2chunk(mem);
4449
    if (cinuse(p))
4450
      return chunksize(p) - overhead_for(p);
4451
  }
4452
  return 0;
4453
}
4454
 
4455
int dlmallopt(int param_number, int value) {
4456
  return change_mparam(param_number, value);
4457
}
4458
 
4459
#endif /* !ONLY_MSPACES */
4460
 
4461
/* ----------------------------- user mspaces ---------------------------- */
4462
 
4463
#if MSPACES
4464
 
4465
static mstate init_user_mstate(char* tbase, size_t tsize) {
4466
  size_t msize = pad_request(sizeof(struct malloc_state));
4467
  mchunkptr mn;
4468
  mchunkptr msp = align_as_chunk(tbase);
4469
  mstate m = (mstate)(chunk2mem(msp));
4470
  memset(m, 0, msize);
4471
  INITIAL_LOCK(&m->mutex);
4472
  msp->head = (msize|PINUSE_BIT|CINUSE_BIT);
4473
  m->seg.base = m->least_addr = tbase;
4474
  m->seg.size = m->footprint = m->max_footprint = tsize;
4475
  m->magic = mparams.magic;
4476
  m->mflags = mparams.default_mflags;
4477
  disable_contiguous(m);
4478
  init_bins(m);
4479
  mn = next_chunk(mem2chunk(m));
4480
  init_top(m, mn, (size_t)((tbase + tsize) - (char*)mn) - TOP_FOOT_SIZE);
4481
  check_top_chunk(m, m->top);
4482
  return m;
4483
}
4484
 
4485
mspace create_mspace(size_t capacity, int locked) {
4486
  mstate m = 0;
4487
  size_t msize = pad_request(sizeof(struct malloc_state));
4488
  init_mparams(); /* Ensure pagesize etc initialized */
4489
 
4490
  if (capacity < (size_t) -(msize + TOP_FOOT_SIZE + mparams.page_size)) {
4491
    size_t rs = ((capacity == 0)? mparams.granularity :
4492
                 (capacity + TOP_FOOT_SIZE + msize));
4493
    size_t tsize = granularity_align(rs);
4494
    char* tbase = (char*)(CALL_MMAP(tsize));
4495
    if (tbase != CMFAIL) {
4496
      m = init_user_mstate(tbase, tsize);
4497
      set_segment_flags(&m->seg, IS_MMAPPED_BIT);
4498
      set_lock(m, locked);
4499
    }
4500
  }
4501
  return (mspace)m;
4502
}
4503
 
4504
mspace create_mspace_with_base(void* base, size_t capacity, int locked) {
4505
  mstate m = 0;
4506
  size_t msize = pad_request(sizeof(struct malloc_state));
4507
  init_mparams(); /* Ensure pagesize etc initialized */
4508
 
4509
  if (capacity > msize + TOP_FOOT_SIZE &&
4510
      capacity < (size_t) -(msize + TOP_FOOT_SIZE + mparams.page_size)) {
4511
    m = init_user_mstate((char*)base, capacity);
4512
    set_segment_flags(&m->seg, EXTERN_BIT);
4513
    set_lock(m, locked);
4514
  }
4515
  return (mspace)m;
4516
}
4517
 
4518
size_t destroy_mspace(mspace msp) {
4519
  size_t freed = 0;
4520
  mstate ms = (mstate)msp;
4521
  if (ok_magic(ms)) {
4522
    msegmentptr sp = &ms->seg;
4523
    while (sp != 0) {
4524
      char* base = sp->base;
4525
      size_t size = sp->size;
4526
      flag_t flag = get_segment_flags(sp);
4527
      sp = sp->next;
4528
      if ((flag & IS_MMAPPED_BIT) && !(flag & EXTERN_BIT) &&
4529
          CALL_MUNMAP(base, size) == 0)
4530
        freed += size;
4531
    }
4532
  }
4533
  else {
4534
    USAGE_ERROR_ACTION(ms,ms);
4535
  }
4536
  return freed;
4537
}
4538
 
4539
/*
4540
  mspace versions of routines are near-clones of the global
4541
  versions. This is not so nice but better than the alternatives.
4542
*/
4543
 
4544
 
4545
void* mspace_malloc(mspace msp, size_t bytes) {
4546
  mstate ms = (mstate)msp;
4547
  if (!ok_magic(ms)) {
4548
    USAGE_ERROR_ACTION(ms,ms);
4549
    return 0;
4550
  }
4551
  if (!PREACTION(ms)) {
4552
    void* mem;
4553
    size_t nb;
4554
    if (bytes <= MAX_SMALL_REQUEST) {
4555
      bindex_t idx;
4556
      binmap_t smallbits;
4557
      nb = (bytes < MIN_REQUEST)? MIN_CHUNK_SIZE : pad_request(bytes);
4558
      idx = small_index(nb);
4559
      smallbits = ms->smallmap >> idx;
4560
 
4561
      if ((smallbits & 0x3U) != 0) { /* Remainderless fit to a smallbin. */
4562
        mchunkptr b, p;
4563
        idx += ~smallbits & 1;       /* Uses next bin if idx empty */
4564
        b = smallbin_at(ms, idx);
4565
        p = b->fd;
4566
        assert(chunksize(p) == small_index2size(idx));
4567
        unlink_first_small_chunk(ms, b, p, idx);
4568
        set_inuse_and_pinuse(ms, p, small_index2size(idx));
4569
        mem = chunk2mem(p);
4570
        check_malloced_chunk(ms, mem, nb);
4571
        goto postaction;
4572
      }
4573
 
4574
      else if (nb > ms->dvsize) {
4575
        if (smallbits != 0) { /* Use chunk in next nonempty smallbin */
4576
          mchunkptr b, p, r;
4577
          size_t rsize;
4578
          bindex_t i;
4579
          binmap_t leftbits = (smallbits << idx) & left_bits(idx2bit(idx));
4580
          binmap_t leastbit = least_bit(leftbits);
4581
          compute_bit2idx(leastbit, i);
4582
          b = smallbin_at(ms, i);
4583
          p = b->fd;
4584
          assert(chunksize(p) == small_index2size(i));
4585
          unlink_first_small_chunk(ms, b, p, i);
4586
          rsize = small_index2size(i) - nb;
4587
          /* Fit here cannot be remainderless if 4byte sizes */
4588
          if (SIZE_T_SIZE != 4 && rsize < MIN_CHUNK_SIZE)
4589
            set_inuse_and_pinuse(ms, p, small_index2size(i));
4590
          else {
4591
            set_size_and_pinuse_of_inuse_chunk(ms, p, nb);
4592
            r = chunk_plus_offset(p, nb);
4593
            set_size_and_pinuse_of_free_chunk(r, rsize);
4594
            replace_dv(ms, r, rsize);
4595
          }
4596
          mem = chunk2mem(p);
4597
          check_malloced_chunk(ms, mem, nb);
4598
          goto postaction;
4599
        }
4600
 
4601
        else if (ms->treemap != 0 && (mem = tmalloc_small(ms, nb)) != 0) {
4602
          check_malloced_chunk(ms, mem, nb);
4603
          goto postaction;
4604
        }
4605
      }
4606
    }
4607
    else if (bytes >= MAX_REQUEST)
4608
      nb = MAX_SIZE_T; /* Too big to allocate. Force failure (in sys alloc) */
4609
    else {
4610
      nb = pad_request(bytes);
4611
      if (ms->treemap != 0 && (mem = tmalloc_large(ms, nb)) != 0) {
4612
        check_malloced_chunk(ms, mem, nb);
4613
        goto postaction;
4614
      }
4615
    }
4616
 
4617
    if (nb <= ms->dvsize) {
4618
      size_t rsize = ms->dvsize - nb;
4619
      mchunkptr p = ms->dv;
4620
      if (rsize >= MIN_CHUNK_SIZE) { /* split dv */
4621
        mchunkptr r = ms->dv = chunk_plus_offset(p, nb);
4622
        ms->dvsize = rsize;
4623
        set_size_and_pinuse_of_free_chunk(r, rsize);
4624
        set_size_and_pinuse_of_inuse_chunk(ms, p, nb);
4625
      }
4626
      else { /* exhaust dv */
4627
        size_t dvs = ms->dvsize;
4628
        ms->dvsize = 0;
4629
        ms->dv = 0;
4630
        set_inuse_and_pinuse(ms, p, dvs);
4631
      }
4632
      mem = chunk2mem(p);
4633
      check_malloced_chunk(ms, mem, nb);
4634
      goto postaction;
4635
    }
4636
 
4637
    else if (nb < ms->topsize) { /* Split top */
4638
      size_t rsize = ms->topsize -= nb;
4639
      mchunkptr p = ms->top;
4640
      mchunkptr r = ms->top = chunk_plus_offset(p, nb);
4641
      r->head = rsize | PINUSE_BIT;
4642
      set_size_and_pinuse_of_inuse_chunk(ms, p, nb);
4643
      mem = chunk2mem(p);
4644
      check_top_chunk(ms, ms->top);
4645
      check_malloced_chunk(ms, mem, nb);
4646
      goto postaction;
4647
    }
4648
 
4649
    mem = sys_alloc(ms, nb);
4650
 
4651
  postaction:
4652
    POSTACTION(ms);
4653
    return mem;
4654
  }
4655
 
4656
  return 0;
4657
}
4658
 
4659
void mspace_free(mspace msp, void* mem) {
4660
  if (mem != 0) {
4661
    mchunkptr p  = mem2chunk(mem);
4662
#if FOOTERS
4663
    mstate fm = get_mstate_for(p);
4664
#else /* FOOTERS */
4665
    mstate fm = (mstate)msp;
4666
#endif /* FOOTERS */
4667
    if (!ok_magic(fm)) {
4668
      USAGE_ERROR_ACTION(fm, p);
4669
      return;
4670
    }
4671
    if (!PREACTION(fm)) {
4672
      check_inuse_chunk(fm, p);
4673
      if (RTCHECK(ok_address(fm, p) && ok_cinuse(p))) {
4674
        size_t psize = chunksize(p);
4675
        mchunkptr next = chunk_plus_offset(p, psize);
4676
        if (!pinuse(p)) {
4677
          size_t prevsize = p->prev_foot;
4678
          if ((prevsize & IS_MMAPPED_BIT) != 0) {
4679
            prevsize &= ~IS_MMAPPED_BIT;
4680
            psize += prevsize + MMAP_FOOT_PAD;
4681
            if (CALL_MUNMAP((char*)p - prevsize, psize) == 0)
4682
              fm->footprint -= psize;
4683
            goto postaction;
4684
          }
4685
          else {
4686
            mchunkptr prev = chunk_minus_offset(p, prevsize);
4687
            psize += prevsize;
4688
            p = prev;
4689
            if (RTCHECK(ok_address(fm, prev))) { /* consolidate backward */
4690
              if (p != fm->dv) {
4691
                unlink_chunk(fm, p, prevsize);
4692
              }
4693
              else if ((next->head & INUSE_BITS) == INUSE_BITS) {
4694
                fm->dvsize = psize;
4695
                set_free_with_pinuse(p, psize, next);
4696
                goto postaction;
4697
              }
4698
            }
4699
            else
4700
              goto erroraction;
4701
          }
4702
        }
4703
 
4704
        if (RTCHECK(ok_next(p, next) && ok_pinuse(next))) {
4705
          if (!cinuse(next)) {  /* consolidate forward */
4706
            if (next == fm->top) {
4707
              size_t tsize = fm->topsize += psize;
4708
              fm->top = p;
4709
              p->head = tsize | PINUSE_BIT;
4710
              if (p == fm->dv) {
4711
                fm->dv = 0;
4712
                fm->dvsize = 0;
4713
              }
4714
              if (should_trim(fm, tsize))
4715
                sys_trim(fm, 0);
4716
              goto postaction;
4717
            }
4718
            else if (next == fm->dv) {
4719
              size_t dsize = fm->dvsize += psize;
4720
              fm->dv = p;
4721
              set_size_and_pinuse_of_free_chunk(p, dsize);
4722
              goto postaction;
4723
            }
4724
            else {
4725
              size_t nsize = chunksize(next);
4726
              psize += nsize;
4727
              unlink_chunk(fm, next, nsize);
4728
              set_size_and_pinuse_of_free_chunk(p, psize);
4729
              if (p == fm->dv) {
4730
                fm->dvsize = psize;
4731
                goto postaction;
4732
              }
4733
            }
4734
          }
4735
          else
4736
            set_free_with_pinuse(p, psize, next);
4737
          insert_chunk(fm, p, psize);
4738
          check_free_chunk(fm, p);
4739
          goto postaction;
4740
        }
4741
      }
4742
    erroraction:
4743
      USAGE_ERROR_ACTION(fm, p);
4744
    postaction:
4745
      POSTACTION(fm);
4746
    }
4747
  }
4748
}
4749
 
4750
void* mspace_calloc(mspace msp, size_t n_elements, size_t elem_size) {
4751
  void* mem;
4752
  size_t req = 0;
4753
  mstate ms = (mstate)msp;
4754
  if (!ok_magic(ms)) {
4755
    USAGE_ERROR_ACTION(ms,ms);
4756
    return 0;
4757
  }
4758
  if (n_elements != 0) {
4759
    req = n_elements * elem_size;
4760
    if (((n_elements | elem_size) & ~(size_t)0xffff) &&
4761
        (req / n_elements != elem_size))
4762
      req = MAX_SIZE_T; /* force downstream failure on overflow */
4763
  }
4764
  mem = internal_malloc(ms, req);
4765
  if (mem != 0 && calloc_must_clear(mem2chunk(mem)))
4766
    memset(mem, 0, req);
4767
  return mem;
4768
}
4769
 
4770
void* mspace_realloc(mspace msp, void* oldmem, size_t bytes) {
4771
  if (oldmem == 0)
4772
    return mspace_malloc(msp, bytes);
4773
#ifdef REALLOC_ZERO_BYTES_FREES
4774
  if (bytes == 0) {
4775
    mspace_free(msp, oldmem);
4776
    return 0;
4777
  }
4778
#endif /* REALLOC_ZERO_BYTES_FREES */
4779
  else {
4780
#if FOOTERS
4781
    mchunkptr p  = mem2chunk(oldmem);
4782
    mstate ms = get_mstate_for(p);
4783
#else /* FOOTERS */
4784
    mstate ms = (mstate)msp;
4785
#endif /* FOOTERS */
4786
    if (!ok_magic(ms)) {
4787
      USAGE_ERROR_ACTION(ms,ms);
4788
      return 0;
4789
    }
4790
    return internal_realloc(ms, oldmem, bytes);
4791
  }
4792
}
4793
 
4794
void* mspace_memalign(mspace msp, size_t alignment, size_t bytes) {
4795
  mstate ms = (mstate)msp;
4796
  if (!ok_magic(ms)) {
4797
    USAGE_ERROR_ACTION(ms,ms);
4798
    return 0;
4799
  }
4800
  return internal_memalign(ms, alignment, bytes);
4801
}
4802
 
4803
void** mspace_independent_calloc(mspace msp, size_t n_elements,
4804
                                 size_t elem_size, void* chunks[]) {
4805
  size_t sz = elem_size; /* serves as 1-element array */
4806
  mstate ms = (mstate)msp;
4807
  if (!ok_magic(ms)) {
4808
    USAGE_ERROR_ACTION(ms,ms);
4809
    return 0;
4810
  }
4811
  return ialloc(ms, n_elements, &sz, 3, chunks);
4812
}
4813
 
4814
void** mspace_independent_comalloc(mspace msp, size_t n_elements,
4815
                                   size_t sizes[], void* chunks[]) {
4816
  mstate ms = (mstate)msp;
4817
  if (!ok_magic(ms)) {
4818
    USAGE_ERROR_ACTION(ms,ms);
4819
    return 0;
4820
  }
4821
  return ialloc(ms, n_elements, sizes, 0, chunks);
4822
}
4823
 
4824
int mspace_trim(mspace msp, size_t pad) {
4825
  int result = 0;
4826
  mstate ms = (mstate)msp;
4827
  if (ok_magic(ms)) {
4828
    if (!PREACTION(ms)) {
4829
      result = sys_trim(ms, pad);
4830
      POSTACTION(ms);
4831
    }
4832
  }
4833
  else {
4834
    USAGE_ERROR_ACTION(ms,ms);
4835
  }
4836
  return result;
4837
}
4838
 
4839
void mspace_malloc_stats(mspace msp) {
4840
  mstate ms = (mstate)msp;
4841
  if (ok_magic(ms)) {
4842
    internal_malloc_stats(ms);
4843
  }
4844
  else {
4845
    USAGE_ERROR_ACTION(ms,ms);
4846
  }
4847
}
4848
 
4849
size_t mspace_footprint(mspace msp) {
4850
  size_t result;
4851
  mstate ms = (mstate)msp;
4852
  if (ok_magic(ms)) {
4853
    result = ms->footprint;
4854
  }
4855
  USAGE_ERROR_ACTION(ms,ms);
4856
  return result;
4857
}
4858
 
4859
 
4860
size_t mspace_max_footprint(mspace msp) {
4861
  size_t result;
4862
  mstate ms = (mstate)msp;
4863
  if (ok_magic(ms)) {
4864
    result = ms->max_footprint;
4865
  }
4866
  USAGE_ERROR_ACTION(ms,ms);
4867
  return result;
4868
}
4869
 
4870
 
4871
#if !NO_MALLINFO
4872
struct mallinfo mspace_mallinfo(mspace msp) {
4873
  mstate ms = (mstate)msp;
4874
  if (!ok_magic(ms)) {
4875
    USAGE_ERROR_ACTION(ms,ms);
4876
  }
4877
  return internal_mallinfo(ms);
4878
}
4879
#endif /* NO_MALLINFO */
4880
 
4881
int mspace_mallopt(int param_number, int value) {
4882
  return change_mparam(param_number, value);
4883
}
4884
 
4885
#endif /* MSPACES */
4886
 
4887
/* -------------------- Alternative MORECORE functions ------------------- */
4888
 
4889
/*
4890
  Guidelines for creating a custom version of MORECORE:
4891
 
4892
  * For best performance, MORECORE should allocate in multiples of pagesize.
4893
  * MORECORE may allocate more memory than requested. (Or even less,
4894
      but this will usually result in a malloc failure.)
4895
  * MORECORE must not allocate memory when given argument zero, but
4896
      instead return one past the end address of memory from previous
4897
      nonzero call.
4898
  * For best performance, consecutive calls to MORECORE with positive
4899
      arguments should return increasing addresses, indicating that
4900
      space has been contiguously extended.
4901
  * Even though consecutive calls to MORECORE need not return contiguous
4902
      addresses, it must be OK for malloc'ed chunks to span multiple
4903
      regions in those cases where they do happen to be contiguous.
4904
  * MORECORE need not handle negative arguments -- it may instead
4905
      just return MFAIL when given negative arguments.
4906
      Negative arguments are always multiples of pagesize. MORECORE
4907
      must not misinterpret negative args as large positive unsigned
4908
      args. You can suppress all such calls from even occurring by defining
4909
      MORECORE_CANNOT_TRIM,
4910
 
4911
  As an example alternative MORECORE, here is a custom allocator
4912
  kindly contributed for pre-OSX macOS.  It uses virtually but not
4913
  necessarily physically contiguous non-paged memory (locked in,
4914
  present and won't get swapped out).  You can use it by uncommenting
4915
  this section, adding some #includes, and setting up the appropriate
4916
  defines above:
4917
 
4918
      #define MORECORE osMoreCore
4919
 
4920
  There is also a shutdown routine that should somehow be called for
4921
  cleanup upon program exit.
4922
 
4923
  #define MAX_POOL_ENTRIES 100
4924
  #define MINIMUM_MORECORE_SIZE  (64 * 1024U)
4925
  static int next_os_pool;
4926
  void *our_os_pools[MAX_POOL_ENTRIES];
4927
 
4928
  void *osMoreCore(int size)
4929
  {
4930
    void *ptr = 0;
4931
    static void *sbrk_top = 0;
4932
 
4933
    if (size > 0)
4934
    {
4935
      if (size < MINIMUM_MORECORE_SIZE)
4936
         size = MINIMUM_MORECORE_SIZE;
4937
      if (CurrentExecutionLevel() == kTaskLevel)
4938
         ptr = PoolAllocateResident(size + RM_PAGE_SIZE, 0);
4939
      if (ptr == 0)
4940
      {
4941
        return (void *) MFAIL;
4942
      }
4943
      // save ptrs so they can be freed during cleanup
4944
      our_os_pools[next_os_pool] = ptr;
4945
      next_os_pool++;
4946
      ptr = (void *) ((((size_t) ptr) + RM_PAGE_MASK) & ~RM_PAGE_MASK);
4947
      sbrk_top = (char *) ptr + size;
4948
      return ptr;
4949
    }
4950
    else if (size < 0)
4951
    {
4952
      // we don't currently support shrink behavior
4953
      return (void *) MFAIL;
4954
    }
4955
    else
4956
    {
4957
      return sbrk_top;
4958
    }
4959
  }
4960
 
4961
  // cleanup any allocated memory pools
4962
  // called as last thing before shutting down driver
4963
 
4964
  void osCleanupMem(void)
4965
  {
4966
    void **ptr;
4967
 
4968
    for (ptr = our_os_pools; ptr < &our_os_pools[MAX_POOL_ENTRIES]; ptr++)
4969
      if (*ptr)
4970
      {
4971
         PoolDeallocate(*ptr);
4972
         *ptr = 0;
4973
      }
4974
  }
4975
 
4976
*/
4977
 
4978
 
4979
/* -----------------------------------------------------------------------
4980
History:
4981
    V2.8.3 Thu Sep 22 11:16:32 2005  Doug Lea  (dl at gee)
4982
      * Add max_footprint functions
4983
      * Ensure all appropriate literals are size_t
4984
      * Fix conditional compilation problem for some #define settings
4985
      * Avoid concatenating segments with the one provided
4986
        in create_mspace_with_base
4987
      * Rename some variables to avoid compiler shadowing warnings
4988
      * Use explicit lock initialization.
4989
      * Better handling of sbrk interference.
4990
      * Simplify and fix segment insertion, trimming and mspace_destroy
4991
      * Reinstate REALLOC_ZERO_BYTES_FREES option from 2.7.x
4992
      * Thanks especially to Dennis Flanagan for help on these.
4993
 
4994
    V2.8.2 Sun Jun 12 16:01:10 2005  Doug Lea  (dl at gee)
4995
      * Fix memalign brace error.
4996
 
4997
    V2.8.1 Wed Jun  8 16:11:46 2005  Doug Lea  (dl at gee)
4998
      * Fix improper #endif nesting in C++
4999
      * Add explicit casts needed for C++
5000
 
5001
    V2.8.0 Mon May 30 14:09:02 2005  Doug Lea  (dl at gee)
5002
      * Use trees for large bins
5003
      * Support mspaces
5004
      * Use segments to unify sbrk-based and mmap-based system allocation,
5005
        removing need for emulation on most platforms without sbrk.
5006
      * Default safety checks
5007
      * Optional footer checks. Thanks to William Robertson for the idea.
5008
      * Internal code refactoring
5009
      * Incorporate suggestions and platform-specific changes.
5010
        Thanks to Dennis Flanagan, Colin Plumb, Niall Douglas,
5011
        Aaron Bachmann,  Emery Berger, and others.
5012
      * Speed up non-fastbin processing enough to remove fastbins.
5013
      * Remove useless cfree() to avoid conflicts with other apps.
5014
      * Remove internal memcpy, memset. Compilers handle builtins better.
5015
      * Remove some options that no one ever used and rename others.
5016
 
5017
    V2.7.2 Sat Aug 17 09:07:30 2002  Doug Lea  (dl at gee)
5018
      * Fix malloc_state bitmap array misdeclaration
5019
 
5020
    V2.7.1 Thu Jul 25 10:58:03 2002  Doug Lea  (dl at gee)
5021
      * Allow tuning of FIRST_SORTED_BIN_SIZE
5022
      * Use PTR_UINT as type for all ptr->int casts. Thanks to John Belmonte.
5023
      * Better detection and support for non-contiguousness of MORECORE.
5024
        Thanks to Andreas Mueller, Conal Walsh, and Wolfram Gloger
5025
      * Bypass most of malloc if no frees. Thanks To Emery Berger.
5026
      * Fix freeing of old top non-contiguous chunk im sysmalloc.
5027
      * Raised default trim and map thresholds to 256K.
5028
      * Fix mmap-related #defines. Thanks to Lubos Lunak.
5029
      * Fix copy macros; added LACKS_FCNTL_H. Thanks to Neal Walfield.
5030
      * Branch-free bin calculation
5031
      * Default trim and mmap thresholds now 256K.
5032
 
5033
    V2.7.0 Sun Mar 11 14:14:06 2001  Doug Lea  (dl at gee)
5034
      * Introduce independent_comalloc and independent_calloc.
5035
        Thanks to Michael Pachos for motivation and help.
5036
      * Make optional .h file available
5037
      * Allow > 2GB requests on 32bit systems.
5038
      * new WIN32 sbrk, mmap, munmap, lock code from <Walter@GeNeSys-e.de>.
5039
        Thanks also to Andreas Mueller <a.mueller at paradatec.de>,
5040
        and Anonymous.
5041
      * Allow override of MALLOC_ALIGNMENT (Thanks to Ruud Waij for
5042
        helping test this.)
5043
      * memalign: check alignment arg
5044
      * realloc: don't try to shift chunks backwards, since this
5045
        leads to  more fragmentation in some programs and doesn't
5046
        seem to help in any others.
5047
      * Collect all cases in malloc requiring system memory into sysmalloc
5048
      * Use mmap as backup to sbrk
5049
      * Place all internal state in malloc_state
5050
      * Introduce fastbins (although similar to 2.5.1)
5051
      * Many minor tunings and cosmetic improvements
5052
      * Introduce USE_PUBLIC_MALLOC_WRAPPERS, USE_MALLOC_LOCK
5053
      * Introduce MALLOC_FAILURE_ACTION, MORECORE_CONTIGUOUS
5054
        Thanks to Tony E. Bennett <tbennett@nvidia.com> and others.
5055
      * Include errno.h to support default failure action.
5056
 
5057
    V2.6.6 Sun Dec  5 07:42:19 1999  Doug Lea  (dl at gee)
5058
      * return null for negative arguments
5059
      * Added Several WIN32 cleanups from Martin C. Fong <mcfong at yahoo.com>
5060
         * Add 'LACKS_SYS_PARAM_H' for those systems without 'sys/param.h'
5061
          (e.g. WIN32 platforms)
5062
         * Cleanup header file inclusion for WIN32 platforms
5063
         * Cleanup code to avoid Microsoft Visual C++ compiler complaints
5064
         * Add 'USE_DL_PREFIX' to quickly allow co-existence with existing
5065
           memory allocation routines
5066
         * Set 'malloc_getpagesize' for WIN32 platforms (needs more work)
5067
         * Use 'assert' rather than 'ASSERT' in WIN32 code to conform to
5068
           usage of 'assert' in non-WIN32 code
5069
         * Improve WIN32 'sbrk()' emulation's 'findRegion()' routine to
5070
           avoid infinite loop
5071
      * Always call 'fREe()' rather than 'free()'
5072
 
5073
    V2.6.5 Wed Jun 17 15:57:31 1998  Doug Lea  (dl at gee)
5074
      * Fixed ordering problem with boundary-stamping
5075
 
5076
    V2.6.3 Sun May 19 08:17:58 1996  Doug Lea  (dl at gee)
5077
      * Added pvalloc, as recommended by H.J. Liu
5078
      * Added 64bit pointer support mainly from Wolfram Gloger
5079
      * Added anonymously donated WIN32 sbrk emulation
5080
      * Malloc, calloc, getpagesize: add optimizations from Raymond Nijssen
5081
      * malloc_extend_top: fix mask error that caused wastage after
5082
        foreign sbrks
5083
      * Add linux mremap support code from HJ Liu
5084
 
5085
    V2.6.2 Tue Dec  5 06:52:55 1995  Doug Lea  (dl at gee)
5086
      * Integrated most documentation with the code.
5087
      * Add support for mmap, with help from
5088
        Wolfram Gloger (Gloger@lrz.uni-muenchen.de).
5089
      * Use last_remainder in more cases.
5090
      * Pack bins using idea from  colin@nyx10.cs.du.edu
5091
      * Use ordered bins instead of best-fit threshhold
5092
      * Eliminate block-local decls to simplify tracing and debugging.
5093
      * Support another case of realloc via move into top
5094
      * Fix error occuring when initial sbrk_base not word-aligned.
5095
      * Rely on page size for units instead of SBRK_UNIT to
5096
        avoid surprises about sbrk alignment conventions.
5097
      * Add mallinfo, mallopt. Thanks to Raymond Nijssen
5098
        (raymond@es.ele.tue.nl) for the suggestion.
5099
      * Add `pad' argument to malloc_trim and top_pad mallopt parameter.
5100
      * More precautions for cases where other routines call sbrk,
5101
        courtesy of Wolfram Gloger (Gloger@lrz.uni-muenchen.de).
5102
      * Added macros etc., allowing use in linux libc from
5103
        H.J. Lu (hjl@gnu.ai.mit.edu)
5104
      * Inverted this history list
5105
 
5106
    V2.6.1 Sat Dec  2 14:10:57 1995  Doug Lea  (dl at gee)
5107
      * Re-tuned and fixed to behave more nicely with V2.6.0 changes.
5108
      * Removed all preallocation code since under current scheme
5109
        the work required to undo bad preallocations exceeds
5110
        the work saved in good cases for most test programs.
5111
      * No longer use return list or unconsolidated bins since
5112
        no scheme using them consistently outperforms those that don't
5113
        given above changes.
5114
      * Use best fit for very large chunks to prevent some worst-cases.
5115
      * Added some support for debugging
5116
 
5117
    V2.6.0 Sat Nov  4 07:05:23 1995  Doug Lea  (dl at gee)
5118
      * Removed footers when chunks are in use. Thanks to
5119
        Paul Wilson (wilson@cs.texas.edu) for the suggestion.
5120
 
5121
    V2.5.4 Wed Nov  1 07:54:51 1995  Doug Lea  (dl at gee)
5122
      * Added malloc_trim, with help from Wolfram Gloger
5123
        (wmglo@Dent.MED.Uni-Muenchen.DE).
5124
 
5125
    V2.5.3 Tue Apr 26 10:16:01 1994  Doug Lea  (dl at g)
5126
 
5127
    V2.5.2 Tue Apr  5 16:20:40 1994  Doug Lea  (dl at g)
5128
      * realloc: try to expand in both directions
5129
      * malloc: swap order of clean-bin strategy;
5130
      * realloc: only conditionally expand backwards
5131
      * Try not to scavenge used bins
5132
      * Use bin counts as a guide to preallocation
5133
      * Occasionally bin return list chunks in first scan
5134
      * Add a few optimizations from colin@nyx10.cs.du.edu
5135
 
5136
    V2.5.1 Sat Aug 14 15:40:43 1993  Doug Lea  (dl at g)
5137
      * faster bin computation & slightly different binning
5138
      * merged all consolidations to one part of malloc proper
5139
         (eliminating old malloc_find_space & malloc_clean_bin)
5140
      * Scan 2 returns chunks (not just 1)
5141
      * Propagate failure in realloc if malloc returns 0
5142
      * Add stuff to allow compilation on non-ANSI compilers
5143
          from kpv@research.att.com
5144
 
5145
    V2.5 Sat Aug  7 07:41:59 1993  Doug Lea  (dl at g.oswego.edu)
5146
      * removed potential for odd address access in prev_chunk
5147
      * removed dependency on getpagesize.h
5148
      * misc cosmetics and a bit more internal documentation
5149
      * anticosmetics: mangled names in macros to evade debugger strangeness
5150
      * tested on sparc, hp-700, dec-mips, rs6000
5151
          with gcc & native cc (hp, dec only) allowing
5152
          Detlefs & Zorn comparison study (in SIGPLAN Notices.)
5153
 
5154
    Trial version Fri Aug 28 13:14:29 1992  Doug Lea  (dl at g.oswego.edu)
5155
      * Based loosely on libg++-1.2X malloc. (It retains some of the overall
5156
         structure of old version,  but most details differ.)
5157
 
5158
*/

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