FD.io VPP  v19.01.1-17-ge106252
Vector Packet Processing
pool.h
Go to the documentation of this file.
1 /*
2  * Copyright (c) 2015 Cisco and/or its affiliates.
3  * Licensed under the Apache License, Version 2.0 (the "License");
4  * you may not use this file except in compliance with the License.
5  * You may obtain a copy of the License at:
6  *
7  * http://www.apache.org/licenses/LICENSE-2.0
8  *
9  * Unless required by applicable law or agreed to in writing, software
10  * distributed under the License is distributed on an "AS IS" BASIS,
11  * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
12  * See the License for the specific language governing permissions and
13  * limitations under the License.
14  */
15 /*
16  Copyright (c) 2001, 2002, 2003, 2004 Eliot Dresselhaus
17 
18  Permission is hereby granted, free of charge, to any person obtaining
19  a copy of this software and associated documentation files (the
20  "Software"), to deal in the Software without restriction, including
21  without limitation the rights to use, copy, modify, merge, publish,
22  distribute, sublicense, and/or sell copies of the Software, and to
23  permit persons to whom the Software is furnished to do so, subject to
24  the following conditions:
25 
26  The above copyright notice and this permission notice shall be
27  included in all copies or substantial portions of the Software.
28 
29  THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND,
30  EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF
31  MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND
32  NONINFRINGEMENT. IN NO EVENT SHALL THE AUTHORS OR COPYRIGHT HOLDERS BE
33  LIABLE FOR ANY CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER IN AN ACTION
34  OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN CONNECTION
35  WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE.
36 */
37 /** @file
38  * @brief Fixed length block allocator.
39  Pools are built from clib vectors and bitmaps. Use pools when
40  repeatedly allocating and freeing fixed-size data. Pools are
41  fast, and avoid memory fragmentation.
42  */
43 
44 #ifndef included_pool_h
45 #define included_pool_h
46 
47 #include <vppinfra/bitmap.h>
48 #include <vppinfra/error.h>
49 #include <vppinfra/mheap.h>
50 
51 
52 typedef struct
53 {
54  /** Bitmap of indices of free objects. */
55  uword *free_bitmap;
56 
57  /** Vector of free indices. One element for each set bit in bitmap. */
58  u32 *free_indices;
59 
60  /* The following fields are set for fixed-size, preallocated pools */
61 
62  /** Maximum size of the pool, in elements */
63  u32 max_elts;
64 
65  /** mmap segment info: base + length */
66  u8 *mmap_base;
67  u64 mmap_size;
68 
69 } pool_header_t;
70 
71 /** Align pool header so that pointers are naturally aligned. */
72 #define pool_aligned_header_bytes \
73  vec_aligned_header_bytes (sizeof (pool_header_t), sizeof (void *))
74 
75 /** Get pool header from user pool pointer */
76 always_inline pool_header_t *
77 pool_header (void *v)
78 {
79  return vec_aligned_header (v, sizeof (pool_header_t), sizeof (void *));
80 }
81 
82 extern void _pool_init_fixed (void **, u32, u32);
83 extern void fpool_free (void *);
84 
85 /** initialize a fixed-size, preallocated pool */
86 #define pool_init_fixed(pool,max_elts) \
87 { \
88  _pool_init_fixed((void **)&(pool),sizeof(pool[0]),max_elts); \
89 }
90 
91 /** Validate a pool */
92 always_inline void
93 pool_validate (void *v)
94 {
95  pool_header_t *p = pool_header (v);
96  uword i, n_free_bitmap;
97 
98  if (!v)
99  return;
100 
101  n_free_bitmap = clib_bitmap_count_set_bits (p->free_bitmap);
102  ASSERT (n_free_bitmap == vec_len (p->free_indices));
103  for (i = 0; i < vec_len (p->free_indices); i++)
104  ASSERT (clib_bitmap_get (p->free_bitmap, p->free_indices[i]) == 1);
105 }
106 
107 always_inline void
108 pool_header_validate_index (void *v, uword index)
109 {
110  pool_header_t *p = pool_header (v);
111 
112  if (v)
113  vec_validate (p->free_bitmap, index / BITS (uword));
114 }
115 
116 #define pool_validate_index(v,i) \
117 do { \
118  uword __pool_validate_index = (i); \
119  vec_validate_ha ((v), __pool_validate_index, \
120  pool_aligned_header_bytes, /* align */ 0); \
121  pool_header_validate_index ((v), __pool_validate_index); \
122 } while (0)
123 
124 /** Number of active elements in a pool.
125  * @return Number of active elements in a pool
126  */
127 always_inline uword
128 pool_elts (void *v)
129 {
130  uword ret = vec_len (v);
131  if (v)
132  ret -= vec_len (pool_header (v)->free_indices);
133  return ret;
134 }
135 
136 /** Number of elements in pool vector.
137 
138  @note You probably want to call pool_elts() instead.
139 */
140 #define pool_len(p) vec_len(p)
141 
142 /** Number of elements in pool vector (usable as an lvalue)
143 
144  @note You probably don't want to use this macro.
145 */
146 #define _pool_len(p) _vec_len(p)
147 
148 /** Memory usage of pool header. */
149 always_inline uword
150 pool_header_bytes (void *v)
151 {
152  pool_header_t *p = pool_header (v);
153 
154  if (!v)
155  return 0;
156 
157  return vec_bytes (p->free_bitmap) + vec_bytes (p->free_indices);
158 }
159 
160 /** Memory usage of pool. */
161 #define pool_bytes(P) (vec_bytes (P) + pool_header_bytes (P))
162 
163 /** Local variable naming macro. */
164 #define _pool_var(v) _pool_##v
165 
166 /** Queries whether pool has at least N_FREE free elements. */
167 always_inline uword
168 pool_free_elts (void *v)
169 {
170  pool_header_t *p = pool_header (v);
171  uword n_free = 0;
172 
173  if (v)
174  {
175  n_free += vec_len (p->free_indices);
176 
177  /* Space left at end of vector? */
178  n_free += vec_capacity (v, sizeof (p[0])) - vec_len (v);
179  }
180 
181  return n_free;
182 }
183 
184 /** Allocate an object E from a pool P (general version).
185 
186  First search free list. If nothing is free extend vector of objects.
187 */
188 #define _pool_get_aligned_internal(P,E,A,Z) \
189 do { \
190  pool_header_t * _pool_var (p) = pool_header (P); \
191  uword _pool_var (l); \
192  \
193  STATIC_ASSERT(A==0 || ((A % sizeof(P[0]))==0) || ((sizeof(P[0]) % A) == 0), \
194  "Pool aligned alloc of incorrectly sized object"); \
195  _pool_var (l) = 0; \
196  if (P) \
197  _pool_var (l) = vec_len (_pool_var (p)->free_indices); \
198  \
199  if (_pool_var (l) > 0) \
200  { \
201  /* Return free element from free list. */ \
202  uword _pool_var (i) = _pool_var (p)->free_indices[_pool_var (l) - 1]; \
203  (E) = (P) + _pool_var (i); \
204  _pool_var (p)->free_bitmap = \
205  clib_bitmap_andnoti_notrim (_pool_var (p)->free_bitmap, \
206  _pool_var (i)); \
207  _vec_len (_pool_var (p)->free_indices) = _pool_var (l) - 1; \
208  } \
209  else \
210  { \
211  /* fixed-size, preallocated pools cannot expand */ \
212  if ((P) && _pool_var(p)->max_elts) \
213  { \
214  clib_warning ("can't expand fixed-size pool"); \
215  os_out_of_memory(); \
216  } \
217  /* Nothing on free list, make a new element and return it. */ \
218  P = _vec_resize (P, \
219  /* length_increment */ 1, \
220  /* new size */ (vec_len (P) + 1) * sizeof (P[0]), \
221  pool_aligned_header_bytes, \
222  /* align */ (A)); \
223  E = vec_end (P) - 1; \
224  } \
225  if (Z) \
226  memset(E, 0, sizeof(*E)); \
227 } while (0)
228 
229 /** Allocate an object E from a pool P with alignment A */
230 #define pool_get_aligned(P,E,A) _pool_get_aligned_internal(P,E,A,0)
231 
232 /** Allocate an object E from a pool P with alignment A and zero it */
233 #define pool_get_aligned_zero(P,E,A) _pool_get_aligned_internal(P,E,A,1)
234 
235 /** Allocate an object E from a pool P (unspecified alignment). */
236 #define pool_get(P,E) pool_get_aligned(P,E,0)
237 
238 /** Allocate an object E from a pool P and zero it */
239 #define pool_get_zero(P,E) pool_get_aligned_zero(P,E,0)
240 
241 /** See if pool_get will expand the pool or not */
242 #define pool_get_aligned_will_expand(P,YESNO,A) \
243 do { \
244  pool_header_t * _pool_var (p) = pool_header (P); \
245  uword _pool_var (l); \
246  \
247  _pool_var (l) = 0; \
248  if (P) \
249  { \
250  if (_pool_var (p)->max_elts) \
251  _pool_var (l) = _pool_var (p)->max_elts; \
252  else \
253  _pool_var (l) = vec_len (_pool_var (p)->free_indices); \
254  } \
255  \
256  /* Free elements, certainly won't expand */ \
257  if (_pool_var (l) > 0) \
258  YESNO=0; \
259  else \
260  { \
261  /* Nothing on free list, make a new element and return it. */ \
262  YESNO = _vec_resize_will_expand \
263  (P, \
264  /* length_increment */ 1, \
265  /* new size */ (vec_len (P) + 1) * sizeof (P[0]), \
266  pool_aligned_header_bytes, \
267  /* align */ (A)); \
268  } \
269 } while (0)
270 
271 /** Tell the caller if pool get will expand the pool */
272 #define pool_get_will_expand(P,YESNO) pool_get_aligned_will_expand(P,YESNO,0)
273 
274 /** Use free bitmap to query whether given element is free. */
275 #define pool_is_free(P,E) \
276 ({ \
277  pool_header_t * _pool_var (p) = pool_header (P); \
278  uword _pool_var (i) = (E) - (P); \
279  (_pool_var (i) < vec_len (P)) ? clib_bitmap_get (_pool_var (p)->free_bitmap, _pool_i) : 1; \
280 })
281 
282 /** Use free bitmap to query whether given index is free */
283 #define pool_is_free_index(P,I) pool_is_free((P),(P)+(I))
284 
285 /** Free an object E in pool P. */
286 #define pool_put(P,E) \
287 do { \
288  pool_header_t * _pool_var (p) = pool_header (P); \
289  uword _pool_var (l) = (E) - (P); \
290  ASSERT (vec_is_member (P, E)); \
291  ASSERT (! pool_is_free (P, E)); \
292  \
293  /* Add element to free bitmap and to free list. */ \
294  _pool_var (p)->free_bitmap = \
295  clib_bitmap_ori_notrim (_pool_var (p)->free_bitmap, \
296  _pool_var (l)); \
297  \
298  /* Preallocated pool? */ \
299  if (_pool_var (p)->max_elts) \
300  { \
301  ASSERT(_pool_var(l) < _pool_var (p)->max_elts); \
302  _pool_var(p)->free_indices[_vec_len(_pool_var(p)->free_indices)] = \
303  _pool_var(l); \
304  _vec_len(_pool_var(p)->free_indices) += 1; \
305  } \
306  else \
307  vec_add1 (_pool_var (p)->free_indices, _pool_var (l)); \
308 } while (0)
309 
310 /** Free pool element with given index. */
311 #define pool_put_index(p,i) \
312 do { \
313  typeof (p) _e = (p) + (i); \
314  pool_put (p, _e); \
315 } while (0)
316 
317 /** Allocate N more free elements to pool (general version). */
318 #define pool_alloc_aligned(P,N,A) \
319 do { \
320  pool_header_t * _p; \
321  \
322  if ((P)) \
323  { \
324  _p = pool_header (P); \
325  if (_p->max_elts) \
326  { \
327  clib_warning ("Can't expand fixed-size pool"); \
328  os_out_of_memory(); \
329  } \
330  } \
331  \
332  (P) = _vec_resize ((P), 0, (vec_len (P) + (N)) * sizeof (P[0]), \
333  pool_aligned_header_bytes, \
334  (A)); \
335  _p = pool_header (P); \
336  vec_resize (_p->free_indices, (N)); \
337  _vec_len (_p->free_indices) -= (N); \
338 } while (0)
339 
340 /** Allocate N more free elements to pool (unspecified alignment). */
341 #define pool_alloc(P,N) pool_alloc_aligned(P,N,0)
342 
343 /**
344  * Return copy of pool with alignment
345  *
346  * @param P pool to copy
347  * @param A alignment (may be zero)
348  * @return copy of pool
349  */
350 #define pool_dup_aligned(P,A) \
351 ({ \
352  typeof (P) _pool_var (new) = 0; \
353  pool_header_t * _pool_var (ph), * _pool_var (new_ph); \
354  u32 _pool_var (n) = pool_len (P); \
355  _pool_var (new) = _vec_resize (_pool_var (new), _pool_var (n), \
356  _pool_var (n) * sizeof ((P)[0]), \
357  pool_aligned_header_bytes, (A)); \
358  clib_memcpy_fast (_pool_var (new), (P), \
359  _pool_var (n) * sizeof ((P)[0])); \
360  _pool_var (ph) = pool_header (P); \
361  _pool_var (new_ph) = pool_header (_pool_var (new)); \
362  _pool_var (new_ph)->free_bitmap = \
363  clib_bitmap_dup (_pool_var (ph)->free_bitmap); \
364  _pool_var (new_ph)->free_indices = \
365  vec_dup (_pool_var (ph)->free_indices); \
366  _pool_var (new_ph)->max_elts = _pool_var (ph)->max_elts; \
367  _pool_var (new); \
368 })
369 
370 /**
371  * Return copy of pool without alignment
372  *
373  * @param P pool to copy
374  * @return copy of pool
375  */
376 #define pool_dup(P) pool_dup_aligned(P,0)
377 
378 /** Low-level free pool operator (do not call directly). */
379 always_inline void *
380 _pool_free (void *v)
381 {
382  pool_header_t *p = pool_header (v);
383  if (!v)
384  return v;
385  clib_bitmap_free (p->free_bitmap);
386 
387  if (p->max_elts)
388  {
389  int rv;
390 
391  rv = munmap (p->mmap_base, p->mmap_size);
392  if (rv)
393  clib_unix_warning ("munmap");
394  }
395  else
396  {
397  vec_free (p->free_indices);
398  vec_free_h (v, pool_aligned_header_bytes);
399  }
400  return 0;
401 }
402 
403 /** Free a pool. */
404 #define pool_free(p) (p) = _pool_free(p)
405 
406 /** Optimized iteration through pool.
407 
408  @param LO pointer to first element in chunk
409  @param HI pointer to last element in chunk
410  @param POOL pool to iterate across
411  @param BODY operation to perform
412 
413  Optimized version which assumes that BODY is smart enough to
414  process multiple (LOW,HI) chunks. See also pool_foreach().
415  */
416 #define pool_foreach_region(LO,HI,POOL,BODY) \
417 do { \
418  uword _pool_var (i), _pool_var (lo), _pool_var (hi), _pool_var (len); \
419  uword _pool_var (bl), * _pool_var (b); \
420  pool_header_t * _pool_var (p); \
421  \
422  _pool_var (p) = pool_header (POOL); \
423  _pool_var (b) = (POOL) ? _pool_var (p)->free_bitmap : 0; \
424  _pool_var (bl) = vec_len (_pool_var (b)); \
425  _pool_var (len) = vec_len (POOL); \
426  _pool_var (lo) = 0; \
427  \
428  for (_pool_var (i) = 0; \
429  _pool_var (i) <= _pool_var (bl); \
430  _pool_var (i)++) \
431  { \
432  uword _pool_var (m), _pool_var (f); \
433  _pool_var (m) = (_pool_var (i) < _pool_var (bl) \
434  ? _pool_var (b) [_pool_var (i)] \
435  : 1); \
436  while (_pool_var (m) != 0) \
437  { \
438  _pool_var (f) = first_set (_pool_var (m)); \
439  _pool_var (hi) = (_pool_var (i) * BITS (_pool_var (b)[0]) \
440  + min_log2 (_pool_var (f))); \
441  _pool_var (hi) = (_pool_var (i) < _pool_var (bl) \
442  ? _pool_var (hi) : _pool_var (len)); \
443  _pool_var (m) ^= _pool_var (f); \
444  if (_pool_var (hi) > _pool_var (lo)) \
445  { \
446  (LO) = _pool_var (lo); \
447  (HI) = _pool_var (hi); \
448  do { BODY; } while (0); \
449  } \
450  _pool_var (lo) = _pool_var (hi) + 1; \
451  } \
452  } \
453 } while (0)
454 
455 /** Iterate through pool.
456 
457  @param VAR A variable of same type as pool vector to be used as an
458  iterator.
459  @param POOL The pool to iterate across.
460  @param BODY The operation to perform, typically a code block. See
461  the example below.
462 
463  This macro will call @c BODY with each active pool element.
464 
465  It is a bad idea to allocate or free pool element from within
466  @c pool_foreach. Build a vector of indices and dispose of them later.
467  Or call pool_flush.
468 
469 
470  @par Example
471  @code{.c}
472  proc_t *procs; // a pool of processes.
473  proc_t *proc; // pointer to one process; used as the iterator.
474 
475  pool_foreach (proc, procs, ({
476  if (proc->state != PROC_STATE_RUNNING)
477  continue;
478 
479  // check a running proc in some way
480  ...
481  }));
482  @endcode
483 
484  @warning Because @c pool_foreach is a macro, syntax errors can be
485  difficult to find inside @c BODY, let alone actual code bugs. One
486  can temporarily split a complex @c pool_foreach into a trivial
487  @c pool_foreach which builds a vector of active indices, and a
488  vec_foreach() (or plain for-loop) to walk the active index vector.
489  */
490 #define pool_foreach(VAR,POOL,BODY) \
491 do { \
492  uword _pool_foreach_lo, _pool_foreach_hi; \
493  pool_foreach_region (_pool_foreach_lo, _pool_foreach_hi, (POOL), \
494  ({ \
495  for ((VAR) = (POOL) + _pool_foreach_lo; \
496  (VAR) < (POOL) + _pool_foreach_hi; \
497  (VAR)++) \
498  do { BODY; } while (0); \
499  })); \
500 } while (0)
501 
502 /** Returns pointer to element at given index.
503 
504  ASSERTs that the supplied index is valid.
505  Even though one can write correct code of the form
506  @code
507  p = pool_base + index;
508  @endcode
509  use of @c pool_elt_at_index is strongly suggested.
510  */
511 #define pool_elt_at_index(p,i) \
512 ({ \
513  typeof (p) _e = (p) + (i); \
514  ASSERT (! pool_is_free (p, _e)); \
515  _e; \
516 })
517 
518 /** Return next occupied pool index after @c i, useful for safe iteration. */
519 #define pool_next_index(P,I) \
520 ({ \
521  pool_header_t * _pool_var (p) = pool_header (P); \
522  uword _pool_var (rv) = (I) + 1; \
523  \
524  _pool_var(rv) = \
525  (_pool_var (rv) < vec_len (P) ? \
526  clib_bitmap_next_clear (_pool_var (p)->free_bitmap, _pool_var(rv)) \
527  : ~0); \
528  _pool_var(rv) = \
529  (_pool_var (rv) < vec_len (P) ? \
530  _pool_var (rv) : ~0); \
531  _pool_var(rv); \
532 })
533 
534 /** Iterate pool by index. */
535 #define pool_foreach_index(i,v,body) \
536  for ((i) = 0; (i) < vec_len (v); (i)++) \
537  { \
538  if (! pool_is_free_index ((v), (i))) \
539  do { body; } while (0); \
540  }
541 
542 /**
543  * @brief Remove all elements from a pool in a safe way
544  *
545  * @param VAR each element in the pool
546  * @param POOL The pool to flush
547  * @param BODY The actions to perform on each element before it is returned to
548  * the pool. i.e. before it is 'freed'
549  */
550 #define pool_flush(VAR, POOL, BODY) \
551 { \
552  uword *_pool_var(ii), *_pool_var(dv) = NULL; \
553  \
554  pool_foreach((VAR), (POOL), \
555  ({ \
556  vec_add1(_pool_var(dv), (VAR) - (POOL)); \
557  })); \
558  vec_foreach(_pool_var(ii), _pool_var(dv)) \
559  { \
560  (VAR) = pool_elt_at_index((POOL), *_pool_var(ii)); \
561  do { BODY; } while (0); \
562  pool_put((POOL), (VAR)); \
563  } \
564  vec_free(_pool_var(dv)); \
565 }
566 
567 #endif /* included_pool_h */
568 
569 /*
570  * fd.io coding-style-patch-verification: ON
571  *
572  * Local Variables:
573  * eval: (c-set-style "gnu")
574  * End:
575  */
vec_validate
#define vec_validate(V, I)
Make sure vector is long enough for given index (no header, unspecified alignment) ...
Definition: vec.h:439
pool_header_t::mmap_size
u64 mmap_size
Definition: pool.h:67
u64
unsigned long u64
Definition: types.h:89
pool_header_validate_index
static void pool_header_validate_index(void *v, uword index)
Definition: pool.h:108
pool_header_t::free_indices
u32 * free_indices
Vector of free indices.
Definition: pool.h:58
i
int i
Definition: flowhash_template.h:376
vec_bytes
#define vec_bytes(v)
Number of data bytes in vector.
Definition: vec_bootstrap.h:153
u8
unsigned char u8
Definition: types.h:56
always_inline
#define always_inline
Definition: clib.h:98
u32
unsigned int u32
Definition: types.h:88
fpool_free
void fpool_free(void *)
pool_header
static pool_header_t * pool_header(void *v)
Get pool header from user pool pointer.
Definition: pool.h:77
pool_header_t
Definition: pool.h:52
pool_aligned_header_bytes
#define pool_aligned_header_bytes
Align pool header so that pointers are naturally aligned.
Definition: pool.h:72
pool_header_bytes
static uword pool_header_bytes(void *v)
Memory usage of pool header.
Definition: pool.h:150
pool_validate
static void pool_validate(void *v)
Validate a pool.
Definition: pool.h:93
vec_free
#define vec_free(V)
Free vector&#39;s memory (no header).
Definition: vec.h:341
vec_aligned_header
static void * vec_aligned_header(void *v, uword header_bytes, uword align)
Definition: vec_bootstrap.h:117
vec_capacity
#define vec_capacity(v, b)
Total number of bytes that can fit in vector with current allocation.
Definition: vec_bootstrap.h:157
clib_bitmap_get
static uword clib_bitmap_get(uword *ai, uword i)
Gets the ith bit value from a bitmap.
Definition: bitmap.h:197
ASSERT
#define ASSERT(truth)
Definition: error_bootstrap.h:69
bitmap.h
Bitmaps built as vectors of machine words.
clib_bitmap_free
#define clib_bitmap_free(v)
Free a bitmap.
Definition: bitmap.h:92
pool_header_t::free_bitmap
uword * free_bitmap
Bitmap of indices of free objects.
Definition: pool.h:55
clib_bitmap_count_set_bits
static uword clib_bitmap_count_set_bits(uword *ai)
Return the number of set bits in a bitmap.
Definition: bitmap.h:462
vec_free_h
#define vec_free_h(V, H)
Free vector&#39;s memory (general version)
Definition: vec.h:328
vec_len
#define vec_len(v)
Number of elements in vector (rvalue-only, NULL tolerant)
Definition: vec_bootstrap.h:143
uword
u64 uword
Definition: types.h:112
clib_unix_warning
#define clib_unix_warning(format, args...)
Definition: error.h:68
pool_header_t::max_elts
u32 max_elts
Maximum size of the pool, in elements.
Definition: pool.h:63
BITS
#define BITS(x)
Definition: clib.h:61
pool_free_elts
static uword pool_free_elts(void *v)
Queries whether pool has at least N_FREE free elements.
Definition: pool.h:168
pool_header_t::mmap_base
u8 * mmap_base
mmap segment info: base + length
Definition: pool.h:66
pool_elts
static uword pool_elts(void *v)
Number of active elements in a pool.
Definition: pool.h:128